diff --git a/.github/workflows/release.yml b/.github/workflows/release.yml deleted file mode 100644 index 740ee4a..0000000 --- a/.github/workflows/release.yml +++ /dev/null @@ -1,236 +0,0 @@ -name: release - -# Build the self-contained joltc binary for each platform and attach it to the -# GitHub Release when a v* tag is pushed. The binary bundles the runtime, -# compiler, jolt-core + stdlib source, the Chez boots, and a launcher stub, so it -# runs AND compiles jolt apps with no Chez or cc on the user's machine (jolt-eaj). -# -# No Apple notarization, mirroring dirge: macOS users who download the tarball -# clear Gatekeeper quarantine once (`xattr -d com.apple.quarantine joltc`), or -# install via a Homebrew tap that de-quarantines on install. -on: - push: - tags: - - 'v*' - workflow_dispatch: {} # dry-run the build matrix without tagging - -permissions: - contents: write # create/update the GitHub Release and upload assets - -jobs: - build: - name: build ${{ matrix.target }} - runs-on: ${{ matrix.os }} - strategy: - fail-fast: false - matrix: - include: - - os: ubuntu-latest - target: x86_64-linux - shell: bash - # No x86_64-macos: GitHub is retiring the macos-13 Intel runner (jobs - # queue forever). Intel Macs build from source. macos-14 is arm64. - - os: macos-14 - target: aarch64-macos - shell: bash - - os: windows-latest - target: x86_64-windows - shell: msys2 {0} - defaults: - run: - shell: ${{ matrix.shell }} - steps: - - uses: actions/checkout@v5 - with: - submodules: recursive # vendor/irregex, used by the Chez regex shim - - # --- Linux: build Chez from source. The apt chezscheme ships petite+scheme - # only, with no kernel dev files (libkernel.a, scheme.h), which build-joltc - # needs to cc-link. Same setup as .github/workflows/tests.yml. --- - - name: Install build dependencies (Linux) - if: runner.os == 'Linux' - run: | - sudo apt-get update - sudo apt-get install -y build-essential git liblz4-dev zlib1g-dev libncurses-dev uuid-dev - - - name: Cache Chez Scheme (Linux) - if: runner.os == 'Linux' - id: cache-chez - uses: actions/cache@v4 - with: - path: /opt/chez - key: chez-${{ runner.os }}-v10.4.1-x11off - - - name: Build Chez Scheme from source (Linux) - if: runner.os == 'Linux' && steps.cache-chez.outputs.cache-hit != 'true' - run: | - git clone --depth 1 --branch v10.4.1 https://github.com/cisco/ChezScheme.git /tmp/chez-src - cd /tmp/chez-src - ./configure --installprefix=/opt/chez --threads --disable-x11 - make -j"$(nproc)" - sudo make install - sudo chown -R "$USER" /opt/chez - - - name: Put chez on PATH (Linux) - if: runner.os == 'Linux' - run: | - # Installed as `scheme`; the build invokes `chez`. A wrapper that execs - # scheme keeps argv0 so Chez finds its boot files, and sits next to - # scheme so build.ss derives the csv dir (libkernel.a/scheme.h) from it. - printf '#!/bin/sh\nexec /opt/chez/bin/scheme "$@"\n' > /opt/chez/bin/chez - chmod +x /opt/chez/bin/chez - echo '/opt/chez/bin' >> "$GITHUB_PATH" - - # --- macOS: Homebrew chezscheme ships `chez` plus the csv kernel dev files - # (libkernel.a, scheme.h, *.boot), which is all build-joltc needs. --- - - name: Install Chez Scheme (macOS) - if: runner.os == 'macOS' - run: brew install chezscheme lz4 - - # --- Windows: MSYS2/MinGW-w64 toolchain + Chez built from source (ta6nt). - # The whole job runs in the msys2 shell so cc/xxd/paths behave; the - # produced joltc.exe is a plain Windows binary (no MSYS runtime dep). --- - - name: Set up MSYS2 (Windows) - if: runner.os == 'Windows' - uses: msys2/setup-msys2@v2 - with: - msystem: MINGW64 - update: false - # inherit the runner PATH so GITHUB_PATH additions (the chez wrapper - # dir) are visible inside the msys2 shell - path-type: inherit - install: >- - git make vim unzip zip - mingw-w64-x86_64-gcc - mingw-w64-x86_64-lz4 - mingw-w64-x86_64-zlib - mingw-w64-x86_64-ntldd - - - name: Cache Chez Scheme (Windows) - if: runner.os == 'Windows' - id: cache-chez-win - uses: actions/cache@v4 - with: - path: chez-install - key: chez-${{ runner.os }}-v10.4.1-mingw64 - - - name: Build Chez Scheme from source (Windows) - if: runner.os == 'Windows' && steps.cache-chez-win.outputs.cache-hit != 'true' - run: | - git clone --depth 1 --branch v10.4.1 https://github.com/cisco/ChezScheme.git /tmp/chez-src - cd /tmp/chez-src - ./configure --threads - make -j"$(nproc)" - # `make install` drives the unix installsh through cmd and dies; the - # build tree has everything — assemble the layout by hand. Boot files - # sit next to scheme.exe (that's where the Windows kernel looks). - inst="$GITHUB_WORKSPACE/chez-install" - mkdir -p "$inst/bin" "$inst/csv" - cp ta6nt/bin/ta6nt/*.exe "$inst/bin/" - cp ta6nt/bin/ta6nt/*.dll "$inst/bin/" 2>/dev/null || true - cp ta6nt/boot/ta6nt/petite.boot ta6nt/boot/ta6nt/scheme.boot "$inst/bin/" - cp ta6nt/boot/ta6nt/petite.boot ta6nt/boot/ta6nt/scheme.boot "$inst/csv/" - cp ta6nt/boot/ta6nt/scheme.h "$inst/csv/" - cp ta6nt/boot/ta6nt/equates.h "$inst/csv/" 2>/dev/null || true - cp ta6nt/boot/ta6nt/libkernel.a "$inst/csv/" || { echo "libkernel.a not found:"; find ta6nt -name "*.a" -o -name "kernel*"; exit 1; } - - - name: Put chez on PATH (Windows) - if: runner.os == 'Windows' - run: | - bindir="$GITHUB_WORKSPACE/chez-install/bin" - { echo '#!/bin/sh'; echo "exec \"$bindir/scheme.exe\" \"\$@\""; } > "$bindir/chez" - chmod +x "$bindir/chez" - echo "$bindir" >> "$GITHUB_PATH" - echo "JOLT_CHEZ_CSV=$GITHUB_WORKSPACE/chez-install/csv" >> "$GITHUB_ENV" - # cc is the build's compiler name; alias it to mingw gcc - { echo '#!/bin/sh'; echo 'exec gcc "$@"'; } > "$bindir/cc" - chmod +x "$bindir/cc" - - - name: Show Chez version - run: chez --version - - # build-joltc compiles in a fresh Chez and cc-links; the checked-in seed is - # the compiler image, so no selfhost re-mint (that byte-fixpoint is a - # dev-machine check — see jolt-8479). `make joltc-release`, not `make joltc`. - - name: Build joltc (release) - run: make joltc-release - env: - # Bake the release tag into the binary (build-joltc falls back to - # `git describe` when this is empty, e.g. a workflow_dispatch dry run). - JOLT_VERSION: ${{ startsWith(github.ref, 'refs/tags/') && github.ref_name || '' }} - - - name: Inspect the binary (Windows) - if: runner.os == 'Windows' - run: | - set +e - ls -la target/release/ - ntldd target/release/joltc.exe 2>&1 | head -20 - ./target/release/joltc.exe -e '(+ 1 2)' - echo "exit=$?" - - # Sanity: the built binary runs (no Chez needed) and self-reports a value. - - name: Smoke the binary - run: | - out="$(./target/release/joltc -e '(reduce + (range 10))')" - test "$out" = "45" || { echo "joltc -e gave '$out', want 45"; exit 1; } - - # The binary is a self-contained COMPILER: it must `build` an app with no - # jolt source on disk. Run from an isolated dir (nothing but the tiny app) - # so a build that reaches for host/chez/*.ss on the filesystem fails here, - # not on a user's machine. - - name: Smoke a self-contained build - run: | - joltc="$(pwd)/target/release/joltc" - work="$(mktemp -d)" - mkdir -p "$work/app/src/app" - printf '{:paths ["src"]}\n' > "$work/app/deps.edn" - printf '(ns app.core)\n(defn -main [& _] (println "built:" (reduce + (range 10))))\n' \ - > "$work/app/src/app/core.clj" - ( cd "$work/app" && "$joltc" build -m app.core -o app ) - out="$("$work/app/app")" - test "$out" = "built: 45" || { echo "self-contained build ran '$out', want 'built: 45'"; exit 1; } - - # A built binary must also run the DYNAMIC require path: a namespace not - # in the static ns graph compiles from the source roots at runtime, so the - # boot's top-level defines must be visible to the runtime compiler's eval - # (issue #290: this died with "variable var-deref is not bound"). - - name: Smoke a runtime require in a built binary - run: | - joltc="$(pwd)/target/release/joltc" - work="$(mktemp -d)" - mkdir -p "$work/app/src/app" - printf '{:paths ["src"]}\n' > "$work/app/deps.edn" - printf '(ns app.extra)\n(defn greet [s] (str "Hello, " s "!"))\n' \ - > "$work/app/src/app/extra.clj" - printf '(ns app.core)\n(defn -main [& _]\n (println ((requiring-resolve (quote app.extra/greet)) "runtime")))\n' \ - > "$work/app/src/app/core.clj" - ( cd "$work/app" && "$joltc" build -m app.core -o app ) - out="$(cd "$work/app" && ./app)" - test "$out" = "Hello, runtime!" || { echo "runtime require ran '$out', want 'Hello, runtime!'"; exit 1; } - - - name: Package - run: | - ver="${GITHUB_REF_NAME}" - name="joltc-${ver}-${{ matrix.target }}" - mkdir -p "dist/${name}" - cp README.md LICENSE "dist/${name}/" - if [ "${{ runner.os }}" = "Windows" ]; then - cp target/release/joltc.exe "dist/${name}/joltc.exe" - ( cd dist && zip -r "${name}.zip" "${name}" && sha256sum "${name}.zip" > "${name}.zip.sha256" ) - else - cp target/release/joltc "dist/${name}/joltc" - tar -C dist -czf "dist/${name}.tar.gz" "${name}" - ( cd dist && shasum -a 256 "${name}.tar.gz" > "${name}.tar.gz.sha256" ) - fi - ls -la dist - - - name: Upload to the GitHub Release - if: startsWith(github.ref, 'refs/tags/') - uses: softprops/action-gh-release@v2 - with: - files: | - dist/*.tar.gz - dist/*.tar.gz.sha256 - dist/*.zip - dist/*.zip.sha256 - fail_on_unmatched_files: false diff --git a/.github/workflows/tests.yml b/.github/workflows/tests.yml index a3eff9c..d0036df 100644 --- a/.github/workflows/tests.yml +++ b/.github/workflows/tests.yml @@ -56,11 +56,7 @@ jobs: - name: Install JDK + Clojure (certify oracle) run: | sudo apt-get install -y default-jdk rlwrap - # --retry + --fail so a transient CDN error retries instead of handing - # bash an HTML error page (a 2min timeout page flaked a run) - curl --fail --retry 5 --retry-delay 10 --retry-all-errors -L -O \ - https://github.com/clojure/brew-install/releases/latest/download/linux-install.sh - head -1 linux-install.sh | grep -q '^#!' || { echo "installer download corrupt"; cat linux-install.sh | head -5; exit 1; } + curl -L -O https://github.com/clojure/brew-install/releases/latest/download/linux-install.sh sudo bash linux-install.sh clojure --version diff --git a/.gitignore b/.gitignore index ab386cf..b62bfd2 100644 --- a/.gitignore +++ b/.gitignore @@ -2,7 +2,6 @@ AGENTS.md .DS_Store CLAUDE.md build/ -target/ .clj-kondo/ .dirge/ .claude/ diff --git a/.gitmodules b/.gitmodules index e2374ec..77affa0 100644 --- a/.gitmodules +++ b/.gitmodules @@ -4,6 +4,3 @@ [submodule "vendor/sci"] path = vendor/sci url = https://github.com/borkdude/sci.git -[submodule "vendor/clojure-test-suite"] - path = vendor/clojure-test-suite - url = https://github.com/jank-lang/clojure-test-suite.git diff --git a/LICENSE b/LICENSE index e48e096..4a729a7 100644 --- a/LICENSE +++ b/LICENSE @@ -1,179 +1,143 @@ -Eclipse Public License - v 2.0 +Eclipse Public License - v 1.0 - THE ACCOMPANYING PROGRAM IS PROVIDED UNDER THE TERMS OF THIS ECLIPSE - PUBLIC LICENSE ("AGREEMENT"). ANY USE, REPRODUCTION OR DISTRIBUTION - OF THE PROGRAM CONSTITUTES RECIPIENT'S ACCEPTANCE OF THIS AGREEMENT. +THE ACCOMPANYING PROGRAM IS PROVIDED UNDER THE TERMS OF THIS ECLIPSE +PUBLIC LICENSE ("AGREEMENT"). ANY USE, REPRODUCTION OR DISTRIBUTION OF +THE PROGRAM CONSTITUTES RECIPIENT'S ACCEPTANCE OF THIS AGREEMENT. 1. DEFINITIONS "Contribution" means: - a) in the case of the initial Contributor, the initial content - Distributed under this Agreement, and +a) in the case of the initial Contributor, the initial code and +documentation distributed under this Agreement, and - b) in the case of each subsequent Contributor: - i) changes to the Program, and - ii) additions to the Program; - where such changes and/or additions to the Program originate from - and are Distributed by that particular Contributor. A Contribution - "originates" from a Contributor if it was added to the Program by - such Contributor itself or anyone acting on such Contributor's behalf. - Contributions do not include changes or additions to the Program that - are not Modified Works. +b) in the case of each subsequent Contributor: -"Contributor" means any person or entity that Distributes the Program. +i) changes to the Program, and + +ii) additions to the Program; + +where such changes and/or additions to the Program originate from and +are distributed by that particular Contributor. A Contribution +'originates' from a Contributor if it was added to the Program by such +Contributor itself or anyone acting on such Contributor's behalf. +Contributions do not include additions to the Program which: (i) are +separate modules of software distributed in conjunction with the Program +under their own license agreement, and (ii) are not derivative works of +the Program. + +"Contributor" means any person or entity that distributes the Program. "Licensed Patents" mean patent claims licensable by a Contributor which are necessarily infringed by the use or sale of its Contribution alone or when combined with the Program. -"Program" means the Contributions Distributed in accordance with this +"Program" means the Contributions distributed in accordance with this Agreement. -"Recipient" means anyone who receives the Program under this Agreement -or any Secondary License (as applicable), including Contributors. - -"Derivative Works" shall mean any work, whether in Source Code or other -form, that is based on (or derived from) the Program and for which the -editorial revisions, annotations, elaborations, or other modifications -represent, as a whole, an original work of authorship. - -"Modified Works" shall mean any work in Source Code or other form that -results from an addition to, deletion from, or modification of the -contents of the Program, including, for purposes of clarity any new file -in Source Code form that contains any contents of the Program. Modified -Works shall not include works that contain only declarations, -interfaces, types, classes, structures, or files of the Program solely -in each case in order to link to, bind by name, or subclass the Program -or Modified Works thereof. - -"Distribute" means the acts of a) distributing or b) making available -in any manner that enables the transfer of a copy. - -"Source Code" means the form of a Program preferred for making -modifications, including but not limited to software source code, -documentation source, and configuration files. - -"Secondary License" means either the GNU General Public License, -Version 2.0, or any later versions of that license, including any -exceptions or additional permissions as identified by the initial -Contributor. +"Recipient" means anyone who receives the Program under this Agreement, +including all Contributors. 2. 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This patent license shall - apply to the combination of the Contribution and the Program if, at - the time the Contribution is added by the Contributor, such addition - of the Contribution causes such combination to be covered by the - Licensed Patents. The patent license shall not apply to any other - combinations which include the Contribution. No hardware per se is - licensed hereunder. +b) Subject to the terms of this Agreement, each Contributor hereby +grants Recipient a non-exclusive, worldwide, royalty-free patent license +under Licensed Patents to make, use, sell, offer to sell, import and +otherwise transfer the Contribution of such Contributor, if any, in +source code and object code form. This patent license shall apply to the +combination of the Contribution and the Program if, at the time the +Contribution is added by the Contributor, such addition of the +Contribution causes such combination to be covered by the Licensed +Patents. The patent license shall not apply to any other combinations +which include the Contribution. No hardware per se is licensed +hereunder. - c) Recipient understands that although each Contributor grants the - licenses to its Contributions set forth herein, no assurances are - provided by any Contributor that the Program does not infringe the - patent or other intellectual property rights of any other entity. - Each Contributor disclaims any liability to Recipient for claims - brought by any other entity based on infringement of intellectual - property rights or otherwise. As a condition to exercising the - rights and licenses granted hereunder, each Recipient hereby - assumes sole responsibility to secure any other intellectual - property rights needed, if any. 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For +example, if a third party patent license is required to allow Recipient +to distribute the Program, it is Recipient's responsibility to acquire +that license before distributing the Program. - d) Each Contributor represents that to its knowledge it has - sufficient copyright rights in its Contribution, if any, to grant - the copyright license set forth in this Agreement. - - e) Notwithstanding the terms of any Secondary License, no - Contributor makes additional grants to any Recipient (other than - those set forth in this Agreement) as a result of such Recipient's - receipt of the Program under the terms of a Secondary License - (if permitted under the terms of Section 3). +d) Each Contributor represents that to its knowledge it has sufficient +copyright rights in its Contribution, if any, to grant the copyright +license set forth in this Agreement. 3. REQUIREMENTS -3.1 If a Contributor Distributes the Program in any form, then: +A Contributor may choose to distribute the Program in object code form +under its own license agreement, provided that: - a) the Program must also be made available as Source Code, in - accordance with section 3.2, and the Contributor must accompany - the Program with a statement that the Source Code for the Program - is available under this Agreement, and informs Recipients how to - obtain it in a reasonable manner on or through a medium customarily - used for software exchange; and +a) it complies with the terms and conditions of this Agreement; and - b) the Contributor may Distribute the Program under a license - different than this Agreement, provided that such license: - i) effectively disclaims on behalf of all other Contributors all - warranties and conditions, express and implied, including - warranties or conditions of title and non-infringement, and - implied warranties or conditions of merchantability and fitness - for a particular purpose; +b) its license agreement: - ii) effectively excludes on behalf of all other Contributors all - liability for damages, including direct, indirect, special, - incidental and consequential damages, such as lost profits; +i) effectively disclaims on behalf of all Contributors all warranties +and conditions, express and implied, including warranties or conditions +of title and non-infringement, and implied warranties or conditions of +merchantability and fitness for a particular purpose; - iii) does not attempt to limit or alter the recipients' rights - in the Source Code under section 3.2; and +ii) effectively excludes on behalf of all Contributors all liability for +damages, including direct, indirect, special, incidental and +consequential damages, such as lost profits; - iv) requires any subsequent distribution of the Program by any - party to be under a license that satisfies the requirements - of this section 3. +iii) states that any provisions which differ from this Agreement are +offered by that Contributor alone and not by any other party; and -3.2 When the Program is Distributed as Source Code: +iv) states that source code for the Program is available from such +Contributor, and informs licensees how to obtain it in a reasonable +manner on or through a medium customarily used for software exchange. - a) it must be made available under this Agreement, or if the - Program (i) is combined with other material in a separate file or - files made available under a Secondary License, and (ii) the initial - Contributor attached to the Source Code the notice described in - Exhibit A of this Agreement, then the Program may be made available - under the terms of such Secondary Licenses, and +When the Program is made available in source code form: - b) a copy of this Agreement must be included with each copy of - the Program. +a) it must be made available under this Agreement; and -3.3 Contributors may not remove or alter any copyright, patent, -trademark, attribution notices, disclaimers of warranty, or limitations -of liability ("notices") contained within the Program from any copy of -the Program which they Distribute, provided that Contributors may add -their own appropriate notices. +b) a copy of this Agreement must be included with each copy of the +Program. + +Contributors may not remove or alter any copyright notices contained +within the Program. + +Each Contributor must identify itself as the originator of its +Contribution, if any, in a manner that reasonably allows subsequent +Recipients to identify the originator of the Contribution. 4. COMMERCIAL DISTRIBUTION Commercial distributors of software may accept certain responsibilities with respect to end users, business partners and the like. While this -license is intended to facilitate the commercial use of the Program, -the Contributor who includes the Program in a commercial product -offering should do so in a manner which does not create potential -liability for other Contributors. Therefore, if a Contributor includes -the Program in a commercial product offering, such Contributor -("Commercial Contributor") hereby agrees to defend and indemnify every -other Contributor ("Indemnified Contributor") against any losses, -damages and costs (collectively "Losses") arising from claims, lawsuits -and other legal actions brought by a third party against the Indemnified +license is intended to facilitate the commercial use of the Program, the +Contributor who includes the Program in a commercial product offering +should do so in a manner which does not create potential liability for +other Contributors. Therefore, if a Contributor includes the Program in +a commercial product offering, such Contributor ("Commercial +Contributor") hereby agrees to defend and indemnify every other +Contributor ("Indemnified Contributor") against any losses, damages and +costs (collectively "Losses") arising from claims, lawsuits and other +legal actions brought by a third party against the Indemnified Contributor to the extent caused by the acts or omissions of such -Commercial Contributor in connection with its distribution of the Program -in a commercial product offering. The obligations in this section do not -apply to any claims or Losses relating to any actual or alleged -intellectual property infringement. In order to qualify, an Indemnified -Contributor must: a) promptly notify the Commercial Contributor in -writing of such claim, and b) allow the Commercial Contributor to control, -and cooperate with the Commercial Contributor in, the defense and any -related settlement negotiations. The Indemnified Contributor may -participate in any such claim at its own expense. +Commercial Contributor in connection with its distribution of the +Program in a commercial product offering. The obligations in this +section do not apply to any claims or Losses relating to any actual or +alleged intellectual property infringement. In order to qualify, an +Indemnified Contributor must: a) promptly notify the Commercial +Contributor in writing of such claim, and b) allow the Commercial +Contributor to control, and cooperate with the Commercial Contributor +in, the defense and any related settlement negotiations. The Indemnified +Contributor may participate in any such claim at its own expense. For example, a Contributor might include the Program in a commercial product offering, Product X. That Contributor is then a Commercial @@ -181,97 +145,80 @@ Contributor. If that Commercial Contributor then makes performance claims, or offers warranties related to Product X, those performance claims and warranties are such Commercial Contributor's responsibility alone. Under this section, the Commercial Contributor would have to -defend claims against the other Contributors related to those performance -claims and warranties, and if a court requires any other Contributor to -pay any damages as a result, the Commercial Contributor must pay -those damages. +defend claims against the other Contributors related to those +performance claims and warranties, and if a court requires any other +Contributor to pay any damages as a result, the Commercial Contributor +must pay those damages. 5. 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No party to +this Agreement will bring a legal action under this Agreement more than +one year after the cause of action arose. Each party waives its rights +to a jury trial in any resulting litigation. diff --git a/Makefile b/Makefile index 5d87481..2cd029b 100644 --- a/Makefile +++ b/Makefile @@ -4,23 +4,18 @@ # build step. `make test` is the full gate. `make remint` rebuilds the seed after a # source change. -.PHONY: test ci values corpus unit smoke buildsmoke staticnativesmoke selfhost sci cts certify ffi transient infer wp devirt fieldread numwp fieldnum protoret narrow directlink numeric inline shakesmoke remint joltc joltc-release joltc-debug joltcsmoke submodules - -# Every target needs the vendored submodules; fail with the fix, not a load error. -submodules: - @test -f vendor/irregex/irregex.scm || { \ - echo "vendor submodules missing; run: git submodule update --init --recursive"; exit 1; } +.PHONY: test ci values corpus unit smoke buildsmoke selfhost sci certify ffi transient infer directlink numeric inline shakesmoke remint # Full gate (dev machine). Includes the self-host byte-fixpoint, which only holds # on the same Chez that minted the seed. -test: submodules selfhost ci +test: selfhost ci @echo "OK: all gates passed" # CI gate: behavior only. The checked-in seed is a minted artifact (like a # lockfile) — it RUNS correctly on any Chez, but `selfhost` rebuilds it and a # different Chez version may emit byte-different (gensym/order) output, so the # byte-fixpoint is a dev-machine check, not a CI one (jolt-8479). -ci: submodules values corpus unit smoke buildsmoke staticnativesmoke sci cts ffi transient infer wp devirt fieldread numwp fieldnum protoret narrow directlink numeric inline certify +ci: values corpus unit smoke buildsmoke sci ffi transient infer directlink numeric inline certify @echo "OK: CI gates passed" # Self-host fixpoint: bootstrap.ss rebuild == checked-in seed. @@ -47,38 +42,10 @@ smoke: buildsmoke: @sh host/chez/build-smoke.sh -# `jolt build` cc-links a :jolt/native :static archive into the binary (the -# default), and --dynamic keeps the runtime load-shared-object path. -staticnativesmoke: - @sh host/chez/static-native-smoke.sh - -# Build joltc as a self-contained native binary into target//joltc. The -# binary bundles the runtime, compiler, jolt-core + stdlib source, the Chez boots, -# and a launcher stub, so it runs AND compiles jolt apps with no Chez or cc on the -# machine. Built on a dev/CI host that HAS Chez + cc. release = optimize-level 3, -# no inspector info, compressed; debug = optimize-level 0 + inspector + debug info. -joltc-release: - @chez --script host/chez/build-joltc.ss release target/release/joltc -joltc-debug: - @chez --script host/chez/build-joltc.ss debug target/debug/joltc -# Re-mint the seed first so the embedded compiler image is current, then both builds. -joltc: selfhost joltc-release joltc-debug - @echo "OK: target/release/joltc and target/debug/joltc built" - -# Self-build smoke: the distributed joltc compiles an app with Chez + cc removed. -joltcsmoke: - @sh host/chez/joltc-selfbuild-smoke.sh - # SCI conformance: load borkdude/sci's source through joltc (floor-gated). sci: @chez --script host/chez/run-sci.ss -# clojure-test-suite conformance: run the vendored jank-lang/clojure-test-suite -# per-namespace under joltc, gated on the per-namespace baseline -# (test/chez/cts-known-failures.txt). -cts: - @bash host/chez/cts.sh - # FFI: bind native functions (typed foreign-procedure), memory, and that a # :blocking call is collect-safe (a parked thread doesn't pin the collector). ffi: @@ -94,49 +61,6 @@ transient: infer: @chez --script host/chez/run-infer.ss -# Whole-program param-type fixpoint: record types flowing across fn boundaries -# (a callee's param picks up its callers' ctor return types), the foundation the -# bare-index field reads + protocol devirtualization build on. -wp: - @chez --script host/chez/run-wp.ss - -# Protocol-call devirtualization: a monomorphic call resolves its impl by the -# inferred record tag (find-protocol-method) instead of routing through the -# protocol var; the result must match ordinary dispatch. -devirt: - @chez --script host/chez/run-devirt.ss - -# Native record field reads: a keyword lookup on a statically-known record reads -# the field by its declared slot (jrec-field-at) instead of jolt-get; the value -# must match, and a non-field key / default-arg form keeps the generic path. -fieldread: - @chez --script host/chez/run-fieldread.ss - -# Hintless whole-program double inference: a fn whose every call site passes a -# flonum has its param typed :double by the closed-world fixpoint and unboxed to -# fl-ops with no ^double hint; an integer caller leaves it generic, an escaped fn -# keeps :any. -numwp: - @chez --script host/chez/run-numwp.ss - -# Double record fields: a ^double-tagged field reads back as a flonum (coerced at -# construction and set!), so hintless arithmetic over those fields unboxes to fl-ops; -# an untagged field stays generic. -fieldnum: - @chez --script host/chez/run-fieldnum.ss - -# Protocol-method return inference: a method whose impls all return the same record -# type has a monomorphic return, so a (method recv ..) call types as that record and -# a field read off the result bare-indexes; a disagreeing impl keeps the generic path. -protoret: - @chez --script host/chez/run-protoret.ss - -# Nilable record types + flow-sensitive narrowing: a record-or-nil types as a nilable -# record (some?/nil? don't fold, so a runtime guard stays); inside (if (some? x) ..) -# the then-branch narrows x to non-nil, so its field reads bare-index and unbox. -narrow: - @chez --script host/chez/run-narrow.ss - # Direct-linking emission: a closed-world build binds top-level app defs to jv$ # Scheme bindings and routes app->app calls/refs to them, skipping var-deref + # jolt-invoke; ^:dynamic/^:redef and nested defs opt out. diff --git a/README.md b/README.md index 16c1f50..fa808c5 100644 --- a/README.md +++ b/README.md @@ -7,31 +7,6 @@ Jolt reads Clojure source, analyzes it to a host-neutral IR, emits Scheme, and runs it on Chez. The compiler is self-hosted: it is written in Clojure (`jolt-core/`) and compiles itself. It ships a Clojure-compatible standard library. -## Install - -Grab the self-contained `joltc` binary (Linux/macOS/Windows) — it bundles the -runtime, compiler, and standard library, so there is nothing else to install. -Download the binary archive for your platform from the -[releases page](https://github.com/jolt-lang/jolt/releases) (`joltc--.tar.gz`, -or the `.zip` on Windows). The "Source code" archives GitHub attaches to every -release are not binaries — see [Build](#build) before using one. - -With Homebrew: - -```bash -brew install jolt-lang/jolt/jolt -``` - -Or with the install script (installs to `/usr/local/bin` by default; `--dir ` -and `--version ` override that): - -```bash -curl -sL https://raw.githubusercontent.com/jolt-lang/jolt/main/install | bash -``` - -Then `joltc -e '(+ 1 2)'`. To run from source instead (needs Chez), see -[Build](#build). - ## Requirements Only [Chez Scheme](https://cisco.github.io/ChezScheme/) (the gate invokes it as @@ -49,18 +24,6 @@ cd jolt bin/joltc -e '(+ 1 2)' # => 3 ``` -The `--recurse-submodules` matters: jolt vendors its regex engine and test -suites as git submodules. In a checkout that's missing them (a plain -`git clone`, or after pulling a commit that adds one), fetch them with: - -```bash -git submodule update --init --recursive -``` - -Note that GitHub's auto-generated "Source code (zip/tar.gz)" archives on the -releases page do **not** contain submodules, so they can't run or build — -clone the repo instead (or grab a prebuilt binary from the same page). - After changing a compiler source — the reader (`host/chez/reader.ss`), the analyzer/IR/backend (`jolt-core/jolt/*.clj`), or the `clojure.core` overlay (`jolt-core/clojure/core/*.clj`) — re-mint the seed: @@ -82,32 +45,6 @@ $ bin/joltc -e '(/ 1 2)' 1/2 ``` -## REPL and editor integration - -```bash -bin/joltc repl # a line REPL with the project's deps loaded -bin/joltc --nrepl-server [port] # an nREPL server (default 7888) for editors -``` - -Both resolve the `deps.edn` in the current directory first, so the project's -source roots and native libraries are loaded — `(require '[my.ns])` works live. -`--nrepl-server` writes a `.nrepl-port` file in the project dir, so CIDER / Calva / Cursive -auto-detect the port; override it with the argument or `JOLT_NREPL_PORT`. - -The server runs in dev mode — calls deref their var, so redefining a function -takes effect on the next call without restarting the process. The built-in -handler speaks `clone`/`describe`/`eval`/`load-file`/`close`; heavier ops -(sessions, interruptible eval, completion) are added as nREPL middleware listed -in `deps.edn` under `:nrepl/middleware`. - -```clojure -;; from your editor, against the running process: -(require '[myapp.core :as app]) -(app/start!) ; bring the app up -;; edit a handler, re-evaluate the defn — the running app sees it, no restart -(app/stop!) -``` - ## Compile a binary `bin/joltc build` ahead-of-time compiles a project into a single self-contained @@ -143,24 +80,6 @@ compiler. They come with a from-source Chez install; a distro `chezscheme` package ships only the runtime, so `build` won't link a binary there. RFC 0007 (`docs/rfc/`) covers the design and the three-mode model. -## Standalone joltc binary - -`make` builds joltc itself into a single self-contained native binary — the -runtime, compiler, `jolt-core`/`stdlib` source, and the Chez boots are baked in, -so the result runs and `build`s jolt apps on a machine with neither Chez nor a C -compiler. Build it on a host that *does* have both. - -```bash -make joltc-release # => target/release/joltc (optimize-level 3, compressed) -make joltc-debug # => target/debug/joltc (optimize-level 0, inspector + debug info) -make joltc # re-mint the seed first, then both -``` - -`make joltc` re-mints the seed so the embedded compiler image is current before -linking; use `joltc-release`/`joltc-debug` directly to skip that when the seed is -already minted. Like `build`, both require Chez's kernel development files -(`libkernel.a`, `scheme.h`) and a C compiler. - ## Architecture A small Chez runtime (`host/chez/*.ss`: value model, persistent collections, seqs, @@ -231,4 +150,4 @@ whose expected values are sourced from reference JVM Clojure. See ## License -[Eclipse Public License 2.0](https://www.eclipse.org/legal/epl-2.0/) +[Eclipse Public License 1.0](https://opensource.org/licenses/EPL-1.0) diff --git a/bench/.gitignore b/bench/.gitignore deleted file mode 100644 index bd04223..0000000 --- a/bench/.gitignore +++ /dev/null @@ -1 +0,0 @@ -.cpcache/ diff --git a/bench/README.md b/bench/README.md index dffd3fc..d4c5219 100644 --- a/bench/README.md +++ b/bench/README.md @@ -34,87 +34,34 @@ control with record state), k-nucleotide proper. ## Holistic scorecard -`bench/run.sh` compiles each benchmark to an **optimized AOT binary** (`joltc build ---direct-link --opt`) and times it against JVM Clojure running the same portable -source — the jolt/JVM scorecard. jolt's optimizing passes fire only in a build; -`joltc run -m` is unoptimized, so the harness always builds. +`JVM=1 bench/run.sh` runs each benchmark on jolt **and** JVM Clojure and prints +the jolt/JVM ratio — the absolute-reference scorecard. As of +the broadening (2026-06-16), ratios cluster by axis: -Indicative ratios (M-series, single isolated run — numbers are machine-specific, -regenerate locally), ascending: - -| benchmark | ratio | axis | -|---|---|---| -| `fib` | ~0.6× | call + integer arith | -| `collections` | ~3.5× | persistent map/vector churn | -| `mandelbrot` | ~7.5× | pure float compute | -| `binary-trees` | ~10× | escaping short-lived records (allocation/GC) | -| `dispatch` | ~12× | megamorphic protocol dispatch | -| `mono-dispatch` | ~15× | monomorphic protocol dispatch | - -- **Compute (~0.6–7.5×)** is the substrate floor: Chez is a native-compiling AOT - Scheme, not a profiling JIT. With native arith + direct-linking + inlining jolt - is at parity here — `fib` runs *faster* than JVM Clojure (no JIT warmup over a - short run), `collections` is within ~3.5×, and `mandelbrot` (~7.5×) is the - pure-tight-loop float ceiling that only native codegen moves further. -- **Dispatch & allocation (~10–15×)** are the remaining architectural gaps, though - the type-proving / native-record / bare-field-read work has collapsed them by an - order of magnitude (`binary-trees` ~140×→~10×, `mono-dispatch` ~330×→~15×). On a - *statically proven* monomorphic receiver — which whole-program inference now gives - for a record iterated out of a vector — devirt resolves the impl and a per-site - inline cache holds it (resolved once, not per call), so `mono-dispatch` is no - longer worse than megamorphic. The remaining lever is `dispatch`: a *megamorphic* - site has no static type, so it pays a full protocol-registry lookup every call - where the JVM uses a polymorphic inline cache — a runtime (receiver-type-keyed) - cache is the missing piece. `binary-trees` - nodes escape into the tree, so scalar-replace can't remove them — residual GC - pressure. - -## 64-bit integer arithmetic & generators (test.check) - -The AOT suite above is float-compute / dispatch / allocation bound; none of it -exercises **64-bit integer arithmetic**, which Chez can't hold in a fixnum -(61-bit), so genuine 64-bit values are heap bignums. The SplitMix PRNG behind -`clojure.test.check` is the worst case — every `rand-long` is ~8 bignum ops. These -were measured in **run mode** (`joltc run`, where per-site var-cell caching is on; -the AOT build keeps it off) against JVM Clojure on the same portable source. The -first two rows are isolating microbenchmarks; the rest are real test.check -generators. - -| workload | jolt | JVM | ratio | bound by | -|---|---|---|---|---| -| SplitMix `mix-64` (×100k) | 45ms | 14ms | ~3.2× | 64-bit integer arithmetic | -| deftype alloc + protocol dispatch (×100k) | 41ms | 5ms | ~8× | open-world dispatch | -| raw `split` + `rand-long` (×20k) | 74ms | 6ms | ~12× | bignum 64-bit + dispatch | -| `gen/large-integer` (×2k) | 108ms | 23ms | ~4.7× | arithmetic + rose-tree machinery | -| `(gen/vector gen/large-integer)` (×500) | 1289ms | 88ms | ~14.6× | element gen + gen machinery | - -Two no-C codegen levers collapsed the **arithmetic** half: emitting `bit-and`/ -`bit-or`/`bit-xor`/`bit-not` as inlined Chez `bitwise-*` primitives (they had gone -through a var-deref'd variadic overlay), and caching the resolved var cell per -reference site (a name lookup was ~45ns/access). Together they took `mix-64` from -~18× → ~3.2× JVM and the raw PRNG from ~30× → ~12×, and the generators ~1.6× each. - -The residual gap is **machinery, not arithmetic**: the open-world generator -deftype/protocol dispatch + rose-tree allocation (~8–10×) can't be devirtualized -without static types, and the raw 64-bit ops bottom out at the Chez bignum floor -(~20× a native long, substrate-inherent). A native SplitMix C/FFI shim would give -the PRNG ~27× but is the only path that needs C. +- **pure compute** (`mandelbrot`) is the floor, ~15× — native arith + already gets jolt closest to the JVM. +- **collections** ~28×, **fib** ~37×. +- **dispatch** ~75× (megamorphic), and `mono-dispatch` is *worse* (~110×): the + JVM inline-caches a runtime-monomorphic call site to near-free, while jolt does + a full registry dispatch regardless (devirt only fires on *statically* proven + receivers, which `reduce` over a vector doesn't give). This is the signal for + the call-site inline cache. +- **allocation** (`binary-trees`) is the widest gap — but also the most inflated + by host memory pressure, so read it as "alloc is the worst axis," not a precise + multiple. Numbers are machine-specific; regenerate with `JVM=1 bench/run.sh`. ## Running ```sh -bench/run.sh # full suite + JVM scorecard -bench/run.sh fib # one benchmark, default size -bench/run.sh fib 32 # one benchmark, custom size -NO_JVM=1 bench/run.sh # jolt only (skip the JVM reference) +bench/run.sh # whole-program optimization on (default) +JOLT_WHOLE_PROGRAM=0 bench/run.sh # WP off, to measure what WP buys +bench/run.sh binary-trees 16 # one benchmark, custom size ``` -Needs Chez's kernel dev files (`libkernel.a` + `scheme.h`) and `cc` for the build, -like `jolt build`; set `JOLT_CHEZ_CSV` to override the detected csv dir. - ## A/B against a change To measure a pass, run the suite on `main`, then on the branch, back to back -(same machine, quiet). Each benchmark prints `runs: [...]` and `mean: N ms`; -compare the means. A pass is worth landing when it moves a benchmark whose axis it +(same machine, quiet) — the same protocol used for the ray tracer. Each +benchmark prints `runs: [...]` and `mean: N ms`; compare +the means. A pass is worth landing when it moves a benchmark whose axis it targets, even if the ray tracer stays flat. diff --git a/bench/binary_trees.clj b/bench/binary_trees.clj index 28428ec..e3f580e 100644 --- a/bench/binary_trees.clj +++ b/bench/binary_trees.clj @@ -4,7 +4,8 @@ ;; targets and the ray tracer never exercises (~7% alloc). ;; ;; Portable Clojure: runs on jolt and JVM Clojure for cross-impl comparison. -;; bench/run.sh binary-trees 14 +;; jolt -m binary-trees 14 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) +;; clojure -M -m binary-trees 14 (ns binary-trees) (defrecord Node [left right]) diff --git a/bench/collections.clj b/bench/collections.clj index 2c0304d..16e9807 100644 --- a/bench/collections.clj +++ b/bench/collections.clj @@ -5,7 +5,7 @@ ;; records, no collections in the hot loop) doesn't touch. ;; ;; Portable Clojure (jolt + JVM Clojure). -;; bench/run.sh collections 200000 +;; jolt -m collections 200000 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) (ns collections) ;; map churn: accumulate a frequency map over a stream of keys, then sum it back diff --git a/bench/deps.edn b/bench/deps.edn deleted file mode 100644 index 5837a2a..0000000 --- a/bench/deps.edn +++ /dev/null @@ -1 +0,0 @@ -{:paths ["."]} diff --git a/bench/dispatch.clj b/bench/dispatch.clj index d60527b..f6decc0 100644 --- a/bench/dispatch.clj +++ b/bench/dispatch.clj @@ -6,7 +6,7 @@ ;; float-math cost (devirt measured FLAT there). ;; ;; Portable Clojure (jolt + JVM Clojure). -;; bench/run.sh dispatch 20000 +;; jolt -m dispatch 20000 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) (ns dispatch) (defprotocol Shape diff --git a/bench/fib.clj b/bench/fib.clj index 2457a6e..6715e58 100644 --- a/bench/fib.clj +++ b/bench/fib.clj @@ -4,7 +4,7 @@ ;; single-call-site / small-fn inlining and self-call direct-linking. ;; ;; Portable Clojure (jolt + JVM Clojure). -;; bench/run.sh fib 32 +;; jolt -m fib 32 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) (ns fib) (defn fib [n] diff --git a/bench/mandelbrot.clj b/bench/mandelbrot.clj index 0367f02..0a715d9 100644 --- a/bench/mandelbrot.clj +++ b/bench/mandelbrot.clj @@ -5,10 +5,10 @@ ;; on (where devirt/alloc passes measured flat), so it tracks native-arith codegen ;; and loop quality directly. ;; -;; Portable Clojure (jolt + JVM Clojure). The jolt.png picture demo lives in -;; mandelbrot_png.clj so this file stays portable for the JVM reference run. -;; bench/run.sh mandelbrot 1000 -(ns mandelbrot) +;; Portable Clojure (jolt + JVM Clojure). +;; jolt -m mandelbrot 1000 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) +(ns mandelbrot + (:require [jolt.png :as png])) (defn count-point [cr ci cap] (loop [i 0 zr 0.0 zi 0.0] @@ -32,6 +32,35 @@ (recur (inc y) (+ acc row))) acc)))) +;; --- PNG demo (jolt.png) -------------------------------------------------- +;; Render a real picture of the set, reusing count-point as the kernel. `render` +;; is a separate -main subcommand so the numeric-arg bench path is untouched. + +(defn- color + "Escape-iteration count -> RGB. In-set points (n>=cap) are black; faster + escapes run through a warm gradient." + [n cap] + (if (>= n cap) + [0 0 0] + (let [t (/ (double n) cap)] + [(int (* 255 (min 1.0 (* 3.0 t)))) + (int (* 255 (min 1.0 (max 0.0 (* 3.0 (- t 0.33)))))) + (int (* 255 (min 1.0 (max 0.0 (* 3.0 (- t 0.66))))))]))) + +(defn render! + "Render a size×size view of the Mandelbrot set to a PNG at path." + [path size] + (let [w size h size cap 1000 + img (png/image w h)] + (doseq [py (range h)] + (doseq [px (range w)] + (let [cr (- (* 3.5 (/ (double px) w)) 2.5) ; real ∈ [-2.5, 1.0] + ci (- (* 2.8 (/ (double py) h)) 1.4) ; imag ∈ [-1.4, 1.4] + [r g b] (color (count-point cr ci cap) cap)] + (png/put! img r g b)))) + (png/write img w h path) + (println "wrote" path (str w "×" h ", cap " cap)))) + (defn- run-bench [args] (let [n (if (seq args) (Integer/parseInt (first args)) 1000)] (dotimes [_ 2] (run (quot n 2))) ; warmup @@ -49,4 +78,7 @@ (println "mean:" (/ (Math/round (* mean 10.0)) 10.0) "ms")))) (defn -main [& args] - (run-bench args)) + (if (= (first args) "render") + (render! (or (second args) "mandelbrot.png") + (if (nth args 2 nil) (Integer/parseInt (nth args 2)) 600)) + (run-bench args))) diff --git a/bench/mandelbrot_png.clj b/bench/mandelbrot_png.clj deleted file mode 100644 index f73d441..0000000 --- a/bench/mandelbrot_png.clj +++ /dev/null @@ -1,36 +0,0 @@ -;; mandelbrot picture demo — renders a real image of the set to a PNG via -;; jolt.png (FFI), reusing mandelbrot/count-point as the kernel. jolt-only (the -;; benchmark in mandelbrot.clj stays portable for the JVM reference). -;; joltc run -m mandelbrot-png [path] [size] -(ns mandelbrot-png - (:require [mandelbrot :as m] - [jolt.png :as png])) - -(defn- color - "Escape-iteration count -> RGB. In-set points (n>=cap) are black; faster - escapes run through a warm gradient." - [n cap] - (if (>= n cap) - [0 0 0] - (let [t (/ (double n) cap)] - [(int (* 255 (min 1.0 (* 3.0 t)))) - (int (* 255 (min 1.0 (max 0.0 (* 3.0 (- t 0.33)))))) - (int (* 255 (min 1.0 (max 0.0 (* 3.0 (- t 0.66))))))]))) - -(defn render! - "Render a size×size view of the Mandelbrot set to a PNG at path." - [path size] - (let [w size h size cap 1000 - img (png/image w h)] - (doseq [py (range h)] - (doseq [px (range w)] - (let [cr (- (* 3.5 (/ (double px) w)) 2.5) ; real ∈ [-2.5, 1.0] - ci (- (* 2.8 (/ (double py) h)) 1.4) ; imag ∈ [-1.4, 1.4] - [r g b] (color (m/count-point cr ci cap) cap)] - (png/put! img r g b)))) - (png/write img w h path) - (println "wrote" path (str w "×" h ", cap " cap)))) - -(defn -main [& args] - (render! (or (first args) "mandelbrot.png") - (if (second args) (Integer/parseInt (second args)) 600))) diff --git a/bench/mono_dispatch.clj b/bench/mono_dispatch.clj index dba72dd..0755acb 100644 --- a/bench/mono_dispatch.clj +++ b/bench/mono_dispatch.clj @@ -5,7 +5,7 @@ ;; monomorphic dispatch gets to a direct call. Same per-call work as `dispatch`. ;; ;; Portable Clojure (jolt + JVM Clojure). -;; bench/run.sh mono-dispatch 20000 +;; jolt -m mono-dispatch 20000 (JOLT_DIRECT_LINK=1 JOLT_WHOLE_PROGRAM=1) (ns mono-dispatch) (defprotocol Shape diff --git a/bench/run.sh b/bench/run.sh index 73db4cc..63d77af 100755 --- a/bench/run.sh +++ b/bench/run.sh @@ -1,70 +1,48 @@ #!/bin/sh -# Run the jolt benchmark suite against JVM Clojure and print a jolt/JVM scorecard. +# Run the jolt benchmark suite and print mean ms per benchmark. # -# jolt's optimizing passes (direct-linking, inlining, scalar-replace, whole-program -# inference) fire only in an AOT BUILD — `joltc run -m` is unoptimized — so each -# benchmark is compiled to an optimized standalone binary and timed. JVM Clojure -# runs the same portable source for the absolute reference. Each benchmark prints -# `runs: [...]` and `mean: N ms`; the table shows the means and the jolt/JVM ratio. +# Each benchmark isolates an axis the ray tracer (float-compute-bound) doesn't +# capture — see README.md. Run back-to-back against `main` to measure a pass's +# impact. # -# bench/run.sh # full suite + JVM scorecard -# bench/run.sh fib # one benchmark, default size -# bench/run.sh fib 32 # one benchmark, custom size -# NO_JVM=1 bench/run.sh # jolt only (skip the JVM reference) +# bench/run.sh # default sizes, whole-program optimization on +# JOLT_WHOLE_PROGRAM=0 bench/run.sh # compare with WP off +# bench/run.sh binary-trees # one benchmark # -# Building needs Chez's kernel dev files (libkernel.a + scheme.h) and a C compiler, -# the same as `jolt build`; set JOLT_CHEZ_CSV to override the detected csv dir. +# Needs `jolt` on PATH (build with `jpm build`; export PATH="$PWD/build:$PATH"). set -e cd "$(dirname "$0")" -root="$(cd .. && pwd)" -joltc="$root/bin/joltc" -export JOLT_PWD="$PWD" -# Locate Chez's kernel dev files for the optimized build (as build-smoke.sh does). -csv="$JOLT_CHEZ_CSV" -if [ -z "$csv" ]; then - chez_bin="$(command -v chez || command -v scheme || command -v petite || true)" - if [ -n "$chez_bin" ]; then - base="$(cd "$(dirname "$chez_bin")/.." 2>/dev/null && pwd)" - for d in "$base"/lib/csv*/*/; do - [ -f "${d}libkernel.a" ] && csv="${d%/}" && break - done - fi -fi -if [ -z "$csv" ] || [ ! -f "$csv/libkernel.a" ] || [ ! -f "$csv/scheme.h" ] || ! command -v cc >/dev/null 2>&1; then - echo "error: the optimized build needs Chez kernel dev files (libkernel.a + scheme.h) and cc." >&2 - echo " set JOLT_CHEZ_CSV to the csv dir, e.g. \$(brew --prefix chezscheme)/lib/csv*/." >&2 - exit 1 -fi -export JOLT_CHEZ_CSV="$csv" +export JOLT_DIRECT_LINK="${JOLT_DIRECT_LINK:-1}" +export JOLT_WHOLE_PROGRAM="${JOLT_WHOLE_PROGRAM:-1}" +export JOLT_APP_PATHS="$PWD" +export JOLT_PATH="$PWD" -bindir="$(mktemp -d)" -trap 'rm -rf "$bindir"' EXIT - -# name:default-arg, each sized to run in a few seconds. Axes: see README.md. -BENCHES="fib:30 mandelbrot:200 collections:30000 mono-dispatch:2000 dispatch:2000 binary-trees:14" +# name:default-arg (arg sized to run in a few seconds each). Axes: allocation +# (binary-trees), megamorphic vs monomorphic dispatch, persistent-collection +# churn (collections — now O(log n) via the HAMT, so sized up), pure +# float compute (mandelbrot), call+arith recursion (fib). +BENCHES="binary-trees:14 dispatch:2000 mono-dispatch:2000 collections:30000 mandelbrot:200 fib:30" +# JVM=1 also runs each bench on JVM Clojure and prints a jolt/JVM ratio — the +# holistic absolute-reference scorecard for the optimization work. run_one() { ns="${1%%:*}"; arg="${2:-${1##*:}}" - if ! "$joltc" build -m "$ns" -o "$bindir/$ns" --direct-link --opt >/dev/null 2>&1; then - printf '%-16s jolt build FAILED\n' "$ns"; return - fi - jmean=$("$bindir/$ns" "$arg" 2>/dev/null | awk '/^mean:/{print $2}') - if [ -z "$NO_JVM" ]; then - vmean=$(clojure -Sdeps '{:paths ["."]}' -M -m "$ns" "$arg" 2>/dev/null | awk '/^mean:/{print $2}') - ratio=$(awk "BEGIN{ if (\"$vmean\"+0>0 && \"$jmean\"+0>0) printf \"%.1fx\", (\"$jmean\"+0)/(\"$vmean\"+0); else printf \"-\" }") - printf '%-16s jolt %9s ms jvm %8s ms %s\n' "$ns" "${jmean:--}" "${vmean:--}" "$ratio" + jmean=$(jolt -m "$ns" "$arg" 2>&1 | awk '/^mean:/{print $2}') + if [ -n "$JVM" ]; then + vmean=$(clojure -Sdeps '{:paths ["."]}' -M -m "$ns" "$arg" 2>&1 | awk '/^mean:/{print $2}') + ratio=$(awk "BEGIN{ if ($vmean+0>0) printf \"%.1f\", ($jmean+0)/($vmean+0); else printf \"-\" }") + printf '%-16s jolt %9s ms jvm %8s ms %sx\n' "$ns" "${jmean:--}" "${vmean:--}" "$ratio" else - printf '%-16s jolt %9s ms\n' "$ns" "${jmean:--}" + printf '%-16s %9s ms\n' "$ns" "${jmean:--}" fi } if [ -n "$1" ]; then - spec="" - for s in $BENCHES; do [ "${s%%:*}" = "$1" ] && spec="$s"; done - [ -n "$spec" ] || { echo "unknown benchmark: $1 (have: ${BENCHES})" >&2; exit 1; } - run_one "$spec" "$2" + for spec in $BENCHES; do + [ "${spec%%:*}" = "$1" ] && run_one "$spec" "$2" + done else - echo "jolt benchmark suite — optimized AOT binaries${NO_JVM:+ }${NO_JVM:-, vs JVM Clojure}" + echo "jolt benchmark suite (WP=$JOLT_WHOLE_PROGRAM${JVM:+, vs JVM Clojure})" for spec in $BENCHES; do run_one "$spec"; done fi diff --git a/bin/joltc b/bin/joltc index 8b3bb2a..0ccce51 100755 --- a/bin/joltc +++ b/bin/joltc @@ -13,29 +13,7 @@ # the user's original cwd (the project dir, where deps.edn lives) is passed in # JOLT_PWD. root="$(CDPATH= cd -- "$(dirname -- "$0")/.." && pwd)" -export JOLT_PWD="${JOLT_PWD:-$PWD}" - -# Identify the Chez Scheme executable -while read -r CHEZ -do - if [ `which ${CHEZ}` ] - then - break; - fi -done </dev/null || echo dev)}" +JOLT_PWD="${JOLT_PWD:-$PWD}" +export JOLT_PWD cd "$root" || exit 1 -exec ${CHEZ} --script host/chez/cli.ss "$@" - +exec chez --script host/chez/cli.ss "$@" diff --git a/docs/building-and-deps.md b/docs/building-and-deps.md index c8b82e9..5341769 100644 --- a/docs/building-and-deps.md +++ b/docs/building-and-deps.md @@ -57,14 +57,14 @@ dependencies, and prepends the resolved source directories to the source roots for the run. The CLI commands (`jolt.deps` + `jolt.main`): ```bash -bin/joltc run -m NS [args] # resolve deps.edn, load NS, call its -main -bin/joltc run FILE # resolve deps.edn, load a Clojure file -bin/joltc -M:alias [args] # run the alias's :main-opts -bin/joltc -A:alias [args] # add the alias's paths/deps, then run the rest -bin/joltc repl # start a line REPL (project deps + native libs loaded) -bin/joltc --nrepl-server [port] # start an nREPL server (default 7888) for editors -bin/joltc path # print the resolved source roots (':'-joined) -bin/joltc # run a deps.edn :tasks entry +bin/joltc run -m NS [args] # resolve deps.edn, load NS, call its -main +bin/joltc run FILE # resolve deps.edn, load a Clojure file +bin/joltc -M:alias [args] # run the alias's :main-opts +bin/joltc -A:alias [args] # add the alias's paths/deps, then run the rest +bin/joltc repl # start a line REPL (project deps + native libs loaded) +bin/joltc nrepl [port] # start an nREPL server (default 7888) for editors +bin/joltc path # print the resolved source roots (':'-joined) +bin/joltc # run a deps.edn :tasks entry ``` Example `deps.edn`: diff --git a/docs/host-interop.md b/docs/host-interop.md index 8c2277f..adf7846 100644 --- a/docs/host-interop.md +++ b/docs/host-interop.md @@ -19,36 +19,6 @@ reflection and no class hierarchy. `(class x)` returns the JVM class name for th scalar/collection types Clojure programs compare against (`"java.lang.Long"`, `"java.lang.String"`, and so on). -## Source layering: JVM-specific code lives in the java layer - -Keep anything JVM-specific in `host/chez/java/`. The rest of the runtime stays -JVM-free, and the compiler in `jolt-core/` is JVM-free by construction. - -- `host/chez/java/` holds the JVM model: the `java.*` mirrors, the class tokens - and class hierarchy, `(class x)`/`(type x)`/`instance?`, exception classes, the - interop dispatch for `.method`/`Class/static`/`(Class.)`. If a value or name - only means something because the JVM has it, it belongs here. -- The rest of `host/chez/` is the host-neutral runtime — the value model - (`values.ss`, `collections.ss`, `seq.ss`), reader, vars, multimethods, meta. It - speaks jolt's own taxonomy (`:string`, `:vector`, `:jolt/inst`), never JVM class - names. -- `jolt-core/` (the Clojure compiler + `clojure.core` overlay) emits and reasons - in that taxonomy only. The JVM mapping happens *after*, in the java layer. - -The worked example is `type`. The core layer (`natives-meta.ss`) computes the -keyword taxonomy and binds it as `__type-tag` — that's what `print-method` and the -reader dispatch on, with no JVM in scope. The java layer (`java/host-class.ss`) -then rebinds the public `clojure.core/type` to Clojure's `(or (:type meta) (class -x))`, mapping `:jolt/inst` → `java.util.Date` and so on, right next to `(class -…)`. So the compiler keeps emitting `:jolt/inst`; the java layer remaps it. - -When you add interop behaviour, prefer registering it through the generic hooks a -java-layer file already uses — `register-class-arm!` for `(class x)`, -`register-instance-check-arm!` for `instance?`, `register-eq-arm!` for value -equality — rather than threading a JVM concept back into a host-neutral file. A -new `java.*` shim is a new file under `host/chez/java/` loaded from `rt.ss`, not a -branch added to `collections.ss` or `seq.ss`. - ## What's shimmed This is the surface today, not the whole JVM. Methods not listed generally @@ -87,10 +57,7 @@ aren't implemented; a few are accepted but no-ops (noted inline). `.hashCode` `.equals` `.getClass` work on any value. - **`java.lang.Class`** — `forName` (throws a catchable `ClassNotFoundException` for a class jolt can't back, so `(try (Class/forName "opt.Dep") (catch …))` - dependency probes work). There is no reflection, but a few common interfaces - carry a modeled ancestry so `(supers c)` / `(ancestors c)` answer like the JVM — - e.g. `(ancestors (class f))` for a function yields `Runnable` and `Callable`, - the check `core.memoize` uses to validate a memoizable argument. + dependency probes work). ### Strings and text @@ -171,13 +138,8 @@ aren't implemented; a few are accepted but no-ops (noted inline). `IllegalArgumentException` `IllegalStateException` `IOException` `NumberFormatException` `ArithmeticException` `NullPointerException` `ClassCastException` `IndexOutOfBoundsException` `FileNotFoundException` - `UnsupportedOperationException` `Error` `AssertionError` and the common network - exceptions, each with the `(E.)` / `(E. msg)` / `(E. msg cause)` / `(E. cause)` - constructors. `try` dispatches its `catch` clauses by class in order, respecting - the exception supertype hierarchy (`(catch Exception e …)` catches a - `RuntimeException` but not an `Error`); a thrown value matching no clause - re-throws. An untyped host condition (e.g. from `(/ 1 0)`) is caught by a - `RuntimeException`/`Exception`/`Throwable` clause. + `UnsupportedOperationException` and the common network exceptions, each with + the `(E.)` / `(E. msg)` / `(E. msg cause)` / `(E. cause)` constructors. What's deliberately absent: STM (`clojure.lang.LockingTransaction/isRunning` returns `false`), reflection, `gen-class`/`proxy` of Java classes, and @@ -240,32 +202,6 @@ register checks without clobbering each other. This is the mechanism jolt's HTTP client library uses to emulate `java.net.URL` and `HttpURLConnection` so `clj-http-lite` runs unchanged. -`__register-instance-check!` answers one `(instance? Foo x)` question. When a -class belongs to a *hierarchy* — a custom exception that should be caught as an -`IOException`, or a value that should match `(instance? SomeInterface x)` across -its whole supertype chain and dispatch a protocol extended to any of those -supertypes — declare its direct supers once with `jolt.host/register-class-supers!` -instead. `instance?`, `isa?`, `supers`/`ancestors`, and `extend-protocol` -dispatch all derive from the one declaration (supers are given by canonical name; -transitivity is computed): - -```clojure -;; a library's exception type that catch/instance? should treat as an IOException -(jolt.host/register-class-supers! "com.acme.RetryExhaustedException" - ["java.io.IOException"]) - -(throw (jolt.host/throwable "com.acme.RetryExhaustedException" "gave up")) -;; (catch java.io.IOException e …) now matches it; (instance? java.lang.Exception e) is true -``` - -deftype/defrecord classes join the same graph automatically at definition: a -record's ancestry carries the record interfaces (`clojure.lang.IRecord`, -`IPersistentMap`, `Associative`, …), a bare deftype carries -`clojure.lang.IType`, and every protocol the type implements inline appears as -an implemented interface — so `(ancestors MyRecord)`, `(isa? MyRecord -clojure.lang.IPersistentMap)`, and hierarchy relationships `derive`d on a -class's supers all answer like the JVM. - Extending a *built-in* class instead (adding a method to core's `String` shim, say) means editing the relevant `host/chez/*.ss` file and running `make remint` — see [building-and-deps.md](building-and-deps.md). diff --git a/docs/libraries.md b/docs/libraries.md index e5c7fec..4a1c9ea 100644 --- a/docs/libraries.md +++ b/docs/libraries.md @@ -1,8 +1,9 @@ # Clojure libraries known to work with Jolt Libraries confirmed to load and pass their conformance checks on Jolt. A library -listed here works. See the [examples](https://github.com/jolt-lang/examples), -e.g. the [ring-app example](https://github.com/jolt-lang/examples/tree/main/ring-app). +listed here works; some need `JOLT_FEATURES` including `clj` (noted below). See +the [examples](https://github.com/jolt-lang/examples), e.g. the +[ring-app example](https://github.com/jolt-lang/examples/tree/main/ring-app). * [aero](https://github.com/juxt/aero) — EDN configuration with tag literals (`#ref`/`#env`/`#or`/`#profile`/`#long`/…) @@ -19,21 +20,23 @@ e.g. the [ring-app example](https://github.com/jolt-lang/examples/tree/main/ring [jolt-lang/jolt-crypto](https://github.com/jolt-lang/jolt-crypto) (OpenSSL) * [reitit-core](https://github.com/metosin/reitit) — data-driven routing; the `reitit.Trie` Java class is mirrored by - [jolt-lang/router](https://github.com/jolt-lang/router). + [jolt-lang/router](https://github.com/jolt-lang/router). `JOLT_FEATURES` `clj`. * [integrant](https://github.com/weavejester/integrant) — data-driven system configuration (`#ig/ref`), with its [dependency](https://github.com/weavejester/dependency) and [meta-merge](https://github.com/weavejester/meta-merge) deps * [honeysql](https://github.com/seancorfield/honeysql) — SQL formatter and helpers -* [clojure.jdbc](https://github.com/yogthos/clojure.jdbc) — via +* [clojure.jdbc](https://github.com/yogthos/clojure.jdbc) — as [jolt-lang/db](https://github.com/jolt-lang/db)'s `jdbc.core`, over the built-in SQLite access (libsqlite3 via Chez's FFI) +* [next.jdbc](https://github.com/seancorfield/next-jdbc) — a compatibility layer in + [jolt-lang/db](https://github.com/jolt-lang/db) over `jdbc.core` * [tools.logging](https://github.com/clojure/tools.logging) — runs verbatim over a native `clojure.tools.logging.impl` stderr backend -* [migratus](https://github.com/yogthos/migratus) — database migrations over - [jolt-lang/db](https://github.com/jolt-lang/db) +* [migratus](https://github.com/yogthos/migratus) — database migrations over the + next.jdbc layer * [malli](https://github.com/metosin/malli) — data schema validation, on the - malli-app example. + malli-app example. `JOLT_FEATURES` `clj`. * [markdown-clj](https://github.com/yogthos/markdown-clj) — Markdown → HTML, on the markdown-app example * [hiccup](https://github.com/weavejester/hiccup) — HTML from Clojure data, on the @@ -41,40 +44,11 @@ e.g. the [ring-app example](https://github.com/jolt-lang/examples/tree/main/ring * [clojure.data.json](https://github.com/clojure/data.json) — JSON reading and writing * [clojure.spec.alpha](https://github.com/clojure/spec.alpha) — data specs * [core.match](https://github.com/clojure/core.match) — pattern matching. + `JOLT_FEATURES` `clj`. * [core.cache](https://github.com/clojure/core.cache) — caching (Basic/FIFO/LRU/ LU/TTL/Soft + the wrapped atom API), over [data.priority-map](https://github.com/clojure/data.priority-map). -* [core.memoize](https://github.com/clojure/core.memoize) — function memoization - over [core.cache](https://github.com/clojure/core.cache). -* [core.async](https://github.com/clojure/core.async) — CSP channels and `go` blocks - (`!`/`alts!`, `pipeline`, `mult`/`mix`/`pub`/`sub`) on real OS threads. -* [core.logic](https://github.com/clojure/core.logic) — relational logic programming - (unification, `run`/`fresh`/`conde`, finite domains). -* [math.combinatorics](https://github.com/clojure/math.combinatorics) — permutations, - combinations, subsets, selections, cartesian products, partitions. -* [core.contracts](https://github.com/clojure/core.contracts) — programming by - contract (`contract`/`with-constraints`/`provide`), over - [core.unify](https://github.com/clojure/core.unify). -* [data.zip](https://github.com/clojure/data.zip) — zipper navigation, including - `clojure.data.zip.xml`; XML parsing via [jolt-lang/xml](https://github.com/jolt-lang/xml) - (which now ships `clojure.xml/parse`). -* [data.csv](https://github.com/clojure/data.csv) — reading and writing CSV. -* [data.codec](https://github.com/clojure/data.codec) — base64 encode/decode over - byte arrays. -* [data.priority-map](https://github.com/clojure/data.priority-map) — priority - maps (incl. keyfn / custom comparator), with `subseq`/`rsubseq`. -* [tools.macro](https://github.com/clojure/tools.macro) — local macros - (`macrolet`/`symbol-macrolet`), `mexpand`/`mexpand-all`. -* [algo.monads](https://github.com/clojure/algo.monads) — monad macros and - monads (maybe/seq/state/writer/reader/…), over - [tools.macro](https://github.com/clojure/tools.macro). -* [test.check](https://github.com/clojure/test.check) — property-based testing - (generators, `quick-check`, shrinking). -* [tools.reader](https://github.com/clojure/tools.reader) — a Clojure reader in - Clojure (edn + full reader, indexing/pushback reader types). -* [rewrite-clj](https://github.com/clj-commons/rewrite-clj) — parse/rewrite Clojure - source while preserving whitespace and comments (nodes + zipper), over - [tools.reader](https://github.com/clojure/tools.reader). + `JOLT_FEATURES` `clj`. * [tick](https://github.com/juxt/tick) — date/time over Jolt's `java.time`; - `#time/…` literals via `time-literals`. + `#time/…` literals via `time-literals`. `JOLT_FEATURES` `clj`. * [transit-jolt](https://github.com/jolt-lang/transit-jolt) — Transit (JSON) read/write diff --git a/docs/rfc/0002-reader-conditional-features.md b/docs/rfc/0002-reader-conditional-features.md index 98affb3..1f5b7ba 100644 --- a/docs/rfc/0002-reader-conditional-features.md +++ b/docs/rfc/0002-reader-conditional-features.md @@ -1,22 +1,9 @@ # RFC 0002 — Reader-Conditional Feature Set -- **Status**: Superseded (2026-06-25) — jolt now includes `:clj` in the default - set; see the note below. +- **Status**: Accepted (implemented; measured) - **Created**: 2026-06-10 - **Spec**: `docs/spec/02-reader.md` §2.3 S18 -> **Update (2026-06-25).** The default set is now **`#{:jolt :clj :default}`** — -> `:clj` is satisfied by default. The clj ecosystem's `.cljc` libraries gate -> their host code behind `#?(:clj …)` with no `:jolt`/`:default` fallback, so -> the conformance libraries (core.cache, core.match, tick, malli, …) only load -> with `:clj` present; requiring an opt-in for each was friction with no payoff -> once jolt's `clojure.lang.*`/`java.*` emulation was broad enough to run those -> `:clj` branches. Matching is still by **clause order**, so a library can place -> a `:jolt` branch first to override. There is no `JOLT_FEATURES` environment -> variable; a loading context overrides the set at runtime with -> `reader-features-set!`. The rest of this RFC is the original (reverted) -> design. - ## Summary jolt's reader-conditional feature set is **`#{:jolt :default}`**, matched in diff --git a/docs/spec/02-reader.md b/docs/spec/02-reader.md index 169bae5..9b7c31a 100644 --- a/docs/spec/02-reader.md +++ b/docs/spec/02-reader.md @@ -159,10 +159,9 @@ checks → UNVERIFIED (rows to add). key the platform satisfies wins (`#?(:default 5 :clj 6)` is `5` everywhere) — not by key priority. Implementations SHOULD provide a per-loading-context compatibility override for foreign-dialect libraries. (jolt: - `#{:jolt :clj :default}` — jolt emulates `clojure.lang.*`/`java.*`, so it - reads the `:clj` branch of a `.cljc` library by default; a library can put a - `:jolt` branch first to override, or a loading context can call - `reader-features-set!`. History in RFC 0002.) + `#{:jolt :default}`, opt-in via `reader-features-set!`/`JOLT_FEATURES`; + decision + A/B data in RFC 0002 — inheriting `:clj` cost 146 suite + assertions and 38 errors.) - Reader conditionals MUST be an error outside `.cljc`-style reading unless the implementation documents otherwise. @@ -225,31 +224,3 @@ reader functions are the deliberate exception, S20). Forms read identically whether or not they will be evaluated; `read-string` of any printable value `v` followed by evaluation yields a value equal to `v` for the self-evaluating types (§4 print/read round-trip contract). - -## Strict tokens and edn mode - -The reader rejects what the reference rejects (corpus `edn / strictness`, -`reader / strict tokens`): - -- A token that starts like a number but doesn't parse as one is - NumberFormatException, never a symbol: `1a`, `08` (a leading zero demands - octal digits; `042` is 34), `0x2g`, `2r2`. A ratio's parts are plain digit - runs (`1/-1` is invalid); a zero denominator is ArithmeticException. -- Empty ns/name parts are invalid tokens: `:`, `::`, `foo/`, `/foo`, `:/foo`. - `/` (division), `ns//` and `:/` (a name of exactly `/`) are valid. -- Map literals with duplicate keys and set literals with duplicate elements - throw IllegalArgumentException at read. -- An unsupported string escape (`"\q"`) and an octal escape past `\377` - (string or `\o` char) throw. A stray close delimiter at top level is - "Unmatched delimiter". `\r` terminates a line comment like `\n`. -- `#inst` validates its calendar fields progressively (month 1–12, day valid - for the month including leap years, hour < 24, minute < 60); `#uuid` - demands canonical 8-4-4-4-12 hex. - -clojure.edn adds on top of that (`__read-form-edn` seam): auto-resolved -keywords (`::k`) are invalid (no resolution context), each `#_` discarded -form is validated through the same `:readers`/`:default` pipeline (an -unreadable tagged element throws even when discarded), `M` literals -construct BigDecimals, lists satisfy `list?`, and end-of-input honors the -`:eof` option — an opts map without `:eof` makes EOF an error, while the -no-opts arity returns nil. diff --git a/docs/spec/09-core-library.md b/docs/spec/09-core-library.md index 2d9138e..778c274 100644 --- a/docs/spec/09-core-library.md +++ b/docs/spec/09-core-library.md @@ -10,40 +10,6 @@ them (e.g. vector `nth` is "effectively constant time" — SHOULD-level). --- -## Collection return types & laziness (cross-cutting) - -Two contracts hold across the sequence library and are not restated per entry. - -**Return-type fidelity.** A function returns the same *kind* of collection the -reference does — value equality is not enough, since `(= [0 1] '(0 1))`. - -- Sequence transformations return **seqs** (lazy unless noted): `map`, `filter`, - `remove`, `keep`, `mapcat`, `take`/`drop` and their `-while` forms, `partition`, - `partition-all`, `partition-by`, `interpose`, `dedupe`, `distinct`, `concat`, - `reductions`, `cons`, `rest`, `sequence`. The *elements* of `partition` / - `partition-all` / `partition-by` are themselves seqs, not vectors. -- The vector variants return **vectors**: `mapv`, `filterv`, `vec`, `subvec`, - `partitionv`, `partitionv-all`, `splitv-at`. `split-at` / `split-with` return a - 2-vector `[take drop]`. A transducer applied eagerly (`into []`, the - `partition-all` transducer's chunks) yields vectors. -- Type-preserving functions return the input's type: `replace` over a vector is a - vector, over any other seqable a (lazy) seq; `empty`/`into (empty coll)` keep the - collection kind; `set`/`into #{}` return sets; `into {}`/`select-keys`/`zipmap`/ - `frequencies`/`group-by`/`merge` return maps (`group-by` values are vectors). - -**Laziness.** The lazy sequence functions — including `sequence`, `eduction`, and -`mapcat` — MUST consume their source incrementally and so terminate on an infinite -or unbounded source when only a prefix is demanded: `(first (sequence (map inc) -(range)))` and `(take n (mapcat f (range)))` return without realizing the whole -source. `(apply concat coll-of-colls)` is likewise lazy in its argument seq. The -eager consumers (`reduce`, `into`, `count`, `vec`, `doall`) realize the demanded -portion fully. - -These are exercised by the `seq / lazy over infinite` and the per-fn type-predicate -rows in the conformance corpus. - ---- - ### first — since 1.0 ``` @@ -196,164 +162,6 @@ cases; clojure-test-suite `core_test/parse_uuid.cljc`, --- -### clojure.template/apply-template, clojure.test/are — since 1.1 - -``` -(apply-template argv expr values) -(are argv expr & args) -``` - -**Semantics** - -- S1. `apply-template` MUST replace every occurrence of each `argv` symbol - in `expr` with its corresponding value by structural walk (postwalk symbol - substitution), not by lexical binding. Occurrences inside `quote` and at - any nesting depth substitute: `(apply-template '[x] '(f 'x) '[if])` ⇒ - `(f 'if)`. -- S2. `do-template` MUST partition `args` by `(count argv)` and expand to a - `do` of one substituted `expr` per group. -- S3. `clojure.test/are` MUST expand through `do-template` with `expr` - wrapped in `is`. Consequently `(are [x] (special-symbol? 'x) if def)` - asserts `(special-symbol? 'if)` and `(special-symbol? 'def)` — a - let-binding implementation is non-conforming (the quoted symbol would not - substitute). - -**Errors** - -- X1. `are` MUST throw at macroexpansion when `(count args)` is not a - positive multiple of a non-empty `(count argv)` (empty/empty is allowed). -- X2. `apply-template` MUST throw when `argv` is not a vector of symbols. - -**Conformance** - -S1–S3 → `test/chez/clojure-test.clj` (are with quoted template var); -clojure-test-suite `core_test/special_symbol_qmark.cljc` and every -`are`-based suite namespace. - ---- - -### make-hierarchy, derive, underive, isa?, parents, ancestors, descendants — since 1.0 - -``` -(make-hierarchy) -(derive tag parent) (derive h tag parent) -(underive tag parent) (underive h tag parent) -(isa? child parent) (isa? h child parent) -(parents tag) (ancestors tag) (descendants tag) ; + (f h tag) forms -``` - -**Semantics** - -- S1. A hierarchy is a pure value `{:parents {tag #{...}} :ancestors {...} - :descendants {...}}`; the 3-arity forms are pure, the shorter arities read and - mutate the global hierarchy. -- S2. `isa?` is true when `(= child parent)`, when the host type system says - parent is assignable from child (both classes), when the relationship was - `derive`d — including a relationship derived on one of a class child's - supers — or component-wise for equal-length vectors. -- S3. Class tags answer through the host type hierarchy: `(parents c)` includes - the class's direct supers (`bases` — a concrete class's chain roots at - `java.lang.Object`, an interface's does not); `(ancestors c)` is the - transitive set plus anything `derive`d on the class or its supers. A - deftype/defrecord class's ancestry includes its implemented protocol - interfaces and, for records, the record interfaces - (`clojure.lang.IRecord`/`IPersistentMap`/`Associative`/…; `clojure.lang.IType` - for a bare deftype). -- S4. `derive` returns the updated hierarchy (3-arity) or nil (2-arity); - deriving a relationship that already holds transitively, or one that would - create a cycle, throws. - -**Errors** - -- X1. `derive` asserts its argument shapes: parent must be a namespaced Named - value; tag must be a class or a Named value (namespaced in the 2-arity - global form); `(derive h tag tag)` fails the `not=` assert. AssertionError. -- X2. `underive`/`derive` with a non-hierarchy `h` throw at the parents - lookup (the map is called as a function, like the reference). -- X3. `(descendants h SomeClass)` throws UnsupportedOperationException - ("Can't get descendants of classes") — Java type inheritance is not - enumerable downward. - -**Conformance** - -S1–S4, X1–X3 → corpus `hierarchy / *` rows; clojure-test-suite -`core_test/{derive,underive,isa_…,parents,ancestors,descendants}.cljc` -(all fully passing). - ---- - -### atom, add-watch, remove-watch, set-validator!, get-validator — since 1.0 - -``` -(atom x & {:keys [meta validator]}) -(add-watch iref key f) (remove-watch iref key) -(set-validator! iref f) (get-validator iref) -``` - -**Semantics** - -- S1. Watches, validators, and reference metadata are one contract (the JVM's - ARef/IRef) shared by atoms, vars, and agents. `add-watch`/`remove-watch` - return the reference; re-adding a key replaces that watch in place. -- S2. A watch is called `(f key ref old new)` after a state change: atom - swap!/reset!/compare-and-set!, var ROOT changes (`def` on a watched var, - `var-set` outside a thread binding, `alter-var-root` — a thread-binding set - does not notify), and each agent action's state change. -- S3. A validator gates every state change and, via the `:validator` ctor - option, the initial value — an invalid initial value never constructs the - reference. -- S4. The `:meta` ctor option attaches reference metadata (`meta` reads it, - `alter-meta!`/`reset-meta!` update it); nil is allowed. - -**Errors** - -- X1. A rejected value (validator returns logical false or the ctor option - fails on the initial value) throws IllegalStateException "Invalid reference - state". -- X2. A non-map `:meta` ctor option throws ClassCastException. - -**Conformance** - -S1–S4, X1–X2 → corpus `iref / *` rows; clojure-test-suite -`core_test/{atom,add-watch,remove-watch}.cljc` (the remaining baselined error -in the watch namespaces is their STM `ref` section — refs are out of scope, -`stm-refs` in `coverage.md`). - ---- - -### clojure.string coercion, some-fn, ifn? — since 1.2/1.3 - -``` -(clojure.string/upper-case s) … (some-fn p & ps) (ifn? x) -``` - -**Semantics** - -- S1. The clojure.string case fns and searches (`upper-case`, `lower-case`, - `capitalize`, `starts-with?`, `ends-with?`, `includes?`, `index-of`, - `replace`) take any Object `s` through its `toString`, like the reference's - `^CharSequence`+`.toString` signatures: `(upper-case :kw)` is `":KW"`, - `(capitalize 1)` is `"1"`. nil throws (method call on null); a nil `substr` - throws. -- S2. `some-fn` follows the reference arities: at least one predicate - (`(some-fn)` is an arity error) and the returned fn chains with `or`, so a - no-match result is the last predicate's own falsy value (`false` stays - `false`). -- S3. `ifn?` covers fns, keywords, symbols, maps, sets, vectors, vars, - multimethods, promises (invoking a promise delivers it), and a - deftype/defrecord implementing `clojure.lang.IFn`'s `invoke`. -- S4. A `defmulti`/`defmethod` deferred inside a fn body interns/resolves in - the namespace it was WRITTEN in (the macros bake their expansion ns), not - whatever namespace is current when it runs. - -**Conformance** - -S1–S4 → corpus `string / toString coercion`, `core / some-fn`, `core / ifn?`, -`multimethods / deferred definition`; clojure-test-suite string/some-fn/ -ifn-qmark/boolean-qmark/reduce namespaces (all fully passing). - ---- - ## Authoring notes - Source examples from the ClojureDocs export (`clojuredocs-export.edn`, diff --git a/docs/spec/coverage.md b/docs/spec/coverage.md index cad2def..c045dbe 100644 --- a/docs/spec/coverage.md +++ b/docs/spec/coverage.md @@ -1,21 +1,21 @@ # Appendix A — Coverage Dashboard (generated) -Generated 2026-06-26 by `tools/spec_coverage.py` — do not edit by hand. +Generated 2026-06-22 by `tools/spec_coverage.py` — do not edit by hand. Surface: **694** clojure.core vars (ClojureDocs export; 648 with -community examples). jolt interns 594 of them. +community examples). jolt interns 574 of them. | Status | Count | Meaning | |---|---|---| -| implemented+tested | 590 | in jolt and exercised by spec/conformance | -| implemented-untested | 4 | in jolt, no direct test — spec entries will add them | +| implemented+tested | 568 | in jolt and exercised by spec/conformance | +| implemented-untested | 6 | in jolt, no direct test — spec entries will add them | | resolvable-not-interned | 0 | works in code but invisible to ns introspection (conformance finding) | -| missing-portable | 0 | portable semantics, jolt lacks it — implementation gap | +| missing-portable | 6 | portable semantics, jolt lacks it — implementation gap | | special-form | 16 | specified in §3, not a library var | -| dynamic-var | 11 | classification needed: portable default vs host-dependent | +| dynamic-var | 24 | classification needed: portable default vs host-dependent | | agents-taps | 16 | out of scope pending concurrency design note | | stm-refs | 11 | out of scope pending concurrency design note | -| jvm-specific | 46 | catalogued, not specified | +| jvm-specific | 47 | catalogued, not specified | Classifications are initial and mechanical — reclassifying is an ordinary spec change. A var is *Verified* only when its §9 entry exists and carries no @@ -27,35 +27,35 @@ UNVERIFIED field; that column will be added as entries land. |---|---|---| | `*` | implemented+tested | ✓ | | `*'` | implemented+tested | ✓ | -| `*1` | implemented+tested | ✓ | -| `*2` | implemented+tested | ✓ | -| `*3` | implemented+tested | ✓ | +| `*1` | missing-portable | ✓ | +| `*2` | missing-portable | ✓ | +| `*3` | missing-portable | ✓ | | `*agent*` | dynamic-var | ✓ | | `*allow-unresolved-vars*` | dynamic-var | ✓ | | `*assert*` | implemented+tested | ✓ | | `*clojure-version*` | implemented+tested | ✓ | -| `*command-line-args*` | implemented-untested | ✓ | -| `*compile-files*` | implemented+tested | ✓ | +| `*command-line-args*` | dynamic-var | ✓ | +| `*compile-files*` | dynamic-var | ✓ | | `*compile-path*` | dynamic-var | ✓ | | `*compiler-options*` | dynamic-var | ✓ | -| `*data-readers*` | implemented+tested | ✓ | -| `*default-data-reader-fn*` | implemented+tested | ✓ | -| `*e` | implemented+tested | ✓ | -| `*err*` | implemented+tested | ✓ | -| `*file*` | implemented-untested | ✓ | -| `*flush-on-newline*` | implemented+tested | | +| `*data-readers*` | dynamic-var | ✓ | +| `*default-data-reader-fn*` | dynamic-var | ✓ | +| `*e` | missing-portable | ✓ | +| `*err*` | implemented-untested | ✓ | +| `*file*` | dynamic-var | ✓ | +| `*flush-on-newline*` | dynamic-var | | | `*fn-loader*` | dynamic-var | | | `*in*` | implemented+tested | | -| `*math-context*` | implemented+tested | | +| `*math-context*` | dynamic-var | | | `*ns*` | implemented+tested | ✓ | -| `*out*` | implemented+tested | ✓ | -| `*print-dup*` | implemented+tested | ✓ | -| `*print-length*` | implemented+tested | ✓ | -| `*print-level*` | implemented+tested | ✓ | -| `*print-meta*` | implemented+tested | ✓ | -| `*print-namespace-maps*` | implemented-untested | ✓ | +| `*out*` | implemented-untested | ✓ | +| `*print-dup*` | dynamic-var | ✓ | +| `*print-length*` | dynamic-var | ✓ | +| `*print-level*` | dynamic-var | ✓ | +| `*print-meta*` | dynamic-var | ✓ | +| `*print-namespace-maps*` | dynamic-var | ✓ | | `*print-readably*` | implemented+tested | ✓ | -| `*read-eval*` | implemented+tested | ✓ | +| `*read-eval*` | dynamic-var | ✓ | | `*reader-resolver*` | dynamic-var | | | `*repl*` | dynamic-var | | | `*source-path*` | dynamic-var | ✓ | @@ -63,7 +63,7 @@ UNVERIFIED field; that column will be added as entries land. | `*unchecked-math*` | implemented+tested | ✓ | | `*use-context-classloader*` | dynamic-var | ✓ | | `*verbose-defrecords*` | dynamic-var | | -| `*warn-on-reflection*` | implemented+tested | ✓ | +| `*warn-on-reflection*` | implemented-untested | ✓ | | `+` | implemented+tested | ✓ | | `+'` | implemented+tested | ✓ | | `-` | implemented+tested | ✓ | @@ -131,7 +131,7 @@ UNVERIFIED field; that column will be added as entries land. | `assoc-in` | implemented+tested | ✓ | | `associative?` | implemented+tested | ✓ | | `atom` | implemented+tested | ✓ | -| `await` | implemented+tested | ✓ | +| `await` | implemented-untested | ✓ | | `await-for` | agents-taps | ✓ | | `await1` | agents-taps | | | `bases` | jvm-specific | ✓ | @@ -218,7 +218,7 @@ UNVERIFIED field; that column will be added as entries land. | `declare` | implemented+tested | ✓ | | `dedupe` | implemented+tested | ✓ | | `def` | special-form | ✓ | -| `default-data-readers` | implemented+tested | ✓ | +| `default-data-readers` | jvm-specific | ✓ | | `definline` | jvm-specific | | | `definterface` | implemented+tested | ✓ | | `defmacro` | special-form | ✓ | @@ -375,7 +375,7 @@ UNVERIFIED field; that column will be added as entries land. | `lazy-cat` | implemented+tested | ✓ | | `lazy-seq` | implemented+tested | ✓ | | `let` | implemented+tested | ✓ | -| `letfn` | implemented+tested | ✓ | +| `letfn` | missing-portable | ✓ | | `line-seq` | implemented+tested | ✓ | | `list` | implemented+tested | ✓ | | `list*` | implemented+tested | ✓ | @@ -512,7 +512,7 @@ UNVERIFIED field; that column will be added as entries land. | `rational?` | implemented+tested | ✓ | | `rationalize` | implemented+tested | ✓ | | `re-find` | implemented+tested | ✓ | -| `re-groups` | implemented+tested | ✓ | +| `re-groups` | missing-portable | ✓ | | `re-matcher` | implemented+tested | ✓ | | `re-matches` | implemented+tested | ✓ | | `re-pattern` | implemented+tested | ✓ | @@ -558,7 +558,7 @@ UNVERIFIED field; that column will be added as entries land. | `reset-vals!` | implemented+tested | ✓ | | `resolve` | implemented+tested | ✓ | | `rest` | implemented+tested | ✓ | -| `restart-agent` | implemented+tested | ✓ | +| `restart-agent` | implemented-untested | ✓ | | `resultset-seq` | jvm-specific | ✓ | | `reverse` | implemented+tested | ✓ | | `reversible?` | implemented+tested | ✓ | diff --git a/docs/tools-deps.md b/docs/tools-deps.md index cba1912..a5501ed 100644 --- a/docs/tools-deps.md +++ b/docs/tools-deps.md @@ -72,41 +72,11 @@ bindings resolve. Each entry is a map — `{:name "sqlite3" :darwin the running process's own symbols, e.g. libc sockets, no external file). A project inherits its dependencies' `:jolt/native`. -### Static vs dynamic linking - -When you `joltc build`, a native lib is **statically linked** into the binary by -default if the spec carries a `:static` archive — so the executable calls the C -code with no shared object present at runtime. Add `:static` alongside the runtime -candidates: - -```clojure -{:name "sqlite3" - :static {:archive "/opt/homebrew/lib/libsqlite3.a"} ; or {:lib "sqlite3" :libdir "/usr/lib"} - :darwin ["libsqlite3.0.dylib"] ; still used by `run`/`repl` and by --dynamic - :linux ["libsqlite3.so.0"]} -``` - -`:static {:archive PATH}` force-loads the whole `.a` and is the reliable -cross-platform form. `:static {:lib NAME :libdir DIR}` links `-lNAME` (with a -`-Bstatic` preference on Linux); on macOS, which has no `-Bstatic`, prefer the -archive form. A spec with no `:static` (or a build passed `--dynamic`, or -`:jolt/build {:dynamic-natives true}`) keeps the old behavior — the shared object -is loaded at startup via `load-shared-object`. - -Static linking needs a C compiler (`cc`) on `PATH` at build time (plus the C libs -the Chez kernel links — lz4, zlib, ncurses). The distributed `joltc` bundles the -Chez kernel, so it re-links the launcher stub with the archive baked in — no -external Chez, just `cc`. Without a `cc`, a `:static` lib fails with a message -pointing you to install one or pass `--dynamic`. Keep a `:darwin`/`:linux` -candidate on any `:static` spec so `run`/`repl` (which have no static binary) can -still load it. - ## Standalone binaries `joltc build -m NS` compiles the app and every library into one executable (the -runtime + compiler are baked in). Resolved `:jolt/native` libs are statically -linked in (or loaded at startup — see [Native libraries](#native-libraries)), so -an FFI app — sockets, SQLite — runs with no jolt or Chez on the path. +runtime + compiler are baked in). It loads the resolved `:jolt/native` libs at +startup, so an FFI app — sockets, SQLite — runs with no jolt or Chez on the path. Output goes under the project's `target/`, cargo-style: `target/release/` by default and with `--opt`, `target/debug/` with `--dev` (the @@ -182,30 +152,6 @@ a root, transitively. - Source only; compiled `.class` files in a git dep are ignored. - git `:git/sha` must be a full SHA (`git fetch` can't resolve a short one). -## Stack traces - -An uncaught error prints the message, the top-level source location, and — when -frames are available — a `trace:` backtrace. In an AOT `jolt build --direct-link` -binary the frames map to `ns/name (file:line)`; on the runtime eval path they are -the surviving fn names. Tail-call optimization erases tail-called frames, so the -default trace shows only the non-tail spine. - -A fuller **tail-frame history** recovers the frames TCO erases: each compiled fn -records itself on entry into a bounded ring-of-rings buffer, so the trace shows -TCO-elided frames (including the immediate error site) while a tight tail loop -stays bounded and its non-tail caller context is preserved. - -It is **on by default in REPL-driven development** — a `repl` or nREPL session -turns it on, so an error in code you evaluate or reload shows a tail-frame trace -with no setup. Because the recording is baked in at compile time, only code -compiled while a session is live is traced; reload a namespace to trace code that -was already loaded (e.g. an app's initial `-M:run` load before its nREPL started). - -Elsewhere it is off (a small per-call cost, and never emitted into a `jolt build` -binary). Override with the environment: `JOLT_TRACE=1` forces it on for a whole -run — including a plain `-M:run`, so the app's own load is traced — and -`JOLT_TRACE=0` forces it off, even in a REPL/nREPL session. - ## Conformance The known-working libraries (see [libraries.md](libraries.md)) and the diff --git a/host/chez/java/async.ss b/host/chez/async.ss similarity index 55% rename from host/chez/java/async.ss rename to host/chez/async.ss index 98a4a11..b988bcf 100644 --- a/host/chez/java/async.ss +++ b/host/chez/async.ss @@ -1,20 +1,17 @@ -;; async.ss — clojure.core.async channel primitives on real OS threads. +;; async.ss — clojure.core.async on real OS threads for the Chez host. ;; -;; A `go` block is an OS thread and a channel is a Chez mutex+condition blocking -;; queue: ! are the blocking !! (they "park" by blocking the thread), -;; and work ANYWHERE — no CPS transform, no go-only restriction. Real parallelism, -;; shared heap. This is a superset of the JVM model: it has no fixed go-block -;; thread pool, no MAX-QUEUE-SIZE on pending ops, and parking ops are legal outside -;; a go block. One OS thread per go block (fine for typical use). +;; A `go` block is an OS thread and a channel is a mutex+condition blocking +;; queue: ! are the blocking !! (they "park" by blocking the thread). +;; ! work ANYWHERE — no CPS transform — because they are ordinary blocking +;; calls. Real parallelism, shared heap. Trade-off: one OS thread per go block +;; (fine for typical use, not for thousands of simultaneous go blocks). ;; ;; Channel: an unbuffered channel is a rendezvous (the putter blocks until its ;; value is taken); a buffered (chan n) put blocks only when full; dropping/sliding -;; buffers never block the putter. A transducer is applied on the put side; an -;; optional ex-handler catches a throw from the transducer step. +;; buffers never block the putter. A transducer is applied on the put side. ;; -;; This file provides the primitives; the higher-level dataflow API (mult, mix, -;; pub/sub, pipeline, map, merge, reduce, …) is a Clojure overlay over them. -;; go/go-loop/thread are macros (mark-macro!) expanding to go-spawn. Loaded after +;; The fns are def-var!'d into clojure.core.async; go/go-loop/thread are macros +;; (mark-macro!) expanding to go-spawn. Loaded after ;; concurrency.ss (reuses ms->duration). Requires a threaded Chez build. ;; --- buffers ---------------------------------------------------------------- @@ -22,8 +19,6 @@ (define (jolt-async-buffer n) (make-async-buffer n 'fixed)) (define (jolt-async-dropping-buffer n) (make-async-buffer n 'dropping)) (define (jolt-async-sliding-buffer n) (make-async-buffer n 'sliding)) -(define (jolt-async-unblocking-buffer? b) - (if (and (async-buffer? b) (memq (async-buffer-kind b) '(dropping sliding promise))) #t #f)) ;; --- channels --------------------------------------------------------------- ;; items: an amortized-O(1) FIFO held as a mutable #(out in len) — `out` is the @@ -32,12 +27,9 @@ ;; Each entry is (value . box); box is #f for a buffered value or a 1-slot vector ;; for an unbuffered rendezvous put (set #t when taken, waking the putter). ;; cap 0 + kind 'unbuffered = rendezvous; cap>0 with kind fixed/dropping/sliding. -;; takew counts threads parked in a blocking take (so a non-blocking offer! to an -;; unbuffered channel can tell a taker is waiting). xrf is the transducer reducing -;; fn (or #f); exh the ex-handler (or #f). (define-record-type async-chan - (fields mu cv (mutable items) cap kind (mutable closed?) (mutable xrf) (mutable takew) exh) - (nongenerative async-chan-v2)) + (fields mu cv (mutable items) cap kind (mutable closed?) (mutable xrf)) + (nongenerative async-chan-v1)) (define (ac-qnew) (vector '() '() 0)) (define (ac-qlen ch) (vector-ref (async-chan-items ch) 2)) @@ -81,30 +73,17 @@ ((null? (cdr args)) (car args)) ; completion (else (ac-buf-give! ch (cadr args)) (car args))))) ; step -;; run the transducer step (or completion) guarded by the channel's ex-handler: -;; if the xform throws and exh returns non-nil, that value is added to the buffer. -(define (ac-xrf-apply ch . v) - (let ((xrf (async-chan-xrf ch)) (exh (async-chan-exh ch))) - (guard (e (#t (if exh - (let ((else (jolt-invoke exh e))) - (unless (jolt-nil? else) (ac-buf-give! ch else)) - (async-chan-xrf ch)) ; treat as non-reduced - (raise e)))) - (apply jolt-invoke xrf ch v)))) +(define (ac-make cap kind xrf) (make-async-chan (make-mutex) (make-condition) (ac-qnew) cap kind #f xrf)) -(define (ac-make cap kind xrf) (make-async-chan (make-mutex) (make-condition) (ac-qnew) cap kind #f xrf 0 #f)) -(define (ac-make/exh cap kind exh) (make-async-chan (make-mutex) (make-condition) (ac-qnew) cap kind #f #f 0 exh)) - -;; (chan) | (chan n) | (chan buf) | (chan n|buf xform) | (chan n|buf xform exh) +;; (chan) | (chan n) | (chan buf) | (chan n|buf xform) (define (jolt-async-chan . args) (let ((buf (if (pair? args) (car args) jolt-nil)) - (xform (if (and (pair? args) (pair? (cdr args))) (cadr args) jolt-nil)) - (exh (if (and (pair? args) (pair? (cdr args)) (pair? (cddr args))) (caddr args) jolt-nil))) + (xform (if (and (pair? args) (pair? (cdr args))) (cadr args) jolt-nil))) (let-values (((cap kind) (cond ((async-buffer? buf) (values (async-buffer-n buf) (async-buffer-kind buf))) ((and (number? buf) (> buf 0)) (values buf 'fixed)) (else (values 0 'unbuffered))))) - (let ((ch (ac-make/exh cap kind (if (jolt-nil? exh) #f exh)))) + (let ((ch (ac-make cap kind #f))) (unless (jolt-nil? xform) (async-chan-xrf-set! ch (jolt-invoke xform (ac-make-add-rf ch)))) ch)))) @@ -114,7 +93,7 @@ (define (ac-close! ch) (unless (async-chan-closed? ch) (async-chan-closed?-set! ch #t) - (when (async-chan-xrf ch) (guard (e (#t #f)) (ac-xrf-apply ch))) + (when (async-chan-xrf ch) (guard (e (#t #f)) (jolt-invoke (async-chan-xrf ch) ch))) (condition-broadcast (async-chan-cv ch))) jolt-nil) (define (jolt-async-close! ch) (with-mutex (async-chan-mu ch) (ac-close! ch))) @@ -123,22 +102,17 @@ ;; transducer the value is run through it (one put -> zero or more channel values); ;; a `reduced` result closes the channel. (define (jolt-async-give ch v) - (when (jolt-nil? v) (jolt-throw (jolt-host-throwable "java.lang.IllegalArgumentException" "Can't put nil on a channel"))) + (when (jolt-nil? v) (jolt-throw (jolt-ex-info "Can't put nil on a channel" (jolt-hash-map)))) (with-mutex (async-chan-mu ch) (cond ((async-chan-closed? ch) #f) ((async-chan-xrf ch) - (let ((r (ac-xrf-apply ch v))) + (let ((r (jolt-invoke (async-chan-xrf ch) ch v))) (when (jolt-reduced? r) (ac-close! ch)) #t)) (else (case (async-chan-kind ch) ((dropping sliding) (ac-buf-give! ch v) #t) - ;; a promise channel takes ONE value, delivered to every taker; further - ;; puts are dropped. Never blocks. - ((promise) (when (ac-qempty? ch) - (ac-qpush! ch (cons v #f)) (condition-broadcast (async-chan-cv ch))) - #t) (else (if (> (async-chan-cap ch) 0) (let loop () ; buffered fixed: wait for room @@ -161,75 +135,44 @@ (condition-broadcast (async-chan-cv ch)) v)) -;; peek the front value without removing it (promise channels keep their value). -(define (ac-peek ch) - (let ((q (async-chan-items ch))) - (ac-qfront! q) - (car (car (vector-ref q 0))))) - ;; (async-chan-cap ch) 0) - (if (< (ac-qlen ch) (async-chan-cap ch)) - (begin (ac-qpush! ch (cons v #f)) (condition-broadcast (async-chan-cv ch)) 'ok) - 'full)) - ;; unbuffered: only immediate if a taker is parked to receive it. - ((> (async-chan-takew ch) 0) - (let ((box (vector #f))) - (ac-qpush! ch (cons v box)) - (condition-broadcast (async-chan-cv ch)) - 'ok)) - (else 'full)))))))) - -;; offer! / poll! — never block. offer! returns #t/#f(closed) on completion, nil if -;; it would block; poll! returns a value, nil (closed+empty), or the ::none sentinel. -(define cca-none (keyword "clojure.core.async" "none")) -(define (jolt-async-offer! ch v) - (case (ac-try-give! ch v) ((ok) #t) ((closed) #f) (else jolt-nil))) -(define (jolt-async-poll! ch) - (let ((r (ac-poll! ch))) (if (eq? r ac-poll-empty) cca-none r))) +;; (alts! [ch ...]) — take from whichever channel is ready first; returns +;; [value channel] (value nil if that channel closed). Take-only: every port must +;; be a channel — put specs [ch val] and the :default option are not supported, so +;; reject them with a clear error instead of crashing inside ac-poll!. +;; Polls with a 1ms backoff — no cross-channel wait-set yet. +(define ac-1ms (make-time 'time-duration 1000000 0)) +(define (jolt-async-alts chans) + (let ((cs (seq->list (jolt-seq chans)))) + (for-each (lambda (c) + (unless (async-chan? c) + (jolt-throw (jolt-ex-info + "alts! supports channel ports only (put specs [ch val] and :default are not supported)" + (jolt-hash-map))))) + cs) + (let loop () + (let try ((rest cs)) + (if (null? rest) + (begin (sleep ac-1ms) (loop)) + (let ((r (ac-poll! (car rest)))) + (if (eq? r ac-poll-empty) + (try (cdr rest)) + (jolt-vector r (car rest))))))))) ;; (timeout ms) — a channel that closes after ms milliseconds. (define (jolt-async-timeout ms) @@ -237,28 +180,17 @@ (fork-thread (lambda () (sleep (ms->duration ms)) (jolt-async-close! w))) w)) -;; (put! ch v [cb [on-caller?]]) — async put, optional completion callback. If the -;; put completes immediately and on-caller? (default #t), the callback runs on the -;; calling thread; otherwise on another thread. Returns true unless already closed. -(define (jolt-async-put! ch v . rest) - (let* ((cb (if (pair? rest) (car rest) jolt-nil)) - (on-caller? (if (and (pair? rest) (pair? (cdr rest))) (jolt-truthy? (cadr rest)) #t)) - (call-cb (lambda (ok) (unless (jolt-nil? cb) (jolt-invoke cb ok))))) - (case (ac-try-give! ch v) - ((ok) (if on-caller? (call-cb #t) (fork-thread (lambda () (call-cb #t)))) #t) - ((closed) (if on-caller? (call-cb #f) (fork-thread (lambda () (call-cb #f)))) #f) - (else (fork-thread (lambda () (call-cb (jolt-async-give ch v)))) #t)))) - -;; (take! ch cb [on-caller?]) — async take. Same on-caller? rule as put!. -(define (jolt-async-take! ch cb . rest) - (let* ((on-caller? (if (pair? rest) (jolt-truthy? (car rest)) #t)) - (call-cb (lambda (v) (unless (jolt-nil? cb) (jolt-invoke cb v)))) - (r (ac-poll! ch))) - (cond - ((eq? r ac-poll-empty) (fork-thread (lambda () (call-cb (jolt-async-take ch))))) - (on-caller? (call-cb r)) - (else (fork-thread (lambda () (call-cb r))))) - jolt-nil)) +;; (put! ch v [cb]) / (take! ch cb) — async put/take on a thread, optional callback. +(define (jolt-async-put! ch v . cb) + (fork-thread (lambda () + (let ((ok (jolt-async-give ch v))) + (when (and (pair? cb) (not (jolt-nil? (car cb)))) (jolt-invoke (car cb) ok))))) + jolt-nil) +(define (jolt-async-take! ch cb) + (fork-thread (lambda () + (let ((v (jolt-async-take ch))) + (unless (jolt-nil? cb) (jolt-invoke cb v))))) + jolt-nil) ;; (go-spawn thunk) — run thunk on a thread; return a buffered(1) channel that ;; conveys its value once then closes (a nil result just closes). Dynamic bindings @@ -292,24 +224,18 @@ ;; --- install clojure.core.async --------------------------------------------- (define (cca-def! name v) (def-var! "clojure.core.async" name v)) (cca-def! "chan" jolt-async-chan) -(cca-def! "promise-chan" (lambda args (ac-make 1 'promise #f))) (cca-def! "chan?" async-chan?) (cca-def! "buffer" jolt-async-buffer) (cca-def! "dropping-buffer" jolt-async-dropping-buffer) (cca-def! "sliding-buffer" jolt-async-sliding-buffer) -(cca-def! "__promise-buffer" (lambda () (make-async-buffer 1 'promise))) -(cca-def! "unblocking-buffer?" jolt-async-unblocking-buffer?) (cca-def! "close!" jolt-async-close!) (cca-def! "!" jolt-async-give) (cca-def! ">!!" jolt-async-give) +(cca-def! "alts!" jolt-async-alts) (cca-def! "alts!!" jolt-async-alts) (cca-def! "timeout" jolt-async-timeout) (cca-def! "put!" jolt-async-put!) (cca-def! "take!" jolt-async-take!) -(cca-def! "offer!" jolt-async-offer!) (cca-def! "go-spawn" async-go-spawn) -;; non-blocking primitives the Clojure overlay's do-alts polls over. -(cca-def! "__poll!" jolt-async-poll!) -(cca-def! "__offer!" jolt-async-offer!) (cca-def! "go" cca-go-macro) (mark-macro! "clojure.core.async" "go") (cca-def! "go-loop" cca-go-loop-macro) (mark-macro! "clojure.core.async" "go-loop") (cca-def! "thread" cca-thread-macro) (mark-macro! "clojure.core.async" "thread") diff --git a/host/chez/atoms.ss b/host/chez/atoms.ss index 5fcd27c..fedd144 100644 --- a/host/chez/atoms.ss +++ b/host/chez/atoms.ss @@ -23,38 +23,21 @@ (fields (mutable val) (mutable watches) (mutable validator) lock) (nongenerative jolt-atom-v3)) -;; a rejected reference value is IllegalStateException, like ARef.validate. -(define (jolt-iref-state-throw) - (jolt-throw (jolt-host-throwable "java.lang.IllegalStateException" "Invalid reference state"))) - -;; (atom init :meta m :validator f) — the ARef ctor contract: the validator runs -;; against the initial value (an invalid init never constructs), :meta must be a -;; map (anything else is the JVM's IPersistentMap cast failure). +;; (atom init) / (atom init :validator f :meta m): scan the trailing keyword opts +;; for :validator (the only one with runtime behaviour; :meta is accepted/ignored). (define (jolt-atom-new v . opts) - (let loop ((o opts) (validator jolt-nil) (m #f)) + (let loop ((o opts) (validator jolt-nil)) (cond - ((or (null? o) (null? (cdr o))) - (let ((a (make-jolt-atom v '() validator (make-mutex)))) - (jolt-atom-validate a v) - (when (and m (not (jolt-nil? m))) - (unless (jolt-map? m) - (jolt-throw (jolt-host-throwable - "java.lang.ClassCastException" - (string-append "class " (jolt-class-name m) - " cannot be cast to class clojure.lang.IPersistentMap")))) - (hashtable-set! meta-table a m)) - a)) + ((or (null? o) (null? (cdr o))) (make-jolt-atom v '() validator (make-mutex))) ((and (keyword-t? (car o)) (string=? (keyword-t-name (car o)) "validator")) - (loop (cddr o) (cadr o) m)) - ((and (keyword-t? (car o)) (string=? (keyword-t-name (car o)) "meta")) - (loop (cddr o) validator (cadr o))) - (else (loop (cddr o) validator m))))) + (loop (cddr o) (cadr o))) + (else (loop (cddr o) validator))))) ;; validate a candidate value: a non-nil validator that returns falsey rejects. (define (jolt-atom-validate a v) (let ((vf (jolt-atom-validator a))) (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf v))) - (jolt-iref-state-throw)))) + (error #f "Invalid reference state")))) ;; notify each watch (k ref old new), in insertion order (alist is reverse-built, ;; so walk it reversed to match add order). @@ -123,87 +106,27 @@ (jolt-atom-notify a old v) (jolt-vector old v))) -;; --- watches / validators: the IRef seam -------------------------------------- -;; On the JVM these are the ARef contract shared by atom/var/agent/ref. The atom -;; keeps its record slots (the hot swap!/reset! path); every OTHER watchable -;; reference type registers a predicate here and stores its watches/validator in -;; identity-keyed side tables. A ref type makes itself notify by calling -;; iref-notify at its mutation points (vars do at root set). -(define iref-arms '()) -(define (register-iref-arm! pred) (set! iref-arms (cons pred iref-arms))) -(define (iref? r) - (let loop ((as iref-arms)) - (cond ((null? as) #f) (((car as) r) #t) (else (loop (cdr as)))))) -(define iref-watch-tbl (make-weak-eq-hashtable)) -(define iref-validator-tbl (make-weak-eq-hashtable)) -(define (iref-notify r old new) - (for-each (lambda (kv) (jolt-invoke (cdr kv) (car kv) r old new)) - (reverse (hashtable-ref iref-watch-tbl r '())))) -(define (iref-validate r v) - (let ((vf (hashtable-ref iref-validator-tbl r jolt-nil))) - (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf v))) - (jolt-iref-state-throw)))) - +;; --- watches / validators --------------------------------------------------- ;; add-watch interns (key . fn) (replacing any existing key, keeping order); -;; remove-watch drops it; both return the reference. set-validator! installs a +;; remove-watch drops it; both return the atom. set-validator! installs a ;; validator and validates the CURRENT value immediately (Clojure throws if it's ;; already invalid); get-validator reads the slot. -(define (jolt-watch-add alist key f) - (cons (cons key f) (remp (lambda (kv) (jolt=2 (car kv) key)) alist))) (define (jolt-add-watch a key f) - (cond - ((jolt-atom? a) - (jolt-atom-watches-set! a (jolt-watch-add (jolt-atom-watches a) key f)) - a) - ((iref? a) - (hashtable-set! iref-watch-tbl a (jolt-watch-add (hashtable-ref iref-watch-tbl a '()) key f)) - a) - (else (error #f "add-watch: not a watchable reference" a)))) + (jolt-atom-watches-set! a + (cons (cons key f) + (remp (lambda (kv) (jolt=2 (car kv) key)) (jolt-atom-watches a)))) + a) (define (jolt-remove-watch a key) - (cond - ((jolt-atom? a) - (jolt-atom-watches-set! a - (remp (lambda (kv) (jolt=2 (car kv) key)) (jolt-atom-watches a))) - a) - ((iref? a) - (hashtable-set! iref-watch-tbl a - (remp (lambda (kv) (jolt=2 (car kv) key)) (hashtable-ref iref-watch-tbl a '()))) - a) - (else (error #f "remove-watch: not a watchable reference" a)))) + (jolt-atom-watches-set! a + (remp (lambda (kv) (jolt=2 (car kv) key)) (jolt-atom-watches a))) + a) (define (jolt-set-validator! a f) (let ((vf (if (jolt-nil? f) jolt-nil f))) - (cond - ((jolt-atom? a) - (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf (jolt-atom-val a)))) - (jolt-iref-state-throw)) - (jolt-atom-validator-set! a vf)) - ((iref? a) - (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf (jolt-deref a)))) - (jolt-iref-state-throw)) - (hashtable-set! iref-validator-tbl a vf)) - (else (error #f "set-validator!: not a reference" a))) + (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf (jolt-atom-val a)))) + (error #f "Invalid reference state")) + (jolt-atom-validator-set! a vf) jolt-nil)) -(define (jolt-get-validator a) - (cond ((jolt-atom? a) (jolt-atom-validator a)) - ((iref? a) (hashtable-ref iref-validator-tbl a jolt-nil)) - (else jolt-nil))) - -;; vars are watchable IRefs: a root change (def / var-set on the root / -;; alter-var-root) validates and notifies like Var.bindRoot. The def-var! wrap -;; pays two weak-table probes per def and only does IRef work on a watched var. -(register-iref-arm! var-cell?) -(define def-var!-pre-iref def-var!) -(set! def-var! - (lambda (ns name v) - (let ((c (jolt-var ns name))) - (if (or (pair? (hashtable-ref iref-watch-tbl c '())) - (not (jolt-nil? (hashtable-ref iref-validator-tbl c jolt-nil)))) - (let ((old (var-cell-root c))) - (iref-validate c v) - (let ((r (def-var!-pre-iref ns name v))) - (iref-notify c old v) - r)) - (def-var!-pre-iref ns name v))))) +(define (jolt-get-validator a) (jolt-atom-validator a)) (def-var! "clojure.core" "atom" jolt-atom-new) (def-var! "clojure.core" "deref" jolt-deref) diff --git a/host/chez/bigdec.ss b/host/chez/bigdec.ss new file mode 100644 index 0000000..f0a5192 --- /dev/null +++ b/host/chez/bigdec.ss @@ -0,0 +1,74 @@ +;; BigDecimal. A jbigdec is {unscaled, scale} over Chez arbitrary-precision exact +;; integers; its value is unscaled * 10^-scale (1.5M = {15,1}, 1.00M = {100,2}, +;; 3M = {3,0}). M-suffix literals read to a :bigdec form that the back end lowers +;; to jolt-bigdec-from-string; bigdec coerces a number/string. Equality is by +;; value (1.0M = 1.00M), str drops the M, pr keeps it, class is +;; java.math.BigDecimal. Arithmetic contagion is not modelled. + +(define-record-type jbigdec (fields unscaled scale) (nongenerative chez-jbigdec-v1)) + +(define (bd-index-char s ch) + (let loop ((i 0)) + (cond ((>= i (string-length s)) #f) + ((char=? (string-ref s i) ch) i) + (else (loop (+ i 1)))))) + +;; "1.50" -> {150,2}; "3" -> {3,0}; "-0.0" -> {0,1}; ".5" -> {5,1}. +(define (jolt-bigdec-from-string s) + (let* ((neg (and (> (string-length s) 0) (char=? (string-ref s 0) #\-))) + (sgn (and (> (string-length s) 0) (or neg (char=? (string-ref s 0) #\+)))) + (s1 (if sgn (substring s 1 (string-length s)) s)) + (sign (if neg -1 1)) + (dot (bd-index-char s1 #\.))) + (if dot + (let* ((intp (substring s1 0 dot)) + (fracp (substring s1 (+ dot 1) (string-length s1))) + (digs (string-append intp fracp)) + (unscaled (if (= 0 (string-length digs)) 0 (string->number digs)))) + (make-jbigdec (* sign unscaled) (string-length fracp))) + (make-jbigdec (* sign (string->number s1)) 0)))) + +;; bigdec coercion: a bigdec is itself; an exact integer keeps scale 0; a string +;; or any other number routes through its decimal text. +(define (jolt-bigdec x) + (cond + ((jbigdec? x) x) + ((and (number? x) (exact? x) (integer? x)) (make-jbigdec x 0)) + ((string? x) (jolt-bigdec-from-string x)) + ((number? x) (jolt-bigdec-from-string (jolt-num->string x))) + (else (error #f "bigdec: cannot coerce" x)))) + +;; value equality: unscaled_a * 10^scale_b == unscaled_b * 10^scale_a. +(define (jbigdec=? a b) + (= (* (jbigdec-unscaled a) (expt 10 (jbigdec-scale b))) + (* (jbigdec-unscaled b) (expt 10 (jbigdec-scale a))))) + +;; render the decimal text (no M): insert the point `scale` digits from the right. +(define (jbigdec->string bd) + (let* ((u (jbigdec-unscaled bd)) (sc (jbigdec-scale bd)) + (neg (< u 0)) (digs (number->string (abs u)))) + (string-append + (if neg "-" "") + (if (<= sc 0) + digs + (let* ((padded (if (<= (string-length digs) sc) + (string-append (make-string (- (+ sc 1) (string-length digs)) #\0) digs) + digs)) + (pl (string-length padded))) + (string-append (substring padded 0 (- pl sc)) "." (substring padded (- pl sc) pl))))))) + +;; --- wire into the value model ---------------------------------------------- +(def-var! "clojure.core" "bigdec" jolt-bigdec) + +;; equality: a bigdec equals only another bigdec, by value (matching (= 3M 3) = false). +(register-eq-arm! (lambda (a b) (or (jbigdec? a) (jbigdec? b))) + (lambda (a b) (and (jbigdec? a) (jbigdec? b) (jbigdec=? a b)))) + +;; str drops the M; pr/pr-str keep it. +(register-str-render! jbigdec? jbigdec->string) +(register-pr-arm! jbigdec? (lambda (x) (string-append (jbigdec->string x) "M"))) + +;; class / decimal? +(register-class-arm! jbigdec? (lambda (x) "java.math.BigDecimal")) +(set! jolt-decimal? (lambda (x) (jbigdec? x))) +(def-var! "clojure.core" "decimal?" jolt-decimal?) diff --git a/host/chez/build-joltc.ss b/host/chez/build-joltc.ss deleted file mode 100644 index 12612a1..0000000 --- a/host/chez/build-joltc.ss +++ /dev/null @@ -1,264 +0,0 @@ -;; build-joltc.ss — build joltc itself as a self-contained native binary (jolt-eaj). -;; -;; chez --script host/chez/build-joltc.ss -;; profile: "release" | "debug" out-path: e.g. target/release/joltc -;; -;; Runs on a dev/CI machine that HAS Chez + cc. Produces a binary that needs -;; NEITHER: it bakes the full runtime + compiler image + all jolt-core/stdlib -;; source + the Chez petite/scheme boots + a prebuilt launcher stub into one -;; cc-linked executable, so the resulting joltc can run AND `build` jolt apps on -;; its own. joltc itself is cc-linked (not appended) so its signature stays clean -;; for Homebrew/codesign, like dirge's binaries; only the apps it later builds use -;; the appended-stub path (host/chez/build.ss build-self-contained). -;; -;; Pipeline: -;; 0. cc-compile host/chez/stub/launcher.c against the Chez kernel. -;; 1. emit flat.ss = runtime + compiler image (cli.ss load order) + inlined -;; build.ss + every jolt-core/stdlib file as a baked string literal + the -;; joltc launcher. -;; 2. in-process compile-file + make-boot-file (profile Chez settings), error -;; restored around the call (the runtime shadows it; regex.ss/%chez-error). -;; 3. xxd the joltc boot + petite/scheme boots + stub into C arrays, generate -;; main.c, cc-link -> out-path. The launcher reads the petite/scheme/stub -;; arrays via FFI on `build` (jolt-materialize-bundles!). - -(import (chezscheme)) - -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") -(load "host/chez/png.ss") -(load "host/chez/loader.ss") -(load "host/chez/java/ffi.ss") -(set-source-roots! (list "jolt-core" "stdlib")) -(load "host/chez/build.ss") ; bld-* helpers, ei-* (emit-image), dce - -(define jb-args (cdr (command-line))) -(define jb-profile (if (pair? jb-args) (car jb-args) "release")) -(define jb-out (if (and (pair? jb-args) (pair? (cdr jb-args))) (cadr jb-args) - (string-append "target/" jb-profile "/joltc"))) -(define jb-release? (string=? jb-profile "release")) -(unless (or jb-release? (string=? jb-profile "debug")) - (error 'build-joltc "profile must be \"release\" or \"debug\"" jb-profile)) - -;; Version baked into the binary's saved heap. Prefer $JOLT_VERSION (CI sets it to -;; the release tag); else derive it from git in this checkout; else "dev". -(define jb-version - (let ((env (getenv "JOLT_VERSION"))) - (if (and env (> (string-length env) 0)) - env - (let ((s (bld-sh-capture "git describe --tags --always --dirty 2>/dev/null"))) - (if (> (string-length s) 0) s "dev"))))) - -(define jb-build (string-append jb-out ".build")) -(bld-check-toolchain) -(bld-system (string-append "mkdir -p '" (path-parent jb-out) "' '" jb-build "'")) - -;; --- 0. compile the launcher stub ------------------------------------------- -(define jb-stub (string-append jb-build "/launcher")) -(display "build-joltc: compiling launcher stub\n") -(bld-system (string-append - "cc -O2 -I'" bld-csv-dir "' 'host/chez/stub/launcher.c' '" - bld-csv-dir "/libkernel.a' -o '" jb-stub "' " (bld-link-libs))) - -;; --- 1. emit flat.ss -------------------------------------------------------- -(define jb-flat-ss (string-append jb-build "/flat.ss")) -(define (str-suffix? s suf) - (let ((n (string-length s)) (m (string-length suf))) - (and (>= n m) (string=? (substring s (- n m) n) suf)))) - -;; Bake every jolt-core/stdlib source file as an in-heap string literal keyed by -;; its root-relative path ("jolt/main.clj", "clojure/string.clj") — exactly what -;; resolve-on-roots probes. Literals (not read-file-string at startup) because -;; flat.ss top-level forms run at every startup, with no source on disk. -(define (jb-emit-source-embeds out) - (for-each - (lambda (root) - (for-each - (lambda (rp) - (let ((rel (car rp)) (abs (cdr rp))) - (when (or (str-suffix? rel ".clj") (str-suffix? rel ".cljc")) - (put-string out (string-append - "(register-embedded-resource! " (ei-str-lit rel) " " - (ei-str-lit (read-file-string abs)) ")\n"))))) - (bld-walk-files root "" '()))) - (list "jolt-core" "stdlib"))) - -;; Embed every runtime .ss the build inlines into an app (the transitive closure of -;; the manifest's loads: rt.ss + all it loads, the seed, compile-eval, loader, ffi, -;; png, vendored irregex). Keyed by the exact path the (load "…") forms use, so -;; build.ss's bld-source-string reads them from the binary with no jolt source on -;; disk. Traversal mirrors bld-emit-runtime/bld-inline-line via the same -;; bld-file-lines + bld-load-path, so the embedded set is exactly what build reads. -(define (jb-collect-load-paths) - (let ((seen (make-hashtable string-hash string=?)) (order '())) - (define (walk path) - (when (and path (not (hashtable-ref seen path #f))) - (hashtable-set! seen path #t) - (set! order (cons path order)) - (for-each (lambda (l) (walk (bld-load-path l))) (bld-file-lines path)))) - (for-each (lambda (entry) (when (string? entry) (walk (bld-load-path entry)))) - bld-runtime-manifest) - (for-each (lambda (kv) (walk (bld-load-path (cdr kv)))) bld-tagged-loads) - (reverse order))) - -(define (jb-emit-runtime-embeds out) - (for-each - (lambda (path) - (put-string out (string-append - "(register-embedded-resource! " (ei-str-lit path) " " - (ei-str-lit (read-file-string path)) ")\n"))) - (jb-collect-load-paths))) - -;; The launcher (Chez scheme-start): replicates host/chez/cli.ss but reads argv -;; from the scheme-start lambda and has no repo root to cd into (all source is -;; embedded; JOLT_PWD defaults to cwd via io/jolt.main). build.ss is already -;; inlined, so `build` dispatches straight to jolt.host/build-binary after the -;; bundled boots/stub are materialized from the binary's own C arrays. -(define (jb-emit-launcher out) - (put-string out " -;; Materialize the bundled Chez boots + launcher stub (cc-linked into this binary -;; as C arrays) into the embedded-bytes store, so build-self-contained can spill -;; them. Done lazily on `build` only. -(define (jolt-materialize-bundles!) - (load-shared-object #f) - (let ((memcpy (foreign-procedure \"memcpy\" (u8* uptr uptr) void*))) - (for-each - (lambda (spec) - (let* ((len (foreign-ref 'unsigned-int (foreign-entry (caddr spec)) 0)) - (bv (make-bytevector len))) - (memcpy bv (foreign-entry (cadr spec)) len) - (register-embedded-bytes! (car spec) bv))) - '((\"csv/petite.boot\" \"jolt_petite_boot\" \"jolt_petite_boot_len\") - (\"csv/scheme.boot\" \"jolt_scheme_boot\" \"jolt_scheme_boot_len\") - (\"stub/launcher\" \"jolt_stub\" \"jolt_stub_len\") - (\"csv/scheme.h\" \"jolt_scheme_h\" \"jolt_scheme_h_len\") - (\"csv/libkernel.a\" \"jolt_libkernel_a\" \"jolt_libkernel_a_len\") - (\"stub/launcher.c\" \"jolt_launcher_c\" \"jolt_launcher_c_len\"))))) - -(suppress-greeting #t) -(scheme-start - (lambda args - (set-source-roots! (list \"jolt-core\" \"stdlib\")) - ;; JOLT_TRACE at RUNTIME (the env is unset at heap-build), before any app ns - ;; compiles, so a `-M:run` traces the app's own code. - (jolt-trace-init-from-env!) - (guard (v (#t (jolt-report-throwable v (current-error-port)) (exit 1))) - (cond - ((and (= (length args) 2) (string=? (car args) \"-e\")) - (let ((result (jolt-final-str - (jolt-compile-eval (string-append \"(do \" (cadr args) \")\") \"user\")))) - (unless (string=? result \"\") (display result) (newline)))) - (else - (when (and (pair? args) (string=? (car args) \"build\")) - (jolt-materialize-bundles!)) - (load-namespace \"jolt.main\") - (apply jolt-invoke (var-deref \"jolt.main\" \"-main\") args)))) - (exit 0))) -")) - -(display "build-joltc: emitting flat source\n") -(let ((out (open-output-file jb-flat-ss 'replace))) - ;; full runtime + compiler image: keep the compiler (joltc evals at runtime). - (bld-emit-runtime out #f #f) - (put-string out "\n;; === build driver (inlined for self-contained `jolt build`) ===\n") - (bld-inline-line "(load \"host/chez/build.ss\")" out 0) - (put-string out "\n;; === embedded runtime source (self-contained `build` reads these) ===\n") - (jb-emit-runtime-embeds out) - (put-string out "\n;; === embedded jolt-core + stdlib source ===\n") - (jb-emit-source-embeds out) - ;; Bake the version into the saved heap (runs at heap-build; loader.ss defined - ;; jolt-baked-version above, so this set! resolves). - (put-string out (string-append "\n;; === baked version ===\n(set! jolt-baked-version " - (ei-str-lit jb-version) ")\n")) - (put-string out "\n;; === joltc launcher ===\n") - (jb-emit-launcher out) - (close-port out)) - -;; --- 2. compile + boot in a FRESH Chez (profile Chez settings) -------------- -;; joltc is a compiler/REPL: it evals jolt-compiled Scheme at runtime, which must -;; resolve the runtime's top-level procedures (var-deref, jolt-inc, …) through the -;; boot's interaction-environment. compile-file's top-level defines are visible -;; there only when compiled in the REAL interaction-environment, and `error` (and -;; other primitives the inlined runtime references before redefining) bind to the -;; kernel primitive only when compiled against a clean chezscheme env. A fresh -;; Chez process gives both at once — exactly the legacy build-with-cc pass. The -;; in-process compile in build.ss/build-self-contained is for the distributed -;; joltc building (non-eval) apps, where no Chez is available. -(define jb-flat-so (string-append jb-build "/flat.so")) -(define jb-boot (string-append jb-build "/joltc.boot")) -(define jb-bool (lambda (b) (if b "#t" "#f"))) -(display (string-append "build-joltc: compiling (" jb-profile " profile)\n")) -(let ((cs (string-append jb-build "/compile.ss"))) - (let ((p (open-output-file cs 'replace))) - (put-string p - (string-append - "(import (chezscheme))\n" - "(optimize-level " (if jb-release? "3" "0") ")\n" - "(generate-inspector-information " (jb-bool (not jb-release?)) ")\n" - "(generate-procedure-source-information " (jb-bool (not jb-release?)) ")\n" - "(debug-on-exception " (jb-bool (not jb-release?)) ")\n" - "(fasl-compressed " (jb-bool jb-release?) ")\n" - "(compile-file " (ei-str-lit jb-flat-ss) " " (ei-str-lit jb-flat-so) ")\n" - "(make-boot-file " (ei-str-lit jb-boot) " '()\n " - (ei-str-lit (string-append bld-csv-dir "/petite.boot")) "\n " - (ei-str-lit (string-append bld-csv-dir "/scheme.boot")) "\n " - (ei-str-lit jb-flat-so) ")\n")) - (close-port p)) - (bld-system (string-append bld-chez " --script '" cs "'"))) - -;; --- 3. embed boots/stub as C arrays + cc-link ------------------------------ -;; xxd a file into header H and rename its symbol to NAME / NAME_len. -(define (jb-c-array file h name) - (bld-system (string-append "xxd -i '" file "' > '" h "'")) - (bld-system (string-append - "sed -i.bak -E 's/unsigned char [A-Za-z0-9_]+\\[\\]/unsigned char " name "[]/; " - "s/unsigned int [A-Za-z0-9_]+_len/unsigned int " name "_len/' '" h "'"))) - -(display "build-joltc: embedding boots + stub, linking\n") -(jb-c-array jb-boot (string-append jb-build "/boot_data.h") "jolt_boot") -(jb-c-array (string-append bld-csv-dir "/petite.boot") (string-append jb-build "/petite_data.h") "jolt_petite_boot") -(jb-c-array (string-append bld-csv-dir "/scheme.boot") (string-append jb-build "/scheme_data.h") "jolt_scheme_boot") -(jb-c-array jb-stub (string-append jb-build "/stub_data.h") "jolt_stub") -;; Also bundle the Chez kernel (libkernel.a + scheme.h) and the launcher source, -;; so a `build` with :static native libs can re-link a custom stub with those -;; archives baked in — the appended-stub path can't add object code to a prebuilt -;; stub, so it relinks (build.ss bld-relink-stub). Needs the system cc at build. -(jb-c-array (string-append bld-csv-dir "/scheme.h") (string-append jb-build "/schemeh_data.h") "jolt_scheme_h") -(jb-c-array (string-append bld-csv-dir "/libkernel.a") (string-append jb-build "/libkernel_data.h") "jolt_libkernel_a") -(jb-c-array "host/chez/stub/launcher.c" (string-append jb-build "/launcherc_data.h") "jolt_launcher_c") - -(define jb-main-c (string-append jb-build "/main.c")) -(let ((mc (open-output-file jb-main-c 'replace))) - (put-string mc - (string-append - "#include \"scheme.h\"\n" - "#include \"boot_data.h\"\n" - "#include \"petite_data.h\"\n" - "#include \"scheme_data.h\"\n" - "#include \"stub_data.h\"\n" - "#include \"schemeh_data.h\"\n" - "#include \"libkernel_data.h\"\n" - "#include \"launcherc_data.h\"\n" - "int main(int argc, char *argv[]) {\n" - " Sscheme_init(0);\n" - " Sregister_boot_file_bytes(\"jolt\", jolt_boot, jolt_boot_len);\n" - " Sbuild_heap(0, 0);\n" - " int status = Sscheme_start(argc, (const char **)argv);\n" - " Sscheme_deinit();\n return status;\n}\n")) - (close-port mc)) - -;; -rdynamic puts the embedded jolt_* boot/stub symbols in the dynamic symbol -;; table so `build` can foreign-entry them to spill the bundled Chez boots. On -;; Linux dlsym can't see executable symbols otherwise (macOS exports them anyway). -(bld-system (string-append - ;; the embedded jolt_* arrays must be foreign-entry-visible at runtime: - ;; -rdynamic on ELF; on Windows an exe needs an export table (GetProcAddress). - "cc -O2 " (if bld-nt? "-Wl,--export-all-symbols " "-rdynamic ") "-I'" bld-csv-dir "' -I'" jb-build "' '" jb-main-c "' '" - bld-csv-dir "/libkernel.a' -o '" jb-out "' " (bld-link-libs))) -(display (string-append "build-joltc: wrote " jb-out "\n")) diff --git a/host/chez/build-smoke.sh b/host/chez/build-smoke.sh index 76b4f50..95ae1f2 100755 --- a/host/chez/build-smoke.sh +++ b/host/chez/build-smoke.sh @@ -81,41 +81,6 @@ fi if ! grep -q '(jv\$app.util\$shout' "$out.build/flat.ss"; then echo " FAIL: --direct-link did not emit a direct app->app call"; exit 1 fi -# A direct-link build registers fn sources, so an uncaught throw prints a Clojure -# stack trace mapping each native frame back to ns/name (file:line). -if ! grep -q 'jolt-register-source!' "$out.build/flat.ss"; then - echo " FAIL: --direct-link did not emit source registrations"; exit 1 -fi -boom_err="$(cd / && "$out" --boom 2>&1 >/dev/null)" -for frame in 'app.util/deep-boom' 'app.util/mid-boom' 'app.core/-main'; do - if ! printf '%s' "$boom_err" | grep -q "$frame"; then - echo " FAIL: stack trace missing frame $frame" - echo "--- got ----"; echo "$boom_err" - exit 1 - fi -done -# A built binary runs -main with *ns* = user, like clojure.main — so a runtime -# resolve of an aliased symbol is nil (the alias lives in the entry ns, not user), -# matching the JVM and interpreted joltc rather than the entry ns's alias table. A -# separate app: `resolve` defeats tree-shaking, so keep it out of the shake test's -# app above. -nsp="$(dirname "$out")/nsparity" -mkdir -p "$nsp/src/nsp" -printf '{:paths ["src"]}\n' > "$nsp/deps.edn" -printf '(ns nsp.lib)\n(defn thing [] 1)\n' > "$nsp/src/nsp/lib.clj" -printf '(ns nsp.main (:require [nsp.lib :as l]))\n(defn -main [& _]\n (println "ns:" (str *ns*))\n (println "resolve:" (pr-str (resolve (quote l/thing))))\n (println "ns-resolve:" (pr-str (ns-resolve (quote nsp.lib) (quote thing)))))\n' > "$nsp/src/nsp/main.clj" -nspout="$(dirname "$out")/nsparity-bin" -if ! JOLT_PWD="$nsp" bin/joltc build -m nsp.main -o "$nspout" >/dev/null 2>&1; then - echo " FAIL: jolt build of the ns-parity app exited non-zero"; exit 1 -fi -nsp_out="$(cd / && "$nspout" 2>&1)" -if ! printf '%s' "$nsp_out" | grep -q 'ns: user' \ - || ! printf '%s' "$nsp_out" | grep -q '^resolve: nil' \ - || ! printf '%s' "$nsp_out" | grep -q "ns-resolve: #'nsp.lib/thing"; then - echo " FAIL: built binary -main ns parity — want 'ns: user', 'resolve: nil', ns-resolve found" - echo "--- got ----"; echo "$nsp_out" - exit 1 -fi # Tree-shaking (opt-in): same result, and an unreachable def (the `twice` macro, # expanded at AOT and never called at runtime) is dropped. if ! JOLT_PWD="$app" bin/joltc build -m app.core -o "$out" --tree-shake >/dev/null 2>&1; then @@ -138,33 +103,4 @@ fi if grep -q 'def-var! "clojure.core" "group-by"' "$out.build/flat.ss"; then echo " FAIL: --tree-shake kept an unreachable clojure.core fn (group-by)"; exit 1 fi -# A registered data reader that returns a CODE form must be compiled into the -# binary (the emit path applies it too, not just the interpreted loader): the -# datareader-app's #code literal builds to 42, not the literal list. -drapp="$root/test/chez/datareader-app" -drout="$(dirname "$out")/dr-bin" -if ! JOLT_PWD="$drapp" bin/joltc build -m drtest.main -o "$drout" >/dev/null 2>&1; then - echo " FAIL: jolt build of a data-reader app exited non-zero"; exit 1 -fi -got_dr="$(cd / && "$drout" 2>&1 | tail -1)" -if [ "$got_dr" != "42" ]; then - echo " FAIL: built #code data reader — want 42, got \`$got_dr\`"; exit 1 -fi - -# A script namespace with no -main (just top-level side effects) must build and -# run its top-level forms, then exit cleanly — not crash calling a nil -main. -nomain="$(dirname "$out")/nomain" -mkdir -p "$nomain/src" -printf '{:paths ["src"]}\n' > "$nomain/deps.edn" -printf '(ns script)\n(println "no-main script ran")\n' > "$nomain/src/script.clj" -nmout="$(dirname "$out")/nomain-bin" -if ! JOLT_PWD="$nomain" bin/joltc build -m script -o "$nmout" >/dev/null 2>&1; then - echo " FAIL: jolt build of a no-main script exited non-zero"; exit 1 -fi -got_nm="$(cd / && "$nmout" 2>&1)"; rc_nm=$? -if [ "$got_nm" != "no-main script ran" ] || [ "$rc_nm" != "0" ]; then - echo " FAIL: no-main script binary — want 'no-main script ran' rc 0, got \`$got_nm\` rc $rc_nm" - exit 1 -fi - -echo "build smoke: passed (release + optimized + direct-link + tree-shake + compiler+core shake + data-reader + no-main)" +echo "build smoke: passed (release + optimized + direct-link + tree-shake + compiler+core shake)" diff --git a/host/chez/build.ss b/host/chez/build.ss index 2f60edd..bb36752 100644 --- a/host/chez/build.ss +++ b/host/chez/build.ss @@ -23,7 +23,7 @@ ;; --- shell helpers ---------------------------------------------------------- ;; Run a command, return its stdout as one trimmed string ("" on no output). (define (bld-sh-capture cmd) - (let* ((p (process (bld-sh-wrap cmd))) (in (car p))) + (let* ((p (process cmd)) (in (car p))) (let loop ((acc '())) (let ((l (get-line in))) (if (eof-object? l) @@ -37,16 +37,10 @@ (loop (cons l acc))))))) (define (bld-system cmd) - (let ((rc (system (bld-sh-wrap cmd)))) + (let ((rc (system cmd))) (unless (zero? rc) (error 'jolt-build (string-append "command failed (" (number->string rc) "): " cmd))))) -;; mkdir -p without a subprocess (the self-contained build shells out to nothing). -(define (bld-mkdir-p dir) - (unless (or (string=? dir "") (string=? dir "/") (string=? dir ".") (file-exists? dir)) - (bld-mkdir-p (path-parent dir)) - (guard (e (#t #f)) (mkdir dir)))) - (define (bld-contains? s sub) (let ((ns (string-length s)) (nsub (string-length sub))) (let loop ((i 0)) @@ -57,24 +51,6 @@ ;; --- toolchain discovery ---------------------------------------------------- (define bld-machine (symbol->string (machine-type))) (define bld-osx? (bld-contains? bld-machine "osx")) -(define bld-nt? (bld-contains? bld-machine "nt")) - -;; Chez's system/process run through cmd.exe on Windows; every build command -;; here is written for sh (MSYS2 provides it). On nt, spill the command to a -;; script and run `sh ` — workspace paths carry no spaces, and the -;; script file sidesteps cmd's quoting entirely. Identity elsewhere. -(define bld-shell-counter 0) -(define (bld-sh-wrap cmd) - (if bld-nt? - (let* ((tmp (or (getenv "TEMP") (getenv "TMP") ".")) - (f (begin (set! bld-shell-counter (+ bld-shell-counter 1)) - (string-append tmp "\\jolt-sh-" - (number->string bld-shell-counter) ".sh")))) - (let ((p (open-output-file f 'replace))) - (put-string p cmd) - (close-port p)) - (string-append "sh " f)) - cmd)) ;; The Chez executable, for the isolated compile pass (see build-binary step 4). (define bld-chez @@ -98,9 +74,6 @@ (cand (string-append bindir "/../lib/csv" bld-version "/" bld-machine))) cand)))) -(define (bld-have-cc?) - (> (string-length (bld-sh-capture "command -v cc")) 0)) - (define (bld-check-toolchain) (for-each (lambda (f) @@ -112,21 +85,14 @@ ;; Link flags. macOS Homebrew layout for the kernel's lz4/zlib/ncurses deps. (define (bld-link-libs) - (cond - (bld-osx? - (let ((lz4 (bld-sh-capture "brew --prefix lz4 2>/dev/null"))) - (string-append - (if (> (string-length lz4) 0) (string-append "-L" lz4 "/lib ") "") - "-llz4 -lz -lncurses -framework Foundation -liconv -lm"))) - ;; Windows (ta6nt, MinGW-w64 under MSYS2): the Chez kernel pulls in - ;; compression, winsock, COM/UUID, and the registry. - (bld-nt? - ;; -static: a single-file exe (no libwinpthread/libgcc/lz4 DLL deps) — - ;; required for a distributable binary and for TLS init consistency. - "-static -llz4 -lz -lws2_32 -lrpcrt4 -lole32 -luuid -ladvapi32 -luser32 -lshell32 -lm") - ;; Linux: the Chez kernel pulls in compression (lz4/z), the expression - ;; editor (ncurses + terminfo), threads, dlopen, libuuid, and clock_gettime. - (else "-llz4 -lz -lncurses -ltinfo -ldl -lm -lpthread -luuid -lrt"))) + (if bld-osx? + (let ((lz4 (bld-sh-capture "brew --prefix lz4 2>/dev/null"))) + (string-append + (if (> (string-length lz4) 0) (string-append "-L" lz4 "/lib ") "") + "-llz4 -lz -lncurses -framework Foundation -liconv -lm")) + ;; Linux: the Chez kernel pulls in compression (lz4/z), the expression + ;; editor (ncurses + terminfo), threads, dlopen, libuuid, and clock_gettime. + "-llz4 -lz -lncurses -ltinfo -ldl -lm -lpthread -luuid -lrt")) ;; --- runtime manifest (mirrors host/chez/cli.ss's load order) --------------- ;; A line is either literal Scheme text to inline, or a tag whose emission the build @@ -145,7 +111,7 @@ 'compile-eval "(load \"host/chez/png.ss\")" "(load \"host/chez/loader.ss\")" - "(load \"host/chez/java/ffi.ss\")" + "(load \"host/chez/ffi.ss\")" "(set-source-roots! (list \"jolt-core\" \"stdlib\"))")) (define bld-tagged-loads @@ -166,23 +132,12 @@ (q2 (let scan ((i (+ q1 1))) (if (char=? (string-ref s i) #\") i (scan (+ i 1)))))) (substring s (+ q1 1) q2))))) -;; runtime source for PATH: from the binary's embedded store if present (a -;; self-contained joltc building an app, with no jolt checkout on disk), else read -;; from disk (running from a source checkout). build-joltc embeds every runtime -;; .ss the manifest inlines, so `build` never touches the filesystem for them. -(define (bld-source-string path) - (let ((emb (hashtable-ref embedded-resources path #f))) - (if (string? emb) emb (read-file-string path)))) - -(define (bld-string-lines s) - (let ((n (string-length s))) - (let loop ((i 0) (start 0) (acc '())) - (cond ((>= i n) (reverse (if (> i start) (cons (substring s start i) acc) acc))) - ((char=? (string-ref s i) #\newline) - (loop (+ i 1) (+ i 1) (cons (substring s start i) acc))) - (else (loop (+ i 1) start acc)))))) - -(define (bld-file-lines path) (bld-string-lines (bld-source-string path))) +(define (bld-file-lines path) + (call-with-input-file path + (lambda (p) + (let loop ((acc '())) + (let ((l (get-line p))) + (if (eof-object? l) (reverse acc) (loop (cons l acc)))))))) ;; Emit one line to OUT, recursively inlining a `(load ...)` of a repo file. (define (bld-inline-line line out depth) @@ -215,38 +170,6 @@ ;; The loop itself is emit-image's ei-emit-ns* (optimize? #t, guard? #f). (define (bld-emit-ns ns-name src) (ei-emit-ns* ns-name src #t #f)) -;; --- whole-program inference pre-pass --------------------------------------- -;; Analyze every app form (all namespaces, deps-first) to IR and run the -;; closed-world param-type fixpoint, so each fn's param types pick up the record -;; types its callers pass. The per-ns emit below then bare-indexes field reads and -;; devirtualizes protocol calls at those sites (the back end reads the resulting -;; :hint/:devirt annotations). Optimized builds only; registries come from the -;; runtime tables populated as the app loaded. -(define jolt-wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define jolt-wp-set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define jolt-wp-set-proto-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define jolt-wp-host-record-shapes (var-deref "jolt.host" "record-shapes")) -(define jolt-wp-host-proto-methods (var-deref "jolt.host" "protocol-methods")) - -(define (bld-wp-infer! ordered) - (jolt-wp-set-record-shapes! (jolt-wp-host-record-shapes #f)) - (jolt-wp-set-proto-methods! (jolt-wp-host-proto-methods #f)) - (let ((nodes '())) - (for-each - (lambda (nf) - (set-chez-ns! (car nf)) - (let ((src (ldr-read-source (cdr nf)))) - (parameterize ((rdr-source-file (cdr nf))) - (for-each - (lambda (f) - (ce-scan-requires! f (car nf)) - (unless (or (ei-ns-form? f) (ce-macro-form? f)) - (guard (e (#t #f)) - (set! nodes (cons (jolt-ce-analyze (make-analyze-ctx (car nf)) f) nodes))))) - (ei-read-all src))))) - ordered) - (jolt-wp-infer! (apply jolt-vector (reverse nodes))))) - ;; Strings emitted before each app ns's forms, replaying what the source loader ;; does per file: (1) set chez-current-ns so runtime ns-sensitive setup forms ;; (defmulti/defmethod resolve their target var through it) land in the right ns; @@ -310,24 +233,21 @@ (define (bld-strs x) (map jolt-str-render-one (seq->list x))) ;; Emit native-library loads. `natives` is the encoded jolt seq jolt.main/ -;; encode-natives produced: each entry is ["process"] | ["static" form…] | -;; ["req" cand…] | ["opt" cand…]. `which` selects 'required (process + static + -;; req) or 'optional. Required loads are emitted before the app forms (the app's -;; defcfn foreign-procedures resolve their symbols at top-level eval during -;; startup, so the libs must be loaded first); a load-shared-object failure there -;; is fatal — correct for a required lib. A "static" lib is cc-linked into the -;; binary (see bld-native-link-flags), so its symbols are already in the process: -;; it loads them the same way a "process" lib does. Optional loads run in the -;; scheme-start launcher, where guard catches a missing lib (an optional lib's -;; namespace is only present when the app requires it, so its foreign-procedures -;; aren't among the baked top-level forms). +;; encode-natives produced: each entry is ["process"] | ["req" cand…] | ["opt" cand…]. +;; `which` selects 'required (process + req) or 'optional. Required + process loads +;; are emitted before the app forms (the app's defcfn foreign-procedures resolve +;; their symbols at top-level eval during startup, so the libs must be loaded +;; first); a load-shared-object failure there is fatal — correct for a required +;; lib. Optional loads run in the scheme-start launcher, where guard catches a +;; missing lib (an optional lib's namespace is only present when the app requires +;; it, so its foreign-procedures aren't among the baked top-level forms). (define (bld-emit-natives out natives which) (for-each (lambda (entry) (let* ((parts (bld-strs entry)) (kind (car parts)) (cands (cdr parts)) (cand-lits (fold-left (lambda (s c) (string-append s (ei-str-lit c) " ")) "" cands))) (cond - ((and (eq? which 'required) (or (string=? kind "process") (string=? kind "static"))) + ((and (eq? which 'required) (string=? kind "process")) (put-string out "(jolt-build-load-native '() #f #t)\n")) ((and (eq? which 'required) (string=? kind "req")) (put-string out (string-append "(jolt-build-load-native (list " cand-lits ") #f #f)\n"))) @@ -335,66 +255,6 @@ (put-string out (string-append "(jolt-build-load-native (list " cand-lits ") #t #f)\n")))))) (seq->list natives))) -;; The cc link fragment for the "static" natives: each archive must be FORCE-loaded -;; (the linker would otherwise drop an archive member main.c never references) and, -;; on Linux, the executable's symbols exported into the dynamic table so the -;; startup (load-shared-object #f) + foreign-procedure can resolve them (-rdynamic, -;; added by build-with-cc when this fragment is non-empty). Returns "" when no lib -;; is statically linked. Entry forms: ["static" "archive" path] | ["static" "lib" -;; name libdir]. -(define (bld-native-link-flags natives) - (fold-left - (lambda (acc entry) - (let ((parts (bld-strs entry))) - (if (string=? (car parts) "static") - (string-append acc " " (bld-one-static-link (cdr parts))) - acc))) - "" (seq->list natives))) - -;; A statically-linked native is only in the OUTPUT binary, but build step 1 -;; evaluates the app's `foreign-procedure` forms in THIS process (to register its -;; macros/vars), and Chez resolves a foreign entry eagerly. So make the archive's -;; symbols resolvable here: build a throwaway shared object from it (force-loading -;; every member) and load it. The output binary still cc-links the static archive; -;; this temp .so is build-time only. Only the "archive" form is preloaded — the -;; "lib" form names a system library the OS loader already finds by soname. -(define (bld-preload-static-natives! natives builddir) - (let ((n 0)) - (for-each - (lambda (entry) - (let ((parts (bld-strs entry))) - (when (and (string=? (car parts) "static") (string=? (cadr parts) "archive")) - (let* ((archive (caddr parts)) - (so (string-append builddir "/native-" (number->string n) - (if bld-osx? ".dylib" ".so")))) - (set! n (+ n 1)) - (bld-system - (if bld-osx? - (string-append "cc -dynamiclib -undefined dynamic_lookup -Wl,-all_load '" - archive "' -o '" so "'") - (string-append "cc -shared -Wl,--whole-archive '" archive - "' -Wl,--no-whole-archive -Wl,--unresolved-symbols=ignore-all -o '" so "'"))) - (load-shared-object so))))) - (seq->list natives)))) - -(define (bld-one-static-link form) - (let ((kind (car form))) - (cond - ((string=? kind "archive") - (let ((path (cadr form))) - (if bld-osx? - (string-append "-Wl,-force_load," path) - (string-append "-Wl,--whole-archive " path " -Wl,--no-whole-archive")))) - ((string=? kind "lib") - (let* ((lib (cadr form)) (dir (caddr form)) - (L (if (> (string-length dir) 0) (string-append "-L" dir " ") ""))) - ;; -Bstatic forces the .a over a .so of the same -l name (GNU ld). macOS's - ;; ld64 has no -Bstatic; there an :archive path is the reliable form. - (if bld-osx? - (string-append L "-l" lib) - (string-append L "-Wl,-Bstatic -l" lib " -Wl,-Bdynamic")))) - (else "")))) - ;; Walk an embed root recursively; return (resource-name . abspath) pairs, where ;; resource-name is the "/"-joined path under the root (what io/resource is asked for). (define (bld-walk-files root rel acc) @@ -436,31 +296,8 @@ ;; direct-link?: opt-in closed-world direct-linking (app->app calls bind directly, ;; no runtime redefinition). Off by default in every mode — release stays ;; dynamically linked. -(define (bld-suffix? s suf) - (let ((n (string-length s)) (m (string-length suf))) - (and (>= n m) (string=? (substring s (- n m) n) suf)))) (define (build-binary entry-ns out-path mode natives embed-dirs ext-roots direct-link? tree-shake?) - ;; Windows executables carry .exe; normalize here so the append-payload and - ;; cc paths agree and the shell can run the result. - (let ((out-path (if (and bld-nt? (not (bld-suffix? out-path ".exe"))) - (string-append out-path ".exe") - out-path))) - ;; The self-contained path (jolt-embedded-bytes "stub/launcher") needs no csv - ;; kernel files, no Chez, no cc — only the legacy cc path does. - (unless (jolt-embedded-bytes "stub/launcher") (bld-check-toolchain)) - (when (> (string-length (bld-native-link-flags natives)) 0) - ;; :static natives are cc-linked into the binary, so a C compiler must be on - ;; PATH — the self-contained joltc bundles the Chez kernel (libkernel.a + - ;; scheme.h) and relinks a custom stub (see build-self-contained), but still - ;; needs the system cc for that link. Fail early (before the app's foreign- - ;; procedure forms eval below) with an actionable message. - (unless (bld-have-cc?) - (error 'jolt-build - "static native linking needs a C compiler (cc) on PATH; install one, or pass --dynamic to load the library at runtime.")) - ;; Preload static archives' symbols into this process so step 1's foreign- - ;; procedure evals resolve; the .build dir must exist first. - (bld-mkdir-p (string-append out-path ".build")) - (bld-preload-static-natives! natives (string-append out-path ".build"))) + (bld-check-toolchain) ;; 1. record app namespaces in dependency order as they finish loading. (let ((app-order '())) (set-ns-loaded-hook! @@ -489,15 +326,8 @@ (set-optimize! (string=? mode "optimized")) (when direct-link? ((var-deref "jolt.backend-scheme" "set-direct-link!") #t) - ((var-deref "jolt.backend-scheme" "direct-link-reset!"))) - ;; whole-program param-type fixpoint before per-form emit - (when (string=? mode "optimized") (bld-wp-infer! ordered))) + ((var-deref "jolt.backend-scheme" "direct-link-reset!")))) (lambda () - ;; A #tag data-reader literal must compile in the binary the same as - ;; it loads interpreted — apply the reader rewrite to each emitted - ;; form too (no-op unless the app registered data readers). - (parameterize ((ei-emit-form-hook - (lambda (form) (if data-readers-active (ldr-apply-readers form) form)))) (if tree-shake? (dce-shake (dce-blob-records "host/chez/seed/prelude.ss") @@ -506,23 +336,21 @@ ;; ns-prelude forms (always kept, no fqn/refs) set the ;; ns + register aliases before this ns's forms; dce ;; keeps original order. - (let ((src (ldr-read-source (cdr nf)))) - (parameterize ((rdr-source-file (cdr nf))) - (append - (map (lambda (s) (dce-rec #t #f '() s)) - (bld-ns-prelude (car nf) src)) - (ei-emit-ns-records (car nf) src))))) + (let ((src (read-file-string (cdr nf)))) + (append + (map (lambda (s) (dce-rec #t #f '() s)) + (bld-ns-prelude (car nf) src)) + (ei-emit-ns-records (car nf) src)))) ordered)) (string-append entry-ns "/-main")) (values #f (apply append (map (lambda (nf) - (let ((src (ldr-read-source (cdr nf)))) - (parameterize ((rdr-source-file (cdr nf))) - (append (bld-ns-prelude (car nf) src) - (bld-emit-ns (car nf) src))))) + (let ((src (read-file-string (cdr nf)))) + (append (bld-ns-prelude (car nf) src) + (bld-emit-ns (car nf) src)))) ordered)) - #f)))) + #f))) (lambda () (set-optimize! #f) ((var-deref "jolt.backend-scheme" "set-direct-link!") #f))))) @@ -533,7 +361,7 @@ (boot (string-append builddir "/jolt.boot")) (boot-h (string-append builddir "/boot_data.h")) (main-c (string-append builddir "/main.c"))) - (bld-mkdir-p builddir) + (bld-system (string-append "mkdir -p '" builddir "'")) ;; 3. flat source = runtime + app + launcher. (let ((out (open-output-file flat-ss 'replace))) (bld-emit-runtime out drop-compiler? core-strs) @@ -571,176 +399,47 @@ "))\n" " (list \"jolt-core\" \"stdlib\"))))\n")) (put-string out (string-append - ;; Call -main only if the entry namespace defines one; - ;; a script ns (top-level side effects, no -main) has - ;; already run its forms at heap build, so invoking a nil - ;; -main would crash ("nil cannot be cast to IFn") — just - ;; exit cleanly instead. - " (let ((maincell (var-cell-lookup " (ei-str-lit entry-ns) " \"-main\")))\n" - ;; render an uncaught throw (+ Clojure backtrace) instead - ;; of Chez's opaque dump, then exit non-zero. - " (guard (v (#t (jolt-report-throwable v (current-error-port)) (exit 1)))\n" - ;; Loading the app left the current ns at the entry ns; reset - ;; it to `user` before -main, matching clojure.main (*ns* is - ;; `user` when a `-m` -main runs, so a runtime resolve of an - ;; aliased symbol behaves the same as on the JVM / interpreted - ;; joltc, not off the entry ns's alias table). - " (set-chez-ns! \"user\")\n" - " (when (and maincell (var-cell-defined? maincell))\n" - " (apply jolt-invoke (var-cell-root maincell) args))))\n" + " (let ((mainv (var-deref " (ei-str-lit entry-ns) " \"-main\")))\n" + " (apply jolt-invoke mainv args))\n" " (exit 0)))\n")) (close-port out)) - ;; 4. compile -> boot -> link. Two paths, chosen by whether this process - ;; carries the bundled Chez boots + launcher stub: - ;; - SELF-CONTAINED (the distributed joltc, jolt-eaj): compile-file + - ;; make-boot-file run IN PROCESS (the compiler is resident — joltc is - ;; built from scheme.boot), then the boot is appended to a copy of the - ;; embedded stub. No external Chez, no cc. - ;; - LEGACY (dev bin/joltc): spawn a fresh Chez for compile-file/ - ;; make-boot-file, then xxd the boot into a C array and cc-link against - ;; libkernel.a. Kept so `make buildsmoke` still exercises the cc path. - (if (jolt-embedded-bytes "stub/launcher") - (build-self-contained entry-ns out-path mode builddir flat-ss flat-so boot - (bld-native-link-flags natives)) - (build-with-cc entry-ns out-path mode builddir flat-ss flat-so boot boot-h main-c - (bld-native-link-flags natives))))))))) - -;; --- self-contained link (in-process compile + append the boot to the stub) --- -;; compile-file runs against the DEFAULT interaction environment, so the boot's -;; top-level defines land in the real symbol cells — the runtime compiler's -;; eval'd code must resolve them (var-deref, jolt-invoke, the jolt-n* macros) -;; when the built binary dynamically requires a namespace. Compiling in a clean -;; copy-environment instead orphans every define in locations eval can't see, -;; and the binary dies with "variable var-deref is not bound" the moment a -;; runtime require compiles source. -;; -;; The default env has a wrinkle the legacy fresh-Chez path doesn't: THIS -;; process's cells hold jolt's redefinitions of some kernel names (`error`, -;; regex.ss), so references to them compile as cell reads — and a read that -;; runs before the redefining form would find the fresh binary's cell unbound. -;; The prologue closes that: it first binds each redefined kernel name's cell -;; to its kernel value, making the boot's earliest reads identical to the -;; legacy path's primitive references. - -;; every top-level (define nm …)/(define (nm …) …) name in the flat file that -;; shadows a scheme-environment VARIABLE (syntax names don't eval; skip them). -(define (bld-kernel-prologue flat-ss) - (let ((seen (make-eq-hashtable)) - (kenv (scheme-environment)) - (names '())) - (let ((ip (open-input-file flat-ss))) - (let loop () - (let ((f (read ip))) - (unless (eof-object? f) - (when (and (pair? f) (eq? (car f) 'define) (pair? (cdr f))) - (let* ((h (cadr f)) - (nm (if (pair? h) (car h) h))) - (when (and (symbol? nm) - (not (hashtable-ref seen nm #f)) - (guard (e (#t #f)) (begin (eval nm kenv) #t))) - (hashtable-set! seen nm #t) - (set! names (cons nm names))))) - (loop)))) - (close-port ip)) - (apply string-append - (map (lambda (nm) - (let ((s (symbol->string nm))) - (string-append "(define " s " (eval '" s " (scheme-environment)))\n"))) - (reverse names))))) - -;; prepend the prologue to the flat file in place. -(define (bld-prepend-prologue! flat-ss) - (let ((prologue (bld-kernel-prologue flat-ss)) - (body (read-file-string flat-ss))) - (let ((out (open-output-file flat-ss 'replace))) - (put-string out ";; kernel-name cells pre-bound so early reads match the kernel primitives\n") - (put-string out prologue) - (put-string out body) - (close-port out)))) - -(define (build-self-contained entry-ns out-path mode builddir flat-ss flat-so boot native-link) - (let ((petite (string-append builddir "/petite.boot")) - (scheme (string-append builddir "/scheme.boot"))) - (jolt-spill-embedded! "csv/petite.boot" petite) - (jolt-spill-embedded! "csv/scheme.boot" scheme) - (display (string-append "jolt build: compiling " entry-ns " (" mode " mode, self-contained)\n")) - (bld-prepend-prologue! flat-ss) - (compile-file flat-ss flat-so) - (make-boot-file boot '() petite scheme flat-so) - ;; The stub is the native launcher the boot is appended to. With no :static - ;; natives it's the prebuilt one bundled in joltc (no cc needed); with :static - ;; natives it's re-linked here from the bundled kernel + launcher source so the - ;; archives are baked in and their symbols resolve in the running binary. - (if (> (string-length native-link) 0) - (bld-relink-stub builddir native-link out-path) - (jolt-spill-embedded! "stub/launcher" out-path)) - ;; link: stub bytes ++ boot ++ frame, then make it executable. - (jolt-append-payload! out-path (read-file-bytes boot)) - (jolt-chmod-755 out-path) - (display (string-append "jolt build: wrote " out-path "\n")) - (when bld-osx? - (display (string-append - "jolt build: note — on macOS this binary is unsigned; to share it,\n" - " `xattr -d com.apple.quarantine " out-path "` on the target, or sign it.\n"))))) - -;; Re-link the launcher stub with the app's static native archives baked in, to -;; OUT-PATH. The self-contained joltc bundles the Chez kernel (libkernel.a), -;; header, and launcher source; spill them and drive the system cc — the same link -;; build-joltc.ss ran once at joltc-build time, plus the force-load archive flags -;; (native-link) and, on Linux, -rdynamic so the baked-in symbols stay dlsym- -;; visible for (load-shared-object #f) + foreign-procedure at startup. -(define (bld-relink-stub builddir native-link out-path) - (let ((h (string-append builddir "/scheme.h")) - (lk (string-append builddir "/libkernel.a")) - (lc (string-append builddir "/launcher.c"))) - (jolt-spill-embedded! "csv/scheme.h" h) - (jolt-spill-embedded! "csv/libkernel.a" lk) - (jolt-spill-embedded! "stub/launcher.c" lc) - (display "jolt build: relinking launcher stub with static native libraries\n") - (bld-system (string-append - "cc -O2 " (if bld-osx? "" "-rdynamic ") - "-I'" builddir "' '" lc "' '" lk "' -o '" out-path "' " - (bld-link-libs) native-link)))) - -;; --- legacy cc link (dev bin/joltc): fresh Chez compile + xxd + cc ------------ -(define (build-with-cc entry-ns out-path mode builddir flat-ss flat-so boot boot-h main-c native-link) - (display (string-append "jolt build: compiling " entry-ns " (" mode " mode)\n")) - (let ((cs (string-append builddir "/compile.ss"))) - (let ((p (open-output-file cs 'replace))) - (put-string p - (string-append - "(import (chezscheme))\n" - "(compile-file " (ei-str-lit flat-ss) " " (ei-str-lit flat-so) ")\n" - "(make-boot-file " (ei-str-lit boot) " '()\n " - (ei-str-lit (string-append bld-csv-dir "/petite.boot")) "\n " - (ei-str-lit (string-append bld-csv-dir "/scheme.boot")) "\n " - (ei-str-lit flat-so) ")\n")) - (close-port p)) - (bld-system (string-append bld-chez " --script '" cs "'"))) - (bld-system (string-append "xxd -i '" boot "' > '" boot-h "'")) - ;; The xxd symbol is derived from the path; normalize to jolt_boot. - (bld-system (string-append - "sed -i.bak -E 's/unsigned char [A-Za-z0-9_]+\\[\\]/unsigned char jolt_boot[]/; " - "s/unsigned int [A-Za-z0-9_]+_len/unsigned int jolt_boot_len/' '" boot-h "'")) - (let ((mc (open-output-file main-c 'replace))) - (put-string mc - (string-append - "#include \"scheme.h\"\n#include \"boot_data.h\"\n" - "int main(int argc, char *argv[]) {\n" - " Sscheme_init(0);\n" - " Sregister_boot_file_bytes(\"jolt\", jolt_boot, jolt_boot_len);\n" - " Sbuild_heap(0, 0);\n" - " int status = Sscheme_start(argc, (const char **)argv);\n" - " Sscheme_deinit();\n return status;\n}\n")) - (close-port mc)) - ;; -rdynamic (Linux) exports the executable's symbols into the dynamic table so - ;; a statically-linked native lib's symbols resolve via (load-shared-object #f) - ;; at startup. macOS keeps unstripped executable symbols dlsym-visible already. - (bld-system (string-append - "cc -O2 " (if (and (not bld-osx?) (> (string-length native-link) 0)) "-rdynamic " "") - "-I'" bld-csv-dir "' '" main-c "' '" bld-csv-dir "/libkernel.a' " - "-o '" out-path "' " (bld-link-libs) native-link)) - (display (string-append "jolt build: wrote " out-path "\n"))) + ;; 4. compile -> boot -> embed -> link. + ;; compile-file/make-boot-file run in a FRESH Chez, not this process: the + ;; loaded runtime shadows `error` (regex.ss, for irregex), which would + ;; otherwise bake a broken `error` reference into the boot. + (display (string-append "jolt build: compiling " entry-ns " (" mode " mode)\n")) + (let ((cs (string-append builddir "/compile.ss"))) + (let ((p (open-output-file cs 'replace))) + (put-string p + (string-append + "(import (chezscheme))\n" + "(compile-file " (ei-str-lit flat-ss) " " (ei-str-lit flat-so) ")\n" + "(make-boot-file " (ei-str-lit boot) " '()\n " + (ei-str-lit (string-append bld-csv-dir "/petite.boot")) "\n " + (ei-str-lit (string-append bld-csv-dir "/scheme.boot")) "\n " + (ei-str-lit flat-so) ")\n")) + (close-port p)) + (bld-system (string-append bld-chez " --script '" cs "'"))) + (bld-system (string-append "xxd -i '" boot "' > '" boot-h "'")) + ;; The xxd symbol is derived from the path; normalize to jolt_boot. + (bld-system (string-append + "sed -i.bak -E 's/unsigned char [A-Za-z0-9_]+\\[\\]/unsigned char jolt_boot[]/; " + "s/unsigned int [A-Za-z0-9_]+_len/unsigned int jolt_boot_len/' '" boot-h "'")) + (let ((mc (open-output-file main-c 'replace))) + (put-string mc + (string-append + "#include \"scheme.h\"\n#include \"boot_data.h\"\n" + "int main(int argc, char *argv[]) {\n" + " Sscheme_init(0);\n" + " Sregister_boot_file_bytes(\"jolt\", jolt_boot, jolt_boot_len);\n" + " Sbuild_heap(0, 0);\n" + " int status = Sscheme_start(argc, (const char **)argv);\n" + " Sscheme_deinit();\n return status;\n}\n")) + (close-port mc)) + (bld-system (string-append + "cc -O2 -I'" bld-csv-dir "' '" main-c "' '" bld-csv-dir "/libkernel.a' " + "-o '" out-path "' " (bld-link-libs))) + (display (string-append "jolt build: wrote " out-path "\n"))))))) (def-var! "jolt.host" "build-binary" (lambda (entry out mode natives embed-dirs ext-roots direct-link? tree-shake?) diff --git a/host/chez/cli.ss b/host/chez/cli.ss index 7d978af..9f597cb 100644 --- a/host/chez/cli.ss +++ b/host/chez/cli.ss @@ -11,26 +11,6 @@ (define cli-args (cdr (command-line))) ; drop the script name -;; Fail early and actionably when the vendored submodules aren't checked out — -;; a plain `git clone` or GitHub's auto-generated "Source code" release archive -;; lacks them, and the raw failure ("load failed for vendor/irregex/irregex.scm") -;; doesn't say how to fix it. (The self-contained joltc binary embeds these and -;; never runs this file.) -(unless (file-exists? "vendor/irregex/irregex.scm") - (display "jolt: vendor submodules are missing (vendor/irregex). -" (current-error-port)) - (display "GitHub's 'Source code' release archives don't include submodules. -" (current-error-port)) - (display "Clone the repo instead: -" (current-error-port)) - (display " git clone --recurse-submodules https://github.com/jolt-lang/jolt.git -" (current-error-port)) - (display "or, in an existing checkout: -" (current-error-port)) - (display " git submodule update --init --recursive -" (current-error-port)) - (exit 1)) - (load "host/chez/rt.ss") (set-chez-ns! "clojure.core") (load "host/chez/seed/prelude.ss") @@ -44,7 +24,7 @@ ;; jolt.ffi host primitives (memory / library loading) load AFTER the loader's ;; baked-ns snapshot, so a library's (require '[jolt.ffi]) still loads jolt.ffi's ;; Clojure side (the foreign-fn / defcfn macros, stdlib/jolt/ffi.clj). -(load "host/chez/java/ffi.ss") ; jolt.ffi (FFI: a library binds native code) +(load "host/chez/ffi.ss") ; jolt.ffi (FFI: a library binds native code) ;; jolt.main + jolt.deps live under jolt-core; keep them (and stdlib) on the ;; roots so the CLI's own namespaces — and any jolt.* an app pulls in — resolve. @@ -52,23 +32,29 @@ (set-source-roots! (list "jolt-core" "stdlib")) ;; Render an uncaught jolt throw (any value, not just a Chez condition) to stderr -;; and exit non-zero, instead of Chez's opaque "non-condition value" dump. The -;; message/ex-data/cause + a mapped Clojure backtrace come from the shared -;; renderer (source-registry.ss); the cli adds the top-level source location. -(define (jolt-report-uncaught raw) - (let ((v (jolt-unwrap-throw raw)) - (port (current-error-port))) - (jolt-render-throwable v port) - ;; The top-level form that was evaluating when this propagated (file:line:col). - (let ((loc (jolt-current-source-string))) - (when loc (display " at " port) (display loc port) (newline port))) - (let ((bt (jolt-backtrace-string v))) - (when bt (display " trace:\n" port) (display bt port))) +;; and exit non-zero, instead of Chez's opaque "non-condition value" dump. An +;; ex-info shows its message + ex-data; anything else is pr-str'd. +(define (jolt-report-uncaught v) + (let ((port (current-error-port))) + (if (and (jolt=2 (jolt-get v jolt-kw-ex-type jolt-nil) jolt-kw-ex-info)) + (begin + (display "Unhandled exception: " port) + (display (jolt-str-render-one (jolt-get v jolt-kw-message jolt-nil)) port) + (newline port) + (let ((data (jolt-get v jolt-kw-data jolt-nil))) + (unless (jolt-nil? data) + (display " ex-data: " port) (display (jolt-pr-str data) port) (newline port))) + (let ((cause (jolt-get v jolt-kw-cause jolt-nil))) + (when (condition? cause) + (display " cause: " port) + (display (with-output-to-string (lambda () (display-condition cause))) port) + (newline port)))) + (begin + (display "Unhandled exception: " port) + (display (if (condition? v) (with-output-to-string (lambda () (display-condition v))) (jolt-pr-str v)) port) + (newline port))) (exit 1))) -;; JOLT_TRACE opt-in, at runtime (before any app ns compiles) so the app is traced. -(jolt-trace-init-from-env!) - (guard (v (#t (jolt-report-uncaught v))) (cond ;; -e EXPR — evaluate one expression and print it (blank for nil). Wrapped in diff --git a/host/chez/collections.ss b/host/chez/collections.ss index d2ae770..108bc6a 100644 --- a/host/chez/collections.ss +++ b/host/chez/collections.ss @@ -32,161 +32,45 @@ out)) ;; ============================================================================ -;; persistent vector — 32-way trie + tail (Clojure's PersistentVector) +;; persistent vector — copy-on-write over a Scheme vector ;; ============================================================================ -;; cnt elements live in a trie of 32-wide nodes (root, height = shift bits) plus a -;; trailing `tail` chunk of 1..32. conj appends to the tail and, when it fills, -;; pushes it into the trie by path-copy — so conj is O(1) amortized and a linear -;; build is O(n), not the O(n^2) of a flat copy-on-write array. nth/assoc/pop are -;; O(log32 n). Trie nodes are Scheme vectors holding only their live children -;; (grown left-to-right), so a node's length is its child count. -;; -;; `ent` #t marks a MAP ENTRY (the [k v] pair seq'd out of a map). An entry has 2 -;; elements (all in the tail), equals its [k v] vector and walks like one, and is -;; both vector? (Clojure's MapEntry implements IPersistentVector) and map-entry?. -;; Modifying an entry (conj/assoc/pop) yields a plain vector (ent #f). -;; -;; make-pvec and pvec-v keep the old flat-vector API: make-pvec builds a trie from -;; a Scheme vector (every existing caller still passes one) and pvec-v materializes -;; it back, so only this file's internals change. -(define pv-bits 5) -(define pv-width 32) -(define pv-mask 31) -(define pv-empty-node (vector)) -(define-record-type (pvec mk-pvec pvec?) - (fields cnt shift root tail ent) (nongenerative chez-pvec-v2)) - -;; trailing helpers over Scheme vectors used by the trie -(define (vec-snoc v x) ; copy v with x appended - (let* ((n (vector-length v)) (out (make-vector (fx+ n 1)))) - (let loop ((i 0)) (when (fx=? i (pv-tailoff (pvec-cnt p))) - (pvec-tail p) - (let loop ((node (pvec-root p)) (level (pvec-shift p))) - (if (fx>? level 0) - (loop (vector-ref node (fxand (fxsra i level) pv-mask)) (fx- level pv-bits)) - node)))) - -;; jolt models every number as a double, so vector indices arrive as flonums — -;; coerce an integer-valued index to a Scheme fixnum before bounds math. -(define (->idx i) (if (fixnum? i) i (if (flonum? i) (exact (floor i)) i))) -(define (pvec-count p) (pvec-cnt p)) -(define (pvec-nth-d p i d) - (let ((i (->idx i))) - (if (and (fixnum? i) (fx>=? i 0) (fx? (fxsra cnt pv-bits) (fxsll 1 shift)) - ;; root overflow: grow the trie a level - (mk-pvec (fx+ cnt 1) (fx+ shift pv-bits) - (vector (pvec-root p) (pv-new-path shift tail-node)) - (vector x) #f) - (mk-pvec (fx+ cnt 1) shift - (pv-push-tail cnt shift (pvec-root p) tail-node) - (vector x) #f)))))) - -(define (pv-assoc-trie level node i x) - (if (fx=? level 0) - (vec-set node (fxand i pv-mask) x) - (let ((subidx (fxand (fxsra i level) pv-mask))) - (vec-set node subidx (pv-assoc-trie (fx- level pv-bits) (vector-ref node subidx) i x))))) -(define (pvec-assoc p i x) ; i in [0,count]; =count appends - (let ((i (->idx i)) (cnt (pvec-cnt p))) - (cond - ((fx=? i cnt) (pvec-conj p x)) - ((and (fx>=? i 0) (fx=? i (pv-tailoff cnt)) - (mk-pvec cnt (pvec-shift p) (pvec-root p) - (vec-set (pvec-tail p) (fxand i pv-mask) x) #f) - (mk-pvec cnt (pvec-shift p) - (pv-assoc-trie (pvec-shift p) (pvec-root p) i x) (pvec-tail p) #f))) - (else (jolt-throw (jolt-host-throwable "java.lang.IndexOutOfBoundsException" "vector index out of bounds")))))) -(define (pvec-peek p) - (let ((n (pvec-cnt p))) (if (fx=? n 0) jolt-nil (pvec-nth-d p (fx- n 1) jolt-nil)))) -;; pop the last trie chunk back into the tail; #f means the subtree emptied. -(define (pv-pop-tail cnt level node) - (let ((subidx (fxand (fxsra (fx- cnt 2) level) pv-mask))) - (cond - ((fx>? level pv-bits) - (let ((newchild (pv-pop-tail cnt (fx- level pv-bits) (vector-ref node subidx)))) - (cond ((and (not newchild) (fx=? subidx 0)) #f) - (newchild (vec-set node subidx newchild)) - (else (vec-take node subidx))))) - ((fx=? subidx 0) #f) - (else (vec-take node subidx))))) -(define (pvec-pop p) - (let ((cnt (pvec-cnt p)) (shift (pvec-shift p))) - (cond - ((fx=? cnt 0) (error 'pop "can't pop empty vector")) - ((fx=? cnt 1) empty-pvec) - ((fx>? (fx- cnt (pv-tailoff cnt)) 1) - (mk-pvec (fx- cnt 1) shift (pvec-root p) (vec-drop-last (pvec-tail p)) #f)) - (else - (let* ((new-tail (pv-chunk-for p (fx- cnt 2))) - (popped (pv-pop-tail cnt shift (pvec-root p))) - (new-root (or popped pv-empty-node))) - (if (and (fx>? shift pv-bits) (fxvector xs))) (define (make-map-entry k v) (make-pvec (vector k v) #t)) (define (jolt-map-entry? x) (and (pvec? x) (pvec-ent x) #t)) +(define (pvec-count p) (vector-length (pvec-v p))) +;; jolt models every number as a double, so vector indices arrive as flonums — +;; coerce an integer-valued index to a Scheme fixnum before bounds math. +(define (->idx i) (if (fixnum? i) i (if (flonum? i) (exact (floor i)) i))) +(define (pvec-nth-d p i d) + (let ((v (pvec-v p)) (i (->idx i))) + (if (and (fixnum? i) (fx>=? i 0) (fxidx i))) + (cond ((and (fx>=? i 0) (fx= 16 in the reference). Clojure 1.13 -;; raised the limit to 64 for maps whose keys are ALL keywords (the common -;; keyword-map case); mixed-key maps still cap at 8. -(define array-map-limit 8) -(define array-map-limit-kw 64) -(define (all-keywords? ks) - (or (null? ks) (and (keyword? (car ks)) (all-keywords? (cdr ks))))) -;; Should a map of `cnt` entries with insertion order `ord` stay in array mode -;; when key `k` is added? Under 8 always; a keyword-only map (existing keys + the -;; new key all keywords) grows to 64; otherwise it caps at 8. -(define (pmap-array-keep? cnt ord k) - (cond ((fx=? cnt array-map-limit-kw) #f) - ((and (keyword? k) (all-keywords? ord)) #t) - (else #f))) -(define (append-key ord k) (append ord (list k))) -(define (remove-key ord k) (let loop ((o ord)) (cond ((null? o) '()) ((jolt= (car o) k) (cdr o)) (else (cons (car o) (loop (cdr o))))))) - -;; growth rule (PersistentArrayMap.assoc): a new key appends to the order while in -;; array mode under the limit; otherwise the result is hash-ordered. Replacing an -;; existing key (or assoc onto an already-hash map) keeps the current order. (define (pmap-assoc m k v) - (let* ((added (box #f)) (r (node-assoc (pmap-root m) 0 (key-hash k) k v added)) - (cnt (pmap-cnt m)) (ord (pmap-order m))) - (if (unbox added) - (if (and ord (pmap-array-keep? cnt ord k)) - (make-pmap r (fx+ cnt 1) (append-key ord k)) - (make-pmap r (fx+ cnt 1) #f)) - (make-pmap r cnt ord)))) -;; force-ordered / force-hash inserts for rebuilding a map whose final mode is -;; already decided (array-map ctor, transient persistent!). -(define (pmap-put-ordered m k v) (let* ((added (box #f)) (r (node-assoc (pmap-root m) 0 (key-hash k) k v added))) - (if (unbox added) - (make-pmap r (fx+ (pmap-cnt m) 1) (append-key (or (pmap-order m) '()) k)) - (make-pmap r (pmap-cnt m) (pmap-order m))))) -(define (pmap-put-hash m k v) - (let* ((added (box #f)) (r (node-assoc (pmap-root m) 0 (key-hash k) k v added))) - (make-pmap r (if (unbox added) (fx+ (pmap-cnt m) 1) (pmap-cnt m)) #f))) -(define (pmap->hash m) (if (pmap-order m) (make-pmap (pmap-root m) (pmap-cnt m) #f) m)) + (make-pmap r (if (unbox added) (fx+ (pmap-cnt m) 1) (pmap-cnt m))))) (define (pmap-dissoc m k) - (let* ((removed (box #f)) (r (node-dissoc (pmap-root m) 0 (key-hash k) k removed)) - (ord (pmap-order m))) - (if (unbox removed) - (make-pmap r (fx- (pmap-cnt m) 1) (if ord (remove-key ord k) #f)) - m))) + (let* ((removed (box #f)) (r (node-dissoc (pmap-root m) 0 (key-hash k) k removed))) + (make-pmap r (if (unbox removed) (fx- (pmap-cnt m) 1) (pmap-cnt m))))) (define (pmap-get m k default) (node-get (pmap-root m) 0 (key-hash k) k default)) (define (pmap-contains? m k) (not (eq? pmap-absent (node-get (pmap-root m) 0 (key-hash k) k pmap-absent)))) -;; The universal fold idiom across the runtime is `(pmap-fold m (lambda (k v a) -;; (cons ... a)) '())`, which accumulates in REVERSE visitation order. So that this -;; reconstructs the map's INSERTION order, pmap-fold visits an array-mode map's keys -;; in reverse insertion order; a hash-mode map visits HAMT order (its iteration -;; order is unspecified, so reverse-of-HAMT is equivalent and matches prior -;; behaviour). Use pmap-fold-fwd when building a value directly in iteration order. -(define (pmap-fold m proc acc) - (let ((ord (pmap-order m))) - (if ord - (fold-right (lambda (k a) (proc k (pmap-get m k jolt-nil) a)) acc ord) ; visits last->first - (node-fold (pmap-root m) proc acc)))) -;; visit entries in iteration (insertion) order — for code that builds a new map / -;; ordered value directly rather than via cons-accumulation. -(define (pmap-fold-fwd m proc acc) - (let ((ord (pmap-order m))) - (if ord - (let loop ((ks ord) (a acc)) - (if (null? ks) a (loop (cdr ks) (proc (car ks) (pmap-get m (car ks) jolt-nil) a)))) - (node-fold (pmap-root m) proc acc)))) -;; map LITERAL ({...}): array map up to 8 entries (64 if keyword-only, per 1.13), -;; hash map beyond (RT.map). +(define (pmap-fold m proc acc) (node-fold (pmap-root m) proc acc)) (define (jolt-hash-map . kvs) (let loop ((m empty-pmap) (kvs kvs)) - (cond ((null? kvs) - (let ((cnt (pmap-cnt m)) (ord (pmap-order m))) - (if (fx>? cnt (if (all-keywords? ord) array-map-limit-kw array-map-limit)) - (pmap->hash m) m))) + (cond ((null? kvs) m) ((null? (cdr kvs)) (error 'hash-map "odd number of map literal entries")) - (else (loop (pmap-put-ordered m (car kvs) (cadr kvs)) (cddr kvs)))))) -;; array-map ctor: insertion-ordered regardless of size (createAsIfByAssoc). -(define (jolt-array-map-build kvs) - (let loop ((m empty-pmap) (kvs kvs)) - (cond ((null? kvs) m) - ((null? (cdr kvs)) (error 'array-map "odd number of map entries")) - (else (loop (pmap-put-ordered m (car kvs) (cadr kvs)) (cddr kvs)))))) -;; hash-map ctor: hash order (PersistentHashMap). -(define (jolt-hash-map-build kvs) - (let loop ((m empty-pmap-hash) (kvs kvs)) - (cond ((null? kvs) m) - ((null? (cdr kvs)) (error 'hash-map "odd number of map entries")) - (else (loop (pmap-put-hash m (car kvs) (cadr kvs)) (cddr kvs)))))) + (else (loop (pmap-assoc m (car kvs) (cadr kvs)) (cddr kvs)))))) (define-record-type pset (fields m) (nongenerative chez-pset-v1)) -(define empty-pset (make-pset empty-pmap-hash)) ; sets are hash-ordered +(define empty-pset (make-pset empty-pmap)) (define (pset-conj s e) (if (pmap-contains? (pset-m s) e) s (make-pset (pmap-assoc (pset-m s) e e)))) (define (pset-disj s e) (make-pset (pmap-dissoc (pset-m s) e))) (define (pset-contains? s e) (pmap-contains? (pset-m s) e)) @@ -410,7 +211,7 @@ ((empty-list-t? coll) (cseq-list x jolt-nil)) ((pmap? coll) (cond ((jolt-nil? x) coll) ; (conj m nil) = m - ((pmap? x) (pmap-fold-fwd x (lambda (k v m) (pmap-assoc m k v)) coll)) ; merge in x's order + ((pmap? x) (pmap-fold x (lambda (k v m) (pmap-assoc m k v)) coll)) ; merge ((and (pvec? x) (fx=? 2 (pvec-count x))) (pmap-assoc coll (pvec-nth-d x 0 jolt-nil) (pvec-nth-d x 1 jolt-nil))) (else (error 'conj "conj on a map expects a [k v] pair or a map")))) @@ -421,11 +222,9 @@ (if (null? args) (jolt-vector) (let ((coll (car args)) (xs (cdr args))) - (cond - ;; 1-arity returns the coll untouched — (conj nil) is nil - ((null? xs) coll) - ((jolt-nil? coll) (fold-left jolt-conj1 jolt-empty-list xs)) - (else (meta-carry coll (fold-left jolt-conj1 coll xs))))))) + (if (jolt-nil? coll) + (fold-left jolt-conj1 jolt-empty-list xs) + (meta-carry coll (fold-left jolt-conj1 coll xs)))))) ;; A host shim registers a type's get via register-get-arm! (handler: (coll k d) -> ;; value) instead of set!-wrapping jolt-get — disjoint coll types, checked before the @@ -440,16 +239,11 @@ ((string? coll) (let ((i (->idx k))) (if (and (fixnum? i) (fx>=? i 0) (fxidx i))) - (cond ((jolt-nil? coll) jolt-nil) ; RT.nth(nil, i) is nil at any index - ((pvec? coll) (let ((v (pvec-v coll))) + (cond ((pvec? coll) (let ((v (pvec-v coll))) (if (and (fx>=? i 0) (fx=? i 0) (fx (lambda (m) (jolt-invoke m coll i))) (else (error 'nth "unsupported collection"))))) ((coll i d) - (jolt-nth-nil-idx! i) (let ((i (->idx i))) - (cond ((jolt-nil? coll) d) ; RT.nth(nil, i, notFound) is notFound - ((pvec? coll) (pvec-nth-d coll i d)) + (cond ((pvec? coll) (pvec-nth-d coll i d)) ((string? coll) (if (and (fx>=? i 0) (fx (lambda (m) (jolt-invoke m coll i d))) @@ -528,21 +315,6 @@ ((pset? coll) (pset-contains? coll k)) ((pvec? coll) (let ((k (->idx k))) (and (fixnum? k) (fx>=? k 0) (fx= k 0) (< k (string-length coll))) - (jolt-throw (jolt-host-throwable - "java.lang.IllegalArgumentException" - "contains? not supported on type: java.lang.String")))) - ((or (cseq? coll) (empty-list-t? coll) (number? coll) (boolean? coll) - (keyword? coll) (jolt-symbol? coll) (char? coll)) - (jolt-throw (jolt-host-throwable - "java.lang.IllegalArgumentException" - (string-append "contains? not supported on type: " - (guard (e (#t "?")) (jolt-class-name coll)))))) (else #f))) (define (jolt-empty? coll) @@ -555,25 +327,15 @@ ((cseq? coll) #f) ; a cseq is non-empty by construction (else (error 'empty? "unsupported collection")))) -(define (jolt-stack-throw coll) - (jolt-throw (jolt-host-throwable - "java.lang.ClassCastException" - (string-append "class " (guard (e (#t "?")) (jolt-class-name coll)) - " cannot be cast to class clojure.lang.IPersistentStack")))) (define (jolt-peek coll) (cond ((pvec? coll) (pvec-peek coll)) - ;; list peek = first; a non-list seq (range, a rest chain) is not an - ;; IPersistentStack on the JVM - ((and (cseq? coll) (cseq-list? coll)) (jolt-first coll)) - ((empty-list-t? coll) (jolt-first coll)) - ((jolt-nil? coll) jolt-nil) - (else (jolt-stack-throw coll)))) + ((or (cseq? coll) (empty-list-t? coll)) (jolt-first coll)) ; list peek = first + ((jolt-nil? coll) jolt-nil) (else (error 'peek "unsupported collection")))) (define (jolt-pop coll) - (cond ((jolt-nil? coll) jolt-nil) ; RT.pop(nil) is nil - ((pvec? coll) (meta-carry coll (pvec-pop coll))) - ((and (cseq? coll) (cseq-list? coll)) (meta-carry coll (jolt-rest coll))) + (cond ((pvec? coll) (meta-carry coll (pvec-pop coll))) + ((cseq? coll) (meta-carry coll (jolt-rest coll))) ; list pop = rest ((empty-list-t? coll) (error 'pop "can't pop empty list")) - (else (jolt-stack-throw coll)))) + (else (error 'pop "unsupported collection")))) ;; ============================================================================ ;; equality / hash hooks called from values.ss (jolt=2 / jolt-hash) diff --git a/host/chez/compile-eval.ss b/host/chez/compile-eval.ss index 4c2da62..624511b 100644 --- a/host/chez/compile-eval.ss +++ b/host/chez/compile-eval.ss @@ -20,138 +20,12 @@ ;; whose data conversion would turn those into real sets. (define jolt-ce-read jolt-read-form-raw) -;; --- current source location ------------------------------------------------ -;; The position of the top-level form currently compiling/evaluating, so an -;; uncaught error can report where it came from (cli.ss jolt-report-uncaught). -;; Thread-local: a future/agent worker tracks its own form. Holds #f or a -;; {:line :column :file?} position map (jolt.host/form-position's shape). -;; Top-level granularity — one set per top-level form, nothing per call. -(define jolt-current-source (make-thread-parameter #f)) - -;; clojure.lang.Compiler/LINE and /COLUMN — derefable cells (Vars on the JVM) -;; holding the line/column of the form being compiled. Macros read @Compiler/LINE -;; as a fallback when &form carries no position (jolt's reader stamps :line on list -;; forms, so this is rarely hit). Updated per top-level form, like *current-source*. -(define compiler-line-cell (jolt-atom-new 0)) -(define compiler-column-cell (jolt-atom-new 0)) -;; clojure.lang.Compiler/specials — the JVM's special-form table (sym -> parser). -;; tools.macro reads (keys Compiler/specials) to know which heads NOT to expand. -;; Only the keys matter here; values are #t. The set matches Clojure 1.2/1.3. -(define compiler-specials - (let ((unq '("def" "loop*" "recur" "if" "case*" "let*" "letfn*" "do" "fn*" - "quote" "var" "." "set!" "try" "monitor-enter" "monitor-exit" - "throw" "new" "&" "catch" "finally" "reify*" "deftype*"))) - (fold-left (lambda (m s) (jolt-assoc1 m (jolt-symbol #f s) #t)) - (jolt-assoc1 (jolt-hash-map) (jolt-symbol "clojure.core" "import*") #t) - unq))) -;; clojure.lang.Compiler/demunge — reverse the name munging Clojure applies to -;; build JVM class/method names, so "clojure.core$odd_QMARK_" -> clojure.core/odd?. -;; clojure.spec.alpha's fn-sym uses it to recover a symbol from a fn's class name. -;; Longest tokens first; a standalone _ is a hyphen; $ separates ns from name. -(define demunge-token-map - '(("_DOUBLEQUOTE_" . "\"") ("_SINGLEQUOTE_" . "'") ("_AMPERSAND_" . "&") ("_PERCENT_" . "%") - ("_LBRACE_" . "{") ("_RBRACE_" . "}") ("_LBRACK_" . "[") ("_RBRACK_" . "]") - ("_BSLASH_" . "\\") ("_TILDE_" . "~") ("_CIRCA_" . "@") ("_SHARP_" . "#") ("_BANG_" . "!") - ("_CARET_" . "^") ("_COLON_" . ":") ("_QMARK_" . "?") ("_SLASH_" . "/") ("_PLUS_" . "+") - ("_STAR_" . "*") ("_BAR_" . "|") ("_GT_" . ">") ("_LT_" . "<") ("_EQ_" . "=") ("_DOT_" . "."))) -(define (compiler-demunge s) - (let* ((s (if (string? s) s (jolt-str-render-one s))) - (n (string-length s)) - (out (open-output-string))) - (let loop ((i 0)) - (if (>= i n) (get-output-string out) - (let ((tok (let scan ((ts demunge-token-map)) - (cond ((null? ts) #f) - ((let ((t (caar ts))) - (and (<= (+ i (string-length t)) n) - (string=? (substring s i (+ i (string-length t))) t))) - (car ts)) - (else (scan (cdr ts))))))) - (cond - (tok (display (cdr tok) out) (loop (+ i (string-length (car tok))))) - ((char=? (string-ref s i) #\_) (write-char #\- out) (loop (+ i 1))) - ((char=? (string-ref s i) #\$) (write-char #\/ out) (loop (+ i 1))) - (else (write-char (string-ref s i) out) (loop (+ i 1))))))))) -(let ((members (list (cons "LINE" compiler-line-cell) (cons "COLUMN" compiler-column-cell) - (cons "specials" compiler-specials) - (cons "demunge" compiler-demunge)))) - (register-class-statics! "Compiler" members) - (register-class-statics! "clojure.lang.Compiler" members)) - -(define (jolt-enter-form! form) - (let ((p (hc-form-position form))) - (when (pmap? p) - (jolt-current-source p) - (let ((line (jolt-get p hc-kw-line jolt-nil)) (col (jolt-get p hc-kw-column jolt-nil))) - (jolt-atom-val-set! compiler-line-cell (if (jolt-nil? line) 0 line)) - (jolt-atom-val-set! compiler-column-cell (if (jolt-nil? col) 0 col)))))) - -;; "file:line:col" / "line:col" for the current form, or #f when none is set. -(define (jolt-current-source-string) - (let ((p (jolt-current-source))) - (and (pmap? p) - (let ((line (jolt-get p hc-kw-line jolt-nil)) - (col (jolt-get p hc-kw-column jolt-nil)) - (file (jolt-get p hc-kw-file jolt-nil))) - (string-append - (if (jolt-nil? file) "" (string-append file ":")) - (if (jolt-nil? line) "?" (number->string line)) ":" - (if (jolt-nil? col) "?" (number->string col))))))) - ;; The spine ALWAYS runs with the full clojure.core prelude loaded, so a clojure.* ;; ref must lower to var-deref (resolved from the prelude), not trip the emitter's ;; "unsupported stdlib fn (no core on Chez yet)" out-of-subset guard — that guard ;; is only for the bare -e subset with no prelude. Turn prelude mode on once, here, ;; so every analyze->emit on this spine sees the full core. ((var-deref "jolt.backend-scheme" "set-prelude-mode!") #t) -;; Cache resolved var cells per reference site in runtime-compiled code (the big -;; win for libraries / REPL code). emit-image.ss turns this back off so the seed -;; mint and AOT build stay byte-deterministic. Guarded: the flag is absent in an -;; older seed during the first re-mint pass. -(let ((scv (var-deref "jolt.backend-scheme" "set-var-cache!"))) - (when (procedure? scv) (scv #t))) -;; JOLT_TRACE is a falsey value (case-insensitive) — the single predicate both the -;; dev-mode enable and the whole-run enable consult, so "off" never accidentally -;; means "on". An empty / unset value is NOT falsey here — it carries no signal, so -;; dev mode still traces and a whole run still doesn't. -(define (jolt-trace-env-off? e) - (and (string? e) - (let ((s (string-downcase e))) - (or (string=? s "0") (string=? s "false") (string=? s "no") - (string=? s "off") (string=? s "n"))))) -;; Tail-frame history. Turning it on makes the emitter add a per-fn history push to -;; every fn compiled AFTERWARD, and allocates this thread's ring. Suppressed when -;; JOLT_TRACE is a falsey value, so JOLT_TRACE=0 / off / no disables it in dev mode. -(define (jolt-enable-trace!) - (unless (jolt-trace-env-off? (getenv "JOLT_TRACE")) - (let ((stf (var-deref "jolt.backend-scheme" "set-trace-frames!"))) - (when (procedure? stf) (stf #t))) - (jolt-trace-enable!))) -;; Exposed so the REPL / nREPL entrypoints (jolt.main, jolt.nrepl) can turn tracing -;; on for REPL-driven development without the user setting JOLT_TRACE. Because the -;; push is baked in at compile time, only code compiled after this call is traced — -;; which is exactly the code you eval / reload in a live session. -(def-var! "jolt.host" "enable-trace!" jolt-enable-trace!) -;; Explicit opt-in for a whole run (JOLT_TRACE=1): turn tracing on BEFORE any app -;; namespace is compiled, so a plain `-M:run` traces the app's own code too. Called -;; from the runtime entrypoints (cli.ss, and the built joltc launcher) — NOT at load -;; time: a built joltc runs top-level forms at heap-build time, where JOLT_TRACE is -;; always unset, so a load-time check would never see the user's runtime env. Only an -;; affirmative value (set, non-empty, not falsey) forces it on. -(define (jolt-trace-init-from-env!) - (let ((e (getenv "JOLT_TRACE"))) - (when (and e (fx>? (string-length e) 0) (not (jolt-trace-env-off? e))) - (jolt-enable-trace!)))) - -;; (with-meta sym m) -> sym, else x — an (ns ^:no-doc name …) yields the name with -;; reader metadata as a with-meta form; strip it to read the bare ns symbol. -(define (ce-unwrap-meta x) - (if (and (cseq? x) (cseq-list? x)) - (let ((items (seq->list x))) - (if (and (pair? items) (symbol-t? (car items)) - (string=? (symbol-t-name (car items)) "with-meta") (pair? (cdr items))) - (cadr items) x)) - x)) ;; (quote X) -> X, else x — unwraps a quoted require spec. (define (ce-unquote x) @@ -177,22 +51,14 @@ ;; (require spec...) / (use spec...) — specs are quoted ((and hn (or (string=? hn "require") (string=? hn "use"))) (for-each (lambda (a) (chez-register-spec! ns (ce-unquote a))) (cdr items))) - ;; (ns name (:require [a :as x]) ...) — clause specs are literal. Register - ;; the aliases under NAME (the ns being defined), not the passed `ns`: - ;; when a file is loaded its ns form compiles while (chez-current-ns) is - ;; still the requiring ns, so using `ns` would leak the loaded ns's - ;; aliases into its requirer and clobber a same-named alias there - ;; (rewrite-clj.zip.base's [node.protocols :as node] over the caller's node). + ;; (ns name (:require [a :as x]) ...) — clause specs are literal ((and hn (string=? hn "ns")) - (let ((ns-name (if (and (pair? (cdr items)) (symbol-t? (ce-unwrap-meta (cadr items)))) - (symbol-t-name (ce-unwrap-meta (cadr items))) - ns))) - (for-each (lambda (clause) - (when (and (cseq? clause) (cseq-list? clause)) - (let ((cl (seq->list clause))) - (when (ce-clause-require? cl) - (for-each (lambda (spec) (chez-register-spec! ns-name spec)) (cdr cl)))))) - (if (pair? (cdr items)) (cddr items) '())))) + (for-each (lambda (clause) + (when (and (cseq? clause) (cseq-list? clause)) + (let ((cl (seq->list clause))) + (when (ce-clause-require? cl) + (for-each (lambda (spec) (chez-register-spec! ns spec)) (cdr cl)))))) + (if (pair? (cdr items)) (cddr items) '()))) (else (for-each (lambda (x) (ce-scan-requires! x ns)) items)))))))) ;; Already-read FORM -> Scheme source string (analyze -> emit on Chez). @@ -243,13 +109,7 @@ ;; A top-level (do ...) is UNROLLED — each subform compiled+eval'd in turn, like ;; Clojure's top-level do — so a runtime defmacro/def in an earlier subform is ;; visible (macro flag set, var interned) before a later subform is analyzed. -;; a non-form VALUE (a function object, a BigDecimal, a reference type) -;; self-evaluates, like eval on the JVM. (define (jolt-compile-eval-form form ns) - (if (or (procedure? form) (jbigdec? form) (jolt-atom? form) (jolt-multifn? form)) - form - (jolt-compile-eval-form* form ns))) -(define (jolt-compile-eval-form* form ns) (cond ;; thread the current ns: an earlier subform may switch it (ns/in-ns call ;; set-chez-ns!), and the next subform must be ANALYZED in that ns so its defs @@ -264,12 +124,6 @@ ;; of the expander fn + (mark-macro! …) so subsequent forms expand it. One ;; macro-expansion path (no separate spine interception). (else - ;; record this form's source location first, so a compile- or run-time error - ;; in it reports the right place. - (jolt-enter-form! form) - ;; drop tail-frame history from earlier top-level forms, so an error's trace - ;; shows only this form's own call history (a no-op unless JOLT_TRACE is on). - (jolt-trace-reset!) (eval (read (open-input-string (jolt-analyze-emit-form form ns))) (interaction-environment))))) diff --git a/host/chez/java/concurrency.ss b/host/chez/concurrency.ss similarity index 57% rename from host/chez/java/concurrency.ss rename to host/chez/concurrency.ss index f0ed225..0f6bdfb 100644 --- a/host/chez/java/concurrency.ss +++ b/host/chez/concurrency.ss @@ -151,31 +151,16 @@ (mutable queue) (mutable running?) mu cv) (nongenerative jolt-agent-v1)) -;; (agent state :meta m :validator f :error-mode e): the ARef ctor contract like -;; atom's — the validator runs against the initial state, :meta must be a map. -;; :error-mode is accepted/ignored (jolt agents are always :fail). +;; (agent state) / (agent state :validator f :error-mode m :meta x): only :validator +;; has runtime behaviour here; other opts are accepted/ignored. (define (jolt-agent-new state . opts) - (let loop ((o opts) (validator jolt-nil) (m #f)) + (let loop ((o opts) (validator jolt-nil)) (cond ((or (null? o) (null? (cdr o))) - (let ((a (make-jolt-agent state jolt-nil validator (vector '() '()) #f (make-mutex) (make-condition)))) - (when (and (not (jolt-nil? validator)) (jolt-not (jolt-invoke validator state))) - (jolt-iref-state-throw)) - (when (and m (not (jolt-nil? m))) - (unless (jolt-map? m) - (jolt-throw (jolt-host-throwable - "java.lang.ClassCastException" - (string-append "class " (jolt-class-name m) - " cannot be cast to class clojure.lang.IPersistentMap")))) - (hashtable-set! meta-table a m)) - a)) + (make-jolt-agent state jolt-nil validator (vector '() '()) #f (make-mutex) (make-condition))) ((and (keyword-t? (car o)) (string=? (keyword-t-name (car o)) "validator")) - (loop (cddr o) (cadr o) m)) - ((and (keyword-t? (car o)) (string=? (keyword-t-name (car o)) "meta")) - (loop (cddr o) validator (cadr o))) - (else (loop (cddr o) validator m))))) -;; agents are watchable IRefs; the worker notifies on each state change. -(register-iref-arm! jolt-agent?) + (loop (cddr o) (cadr o))) + (else (loop (cddr o) validator))))) ;; The action queue is an amortized-O(1) FIFO held as a mutable #(out in): `out` is ;; the front, `in` holds sends reversed onto it (an append-to-a-list send was O(n)). @@ -204,13 +189,11 @@ (guard (e (#t (with-mutex (jolt-agent-mu a) (jolt-agent-err-set! a e) (condition-broadcast (jolt-agent-cv a))))) - (let* ((old (jolt-agent-state a)) - (nv (apply jolt-invoke (car act) old (cdr act)))) + (let ((nv (apply jolt-invoke (car act) (jolt-agent-state a) (cdr act)))) (let ((vf (jolt-agent-validator a))) (when (and (not (jolt-nil? vf)) (jolt-not (jolt-invoke vf nv))) - (jolt-iref-state-throw))) - (jolt-agent-state-set! a nv) - (iref-notify a old nv))) + (error #f "Invalid reference state"))) + (jolt-agent-state-set! a nv))) (loop))))) ;; send / send-off: enqueue the action, start the worker if idle. (jolt treats them @@ -277,12 +260,6 @@ (jolt-promise-deref-timed x (car opts) (cadr opts)))) ((jolt-agent? x) (jolt-agent-state x)) ((jolt-delay? x) (jolt-delay-force x)) - ;; a record/reify implementing clojure.lang.IDeref: @x calls its `deref` - ;; method with the value itself as the leading `this`. - ((and (jrec? x) (find-method-any-protocol (jrec-tag x) "deref")) - => (lambda (m) (jolt-invoke m x))) - ((and (reified-methods x) (hashtable-ref (reified-methods x) "deref" #f)) - => (lambda (m) (jolt-invoke m x))) (else (apply %pre-conc-deref x opts))))) ;; realized? for a future/promise/delay. Wrapped over the overlay version in @@ -301,16 +278,6 @@ (def-var! "clojure.core" "future-cancelled?" jolt-native-future-cancelled?) (def-var! "clojure.core" "promise" jolt-promise-new) (def-var! "clojure.core" "deliver" jolt-deliver) -;; a promise is an IFn on the JVM: (p val) delivers. Registered as a cold -;; invoke arm; callable-host? feeds the ifn? overlay (multimethods included). -(register-invoke-arm! jolt-promise? - (lambda (p args) - (if (and (pair? args) (null? (cdr args))) - (jolt-deliver p (car args)) - (jolt-throw (jolt-host-throwable "clojure.lang.ArityException" - "Wrong number of args passed to a promise"))))) -(def-var! "jolt.host" "callable-host?" - (lambda (x) (if (or (jolt-multifn? x) (jolt-promise? x)) #t jolt-nil))) (def-var! "clojure.core" "agent" jolt-agent-new) (def-var! "clojure.core" "agent?" jolt-agent?) (def-var! "clojure.core" "send" jolt-agent-send) @@ -322,26 +289,6 @@ (def-var! "clojure.core" "delay?" jolt-delay?) (def-var! "clojure.core" "deref" jolt-deref) -;; --- object monitors (locking) ---------------------------------------------- -;; (locking obj body…) takes obj's monitor for the body — a real per-object lock -;; now that futures/agents/threads share one heap. Each object gets a recursive -;; Chez mutex (a thread may re-enter a monitor it already holds, like the JVM), -;; held in an identity-keyed weak table so monitors are reclaimed with their -;; objects. dynamic-wind releases on normal, exceptional, and continuation exit. -(define monitor-table (make-weak-eq-hashtable)) -(define monitor-table-lock (make-mutex)) -(define (object-monitor obj) - (with-mutex monitor-table-lock - (or (hashtable-ref monitor-table obj #f) - (let ((m (make-mutex))) (hashtable-set! monitor-table obj m) m)))) -(define (jolt-with-monitor obj thunk) - (let ((m (object-monitor obj))) - (dynamic-wind - (lambda () (mutex-acquire m)) - thunk - (lambda () (mutex-release m))))) -(def-var! "jolt.host" "with-monitor" jolt-with-monitor) - ;; --- cooperative thread interrupt ------------------------------------------- ;; Chez has no force-kill, but its engine timer (set-timer + timer-interrupt- ;; handler, thread-local) is polled at procedure-call / loop back-edges — so a @@ -424,188 +371,4 @@ (with-mutex (vector-ref st 1) (let loop () (when (> (vector-ref st 0) 0) (condition-wait (vector-ref st 2) (vector-ref st 1)) (loop))))) jolt-nil)) - (cons "getCount" (lambda (self) (vector-ref (jhost-state self) 0))))) - -;; --- main-thread executor --------------------------------------------------- -;; Lets a worker thread (e.g. an nREPL eval future) run a thunk on the thread -;; that owns the GUI main loop. On macOS GTK quartz, g_application_run must run -;; on the process main thread or AppKit aborts (setMainMenu off-main → SIGABRT). -;; Under `joltc nrepl` the accept loop is backgrounded in a future and the -;; primordial thread enters jolt-run-main-pump; glimmer's run marshals its -;; startup through jolt-call-on-main-thread. -;; -;; - With no pump running (`joltc -M:run` calls run directly on the main thread), -;; call-on-main-thread runs the thunk INLINE — unchanged behaviour. -;; - A call from a thunk already executing on the pump runs inline too, so the -;; pump can't deadlock on itself. -;; - Otherwise the thunk is enqueued; the caller blocks until the pump runs it, -;; then receives the value, or the thrown condition is re-raised. -;; -;; stop-main-pump is the graceful-shutdown / external API: it tells the pump to -;; drain whatever is queued and return. The pump-active flag is flipped to #f -;; under jolt-main-queue-mu in the same critical section that decides to exit, and -;; call-on-main-thread reads that flag and enqueues under the SAME mutex, so a job -;; can never slip in after the pump has decided to leave — a call that loses the -;; race simply runs inline instead of blocking forever on a pump that is gone. - -(define jolt-main-queue-mu (make-mutex)) -(define jolt-main-queue-cv (make-condition)) -(define jolt-main-queue '()) ; FIFO of jolt-main-job, guarded by mu -(define jolt-main-pump-active (box #f)) ; #t while run-main-pump owns this thread -(define jolt-main-pump-stop (box #f)) ; set by stop-main-pump to drain + exit -;; thread-local: this thread is the pump, mid-thunk → nested calls run inline. -(define jolt-in-main-pump? (make-thread-parameter #f)) - -(define-record-type jolt-main-job - (fields thunk (mutable done?) (mutable ok?) (mutable val) mu cv) - (nongenerative jolt-main-job-v1)) - -(define (jolt-call-on-main-thread thunk) - (if (jolt-in-main-pump?) ; reentrant — already on the pump - (jolt-invoke thunk) - ;; Decide-and-enqueue atomically: read pump-active and (if active) push the - ;; job under jolt-main-queue-mu, the same lock the pump holds when it flips - ;; active to #f on exit. So we either get queued before the pump leaves, or - ;; we see #f and fall through to inline — never enqueue onto a dead pump. - (let ((job (with-mutex jolt-main-queue-mu - (and (unbox jolt-main-pump-active) - (let ((j (make-jolt-main-job thunk #f #f jolt-nil - (make-mutex) (make-condition)))) - (set! jolt-main-queue (append jolt-main-queue (list j))) - (condition-signal jolt-main-queue-cv) - j))))) - (if (not job) - (jolt-invoke thunk) ; no pump (or stopped) — inline, like -M:run - (begin - (with-mutex (jolt-main-job-mu job) - (let wait () - (unless (jolt-main-job-done? job) - (condition-wait (jolt-main-job-cv job) (jolt-main-job-mu job)) - (wait)))) - (if (jolt-main-job-ok? job) - (jolt-main-job-val job) - (raise (jolt-main-job-val job)))))))) - -(define jolt-pump-kih - (lambda () - (for-each (lambda (th) (guard (e (#t #f)) (th))) - (reverse (unbox jolt-shutdown-hooks))) - (exit 0))) - -;; Park the calling thread until a keyboard interrupt (^C), then run the shutdown -;; hooks and exit. Unlike run-main-pump (whose tight recursive condition-wait -;; loop elides Chez's interrupt poll points, so the handler never fires), this -;; uses a single condition-wait — the form Chez reliably interrupts. The nREPL -;; server parks here; SIGINT is unblocked in this thread first (it was masked by -;; jolt-block-sigint so the accept loop inherited a blocked mask and couldn't -;; absorb ^C in its foreign accept() call). -(define jolt-park-mu (make-mutex)) -(define jolt-park-cv (make-condition)) -(define (jolt-park-until-interrupt) - (keyboard-interrupt-handler jolt-pump-kih) - (jolt-set-sigint-blocked #f) - (with-mutex jolt-park-mu (condition-wait jolt-park-cv jolt-park-mu)) - jolt-nil) - -(define (jolt-run-main-pump) - (with-mutex jolt-main-queue-mu - (set-box! jolt-main-pump-stop #f) - (set-box! jolt-main-pump-active #t)) - ;; dynamic-wind guarantees active is cleared even if the pump escapes abnormally, - ;; so a later run-main-pump starts clean and call-on-main-thread never sees a - ;; stale #t. The clean-exit path below also clears it under the mutex (the flip - ;; that races call-on-main-thread); this is the belt-and-suspenders for escapes. - (dynamic-wind - (lambda () #f) - (lambda () - (let loop () - (let ((job (with-mutex jolt-main-queue-mu - (let wait () - (cond - ((not (null? jolt-main-queue)) - (let ((j (car jolt-main-queue))) - (set! jolt-main-queue (cdr jolt-main-queue)) - j)) - ((unbox jolt-main-pump-stop) - ;; drain done, told to exit — clear active in the same - ;; critical section so no job can be enqueued after. - (set-box! jolt-main-pump-active #f) - #f) - (else (condition-wait jolt-main-queue-cv jolt-main-queue-mu) - (wait))))))) - (when job - (let ((r (dynamic-wind - (lambda () (jolt-in-main-pump? #t)) - (lambda () - (guard (e (#t (cons #f e))) - (cons #t (jolt-invoke (jolt-main-job-thunk job))))) - (lambda () (jolt-in-main-pump? #f))))) - (with-mutex (jolt-main-job-mu job) - (jolt-main-job-ok?-set! job (car r)) - (jolt-main-job-val-set! job (cdr r)) - (jolt-main-job-done?-set! job #t) - (condition-broadcast (jolt-main-job-cv job)))) - (loop))))) - (lambda () - (with-mutex jolt-main-queue-mu (set-box! jolt-main-pump-active #f)))) - jolt-nil) - -(define (jolt-stop-main-pump) - (with-mutex jolt-main-queue-mu - (set-box! jolt-main-pump-stop #t) - (condition-broadcast jolt-main-queue-cv)) - jolt-nil) - -;; Shutdown hooks run by jolt-pump-kih (the keyboard-interrupt-handler installed by -;; park-until-interrupt) before (exit 0), so a foreground server (nREPL) can close -;; its socket and drop .nrepl-port on ^C instead of Chez's default mutex-corrupting -;; abort. Newest-first; each hook is isolated so one failing hook can't block the exit. -(define jolt-shutdown-hooks (box '())) -(define (jolt-add-shutdown-hook thunk) - (set-box! jolt-shutdown-hooks (cons thunk (unbox jolt-shutdown-hooks))) - jolt-nil) - -;; Per-thread SIGINT mask. A worker thread parked in a foreign call (the nREPL -;; accept loop in c-accept, or a conn handler) can't run Chez's keyboard-interrupt -;; handler on ^C, so if SIGINT is delivered there the process hangs. Block SIGINT -;; in the primordial thread BEFORE forking such workers (they inherit the mask), -;; then park-until-interrupt unblocks it in the primordial once its handler is -;; installed, so ^C is always delivered to the parked thread. pthread_sigmask/ -;; sigaddset are libc/libpthread symbols, resolvable once the process object is -;; loaded (as the socket fns already are). 128 bytes covers Linux's 1024-bit -;; sigset_t and is larger than macOS's 4-byte one. -;; foreign-procedure resolves its symbol eagerly, and these POSIX signal fns don't -;; exist on Windows — resolving them unguarded aborted startup ("no entry for -;; pthread_sigmask"). Guard so a non-POSIX host yields #f; jolt-set-sigint-blocked -;; then no-ops (Windows delivers ^C through the console, not a per-thread mask). -(define c-pthread-sigmask - (jolt-foreign-proc-safe "pthread_sigmask" '(int u8* u8*) 'int)) -(define c-sigemptyset (jolt-foreign-proc-safe "sigemptyset" '(u8*) 'int)) -(define c-sigaddset (jolt-foreign-proc-safe "sigaddset" '(u8* int) 'int)) -;; POSIX SIG_BLOCK/SIG_UNBLOCK numerics differ by platform: Linux/glibc 0/1, -;; Darwin/macOS 1/2 (SIG_UNBLOCK is SIG_BLOCK+1 on both). Resolve SIG_BLOCK for -;; this host from the machine-type symbol — macOS builds contain "osx". -(define jolt-sig-block-how - (let* ((s (symbol->string (machine-type))) - (n (string-length s))) - (let loop ((i 0)) - (cond - ((> (+ i 3) n) 0) ; default: Linux/glibc - ((string=? (substring s i (+ i 3)) "osx") 1) ; Darwin/macOS - (else (loop (+ i 1))))))) -(define (jolt-set-sigint-blocked block?) - (when (and c-pthread-sigmask c-sigemptyset c-sigaddset) - (let ((set (make-bytevector 128 0)) - (old (make-bytevector 128 0))) - (c-sigemptyset set) - (c-sigaddset set 2) ; SIGINT = 2 - (c-pthread-sigmask (if block? jolt-sig-block-how (+ jolt-sig-block-how 1)) set old))) - jolt-nil) - -(def-var! "jolt.host" "call-on-main-thread" jolt-call-on-main-thread) -(def-var! "jolt.host" "run-main-pump" jolt-run-main-pump) -(def-var! "jolt.host" "stop-main-pump" jolt-stop-main-pump) -(def-var! "jolt.host" "add-shutdown-hook" jolt-add-shutdown-hook) -(def-var! "jolt.host" "block-sigint" (lambda () (jolt-set-sigint-blocked #t))) -(def-var! "jolt.host" "park-until-interrupt" jolt-park-until-interrupt) -(def-var! "jolt.host" "delete-file" delete-file) + (cons "getCount" (lambda (self) (vector-ref (jhost-state self) 0))))) diff --git a/host/chez/converters.ss b/host/chez/converters.ss index afef684..04bf7c4 100644 --- a/host/chez/converters.ss +++ b/host/chez/converters.ss @@ -27,48 +27,17 @@ ((and (flonum? v) (fl= v +inf.0)) "Infinity") ((and (flonum? v) (fl= v -inf.0)) "-Infinity") ((and (flonum? v) (not (fl= v v))) "NaN") - ;; a symbol stringifies to its name (JVM Symbol.toString returns the interned - ;; name), so (str sym) of a no-ns symbol is the SAME string object the symbol - ;; holds — code that compares those by identity (core.logic's non-unique lvar - ;; equality) depends on it. - ((symbol-t? v) - (let ((ns (symbol-t-ns v))) - (if (or (not ns) (jolt-nil? ns)) - (symbol-t-name v) - (string-append ns "/" (symbol-t-name v))))) (else (let loop ((rs str-render-registry)) (cond ((null? rs) (jolt-pr-str v)) (((caar rs) v) ((cdar rs) v)) (else (loop (cdr rs)))))))) -;; print/println render non-readably: a nested string is raw. jolt-str-render-one -;; is exactly that (collections fall through to jolt-pr-str). The print family -;; uses this seam, NOT the str fn — which renders readably (below). A top-level nil -;; prints "nil" (str renders it ""), so the seam special-cases it. -(define (jolt-print-one v) (if (jolt-nil? v) "nil" (jolt-str-render-one v))) -(def-var! "clojure.core" "__print1" jolt-print-one) - -;; str: a top-level string/scalar renders as jolt-str-render-one (raw string, -;; "Infinity"…), but a COLLECTION renders as its readable form — nested strings -;; are QUOTED ((str ["x"]) => "[\"x\"]"), matching the JVM (a collection's -;; toString is readable). jolt-pr-readable resolves at call time. -(define (jolt-str-one v) - (if (or (pvec? v) (pmap? v) (pset? v) (cseq? v) (empty-list-t? v) (jolt-lazyseq? v)) - (jolt-pr-readable v) - (jolt-str-render-one v))) (define (jolt-str . xs) - (cond - ((null? xs) "") - ;; single arg returns its rendering directly (no string-append copy), so - ;; (str sym) hands back the symbol's own name string — JVM (str x) is - ;; x.toString(), and core.logic's non-unique lvar equality compares those by - ;; identity. - ((null? (cdr xs)) (jolt-str-one (car xs))) - (else (let loop ((xs xs) (acc '())) - (if (null? xs) - (apply string-append (reverse acc)) - (loop (cdr xs) (cons (jolt-str-one (car xs)) acc))))))) + (let loop ((xs xs) (acc '())) + (if (null? xs) + (apply string-append (reverse acc)) + (loop (cdr xs) (cons (jolt-str-render-one (car xs)) acc))))) ;; jolt indices are flonums; substring etc. need exact ints. (define (jolt->idx n) (exact (truncate n))) @@ -117,31 +86,23 @@ (let ((a (car args))) (cond ((jolt-symbol? a) a) - ;; (symbol "ns/name") splits the namespace at the FIRST "/" (JVM - ;; Symbol.intern), so (namespace (symbol "foo/bar/baz")) => "foo" with - ;; name "bar/baz". A lone "/" or a leading slash has no namespace. The - ;; no-ns sentinel is #f — matches emit's quoted-symbol lowering - ;; (jolt-symbol #f "x"), so (= 'x (symbol "x")) holds (jolt= compares - ;; ns with strict equal?). + ;; (symbol "ns/name") splits the namespace at the LAST "/" (JVM + ;; Symbol.intern), so (namespace (symbol "foo/bar")) => "foo". A lone "/" + ;; or a leading slash has no namespace. The no-ns sentinel is #f — matches + ;; emit's quoted-symbol lowering (jolt-symbol #f "x"), so (= 'x (symbol + ;; "x")) holds (jolt= compares ns with strict equal?). ((string? a) (let ((slen (string-length a))) (if (string=? a "/") (jolt-symbol #f "/") - (let loop ((i 1)) - (cond ((>= i slen) (jolt-symbol #f a)) + (let loop ((i (- slen 1))) + (cond ((<= i 0) (jolt-symbol #f a)) ((char=? (string-ref a i) #\/) (jolt-symbol (substring a 0 i) (substring a (+ i 1) slen))) - (else (loop (+ i 1)))))))) + (else (loop (- i 1)))))))) ((keyword? a) (jolt-symbol (keyword-t-ns a) (keyword-t-name a))) - ;; (symbol a-var) -> the var's qualified symbol (clojure.spec.alpha/->sym). - ((var-cell? a) (jolt-symbol (var-cell-ns a) (var-cell-name a))) (else (error #f "symbol: requires string/symbol" a))))) - ;; (symbol ns name): a nil namespace is the no-ns sentinel #f (NOT jolt-nil), - ;; so (symbol nil "x") equals (symbol "x") and the reader literal 'x — jolt= - ;; compares ns with strict equal?, so a jolt-nil ns would differ from #f. - ((= (length args) 2) - (let ((ns (car args))) - (jolt-symbol (if (jolt-nil? ns) #f ns) (cadr args)))) + ((= (length args) 2) (jolt-symbol (car args) (cadr args))) (else (error #f "symbol: wrong arity")))) ;; gensym: per-process counter. @@ -156,12 +117,7 @@ ;; int/long: truncate toward zero to an EXACT integer (= JVM long). char -> code ;; point (exact). double: always a flonum (= JVM double). (define (jolt-int x) (if (char? x) (char->integer x) (exact (truncate x)))) -;; a numeric type outside Chez's tower converts through this hook (bigdec). -(define (jolt-double-slow x) (jolt-num-cast-throw x)) -(define (jolt-double x) - (cond ((char? x) (exact->inexact (char->integer x))) - ((number? x) (exact->inexact x)) - (else (jolt-double-slow x)))) +(define (jolt-double x) (if (char? x) (exact->inexact (char->integer x)) (exact->inexact x))) ;; compare: 3-way, returns an EXACT integer (= JVM compare -> int). (define (jolt-cmp3 x y) (cond ((< x y) -1) ((> x y) 1) (else 0))) @@ -178,11 +134,7 @@ ((jolt-nil? b) 1) ((and (number? a) (number? b)) (jolt-cmp3 a b)) ((and (string? a) (string? b)) (jolt-strcmp a b)) - ;; keywords order like symbols: a nil namespace sorts before any namespace, - ;; then by namespace, then by name (Keyword.compareTo -> Symbol.compareTo) - ((and (keyword? a) (keyword? b)) - (let ((r (jolt-strcmp (or (keyword-t-ns a) "") (or (keyword-t-ns b) "")))) - (if (= r 0) (jolt-strcmp (keyword-t-name a) (keyword-t-name b)) r))) + ((and (keyword? a) (keyword? b)) (jolt-strcmp (jolt-kw->string a) (jolt-kw->string b))) ((and (jolt-symbol? a) (jolt-symbol? b)) (let ((r (jolt-strcmp (jolt-sym-ns-string a) (jolt-sym-ns-string b)))) (if (= r 0) (jolt-strcmp (symbol-t-name a) (symbol-t-name b)) r))) @@ -205,84 +157,16 @@ (def-var! "clojure.core" "keyword" jolt-keyword) (def-var! "clojure.core" "symbol" jolt-symbol-new) (def-var! "clojure.core" "gensym" jolt-gensym) -;; --- checked narrow casts (RT.byteCast/shortCast/intCast/longCast/charCast) -- -;; One helper carries the JVM ranges: truncate toward zero, then range-check. -;; NaN casts to 0 (Java (long)NaN); an out-of-range value (including a float -;; infinity) is IllegalArgumentException "Value out of range for : x". -;; A non-numeric operand is the usual ClassCastException. Numeric types outside -;; Chez's tower truncate through a hook the shim extends (BigDecimal). -(define (jolt-cast-range-throw name x) - (jolt-throw (jolt-host-throwable - "java.lang.IllegalArgumentException" - (string-append "Value out of range for " name ": " (jolt-str x))))) -(define (jolt-cast-truncate-slow x) (jolt-num-cast-throw x)) -(define (jolt-checked-cast name lo hi x) - (let ((n (cond ((char? x) (char->integer x)) - ((and (number? x) (exact? x)) (truncate x)) - ;; a double range-checks ITSELF (before truncation): (byte - ;; 127.000001) throws, (byte 1.1) is 1; NaN casts to 0; an - ;; infinity always fails the compare. - ((flonum? x) (cond ((nan? x) 0) - ((or (< x lo) (> x hi)) (+ hi 1)) - (else (exact (truncate x))))) - (else (jolt-cast-truncate-slow x))))) - (if (and (>= n lo) (<= n hi)) n (jolt-cast-range-throw name x)))) -(define (jolt-byte-cast x) (jolt-checked-cast "byte" -128 127 x)) -(define (jolt-short-cast x) (jolt-checked-cast "short" -32768 32767 x)) -(define (jolt-int-cast x) (jolt-checked-cast "int" -2147483648 2147483647 x)) -(define (jolt-long-cast x) (jolt-checked-cast "long" -9223372036854775808 9223372036854775807 x)) -(def-var! "clojure.core" "int" jolt-int-cast) -(def-var! "clojure.core" "long" jolt-long-cast) -(def-var! "clojure.core" "byte" jolt-byte-cast) -(def-var! "clojure.core" "short" jolt-short-cast) -;; char: pass a char through; a code point must be in [0, 0xFFFF] (charCast). -(define (jolt-char x) - (if (char? x) x (integer->char (jolt-checked-cast "char" 0 65535 x)))) +(def-var! "clojure.core" "int" jolt-int) +;; char: coerce a code point (jolt's all-flonum number) to a Chez char; pass a +;; char through. Inverse of int on chars. The cross-compiled emitter's +;; chez-str-lit needs it for printable-ASCII escaping. +(define (jolt-char x) (if (char? x) x (integer->char (exact (round x))))) (def-var! "clojure.core" "char" jolt-char) -;; unchecked-long: truncate + wrap to 64 bits (RT.uncheckedLongCast — a float -;; infinity saturates, NaN is 0). unchecked-int wraps and sign-folds to 32. -(define (jolt-cast-saturate n lo hi) (cond ((< n lo) lo) ((> n hi) hi) (else n))) -(define (jolt-unchecked-long x) - (cond ((char? x) (char->integer x)) - ;; an exact integer wraps (long narrowing); a double SATURATES (Java's - ;; double->long conversion clamps at the bounds, NaN is 0). - ((and (number? x) (exact? x)) (jolt-wrap64 (truncate x))) - ((flonum? x) (if (nan? x) 0 - (jolt-cast-saturate (if (infinite? x) (if (> x 0.0) unc-2^63 (- unc-2^63)) (exact (truncate x))) - -9223372036854775808 9223372036854775807))) - (else (jolt-wrap64 (jolt-cast-truncate-slow x))))) -(define (jolt-unchecked-int x) - (if (flonum? x) - ;; double->int clamps like Java - (if (nan? x) 0 - (jolt-cast-saturate (if (infinite? x) (if (> x 0.0) #x80000000 (- #x80000000)) (exact (truncate x))) - -2147483648 2147483647)) - (let ((i (bitwise-and (jolt-unchecked-long x) #xffffffff))) - (if (>= i #x80000000) (- i #x100000000) i)))) -(def-var! "clojure.core" "unchecked-long" jolt-unchecked-long) -(def-var! "clojure.core" "unchecked-int" jolt-unchecked-int) +;; long: same truncation as int in jolt's all-flonum model (seed core-long = +;; math/trunc; char -> code point). Distinct cell so (long ...) resolves. +(def-var! "clojure.core" "long" jolt-int) (def-var! "clojure.core" "double" jolt-double) -;; float: Chez has no single-float type, so the value stays a flonum — but the -;; cast range-checks against Float/MAX_VALUE like RT.floatCast (an infinity is -;; out of range; NaN passes). -(define fl-float-max 3.4028234663852886e38) -(define (jolt-float x) - (let ((d (jolt-double x))) - (if (and (flonum? d) (not (nan? d)) - (or (< d (- fl-float-max)) (> d fl-float-max))) - (jolt-cast-range-throw "float" x) - d))) -(def-var! "clojure.core" "float" jolt-float) -;; numerator/denominator: jolt ratios are Chez exact rationals; a non-ratio is -;; the JVM's Ratio cast failure. -(define (jolt-ratio-part name f) - (lambda (x) - (if (and (number? x) (exact? x) (rational? x) (not (integer? x))) - (f x) - (jolt-throw (jolt-host-throwable - "java.lang.ClassCastException" - (string-append "class " (guard (e (#t "?")) (jolt-class-name x)) - " cannot be cast to class clojure.lang.Ratio")))))) -(def-var! "clojure.core" "numerator" (jolt-ratio-part "numerator" numerator)) -(def-var! "clojure.core" "denominator" (jolt-ratio-part "denominator" denominator)) +;; float: Chez has no single-float type, so float coerces to a flonum like double. +(def-var! "clojure.core" "float" jolt-double) (def-var! "clojure.core" "compare" jolt-compare) diff --git a/host/chez/cts.sh b/host/chez/cts.sh deleted file mode 100755 index 0c2f1cb..0000000 --- a/host/chez/cts.sh +++ /dev/null @@ -1,120 +0,0 @@ -#!/bin/bash -# clojure-test-suite gate: run the vendored jank-lang/clojure-test-suite -# (vendor/clojure-test-suite) against joltc, one process per test namespace (a -# hang or crash is contained), and compare per-namespace fail/error counts -# against the checked-in baseline test/chez/cts-known-failures.txt. -# -# The comparison is exact, like certify's allowlist: a namespace doing WORSE -# than the baseline fails the gate (regression), and one doing BETTER also -# fails (stale baseline — update the file in the same change that improved it). -# -# JOLT_CTS_JOBS=N parallel workers (default 4) -# JOLT_CTS_TIMEOUT=SECS per-namespace timeout (default 120) -# JOLT_CTS_WRITE_BASELINE=1 regenerate the baseline file instead of gating -# JOLT_CTS_NS=ns1,ns2 run only these namespaces, verbose, no gating -set -u -root="$(CDPATH= cd -- "$(dirname -- "$0")/../.." && pwd)" -cd "$root" - -suite="vendor/clojure-test-suite/test" -baseline="test/chez/cts-known-failures.txt" -app="$root/test/chez/cts-app" -jobs="${JOLT_CTS_JOBS:-4}" -tmo="${JOLT_CTS_TIMEOUT:-120}" - -if [ ! -d "$suite/clojure" ]; then - echo "cts: skipped (git submodule update --init vendor/clojure-test-suite)" - exit 0 -fi - -work="$(mktemp -d)" -trap 'rm -rf "$work"' EXIT - -# test namespaces from the .cljc files (portability is a helper, not a test ns) -find "$suite" -name '*.cljc' | sed "s|^$suite/||;s|\.cljc$||;s|/|.|g;s|_|-|g" \ - | grep -v '\.portability$' | sort > "$work/nses" -if [ -n "${JOLT_CTS_NS:-}" ]; then - echo "${JOLT_CTS_NS}" | tr ',' '\n' > "$work/nses" -fi - -# round-robin the namespaces over N sequential workers; each worker appends -# "ns pass fail error" lines (HUNG/CRASH in the pass column) to its own file. -awk -v j="$jobs" '{print > ("'"$work"'/chunk." (NR % j))}' "$work/nses" -run_chunk() { - chunk="$1"; out="$2" - while IFS= read -r ns; do - res=$(JOLT_PWD="$app" perl -e "alarm $tmo; exec @ARGV" -- "$root/bin/joltc" -M:cts "$ns" 2>&1 > "$out" - if [ -n "${JOLT_CTS_NS:-}" ]; then - echo "$res" | grep -E 'FAIL:|ERROR:|LOAD:' | sed 's/^/ /' >> "$out" - fi - elif [ $rc -ge 128 ]; then - echo "$ns HUNG 0 0" >> "$out" - else - echo "$ns CRASH 0 0" >> "$out" - fi - done < "$chunk" -} -for c in "$work"/chunk.*; do - run_chunk "$c" "$c.res" & -done -wait -cat "$work"/chunk.*.res 2>/dev/null | sort > "$work/results" - -if [ -n "${JOLT_CTS_NS:-}" ]; then - cat "$work/results" - exit 0 -fi - -summary=$(awk '$2!="HUNG" && $2!="CRASH" {p+=$2; f+=$3; e+=$4; c++} - $2=="HUNG" {h++} $2=="CRASH" {x++} - END {printf "%d namespaces: pass %d, fail %d, error %d, hung %d, crash %d", - c+h+x, p, f, e, h, x}' "$work/results") - -if [ "${JOLT_CTS_WRITE_BASELINE:-0}" = "1" ]; then - { - echo "# clojure-test-suite known failures: " - echo "# The gate fails on any per-namespace change, worse OR better; regenerate" - echo "# with: JOLT_CTS_WRITE_BASELINE=1 host/chez/cts.sh" - awk '$2=="HUNG" || $2=="CRASH" {print $1, $2, $2; next} - $3 != 0 || $4 != 0 {print $1, $3, $4}' "$work/results" - } > "$baseline" - echo "cts: $summary" - echo "cts: baseline written to $baseline ($(grep -cv '^#' "$baseline") namespaces)" - exit 0 -fi - -if [ ! -f "$baseline" ]; then - echo "cts: FAIL — no baseline; run JOLT_CTS_WRITE_BASELINE=1 host/chez/cts.sh" - exit 1 -fi - -status=0 -while read -r ns p f e; do - case "$p" in HUNG|CRASH) f="$p"; e="$p" ;; esac - bl=$(grep -v '^#' "$baseline" | awk -v n="$ns" '$1==n {print $2, $3; exit}') - if [ -n "$bl" ]; then bf="${bl%% *}"; be="${bl##* }"; else bf=0; be=0; fi - if [ "$f" = "$bf" ] && [ "$e" = "$be" ]; then - continue - elif [ "$f" = "HUNG" ] || [ "$f" = "CRASH" ] \ - || { [ "$bf" != "HUNG" ] && [ "$bf" != "CRASH" ] \ - && { [ "$f" -gt "$bf" ] || [ "$e" -gt "$be" ]; }; }; then - echo "cts: NEW regression in $ns — fail $f error $e (baseline $bf $be)" - status=1 - else - echo "cts: STALE baseline for $ns — now fail $f error $e (baseline $bf $be); update $baseline" - status=1 - fi -done < "$work/results" - -# a baseline entry whose namespace no longer reports is stale too -while read -r ns bf be; do - grep -q "^$ns " "$work/results" || { echo "cts: STALE baseline entry $ns (namespace gone)"; status=1; } -done < <(grep -v '^#' "$baseline") - -echo "cts: $summary" -if [ $status -eq 0 ]; then echo "cts: passed (matches baseline)"; else echo "cts: FAILED"; fi -exit $status diff --git a/host/chez/dce.ss b/host/chez/dce.ss index b7d9d06..19a6eef 100644 --- a/host/chez/dce.ss +++ b/host/chez/dce.ss @@ -90,10 +90,7 @@ ;; str re-serializes the read form (compiled identically; comments/whitespace are ;; irrelevant). (define (dce-blob-records path) - ;; bld-source-string (build.ss) reads the embedded copy when running from a - ;; self-contained joltc, else the file on disk — so tree-shake works with no - ;; jolt checkout present. Forward ref: build.ss loads after this file. - (call-with-port (open-input-string (bld-source-string path)) + (call-with-input-file path (lambda (p) (let loop ((acc '())) (let ((form (read p))) diff --git a/host/chez/java/dot-forms.ss b/host/chez/dot-forms.ss similarity index 63% rename from host/chez/java/dot-forms.ss rename to host/chez/dot-forms.ss index 8d7206b..553dea1 100644 --- a/host/chez/java/dot-forms.ss +++ b/host/chez/dot-forms.ss @@ -17,6 +17,8 @@ ;; A record (jrec) is jolt-map? here (records.ss makes it so) and a collection, ;; so its protocol method (no dash, not a coll method) lands in the base. +(define %dot-rmd record-method-dispatch) + ;; Vectors / maps / sets only (records are jolt-map? here). Raw seqs are excluded: ;; coll-interop accepts some seq representations and not others (a ;; plain (seq v) returns nil from .count, a lazy-seq returns the count), an @@ -36,17 +38,6 @@ ((or (string=? name "get") (string=? name "valAt")) (list (apply jolt-get obj args))) ((string=? name "containsKey") (list (jolt-contains? obj (car args)))) - ;; java.util.Collection.contains(o): VALUE membership (a set is O(1) via - ;; contains?; a list/vector/seq is a linear scan — contains? on a vector tests - ;; an index, so it is wrong here). - ((string=? name "contains") - (list (if (pset? obj) - (jolt-contains? obj (car args)) - (let ((x (car args))) - (let loop ((s (jolt-seq obj))) - (cond ((jolt-nil? s) #f) - ((jolt=2 (seq-first s) x) #t) - (else (loop (jolt-seq (seq-more s)))))))))) ((string=? name "size") (list (jolt-count obj))) ((string=? name "isEmpty") (list (jolt-empty? obj))) ;; java.util.Map views: keySet (a Set), values (a Collection), entrySet. @@ -60,12 +51,6 @@ ;; branch and is mis-read as a missing :iterator key (nil). Some libraries ;; (e.g. malli's -vmap) iterate a map this way. ((string=? name "iterator") (list (make-jiterator (jolt-seq obj)))) - ;; (.reduce coll f) / (.reduce coll f init): clojure.lang.IReduce — every - ;; persistent collection reduces itself on the JVM. - ((string=? name "reduce") - (list (if (pair? (cdr args)) - (jolt-reduce (car args) (cadr args) obj) - (jolt-reduce (car args) obj)))) (else #f))) ;; Universal object-methods: on a @@ -88,7 +73,7 @@ ((string=? name "equals") (list (if (jolt= obj (car args)) #t #f))) (else #f))) -(register-method-arm! 30 +(set! record-method-dispatch (lambda (obj method-name rest-args) (let* ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args))) (field? (and (> (string-length method-name) 0) @@ -97,45 +82,12 @@ (substring method-name 1 (string-length method-name)) method-name))) (cond - ;; clojure.lang.MultiFn .dispatchFn / .getMethod — clojure.spec.alpha's - ;; multi-spec walks a multimethod through these. - ((jolt-multifn? obj) - (cond - ((string=? mname "dispatchFn") (jolt-multifn-dispatch-fn obj)) - ((string=? mname "getMethod") - (let ((methods (jolt-multifn-methods obj)) (dv (car rest))) - (or (hashtable-ref methods dv #f) - (mm-find-isa obj dv) - (hashtable-ref methods (jolt-multifn-default obj) #f) - jolt-nil))) - (else 'pass))) - ;; (.applyTo f args): apply a fn to a seq of args (clojure.spec instrument). - ((and (procedure? obj) (string=? mname "applyTo")) - (apply jolt-invoke obj (seq->list (jolt-seq (car rest))))) - ;; a transient (ITransientCollection/Set/Map): .contains / .valAt / .count — - ;; test.check's distinct-collection gen uses (.contains transient-set k). - ((jolt-transient? obj) - (cond - ((string=? mname "contains") (if (jolt-truthy? (t-contains? obj (car rest))) #t #f)) - ((or (string=? mname "valAt") (string=? mname "get")) - (t-get obj (car rest) (if (null? (cdr rest)) jolt-nil (cadr rest)))) - ((string=? mname "count") (t-count obj)) - (else 'pass))) - ;; a deftype/record's OWN declared method (matched by name AND arity) wins - ;; over the generic collection interop below — e.g. data.priority-map - ;; declares both seq[this] (Seqable) and seq[this ascending] (Sorted), and - ;; (.seq pm false) must reach the 2-arg one, not dot-coll's plain seq. - ((and (not field?) (jrec? obj) - (find-method-any-protocol-arity (jrec-tag obj) mname (+ 1 (length rest)))) - => (lambda (f) (apply jolt-invoke f obj rest))) + ;; (.getClass x) universal — the class token for any value, before the + ;; collection/map field-lookup arms below would read it as a missing key. + ((string=? method-name "getClass") (jolt-class obj)) ;; collection interop first (entry count / seq / nth / get / containsKey). ((and (dot-coll? obj) (dot-coll-method obj mname rest)) => (lambda (box) (car box))) - ;; clojure.lang.Sorted (comparator / entryKey / seqFrom) on a sorted - ;; map/set, before the map arm below reads the method name as a key. - ;; data.priority-map's subseq/rsubseq reach for these. - ((and (not field?) (htable-sorted? obj) (sorted-iface-method? mname)) - (sorted-iface-dispatch obj mname rest)) ;; (.-field obj) / (. obj -field): field read on a record or map. (field? (jolt-get obj (keyword #f mname) jolt-nil)) ;; non-record map: a universal object-method (getMessage/...) wins first, @@ -146,4 +98,4 @@ (else (let ((v (jolt-get obj (keyword #f mname) jolt-nil))) (if (procedure? v) (apply jolt-invoke v obj rest) v))))) - (else 'pass))))) + (else (%dot-rmd obj method-name rest-args)))))) diff --git a/host/chez/dyn-binding.ss b/host/chez/dyn-binding.ss index dd2742d..5aad938 100644 --- a/host/chez/dyn-binding.ss +++ b/host/chez/dyn-binding.ss @@ -77,23 +77,14 @@ (let ((p (dyn-find-binding v))) (if p (begin (set-cdr! p val) val) - ;; a ROOT change is Var.bindRoot: validate, set, notify watches - ;; (a thread-binding set does not notify, like the JVM). - (let ((old (var-cell-root v))) - (iref-validate v val) - (var-cell-root-set! v val) (var-cell-defined?-set! v #t) - (iref-notify v old val) - val))) + (begin (var-cell-root-set! v val) (var-cell-defined?-set! v #t) val))) (error #f "var-set: not a var" v))) ;; alter-var-root: atomically apply f to the current root plus args. (define (jolt-alter-var-root v f . args) - (let* ((old (var-cell-root v)) - (new (apply jolt-invoke f old args))) - (iref-validate v new) + (let ((new (apply jolt-invoke f (var-cell-root v) args))) (var-cell-root-set! v new) (var-cell-defined?-set! v #t) - (iref-notify v old new) new)) ;; __local-var: a fresh free-standing var cell (not interned). with-local-vars @@ -126,16 +117,6 @@ ((eq? cell star-ns-cell) (intern-ns! (chez-current-ns))) (else (var-cell-root cell))))))) -;; var-deref's read on an ALREADY-RESOLVED cell — what compiled code emits when it -;; caches the cell at a reference site. Binding stack first, then *ns* thread-local, -;; else the raw root. Lenient on an unbound root (returns the sentinel), matching -;; var-deref — NOT the strict jolt-var-get, which throws "Unbound var". -(define (var-cell-deref cell) - (let ((bv (dyn-binding-value cell))) - (cond ((not (eq? bv dyn-no-binding)) bv) - ((eq? cell star-ns-cell) (intern-ns! (chez-current-ns))) - (else (var-cell-root cell))))) - ;; jolt-var-get (vars.ss): the var-get fn + deref/@ on a cell. Stack first, then ;; the original (which errors on an unbound root, matching Clojure). (define %dyn-var-get jolt-var-get) diff --git a/host/chez/dynamic-var-defaults.ss b/host/chez/dynamic-var-defaults.ss index 9520dfa..387e048 100644 --- a/host/chez/dynamic-var-defaults.ss +++ b/host/chez/dynamic-var-defaults.ss @@ -28,43 +28,3 @@ ;; *print-meta* — when true, pr prints metadata with a ^ prefix; default false. (def-var! "clojure.core" "*print-meta*" #f) - -;; *print-length* / *print-level* — collection print limits, honored by both -;; printers (rt.ss jolt-pr-str + printing.ss jolt-pr-readable). nil = unlimited -;; (the default); a number truncates elements / collapses depth to "#". -;; *print-length* limits a lazy/infinite seq before realizing it. -(def-var! "clojure.core" "*print-length*" jolt-nil) -(def-var! "clojure.core" "*print-level*" jolt-nil) -;; *default-data-reader-fn* — a (fn [tag value]) the reader consults for an -;; unregistered #tag before raising; nil = no default handler. -(def-var! "clojure.core" "*default-data-reader-fn*" jolt-nil) - -;; Portable clojure.core dynamic vars whose DEFAULT already matches jolt's -;; behaviour, so exposing them is sound (resolve/binding work, reads return the -;; right value) — not a silent divergence. -;; -;; *read-eval* — gates #=() read-eval. jolt's reader has no #=, so it reads true -;; (no eval-on-read happens regardless); a lib can (binding [*read-eval* false] …). -(def-var! "clojure.core" "*read-eval*" #t) -;; *print-dup* — gates print-dup (a multimethod that exists); default false. -(def-var! "clojure.core" "*print-dup*" #f) -;; *print-namespace-maps* — jolt never prints the #:ns{…} map shorthand, so the -;; var reads false (accurate); settable for code that toggles it. -(def-var! "clojure.core" "*print-namespace-maps*" #f) -;; *flush-on-newline* — jolt flushes line output; default true. -(def-var! "clojure.core" "*flush-on-newline*" #t) -;; *compile-files* — jolt has no separate compile phase that emits .class files. -(def-var! "clojure.core" "*compile-files*" #f) -;; *math-context* — BigDecimal rounding context; nil = unlimited, jolt's default. -(def-var! "clojure.core" "*math-context*" jolt-nil) -;; *command-line-args* — the args after the script/-main; nil outside a -m run. -(def-var! "clojure.core" "*command-line-args*" jolt-nil) -;; *file* — the source file being loaded; "NO_SOURCE_PATH" when none, like the JVM. -(def-var! "clojure.core" "*file*" "NO_SOURCE_PATH") - -;; REPL result/exception history. Bound by the REPL after each evaluation; nil -;; outside a REPL, which is what reading them returns here. -(def-var! "clojure.core" "*1" jolt-nil) -(def-var! "clojure.core" "*2" jolt-nil) -(def-var! "clojure.core" "*3" jolt-nil) -(def-var! "clojure.core" "*e" jolt-nil) diff --git a/host/chez/emit-image.ss b/host/chez/emit-image.ss index a2489cc..adb6329 100644 --- a/host/chez/emit-image.ss +++ b/host/chez/emit-image.ss @@ -41,15 +41,6 @@ ;; top-level entry: in direct-link mode it binds jv$ for a top-level def; off ;; that mode (the minter, runtime eval) it is exactly emit, so output is unchanged. (define jolt-ce-emit-top (var-deref "jolt.backend-scheme" "emit-top-form")) -;; Seed mint and AOT build must stay byte-deterministic, so emit the image with var -;; cell-caching OFF (compile-eval.ss turned it on for runtime eval; this file loads -;; after it). Guarded for the first re-mint pass off an older seed. -(let ((scv (var-deref "jolt.backend-scheme" "set-var-cache!"))) - (when (procedure? scv) (scv #f))) -;; Tail-frame tracing off for the mint + `jolt build`: the seed must stay a -;; byte-fixpoint, and a built app should carry no per-call trace overhead. -(let ((stf (var-deref "jolt.backend-scheme" "set-trace-frames!"))) - (when (procedure? stf) (stf #f))) (define (ei-compile-form ctx f optimize?) (let ((ir (jolt-ce-analyze ctx f))) (jolt-ce-emit-top (if optimize? (jolt-ce-run-passes ir ctx) ir)))) @@ -67,23 +58,15 @@ ;; the seed minter (ei-emit-ns: optimize? #f, guard? #t — tolerant, skips a form ;; that fails to emit) and `jolt build` (bld-emit-ns: optimize? #t, guard? #f — ;; strict, a failing form errors the build). -;; A per-form transform applied to each read form before emit — the build sets it -;; to the data-reader rewrite (loader.ss ldr-apply-readers) so a registered #tag -;; literal compiles in a `jolt build` the same as it does in an interpreted load. -;; #f (the default, and during the seed mint where loader.ss isn't loaded) is no -;; transform, so emit-image.ss carries no loader dependency. -(define ei-emit-form-hook (make-parameter #f)) - (define (ei-emit-ns* ns-name src optimize? guard?) ;; set the ns before reading so ::kw auto-resolves against this ns (the runtime ;; loader reads form-by-form after the ns form sets it; the cross-compile reads ;; all forms up front, so set it here). (set-chez-ns! ns-name) - (let ((hook (ei-emit-form-hook))) - (let loop ((forms (ei-read-all src)) (acc '())) + (let loop ((forms (ei-read-all src)) (acc '())) (if (null? forms) (reverse acc) - (let ((f (let ((f0 (car forms))) (if hook (hook f0) f0)))) + (let ((f (car forms))) (ce-scan-requires! f ns-name) (cond ((ei-ns-form? f) (loop (cdr forms) acc)) @@ -101,7 +84,7 @@ (ei-compile-form (make-analyze-ctx ns-name) f optimize?)))) (loop (cdr forms) (if (and guard? (not scm)) acc - (cons (if guard? (string-append "(guard (e (#t #f))\n " scm ")") scm) acc))))))))))) + (cons (if guard? (string-append "(guard (e (#t #f))\n " scm ")") scm) acc)))))))))) (define (ei-emit-ns ns-name src) (ei-emit-ns* ns-name src #f #t)) diff --git a/host/chez/java/ffi.ss b/host/chez/ffi.ss similarity index 100% rename from host/chez/java/ffi.ss rename to host/chez/ffi.ss diff --git a/host/chez/java/host-class.ss b/host/chez/host-class.ss similarity index 63% rename from host/chez/java/host-class.ss rename to host/chez/host-class.ss index 10d8940..7a25f52 100644 --- a/host/chez/java/host-class.ss +++ b/host/chez/host-class.ss @@ -35,56 +35,15 @@ ((jolt-atom? x) "clojure.lang.Atom") ((char? x) "java.lang.Character") ((regex-t? x) "java.util.regex.Pattern") - ;; an anonymous / unregistered fn — like the JVM, where (class #(..)) is a - ;; concrete ns$fn__N subclass. The $fn marker lets clojure.spec.alpha's fn-sym - ;; recognize it as anonymous and return ::s/unknown. A named fn is registered - ;; (proc-name-tbl) and handled by a class-arm with its real ns$name. - ((procedure? x) "clojure.lang.AFunction$fn") + ((procedure? x) "clojure.lang.IFn") ;; an exception value (ex-info / host-constructed throwable) reports its JVM ;; class, so (= clojure.lang.ExceptionInfo (class e)) and clojure.test's ;; (thrown? Class …) match (records.ss ex-info-map?/ex-info-class). ((ex-info-map? x) (ex-info-class x)) - ;; persistent collections + namespace report their JVM class names (not jolt's - ;; internal :vector/:set/… type keyword), so class-based dispatch — e.g. a - ;; defmulti on [(class a) (class b)] — sees a real clojure.lang.* class. - ((jns? x) "clojure.lang.Namespace") - ((pvec? x) "clojure.lang.PersistentVector") - ((pset? x) "clojure.lang.PersistentHashSet") - ((pmap? x) "clojure.lang.PersistentArrayMap") - ((jolt-lazyseq? x) "clojure.lang.LazySeq") - ((empty-list-t? x) "clojure.lang.PersistentList$EmptyList") - ((cseq? x) "clojure.lang.PersistentList") (else (jolt-str-render-one (jolt-type x))))) ;; the class NAME of x (string), or nil for nil. (class x) wraps it in a Class ;; value (make-class-obj, host-static-classes.ss) so it renders like a JVM Class ;; while staying = its name string. -;; a raw Chez condition Clojure raises a specific class for (records-interop.ss -;; chez-condition-exc-class) reports that JVM class, so (class e) and a -;; (thrown? ArityException …) test match — not the opaque :object fallback. -(register-class-arm! - (lambda (x) (and (chez-condition-exc-class x) #t)) - (lambda (x) (let ((p (assoc (chez-condition-exc-class x) class-token-alist))) - (if p (cdr p) "java.lang.IllegalArgumentException")))) -;; A fn def'd into a var reports a JVM-style class name "ns$munged-name" (the -;; forward CHAR_MAP), so clojure.spec.alpha's fn-sym (which splits on $ and -;; demunges) recovers the predicate's symbol. Anonymous / unregistered fns stay -;; clojure.lang.IFn (fn-sym yields :unknown, as on the JVM). -(define class-munge-map - '((#\? . "_QMARK_") (#\! . "_BANG_") (#\* . "_STAR_") (#\+ . "_PLUS_") - (#\> . "_GT_") (#\< . "_LT_") (#\= . "_EQ_") (#\/ . "_SLASH_") (#\- . "_") - (#\& . "_AMPERSAND_") (#\% . "_PERCENT_") (#\~ . "_TILDE_") (#\^ . "_CARET_") - (#\| . "_BAR_") (#\: . "_COLON_"))) -(define (class-munge-name s) - (let ((out (open-output-string))) - (string-for-each - (lambda (c) (let ((t (assv c class-munge-map))) (if t (display (cdr t) out) (write-char c out)))) - s) - (get-output-string out))) -(register-class-arm! - (lambda (x) (and (procedure? x) (hashtable-ref proc-name-tbl x #f))) - (lambda (x) (let ((p (hashtable-ref proc-name-tbl x #f))) - (string-append (car p) "$" (class-munge-name (cdr p)))))) - (define (jolt-class-name x) (let loop ((as jolt-class-arms)) (cond ((null? as) (jolt-class-base x)) @@ -96,25 +55,11 @@ (def-var! "clojure.core" "class" jolt-class) -;; The PUBLIC clojure.core/type — Clojure's (or (:type meta) (class x)). This is the -;; java host layer's job: the core taxonomy (natives-meta.ss jolt-type, kept under -;; __type-tag for print-method) is JVM-free, and the JVM class mapping lives HERE, -;; next to (class …). The inst/array/byte-buffer host files extend `class` (a -;; class-arm or jolt-type fallthrough) and re-point `type` at this same fn, so the -;; remap of every value — :jolt/inst -> java.util.Date etc. — happens in one place. -(define ty-meta-key (keyword #f "type")) -(define (jolt-type-pub x) - (let* ((m (jolt-meta x)) - (override (if (jolt-nil? m) jolt-nil (jolt-get m ty-meta-key jolt-nil)))) - (if (not (jolt-nil? override)) override (jolt-class x)))) -(def-var! "clojure.core" "type" jolt-type-pub) - ;; bare class-name tokens -> canonical JVM class-name strings. (define class-token-alist '(("String" . "java.lang.String") ("Number" . "java.lang.Number") ("Boolean" . "java.lang.Boolean") ("Long" . "java.lang.Long") ("Integer" . "java.lang.Integer") ("Double" . "java.lang.Double") - ("Float" . "java.lang.Float") ("Byte" . "java.lang.Byte") ("Short" . "java.lang.Short") ("Object" . "java.lang.Object") ("Character" . "java.lang.Character") ("InputStream" . "java.io.InputStream") ("OutputStream" . "java.io.OutputStream") ("File" . "java.io.File") ("Reader" . "java.io.Reader") ("Writer" . "java.io.Writer") @@ -126,7 +71,6 @@ ("Charset" . "java.nio.charset.Charset") ("Base64" . "java.util.Base64") ("Exception" . "java.lang.Exception") ("IllegalArgumentException" . "java.lang.IllegalArgumentException") - ("ArityException" . "clojure.lang.ArityException") ("IllegalStateException" . "java.lang.IllegalStateException") ("RuntimeException" . "java.lang.RuntimeException") ("UnsupportedOperationException" . "java.lang.UnsupportedOperationException") @@ -149,20 +93,7 @@ ("IndexOutOfBoundsException" . "java.lang.IndexOutOfBoundsException") ("UnsupportedEncodingException" . "java.io.UnsupportedEncodingException") ("FileNotFoundException" . "java.io.FileNotFoundException") - ("Throwable" . "java.lang.Throwable") - ;; clojure.lang / java.util types that class-based multimethods dispatch on. - ("Fn" . "clojure.lang.Fn") ("IFn" . "clojure.lang.IFn") - ("Namespace" . "clojure.lang.Namespace") ("Named" . "clojure.lang.Named") - ("Set" . "java.util.Set") ("List" . "java.util.List") ("Map" . "java.util.Map") - ("Collection" . "java.util.Collection") ("Iterable" . "java.lang.Iterable") - ("CharSequence" . "java.lang.CharSequence") ("Comparable" . "java.lang.Comparable") - ("Runnable" . "java.lang.Runnable") ("Callable" . "java.util.concurrent.Callable") - ("IPersistentSet" . "clojure.lang.IPersistentSet") - ("IPersistentVector" . "clojure.lang.IPersistentVector") - ("IPersistentMap" . "clojure.lang.IPersistentMap") - ("IPersistentCollection" . "clojure.lang.IPersistentCollection") - ("Sequential" . "clojure.lang.Sequential") ("Seqable" . "clojure.lang.Seqable") - ("Associative" . "clojure.lang.Associative"))) + ("Throwable" . "java.lang.Throwable"))) (for-each (lambda (pair) (def-var! "clojure.core" (car pair) (cdr pair))) class-token-alist) @@ -184,7 +115,6 @@ (for-each (lambda (nm) (def-var! "clojure.core" nm nm)) '("java.lang.Long" "java.lang.Integer" "java.lang.Double" "java.lang.Float" - "java.lang.Byte" "java.lang.Short" "java.lang.Number" "java.lang.String" "java.lang.Boolean" "java.lang.Character" "java.lang.Object" ;; exception classes compared against (class e): (= java.net.SocketTimeoutException (class e)) @@ -199,7 +129,7 @@ "java.lang.IndexOutOfBoundsException" "java.io.FileNotFoundException" "java.io.UnsupportedEncodingException" ;; clojure.lang.ExceptionInfo / IExceptionInfo compared against (class e) - "clojure.lang.ExceptionInfo" "clojure.lang.IExceptionInfo" "clojure.lang.ArityException" + "clojure.lang.ExceptionInfo" "clojure.lang.IExceptionInfo" "java.util.regex.Pattern" "java.net.URI" "java.util.UUID" "clojure.lang.PersistentQueue" "clojure.lang.Keyword" "clojure.lang.Symbol" "clojure.lang.Ratio" "clojure.lang.Atom")) diff --git a/host/chez/host-contract.ss b/host/chez/host-contract.ss index 9593a0e..7c850f7 100644 --- a/host/chez/host-contract.ss +++ b/host/chez/host-contract.ss @@ -46,9 +46,7 @@ ;; ANY non-empty seq is a list form for analysis (a macro/eval form built via ;; concat/map/cons is a lazy cseq with list?=#f, but evaluating it still means ;; calling its head) — not just reader-built lists. -;; a lazy seq is a list form too: a macro that builds its expansion with map/for -;; (now a LazySeq, not an eager cseq) and splices it must still analyze. -(define (hc-list? x) (or (empty-list-t? x) (cseq? x) (jolt-lazyseq? x))) +(define (hc-list? x) (or (empty-list-t? x) (cseq? x))) (define (hc-vec? x) (pvec? x)) (define (hc-map? x) (and (pmap? x) (jolt-nil? (jolt-get x hc-kw-jolt-type)))) ;; A set form is the reader's tagged map {:jolt/type :jolt/set :value } OR a @@ -76,17 +74,6 @@ ;; reconstruct it by name at the call site. (define (hc-ns-value? x) (jns? x)) (define (hc-ns-value-name x) (jns-name x)) -;; a live Var value spliced into a form (a macro that does `(~v …)` with v a -;; resolved var) — the analyzer turns it into a :the-var reference by ns+name. -(define (hc-var-value? x) (var-cell? x)) -(define (hc-var-value-ns x) (var-cell-ns x)) -(define (hc-var-value-name x) (var-cell-name x)) - -;; *unchecked-math* read at compile time: when truthy (a file's (set! -;; *unchecked-math* …)), the analyzer rewrites +/-/*/inc/dec to their wrapping -;; unchecked-* forms for the rest of that file, like the JVM. -(define (hc-unchecked-math?) - (jolt-truthy? (guard (e (#t #f)) (var-deref "clojure.core" "*unchecked-math*")))) ;; --- form accessors --------------------------------------------------------- (define (hc-char-code x) (char->integer x)) ; native Chez char -> codepoint @@ -108,7 +95,7 @@ ;; list items -> jolt vector (pvec); the analyzer mapv's over the result. (define (hc-elements x) (cond ((empty-list-t? x) empty-pvec) - ((or (cseq? x) (jolt-lazyseq? x)) (make-pvec (list->vector (seq->list x)))) + ((cseq? x) (make-pvec (list->vector (seq->list x)))) (else empty-pvec))) (define (hc-vec-items x) x) ; already a pvec (define (hc-set-items x) @@ -132,22 +119,8 @@ (define (hc-inst-source x) (jolt-get x hc-kw-form)) (define (hc-uuid-source x) (jolt-get x hc-kw-form)) -;; Source position for a list form: the reader stamps :line/:column (+ :file when -;; compiling a file) into the form's metadata. Return a clean {:line :column -;; :file?} map, or nil for a synthetic/macro-built form that carries none. -(define hc-kw-line (keyword #f "line")) -(define hc-kw-column (keyword #f "column")) -(define hc-kw-file (keyword #f "file")) -(define (hc-form-position x) - (let ((m (jolt-meta x))) - (if (and (pmap? m) (not (jolt-nil? (jolt-get m hc-kw-line)))) - (let ((line (jolt-get m hc-kw-line)) - (col (jolt-get m hc-kw-column)) - (file (jolt-get m hc-kw-file))) - (if (jolt-nil? file) - (jolt-hash-map hc-kw-line line hc-kw-column col) - (jolt-hash-map hc-kw-line line hc-kw-column col hc-kw-file file))) - jolt-nil))) +;; The Chez reader does not record source offsets yet. +(define (hc-form-position x) jolt-nil) ;; --- special forms ---------------------------------------------------------- ;; Mirrors host_iface special-names + interop-head? — forms the analyzer marks @@ -184,12 +157,7 @@ ;; a qualified ns may be a require :as alias (s/split -> clojure.string/split) (let ((target (or (chez-resolve-alias (chez-actx-cns ctx) qualified) qualified))) (var-cell-lookup target nm)) - (or (let ((c (var-cell-lookup (chez-actx-cns ctx) nm))) - ;; an undefined forward-intern must not shadow a real referred - ;; or clojure.core var — e.g. the compiler ns referencing `set`, - ;; which late-binds (interns `jolt.backend-scheme/set` undefined) - ;; and would otherwise hide clojure.core/set on the mint fixpoint. - (and c (var-cell-defined? c) c)) + (or (var-cell-lookup (chez-actx-cns ctx) nm) ;; a :refer'd name resolves to its source ns (let ((ref (chez-resolve-refer (chez-actx-cns ctx) nm))) (and ref (var-cell-lookup ref nm))) @@ -202,54 +170,12 @@ ;; of the list), and the analyzer re-analyzes the returned form. (define (hc-macro? ctx sym) (macro-var? (hc-resolve-cell ctx sym))) -;; Clojure parity: a macro expansion inherits the call form's source position, so -;; errors/traces in macro-generated code point at the macro call site. Carry it -;; onto the top of a LIST expansion (code) that has none of its own — merged under -;; any meta the macro set, leaving collection literals (runtime data) alone. The -;; recursion through analyze re-expands inner macros, so each level's top form -;; picks up the position the same way (as the reference compiler does). -(define (hc-propagate-pos src dst) - (if (and (cseq? dst) (cseq-list? dst)) - (let ((sp (hc-form-position src)) - (dm (jolt-meta dst))) - (if (and (pmap? sp) - (or (jolt-nil? dm) (jolt-nil? (jolt-get dm hc-kw-line)))) - (jolt-with-meta dst - (if (pmap? dm) - (pmap-fold-fwd sp (lambda (k v acc) (jolt-assoc1 acc k v)) dm) - sp)) - dst)) - dst)) - -;; A set literal reads as the tagged set-form {:jolt/type :jolt/set :value [...]} -;; for the analyzer, but a macro must see a real set value (Clojure parity, so -;; (set? arg) / seq / conj work — hiccup's compiler does this). Convert a set-form -;; argument to a set; elements stay as read (a deeply-nested set literal inside -;; another form is rarer and left for the analyzer). -(define (hc-macro-arg x) - (if (rdr-set-form? x) - (let ((items (jolt-get x rdr-kw-value))) - (let loop ((i 0) (s empty-pset)) - (if (fx>=? i (pvec-count items)) s - (loop (fx+ i 1) (pset-conj s (pvec-nth-d items i jolt-nil)))))) - x)) -;; &form and &env are bound (as dynamic vars) around the expander call, so a -;; macro body can read the call form / lexical env without changing the calling -;; convention. The analyzer passes amp-env (the in-scope locals); macroexpand-1 -;; has none, so it defaults to {}. -(define hc-amp-form-cell (declare-var! "clojure.core" "&form")) -(define hc-amp-env-cell (declare-var! "clojure.core" "&env")) -(define (hc-expand-1 ctx form . maybe-env) +(define (hc-expand-1 ctx form) (let* ((items (seq->list form)) (head (car items)) - (args (map hc-macro-arg (cdr items))) - (expander (var-cell-root (hc-resolve-cell ctx head))) - (amp-env (if (pair? maybe-env) (car maybe-env) (jolt-hash-map)))) - (dynamic-wind - (lambda () (jolt-push-thread-bindings - (jolt-hash-map hc-amp-form-cell form hc-amp-env-cell amp-env))) - (lambda () (hc-propagate-pos form (apply jolt-invoke expander args))) - (lambda () (jolt-pop-thread-bindings))))) + (args (cdr items)) + (expander (var-cell-root (hc-resolve-cell ctx head)))) + (apply jolt-invoke expander args))) ;; Classify a global (non-local) symbol reference against the var registry: ;; {:kind :var :ns NS :name NAME} — a defined var (compile ns / clojure.core) @@ -327,15 +253,10 @@ ;; Any seq counts, not just a proper list: a macro that builds the template with ;; map/for (e.g. deftype's rewrite-set) yields a LAZY seq, and its ~unquotes must ;; still be recognized. -;; head symbol matches name nm, bare or clojure.core-qualified — the reader -;; produces clojure.core/unquote(-splicing) for ~/~@ (JVM parity), and this is -;; only used to spot those heads in syntax-quote templates. (define (hc-head-is? x nm) (and (cseq? x) (let ((h (seq-first x))) - (and (symbol-t? h) (string=? (symbol-t-name h) nm) - (let ((ns (hc-sym-ns h))) - (or (jolt-nil? ns) (and (string? ns) (string=? ns "clojure.core")))))))) + (and (symbol-t? h) (jolt-nil? (hc-sym-ns h)) (string=? (symbol-t-name h) nm))))) (define (hc-second x) (seq-first (jolt-seq (seq-more x)))) (define (hc-sq-symbol ctx form gsmap) @@ -354,16 +275,6 @@ ;; a class token, not a var to namespace-qualify — leave it bare, as ;; Clojure's syntax-quote resolves it to the class. ((hc-fq-class-name? nm) form) - ;; the compile ns's OWN def shadows clojure.core — a name the ns - ;; excluded and redefined (e.g. core.logic's `==` after - ;; (:refer-clojure :exclude [==])), or any ns-local redefinition. - ;; Referred names live in a separate table, so this only hits a real - ;; local intern, matching how the analyzer resolves the bare symbol. - ((var-cell-lookup (chez-actx-cns ctx) nm) (jolt-symbol (chez-actx-cns ctx) nm)) - ;; a name the compile ns excluded from clojure.core (:refer-clojure - ;; :exclude) is not clojure.core/nm even before the ns defines its own — - ;; qualify to the compile ns, like Clojure (core.logic.fd's `==`). - ((chez-core-excluded? (chez-actx-cns ctx) nm) (jolt-symbol (chez-actx-cns ctx) nm)) ((var-cell-lookup "clojure.core" nm) (jolt-symbol "clojure.core" nm)) ;; a name referred into the compile ns (:require :refer / :use :only) ;; qualifies to its SOURCE ns, not the compile ns — so a macro that @@ -417,36 +328,9 @@ (define (hc-syntax-quote-lower ctx inner) (hc-sq-lower ctx inner (make-hashtable string-hash string=?))) -;; a ^Type param hint: name is the tag (a symbol, sometimes a string). Resolve it -;; against the record registry (records.ss) so the inference seeds the param as -;; that record — the open-world / cross-ns path where no caller type is inferred. -(define (hc-record-tag-name name) - (cond ((symbol-t? name) (symbol-t-name name)) - ((string? name) name) - (else #f))) -(define (hc-record-type? ctx name) - (let ((nm (hc-record-tag-name name))) - (if (and nm (chez-find-ctor-key nm (chez-current-ns))) #t #f))) -(define (hc-record-ctor-key ctx name) - (let ((nm (hc-record-tag-name name))) - (or (and nm (chez-find-ctor-key nm (chez-current-ns))) jolt-nil))) -;; The fully-qualified deftype tag ("ns.Name") IFF `class` names a deftype DEFINED -;; in the ctx's compile ns — the analyzer qualifies a bare (Name. …) to it, so a -;; deftype doesn't shadow a same-named built-in host class in an unrelated ns -;; (rewrite-clj imports java.io.PushbackReader; tools.reader defines its own). Strict: -;; only this ns's own def (the preferred shape key) counts, not the global -;; simple-name fallback, so a ns that merely uses the built-in resolves nil. -(define (hc-deftype-ctor-class ctx class) - (let* ((nm (jolt-str-render-one class)) - (cns (hc-current-ns ctx)) - (key (string-append cns "/->" nm))) - (if (hashtable-ref chez-record-shapes-tbl key #f) - (string-append cns "." nm) - jolt-nil))) -;; record + protocol-method shapes for the inference, from the runtime registries -;; (records.ss) populated as deftype/defprotocol forms load. -(define (hc-record-shapes ctx) (chez-record-shapes-map)) -(define (hc-protocol-methods ctx) (chez-protocol-methods-map)) +(define (hc-record-type? ctx name) #f) +(define (hc-record-ctor-key ctx name) jolt-nil) +(define (hc-record-shapes ctx) (jolt-hash-map)) ;; Optimization gate. Off for ordinary runs (open world, redefinition); `jolt ;; build` flips it on during app emission for release/optimized modes (closed ;; world), turning on the inference + flatten + scalar-replace passes. @@ -494,10 +378,6 @@ (def-var! "jolt.host" "form-uuid?" hc-uuid?) (def-var! "jolt.host" "form-ns-value?" hc-ns-value?) (def-var! "jolt.host" "form-ns-value-name" hc-ns-value-name) - (def-var! "jolt.host" "form-var-value?" hc-var-value?) - (def-var! "jolt.host" "form-var-value-ns" hc-var-value-ns) - (def-var! "jolt.host" "form-var-value-name" hc-var-value-name) - (def-var! "jolt.host" "unchecked-math?" hc-unchecked-math?) (def-var! "jolt.host" "form-bigdec?" hc-bigdec?) (def-var! "jolt.host" "form-bigdec-source" hc-bigdec-source) (def-var! "jolt.host" "form-elements" hc-elements) @@ -518,9 +398,7 @@ (def-var! "jolt.host" "form-syntax-quote-lower" hc-syntax-quote-lower) (def-var! "jolt.host" "record-type?" hc-record-type?) (def-var! "jolt.host" "record-ctor-key" hc-record-ctor-key) - (def-var! "jolt.host" "deftype-ctor-class" hc-deftype-ctor-class) (def-var! "jolt.host" "record-shapes" hc-record-shapes) - (def-var! "jolt.host" "protocol-methods" hc-protocol-methods) (def-var! "jolt.host" "inline-enabled?" hc-inline-enabled?) (def-var! "jolt.host" "inline-ir" hc-inline-ir) (def-var! "jolt.host" "stash-inline!" hc-stash-inline!)) diff --git a/host/chez/java/host-static-classes.ss b/host/chez/host-static-classes.ss similarity index 63% rename from host/chez/java/host-static-classes.ss rename to host/chez/host-static-classes.ss index a5730d5..4856bd6 100644 --- a/host/chez/java/host-static-classes.ss +++ b/host/chez/host-static-classes.ss @@ -50,7 +50,7 @@ (cond ((null? args) (make-arraylist '())) ((number? (car args)) (make-arraylist '())) (else (make-arraylist (seq->list (jolt-seq (car args)))))))) -(define arraylist-methods +(register-host-methods! "arraylist" (list (cons "add" (lambda (self . a) ;; (.add x) -> append+true; (.add i x) -> insert at i, returns nil. @@ -58,14 +58,6 @@ (begin (al-push! self (car a)) #t) (begin (al-insert-at! self (jnum->exact (car a)) (cadr a)) jolt-nil)))) (cons "add!" (lambda (self x) (al-push! self x) #t)) - (cons "addAll" (lambda (self . a) - ;; (.addAll coll) appends; (.addAll i coll) inserts at i. - (let* ((at-i (= 2 (length a))) - (i (if at-i (jnum->exact (car a)) (al-cnt self))) - (coll (if at-i (cadr a) (car a)))) - (let loop ((xs (seq->list (jolt-seq coll))) (k i)) - (if (null? xs) (pair? (seq->list (jolt-seq coll))) - (begin (al-insert-at! self k (car xs)) (loop (cdr xs) (fx+ k 1)))))))) (cons "get" (lambda (self i) (vector-ref (al-vec self) (jnum->exact i)))) (cons "set" (lambda (self i x) (let* ((idx (jnum->exact i)) (old (vector-ref (al-vec self) idx))) @@ -80,43 +72,6 @@ (cons "toArray" (lambda (self . _) (apply jolt-vector (al->list self)))) (cons "iterator" (lambda (self) (make-jiterator (list->cseq (al->list self))))) (cons "toString" (lambda (self) (jolt-pr-str (list->cseq (al->list self))))))) -(register-host-methods! "arraylist" arraylist-methods) - -;; java.util.LinkedList: the ArrayList backing plus the Deque surface -;; (addFirst/addLast/removeFirst/removeLast/getFirst/getLast/peek/push/pop). -;; tools.reader holds pending splice forms in one and (seq)s / .remove(0)s it. -(define (al-first self) (vector-ref (al-vec self) 0)) -(define (al-last self) (vector-ref (al-vec self) (fx- (al-cnt self) 1))) -(define linkedlist-methods - (append arraylist-methods - (list - (cons "addFirst" (lambda (self x) (al-insert-at! self 0 x) jolt-nil)) - (cons "addLast" (lambda (self x) (al-push! self x) jolt-nil)) - (cons "offer" (lambda (self x) (al-push! self x) #t)) - (cons "removeFirst" (lambda (self) (let ((o (al-first self))) (al-remove-at! self 0) o))) - (cons "removeLast" (lambda (self) (let ((o (al-last self))) (al-remove-at! self (fx- (al-cnt self) 1)) o))) - (cons "getFirst" al-first) (cons "getLast" al-last) - (cons "peek" (lambda (self) (if (fx=? 0 (al-cnt self)) jolt-nil (al-first self)))) - (cons "poll" (lambda (self) (if (fx=? 0 (al-cnt self)) jolt-nil (let ((o (al-first self))) (al-remove-at! self 0) o)))) - (cons "push" (lambda (self x) (al-insert-at! self 0 x) jolt-nil)) - (cons "pop" (lambda (self) (let ((o (al-first self))) (al-remove-at! self 0) o)))))) -(define (make-linkedlist xs) - (let ((al (make-arraylist xs))) (make-jhost "linkedlist" (jhost-state al)))) -(register-host-methods! "linkedlist" linkedlist-methods) -(let ((ctor (lambda args - (cond ((null? args) (make-linkedlist '())) - (else (make-linkedlist (seq->list (jolt-seq (car args))))))))) - (register-class-ctor! "LinkedList" ctor) - (register-class-ctor! "java.util.LinkedList" ctor)) - -;; ArrayList / LinkedList are Iterable: (seq al) walks the elements (nil if empty), -;; so (seq pending-forms) and reduce/into over one work like the JVM. -(define %al-seq jolt-seq) -(set! jolt-seq - (lambda (x) - (if (and (jhost? x) (or (string=? (jhost-tag x) "arraylist") (string=? (jhost-tag x) "linkedlist"))) - (list->cseq (al->list x)) - (%al-seq x)))) ;; Appendable.append text: append(x) renders x; append(csq,start,end) appends the ;; subsequence csq[start,end) (data.json's writer appends string runs this way). @@ -154,9 +109,6 @@ (cons "flush" (lambda (self) jolt-nil)) (cons "close" (lambda (self) jolt-nil)) (cons "toString" (lambda (self) (sb-str self))))) -;; (str sw) / print a StringWriter -> its accumulated content, like the JVM -;; (str calls toString) — data.csv writes CSV to a StringWriter and reads it back. -(register-str-render! (lambda (x) (and (jhost? x) (string=? (jhost-tag x) "writer"))) sb-str) ;; a file-backed writer (clojure.java.io/writer of a File/path): accumulates like ;; StringWriter, then persists to the path on flush/close, so @@ -176,26 +128,14 @@ ;; push to the port (so (.write *out* s) and (binding [*out* *err*] …) work); ;; it isn't a buffer, so toString is empty. Lets libraries that touch *out*/*err* ;; (tools.logging, selmer) compile and run. -;; *out*/*err* resolve their port LIVE — 'out -> (current-output-port), 'err -> -;; (current-error-port) — so a (.write *out* …) / (.flush *out*) follows a -;; with-out-str redirect (with-output-to-string rebinds current-output-port) the -;; same way print/__write do. Storing the startup port instead pinned *out* to the -;; real stdout, so rewrite-clj's (z/print) — which writes via *out* — escaped the -;; capture. A stored port object (should any other code make a port-writer) is used -;; as-is. -(define (port-writer-port self) - (let ((p (vector-ref (jhost-state self) 0))) - (cond ((eq? p 'out) (current-output-port)) - ((eq? p 'err) (current-error-port)) - (else p)))) (register-host-methods! "port-writer" - (list (cons "write" (lambda (self x) (display (writer-piece x) (port-writer-port self)) jolt-nil)) - (cons "append" (lambda (self x . rest) (display (append-text x rest) (port-writer-port self)) self)) - (cons "flush" (lambda (self) (flush-output-port (port-writer-port self)) jolt-nil)) + (list (cons "write" (lambda (self x) (display (writer-piece x) (vector-ref (jhost-state self) 0)) jolt-nil)) + (cons "append" (lambda (self x . rest) (display (append-text x rest) (vector-ref (jhost-state self) 0)) self)) + (cons "flush" (lambda (self) (flush-output-port (vector-ref (jhost-state self) 0)) jolt-nil)) (cons "close" (lambda (self) jolt-nil)) (cons "toString" (lambda (self) "")))) -(def-var! "clojure.core" "*out*" (make-jhost "port-writer" (vector 'out))) -(def-var! "clojure.core" "*err*" (make-jhost "port-writer" (vector 'err))) +(def-var! "clojure.core" "*out*" (make-jhost "port-writer" (vector (current-output-port)))) +(def-var! "clojure.core" "*err*" (make-jhost "port-writer" (vector (current-error-port)))) ;; PrintWriter — a thin wrapper over a target writer. write/append/print forward ;; the rendered text to the target. clojure.data.json's pretty printer builds @@ -387,11 +327,6 @@ ;; state: a vector #(wrapped-reader pushed-list) (register-class-ctor! "PushbackReader" (lambda (rdr . _) (make-jhost "pushback-reader" (vector rdr '())))) -;; Fully-qualified aliases so (java.io.PushbackReader. …) / (java.io.StringReader. …) -;; resolve to these built-ins even when a library defines a deftype of the same -;; simple name (tools.reader), which would otherwise take the bare-name slot. -(register-class-ctor! "java.io.PushbackReader" (lookup-class class-ctors-tbl "PushbackReader")) -(register-class-ctor! "java.io.StringReader" (lookup-class class-ctors-tbl "StringReader")) ;; LineNumberingPushbackReader: a pushback-reader (jolt doesn't track line ;; numbers; getLineNumber is a stub for error-reporting paths that read it). (register-class-ctor! "LineNumberingPushbackReader" @@ -455,15 +390,7 @@ (let ((toks (vector-ref (jhost-state self) 0)) (p (vector-ref (jhost-state self) 1))) (if (< p (length toks)) (begin (vector-set! (jhost-state self) 1 (+ p 1)) (list-ref toks p)) - (jolt-throw (jolt-host-throwable "java.util.NoSuchElementException" "no more tokens")))))) - ;; StringTokenizer implements java.util.Enumeration — enumeration-seq drives - ;; it through these, so alias them onto the token methods. - (cons "hasMoreElements" (lambda (self) (< (vector-ref (jhost-state self) 1) (length (vector-ref (jhost-state self) 0))))) - (cons "nextElement" (lambda (self) - (let ((toks (vector-ref (jhost-state self) 0)) (p (vector-ref (jhost-state self) 1))) - (if (< p (length toks)) - (begin (vector-set! (jhost-state self) 1 (+ p 1)) (list-ref toks p)) - (jolt-throw (jolt-host-throwable "java.util.NoSuchElementException" "no more tokens")))))))) + (error #f "NoSuchElementException"))))))) ;; ---- String / BigInteger / MapEntry constructors ---------------------------- ;; (String. bytes [charset]) decodes bytes (a bytevector OR a jolt byte-array) @@ -506,12 +433,8 @@ (list->string (vector->list v))))) ((string? x) x) (else (jolt-str-render-one x))))) -;; (BigInteger. s) | (BigInteger. s radix) — parse a string in the given radix -;; (default 10). tools.reader's integer parser builds (BigInteger. digits radix). (register-class-ctor! "BigInteger" - (lambda (v . r) (parse-int-or-throw v (if (null? r) 10 (jnum->exact (car r))) "BigInteger"))) -(register-class-ctor! "java.math.BigInteger" - (lambda (v . r) (parse-int-or-throw v (if (null? r) 10 (jnum->exact (car r))) "BigInteger"))) + (lambda (v) (parse-int-or-throw v 10 "BigInteger"))) (register-class-ctor! "MapEntry" (lambda (k v) (make-map-entry k v))) ;; JVM exception ctors -> a typed host throwable carrying the canonical :jolt/class ;; (so class / instance? / getMessage / ex-message reflect the real type) and the @@ -533,8 +456,7 @@ '("Throwable" "Exception" "RuntimeException" "IllegalArgumentException" "IllegalStateException" "InterruptedException" "UnsupportedOperationException" "IOException" "NumberFormatException" "ArithmeticException" "NullPointerException" "ClassCastException" "IndexOutOfBoundsException" - "FileNotFoundException" "UnsupportedEncodingException" "EOFException" "java.io.EOFException" - "Error" "AssertionError")) + "FileNotFoundException" "UnsupportedEncodingException" "EOFException" "java.io.EOFException")) ;; ---- URLEncoder / URLDecoder (www-form-urlencoded) -------------------------- (define (url-unreserved? b) @@ -642,31 +564,20 @@ ;; record-method-dispatch already routes string? -> jolt-string-method. Add a ;; regex-t arm (Pattern .split / .matcher-less surface used by corpus) by wrapping ;; once more — a regex-t isn't a jhost. -(register-method-arm! 42 +(define %hs-rmd2 record-method-dispatch) +(set! record-method-dispatch (lambda (obj method-name rest-args) - (let ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args)))) - (cond - ((regex-t? obj) - (cond ((string=? method-name "split") - ;; .split returns a String[] — a seq (prints - ;; (a b c), not a vector). re-split with no limit; drop trailing - ;; empties (JVM default). - (let ((parts (re-split (regex-t-irx obj) (car rest) #f))) - (list->cseq (str-split-drop-trailing parts)))) - ((string=? method-name "pattern") (regex-t-source obj)) - ((or (string=? method-name "toString")) (regex-t-source obj)) - ;; (.matcher pattern s) -> a Matcher (matcher-t) for stepping matches. - ((string=? method-name "matcher") (jolt-re-matcher obj (car rest))) - (else (error #f (string-append "No method " method-name " on Pattern"))))) - ;; java.util.regex.Matcher: .matches (anchored whole-region), .find - ;; (next match), .group [n], .groupCount. - ((jolt-matcher? obj) - (cond ((string=? method-name "matches") (jolt-matcher-matches obj)) - ((string=? method-name "find") (not (jolt-nil? (jolt-re-find obj)))) - ((string=? method-name "group") (apply jolt-matcher-group obj rest)) - ((string=? method-name "groupCount") (jolt-matcher-group-count obj)) - (else (error #f (string-append "No method " method-name " on Matcher"))))) - (else 'pass))))) + (if (regex-t? obj) + (let ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args)))) + (cond ((string=? method-name "split") + ;; .split returns a String[] — a seq (prints + ;; (a b c), not a vector). re-split with no limit; drop trailing + ;; empties (JVM default). + (let ((parts (re-split (regex-t-irx obj) (car rest) #f))) + (list->cseq (str-split-drop-trailing parts)))) + ((string=? method-name "pattern") (regex-t-source obj)) + (else (error #f (string-append "No method " method-name " on Pattern"))))) + (%hs-rmd2 obj method-name rest-args)))) ;; ---- def-var! the registry entry points so emit can also reach them --------- (def-var! "clojure.core" "host-static-ref" host-static-ref) @@ -708,34 +619,19 @@ ;; htable arm: dispatch (.method obj a*) through the table's tag method registry; ;; an unregistered method falls through (sorted colls are htables too). -(register-method-arm! 43 +(define %hs-rmd-htable record-method-dispatch) +(set! record-method-dispatch (lambda (obj method-name rest-args) (let ((tag (and (htable? obj) (hashtable-ref (htable-h obj) "jolt/type" #f)))) (let* ((mh (and tag (hashtable-ref tagged-methods-tbl (tag->method-key tag) #f))) (f (and mh (hashtable-ref mh method-name #f)))) (if f (apply f obj (if (jolt-nil? rest-args) '() (seq->list rest-args))) - 'pass))))) + (%hs-rmd-htable obj method-name rest-args)))))) (def-var! "clojure.core" "__register-class-methods!" (lambda (tag members) (register-tagged-methods! tag (jmap->static-alist members)) jolt-nil)) -;; java.lang.ThreadLocal via a Chez thread-parameter: real per-thread storage with -;; a lazy initialValue (the proxy macro lowers (proxy [ThreadLocal] …) to this). -;; .get returns the thread's value, computing initialValue once; .set / .remove. -(define tl-unset (list 'tl-unset)) -(define (jolt-make-thread-local init-thunk) - (make-jhost "threadlocal" (vector (make-thread-parameter tl-unset) init-thunk))) -(register-host-methods! "threadlocal" - (list (cons "get" (lambda (self) - (let* ((st (jhost-state self)) (tp (vector-ref st 0)) (v (tp))) - (if (eq? v tl-unset) - (let ((nv (jolt-invoke (vector-ref st 1)))) (tp nv) nv) - v)))) - (cons "set" (lambda (self v) ((vector-ref (jhost-state self) 0) v) jolt-nil)) - (cons "remove" (lambda (self) ((vector-ref (jhost-state self) 0) tl-unset) jolt-nil)))) -(def-var! "jolt.host" "make-thread-local" jolt-make-thread-local) - ;; Pluggable instance? — a library registers (fn [class-name-string val] -> true ;; | false | nil); nil means "not my class, fall through". First non-nil wins. (define user-instance-checks '()) @@ -765,12 +661,6 @@ (register-instance-check-arm! (lambda (type-sym val) (let ((iface (hsc-last-segment (symbol-t-name type-sym)))) - ;; the value's own class-graph tags (value-host-tags) are authoritative — the - ;; SAME source protocol dispatch reads, so instance? and extend-protocol can't - ;; disagree about the interfaces a builtin implements. - (if (let ((tags (value-host-tags val))) - (or (member (symbol-t-name type-sym) tags) (member iface tags))) - #t (let ((hit (cond ((or (string=? iface "IObj") (string=? iface "IMeta")) (hsc-imeta? val)) ((or (string=? iface "IMapEntry") (string=? iface "MapEntry")) (jolt-map-entry? val)) @@ -778,15 +668,8 @@ ((string=? iface "IPersistentMap") (or (pmap? val) (htable-sorted-map? val))) ((string=? iface "IPersistentVector") (and (pvec? val) (not (jolt-map-entry? val)))) ((string=? iface "IPersistentSet") (or (pset? val) (htable-sorted-set? val))) - ((string=? iface "ISeq") + ((or (string=? iface "ISeq") (string=? iface "Seqable")) (or (cseq? val) (empty-list-t? val) (jolt-lazyseq? val))) - ((string=? iface "LazySeq") (jolt-lazyseq? val)) - ;; Seqable is anything (seq x) works on — every persistent - ;; collection, not just seqs (a vector IS Seqable, not an ISeq). - ((string=? iface "Seqable") - (or (cseq? val) (empty-list-t? val) (jolt-lazyseq? val) - (pvec? val) (pmap? val) (pset? val) - (htable-sorted-map? val) (htable-sorted-set? val))) ((string=? iface "Sequential") (or (pvec? val) (cseq? val) (empty-list-t? val) (jolt-lazyseq? val))) ((string=? iface "IFn") @@ -831,7 +714,7 @@ ((or (string=? iface "Reader") (string=? iface "BufferedReader")) (reader-jhost? val)) (else 'none)))) - (if (eq? hit 'none) 'pass (if hit #t #f))))))) + (if (eq? hit 'none) 'pass (if hit #t #f)))))) ;; java.lang.Class value: (class x) / (.getClass x) return one. It renders like ;; the JVM — str/.toString -> "class ", pr -> "", .getName -> "" @@ -841,12 +724,7 @@ (define (make-class-obj name) (make-jhost "class" (vector name))) (define (jclass? x) (and (jhost? x) (string=? (jhost-tag x) "class"))) (define (jclass-name x) (vector-ref (jhost-state x) 0)) -(define (class-key x) - (cond ((jclass? x) (jclass-name x)) - ((string? x) x) - ;; a deftype/defrecord NAME var holds its ctor; treat it as the class - ((procedure? x) (hashtable-ref chez-deftype-ctor-tag x #f)) - (else #f))) +(define (class-key x) (cond ((jclass? x) (jclass-name x)) ((string? x) x) (else #f))) (register-eq-arm! (lambda (a b) (or (jclass? a) (jclass? b))) (lambda (a b) (let ((ka (class-key a)) (kb (class-key b))) (and ka kb (string=? ka kb) #t)))) @@ -860,254 +738,7 @@ (cons "toString" (lambda (self) (string-append "class " (jclass-name self)))) (cons "isArray" (lambda (self) (let ((n (jclass-name self))) (and (fx>? (string-length n) 0) (char=? (string-ref n 0) #\[))))) - ;; Class.isInstance(o) == (instance? class o); core.logic's deftype .equals - ;; uses (.. this getClass (isInstance o)). - (cons "isInstance" (lambda (self o) (if (instance-check self o) #t #f))) (cons "getClass" (lambda (self) (make-class-obj "java.lang.Class"))))) ;; (jolt.host/table? x) — is x a host tagged-table? (def-var! "jolt.host" "table?" (lambda (x) (if (htable? x) #t #f))) - -;; --- java.util.Arrays ------------------------------------------------------- -(let ((arrays-statics - (list - (cons "equals" (lambda (a b) - (cond ((and (jolt-nil? a) (jolt-nil? b)) #t) - ((or (jolt-nil? a) (jolt-nil? b)) #f) - (else (equal? (jolt-array-vec a) (jolt-array-vec b)))))) - (cons "fill" (lambda (a v) (vector-fill! (jolt-array-vec a) v) jolt-nil)) - (cons "copyOf" (lambda (a n) - (let* ((src (jolt-array-vec a)) (len (jnum->exact n)) - (out (make-vector len 0))) - (do ((i 0 (fx+ i 1))) ((fx=? i (min len (vector-length src)))) - (vector-set! out i (vector-ref src i))) - (make-jolt-array out (jolt-array-kind a))))) - (cons "copyOfRange" (lambda (a from to) - (let* ((src (jolt-array-vec a)) (f (jnum->exact from)) (tt (jnum->exact to)) - (len (- tt f)) (out (make-vector len 0))) - (do ((i 0 (fx+ i 1))) ((fx=? i len)) - (vector-set! out i (vector-ref src (+ f i)))) - (make-jolt-array out (jolt-array-kind a))))) - (cons "toString" (lambda (a) (jolt-pr-str (apply jolt-vector (vector->list (jolt-array-vec a))))))))) - (register-class-statics! "Arrays" arrays-statics) - (register-class-statics! "java.util.Arrays" arrays-statics)) - -;; --- java.util.Random ------------------------------------------------------- -;; A non-cryptographic PRNG over Chez's `random`. A seed argument is accepted but -;; not honored for reproducibility (jolt has no seedable Random state); callers -;; that need determinism use SecureRandom or their own generator. -(for-each - (lambda (nm) (register-class-ctor! nm (lambda args (make-jhost "random" (vector))))) - '("Random" "java.util.Random")) -(register-host-methods! "random" - (list - (cons "nextBytes" (lambda (self ba) - (let ((v (jolt-array-vec ba))) - (do ((i 0 (fx+ i 1))) ((fx=? i (vector-length v))) - (vector-set! v i (random 256)))) - jolt-nil)) - (cons "nextInt" (lambda (self . a) - (->num (if (pair? a) (random (jnum->exact (car a))) (- (random 4294967296) 2147483648))))) - (cons "nextLong" (lambda (self) (->num (- (random 18446744073709551616) 9223372036854775808)))) - (cons "nextDouble" (lambda (self) (random 1.0))) - (cons "nextFloat" (lambda (self) (random 1.0))) - (cons "nextBoolean" (lambda (self) (fx=? 0 (random 2)))))) - -;; --- java.util.Optional ----------------------------------------------------- -;; Returned by getters across java.time / java.net.http (e.g. HttpRequest.timeout, -;; HttpClient.connectTimeout). Value-equal so (= (Optional/of x) (Optional/of x)). -(define (jt-optional present? value) (make-jhost "optional" (vector present? value))) -(define jt-optional-empty (jt-optional #f jolt-nil)) -(define (opt? x) (and (jhost? x) (string=? (jhost-tag x) "optional"))) -(define (opt-present? o) (vector-ref (jhost-state o) 0)) -(define (opt-value o) (vector-ref (jhost-state o) 1)) -(let ((statics (list (cons "of" (lambda (v) (if (jolt-nil? v) (error #f "Optional.of(null)") (jt-optional #t v)))) - (cons "ofNullable" (lambda (v) (if (jolt-nil? v) jt-optional-empty (jt-optional #t v)))) - (cons "empty" (lambda _ jt-optional-empty))))) - (register-class-statics! "Optional" statics) - (register-class-statics! "java.util.Optional" statics)) -(register-host-methods! "optional" - (list (cons "isPresent" (lambda (o) (opt-present? o))) - (cons "isEmpty" (lambda (o) (not (opt-present? o)))) - (cons "get" (lambda (o) (if (opt-present? o) (opt-value o) (error #f "Optional.get() on empty Optional")))) - (cons "orElse" (lambda (o d) (if (opt-present? o) (opt-value o) d))) - (cons "orElseGet" (lambda (o f) (if (opt-present? o) (opt-value o) (jolt-invoke f)))) - (cons "ifPresent" (lambda (o f) (when (opt-present? o) (jolt-invoke f (opt-value o))) jolt-nil)) - (cons "toString" (lambda (o) (if (opt-present? o) - (string-append "Optional[" (jolt-str-render-one (opt-value o)) "]") - "Optional.empty"))))) -(register-eq-arm! (lambda (a b) (or (opt? a) (opt? b))) - (lambda (a b) (and (opt? a) (opt? b) (eq? (opt-present? a) (opt-present? b)) - (or (not (opt-present? a)) (jolt=2 (opt-value a) (opt-value b)))))) - -;; --- minimal JVM class/interface ancestry ----------------------------------- -;; A handful of libraries reflect over the class hierarchy — e.g. core.memoize -;; validates its first argument with (some #{IFn AFn Runnable Callable} -;; (ancestors (class f))). jolt models a class as its name string and has no -;; reflection, so supers/ancestors return nothing on their own. This table gives -;; the common interfaces the direct supers the JVM reports, and the overlay's -;; supers/ancestors fold it in. Keyed by canonical class name; value = direct -;; supers. Extend as more interfaces are exercised. -(define class-supers-tbl (make-hashtable string-hash string=?)) -(define (reg-class-supers! name supers) (hashtable-set! class-supers-tbl name supers)) -(reg-class-supers! "clojure.lang.IFn" '("java.lang.Runnable" "java.util.concurrent.Callable")) -(reg-class-supers! "clojure.lang.AFn" '("clojure.lang.IFn" "java.lang.Runnable" "java.util.concurrent.Callable")) -(reg-class-supers! "clojure.lang.AFunction" '("clojure.lang.AFn" "clojure.lang.IFn" "clojure.lang.Fn" - "java.lang.Runnable" "java.util.concurrent.Callable")) -;; common exception hierarchy, so (instance? IOException e) / (catch IOException e) -;; match a more specific throwable a library threw (e.g. http-client's -;; UnknownHostException, caught by clj-http-lite's :ignore-unknown-host?). -(reg-class-supers! "java.lang.Throwable" '("java.lang.Object")) -(reg-class-supers! "java.lang.Exception" '("java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.lang.RuntimeException" '("java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.io.IOException" '("java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.io.InterruptedIOException" '("java.io.IOException" "java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.net.SocketException" '("java.io.IOException" "java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.net.UnknownHostException" '("java.io.IOException" "java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.net.ConnectException" '("java.net.SocketException" "java.io.IOException" "java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -(reg-class-supers! "java.net.SocketTimeoutException" '("java.io.InterruptedIOException" "java.io.IOException" "java.lang.Exception" "java.lang.Throwable" "java.lang.Object")) -;; clojure.lang / java.util ancestry for the builtins (class) reports, so a -;; class-keyed multimethod / (isa? (class x) SomeClass) dispatches like the JVM. -;; (Object is supplied universally by class-isa?, so it need not be listed.) -(reg-class-supers! "clojure.lang.IFn" '("clojure.lang.Fn" "java.lang.Runnable" "java.util.concurrent.Callable")) -;; Keyword and Symbol implement IFn (they are callable: (:k m) / ('s m)), so a -;; (class x)-dispatched multimethod with an IFn method matches them, like the JVM. -(reg-class-supers! "clojure.lang.Keyword" '("clojure.lang.Named" "java.lang.Comparable" - "clojure.lang.IFn" "clojure.lang.Fn" - "java.lang.Runnable" "java.util.concurrent.Callable")) -(reg-class-supers! "clojure.lang.Symbol" '("clojure.lang.Named" "java.lang.Comparable" - "clojure.lang.IFn" "clojure.lang.Fn" - "java.lang.Runnable" "java.util.concurrent.Callable")) -(reg-class-supers! "java.lang.String" '("java.lang.CharSequence" "java.lang.Comparable")) -(reg-class-supers! "clojure.lang.PersistentHashSet" '("clojure.lang.APersistentSet" "clojure.lang.IPersistentSet" "clojure.lang.IPersistentCollection" "java.util.Set" "java.util.Collection" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.PersistentTreeSet" '("clojure.lang.APersistentSet" "clojure.lang.IPersistentSet" "clojure.lang.IPersistentCollection" "java.util.Set" "java.util.Collection" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.PersistentVector" '("clojure.lang.APersistentVector" "clojure.lang.IPersistentVector" "clojure.lang.IPersistentCollection" "clojure.lang.Sequential" "clojure.lang.Associative" "java.util.List" "java.util.Collection" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.PersistentArrayMap" '("clojure.lang.APersistentMap" "clojure.lang.IPersistentMap" "clojure.lang.IPersistentCollection" "clojure.lang.Associative" "java.util.Map" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.PersistentHashMap" '("clojure.lang.APersistentMap" "clojure.lang.IPersistentMap" "clojure.lang.IPersistentCollection" "clojure.lang.Associative" "java.util.Map" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.PersistentList" '("clojure.lang.ASeq" "clojure.lang.ISeq" "clojure.lang.IPersistentCollection" "clojure.lang.Sequential" "clojure.lang.Seqable" "java.util.List" "java.util.Collection" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.LazySeq" '("clojure.lang.ISeq" "clojure.lang.IPersistentCollection" "clojure.lang.Sequential" "clojure.lang.Seqable" "java.lang.Iterable")) -(reg-class-supers! "clojure.lang.Cons" '("clojure.lang.ASeq" "clojure.lang.ISeq" "clojure.lang.Sequential" "clojure.lang.Seqable" "java.lang.Iterable")) - -;; A munged fn class name "ns$name" (jolt-class for a def'd fn) isn't in the table; -;; like the JVM (a fn extends clojure.lang.AFunction) its super is AFunction, whose -;; registered supers give AFn / IFn / Fn / Runnable / Callable transitively. -(define (str-has-dollar? s) - (let loop ((i 0)) (and (< i (string-length s)) (or (char=? (string-ref s i) #\$) (loop (+ i 1)))))) -(define (class-direct-supers name) - ;; union the modeled class graph (jch, direct edges) with any legacy table entry, - ;; so isa?/supers/ancestors see the single hierarchy source plus anything not yet - ;; migrated. The closure below traverses these to the full transitive set. - (let ((jch (jch-direct-supers name)) - (old (hashtable-ref class-supers-tbl name #f))) - (cond ((and (pair? jch) old) - (let merge ((ss old) (acc jch)) - (cond ((null? ss) acc) - ((member (car ss) acc) (merge (cdr ss) acc)) - (else (merge (cdr ss) (append acc (list (car ss)))))))) - ((pair? jch) jch) - (old old) - ((str-has-dollar? name) '("clojure.lang.AFunction")) - (else '())))) -;; transitive closure of direct supers (set semantics via an accumulator list) -(define (class-ancestors-list name) - (let loop ((pending (class-direct-supers name)) (seen '())) - (cond ((null? pending) (reverse seen)) - ((member (car pending) seen) (loop (cdr pending) seen)) - (else (loop (append (class-direct-supers (car pending)) (cdr pending)) - (cons (car pending) seen)))))) - -;; (instance? Class e) on a throwable tagged-table carrying a JVM :class matches the -;; carried class or any of its ancestors (full name or last segment), so a library's -;; (catch UnknownHostException e …) / (catch IOException e …) matches the ex-info -;; envelope it threw. Mirrors the (class e) arm (host-table.ss) for catch dispatch, -;; which lowers to (instance? C e). Non-match returns 'pass so other arms still run. -(register-instance-check-arm! - (lambda (type-sym val) - (if (and (htable? val) (string? (hashtable-ref (htable-h val) "class" #f))) - (let* ((cls (hashtable-ref (htable-h val) "class" #f)) - (want (symbol-t-name type-sym)) - (want-seg (hsc-last-segment want))) - (let loop ((names (cons cls (class-ancestors-list cls)))) - (cond ((null? names) 'pass) - ((or (string=? want (car names)) - (string=? want-seg (hsc-last-segment (car names)))) #t) - (else (loop (cdr names)))))) - 'pass))) - -;; JVM class assignability for isa? (20-coll): true when child and parent are both -;; class values and parent is child, java.lang.Object (every class's root), or a -;; modeled ancestor of child (full name or last segment). nil for non-class args, so -;; isa? falls through to its hierarchy/vector logic. -(def-var! "jolt.host" "class-isa?" - (lambda (child parent) - (let ((cc (class-key child)) (pp (class-key parent))) - (if (and cc pp) - (let ((pseg (hsc-last-segment pp))) - (if (let loop ((names (cons cc (class-ancestors-list cc)))) - (cond ((string=? pp "java.lang.Object") #t) - ((null? names) #f) - ((or (string=? pp (car names)) - (string=? pseg (hsc-last-segment (car names)))) #t) - (else (loop (cdr names))))) - #t jolt-nil)) - jolt-nil)))) - -;; is NAME a class the host models (registered in the class graph, a legacy -;; supers-table entry, or a fn class)? Object itself is modeled. -(define (hsc-class-known? name) - (or (string=? name "java.lang.Object") - (jch-known? name) - (and (hashtable-ref class-supers-tbl name #f) #t) - (str-has-dollar? name))) - -;; transitive ancestry, rooted at Object for a concrete class like (supers c); -;; an interface's chain has no Object (its getSuperclass is null). '() for -;; Object itself and for a name the host doesn't model. -(define (class-ancestors-rooted name) - (if (or (string=? name "java.lang.Object") (jch-interface? name)) - (class-ancestors-list name) - (let ((as (class-ancestors-list name))) - (cond ((member "java.lang.Object" as) as) - ((null? as) (if (hsc-class-known? name) '("java.lang.Object") '())) - (else (append as '("java.lang.Object"))))))) - -;; (jolt.host/class-supers name) / (jolt.host/class-ancestors name) — a jolt seq of -;; super / ancestor class-name strings (transitive, Object-rooted), or nil when -;; jolt models no hierarchy for it. class-bases is the DIRECT supers (clojure.core -;; `bases` / the class arm of `parents`). -(def-var! "jolt.host" "class-supers" - (lambda (x) - (let ((name (class-key x))) - (if name - (let ((as (class-ancestors-rooted name))) - (if (null? as) jolt-nil (list->cseq as))) - jolt-nil)))) -(def-var! "jolt.host" "class-ancestors" - (lambda (x) - (let ((name (class-key x))) - (if name - (let ((as (class-ancestors-rooted name))) - (if (null? as) jolt-nil (list->cseq as))) - jolt-nil)))) -(def-var! "jolt.host" "class-bases" - (lambda (x) - (let ((name (class-key x))) - (if name - (let* ((ds (class-direct-supers name)) - ;; a concrete class's bases include its superclass — Object when - ;; nothing more specific is modeled (interfaces have none). - (ds (if (or (string=? name "java.lang.Object") - (jch-interface? name) - (member "java.lang.Object" ds)) - ds - (append ds '("java.lang.Object"))))) - (if (null? ds) jolt-nil (list->cseq ds))) - jolt-nil)))) -;; is X a class value — a jclass, a deftype ctor, or a name string the host -;; graph models? -(def-var! "jolt.host" "class-value?" - (lambda (x) - (if (jclass? x) - #t - (let ((n (class-key x))) - (if (and n (hsc-class-known? n)) #t jolt-nil))))) diff --git a/host/chez/java/host-static-methods.ss b/host/chez/host-static-methods.ss similarity index 66% rename from host/chez/java/host-static-methods.ss rename to host/chez/host-static-methods.ss index ea8981f..4bdf1cc 100644 --- a/host/chez/java/host-static-methods.ss +++ b/host/chez/host-static-methods.ss @@ -21,11 +21,6 @@ (cons "acos" (lambda (x) (->dbl (acos x)))) (cons "atan" (lambda (x) (->dbl (atan x)))) (cons "log" (lambda (x) (->dbl (log x)))) (cons "log10" (lambda (x) (->dbl (/ (log x) (log 10))))) (cons "exp" (lambda (x) (->dbl (exp x)))) - ;; getExponent: the unbiased binary exponent of a double (floor(log2|x|)); - ;; scalb: x * 2^n. test.check's double generator uses both. - (cons "getExponent" (lambda (x) (if (= x 0.0) -1023 - (exact (floor (/ (log (abs (exact->inexact x))) (log 2.0))))))) - (cons "scalb" (lambda (x n) (->dbl (* (exact->inexact x) (expt 2.0 (jnum->exact n)))))) (cons "max" (lambda (a b) (if (> a b) a b))) (cons "min" (lambda (a b) (if (< a b) a b))) (cons "signum" (lambda (x) (cond ((< x 0) -1.0) ((> x 0) 1.0) (else 0.0)))) (cons "PI" (->dbl (* 4 (atan 1)))) (cons "E" (->dbl (exp 1))) @@ -55,7 +50,9 @@ (lambda () (unless tried? (set! tried? #t) - (set! fp (jolt-foreign-proc-safe "sched_yield" '() 'int))) + (set! fp (guard (e (#t #f)) + (load-shared-object #f) + (foreign-procedure "sched_yield" () int)))) (if fp (fp) (sleep (make-time 'time-duration 0 0))) jolt-nil))) @@ -99,70 +96,6 @@ (register-class-statics! "PersistentArrayMap" (list (cons "createWithCheck" pam-create-with-check))) (register-class-statics! "clojure.lang.PersistentArrayMap" (list (cons "createWithCheck" pam-create-with-check))) -;; clojure.lang.RT/map: build a map from a [k v k v…] array/seq (RT.map). Small -;; maps keep insertion order (PersistentArrayMap). tools.reader builds map and -;; namespaced-map literals this way. -(define (rt-map arr) - (let loop ((xs (if (jolt-nil? arr) '() (seq->list (jolt-seq arr)))) (m (jolt-hash-map))) - (cond ((null? xs) m) - ((null? (cdr xs)) (error #f "RT/map: odd key/value count")) - (else (loop (cddr xs) (jolt-assoc m (car xs) (cadr xs))))))) -(register-class-statics! "RT" (list (cons "map" rt-map))) -(register-class-statics! "clojure.lang.RT" (list (cons "map" rt-map))) - -;; clojure.lang.PersistentList/create: a list (in order) from a seq; empty -> (). -(define (plist-create x) - (let ((items (seq->list (jolt-seq x)))) - (if (null? items) jolt-empty-list (list->cseq items)))) -(register-class-statics! "PersistentList" (list (cons "create" plist-create))) -(register-class-statics! "clojure.lang.PersistentList" (list (cons "create" plist-create))) - -;; clojure.lang.PersistentHashSet/createWithCheck: a set from a seq, throwing on a -;; duplicate element (tools.reader's #{…} reader reports the dup). -(define (phs-create-with-check x) - (let loop ((xs (seq->list (jolt-seq x))) (s (jolt-hash-set))) - (if (null? xs) s - (let ((e (car xs))) - (if (jolt-truthy? (jolt-contains? s e)) - (jolt-throw (jolt-ex-info (string-append "Duplicate key: " (jolt-str-render-one e)) (jolt-hash-map))) - (loop (cdr xs) (jolt-conj1 s e))))))) -(register-class-statics! "PersistentHashSet" (list (cons "createWithCheck" phs-create-with-check))) -(register-class-statics! "clojure.lang.PersistentHashSet" (list (cons "createWithCheck" phs-create-with-check))) - -;; java.lang.Character statics. digit(ch, radix) -> the digit value or -1; ch may -;; be a char or an int codepoint (tools.reader passes (int c)). isDigit/ -;; isWhitespace take a char; valueOf boxes a char (identity on jolt). -(define (char->cp x) (if (char? x) (char->integer x) (jnum->exact x))) -(define (char-digit-value cp radix) - (let ((d (cond ((and (fx>=? cp 48) (fx<=? cp 57)) (fx- cp 48)) ; 0-9 - ((and (fx>=? cp 97) (fx<=? cp 122)) (fx+ 10 (fx- cp 97))) ; a-z - ((and (fx>=? cp 65) (fx<=? cp 90)) (fx+ 10 (fx- cp 65))) ; A-Z - (else 99)))) - (if (fxnum (char-digit-value (char->cp ch) (jnum->exact radix))))) - (cons "isDigit" (lambda (ch) (let ((cp (char->cp ch))) (and (fx>=? cp 48) (fx<=? cp 57))))) - (cons "isWhitespace" (lambda (ch) (char-whitespace? (integer->char (char->cp ch))))) - (cons "valueOf" (lambda (ch) (if (char? ch) ch (integer->char (char->cp ch))))))) -(register-class-statics! "Character" character-statics) -(register-class-statics! "java.lang.Character" character-statics) - -;; java.util.regex.Pattern/compile: a regex value from a string pattern. -(define pattern-statics (list (cons "compile" (lambda (s) (jolt-regex (jolt-str-render-one s)))))) -(register-class-statics! "Pattern" pattern-statics) -(register-class-statics! "java.util.regex.Pattern" pattern-statics) - -;; clojure.lang.BigInt / clojure.lang.Numbers: jolt has one exact-integer type -;; (Chez bignums auto-reduce), so BigInt.fromBigInteger and Numbers.reduceBigInt -;; are identity. tools.reader's number parser threads integers through these. -(define identity-num-statics (list (cons "fromBigInteger" (lambda (x) x)))) -(register-class-statics! "BigInt" identity-num-statics) -(register-class-statics! "clojure.lang.BigInt" identity-num-statics) -(register-class-statics! "Numbers" - (list (cons "reduceBigInt" (lambda (x) x)) (cons "toRatio" (lambda (x) x)))) -(register-class-statics! "clojure.lang.Numbers" - (list (cons "reduceBigInt" (lambda (x) x)) (cons "toRatio" (lambda (x) x)))) - (define (now-millis) (let ((t (current-time 'time-utc))) (+ (* 1000 (time-second t)) (quotient (time-nanosecond t) 1000000)))) @@ -183,29 +116,9 @@ (cons "getProperties" (lambda () (sys-properties-map))) (cons "getenv" (lambda k (apply sys-getenv k))))) -;; java.lang.Long.bitCount: the population count of the value's 64-bit two's- -;; complement (mask to 64 bits so a negative long counts like the JVM, e.g. -;; bitCount(-1) = 64). test.check's splittable PRNG uses it. -(define long-mask64 #xFFFFFFFFFFFFFFFF) -(define long-2^63 (expt 2 63)) -(define long-2^64 (expt 2 64)) -;; interpret a 64-bit value as a signed long (top bit = sign), like the JVM. -(define (as-signed64 v) (if (>= v long-2^63) (- v long-2^64) v)) -(define (long-nlz n) (- 64 (integer-length (bitwise-and (jnum->exact n) long-mask64)))) -(define (long-reverse n) - (let ((v (bitwise-and (jnum->exact n) long-mask64))) - (let loop ((i 0) (r 0)) - (if (fx=? i 64) (as-signed64 r) - (loop (fx+ i 1) - (bitwise-ior (bitwise-arithmetic-shift-left r 1) - (bitwise-and (bitwise-arithmetic-shift-right v i) 1))))))) (register-class-statics! "Long" - (list (cons "TYPE" "long") - (cons "MAX_VALUE" (->num 9223372036854775807)) + (list (cons "MAX_VALUE" (->num 9223372036854775807)) (cons "MIN_VALUE" (->num -9223372036854775808)) - (cons "bitCount" (lambda (n) (->num (bitwise-bit-count (bitwise-and (jnum->exact n) long-mask64))))) - (cons "numberOfLeadingZeros" (lambda (n) (->num (long-nlz n)))) - (cons "reverse" (lambda (n) (->num (long-reverse n)))) (cons "parseLong" (lambda (s . r) (parse-int-or-throw s (if (null? r) 10 (jnum->exact (car r))) "parseLong"))) (cons "valueOf" (lambda (s . r) (parse-int-or-throw s (if (null? r) 10 (jnum->exact (car r))) "valueOf"))))) @@ -213,8 +126,6 @@ (define (int->u32 n) (if (< n 0) (+ n 4294967296) n)) (register-class-statics! "Integer" (list (cons "MAX_VALUE" (->num 2147483647)) (cons "MIN_VALUE" (->num -2147483648)) - ;; the primitive class token (int.class); jolt models a class as its name - (cons "TYPE" "int") (cons "valueOf" (lambda (x . r) (if (number? x) (->num x) (parse-int-or-throw x (if (null? r) 10 (jnum->exact (car r))) "valueOf")))) @@ -225,40 +136,14 @@ (cons "toBinaryString" (lambda (x) (number->string (int->u32 (jnum->exact x)) 2))) (cons "toString" (lambda (x . r) (number->string (jnum->exact x) (if (null? r) 10 (jnum->exact (car r)))))))) -;; Byte / Short bounds (their values are plain integers on jolt; the statics let -;; libraries reference the JVM ranges — clojure.test.check generates over them). -(register-class-statics! "Byte" - (list (cons "TYPE" "byte") - (cons "MAX_VALUE" (->num 127)) (cons "MIN_VALUE" (->num -128)) - (cons "valueOf" (lambda (x . r) (->num (if (number? x) x (parse-int-or-throw x 10 "valueOf"))))) - (cons "parseByte" (lambda (x . r) (parse-int-or-throw x (if (null? r) 10 (jnum->exact (car r))) "parseByte"))) - (cons "toString" (lambda (x . r) (number->string (jnum->exact x)))))) -(register-class-statics! "Short" - (list (cons "TYPE" "short") - (cons "MAX_VALUE" (->num 32767)) (cons "MIN_VALUE" (->num -32768)) - (cons "valueOf" (lambda (x . r) (->num (if (number? x) x (parse-int-or-throw x 10 "valueOf"))))) - (cons "parseShort" (lambda (x . r) (parse-int-or-throw x (if (null? r) 10 (jnum->exact (car r))) "parseShort"))) - (cons "toString" (lambda (x . r) (number->string (jnum->exact x)))))) - -;; java.util.Locale — jolt's case ops are codepoint-based (locale-independent), so -;; the default locale is a no-op token. Libraries set/restore it around formatting -;; to prove output is locale-stable (honeysql's Turkish-İ regression guard). -(register-class-statics! "Locale" - (list (cons "getDefault" (lambda () "und")) - (cons "setDefault" (lambda (x) jolt-nil)) - (cons "forLanguageTag" (lambda (tag) (if (string? tag) tag (jolt-str-render-one tag)))) - (cons "ROOT" "und") (cons "US" "en-US") (cons "ENGLISH" "en"))) - (register-class-statics! "Boolean" - (list (cons "TYPE" "boolean") - (cons "parseBoolean" (lambda (s) (string=? "true" (ascii-string-down (if (string? s) s (jolt-str-render-one s)))))) + (list (cons "parseBoolean" (lambda (s) (string=? "true" (ascii-string-down (if (string? s) s (jolt-str-render-one s)))))) (cons "TRUE" #t) (cons "FALSE" #f))) (register-class-ctor! "Double" ->double) (register-class-ctor! "Float" ->double) (register-class-statics! "Double" - (list (cons "TYPE" "double") - (cons "parseDouble" parse-double-or-throw) + (list (cons "parseDouble" parse-double-or-throw) (cons "valueOf" ->double) (cons "toString" (lambda (x) (jolt-str-render-one (->double x)))) (cons "isNaN" (lambda (x) (and (flonum? x) (nan? x)))) @@ -266,21 +151,14 @@ (cons "MAX_VALUE" 1.7976931348623157e308) (cons "MIN_VALUE" 4.9e-324) (cons "POSITIVE_INFINITY" +inf.0) (cons "NEGATIVE_INFINITY" -inf.0) (cons "NaN" +nan.0))) (register-class-statics! "Float" - (list (cons "TYPE" "float") - (cons "parseFloat" parse-double-or-throw) (cons "valueOf" ->double))) + (list (cons "parseFloat" parse-double-or-throw) (cons "valueOf" ->double))) ;; Character: ASCII predicates (the engine is byte/ASCII oriented). (register-class-statics! "Character" - (list (cons "TYPE" "char") - (cons "isUpperCase" (lambda (c) (let ((n (char-code c))) (and (>= n 65) (<= n 90))))) + (list (cons "isUpperCase" (lambda (c) (let ((n (char-code c))) (and (>= n 65) (<= n 90))))) (cons "isLowerCase" (lambda (c) (let ((n (char-code c))) (and (>= n 97) (<= n 122))))) (cons "isDigit" (lambda (c) (let ((n (char-code c))) (and (>= n 48) (<= n 57))))) - ;; JVM Character.isWhitespace: Unicode whitespace (so U+2028 line separator - ;; counts, like the JVM) MINUS the no-break spaces the JVM excludes - ;; (U+00A0/U+2007/U+202F). char<=?space missed everything above ASCII. - (cons "isWhitespace" (lambda (c) (let ((cp (char-code c))) - (and (char-whitespace? (integer->char cp)) - (not (fx=? cp #xA0)) (not (fx=? cp #x2007)) (not (fx=? cp #x202F)))))))) + (cons "isWhitespace" (lambda (c) (char<=? (integer->char (char-code c)) #\space))))) ;; String/valueOf(Object): "null" for nil, else jolt's str semantics. ;; String/format(fmt args…) / (locale fmt args…) -> the clojure.core format engine. @@ -336,22 +214,12 @@ ;; class object; anything else throws a catchable ClassNotFoundException, like the ;; JVM — so the common `(try (Class/forName "optional.Dep") (catch …))` probe a ;; library uses to detect an absent dependency works (e.g. ring's joda-time check). -;; java.* / clojure.* packages jolt does NOT back, even though the broad prefix -;; below would otherwise claim them — optional backends a library feature-probes -;; with (Class/forName …) (e.g. tools.logging's java.util.logging / log4j). Listing -;; them here keeps class-found? honest so the probe sees them absent and skips the -;; backend (jolt has its own logging) instead of trying to use it and crashing. -(define forname-absent-prefixes - '("java.util.logging." "javax.management." "java.lang.management.")) (define (forname-known? nm) - ;; exact lookups only — lookup-class would fall back to the short class name, so - ;; any "x.y.Class" would spuriously match the registered java.lang.Class. - (or (hashtable-ref class-statics-tbl nm #f) - (hashtable-ref class-ctors-tbl nm #f) + (or (lookup-class class-statics-tbl nm) + (lookup-class class-ctors-tbl nm) (let ((pre? (lambda (p) (and (>= (string-length nm) (string-length p)) (string=? (substring nm 0 (string-length p)) p))))) - (and (or (pre? "java.") (pre? "clojure.") (pre? "jolt.")) - (not (exists pre? forname-absent-prefixes)))))) + (or (pre? "java.") (pre? "clojure.") (pre? "jolt."))))) (register-class-statics! "Class" (list (cons "forName" (lambda (nm . _) diff --git a/host/chez/java/host-static.ss b/host/chez/host-static.ss similarity index 68% rename from host/chez/java/host-static.ss rename to host/chez/host-static.ss index a579803..cd085f3 100644 --- a/host/chez/java/host-static.ss +++ b/host/chez/host-static.ss @@ -56,56 +56,26 @@ ;; record-method-dispatch (records.ss) gets a jhost arm: dispatch (.method obj a*) ;; through the tag's method table. -;; clojure.lang.Sorted on jolt's sorted-map / sorted-set: comparator / entryKey / -;; seqFrom / seq. data.priority-map's subseq/rsubseq reach for these (its -;; PersistentPriorityMap delegates .comparator to the backing sorted-map). The -;; comparator is returned as a small Comparator object whose .compare runs the -;; map's 3-way fn, since (.. sc comparator (compare a b)) is the calling form. -(define sorted-cmp-kw (keyword #f "cmp")) -(register-host-methods! "jolt-comparator" - (list (cons "compare" (lambda (self a b) (jolt-invoke (jhost-state self) a b))))) -(define (sorted-comparator-of sc) - (let ((c (jolt-ref-get sc sorted-cmp-kw))) - (make-jhost "jolt-comparator" (if (jolt-nil? c) jolt-compare c)))) -(define (sorted-iface-method? m) - (or (string=? m "comparator") (string=? m "entryKey") - (string=? m "seqFrom") (string=? m "seq"))) -(define (sorted-iface-dispatch obj method rest) - (cond - ((string=? method "comparator") (sorted-comparator-of obj)) - ((string=? method "entryKey") (jolt-first (car rest))) ; map entry -> its key - ((string=? method "seq") ; (.seq sc) or (.seq sc ascending?) - (if (or (null? rest) (jolt-truthy? (car rest))) (jolt-seq obj) (jolt-rseq obj))) - ;; (.seqFrom sc k ascending?) — the entries from k onward, in order. Done with a - ;; comparator filter over the seq (jolt has no tree cursor), like subseq. - ((string=? method "seqFrom") - (let* ((k (car rest)) (asc (jolt-truthy? (cadr rest))) - (cmp (jolt-ref-get obj sorted-cmp-kw)) - (cmpf (if (jolt-nil? cmp) jolt-compare cmp)) - (es (seq->list (jolt-seq obj))) - (keep (filter (lambda (e) - (let ((c (jnum->exact (jolt-invoke cmpf (jolt-first e) k)))) - (if asc (>= c 0) (<= c 0)))) - es))) - (list->cseq (if asc keep (reverse keep))))) - (else (error #f (string-append "No method " method " on sorted collection"))))) - -(register-method-arm! 44 +(define %hs-record-method-dispatch record-method-dispatch) +(set! record-method-dispatch (lambda (obj method-name rest-args) (cond + ;; (.getClass x) is universal — the class token for any value (incl. numbers + ;; / jhost) — before the per-type arms that would otherwise reject it. + ((string=? method-name "getClass") (jolt-class obj)) ((jhost? obj) (let ((mh (hashtable-ref host-methods-tbl (jhost-tag obj) #f))) (let ((f (and mh (hashtable-ref mh method-name #f)))) (if f (apply f obj (if (jolt-nil? rest-args) '() (seq->list rest-args))) (error #f (string-append "No method " method-name " on host " (jhost-tag obj))))))) - ((number? obj) (apply number-method method-name obj (if (jolt-nil? rest-args) '() (seq->list rest-args)))) - (else 'pass)))) + ((number? obj) (number-method method-name obj)) + (else (%hs-record-method-dispatch obj method-name rest-args))))) ;; java.lang.Number method surface (the boxed-number methods cljc code calls). The ;; integer projections wrap modulo their width (ring-codec relies on byteValue ;; overflow: (.byteValue 255) => -1); the float projections are identity flonums. -(define (number-method method n . args) +(define (number-method method n) (cond ((string=? method "byteValue") (let ((b (modulo (jnum->exact n) 256))) (->num (if (>= b 128) (- b 256) b)))) ((string=? method "shortValue") (let ((b (modulo (jnum->exact n) 65536))) (->num (if (>= b 32768) (- b 65536) b)))) @@ -113,27 +83,11 @@ ((string=? method "longValue") (->num (jnum->exact n))) ((string=? method "doubleValue") (->num n)) ((string=? method "floatValue") (->num n)) - ;; .toString(radix) — BigInteger/Integer render in a base, lowercase like the - ;; JVM (rewrite-clj's integer node reconstructs 0xff / 0377 / 2r1001 this way). - ((string=? method "toString") - (if (pair? args) - (string-downcase (number->string (jnum->exact n) (jnum->exact (car args)))) - (jolt-num->string n))) + ((string=? method "toString") (jolt-num->string n)) ((string=? method "hashCode") (->num (jnum->exact n))) ;; Double/Float .isNaN / .isInfinite (a non-flonum is neither). ((string=? method "isNaN") (and (flonum? n) (not (= n n)))) ((string=? method "isInfinite") (and (flonum? n) (infinite? n))) - ;; BigInteger interop: .negate / .bitLength / .signum / .abs. A jolt integer is - ;; a Chez exact integer, so these are native (integer-length = JVM bitLength, - ;; matching for negative values too). tools.reader's number parser uses them. - ((string=? method "negate") (->num (- (jnum->exact n)))) - ((string=? method "abs") (->num (abs (jnum->exact n)))) - ((string=? method "bitLength") (->num (integer-length (jnum->exact n)))) - ((string=? method "signum") (->num (let ((e (jnum->exact n))) (cond ((> e 0) 1) ((< e 0) -1) (else 0))))) - ;; BigInteger.shiftLeft/shiftRight (test.check's size-bounded-bigint): arbitrary - ;; precision, so an arithmetic shift by the (positive) amount. - ((string=? method "shiftLeft") (->num (bitwise-arithmetic-shift-left (jnum->exact n) (jnum->exact (car args))))) - ((string=? method "shiftRight") (->num (bitwise-arithmetic-shift-right (jnum->exact n) (jnum->exact (car args))))) (else (error #f (string-append "No method " method " for number"))))) ;; Mutable static fields: "Class" -> (member -> 1-vector cell). A library that @@ -194,9 +148,8 @@ (and n (integer? n) (->num n)))) (define (parse-int-or-throw s radix what) (or (parse-int-str s radix) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - (string-append "For input string: \"" - (if (string? s) s (jolt-str-render-one s)) "\""))))) + (error #f (string-append "NumberFormatException: For input string: \"" + (if (string? s) s (jolt-str-render-one s)) "\"")))) (define (char-code c) (if (char? c) (char->integer c) (jnum->exact c))) ;; parse a double string (Double/parseDouble, (Double. s)); JVM accepts NaN / @@ -210,8 +163,7 @@ (else (let ((n (string->number t))) (and n (real? n) (exact->inexact n))))))) (define (parse-double-or-throw s) (or (parse-double-str s) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - (string-append "For input string: \"" - (if (string? s) s (jolt-str-render-one s)) "\""))))) + (error #f (string-append "NumberFormatException: For input string: \"" + (if (string? s) s (jolt-str-render-one s)) "\"")))) (define (->double x) (if (number? x) (exact->inexact x) (parse-double-or-throw x))) diff --git a/host/chez/host-table.ss b/host/chez/host-table.ss index cda2330..0ed61f5 100644 --- a/host/chez/host-table.ss +++ b/host/chez/host-table.ss @@ -113,7 +113,7 @@ (define %h-set? jolt-set?) (set! jolt-set? (lambda (x) (or (htable-sorted-set? x) (%h-set? x)))) (def-var! "clojure.core" "set?" jolt-set?) -(def-var! "clojure.core" "coll?" (lambda (x) (or (htable-sorted? x) (jrec-collection? x) (jolt-coll-pred? x)))) +(def-var! "clojure.core" "coll?" (lambda (x) (or (htable-sorted? x) (jrec? x) (jolt-coll-pred? x)))) ;; --- equality / hash --------------------------------------------------------- ;; A sorted coll canonicalizes like its unordered counterpart: diff --git a/host/chez/java/inst-time.ss b/host/chez/inst-time.ss similarity index 93% rename from host/chez/java/inst-time.ss rename to host/chez/inst-time.ss index 4b2937f..c271824 100644 --- a/host/chez/java/inst-time.ss +++ b/host/chez/inst-time.ss @@ -179,12 +179,8 @@ (else (loop (+ i 1))))))) (define (parse-ms pattern input) (let ((pn (string-length pattern)) (inn (string-length input)) - (y 1970) (mo 1) (d 1) (hh 0) (mi 0) (ss 0) (frac-ms 0) (pm 'none)) - ;; a parse failure is a java.time.format.DateTimeParseException (typed, so a - ;; (catch DateTimeParseException …) over a bad date matches), like the JVM. - (define (pfail) - (jolt-throw (jolt-host-throwable "java.time.format.DateTimeParseException" - (string-append "unparseable date \"" input "\"") jolt-nil))) + (y 1970) (mo 1) (d 1) (hh 0) (mi 0) (ss 0) (pm 'none)) + (define (pfail) (error #f (string-append "ParseException: unparseable date \"" input "\""))) (define (run-len i c) (let loop ((j i)) (if (and (< j pn) (char=? (string-ref pattern j) c)) (loop (+ j 1)) (- j i)))) ;; read up to `maxw` digits (#f = unbounded). A fixed-width field (k>=2, e.g. ;; HHmm) caps the read at its run length so adjacent numeric fields split. @@ -208,7 +204,7 @@ (begin (when (eq? pm 'pm) (when (< hh 12) (set! hh (+ hh 12)))) (when (eq? pm 'am) (when (= hh 12) (set! hh 0))) - (make-jinst (+ (* 1000 (+ (* (days-from-civil y mo d) 86400) (* hh 3600) (* mi 60) ss)) frac-ms))) + (make-jinst (* 1000 (+ (* (days-from-civil y mo d) 86400) (* hh 3600) (* mi 60) ss)))) (let ((c (string-ref pattern pi))) (cond ((char-alphabetic? c) @@ -225,25 +221,7 @@ ((char=? c #\d) (let ((r (read-digits-w ii (if (>= k 2) k #f)))) (set! d (car r)) (loop (+ pi k) (cdr r)))) ((or (char=? c #\H) (char=? c #\h)) (let ((r (read-digits-w ii (if (>= k 2) k #f)))) (set! hh (car r)) (loop (+ pi k) (cdr r)))) ((char=? c #\m) (let ((r (read-digits-w ii (if (>= k 2) k #f)))) (set! mi (car r)) (loop (+ pi k) (cdr r)))) - ((char=? c #\s) (let ((r (read-digits-w ii (if (>= k 2) k #f)))) - (set! ss (car r)) - ;; an ISO formatter (modeled here as an ss-pattern with no S - ;; field) still accepts an optional fractional second; consume - ;; .fff -> millis from the input. Skip when the pattern carries - ;; the fraction itself (a following '.'/S handles it). - (let ((j (cdr r)) (pnext (if (< (+ pi k) pn) (string-ref pattern (+ pi k)) #\nul))) - (if (and (not (char=? pnext #\.)) (not (char=? pnext #\S)) - (< j inn) (char=? (string-ref input j) #\.) - (< (+ j 1) inn) (digit? (string-ref input (+ j 1)))) - (let frac ((p (+ j 1)) (kk 0) (acc 0)) - (if (and (< p inn) (digit? (string-ref input p))) - (frac (+ p 1) (+ kk 1) (if (< kk 3) (+ (* acc 10) (- (char->integer (string-ref input p)) 48)) acc)) - (begin (set! frac-ms (* acc (expt 10 (max 0 (- 3 kk))))) (loop (+ pi k) p)))) - (loop (+ pi k) j))))) - ((char=? c #\S) (let frac ((p ii) (kk 0) (acc 0)) - (if (and (< p inn) (< kk k) (digit? (string-ref input p))) - (frac (+ p 1) (+ kk 1) (+ (* acc 10) (- (char->integer (string-ref input p)) 48))) - (begin (set! frac-ms (* acc (expt 10 (max 0 (- 3 kk))))) (loop (+ pi k) p))))) + ((char=? c #\s) (let ((r (read-digits-w ii (if (>= k 2) k #f)))) (set! ss (car r)) (loop (+ pi k) (cdr r)))) ((char=? c #\E) (loop (+ pi k) (cdr (read-alpha ii)))) ((char=? c #\a) (let ((r (read-alpha ii))) (set! pm (if (string=? (ascii-string-down (car r)) "pm") 'pm 'am)) @@ -280,10 +258,6 @@ (register-hash-arm! jinst? (lambda (x) (jolt-hash (jinst-ms x)))) -;; #inst is a java.util.Date — (class x) / (type x) report that, not the internal -;; :jolt/inst tag (which print-method still dispatches on via __type-tag). -(register-class-arm! jinst? (lambda (x) "java.util.Date")) - ;; java.time.Instant is nano-precise: two Instants are = when their epoch-nanos ;; match (so an Instant and one shifted by a single nanosecond differ). (define (jt-instant-tag? x) (and (jhost? x) (string=? (jhost-tag x) "instant"))) @@ -307,6 +281,7 @@ (define %it-type jolt-type) (set! jolt-type (lambda (x) (if (jinst? x) inst-type-kw (%it-type x)))) +(def-var! "clojure.core" "type" jolt-type) ;; instance? java.util.Date -> a jinst; java.time.Instant/LocalDateTime -> the ;; matching jhost tag. The instance? macro passes the class-name symbol. @@ -562,7 +537,8 @@ (cons "format" (lambda (self d) (format-ms (vector-ref (jhost-state self) 0) (ms-of d)))))) ;; a jinst's java.util.Date method surface (record-method-dispatch arm). -(register-method-arm! 40 +(define %it-rmd record-method-dispatch) +(set! record-method-dispatch (lambda (obj method-name rest-args) (cond ((jinst? obj) @@ -585,7 +561,7 @@ ((string=? method-name "before") (< (jinst-ms obj) (ms-of (car (seq->list rest-args))))) ((string=? method-name "after") (> (jinst-ms obj) (ms-of (car (seq->list rest-args))))) (else (error #f (string-append "No method " method-name " on Date"))))) - (else 'pass)))) + (else (%it-rmd obj method-name rest-args))))) ;; Clojure's built-in data readers, so a library that merges default-data-readers ;; or binds *data-readers* (e.g. aero's reader opts) resolves #inst / #uuid. diff --git a/host/chez/java/io-streams.ss b/host/chez/io-streams.ss similarity index 100% rename from host/chez/java/io-streams.ss rename to host/chez/io-streams.ss diff --git a/host/chez/java/io.ss b/host/chez/io.ss similarity index 79% rename from host/chez/java/io.ss rename to host/chez/io.ss index d6ce4b7..9bd9454 100644 --- a/host/chez/java/io.ss +++ b/host/chez/io.ss @@ -29,70 +29,6 @@ (hashtable-set! embedded-resources name content)) (define-record-type embedded-res (fields name content) (nongenerative jolt-embres-v1)) -;; --- self-contained build artifacts (jolt-eaj) ------------------------------ -;; A toolchain-free `jolt build` (the distributed joltc) carries the Chez -;; petite/scheme boots and a prebuilt launcher stub baked into its own boot image. -;; They live in the same table as embedded-resources, but keyed under bytevector -;; values (register-embedded-bytes!) rather than strings; resolve-on-roots / -;; io/resource only ever ask for the string-keyed source entries, so the two -;; coexist. The build driver reads them at heap-build time from files that exist -;; only on the dev machine. -(define (register-embedded-bytes! name bv) (hashtable-set! embedded-resources name bv)) -(define (jolt-embedded-bytes name) - (let ((v (hashtable-ref embedded-resources name #f))) - (and (bytevector? v) v))) - -;; Read a whole file as a bytevector ("" -> empty). Used to slurp boot/stub files. -(define (read-file-bytes path) - (let ((p (open-file-input-port path))) - (let ((bv (get-bytevector-all p))) - (close-port p) - (if (eof-object? bv) (bytevector) bv)))) - -;; Write an embedded bytevector resource out to a path. make-boot-file needs the -;; petite/scheme boots as files, so they are spilled to scratch before the call. -(define (jolt-spill-embedded! name path) - (let ((bv (jolt-embedded-bytes name))) - (unless bv (error 'jolt-spill-embedded! "no embedded bytes for" name)) - (let ((p (open-file-output-port path (file-options no-fail) (buffer-mode block)))) - (put-bytevector p bv) - (close-port p)))) - -;; Frame an app boot onto a file that already holds the stub bytes. Layout: -;; [stub][boot][boot-length:le64]["JOLTBOOT"]. The stub (host/chez/stub/launcher.c) -;; reads the trailing 16 bytes — the 8-byte magic, then the preceding 8-byte LE -;; length — to locate and register the boot, so a boot that itself contains the -;; magic bytes can't be mistaken for the frame. -(define jolt-payload-magic (string->utf8 "JOLTBOOT")) -(define (jolt-append-payload! path boot-bv) - (let ((head (read-file-bytes path))) ; the stub bytes already written - (let ((p (open-file-output-port path (file-options no-fail) (buffer-mode block))) - (lb (make-bytevector 8 0))) - (bytevector-u64-set! lb 0 (bytevector-length boot-bv) (endianness little)) - (put-bytevector p head) - (put-bytevector p boot-bv) - (put-bytevector p lb) - (put-bytevector p jolt-payload-magic) - (close-port p)))) - -;; chmod 0755 via libc, so the produced binary is executable. load-shared-object -;; with #f pulls the running process's own symbols (chmod is in libc, linked into -;; every Chez binary) — no external toolchain. Falls back to /bin/sh chmod if the -;; symbol can't be resolved. -(define jolt-chmod-755 - (let ((c (jolt-foreign-proc-safe "chmod" '(string int) 'int))) - (lambda (path) - (cond - (c (c path #o755)) - ;; Windows has no chmod and needs none (execute is by extension) - ((let ((m (symbol->string (machine-type)))) - (let loop ((i 0)) - (cond ((> (+ i 2) (string-length m)) #f) - ((string=? (substring m i (+ i 2)) "nt") #t) - (else (loop (+ i 1)))))) - 0) - (else (system (string-append "chmod 755 '" path "'"))))))) - ;; A user-facing relative path resolves against JOLT_PWD — the user's cwd before ;; the launcher cd'd to the jolt repo root — matching the JVM, where io/file is ;; cwd-relative. (io/resource builds jfiles from the source roots directly, so it @@ -245,13 +181,14 @@ (else (loop (- i 1)))))) (else #f)))) -(register-method-arm! 41 +(define %io-rmd record-method-dispatch) +(set! record-method-dispatch (lambda (obj method-name rest-args) (if (jfile? obj) (let* ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args))) (r (jfile-method obj method-name rest))) (if r (car r) (error #f "no File method" method-name))) - 'pass))) + (%io-rmd obj method-name rest-args)))) ;; .isDirectory / .listFiles emit to jolt-host-call (rt.ss), not record-method- ;; dispatch — the shims there assume a path STRING target. Make them jfile-aware @@ -382,6 +319,7 @@ (define io-kw-file (keyword "jolt" "file")) (define %io-type jolt-type) (set! jolt-type (lambda (x) (if (jfile? x) io-kw-file (%io-type x)))) +(def-var! "clojure.core" "type" jolt-type) ;; (instance? java.io.File f): the instance? macro passes the class-name symbol; ;; match "File" / "java.io.File" (and any *.File) against a jfile. @@ -416,11 +354,6 @@ ;; method (a no-op for in-memory streams); absent method -> no-op. ((htable? x) (guard (e (#t jolt-nil)) (record-method-dispatch x "close" jolt-nil)) jolt-nil) ((jfile? x) jolt-nil) - ;; a deftype/defrecord that implements a `close` method (java.io.Closeable / - ;; AutoCloseable, e.g. tools.reader's reader types) closes through it — the - ;; same method (.close x) would dispatch to. - ((and (jrec? x) (jrec-cl x "close")) - (record-method-dispatch x "close" jolt-nil) jolt-nil) (else (let ((closef (jolt-get x (keyword #f "close") jolt-nil))) (if (and (not (jolt-nil? closef)) (procedure? closef)) @@ -524,29 +457,6 @@ (if (jolt-nil? u) jolt-nil (host-new "StringReader" (jolt-slurp (url-strip-scheme (url-spec u)))))))))) (register-class-statics! "ClassLoader" (list (cons "getSystemClassLoader" (lambda () the-classloader)))) (register-class-statics! "java.lang.ClassLoader" (list (cons "getSystemClassLoader" (lambda () the-classloader)))) -;; clojure.lang.RT/baseLoader — the resource-resolving class loader (RT/baseLoader -;; is how libraries reach Clojure's base loader, e.g. aws-api's resources ns). -(register-class-statics! "RT" (list (cons "baseLoader" (lambda () the-classloader)))) -(register-class-statics! "clojure.lang.RT" (list (cons "baseLoader" (lambda () the-classloader)))) -;; clojure.lang.RT/nextID — process-unique increasing id (AtomicInteger(1) -;; getAndIncrement), used by id generators such as core.logic's lvar. -(define rt-next-id-counter 1) -(define (rt-next-id) - (let ((v rt-next-id-counter)) - (set! rt-next-id-counter (+ rt-next-id-counter 1)) - v)) -(register-class-statics! "RT" (list (cons "nextID" rt-next-id))) -(register-class-statics! "clojure.lang.RT" (list (cons "nextID" rt-next-id))) -;; clojure.lang.Util — hash/equality helpers libraries call directly (core.logic's -;; LCons.hashCode uses Util/hash). hash = Java hashCode (0 for nil); hasheq = the -;; value hash jolt's = uses; equiv = value equality; identical = reference identity. -(let ((util-statics - (list (cons "hash" (lambda (x) (if (jolt-nil? x) 0 (record-method-dispatch x "hashCode" jolt-nil)))) - (cons "hasheq" (lambda (x) (jolt-hash x))) - (cons "equiv" (lambda (a b) (if (jolt= a b) #t #f))) - (cons "identical" (lambda (a b) (if (eq? a b) #t #f)))))) - (register-class-statics! "Util" util-statics) - (register-class-statics! "clojure.lang.Util" util-statics)) ;; Thread/currentThread -> a fresh thread jhost wrapping THIS thread's interrupt ;; flag (the box from current-interrupt-box, host-static.ss), so .interrupt from ;; any thread sets the target thread's flag and .isInterrupted reads it without @@ -555,11 +465,6 @@ (register-host-methods! "thread" (list (cons "getContextClassLoader" (lambda (self) the-classloader)) (cons "getName" (lambda (self) "main")) - ;; no reified call stack (jolt does TCO, so caller frames are erased) — an - ;; empty StackTraceElement[]. clojure.spec.test.alpha's instrument reads it - ;; to name the caller var; it degrades to no ::caller, the conform error - ;; (the ExceptionInfo) is still thrown. - (cons "getStackTrace" (lambda (self) (jolt-vector))) (cons "interrupt" (lambda (self) (when (box? (jhost-state self)) (set-box! (jhost-state self) #t)) jolt-nil)) @@ -609,51 +514,7 @@ (register-class-statics! "java.util.UUID" (list (cons "randomUUID" (lambda () (jolt-random-uuid))) (cons "fromString" (lambda (s) (jolt-parse-uuid (jolt-str-render-one s)))))) -;; (UUID. msb lsb): build from the most/least-significant 64-bit halves (the JVM's -;; 2-long ctor), the form test.check's uuid generator uses. (UUID. s) parses a -;; string. The 128 bits format as the canonical 8-4-4-4-12 lowercase hex string. -(define (uuid-long->hex16 n) - (let* ((u (bitwise-and (jnum->exact n) #xFFFFFFFFFFFFFFFF)) - (s (string-downcase (number->string u 16)))) ; JVM UUIDs are lowercase - (string-append (make-string (- 16 (string-length s)) #\0) s))) -(define (uuid-from-halves msb lsb) - (let ((h (uuid-long->hex16 msb)) (l (uuid-long->hex16 lsb))) - (make-juuid (string-append (substring h 0 8) "-" (substring h 8 12) "-" (substring h 12 16) - "-" (substring l 0 4) "-" (substring l 4 16))))) -(define (uuid-ctor . args) - (if (= (length args) 2) - (uuid-from-halves (car args) (cadr args)) - (jolt-parse-uuid (jolt-str-render-one (car args))))) -(register-class-ctor! "UUID" uuid-ctor) -(register-class-ctor! "java.util.UUID" uuid-ctor) -;; (Long. n) / (Long. "n"): a Long is just jolt's integer; return it (parse a string). -(register-class-ctor! "Long" (lambda (x) (if (string? x) (parse-int-or-throw x 10 "Long") (->num (jnum->exact x))))) -(register-class-ctor! "java.lang.Long" (lambda (x) (if (string? x) (parse-int-or-throw x 10 "Long") (->num (jnum->exact x))))) -;; (Integer. n) / (Integer. "n"): jolt's integer, range-checked like intCast. -(define (integer-ctor x) - (jolt-int-cast (if (string? x) (parse-int-or-throw x 10 "Integer") x))) -(register-class-ctor! "Integer" integer-ctor) -(register-class-ctor! "java.lang.Integer" integer-ctor) -;; (Double. x) / (Double. "x"): jolt's double. -(define (double-ctor x) - (if (string? x) - (let ((n (string->number x))) - (if n (exact->inexact n) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - (string-append "For input string: \"" x "\""))))) - (jolt-double x))) -(register-class-ctor! "Double" double-ctor) -(register-class-ctor! "java.lang.Double" double-ctor) - -;; (Boolean. "true") / (Boolean. b): true for the string "true" (case-insensitive, -;; anything else false) or the boolean itself — Boolean.valueOf semantics; the -;; box is jolt's plain boolean. -(define (boolean-ctor x) - (cond ((string? x) (string-ci=? x "true")) - ((boolean? x) x) - (else #f))) -(register-class-ctor! "Boolean" boolean-ctor) -(register-class-ctor! "java.lang.Boolean" boolean-ctor) +(register-class-ctor! "UUID" (lambda (s) (jolt-parse-uuid (jolt-str-render-one s)))) ;; --- java.net.URI ----------------------------------------------------------- ;; A minimal RFC-3986 split into scheme/authority/host/port/path/query/fragment, @@ -722,9 +583,6 @@ (define (uri-field u k) (let ((p (assq k (jhost-state u)))) (if p (cdr p) jolt-nil))) (register-class-ctor! "URI" (lambda (s) (uri-parse (jolt-str-render-one s)))) (register-class-ctor! "java.net.URI" (lambda (s) (uri-parse (jolt-str-render-one s)))) -;; URI/create — the static factory, same as the (URI. s) constructor. -(register-class-statics! "URI" (list (cons "create" (lambda (s) (uri-parse (jolt-str-render-one s)))))) -(register-class-statics! "java.net.URI" (list (cons "create" (lambda (s) (uri-parse (jolt-str-render-one s)))))) (register-host-methods! "uri" (list (cons "toString" (lambda (u) (uri-field u 'string))) (cons "toASCIIString" (lambda (u) (uri-field u 'string))) @@ -741,14 +599,6 @@ (cons "hashCode" (lambda (u) (string-hash (uri-field u 'string)))) (cons "equals" (lambda (u o) (and (jhost? o) (string=? (jhost-tag o) "uri") (string=? (uri-field u 'string) (uri-field o 'string))))))) -;; (= u1 u2) is value equality by string form (the .equals method above only -;; serves explicit (.equals …)); hash matches so a URI works as a map key / set -;; member (ring/hiccup compare (URI. "/") values). -(define (uri-jhost? x) (and (jhost? x) (string=? (jhost-tag x) "uri"))) -(register-eq-arm! (lambda (a b) (or (uri-jhost? a) (uri-jhost? b))) - (lambda (a b) (and (uri-jhost? a) (uri-jhost? b) - (string=? (uri-field a 'string) (uri-field b 'string))))) -(register-hash-arm! uri-jhost? (lambda (x) (string-hash (uri-field x 'string)))) ;; str / pr-str of a uri -> its string form. (register-str-render! (lambda (x) (and (jhost? x) (string=? (jhost-tag x) "uri"))) (lambda (x) (uri-field x 'string))) diff --git a/host/chez/java/java-time.ss b/host/chez/java-time.ss similarity index 97% rename from host/chez/java/java-time.ss rename to host/chez/java-time.ss index 836dc15..cb2f8ff 100644 --- a/host/chez/java/java-time.ss +++ b/host/chez/java-time.ss @@ -1116,37 +1116,20 @@ ((string=? f "PROLEPTIC_MONTH") (+ (* y 12) (- m 1))) ((string=? f "YEAR_OF_ERA") (if (>= y 1) y (- 1 y))) ((string=? f "ERA") (if (>= y 1) 1 0)) - ;; aligned-* group the day-of-month/year into 7-day blocks from the - ;; 1st (java.time): the within-block weekday is ((n-1) mod 7)+1, the - ;; block number is ((n-1) quotient 7)+1. - ((string=? f "ALIGNED_DAY_OF_WEEK_IN_MONTH") (+ (modulo (- d 1) 7) 1)) - ((string=? f "ALIGNED_WEEK_OF_MONTH") (+ (quotient (- d 1) 7) 1)) - ((string=? f "ALIGNED_DAY_OF_WEEK_IN_YEAR") - (+ (modulo (- (ld-day-of-year (ld-epoch-day t)) 1) 7) 1)) - ((string=? f "ALIGNED_WEEK_OF_YEAR") - (+ (quotient (- (ld-day-of-year (ld-epoch-day t)) 1) 7) 1)) (else (error #f (string-append "LocalDate has no field " f))))))) ((jt-time? t) (cond ((string=? f "HOUR_OF_DAY") (lt-hour t)) ((string=? f "MINUTE_OF_HOUR") (lt-minute t)) ((string=? f "SECOND_OF_MINUTE") (lt-second t)) ((string=? f "NANO_OF_SECOND") (lt-nano t)) ((string=? f "NANO_OF_DAY") (lt-nano-of-day t)) ((string=? f "MILLI_OF_DAY") (quotient (lt-nano-of-day t) 1000000)) - ((string=? f "MICRO_OF_DAY") (quotient (lt-nano-of-day t) 1000)) ((string=? f "SECOND_OF_DAY") (quotient (lt-nano-of-day t) nanos-per-sec)) ((string=? f "MINUTE_OF_DAY") (quotient (lt-nano-of-day t) (* 60 nanos-per-sec))) ((string=? f "MILLI_OF_SECOND") (quotient (lt-nano t) 1000000)) ((string=? f "MICRO_OF_SECOND") (quotient (lt-nano t) 1000)) - ;; CLOCK_HOUR_OF_DAY is 1..24 (midnight is 24), HOUR_OF_AMPM 0..11, - ;; CLOCK_HOUR_OF_AMPM 1..12, AMPM_OF_DAY 0 (AM) / 1 (PM). - ((string=? f "CLOCK_HOUR_OF_DAY") (let ((h (lt-hour t))) (if (= h 0) 24 h))) - ((string=? f "HOUR_OF_AMPM") (modulo (lt-hour t) 12)) - ((string=? f "CLOCK_HOUR_OF_AMPM") (let ((h (modulo (lt-hour t) 12))) (if (= h 0) 12 h))) ((string=? f "AMPM_OF_DAY") (quotient (lt-hour t) 12)) (else (error #f (string-append "LocalTime has no field " f))))) ((jt-dt? t) - ;; route a field to whichever part supports it (date fields incl. the - ;; aligned-* group to the date, the rest to the time). - (if (temporal-supports-field? (ldt-date t) f) + (if (member f '("YEAR" "MONTH_OF_YEAR" "DAY_OF_MONTH" "DAY_OF_WEEK" "DAY_OF_YEAR" "EPOCH_DAY" "PROLEPTIC_MONTH" "YEAR_OF_ERA" "ERA")) (temporal-get-field (ldt-date t) f) (temporal-get-field (ldt-time t) f))) ((jt-instant? t) @@ -1155,17 +1138,6 @@ ((string=? f "MILLI_OF_SECOND") (jt-floor-div (jt-floor-mod (inst-nanos t) nanos-per-sec) 1000000)) ((string=? f "MICRO_OF_SECOND") (jt-floor-div (jt-floor-mod (inst-nanos t) nanos-per-sec) 1000)) (else (error #f (string-append "Instant has no field " f))))) - ((and (jhost? t) (string=? (jhost-tag t) "year")) - (let ((y (year-val t))) - (cond ((string=? f "YEAR") y) ((string=? f "YEAR_OF_ERA") (if (>= y 1) y (- 1 y))) - ((string=? f "ERA") (if (>= y 1) 1 0)) - (else (error #f (string-append "Year has no field " f)))))) - ((and (jhost? t) (string=? (jhost-tag t) "year-month")) - (let ((y (ym-year t)) (m (ym-month t))) - (cond ((string=? f "YEAR") y) ((string=? f "MONTH_OF_YEAR") m) - ((string=? f "PROLEPTIC_MONTH") (+ (* y 12) (- m 1))) - ((string=? f "YEAR_OF_ERA") (if (>= y 1) y (- 1 y))) ((string=? f "ERA") (if (>= y 1) 1 0)) - (else (error #f (string-append "YearMonth has no field " f)))))) (else (error #f "get(field): unsupported temporal"))))) ;; field set: (with temporal ChronoField value) -> a new temporal. @@ -1196,17 +1168,10 @@ (else #f)))) (define (temporal-supports-field? t field) (let ((f (string-upcase field))) - (cond ((jt-date? t) (and (member f '("YEAR" "MONTH_OF_YEAR" "DAY_OF_MONTH" "DAY_OF_WEEK" "DAY_OF_YEAR" "EPOCH_DAY" "PROLEPTIC_MONTH" "YEAR_OF_ERA" "ERA" - "ALIGNED_DAY_OF_WEEK_IN_MONTH" "ALIGNED_DAY_OF_WEEK_IN_YEAR" "ALIGNED_WEEK_OF_MONTH" "ALIGNED_WEEK_OF_YEAR")) #t)) - ((jt-time? t) (and (member f '("HOUR_OF_DAY" "CLOCK_HOUR_OF_DAY" "HOUR_OF_AMPM" "CLOCK_HOUR_OF_AMPM" "AMPM_OF_DAY" - "MINUTE_OF_HOUR" "MINUTE_OF_DAY" "SECOND_OF_MINUTE" "SECOND_OF_DAY" - "MILLI_OF_SECOND" "MILLI_OF_DAY" "MICRO_OF_SECOND" "MICRO_OF_DAY" - "NANO_OF_SECOND" "NANO_OF_DAY")) #t)) + (cond ((jt-date? t) (and (member f '("YEAR" "MONTH_OF_YEAR" "DAY_OF_MONTH" "DAY_OF_WEEK" "DAY_OF_YEAR" "EPOCH_DAY" "PROLEPTIC_MONTH" "YEAR_OF_ERA" "ERA")) #t)) + ((jt-time? t) (and (member f '("HOUR_OF_DAY" "MINUTE_OF_HOUR" "SECOND_OF_MINUTE" "NANO_OF_SECOND" "NANO_OF_DAY" "MILLI_OF_DAY" "SECOND_OF_DAY" "MINUTE_OF_DAY" "MILLI_OF_SECOND" "MICRO_OF_SECOND" "AMPM_OF_DAY")) #t)) ((jt-dt? t) (or (temporal-supports-field? (ldt-date t) field) (temporal-supports-field? (ldt-time t) field))) ((jt-instant? t) (and (member f '("INSTANT_SECONDS" "NANO_OF_SECOND" "MILLI_OF_SECOND" "MICRO_OF_SECOND")) #t)) - ((and (jhost? t) (string=? (jhost-tag t) "year")) (and (member f '("YEAR" "YEAR_OF_ERA" "ERA")) #t)) - ((and (jhost? t) (string=? (jhost-tag t) "year-month")) - (and (member f '("YEAR" "MONTH_OF_YEAR" "PROLEPTIC_MONTH" "YEAR_OF_ERA" "ERA")) #t)) (else #f)))) ;; isSupported / get / getLong / with / range / plus / minus / until accept a @@ -1248,16 +1213,6 @@ (register-host-methods! "local-date" (mk-temporal-methods)) (register-host-methods! "local-time" (mk-temporal-methods)) (register-host-methods! "local-date-time" (mk-temporal-methods)) -;; Year/YearMonth answer the field accessors too (a fields-over-all-temporals walk -;; queries them); their own plus/minus/with stay the specific methods above. -(let ((field-methods - (list (cons "isSupported" (lambda (t x) (cond ((arg-is-unit? x) (temporal-supports-unit? t (cu-name x))) - ((arg-is-field? x) (temporal-supports-field? t (cf-name x))) - (else #f)))) - (cons "get" (lambda (t f) (temporal-get-field t (arg-field-name f)))) - (cons "getLong" (lambda (t f) (temporal-get-field t (arg-field-name f))))))) - (register-host-methods! "year" field-methods) - (register-host-methods! "year-month" field-methods)) (register-host-methods! "instant" (mk-temporal-methods)) ;; --- TemporalAdjuster: a date->date transform applied via (.with t adjuster) -- diff --git a/host/chez/java/bigdec.ss b/host/chez/java/bigdec.ss deleted file mode 100644 index f8e202b..0000000 --- a/host/chez/java/bigdec.ss +++ /dev/null @@ -1,402 +0,0 @@ -;; BigDecimal. A jbigdec is {unscaled, scale} over Chez arbitrary-precision exact -;; integers; its value is unscaled * 10^-scale (1.5M = {15,1}, 1.00M = {100,2}, -;; 3M = {3,0}). M-suffix literals read to a :bigdec form that the back end lowers -;; to jolt-bigdec-from-string; bigdec coerces a number/string. Equality is by -;; value (1.0M = 1.00M), str drops the M, pr keeps it, class is -;; java.math.BigDecimal. -;; -;; Arithmetic follows java.math.BigDecimal's scale rules: add/sub align to the -;; larger scale; multiply adds scales; divide gives the exact quotient at minimal -;; scale or throws ArithmeticException on a non-terminating expansion (a bound -;; *math-context* rounds instead). Clojure contagion: a bigdec mixed with an -;; integer or ratio stays a bigdec; a flonum operand wins (the result is a -;; double). jbd-add/-sub/-mul/-div, jbd-min/-max, the jbd-lt?/…/zero? helpers, -;; and jbd-quot/-rem are the shared engine. Two paths reach it, both leaving the -;; inlined fast path untouched: -;; - the seq.ss binary dispatch: every generic op (any position — (+ (bigdec x) -;; 1), (reduce + bigs), (quot 10.0 3M)) whose operand is outside Chez's tower -;; falls to the jolt-*-slow hooks extended below. -;; - static call position ((+ 1.5M 2.5M), (< a b), (zero? b)): jolt.passes.numeric -;; tags the invoke :num-kind :bigdec when every operand is statically a bigdec -;; (M literal or a let-bound copy, integer literals allowed), and the back end -;; lowers it directly to the jbd op. - -(define-record-type jbigdec (fields unscaled scale) (nongenerative chez-jbigdec-v1)) - -(define (bd-index-char s ch) - (let loop ((i 0)) - (cond ((>= i (string-length s)) #f) - ((char=? (string-ref s i) ch) i) - (else (loop (+ i 1)))))) - -;; "1.50" -> {150,2}; "3" -> {3,0}; "-0.0" -> {0,1}; ".5" -> {5,1}. -(define (jolt-bigdec-from-string s) - (let* ((neg (and (> (string-length s) 0) (char=? (string-ref s 0) #\-))) - (sgn (and (> (string-length s) 0) (or neg (char=? (string-ref s 0) #\+)))) - (s1 (if sgn (substring s 1 (string-length s)) s)) - (sign (if neg -1 1)) - (dot (bd-index-char s1 #\.))) - (if dot - (let* ((intp (substring s1 0 dot)) - (fracp (substring s1 (+ dot 1) (string-length s1))) - (digs (string-append intp fracp)) - (unscaled (if (= 0 (string-length digs)) 0 (string->number digs)))) - (make-jbigdec (* sign unscaled) (string-length fracp))) - (make-jbigdec (* sign (string->number s1)) 0)))) - -;; bigdec coercion: a bigdec is itself; an exact integer keeps scale 0; a string -;; or any other number routes through its decimal text. -(define (jolt-bigdec x) - (cond - ((jbigdec? x) x) - ((and (number? x) (exact? x) (integer? x)) (make-jbigdec x 0)) - ((string? x) (jolt-bigdec-from-string x)) - ((number? x) (jolt-bigdec-from-string (jolt-num->string x))) - (else (error #f "bigdec: cannot coerce" x)))) - -;; value equality: unscaled_a * 10^scale_b == unscaled_b * 10^scale_a. -(define (jbigdec=? a b) - (= (* (jbigdec-unscaled a) (expt 10 (jbigdec-scale b))) - (* (jbigdec-unscaled b) (expt 10 (jbigdec-scale a))))) - -;; render the decimal text (no M): insert the point `scale` digits from the right. -(define (jbigdec->string bd) - (let* ((u (jbigdec-unscaled bd)) (sc (jbigdec-scale bd)) - (neg (< u 0)) (digs (number->string (abs u)))) - (string-append - (if neg "-" "") - (if (<= sc 0) - digs - (let* ((padded (if (<= (string-length digs) sc) - (string-append (make-string (- (+ sc 1) (string-length digs)) #\0) digs) - digs)) - (pl (string-length padded))) - (string-append (substring padded 0 (- pl sc)) "." (substring padded (- pl sc) pl))))))) - -;; value as a Chez flonum (for double contagion: a flonum operand wins). -(define (jbigdec->flonum b) - (exact->inexact (/ (jbigdec-unscaled b) (expt 10 (jbigdec-scale b))))) - -;; coerce an exact operand to a bigdec; pass a bigdec through. Used on the -;; non-flonum mixed path (bigdec + long -> bigdec). A Ratio converts like -;; Numbers.toBigDecimal — exact decimal expansion or throw on non-terminating. -(define (jbd-coerce x) - (cond ((jbigdec? x) x) - ((and (number? x) (exact? x) (integer? x)) (make-jbigdec x 0)) - ((and (number? x) (exact? x) (rational? x)) (jbd-rational->bigdec x)) - (else (error #f "bigdec arithmetic: cannot coerce operand" x)))) - -;; --- core arithmetic on the {unscaled, scale} pair -------------------------- -;; align two bigdecs to a common scale, returning (unscaled-a unscaled-b scale). -(define (jbd-align a b) - (let ((sa (jbigdec-scale a)) (sb (jbigdec-scale b))) - (cond - ((= sa sb) (values (jbigdec-unscaled a) (jbigdec-unscaled b) sa)) - ((> sa sb) (values (jbigdec-unscaled a) - (* (jbigdec-unscaled b) (expt 10 (- sa sb))) sa)) - (else (values (* (jbigdec-unscaled a) (expt 10 (- sb sa))) - (jbigdec-unscaled b) sb))))) - -(define (jbd2+ a b) (let-values (((ua ub s) (jbd-align a b))) (make-jbigdec (+ ua ub) s))) -(define (jbd2- a b) (let-values (((ua ub s) (jbd-align a b))) (make-jbigdec (- ua ub) s))) -(define (jbd2* a b) (make-jbigdec (* (jbigdec-unscaled a) (jbigdec-unscaled b)) - (+ (jbigdec-scale a) (jbigdec-scale b)))) -(define (jbd-negate a) (make-jbigdec (- (jbigdec-unscaled a)) (jbigdec-scale a))) - -;; exact rational -> bigdec at minimal scale, or throw if non-terminating. den must -;; factor into 2s and 5s; scale = max(count2, count5). -(define (jbd-rational->bigdec r) - (let ((p (numerator r)) (q (denominator r))) - (let loop ((d q) (c2 0) (c5 0)) - (cond - ((= d 1) (let ((sc (max c2 c5))) - (make-jbigdec (* p (quotient (expt 10 sc) q)) sc))) - ((= 0 (modulo d 2)) (loop (quotient d 2) (+ c2 1) c5)) - ((= 0 (modulo d 5)) (loop (quotient d 5) c2 (+ c5 1))) - (else (jolt-throw (jolt-host-throwable - "java.lang.ArithmeticException" - "Non-terminating decimal expansion; no exact representable decimal result."))))))) - -;; floor(log10 |r|) for a nonzero exact rational. -(define (jbd-exp10 r) - (let ((n (abs (numerator r))) (d (denominator r))) - (if (>= n d) - (- (jbd-digits (quotient n d)) 1) - (let loop ((x (* n 10)) (e -1)) - (if (>= x d) e (loop (* x 10) (- e 1))))))) -;; round an exact rational to `prec` significant digits (the MathContext divide). -(define (jbd-rational-prec r prec mode) - (if (= r 0) - (make-jbigdec 0 0) - (let* ((neg (< r 0)) (ar (abs r)) - (s (- prec 1 (jbd-exp10 ar))) - (scaled (* ar (expt 10 s))) - (q (floor scaled)) (frac (- scaled q)) - (q2 (if (jbd-round-inc? q frac 1 mode neg) (+ q 1) q)) - (res (make-jbigdec (if neg (- q2) q2) s))) - ;; a carry can add a digit (9.99 -> 10.0); re-normalizing drops an exact - ;; trailing zero, never re-rounds. - (if (> (jbd-digits q2) prec) (jbd-round-prec res prec mode) res)))) - -(define (jbd2-div a b) - (when (= 0 (jbigdec-unscaled b)) - (jolt-throw (jolt-host-throwable "java.lang.ArithmeticException" "Divide by zero"))) - ;; a/b = (ua * 10^sb) / (ub * 10^sa) as an exact rational. Unlimited context: - ;; exact result at minimal scale or throw on a non-terminating expansion. A - ;; bound *math-context* instead rounds to its precision. - (let ((r (/ (* (jbigdec-unscaled a) (expt 10 (jbigdec-scale b))) - (* (jbigdec-unscaled b) (expt 10 (jbigdec-scale a))))) - (mc (jbd-math-context))) - (if mc - (jbd-rational-prec r (jbd-mc-precision mc) (jbd-mc-mode mc)) - (jbd-rational->bigdec r)))) - -;; integer-division semantics (quot/rem): truncate toward zero, scale 0. -(define (jbd-int-quot a b) - (when (= 0 (jbigdec-unscaled b)) - (jolt-throw (jolt-host-throwable "java.lang.ArithmeticException" "Divide by zero"))) - (let-values (((ua ub s) (jbd-align a b))) (make-jbigdec (quotient ua ub) 0))) -(define (jbd-int-rem a b) - (when (= 0 (jbigdec-unscaled b)) - (jolt-throw (jolt-host-throwable "java.lang.ArithmeticException" "Divide by zero"))) - (let-values (((ua ub s) (jbd-align a b))) - (make-jbigdec (remainder ua ub) (max (jbigdec-scale a) (jbigdec-scale b))))) - -;; scale-independent ordering: compare unscaled values aligned to a common scale. -(define (jbd-compare2 a b) - (let-values (((ua ub s) (jbd-align a b))) (cond ((< ua ub) -1) ((> ua ub) 1) (else 0)))) - -;; --- *math-context* (with-precision) ----------------------------------------- -;; with-precision binds clojure.core/*math-context* to {:precision N :rounding -;; MODE}; every exact bigdec result rounds through it (java.math.MathContext). -(define jbd-kw-precision (keyword #f "precision")) -(define jbd-kw-rounding (keyword #f "rounding")) -(define (jbd-math-context) - (let ((mc (var-deref "clojure.core" "*math-context*"))) - (if (jolt-nil? mc) #f mc))) -(define (jbd-mc-precision mc) (jolt-get mc jbd-kw-precision)) -(define (jbd-mc-mode mc) - (let ((r (jolt-get mc jbd-kw-rounding))) - (cond ((symbol-t? r) (symbol-t-name r)) - ((string? r) r) - (else "HALF_UP")))) - -;; should |value| = q + r/div (0 <= r < div) round up in magnitude? neg is the -;; value's sign; r/div may be exact rationals (the division path). -(define (jbd-round-inc? q r div mode neg) - (cond ((= r 0) #f) - ((string=? mode "UP") #t) - ((string=? mode "DOWN") #f) - ((string=? mode "CEILING") (not neg)) - ((string=? mode "FLOOR") neg) - ((string=? mode "HALF_DOWN") (> (* 2 r) div)) - ((string=? mode "HALF_EVEN") - (let ((c (- (* 2 r) div))) - (cond ((> c 0) #t) ((< c 0) #f) (else (odd? q))))) - ((string=? mode "UNNECESSARY") - (jolt-throw (jolt-host-throwable "java.lang.ArithmeticException" "Rounding necessary"))) - (else (>= (* 2 r) div)))) ; HALF_UP, the MathContext default - -(define (jbd-digits n) (string-length (number->string (abs n)))) -;; round a bigdec to `prec` significant digits with `mode` (a RoundingMode name). -(define (jbd-round-prec bd prec mode) - (let ((u (jbigdec-unscaled bd)) (s (jbigdec-scale bd))) - (if (= u 0) - bd - (let ((digs (jbd-digits u))) - (if (<= digs prec) - bd - (let* ((drop (- digs prec)) (div (expt 10 drop)) - (neg (< u 0)) (au (abs u)) - (q (quotient au div)) (r (remainder au div)) - (q2 (if (jbd-round-inc? q r div mode neg) (+ q 1) q)) - (res (make-jbigdec (if neg (- q2) q2) (- s drop)))) - ;; a carry can add a digit back (99 -> 100 at precision 2) - (if (> (jbd-digits q2) prec) (jbd-round-prec res prec mode) res))))))) -(define (jbd-mc-round x) - (let ((mc (and (jbigdec? x) (jbd-math-context)))) - (if mc (jbd-round-prec x (jbd-mc-precision mc) (jbd-mc-mode mc)) x))) - -;; A binary op over operands that may mix bigdec / integer / flonum. flonum-op is -;; the native fallback for the double-contagion path; bd-op is the exact bigdec op -;; (its result rounds through a bound *math-context*). -(define (jbd-binop flonum-op bd-op a b) - (if (or (flonum? a) (flonum? b)) - (flonum-op (if (jbigdec? a) (jbigdec->flonum a) a) - (if (jbigdec? b) (jbigdec->flonum b) b)) - (jbd-mc-round (bd-op (jbd-coerce a) (jbd-coerce b))))) - -;; --- variadic engine ops (Phase-2 emit targets + value-position folds) ------- -(define (jbd-fold flonum-op bd-op init xs) - (let loop ((acc init) (rest xs)) - (if (null? rest) acc (loop (jbd-binop flonum-op bd-op acc (car rest)) (cdr rest))))) - -(define (jbd-add . xs) - (cond ((null? xs) (make-jbigdec 0 0)) - ((null? (cdr xs)) (car xs)) - (else (jbd-fold + jbd2+ (car xs) (cdr xs))))) -(define (jbd-sub . xs) - (cond ((null? xs) (error #f "- needs at least 1 arg")) - ((null? (cdr xs)) (if (jbigdec? (car xs)) (jbd-negate (car xs)) (- (car xs)))) - (else (jbd-fold - jbd2- (car xs) (cdr xs))))) -(define (jbd-mul . xs) - (cond ((null? xs) (make-jbigdec 1 0)) - ((null? (cdr xs)) (car xs)) - (else (jbd-fold * jbd2* (car xs) (cdr xs))))) -(define (jbd-div . xs) - (cond ((null? xs) (error #f "/ needs at least 1 arg")) - ((null? (cdr xs)) (jbd-binop / jbd2-div (make-jbigdec 1 0) (car xs))) - (else (jbd-fold / jbd2-div (car xs) (cdr xs))))) - -;; comparison / predicate helpers (Phase-2 emit targets). A flonum operand demotes -;; to the native comparison on the flonum values. -(define (jbd-cmp-num op flop a b) - (if (or (flonum? a) (flonum? b)) - (flop (if (jbigdec? a) (jbigdec->flonum a) a) (if (jbigdec? b) (jbigdec->flonum b) b)) - (op (jbd-compare2 (jbd-coerce a) (jbd-coerce b)) 0))) -(define (jbd-lt? a b) (jbd-cmp-num < < a b)) -(define (jbd-gt? a b) (jbd-cmp-num > > a b)) -(define (jbd-le? a b) (jbd-cmp-num <= <= a b)) -(define (jbd-ge? a b) (jbd-cmp-num >= >= a b)) -(define (jbd-zero? a) (= 0 (jbigdec-unscaled a))) -(define (jbd-pos? a) (> (jbigdec-unscaled a) 0)) -(define (jbd-neg? a) (< (jbigdec-unscaled a) 0)) -(define (jbd-quot a b) (jbd-int-quot (jbd-coerce a) (jbd-coerce b))) -(define (jbd-rem a b) (jbd-int-rem (jbd-coerce a) (jbd-coerce b))) - -;; min/max compare by value but return the ORIGINAL operand (its type and scale -;; unchanged), matching java/Clojure: (min 1M 2.0) -> 1M, (max 1M 2.0) -> 2.0, -;; (min 1.50M 2M) -> 1.50M. Comparison handles a bigdec mixed with an int / flonum. -(define (jbd-value-compare a b) - (if (or (flonum? a) (flonum? b)) - (let ((fa (if (jbigdec? a) (jbigdec->flonum a) a)) (fb (if (jbigdec? b) (jbigdec->flonum b) b))) - (cond ((< fa fb) -1) ((> fa fb) 1) (else 0))) - (jbd-compare2 (jbd-coerce a) (jbd-coerce b)))) -;; strict comparison so a tie keeps the second operand, like Clojure's -;; (if (< x y) x y) / (if (> x y) x y): (max 1.5M 1.50M) -> 1.50M. -(define (jbd-min2 a b) (if (< (jbd-value-compare a b) 0) a b)) -(define (jbd-max2 a b) (if (> (jbd-value-compare a b) 0) a b)) -(define (jbd-min x . xs) (fold-left jbd-min2 x xs)) -(define (jbd-max x . xs) (fold-left jbd-max2 x xs)) - -;; --- wire into the value model ---------------------------------------------- -(def-var! "clojure.core" "bigdec" jolt-bigdec) - -;; The seq.ss binary numeric dispatch (jolt-add2/… and the jolt-n* macros) routes -;; any op whose operand is outside Chez's tower to the *-slow hooks; extend each -;; with a bigdec arm. Every arithmetic position (call, value, higher-order) -;; funnels through these, so contagion and *math-context* rounding apply -;; uniformly. min/max need no arm: the generic jolt-min2 compares through -;; jolt-num-cmp-slow and returns the original operand. -(set! jolt-num-slow? - (let ((prev jolt-num-slow?)) (lambda (x) (or (jbigdec? x) (prev x))))) -(define (jbd-extend-hook prev bd-op) - (lambda (a b) - (if (or (jbigdec? a) (jbigdec? b)) (bd-op a b) (prev a b)))) -(set! jolt-add-slow (jbd-extend-hook jolt-add-slow (lambda (a b) (jbd-binop + jbd2+ a b)))) -(set! jolt-sub-slow (jbd-extend-hook jolt-sub-slow (lambda (a b) (jbd-binop - jbd2- a b)))) -(set! jolt-mul-slow (jbd-extend-hook jolt-mul-slow (lambda (a b) (jbd-binop * jbd2* a b)))) -(set! jolt-div-slow (jbd-extend-hook jolt-div-slow (lambda (a b) (jbd-binop / jbd2-div a b)))) -(set! jolt-num-cmp-slow - (let ((prev jolt-num-cmp-slow)) - (lambda (a b) - (if (and (or (jbigdec? a) (jbigdec? b)) (jbd-numberish? a) (jbd-numberish? b)) - (jbd-value-compare a b) - (prev a b))))) -;; quot/rem/mod: a double operand demotes to the double path; exact operands use -;; the integer-division bigdec ops (mod = rem, floor-adjusted to the divisor's sign). -(define (jbd->num x) (if (jbigdec? x) (jbigdec->flonum x) x)) -(set! jolt-quot-slow - (jbd-extend-hook jolt-quot-slow - (lambda (a b) (if (or (flonum? a) (flonum? b)) - (jolt-quot (jbd->num a) (jbd->num b)) - (jbd-int-quot (jbd-coerce a) (jbd-coerce b)))))) -(set! jolt-rem-slow - (jbd-extend-hook jolt-rem-slow - (lambda (a b) (if (or (flonum? a) (flonum? b)) - (jolt-rem (jbd->num a) (jbd->num b)) - (jbd-int-rem (jbd-coerce a) (jbd-coerce b)))))) -(set! jolt-mod-slow - (jbd-extend-hook jolt-mod-slow - (lambda (a b) - (if (or (flonum? a) (flonum? b)) - (jolt-mod (jbd->num a) (jbd->num b)) - (let* ((bb (jbd-coerce b)) - (m (jbd-int-rem (jbd-coerce a) bb))) - (if (or (jbd-zero? m) (eq? (jbd-neg? m) (jbd-neg? bb))) m (jbd2+ m bb))))))) -;; unary shims: inc/dec and the sign predicates take a bigdec arm. set! updates -;; call-position references; the re-def-var! updates the var cell AND claims the -;; wrapped proc's class name before the prelude's inc'/dec' aliases are defined -;; ((type inc) stays clojure.core$inc — first def wins in the class registry). -(define jbd-one (make-jbigdec 1 0)) -(set! jolt-inc (let ((prev jolt-inc)) (lambda (x) (if (jbigdec? x) (jbd-mc-round (jbd2+ x jbd-one)) (prev x))))) -(set! jolt-dec (let ((prev jolt-dec)) (lambda (x) (if (jbigdec? x) (jbd-mc-round (jbd2- x jbd-one)) (prev x))))) -(set! jolt-zero? (let ((prev jolt-zero?)) (lambda (x) (if (jbigdec? x) (jbd-zero? x) (prev x))))) -(set! jolt-pos? (let ((prev jolt-pos?)) (lambda (x) (if (jbigdec? x) (jbd-pos? x) (prev x))))) -(set! jolt-neg? (let ((prev jolt-neg?)) (lambda (x) (if (jbigdec? x) (jbd-neg? x) (prev x))))) -;; a BigDecimal IS a number (java.lang.Number): extend the number? native so the -;; predicate — and everything defined over it (num, =='s guard) — accepts it. -;; The compiled fast paths test Chez number? directly and are unaffected. -(set! jolt-number? (let ((prev jolt-number?)) (lambda (x) (if (jbigdec? x) #t (prev x))))) -(def-var! "clojure.core" "number?" jolt-number?) -(def-var! "clojure.core" "inc" jolt-inc) -(def-var! "clojure.core" "dec" jolt-dec) -(def-var! "clojure.core" "zero?" jolt-zero?) -(def-var! "clojure.core" "pos?" jolt-pos?) -(def-var! "clojure.core" "neg?" jolt-neg?) - -;; rationalize: reference Clojure goes through BigDecimal.valueOf(double) — the -;; SHORTEST decimal print of the double, not its exact binary value — so -;; (rationalize 1.1) is 11/10. A bigdec is exact already; other exacts pass through. -(define (jolt-rationalize x) - (cond ((jbigdec? x) (/ (jbigdec-unscaled x) (expt 10 (jbigdec-scale x)))) - ((flonum? x) - (if (or (nan? x) (infinite? x)) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - (string-append "Invalid input: " (number->string x)))) - (let ((bd (jolt-bigdec-from-string (jolt-num->string x)))) - (/ (jbigdec-unscaled bd) (expt 10 (jbigdec-scale bd)))))) - ((number? x) x) - (else (jolt-num-cast-throw x)))) -(def-var! "clojure.core" "rationalize" jolt-rationalize) - -;; double/float of a bigdec is its flonum value. -(set! jolt-double-slow - (let ((prev jolt-double-slow)) - (lambda (x) (if (jbigdec? x) (jbigdec->flonum x) (prev x))))) - -;; narrow casts truncate a bigdec like Number.longValue. -(set! jolt-cast-truncate-slow - (let ((prev jolt-cast-truncate-slow)) - (lambda (x) - (if (jbigdec? x) - (truncate (/ (jbigdec-unscaled x) (expt 10 (jbigdec-scale x)))) - (prev x))))) - -;; compare: add a bigdec arm (enables compare / sort / sorted collections). A -;; bigdec vs a plain number compares by value; bigdec vs bigdec is scale-independent. -(define jbd-prev-compare jolt-compare) -(define (jbd-numberish? x) (or (jbigdec? x) (number? x))) -(set! jolt-compare - (lambda (a b) - (if (and (or (jbigdec? a) (jbigdec? b)) (jbd-numberish? a) (jbd-numberish? b)) - (if (or (flonum? a) (flonum? b)) - (let ((fa (if (jbigdec? a) (jbigdec->flonum a) a)) - (fb (if (jbigdec? b) (jbigdec->flonum b) b))) - (cond ((< fa fb) -1) ((> fa fb) 1) (else 0))) - (jbd-compare2 (jbd-coerce a) (jbd-coerce b))) - (jbd-prev-compare a b)))) -(def-var! "clojure.core" "compare" jolt-compare) - -;; equality: a bigdec equals only another bigdec, by value (matching (= 3M 3) = false). -(register-eq-arm! (lambda (a b) (or (jbigdec? a) (jbigdec? b))) - (lambda (a b) (and (jbigdec? a) (jbigdec? b) (jbigdec=? a b)))) - -;; str drops the M; pr/pr-str keep it. -(register-str-render! jbigdec? jbigdec->string) -(register-pr-arm! jbigdec? (lambda (x) (string-append (jbigdec->string x) "M"))) - -;; class / decimal? -(register-class-arm! jbigdec? (lambda (x) "java.math.BigDecimal")) -(set! jolt-decimal? (lambda (x) (jbigdec? x))) -(def-var! "clojure.core" "decimal?" jolt-decimal?) diff --git a/host/chez/java/byte-buffer.ss b/host/chez/java/byte-buffer.ss deleted file mode 100644 index e2a7f62..0000000 --- a/host/chez/java/byte-buffer.ss +++ /dev/null @@ -1,85 +0,0 @@ -;; byte-buffer.ss — java.nio.ByteBuffer over a jolt byte-array. A buffer is a -;; jhost tagged "byte-buffer" with mutable #(backing-array position limit); the -;; backing is a jolt byte-array (vector of 0..255). Covers the slice of the API -;; portable code reaches for — wrap / get(byte[]) / array / remaining / position / -;; limit / duplicate / flip / rewind — e.g. cognitect aws-api wrapping blob bytes. - -(define (make-byte-buffer backing pos limit) (make-jhost "byte-buffer" (vector backing pos limit))) -(define (bb? x) (and (jhost? x) (string=? (jhost-tag x) "byte-buffer"))) -(define (bb-backing b) (vector-ref (jhost-state b) 0)) -(define (bb-pos b) (vector-ref (jhost-state b) 1)) -(define (bb-limit b) (vector-ref (jhost-state b) 2)) -(define (bb-pos! b n) (vector-set! (jhost-state b) 1 n)) -(define (bb-limit! b n) (vector-set! (jhost-state b) 2 n)) -(define (bb-capacity b) (vector-length (jolt-array-vec (bb-backing b)))) - -;; (ByteBuffer/wrap ba) | (ByteBuffer/wrap ba off len) | (ByteBuffer/allocate n) -(register-class-statics! "ByteBuffer" - (list - (cons "wrap" (lambda (ba . rest) - (let ((cap (vector-length (jolt-array-vec ba)))) - (if (pair? rest) - (let ((off (jnum->exact (car rest))) (len (jnum->exact (cadr rest)))) - (make-byte-buffer ba off (+ off len))) - (make-byte-buffer ba 0 cap))))) - (cons "allocate" (lambda (n) - (let ((cap (jnum->exact n))) - (make-byte-buffer (make-jolt-array (make-vector cap 0) 'byte) 0 cap)))) - ;; jolt has one heap; a direct buffer is just a buffer here. - (cons "allocateDirect" (lambda (n) - (let ((cap (jnum->exact n))) - (make-byte-buffer (make-jolt-array (make-vector cap 0) 'byte) 0 cap)))))) - -(register-host-methods! "byte-buffer" - (list - (cons "remaining" (lambda (self) (->num (- (bb-limit self) (bb-pos self))))) - (cons "hasRemaining" (lambda (self) (> (bb-limit self) (bb-pos self)))) - ;; position / limit are getters with no arg, setters (returning the buffer) with one - (cons "position" (lambda (self . a) - (if (pair? a) (begin (bb-pos! self (jnum->exact (car a))) self) (->num (bb-pos self))))) - (cons "limit" (lambda (self . a) - (if (pair? a) (begin (bb-limit! self (jnum->exact (car a))) self) (->num (bb-limit self))))) - (cons "capacity" (lambda (self) (->num (bb-capacity self)))) - (cons "hasArray" (lambda (self) #t)) - (cons "array" (lambda (self) (bb-backing self))) - (cons "duplicate" (lambda (self) (make-byte-buffer (bb-backing self) (bb-pos self) (bb-limit self)))) - (cons "rewind" (lambda (self) (bb-pos! self 0) self)) - (cons "flip" (lambda (self) (bb-limit! self (bb-pos self)) (bb-pos! self 0) self)) - (cons "clear" (lambda (self) (bb-pos! self 0) (bb-limit! self (bb-capacity self)) self)) - ;; (.get dst) | (.get dst off len): bulk copy from position into a byte-array, - ;; advancing position. Returns the buffer like the JVM. - ;; (.put src): copy bytes into the buffer at position, advancing it. src is - ;; another ByteBuffer (its remaining bytes), a byte-array, or a single byte. - (cons "put" (lambda (self src . rest) - (let ((dv (jolt-array-vec (bb-backing self))) (dp (bb-pos self))) - (cond - ((bb? src) - (let* ((sv (jolt-array-vec (bb-backing src))) (sp (bb-pos src)) - (n (- (bb-limit src) sp))) - (do ((i 0 (fx+ i 1))) ((fx=? i n)) - (vector-set! dv (+ dp i) (vector-ref sv (+ sp i)))) - (bb-pos! src (bb-limit src)) (bb-pos! self (+ dp n)))) - ((jolt-array? src) - (let* ((sv (jolt-array-vec src)) (n (vector-length sv))) - (do ((i 0 (fx+ i 1))) ((fx=? i n)) - (vector-set! dv (+ dp i) (vector-ref sv i))) - (bb-pos! self (+ dp n)))) - (else (vector-set! dv dp (jnum->exact src)) (bb-pos! self (+ dp 1)))) - self))) - (cons "get" (lambda (self dst . rest) - (let* ((src (jolt-array-vec (bb-backing self))) - (dv (jolt-array-vec dst)) - (off (if (pair? rest) (jnum->exact (car rest)) 0)) - (len (if (and (pair? rest) (pair? (cdr rest))) (jnum->exact (cadr rest)) (vector-length dv))) - (p (bb-pos self))) - (do ((i 0 (+ i 1))) ((= i len)) - (vector-set! dv (+ off i) (vector-ref src (+ p i)))) - (bb-pos! self (+ p len)) - self))))) - -(register-class-arm! bb? (lambda (x) "java.nio.ByteBuffer")) -(register-instance-check-arm! - (lambda (type-sym val) - (if (and (symbol-t? type-sym) (bb? val) - (member (last-dot (symbol-t-name type-sym)) '("ByteBuffer"))) - #t 'pass))) diff --git a/host/chez/java/class-hierarchy.ss b/host/chez/java/class-hierarchy.ss deleted file mode 100644 index 484a908..0000000 --- a/host/chez/java/class-hierarchy.ss +++ /dev/null @@ -1,261 +0,0 @@ -;; class-hierarchy.ss — one JVM class/interface graph, the single source of truth -;; for every "what classes does this satisfy" question. value-host-tags (protocol -;; dispatch), instance?, isa?/supers/ancestors, and the exception hierarchy all -;; derive from the ONE table here instead of maintaining parallel hand-kept lists -;; that drift apart. -;; -;; The graph is keyed by canonical (FQN) class name -> its DIRECT super -;; interfaces/classes (also FQN). Transitivity is computed (jch-closure), so a row -;; lists only what a class directly extends/implements, matching the JVM source. -;; -;; It is OPEN: a library registers a class and its supers with -;; jolt.host/register-class-supers! (plus a class-arm in host-class.ss to map its -;; values to that class name), and every derived view picks the class up with no -;; core change. Loaded before records.ss so value-host-tags can derive from it. - -;; canonical-name -> list of direct super canonical-names. Mutable + extensible. -(define jvm-class-parents (make-hashtable string-hash string=?)) -;; closure cache, invalidated whenever the graph is extended. -(define jch-closure-cache (make-hashtable string-hash string=?)) -(define jch-tags-cache (make-hashtable string-hash string=?)) - -;; Merge direct supers for a class (union with any already registered). Public so -;; libraries can graft their own classes onto the modeled hierarchy. -(define (jch-register-supers! name supers) - (let ((cur (hashtable-ref jvm-class-parents name '()))) - (hashtable-set! jvm-class-parents name - (let add ((ss supers) (acc cur)) - (cond ((null? ss) acc) - ((member (car ss) acc) (add (cdr ss) acc)) - (else (add (cdr ss) (append acc (list (car ss))))))))) - (hashtable-clear! jch-closure-cache) - (hashtable-clear! jch-tags-cache)) - -(define (jch-direct-supers name) (hashtable-ref jvm-class-parents name '())) - -;; Replace a class's direct supers outright (defrecord re-declares the row its -;; deftype half registered). Same cache invalidation as a register. -(define (jch-set-supers! name supers) - (hashtable-set! jvm-class-parents name supers) - (hashtable-clear! jch-closure-cache) - (hashtable-clear! jch-tags-cache) - (set! jch-known-cache #f) - (set! jch-simple->fqn-cache #f)) - -;; transitive supers of NAME (canonical), excluding NAME and Object; Object is the -;; universal root supplied by callers. Breadth-first, deduped, stable order. -(define (jch-closure name) - (or (hashtable-ref jch-closure-cache name #f) - (let ((result - (let loop ((pending (jch-direct-supers name)) (seen '())) - (cond ((null? pending) (reverse seen)) - ((member (car pending) seen) (loop (cdr pending) seen)) - (else (loop (append (jch-direct-supers (car pending)) (cdr pending)) - (cons (car pending) seen))))))) - (hashtable-set! jch-closure-cache name result) - result))) - -;; ns segment munging for a JVM-spelled class name: dashes become underscores -;; (clojure.core-test.x -> clojure.core_test.x). -(define (jch-munge-segments s) - (list->string (map (lambda (c) (if (char=? c #\-) #\_ c)) (string->list s)))) - -(define (jch-last-segment s) - (let loop ((i (- (string-length s) 1))) - (cond ((< i 0) s) - ((char=? (string-ref s i) #\.) (substring s (+ i 1) (string-length s))) - ((char=? (string-ref s i) #\$) (substring s (+ i 1) (string-length s))) - (else (loop (- i 1)))))) - -;; The protocol-dispatch / instance? tag list for a value of class NAME: the class -;; and its whole ancestry, each in BOTH canonical and simple spelling (extend-protocol -;; and instance? accept either "Associative" or "clojure.lang.Associative"), plus -;; "Object". Memoized — this is on the hot protocol-dispatch path. -(define (jch-tags name) - (or (hashtable-ref jch-tags-cache name #f) - (let* ((chain (cons name (jch-closure name))) - (result - (let build ((cs chain) (acc '())) - (if (null? cs) - (reverse (cons "Object" acc)) - (let* ((fqn (car cs)) - (simple (jch-last-segment fqn)) - (acc1 (if (member fqn acc) acc (cons fqn acc))) - (acc2 (if (or (string=? simple fqn) (member simple acc1)) - acc1 (cons simple acc1)))) - (build (cdr cs) acc2)))))) - (hashtable-set! jch-tags-cache name result) - result))) - -;; Is WANTED (canonical or simple) the class CHILD (canonical) or one of its -;; ancestors? Object is every class's root. Matched by full name or last segment so -;; "IOException" and "java.io.IOException" both hit. -(define (jch-isa? child wanted) - (let ((wseg (jch-last-segment wanted))) - (or (string=? wanted "java.lang.Object") (string=? wanted "Object") - (let loop ((names (cons child (jch-closure child)))) - (cond ((null? names) #f) - ((or (string=? wanted (car names)) - (string=? wseg (jch-last-segment (car names)))) #t) - (else (loop (cdr names)))))))) - -;; Does the graph model WANTED at all (as a class or as any class's ancestor)? Used -;; by instance? to decide between a definitive #f and 'pass (defer to other arms). -(define jch-known-cache #f) -(define (jch-known? wanted) - (when (not jch-known-cache) - (set! jch-known-cache (make-hashtable string-hash string=?)) - (let-values (((keys vals) (hashtable-entries jvm-class-parents))) - (vector-for-each - (lambda (k supers) - (hashtable-set! jch-known-cache k #t) - (hashtable-set! jch-known-cache (jch-last-segment k) #t) - (for-each (lambda (s) - (hashtable-set! jch-known-cache s #t) - (hashtable-set! jch-known-cache (jch-last-segment s) #t)) - supers)) - keys vals))) - (or (hashtable-ref jch-known-cache wanted #f) - (hashtable-ref jch-known-cache (jch-last-segment wanted) #f))) - -;; simple last-segment -> canonical FQN for a modeled class (first registered -;; wins). Lets a simple exception name (from chez-condition-exc-class) resolve to -;; its graph key so the exception hierarchy answers through the one graph. -(define jch-simple->fqn-cache #f) -(define (jch-fqn-of-simple name) - (when (not jch-simple->fqn-cache) - (set! jch-simple->fqn-cache (make-hashtable string-hash string=?)) - (let-values (((keys vals) (hashtable-entries jvm-class-parents))) - (vector-for-each - (lambda (k supers) - (for-each (lambda (n) - (let ((seg (jch-last-segment n))) - (when (not (hashtable-ref jch-simple->fqn-cache seg #f)) - (hashtable-set! jch-simple->fqn-cache seg n)))) - (cons k supers))) - keys vals))) - (or (hashtable-ref jch-simple->fqn-cache name #f) name)) - -;; A register also invalidates the derived caches. -(define jch-register-supers!-inner jch-register-supers!) -(set! jch-register-supers! - (lambda (name supers) - (set! jch-known-cache #f) - (set! jch-simple->fqn-cache #f) - (jch-register-supers!-inner name supers))) - -;; ---- interface marking --------------------------------------------------------- -;; The JVM distinguishes a concrete class (whose bases/supers chain roots at -;; Object) from an interface (whose don't). The graph marks the modeled -;; interfaces; anything unmarked is treated as a concrete class. -(define jch-interface-set (make-hashtable string-hash string=?)) -(define (jch-mark-interface! name) (hashtable-set! jch-interface-set name #t)) -(define (jch-interface? name) (hashtable-ref jch-interface-set name #f)) -(for-each jch-mark-interface! - '("clojure.lang.Seqable" "clojure.lang.Sequential" "clojure.lang.Sorted" - "clojure.lang.Reversible" "clojure.lang.Indexed" "clojure.lang.Counted" - "clojure.lang.Named" "clojure.lang.Fn" "clojure.lang.IFn" - "clojure.lang.IPersistentCollection" "clojure.lang.ISeq" - "clojure.lang.Associative" "clojure.lang.ILookup" - "clojure.lang.IPersistentStack" "clojure.lang.IPersistentVector" - "clojure.lang.IPersistentMap" "clojure.lang.IPersistentSet" - "clojure.lang.IPersistentList" "clojure.lang.IObj" "clojure.lang.IMeta" - "clojure.lang.IDeref" "clojure.lang.IRecord" "clojure.lang.IType" - "clojure.lang.IHashEq" "clojure.lang.IEditableCollection" - "clojure.lang.IExceptionInfo" "clojure.lang.IReduceInit" - "java.util.List" "java.util.Set" "java.util.Collection" "java.util.Map" - "java.util.Iterator" "java.lang.Iterable" "java.lang.CharSequence" - "java.lang.Comparable" "java.lang.Runnable" - "java.util.concurrent.Callable" "java.io.Serializable")) - -;; ---- seed the built-in graph: direct supers only, faithful to the JVM --------- -;; core clojure.lang interfaces -(jch-register-supers! "clojure.lang.IPersistentCollection" '("clojure.lang.Seqable")) -(jch-register-supers! "clojure.lang.ISeq" '("clojure.lang.IPersistentCollection")) -(jch-register-supers! "clojure.lang.Associative" '("clojure.lang.IPersistentCollection" "clojure.lang.ILookup")) -(jch-register-supers! "clojure.lang.IPersistentStack" '("clojure.lang.IPersistentCollection")) -(jch-register-supers! "clojure.lang.IPersistentVector" '("clojure.lang.Associative" "clojure.lang.Sequential" - "clojure.lang.IPersistentStack" "clojure.lang.Reversible" - "clojure.lang.Indexed")) -(jch-register-supers! "clojure.lang.IPersistentMap" '("java.lang.Iterable" "clojure.lang.Associative" "clojure.lang.Counted")) -(jch-register-supers! "clojure.lang.IPersistentSet" '("clojure.lang.IPersistentCollection" "clojure.lang.Counted")) -(jch-register-supers! "clojure.lang.IPersistentList" '("clojure.lang.Sequential" "clojure.lang.IPersistentStack")) -(jch-register-supers! "clojure.lang.IObj" '("clojure.lang.IMeta")) -(jch-register-supers! "clojure.lang.IFn" '("java.lang.Runnable" "java.util.concurrent.Callable")) -(jch-register-supers! "clojure.lang.Fn" '("clojure.lang.IFn")) -(jch-register-supers! "clojure.lang.AFn" '("clojure.lang.IFn")) -(jch-register-supers! "clojure.lang.AFunction" '("clojure.lang.AFn" "clojure.lang.Fn")) -;; java.util collection interfaces -(jch-register-supers! "java.util.List" '("java.util.Collection")) -(jch-register-supers! "java.util.Set" '("java.util.Collection")) -(jch-register-supers! "java.util.Collection" '("java.lang.Iterable")) -;; concrete collection classes -(jch-register-supers! "clojure.lang.APersistentVector" '("clojure.lang.IPersistentVector" "java.util.List")) -(jch-register-supers! "clojure.lang.PersistentVector" '("clojure.lang.APersistentVector" "clojure.lang.IObj" - "java.util.List" "java.lang.Comparable")) -(jch-register-supers! "clojure.lang.APersistentMap" '("clojure.lang.IPersistentMap" "java.util.Map")) -(jch-register-supers! "clojure.lang.PersistentArrayMap" '("clojure.lang.APersistentMap" "clojure.lang.IObj")) -(jch-register-supers! "clojure.lang.PersistentHashMap" '("clojure.lang.APersistentMap" "clojure.lang.IObj")) -(jch-register-supers! "clojure.lang.PersistentTreeMap" '("clojure.lang.APersistentMap" "clojure.lang.IObj" "clojure.lang.Sorted" "clojure.lang.Reversible")) -(jch-register-supers! "clojure.lang.APersistentSet" '("clojure.lang.IPersistentSet" "java.util.Set")) -(jch-register-supers! "clojure.lang.PersistentHashSet" '("clojure.lang.APersistentSet" "clojure.lang.IObj")) -(jch-register-supers! "clojure.lang.PersistentTreeSet" '("clojure.lang.APersistentSet" "clojure.lang.IObj" "clojure.lang.Sorted" "clojure.lang.Reversible")) -(jch-register-supers! "clojure.lang.ASeq" '("clojure.lang.ISeq" "clojure.lang.Sequential" "java.util.List")) -(jch-register-supers! "clojure.lang.PersistentList" '("clojure.lang.ASeq" "clojure.lang.IPersistentList" "clojure.lang.Counted")) -(jch-register-supers! "clojure.lang.PersistentList$EmptyList" '("clojure.lang.PersistentList")) -(jch-register-supers! "clojure.lang.LazySeq" '("clojure.lang.ISeq" "clojure.lang.Sequential" "java.util.List" "clojure.lang.IObj")) -(jch-register-supers! "clojure.lang.Cons" '("clojure.lang.ASeq")) -(jch-register-supers! "clojure.lang.PersistentQueue" '("clojure.lang.IPersistentList" "clojure.lang.IPersistentCollection" "java.util.Collection")) -;; scalars / named / callable -(jch-register-supers! "clojure.lang.Keyword" '("clojure.lang.IFn" "clojure.lang.Named" "java.lang.Comparable")) -(jch-register-supers! "clojure.lang.Symbol" '("clojure.lang.IObj" "clojure.lang.IFn" "clojure.lang.Named" "java.lang.Comparable")) -(jch-register-supers! "clojure.lang.Var" '("clojure.lang.IDeref" "clojure.lang.IFn")) -(jch-register-supers! "clojure.lang.Atom" '("clojure.lang.IDeref")) -(jch-register-supers! "clojure.lang.Ratio" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "clojure.lang.BigInt" '("java.lang.Number")) -(jch-register-supers! "java.lang.String" '("java.lang.CharSequence" "java.lang.Comparable")) -(jch-register-supers! "java.lang.Long" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.lang.Integer" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.lang.Double" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.lang.Float" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.math.BigDecimal" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.math.BigInteger" '("java.lang.Number" "java.lang.Comparable")) -(jch-register-supers! "java.lang.Boolean" '("java.lang.Comparable")) -(jch-register-supers! "java.lang.Character" '("java.lang.Comparable")) -(jch-register-supers! "java.util.UUID" '("java.lang.Comparable")) -;; exception hierarchy (folds in the former exception-parent table) -(jch-register-supers! "java.lang.Exception" '("java.lang.Throwable")) -(jch-register-supers! "java.lang.RuntimeException" '("java.lang.Exception")) -(jch-register-supers! "clojure.lang.ExceptionInfo" '("java.lang.RuntimeException" "clojure.lang.IExceptionInfo")) -(jch-register-supers! "java.lang.IllegalArgumentException" '("java.lang.RuntimeException")) -(jch-register-supers! "clojure.lang.ArityException" '("java.lang.IllegalArgumentException")) -(jch-register-supers! "java.lang.NumberFormatException" '("java.lang.IllegalArgumentException")) -(jch-register-supers! "java.lang.IllegalStateException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.lang.UnsupportedOperationException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.lang.ArithmeticException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.lang.NullPointerException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.lang.ClassCastException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.lang.IndexOutOfBoundsException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.util.ConcurrentModificationException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.util.NoSuchElementException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.io.UncheckedIOException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.time.DateTimeException" '("java.lang.RuntimeException")) -(jch-register-supers! "java.time.format.DateTimeParseException" '("java.time.DateTimeException")) -(jch-register-supers! "java.lang.InterruptedException" '("java.lang.Exception")) -(jch-register-supers! "java.io.IOException" '("java.lang.Exception")) -(jch-register-supers! "java.io.InterruptedIOException" '("java.io.IOException")) -(jch-register-supers! "java.io.FileNotFoundException" '("java.io.IOException")) -(jch-register-supers! "java.io.UnsupportedEncodingException" '("java.io.IOException")) -(jch-register-supers! "java.net.UnknownHostException" '("java.io.IOException")) -(jch-register-supers! "java.net.SocketException" '("java.io.IOException")) -(jch-register-supers! "java.net.ConnectException" '("java.net.SocketException")) -(jch-register-supers! "java.net.SocketTimeoutException" '("java.io.InterruptedIOException")) -(jch-register-supers! "java.net.MalformedURLException" '("java.io.IOException")) -(jch-register-supers! "javax.net.ssl.SSLException" '("java.io.IOException")) -(jch-register-supers! "java.lang.Error" '("java.lang.Throwable")) -(jch-register-supers! "java.lang.AssertionError" '("java.lang.Error")) -;; Throwable's only super is Object (universal), so no row needed for it. - -;; Public seam: libraries extend the modeled hierarchy. -(def-var! "jolt.host" "register-class-supers!" - (lambda (name supers) (jch-register-supers! name (seq->list supers)) jolt-nil)) diff --git a/host/chez/joltc-selfbuild-smoke.sh b/host/chez/joltc-selfbuild-smoke.sh deleted file mode 100644 index b9f267a..0000000 --- a/host/chez/joltc-selfbuild-smoke.sh +++ /dev/null @@ -1,122 +0,0 @@ -#!/bin/sh -# joltc self-build smoke (jolt-eaj): build joltc as a self-contained binary, then -# use THAT binary to compile a jolt app with Chez and cc removed from the -# environment — the whole point of the feature. The produced app must then run -# and match the same expected output as build-smoke.sh. -root="$(CDPATH= cd -- "$(dirname -- "$0")/../.." && pwd)" -cd "$root" - -# Preflight: building joltc itself needs the Chez kernel dev files (libkernel.a + -# scheme.h) and a C compiler, same as build-smoke.sh. A distro chezscheme package -# ships neither, so skip there (CI included). -csv="$JOLT_CHEZ_CSV" -if [ -z "$csv" ]; then - chez_bin="$(command -v chez || command -v scheme || command -v petite || true)" - if [ -n "$chez_bin" ]; then - base="$(cd "$(dirname "$chez_bin")/.." 2>/dev/null && pwd)" - for d in "$base"/lib/csv*/*/; do - [ -f "${d}libkernel.a" ] && csv="${d%/}" && break - done - fi -fi -if ! command -v cc >/dev/null 2>&1 || [ -z "$csv" ] || [ ! -f "$csv/scheme.h" ] || [ ! -f "$csv/libkernel.a" ]; then - echo "joltc self-build smoke: skipped (Chez kernel dev files or C compiler not available)" - exit 0 -fi -export JOLT_CHEZ_CSV="$csv" - -# 1. Build joltc (debug profile — faster; the self-contained app-build mechanism -# is identical to release, only Chez compile settings differ). -joltc="$root/target/debug/joltc" -echo "joltc self-build smoke: building $joltc" -if ! chez --script host/chez/build-joltc.ss debug "$joltc" >/dev/null 2>&1; then - echo " FAIL: build-joltc.ss exited non-zero" - exit 1 -fi -[ -x "$joltc" ] || { echo " FAIL: no joltc executable produced"; exit 1; } - -# 2. The distributed joltc must run with no Chez install: a basic eval. -got_e="$(env -i HOME="$HOME" "$joltc" -e '(reduce + (range 10))' 2>&1)" -if [ "$got_e" != "45" ]; then - echo " FAIL: joltc -e under empty env gave '$got_e', want 45" - exit 1 -fi - -# 2b. JOLT_TRACE must take effect in the BUILT binary. The env check runs at -# runtime (the launcher), NOT at heap-build where JOLT_TRACE is always unset — so -# an uncaught error shows a tail-frame trace recovering the TCO-elided chain, and -# exactly ONE trace block (the launcher must not double-print it). -got_tr="$(env -i HOME="$HOME" JOLT_TRACE=1 "$joltc" -e '(defn a [x] (+ x 1)) (defn b [x] (a x)) (b :x)' 2>&1)" -if ! printf '%s' "$got_tr" | grep -q ' trace:' || ! printf '%s' "$got_tr" | grep -q 'b'; then - echo " FAIL: JOLT_TRACE=1 in the built joltc produced no tail-frame trace" - echo "--- got ---"; echo "$got_tr"; exit 1 -fi -if [ "$(printf '%s' "$got_tr" | grep -c ' trace:')" != "1" ]; then - echo " FAIL: built joltc double-printed the trace block" - echo "--- got ---"; echo "$got_tr"; exit 1 -fi - -# 3. Build an app through the distributed joltc with an EMPTY environment — no -# PATH at all, so no chez, no cc, no shell tools are reachable. This is the core -# guarantee: joltc compiles apps entirely on its own. -app="$(mktemp -d)/build-app" -cp -r "$root/test/chez/build-app" "$app" -out="$app/app" -echo "joltc self-build smoke: compiling app.core via the binary (no chez/cc on PATH)" -if ! env -i HOME="$HOME" JOLT_PWD="$app" "$joltc" build -m app.core -o "$out" >/dev/null 2>&1; then - echo " FAIL: self-contained jolt build exited non-zero" - rm -rf "$(dirname "$app")" - exit 1 -fi -[ -x "$out" ] || { echo " FAIL: no app executable produced"; rm -rf "$(dirname "$app")"; exit 1; } - -# 4. The produced app runs from a neutral cwd and matches build-smoke's output. -got="$(cd / && "$out" alpha bb ccc 2>&1)" -want='embedded resource ok -HELLO FROM A BUILT BINARY! -HELLO FROM A BUILT BINARY! -args: [alpha bb ccc] -sum: 10 -greet-default: greet:default -greet-loud: greet:loud -greet-soft: greet:soft' -rm -rf "$(dirname "$app")" -if [ "$got" != "$want" ]; then - echo " FAIL: produced app output mismatch" - echo "--- want ---"; echo "$want" - echo "--- got ----"; echo "$got" - exit 1 -fi - -# 5. Static native linking through the distributed joltc: it bundles the Chez -# kernel, so with the system cc (but still no external Chez) it re-links a stub -# that bakes a :jolt/native :static archive into the app. The app then calls the -# C function with the archive removed from disk. Uses the normal PATH so cc — and -# the kernel's link deps (lz4/…) — are found, but Chez stays out of the build. -napp="$(mktemp -d)/native-app" -mkdir -p "$napp/src/app" -printf 'int jolt_static_answer(void){return 42;}\n' > "$napp/greet.c" -cc -c "$napp/greet.c" -o "$napp/greet.o" && ar rcs "$napp/libgreet.a" "$napp/greet.o" -cat > "$napp/src/app/core.clj" <<'EOF' -(ns app.core (:require [jolt.ffi :as ffi])) -(ffi/defcfn answer "jolt_static_answer" [] :int) -(defn -main [& _] (println "answer:" (answer))) -EOF -cat > "$napp/deps.edn" </dev/null 2>&1; then - echo " FAIL: static native build via distributed joltc exited non-zero" - rm -rf "$(dirname "$napp")"; exit 1 -fi -rm -f "$napp/libgreet.a" "$napp/greet.o" # nothing to load at runtime -got_n="$(cd / && "$nout" 2>&1)" -rm -rf "$(dirname "$napp")" -if [ "$got_n" != "answer: 42" ]; then - echo " FAIL: static-linked app (via distributed joltc) output mismatch" - echo "--- got ----"; echo "$got_n"; exit 1 -fi -echo "joltc self-build smoke: passed (joltc runs + builds a working app with no external toolchain, incl. static native linking)" diff --git a/host/chez/lazy-bridge.ss b/host/chez/lazy-bridge.ss index 76e0043..86ed2df 100644 --- a/host/chez/lazy-bridge.ss +++ b/host/chez/lazy-bridge.ss @@ -49,13 +49,6 @@ (cseq-lazy x (lambda () (force-lazyseq coll))) (%ls-cons x coll)))) -;; (conj lazyseq x): conj onto a seq prepends, like any seq — (conj (rest xs) y). -;; rest returns a lazyseq, so this is a common path; without it conj reports the -;; lazyseq as an "unsupported collection". -(define %ls-conj1 jolt-conj1) -(set! jolt-conj1 (lambda (coll x) - (if (jolt-lazyseq? coll) (jolt-cons x coll) (%ls-conj1 coll x)))) - ;; A lazyseq is a NEW value type, so the dispatchers that DON'T route through ;; jolt-seq must learn it or a raw (unrealized) lazyseq escapes — e.g. the corpus ;; compares (= [1 3 5] (take-nth 2 …)) against the raw lazyseq, and jolt=2 would @@ -72,15 +65,10 @@ (set! jolt-nth (case-lambda ((coll i) (if (jolt-lazyseq? coll) (%ls-nth (jolt-seq coll) i) (%ls-nth coll i))) ((coll i d) (if (jolt-lazyseq? coll) (%ls-nth (jolt-seq coll) i d) (%ls-nth coll i d))))) -;; a lazy seq prints as its realized seq — force, then re-dispatch through the -;; printer. An empty realized lazy seq is still a sequence, printing "()" (like a -;; JVM LazySeq), not "nil" — so (lazy-seq nil) and (rest '(1)) render "()". -(register-pr-str-arm! jolt-lazyseq? - (lambda (x) (let ((s (jolt-seq x))) (if (jolt-nil? s) "()" (jolt-pr-str s))))) -(register-pr-readable-arm! jolt-lazyseq? - (lambda (x) (let ((s (jolt-seq x))) (if (jolt-nil? s) "()" (jolt-pr-readable s))))) -(register-str-render! jolt-lazyseq? - (lambda (x) (let ((s (jolt-seq x))) (if (jolt-nil? s) "()" (jolt-str-render-one s))))) +;; a lazy seq prints as its realized seq — force, then re-dispatch through the printer. +(register-pr-str-arm! jolt-lazyseq? (lambda (x) (jolt-pr-str (jolt-seq x)))) +(register-pr-readable-arm! jolt-lazyseq? (lambda (x) (jolt-pr-readable (jolt-seq x)))) +(register-str-render! jolt-lazyseq? (lambda (x) (jolt-str-render-one (jolt-seq x)))) ;; seq? — a lazy seq IS a seq (predicates.ss's jolt-seq? predates the lazyseq ;; record). Unlike the native-op dispatchers above (called via a direct top-level diff --git a/host/chez/loader.ss b/host/chez/loader.ss index 4ea8bd1..d2cd31d 100644 --- a/host/chez/loader.ss +++ b/host/chez/loader.ss @@ -57,25 +57,9 @@ ((and (pmap? x) (eq? (jolt-get x rdr-kw-jolt-type) rdr-kw-jolt-tagged)) (let ((rdr (data-reader-symbol (jolt-get x rdr-kw-tag))) (inner (ldr-apply-readers (jolt-get x rdr-kw-form)))) - (cond - (rdr - ;; Clojure applies a data reader at read time and substitutes its result - ;; as code. A reader that returns a FORM (a list — e.g. borkdude.html's - ;; #html expands to (->Html (str …))) must be compiled, so splice it in. - ;; A reader that returns a VALUE (time-literals #time/date -> a Date) is - ;; left as a runtime call (reader-fn 'inner): the value rebuilds at - ;; startup, which also keeps a non-serializable constant out of an AOT - ;; build. Apply is guarded — a reader that can't run at load time (its - ;; deps not ready) falls back to the runtime call too. - (let ((result (and (symbol-t? rdr) (not (jolt-nil? (symbol-t-ns rdr))) - (guard (e (#t #f)) - (let ((fn (var-deref (symbol-t-ns rdr) (symbol-t-name rdr)))) - (and (procedure? fn) (jolt-invoke fn inner))))))) - (if (cseq? result) - result - (jolt-list rdr (jolt-list (jolt-symbol #f "quote") inner))))) - ((eq? inner (jolt-get x rdr-kw-form)) x) - (else (rdr-make-tagged (jolt-get x rdr-kw-tag) inner))))) + (cond (rdr (jolt-list rdr (jolt-list (jolt-symbol #f "quote") inner))) + ((eq? inner (jolt-get x rdr-kw-form)) x) + (else (rdr-make-tagged (jolt-get x rdr-kw-tag) inner))))) ((rdr-set-form? x) (let-values (((items changed) (ldr-conv-each (seq->list (jolt-get x rdr-kw-value))))) (if changed (rdr-carry-meta x (rdr-make-set items)) x))) @@ -138,31 +122,14 @@ (else (loop (cdr cs) (cons (car cs) seg) segs))))) ;; First existing /rel.clj or /rel.cljc on the search roots, else #f. -;; A self-contained joltc binary embeds jolt-core + stdlib source keyed by their -;; root-relative path ("clojure/string.clj"); those are checked first, so a -;; `require` resolves with no source on disk. The dev bin/joltc has an empty -;; source store, so the two hashtable probes miss and it falls straight to disk. (define (resolve-on-roots rel) - (let ((eclj (string-append rel ".clj")) (ecljc (string-append rel ".cljc"))) - (cond - ((string? (hashtable-ref embedded-resources eclj #f)) eclj) - ((string? (hashtable-ref embedded-resources ecljc #f)) ecljc) - (else - (let loop ((roots source-roots)) - (if (null? roots) #f - (let ((clj (string-append (car roots) "/" rel ".clj")) - (cljc (string-append (car roots) "/" rel ".cljc"))) - (cond ((file-exists? clj) clj) - ((file-exists? cljc) cljc) - (else (loop (cdr roots))))))))))) - -;; Read a namespace source. An embedded key (resolve-on-roots above, or the -;; build driver's app-order entries) reads its baked string; everything else is -;; a real path read off disk. Bytevector entries (the bundled boots/stub) are not -;; source, so a string? guard skips them. -(define (ldr-read-source path) - (let ((emb (hashtable-ref embedded-resources path #f))) - (if (string? emb) emb (read-file-string path)))) + (let loop ((roots source-roots)) + (if (null? roots) #f + (let ((clj (string-append (car roots) "/" rel ".clj")) + (cljc (string-append (car roots) "/" rel ".cljc"))) + (cond ((file-exists? clj) clj) + ((file-exists? cljc) cljc) + (else (loop (cdr roots)))))))) (define (find-ns-file name) (resolve-on-roots (ns-name->rel name))) @@ -174,14 +141,6 @@ (vector-for-each (lambda (c) (hashtable-set! loaded-ns (var-cell-ns c) #t)) (hashtable-values var-table)) -;; clojure.core.async ships native channel primitives (async.ss) AND a Clojure -;; overlay (stdlib/clojure/core/async.clj) with the higher-level dataflow API -;; (alts!, pipe, mult, mix, pub/sub, map, merge, …). The primitives pre-seed the -;; namespace above, which would make a `require` no-op and skip the overlay. Drop -;; it from the loaded set so a require pulls the overlay from the source roots -;; (like clojure.test); the primitives stay defined either way. -(hashtable-delete! loaded-ns "clojure.core.async") - ;; Does `name` already have vars in the var-table? A namespace baked into the ;; image after the snapshot above — an AOT'd app namespace in a `jolt build` ;; binary — exists in memory with no source file; a later `require` of it must @@ -209,21 +168,18 @@ ;; more forms", which would silently drop the entire rest of the file; here we ;; skip the no-op form and continue to true end-of-string. (define (load-jolt-file path) - (let* ((src (ldr-read-source path)) (end (string-length src))) - ;; parameterize (not a bare set!) so a require nested in this file's ns form - ;; restores path when control returns to the rest of this file. - (parameterize ((rdr-source-file path)) ; list forms read here carry :file = path - (let loop ((i 0)) - (when (< i end) - (let-values (((form j) (rdr-read-form src i end))) - (when (> j i) - (unless (rdr-eof? form) - (when (getenv "JOLT_TRACE_LOAD") - (display " [load-form] " (current-error-port)) - (display (jolt-pr-str form) (current-error-port)) (newline (current-error-port))) - (jolt-compile-eval-form (if data-readers-active (ldr-apply-readers form) form) - (chez-current-ns))) - (loop j)))))))) + (let* ((src (read-file-string path)) (end (string-length src))) + (let loop ((i 0)) + (when (< i end) + (let-values (((form j) (rdr-read-form src i end))) + (when (> j i) + (unless (rdr-eof? form) + (when (getenv "JOLT_TRACE_LOAD") + (display " [load-form] " (current-error-port)) + (display (jolt-pr-str form) (current-error-port)) (newline (current-error-port))) + (jolt-compile-eval-form (if data-readers-active (ldr-apply-readers form) form) + (chez-current-ns))) + (loop j))))))) ;; load-namespace: load `name`'s source once. Marked loaded BEFORE eval so a ;; dependency cycle terminates (Clojure's behavior). The caller's current ns is @@ -260,93 +216,50 @@ (else '())))) (and (pair? items) (symbol-t? (car items)) (symbol-t-name (car items))))) -;; A libspec under a prefix joins onto it: a bare symbol `string` -> `prefix.string`, -;; a vector `[string :as s]` -> `[prefix.string :as s]` (opts preserved). -(define (prefix-join prefix lib) - (cond - ((symbol-t? lib) (jolt-symbol #f (string-append prefix "." (symbol-t-name lib)))) - ((pvec? lib) - (let ((items (seq->list lib))) - (if (and (pair? items) (symbol-t? (car items))) - (apply jolt-vector (jolt-symbol #f (string-append prefix "." (symbol-t-name (car items)))) (cdr items)) - lib))) - (else lib))) - -;; The prefix-list form of a require/use spec: a LIST `(prefix lib …)` expands to -;; one spec per lib (prefix.lib), so (:require (clojure [string :as str])) means -;; clojure.string :as str. A vector / symbol spec is already a single lib. -(define (expand-spec s) - (if (or (cseq? s) (empty-list-t? s)) - (let ((items (seq->list s))) - (if (and (pair? items) (symbol-t? (car items)) (pair? (cdr items))) - (map (lambda (lib) (prefix-join (symbol-t-name (car items)) lib)) (cdr items)) - (list s))) - (list s))) - ;; --- require/use that LOAD --------------------------------------------------- ;; Override the alias-only versions from natives-str.ss. Load each spec's target ;; (no-op if baked/already loaded), THEN register its :as/:refer under the caller ;; ns (chez-register-spec! reads the current ns, restored by load-namespace). (define (loader-require . specs) (for-each - (lambda (s0) - (for-each - (lambda (s) - (let ((target (spec-target-name s))) - (when target (load-namespace target))) - (chez-register-spec! (chez-current-ns) s)) - (expand-spec s0))) + (lambda (s) + (let ((target (spec-target-name s))) + (when target (load-namespace target))) + (chez-register-spec! (chez-current-ns) s)) specs) jolt-nil) (def-var! "clojure.core" "require" loader-require) -(define (loader-use . specs0) +(define (loader-use . specs) (for-each - (lambda (spec0) - (for-each - (lambda (spec) - (let ((target (spec-target-name spec))) - (when target (load-namespace target))) - (chez-register-spec! (chez-current-ns) spec) - (let* ((items (cond ((pvec? spec) (seq->list spec)) - ((symbol-t? spec) (list spec)) - (else '()))) - (target (and (pair? items) (symbol-t? (car items)) (symbol-t-name (car items)))) - (filtered (let scan ((xs (if (pair? items) (cdr items) '()))) - (cond ((null? xs) #f) - ((and (keyword? (car xs)) - (member (keyword-t-name (car xs)) '("only" "refer"))) #t) - (else (scan (cdr xs))))))) - (when (and target (not filtered)) - (chez-register-refer-all! (chez-current-ns) target)))) - (expand-spec spec0))) - specs0) + (lambda (spec) + (let ((target (spec-target-name spec))) + (when target (load-namespace target))) + (chez-register-spec! (chez-current-ns) spec) + (let* ((items (cond ((pvec? spec) (seq->list spec)) + ((or (cseq? spec) (empty-list-t? spec)) (seq->list spec)) + ((symbol-t? spec) (list spec)) + (else '()))) + (target (and (pair? items) (symbol-t? (car items)) (symbol-t-name (car items)))) + (filtered (let scan ((xs (if (pair? items) (cdr items) '()))) + (cond ((null? xs) #f) + ((and (keyword? (car xs)) + (member (keyword-t-name (car xs)) '("only" "refer"))) #t) + (else (scan (cdr xs))))))) + (when (and target (not filtered)) + (chez-register-refer-all! (chez-current-ns) target)))) + specs) jolt-nil) (def-var! "clojure.core" "use" loader-use) (def-var! "clojure.core" "load-file" jolt-load-file) - -;; The directory of a namespace's resource path: "clojure.tools.reader-test" -> -;; "clojure/tools" (drop the last segment of ns-name->rel). "" for a top-level ns. -(define (ns-rel-dir name) - (let* ((r (ns-name->rel name))) - (let loop ((k (fx- (string-length r) 1))) - (cond ((fx (string-length p) 0) (char=? (string-ref p 0) #\/)) - (substring p 1 (string-length p))) - (else (let ((dir (ns-rel-dir (chez-current-ns)))) - (if (string=? dir "") p (string-append dir "/" p)))))) + (let* ((rel (if (and (> (string-length p) 0) (char=? (string-ref p 0) #\/)) + (substring p 1 (string-length p)) p)) (f (resolve-on-roots rel))) (if f (load-jolt-file f) (error #f "Could not locate resource on source roots" p)))) @@ -384,14 +297,3 @@ (def-var! "jolt.host" "load-namespace" (lambda (n) (load-namespace n) jolt-nil)) (def-var! "jolt.host" "file-exists?" (lambda (p) (if (file-exists? p) #t #f))) (def-var! "jolt.host" "getenv" (lambda (n) (let ((v (getenv n))) (if v v jolt-nil)))) - -;; jolt version string. A self-contained binary build bakes the real tag into the -;; saved heap by emitting (set! jolt-baked-version "…") in flat.ss; a dev run off -;; the seed leaves it #f and falls back to $JOLT_VERSION (bin/joltc sets it from -;; `git describe`), then "dev". -(define jolt-baked-version #f) -(def-var! "jolt.host" "jolt-version" - (lambda () - (or jolt-baked-version - (let ((v (getenv "JOLT_VERSION"))) (and v (> (string-length v) 0) v)) - "dev"))) diff --git a/host/chez/java/math.ss b/host/chez/math.ss similarity index 100% rename from host/chez/java/math.ss rename to host/chez/math.ss diff --git a/host/chez/multimethods.ss b/host/chez/multimethods.ss index 438cd40..f97c25d 100644 --- a/host/chez/multimethods.ss +++ b/host/chez/multimethods.ss @@ -61,36 +61,26 @@ (define (jolt-defmulti-setup name-sym dispatch . opts) (let-values (((dk h) (parse-mm-opts opts))) - (let* ((sns (symbol-t-ns name-sym)) - ;; the macro qualifies the name with its EXPANSION ns, so a defmulti - ;; deferred inside a fn (a deftest body) still defines in the ns it - ;; was written in, not whatever ns is current when it finally runs. - (ns (if (string? sns) sns (chez-current-ns))) - (mf (make-jolt-multifn (symbol-t-name name-sym) dispatch - (new-mm-table) dk h (new-mm-table)))) - (def-var! ns (symbol-t-name name-sym) mf) + (let ((mf (make-jolt-multifn (symbol-t-name name-sym) dispatch + (new-mm-table) dk h (new-mm-table)))) + (def-var! (chez-current-ns) (symbol-t-name name-sym) mf) mf))) ;; (defmethod-setup 'mm dispatch-val impl) — add a method. Auto-creates the multifn ;; if absent (defmethod before defmulti — rare; identity dispatch as a fallback). -(define (jolt-defmethod-setup mm-sym dval impl . rest) +(define (jolt-defmethod-setup mm-sym dval impl) (let* ((nm (symbol-t-name mm-sym)) (sns (symbol-t-ns mm-sym)) (qns (and sns (not (jolt-nil? sns)) (not (null? sns)) sns)) - ;; the macro passes its EXPANSION ns so a defmethod deferred inside a - ;; fn resolves like the JVM (against the ns it was written in, not the - ;; ns current when it runs); absent (old emitted code) fall back to the - ;; runtime ns. - (here (if (and (pair? rest) (string? (car rest))) (car rest) (chez-current-ns))) ;; qualified (cf.mm/ext) resolves in its own ns (cross-ns defmethod); - ;; unqualified resolves in the writing ns, else a :refer's home ns (so a + ;; unqualified resolves in the current ns, else a :refer's home ns (so a ;; defmethod on a referred multifn lands on the real one), else stays in - ;; the writing ns (a shadow, as before). + ;; the current ns (a shadow, as before). (mns (cond - (qns (or (chez-resolve-alias here qns) qns)) - ((var-cell-lookup here nm) here) - ((chez-resolve-refer here nm) => values) - (else here))) + (qns (or (chez-resolve-alias (chez-current-ns) qns) qns)) + ((var-cell-lookup (chez-current-ns) nm) (chez-current-ns)) + ((chez-resolve-refer (chez-current-ns) nm) => values) + (else (chez-current-ns)))) (cur (var-deref mns nm)) (mf (if (jolt-multifn? cur) cur ;; auto-create: copy the dispatch fn + default from a same-named diff --git a/host/chez/java/natives-array.ss b/host/chez/natives-array.ss similarity index 86% rename from host/chez/java/natives-array.ss rename to host/chez/natives-array.ss index 6cbe13a..de130fb 100644 --- a/host/chez/java/natives-array.ss +++ b/host/chez/natives-array.ss @@ -85,22 +85,42 @@ (define (na-bytes x) (if (and (jolt-array? x) (eq? (jolt-array-kind x) 'byte)) x (na-byte-array x))) (define (na-bytes? x) (and (jolt-array? x) (eq? (jolt-array-kind x) 'byte))) (define (na-identity x) x) -(define (na-byte x) (jolt-byte-cast x)) -(define (na-short x) (jolt-short-cast x)) +(define (na-byte x) + (let ((b (bitwise-and (exact (floor x)) #xff))) (if (>= b 128) (- b 256) b))) +(define (na-short x) + (let ((s (bitwise-and (exact (floor x)) #xffff))) (if (>= s #x8000) (- s #x10000) s))) ;; --- chunked seqs ----------------------------------------------------------- -;; The chunked-seq accessors (chunked-seq? / chunk-first / chunk-rest / chunk-next) -;; live in seq.ss with the cseq core they read; here we only bind them plus the -;; chunk-builder API (clojure.lang.ChunkBuffer + chunk-cons). chunk-buffer collects -;; appended items, chunk seals them into a pvec chunk, and chunk-cons prepends that -;; chunk onto a rest seq as a real ChunkedCons (cseq-chunked) — empty chunk == just -;; the rest, like clojure.core/chunk-cons. +;; A vector's seq is a REAL chunked-seq: (seq v) carries its backing vector + +;; element index (seq.ss cseq-vec), so chunked-seq? is true and chunk-first hands +;; out a 32-element block (a pvec slice) while chunk-rest is the seq at the next +;; block boundary — the Clojure/CLJS ChunkedSeq contract (chunk-first ++ +;; chunk-rest == the seq). The eager buffer model (chunk-buffer/chunk-append/ +;; chunk) builds a plain cseq; chunk-cons/first/rest fall back to seq ops over it. +(define na-chunk-size 32) (define-record-type jolt-chunkbuf (fields (mutable items)) (nongenerative jolt-chunkbuf-v1)) (define (na-chunk-buffer cap) (make-jolt-chunkbuf '())) (define (na-chunk-append b x) (jolt-chunkbuf-items-set! b (append (jolt-chunkbuf-items b) (list x))) b) -(define (na-chunk b) (make-pvec (list->vector (jolt-chunkbuf-items b)))) -(define (na-chunk-cons chunk rest) - (if (fx=? 0 (pvec-count chunk)) rest (cseq-chunked chunk 0 rest))) +(define (na-chunk b) (list->cseq (jolt-chunkbuf-items b))) +(define (na-chunk-cons chunk rest) (jolt-concat chunk rest)) +;; backing (vector . end-of-block index) for a vector-seq cell, or #f. +(define (na-vblock s) + (and (cseq? s) (cseq-cvec s) + (let* ((v (cseq-cvec s)) (i (cseq-ci s))) + (cons v (fxmin (fx+ i na-chunk-size) (pvec-count v)))))) +(define (na-chunked-seq? x) (and (na-vblock x) #t)) +(define (na-chunk-first s) + (let ((vb (na-vblock s))) + (if vb (make-pvec (vec-copy-range (pvec-v (car vb)) (cseq-ci s) (cdr vb))) + (jolt-first s)))) ; eager-buffer fallback +(define (na-chunk-rest s) + (let ((vb (na-vblock s))) + (if vb (if (fx>=? (cdr vb) (pvec-count (car vb))) jolt-empty-list (vec->seq (car vb) (cdr vb))) + (jolt-rest s)))) +(define (na-chunk-next s) + (let ((vb (na-vblock s))) + (if vb (if (fx>=? (cdr vb) (pvec-count (car vb))) jolt-nil (vec->seq (car vb) (cdr vb))) + (jolt-next s)))) ;; --- extend the collection dispatchers to see a jolt-array ------------------ (define %na-count jolt-count) @@ -115,11 +135,10 @@ (let ((v (jolt-array-vec c)) (j (exact (na-idx i)))) (if (and (>= j 0) (< j (vector-length v))) (vector-ref v j) d)) (%na-nth c i d))))) -(def-var! "jolt.host" "array-value?" (lambda (x) (if (jolt-array? x) #t jolt-nil))) (define %na-get jolt-get) (set! jolt-get (case-lambda - ((c k) (if (jolt-array? c) (jolt-nth c k jolt-nil) (%na-get c k))) + ((c k) (if (jolt-array? c) (jolt-nth c k) (%na-get c k))) ((c k d) (if (jolt-array? c) (jolt-nth c k d) (%na-get c k d))))) ;; aset (overlay) writes through jolt.host/ref-put! — mutate the slot, return arr. ;; count/nth/seq/get above are NATIVE-OPS (inlined at call sites), so aget/alength/ @@ -137,6 +156,7 @@ ;; (jolt-type …) for arrays, so extending jolt-type covers both. (define %na-type jolt-type) (set! jolt-type (lambda (x) (if (jolt-array? x) (na-array-class-name x) (%na-type x)))) +(def-var! "clojure.core" "type" jolt-type) ;; instance? over an array class token ([I, [C, …). An array token reaches us as ;; a string ("[C", from (Class/forName "[C")) — the dispatcher leaves it a string diff --git a/host/chez/natives-coll.ss b/host/chez/natives-coll.ss index 1dac844..a621b63 100644 --- a/host/chez/natives-coll.ss +++ b/host/chez/natives-coll.ss @@ -4,16 +4,15 @@ ;; binds the public clojure.core names to them. Loaded after def-var! (rt.ss) + ;; the collections + seq tiers. hash-map/array-map/hash-set/set/rand semantics. -;; array-map: insertion-ordered, any size (Clojure's PersistentArrayMap, via -;; createAsIfByAssoc). hash-map: hash order (PersistentHashMap). The map LITERAL -;; ctor (jolt-hash-map, emitted for {...}) is array-ordered up to 8 entries and -;; hash beyond, matching RT.map. -(define (jolt-array-map . kvs) (jolt-array-map-build kvs)) -(define (jolt-hash-map-fn . kvs) (jolt-hash-map-build kvs)) +;; hash-map / hash-set: variadic kvs / elems straight onto the existing ctors. +;; array-map: Clojure preserves insertion order, but jolt's `=` is structural and +;; the parity corpus compares by value, so a pmap is observationally equal for +;; the tested cases; keys-ordering is a separate (untested-here) concern. +(define (jolt-array-map . kvs) (apply jolt-hash-map kvs)) -;; set lives in the kernel overlay tier (clojure/core/00-kernel.clj): it's a pure -;; composition (apply hash-set (seq coll)) the compiler uses only off the emit path, -;; so the Clojure version lowers to the same code without a bootstrap cycle. +;; set: realize any seqable to a list, then dedup through the set ctor. nil -> #{}. +(define (jolt-set coll) + (if (jolt-nil? coll) (jolt-hash-set) (apply jolt-hash-set (seq->list coll)))) ;; rand: a flonum in [0, n) (n defaults to 1.0) — jolt is all-flonum, so the ;; result is a double like every other number. @@ -21,8 +20,9 @@ (let ((r (random 1.0))) (if (null? n) r (* r (exact->inexact (car n)))))) -(def-var! "clojure.core" "hash-map" jolt-hash-map-fn) +(def-var! "clojure.core" "hash-map" jolt-hash-map) (def-var! "clojure.core" "hash-set" jolt-hash-set) (def-var! "clojure.core" "array-map" jolt-array-map) +(def-var! "clojure.core" "set" jolt-set) (def-var! "clojure.core" "rand" jolt-rand) (def-var! "clojure.core" "map-entry?" jolt-map-entry?) diff --git a/host/chez/natives-meta.ss b/host/chez/natives-meta.ss index 9c7b205..836ccc6 100644 --- a/host/chez/natives-meta.ss +++ b/host/chez/natives-meta.ss @@ -22,45 +22,29 @@ (jolt-assoc (if user user (jolt-hash-map)) jolt-kw-var-ns (var-cell-ns x) jolt-kw-var-name (var-cell-name x)))) - ;; a deftype implementing clojure.lang.IObj stores meta in a field and threads - ;; it through its own assoc/withMeta (core.logic's Substitutions/LVar/LCons), - ;; so dispatch to its meta method rather than the identity side-table — which - ;; the deftype's reconstructed instances would not share. - ((and (jrec? x) (jrec-cl x "meta")) => (lambda (m) (jolt-invoke m x))) - ;; everything else (collections, fns, reify, atoms/agents and any reference - ;; type) reads the identity side-table; a value with no entry is nil meta. - (else (hashtable-ref meta-table x jolt-nil)))) + ((or (pvec? x) (pmap? x) (pset? x) (cseq? x) (empty-list-t? x) (jolt-lazyseq? x) (jrec? x) (jreify? x) (procedure? x)) + (hashtable-ref meta-table x jolt-nil)) + (else jolt-nil))) ;; fresh-identity copy of a metadatable value (so attaching meta doesn't mutate ;; the original). cseq/procedure can't be copied meaningfully — keyed in place. (define (meta-copy x) (cond ((pvec? x) (make-pvec (pvec-v x) (pvec-ent x))) - ((pmap? x) (make-pmap (pmap-root x) (pmap-cnt x) (pmap-order x))) + ((pmap? x) (make-pmap (pmap-root x) (pmap-cnt x))) ((pset? x) (make-pset (pset-m x))) - ((jrec? x) (make-jrec (jrec-desc x) (jrec-vec-copy (jrec-vals x)) (jrec-ext x))) + ((jrec? x) (make-jrec (jrec-tag x) (jrec-pairs x))) ;; a reify shares its (read-only) method table + protos but gets a fresh ;; identity, so attaching meta leaves the original's meta untouched. Every ;; Clojure reify implements IObj. ((jreify? x) (make-jreify (jreify-methods x) (jreify-protos x))) ;; () is a shared singleton — a fresh instance keeps meta off every other (). ((empty-list-t? x) (fresh-empty-list)) - ;; a list/seq node gets a fresh identity too (Clojure's PersistentList is - ;; immutable — (with-meta a-list m) returns a NEW list). Keying meta on the - ;; original mutated it, so (with-meta xs {:k xs}) built a self-referential - ;; cycle that loops *print-meta* printing. - ((cseq? x) (make-cseq (cseq-head x) (cseq-tail x) (cseq-forced? x) - (cseq-list? x) (cseq-cvec x) (cseq-ci x) (cseq-crest x))) - ((jolt-lazyseq? x) (make-jolt-lazyseq (jolt-lazyseq-thunk x) (jolt-lazyseq-val x) - (jolt-lazyseq-realized? x))) - (else x))) ; procedure + (else x))) ; cseq / procedure (define (jolt-with-meta x m) (cond ((symbol-t? x) (make-symbol-t (symbol-t-ns x) (symbol-t-name x) m)) - ;; a deftype with an explicit clojure.lang.IObj withMeta carries meta in a - ;; field; dispatch to it (see jolt-meta) so the meta survives reconstruction. - ((and (jrec? x) (jrec-cl x "withMeta")) => (lambda (meth) (jolt-invoke meth x m))) ((or (pvec? x) (pmap? x) (pset? x) (cseq? x) (empty-list-t? x) (jolt-lazyseq? x) (jrec? x) (jreify? x) (procedure? x)) (let ((c (meta-copy x))) (if (jolt-nil? m) (hashtable-delete! meta-table c) (hashtable-set! meta-table c m)) @@ -148,10 +132,4 @@ ((procedure? x) ty-fn) (else ty-object)))) -;; jolt-type is the keyword TAXONOMY (:string/:set/:jolt/inst/…) — jolt's native -;; value model, with no JVM in it. print-method/print-dup dispatch on it (via -;; __type-tag). The PUBLIC clojure.core/type is Clojure's (or (:type meta) (class -;; x)) — a JVM class — but that mapping belongs to the java host layer (host-class.ss -;; rebinds `type` next to `class`), so this core layer stays JVM-free. -(def-var! "clojure.core" "__type-tag" jolt-type) (def-var! "clojure.core" "type" jolt-type) diff --git a/host/chez/natives-num.ss b/host/chez/natives-num.ss index 0944dbe..e4ef682 100644 --- a/host/chez/natives-num.ss +++ b/host/chez/natives-num.ss @@ -17,12 +17,11 @@ (define (jolt-bit-clear x n) (bitwise-and (->int x) (bitwise-not (bit-mask n)))) (define (jolt-bit-flip x n) (bitwise-xor (->int x) (bit-mask n))) (define (jolt-bit-test x n) (not (zero? (bitwise-and (->int x) (bit-mask n))))) -;; unsigned-bit-shift-right: LOGICAL right shift over a 64-bit long (Java >>>), -;; so a negative operand shifts in zeros from its 64-bit two's-complement window -;; ((>>> -1 1) = 2^63-1), not the sign. The shift count is taken mod 64. +;; unsigned-bit-shift-right: logical shift over 64-bit longs. For the common +;; non-negative operand it equals the arithmetic shift; the negative-operand +;; 64-bit-window case is not modeled. (define (jolt-unsigned-bit-shift-right x n) - (bitwise-arithmetic-shift-right (bitwise-and (->int x) #xFFFFFFFFFFFFFFFF) - (bitwise-and (->int n) 63))) + (bitwise-arithmetic-shift-right (->int x) (->int n))) ;; ---- string->scalar parsers ------------------------------------------------- (define (ascii-digit? c) (and (char>=? c #\0) (char<=? c #\9))) diff --git a/host/chez/java/natives-queue.ss b/host/chez/natives-queue.ss similarity index 100% rename from host/chez/java/natives-queue.ss rename to host/chez/natives-queue.ss diff --git a/host/chez/natives-reader.ss b/host/chez/natives-reader.ss index df5c32f..458ad6a 100644 --- a/host/chez/natives-reader.ss +++ b/host/chez/natives-reader.ss @@ -16,19 +16,20 @@ (seq->list (jolt-seq names)))) jolt-nil) -;; --- reader-conditional: a tagged map (reader-conditional? is an overlay -;; tagged-value predicate that reads :jolt/type). STAYS NATIVE: building a -;; :jolt/type-tagged map is part of the native value model — an overlay defn -;; returning {:jolt/type ...} silently fails to bind during the seed mint (the -;; guard around each prelude form swallows the load-time error), the same reason -;; every other tagged-value constructor (atom/volatile!/tagged-literal) is native. -;; re-matcher / re-find / re-groups are the stateful matcher API in regex.ss. +;; --- reader-conditional / re-matcher: tagged maps (reader-conditional? + the +;; matcher consumers are overlay tagged-value predicates that read :jolt/type). (define nr-kw-type (keyword "jolt" "type")) (define nr-kw-rc (keyword "jolt" "reader-conditional")) (define nr-kw-form (keyword #f "form")) (define nr-kw-spl (keyword #f "splicing?")) +(define nr-kw-mat (keyword "jolt" "matcher")) +(define nr-kw-re (keyword #f "re")) +(define nr-kw-s (keyword #f "s")) +(define nr-kw-pos (keyword #f "pos")) (define (nr-reader-conditional form splicing?) (jolt-hash-map nr-kw-type nr-kw-rc nr-kw-form form nr-kw-spl splicing?)) +(define (nr-re-matcher re s) + (jolt-hash-map nr-kw-type nr-kw-mat nr-kw-re re nr-kw-s s nr-kw-pos 0.0)) ;; --- macroexpand-1 / macroexpand: expand a (quoted) call form via the runtime ;; macro table (host-contract hc-macro?/hc-expand-1; forward-referenced, resolved @@ -46,13 +47,6 @@ (def-var! "clojure.core" "__reader-features" nr-reader-features-get) (def-var! "clojure.core" "__reader-features-set!" nr-reader-features-set!) (def-var! "clojure.core" "reader-conditional" nr-reader-conditional) +(def-var! "clojure.core" "re-matcher" nr-re-matcher) (def-var! "clojure.core" "macroexpand-1" nr-macroexpand-1) - -;; letfn is a special form (the analyzer lowers it to letrec*, checked before any -;; macro), but on the JVM it is also a clojure.core macro that (resolve 'letfn) -;; finds — like let / loop / fn here. Intern a var so resolution matches; the value -;; is never invoked (the analyzer handles every (letfn …) form), and it is NOT -;; marked a macro, so macroexpand leaves a letfn form alone (it is special). -(def-var! "clojure.core" "letfn" - (lambda args (jolt-throw (jolt-ex-info "letfn is a special form" (jolt-hash-map))))) (def-var! "clojure.core" "macroexpand" nr-macroexpand) diff --git a/host/chez/natives-seq.ss b/host/chez/natives-seq.ss index 0e6b63f..eef5cb0 100644 --- a/host/chez/natives-seq.ss +++ b/host/chez/natives-seq.ss @@ -17,16 +17,13 @@ ;; call routes through jolt-invoke. A `reduced` step stops the fold — reduce-seq ;; (seq.ss) already short-circuits on a jolt-reduced. ;; ============================================================================ -;; The map transducer's step fn supports multiple inputs ([result input & inputs]), -;; so a multi-collection sequence/transduce — or medley's sequence-padded, which -;; calls (f acc i1 i2 …) — applies f across all of them: (rf result (apply f inputs)). (define (td-map f) (lambda (rf) (lambda a (case (length a) ((0) (jolt-invoke rf)) ((1) (jolt-invoke rf (car a))) - (else (jolt-invoke rf (car a) (apply jolt-invoke f (cdr a)))))))) + (else (jolt-invoke rf (car a) (jolt-invoke f (cadr a)))))))) (define (td-filter pred) (lambda (rf) (lambda a @@ -104,10 +101,7 @@ (define (jolt-mapcat f . colls) (if (null? colls) (td-mapcat f) - ;; lazily concat the per-element results — no seq->list, so mapcat over an - ;; infinite source stays lazy; the outer lazy-seq node defers the first - ;; element so a side-effecting f does not fire at construction (LazySeq). - (jolt-make-lazy-seq (lambda () (jolt-seq (lazy-concat-seq (apply jolt-map f colls))))))) + (apply jolt-concat (seq->list (apply jolt-map f colls))))) ;; take-while / drop-while: 1-arg -> transducer; 2-arg -> a seq over the coll. (define (take-while-seq pred s) @@ -119,7 +113,7 @@ (define jolt-take-while (case-lambda ((pred) (td-take-while pred)) - ((pred coll) (jolt-make-lazy-seq (lambda () (jolt-seq (take-while-seq pred (jolt-seq coll)))))))) + ((pred coll) (take-while-seq pred (jolt-seq coll))))) (define (drop-while-seq pred coll) (let loop ((s (jolt-seq coll))) (if (and (not (jolt-nil? s)) (jolt-truthy? (jolt-invoke pred (seq-first s)))) @@ -128,7 +122,7 @@ (define jolt-drop-while (case-lambda ((pred) (td-drop-while pred)) - ((pred coll) (jolt-make-lazy-seq (lambda () (jolt-seq (drop-while-seq pred coll))))))) + ((pred coll) (drop-while-seq pred coll)))) ;; partition: (partition n coll), (partition n step coll), or ;; (partition n step pad coll). Only complete partitions of size n are kept; @@ -136,9 +130,9 @@ ;; runs out). Each partition is a seq; the whole result is a lazy seq of seqs. (define jolt-partition (case-lambda - ((n coll) (jolt-make-lazy-seq (lambda () (jolt-seq (partition* (->idx n) (->idx n) #f #f coll))))) - ((n step coll) (jolt-make-lazy-seq (lambda () (jolt-seq (partition* (->idx n) (->idx step) #f #f coll))))) - ((n step pad coll) (jolt-make-lazy-seq (lambda () (jolt-seq (partition* (->idx n) (->idx step) #t pad coll))))))) + ((n coll) (partition* (->idx n) (->idx n) #f #f coll)) + ((n step coll) (partition* (->idx n) (->idx step) #f #f coll)) + ((n step pad coll) (partition* (->idx n) (->idx step) #t pad coll)))) (define (take-n n s) ; -> (values list-of-first-n remaining-seq taken-count) (let loop ((n n) (s s) (acc '())) (if (or (fx<=? n 0) (jolt-nil? s)) @@ -183,12 +177,9 @@ (if (jolt-nil? s) jolt-empty-list (list->cseq (list-sort less? (seq->list s)))))) -;; identical?: reference identity (Clojure ==). eq? gives pointer identity over -;; the value model — interned keywords/fixnums/nil compare equal, distinct -;; collections do not. Must NOT be value equality: a deftype whose .equals calls -;; (identical? this o) to short-circuit (e.g. core.logic's Substitutions) would -;; otherwise recur forever (identical? -> = -> equiv -> .equals -> identical?). -(define (jolt-identical? a b) (eq? a b)) +;; identical?: jolt reference identity, defined as (= a b) over the +;; value model, where interned keywords/small values compare equal. +(define (jolt-identical? a b) (jolt= a b)) ;; Give the seq.ss native procedures their transducer (1-arg) arity — the emitter ;; lowers (map f)/(filter p)/(take n) at the wrong arity to the bare procedure @@ -225,23 +216,7 @@ ;; rseq: vectors + sorted colls only (Clojure), the reverse of the ascending seq. (define (jolt-rseq coll) - (cond - ((or (pvec? coll) (htable-sorted? coll)) - (list->cseq (reverse (seq->list (jolt-seq coll))))) - ;; a deftype/record implementing clojure.lang.Reversible (rseq) — e.g. - ;; data.priority-map — drives rseq through its own method. - ((and (jrec? coll) (find-method-any-protocol (jrec-tag coll) "rseq")) - => (lambda (f) (jolt-invoke f coll))) - (else (jolt-throw (jolt-ex-info "rseq requires a vector or sorted collection" (jolt-hash-map)))))) + (if (or (pvec? coll) (htable-sorted? coll)) + (list->cseq (reverse (seq->list (jolt-seq coll)))) + (jolt-throw (jolt-ex-info "rseq requires a vector or sorted collection" (jolt-hash-map))))) (def-var! "clojure.core" "rseq" jolt-rseq) - -;; clojure.core/unchecked-* — host-defined wrapping (Java long) arithmetic from -;; seq.ss. def-var!'d here because def-var! isn't bound when seq.ss loads. -(let ((d! (lambda (n v) (def-var! "clojure.core" n v)))) - (d! "unchecked-add" jolt-unchecked-add) (d! "unchecked-add-int" jolt-unchecked-add) - (d! "unchecked-subtract" jolt-unchecked-sub) (d! "unchecked-subtract-int" jolt-unchecked-sub) - (d! "unchecked-multiply" jolt-unchecked-mul) (d! "unchecked-multiply-int" jolt-unchecked-mul) - (d! "unchecked-negate" jolt-uncneg) (d! "unchecked-negate-int" jolt-uncneg) - (d! "unchecked-inc" jolt-uncinc) (d! "unchecked-inc-int" jolt-uncinc) - (d! "unchecked-dec" jolt-uncdec) (d! "unchecked-dec-int" jolt-uncdec) - (d! "unchecked-divide-int" jolt-unchecked-div) (d! "unchecked-remainder-int" jolt-unchecked-rem)) diff --git a/host/chez/java/natives-str.ss b/host/chez/natives-str.ss similarity index 95% rename from host/chez/java/natives-str.ss rename to host/chez/natives-str.ss index d1886ac..474f631 100644 --- a/host/chez/java/natives-str.ss +++ b/host/chez/natives-str.ss @@ -108,30 +108,10 @@ ((string=? cs "utf-32le") (string->utf32 s (endianness little))) (else (string->utf8 s))))) -;; Object.hashCode parity: Java's specified String hash and Clojure's Symbol hash -;; (Util.hashCombine), so (.hashCode s) / (.hashCode sym) match the JVM. 32-bit int. -(define (jolt-u32 x) (bitwise-and x #xFFFFFFFF)) -(define (jolt-s32 x) (let ((m (jolt-u32 x))) (if (>= m #x80000000) (- m #x100000000) m))) -(define (java-string-hash s) - (let ((n (string-length s))) - (let loop ((i 0) (h 0)) - (if (fxinteger (string-ref s i))))) - (jolt-s32 h))))) -(define (java-hash-combine seed hash) - (let* ((su (jolt-u32 seed)) - (sl (bitwise-arithmetic-shift-left su 6)) - (sr (bitwise-arithmetic-shift-right (jolt-s32 su) 2)) - (add (+ (jolt-u32 hash) #x9e3779b9 sl sr))) - (jolt-s32 (bitwise-xor su (jolt-u32 add))))) -(define (java-symbol-hash name ns) - (java-hash-combine (java-string-hash name) (if ns (java-string-hash ns) 0))) - (define (jolt-string-method method s rest) (define (arg n) (list-ref rest n)) (cond ((string=? method "toString") s) - ((string=? method "hashCode") (java-string-hash s)) ((string=? method "toLowerCase") (ascii-string-down s)) ((string=? method "toUpperCase") (ascii-string-up s)) ((string=? method "trim") (str-trim s)) diff --git a/host/chez/natives-transduce.ss b/host/chez/natives-transduce.ss index 3034b4f..96ae477 100644 --- a/host/chez/natives-transduce.ss +++ b/host/chez/natives-transduce.ss @@ -25,61 +25,28 @@ (def-var! "clojure.core" "volatile!" jolt-volatile!) (def-var! "clojure.core" "deref" jolt-deref) -;; --- sequence ---------------------------------------------------------------- -;; transduce lives in the overlay (clojure/core/22-coll.clj): it's a pure -;; composition (xf (reduce xf init coll)) over reduce, so the Clojure version -;; lowers to the same code the native shim did. sequence stays native (below): -;; its transformer iterator drives the reduced box + lazy realization directly. - -;; (sequence coll) -> a seq; (sequence xform coll) -> a LAZY seq of coll transformed -;; by xform. A transformer iterator (mirrors clojure.core's TransformerIterator): -;; pull one input at a time through (xform rf), where rf buffers each emitted value; -;; emit the buffer lazily, pulling more input only when it drains. So an infinite or -;; expensive source is consumed incrementally — (first (sequence (map inc) (range))) -;; returns at once. Honors `reduced` (stop pulling) and runs the 1-arg completion to -;; flush a stateful xform (partition-all / dedupe / a trailing partition). -(define (sequence-xf xform coll) - (let* ((buf (box '())) ; emitted values for the current step, reversed - (rf (case-lambda - (() jolt-nil) - ((acc) acc) - ((acc x) (set-box! buf (cons x (unbox buf))) acc))) - (xrf (jolt-invoke xform rf))) - ;; advance the source until buf holds output or the input is drained+completed. - (define (fill src acc completed) - (let loop ((src src) (acc acc) (completed completed)) - (cond - ((pair? (unbox buf)) (values src acc completed)) - (completed (values src acc #t)) - ((jolt-reduced? acc) - (jolt-invoke xrf (jolt-reduced-val acc)) ; completion may flush - (loop src (jolt-reduced-val acc) #t)) - (else - (let ((s (jolt-seq src))) - (if (jolt-nil? s) - (begin (jolt-invoke xrf acc) (loop src acc #t)) ; complete -> flush - (loop (seq-more s) (jolt-invoke xrf acc (seq-first s)) completed))))))) - ;; Resolve the next chunk now (one fill pulls just enough input to emit or to - ;; exhaust), so the result is a real cseq | empty — `empty` is jolt-empty-list - ;; at the top (so an empty result still prints "()") and jolt-nil inside a tail - ;; (the cseq terminator). The TAILS stay lazy, so an infinite source is fine. - (define (step src acc completed empty) - (let-values (((src2 acc2 comp2) (fill src acc completed))) - (let ((out (reverse (unbox buf)))) - (set-box! buf '()) - (if (null? out) - empty - (let build ((o out)) - (if (null? (cdr o)) - (cseq-lazy (car o) (lambda () (step src2 acc2 comp2 jolt-nil))) - (cseq-lazy (car o) (lambda () (build (cdr o)))))))))) - (step coll jolt-nil #f jolt-empty-list))) +;; --- transduce / sequence ---------------------------------------------------- +;; (transduce xform f coll) / (transduce xform f init coll): build the transformed +;; reducing fn (xform f), reduce it over coll (reduce-seq honors `reduced`), then +;; run the completion (1-arg) arity. The 3-arg init defaults to (f) — the rf's +;; 0-arity, e.g. (+) = 0, (conj) = []. +(define jolt-transduce + (case-lambda + ((xform f coll) (jolt-transduce xform f (jolt-invoke f) coll)) + ((xform f init coll) + (let* ((xf (jolt-invoke xform f)) + (res (reduce-seq xf init (jolt-seq coll)))) + (jolt-invoke xf res))))) +;; (sequence coll) -> a seq; (sequence xform coll) -> coll transformed by xform. +;; Materialized eagerly through into-xform then seq'd (corpus inputs are finite; a +;; fully-lazy pull is future work). Honors reduced via into-xform/reduce-seq. (define jolt-sequence (case-lambda ((coll) (jolt-seq coll)) - ((xform coll) (sequence-xf xform coll)))) + ((xform coll) (jolt-seq (into-xform (jolt-vector) xform coll))))) +(def-var! "clojure.core" "transduce" jolt-transduce) (def-var! "clojure.core" "sequence" jolt-sequence) ;; --- cat --------------------------------------------------------------------- diff --git a/host/chez/ns.ss b/host/chez/ns.ss index 435a18e..e4fdfdf 100644 --- a/host/chez/ns.ss +++ b/host/chez/ns.ss @@ -74,8 +74,7 @@ ;; :refer :all — bring in every public var (require :refer :all) ((and (keyword? v) (string=? (keyword-t-name v) "all")) (chez-register-refer-all! cns target)) - ;; :refer [a b] or :refer (a b) — both forms list names to bring in. - ((or (pvec? v) (cseq? v) (empty-list-t? v)) + ((pvec? v) (for-each (lambda (n) (when (symbol-t? n) (chez-register-refer! cns (symbol-t-name n) target))) (seq->list v)))))))) @@ -129,23 +128,17 @@ (list->cseq (map intern-ns! (vector->list (hashtable-keys seen)))))) ;; ns-publics / ns-map / ns-interns: a {sym -> var-cell} jolt map built by scanning -;; the var-table for defined cells in the namespace. ns-interns/ns-map keep every -;; var; ns-publics drops the ones marked ^:private (defn-/def ^:private), like the -;; JVM. ns-aliases is an empty map (map? is true). -(define (var-private? c) - (let ((m (hashtable-ref var-meta-table c #f))) - (and m (jolt-truthy? (jolt-get m (keyword #f "private")))))) -(define (ns-vars-pmap-when nm keep?) +;; the var-table for defined cells in the namespace. (Private vars are not tracked +;; yet, so ns-publics == ns-interns.) ns-aliases is an empty map (map? is true). +(define (ns-vars-pmap nm) (let ((m (jolt-hash-map))) (vector-for-each (lambda (c) - (when (and (string=? (var-cell-ns c) nm) (var-cell-defined? c) (keep? c)) + (when (and (string=? (var-cell-ns c) nm) (var-cell-defined? c)) (set! m (jolt-assoc m (jolt-symbol #f (var-cell-name c)) c)))) (hashtable-values var-table)) m)) -(define (ns-vars-pmap nm) (ns-vars-pmap-when nm (lambda (c) #t))) -(define (jolt-ns-publics desig) (ns-vars-pmap-when (ns-desig->name desig) (lambda (c) (not (var-private? c))))) -(define (jolt-ns-interns desig) (ns-vars-pmap (ns-desig->name desig))) +(define (jolt-ns-publics desig) (ns-vars-pmap (ns-desig->name desig))) ;; ns-aliases: the {alias-sym -> ns-value} registered under `desig` ;; (default the current ns) via require :as / alias. Reads ns-alias-table. @@ -260,9 +253,6 @@ ;; intern: create/set a var ns/sym to val (or an unbound cell). Returns the var. (define (jolt-intern ns-desig sym . vopt) (let ((nm (ns-desig->name ns-desig)) (s (symbol-t-name sym))) - ;; the namespace must exist (Namespace.find), like the JVM's intern - (unless (hashtable-ref ns-registry nm #f) - (jolt-throw (jolt-ex-info (string-append "No namespace: " nm " found") empty-pmap))) (if (pair? vopt) (def-var! nm s (car vopt)) (declare-var! nm s)))) ;; alias / ns-unalias: register/drop an :as alias under the current (or given) ns. @@ -285,48 +275,15 @@ (chez-register-refer! cns (var-cell-name c) target))) (hashtable-values var-table)) jolt-nil)) -;; (:refer-clojure :exclude [names…]) — clojure.core always resolves on Chez, so -;; the only thing to track is the EXCLUDE set: an excluded name is not -;; clojure.core/name, so syntax-quote qualifies it to the current ns instead (a ns -;; that excludes and defines its own, e.g. core.logic.fd's ==). -(define ns-core-exclude-table (make-hashtable equal-hash equal?)) ; cns -> (name -> #t) -(define (chez-register-core-exclude! cns name) - (let ((h (or (hashtable-ref ns-core-exclude-table cns #f) - (let ((h (make-hashtable string-hash string=?))) - (hashtable-set! ns-core-exclude-table cns h) h)))) - (hashtable-set! h name #t))) -(define (chez-core-excluded? cns name) - (let ((h (hashtable-ref ns-core-exclude-table cns #f))) - (and h (hashtable-ref h name #f) #t))) -(define (jolt-refer-clojure . args) - (let ((cns (chez-current-ns))) - (let loop ((a args)) - (when (and (pair? a) (pair? (cdr a))) - (when (and (keyword? (car a)) (string=? (keyword-t-name (car a)) "exclude")) - (for-each (lambda (n) (when (symbol-t? n) - (chez-register-core-exclude! cns (symbol-t-name n)))) - (seq->list (cadr a)))) - (loop (cddr a))))) - jolt-nil) +(define (jolt-refer-clojure . _) jolt-nil) -;; alter-meta! / reset-meta!: a var's metadata lives in var-meta-table (rt.ss); -;; any other reference (atom/agent/namespace) uses the identity meta side-table -;; jolt-meta reads. +;; alter-meta! / reset-meta!: update a var's metadata (var-meta-table, rt.ss). (define (jolt-alter-meta! ref f . args) - (if (var-cell? ref) - (let* ((cur (or (hashtable-ref var-meta-table ref #f) (jolt-hash-map))) - (new (apply jolt-invoke f cur args))) - (hashtable-set! var-meta-table ref new) - new) - (let* ((cur (let ((m (jolt-meta ref))) (if (jolt-nil? m) (jolt-hash-map) m))) - (new (apply jolt-invoke f cur args))) - (hashtable-set! meta-table ref new) - new))) -(define (jolt-reset-meta! ref m) - (if (var-cell? ref) - (hashtable-set! var-meta-table ref m) - (hashtable-set! meta-table ref m)) - m) + (let* ((cur (or (hashtable-ref var-meta-table ref #f) (jolt-hash-map))) + (new (apply jolt-invoke f cur args))) + (hashtable-set! var-meta-table ref new) + new)) +(define (jolt-reset-meta! ref m) (hashtable-set! var-meta-table ref m) m) ;; --- RESOLVE FRICTION: native-op cells ------------------------------------- ;; Native-op primitives (+ map reduce …) are INLINED at emit, so they have no @@ -365,8 +322,8 @@ (def-var! "clojure.core" "in-ns" jolt-in-ns) (def-var! "clojure.core" "all-ns" jolt-all-ns) (def-var! "clojure.core" "ns-publics" jolt-ns-publics) -(def-var! "clojure.core" "ns-map" jolt-ns-interns) -(def-var! "clojure.core" "ns-interns" jolt-ns-interns) +(def-var! "clojure.core" "ns-map" jolt-ns-publics) +(def-var! "clojure.core" "ns-interns" jolt-ns-publics) (def-var! "clojure.core" "ns-aliases" jolt-ns-aliases) (def-var! "clojure.core" "ns-refers" jolt-ns-refers) (def-var! "clojure.core" "ns-imports" jolt-ns-imports) diff --git a/host/chez/post-prelude.ss b/host/chez/post-prelude.ss index fefaec4..9a6ee38 100644 --- a/host/chez/post-prelude.ss +++ b/host/chez/post-prelude.ss @@ -63,17 +63,6 @@ ;; a lazy-seq carries its own realized? flag (lazy-bridge.ss). The overlay ;; realized? reads :jolt/type and throws on a jolt-lazyseq record. ((jolt-lazyseq? x) (jolt-lazyseq-realized? x)) - ;; a seq cell answers by its forced flag: the rest of a realized lazy - ;; chain is a cseq under jolt's seq model, and (realized? (rest s)) after - ;; a next must be true like the JVM's realized LazySeq — never a throw - ;; whose message renders the (possibly infinite) seq. - ;; a PLAIN seq (list/cons/range — not a lazy-seq wrapper) is not an - ;; IPending on the JVM: realized? throws. - ((or (cseq? x) (empty-list-t? x)) - (jolt-throw (jolt-host-throwable - "java.lang.ClassCastException" - (string-append "class " (guard (e (#t "?")) (jolt-class-name x)) - " cannot be cast to class clojure.lang.IPending")))) (else (jolt-invoke overlay-realized? x)))))) ;; clojure.edn/read over a reader: drain the jhost reader, then read through the ;; overlay read-string so the opts map (:readers/:default/:eof) is honored. @@ -89,28 +78,27 @@ (def-var! "clojure.core" "line-seq" (lambda (rdr) (if (reader-jhost? rdr) (chez-line-seq rdr) (jolt-invoke overlay-line-seq rdr))))) -;; JVM-parity numeric tower. integer?/float? are on the compiler emit/inference -;; path (so they stay native) but the overlay (20-coll.clj) still carries an -;; all-flonum int?/double? (int? -> integer?, double? -> not-integer) that -;; misclassifies exact rationals (e.g. (double? 1/2) -> true). Re-assert the -;; native tower-correct versions so they win over those overlay defs. int?/double? -;; alias integer?/float?. == is value-equality. (ratio?/rational? are now correct -;; in the overlay, built on jolt.host tower tests, so they need no re-assertion.) +;; JVM-parity numeric tower: the overlay (20-coll.clj) carries an +;; all-flonum number-predicate web with no Ratio concept (ratio? -> false, +;; double? -> not-integer, float? -> double?, rational? -> int?), which +;; misclassifies exact rationals on the Chez tower (e.g. (double? 1/2) -> true). +;; Re-assert the native tower-correct versions (predicates.ss) so they win over +;; the overlay defs. int?/double? alias integer?/float?. == is value-equality. (def-var! "clojure.core" "integer?" jolt-integer?) (def-var! "clojure.core" "int?" jolt-integer?) (def-var! "clojure.core" "float?" jolt-float?) (def-var! "clojure.core" "double?" jolt-float?) -;; ratio?/rational? now live (correctly) in the overlay, so they no longer need a -;; native re-assertion here. decimal? stays (bigdec re-binds it). +(def-var! "clojure.core" "ratio?" jolt-ratio?) +(def-var! "clojure.core" "rational?" jolt-rational?) (def-var! "clojure.core" "decimal?" jolt-decimal?) (def-var! "clojure.core" "==" jolt-num-equiv) ;; chunked-seq? is true for a vector's seq (a real chunked-seq); the overlay's ;; always-false stub loaded over the host fn, so re-assert it. (def-var! "clojure.core" "chunked-seq?" na-chunked-seq?) -;; record? is a host type check — true only for a defrecord, not a bare deftype -;; (jrec-record?), matching the JVM (instance? IRecord). The overlay's -;; (some? (get x :jolt/deftype)) get-trick would invoke a sorted-map comparator. -(def-var! "clojure.core" "record?" (lambda (x) (jrec-record? x))) +;; record? is a host type check (jrec?), not the overlay's (some? (get x +;; :jolt/deftype)) — the get-trick invokes a sorted-map's comparator on +;; :jolt/deftype and throws. Matches the JVM (instance? IRecord). +(def-var! "clojure.core" "record?" (lambda (x) (jrec? x))) ;; read / read+string over a HOST reader jhost (java.io StringReader/PushbackReader): ;; the overlay's IReader protocol only covers the reify map-reader, so a (read @@ -123,13 +111,13 @@ ((stream) (if (reader-jhost? stream) (let-values (((form found?) (host-reader-read-form stream))) - (if found? form (jolt-throw (jolt-ex-info "EOF while reading" empty-pmap)))) + (if found? form (jolt-throw (jolt-ex-info "EOF while reading" (empty-pmap))))) (jolt-invoke ov-read stream))) ((stream e? ev) (if (reader-jhost? stream) (let-values (((form found?) (host-reader-read-form stream))) (cond (found? form) - ((jolt-truthy? e?) (jolt-throw (jolt-ex-info "EOF while reading" empty-pmap))) + ((jolt-truthy? e?) (jolt-throw (jolt-ex-info "EOF while reading" (empty-pmap)))) (else ev))) (jolt-invoke ov-read stream e? ev)))))) (let ((ov-rps (var-deref "clojure.core" "read+string"))) @@ -142,7 +130,7 @@ (let* ((s (drain-reader stream)) (pr (jolt-parse-next s))) (if (jolt-nil? pr) (begin (reader-refill! stream "") - (if (jolt-truthy? e?) (jolt-throw (jolt-ex-info "EOF while reading" empty-pmap)) + (if (jolt-truthy? e?) (jolt-throw (jolt-ex-info "EOF while reading" (empty-pmap))) (jolt-vector ev ""))) (let ((rest (jolt-nth pr 1))) (reader-refill! stream rest) diff --git a/host/chez/predicates.ss b/host/chez/predicates.ss index 9419755..5bacdaf 100644 --- a/host/chez/predicates.ss +++ b/host/chez/predicates.ss @@ -12,9 +12,11 @@ (define (jolt-vector? x) (pvec? x)) (define (jolt-set? x) (pset? x)) (define (jolt-seq? x) (or (cseq? x) (empty-list-t? x))) -;; list? lives in the overlay (clojure/core/20-coll.clj) — see jolt.host/cseq? etc. +;; (list? x): a list-marked cseq node or the empty list (). A lazy/vector-backed +;; seq, (rest list), (seq coll), (map …) are seqs but not lists. +(define (jolt-list-pred? x) (or (and (cseq? x) (cseq-list? x)) (empty-list-t? x))) (define (jolt-coll-pred? x) - (or (pvec? x) (pmap? x) (pset? x) (cseq? x) (empty-list-t? x) (jolt-lazyseq? x))) + (or (pvec? x) (pmap? x) (pset? x) (cseq? x) (empty-list-t? x))) (define (jolt-number? x) (number? x)) (define (jolt-string? x) (string? x)) (define (jolt-char-pred? x) (char? x)) @@ -25,18 +27,13 @@ ;; BigDecimal). decimal? is always false (no BigDecimal type). (define (jolt-integer? x) (and (number? x) (exact? x) (integer? x))) (define (jolt-float? x) (and (number? x) (flonum? x))) -;; ratio?/rational? live in the overlay (clojure/core/20-coll.clj), built on the -;; jolt.host tower tests. decimal? stays native: the optional bigdec module -;; (java/bigdec.ss) re-binds it to jbigdec?, so it can't be a static overlay const. +(define (jolt-ratio? x) (and (number? x) (exact? x) (rational? x) (not (integer? x)))) +(define (jolt-rational? x) (and (number? x) (exact? x))) (define (jolt-decimal? x) #f) (define (jolt-fn? x) (procedure? x)) (define (jolt-boolean-pred? x) (boolean? x)) -;; (boolean x) coerces truthiness (nil/false -> false, else true). MUST stay native: -;; the backend's emit path calls clojure.core/boolean for every :if node -;; (backend_scheme.clj bool tracking), so it has to exist before ANY compilation, -;; including the kernel overlay tier (whose own fns contain `if`). Migrating it even -;; to the kernel tier deadlocks: compiling the tier that defines boolean needs boolean. +;; (boolean x) coerces truthiness (nil/false -> false, else true). (define (jolt-boolean x) (if (jolt-truthy? x) #t #f)) ;; (name x): keyword/symbol -> name string; string -> itself. @@ -60,6 +57,8 @@ (def-var! "clojure.core" "char?" jolt-char-pred?) (def-var! "clojure.core" "integer?" jolt-integer?) (def-var! "clojure.core" "float?" jolt-float?) +(def-var! "clojure.core" "ratio?" jolt-ratio?) +(def-var! "clojure.core" "rational?" jolt-rational?) (def-var! "clojure.core" "decimal?" jolt-decimal?) ;; == numeric value-equality (ignores exactness, unlike =): (== 3 3.0) -> true. ;; 1-arity is trivially true; 2+ args must all be numbers (Numbers.equiv throws @@ -81,30 +80,10 @@ (def-var! "clojure.core" "vector?" jolt-vector?) (def-var! "clojure.core" "set?" jolt-set?) (def-var! "clojure.core" "seq?" jolt-seq?) +(def-var! "clojure.core" "list?" jolt-list-pred?) (def-var! "clojure.core" "coll?" jolt-coll-pred?) (def-var! "clojure.core" "fn?" jolt-fn?) (def-var! "clojure.core" "boolean?" jolt-boolean-pred?) (def-var! "clojure.core" "boolean" jolt-boolean) (def-var! "clojure.core" "name" jolt-name) (def-var! "clojure.core" "namespace" jolt-namespace) - -;; --- jolt.host raw type-test primitives ------------------------------------- -;; Some clojure.core predicates bottom out at host tests overlay Clojure can't -;; reach. Expose the ones the migratable predicates need so the overlay versions -;; lower to exactly these calls — no perf loss. rational-type? is the Chez TYPE -;; test (exact rational), distinct from clojure.core/rational? (which gates on -;; number? first). exact? is wrapped TOTAL (Chez's raw exact? errors on a -;; non-number); rational-type? already returns #f for a non-match. -;; -;; Only the tests consumed by the migrated predicates (ratio?/rational? -> exact?, -;; rational-type?; list? -> cseq?/cseq-list?/empty-list?) are exposed. The rest of -;; the predicate web stays native and is NOT exposed: map?/set?/seq?/coll? are -;; extended at runtime with sorted/record/lazy arms, decimal? is extended by the -;; optional bigdec module, integer?/float? are on the compiler emit/inference path, -;; and vector? is reached by the kernel-tier peek during bootstrap. -(define (jh-exact? x) (and (number? x) (exact? x))) -(def-var! "jolt.host" "exact?" jh-exact?) -(def-var! "jolt.host" "rational-type?" rational?) -(def-var! "jolt.host" "cseq?" cseq?) -(def-var! "jolt.host" "empty-list?" empty-list-t?) -(def-var! "jolt.host" "cseq-list?" cseq-list?) diff --git a/host/chez/printing.ss b/host/chez/printing.ss index 5df1dbf..464c9ee 100644 --- a/host/chez/printing.ss +++ b/host/chez/printing.ss @@ -47,22 +47,25 @@ ((jolt-transient? x) (case (jolt-transient-kind x) ((vec) "#") ((set) "#") (else "#"))) - ((pvec? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "[" (jolt-str-join (jolt-limited-vec-strs x jolt-pr-readable)) "]")))) - ((pset? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "#{" (jolt-str-join (jolt-limited-list-strs - (pset-fold x (lambda (e a) (cons (jolt-pr-readable e) a)) '()))) "}")))) - ((pmap? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "{" (jolt-str-join (jolt-limited-list-strs - (pmap-fold x (lambda (k v a) - (cons (string-append (jolt-pr-readable k) " " (jolt-pr-readable v)) a)) '()))) "}")))) - ((empty-list-t? x) (if (jolt-print-hash?) "#" "()")) - ((cseq? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "(" (jolt-str-join (jolt-limited-seq-strs x jolt-pr-readable)) ")")))) + ((pvec? x) + (let ((acc '())) + (let loop ((i (fx- (pvec-count x) 1))) + (when (fx>=? i 0) + (set! acc (cons (jolt-pr-readable (pvec-nth-d x i jolt-nil)) acc)) + (loop (fx- i 1)))) + (string-append "[" (jolt-str-join acc) "]"))) + ((pset? x) + (string-append "#{" (jolt-str-join (pset-fold x (lambda (e a) (cons (jolt-pr-readable e) a)) '())) "}")) + ((pmap? x) + (string-append "{" (jolt-str-join + (pmap-fold x (lambda (k v a) + (cons (string-append (jolt-pr-readable k) " " (jolt-pr-readable v)) a)) '())) "}")) + ((empty-list-t? x) "()") + ((cseq? x) + (string-append "(" (jolt-str-join + (let loop ((s x) (acc '())) + (if (jolt-nil? s) (reverse acc) + (loop (jolt-seq (seq-more s)) (cons (jolt-pr-readable (seq-first s)) acc))))) ")")) (else (jolt-pr-str x)))) (define (jolt-pr-readable-dispatch x) (let loop ((as jolt-pr-readable-arms)) diff --git a/host/chez/reader.ss b/host/chez/reader.ss index 068bfa3..42a9abb 100644 --- a/host/chez/reader.ss +++ b/host/chez/reader.ss @@ -47,25 +47,8 @@ (memv c '(#\( #\) #\[ #\] #\{ #\} #\" #\; #\@ #\^ #\` #\~ #\\)))) (define (rdr-digit? c) (and (char>=? c #\0) (char<=? c #\9))) -(define (rdr-octal? c) (and (char>=? c #\0) (char<=? c #\7))) -(define (rdr-all-digits? s from to) - (and (> to from) - (let loop ((i from)) - (cond ((>= i to) #t) - ((rdr-digit? (string-ref s i)) (loop (+ i 1))) - (else #f))))) -;; every char of s in [from,to) is an octal digit (and the span is non-empty). -(define (rdr-all-octal? s from to) - (and (fx= j end) (char=? (string-ref s j) #\newline) - (char=? (string-ref s j) #\return)) + (if (or (>= j end) (char=? (string-ref s j) #\newline)) (loop j) (eol (+ j 1))))) (else i)))) @@ -128,17 +110,12 @@ (slash (rdr-string-index-char body #\/))) (cond ;; ratio a/b -> exact rational (= JVM Ratio); reduces to an exact integer - ;; when d divides n. Both parts must be plain digit runs (1/-1 is an - ;; invalid token); a zero denominator is the JVM's divide error. + ;; when d divides n. (slash - (let ((ns (substring body 0 slash)) - (ds (substring body (+ slash 1) blen))) - (and (rdr-all-digits? ns 0 (string-length ns)) - (rdr-all-digits? ds 0 (string-length ds)) - (let ((n (string->number ns)) (d (string->number ds))) - (when (= d 0) - (jolt-throw (jolt-host-throwable "java.lang.ArithmeticException" "Divide by zero"))) - (* sign (/ n d)))))) + (let ((n (string->number (substring body 0 slash))) + (d (string->number (substring body (+ slash 1) blen)))) + (and (integer? n) (integer? d) (not (= d 0)) + (* sign (/ n d))))) ;; hex 0x.. ((and (>= blen 2) (char=? (string-ref body 0) #\0) (or (char=? (string-ref body 1) #\x) (char=? (string-ref body 1) #\X))) @@ -152,16 +129,6 @@ (and radix (integer? radix) (>= radix 2) (<= radix 36) (let ((v (rdr-parse-radix (substring body (+ ri 1) blen) radix))) (and v (* sign v))))))) - ;; octal 0NNN: a leading 0 followed by octal digits (Clojure reads 042 as 34, - ;; not decimal 42). "0" alone, 0x.., 0r.. and a float "0.5" are handled - ;; elsewhere or fall through (a non-octal digit fails rdr-all-octal?). - ((and (>= blen 2) (char=? (string-ref body 0) #\0) (rdr-all-octal? body 1 blen)) - (let ((o (rdr-parse-radix (substring body 1 blen) 8))) (and o (* sign o)))) - ;; a leading zero on a plain multi-digit integer is invalid (the octal - ;; branch above accepted real octals; 08/09 match the JVM's trailing - ;; "invalid number" alternative) - ((and (>= blen 2) (char=? (string-ref body 0) #\0) (rdr-all-digits? body 1 blen)) - #f) ;; bigint suffix N ((and (> blen 1) (char=? (string-ref body (- blen 1)) #\N)) (let ((n (string->number (substring body 0 (- blen 1))))) @@ -193,7 +160,7 @@ ;; opening quote already consumed; read to the closing quote, processing escapes. (define (rdr-read-string-lit s i end) (let loop ((i i) (acc '())) - (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading string" empty-pmap))) + (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading string" (empty-pmap)))) (let ((c (string-ref s i))) (cond ((char=? c #\") (values (list->string (reverse acc)) (+ i 1))) @@ -207,16 +174,7 @@ ((#\") (loop (+ i 2) (cons #\" acc))) ((#\b) (loop (+ i 2) (cons #\backspace acc))) ((#\f) (loop (+ i 2) (cons #\page acc))) - ;; octal escape \ooo: 1-3 octal digits (Clojure's \0..\377), so \000 - ;; is one null char, not \0 + literal "00". - ((#\0 #\1 #\2 #\3 #\4 #\5 #\6 #\7) - (let oct ((j (+ i 1)) (val 0) (cnt 0)) - (if (and (fxinteger (string-ref s j)) 48)) (fx+ cnt 1)) - (begin - (when (> val 255) - (jolt-throw (jolt-ex-info "Octal escape sequence must be in range [0, 377]" empty-pmap))) - (loop j (cons (integer->char val) acc)))))) + ((#\0) (loop (+ i 2) (cons #\nul acc))) ((#\u) (let-values (((cp j) (rdr-hex->int s (+ i 2) 4))) ;; A \u escape is a UTF-16 code unit. jolt chars are Unicode scalars, @@ -234,13 +192,12 @@ (loop j (cons #\xFFFD acc))))) ((and (fx>=? cp #xD800) (fx<=? cp #xDFFF)) (loop j (cons #\xFFFD acc))) (else (loop j (cons (integer->char cp) acc)))))) - (else (jolt-throw (jolt-ex-info (string-append "Unsupported escape character: \\" (string e)) - empty-pmap)))))) + (else (loop (+ i 2) (cons e acc)))))) (else (loop (+ i 1) (cons c acc))))))) ;; backslash already consumed; read a Clojure character literal. (define (rdr-read-char s i end) - (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading char" empty-pmap))) + (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading char" (empty-pmap)))) (let ((c0 (string-ref s i))) (if (char-alphabetic? c0) ;; named / unicode / single-letter: collect the alnum run @@ -267,12 +224,9 @@ ((char=? (string-ref name 0) #\u) (integer->char (string->number (substring name 1 (string-length name)) 16))) ((char=? (string-ref name 0) #\o) - (let ((v (string->number (substring name 1 (string-length name)) 8))) - (when (or (not v) (> v 255)) - (jolt-throw (jolt-ex-info "Octal escape sequence must be in range [0, 377]" empty-pmap))) - (integer->char v))) + (integer->char (string->number (substring name 1 (string-length name)) 8))) (else (jolt-throw (jolt-ex-info (string-append "Unsupported character: \\" name) - empty-pmap))))) + (empty-pmap)))))) ;; --- token (symbol / keyword / number / nil|true|false) --------------------- (define (rdr-read-token s i end) @@ -288,39 +242,14 @@ (values #f tok) (values (substring tok 0 slash) (substring tok (+ slash 1) (string-length tok)))))) -(define (rdr-numeric-lead? tok) - (let ((len (string-length tok))) - (and (> len 0) - (let ((c0 (string-ref tok 0))) - (or (rdr-digit? c0) - (and (or (char=? c0 #\+) (char=? c0 #\-)) (> len 1) - (rdr-digit? (string-ref tok 1)))))))) -(define (rdr-invalid-token tok) - (jolt-throw (jolt-host-throwable "java.lang.RuntimeException" - (string-append "Invalid token: " tok)))) (define (rdr-token->value tok) (let ((n (rdr-try-number tok))) (cond (n n) - ;; a token that starts like a number but doesn't parse as one is an - ;; invalid number (1a, 08, 0x2g, 2r2), never a symbol — like the JVM. - ((rdr-numeric-lead? tok) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - (string-append "Invalid number: " tok)))) ((string=? tok "nil") jolt-nil) ((string=? tok "true") #t) ((string=? tok "false") #f) - (else - (let ((len (string-length tok))) - ;; a lone "/" is the division symbol, and "ns//" names it in a - ;; namespace (clojure.core//); otherwise a leading or trailing slash - ;; leaves an empty ns/name part — an invalid token. - (when (and (> len 1) - (or (char=? (string-ref tok 0) #\/) - (and (char=? (string-ref tok (- len 1)) #\/) - (not (and (> len 2) (char=? (string-ref tok (- len 2)) #\/)))))) - (rdr-invalid-token tok)) - (let-values (((ns name) (rdr-sym-parts tok))) (jolt-symbol ns name))))))) + (else (let-values (((ns name) (rdr-sym-parts tok))) (jolt-symbol ns name)))))) ;; --- collections ------------------------------------------------------------ ;; Read forms until the close delimiter; returns (values reversed?-no list j). @@ -328,7 +257,7 @@ (let loop ((i i) (acc '())) (let ((i (rdr-skip-ws s i end))) (cond - ((>= i end) (jolt-throw (jolt-ex-info "EOF while reading" empty-pmap))) + ((>= i end) (jolt-throw (jolt-ex-info "EOF while reading" (empty-pmap)))) ((char=? (string-ref s i) close) (values (reverse acc) (+ i 1))) (else (let-values (((form j) (rdr-read-form s i end))) @@ -344,14 +273,6 @@ ;; sequence in a weak side-table the host contract's form-map-pairs consults. (define rdr-map-order (make-weak-eq-hashtable)) (define (rdr-make-map es) - ;; the JVM reader rejects duplicate literal keys before building the map - (let dupchk ((kvs es) (seen empty-pset)) - (when (pair? kvs) - (let ((k (car kvs))) - (when (jolt-truthy? (jolt-contains? seen k)) - (jolt-throw (jolt-host-throwable "java.lang.IllegalArgumentException" - (string-append "Duplicate key: " (jolt-pr-str k))))) - (dupchk (cddr kvs) (pset-conj seen k))))) (let ((m (apply jolt-hash-map es))) (when (pair? es) (hashtable-set! rdr-map-order m es)) m)) @@ -378,7 +299,7 @@ (define (rdr-merge-meta old new) (if (pmap? old) - (pmap-fold-fwd new (lambda (k v acc) (jolt-assoc1 acc k v)) old) + (pmap-fold new (lambda (k v acc) (jolt-assoc1 acc k v)) old) new)) (define (rdr-attach-meta target meta) @@ -386,6 +307,7 @@ ((symbol-t? target) (make-symbol-t (symbol-t-ns target) (symbol-t-name target) (rdr-merge-meta (symbol-t-meta target) meta))) + ((empty-list-t? target) target) ;; Lists/vectors/maps/sets attach metadata to the value itself, as Clojure's ;; reader does. Reading DATA (read-string, edn) then preserves it. A list form ;; is code: ^Type (expr) is a compile-time hint on the FORM, read off the form @@ -394,11 +316,7 @@ ;; (with-meta form meta) for a meta-carrying collection literal in code, so ;; (meta ^{:tag :int} [1 2]) / ^:foo {} still works. (else - ;; Merge onto any metadata the target already carries (a list form picks up - ;; :line/:column first, then ^meta folds its keys on top). - (let* ((old (jolt-meta target)) - (merged (rdr-merge-meta (if (jolt-nil? old) jolt-nil old) meta)) - (c (jolt-with-meta target merged))) + (let ((c (jolt-with-meta target meta))) ;; jolt-with-meta copies a pmap, giving it a fresh identity the rdr-map-order ;; side-table (source key order for left-to-right map-literal eval) loses — ;; carry the order entry over to the copy. @@ -406,45 +324,6 @@ (when order (hashtable-set! rdr-map-order c order))) c)))) -;; --- source position -------------------------------------------------------- -;; List forms (code) carry 1-based :line/:column, plus :file when the compiler -;; bound rdr-source-file. read-string leaves the file unset. The analyzer reads -;; this back via jolt.host/form-position to stamp :pos on call nodes; macros and -;; (meta (read-string "(…)")) see it too. -(define rdr-source-file (make-thread-parameter #f)) -(define rdr-kw-line (keyword #f "line")) -(define rdr-kw-column (keyword #f "column")) -(define rdr-kw-file (keyword #f "file")) - -;; Forms are read left-to-right, so the indices queried are non-decreasing within -;; one source string — keep a cursor and count newlines only over the delta -;; (O(n) total, not O(n^2)). A different string or a backward index resets it. -(define rdr-pos-cursor (make-thread-parameter #f)) ; #f | (vector s i line col) -(define (rdr-line-col-at s i) - (let* ((cur (rdr-pos-cursor)) - (reuse (and (vector? cur) (eq? (vector-ref cur 0) s) - (fx<=? (vector-ref cur 1) i))) - (k0 (if reuse (vector-ref cur 1) 0)) - (l0 (if reuse (vector-ref cur 2) 1)) - (c0 (if reuse (vector-ref cur 3) 1))) - (let loop ((k k0) (line l0) (col c0)) - (if (fx>=? k i) - (begin (rdr-pos-cursor (vector s k line col)) (values line col)) - (if (char=? (string-ref s k) #\newline) - (loop (fx+ k 1) (fx+ line 1) 1) - (loop (fx+ k 1) line (fx+ col 1))))))) - -(define (rdr-pos-meta line col) - (let ((f (rdr-source-file))) - (if f - (jolt-hash-map rdr-kw-line line rdr-kw-column col rdr-kw-file f) - (jolt-hash-map rdr-kw-line line rdr-kw-column col)))) - -(define (rdr-attach-pos lst line col) - (if (empty-list-t? lst) ; () is interned, can't carry meta (= Clojure) - lst - (rdr-attach-meta lst (rdr-pos-meta line col)))) - ;; --- # dispatch ------------------------------------------------------------- ;; #(...) anonymous fn shorthand: % -> p1, %N -> pN, %& -> rest. The ;; fixed arity is the MAX positional used (Clojure: #(do %2 %&) -> [p1 p2 & rest]). @@ -515,7 +394,7 @@ (let* ((splice (and (< i end) (char=? (string-ref s i) #\@))) (start (if splice (+ i 1) i))) (let-values (((form j) (rdr-read-form s start end))) - (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after #?" empty-pmap))) + (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after #?" (empty-pmap)))) (let ((items (cond ((pvec? form) (seq->list form)) ((or (cseq? form) (empty-list-t? form)) (seq->list form)) (else '())))) @@ -534,69 +413,8 @@ (values (cadr xs) j))) (else (loop (cddr xs))))))))) -(define (rdr-string-rindex-char str c) - (let loop ((i (- (string-length str) 1))) - (cond ((< i 0) #f) ((char=? (string-ref str i) c) i) (else (loop (- i 1)))))) - -;; A record/type literal tag (#ns.Type{..} / #ns.Type[..]) is any tag containing -;; a dot — Clojure routes those to a constructor instead of a data reader. -(define (rdr-record-tag? tok) (and (rdr-string-rindex-char tok #\.) #t)) - -;; #a.b.C{..} -> (a.b/map->C {..}); #a.b.C[..] -> (a.b/->C ..). The factory call -;; compiles like any invoke; defrecord interns map->C/->C in the type's ns. -(define (rdr-record-ctor-form tok form) - (let* ((di (rdr-string-rindex-char tok #\.)) - (ns (substring tok 0 di)) - (simple (substring tok (+ di 1) (string-length tok)))) - (cond - ((pmap? form) - (jolt-list (jolt-symbol ns (string-append "map->" simple)) form)) - ((pvec? form) - (apply jolt-list (jolt-symbol ns (string-append "->" simple)) - (vector->list (pvec-v form)))) - (else (jolt-throw (jolt-ex-info - (string-append "Unreadable constructor form: #" tok) - empty-pmap)))))) - -;; #:ns{…} namespaced map literal: a bare keyword/symbol key gets `ns`, a `:_/x` -;; key is un-namespaced, an already-qualified key stays. #::{…} uses the current -;; ns; #::alias{…} resolves the alias. -(define (rdr-nsmap-key mapns k) - (cond - ((keyword? k) - (let ((kns (keyword-t-ns k)) (kn (keyword-t-name k))) - (cond ((and (string? kns) (string=? kns "_")) (keyword #f kn)) - (kns k) - (else (keyword mapns kn))))) - ((symbol-t? k) - (let ((kns (symbol-t-ns k)) (kn (symbol-t-name k))) - (cond ((and (string? kns) (string=? kns "_")) (jolt-symbol #f kn)) - (kns k) - (else (jolt-symbol mapns kn))))) - (else k))) -(define (rdr-nsmap-kvs mapns es) - (cond ((null? es) '()) - ((null? (cdr es)) es) - (else (cons (rdr-nsmap-key mapns (car es)) - (cons (cadr es) (rdr-nsmap-kvs mapns (cddr es))))))) -(define (rdr-read-ns-map s i end) ; i points just past "#:" - (let* ((auto? (and (< i end) (char=? (string-ref s i) #\:))) - (i2 (if auto? (+ i 1) i))) - (let loop ((j i2)) - (cond - ((>= j end) (jolt-throw (jolt-ex-info "EOF in namespaced map literal" empty-pmap))) - ((char=? (string-ref s j) #\{) - (let* ((nstok (substring s i2 j)) - (mapns (if auto? - (if (string=? nstok "") (chez-current-ns) - (let ((a (chez-resolve-alias (chez-current-ns) nstok))) (if a a nstok))) - nstok))) - (let-values (((es k) (rdr-read-seq s (+ j 1) end #\}))) - (values (rdr-make-map (rdr-nsmap-kvs mapns es)) k)))) - (else (loop (+ j 1))))))) - (define (rdr-read-dispatch s i end) ; i points just past the '#' - (when (>= i end) (jolt-throw (jolt-ex-info "EOF after #" empty-pmap))) + (when (>= i end) (jolt-throw (jolt-ex-info "EOF after #" (empty-pmap)))) (let ((c (string-ref s i))) (cond ((char=? c #\{) ; #{...} set @@ -611,12 +429,8 @@ (let-values (((src j) (rdr-read-regex s (+ i 1) end))) (values (jolt-re-pattern src) j))) ((char=? c #\_) ; #_ discard the next form - (let-values (((d j) (rdr-read-form s (+ i 1) end))) - (when (rdr-eof? d) (jolt-throw (jolt-ex-info "EOF after #_" empty-pmap))) - ;; edn validates the discarded element (its tags go through the same - ;; :readers/:default pipeline; an unreadable one throws) - (let ((cb (rdr-discard-cb))) - (when cb (jolt-invoke cb d))) + (let-values (((_ j) (rdr-read-form s (+ i 1) end))) + (when (rdr-eof? _) (jolt-throw (jolt-ex-info "EOF after #_" (empty-pmap)))) (rdr-read-form s j end))) ((char=? c #\') ; #'x var-quote -> (var x) (let-values (((form j) (rdr-read-form s (+ i 1) end))) @@ -625,7 +439,7 @@ (let-values (((mform j) (rdr-read-form s (+ i 1) end))) (let-values (((target k) (rdr-read-form s j end))) (when (rdr-eof? target) - (jolt-throw (jolt-ex-info "EOF after #^meta" empty-pmap))) + (jolt-throw (jolt-ex-info "EOF after #^meta" (empty-pmap)))) (values (rdr-attach-meta target (rdr-meta-map mform)) k)))) ((char=? c #\#) ; ## symbolic value: ##Inf / ##-Inf / ##NaN (let-values (((tok j) (rdr-read-token s (+ i 1) end))) @@ -633,25 +447,21 @@ ((string=? tok "-Inf") -inf.0) ((string=? tok "NaN") +nan.0) (else (jolt-throw (jolt-ex-info (string-append "unknown ## literal: " tok) - empty-pmap)))) + (empty-pmap))))) j))) ((char=? c #\?) ; #?(...) / #?@(...) reader conditional (rdr-read-reader-cond s (+ i 1) end)) - ((char=? c #\:) ; #:ns{...} namespaced map literal - (rdr-read-ns-map s (+ i 1) end)) (else ; #tag form -> tagged {:tag :#tag :form ...} (let-values (((tok j) (rdr-read-token s i end))) (let-values (((form k) (rdr-read-form s j end))) - (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after #tag" empty-pmap))) - (if (rdr-record-tag? tok) ; #ns.Type{..}/[..] record literal - (values (rdr-record-ctor-form tok form) k) - (values (rdr-make-tagged (keyword #f (string-append "#" tok)) form) k)))))))) + (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after #tag" (empty-pmap)))) + (values (rdr-make-tagged (keyword #f (string-append "#" tok)) form) k))))))) ;; regex literal source: raw chars to the closing quote; \" is an escaped quote, ;; every other backslash sequence is kept verbatim (regex engine semantics). (define (rdr-read-regex s i end) (let loop ((i i) (acc '())) - (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading regex" empty-pmap))) + (when (>= i end) (jolt-throw (jolt-ex-info "EOF while reading regex" (empty-pmap)))) (let ((c (string-ref s i))) (cond ((char=? c #\") (values (list->string (reverse acc)) (+ i 1))) @@ -668,17 +478,6 @@ (let ((auto? (and (< i end) (char=? (string-ref s i) #\:)))) (let ((i (if auto? (+ i 1) i))) (let-values (((tok j) (rdr-read-token s i end))) - (let ((len (string-length tok))) - ;; ":" and "::" alone, a leading or trailing slash (a name of exactly - ;; "/" is fine, :ns//), or an auto-resolved keyword in edn (no - ;; resolution context) are invalid tokens. - (when (or (= len 0) - (and (> len 1) (char=? (string-ref tok 0) #\/)) - (and (> len 1) (char=? (string-ref tok (- len 1)) #\/) - (not (and (> len 2) (char=? (string-ref tok (- len 2)) #\/))))) - (rdr-invalid-token (string-append (if auto? "::" ":") tok))) - (when (and auto? (rdr-edn-mode)) - (rdr-invalid-token (string-append "::" tok)))) (let-values (((ns name) (rdr-sym-parts tok))) (if auto? (let* ((cur (chez-current-ns)) @@ -697,9 +496,8 @@ (values rdr-eof i) (let ((c (string-ref s i))) (cond - ((char=? c #\() (let-values (((line col) (rdr-line-col-at s i))) - (let-values (((es j) (rdr-read-seq s (+ i 1) end #\)))) - (values (rdr-attach-pos (apply jolt-list es) line col) j)))) + ((char=? c #\() (let-values (((es j) (rdr-read-seq s (+ i 1) end #\)))) + (values (apply jolt-list es) j))) ((char=? c #\[) (let-values (((es j) (rdr-read-seq s (+ i 1) end #\]))) (values (apply jolt-vector es) j))) ((char=? c #\{) (let-values (((es j) (rdr-read-seq s (+ i 1) end #\}))) @@ -716,24 +514,21 @@ ;; inert: ``42 reads as 42, ```"meow" as "meow". ((char=? c #\`) (let-values (((form j) (rdr-read-form s (+ i 1) end))) - (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after `" empty-pmap))) + (when (rdr-eof? form) (jolt-throw (jolt-ex-info "EOF after `" (empty-pmap)))) (values (if (rdr-self-eval-literal? form) form (jolt-list (jolt-symbol #f "syntax-quote") form)) j))) ((char=? c #\@) (rdr-wrap s (+ i 1) end (jolt-symbol "clojure.core" "deref"))) - ;; ~ / ~@ read as clojure.core/unquote(-splicing), like the JVM reader — - ;; so code that inspects pattern/template data (core.logic's defne) sees - ;; the qualified symbol it expects. ((char=? c #\~) (if (and (< (+ i 1) end) (char=? (string-ref s (+ i 1)) #\@)) - (rdr-wrap s (+ i 2) end (jolt-symbol "clojure.core" "unquote-splicing")) - (rdr-wrap s (+ i 1) end (jolt-symbol "clojure.core" "unquote")))) + (rdr-wrap s (+ i 2) end (jolt-symbol #f "unquote-splicing")) + (rdr-wrap s (+ i 1) end (jolt-symbol #f "unquote")))) ((char=? c #\^) (let-values (((mform j) (rdr-read-form s (+ i 1) end))) (let-values (((target k) (rdr-read-form s j end))) (when (rdr-eof? target) - (jolt-throw (jolt-ex-info "EOF after ^meta" empty-pmap))) + (jolt-throw (jolt-ex-info "EOF after ^meta" (empty-pmap)))) (values (rdr-attach-meta target (rdr-meta-map mform)) k)))) (else (let-values (((tok j) (rdr-read-token s i end))) @@ -748,7 +543,7 @@ (define (rdr-wrap s i end head) (let-values (((form j) (rdr-read-form s i end))) (when (rdr-eof? form) - (jolt-throw (jolt-ex-info "EOF while reading reader macro" empty-pmap))) + (jolt-throw (jolt-ex-info "EOF while reading reader macro" (empty-pmap)))) (values (jolt-list head form) j))) ;; --- form -> data ----------------------------------------------------------- @@ -768,11 +563,8 @@ (let ((c (rdr-form->data (car xs)))) (loop (cdr xs) (cons c acc) (or changed (not (eq? c (car xs))))))))) -;; carry the reader metadata, converting its nested forms too — a set/tagged -;; literal inside a ^{…} map (^{:k #{…}}) must become a value like the rest of -;; the data, not stay the tagged set-form. (define (rdr-carry-meta src dst) - (let ((m (jolt-meta src))) (if (jolt-nil? m) dst (jolt-with-meta dst (rdr-form->data m))))) + (let ((m (jolt-meta src))) (if (jolt-nil? m) dst (jolt-with-meta dst m)))) ;; tag keyword (:#time/date) -> its *data-readers* reader fn, or #f. The fn's ;; namespace must already be loaded (the loader requires them when a project's @@ -795,173 +587,52 @@ (guard (e (#t #f)) (let ((fn (var-deref (symbol-t-ns v) (symbol-t-name v)))) (and (procedure? fn) fn))))))))) -;; the bare tag SYMBOL for a :#name / :#ns/name reader keyword (strip the leading -;; #, split a qualified tag on /). *default-data-reader-fn* receives it. -(define (rdr-tag->symbol tag) - (let* ((nm (keyword-t-name tag)) - (bare (if (and (> (string-length nm) 0) (char=? (string-ref nm 0) #\#)) - (substring nm 1 (string-length nm)) nm))) - (let loop ((i 0)) - (cond ((>= i (string-length bare)) (jolt-symbol #f bare)) - ((char=? (string-ref bare i) #\/) - (jolt-symbol (substring bare 0 i) (substring bare (+ i 1) (string-length bare)))) - (else (loop (+ i 1))))))) -;; *default-data-reader-fn* — a (fn [tag value]) consulted for an unregistered -;; tag, or #f when unset/nil. Honors a `binding` (var-deref reads the stack). -(define (rdr-default-data-reader-fn) - (guard (e (#t #f)) - (let ((v (var-deref "clojure.core" "*default-data-reader-fn*"))) - (and (not (jolt-nil? v)) (procedure? v) v)))) - -;; strict #inst validation: RFC-3339 calendar fields must be real (month 1-12, -;; day valid for the month incl. leap years, hour < 24, minute/second < 60). -(define (rdr-2dig s i) - (and (< (+ i 1) (string-length s)) - (rdr-digit? (string-ref s i)) (rdr-digit? (string-ref s (+ i 1))) - (+ (* 10 (- (char->integer (string-ref s i)) 48)) - (- (char->integer (string-ref s (+ i 1))) 48)))) -(define (rdr-leap? y) (and (= 0 (modulo y 4)) (or (not (= 0 (modulo y 100))) (= 0 (modulo y 400))))) -(define (rdr-inst-throw s) - (jolt-throw (jolt-host-throwable "java.lang.RuntimeException" - (string-append "Unrecognized date/time syntax: " s)))) -(define (rdr-validate-inst! s) - ;; progressive RFC-3339 like clojure.instant: yyyy[-MM[-dd[Thh[:mm[:ss[.f]]]]]] - ;; with an optional Z/±hh:mm offset; each present field must be in range - ;; (months 1-12, day valid for the month incl. leap years, hour < 24, min < 60). - (let* ((len (string-length s)) - (y (and (>= len 4) (rdr-all-digits? s 0 4) (string->number (substring s 0 4))))) - (unless y (rdr-inst-throw s)) - (when (>= len 5) - (unless (char=? (string-ref s 4) #\-) (rdr-inst-throw s)) - (let ((mo (rdr-2dig s 5))) - (unless (and mo (>= mo 1) (<= mo 12)) (rdr-inst-throw s)) - (when (>= len 8) - (unless (char=? (string-ref s 7) #\-) (rdr-inst-throw s)) - (let ((d (rdr-2dig s 8))) - (unless (and d (>= d 1) - (<= d (vector-ref (if (rdr-leap? y) - '#(31 29 31 30 31 30 31 31 30 31 30 31) - '#(31 28 31 30 31 30 31 31 30 31 30 31)) - (- mo 1)))) - (rdr-inst-throw s)) - (when (>= len 11) - (unless (char=? (string-ref s 10) #\T) (rdr-inst-throw s)) - (let ((h (rdr-2dig s 11))) - (unless (and h (<= h 23)) (rdr-inst-throw s)) - (when (>= len 14) - (when (char=? (string-ref s 13) #\:) - (let ((mi (rdr-2dig s 14))) - (unless (and mi (<= mi 59)) (rdr-inst-throw s))))))))))))) -;; strict #uuid: canonical 8-4-4-4-12 hex groups. -(define (rdr-validate-uuid! s) - (define (hexrun? from to) - (let loop ((i from)) - (cond ((>= i to) #t) - ((let ((c (char-downcase (string-ref s i)))) - (or (rdr-digit? c) (and (char>=? c #\a) (char<=? c #\f)))) - (loop (+ i 1))) - (else #f)))) - (unless (and (= (string-length s) 36) - (char=? (string-ref s 8) #\-) (char=? (string-ref s 13) #\-) - (char=? (string-ref s 18) #\-) (char=? (string-ref s 23) #\-) - (hexrun? 0 8) (hexrun? 9 13) (hexrun? 14 18) (hexrun? 19 23) (hexrun? 24 36)) - (jolt-throw (jolt-host-throwable "java.lang.IllegalArgumentException" - (string-append "Invalid UUID string: " s))))) - ;; read-string / read data seam: construct the value for a #tag literal. #inst, -;; #uuid and #"regex" are built in; any other tag is applied from *data-readers*, -;; then *default-data-reader-fn*. An unregistered tag with no default handler stays -;; a tagged FORM (lenient — clojure.edn raises instead). +;; #uuid and #"regex" are built in; any other tag is applied from *data-readers*. +;; An unregistered tag stays a tagged FORM (lenient — clojure.edn raises instead). (define (rdr-construct-tag tag inner) (cond - ((eq? tag (keyword #f "#inst")) - (when (string? inner) (rdr-validate-inst! inner)) - (jolt-inst-from-string inner)) - ((eq? tag (keyword #f "#uuid")) - (when (string? inner) (rdr-validate-uuid! inner)) - (jolt-uuid-from-string inner)) + ((eq? tag (keyword #f "#inst")) (jolt-inst-from-string inner)) + ((eq? tag (keyword #f "#uuid")) (jolt-uuid-from-string inner)) ((eq? tag (keyword #f "regex")) (jolt-re-pattern inner)) - ;; the M-literal form: construct the BigDecimal from its numeric text - ((eq? tag (keyword #f "bigdec")) (jolt-bigdec-from-string inner)) (else (let ((fn (rdr-data-reader-fn tag))) - (if fn (jolt-invoke fn inner) - (let ((dfn (rdr-default-data-reader-fn))) - (if dfn (jolt-invoke dfn (rdr-tag->symbol tag) inner) - ;; no reader for the tag: a proper tagged-literal value, like - ;; Clojure's *default-data-reader-fn* (tagged-literal), so - ;; tagged-literal? / :tag / :form / printing all work — not the - ;; internal reader form. clojure.edn reads raw forms via - ;; __read-form-raw, so its :readers/:default path is unaffected. - (jolt-tagged-literal (rdr-tag->symbol tag) inner)))))))) + (if fn (jolt-invoke fn inner) (rdr-make-tagged tag inner)))))) -;; rdr-form->data*: convert the VALUE structure (set/tagged/nested forms). The -;; wrapper below adds the metadata, so the unchanged branches return x bare. -(define (rdr-form->data* x) +(define (rdr-form->data x) (cond ((and (pmap? x) (eq? (jolt-get x rdr-kw-jolt-type) rdr-kw-jolt-tagged)) (rdr-construct-tag (jolt-get x rdr-kw-tag) (rdr-form->data (jolt-get x rdr-kw-form)))) ((rdr-set-form? x) (let ((items (jolt-get x rdr-kw-value))) - (let loop ((i 0) (s empty-pset)) - (if (fx>=? i (pvec-count items)) s - (let ((v (rdr-form->data (pvec-nth-d items i jolt-nil)))) - (when (jolt-truthy? (jolt-contains? s v)) - (jolt-throw (jolt-host-throwable "java.lang.IllegalArgumentException" - (string-append "Duplicate key: " (jolt-pr-str v))))) - (loop (fx+ i 1) (pset-conj s v))))))) + (rdr-carry-meta x + (let loop ((i 0) (s empty-pset)) + (if (fx>=? i (pvec-count items)) s + (loop (fx+ i 1) (pset-conj s (rdr-form->data (pvec-nth-d items i jolt-nil))))))))) ((pvec? x) (let-values (((items changed) (rdr-conv-each (vector->list (pvec-v x))))) - (if changed (apply jolt-vector items) x))) + (if changed (rdr-carry-meta x (apply jolt-vector items)) x))) ((pmap? x) (let ((order (hashtable-ref rdr-map-order x #f))) (if order (let-values (((kvs changed) (rdr-conv-each order))) - (if changed (rdr-make-map kvs) x)) + (if changed + (let ((m (rdr-make-map kvs))) (rdr-carry-meta x m)) + x)) (let-values (((kvs changed) (rdr-conv-each (pmap-fold x (lambda (k v a) (cons k (cons v a))) '())))) - (if changed (apply jolt-hash-map kvs) x))))) + (if changed (rdr-carry-meta x (apply jolt-hash-map kvs)) x))))) ((cseq? x) (let-values (((items changed) (rdr-conv-each (seq->list x)))) - (if changed (apply jolt-list items) x))) + (if changed (rdr-carry-meta x (apply jolt-list items)) x))) (else x))) -;; Read DATA always carries metadata, converting its nested forms too — Clojure's -;; reader reads a ^{…} map with the same read() as any value, so a set/tagged -;; literal in metadata is a value, not a form. Carry it whether or not the value -;; itself changed (a set-form in the metadata of an otherwise-unchanged value). -(define (rdr-form->data x) - (let ((v (rdr-form->data* x)) (m (jolt-meta x))) - (if (jolt-nil? m) v (jolt-with-meta v (rdr-form->data m))))) ;; --- the two host seams ----------------------------------------------------- -;; a top-level read: a stray close delimiter is unmatched (read-seq consumes the -;; close of an open collection; anything reaching here is unbalanced input). -(define (rdr-read-top s i end) - (let ((k (rdr-skip-ws s i end))) - (when (and (< k end) - (let ((c (string-ref s k))) - (or (char=? c #\)) (char=? c #\]) (char=? c #\})))) - (jolt-throw (jolt-ex-info (string-append "Unmatched delimiter: " - (string (string-ref s k))) - empty-pmap))) - (rdr-read-form s k end))) - ;; clojure.core/read-string: first form, or nil for blank / comment-only input ;; (parse-string wart, matched deliberately). jolt-read-form-raw keeps set FORMS ;; for the compiler spine (compile-eval); the data seam converts them to sets. (define (jolt-read-form-raw s) - (let-values (((form j) (rdr-read-top s 0 (string-length s)))) + (let-values (((form j) (rdr-read-form s 0 (string-length s)))) (if (rdr-eof? form) jolt-nil form))) - -;; the edn seam: strict mode (no auto-resolved keywords), each #_ discard handed -;; to the callback for tag validation, and a distinct EOF sentinel so the edn -;; layer can honor its :eof option (nil input is a plain EOF). -(define (jolt-read-form-edn s cb) - (if (jolt-nil? s) - (keyword "jolt" "reader-eof") - (parameterize ((rdr-edn-mode #t) - (rdr-discard-cb (if (jolt-nil? cb) #f cb))) - (let-values (((form j) (rdr-read-top s 0 (string-length s)))) - (if (rdr-eof? form) (keyword "jolt" "reader-eof") form))))) (define (jolt-read-string s) (let ((form (jolt-read-form-raw s))) (if (jolt-nil? form) form (rdr-form->data form)))) @@ -969,7 +640,7 @@ ;; __parse-next: [form rest-of-string] or nil when only whitespace/comments left. (define (jolt-parse-next s) (let ((end (string-length s))) - (let-values (((form j) (rdr-read-top s 0 end))) + (let-values (((form j) (rdr-read-form s 0 end))) (if (rdr-eof? form) jolt-nil (jolt-vector (rdr-form->data form) (substring s j end)))))) @@ -978,30 +649,16 @@ ;; is the :#name keyword the reader produced; #uuid/#inst reuse the inst-time ctors. (define (jolt-read-tagged tag form) (cond - ((eq? tag (keyword #f "#uuid")) - (when (string? form) (rdr-validate-uuid! form)) - (jolt-uuid-from-string form)) - ((eq? tag (keyword #f "#inst")) - (when (string? form) (rdr-validate-inst! form)) - (jolt-inst-from-string form)) - ((eq? tag (keyword #f "bigdec")) (jolt-bigdec-from-string form)) - ;; No registered reader: consult *default-data-reader-fn*, else throw a clean, - ;; catchable ex-info naming the tag, like the JVM's "No reader function for tag - ;; foobar" (empty-pmap is a VALUE — the old (empty-pmap) applied it as a - ;; procedure and crashed the Chez VM). - (else (let ((dfn (rdr-default-data-reader-fn))) - (if dfn (jolt-invoke dfn (rdr-tag->symbol tag) form) - (let* ((nm (keyword-t-name tag)) - (bare (if (and (> (string-length nm) 0) (char=? (string-ref nm 0) #\#)) - (substring nm 1 (string-length nm)) nm))) - (jolt-throw (jolt-ex-info (string-append "No reader function for tag " bare) empty-pmap)))))))) + ((eq? tag (keyword #f "#uuid")) (jolt-uuid-from-string form)) + ((eq? tag (keyword #f "#inst")) (jolt-inst-from-string form)) + ;; No registered reader: throw a clean, catchable ex-info naming the tag, like + ;; the JVM's "No reader function for tag foobar" (empty-pmap is a VALUE — the + ;; old (empty-pmap) applied it as a procedure and crashed the Chez VM). + (else (let* ((nm (keyword-t-name tag)) + (bare (if (and (> (string-length nm) 0) (char=? (string-ref nm 0) #\#)) + (substring nm 1 (string-length nm)) nm))) + (jolt-throw (jolt-ex-info (string-append "No reader function for tag " bare) empty-pmap)))))) (def-var! "clojure.core" "read-string" jolt-read-string) (def-var! "clojure.core" "__parse-next" jolt-parse-next) (def-var! "clojure.core" "__read-tagged" jolt-read-tagged) -;; __read-form-raw: the read form WITHOUT building values — set/tagged literals -;; stay FORMS. clojure.edn reads this so it applies a #tag through its :readers/ -;; :default (a #inst can be overridden to defer), rather than read-string building -;; the built-in #inst eagerly (which fails on a non-string like #inst ^:ref […]). -(def-var! "clojure.core" "__read-form-raw" jolt-read-form-raw) -(def-var! "clojure.core" "__read-form-edn" jolt-read-form-edn) diff --git a/host/chez/java/records-interop.ss b/host/chez/records-interop.ss similarity index 51% rename from host/chez/java/records-interop.ss rename to host/chez/records-interop.ss index 826db96..e1b98fe 100644 --- a/host/chez/java/records-interop.ss +++ b/host/chez/records-interop.ss @@ -10,42 +10,44 @@ (define (ex-info-class v) (let ((c (jolt-get v jolt-kw-class jolt-nil))) (if (string? c) c "clojure.lang.ExceptionInfo"))) -;; Is `wanted` (simple name) `cls` or a supertype of it? The exception hierarchy -;; lives in the one class graph (class-hierarchy.ss) — resolve the simple name to -;; its graph key and ask jch-isa?, so exceptions and every other class share a -;; single source of truth (ExceptionInfo -> IExceptionInfo is a graph edge). +;; immediate-parent chain of the JVM exception hierarchy (simple names). Drives +;; instance? across exception supertypes — (instance? Throwable (ex-info …)) etc. +(define exception-parent + '(("ExceptionInfo" . "RuntimeException") + ("RuntimeException" . "Exception") + ("IllegalArgumentException" . "RuntimeException") + ("NumberFormatException" . "IllegalArgumentException") + ("IllegalStateException" . "RuntimeException") + ("UnsupportedOperationException" . "RuntimeException") + ("ArithmeticException" . "RuntimeException") + ("NullPointerException" . "RuntimeException") + ("ClassCastException" . "RuntimeException") + ("IndexOutOfBoundsException" . "RuntimeException") + ("ConcurrentModificationException" . "RuntimeException") + ("NoSuchElementException" . "RuntimeException") + ("UncheckedIOException" . "RuntimeException") + ("InterruptedException" . "Exception") + ("IOException" . "Exception") + ("FileNotFoundException" . "IOException") + ("UnsupportedEncodingException" . "IOException") + ("UnknownHostException" . "IOException") + ("SocketException" . "IOException") + ("ConnectException" . "IOException") + ("SocketTimeoutException" . "IOException") + ("MalformedURLException" . "IOException") + ("SSLException" . "IOException") + ("Exception" . "Throwable") + ("Error" . "Throwable") + ("AssertionError" . "Error") + ("Throwable" . "Object"))) +;; Is `wanted` (simple name) `cls` or a supertype of it? ExceptionInfo also +;; implements the IExceptionInfo interface. (define (exception-isa? cls wanted) - (jch-isa? (jch-fqn-of-simple cls) wanted)) - -;; A raw Chez condition (an arity or non-seqable error Chez itself raised, not a -;; jolt ex-info) carries no jolt exception class. Map the ones Clojure raises a -;; specific class for, by message, so (class e) and (instance? C e) match the JVM. -;; Returns a simple class name or #f. -(define (ri-substring? needle hay) - (let ((nl (string-length needle)) (hl (string-length hay))) - (let loop ((i 0)) - (cond ((> (+ i nl) hl) #f) - ((string=? needle (substring hay i (+ i nl))) #t) - (else (loop (+ i 1))))))) -(define (chez-condition-exc-class v) - (and (condition? v) (message-condition? v) - (let ((m (condition-message v))) - (and (string? m) - (cond ((ri-substring? "incorrect number of arguments" m) "ArityException") - ((ri-substring? "not seqable" m) "IllegalArgumentException") - ;; Chez's numeric ops raise "~s is not a real number" on a bad - ;; operand. The JVM throws NullPointerException for a nil operand - ;; (null deref) and ClassCastException for a non-number (can't - ;; cast to Number) — clojure.spec.alpha's conform-explain relies - ;; on the distinction. The offending value rides in the irritants. - ((or (ri-substring? "is not a real number" m) - (ri-substring? "is not a number" m)) - (if (and (irritants-condition? v) - (let loop ((xs (condition-irritants v))) - (and (pair? xs) (or (jolt-nil? (car xs)) (loop (cdr xs)))))) - "NullPointerException" - "ClassCastException")) - (else #f)))))) + (let loop ((c cls)) + (cond ((not c) #f) + ((string=? c wanted) #t) + ((and (string=? c "ExceptionInfo") (string=? wanted "IExceptionInfo")) #t) + (else (let ((p (assoc c exception-parent))) (loop (and p (cdr p)))))))) ;; instance-check: (type-sym val) — type/protocol membership. Host shims loaded ;; later (io, inst-time, natives-array, natives-queue, host-static-classes) @@ -57,35 +59,14 @@ (define (register-instance-check-arm! f) ; f: (type-sym val) -> #t | #f | 'pass (set! instance-check-registry (cons f instance-check-registry))) -;; (instance? C raw-condition): match when C is the condition's mapped class or a -;; supertype of it (ArityException is also an IllegalArgumentException, etc.). -(register-instance-check-arm! - (lambda (type-sym val) - (let ((k (chez-condition-exc-class val))) - (if k (if (exception-isa? k (last-dot (symbol-t-name type-sym))) #t #f) 'pass)))) - -;; Object / java.lang.Object is the root of the type hierarchy: every non-nil -;; value is an instance of Object; nil is not an instance of anything. -(register-instance-check-arm! - (lambda (type-sym val) - (let ((tn (symbol-t-name type-sym))) - (if (or (string=? tn "Object") (string=? tn "java.lang.Object")) - (not (jolt-nil? val)) - 'pass)))) - (define (instance-check-base type-sym val) (let ((tname (symbol-t-name type-sym))) (cond ((jrec? val) (let ((tag (jrec-tag val))) (or (string=? tag tname) - ;; a simple name matches a qualified tag only at a `.` boundary: - ;; "a.b.IntervalFD" is an IntervalFD, but "a.b.MultiIntervalFD" is NOT - ;; (a raw string-suffix would wrongly match the latter). - (let ((tl (string-length tag)) (nl (string-length tname))) - (and (fx>? tl nl) - (char=? (string-ref tag (fx- (fx- tl nl) 1)) #\.) - (string=? (substring tag (fx- tl nl) tl) tname))) + (and (> (string-length tag) (string-length tname)) + (string=? (substring tag (- (string-length tag) (string-length tname)) (string-length tag)) tname)) ;; a protocol/interface the type implements (defprotocol generates an ;; interface; (instance? SomeProtocol record) is true when the record ;; implements it — core.match dispatches on instance? IPatternCompile). @@ -138,26 +119,3 @@ ;; records.ss, so this set! sees the registry — forward refs resolve at call time. (def-var! "clojure.core" "instance-check" instance-check) - -;; Broad-catch fallback for catch-clause dispatch (analyze-try desugars -;; (catch C e …) to (or (instance? C e) (__catch-broad? "C" e))). A jolt host -;; condition or a raw raised value carries no jolt exception class, so instance? -;; can't place it; a Clojure (catch C e) over such a value matches when C is -;; RuntimeException (or a subclass) / Exception / Throwable — most host runtime -;; errors are RuntimeExceptions. Typed throwables (ex-info, (SomeException. …)) are -;; recognized by instance? as Throwable, so untyped? is false and they dispatch -;; precisely through the instance? arm instead. -(define throwable-type-sym (jolt-symbol #f "Throwable")) -(define (simple-class-name nm) - (let loop ((i (- (string-length nm) 1))) - (cond ((< i 0) nm) - ((char=? (string-ref nm i) #\.) (substring nm (+ i 1) (string-length nm))) - (else (loop (- i 1)))))) -(define (jolt-catch-broad? nm v) - (and (not (instance-check throwable-type-sym v)) - (let ((s (simple-class-name nm))) - (or (exception-isa? s "RuntimeException") - (string=? s "Exception") - (string=? s "Throwable"))))) -(def-var! "clojure.core" "__catch-broad?" - (lambda (nm v) (if (jolt-catch-broad? nm v) #t #f))) diff --git a/host/chez/records.ss b/host/chez/records.ss index 806e9f8..7bfe4ae 100644 --- a/host/chez/records.ss +++ b/host/chez/records.ss @@ -1,13 +1,9 @@ ;; records + protocols — the deftype/defrecord + defprotocol/extend-type ;; subsystem. ;; -;; A record is a `jrec`: a shared per-type descriptor + a flat vector of field -;; values in declared order, plus an extension map for any non-field keys assoc'd -;; on (jolt-nil when there are none — the common case). This lays fields out like a -;; native struct: construction allocates one vector, not a chain of cons cells, and -;; a field read is an index lookup, not a list scan. It is map?/coll?, equal to -;; another jrec of the same type with equal fields (never equal to a plain map), -;; and prints as #ns.Name{...}. +;; A record is a `jrec`: a type tag ("ns.Name") + an alist of (kw . val) in +;; declared field order. It is map?/coll?, equal to another jrec of the same tag +;; with equal fields (never equal to a plain map), and prints as #ns.Name{...}. ;; The collection dispatchers (jolt-get/count/keys/vals/seq/assoc/contains?/=/ ;; hash/conj + the printers) are set!-extended with a jrec arm that delegates to ;; the original — the transients.ss pattern — so all record logic lives here and @@ -17,261 +13,53 @@ ;; Loaded after collections/seq/values/converters/printing/transients/multimethods ;; (the dispatchers it wraps + chez-current-ns). -;; The per-type descriptor: built once at deftype/defrecord definition and shared -;; by every instance. Holds the tag, the field keywords in declared order, and an -;; eq?-keyed keyword->index table (field keys are interned, so identity lookup). -(define-record-type (jrdesc make-jrdesc-rec jrdesc?) - (fields tag fkeys index) (nongenerative chez-jrdesc-v1)) -(define (make-jrdesc tag fkey-list) - (let ((index (make-eq-hashtable))) - (let loop ((ks fkey-list) (i 0)) - (unless (null? ks) (hashtable-set! index (car ks) i) (loop (cdr ks) (+ i 1)))) - (make-jrdesc-rec tag (list->vector fkey-list) index))) -;; An instance: the shared descriptor, the field-value vector, and an extension -;; map (jolt-nil unless non-field keys have been assoc'd on). -(define-record-type (jrec make-jrec jrec?) (fields desc vals ext) (nongenerative chez-jrec-v2)) -(define (jrec-tag r) (jrdesc-tag (jrec-desc r))) - -;; defrecord vs deftype: a defrecord IS a map (map?/seq/keys/assoc over its -;; fields); a bare deftype is an opaque object with only its declared interfaces, -;; never a map (Clojure semantics). defrecord registers its type tag here; the -;; default jrec-as-map behaviour (map?/record?/field-seq) is gated on it, while -;; method dispatch (a deftype implementing ISeq/Counted/…) stays open to any jrec. -(define chez-record-type-tbl (make-hashtable string-hash string=?)) -(define (jrec-record? x) (and (jrec? x) (hashtable-ref chez-record-type-tbl (jrec-tag x) #f) #t)) -;; every deftype/defrecord tag, and a simple-name -> tag index. An extend-protocol -;; in a DIFFERENT ns names the type bare (it is :import-ed), so register-method -;; resolves "Raw" to its real tag "a.util.Raw" here instead of prepending the -;; calling ns. The local ns is preferred, so a same-named local type still wins. -(define chez-deftype-tag-set (make-hashtable string-hash string=?)) -;; ctor procedure -> its class tag: the type NAME var holds the ctor (a jolt-ism; -;; the JVM resolves it to the class), so class-key maps the ctor back to the -;; class for (ancestors TypeName) / (isa? x TypeName) / derive on the type. -(define chez-deftype-ctor-tag (make-weak-eq-hashtable)) -(define chez-simple-name-tag (make-hashtable string-hash string=?)) -;; a jrec that is coll? — a record, or a deftype implementing a collection -;; interface (its seq/count/nth/valAt/cons method is registered). find-method-any- -;; protocol is defined later; resolved at call time. An opaque deftype is not coll?. -(define (jrec-collection? x) - (and (jrec? x) - (or (jrec-record? x) - (let ((tag (jrec-tag x))) - ;; coll? is instance? IPersistentCollection — its marker is `cons` - ;; (and ISeq's `first`). ILookup(valAt) / Indexed(nth) / Counted(count) - ;; / Seqable(seq) alone do NOT make a value coll?, matching the JVM - ;; (e.g. core.logic's LVar implements only valAt and is not coll?). - (or (find-method-any-protocol tag "cons") - (find-method-any-protocol tag "first")))) - #t)) -;; a jrec that is map? — a record, or a deftype implementing clojure.lang -;; .IPersistentMap (clojure.core.cache's caches do). `without` (dissoc) is the -;; map-distinctive method: vectors/sets implement Associative/ILookup but not it. -(define (jrec-maplike? x) - (and (jrec? x) - (or (jrec-record? x) - (find-method-any-protocol (jrec-tag x) "without")) - #t)) +(define-record-type jrec (fields tag pairs) (nongenerative chez-jrec-v1)) (define jolt-deftype-kw (keyword "jolt" "deftype")) -;; unique present-vs-absent sentinel for extension-map lookups (so a present nil -;; in the extension map is distinguished from a genuine miss). -(define jrec-absent (list 'jrec-absent)) -;; --- whole-program inference registries ------------------------------------- -;; Populated at definition/load time (deftype/defrecord and defprotocol forms run -;; before `jolt build` re-emits), read by the inference driver to seed record and -;; protocol-method types across fn boundaries. A no-op for the runtime itself; the -;; tables just accumulate. jolt.host/record-shapes and /protocol-methods (host- -;; contract.ss) materialize them into the shape jolt.passes.types expects. - -;; ctor-key "ns/->Name" -> (vector field-kw-list field-tag-list type-tag). -;; field-tag-list parallels the fields: "num", a record simple-name string, or #f. -(define chez-record-shapes-tbl (make-hashtable string-hash string=?)) -;; method var-key "ns/method" -> (cons proto-name method-name). -(define chez-protocol-methods-tbl (make-hashtable string-hash string=?)) -;; type-tag "ns.Name" -> #(bool ...) marking which fields are ^double, so the ctor -;; and set! coerce them to flonums (JVM primitive-field semantics, and what makes -;; reading the field back as :double sound for fl-ops). -(define chez-record-dbl-tbl (make-hashtable string-hash string=?)) -(define (chez-double-tag? t) (and (string? t) (string=? t "double"))) - -(define (register-record-shape! ctor-key field-kws field-tags type-tag) - (hashtable-set! chez-record-shapes-tbl ctor-key - (vector field-kws field-tags type-tag)) - (hashtable-set! chez-record-dbl-tbl type-tag - (list->vector (map chez-double-tag? field-tags)))) - -;; simple name of a dotted/slashed string: the segment after the last . or /. -(define (chez-shape-simple-name s) - (let loop ((i (- (string-length s) 1))) - (cond ((< i 0) s) - ((or (char=? (string-ref s i) #\.) (char=? (string-ref s i) #\/)) - (substring s (+ i 1) (string-length s))) - (else (loop (- i 1)))))) - -;; resolve a field's declared type tag to what jolt.passes.types wants: "num" -;; passes through; a record name (simple "Vec3" or qualified "ns.Vec3") resolves -;; to its ctor-key (so the field reads back as that record); anything else -> nil. -(define (chez-resolve-field-tag tag by-name) - (cond ((or (not tag) (jolt-nil-t? tag)) jolt-nil) - ((string=? tag "num") "num") - ((string=? tag "double") "double") ; a ^double field reads back as a flonum - (else (let ((ck (hashtable-ref by-name (chez-shape-simple-name tag) #f))) - (if ck ck jolt-nil))))) - -;; materialize chez-record-shapes-tbl into "ns/->Name" -> {:fields :tags :type}, -;; the shape record-type-from-entry consumes. -(define (chez-record-shapes-map) - (let ((by-name (make-hashtable string-hash string=?)) - (kw-fields (keyword #f "fields")) (kw-tags (keyword #f "tags")) (kw-type (keyword #f "type")) - (out (jolt-hash-map))) - ;; index simple record name (from the type tag "ns.Name") -> ctor-key for - ;; nested-field-tag resolution. - (let-values (((ks vs) (hashtable-entries chez-record-shapes-tbl))) - (vector-for-each - (lambda (k v) (hashtable-set! by-name (chez-shape-simple-name (vector-ref v 2)) k)) ks vs) - (vector-for-each - (lambda (k v) - (let* ((fields (vector-ref v 0)) (tags (vector-ref v 1)) (type-tag (vector-ref v 2)) - (rtags (map (lambda (t) (chez-resolve-field-tag t by-name)) tags))) - (set! out (jolt-assoc out k - (jolt-hash-map kw-fields (apply jolt-vector fields) - kw-tags (apply jolt-vector rtags) - kw-type type-tag))))) - ks vs)) - out)) - -;; resolve a record TYPE name (a ^Type param hint's tag) to the ctor-key -;; "ns/->Name" the inference seeds with. Prefer the ctor in `ns` (the compile ns); -;; else any registered record with that simple name (cross-ns / imported). #f if -;; the name isn't a record type (so a ^double/^String hint resolves to nil). -(define (chez-find-ctor-key name ns) - (let* ((simple (chez-shape-simple-name name)) - (target (string-append "->" simple)) - (preferred (string-append ns "/->" simple))) - (if (hashtable-ref chez-record-shapes-tbl preferred #f) - preferred - (let loop ((ks (vector->list (hashtable-keys chez-record-shapes-tbl)))) - (cond ((null? ks) #f) - ((string=? (chez-shape-simple-name (car ks)) target) (car ks)) - (else (loop (cdr ks)))))))) - -;; materialize chez-protocol-methods-tbl into "ns/method" -> [proto method]. -(define (chez-protocol-methods-map) - (let ((out (jolt-hash-map))) - (let-values (((ks vs) (hashtable-entries chez-protocol-methods-tbl))) - (vector-for-each - (lambda (k v) (set! out (jolt-assoc out k (jolt-vector (car v) (cdr v))))) - ks vs)) - out)) - -;; index of a declared field key, or #f (only an interned keyword can be one). -(define (jrec-field-index r k) (hashtable-ref (jrdesc-index (jrec-desc r)) k #f)) -;; a vector-copy that doesn't depend on the optional rnrs vector-copy being present. -(define (jrec-vec-copy v) - (let* ((n (vector-length v)) (out (make-vector n))) - (let loop ((i 0)) (when (< i n) (vector-set! out i (vector-ref v i)) (loop (+ i 1)))) - out)) -;; extension-map entries as an (k . v) alist in iteration order. -(define (jrec-ext-pairs ext) - (let loop ((s (jolt-seq ext)) (acc '())) - (if (jolt-nil? s) (reverse acc) - (let ((e (seq-first s))) - (loop (jolt-seq (seq-more s)) (cons (cons (jolt-nth e 0) (jolt-nth e 1)) acc)))))) - -;; lookup with default d: a declared field reads index+vector-ref (a present nil -;; returns nil), then the extension map, then d. (define (jrec-lookup r k d) - (if (eq? k jolt-deftype-kw) + (if (jolt=2 k jolt-deftype-kw) (jrec-tag r) - (let ((i (jrec-field-index r k))) - (if i (vector-ref (jrec-vals r) i) - (let ((ext (jrec-ext r))) - (if (jolt-nil? ext) d - (let ((v (jolt-get ext k jrec-absent))) - (if (eq? v jrec-absent) d v)))))))) + (let loop ((ps (jrec-pairs r))) + (cond ((null? ps) d) + ((jolt=2 (caar ps) k) (cdar ps)) + (else (loop (cdr ps))))))) (define (jrec-has? r k) - (and (not (eq? k jolt-deftype-kw)) - (or (and (jrec-field-index r k) #t) - (let ((ext (jrec-ext r))) - (and (not (jolt-nil? ext)) - (not (eq? jrec-absent (jolt-get ext k jrec-absent)))))))) -;; The get path: like jrec-lookup, but a deftype's ILookup valAt runs when a key -;; is genuinely missing from both the fields and the extension map. -(define (jrec-ref coll k d) - (if (eq? k jolt-deftype-kw) - (jrec-tag coll) - (let ((i (jrec-field-index coll k))) - (if i (vector-ref (jrec-vals coll) i) - (let* ((ext (jrec-ext coll)) - (v (if (jolt-nil? ext) jrec-absent (jolt-get ext k jrec-absent)))) - (if (eq? v jrec-absent) - (cond ((find-method-any-protocol (jrec-tag coll) "valAt") - => (lambda (m) (jolt-invoke m coll k d))) - (else d)) - v)))))) -;; bare-index field read for a statically-known record field — emitted by `jolt -;; build --opt` for a struct-typed receiver, where i is the field's declared slot. -;; When r is the expected record it reads the value vector directly: no field-key -;; hashtable lookup, no jolt-get dispatch. Falls back to jolt-get otherwise (a map -;; downgraded by dissoc, or a value the inference mistyped), so it stays correct -;; even if the static type is wrong. -(define (jrec-field-at r i k) - (if (and (jrec? r) (fx< i (vector-length (jrec-vals r)))) - (vector-ref (jrec-vals r) i) - (jolt-get r k))) - -;; mutate a deftype's mutable field in place: the value vector is mutable, so -;; vector-set! updates the field. (set! field v) inside a method lowers to this; -;; returns v, as set! does. + (let loop ((ps (jrec-pairs r))) + (cond ((null? ps) #f) ((jolt=2 (caar ps) k) #t) (else (loop (cdr ps)))))) +;; mutate a deftype's mutable field in place: the pairs are runtime cons cells, +;; so set-cdr! updates the field. (set! field v) inside a method +;; lowers to this; returns v, as set! does. (define (jolt-set-field! inst k v) (if (jrec? inst) - (let ((i (jrec-field-index inst k))) - (if i (let* ((flags (hashtable-ref chez-record-dbl-tbl (jrec-tag inst) #f)) - ;; a ^double field stays a flonum across set!, like the ctor — - ;; keeps a later field read sound to unbox. - (v2 (if (and flags (fx< i (vector-length flags)) (vector-ref flags i) - (number? v) (not (flonum? v))) - (exact->inexact v) v))) - (vector-set! (jrec-vals inst) i v2) v2) - (error #f "set! of an unknown field" k))) + (let loop ((ps (jrec-pairs inst))) + (cond ((null? ps) (error #f "set! of an unknown field" k)) + ((jolt=2 (caar ps) k) (set-cdr! (car ps) v) v) + (else (loop (cdr ps))))) (error #f "set! of a field on a non-record" inst))) -(define (jrec-ext=? ea eb) - (cond ((and (jolt-nil? ea) (jolt-nil? eb)) #t) - ((or (jolt-nil? ea) (jolt-nil? eb)) #f) - (else (jolt=2 ea eb)))) +(define (jrec-replace pairs k v) ; replace existing field (keep order) or append + (let loop ((ps pairs) (acc '()) (hit #f)) + (cond ((null? ps) (reverse (if hit acc (cons (cons k v) acc)))) + ((jolt=2 (caar ps) k) (loop (cdr ps) (cons (cons k v) acc) #t)) + (else (loop (cdr ps) (cons (car ps) acc) hit))))) (define (jrec=? a b) (and (string=? (jrec-tag a) (jrec-tag b)) - (= (vector-length (jrec-vals a)) (vector-length (jrec-vals b))) - (let ((va (jrec-vals a)) (vb (jrec-vals b)) (n (vector-length (jrec-vals a)))) - (let loop ((i 0)) - (or (= i n) - (and (jolt=2 (vector-ref va i) (vector-ref vb i)) (loop (+ i 1)))))) - (jrec-ext=? (jrec-ext a) (jrec-ext b)))) + (= (length (jrec-pairs a)) (length (jrec-pairs b))) + (let loop ((ps (jrec-pairs a))) + (or (null? ps) + (and (jrec-has? b (caar ps)) + (jolt=2 (cdar ps) (jrec-lookup b (caar ps) jolt-nil)) + (loop (cdr ps))))))) (define (jrec-hash r) - (let* ((fkeys (jrdesc-fkeys (jrec-desc r))) (vals (jrec-vals r)) (n (vector-length vals)) - (base (let loop ((i 0) (acc (string-hash (jrec-tag r)))) - (if (= i n) acc - (loop (+ i 1) (+ acc (jolt-hash (vector-ref fkeys i)) - (jolt-hash (vector-ref vals i)))))))) - (let ((ext (jrec-ext r))) - (if (jolt-nil? ext) base (+ base (jolt-hash ext)))))) + (fold-left (lambda (acc p) (+ acc (jolt-hash (car p)) (jolt-hash (cdr p)))) + (string-hash (jrec-tag r)) (jrec-pairs r))) (define (jrec-pr r) ; #ns.Name{:k v, :k v} - (let ((fkeys (jrdesc-fkeys (jrec-desc r))) (vals (jrec-vals r))) - (string-append "#" (jrec-tag r) "{" - (let ((n (vector-length vals))) - (let loop ((i 0) (first #t) (acc "")) - (if (= i n) - (let ((ext (jrec-ext r))) - (if (jolt-nil? ext) acc - (let eloop ((es (jrec-ext-pairs ext)) (first first) (acc acc)) - (if (null? es) acc - (eloop (cdr es) #f - (string-append acc (if first "" ", ") - (jolt-pr-readable (caar es)) " " (jolt-pr-readable (cdar es)))))))) - (loop (+ i 1) #f - (string-append acc (if first "" ", ") - (jolt-pr-readable (vector-ref fkeys i)) " " (jolt-pr-readable (vector-ref vals i))))))) - "}"))) + (string-append "#" (jrec-tag r) "{" + (let loop ((ps (jrec-pairs r)) (first #t) (acc "")) + (if (null? ps) acc + (loop (cdr ps) #f + (string-append acc (if first "" ", ") + (jolt-pr-readable (caar ps)) " " (jolt-pr-readable (cdar ps)))))) + "}")) ;; ---- extend the collection dispatchers with a jrec arm ---------------------- ;; equality for a jrec: a deftype implementing IPersistentCollection/equiv (e.g. @@ -282,56 +70,28 @@ (lambda (a b) (cond ((and (jrec? a) (jrec-cl a "equiv")) => (lambda (m) (if (jolt-truthy? (jolt-invoke m a b)) #t #f))) ((and (jrec? b) (jrec-cl b "equiv")) => (lambda (m) (if (jolt-truthy? (jolt-invoke m b a)) #t #f))) - ;; a deftype with a custom Object.equals (but no equiv) governs - ;; its own value equality and map-key identity — core.logic's - ;; LVar/LCons key substitutions on id, ignoring metadata, so - ;; structural jrec=? (which sees the meta field) is wrong here. - ((and (jrec? a) (jrec-cl a "equals")) => (lambda (m) (if (jolt-truthy? (jolt-invoke m a b)) #t #f))) - ((and (jrec? b) (jrec-cl b "equals")) => (lambda (m) (if (jolt-truthy? (jolt-invoke m b a)) #t #f))) ((and (jrec? a) (jrec? b)) (jrec=? a b)) (else #f)))) -;; a deftype's declared hashCode governs its map/set hashing (paired with the -;; equals/equiv above so the hash/eq contract holds); a plain record hashes its -;; fields structurally via jrec-hash. -(register-hash-arm! jrec? - (lambda (x) (let ((m (jrec-cl x "hashCode"))) - (if m (jolt-invoke m x) (jrec-hash x))))) +(register-hash-arm! jrec? jrec-hash) ;; get on a jrec: a real field reads raw (so a deftype method's own field bindings, ;; compiled to (get inst :field), never recurse); a NON-field key on a deftype that ;; implements clojure.lang.ILookup routes to its valAt (core.match's pattern types ;; compute ::tag in valAt), else the default. -;; jrec is the hottest get target (every record field read); jolt-get-dispatch -;; (collections.ss) checks jrec? directly and calls jrec-ref, skipping the get-arm -;; walk. This registration is the equivalent fallback for any other caller. -(register-get-arm! jrec? jrec-ref) +(register-get-arm! jrec? + (lambda (coll k d) + (cond ((jrec-has? coll k) (jrec-lookup coll k d)) + ((find-method-any-protocol (jrec-tag coll) "valAt") + => (lambda (m) (jolt-invoke m coll k d))) + (else d)))) ;; A jrec is a defrecord (map of fields) by default, BUT a deftype that ;; implements a clojure.lang collection interface carries the op as an inline ;; method — prefer that method, else fall back to the field/map behavior. (jrec-cl ;; finds the method; find-method-any-protocol / jolt-invoke resolve at call time.) -;; Same lookup as collections.ss rec-coll-method — one definition, aliased here. -(define jrec-cl rec-coll-method) - -;; iface-method: the single deftype/reify interface-method lookup. Returns the -;; impl fn for METHOD declared by V (a deftype/record OR a reify), or #f. NARGS -;; (including `this`) selects the matching arity for a deftype; #f means any -;; arity. Core fns route interface dispatch through this instead of each -;; re-deriving jrec-vs-reify lookup and arity handling. -(define (iface-method v method nargs) - (cond ((jrec? v) - (if nargs (find-method-any-protocol-arity (jrec-tag v) method nargs) - (find-method-any-protocol (jrec-tag v) method))) - ((jreify? v) (let ((rm (reified-methods v))) (and rm (hashtable-ref rm method #f)))) - (else #f))) -;; Call METHOD on V with ARGS (a list, `this` excluded) if V declares it, else run -;; FALLBACK. The one seam a core fn's deftype/reify arm collapses to. -(define (iface-call v method args fallback) - (let ((m (iface-method v method (+ 1 (length args))))) - (if m (apply jolt-invoke m v args) (fallback)))) +(define (jrec-cl coll name) (and (jrec? coll) (find-method-any-protocol (jrec-tag coll) name))) (define %r-jolt-count jolt-count) (set! jolt-count (lambda (coll) (cond ((jrec-cl coll "count") => (lambda (m) (jolt-invoke m coll))) - ((jrec? coll) (+ (vector-length (jrec-vals coll)) - (let ((ext (jrec-ext coll))) (if (jolt-nil? ext) 0 (%r-jolt-count ext))))) + ((jrec? coll) (length (jrec-pairs coll))) (else (%r-jolt-count coll))))) ;; contains?: a deftype implementing Associative/containsKey (e.g. core.cache's ;; caches) answers through that; a plain defrecord checks its fields. @@ -340,48 +100,21 @@ (cond ((jrec-cl coll "containsKey") => (lambda (m) (if (jolt-truthy? (jolt-invoke m coll k)) #t #f))) ((jrec? coll) (jrec-has? coll k)) (else (%r-jolt-contains? coll k))))) -;; assoc: replacing a declared field copies the value vector; any other key grows -;; the extension map (the value vector is shared — fields are immutable). (define %r-jolt-assoc1 jolt-assoc1) (set! jolt-assoc1 (lambda (coll k v) (cond ((jrec-cl coll "assoc") => (lambda (m) (jolt-invoke m coll k v))) - ((jrec? coll) - (let ((i (and (keyword? k) (jrec-field-index coll k)))) - (if i - (let ((nv (jrec-vec-copy (jrec-vals coll)))) - (vector-set! nv i v) - (make-jrec (jrec-desc coll) nv (jrec-ext coll))) - (let ((ext (jrec-ext coll))) - (make-jrec (jrec-desc coll) (jrec-vals coll) - (%r-jolt-assoc1 (if (jolt-nil? ext) empty-pmap ext) k v)))))) + ((jrec? coll) (make-jrec (jrec-tag coll) (jrec-replace (jrec-pairs coll) k v))) (else (%r-jolt-assoc1 coll k v))))) -;; dissoc: a deftype implementing IPersistentMap/without answers through it. -;; Removing a declared field downgrades a plain record to a map (JVM parity); an -;; extension key drops from the ext map (normalized back to jolt-nil when empty). -(define (jrec->map-without r drop-k) - (let* ((fkeys (jrdesc-fkeys (jrec-desc r))) (vals (jrec-vals r)) (n (vector-length vals))) - (let loop ((i 0) (m empty-pmap)) - (if (= i n) - (let ((ext (jrec-ext r))) - (if (jolt-nil? ext) m - (fold-left (lambda (mm p) (%r-jolt-assoc1 mm (car p) (cdr p))) m (jrec-ext-pairs ext)))) - (let ((fk (vector-ref fkeys i))) - (loop (+ i 1) (if (eq? fk drop-k) m (%r-jolt-assoc1 m fk (vector-ref vals i))))))))) +;; dissoc: a deftype implementing IPersistentMap/without answers through it; a +;; plain defrecord drops the field pair. (define %r-jolt-dissoc jolt-dissoc) -(define (jrec-dissoc1 coll k) - (if (not (jrec? coll)) - (%r-jolt-dissoc coll k) ; an earlier declared-field dissoc downgraded it - (let ((i (and (keyword? k) (jrec-field-index coll k)))) - (if i (jrec->map-without coll k) - (let ((ext (jrec-ext coll))) - (if (jolt-nil? ext) coll - (let ((ne (%r-jolt-dissoc ext k))) - (make-jrec (jrec-desc coll) (jrec-vals coll) - (if (= 0 (%r-jolt-count ne)) jolt-nil ne))))))))) (set! jolt-dissoc (lambda (coll . ks) (cond ((jrec-cl coll "without") => (lambda (m) (fold-left (lambda (c k) (jolt-invoke m c k)) coll ks))) - ((jrec? coll) (fold-left jrec-dissoc1 coll ks)) + ((jrec? coll) + (fold-left (lambda (c k) (make-jrec (jrec-tag c) + (filter (lambda (p) (not (jolt=2 (car p) k))) (jrec-pairs c)))) + coll ks)) (else (apply %r-jolt-dissoc coll ks))))) ;; keys/vals over a jrec read its entry seq (jolt-seq is method-first, so a ;; map-like deftype delegates to its Seqable; a defrecord's seq is its fields, so @@ -394,22 +127,10 @@ (set! jolt-keys (lambda (m) (if (jrec? m) (jrec-seq-col m 0) (%r-jolt-keys m)))) (define %r-jolt-vals jolt-vals) (set! jolt-vals (lambda (m) (if (jrec? m) (jrec-seq-col m 1) (%r-jolt-vals m)))) -;; a record's seq is its field map-entries in declared order, then any extensions. -(define (jrec-entry-list r) - (let* ((fkeys (jrdesc-fkeys (jrec-desc r))) (vals (jrec-vals r)) (n (vector-length vals))) - (let loop ((i 0) (acc '())) - (if (= i n) - (let ((ext (jrec-ext r))) - (append (reverse acc) - (if (jolt-nil? ext) '() - (map (lambda (p) (make-map-entry (car p) (cdr p))) (jrec-ext-pairs ext))))) - (loop (+ i 1) (cons (make-map-entry (vector-ref fkeys i) (vector-ref vals i)) acc)))))) (define %r-jolt-seq jolt-seq) (set! jolt-seq (lambda (x) (cond ((jrec-cl x "seq") => (lambda (m) (jolt-seq (jolt-invoke m x)))) - ;; a record seqs its fields; a bare deftype is not seqable (falls through - ;; to %r-jolt-seq, which errors like the JVM). - ((jrec-record? x) (list->cseq (jrec-entry-list x))) + ((jrec? x) (list->cseq (map (lambda (p) (make-map-entry (car p) (cdr p))) (jrec-pairs x)))) (else (%r-jolt-seq x))))) (define %r-jolt-conj1 jolt-conj1) (set! jolt-conj1 (lambda (coll x) @@ -421,8 +142,7 @@ ;; empty? over a jrec: a map-like deftype is empty iff its entry seq is (data ;; .priority-map's peek calls (.isEmpty this) -> empty?). jolt-seq is method-first. (define %r-jolt-empty? jolt-empty?) -(set! jolt-empty? (lambda (coll) - (if (jrec-collection? coll) (jolt-nil? (jolt-seq coll)) (%r-jolt-empty? coll)))) +(set! jolt-empty? (lambda (coll) (if (jrec? coll) (jolt-nil? (jolt-seq coll)) (%r-jolt-empty? coll)))) (define %r-jolt-peek jolt-peek) (set! jolt-peek (lambda (coll) (cond ((jrec-cl coll "peek") => (lambda (m) (jolt-invoke m coll))) @@ -437,13 +157,10 @@ ;; predicates.ss vars hold a snapshot, so re-def-var! after extending. record? is ;; the overlay's (some? (get x :jolt/deftype)) — works for free since the get ;; override returns the tag for that key. -;; only a defrecord is a map (Clojure: a record IS an associative map); a bare -;; deftype is not. coll? additionally covers a deftype implementing a collection -;; interface. predicates.ss vars hold a snapshot, so re-def-var! after extending. (define %r-jolt-map? jolt-map?) -(set! jolt-map? (lambda (x) (or (jrec-maplike? x) (%r-jolt-map? x)))) +(set! jolt-map? (lambda (x) (or (jrec? x) (%r-jolt-map? x)))) (def-var! "clojure.core" "map?" jolt-map?) -(def-var! "clojure.core" "coll?" (lambda (x) (or (jrec-collection? x) (jolt-coll-pred? x)))) +(def-var! "clojure.core" "coll?" (lambda (x) (or (jrec? x) (jolt-coll-pred? x)))) ;; ---- protocol registry ------------------------------------------------------ ;; type-tag -> (proto-name -> (method-name -> fn)) @@ -463,28 +180,9 @@ (and (pair? protos) (let ((f (hashtable-ref (hashtable-ref ti (car protos) #f) method #f))) (or f (loop (cdr protos))))))))) -;; A deftype can implement a method NAME at two arities from two interfaces (e.g. -;; data.priority-map's seq: Seqable.seq[this] and Sorted.seq[this ascending]), -;; registered under different protocols. Pick the impl whose procedure accepts -;; the call's arg count (this + args); fall back to any same-named impl. -(define (proc-accepts? f n) - (and (procedure? f) (bitwise-bit-set? (procedure-arity-mask f) n))) -(define (find-method-any-protocol-arity type-tag method nargs) - (let ((ti (hashtable-ref type-registry type-tag #f))) - (and ti (let loop ((protos (vector->list (hashtable-keys ti))) (fallback #f)) - (if (null? protos) - fallback - (let ((f (hashtable-ref (hashtable-ref ti (car protos) #f) method #f))) - (cond ((and f (proc-accepts? f nargs)) f) - (else (loop (cdr protos) (or fallback f)))))))))) (define (type-satisfies? type-tag proto) (let ((ti (hashtable-ref type-registry type-tag #f))) (and ti (hashtable-ref ti proto #f) #t))) -;; True when a deftype/record instance DECLARES a method by this name (an inline -;; protocol impl), so clojure.core can prefer it over generic collection behavior -;; — e.g. (empty priority-map) must use the type's own empty, not return {}. -(def-var! "jolt.host" "jrec-method?" - (lambda (v name) (if (and (jrec? v) (find-method-any-protocol (jrec-tag v) name)) #t #f))) ;; host type-tag candidates for a non-record value (extend-protocol on builtins). (define (value-host-tags obj) @@ -495,43 +193,16 @@ ((number? obj) '("Long" "Integer" "BigInteger" "BigInt" "Number" "Object")) ((string? obj) '("String" "CharSequence" "Object")) ((boolean? obj) '("Boolean" "Object")) - ((keyword? obj) (jch-tags "clojure.lang.Keyword")) - ((jolt-symbol? obj) (jch-tags "clojure.lang.Symbol")) - ((pvec? obj) (jch-tags "clojure.lang.PersistentVector")) - ((pmap? obj) (jch-tags "clojure.lang.PersistentArrayMap")) - ((pset? obj) (jch-tags "clojure.lang.PersistentHashSet")) - ;; jolt models every seq as a list (no distinct LazySeq), so a seq also - ;; reports PersistentList / IPersistentList / IPersistentStack — extend-protocol - ;; clojure.lang.IPersistentList (algo.monads' writer monad) dispatches on one. - ((or (cseq? obj) (empty-list-t? obj)) (jch-tags "clojure.lang.PersistentList")) - ;; a lazy seq (map/filter/… result) is clojure.lang.LazySeq: a Sequential - ;; ISeq, but not a PersistentList — matching the JVM so extend-protocol / - ;; instance? on a deferred seq dispatch like an eager one where they should. - ((jolt-lazyseq? obj) (jch-tags "clojure.lang.LazySeq")) - ;; a var is clojure.lang.Var (also IDeref / IFn) — reitit's Expand protocol - ;; extends to Var so a #'handler route dispatches. - ((var-cell? obj) (jch-tags "clojure.lang.Var")) + ((keyword? obj) '("Keyword" "Named" "Object")) + ((jolt-symbol? obj) '("Symbol" "Named" "Object")) + ((pvec? obj) '("PersistentVector" "APersistentVector" "IPersistentVector" "IPersistentCollection" + "List" "java.util.List" "Sequential" "Collection" "Iterable" "java.lang.Iterable" "Object")) + ((pmap? obj) '("PersistentArrayMap" "APersistentMap" "IPersistentMap" "Associative" + "Map" "java.util.Map" "Iterable" "java.lang.Iterable" "Object")) + ((pset? obj) '("PersistentHashSet" "APersistentSet" "IPersistentSet" "Set" "java.util.Set" "Collection" "Iterable" "java.lang.Iterable" "Object")) + ((or (cseq? obj) (empty-list-t? obj)) '("ASeq" "ISeq" "IPersistentCollection" "Sequential" "Collection" "Iterable" "java.lang.Iterable" "Object")) ;; java.net.URI jhost — extend-protocol java.net.URI (hiccup ToURI/ToStr). ((and (jhost? obj) (string=? (jhost-tag obj) "uri")) '("URI" "java.net.URI" "Object")) - ;; a ByteBuffer — extend-protocol java.nio.ByteBuffer (aws-api util). - ((and (jhost? obj) (string=? (jhost-tag obj) "byte-buffer")) '("ByteBuffer" "java.nio.ByteBuffer" "Object")) - ;; java.io readers/writers — so (extend-protocol java.io.Reader …) (data.csv) - ;; and the like dispatch on one. A PushbackReader is also a Reader. - ((and (jhost? obj) (string=? (jhost-tag obj) "string-reader")) - '("StringReader" "java.io.StringReader" "Reader" "java.io.Reader" "Object")) - ((and (jhost? obj) (string=? (jhost-tag obj) "pushback-reader")) - '("PushbackReader" "java.io.PushbackReader" "FilterReader" "java.io.FilterReader" "Reader" "java.io.Reader" "Object")) - ((and (jhost? obj) (string=? (jhost-tag obj) "char-reader")) - '("Reader" "java.io.Reader" "Object")) - ((and (jhost? obj) (string=? (jhost-tag obj) "char-writer")) - '("Writer" "java.io.Writer" "Object")) - ((and (jhost? obj) (string=? (jhost-tag obj) "writer")) - '("Writer" "java.io.Writer" "Object")) - ;; arrays dispatch by their JVM array-class name — extend-protocol to - ;; (Class/forName "[B") for byte[] (data.json, aws-api), "[C" for char[]. - ((and (jolt-array? obj) (eq? (jolt-array-kind obj) 'byte)) '("[B" "Object")) - ((and (jolt-array? obj) (eq? (jolt-array-kind obj) 'char)) '("[C" "Object")) - ((jolt-array? obj) '("[Ljava.lang.Object;" "Object")) ;; a regex VALUE — extend-protocol java.util.regex.Pattern (core.match.regex). ((regex-t? obj) '("Pattern" "java.util.regex.Pattern" "Object")) ;; host value types a library may extend a protocol to by class (data.json @@ -561,23 +232,8 @@ ;; extended to both (data.json's JSONWriter) routes a sql.Date to its impl. ((and (jhost? obj) (string=? (jhost-tag obj) "sql-date")) '("java.sql.Date" "Date" "java.util.Date" "Object")) ;; a bare procedure (fn) — extend-protocol to clojure.lang.{Fn,IFn,AFn}. - ((procedure? obj) (jch-tags "clojure.lang.AFunction")) + ((procedure? obj) '("Fn" "IFn" "AFn" "Object")) ((jolt-nil? obj) '("nil")) - ;; a defrecord IS the clojure.lang map/record interfaces, so a protocol - ;; extended to IRecord / IPersistentMap / Associative / Seqable / … (and not - ;; to the record's own type) dispatches to it — e.g. core.logic extends - ;; IWalkTerm to clojure.lang.IRecord, and walking a record value must hit - ;; that, not the Object default (which would recur forever). The record's - ;; own type is tried first (dispatch checks jrec-tag before these tags). - ((jrec-record? obj) - (cons (jrec-tag obj) - '("IRecord" "clojure.lang.IRecord" "IPersistentMap" "clojure.lang.IPersistentMap" - "APersistentMap" "Associative" "ILookup" "Seqable" "Counted" - "IPersistentCollection" "IObj" "IMeta" "Map" "java.util.Map" - "Iterable" "java.lang.Iterable" "Object"))) - ;; a bare deftype is opaque — its declared interfaces dispatch via the - ;; inline methods registered under its own tag (tried before these tags). - ((jrec? obj) (list (jrec-tag obj) "Object")) (else '("Object")))) (define (record-tag obj) (and (jrec? obj) (jrec-tag obj))) @@ -585,52 +241,19 @@ ;; ---- the native that handles the analyzer/overlay call ---------------------- ;; make-deftype-ctor: (name-sym field-kws field-tags field-muts) -> ctor closure. ;; The tag is baked at definition time in the type's ns (chez-current-ns). -(define (make-deftype-ctor name-sym field-kws . rest-args) +(define (make-deftype-ctor name-sym field-kws . _ignored) (let* ((tag (string-append (chez-current-ns) "." (symbol-t-name name-sym))) (kws (seq->list field-kws)) - (field-tags (if (pair? rest-args) (seq->list (car rest-args)) '())) - ;; which fields are ^double — coerced to a flonum on construction (JVM - ;; primitive-field parity), so reading them back is a genuine flonum. - (dbl-flags (list->vector (map chez-double-tag? field-tags))) - (ndbl (vector-length dbl-flags)) - (desc (make-jrdesc tag kws)) - (nf (length kws)) (ctor (lambda args - ;; fill the value vector from the positional args, padding missing - ;; trailing fields with nil and ignoring any extras. - (let ((v (make-vector nf jolt-nil))) - (let loop ((as args) (i 0)) - (if (or (null? as) (= i nf)) (make-jrec desc v jolt-nil) - (let ((a (car as))) - (vector-set! v i - (if (and (fx< i ndbl) (vector-ref dbl-flags i) - (number? a) (not (flonum? a))) - (exact->inexact a) a)) - (loop (cdr as) (+ i 1))))))))) - ;; Register the ctor under its fully-qualified tag ("ns.Name") — a bare - ;; (Name. …) in the DEFINING ns is qualified to this by the analyzer, so a - ;; deftype whose simple name collides with a built-in host class (tools.reader's - ;; PushbackReader vs java.io.PushbackReader) still resolves correctly there. - (register-class-ctor! tag ctor) - ;; Also register the simple name so (Name. …) resolves ns-agnostically across - ;; files — BUT never clobber a built-in host class of the same simple name (an - ;; unrelated ns's bare (Name. …) must still reach the built-in). A prior deftype - ;; (tracked in chez-simple-name-tag) is fine to overwrite (last def wins / redef). - (when (or (not (hashtable-ref class-ctors-tbl (symbol-t-name name-sym) #f)) - (hashtable-ref chez-simple-name-tag (symbol-t-name name-sym) #f)) - (register-class-ctor! (symbol-t-name name-sym) ctor)) - ;; index the tag so a cross-ns extend-protocol resolves the bare type name. - (hashtable-set! chez-deftype-tag-set tag #t) - (hashtable-set! chez-simple-name-tag (symbol-t-name name-sym) tag) - ;; graft the type onto the class graph so isa?/supers/ancestors see it. A - ;; bare deftype is an IType; defrecord (which runs register-record-type! - ;; right after) replaces the row with the record interface set. - (jch-set-supers! tag '("clojure.lang.IType")) - (hashtable-set! chez-deftype-ctor-tag ctor tag) - ;; record the shape for whole-program inference, keyed by the positional - ;; ctor var "ns/->Name" the analyzer resolves a (->Name …) call to. - (register-record-shape! (string-append (chez-current-ns) "/->" (symbol-t-name name-sym)) - kws field-tags tag) + (make-jrec tag (let loop ((ks kws) (as args) (acc '())) + (if (null? ks) (reverse acc) + (loop (cdr ks) (if (null? as) '() (cdr as)) + (cons (cons (car ks) (if (null? as) jolt-nil (car as))) acc)))))))) + ;; Register the ctor globally by simple class name (like StringBuilder) so + ;; (Name. …) interop resolves ns-agnostically: a deftype used across files works + ;; even when the runtime current ns is the caller's, not the defining ns + ;; (host-new checks class-ctors-tbl before the current-ns var fallback). + (register-class-ctor! (symbol-t-name name-sym) ctor) ctor)) ;; make-protocol: a protocol value the overlay reads via (get p :name)/(get p :methods). @@ -639,18 +262,10 @@ (keyword #f "name") (jolt-symbol jolt-nil name-str) (keyword #f "methods") methods)) -;; register-protocol-methods!: record each method's var-key -> [proto method] for -;; the inference driver (devirtualization). Dispatch itself is by the receiver's -;; type tag at call time, so this table is read only by `jolt build` inference. -;; Called by defprotocol-emitted code in the protocol's ns. -(define (register-protocol-methods! proto-name method-names) - (let ((ns (chez-current-ns))) - (for-each (lambda (mn) - (let ((m (if (symbol-t? mn) (symbol-t-name mn) mn))) - (hashtable-set! chez-protocol-methods-tbl - (string-append ns "/" m) (cons proto-name m)))) - (seq->list method-names))) - jolt-nil) +;; register-protocol-methods!: intentional no-op. Chez dispatches a protocol method +;; by the receiver's type tag at call time, so there is no method table to register; +;; this binding exists only because defprotocol-emitted code calls it. +(define (register-protocol-methods! proto-name method-names) jolt-nil) ;; register-method: extend-type/extend register an impl. Host type names keep a ;; bare canonical tag; record names qualify to the current ns. @@ -660,12 +275,11 @@ '("Long" "Integer" "Number" "Double" "Ratio" "BigInt" "BigInteger" "String" "CharSequence" "Boolean" "Character" "Keyword" "Symbol" "Named" "Object" "nil" - "Fn" "IFn" "AFn" "URI" "Var" "IDeref" + "Fn" "IFn" "AFn" "URI" "PersistentVector" "APersistentVector" "IPersistentVector" "PersistentArrayMap" "APersistentMap" "IPersistentMap" "PersistentHashSet" "APersistentSet" "IPersistentSet" "ASeq" "ISeq" "IPersistentCollection" "Associative" "Sequential" - "PersistentList" "IPersistentList" "IPersistentStack" "Map" "java.util.Map" "List" "java.util.List" "Set" "java.util.Set" "Collection" "java.util.Collection" "Iterable" "java.lang.Iterable" "UUID" "BigDecimal" "Date" "Timestamp" "Instant" "java.sql.Date" @@ -674,15 +288,7 @@ "Duration" "Period" "LocalDate" "LocalTime" "LocalDateTime" "ZonedDateTime" "OffsetDateTime" "OffsetTime" "ZoneId" "ZoneOffset" "Clock" "Year" "YearMonth" "Month" "DayOfWeek" - "ChronoUnit" "ChronoField" "TemporalAmount" "TemporalUnit" "TemporalField" - ;; ByteBuffer + JVM array classes (extend-protocol to (Class/forName "[B")) - "ByteBuffer" "java.nio.ByteBuffer" - "[B" "[C" "[I" "[J" "[D" "[Ljava.lang.Object;" - ;; java.io readers/writers — extend-protocol java.io.Reader (data.csv) - "Reader" "java.io.Reader" "Writer" "java.io.Writer" - "StringReader" "java.io.StringReader" "PushbackReader" "java.io.PushbackReader" - "BufferedReader" "java.io.BufferedReader" "FilterReader" "java.io.FilterReader" - "InputStream" "java.io.InputStream" "OutputStream" "java.io.OutputStream")) + "ChronoUnit" "ChronoField" "TemporalAmount" "TemporalUnit" "TemporalField")) h)) (define (strip-prefix s p) (let ((pl (string-length p))) @@ -696,17 +302,7 @@ (strip-prefix type-name "java.time.") (strip-prefix type-name "clojure.lang.") type-name))) - ;; a host class if the literal set lists it OR the class graph models it — both - ;; feed value-host-tags (which emits the same bare segment), so a protocol - ;; extended to any modeled class keys under a tag the value reports. A - ;; deftype/defrecord is in the graph too (its ancestry), but its VALUES report - ;; the ns-qualified tag, not the bare segment — so a name that resolves to a - ;; deftype never canonicalizes through the graph arm. - (and (or (hashtable-ref host-type-set base #f) - (and (not (hashtable-ref chez-simple-name-tag type-name #f)) - (not (hashtable-ref chez-deftype-tag-set type-name #f)) - (or (jch-known? base) (jch-known? type-name)))) - base))) + (and (hashtable-ref host-type-set base #f) base))) ;; An extend/extend-type/extend-protocol registration marks the tag as an ;; extender of the protocol (recorded inside type-registry so the per-case prune ;; restores it). deftype/defrecord inline impls go through register-inline-method @@ -719,14 +315,7 @@ (when pi (hashtable-set! pi extend-mark #t)))))) (define (register-method type-name proto-name method-name fn) (let* ((host (canonical-host-tag type-name)) - (local (string-append (chez-current-ns) "." type-name)) - ;; a host class -> its canonical tag; a deftype defined in THIS ns -> the - ;; local tag; an :import-ed deftype from another ns -> its real tag via the - ;; simple-name index; otherwise the local tag (a forward extend). - (tag (cond (host host) - ((hashtable-ref chez-deftype-tag-set local #f) local) - ((hashtable-ref chez-simple-name-tag type-name #f)) - (else local)))) + (tag (or host (string-append (chez-current-ns) "." type-name)))) (register-protocol-method tag proto-name method-name fn) (mark-extend! tag proto-name) jolt-nil)) @@ -745,60 +334,34 @@ (let ((h (make-hashtable string-hash string=?))) (hashtable-set! type-registry tag h) h)))) (unless (hashtable-ref ti proto-name #f) (hashtable-set! ti proto-name (make-hashtable string-hash string=?)))) - ;; the protocol's interface joins the type's class ancestry, spelled like the - ;; JVM interface (munged ns; the defining ns is assumed to be the current one — - ;; the macro passes only the simple protocol name). - (let ((iface (string-append (jch-munge-segments (chez-current-ns)) "." proto-name))) - (jch-mark-interface! iface) - (jch-register-supers! (string-append (chez-current-ns) "." type-name) (list iface))) jolt-nil) -;; protocol-resolve: the impl procedure for obj — by record type tag, a reify's -;; instance-local method, or the protocol's extended impls over obj's host tags. -;; Raises if none implements the method. The dispatchN entry points apply it -;; directly so a protocol call doesn't cons a rest-list (the impl fn is always a -;; procedure, registered by register-(inline-)method/extend). -(define (protocol-resolve proto-name method-name obj) - (cond - ((and (jrec? obj) (find-protocol-method (jrec-tag obj) proto-name method-name))) - ((reified-methods obj) - => (lambda (rm) - (or (hashtable-ref rm method-name #f) - ;; not implemented on the reify — fall back to the protocol's - ;; extended impls over the reify's host tags (e.g. an Object/default - ;; extension). malli reifies some protocols and leans on the default. - (let loop ((tags (value-host-tags obj))) - (cond ((null? tags) (error #f (string-append "No reified method " method-name))) - ((find-protocol-method (car tags) proto-name method-name)) - (else (loop (cdr tags)))))))) - (else - (let loop ((tags (value-host-tags obj))) - (cond ((null? tags) (error #f (string-append "No method " method-name " in " proto-name))) - ((find-protocol-method (car tags) proto-name method-name)) - (else (loop (cdr tags)))))))) -;; Fixed-arity entry points the protocol-method shims call: no rest-list, no seq -;; round-trip — apply the resolved impl directly. defprotocol emits one clause per -;; declared arity that calls the matching dispatchN. -(define (protocol-dispatch1 proto-name method-name obj) - ((protocol-resolve proto-name method-name obj) obj)) -(define (protocol-dispatch2 proto-name method-name obj a) - ((protocol-resolve proto-name method-name obj) obj a)) -(define (protocol-dispatch3 proto-name method-name obj a b) - ((protocol-resolve proto-name method-name obj) obj a b)) -;; the variadic fallback (a declared arity of 4+ args) takes a seqable rest. +;; protocol-dispatch: look up the impl by the value's type tag (record) or host +;; candidates, invoke it; reified objects carry instance-local methods. (define (protocol-dispatch proto-name method-name obj rest-args) (let ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args)))) - (apply (protocol-resolve proto-name method-name obj) obj rest))) - -;; devirt-resolve: the impl for a call the inference proved monomorphic. Try the -;; static type tag directly (the fast path that skips receiver-type computation), -;; and fall back to ordinary dispatch when it misses — a record can satisfy a -;; protocol via an Object/host-tag default rather than a direct impl, which -;; find-protocol-method on its own tag wouldn't see. Mirrors jrec-field-at falling -;; back to jolt-get: correct regardless of how precise the inference was. -(define (devirt-resolve type-tag proto-name method-name obj) - (or (find-protocol-method type-tag proto-name method-name) - (protocol-resolve proto-name method-name obj))) + (cond + ((and (jrec? obj) (find-protocol-method (jrec-tag obj) proto-name method-name)) + => (lambda (f) (apply jolt-invoke f obj rest))) + ((reified-methods obj) + => (lambda (rm) (let ((f (hashtable-ref rm method-name #f))) + (if f (apply jolt-invoke f obj rest) + ;; not implemented on the reify — fall back to the + ;; protocol's extended impls over the reify's host tags + ;; (e.g. an Object/default extension). malli reifies some + ;; protocols and relies on a protocol's default for the + ;; rest. + (let loop ((tags (value-host-tags obj))) + (cond ((null? tags) (error #f (string-append "No reified method " method-name))) + ((find-protocol-method (car tags) proto-name method-name) + => (lambda (g) (apply jolt-invoke g obj rest))) + (else (loop (cdr tags))))))))) + (else + (let loop ((tags (value-host-tags obj))) + (cond ((null? tags) (error #f (string-append "No method " method-name " in " proto-name))) + ((find-protocol-method (car tags) proto-name method-name) + => (lambda (f) (apply jolt-invoke f obj rest))) + (else (loop (cdr tags))))))))) ;; dot-dispatch fallback used by emit for (.method record args): find the method ;; in ANY protocol the record's type implements. @@ -835,38 +398,21 @@ ;; "#". (def-var! "jolt.host" "condition-message" (lambda (c) (if (condition? c) (condition->message-string c) jolt-nil))) -(define (record-method-dispatch-base obj method-name rest-args) +(define (record-method-dispatch obj method-name rest-args) (let ((rest (if (jolt-nil? rest-args) '() (seq->list rest-args)))) (cond - ((and (jrec? obj) (find-method-any-protocol-arity (jrec-tag obj) method-name (+ 1 (length rest)))) + ;; (.getClass x): universal Object method — the class token for any value + ;; (jolt has no Class objects; the token is the canonical name string, on + ;; which .getName/.getSimpleName work via the String method shim). + ((and (string=? method-name "getClass") (not (jrec? obj)) (not (jreify? obj))) + (jolt-class obj)) + ((and (jrec? obj) (find-method-any-protocol (jrec-tag obj) method-name)) => (lambda (f) (apply jolt-invoke f obj rest))) ;; (.field inst): a deftype/record field read with no matching method. ;; Clojure reads the field for (.q x) just like (.-q x); a declared method ;; (above) wins, this is the field-accessor fallback. ((and (jrec? obj) (null? rest) (jrec-has? obj (keyword #f method-name))) (jrec-lookup obj (keyword #f method-name) jolt-nil)) - ;; a defrecord is Associative / ILookup / IPersistentMap / Seqable / Counted, - ;; so its clojure.lang interface methods delegate to the map fns when not - ;; overridden by a declared method — reitit's impl calls (.assoc match k v), - ;; (.valAt …), (.without …) directly. A bare deftype implements these via its - ;; own declared methods (handled above), so this is record-only. - ((and (jrec-record? obj) - (member method-name '("valAt" "assoc" "without" "containsKey" "cons" - "count" "seq" "equiv" "entryAt" "empty"))) - (cond - ((string=? method-name "valAt") - (if (null? (cdr rest)) (jolt-get obj (car rest) jolt-nil) (jolt-get obj (car rest) (cadr rest)))) - ((string=? method-name "assoc") (jolt-assoc1 obj (car rest) (cadr rest))) - ((string=? method-name "without") (jolt-dissoc obj (car rest))) - ((string=? method-name "containsKey") (if (jolt-truthy? (jolt-contains? obj (car rest))) #t #f)) - ((string=? method-name "cons") (jolt-conj1 obj (car rest))) - ((string=? method-name "count") (jolt-count obj)) - ((string=? method-name "seq") (jolt-seq obj)) - ((string=? method-name "equiv") (if (jolt= obj (car rest)) #t #f)) - ((string=? method-name "entryAt") - (if (jolt-truthy? (jolt-contains? obj (car rest))) - (make-map-entry (car rest) (jolt-get obj (car rest) jolt-nil)) jolt-nil)) - (else jolt-nil))) ; .empty of a record is nil on the JVM ((reified-methods obj) => (lambda (rm) (let ((f (hashtable-ref rm method-name #f))) (if f (apply jolt-invoke f obj rest) (error #f (string-append "No method " method-name)))))) @@ -903,8 +449,6 @@ (string-append (if (symbol-t-ns obj) (string-append (symbol-t-ns obj) "/") "") (symbol-t-name obj))) ((string=? method-name "equals") (and (pair? rest) (jolt=2 obj (car rest)))) - ((string=? method-name "hashCode") - (java-symbol-hash (symbol-t-name obj) (symbol-t-ns obj))) (else (error #f (string-append "No method " method-name " on Symbol"))))) ;; clojure.lang.Namespace: name/getName yield the ns name as a Symbol (JVM: ;; Namespace.name is a Symbol). clojure.spec.alpha reads (.name *ns*). @@ -954,14 +498,6 @@ ((jolt=2 (seq-first s) target) (if last? (loop (jolt-seq (seq-more s)) (fx+ i 1) i) i)) (else (loop (jolt-seq (seq-more s)) (fx+ i 1) found)))))) - ;; java.util.Collection.contains over a list/seq (vectors/sets handle it in - ;; dot-coll-method): value membership, like the JVM. - ((string=? method-name "contains") - (let ((target (car rest))) - (let loop ((s (jolt-seq obj))) - (cond ((jolt-nil? s) #f) - ((jolt=2 (seq-first s) target) #t) - (else (loop (jolt-seq (seq-more s)))))))) ;; universal Object methods on any remaining value (boolean, etc.). ((string=? method-name "toString") (jolt-str-render-one obj)) ((string=? method-name "hashCode") (jolt-hash obj)) @@ -969,46 +505,10 @@ (else (error #f (string-append "No method " method-name " for value: " (jolt-pr-str obj))))))) -;; ---- method-dispatch arm registry ------------------------------------------ -;; A .method call (record-method-dispatch) is resolved by an ordered list of arms -;; (ascending priority), each (obj method-name rest-args) -> result | 'pass. -;; This replaces a stack of (set! record-method-dispatch ...) rebindings across -;; six files whose precedence was implicit in load order — priority is now -;; explicit data. record-method-dispatch-base is the final fallback (the -;; string/keyword/symbol/Object-method surface). A host shim / library registers -;; an arm with register-method-arm! instead of set!-wrapping the dispatcher. -(define method-dispatch-arms '()) ; list of (priority . arm), ascending priority -(define (register-method-arm! priority arm) - (set! method-dispatch-arms - (let ins ((as method-dispatch-arms)) - (cond ((null? as) (list (cons priority arm))) - ((< priority (caar as)) (cons (cons priority arm) as)) - (else (cons (car as) (ins (cdr as)))))))) -(define (record-method-dispatch obj method-name rest-args) - (let loop ((as method-dispatch-arms)) - (if (null? as) - (record-method-dispatch-base obj method-name rest-args) - (let ((r ((cdar as) obj method-name rest-args))) - (if (eq? r 'pass) (loop (cdr as)) r))))) - -;; (.getClass x): a universal Object method reached by EVERY value before any -;; per-type arm — the class token for the value (jolt has no Class objects; the -;; token is the canonical name string, on which .getName/.getSimpleName work). -;; One arm, so a type arm that only whitelists its own methods can't steal it. -(register-method-arm! 5 - (lambda (obj method-name rest-args) - (if (string=? method-name "getClass") (jolt-class obj) 'pass))) - ;; reify: instance-local method table. obj is a jreify carrying a method ht + ;; the protocol short-names it implements (for satisfies?/instance?). (define-record-type jreify (fields methods protos) (nongenerative chez-jreify-v1)) (define (reified-methods obj) (and (jreify? obj) (jreify-methods obj))) -;; (get reify k) / (:k reify) routes to a reify's ILookup valAt — clojure.spec.alpha -;; reifies fspec/regex specs as clojure.lang.ILookup and reads (:args spec) off them. -(register-get-arm! jreify? - (lambda (coll k d) - (let ((m (and (reified-methods coll) (hashtable-ref (reified-methods coll) "valAt" #f)))) - (if m (jolt-invoke m coll k d) d)))) (define (make-reified methods-map . proto-names) (let ((ht (make-hashtable string-hash string=?)) (protos (if (and (pair? proto-names) (null? (cdr proto-names)) (jolt-coll-pred? (car proto-names))) @@ -1066,24 +566,6 @@ ;; yields (jolt-symbol #f (jrec-tag x)), the ns.Name class-name symbol. (def-var! "clojure.core" "make-deftype-ctor" make-deftype-ctor) - -;; defrecord marks its type a record (deftype does not), keyed by the same -;; "ns.Name" tag make-deftype-ctor bakes — so jrec-record? distinguishes the two. -(define (register-record-type! name-sym) - (let ((tag (string-append (chez-current-ns) "." (symbol-t-name name-sym)))) - (hashtable-set! chez-record-type-tbl tag #t) - ;; a defrecord's class ancestry: replace the deftype IType row with the - ;; record interfaces (their closure supplies Associative/Seqable/ILookup/…), - ;; keeping any protocol interfaces already grafted by the inline - ;; registrations that ran between the deftype ctor and this call. - (let ((protos (filter (lambda (s) (not (string=? s "clojure.lang.IType"))) - (jch-direct-supers tag)))) - (jch-set-supers! tag (append protos - '("clojure.lang.IRecord" "clojure.lang.IObj" - "clojure.lang.IPersistentMap" "java.util.Map" - "clojure.lang.IHashEq" "java.io.Serializable"))))) - jolt-nil) -(def-var! "clojure.core" "register-record-type!" register-record-type!) (def-var! "clojure.core" "make-protocol" make-protocol) (def-var! "clojure.core" "register-protocol-methods!" register-protocol-methods!) (def-var! "clojure.core" "register-method" register-method) @@ -1091,9 +573,6 @@ (def-var! "clojure.core" "register-inline-protocol!" register-inline-protocol!) (def-var! "jolt.host" "set-field!" jolt-set-field!) (def-var! "clojure.core" "protocol-dispatch" (lambda (pn mn obj rest) (protocol-dispatch pn mn obj rest))) -(def-var! "clojure.core" "protocol-dispatch1" (lambda (pn mn obj) (protocol-dispatch1 pn mn obj))) -(def-var! "clojure.core" "protocol-dispatch2" (lambda (pn mn obj a) (protocol-dispatch2 pn mn obj a))) -(def-var! "clojure.core" "protocol-dispatch3" (lambda (pn mn obj a b) (protocol-dispatch3 pn mn obj a b))) (def-var! "clojure.core" "satisfies?" jolt-satisfies?) (def-var! "clojure.core" "extenders" extenders) (def-var! "clojure.core" "make-reified" (lambda (mm . rest) (apply make-reified mm rest))) diff --git a/host/chez/regex.ss b/host/chez/regex.ss index d320284..4436017 100644 --- a/host/chez/regex.ss +++ b/host/chez/regex.ss @@ -33,14 +33,6 @@ (apply %chez-error args))) (load "vendor/irregex/irregex.scm") -;; irregex rejects a quantifier applied to anything that already contains one — -;; including a GROUP like (a+)* — because sre-repeater? recurses through submatch. -;; Java only rejects a DANGLING double quantifier (a**); it allows a quantifier on -;; a group whose body is quantified. Restrict the check to a bare leading * / + so -;; a** still errors but (a+)* parses (cuerdas's format tokenizer needs this). -(set! sre-repeater? - (lambda (sre) (and (pair? sre) (memq (car sre) '(* +)) #t))) - ;; Unicode property classes \p{...}: irregex's string syntax has no ;; \p{...}, so translate a fixed set of property names ;; to ASCII char classes before compiling. ASCII-only — \p{L} would need @@ -100,36 +92,6 @@ (write-char c out) (loop (fx+ i 1) #f)) (else (write-char c out) (loop (fx+ i 1) in-class)))))))) -;; Inside a [...] class, irregex reads a '-' that follows a shorthand class -;; (\w \d \s \W \D \S) as the start of a range and errors ("bad char-set"); Java -;; reads it as a literal hyphen (a shorthand can't be a range endpoint). Escape -;; such a '-' to \- so the class parses. Only a '-' right after a shorthand and -;; not the class terminator is touched; a '-' after a plain char (a real range -;; like [a-z]) is left alone. -(define (escape-class-shorthand-dash src) - (let ((len (string-length src)) (out (open-output-string))) - (let loop ((i 0) (in-class #f) (after-shorthand #f)) - (if (fx>=? i len) - (get-output-string out) - (let ((c (string-ref src i))) - (cond - ;; an escape pair: \w-style shorthand sets after-shorthand inside a class - ((and (char=? c #\\) (fx (irregex-num-submatches irx) 0) - (apply irregex p 'backtrack opts) - irx))))) + (make-regex-t source (apply irregex (translate-prop-classes pat) opts)))) (define (jolt-regex? x) (regex-t? x)) (define (jolt-re-pattern x) (if (regex-t? x) x (jolt-regex x))) @@ -195,59 +143,9 @@ (let ((m (irregex-match (regex-t-irx (jolt-re-pattern re)) s))) (if m (irx-result m) jolt-nil))) -;; A stateful matcher (java.util.regex.Matcher): the compiled pattern, the target -;; string, the next search position, and the last successful irregex match. re-find -;; over a matcher steps through non-overlapping matches; re-groups returns the -;; groups of the last one. -(define-record-type matcher-t - (fields irx str (mutable pos) (mutable last)) - (nongenerative jolt-matcher-v1)) -(define (jolt-re-matcher re s) - (make-matcher-t (regex-t-irx (jolt-re-pattern re)) s 0 #f)) -(define (jolt-matcher? x) (matcher-t? x)) - -;; re-find: stateless over (re s), or stateful over a matcher (advance + remember). -(define jolt-re-find - (case-lambda - ((re s) - (let ((m (irregex-search (regex-t-irx (jolt-re-pattern re)) s))) - (if m (irx-result m) jolt-nil))) - ((m) - (let* ((str (matcher-t-str m)) - (len (string-length str)) - (start (matcher-t-pos m)) - (mm (and (<= start len) (irregex-search (matcher-t-irx m) str start)))) - (if mm - (let ((ms (irregex-match-start-index mm 0)) - (e (irregex-match-end-index mm 0))) - (matcher-t-last-set! m mm) - ;; advance past this match: to its end, or one past a zero-width match - ;; (which may sit past the search origin, e.g. a lookahead/boundary). - (matcher-t-pos-set! m (if (> e ms) e (+ e 1))) - (irx-result mm)) - (begin (matcher-t-last-set! m #f) jolt-nil)))))) - -;; re-groups: the groups of the matcher's last successful find. Throws when no -;; match has succeeded, like Clojure's IllegalStateException "No match found". -(define (jolt-re-groups m) - (let ((last (matcher-t-last m))) - (if last (irx-result last) - (jolt-throw (jolt-ex-info "No match found" (jolt-hash-map)))))) - -;; java.util.regex.Matcher methods over a matcher-t. .matches anchors a full-region -;; match and remembers it for .group; .group n returns submatch n (0 = whole) or -;; nil; .groupCount is the pattern's capturing-group count. -(define (jolt-matcher-matches m) - (let ((mm (irregex-match (matcher-t-irx m) (matcher-t-str m)))) - (matcher-t-last-set! m mm) - (if mm #t #f))) -(define (jolt-matcher-group m . n) - (let ((last (matcher-t-last m))) - (if last - (let ((s (irregex-match-substring last (if (pair? n) (->idx (car n)) 0)))) - (if s s jolt-nil)) - (jolt-throw (jolt-ex-info "No match available" (jolt-hash-map)))))) -(define (jolt-matcher-group-count m) (irregex-num-submatches (matcher-t-irx m))) +(define (jolt-re-find re s) + (let ((m (irregex-search (regex-t-irx (jolt-re-pattern re)) s))) + (if m (irx-result m) jolt-nil))) ;; All non-overlapping matches, left to right. Advance past each match end (or by ;; one on a zero-width match). nil when there are no matches (Clojure: seq-able as @@ -258,17 +156,12 @@ (let loop ((start 0) (acc '())) (let ((m (and (<= start len) (irregex-search irx s start)))) (if m - (let ((ms (irregex-match-start-index m 0)) - (e (irregex-match-end-index m 0))) - ;; to the match end, or one past a zero-width match (relative to its - ;; own start, which may be past the search origin). - (loop (if (> e ms) e (+ e 1)) (cons (irx-result m) acc))) + (let ((e (irregex-match-end-index m 0))) + (loop (if (> e start) e (+ start 1)) (cons (irx-result m) acc))) (list->cseq (reverse acc))))))) (def-var! "clojure.core" "re-pattern" jolt-re-pattern) (def-var! "clojure.core" "re-matches" jolt-re-matches) (def-var! "clojure.core" "re-find" jolt-re-find) (def-var! "clojure.core" "re-seq" jolt-re-seq) -(def-var! "clojure.core" "re-matcher" jolt-re-matcher) -(def-var! "clojure.core" "re-groups" jolt-re-groups) (def-var! "clojure.core" "regex?" jolt-regex?) diff --git a/host/chez/rt.ss b/host/chez/rt.ss index 0649697..1fb57a5 100644 --- a/host/chez/rt.ss +++ b/host/chez/rt.ss @@ -11,17 +11,6 @@ ;; Emitted programs do `(load "host/chez/rt.ss")`; this loads values.ss in turn. (load "host/chez/values.ss") -;; Resolve a libc entry point at RUN time. A literal (foreign-procedure "name" …) -;; in COMPILED code becomes a fasl relocation resolved when the boot loads — on a -;; platform lacking the symbol (chmod/sigaddset on Windows) that kills the boot -;; before any guard can run. eval defers the lookup to evaluation time, where the -;; guard works; returns #f when the entry doesn't exist. -(define (jolt-foreign-proc-safe name args res) - (guard (e (#t #f)) - (load-shared-object #f) - (and (foreign-entry? name) - (eval `(foreign-procedure ,name ,args ,res))))) - (load "host/chez/collections.ss") (load "host/chez/seq.ss") @@ -33,157 +22,20 @@ ;; pass an exact integer through, error if it doesn't fit a fixnum or isn't a ;; number. The hint is a promise the value is a fixnum-range long; the body's fx* ;; ops rely on it. (^double params coerce with the built-in exact->inexact.) -;; A ^long is a 64-bit value; a Chez fixnum is only 61-bit, so a value that -;; overflows the fixnum range (a full-width long, e.g. from unchecked / wrapping -;; arithmetic) passes through as an exact integer rather than erroring. fx ops in -;; the body still require fixnums (they raise on a bignum), but generic / -;; unchecked-* ops handle it. (define (jolt->fx x) - (cond ((fixnum? x) x) - ((and (number? x) (exact? x) (integer? x)) x) - ((flonum? x) (exact (truncate x))) - ((rational? x) (exact (truncate x))) - (else (error 'jolt "^long hint: not a number" x)))) + (let ((n (cond ((fixnum? x) x) + ((flonum? x) (exact (truncate x))) + ((rational? x) (exact (truncate x))) + (else (error 'jolt "^long hint: not a number" x))))) + (if (fixnum? n) n (error 'jolt "^long hint: value out of fixnum range" x)))) ;; jolt `not`: only nil and false are falsey. (define (jolt-not x) (if (jolt-truthy? x) #f #t)) ;; --- exceptions -------------------------------------------------------------- -;; throw raises a Chez condition WRAPPING the jolt value; catch (emitted as -;; `guard`) and jolt-report-uncaught unwrap it back via jolt-unwrap-throw. -;; Raising the value RAW broke when a throw crossed the host/`eval` boundary: -;; Chez re-wrapped the non-condition into a compound condition whose -;; message-extraction APPLIES the value (crashing on an empty-map :data -> -;; "attempt to apply non-procedure"), and the real message was lost. A real -;; condition propagates intact through any number of eval boundaries. -;; Capture the live continuation at the throw site (identity-tagged with the -;; thrown value) so an uncaught error can walk the native frames back to a Clojure -;; stack trace (source-registry.ss). call/cc is paid only on a throw, never per -;; call; the captured k is walked, never invoked. -(define jolt-throw-cont (make-thread-parameter #f)) - -;; --- tail-frame history: a ring of rings (opt-in) ---------------------------- -;; TCO erases tail-called frames from the native continuation, so an uncaught -;; error's backtrace shows only the surviving non-tail spine — the immediate error -;; site is often a tail call and is missing. When tracing is enabled (JOLT_TRACE, -;; wired in compile-eval.ss), each compiled fn records its frame-name on entry, and -;; the reporter reads this history to recover TCO-elided frames. -;; -;; The store is MIT-Scheme's "history" shape — a ring of rings. The OUTER ring -;; holds one RIB per non-tail subproblem (the real call spine); each rib's INNER -;; ring holds the recent tail-calls made AT that subproblem. A non-tail entry -;; advances the outer ring (a fresh rib); a tail entry rotates the current rib's -;; inner ring. So a tight tail loop (mutual recursion, a non-recur self-tail-call) -;; churns ONE rib's small inner ring instead of flushing the outer spine — the -;; caller context that led into the loop survives. Both rings are fixed-size, so -;; the whole history is bounded: a constant space factor, NOT a change to the -;; asymptotic space TCO guarantees. -;; -;; Whether an entry is tail or non-tail is set by the CALLER: the emitter marks a -;; tail call with (jolt-trace-mark! #t) right before it; a non-tail entry is the -;; default. NOTE this is best-effort: a tail call routed through jolt-invoke to a -;; target that has no entry prologue (a core/native fn, an anonymous fn held in a -;; var) does not consume the mark, so a following non-tail frame can be mislabeled -;; as a tail rotation — a cosmetic mis-grouping in the trace, never a wrong result. -(define jolt-trace-outer-size 48) ; ribs (non-tail spine depth kept) -(define jolt-trace-inner-size 6) ; tail-calls kept per subproblem -;; A history: #(ribs-vector outer-head outer-count). A rib: #(name-vector head count). -(define (jolt-make-rib) (vector (make-vector jolt-trace-inner-size #f) 0 0)) -(define (jolt-make-history) - (let ((ribs (make-vector jolt-trace-outer-size #f))) - (let loop ((i 0)) - (when (fx? k cnt) - (reverse acc) - (loop (fx+ k 1) - (cons (vector-ref buf (fxmod (fx+ (fx- head k) jolt-trace-inner-size) - jolt-trace-inner-size)) - acc)))))) -;; The whole history flattened to frame-names, most-recent (deepest) first: -;; current rib's tail-history, then its non-tail caller's, and so on outward. -(define (jolt-trace-snapshot) - (let ((h (jolt-trace-ring))) - (if (not h) '() - (let* ((ribs (vector-ref h 0)) (oh (vector-ref h 1)) (oc (vector-ref h 2))) - (let loop ((k 1) (acc '())) - (if (fx>? k oc) - (apply append (reverse acc)) - (let ((idx (fxmod (fx+ (fx- oh k) jolt-trace-outer-size) jolt-trace-outer-size))) - (loop (fx+ k 1) (cons (jolt-rib-names (vector-ref ribs idx)) acc))))))))) - -(define-condition-type &jolt-throw &condition - make-jolt-throw-condition jolt-throw-condition? - (value jolt-throw-condition-value)) -;; Fallback &message for a leaked condition; the real message always comes from -;; the unwrapped value via ex-message. -(define (jolt-throw-message v) - (if (and (pmap? v) - (jolt=2 (jolt-get v jolt-kw-ex-type jolt-nil) jolt-kw-ex-info)) - (let ((m (jolt-get v jolt-kw-message jolt-nil))) - (if (string? m) m "jolt error")) - "jolt error")) -(define (jolt-throw v) - (call/cc (lambda (k) - (jolt-throw-cont (cons v k)) - (raise (condition (make-message-condition (jolt-throw-message v)) - (make-jolt-throw-condition v)))))) -(define (jolt-unwrap-throw x) - (if (jolt-throw-condition? x) (jolt-throw-condition-value x) x)) +;; throw raises the jolt value RAW (no envelope); +;; catch (emitted as `guard`) binds it directly. Chez `raise` accepts any +;; object, so a thrown number/map/ex-info all work; uncaught -> non-zero exit. +(define (jolt-throw v) (raise v)) ;; ex-info builds the tagged map {:jolt/type :jolt/ex-info :message :data :cause} ;; — a real jolt-hash-map, so the ex-data/ex-message/ex-cause tier fns read it ;; via jolt-get for free. Arity 2 (msg data) or 3 (msg data cause). @@ -251,21 +103,7 @@ ;; evaluates to #'ns/name (a first-class var), so (var? (def x 1)) is true and ;; (pr-str (def x 1)) is "#'ns/x". The prelude's def-var! forms discard the ;; return, so this is transparent there. -;; proc -> (ns . name) for the var it was def'd into, so (class a-fn) can report a -;; JVM-style class name and clojure.spec.alpha's fn-sym can recover the symbol of a -;; bare-fn predicate. Weak so GC'd fns drop out. Last def of a given proc wins. -(define proc-name-tbl (make-weak-eq-hashtable)) -(define (def-var! ns name v) - ;; first def of a given proc wins, so an alias like (def inc' inc) — which binds - ;; the SAME proc to a second var — doesn't rename inc. - (when (and (procedure? v) (not (hashtable-contains? proc-name-tbl v))) - (hashtable-set! proc-name-tbl v (cons ns name))) - (let ((c (jolt-var ns name))) (var-cell-root-set! c v) (var-cell-defined?-set! c #t) c)) -;; jolt.host/throwable — build a typed throwable a library can throw so (class …), -;; instance?, .getMessage and ex-message all reflect the named JVM class (e.g. an -;; http client throwing java.net.ConnectException). Strictly better than a -;; hand-rolled :jolt/ex-info table, which carries only the class. -(def-var! "jolt.host" "throwable" jolt-host-throwable) +(define (def-var! ns name v) (let ((c (jolt-var ns name))) (var-cell-root-set! c v) (var-cell-defined?-set! c #t) c)) ;; var def-time metadata: the :def emit passes the def's reader meta ;; (^:private / ^Type tag / docstring -> {:doc}) here, stored in an eq side-table ;; keyed by the cell. jolt-meta (natives-meta.ss) merges it onto {:ns :name}, @@ -341,59 +179,6 @@ ;; bare nil renders as the empty string (a nil ELEMENT inside a collection still ;; prints "nil", which jolt-pr-str handles). (define (jolt-final-str x) (if (jolt-nil? x) "" (jolt-pr-str x))) -;; --- *print-level* / *print-length* ----------------------------------------- -;; Both vars default to nil (= unlimited). A non-nil number limits collection -;; nesting depth / element count in BOTH printers (jolt-pr-str here and -;; jolt-pr-readable in printing.ss). Cells captured lazily — the vars are def'd -;; after rt.ss. The nil default takes a fast path: jolt-print-hash? is #f and the -;; limited-string walkers never truncate. -(define plevel-cell #f) -(define plength-cell #f) -(define (jolt-print-level) - (unless plevel-cell (set! plevel-cell (jolt-var "clojure.core" "*print-level*"))) - (let ((v (jolt-var-get plevel-cell))) (and (number? v) v))) -(define (jolt-print-length) - (unless plength-cell (set! plength-cell (jolt-var "clojure.core" "*print-length*"))) - (let ((v (jolt-var-get plength-cell))) (and (number? v) v))) -(define jolt-print-depth (make-thread-parameter 0)) -;; A collection at depth >= *print-level* renders as "#". The top-level collection -;; is depth 0, so *print-level* 0 collapses any collection, 1 keeps the outermost. -(define (jolt-print-hash?) - (let ((lvl (jolt-print-level))) (and lvl (fx>=? (jolt-print-depth) lvl)))) -;; Rendered element strings of a vector (by index), honoring *print-length*: at -;; most N, then "...". render-one runs at the current (already bumped) depth. -(define (jolt-limited-vec-strs x render-one) - (let ((len (pvec-count x)) (lim (jolt-print-length))) - (let loop ((i 0) (acc '())) - (cond ((fx>=? i len) (reverse acc)) - ((and lim (fx>=? i lim)) (reverse (cons "..." acc))) - (else (loop (fx+ i 1) (cons (render-one (pvec-nth-d x i jolt-nil)) acc))))))) -;; Rendered element strings of a seq, walked lazily so an infinite seq is realized -;; only up to *print-length*. -(define (jolt-limited-seq-strs s render-one) - (let ((lim (jolt-print-length))) - (let loop ((s s) (i 0) (acc '())) - (cond ((jolt-nil? s) (reverse acc)) - ((and lim (fx>=? i lim)) (reverse (cons "..." acc))) - (else (loop (jolt-seq (seq-more s)) (fx+ i 1) (cons (render-one (seq-first s)) acc))))))) -;; Truncate an already-collected element-string list (set / map, finite) to -;; *print-length*, appending "..." when more remain. -(define (jolt-limited-list-strs strs) - (let ((lim (jolt-print-length))) - (if (not lim) strs - (let loop ((s strs) (i 0) (acc '())) - (cond ((null? s) (reverse acc)) - ((fx>=? i lim) (reverse (cons "..." acc))) - (else (loop (cdr s) (fx+ i 1) (cons (car s) acc)))))))) -;; bump the print depth around a collection's element rendering — but only when -;; *print-level* is set, since depth is consulted only to enforce it. With the -;; common nil default this is a plain begin, so printing pays no parameterize. -(define-syntax with-deeper-print - (syntax-rules () - ((_ body ...) (if (jolt-print-level) - (parameterize ((jolt-print-depth (fx+ (jolt-print-depth) 1))) body ...) - (begin body ...))))) - ;; A host shim registers a type's str-style rendering via register-pr-str-arm! (or ;; register-pr-arm! in printing.ss for both printers at once) instead of ;; set!-wrapping jolt-pr-str. Disjoint types, checked before the base cases. @@ -414,23 +199,18 @@ (if (or (jolt-nil? ns) (not ns) (eq? ns '())) (symbol-t-name x) (string-append ns "/" (symbol-t-name x))))) ((regex-t? x) (string-append "#\"" (regex-t-source x) "\"")) - ((pvec? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "[" (jolt-str-join (jolt-limited-vec-strs x jolt-pr-str)) "]")))) - ((pset? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "#{" (jolt-str-join (jolt-limited-list-strs - (pset-fold x (lambda (e a) (cons (jolt-pr-str e) a)) '()))) "}")))) - ((pmap? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "{" (jolt-str-join (jolt-limited-list-strs - (pmap-fold x (lambda (k v a) (cons (string-append (jolt-pr-str k) " " (jolt-pr-str v)) a)) '()))) "}")))) - ;; lists / cons / lazy seqs all print as (...) — forces a finite seq (or up to - ;; *print-length* of an infinite one). - ((empty-list-t? x) (if (jolt-print-hash?) "#" "()")) - ((cseq? x) (if (jolt-print-hash?) "#" - (with-deeper-print - (string-append "(" (jolt-str-join (jolt-limited-seq-strs x jolt-pr-str)) ")")))) + ((pvec? x) (let ((acc '())) (let loop ((i (fx- (pvec-count x) 1))) + (when (fx>=? i 0) (set! acc (cons (jolt-pr-str (pvec-nth-d x i jolt-nil)) acc)) (loop (fx- i 1)))) + (string-append "[" (jolt-str-join acc) "]"))) + ((pset? x) (string-append "#{" (jolt-str-join (pset-fold x (lambda (e a) (cons (jolt-pr-str e) a)) '())) "}")) + ((pmap? x) (string-append "{" (jolt-str-join + (pmap-fold x (lambda (k v a) (cons (string-append (jolt-pr-str k) " " (jolt-pr-str v)) a)) '())) "}")) + ;; lists / cons / lazy seqs all print as (...) — forces a finite seq. + ((empty-list-t? x) "()") + ((cseq? x) (string-append "(" (jolt-str-join + (let loop ((s x) (acc '())) + (if (jolt-nil? s) (reverse acc) + (loop (jolt-seq (seq-more s)) (cons (jolt-pr-str (seq-first s)) acc))))) ")")) (else (format "~a" x)))) (define (jolt-pr-str x) (let loop ((as jolt-pr-str-arms)) @@ -473,18 +253,13 @@ ;; jolt-pr-str (above), and the var-cell machinery — so loaded last. (load "host/chez/multimethods.ss") -;; the single JVM class/interface graph — value-host-tags, instance?, isa?/supers, -;; and the exception hierarchy all derive from it. Before records.ss so -;; value-host-tags can build on jch-tags. -(load "host/chez/java/class-hierarchy.ss") - ;; records + protocols: defrecord/deftype/defprotocol/ ;; extend-type/reify. A jrec record type set!-extended into the collection ;; dispatchers + a protocol registry. After multimethods.ss (chez-current-ns) and ;; the dispatchers/printers it wraps (collections/seq/values/converters/printing/ ;; transients). (load "host/chez/records.ss") -(load "host/chez/java/records-interop.ss") ; exception hierarchy + instance-check taxonomy +(load "host/chez/records-interop.ss") ; exception hierarchy + instance-check taxonomy ;; metadata: meta / with-meta over an identity-keyed ;; side-table. After records.ss (jrec) + the collection ctors it copies. @@ -493,7 +268,7 @@ ;; host class tokens: bare class names (String/Keyword/File...) -> ;; canonical JVM class-name strings + (class x). After natives-meta.ss (jolt-type) ;; and the printer (jolt-str-render-one). -(load "host/chez/java/host-class.ss") +(load "host/chez/host-class.ss") ;; dynamic vars: *clojure-version* / *unchecked-math* constants the host ;; binds natively. After collections.ss (jolt-hash-map) + def-var!. @@ -549,39 +324,38 @@ ;; portable String/CharSequence surface record-method-dispatch falls through to on ;; a string target. After regex.ss (jolt-re-pattern/regex-t-irx) + records.ss ;; (which references jolt-string-method). -(load "host/chez/java/natives-str.ss") +(load "host/chez/natives-str.ss") ;; host class statics + constructors: host-static-ref/ ;; host-static-call/host-new + the jhost method registry. Loads LAST — it extends ;; record-method-dispatch (records.ss) and reuses natives-str helpers (str-trim, ;; ascii-string-down, re-split, str-split-drop-trailing) + the regex-t accessors. -(load "host/chez/java/host-static.ss") ; registries + jhost + coercion helpers -(load "host/chez/java/host-static-methods.ss") ; Class/member static methods + fields -(load "host/chez/java/host-static-classes.ss") ; instantiable host object classes -(load "host/chez/java/byte-buffer.ss") ; java.nio.ByteBuffer over a byte-array +(load "host/chez/host-static.ss") ; registries + jhost + coercion helpers +(load "host/chez/host-static-methods.ss") ; Class/member static methods + fields +(load "host/chez/host-static-classes.ss") ; instantiable host object classes ;; generic dot-form dispatch: field access + map/vector member access ;; for the `.` / `.-field` desugar. Loads after host-static.ss so it wraps every ;; record-method-dispatch arm (jhost/number/regex/jrec/string) and falls through. -(load "host/chez/java/dot-forms.ss") +(load "host/chez/dot-forms.ss") ;; java.io.File + host file I/O: path-backed jfile record, slurp/spit/ ;; flush, file-seq dir primitives, clojure.java.io/file. Loads LAST so its jfile ;; arm wraps the fully-built record-method-dispatch and the str/type/instance-check ;; extensions sit over every prior shim. -(load "host/chez/java/io.ss") +(load "host/chez/io.ss") ;; #inst values + java.time formatting: jinst (RFC3339 ms) + ;; DateTimeFormatter/Instant/ZoneId/LocalDateTime/FormatStyle/Locale/Date. Loads ;; LAST — it extends record-method-dispatch / jolt-get / jolt= / jolt-hash / ;; jolt-pr-str / jolt-type / instance-check and uses host-static.ss's registries. -(load "host/chez/java/inst-time.ss") +(load "host/chez/inst-time.ss") ;; java.time value types: LocalDate / LocalTime / LocalDateTime / Instant as ;; tz-free jhost values (epoch-day / nano-of-day / epoch-ms). Loads after ;; inst-time.ss — it reuses its civil<->days helpers, the jhost registries, and ;; re-registers a few LocalDateTime/Instant statics to use the richer reps. -(load "host/chez/java/java-time.ss") +(load "host/chez/java-time.ss") ;; Chez-side data reader: read-string / __parse-next / ;; __read-tagged. Loads after inst-time.ss — __read-tagged reuses its #uuid/#inst @@ -590,7 +364,7 @@ ;; clojure.math: native flonum-math shims def-var!'d into the ;; clojure.math ns. Self-contained (only def-var! + Chez math), order-independent. -(load "host/chez/java/math.ss") +(load "host/chez/math.ss") ;; reader/macro runtime support: #?() feature set, reader-conditional + re-matcher ;; tagged-map ctors, macroexpand. After ns.ss; macroexpand call-time-refs the macro @@ -600,17 +374,17 @@ ;; Java-style arrays: object/typed array constructors + a jolt-array ;; backing; extends count/nth/seq/get/ref-put! so the overlay aget/aset/alength see ;; it. After the dispatchers it chains. -(load "host/chez/java/natives-array.ss") +(load "host/chez/natives-array.ss") ;; java.io byte/char streams (FileInputStream/…/ByteArrayOutputStream/Buffered*) ;; over Chez ports. After io.ss (extends its slurp/__close/reader-jhost?) and ;; natives-array.ss (the byte-array <-> bytevector bridge). -(load "host/chez/java/io-streams.ss") +(load "host/chez/io-streams.ss") ;; clojure.lang.PersistentQueue: a functional queue + EMPTY static. ;; Chains seq/count/empty?/peek/pop/conj/sequential?/class/instance?/printer, so ;; load after natives-array (the dispatchers it extends). -(load "host/chez/java/natives-queue.ss") +(load "host/chez/natives-queue.ss") ;; syntax-quote form builders: __sqcat/__sqvec/__sqmap/__sqset/ ;; __sq1, def-var!'d into clojure.core. A cross-compiled macro expander (analyzer @@ -622,18 +396,14 @@ ;; (JVM) semantics. Loaded LAST — chains the fully-built jolt-deref and conveys the ;; thread-local binding stack (dyn-binding.ss) into workers. pmap/pcalls/pvalues ;; (overlay, over `future`) light up once future-call exists here. -(load "host/chez/java/concurrency.ss") +(load "host/chez/concurrency.ss") ;; clojure.core.async: real-thread blocking channels + go/go-loop/ ;; thread macros, def-var!'d into clojure.core.async. After concurrency.ss (reuses ;; ms->duration) and the collection/seq layer. -(load "host/chez/java/async.ss") +(load "host/chez/async.ss") ;; BigDecimal: the jbigdec value type + bigdec/decimal?/class/equality/ ;; printing. Loads LAST so its set!-wraps of jolt-class/jolt=2/the printers sit ;; outermost over every earlier extension. -(load "host/chez/java/bigdec.ss") - -;; Native stack traces: jv$ns$name -> source registry + continuation frame walk + -;; uncaught-throwable renderer. After the printers/equality it relies on. -(load "host/chez/source-registry.ss") +(load "host/chez/bigdec.ss") diff --git a/host/chez/run-corpus.ss b/host/chez/run-corpus.ss index 4dbad37..d581f0b 100644 --- a/host/chez/run-corpus.ss +++ b/host/chez/run-corpus.ss @@ -11,7 +11,7 @@ ;; reset between cases so there is no leakage — same isolation a fresh process gives. ;; ;; chez --script host/chez/run-corpus.ss -;; JOLT_CHEZ_ZJ_FLOOR=N override the regression floor (default 3390) +;; JOLT_CHEZ_ZJ_FLOOR=N override the regression floor (default 2730) ;; JOLT_CORPUS_LIMIT=N every-Nth stride (fast iteration; floor drops to 0) ;; JOLT_DUMP_CRASH_LABELS=1 list crash + allowlisted labels (import (chezscheme)) @@ -196,7 +196,7 @@ ;; Regression floor: fail on any NEW divergence or if pass drops below the floor. (define base-floor (let ((s (getenv "JOLT_CHEZ_ZJ_FLOOR"))) - (if s (string->number s) 3390))) + (if s (string->number s) 2730))) (define floor (if limit 0 base-floor)) (when (or (> (length diverged) 0) (< pass floor)) (printf "REGRESSION: pass ~a < floor ~a or ~a new divergence(s)\n" diff --git a/host/chez/run-devirt.ss b/host/chez/run-devirt.ss deleted file mode 100644 index 82fc185..0000000 --- a/host/chez/run-devirt.ss +++ /dev/null @@ -1,104 +0,0 @@ -;; run-devirt.ss — protocol-call devirtualization gate (backend_scheme emit). -;; -;; The inference annotates a monomorphic protocol call with :devirt-type/-proto/ -;; -method (jolt.passes.types); the back end then resolves the impl by that static -;; tag. This gate pins both halves: the emitted form uses find-protocol-method, and -;; evaluating it returns the same value the ordinary dispatch would — for a record's -;; inline impl, an extend-type impl, and across distinct receiver types. -;; -;; chez --script host/chez/run-devirt.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define emit (var-deref "jolt.backend-scheme" "emit")) -(define kw (lambda (n) (keyword #f n))) - -(define (evals src) (jolt-compile-eval (string-append "(do " src ")") "user")) -;; define two record types implementing one protocol — Circle via an inline impl, -;; Square via extend-type — plus instances to dispatch on. -(evals "(defprotocol Shape (area [s]))") -(evals "(defrecord Circle [r] Shape (area [s] (:r s)))") -(evals "(defrecord Square [w])") -(evals "(extend-type Square Shape (area [s] (* (:w s) (:w s))))") -(evals "(def c (->Circle 7))") -(evals "(def sq (->Square 5))") - -;; analyze (area RECV), annotate it as a devirt call on `type`, and emit. RECV is a -;; var name (c/sq) the emitted code resolves at eval time. -(define (devirt-emit type recv) - (let* ((ir (analyze (make-analyze-ctx "user") (jolt-ce-read (string-append "(area " recv ")")))) - (dv (jolt-assoc ir (kw "devirt-type") type (kw "devirt-proto") "Shape" - (kw "devirt-method") "area"))) - (emit dv))) - -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) -(define (has-sub? s sub) - (let ((n (string-length s)) (m (string-length sub))) - (let loop ((i 0)) (cond ((> (+ i m) n) #f) - ((string=? (substring s i (+ i m)) sub) #t) - (else (loop (+ i 1))))))) -;; eval an emitted Scheme string in the loaded runtime (var-deref resolves c/sq). -(define (run-emit scm) (eval (read (open-input-string scm)) (interaction-environment))) - -(let ((e (devirt-emit "user.Circle" "c"))) - (check "emit uses devirt-resolve" (has-sub? e "devirt-resolve") #t) - (check "devirt inline impl == dispatch" (run-emit e) (evals "(area c)"))) ; 7 - -(let ((e (devirt-emit "user.Square" "sq"))) - (check "devirt extend-type impl == dispatch" (run-emit e) (evals "(area sq)"))) ; 25 - -;; a normal (no devirt) call still goes through dispatch and agrees — the path the -;; megamorphic / unknown-receiver site keeps. -(let ((e (emit (analyze (make-analyze-ctx "user") (jolt-ce-read "(area c)"))))) - (check "non-devirt path no devirt-resolve" (has-sub? e "devirt-resolve") #f) - (check "non-devirt still dispatches" (run-emit e) 7)) - -;; a record that relies on the protocol's Object default (no direct impl): the -;; inference still types it as a concrete record and annotates devirt, so the -;; emitted call must resolve the same value dispatch would. find-protocol-method -;; on the record's own tag misses here, so the devirt path has to fall back to -;; ordinary dispatch (else it applies #f and crashes). -(evals "(extend-protocol Shape Object (area [s] :obj-default))") -(evals "(defrecord Plain [n])") -(evals "(def pl (->Plain 9))") -(let ((e (devirt-emit "user.Plain" "pl"))) - (check "devirt Object-default == dispatch" (run-emit e) (evals "(area pl)"))) ; :obj-default - -;; in a direct-link build a devirt site caches the resolved impl in a per-site cell -;; (resolved once, reused) instead of resolving per call. Annotate the (area x) in a -;; def body and emit the top form; the result must carry the cell and still be right. -(let* ((set-direct-link! (var-deref "jolt.backend-scheme" "set-direct-link!")) - (emit-top-form (var-deref "jolt.backend-scheme" "emit-top-form")) - (dn (analyze (make-analyze-ctx "user") (jolt-ce-read "(def usearea (fn [x] (area x)))"))) - (ar0 (jolt-nth (jolt-get (jolt-get dn (kw "init")) (kw "arities")) 0)) - (inv (jolt-get ar0 (kw "body"))) - (inv2 (jolt-assoc inv (kw "devirt-type") "user.Circle" (kw "devirt-proto") "Shape" (kw "devirt-method") "area")) - (dn2 (jolt-assoc dn (kw "init") - (jolt-assoc (jolt-get dn (kw "init")) (kw "arities") - (jolt-vector (jolt-assoc ar0 (kw "body") inv2)))))) - (set-direct-link! #t) - (let ((e (emit-top-form dn2))) - (set-direct-link! #f) - (check "devirt in a def caches in a per-site cell" (has-sub? e "_dvc$") #t) - (check "cached cell still resolves the impl" (has-sub? e "devirt-resolve") #t) - ;; eval the def, then call it: caches on first call, reuses after — still 7. - (run-emit e) - (check "cached devirt == dispatch (1st call)" (jolt-invoke (var-deref "user" "usearea") (var-deref "user" "c")) 7) - (check "cached devirt == dispatch (2nd call, from cell)" (jolt-invoke (var-deref "user" "usearea") (var-deref "user" "c")) 7))) - -(if (= fails 0) - (begin (printf "devirt gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "devirt gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-fieldnum.ss b/host/chez/run-fieldnum.ss deleted file mode 100644 index 567b5c3..0000000 --- a/host/chez/run-fieldnum.ss +++ /dev/null @@ -1,82 +0,0 @@ -;; run-fieldnum.ss — ^double record field reads unbox to fl-ops (jolt-evr9 R2). -;; -;; A record field tagged ^double reads back as a flonum (:double in the lattice), -;; so hintless arithmetic over those fields — (* (:x a) (:x b)) — lowers to fl-ops, -;; the same machinery as a ^double param. Two halves pinned here: (1) the ctor -;; coerces a ^double field to a flonum at construction (JVM parity, and what makes -;; the fl-op sound), and (2) field-field arithmetic over a record param (typed by -;; the whole-program fixpoint) emits fl*. -;; -;; chez --script host/chez/run-fieldnum.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define set-protocol-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define run-passes (var-deref "jolt.passes" "run-passes")) -(define emit (var-deref "jolt.backend-scheme" "emit")) - -(define (anode src) (analyze (make-analyze-ctx "user") (jolt-ce-read src))) -(define (evals src) (jolt-compile-eval (string-append "(do " src ")") "user")) -(define (contains-sub? s sub) - (let ((n (string-length s)) (m (string-length sub))) - (let loop ((i 0)) - (cond ((> (+ i m) n) #f) - ((string=? (substring s i (+ i m)) sub) #t) - (else (loop (+ i 1))))))) - -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -;; a record with ^double fields; the ctor must coerce an integer arg to a flonum. -(evals "(defrecord V [^double x ^double y])") -(check "ctor coerces ^double field to flonum" (flonum? (evals "(:x (->V 1 2))")) #t) -(check "coerced field value matches" (evals "(:x (->V 1 2))") 1.0) -(check "a flonum arg passes through" (evals "(:y (->V 1.5 2.5))") 2.5) - -;; dot is hintless; its caller passes V instances, so the fixpoint types a/b as V -;; records, the ^double fields read :double, and the field-field arithmetic unboxes. -(define dot (anode "(def dot (fn [a b] (+ (* (:x a) (:x b)) (* (:y a) (:y b)))))")) -(define used (anode "(def used (fn [] (dot (->V 1.0 2.0) (->V 3.0 4.0))))")) -(set-record-shapes! (chez-record-shapes-map)) -(set-protocol-methods! (jolt-hash-map)) -(wp-infer! (jolt-vector dot used)) -(set-optimize! #t) -(define dot-emit (emit (run-passes dot (make-analyze-ctx "user")))) -(check "field-field arithmetic unboxes to fl*" (contains-sub? dot-emit "fl*") #t) -(check "field-field arithmetic unboxes to fl+" (contains-sub? dot-emit "fl+") #t) - -;; a ^V param hint types the param with no inferable caller (open-world / cross-fn: -;; the receiver isn't a ctor return). This is the record-ctor-key path — without it -;; the hint is dead and the reads fall back to generic jolt-get + boxed arithmetic. -(define hinted (anode "(def hyp (fn [^V v] (+ (* (:x v) (:x v)) (* (:y v) (:y v)))))")) -(define hint-emit (emit (run-passes hinted (make-analyze-ctx "user")))) -(check "^V param hint bare-indexes field reads" (contains-sub? hint-emit "jrec-field-at") #t) -(check "^V param hint unboxes arithmetic" (contains-sub? hint-emit "fl*") #t) -(check "^V param hint leaves no generic jolt-get" (contains-sub? hint-emit "jolt-get") #f) - -;; an UNTAGGED field stays generic — no fl-op (the read is :any, not :double). -(evals "(defrecord W [p q])") -(define dotw (anode "(def dotw (fn [a b] (* (:p a) (:p b))))")) -(define usew (anode "(def usew (fn [] (dotw (->W 1.0 2.0) (->W 3.0 4.0))))")) -(set-record-shapes! (chez-record-shapes-map)) -(wp-infer! (jolt-vector dotw usew)) -(check "untagged field stays generic (no fl*)" - (contains-sub? (emit (run-passes dotw (make-analyze-ctx "user"))) "fl*") #f) - -(if (= fails 0) - (begin (printf "fieldnum gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "fieldnum gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-fieldread.ss b/host/chez/run-fieldread.ss deleted file mode 100644 index c09b58d..0000000 --- a/host/chez/run-fieldread.ss +++ /dev/null @@ -1,72 +0,0 @@ -;; run-fieldread.ss — native record field-read gate (backend_scheme emit). -;; -;; When the inference types a keyword-lookup receiver as a record (it carries the -;; field-order :shape + :hint :struct), the back end reads the field by its static -;; slot via jrec-field-at instead of jolt-get. This gate pins the emit shape and -;; that the value matches jolt-get — for a declared field, a non-field key (no -;; bare path), and a default-arg form (no bare path). -;; -;; chez --script host/chez/run-fieldread.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define emit (var-deref "jolt.backend-scheme" "emit")) -(define kw (lambda (n) (keyword #f n))) -(define (evals src) (jolt-compile-eval (string-append "(do " src ")") "user")) - -(evals "(defrecord Vec3 [x y z])") -(evals "(def a (->Vec3 10 20 30))") - -;; emit (:KEY a [default]) with arg 0 marked as a Vec3 struct receiver. -(define (mark-emit src) - (let* ((ir (analyze (make-analyze-ctx "user") (jolt-ce-read src))) - (a0 (jolt-nth (jolt-get ir (kw "args")) 0)) - (marked (jolt-assoc a0 (kw "hint") (kw "struct") - (kw "shape") (jolt-vector (kw "x") (kw "y") (kw "z")))) - (args (jolt-get ir (kw "args"))) - (args2 (jolt-assoc args 0 marked))) - (emit (jolt-assoc ir (kw "args") args2)))) - -(define (run-emit scm) (eval (read (open-input-string scm)) (interaction-environment))) -(define (has-sub? s sub) - (let ((n (string-length s)) (m (string-length sub))) - (let loop ((i 0)) (cond ((> (+ i m) n) #f) - ((string=? (substring s i (+ i m)) sub) #t) - (else (loop (+ i 1))))))) -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -;; a declared field -> bare-index path, value matches jolt-get -(let ((e (mark-emit "(:y a)"))) - (check "declared field uses jrec-field-at" (has-sub? e "jrec-field-at") #t) - (check "field 1 -> static slot 1" (has-sub? e " 1 ") #t) - (check "bare read == jolt-get" (run-emit e) (evals "(:y a)"))) ; 20 - -;; first/last fields too -(check "field x == jolt-get" (run-emit (mark-emit "(:x a)")) (evals "(:x a)")) ; 10 -(check "field z == jolt-get" (run-emit (mark-emit "(:z a)")) (evals "(:z a)")) ; 30 - -;; a key that is NOT a declared field -> no bare path, still correct (nil) -(let ((e (mark-emit "(:w a)"))) - (check "non-field key no jrec-field-at" (has-sub? e "jrec-field-at") #f) - (check "non-field key == jolt-get" (run-emit e) (evals "(:w a)"))) ; nil - -;; a default-arg form keeps jolt-get (the bare path is no-default only) -(let ((e (mark-emit "(:y a 99)"))) - (check "default-arg keeps jolt-get" (has-sub? e "jrec-field-at") #f)) - -(if (= fails 0) - (begin (printf "fieldread gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "fieldread gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-narrow.ss b/host/chez/run-narrow.ss deleted file mode 100644 index cb3c3d7..0000000 --- a/host/chez/run-narrow.ss +++ /dev/null @@ -1,76 +0,0 @@ -;; run-narrow.ss — nilable record types + flow-sensitive some?/nil? narrowing. -;; -;; A protocol method (or `if`) returning a record-or-nil types as a NILABLE record: -;; some?/nil? do NOT fold on it (it might be nil), so a runtime guard stays. Inside -;; (if (some? x) ..) / (if x ..) the then-branch narrows x to the non-nil record, so -;; its field reads bare-index and unbox. This is the ray tracer's -;; (let [scattered (scatter ..)] (if (some? scattered) (.. (:ray scattered) ..))). -;; -;; The load-bearing soundness check: the nil case must still take the else branch — -;; narrowing must NOT fold the guard away (else a real nil reaches the bare read). -;; -;; chez --script host/chez/run-narrow.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define set-protocol-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define run-passes (var-deref "jolt.passes" "run-passes")) -(define emit (var-deref "jolt.backend-scheme" "emit")) -(define (anode src) (analyze (make-analyze-ctx "user") (jolt-ce-read src))) -(define (evals src) (jolt-compile-eval (string-append "(do " src ")") "user")) -(define (built scm) (eval (read (open-input-string scm)) (interaction-environment))) -(define (sub? s t)(let((n(string-length s))(m(string-length t)))(let loop((i 0))(cond((>(+ i m)n)#f)((string=?(substring s i(+ i m))t)#t)(else(loop(+ i 1))))))) -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -(evals "(defrecord R [^double k])") -(evals "(defprotocol P (m [x]))") -(evals "(defrecord A [v] P (m [x] (->R 1.0)))") -(evals "(defrecord B [v] P (m [x] (if (< (:v x) 0) (->R 2.0) nil)))") ; B.m returns R-or-nil -(set-record-shapes! (chez-record-shapes-map)) -(set-protocol-methods! (chez-protocol-methods-map)) -(set-optimize! #t) -(define na (anode "(defrecord A [v] P (m [x] (->R 1.0)))")) -(define nb (anode "(defrecord B [v] P (m [x] (if (< (:v x) 0) (->R 2.0) nil)))")) -;; guarded read: inside (some? s), s narrows to non-nil R -> (:k s) bare-indexes + unboxes -(define f (anode "(def f (fn [a] (let [s (m a)] (if (some? s) (* (:k s) 2.0) 0.0))))")) -(wp-infer! (jolt-vector na nb f)) -(define fe (emit (run-passes f (make-analyze-ctx "user")))) -(check "guarded nullable read bare-indexes" (sub? fe "jrec-field-at") #t) -(check "guarded nullable read unboxes to fl*" (sub? fe "fl*") #t) - -;; CORRECTNESS + the load-bearing soundness check: the nil case must take the else -;; branch (the guard is preserved), not run the bare read on nil. -(built fe) -(define ff (var-deref "user" "f")) -(check "non-nil (A.m -> R 1.0)" (jolt-invoke ff (evals "(->A 5)")) 2.0) -(check "non-nil (B.m v<0 -> R 2.0)" (jolt-invoke ff (evals "(->B -5)")) 4.0) -(check "nil case takes else (guard preserved, no crash)" - (jolt-invoke ff (evals "(->B 5)")) 0.0) - -;; an UNGUARDED nullable read must stay safe: jrec-field-at falls back to jolt-get on -;; nil. (Its result type is conservative — no unbox — so this just checks no crash.) -(define g (anode "(def g (fn [a] (let [s (m a)] (:k s))))")) -(define ge (emit (run-passes g (make-analyze-ctx "user")))) -(built ge) -(define gg (var-deref "user" "g")) -(check "unguarded nullable read on nil returns nil" (jolt-nil? (jolt-invoke gg (evals "(->B 5)"))) #t) -(check "unguarded nullable read on non-nil returns the field" (jolt-invoke gg (evals "(->A 5)")) 1.0) - -(if (= fails 0) - (begin (printf "narrow gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "narrow gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-numwp.ss b/host/chez/run-numwp.ss deleted file mode 100644 index d2a7a0a..0000000 --- a/host/chez/run-numwp.ss +++ /dev/null @@ -1,108 +0,0 @@ -;; run-numwp.ss — hintless whole-program :double inference gate (jolt-evr9 R3). -;; -;; run-wp.ss drives the structural (record) fixpoint; this drives its numeric -;; refinement: a hintless fn whose every call site passes a flonum has its param -;; typed :double, which the back end then unboxes to fl-ops — no ^double hint. The -;; bridge is a synthetic [param :double] nhint (jolt.passes/inject-wp-nhints) that -;; the existing hint-directed pass + entry coercion consume unchanged. -;; -;; Soundness pinned here: :double only (never :long — an untyped integer can be a -;; bignum), so a caller passing an integer leaves the param generic; an escaped fn -;; keeps :any. -;; -;; chez --script host/chez/run-numwp.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define set-protocol-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define param-num-seeds-for (var-deref "jolt.passes.types" "param-num-seeds-for")) -(define inject-wp-nhints (var-deref "jolt.passes" "inject-wp-nhints")) -(define annotate (var-deref "jolt.passes.numeric" "annotate")) -(define run-passes (var-deref "jolt.passes" "run-passes")) -(define emit (var-deref "jolt.backend-scheme" "emit")) -(define pr-str (var-deref "clojure.core" "pr-str")) - -(define (anode src) (analyze (make-analyze-ctx "user") (jolt-ce-read src))) -(define (contains-sub? s sub) - (let ((n (string-length s)) (m (string-length sub))) - (let loop ((i 0)) - (cond ((> (+ i m) n) #f) - ((string=? (substring s i (+ i m)) sub) #t) - (else (loop (+ i 1))))))) - -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -(set-record-shapes! (jolt-hash-map)) -(set-protocol-methods! (jolt-hash-map)) - -;; sq is hintless; its only caller passes a flonum literal, so the fixpoint must -;; type x :double across the fn boundary. -(define sq (anode "(def sq (fn [x] (* x x)))")) -(define usef (anode "(def usef (fn [] (sq 2.0)))")) -(wp-infer! (jolt-vector sq usef)) - -(define nseed (param-num-seeds-for "user/sq")) -(check "sq has a numeric param seed" (jolt-truthy? nseed) #t) -(when (jolt-truthy? nseed) - (check "x seeded :double" (contains-sub? (pr-str nseed) ":double") #t)) - -;; the bridge: inject the derived nhint, run the numeric pass, emit -> fl*. -(define sq-opt (annotate (inject-wp-nhints sq))) -(check "sq body unboxes to fl*" (contains-sub? (emit sq-opt) "fl*") #t) -;; and the param is coerced at entry like a ^double param (no-op on a real flonum). -(check "sq coerces param at entry" (contains-sub? (emit sq-opt) "exact->inexact") #t) - -;; a caller passing an INTEGER must NOT make the param :double — an untyped integer -;; can be a bignum, so fl-ops would diverge. The param stays generic. -(define sqi (anode "(def sqi (fn [x] (* x x)))")) -(define usei (anode "(def usei (fn [] (sqi 2)))")) -(wp-infer! (jolt-vector sqi usei)) -(check "integer caller leaves param generic" - (jolt-truthy? (param-num-seeds-for "user/sqi")) #f) - -;; a fn used in value position (escapes) has unknown callers -> no double seed. -(define esc (anode "(def esc (fn [x] (* x x)))")) -(define hof (anode "(def hof (fn [g] (g 2.0)))")) -(define ecl (anode "(def ecaller (fn [] (hof esc)))")) ; esc escapes -(wp-infer! (jolt-vector esc hof ecl)) -(check "escaped fn keeps no double seed" - (jolt-truthy? (param-num-seeds-for "user/esc")) #f) - -;; :double flows through a returning helper: mag returns a flonum, so a param fed -;; only (mag _) results types :double too (cross-fn return propagation). -(define mag (anode "(def mag (fn [a] (* a 2.0)))")) -(define dist (anode "(def dist (fn [b] (+ b b)))")) -(define dcl (anode "(def dcaller (fn [] (dist (mag 3.0))))")) -(wp-infer! (jolt-vector mag dist dcl)) -(check "param fed a flonum-returning call types :double" - (jolt-truthy? (param-num-seeds-for "user/dist")) #t) - -;; end to end through the real build pipeline: with optimize on, run-passes wires -;; the WP fixpoint's :double seeds into the numeric pass (inject-wp-nhints) so the -;; emitted def unboxes — proves the production path fires, not just the bridge in -;; isolation. -(set-optimize! #t) -(define sq2 (anode "(def sq2 (fn [x] (* x x)))")) -(define use2 (anode "(def use2 (fn [] (sq2 4.0)))")) -(wp-infer! (jolt-vector sq2 use2)) -(check "run-passes unboxes a hintless double fn" - (contains-sub? (emit (run-passes sq2 (make-analyze-ctx "user"))) "fl*") #t) - -(if (= fails 0) - (begin (printf "numwp gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "numwp gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-protoret.ss b/host/chez/run-protoret.ss deleted file mode 100644 index 86485c7..0000000 --- a/host/chez/run-protoret.ss +++ /dev/null @@ -1,70 +0,0 @@ -;; run-protoret.ss — protocol-method return-type inference gate. -;; -;; A protocol method whose impls all return the same record type has a monomorphic -;; return: collect-pm-rets! joins the impl return types, and call-ret-type then types -;; a (method recv ..) call as that record — so a field read off the result bare- -;; indexes. This is the ray tracer's (:ray (scatter material ..)): scatter's impls -;; all return a ScatterResult, so the bounced ray types without a hint. -;; -;; chez --script host/chez/run-protoret.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define set-protocol-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define run-passes (var-deref "jolt.passes" "run-passes")) -(define emit (var-deref "jolt.backend-scheme" "emit")) -(define (anode src) (analyze (make-analyze-ctx "user") (jolt-ce-read src))) -(define (evals src) (jolt-compile-eval (string-append "(do " src ")") "user")) -(define (sub? s t)(let((n(string-length s))(m(string-length t)))(let loop((i 0))(cond((>(+ i m)n)#f)((string=?(substring s i(+ i m))t)#t)(else(loop(+ i 1))))))) - -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -(evals "(defrecord R [^double k])") -(evals "(defprotocol P (m [x]))") -(evals "(defrecord A [v] P (m [x] (->R 1.0)))") -(evals "(defrecord B [v] P (m [x] (->R 2.0)))") -(evals "(defprotocol Q (q [x]))") -(evals "(defrecord C [v] Q (q [x] (->R 3.0)))") -(evals "(defrecord D [v] Q (q [x] 7)))") ; one impl returns a number, not R -(set-record-shapes! (chez-record-shapes-map)) -(set-protocol-methods! (chez-protocol-methods-map)) -(set-optimize! #t) - -;; analyze the impl-registering forms + a consumer; the fixpoint collects the -;; impl return types. (the analyzed defrecord nodes carry register-inline-method.) -(define na (anode "(defrecord A [v] P (m [x] (->R 1.0)))")) -(define nb (anode "(defrecord B [v] P (m [x] (->R 2.0)))")) -(define nc (anode "(defrecord C [v] Q (q [x] (->R 3.0)))")) -(define nd (anode "(defrecord D [v] Q (q [x] 7))")) -(define f (anode "(def f (fn [a] (* (:k (m a)) 2.0)))")) -(define g (anode "(def g (fn [a] (:k (q a))))")) -(wp-infer! (jolt-vector na nb nc nd f g)) - -;; m's impls all return R -> (:k (m a)) reads off an R -> bare-index + unbox. -(define fe (emit (run-passes f (make-analyze-ctx "user")))) -(check "monomorphic protocol return bare-indexes the field read" (sub? fe "jrec-field-at") #t) -(check "monomorphic protocol return unboxes the ^double field" (sub? fe "fl") #t) - -;; q's impls return R and a number -> joined to non-record -> stays generic (sound). -(define ge (emit (run-passes g (make-analyze-ctx "user")))) -(check "mixed-return protocol keeps generic jolt-get" (sub? ge "jolt-get") #t) -(check "mixed-return protocol does not bare-index" (sub? ge "jrec-field-at") #f) - -(if (= fails 0) - (begin (printf "protoret gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "protoret gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/run-sci.ss b/host/chez/run-sci.ss index 700b234..1864174 100644 --- a/host/chez/run-sci.ss +++ b/host/chez/run-sci.ss @@ -1,11 +1,11 @@ ;; run-sci.ss — SCI conformance: load borkdude/sci's own source (vendor/sci) through ;; joltc and require its forms to compile+eval. A real-world Clojure-compatibility ;; stress test. Floor-gated like the corpus: a regression below -;; the floor (or the count today, 210/218) fails. Raise the floor as host gaps close +;; the floor (or the count today, 205/218) fails. Raise the floor as host gaps close ;; (the tail is genuine gaps — set! on vars, some macro/def shapes). ;; ;; chez --script host/chez/run-sci.ss -;; JOLT_SCI_FLOOR=N override the floor (default 210) +;; JOLT_SCI_FLOOR=N override the floor (default 205) ;; SCI_VERBOSE=1 print each failing form's error (import (chezscheme)) @@ -74,7 +74,7 @@ load-order) (printf "\nSCI load: ~a/~a forms ok (~a fail)\n" total-ok (+ total-ok total-fail) total-fail) -(define floor (let ((s (getenv "JOLT_SCI_FLOOR"))) (if s (string->number s) 210))) +(define floor (let ((s (getenv "JOLT_SCI_FLOOR"))) (if s (string->number s) 205))) (when (< total-ok floor) (printf "REGRESSION: ~a forms loaded < floor ~a\n" total-ok floor)) (flush-output-port) diff --git a/host/chez/run-wp.ss b/host/chez/run-wp.ss deleted file mode 100644 index 84fbf2b..0000000 --- a/host/chez/run-wp.ss +++ /dev/null @@ -1,108 +0,0 @@ -;; run-wp.ss — whole-program param-type fixpoint gate (jolt.passes.types/wp-infer!). -;; -;; run-infer.ss drives the per-form inference; this drives the inter-procedural -;; driver: analyze a multi-def unit, run wp-infer!, and assert that a record type -;; flows across fn boundaries — a callee's param picks up its caller's ctor return -;; type, so a field read off it is marked for the bare-index back-end path. -;; -;; chez --script host/chez/run-wp.ss -(import (chezscheme)) -(load "host/chez/rt.ss") -(set-chez-ns! "clojure.core") -(load "host/chez/seed/prelude.ss") -(load "host/chez/post-prelude.ss") -(set-chez-ns! "user") -(load "host/chez/host-contract.ss") -(load "host/chez/seed/image.ss") -(load "host/chez/compile-eval.ss") - -(define analyze (var-deref "jolt.analyzer" "analyze")) -(define run-inference (var-deref "jolt.passes.types" "run-inference")) -(define set-record-shapes! (var-deref "jolt.passes.types" "set-record-shapes!")) -(define set-protocol-methods! (var-deref "jolt.passes.types" "set-protocol-methods!")) -(define wp-infer! (var-deref "jolt.passes.types" "wp-infer!")) -(define param-seeds-for (var-deref "jolt.passes.types" "param-seeds-for")) -(define reinfer-def (var-deref "jolt.passes.types" "reinfer-def")) -(define pr-str (var-deref "clojure.core" "pr-str")) - -(define (anode src) (analyze (make-analyze-ctx "user") (jolt-ce-read src))) -(define (contains-sub? s sub) - (let ((n (string-length s)) (m (string-length sub))) - (let loop ((i 0)) - (cond ((> (+ i m) n) #f) - ((string=? (substring s i (+ i m)) sub) #t) - (else (loop (+ i 1))))))) - -(define fails 0) (define total 0) -(define (check label actual expected) - (set! total (+ total 1)) - (unless (equal? actual expected) - (set! fails (+ fails 1)) - (printf " FAIL ~a: got ~s expected ~s\n" label actual expected))) - -;; Node record shape (left/right untagged), like binary-trees. -(set-record-shapes! - (jolt-hash-map "user/->Node" - (jolt-hash-map (keyword #f "fields") (jolt-vector (keyword #f "left") (keyword #f "right")) - (keyword #f "tags") (jolt-vector jolt-nil jolt-nil) - (keyword #f "type") "user.Node"))) -(set-protocol-methods! (jolt-hash-map)) - -;; a 3-def unit: make-tree returns ->Node, run calls check-tree with a make-tree -;; result, so check-tree's `node` param must be inferred as a Node. -(define mt (anode "(def make-tree (fn [depth] (if (zero? depth) (->Node nil nil) (->Node (make-tree (dec depth)) (make-tree (dec depth))))))")) -(define ct (anode "(def check-tree (fn [node] (:left node)))")) -(define rn (anode "(def run (fn [d] (check-tree (make-tree d))))")) - -(wp-infer! (jolt-vector mt ct rn)) - -;; check-tree's param `node` should be seeded with a struct carrying the Node type -(define seed (param-seeds-for "user/check-tree")) -(check "check-tree has a param seed" (jolt-truthy? seed) #t) -(when (jolt-truthy? seed) - (check "node seeded as user.Node struct" - (contains-sub? (pr-str seed) "user.Node") #t)) - -;; reinfer-def then must mark the (:left node) read site for the bare-index path -(define marked (reinfer-def ct seed)) -(check "read site marked :hint :struct" (contains-sub? (pr-str marked) ":hint :struct") #t) - -;; a fn used only via value position (escape) must NOT be specialized — unknown -;; callers make a concrete seed unsound. -(define ev (anode "(def use-it (fn [f] (f 1)))")) -(define ec (anode "(def caller (fn [] (use-it check-tree)))")) ; check-tree escapes -(wp-infer! (jolt-vector mt ct rn ev ec)) -(check "escaped fn keeps no param seed" (jolt-truthy? (param-seeds-for "user/check-tree")) #f) - -;; a self-recursive fn that recurses on a NILABLE field (an untagged record field -;; is :any, so the child can be nil) must NOT be specialized — the recursion can -;; pass nil, so typing the param as a non-nil record would be unsound. -(define ctr (anode "(def walk (fn [node] (let [l (:left node)] (if (nil? l) 1 (walk l)))))")) -(define rnr (anode "(def run2 (fn [d] (walk (make-tree d))))")) -(wp-infer! (jolt-vector mt ctr rnr)) -(check "self-recursive nilable param not specialized" - (jolt-truthy? (param-seeds-for "user/walk")) #f) - -;; a self-recursive fn that recurses passing the SAME record type (make-tree always -;; returns a Node) is still safe to specialize — the recursion preserves the type. -(define mtt (anode "(def grow (fn [n acc] (if (zero? n) acc (grow (dec n) (->Node acc acc)))))")) -(define gcl (anode "(def gcaller (fn [] (grow 5 (->Node nil nil))))")) -(wp-infer! (jolt-vector mtt gcl)) -(check "self-recursive same-type param keeps its seed" - (jolt-truthy? (param-seeds-for "user/grow")) #t) - -;; a recursive fn that threads a param STRAIGHT THROUGH its recursion (same arg at -;; the same position) must keep that param's type — a pass-through self-call adds no -;; information and must not poison the param to :any. This is the ray tracer's -;; hittables, passed unchanged through ray-cast's recursion while its reduce element -;; reads the records' fields. -(define cwalk (anode "(def cwalk (fn [hs] (reduce (fn [acc h] (:left h)) nil hs)))")) -(define crec (anode "(def crec (fn [hs d] (if (< d 0) nil (do (cwalk hs) (crec hs (- d 1))))))")) -(define cdrv (anode "(def cdrive (fn [] (crec [(->Node nil nil) (->Node nil nil)] 5)))")) -(wp-infer! (jolt-vector cwalk crec cdrv)) -(check "recursion pass-through param keeps its vec element type" - (contains-sub? (pr-str (param-seeds-for "user/crec")) "user.Node") #t) - -(if (= fails 0) - (begin (printf "wp gate: ~a/~a passed\n" total total) (exit 0)) - (begin (printf "wp gate: ~a/~a passed (~a failed)\n" (- total fails) total fails) (exit 1))) diff --git a/host/chez/seed/image.ss b/host/chez/seed/image.ss index c51e971..f1cf205 100644 --- a/host/chez/seed/image.ss +++ b/host/chez/seed/image.ss @@ -1,636 +1,542 @@ (guard (e (#t #f)) - (def-var! "jolt.ir" "const" (letrec ((const (lambda (v) (let fnrec8455 ((v v)) (let* ((_o$8456 (keyword #f "op")) (_o$8457 (keyword #f "const")) (_o$8458 (keyword #f "val")) (_o$8459 v)) (jolt-hash-map _o$8456 _o$8457 _o$8458 _o$8459)))))) const))) + (def-var! "jolt.ir" "const" (letrec ((const (lambda (v) (let fnrec6782 ((v v)) (let* ((_o$6783 (keyword #f "op")) (_o$6784 (keyword #f "const")) (_o$6785 (keyword #f "val")) (_o$6786 v)) (jolt-hash-map _o$6783 _o$6784 _o$6785 _o$6786)))))) const))) (guard (e (#t #f)) - (def-var! "jolt.ir" "local" (letrec ((local (lambda (name) (let fnrec8460 ((name name)) (let* ((_o$8461 (keyword #f "op")) (_o$8462 (keyword #f "local")) (_o$8463 (keyword #f "name")) (_o$8464 name)) (jolt-hash-map _o$8461 _o$8462 _o$8463 _o$8464)))))) local))) + (def-var! "jolt.ir" "local" (letrec ((local (lambda (name) (let fnrec6787 ((name name)) (let* ((_o$6788 (keyword #f "op")) (_o$6789 (keyword #f "local")) (_o$6790 (keyword #f "name")) (_o$6791 name)) (jolt-hash-map _o$6788 _o$6789 _o$6790 _o$6791)))))) local))) (guard (e (#t #f)) - (def-var! "jolt.ir" "var-ref" (letrec ((var-ref (lambda (ns name) (let fnrec8465 ((ns ns) (name name)) (let* ((_o$8466 (keyword #f "op")) (_o$8467 (keyword #f "var")) (_o$8468 (keyword #f "ns")) (_o$8469 ns) (_o$8470 (keyword #f "name")) (_o$8471 name)) (jolt-hash-map _o$8466 _o$8467 _o$8468 _o$8469 _o$8470 _o$8471)))))) var-ref))) + (def-var! "jolt.ir" "var-ref" (letrec ((var-ref (lambda (ns name) (let fnrec6792 ((ns ns) (name name)) (let* ((_o$6793 (keyword #f "op")) (_o$6794 (keyword #f "var")) (_o$6795 (keyword #f "ns")) (_o$6796 ns) (_o$6797 (keyword #f "name")) (_o$6798 name)) (jolt-hash-map _o$6793 _o$6794 _o$6795 _o$6796 _o$6797 _o$6798)))))) var-ref))) (guard (e (#t #f)) - (def-var! "jolt.ir" "the-var" (letrec ((the-var (lambda (ns name) (let fnrec8472 ((ns ns) (name name)) (let* ((_o$8473 (keyword #f "op")) (_o$8474 (keyword #f "the-var")) (_o$8475 (keyword #f "ns")) (_o$8476 ns) (_o$8477 (keyword #f "name")) (_o$8478 name)) (jolt-hash-map _o$8473 _o$8474 _o$8475 _o$8476 _o$8477 _o$8478)))))) the-var))) + (def-var! "jolt.ir" "the-var" (letrec ((the-var (lambda (ns name) (let fnrec6799 ((ns ns) (name name)) (let* ((_o$6800 (keyword #f "op")) (_o$6801 (keyword #f "the-var")) (_o$6802 (keyword #f "ns")) (_o$6803 ns) (_o$6804 (keyword #f "name")) (_o$6805 name)) (jolt-hash-map _o$6800 _o$6801 _o$6802 _o$6803 _o$6804 _o$6805)))))) the-var))) (guard (e (#t #f)) - (def-var! "jolt.ir" "host-ref" (letrec ((host-ref (lambda (name) (let fnrec8479 ((name name)) (let* ((_o$8480 (keyword #f "op")) (_o$8481 (keyword #f "host")) (_o$8482 (keyword #f "name")) (_o$8483 name)) (jolt-hash-map _o$8480 _o$8481 _o$8482 _o$8483)))))) host-ref))) + (def-var! "jolt.ir" "host-ref" (letrec ((host-ref (lambda (name) (let fnrec6806 ((name name)) (let* ((_o$6807 (keyword #f "op")) (_o$6808 (keyword #f "host")) (_o$6809 (keyword #f "name")) (_o$6810 name)) (jolt-hash-map _o$6807 _o$6808 _o$6809 _o$6810)))))) host-ref))) (guard (e (#t #f)) - (def-var! "jolt.ir" "host-static" (letrec ((host-static (lambda (class member) (let fnrec8484 ((class class) (member member)) (let* ((_o$8485 (keyword #f "op")) (_o$8486 (keyword #f "host-static")) (_o$8487 (keyword #f "class")) (_o$8488 class) (_o$8489 (keyword #f "member")) (_o$8490 member)) (jolt-hash-map _o$8485 _o$8486 _o$8487 _o$8488 _o$8489 _o$8490)))))) host-static))) + (def-var! "jolt.ir" "host-static" (letrec ((host-static (lambda (class member) (let fnrec6811 ((class class) (member member)) (let* ((_o$6812 (keyword #f "op")) (_o$6813 (keyword #f "host-static")) (_o$6814 (keyword #f "class")) (_o$6815 class) (_o$6816 (keyword #f "member")) (_o$6817 member)) (jolt-hash-map _o$6812 _o$6813 _o$6814 _o$6815 _o$6816 _o$6817)))))) host-static))) (guard (e (#t #f)) - (def-var! "jolt.ir" "host-new" (letrec ((host-new (lambda (class args) (let fnrec8491 ((class class) (args args)) (let* ((_o$8492 (keyword #f "op")) (_o$8493 (keyword #f "host-new")) (_o$8494 (keyword #f "class")) (_o$8495 class) (_o$8496 (keyword #f "args")) (_o$8497 args)) (jolt-hash-map _o$8492 _o$8493 _o$8494 _o$8495 _o$8496 _o$8497)))))) host-new))) + (def-var! "jolt.ir" "host-new" (letrec ((host-new (lambda (class args) (let fnrec6818 ((class class) (args args)) (let* ((_o$6819 (keyword #f "op")) (_o$6820 (keyword #f "host-new")) (_o$6821 (keyword #f "class")) (_o$6822 class) (_o$6823 (keyword #f "args")) (_o$6824 args)) (jolt-hash-map _o$6819 _o$6820 _o$6821 _o$6822 _o$6823 _o$6824)))))) host-new))) (guard (e (#t #f)) - (def-var! "jolt.ir" "if-node" (letrec ((if-node (lambda (test then _else) (let fnrec8498 ((test test) (then then) (_else _else)) (let* ((_o$8499 (keyword #f "op")) (_o$8500 (keyword #f "if")) (_o$8501 (keyword #f "test")) (_o$8502 test) (_o$8503 (keyword #f "then")) (_o$8504 then) (_o$8505 (keyword #f "else")) (_o$8506 _else)) (jolt-hash-map _o$8499 _o$8500 _o$8501 _o$8502 _o$8503 _o$8504 _o$8505 _o$8506)))))) if-node))) + (def-var! "jolt.ir" "if-node" (letrec ((if-node (lambda (test then _else) (let fnrec6825 ((test test) (then then) (_else _else)) (let* ((_o$6826 (keyword #f "op")) (_o$6827 (keyword #f "if")) (_o$6828 (keyword #f "test")) (_o$6829 test) (_o$6830 (keyword #f "then")) (_o$6831 then) (_o$6832 (keyword #f "else")) (_o$6833 _else)) (jolt-hash-map _o$6826 _o$6827 _o$6828 _o$6829 _o$6830 _o$6831 _o$6832 _o$6833)))))) if-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "do-node" (letrec ((do-node (lambda (statements ret) (let fnrec8507 ((statements statements) (ret ret)) (let* ((_o$8508 (keyword #f "op")) (_o$8509 (keyword #f "do")) (_o$8510 (keyword #f "statements")) (_o$8511 statements) (_o$8512 (keyword #f "ret")) (_o$8513 ret)) (jolt-hash-map _o$8508 _o$8509 _o$8510 _o$8511 _o$8512 _o$8513)))))) do-node))) + (def-var! "jolt.ir" "do-node" (letrec ((do-node (lambda (statements ret) (let fnrec6834 ((statements statements) (ret ret)) (let* ((_o$6835 (keyword #f "op")) (_o$6836 (keyword #f "do")) (_o$6837 (keyword #f "statements")) (_o$6838 statements) (_o$6839 (keyword #f "ret")) (_o$6840 ret)) (jolt-hash-map _o$6835 _o$6836 _o$6837 _o$6838 _o$6839 _o$6840)))))) do-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "invoke" (letrec ((invoke (lambda (f args) (let fnrec8514 ((f f) (args args)) (let* ((_o$8515 (keyword #f "op")) (_o$8516 (keyword #f "invoke")) (_o$8517 (keyword #f "fn")) (_o$8518 f) (_o$8519 (keyword #f "args")) (_o$8520 args)) (jolt-hash-map _o$8515 _o$8516 _o$8517 _o$8518 _o$8519 _o$8520)))))) invoke))) + (def-var! "jolt.ir" "invoke" (letrec ((invoke (lambda (f args) (let fnrec6841 ((f f) (args args)) (let* ((_o$6842 (keyword #f "op")) (_o$6843 (keyword #f "invoke")) (_o$6844 (keyword #f "fn")) (_o$6845 f) (_o$6846 (keyword #f "args")) (_o$6847 args)) (jolt-hash-map _o$6842 _o$6843 _o$6844 _o$6845 _o$6846 _o$6847)))))) invoke))) (guard (e (#t #f)) - (def-var! "jolt.ir" "def-node" (letrec ((def-node (case-lambda ((ns name init) (let fnrec8521 ((ns ns) (name name) (init init)) (let* ((_o$8522 (keyword #f "op")) (_o$8523 (keyword #f "def")) (_o$8524 (keyword #f "ns")) (_o$8525 ns) (_o$8526 (keyword #f "name")) (_o$8527 name) (_o$8528 (keyword #f "init")) (_o$8529 init)) (jolt-hash-map _o$8522 _o$8523 _o$8524 _o$8525 _o$8526 _o$8527 _o$8528 _o$8529)))) ((ns name init meta) (let fnrec8530 ((ns ns) (name name) (init init) (meta meta)) (if (jolt-truthy? meta) (let* ((_o$8531 (keyword #f "op")) (_o$8532 (keyword #f "def")) (_o$8533 (keyword #f "ns")) (_o$8534 ns) (_o$8535 (keyword #f "name")) (_o$8536 name) (_o$8537 (keyword #f "init")) (_o$8538 init) (_o$8539 (keyword #f "meta")) (_o$8540 meta)) (jolt-hash-map _o$8531 _o$8532 _o$8533 _o$8534 _o$8535 _o$8536 _o$8537 _o$8538 _o$8539 _o$8540)) (let* ((_o$8541 (keyword #f "op")) (_o$8542 (keyword #f "def")) (_o$8543 (keyword #f "ns")) (_o$8544 ns) (_o$8545 (keyword #f "name")) (_o$8546 name) (_o$8547 (keyword #f "init")) (_o$8548 init)) (jolt-hash-map _o$8541 _o$8542 _o$8543 _o$8544 _o$8545 _o$8546 _o$8547 _o$8548)))))))) def-node))) + (def-var! "jolt.ir" "def-node" (letrec ((def-node (case-lambda ((ns name init) (let fnrec6848 ((ns ns) (name name) (init init)) (let* ((_o$6849 (keyword #f "op")) (_o$6850 (keyword #f "def")) (_o$6851 (keyword #f "ns")) (_o$6852 ns) (_o$6853 (keyword #f "name")) (_o$6854 name) (_o$6855 (keyword #f "init")) (_o$6856 init)) (jolt-hash-map _o$6849 _o$6850 _o$6851 _o$6852 _o$6853 _o$6854 _o$6855 _o$6856)))) ((ns name init meta) (let fnrec6857 ((ns ns) (name name) (init init) (meta meta)) (if (jolt-truthy? meta) (let* ((_o$6858 (keyword #f "op")) (_o$6859 (keyword #f "def")) (_o$6860 (keyword #f "ns")) (_o$6861 ns) (_o$6862 (keyword #f "name")) (_o$6863 name) (_o$6864 (keyword #f "init")) (_o$6865 init) (_o$6866 (keyword #f "meta")) (_o$6867 meta)) (jolt-hash-map _o$6858 _o$6859 _o$6860 _o$6861 _o$6862 _o$6863 _o$6864 _o$6865 _o$6866 _o$6867)) (let* ((_o$6868 (keyword #f "op")) (_o$6869 (keyword #f "def")) (_o$6870 (keyword #f "ns")) (_o$6871 ns) (_o$6872 (keyword #f "name")) (_o$6873 name) (_o$6874 (keyword #f "init")) (_o$6875 init)) (jolt-hash-map _o$6868 _o$6869 _o$6870 _o$6871 _o$6872 _o$6873 _o$6874 _o$6875)))))))) def-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "let-node" (letrec ((let-node (lambda (bindings body) (let fnrec8549 ((bindings bindings) (body body)) (let* ((_o$8550 (keyword #f "op")) (_o$8551 (keyword #f "let")) (_o$8552 (keyword #f "bindings")) (_o$8553 bindings) (_o$8554 (keyword #f "body")) (_o$8555 body)) (jolt-hash-map _o$8550 _o$8551 _o$8552 _o$8553 _o$8554 _o$8555)))))) let-node))) + (def-var! "jolt.ir" "let-node" (letrec ((let-node (lambda (bindings body) (let fnrec6876 ((bindings bindings) (body body)) (let* ((_o$6877 (keyword #f "op")) (_o$6878 (keyword #f "let")) (_o$6879 (keyword #f "bindings")) (_o$6880 bindings) (_o$6881 (keyword #f "body")) (_o$6882 body)) (jolt-hash-map _o$6877 _o$6878 _o$6879 _o$6880 _o$6881 _o$6882)))))) let-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "fn-node" (letrec ((fn-node (lambda (name arities) (let fnrec8556 ((name name) (arities arities)) (if (jolt-truthy? name) (let* ((_o$8557 (keyword #f "op")) (_o$8558 (keyword #f "fn")) (_o$8559 (keyword #f "name")) (_o$8560 name) (_o$8561 (keyword #f "arities")) (_o$8562 arities)) (jolt-hash-map _o$8557 _o$8558 _o$8559 _o$8560 _o$8561 _o$8562)) (let* ((_o$8563 (keyword #f "op")) (_o$8564 (keyword #f "fn")) (_o$8565 (keyword #f "arities")) (_o$8566 arities)) (jolt-hash-map _o$8563 _o$8564 _o$8565 _o$8566))))))) fn-node))) + (def-var! "jolt.ir" "fn-node" (letrec ((fn-node (lambda (name arities) (let fnrec6883 ((name name) (arities arities)) (if (jolt-truthy? name) (let* ((_o$6884 (keyword #f "op")) (_o$6885 (keyword #f "fn")) (_o$6886 (keyword #f "name")) (_o$6887 name) (_o$6888 (keyword #f "arities")) (_o$6889 arities)) (jolt-hash-map _o$6884 _o$6885 _o$6886 _o$6887 _o$6888 _o$6889)) (let* ((_o$6890 (keyword #f "op")) (_o$6891 (keyword #f "fn")) (_o$6892 (keyword #f "arities")) (_o$6893 arities)) (jolt-hash-map _o$6890 _o$6891 _o$6892 _o$6893))))))) fn-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "vector-node" (letrec ((vector-node (lambda (items) (let fnrec8567 ((items items)) (let* ((_o$8568 (keyword #f "op")) (_o$8569 (keyword #f "vector")) (_o$8570 (keyword #f "items")) (_o$8571 items)) (jolt-hash-map _o$8568 _o$8569 _o$8570 _o$8571)))))) vector-node))) + (def-var! "jolt.ir" "vector-node" (letrec ((vector-node (lambda (items) (let fnrec6894 ((items items)) (let* ((_o$6895 (keyword #f "op")) (_o$6896 (keyword #f "vector")) (_o$6897 (keyword #f "items")) (_o$6898 items)) (jolt-hash-map _o$6895 _o$6896 _o$6897 _o$6898)))))) vector-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "map-node" (letrec ((map-node (lambda (pairs) (let fnrec8572 ((pairs pairs)) (let* ((_o$8573 (keyword #f "op")) (_o$8574 (keyword #f "map")) (_o$8575 (keyword #f "pairs")) (_o$8576 pairs)) (jolt-hash-map _o$8573 _o$8574 _o$8575 _o$8576)))))) map-node))) + (def-var! "jolt.ir" "map-node" (letrec ((map-node (lambda (pairs) (let fnrec6899 ((pairs pairs)) (let* ((_o$6900 (keyword #f "op")) (_o$6901 (keyword #f "map")) (_o$6902 (keyword #f "pairs")) (_o$6903 pairs)) (jolt-hash-map _o$6900 _o$6901 _o$6902 _o$6903)))))) map-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "set-node" (letrec ((set-node (lambda (items) (let fnrec8577 ((items items)) (let* ((_o$8578 (keyword #f "op")) (_o$8579 (keyword #f "set")) (_o$8580 (keyword #f "items")) (_o$8581 items)) (jolt-hash-map _o$8578 _o$8579 _o$8580 _o$8581)))))) set-node))) + (def-var! "jolt.ir" "set-node" (letrec ((set-node (lambda (items) (let fnrec6904 ((items items)) (let* ((_o$6905 (keyword #f "op")) (_o$6906 (keyword #f "set")) (_o$6907 (keyword #f "items")) (_o$6908 items)) (jolt-hash-map _o$6905 _o$6906 _o$6907 _o$6908)))))) set-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "quote-node" (letrec ((quote-node (lambda (form) (let fnrec8582 ((form form)) (let* ((_o$8583 (keyword #f "op")) (_o$8584 (keyword #f "quote")) (_o$8585 (keyword #f "form")) (_o$8586 form)) (jolt-hash-map _o$8583 _o$8584 _o$8585 _o$8586)))))) quote-node))) + (def-var! "jolt.ir" "quote-node" (letrec ((quote-node (lambda (form) (let fnrec6909 ((form form)) (let* ((_o$6910 (keyword #f "op")) (_o$6911 (keyword #f "quote")) (_o$6912 (keyword #f "form")) (_o$6913 form)) (jolt-hash-map _o$6910 _o$6911 _o$6912 _o$6913)))))) quote-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "throw-node" (letrec ((throw-node (lambda (expr) (let fnrec8587 ((expr expr)) (let* ((_o$8588 (keyword #f "op")) (_o$8589 (keyword #f "throw")) (_o$8590 (keyword #f "expr")) (_o$8591 expr)) (jolt-hash-map _o$8588 _o$8589 _o$8590 _o$8591)))))) throw-node))) + (def-var! "jolt.ir" "throw-node" (letrec ((throw-node (lambda (expr) (let fnrec6914 ((expr expr)) (let* ((_o$6915 (keyword #f "op")) (_o$6916 (keyword #f "throw")) (_o$6917 (keyword #f "expr")) (_o$6918 expr)) (jolt-hash-map _o$6915 _o$6916 _o$6917 _o$6918)))))) throw-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "coerce-node" (letrec ((coerce-node (lambda (kind expr) (let fnrec8592 ((kind kind) (expr expr)) (let* ((_o$8593 (keyword #f "op")) (_o$8594 (keyword #f "coerce")) (_o$8595 (keyword #f "kind")) (_o$8596 kind) (_o$8597 (keyword #f "expr")) (_o$8598 expr)) (jolt-hash-map _o$8593 _o$8594 _o$8595 _o$8596 _o$8597 _o$8598)))))) coerce-node))) + (def-var! "jolt.ir" "coerce-node" (letrec ((coerce-node (lambda (kind expr) (let fnrec6919 ((kind kind) (expr expr)) (let* ((_o$6920 (keyword #f "op")) (_o$6921 (keyword #f "coerce")) (_o$6922 (keyword #f "kind")) (_o$6923 kind) (_o$6924 (keyword #f "expr")) (_o$6925 expr)) (jolt-hash-map _o$6920 _o$6921 _o$6922 _o$6923 _o$6924 _o$6925)))))) coerce-node))) (guard (e (#t #f)) - (def-var! "jolt.ir" "map-ir-children" (letrec ((map-ir-children (lambda (f node) (let fnrec8599 ((f f) (node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "if")) (let* ((_a$8600 node) (_a$8601 (keyword #f "test")) (_a$8602 (jolt-invoke f (jolt-get node (keyword #f "test")))) (_a$8603 (keyword #f "then")) (_a$8604 (jolt-invoke f (jolt-get node (keyword #f "then")))) (_a$8605 (keyword #f "else")) (_a$8606 (jolt-invoke f (jolt-get node (keyword #f "else"))))) (jolt-assoc _a$8600 _a$8601 _a$8602 _a$8603 _a$8604 _a$8605 _a$8606)) (if (jolt= op (keyword #f "do")) (let* ((_a$8607 node) (_a$8608 (keyword #f "statements")) (_a$8609 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "statements")))) (_a$8610 (keyword #f "ret")) (_a$8611 (jolt-invoke f (jolt-get node (keyword #f "ret"))))) (jolt-assoc _a$8607 _a$8608 _a$8609 _a$8610 _a$8611)) (if (jolt= op (keyword #f "throw")) (jolt-assoc node (keyword #f "expr") (jolt-invoke f (jolt-get node (keyword #f "expr")))) (if (jolt= op (keyword #f "coerce")) (jolt-assoc node (keyword #f "expr") (jolt-invoke f (jolt-get node (keyword #f "expr")))) (if (jolt= op (keyword #f "set-var")) (jolt-assoc node (keyword #f "val") (jolt-invoke f (jolt-get node (keyword #f "val")))) (if (jolt= op (keyword #f "set-field")) (let* ((_a$8612 node) (_a$8613 (keyword #f "obj")) (_a$8614 (jolt-invoke f (jolt-get node (keyword #f "obj")))) (_a$8615 (keyword #f "val")) (_a$8616 (jolt-invoke f (jolt-get node (keyword #f "val"))))) (jolt-assoc _a$8612 _a$8613 _a$8614 _a$8615 _a$8616)) (if (jolt= op (keyword #f "defmacro")) (jolt-assoc node (keyword #f "fn") (jolt-invoke f (jolt-get node (keyword #f "fn")))) (if (jolt= op (keyword #f "ffi-callable")) (jolt-assoc node (keyword #f "fn") (jolt-invoke f (jolt-get node (keyword #f "fn")))) (if (jolt= op (keyword #f "invoke")) (let* ((_a$8617 node) (_a$8618 (keyword #f "fn")) (_a$8619 (jolt-invoke f (jolt-get node (keyword #f "fn")))) (_a$8620 (keyword #f "args")) (_a$8621 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args"))))) (jolt-assoc _a$8617 _a$8618 _a$8619 _a$8620 _a$8621)) (if (jolt= op (keyword #f "vector")) (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "items")))) (if (jolt= op (keyword #f "set")) (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "items")))) (if (jolt= op (keyword #f "map")) (jolt-assoc node (keyword #f "pairs") (let* ((_a$8625 (var-deref "clojure.core" "mapv")) (_a$8626 (lambda (pr) (let fnrec8622 ((pr pr)) (let* ((_o$8623 (jolt-invoke f (jolt-nth pr 0))) (_o$8624 (jolt-invoke f (jolt-nth pr 1)))) (jolt-vector _o$8623 _o$8624))))) (_a$8627 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$8625 _a$8626 _a$8627))) (if (jolt= op (keyword #f "let")) (let* ((_a$8634 node) (_a$8635 (keyword #f "bindings")) (_a$8636 (let* ((_a$8631 (var-deref "clojure.core" "mapv")) (_a$8632 (lambda (b) (let fnrec8628 ((b b)) (let* ((_o$8629 (jolt-nth b 0)) (_o$8630 (jolt-invoke f (jolt-nth b 1)))) (jolt-vector _o$8629 _o$8630))))) (_a$8633 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$8631 _a$8632 _a$8633))) (_a$8637 (keyword #f "body")) (_a$8638 (jolt-invoke f (jolt-get node (keyword #f "body"))))) (jolt-assoc _a$8634 _a$8635 _a$8636 _a$8637 _a$8638)) (if (jolt= op (keyword #f "loop")) (let* ((_a$8645 node) (_a$8646 (keyword #f "bindings")) (_a$8647 (let* ((_a$8642 (var-deref "clojure.core" "mapv")) (_a$8643 (lambda (b) (let fnrec8639 ((b b)) (let* ((_o$8640 (jolt-nth b 0)) (_o$8641 (jolt-invoke f (jolt-nth b 1)))) (jolt-vector _o$8640 _o$8641))))) (_a$8644 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$8642 _a$8643 _a$8644))) (_a$8648 (keyword #f "body")) (_a$8649 (jolt-invoke f (jolt-get node (keyword #f "body"))))) (jolt-assoc _a$8645 _a$8646 _a$8647 _a$8648 _a$8649)) (if (jolt= op (keyword #f "recur")) (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args")))) (if (jolt= op (keyword #f "fn")) (jolt-assoc node (keyword #f "arities") (let* ((_a$8651 (var-deref "clojure.core" "mapv")) (_a$8652 (lambda (a) (let fnrec8650 ((a a)) (jolt-assoc a (keyword #f "body") (jolt-invoke f (jolt-get a (keyword #f "body"))))))) (_a$8653 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$8651 _a$8652 _a$8653))) (if (jolt= op (keyword #f "def")) (let* ((n (jolt-assoc node (keyword #f "init") (jolt-invoke f (jolt-get node (keyword #f "init")))))) (if (jolt-truthy? (jolt-get node (keyword #f "meta-expr"))) (jolt-assoc n (keyword #f "meta-expr") (jolt-invoke f (jolt-get node (keyword #f "meta-expr")))) n)) (if (jolt= op (keyword #f "host-call")) (let* ((_a$8654 node) (_a$8655 (keyword #f "target")) (_a$8656 (jolt-invoke f (jolt-get node (keyword #f "target")))) (_a$8657 (keyword #f "args")) (_a$8658 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args"))))) (jolt-assoc _a$8654 _a$8655 _a$8656 _a$8657 _a$8658)) (if (jolt= op (keyword #f "host-new")) (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args")))) (if (jolt= op (keyword #f "try")) (let* ((n (jolt-assoc node (keyword #f "body") (jolt-invoke f (jolt-get node (keyword #f "body"))))) (n (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-assoc n (keyword #f "catch-body") (jolt-invoke f (jolt-get node (keyword #f "catch-body")))) n)) (n (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-assoc n (keyword #f "finally") (jolt-invoke f (jolt-get node (keyword #f "finally")))) n))) n) (if (jolt-truthy? (keyword #f "else")) node jolt-nil)))))))))))))))))))))))))) map-ir-children))) + (def-var! "jolt.ir" "map-ir-children" (letrec ((map-ir-children (lambda (f node) (let fnrec6926 ((f f) (node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "if")) (let* ((_a$6927 node) (_a$6928 (keyword #f "test")) (_a$6929 (jolt-invoke f (jolt-get node (keyword #f "test")))) (_a$6930 (keyword #f "then")) (_a$6931 (jolt-invoke f (jolt-get node (keyword #f "then")))) (_a$6932 (keyword #f "else")) (_a$6933 (jolt-invoke f (jolt-get node (keyword #f "else"))))) (jolt-assoc _a$6927 _a$6928 _a$6929 _a$6930 _a$6931 _a$6932 _a$6933)) (if (jolt= op (keyword #f "do")) (let* ((_a$6934 node) (_a$6935 (keyword #f "statements")) (_a$6936 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "statements")))) (_a$6937 (keyword #f "ret")) (_a$6938 (jolt-invoke f (jolt-get node (keyword #f "ret"))))) (jolt-assoc _a$6934 _a$6935 _a$6936 _a$6937 _a$6938)) (if (jolt= op (keyword #f "throw")) (jolt-assoc node (keyword #f "expr") (jolt-invoke f (jolt-get node (keyword #f "expr")))) (if (jolt= op (keyword #f "coerce")) (jolt-assoc node (keyword #f "expr") (jolt-invoke f (jolt-get node (keyword #f "expr")))) (if (jolt= op (keyword #f "set-var")) (jolt-assoc node (keyword #f "val") (jolt-invoke f (jolt-get node (keyword #f "val")))) (if (jolt= op (keyword #f "set-field")) (let* ((_a$6939 node) (_a$6940 (keyword #f "obj")) (_a$6941 (jolt-invoke f (jolt-get node (keyword #f "obj")))) (_a$6942 (keyword #f "val")) (_a$6943 (jolt-invoke f (jolt-get node (keyword #f "val"))))) (jolt-assoc _a$6939 _a$6940 _a$6941 _a$6942 _a$6943)) (if (jolt= op (keyword #f "defmacro")) (jolt-assoc node (keyword #f "fn") (jolt-invoke f (jolt-get node (keyword #f "fn")))) (if (jolt= op (keyword #f "ffi-callable")) (jolt-assoc node (keyword #f "fn") (jolt-invoke f (jolt-get node (keyword #f "fn")))) (if (jolt= op (keyword #f "invoke")) (let* ((_a$6944 node) (_a$6945 (keyword #f "fn")) (_a$6946 (jolt-invoke f (jolt-get node (keyword #f "fn")))) (_a$6947 (keyword #f "args")) (_a$6948 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args"))))) (jolt-assoc _a$6944 _a$6945 _a$6946 _a$6947 _a$6948)) (if (jolt= op (keyword #f "vector")) (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "items")))) (if (jolt= op (keyword #f "set")) (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "items")))) (if (jolt= op (keyword #f "map")) (jolt-assoc node (keyword #f "pairs") (let* ((_a$6952 (var-deref "clojure.core" "mapv")) (_a$6953 (lambda (pr) (let fnrec6949 ((pr pr)) (let* ((_o$6950 (jolt-invoke f (jolt-nth pr 0))) (_o$6951 (jolt-invoke f (jolt-nth pr 1)))) (jolt-vector _o$6950 _o$6951))))) (_a$6954 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$6952 _a$6953 _a$6954))) (if (jolt= op (keyword #f "let")) (let* ((_a$6961 node) (_a$6962 (keyword #f "bindings")) (_a$6963 (let* ((_a$6958 (var-deref "clojure.core" "mapv")) (_a$6959 (lambda (b) (let fnrec6955 ((b b)) (let* ((_o$6956 (jolt-nth b 0)) (_o$6957 (jolt-invoke f (jolt-nth b 1)))) (jolt-vector _o$6956 _o$6957))))) (_a$6960 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$6958 _a$6959 _a$6960))) (_a$6964 (keyword #f "body")) (_a$6965 (jolt-invoke f (jolt-get node (keyword #f "body"))))) (jolt-assoc _a$6961 _a$6962 _a$6963 _a$6964 _a$6965)) (if (jolt= op (keyword #f "loop")) (let* ((_a$6972 node) (_a$6973 (keyword #f "bindings")) (_a$6974 (let* ((_a$6969 (var-deref "clojure.core" "mapv")) (_a$6970 (lambda (b) (let fnrec6966 ((b b)) (let* ((_o$6967 (jolt-nth b 0)) (_o$6968 (jolt-invoke f (jolt-nth b 1)))) (jolt-vector _o$6967 _o$6968))))) (_a$6971 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$6969 _a$6970 _a$6971))) (_a$6975 (keyword #f "body")) (_a$6976 (jolt-invoke f (jolt-get node (keyword #f "body"))))) (jolt-assoc _a$6972 _a$6973 _a$6974 _a$6975 _a$6976)) (if (jolt= op (keyword #f "recur")) (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args")))) (if (jolt= op (keyword #f "fn")) (jolt-assoc node (keyword #f "arities") (let* ((_a$6978 (var-deref "clojure.core" "mapv")) (_a$6979 (lambda (a) (let fnrec6977 ((a a)) (jolt-assoc a (keyword #f "body") (jolt-invoke f (jolt-get a (keyword #f "body"))))))) (_a$6980 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$6978 _a$6979 _a$6980))) (if (jolt= op (keyword #f "def")) (jolt-assoc node (keyword #f "init") (jolt-invoke f (jolt-get node (keyword #f "init")))) (if (jolt= op (keyword #f "host-call")) (let* ((_a$6981 node) (_a$6982 (keyword #f "target")) (_a$6983 (jolt-invoke f (jolt-get node (keyword #f "target")))) (_a$6984 (keyword #f "args")) (_a$6985 (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args"))))) (jolt-assoc _a$6981 _a$6982 _a$6983 _a$6984 _a$6985)) (if (jolt= op (keyword #f "host-new")) (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") f (jolt-get node (keyword #f "args")))) (if (jolt= op (keyword #f "try")) (let* ((n (jolt-assoc node (keyword #f "body") (jolt-invoke f (jolt-get node (keyword #f "body"))))) (n (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-assoc n (keyword #f "catch-body") (jolt-invoke f (jolt-get node (keyword #f "catch-body")))) n)) (n (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-assoc n (keyword #f "finally") (jolt-invoke f (jolt-get node (keyword #f "finally")))) n))) n) (if (jolt-truthy? (keyword #f "else")) node jolt-nil)))))))))))))))))))))))))) map-ir-children))) (guard (e (#t #f)) - (def-var! "jolt.ir" "reduce-ir-children" (letrec ((reduce-ir-children (lambda (f acc node) (let fnrec8659 ((f f) (acc acc) (node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "if")) (let* ((_a$8663 f) (_a$8664 (let* ((_a$8660 f) (_a$8661 (jolt-invoke f acc (jolt-get node (keyword #f "test")))) (_a$8662 (jolt-get node (keyword #f "then")))) (jolt-invoke _a$8660 _a$8661 _a$8662))) (_a$8665 (jolt-get node (keyword #f "else")))) (jolt-invoke _a$8663 _a$8664 _a$8665)) (if (jolt= op (keyword #f "do")) (let* ((_a$8666 f) (_a$8667 (jolt-reduce f acc (jolt-get node (keyword #f "statements")))) (_a$8668 (jolt-get node (keyword #f "ret")))) (jolt-invoke _a$8666 _a$8667 _a$8668)) (if (jolt= op (keyword #f "throw")) (jolt-invoke f acc (jolt-get node (keyword #f "expr"))) (if (jolt= op (keyword #f "coerce")) (jolt-invoke f acc (jolt-get node (keyword #f "expr"))) (if (jolt= op (keyword #f "set-var")) (jolt-invoke f acc (jolt-get node (keyword #f "val"))) (if (jolt= op (keyword #f "set-field")) (let* ((_a$8669 f) (_a$8670 (jolt-invoke f acc (jolt-get node (keyword #f "obj")))) (_a$8671 (jolt-get node (keyword #f "val")))) (jolt-invoke _a$8669 _a$8670 _a$8671)) (if (jolt= op (keyword #f "defmacro")) (jolt-invoke f acc (jolt-get node (keyword #f "fn"))) (if (jolt= op (keyword #f "ffi-callable")) (jolt-invoke f acc (jolt-get node (keyword #f "fn"))) (if (jolt= op (keyword #f "invoke")) (let* ((_a$8672 f) (_a$8673 (jolt-invoke f acc (jolt-get node (keyword #f "fn")))) (_a$8674 (jolt-get node (keyword #f "args")))) (jolt-reduce _a$8672 _a$8673 _a$8674)) (if (jolt= op (keyword #f "vector")) (jolt-reduce f acc (jolt-get node (keyword #f "items"))) (if (jolt= op (keyword #f "set")) (jolt-reduce f acc (jolt-get node (keyword #f "items"))) (if (jolt= op (keyword #f "map")) (let* ((_a$8679 (lambda (a pr) (let fnrec8675 ((a a) (pr pr)) (let* ((_a$8676 f) (_a$8677 (jolt-invoke f a (jolt-nth pr 0))) (_a$8678 (jolt-nth pr 1))) (jolt-invoke _a$8676 _a$8677 _a$8678))))) (_a$8680 acc) (_a$8681 (jolt-get node (keyword #f "pairs")))) (jolt-reduce _a$8679 _a$8680 _a$8681)) (if (jolt= op (keyword #f "let")) (let* ((_a$8686 f) (_a$8687 (let* ((_a$8683 (lambda (a b) (let fnrec8682 ((a a) (b b)) (jolt-invoke f a (jolt-nth b 1))))) (_a$8684 acc) (_a$8685 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$8683 _a$8684 _a$8685))) (_a$8688 (jolt-get node (keyword #f "body")))) (jolt-invoke _a$8686 _a$8687 _a$8688)) (if (jolt= op (keyword #f "loop")) (let* ((_a$8693 f) (_a$8694 (let* ((_a$8690 (lambda (a b) (let fnrec8689 ((a a) (b b)) (jolt-invoke f a (jolt-nth b 1))))) (_a$8691 acc) (_a$8692 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$8690 _a$8691 _a$8692))) (_a$8695 (jolt-get node (keyword #f "body")))) (jolt-invoke _a$8693 _a$8694 _a$8695)) (if (jolt= op (keyword #f "recur")) (jolt-reduce f acc (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "fn")) (let* ((_a$8697 (lambda (a ar) (let fnrec8696 ((a a) (ar ar)) (jolt-invoke f a (jolt-get ar (keyword #f "body")))))) (_a$8698 acc) (_a$8699 (jolt-get node (keyword #f "arities")))) (jolt-reduce _a$8697 _a$8698 _a$8699)) (if (jolt= op (keyword #f "def")) (let* ((a (if (jolt-truthy? (jolt-get node (keyword #f "init"))) (jolt-invoke f acc (jolt-get node (keyword #f "init"))) acc))) (if (jolt-truthy? (jolt-get node (keyword #f "meta-expr"))) (jolt-invoke f a (jolt-get node (keyword #f "meta-expr"))) a)) (if (jolt= op (keyword #f "host-call")) (let* ((_a$8700 f) (_a$8701 (jolt-invoke f acc (jolt-get node (keyword #f "target")))) (_a$8702 (jolt-get node (keyword #f "args")))) (jolt-reduce _a$8700 _a$8701 _a$8702)) (if (jolt= op (keyword #f "host-new")) (jolt-reduce f acc (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "try")) (let* ((a (jolt-invoke f acc (jolt-get node (keyword #f "body")))) (a (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-invoke f a (jolt-get node (keyword #f "catch-body"))) a)) (a (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-invoke f a (jolt-get node (keyword #f "finally"))) a))) a) (if (jolt-truthy? (keyword #f "else")) acc jolt-nil)))))))))))))))))))))))))) reduce-ir-children))) + (def-var! "jolt.ir" "reduce-ir-children" (letrec ((reduce-ir-children (lambda (f acc node) (let fnrec6986 ((f f) (acc acc) (node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "if")) (let* ((_a$6990 f) (_a$6991 (let* ((_a$6987 f) (_a$6988 (jolt-invoke f acc (jolt-get node (keyword #f "test")))) (_a$6989 (jolt-get node (keyword #f "then")))) (jolt-invoke _a$6987 _a$6988 _a$6989))) (_a$6992 (jolt-get node (keyword #f "else")))) (jolt-invoke _a$6990 _a$6991 _a$6992)) (if (jolt= op (keyword #f "do")) (let* ((_a$6993 f) (_a$6994 (jolt-reduce f acc (jolt-get node (keyword #f "statements")))) (_a$6995 (jolt-get node (keyword #f "ret")))) (jolt-invoke _a$6993 _a$6994 _a$6995)) (if (jolt= op (keyword #f "throw")) (jolt-invoke f acc (jolt-get node (keyword #f "expr"))) (if (jolt= op (keyword #f "coerce")) (jolt-invoke f acc (jolt-get node (keyword #f "expr"))) (if (jolt= op (keyword #f "set-var")) (jolt-invoke f acc (jolt-get node (keyword #f "val"))) (if (jolt= op (keyword #f "set-field")) (let* ((_a$6996 f) (_a$6997 (jolt-invoke f acc (jolt-get node (keyword #f "obj")))) (_a$6998 (jolt-get node (keyword #f "val")))) (jolt-invoke _a$6996 _a$6997 _a$6998)) (if (jolt= op (keyword #f "defmacro")) (jolt-invoke f acc (jolt-get node (keyword #f "fn"))) (if (jolt= op (keyword #f "ffi-callable")) (jolt-invoke f acc (jolt-get node (keyword #f "fn"))) (if (jolt= op (keyword #f "invoke")) (let* ((_a$6999 f) (_a$7000 (jolt-invoke f acc (jolt-get node (keyword #f "fn")))) (_a$7001 (jolt-get node (keyword #f "args")))) (jolt-reduce _a$6999 _a$7000 _a$7001)) (if (jolt= op (keyword #f "vector")) (jolt-reduce f acc (jolt-get node (keyword #f "items"))) (if (jolt= op (keyword #f "set")) (jolt-reduce f acc (jolt-get node (keyword #f "items"))) (if (jolt= op (keyword #f "map")) (let* ((_a$7006 (lambda (a pr) (let fnrec7002 ((a a) (pr pr)) (let* ((_a$7003 f) (_a$7004 (jolt-invoke f a (jolt-nth pr 0))) (_a$7005 (jolt-nth pr 1))) (jolt-invoke _a$7003 _a$7004 _a$7005))))) (_a$7007 acc) (_a$7008 (jolt-get node (keyword #f "pairs")))) (jolt-reduce _a$7006 _a$7007 _a$7008)) (if (jolt= op (keyword #f "let")) (let* ((_a$7013 f) (_a$7014 (let* ((_a$7010 (lambda (a b) (let fnrec7009 ((a a) (b b)) (jolt-invoke f a (jolt-nth b 1))))) (_a$7011 acc) (_a$7012 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$7010 _a$7011 _a$7012))) (_a$7015 (jolt-get node (keyword #f "body")))) (jolt-invoke _a$7013 _a$7014 _a$7015)) (if (jolt= op (keyword #f "loop")) (let* ((_a$7020 f) (_a$7021 (let* ((_a$7017 (lambda (a b) (let fnrec7016 ((a a) (b b)) (jolt-invoke f a (jolt-nth b 1))))) (_a$7018 acc) (_a$7019 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$7017 _a$7018 _a$7019))) (_a$7022 (jolt-get node (keyword #f "body")))) (jolt-invoke _a$7020 _a$7021 _a$7022)) (if (jolt= op (keyword #f "recur")) (jolt-reduce f acc (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "fn")) (let* ((_a$7024 (lambda (a ar) (let fnrec7023 ((a a) (ar ar)) (jolt-invoke f a (jolt-get ar (keyword #f "body")))))) (_a$7025 acc) (_a$7026 (jolt-get node (keyword #f "arities")))) (jolt-reduce _a$7024 _a$7025 _a$7026)) (if (jolt= op (keyword #f "def")) (if (jolt-truthy? (jolt-get node (keyword #f "init"))) (jolt-invoke f acc (jolt-get node (keyword #f "init"))) acc) (if (jolt= op (keyword #f "host-call")) (let* ((_a$7027 f) (_a$7028 (jolt-invoke f acc (jolt-get node (keyword #f "target")))) (_a$7029 (jolt-get node (keyword #f "args")))) (jolt-reduce _a$7027 _a$7028 _a$7029)) (if (jolt= op (keyword #f "host-new")) (jolt-reduce f acc (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "try")) (let* ((a (jolt-invoke f acc (jolt-get node (keyword #f "body")))) (a (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-invoke f a (jolt-get node (keyword #f "catch-body"))) a)) (a (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-invoke f a (jolt-get node (keyword #f "finally"))) a))) a) (if (jolt-truthy? (keyword #f "else")) acc jolt-nil)))))))))))))))))))))))))) reduce-ir-children))) (guard (e (#t #f)) (declare-var! "jolt.analyzer" "analyze")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "handled" (let* ((_o$8703 "quote") (_o$8704 "if") (_o$8705 "do") (_o$8706 "def") (_o$8707 "fn*") (_o$8708 "let*") (_o$8709 "loop*") (_o$8710 "recur") (_o$8711 "throw") (_o$8712 "try") (_o$8713 "syntax-quote") (_o$8714 "var") (_o$8715 "letfn*") (_o$8716 "set!") (_o$8717 "defmacro")) (jolt-hash-set _o$8703 _o$8704 _o$8705 _o$8706 _o$8707 _o$8708 _o$8709 _o$8710 _o$8711 _o$8712 _o$8713 _o$8714 _o$8715 _o$8716 _o$8717)) (let* ((_o$8718 (keyword #f "private")) (_o$8719 #t)) (jolt-hash-map _o$8718 _o$8719)))) + (def-var-with-meta! "jolt.analyzer" "handled" (let* ((_o$7030 "quote") (_o$7031 "if") (_o$7032 "do") (_o$7033 "def") (_o$7034 "fn*") (_o$7035 "let*") (_o$7036 "loop*") (_o$7037 "recur") (_o$7038 "throw") (_o$7039 "try") (_o$7040 "syntax-quote") (_o$7041 "var") (_o$7042 "letfn") (_o$7043 "set!") (_o$7044 "defmacro")) (jolt-hash-set _o$7030 _o$7031 _o$7032 _o$7033 _o$7034 _o$7035 _o$7036 _o$7037 _o$7038 _o$7039 _o$7040 _o$7041 _o$7042 _o$7043 _o$7044)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "uncompilable" (letrec ((uncompilable (lambda (why) (let fnrec8720 ((why why)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt/uncompilable: " why)))))) uncompilable) (let* ((_o$8721 (keyword #f "private")) (_o$8722 #t)) (jolt-hash-map _o$8721 _o$8722)))) + (def-var! "jolt.analyzer" "uncompilable" (letrec ((uncompilable (lambda (why) (let fnrec7045 ((why why)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt/uncompilable: " why)))))) uncompilable))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "gensym-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (let* ((_o$8723 (keyword #f "private")) (_o$8724 #t)) (jolt-hash-map _o$8723 _o$8724)))) + (def-var-with-meta! "jolt.analyzer" "gensym-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "gen-name" (letrec ((gen-name (lambda (prefix) (let fnrec8725 ((prefix prefix)) (let* ((n (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.analyzer" "gensym-counter")))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.analyzer" "gensym-counter") jolt-inc) (jolt-invoke (var-deref "clojure.core" "str") "_r$" prefix n))))))) gen-name) (let* ((_o$8726 (keyword #f "private")) (_o$8727 #t)) (jolt-hash-map _o$8726 _o$8727)))) + (def-var! "jolt.analyzer" "gen-name" (letrec ((gen-name (lambda (prefix) (let fnrec7046 ((prefix prefix)) (let* ((n (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.analyzer" "gensym-counter")))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.analyzer" "gensym-counter") jolt-inc) (jolt-invoke (var-deref "clojure.core" "str") "_r$" prefix n))))))) gen-name))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "empty-env" (letrec ((empty-env (lambda () (let fnrec8728 () (let* ((_o$8729 (keyword #f "locals")) (_o$8730 (jolt-hash-set)) (_o$8731 (keyword #f "hints")) (_o$8732 (jolt-hash-map))) (jolt-hash-map _o$8729 _o$8730 _o$8731 _o$8732)))))) empty-env) (let* ((_o$8733 (keyword #f "private")) (_o$8734 #t)) (jolt-hash-map _o$8733 _o$8734)))) + (def-var! "jolt.analyzer" "empty-env" (letrec ((empty-env (lambda () (let fnrec7047 () (let* ((_o$7048 (keyword #f "locals")) (_o$7049 (jolt-hash-set)) (_o$7050 (keyword #f "hints")) (_o$7051 (jolt-hash-map))) (jolt-hash-map _o$7048 _o$7049 _o$7050 _o$7051)))))) empty-env))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "local?" (letrec ((local? (lambda (env nm) (let fnrec8735 ((env env) (nm nm)) (jolt-contains? (jolt-get env (keyword #f "locals")) nm))))) local?) (let* ((_o$8736 (keyword #f "private")) (_o$8737 #t)) (jolt-hash-map _o$8736 _o$8737)))) + (def-var! "jolt.analyzer" "local?" (letrec ((local? (lambda (env nm) (let fnrec7052 ((env env) (nm nm)) (jolt-contains? (jolt-get env (keyword #f "locals")) nm))))) local?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "add-locals" (letrec ((add-locals (lambda (env names) (let fnrec8738 ((env env) (names names)) (jolt-invoke (var-deref "clojure.core" "update") env (keyword #f "locals") (lambda (p__97_) (let fnrec8739 ((p__97_ p__97_)) (jolt-reduce jolt-conj p__97_ names)))))))) add-locals) (let* ((_o$8740 (keyword #f "private")) (_o$8741 #t)) (jolt-hash-map _o$8740 _o$8741)))) + (def-var! "jolt.analyzer" "add-locals" (letrec ((add-locals (lambda (env names) (let fnrec7053 ((env env) (names names)) (jolt-invoke (var-deref "clojure.core" "update") env (keyword #f "locals") (lambda (p__85_) (let fnrec7054 ((p__85_ p__85_)) (jolt-reduce jolt-conj p__85_ names)))))))) add-locals))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "amp-env-map" (letrec ((amp-env-map (lambda (env) (let fnrec8742 ((env env)) (let* ((_a$8744 (lambda (m n) (let fnrec8743 ((m m) (n n)) (jolt-assoc m (jolt-invoke (var-deref "clojure.core" "symbol") n) jolt-nil)))) (_a$8745 (jolt-hash-map)) (_a$8746 (jolt-get env (keyword #f "locals")))) (jolt-reduce _a$8744 _a$8745 _a$8746)))))) amp-env-map) (let* ((_o$8747 (keyword #f "private")) (_o$8748 #t)) (jolt-hash-map _o$8747 _o$8748)))) + (def-var! "jolt.analyzer" "with-recur" (letrec ((with-recur (lambda (env name) (let fnrec7055 ((env env) (name name)) (jolt-assoc env (keyword #f "recur") name))))) with-recur))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "with-recur" (letrec ((with-recur (lambda (env name) (let fnrec8749 ((env env) (name name)) (jolt-assoc env (keyword #f "recur") name))))) with-recur) (let* ((_o$8750 (keyword #f "private")) (_o$8751 #t)) (jolt-hash-map _o$8750 _o$8751)))) + (def-var! "jolt.analyzer" "hint-of" (letrec ((hint-of (lambda (ctx sym) (let fnrec7056 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") m)) jolt-nil (if (jolt-truthy? (jolt-get m (keyword #f "struct"))) (keyword #f "struct") (if (jolt-truthy? (keyword #f "else")) (let* ((t (jolt-get m (keyword #f "tag")))) (if (jolt-truthy? (let* ((and__25__auto t)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "record-type?") ctx t) and__25__auto))) (keyword #f "struct") jolt-nil)) jolt-nil)))))))) hint-of))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "hint-of" (letrec ((hint-of (lambda (ctx sym) (let fnrec8752 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-nil? m) jolt-nil (if (jolt-truthy? (jolt-get m (keyword #f "struct"))) (keyword #f "struct") (if (jolt-truthy? (keyword #f "else")) (let* ((t (jolt-get m (keyword #f "tag")))) (if (jolt-truthy? (let* ((and__25__auto t)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "record-type?") ctx t) and__25__auto))) (keyword #f "struct") jolt-nil)) jolt-nil)))))))) hint-of) (let* ((_o$8753 (keyword #f "private")) (_o$8754 #t)) (jolt-hash-map _o$8753 _o$8754)))) + (def-var! "jolt.analyzer" "add-hint" (letrec ((add-hint (lambda (env nm h) (let fnrec7057 ((env env) (nm nm) (h h)) (if (jolt-truthy? h) (jolt-assoc env (keyword #f "hints") (jolt-assoc (jolt-get env (keyword #f "hints")) nm h)) env))))) add-hint))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "add-hint" (letrec ((add-hint (lambda (env nm h) (let fnrec8755 ((env env) (nm nm) (h h)) (if (jolt-truthy? h) (jolt-assoc env (keyword #f "hints") (jolt-assoc (jolt-get env (keyword #f "hints")) nm h)) env))))) add-hint) (let* ((_o$8756 (keyword #f "private")) (_o$8757 #t)) (jolt-hash-map _o$8756 _o$8757)))) + (def-var! "jolt.analyzer" "phint-of" (letrec ((phint-of (lambda (ctx sym) (let fnrec7058 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-truthy? m) (let* ((t (jolt-get m (keyword #f "tag")))) (if (jolt-truthy? t) (jolt-invoke (var-deref "jolt.host" "record-ctor-key") ctx t) jolt-nil)) jolt-nil)))))) phint-of))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "phint-of" (letrec ((phint-of (lambda (ctx sym) (let fnrec8758 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-truthy? m) (let* ((t (jolt-get m (keyword #f "tag")))) (if (jolt-truthy? t) (jolt-invoke (var-deref "jolt.host" "record-ctor-key") ctx t) jolt-nil)) jolt-nil)))))) phint-of) (let* ((_o$8759 (keyword #f "private")) (_o$8760 #t)) (jolt-hash-map _o$8759 _o$8760)))) + (def-var! "jolt.analyzer" "tag->nkind" (letrec ((tag->nkind (lambda (t) (let fnrec7059 ((t t)) (let* ((s (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") t)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") t) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") t)) t (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (if (jolt= s "double") (keyword #f "double") (if (jolt= s "long") (keyword #f "long") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))))) tag->nkind))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "tag->nkind" (letrec ((tag->nkind (lambda (t) (let fnrec8761 ((t t)) (let* ((s (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") t)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") t) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") t)) t (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (if (jolt= s "double") (keyword #f "double") (if (jolt= s "long") (keyword #f "long") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))))) tag->nkind) (let* ((_o$8762 (keyword #f "private")) (_o$8763 #t)) (jolt-hash-map _o$8762 _o$8763)))) + (def-var! "jolt.analyzer" "nhint-of" (letrec ((nhint-of (lambda (ctx sym) (let fnrec7060 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-truthy? m) (jolt-invoke (var-deref "jolt.analyzer" "tag->nkind") (jolt-get m (keyword #f "tag"))) jolt-nil)))))) nhint-of))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "nhint-of" (letrec ((nhint-of (lambda (ctx sym) (let fnrec8764 ((ctx ctx) (sym sym)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") sym))) (if (jolt-truthy? m) (jolt-invoke (var-deref "jolt.analyzer" "tag->nkind") (jolt-get m (keyword #f "tag"))) jolt-nil)))))) nhint-of) (let* ((_o$8765 (keyword #f "private")) (_o$8766 #t)) (jolt-hash-map _o$8765 _o$8766)))) + (def-var! "jolt.analyzer" "with-ret-nhint" (letrec ((with-ret-nhint (lambda (node kind) (let fnrec7061 ((node node) (kind kind)) (if (jolt-truthy? (let* ((and__25__auto kind)) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get node (keyword #f "op"))) and__25__auto))) (jolt-assoc node (keyword #f "arities") (let* ((_a$7063 (var-deref "clojure.core" "mapv")) (_a$7064 (lambda (a) (let fnrec7062 ((a a)) (if (jolt-truthy? (jolt-get a (keyword #f "ret-nhint"))) a (jolt-assoc a (keyword #f "ret-nhint") kind))))) (_a$7065 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$7063 _a$7064 _a$7065))) node))))) with-ret-nhint))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "with-ret-nhint" (letrec ((with-ret-nhint (lambda (node kind) (let fnrec8767 ((node node) (kind kind)) (if (jolt-truthy? (let* ((and__25__auto kind)) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get node (keyword #f "op"))) and__25__auto))) (jolt-assoc node (keyword #f "arities") (let* ((_a$8769 (var-deref "clojure.core" "mapv")) (_a$8770 (lambda (a) (let fnrec8768 ((a a)) (if (jolt-truthy? (jolt-get a (keyword #f "ret-nhint"))) a (jolt-assoc a (keyword #f "ret-nhint") kind))))) (_a$8771 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$8769 _a$8770 _a$8771))) node))))) with-ret-nhint) (let* ((_o$8772 (keyword #f "private")) (_o$8773 #t)) (jolt-hash-map _o$8772 _o$8773)))) + (def-var! "jolt.analyzer" "analyze-seq" (letrec ((analyze-seq (lambda (ctx forms env) (let fnrec7066 ((ctx ctx) (forms forms) (env env)) (let* ((v (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__86_) (let fnrec7067 ((p__86_ p__86_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__86_ env))) forms)) (n (jolt-count v))) (if (jolt-zero? n) (jolt-invoke (var-deref "jolt.ir" "const") jolt-nil) (if (jolt= 1 n) (jolt-first v) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$7068 (var-deref "jolt.ir" "do-node")) (_a$7069 (jolt-invoke (var-deref "clojure.core" "subvec") v 0 (jolt-dec n))) (_a$7070 (jolt-peek v))) (jolt-invoke _a$7068 _a$7069 _a$7070)) jolt-nil)))))))) analyze-seq))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-seq" (letrec ((analyze-seq (lambda (ctx forms env) (let fnrec8774 ((ctx ctx) (forms forms) (env env)) (let* ((v (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__98_) (let fnrec8775 ((p__98_ p__98_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__98_ env))) forms)) (n (jolt-count v))) (if (jolt-zero? n) (jolt-invoke (var-deref "jolt.ir" "const") jolt-nil) (if (jolt= 1 n) (jolt-first v) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$8776 (var-deref "jolt.ir" "do-node")) (_a$8777 (jolt-invoke (var-deref "clojure.core" "subvec") v 0 (jolt-dec n))) (_a$8778 (jolt-peek v))) (jolt-invoke _a$8776 _a$8777 _a$8778)) jolt-nil)))))))) analyze-seq) (let* ((_o$8779 (keyword #f "private")) (_o$8780 #t)) (jolt-hash-map _o$8779 _o$8780)))) + (def-var! "jolt.analyzer" "analyze-bindings" (letrec ((analyze-bindings (lambda (ctx bvec env) (let fnrec7071 ((ctx ctx) (bvec bvec) (env env)) (let* ((i 0) (env env) (pairs (jolt-vector))) (let loop7072 ((i i) (env env) (pairs pairs)) (if (< i (jolt-count bvec)) (let* ((bsym (jolt-nth bvec i))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") bsym)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring binding") jolt-nil) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") bsym)) (init (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth bvec (jolt-inc i)) env))) (let* ((_a$7079 (+ i 2)) (_a$7080 (let* ((_a$7073 (var-deref "jolt.analyzer" "add-hint")) (_a$7074 (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env (jolt-vector nm))) (_a$7075 nm) (_a$7076 (jolt-invoke (var-deref "jolt.analyzer" "hint-of") ctx bsym))) (jolt-invoke _a$7073 _a$7074 _a$7075 _a$7076))) (_a$7081 (jolt-conj pairs (let* ((_o$7077 nm) (_o$7078 init)) (jolt-vector _o$7077 _o$7078))))) (loop7072 _a$7079 _a$7080 _a$7081))))) (let* ((_o$7082 pairs) (_o$7083 env)) (jolt-vector _o$7082 _o$7083))))))))) analyze-bindings))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-bindings" (letrec ((analyze-bindings (lambda (ctx bvec env) (let fnrec8781 ((ctx ctx) (bvec bvec) (env env)) (let* ((i 0) (env env) (pairs (jolt-vector))) (let loop8782 ((i i) (env env) (pairs pairs)) (if (jolt-n< i (jolt-count bvec)) (let* ((bsym (jolt-nth bvec i))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") bsym)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring binding") jolt-nil) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") bsym)) (init (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth bvec (jolt-inc i)) env))) (let* ((_a$8789 (jolt-n+ i 2)) (_a$8790 (let* ((_a$8783 (var-deref "jolt.analyzer" "add-hint")) (_a$8784 (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env (jolt-vector nm))) (_a$8785 nm) (_a$8786 (jolt-invoke (var-deref "jolt.analyzer" "hint-of") ctx bsym))) (jolt-invoke _a$8783 _a$8784 _a$8785 _a$8786))) (_a$8791 (jolt-conj pairs (let* ((_o$8787 nm) (_o$8788 init)) (jolt-vector _o$8787 _o$8788))))) (loop8782 _a$8789 _a$8790 _a$8791))))) (let* ((_o$8792 pairs) (_o$8793 env)) (jolt-vector _o$8792 _o$8793))))))))) analyze-bindings) (let* ((_o$8794 (keyword #f "private")) (_o$8795 #t)) (jolt-hash-map _o$8794 _o$8795)))) + (def-var! "jolt.analyzer" "parse-params" (letrec ((parse-params (lambda (ctx pvec) (let fnrec7084 ((ctx ctx) (pvec pvec)) (let* ((i 0) (fixed (jolt-vector)) (rest-name jolt-nil) (hints (jolt-vector)) (phints (jolt-vector)) (nhints (jolt-vector))) (let loop7085 ((i i) (fixed fixed) (rest-name rest-name) (hints hints) (phints phints) (nhints nhints)) (if (< i (jolt-count pvec)) (let* ((p (jolt-nth pvec i))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") p)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring fn param") jolt-nil) (if (jolt= "&" (jolt-invoke (var-deref "jolt.host" "form-sym-name") p)) (let* ((r (jolt-nth pvec (jolt-inc i)))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") r)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring fn rest") jolt-nil) (let* ((_a$7086 (+ i 2)) (_a$7087 fixed) (_a$7088 (jolt-invoke (var-deref "jolt.host" "form-sym-name") r)) (_a$7089 hints) (_a$7090 phints) (_a$7091 nhints)) (loop7085 _a$7086 _a$7087 _a$7088 _a$7089 _a$7090 _a$7091)))) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") p)) (h (jolt-invoke (var-deref "jolt.analyzer" "hint-of") ctx p)) (ph (jolt-invoke (var-deref "jolt.analyzer" "phint-of") ctx p)) (nh (jolt-invoke (var-deref "jolt.analyzer" "nhint-of") ctx p))) (let* ((_a$7098 (jolt-inc i)) (_a$7099 (jolt-conj fixed nm)) (_a$7100 rest-name) (_a$7101 (if (jolt-truthy? h) (jolt-conj hints (let* ((_o$7092 nm) (_o$7093 h)) (jolt-vector _o$7092 _o$7093))) hints)) (_a$7102 (if (jolt-truthy? ph) (jolt-conj phints (let* ((_o$7094 nm) (_o$7095 ph)) (jolt-vector _o$7094 _o$7095))) phints)) (_a$7103 (if (jolt-truthy? nh) (jolt-conj nhints (let* ((_o$7096 nm) (_o$7097 nh)) (jolt-vector _o$7096 _o$7097))) nhints))) (loop7085 _a$7098 _a$7099 _a$7100 _a$7101 _a$7102 _a$7103)))))) (let* ((_o$7104 (keyword #f "fixed")) (_o$7105 fixed) (_o$7106 (keyword #f "rest")) (_o$7107 rest-name) (_o$7108 (keyword #f "hints")) (_o$7109 hints) (_o$7110 (keyword #f "phints")) (_o$7111 phints) (_o$7112 (keyword #f "nhints")) (_o$7113 nhints)) (jolt-hash-map _o$7104 _o$7105 _o$7106 _o$7107 _o$7108 _o$7109 _o$7110 _o$7111 _o$7112 _o$7113))))))))) parse-params))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "parse-params" (letrec ((parse-params (lambda (ctx pvec) (let fnrec8796 ((ctx ctx) (pvec pvec)) (let* ((i 0) (fixed (jolt-vector)) (rest-name jolt-nil) (hints (jolt-vector)) (phints (jolt-vector)) (nhints (jolt-vector))) (let loop8797 ((i i) (fixed fixed) (rest-name rest-name) (hints hints) (phints phints) (nhints nhints)) (if (jolt-n< i (jolt-count pvec)) (let* ((p (jolt-nth pvec i))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") p)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring fn param") jolt-nil) (if (jolt= "&" (jolt-invoke (var-deref "jolt.host" "form-sym-name") p)) (let* ((r (jolt-nth pvec (jolt-inc i)))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") r)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "destructuring fn rest") jolt-nil) (let* ((_a$8798 (jolt-n+ i 2)) (_a$8799 fixed) (_a$8800 (jolt-invoke (var-deref "jolt.host" "form-sym-name") r)) (_a$8801 hints) (_a$8802 phints) (_a$8803 nhints)) (loop8797 _a$8798 _a$8799 _a$8800 _a$8801 _a$8802 _a$8803)))) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") p)) (h (jolt-invoke (var-deref "jolt.analyzer" "hint-of") ctx p)) (ph (jolt-invoke (var-deref "jolt.analyzer" "phint-of") ctx p)) (nh (jolt-invoke (var-deref "jolt.analyzer" "nhint-of") ctx p))) (let* ((_a$8810 (jolt-inc i)) (_a$8811 (jolt-conj fixed nm)) (_a$8812 rest-name) (_a$8813 (if (jolt-truthy? h) (jolt-conj hints (let* ((_o$8804 nm) (_o$8805 h)) (jolt-vector _o$8804 _o$8805))) hints)) (_a$8814 (if (jolt-truthy? ph) (jolt-conj phints (let* ((_o$8806 nm) (_o$8807 ph)) (jolt-vector _o$8806 _o$8807))) phints)) (_a$8815 (if (jolt-truthy? nh) (jolt-conj nhints (let* ((_o$8808 nm) (_o$8809 nh)) (jolt-vector _o$8808 _o$8809))) nhints))) (loop8797 _a$8810 _a$8811 _a$8812 _a$8813 _a$8814 _a$8815)))))) (let* ((_o$8816 (keyword #f "fixed")) (_o$8817 fixed) (_o$8818 (keyword #f "rest")) (_o$8819 rest-name) (_o$8820 (keyword #f "hints")) (_o$8821 hints) (_o$8822 (keyword #f "phints")) (_o$8823 phints) (_o$8824 (keyword #f "nhints")) (_o$8825 nhints)) (jolt-hash-map _o$8816 _o$8817 _o$8818 _o$8819 _o$8820 _o$8821 _o$8822 _o$8823 _o$8824 _o$8825))))))))) parse-params) (let* ((_o$8826 (keyword #f "private")) (_o$8827 #t)) (jolt-hash-map _o$8826 _o$8827)))) + (def-var! "jolt.analyzer" "uniquify-params" (letrec ((uniquify-params (lambda (names) (let fnrec7114 ((names names)) (let* ((n (jolt-count names))) (let* ((i 0) (out (jolt-vector))) (let loop7115 ((i i) (out out)) (if (< i n) (let* ((nm (jolt-nth names i)) (dup? (let* ((j (jolt-inc i))) (let loop7116 ((j j)) (if (>= j n) #f (if (jolt= nm (jolt-nth names j)) #t (if (jolt-truthy? (keyword #f "else")) (loop7116 (jolt-inc j)) jolt-nil))))))) (let* ((_a$7117 (jolt-inc i)) (_a$7118 (jolt-conj out (if (jolt-truthy? dup?) (jolt-invoke (var-deref "jolt.analyzer" "gen-name") (jolt-invoke (var-deref "clojure.core" "str") nm "_")) nm)))) (loop7115 _a$7117 _a$7118))) out)))))))) uniquify-params))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "uniquify-params" (letrec ((uniquify-params (lambda (names) (let fnrec8828 ((names names)) (let* ((n (jolt-count names))) (let* ((i 0) (out (jolt-vector))) (let loop8829 ((i i) (out out)) (if (jolt-n< i n) (let* ((nm (jolt-nth names i)) (dup? (let* ((j (jolt-inc i))) (let loop8830 ((j j)) (if (jolt-n>= j n) #f (if (jolt= nm (jolt-nth names j)) #t (if (jolt-truthy? (keyword #f "else")) (loop8830 (jolt-inc j)) jolt-nil))))))) (let* ((_a$8831 (jolt-inc i)) (_a$8832 (jolt-conj out (if (jolt-truthy? dup?) (jolt-invoke (var-deref "jolt.analyzer" "gen-name") (jolt-invoke (var-deref "clojure.core" "str") nm "_")) nm)))) (loop8829 _a$8831 _a$8832))) out)))))))) uniquify-params) (let* ((_o$8833 (keyword #f "private")) (_o$8834 #t)) (jolt-hash-map _o$8833 _o$8834)))) + (def-var! "jolt.analyzer" "analyze-arity" (letrec ((analyze-arity (lambda (ctx pvec body env fn-name) (let fnrec7119 ((ctx ctx) (pvec pvec) (body body) (env env) (fn-name fn-name)) (let* ((pp (jolt-invoke (var-deref "jolt.analyzer" "parse-params") ctx (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-vec-items") pvec)))) (fixed (jolt-invoke (var-deref "jolt.analyzer" "uniquify-params") (jolt-get pp (keyword #f "fixed")))) (rst (jolt-get pp (keyword #f "rest"))) (rname (jolt-invoke (var-deref "jolt.analyzer" "gen-name") (let* ((_a$7120 (var-deref "clojure.core" "str")) (_a$7121 (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx)) (_a$7122 "/") (_a$7123 (let* ((or__26__auto fn-name)) (if (jolt-truthy? or__26__auto) or__26__auto "fn"))) (_a$7124 "--")) (jolt-invoke _a$7120 _a$7121 _a$7122 _a$7123 _a$7124)))) (names (let* ((G__130 (jolt-invoke (var-deref "clojure.core" "vec") fixed))) (let* ((G__131 (if (jolt-truthy? rst) (jolt-conj G__130 rst) G__130))) (let* ((G__132 (if (jolt-truthy? fn-name) (jolt-conj G__131 fn-name) G__131))) G__132)))) (env0 (jolt-invoke (var-deref "jolt.analyzer" "with-recur") (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env names) rname)) (env* (let* ((_a$7130 (lambda (e pr) (let fnrec7125 ((e e) (pr pr)) (let* ((_a$7126 (var-deref "jolt.analyzer" "add-hint")) (_a$7127 e) (_a$7128 (jolt-nth pr 0)) (_a$7129 (jolt-nth pr 1))) (jolt-invoke _a$7126 _a$7127 _a$7128 _a$7129))))) (_a$7131 env0) (_a$7132 (jolt-get pp (keyword #f "hints")))) (jolt-reduce _a$7130 _a$7131 _a$7132))) (arity (let* ((_o$7133 (keyword #f "params")) (_o$7134 fixed) (_o$7135 (keyword #f "recur-name")) (_o$7136 rname) (_o$7137 (keyword #f "body")) (_o$7138 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx body env*))) (jolt-hash-map _o$7133 _o$7134 _o$7135 _o$7136 _o$7137 _o$7138))) (arity (if (jolt-truthy? (jolt-seq (jolt-get pp (keyword #f "phints")))) (jolt-assoc arity (keyword #f "phints") (jolt-get pp (keyword #f "phints"))) arity)) (arity (if (jolt-truthy? (jolt-seq (jolt-get pp (keyword #f "nhints")))) (jolt-assoc arity (keyword #f "nhints") (jolt-get pp (keyword #f "nhints"))) arity))) (if (jolt-truthy? rst) (jolt-assoc arity (keyword #f "rest") rst) arity)))))) analyze-arity))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-arity" (letrec ((analyze-arity (lambda (ctx pvec body env fn-name) (let fnrec8835 ((ctx ctx) (pvec pvec) (body body) (env env) (fn-name fn-name)) (let* ((pp (jolt-invoke (var-deref "jolt.analyzer" "parse-params") ctx (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-vec-items") pvec)))) (fixed (jolt-invoke (var-deref "jolt.analyzer" "uniquify-params") (jolt-get pp (keyword #f "fixed")))) (rst (jolt-get pp (keyword #f "rest"))) (rname (jolt-invoke (var-deref "jolt.analyzer" "gen-name") (let* ((_a$8836 (var-deref "clojure.core" "str")) (_a$8837 (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx)) (_a$8838 "/") (_a$8839 (let* ((or__26__auto fn-name)) (if (jolt-truthy? or__26__auto) or__26__auto "fn"))) (_a$8840 "--")) (jolt-invoke _a$8836 _a$8837 _a$8838 _a$8839 _a$8840)))) (names (let* ((G__149 (jolt-invoke (var-deref "clojure.core" "vec") fixed))) (let* ((G__150 (if (jolt-truthy? rst) (jolt-conj G__149 rst) G__149))) (let* ((G__151 (if (jolt-truthy? fn-name) (jolt-conj G__150 fn-name) G__150))) G__151)))) (env0 (jolt-invoke (var-deref "jolt.analyzer" "with-recur") (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env names) rname)) (env* (let* ((_a$8846 (lambda (e pr) (let fnrec8841 ((e e) (pr pr)) (let* ((_a$8842 (var-deref "jolt.analyzer" "add-hint")) (_a$8843 e) (_a$8844 (jolt-nth pr 0)) (_a$8845 (jolt-nth pr 1))) (jolt-invoke _a$8842 _a$8843 _a$8844 _a$8845))))) (_a$8847 env0) (_a$8848 (jolt-get pp (keyword #f "hints")))) (jolt-reduce _a$8846 _a$8847 _a$8848))) (arity (let* ((_o$8849 (keyword #f "params")) (_o$8850 fixed) (_o$8851 (keyword #f "recur-name")) (_o$8852 rname) (_o$8853 (keyword #f "body")) (_o$8854 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx body env*))) (jolt-hash-map _o$8849 _o$8850 _o$8851 _o$8852 _o$8853 _o$8854))) (arity (if (jolt-truthy? (jolt-seq (jolt-get pp (keyword #f "phints")))) (jolt-assoc arity (keyword #f "phints") (jolt-get pp (keyword #f "phints"))) arity)) (arity (if (jolt-truthy? (jolt-seq (jolt-get pp (keyword #f "nhints")))) (jolt-assoc arity (keyword #f "nhints") (jolt-get pp (keyword #f "nhints"))) arity))) (if (jolt-truthy? rst) (jolt-assoc arity (keyword #f "rest") rst) arity)))))) analyze-arity) (let* ((_o$8855 (keyword #f "private")) (_o$8856 #t)) (jolt-hash-map _o$8855 _o$8856)))) + (def-var! "jolt.analyzer" "strip-arglist-meta" (letrec ((strip-arglist-meta (lambda (form) (let fnrec7139 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (let* ((es (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") form)))) (if (jolt-truthy? (let* ((and__25__auto (jolt= 3 (jolt-count es)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-first es)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "with-meta" (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first es))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-vec?") (jolt-nth es 1)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-nth es 1) form)) form))))) strip-arglist-meta))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "strip-arglist-meta" (letrec ((strip-arglist-meta (lambda (form) (let fnrec8857 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (let* ((es (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") form)))) (if (jolt-truthy? (let* ((and__25__auto (jolt= 3 (jolt-count es)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-first es)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "with-meta" (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first es))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-vec?") (jolt-nth es 1)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-nth es 1) form)) form))))) strip-arglist-meta) (let* ((_o$8858 (keyword #f "private")) (_o$8859 #t)) (jolt-hash-map _o$8858 _o$8859)))) + (def-var! "jolt.analyzer" "analyze-fn" (letrec ((analyze-fn (lambda (ctx items env) (let fnrec7140 ((ctx ctx) (items items) (env env)) (let* ((named (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth items 1))) (fn-name (if (jolt-truthy? named) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth items 1)) jolt-nil)) (rest-items (if (jolt-truthy? named) (jolt-drop 2 items) (jolt-drop 1 items))) (first* (jolt-invoke (var-deref "jolt.analyzer" "strip-arglist-meta") (jolt-first rest-items)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") first*)) (jolt-invoke (var-deref "jolt.ir" "fn-node") fn-name (jolt-vector (jolt-invoke (var-deref "jolt.analyzer" "analyze-arity") ctx first* (jolt-rest rest-items) env fn-name))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") first*)) (jolt-invoke (var-deref "jolt.ir" "fn-node") fn-name (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (clause) (let fnrec7141 ((clause clause)) (let* ((cl (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") clause)))) (let* ((_a$7142 (var-deref "jolt.analyzer" "analyze-arity")) (_a$7143 ctx) (_a$7144 (jolt-invoke (var-deref "jolt.analyzer" "strip-arglist-meta") (jolt-first cl))) (_a$7145 (jolt-rest cl)) (_a$7146 env) (_a$7147 fn-name)) (jolt-invoke _a$7142 _a$7143 _a$7144 _a$7145 _a$7146 _a$7147))))) rest-items)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "fn: bad params") jolt-nil)))))))) analyze-fn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-fn" (letrec ((analyze-fn (lambda (ctx items env) (let fnrec8860 ((ctx ctx) (items items) (env env)) (let* ((named (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth items 1))) (fn-name (if (jolt-truthy? named) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth items 1)) jolt-nil)) (rest-items (if (jolt-truthy? named) (jolt-drop 2 items) (jolt-drop 1 items))) (first* (jolt-invoke (var-deref "jolt.analyzer" "strip-arglist-meta") (jolt-first rest-items)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") first*)) (jolt-invoke (var-deref "jolt.ir" "fn-node") fn-name (jolt-vector (jolt-invoke (var-deref "jolt.analyzer" "analyze-arity") ctx first* (jolt-rest rest-items) env fn-name))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") first*)) (jolt-invoke (var-deref "jolt.ir" "fn-node") fn-name (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (clause) (let fnrec8861 ((clause clause)) (let* ((cl (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") clause)))) (let* ((_a$8862 (var-deref "jolt.analyzer" "analyze-arity")) (_a$8863 ctx) (_a$8864 (jolt-invoke (var-deref "jolt.analyzer" "strip-arglist-meta") (jolt-first cl))) (_a$8865 (jolt-rest cl)) (_a$8866 env) (_a$8867 fn-name)) (jolt-invoke _a$8862 _a$8863 _a$8864 _a$8865 _a$8866 _a$8867))))) rest-items)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "fn: bad params") jolt-nil)))))))) analyze-fn) (let* ((_o$8868 (keyword #f "private")) (_o$8869 #t)) (jolt-hash-map _o$8868 _o$8869)))) + (def-var! "jolt.analyzer" "analyze-try" (letrec ((analyze-try (lambda (ctx items env) (let fnrec7148 ((ctx ctx) (items items) (env env)) (let* ((clauses (jolt-rest items)) (body (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (catch-sym (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil)) (catch-body (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil)) (finally-body (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil))) (begin (begin (jolt-count (jolt-map (lambda (c) (let fnrec7149 ((c c)) (begin (let* ((head (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") c)) (jolt-first (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c))) jolt-nil)) (hname (if (jolt-truthy? (let* ((and__25__auto head)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") head) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil))) (if (jolt= hname "catch") (let* ((cl (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c)))) (begin (if (jolt-truthy? (let* ((or__26__auto (< (jolt-count cl) 3))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth cl 2)))))) (jolt-throw "Unable to parse catch clause; expected (catch class binding body*)") jolt-nil) (jolt-invoke (var-deref "clojure.core" "reset!") catch-sym (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth cl 2))) (jolt-invoke (var-deref "clojure.core" "reset!") catch-body (jolt-drop 3 cl)))) (if (jolt= hname "finally") (jolt-invoke (var-deref "clojure.core" "reset!") finally-body (jolt-rest (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c)))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "swap!") body jolt-conj c) jolt-nil)))) jolt-nil))) clauses)) jolt-nil) (let* ((n (let* ((_o$7150 (keyword #f "op")) (_o$7151 (keyword #f "try")) (_o$7152 (keyword #f "body")) (_o$7153 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-invoke (var-deref "clojure.core" "deref") body) env))) (jolt-hash-map _o$7150 _o$7151 _o$7152 _o$7153))) (n (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "deref") catch-body)) (let* ((_a$7158 n) (_a$7159 (keyword #f "catch-sym")) (_a$7160 (jolt-invoke (var-deref "clojure.core" "deref") catch-sym)) (_a$7161 (keyword #f "catch-body")) (_a$7162 (let* ((_a$7154 (var-deref "jolt.analyzer" "analyze-seq")) (_a$7155 ctx) (_a$7156 (jolt-invoke (var-deref "clojure.core" "deref") catch-body)) (_a$7157 (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env (jolt-vector (jolt-invoke (var-deref "clojure.core" "deref") catch-sym))))) (jolt-invoke _a$7154 _a$7155 _a$7156 _a$7157)))) (jolt-assoc _a$7158 _a$7159 _a$7160 _a$7161 _a$7162)) n)) (n (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "deref") finally-body)) (jolt-assoc n (keyword #f "finally") (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-invoke (var-deref "clojure.core" "deref") finally-body) env)) n))) n))))))) analyze-try))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "catch-all-names" (let* ((_o$8870 "Throwable") (_o$8871 "java.lang.Throwable") (_o$8872 "Object") (_o$8873 "java.lang.Object")) (jolt-hash-set _o$8870 _o$8871 _o$8872 _o$8873)) (let* ((_o$8874 (keyword #f "private")) (_o$8875 #t)) (jolt-hash-map _o$8874 _o$8875)))) + (def-var! "jolt.analyzer" "analyze-letfn" (letrec ((analyze-letfn (lambda (ctx items env) (let fnrec7163 ((ctx ctx) (items items) (env env)) (let* ((specs (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 1)))) (names (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__87_) (let fnrec7164 ((p__87_ p__87_)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") p__87_)))))) specs)) (env* (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env names)) (binds (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (spec) (let fnrec7165 ((spec spec)) (let* ((cl (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") spec)))) (let* ((_o$7166 (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first cl))) (_o$7167 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-cons (jolt-invoke (var-deref "clojure.core" "symbol") "fn") cl) env*))) (jolt-vector _o$7166 _o$7167))))) specs))) (let* ((_o$7168 (keyword #f "op")) (_o$7169 (keyword #f "let")) (_o$7170 (keyword #f "letrec")) (_o$7171 #t) (_o$7172 (keyword #f "bindings")) (_o$7173 binds) (_o$7174 (keyword #f "body")) (_o$7175 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-drop 2 items) env*))) (jolt-hash-map _o$7168 _o$7169 _o$7170 _o$7171 _o$7172 _o$7173 _o$7174 _o$7175))))))) analyze-letfn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-try" (letrec ((analyze-try (lambda (ctx items env) (let fnrec8876 ((ctx ctx) (items items) (env env)) (let* ((clauses (jolt-rest items)) (body (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (catches (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (finally-body (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil))) (begin (begin (jolt-count (jolt-map (lambda (c) (let fnrec8877 ((c c)) (begin (let* ((head (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") c)) (jolt-first (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c))) jolt-nil)) (hname (if (jolt-truthy? (let* ((and__25__auto head)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") head) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil))) (if (jolt= hname "catch") (let* ((cl (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c)))) (begin (if (let* ((or__26__auto (jolt-n< (jolt-count cl) 3))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth cl 2))))) (jolt-throw "Unable to parse catch clause; expected (catch class binding body*)") jolt-nil) (jolt-invoke (var-deref "clojure.core" "swap!") catches jolt-conj cl))) (if (jolt= hname "finally") (jolt-invoke (var-deref "clojure.core" "reset!") finally-body (jolt-rest (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") c)))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "swap!") body jolt-conj c) jolt-nil)))) jolt-nil))) clauses)) jolt-nil) (let* ((n (let* ((_o$8878 (keyword #f "op")) (_o$8879 (keyword #f "try")) (_o$8880 (keyword #f "body")) (_o$8881 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-invoke (var-deref "clojure.core" "deref") body) env))) (jolt-hash-map _o$8878 _o$8879 _o$8880 _o$8881))) (n (if (jolt-truthy? (jolt-seq (jolt-invoke (var-deref "clojure.core" "deref") catches))) (let* ((evar-name (jolt-invoke (var-deref "jolt.analyzer" "gen-name") "catch")) (raw-name (jolt-invoke (var-deref "jolt.analyzer" "gen-name") "catch-raw")) (evar (jolt-invoke (var-deref "clojure.core" "symbol") evar-name)) (dispatch (let* ((_a$8886 (lambda (_else cl) (let fnrec8882 ((_else _else) (cl cl)) (let* ((cform (jolt-nth cl 1)) (bindsym (jolt-nth cl 2)) (bodyf (jolt-drop 3 cl)) (letform (jolt-cons (jolt-symbol #f "let") (jolt-cons (jolt-vector bindsym evar) bodyf))) (fullname (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") cform)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") cform) jolt-nil)) (catch-all? (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") cform)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-contains? (var-deref "jolt.analyzer" "catch-all-names") fullname))))) (if (jolt-truthy? catch-all?) letform (jolt-list (jolt-symbol #f "if") (let* ((_a$8883 (jolt-symbol #f "or")) (_a$8884 (jolt-list (jolt-symbol #f "instance?") cform evar)) (_a$8885 (jolt-list (jolt-symbol #f "__catch-broad?") fullname evar))) (jolt-list _a$8883 _a$8884 _a$8885)) letform _else)))))) (_a$8887 (jolt-list (jolt-symbol #f "throw") evar)) (_a$8888 (jolt-reverse (jolt-invoke (var-deref "clojure.core" "deref") catches)))) (jolt-reduce _a$8886 _a$8887 _a$8888)))) (jolt-assoc n (keyword #f "catch-sym") evar-name (keyword #f "catch-raw-sym") raw-name (keyword #f "catch-body") (let* ((_a$8889 (var-deref "jolt.analyzer" "analyze-seq")) (_a$8890 ctx) (_a$8891 (jolt-list dispatch)) (_a$8892 (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env (jolt-vector evar-name)))) (jolt-invoke _a$8889 _a$8890 _a$8891 _a$8892)))) n)) (n (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "deref") finally-body)) (jolt-assoc n (keyword #f "finally") (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-invoke (var-deref "clojure.core" "deref") finally-body) env)) n))) n))))))) analyze-try) (let* ((_o$8893 (keyword #f "private")) (_o$8894 #t)) (jolt-hash-map _o$8893 _o$8894)))) + (def-var! "jolt.analyzer" "field-head?" (letrec ((field-head? (lambda (nm) (let fnrec7176 ((nm nm)) (let* ((and__25__auto (> (jolt-count nm) 2))) (if (jolt-truthy? and__25__auto) (jolt= ".-" (jolt-invoke (var-deref "clojure.core" "subs") nm 0 2)) and__25__auto)))))) field-head?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-letfn*" (letrec ((analyze-letfn* (lambda (ctx items env) (let fnrec8895 ((ctx ctx) (items items) (env env)) (let* ((bvec (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 1)))) (n (jolt-quot (jolt-count bvec) 2)) (names (let* ((_a$8897 (var-deref "clojure.core" "mapv")) (_a$8898 (lambda (i) (let fnrec8896 ((i i)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth bvec (jolt-n* 2 i)))))) (_a$8899 (jolt-range n))) (jolt-invoke _a$8897 _a$8898 _a$8899))) (env* (jolt-invoke (var-deref "jolt.analyzer" "add-locals") env names)) (binds (let* ((_a$8903 (var-deref "clojure.core" "mapv")) (_a$8904 (lambda (i) (let fnrec8900 ((i i)) (let* ((_o$8901 (jolt-nth names i)) (_o$8902 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth bvec (jolt-inc (jolt-n* 2 i))) env*))) (jolt-vector _o$8901 _o$8902))))) (_a$8905 (jolt-range n))) (jolt-invoke _a$8903 _a$8904 _a$8905)))) (let* ((_o$8906 (keyword #f "op")) (_o$8907 (keyword #f "let")) (_o$8908 (keyword #f "letrec")) (_o$8909 #t) (_o$8910 (keyword #f "bindings")) (_o$8911 binds) (_o$8912 (keyword #f "body")) (_o$8913 (jolt-invoke (var-deref "jolt.analyzer" "analyze-seq") ctx (jolt-drop 2 items) env*))) (jolt-hash-map _o$8906 _o$8907 _o$8908 _o$8909 _o$8910 _o$8911 _o$8912 _o$8913))))))) analyze-letfn*) (let* ((_o$8914 (keyword #f "private")) (_o$8915 #t)) (jolt-hash-map _o$8914 _o$8915)))) + (def-var! "jolt.analyzer" "analyze-def" (letrec ((analyze-def (lambda (ctx items env) (let fnrec7177 ((ctx ctx) (items items) (env env)) (let* ((name-sym (jolt-nth items 1))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") name-sym)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "def name with map metadata") jolt-nil) (if (< (jolt-count items) 3) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") name-sym)) (cur (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx))) (begin (jolt-invoke (var-deref "jolt.host" "host-intern!") ctx cur nm) (let* ((_o$7178 (keyword #f "op")) (_o$7179 (keyword #f "def")) (_o$7180 (keyword #f "ns")) (_o$7181 cur) (_o$7182 (keyword #f "name")) (_o$7183 nm) (_o$7184 (keyword #f "no-init")) (_o$7185 #t)) (jolt-hash-map _o$7178 _o$7179 _o$7180 _o$7181 _o$7182 _o$7183 _o$7184 _o$7185)))) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") name-sym)) (cur (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx)) (has-doc (let* ((and__25__auto (> (jolt-count items) 3))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "string?") (jolt-nth items 2)) and__25__auto))) (val-form (jolt-nth items (if (jolt-truthy? has-doc) 3 2))) (base0 (let* ((or__26__auto (jolt-invoke (var-deref "jolt.host" "form-sym-meta") name-sym))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))) (tag (jolt-get base0 (keyword #f "tag"))) (tag-name (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") tag)) (jolt-invoke (var-deref "jolt.host" "form-sym-name") tag) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") tag)) tag (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))) (base-meta (if (jolt-truthy? tag-name) (let* ((c (jolt-invoke (var-deref "jolt.host" "resolve-class-hint") tag-name))) (if (jolt-truthy? c) (jolt-assoc base0 (keyword #f "tag") c) base0)) base0)) (node-meta (if (jolt-truthy? has-doc) (jolt-assoc base-meta (keyword #f "doc") (jolt-nth items 2)) base-meta))) (begin (jolt-invoke (var-deref "jolt.host" "host-intern!") ctx cur nm) (jolt-invoke (var-deref "jolt.ir" "def-node") cur nm (let* ((_a$7186 (var-deref "jolt.analyzer" "with-ret-nhint")) (_a$7187 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx val-form env)) (_a$7188 (jolt-invoke (var-deref "jolt.analyzer" "tag->nkind") tag))) (jolt-invoke _a$7186 _a$7187 _a$7188)) node-meta)))))))))) analyze-def))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "field-head?" (letrec ((field-head? (lambda (nm) (let fnrec8916 ((nm nm)) (let* ((and__25__auto (jolt-n> (jolt-count nm) 2))) (if (jolt-truthy? and__25__auto) (jolt= ".-" (jolt-invoke (var-deref "clojure.core" "subs") nm 0 2)) and__25__auto)))))) field-head?) (let* ((_o$8917 (keyword #f "private")) (_o$8918 #t)) (jolt-hash-map _o$8917 _o$8918)))) + (def-var! "jolt.analyzer" "analyze-set!" (letrec ((analyze-set! (lambda (ctx items env) (let fnrec7189 ((ctx ctx) (items items) (env env)) (let* ((target (jolt-nth items 1)) (val-node (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 2) env)) (ti (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") target)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") target)) jolt-nil)) (thead (if (jolt-truthy? (let* ((and__25__auto ti)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-pos? (jolt-count ti)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-first ti)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first ti)) jolt-nil))) (if (jolt-truthy? (let* ((and__25__auto thead)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "field-head?") thead) and__25__auto))) (let* ((_o$7190 (keyword #f "op")) (_o$7191 (keyword #f "set-field")) (_o$7192 (keyword #f "obj")) (_o$7193 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth ti 1) env)) (_o$7194 (keyword #f "field")) (_o$7195 (jolt-invoke (var-deref "clojure.core" "subs") thead 2)) (_o$7196 (keyword #f "val")) (_o$7197 val-node)) (jolt-hash-map _o$7190 _o$7191 _o$7192 _o$7193 _o$7194 _o$7195 _o$7196 _o$7197)) (if (jolt-truthy? (let* ((and__25__auto (jolt= thead "."))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= (jolt-count ti) 3))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth ti 1)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth ti 2)))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "class") (jolt-get (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx (jolt-nth ti 1)) (keyword #f "kind"))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_a$7201 (var-deref "jolt.ir" "invoke")) (_a$7202 (jolt-invoke (var-deref "jolt.ir" "var-ref") "jolt.host" "set-static-field!")) (_a$7203 (let* ((_o$7198 (jolt-invoke (var-deref "jolt.ir" "const") (jolt-get (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx (jolt-nth ti 1)) (keyword #f "name")))) (_o$7199 (jolt-invoke (var-deref "jolt.ir" "const") (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth ti 2)))) (_o$7200 val-node)) (jolt-vector _o$7198 _o$7199 _o$7200)))) (jolt-invoke _a$7201 _a$7202 _a$7203)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") target)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "jolt.analyzer" "local?") env (jolt-invoke (var-deref "jolt.host" "form-sym-name") target))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of a local") jolt-nil) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx target))) (begin (if (jolt-not (jolt= (keyword #f "var") (jolt-get r (keyword #f "kind")))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of a non-var") jolt-nil) (let* ((_o$7207 (keyword #f "op")) (_o$7208 (keyword #f "set-var")) (_o$7209 (keyword #f "the-var")) (_o$7210 (let* ((_a$7204 (var-deref "jolt.ir" "the-var")) (_a$7205 (jolt-get r (keyword #f "ns"))) (_a$7206 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$7204 _a$7205 _a$7206))) (_o$7211 (keyword #f "val")) (_o$7212 val-node)) (jolt-hash-map _o$7207 _o$7208 _o$7209 _o$7210 _o$7211 _o$7212))))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of an unsupported target") jolt-nil))))))))) analyze-set!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "def-meta-expr" (letrec ((def-meta-expr (lambda (ctx base env) (let fnrec8919 ((ctx ctx) (base base) (env env)) (if (jolt-pos? (jolt-count base)) (jolt-invoke (var-deref "jolt.ir" "map-node") (let* ((_a$8923 (var-deref "clojure.core" "mapv")) (_a$8924 (lambda (p) (let fnrec8920 ((p p)) (let* ((k (jolt-first p)) (v (jolt-invoke (var-deref "clojure.core" "second") p))) (let* ((_o$8921 (jolt-invoke (var-deref "jolt.ir" "const") k)) (_o$8922 (if (jolt= k (keyword #f "tag")) (jolt-invoke (var-deref "jolt.ir" "quote-node") v) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx v env)))) (jolt-vector _o$8921 _o$8922)))))) (_a$8925 (jolt-seq base))) (jolt-invoke _a$8923 _a$8924 _a$8925))) jolt-nil))))) def-meta-expr) (let* ((_o$8926 (keyword #f "private")) (_o$8927 #t)) (jolt-hash-map _o$8926 _o$8927)))) + (def-var! "jolt.analyzer" "analyze-special" (letrec ((analyze-special (lambda (ctx op items env) (let fnrec7213 ((ctx ctx) (op op) (items items) (env env)) (let* ((G__133 op)) (if (jolt= G__133 "quote") (jolt-invoke (var-deref "jolt.ir" "quote-node") (jolt-invoke (var-deref "clojure.core" "second") items)) (if (jolt= G__133 "if") (begin (if (jolt-truthy? 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(jolt-invoke (var-deref "clojure.core" "string?") (jolt-first after))) (jolt-rest after) after)) (after (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-map?") (jolt-first after))) (jolt-rest after) after)) (fn-form (jolt-cons (jolt-invoke (var-deref "clojure.core" "symbol") "fn") after))) (begin (jolt-invoke (var-deref "jolt.host" "host-intern!") ctx cur nm) (let* ((_o$7246 (keyword #f "op")) (_o$7247 (keyword #f "defmacro")) (_o$7248 (keyword #f "ns")) (_o$7249 cur) (_o$7250 (keyword #f "name")) (_o$7251 nm) (_o$7252 (keyword #f "fn")) (_o$7253 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx fn-form env))) (jolt-hash-map _o$7246 _o$7247 _o$7248 _o$7249 _o$7250 _o$7251 _o$7252 _o$7253)))) (if (jolt= G__133 "set!") (jolt-invoke (var-deref "jolt.analyzer" "analyze-set!") ctx items env) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") (jolt-invoke (var-deref "clojure.core" "str") "special form " op)))))))))))))))))))))) analyze-special))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-def" (letrec ((analyze-def (lambda (ctx items env) (let fnrec8928 ((ctx ctx) (items items) (env env)) (let* ((name-sym (jolt-nth items 1))) (begin (if (jolt-not (jolt-invoke (var-deref "jolt.host" "form-sym?") name-sym)) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "def name with map metadata") jolt-nil) (if (jolt-n< (jolt-count items) 3) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") name-sym)) (cur (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx))) (begin (jolt-invoke (var-deref "jolt.host" "host-intern!") ctx cur nm) (let* ((_o$8929 (keyword #f "op")) (_o$8930 (keyword #f "def")) (_o$8931 (keyword #f "ns")) (_o$8932 cur) (_o$8933 (keyword #f "name")) (_o$8934 nm) (_o$8935 (keyword #f "no-init")) (_o$8936 #t)) (jolt-hash-map _o$8929 _o$8930 _o$8931 _o$8932 _o$8933 _o$8934 _o$8935 _o$8936)))) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") name-sym)) (cur (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx)) (has-doc (let* ((and__25__auto (jolt-n> (jolt-count items) 3))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "string?") 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(keyword #f "else")) jolt-nil jolt-nil)))) (base-meta (if (jolt-truthy? tag-name) (let* ((c (jolt-invoke (var-deref "jolt.host" "resolve-class-hint") tag-name))) (if (jolt-truthy? c) (jolt-assoc base0 (keyword #f "tag") c) base0)) base0)) (node-meta (if (jolt-truthy? has-doc) (jolt-assoc base-meta (keyword #f "doc") (jolt-nth items 2)) base-meta))) (begin (jolt-invoke (var-deref "jolt.host" "host-intern!") ctx cur nm) (let* ((node (jolt-invoke (var-deref "jolt.ir" "def-node") cur nm (let* ((_a$8937 (var-deref "jolt.analyzer" "with-ret-nhint")) (_a$8938 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx val-form env)) (_a$8939 (jolt-invoke (var-deref "jolt.analyzer" "tag->nkind") tag))) (jolt-invoke _a$8937 _a$8938 _a$8939)) node-meta)) (me (jolt-invoke (var-deref "jolt.analyzer" "def-meta-expr") ctx node-meta env))) (if (jolt-truthy? me) (jolt-assoc node (keyword #f "meta-expr") me) node))))))))))) analyze-def) (let* ((_o$8940 (keyword #f "private")) (_o$8941 #t)) (jolt-hash-map _o$8940 _o$8941)))) + (def-var! "jolt.analyzer" "method-head?" (letrec ((method-head? (lambda (nm) (let fnrec7254 ((nm nm)) (let* ((and__25__auto (> (jolt-count nm) 1))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "." (jolt-invoke (var-deref "clojure.core" "subs") nm 0 1)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt= "-" (jolt-invoke (var-deref "clojure.core" "subs") nm 1 2))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt= "." (jolt-invoke (var-deref "clojure.core" "subs") nm 1 2))) and__25__auto)) and__25__auto)) and__25__auto)))))) method-head?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-set!" (letrec ((analyze-set! (lambda (ctx items env) (let fnrec8942 ((ctx ctx) (items items) (env env)) (let* ((target (jolt-nth items 1)) (val-node (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 2) env)) (ti (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") target)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") target)) jolt-nil)) (thead (if (jolt-truthy? (let* ((and__25__auto ti)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-pos? (jolt-count ti)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-first ti)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-first ti)) jolt-nil))) (if (jolt-truthy? 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(jolt-nth ti 2)))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "class") (jolt-get (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx (jolt-nth ti 1)) (keyword #f "kind"))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_a$8954 (var-deref "jolt.ir" "invoke")) (_a$8955 (jolt-invoke (var-deref "jolt.ir" "var-ref") "jolt.host" "set-static-field!")) (_a$8956 (let* ((_o$8951 (jolt-invoke (var-deref "jolt.ir" "const") (jolt-get (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx (jolt-nth ti 1)) (keyword #f "name")))) (_o$8952 (jolt-invoke (var-deref "jolt.ir" "const") (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth ti 2)))) (_o$8953 val-node)) (jolt-vector _o$8951 _o$8952 _o$8953)))) (jolt-invoke _a$8954 _a$8955 _a$8956)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") target)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "jolt.analyzer" "local?") env (jolt-invoke (var-deref "jolt.host" "form-sym-name") target))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of a local") jolt-nil) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx target))) (begin (if (jolt-not (jolt= (keyword #f "var") (jolt-get r (keyword #f "kind")))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of a non-var") jolt-nil) (let* ((_o$8960 (keyword #f "op")) (_o$8961 (keyword #f "set-var")) (_o$8962 (keyword #f "the-var")) (_o$8963 (let* ((_a$8957 (var-deref "jolt.ir" "the-var")) (_a$8958 (jolt-get r (keyword #f "ns"))) (_a$8959 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$8957 _a$8958 _a$8959))) (_o$8964 (keyword #f "val")) (_o$8965 val-node)) (jolt-hash-map _o$8960 _o$8961 _o$8962 _o$8963 _o$8964 _o$8965))))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "set! of an unsupported target") jolt-nil))))))))) analyze-set!) (let* ((_o$8966 (keyword #f "private")) (_o$8967 #t)) (jolt-hash-map _o$8966 _o$8967)))) + (def-var! "jolt.analyzer" "analyze-host-call" (letrec ((analyze-host-call (lambda (ctx hname items env) (let fnrec7255 ((ctx ctx) (hname hname) (items items) (env env)) (begin (if (< (jolt-count items) 2) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed member expression, expecting (.method target ...): " hname)) jolt-nil) (let* ((_o$7260 (keyword #f "op")) (_o$7261 (keyword #f "host-call")) (_o$7262 (keyword #f "method")) (_o$7263 (jolt-invoke (var-deref "clojure.core" "subs") hname 1)) (_o$7264 (keyword #f "target")) (_o$7265 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$7266 (keyword #f "args")) (_o$7267 (let* ((_a$7257 (var-deref "clojure.core" "mapv")) (_a$7258 (lambda (p__89_) (let fnrec7256 ((p__89_ p__89_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__89_ env)))) (_a$7259 (jolt-drop 2 items))) (jolt-invoke _a$7257 _a$7258 _a$7259)))) (jolt-hash-map _o$7260 _o$7261 _o$7262 _o$7263 _o$7264 _o$7265 _o$7266 _o$7267))))))) analyze-host-call))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-special" (letrec ((analyze-special (lambda (ctx op items env) (let fnrec8968 ((ctx ctx) (op op) (items items) (env env)) (let* ((G__152 op)) (if (jolt= G__152 "quote") (let* ((qf (jolt-invoke (var-deref "clojure.core" "second") items)) (m (jolt-invoke (var-deref "jolt.host" "form-coll-meta") qf)) (m (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") m)) (let* ((u (jolt-dissoc m (keyword #f "line") (keyword #f "column") (keyword #f "end-line") (keyword #f "end-column") (keyword #f "file")))) (if (jolt-truthy? 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(lambda (nm) (let fnrec9016 ((nm nm)) (let* ((and__25__auto (jolt-n> (jolt-count nm) 1))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "." (jolt-invoke (var-deref "clojure.core" "subs") nm 0 1)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt= "-" (jolt-invoke (var-deref "clojure.core" "subs") nm 1 2))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt= "." (jolt-invoke (var-deref "clojure.core" "subs") nm 1 2))) and__25__auto)) and__25__auto)) and__25__auto)))))) method-head?) (let* ((_o$9017 (keyword #f "private")) (_o$9018 #t)) (jolt-hash-map _o$9017 _o$9018)))) + (def-var! "jolt.analyzer" "analyze-ctor" (letrec ((analyze-ctor (lambda (ctx class args env) (let fnrec7273 ((ctx ctx) (class class) (args args) (env env)) (jolt-invoke (var-deref "jolt.ir" "host-new") class (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__90_) (let fnrec7274 ((p__90_ p__90_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__90_ env))) args)))))) analyze-ctor))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-host-call" (letrec ((analyze-host-call (lambda (ctx hname items env) (let fnrec9019 ((ctx ctx) (hname hname) (items items) (env env)) (begin (if (jolt-n< (jolt-count items) 2) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed member expression, expecting (.method target ...): " hname)) jolt-nil) (let* ((_o$9024 (keyword #f "op")) (_o$9025 (keyword #f "host-call")) (_o$9026 (keyword #f "method")) (_o$9027 (jolt-invoke (var-deref "clojure.core" "subs") hname 1)) (_o$9028 (keyword #f "target")) (_o$9029 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$9030 (keyword #f "args")) (_o$9031 (let* ((_a$9021 (var-deref "clojure.core" "mapv")) (_a$9022 (lambda (p__100_) (let fnrec9020 ((p__100_ p__100_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__100_ env)))) (_a$9023 (jolt-drop 2 items))) (jolt-invoke _a$9021 _a$9022 _a$9023)))) (jolt-hash-map _o$9024 _o$9025 _o$9026 _o$9027 _o$9028 _o$9029 _o$9030 _o$9031))))))) analyze-host-call) (let* ((_o$9032 (keyword #f "private")) (_o$9033 #t)) (jolt-hash-map _o$9032 _o$9033)))) + (def-var! "jolt.analyzer" "analyze-ffi-fn" (letrec ((analyze-ffi-fn (lambda (ctx items env) (let fnrec7275 ((ctx ctx) (items items) (env env)) (begin (if (jolt-not (<= 4 (jolt-count items) 5)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi/foreign-fn expects (foreign-fn \"sym\" [argtypes] rettype [:blocking])")) jolt-nil) (let* ((_o$7276 (keyword #f "op")) (_o$7277 (keyword #f "ffi-fn")) (_o$7278 (keyword #f "csym")) (_o$7279 (jolt-nth items 1)) (_o$7280 (keyword #f "argtypes")) (_o$7281 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "name") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 2)))) (_o$7282 (keyword #f "rettype")) (_o$7283 (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 3))) (_o$7284 (keyword #f "blocking")) (_o$7285 (let* ((and__25__auto (jolt= 5 (jolt-count items)))) (if (jolt-truthy? and__25__auto) (jolt= "blocking" (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 4))) and__25__auto)))) (jolt-hash-map _o$7276 _o$7277 _o$7278 _o$7279 _o$7280 _o$7281 _o$7282 _o$7283 _o$7284 _o$7285))))))) analyze-ffi-fn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "ctor-head?" (letrec ((ctor-head? (lambda (nm) (let fnrec9034 ((nm nm)) (let* ((and__25__auto (jolt-n> (jolt-count nm) 1))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "." (let* ((_a$9035 (var-deref "clojure.core" "subs")) (_a$9036 nm) (_a$9037 (jolt-dec (jolt-count nm))) (_a$9038 (jolt-count nm))) (jolt-invoke _a$9035 _a$9036 _a$9037 _a$9038))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt= "." (jolt-invoke (var-deref "clojure.core" "subs") nm 0 1))) and__25__auto)) and__25__auto)))))) ctor-head?) (let* ((_o$9039 (keyword #f "private")) (_o$9040 #t)) (jolt-hash-map _o$9039 _o$9040)))) + (def-var! "jolt.analyzer" "analyze-ffi-callable" (letrec ((analyze-ffi-callable (lambda (ctx items env) (let fnrec7286 ((ctx ctx) (items items) (env env)) (begin (if (jolt-not (<= 4 (jolt-count items) 5)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi/foreign-callable expects (foreign-callable f [argtypes] rettype [:collect-safe])")) jolt-nil) (let* ((_o$7287 (keyword #f "op")) (_o$7288 (keyword #f "ffi-callable")) (_o$7289 (keyword #f "fn")) (_o$7290 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$7291 (keyword #f "argtypes")) (_o$7292 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "name") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 2)))) (_o$7293 (keyword #f "rettype")) (_o$7294 (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 3))) (_o$7295 (keyword #f "collect-safe")) (_o$7296 (let* ((and__25__auto (jolt= 5 (jolt-count items)))) (if (jolt-truthy? and__25__auto) (jolt= "collect-safe" (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 4))) and__25__auto)))) (jolt-hash-map _o$7287 _o$7288 _o$7289 _o$7290 _o$7291 _o$7292 _o$7293 _o$7294 _o$7295 _o$7296))))))) analyze-ffi-callable))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-ctor" (letrec ((analyze-ctor (lambda (ctx class args env) (let fnrec9041 ((ctx ctx) (class class) (args args) (env env)) (let* ((_a$9043 (var-deref "jolt.ir" "host-new")) (_a$9044 (let* ((or__26__auto (jolt-invoke (var-deref "jolt.host" "deftype-ctor-class") ctx class))) (if (jolt-truthy? or__26__auto) or__26__auto class))) (_a$9045 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__101_) (let fnrec9042 ((p__101_ p__101_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__101_ env))) args))) (jolt-invoke _a$9043 _a$9044 _a$9045)))))) analyze-ctor) (let* ((_o$9046 (keyword #f "private")) (_o$9047 #t)) (jolt-hash-map _o$9046 _o$9047)))) + (def-var! "jolt.analyzer" "analyze-dot" (letrec ((analyze-dot (lambda (ctx items env) (let fnrec7297 ((ctx ctx) (items items) (env env)) (begin (if (< (jolt-count items) 3) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed (. target member ...) form")) jolt-nil) (let* ((target (jolt-nth items 1)) (member (jolt-nth items 2)) (class-target (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") target))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.analyzer" "local?") env (jolt-invoke (var-deref "jolt.host" "form-sym-name") target))) and__25__auto))) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx target))) (if (jolt= (keyword #f "class") (jolt-get r (keyword #f "kind"))) (jolt-get r (keyword #f "name")) jolt-nil)) jolt-nil))) (if (jolt-truthy? 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(jolt-invoke (var-deref "jolt.host" "form-keyword?") member)) (let* ((_a$7317 (var-deref "jolt.ir" "invoke")) (_a$7318 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx member env)) (_a$7319 (jolt-vector (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)))) (jolt-invoke _a$7317 _a$7318 _a$7319)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "special form . (non-symbol member)") jolt-nil)))))))))) analyze-dot))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-ffi-fn" (letrec ((analyze-ffi-fn (lambda (ctx items env) (let fnrec9048 ((ctx ctx) (items items) (env env)) (begin (if (jolt-not (jolt-n<= 4 (jolt-count items) 5)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi/foreign-fn expects (foreign-fn \"sym\" [argtypes] rettype [:blocking])")) jolt-nil) (let* ((_o$9049 (keyword #f "op")) (_o$9050 (keyword #f "ffi-fn")) (_o$9051 (keyword #f "csym")) (_o$9052 (jolt-nth items 1)) (_o$9053 (keyword #f "argtypes")) (_o$9054 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "name") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 2)))) (_o$9055 (keyword #f "rettype")) (_o$9056 (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 3))) (_o$9057 (keyword #f "blocking")) (_o$9058 (let* ((and__25__auto (jolt= 5 (jolt-count items)))) (if (jolt-truthy? and__25__auto) (jolt= "blocking" (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 4))) and__25__auto)))) (jolt-hash-map _o$9049 _o$9050 _o$9051 _o$9052 _o$9053 _o$9054 _o$9055 _o$9056 _o$9057 _o$9058))))))) analyze-ffi-fn) (let* ((_o$9059 (keyword #f "private")) (_o$9060 #t)) (jolt-hash-map _o$9059 _o$9060)))) + (def-var! "jolt.analyzer" "analyze-field" (letrec ((analyze-field (lambda (ctx hname items env) (let fnrec7320 ((ctx ctx) (hname hname) (items items) (env env)) (begin (if (< (jolt-count items) 2) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed (.-field target) form")) jolt-nil) (let* ((_o$7321 (keyword #f "op")) (_o$7322 (keyword #f "host-call")) (_o$7323 (keyword #f "method")) (_o$7324 (jolt-invoke (var-deref "clojure.core" "subs") hname 1)) (_o$7325 (keyword #f "target")) (_o$7326 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$7327 (keyword #f "args")) (_o$7328 (jolt-vector))) (jolt-hash-map _o$7321 _o$7322 _o$7323 _o$7324 _o$7325 _o$7326 _o$7327 _o$7328))))))) analyze-field))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-ffi-callable" (letrec ((analyze-ffi-callable (lambda (ctx items env) (let fnrec9061 ((ctx ctx) (items items) (env env)) (begin (if (jolt-not (jolt-n<= 4 (jolt-count items) 5)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi/foreign-callable expects (foreign-callable f [argtypes] rettype [:collect-safe])")) jolt-nil) (let* ((_o$9062 (keyword #f "op")) (_o$9063 (keyword #f "ffi-callable")) (_o$9064 (keyword #f "fn")) (_o$9065 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$9066 (keyword #f "argtypes")) (_o$9067 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "name") (jolt-invoke (var-deref "jolt.host" "form-vec-items") (jolt-nth items 2)))) (_o$9068 (keyword #f "rettype")) (_o$9069 (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 3))) (_o$9070 (keyword #f "collect-safe")) (_o$9071 (let* ((and__25__auto (jolt= 5 (jolt-count items)))) (if (jolt-truthy? and__25__auto) (jolt= "collect-safe" (jolt-invoke (var-deref "clojure.core" "name") (jolt-nth items 4))) and__25__auto)))) (jolt-hash-map _o$9062 _o$9063 _o$9064 _o$9065 _o$9066 _o$9067 _o$9068 _o$9069 _o$9070 _o$9071))))))) analyze-ffi-callable) (let* ((_o$9072 (keyword #f "private")) (_o$9073 #t)) (jolt-hash-map _o$9072 _o$9073)))) + (def-var! "jolt.analyzer" "analyze-symbol" (letrec ((analyze-symbol (lambda (ctx form env) (let fnrec7329 ((ctx ctx) (form form) (env env)) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") form)) (ns (jolt-invoke (var-deref "jolt.host" "form-sym-ns") form))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "nil?") ns))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "local?") env nm) and__25__auto))) (let* ((h (jolt-get (jolt-get env (keyword #f "hints")) nm))) (if (jolt-truthy? h) (jolt-assoc (jolt-invoke (var-deref "jolt.ir" "local") nm) (keyword #f "hint") h) (jolt-invoke (var-deref "jolt.ir" "local") nm))) (if (jolt-truthy? ns) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx form))) (if (jolt= (keyword #f "var") (jolt-get r (keyword #f "kind"))) (let* ((G__134 (let* ((_a$7330 (var-deref "jolt.ir" "var-ref")) (_a$7331 (jolt-get r (keyword #f "ns"))) (_a$7332 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$7330 _a$7331 _a$7332)))) (let* ((G__135 (if (jolt-truthy? (jolt-get r (keyword #f "num-ret"))) (jolt-assoc G__134 (keyword #f "num-ret") (jolt-get r (keyword #f "num-ret"))) G__134))) G__135)) (jolt-invoke (var-deref "jolt.ir" "host-static") ns nm))) (if (jolt-truthy? (keyword #f "else")) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx form))) (let* ((G__136 (jolt-get r (keyword #f "kind")))) (if (jolt= G__136 (keyword #f "var")) (let* ((G__137 (let* ((_a$7333 (var-deref "jolt.ir" "var-ref")) (_a$7334 (jolt-get r (keyword #f "ns"))) (_a$7335 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$7333 _a$7334 _a$7335)))) (let* ((G__138 (if (jolt-truthy? (jolt-get r (keyword #f "num-ret"))) (jolt-assoc G__137 (keyword #f "num-ret") (jolt-get r (keyword #f "num-ret"))) G__137))) G__138)) (if (jolt= G__136 (keyword #f "host")) (jolt-invoke (var-deref "jolt.ir" "host-ref") (jolt-get r (keyword #f "name"))) (if (jolt= G__136 (keyword #f "class")) (jolt-invoke (var-deref "jolt.ir" "const") (jolt-get r (keyword #f "name"))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "late-bind?") ctx)) (jolt-invoke (var-deref "jolt.ir" "var-ref") (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx) nm) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") (jolt-invoke (var-deref "clojure.core" "str") "Unable to resolve symbol: " nm " in this context")))))))) jolt-nil)))))))) analyze-symbol))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-dot" (letrec ((analyze-dot (lambda (ctx items env) (let fnrec9074 ((ctx ctx) (items items) (env env)) (begin (if (jolt-n< (jolt-count items) 3) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed (. target member ...) form")) jolt-nil) (let* ((member0 (jolt-nth items 2)) (items (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") member0)) (let* ((ml (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") member0)))) (let* ((_a$9078 (let* ((_o$9075 (jolt-nth items 0)) (_o$9076 (jolt-nth items 1)) (_o$9077 (jolt-first ml))) (jolt-vector _o$9075 _o$9076 _o$9077))) (_a$9079 (jolt-rest ml))) (jolt-into _a$9078 _a$9079))) items)) (target (jolt-nth items 1)) (member (jolt-nth items 2)) (class-target (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") target))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.analyzer" "local?") env (jolt-invoke (var-deref "jolt.host" "form-sym-name") target))) and__25__auto))) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx target))) (if (jolt= (keyword #f "class") (jolt-get r (keyword #f "kind"))) (jolt-get r (keyword #f "name")) jolt-nil)) jolt-nil))) (if (jolt-truthy? (let* ((and__25__auto class-target)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") member) and__25__auto))) (let* ((_a$9084 (var-deref "jolt.ir" "invoke")) (_a$9085 (jolt-invoke (var-deref "jolt.ir" "host-static") class-target (jolt-invoke (var-deref "jolt.host" "form-sym-name") member))) (_a$9086 (let* ((_a$9081 (var-deref "clojure.core" "mapv")) (_a$9082 (lambda (p__102_) (let fnrec9080 ((p__102_ p__102_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__102_ env)))) (_a$9083 (jolt-drop 3 items))) (jolt-invoke _a$9081 _a$9082 _a$9083)))) (jolt-invoke _a$9084 _a$9085 _a$9086)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") member)) (let* ((_o$9091 (keyword #f "op")) (_o$9092 (keyword #f "host-call")) (_o$9093 (keyword #f "method")) (_o$9094 (jolt-invoke (var-deref "jolt.host" "form-sym-name") member)) (_o$9095 (keyword #f "target")) (_o$9096 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx target env)) (_o$9097 (keyword #f "args")) (_o$9098 (let* ((_a$9088 (var-deref "clojure.core" "mapv")) (_a$9089 (lambda (p__103_) (let fnrec9087 ((p__103_ p__103_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__103_ env)))) (_a$9090 (jolt-drop 3 items))) (jolt-invoke _a$9088 _a$9089 _a$9090)))) (jolt-hash-map _o$9091 _o$9092 _o$9093 _o$9094 _o$9095 _o$9096 _o$9097 _o$9098)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-keyword?") member)) (let* ((_a$9099 (var-deref "jolt.ir" "invoke")) (_a$9100 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx member env)) (_a$9101 (jolt-vector (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)))) (jolt-invoke _a$9099 _a$9100 _a$9101)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "special form . (non-symbol member)") jolt-nil)))))))))) analyze-dot) (let* ((_o$9102 (keyword #f "private")) (_o$9103 #t)) (jolt-hash-map _o$9102 _o$9103)))) + (def-var! "jolt.analyzer" "analyze-list" (letrec ((analyze-list (lambda (ctx form env) (let fnrec7336 ((ctx ctx) (form form) (env env)) (let* ((items (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") form)))) (if (jolt-zero? (jolt-count items)) (jolt-invoke (var-deref "jolt.ir" "quote-node") form) (let* ((head (jolt-first items)) (hname (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil)) (shadowed (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "local?") env hname) and__25__auto)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-contains? (var-deref "jolt.analyzer" "handled") hname)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-macro?") ctx head) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-invoke (var-deref "jolt.host" "form-expand-1") ctx form) env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "jolt.ffi" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)))) (if (jolt-truthy? and__25__auto) (jolt= "__cfn" (jolt-invoke (var-deref "jolt.host" "form-sym-name") head)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-ffi-fn") ctx items env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "jolt.ffi" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)))) (if (jolt-truthy? and__25__auto) (jolt= "__ccallable" (jolt-invoke (var-deref "jolt.host" "form-sym-name") head)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-ffi-callable") ctx items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (jolt-contains? (var-deref "jolt.analyzer" "handled") hname) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-special") ctx hname items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "method-head?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-host-call") ctx hname items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "ctor-head?") hname) and__25__auto)) and__25__auto))) (let* ((_a$7337 (var-deref "jolt.analyzer" "analyze-ctor")) (_a$7338 ctx) (_a$7339 (jolt-invoke (var-deref "clojure.core" "subs") hname 0 (jolt-dec (jolt-count hname)))) (_a$7340 (jolt-rest items)) (_a$7341 env)) (jolt-invoke _a$7337 _a$7338 _a$7339 _a$7340 _a$7341)) (if (jolt-truthy? (let* ((and__25__auto (jolt= hname "new"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= (jolt-count items) 2))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth items 1)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_a$7342 (var-deref "jolt.analyzer" "analyze-ctor")) (_a$7343 ctx) (_a$7344 (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth items 1))) (_a$7345 (jolt-drop 2 items)) (_a$7346 env)) (jolt-invoke _a$7342 _a$7343 _a$7344 _a$7345 _a$7346)) (if (jolt-truthy? (let* ((and__25__auto (jolt= hname "."))) (if (jolt-truthy? and__25__auto) (jolt-not shadowed) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-dot") ctx items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "field-head?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-field") ctx hname items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-special?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") (jolt-invoke (var-deref "clojure.core" "str") "special form " hname)) (if (jolt-truthy? (keyword #f "else")) (let* ((n (let* ((_a$7351 (var-deref "jolt.ir" "invoke")) (_a$7352 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx head env)) (_a$7353 (let* ((_a$7348 (var-deref "clojure.core" "mapv")) (_a$7349 (lambda (p__93_) (let fnrec7347 ((p__93_ p__93_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__93_ env)))) (_a$7350 (jolt-rest items))) (jolt-invoke _a$7348 _a$7349 _a$7350)))) (jolt-invoke _a$7351 _a$7352 _a$7353))) (p (jolt-invoke (var-deref "jolt.host" "form-position") form))) (if (jolt-truthy? p) (jolt-assoc n (keyword #f "pos") p) n)) jolt-nil)))))))))))))))))) analyze-list))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-field" (letrec ((analyze-field (lambda (ctx hname items env) (let fnrec9104 ((ctx ctx) (hname hname) (items items) (env env)) (begin (if (jolt-n< (jolt-count items) 2) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Malformed (.-field target) form")) jolt-nil) (let* ((_o$9105 (keyword #f "op")) (_o$9106 (keyword #f "host-call")) (_o$9107 (keyword #f "method")) (_o$9108 (jolt-invoke (var-deref "clojure.core" "subs") hname 1)) (_o$9109 (keyword #f "target")) (_o$9110 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-nth items 1) env)) (_o$9111 (keyword #f "args")) (_o$9112 (jolt-vector))) (jolt-hash-map _o$9105 _o$9106 _o$9107 _o$9108 _o$9109 _o$9110 _o$9111 _o$9112))))))) analyze-field) (let* ((_o$9113 (keyword #f "private")) (_o$9114 #t)) (jolt-hash-map _o$9113 _o$9114)))) + (def-var! "jolt.analyzer" "with-coll-meta" (letrec ((with-coll-meta (lambda (ctx form env node) (let fnrec7354 ((ctx ctx) (form form) (env env) (node node)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-coll-meta") form))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") m)) node (let* ((_a$7357 (var-deref "jolt.ir" "invoke")) (_a$7358 (jolt-invoke (var-deref "jolt.ir" "var-ref") "clojure.core" "with-meta")) (_a$7359 (let* ((_o$7355 node) (_o$7356 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx m env))) (jolt-vector _o$7355 _o$7356)))) (jolt-invoke _a$7357 _a$7358 _a$7359)))))))) with-coll-meta))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-symbol" (letrec ((analyze-symbol (lambda (ctx form env) (let fnrec9115 ((ctx ctx) (form form) (env env)) (let* ((nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") form)) (ns (jolt-invoke (var-deref "jolt.host" "form-sym-ns") form))) (if (jolt-truthy? (let* ((and__25__auto (jolt-nil? ns))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "local?") env nm) and__25__auto))) (let* ((h (jolt-get (jolt-get env (keyword #f "hints")) nm))) (if (jolt-truthy? h) (jolt-assoc (jolt-invoke (var-deref "jolt.ir" "local") nm) (keyword #f "hint") h) (jolt-invoke (var-deref "jolt.ir" "local") nm))) (if (jolt-truthy? ns) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx form))) (if (jolt= (keyword #f "var") (jolt-get r (keyword #f "kind"))) (let* ((G__153 (let* ((_a$9116 (var-deref "jolt.ir" "var-ref")) (_a$9117 (jolt-get r (keyword #f "ns"))) (_a$9118 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$9116 _a$9117 _a$9118)))) (let* ((G__154 (if (jolt-truthy? (jolt-get r (keyword #f "num-ret"))) (jolt-assoc G__153 (keyword #f "num-ret") (jolt-get r (keyword #f "num-ret"))) G__153))) G__154)) (jolt-invoke (var-deref "jolt.ir" "host-static") ns nm))) (if (jolt-truthy? (keyword #f "else")) (let* ((r (jolt-invoke (var-deref "jolt.host" "resolve-global") ctx form))) (let* ((G__155 (jolt-get r (keyword #f "kind")))) (if (jolt= G__155 (keyword #f "var")) (let* ((G__156 (let* ((_a$9119 (var-deref "jolt.ir" "var-ref")) (_a$9120 (jolt-get r (keyword #f "ns"))) (_a$9121 (jolt-get r (keyword #f "name")))) (jolt-invoke _a$9119 _a$9120 _a$9121)))) (let* ((G__157 (if (jolt-truthy? (jolt-get r (keyword #f "num-ret"))) (jolt-assoc G__156 (keyword #f "num-ret") (jolt-get r (keyword #f "num-ret"))) G__156))) G__157)) (if (jolt= G__155 (keyword #f "host")) (jolt-invoke (var-deref "jolt.ir" "host-ref") (jolt-get r (keyword #f "name"))) (if (jolt= G__155 (keyword #f "class")) (jolt-invoke (var-deref "jolt.ir" "const") (jolt-get r (keyword #f "name"))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "late-bind?") ctx)) (jolt-invoke (var-deref "jolt.ir" "var-ref") (jolt-invoke (var-deref "jolt.host" "compile-ns") ctx) nm) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") (jolt-invoke (var-deref "clojure.core" "str") "Unable to resolve symbol: " nm " in this context")))))))) jolt-nil)))))))) analyze-symbol) (let* ((_o$9122 (keyword #f "private")) (_o$9123 #t)) (jolt-hash-map _o$9122 _o$9123)))) + (def-var! "jolt.analyzer" "analyze" (letrec ((analyze (case-lambda ((ctx form) (let fnrec7360 ((ctx ctx) (form form)) (jolt-invoke analyze ctx form (jolt-invoke (var-deref "jolt.analyzer" "empty-env"))))) ((ctx form env) (let fnrec7361 ((ctx ctx) (form form) (env env)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-literal?") form)) (jolt-invoke (var-deref "jolt.ir" "const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") form)) (jolt-invoke (var-deref "jolt.analyzer" "analyze-symbol") ctx form env) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "vector-node") (let* ((_a$7363 (var-deref "clojure.core" "mapv")) (_a$7364 (lambda (p__94_) (let fnrec7362 ((p__94_ p__94_)) (jolt-invoke analyze ctx p__94_ env)))) (_a$7365 (jolt-invoke (var-deref "jolt.host" "form-vec-items") form))) (jolt-invoke _a$7363 _a$7364 _a$7365)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-map?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "map-node") (let* ((_a$7369 (var-deref "clojure.core" "mapv")) (_a$7370 (lambda (p) (let fnrec7366 ((p p)) (let* ((_o$7367 (jolt-invoke analyze ctx (jolt-first p) env)) (_o$7368 (jolt-invoke analyze ctx (jolt-invoke (var-deref "clojure.core" "second") p) env))) (jolt-vector _o$7367 _o$7368))))) (_a$7371 (jolt-invoke (var-deref "jolt.host" "form-map-pairs") form))) (jolt-invoke _a$7369 _a$7370 _a$7371)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-set?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "set-node") (let* ((_a$7373 (var-deref "clojure.core" "mapv")) (_a$7374 (lambda (p__95_) (let fnrec7372 ((p__95_ p__95_)) (jolt-invoke analyze ctx p__95_ env)))) (_a$7375 (jolt-invoke (var-deref "jolt.host" "form-set-items") form))) (jolt-invoke _a$7373 _a$7374 _a$7375)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (jolt-invoke (var-deref "jolt.analyzer" "analyze-list") ctx form env) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-regex?") form)) (let* ((_o$7376 (keyword #f "op")) (_o$7377 (keyword #f "regex")) (_o$7378 (keyword #f "source")) (_o$7379 (jolt-invoke (var-deref "jolt.host" "form-regex-source") form))) (jolt-hash-map _o$7376 _o$7377 _o$7378 _o$7379)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-inst?") form)) (let* ((_o$7380 (keyword #f "op")) (_o$7381 (keyword #f "inst")) (_o$7382 (keyword #f "source")) (_o$7383 (jolt-invoke (var-deref "jolt.host" "form-inst-source") form))) (jolt-hash-map _o$7380 _o$7381 _o$7382 _o$7383)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-uuid?") form)) (let* ((_o$7384 (keyword #f "op")) (_o$7385 (keyword #f "uuid")) (_o$7386 (keyword #f "source")) (_o$7387 (jolt-invoke (var-deref "jolt.host" "form-uuid-source") form))) (jolt-hash-map _o$7384 _o$7385 _o$7386 _o$7387)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-bigdec?") form)) (let* ((_o$7388 (keyword #f "op")) (_o$7389 (keyword #f "bigdec")) (_o$7390 (keyword #f "source")) (_o$7391 (jolt-invoke (var-deref "jolt.host" "form-bigdec-source") form))) (jolt-hash-map _o$7388 _o$7389 _o$7390 _o$7391)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-ns-value?") form)) (let* ((_o$7392 (keyword #f "op")) (_o$7393 (keyword #f "the-ns")) (_o$7394 (keyword #f "name")) (_o$7395 (jolt-invoke (var-deref "jolt.host" "form-ns-value-name") form))) (jolt-hash-map _o$7392 _o$7393 _o$7394 _o$7395)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "unsupported form") jolt-nil))))))))))))))))) analyze))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "unchecked-arith" (letrec ((unchecked-arith (lambda (hname n) (let fnrec9124 ((hname hname) (n n)) (if (jolt= hname "+") "unchecked-add" (if (jolt= hname "*") "unchecked-multiply" (if (jolt= hname "-") (if (jolt= n 2) "unchecked-negate" "unchecked-subtract") (if (jolt= hname "inc") "unchecked-inc" (if (jolt= hname "dec") "unchecked-dec" (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))))))) unchecked-arith) (let* ((_o$9125 (keyword #f "private")) (_o$9126 #t)) (jolt-hash-map _o$9125 _o$9126)))) + (def-var-with-meta! "jolt.backend-scheme" "native-ops" (let* ((_o$5955 "+") (_o$5956 "+") (_o$5957 "-") (_o$5958 "-") (_o$5959 "*") (_o$5960 "*") (_o$5961 "/") (_o$5962 "/") (_o$5963 "<") (_o$5964 "<") (_o$5965 ">") (_o$5966 ">") (_o$5967 "<=") (_o$5968 "<=") (_o$5969 ">=") (_o$5970 ">=") (_o$5971 "=") (_o$5972 "jolt=") (_o$5973 "inc") (_o$5974 "jolt-inc") (_o$5975 "dec") (_o$5976 "jolt-dec") (_o$5977 "not") (_o$5978 "jolt-not") (_o$5979 "min") (_o$5980 "min") (_o$5981 "max") (_o$5982 "max") (_o$5983 "mod") (_o$5984 "modulo") (_o$5985 "rem") (_o$5986 "remainder") (_o$5987 "quot") (_o$5988 "quotient") (_o$5989 "vector") (_o$5990 "jolt-vector") (_o$5991 "hash-map") (_o$5992 "jolt-hash-map") (_o$5993 "hash-set") (_o$5994 "jolt-hash-set") (_o$5995 "conj") (_o$5996 "jolt-conj") (_o$5997 "get") (_o$5998 "jolt-get") (_o$5999 "nth") (_o$6000 "jolt-nth") (_o$6001 "count") (_o$6002 "jolt-count") (_o$6003 "assoc") (_o$6004 "jolt-assoc") (_o$6005 "dissoc") (_o$6006 "jolt-dissoc") (_o$6007 "contains?") (_o$6008 "jolt-contains?") (_o$6009 "empty?") (_o$6010 "jolt-empty?") (_o$6011 "peek") (_o$6012 "jolt-peek") (_o$6013 "pop") (_o$6014 "jolt-pop") (_o$6015 "first") (_o$6016 "jolt-first") (_o$6017 "rest") (_o$6018 "jolt-rest") (_o$6019 "next") (_o$6020 "jolt-next") (_o$6021 "seq") (_o$6022 "jolt-seq") (_o$6023 "cons") (_o$6024 "jolt-cons") (_o$6025 "list") (_o$6026 "jolt-list") (_o$6027 "reverse") (_o$6028 "jolt-reverse") (_o$6029 "last") (_o$6030 "jolt-last") (_o$6031 "map") (_o$6032 "jolt-map") (_o$6033 "filter") (_o$6034 "jolt-filter") (_o$6035 "remove") (_o$6036 "jolt-remove") (_o$6037 "reduce") (_o$6038 "jolt-reduce") (_o$6039 "into") (_o$6040 "jolt-into") (_o$6041 "concat") (_o$6042 "jolt-concat") (_o$6043 "apply") (_o$6044 "jolt-apply") (_o$6045 "range") (_o$6046 "jolt-range") (_o$6047 "take") (_o$6048 "jolt-take") (_o$6049 "drop") (_o$6050 "jolt-drop") (_o$6051 "keys") (_o$6052 "jolt-keys") (_o$6053 "vals") (_o$6054 "jolt-vals") (_o$6055 "even?") (_o$6056 "jolt-even?") (_o$6057 "odd?") (_o$6058 "jolt-odd?") (_o$6059 "pos?") (_o$6060 "jolt-pos?") (_o$6061 "neg?") (_o$6062 "jolt-neg?") (_o$6063 "zero?") (_o$6064 "jolt-zero?") (_o$6065 "identity") (_o$6066 "jolt-identity") (_o$6067 "ex-info") (_o$6068 "jolt-ex-info")) (jolt-hash-map _o$5955 _o$5956 _o$5957 _o$5958 _o$5959 _o$5960 _o$5961 _o$5962 _o$5963 _o$5964 _o$5965 _o$5966 _o$5967 _o$5968 _o$5969 _o$5970 _o$5971 _o$5972 _o$5973 _o$5974 _o$5975 _o$5976 _o$5977 _o$5978 _o$5979 _o$5980 _o$5981 _o$5982 _o$5983 _o$5984 _o$5985 _o$5986 _o$5987 _o$5988 _o$5989 _o$5990 _o$5991 _o$5992 _o$5993 _o$5994 _o$5995 _o$5996 _o$5997 _o$5998 _o$5999 _o$6000 _o$6001 _o$6002 _o$6003 _o$6004 _o$6005 _o$6006 _o$6007 _o$6008 _o$6009 _o$6010 _o$6011 _o$6012 _o$6013 _o$6014 _o$6015 _o$6016 _o$6017 _o$6018 _o$6019 _o$6020 _o$6021 _o$6022 _o$6023 _o$6024 _o$6025 _o$6026 _o$6027 _o$6028 _o$6029 _o$6030 _o$6031 _o$6032 _o$6033 _o$6034 _o$6035 _o$6036 _o$6037 _o$6038 _o$6039 _o$6040 _o$6041 _o$6042 _o$6043 _o$6044 _o$6045 _o$6046 _o$6047 _o$6048 _o$6049 _o$6050 _o$6051 _o$6052 _o$6053 _o$6054 _o$6055 _o$6056 _o$6057 _o$6058 _o$6059 _o$6060 _o$6061 _o$6062 _o$6063 _o$6064 _o$6065 _o$6066 _o$6067 _o$6068)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "analyze-list" (letrec ((analyze-list (lambda (ctx form env) (let fnrec9127 ((ctx ctx) (form form) (env env)) (let* ((items (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "jolt.host" "form-elements") form)))) (if (jolt-zero? (jolt-count items)) (jolt-invoke (var-deref "jolt.ir" "quote-node") form) (let* ((head (jolt-first items)) (hname (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (jolt-nil? (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil)) (sf-name (let* ((or__26__auto hname)) (if (jolt-truthy? or__26__auto) or__26__auto (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)))) (if (jolt-truthy? and__25__auto) (jolt-contains? (var-deref "jolt.analyzer" "handled") (jolt-invoke (var-deref "jolt.host" "form-sym-name") head)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil)))) (shadowed (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "local?") env hname) and__25__auto))) (unm (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "unchecked-math?"))) (let* ((opn (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (jolt-not shadowed) and__25__auto))) hname (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)) and__25__auto))) (jolt-invoke (var-deref "jolt.host" "form-sym-name") head) jolt-nil)))) (if (jolt-truthy? opn) (jolt-invoke (var-deref "jolt.analyzer" "unchecked-arith") opn (jolt-count items)) jolt-nil)) jolt-nil))) (if (jolt-truthy? unm) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (let* ((_a$9128 (jolt-invoke (var-deref "clojure.core" "symbol") unm)) (_a$9129 (jolt-rest items))) (jolt-cons _a$9128 _a$9129)) env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-contains? (var-deref "jolt.analyzer" "handled") sf-name)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-macro?") ctx head) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((node (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx (jolt-invoke (var-deref "jolt.host" "form-expand-1") ctx form (jolt-invoke (var-deref "jolt.analyzer" "amp-env-map") env)) env)) (p (jolt-invoke (var-deref "jolt.host" "form-position") form))) (if (jolt-truthy? (let* ((and__25__auto p)) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))) and__25__auto))) (jolt-assoc node (keyword #f "pos") p) node)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "jolt.ffi" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)))) (if (jolt-truthy? and__25__auto) (jolt= "__cfn" (jolt-invoke (var-deref "jolt.host" "form-sym-name") head)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-ffi-fn") ctx items env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "form-sym?") head))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "jolt.ffi" (jolt-invoke (var-deref "jolt.host" "form-sym-ns") head)))) (if (jolt-truthy? and__25__auto) (jolt= "__ccallable" (jolt-invoke (var-deref "jolt.host" "form-sym-name") head)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-ffi-callable") ctx items env) (if (jolt-truthy? (let* ((and__25__auto sf-name)) (if (jolt-truthy? and__25__auto) (jolt-contains? (var-deref "jolt.analyzer" "handled") sf-name) and__25__auto))) (let* ((node (jolt-invoke (var-deref "jolt.analyzer" "analyze-special") ctx sf-name items env)) (p (jolt-invoke (var-deref "jolt.host" "form-position") form))) (if (jolt-truthy? (let* ((and__25__auto p)) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))) and__25__auto))) (jolt-assoc node (keyword #f "pos") p) node)) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "method-head?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-host-call") ctx hname items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "ctor-head?") hname) and__25__auto)) and__25__auto))) (let* ((_a$9130 (var-deref "jolt.analyzer" "analyze-ctor")) (_a$9131 ctx) (_a$9132 (jolt-invoke (var-deref "clojure.core" "subs") hname 0 (jolt-dec (jolt-count hname)))) (_a$9133 (jolt-rest items)) (_a$9134 env)) (jolt-invoke _a$9130 _a$9131 _a$9132 _a$9133 _a$9134)) (if (jolt-truthy? (let* ((and__25__auto (jolt= hname "new"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n>= (jolt-count items) 2))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-sym?") (jolt-nth items 1)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_a$9135 (var-deref "jolt.analyzer" "analyze-ctor")) (_a$9136 ctx) (_a$9137 (jolt-invoke (var-deref "jolt.host" "form-sym-name") (jolt-nth items 1))) (_a$9138 (jolt-drop 2 items)) (_a$9139 env)) (jolt-invoke _a$9135 _a$9136 _a$9137 _a$9138 _a$9139)) (if (let* ((and__25__auto (jolt= hname "."))) (if (jolt-truthy? and__25__auto) (jolt-not shadowed) and__25__auto)) (jolt-invoke (var-deref "jolt.analyzer" "analyze-dot") ctx items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.analyzer" "field-head?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "analyze-field") ctx hname items env) (if (jolt-truthy? (let* ((and__25__auto hname)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not shadowed))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "form-special?") hname) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") (jolt-invoke (var-deref "clojure.core" "str") "special form " hname)) (if (jolt-truthy? (keyword #f "else")) (let* ((n (let* ((_a$9144 (var-deref "jolt.ir" "invoke")) (_a$9145 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx head env)) (_a$9146 (let* ((_a$9141 (var-deref "clojure.core" "mapv")) (_a$9142 (lambda (p__104_) (let fnrec9140 ((p__104_ p__104_)) (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx p__104_ env)))) (_a$9143 (jolt-rest items))) (jolt-invoke _a$9141 _a$9142 _a$9143)))) (jolt-invoke _a$9144 _a$9145 _a$9146))) (p (jolt-invoke (var-deref "jolt.host" "form-position") form))) (if (jolt-truthy? p) (jolt-assoc n (keyword #f "pos") p) n)) jolt-nil))))))))))))))))))) analyze-list) (let* ((_o$9147 (keyword #f "private")) (_o$9148 #t)) (jolt-hash-map _o$9147 _o$9148)))) + (def-var-with-meta! "jolt.backend-scheme" "core-value-procs" (jolt-invoke (var-deref "clojure.core" "merge") (var-deref "jolt.backend-scheme" "native-ops") (let* ((_o$6069 "+") (_o$6070 "jolt-add") (_o$6071 "-") (_o$6072 "jolt-sub") (_o$6073 "*") (_o$6074 "jolt-mul") (_o$6075 "/") (_o$6076 "jolt-div")) (jolt-hash-map _o$6069 _o$6070 _o$6071 _o$6072 _o$6073 _o$6074 _o$6075 _o$6076))) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.analyzer" "with-coll-meta" (letrec ((with-coll-meta (lambda (ctx form env node) (let fnrec9149 ((ctx ctx) (form form) (env env) (node node)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-coll-meta") form))) (if (jolt-nil? m) node (let* ((_a$9152 (var-deref "jolt.ir" "invoke")) (_a$9153 (jolt-invoke (var-deref "jolt.ir" "var-ref") "clojure.core" "with-meta")) (_a$9154 (let* ((_o$9150 node) (_o$9151 (jolt-invoke (var-deref "jolt.analyzer" "analyze") ctx m env))) (jolt-vector _o$9150 _o$9151)))) (jolt-invoke _a$9152 _a$9153 _a$9154)))))))) with-coll-meta) (let* ((_o$9155 (keyword #f "private")) (_o$9156 #t)) (jolt-hash-map _o$9155 _o$9156)))) + (def-var-with-meta! 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"jolt.analyzer" "analyze" (letrec ((analyze (case-lambda ((ctx form) (let fnrec9157 ((ctx ctx) (form form)) (analyze ctx form (jolt-invoke (var-deref "jolt.analyzer" "empty-env"))))) ((ctx form env) (let fnrec9158 ((ctx ctx) (form form) (env env)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-literal?") form)) (jolt-invoke (var-deref "jolt.ir" "const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") form)) (jolt-invoke (var-deref "jolt.analyzer" "analyze-symbol") ctx form env) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "vector-node") (let* ((_a$9160 (var-deref "clojure.core" "mapv")) (_a$9161 (lambda (p__105_) (let fnrec9159 ((p__105_ p__105_)) (analyze ctx p__105_ env)))) (_a$9162 (jolt-invoke (var-deref "jolt.host" "form-vec-items") form))) (jolt-invoke _a$9160 _a$9161 _a$9162)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-map?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "map-node") (let* ((_a$9166 (var-deref "clojure.core" "mapv")) (_a$9167 (lambda (p) (let fnrec9163 ((p p)) (let* ((_o$9164 (analyze ctx (jolt-first p) env)) (_o$9165 (analyze ctx (jolt-invoke (var-deref "clojure.core" "second") p) env))) (jolt-vector _o$9164 _o$9165))))) (_a$9168 (jolt-invoke (var-deref "jolt.host" "form-map-pairs") form))) (jolt-invoke _a$9166 _a$9167 _a$9168)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-set?") form)) (jolt-invoke (var-deref "jolt.analyzer" "with-coll-meta") ctx form env (jolt-invoke (var-deref "jolt.ir" "set-node") (let* ((_a$9170 (var-deref "clojure.core" "mapv")) (_a$9171 (lambda (p__106_) (let fnrec9169 ((p__106_ p__106_)) (analyze ctx p__106_ env)))) (_a$9172 (jolt-invoke (var-deref "jolt.host" "form-set-items") form))) (jolt-invoke _a$9170 _a$9171 _a$9172)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (jolt-invoke (var-deref "jolt.analyzer" "analyze-list") ctx form env) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-regex?") form)) (let* ((_o$9173 (keyword #f "op")) (_o$9174 (keyword #f "regex")) (_o$9175 (keyword #f "source")) (_o$9176 (jolt-invoke (var-deref "jolt.host" "form-regex-source") form))) (jolt-hash-map _o$9173 _o$9174 _o$9175 _o$9176)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-inst?") form)) (let* ((_o$9177 (keyword #f "op")) (_o$9178 (keyword #f "inst")) (_o$9179 (keyword #f "source")) (_o$9180 (jolt-invoke (var-deref "jolt.host" "form-inst-source") form))) (jolt-hash-map _o$9177 _o$9178 _o$9179 _o$9180)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-uuid?") form)) (let* ((_o$9181 (keyword #f "op")) (_o$9182 (keyword #f "uuid")) (_o$9183 (keyword #f "source")) (_o$9184 (jolt-invoke (var-deref "jolt.host" "form-uuid-source") form))) (jolt-hash-map _o$9181 _o$9182 _o$9183 _o$9184)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-bigdec?") form)) (let* ((_o$9185 (keyword #f "op")) (_o$9186 (keyword #f "bigdec")) (_o$9187 (keyword #f "source")) (_o$9188 (jolt-invoke (var-deref "jolt.host" "form-bigdec-source") form))) (jolt-hash-map _o$9185 _o$9186 _o$9187 _o$9188)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-ns-value?") form)) (let* ((_o$9189 (keyword #f "op")) (_o$9190 (keyword #f "the-ns")) (_o$9191 (keyword #f "name")) (_o$9192 (jolt-invoke (var-deref "jolt.host" "form-ns-value-name") form))) (jolt-hash-map _o$9189 _o$9190 _o$9191 _o$9192)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-var-value?") form)) (let* ((_a$9193 (var-deref "jolt.ir" "the-var")) (_a$9194 (jolt-invoke (var-deref "jolt.host" "form-var-value-ns") form)) (_a$9195 (jolt-invoke (var-deref "jolt.host" "form-var-value-name") form))) (jolt-invoke _a$9193 _a$9194 _a$9195)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.analyzer" "uncompilable") "unsupported form") jolt-nil)))))))))))))))))) analyze))) + (def-var-with-meta! "jolt.backend-scheme" "cmp1-ops" (let* ((_o$6200 "<") (_o$6201 ">") (_o$6202 "<=") (_o$6203 ">=")) (jolt-hash-set _o$6200 _o$6201 _o$6202 _o$6203)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "native-ops" (let* ((_o$7267 "+") (_o$7268 "jolt-n+") (_o$7269 "-") (_o$7270 "jolt-n-") (_o$7271 "*") (_o$7272 "jolt-n*") (_o$7273 "/") (_o$7274 "jolt-n-div") (_o$7275 "<") (_o$7276 "jolt-n<") (_o$7277 ">") (_o$7278 "jolt-n>") (_o$7279 "<=") (_o$7280 "jolt-n<=") (_o$7281 ">=") (_o$7282 "jolt-n>=") (_o$7283 "=") (_o$7284 "jolt=") (_o$7285 "inc") (_o$7286 "jolt-inc") (_o$7287 "dec") (_o$7288 "jolt-dec") (_o$7289 "not") (_o$7290 "jolt-not") (_o$7291 "min") (_o$7292 "jolt-n-min") (_o$7293 "max") (_o$7294 "jolt-n-max") (_o$7295 "mod") (_o$7296 "jolt-mod") (_o$7297 "rem") (_o$7298 "jolt-rem") (_o$7299 "quot") (_o$7300 "jolt-quot") (_o$7301 "vector") (_o$7302 "jolt-vector") (_o$7303 "hash-map") (_o$7304 "jolt-hash-map-fn") (_o$7305 "hash-set") (_o$7306 "jolt-hash-set") (_o$7307 "conj") (_o$7308 "jolt-conj") (_o$7309 "get") (_o$7310 "jolt-get") (_o$7311 "nth") (_o$7312 "jolt-nth") (_o$7313 "count") (_o$7314 "jolt-count") (_o$7315 "assoc") (_o$7316 "jolt-assoc") (_o$7317 "dissoc") (_o$7318 "jolt-dissoc") (_o$7319 "contains?") (_o$7320 "jolt-contains?") (_o$7321 "empty?") (_o$7322 "jolt-empty?") (_o$7323 "peek") (_o$7324 "jolt-peek") (_o$7325 "pop") (_o$7326 "jolt-pop") (_o$7327 "first") (_o$7328 "jolt-first") (_o$7329 "rest") (_o$7330 "jolt-rest") (_o$7331 "next") (_o$7332 "jolt-next") (_o$7333 "seq") (_o$7334 "jolt-seq") (_o$7335 "cons") (_o$7336 "jolt-cons") (_o$7337 "list") (_o$7338 "jolt-list") (_o$7339 "reverse") (_o$7340 "jolt-reverse") (_o$7341 "last") (_o$7342 "jolt-last") (_o$7343 "map") (_o$7344 "jolt-map") (_o$7345 "filter") (_o$7346 "jolt-filter") (_o$7347 "remove") (_o$7348 "jolt-remove") (_o$7349 "reduce") (_o$7350 "jolt-reduce") (_o$7351 "into") (_o$7352 "jolt-into") (_o$7353 "concat") (_o$7354 "jolt-concat") (_o$7355 "apply") (_o$7356 "jolt-apply") (_o$7357 "range") (_o$7358 "jolt-range") (_o$7359 "take") (_o$7360 "jolt-take") (_o$7361 "drop") (_o$7362 "jolt-drop") (_o$7363 "keys") (_o$7364 "jolt-keys") (_o$7365 "vals") (_o$7366 "jolt-vals") (_o$7367 "even?") (_o$7368 "jolt-even?") (_o$7369 "odd?") (_o$7370 "jolt-odd?") (_o$7371 "pos?") (_o$7372 "jolt-pos?") (_o$7373 "neg?") (_o$7374 "jolt-neg?") (_o$7375 "zero?") (_o$7376 "jolt-zero?") (_o$7377 "identity") (_o$7378 "jolt-identity") (_o$7379 "nil?") (_o$7380 "jolt-nil?") (_o$7381 "some?") (_o$7382 "jolt-some?") (_o$7383 "ex-info") (_o$7384 "jolt-ex-info") (_o$7385 "bit-and") (_o$7386 "bitwise-and") (_o$7387 "bit-or") (_o$7388 "bitwise-ior") (_o$7389 "bit-xor") (_o$7390 "bitwise-xor") (_o$7391 "bit-not") (_o$7392 "bitwise-not") (_o$7393 "bit-shift-left") (_o$7394 "jolt-bit-shift-left") (_o$7395 "bit-shift-right") (_o$7396 "jolt-bit-shift-right") (_o$7397 "unsigned-bit-shift-right") (_o$7398 "jolt-unsigned-bit-shift-right") (_o$7399 "protocol-dispatch1") (_o$7400 "protocol-dispatch1") (_o$7401 "protocol-dispatch2") (_o$7402 "protocol-dispatch2") (_o$7403 "protocol-dispatch3") (_o$7404 "protocol-dispatch3")) (jolt-hash-map _o$7267 _o$7268 _o$7269 _o$7270 _o$7271 _o$7272 _o$7273 _o$7274 _o$7275 _o$7276 _o$7277 _o$7278 _o$7279 _o$7280 _o$7281 _o$7282 _o$7283 _o$7284 _o$7285 _o$7286 _o$7287 _o$7288 _o$7289 _o$7290 _o$7291 _o$7292 _o$7293 _o$7294 _o$7295 _o$7296 _o$7297 _o$7298 _o$7299 _o$7300 _o$7301 _o$7302 _o$7303 _o$7304 _o$7305 _o$7306 _o$7307 _o$7308 _o$7309 _o$7310 _o$7311 _o$7312 _o$7313 _o$7314 _o$7315 _o$7316 _o$7317 _o$7318 _o$7319 _o$7320 _o$7321 _o$7322 _o$7323 _o$7324 _o$7325 _o$7326 _o$7327 _o$7328 _o$7329 _o$7330 _o$7331 _o$7332 _o$7333 _o$7334 _o$7335 _o$7336 _o$7337 _o$7338 _o$7339 _o$7340 _o$7341 _o$7342 _o$7343 _o$7344 _o$7345 _o$7346 _o$7347 _o$7348 _o$7349 _o$7350 _o$7351 _o$7352 _o$7353 _o$7354 _o$7355 _o$7356 _o$7357 _o$7358 _o$7359 _o$7360 _o$7361 _o$7362 _o$7363 _o$7364 _o$7365 _o$7366 _o$7367 _o$7368 _o$7369 _o$7370 _o$7371 _o$7372 _o$7373 _o$7374 _o$7375 _o$7376 _o$7377 _o$7378 _o$7379 _o$7380 _o$7381 _o$7382 _o$7383 _o$7384 _o$7385 _o$7386 _o$7387 _o$7388 _o$7389 _o$7390 _o$7391 _o$7392 _o$7393 _o$7394 _o$7395 _o$7396 _o$7397 _o$7398 _o$7399 _o$7400 _o$7401 _o$7402 _o$7403 _o$7404)) (let* ((_o$7405 (keyword #f "private")) (_o$7406 #t)) (jolt-hash-map _o$7405 _o$7406)))) + (def-var-with-meta! 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(lambda () (let fnrec6279 () (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "direct-link-defined") (jolt-hash-set)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "direct-link-fns") (jolt-hash-set))))))) direct-link-reset!))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "var-cache?" (jolt-invoke (var-deref "clojure.core" "atom") #f))) + (def-var! "jolt.backend-scheme" "dl-munge" (letrec ((dl-munge (lambda (s) (let fnrec6280 ((s s)) (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") s "$" "_D_") "#" "_H_") "'" "_Q_"))))) dl-munge))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "set-var-cache!" (letrec ((set-var-cache! (lambda (on) (let fnrec7714 ((on on)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "var-cache?") on))))) set-var-cache!))) + (def-var! "jolt.backend-scheme" "dl-name" (letrec ((dl-name (lambda (ns nm) (let fnrec6281 ((ns ns) (nm nm)) (let* ((_a$6282 (var-deref "clojure.core" "str")) (_a$6283 "jv$") (_a$6284 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-munge") ns)) (_a$6285 "$") (_a$6286 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-munge") nm))) (jolt-invoke _a$6282 _a$6283 _a$6284 _a$6285 _a$6286)))))) dl-name))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "trace-frames?" (jolt-invoke (var-deref "clojure.core" "atom") #f))) + (def-var! "jolt.backend-scheme" "dl-fqn" (letrec ((dl-fqn (lambda (ns nm) (let fnrec6287 ((ns ns) (nm nm)) (jolt-invoke (var-deref "clojure.core" "str") ns "/" nm))))) dl-fqn))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "set-trace-frames!" (letrec ((set-trace-frames! (lambda (on) (let fnrec7715 ((on on)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "trace-frames?") on))))) set-trace-frames!))) + (def-var! "jolt.backend-scheme" "direct-linkable?" (letrec ((direct-linkable? (lambda (ns nm) (let fnrec6288 ((ns ns) (nm nm)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link?")))) (if (jolt-truthy? and__25__auto) (let* ((_a$6289 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link-defined"))) (_a$6290 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm))) (jolt-contains? _a$6289 _a$6290)) and__25__auto)))))) direct-linkable?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "dl-munge" (letrec ((dl-munge (lambda (s) (let fnrec7716 ((s s)) (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") s "$" "_D_") "#" "_H_") "'" "_Q_"))))) dl-munge) (let* ((_o$7717 (keyword #f "private")) (_o$7718 #t)) (jolt-hash-map _o$7717 _o$7718)))) + (def-var! "jolt.backend-scheme" "direct-link-fn?" (letrec ((direct-link-fn? (lambda (ns nm) (let fnrec6291 ((ns ns) (nm nm)) (let* ((_a$6292 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link-fns"))) (_a$6293 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm))) (jolt-contains? _a$6292 _a$6293)))))) direct-link-fn?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "dl-name" (letrec ((dl-name (lambda (ns nm) (let fnrec7719 ((ns ns) (nm nm)) (let* ((_a$7720 (var-deref "clojure.core" "str")) (_a$7721 "jv$") (_a$7722 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-munge") ns)) (_a$7723 "$") (_a$7724 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-munge") nm))) (jolt-invoke _a$7720 _a$7721 _a$7722 _a$7723 _a$7724)))))) dl-name) (let* ((_o$7725 (keyword #f "private")) (_o$7726 #t)) (jolt-hash-map _o$7725 _o$7726)))) + (def-var-with-meta! "jolt.backend-scheme" "*recur-target*" jolt-nil (jolt-hash-map (keyword #f "dynamic") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "dl-fqn" (letrec ((dl-fqn (lambda (ns nm) (let fnrec7727 ((ns ns) (nm nm)) (jolt-invoke (var-deref "clojure.core" "str") ns "/" nm))))) dl-fqn) (let* ((_o$7728 (keyword #f "private")) (_o$7729 #t)) (jolt-hash-map _o$7728 _o$7729)))) + (def-var-with-meta! "jolt.backend-scheme" "*known-procs*" (jolt-hash-set) (jolt-hash-map (keyword #f "dynamic") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "direct-linkable?" (letrec ((direct-linkable? (lambda (ns nm) (let fnrec7730 ((ns ns) (nm nm)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link?")))) (if (jolt-truthy? and__25__auto) (let* ((_a$7731 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link-defined"))) (_a$7732 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm))) (jolt-contains? _a$7731 _a$7732)) and__25__auto)))))) direct-linkable?) (let* ((_o$7733 (keyword #f "private")) (_o$7734 #t)) (jolt-hash-map _o$7733 _o$7734)))) + (def-var-with-meta! "jolt.backend-scheme" "gensym-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "direct-link-fn?" (letrec ((direct-link-fn? (lambda (ns nm) (let fnrec7735 ((ns ns) (nm nm)) (let* ((_a$7736 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link-fns"))) (_a$7737 (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm))) (jolt-contains? _a$7736 _a$7737)))))) direct-link-fn?) (let* ((_o$7738 (keyword #f "private")) (_o$7739 #t)) (jolt-hash-map _o$7738 _o$7739)))) + (def-var! "jolt.backend-scheme" "fresh-label" (letrec ((fresh-label (lambda (prefix) (let fnrec6294 ((prefix prefix)) (jolt-invoke (var-deref "clojure.core" "str") prefix (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "gensym-counter") jolt-inc)))))) fresh-label))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "*recur-target*" jolt-nil (let* ((_o$7740 (keyword #f "dynamic")) (_o$7741 #t)) (jolt-hash-map _o$7740 _o$7741)))) + (def-var-with-meta! "jolt.backend-scheme" "scheme-reserved" (let* ((_o$6295 "if") (_o$6296 "begin") (_o$6297 "lambda") (_o$6298 "let") (_o$6299 "let*") (_o$6300 "letrec") (_o$6301 "letrec*") (_o$6302 "quote") (_o$6303 "quasiquote") (_o$6304 "unquote") (_o$6305 "set!") (_o$6306 "define") (_o$6307 "define-syntax") (_o$6308 "cond") (_o$6309 "case") (_o$6310 "when") (_o$6311 "unless") (_o$6312 "and") (_o$6313 "or") (_o$6314 "do") (_o$6315 "else") (_o$6316 "guard") (_o$6317 "parameterize") (_o$6318 "delay") (_o$6319 "values")) (jolt-hash-set _o$6295 _o$6296 _o$6297 _o$6298 _o$6299 _o$6300 _o$6301 _o$6302 _o$6303 _o$6304 _o$6305 _o$6306 _o$6307 _o$6308 _o$6309 _o$6310 _o$6311 _o$6312 _o$6313 _o$6314 _o$6315 _o$6316 _o$6317 _o$6318 _o$6319)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "*known-procs*" (jolt-hash-set) (let* ((_o$7742 (keyword #f "dynamic")) (_o$7743 #t)) (jolt-hash-map _o$7742 _o$7743)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "*tail?*" #f (let* ((_o$7744 (keyword #f "dynamic")) (_o$7745 #t)) (jolt-hash-map _o$7744 _o$7745)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "gensym-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (let* ((_o$7746 (keyword #f "private")) (_o$7747 #t)) (jolt-hash-map _o$7746 _o$7747)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "fresh-label" (letrec ((fresh-label (lambda (prefix) (let fnrec7748 ((prefix prefix)) (jolt-invoke (var-deref "clojure.core" "str") prefix (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "gensym-counter") jolt-inc)))))) fresh-label) (let* ((_o$7749 (keyword #f "private")) (_o$7750 #t)) (jolt-hash-map _o$7749 _o$7750)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "cache-cells" (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil) (let* ((_o$7751 (keyword #f "private")) (_o$7752 #t)) (jolt-hash-map _o$7751 _o$7752)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-with-cells" (letrec ((emit-with-cells (lambda (emit-thunk) (let fnrec7753 ((emit-thunk emit-thunk)) (let* ((cells (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (prev (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "cache-cells"))) (_ (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "cache-cells") cells)) (raw (jolt-invoke emit-thunk)) (_ (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.backend-scheme" "cache-cells") prev))) (if (jolt-truthy? 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(_o$7770 "define") (_o$7771 "define-syntax") (_o$7772 "cond") (_o$7773 "case") (_o$7774 "when") (_o$7775 "unless") (_o$7776 "and") (_o$7777 "or") (_o$7778 "do") (_o$7779 "else") (_o$7780 "guard") (_o$7781 "parameterize") (_o$7782 "delay") (_o$7783 "values")) (jolt-hash-set _o$7759 _o$7760 _o$7761 _o$7762 _o$7763 _o$7764 _o$7765 _o$7766 _o$7767 _o$7768 _o$7769 _o$7770 _o$7771 _o$7772 _o$7773 _o$7774 _o$7775 _o$7776 _o$7777 _o$7778 _o$7779 _o$7780 _o$7781 _o$7782 _o$7783)) (let* ((_o$7784 (keyword #f "private")) (_o$7785 #t)) (jolt-hash-map _o$7784 _o$7785)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "bare-native-names" (jolt-invoke (var-deref "clojure.core" "set") (jolt-invoke (var-deref "clojure.core" "keep") (lambda (G__141) (let fnrec7786 ((G__141 G__141)) (let* ((G__142 G__141) (k (jolt-nth G__142 0 jolt-nil)) (v (jolt-nth G__142 1 jolt-nil))) (if (jolt= k v) k jolt-nil)))) (var-deref "jolt.backend-scheme" "native-ops"))) (let* ((_o$7787 (keyword #f "private")) (_o$7788 #t)) (jolt-hash-map _o$7787 _o$7788)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "munge-name" (letrec ((munge-name (lambda (s) (let fnrec7789 ((s s)) (let* ((s (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") s "#" "_") "'" "_PRIME_"))) (if (let* ((or__26__auto (jolt-contains? (var-deref "jolt.backend-scheme" "scheme-reserved") s))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-contains? (var-deref "jolt.backend-scheme" "bare-native-names") s))) (jolt-invoke (var-deref "clojure.core" "str") "_" s) s)))))) munge-name) (let* ((_o$7790 (keyword #f "private")) (_o$7791 #t)) (jolt-hash-map _o$7790 _o$7791)))) + (def-var! "jolt.backend-scheme" "munge-name" (letrec ((munge-name (lambda (s) (let fnrec6320 ((s s)) (let* ((s (jolt-invoke (var-deref "clojure.string" "replace") (jolt-invoke (var-deref "clojure.string" "replace") s "#" "_") "'" "_PRIME_"))) (if (jolt-contains? (var-deref "jolt.backend-scheme" "scheme-reserved") s) (jolt-invoke (var-deref "clojure.core" "str") "_" s) s)))))) munge-name))) (guard (e (#t #f)) (declare-var! "jolt.backend-scheme" "emit")) (guard (e (#t #f)) - (declare-var! "jolt.backend-scheme" "emit*")) + (def-var! "jolt.backend-scheme" "char-escape" (letrec ((char-escape (lambda (cp) (let fnrec6321 ((cp cp)) (if (jolt= cp 34) "\\\"" (if (jolt= cp 92) "\\\\" (if (jolt= cp 10) "\\n" (if (jolt= cp 9) "\\t" (if (jolt= cp 13) "\\r" (if (jolt-truthy? (let* ((and__25__auto (>= cp 32))) (if (jolt-truthy? and__25__auto) (< cp 127) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "char") cp)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") "\\x" (jolt-invoke (var-deref "clojure.core" "format") "%x" cp) ";") jolt-nil))))))))))) char-escape))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "tail-transparent-ops" (let* ((_o$7792 (keyword #f "if")) (_o$7793 (keyword #f "do")) (_o$7794 (keyword #f "let")) (_o$7795 (keyword #f "loop")) (_o$7796 (keyword #f "invoke"))) (jolt-hash-set _o$7792 _o$7793 _o$7794 _o$7795 _o$7796)) (let* ((_o$7797 (keyword #f "private")) (_o$7798 #t)) (jolt-hash-map _o$7797 _o$7798)))) + (def-var! "jolt.backend-scheme" "chez-str-lit" (letrec ((chez-str-lit (lambda (s) (let fnrec6322 ((s s)) (jolt-invoke (var-deref "clojure.core" "str") "\"" (jolt-apply (var-deref "clojure.core" "str") (jolt-map (lambda (c) (let fnrec6323 ((c c)) (jolt-invoke (var-deref "jolt.backend-scheme" "char-escape") (jolt-invoke (var-deref "clojure.core" "int") c)))) s)) "\""))))) chez-str-lit))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "emit" (letrec ((emit (lambda (node) (let fnrec7799 ((node node)) (if (jolt-truthy? (let* ((and__25__auto (var-deref "jolt.backend-scheme" "*tail?*"))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.backend-scheme" "tail-transparent-ops") (jolt-get node (keyword #f "op")))) and__25__auto))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "jolt.backend-scheme" "emit*") node)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit*") node)))))) emit))) + (def-var! "jolt.backend-scheme" "emit-const" (letrec ((emit-const (lambda (v) (let fnrec6324 ((v v)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") v)) "jolt-nil" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "boolean?") v)) (if (jolt-truthy? v) "#t" "#f") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") v)) (if (jolt= v +inf.0) "+inf.0" (if (jolt= v -inf.0) "-inf.0" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") v v)) "+nan.0" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "float?") v)) (let* ((s (jolt-invoke (var-deref "clojure.core" "str") v))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.string" "includes?") s "."))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.string" "includes?") s "e")))) s (jolt-invoke (var-deref "clojure.core" "str") s ".0"))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") v) jolt-nil))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") v)) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") v) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") v)) (let* ((temp__16__auto (jolt-invoke (var-deref "clojure.core" "namespace") v))) (if (jolt-truthy? temp__16__auto) (let* ((kns temp__16__auto)) (let* ((_a$6325 (var-deref "clojure.core" "str")) (_a$6326 "(keyword ") (_a$6327 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") kns)) (_a$6328 " ") (_a$6329 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "clojure.core" "name") v))) (_a$6330 ")")) (jolt-invoke _a$6325 _a$6326 _a$6327 _a$6328 _a$6329 _a$6330))) (jolt-invoke (var-deref "clojure.core" "str") "(keyword #f " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "clojure.core" "name") v)) ")"))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-char?") v)) (jolt-invoke (var-deref "clojure.core" "str") "(integer->char " (jolt-invoke (var-deref "jolt.host" "form-char-code") v) ")") (if (jolt-truthy? (keyword #f "else")) (jolt-throw (let* ((_a$6331 (jolt-invoke (var-deref "clojure.core" "str") "emit-const: unsupported literal " (jolt-invoke (var-deref "clojure.core" "pr-str") v))) (_a$6332 (jolt-hash-map))) (jolt-ex-info _a$6331 _a$6332))) jolt-nil))))))))))) emit-const))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "char-escape" (letrec ((char-escape (lambda (cp) (let fnrec7800 ((cp cp)) (if (jolt= cp 34) "\\\"" (if (jolt= cp 92) "\\\\" (if (jolt= cp 10) "\\n" (if (jolt= cp 9) "\\t" (if (jolt= cp 13) "\\r" (if (let* ((and__25__auto (jolt-n>= cp 32))) (if (jolt-truthy? and__25__auto) (jolt-n< cp 127) and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "char") cp)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") "\\x" (jolt-invoke (var-deref "clojure.core" "format") "%x" cp) ";") jolt-nil))))))))))) char-escape) (let* ((_o$7801 (keyword #f "private")) (_o$7802 #t)) (jolt-hash-map _o$7801 _o$7802)))) + (def-var! "jolt.backend-scheme" "emit-ordered" (letrec ((emit-ordered (lambda (ctor arg-strs) (let fnrec6333 ((ctor ctor) (arg-strs arg-strs)) (if (< (jolt-count arg-strs) 2) (jolt-invoke (var-deref "clojure.core" "str") "(" ctor (if (jolt-empty? arg-strs) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " arg-strs))) ")") (let* ((tmps (jolt-map (lambda (_) (let fnrec6334 ((_ _)) (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_o$"))) arg-strs)) (binds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (t a) (let fnrec6335 ((t t) (a a)) (jolt-invoke (var-deref "clojure.core" "str") "(" t " " a ")"))) tmps arg-strs)))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" binds ") (" ctor " " (jolt-invoke (var-deref "clojure.string" "join") " " tmps) "))"))))))) emit-ordered))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "chez-str-lit" (letrec ((chez-str-lit (lambda (s) (let fnrec7803 ((s s)) (jolt-invoke (var-deref "clojure.core" "str") "\"" (jolt-apply (var-deref "clojure.core" "str") (jolt-map (lambda (c) (let fnrec7804 ((c c)) (jolt-invoke (var-deref "jolt.backend-scheme" "char-escape") (jolt-invoke (var-deref "clojure.core" "int") c)))) s)) "\""))))) chez-str-lit) (let* ((_o$7805 (keyword #f "private")) (_o$7806 #t)) (jolt-hash-map _o$7805 _o$7806)))) + (def-var! "jolt.backend-scheme" "side-effect-free?" (letrec ((side-effect-free? (lambda (n) (let fnrec6336 ((n n)) (let* ((_a$6342 (let* ((_o$6337 (keyword #f "const")) (_o$6338 (keyword #f "local")) (_o$6339 (keyword #f "var")) (_o$6340 (keyword #f "the-var")) (_o$6341 (keyword #f "quote"))) (jolt-hash-set _o$6337 _o$6338 _o$6339 _o$6340 _o$6341))) (_a$6343 (jolt-get n (keyword #f "op")))) (jolt-contains? _a$6342 _a$6343)))))) side-effect-free?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-const" (letrec ((emit-const (lambda (v) (let fnrec7807 ((v v)) (if (jolt-nil? v) "jolt-nil" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "boolean?") v)) (if (jolt-truthy? v) "#t" "#f") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") v)) (if (jolt= v +inf.0) "+inf.0" (if (jolt= v -inf.0) "-inf.0" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") v v)) "+nan.0" (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "float?") v)) (let* ((s (jolt-invoke (var-deref "clojure.core" "str") v))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.string" "includes?") s "."))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.string" "includes?") s "e")))) s (jolt-invoke (var-deref "clojure.core" "str") s ".0"))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") v) jolt-nil))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") v)) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") v) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") v)) (let* ((temp__16__auto (jolt-invoke (var-deref "clojure.core" "namespace") v))) (if (jolt-truthy? temp__16__auto) (let* ((kns temp__16__auto)) (let* ((_a$7808 (var-deref "clojure.core" "str")) (_a$7809 "(keyword ") (_a$7810 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") kns)) (_a$7811 " ") (_a$7812 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "clojure.core" "name") v))) (_a$7813 ")")) (jolt-invoke _a$7808 _a$7809 _a$7810 _a$7811 _a$7812 _a$7813))) (jolt-invoke (var-deref "clojure.core" "str") "(keyword #f " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "clojure.core" "name") v)) ")"))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-char?") v)) (jolt-invoke (var-deref "clojure.core" "str") "(integer->char " (jolt-invoke (var-deref "jolt.host" "form-char-code") v) ")") (if (jolt-truthy? (keyword #f "else")) (jolt-throw (let* ((_a$7814 (jolt-invoke (var-deref "clojure.core" "str") "emit-const: unsupported literal " (jolt-invoke (var-deref "clojure.core" "pr-str") v))) (_a$7815 (jolt-hash-map))) (jolt-ex-info _a$7814 _a$7815))) jolt-nil))))))))))) emit-const) (let* ((_o$7816 (keyword #f "private")) (_o$7817 #t)) (jolt-hash-map _o$7816 _o$7817)))) + (def-var! "jolt.backend-scheme" "needs-order?" (letrec ((needs-order? (lambda (nodes) (let fnrec6344 ((nodes nodes)) (> (jolt-count (jolt-remove (var-deref "jolt.backend-scheme" "side-effect-free?") nodes)) 1))))) needs-order?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-ordered" (letrec ((emit-ordered (lambda (ctor arg-strs) (let fnrec7818 ((ctor ctor) (arg-strs arg-strs)) (if (jolt-n< (jolt-count arg-strs) 2) (jolt-invoke (var-deref "clojure.core" "str") "(" ctor (if (jolt-empty? arg-strs) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " arg-strs))) ")") (let* ((tmps (jolt-map (lambda (_) (let fnrec7819 ((_ _)) (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_o$"))) arg-strs)) (binds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (t a) (let fnrec7820 ((t t) (a a)) (jolt-invoke (var-deref "clojure.core" "str") "(" t " " a ")"))) tmps arg-strs)))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" binds ") (" ctor " " (jolt-invoke (var-deref "clojure.string" "join") " " tmps) "))"))))))) emit-ordered) (let* ((_o$7821 (keyword #f "private")) (_o$7822 #t)) (jolt-hash-map _o$7821 _o$7822)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "side-effect-free?" (letrec ((side-effect-free? (lambda (n) (let fnrec7823 ((n n)) (let* ((_a$7829 (let* ((_o$7824 (keyword #f "const")) (_o$7825 (keyword #f "local")) (_o$7826 (keyword #f "var")) (_o$7827 (keyword #f "the-var")) (_o$7828 (keyword #f "quote"))) (jolt-hash-set _o$7824 _o$7825 _o$7826 _o$7827 _o$7828))) (_a$7830 (jolt-get n (keyword #f "op")))) (jolt-contains? _a$7829 _a$7830)))))) side-effect-free?) (let* ((_o$7831 (keyword #f "private")) (_o$7832 #t)) (jolt-hash-map _o$7831 _o$7832)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "needs-order?" (letrec ((needs-order? (lambda (nodes) (let fnrec7833 ((nodes nodes)) (jolt-n> (jolt-count (jolt-remove (var-deref "jolt.backend-scheme" "side-effect-free?") nodes)) 1))))) needs-order?) (let* ((_o$7834 (keyword #f "private")) (_o$7835 #t)) (jolt-hash-map _o$7834 _o$7835)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "ordered-call" (letrec ((ordered-call (lambda (nodes strs build) (let fnrec7836 ((nodes nodes) (strs strs) (build build)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "needs-order?") nodes)) (let* ((tmps (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (_) (let fnrec7837 ((_ _)) (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_a$"))) strs)) (binds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (t a) (let fnrec7838 ((t t) (a a)) (jolt-invoke (var-deref "clojure.core" "str") "(" t " " a ")"))) tmps strs)))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" binds ") " (jolt-invoke build tmps) ")")) (jolt-invoke build strs)))))) ordered-call) (let* ((_o$7839 (keyword #f "private")) (_o$7840 #t)) (jolt-hash-map _o$7839 _o$7840)))) + (def-var! "jolt.backend-scheme" "ordered-call" (letrec ((ordered-call (lambda (nodes strs build) (let fnrec6345 ((nodes nodes) (strs strs) (build build)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "needs-order?") nodes)) (let* ((tmps (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (_) (let fnrec6346 ((_ _)) (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_a$"))) strs)) (binds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (t a) (let fnrec6347 ((t t) (a a)) (jolt-invoke (var-deref "clojure.core" "str") "(" t " " a ")"))) tmps strs)))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" binds ") " (jolt-invoke build tmps) ")")) (jolt-invoke build strs)))))) ordered-call))) (guard (e (#t #f)) (declare-var! "jolt.backend-scheme" "emit-quoted")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-quoted-map" (letrec ((emit-quoted-map (lambda (pairs) (let fnrec7841 ((pairs pairs)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-map " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "mapcat") (lambda (p) (let fnrec7842 ((p p)) (let* ((_o$7843 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-nth p 0))) (_o$7844 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-nth p 1)))) (jolt-vector _o$7843 _o$7844)))) pairs)) ")"))))) emit-quoted-map) (let* ((_o$7845 (keyword #f "private")) (_o$7846 #t)) (jolt-hash-map _o$7845 _o$7846)))) + (def-var! "jolt.backend-scheme" "emit-quoted-map" (letrec ((emit-quoted-map (lambda (pairs) (let fnrec6348 ((pairs pairs)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-map " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "mapcat") (lambda (p) (let fnrec6349 ((p p)) (let* ((_o$6350 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-nth p 0))) (_o$6351 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-nth p 1)))) (jolt-vector _o$6350 _o$6351)))) pairs)) ")"))))) emit-quoted-map))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-quoted-map-value" (letrec ((emit-quoted-map-value (lambda (m) (let fnrec7847 ((m m)) (let* ((pairs (jolt-invoke (var-deref "clojure.core" "sort") (let* ((_a$7853 (lambda (k) (let fnrec7848 ((k k)) (let* ((_a$7849 (var-deref "clojure.core" "str")) (_a$7850 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") k)) (_a$7851 " ") (_a$7852 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get m k)))) (jolt-invoke _a$7849 _a$7850 _a$7851 _a$7852))))) (_a$7854 (jolt-keys m))) (jolt-map _a$7853 _a$7854))))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-map " (jolt-invoke (var-deref "clojure.string" "join") " " pairs) ")")))))) emit-quoted-map-value) (let* ((_o$7855 (keyword #f "private")) (_o$7856 #t)) (jolt-hash-map _o$7855 _o$7856)))) + (def-var! "jolt.backend-scheme" "emit-quoted-map-value" (letrec ((emit-quoted-map-value (lambda (m) (let fnrec6352 ((m m)) (let* ((pairs (jolt-invoke (var-deref "clojure.core" "sort") (let* ((_a$6358 (lambda (k) (let fnrec6353 ((k k)) (let* ((_a$6354 (var-deref "clojure.core" "str")) (_a$6355 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") k)) (_a$6356 " ") (_a$6357 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get m k)))) (jolt-invoke _a$6354 _a$6355 _a$6356 _a$6357))))) (_a$6359 (jolt-keys m))) (jolt-map _a$6358 _a$6359))))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-map " (jolt-invoke (var-deref "clojure.string" "join") " " pairs) ")")))))) emit-quoted-map-value))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-quoted" (letrec ((emit-quoted (lambda (form) (let fnrec7857 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-char?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-literal?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") form)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") form)) (sns (jolt-invoke (var-deref "jolt.host" "form-sym-ns") form)) (nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") form))) (if (jolt-truthy? (let* ((and__25__auto m)) (if (jolt-truthy? and__25__auto) (jolt-pos? (jolt-count m)) and__25__auto))) (let* ((_a$7858 (var-deref "clojure.core" "str")) (_a$7859 "(jolt-symbol/meta ") (_a$7860 (if (jolt-truthy? sns) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") sns) "#f")) (_a$7861 " ") (_a$7862 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$7863 " ") (_a$7864 (emit-quoted m)) (_a$7865 ")")) (jolt-invoke _a$7858 _a$7859 _a$7860 _a$7861 _a$7862 _a$7863 _a$7864 _a$7865)) (let* ((_a$7866 (var-deref "clojure.core" "str")) (_a$7867 "(jolt-symbol ") (_a$7868 (if (jolt-truthy? sns) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") sns) "#f")) (_a$7869 " ") (_a$7870 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$7871 ")")) (jolt-invoke _a$7866 _a$7867 _a$7868 _a$7869 _a$7870 _a$7871)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-set?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-set " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "sort") (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-set-items") form)))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-list " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-elements") form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-vector " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-vec-items") form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-map?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted-map") (jolt-invoke (var-deref "jolt.host" "form-map-pairs") form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-regex?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-regex " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "jolt.host" "form-regex-source") form)) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-inst?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-inst-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "jolt.host" "form-inst-source") form)) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-uuid?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-uuid-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "jolt.host" "form-uuid-source") form)) ")") (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") form))) (if (jolt-truthy? and__25__auto) (jolt= (keyword "jolt" "tagged") (jolt-get form (keyword "jolt" "type"))) and__25__auto))) (let* ((nm (jolt-invoke (var-deref "clojure.core" "name") (jolt-get form (keyword #f "tag")))) (tsym (if (jolt= (integer->char 35) (jolt-first nm)) (jolt-invoke (var-deref "clojure.core" "subs") nm 1) nm))) (let* ((_a$7872 (var-deref "clojure.core" "str")) (_a$7873 "(jolt-tagged-literal (jolt-symbol #f ") (_a$7874 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") tsym)) (_a$7875 ") ") (_a$7876 (emit-quoted (jolt-get form (keyword #f "form")))) (_a$7877 ")")) (jolt-invoke _a$7872 _a$7873 _a$7874 _a$7875 _a$7876 _a$7877))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted-map-value") form) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-vector " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted form)) ")") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-set " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "sort") (jolt-map emit-quoted form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-list " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted form)) ")") (if (jolt-truthy? (keyword #f "else")) (jolt-throw (let* ((_a$7878 (jolt-invoke (var-deref "clojure.core" "str") "emit-quoted: unsupported quoted form " (jolt-invoke (var-deref "clojure.core" "pr-str") form))) (_a$7879 (jolt-hash-map))) (jolt-ex-info _a$7878 _a$7879))) jolt-nil)))))))))))))))))))) emit-quoted) (let* ((_o$7880 (keyword #f "private")) (_o$7881 #t)) (jolt-hash-map _o$7880 _o$7881)))) + (def-var! "jolt.backend-scheme" "emit-quoted" (letrec ((emit-quoted (lambda (form) (let fnrec6360 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-char?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-literal?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") form) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-sym?") form)) (let* ((m (jolt-invoke (var-deref "jolt.host" "form-sym-meta") form)) (sns (jolt-invoke (var-deref "jolt.host" "form-sym-ns") form)) (nm (jolt-invoke (var-deref "jolt.host" "form-sym-name") form))) (if (jolt-truthy? (let* ((and__25__auto m)) (if (jolt-truthy? and__25__auto) (jolt-pos? (jolt-count m)) and__25__auto))) (let* ((_a$6361 (var-deref "clojure.core" "str")) (_a$6362 "(jolt-symbol/meta ") (_a$6363 (if (jolt-truthy? sns) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") sns) "#f")) (_a$6364 " ") (_a$6365 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$6366 " ") (_a$6367 (jolt-invoke emit-quoted m)) (_a$6368 ")")) (jolt-invoke _a$6361 _a$6362 _a$6363 _a$6364 _a$6365 _a$6366 _a$6367 _a$6368)) (let* ((_a$6369 (var-deref "clojure.core" "str")) (_a$6370 "(jolt-symbol ") (_a$6371 (if (jolt-truthy? sns) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") sns) "#f")) (_a$6372 " ") (_a$6373 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$6374 ")")) (jolt-invoke _a$6369 _a$6370 _a$6371 _a$6372 _a$6373 _a$6374)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-set?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-set " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "sort") (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-set-items") form)))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-list?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-list " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-elements") form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-vec?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-vector " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted (jolt-invoke (var-deref "jolt.host" "form-vec-items") form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-map?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted-map") (jolt-invoke (var-deref "jolt.host" "form-map-pairs") form)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "form-regex?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-regex " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "jolt.host" "form-regex-source") form)) ")") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") form)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted-map-value") form) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-vector " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted form)) ")") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-hash-set " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "sort") (jolt-map emit-quoted form))) ")") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") form)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-list " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-quoted form)) ")") (if (jolt-truthy? (keyword #f "else")) (jolt-throw (let* ((_a$6375 (jolt-invoke (var-deref "clojure.core" "str") "emit-quoted: unsupported quoted form " (jolt-invoke (var-deref "clojure.core" "pr-str") form))) (_a$6376 (jolt-hash-map))) (jolt-ex-info _a$6375 _a$6376))) jolt-nil))))))))))))))))) emit-quoted))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "jmeta-nonempty?" (letrec ((jmeta-nonempty? (lambda (m) (let fnrec7882 ((m m)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") m))) (if (jolt-truthy? and__25__auto) (jolt-pos? (jolt-count m)) and__25__auto)))))) jmeta-nonempty?) (let* ((_o$7883 (keyword #f "private")) (_o$7884 #t)) (jolt-hash-map _o$7883 _o$7884)))) + (def-var! "jolt.backend-scheme" "jmeta-nonempty?" (letrec ((jmeta-nonempty? (lambda (m) (let fnrec6377 ((m m)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") m))) (if (jolt-truthy? and__25__auto) (jolt-pos? (jolt-count m)) and__25__auto)))))) jmeta-nonempty?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-def-meta" (letrec ((emit-def-meta (lambda (node) (let fnrec7885 ((node node)) (if (jolt-truthy? (jolt-get node (keyword #f "meta-expr"))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "meta-expr"))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get node (keyword #f "meta")))))))) emit-def-meta) (let* ((_o$7886 (keyword #f "private")) (_o$7887 #t)) (jolt-hash-map _o$7886 _o$7887)))) + (def-var! "jolt.backend-scheme" "emit-binding" (letrec ((emit-binding (lambda (b) (let fnrec6378 ((b b)) (let* ((_a$6379 (var-deref "clojure.core" "str")) (_a$6380 "(") (_a$6381 (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-nth b 0))) (_a$6382 " ") (_a$6383 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth b 1))) (_a$6384 ")")) (jolt-invoke _a$6379 _a$6380 _a$6381 _a$6382 _a$6383 _a$6384)))))) emit-binding))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-binding" (letrec ((emit-binding (lambda (b) (let fnrec7888 ((b b)) (let* ((_a$7889 (var-deref "clojure.core" "str")) (_a$7890 "(") (_a$7891 (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-nth b 0))) (_a$7892 " ") (_a$7893 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth b 1))) (_a$7894 ")")) (jolt-invoke _a$7889 _a$7890 _a$7891 _a$7892 _a$7893 _a$7894)))))) emit-binding) (let* ((_o$7895 (keyword #f "private")) (_o$7896 #t)) (jolt-hash-map _o$7895 _o$7896)))) + (def-var! "jolt.backend-scheme" "emit-let" (letrec ((emit-let (lambda (node) (let fnrec6385 ((node node)) (let* ((kw (if (jolt-truthy? (jolt-get node (keyword #f "letrec"))) "letrec*" "let*"))) (let* ((_a$6386 (var-deref "clojure.core" "str")) (_a$6387 "(") (_a$6388 kw) (_a$6389 " (") (_a$6390 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (var-deref "jolt.backend-scheme" "emit-binding") (jolt-get node (keyword #f "bindings"))))) (_a$6391 ") ") (_a$6392 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body")))) (_a$6393 ")")) (jolt-invoke _a$6386 _a$6387 _a$6388 _a$6389 _a$6390 _a$6391 _a$6392 _a$6393))))))) emit-let))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-let" (letrec ((emit-let (lambda (node) (let fnrec7897 ((node node)) (let* ((kw (if (jolt-truthy? (jolt-get node (keyword #f "letrec"))) "letrec*" "let*")) (binds (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit-binding") (jolt-get node (keyword #f "bindings"))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (jolt-invoke (var-deref "clojure.core" "str") "(" kw " (" binds ") " (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body"))) ")")))))) emit-let) (let* ((_o$7898 (keyword #f "private")) (_o$7899 #t)) (jolt-hash-map _o$7898 _o$7899)))) + (def-var! "jolt.backend-scheme" "emit-loop" (letrec ((emit-loop (lambda (node) (let fnrec6394 ((node node)) (let* ((label (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "loop")) (pairs (jolt-get node (keyword #f "bindings"))) (names (jolt-map (lambda (p__83_) (let fnrec6395 ((p__83_ p__83_)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-nth p__83_ 0)))) pairs)) (inits (jolt-map (lambda (p__84_) (let fnrec6396 ((p__84_ p__84_)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth p__84_ 1)))) pairs)) (seq-bs (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (n i) (let fnrec6397 ((n n) (i i)) (jolt-invoke (var-deref "clojure.core" "str") "(" n " " i ")"))) names inits))) (rebinds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (n) (let fnrec6398 ((n n)) (jolt-invoke (var-deref "clojure.core" "str") "(" n " " n ")"))) names))) (body (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*recur-target*") label))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" seq-bs ") (let " label " (" rebinds ") " body "))")))))) emit-loop))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-loop" (letrec ((emit-loop (lambda (node) (let fnrec7900 ((node node)) (let* ((label (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "loop")) (pairs (jolt-get node (keyword #f "bindings"))) (names (jolt-map (lambda (p__95_) (let fnrec7901 ((p__95_ p__95_)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-nth p__95_ 0)))) pairs)) (inits (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (p__96_) (let fnrec7902 ((p__96_ p__96_)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth p__96_ 1)))) pairs)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (seq-bs (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (n i) (let fnrec7903 ((n n) (i i)) (jolt-invoke (var-deref "clojure.core" "str") "(" n " " i ")"))) names inits))) (rebinds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (n) (let fnrec7904 ((n n)) (jolt-invoke (var-deref "clojure.core" "str") "(" n " " n ")"))) names))) (body (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*recur-target*") label))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" seq-bs ") (let " label " (" rebinds ") " body "))")))))) emit-loop) (let* ((_o$7905 (keyword #f "private")) (_o$7906 #t)) (jolt-hash-map _o$7905 _o$7906)))) + (def-var-with-meta! "jolt.backend-scheme" "ffi-types" (let* ((_o$6399 "int") (_o$6400 "int") (_o$6401 "uint") (_o$6402 "unsigned-int") (_o$6403 "long") (_o$6404 "long") (_o$6405 "ulong") (_o$6406 "unsigned-long") (_o$6407 "int64") (_o$6408 "integer-64") (_o$6409 "uint64") (_o$6410 "unsigned-64") (_o$6411 "size_t") (_o$6412 "size_t") (_o$6413 "ssize_t") (_o$6414 "ssize_t") (_o$6415 "iptr") (_o$6416 "iptr") (_o$6417 "uptr") (_o$6418 "uptr") (_o$6419 "double") (_o$6420 "double") (_o$6421 "float") (_o$6422 "float") (_o$6423 "pointer") (_o$6424 "void*") (_o$6425 "void*") (_o$6426 "void*") (_o$6427 "string") (_o$6428 "string") (_o$6429 "void") (_o$6430 "void") (_o$6431 "uint8") (_o$6432 "unsigned-8") (_o$6433 "u8") (_o$6434 "unsigned-8") (_o$6435 "byte") (_o$6436 "unsigned-8") (_o$6437 "char") (_o$6438 "char")) (jolt-hash-map _o$6399 _o$6400 _o$6401 _o$6402 _o$6403 _o$6404 _o$6405 _o$6406 _o$6407 _o$6408 _o$6409 _o$6410 _o$6411 _o$6412 _o$6413 _o$6414 _o$6415 _o$6416 _o$6417 _o$6418 _o$6419 _o$6420 _o$6421 _o$6422 _o$6423 _o$6424 _o$6425 _o$6426 _o$6427 _o$6428 _o$6429 _o$6430 _o$6431 _o$6432 _o$6433 _o$6434 _o$6435 _o$6436 _o$6437 _o$6438)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "ffi-types" (let* ((_o$7907 "int") (_o$7908 "int") (_o$7909 "uint") (_o$7910 "unsigned-int") (_o$7911 "long") (_o$7912 "long") (_o$7913 "ulong") (_o$7914 "unsigned-long") (_o$7915 "int64") (_o$7916 "integer-64") (_o$7917 "uint64") (_o$7918 "unsigned-64") (_o$7919 "size_t") (_o$7920 "size_t") (_o$7921 "ssize_t") (_o$7922 "ssize_t") (_o$7923 "iptr") (_o$7924 "iptr") (_o$7925 "uptr") (_o$7926 "uptr") (_o$7927 "double") (_o$7928 "double") (_o$7929 "float") (_o$7930 "float") (_o$7931 "pointer") (_o$7932 "void*") (_o$7933 "void*") (_o$7934 "void*") (_o$7935 "string") (_o$7936 "string") (_o$7937 "void") (_o$7938 "void") (_o$7939 "uint8") (_o$7940 "unsigned-8") (_o$7941 "u8") (_o$7942 "unsigned-8") (_o$7943 "byte") (_o$7944 "unsigned-8") (_o$7945 "char") (_o$7946 "char")) (jolt-hash-map _o$7907 _o$7908 _o$7909 _o$7910 _o$7911 _o$7912 _o$7913 _o$7914 _o$7915 _o$7916 _o$7917 _o$7918 _o$7919 _o$7920 _o$7921 _o$7922 _o$7923 _o$7924 _o$7925 _o$7926 _o$7927 _o$7928 _o$7929 _o$7930 _o$7931 _o$7932 _o$7933 _o$7934 _o$7935 _o$7936 _o$7937 _o$7938 _o$7939 _o$7940 _o$7941 _o$7942 _o$7943 _o$7944 _o$7945 _o$7946)) (let* ((_o$7947 (keyword #f "private")) (_o$7948 #t)) (jolt-hash-map _o$7947 _o$7948)))) + (def-var! "jolt.backend-scheme" "ffi-type->chez" (letrec ((ffi-type->chez (lambda (t) (let fnrec6439 ((t t)) (let* ((or__26__auto (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-types") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-throw (let* ((_a$6440 (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi: unknown foreign type :" t)) (_a$6441 (jolt-hash-map))) (jolt-ex-info _a$6440 _a$6441))))))))) ffi-type->chez))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "ffi-type->chez" (letrec ((ffi-type->chez (lambda (t) (let fnrec7949 ((t t)) (let* ((or__26__auto (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-types") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-throw (let* ((_a$7950 (jolt-invoke (var-deref "clojure.core" "str") "jolt.ffi: unknown foreign type :" t)) (_a$7951 (jolt-hash-map))) (jolt-ex-info _a$7950 _a$7951))))))))) ffi-type->chez) (let* ((_o$7952 (keyword #f "private")) (_o$7953 #t)) (jolt-hash-map _o$7952 _o$7953)))) + (def-var! "jolt.backend-scheme" "emit-ffi-fn" (letrec ((emit-ffi-fn (lambda (node) (let fnrec6442 ((node node)) (let* ((_a$6443 (var-deref "clojure.core" "str")) (_a$6444 "(foreign-procedure ") (_a$6445 (if (jolt-truthy? (jolt-get node (keyword #f "blocking"))) "__collect_safe " jolt-nil)) (_a$6446 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "csym")))) (_a$6447 " (") (_a$6448 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "argtypes"))))) (_a$6449 ") ") (_a$6450 (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "rettype")))) (_a$6451 ")")) (jolt-invoke _a$6443 _a$6444 _a$6445 _a$6446 _a$6447 _a$6448 _a$6449 _a$6450 _a$6451)))))) emit-ffi-fn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-ffi-fn" (letrec ((emit-ffi-fn (lambda (node) (let fnrec7954 ((node node)) (let* ((_a$7955 (var-deref "clojure.core" "str")) (_a$7956 "(foreign-procedure ") (_a$7957 (if (jolt-truthy? (jolt-get node (keyword #f "blocking"))) "__collect_safe " jolt-nil)) (_a$7958 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "csym")))) (_a$7959 " (") (_a$7960 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "argtypes"))))) (_a$7961 ") ") (_a$7962 (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "rettype")))) (_a$7963 ")")) (jolt-invoke _a$7955 _a$7956 _a$7957 _a$7958 _a$7959 _a$7960 _a$7961 _a$7962 _a$7963)))))) emit-ffi-fn) (let* ((_o$7964 (keyword #f "private")) (_o$7965 #t)) (jolt-hash-map _o$7964 _o$7965)))) + (def-var! "jolt.backend-scheme" "emit-ffi-callable" (letrec ((emit-ffi-callable (lambda (node) (let fnrec6452 ((node node)) (let* ((_a$6453 (var-deref "clojure.core" "str")) (_a$6454 "(jolt-ffi-register-callable! (foreign-callable ") (_a$6455 (if (jolt-truthy? (jolt-get node (keyword #f "collect-safe"))) "__collect_safe " jolt-nil)) (_a$6456 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "fn")))) (_a$6457 " (") (_a$6458 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "argtypes"))))) (_a$6459 ") ") (_a$6460 (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "rettype")))) (_a$6461 "))")) (jolt-invoke _a$6453 _a$6454 _a$6455 _a$6456 _a$6457 _a$6458 _a$6459 _a$6460 _a$6461)))))) emit-ffi-callable))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-ffi-callable" (letrec ((emit-ffi-callable (lambda (node) (let fnrec7966 ((node node)) (let* ((_a$7967 (var-deref "clojure.core" "str")) (_a$7968 "(jolt-ffi-register-callable! (foreign-callable ") (_a$7969 (if (jolt-truthy? (jolt-get node (keyword #f "collect-safe"))) "__collect_safe " jolt-nil)) (_a$7970 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "fn")))) (_a$7971 " (") (_a$7972 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "argtypes"))))) (_a$7973 ") ") (_a$7974 (jolt-invoke (var-deref "jolt.backend-scheme" "ffi-type->chez") (jolt-get node (keyword #f "rettype")))) (_a$7975 "))")) (jolt-invoke _a$7967 _a$7968 _a$7969 _a$7970 _a$7971 _a$7972 _a$7973 _a$7974 _a$7975)))))) emit-ffi-callable) (let* ((_o$7976 (keyword #f "private")) (_o$7977 #t)) (jolt-hash-map _o$7976 _o$7977)))) + (def-var! "jolt.backend-scheme" "emit-recur" (letrec ((emit-recur (lambda (node) (let fnrec6462 ((node node)) (begin (if (jolt-not (var-deref "jolt.backend-scheme" "*recur-target*")) (jolt-throw (jolt-ex-info "emit: recur outside a loop/fn target" (jolt-hash-map))) jolt-nil) (let* ((arg-nodes (jolt-get node (keyword #f "args")))) (let* ((_a$6464 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$6465 arg-nodes) (_a$6466 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit") arg-nodes)) (_a$6467 (lambda (as) (let fnrec6463 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" (var-deref "jolt.backend-scheme" "*recur-target*") " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")"))))) (jolt-invoke _a$6464 _a$6465 _a$6466 _a$6467)))))))) emit-recur))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-recur" (letrec ((emit-recur (lambda (node) (let fnrec7978 ((node node)) (begin (if (jolt-not (var-deref "jolt.backend-scheme" "*recur-target*")) (jolt-throw (jolt-ex-info "emit: recur outside a loop/fn target" (jolt-hash-map))) jolt-nil) (let* ((arg-nodes (jolt-get node (keyword #f "args")))) (let* ((_a$7980 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$7981 arg-nodes) (_a$7982 (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit") arg-nodes)) (_a$7983 (lambda (as) (let fnrec7979 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" (var-deref "jolt.backend-scheme" "*recur-target*") " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")"))))) (jolt-invoke _a$7980 _a$7981 _a$7982 _a$7983)))))))) emit-recur) (let* ((_o$7984 (keyword #f "private")) (_o$7985 #t)) (jolt-hash-map _o$7984 _o$7985)))) + (def-var! "jolt.backend-scheme" "nhint-init" (letrec ((nhint-init (lambda (nh orig munged) (let fnrec6468 ((nh nh) (orig orig) (munged munged)) (let* ((k (jolt-get nh orig))) (if (jolt= k (keyword #f "double")) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " munged ")") (if (jolt= k (keyword #f "long")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " munged ")") (if (jolt-truthy? (keyword #f "else")) munged jolt-nil)))))))) nhint-init))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "nhint-init" (letrec ((nhint-init (lambda (nh orig munged) (let fnrec7986 ((nh nh) (orig orig) (munged munged)) (let* ((k (jolt-get nh orig))) (if (jolt= k (keyword #f "double")) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " munged ")") (if (jolt= k (keyword #f "long")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " munged ")") (if (jolt-truthy? (keyword #f "else")) munged jolt-nil)))))))) nhint-init) (let* ((_o$7987 (keyword #f "private")) (_o$7988 #t)) (jolt-hash-map _o$7987 _o$7988)))) + (def-var! "jolt.backend-scheme" "emit-arity-clause" (letrec ((emit-arity-clause (lambda (a) (let fnrec6469 ((a a)) (let* ((orig (jolt-get a (keyword #f "params"))) (nh (let* ((_a$6470 (jolt-hash-map)) (_a$6471 (jolt-get a (keyword #f "nhints")))) (jolt-into _a$6470 _a$6471))) (params (jolt-map (var-deref "jolt.backend-scheme" "munge-name") orig)) (restp (let* ((temp__27__auto (jolt-get a (keyword #f "rest")))) (if (jolt-truthy? temp__27__auto) (let* ((r temp__27__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") r)) jolt-nil))) (label (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "fnrec")) (body (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*recur-target*") label))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get a (keyword #f "body")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (paramlist (if (jolt-truthy? (let* ((and__25__auto restp)) (if (jolt-truthy? and__25__auto) (jolt-empty? params) and__25__auto))) restp (if (jolt-truthy? restp) (jolt-invoke (var-deref "clojure.core" "str") "(" (jolt-invoke (var-deref "clojure.string" "join") " " params) " . " restp ")") (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") "(" (jolt-invoke (var-deref "clojure.string" "join") " " params) ")") jolt-nil)))) (pbind (jolt-map (lambda (o p) (let fnrec6472 ((o o) (p p)) (jolt-invoke (var-deref "clojure.core" "str") "(" p " " (jolt-invoke (var-deref "jolt.backend-scheme" "nhint-init") nh o p) ")"))) orig params)) (binds (if (jolt-truthy? restp) (jolt-concat pbind (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "(" restp " (list->cseq " restp "))"))) pbind)) (lett (jolt-invoke (var-deref "clojure.core" "str") "(let " label " (" (jolt-invoke (var-deref "clojure.string" "join") " " binds) ") " body ")")) (ret (jolt-get a (keyword #f "ret-nhint")))) (let* ((_o$6473 paramlist) (_o$6474 (if (jolt= ret (keyword #f "double")) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " lett ")") (if (jolt= ret (keyword #f "long")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " lett ")") (if (jolt-truthy? (keyword #f "else")) lett jolt-nil))))) (jolt-vector _o$6473 _o$6474))))))) emit-arity-clause))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-arity-clause" (letrec ((emit-arity-clause (lambda (a) (let fnrec7989 ((a a)) (let* ((orig (jolt-get a (keyword #f "params"))) (nh (let* ((_a$7990 (jolt-hash-map)) (_a$7991 (jolt-get a (keyword #f "nhints")))) (jolt-into _a$7990 _a$7991))) (params (jolt-map (var-deref "jolt.backend-scheme" "munge-name") orig)) (restp (let* ((temp__27__auto (jolt-get a (keyword #f "rest")))) (if (jolt-truthy? temp__27__auto) (let* ((r temp__27__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") r)) jolt-nil))) (label (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "fnrec")) (ret (jolt-get a (keyword #f "ret-nhint"))) (body-tail? (jolt-not (let* ((or__26__auto (jolt= ret (keyword #f "double")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= ret (keyword #f "long")))))) (body (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*recur-target*") label (jolt-var "jolt.backend-scheme" "*tail?*") body-tail?))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get a (keyword #f "body")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (paramlist (if (jolt-truthy? (let* ((and__25__auto restp)) (if (jolt-truthy? and__25__auto) (jolt-empty? params) and__25__auto))) restp (if (jolt-truthy? restp) (jolt-invoke (var-deref "clojure.core" "str") "(" (jolt-invoke (var-deref "clojure.string" "join") " " params) " . " restp ")") (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") "(" (jolt-invoke (var-deref "clojure.string" "join") " " params) ")") jolt-nil)))) (pbind (jolt-map (lambda (o p) (let fnrec7992 ((o o) (p p)) (jolt-invoke (var-deref "clojure.core" "str") "(" p " " (jolt-invoke (var-deref "jolt.backend-scheme" "nhint-init") nh o p) ")"))) orig params)) (binds (if (jolt-truthy? restp) (jolt-concat pbind (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "(" restp " (list->cseq " restp "))"))) pbind)) (lett (jolt-invoke (var-deref "clojure.core" "str") "(let " label " (" (jolt-invoke (var-deref "clojure.string" "join") " " binds) ") " body ")")) (ret (jolt-get a (keyword #f "ret-nhint")))) (let* ((_o$7993 paramlist) (_o$7994 (if (jolt= ret (keyword #f "double")) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " lett ")") (if (jolt= ret (keyword #f "long")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " lett ")") (if (jolt-truthy? (keyword #f "else")) lett jolt-nil))))) (jolt-vector _o$7993 _o$7994))))))) emit-arity-clause) (let* ((_o$7995 (keyword #f "private")) (_o$7996 #t)) (jolt-hash-map _o$7995 _o$7996)))) + (def-var! "jolt.backend-scheme" "emit-fn" (letrec ((emit-fn (lambda (node) (let fnrec6475 ((node node)) (let* ((arities (jolt-get node (keyword #f "arities"))) (self (let* ((temp__27__auto (jolt-get node (keyword #f "name")))) (if (jolt-truthy? temp__27__auto) (let* ((nm temp__27__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") nm)) jolt-nil))) (clauses (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*known-procs*") (if (jolt-truthy? self) (jolt-conj (var-deref "jolt.backend-scheme" "*known-procs*") self) (var-deref "jolt.backend-scheme" "*known-procs*"))))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit-arity-clause") arities)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (_lambda (if (jolt= 1 (jolt-count clauses)) (let* ((c (jolt-first clauses))) (let* ((_a$6476 (var-deref "clojure.core" "str")) (_a$6477 "(lambda ") (_a$6478 (jolt-nth c 0)) (_a$6479 " ") (_a$6480 (jolt-nth c 1)) (_a$6481 ")")) (jolt-invoke _a$6476 _a$6477 _a$6478 _a$6479 _a$6480 _a$6481))) (jolt-invoke (var-deref "clojure.core" "str") "(case-lambda " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (c) (let fnrec6482 ((c c)) (let* ((_a$6483 (var-deref "clojure.core" "str")) (_a$6484 "(") (_a$6485 (jolt-nth c 0)) (_a$6486 " ") (_a$6487 (jolt-nth c 1)) (_a$6488 ")")) (jolt-invoke _a$6483 _a$6484 _a$6485 _a$6486 _a$6487 _a$6488)))) clauses)) ")")))) (let* ((temp__16__auto (jolt-get node (keyword #f "name")))) (if (jolt-truthy? temp__16__auto) (let* ((nm temp__16__auto)) (let* ((m (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") nm))) (jolt-invoke (var-deref "clojure.core" "str") "(letrec ((" m " " _lambda ")) " m ")"))) _lambda))))))) emit-fn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-fn" (letrec ((emit-fn (lambda (node) (let fnrec7997 ((node node)) (let* ((arities (jolt-get node (keyword #f "arities"))) (self (let* ((temp__27__auto (jolt-get node (keyword #f "name")))) (if (jolt-truthy? temp__27__auto) (let* ((nm temp__27__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") nm)) jolt-nil))) (clauses (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*known-procs*") (if (jolt-truthy? self) (jolt-conj (var-deref "jolt.backend-scheme" "*known-procs*") self) (var-deref "jolt.backend-scheme" "*known-procs*"))))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit-arity-clause") arities)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (clauses (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "trace-frames?")))) (if (jolt-truthy? and__25__auto) self and__25__auto))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (c) (let fnrec7998 ((c c)) (let* ((_o$8005 (jolt-nth c 0)) (_o$8006 (let* ((_a$7999 (var-deref "clojure.core" "str")) (_a$8000 "(begin (jolt-trace-push! ") (_a$8001 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") self)) (_a$8002 ") ") (_a$8003 (jolt-nth c 1)) (_a$8004 ")")) (jolt-invoke _a$7999 _a$8000 _a$8001 _a$8002 _a$8003 _a$8004)))) (jolt-vector _o$8005 _o$8006)))) clauses) clauses)) (_lambda (if (jolt= 1 (jolt-count clauses)) (let* ((c (jolt-first clauses))) (let* ((_a$8007 (var-deref "clojure.core" "str")) (_a$8008 "(lambda ") (_a$8009 (jolt-nth c 0)) (_a$8010 " ") (_a$8011 (jolt-nth c 1)) (_a$8012 ")")) (jolt-invoke _a$8007 _a$8008 _a$8009 _a$8010 _a$8011 _a$8012))) (jolt-invoke (var-deref "clojure.core" "str") "(case-lambda " (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (c) (let fnrec8013 ((c c)) (let* ((_a$8014 (var-deref "clojure.core" "str")) (_a$8015 "(") (_a$8016 (jolt-nth c 0)) (_a$8017 " ") (_a$8018 (jolt-nth c 1)) (_a$8019 ")")) (jolt-invoke _a$8014 _a$8015 _a$8016 _a$8017 _a$8018 _a$8019)))) clauses)) ")")))) (let* ((temp__16__auto (jolt-get node (keyword #f "name")))) (if (jolt-truthy? temp__16__auto) (let* ((nm temp__16__auto)) (let* ((m (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") nm))) (jolt-invoke (var-deref "clojure.core" "str") "(letrec ((" m " " _lambda ")) " m ")"))) _lambda))))))) emit-fn) (let* ((_o$8020 (keyword #f "private")) (_o$8021 #t)) (jolt-hash-map _o$8020 _o$8021)))) + (def-var! "jolt.backend-scheme" "native-op" (letrec ((native-op (lambda (fnode nargs) (let fnrec6489 ((fnode fnode) (nargs nargs)) (let* ((nm (let* ((G__123 (jolt-get fnode (keyword #f "op")))) (if (jolt= G__123 (keyword #f "var")) (if (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) (jolt-get fnode (keyword #f "name")) jolt-nil) (if (jolt= G__123 (keyword #f "host")) (jolt-get fnode (keyword #f "name")) jolt-nil)))) (op (if (jolt-truthy? nm) (jolt-invoke (var-deref "jolt.backend-scheme" "native-ops") nm) jolt-nil)) (arity-ok (if (jolt-truthy? nm) (jolt-invoke (var-deref "jolt.backend-scheme" "op-arity") nm) jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") op)) jolt-nil (if (jolt-truthy? (let* ((and__25__auto arity-ok)) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke arity-ok nargs)) and__25__auto))) jolt-nil (if (jolt-truthy? (keyword #f "else")) op jolt-nil)))))))) native-op))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "native-op" (letrec ((native-op (lambda (fnode nargs) (let fnrec8022 ((fnode fnode) (nargs nargs)) (let* ((nm (let* ((G__143 (jolt-get fnode (keyword #f "op")))) (if (jolt= G__143 (keyword #f "var")) (if (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) (jolt-get fnode (keyword #f "name")) jolt-nil) (if (jolt= G__143 (keyword #f "host")) (jolt-get fnode (keyword #f "name")) jolt-nil)))) (op (if (jolt-truthy? nm) (jolt-invoke (var-deref "jolt.backend-scheme" "native-ops") nm) jolt-nil)) (arity-ok (if (jolt-truthy? nm) (jolt-invoke (var-deref "jolt.backend-scheme" "op-arity") nm) jolt-nil))) (if (jolt-nil? op) jolt-nil (if (jolt-truthy? (let* ((and__25__auto arity-ok)) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke arity-ok nargs)) and__25__auto))) jolt-nil (if (jolt-truthy? (keyword #f "else")) op jolt-nil)))))))) native-op) (let* ((_o$8023 (keyword #f "private")) (_o$8024 #t)) (jolt-hash-map _o$8023 _o$8024)))) + (def-var! "jolt.backend-scheme" "ifn-kind" (letrec ((ifn-kind (lambda (fnode) (let fnrec6490 ((fnode fnode)) (let* ((G__124 (jolt-get fnode (keyword #f "op")))) (if (jolt= G__124 (keyword #f "const")) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get fnode (keyword #f "val")))) (keyword #f "keyword") jolt-nil) (if (jolt-truthy? (let* ((or__26__auto (jolt= G__124 (keyword #f "map")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= G__124 (keyword #f "set")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= G__124 (keyword #f "vector"))))))) (keyword #f "coll") jolt-nil))))))) ifn-kind))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "ifn-kind" (letrec ((ifn-kind (lambda (fnode) (let fnrec8025 ((fnode fnode)) (let* ((G__144 (jolt-get fnode (keyword #f "op")))) (if (jolt= G__144 (keyword #f "const")) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get fnode (keyword #f "val")))) (keyword #f "keyword") jolt-nil) (if (let* ((or__26__auto (jolt= G__144 (keyword #f "map")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= G__144 (keyword #f "set")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= G__144 (keyword #f "vector")))))) (keyword #f "coll") jolt-nil))))))) ifn-kind) (let* ((_o$8026 (keyword #f "private")) (_o$8027 #t)) (jolt-hash-map _o$8026 _o$8027)))) + (def-var! "jolt.backend-scheme" "stdlib-var?" (letrec ((stdlib-var? (lambda (n) (let fnrec6491 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.string" "starts-with?") (let* ((or__26__auto (jolt-get n (keyword #f "ns")))) (if (jolt-truthy? or__26__auto) or__26__auto "")) "clojure.") and__25__auto)))))) stdlib-var?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "stdlib-var?" (letrec ((stdlib-var? (lambda (n) (let fnrec8028 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.string" "starts-with?") (let* ((or__26__auto (jolt-get n (keyword #f "ns")))) (if (jolt-truthy? or__26__auto) or__26__auto "")) "clojure.") and__25__auto)))))) stdlib-var?) (let* ((_o$8029 (keyword #f "private")) (_o$8030 #t)) (jolt-hash-map _o$8029 _o$8030)))) + (def-var! "jolt.backend-scheme" "emit-numeric" (letrec ((emit-numeric (lambda (kind nm args order-args) (let fnrec6492 ((kind kind) (nm nm) (args args) (order-args order-args)) (if (jolt-truthy? (let* ((and__25__auto (jolt= kind (keyword #f "double")))) (if (jolt-truthy? and__25__auto) (jolt= nm "inc") and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(fl+ " (jolt-first args) " 1.0)") (if (jolt-truthy? (let* ((and__25__auto (jolt= kind (keyword #f "double")))) (if (jolt-truthy? and__25__auto) (jolt= nm "dec") and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(fl- " (jolt-first args) " 1.0)") (if (jolt-truthy? (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= nm "inc"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= nm "unchecked-inc"))) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(fx1+ " (jolt-first args) ")") (if (jolt-truthy? (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= nm "dec"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= nm "unchecked-dec"))) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(fx1- " (jolt-first args) ")") (if (jolt-truthy? (keyword #f "else")) (let* ((op (if (jolt= kind (keyword #f "double")) (jolt-invoke (var-deref "jolt.backend-scheme" "dbl-ops") nm) (jolt-invoke (var-deref "jolt.backend-scheme" "lng-ops") nm)))) (jolt-invoke order-args (lambda (as) (let fnrec6493 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" op " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")"))))) jolt-nil))))))))) emit-numeric))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-numeric" (letrec ((emit-numeric (lambda (kind nm args order-args) (let fnrec8031 ((kind kind) (nm nm) (args args) (order-args order-args)) (if (let* ((and__25__auto (jolt= kind (keyword #f "double")))) (if (jolt-truthy? and__25__auto) (jolt= nm "inc") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(fl+ " (jolt-first args) " 1.0)") (if (let* ((and__25__auto (jolt= kind (keyword #f "double")))) (if (jolt-truthy? and__25__auto) (jolt= nm "dec") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(fl- " (jolt-first args) " 1.0)") (if (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (jolt= nm "inc") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-l-inc " (jolt-first args) ")") (if (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (jolt= nm "dec") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-l-dec " (jolt-first args) ")") (if (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (jolt= nm "unchecked-inc") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-uncinc " (jolt-first args) ")") (if (let* ((and__25__auto (jolt= kind (keyword #f "long")))) (if (jolt-truthy? and__25__auto) (jolt= nm "unchecked-dec") and__25__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-uncdec " (jolt-first args) ")") (if (jolt-truthy? (keyword #f "else")) (let* ((op (let* ((G__145 kind)) (if (jolt= G__145 (keyword #f "double")) (jolt-invoke (var-deref "jolt.backend-scheme" "dbl-ops") nm) (if (jolt= G__145 (keyword #f "long")) (jolt-invoke (var-deref "jolt.backend-scheme" "lng-ops") nm) (if (jolt= G__145 (keyword #f "bigdec")) (jolt-invoke (var-deref "jolt.backend-scheme" "bd-ops") nm) (jolt-throw (let* ((_a$8032 (jolt-invoke (var-deref "clojure.core" "str") "No matching clause: " G__145)) (_a$8033 (jolt-hash-map))) (jolt-ex-info _a$8032 _a$8033))))))))) (jolt-invoke order-args (lambda (as) (let fnrec8034 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" op " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")"))))) jolt-nil))))))))))) emit-numeric) (let* ((_o$8035 (keyword #f "private")) (_o$8036 #t)) (jolt-hash-map _o$8035 _o$8036)))) + (def-var! "jolt.backend-scheme" "emit-invoke" (letrec ((emit-invoke (lambda (node) (let fnrec6494 ((node node)) (let* ((fnode (jolt-get node (keyword #f "fn"))) (arg-nodes (jolt-get node (keyword #f "args"))) (args (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit") arg-nodes)) (nop (jolt-invoke (var-deref "jolt.backend-scheme" "native-op") fnode (jolt-count args))) (kind (jolt-invoke (var-deref "jolt.backend-scheme" "ifn-kind") fnode)) (order-args (lambda (build) (let fnrec6495 ((build build)) (jolt-invoke (var-deref "jolt.backend-scheme" "ordered-call") arg-nodes args build)))) (defstr (lambda (as) (let fnrec6496 ((as as)) (if (> (jolt-count as) 1) (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-nth as 1)) "")))) (invoke (lambda () (let fnrec6497 () (let* ((_a$6499 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$6500 (jolt-cons fnode arg-nodes)) (_a$6501 (jolt-cons (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode) args)) (_a$6502 (lambda (G__125) (let fnrec6498 ((G__125 G__125)) (let* ((G__126 G__125) (f (jolt-nth G__126 0 jolt-nil)) (as (jolt-invoke (var-deref "clojure.core" "nthnext") G__126 1))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-invoke " f (if (jolt-truthy? (jolt-seq as)) (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " as)) "") ")")))))) (jolt-invoke _a$6499 _a$6500 _a$6501 _a$6502)))))) (if (jolt-truthy? (jolt-get node (keyword #f "num-kind"))) (let* ((_a$6503 (var-deref "jolt.backend-scheme" "emit-numeric")) (_a$6504 (jolt-get node (keyword #f "num-kind"))) (_a$6505 (jolt-get fnode (keyword #f "name"))) (_a$6506 args) (_a$6507 order-args)) (jolt-invoke _a$6503 _a$6504 _a$6505 _a$6506 _a$6507)) (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-empty? args))) (if (jolt-truthy? and__25__auto) (jolt= nop "+") and__25__auto)) and__25__auto))) "0" (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-empty? args))) (if (jolt-truthy? and__25__auto) (jolt= nop "*") and__25__auto)) and__25__auto))) "1" (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "cmp1-ops") nop) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(begin " (jolt-first args) " #t)") (if (jolt-truthy? nop) (jolt-invoke order-args (lambda (as) (let fnrec6508 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" nop " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")")))) (if (jolt= kind (keyword #f "keyword")) (jolt-invoke order-args (lambda (as) (let fnrec6509 ((as as)) (let* ((_a$6510 (var-deref "clojure.core" "str")) (_a$6511 "(jolt-get ") (_a$6512 (jolt-first as)) (_a$6513 " ") (_a$6514 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode)) (_a$6515 (jolt-invoke defstr as)) (_a$6516 ")")) (jolt-invoke _a$6510 _a$6511 _a$6512 _a$6513 _a$6514 _a$6515 _a$6516))))) (if (jolt= kind (keyword #f "coll")) (let* ((_a$6518 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$6519 (jolt-cons fnode arg-nodes)) (_a$6520 (jolt-cons (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode) args)) (_a$6521 (lambda (G__127) (let fnrec6517 ((G__127 G__127)) (let* ((G__128 G__127) (c (jolt-nth G__128 0 jolt-nil)) (as (jolt-invoke (var-deref "clojure.core" "nthnext") G__128 1))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-get " c " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")")))))) (jolt-invoke _a$6518 _a$6519 _a$6520 _a$6521)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.backend-scheme" "stdlib-var?") fnode))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "prelude-mode?"))) and__25__auto))) (jolt-throw (let* ((_a$6528 (let* ((_a$6522 (var-deref "clojure.core" "str")) (_a$6523 "emit: unsupported stdlib fn `") (_a$6524 (jolt-get fnode (keyword #f "ns"))) (_a$6525 "/") (_a$6526 (jolt-get fnode (keyword #f "name"))) (_a$6527 "` (no core on Chez yet)")) (jolt-invoke _a$6522 _a$6523 _a$6524 _a$6525 _a$6526 _a$6527))) (_a$6529 (jolt-hash-map))) (jolt-ex-info _a$6528 _a$6529))) (if (jolt= (keyword #f "host-static") (jolt-get fnode (keyword #f "op"))) (jolt-invoke order-args (lambda (as) (let fnrec6530 ((as as)) (let* ((_a$6531 (var-deref "clojure.core" "str")) (_a$6532 "(host-static-call ") (_a$6533 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get fnode (keyword #f "class")))) (_a$6534 " ") (_a$6535 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get fnode (keyword #f "member")))) (_a$6536 (if (jolt-empty? as) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " as)))) (_a$6537 ")")) (jolt-invoke _a$6531 _a$6532 _a$6533 _a$6534 _a$6535 _a$6536 _a$6537))))) (if (jolt= (keyword #f "host") (jolt-get fnode (keyword #f "op"))) (jolt-throw (let* ((_a$6538 (jolt-invoke (var-deref "clojure.core" "str") "emit: unsupported host call `" (jolt-get fnode (keyword #f "name")) "`")) (_a$6539 (jolt-hash-map))) (jolt-ex-info _a$6538 _a$6539))) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.backend-scheme" "*known-procs*") (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get fnode (keyword #f "name"))))) and__25__auto))) (jolt-invoke invoke) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$6540 (var-deref "jolt.backend-scheme" "direct-linkable?")) (_a$6541 (jolt-get fnode (keyword #f "ns"))) (_a$6542 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$6540 _a$6541 _a$6542)))) (if (jolt-truthy? and__25__auto) (let* ((_a$6543 (var-deref "jolt.backend-scheme" "direct-link-fn?")) (_a$6544 (jolt-get fnode (keyword #f "ns"))) (_a$6545 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$6543 _a$6544 _a$6545)) and__25__auto)) and__25__auto))) (jolt-invoke order-args (lambda (as) (let fnrec6546 ((as as)) (let* ((_a$6550 (var-deref "clojure.core" "str")) (_a$6551 "(") (_a$6552 (let* ((_a$6547 (var-deref "jolt.backend-scheme" "dl-name")) (_a$6548 (jolt-get fnode (keyword #f "ns"))) (_a$6549 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$6547 _a$6548 _a$6549))) (_a$6553 (if (jolt-truthy? (jolt-seq as)) (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " as)) "")) (_a$6554 ")")) (jolt-invoke _a$6550 _a$6551 _a$6552 _a$6553 _a$6554))))) (if (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))) (jolt-invoke invoke) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke invoke) jolt-nil))))))))))))))))))) emit-invoke))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "struct-field-index" (letrec ((struct-field-index (lambda (shape kw) (let fnrec8037 ((shape shape) (kw kw)) (if (jolt-truthy? shape) (let* ((i 0)) (let loop8038 ((i i)) (if (jolt-n>= i (jolt-count shape)) jolt-nil (if (jolt= (jolt-nth shape i) kw) i (if (jolt-truthy? (keyword #f "else")) (loop8038 (jolt-inc i)) jolt-nil))))) jolt-nil))))) struct-field-index) (let* ((_o$8039 (keyword #f "private")) (_o$8040 #t)) (jolt-hash-map _o$8039 _o$8040)))) + (def-var! "jolt.backend-scheme" "emit-try" (letrec ((emit-try (lambda (node) (let fnrec6555 ((node node)) (let* ((core (let* ((temp__16__auto (jolt-get node (keyword #f "catch-sym")))) (if (jolt-truthy? temp__16__auto) (let* ((cs temp__16__auto)) (let* ((_a$6556 (var-deref "clojure.core" "str")) (_a$6557 "(guard (") (_a$6558 (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") cs)) (_a$6559 " (else ") (_a$6560 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "catch-body")))) (_a$6561 ")) ") (_a$6562 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body")))) (_a$6563 ")")) (jolt-invoke _a$6556 _a$6557 _a$6558 _a$6559 _a$6560 _a$6561 _a$6562 _a$6563))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body"))))))) (let* ((temp__16__auto (jolt-get node (keyword #f "finally")))) (if (jolt-truthy? temp__16__auto) (let* ((fin temp__16__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(dynamic-wind (lambda () #f) (lambda () " core ") (lambda () " (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fin) "))")) core))))))) emit-try))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "plain-call" (letrec ((plain-call (lambda (callee operand-strs) (let fnrec8041 ((callee callee) (operand-strs operand-strs)) (jolt-invoke (var-deref "clojure.core" "str") "(" callee (if (jolt-truthy? (jolt-seq operand-strs)) (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " operand-strs)) "") ")"))))) plain-call) (let* ((_o$8042 (keyword #f "private")) (_o$8043 #t)) (jolt-hash-map _o$8042 _o$8043)))) + (def-var! "jolt.backend-scheme" "returns-scheme-bool?" (letrec ((returns-scheme-bool? (lambda (node) (let fnrec6564 ((node node)) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "boolean?") (jolt-get node (keyword #f "val"))) and__25__auto))) #t (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((nop (let* ((_a$6565 (var-deref "jolt.backend-scheme" "native-op")) (_a$6566 (jolt-get node (keyword #f "fn"))) (_a$6567 (jolt-count (jolt-get node (keyword #f "args"))))) (jolt-invoke _a$6565 _a$6566 _a$6567)))) (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "bool-returning-ops") nop) and__25__auto))) #t #f)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))) returns-scheme-bool?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "tail-marked-call" (letrec ((tail-marked-call (lambda (callee operand-strs) (let fnrec8044 ((callee callee) (operand-strs operand-strs)) (let* ((tmps (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (_) (let fnrec8045 ((_ _)) (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_tt$"))) operand-strs)) (binds (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map (lambda (t a) (let fnrec8046 ((t t) (a a)) (jolt-invoke (var-deref "clojure.core" "str") "(" t " " a ")"))) tmps operand-strs)))) (jolt-invoke (var-deref "clojure.core" "str") "(let* (" binds ") (jolt-trace-mark! #t) " (jolt-invoke (var-deref "jolt.backend-scheme" "plain-call") callee tmps) ")")))))) tail-marked-call) (let* ((_o$8047 (keyword #f "private")) (_o$8048 #t)) (jolt-hash-map _o$8047 _o$8048)))) + (def-var! "jolt.backend-scheme" "emit" (letrec ((emit (lambda (node) (let fnrec6568 ((node node)) (let* ((G__129 (jolt-get node (keyword #f "op")))) (if (jolt= G__129 (keyword #f "const")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") (jolt-get node (keyword #f "val"))) (if (jolt= G__129 (keyword #f "local")) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get node (keyword #f "name"))) (if (jolt= G__129 (keyword #f "var")) (let* ((core-proc (let* ((and__25__auto (jolt= "clojure.core" (jolt-get node (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "core-value-procs") (jolt-get node (keyword #f "name"))) and__25__auto)))) (if (jolt-truthy? core-proc) core-proc (if (jolt-truthy? (let* ((_a$6569 (var-deref "jolt.backend-scheme" "direct-linkable?")) (_a$6570 (jolt-get node (keyword #f "ns"))) (_a$6571 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$6569 _a$6570 _a$6571))) (let* ((_a$6572 (var-deref "jolt.backend-scheme" "dl-name")) (_a$6573 (jolt-get node (keyword #f "ns"))) (_a$6574 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$6572 _a$6573 _a$6574)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.backend-scheme" "stdlib-var?") node))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "prelude-mode?"))) and__25__auto))) (jolt-throw (let* ((_a$6581 (let* ((_a$6575 (var-deref "clojure.core" "str")) (_a$6576 "emit: unsupported stdlib ref `") (_a$6577 (jolt-get node (keyword #f "ns"))) (_a$6578 "/") (_a$6579 (jolt-get node (keyword #f "name"))) (_a$6580 "` (no core on Chez yet)")) (jolt-invoke _a$6575 _a$6576 _a$6577 _a$6578 _a$6579 _a$6580))) (_a$6582 (jolt-hash-map))) (jolt-ex-info _a$6581 _a$6582))) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$6583 (var-deref "clojure.core" "str")) (_a$6584 "(var-deref ") (_a$6585 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6586 " ") (_a$6587 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6588 ")")) (jolt-invoke _a$6583 _a$6584 _a$6585 _a$6586 _a$6587 _a$6588)) jolt-nil))))) (if (jolt= G__129 (keyword #f "the-var")) (let* ((_a$6589 (var-deref "clojure.core" "str")) (_a$6590 "(jolt-var ") (_a$6591 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6592 " ") (_a$6593 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6594 ")")) (jolt-invoke _a$6589 _a$6590 _a$6591 _a$6592 _a$6593 _a$6594)) (if (jolt= G__129 (keyword #f "set-var")) (let* ((_a$6595 (var-deref "clojure.core" "str")) (_a$6596 "(jolt-var-set ") (_a$6597 (jolt-invoke emit (jolt-get node (keyword #f "the-var")))) (_a$6598 " ") (_a$6599 (jolt-invoke emit (jolt-get node (keyword #f "val")))) (_a$6600 ")")) (jolt-invoke _a$6595 _a$6596 _a$6597 _a$6598 _a$6599 _a$6600)) (if (jolt= G__129 (keyword #f "set-field")) (let* ((_a$6601 (var-deref "clojure.core" "str")) (_a$6602 "(jolt-set-field! ") (_a$6603 (jolt-invoke emit (jolt-get node (keyword #f "obj")))) (_a$6604 " (keyword #f ") (_a$6605 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "field")))) (_a$6606 ") ") (_a$6607 (jolt-invoke emit (jolt-get node (keyword #f "val")))) (_a$6608 ")")) (jolt-invoke _a$6601 _a$6602 _a$6603 _a$6604 _a$6605 _a$6606 _a$6607 _a$6608)) (if (jolt= G__129 (keyword #f "defmacro")) (let* ((_a$6609 (var-deref "clojure.core" "str")) (_a$6610 "(begin (def-var! ") (_a$6611 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6612 " ") (_a$6613 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6614 " ") (_a$6615 (jolt-invoke emit (jolt-get node (keyword #f "fn")))) (_a$6616 ") (mark-macro! ") (_a$6617 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6618 " ") (_a$6619 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6620 ") jolt-nil)")) (jolt-invoke _a$6609 _a$6610 _a$6611 _a$6612 _a$6613 _a$6614 _a$6615 _a$6616 _a$6617 _a$6618 _a$6619 _a$6620)) (if (jolt= G__129 (keyword #f "host")) (jolt-throw (let* ((_a$6621 (jolt-invoke (var-deref "clojure.core" "str") "emit: unsupported host ref `" (jolt-get node (keyword #f "name")) "`")) (_a$6622 (jolt-hash-map))) (jolt-ex-info _a$6621 _a$6622))) (if (jolt= G__129 (keyword #f "host-static")) (let* ((_a$6623 (var-deref "clojure.core" "str")) (_a$6624 "(host-static-ref ") (_a$6625 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "class")))) (_a$6626 " ") (_a$6627 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "member")))) (_a$6628 ")")) (jolt-invoke _a$6623 _a$6624 _a$6625 _a$6626 _a$6627 _a$6628)) (if (jolt= G__129 (keyword #f "host-new")) (let* ((_a$6629 (var-deref "clojure.core" "str")) (_a$6630 "(host-new ") (_a$6631 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "class")))) (_a$6632 (let* ((args (jolt-map emit (jolt-get node (keyword #f "args"))))) (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args))))) (_a$6633 ")")) (jolt-invoke _a$6629 _a$6630 _a$6631 _a$6632 _a$6633)) (if (jolt= G__129 (keyword #f "if")) (let* ((test (jolt-get node (keyword #f "test"))) (t (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "returns-scheme-bool?") test)) (jolt-invoke emit test) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-truthy? " (jolt-invoke emit test) ")")))) (let* ((_a$6634 (var-deref "clojure.core" "str")) (_a$6635 "(if ") (_a$6636 t) (_a$6637 " ") (_a$6638 (jolt-invoke emit (jolt-get node (keyword #f "then")))) (_a$6639 " ") (_a$6640 (jolt-invoke emit (jolt-get node (keyword #f "else")))) (_a$6641 ")")) (jolt-invoke _a$6634 _a$6635 _a$6636 _a$6637 _a$6638 _a$6639 _a$6640 _a$6641))) (if (jolt= G__129 (keyword #f "do")) (let* ((_a$6642 (var-deref "clojure.core" "str")) (_a$6643 "(begin ") (_a$6644 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit (jolt-get node (keyword #f "statements"))))) (_a$6645 (if (jolt-empty? (jolt-get node (keyword #f "statements"))) "" " ")) (_a$6646 (jolt-invoke emit (jolt-get node (keyword #f "ret")))) (_a$6647 ")")) (jolt-invoke _a$6642 _a$6643 _a$6644 _a$6645 _a$6646 _a$6647)) (if (jolt= G__129 (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-invoke") node) (if (jolt= G__129 (keyword #f "vector")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-vector" (jolt-map emit (jolt-get node (keyword #f "items")))) (if (jolt= G__129 (keyword #f "set")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-hash-set" (jolt-map emit (jolt-get node (keyword #f "items")))) (if (jolt= G__129 (keyword #f "map")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-hash-map" (let* ((_a$6651 (var-deref "clojure.core" "mapcat")) (_a$6652 (lambda (p) (let fnrec6648 ((p p)) (let* ((_o$6649 (jolt-invoke emit (jolt-nth p 0))) (_o$6650 (jolt-invoke emit (jolt-nth p 1)))) (jolt-vector _o$6649 _o$6650))))) (_a$6653 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$6651 _a$6652 _a$6653))) (if (jolt= G__129 (keyword #f "quote")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get node (keyword #f "form"))) (if (jolt= G__129 (keyword #f "throw")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-throw " (jolt-invoke emit (jolt-get node (keyword #f "expr"))) ")") (if (jolt= G__129 (keyword #f "coerce")) (let* ((e (jolt-invoke emit (jolt-get node (keyword #f "expr"))))) (if (jolt= (keyword #f "double") (jolt-get node (keyword #f "kind"))) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " e ")") (if (jolt= (keyword #f "long") (jolt-get node (keyword #f "kind"))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " e ")") (if (jolt-truthy? (keyword #f "else")) e jolt-nil)))) (if (jolt= G__129 (keyword #f "try")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-try") node) (if (jolt= G__129 (keyword #f "regex")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-regex " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__129 (keyword #f "inst")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-inst-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__129 (keyword #f "uuid")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-uuid-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__129 (keyword #f "bigdec")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-bigdec-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__129 (keyword #f "the-ns")) (jolt-invoke (var-deref "clojure.core" "str") "(intern-ns! " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name"))) ")") (if (jolt= G__129 (keyword #f "host-call")) (let* ((m (jolt-get node (keyword #f "method"))) (target (jolt-invoke emit (jolt-get node (keyword #f "target")))) (args (jolt-map emit (jolt-get node (keyword #f "args"))))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "supported-host-methods") m)) (let* ((_a$6654 (var-deref "clojure.core" "str")) (_a$6655 "(jolt-host-call ") (_a$6656 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") m)) (_a$6657 " ") (_a$6658 target) (_a$6659 (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args)))) (_a$6660 ")")) (jolt-invoke _a$6654 _a$6655 _a$6656 _a$6657 _a$6658 _a$6659 _a$6660)) (let* ((_a$6661 (var-deref "clojure.core" "str")) (_a$6662 "(record-method-dispatch ") (_a$6663 target) (_a$6664 " ") (_a$6665 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") m)) (_a$6666 " (jolt-vector") (_a$6667 (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args)))) (_a$6668 "))")) (jolt-invoke _a$6661 _a$6662 _a$6663 _a$6664 _a$6665 _a$6666 _a$6667 _a$6668)))) (if (jolt= G__129 (keyword #f "let")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-let") node) (if (jolt= G__129 (keyword #f "loop")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-loop") node) (if (jolt= G__129 (keyword #f "recur")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-recur") node) (if (jolt= G__129 (keyword #f "ffi-fn")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ffi-fn") node) (if (jolt= G__129 (keyword #f "ffi-callable")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ffi-callable") node) (if (jolt= G__129 (keyword #f "fn")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-fn") node) (if (jolt= G__129 (keyword #f "def")) (if (jolt-truthy? (jolt-get node (keyword #f "no-init"))) (let* ((_a$6669 (var-deref "clojure.core" "str")) (_a$6670 "(declare-var! ") (_a$6671 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6672 " ") (_a$6673 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6674 ")")) (jolt-invoke _a$6669 _a$6670 _a$6671 _a$6672 _a$6673 _a$6674)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "jmeta-nonempty?") (jolt-get node (keyword #f "meta")))) (let* ((_a$6675 (var-deref "clojure.core" "str")) (_a$6676 "(def-var-with-meta! ") (_a$6677 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6678 " ") (_a$6679 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6680 " ") (_a$6681 (jolt-invoke emit (jolt-get node (keyword #f "init")))) (_a$6682 " ") (_a$6683 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get node (keyword #f "meta")))) (_a$6684 ")")) (jolt-invoke _a$6675 _a$6676 _a$6677 _a$6678 _a$6679 _a$6680 _a$6681 _a$6682 _a$6683 _a$6684)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$6685 (var-deref "clojure.core" "str")) (_a$6686 "(def-var! ") (_a$6687 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$6688 " ") (_a$6689 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$6690 " ") (_a$6691 (jolt-invoke emit (jolt-get node (keyword #f "init")))) (_a$6692 ")")) (jolt-invoke _a$6685 _a$6686 _a$6687 _a$6688 _a$6689 _a$6690 _a$6691 _a$6692)) jolt-nil))) (jolt-throw (let* ((_a$6693 (jolt-invoke (var-deref "clojure.core" "str") "emit: op not yet ported / unhandled: " (jolt-invoke (var-deref "clojure.core" "pr-str") (jolt-get node (keyword #f "op"))))) (_a$6694 (jolt-hash-map))) (jolt-ex-info _a$6693 _a$6694))))))))))))))))))))))))))))))))))))))))) emit))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-call" (letrec ((emit-call (lambda (tail? callee operand-strs) (let fnrec8049 ((tail? tail?) (callee callee) (operand-strs operand-strs)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "trace-frames?")))) (if (jolt-truthy? and__25__auto) tail? and__25__auto))) (jolt-invoke (var-deref "jolt.backend-scheme" "tail-marked-call") callee operand-strs) (jolt-invoke (var-deref "jolt.backend-scheme" "plain-call") callee operand-strs)))))) emit-call) (let* ((_o$8050 (keyword #f "private")) (_o$8051 #t)) (jolt-hash-map _o$8050 _o$8051)))) + (def-var! "jolt.backend-scheme" "dl-opt-out?" (letrec ((dl-opt-out? (lambda (m) (let fnrec6695 ((m m)) (let* ((or__26__auto (jolt-get m (keyword #f "dynamic")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get m (keyword #f "redef")))))))) dl-opt-out?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-invoke" (letrec ((emit-invoke (lambda (node) (let fnrec8052 ((node node)) (let* ((tail? (var-deref "jolt.backend-scheme" "*tail?*"))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (let* ((fnode (jolt-get node (keyword #f "fn"))) (arg-nodes (jolt-get node (keyword #f "args"))) (args (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit") arg-nodes)) (nop (jolt-invoke (var-deref "jolt.backend-scheme" "native-op") fnode (jolt-count args))) (kind (jolt-invoke (var-deref "jolt.backend-scheme" "ifn-kind") fnode)) (order-args (lambda (build) (let fnrec8053 ((build build)) (jolt-invoke (var-deref "jolt.backend-scheme" "ordered-call") arg-nodes args build)))) (defstr (lambda (as) (let fnrec8054 ((as as)) (if (jolt-n> (jolt-count as) 1) (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-nth as 1)) "")))) (invoke (lambda () (let fnrec8055 () (let* ((_a$8057 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$8058 (jolt-cons fnode arg-nodes)) (_a$8059 (jolt-cons (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode) args)) (_a$8060 (lambda (operands) (let fnrec8056 ((operands operands)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-call") tail? "jolt-invoke" operands))))) (jolt-invoke _a$8057 _a$8058 _a$8059 _a$8060)))))) (if (jolt-truthy? (jolt-get node (keyword #f "devirt-type"))) (jolt-invoke order-args (lambda (as) (let fnrec8061 ((as as)) (let* ((r (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_r$")) (dv (let* ((_a$8062 (var-deref "clojure.core" "str")) (_a$8063 "(devirt-resolve ") (_a$8064 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "devirt-type")))) (_a$8065 " ") (_a$8066 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "devirt-proto")))) (_a$8067 " ") (_a$8068 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "devirt-method")))) (_a$8069 " ") (_a$8070 r) (_a$8071 ")")) (jolt-invoke _a$8062 _a$8063 _a$8064 _a$8065 _a$8066 _a$8067 _a$8068 _a$8069 _a$8070 _a$8071))) (cells (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "cache-cells"))) (resolver (if (jolt-truthy? cells) (let* ((c (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_dvc$"))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") cells jolt-conj c) (jolt-invoke (var-deref "clojure.core" "str") "(or " c " (let ((_f " dv ")) (set! " c " _f) _f))"))) dv))) (let* ((_a$8072 (var-deref "clojure.core" "str")) (_a$8073 "(let* ((") (_a$8074 r) (_a$8075 " ") (_a$8076 (jolt-first as)) (_a$8077 ")) (") (_a$8078 resolver) (_a$8079 " ") (_a$8080 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-cons r (jolt-rest as)))) (_a$8081 "))")) (jolt-invoke _a$8072 _a$8073 _a$8074 _a$8075 _a$8076 _a$8077 _a$8078 _a$8079 _a$8080 _a$8081)))))) (if (jolt-truthy? (jolt-get node (keyword #f "num-kind"))) (let* ((_a$8082 (var-deref "jolt.backend-scheme" "emit-numeric")) (_a$8083 (jolt-get node (keyword #f "num-kind"))) (_a$8084 (jolt-get fnode (keyword #f "name"))) (_a$8085 args) (_a$8086 order-args)) (jolt-invoke _a$8082 _a$8083 _a$8084 _a$8085 _a$8086)) (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-empty? args))) (if (jolt-truthy? and__25__auto) (jolt= nop "+") and__25__auto)) and__25__auto))) "0" (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-empty? args))) (if (jolt-truthy? and__25__auto) (jolt= nop "*") and__25__auto)) and__25__auto))) "1" (if (jolt-truthy? (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "cmp1-ops") nop) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "str") "(begin " (jolt-first args) " #t)") (if (jolt-truthy? nop) (jolt-invoke order-args (lambda (as) (let fnrec8087 ((as as)) (jolt-invoke (var-deref "clojure.core" "str") "(" nop " " (jolt-invoke (var-deref "clojure.string" "join") " " as) ")")))) (if (jolt= kind (keyword #f "keyword")) (let* ((recv (jolt-first arg-nodes)) (idx (if (let* ((and__25__auto (jolt= (keyword #f "struct") (jolt-get recv (keyword #f "hint"))))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count arg-nodes)) and__25__auto)) (let* ((_a$8088 (var-deref "jolt.backend-scheme" "struct-field-index")) (_a$8089 (jolt-get recv (keyword #f "shape"))) (_a$8090 (jolt-get fnode (keyword #f "val")))) (jolt-invoke _a$8088 _a$8089 _a$8090)) jolt-nil))) (if (jolt-truthy? idx) (jolt-invoke order-args (lambda (as) (let fnrec8091 ((as as)) (let* ((_a$8092 (var-deref "clojure.core" "str")) (_a$8093 "(jrec-field-at ") (_a$8094 (jolt-first as)) (_a$8095 " ") (_a$8096 idx) (_a$8097 " ") (_a$8098 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode)) (_a$8099 ")")) (jolt-invoke _a$8092 _a$8093 _a$8094 _a$8095 _a$8096 _a$8097 _a$8098 _a$8099))))) (jolt-invoke order-args (lambda (as) (let fnrec8100 ((as as)) (let* ((_a$8101 (var-deref "clojure.core" "str")) (_a$8102 "(jolt-get ") (_a$8103 (jolt-first as)) (_a$8104 " ") (_a$8105 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode)) (_a$8106 (jolt-invoke defstr as)) (_a$8107 ")")) (jolt-invoke _a$8101 _a$8102 _a$8103 _a$8104 _a$8105 _a$8106 _a$8107))))))) (if (jolt= kind (keyword #f "coll")) (let* ((_a$8115 (var-deref "jolt.backend-scheme" "ordered-call")) (_a$8116 (jolt-cons fnode arg-nodes)) (_a$8117 (jolt-cons (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fnode) args)) (_a$8118 (lambda (G__146) (let fnrec8108 ((G__146 G__146)) (let* ((G__147 G__146) (c (jolt-nth G__147 0 jolt-nil)) (as (jolt-invoke (var-deref "clojure.core" "nthnext") G__147 1))) (let* ((_a$8109 (var-deref "clojure.core" "str")) (_a$8110 (if (let* ((and__25__auto (jolt= (keyword #f "vector") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count as)) and__25__auto)) "(jolt-nth " "(jolt-get ")) (_a$8111 c) (_a$8112 " ") (_a$8113 (jolt-invoke (var-deref "clojure.string" "join") " " as)) (_a$8114 ")")) (jolt-invoke _a$8109 _a$8110 _a$8111 _a$8112 _a$8113 _a$8114))))))) (jolt-invoke _a$8115 _a$8116 _a$8117 _a$8118)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.backend-scheme" "stdlib-var?") fnode))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "prelude-mode?"))) and__25__auto))) (jolt-throw (let* ((_a$8125 (let* ((_a$8119 (var-deref "clojure.core" "str")) (_a$8120 "emit: unsupported stdlib fn `") (_a$8121 (jolt-get fnode (keyword #f "ns"))) (_a$8122 "/") (_a$8123 (jolt-get fnode (keyword #f "name"))) (_a$8124 "` (no core on Chez yet)")) (jolt-invoke _a$8119 _a$8120 _a$8121 _a$8122 _a$8123 _a$8124))) (_a$8126 (jolt-hash-map))) (jolt-ex-info _a$8125 _a$8126))) (if (jolt= (keyword #f "host-static") (jolt-get fnode (keyword #f "op"))) (jolt-invoke order-args (lambda (as) (let fnrec8127 ((as as)) (let* ((_a$8128 (var-deref "clojure.core" "str")) (_a$8129 "(host-static-call ") (_a$8130 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get fnode (keyword #f "class")))) (_a$8131 " ") (_a$8132 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get fnode (keyword #f "member")))) (_a$8133 (if (jolt-empty? as) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " as)))) (_a$8134 ")")) (jolt-invoke _a$8128 _a$8129 _a$8130 _a$8131 _a$8132 _a$8133 _a$8134))))) (if (jolt= (keyword #f "host") (jolt-get fnode (keyword #f "op"))) (jolt-throw (let* ((_a$8135 (jolt-invoke (var-deref "clojure.core" "str") "emit: unsupported host call `" (jolt-get fnode (keyword #f "name")) "`")) (_a$8136 (jolt-hash-map))) (jolt-ex-info _a$8135 _a$8136))) (if (jolt= (keyword #f "local") (jolt-get fnode (keyword #f "op"))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "*known-procs*") (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get fnode (keyword #f "name"))))) (jolt-invoke order-args (lambda (as) (let fnrec8137 ((as as)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-call") tail? (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get fnode (keyword #f "name"))) as)))) (jolt-invoke invoke)) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$8138 (var-deref "jolt.backend-scheme" "direct-linkable?")) (_a$8139 (jolt-get fnode (keyword #f "ns"))) (_a$8140 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$8138 _a$8139 _a$8140)))) (if (jolt-truthy? and__25__auto) (let* ((_a$8141 (var-deref "jolt.backend-scheme" "direct-link-fn?")) (_a$8142 (jolt-get fnode (keyword #f "ns"))) (_a$8143 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$8141 _a$8142 _a$8143)) and__25__auto)) and__25__auto))) (jolt-invoke order-args (lambda (as) (let fnrec8144 ((as as)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-call") tail? (let* ((_a$8145 (var-deref "jolt.backend-scheme" "dl-name")) (_a$8146 (jolt-get fnode (keyword #f "ns"))) (_a$8147 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$8145 _a$8146 _a$8147)) as)))) (if (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))) (jolt-invoke invoke) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke invoke) jolt-nil))))))))))))))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))))) emit-invoke) (let* ((_o$8148 (keyword #f "private")) (_o$8149 #t)) (jolt-hash-map _o$8148 _o$8149)))) + (def-var! "jolt.backend-scheme" "emit-top-form" (letrec ((emit-top-form (lambda (node) (let fnrec6696 ((node node)) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link?"))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") node) (if (jolt= (keyword #f "do") (jolt-get node (keyword #f "op"))) (let* ((_a$6697 (var-deref "clojure.core" "str")) (_a$6698 "(begin ") (_a$6699 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-top-form (jolt-get node (keyword #f "statements"))))) (_a$6700 (if (jolt-empty? (jolt-get node (keyword #f "statements"))) "" " ")) (_a$6701 (jolt-invoke emit-top-form (jolt-get node (keyword #f "ret")))) (_a$6702 ")")) (jolt-invoke _a$6697 _a$6698 _a$6699 _a$6700 _a$6701 _a$6702)) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-get node (keyword #f "no-init"))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.backend-scheme" "dl-opt-out?") (jolt-get node (keyword #f "meta")))) and__25__auto)) and__25__auto))) (let* ((ns (jolt-get node (keyword #f "ns"))) (nm (jolt-get node (keyword #f "name"))) (b (jolt-invoke (var-deref "jolt.backend-scheme" "dl-name") ns nm))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "direct-link-defined") jolt-conj (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm)) (if (jolt= (keyword #f "fn") (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "op"))) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "direct-link-fns") jolt-conj (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm)) jolt-nil) (let* ((init (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "init"))))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "jmeta-nonempty?") (jolt-get node (keyword #f "meta")))) (let* ((_a$6703 (var-deref "clojure.core" "str")) (_a$6704 "(begin (define ") (_a$6705 b) (_a$6706 " ") (_a$6707 init) (_a$6708 ") (def-var-with-meta! ") (_a$6709 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$6710 " ") (_a$6711 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$6712 " ") (_a$6713 b) (_a$6714 " ") (_a$6715 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get node (keyword #f "meta")))) (_a$6716 "))")) (jolt-invoke _a$6703 _a$6704 _a$6705 _a$6706 _a$6707 _a$6708 _a$6709 _a$6710 _a$6711 _a$6712 _a$6713 _a$6714 _a$6715 _a$6716)) (let* ((_a$6717 (var-deref "clojure.core" "str")) (_a$6718 "(begin (define ") (_a$6719 b) (_a$6720 " ") (_a$6721 init) (_a$6722 ") (def-var! ") (_a$6723 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$6724 " ") (_a$6725 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$6726 " ") (_a$6727 b) (_a$6728 "))")) (jolt-invoke _a$6717 _a$6718 _a$6719 _a$6720 _a$6721 _a$6722 _a$6723 _a$6724 _a$6725 _a$6726 _a$6727 _a$6728)))))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") node) jolt-nil)))))))) emit-top-form))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-try" (letrec ((emit-try (lambda (node) (let fnrec8150 ((node node)) (let* ((core (let* ((temp__16__auto (jolt-get node (keyword #f "catch-sym")))) (if (jolt-truthy? temp__16__auto) (let* ((cs temp__16__auto)) (let* ((raw (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get node (keyword #f "catch-raw-sym"))))) (let* ((_a$8151 (var-deref "clojure.core" "str")) (_a$8152 "(guard (") (_a$8153 raw) (_a$8154 " (else (let ((") (_a$8155 (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") cs)) (_a$8156 " (jolt-unwrap-throw ") (_a$8157 raw) (_a$8158 "))) ") (_a$8159 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "catch-body")))) (_a$8160 "))) ") (_a$8161 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body")))) (_a$8162 ")")) (jolt-invoke _a$8151 _a$8152 _a$8153 _a$8154 _a$8155 _a$8156 _a$8157 _a$8158 _a$8159 _a$8160 _a$8161 _a$8162)))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "body"))))))) (let* ((temp__16__auto (jolt-get node (keyword #f "finally")))) (if (jolt-truthy? temp__16__auto) (let* ((fin temp__16__auto)) (jolt-invoke (var-deref "clojure.core" "str") "(dynamic-wind (lambda () #f) (lambda () " core ") (lambda () " (jolt-invoke (var-deref "jolt.backend-scheme" "emit") fin) "))")) core))))))) emit-try) (let* ((_o$8163 (keyword #f "private")) (_o$8164 #t)) (jolt-hash-map _o$8163 _o$8164)))) + (def-var-with-meta! "jolt.passes.fold" "foldable" (let* ((_o$6729 "+") (_o$6730 jolt-add) (_o$6731 "-") (_o$6732 jolt-sub) (_o$6733 "*") (_o$6734 jolt-mul) (_o$6735 "/") (_o$6736 jolt-div) (_o$6737 "<") (_o$6738 <) (_o$6739 ">") (_o$6740 >) (_o$6741 "<=") (_o$6742 <=) (_o$6743 ">=") (_o$6744 >=) (_o$6745 "=") (_o$6746 jolt=) (_o$6747 "inc") (_o$6748 jolt-inc) (_o$6749 "dec") (_o$6750 jolt-dec) (_o$6751 "mod") (_o$6752 modulo) (_o$6753 "rem") (_o$6754 remainder) (_o$6755 "quot") (_o$6756 quotient) (_o$6757 "bit-and") (_o$6758 (var-deref "clojure.core" "__bit-and")) (_o$6759 "bit-or") (_o$6760 (var-deref "clojure.core" "__bit-or")) (_o$6761 "bit-xor") (_o$6762 (var-deref "clojure.core" "__bit-xor"))) (jolt-hash-map _o$6729 _o$6730 _o$6731 _o$6732 _o$6733 _o$6734 _o$6735 _o$6736 _o$6737 _o$6738 _o$6739 _o$6740 _o$6741 _o$6742 _o$6743 _o$6744 _o$6745 _o$6746 _o$6747 _o$6748 _o$6749 _o$6750 _o$6751 _o$6752 _o$6753 _o$6754 _o$6755 _o$6756 _o$6757 _o$6758 _o$6759 _o$6760 _o$6761 _o$6762)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "returns-scheme-bool?" (letrec ((returns-scheme-bool? (case-lambda ((node) (let fnrec8165 ((node node)) (returns-scheme-bool? node (jolt-hash-set)))) ((node bools) (let fnrec8166 ((node node) (bools bools)) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "boolean?") (jolt-get node (keyword #f "val"))) and__25__auto))) #t (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((nop (let* ((_a$8167 (var-deref "jolt.backend-scheme" "native-op")) (_a$8168 (jolt-get node (keyword #f "fn"))) (_a$8169 (jolt-count (jolt-get node (keyword #f "args"))))) (jolt-invoke _a$8167 _a$8168 _a$8169)))) (jolt-invoke (var-deref "clojure.core" "boolean") (let* ((and__25__auto nop)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "bool-returning-ops") nop) and__25__auto)))) (if (jolt= (keyword #f "local") (jolt-get node (keyword #f "op"))) (jolt-contains? bools (jolt-get node (keyword #f "name"))) (if (jolt= (keyword #f "if") (jolt-get node (keyword #f "op"))) (let* ((and__25__auto (returns-scheme-bool? (jolt-get node (keyword #f "then")) bools))) (if (jolt-truthy? and__25__auto) (returns-scheme-bool? (jolt-get node (keyword #f "else")) bools) and__25__auto)) (if (jolt= (keyword #f "let") (jolt-get node (keyword #f "op"))) (let* ((bools_PRIME_ (let* ((_a$8171 (lambda (s b) (let fnrec8170 ((s s) (b b)) (if (jolt-truthy? (returns-scheme-bool? (jolt-nth b 1) s)) (jolt-conj s (jolt-nth b 0)) (jolt-invoke (var-deref "clojure.core" "disj") s (jolt-nth b 0)))))) (_a$8172 bools) (_a$8173 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$8171 _a$8172 _a$8173)))) (returns-scheme-bool? (jolt-get node (keyword #f "body")) bools_PRIME_)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))))))) returns-scheme-bool?) (let* ((_o$8174 (keyword #f "private")) (_o$8175 #t)) (jolt-hash-map _o$8174 _o$8175)))) + (def-var! "jolt.passes.fold" "const?" (letrec ((const? (lambda (n) (let fnrec6763 ((n n)) (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))))) const?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "trace-source-reg" (letrec ((trace-source-reg (lambda (node) (let fnrec8176 ((node node)) (let* ((init (jolt-get node (keyword #f "init"))) (pos (jolt-get node (keyword #f "pos")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "trace-frames?")))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get init (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get init (keyword #f "name")))) (if (jolt-truthy? and__25__auto) pos and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_a$8177 (var-deref "clojure.core" "str")) (_a$8178 " (jolt-register-source! ") (_a$8179 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get init (keyword #f "name"))))) (_a$8180 " ") (_a$8181 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8182 " ") (_a$8183 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8184 " ") (_a$8185 (if (jolt-truthy? (jolt-get pos (keyword #f "file"))) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get pos (keyword #f "file"))) "jolt-nil")) (_a$8186 " ") (_a$8187 (let* ((or__26__auto (jolt-get pos (keyword #f "line")))) (if (jolt-truthy? or__26__auto) or__26__auto 0))) (_a$8188 ")")) (jolt-invoke _a$8177 _a$8178 _a$8179 _a$8180 _a$8181 _a$8182 _a$8183 _a$8184 _a$8185 _a$8186 _a$8187 _a$8188)) "")))))) trace-source-reg) (let* ((_o$8189 (keyword #f "private")) (_o$8190 #t)) (jolt-hash-map _o$8189 _o$8190)))) + (def-var! "jolt.passes.fold" "const-num?" (letrec ((const-num? (lambda (n) (let fnrec6764 ((n n)) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "const?") n))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "number?") (jolt-get n (keyword #f "val"))) and__25__auto)))))) const-num?))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "emit*" (letrec ((emit* (lambda (node) (let fnrec8191 ((node node)) (let* ((G__148 (jolt-get node (keyword #f "op")))) (if (jolt= G__148 (keyword #f "const")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-const") (jolt-get node (keyword #f "val"))) (if (jolt= G__148 (keyword #f "local")) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") (jolt-get node (keyword #f "name"))) (if (jolt= G__148 (keyword #f "var")) (let* ((core-proc (let* ((and__25__auto (jolt= "clojure.core" (jolt-get node (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.backend-scheme" "core-value-procs") (jolt-get node (keyword #f "name"))) and__25__auto)))) (if (jolt-truthy? core-proc) core-proc (if (jolt-truthy? (let* ((_a$8192 (var-deref "jolt.backend-scheme" "direct-linkable?")) (_a$8193 (jolt-get node (keyword #f "ns"))) (_a$8194 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$8192 _a$8193 _a$8194))) (let* ((_a$8195 (var-deref "jolt.backend-scheme" "dl-name")) (_a$8196 (jolt-get node (keyword #f "ns"))) (_a$8197 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$8195 _a$8196 _a$8197)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.backend-scheme" "stdlib-var?") node))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "prelude-mode?"))) and__25__auto))) (jolt-throw (let* ((_a$8204 (let* ((_a$8198 (var-deref "clojure.core" "str")) (_a$8199 "emit: unsupported stdlib ref `") (_a$8200 (jolt-get node (keyword #f "ns"))) (_a$8201 "/") (_a$8202 (jolt-get node (keyword #f "name"))) (_a$8203 "` (no core on Chez yet)")) (jolt-invoke _a$8198 _a$8199 _a$8200 _a$8201 _a$8202 _a$8203))) (_a$8205 (jolt-hash-map))) (jolt-ex-info _a$8204 _a$8205))) (if (jolt-truthy? (keyword #f "else")) (let* ((cells (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "cache-cells"))) (nslit (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (nmlit (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name"))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "var-cache?")))) (if (jolt-truthy? and__25__auto) cells and__25__auto))) (let* ((c (jolt-invoke (var-deref "jolt.backend-scheme" "fresh-label") "_vc$"))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") cells jolt-conj c) (jolt-invoke (var-deref "clojure.core" "str") "(var-cell-deref (or " c " (let ((_v (jolt-var " nslit " " nmlit "))) (set! " c " _v) _v)))"))) (jolt-invoke (var-deref "clojure.core" "str") "(var-deref " nslit " " nmlit ")"))) jolt-nil))))) (if (jolt= G__148 (keyword #f "the-var")) (let* ((_a$8206 (var-deref "clojure.core" "str")) (_a$8207 "(jolt-var ") (_a$8208 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8209 " ") (_a$8210 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8211 ")")) (jolt-invoke _a$8206 _a$8207 _a$8208 _a$8209 _a$8210 _a$8211)) (if (jolt= G__148 (keyword #f "set-var")) (let* ((_a$8212 (var-deref "clojure.core" "str")) (_a$8213 "(jolt-var-set ") (_a$8214 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "the-var")))) (_a$8215 " ") (_a$8216 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "val")))) (_a$8217 ")")) (jolt-invoke _a$8212 _a$8213 _a$8214 _a$8215 _a$8216 _a$8217)) (if (jolt= G__148 (keyword #f "set-field")) (let* ((_a$8218 (var-deref "clojure.core" "str")) (_a$8219 "(jolt-set-field! ") (_a$8220 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "obj")))) (_a$8221 " (keyword #f ") (_a$8222 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "field")))) (_a$8223 ") ") (_a$8224 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "val")))) (_a$8225 ")")) (jolt-invoke _a$8218 _a$8219 _a$8220 _a$8221 _a$8222 _a$8223 _a$8224 _a$8225)) (if (jolt= G__148 (keyword #f "defmacro")) (let* ((_a$8226 (var-deref "clojure.core" "str")) (_a$8227 "(begin (def-var! ") (_a$8228 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8229 " ") (_a$8230 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8231 " ") (_a$8232 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "fn")))) (_a$8233 ") (mark-macro! ") (_a$8234 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8235 " ") (_a$8236 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8237 ") jolt-nil)")) (jolt-invoke _a$8226 _a$8227 _a$8228 _a$8229 _a$8230 _a$8231 _a$8232 _a$8233 _a$8234 _a$8235 _a$8236 _a$8237)) (if (jolt= G__148 (keyword #f "host")) (jolt-throw (let* ((_a$8238 (jolt-invoke (var-deref "clojure.core" "str") "emit: unsupported host ref `" (jolt-get node (keyword #f "name")) "`")) (_a$8239 (jolt-hash-map))) (jolt-ex-info _a$8238 _a$8239))) (if (jolt= G__148 (keyword #f "host-static")) (let* ((_a$8240 (var-deref "clojure.core" "str")) (_a$8241 "(host-static-ref ") (_a$8242 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "class")))) (_a$8243 " ") (_a$8244 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "member")))) (_a$8245 ")")) (jolt-invoke _a$8240 _a$8241 _a$8242 _a$8243 _a$8244 _a$8245)) (if (jolt= G__148 (keyword #f "host-new")) (let* ((_a$8246 (var-deref "clojure.core" "str")) (_a$8247 "(host-new ") (_a$8248 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "class")))) (_a$8249 (let* ((args (jolt-map (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "args"))))) (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args))))) (_a$8250 ")")) (jolt-invoke _a$8246 _a$8247 _a$8248 _a$8249 _a$8250)) (if (jolt= G__148 (keyword #f "if")) (let* ((test (jolt-get node (keyword #f "test"))) (t (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "returns-scheme-bool?") test)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") test) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-truthy? " (jolt-invoke (var-deref "jolt.backend-scheme" "emit") test) ")"))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (let* ((_a$8251 (var-deref "clojure.core" "str")) (_a$8252 "(if ") (_a$8253 t) (_a$8254 " ") (_a$8255 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "then")))) (_a$8256 " ") (_a$8257 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "else")))) (_a$8258 ")")) (jolt-invoke _a$8251 _a$8252 _a$8253 _a$8254 _a$8255 _a$8256 _a$8257 _a$8258))) (if (jolt= G__148 (keyword #f "do")) (let* ((_a$8259 (var-deref "clojure.core" "str")) (_a$8260 "(begin ") (_a$8261 (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "jolt.backend-scheme" "*tail?*") #f))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "statements"))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (_a$8262 (if (jolt-empty? (jolt-get node (keyword #f "statements"))) "" " ")) (_a$8263 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "ret")))) (_a$8264 ")")) (jolt-invoke _a$8259 _a$8260 _a$8261 _a$8262 _a$8263 _a$8264)) (if (jolt= G__148 (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-invoke") node) (if (jolt= G__148 (keyword #f "vector")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-vector" (jolt-map (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "items")))) (if (jolt= G__148 (keyword #f "set")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-hash-set" (jolt-map (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "items")))) (if (jolt= G__148 (keyword #f "map")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ordered") "jolt-hash-map" (let* ((_a$8268 (var-deref "clojure.core" "mapcat")) (_a$8269 (lambda (p) (let fnrec8265 ((p p)) (let* ((_o$8266 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth p 0))) (_o$8267 (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-nth p 1)))) (jolt-vector _o$8266 _o$8267))))) (_a$8270 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$8268 _a$8269 _a$8270))) (if (jolt= G__148 (keyword #f "quote")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-quoted") (jolt-get node (keyword #f "form"))) (if (jolt= G__148 (keyword #f "throw")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-throw " (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "expr"))) ")") (if (jolt= G__148 (keyword #f "coerce")) (let* ((e (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "expr"))))) (if (jolt= (keyword #f "double") (jolt-get node (keyword #f "kind"))) (jolt-invoke (var-deref "clojure.core" "str") "(exact->inexact " e ")") (if (jolt= (keyword #f "long") (jolt-get node (keyword #f "kind"))) (jolt-invoke (var-deref "clojure.core" "str") "(jolt->fx " e ")") (if (jolt-truthy? (keyword #f "else")) e jolt-nil)))) (if (jolt= G__148 (keyword #f "try")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-try") node) (if (jolt= G__148 (keyword #f "regex")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-regex " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__148 (keyword #f "inst")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-inst-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__148 (keyword #f "uuid")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-uuid-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__148 (keyword #f "bigdec")) (jolt-invoke (var-deref "clojure.core" "str") "(jolt-bigdec-from-string " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "source"))) ")") (if (jolt= G__148 (keyword #f "the-ns")) (jolt-invoke (var-deref "clojure.core" "str") "(intern-ns! " (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name"))) ")") (if (jolt= G__148 (keyword #f "host-call")) (let* ((m (jolt-get node (keyword #f "method"))) (target (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "target")))) (args (jolt-map (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "args"))))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "supported-host-methods") m)) (let* ((_a$8271 (var-deref "clojure.core" "str")) (_a$8272 "(jolt-host-call ") (_a$8273 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") m)) (_a$8274 " ") (_a$8275 target) (_a$8276 (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args)))) (_a$8277 ")")) (jolt-invoke _a$8271 _a$8272 _a$8273 _a$8274 _a$8275 _a$8276 _a$8277)) (let* ((_a$8278 (var-deref "clojure.core" "str")) (_a$8279 "(record-method-dispatch ") (_a$8280 target) (_a$8281 " ") (_a$8282 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") m)) (_a$8283 " (jolt-vector") (_a$8284 (if (jolt-empty? args) "" (jolt-invoke (var-deref "clojure.core" "str") " " (jolt-invoke (var-deref "clojure.string" "join") " " args)))) (_a$8285 "))")) (jolt-invoke _a$8278 _a$8279 _a$8280 _a$8281 _a$8282 _a$8283 _a$8284 _a$8285)))) (if (jolt= G__148 (keyword #f "let")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-let") node) (if (jolt= G__148 (keyword #f "loop")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-loop") node) (if (jolt= G__148 (keyword #f "recur")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-recur") node) (if (jolt= G__148 (keyword #f "ffi-fn")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ffi-fn") node) (if (jolt= G__148 (keyword #f "ffi-callable")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-ffi-callable") node) (if (jolt= G__148 (keyword #f "fn")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-fn") node) (if (jolt= G__148 (keyword #f "def")) (let* ((reg (jolt-invoke (var-deref "jolt.backend-scheme" "trace-source-reg") node)) (d (if (jolt-truthy? (jolt-get node (keyword #f "no-init"))) (let* ((_a$8286 (var-deref "clojure.core" "str")) (_a$8287 "(declare-var! ") (_a$8288 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8289 " ") (_a$8290 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8291 ")")) (jolt-invoke _a$8286 _a$8287 _a$8288 _a$8289 _a$8290 _a$8291)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "jmeta-nonempty?") (jolt-get node (keyword #f "meta")))) (let* ((_a$8293 (var-deref "clojure.core" "str")) (_a$8294 "(def-var-with-meta! ") (_a$8295 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8296 " ") (_a$8297 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8298 " ") (_a$8299 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-with-cells") (lambda () (let fnrec8292 () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "init"))))))) (_a$8300 " ") (_a$8301 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-def-meta") node)) (_a$8302 ")")) (jolt-invoke _a$8293 _a$8294 _a$8295 _a$8296 _a$8297 _a$8298 _a$8299 _a$8300 _a$8301 _a$8302)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$8304 (var-deref "clojure.core" "str")) (_a$8305 "(def-var! ") (_a$8306 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "ns")))) (_a$8307 " ") (_a$8308 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get node (keyword #f "name")))) (_a$8309 " ") (_a$8310 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-with-cells") (lambda () (let fnrec8303 () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "init"))))))) (_a$8311 ")")) (jolt-invoke _a$8304 _a$8305 _a$8306 _a$8307 _a$8308 _a$8309 _a$8310 _a$8311)) jolt-nil))))) (if (jolt= reg "") d (jolt-invoke (var-deref "clojure.core" "str") "(begin " d reg ")"))) (jolt-throw (let* ((_a$8312 (jolt-invoke (var-deref "clojure.core" "str") "emit: op not yet ported / unhandled: " (jolt-invoke (var-deref "clojure.core" "pr-str") (jolt-get node (keyword #f "op"))))) (_a$8313 (jolt-hash-map))) (jolt-ex-info _a$8312 _a$8313))))))))))))))))))))))))))))))))))))))))) emit*))) + (def-var! "jolt.passes.fold" "fold-fn" (letrec ((fold-fn (lambda (fnode) (let fnrec6765 ((fnode fnode)) (let* ((op (jolt-get fnode (keyword #f "op")))) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt= op (keyword #f "var")))) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "host"))))) (jolt-get (var-deref "jolt.passes.fold" "foldable") (jolt-get fnode (keyword #f "name"))) jolt-nil)))))) fold-fn))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "dl-opt-out?" (letrec ((dl-opt-out? (lambda (m) (let fnrec8314 ((m m)) (let* ((or__26__auto (jolt-get m (keyword #f "dynamic")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get m (keyword #f "redef")))))))) dl-opt-out?) (let* ((_o$8315 (keyword #f "private")) (_o$8316 #t)) (jolt-hash-map _o$8315 _o$8316)))) + (def-var! "jolt.passes.fold" "const-fold" (letrec ((const-fold (lambda (node) (let fnrec6766 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (let* ((n (jolt-invoke (var-deref "jolt.ir" "map-ir-children") const-fold node)) (ff (jolt-invoke (var-deref "jolt.passes.fold" "fold-fn") (jolt-get n (keyword #f "fn")))) (args (jolt-get n (keyword #f "args"))) (folded (if (jolt-truthy? (let* ((and__25__auto ff)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-pos? (jolt-count args)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.fold" "const-num?") args) and__25__auto)) and__25__auto))) (guard (e (else jolt-nil)) (let* ((_o$6768 (keyword #f "op")) (_o$6769 (keyword #f "const")) (_o$6770 (keyword #f "val")) (_o$6771 (jolt-apply ff (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec6767 ((a a)) (jolt-get a (keyword #f "val")))) args)))) (jolt-hash-map _o$6768 _o$6769 _o$6770 _o$6771))) jolt-nil))) (let* ((or__26__auto folded)) (if (jolt-truthy? or__26__auto) or__26__auto n))) (if (jolt= op (keyword #f "if")) (let* ((t (jolt-invoke const-fold (jolt-get node (keyword #f "test"))))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.fold" "const?") t)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-get t (keyword #f "val"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= #f (jolt-get t (keyword #f "val")))))) (jolt-invoke const-fold (jolt-get node (keyword #f "else"))) (jolt-invoke const-fold (jolt-get node (keyword #f "then")))) (let* ((_a$6772 node) (_a$6773 (keyword #f "test")) (_a$6774 t) (_a$6775 (keyword #f "then")) (_a$6776 (jolt-invoke const-fold (jolt-get node (keyword #f "then")))) (_a$6777 (keyword #f "else")) (_a$6778 (jolt-invoke const-fold (jolt-get node (keyword #f "else"))))) (jolt-assoc _a$6772 _a$6773 _a$6774 _a$6775 _a$6776 _a$6777 _a$6778)))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") const-fold node) jolt-nil)))))))) const-fold))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.backend-scheme" "emit-def-cached" (letrec ((emit-def-cached (lambda (node) (let fnrec8317 ((node node)) (let* ((ns (jolt-get node (keyword #f "ns"))) (nm (jolt-get node (keyword #f "name"))) (dl? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link?")))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.backend-scheme" "dl-opt-out?") (jolt-get node (keyword #f "meta")))) and__25__auto))) (b (jolt-invoke (var-deref "jolt.backend-scheme" "dl-name") ns nm)) (fn? (jolt= (keyword #f "fn") (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "op")))) (pos (jolt-get node (keyword #f "pos"))) (frame-name (if (jolt-truthy? fn?) (let* ((temp__16__auto (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "name")))) (if (jolt-truthy? temp__16__auto) (let* ((fnm temp__16__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "munge-name") fnm)) b)) jolt-nil)) (reg (if (jolt-truthy? (let* ((and__25__auto dl?)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto fn?)) (if (jolt-truthy? and__25__auto) pos and__25__auto)) and__25__auto))) (let* ((_a$8318 (var-deref "clojure.core" "str")) (_a$8319 " (jolt-register-source! ") (_a$8320 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") frame-name)) (_a$8321 " ") (_a$8322 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$8323 " ") (_a$8324 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$8325 " ") (_a$8326 (if (jolt-truthy? (jolt-get pos (keyword #f "file"))) (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") (jolt-get pos (keyword #f "file"))) "jolt-nil")) (_a$8327 " ") (_a$8328 (let* ((or__26__auto (jolt-get pos (keyword #f "line")))) (if (jolt-truthy? or__26__auto) or__26__auto 0))) (_a$8329 ")")) (jolt-invoke _a$8318 _a$8319 _a$8320 _a$8321 _a$8322 _a$8323 _a$8324 _a$8325 _a$8326 _a$8327 _a$8328 _a$8329)) jolt-nil)) (_ (if (jolt-truthy? dl?) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "direct-link-defined") jolt-conj (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm)) (if (jolt-truthy? fn?) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.backend-scheme" "direct-link-fns") jolt-conj (jolt-invoke (var-deref "jolt.backend-scheme" "dl-fqn") ns nm)) jolt-nil)) jolt-nil)) (init (jolt-invoke (var-deref "jolt.backend-scheme" "emit-with-cells") (lambda () (let fnrec8330 () (jolt-invoke (var-deref "jolt.backend-scheme" "emit") (jolt-get node (keyword #f "init")))))))) (if (jolt-truthy? dl?) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "jmeta-nonempty?") (jolt-get node (keyword #f "meta")))) (let* ((_a$8331 (var-deref "clojure.core" "str")) (_a$8332 "(begin (define ") (_a$8333 b) (_a$8334 " ") (_a$8335 init) (_a$8336 ") (def-var-with-meta! ") (_a$8337 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$8338 " ") (_a$8339 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$8340 " ") (_a$8341 b) (_a$8342 " ") (_a$8343 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-def-meta") node)) (_a$8344 ")") (_a$8345 (let* ((or__26__auto reg)) (if (jolt-truthy? or__26__auto) or__26__auto ""))) (_a$8346 ")")) (jolt-invoke _a$8331 _a$8332 _a$8333 _a$8334 _a$8335 _a$8336 _a$8337 _a$8338 _a$8339 _a$8340 _a$8341 _a$8342 _a$8343 _a$8344 _a$8345 _a$8346)) (let* ((_a$8347 (var-deref "clojure.core" "str")) (_a$8348 "(begin (define ") (_a$8349 b) (_a$8350 " ") (_a$8351 init) (_a$8352 ") (def-var! ") (_a$8353 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$8354 " ") (_a$8355 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$8356 " ") (_a$8357 b) (_a$8358 ")") (_a$8359 (let* ((or__26__auto reg)) (if (jolt-truthy? or__26__auto) or__26__auto ""))) (_a$8360 ")")) (jolt-invoke _a$8347 _a$8348 _a$8349 _a$8350 _a$8351 _a$8352 _a$8353 _a$8354 _a$8355 _a$8356 _a$8357 _a$8358 _a$8359 _a$8360))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.backend-scheme" "jmeta-nonempty?") (jolt-get node (keyword #f "meta")))) (let* ((_a$8361 (var-deref "clojure.core" "str")) (_a$8362 "(def-var-with-meta! ") (_a$8363 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$8364 " ") (_a$8365 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$8366 " ") (_a$8367 init) (_a$8368 " ") (_a$8369 (jolt-invoke (var-deref "jolt.backend-scheme" "emit-def-meta") node)) (_a$8370 ")")) (jolt-invoke _a$8361 _a$8362 _a$8363 _a$8364 _a$8365 _a$8366 _a$8367 _a$8368 _a$8369 _a$8370)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$8371 (var-deref "clojure.core" "str")) (_a$8372 "(def-var! ") (_a$8373 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") ns)) (_a$8374 " ") (_a$8375 (jolt-invoke (var-deref "jolt.backend-scheme" "chez-str-lit") nm)) (_a$8376 " ") (_a$8377 init) (_a$8378 ")")) (jolt-invoke _a$8371 _a$8372 _a$8373 _a$8374 _a$8375 _a$8376 _a$8377 _a$8378)) jolt-nil)))))))) emit-def-cached) (let* ((_o$8379 (keyword #f "private")) (_o$8380 #t)) (jolt-hash-map _o$8379 _o$8380)))) + (def-var! "jolt.passes.fold" "scalar-const?" (letrec ((scalar-const? (lambda (n) (let fnrec6779 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "string?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "boolean?") v)))))))) and__25__auto)))))) scalar-const?))) (guard (e (#t #f)) - (def-var! "jolt.backend-scheme" "emit-top-form" (letrec ((emit-top-form (lambda (node) (let fnrec8381 ((node node)) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.backend-scheme" "direct-link?"))) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") node) (if (jolt= (keyword #f "do") (jolt-get node (keyword #f "op"))) (let* ((_a$8382 (var-deref "clojure.core" "str")) (_a$8383 "(begin ") (_a$8384 (jolt-invoke (var-deref "clojure.string" "join") " " (jolt-map emit-top-form (jolt-get node (keyword #f "statements"))))) (_a$8385 (if (jolt-empty? (jolt-get node (keyword #f "statements"))) "" " ")) (_a$8386 (emit-top-form (jolt-get node (keyword #f "ret")))) (_a$8387 ")")) (jolt-invoke _a$8382 _a$8383 _a$8384 _a$8385 _a$8386 _a$8387)) (if (let* ((and__25__auto (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-get node (keyword #f "no-init"))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "jolt.backend-scheme" "dl-opt-out?") (jolt-get node (keyword #f "meta")))) and__25__auto)) and__25__auto)) (jolt-invoke (var-deref "jolt.backend-scheme" "emit-def-cached") node) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.backend-scheme" "emit") node) jolt-nil)))))))) emit-top-form))) + (def-var! "jolt.passes.fold" "kw-callee?" (letrec ((kw-callee? (lambda (fnode) (let fnrec6780 ((fnode fnode)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get fnode (keyword #f "val"))) and__25__auto)))))) kw-callee?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "foldable" (let* ((_o$8388 "+") (_o$8389 jolt-add) (_o$8390 "-") (_o$8391 jolt-sub) (_o$8392 "*") (_o$8393 jolt-mul) (_o$8394 "/") (_o$8395 jolt-div) (_o$8396 "<") (_o$8397 jolt-lt) (_o$8398 ">") (_o$8399 jolt-gt) (_o$8400 "<=") (_o$8401 jolt-le) (_o$8402 ">=") (_o$8403 jolt-ge) (_o$8404 "=") (_o$8405 jolt=) (_o$8406 "inc") (_o$8407 jolt-inc) (_o$8408 "dec") (_o$8409 jolt-dec) (_o$8410 "mod") (_o$8411 jolt-mod) (_o$8412 "rem") (_o$8413 jolt-rem) (_o$8414 "quot") (_o$8415 jolt-quot) (_o$8416 "bit-and") (_o$8417 (var-deref "clojure.core" "__bit-and")) (_o$8418 "bit-or") (_o$8419 (var-deref "clojure.core" "__bit-or")) (_o$8420 "bit-xor") (_o$8421 (var-deref "clojure.core" "__bit-xor"))) (jolt-hash-map _o$8388 _o$8389 _o$8390 _o$8391 _o$8392 _o$8393 _o$8394 _o$8395 _o$8396 _o$8397 _o$8398 _o$8399 _o$8400 _o$8401 _o$8402 _o$8403 _o$8404 _o$8405 _o$8406 _o$8407 _o$8408 _o$8409 _o$8410 _o$8411 _o$8412 _o$8413 _o$8414 _o$8415 _o$8416 _o$8417 _o$8418 _o$8419 _o$8420 _o$8421)) (let* ((_o$8422 (keyword #f "private")) (_o$8423 #t)) (jolt-hash-map _o$8422 _o$8423)))) + (def-var! "jolt.passes.fold" "get-callee?" (letrec ((get-callee? (lambda (fnode) (let fnrec6781 ((fnode fnode)) (let* ((or__26__auto (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt= "get" (jolt-get fnode (keyword #f "name"))) and__25__auto)) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt= (keyword #f "host") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= "get" (jolt-get fnode (keyword #f "name"))) and__25__auto)))))))) get-callee?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "const?" (letrec ((const? (lambda (n) (let fnrec8424 ((n n)) (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))))) const?) (let* ((_o$8425 (keyword #f "private")) (_o$8426 #t)) (jolt-hash-map _o$8425 _o$8426)))) + (def-var! "jolt.passes.numeric" "int-lit?" (letrec ((int-lit? (lambda (n) (let fnrec5548 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "integer?") v) and__25__auto))) and__25__auto)))))) int-lit?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "const-num?" (letrec ((const-num? (lambda (n) (let fnrec8427 ((n n)) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "const?") n))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "number?") (jolt-get n (keyword #f "val"))) and__25__auto)))))) const-num?) (let* ((_o$8428 (keyword #f "private")) (_o$8429 #t)) (jolt-hash-map _o$8428 _o$8429)))) + (def-var! "jolt.passes.numeric" "float-lit?" (letrec ((float-lit? (lambda (n) (let fnrec5549 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "float?") v) and__25__auto))) and__25__auto)))))) float-lit?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "fold-fn" (letrec ((fold-fn (lambda (fnode) (let fnrec8430 ((fnode fnode)) (let* ((op (jolt-get fnode (keyword #f "op")))) (if (let* ((or__26__auto (let* ((and__25__auto (jolt= op (keyword #f "var")))) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "host")))) (jolt-get (var-deref "jolt.passes.fold" "foldable") (jolt-get fnode (keyword #f "name"))) jolt-nil)))))) fold-fn) (let* ((_o$8431 (keyword #f "private")) (_o$8432 #t)) (jolt-hash-map _o$8431 _o$8432)))) + (def-var! "jolt.passes.numeric" "dbl-spec" (letrec ((dbl-spec (lambda (nm n) (let fnrec5550 ((nm nm) (n n)) (if (jolt-truthy? (let* ((and__25__auto (>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5551 "+") (_o$5552 "-") (_o$5553 "*") (_o$5554 "/") (_o$5555 "min") (_o$5556 "max")) (jolt-hash-set _o$5551 _o$5552 _o$5553 _o$5554 _o$5555 _o$5556)) nm) and__25__auto))) (keyword #f "double") (if (jolt-truthy? (let* ((and__25__auto (jolt= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5557 "inc") (_o$5558 "dec")) (jolt-hash-set _o$5557 _o$5558)) nm) and__25__auto))) (keyword #f "double") (if (jolt-truthy? (let* ((and__25__auto (>= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5559 "<") (_o$5560 ">") (_o$5561 "<=") (_o$5562 ">=") (_o$5563 "=") (_o$5564 "==")) (jolt-hash-set _o$5559 _o$5560 _o$5561 _o$5562 _o$5563 _o$5564)) nm) and__25__auto))) (keyword #f "bool") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))))) dbl-spec))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "const-fold" (letrec ((const-fold (lambda (node) (let fnrec8433 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (let* ((n (jolt-invoke (var-deref "jolt.ir" "map-ir-children") const-fold node)) (ff (jolt-invoke (var-deref "jolt.passes.fold" "fold-fn") (jolt-get n (keyword #f "fn")))) (args (jolt-get n (keyword #f "args"))) (folded (if (jolt-truthy? (let* ((and__25__auto ff)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-pos? (jolt-count args)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.fold" "const-num?") args) and__25__auto)) and__25__auto))) (guard (_r$catch-raw1629 (else (let ((_r$catch1628 (jolt-unwrap-throw _r$catch-raw1629))) (let* ((e _r$catch1628)) jolt-nil)))) (let* ((_o$8435 (keyword #f "op")) (_o$8436 (keyword #f "const")) (_o$8437 (keyword #f "val")) (_o$8438 (jolt-apply ff (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec8434 ((a a)) (jolt-get a (keyword #f "val")))) args)))) (jolt-hash-map _o$8435 _o$8436 _o$8437 _o$8438))) jolt-nil))) (let* ((or__26__auto folded)) (if (jolt-truthy? or__26__auto) or__26__auto n))) (if (jolt= op (keyword #f "if")) (let* ((t (const-fold (jolt-get node (keyword #f "test"))))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.fold" "const?") t)) (if (let* ((or__26__auto (jolt-nil? (jolt-get t (keyword #f "val"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= #f (jolt-get t (keyword #f "val"))))) (const-fold (jolt-get node (keyword #f "else"))) (const-fold (jolt-get node (keyword #f "then")))) (let* ((_a$8439 node) (_a$8440 (keyword #f "test")) (_a$8441 t) (_a$8442 (keyword #f "then")) (_a$8443 (const-fold (jolt-get node (keyword #f "then")))) (_a$8444 (keyword #f "else")) (_a$8445 (const-fold (jolt-get node (keyword #f "else"))))) (jolt-assoc _a$8439 _a$8440 _a$8441 _a$8442 _a$8443 _a$8444 _a$8445)))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") const-fold node) jolt-nil)))))))) const-fold) (let* ((_o$8446 (keyword #f "doc")) (_o$8447 "Bottom-up constant folding: a call of a foldable numeric fn whose args are\n all constant numbers becomes a constant; an if with a constant test becomes\n the taken branch.")) (jolt-hash-map _o$8446 _o$8447)))) + (def-var! "jolt.passes.numeric" "lng-spec" (letrec ((lng-spec (lambda (nm n) (let fnrec5565 ((nm nm) (n n)) (if (jolt-truthy? (let* ((and__25__auto (>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5566 "+") (_o$5567 "-") (_o$5568 "*") (_o$5569 "min") (_o$5570 "max") (_o$5571 "unchecked-add") (_o$5572 "unchecked-subtract") (_o$5573 "unchecked-multiply")) (jolt-hash-set _o$5566 _o$5567 _o$5568 _o$5569 _o$5570 _o$5571 _o$5572 _o$5573)) nm) and__25__auto))) (keyword #f "long") (if (jolt-truthy? (let* ((and__25__auto (jolt= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5574 "inc") (_o$5575 "dec") (_o$5576 "unchecked-inc") (_o$5577 "unchecked-dec")) (jolt-hash-set _o$5574 _o$5575 _o$5576 _o$5577)) nm) and__25__auto))) (keyword #f "long") (if (jolt-truthy? (let* ((and__25__auto (jolt= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5578 "quot") (_o$5579 "rem") (_o$5580 "mod")) (jolt-hash-set _o$5578 _o$5579 _o$5580)) nm) and__25__auto))) (keyword #f "long") (if (jolt-truthy? (let* ((and__25__auto (>= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$5581 "<") (_o$5582 ">") (_o$5583 "<=") (_o$5584 ">=") (_o$5585 "=") (_o$5586 "==")) (jolt-hash-set _o$5581 _o$5582 _o$5583 _o$5584 _o$5585 _o$5586)) nm) and__25__auto))) (keyword #f "bool") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))))) lng-spec))) (guard (e (#t #f)) - (def-var! "jolt.passes.fold" "scalar-const?" (letrec ((scalar-const? (lambda (n) (let fnrec8448 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "string?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "boolean?") v)))))))) and__25__auto)))))) scalar-const?))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "kw-callee?" (letrec ((kw-callee? (lambda (fnode) (let fnrec8449 ((fnode fnode)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get fnode (keyword #f "val"))) and__25__auto)))))) kw-callee?) (let* ((_o$8450 (keyword #f "doc")) (_o$8451 "True if fnode is a constant keyword used as a function head \x2014; the (:k m) form.")) (jolt-hash-map _o$8450 _o$8451)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.fold" "get-callee?" (letrec ((get-callee? (lambda (fnode) (let fnrec8452 ((fnode fnode)) (let* ((or__26__auto (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt= "get" (jolt-get fnode (keyword #f "name"))) and__25__auto)) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt= (keyword #f "host") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= "get" (jolt-get fnode (keyword #f "name"))) and__25__auto)))))))) get-callee?) (let* ((_o$8453 (keyword #f "doc")) (_o$8454 "True if fnode is the clojure.core/get (or host get) callee \x2014; the (get m k) form.")) (jolt-hash-map _o$8453 _o$8454)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "int-lit?" (letrec ((int-lit? (lambda (n) (let fnrec6706 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "integer?") v) and__25__auto))) and__25__auto)))))) int-lit?) (let* ((_o$6707 (keyword #f "private")) (_o$6708 #t)) (jolt-hash-map _o$6707 _o$6708)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "float-lit?" (letrec ((float-lit? (lambda (n) (let fnrec6709 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "float?") v) and__25__auto))) and__25__auto)))))) float-lit?) (let* ((_o$6710 (keyword #f "private")) (_o$6711 #t)) (jolt-hash-map _o$6710 _o$6711)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "dbl-spec" (letrec ((dbl-spec (lambda (nm n) (let fnrec6712 ((nm nm) (n n)) (if (let* ((and__25__auto (jolt-n>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6713 "+") (_o$6714 "-") (_o$6715 "*") (_o$6716 "/") (_o$6717 "min") (_o$6718 "max")) (jolt-hash-set _o$6713 _o$6714 _o$6715 _o$6716 _o$6717 _o$6718)) nm) and__25__auto)) (keyword #f "double") (if (let* ((and__25__auto (jolt= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6719 "inc") (_o$6720 "dec")) (jolt-hash-set _o$6719 _o$6720)) nm) and__25__auto)) (keyword #f "double") (if (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6721 "<") (_o$6722 ">") (_o$6723 "<=") (_o$6724 ">=") (_o$6725 "=") (_o$6726 "==")) (jolt-hash-set _o$6721 _o$6722 _o$6723 _o$6724 _o$6725 _o$6726)) nm) and__25__auto)) (keyword #f "bool") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))))) dbl-spec) (let* ((_o$6727 (keyword #f "private")) (_o$6728 #t)) (jolt-hash-map _o$6727 _o$6728)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "lng-spec" (letrec ((lng-spec (lambda (nm n) (let fnrec6729 ((nm nm) (n n)) (if (let* ((and__25__auto (jolt-n>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6730 "+") (_o$6731 "-") (_o$6732 "*") (_o$6733 "min") (_o$6734 "max") (_o$6735 "unchecked-add") (_o$6736 "unchecked-subtract") (_o$6737 "unchecked-multiply")) (jolt-hash-set _o$6730 _o$6731 _o$6732 _o$6733 _o$6734 _o$6735 _o$6736 _o$6737)) nm) and__25__auto)) (keyword #f "long") (if (let* ((and__25__auto (jolt= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6738 "inc") (_o$6739 "dec") (_o$6740 "unchecked-inc") (_o$6741 "unchecked-dec")) (jolt-hash-set _o$6738 _o$6739 _o$6740 _o$6741)) nm) and__25__auto)) (keyword #f "long") (if (let* ((and__25__auto (jolt= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6742 "quot") (_o$6743 "rem") (_o$6744 "mod")) (jolt-hash-set _o$6742 _o$6743 _o$6744)) nm) and__25__auto)) (keyword #f "long") (if (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6745 "<") (_o$6746 ">") (_o$6747 "<=") (_o$6748 ">=") (_o$6749 "=") (_o$6750 "==")) (jolt-hash-set _o$6745 _o$6746 _o$6747 _o$6748 _o$6749 _o$6750)) nm) and__25__auto)) (keyword #f "bool") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))))) lng-spec) (let* ((_o$6751 (keyword #f "private")) (_o$6752 #t)) (jolt-hash-map _o$6751 _o$6752)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "bd-spec" (letrec ((bd-spec (lambda (nm n) (let fnrec6753 ((nm nm) (n n)) (if (let* ((and__25__auto (jolt-n>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6754 "+") (_o$6755 "-") (_o$6756 "*") (_o$6757 "/") (_o$6758 "min") (_o$6759 "max")) (jolt-hash-set _o$6754 _o$6755 _o$6756 _o$6757 _o$6758 _o$6759)) nm) and__25__auto)) (keyword #f "bigdec") (if (let* ((and__25__auto (jolt= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6760 "quot") (_o$6761 "rem")) (jolt-hash-set _o$6760 _o$6761)) nm) and__25__auto)) (keyword #f "bigdec") (if (let* ((and__25__auto (jolt= n 1))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6762 "zero?") (_o$6763 "pos?") (_o$6764 "neg?")) (jolt-hash-set _o$6762 _o$6763 _o$6764)) nm) and__25__auto)) (keyword #f "bool") (if (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (jolt-contains? (let* ((_o$6765 "<") (_o$6766 ">") (_o$6767 "<=") (_o$6768 ">=")) (jolt-hash-set _o$6765 _o$6766 _o$6767 _o$6768)) nm) and__25__auto)) (keyword #f "bool") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))))) bd-spec) (let* ((_o$6769 (keyword #f "private")) (_o$6770 #t)) (jolt-hash-map _o$6769 _o$6770)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "propagate" (letrec ((propagate (lambda (spec) (let fnrec6771 ((spec spec)) (if (jolt= spec (keyword #f "bool")) jolt-nil spec))))) propagate) (let* ((_o$6772 (keyword #f "private")) (_o$6773 #t)) (jolt-hash-map _o$6772 _o$6773)))) + (def-var! "jolt.passes.numeric" "propagate" (letrec ((propagate (lambda (spec) (let fnrec5587 ((spec spec)) (if (jolt= spec (keyword #f "bool")) jolt-nil spec))))) propagate))) (guard (e (#t #f)) (declare-var! "jolt.passes.numeric" "an")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "recur-kinds" (letrec ((recur-kinds (lambda (node tenv) (let fnrec6774 ((node node) (tenv tenv)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "recur")) (jolt-vector (let* ((_a$6776 (var-deref "clojure.core" "mapv")) (_a$6777 (lambda (a) (let fnrec6775 ((a a)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") a tenv) 0)))) (_a$6778 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$6776 _a$6777 _a$6778))) (if (jolt= op (keyword #f "let")) (let* ((_a$6786 (jolt-get node (keyword #f "body"))) (_a$6787 (let* ((_a$6783 (lambda (te b) (let fnrec6779 ((te te) (b b)) (let* ((_a$6780 te) (_a$6781 (jolt-nth b 0)) (_a$6782 (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") (jolt-nth b 1) te) 0))) (jolt-assoc _a$6780 _a$6781 _a$6782))))) (_a$6784 tenv) (_a$6785 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$6783 _a$6784 _a$6785)))) (recur-kinds _a$6786 _a$6787)) (if (jolt= op (keyword #f "if")) (let* ((_a$6788 (recur-kinds (jolt-get node (keyword #f "then")) tenv)) (_a$6789 (recur-kinds (jolt-get node (keyword #f "else")) tenv))) (jolt-concat _a$6788 _a$6789)) (if (jolt= op (keyword #f "do")) (recur-kinds (jolt-get node (keyword #f "ret")) tenv) (if (jolt-truthy? (keyword #f "else")) (jolt-vector) jolt-nil)))))))))) recur-kinds) (let* ((_o$6790 (keyword #f "private")) (_o$6791 #t)) (jolt-hash-map _o$6790 _o$6791)))) + (def-var! "jolt.passes.numeric" "recur-kinds" (letrec ((recur-kinds (lambda (node tenv) (let fnrec5588 ((node node) (tenv tenv)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "recur")) (jolt-vector (let* ((_a$5590 (var-deref "clojure.core" "mapv")) (_a$5591 (lambda (a) (let fnrec5589 ((a a)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") a tenv) 0)))) (_a$5592 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$5590 _a$5591 _a$5592))) (if (jolt= op (keyword #f "let")) (let* ((_a$5600 recur-kinds) (_a$5601 (jolt-get node (keyword #f "body"))) (_a$5602 (let* ((_a$5597 (lambda (te b) (let fnrec5593 ((te te) (b b)) (let* ((_a$5594 te) (_a$5595 (jolt-nth b 0)) (_a$5596 (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") (jolt-nth b 1) te) 0))) (jolt-assoc _a$5594 _a$5595 _a$5596))))) (_a$5598 tenv) (_a$5599 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$5597 _a$5598 _a$5599)))) (jolt-invoke _a$5600 _a$5601 _a$5602)) (if (jolt= op (keyword #f "if")) (let* ((_a$5603 (jolt-invoke recur-kinds (jolt-get node (keyword #f "then")) tenv)) (_a$5604 (jolt-invoke recur-kinds (jolt-get node (keyword #f "else")) tenv))) (jolt-concat _a$5603 _a$5604)) (if (jolt= op (keyword #f "do")) (jolt-invoke recur-kinds (jolt-get node (keyword #f "ret")) tenv) (if (jolt-truthy? (keyword #f "else")) (jolt-vector) jolt-nil)))))))))) recur-kinds))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "recur-arg-lists" (letrec ((recur-arg-lists (lambda (node) (let fnrec6792 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "recur")) (jolt-vector (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "let")) (recur-arg-lists (jolt-get node (keyword #f "body"))) (if (jolt= op (keyword #f "if")) (let* ((_a$6793 (recur-arg-lists (jolt-get node (keyword #f "then")))) (_a$6794 (recur-arg-lists (jolt-get node (keyword #f "else"))))) (jolt-concat _a$6793 _a$6794)) (if (jolt= op (keyword #f "do")) (recur-arg-lists (jolt-get node (keyword #f "ret"))) (if (jolt-truthy? (keyword #f "else")) (jolt-vector) jolt-nil)))))))))) recur-arg-lists) (let* ((_o$6795 (keyword #f "private")) (_o$6796 #t)) (jolt-hash-map _o$6795 _o$6796)))) + (def-var! "jolt.passes.numeric" "recur-arg-lists" (letrec ((recur-arg-lists (lambda (node) (let fnrec5605 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "recur")) (jolt-vector (jolt-get node (keyword #f "args"))) (if (jolt= op (keyword #f "let")) (jolt-invoke recur-arg-lists (jolt-get node (keyword #f "body"))) (if (jolt= op (keyword #f "if")) (let* ((_a$5606 (jolt-invoke recur-arg-lists (jolt-get node (keyword #f "then")))) (_a$5607 (jolt-invoke recur-arg-lists (jolt-get node (keyword #f "else"))))) (jolt-concat _a$5606 _a$5607)) (if (jolt= op (keyword #f "do")) (jolt-invoke recur-arg-lists (jolt-get node (keyword #f "ret"))) (if (jolt-truthy? (keyword #f "else")) (jolt-vector) jolt-nil)))))))))) recur-arg-lists))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "counter-step?" (letrec ((counter-step? (lambda (arg vname) (let fnrec6797 ((arg arg) (vname vname)) (if (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get arg (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= vname (jolt-get arg (keyword #f "name"))) and__25__auto)) #t (if (jolt= (keyword #f "invoke") (jolt-get arg (keyword #f "op"))) (let* ((f (jolt-get arg (keyword #f "fn"))) (as (jolt-get arg (keyword #f "args")))) (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get f (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (let* ((nm (jolt-get f (keyword #f "name"))) (v? (lambda (n) (let fnrec6798 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= vname (jolt-get n (keyword #f "name"))) and__25__auto)))))) (if (let* ((and__25__auto (jolt-contains? (let* ((_o$6799 "inc") (_o$6800 "dec") (_o$6801 "unchecked-inc") (_o$6802 "unchecked-dec")) (jolt-hash-set _o$6799 _o$6800 _o$6801 _o$6802)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count as)) and__25__auto)) (jolt-invoke v? (jolt-nth as 0)) (if (let* ((and__25__auto (jolt-contains? (let* ((_o$6803 "+") (_o$6804 "unchecked-add")) (jolt-hash-set _o$6803 _o$6804)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count as)) and__25__auto)) (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 0)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 1)) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 1)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 0)) and__25__auto)))) (if (let* ((and__25__auto (jolt-contains? (let* ((_o$6805 "-") (_o$6806 "unchecked-subtract")) (jolt-hash-set _o$6805 _o$6806)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count as)) and__25__auto)) (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 0)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 1)) and__25__auto)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))) and__25__auto)) and__25__auto))) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))) counter-step?) (let* ((_o$6807 (keyword #f "private")) (_o$6808 #t)) (jolt-hash-map _o$6807 _o$6808)))) + (def-var! "jolt.passes.numeric" "counter-step?" (letrec ((counter-step? (lambda (arg vname) (let fnrec5608 ((arg arg) (vname vname)) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get arg (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= vname (jolt-get arg (keyword #f "name"))) and__25__auto))) #t (if (jolt= (keyword #f "invoke") (jolt-get arg (keyword #f "op"))) (let* ((f (jolt-get arg (keyword #f "fn"))) (as (jolt-get arg (keyword #f "args")))) (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get f (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (let* ((nm (jolt-get f (keyword #f "name"))) (v? (lambda (n) (let fnrec5609 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= vname (jolt-get n (keyword #f "name"))) and__25__auto)))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-contains? (let* ((_o$5610 "inc") (_o$5611 "dec") (_o$5612 "unchecked-inc") (_o$5613 "unchecked-dec")) (jolt-hash-set _o$5610 _o$5611 _o$5612 _o$5613)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count as)) and__25__auto))) (jolt-invoke v? (jolt-nth as 0)) (if (jolt-truthy? (let* ((and__25__auto (jolt-contains? (let* ((_o$5614 "+") (_o$5615 "unchecked-add")) (jolt-hash-set _o$5614 _o$5615)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count as)) and__25__auto))) (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 0)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 1)) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 1)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 0)) and__25__auto)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-contains? (let* ((_o$5616 "-") (_o$5617 "unchecked-subtract")) (jolt-hash-set _o$5616 _o$5617)) nm))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count as)) and__25__auto))) (let* ((and__25__auto (jolt-invoke v? (jolt-nth as 0)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth as 1)) and__25__auto)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))) and__25__auto)) and__25__auto))) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))) counter-step?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "loop-kinds" (letrec ((loop-kinds (lambda (names seed body tenv) (let fnrec6809 ((names names) (seed seed) (body body) (tenv tenv)) (let* ((cur seed) (iter 0)) (let loop6810 ((cur cur) (iter iter)) (if (jolt-n> iter (jolt-count names)) cur (let* ((te (let* ((_a$6815 (lambda (t i) (let fnrec6811 ((t t) (i i)) (let* ((_a$6812 t) (_a$6813 (jolt-nth names i)) (_a$6814 (jolt-nth cur i))) (jolt-assoc _a$6812 _a$6813 _a$6814))))) (_a$6816 tenv) (_a$6817 (jolt-range (jolt-count names)))) (jolt-reduce _a$6815 _a$6816 _a$6817))) (rks (jolt-invoke (var-deref "jolt.passes.numeric" "recur-kinds") body te)) (nxt (let* ((_a$6820 (var-deref "clojure.core" "mapv")) (_a$6821 (lambda (j) (let fnrec6818 ((j j)) (let* ((k (jolt-nth cur j))) (if (jolt-truthy? (let* ((and__25__auto k)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (rk) (let fnrec6819 ((rk rk)) (jolt= k (jolt-nth rk j)))) rks) and__25__auto))) k jolt-nil))))) (_a$6822 (jolt-range (jolt-count names)))) (jolt-invoke _a$6820 _a$6821 _a$6822)))) (if (jolt= nxt cur) cur (loop6810 nxt (jolt-inc iter))))))))))) loop-kinds) (let* ((_o$6823 (keyword #f "private")) (_o$6824 #t)) (jolt-hash-map _o$6823 _o$6824)))) + (def-var! "jolt.passes.numeric" "loop-kinds" (letrec ((loop-kinds (lambda (names seed body tenv) (let fnrec5618 ((names names) (seed seed) (body body) (tenv tenv)) (let* ((cur seed) (iter 0)) (let loop5619 ((cur cur) (iter iter)) (if (> iter (jolt-count names)) cur (let* ((te (let* ((_a$5624 (lambda (t i) (let fnrec5620 ((t t) (i i)) (let* ((_a$5621 t) (_a$5622 (jolt-nth names i)) (_a$5623 (jolt-nth cur i))) (jolt-assoc _a$5621 _a$5622 _a$5623))))) (_a$5625 tenv) (_a$5626 (jolt-range (jolt-count names)))) (jolt-reduce _a$5624 _a$5625 _a$5626))) (rks (jolt-invoke (var-deref "jolt.passes.numeric" "recur-kinds") body te)) (nxt (let* ((_a$5629 (var-deref "clojure.core" "mapv")) (_a$5630 (lambda (j) (let fnrec5627 ((j j)) (let* ((k (jolt-nth cur j))) (if (jolt-truthy? (let* ((and__25__auto k)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (rk) (let fnrec5628 ((rk rk)) (jolt= k (jolt-nth rk j)))) rks) and__25__auto))) k jolt-nil))))) (_a$5631 (jolt-range (jolt-count names)))) (jolt-invoke _a$5629 _a$5630 _a$5631)))) (if (jolt= nxt cur) cur (loop5619 nxt (jolt-inc iter))))))))))) loop-kinds))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "arity-env" (letrec ((arity-env (lambda (tenv a) (let fnrec6825 ((tenv tenv) (a a)) (let* ((nh (let* ((_a$6826 (jolt-hash-map)) (_a$6827 (jolt-get a (keyword #f "nhints")))) (jolt-into _a$6826 _a$6827))) (pe (let* ((_a$6829 (lambda (e p) (let fnrec6828 ((e e) (p p)) (jolt-assoc e p (jolt-get nh p))))) (_a$6830 tenv) (_a$6831 (jolt-get a (keyword #f "params")))) (jolt-reduce _a$6829 _a$6830 _a$6831)))) (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) jolt-nil) pe)))))) arity-env) (let* ((_o$6832 (keyword #f "private")) (_o$6833 #t)) (jolt-hash-map _o$6832 _o$6833)))) + (def-var! "jolt.passes.numeric" "arity-env" (letrec ((arity-env (lambda (tenv a) (let fnrec5632 ((tenv tenv) (a a)) (let* ((nh (let* ((_a$5633 (jolt-hash-map)) (_a$5634 (jolt-get a (keyword #f "nhints")))) (jolt-into _a$5633 _a$5634))) (pe (let* ((_a$5636 (lambda (e p) (let fnrec5635 ((e e) (p p)) (jolt-assoc e p (jolt-get nh p))))) (_a$5637 tenv) (_a$5638 (jolt-get a (keyword #f "params")))) (jolt-reduce _a$5636 _a$5637 _a$5638)))) (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) jolt-nil) pe)))))) arity-env))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "an-invoke" (letrec ((an-invoke (lambda (node tenv) (let fnrec6834 ((node node) (tenv tenv)) (let* ((fnode (jolt-get node (keyword #f "fn"))) (nm (if (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto)) (jolt-get fnode (keyword #f "name")) jolt-nil)) (ars (let* ((_a$6836 (var-deref "clojure.core" "mapv")) (_a$6837 (lambda (a) (let fnrec6835 ((a a)) (jolt-invoke (var-deref "jolt.passes.numeric" "an") a tenv)))) (_a$6838 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$6836 _a$6837 _a$6838))) (argnodes (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6839 ((r r)) (jolt-nth r 1))) ars)) (node1 (jolt-assoc node (keyword #f "args") argnodes)) (n (jolt-count ars))) (if (jolt= (keyword #f "double") (jolt-get node (keyword #f "num-read"))) (let* ((_o$6840 (keyword #f "double")) (_o$6841 node1)) (jolt-vector _o$6840 _o$6841)) (if (jolt-truthy? (jolt-get fnode (keyword #f "num-ret"))) (let* ((_o$6842 (jolt-get fnode (keyword #f "num-ret"))) (_o$6843 node1)) (jolt-vector _o$6842 _o$6843)) (if (jolt-nil? nm) (let* ((_o$6844 jolt-nil) (_o$6845 node1)) (jolt-vector _o$6844 _o$6845)) (if (jolt-truthy? (keyword #f "else")) (let* ((cls (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6846 ((r r)) (let* ((k (jolt-nth r 0)) (nd (jolt-nth r 1))) (if (jolt= k (keyword #f "double")) (keyword #f "double") (if (jolt= k (keyword #f "long")) (keyword #f "long") (if (jolt= k (keyword #f "bigdec")) (keyword #f "bigdec") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") nd)) (keyword #f "wild") (if (jolt-truthy? (keyword #f "else")) (keyword #f "no") jolt-nil)))))))) ars)) (ok? (lambda (allowed need) (let fnrec6847 ((allowed allowed) (need need)) (let* ((and__25__auto (jolt-pos? n))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "every?") (lambda (c) (let fnrec6848 ((c c)) (let* ((or__26__auto (jolt= c (keyword #f "wild")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c allowed))))) cls))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some") (lambda (c) (let fnrec6849 ((c c)) (jolt= c need))) cls) and__25__auto)) and__25__auto))))) (ds (jolt-invoke (var-deref "jolt.passes.numeric" "dbl-spec") nm n)) (ls (jolt-invoke (var-deref "jolt.passes.numeric" "lng-spec") nm n)) (bs (jolt-invoke (var-deref "jolt.passes.numeric" "bd-spec") nm n))) (if (jolt-truthy? (let* ((and__25__auto ds)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke ok? (keyword #f "double") (keyword #f "double")))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-contains? (let* ((_o$6850 "min") (_o$6851 "max")) (jolt-hash-set _o$6850 _o$6851)) nm)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "every?") (lambda (c) (let fnrec6852 ((c c)) (jolt= c (keyword #f "double")))) cls))) and__25__auto)) and__25__auto))) (let* ((args_PRIME_ (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (nd) (let fnrec6853 ((nd nd)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") nd)) (jolt-assoc nd (keyword #f "val") (jolt-invoke (var-deref "clojure.core" "double") (jolt-get nd (keyword #f "val")))) nd))) argnodes))) (let* ((_o$6854 (jolt-invoke (var-deref "jolt.passes.numeric" "propagate") ds)) (_o$6855 (jolt-assoc node1 (keyword #f "args") args_PRIME_ (keyword #f "num-kind") (keyword #f "double")))) (jolt-vector _o$6854 _o$6855))) (if (jolt-truthy? (let* ((and__25__auto ls)) (if (jolt-truthy? and__25__auto) (jolt-invoke ok? (keyword #f "long") (keyword #f "long")) and__25__auto))) (let* ((_o$6856 (jolt-invoke (var-deref "jolt.passes.numeric" "propagate") ls)) (_o$6857 (jolt-assoc node1 (keyword #f "num-kind") (keyword #f "long")))) (jolt-vector _o$6856 _o$6857)) (if (jolt-truthy? (let* ((and__25__auto bs)) (if (jolt-truthy? and__25__auto) (jolt-invoke ok? (keyword #f "bigdec") (keyword #f "bigdec")) and__25__auto))) (let* ((_o$6858 (jolt-invoke (var-deref "jolt.passes.numeric" "propagate") bs)) (_o$6859 (jolt-assoc node1 (keyword #f "num-kind") (keyword #f "bigdec")))) (jolt-vector _o$6858 _o$6859)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$6860 jolt-nil) (_o$6861 node1)) (jolt-vector _o$6860 _o$6861)) jolt-nil))))) jolt-nil))))))))) an-invoke) (let* ((_o$6862 (keyword #f "private")) (_o$6863 #t) (_o$6864 (keyword #f "doc")) (_o$6865 "Annotate an :invoke with its numeric kind. An arithmetic core op specializes to\n the Chez fl*/fx* op only when every operand is the same kind (:double or :long),\n except an integer literal is :wild \x2014; valid in either \x2014; so (+ ^double x 2) stays\n double. A call to a ^double/^long-returning var yields that kind without lowering\n the call (its body already coerces the return).")) (jolt-hash-map _o$6862 _o$6863 _o$6864 _o$6865)))) + (def-var! "jolt.passes.numeric" "an-invoke" (letrec ((an-invoke (lambda (node tenv) (let fnrec5639 ((node node) (tenv tenv)) (let* ((fnode (jolt-get node (keyword #f "fn"))) (nm (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto))) (jolt-get fnode (keyword #f "name")) jolt-nil)) (ars (let* ((_a$5641 (var-deref "clojure.core" "mapv")) (_a$5642 (lambda (a) (let fnrec5640 ((a a)) (jolt-invoke (var-deref "jolt.passes.numeric" "an") a tenv)))) (_a$5643 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$5641 _a$5642 _a$5643))) (argnodes (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5644 ((r r)) (jolt-nth r 1))) ars)) (node1 (jolt-assoc node (keyword #f "args") argnodes)) (n (jolt-count ars))) (if (jolt-truthy? (jolt-get fnode (keyword #f "num-ret"))) (let* ((_o$5645 (jolt-get fnode (keyword #f "num-ret"))) (_o$5646 node1)) (jolt-vector _o$5645 _o$5646)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") nm)) (let* ((_o$5647 jolt-nil) (_o$5648 node1)) (jolt-vector _o$5647 _o$5648)) (if (jolt-truthy? (keyword #f "else")) (let* ((cls (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5649 ((r r)) (let* ((k (jolt-nth r 0)) (nd (jolt-nth r 1))) (if (jolt= k (keyword #f "double")) (keyword #f "double") (if (jolt= k (keyword #f "long")) (keyword #f "long") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") nd)) (keyword #f "wild") (if (jolt-truthy? (keyword #f "else")) (keyword #f "no") jolt-nil))))))) ars)) (ok? (lambda (allowed need) (let fnrec5650 ((allowed allowed) (need need)) (let* ((and__25__auto (jolt-pos? n))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "every?") (lambda (c) (let fnrec5651 ((c c)) (let* ((or__26__auto (jolt= c (keyword #f "wild")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c allowed))))) cls))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some") (lambda (c) (let fnrec5652 ((c c)) (jolt= c need))) cls) and__25__auto)) and__25__auto))))) (ds (jolt-invoke (var-deref "jolt.passes.numeric" "dbl-spec") nm n)) (ls (jolt-invoke (var-deref "jolt.passes.numeric" "lng-spec") nm n))) (if (jolt-truthy? (let* ((and__25__auto ds)) (if (jolt-truthy? and__25__auto) (jolt-invoke ok? (keyword #f "double") (keyword #f "double")) and__25__auto))) (let* ((args_PRIME_ (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (nd) (let fnrec5653 ((nd nd)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") nd)) (jolt-assoc nd (keyword #f "val") (jolt-invoke (var-deref "clojure.core" "double") (jolt-get nd (keyword #f "val")))) nd))) argnodes))) (let* ((_o$5654 (jolt-invoke (var-deref "jolt.passes.numeric" "propagate") ds)) (_o$5655 (jolt-assoc node1 (keyword #f "args") args_PRIME_ (keyword #f "num-kind") (keyword #f "double")))) (jolt-vector _o$5654 _o$5655))) (if (jolt-truthy? (let* ((and__25__auto ls)) (if (jolt-truthy? and__25__auto) (jolt-invoke ok? (keyword #f "long") (keyword #f "long")) and__25__auto))) (let* ((_o$5656 (jolt-invoke (var-deref "jolt.passes.numeric" "propagate") ls)) (_o$5657 (jolt-assoc node1 (keyword #f "num-kind") (keyword #f "long")))) (jolt-vector _o$5656 _o$5657)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$5658 jolt-nil) (_o$5659 node1)) (jolt-vector _o$5658 _o$5659)) jolt-nil)))) jolt-nil)))))))) an-invoke))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "an" (letrec ((an (lambda (node tenv) (let fnrec6866 ((node node) (tenv tenv)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "const")) (let* ((_o$6867 (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "float-lit?") node)) (keyword #f "double") jolt-nil)) (_o$6868 node)) (jolt-vector _o$6867 _o$6868)) (if (jolt= op (keyword #f "bigdec")) (let* ((_o$6869 (keyword #f "bigdec")) (_o$6870 node)) (jolt-vector _o$6869 _o$6870)) (if (jolt= op (keyword #f "local")) (let* ((_o$6871 (jolt-get tenv (jolt-get node (keyword #f "name")))) (_o$6872 node)) (jolt-vector _o$6871 _o$6872)) (if (jolt= op (keyword #f "coerce")) (let* ((_o$6873 (jolt-get node (keyword #f "kind"))) (_o$6874 (jolt-assoc node (keyword #f "expr") (jolt-nth (an (jolt-get node (keyword #f "expr")) tenv) 1)))) (jolt-vector _o$6873 _o$6874)) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.numeric" "an-invoke") node tenv) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$6885 (lambda (acc b) (let fnrec6875 ((acc acc) (b b)) (let* ((te (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (ir (an (jolt-nth b 1) te))) (let* ((_o$6881 (let* ((_a$6876 te) (_a$6877 (jolt-nth b 0)) (_a$6878 (jolt-nth ir 0))) (jolt-assoc _a$6876 _a$6877 _a$6878))) (_o$6882 (jolt-conj binds (let* ((_o$6879 (jolt-nth b 0)) (_o$6880 (jolt-nth ir 1))) (jolt-vector _o$6879 _o$6880))))) (jolt-vector _o$6881 _o$6882)))))) (_a$6886 (let* ((_o$6883 tenv) (_o$6884 (jolt-vector))) (jolt-vector _o$6883 _o$6884))) (_a$6887 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$6885 _a$6886 _a$6887))) (br (let* ((_a$6888 (jolt-get node (keyword #f "body"))) (_a$6889 (jolt-nth res 0))) (an _a$6888 _a$6889)))) (let* ((_o$6895 (jolt-nth br 0)) (_o$6896 (let* ((_a$6890 node) (_a$6891 (keyword #f "bindings")) (_a$6892 (jolt-nth res 1)) (_a$6893 (keyword #f "body")) (_a$6894 (jolt-nth br 1))) (jolt-assoc _a$6890 _a$6891 _a$6892 _a$6893 _a$6894)))) (jolt-vector _o$6895 _o$6896))) (if (jolt= op (keyword #f "loop")) (let* ((binds (jolt-get node (keyword #f "bindings"))) (names (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec6897 ((b b)) (jolt-nth b 0))) binds)) (ik (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec6898 ((b b)) (jolt-nth (an (jolt-nth b 1) tenv) 0))) binds)) (rlists (jolt-invoke (var-deref "jolt.passes.numeric" "recur-arg-lists") (jolt-get node (keyword #f "body")))) (seed (let* ((_a$6904 (var-deref "clojure.core" "mapv")) (_a$6905 (lambda (j) (let fnrec6899 ((j j)) (let* ((k (jolt-nth ik j)) (b (jolt-nth binds j))) (if (jolt-truthy? k) k (if (jolt-truthy? (let* ((and__25__auto (jolt-seq rlists))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth b 1)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (args) (let fnrec6900 ((args args)) (let* ((_a$6901 (var-deref "jolt.passes.numeric" "counter-step?")) (_a$6902 (jolt-nth args j)) (_a$6903 (jolt-nth b 0))) (jolt-invoke _a$6901 _a$6902 _a$6903)))) rlists) and__25__auto)) and__25__auto))) (keyword #f "long") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) (_a$6906 (jolt-range (jolt-count names)))) (jolt-invoke _a$6904 _a$6905 _a$6906))) (lk (jolt-invoke (var-deref "jolt.passes.numeric" "loop-kinds") names seed (jolt-get node (keyword #f "body")) tenv)) (te (let* ((_a$6911 (lambda (t i) (let fnrec6907 ((t t) (i i)) (let* ((_a$6908 t) (_a$6909 (jolt-nth names i)) (_a$6910 (jolt-nth lk i))) (jolt-assoc _a$6908 _a$6909 _a$6910))))) (_a$6912 tenv) (_a$6913 (jolt-range (jolt-count names)))) (jolt-reduce _a$6911 _a$6912 _a$6913)))) (let* ((_o$6922 jolt-nil) (_o$6923 (let* ((_a$6917 node) (_a$6918 (keyword #f "bindings")) (_a$6919 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec6914 ((b b)) (let* ((_o$6915 (jolt-nth b 0)) (_o$6916 (jolt-nth (an (jolt-nth b 1) tenv) 1))) (jolt-vector _o$6915 _o$6916)))) binds)) (_a$6920 (keyword #f "body")) (_a$6921 (jolt-nth (an (jolt-get node (keyword #f "body")) te) 1))) (jolt-assoc _a$6917 _a$6918 _a$6919 _a$6920 _a$6921)))) (jolt-vector _o$6922 _o$6923))) (if (jolt= op (keyword #f "if")) (let* ((tr (an (jolt-get node (keyword #f "test")) tenv)) (thn (an (jolt-get node (keyword #f "then")) tenv)) (els (an (jolt-get node (keyword #f "else")) tenv)) (tk (jolt-nth thn 0)) (ek (jolt-nth els 0))) (let* ((_o$6931 (if (jolt= tk ek) tk jolt-nil)) (_o$6932 (let* ((_a$6924 node) (_a$6925 (keyword #f "test")) (_a$6926 (jolt-nth tr 1)) (_a$6927 (keyword #f "then")) (_a$6928 (jolt-nth thn 1)) (_a$6929 (keyword #f "else")) (_a$6930 (jolt-nth els 1))) (jolt-assoc _a$6924 _a$6925 _a$6926 _a$6927 _a$6928 _a$6929 _a$6930)))) (jolt-vector _o$6931 _o$6932))) (if (jolt= op (keyword #f "do")) (let* ((stmts (let* ((_a$6934 (var-deref "clojure.core" "mapv")) (_a$6935 (lambda (s) (let fnrec6933 ((s s)) (jolt-nth (an s tenv) 1)))) (_a$6936 (jolt-get node (keyword #f "statements")))) (jolt-invoke _a$6934 _a$6935 _a$6936))) (r (an (jolt-get node (keyword #f "ret")) tenv))) (let* ((_o$6937 (jolt-nth r 0)) (_o$6938 (jolt-assoc node (keyword #f "statements") stmts (keyword #f "ret") (jolt-nth r 1)))) (jolt-vector _o$6937 _o$6938))) (if (jolt= op (keyword #f "fn")) (let* ((_o$6945 jolt-nil) (_o$6946 (jolt-assoc node (keyword #f "arities") (let* ((_a$6942 (var-deref "clojure.core" "mapv")) (_a$6943 (lambda (a) (let fnrec6939 ((a a)) (jolt-assoc a (keyword #f "body") (jolt-nth (let* ((_a$6940 (jolt-get a (keyword #f "body"))) (_a$6941 (jolt-invoke (var-deref "jolt.passes.numeric" "arity-env") tenv a))) (an _a$6940 _a$6941)) 1))))) (_a$6944 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$6942 _a$6943 _a$6944))))) (jolt-vector _o$6945 _o$6946)) (if (jolt= op (keyword #f "def")) (let* ((_o$6947 jolt-nil) (_o$6948 (jolt-assoc node (keyword #f "init") (jolt-nth (an (jolt-get node (keyword #f "init")) tenv) 1)))) (jolt-vector _o$6947 _o$6948)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$6950 jolt-nil) (_o$6951 (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec6949 ((c c)) (jolt-nth (an c tenv) 1))) node))) (jolt-vector _o$6950 _o$6951)) jolt-nil))))))))))))))))) an) (let* ((_o$6952 (keyword #f "private")) (_o$6953 #t)) (jolt-hash-map _o$6952 _o$6953)))) + (def-var! "jolt.passes.numeric" "an" (letrec ((an (lambda (node tenv) (let fnrec5660 ((node node) (tenv tenv)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "const")) (let* ((_o$5661 (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.numeric" "float-lit?") node)) (keyword #f "double") jolt-nil)) (_o$5662 node)) (jolt-vector _o$5661 _o$5662)) (if (jolt= op (keyword #f "local")) (let* ((_o$5663 (jolt-get tenv (jolt-get node (keyword #f "name")))) (_o$5664 node)) (jolt-vector _o$5663 _o$5664)) (if (jolt= op (keyword #f "coerce")) (let* ((_o$5665 (jolt-get node (keyword #f "kind"))) (_o$5666 (jolt-assoc node (keyword #f "expr") (jolt-nth (jolt-invoke an (jolt-get node (keyword #f "expr")) tenv) 1)))) (jolt-vector _o$5665 _o$5666)) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.numeric" "an-invoke") node tenv) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$5677 (lambda (acc b) (let fnrec5667 ((acc acc) (b b)) (let* ((te (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (ir (jolt-invoke an (jolt-nth b 1) te))) (let* ((_o$5673 (let* ((_a$5668 te) (_a$5669 (jolt-nth b 0)) (_a$5670 (jolt-nth ir 0))) (jolt-assoc _a$5668 _a$5669 _a$5670))) (_o$5674 (jolt-conj binds (let* ((_o$5671 (jolt-nth b 0)) (_o$5672 (jolt-nth ir 1))) (jolt-vector _o$5671 _o$5672))))) (jolt-vector _o$5673 _o$5674)))))) (_a$5678 (let* ((_o$5675 tenv) (_o$5676 (jolt-vector))) (jolt-vector _o$5675 _o$5676))) (_a$5679 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$5677 _a$5678 _a$5679))) (br (let* ((_a$5680 an) (_a$5681 (jolt-get node (keyword #f "body"))) (_a$5682 (jolt-nth res 0))) (jolt-invoke _a$5680 _a$5681 _a$5682)))) (let* ((_o$5688 (jolt-nth br 0)) (_o$5689 (let* ((_a$5683 node) (_a$5684 (keyword #f "bindings")) (_a$5685 (jolt-nth res 1)) (_a$5686 (keyword #f "body")) (_a$5687 (jolt-nth br 1))) (jolt-assoc _a$5683 _a$5684 _a$5685 _a$5686 _a$5687)))) (jolt-vector _o$5688 _o$5689))) (if (jolt= op (keyword #f "loop")) (let* ((binds (jolt-get node (keyword #f "bindings"))) (names (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec5690 ((b b)) (jolt-nth b 0))) binds)) (ik (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec5691 ((b b)) (jolt-nth (jolt-invoke an (jolt-nth b 1) tenv) 0))) binds)) (rlists (jolt-invoke (var-deref "jolt.passes.numeric" "recur-arg-lists") (jolt-get node (keyword #f "body")))) (seed (let* ((_a$5697 (var-deref "clojure.core" "mapv")) (_a$5698 (lambda (j) (let fnrec5692 ((j j)) (let* ((k (jolt-nth ik j)) (b (jolt-nth binds j))) (if (jolt-truthy? k) k (if (jolt-truthy? (let* ((and__25__auto (jolt-seq rlists))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.numeric" "int-lit?") (jolt-nth b 1)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (args) (let fnrec5693 ((args args)) (let* ((_a$5694 (var-deref "jolt.passes.numeric" "counter-step?")) (_a$5695 (jolt-nth args j)) (_a$5696 (jolt-nth b 0))) (jolt-invoke _a$5694 _a$5695 _a$5696)))) rlists) and__25__auto)) and__25__auto))) (keyword #f "long") (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) (_a$5699 (jolt-range (jolt-count names)))) (jolt-invoke _a$5697 _a$5698 _a$5699))) (lk (jolt-invoke (var-deref "jolt.passes.numeric" "loop-kinds") names seed (jolt-get node (keyword #f "body")) tenv)) (te (let* ((_a$5704 (lambda (t i) (let fnrec5700 ((t t) (i i)) (let* ((_a$5701 t) (_a$5702 (jolt-nth names i)) (_a$5703 (jolt-nth lk i))) (jolt-assoc _a$5701 _a$5702 _a$5703))))) (_a$5705 tenv) (_a$5706 (jolt-range (jolt-count names)))) (jolt-reduce _a$5704 _a$5705 _a$5706)))) (let* ((_o$5715 jolt-nil) (_o$5716 (let* ((_a$5710 node) (_a$5711 (keyword #f "bindings")) (_a$5712 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (b) (let fnrec5707 ((b b)) (let* ((_o$5708 (jolt-nth b 0)) (_o$5709 (jolt-nth (jolt-invoke an (jolt-nth b 1) tenv) 1))) (jolt-vector _o$5708 _o$5709)))) binds)) (_a$5713 (keyword #f "body")) (_a$5714 (jolt-nth (jolt-invoke an (jolt-get node (keyword #f "body")) te) 1))) (jolt-assoc _a$5710 _a$5711 _a$5712 _a$5713 _a$5714)))) (jolt-vector _o$5715 _o$5716))) (if (jolt= op (keyword #f "if")) (let* ((tr (jolt-invoke an (jolt-get node (keyword #f "test")) tenv)) (thn (jolt-invoke an (jolt-get node (keyword #f "then")) tenv)) (els (jolt-invoke an (jolt-get node (keyword #f "else")) tenv)) (tk (jolt-nth thn 0)) (ek (jolt-nth els 0))) (let* ((_o$5724 (if (jolt= tk ek) tk jolt-nil)) (_o$5725 (let* ((_a$5717 node) (_a$5718 (keyword #f "test")) (_a$5719 (jolt-nth tr 1)) (_a$5720 (keyword #f "then")) (_a$5721 (jolt-nth thn 1)) (_a$5722 (keyword #f "else")) (_a$5723 (jolt-nth els 1))) (jolt-assoc _a$5717 _a$5718 _a$5719 _a$5720 _a$5721 _a$5722 _a$5723)))) (jolt-vector _o$5724 _o$5725))) (if (jolt= op (keyword #f "do")) (let* ((stmts (let* ((_a$5727 (var-deref "clojure.core" "mapv")) (_a$5728 (lambda (s) (let fnrec5726 ((s s)) (jolt-nth (jolt-invoke an s tenv) 1)))) (_a$5729 (jolt-get node (keyword #f "statements")))) (jolt-invoke _a$5727 _a$5728 _a$5729))) (r (jolt-invoke an (jolt-get node (keyword #f "ret")) tenv))) (let* ((_o$5730 (jolt-nth r 0)) (_o$5731 (jolt-assoc node (keyword #f "statements") stmts (keyword #f "ret") (jolt-nth r 1)))) (jolt-vector _o$5730 _o$5731))) (if (jolt= op (keyword #f "fn")) (let* ((_o$5739 jolt-nil) (_o$5740 (jolt-assoc node (keyword #f "arities") (let* ((_a$5736 (var-deref "clojure.core" "mapv")) (_a$5737 (lambda (a) (let fnrec5732 ((a a)) (jolt-assoc a (keyword #f "body") (jolt-nth (let* ((_a$5733 an) (_a$5734 (jolt-get a (keyword #f "body"))) (_a$5735 (jolt-invoke (var-deref "jolt.passes.numeric" "arity-env") tenv a))) (jolt-invoke _a$5733 _a$5734 _a$5735)) 1))))) (_a$5738 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$5736 _a$5737 _a$5738))))) (jolt-vector _o$5739 _o$5740)) (if (jolt= op (keyword #f "def")) (let* ((_o$5741 jolt-nil) (_o$5742 (jolt-assoc node (keyword #f "init") (jolt-nth (jolt-invoke an (jolt-get node (keyword #f "init")) tenv) 1)))) (jolt-vector _o$5741 _o$5742)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$5744 jolt-nil) (_o$5745 (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5743 ((c c)) (jolt-nth (jolt-invoke an c tenv) 1))) node))) (jolt-vector _o$5744 _o$5745)) jolt-nil)))))))))))))))) an))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.numeric" "annotate" (letrec ((annotate (lambda (node) (let fnrec6954 ((node node)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") node (jolt-hash-map)) 1))))) annotate) (let* ((_o$6955 (keyword #f "doc")) (_o$6956 "Tag arithmetic nodes with :num-kind from local numeric type-flow. Returns the\n rewritten IR (no kind escapes to the caller).")) (jolt-hash-map _o$6955 _o$6956)))) + (def-var! "jolt.passes.numeric" "annotate" (letrec ((annotate (lambda (node) (let fnrec5746 ((node node)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.numeric" "an") node (jolt-hash-map)) 1))))) annotate))) (guard (e (#t #f)) (def-var! "jolt.passes.inline" "dirty" (jolt-invoke (var-deref "clojure.core" "atom") #f))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "mark!" (letrec ((mark! (lambda () (let fnrec6957 () (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "dirty") #t))))) mark!) (let* ((_o$6958 (keyword #f "private")) (_o$6959 #t)) (jolt-hash-map _o$6958 _o$6959)))) + (def-var! "jolt.passes.inline" "mark!" (letrec ((mark! (lambda () (let fnrec5747 () (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "dirty") #t))))) mark!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "rec-shapes" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (let* ((_o$6960 (keyword #f "private")) (_o$6961 #t)) (jolt-hash-map _o$6960 _o$6961)))) + (def-var-with-meta! "jolt.passes.inline" "rec-shapes" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "set-rec-shapes!" (letrec ((set-rec-shapes! (lambda (m) (let fnrec6962 ((m m)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "rec-shapes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-rec-shapes!) (let* ((_o$6963 (keyword #f "doc")) (_o$6964 "Install the record-ctor shape registry the record fold consults.")) (jolt-hash-map _o$6963 _o$6964)))) + (def-var! "jolt.passes.inline" "set-rec-shapes!" (letrec ((set-rec-shapes! (lambda (m) (let fnrec5748 ((m m)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "rec-shapes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-rec-shapes!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "fresh-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (let* ((_o$6965 (keyword #f "private")) (_o$6966 #t)) (jolt-hash-map _o$6965 _o$6966)))) + (def-var-with-meta! "jolt.passes.inline" "fresh-counter" (jolt-invoke (var-deref "clojure.core" "atom") 0) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "fresh" (letrec ((fresh (lambda (base) (let fnrec6967 ((base base)) (let* ((n (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "fresh-counter")))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.inline" "fresh-counter") jolt-inc) (jolt-invoke (var-deref "clojure.core" "str") base "__il" n))))))) fresh) (let* ((_o$6968 (keyword #f "private")) (_o$6969 #t)) (jolt-hash-map _o$6968 _o$6969)))) + (def-var! "jolt.passes.inline" "fresh" (letrec ((fresh (lambda (base) (let fnrec5749 ((base base)) (let* ((n (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "fresh-counter")))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.inline" "fresh-counter") jolt-inc) (jolt-invoke (var-deref "clojure.core" "str") base "__il" n))))))) fresh))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "safe-op?" (letrec ((safe-op? (lambda (op) (let fnrec6970 ((op op)) (let* ((or__26__auto (jolt= op (keyword #f "const")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "local")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "var")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "host")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "the-var")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "quote")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "if")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "do")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "let")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "invoke")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "map")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "vector")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "set")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "throw")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "coerce")))))))))))))))))))))))))))))))))) safe-op?) (let* ((_o$6971 (keyword #f "private")) (_o$6972 #t)) (jolt-hash-map _o$6971 _o$6972)))) + (def-var! "jolt.passes.inline" "safe-op?" (letrec ((safe-op? (lambda (op) (let fnrec5750 ((op op)) (let* ((or__26__auto (jolt= op (keyword #f "const")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "local")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "var")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "host")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "the-var")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "quote")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "if")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "do")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "let")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "invoke")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "map")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "vector")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "set")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= op (keyword #f "throw")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "coerce")))))))))))))))))))))))))))))))))) safe-op?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "inline-budget" 120 (let* ((_o$6973 (keyword #f "private")) (_o$6974 #t)) (jolt-hash-map _o$6973 _o$6974)))) + (def-var-with-meta! "jolt.passes.inline" "inline-budget" 120 (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "body-size" (letrec ((body-size (lambda (node) (let fnrec6975 ((node node)) (if (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") (jolt-get node (keyword #f "op")))) 100000 (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (acc c) (let fnrec6976 ((acc acc) (c c)) (jolt-n+ acc (body-size c)))) 1 node)))))) body-size) (let* ((_o$6977 (keyword #f "private")) (_o$6978 #t) (_o$6979 (keyword #f "doc")) (_o$6980 "Node count of an inline-eligible body. A disallowed op contributes a number\n larger than any budget, so the caller's (<= size budget) test fails and we\n never try to inline (or alpha-rename) such a body. Only reached for safe ops,\n so the shared child fold covers it exactly (leaves fold to 1).")) (jolt-hash-map _o$6977 _o$6978 _o$6979 _o$6980)))) + (def-var! "jolt.passes.inline" "body-size" (letrec ((body-size (lambda (node) (let fnrec5751 ((node node)) (if (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") (jolt-get node (keyword #f "op")))) 100000 (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (acc c) (let fnrec5752 ((acc acc) (c c)) (+ acc (jolt-invoke body-size c)))) 1 node)))))) body-size))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "subst" (letrec ((subst (lambda (node env) (let fnrec6981 ((node node) (env env)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "local")) (let* ((r (jolt-get env (jolt-get node (keyword #f "name"))))) (if (jolt-truthy? r) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get r (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get node (keyword #f "hint")))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get r (keyword #f "hint"))) and__25__auto)) and__25__auto))) (jolt-assoc r (keyword #f "hint") (jolt-get node (keyword #f "hint"))) r) node)) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$6993 (lambda (acc b) (let fnrec6982 ((acc acc) (b b)) (let* ((e (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (nm (jolt-nth b 0)) (init (subst (jolt-nth b 1) e)) (f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") nm))) (let* ((_o$6989 (jolt-assoc e nm (let* ((_o$6983 (keyword #f "op")) (_o$6984 (keyword #f "local")) (_o$6985 (keyword #f "name")) (_o$6986 f)) (jolt-hash-map _o$6983 _o$6984 _o$6985 _o$6986)))) (_o$6990 (jolt-conj binds (let* ((_o$6987 f) (_o$6988 init)) (jolt-vector _o$6987 _o$6988))))) (jolt-vector _o$6989 _o$6990)))))) (_a$6994 (let* ((_o$6991 env) (_o$6992 (jolt-vector))) (jolt-vector _o$6991 _o$6992))) (_a$6995 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$6993 _a$6994 _a$6995)))) (let* ((_a$6998 node) (_a$6999 (keyword #f "bindings")) (_a$7000 (jolt-nth res 1)) (_a$7001 (keyword #f "body")) (_a$7002 (let* ((_a$6996 (jolt-get node (keyword #f "body"))) (_a$6997 (jolt-nth res 0))) (subst _a$6996 _a$6997)))) (jolt-assoc _a$6998 _a$6999 _a$7000 _a$7001 _a$7002))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec7003 ((c c)) (subst c env))) node) jolt-nil)))))))) subst) (let* ((_o$7004 (keyword #f "private")) (_o$7005 #t) (_o$7006 (keyword #f "doc")) (_o$7007 "Substitute locals in node per env (a map name -> replacement IR node), and\n alpha-rename every inner :let binder to a globally fresh name (so the spliced\n body shares no name with the caller). env seeds the params: a trivial arg\n (local/const) maps a param straight to the arg node (copy propagation \x2014; this\n is what lets scalar-replace see a map-literal arg through the call boundary);\n a non-trivial arg maps the param to a fresh :local that a wrapping let binds.")) (jolt-hash-map _o$7004 _o$7005 _o$7006 _o$7007)))) + (def-var! "jolt.passes.inline" "subst" (letrec ((subst (lambda (node env) (let fnrec5753 ((node node) (env env)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "local")) (let* ((r (jolt-get env (jolt-get node (keyword #f "name"))))) (if (jolt-truthy? r) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get r (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get node (keyword #f "hint")))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get r (keyword #f "hint"))) and__25__auto)) and__25__auto))) (jolt-assoc r (keyword #f "hint") (jolt-get node (keyword #f "hint"))) r) node)) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$5765 (lambda (acc b) (let fnrec5754 ((acc acc) (b b)) (let* ((e (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (nm (jolt-nth b 0)) (init (jolt-invoke subst (jolt-nth b 1) e)) (f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") nm))) (let* ((_o$5761 (jolt-assoc e nm (let* ((_o$5755 (keyword #f "op")) (_o$5756 (keyword #f "local")) (_o$5757 (keyword #f "name")) (_o$5758 f)) (jolt-hash-map _o$5755 _o$5756 _o$5757 _o$5758)))) (_o$5762 (jolt-conj binds (let* ((_o$5759 f) (_o$5760 init)) (jolt-vector _o$5759 _o$5760))))) (jolt-vector _o$5761 _o$5762)))))) (_a$5766 (let* ((_o$5763 env) (_o$5764 (jolt-vector))) (jolt-vector _o$5763 _o$5764))) (_a$5767 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$5765 _a$5766 _a$5767)))) (let* ((_a$5771 node) (_a$5772 (keyword #f "bindings")) (_a$5773 (jolt-nth res 1)) (_a$5774 (keyword #f "body")) (_a$5775 (let* ((_a$5768 subst) (_a$5769 (jolt-get node (keyword #f "body"))) (_a$5770 (jolt-nth res 0))) (jolt-invoke _a$5768 _a$5769 _a$5770)))) (jolt-assoc _a$5771 _a$5772 _a$5773 _a$5774 _a$5775))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5776 ((c c)) (jolt-invoke subst c env))) node) jolt-nil)))))))) subst))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "trivial-arg?" (letrec ((trivial-arg? (lambda (n) (let fnrec7008 ((n n)) (let* ((op (jolt-get n (keyword #f "op")))) (let* ((or__26__auto (jolt= op (keyword #f "local")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "const"))))))))) trivial-arg?) (let* ((_o$7009 (keyword #f "private")) (_o$7010 #t)) (jolt-hash-map _o$7009 _o$7010)))) + (def-var! "jolt.passes.inline" "trivial-arg?" (letrec ((trivial-arg? (lambda (n) (let fnrec5777 ((n n)) (let* ((op (jolt-get n (keyword #f "op")))) (let* ((or__26__auto (jolt= op (keyword #f "local")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "const"))))))))) trivial-arg?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "body-closed?" (letrec ((body-closed? (lambda (node scope) (let fnrec7011 ((node node) (scope scope)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "local")) (jolt-contains? scope (jolt-get node (keyword #f "name"))) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$7017 (lambda (acc b) (let fnrec7012 ((acc acc) (b b)) (let* ((sc (jolt-nth acc 0)) (ok (jolt-nth acc 1))) (if (jolt-not ok) acc (let* ((_o$7013 (jolt-conj sc (jolt-nth b 0))) (_o$7014 (body-closed? (jolt-nth b 1) sc))) (jolt-vector _o$7013 _o$7014))))))) (_a$7018 (let* ((_o$7015 scope) (_o$7016 #t)) (jolt-vector _o$7015 _o$7016))) (_a$7019 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$7017 _a$7018 _a$7019)))) (let* ((and__25__auto (jolt-nth res 1))) (if (jolt-truthy? and__25__auto) (let* ((_a$7020 (jolt-get node (keyword #f "body"))) (_a$7021 (jolt-nth res 0))) (body-closed? _a$7020 _a$7021)) and__25__auto))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") op)) (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (ok c) (let fnrec7022 ((ok ok) (c c)) (let* ((and__25__auto ok)) (if (jolt-truthy? and__25__auto) (body-closed? c scope) and__25__auto)))) #t node) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))))) body-closed?) (let* ((_o$7023 (keyword #f "private")) (_o$7024 #t) (_o$7025 (keyword #f "doc")) (_o$7026 "True if every :local in node is bound \x2014; by a param (in the initial scope set)\n or by an enclosing :let within the body. A self-recursive fn fails this: the\n analyzer binds the fn's own name as a local, so its body has a FREE local (the\n self-reference) that would dangle once the body is spliced elsewhere.")) (jolt-hash-map _o$7023 _o$7024 _o$7025 _o$7026)))) + (def-var! "jolt.passes.inline" "body-closed?" (letrec ((body-closed? (lambda (node scope) (let fnrec5778 ((node node) (scope scope)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "local")) (jolt-contains? scope (jolt-get node (keyword #f "name"))) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$5784 (lambda (acc b) (let fnrec5779 ((acc acc) (b b)) (let* ((sc (jolt-nth acc 0)) (ok (jolt-nth acc 1))) (if (jolt-not ok) acc (let* ((_o$5780 (jolt-conj sc (jolt-nth b 0))) (_o$5781 (jolt-invoke body-closed? (jolt-nth b 1) sc))) (jolt-vector _o$5780 _o$5781))))))) (_a$5785 (let* ((_o$5782 scope) (_o$5783 #t)) (jolt-vector _o$5782 _o$5783))) (_a$5786 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$5784 _a$5785 _a$5786)))) (let* ((and__25__auto (jolt-nth res 1))) (if (jolt-truthy? and__25__auto) (let* ((_a$5787 body-closed?) (_a$5788 (jolt-get node (keyword #f "body"))) (_a$5789 (jolt-nth res 0))) (jolt-invoke _a$5787 _a$5788 _a$5789)) and__25__auto))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") op)) (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (ok c) (let fnrec5790 ((ok ok) (c c)) (let* ((and__25__auto ok)) (if (jolt-truthy? and__25__auto) (jolt-invoke body-closed? c scope) and__25__auto)))) #t node) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))))) body-closed?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "try-inline" (letrec ((try-inline (lambda (node ctx) (let fnrec7027 ((node node) (ctx ctx)) (let* ((f (jolt-get node (keyword #f "fn")))) (if (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))) (let* ((stash (let* ((_a$7028 (var-deref "jolt.host" "inline-ir")) (_a$7029 ctx) (_a$7030 (jolt-get f (keyword #f "ns"))) (_a$7031 (jolt-get f (keyword #f "name")))) (jolt-invoke _a$7028 _a$7029 _a$7030 _a$7031)))) (if (jolt-truthy? stash) (let* ((params (jolt-get stash (keyword #f "params"))) (body (jolt-get stash (keyword #f "body"))) (nh (let* ((_a$7036 (lambda (m pr) (let fnrec7032 ((m m) (pr pr)) (let* ((_a$7033 m) (_a$7034 (jolt-nth pr 0)) (_a$7035 (jolt-nth pr 1))) (jolt-assoc _a$7033 _a$7034 _a$7035))))) (_a$7037 (jolt-hash-map)) (_a$7038 (jolt-get stash (keyword #f "nhints")))) (jolt-reduce _a$7036 _a$7037 _a$7038))) (ret (jolt-get stash (keyword #f "ret"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (let* ((_a$7039 (jolt-count params)) (_a$7040 (jolt-count args))) (jolt= _a$7039 _a$7040)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n<= (jolt-invoke (var-deref "jolt.passes.inline" "body-size") body) (var-deref "jolt.passes.inline" "inline-budget")))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "body-closed?") body (jolt-reduce jolt-conj (jolt-hash-set) params)) and__25__auto)) and__25__auto))) (let* ((n (jolt-count params)) (res (let* ((i 0) (env (jolt-hash-map)) (binds (jolt-vector))) (let loop7041 ((i i) (env env) (binds binds)) (if (jolt-n< i n) (let* ((p (jolt-nth params i)) (a (jolt-nth args i)) (k (jolt-get nh p))) (if (jolt-truthy? k) (let* ((f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") p))) (let* ((_a$7048 (jolt-inc i)) (_a$7049 (jolt-assoc env p (let* ((_o$7042 (keyword #f "op")) (_o$7043 (keyword #f "local")) (_o$7044 (keyword #f "name")) (_o$7045 f)) (jolt-hash-map _o$7042 _o$7043 _o$7044 _o$7045)))) (_a$7050 (jolt-conj binds (let* ((_o$7046 f) (_o$7047 (jolt-invoke (var-deref "jolt.ir" "coerce-node") k a))) (jolt-vector _o$7046 _o$7047))))) (loop7041 _a$7048 _a$7049 _a$7050))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "trivial-arg?") a)) (let* ((_a$7051 (jolt-inc i)) (_a$7052 (jolt-assoc env p a)) (_a$7053 binds)) (loop7041 _a$7051 _a$7052 _a$7053)) (if (jolt-truthy? (keyword #f "else")) (let* ((f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") p))) (let* ((_a$7060 (jolt-inc i)) (_a$7061 (jolt-assoc env p (let* ((_o$7054 (keyword #f "op")) (_o$7055 (keyword #f "local")) (_o$7056 (keyword #f "name")) (_o$7057 f)) (jolt-hash-map _o$7054 _o$7055 _o$7056 _o$7057)))) (_a$7062 (jolt-conj binds (let* ((_o$7058 f) (_o$7059 a)) (jolt-vector _o$7058 _o$7059))))) (loop7041 _a$7060 _a$7061 _a$7062))) jolt-nil)))) (let* ((_o$7063 env) (_o$7064 binds)) (jolt-vector _o$7063 _o$7064)))))) (env (jolt-nth res 0)) (binds (jolt-nth res 1)) (rbody0 (jolt-invoke (var-deref "jolt.passes.inline" "subst") body env)) (rbody (if (jolt-truthy? ret) (jolt-invoke (var-deref "jolt.ir" "coerce-node") ret rbody0) rbody0))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (if (jolt= 0 (jolt-count binds)) rbody (let* ((_o$7065 (keyword #f "op")) (_o$7066 (keyword #f "let")) (_o$7067 (keyword #f "bindings")) (_o$7068 binds) (_o$7069 (keyword #f "body")) (_o$7070 rbody)) (jolt-hash-map _o$7065 _o$7066 _o$7067 _o$7068 _o$7069 _o$7070))))) node)) node)) node)))))) try-inline) (let* ((_o$7071 (keyword #f "private")) (_o$7072 #t) (_o$7073 (keyword #f "doc")) (_o$7074 "node is an :invoke whose children are already inlined. If its :fn is a var\n with a stashed, in-budget, arity-matching inline body, return the spliced\n let; else node.")) (jolt-hash-map _o$7071 _o$7072 _o$7073 _o$7074)))) + (def-var! "jolt.passes.inline" "try-inline" (letrec ((try-inline (lambda (node ctx) (let fnrec5791 ((node node) (ctx ctx)) (let* ((f (jolt-get node (keyword #f "fn")))) (if (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))) (let* ((stash (let* ((_a$5792 (var-deref "jolt.host" "inline-ir")) (_a$5793 ctx) (_a$5794 (jolt-get f (keyword #f "ns"))) (_a$5795 (jolt-get f (keyword #f "name")))) (jolt-invoke _a$5792 _a$5793 _a$5794 _a$5795)))) (if (jolt-truthy? stash) (let* ((params (jolt-get stash (keyword #f "params"))) (body (jolt-get stash (keyword #f "body"))) (nh (let* ((_a$5800 (lambda (m pr) (let fnrec5796 ((m m) (pr pr)) (let* ((_a$5797 m) (_a$5798 (jolt-nth pr 0)) (_a$5799 (jolt-nth pr 1))) (jolt-assoc _a$5797 _a$5798 _a$5799))))) (_a$5801 (jolt-hash-map)) (_a$5802 (jolt-get stash (keyword #f "nhints")))) (jolt-reduce _a$5800 _a$5801 _a$5802))) (ret (jolt-get stash (keyword #f "ret"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (let* ((_a$5803 (jolt-count params)) (_a$5804 (jolt-count args))) (jolt= _a$5803 _a$5804)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (<= (jolt-invoke (var-deref "jolt.passes.inline" "body-size") body) (var-deref "jolt.passes.inline" "inline-budget")))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "body-closed?") body (jolt-reduce jolt-conj (jolt-hash-set) params)) and__25__auto)) and__25__auto))) (let* ((n (jolt-count params)) (res (let* ((i 0) (env (jolt-hash-map)) (binds (jolt-vector))) (let loop5805 ((i i) (env env) (binds binds)) (if (< i n) (let* ((p (jolt-nth params i)) (a (jolt-nth args i)) (k (jolt-get nh p))) (if (jolt-truthy? k) (let* ((f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") p))) (let* ((_a$5812 (jolt-inc i)) (_a$5813 (jolt-assoc env p (let* ((_o$5806 (keyword #f "op")) (_o$5807 (keyword #f "local")) (_o$5808 (keyword #f "name")) (_o$5809 f)) (jolt-hash-map _o$5806 _o$5807 _o$5808 _o$5809)))) (_a$5814 (jolt-conj binds (let* ((_o$5810 f) (_o$5811 (jolt-invoke (var-deref "jolt.ir" "coerce-node") k a))) (jolt-vector _o$5810 _o$5811))))) (loop5805 _a$5812 _a$5813 _a$5814))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "trivial-arg?") a)) (let* ((_a$5815 (jolt-inc i)) (_a$5816 (jolt-assoc env p a)) (_a$5817 binds)) (loop5805 _a$5815 _a$5816 _a$5817)) (if (jolt-truthy? (keyword #f "else")) (let* ((f (jolt-invoke (var-deref "jolt.passes.inline" "fresh") p))) (let* ((_a$5824 (jolt-inc i)) (_a$5825 (jolt-assoc env p (let* ((_o$5818 (keyword #f "op")) (_o$5819 (keyword #f "local")) (_o$5820 (keyword #f "name")) (_o$5821 f)) (jolt-hash-map _o$5818 _o$5819 _o$5820 _o$5821)))) (_a$5826 (jolt-conj binds (let* ((_o$5822 f) (_o$5823 a)) (jolt-vector _o$5822 _o$5823))))) (loop5805 _a$5824 _a$5825 _a$5826))) jolt-nil)))) (let* ((_o$5827 env) (_o$5828 binds)) (jolt-vector _o$5827 _o$5828)))))) (env (jolt-nth res 0)) (binds (jolt-nth res 1)) (rbody0 (jolt-invoke (var-deref "jolt.passes.inline" "subst") body env)) (rbody (if (jolt-truthy? ret) (jolt-invoke (var-deref "jolt.ir" "coerce-node") ret rbody0) rbody0))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (if (jolt= 0 (jolt-count binds)) rbody (let* ((_o$5829 (keyword #f "op")) (_o$5830 (keyword #f "let")) (_o$5831 (keyword #f "bindings")) (_o$5832 binds) (_o$5833 (keyword #f "body")) (_o$5834 rbody)) (jolt-hash-map _o$5829 _o$5830 _o$5831 _o$5832 _o$5833 _o$5834))))) node)) node)) node)))))) try-inline))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "inline-node" (letrec ((inline-node (lambda (node ctx) (let fnrec7075 ((node node) (ctx ctx)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.inline" "try-inline") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec7076 ((c c)) (inline-node c ctx))) node) ctx) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec7077 ((c c)) (inline-node c ctx))) node)))))) inline-node) (let* ((_o$7078 (keyword #f "doc")) (_o$7079 "Bottom-up: inline children first, then attempt to inline this node.")) (jolt-hash-map _o$7078 _o$7079)))) + (def-var! "jolt.passes.inline" "inline-node" (letrec ((inline-node (lambda (node ctx) (let fnrec5835 ((node node) (ctx ctx)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.inline" "try-inline") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5836 ((c c)) (jolt-invoke inline-node c ctx))) node) ctx) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5837 ((c c)) (jolt-invoke inline-node c ctx))) node)))))) inline-node))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "flatten-let-bindings" (letrec ((flatten-let-bindings (lambda (binds) (let fnrec7080 ((binds binds)) (let* ((_a$7086 (lambda (out b) (let fnrec7081 ((out out) (b b)) (let* ((nm (jolt-nth b 0)) (init (jolt-nth b 1))) (if (jolt= (keyword #f "let") (jolt-get init (keyword #f "op"))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (let* ((_a$7084 (jolt-reduce jolt-conj out (jolt-get init (keyword #f "bindings")))) (_a$7085 (let* ((_o$7082 nm) (_o$7083 (jolt-get init (keyword #f "body")))) (jolt-vector _o$7082 _o$7083)))) (jolt-conj _a$7084 _a$7085))) (jolt-conj out b)))))) (_a$7087 (jolt-vector)) (_a$7088 binds)) (jolt-reduce _a$7086 _a$7087 _a$7088)))))) flatten-let-bindings) (let* ((_o$7089 (keyword #f "private")) (_o$7090 #t)) (jolt-hash-map _o$7089 _o$7090)))) + (def-var! "jolt.passes.inline" "flatten-let-bindings" (letrec ((flatten-let-bindings (lambda (binds) (let fnrec5838 ((binds binds)) (let* ((_a$5844 (lambda (out b) (let fnrec5839 ((out out) (b b)) (let* ((nm (jolt-nth b 0)) (init (jolt-nth b 1))) (if (jolt= (keyword #f "let") (jolt-get init (keyword #f "op"))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (let* ((_a$5842 (jolt-reduce jolt-conj out (jolt-get init (keyword #f "bindings")))) (_a$5843 (let* ((_o$5840 nm) (_o$5841 (jolt-get init (keyword #f "body")))) (jolt-vector _o$5840 _o$5841)))) (jolt-conj _a$5842 _a$5843))) (jolt-conj out b)))))) (_a$5845 (jolt-vector)) (_a$5846 binds)) (jolt-reduce _a$5844 _a$5845 _a$5846)))))) flatten-let-bindings))) (guard (e (#t #f)) - (def-var! "jolt.passes.inline" "flatten-lets" (letrec ((flatten-lets (lambda (node) (let fnrec7091 ((node node)) (if (jolt= (keyword #f "let") (jolt-get node (keyword #f "op"))) (let* ((n (jolt-invoke (var-deref "jolt.ir" "map-ir-children") flatten-lets node))) (jolt-assoc n (keyword #f "bindings") (jolt-invoke (var-deref "jolt.passes.inline" "flatten-let-bindings") (jolt-get n (keyword #f "bindings"))))) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") flatten-lets node)))))) flatten-lets))) + (def-var! "jolt.passes.inline" "flatten-lets" (letrec ((flatten-lets (lambda (node) (let fnrec5847 ((node node)) (if (jolt= (keyword #f "let") (jolt-get node (keyword #f "op"))) (let* ((n (jolt-invoke (var-deref "jolt.ir" "map-ir-children") flatten-lets node))) (jolt-assoc n (keyword #f "bindings") (jolt-invoke (var-deref "jolt.passes.inline" "flatten-let-bindings") (jolt-get n (keyword #f "bindings"))))) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") flatten-lets node)))))) flatten-lets))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "pure-fns" (let* ((_o$7092 "+") (_o$7093 "-") (_o$7094 "*") (_o$7095 "/") (_o$7096 "<") (_o$7097 ">") (_o$7098 "<=") (_o$7099 ">=") (_o$7100 "=") (_o$7101 "not=") (_o$7102 "inc") (_o$7103 "dec") (_o$7104 "mod") (_o$7105 "rem") (_o$7106 "quot") (_o$7107 "min") (_o$7108 "max") (_o$7109 "abs") (_o$7110 "nil?") (_o$7111 "some?") (_o$7112 "not") (_o$7113 "get") (_o$7114 "zero?") (_o$7115 "pos?") (_o$7116 "neg?") (_o$7117 "even?") (_o$7118 "odd?") (_o$7119 "bit-and") (_o$7120 "bit-or") (_o$7121 "bit-xor")) (jolt-hash-set _o$7092 _o$7093 _o$7094 _o$7095 _o$7096 _o$7097 _o$7098 _o$7099 _o$7100 _o$7101 _o$7102 _o$7103 _o$7104 _o$7105 _o$7106 _o$7107 _o$7108 _o$7109 _o$7110 _o$7111 _o$7112 _o$7113 _o$7114 _o$7115 _o$7116 _o$7117 _o$7118 _o$7119 _o$7120 _o$7121)) (let* ((_o$7122 (keyword #f "private")) (_o$7123 #t)) (jolt-hash-map _o$7122 _o$7123)))) + (def-var-with-meta! "jolt.passes.inline" "pure-fns" (let* ((_o$5848 "+") (_o$5849 "-") (_o$5850 "*") (_o$5851 "/") (_o$5852 "<") (_o$5853 ">") (_o$5854 "<=") (_o$5855 ">=") (_o$5856 "=") (_o$5857 "not=") (_o$5858 "inc") (_o$5859 "dec") (_o$5860 "mod") (_o$5861 "rem") (_o$5862 "quot") (_o$5863 "min") (_o$5864 "max") (_o$5865 "abs") (_o$5866 "nil?") (_o$5867 "some?") (_o$5868 "not") (_o$5869 "get") (_o$5870 "zero?") (_o$5871 "pos?") (_o$5872 "neg?") (_o$5873 "even?") (_o$5874 "odd?") (_o$5875 "bit-and") (_o$5876 "bit-or") (_o$5877 "bit-xor")) (jolt-hash-set _o$5848 _o$5849 _o$5850 _o$5851 _o$5852 _o$5853 _o$5854 _o$5855 _o$5856 _o$5857 _o$5858 _o$5859 _o$5860 _o$5861 _o$5862 _o$5863 _o$5864 _o$5865 _o$5866 _o$5867 _o$5868 _o$5869 _o$5870 _o$5871 _o$5872 _o$5873 _o$5874 _o$5875 _o$5876 _o$5877)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "pure-fn?" (letrec ((pure-fn? (lambda (f) (let fnrec7124 ((f f)) (let* ((op (jolt-get f (keyword #f "op")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f)) #t (if (jolt= op (keyword #f "var")) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get f (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-contains? (var-deref "jolt.passes.inline" "pure-fns") (jolt-get f (keyword #f "name"))) and__25__auto)) (if (jolt= op (keyword #f "host")) (jolt-contains? (var-deref "jolt.passes.inline" "pure-fns") (jolt-get f (keyword #f "name"))) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))))) pure-fn?) (let* ((_o$7125 (keyword #f "private")) (_o$7126 #t)) (jolt-hash-map _o$7125 _o$7126)))) + (def-var! "jolt.passes.inline" "pure-fn?" (letrec ((pure-fn? (lambda (f) (let fnrec5878 ((f f)) (let* ((op (jolt-get f (keyword #f "op")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f)) #t (if (jolt= op (keyword #f "var")) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get f (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-contains? (var-deref "jolt.passes.inline" "pure-fns") (jolt-get f (keyword #f "name"))) and__25__auto)) (if (jolt= op (keyword #f "host")) (jolt-contains? (var-deref "jolt.passes.inline" "pure-fns") (jolt-get f (keyword #f "name"))) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))))) pure-fn?))) (guard (e (#t #f)) (declare-var! "jolt.passes.inline" "ctor-shape")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "pure?" (letrec ((pure? (lambda (node) (let fnrec7127 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (let* ((and__25__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "pure-fn?") (jolt-get node (keyword #f "fn"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") node))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") pure? (jolt-get node (keyword #f "args"))) and__25__auto)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") op)) (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (ok c) (let fnrec7128 ((ok ok) (c c)) (let* ((and__25__auto ok)) (if (jolt-truthy? and__25__auto) (pure? c) and__25__auto)))) #t node) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil)))))))) pure?) (let* ((_o$7129 (keyword #f "private")) (_o$7130 #t) (_o$7131 (keyword #f "doc")) (_o$7132 "Conservative: true only for expressions with no side effects that are safe to\n duplicate or discard. A var/host ref is a pure read; an invoke is pure for a\n known-pure fn (arithmetic, comparison, keyword lookup, get) or a record\n constructor (an immutable struct alloc) whose args are themselves pure.")) (jolt-hash-map _o$7129 _o$7130 _o$7131 _o$7132)))) + (def-var! "jolt.passes.inline" "pure?" (letrec ((pure? (lambda (node) (let fnrec5879 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (let* ((and__25__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "pure-fn?") (jolt-get node (keyword #f "fn"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") node))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") pure? (jolt-get node (keyword #f "args"))) and__25__auto)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "safe-op?") op)) (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (ok c) (let fnrec5880 ((ok ok) (c c)) (let* ((and__25__auto ok)) (if (jolt-truthy? and__25__auto) (jolt-invoke pure? c) and__25__auto)))) #t node) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil)))))))) pure?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "const-key-map?" (letrec ((const-key-map? (lambda (node) (let fnrec7133 ((node node)) (let* ((prs (jolt-get node (keyword #f "pairs")))) (let* ((and__25__auto (jolt-n> (jolt-count prs) 0))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (pr) (let fnrec7134 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth pr 0)))) prs) and__25__auto))))))) const-key-map?) (let* ((_o$7135 (keyword #f "private")) (_o$7136 #t)) (jolt-hash-map _o$7135 _o$7136)))) + (def-var! "jolt.passes.inline" "const-key-map?" (letrec ((const-key-map? (lambda (node) (let fnrec5881 ((node node)) (let* ((prs (jolt-get node (keyword #f "pairs")))) (let* ((and__25__auto (> (jolt-count prs) 0))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (pr) (let fnrec5882 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth pr 0)))) prs) and__25__auto))))))) const-key-map?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "all-vals-pure?" (letrec ((all-vals-pure? (lambda (node) (let fnrec7137 ((node node)) (let* ((_a$7139 (var-deref "clojure.core" "every?")) (_a$7140 (lambda (pr) (let fnrec7138 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.inline" "pure?") (jolt-nth pr 1))))) (_a$7141 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$7139 _a$7140 _a$7141)))))) all-vals-pure?) (let* ((_o$7142 (keyword #f "private")) (_o$7143 #t)) (jolt-hash-map _o$7142 _o$7143)))) + (def-var! "jolt.passes.inline" "all-vals-pure?" (letrec ((all-vals-pure? (lambda (node) (let fnrec5883 ((node node)) (let* ((_a$5885 (var-deref "clojure.core" "every?")) (_a$5886 (lambda (pr) (let fnrec5884 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.inline" "pure?") (jolt-nth pr 1))))) (_a$5887 (jolt-get node (keyword #f "pairs")))) (jolt-invoke _a$5885 _a$5886 _a$5887)))))) all-vals-pure?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "map-val" (letrec ((map-val (lambda (mapnode k) (let fnrec7144 ((mapnode mapnode) (k k)) (let* ((prs (jolt-get mapnode (keyword #f "pairs"))) (n (jolt-count prs))) (let* ((i 0)) (let loop7145 ((i i)) (if (jolt-n< i n) (let* ((pr (jolt-nth prs i))) (if (jolt= (jolt-get (jolt-nth pr 0) (keyword #f "val")) k) (jolt-nth pr 1) (loop7145 (jolt-inc i)))) (let* ((_o$7146 (keyword #f "op")) (_o$7147 (keyword #f "const")) (_o$7148 (keyword #f "val")) (_o$7149 jolt-nil)) (jolt-hash-map _o$7146 _o$7147 _o$7148 _o$7149)))))))))) map-val) (let* ((_o$7150 (keyword #f "private")) (_o$7151 #t) (_o$7152 (keyword #f "doc")) (_o$7153 "The value IR at scalar key k in a const-key map node, or a nil constant when k\n is absent (struct-eligible literal: a missing key reads nil, like the back end).")) (jolt-hash-map _o$7150 _o$7151 _o$7152 _o$7153)))) + (def-var! "jolt.passes.inline" "map-val" (letrec ((map-val (lambda (mapnode k) (let fnrec5888 ((mapnode mapnode) (k k)) (let* ((prs (jolt-get mapnode (keyword #f "pairs"))) (n (jolt-count prs))) (let* ((i 0)) (let loop5889 ((i i)) (if (< i n) (let* ((pr (jolt-nth prs i))) (if (jolt= (jolt-get (jolt-nth pr 0) (keyword #f "val")) k) (jolt-nth pr 1) (loop5889 (jolt-inc i)))) (let* ((_o$5890 (keyword #f "op")) (_o$5891 (keyword #f "const")) (_o$5892 (keyword #f "val")) (_o$5893 jolt-nil)) (jolt-hash-map _o$5890 _o$5891 _o$5892 _o$5893)))))))))) map-val))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "lookup-key" (letrec ((lookup-key (lambda (node nm) (let fnrec7154 ((node node) (nm nm)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((f (jolt-get node (keyword #f "fn"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get (jolt-nth args 0) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= nm (jolt-get (jolt-nth args 0) (keyword #f "name"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-get f (keyword #f "val")) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "get-callee?") f))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 2 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get (jolt-nth args 0) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= nm (jolt-get (jolt-nth args 0) (keyword #f "name"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth args 1)) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-get (jolt-nth args 1) (keyword #f "val")) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))) jolt-nil))))) lookup-key) (let* ((_o$7155 (keyword #f "private")) (_o$7156 #t) (_o$7157 (keyword #f "doc")) (_o$7158 "If node is a constant-keyword lookup of (:local nm) \x2014; either (:k nm) or\n (get nm :k) \x2014; return the keyword k; else nil.")) (jolt-hash-map _o$7155 _o$7156 _o$7157 _o$7158)))) + (def-var! "jolt.passes.inline" "lookup-key" (letrec ((lookup-key (lambda (node nm) (let fnrec5894 ((node node) (nm nm)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((f (jolt-get node (keyword #f "fn"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get (jolt-nth args 0) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= nm (jolt-get (jolt-nth args 0) (keyword #f "name"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-get f (keyword #f "val")) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "get-callee?") f))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 2 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get (jolt-nth args 0) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= nm (jolt-get (jolt-nth args 0) (keyword #f "name"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth args 1)) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-get (jolt-nth args 1) (keyword #f "val")) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))) jolt-nil))))) lookup-key))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "any-binding-named?" (letrec ((any-binding-named? (lambda (binds nm) (let fnrec7159 ((binds binds) (nm nm)) (let* ((i 0)) (let loop7160 ((i i)) (if (jolt-n< i (jolt-count binds)) (if (jolt= nm (jolt-nth (jolt-nth binds i) 0)) #t (loop7160 (jolt-inc i))) #f))))))) any-binding-named?) (let* ((_o$7161 (keyword #f "private")) (_o$7162 #t)) (jolt-hash-map _o$7161 _o$7162)))) + (def-var! "jolt.passes.inline" "any-binding-named?" (letrec ((any-binding-named? (lambda (binds nm) (let fnrec5895 ((binds binds) (nm nm)) (let* ((i 0)) (let loop5896 ((i i)) (if (< i (jolt-count binds)) (if (jolt= nm (jolt-nth (jolt-nth binds i) 0)) #t (loop5896 (jolt-inc i))) #f))))))) any-binding-named?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "any-name?" (letrec ((any-name? (lambda (names nm) (let fnrec7163 ((names names) (nm nm)) (let* ((i 0)) (let loop7164 ((i i)) (if (jolt-n< i (jolt-count names)) (if (jolt= nm (jolt-nth names i)) #t (loop7164 (jolt-inc i))) #f))))))) any-name?) (let* ((_o$7165 (keyword #f "private")) (_o$7166 #t)) (jolt-hash-map _o$7165 _o$7166)))) + (def-var! "jolt.passes.inline" "any-name?" (letrec ((any-name? (lambda (names nm) (let fnrec5897 ((names names) (nm nm)) (let* ((i 0)) (let loop5898 ((i i)) (if (< i (jolt-count names)) (if (jolt= nm (jolt-nth names i)) #t (loop5898 (jolt-inc i))) #f))))))) any-name?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "local-escapes?" (letrec ((local-escapes? (lambda (node nm) (let fnrec7167 ((node node) (nm nm)) (let* ((op (jolt-get node (keyword #f "op"))) (k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (let* ((args (jolt-get node (keyword #f "args")))) (if (jolt-n> (jolt-count args) 1) (let* ((i 1)) (let loop7168 ((i i)) (if (jolt-n< i (jolt-count args)) (if (jolt-truthy? (local-escapes? (jolt-nth args i) nm)) #t (loop7168 (jolt-inc i))) #f))) #f)) (if (jolt= op (keyword #f "local")) (jolt= nm (jolt-get node (keyword #f "name"))) (if (jolt= op (keyword #f "const")) #f (if (jolt= op (keyword #f "var")) #f (if (jolt= op (keyword #f "host")) #f (if (jolt= op (keyword #f "the-var")) #f (if (jolt= op (keyword #f "quote")) #f (if (jolt= op (keyword #f "if")) (let* ((or__26__auto (local-escapes? (jolt-get node (keyword #f "test")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (local-escapes? (jolt-get node (keyword #f "then")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (local-escapes? (jolt-get node (keyword #f "else")) nm))))) (if (jolt= op (keyword #f "do")) (let* ((or__26__auto (let* ((i 0) (ss (jolt-get node (keyword #f "statements")))) (let loop7169 ((i i) (ss ss)) (if (jolt-n< i (jolt-count ss)) (if (jolt-truthy? (local-escapes? (jolt-nth ss i) nm)) #t (loop7169 (jolt-inc i) ss)) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (local-escapes? (jolt-get node (keyword #f "ret")) nm))) (if (jolt= op (keyword #f "throw")) (local-escapes? (jolt-get node (keyword #f "expr")) nm) (if (jolt= op (keyword #f "invoke")) (let* ((or__26__auto (local-escapes? (jolt-get node (keyword #f "fn")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((i 0) (as (jolt-get node (keyword #f "args")))) (let loop7170 ((i i) (as as)) (if (jolt-n< i (jolt-count as)) (if (jolt-truthy? (local-escapes? (jolt-nth as i) nm)) #t (loop7170 (jolt-inc i) as)) #f))))) (if (jolt= op (keyword #f "vector")) (let* ((i 0) (xs (jolt-get node (keyword #f "items")))) (let loop7171 ((i i) (xs xs)) (if (jolt-n< i (jolt-count xs)) (if (jolt-truthy? (local-escapes? (jolt-nth xs i) nm)) #t (loop7171 (jolt-inc i) xs)) #f))) (if (jolt= op (keyword #f "set")) (let* ((i 0) (xs (jolt-get node (keyword #f "items")))) (let loop7172 ((i i) (xs xs)) (if (jolt-n< i (jolt-count xs)) (if (jolt-truthy? (local-escapes? (jolt-nth xs i) nm)) #t (loop7172 (jolt-inc i) xs)) #f))) (if (jolt= op (keyword #f "map")) (let* ((i 0) (ps (jolt-get node (keyword #f "pairs")))) (let loop7173 ((i i) (ps ps)) (if (jolt-n< i (jolt-count ps)) (if (jolt-truthy? (let* ((or__26__auto (local-escapes? (jolt-nth (jolt-nth ps i) 0) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (local-escapes? (jolt-nth (jolt-nth ps i) 1) nm)))) #t (loop7173 (jolt-inc i) ps)) #f))) (if (jolt= op (keyword #f "let")) (let* ((binds (jolt-get node (keyword #f "bindings")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") binds nm)) #t (let* ((or__26__auto (let* ((i 0)) (let loop7174 ((i i)) (if (jolt-n< i (jolt-count binds)) (if (jolt-truthy? (local-escapes? (jolt-nth (jolt-nth binds i) 1) nm)) #t (loop7174 (jolt-inc i))) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (local-escapes? (jolt-get node (keyword #f "body")) nm))))) (if (jolt= op (keyword #f "recur")) (let* ((i 0) (as (jolt-get node (keyword #f "args")))) (let loop7175 ((i i) (as as)) (if (jolt-n< i (jolt-count as)) (if (jolt-truthy? (local-escapes? (jolt-nth as i) nm)) #t (loop7175 (jolt-inc i) as)) #f))) (if (jolt= op (keyword #f "loop")) (let* ((binds (jolt-get node (keyword #f "bindings")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") binds nm)) #t (let* ((or__26__auto (let* ((i 0)) (let loop7176 ((i i)) (if (jolt-n< i (jolt-count binds)) (if (jolt-truthy? (local-escapes? (jolt-nth (jolt-nth binds i) 1) nm)) #t (loop7176 (jolt-inc i))) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (local-escapes? (jolt-get node (keyword #f "body")) nm))))) (if (jolt= op (keyword #f "fn")) (let* ((i 0) (ars (jolt-get node (keyword #f "arities")))) (let loop7177 ((i i) (ars ars)) (if (jolt-n< i (jolt-count ars)) (let* ((ar (jolt-nth ars i)) (ps (jolt-get ar (keyword #f "params")))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "any-name?") ps nm))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= nm (jolt-get ar (keyword #f "rest")))))) #t (if (jolt-truthy? (local-escapes? (jolt-get ar (keyword #f "body")) nm)) #t (loop7177 (jolt-inc i) ars)))) #f))) (if (jolt= op (keyword #f "try")) (let* ((or__26__auto (local-escapes? (jolt-get node (keyword #f "body")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (let* ((cb (jolt-get node (keyword #f "catch-body")))) (let* ((and__25__auto cb)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt= nm (jolt-get node (keyword #f "catch-sym")))))) (if (jolt-truthy? and__25__auto) (local-escapes? cb nm) and__25__auto)) and__25__auto))))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((f (jolt-get node (keyword #f "finally")))) (let* ((and__25__auto f)) (if (jolt-truthy? and__25__auto) (local-escapes? f nm) and__25__auto))))))) (if (jolt= op (keyword #f "def")) (local-escapes? (jolt-get node (keyword #f "init")) nm) (if (jolt-truthy? (keyword #f "else")) #t jolt-nil)))))))))))))))))))))))))) local-escapes?) (let* ((_o$7178 (keyword #f "private")) (_o$7179 #t) (_o$7180 (keyword #f "doc")) (_o$7181 "Does local nm escape in node \x2014; i.e. is it used anywhere other than as the\n subject of a constant-keyword lookup? Precise over straight-line expression\n ops; conservatively true for loop/fn/try/recur/def (and any rebinding of nm),\n so scalar replacement only fires where the whole use region is simple.\n\n Stays an explicit per-op walk (not the shared reduce-ir-children fold): its\n default is conservatively TRUE, and the lookup-subject and rebinding cases\n inspect node shape beyond child purity \x2014; folding an unhandled op over its\n children would under-report escape and is unsound for scalar replacement.")) (jolt-hash-map _o$7178 _o$7179 _o$7180 _o$7181)))) + (def-var! "jolt.passes.inline" "local-escapes?" (letrec ((local-escapes? (lambda (node nm) (let fnrec5899 ((node node) (nm nm)) (let* ((op (jolt-get node (keyword #f "op"))) (k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (let* ((args (jolt-get node (keyword #f "args")))) (if (> (jolt-count args) 1) (let* ((i 1)) (let loop5900 ((i i)) (if (< i (jolt-count args)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth args i) nm)) #t (loop5900 (jolt-inc i))) #f))) #f)) (if (jolt= op (keyword #f "local")) (jolt= nm (jolt-get node (keyword #f "name"))) (if (jolt= op (keyword #f "const")) #f (if (jolt= op (keyword #f "var")) #f (if (jolt= op (keyword #f "host")) #f (if (jolt= op (keyword #f "the-var")) #f (if (jolt= op (keyword #f "quote")) #f (if (jolt= op (keyword #f "if")) (let* ((or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "test")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "then")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "else")) nm))))) (if (jolt= op (keyword #f "do")) (let* ((or__26__auto (let* ((i 0) (ss (jolt-get node (keyword #f "statements")))) (let loop5901 ((i i) (ss ss)) (if (< i (jolt-count ss)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth ss i) nm)) #t (loop5901 (jolt-inc i) ss)) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "ret")) nm))) (if (jolt= op (keyword #f "throw")) (jolt-invoke local-escapes? (jolt-get node (keyword #f "expr")) nm) (if (jolt= op (keyword #f "invoke")) (let* ((or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "fn")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((i 0) (as (jolt-get node (keyword #f "args")))) (let loop5902 ((i i) (as as)) (if (< i (jolt-count as)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth as i) nm)) #t (loop5902 (jolt-inc i) as)) #f))))) (if (jolt= op (keyword #f "vector")) (let* ((i 0) (xs (jolt-get node (keyword #f "items")))) (let loop5903 ((i i) (xs xs)) (if (< i (jolt-count xs)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth xs i) nm)) #t (loop5903 (jolt-inc i) xs)) #f))) (if (jolt= op (keyword #f "set")) (let* ((i 0) (xs (jolt-get node (keyword #f "items")))) (let loop5904 ((i i) (xs xs)) (if (< i (jolt-count xs)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth xs i) nm)) #t (loop5904 (jolt-inc i) xs)) #f))) (if (jolt= op (keyword #f "map")) (let* ((i 0) (ps (jolt-get node (keyword #f "pairs")))) (let loop5905 ((i i) (ps ps)) (if (< i (jolt-count ps)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke local-escapes? (jolt-nth (jolt-nth ps i) 0) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke local-escapes? (jolt-nth (jolt-nth ps i) 1) nm)))) #t (loop5905 (jolt-inc i) ps)) #f))) (if (jolt= op (keyword #f "let")) (let* ((binds (jolt-get node (keyword #f "bindings")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") binds nm)) #t (let* ((or__26__auto (let* ((i 0)) (let loop5906 ((i i)) (if (< i (jolt-count binds)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth (jolt-nth binds i) 1) nm)) #t (loop5906 (jolt-inc i))) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "body")) nm))))) (if (jolt= op (keyword #f "recur")) (let* ((i 0) (as (jolt-get node (keyword #f "args")))) (let loop5907 ((i i) (as as)) (if (< i (jolt-count as)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth as i) nm)) #t (loop5907 (jolt-inc i) as)) #f))) (if (jolt= op (keyword #f "loop")) (let* ((binds (jolt-get node (keyword #f "bindings")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") binds nm)) #t (let* ((or__26__auto (let* ((i 0)) (let loop5908 ((i i)) (if (< i (jolt-count binds)) (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-nth (jolt-nth binds i) 1) nm)) #t (loop5908 (jolt-inc i))) #f))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "body")) nm))))) (if (jolt= op (keyword #f "fn")) (let* ((i 0) (ars (jolt-get node (keyword #f "arities")))) (let loop5909 ((i i) (ars ars)) (if (< i (jolt-count ars)) (let* ((ar (jolt-nth ars i)) (ps (jolt-get ar (keyword #f "params")))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.inline" "any-name?") ps nm))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= nm (jolt-get ar (keyword #f "rest")))))) #t (if (jolt-truthy? (jolt-invoke local-escapes? (jolt-get ar (keyword #f "body")) nm)) #t (loop5909 (jolt-inc i) ars)))) #f))) (if (jolt= op (keyword #f "try")) (let* ((or__26__auto (jolt-invoke local-escapes? (jolt-get node (keyword #f "body")) nm))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (let* ((cb (jolt-get node (keyword #f "catch-body")))) (let* ((and__25__auto cb)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt= nm (jolt-get node (keyword #f "catch-sym")))))) (if (jolt-truthy? and__25__auto) (jolt-invoke local-escapes? cb nm) and__25__auto)) and__25__auto))))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((f (jolt-get node (keyword #f "finally")))) (let* ((and__25__auto f)) (if (jolt-truthy? and__25__auto) (jolt-invoke local-escapes? f nm) and__25__auto))))))) (if (jolt= op (keyword #f "def")) (jolt-invoke local-escapes? (jolt-get node (keyword #f "init")) nm) (if (jolt-truthy? (keyword #f "else")) #t jolt-nil)))))))))))))))))))))))))) local-escapes?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "ctor-shape" (letrec ((ctor-shape (lambda (node) (let fnrec7182 ((node node)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((f (jolt-get node (keyword #f "fn")))) (if (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))) (let* ((rs (let* ((_a$7187 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "rec-shapes"))) (_a$7188 (let* ((_a$7183 (var-deref "clojure.core" "str")) (_a$7184 (jolt-get f (keyword #f "ns"))) (_a$7185 "/") (_a$7186 (jolt-get f (keyword #f "name")))) (jolt-invoke _a$7183 _a$7184 _a$7185 _a$7186)))) (jolt-get _a$7187 _a$7188)))) (if (jolt-truthy? (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (let* ((_a$7189 (jolt-count (jolt-get rs (keyword #f "fields")))) (_a$7190 (jolt-count (jolt-get node (keyword #f "args"))))) (jolt= _a$7189 _a$7190)) and__25__auto))) rs jolt-nil)) jolt-nil)) jolt-nil))))) ctor-shape) (let* ((_o$7191 (keyword #f "private")) (_o$7192 #t) (_o$7193 (keyword #f "doc")) (_o$7194 "If node is a record-constructor :invoke (its :fn a :var whose ns/name is a\n registered ctor key, with arg count matching the declared field count), return\n that record's shape entry; else nil.")) (jolt-hash-map _o$7191 _o$7192 _o$7193 _o$7194)))) + (def-var! "jolt.passes.inline" "ctor-shape" (letrec ((ctor-shape (lambda (node) (let fnrec5910 ((node node)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((f (jolt-get node (keyword #f "fn")))) (if (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))) (let* ((rs (let* ((_a$5915 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "rec-shapes"))) (_a$5916 (let* ((_a$5911 (var-deref "clojure.core" "str")) (_a$5912 (jolt-get f (keyword #f "ns"))) (_a$5913 "/") (_a$5914 (jolt-get f (keyword #f "name")))) (jolt-invoke _a$5911 _a$5912 _a$5913 _a$5914)))) (jolt-get _a$5915 _a$5916)))) (if (jolt-truthy? (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (let* ((_a$5917 (jolt-count (jolt-get rs (keyword #f "fields")))) (_a$5918 (jolt-count (jolt-get node (keyword #f "args"))))) (jolt= _a$5917 _a$5918)) and__25__auto))) rs jolt-nil)) jolt-nil)) jolt-nil))))) ctor-shape))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "ctor-all-args-pure?" (letrec ((ctor-all-args-pure? (lambda (node) (let fnrec7195 ((node node)) (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.inline" "pure?") (jolt-get node (keyword #f "args"))))))) ctor-all-args-pure?) (let* ((_o$7196 (keyword #f "private")) (_o$7197 #t)) (jolt-hash-map _o$7196 _o$7197)))) + (def-var! "jolt.passes.inline" "ctor-all-args-pure?" (letrec ((ctor-all-args-pure? (lambda (node) (let fnrec5919 ((node node)) (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.inline" "pure?") (jolt-get node (keyword #f "args"))))))) ctor-all-args-pure?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "field-index" (letrec ((field-index (lambda (fields k) (let fnrec7198 ((fields fields) (k k)) (let* ((n (jolt-count fields))) (let* ((i 0)) (let loop7199 ((i i)) (if (jolt-n< i n) (if (jolt= (jolt-nth fields i) k) i (loop7199 (jolt-inc i))) jolt-nil)))))))) field-index) (let* ((_o$7200 (keyword #f "private")) (_o$7201 #t) (_o$7202 (keyword #f "doc")) (_o$7203 "Index of scalar key k in the declared field tuple fields, or nil.")) (jolt-hash-map _o$7200 _o$7201 _o$7202 _o$7203)))) + (def-var! "jolt.passes.inline" "field-index" (letrec ((field-index (lambda (fields k) (let fnrec5920 ((fields fields) (k k)) (let* ((n (jolt-count fields))) (let* ((i 0)) (let loop5921 ((i i)) (if (< i n) (if (jolt= (jolt-nth fields i) k) i (loop5921 (jolt-inc i))) jolt-nil)))))))) field-index))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "ctor-val" (letrec ((ctor-val (lambda (ctor rs k) (let fnrec7204 ((ctor ctor) (rs rs) (k k)) (let* ((_a$7205 (jolt-get ctor (keyword #f "args"))) (_a$7206 (jolt-invoke (var-deref "jolt.passes.inline" "field-index") (jolt-get rs (keyword #f "fields")) k))) (jolt-nth _a$7205 _a$7206)))))) ctor-val) (let* ((_o$7207 (keyword #f "private")) (_o$7208 #t) (_o$7209 (keyword #f "doc")) (_o$7210 "The positional arg IR at declared field k of record ctor node (shape rs). Only\n called for a key known to be a field, so the index is always present.")) (jolt-hash-map _o$7207 _o$7208 _o$7209 _o$7210)))) + (def-var! "jolt.passes.inline" "ctor-val" (letrec ((ctor-val (lambda (ctor rs k) (let fnrec5922 ((ctor ctor) (rs rs) (k k)) (let* ((_a$5923 (jolt-get ctor (keyword #f "args"))) (_a$5924 (jolt-invoke (var-deref "jolt.passes.inline" "field-index") (jolt-get rs (keyword #f "fields")) k))) (jolt-nth _a$5923 _a$5924)))))) ctor-val))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "collect-keys!" (letrec ((collect-keys! (lambda (node nm acc) (let fnrec7211 ((node node) (nm nm) (acc acc)) (let* ((k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (jolt-invoke (var-deref "clojure.core" "swap!") acc jolt-conj k) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec7212 ((c c)) (begin (collect-keys! c nm acc) c))) node))))))) collect-keys!) (let* ((_o$7213 (keyword #f "private")) (_o$7214 #t) (_o$7215 (keyword #f "doc")) (_o$7216 "Accumulate (into atom acc) every constant-keyword lookup key applied to local\n nm in node. The caller has proven (via local-escapes?) that nm appears only as\n a lookup subject and is never rebound, so a uniform recursion suffices: at a\n lookup of nm we record the key and stop (its subject is nm itself); elsewhere\n we recurse into children.")) (jolt-hash-map _o$7213 _o$7214 _o$7215 _o$7216)))) + (def-var! "jolt.passes.inline" "collect-keys!" (letrec ((collect-keys! (lambda (node nm acc) (let fnrec5925 ((node node) (nm nm) (acc acc)) (let* ((k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (jolt-invoke (var-deref "clojure.core" "swap!") acc jolt-conj k) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5926 ((c c)) (begin (jolt-invoke collect-keys! c nm acc) c))) node))))))) collect-keys!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "lookups-all-fields?" (letrec ((lookups-all-fields? (lambda (nodes nm fields) (let fnrec7217 ((nodes nodes) (nm nm) (fields fields)) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (node) (let fnrec7218 ((node node)) (let* ((acc (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set)))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "collect-keys!") node nm acc) (let* ((_a$7220 (var-deref "clojure.core" "every?")) (_a$7221 (lambda (k) (let fnrec7219 ((k k)) (jolt-invoke (var-deref "jolt.passes.inline" "field-index") fields k)))) (_a$7222 (jolt-invoke (var-deref "clojure.core" "deref") acc))) (jolt-invoke _a$7220 _a$7221 _a$7222)))))) nodes))))) lookups-all-fields?) (let* ((_o$7223 (keyword #f "private")) (_o$7224 #t) (_o$7225 (keyword #f "doc")) (_o$7226 "True if every lookup of nm across nodes uses a declared field in fields \x2014; the\n record-only guard that keeps a :jolt/deftype/unknown-key read (not a positional\n arg) from being folded to the wrong value.")) (jolt-hash-map _o$7223 _o$7224 _o$7225 _o$7226)))) + (def-var! "jolt.passes.inline" "lookups-all-fields?" (letrec ((lookups-all-fields? (lambda (nodes nm fields) (let fnrec5927 ((nodes nodes) (nm nm) (fields fields)) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (node) (let fnrec5928 ((node node)) (let* ((acc (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set)))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "collect-keys!") node nm acc) (let* ((_a$5930 (var-deref "clojure.core" "every?")) (_a$5931 (lambda (k) (let fnrec5929 ((k k)) (jolt-invoke (var-deref "jolt.passes.inline" "field-index") fields k)))) (_a$5932 (jolt-invoke (var-deref "clojure.core" "deref") acc))) (jolt-invoke _a$5930 _a$5931 _a$5932)))))) nodes))))) lookups-all-fields?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "src-val" (letrec ((src-val (lambda (src k) (let fnrec7227 ((src src) (k k)) (if (jolt= (keyword #f "map") (jolt-get src (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.inline" "map-val") src k) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-val") src (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") src) k)))))) src-val) (let* ((_o$7228 (keyword #f "private")) (_o$7229 #t) (_o$7230 (keyword #f "doc")) (_o$7231 "Field value at k from a foldable struct source \x2014; a const-key map (absent key\n -> nil, struct-map semantics) or a record ctor (k is always a declared field\n here, guaranteed by lookups-all-fields?).")) (jolt-hash-map _o$7228 _o$7229 _o$7230 _o$7231)))) + (def-var! "jolt.passes.inline" "src-val" (letrec ((src-val (lambda (src k) (let fnrec5933 ((src src) (k k)) (if (jolt= (keyword #f "map") (jolt-get src (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.inline" "map-val") src k) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-val") src (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") src) k)))))) src-val))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "subst-lookup" (letrec ((subst-lookup (lambda (node nm src) (let fnrec7232 ((node node) (nm nm) (src src)) (let* ((k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (jolt-invoke (var-deref "jolt.passes.inline" "src-val") src k) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec7233 ((c c)) (subst-lookup c nm src))) node))))))) subst-lookup) (let* ((_o$7234 (keyword #f "private")) (_o$7235 #t) (_o$7236 (keyword #f "doc")) (_o$7237 "Replace every (:k nm)/(get nm :k) in node with the source value at k. The\n caller guarantees (via local-escapes?) that nm is never rebound here and\n appears only as a lookup subject, so no shadowing logic is needed.")) (jolt-hash-map _o$7234 _o$7235 _o$7236 _o$7237)))) + (def-var! "jolt.passes.inline" "subst-lookup" (letrec ((subst-lookup (lambda (node nm src) (let fnrec5934 ((node node) (nm nm) (src src)) (let* ((k (jolt-invoke (var-deref "jolt.passes.inline" "lookup-key") node nm))) (if (jolt-truthy? k) (jolt-invoke (var-deref "jolt.passes.inline" "src-val") src k) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") (lambda (c) (let fnrec5935 ((c c)) (jolt-invoke subst-lookup c nm src))) node))))))) subst-lookup))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "fold-kw-literal" (letrec ((fold-kw-literal (lambda (node) (let fnrec7238 ((node node)) (let* ((f (jolt-get node (keyword #f "fn"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count args)) and__25__auto))) (let* ((m (jolt-nth args 0)) (k (jolt-get f (keyword #f "val")))) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "map") (jolt-get m (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "const-key-map?") m))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "all-vals-pure?") m) and__25__auto)) and__25__auto))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (jolt-invoke (var-deref "jolt.passes.inline" "map-val") m k)) (let* ((rs (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") m))) (if (jolt-truthy? (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "ctor-all-args-pure?") m))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "field-index") (jolt-get rs (keyword #f "fields")) k) and__25__auto)) and__25__auto))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-val") m rs k)) node)))) node)))))) fold-kw-literal) (let* ((_o$7239 (keyword #f "private")) (_o$7240 #t) (_o$7241 (keyword #f "doc")) (_o$7242 "(a) (:k ) -> the value at k. is a const-key pure map\n ((:k {:k a ..}) -> a) or a pure record ctor ((:k (->Rec a ..)) -> the arg for\n field k). Siblings are duplicated/discarded, so all must be pure; a record\n lookup folds only for a declared field.")) (jolt-hash-map _o$7239 _o$7240 _o$7241 _o$7242)))) + (def-var! "jolt.passes.inline" "fold-kw-literal" (letrec ((fold-kw-literal (lambda (node) (let fnrec5936 ((node node)) (let* ((f (jolt-get node (keyword #f "fn"))) (args (jolt-get node (keyword #f "args")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") f))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count args)) and__25__auto))) (let* ((m (jolt-nth args 0)) (k (jolt-get f (keyword #f "val")))) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "map") (jolt-get m (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "const-key-map?") m))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "all-vals-pure?") m) and__25__auto)) and__25__auto))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (jolt-invoke (var-deref "jolt.passes.inline" "map-val") m k)) (let* ((rs (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") m))) (if (jolt-truthy? (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "ctor-all-args-pure?") m))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "field-index") (jolt-get rs (keyword #f "fields")) k) and__25__auto)) and__25__auto))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-val") m rs k)) node)))) node)))))) fold-kw-literal))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "elim-let-structs" (letrec ((elim-let-structs (lambda (node) (let fnrec7243 ((node node)) (let* ((binds (jolt-get node (keyword #f "bindings"))) (n (jolt-count binds)) (body (jolt-get node (keyword #f "body")))) (let* ((i 0)) (let loop7244 ((i i)) (if (jolt-n< i n) (let* ((b (jolt-nth binds i)) (nm (jolt-nth b 0)) (init (jolt-nth b 1)) (ismap (let* ((and__25__auto (jolt= (keyword #f "map") (jolt-get init (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "const-key-map?") init))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "all-vals-pure?") init) and__25__auto)) and__25__auto))) (rs (if (jolt-not ismap) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") init) jolt-nil)) (isrec (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-all-args-pure?") init) and__25__auto)))) (if (jolt-truthy? (let* ((and__25__auto (let* ((or__26__auto ismap)) (if (jolt-truthy? or__26__auto) or__26__auto isrec)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n) nm)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (let* ((j (jolt-inc i))) (let loop7245 ((j j)) (if (jolt-n< j n) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "local-escapes?") (jolt-nth (jolt-nth binds j) 1) nm)) #t (loop7245 (jolt-inc j))) #f)))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "local-escapes?") body nm)))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto ismap)) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((_a$7250 (var-deref "jolt.passes.inline" "lookups-all-fields?")) (_a$7251 (jolt-conj (let* ((_a$7247 (var-deref "clojure.core" "mapv")) (_a$7248 (lambda (bb) (let fnrec7246 ((bb bb)) (jolt-nth bb 1)))) (_a$7249 (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n))) (jolt-invoke _a$7247 _a$7248 _a$7249)) body)) (_a$7252 nm) (_a$7253 (jolt-get rs (keyword #f "fields")))) (jolt-invoke _a$7250 _a$7251 _a$7252 _a$7253)))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((head (jolt-invoke (var-deref "clojure.core" "subvec") binds 0 i)) (tail (let* ((_a$7257 (var-deref "clojure.core" "mapv")) (_a$7258 (lambda (bb) (let fnrec7254 ((bb bb)) (let* ((_o$7255 (jolt-nth bb 0)) (_o$7256 (jolt-invoke (var-deref "jolt.passes.inline" "subst-lookup") (jolt-nth bb 1) nm init))) (jolt-vector _o$7255 _o$7256))))) (_a$7259 (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n))) (jolt-invoke _a$7257 _a$7258 _a$7259))) (newbinds (jolt-reduce jolt-conj head tail)) (newbody (jolt-invoke (var-deref "jolt.passes.inline" "subst-lookup") body nm init))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (if (jolt= 0 (jolt-count newbinds)) newbody (jolt-assoc node (keyword #f "bindings") newbinds (keyword #f "body") newbody)))) (loop7244 (jolt-inc i)))) node)))))))) elim-let-structs) (let* ((_o$7260 (keyword #f "private")) (_o$7261 #t) (_o$7262 (keyword #f "doc")) (_o$7263 "(b) Drop the first non-escaping let binding whose init is a foldable struct\n source \x2014; a pure const-key map literal or a pure record ctor \x2014; substituting its\n field reads into the remaining bindings and body. Fixpoint re-runs us for the\n rest, so one elimination per call keeps it simple. For a record every lookup\n of the binding must hit a declared field, else we keep the allocation.")) (jolt-hash-map _o$7260 _o$7261 _o$7262 _o$7263)))) + (def-var! "jolt.passes.inline" "elim-let-structs" (letrec ((elim-let-structs (lambda (node) (let fnrec5937 ((node node)) (let* ((binds (jolt-get node (keyword #f "bindings"))) (n (jolt-count binds)) (body (jolt-get node (keyword #f "body")))) (let* ((i 0)) (let loop5938 ((i i)) (if (< i n) (let* ((b (jolt-nth binds i)) (nm (jolt-nth b 0)) (init (jolt-nth b 1)) (ismap (let* ((and__25__auto (jolt= (keyword #f "map") (jolt-get init (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.inline" "const-key-map?") init))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "all-vals-pure?") init) and__25__auto)) and__25__auto))) (rs (if (jolt-not ismap) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-shape") init) jolt-nil)) (isrec (let* ((and__25__auto rs)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.inline" "ctor-all-args-pure?") init) and__25__auto)))) (if (jolt-truthy? (let* ((and__25__auto (let* ((or__26__auto ismap)) (if (jolt-truthy? or__26__auto) or__26__auto isrec)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "any-binding-named?") (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n) nm)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (let* ((j (jolt-inc i))) (let loop5939 ((j j)) (if (< j n) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.inline" "local-escapes?") (jolt-nth (jolt-nth binds j) 1) nm)) #t (loop5939 (jolt-inc j))) #f)))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "jolt.passes.inline" "local-escapes?") body nm)))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto ismap)) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((_a$5944 (var-deref "jolt.passes.inline" "lookups-all-fields?")) (_a$5945 (jolt-conj (let* ((_a$5941 (var-deref "clojure.core" "mapv")) (_a$5942 (lambda (bb) (let fnrec5940 ((bb bb)) (jolt-nth bb 1)))) (_a$5943 (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n))) (jolt-invoke _a$5941 _a$5942 _a$5943)) body)) (_a$5946 nm) (_a$5947 (jolt-get rs (keyword #f "fields")))) (jolt-invoke _a$5944 _a$5945 _a$5946 _a$5947)))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((head (jolt-invoke (var-deref "clojure.core" "subvec") binds 0 i)) (tail (let* ((_a$5951 (var-deref "clojure.core" "mapv")) (_a$5952 (lambda (bb) (let fnrec5948 ((bb bb)) (let* ((_o$5949 (jolt-nth bb 0)) (_o$5950 (jolt-invoke (var-deref "jolt.passes.inline" "subst-lookup") (jolt-nth bb 1) nm init))) (jolt-vector _o$5949 _o$5950))))) (_a$5953 (jolt-invoke (var-deref "clojure.core" "subvec") binds (jolt-inc i) n))) (jolt-invoke _a$5951 _a$5952 _a$5953))) (newbinds (jolt-reduce jolt-conj head tail)) (newbody (jolt-invoke (var-deref "jolt.passes.inline" "subst-lookup") body nm init))) (begin (jolt-invoke (var-deref "jolt.passes.inline" "mark!")) (if (jolt= 0 (jolt-count newbinds)) newbody (jolt-assoc node (keyword #f "bindings") newbinds (keyword #f "body") newbody)))) (loop5938 (jolt-inc i)))) node)))))))) elim-let-structs))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.inline" "scalar-replace" (letrec ((scalar-replace (lambda (node) (let fnrec7264 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.inline" "fold-kw-literal") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node)) (if (jolt= op (keyword #f "let")) (jolt-invoke (var-deref "jolt.passes.inline" "elim-let-structs") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node) jolt-nil)))))))) scalar-replace) (let* ((_o$7265 (keyword #f "doc")) (_o$7266 "Bottom-up: scalar-replace children, then apply (a) at invokes / (b) at lets.")) (jolt-hash-map _o$7265 _o$7266)))) + (def-var! "jolt.passes.inline" "scalar-replace" (letrec ((scalar-replace (lambda (node) (let fnrec5954 ((node node)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.inline" "fold-kw-literal") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node)) (if (jolt= op (keyword #f "let")) (jolt-invoke (var-deref "jolt.passes.inline" "elim-let-structs") (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.ir" "map-ir-children") scalar-replace node) jolt-nil)))))))) scalar-replace))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "velem" (letrec ((velem (lambda (t) (let fnrec6492 ((t t)) (jolt-get t (keyword #f "vec")))))) velem))) + (def-var! "jolt.passes.types.lattice" "velem" (letrec ((velem (lambda (t) (let fnrec5355 ((t t)) (jolt-get t (keyword #f "vec")))))) velem))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "selem" (letrec ((selem (lambda (t) (let fnrec6493 ((t t)) (jolt-get t (keyword #f "set")))))) selem))) + (def-var! "jolt.passes.types.lattice" "selem" (letrec ((selem (lambda (t) (let fnrec5356 ((t t)) (jolt-get t (keyword #f "set")))))) selem))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "sfields" (letrec ((sfields (lambda (t) (let fnrec6494 ((t t)) (jolt-get t (keyword #f "struct")))))) sfields))) + (def-var! "jolt.passes.types.lattice" "sfields" (letrec ((sfields (lambda (t) (let fnrec5357 ((t t)) (jolt-get t (keyword #f "struct")))))) sfields))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "vec-type?" (letrec ((vec-type? (lambda (t) (let fnrec6495 ((t t)) (jolt-some? (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") t)))))) vec-type?))) + (def-var! "jolt.passes.types.lattice" "vec-type?" (letrec ((vec-type? (lambda (t) (let fnrec5358 ((t t)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") t)))))) vec-type?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "set-type?" (letrec ((set-type? (lambda (t) (let fnrec6496 ((t t)) (jolt-some? (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") t)))))) set-type?))) + (def-var! "jolt.passes.types.lattice" "set-type?" (letrec ((set-type? (lambda (t) (let fnrec5359 ((t t)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") t)))))) set-type?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "struct-type?" (letrec ((struct-type? (lambda (t) (let fnrec6497 ((t t)) (jolt-some? (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t)))))) struct-type?))) + (def-var! "jolt.passes.types.lattice" "struct-type?" (letrec ((struct-type? (lambda (t) (let fnrec5360 ((t t)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t)))))) struct-type?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "mk-vec" (letrec ((mk-vec (lambda (t) (let fnrec6498 ((t t)) (let* ((_o$6499 (keyword #f "vec")) (_o$6500 (if (jolt-truthy? t) t (keyword #f "any")))) (jolt-hash-map _o$6499 _o$6500)))))) mk-vec))) + (def-var! "jolt.passes.types.lattice" "mk-vec" (letrec ((mk-vec (lambda (t) (let fnrec5361 ((t t)) (let* ((_o$5362 (keyword #f "vec")) (_o$5363 (if (jolt-truthy? t) t (keyword #f "any")))) (jolt-hash-map _o$5362 _o$5363)))))) mk-vec))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "mk-set" (letrec ((mk-set (lambda (t) (let fnrec6501 ((t t)) (let* ((_o$6502 (keyword #f "set")) (_o$6503 (if (jolt-truthy? t) t (keyword #f "any")))) (jolt-hash-map _o$6502 _o$6503)))))) mk-set))) + (def-var! "jolt.passes.types.lattice" "mk-set" (letrec ((mk-set (lambda (t) (let fnrec5364 ((t t)) (let* ((_o$5365 (keyword #f "set")) (_o$5366 (if (jolt-truthy? t) t (keyword #f "any")))) (jolt-hash-map _o$5365 _o$5366)))))) mk-set))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "mk-struct" (letrec ((mk-struct (lambda (fs) (let fnrec6504 ((fs fs)) (let* ((_o$6505 (keyword #f "struct")) (_o$6506 fs)) (jolt-hash-map _o$6505 _o$6506)))))) mk-struct))) + (def-var! "jolt.passes.types.lattice" "mk-struct" (letrec ((mk-struct (lambda (fs) (let fnrec5367 ((fs fs)) (let* ((_o$5368 (keyword #f "struct")) (_o$5369 fs)) (jolt-hash-map _o$5368 _o$5369)))))) mk-struct))) (guard (e (#t #f)) (def-var! "jolt.passes.types.lattice" "union-cap" 4)) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "scalar-t?" (letrec ((scalar-t? (lambda (t) (let fnrec6507 ((t t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "truthy")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "phm")))))))))))))) scalar-t?))) + (def-var! "jolt.passes.types.lattice" "scalar-t?" (letrec ((scalar-t? (lambda (t) (let fnrec5370 ((t t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "truthy")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "phm")))))))))))))) scalar-t?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "union-type?" (letrec ((union-type? (lambda (t) (let fnrec6508 ((t t)) (jolt-some? (jolt-get t (keyword #f "union"))))))) union-type?))) + (def-var! "jolt.passes.types.lattice" "union-type?" (letrec ((union-type? (lambda (t) (let fnrec5371 ((t t)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-get t (keyword #f "union"))))))) union-type?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "umembers" (letrec ((umembers (lambda (t) (let fnrec6509 ((t t)) (jolt-get t (keyword #f "union")))))) umembers))) + (def-var! "jolt.passes.types.lattice" "umembers" (letrec ((umembers (lambda (t) (let fnrec5372 ((t t)) (jolt-get t (keyword #f "union")))))) umembers))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.lattice" "union-of" (letrec ((union-of (lambda (ts) (let fnrec6510 ((ts ts)) (let* ((flat (let* ((_a$6512 (lambda (acc t) (let fnrec6511 ((acc acc) (t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-reduce jolt-conj acc (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (jolt-conj acc t))))) (_a$6513 (jolt-hash-set)) (_a$6514 ts)) (jolt-reduce _a$6512 _a$6513 _a$6514)))) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.types.lattice" "scalar-t?") flat)) (keyword #f "any") (if (jolt= 0 (jolt-count flat)) (keyword #f "any") (if (jolt= 1 (jolt-count flat)) (jolt-first flat) (if (jolt-n> (jolt-count flat) (var-deref "jolt.passes.types.lattice" "union-cap")) (keyword #f "any") (if (jolt-truthy? (keyword #f "else")) (let* ((_o$6515 (keyword #f "union")) (_o$6516 flat)) (jolt-hash-map _o$6515 _o$6516)) jolt-nil)))))))))) union-of) (let* ((_o$6517 (keyword #f "doc")) (_o$6518 "Normalize a seq of member types into a lattice value: flatten nested unions,\n keep only scalars (any non-scalar member collapses the whole thing to :any,\n the conservative top), then return the lone member if one, {:union #{...}}\n for 2..cap distinct scalars, or :any past the cap.")) (jolt-hash-map _o$6517 _o$6518)))) + (def-var! "jolt.passes.types.lattice" "union-of" (letrec ((union-of (lambda (ts) (let fnrec5373 ((ts ts)) (let* ((flat (let* ((_a$5375 (lambda (acc t) (let fnrec5374 ((acc acc) (t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-reduce jolt-conj acc (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (jolt-conj acc t))))) (_a$5376 (jolt-hash-set)) (_a$5377 ts)) (jolt-reduce _a$5375 _a$5376 _a$5377)))) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "jolt.passes.types.lattice" "scalar-t?") flat)) (keyword #f "any") (if (jolt= 0 (jolt-count flat)) (keyword #f "any") (if (jolt= 1 (jolt-count flat)) (jolt-first flat) (if (> (jolt-count flat) (var-deref "jolt.passes.types.lattice" "union-cap")) (keyword #f "any") (if (jolt-truthy? (keyword #f "else")) (let* ((_o$5378 (keyword #f "union")) (_o$5379 flat)) (jolt-hash-map _o$5378 _o$5379)) jolt-nil)))))))))) union-of))) (guard (e (#t #f)) (declare-var! "jolt.passes.types.lattice" "join-t")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.lattice" "merge-fields" (letrec ((merge-fields (lambda (fa fb) (let fnrec6519 ((fa fa) (fb fb)) (let* ((m1 (let* ((_a$6524 (lambda (m k) (let fnrec6520 ((m m) (k k)) (jolt-assoc m k (let* ((_a$6521 (var-deref "jolt.passes.types.lattice" "join-t")) (_a$6522 (jolt-get fa k (keyword #f "any"))) (_a$6523 (jolt-get fb k (keyword #f "any")))) (jolt-invoke _a$6521 _a$6522 _a$6523)))))) (_a$6525 (jolt-hash-map)) (_a$6526 (jolt-keys fa))) (jolt-reduce _a$6524 _a$6525 _a$6526)))) (let* ((_a$6531 (lambda (m k) (let fnrec6527 ((m m) (k k)) (if (jolt-truthy? (jolt-get m k)) m (jolt-assoc m k (let* ((_a$6528 (var-deref "jolt.passes.types.lattice" "join-t")) (_a$6529 (jolt-get fa k (keyword #f "any"))) (_a$6530 (jolt-get fb k (keyword #f "any")))) (jolt-invoke _a$6528 _a$6529 _a$6530))))))) (_a$6532 m1) (_a$6533 (jolt-keys fb))) (jolt-reduce _a$6531 _a$6532 _a$6533))))))) merge-fields) (let* ((_o$6534 (keyword #f "doc")) (_o$6535 "Per-field join of two field maps (a key in only one side joins with :any).")) (jolt-hash-map _o$6534 _o$6535)))) + (def-var! "jolt.passes.types.lattice" "merge-fields" (letrec ((merge-fields (lambda (fa fb) (let fnrec5380 ((fa fa) (fb fb)) (let* ((m1 (let* ((_a$5385 (lambda (m k) (let fnrec5381 ((m m) (k k)) (jolt-assoc m k (let* ((_a$5382 (var-deref "jolt.passes.types.lattice" "join-t")) (_a$5383 (jolt-get fa k (keyword #f "any"))) (_a$5384 (jolt-get fb k (keyword #f "any")))) (jolt-invoke _a$5382 _a$5383 _a$5384)))))) (_a$5386 (jolt-hash-map)) (_a$5387 (jolt-keys fa))) (jolt-reduce _a$5385 _a$5386 _a$5387)))) (let* ((_a$5392 (lambda (m k) (let fnrec5388 ((m m) (k k)) (if (jolt-truthy? (jolt-get m k)) m (jolt-assoc m k (let* ((_a$5389 (var-deref "jolt.passes.types.lattice" "join-t")) (_a$5390 (jolt-get fa k (keyword #f "any"))) (_a$5391 (jolt-get fb k (keyword #f "any")))) (jolt-invoke _a$5389 _a$5390 _a$5391))))))) (_a$5393 m1) (_a$5394 (jolt-keys fb))) (jolt-reduce _a$5392 _a$5393 _a$5394))))))) merge-fields))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "join-t" (letrec ((join-t (lambda (a b) (let fnrec6536 ((a a) (b b)) (if (jolt= a b) a (if (jolt-nil? a) b (if (jolt-nil? b) a (if (let* ((or__26__auto (jolt= a (keyword #f "nil")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= b (keyword #f "nil")))) (let* ((o (if (jolt= a (keyword #f "nil")) b a))) (if (jolt= o (keyword #f "nil")) (keyword #f "nil") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") o)) (jolt-assoc o (keyword #f "nilable") #t) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil)))) (if (let* ((or__26__auto (jolt= a (keyword #f "double")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= b (keyword #f "double")))) (let* ((_a$6537 (if (jolt= a (keyword #f "double")) (keyword #f "num") a)) (_a$6538 (if (jolt= b (keyword #f "double")) (keyword #f "num") b))) (join-t _a$6537 _a$6538)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") b) and__25__auto))) (let* ((merged (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$6539 (var-deref "jolt.passes.types.lattice" "merge-fields")) (_a$6540 (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") a)) (_a$6541 (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") b))) (jolt-invoke _a$6539 _a$6540 _a$6541)))) (merged (if (jolt-truthy? (let* ((and__25__auto (jolt-get a (keyword #f "shape")))) (if (jolt-truthy? and__25__auto) (let* ((_a$6542 (jolt-get a (keyword #f "shape"))) (_a$6543 (jolt-get b (keyword #f "shape")))) (jolt= _a$6542 _a$6543)) and__25__auto))) (jolt-assoc merged (keyword #f "shape") (jolt-get a (keyword #f "shape"))) merged)) (merged (if (jolt-truthy? (let* ((and__25__auto (jolt-get a (keyword #f "type")))) (if (jolt-truthy? and__25__auto) (let* ((_a$6544 (jolt-get a (keyword #f "type"))) (_a$6545 (jolt-get b (keyword #f "type")))) (jolt= _a$6544 _a$6545)) and__25__auto))) (jolt-assoc merged (keyword #f "type") (jolt-get a (keyword #f "type"))) merged)) (merged (if (jolt-truthy? (let* ((or__26__auto (jolt-get a (keyword #f "nilable")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get b (keyword #f "nilable"))))) (jolt-assoc merged (keyword #f "nilable") #t) merged))) merged) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") b) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$6546 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") a)) (_a$6547 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") b))) (join-t _a$6546 _a$6547))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") b) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") (let* ((_a$6548 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") a)) (_a$6549 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") b))) (join-t _a$6548 _a$6549))) (if (jolt-truthy? (keyword #f "else")) (let* ((ma (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") a)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") a) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "scalar-t?") a)) (jolt-hash-set a) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))) (mb (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") b) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "scalar-t?") b)) (jolt-hash-set b) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (if (jolt-truthy? (let* ((and__25__auto ma)) (if (jolt-truthy? and__25__auto) mb and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-of") (jolt-reduce jolt-conj ma mb)) (keyword #f "any"))) jolt-nil))))))))))))) join-t))) + (def-var! "jolt.passes.types.lattice" "join-t" (letrec ((join-t (lambda (a b) (let fnrec5395 ((a a) (b b)) (if (jolt= a b) a (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") a)) b (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") b)) a (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") b) and__25__auto))) (let* ((merged (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$5396 (var-deref "jolt.passes.types.lattice" "merge-fields")) (_a$5397 (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") a)) (_a$5398 (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") b))) (jolt-invoke _a$5396 _a$5397 _a$5398))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-get a (keyword #f "shape")))) (if (jolt-truthy? and__25__auto) (let* ((_a$5399 (jolt-get a (keyword #f "shape"))) (_a$5400 (jolt-get b (keyword #f "shape")))) (jolt= _a$5399 _a$5400)) and__25__auto))) (jolt-assoc merged (keyword #f "shape") (jolt-get a (keyword #f "shape"))) merged)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") b) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$5401 join-t) (_a$5402 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") a)) (_a$5403 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") b))) (jolt-invoke _a$5401 _a$5402 _a$5403))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") a))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") b) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") (let* ((_a$5404 join-t) (_a$5405 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") a)) (_a$5406 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") b))) (jolt-invoke _a$5404 _a$5405 _a$5406))) (if (jolt-truthy? (keyword #f "else")) (let* ((ma (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") a)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") a) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "scalar-t?") a)) (jolt-hash-set a) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))) (mb (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") b) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "scalar-t?") b)) (jolt-hash-set b) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (if (jolt-truthy? (let* ((and__25__auto ma)) (if (jolt-truthy? and__25__auto) mb and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-of") (jolt-reduce jolt-conj ma mb)) (keyword #f "any"))) jolt-nil))))))))))) join-t))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "join" (letrec ((join (lambda (a b) (let fnrec6550 ((a a) (b b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join-t") a b))))) join))) + (def-var! "jolt.passes.types.lattice" "join" (letrec ((join (lambda (a b) (let fnrec5407 ((a a) (b b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join-t") a b))))) join))) (guard (e (#t #f)) (def-var! "jolt.passes.types.lattice" "type-depth" 4)) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "cap" (letrec ((cap (lambda (t d) (let fnrec6551 ((t t) (d d)) (if (jolt-n<= d 0) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)))))) (keyword #f "any") t) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t)) (let* ((capped (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$6555 (lambda (m k) (let fnrec6552 ((m m) (k k)) (jolt-assoc m k (let* ((_a$6553 (jolt-get (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t) k)) (_a$6554 (jolt-dec d))) (cap _a$6553 _a$6554)))))) (_a$6556 (jolt-hash-map)) (_a$6557 (jolt-keys (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t)))) (jolt-reduce _a$6555 _a$6556 _a$6557)))) (capped (if (jolt-truthy? (jolt-get t (keyword #f "shape"))) (jolt-assoc capped (keyword #f "shape") (jolt-get t (keyword #f "shape"))) capped)) (capped (if (jolt-truthy? (jolt-get t (keyword #f "type"))) (jolt-assoc capped (keyword #f "type") (jolt-get t (keyword #f "type"))) capped))) capped) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$6558 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") t)) (_a$6559 (jolt-dec d))) (cap _a$6558 _a$6559))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") (let* ((_a$6560 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") t)) (_a$6561 (jolt-dec d))) (cap _a$6560 _a$6561))) (if (jolt-truthy? (keyword #f "else")) t jolt-nil))))))))) cap))) + (def-var! "jolt.passes.types.lattice" "cap" (letrec ((cap (lambda (t d) (let fnrec5408 ((t t) (d d)) (if (<= d 0) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)))))) (keyword #f "any") t) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t)) (let* ((capped (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$5413 (lambda (m k) (let fnrec5409 ((m m) (k k)) (jolt-assoc m k (let* ((_a$5410 cap) (_a$5411 (jolt-get (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t) k)) (_a$5412 (jolt-dec d))) (jolt-invoke _a$5410 _a$5411 _a$5412)))))) (_a$5414 (jolt-hash-map)) (_a$5415 (jolt-keys (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t)))) (jolt-reduce _a$5413 _a$5414 _a$5415)))) (capped (if (jolt-truthy? (jolt-get t (keyword #f "shape"))) (jolt-assoc capped (keyword #f "shape") (jolt-get t (keyword #f "shape"))) capped)) (capped (if (jolt-truthy? (jolt-get t (keyword #f "type"))) (jolt-assoc capped (keyword #f "type") (jolt-get t (keyword #f "type"))) capped))) capped) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$5416 cap) (_a$5417 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") t)) (_a$5418 (jolt-dec d))) (jolt-invoke _a$5416 _a$5417 _a$5418))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") (let* ((_a$5419 cap) (_a$5420 (jolt-invoke (var-deref "jolt.passes.types.lattice" "selem") t)) (_a$5421 (jolt-dec d))) (jolt-invoke _a$5419 _a$5420 _a$5421))) (if (jolt-truthy? (keyword #f "else")) t jolt-nil))))))))) cap))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "struct-safe?" (letrec ((struct-safe? (lambda (t) (let fnrec6562 ((t t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))))) struct-safe?))) + (def-var! "jolt.passes.types.lattice" "struct-safe?" (letrec ((struct-safe? (lambda (t) (let fnrec5422 ((t t)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))))) struct-safe?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "field-type" (letrec ((field-type (lambda (t k) (let fnrec6563 ((t t) (k k)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get t (keyword #f "nilable"))) and__25__auto))) (jolt-get (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t) k (keyword #f "any")) (keyword #f "any")))))) field-type))) + (def-var! "jolt.passes.types.lattice" "field-type" (letrec ((field-type (lambda (t k) (let fnrec5423 ((t t) (k k)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t)) (jolt-get (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") t) k (keyword #f "any")) (keyword #f "any")))))) field-type))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "nilable?" (letrec ((nilable? (lambda (t) (let fnrec6564 ((t t)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") t))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get t (keyword #f "nilable")))) (if (jolt-truthy? and__25__auto) #t and__25__auto)) and__25__auto)))))) nilable?))) + (def-var! "jolt.passes.types.lattice" "shape-order" (letrec ((shape-order (lambda (ks) (let fnrec5424 ((ks ks)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "sort") (lambda (a b) (let fnrec5425 ((a a) (b b)) (let* ((_a$5426 (var-deref "clojure.core" "compare")) (_a$5427 (jolt-invoke (var-deref "clojure.core" "str") a)) (_a$5428 (jolt-invoke (var-deref "clojure.core" "str") b))) (jolt-invoke _a$5426 _a$5427 _a$5428)))) ks)))))) shape-order))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "strip-nilable" (letrec ((strip-nilable (lambda (t) (let fnrec6565 ((t t)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") t))) (if (jolt-truthy? and__25__auto) (jolt-get t (keyword #f "nilable")) and__25__auto))) (jolt-dissoc t (keyword #f "nilable")) t))))) strip-nilable))) + (def-var! "jolt.passes.types.lattice" "type-shape" (letrec ((type-shape (lambda (t) (let fnrec5429 ((t t)) (jolt-get t (keyword #f "shape")))))) type-shape))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.lattice" "shape-order" (letrec ((shape-order (lambda (ks) (let fnrec6566 ((ks ks)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "sort") (lambda (a b) (let fnrec6567 ((a a) (b b)) (let* ((_a$6568 (var-deref "clojure.core" "compare")) (_a$6569 (jolt-invoke (var-deref "clojure.core" "str") a)) (_a$6570 (jolt-invoke (var-deref "clojure.core" "str") b))) (jolt-invoke _a$6568 _a$6569 _a$6570)))) ks)))))) shape-order) (let* ((_o$6571 (keyword #f "doc")) (_o$6572 "Canonical key order for a shape: keys sorted by their string form, so two\n literals with the same keys in any order intern to the same shape.")) (jolt-hash-map _o$6571 _o$6572)))) + (def-var! "jolt.passes.types.lattice" "mark-struct" (letrec ((mark-struct (lambda (node t) (let fnrec5430 ((node node) (t t)) (let* ((n (jolt-assoc node (keyword #f "hint") (keyword #f "struct")))) (if (jolt-truthy? (jolt-get t (keyword #f "shape"))) (jolt-assoc n (keyword #f "shape") (jolt-get t (keyword #f "shape"))) n)))))) mark-struct))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "type-shape" (letrec ((type-shape (lambda (t) (let fnrec6573 ((t t)) (jolt-get t (keyword #f "shape")))))) type-shape))) + (def-var! "jolt.passes.types.lattice" "truthy-type?" (letrec ((truthy-type? (lambda (t) (let fnrec5431 ((t t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "truthy")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "phm")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t))))))))))))))))))) truthy-type?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "mark-struct" (letrec ((mark-struct (lambda (node t) (let fnrec6574 ((node node) (t t)) (let* ((n (jolt-assoc node (keyword #f "hint") (keyword #f "struct")))) (if (jolt-truthy? (jolt-get t (keyword #f "shape"))) (jolt-assoc n (keyword #f "shape") (jolt-get t (keyword #f "shape"))) n)))))) mark-struct))) + (def-var! "jolt.passes.types.lattice" "num-ret-fns" (let* ((_o$5432 "+") (_o$5433 "-") (_o$5434 "*") (_o$5435 "/") (_o$5436 "inc") (_o$5437 "dec") (_o$5438 "mod") (_o$5439 "rem") (_o$5440 "quot") (_o$5441 "min") (_o$5442 "max") (_o$5443 "abs") (_o$5444 "bit-and") (_o$5445 "bit-or") (_o$5446 "bit-xor") (_o$5447 "count")) (jolt-hash-set _o$5432 _o$5433 _o$5434 _o$5435 _o$5436 _o$5437 _o$5438 _o$5439 _o$5440 _o$5441 _o$5442 _o$5443 _o$5444 _o$5445 _o$5446 _o$5447)))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "truthy-type?" (letrec ((truthy-type? (lambda (t) (let fnrec6575 ((t t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "double")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "truthy")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "phm")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get t (keyword #f "nilable"))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t))))))))))))))))))))) truthy-type?))) + (def-var! "jolt.passes.types.lattice" "vector-ret-fns" (let* ((_o$5448 "vec") (_o$5449 "vector") (_o$5450 "mapv") (_o$5451 "filterv") (_o$5452 "subvec")) (jolt-hash-set _o$5448 _o$5449 _o$5450 _o$5451 _o$5452)))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "num-ret-fns" (let* ((_o$6576 "+") (_o$6577 "-") (_o$6578 "*") (_o$6579 "/") (_o$6580 "inc") (_o$6581 "dec") (_o$6582 "mod") (_o$6583 "rem") (_o$6584 "quot") (_o$6585 "min") (_o$6586 "max") (_o$6587 "abs") (_o$6588 "bit-and") (_o$6589 "bit-or") (_o$6590 "bit-xor") (_o$6591 "count")) (jolt-hash-set _o$6576 _o$6577 _o$6578 _o$6579 _o$6580 _o$6581 _o$6582 _o$6583 _o$6584 _o$6585 _o$6586 _o$6587 _o$6588 _o$6589 _o$6590 _o$6591)))) + (def-var! "jolt.passes.types.check" "not-number?" (letrec ((not-number? (lambda (t) (let fnrec5453 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-number? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "phm")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)))))))))))))))) not-number?))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.lattice" "vector-ret-fns" (let* ((_o$6592 "vec") (_o$6593 "vector") (_o$6594 "mapv") (_o$6595 "filterv") (_o$6596 "subvec")) (jolt-hash-set _o$6592 _o$6593 _o$6594 _o$6595 _o$6596)))) + (def-var! "jolt.passes.types.check" "not-seqable?" (letrec ((not-seqable? (lambda (t) (let fnrec5454 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-seqable? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "kw"))))))))) not-seqable?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "not-number?" (letrec ((not-number? (lambda (t) (let fnrec6597 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-number? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "str")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "kw")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt= t (keyword #f "phm")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)))))))))))))))) not-number?) (let* ((_o$6598 (keyword #f "private")) (_o$6599 #t)) (jolt-hash-map _o$6598 _o$6599)))) + (def-var! "jolt.passes.types.check" "not-callable?" (letrec ((not-callable? (lambda (t) (let fnrec5455 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-callable? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "str"))))))))) not-callable?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "not-seqable?" (letrec ((not-seqable? (lambda (t) (let fnrec6600 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-seqable? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "kw"))))))))) not-seqable?) (let* ((_o$6601 (keyword #f "private")) (_o$6602 #t)) (jolt-hash-map _o$6601 _o$6602)))) + (def-var-with-meta! "jolt.passes.types.check" "num-ops" (let* ((_o$5456 "+") (_o$5457 "-") (_o$5458 "*") (_o$5459 "/") (_o$5460 "inc") (_o$5461 "dec") (_o$5462 "mod") (_o$5463 "rem") (_o$5464 "quot") (_o$5465 "min") (_o$5466 "max") (_o$5467 "abs") (_o$5468 "bit-and") (_o$5469 "bit-or") (_o$5470 "bit-xor") (_o$5471 "bit-not") (_o$5472 "bit-shift-left") (_o$5473 "bit-shift-right")) (jolt-hash-set _o$5456 _o$5457 _o$5458 _o$5459 _o$5460 _o$5461 _o$5462 _o$5463 _o$5464 _o$5465 _o$5466 _o$5467 _o$5468 _o$5469 _o$5470 _o$5471 _o$5472 _o$5473)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var! "jolt.passes.types.check" "not-callable?" (letrec ((not-callable? (lambda (t) (let fnrec6603 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (jolt-invoke (var-deref "clojure.core" "every?") not-callable? (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t)) (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "str"))))))))) not-callable?))) + (def-var-with-meta! "jolt.passes.types.check" "seq-ops" (let* ((_o$5474 "count") (_o$5475 "first") (_o$5476 "rest") (_o$5477 "next") (_o$5478 "seq") (_o$5479 "nth")) (jolt-hash-set _o$5474 _o$5475 _o$5476 _o$5477 _o$5478 _o$5479)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "num-ops" (let* ((_o$6604 "+") (_o$6605 "-") (_o$6606 "*") (_o$6607 "/") (_o$6608 "inc") (_o$6609 "dec") (_o$6610 "mod") (_o$6611 "rem") (_o$6612 "quot") (_o$6613 "min") (_o$6614 "max") (_o$6615 "abs") (_o$6616 "bit-and") (_o$6617 "bit-or") (_o$6618 "bit-xor") (_o$6619 "bit-not") (_o$6620 "bit-shift-left") (_o$6621 "bit-shift-right")) (jolt-hash-set _o$6604 _o$6605 _o$6606 _o$6607 _o$6608 _o$6609 _o$6610 _o$6611 _o$6612 _o$6613 _o$6614 _o$6615 _o$6616 _o$6617 _o$6618 _o$6619 _o$6620 _o$6621)) (let* ((_o$6622 (keyword #f "private")) (_o$6623 #t)) (jolt-hash-map _o$6622 _o$6623)))) + (def-var! "jolt.passes.types.check" "type-name" (letrec ((type-name (lambda (t) (let fnrec5480 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (let* ((_a$5482 (lambda (s m) (let fnrec5481 ((s s) (m m)) (if (jolt= s "") (jolt-invoke type-name m) (jolt-invoke (var-deref "clojure.core" "str") s " or " (jolt-invoke type-name m)))))) (_a$5483 "") (_a$5484 (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t))) (jolt-reduce _a$5482 _a$5483 _a$5484)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t)) "a map" (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) "a vector" (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)) "a set" (if (jolt= t (keyword #f "str")) "a string" (if (jolt= t (keyword #f "kw")) "a keyword" (if (jolt= t (keyword #f "num")) "a number" (if (jolt= t (keyword #f "phm")) "a map" (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") t) jolt-nil))))))))))))) type-name))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "seq-ops" (let* ((_o$6624 "count") (_o$6625 "first") (_o$6626 "rest") (_o$6627 "next") (_o$6628 "seq") (_o$6629 "nth")) (jolt-hash-set _o$6624 _o$6625 _o$6626 _o$6627 _o$6628 _o$6629)) (let* ((_o$6630 (keyword #f "private")) (_o$6631 #t)) (jolt-hash-map _o$6630 _o$6631)))) + (def-var! "jolt.passes.types.check" "check-invoke" (letrec ((check-invoke (lambda (cn args arg-types pos env) (let fnrec5485 ((cn cn) (args args) (arg-types arg-types) (pos pos) (env env)) (if (jolt-contains? (var-deref "jolt.passes.types.check" "num-ops") cn) (let* ((_a$5508 (lambda (_ i) (let fnrec5486 ((_ _) (i i)) (begin (let* ((t (jolt-nth arg-types i))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-number?") t)) (let* ((_a$5504 (var-deref "clojure.core" "swap!")) (_a$5505 (jolt-get env (keyword #f "diags"))) (_a$5506 jolt-conj) (_a$5507 (let* ((_o$5494 (keyword #f "op")) (_o$5495 cn) (_o$5496 (keyword #f "argpos")) (_o$5497 i) (_o$5498 (keyword #f "type")) (_o$5499 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t)) (_o$5500 (keyword #f "pos")) (_o$5501 pos) (_o$5502 (keyword #f "msg")) (_o$5503 (let* ((_a$5487 (var-deref "clojure.core" "str")) (_a$5488 "`") (_a$5489 cn) (_a$5490 "` requires a number, but argument ") (_a$5491 (jolt-inc i)) (_a$5492 " is ") (_a$5493 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t))) (jolt-invoke _a$5487 _a$5488 _a$5489 _a$5490 _a$5491 _a$5492 _a$5493)))) (jolt-hash-map _o$5494 _o$5495 _o$5496 _o$5497 _o$5498 _o$5499 _o$5500 _o$5501 _o$5502 _o$5503)))) (jolt-invoke _a$5504 _a$5505 _a$5506 _a$5507)) jolt-nil)) jolt-nil)))) (_a$5509 jolt-nil) (_a$5510 (jolt-range (jolt-count args)))) (jolt-reduce _a$5508 _a$5509 _a$5510)) (if (jolt-truthy? (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types.check" "seq-ops") cn))) (if (jolt-truthy? and__25__auto) (> (jolt-count args) 0) and__25__auto))) (let* ((t (jolt-nth arg-types 0))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-seqable?") t)) (let* ((_a$5528 (var-deref "clojure.core" "swap!")) (_a$5529 (jolt-get env (keyword #f "diags"))) (_a$5530 jolt-conj) (_a$5531 (let* ((_o$5518 (keyword #f "op")) (_o$5519 cn) (_o$5520 (keyword #f "argpos")) (_o$5521 0) (_o$5522 (keyword #f "type")) (_o$5523 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t)) (_o$5524 (keyword #f "pos")) (_o$5525 pos) (_o$5526 (keyword #f "msg")) (_o$5527 (let* ((_a$5511 (var-deref "clojure.core" "str")) (_a$5512 "`") (_a$5513 cn) (_a$5514 "` requires ") (_a$5515 (if (jolt= cn "count") "a countable collection" "a seqable")) (_a$5516 ", but argument 1 is ") (_a$5517 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t))) (jolt-invoke _a$5511 _a$5512 _a$5513 _a$5514 _a$5515 _a$5516 _a$5517)))) (jolt-hash-map _o$5518 _o$5519 _o$5520 _o$5521 _o$5522 _o$5523 _o$5524 _o$5525 _o$5526 _o$5527)))) (jolt-invoke _a$5528 _a$5529 _a$5530 _a$5531)) jolt-nil)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) check-invoke))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "type-name" (letrec ((type-name (lambda (t) (let fnrec6632 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (let* ((_a$6634 (lambda (s m) (let fnrec6633 ((s s) (m m)) (if (jolt= s "") (type-name m) (jolt-invoke (var-deref "clojure.core" "str") s " or " (type-name m)))))) (_a$6635 "") (_a$6636 (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t))) (jolt-reduce _a$6634 _a$6635 _a$6636)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t)) "a map" (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) "a vector" (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "set-type?") t)) "a set" (if (jolt= t (keyword #f "str")) "a string" (if (jolt= t (keyword #f "kw")) "a keyword" (if (jolt= t (keyword #f "num")) "a number" (if (jolt= t (keyword #f "phm")) "a map" (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "str") t) jolt-nil))))))))))))) type-name) (let* ((_o$6637 (keyword #f "doc")) (_o$6638 "Render an inferred type for an error message.")) (jolt-hash-map _o$6637 _o$6638)))) + (def-var! "jolt.passes.types.check" "register-user-fn!" (letrec ((register-user-fn! (lambda (node env) (let fnrec5532 ((node node) (env env)) (let* ((init (jolt-get node (keyword #f "init"))) (m (jolt-get node (keyword #f "meta"))) (redefable (let* ((and__25__auto m)) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-get m (keyword #f "redef")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get m (keyword #f "dynamic")))) and__25__auto)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-not redefable))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get init (keyword #f "op"))) and__25__auto))) (let* ((arities (jolt-get init (keyword #f "arities")))) (if (jolt= 1 (jolt-count arities)) (let* ((ar (jolt-first arities))) (if (jolt-not (jolt-get ar (keyword #f "rest"))) (let* ((_a$5543 (var-deref "clojure.core" "swap!")) (_a$5544 (jolt-get env (keyword #f "user-sigs"))) (_a$5545 jolt-assoc) (_a$5546 (let* ((_a$5533 (var-deref "clojure.core" "str")) (_a$5534 (jolt-get node (keyword #f "ns"))) (_a$5535 "/") (_a$5536 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$5533 _a$5534 _a$5535 _a$5536))) (_a$5547 (let* ((_o$5537 (keyword #f "name")) (_o$5538 (jolt-get node (keyword #f "name"))) (_o$5539 (keyword #f "params")) (_o$5540 (jolt-get ar (keyword #f "params"))) (_o$5541 (keyword #f "body")) (_o$5542 (jolt-get ar (keyword #f "body")))) (jolt-hash-map _o$5537 _o$5538 _o$5539 _o$5540 _o$5541 _o$5542)))) (jolt-invoke _a$5543 _a$5544 _a$5545 _a$5546 _a$5547)) jolt-nil)) jolt-nil)) jolt-nil)))))) register-user-fn!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "check-invoke" (letrec ((check-invoke (lambda (cn args arg-types pos env) (let fnrec6639 ((cn cn) (args args) (arg-types arg-types) (pos pos) (env env)) (if (jolt-contains? (var-deref "jolt.passes.types.check" "num-ops") cn) (let* ((_a$6662 (lambda (_ i) (let fnrec6640 ((_ _) (i i)) (begin (let* ((t (jolt-nth arg-types i))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-number?") t)) (let* ((_a$6658 (var-deref "clojure.core" "swap!")) (_a$6659 (jolt-get env (keyword #f "diags"))) (_a$6660 jolt-conj) (_a$6661 (let* ((_o$6648 (keyword #f "op")) (_o$6649 cn) (_o$6650 (keyword #f "argpos")) (_o$6651 i) (_o$6652 (keyword #f "type")) (_o$6653 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t)) (_o$6654 (keyword #f "pos")) (_o$6655 pos) (_o$6656 (keyword #f "msg")) (_o$6657 (let* ((_a$6641 (var-deref "clojure.core" "str")) (_a$6642 "`") (_a$6643 cn) (_a$6644 "` requires a number, but argument ") (_a$6645 (jolt-inc i)) (_a$6646 " is ") (_a$6647 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t))) (jolt-invoke _a$6641 _a$6642 _a$6643 _a$6644 _a$6645 _a$6646 _a$6647)))) (jolt-hash-map _o$6648 _o$6649 _o$6650 _o$6651 _o$6652 _o$6653 _o$6654 _o$6655 _o$6656 _o$6657)))) (jolt-invoke _a$6658 _a$6659 _a$6660 _a$6661)) jolt-nil)) jolt-nil)))) (_a$6663 jolt-nil) (_a$6664 (jolt-range (jolt-count args)))) (jolt-reduce _a$6662 _a$6663 _a$6664)) (if (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types.check" "seq-ops") cn))) (if (jolt-truthy? and__25__auto) (jolt-n> (jolt-count args) 0) and__25__auto)) (let* ((t (jolt-nth arg-types 0))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-seqable?") t)) (let* ((_a$6682 (var-deref "clojure.core" "swap!")) (_a$6683 (jolt-get env (keyword #f "diags"))) (_a$6684 jolt-conj) (_a$6685 (let* ((_o$6672 (keyword #f "op")) (_o$6673 cn) (_o$6674 (keyword #f "argpos")) (_o$6675 0) (_o$6676 (keyword #f "type")) (_o$6677 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t)) (_o$6678 (keyword #f "pos")) (_o$6679 pos) (_o$6680 (keyword #f "msg")) (_o$6681 (let* ((_a$6665 (var-deref "clojure.core" "str")) (_a$6666 "`") (_a$6667 cn) (_a$6668 "` requires ") (_a$6669 (if (jolt= cn "count") "a countable collection" "a seqable")) (_a$6670 ", but argument 1 is ") (_a$6671 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") t))) (jolt-invoke _a$6665 _a$6666 _a$6667 _a$6668 _a$6669 _a$6670 _a$6671)))) (jolt-hash-map _o$6672 _o$6673 _o$6674 _o$6675 _o$6676 _o$6677 _o$6678 _o$6679 _o$6680 _o$6681)))) (jolt-invoke _a$6682 _a$6683 _a$6684 _a$6685)) jolt-nil)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) check-invoke) (let* ((_o$6686 (keyword #f "doc")) (_o$6687 "If node is a core-op call whose argument type is provably in the error domain,\n conj a diagnostic into env's diags cell. arg-types is the vector of inferred\n argument types; pos is the call form's source offset, carried into each\n diagnostic.")) (jolt-hash-map _o$6686 _o$6687)))) + (def-var-with-meta! "jolt.passes.types" "config-box" (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$4859 (keyword #f "rtenv")) (_o$4860 (jolt-hash-map)) (_o$4861 (keyword #f "vtypes")) (_o$4862 (jolt-hash-map)) (_o$4863 (keyword #f "record-shapes")) (_o$4864 (jolt-hash-map)) (_o$4865 (keyword #f "protocol-methods")) (_o$4866 (jolt-hash-map)) (_o$4867 (keyword #f "map-shapes?")) (_o$4868 #f)) (jolt-hash-map _o$4859 _o$4860 _o$4861 _o$4862 _o$4863 _o$4864 _o$4865 _o$4866 _o$4867 _o$4868))) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types.check" "register-user-fn!" (letrec ((register-user-fn! (lambda (node env) (let fnrec6688 ((node node) (env env)) (let* ((init (jolt-get node (keyword #f "init"))) (m (jolt-get node (keyword #f "meta"))) (redefable (let* ((and__25__auto m)) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-get m (keyword #f "redef")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get m (keyword #f "dynamic")))) and__25__auto)))) (if (let* ((and__25__auto (jolt-not redefable))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get init (keyword #f "op"))) and__25__auto)) (let* ((arities (jolt-get init (keyword #f "arities")))) (if (jolt= 1 (jolt-count arities)) (let* ((ar (jolt-first arities))) (if (jolt-not (jolt-get ar (keyword #f "rest"))) (let* ((_a$6699 (var-deref "clojure.core" "swap!")) (_a$6700 (jolt-get env (keyword #f "user-sigs"))) (_a$6701 jolt-assoc) (_a$6702 (let* ((_a$6689 (var-deref "clojure.core" "str")) (_a$6690 (jolt-get node (keyword #f "ns"))) (_a$6691 "/") (_a$6692 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$6689 _a$6690 _a$6691 _a$6692))) (_a$6703 (let* ((_o$6693 (keyword #f "name")) (_o$6694 (jolt-get node (keyword #f "name"))) (_o$6695 (keyword #f "params")) (_o$6696 (jolt-get ar (keyword #f "params"))) (_o$6697 (keyword #f "body")) (_o$6698 (jolt-get ar (keyword #f "body")))) (jolt-hash-map _o$6693 _o$6694 _o$6695 _o$6696 _o$6697 _o$6698)))) (jolt-invoke _a$6699 _a$6700 _a$6701 _a$6702 _a$6703)) jolt-nil)) jolt-nil)) jolt-nil)))))) register-user-fn!) (let* ((_o$6704 (keyword #f "doc")) (_o$6705 "Record a (def name (fn [params] body)) \x2014; single fixed arity, not redefinable \x2014;\n for later user-fn call checking. Redefinable/dynamic and multi/variadic fns are\n skipped (their body is not a stable requirement).")) (jolt-hash-map _o$6704 _o$6705)))) + (def-var-with-meta! "jolt.passes.types" "escapes-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "config-box" (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$5648 (keyword #f "rtenv")) (_o$5649 (jolt-hash-map)) (_o$5650 (keyword #f "vtypes")) (_o$5651 (jolt-hash-map)) (_o$5652 (keyword #f "record-shapes")) (_o$5653 (jolt-hash-map)) (_o$5654 (keyword #f "protocol-methods")) (_o$5655 (jolt-hash-map)) (_o$5656 (keyword #f "map-shapes?")) (_o$5657 #f)) (jolt-hash-map _o$5648 _o$5649 _o$5650 _o$5651 _o$5652 _o$5653 _o$5654 _o$5655 _o$5656 _o$5657))) (let* ((_o$5658 (keyword #f "private")) (_o$5659 #t)) (jolt-hash-map _o$5658 _o$5659)))) + (def-var-with-meta! "jolt.passes.types" "user-sig-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "escapes-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set)) (let* ((_o$5660 (keyword #f "private")) (_o$5661 #t)) (jolt-hash-map _o$5660 _o$5661)))) + (def-var-with-meta! "jolt.passes.types" "last-diags-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "user-sig-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (let* ((_o$5662 (keyword #f "private")) (_o$5663 #t)) (jolt-hash-map _o$5662 _o$5663)))) + (def-var-with-meta! "jolt.passes.types" "check-mode-box" (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$4869 (keyword #f "on")) (_o$4870 #f) (_o$4871 (keyword #f "strict")) (_o$4872 #f)) (jolt-hash-map _o$4869 _o$4870 _o$4871 _o$4872))) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "last-diags-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector)) (let* ((_o$5664 (keyword #f "private")) (_o$5665 #t)) (jolt-hash-map _o$5664 _o$5665)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "check-mode-box" (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$5666 (keyword #f "on")) (_o$5667 #f) (_o$5668 (keyword #f "strict")) (_o$5669 #f)) (jolt-hash-map _o$5666 _o$5667 _o$5668 _o$5669))) (let* ((_o$5670 (keyword #f "private")) (_o$5671 #t)) (jolt-hash-map _o$5670 _o$5671)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "pm-rets-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (let* ((_o$5672 (keyword #f "private")) (_o$5673 #t)) (jolt-hash-map _o$5672 _o$5673)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "mk-env" (letrec ((mk-env (lambda (checking? strict?) (let fnrec5674 ((checking? checking?) (strict? strict?)) (let* ((c (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "config-box")))) (let* ((_o$5675 (keyword #f "rtenv")) (_o$5676 (jolt-get c (keyword #f "rtenv"))) (_o$5677 (keyword #f "vtypes")) (_o$5678 (jolt-get c (keyword #f "vtypes"))) (_o$5679 (keyword #f "record-shapes")) (_o$5680 (jolt-get c (keyword #f "record-shapes"))) (_o$5681 (keyword #f "protocol-methods")) (_o$5682 (jolt-get c (keyword #f "protocol-methods"))) (_o$5683 (keyword #f "map-shapes?")) (_o$5684 (jolt-get c (keyword #f "map-shapes?"))) (_o$5685 (keyword #f "checking?")) (_o$5686 checking?) (_o$5687 (keyword #f "strict?")) (_o$5688 strict?) (_o$5689 (keyword #f "diags")) (_o$5690 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (_o$5691 (keyword #f "calls")) (_o$5692 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (_o$5693 (keyword #f "checking-set")) (_o$5694 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set))) (_o$5695 (keyword #f "diag-memo")) (_o$5696 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map))) (_o$5697 (keyword #f "escapes")) (_o$5698 (var-deref "jolt.passes.types" "escapes-box")) (_o$5699 (keyword #f "user-sigs")) (_o$5700 (var-deref "jolt.passes.types" "user-sig-box"))) (jolt-hash-map _o$5675 _o$5676 _o$5677 _o$5678 _o$5679 _o$5680 _o$5681 _o$5682 _o$5683 _o$5684 _o$5685 _o$5686 _o$5687 _o$5688 _o$5689 _o$5690 _o$5691 _o$5692 _o$5693 _o$5694 _o$5695 _o$5696 _o$5697 _o$5698 _o$5699 _o$5700))))))) mk-env) (let* ((_o$5701 (keyword #f "private")) (_o$5702 #t)) (jolt-hash-map _o$5701 _o$5702)))) + (def-var! "jolt.passes.types" "mk-env" (letrec ((mk-env (lambda (checking? strict?) (let fnrec4873 ((checking? checking?) (strict? strict?)) (let* ((c (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "config-box")))) (let* ((_o$4874 (keyword #f "rtenv")) (_o$4875 (jolt-get c (keyword #f "rtenv"))) (_o$4876 (keyword #f "vtypes")) (_o$4877 (jolt-get c (keyword #f "vtypes"))) (_o$4878 (keyword #f "record-shapes")) (_o$4879 (jolt-get c (keyword #f "record-shapes"))) (_o$4880 (keyword #f "protocol-methods")) (_o$4881 (jolt-get c (keyword #f "protocol-methods"))) (_o$4882 (keyword #f "map-shapes?")) (_o$4883 (jolt-get c (keyword #f "map-shapes?"))) (_o$4884 (keyword #f "checking?")) (_o$4885 checking?) (_o$4886 (keyword #f "strict?")) (_o$4887 strict?) (_o$4888 (keyword #f "diags")) (_o$4889 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (_o$4890 (keyword #f "calls")) (_o$4891 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))) (_o$4892 (keyword #f "checking-set")) (_o$4893 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-set))) (_o$4894 (keyword #f "diag-memo")) (_o$4895 (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map))) (_o$4896 (keyword #f "escapes")) (_o$4897 (var-deref "jolt.passes.types" "escapes-box")) (_o$4898 (keyword #f "user-sigs")) (_o$4899 (var-deref "jolt.passes.types" "user-sig-box"))) (jolt-hash-map _o$4874 _o$4875 _o$4876 _o$4877 _o$4878 _o$4879 _o$4880 _o$4881 _o$4882 _o$4883 _o$4884 _o$4885 _o$4886 _o$4887 _o$4888 _o$4889 _o$4890 _o$4891 _o$4892 _o$4893 _o$4894 _o$4895 _o$4896 _o$4897 _o$4898 _o$4899))))))) mk-env))) (guard (e (#t #f)) (declare-var! "jolt.passes.types" "record-type-from-entry")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "field-type-from-tag" (letrec ((field-type-from-tag (lambda (tag depth shapes) (let fnrec5703 ((tag tag) (depth depth) (shapes shapes)) (if (let* ((or__26__auto (jolt-nil? tag))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n<= depth 0))) (keyword #f "any") (if (jolt= tag "num") (keyword #f "num") (if (jolt= tag "double") (keyword #f "double") (if (jolt-truthy? (keyword #f "else")) (let* ((e (jolt-get shapes tag))) (if (jolt-truthy? e) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e depth shapes) (keyword #f "any"))) jolt-nil)))))))) field-type-from-tag) (let* ((_o$5704 (keyword #f "private")) (_o$5705 #t)) (jolt-hash-map _o$5704 _o$5705)))) + (def-var! "jolt.passes.types" "field-type-from-tag" (letrec ((field-type-from-tag (lambda (tag depth shapes) (let fnrec4900 ((tag tag) (depth depth) (shapes shapes)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") tag))) (if (jolt-truthy? or__26__auto) or__26__auto (<= depth 0)))) (keyword #f "any") (if (jolt= tag "num") (keyword #f "num") (if (jolt-truthy? (keyword #f "else")) (let* ((e (jolt-get shapes tag))) (if (jolt-truthy? e) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e depth shapes) (keyword #f "any"))) jolt-nil))))))) field-type-from-tag))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "record-type-from-entry" (letrec ((record-type-from-entry (lambda (rs depth shapes) (let fnrec5706 ((rs rs) (depth depth) (shapes shapes)) (let* ((fields (jolt-get rs (keyword #f "fields"))) (tags (jolt-get rs (keyword #f "tags"))) (fmap (let* ((_a$5715 (lambda (m i) (let fnrec5707 ((m m) (i i)) (let* ((_a$5712 m) (_a$5713 (jolt-nth fields i)) (_a$5714 (let* ((_a$5708 (var-deref "jolt.passes.types" "field-type-from-tag")) (_a$5709 (if (jolt-truthy? tags) (jolt-nth tags i) jolt-nil)) (_a$5710 (jolt-dec depth)) (_a$5711 shapes)) (jolt-invoke _a$5708 _a$5709 _a$5710 _a$5711)))) (jolt-assoc _a$5712 _a$5713 _a$5714))))) (_a$5716 (jolt-hash-map)) (_a$5717 (jolt-range (jolt-count fields)))) (jolt-reduce _a$5715 _a$5716 _a$5717)))) (let* ((_a$5718 (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") fmap)) (_a$5719 (keyword #f "shape")) (_a$5720 (jolt-invoke (var-deref "clojure.core" "vec") fields)) (_a$5721 (keyword #f "type")) (_a$5722 (jolt-get rs (keyword #f "type")))) (jolt-assoc _a$5718 _a$5719 _a$5720 _a$5721 _a$5722))))))) record-type-from-entry) (let* ((_o$5723 (keyword #f "private")) (_o$5724 #t)) (jolt-hash-map _o$5723 _o$5724)))) + (def-var! "jolt.passes.types" "record-type-from-entry" (letrec ((record-type-from-entry (lambda (rs depth shapes) (let fnrec4901 ((rs rs) (depth depth) (shapes shapes)) (let* ((fields (jolt-get rs (keyword #f "fields"))) (tags (jolt-get rs (keyword #f "tags"))) (fmap (let* ((_a$4910 (lambda (m i) (let fnrec4902 ((m m) (i i)) (let* ((_a$4907 m) (_a$4908 (jolt-nth fields i)) (_a$4909 (let* ((_a$4903 (var-deref "jolt.passes.types" "field-type-from-tag")) (_a$4904 (if (jolt-truthy? tags) (jolt-nth tags i) jolt-nil)) (_a$4905 (jolt-dec depth)) (_a$4906 shapes)) (jolt-invoke _a$4903 _a$4904 _a$4905 _a$4906)))) (jolt-assoc _a$4907 _a$4908 _a$4909))))) (_a$4911 (jolt-hash-map)) (_a$4912 (jolt-range (jolt-count fields)))) (jolt-reduce _a$4910 _a$4911 _a$4912)))) (let* ((_a$4913 (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") fmap)) (_a$4914 (keyword #f "shape")) (_a$4915 (jolt-invoke (var-deref "clojure.core" "vec") fields)) (_a$4916 (keyword #f "type")) (_a$4917 (jolt-get rs (keyword #f "type")))) (jolt-assoc _a$4913 _a$4914 _a$4915 _a$4916 _a$4917))))))) record-type-from-entry))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "elem-fns" (let* ((_o$5725 "rand-nth") (_o$5726 "first") (_o$5727 "peek") (_o$5728 "last") (_o$5729 "nth") (_o$5730 "fnext") (_o$5731 "second")) (jolt-hash-set _o$5725 _o$5726 _o$5727 _o$5728 _o$5729 _o$5730 _o$5731)) (let* ((_o$5732 (keyword #f "private")) (_o$5733 #t)) (jolt-hash-map _o$5732 _o$5733)))) + (def-var-with-meta! "jolt.passes.types" "elem-fns" (let* ((_o$4918 "rand-nth") (_o$4919 "first") (_o$4920 "peek") (_o$4921 "last") (_o$4922 "nth") (_o$4923 "fnext") (_o$4924 "second")) (jolt-hash-set _o$4918 _o$4919 _o$4920 _o$4921 _o$4922 _o$4923 _o$4924)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) (declare-var! "jolt.passes.types" "check-user-call")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "var-key" (letrec ((var-key (lambda (fnode) (let fnrec5734 ((fnode fnode)) (let* ((_a$5735 (var-deref "clojure.core" "str")) (_a$5736 (jolt-get fnode (keyword #f "ns"))) (_a$5737 "/") (_a$5738 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$5735 _a$5736 _a$5737 _a$5738)))))) var-key) (let* ((_o$5739 (keyword #f "private")) (_o$5740 #t)) (jolt-hash-map _o$5739 _o$5740)))) + (def-var! "jolt.passes.types" "var-key" (letrec ((var-key (lambda (fnode) (let fnrec4925 ((fnode fnode)) (let* ((_a$4926 (var-deref "clojure.core" "str")) (_a$4927 (jolt-get fnode (keyword #f "ns"))) (_a$4928 "/") (_a$4929 (jolt-get fnode (keyword #f "name")))) (jolt-invoke _a$4926 _a$4927 _a$4928 _a$4929)))))) var-key))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "call-ret-type" (letrec ((call-ret-type (lambda (fnode env) (let fnrec5741 ((fnode fnode) (env env)) (let* ((op (jolt-get fnode (keyword #f "op"))) (shapes (jolt-get env (keyword #f "record-shapes")))) (if (jolt= op (keyword #f "var")) (let* ((rs (jolt-get shapes (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)))) (if (jolt-truthy? rs) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") rs (var-deref "jolt.passes.types.lattice" "type-depth") shapes) (let* ((r (let* ((_a$5742 (jolt-get env (keyword #f "rtenv"))) (_a$5743 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$5742 _a$5743)))) (if (jolt-truthy? r) r (let* ((pm (let* ((_a$5744 (jolt-get env (keyword #f "protocol-methods"))) (_a$5745 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$5744 _a$5745))) (pmr (if (jolt-truthy? pm) (let* ((_a$5750 (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "pm-rets-box"))) (_a$5751 (let* ((_a$5746 (var-deref "clojure.core" "str")) (_a$5747 (jolt-nth pm 0)) (_a$5748 "/") (_a$5749 (jolt-nth pm 1))) (jolt-invoke _a$5746 _a$5747 _a$5748 _a$5749)))) (jolt-get _a$5750 _a$5751)) jolt-nil))) (if (jolt-truthy? (let* ((and__25__auto pmr)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "not=") pmr (keyword #f "any")) and__25__auto))) pmr (let* ((nm (let* ((and__25__auto (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-get fnode (keyword #f "name")) and__25__auto)))) (if (jolt-nil? nm) (keyword #f "any") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "num-ret-fns") nm) (keyword #f "num") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "vector-ret-fns") nm) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "any")) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil))))))))))) (if (jolt= op (keyword #f "host")) (let* ((nm (jolt-get fnode (keyword #f "name")))) (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "num-ret-fns") nm) (keyword #f "num") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "vector-ret-fns") nm) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "any")) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil)))) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil)))))))) call-ret-type) (let* ((_o$5752 (keyword #f "private")) (_o$5753 #t)) (jolt-hash-map _o$5752 _o$5753)))) + (def-var! "jolt.passes.types" "call-ret-type" (letrec ((call-ret-type (lambda (fnode env) (let fnrec4930 ((fnode fnode) (env env)) (let* ((op (jolt-get fnode (keyword #f "op"))) (shapes (jolt-get env (keyword #f "record-shapes")))) (if (jolt= op (keyword #f "var")) (let* ((rs (jolt-get shapes (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)))) (if (jolt-truthy? rs) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") rs (var-deref "jolt.passes.types.lattice" "type-depth") shapes) (let* ((r (let* ((_a$4931 (jolt-get env (keyword #f "rtenv"))) (_a$4932 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$4931 _a$4932)))) (if (jolt-truthy? r) r (let* ((nm (let* ((and__25__auto (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (jolt-get fnode (keyword #f "name")) and__25__auto)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") nm)) (keyword #f "any") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "num-ret-fns") nm) (keyword #f "num") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "vector-ret-fns") nm) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "any")) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil))))))))) (if (jolt= op (keyword #f "host")) (let* ((nm (jolt-get fnode (keyword #f "name")))) (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "num-ret-fns") nm) (keyword #f "num") (if (jolt-contains? (var-deref "jolt.passes.types.lattice" "vector-ret-fns") nm) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "any")) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil)))) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil)))))))) call-ret-type))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "fold-preds" (let* ((_o$5754 "number?") (_o$5755 "string?") (_o$5756 "keyword?") (_o$5757 "record?") (_o$5758 "nil?") (_o$5759 "some?")) (jolt-hash-set _o$5754 _o$5755 _o$5756 _o$5757 _o$5758 _o$5759)) (let* ((_o$5760 (keyword #f "private")) (_o$5761 #t)) (jolt-hash-map _o$5760 _o$5761)))) + (def-var-with-meta! "jolt.passes.types" "fold-preds" (let* ((_o$4933 "number?") (_o$4934 "string?") (_o$4935 "keyword?") (_o$4936 "record?") (_o$4937 "nil?") (_o$4938 "some?")) (jolt-hash-set _o$4933 _o$4934 _o$4935 _o$4936 _o$4937 _o$4938)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "record-t?" (letrec ((record-t? (lambda (t) (let fnrec5762 ((t t)) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? and__25__auto) (jolt-some? (jolt-get t (keyword #f "type"))) and__25__auto)))))) record-t?) (let* ((_o$5763 (keyword #f "private")) (_o$5764 #t)) (jolt-hash-map _o$5763 _o$5764)))) + (def-var! "jolt.passes.types" "record-t?" (letrec ((record-t? (lambda (t) (let fnrec4939 ((t t)) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") t))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-get t (keyword #f "type"))) and__25__auto)))))) record-t?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "pred-on" (letrec ((pred-on (lambda (pname t) (let fnrec5765 ((pname pname) (t t)) (if (let* ((or__26__auto (jolt= t (keyword #f "any")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "truthy")))) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "nilable?") t)) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (let* ((vs (let* ((_a$5767 (lambda (m) (let fnrec5766 ((m m)) (pred-on pname m)))) (_a$5768 (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t))) (jolt-map _a$5767 _a$5768)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq vs))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-nil? (jolt-first vs))))) (if (jolt-truthy? and__25__auto) (jolt-apply jolt= vs) and__25__auto)) and__25__auto))) (jolt-first vs) jolt-nil)) (if (jolt-truthy? (keyword #f "else")) (let* ((G__138 pname)) (if (jolt= G__138 "number?") (let* ((or__26__auto (jolt= t (keyword #f "num")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "double")))) (if (jolt= G__138 "string?") (jolt= t (keyword #f "str")) (if (jolt= G__138 "keyword?") (jolt= t (keyword #f "kw")) (if (jolt= G__138 "record?") (jolt-invoke (var-deref "jolt.passes.types" "record-t?") t) (if (jolt= G__138 "nil?") #f (if (jolt= G__138 "some?") #t jolt-nil))))))) jolt-nil)))))))) pred-on) (let* ((_o$5769 (keyword #f "private")) (_o$5770 #t)) (jolt-hash-map _o$5769 _o$5770)))) + (def-var! "jolt.passes.types" "pred-on" (letrec ((pred-on (lambda (pname t) (let fnrec4940 ((pname pname) (t t)) (if (jolt-truthy? (let* ((or__26__auto (jolt= t (keyword #f "any")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= t (keyword #f "truthy"))))) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "union-type?") t)) (let* ((vs (let* ((_a$4942 (lambda (m) (let fnrec4941 ((m m)) (jolt-invoke pred-on pname m)))) (_a$4943 (jolt-invoke (var-deref "jolt.passes.types.lattice" "umembers") t))) (jolt-map _a$4942 _a$4943)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq vs))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-first vs))))) (if (jolt-truthy? and__25__auto) (jolt-apply jolt= vs) and__25__auto)) and__25__auto))) (jolt-first vs) jolt-nil)) (if (jolt-truthy? (keyword #f "else")) (let* ((G__122 pname)) (if (jolt= G__122 "number?") (jolt= t (keyword #f "num")) (if (jolt= G__122 "string?") (jolt= t (keyword #f "str")) (if (jolt= G__122 "keyword?") (jolt= t (keyword #f "kw")) (if (jolt= G__122 "record?") (jolt-invoke (var-deref "jolt.passes.types" "record-t?") t) (if (jolt= G__122 "nil?") #f (if (jolt= G__122 "some?") #t jolt-nil))))))) jolt-nil))))))) pred-on))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "pure-node?" (letrec ((pure-node? (lambda (n) (let fnrec5771 ((n n)) (let* ((op (jolt-get n (keyword #f "op")))) (let* ((or__26__auto (jolt= op (keyword #f "const")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "local"))))))))) pure-node?) (let* ((_o$5772 (keyword #f "private")) (_o$5773 #t)) (jolt-hash-map _o$5772 _o$5773)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "test-local" (letrec ((test-local (lambda (test pred-name) (let fnrec5774 ((test test) (pred-name pred-name)) (if (jolt= (keyword #f "invoke") (jolt-get test (keyword #f "op"))) (let* ((f (jolt-get test (keyword #f "fn"))) (args (jolt-get test (keyword #f "args")))) (if (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= "clojure.core" (jolt-get f (keyword #f "ns"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= pred-name (jolt-get f (keyword #f "name"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count args)))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "local") (jolt-get (jolt-nth args 0) (keyword #f "op"))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto)) (jolt-get (jolt-nth args 0) (keyword #f "name")) jolt-nil)) jolt-nil))))) test-local) (let* ((_o$5775 (keyword #f "private")) (_o$5776 #t)) (jolt-hash-map _o$5775 _o$5776)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "narrow-nonnil" (letrec ((narrow-nonnil (lambda (tenv nm) (let fnrec5777 ((tenv tenv) (nm nm)) (let* ((t (jolt-get tenv nm))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "nilable?") t)) (jolt-assoc tenv nm (jolt-invoke (var-deref "jolt.passes.types.lattice" "strip-nilable") t)) tenv)))))) narrow-nonnil) (let* ((_o$5778 (keyword #f "private")) (_o$5779 #t)) (jolt-hash-map _o$5778 _o$5779)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "if-narrow" (letrec ((if-narrow (lambda (test tenv) (let fnrec5780 ((test test) (tenv tenv)) (let* ((somev (jolt-invoke (var-deref "jolt.passes.types" "test-local") test "some?")) (nilv (jolt-invoke (var-deref "jolt.passes.types" "test-local") test "nil?"))) (if (jolt= (keyword #f "local") (jolt-get test (keyword #f "op"))) (let* ((_o$5781 (jolt-invoke (var-deref "jolt.passes.types" "narrow-nonnil") tenv (jolt-get test (keyword #f "name")))) (_o$5782 tenv)) (jolt-vector _o$5781 _o$5782)) (if (jolt-truthy? somev) (let* ((_o$5783 (jolt-invoke (var-deref "jolt.passes.types" "narrow-nonnil") tenv somev)) (_o$5784 tenv)) (jolt-vector _o$5783 _o$5784)) (if (jolt-truthy? nilv) (let* ((_o$5785 tenv) (_o$5786 (jolt-invoke (var-deref "jolt.passes.types" "narrow-nonnil") tenv nilv))) (jolt-vector _o$5785 _o$5786)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$5787 tenv) (_o$5788 tenv)) (jolt-vector _o$5787 _o$5788)) jolt-nil))))))))) if-narrow) (let* ((_o$5789 (keyword #f "private")) (_o$5790 #t)) (jolt-hash-map _o$5789 _o$5790)))) + (def-var! "jolt.passes.types" "pure-node?" (letrec ((pure-node? (lambda (n) (let fnrec4944 ((n n)) (let* ((op (jolt-get n (keyword #f "op")))) (let* ((or__26__auto (jolt= op (keyword #f "const")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= op (keyword #f "local"))))))))) pure-node?))) (guard (e (#t #f)) (declare-var! "jolt.passes.types" "infer")) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "ty" (letrec ((ty (lambda (r) (let fnrec5791 ((r r)) (jolt-nth r 0))))) ty) (let* ((_o$5792 (keyword #f "private")) (_o$5793 #t)) (jolt-hash-map _o$5792 _o$5793)))) + (def-var! "jolt.passes.types" "ty" (letrec ((ty (lambda (r) (let fnrec4945 ((r r)) (jolt-nth r 0))))) ty))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "nd" (letrec ((nd (lambda (r) (let fnrec5794 ((r r)) (jolt-nth r 1))))) nd) (let* ((_o$5795 (keyword #f "private")) (_o$5796 #t)) (jolt-hash-map _o$5795 _o$5796)))) + (def-var! "jolt.passes.types" "nd" (letrec ((nd (lambda (r) (let fnrec4946 ((r r)) (jolt-nth r 1))))) nd))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "self-rec-argtys" (letrec ((self-rec-argtys (lambda (args ares self-params) (let fnrec5797 ((args args) (ares ares) (self-params self-params)) (let* ((_a$5801 (var-deref "clojure.core" "mapv")) (_a$5802 (lambda (i) (let fnrec5798 ((i i)) (let* ((a (jolt-nth args i))) (if (jolt-truthy? (let* ((and__25__auto self-params)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n< i (jolt-count self-params)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get a (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((_a$5799 (jolt-get a (keyword #f "name"))) (_a$5800 (jolt-nth self-params i))) (jolt= _a$5799 _a$5800)) and__25__auto)) and__25__auto)) and__25__auto))) jolt-nil (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares i))))))) (_a$5803 (jolt-range (jolt-count ares)))) (jolt-invoke _a$5801 _a$5802 _a$5803)))))) self-rec-argtys) (let* ((_o$5804 (keyword #f "private")) (_o$5805 #t)) (jolt-hash-map _o$5804 _o$5805)))) + (def-var-with-meta! "jolt.passes.types" "hof-table" (let* ((_o$4963 "map") (_o$4964 (let* ((_o$4947 (keyword #f "epos")) (_o$4948 0)) (jolt-hash-map _o$4947 _o$4948))) (_o$4965 "mapv") (_o$4966 (let* ((_o$4949 (keyword #f "epos")) (_o$4950 0)) (jolt-hash-map _o$4949 _o$4950))) (_o$4967 "filter") (_o$4968 (let* ((_o$4951 (keyword #f "epos")) (_o$4952 0)) (jolt-hash-map _o$4951 _o$4952))) (_o$4969 "filterv") (_o$4970 (let* ((_o$4953 (keyword #f "epos")) (_o$4954 0)) (jolt-hash-map _o$4953 _o$4954))) (_o$4971 "keep") (_o$4972 (let* ((_o$4955 (keyword #f "epos")) (_o$4956 0)) (jolt-hash-map _o$4955 _o$4956))) (_o$4973 "remove") (_o$4974 (let* ((_o$4957 (keyword #f "epos")) (_o$4958 0)) (jolt-hash-map _o$4957 _o$4958))) (_o$4975 "run!") (_o$4976 (let* ((_o$4959 (keyword #f "epos")) (_o$4960 0)) (jolt-hash-map _o$4959 _o$4960))) (_o$4977 "mapcat") (_o$4978 (let* ((_o$4961 (keyword #f "epos")) (_o$4962 0)) (jolt-hash-map _o$4961 _o$4962)))) (jolt-hash-map _o$4963 _o$4964 _o$4965 _o$4966 _o$4967 _o$4968 _o$4969 _o$4970 _o$4971 _o$4972 _o$4973 _o$4974 _o$4975 _o$4976 _o$4977 _o$4978)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "dbl-arith-ops" (let* ((_o$5806 "+") (_o$5807 "-") (_o$5808 "*") (_o$5809 "/") (_o$5810 "min") (_o$5811 "max") (_o$5812 "inc") (_o$5813 "dec")) (jolt-hash-set _o$5806 _o$5807 _o$5808 _o$5809 _o$5810 _o$5811 _o$5812 _o$5813)) (let* ((_o$5814 (keyword #f "private")) (_o$5815 #t)) (jolt-hash-map _o$5814 _o$5815)))) + (def-var! "jolt.passes.types" "infer-fn-seeded" (letrec ((infer-fn-seeded (lambda (node seeds tenv env) (let fnrec4979 ((node node) (seeds seeds) (tenv tenv) (env env)) (let* ((res (let* ((_a$4990 (var-deref "clojure.core" "mapv")) (_a$4991 (lambda (a) (let fnrec4980 ((a a)) (let* ((params (jolt-get a (keyword #f "params"))) (pe (let* ((_a$4985 (lambda (e i) (let fnrec4981 ((e e) (i i)) (let* ((_a$4982 e) (_a$4983 (jolt-nth params i)) (_a$4984 (let* ((s (jolt-get seeds i))) (if (jolt-truthy? s) s (keyword #f "any"))))) (jolt-assoc _a$4982 _a$4983 _a$4984))))) (_a$4986 tenv) (_a$4987 (jolt-range (jolt-count params)))) (jolt-reduce _a$4985 _a$4986 _a$4987))) (pe (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) (keyword #f "any")) pe)) (br (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-get a (keyword #f "body")) pe env))) (let* ((_o$4988 (jolt-invoke (var-deref "jolt.passes.types" "ty") br)) (_o$4989 (jolt-assoc a (keyword #f "body") (jolt-invoke (var-deref "jolt.passes.types" "nd") br)))) (jolt-vector _o$4988 _o$4989)))))) (_a$4992 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$4990 _a$4991 _a$4992))) (rets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec4993 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) res)) (ret (if (jolt-empty? rets) (keyword #f "any") (let* ((_a$4994 (var-deref "jolt.passes.types.lattice" "join")) (_a$4995 (jolt-first rets)) (_a$4996 (jolt-rest rets))) (jolt-reduce _a$4994 _a$4995 _a$4996))))) (let* ((_o$4998 ret) (_o$4999 (jolt-assoc node (keyword #f "arities") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec4997 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) res)))) (jolt-vector _o$4998 _o$4999))))))) infer-fn-seeded))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "int-lit-node?" (letrec ((int-lit-node? (lambda (n) (let fnrec5816 ((n n)) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get n (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((v (jolt-get n (keyword #f "val")))) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "integer?") v) and__25__auto))) and__25__auto)))))) int-lit-node?) (let* ((_o$5817 (keyword #f "private")) (_o$5818 #t)) (jolt-hash-map _o$5817 _o$5818)))) + (def-var! "jolt.passes.types" "infer-pred-fold" (letrec ((infer-pred-fold (lambda (node fnode cn args tenv env) (let fnrec5000 ((node node) (fnode fnode) (cn cn) (args args) (tenv tenv) (env env)) (let* ((ar (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (v (jolt-invoke (var-deref "jolt.passes.types" "pred-on") cn (jolt-invoke (var-deref "jolt.passes.types" "ty") ar)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") v)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types" "pure-node?") (jolt-invoke (var-deref "jolt.passes.types" "nd") ar)) and__25__auto))) (let* ((_o$5005 (keyword #f "any")) (_o$5006 (let* ((_o$5001 (keyword #f "op")) (_o$5002 (keyword #f "const")) (_o$5003 (keyword #f "val")) (_o$5004 v)) (jolt-hash-map _o$5001 _o$5002 _o$5003 _o$5004)))) (jolt-vector _o$5005 _o$5006)) (let* ((_o$5007 (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env)) (_o$5008 (jolt-assoc node (keyword #f "args") (jolt-vector (jolt-invoke (var-deref "jolt.passes.types" "nd") ar))))) (jolt-vector _o$5007 _o$5008)))))))) infer-pred-fold))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "dbl-arith?" (letrec ((dbl-arith? (lambda (ares argnodes) (let fnrec5819 ((ares ares) (argnodes argnodes)) (let* ((and__25__auto (jolt-pos? (jolt-count ares)))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$5821 (var-deref "clojure.core" "every?")) (_a$5822 (lambda (i) (let fnrec5820 ((i i)) (let* ((or__26__auto (jolt= (keyword #f "double") (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares i))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.passes.types" "int-lit-node?") (jolt-nth argnodes i))))))) (_a$5823 (jolt-range (jolt-count ares)))) (jolt-invoke _a$5821 _a$5822 _a$5823)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some") (lambda (r) (let fnrec5824 ((r r)) (jolt= (keyword #f "double") (jolt-invoke (var-deref "jolt.passes.types" "ty") r)))) ares) and__25__auto)) and__25__auto)))))) dbl-arith?) (let* ((_o$5825 (keyword #f "private")) (_o$5826 #t)) (jolt-hash-map _o$5825 _o$5826)))) + (def-var! "jolt.passes.types" "infer-kw-lookup" (letrec ((infer-kw-lookup (lambda (node fnode args n tenv env) (let fnrec5009 ((node node) (fnode fnode) (args args) (n n) (tenv tenv) (env env)) (let* ((mr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (mt (jolt-invoke (var-deref "jolt.passes.types" "ty") mr)) (msub (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") mt)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mark-struct") (jolt-invoke (var-deref "jolt.passes.types" "nd") mr) mt) (jolt-invoke (var-deref "jolt.passes.types" "nd") mr))) (ft (jolt-invoke (var-deref "jolt.passes.types.lattice" "field-type") mt (jolt-get fnode (keyword #f "val")))) (dr (if (jolt= n 2) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env) jolt-nil))) (let* ((_o$5012 (if (jolt-truthy? dr) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") ft (jolt-invoke (var-deref "jolt.passes.types" "ty") dr)) ft)) (_o$5013 (jolt-assoc node (keyword #f "args") (if (jolt-truthy? dr) (let* ((_o$5010 msub) (_o$5011 (jolt-invoke (var-deref "jolt.passes.types" "nd") dr))) (jolt-vector _o$5010 _o$5011)) (jolt-vector msub))))) (jolt-vector _o$5012 _o$5013))))))) infer-kw-lookup))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "hof-table" (let* ((_o$5843 "map") (_o$5844 (let* ((_o$5827 (keyword #f "epos")) (_o$5828 0)) (jolt-hash-map _o$5827 _o$5828))) (_o$5845 "mapv") (_o$5846 (let* ((_o$5829 (keyword #f "epos")) (_o$5830 0)) (jolt-hash-map _o$5829 _o$5830))) (_o$5847 "filter") (_o$5848 (let* ((_o$5831 (keyword #f "epos")) (_o$5832 0)) (jolt-hash-map _o$5831 _o$5832))) (_o$5849 "filterv") (_o$5850 (let* ((_o$5833 (keyword #f "epos")) (_o$5834 0)) (jolt-hash-map _o$5833 _o$5834))) (_o$5851 "keep") (_o$5852 (let* ((_o$5835 (keyword #f "epos")) (_o$5836 0)) (jolt-hash-map _o$5835 _o$5836))) (_o$5853 "remove") (_o$5854 (let* ((_o$5837 (keyword #f "epos")) (_o$5838 0)) (jolt-hash-map _o$5837 _o$5838))) (_o$5855 "run!") (_o$5856 (let* ((_o$5839 (keyword #f "epos")) (_o$5840 0)) (jolt-hash-map _o$5839 _o$5840))) (_o$5857 "mapcat") (_o$5858 (let* ((_o$5841 (keyword #f "epos")) (_o$5842 0)) (jolt-hash-map _o$5841 _o$5842)))) (jolt-hash-map _o$5843 _o$5844 _o$5845 _o$5846 _o$5847 _o$5848 _o$5849 _o$5850 _o$5851 _o$5852 _o$5853 _o$5854 _o$5855 _o$5856 _o$5857 _o$5858)) (let* ((_o$5859 (keyword #f "private")) (_o$5860 #t)) (jolt-hash-map _o$5859 _o$5860)))) + (def-var! "jolt.passes.types" "infer-get-lookup" (letrec ((infer-get-lookup (lambda (node args n tenv env) (let fnrec5014 ((node node) (args args) (n n) (tenv tenv) (env env)) (let* ((mr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (mt (jolt-invoke (var-deref "jolt.passes.types" "ty") mr)) (msub (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") mt)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mark-struct") (jolt-invoke (var-deref "jolt.passes.types" "nd") mr) mt) (jolt-invoke (var-deref "jolt.passes.types" "nd") mr))) (kr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env)) (ft (jolt-invoke (var-deref "jolt.passes.types.lattice" "field-type") mt (jolt-get (jolt-nth args 1) (keyword #f "val")))) (dr (if (jolt= n 3) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 2) tenv env) jolt-nil))) (let* ((_o$5020 (if (jolt-truthy? dr) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") ft (jolt-invoke (var-deref "jolt.passes.types" "ty") dr)) ft)) (_o$5021 (jolt-assoc node (keyword #f "args") (if (jolt-truthy? dr) (let* ((_o$5015 msub) (_o$5016 (jolt-invoke (var-deref "jolt.passes.types" "nd") kr)) (_o$5017 (jolt-invoke (var-deref "jolt.passes.types" "nd") dr))) (jolt-vector _o$5015 _o$5016 _o$5017)) (let* ((_o$5018 msub) (_o$5019 (jolt-invoke (var-deref "jolt.passes.types" "nd") kr))) (jolt-vector _o$5018 _o$5019)))))) (jolt-vector _o$5020 _o$5021))))))) infer-get-lookup))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-fn-seeded" (letrec ((infer-fn-seeded (lambda (node seeds tenv env) (let fnrec5861 ((node node) (seeds seeds) (tenv tenv) (env env)) (let* ((res (let* ((_a$5872 (var-deref "clojure.core" "mapv")) (_a$5873 (lambda (a) (let fnrec5862 ((a a)) (let* ((params (jolt-get a (keyword #f "params"))) (pe (let* ((_a$5867 (lambda (e i) (let fnrec5863 ((e e) (i i)) (let* ((_a$5864 e) (_a$5865 (jolt-nth params i)) (_a$5866 (let* ((s (jolt-get seeds i))) (if (jolt-truthy? s) s (keyword #f "any"))))) (jolt-assoc _a$5864 _a$5865 _a$5866))))) (_a$5868 tenv) (_a$5869 (jolt-range (jolt-count params)))) (jolt-reduce _a$5867 _a$5868 _a$5869))) (pe (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) (keyword #f "any")) pe)) (br (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-get a (keyword #f "body")) pe env))) (let* ((_o$5870 (jolt-invoke (var-deref "jolt.passes.types" "ty") br)) (_o$5871 (jolt-assoc a (keyword #f "body") (jolt-invoke (var-deref "jolt.passes.types" "nd") br)))) (jolt-vector _o$5870 _o$5871)))))) (_a$5874 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$5872 _a$5873 _a$5874))) (rets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5875 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) res)) (ret (if (jolt-empty? rets) (keyword #f "any") (let* ((_a$5876 (var-deref "jolt.passes.types.lattice" "join")) (_a$5877 (jolt-first rets)) (_a$5878 (jolt-rest rets))) (jolt-reduce _a$5876 _a$5877 _a$5878))))) (let* ((_o$5880 ret) (_o$5881 (jolt-assoc node (keyword #f "arities") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5879 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) res)))) (jolt-vector _o$5880 _o$5881))))))) infer-fn-seeded) (let* ((_o$5882 (keyword #f "private")) (_o$5883 #t) (_o$5884 (keyword #f "doc")) (_o$5885 "Infer a fn-literal passed to a HOF, seeding the given params to element/accum\n types (seeds: param-index -> type), other params :any, captured locals from\n tenv. Returns [ret-type node'] \x2014; ret is the lub of arity tail types, used to\n type the HOF result (e.g. reduce's accumulator, mapv's element).")) (jolt-hash-map _o$5882 _o$5883 _o$5884 _o$5885)))) + (def-var! "jolt.passes.types" "infer-reduce-hof" (letrec ((infer-reduce-hof (lambda (node args n tenv env) (let fnrec5022 ((node node) (args args) (n n) (tenv tenv) (env env)) (let* ((three (>= n 3)) (coll-r (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args (if (jolt-truthy? three) 2 1)) tenv env)) (init-r (if (jolt-truthy? three) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env) jolt-nil)) (et (let* ((ct (jolt-invoke (var-deref "jolt.passes.types" "ty") coll-r))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") ct)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") ct) (keyword #f "any")))) (init-t (if (jolt-truthy? init-r) (jolt-invoke (var-deref "jolt.passes.types" "ty") init-r) (keyword #f "any"))) (fn-r (let* ((_a$5027 (var-deref "jolt.passes.types" "infer-fn-seeded")) (_a$5028 (jolt-nth args 0)) (_a$5029 (let* ((_o$5023 0) (_o$5024 init-t) (_o$5025 1) (_o$5026 et)) (jolt-hash-map _o$5023 _o$5024 _o$5025 _o$5026))) (_a$5030 tenv) (_a$5031 env)) (jolt-invoke _a$5027 _a$5028 _a$5029 _a$5030 _a$5031)))) (let* ((_o$5037 (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") init-t (jolt-invoke (var-deref "jolt.passes.types" "ty") fn-r))) (_o$5038 (jolt-assoc node (keyword #f "args") (if (jolt-truthy? three) (let* ((_o$5032 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5033 (jolt-invoke (var-deref "jolt.passes.types" "nd") init-r)) (_o$5034 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5032 _o$5033 _o$5034)) (let* ((_o$5035 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5036 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5035 _o$5036)))))) (jolt-vector _o$5037 _o$5038))))))) infer-reduce-hof))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-pred-fold" (letrec ((infer-pred-fold (lambda (node fnode cn args tenv env) (let fnrec5886 ((node node) (fnode fnode) (cn cn) (args args) (tenv tenv) (env env)) (let* ((ar (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (v (jolt-invoke (var-deref "jolt.passes.types" "pred-on") cn (jolt-invoke (var-deref "jolt.passes.types" "ty") ar)))) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-nil? v)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types" "pure-node?") (jolt-invoke (var-deref "jolt.passes.types" "nd") ar)) and__25__auto))) (let* ((_o$5891 (keyword #f "any")) (_o$5892 (let* ((_o$5887 (keyword #f "op")) (_o$5888 (keyword #f "const")) (_o$5889 (keyword #f "val")) (_o$5890 v)) (jolt-hash-map _o$5887 _o$5888 _o$5889 _o$5890)))) (jolt-vector _o$5891 _o$5892)) (let* ((_o$5893 (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env)) (_o$5894 (jolt-assoc node (keyword #f "args") (jolt-vector (jolt-invoke (var-deref "jolt.passes.types" "nd") ar))))) (jolt-vector _o$5893 _o$5894)))))))) infer-pred-fold) (let* ((_o$5895 (keyword #f "private")) (_o$5896 #t) (_o$5897 (keyword #f "doc")) (_o$5898 "A type predicate over a single side-effect-free arg whose type PROVES the answer\n folds to a boolean constant \x2014; eliminating the call, and (once const-fold runs\n after inference) collapsing any `if` it gates. Falls back to the normal call path\n when the answer isn't provable or the arg is impure.")) (jolt-hash-map _o$5895 _o$5896 _o$5897 _o$5898)))) + (def-var! "jolt.passes.types" "infer-seq-hof" (letrec ((infer-seq-hof (lambda (node cn args tenv env) (let fnrec5039 ((node node) (cn cn) (args args) (tenv tenv) (env env)) (let* ((coll-r (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env)) (et (let* ((ct (jolt-invoke (var-deref "jolt.passes.types" "ty") coll-r))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") ct)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") ct) (keyword #f "any")))) (fn-r (let* ((_a$5042 (var-deref "jolt.passes.types" "infer-fn-seeded")) (_a$5043 (jolt-nth args 0)) (_a$5044 (let* ((_o$5040 (jolt-get (jolt-get (var-deref "jolt.passes.types" "hof-table") cn) (keyword #f "epos"))) (_o$5041 et)) (jolt-hash-map _o$5040 _o$5041))) (_a$5045 tenv) (_a$5046 env)) (jolt-invoke _a$5042 _a$5043 _a$5044 _a$5045 _a$5046))) (rt (if (jolt= cn "mapv") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (jolt-invoke (var-deref "jolt.passes.types" "ty") fn-r)) (if (jolt= cn "filterv") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") et) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil))))) (let* ((_o$5049 rt) (_o$5050 (jolt-assoc node (keyword #f "args") (let* ((_o$5047 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5048 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5047 _o$5048))))) (jolt-vector _o$5049 _o$5050))))))) infer-seq-hof))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-kw-lookup" (letrec ((infer-kw-lookup (lambda (node fnode args n tenv env) (let fnrec5899 ((node node) (fnode fnode) (args args) (n n) (tenv tenv) (env env)) (let* ((mr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (mt (jolt-invoke (var-deref "jolt.passes.types" "ty") mr)) (msub (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") mt)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mark-struct") (jolt-invoke (var-deref "jolt.passes.types" "nd") mr) mt) (jolt-invoke (var-deref "jolt.passes.types" "nd") mr))) (ft (jolt-invoke (var-deref "jolt.passes.types.lattice" "field-type") mt (jolt-get fnode (keyword #f "val")))) (dr (if (jolt= n 2) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env) jolt-nil)) (rt (if (jolt-truthy? dr) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") ft (jolt-invoke (var-deref "jolt.passes.types" "ty") dr)) ft)) (node_PRIME_ (jolt-assoc node (keyword #f "args") (if (jolt-truthy? dr) (let* ((_o$5900 msub) (_o$5901 (jolt-invoke (var-deref "jolt.passes.types" "nd") dr))) (jolt-vector _o$5900 _o$5901)) (jolt-vector msub))))) (let* ((_o$5902 rt) (_o$5903 (if (jolt= rt (keyword #f "double")) (jolt-assoc node_PRIME_ (keyword #f "num-read") (keyword #f "double")) node_PRIME_))) (jolt-vector _o$5902 _o$5903))))))) infer-kw-lookup) (let* ((_o$5904 (keyword #f "private")) (_o$5905 #t) (_o$5906 (keyword #f "doc")) (_o$5907 "(:k m) / (:k m default): the result is m's field type, and if m is a struct the\n subject is tagged so the back end drops the guard \x2014; this types nested access end\n to end (RFC 0005).")) (jolt-hash-map _o$5904 _o$5905 _o$5906 _o$5907)))) + (def-var! "jolt.passes.types" "infer-conj-into" (letrec ((infer-conj-into (lambda (node fnode cn args n tenv env) (let fnrec5051 ((node node) (fnode fnode) (cn cn) (args args) (n n) (tenv tenv) (env env)) (let* ((ares (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec5052 ((a a)) (jolt-invoke (var-deref "jolt.passes.types" "infer") a tenv env))) args)) (base (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0))) (rest-ts (let* ((_a$5054 (var-deref "clojure.core" "mapv")) (_a$5055 (lambda (r) (let fnrec5053 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r)))) (_a$5056 (jolt-rest ares))) (jolt-invoke _a$5054 _a$5055 _a$5056))) (rt (if (jolt-truthy? (let* ((and__25__auto (jolt= cn "conj"))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") base) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (jolt-reduce (var-deref "jolt.passes.types.lattice" "join") (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") base) rest-ts)) (if (jolt-truthy? (let* ((and__25__auto (jolt= cn "into"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") base))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 2 n))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") (jolt-nth rest-ts 0)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$5057 (var-deref "jolt.passes.types.lattice" "join")) (_a$5058 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") base)) (_a$5059 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") (jolt-nth rest-ts 0)))) (jolt-invoke _a$5057 _a$5058 _a$5059))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env) jolt-nil))))) (let* ((_o$5061 rt) (_o$5062 (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5060 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) ares)))) (jolt-vector _o$5061 _o$5062))))))) infer-conj-into))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-get-lookup" (letrec ((infer-get-lookup (lambda (node args n tenv env) (let fnrec5908 ((node node) (args args) (n n) (tenv tenv) (env env)) (let* ((mr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 0) tenv env)) (mt (jolt-invoke (var-deref "jolt.passes.types" "ty") mr)) (msub (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") mt)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mark-struct") (jolt-invoke (var-deref "jolt.passes.types" "nd") mr) mt) (jolt-invoke (var-deref "jolt.passes.types" "nd") mr))) (kr (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env)) (ft (jolt-invoke (var-deref "jolt.passes.types.lattice" "field-type") mt (jolt-get (jolt-nth args 1) (keyword #f "val")))) (dr (if (jolt= n 3) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 2) tenv env) jolt-nil)) (rt (if (jolt-truthy? dr) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") ft (jolt-invoke (var-deref "jolt.passes.types" "ty") dr)) ft)) (node_PRIME_ (jolt-assoc node (keyword #f "args") (if (jolt-truthy? dr) (let* ((_o$5909 msub) (_o$5910 (jolt-invoke (var-deref "jolt.passes.types" "nd") kr)) (_o$5911 (jolt-invoke (var-deref "jolt.passes.types" "nd") dr))) (jolt-vector _o$5909 _o$5910 _o$5911)) (let* ((_o$5912 msub) (_o$5913 (jolt-invoke (var-deref "jolt.passes.types" "nd") kr))) (jolt-vector _o$5912 _o$5913)))))) (let* ((_o$5914 rt) (_o$5915 (if (jolt= rt (keyword #f "double")) (jolt-assoc node_PRIME_ (keyword #f "num-read") (keyword #f "double")) node_PRIME_))) (jolt-vector _o$5914 _o$5915))))))) infer-get-lookup) (let* ((_o$5916 (keyword #f "private")) (_o$5917 #t) (_o$5918 (keyword #f "doc")) (_o$5919 "(get m :k [default]): the keyword-lookup result type, when the key is a constant\n keyword.")) (jolt-hash-map _o$5916 _o$5917 _o$5918 _o$5919)))) + (def-var! "jolt.passes.types" "infer-call" (letrec ((infer-call (lambda (node fnode iscall-var cn args n tenv env) (let fnrec5063 ((node node) (fnode fnode) (iscall-var iscall-var) (cn cn) (args args) (n n) (tenv tenv) (env env)) (let* ((fr (if (jolt-not iscall-var) (jolt-invoke (var-deref "jolt.passes.types" "infer") fnode tenv env) jolt-nil)) (fnode_PRIME_ (if (jolt-truthy? iscall-var) fnode (jolt-invoke (var-deref "jolt.passes.types" "nd") fr))) (callee-t (if (jolt-truthy? iscall-var) (let* ((_a$5064 (jolt-get env (keyword #f "vtypes"))) (_a$5065 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$5064 _a$5065)) (jolt-invoke (var-deref "jolt.passes.types" "ty") fr))) (ares (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec5066 ((a a)) (jolt-invoke (var-deref "jolt.passes.types" "infer") a tenv env))) args))) (begin (if (jolt-truthy? iscall-var) (let* ((_a$5070 (var-deref "clojure.core" "swap!")) (_a$5071 (jolt-get env (keyword #f "calls"))) (_a$5072 jolt-conj) (_a$5073 (let* ((_o$5068 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)) (_o$5069 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5067 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) ares))) (jolt-vector _o$5068 _o$5069)))) (jolt-invoke _a$5070 _a$5071 _a$5072 _a$5073)) jolt-nil) (if (jolt-truthy? (jolt-get env (keyword #f "checking?"))) (let* ((ats (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5074 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) ares)) (pos (jolt-get node (keyword #f "pos")))) (begin (if (jolt-truthy? cn) (jolt-invoke (var-deref "jolt.passes.types.check" "check-invoke") cn args ats pos env) jolt-nil) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-callable?") callee-t)) (let* ((_a$5083 (var-deref "clojure.core" "swap!")) (_a$5084 (jolt-get env (keyword #f "diags"))) (_a$5085 jolt-conj) (_a$5086 (let* ((_o$5075 (keyword #f "op")) (_o$5076 (keyword #f "call")) (_o$5077 (keyword #f "type")) (_o$5078 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") callee-t)) (_o$5079 (keyword #f "pos")) (_o$5080 pos) (_o$5081 (keyword #f "msg")) (_o$5082 (jolt-invoke (var-deref "clojure.core" "str") "cannot call " (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") callee-t) " as a function"))) (jolt-hash-map _o$5075 _o$5076 _o$5077 _o$5078 _o$5079 _o$5080 _o$5081 _o$5082)))) (jolt-invoke _a$5083 _a$5084 _a$5085 _a$5086)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-get env (keyword #f "strict?")))) (if (jolt-truthy? and__25__auto) iscall-var and__25__auto))) (let* ((k (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)) (usig (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "user-sigs"))) k))) (if (jolt-truthy? usig) (jolt-invoke (var-deref "jolt.passes.types" "check-user-call") k usig ats pos env) jolt-nil)) jolt-nil))) jolt-nil) (let* ((pm (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (let* ((_a$5087 (jolt-get env (keyword #f "protocol-methods"))) (_a$5088 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$5087 _a$5088)) and__25__auto))) (rtype (if (jolt-truthy? (let* ((and__25__auto pm)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (jolt-get (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0)) (keyword #f "type")) jolt-nil)) (base (jolt-assoc node (keyword #f "fn") fnode_PRIME_ (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5089 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) ares)))) (let* ((_o$5097 (if (jolt= cn "range") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "num")) (if (jolt-truthy? (let* ((and__25__auto cn)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types" "elem-fns") cn))) (if (jolt-truthy? and__25__auto) (> n 0) and__25__auto)) and__25__auto))) (let* ((a0 (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") a0)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") a0) (keyword #f "any"))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env) jolt-nil)))) (_o$5098 (if (jolt-truthy? rtype) (let* ((_a$5090 base) (_a$5091 (keyword #f "devirt-type")) (_a$5092 rtype) (_a$5093 (keyword #f "devirt-proto")) (_a$5094 (jolt-nth pm 0)) (_a$5095 (keyword #f "devirt-method")) (_a$5096 (jolt-nth pm 1))) (jolt-assoc _a$5090 _a$5091 _a$5092 _a$5093 _a$5094 _a$5095 _a$5096)) base))) (jolt-vector _o$5097 _o$5098))))))))) infer-call))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-reduce-hof" (letrec ((infer-reduce-hof (lambda (node args n tenv env) (let fnrec5920 ((node node) (args args) (n n) (tenv tenv) (env env)) (let* ((three (jolt-n>= n 3)) (coll-r (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args (if (jolt-truthy? three) 2 1)) tenv env)) (init-r (if (jolt-truthy? three) (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env) jolt-nil)) (et (let* ((ct (jolt-invoke (var-deref "jolt.passes.types" "ty") coll-r))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") ct)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") ct) (keyword #f "any")))) (init-t (if (jolt-truthy? init-r) (jolt-invoke (var-deref "jolt.passes.types" "ty") init-r) (keyword #f "any"))) (fn-r (let* ((_a$5925 (var-deref "jolt.passes.types" "infer-fn-seeded")) (_a$5926 (jolt-nth args 0)) (_a$5927 (let* ((_o$5921 0) (_o$5922 init-t) (_o$5923 1) (_o$5924 et)) (jolt-hash-map _o$5921 _o$5922 _o$5923 _o$5924))) (_a$5928 tenv) (_a$5929 env)) (jolt-invoke _a$5925 _a$5926 _a$5927 _a$5928 _a$5929)))) (let* ((_o$5935 (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") init-t (jolt-invoke (var-deref "jolt.passes.types" "ty") fn-r))) (_o$5936 (jolt-assoc node (keyword #f "args") (if (jolt-truthy? three) (let* ((_o$5930 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5931 (jolt-invoke (var-deref "jolt.passes.types" "nd") init-r)) (_o$5932 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5930 _o$5931 _o$5932)) (let* ((_o$5933 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5934 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5933 _o$5934)))))) (jolt-vector _o$5935 _o$5936))))))) infer-reduce-hof) (let* ((_o$5937 (keyword #f "private")) (_o$5938 #t) (_o$5939 (keyword #f "doc")) (_o$5940 "reduce over a typed vector with a fn-literal: seed the closure's accumulator\n (param 0) to the init type and its element (param 1) to the vector's element\n type, so its body \x2014; and any calls it makes \x2014; see those types.")) (jolt-hash-map _o$5937 _o$5938 _o$5939 _o$5940)))) + (def-var! "jolt.passes.types" "infer-invoke" (letrec ((infer-invoke (lambda (node tenv env) (let fnrec5099 ((node node) (tenv tenv) (env env)) (let* ((fnode (jolt-get node (keyword #f "fn"))) (iscall-var (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op")))) (cn (if (jolt-truthy? (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto))) (jolt-get fnode (keyword #f "name")) jolt-nil)) (args (jolt-get node (keyword #f "args"))) (n (jolt-count args))) (if (jolt-truthy? (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types" "fold-preds") cn))) (if (jolt-truthy? and__25__auto) (jolt= n 1) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-pred-fold") node fnode cn args tenv env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") fnode))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= n 1))) (if (jolt-truthy? and__25__auto) (<= n 2) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-kw-lookup") node fnode args n tenv env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "get-callee?") fnode))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= n 2))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get (jolt-nth args 1) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get (jolt-nth args 1) (keyword #f "val"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-get-lookup") node args n tenv env) (if (jolt-truthy? (let* ((and__25__auto (jolt= cn "reduce"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= n 2))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get (jolt-nth args 0) (keyword #f "op"))) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-reduce-hof") node args n tenv env) (if (jolt-truthy? (let* ((and__25__auto cn)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get (var-deref "jolt.passes.types" "hof-table") cn))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (>= n 2))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get (jolt-nth args 0) (keyword #f "op"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-seq-hof") node cn args tenv env) (if (jolt-truthy? (let* ((and__25__auto (let* ((or__26__auto (jolt= cn "conj"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= cn "into"))))) (if (jolt-truthy? and__25__auto) (>= n 1) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-conj-into") node fnode cn args n tenv env) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "infer-call") node fnode iscall-var cn args n tenv env) jolt-nil)))))))))))) infer-invoke))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-seq-hof" (letrec ((infer-seq-hof (lambda (node cn args tenv env) (let fnrec5941 ((node node) (cn cn) (args args) (tenv tenv) (env env)) (let* ((coll-r (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-nth args 1) tenv env)) (et (let* ((ct (jolt-invoke (var-deref "jolt.passes.types" "ty") coll-r))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") ct)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") ct) (keyword #f "any")))) (fn-r (let* ((_a$5944 (var-deref "jolt.passes.types" "infer-fn-seeded")) (_a$5945 (jolt-nth args 0)) (_a$5946 (let* ((_o$5942 (jolt-get (jolt-get (var-deref "jolt.passes.types" "hof-table") cn) (keyword #f "epos"))) (_o$5943 et)) (jolt-hash-map _o$5942 _o$5943))) (_a$5947 tenv) (_a$5948 env)) (jolt-invoke _a$5944 _a$5945 _a$5946 _a$5947 _a$5948))) (rt (if (jolt= cn "mapv") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (jolt-invoke (var-deref "jolt.passes.types" "ty") fn-r)) (if (jolt= cn "filterv") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") et) (if (jolt-truthy? (keyword #f "else")) (keyword #f "any") jolt-nil))))) (let* ((_o$5951 rt) (_o$5952 (jolt-assoc node (keyword #f "args") (let* ((_o$5949 (jolt-invoke (var-deref "jolt.passes.types" "nd") fn-r)) (_o$5950 (jolt-invoke (var-deref "jolt.passes.types" "nd") coll-r))) (jolt-vector _o$5949 _o$5950))))) (jolt-vector _o$5951 _o$5952))))))) infer-seq-hof) (let* ((_o$5953 (keyword #f "private")) (_o$5954 #t) (_o$5955 (keyword #f "doc")) (_o$5956 "map/mapv/filter/... over a typed vector with a fn-literal: seed the fn's element\n param; mapv/filterv produce a typed vector.")) (jolt-hash-map _o$5953 _o$5954 _o$5955 _o$5956)))) + (def-var! "jolt.passes.types" "infer" (letrec ((infer (lambda (node tenv env) (let fnrec5100 ((node node) (tenv tenv) (env env)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "const")) (let* ((_o$5101 (let* ((v (jolt-get node (keyword #f "val")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") v)) (keyword #f "num") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") v)) (keyword #f "str") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") v)) (keyword #f "kw") (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") v))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= #f v)))) (keyword #f "any") (if (jolt-truthy? (keyword #f "else")) (keyword #f "truthy") jolt-nil))))))) (_o$5102 node)) (jolt-vector _o$5101 _o$5102)) (if (jolt= op (keyword #f "local")) (let* ((t (jolt-get tenv (jolt-get node (keyword #f "name"))))) (let* ((_o$5103 (if (jolt-truthy? t) t (keyword #f "any"))) (_o$5104 (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") t)) (let* ((n (jolt-assoc node (keyword #f "hint") (keyword #f "struct")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "type-shape") t)) (jolt-assoc n (keyword #f "shape") (jolt-invoke (var-deref "jolt.passes.types.lattice" "type-shape") t)) n)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) (jolt-assoc node (keyword #f "hint") (keyword #f "vector")) (if (jolt-truthy? (keyword #f "else")) node jolt-nil))))) (jolt-vector _o$5103 _o$5104))) (if (jolt= op (keyword #f "map")) (let* ((pairs (jolt-get node (keyword #f "pairs"))) (res (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (pr) (let fnrec5105 ((pr pr)) (let* ((kr (jolt-invoke infer (jolt-nth pr 0) tenv env)) (vr (jolt-invoke infer (jolt-nth pr 1) tenv env))) (let* ((_o$5106 (jolt-nth kr 1)) (_o$5107 (jolt-nth vr 1)) (_o$5108 (jolt-nth vr 0)) (_o$5109 (jolt-get (jolt-nth pr 0) (keyword #f "val")))) (jolt-vector _o$5106 _o$5107 _o$5108 _o$5109))))) pairs)) (struct? (let* ((and__25__auto (> (jolt-count res) 0))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "every?") (lambda (pr) (let fnrec5110 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth pr 0)))) pairs))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (r) (let fnrec5111 ((r r)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "truthy-type?") (jolt-nth r 2)))) res) and__25__auto)) and__25__auto))) (base (if (jolt-truthy? struct?) (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$5116 (lambda (m r) (let fnrec5112 ((m m) (r r)) (let* ((_a$5113 m) (_a$5114 (jolt-nth r 3)) (_a$5115 (jolt-nth r 2))) (jolt-assoc _a$5113 _a$5114 _a$5115))))) (_a$5117 (jolt-hash-map)) (_a$5118 res)) (jolt-reduce _a$5116 _a$5117 _a$5118))) (var-deref "jolt.passes.types.lattice" "type-depth")) jolt-nil)) (shp (if (jolt-truthy? (let* ((and__25__auto (jolt-get env (keyword #f "map-shapes?")))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto base)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") base) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "shape-order") (jolt-keys (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") base))) jolt-nil)) (t (if (jolt-truthy? base) (if (jolt-truthy? shp) (jolt-assoc base (keyword #f "shape") shp) base) (keyword #f "any"))) (node_PRIME_ (jolt-assoc node (keyword #f "pairs") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5119 ((r r)) (let* ((_o$5120 (jolt-nth r 0)) (_o$5121 (jolt-nth r 1))) (jolt-vector _o$5120 _o$5121)))) res)))) (let* ((_o$5122 t) (_o$5123 (if (jolt-truthy? shp) (jolt-assoc node_PRIME_ (keyword #f "shape") shp) node_PRIME_))) (jolt-vector _o$5122 _o$5123))) (if (jolt= op (keyword #f "vector")) (let* ((irs (let* ((_a$5125 (var-deref "clojure.core" "mapv")) (_a$5126 (lambda (x) (let fnrec5124 ((x x)) (jolt-invoke infer x tenv env)))) (_a$5127 (jolt-get node (keyword #f "items")))) (jolt-invoke _a$5125 _a$5126 _a$5127))) (ets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5128 ((r r)) (jolt-nth r 0))) irs)) (el (if (jolt-empty? ets) (keyword #f "any") (let* ((_a$5129 (var-deref "jolt.passes.types.lattice" "join")) (_a$5130 (jolt-first ets)) (_a$5131 (jolt-rest ets))) (jolt-reduce _a$5129 _a$5130 _a$5131))))) (let* ((_o$5133 (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") el) (var-deref "jolt.passes.types.lattice" "type-depth"))) (_o$5134 (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5132 ((r r)) (jolt-nth r 1))) irs)))) (jolt-vector _o$5133 _o$5134))) (if (jolt= op (keyword #f "set")) (let* ((irs (let* ((_a$5136 (var-deref "clojure.core" "mapv")) (_a$5137 (lambda (x) (let fnrec5135 ((x x)) (jolt-invoke infer x tenv env)))) (_a$5138 (jolt-get node (keyword #f "items")))) (jolt-invoke _a$5136 _a$5137 _a$5138))) (ets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5139 ((r r)) (jolt-nth r 0))) irs)) (el (if (jolt-empty? ets) (keyword #f "any") (let* ((_a$5140 (var-deref "jolt.passes.types.lattice" "join")) (_a$5141 (jolt-first ets)) (_a$5142 (jolt-rest ets))) (jolt-reduce _a$5140 _a$5141 _a$5142))))) (let* ((_o$5144 (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") el) (var-deref "jolt.passes.types.lattice" "type-depth"))) (_o$5145 (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5143 ((r r)) (jolt-nth r 1))) irs)))) (jolt-vector _o$5144 _o$5145))) (if (jolt= op (keyword #f "if")) (let* ((tr (jolt-invoke infer (jolt-get node (keyword #f "test")) tenv env)) (thn (jolt-invoke infer (jolt-get node (keyword #f "then")) tenv env)) (els (jolt-invoke infer (jolt-get node (keyword #f "else")) tenv env))) (let* ((_o$5156 (let* ((_a$5146 (var-deref "jolt.passes.types.lattice" "join")) (_a$5147 (jolt-nth thn 0)) (_a$5148 (jolt-nth els 0))) (jolt-invoke _a$5146 _a$5147 _a$5148))) (_o$5157 (let* ((_a$5149 node) (_a$5150 (keyword #f "test")) (_a$5151 (jolt-nth tr 1)) (_a$5152 (keyword #f "then")) (_a$5153 (jolt-nth thn 1)) (_a$5154 (keyword #f "else")) (_a$5155 (jolt-nth els 1))) (jolt-assoc _a$5149 _a$5150 _a$5151 _a$5152 _a$5153 _a$5154 _a$5155)))) (jolt-vector _o$5156 _o$5157))) (if (jolt= op (keyword #f "do")) (let* ((stmts (let* ((_a$5159 (var-deref "clojure.core" "mapv")) (_a$5160 (lambda (s) (let fnrec5158 ((s s)) (jolt-nth (jolt-invoke infer s tenv env) 1)))) (_a$5161 (jolt-get node (keyword #f "statements")))) (jolt-invoke _a$5159 _a$5160 _a$5161))) (r (jolt-invoke infer (jolt-get node (keyword #f "ret")) tenv env))) (let* ((_o$5162 (jolt-nth r 0)) (_o$5163 (jolt-assoc node (keyword #f "statements") stmts (keyword #f "ret") (jolt-nth r 1)))) (jolt-vector _o$5162 _o$5163))) (if (jolt= op (keyword #f "throw")) (let* ((_o$5164 (keyword #f "any")) (_o$5165 (jolt-assoc node (keyword #f "expr") (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "expr")) tenv env) 1)))) (jolt-vector _o$5164 _o$5165)) (if (jolt= op (keyword #f "var")) (begin (let* ((_a$5166 (var-deref "clojure.core" "swap!")) (_a$5167 (jolt-get env (keyword #f "escapes"))) (_a$5168 jolt-conj) (_a$5169 (jolt-invoke (var-deref "jolt.passes.types" "var-key") node))) (jolt-invoke _a$5166 _a$5167 _a$5168 _a$5169)) (let* ((_o$5172 (let* ((vt (let* ((_a$5170 (jolt-get env (keyword #f "vtypes"))) (_a$5171 (jolt-invoke (var-deref "jolt.passes.types" "var-key") node))) (jolt-get _a$5170 _a$5171)))) (if (jolt-truthy? vt) vt (keyword #f "any")))) (_o$5173 node)) (jolt-vector _o$5172 _o$5173))) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.types" "infer-invoke") node tenv env) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$5184 (lambda (acc b) (let fnrec5174 ((acc acc) (b b)) (let* ((te (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (ir (jolt-invoke infer (jolt-nth b 1) te env))) (let* ((_o$5180 (let* ((_a$5175 te) (_a$5176 (jolt-nth b 0)) (_a$5177 (jolt-nth ir 0))) (jolt-assoc _a$5175 _a$5176 _a$5177))) (_o$5181 (jolt-conj binds (let* ((_o$5178 (jolt-nth b 0)) (_o$5179 (jolt-nth ir 1))) (jolt-vector _o$5178 _o$5179))))) (jolt-vector _o$5180 _o$5181)))))) (_a$5185 (let* ((_o$5182 tenv) (_o$5183 (jolt-vector))) (jolt-vector _o$5182 _o$5183))) (_a$5186 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$5184 _a$5185 _a$5186))) (br (let* ((_a$5187 infer) (_a$5188 (jolt-get node (keyword #f "body"))) (_a$5189 (jolt-nth res 0)) (_a$5190 env)) (jolt-invoke _a$5187 _a$5188 _a$5189 _a$5190)))) (let* ((_o$5196 (jolt-nth br 0)) (_o$5197 (let* ((_a$5191 node) (_a$5192 (keyword #f "bindings")) (_a$5193 (jolt-nth res 1)) (_a$5194 (keyword #f "body")) (_a$5195 (jolt-nth br 1))) (jolt-assoc _a$5191 _a$5192 _a$5193 _a$5194 _a$5195)))) (jolt-vector _o$5196 _o$5197))) (if (jolt= op (keyword #f "loop")) (let* ((_o$5209 (keyword #f "any")) (_o$5210 (let* ((_a$5204 node) (_a$5205 (keyword #f "bindings")) (_a$5206 (let* ((_a$5201 (var-deref "clojure.core" "mapv")) (_a$5202 (lambda (b) (let fnrec5198 ((b b)) (let* ((_o$5199 (jolt-nth b 0)) (_o$5200 (jolt-nth (jolt-invoke infer (jolt-nth b 1) tenv env) 1))) (jolt-vector _o$5199 _o$5200))))) (_a$5203 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$5201 _a$5202 _a$5203))) (_a$5207 (keyword #f "body")) (_a$5208 (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "body")) tenv env) 1))) (jolt-assoc _a$5204 _a$5205 _a$5206 _a$5207 _a$5208)))) (jolt-vector _o$5209 _o$5210)) (if (jolt= op (keyword #f "recur")) (let* ((_o$5215 (keyword #f "any")) (_o$5216 (jolt-assoc node (keyword #f "args") (let* ((_a$5212 (var-deref "clojure.core" "mapv")) (_a$5213 (lambda (a) (let fnrec5211 ((a a)) (jolt-nth (jolt-invoke infer a tenv env) 1)))) (_a$5214 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$5212 _a$5213 _a$5214))))) (jolt-vector _o$5215 _o$5216)) (if (jolt= op (keyword #f "fn")) (let* ((_o$5232 (keyword #f "any")) (_o$5233 (jolt-assoc node (keyword #f "arities") (let* ((_a$5229 (var-deref "clojure.core" "mapv")) (_a$5230 (lambda (a) (let fnrec5217 ((a a)) (let* ((shapes (jolt-get env (keyword #f "record-shapes"))) (phm (let* ((_a$5222 (lambda (m pr) (let fnrec5218 ((m m) (pr pr)) (let* ((_a$5219 m) (_a$5220 (jolt-nth pr 0)) (_a$5221 (jolt-nth pr 1))) (jolt-assoc _a$5219 _a$5220 _a$5221))))) (_a$5223 (jolt-hash-map)) (_a$5224 (jolt-get a (keyword #f "phints")))) (jolt-reduce _a$5222 _a$5223 _a$5224))) (pe (let* ((_a$5226 (lambda (e p) (let fnrec5225 ((e e) (p p)) (jolt-assoc e p (let* ((ent (jolt-get shapes (jolt-get phm p)))) (if (jolt-truthy? ent) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") ent (var-deref "jolt.passes.types.lattice" "type-depth") shapes) (keyword #f "any"))))))) (_a$5227 tenv) (_a$5228 (jolt-get a (keyword #f "params")))) (jolt-reduce _a$5226 _a$5227 _a$5228))) (pe (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) (keyword #f "any")) pe))) (jolt-assoc a (keyword #f "body") (jolt-nth (jolt-invoke infer (jolt-get a (keyword #f "body")) pe env) 1)))))) (_a$5231 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$5229 _a$5230 _a$5231))))) (jolt-vector _o$5232 _o$5233)) (if (jolt= op (keyword #f "def")) (begin (if (jolt-truthy? (jolt-get env (keyword #f "checking?"))) (jolt-invoke (var-deref "jolt.passes.types.check" "register-user-fn!") node env) jolt-nil) (let* ((_o$5234 (keyword #f "any")) (_o$5235 (jolt-assoc node (keyword #f "init") (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "init")) tenv env) 1)))) (jolt-vector _o$5234 _o$5235))) (if (jolt= op (keyword #f "try")) (let* ((_o$5243 (keyword #f "any")) (_o$5244 (let* ((_a$5236 node) (_a$5237 (keyword #f "body")) (_a$5238 (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "body")) tenv env) 1)) (_a$5239 (keyword #f "catch-body")) (_a$5240 (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "catch-body")) tenv env) 1) jolt-nil)) (_a$5241 (keyword #f "finally")) (_a$5242 (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-nth (jolt-invoke infer (jolt-get node (keyword #f "finally")) tenv env) 1) jolt-nil))) (jolt-assoc _a$5236 _a$5237 _a$5238 _a$5239 _a$5240 _a$5241 _a$5242)))) (jolt-vector _o$5243 _o$5244)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$5245 (keyword #f "any")) (_o$5246 node)) (jolt-vector _o$5245 _o$5246)) jolt-nil)))))))))))))))))))))) infer))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-conj-into" (letrec ((infer-conj-into (lambda (node fnode cn args n tenv env) (let fnrec5957 ((node node) (fnode fnode) (cn cn) (args args) (n n) (tenv tenv) (env env)) (let* ((ares (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec5958 ((a a)) (jolt-invoke (var-deref "jolt.passes.types" "infer") a tenv env))) args)) (base (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0))) (rest-ts (let* ((_a$5960 (var-deref "clojure.core" "mapv")) (_a$5961 (lambda (r) (let fnrec5959 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r)))) (_a$5962 (jolt-rest ares))) (jolt-invoke _a$5960 _a$5961 _a$5962))) (rt (if (jolt-truthy? (let* ((and__25__auto (jolt= cn "conj"))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") base) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (jolt-reduce (var-deref "jolt.passes.types.lattice" "join") (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") base) rest-ts)) (if (jolt-truthy? (let* ((and__25__auto (jolt= cn "into"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") base))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 2 n))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") (jolt-nth rest-ts 0)) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (let* ((_a$5963 (var-deref "jolt.passes.types.lattice" "join")) (_a$5964 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") base)) (_a$5965 (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") (jolt-nth rest-ts 0)))) (jolt-invoke _a$5963 _a$5964 _a$5965))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env) jolt-nil))))) (let* ((_o$5967 rt) (_o$5968 (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5966 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) ares)))) (jolt-vector _o$5967 _o$5968))))))) infer-conj-into) (let* ((_o$5969 (keyword #f "private")) (_o$5970 #t) (_o$5971 (keyword #f "doc")) (_o$5972 "conj/into: track the element type of a vector being grown.")) (jolt-hash-map _o$5969 _o$5970 _o$5971 _o$5972)))) + (def-var! "jolt.passes.types" "infer-top" (letrec ((infer-top (lambda (node env) (let fnrec5247 ((node node) (env env)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.types" "infer") node (jolt-hash-map) env) 1))))) infer-top))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-call" (letrec ((infer-call (lambda (node fnode iscall-var cn args n tenv env) (let fnrec5973 ((node node) (fnode fnode) (iscall-var iscall-var) (cn cn) (args args) (n n) (tenv tenv) (env env)) (let* ((fr (if (jolt-not iscall-var) (jolt-invoke (var-deref "jolt.passes.types" "infer") fnode tenv env) jolt-nil)) (fnode_PRIME_ (if (jolt-truthy? iscall-var) fnode (jolt-invoke (var-deref "jolt.passes.types" "nd") fr))) (callee-t (if (jolt-truthy? iscall-var) (let* ((_a$5974 (jolt-get env (keyword #f "vtypes"))) (_a$5975 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$5974 _a$5975)) (jolt-invoke (var-deref "jolt.passes.types" "ty") fr))) (ares (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (a) (let fnrec5976 ((a a)) (jolt-invoke (var-deref "jolt.passes.types" "infer") a tenv env))) args))) (begin (if (jolt-truthy? iscall-var) (let* ((_a$5982 (var-deref "clojure.core" "swap!")) (_a$5983 (jolt-get env (keyword #f "calls"))) (_a$5984 jolt-conj) (_a$5985 (let* ((_o$5980 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)) (_o$5981 (if (let* ((_a$5977 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)) (_a$5978 (jolt-get env (keyword #f "self-key")))) (jolt= _a$5977 _a$5978)) (jolt-invoke (var-deref "jolt.passes.types" "self-rec-argtys") args ares (jolt-get env (keyword #f "self-params"))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5979 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) ares)))) (jolt-vector _o$5980 _o$5981)))) (jolt-invoke _a$5982 _a$5983 _a$5984 _a$5985)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "local") (jolt-get fnode (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get env (keyword #f "self-key")))) (if (jolt-truthy? and__25__auto) (let* ((_a$5986 (jolt-get fnode (keyword #f "name"))) (_a$5987 (jolt-get env (keyword #f "self-name")))) (jolt= _a$5986 _a$5987)) and__25__auto)) and__25__auto))) (let* ((_a$5990 (var-deref "clojure.core" "swap!")) (_a$5991 (jolt-get env (keyword #f "calls"))) (_a$5992 jolt-conj) (_a$5993 (let* ((_o$5988 (jolt-get env (keyword #f "self-key"))) (_o$5989 (jolt-invoke (var-deref "jolt.passes.types" "self-rec-argtys") args ares (jolt-get env (keyword #f "self-params"))))) (jolt-vector _o$5988 _o$5989)))) (jolt-invoke _a$5990 _a$5991 _a$5992 _a$5993)) jolt-nil) (if (jolt-truthy? (jolt-get env (keyword #f "checking?"))) (let* ((ats (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec5994 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "ty") r))) ares)) (pos (jolt-get node (keyword #f "pos")))) (begin (if (jolt-truthy? cn) (jolt-invoke (var-deref "jolt.passes.types.check" "check-invoke") cn args ats pos env) jolt-nil) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.check" "not-callable?") callee-t)) (let* ((_a$6003 (var-deref "clojure.core" "swap!")) (_a$6004 (jolt-get env (keyword #f "diags"))) (_a$6005 jolt-conj) (_a$6006 (let* ((_o$5995 (keyword #f "op")) (_o$5996 (keyword #f "call")) (_o$5997 (keyword #f "type")) (_o$5998 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") callee-t)) (_o$5999 (keyword #f "pos")) (_o$6000 pos) (_o$6001 (keyword #f "msg")) (_o$6002 (jolt-invoke (var-deref "clojure.core" "str") "cannot call " (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") callee-t) " as a function"))) (jolt-hash-map _o$5995 _o$5996 _o$5997 _o$5998 _o$5999 _o$6000 _o$6001 _o$6002)))) (jolt-invoke _a$6003 _a$6004 _a$6005 _a$6006)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-get env (keyword #f "strict?")))) (if (jolt-truthy? and__25__auto) iscall-var and__25__auto))) (let* ((k (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode)) (usig (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "user-sigs"))) k))) (if (jolt-truthy? usig) (jolt-invoke (var-deref "jolt.passes.types" "check-user-call") k usig ats pos env) jolt-nil)) jolt-nil))) jolt-nil) (let* ((pm (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (let* ((_a$6007 (jolt-get env (keyword #f "protocol-methods"))) (_a$6008 (jolt-invoke (var-deref "jolt.passes.types" "var-key") fnode))) (jolt-get _a$6007 _a$6008)) and__25__auto))) (rtype (if (jolt-truthy? (let* ((and__25__auto pm)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (jolt-get (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0)) (keyword #f "type")) jolt-nil)) (base (jolt-assoc node (keyword #f "fn") fnode_PRIME_ (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6009 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) ares)))) (let* ((_o$6017 (if (jolt= cn "range") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") (keyword #f "num")) (if (jolt-truthy? (let* ((and__25__auto cn)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types" "elem-fns") cn))) (if (jolt-truthy? and__25__auto) (jolt-n> n 0) and__25__auto)) and__25__auto))) (let* ((a0 (jolt-invoke (var-deref "jolt.passes.types" "ty") (jolt-nth ares 0)))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") a0)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "velem") a0) (keyword #f "any"))) (if (jolt-truthy? (let* ((and__25__auto cn)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types" "dbl-arith-ops") cn))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types" "dbl-arith?") ares args) and__25__auto)) and__25__auto))) (keyword #f "double") (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "call-ret-type") fnode env) jolt-nil))))) (_o$6018 (if (jolt-truthy? rtype) (let* ((_a$6010 base) (_a$6011 (keyword #f "devirt-type")) (_a$6012 rtype) (_a$6013 (keyword #f "devirt-proto")) (_a$6014 (jolt-nth pm 0)) (_a$6015 (keyword #f "devirt-method")) (_a$6016 (jolt-nth pm 1))) (jolt-assoc _a$6010 _a$6011 _a$6012 _a$6013 _a$6014 _a$6015 _a$6016)) base))) (jolt-vector _o$6017 _o$6018))))))))) infer-call) (let* ((_o$6019 (keyword #f "private")) (_o$6020 #t) (_o$6021 (keyword #f "doc")) (_o$6022 "Everything else: type the args, collect the call (var callee) for whole-program\n inference, run the success-type check, and use the declared/estimated return type.\n range produces a numeric vector; an element-returning fn over a typed vector\n yields the element type. A protocol-method call whose receiver (arg 0) is a known\n record type is annotated [type-tag proto method] for devirtualization \x2014; the back\n end looks up the impl at emit time and calls it directly, skipping the registry\n dispatch (~19x cheaper).")) (jolt-hash-map _o$6019 _o$6020 _o$6021 _o$6022)))) + (def-var! "jolt.passes.types" "all-any-env" (letrec ((all-any-env (lambda (params) (let fnrec5248 ((params params)) (let* ((_a$5250 (lambda (e p) (let fnrec5249 ((e e) (p p)) (jolt-assoc e p (keyword #f "any"))))) (_a$5251 (jolt-hash-map)) (_a$5252 params)) (jolt-reduce _a$5250 _a$5251 _a$5252)))))) all-any-env))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-invoke" (letrec ((infer-invoke (lambda (node tenv env) (let fnrec6023 ((node node) (tenv tenv) (env env)) (let* ((fnode (jolt-get node (keyword #f "fn"))) (iscall-var (jolt= (keyword #f "var") (jolt-get fnode (keyword #f "op")))) (cn (if (jolt-truthy? (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (jolt= "clojure.core" (jolt-get fnode (keyword #f "ns"))) and__25__auto))) (jolt-get fnode (keyword #f "name")) jolt-nil)) (args (jolt-get node (keyword #f "args"))) (n (jolt-count args))) (if (jolt-truthy? (let* ((and__25__auto iscall-var)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-contains? (var-deref "jolt.passes.types" "fold-preds") cn))) (if (jolt-truthy? and__25__auto) (jolt= n 1) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-pred-fold") node fnode cn args tenv env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "kw-callee?") fnode))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n>= n 1))) (if (jolt-truthy? and__25__auto) (jolt-n<= n 2) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-kw-lookup") node fnode args n tenv env) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.passes.fold" "get-callee?") fnode))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "const") (jolt-get (jolt-nth args 1) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "keyword?") (jolt-get (jolt-nth args 1) (keyword #f "val"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-get-lookup") node args n tenv env) (if (let* ((and__25__auto (jolt= cn "reduce"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get (jolt-nth args 0) (keyword #f "op"))) and__25__auto)) and__25__auto)) (jolt-invoke (var-deref "jolt.passes.types" "infer-reduce-hof") node args n tenv env) (if (jolt-truthy? (let* ((and__25__auto cn)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get (var-deref "jolt.passes.types" "hof-table") cn))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-n>= n 2))) (if (jolt-truthy? and__25__auto) (jolt= (keyword #f "fn") (jolt-get (jolt-nth args 0) (keyword #f "op"))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types" "infer-seq-hof") node cn args tenv env) (if (let* ((and__25__auto (let* ((or__26__auto (jolt= cn "conj"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= cn "into"))))) (if (jolt-truthy? and__25__auto) (jolt-n>= n 1) and__25__auto)) (jolt-invoke (var-deref "jolt.passes.types" "infer-conj-into") node fnode cn args n tenv env) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "jolt.passes.types" "infer-call") node fnode iscall-var cn args n tenv env) jolt-nil)))))))))))) infer-invoke) (let* ((_o$6024 (keyword #f "private")) (_o$6025 #t) (_o$6026 (keyword #f "doc")) (_o$6027 "Split the callee/args once and dispatch by callee shape to a pattern helper.")) (jolt-hash-map _o$6024 _o$6025 _o$6026 _o$6027)))) + (def-var! "jolt.passes.types" "isolated-diag-count" (letrec ((isolated-diag-count (lambda (body tenv env) (let fnrec5253 ((body body) (tenv tenv) (env env)) (let* ((sub (jolt-assoc env (keyword #f "diags") (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))))) (begin (jolt-invoke (var-deref "jolt.passes.types" "infer") body tenv sub) (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get sub (keyword #f "diags")))))))))) isolated-diag-count))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer" (letrec ((infer (lambda (node tenv env) (let fnrec6028 ((node node) (tenv tenv) (env env)) (let* ((op (jolt-get node (keyword #f "op")))) (if (jolt= op (keyword #f "const")) (let* ((_o$6029 (let* ((v (jolt-get node (keyword #f "val")))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") v))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "float?") v) and__25__auto))) (keyword #f "double") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") v)) (keyword #f "num") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") v)) (keyword #f "str") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") v)) (keyword #f "kw") (if (jolt-nil? v) (keyword #f "nil") (if (jolt= #f v) (keyword #f "any") (if (jolt-truthy? (keyword #f "else")) (keyword #f "truthy") jolt-nil))))))))) (_o$6030 node)) (jolt-vector _o$6029 _o$6030)) (if (jolt= op (keyword #f "local")) (let* ((t (jolt-get tenv (jolt-get node (keyword #f "name"))))) (let* ((_o$6031 (if (jolt-truthy? t) t (keyword #f "any"))) (_o$6032 (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-safe?") t)) (let* ((n (jolt-assoc node (keyword #f "hint") (keyword #f "struct")))) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "type-shape") t)) (jolt-assoc n (keyword #f "shape") (jolt-invoke (var-deref "jolt.passes.types.lattice" "type-shape") t)) n)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.passes.types.lattice" "vec-type?") t)) (jolt-assoc node (keyword #f "hint") (keyword #f "vector")) (if (jolt-truthy? (keyword #f "else")) node jolt-nil))))) (jolt-vector _o$6031 _o$6032))) (if (jolt= op (keyword #f "map")) (let* ((pairs (jolt-get node (keyword #f "pairs"))) (res (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (pr) (let fnrec6033 ((pr pr)) (let* ((kr (infer (jolt-nth pr 0) tenv env)) (vr (infer (jolt-nth pr 1) tenv env))) (let* ((_o$6034 (jolt-nth kr 1)) (_o$6035 (jolt-nth vr 1)) (_o$6036 (jolt-nth vr 0)) (_o$6037 (jolt-get (jolt-nth pr 0) (keyword #f "val")))) (jolt-vector _o$6034 _o$6035 _o$6036 _o$6037))))) pairs)) (struct? (let* ((and__25__auto (jolt-n> (jolt-count res) 0))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "every?") (lambda (pr) (let fnrec6038 ((pr pr)) (jolt-invoke (var-deref "jolt.passes.fold" "scalar-const?") (jolt-nth pr 0)))) pairs))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (r) (let fnrec6039 ((r r)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "truthy-type?") (jolt-nth r 2)))) res) and__25__auto)) and__25__auto))) (base (if (jolt-truthy? struct?) (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-struct") (let* ((_a$6044 (lambda (m r) (let fnrec6040 ((m m) (r r)) (let* ((_a$6041 m) (_a$6042 (jolt-nth r 3)) (_a$6043 (jolt-nth r 2))) (jolt-assoc _a$6041 _a$6042 _a$6043))))) (_a$6045 (jolt-hash-map)) (_a$6046 res)) (jolt-reduce _a$6044 _a$6045 _a$6046))) (var-deref "jolt.passes.types.lattice" "type-depth")) jolt-nil)) (shp (if (jolt-truthy? (let* ((and__25__auto (jolt-get env (keyword #f "map-shapes?")))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto base)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes.types.lattice" "struct-type?") base) and__25__auto)) and__25__auto))) (jolt-invoke (var-deref "jolt.passes.types.lattice" "shape-order") (jolt-keys (jolt-invoke (var-deref "jolt.passes.types.lattice" "sfields") base))) jolt-nil)) (t (if (jolt-truthy? base) (if (jolt-truthy? shp) (jolt-assoc base (keyword #f "shape") shp) base) (keyword #f "any"))) (node_PRIME_ (jolt-assoc node (keyword #f "pairs") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6047 ((r r)) (let* ((_o$6048 (jolt-nth r 0)) (_o$6049 (jolt-nth r 1))) (jolt-vector _o$6048 _o$6049)))) res)))) (let* ((_o$6050 t) (_o$6051 (if (jolt-truthy? shp) (jolt-assoc node_PRIME_ (keyword #f "shape") shp) node_PRIME_))) (jolt-vector _o$6050 _o$6051))) (if (jolt= op (keyword #f "vector")) (let* ((irs (let* ((_a$6053 (var-deref "clojure.core" "mapv")) (_a$6054 (lambda (x) (let fnrec6052 ((x x)) (infer x tenv env)))) (_a$6055 (jolt-get node (keyword #f "items")))) (jolt-invoke _a$6053 _a$6054 _a$6055))) (ets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6056 ((r r)) (jolt-nth r 0))) irs)) (el (if (jolt-empty? ets) (keyword #f "any") (let* ((_a$6057 (var-deref "jolt.passes.types.lattice" "join")) (_a$6058 (jolt-first ets)) (_a$6059 (jolt-rest ets))) (jolt-reduce _a$6057 _a$6058 _a$6059))))) (let* ((_o$6061 (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-vec") el) (var-deref "jolt.passes.types.lattice" "type-depth"))) (_o$6062 (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6060 ((r r)) (jolt-nth r 1))) irs)))) (jolt-vector _o$6061 _o$6062))) (if (jolt= op (keyword #f "set")) (let* ((irs (let* ((_a$6064 (var-deref "clojure.core" "mapv")) (_a$6065 (lambda (x) (let fnrec6063 ((x x)) (infer x tenv env)))) (_a$6066 (jolt-get node (keyword #f "items")))) (jolt-invoke _a$6064 _a$6065 _a$6066))) (ets (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6067 ((r r)) (jolt-nth r 0))) irs)) (el (if (jolt-empty? ets) (keyword #f "any") (let* ((_a$6068 (var-deref "jolt.passes.types.lattice" "join")) (_a$6069 (jolt-first ets)) (_a$6070 (jolt-rest ets))) (jolt-reduce _a$6068 _a$6069 _a$6070))))) (let* ((_o$6072 (jolt-invoke (var-deref "jolt.passes.types.lattice" "cap") (jolt-invoke (var-deref "jolt.passes.types.lattice" "mk-set") el) (var-deref "jolt.passes.types.lattice" "type-depth"))) (_o$6073 (jolt-assoc node (keyword #f "items") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6071 ((r r)) (jolt-nth r 1))) irs)))) (jolt-vector _o$6072 _o$6073))) (if (jolt= op (keyword #f "if")) (let* ((test (jolt-get node (keyword #f "test"))) (tr (infer test tenv env)) (nr (jolt-invoke (var-deref "jolt.passes.types" "if-narrow") test tenv)) (thn (let* ((_a$6074 (jolt-get node (keyword #f "then"))) (_a$6075 (jolt-nth nr 0)) (_a$6076 env)) (infer _a$6074 _a$6075 _a$6076))) (els (let* ((_a$6077 (jolt-get node (keyword #f "else"))) (_a$6078 (jolt-nth nr 1)) (_a$6079 env)) (infer _a$6077 _a$6078 _a$6079)))) (let* ((_o$6090 (let* ((_a$6080 (var-deref "jolt.passes.types.lattice" "join")) (_a$6081 (jolt-nth thn 0)) (_a$6082 (jolt-nth els 0))) (jolt-invoke _a$6080 _a$6081 _a$6082))) (_o$6091 (let* ((_a$6083 node) (_a$6084 (keyword #f "test")) (_a$6085 (jolt-nth tr 1)) (_a$6086 (keyword #f "then")) (_a$6087 (jolt-nth thn 1)) (_a$6088 (keyword #f "else")) (_a$6089 (jolt-nth els 1))) (jolt-assoc _a$6083 _a$6084 _a$6085 _a$6086 _a$6087 _a$6088 _a$6089)))) (jolt-vector _o$6090 _o$6091))) (if (jolt= op (keyword #f "do")) (let* ((stmts (let* ((_a$6093 (var-deref "clojure.core" "mapv")) (_a$6094 (lambda (s) (let fnrec6092 ((s s)) (jolt-nth (infer s tenv env) 1)))) (_a$6095 (jolt-get node (keyword #f "statements")))) (jolt-invoke _a$6093 _a$6094 _a$6095))) (r (infer (jolt-get node (keyword #f "ret")) tenv env))) (let* ((_o$6096 (jolt-nth r 0)) (_o$6097 (jolt-assoc node (keyword #f "statements") stmts (keyword #f "ret") (jolt-nth r 1)))) (jolt-vector _o$6096 _o$6097))) (if (jolt= op (keyword #f "throw")) (let* ((_o$6098 (keyword #f "any")) (_o$6099 (jolt-assoc node (keyword #f "expr") (jolt-nth (infer (jolt-get node (keyword #f "expr")) tenv env) 1)))) (jolt-vector _o$6098 _o$6099)) (if (jolt= op (keyword #f "var")) (begin (let* ((_a$6100 (var-deref "clojure.core" "swap!")) (_a$6101 (jolt-get env (keyword #f "escapes"))) (_a$6102 jolt-conj) (_a$6103 (jolt-invoke (var-deref "jolt.passes.types" "var-key") node))) (jolt-invoke _a$6100 _a$6101 _a$6102 _a$6103)) (let* ((_o$6106 (let* ((vt (let* ((_a$6104 (jolt-get env (keyword #f "vtypes"))) (_a$6105 (jolt-invoke (var-deref "jolt.passes.types" "var-key") node))) (jolt-get _a$6104 _a$6105)))) (if (jolt-truthy? vt) vt (keyword #f "any")))) (_o$6107 node)) (jolt-vector _o$6106 _o$6107))) (if (jolt= op (keyword #f "invoke")) (jolt-invoke (var-deref "jolt.passes.types" "infer-invoke") node tenv env) (if (jolt= op (keyword #f "let")) (let* ((res (let* ((_a$6118 (lambda (acc b) (let fnrec6108 ((acc acc) (b b)) (let* ((te (jolt-nth acc 0)) (binds (jolt-nth acc 1)) (ir (infer (jolt-nth b 1) te env))) (let* ((_o$6114 (let* ((_a$6109 te) (_a$6110 (jolt-nth b 0)) (_a$6111 (jolt-nth ir 0))) (jolt-assoc _a$6109 _a$6110 _a$6111))) (_o$6115 (jolt-conj binds (let* ((_o$6112 (jolt-nth b 0)) (_o$6113 (jolt-nth ir 1))) (jolt-vector _o$6112 _o$6113))))) (jolt-vector _o$6114 _o$6115)))))) (_a$6119 (let* ((_o$6116 tenv) (_o$6117 (jolt-vector))) (jolt-vector _o$6116 _o$6117))) (_a$6120 (jolt-get node (keyword #f "bindings")))) (jolt-reduce _a$6118 _a$6119 _a$6120))) (br (let* ((_a$6121 (jolt-get node (keyword #f "body"))) (_a$6122 (jolt-nth res 0)) (_a$6123 env)) (infer _a$6121 _a$6122 _a$6123)))) (let* ((_o$6129 (jolt-nth br 0)) (_o$6130 (let* ((_a$6124 node) (_a$6125 (keyword #f "bindings")) (_a$6126 (jolt-nth res 1)) (_a$6127 (keyword #f "body")) (_a$6128 (jolt-nth br 1))) (jolt-assoc _a$6124 _a$6125 _a$6126 _a$6127 _a$6128)))) (jolt-vector _o$6129 _o$6130))) (if (jolt= op (keyword #f "loop")) (let* ((lenv (jolt-assoc env (keyword #f "in-loop?") #t))) (let* ((_o$6142 (keyword #f "any")) (_o$6143 (let* ((_a$6137 node) (_a$6138 (keyword #f "bindings")) (_a$6139 (let* ((_a$6134 (var-deref "clojure.core" "mapv")) (_a$6135 (lambda (b) (let fnrec6131 ((b b)) (let* ((_o$6132 (jolt-nth b 0)) (_o$6133 (jolt-nth (infer (jolt-nth b 1) tenv env) 1))) (jolt-vector _o$6132 _o$6133))))) (_a$6136 (jolt-get node (keyword #f "bindings")))) (jolt-invoke _a$6134 _a$6135 _a$6136))) (_a$6140 (keyword #f "body")) (_a$6141 (jolt-nth (infer (jolt-get node (keyword #f "body")) tenv lenv) 1))) (jolt-assoc _a$6137 _a$6138 _a$6139 _a$6140 _a$6141)))) (jolt-vector _o$6142 _o$6143))) (if (jolt= op (keyword #f "recur")) (let* ((ares (let* ((_a$6145 (var-deref "clojure.core" "mapv")) (_a$6146 (lambda (a) (let fnrec6144 ((a a)) (infer a tenv env)))) (_a$6147 (jolt-get node (keyword #f "args")))) (jolt-invoke _a$6145 _a$6146 _a$6147)))) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get env (keyword #f "in-loop?"))))) (if (jolt-truthy? and__25__auto) (jolt-get env (keyword #f "self-key")) and__25__auto))) (let* ((_a$6154 (var-deref "clojure.core" "swap!")) (_a$6155 (jolt-get env (keyword #f "calls"))) (_a$6156 jolt-conj) (_a$6157 (let* ((_o$6152 (jolt-get env (keyword #f "self-key"))) (_o$6153 (let* ((_a$6148 (var-deref "jolt.passes.types" "self-rec-argtys")) (_a$6149 (jolt-get node (keyword #f "args"))) (_a$6150 ares) (_a$6151 (jolt-get env (keyword #f "self-params")))) (jolt-invoke _a$6148 _a$6149 _a$6150 _a$6151)))) (jolt-vector _o$6152 _o$6153)))) (jolt-invoke _a$6154 _a$6155 _a$6156 _a$6157)) jolt-nil) (let* ((_o$6159 (keyword #f "any")) (_o$6160 (jolt-assoc node (keyword #f "args") (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (r) (let fnrec6158 ((r r)) (jolt-invoke (var-deref "jolt.passes.types" "nd") r))) ares)))) (jolt-vector _o$6159 _o$6160)))) (if (jolt= op (keyword #f "fn")) (let* ((fenv (jolt-assoc env (keyword #f "self-name") jolt-nil (keyword #f "self-key") jolt-nil (keyword #f "self-params") jolt-nil (keyword #f "in-loop?") #f))) (let* ((_o$6176 (keyword #f "any")) (_o$6177 (jolt-assoc node (keyword #f "arities") (let* ((_a$6173 (var-deref "clojure.core" "mapv")) (_a$6174 (lambda (a) (let fnrec6161 ((a a)) (let* ((shapes (jolt-get env (keyword #f "record-shapes"))) (phm (let* ((_a$6166 (lambda (m pr) (let fnrec6162 ((m m) (pr pr)) (let* ((_a$6163 m) (_a$6164 (jolt-nth pr 0)) (_a$6165 (jolt-nth pr 1))) (jolt-assoc _a$6163 _a$6164 _a$6165))))) (_a$6167 (jolt-hash-map)) (_a$6168 (jolt-get a (keyword #f "phints")))) (jolt-reduce _a$6166 _a$6167 _a$6168))) (pe (let* ((_a$6170 (lambda (e p) (let fnrec6169 ((e e) (p p)) (jolt-assoc e p (let* ((ent (jolt-get shapes (jolt-get phm p)))) (if (jolt-truthy? ent) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") ent (var-deref "jolt.passes.types.lattice" "type-depth") shapes) (keyword #f "any"))))))) (_a$6171 tenv) (_a$6172 (jolt-get a (keyword #f "params")))) (jolt-reduce _a$6170 _a$6171 _a$6172))) (pe (if (jolt-truthy? (jolt-get a (keyword #f "rest"))) (jolt-assoc pe (jolt-get a (keyword #f "rest")) (keyword #f "any")) pe))) (jolt-assoc a (keyword #f "body") (jolt-nth (infer (jolt-get a (keyword #f "body")) pe fenv) 1)))))) (_a$6175 (jolt-get node (keyword #f "arities")))) (jolt-invoke _a$6173 _a$6174 _a$6175))))) (jolt-vector _o$6176 _o$6177))) (if (jolt= op (keyword #f "def")) (begin (if (jolt-truthy? (jolt-get env (keyword #f "checking?"))) (jolt-invoke (var-deref "jolt.passes.types.check" "register-user-fn!") node env) jolt-nil) (let* ((_o$6178 (keyword #f "any")) (_o$6179 (jolt-assoc node (keyword #f "init") (jolt-nth (infer (jolt-get node (keyword #f "init")) tenv env) 1)))) (jolt-vector _o$6178 _o$6179))) (if (jolt= op (keyword #f "try")) (let* ((_o$6187 (keyword #f "any")) (_o$6188 (let* ((_a$6180 node) (_a$6181 (keyword #f "body")) (_a$6182 (jolt-nth (infer (jolt-get node (keyword #f "body")) tenv env) 1)) (_a$6183 (keyword #f "catch-body")) (_a$6184 (if (jolt-truthy? (jolt-get node (keyword #f "catch-body"))) (jolt-nth (infer (jolt-get node (keyword #f "catch-body")) tenv env) 1) jolt-nil)) (_a$6185 (keyword #f "finally")) (_a$6186 (if (jolt-truthy? (jolt-get node (keyword #f "finally"))) (jolt-nth (infer (jolt-get node (keyword #f "finally")) tenv env) 1) jolt-nil))) (jolt-assoc _a$6180 _a$6181 _a$6182 _a$6183 _a$6184 _a$6185 _a$6186)))) (jolt-vector _o$6187 _o$6188)) (if (jolt-truthy? (keyword #f "else")) (let* ((_o$6189 (keyword #f "any")) (_o$6190 node)) (jolt-vector _o$6189 _o$6190)) jolt-nil)))))))))))))))))))))) infer) (let* ((_o$6191 (keyword #f "private")) (_o$6192 #t) (_o$6193 (keyword #f "doc")) (_o$6194 "Returns [type node'] \x2014; the inferred type of node and node with struct-safe\n :local references annotated :hint :struct. tenv maps in-scope local names to\n inferred types; env carries the inference config and this run's accumulators.")) (jolt-hash-map _o$6191 _o$6192 _o$6193 _o$6194)))) + (def-var! "jolt.passes.types" "check-user-call" (letrec ((check-user-call (lambda (key sig arg-types pos env) (let fnrec5254 ((key key) (sig sig) (arg-types arg-types) (pos pos) (env env)) (let* ((cset (jolt-get env (keyword #f "checking-set")))) (if (jolt-not (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") cset) key)) (let* ((prev (jolt-invoke (var-deref "clojure.core" "deref") cset))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") cset (jolt-conj prev key)) (let* ((params (jolt-get sig (keyword #f "params"))) (body (jolt-get sig (keyword #f "body"))) (npar (jolt-count params)) (nargs (jolt-count arg-types)) (memo (jolt-get env (keyword #f "diag-memo")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") npar nargs)) (let* ((_a$5263 (var-deref "clojure.core" "swap!")) (_a$5264 (jolt-get env (keyword #f "diags"))) (_a$5265 jolt-conj) (_a$5266 (let* ((_o$5255 (keyword #f "op")) (_o$5256 (keyword #f "user-call")) (_o$5257 (keyword #f "type")) (_o$5258 (keyword #f "arity")) (_o$5259 (keyword #f "pos")) (_o$5260 pos) (_o$5261 (keyword #f "msg")) (_o$5262 (jolt-invoke (var-deref "clojure.core" "str") "wrong number of args (" nargs ") passed to `" (jolt-get sig (keyword #f "name")) "` (expected " npar ")"))) (jolt-hash-map _o$5255 _o$5256 _o$5257 _o$5258 _o$5259 _o$5260 _o$5261 _o$5262)))) (jolt-invoke _a$5263 _a$5264 _a$5265 _a$5266)) (let* ((base-env (jolt-invoke (var-deref "jolt.passes.types" "all-any-env") params)) (base (let* ((bk (let* ((_o$5267 (keyword #f "base")) (_o$5268 key)) (jolt-vector _o$5267 _o$5268)))) (if (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") memo) bk) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") memo) bk) (let* ((b (jolt-invoke (var-deref "jolt.passes.types" "isolated-diag-count") body base-env env))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") memo jolt-assoc bk b) b)))))) (let* ((_a$5296 (lambda (_ i) (let fnrec5269 ((_ _) (i i)) (begin (let* ((at (jolt-nth arg-types i))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "not=") at (keyword #f "any")))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "not=") at (keyword #f "truthy")) and__25__auto))) (let* ((mk (let* ((_o$5270 (keyword #f "arg")) (_o$5271 key) (_o$5272 i) (_o$5273 at)) (jolt-vector _o$5270 _o$5271 _o$5272 _o$5273))) (rejects (if (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") memo) mk) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") memo) mk) (let* ((r (> (jolt-invoke (var-deref "jolt.passes.types" "isolated-diag-count") body (jolt-assoc base-env (jolt-nth params i) at) env) base))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") memo jolt-assoc mk r) r))))) (if (jolt-truthy? rejects) (let* ((_a$5292 (var-deref "clojure.core" "swap!")) (_a$5293 (jolt-get env (keyword #f "diags"))) (_a$5294 jolt-conj) (_a$5295 (let* ((_o$5282 (keyword #f "op")) (_o$5283 (keyword #f "user-call")) (_o$5284 (keyword #f "argpos")) (_o$5285 i) (_o$5286 (keyword #f "type")) (_o$5287 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") at)) (_o$5288 (keyword #f "pos")) (_o$5289 pos) (_o$5290 (keyword #f "msg")) (_o$5291 (let* ((_a$5274 (var-deref "clojure.core" "str")) (_a$5275 "argument ") (_a$5276 (jolt-inc i)) (_a$5277 " to `") (_a$5278 (jolt-get sig (keyword #f "name"))) (_a$5279 "` is ") (_a$5280 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") at)) (_a$5281 ", which its body provably rejects")) (jolt-invoke _a$5274 _a$5275 _a$5276 _a$5277 _a$5278 _a$5279 _a$5280 _a$5281)))) (jolt-hash-map _o$5282 _o$5283 _o$5284 _o$5285 _o$5286 _o$5287 _o$5288 _o$5289 _o$5290 _o$5291)))) (jolt-invoke _a$5292 _a$5293 _a$5294 _a$5295)) jolt-nil)) jolt-nil)) jolt-nil)))) (_a$5297 jolt-nil) (_a$5298 (jolt-range npar))) (jolt-reduce _a$5296 _a$5297 _a$5298))))) (jolt-invoke (var-deref "clojure.core" "reset!") cset prev))) jolt-nil)))))) check-user-call))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-top" (letrec ((infer-top (lambda (node env) (let fnrec6195 ((node node) (env env)) (jolt-nth (jolt-invoke (var-deref "jolt.passes.types" "infer") node (jolt-hash-map) env) 1))))) infer-top) (let* ((_o$6196 (keyword #f "private")) (_o$6197 #t)) (jolt-hash-map _o$6196 _o$6197)))) + (def-var! "jolt.passes.types" "set-rtenv!" (letrec ((set-rtenv! (lambda (m) (let fnrec5299 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "rtenv") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-rtenv!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "all-any-env" (letrec ((all-any-env (lambda (params) (let fnrec6198 ((params params)) (let* ((_a$6200 (lambda (e p) (let fnrec6199 ((e e) (p p)) (jolt-assoc e p (keyword #f "any"))))) (_a$6201 (jolt-hash-map)) (_a$6202 params)) (jolt-reduce _a$6200 _a$6201 _a$6202)))))) all-any-env) (let* ((_o$6203 (keyword #f "private")) (_o$6204 #t) (_o$6205 (keyword #f "doc")) (_o$6206 "tenv binding every param name to :any (the all-ambiguous baseline).")) (jolt-hash-map _o$6203 _o$6204 _o$6205 _o$6206)))) + (def-var! "jolt.passes.types" "set-record-shapes!" (letrec ((set-record-shapes! (lambda (m) (let fnrec5300 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "record-shapes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-record-shapes!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "isolated-diag-count" (letrec ((isolated-diag-count (lambda (body tenv env) (let fnrec6207 ((body body) (tenv tenv) (env env)) (let* ((sub (jolt-assoc env (keyword #f "diags") (jolt-invoke (var-deref "clojure.core" "atom") (jolt-vector))))) (begin (jolt-invoke (var-deref "jolt.passes.types" "infer") body tenv sub) (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get sub (keyword #f "diags")))))))))) isolated-diag-count) (let* ((_o$6208 (keyword #f "private")) (_o$6209 #t) (_o$6210 (keyword #f "doc")) (_o$6211 "Count of diagnostics typing body under tenv produces. Runs under a SUB-ENV\n with its own diags cell, so this probe never leaks into the real report (the\n shared calls/escapes/guard cells are intentionally still threaded \x2014; they are\n not read here). Runs the same checking inference as check-form.")) (jolt-hash-map _o$6208 _o$6209 _o$6210 _o$6211)))) + (def-var! "jolt.passes.types" "set-protocol-methods!" (letrec ((set-protocol-methods! (lambda (m) (let fnrec5301 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "protocol-methods") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-protocol-methods!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "check-user-call" (letrec ((check-user-call (lambda (key sig arg-types pos env) (let fnrec6212 ((key key) (sig sig) (arg-types arg-types) (pos pos) (env env)) (let* ((cset (jolt-get env (keyword #f "checking-set")))) (if (jolt-not (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") cset) key)) (let* ((prev (jolt-invoke (var-deref "clojure.core" "deref") cset))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") cset (jolt-conj prev key)) (let* ((params (jolt-get sig (keyword #f "params"))) (body (jolt-get sig (keyword #f "body"))) (npar (jolt-count params)) (nargs (jolt-count arg-types)) (memo (jolt-get env (keyword #f "diag-memo")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") npar nargs)) (let* ((_a$6221 (var-deref "clojure.core" "swap!")) (_a$6222 (jolt-get env (keyword #f "diags"))) (_a$6223 jolt-conj) (_a$6224 (let* ((_o$6213 (keyword #f "op")) (_o$6214 (keyword #f "user-call")) (_o$6215 (keyword #f "type")) (_o$6216 (keyword #f "arity")) (_o$6217 (keyword #f "pos")) (_o$6218 pos) (_o$6219 (keyword #f "msg")) (_o$6220 (jolt-invoke (var-deref "clojure.core" "str") "wrong number of args (" nargs ") passed to `" (jolt-get sig (keyword #f "name")) "` (expected " npar ")"))) (jolt-hash-map _o$6213 _o$6214 _o$6215 _o$6216 _o$6217 _o$6218 _o$6219 _o$6220)))) (jolt-invoke _a$6221 _a$6222 _a$6223 _a$6224)) (let* ((base-env (jolt-invoke (var-deref "jolt.passes.types" "all-any-env") params)) (base (let* ((bk (let* ((_o$6225 (keyword #f "base")) (_o$6226 key)) (jolt-vector _o$6225 _o$6226)))) (if (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") memo) bk) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") memo) bk) (let* ((b (jolt-invoke (var-deref "jolt.passes.types" "isolated-diag-count") body base-env env))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") memo jolt-assoc bk b) b)))))) (let* ((_a$6254 (lambda (_ i) (let fnrec6227 ((_ _) (i i)) (begin (let* ((at (jolt-nth arg-types i))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "not=") at (keyword #f "any")))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "not=") at (keyword #f "truthy")) and__25__auto))) (let* ((mk (let* ((_o$6228 (keyword #f "arg")) (_o$6229 key) (_o$6230 i) (_o$6231 at)) (jolt-vector _o$6228 _o$6229 _o$6230 _o$6231))) (rejects (if (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") memo) mk) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") memo) mk) (let* ((r (jolt-n> (jolt-invoke (var-deref "jolt.passes.types" "isolated-diag-count") body (jolt-assoc base-env (jolt-nth params i) at) env) base))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") memo jolt-assoc mk r) r))))) (if (jolt-truthy? rejects) (let* ((_a$6250 (var-deref "clojure.core" "swap!")) (_a$6251 (jolt-get env (keyword #f "diags"))) (_a$6252 jolt-conj) (_a$6253 (let* ((_o$6240 (keyword #f "op")) (_o$6241 (keyword #f "user-call")) (_o$6242 (keyword #f "argpos")) (_o$6243 i) (_o$6244 (keyword #f "type")) (_o$6245 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") at)) (_o$6246 (keyword #f "pos")) (_o$6247 pos) (_o$6248 (keyword #f "msg")) (_o$6249 (let* ((_a$6232 (var-deref "clojure.core" "str")) (_a$6233 "argument ") (_a$6234 (jolt-inc i)) (_a$6235 " to `") (_a$6236 (jolt-get sig (keyword #f "name"))) (_a$6237 "` is ") (_a$6238 (jolt-invoke (var-deref "jolt.passes.types.check" "type-name") at)) (_a$6239 ", which its body provably rejects")) (jolt-invoke _a$6232 _a$6233 _a$6234 _a$6235 _a$6236 _a$6237 _a$6238 _a$6239)))) (jolt-hash-map _o$6240 _o$6241 _o$6242 _o$6243 _o$6244 _o$6245 _o$6246 _o$6247 _o$6248 _o$6249)))) (jolt-invoke _a$6250 _a$6251 _a$6252 _a$6253)) jolt-nil)) jolt-nil)) jolt-nil)))) (_a$6255 jolt-nil) (_a$6256 (jolt-range npar))) (jolt-reduce _a$6254 _a$6255 _a$6256))))) (jolt-invoke (var-deref "clojure.core" "reset!") cset prev))) jolt-nil)))))) check-user-call) (let* ((_o$6257 (keyword #f "private")) (_o$6258 #t) (_o$6259 (keyword #f "doc")) (_o$6260 "Strict mode: report a call to a registered user fn that provably throws \x2014;\n either a WRONG ARITY (the registered fn has one fixed arity, so a different\n arg count always throws) or an argument whose concrete type the body\n rejects. For the latter, re-check the body with ONLY that parameter bound to\n its arg type (others :any); a diagnostic the all-:any body did not already\n have means the argument alone is provably wrong. Monotonic \x2014; binding a\n concrete type can only ADD error-domain hits \x2014; so no false positive.\n Cycle-guarded (env's checking-set) so mutually recursive fns terminate.")) (jolt-hash-map _o$6257 _o$6258 _o$6259 _o$6260)))) + (def-var! "jolt.passes.types" "set-map-shapes!" (letrec ((set-map-shapes! (lambda (b) (let fnrec5302 ((b b)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "map-shapes?") (jolt-invoke (var-deref "clojure.core" "boolean") b)))))) set-map-shapes!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "set-rtenv!" (letrec ((set-rtenv! (lambda (m) (let fnrec6261 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "rtenv") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-rtenv!) (let* ((_o$6262 (keyword #f "doc")) (_o$6263 "Install the current return-type estimates (a map \"ns/name\" -> type) used to\n type call results during the fixpoint.")) (jolt-hash-map _o$6262 _o$6263)))) + (def-var! "jolt.passes.types" "set-vtypes!" (letrec ((set-vtypes! (lambda (m) (let fnrec5303 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "vtypes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-vtypes!))) (guard (e (#t #f)) - (def-var! "jolt.passes.types" "set-record-shapes!" (letrec ((set-record-shapes! (lambda (m) (let fnrec6264 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "record-shapes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-record-shapes!))) + (def-var! "jolt.passes.types" "join-types" (letrec ((join-types (lambda (a b) (let fnrec5304 ((a a) (b b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join-t") a b))))) join-types))) (guard (e (#t #f)) - (def-var! "jolt.passes.types" "set-protocol-methods!" (letrec ((set-protocol-methods! (lambda (m) (let fnrec6265 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "protocol-methods") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-protocol-methods!))) + (def-var! "jolt.passes.types" "reset-escapes!" (letrec ((reset-escapes! (lambda () (let fnrec5305 () (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "escapes-box") (jolt-hash-set)))))) reset-escapes!))) (guard (e (#t #f)) - (def-var! "jolt.passes.types" "set-map-shapes!" (letrec ((set-map-shapes! (lambda (b) (let fnrec6266 ((b b)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "map-shapes?") (jolt-invoke (var-deref "clojure.core" "boolean") b)))))) set-map-shapes!))) + (def-var! "jolt.passes.types" "collected-escapes" (letrec ((collected-escapes (lambda () (let fnrec5306 () (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "escapes-box"))))))) collected-escapes))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "set-vtypes!" (letrec ((set-vtypes! (lambda (m) (let fnrec6267 ((m m)) (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "jolt.passes.types" "config-box") jolt-assoc (keyword #f "vtypes") (let* ((or__26__auto m)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))))))) set-vtypes!) (let* ((_o$6268 (keyword #f "doc")) (_o$6269 "Install var VALUE types (a map \"ns/name\" -> type): fn vars are :truthy\n (non-nil), def vars carry their inferred init type.")) (jolt-hash-map _o$6268 _o$6269)))) + (def-var! "jolt.passes.types" "check-form" (letrec ((check-form (case-lambda ((node) (let fnrec5307 ((node node)) (jolt-invoke check-form node #f))) ((node strict?) (let fnrec5308 ((node node) (strict? strict?)) (let* ((env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #t strict?))) (begin (jolt-invoke (var-deref "jolt.passes.types" "infer") node (jolt-hash-map) env) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "diags"))))))))))) check-form))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "join-types" (letrec ((join-types (lambda (a b) (let fnrec6270 ((a a) (b b)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join-t") a b))))) join-types) (let* ((_o$6271 (keyword #f "doc")) (_o$6272 "Public structural join (lub), used by the orchestrator's fixpoint so param/\n return types join field-wise/element-wise instead of collapsing to :any.")) (jolt-hash-map _o$6271 _o$6272)))) + (def-var! "jolt.passes.types" "infer-body" (letrec ((infer-body (lambda (body tenv) (let fnrec5309 ((body body) (tenv tenv)) (let* ((env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f)) (r (jolt-invoke (var-deref "jolt.passes.types" "infer") body tenv env))) (let* ((_o$5310 (jolt-nth r 0)) (_o$5311 (jolt-nth r 1)) (_o$5312 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "calls"))))) (jolt-vector _o$5310 _o$5311 _o$5312))))))) infer-body))) (guard (e (#t #f)) - (def-var! "jolt.passes.types" "reset-escapes!" (letrec ((reset-escapes! (lambda () (let fnrec6273 () (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "escapes-box") (jolt-hash-set)))))) reset-escapes!))) + (def-var! "jolt.passes.types" "reinfer-def" (letrec ((reinfer-def (lambda (def-node ptmap) (let fnrec5313 ((def-node def-node) (ptmap ptmap)) (let* ((fnode (jolt-get def-node (keyword #f "init"))) (env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f)) (shapes (jolt-get env (keyword #f "record-shapes")))) (if (jolt= (keyword #f "fn") (jolt-get fnode (keyword #f "op"))) (jolt-assoc def-node (keyword #f "init") (jolt-assoc fnode (keyword #f "arities") (let* ((_a$5319 (var-deref "clojure.core" "mapv")) (_a$5320 (lambda (a) (let fnrec5314 ((a a)) (let* ((pt (let* ((_a$5316 (lambda (m pr) (let fnrec5315 ((m m) (pr pr)) (let* ((nm (jolt-nth pr 0)) (e (jolt-get shapes (jolt-nth pr 1)))) (if (jolt-truthy? (let* ((and__25__auto e)) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-contains? m nm)) and__25__auto))) (jolt-assoc m nm (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e (var-deref "jolt.passes.types.lattice" "type-depth") shapes)) m))))) (_a$5317 ptmap) (_a$5318 (jolt-get a (keyword #f "phints")))) (jolt-reduce _a$5316 _a$5317 _a$5318)))) (jolt-assoc a (keyword #f "body") (jolt-nth (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-get a (keyword #f "body")) pt env) 1)))))) (_a$5321 (jolt-get fnode (keyword #f "arities")))) (jolt-invoke _a$5319 _a$5320 _a$5321)))) def-node)))))) reinfer-def))) (guard (e (#t #f)) - (def-var! "jolt.passes.types" "collected-escapes" (letrec ((collected-escapes (lambda () (let fnrec6274 () (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "escapes-box"))))))) collected-escapes))) + (def-var! "jolt.passes.types" "phint-seed" (letrec ((phint-seed (lambda (params phints) (let fnrec5322 ((params params) (phints phints)) (let* ((shapes (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "config-box")) (keyword #f "record-shapes"))) (m (let* ((_a$5327 (lambda (acc pr) (let fnrec5323 ((acc acc) (pr pr)) (let* ((_a$5324 acc) (_a$5325 (jolt-nth pr 0)) (_a$5326 (jolt-nth pr 1))) (jolt-assoc _a$5324 _a$5325 _a$5326))))) (_a$5328 (jolt-hash-map)) (_a$5329 phints)) (jolt-reduce _a$5327 _a$5328 _a$5329)))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (nm) (let fnrec5330 ((nm nm)) (let* ((ck (jolt-get m nm)) (e (let* ((and__25__auto ck)) (if (jolt-truthy? and__25__auto) (jolt-get shapes ck) and__25__auto)))) (if (jolt-truthy? e) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e (var-deref "jolt.passes.types.lattice" "type-depth") shapes) jolt-nil)))) params)))))) phint-seed))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "check-form" (letrec ((check-form (case-lambda ((node) (let fnrec6275 ((node node)) (check-form node #f))) ((node strict?) (let fnrec6276 ((node node) (strict? strict?)) (let* ((env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #t strict?))) (begin (jolt-invoke (var-deref "jolt.passes.types" "infer") node (jolt-hash-map) env) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "diags"))))))))))) check-form) (let* ((_o$6277 (keyword #f "doc")) (_o$6278 "Success-type check a single analyzed form (RFC 0006). Returns a vector of\n diagnostics [{:op :argpos :type :msg} ...] for provably-wrong calls; empty\n when nothing is provably wrong. Runs independently of specialization so it is\n usable in normal builds (the decoupled checking path).\n\n With strict? true, also reports calls to registered user functions whose\n concrete argument types provably make the body throw (opt-in,\n closed-world). user-sig-box accumulates registered defs across forms, so a\n def must precede its call \x2014; the same ordering RFC 0005 already assumes.")) (jolt-hash-map _o$6277 _o$6278)))) + (def-var! "jolt.passes.types" "set-check-mode!" (letrec ((set-check-mode! (lambda (on strict?) (let fnrec5331 ((on on) (strict? strict?)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "check-mode-box") (let* ((_o$5332 (keyword #f "on")) (_o$5333 (if (jolt-truthy? on) #t #f)) (_o$5334 (keyword #f "strict")) (_o$5335 (if (jolt-truthy? strict?) #t #f))) (jolt-hash-map _o$5332 _o$5333 _o$5334 _o$5335))))))) set-check-mode!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "infer-body" (letrec ((infer-body (case-lambda ((body tenv) (let fnrec6279 ((body body) (tenv tenv)) (infer-body body tenv jolt-nil jolt-nil jolt-nil))) ((body tenv self-name self-key) (let fnrec6280 ((body body) (tenv tenv) (self-name self-name) (self-key self-key)) (infer-body body tenv self-name self-key jolt-nil))) ((body tenv self-name self-key self-params) (let fnrec6281 ((body body) (tenv tenv) (self-name self-name) (self-key self-key) (self-params self-params)) (let* ((env (jolt-assoc (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f) (keyword #f "self-name") self-name (keyword #f "self-key") self-key (keyword #f "self-params") self-params)) (r (jolt-invoke (var-deref "jolt.passes.types" "infer") body tenv env))) (let* ((_o$6282 (jolt-nth r 0)) (_o$6283 (jolt-nth r 1)) (_o$6284 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "calls"))))) (jolt-vector _o$6282 _o$6283 _o$6284)))))))) infer-body) (let* ((_o$6285 (keyword #f "doc")) (_o$6286 "Type `body` under tenv (local-name -> type). Returns [ret-type node' calls],\n where calls is the [[\"ns/name\" [arg-types...]] ...] this body invokes (for\n propagating into callee param types). Also accumulates escapes (read with\n collected-escapes after a full sweep). With self-name/self-key, a recursive\n self-call or fn-level recur in `body` is collected under self-key too, so a\n self-recursive fn's params are constrained by its recursion, not just callers.")) (jolt-hash-map _o$6285 _o$6286)))) + (def-var! "jolt.passes.types" "take-diags!" (letrec ((take-diags! (lambda () (let fnrec5336 () (let* ((d (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "last-diags-box")))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "last-diags-box") (jolt-vector)) d)))))) take-diags!))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "impl-reg-ret" (letrec ((impl-reg-ret (lambda (node) (let fnrec6287 ((node node)) (if (jolt= (keyword #f "invoke") (jolt-get node (keyword #f "op"))) (let* ((f (jolt-get node (keyword #f "fn"))) (args (jolt-get node (keyword #f "args")))) (if (let* ((and__25__auto (jolt= (keyword #f "var") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((or__26__auto (jolt= "register-inline-method" (jolt-get f (keyword #f "name"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= "register-method" (jolt-get f (keyword #f "name"))))))) (if (jolt-truthy? and__25__auto) (jolt= 4 (jolt-count args)) and__25__auto)) and__25__auto)) (let* ((proto (jolt-get (jolt-nth args 1) (keyword #f "val"))) (method (jolt-get (jolt-nth args 2) (keyword #f "val"))) (fnn (jolt-nth args 3))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "string?") proto))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "string?") method))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get fnn (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt-seq (jolt-get fnn (keyword #f "arities"))) and__25__auto)) and__25__auto)) and__25__auto))) (let* ((_o$6291 (jolt-invoke (var-deref "clojure.core" "str") proto "/" method)) (_o$6292 (jolt-nth (let* ((_a$6288 (var-deref "jolt.passes.types" "infer-body")) (_a$6289 (jolt-get (jolt-first (jolt-get fnn (keyword #f "arities"))) (keyword #f "body"))) (_a$6290 (jolt-hash-map))) (jolt-invoke _a$6288 _a$6289 _a$6290)) 0))) (jolt-vector _o$6291 _o$6292)) jolt-nil)) jolt-nil)) jolt-nil))))) impl-reg-ret) (let* ((_o$6293 (keyword #f "private")) (_o$6294 #t)) (jolt-hash-map _o$6293 _o$6294)))) + (def-var! "jolt.passes.types" "run-inference" (letrec ((run-inference (lambda (opt) (let fnrec5337 ((opt opt)) (if (jolt-truthy? (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "check-mode-box")) (keyword #f "on"))) (let* ((env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #t (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "check-mode-box")) (keyword #f "strict")))) (r (jolt-invoke (var-deref "jolt.passes.types" "infer-top") opt env))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "last-diags-box") (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "diags")))) r)) (jolt-invoke (var-deref "jolt.passes.types" "infer-top") opt (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f))))))) run-inference))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "walk-pm-rets" (letrec ((walk-pm-rets (lambda (node acc) (let fnrec6295 ((node node) (acc acc)) (let* ((kr (jolt-invoke (var-deref "jolt.passes.types" "impl-reg-ret") node)) (acc (if (jolt-truthy? kr) (let* ((_a$6297 (var-deref "clojure.core" "update")) (_a$6298 acc) (_a$6299 (jolt-nth kr 0)) (_a$6300 (lambda (t) (let fnrec6296 ((t t)) (if (jolt-truthy? t) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") t (jolt-nth kr 1)) (jolt-nth kr 1)))))) (jolt-invoke _a$6297 _a$6298 _a$6299 _a$6300)) acc))) (jolt-invoke (var-deref "jolt.ir" "reduce-ir-children") (lambda (a c) (let fnrec6301 ((a a) (c c)) (walk-pm-rets c a))) acc node)))))) walk-pm-rets) (let* ((_o$6302 (keyword #f "private")) (_o$6303 #t)) (jolt-hash-map _o$6302 _o$6303)))) + (def-var-with-meta! "jolt.passes" "inline-fixpoint-cap" 8 (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "collect-pm-rets!" (letrec ((collect-pm-rets! (lambda (nodes) (let fnrec6304 ((nodes nodes)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "pm-rets-box") (let* ((_a$6306 (lambda (acc n) (let fnrec6305 ((acc acc) (n n)) (jolt-invoke (var-deref "jolt.passes.types" "walk-pm-rets") n acc)))) (_a$6307 (jolt-hash-map)) (_a$6308 nodes)) (jolt-reduce _a$6306 _a$6307 _a$6308))))))) collect-pm-rets!) (let* ((_o$6309 (keyword #f "doc")) (_o$6310 "Scan the unit's nodes for protocol-method impl registrations and stash each\n method's joined impl-return type (record-shapes must already be installed).")) (jolt-hash-map _o$6309 _o$6310)))) + (def-var! "jolt.passes" "inline-eligible?" (letrec ((inline-eligible? (lambda (node) (let fnrec5338 ((node node)) (let* ((and__25__auto (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get node (keyword #f "init")))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities")))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get (jolt-first (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities"))) (keyword #f "rest"))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto)))))) inline-eligible?))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "reinfer-def" (letrec ((reinfer-def (lambda (def-node ptmap) (let fnrec6311 ((def-node def-node) (ptmap ptmap)) (let* ((fnode (jolt-get def-node (keyword #f "init"))) (env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f)) (shapes (jolt-get env (keyword #f "record-shapes")))) (if (jolt= (keyword #f "fn") (jolt-get fnode (keyword #f "op"))) (jolt-assoc def-node (keyword #f "init") (jolt-assoc fnode (keyword #f "arities") (let* ((_a$6317 (var-deref "clojure.core" "mapv")) (_a$6318 (lambda (a) (let fnrec6312 ((a a)) (let* ((pt (let* ((_a$6314 (lambda (m pr) (let fnrec6313 ((m m) (pr pr)) (let* ((nm (jolt-nth pr 0)) (e (jolt-get shapes (jolt-nth pr 1)))) (if (jolt-truthy? (let* ((and__25__auto e)) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-contains? m nm)) and__25__auto))) (jolt-assoc m nm (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e (var-deref "jolt.passes.types.lattice" "type-depth") shapes)) m))))) (_a$6315 ptmap) (_a$6316 (jolt-get a (keyword #f "phints")))) (jolt-reduce _a$6314 _a$6315 _a$6316)))) (jolt-assoc a (keyword #f "body") (jolt-nth (jolt-invoke (var-deref "jolt.passes.types" "infer") (jolt-get a (keyword #f "body")) pt env) 1)))))) (_a$6319 (jolt-get fnode (keyword #f "arities")))) (jolt-invoke _a$6317 _a$6318 _a$6319)))) def-node)))))) reinfer-def) (let* ((_o$6320 (keyword #f "doc")) (_o$6321 "Re-run inference on a stashed :def's fn arity bodies with param types seeded\n (ptmap: param-name -> type), returning the def with annotated bodies. The back\n end emits the result directly (no further passes), so the param-typed lookups\n keep their specialization. Used by the inter-procedural recompile.")) (jolt-hash-map _o$6320 _o$6321)))) + (def-var! "jolt.passes" "stash-of" (letrec ((stash-of (lambda (node) (let fnrec5339 ((node node)) (let* ((a (jolt-first (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities"))))) (let* ((_o$5340 (keyword #f "params")) (_o$5341 (jolt-get a (keyword #f "params"))) (_o$5342 (keyword #f "body")) (_o$5343 (jolt-get a (keyword #f "body"))) (_o$5344 (keyword #f "nhints")) (_o$5345 (jolt-get a (keyword #f "nhints"))) (_o$5346 (keyword #f "ret")) (_o$5347 (jolt-get a (keyword #f "ret-nhint")))) (jolt-hash-map _o$5340 _o$5341 _o$5342 _o$5343 _o$5344 _o$5345 _o$5346 _o$5347))))))) stash-of))) (guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "phint-seed" (letrec ((phint-seed (lambda (params phints) (let fnrec6322 ((params params) (phints phints)) (let* ((shapes (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "config-box")) (keyword #f "record-shapes"))) (m (let* ((_a$6327 (lambda (acc pr) (let fnrec6323 ((acc acc) (pr pr)) (let* ((_a$6324 acc) (_a$6325 (jolt-nth pr 0)) (_a$6326 (jolt-nth pr 1))) (jolt-assoc _a$6324 _a$6325 _a$6326))))) (_a$6328 (jolt-hash-map)) (_a$6329 phints)) (jolt-reduce _a$6327 _a$6328 _a$6329)))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (nm) (let fnrec6330 ((nm nm)) (let* ((ck (jolt-get m nm)) (e (let* ((and__25__auto ck)) (if (jolt-truthy? and__25__auto) (jolt-get shapes ck) and__25__auto)))) (if (jolt-truthy? e) (jolt-invoke (var-deref "jolt.passes.types" "record-type-from-entry") e (var-deref "jolt.passes.types.lattice" "type-depth") shapes) jolt-nil)))) params)))))) phint-seed) (let* ((_o$6331 (keyword #f "doc")) (_o$6332 "Positional declared-hint type seeds for a fn arity. Given the param-name\n vector and the arity's :phints (a seq of [name ctor-key] pairs), return a\n vector parallel to params whose slot i is the resolved record TYPE of that\n param's ^Record hint (via the record-shapes registry), or nil. The\n whole-program fixpoint seeds these as a param-type FLOOR so a declared hint\n propagates to a fn's callees DURING inference \x2014; not only at the final re-emit\n (reinfer-def). Without it a hinted param with no callers stays :any through the\n fixpoint, so a field read off it (e.g. (:origin ^Ray r)) never tells a shared\n callee its arg is a Vec3.")) (jolt-hash-map _o$6331 _o$6332)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-seeds-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (let* ((_o$6333 (keyword #f "private")) (_o$6334 #t)) (jolt-hash-map _o$6333 _o$6334)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "param-seeds-for" (letrec ((param-seeds-for (lambda (k) (let fnrec6335 ((k k)) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "wp-seeds-box")) k))))) param-seeds-for) (let* ((_o$6336 (keyword #f "doc")) (_o$6337 "The param-name -> type seed map a top-level def should be reinferred with, or\n nil. Set by wp-infer!, read by run-passes during the final per-def emit.")) (jolt-hash-map _o$6336 _o$6337)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-num-seeds-box" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map)) (let* ((_o$6338 (keyword #f "private")) (_o$6339 #t)) (jolt-hash-map _o$6338 _o$6339)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "param-num-seeds-for" (letrec ((param-num-seeds-for (lambda (k) (let fnrec6340 ((k k)) (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "wp-num-seeds-box")) k))))) param-num-seeds-for) (let* ((_o$6341 (keyword #f "doc")) (_o$6342 "The param-name -> :double seed map for a def's hintless flonum params, or nil.")) (jolt-hash-map _o$6341 _o$6342)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-specializable" (letrec ((wp-specializable (lambda (nodes) (let fnrec6343 ((nodes nodes)) (let* ((_a$6358 (lambda (m d) (let fnrec6344 ((m m) (d d)) (let* ((f (jolt-get d (keyword #f "init")))) (if (let* ((and__25__auto (jolt= (keyword #f "def") (jolt-get d (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count (jolt-get f (keyword #f "arities")))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get (jolt-first (jolt-get f (keyword #f "arities"))) (keyword #f "rest"))) and__25__auto)) and__25__auto)) and__25__auto)) (let* ((a (jolt-first (jolt-get f (keyword #f "arities"))))) (let* ((_a$6355 m) (_a$6356 (let* ((_a$6345 (var-deref "clojure.core" "str")) (_a$6346 (jolt-get d (keyword #f "ns"))) (_a$6347 "/") (_a$6348 (jolt-get d (keyword #f "name")))) (jolt-invoke _a$6345 _a$6346 _a$6347 _a$6348))) (_a$6357 (let* ((_o$6349 (keyword #f "name")) (_o$6350 (jolt-get d (keyword #f "name"))) (_o$6351 (keyword #f "params")) (_o$6352 (jolt-get a (keyword #f "params"))) (_o$6353 (keyword #f "body")) (_o$6354 (jolt-get a (keyword #f "body")))) (jolt-hash-map _o$6349 _o$6350 _o$6351 _o$6352 _o$6353 _o$6354)))) (jolt-assoc _a$6355 _a$6356 _a$6357))) m))))) (_a$6359 (jolt-hash-map)) (_a$6360 nodes)) (jolt-reduce _a$6358 _a$6359 _a$6360)))))) wp-specializable) (let* ((_o$6361 (keyword #f "private")) (_o$6362 #t)) (jolt-hash-map _o$6361 _o$6362)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-empty-ptypes" (letrec ((wp-empty-ptypes (lambda (spec ks) (let fnrec6363 ((spec spec) (ks ks)) (let* ((_a$6365 (lambda (m k) (let fnrec6364 ((m m) (k k)) (jolt-assoc m k (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "repeat") (jolt-count (jolt-get (jolt-get spec k) (keyword #f "params"))) jolt-nil)))))) (_a$6366 (jolt-hash-map)) (_a$6367 ks)) (jolt-reduce _a$6365 _a$6366 _a$6367)))))) wp-empty-ptypes) (let* ((_o$6368 (keyword #f "private")) (_o$6369 #t)) (jolt-hash-map _o$6368 _o$6369)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-accum" (letrec ((wp-accum (lambda (pt spec calls) (let fnrec6370 ((pt pt) (spec spec) (calls calls)) (jolt-reduce (lambda (pt2 c) (let fnrec6371 ((pt2 pt2) (c c)) (let* ((callee (jolt-nth c 0)) (args (jolt-nth c 1))) (if (jolt-contains? spec callee) (let* ((cur (jolt-get pt2 callee))) (jolt-assoc pt2 callee (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "map-indexed") (lambda (i t) (let fnrec6372 ((i i) (t t)) (if (jolt-n< i (jolt-count args)) (jolt-invoke (var-deref "jolt.passes.types.lattice" "join") t (jolt-nth args i)) t))) cur)))) pt2)))) pt calls))))) wp-accum) (let* ((_o$6373 (keyword #f "private")) (_o$6374 #t)) (jolt-hash-map _o$6373 _o$6374)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-pass" (letrec ((wp-pass (lambda (nodes spec ks ptypes) (let fnrec6375 ((nodes nodes) (spec spec) (ks ks) (ptypes ptypes)) (let* ((_a$6406 (lambda (acc node) (let fnrec6376 ((acc acc) (node node)) (let* ((k (if (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))) (let* ((_a$6377 (var-deref "clojure.core" "str")) (_a$6378 (jolt-get node (keyword #f "ns"))) (_a$6379 "/") (_a$6380 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$6377 _a$6378 _a$6379 _a$6380)) jolt-nil)) (s (let* ((and__25__auto k)) (if (jolt-truthy? and__25__auto) (jolt-get spec k) and__25__auto)))) (if (jolt-truthy? s) (let* ((r (let* ((_a$6384 (var-deref "jolt.passes.types" "infer-body")) (_a$6385 (jolt-get s (keyword #f "body"))) (_a$6386 (let* ((_a$6381 (var-deref "clojure.core" "zipmap")) (_a$6382 (jolt-get s (keyword #f "params"))) (_a$6383 (jolt-get ptypes k))) (jolt-invoke _a$6381 _a$6382 _a$6383))) (_a$6387 (jolt-get s (keyword #f "name"))) (_a$6388 k) (_a$6389 (jolt-get s (keyword #f "params")))) (jolt-invoke _a$6384 _a$6385 _a$6386 _a$6387 _a$6388 _a$6389)))) (let* ((_a$6396 (var-deref "clojure.core" "update")) (_a$6397 (let* ((_a$6392 (var-deref "clojure.core" "assoc-in")) (_a$6393 acc) (_a$6394 (let* ((_o$6390 (keyword #f "rets")) (_o$6391 k)) (jolt-vector _o$6390 _o$6391))) (_a$6395 (jolt-nth r 0))) (jolt-invoke _a$6392 _a$6393 _a$6394 _a$6395))) (_a$6398 (keyword #f "ptypes")) (_a$6399 (var-deref "jolt.passes.types" "wp-accum")) (_a$6400 spec) (_a$6401 (jolt-nth r 2))) (jolt-invoke _a$6396 _a$6397 _a$6398 _a$6399 _a$6400 _a$6401))) (jolt-invoke (var-deref "clojure.core" "update") acc (keyword #f "ptypes") (var-deref "jolt.passes.types" "wp-accum") spec (jolt-nth (jolt-invoke (var-deref "jolt.passes.types" "infer-body") node (jolt-hash-map)) 2))))))) (_a$6407 (let* ((_o$6402 (keyword #f "rets")) (_o$6403 (jolt-hash-map)) (_o$6404 (keyword #f "ptypes")) (_o$6405 (jolt-invoke (var-deref "jolt.passes.types" "wp-empty-ptypes") spec ks))) (jolt-hash-map _o$6402 _o$6403 _o$6404 _o$6405))) (_a$6408 nodes)) (jolt-reduce _a$6406 _a$6407 _a$6408)))))) wp-pass) (let* ((_o$6409 (keyword #f "private")) (_o$6410 #t)) (jolt-hash-map _o$6409 _o$6410)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "wp-infer!" (letrec ((wp-infer! (lambda (nodes) (let fnrec6411 ((nodes nodes)) (begin (jolt-invoke (var-deref "jolt.passes.types" "collect-pm-rets!") nodes) (let* ((spec (jolt-invoke (var-deref "jolt.passes.types" "wp-specializable") nodes)) (ks (jolt-keys spec))) (let* ((iter 0) (ptypes (jolt-invoke (var-deref "jolt.passes.types" "wp-empty-ptypes") spec ks)) (rets (jolt-hash-map))) (let loop6412 ((iter iter) (ptypes ptypes) (rets rets)) (begin (jolt-invoke (var-deref "jolt.passes.types" "set-rtenv!") (let* ((_a$6414 (lambda (m k) (let fnrec6413 ((m m) (k k)) (let* ((v (jolt-get rets k))) (if (jolt-some? v) (jolt-assoc m k v) m))))) (_a$6415 (jolt-hash-map)) (_a$6416 ks)) (jolt-reduce _a$6414 _a$6415 _a$6416))) (jolt-invoke (var-deref "jolt.passes.types" "reset-escapes!")) (let* ((pass (jolt-invoke (var-deref "jolt.passes.types" "wp-pass") nodes spec ks ptypes)) (escaped (jolt-invoke (var-deref "clojure.core" "set") (jolt-invoke (var-deref "jolt.passes.types" "collected-escapes")))) (new-ptypes (let* ((_a$6418 (lambda (m k) (let fnrec6417 ((m m) (k k)) (if (jolt-contains? escaped k) (jolt-assoc m k (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "repeat") (jolt-count (jolt-get m k)) (keyword #f "any")))) m)))) (_a$6419 (jolt-get pass (keyword #f "ptypes"))) (_a$6420 ks)) (jolt-reduce _a$6418 _a$6419 _a$6420))) (new-rets (jolt-get pass (keyword #f "rets"))) (converged? (let* ((and__25__auto (jolt= new-ptypes ptypes))) (if (jolt-truthy? and__25__auto) (jolt= new-rets rets) and__25__auto)))) (if (jolt-truthy? (let* ((or__26__auto converged?)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n>= iter 16)))) (let* ((seed-ptypes (if (jolt-truthy? converged?) new-ptypes (jolt-reduce (lambda (m k) (let fnrec6421 ((m m) (k k)) (jolt-assoc m k (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "repeat") (jolt-count (jolt-get m k)) (keyword #f "any")))))) new-ptypes ks))) (pick (lambda (keep?) (let fnrec6422 ((keep? keep?)) (let* ((_a$6431 (lambda (m k) (let fnrec6423 ((m m) (k k)) (let* ((s (jolt-get spec k)) (pm (let* ((_a$6428 (lambda (pm pr) (let fnrec6424 ((pm pm) (pr pr)) (let* ((nm (jolt-nth pr 0)) (t (jolt-nth pr 1))) (if (jolt-truthy? (let* ((and__25__auto t)) (if (jolt-truthy? and__25__auto) (jolt-invoke keep? t) and__25__auto))) (jolt-assoc pm nm t) pm))))) (_a$6429 (jolt-hash-map)) (_a$6430 (let* ((_a$6425 jolt-vector) (_a$6426 (jolt-get s (keyword #f "params"))) (_a$6427 (jolt-get seed-ptypes k))) (jolt-map _a$6425 _a$6426 _a$6427)))) (jolt-reduce _a$6428 _a$6429 _a$6430)))) (if (jolt-truthy? (jolt-seq pm)) (jolt-assoc m k pm) m))))) (_a$6432 (jolt-hash-map)) (_a$6433 ks)) (jolt-reduce _a$6431 _a$6432 _a$6433)))))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "wp-seeds-box") (jolt-invoke pick (lambda (t) (let fnrec6434 ((t t)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "not=") t (keyword #f "any")))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "not=") t (keyword #f "double")) and__25__auto)))))) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "wp-num-seeds-box") (jolt-invoke pick (lambda (t) (let fnrec6435 ((t t)) (jolt= t (keyword #f "double")))))))) (loop6412 (jolt-inc iter) new-ptypes new-rets)))))))))))) wp-infer!) (let* ((_o$6436 (keyword #f "doc")) (_o$6437 "Run the closed-world param-type fixpoint over the unit's analyzed top-level\n nodes and stash the resulting per-def seed maps (read via param-seeds-for).\n record-shapes / protocol-methods must already be installed. Idempotent \x2014; resets\n the seed box; called once per build before per-form emit.")) (jolt-hash-map _o$6436 _o$6437)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "set-check-mode!" (letrec ((set-check-mode! (lambda (on strict?) (let fnrec6438 ((on on) (strict? strict?)) (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "check-mode-box") (let* ((_o$6439 (keyword #f "on")) (_o$6440 (if (jolt-truthy? on) #t #f)) (_o$6441 (keyword #f "strict")) (_o$6442 (if (jolt-truthy? strict?) #t #f))) (jolt-hash-map _o$6439 _o$6440 _o$6441 _o$6442))))))) set-check-mode!) (let* ((_o$6443 (keyword #f "doc")) (_o$6444 "Enable/disable checking during the next run-passes inference (direct-link).")) (jolt-hash-map _o$6443 _o$6444)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "take-diags!" (letrec ((take-diags! (lambda () (let fnrec6445 () (let* ((d (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "last-diags-box")))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "last-diags-box") (jolt-vector)) d)))))) take-diags!) (let* ((_o$6446 (keyword #f "doc")) (_o$6447 "Diagnostics accumulated by the last checking run-passes; clears the buffer.")) (jolt-hash-map _o$6446 _o$6447)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes.types" "run-inference" (letrec ((run-inference (lambda (opt) (let fnrec6448 ((opt opt)) (if (jolt-truthy? (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "check-mode-box")) (keyword #f "on"))) (let* ((env (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #t (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.types" "check-mode-box")) (keyword #f "strict")))) (r (jolt-invoke (var-deref "jolt.passes.types" "infer-top") opt env))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.types" "last-diags-box") (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get env (keyword #f "diags")))) r)) (jolt-invoke (var-deref "jolt.passes.types" "infer-top") opt (jolt-invoke (var-deref "jolt.passes.types" "mk-env") #f #f))))))) run-inference) (let* ((_o$6449 (keyword #f "doc")) (_o$6450 "Type-infer the optimized node (the inference walk specializes struct-safe\n lookups). When check mode is on (set-check-mode!), the same walk also emits\n success-type diagnostics, stashed for take-diags! to drain afterward. Pulled\n out of run-passes so the checking state stays private to this namespace.")) (jolt-hash-map _o$6449 _o$6450)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes" "inline-fixpoint-cap" 8 (let* ((_o$6451 (keyword #f "private")) (_o$6452 #t)) (jolt-hash-map _o$6451 _o$6452)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes" "inline-eligible?" (letrec ((inline-eligible? (lambda (node) (let fnrec6453 ((node node)) (let* ((and__25__auto (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get node (keyword #f "init")))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= 1 (jolt-count (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities")))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get (jolt-first (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities"))) (keyword #f "rest"))) and__25__auto)) and__25__auto)) and__25__auto)) and__25__auto)))))) inline-eligible?) (let* ((_o$6454 (keyword #f "private")) (_o$6455 #t)) (jolt-hash-map _o$6454 _o$6455)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes" "stash-of" (letrec ((stash-of (lambda (node) (let fnrec6456 ((node node)) (let* ((a (jolt-first (jolt-get (jolt-get node (keyword #f "init")) (keyword #f "arities"))))) (let* ((_o$6457 (keyword #f "params")) (_o$6458 (jolt-get a (keyword #f "params"))) (_o$6459 (keyword #f "body")) (_o$6460 (jolt-get a (keyword #f "body"))) (_o$6461 (keyword #f "nhints")) (_o$6462 (jolt-get a (keyword #f "nhints"))) (_o$6463 (keyword #f "ret")) (_o$6464 (jolt-get a (keyword #f "ret-nhint")))) (jolt-hash-map _o$6457 _o$6458 _o$6459 _o$6460 _o$6461 _o$6462 _o$6463 _o$6464))))))) stash-of) (let* ((_o$6465 (keyword #f "private")) (_o$6466 #t)) (jolt-hash-map _o$6465 _o$6466)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes" "inject-wp-nhints" (letrec ((inject-wp-nhints (lambda (node) (let fnrec6467 ((node node)) (let* ((seeds (if (jolt= (keyword #f "def") (jolt-get node (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.types" "param-num-seeds-for") (let* ((_a$6468 (var-deref "clojure.core" "str")) (_a$6469 (jolt-get node (keyword #f "ns"))) (_a$6470 "/") (_a$6471 (jolt-get node (keyword #f "name")))) (jolt-invoke _a$6468 _a$6469 _a$6470 _a$6471))) jolt-nil)) (f (jolt-get node (keyword #f "init")))) (if (jolt-truthy? (let* ((and__25__auto seeds)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (keyword #f "fn") (jolt-get f (keyword #f "op"))))) (if (jolt-truthy? and__25__auto) (jolt= 1 (jolt-count (jolt-get f (keyword #f "arities")))) and__25__auto)) and__25__auto))) (let* ((a (jolt-first (jolt-get f (keyword #f "arities")))) (have (let* ((_a$6472 (jolt-hash-set)) (_a$6473 (jolt-map jolt-first (jolt-get a (keyword #f "nhints"))))) (jolt-into _a$6472 _a$6473))) (add (jolt-invoke (var-deref "clojure.core" "mapcat") (lambda (G__139) (let fnrec6474 ((G__139 G__139)) (let* ((G__140 G__139) (p (jolt-nth G__140 0 jolt-nil)) (k (jolt-nth G__140 1 jolt-nil))) (if (jolt-not (jolt-invoke have p)) (jolt-list (let* ((_o$6475 p) (_o$6476 k)) (jolt-vector _o$6475 _o$6476))) (jolt-vector))))) seeds))) (jolt-assoc node (keyword #f "init") (jolt-assoc f (keyword #f "arities") (jolt-vector (jolt-assoc a (keyword #f "nhints") (jolt-invoke (var-deref "clojure.core" "vec") (jolt-concat (jolt-get a (keyword #f "nhints")) add))))))) node)))))) inject-wp-nhints) (let* ((_o$6477 (keyword #f "doc")) (_o$6478 "Merge the whole-program :double param seeds into a def's arity :nhints as\n synthetic ^double hints, so the numeric pass unboxes a hintless fn whose callers\n all pass flonums (the entry coercion exact->inexact is a no-op on a proven\n flonum). Only un-hinted params are added \x2014; an explicit hint wins. A no-op unless\n the closed-world fixpoint typed a param :double (param-num-seeds-for).")) (jolt-hash-map _o$6477 _o$6478)))) -(guard (e (#t #f)) - (def-var-with-meta! "jolt.passes" "run-passes" (letrec ((run-passes (lambda (node ctx) (let fnrec6479 ((node node) (ctx ctx)) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "inline-enabled?") ctx))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes" "inline-eligible?") node) and__25__auto))) (let* ((_a$6480 (var-deref "jolt.host" "stash-inline!")) (_a$6481 ctx) (_a$6482 (jolt-get node (keyword #f "ns"))) (_a$6483 (jolt-get node (keyword #f "name"))) (_a$6484 (jolt-invoke (var-deref "jolt.passes" "stash-of") node))) (jolt-invoke _a$6480 _a$6481 _a$6482 _a$6483 _a$6484)) jolt-nil) (jolt-invoke (var-deref "jolt.passes.numeric" "annotate") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "inline-enabled?") ctx)) (let* ((_ (jolt-invoke (var-deref "jolt.passes.inline" "set-rec-shapes!") (jolt-invoke (var-deref "jolt.host" "record-shapes") ctx))) (_ (jolt-invoke (var-deref "jolt.passes.types" "set-record-shapes!") (jolt-invoke (var-deref "jolt.host" "record-shapes") ctx))) (_ (jolt-invoke (var-deref "jolt.passes.types" "set-protocol-methods!") (jolt-invoke (var-deref "jolt.host" "protocol-methods") ctx))) (opt (let* ((i 0) (n (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") node))) (let loop6485 ((i i) (n n)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "dirty") #f) (let* ((n2 (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") (jolt-invoke (var-deref "jolt.passes.inline" "scalar-replace") (jolt-invoke (var-deref "jolt.passes.inline" "flatten-lets") (jolt-invoke (var-deref "jolt.passes.inline" "inline-node") n ctx)))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "dirty")))) (if (jolt-truthy? and__25__auto) (jolt-n< i (var-deref "jolt.passes" "inline-fixpoint-cap")) and__25__auto))) (loop6485 (jolt-inc i) n2) n2)))))) (seeds (if (jolt= (keyword #f "def") (jolt-get opt (keyword #f "op"))) (jolt-invoke (var-deref "jolt.passes.types" "param-seeds-for") (let* ((_a$6486 (var-deref "clojure.core" "str")) (_a$6487 (jolt-get opt (keyword #f "ns"))) (_a$6488 "/") (_a$6489 (jolt-get opt (keyword #f "name")))) (jolt-invoke _a$6486 _a$6487 _a$6488 _a$6489))) jolt-nil))) (jolt-invoke (var-deref "jolt.passes" "inject-wp-nhints") (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") (if (jolt-truthy? seeds) (jolt-invoke (var-deref "jolt.passes.types" "reinfer-def") opt seeds) (jolt-invoke (var-deref "jolt.passes.types" "run-inference") opt))))) (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") node)))))))) run-passes) (let* ((_o$6490 (keyword #f "doc")) (_o$6491 "All passes, in order. The back end applies this to every analyzed form. When\n inlining is enabled for the unit (user code under direct-linking),\n run inline + flatten + scalar-replace + const-fold to a capped fixpoint \x2014;\n inlining exposes map literals to lookups, scalar-replace collapses them, which\n may expose more \x2014; then a collection-type inference pass (optionally\n also emitting success diagnostics) that auto-drops the lookup guard where the\n type is proven. Otherwise (core + bootstrap) just const-fold, as before.\n\n numeric/annotate runs last in both branches (hint-directed fl*/fx* arithmetic);\n it benefits open builds too, so it is not gated on inlining.")) (jolt-hash-map _o$6490 _o$6491)))) \ No newline at end of file + (def-var! "jolt.passes" "run-passes" (letrec ((run-passes (lambda (node ctx) (let fnrec5348 ((node node) (ctx ctx)) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "inline-enabled?") ctx))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.passes" "inline-eligible?") node) and__25__auto))) (let* ((_a$5349 (var-deref "jolt.host" "stash-inline!")) (_a$5350 ctx) (_a$5351 (jolt-get node (keyword #f "ns"))) (_a$5352 (jolt-get node (keyword #f "name"))) (_a$5353 (jolt-invoke (var-deref "jolt.passes" "stash-of") node))) (jolt-invoke _a$5349 _a$5350 _a$5351 _a$5352 _a$5353)) jolt-nil) (jolt-invoke (var-deref "jolt.passes.numeric" "annotate") (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "inline-enabled?") ctx)) (let* ((_ (jolt-invoke (var-deref "jolt.passes.inline" "set-rec-shapes!") (jolt-invoke (var-deref "jolt.host" "record-shapes") ctx))) (_ (jolt-invoke (var-deref "jolt.passes.types" "set-record-shapes!") (jolt-invoke (var-deref "jolt.host" "record-shapes") ctx))) (opt (let* ((i 0) (n (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") node))) (let loop5354 ((i i) (n n)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "jolt.passes.inline" "dirty") #f) (let* ((n2 (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") (jolt-invoke (var-deref "jolt.passes.inline" "scalar-replace") (jolt-invoke (var-deref "jolt.passes.inline" "flatten-lets") (jolt-invoke (var-deref "jolt.passes.inline" "inline-node") n ctx)))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "jolt.passes.inline" "dirty")))) (if (jolt-truthy? and__25__auto) (< i (var-deref "jolt.passes" "inline-fixpoint-cap")) and__25__auto))) (loop5354 (jolt-inc i) n2) n2))))))) (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") (jolt-invoke (var-deref "jolt.passes.types" "run-inference") opt))) (jolt-invoke (var-deref "jolt.passes.fold" "const-fold") node)))))))) run-passes))) \ No newline at end of file diff --git a/host/chez/seed/prelude.ss b/host/chez/seed/prelude.ss index 1c9f784..9437931 100644 --- a/host/chez/seed/prelude.ss +++ b/host/chez/seed/prelude.ss @@ -1,511 +1,497 @@ (guard (e (#t #f)) - (def-var! "clojure.core" "zero?" (letrec ((zero? (lambda (x) (let fnrec5041 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt= x 0) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "zero? requires a number, got: " x))))))) zero?))) + (def-var! "clojure.core" "zero?" (letrec ((zero? (lambda (x) (let fnrec4278 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt= x 0) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "zero? requires a number, got: " x))))))) zero?))) (guard (e (#t #f)) - (def-var! "clojure.core" "pos?" (letrec ((pos? (lambda (x) (let fnrec5042 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt-n> x 0) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "pos? requires a number, got: " x))))))) pos?))) + (def-var! "clojure.core" "pos?" (letrec ((pos? (lambda (x) (let fnrec4279 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (> x 0) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "pos? requires a number, got: " x))))))) pos?))) (guard (e (#t #f)) - (def-var! "clojure.core" "every?" (letrec ((every? (lambda (pred coll) (let fnrec5043 ((pred pred) (coll coll)) (if (jolt-nil? (jolt-seq coll)) #t (if (jolt-truthy? (jolt-invoke pred (jolt-first coll))) (fnrec5043 pred (jolt-next coll)) #f)))))) every?))) + (def-var! "clojure.core" "every?" (letrec ((every? (lambda (pred coll) (let fnrec4280 ((pred pred) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-seq coll))) #t (if (jolt-truthy? (jolt-invoke pred (jolt-first coll))) (fnrec4280 pred (jolt-next coll)) #f)))))) every?))) (guard (e (#t #f)) - (def-var! "clojure.core" "empty?" (letrec ((empty? (lambda (coll) (let fnrec5044 ((coll coll)) (if (jolt-nil? coll) #t (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") coll)) (jolt-zero? (jolt-count coll)) (jolt-nil? (jolt-seq coll))))))))))) empty?))) + (def-var! "clojure.core" "empty?" (letrec ((empty? (lambda (coll) (let fnrec4281 ((coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") coll)) #t (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") coll)) (jolt-zero? (jolt-count coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") coll)) (jolt-zero? (jolt-count coll)) (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-seq coll))))))))))) empty?))) (guard (e (#t #f)) - (def-var! "clojure.core" "keys" (letrec ((keys (lambda (m) (let fnrec5045 ((m m)) (let* ((s (jolt-seq m))) (if (jolt-truthy? s) (jolt-map (lambda (e) (let fnrec5046 ((e e)) (jolt-nth e 0))) s) jolt-nil)))))) keys))) + (def-var! "clojure.core" "keys" (letrec ((keys (lambda (m) (let fnrec4282 ((m m)) (let* ((s (jolt-seq m))) (if (jolt-truthy? s) (jolt-map (lambda (e) (let fnrec4283 ((e e)) (jolt-nth e 0))) s) jolt-nil)))))) keys))) (guard (e (#t #f)) - (def-var! "clojure.core" "vals" (letrec ((vals (lambda (m) (let fnrec5047 ((m m)) (let* ((s (jolt-seq m))) (if (jolt-truthy? s) (jolt-map (lambda (e) (let fnrec5048 ((e e)) (jolt-nth e 1))) s) jolt-nil)))))) vals))) + (def-var! "clojure.core" "vals" (letrec ((vals (lambda (m) (let fnrec4284 ((m m)) (let* ((s (jolt-seq m))) (if (jolt-truthy? s) (jolt-map (lambda (e) (let fnrec4285 ((e e)) (jolt-nth e 1))) s) jolt-nil)))))) vals))) (guard (e (#t #f)) (def-var! "clojure.core" "when" - (lambda (test . body) (let fnrec5049 ((test test) (body (list->cseq body))) (let* ((_a$5050 (var-deref "clojure.core" "__sqcat")) (_a$5051 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$5052 (jolt-invoke (var-deref "clojure.core" "__sq1") test)) (_a$5053 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do")) body)))) (jolt-invoke _a$5050 _a$5051 _a$5052 _a$5053))))) + (lambda (test . body) (let fnrec4286 ((test test) (body (list->cseq body))) (let* ((_a$4287 (var-deref "clojure.core" "__sqcat")) (_a$4288 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$4289 (jolt-invoke (var-deref "clojure.core" "__sq1") test)) (_a$4290 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do")) body)))) (jolt-invoke _a$4287 _a$4288 _a$4289 _a$4290))))) (mark-macro! "clojure.core" "when")) (guard (e (#t #f)) (def-var! "clojure.core" "when-not" - (lambda (test . body) (let fnrec5054 ((test test) (body (list->cseq body))) (let* ((_a$5058 (var-deref "clojure.core" "__sqcat")) (_a$5059 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$5060 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5055 (var-deref "clojure.core" "__sqcat")) (_a$5056 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "not"))) (_a$5057 (jolt-invoke (var-deref "clojure.core" "__sq1") test))) (jolt-invoke _a$5055 _a$5056 _a$5057)))) (_a$5061 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do")) body)))) (jolt-invoke _a$5058 _a$5059 _a$5060 _a$5061))))) + (lambda (test . body) (let fnrec4291 ((test test) (body (list->cseq body))) (let* ((_a$4295 (var-deref "clojure.core" "__sqcat")) (_a$4296 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$4297 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4292 (var-deref "clojure.core" "__sqcat")) (_a$4293 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "not"))) (_a$4294 (jolt-invoke (var-deref "clojure.core" "__sq1") test))) (jolt-invoke _a$4292 _a$4293 _a$4294)))) (_a$4298 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do")) body)))) (jolt-invoke _a$4295 _a$4296 _a$4297 _a$4298))))) (mark-macro! "clojure.core" "when-not")) (guard (e (#t #f)) (def-var! "clojure.core" "and" - (lambda exprs (let fnrec5062 ((exprs (list->cseq exprs))) (if (jolt-empty? exprs) #t (if (jolt-empty? (jolt-rest exprs)) (jolt-first exprs) (let* ((_a$5074 (var-deref "clojure.core" "__sqcat")) (_a$5075 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "let*"))) (_a$5076 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5063 (var-deref "clojure.core" "__sqvec")) (_a$5064 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto"))) (_a$5065 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first exprs)))) (jolt-invoke _a$5063 _a$5064 _a$5065)))) (_a$5077 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5069 (var-deref "clojure.core" "__sqcat")) (_a$5070 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$5071 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto"))) (_a$5072 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5066 (var-deref "clojure.core" "__sqcat")) (_a$5067 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "and"))) (_a$5068 (jolt-rest exprs))) (jolt-invoke _a$5066 _a$5067 _a$5068)))) (_a$5073 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto")))) (jolt-invoke _a$5069 _a$5070 _a$5071 _a$5072 _a$5073))))) (jolt-invoke _a$5074 _a$5075 _a$5076 _a$5077))))))) + (lambda exprs (let fnrec4299 ((exprs (list->cseq exprs))) (if (jolt-empty? exprs) #t (if (jolt-empty? (jolt-rest exprs)) (jolt-first exprs) (let* ((_a$4311 (var-deref "clojure.core" "__sqcat")) (_a$4312 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "let*"))) (_a$4313 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4300 (var-deref "clojure.core" "__sqvec")) (_a$4301 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto"))) (_a$4302 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first exprs)))) (jolt-invoke _a$4300 _a$4301 _a$4302)))) (_a$4314 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4306 (var-deref "clojure.core" "__sqcat")) (_a$4307 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$4308 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto"))) (_a$4309 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4303 (var-deref "clojure.core" "__sqcat")) (_a$4304 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "and"))) (_a$4305 (jolt-rest exprs))) (jolt-invoke _a$4303 _a$4304 _a$4305)))) (_a$4310 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "and__25__auto")))) (jolt-invoke _a$4306 _a$4307 _a$4308 _a$4309 _a$4310))))) (jolt-invoke _a$4311 _a$4312 _a$4313 _a$4314))))))) (mark-macro! "clojure.core" "and")) (guard (e (#t #f)) (def-var! "clojure.core" "or" - (lambda exprs (let fnrec5078 ((exprs (list->cseq exprs))) (if (jolt-empty? exprs) jolt-nil (if (jolt-empty? (jolt-rest exprs)) (jolt-first exprs) (let* ((_a$5090 (var-deref "clojure.core" "__sqcat")) (_a$5091 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "let*"))) (_a$5092 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5079 (var-deref "clojure.core" "__sqvec")) (_a$5080 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$5081 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first exprs)))) (jolt-invoke _a$5079 _a$5080 _a$5081)))) (_a$5093 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5085 (var-deref "clojure.core" "__sqcat")) (_a$5086 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$5087 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$5088 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$5089 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5082 (var-deref "clojure.core" "__sqcat")) (_a$5083 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "or"))) (_a$5084 (jolt-rest exprs))) (jolt-invoke _a$5082 _a$5083 _a$5084))))) (jolt-invoke _a$5085 _a$5086 _a$5087 _a$5088 _a$5089))))) (jolt-invoke _a$5090 _a$5091 _a$5092 _a$5093))))))) + (lambda exprs (let fnrec4315 ((exprs (list->cseq exprs))) (if (jolt-empty? exprs) jolt-nil (if (jolt-empty? (jolt-rest exprs)) (jolt-first exprs) (let* ((_a$4327 (var-deref "clojure.core" "__sqcat")) (_a$4328 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "let*"))) (_a$4329 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4316 (var-deref "clojure.core" "__sqvec")) (_a$4317 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$4318 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first exprs)))) (jolt-invoke _a$4316 _a$4317 _a$4318)))) (_a$4330 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4322 (var-deref "clojure.core" "__sqcat")) (_a$4323 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$4324 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$4325 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "or__26__auto"))) (_a$4326 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4319 (var-deref "clojure.core" "__sqcat")) (_a$4320 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "or"))) (_a$4321 (jolt-rest exprs))) (jolt-invoke _a$4319 _a$4320 _a$4321))))) (jolt-invoke _a$4322 _a$4323 _a$4324 _a$4325 _a$4326))))) (jolt-invoke _a$4327 _a$4328 _a$4329 _a$4330))))))) (mark-macro! "clojure.core" "or")) (guard (e (#t #f)) (def-var! "clojure.core" "cond" - (lambda clauses (let fnrec5094 ((clauses (list->cseq clauses))) (if (jolt-empty? clauses) jolt-nil (let* ((_a$5098 (var-deref "clojure.core" "__sqcat")) (_a$5099 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$5100 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first clauses))) (_a$5101 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-nth clauses 1))) (_a$5102 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$5095 (var-deref "clojure.core" "__sqcat")) (_a$5096 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "cond"))) (_a$5097 (jolt-drop 2 clauses))) (jolt-invoke _a$5095 _a$5096 _a$5097))))) (jolt-invoke _a$5098 _a$5099 _a$5100 _a$5101 _a$5102)))))) + (lambda clauses (let fnrec4331 ((clauses (list->cseq clauses))) (if (jolt-empty? clauses) jolt-nil (let* ((_a$4335 (var-deref "clojure.core" "__sqcat")) (_a$4336 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "if"))) (_a$4337 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-first clauses))) (_a$4338 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-nth clauses 1))) (_a$4339 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4332 (var-deref "clojure.core" "__sqcat")) (_a$4333 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "cond"))) (_a$4334 (jolt-drop 2 clauses))) (jolt-invoke _a$4332 _a$4333 _a$4334))))) (jolt-invoke _a$4335 _a$4336 _a$4337 _a$4338 _a$4339)))))) (mark-macro! "clojure.core" "cond")) (guard (e (#t #f)) (def-var! "clojure.core" "ns" - (lambda (nm . clauses) (let fnrec5103 ((nm nm) (clauses (list->cseq clauses))) (let* ((nm (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "seq?") nm))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-symbol #f "with-meta") (jolt-first nm)) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "second") nm) nm)) (calls (let* ((_a$5133 (lambda (acc clause) (let fnrec5104 ((acc acc) (clause clause)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "seq?") clause))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") clause)))) (let* ((head (jolt-first clause)) (args (jolt-rest clause))) (if (jolt= head (keyword #f "require")) (jolt-conj acc (let* ((_a$5109 (var-deref "clojure.core" "__sqcat")) (_a$5110 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "require"))) (_a$5111 (jolt-map (lambda (s) (let fnrec5105 ((s s)) (let* ((_a$5106 (var-deref "clojure.core" "__sqcat")) (_a$5107 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$5108 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$5106 _a$5107 _a$5108)))) args))) (jolt-invoke _a$5109 _a$5110 _a$5111))) (if (jolt= head (keyword #f "use")) (jolt-conj acc (let* ((_a$5116 (var-deref "clojure.core" "__sqcat")) (_a$5117 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "use"))) (_a$5118 (jolt-map (lambda (s) (let fnrec5112 ((s s)) (let* ((_a$5113 (var-deref "clojure.core" "__sqcat")) (_a$5114 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$5115 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$5113 _a$5114 _a$5115)))) args))) (jolt-invoke _a$5116 _a$5117 _a$5118))) (if (jolt= head (keyword #f "import")) (jolt-conj acc (let* ((_a$5123 (var-deref "clojure.core" "__sqcat")) (_a$5124 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "import"))) (_a$5125 (jolt-map (lambda (s) (let fnrec5119 ((s s)) (let* ((_a$5120 (var-deref "clojure.core" "__sqcat")) (_a$5121 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$5122 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$5120 _a$5121 _a$5122)))) args))) (jolt-invoke _a$5123 _a$5124 _a$5125))) (if (jolt= head (keyword #f "refer-clojure")) (jolt-conj acc (let* ((_a$5130 (var-deref "clojure.core" "__sqcat")) (_a$5131 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "refer-clojure"))) (_a$5132 (jolt-map (lambda (s) (let fnrec5126 ((s s)) (let* ((_a$5127 (var-deref "clojure.core" "__sqcat")) (_a$5128 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$5129 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$5127 _a$5128 _a$5129)))) args))) (jolt-invoke _a$5130 _a$5131 _a$5132))) (if (jolt-truthy? 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(let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") k))) (if (jolt-truthy? and__25__auto) (jolt= nm (jolt-invoke (var-deref "clojure.core" "name") k)) and__25__auto))) (let* ((_o$4418 #t) (_o$4419 (jolt-get or-map k))) (jolt-vector _o$4418 _o$4419)) acc)))) (_a$4423 (let* ((_o$4420 #f) (_o$4421 jolt-nil)) (jolt-vector _o$4420 _o$4421))) (_a$4424 (if (jolt-truthy? or-map) (jolt-keys or-map) (jolt-vector)))) (jolt-reduce _a$4422 _a$4423 _a$4424))))) (amp? (lambda (x) (let fnrec4425 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? and__25__auto) (jolt= "&" (jolt-invoke (var-deref "clojure.core" "name") x)) and__25__auto))))) (proc (letrec ((proc (lambda (pat init acc) (let fnrec4426 ((pat pat) (init init) (acc acc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") pat)) (jolt-conj (jolt-conj acc pat) init) (if (jolt-truthy? 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(jolt-invoke unhint (jolt-first aftn)))) (let* ((a (jolt-invoke mk aftn))) (if (jolt-truthy? nm) (let* ((_a$5391 (var-deref "clojure.core" "__sqcat")) (_a$5392 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$5393 (jolt-invoke (var-deref "clojure.core" "__sq1") nm)) (_a$5394 a)) (jolt-invoke _a$5391 _a$5392 _a$5393 _a$5394)) (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*")) a))) (let* ((as (jolt-invoke (var-deref "clojure.core" "vec") (jolt-map mk aftn)))) (if (jolt-truthy? nm) (let* ((_a$5395 (var-deref "clojure.core" "__sqcat")) (_a$5396 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$5397 (jolt-invoke (var-deref "clojure.core" "__sq1") nm)) (_a$5398 as)) (jolt-invoke _a$5395 _a$5396 _a$5397 _a$5398)) (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*")) as)))))))) + (lambda raw (let fnrec4566 ((raw (list->cseq raw))) (let* ((nm (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") (jolt-first raw))) (jolt-first raw) jolt-nil)) (aftn (if (jolt-truthy? nm) (jolt-next raw) raw)) (unhint (lambda (x) (let fnrec4567 ((x x)) (if (jolt-truthy? (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") x)) (jolt= (jolt-symbol #f "with-meta") (jolt-first x)) #f)) (jolt-nth x 1) x)))) (wrap-conds (lambda (body) (let fnrec4568 ((body body)) (if (jolt-truthy? (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") 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(jolt-seq ps)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") 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(jolt-not (jolt= body raw-body)))) (if (jolt-truthy? (if (jolt-empty? (jolt-nth r 1)) (if (jolt-not hinted) (jolt-not conds?) #f) #f)) sig (let* ((pv (jolt-invoke (var-deref "clojure.core" "__sqvec") (jolt-nth r 0))) (lv (jolt-invoke (var-deref "clojure.core" "__sqvec") (jolt-nth r 1)))) (if (jolt-empty? (jolt-nth r 1)) (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") pv) body) (let* ((_a$4605 (var-deref "clojure.core" "__sqcat")) (_a$4606 (jolt-invoke (var-deref "clojure.core" "__sq1") pv)) (_a$4607 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4601 (var-deref "clojure.core" "__sqcat")) (_a$4602 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "let"))) (_a$4603 (jolt-invoke (var-deref "clojure.core" "__sq1") lv)) (_a$4604 body)) (jolt-invoke _a$4601 _a$4602 _a$4603 _a$4604))))) (jolt-invoke _a$4605 _a$4606 _a$4607)))))))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") (jolt-invoke unhint (jolt-first aftn)))) (let* ((a (jolt-invoke mk aftn))) (if (jolt-truthy? nm) (let* ((_a$4608 (var-deref "clojure.core" "__sqcat")) (_a$4609 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$4610 (jolt-invoke (var-deref "clojure.core" "__sq1") nm)) (_a$4611 a)) (jolt-invoke _a$4608 _a$4609 _a$4610 _a$4611)) (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*")) a))) (let* ((as (jolt-invoke (var-deref "clojure.core" "vec") (jolt-map mk aftn)))) (if (jolt-truthy? nm) (let* ((_a$4612 (var-deref "clojure.core" "__sqcat")) (_a$4613 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$4614 (jolt-invoke (var-deref "clojure.core" "__sq1") nm)) (_a$4615 as)) (jolt-invoke _a$4612 _a$4613 _a$4614 _a$4615)) (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*")) as)))))))) (mark-macro! "clojure.core" "fn")) (guard (e (#t #f)) (def-var! "clojure.core" "defn" - (lambda (fn-name . body) (let fnrec5399 ((fn-name fn-name) (body (list->cseq body))) (let* ((docstring (if (jolt-truthy? (let* ((and__25__auto (jolt-seq body))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "string?") (jolt-first body)) and__25__auto))) (jolt-first body) jolt-nil)) (body (if (jolt-truthy? docstring) (jolt-rest body) body)) (attr-map (if (jolt-truthy? (let* ((and__25__auto (jolt-seq body))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-next body))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") (jolt-first body)))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "symbol?") (jolt-first body))) and__25__auto)) and__25__auto)) and__25__auto))) (jolt-first body) jolt-nil)) (body (if (jolt-truthy? attr-map) (jolt-rest body) body)) (fn-only-name (if (jolt-truthy? 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(let* ((and__25__auto (jolt-seq body))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "string?") (jolt-first body)) and__25__auto))) (jolt-rest body) body)) (body (if (jolt-truthy? (let* ((and__25__auto (jolt-seq body))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") (jolt-first body)))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "symbol?") (jolt-first body))) and__25__auto)) and__25__auto))) (jolt-rest body) body)) (fn-only-name (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") fn-name)) fn-name (jolt-first (jolt-rest fn-name))))) (let* ((_a$4621 (var-deref "clojure.core" "__sqcat")) (_a$4622 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "def"))) (_a$4623 (jolt-invoke (var-deref "clojure.core" "__sq1") fn-name)) (_a$4624 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$4617 (var-deref "clojure.core" "__sqcat")) (_a$4618 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "fn"))) (_a$4619 (jolt-invoke (var-deref "clojure.core" "__sq1") fn-only-name)) (_a$4620 body)) (jolt-invoke _a$4617 _a$4618 _a$4619 _a$4620))))) (jolt-invoke _a$4621 _a$4622 _a$4623 _a$4624)))))) (mark-macro! "clojure.core" "defn")) (guard (e (#t #f)) (def-var! 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(jolt-invoke (var-deref "clojure.core" "meta") fn-name)) (jolt-invoke (var-deref "clojure.core" "meta") fn-name) (jolt-hash-map)) (keyword #f "private") #t)))) (_a$5420 body)) (jolt-invoke _a$5417 _a$5418 _a$5419 _a$5420))))) + (lambda (fn-name . body) (let fnrec4625 ((fn-name fn-name) (body (list->cseq body))) (let* ((_a$4626 (var-deref "clojure.core" "__sqcat")) (_a$4627 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "defn"))) (_a$4628 (jolt-invoke (var-deref "clojure.core" "__sq1") fn-name)) (_a$4629 body)) (jolt-invoke _a$4626 _a$4627 _a$4628 _a$4629))))) (mark-macro! "clojure.core" "defn-")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "fresh-sym" (letrec ((fresh-sym (lambda () (let fnrec5421 () (jolt-invoke (var-deref "clojure.core" "symbol") (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "gensym")))))))) fresh-sym) (let* ((_o$5422 (keyword #f "private")) (_o$5423 #t)) (jolt-hash-map _o$5422 _o$5423)))) + (def-var! "clojure.core" "fresh-sym" (letrec ((fresh-sym (lambda () (let fnrec4630 () (jolt-invoke (var-deref "clojure.core" "symbol") (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "gensym")))))))) fresh-sym))) (guard (e (#t #f)) (def-var! "clojure.core" "cond->" - (lambda (expr . clauses) (let fnrec5424 ((expr expr) (clauses (list->cseq clauses))) (let* ((step (letrec ((step (lambda (prev cls) (let fnrec5425 ((prev prev) (cls cls)) (if (jolt-empty? cls) prev (let* ((t (jolt-first cls)) (f (jolt-nth cls 1)) (gn (jolt-invoke (var-deref "clojure.core" "fresh-sym"))) (call (if (jolt-truthy? 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"clojure.core" "when-let")) (guard (e (#t #f)) (def-var! 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"clojure.core" "lazy-seq")) (guard (e (#t #f)) (def-var! "clojure.core" "lazy-cat" - (lambda colls (let fnrec5625 ((colls (list->cseq colls))) (let* ((_a$5630 (var-deref "clojure.core" "__sqcat")) (_a$5631 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "concat"))) (_a$5632 (jolt-map (lambda (c) (let fnrec5626 ((c c)) (let* ((_a$5627 (var-deref "clojure.core" "__sqcat")) (_a$5628 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "lazy-seq"))) (_a$5629 (jolt-invoke (var-deref "clojure.core" "__sq1") c))) (jolt-invoke _a$5627 _a$5628 _a$5629)))) colls))) (jolt-invoke _a$5630 _a$5631 _a$5632))))) + (lambda colls (let fnrec4837 ((colls (list->cseq colls))) (let* ((_a$4842 (var-deref "clojure.core" "__sqcat")) (_a$4843 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "concat"))) (_a$4844 (jolt-map (lambda (c) (let fnrec4838 ((c c)) (let* ((_a$4839 (var-deref "clojure.core" "__sqcat")) (_a$4840 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "lazy-seq"))) (_a$4841 (jolt-invoke (var-deref "clojure.core" "__sq1") c))) (jolt-invoke _a$4839 _a$4840 _a$4841)))) colls))) (jolt-invoke _a$4842 _a$4843 _a$4844))))) (mark-macro! "clojure.core" "lazy-cat")) (guard (e (#t #f)) - (def-var! "clojure.core" "not=" (letrec ((not= (case-lambda ((x) (let fnrec5633 ((x x)) #f)) ((x y) (let fnrec5634 ((x x) (y y)) (jolt-not (jolt= x y)))) ((x y . more) (let fnrec5635 ((x x) (y y) (more (list->cseq more))) (jolt-not (jolt-apply jolt= x y more))))))) not=))) + (def-var! "clojure.core" "not=" (letrec ((not= (case-lambda ((x) (let fnrec4845 ((x x)) #f)) ((x y) (let fnrec4846 ((x x) (y y)) (jolt-not (jolt= x y)))) ((x y . more) (let fnrec4847 ((x x) (y y) (more (list->cseq more))) (jolt-not (jolt-apply jolt= x y more))))))) not=))) (guard (e (#t #f)) - (def-var! "clojure.core" "unreduced" (letrec ((unreduced (lambda (x) (let fnrec5636 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") x)) (jolt-invoke (var-deref "clojure.core" "deref") x) x))))) unreduced))) + (def-var! "clojure.core" "unreduced" (letrec ((unreduced (lambda (x) (let fnrec4848 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") x)) (jolt-invoke (var-deref "clojure.core" "deref") x) x))))) unreduced))) (guard (e (#t #f)) - (def-var! "clojure.core" "second" (letrec ((second (lambda (coll) (let fnrec5637 ((coll coll)) (jolt-first (jolt-next coll)))))) second))) + (def-var! "clojure.core" "second" (letrec ((second (lambda (coll) (let fnrec4849 ((coll coll)) (jolt-first (jolt-next coll)))))) second))) (guard (e (#t #f)) - (def-var! "clojure.core" "peek" (letrec ((peek (lambda (coll) (let fnrec5638 ((coll coll)) (if (jolt-nil? coll) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (if (jolt-zero? (jolt-count coll)) jolt-nil (jolt-nth coll (jolt-dec (jolt-count coll)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") coll)) (jolt-first coll) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "peek not supported on: " coll)) jolt-nil)))))))) peek))) + (def-var! "clojure.core" "peek" (letrec ((peek (lambda (coll) (let fnrec4850 ((coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") coll)) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (if (jolt-zero? (jolt-count coll)) jolt-nil (jolt-nth coll (jolt-dec (jolt-count coll)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") coll)) (jolt-first coll) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "peek not supported on: " coll)) jolt-nil)))))))) peek))) (guard (e (#t #f)) - (def-var! "clojure.core" "subvec" (letrec ((subvec (case-lambda ((v start) (let fnrec5639 ((v v) (start start)) (subvec v start (jolt-count v)))) ((v start end) (let fnrec5640 ((v v) (start start) (end end)) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "vector?") v)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec requires a vector")) jolt-nil) (let* ((coerce (lambda (x) (let fnrec5641 ((x x)) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec index must be a number")) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") x x)) 0 (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "long") x) jolt-nil)))))) (s (jolt-invoke coerce start)) (e (jolt-invoke coerce end))) (begin (if (let* ((or__26__auto (jolt-n< s 0))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-n< e s))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n< (jolt-count v) e))))) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec index out of range: " s " " e)) jolt-nil) (let* ((i s) (acc (jolt-vector))) (let loop5642 ((i i) (acc acc)) (if (jolt-n< i e) (let* ((_a$5643 (jolt-inc i)) (_a$5644 (jolt-conj acc (jolt-nth v i)))) (loop5642 _a$5643 _a$5644)) acc))))))))))) subvec))) + (def-var! "clojure.core" "subvec" (letrec ((subvec (case-lambda ((v start) (let fnrec4851 ((v v) (start start)) (jolt-invoke subvec v start (jolt-count v)))) ((v start end) (let fnrec4852 ((v v) (start start) (end end)) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "vector?") v)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec requires a vector")) jolt-nil) (let* ((coerce (lambda (x) (let fnrec4853 ((x x)) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec index must be a number")) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not=") x x)) 0 (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "long") x) jolt-nil)))))) (s (jolt-invoke coerce start)) (e (jolt-invoke coerce end))) (begin (if (jolt-truthy? (let* ((or__26__auto (< s 0))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (< e s))) (if (jolt-truthy? or__26__auto) or__26__auto (< (jolt-count v) e)))))) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "subvec index out of range: " s " " e)) jolt-nil) (let* ((i s) (acc (jolt-vector))) (let loop4854 ((i i) (acc acc)) (if (< i e) (let* ((_a$4855 (jolt-inc i)) (_a$4856 (jolt-conj acc (jolt-nth v i)))) (loop4854 _a$4855 _a$4856)) acc))))))))))) subvec))) (guard (e (#t #f)) - (def-var! "clojure.core" "mapv" (letrec ((mapv (lambda (f . colls) (let fnrec5645 ((f f) (colls (list->cseq colls))) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-apply jolt-map f colls)))))) mapv))) + (def-var! "clojure.core" "mapv" (letrec ((mapv (lambda (f . colls) (let fnrec4857 ((f f) (colls (list->cseq colls))) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-apply jolt-map f colls)))))) mapv))) (guard (e (#t #f)) - (def-var! "clojure.core" "update" (letrec ((update (lambda (m k f . args) (let fnrec5646 ((m m) (k k) (f f) (args (list->cseq args))) (jolt-assoc m k (jolt-apply f (jolt-get m k) args)))))) update))) + (def-var! "clojure.core" "update" (letrec ((update (lambda (m k f . args) (let fnrec4858 ((m m) (k k) (f f) (args (list->cseq args))) (jolt-assoc m k (jolt-apply f (jolt-get m k) args)))))) update))) (guard (e (#t #f)) - (def-var! "clojure.core" "set" (letrec ((set (lambda (coll) (let fnrec5647 ((coll coll)) (if (jolt-nil? coll) (jolt-hash-set) (jolt-apply jolt-hash-set (jolt-seq coll))))))) set))) + (def-var! "clojure.core" "vreset!" (letrec ((vreset! (lambda (vol newval) (let fnrec4007 ((vol vol) (newval newval)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") vol (keyword #f "val") newval) newval))))) vreset!))) (guard (e (#t #f)) - (def-var! "clojure.core" "vreset!" (letrec ((vreset! (lambda (vol newval) (let fnrec4727 ((vol vol) (newval newval)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") vol (keyword #f "val") newval) newval))))) vreset!))) + (def-var! "clojure.core" "vswap!" (letrec ((vswap! (lambda (vol f . args) (let fnrec4008 ((vol vol) (f f) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "vreset!") vol (jolt-apply f (jolt-get vol (keyword #f "val")) args)))))) vswap!))) (guard (e (#t #f)) - (def-var! "clojure.core" "vswap!" (letrec ((vswap! (lambda (vol f . args) (let fnrec4728 ((vol vol) (f f) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "vreset!") vol (jolt-apply f (jolt-get vol (keyword #f "val")) args)))))) vswap!))) + (def-var! "clojure.core" "ffirst" (letrec ((ffirst (lambda (coll) (let fnrec4009 ((coll coll)) (jolt-first (jolt-first coll)))))) ffirst))) (guard (e (#t #f)) - (def-var! "clojure.core" "ffirst" (letrec ((ffirst (lambda (coll) (let fnrec4729 ((coll coll)) (jolt-first (jolt-first coll)))))) ffirst))) + (def-var! "clojure.core" "nfirst" (letrec ((nfirst (lambda (coll) (let fnrec4010 ((coll coll)) (jolt-next (jolt-first coll)))))) nfirst))) (guard (e (#t #f)) - (def-var! "clojure.core" "nfirst" (letrec ((nfirst (lambda (coll) (let fnrec4730 ((coll coll)) (jolt-next (jolt-first coll)))))) nfirst))) + (def-var! "clojure.core" "fnext" (letrec ((fnext (lambda (coll) (let fnrec4011 ((coll coll)) (jolt-first (jolt-next coll)))))) fnext))) (guard (e (#t #f)) - (def-var! "clojure.core" "fnext" (letrec ((fnext (lambda (coll) (let fnrec4731 ((coll coll)) (jolt-first (jolt-next coll)))))) fnext))) + (def-var! "clojure.core" "nnext" (letrec ((nnext (lambda (coll) (let fnrec4012 ((coll coll)) (jolt-next (jolt-next coll)))))) nnext))) (guard (e (#t #f)) - (def-var! "clojure.core" "nnext" (letrec ((nnext (lambda (coll) (let fnrec4732 ((coll coll)) (jolt-next (jolt-next coll)))))) nnext))) + (def-var! "clojure.core" "last" (letrec ((last (lambda (s) (let fnrec4013 ((s s)) (if (jolt-truthy? (jolt-next s)) (fnrec4013 (jolt-next s)) (jolt-first s)))))) last))) (guard (e (#t #f)) - (def-var! "clojure.core" "last" (letrec ((last (lambda (s) (let fnrec4733 ((s s)) (if (jolt-truthy? (jolt-next s)) (fnrec4733 (jolt-next s)) (jolt-first s)))))) last))) + (def-var! "clojure.core" "butlast" (letrec ((butlast (lambda (s) (let fnrec4014 ((s s)) (let* ((ret (jolt-vector)) (s s)) (let loop4015 ((ret ret) (s s)) (if (jolt-truthy? (jolt-next s)) (let* ((_a$4016 (jolt-conj ret (jolt-first s))) (_a$4017 (jolt-next s))) (loop4015 _a$4016 _a$4017)) (jolt-seq ret)))))))) butlast))) (guard (e (#t #f)) - (def-var! "clojure.core" "butlast" (letrec ((butlast (lambda (s) (let fnrec4734 ((s s)) (let* ((ret (jolt-vector)) (s s)) (let loop4735 ((ret ret) (s s)) (if (jolt-truthy? (jolt-next s)) (let* ((_a$4736 (jolt-conj ret (jolt-first s))) (_a$4737 (jolt-next s))) (loop4735 _a$4736 _a$4737)) (jolt-seq ret)))))))) butlast))) + (def-var! "clojure.core" "partition-by" (letrec ((partition-by (case-lambda ((f) (let fnrec4018 ((f f)) (lambda (rf) (let fnrec4019 ((rf rf)) (let* ((buf (jolt-invoke (var-deref "clojure.core" "volatile!") (jolt-vector))) (pv (jolt-invoke (var-deref "clojure.core" "volatile!") jolt-nil)) (started (jolt-invoke (var-deref "clojure.core" "volatile!") #f))) (case-lambda (() (let fnrec4020 () (jolt-invoke rf))) ((result) (let fnrec4021 ((result result)) (let* ((b (jolt-invoke (var-deref "clojure.core" "deref") buf)) (result (if (jolt-zero? (jolt-count b)) result (begin (jolt-invoke (var-deref "clojure.core" "vreset!") buf (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "unreduced") (jolt-invoke rf result b)))))) (jolt-invoke rf result)))) ((result input) (let fnrec4022 ((result result) (input input)) (let* ((val (jolt-invoke f input))) (if (jolt-truthy? (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") started)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= val (jolt-invoke (var-deref "clojure.core" "deref") pv))))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") started #t) (jolt-invoke (var-deref "clojure.core" "vreset!") pv val) (jolt-invoke (var-deref "clojure.core" "vswap!") buf jolt-conj input) result) (let* ((b (jolt-invoke (var-deref "clojure.core" "deref") buf))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") buf (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "vreset!") pv val) (let* ((ret (jolt-invoke rf result b))) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "reduced?") ret)) (jolt-invoke (var-deref "clojure.core" "vswap!") buf jolt-conj input) jolt-nil) ret)))))))))))))) ((f coll) (let fnrec4023 ((f f) (coll coll)) (let* ((step (letrec ((step (lambda (s) (let fnrec4024 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4025 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s (jolt-seq s))) (if (jolt-truthy? s) (let* ((fst (jolt-first s)) (fv (jolt-invoke f fst)) (run (jolt-cons fst (let* ((_a$4027 (var-deref "clojure.core" "take-while")) (_a$4028 (lambda (x) (let fnrec4026 ((x x)) (jolt= fv (jolt-invoke f x))))) (_a$4029 (jolt-rest s))) (jolt-invoke _a$4027 _a$4028 _a$4029))))) (jolt-cons run (jolt-invoke step (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4030 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-drop (jolt-count run) s)))))))) jolt-nil)))))))))) step))) (jolt-invoke step coll))))))) partition-by))) (guard (e (#t #f)) - (def-var! "clojure.core" "partition-by" (letrec ((partition-by (case-lambda ((f) (let fnrec4738 ((f f)) (lambda (rf) (let fnrec4739 ((rf rf)) (let* ((buf (jolt-invoke (var-deref "clojure.core" "volatile!") (jolt-vector))) (pv (jolt-invoke (var-deref "clojure.core" "volatile!") jolt-nil)) (started (jolt-invoke (var-deref "clojure.core" "volatile!") #f))) (case-lambda (() (let fnrec4740 () (jolt-invoke rf))) ((result) (let fnrec4741 ((result result)) (let* ((b (jolt-invoke (var-deref "clojure.core" "deref") buf)) (result (if (jolt-zero? (jolt-count b)) result (begin (jolt-invoke (var-deref "clojure.core" "vreset!") buf (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "unreduced") (jolt-invoke rf result b)))))) (jolt-invoke rf result)))) ((result input) (let fnrec4742 ((result result) (input input)) (let* ((val (jolt-invoke f input))) (if (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.core" "deref") started)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= val (jolt-invoke (var-deref "clojure.core" "deref") pv)))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") started #t) (jolt-invoke (var-deref "clojure.core" "vreset!") pv val) (jolt-invoke (var-deref "clojure.core" "vswap!") buf jolt-conj input) result) (let* ((b (jolt-invoke (var-deref "clojure.core" "deref") buf))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") buf (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "vreset!") pv val) (let* ((ret (jolt-invoke rf result b))) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "reduced?") ret)) (jolt-invoke (var-deref "clojure.core" "vswap!") buf jolt-conj input) jolt-nil) ret)))))))))))))) ((f coll) (let fnrec4743 ((f f) (coll coll)) (let* ((step (letrec ((step (lambda (s) (let fnrec4744 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4745 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s (jolt-seq s))) (if (jolt-truthy? s) (let* ((fst (jolt-first s)) (fv (jolt-invoke f fst)) (run (jolt-cons fst (let* ((_a$4747 (var-deref "clojure.core" "take-while")) (_a$4748 (lambda (x) (let fnrec4746 ((x x)) (jolt= fv (jolt-invoke f x))))) (_a$4749 (jolt-rest s))) (jolt-invoke _a$4747 _a$4748 _a$4749))))) (jolt-cons run (step (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4750 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-drop (jolt-count run) s)))))))) jolt-nil)))))))))) step))) (jolt-invoke step coll))))))) partition-by))) + (def-var! "clojure.core" "some?" (letrec ((some? (lambda (x) (let fnrec4031 ((x x)) (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") x)))))) some?))) (guard (e (#t #f)) - (def-var! "clojure.core" "some?" (letrec ((some? (lambda (x) (let fnrec4751 ((x x)) (jolt-not (jolt-nil? x)))))) some?))) + (def-var! "clojure.core" "identity" (letrec ((identity (lambda (x) (let fnrec4032 ((x x)) x)))) identity))) (guard (e (#t #f)) - (def-var! "clojure.core" "identity" (letrec ((identity (lambda (x) (let fnrec4752 ((x x)) x)))) identity))) + (def-var! "clojure.core" "constantly" (letrec ((constantly (lambda (x) (let fnrec4033 ((x x)) (lambda args (let fnrec4034 ((args (list->cseq args))) x)))))) constantly))) (guard (e (#t #f)) - (def-var! "clojure.core" "constantly" (letrec ((constantly (lambda (x) (let fnrec4753 ((x x)) (lambda args (let fnrec4754 ((args (list->cseq args))) x)))))) constantly))) + (def-var! "clojure.core" "neg?" (letrec ((neg? (lambda (x) (let fnrec4035 ((x x)) (< x 0))))) neg?))) (guard (e (#t #f)) - (def-var! "clojure.core" "neg?" (letrec ((neg? (lambda (x) (let fnrec4755 ((x x)) (jolt-n< x 0))))) neg?))) + (def-var! "clojure.core" "bit-and" (letrec ((bit-and (case-lambda ((x y) (let fnrec4036 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-and") x y))) ((x y . more) (let fnrec4037 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-and") (jolt-invoke (var-deref "clojure.core" "__bit-and") x y) more)))))) bit-and))) (guard (e (#t #f)) - (def-var! "clojure.core" "bit-and" (letrec ((bit-and (case-lambda ((x y) (let fnrec4756 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-and") x y))) ((x y . more) (let fnrec4757 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-and") (jolt-invoke (var-deref "clojure.core" "__bit-and") x y) more)))))) bit-and))) + (def-var! "clojure.core" "bit-or" (letrec ((bit-or (case-lambda ((x y) (let fnrec4038 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-or") x y))) ((x y . more) (let fnrec4039 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-or") (jolt-invoke (var-deref "clojure.core" "__bit-or") x y) more)))))) bit-or))) (guard (e (#t #f)) - (def-var! "clojure.core" "bit-or" (letrec ((bit-or (case-lambda ((x y) (let fnrec4758 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-or") x y))) ((x y . more) (let fnrec4759 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-or") (jolt-invoke (var-deref "clojure.core" "__bit-or") x y) more)))))) bit-or))) + (def-var! "clojure.core" "bit-xor" (letrec ((bit-xor (case-lambda ((x y) (let fnrec4040 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-xor") x y))) ((x y . more) (let fnrec4041 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-xor") (jolt-invoke (var-deref "clojure.core" "__bit-xor") x y) more)))))) bit-xor))) (guard (e (#t #f)) - (def-var! "clojure.core" "bit-xor" (letrec ((bit-xor (case-lambda ((x y) (let fnrec4760 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-xor") x y))) ((x y . more) (let fnrec4761 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-xor") (jolt-invoke (var-deref "clojure.core" "__bit-xor") x y) more)))))) bit-xor))) + (def-var! "clojure.core" "bit-and-not" (letrec ((bit-and-not (case-lambda ((x y) (let fnrec4042 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-and-not") x y))) ((x y . more) (let fnrec4043 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-and-not") (jolt-invoke (var-deref "clojure.core" "__bit-and-not") x y) more)))))) bit-and-not))) (guard (e (#t #f)) - (def-var! "clojure.core" "bit-and-not" (letrec ((bit-and-not (case-lambda ((x y) (let fnrec4762 ((x x) (y y)) (jolt-invoke (var-deref "clojure.core" "__bit-and-not") x y))) ((x y . more) (let fnrec4763 ((x x) (y y) (more (list->cseq more))) (jolt-reduce (var-deref "clojure.core" "__bit-and-not") (jolt-invoke (var-deref "clojure.core" "__bit-and-not") x y) more)))))) bit-and-not))) + (def-var! "clojure.core" "pr-str" (letrec ((pr-str (lambda xs (let fnrec4044 ((xs (list->cseq xs))) (let* ((out "") (s (jolt-seq xs)) (first? #t)) (let loop4045 ((out out) (s s) (first? first?)) (if (jolt-truthy? s) (let* ((_a$4050 (let* ((_a$4046 (var-deref "clojure.core" "str")) (_a$4047 out) (_a$4048 (if (jolt-truthy? first?) "" " ")) (_a$4049 (jolt-invoke (var-deref "clojure.core" "__pr-str1") (jolt-first s)))) (jolt-invoke _a$4046 _a$4047 _a$4048 _a$4049))) (_a$4051 (jolt-next s)) (_a$4052 #f)) (loop4045 _a$4050 _a$4051 _a$4052)) out))))))) pr-str))) (guard (e (#t #f)) - (def-var! "clojure.core" "pr-str" (letrec ((pr-str (lambda xs (let fnrec4764 ((xs (list->cseq xs))) (let* ((out "") (s (jolt-seq xs)) (first? #t)) (let loop4765 ((out out) (s s) (first? first?)) (if (jolt-truthy? s) (let* ((_a$4770 (let* ((_a$4766 (var-deref "clojure.core" "str")) (_a$4767 out) (_a$4768 (if (jolt-truthy? first?) "" " ")) (_a$4769 (jolt-invoke (var-deref "clojure.core" "__pr-str1") (jolt-first s)))) (jolt-invoke _a$4766 _a$4767 _a$4768 _a$4769))) (_a$4771 (jolt-next s)) (_a$4772 #f)) (loop4765 _a$4770 _a$4771 _a$4772)) out))))))) pr-str))) + (def-var! "clojure.core" "pr" (letrec ((pr (lambda xs (let fnrec4053 ((xs (list->cseq xs))) (begin (jolt-invoke (var-deref "clojure.core" "__write") (jolt-apply (var-deref "clojure.core" "pr-str") xs)) jolt-nil))))) pr))) (guard (e (#t #f)) - (def-var! "clojure.core" "pr" (letrec ((pr (lambda xs (let fnrec4773 ((xs (list->cseq xs))) (begin (jolt-invoke (var-deref "clojure.core" "__write") (jolt-apply (var-deref "clojure.core" "pr-str") xs)) jolt-nil))))) pr))) + (def-var! "clojure.core" "prn" (letrec ((prn (lambda xs (let fnrec4054 ((xs (list->cseq xs))) (begin (jolt-apply (var-deref "clojure.core" "pr") xs) (jolt-invoke (var-deref "clojure.core" "__write") "\n") jolt-nil))))) prn))) (guard (e (#t #f)) - (def-var! "clojure.core" "prn" (letrec ((prn (lambda xs (let fnrec4774 ((xs (list->cseq xs))) (begin (jolt-apply (var-deref "clojure.core" "pr") xs) (jolt-invoke (var-deref "clojure.core" "__write") "\n") jolt-nil))))) prn))) + (def-var! "clojure.core" "print" (letrec ((print (lambda xs (let fnrec4055 ((xs (list->cseq xs))) (begin (jolt-invoke (var-deref "clojure.core" "__write") (let* ((out "") (s (jolt-seq xs)) (first? #t)) (let loop4056 ((out out) (s s) (first? first?)) (if (jolt-truthy? s) (let* ((x (jolt-first s)) (r (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") x)) "nil" (jolt-invoke (var-deref "clojure.core" "str") x)))) (let* ((_a$4057 (jolt-invoke (var-deref "clojure.core" "str") out (if (jolt-truthy? first?) "" " ") r)) (_a$4058 (jolt-next s)) (_a$4059 #f)) (loop4056 _a$4057 _a$4058 _a$4059))) out)))) jolt-nil))))) print))) (guard (e (#t #f)) - (def-var! "clojure.core" "print" (letrec ((print (lambda xs (let fnrec4775 ((xs (list->cseq xs))) (begin (jolt-invoke (var-deref "clojure.core" "__write") (let* ((out "") (s (jolt-seq xs)) (first? #t)) (let loop4776 ((out out) (s s) (first? first?)) (if (jolt-truthy? s) (let* ((x (jolt-first s)) (r (jolt-invoke (var-deref "clojure.core" "__print1") x))) (let* ((_a$4777 (jolt-invoke (var-deref "clojure.core" "str") out (if (jolt-truthy? first?) "" " ") r)) (_a$4778 (jolt-next s)) (_a$4779 #f)) (loop4776 _a$4777 _a$4778 _a$4779))) out)))) jolt-nil))))) print))) + (def-var! "clojure.core" "println" (letrec ((println (lambda xs (let fnrec4060 ((xs (list->cseq xs))) (begin (jolt-apply (var-deref "clojure.core" "print") xs) (jolt-invoke (var-deref "clojure.core" "__write") "\n") jolt-nil))))) println))) (guard (e (#t #f)) - (def-var! "clojure.core" "println" (letrec ((println (lambda xs (let fnrec4780 ((xs (list->cseq xs))) (begin (jolt-apply (var-deref "clojure.core" "print") xs) (jolt-invoke (var-deref "clojure.core" "__write") "\n") jolt-nil))))) println))) + (def-var! "clojure.core" "frequencies" (letrec ((frequencies (lambda (coll) (let fnrec4061 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "persistent!") (let* ((_a$4063 (lambda (counts x) (let fnrec4062 ((counts counts) (x x)) (jolt-invoke (var-deref "clojure.core" "assoc!") counts x (jolt-inc (jolt-get counts x 0)))))) (_a$4064 (jolt-invoke (var-deref "clojure.core" "transient") (jolt-hash-map))) (_a$4065 coll)) (jolt-reduce _a$4063 _a$4064 _a$4065))))))) frequencies))) (guard (e (#t #f)) - (def-var! "clojure.core" "frequencies" (letrec ((frequencies (lambda (coll) (let fnrec4781 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "persistent!") (let* ((_a$4783 (lambda (counts x) (let fnrec4782 ((counts counts) (x x)) (jolt-invoke (var-deref "clojure.core" "assoc!") counts x (jolt-inc (jolt-get counts x 0)))))) (_a$4784 (jolt-invoke (var-deref "clojure.core" "transient") (jolt-hash-map))) (_a$4785 coll)) (jolt-reduce _a$4783 _a$4784 _a$4785))))))) frequencies))) + (def-var! "clojure.core" "group-by" (letrec ((group-by (lambda (f coll) (let fnrec4066 ((f f) (coll coll)) (let* ((tm (jolt-invoke (var-deref "clojure.core" "transient") (jolt-hash-map))) (ks (let* ((_a$4068 (lambda (ks x) (let fnrec4067 ((ks ks) (x x)) (let* ((k (jolt-invoke f x)) (b (jolt-get tm k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") b)) (begin (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-vector x)) (jolt-invoke (var-deref "clojure.core" "conj!") ks k)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") b)) (begin (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-invoke (var-deref "clojure.core" "conj!") (jolt-invoke (var-deref "clojure.core" "transient") b) x)) ks) (begin (jolt-invoke (var-deref "clojure.core" "conj!") b x) ks))))))) (_a$4069 (jolt-invoke (var-deref "clojure.core" "transient") (jolt-vector))) (_a$4070 coll)) (jolt-reduce _a$4068 _a$4069 _a$4070)))) (begin (let* ((_a$4072 (lambda (_ k) (let fnrec4071 ((_ _) (k k)) (let* ((b (jolt-get tm k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") b)) jolt-nil (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-invoke (var-deref "clojure.core" "persistent!") b))))))) (_a$4073 jolt-nil) (_a$4074 (jolt-invoke (var-deref "clojure.core" "persistent!") ks))) (jolt-reduce _a$4072 _a$4073 _a$4074)) (jolt-invoke (var-deref "clojure.core" "persistent!") tm))))))) group-by))) (guard (e (#t #f)) - (def-var! "clojure.core" "group-by" (letrec ((group-by (lambda (f coll) (let fnrec4786 ((f f) (coll coll)) (let* ((tm (jolt-invoke (var-deref "clojure.core" "transient") (jolt-hash-map))) (ks (let* ((_a$4788 (lambda (ks x) (let fnrec4787 ((ks ks) (x x)) (let* ((k (jolt-invoke f x)) (b (jolt-get tm k))) (if (jolt-nil? b) (begin (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-vector x)) (jolt-invoke (var-deref "clojure.core" "conj!") ks k)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") b)) (begin (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-invoke (var-deref "clojure.core" "conj!") (jolt-invoke (var-deref "clojure.core" "transient") b) x)) ks) (begin (jolt-invoke (var-deref "clojure.core" "conj!") b x) ks))))))) (_a$4789 (jolt-invoke (var-deref "clojure.core" "transient") (jolt-vector))) (_a$4790 coll)) (jolt-reduce _a$4788 _a$4789 _a$4790)))) (begin (let* ((_a$4792 (lambda (_ k) (let fnrec4791 ((_ _) (k k)) (let* ((b (jolt-get tm k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") b)) jolt-nil (jolt-invoke (var-deref "clojure.core" "assoc!") tm k (jolt-invoke (var-deref "clojure.core" "persistent!") b))))))) (_a$4793 jolt-nil) (_a$4794 (jolt-invoke (var-deref "clojure.core" "persistent!") ks))) (jolt-reduce _a$4792 _a$4793 _a$4794)) (jolt-invoke (var-deref "clojure.core" "persistent!") tm))))))) group-by))) + (def-var! "clojure.core" "not-empty" (letrec ((not-empty (lambda (coll) (let fnrec4075 ((coll coll)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") coll))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-zero? (jolt-count coll))))) jolt-nil coll))))) not-empty))) (guard (e (#t #f)) - (def-var! "clojure.core" "not-empty" (letrec ((not-empty (lambda (coll) (let fnrec4795 ((coll coll)) (if (let* ((or__26__auto (jolt-nil? coll))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-zero? (jolt-count coll)))) jolt-nil coll))))) not-empty))) + (def-var! "clojure.core" "filterv" (letrec ((filterv (lambda (pred coll) (let fnrec4076 ((pred pred) (coll coll)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-filter pred coll)))))) filterv))) (guard (e (#t #f)) - (def-var! "clojure.core" "filterv" (letrec ((filterv (lambda (pred coll) (let fnrec4796 ((pred pred) (coll coll)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-filter pred coll)))))) filterv))) + (def-var! "clojure.core" "max-key" (letrec ((max-key (case-lambda ((k x) (let fnrec4077 ((k k) (x x)) x)) ((k x y) (let fnrec4078 ((k k) (x x) (y y)) (if (let* ((_a$4079 (jolt-invoke k x)) (_a$4080 (jolt-invoke k y))) (> _a$4079 _a$4080)) x y))) ((k x y . more) (let fnrec4081 ((k k) (x x) (y y) (more (list->cseq more))) (let* ((kx (jolt-invoke k x)) (ky (jolt-invoke k y)) (v (if (> kx ky) x y)) (kv (if (> kx ky) kx ky))) (let* ((v v) (kv kv) (more more)) (let loop4082 ((v v) (kv kv) (more more)) (if (jolt-truthy? (jolt-seq more)) (let* ((w (jolt-first more)) (kw (jolt-invoke k w))) (if (>= kw kv) (loop4082 w kw (jolt-next more)) (loop4082 v kv (jolt-next more)))) v))))))))) max-key))) (guard (e (#t #f)) - (def-var! "clojure.core" "max-key" (letrec ((max-key (case-lambda ((k x) (let fnrec4797 ((k k) (x x)) x)) ((k x y) (let fnrec4798 ((k k) (x x) (y y)) (if (let* ((_a$4799 (jolt-invoke k x)) (_a$4800 (jolt-invoke k y))) (jolt-n> _a$4799 _a$4800)) x y))) ((k x y . more) (let fnrec4801 ((k k) (x x) (y y) (more (list->cseq more))) (let* ((kx (jolt-invoke k x)) (ky (jolt-invoke k y)) (v (if (jolt-n> kx ky) x y)) (kv (if (jolt-n> kx ky) kx ky))) (let* ((v v) (kv kv) (more more)) (let loop4802 ((v v) (kv kv) (more more)) (if (jolt-truthy? (jolt-seq more)) (let* ((w (jolt-first more)) (kw (jolt-invoke k w))) (if (jolt-n>= kw kv) (loop4802 w kw (jolt-next more)) (loop4802 v kv (jolt-next more)))) v))))))))) max-key))) + (def-var! "clojure.core" "min-key" (letrec ((min-key (case-lambda ((k x) (let fnrec4083 ((k k) (x x)) x)) ((k x y) (let fnrec4084 ((k k) (x x) (y y)) (if (let* ((_a$4085 (jolt-invoke k x)) (_a$4086 (jolt-invoke k y))) (< _a$4085 _a$4086)) x y))) ((k x y . more) (let fnrec4087 ((k k) (x x) (y y) (more (list->cseq more))) (let* ((kx (jolt-invoke k x)) (ky (jolt-invoke k y)) (v (if (< kx ky) x y)) (kv (if (< kx ky) kx ky))) (let* ((v v) (kv kv) (more more)) (let loop4088 ((v v) (kv kv) (more more)) (if (jolt-truthy? (jolt-seq more)) (let* ((w (jolt-first more)) (kw (jolt-invoke k w))) (if (<= kw kv) (loop4088 w kw (jolt-next more)) (loop4088 v kv (jolt-next more)))) v))))))))) min-key))) (guard (e (#t #f)) - (def-var! "clojure.core" "min-key" (letrec ((min-key (case-lambda ((k x) (let fnrec4803 ((k k) (x x)) x)) ((k x y) (let fnrec4804 ((k k) (x x) (y y)) (if (let* ((_a$4805 (jolt-invoke k x)) (_a$4806 (jolt-invoke k y))) (jolt-n< _a$4805 _a$4806)) x y))) ((k x y . more) (let fnrec4807 ((k k) (x x) (y y) (more (list->cseq more))) (let* ((kx (jolt-invoke k x)) (ky (jolt-invoke k y)) (v (if (jolt-n< kx ky) x y)) (kv (if (jolt-n< kx ky) kx ky))) (let* ((v v) (kv kv) (more more)) (let loop4808 ((v v) (kv kv) (more more)) (if (jolt-truthy? (jolt-seq more)) (let* ((w (jolt-first more)) (kw (jolt-invoke k w))) (if (jolt-n<= kw kv) (loop4808 w kw (jolt-next more)) (loop4808 v kv (jolt-next more)))) v))))))))) min-key))) + (def-var! "clojure.core" "juxt" (letrec ((juxt (lambda fs (let fnrec4089 ((fs (list->cseq fs))) (lambda args (let fnrec4090 ((args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (f) (let fnrec4091 ((f f)) (jolt-apply f args))) fs))))))) juxt))) (guard (e (#t #f)) - (def-var! "clojure.core" "juxt" (letrec ((juxt (lambda fs (let fnrec4809 ((fs (list->cseq fs))) (lambda args (let fnrec4810 ((args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (f) (let fnrec4811 ((f f)) (jolt-apply f args))) fs))))))) juxt))) + (def-var! "clojure.core" "every-pred" (letrec ((every-pred (lambda preds (let fnrec4092 ((preds (list->cseq preds))) (lambda xs (let fnrec4093 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p) (let fnrec4094 ((p p)) (jolt-invoke (var-deref "clojure.core" "every?") p xs))) preds))))))) every-pred))) (guard (e (#t #f)) - (def-var! "clojure.core" "every-pred" (letrec ((every-pred (lambda preds (let fnrec4812 ((preds (list->cseq preds))) (lambda xs (let fnrec4813 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p) (let fnrec4814 ((p p)) (jolt-invoke (var-deref "clojure.core" "every?") p xs))) preds))))))) every-pred))) + (def-var! "clojure.core" "some" (letrec ((some (lambda (pred coll) (let fnrec4095 ((pred pred) (coll coll)) (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((or__26__auto (jolt-invoke pred (jolt-first s)))) (if (jolt-truthy? or__26__auto) or__26__auto (fnrec4095 pred (jolt-next s))))) jolt-nil)))))) some))) (guard (e (#t #f)) - (def-var! "clojure.core" "some" (letrec ((some (lambda (pred coll) (let fnrec4815 ((pred pred) (coll coll)) (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((or__26__auto (jolt-invoke pred (jolt-first s)))) (if (jolt-truthy? or__26__auto) or__26__auto (fnrec4815 pred (jolt-next s))))) jolt-nil)))))) some))) + (def-var! "clojure.core" "some-fn" (letrec ((some-fn (lambda preds (let fnrec4096 ((preds (list->cseq preds))) (lambda xs (let fnrec4097 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "some") (lambda (p) (let fnrec4098 ((p p)) (jolt-invoke (var-deref "clojure.core" "some") p xs))) preds))))))) some-fn))) (guard (e (#t #f)) - (def-var! "clojure.core" "some-fn" (letrec ((some-fn (case-lambda ((p) (let fnrec4816 ((p p)) (letrec ((sp1 (case-lambda (() (let fnrec4817 () jolt-nil)) ((x) (let fnrec4818 ((x x)) (jolt-invoke p x))) ((x y) (let fnrec4819 ((x x) (y y)) (let* ((or__26__auto (jolt-invoke p x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p y))))) ((x y z) (let fnrec4820 ((x x) (y y) (z z)) (let* ((or__26__auto (jolt-invoke p x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p y))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p z))))))) ((x y z . args) (let fnrec4821 ((x x) (y y) (z z) (args (list->cseq args))) (let* ((or__26__auto (sp1 x y z))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") p args)))))))) sp1))) ((p1 p2) (let fnrec4822 ((p1 p1) (p2 p2)) (letrec ((sp2 (case-lambda (() (let fnrec4823 () jolt-nil)) ((x) (let fnrec4824 ((x x)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p2 x))))) ((x y) (let fnrec4825 ((x x) (y y)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p2 y))))))))) ((x y z) (let fnrec4826 ((x x) (y y) (z z)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 z))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 y))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p2 z))))))))))))) ((x y z . args) (let fnrec4827 ((x x) (y y) (z z) (args (list->cseq args))) (let* ((or__26__auto (sp2 x y z))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") (lambda (q) (let fnrec4828 ((q q)) (let* ((or__26__auto (jolt-invoke p1 q))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p2 q))))) args)))))))) sp2))) ((p1 p2 p3) (let fnrec4829 ((p1 p1) (p2 p2) (p3 p3)) (letrec ((sp3 (case-lambda (() (let fnrec4830 () jolt-nil)) ((x) (let fnrec4831 ((x x)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p3 x))))))) ((x y) (let fnrec4832 ((x x) (y y)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p3 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 y))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p3 y))))))))))))) ((x y z) (let fnrec4833 ((x x) (y y) (z z)) (let* ((or__26__auto (jolt-invoke p1 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p3 x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p3 y))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p1 z))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 z))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p3 z))))))))))))))))))) ((x y z . args) (let fnrec4834 ((x x) (y y) (z z) (args (list->cseq args))) (let* ((or__26__auto (sp3 x y z))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") (lambda (q) (let fnrec4835 ((q q)) (let* ((or__26__auto (jolt-invoke p1 q))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke p2 q))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke p3 q))))))) args)))))))) sp3))) ((p1 p2 p3 . ps) (let fnrec4836 ((p1 p1) (p2 p2) (p3 p3) (ps (list->cseq ps))) (let* ((ps (jolt-cons p1 (jolt-cons p2 (jolt-cons p3 ps))))) (letrec ((spn (case-lambda (() (let fnrec4837 () jolt-nil)) ((x) (let fnrec4838 ((x x)) (jolt-invoke (var-deref "clojure.core" "some") (lambda (p) (let fnrec4839 ((p p)) (jolt-invoke p x))) ps))) ((x y) (let fnrec4840 ((x x) (y y)) (let* ((or__26__auto (spn x))) (if (jolt-truthy? or__26__auto) or__26__auto (spn y))))) ((x y z) (let fnrec4841 ((x x) (y y) (z z)) (let* ((or__26__auto (spn x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (spn y))) (if (jolt-truthy? or__26__auto) or__26__auto (spn z))))))) ((x y z . args) (let fnrec4842 ((x x) (y y) (z z) (args (list->cseq args))) (let* ((or__26__auto (spn x y z))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") (lambda (p) (let fnrec4843 ((p p)) (jolt-invoke (var-deref "clojure.core" "some") p args))) ps)))))))) spn))))))) some-fn))) + (def-var! "clojure.core" "not-any?" (letrec ((not-any? (lambda (pred coll) (let fnrec4099 ((pred pred) (coll coll)) (jolt-not (jolt-invoke (var-deref "clojure.core" "some") pred coll)))))) not-any?))) (guard (e (#t #f)) - (def-var! "clojure.core" "not-any?" (letrec ((not-any? (lambda (pred coll) (let fnrec4844 ((pred pred) (coll coll)) (jolt-not (jolt-invoke (var-deref "clojure.core" "some") pred coll)))))) not-any?))) + (def-var! "clojure.core" "not-every?" (letrec ((not-every? (lambda (pred coll) (let fnrec4100 ((pred pred) (coll coll)) (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") pred coll)))))) not-every?))) (guard (e (#t #f)) - (def-var! "clojure.core" "not-every?" (letrec ((not-every? (lambda (pred coll) (let fnrec4845 ((pred pred) (coll coll)) (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") pred coll)))))) not-every?))) + (def-var! "clojure.core" "split-at" (letrec ((split-at (lambda (n coll) (let fnrec4101 ((n n) (coll coll)) (let* ((_o$4102 (jolt-take n coll)) (_o$4103 (jolt-drop n coll))) (jolt-vector _o$4102 _o$4103)))))) split-at))) (guard (e (#t #f)) - (def-var! "clojure.core" "split-at" (letrec ((split-at (lambda (n coll) (let fnrec4846 ((n n) (coll coll)) (let* ((_o$4847 (jolt-take n coll)) (_o$4848 (jolt-drop n coll))) (jolt-vector _o$4847 _o$4848)))))) split-at))) + (def-var! "clojure.core" "split-with" (letrec ((split-with (lambda (pred coll) (let fnrec4104 ((pred pred) (coll coll)) (let* ((_o$4105 (jolt-invoke (var-deref "clojure.core" "take-while") pred coll)) (_o$4106 (jolt-invoke (var-deref "clojure.core" "drop-while") pred coll))) (jolt-vector _o$4105 _o$4106)))))) split-with))) (guard (e (#t #f)) - (def-var! "clojure.core" "split-with" (letrec ((split-with (lambda (pred coll) (let fnrec4849 ((pred pred) (coll coll)) (let* ((_o$4850 (jolt-invoke (var-deref "clojure.core" "take-while") pred coll)) (_o$4851 (jolt-invoke (var-deref "clojure.core" "drop-while") pred coll))) (jolt-vector _o$4850 _o$4851)))))) split-with))) + (def-var! "clojure.core" "qualified-keyword?" (letrec ((qualified-keyword? (lambda (x) (let fnrec4107 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) qualified-keyword?))) (guard (e (#t #f)) - (def-var! "clojure.core" "qualified-keyword?" (letrec ((qualified-keyword? (lambda (x) (let fnrec4852 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? and__25__auto) (jolt-some? (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) qualified-keyword?))) + (def-var! "clojure.core" "simple-keyword?" (letrec ((simple-keyword? (lambda (x) (let fnrec4108 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) simple-keyword?))) (guard (e (#t #f)) - (def-var! "clojure.core" "simple-keyword?" (letrec ((simple-keyword? (lambda (x) (let fnrec4853 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? and__25__auto) (jolt-nil? (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) simple-keyword?))) + (def-var! "clojure.core" "qualified-symbol?" (letrec ((qualified-symbol? (lambda (x) (let fnrec4109 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) qualified-symbol?))) (guard (e (#t #f)) - (def-var! "clojure.core" "qualified-symbol?" (letrec ((qualified-symbol? (lambda (x) (let fnrec4854 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? and__25__auto) (jolt-some? (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) qualified-symbol?))) + (def-var! "clojure.core" "simple-symbol?" (letrec ((simple-symbol? (lambda (x) (let fnrec4110 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) simple-symbol?))) (guard (e (#t #f)) - (def-var! "clojure.core" "simple-symbol?" (letrec ((simple-symbol? (lambda (x) (let fnrec4855 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? and__25__auto) (jolt-nil? (jolt-invoke (var-deref "clojure.core" "namespace") x)) and__25__auto)))))) simple-symbol?))) + (def-var! "clojure.core" "ident?" (letrec ((ident? (lambda (x) (let fnrec4111 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))))))) ident?))) (guard (e (#t #f)) - (def-var! "clojure.core" "ident?" (letrec ((ident? (lambda (x) (let fnrec4856 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))))))) ident?))) + (def-var! "clojure.core" "qualified-ident?" (letrec ((qualified-ident? (lambda (x) (let fnrec4112 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "qualified-symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "qualified-keyword?") x))))))) qualified-ident?))) (guard (e (#t #f)) - (def-var! "clojure.core" "qualified-ident?" (letrec ((qualified-ident? (lambda (x) (let fnrec4857 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "qualified-symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "qualified-keyword?") x))))))) qualified-ident?))) + (def-var! "clojure.core" "simple-ident?" (letrec ((simple-ident? (lambda (x) (let fnrec4113 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "simple-symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "simple-keyword?") x))))))) simple-ident?))) (guard (e (#t #f)) - (def-var! "clojure.core" "simple-ident?" (letrec ((simple-ident? (lambda (x) (let fnrec4858 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "simple-symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "simple-keyword?") x))))))) simple-ident?))) + (def-var! "clojure.core" "ratio?" (letrec ((ratio? (lambda (x) (let fnrec4114 ((x x)) #f)))) ratio?))) (guard (e (#t #f)) - (def-var! "clojure.core" "ratio?" (letrec ((ratio? (lambda (x) (let fnrec4859 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "exact?") x))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "rational-type?") x))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "integer?") x)) and__25__auto)) and__25__auto)) and__25__auto)))))) ratio?))) + (def-var! "clojure.core" "decimal?" (letrec ((decimal? (lambda (x) (let fnrec4115 ((x x)) #f)))) decimal?))) (guard (e (#t #f)) - (def-var! "clojure.core" "rational?" (letrec ((rational? (lambda (x) (let fnrec4860 ((x x)) (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "exact?") x) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "decimal?") x))))))) rational?))) + (def-var! "clojure.core" "class?" (letrec ((class? (lambda (x) (let fnrec4116 ((x x)) #f)))) class?))) (guard (e (#t #f)) - (def-var! "clojure.core" "class?" (letrec ((class? (lambda (x) (let fnrec4861 ((x x)) #f)))) class?))) + (def-var! "clojure.core" "rational?" (letrec ((rational? (lambda (x) (let fnrec4117 ((x x)) (jolt-invoke (var-deref "clojure.core" "int?") x))))) rational?))) (guard (e (#t #f)) - (def-var! "clojure.core" "list?" (letrec ((list? (lambda (x) (let fnrec4862 ((x x)) (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "jolt.host" "cseq?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "jolt.host" "cseq-list?") x) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.host" "empty-list?") x))))))) list?))) + (def-var! "clojure.core" "nat-int?" (letrec ((nat-int? (lambda (x) (let fnrec4118 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (>= x 0) and__25__auto)))))) nat-int?))) (guard (e (#t #f)) - (def-var! "clojure.core" "nat-int?" (letrec ((nat-int? (lambda (x) (let fnrec4863 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (jolt-n>= x 0) and__25__auto)))))) nat-int?))) + (def-var! "clojure.core" "neg-int?" (letrec ((neg-int? (lambda (x) (let fnrec4119 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (jolt-neg? x) and__25__auto)))))) neg-int?))) (guard (e (#t #f)) - (def-var! "clojure.core" "neg-int?" (letrec ((neg-int? (lambda (x) (let fnrec4864 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (jolt-neg? x) and__25__auto)))))) neg-int?))) + (def-var! "clojure.core" "pos-int?" (letrec ((pos-int? (lambda (x) (let fnrec4120 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (jolt-pos? x) and__25__auto)))))) pos-int?))) (guard (e (#t #f)) - (def-var! "clojure.core" "pos-int?" (letrec ((pos-int? (lambda (x) (let fnrec4865 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "int?") x))) (if (jolt-truthy? and__25__auto) (jolt-pos? x) and__25__auto)))))) pos-int?))) + (def-var! "clojure.core" "replicate" (letrec ((replicate (lambda (n x) (let fnrec4121 ((n n) (x x)) (let* ((_a$4123 (lambda (_) (let fnrec4122 ((_ _)) x))) (_a$4124 (jolt-range n))) (jolt-map _a$4123 _a$4124)))))) replicate))) (guard (e (#t #f)) - (def-var! "clojure.core" "replicate" (letrec ((replicate (lambda (n x) (let fnrec4866 ((n n) (x x)) (let* ((_a$4868 (lambda (_) (let fnrec4867 ((_ _)) x))) (_a$4869 (jolt-range n))) (jolt-map _a$4868 _a$4869)))))) replicate))) + (def-var! "clojure.core" "take-last" (letrec ((take-last (lambda (n coll) (let fnrec4125 ((n n) (coll coll)) (let* ((c (jolt-invoke (var-deref "clojure.core" "vec") coll)) (len (jolt-count c))) (if (jolt-pos? len) (jolt-seq (jolt-invoke (var-deref "clojure.core" "subvec") c (max 0 (- len n)))) jolt-nil)))))) take-last))) (guard (e (#t #f)) - (def-var! "clojure.core" "take-last" (letrec ((take-last (lambda (n coll) (let fnrec4870 ((n n) (coll coll)) (let* ((c (jolt-invoke (var-deref "clojure.core" "vec") coll)) (len (jolt-count c))) (if (jolt-pos? len) (jolt-seq (jolt-invoke (var-deref "clojure.core" "subvec") c (jolt-n-max 0 (jolt-n- len n)))) jolt-nil)))))) take-last))) + (def-var! "clojure.core" "drop-last" (letrec ((drop-last (case-lambda ((coll) (let fnrec4126 ((coll coll)) (jolt-invoke drop-last 1 coll))) ((n coll) (let fnrec4127 ((n n) (coll coll)) (let* ((_a$4129 (lambda (x _) (let fnrec4128 ((x x) (_ _)) x))) (_a$4130 coll) (_a$4131 (jolt-drop n coll))) (jolt-map _a$4129 _a$4130 _a$4131))))))) drop-last))) (guard (e (#t #f)) - (def-var! "clojure.core" "drop-last" (letrec ((drop-last (case-lambda ((coll) (let fnrec4871 ((coll coll)) (drop-last 1 coll))) ((n coll) (let fnrec4872 ((n n) (coll coll)) (let* ((_a$4874 (lambda (x _) (let fnrec4873 ((x x) (_ _)) x))) (_a$4875 coll) (_a$4876 (jolt-drop n coll))) (jolt-map _a$4874 _a$4875 _a$4876))))))) drop-last))) + (def-var! "clojure.core" "distinct?" (letrec ((distinct? (case-lambda ((x) (let fnrec4132 ((x x)) #t)) ((x y) (let fnrec4133 ((x x) (y y)) (jolt-not (jolt= x y)))) ((x y . more) (let fnrec4134 ((x x) (y y) (more (list->cseq more))) (if (jolt-not (jolt= x y)) (let* ((s (let* ((_o$4136 x) (_o$4137 y)) (jolt-hash-set _o$4136 _o$4137))) (xs more)) (let loop4135 ((s s) (xs xs)) (if (jolt-truthy? xs) (let* ((x (jolt-first xs))) (if (jolt-contains? s x) #f (let* ((_a$4138 (jolt-conj s x)) (_a$4139 (jolt-next xs))) (loop4135 _a$4138 _a$4139)))) #t))) #f)))))) distinct?))) (guard (e (#t #f)) - (def-var! "clojure.core" "distinct?" (letrec ((distinct? (case-lambda ((x) (let fnrec4877 ((x x)) #t)) ((x y) (let fnrec4878 ((x x) (y y)) (jolt-not (jolt= x y)))) ((x y . more) (let fnrec4879 ((x x) (y y) (more (list->cseq more))) (if (jolt-not (jolt= x y)) (let* ((s (let* ((_o$4881 x) (_o$4882 y)) (jolt-hash-set _o$4881 _o$4882))) (xs more)) (let loop4880 ((s s) (xs xs)) (if (jolt-truthy? xs) (let* ((x (jolt-first xs))) (if (jolt-contains? s x) #f (let* ((_a$4883 (jolt-conj s x)) (_a$4884 (jolt-next xs))) (loop4880 _a$4883 _a$4884)))) #t))) #f)))))) distinct?))) + (def-var! "clojure.core" "replace" (letrec ((replace (lambda (smap coll) (let fnrec4140 ((smap smap) (coll coll)) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (x) (let fnrec4141 ((x x)) (jolt-get smap x x))) coll))))) replace))) (guard (e (#t #f)) - (def-var! "clojure.core" "replace" (letrec ((replace (lambda (smap coll) (let fnrec4885 ((smap smap) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (x) (let fnrec4886 ((x x)) (jolt-get smap x x))) coll) (jolt-map (lambda (x) (let fnrec4887 ((x x)) (jolt-get smap x x))) coll)))))) replace))) + (def-var! "clojure.core" "nthnext" (letrec ((nthnext (lambda (coll n) (let fnrec4142 ((coll coll) (n n)) (let* ((n n) (xs (jolt-seq coll))) (let loop4143 ((n n) (xs xs)) (if (jolt-truthy? (let* ((and__25__auto xs)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (let* ((_a$4144 (jolt-dec n)) (_a$4145 (jolt-next xs))) (loop4143 _a$4144 _a$4145)) xs))))))) nthnext))) (guard (e (#t #f)) - (def-var! "clojure.core" "nthnext" (letrec ((nthnext (lambda (coll n) (let fnrec4888 ((coll coll) (n n)) (let* ((n n) (xs (jolt-seq coll))) (let loop4889 ((n n) (xs xs)) (if (jolt-truthy? (let* ((and__25__auto xs)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (let* ((_a$4890 (jolt-dec n)) (_a$4891 (jolt-next xs))) (loop4889 _a$4890 _a$4891)) xs))))))) nthnext))) + (def-var! "clojure.core" "bounded-count" (letrec ((bounded-count (lambda (n coll) (let fnrec4146 ((n n) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "counted?") coll)) (jolt-count coll) (let* ((i 0) (s (jolt-seq coll))) (let loop4147 ((i i) (s s)) (if (jolt-truthy? (let* ((and__25__auto s)) (if (jolt-truthy? and__25__auto) (< i n) and__25__auto))) (let* ((_a$4148 (jolt-inc i)) (_a$4149 (jolt-next s))) (loop4147 _a$4148 _a$4149)) i)))))))) bounded-count))) (guard (e (#t #f)) - (def-var! "clojure.core" "bounded-count" (letrec ((bounded-count (lambda (n coll) (let fnrec4892 ((n n) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "counted?") coll)) (jolt-count coll) (let* ((i 0) (s (jolt-seq coll))) (let loop4893 ((i i) (s s)) (if (jolt-truthy? (let* ((and__25__auto s)) (if (jolt-truthy? and__25__auto) (jolt-n< i n) and__25__auto))) (let* ((_a$4894 (jolt-inc i)) (_a$4895 (jolt-next s))) (loop4893 _a$4894 _a$4895)) i)))))))) bounded-count))) + (def-var! "clojure.core" "run!" (letrec ((run! (lambda (proc coll) (let fnrec4150 ((proc proc) (coll coll)) (begin (jolt-reduce (lambda (_ x) (let fnrec4151 ((_ _) (x x)) (begin (jolt-invoke proc x) jolt-nil))) jolt-nil coll) jolt-nil))))) run!))) (guard (e (#t #f)) - (def-var! "clojure.core" "run!" (letrec ((run! (lambda (proc coll) (let fnrec4896 ((proc proc) (coll coll)) (begin (jolt-reduce (lambda (_ x) (let fnrec4897 ((_ _) (x x)) (jolt-invoke proc x))) jolt-nil coll) jolt-nil))))) run!))) + (def-var! "clojure.core" "completing" (letrec ((completing (case-lambda ((f) (let fnrec4152 ((f f)) (jolt-invoke completing f jolt-identity))) ((f cf) (let fnrec4153 ((f f) (cf cf)) (case-lambda (() (let fnrec4154 () (jolt-invoke f))) ((x) (let fnrec4155 ((x x)) (jolt-invoke cf x))) ((x y) (let fnrec4156 ((x x) (y y)) (jolt-invoke f x y))))))))) completing))) (guard (e (#t #f)) - (def-var! "clojure.core" "completing" (letrec ((completing (case-lambda ((f) (let fnrec4898 ((f f)) (completing f jolt-identity))) ((f cf) (let fnrec4899 ((f f) (cf cf)) (case-lambda (() (let fnrec4900 () (jolt-invoke f))) ((x) (let fnrec4901 ((x x)) (jolt-invoke cf x))) ((x y) (let fnrec4902 ((x x) (y y)) (jolt-invoke f x y))))))))) completing))) + (def-var! "clojure.core" "nthrest" (letrec ((nthrest (lambda (coll n) (let fnrec4157 ((coll coll) (n n)) (if (jolt-pos? n) (let* ((or__26__auto (let* ((n n) (xs coll)) (let loop4158 ((n n) (xs xs)) (let* ((s (let* ((and__25__auto (jolt-pos? n))) (if (jolt-truthy? and__25__auto) (jolt-seq xs) and__25__auto)))) (if (jolt-truthy? s) (let* ((_a$4159 (jolt-dec n)) (_a$4160 (jolt-rest s))) (loop4158 _a$4159 _a$4160)) (jolt-seq xs))))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-list ))) coll))))) nthrest))) (guard (e (#t #f)) - (def-var! "clojure.core" "nthrest" (letrec ((nthrest (lambda (coll n) (let fnrec4903 ((coll coll) (n n)) (if (jolt-pos? n) (let* ((or__26__auto (let* ((n n) (xs coll)) (let loop4904 ((n n) (xs xs)) (let* ((s (let* ((and__25__auto (jolt-pos? n))) (if (jolt-truthy? and__25__auto) (jolt-seq xs) and__25__auto)))) (if (jolt-truthy? s) (let* ((_a$4905 (jolt-dec n)) (_a$4906 (jolt-rest s))) (loop4904 _a$4905 _a$4906)) (jolt-seq xs))))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-list ))) coll))))) nthrest))) + (def-var! "clojure.core" "abs" (letrec ((abs (lambda (x) (let fnrec4161 ((x x)) (if (jolt-neg? x) (- 0 x) x))))) abs))) (guard (e (#t #f)) - (def-var! "clojure.core" "abs" (letrec ((abs (lambda (x) (let fnrec4907 ((x x)) (if (jolt-neg? x) (jolt-n- 0 x) x))))) abs))) + (def-var! "clojure.core" "NaN?" (letrec ((NaN? (lambda (x) (let fnrec4162 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt-not (jolt= x x)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "NaN? requires a number"))))))) NaN?))) (guard (e (#t #f)) - (def-var! "clojure.core" "NaN?" (letrec ((NaN? (lambda (x) (let fnrec4908 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) (jolt-not (jolt= x x)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "NaN? requires a number"))))))) NaN?))) + (def-var! "clojure.core" "object?" (letrec ((object? (lambda (x) (let fnrec4163 ((x x)) #f)))) object?))) (guard (e (#t #f)) - (def-var! "clojure.core" "object?" (letrec ((object? (lambda (x) (let fnrec4909 ((x x)) #f)))) object?))) + (def-var! "clojure.core" "undefined?" (letrec ((undefined? (lambda (x) (let fnrec4164 ((x x)) #f)))) undefined?))) (guard (e (#t #f)) - (def-var! "clojure.core" "undefined?" (letrec ((undefined? (lambda (x) (let fnrec4910 ((x x)) #f)))) undefined?))) + (def-var! "clojure.core" "keyword-identical?" (letrec ((keyword-identical? (lambda (a b) (let fnrec4165 ((a a) (b b)) (jolt= a b))))) keyword-identical?))) (guard (e (#t #f)) - (def-var! "clojure.core" "keyword-identical?" (letrec ((keyword-identical? (lambda (a b) (let fnrec4911 ((a a) (b b)) (jolt= a b))))) keyword-identical?))) + (def-var! "clojure.core" "any?" (letrec ((any? (lambda (x) (let fnrec4166 ((x x)) #t)))) any?))) (guard (e (#t #f)) - (def-var! "clojure.core" "any?" (letrec ((any? (lambda (x) (let fnrec4912 ((x x)) #t)))) any?))) + (def-var! "clojure.core" "printf" (letrec ((printf (lambda (fmt . args) (let fnrec4167 ((fmt fmt) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "print") (jolt-apply (var-deref "clojure.core" "format") fmt args)))))) printf))) (guard (e (#t #f)) - (def-var! "clojure.core" "printf" (letrec ((printf (lambda (fmt . args) (let fnrec4913 ((fmt fmt) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "print") (jolt-apply (var-deref "clojure.core" "format") fmt args)))))) printf))) + (def-var! "clojure.core" "bound?" (letrec ((bound? (lambda vars (let fnrec4168 ((vars (list->cseq vars))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (v) (let fnrec4169 ((v v)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-get v (keyword #f "root"))))) vars))))) bound?))) (guard (e (#t #f)) - (def-var! "clojure.core" "bound?" (letrec ((bound? (lambda vars (let fnrec4914 ((vars (list->cseq vars))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (v) (let fnrec4915 ((v v)) (jolt-some? (jolt-get v (keyword #f "root"))))) vars))))) bound?))) + (def-var! "clojure.core" "with-bindings*" (letrec ((with-bindings* (lambda (binding-map f . args) (let fnrec4170 ((binding-map binding-map) (f f) (args (list->cseq args))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") binding-map) (dynamic-wind (lambda () #f) (lambda () (jolt-apply f args)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) with-bindings*))) (guard (e (#t #f)) - (def-var! "clojure.core" "with-bindings*" (letrec ((with-bindings* (lambda (binding-map f . args) (let fnrec4916 ((binding-map binding-map) (f f) (args (list->cseq args))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") binding-map) (dynamic-wind (lambda () #f) (lambda () (jolt-apply f args)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) with-bindings*))) + (def-var! "clojure.core" "bound-fn*" (letrec ((bound-fn* (lambda (f) (let fnrec4171 ((f f)) (let* ((bs (jolt-invoke (var-deref "clojure.core" "get-thread-bindings")))) (lambda args (let fnrec4172 ((args (list->cseq args))) (jolt-apply (var-deref "clojure.core" "with-bindings*") bs f args)))))))) bound-fn*))) (guard (e (#t #f)) - (def-var! "clojure.core" "bound-fn*" (letrec ((bound-fn* (lambda (f) (let fnrec4917 ((f f)) (let* ((bs (jolt-invoke (var-deref "clojure.core" "get-thread-bindings")))) (lambda args (let fnrec4918 ((args (list->cseq args))) (jolt-apply (var-deref "clojure.core" "with-bindings*") bs f args)))))))) bound-fn*))) + (def-var! "clojure.core" "thread-bound?" (letrec ((thread-bound? (lambda vars (let fnrec4173 ((vars (list->cseq vars))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (v) (let fnrec4174 ((v v)) (jolt-invoke (var-deref "clojure.core" "__thread-bound?") v))) vars))))) thread-bound?))) (guard (e (#t #f)) - (def-var! "clojure.core" "thread-bound?" (letrec ((thread-bound? (lambda vars (let fnrec4919 ((vars (list->cseq vars))) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (v) (let fnrec4920 ((v v)) (jolt-invoke (var-deref "clojure.core" "__thread-bound?") v))) vars))))) thread-bound?))) + (def-var! "clojure.core" "key" (letrec ((key (lambda (e) (let fnrec4175 ((e e)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map-entry?") e)) (jolt-nth e 0) (jolt-throw (jolt-ex-info "key requires a map entry" (jolt-hash-map)))))))) key))) (guard (e (#t #f)) - (def-var! "clojure.core" "key" (letrec ((key (lambda (e) (let fnrec4921 ((e e)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map-entry?") e)) (jolt-nth e 0) (jolt-throw (jolt-ex-info "key requires a map entry" (jolt-hash-map)))))))) key))) + (def-var! "clojure.core" "val" (letrec ((val (lambda (e) (let fnrec4176 ((e e)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map-entry?") e)) (jolt-nth e 1) (jolt-throw (jolt-ex-info "val requires a map entry" (jolt-hash-map)))))))) val))) (guard (e (#t #f)) - (def-var! "clojure.core" "val" (letrec ((val (lambda (e) (let fnrec4922 ((e e)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map-entry?") e)) (jolt-nth e 1) (jolt-throw (jolt-ex-info "val requires a map entry" (jolt-hash-map)))))))) val))) + (def-var! "clojure.core" "make-hierarchy" (letrec ((make-hierarchy (lambda () (let fnrec4177 () (let* ((_o$4178 (keyword #f "parents")) (_o$4179 (jolt-hash-map)) (_o$4180 (keyword #f "descendants")) (_o$4181 (jolt-hash-map)) (_o$4182 (keyword #f "ancestors")) (_o$4183 (jolt-hash-map))) (jolt-hash-map _o$4178 _o$4179 _o$4180 _o$4181 _o$4182 _o$4183)))))) make-hierarchy))) (guard (e (#t #f)) - (def-var! "clojure.core" "make-hierarchy" (letrec ((make-hierarchy (lambda () (let fnrec4923 () (let* ((_o$4924 (keyword #f "parents")) (_o$4925 (jolt-hash-map)) (_o$4926 (keyword #f "descendants")) (_o$4927 (jolt-hash-map)) (_o$4928 (keyword #f "ancestors")) (_o$4929 (jolt-hash-map))) (jolt-hash-map _o$4924 _o$4925 _o$4926 _o$4927 _o$4928 _o$4929)))))) make-hierarchy))) + (def-var-with-meta! "clojure.core" "global-hierarchy" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-invoke (var-deref "clojure.core" "make-hierarchy"))) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "global-hierarchy" (jolt-invoke (var-deref "clojure.core" "atom") (jolt-invoke (var-deref "clojure.core" "make-hierarchy"))) (let* ((_o$4930 (keyword #f "private")) (_o$4931 #t)) (jolt-hash-map _o$4930 _o$4931)))) + (def-var! "clojure.core" "isa?" (letrec ((isa? (case-lambda ((child parent) (let fnrec4184 ((child child) (parent parent)) (jolt-invoke isa? (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) child parent))) ((h child parent) (let fnrec4185 ((h h) (child child) (parent parent)) (let* ((or__26__auto (jolt= child parent))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-contains? (let* ((_a$4186 (jolt-get h (keyword #f "ancestors"))) (_a$4187 child) (_a$4188 (jolt-hash-set))) (jolt-get _a$4186 _a$4187 _a$4188)) parent))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") parent))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") child))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$4189 (jolt-count parent)) (_a$4190 (jolt-count child))) (jolt= _a$4189 _a$4190)))) (if (jolt-truthy? and__25__auto) (let* ((ret #t) (i 0)) (let loop4191 ((ret ret) (i i)) (if (jolt-truthy? (let* ((or__26__auto (jolt-not ret))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= i (jolt-count parent))))) ret (let* ((_a$4196 (let* ((_a$4192 isa?) (_a$4193 h) (_a$4194 (jolt-nth child i)) (_a$4195 (jolt-nth parent i))) (jolt-invoke _a$4192 _a$4193 _a$4194 _a$4195))) (_a$4197 (jolt-inc i))) (loop4191 _a$4196 _a$4197))))) and__25__auto)) and__25__auto)) and__25__auto))))))))))) isa?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "hier-assert" (letrec ((hier-assert (lambda (ok form) (let fnrec4932 ((ok ok) (form form)) (if (jolt-not ok) (jolt-throw (host-new "AssertionError" (jolt-invoke (var-deref "clojure.core" "str") "Assert failed: " form))) jolt-nil))))) hier-assert) (let* ((_o$4933 (keyword #f "private")) (_o$4934 #t)) (jolt-hash-map _o$4933 _o$4934)))) + (def-var! "clojure.core" "parents" (letrec ((parents (case-lambda ((tag) (let fnrec4198 ((tag tag)) (jolt-invoke parents (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4199 ((h h) (tag tag)) (jolt-invoke (var-deref "clojure.core" "not-empty") (jolt-get (jolt-get h (keyword #f "parents")) tag))))))) parents))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "class-tag?" (letrec ((class-tag? (lambda (tag) (let fnrec4935 ((tag tag)) (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "class-value?") tag)) #t #f))))) class-tag?) (let* ((_o$4936 (keyword #f "private")) (_o$4937 #t)) (jolt-hash-map _o$4936 _o$4937)))) + (def-var! "clojure.core" "ancestors" (letrec ((ancestors (case-lambda ((tag) (let fnrec4200 ((tag tag)) (jolt-invoke ancestors (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4201 ((h h) (tag tag)) (jolt-invoke (var-deref "clojure.core" "not-empty") (jolt-get (jolt-get h (keyword #f "ancestors")) tag))))))) ancestors))) (guard (e (#t #f)) - (def-var! "clojure.core" "isa?" (letrec ((isa? (case-lambda ((child parent) (let fnrec4938 ((child child) (parent parent)) (isa? (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) child parent))) ((h child parent) (let fnrec4939 ((h h) (child child) (parent parent)) (let* ((or__26__auto (jolt= child parent))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.host" "class-isa?") child parent))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-contains? (let* ((_a$4940 (jolt-get h (keyword #f "ancestors"))) (_a$4941 child) (_a$4942 (jolt-hash-set))) (jolt-get _a$4940 _a$4941 _a$4942)) parent))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "class-tag?") child))) (if (jolt-truthy? and__25__auto) (let* ((_a$4947 (var-deref "clojure.core" "some")) (_a$4948 (lambda (s) (let fnrec4943 ((s s)) (jolt-contains? (let* ((_a$4944 (jolt-get h (keyword #f "ancestors"))) (_a$4945 s) (_a$4946 (jolt-hash-set))) (jolt-get _a$4944 _a$4945 _a$4946)) parent)))) (_a$4949 (jolt-invoke (var-deref "jolt.host" "class-supers") child))) (jolt-invoke _a$4947 _a$4948 _a$4949)) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") parent))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") child))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$4950 (jolt-count parent)) (_a$4951 (jolt-count child))) (jolt= _a$4950 _a$4951)))) (if (jolt-truthy? and__25__auto) (let* ((ret #t) (i 0)) (let loop4952 ((ret ret) (i i)) (if (let* ((or__26__auto (jolt-not ret))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= i (jolt-count parent)))) ret (let* ((_a$4956 (let* ((_a$4953 h) (_a$4954 (jolt-nth child i)) (_a$4955 (jolt-nth parent i))) (isa? _a$4953 _a$4954 _a$4955))) (_a$4957 (jolt-inc i))) (loop4952 _a$4956 _a$4957))))) and__25__auto)) and__25__auto)) and__25__auto))))))))))))))) isa?))) + (def-var! "clojure.core" "descendants" (letrec ((descendants (case-lambda ((tag) (let fnrec4202 ((tag tag)) (jolt-invoke descendants (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4203 ((h h) (tag tag)) (jolt-invoke (var-deref "clojure.core" "not-empty") (jolt-get (jolt-get h (keyword #f "descendants")) tag))))))) descendants))) (guard (e (#t #f)) - (def-var! "clojure.core" "parents" (letrec ((parents (case-lambda ((tag) (let fnrec4958 ((tag tag)) (parents (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4959 ((h h) (tag tag)) (jolt-invoke (var-deref "clojure.core" "not-empty") (let* ((tp (jolt-get (jolt-get h (keyword #f "parents")) tag))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "class-tag?") tag)) (jolt-into (jolt-invoke (var-deref "clojure.core" "set") (jolt-invoke (var-deref "jolt.host" "class-bases") tag)) tp) tp)))))))) parents))) + (def-var! "clojure.core" "derive" (letrec ((derive (case-lambda ((tag parent) (let fnrec4204 ((tag tag) (parent parent)) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "global-hierarchy") derive tag parent) jolt-nil))) ((h tag parent) (let fnrec4205 ((h h) (tag tag) (parent parent)) (let* ((tp (jolt-get h (keyword #f "parents"))) (td (jolt-get h (keyword #f "descendants"))) (ta (jolt-get h (keyword #f "ancestors"))) (tf (lambda (m source sources target targets) (let fnrec4206 ((m m) (source source) (sources sources) (target target) (targets targets)) (let* ((_a$4211 (lambda (ret k) (let fnrec4207 ((ret ret) (k k)) (jolt-assoc ret k (let* ((_a$4208 jolt-conj) (_a$4209 (jolt-get targets k (jolt-hash-set))) (_a$4210 (jolt-cons target (jolt-get targets target)))) (jolt-reduce _a$4208 _a$4209 _a$4210)))))) (_a$4212 m) (_a$4213 (jolt-cons source (jolt-get sources source)))) (jolt-reduce _a$4211 _a$4212 _a$4213)))))) (let* ((or__26__auto (if (jolt-not (jolt-contains? (jolt-get tp tag (jolt-hash-set)) parent)) (begin (if (jolt-contains? (jolt-get ta tag (jolt-hash-set)) parent) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") tag " already has " parent " as ancestor")) jolt-nil) (if (jolt-contains? (jolt-get ta parent (jolt-hash-set)) tag) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Cyclic derivation: " parent " has " tag " as ancestor")) jolt-nil) (let* ((_o$4214 (keyword #f "parents")) (_o$4215 (jolt-assoc tp tag (jolt-conj (jolt-get tp tag (jolt-hash-set)) parent))) (_o$4216 (keyword #f "ancestors")) (_o$4217 (jolt-invoke tf ta tag td parent ta)) (_o$4218 (keyword #f "descendants")) (_o$4219 (jolt-invoke tf td parent ta tag td))) (jolt-hash-map _o$4214 _o$4215 _o$4216 _o$4217 _o$4218 _o$4219))) jolt-nil))) (if (jolt-truthy? or__26__auto) or__26__auto h)))))))) derive))) (guard (e (#t #f)) - (def-var! "clojure.core" "ancestors" (letrec ((ancestors (case-lambda ((tag) (let fnrec4960 ((tag tag)) (ancestors (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4961 ((h h) (tag tag)) (jolt-invoke (var-deref "clojure.core" "not-empty") (let* ((ta (jolt-get (jolt-get h (keyword #f "ancestors")) tag))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "class-tag?") tag)) (let* ((superclasses (jolt-invoke (var-deref "clojure.core" "set") (jolt-invoke (var-deref "jolt.host" "class-supers") tag)))) (jolt-reduce jolt-into superclasses (jolt-cons ta (jolt-map (lambda (s) (let fnrec4962 ((s s)) (jolt-get (jolt-get h (keyword #f "ancestors")) s))) superclasses)))) ta)))))))) ancestors))) + (def-var! "clojure.core" "underive" (letrec ((underive (case-lambda ((tag parent) (let fnrec4220 ((tag tag) (parent parent)) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "global-hierarchy") underive tag parent) jolt-nil))) ((h tag parent) (let fnrec4221 ((h h) (tag tag) (parent parent)) (let* ((parent-map (jolt-get h (keyword #f "parents"))) (childs-parents (if (jolt-truthy? (jolt-get parent-map tag)) (jolt-invoke (var-deref "clojure.core" "disj") (jolt-get parent-map tag) parent) (jolt-hash-set))) (new-parents (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not-empty") childs-parents)) (jolt-assoc parent-map tag childs-parents) (jolt-dissoc parent-map tag))) (deriv-seq (let* ((_a$4228 (var-deref "clojure.core" "mapcat")) (_a$4229 (lambda (e) (let fnrec4222 ((e e)) (let* ((_a$4226 (jolt-invoke (var-deref "clojure.core" "key") e)) (_a$4227 (let* ((_a$4223 (var-deref "clojure.core" "interpose")) (_a$4224 (jolt-invoke (var-deref "clojure.core" "key") e)) (_a$4225 (jolt-invoke (var-deref "clojure.core" "val") e))) (jolt-invoke _a$4223 _a$4224 _a$4225)))) (jolt-cons _a$4226 _a$4227))))) (_a$4230 (jolt-seq new-parents))) (jolt-invoke _a$4228 _a$4229 _a$4230)))) (if (jolt-contains? (jolt-get parent-map tag (jolt-hash-set)) parent) (let* ((_a$4232 (lambda (p G__120) (let fnrec4231 ((p p) (G__120 G__120)) (let* ((G__121 G__120) (t (jolt-nth G__121 0 jolt-nil)) (pr (jolt-nth G__121 1 jolt-nil))) (jolt-invoke (var-deref "clojure.core" "derive") p t pr))))) (_a$4233 (jolt-invoke (var-deref "clojure.core" "make-hierarchy"))) (_a$4234 (jolt-invoke (var-deref "clojure.core" "partition") 2 deriv-seq))) (jolt-reduce _a$4232 _a$4233 _a$4234)) h))))))) underive))) (guard (e (#t #f)) - (def-var! "clojure.core" "descendants" (letrec ((descendants (case-lambda ((tag) (let fnrec4963 ((tag tag)) (descendants (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "global-hierarchy")) tag))) ((h tag) (let fnrec4964 ((h h) (tag tag)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "class-tag?") tag)) (jolt-throw (host-new "UnsupportedOperationException" "Can't get descendants of classes")) (jolt-invoke (var-deref "clojure.core" "not-empty") (jolt-get (jolt-get h (keyword #f "descendants")) tag)))))))) descendants))) + (def-var! "clojure.core" "sequential?" (letrec ((sequential? (lambda (x) (let fnrec4235 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "seq?") x))))))) sequential?))) (guard (e (#t #f)) - (def-var! "clojure.core" "derive" (letrec ((derive (case-lambda ((tag parent) (let fnrec4965 ((tag tag) (parent parent)) (begin (jolt-invoke (var-deref "clojure.core" "hier-assert") (jolt-invoke (var-deref "clojure.core" "namespace") parent) "(namespace parent)") (jolt-invoke (var-deref "clojure.core" "hier-assert") (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "class-tag?") tag))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") tag))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") tag))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "namespace") tag) and__25__auto)))) "(or (class? tag) (and (instance? clojure.lang.Named tag) (namespace tag)))") (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "global-hierarchy") derive tag parent) jolt-nil))) ((h tag parent) (let fnrec4966 ((h h) (tag tag) (parent parent)) (begin (jolt-invoke (var-deref "clojure.core" "hier-assert") (jolt-invoke (var-deref "clojure.core" "not=") tag parent) "(not= tag parent)") (jolt-invoke (var-deref "clojure.core" "hier-assert") (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "class-tag?") tag))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") tag))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") tag))))) "(or (class? tag) (instance? clojure.lang.Named tag))") (jolt-invoke (var-deref "clojure.core" "hier-assert") (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") parent))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") parent))) "(instance? clojure.lang.Named parent)") (let* ((tp (jolt-get h (keyword #f "parents"))) (td (jolt-get h (keyword #f "descendants"))) (ta (jolt-get h (keyword #f "ancestors"))) (tf (lambda (m source sources target targets) (let fnrec4967 ((m m) (source source) (sources sources) (target target) (targets targets)) (let* ((_a$4972 (lambda (ret k) (let fnrec4968 ((ret ret) (k k)) (jolt-assoc ret k (let* ((_a$4969 jolt-conj) (_a$4970 (jolt-get targets k (jolt-hash-set))) (_a$4971 (jolt-cons target (jolt-invoke targets target)))) (jolt-reduce _a$4969 _a$4970 _a$4971)))))) (_a$4973 m) (_a$4974 (jolt-cons source (jolt-invoke sources source)))) (jolt-reduce _a$4972 _a$4973 _a$4974)))))) (let* ((or__26__auto (if (jolt-not (jolt-contains? (jolt-invoke tp tag) parent)) (begin (if (jolt-contains? (jolt-invoke ta tag) parent) (jolt-throw (host-new "Exception" (jolt-invoke (var-deref "clojure.core" "str") tag " already has " parent " as ancestor"))) jolt-nil) (if (jolt-contains? (jolt-invoke ta parent) tag) (jolt-throw (host-new "Exception" (jolt-invoke (var-deref "clojure.core" "str") "Cyclic derivation: " parent " has " tag " as ancestor"))) jolt-nil) (let* ((_o$4975 (keyword #f "parents")) (_o$4976 (jolt-assoc tp tag (jolt-conj (jolt-get tp tag (jolt-hash-set)) parent))) (_o$4977 (keyword #f "ancestors")) (_o$4978 (jolt-invoke tf ta tag td parent ta)) (_o$4979 (keyword #f "descendants")) (_o$4980 (jolt-invoke tf td parent ta tag td))) (jolt-hash-map _o$4975 _o$4976 _o$4977 _o$4978 _o$4979 _o$4980))) jolt-nil))) (if (jolt-truthy? or__26__auto) or__26__auto h))))))))) derive))) + (def-var! "clojure.core" "associative?" (letrec ((associative? (lambda (x) (let fnrec4236 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))))))) associative?))) (guard (e (#t #f)) - (def-var! "clojure.core" "underive" (letrec ((underive (case-lambda ((tag parent) (let fnrec4981 ((tag tag) (parent parent)) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "global-hierarchy") underive tag parent) jolt-nil))) ((h tag parent) (let fnrec4982 ((h h) (tag tag) (parent parent)) (let* ((parent-map (jolt-get h (keyword #f "parents"))) (childs-parents (if (jolt-truthy? (jolt-invoke parent-map tag)) (jolt-invoke (var-deref "clojure.core" "disj") (jolt-invoke parent-map tag) parent) (jolt-hash-set))) (new-parents (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "not-empty") childs-parents)) (jolt-assoc parent-map tag childs-parents) (jolt-dissoc parent-map tag))) (deriv-seq (let* ((_a$4989 (var-deref "clojure.core" "mapcat")) (_a$4990 (lambda (e) (let fnrec4983 ((e e)) (let* ((_a$4987 (jolt-invoke (var-deref "clojure.core" "key") e)) (_a$4988 (let* ((_a$4984 (var-deref "clojure.core" "interpose")) (_a$4985 (jolt-invoke (var-deref "clojure.core" "key") e)) (_a$4986 (jolt-invoke (var-deref "clojure.core" "val") e))) (jolt-invoke _a$4984 _a$4985 _a$4986)))) (jolt-cons _a$4987 _a$4988))))) (_a$4991 (jolt-seq new-parents))) (jolt-invoke _a$4989 _a$4990 _a$4991)))) (if (jolt-contains? (jolt-invoke parent-map tag) parent) (let* ((_a$4993 (lambda (p G__136) (let fnrec4992 ((p p) (G__136 G__136)) (let* ((G__137 G__136) (t (jolt-nth G__137 0 jolt-nil)) (pr (jolt-nth G__137 1 jolt-nil))) (jolt-invoke (var-deref "clojure.core" "derive") p t pr))))) (_a$4994 (jolt-invoke (var-deref "clojure.core" "make-hierarchy"))) (_a$4995 (jolt-invoke (var-deref "clojure.core" "partition") 2 deriv-seq))) (jolt-reduce _a$4993 _a$4994 _a$4995)) h))))))) underive))) + (def-var! "clojure.core" "counted?" (letrec ((counted? (lambda (x) (let fnrec4237 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "set?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "list?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "string?") x))))))))))))) counted?))) (guard (e (#t #f)) - (def-var! "clojure.core" "sequential?" (letrec ((sequential? (lambda (x) (let fnrec4996 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "seq?") x))))))) sequential?))) -(guard (e (#t #f)) - (def-var! "clojure.core" "associative?" (letrec ((associative? (lambda (x) (let fnrec4997 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))))))) associative?))) -(guard (e (#t #f)) - (def-var! "clojure.core" "counted?" (letrec ((counted? (lambda (x) (let fnrec4998 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "set?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "list?") x))))))))))) counted?))) -(guard (e (#t #f)) - (def-var! "clojure.core" "indexed?" (letrec ((indexed? (lambda (x) (let fnrec4999 ((x x)) (jolt-invoke (var-deref "clojure.core" "vector?") x))))) indexed?))) + (def-var! "clojure.core" "indexed?" (letrec ((indexed? (lambda (x) (let fnrec4238 ((x x)) (jolt-invoke (var-deref "clojure.core" "vector?") x))))) indexed?))) (guard (e (#t #f)) (declare-var! "clojure.core" "sorted?")) (guard (e (#t #f)) - (def-var! "clojure.core" "reversible?" (letrec ((reversible? (lambda (x) (let fnrec5000 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted?") x))))))) reversible?))) + (def-var! "clojure.core" "reversible?" (letrec ((reversible? (lambda (x) (let fnrec4239 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted?") x))))))) reversible?))) (guard (e (#t #f)) - (def-var! "clojure.core" "seqable?" (letrec ((seqable? (lambda (x) (let fnrec5001 ((x x)) (if (jolt-truthy? (let* ((or__26__auto (jolt-nil? x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "coll?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "string?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.host" "array-value?") x)))))))) #t #f))))) seqable?))) + (def-var! "clojure.core" "seqable?" (letrec ((seqable? (lambda (x) (let fnrec4240 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "coll?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "string?") x))))))))) seqable?))) (guard (e (#t #f)) - (def-var! "clojure.core" "boolean?" (letrec ((boolean? (lambda (x) (let fnrec5002 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "false?") x))))))) boolean?))) + (def-var! "clojure.core" "boolean?" (letrec ((boolean? (lambda (x) (let fnrec4241 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "false?") x))))))) boolean?))) (guard (e (#t #f)) - (def-var! "clojure.core" "double?" (letrec ((double? (lambda (x) (let fnrec5003 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "integer?") x)) and__25__auto)))))) double?))) + (def-var! "clojure.core" "double?" (letrec ((double? (lambda (x) (let fnrec4242 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "integer?") x)) and__25__auto)))))) double?))) (guard (e (#t #f)) - (def-var! "clojure.core" "float?" (letrec ((float? (lambda (x) (let fnrec5004 ((x x)) (jolt-invoke (var-deref "clojure.core" "double?") x))))) float?))) + (def-var! "clojure.core" "float?" (letrec ((float? (lambda (x) (let fnrec4243 ((x x)) (jolt-invoke (var-deref "clojure.core" "double?") x))))) float?))) (guard (e (#t #f)) - (def-var! "clojure.core" "infinite?" (letrec ((infinite? (lambda (x) (let fnrec5005 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= x +inf.0))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= x -inf.0))) and__25__auto)))))) infinite?))) + (def-var! "clojure.core" "infinite?" (letrec ((infinite? (lambda (x) (let fnrec4244 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= x +inf.0))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= x -inf.0))) and__25__auto)))))) infinite?))) (guard (e (#t #f)) - (def-var! "clojure.core" "atom?" (letrec ((atom? (lambda (x) (let fnrec5006 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "atom")))))) atom?))) + (def-var! "clojure.core" "atom?" (letrec ((atom? (lambda (x) (let fnrec4245 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "atom")))))) atom?))) (guard (e (#t #f)) - (def-var! "clojure.core" "volatile?" (letrec ((volatile? (lambda (x) (let fnrec5007 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "volatile")))))) volatile?))) + (def-var! "clojure.core" "volatile?" (letrec ((volatile? (lambda (x) (let fnrec4246 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "volatile")))))) volatile?))) (guard (e (#t #f)) - (def-var! "clojure.core" "reader-conditional?" (letrec ((reader-conditional? (lambda (x) (let fnrec5008 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "reader-conditional")))))) reader-conditional?))) + (def-var! "clojure.core" "reader-conditional?" (letrec ((reader-conditional? (lambda (x) (let fnrec4247 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "reader-conditional")))))) reader-conditional?))) (guard (e (#t #f)) - (def-var! "clojure.core" "tagged-literal?" (letrec ((tagged-literal? (lambda (x) (let fnrec5009 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "tagged-literal")))))) tagged-literal?))) + (def-var! "clojure.core" "tagged-literal?" (letrec ((tagged-literal? (lambda (x) (let fnrec4248 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "tagged-literal")))))) tagged-literal?))) (guard (e (#t #f)) - (def-var! "clojure.core" "record?" (letrec ((record? (lambda (x) (let fnrec5010 ((x x)) (jolt-some? (jolt-get x (keyword "jolt" "deftype"))))))) record?))) + (def-var! "clojure.core" "record?" (letrec ((record? (lambda (x) (let fnrec4249 ((x x)) (jolt-invoke (var-deref "clojure.core" "some?") (jolt-get x (keyword "jolt" "deftype"))))))) record?))) (guard (e (#t #f)) - (def-var! "clojure.core" "uuid?" (letrec ((uuid? (lambda (x) (let fnrec5011 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "uuid")))))) uuid?))) + (def-var! "clojure.core" "uuid?" (letrec ((uuid? (lambda (x) (let fnrec4250 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "uuid")))))) uuid?))) (guard (e (#t #f)) - (def-var! "clojure.core" "inst?" (letrec ((inst? (lambda (x) (let fnrec5012 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "inst")))))) inst?))) + (def-var! "clojure.core" "inst?" (letrec ((inst? (lambda (x) (let fnrec4251 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "inst")))))) inst?))) (guard (e (#t #f)) - (def-var! "clojure.core" "char?" (letrec ((char? (lambda (x) (let fnrec5013 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "char")))))) char?))) + (def-var! "clojure.core" "char?" (letrec ((char? (lambda (x) (let fnrec4252 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "char")))))) char?))) (guard (e (#t #f)) - (def-var! "clojure.core" "realized?" (letrec ((realized? (lambda (x) (let fnrec5014 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "delay?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "realized"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "future?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cached"))) (if (jolt= (keyword "jolt" "lazy-seq") (jolt-get x (keyword "jolt" "type"))) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "realized"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "atom?") x)) #t (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "realized? not supported on: " (jolt-invoke (var-deref "clojure.core" "class") x))) jolt-nil))))))))) realized?))) + (def-var! "clojure.core" "realized?" (letrec ((realized? (lambda (x) (let fnrec4253 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "delay?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "realized"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "future?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cached"))) (if (jolt= (keyword "jolt" "lazy-seq") (jolt-get x (keyword "jolt" "type"))) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "realized"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "atom?") x)) #t (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "realized? not supported on: " x)) jolt-nil))))))))) realized?))) (guard (e (#t #f)) - (def-var! "clojure.core" "force" (letrec ((force (lambda (x) (let fnrec5015 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "delay?") x)) (jolt-invoke (var-deref "clojure.core" "deref") x) x))))) force))) + (def-var! "clojure.core" "force" (letrec ((force (lambda (x) (let fnrec4254 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "delay?") x)) (jolt-invoke (var-deref "clojure.core" "deref") x) x))))) force))) (guard (e (#t #f)) - (def-var! "clojure.core" "pop" (letrec ((pop (lambda (coll) (let fnrec5016 ((coll coll)) (if (jolt-nil? coll) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (if (jolt-zero? (jolt-count coll)) (jolt-throw "Can't pop empty vector") (jolt-invoke (var-deref "clojure.core" "subvec") coll 0 (jolt-dec (jolt-count coll)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") coll)) (if (jolt-nil? (jolt-seq coll)) (jolt-throw "Can't pop empty list") (jolt-rest coll)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "pop not supported on: " coll)) jolt-nil)))))))) pop))) + (def-var! "clojure.core" "pop" (letrec ((pop (lambda (coll) (let fnrec4255 ((coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") coll)) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (if (jolt-zero? (jolt-count coll)) (jolt-throw "Can't pop empty vector") (jolt-invoke (var-deref "clojure.core" "subvec") coll 0 (jolt-dec (jolt-count coll)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-seq coll))) (jolt-throw "Can't pop empty list") (jolt-rest coll)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "pop not supported on: " coll)) jolt-nil)))))))) pop))) (guard (e (#t #f)) - (def-var! "clojure.core" "dorun" (letrec ((dorun (case-lambda ((coll) (let fnrec5017 ((coll coll)) (let* ((s (jolt-seq coll))) (let loop5018 ((s s)) (if (jolt-truthy? s) (loop5018 (jolt-next s)) jolt-nil))))) ((n coll) (let fnrec5019 ((n n) (coll coll)) (let* ((n n) (s (jolt-seq coll))) (let loop5020 ((n n) (s s)) (if (jolt-truthy? (let* ((and__25__auto s)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (let* ((_a$5021 (jolt-dec n)) (_a$5022 (jolt-next s))) (loop5020 _a$5021 _a$5022)) jolt-nil)))))))) dorun))) + (def-var! "clojure.core" "dorun" (letrec ((dorun (case-lambda ((coll) (let fnrec4256 ((coll coll)) (let* ((s (jolt-seq coll))) (let loop4257 ((s s)) (if (jolt-truthy? s) (loop4257 (jolt-next s)) jolt-nil))))) ((n coll) (let fnrec4258 ((n n) (coll coll)) (let* ((n n) (s (jolt-seq coll))) (let loop4259 ((n n) (s s)) (if (jolt-truthy? (let* ((and__25__auto s)) (if (jolt-truthy? and__25__auto) (jolt-pos? n) and__25__auto))) (let* ((_a$4260 (jolt-dec n)) (_a$4261 (jolt-next s))) (loop4259 _a$4260 _a$4261)) jolt-nil)))))))) dorun))) (guard (e (#t #f)) - (def-var! "clojure.core" "doall" (letrec ((doall (case-lambda ((coll) (let fnrec5023 ((coll coll)) (begin (jolt-invoke (var-deref "clojure.core" "dorun") coll) coll))) ((n coll) (let fnrec5024 ((n n) (coll coll)) (begin (jolt-invoke (var-deref "clojure.core" "dorun") n coll) coll)))))) doall))) + (def-var! "clojure.core" "doall" (letrec ((doall (case-lambda ((coll) (let fnrec4262 ((coll coll)) (begin (jolt-invoke (var-deref "clojure.core" "dorun") coll) coll))) ((n coll) (let fnrec4263 ((n n) (coll coll)) (begin (jolt-invoke (var-deref "clojure.core" "dorun") n coll) coll)))))) doall))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "spread" (letrec ((spread (lambda (arglist) (let fnrec5025 ((arglist arglist)) (if (jolt-nil? arglist) jolt-nil (if (jolt-nil? (jolt-next arglist)) (jolt-seq (jolt-first arglist)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$5026 (jolt-first arglist)) (_a$5027 (spread (jolt-next arglist)))) (jolt-cons _a$5026 _a$5027)) jolt-nil))))))) spread) (let* ((_o$5028 (keyword #f "private")) (_o$5029 #t)) (jolt-hash-map _o$5028 _o$5029)))) + (def-var! "clojure.core" "spread" (letrec ((spread (lambda (arglist) (let fnrec4264 ((arglist arglist)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") arglist)) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-next arglist))) (jolt-seq (jolt-first arglist)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$4265 (jolt-first arglist)) (_a$4266 (jolt-invoke spread (jolt-next arglist)))) (jolt-cons _a$4265 _a$4266)) jolt-nil))))))) spread))) (guard (e (#t #f)) - (def-var! "clojure.core" "list*" (letrec ((list* (case-lambda ((args) (let fnrec5030 ((args args)) (jolt-seq args))) ((a args) (let fnrec5031 ((a a) (args args)) (jolt-cons a args))) ((a b args) (let fnrec5032 ((a a) (b b) (args args)) (jolt-cons a (jolt-cons b args)))) ((a b c args) (let fnrec5033 ((a a) (b b) (c c) (args args)) (jolt-cons a (jolt-cons b (jolt-cons c args))))) ((a b c d . more) (let fnrec5034 ((a a) (b b) (c c) (d d) (more (list->cseq more))) (jolt-cons a (jolt-cons b (jolt-cons c (jolt-cons d (jolt-invoke (var-deref "clojure.core" "spread") more)))))))))) list*))) + (def-var! "clojure.core" "list*" (letrec ((list* (case-lambda ((args) (let fnrec4267 ((args args)) (jolt-seq args))) ((a args) (let fnrec4268 ((a a) (args args)) (jolt-cons a args))) ((a b args) (let fnrec4269 ((a a) (b b) (args args)) (jolt-cons a (jolt-cons b args)))) ((a b c args) (let fnrec4270 ((a a) (b b) (c c) (args args)) (jolt-cons a (jolt-cons b (jolt-cons c args))))) ((a b c d . more) (let fnrec4271 ((a a) (b b) (c c) (d d) (more (list->cseq more))) (jolt-cons a (jolt-cons b (jolt-cons c (jolt-cons d (jolt-invoke (var-deref "clojure.core" "spread") more)))))))))) list*))) (guard (e (#t #f)) - (def-var! "clojure.core" "print-str" (letrec ((print-str (lambda xs (let fnrec5035 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec5036 () (jolt-apply (var-deref "clojure.core" "print") xs)))))))) print-str))) + (def-var! "clojure.core" "print-str" (letrec ((print-str (lambda xs (let fnrec4272 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec4273 () (jolt-apply (var-deref "clojure.core" "print") xs)))))))) print-str))) (guard (e (#t #f)) - (def-var! "clojure.core" "println-str" (letrec ((println-str (lambda xs (let fnrec5037 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec5038 () (jolt-apply (var-deref "clojure.core" "println") xs)))))))) println-str))) + (def-var! "clojure.core" "println-str" (letrec ((println-str (lambda xs (let fnrec4274 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec4275 () (jolt-apply (var-deref "clojure.core" "println") xs)))))))) println-str))) (guard (e (#t #f)) - (def-var! "clojure.core" "prn-str" (letrec ((prn-str (lambda xs (let fnrec5039 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec5040 () (jolt-apply (var-deref "clojure.core" "prn") xs)))))))) prn-str))) + (def-var! "clojure.core" "prn-str" (letrec ((prn-str (lambda xs (let fnrec4276 ((xs (list->cseq xs))) (jolt-invoke (var-deref "clojure.core" "__with-out-str") (lambda () (let fnrec4277 () (jolt-apply (var-deref "clojure.core" "prn") xs)))))))) prn-str))) (guard (e (#t #f)) - (def-var! "clojure.core" "rand-int" (letrec ((rand-int (lambda (n) (let fnrec4319 ((n n)) (jolt-invoke (var-deref "clojure.core" "int") (jolt-invoke (var-deref "clojure.core" "rand") n)))))) rand-int))) + (def-var! "clojure.core" "rand-int" (letrec ((rand-int (lambda (n) (let fnrec3629 ((n n)) (jolt-invoke (var-deref "clojure.core" "int") (jolt-invoke (var-deref "clojure.core" "rand") n)))))) rand-int))) (guard (e (#t #f)) - (def-var! "clojure.core" "shuffle" (letrec ((shuffle (lambda (coll) (let fnrec4320 ((coll coll)) (begin (if (jolt-truthy? (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.core" "coll?") coll)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") coll)))) (jolt-throw (let* ((_a$4321 (jolt-invoke (var-deref "clojure.core" "str") "shuffle requires a collection, got: " coll)) (_a$4322 (jolt-hash-map))) (jolt-ex-info _a$4321 _a$4322))) jolt-nil) (let* ((v (jolt-invoke (var-deref "clojure.core" "vec") coll)) (i (jolt-dec (jolt-count v)))) (let loop4323 ((v v) (i i)) (if (jolt-pos? i) (let* ((j (jolt-invoke (var-deref "clojure.core" "rand-int") (jolt-inc i))) (t (jolt-nth v i))) (let* ((_a$4324 (jolt-assoc (jolt-assoc v i (jolt-nth v j)) j t)) (_a$4325 (jolt-dec i))) (loop4323 _a$4324 _a$4325))) v)))))))) shuffle))) + (def-var! "clojure.core" "shuffle" (letrec ((shuffle (lambda (coll) (let fnrec3630 ((coll coll)) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "coll?") coll)) (jolt-throw (let* ((_a$3631 (jolt-invoke (var-deref "clojure.core" "str") "shuffle requires a collection, got: " coll)) (_a$3632 (jolt-hash-map))) (jolt-ex-info _a$3631 _a$3632))) jolt-nil) (let* ((v (jolt-invoke (var-deref "clojure.core" "vec") coll)) (i (jolt-dec (jolt-count v)))) (let loop3633 ((v v) (i i)) (if (jolt-pos? i) (let* ((j (jolt-invoke (var-deref "clojure.core" "rand-int") (jolt-inc i))) (t (jolt-nth v i))) (let* ((_a$3634 (jolt-assoc (jolt-assoc v i (jolt-nth v j)) j t)) (_a$3635 (jolt-dec i))) (loop3633 _a$3634 _a$3635))) v)))))))) shuffle))) (guard (e (#t #f)) - (def-var! "clojure.core" "sort-by" (letrec ((sort-by (case-lambda ((keyfn coll) (let fnrec4326 ((keyfn keyfn) (coll coll)) (sort-by keyfn (var-deref "clojure.core" "compare") coll))) ((keyfn comp coll) (let fnrec4327 ((keyfn keyfn) (comp comp) (coll coll)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "coll?") comp)) (jolt-throw (host-new "ClassCastException" (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "class") comp) " cannot be cast to java.util.Comparator"))) jolt-nil) (jolt-invoke (var-deref "clojure.core" "sort") (lambda (x y) (let fnrec4328 ((x x) (y y)) (let* ((_a$4329 comp) (_a$4330 (jolt-invoke keyfn x)) (_a$4331 (jolt-invoke keyfn y))) (jolt-invoke _a$4329 _a$4330 _a$4331)))) coll))))))) sort-by))) + (def-var! "clojure.core" "sort-by" (letrec ((sort-by (case-lambda ((keyfn coll) (let fnrec3636 ((keyfn keyfn) (coll coll)) (jolt-invoke sort-by keyfn (var-deref "clojure.core" "compare") coll))) ((keyfn comp coll) (let fnrec3637 ((keyfn keyfn) (comp comp) (coll coll)) (jolt-invoke (var-deref "clojure.core" "sort") (lambda (x y) (let fnrec3638 ((x x) (y y)) (let* ((_a$3639 comp) (_a$3640 (jolt-invoke keyfn x)) (_a$3641 (jolt-invoke keyfn y))) (jolt-invoke _a$3639 _a$3640 _a$3641)))) coll)))))) sort-by))) (guard (e (#t #f)) - (def-var! "clojure.core" "parse-uuid" (letrec ((parse-uuid (lambda (s) (let fnrec4332 ((s s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "re-matches") (jolt-regex "[0-9a-fA-F]{8}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{12}") s)) (jolt-invoke (var-deref "clojure.core" "__make-uuid") s) jolt-nil) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "parse-uuid requires a string, got: " s))))))) parse-uuid))) + (def-var! "clojure.core" "parse-uuid" (letrec ((parse-uuid (lambda (s) (let fnrec3642 ((s s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "re-matches") (jolt-regex "[0-9a-fA-F]{8}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{12}") s)) (jolt-invoke (var-deref "clojure.core" "__make-uuid") s) jolt-nil) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "parse-uuid requires a string, got: " s))))))) parse-uuid))) (guard (e (#t #f)) - (def-var! "clojure.core" "random-uuid" (letrec ((random-uuid (lambda () (let fnrec4333 () (let* ((hx4 (lambda () (let fnrec4334 () (jolt-invoke (var-deref "clojure.core" "format") "%04x" (jolt-invoke (var-deref "clojure.core" "rand-int") 65536))))) (hx3 (lambda () (let fnrec4335 () (jolt-invoke (var-deref "clojure.core" "format") "%03x" (jolt-invoke (var-deref "clojure.core" "rand-int") 4096)))))) (jolt-invoke (var-deref "clojure.core" "parse-uuid") (let* ((_a$4336 (var-deref "clojure.core" "str")) (_a$4337 (jolt-invoke hx4)) (_a$4338 (jolt-invoke hx4)) (_a$4339 "-") (_a$4340 (jolt-invoke hx4)) (_a$4341 "-4") (_a$4342 (jolt-invoke hx3)) (_a$4343 "-") (_a$4344 (jolt-invoke (var-deref "clojure.core" "format") "%x" (jolt-n+ 8 (jolt-invoke (var-deref "clojure.core" "rand-int") 4)))) (_a$4345 (jolt-invoke hx3)) (_a$4346 "-") (_a$4347 (jolt-invoke hx4)) (_a$4348 (jolt-invoke hx4)) (_a$4349 (jolt-invoke hx4))) (jolt-invoke _a$4336 _a$4337 _a$4338 _a$4339 _a$4340 _a$4341 _a$4342 _a$4343 _a$4344 _a$4345 _a$4346 _a$4347 _a$4348 _a$4349)))))))) random-uuid))) + (def-var! "clojure.core" "random-uuid" (letrec ((random-uuid (lambda () (let fnrec3643 () (let* ((hx4 (lambda () (let fnrec3644 () (jolt-invoke (var-deref "clojure.core" "format") "%04x" (jolt-invoke (var-deref "clojure.core" "rand-int") 65536))))) (hx3 (lambda () (let fnrec3645 () (jolt-invoke (var-deref "clojure.core" "format") "%03x" (jolt-invoke (var-deref "clojure.core" "rand-int") 4096)))))) (jolt-invoke (var-deref "clojure.core" "parse-uuid") (let* ((_a$3646 (var-deref "clojure.core" "str")) (_a$3647 (jolt-invoke hx4)) (_a$3648 (jolt-invoke hx4)) (_a$3649 "-") (_a$3650 (jolt-invoke hx4)) (_a$3651 "-4") (_a$3652 (jolt-invoke hx3)) (_a$3653 "-") (_a$3654 (jolt-invoke (var-deref "clojure.core" "format") "%x" (+ 8 (jolt-invoke (var-deref "clojure.core" "rand-int") 4)))) (_a$3655 (jolt-invoke hx3)) (_a$3656 "-") (_a$3657 (jolt-invoke hx4)) (_a$3658 (jolt-invoke hx4)) (_a$3659 (jolt-invoke hx4))) (jolt-invoke _a$3646 _a$3647 _a$3648 _a$3649 _a$3650 _a$3651 _a$3652 _a$3653 _a$3654 _a$3655 _a$3656 _a$3657 _a$3658 _a$3659)))))))) random-uuid))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "char-escape-strings" (let* ((_o$4350 (integer->char 10)) (_o$4351 "\\n") (_o$4352 (integer->char 9)) (_o$4353 "\\t") (_o$4354 (integer->char 13)) (_o$4355 "\\r") (_o$4356 (integer->char 12)) (_o$4357 "\\f") (_o$4358 (integer->char 8)) (_o$4359 "\\b") (_o$4360 (integer->char 34)) (_o$4361 "\\\"") (_o$4362 (integer->char 92)) (_o$4363 "\\\\")) (jolt-hash-map _o$4350 _o$4351 _o$4352 _o$4353 _o$4354 _o$4355 _o$4356 _o$4357 _o$4358 _o$4359 _o$4360 _o$4361 _o$4362 _o$4363)) (let* ((_o$4364 (keyword #f "private")) (_o$4365 #t)) (jolt-hash-map _o$4364 _o$4365)))) + (def-var-with-meta! "clojure.core" "char-escape-strings" (let* ((_o$3660 (integer->char 10)) (_o$3661 "\\n") (_o$3662 (integer->char 9)) (_o$3663 "\\t") (_o$3664 (integer->char 13)) (_o$3665 "\\r") (_o$3666 (integer->char 12)) (_o$3667 "\\f") (_o$3668 (integer->char 8)) (_o$3669 "\\b") (_o$3670 (integer->char 34)) (_o$3671 "\\\"") (_o$3672 (integer->char 92)) (_o$3673 "\\\\")) (jolt-hash-map _o$3660 _o$3661 _o$3662 _o$3663 _o$3664 _o$3665 _o$3666 _o$3667 _o$3668 _o$3669 _o$3670 _o$3671 _o$3672 _o$3673)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var! "clojure.core" "char-escape-string" (letrec ((char-escape-string (lambda (c) (let fnrec4366 ((c c)) (jolt-get (var-deref "clojure.core" "char-escape-strings") c))))) char-escape-string))) + (def-var! "clojure.core" "char-escape-string" (letrec ((char-escape-string (lambda (c) (let fnrec3674 ((c c)) (jolt-get (var-deref "clojure.core" "char-escape-strings") c))))) char-escape-string))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "char-name-strings" (let* ((_o$4367 (integer->char 10)) (_o$4368 "newline") (_o$4369 (integer->char 9)) (_o$4370 "tab") (_o$4371 (integer->char 13)) (_o$4372 "return") (_o$4373 (integer->char 12)) (_o$4374 "formfeed") (_o$4375 (integer->char 8)) (_o$4376 "backspace") (_o$4377 (integer->char 32)) (_o$4378 "space")) (jolt-hash-map _o$4367 _o$4368 _o$4369 _o$4370 _o$4371 _o$4372 _o$4373 _o$4374 _o$4375 _o$4376 _o$4377 _o$4378)) (let* ((_o$4379 (keyword #f "private")) (_o$4380 #t)) (jolt-hash-map _o$4379 _o$4380)))) + (def-var-with-meta! "clojure.core" "char-name-strings" (let* ((_o$3675 (integer->char 10)) (_o$3676 "newline") (_o$3677 (integer->char 9)) (_o$3678 "tab") (_o$3679 (integer->char 13)) (_o$3680 "return") (_o$3681 (integer->char 12)) (_o$3682 "formfeed") (_o$3683 (integer->char 8)) (_o$3684 "backspace") (_o$3685 (integer->char 32)) (_o$3686 "space")) (jolt-hash-map _o$3675 _o$3676 _o$3677 _o$3678 _o$3679 _o$3680 _o$3681 _o$3682 _o$3683 _o$3684 _o$3685 _o$3686)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var! "clojure.core" "char-name-string" (letrec ((char-name-string (lambda (c) (let fnrec4381 ((c c)) (jolt-get (var-deref "clojure.core" "char-name-strings") c))))) char-name-string))) + (def-var! "clojure.core" "char-name-string" (letrec ((char-name-string (lambda (c) (let fnrec3687 ((c c)) (jolt-get (var-deref "clojure.core" "char-name-strings") c))))) char-name-string))) (guard (e (#t #f)) - (def-var! "clojure.core" "rand-nth" (letrec ((rand-nth (lambda (coll) (let fnrec4382 ((coll coll)) (jolt-nth coll (jolt-invoke (var-deref "clojure.core" "rand-int") (jolt-count coll))))))) rand-nth))) + (def-var! "clojure.core" "rand-nth" (letrec ((rand-nth (lambda (coll) (let fnrec3688 ((coll coll)) (let* ((v (jolt-invoke (var-deref "clojure.core" "vec") coll))) (jolt-nth v (jolt-invoke (var-deref "clojure.core" "rand-int") (jolt-count v)))))))) rand-nth))) (guard (e (#t #f)) - (def-var! "clojure.core" "random-sample" (letrec ((random-sample (case-lambda ((prob) (let fnrec4383 ((prob prob)) (jolt-invoke jolt-filter (lambda (_) (let fnrec4384 ((_ _)) (jolt-n< (jolt-invoke (var-deref "clojure.core" "rand")) prob)))))) ((prob coll) (let fnrec4385 ((prob prob) (coll coll)) (jolt-filter (lambda (_) (let fnrec4386 ((_ _)) (jolt-n< (jolt-invoke (var-deref "clojure.core" "rand")) prob))) coll)))))) random-sample))) + (def-var! "clojure.core" "random-sample" (letrec ((random-sample (case-lambda ((prob) (let fnrec3689 ((prob prob)) (jolt-invoke jolt-filter (lambda (_) (let fnrec3690 ((_ _)) (< (jolt-invoke (var-deref "clojure.core" "rand")) prob)))))) ((prob coll) (let fnrec3691 ((prob prob) (coll coll)) (jolt-filter (lambda (_) (let fnrec3692 ((_ _)) (< (jolt-invoke (var-deref "clojure.core" "rand")) prob))) coll)))))) random-sample))) (guard (e (#t #f)) - (def-var! "clojure.core" "comparator" (letrec ((comparator (lambda (pred) (let fnrec4387 ((pred pred)) (lambda (a b) (let fnrec4388 ((a a) (b b)) (if (jolt-truthy? (jolt-invoke pred a b)) -1 (if (jolt-truthy? (jolt-invoke pred b a)) 1 (if (jolt-truthy? (keyword #f "else")) 0 jolt-nil))))))))) comparator))) + (def-var! "clojure.core" "comparator" (letrec ((comparator (lambda (pred) (let fnrec3693 ((pred pred)) (lambda (a b) (let fnrec3694 ((a a) (b b)) (if (jolt-truthy? (jolt-invoke pred a b)) -1 (if (jolt-truthy? (jolt-invoke pred b a)) 1 (if (jolt-truthy? (keyword #f "else")) 0 jolt-nil))))))))) comparator))) (guard (e (#t #f)) - (def-var! "clojure.core" "reductions" (letrec ((reductions (case-lambda ((f coll) (let fnrec4389 ((f f) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4390 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s (jolt-seq coll))) (if (jolt-truthy? s) (let* ((_a$4391 f) (_a$4392 (jolt-first s)) (_a$4393 (jolt-rest s))) (reductions _a$4391 _a$4392 _a$4393)) (jolt-list (jolt-invoke f)))))))))) ((f init coll) (let fnrec4394 ((f f) (init init) (coll coll)) (jolt-cons init (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4395 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$4396 f) (_a$4397 (jolt-invoke f init (jolt-first s))) (_a$4398 (jolt-rest s))) (reductions _a$4396 _a$4397 _a$4398))) jolt-nil)))))))))))) reductions))) + (def-var! "clojure.core" "reductions" (letrec ((reductions (case-lambda ((f coll) (let fnrec3695 ((f f) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3696 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s (jolt-seq coll))) (if (jolt-truthy? s) (let* ((_a$3697 reductions) (_a$3698 f) (_a$3699 (jolt-first s)) (_a$3700 (jolt-rest s))) (jolt-invoke _a$3697 _a$3698 _a$3699 _a$3700)) (jolt-list (jolt-invoke f)))))))))) ((f init coll) (let fnrec3701 ((f f) (init init) (coll coll)) (jolt-cons init (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3702 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$3703 reductions) (_a$3704 f) (_a$3705 (jolt-invoke f init (jolt-first s))) (_a$3706 (jolt-rest s))) (jolt-invoke _a$3703 _a$3704 _a$3705 _a$3706))) jolt-nil)))))))))))) reductions))) (guard (e (#t #f)) - (def-var! "clojure.core" "tree-seq" (letrec ((tree-seq (lambda (branch? children root) (let fnrec4399 ((branch? branch?) (children children) (root root)) (let* ((walk (letrec ((walk (lambda (node) (let fnrec4400 ((node node)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4401 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons node (if (jolt-truthy? (jolt-invoke branch? node)) (jolt-invoke (var-deref "clojure.core" "mapcat") walk (jolt-invoke children node)) jolt-nil)))))))))) walk))) (jolt-invoke walk root)))))) tree-seq))) + (def-var! "clojure.core" "tree-seq" (letrec ((tree-seq (lambda (branch? children root) (let fnrec3707 ((branch? branch?) (children children) (root root)) (let* ((walk (letrec ((walk (lambda (node) (let fnrec3708 ((node node)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3709 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons node (if (jolt-truthy? (jolt-invoke branch? node)) (jolt-invoke (var-deref "clojure.core" "mapcat") walk (jolt-invoke children node)) jolt-nil)))))))))) walk))) (jolt-invoke walk root)))))) tree-seq))) (guard (e (#t #f)) - (def-var! "clojure.core" "file-seq" (letrec ((file-seq (lambda (root) (let fnrec4402 ((root root)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "__file?") root)) (let* ((_a$4405 (var-deref "clojure.core" "tree-seq")) (_a$4406 (lambda (f) (let fnrec4403 ((f f)) (jolt-host-call "isDirectory" f)))) (_a$4407 (lambda (f) (let fnrec4404 ((f f)) (jolt-seq (jolt-host-call "listFiles" f))))) (_a$4408 root)) (jolt-invoke _a$4405 _a$4406 _a$4407 _a$4408)) (jolt-invoke (var-deref "clojure.core" "tree-seq") (var-deref "clojure.core" "__dir?") (var-deref "clojure.core" "__list-dir") root)))))) file-seq))) + (def-var! "clojure.core" "file-seq" (letrec ((file-seq (lambda (root) (let fnrec3710 ((root root)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "__file?") root)) (let* ((_a$3713 (var-deref "clojure.core" "tree-seq")) (_a$3714 (lambda (f) (let fnrec3711 ((f f)) (jolt-host-call "isDirectory" f)))) (_a$3715 (lambda (f) (let fnrec3712 ((f f)) (jolt-seq (jolt-host-call "listFiles" f))))) (_a$3716 root)) (jolt-invoke _a$3713 _a$3714 _a$3715 _a$3716)) (jolt-invoke (var-deref "clojure.core" "tree-seq") (var-deref "clojure.core" "__dir?") (var-deref "clojure.core" "__list-dir") root)))))) file-seq))) (guard (e (#t #f)) - (def-var! "clojure.core" "flatten" (letrec ((flatten (lambda (coll) (let fnrec4409 ((coll coll)) (let* ((_a$4410 (jolt-invoke (var-deref "clojure.core" "complement") (var-deref "clojure.core" "sequential?"))) (_a$4411 (jolt-rest (jolt-invoke (var-deref "clojure.core" "tree-seq") (var-deref "clojure.core" "sequential?") jolt-seq coll)))) (jolt-filter _a$4410 _a$4411)))))) flatten))) + (def-var! "clojure.core" "flatten" (letrec ((flatten (lambda (coll) (let fnrec3717 ((coll coll)) (let* ((_a$3718 (jolt-invoke (var-deref "clojure.core" "complement") (var-deref "clojure.core" "sequential?"))) (_a$3719 (jolt-rest (jolt-invoke (var-deref "clojure.core" "tree-seq") (var-deref "clojure.core" "sequential?") jolt-seq coll)))) (jolt-filter _a$3718 _a$3719)))))) flatten))) (guard (e (#t #f)) - (def-var! "clojure.core" "xml-seq" (letrec ((xml-seq (lambda (root) (let fnrec4412 ((root root)) (let* ((_a$4413 (var-deref "clojure.core" "tree-seq")) (_a$4414 (jolt-invoke (var-deref "clojure.core" "complement") (var-deref "clojure.core" "string?"))) (_a$4415 (jolt-invoke (var-deref "clojure.core" "comp") jolt-seq (keyword #f "content"))) (_a$4416 root)) (jolt-invoke _a$4413 _a$4414 _a$4415 _a$4416)))))) xml-seq))) + (def-var! "clojure.core" "xml-seq" (letrec ((xml-seq (lambda (root) (let fnrec3720 ((root root)) (let* ((_a$3721 (var-deref "clojure.core" "tree-seq")) (_a$3722 (jolt-invoke (var-deref "clojure.core" "complement") (var-deref "clojure.core" "string?"))) (_a$3723 (jolt-invoke (var-deref "clojure.core" "comp") jolt-seq (keyword #f "content"))) (_a$3724 root)) (jolt-invoke _a$3721 _a$3722 _a$3723 _a$3724)))))) xml-seq))) (guard (e (#t #f)) - (def-var! "clojure.core" "interleave" (letrec ((interleave (case-lambda (() (let fnrec4417 () (jolt-list ))) ((c1) (let fnrec4418 ((c1 c1)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4419 () (jolt-invoke (var-deref "clojure.core" "coll->cells") c1)))))) ((c1 c2) (let fnrec4420 ((c1 c1) (c2 c2)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4421 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s1 (jolt-seq c1)) (s2 (jolt-seq c2))) (if (jolt-truthy? (let* ((and__25__auto s1)) (if (jolt-truthy? and__25__auto) s2 and__25__auto))) (let* ((_a$4426 (jolt-first s1)) (_a$4427 (let* ((_a$4424 (jolt-first s2)) (_a$4425 (let* ((_a$4422 (jolt-rest s1)) (_a$4423 (jolt-rest s2))) (interleave _a$4422 _a$4423)))) (jolt-cons _a$4424 _a$4425)))) (jolt-cons _a$4426 _a$4427)) jolt-nil)))))))) ((c1 c2 . cs) (let fnrec4428 ((c1 c1) (c2 c2) (cs (list->cseq cs))) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4429 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((ss (jolt-map jolt-seq (jolt-invoke (var-deref "clojure.core" "list*") c1 c2 cs)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "every?") jolt-identity ss)) (let* ((_a$4430 (jolt-map jolt-first ss)) (_a$4431 (jolt-apply interleave (jolt-map jolt-rest ss)))) (jolt-concat _a$4430 _a$4431)) jolt-nil))))))))))) interleave))) + (def-var! "clojure.core" "interleave" (letrec ((interleave (case-lambda (() (let fnrec3725 () (jolt-list ))) ((c1) (let fnrec3726 ((c1 c1)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3727 () (jolt-invoke (var-deref "clojure.core" "coll->cells") c1)))))) ((c1 c2) (let fnrec3728 ((c1 c1) (c2 c2)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3729 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((s1 (jolt-seq c1)) (s2 (jolt-seq c2))) (if (jolt-truthy? (let* ((and__25__auto s1)) (if (jolt-truthy? and__25__auto) s2 and__25__auto))) (let* ((_a$3735 (jolt-first s1)) (_a$3736 (let* ((_a$3733 (jolt-first s2)) (_a$3734 (let* ((_a$3730 interleave) (_a$3731 (jolt-rest s1)) (_a$3732 (jolt-rest s2))) (jolt-invoke _a$3730 _a$3731 _a$3732)))) (jolt-cons _a$3733 _a$3734)))) (jolt-cons _a$3735 _a$3736)) jolt-nil)))))))) ((c1 c2 . cs) (let fnrec3737 ((c1 c1) (c2 c2) (cs (list->cseq cs))) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3738 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((ss (jolt-map jolt-seq (jolt-invoke (var-deref "clojure.core" "list*") c1 c2 cs)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "every?") jolt-identity ss)) (let* ((_a$3739 (jolt-map jolt-first ss)) (_a$3740 (jolt-apply interleave (jolt-map jolt-rest ss)))) (jolt-concat _a$3739 _a$3740)) jolt-nil))))))))))) interleave))) (guard (e (#t #f)) - (def-var! "clojure.core" "dedupe" (letrec ((dedupe (case-lambda (() (let fnrec4432 () (lambda (rf) (let fnrec4433 ((rf rf)) (let* ((pv (jolt-invoke (var-deref "clojure.core" "volatile!") (let* ((_o$4434 #f) (_o$4435 jolt-nil)) (jolt-vector _o$4434 _o$4435))))) (case-lambda (() (let fnrec4436 () (jolt-invoke rf))) ((result) (let fnrec4437 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec4438 ((result result) (input input)) (let* ((G__132 (jolt-invoke (var-deref "clojure.core" "deref") pv)) (seen (jolt-nth G__132 0 jolt-nil)) (prior (jolt-nth G__132 1 jolt-nil))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") pv (let* ((_o$4439 #t) (_o$4440 input)) (jolt-vector _o$4439 _o$4440))) (if (jolt-truthy? (let* ((and__25__auto seen)) (if (jolt-truthy? and__25__auto) (jolt= prior input) and__25__auto))) result (jolt-invoke rf result input)))))))))))) ((coll) (let fnrec4441 ((coll coll)) (let* ((step (letrec ((step (lambda (s prev) (let fnrec4442 ((s s) (prev prev)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4443 () (let* ((s (jolt-seq s))) (if (jolt-truthy? s) (let* ((x (jolt-first s))) (if (jolt= x prev) (jolt-invoke (var-deref "clojure.core" "coll->cells") (step (jolt-rest s) prev)) (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons x (step (jolt-rest s) x))))) jolt-nil))))))))) step))) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4444 () (let* ((s (jolt-seq coll))) (if (jolt-truthy? s) (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((_a$4448 (jolt-first s)) (_a$4449 (let* ((_a$4445 step) (_a$4446 (jolt-rest s)) (_a$4447 (jolt-first s))) (jolt-invoke _a$4445 _a$4446 _a$4447)))) (jolt-cons _a$4448 _a$4449))) jolt-nil))))))))))) dedupe))) + (def-var! "clojure.core" "rationalize" (letrec ((rationalize (lambda (x) (let fnrec3741 ((x x)) x)))) rationalize))) (guard (e (#t #f)) - (def-var! "clojure.core" "seq-to-map-for-destructuring" (letrec ((seq-to-map-for-destructuring (lambda (s) (let fnrec4450 ((s s)) (if (jolt-truthy? (jolt-next s)) (let* ((m (jolt-hash-map)) (xs (jolt-seq s))) (let loop4451 ((m m) (xs xs)) (if (jolt-truthy? xs) (if (jolt-truthy? (jolt-next xs)) (let* ((_a$4455 (let* ((_a$4452 m) (_a$4453 (jolt-first xs)) (_a$4454 (jolt-invoke (var-deref "clojure.core" "second") xs))) (jolt-assoc _a$4452 _a$4453 _a$4454))) (_a$4456 (jolt-invoke (var-deref "clojure.core" "nnext") xs))) (loop4451 _a$4455 _a$4456)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "No value supplied for key: " (jolt-first xs)))) m))) (if (jolt-truthy? (jolt-seq s)) (jolt-first s) (jolt-hash-map))))))) seq-to-map-for-destructuring))) + (def-var! "clojure.core" "dedupe" (letrec ((dedupe (case-lambda (() (let fnrec3742 () (lambda (rf) (let fnrec3743 ((rf rf)) (let* ((pv (jolt-invoke (var-deref "clojure.core" "volatile!") (let* ((_o$3744 #f) (_o$3745 jolt-nil)) (jolt-vector _o$3744 _o$3745))))) (case-lambda (() (let fnrec3746 () (jolt-invoke rf))) ((result) (let fnrec3747 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec3748 ((result result) (input input)) (let* ((G__116 (jolt-invoke (var-deref "clojure.core" "deref") pv)) (seen (jolt-nth G__116 0 jolt-nil)) (prior (jolt-nth G__116 1 jolt-nil))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") pv (let* ((_o$3749 #t) (_o$3750 input)) (jolt-vector _o$3749 _o$3750))) (if (jolt-truthy? (let* ((and__25__auto seen)) (if (jolt-truthy? and__25__auto) (jolt= prior input) and__25__auto))) result (jolt-invoke rf result input)))))))))))) ((coll) (let fnrec3751 ((coll coll)) (let* ((step (letrec ((step (lambda (s prev) (let fnrec3752 ((s s) (prev prev)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3753 () (let* ((s (jolt-seq s))) (if (jolt-truthy? s) (let* ((x (jolt-first s))) (if (jolt= x prev) (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-invoke step (jolt-rest s) prev)) (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons x (jolt-invoke step (jolt-rest s) x))))) jolt-nil))))))))) step))) (let* ((s (jolt-seq coll))) (if (jolt-truthy? s) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec3754 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((_a$3758 (jolt-first s)) (_a$3759 (let* ((_a$3755 step) (_a$3756 (jolt-rest s)) (_a$3757 (jolt-first s))) (jolt-invoke _a$3755 _a$3756 _a$3757)))) (jolt-cons _a$3758 _a$3759)))))) (jolt-list ))))))))) dedupe))) (guard (e (#t #f)) - (def-var! "clojure.core" "vary-meta" (letrec ((vary-meta (lambda (obj f . args) (let fnrec4457 ((obj obj) (f f) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "with-meta") obj (jolt-apply f (jolt-invoke (var-deref "clojure.core" "meta") obj) args)))))) vary-meta))) + (def-var! "clojure.core" "seq-to-map-for-destructuring" (letrec ((seq-to-map-for-destructuring (lambda (s) (let fnrec3760 ((s s)) (if (jolt-truthy? (jolt-next s)) (let* ((m (jolt-hash-map)) (xs (jolt-seq s))) (let loop3761 ((m m) (xs xs)) (if (jolt-truthy? xs) (if (jolt-truthy? (jolt-next xs)) (let* ((_a$3765 (let* ((_a$3762 m) (_a$3763 (jolt-first xs)) (_a$3764 (jolt-invoke (var-deref "clojure.core" "second") xs))) (jolt-assoc _a$3762 _a$3763 _a$3764))) (_a$3766 (jolt-invoke (var-deref "clojure.core" "nnext") xs))) (loop3761 _a$3765 _a$3766)) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "No value supplied for key: " (jolt-first xs)))) m))) (if (jolt-truthy? (jolt-seq s)) (jolt-first s) (jolt-hash-map))))))) seq-to-map-for-destructuring))) (guard (e (#t #f)) - (def-var! "clojure.core" "namespace-munge" (letrec ((namespace-munge (lambda (s) (let fnrec4458 ((s s)) (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$4460 (lambda (c) (let fnrec4459 ((c c)) (if (jolt= c (integer->char 45)) (integer->char 95) c)))) (_a$4461 (jolt-seq (jolt-invoke (var-deref "clojure.core" "str") s)))) (jolt-map _a$4460 _a$4461))))))) namespace-munge))) + (def-var! "clojure.core" "vary-meta" (letrec ((vary-meta (lambda (obj f . args) (let fnrec3767 ((obj obj) (f f) (args (list->cseq args))) (jolt-invoke (var-deref "clojure.core" "with-meta") obj (jolt-apply f (jolt-invoke (var-deref "clojure.core" "meta") obj) args)))))) vary-meta))) (guard (e (#t #f)) - (def-var! "clojure.core" "reduce-kv" (letrec ((reduce-kv (lambda (f init coll) (let fnrec4462 ((f f) (init init) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (let* ((_a$4464 (lambda (acc i) (let fnrec4463 ((acc acc) (i i)) (jolt-invoke f acc i (jolt-nth coll i))))) (_a$4465 init) (_a$4466 (jolt-range (jolt-count coll)))) (jolt-reduce _a$4464 _a$4465 _a$4466)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (let* ((_a$4468 (lambda (acc k) (let fnrec4467 ((acc acc) (k k)) (jolt-invoke f acc k (jolt-get coll k))))) (_a$4469 init) (_a$4470 (jolt-keys coll))) (jolt-reduce _a$4468 _a$4469 _a$4470)) (if (jolt-nil? coll) init (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "reduce-kv not supported on: " coll)) jolt-nil)))))))) reduce-kv))) + (def-var! "clojure.core" "namespace-munge" (letrec ((namespace-munge (lambda (s) (let fnrec3768 ((s s)) (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$3770 (lambda (c) (let fnrec3769 ((c c)) (if (jolt= c (integer->char 45)) (integer->char 95) c)))) (_a$3771 (jolt-seq (jolt-invoke (var-deref "clojure.core" "str") s)))) (jolt-map _a$3770 _a$3771))))))) namespace-munge))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ex-info-val?" (letrec ((ex-info-val? (lambda (x) (let fnrec4471 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "ex-info")))))) ex-info-val?) (let* ((_o$4472 (keyword #f "private")) (_o$4473 #t)) (jolt-hash-map _o$4472 _o$4473)))) + (def-var! "clojure.core" "reduce-kv" (letrec ((reduce-kv (lambda (f init coll) (let fnrec3772 ((f f) (init init) (coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (let* ((_a$3774 (lambda (acc i) (let fnrec3773 ((acc acc) (i i)) (jolt-invoke f acc i (jolt-nth coll i))))) (_a$3775 init) (_a$3776 (jolt-range (jolt-count coll)))) (jolt-reduce _a$3774 _a$3775 _a$3776)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (let* ((_a$3778 (lambda (acc k) (let fnrec3777 ((acc acc) (k k)) (jolt-invoke f acc k (jolt-get coll k))))) (_a$3779 init) (_a$3780 (jolt-keys coll))) (jolt-reduce _a$3778 _a$3779 _a$3780)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") coll)) init (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "reduce-kv not supported on: " coll)) jolt-nil)))))))) reduce-kv))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ex-unwrap" (letrec ((ex-unwrap (lambda (e) (let fnrec4474 ((e e)) (if (jolt= (jolt-get e (keyword "jolt" "type")) (keyword "jolt" "exception")) (jolt-get e (keyword #f "value")) e))))) ex-unwrap) (let* ((_o$4475 (keyword #f "private")) (_o$4476 #t)) (jolt-hash-map _o$4475 _o$4476)))) + (def-var! "clojure.core" "ex-info-val?" (letrec ((ex-info-val? (lambda (x) (let fnrec3781 ((x x)) (jolt= (jolt-get x (keyword "jolt" "type")) (keyword "jolt" "ex-info")))))) ex-info-val?))) (guard (e (#t #f)) - (def-var! "clojure.core" "ex-data" (letrec ((ex-data (lambda (e) (let fnrec4477 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "data")) jolt-nil)))))) ex-data))) + (def-var! "clojure.core" "ex-unwrap" (letrec ((ex-unwrap (lambda (e) (let fnrec3782 ((e e)) (if (jolt= (jolt-get e (keyword "jolt" "type")) (keyword "jolt" "exception")) (jolt-get e (keyword #f "value")) e))))) ex-unwrap))) (guard (e (#t #f)) - (def-var! "clojure.core" "ex-message" (letrec ((ex-message (lambda (e) (let fnrec4478 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "message")) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) ex-message))) + (def-var! "clojure.core" "ex-data" (letrec ((ex-data (lambda (e) (let fnrec3783 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "data")) jolt-nil)))))) ex-data))) (guard (e (#t #f)) - (def-var! "clojure.core" "ex-cause" (letrec ((ex-cause (lambda (e) (let fnrec4479 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "cause")) jolt-nil)))))) ex-cause))) + (def-var! "clojure.core" "ex-message" (letrec ((ex-message (lambda (e) (let fnrec3784 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "message")) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))) ex-message))) (guard (e (#t #f)) - (def-var! "clojure.core" "inst-ms" (letrec ((inst-ms (lambda (x) (let fnrec4480 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "inst?") x)) (jolt-get x (keyword #f "ms")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "inst-ms requires an inst, got: " x))))))) inst-ms))) + (def-var! "clojure.core" "ex-cause" (letrec ((ex-cause (lambda (e) (let fnrec3785 ((e e)) (let* ((e (jolt-invoke (var-deref "clojure.core" "ex-unwrap") e))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "ex-info-val?") e)) (jolt-get e (keyword #f "cause")) jolt-nil)))))) ex-cause))) (guard (e (#t #f)) - (def-var! "clojure.core" "update-keys" (letrec ((update-keys (lambda (m f) (let fnrec4481 ((m m) (f f)) (let* ((_a$4483 (var-deref "clojure.core" "reduce-kv")) (_a$4484 (lambda (acc k v) (let fnrec4482 ((acc acc) (k k) (v v)) (jolt-assoc acc (jolt-invoke f k) v)))) (_a$4485 (jolt-hash-map)) (_a$4486 m)) (jolt-invoke _a$4483 _a$4484 _a$4485 _a$4486)))))) update-keys))) + (def-var! "clojure.core" "inst-ms" (letrec ((inst-ms (lambda (x) (let fnrec3786 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "inst?") x)) (jolt-get x (keyword #f "ms")) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "inst-ms requires an inst, got: " x))))))) inst-ms))) (guard (e (#t #f)) - (def-var! "clojure.core" "update-vals" (letrec ((update-vals (lambda (m f) (let fnrec4487 ((m m) (f f)) (let* ((_a$4489 (var-deref "clojure.core" "reduce-kv")) (_a$4490 (lambda (acc k v) (let fnrec4488 ((acc acc) (k k) (v v)) (jolt-assoc acc k (jolt-invoke f v))))) (_a$4491 (jolt-hash-map)) (_a$4492 m)) (jolt-invoke _a$4489 _a$4490 _a$4491 _a$4492)))))) update-vals))) + (def-var! "clojure.core" "update-keys" (letrec ((update-keys (lambda (m f) (let fnrec3787 ((m m) (f f)) (let* ((_a$3789 (var-deref "clojure.core" "reduce-kv")) (_a$3790 (lambda (acc k v) (let fnrec3788 ((acc acc) (k k) (v v)) (jolt-assoc acc (jolt-invoke f k) v)))) (_a$3791 (jolt-hash-map )) (_a$3792 m)) (jolt-invoke _a$3789 _a$3790 _a$3791 _a$3792)))))) update-keys))) (guard (e (#t #f)) - (def-var! "clojure.core" "partitionv" (letrec ((partitionv (case-lambda ((n coll) (let fnrec4493 ((n n) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n coll)))) ((n step coll) (let fnrec4494 ((n n) (step step) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n step coll)))) ((n step pad coll) (let fnrec4495 ((n n) (step step) (pad pad) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n step pad coll))))))) partitionv))) + (def-var! "clojure.core" "update-vals" (letrec ((update-vals (lambda (m f) (let fnrec3793 ((m m) (f f)) (let* ((_a$3795 (var-deref "clojure.core" "reduce-kv")) (_a$3796 (lambda (acc k v) (let fnrec3794 ((acc acc) (k k) (v v)) (jolt-assoc acc k (jolt-invoke f v))))) (_a$3797 (jolt-hash-map )) (_a$3798 m)) (jolt-invoke _a$3795 _a$3796 _a$3797 _a$3798)))))) update-vals))) +(guard (e (#t #f)) + (def-var! "clojure.core" "partitionv" (letrec ((partitionv (case-lambda ((n coll) (let fnrec3799 ((n n) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n coll)))) ((n step coll) (let fnrec3800 ((n n) (step step) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n step coll)))) ((n step pad coll) (let fnrec3801 ((n n) (step step) (pad pad) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition") n step pad coll))))))) partitionv))) (guard (e (#t #f)) (declare-var! "clojure.core" "partition-all")) (guard (e (#t #f)) - (def-var! "clojure.core" "partitionv-all" (letrec ((partitionv-all (case-lambda ((n coll) (let fnrec4496 ((n n) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition-all") n coll)))) ((n step coll) (let fnrec4497 ((n n) (step step) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition-all") n step coll))))))) partitionv-all))) + (def-var! "clojure.core" "partitionv-all" (letrec ((partitionv-all (case-lambda ((n coll) (let fnrec3802 ((n n) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition-all") n coll)))) ((n step coll) (let fnrec3803 ((n n) (step step) (coll coll)) (jolt-map (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "partition-all") n step coll))))))) partitionv-all))) (guard (e (#t #f)) - (def-var! "clojure.core" "splitv-at" (letrec ((splitv-at (lambda (n coll) (let fnrec4498 ((n n) (coll coll)) (let* ((_o$4499 (jolt-invoke (var-deref "clojure.core" "vec") (jolt-take n coll))) (_o$4500 (jolt-drop n coll))) (jolt-vector _o$4499 _o$4500)))))) splitv-at))) + (def-var! "clojure.core" "splitv-at" (letrec ((splitv-at (lambda (n coll) (let fnrec3804 ((n n) (coll coll)) (let* ((_o$3805 (jolt-invoke (var-deref "clojure.core" "vec") (jolt-take n coll))) (_o$3806 (jolt-drop n coll))) (jolt-vector _o$3805 _o$3806)))))) splitv-at))) (guard (e (#t #f)) - (def-var! "clojure.core" "with-redefs-fn" (letrec ((with-redefs-fn (lambda (binding-map func) (let fnrec4501 ((binding-map binding-map) (func func)) (let* ((vars (jolt-invoke (var-deref "clojure.core" "vec") (jolt-keys binding-map))) (saved (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "var-get") vars))) (begin (begin (jolt-count (jolt-map (lambda (v) (let fnrec4502 ((v v)) (begin (jolt-invoke (var-deref "clojure.core" "var-set") v (jolt-get binding-map v)) jolt-nil))) vars)) jolt-nil) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke func)) (lambda () (let* ((i 0)) (let loop4503 ((i i)) (if (jolt-n< i (jolt-count vars)) (begin (let* ((_a$4504 (var-deref "clojure.core" "var-set")) (_a$4505 (jolt-nth vars i)) (_a$4506 (jolt-nth saved i))) (jolt-invoke _a$4504 _a$4505 _a$4506)) (loop4503 (jolt-inc i))) jolt-nil))))))))))) with-redefs-fn))) + (def-var! "clojure.core" "with-redefs-fn" (letrec ((with-redefs-fn (lambda (binding-map func) (let fnrec3807 ((binding-map binding-map) (func func)) (let* ((vars (jolt-invoke (var-deref "clojure.core" "vec") (jolt-keys binding-map))) (saved (jolt-invoke (var-deref "clojure.core" "mapv") (var-deref "clojure.core" "var-get") vars))) (begin (begin (jolt-count (jolt-map (lambda (v) (let fnrec3808 ((v v)) (begin (jolt-invoke (var-deref "clojure.core" "var-set") v (jolt-get binding-map v)) jolt-nil))) vars)) jolt-nil) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke func)) (lambda () (let* ((i 0)) (let loop3809 ((i i)) (if (< i (jolt-count vars)) (begin (let* ((_a$3810 (var-deref "clojure.core" "var-set")) (_a$3811 (jolt-nth vars i)) (_a$3812 (jolt-nth saved i))) (jolt-invoke _a$3810 _a$3811 _a$3812)) (loop3809 (jolt-inc i))) jolt-nil))))))))))) with-redefs-fn))) (guard (e (#t #f)) - (def-var! "clojure.core" "chunked-seq?" (letrec ((chunked-seq? (lambda (x) (let fnrec4507 ((x x)) #f)))) chunked-seq?))) + (def-var! "clojure.core" "chunked-seq?" (letrec ((chunked-seq? (lambda (x) (let fnrec3813 ((x x)) #f)))) chunked-seq?))) (guard (e (#t #f)) - (def-var! "clojure.core" "swap-vals!" (letrec ((swap-vals! (lambda (a f . args) (let fnrec4508 ((a a) (f f) (args (list->cseq args))) (let* ((old (jolt-invoke (var-deref "clojure.core" "deref") a))) (let* ((_o$4509 old) (_o$4510 (jolt-apply (var-deref "clojure.core" "swap!") a f args))) (jolt-vector _o$4509 _o$4510))))))) swap-vals!))) + (def-var! "clojure.core" "swap-vals!" (letrec ((swap-vals! (lambda (a f . args) (let fnrec3814 ((a a) (f f) (args (list->cseq args))) (let* ((old (jolt-invoke (var-deref "clojure.core" "deref") a))) (let* ((_o$3815 old) (_o$3816 (jolt-apply (var-deref "clojure.core" "swap!") a f args))) (jolt-vector _o$3815 _o$3816))))))) swap-vals!))) (guard (e (#t #f)) - (def-var! "clojure.core" "reset-vals!" (letrec ((reset-vals! (lambda (a newval) (let fnrec4511 ((a a) (newval newval)) (let* ((old (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") a newval) (let* ((_o$4512 old) (_o$4513 newval)) (jolt-vector _o$4512 _o$4513)))))))) reset-vals!))) + (def-var! "clojure.core" "reset-vals!" (letrec ((reset-vals! (lambda (a newval) (let fnrec3817 ((a a) (newval newval)) (let* ((old (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") a newval) (let* ((_o$3818 old) (_o$3819 newval)) (jolt-vector _o$3818 _o$3819)))))))) reset-vals!))) (guard (e (#t #f)) - (def-var! "clojure.core" "compare-and-set!" (letrec ((compare-and-set! (lambda (a oldval newval) (let fnrec4514 ((a a) (oldval oldval) (newval newval)) (if (jolt= oldval (jolt-invoke (var-deref "clojure.core" "deref") a)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") a newval) #t) #f))))) compare-and-set!))) + (def-var! "clojure.core" "compare-and-set!" (letrec ((compare-and-set! (lambda (a oldval newval) (let fnrec3820 ((a a) (oldval oldval) (newval newval)) (if (jolt= oldval (jolt-invoke (var-deref "clojure.core" "deref") a)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") a newval) #t) #f))))) compare-and-set!))) (guard (e (#t #f)) - (def-var! "clojure.core" "get-validator" (letrec ((get-validator (lambda (a) (let fnrec4515 ((a a)) (jolt-get a (keyword #f "validator")))))) get-validator))) + (def-var! "clojure.core" "get-validator" (letrec ((get-validator (lambda (a) (let fnrec3821 ((a a)) (jolt-get a (keyword #f "validator")))))) get-validator))) (guard (e (#t #f)) - (def-var! "clojure.core" "add-watch" (letrec ((add-watch (lambda (a key f) (let fnrec4516 ((a a) (key key) (f f)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-get a (keyword #f "watches")) key f) a))))) add-watch))) + (def-var! "clojure.core" "add-watch" (letrec ((add-watch (lambda (a key f) (let fnrec3822 ((a a) (key key) (f f)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-get a (keyword #f "watches")) key f) a))))) add-watch))) (guard (e (#t #f)) - (def-var! "clojure.core" "remove-watch" (letrec ((remove-watch (lambda (a key) (let fnrec4517 ((a a) (key key)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-get a (keyword #f "watches")) key jolt-nil) a))))) remove-watch))) + (def-var! "clojure.core" "remove-watch" (letrec ((remove-watch (lambda (a key) (let fnrec3823 ((a a) (key key)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-get a (keyword #f "watches")) key jolt-nil) a))))) remove-watch))) (guard (e (#t #f)) - (def-var! "clojure.core" "set-validator!" (letrec ((set-validator! (lambda (a f) (let fnrec4518 ((a a) (f f)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") a (keyword #f "validator") f) jolt-nil))))) set-validator!))) + (def-var! "clojure.core" "set-validator!" (letrec ((set-validator! (lambda (a f) (let fnrec3824 ((a a) (f f)) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") a (keyword #f "validator") f) jolt-nil))))) set-validator!))) (guard (e (#t #f)) - (def-var! "clojure.core" "future-done?" (letrec ((future-done? (lambda (x) (let fnrec4519 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "future?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cached"))) (jolt-throw "future-done? requires a future")))))) future-done?))) + (def-var! "clojure.core" "future-done?" (letrec ((future-done? (lambda (x) (let fnrec3825 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "future?") x)) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cached"))) (jolt-throw "future-done? requires a future")))))) future-done?))) (guard (e (#t #f)) - (def-var! "clojure.core" "future-cancelled?" (letrec ((future-cancelled? (lambda (x) (let fnrec4520 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "future?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cancelled"))) and__25__auto)))))) future-cancelled?))) + (def-var! "clojure.core" "future-cancelled?" (letrec ((future-cancelled? (lambda (x) (let fnrec3826 ((x x)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "future?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "boolean") (jolt-get x (keyword #f "cancelled"))) and__25__auto)))))) future-cancelled?))) (guard (e (#t #f)) - (def-var! "clojure.core" "ns-name" (letrec ((ns-name (lambda (ns) (let fnrec4521 ((ns ns)) (let* ((nm (jolt-get ns (keyword #f "name")))) (if (jolt-truthy? nm) (jolt-invoke (var-deref "clojure.core" "symbol") (jolt-invoke (var-deref "clojure.core" "str") nm)) jolt-nil)))))) ns-name))) + (def-var! "clojure.core" "ns-name" (letrec ((ns-name (lambda (ns) (let fnrec3827 ((ns ns)) (let* ((nm (jolt-get ns (keyword #f "name")))) (if (jolt-truthy? nm) (jolt-invoke (var-deref "clojure.core" "symbol") (jolt-invoke (var-deref "clojure.core" "str") nm)) jolt-nil)))))) ns-name))) (guard (e (#t #f)) - (def-var! "clojure.core" "aget" (letrec ((aget (lambda (arr . idxs) (let fnrec4522 ((arr arr) (idxs (list->cseq idxs))) (jolt-reduce (lambda (v i) (let fnrec4523 ((v v) (i i)) (jolt-nth v i))) arr idxs))))) aget))) + (def-var! "clojure.core" "aget" (letrec ((aget (lambda (arr . idxs) (let fnrec3828 ((arr arr) (idxs (list->cseq idxs))) (jolt-reduce (lambda (v i) (let fnrec3829 ((v v) (i i)) (jolt-nth v i))) arr idxs))))) aget))) (guard (e (#t #f)) - (def-var! "clojure.core" "alength" (letrec ((alength (lambda (arr) (let fnrec4524 ((arr arr)) (jolt-count arr))))) alength))) + (def-var! "clojure.core" "alength" (letrec ((alength (lambda (arr) (let fnrec3830 ((arr arr)) (jolt-count arr))))) alength))) (guard (e (#t #f)) - (def-var! "clojure.core" "aset" (letrec ((aset (lambda (arr . idxs+val) (let fnrec4525 ((arr arr) (idxs+val (list->cseq idxs+val))) (let* ((n (jolt-count idxs+val)) (val (jolt-nth idxs+val (jolt-dec n))) (target (let* ((_a$4527 (lambda (t k) (let fnrec4526 ((t t) (k k)) (jolt-nth t k)))) (_a$4528 arr) (_a$4529 (jolt-take (jolt-n- n 2) idxs+val))) (jolt-reduce _a$4527 _a$4528 _a$4529)))) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") target (jolt-nth idxs+val (jolt-n- n 2)) val) val)))))) aset))) + (def-var! "clojure.core" "aset" (letrec ((aset (lambda (arr . idxs+val) (let fnrec3831 ((arr arr) (idxs+val (list->cseq idxs+val))) (let* ((n (jolt-count idxs+val)) (val (jolt-nth idxs+val (jolt-dec n))) (target (let* ((_a$3833 (lambda (t k) (let fnrec3832 ((t t) (k k)) (jolt-nth t k)))) (_a$3834 arr) (_a$3835 (jolt-take (- n 2) idxs+val))) (jolt-reduce _a$3833 _a$3834 _a$3835)))) (begin (jolt-invoke (var-deref "jolt.host" "ref-put!") target (jolt-nth idxs+val (- n 2)) val) val)))))) aset))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "complement" (letrec ((complement (lambda (f) (let fnrec4530 ((f f)) (lambda args (let fnrec4531 ((args (list->cseq args))) (jolt-not (jolt-apply f args)))))))) complement) (let* ((_o$4532 (keyword #f "doc")) (_o$4533 "Takes a fn f and returns a fn that takes the same arguments as f, has the\n same effects, if any, and returns the opposite truth value.")) (jolt-hash-map _o$4532 _o$4533)))) + (def-var! "clojure.core" "complement" (letrec ((complement (lambda (f) (let fnrec3836 ((f f)) (lambda args (let fnrec3837 ((args (list->cseq args))) (jolt-not (jolt-apply f args)))))))) complement))) (guard (e (#t #f)) - (def-var! "clojure.core" "fnil" (letrec ((fnil (case-lambda ((f x) (let fnrec4534 ((f f) (x x)) (lambda (a . args) (let fnrec4535 ((a a) (args (list->cseq args))) (jolt-apply f (if (jolt-nil? a) x a) args))))) ((f x y) (let fnrec4536 ((f f) (x x) (y y)) (lambda (a b . args) (let fnrec4537 ((a a) (b b) (args (list->cseq args))) (let* ((_a$4538 f) (_a$4539 (if (jolt-nil? a) x a)) (_a$4540 (if (jolt-nil? b) y b)) (_a$4541 args)) (jolt-apply _a$4538 _a$4539 _a$4540 _a$4541)))))) ((f x y z) (let fnrec4542 ((f f) (x x) (y y) (z z)) (lambda (a b c . args) (let fnrec4543 ((a a) (b b) (c c) (args (list->cseq args))) (let* ((_a$4544 f) (_a$4545 (if (jolt-nil? a) x a)) (_a$4546 (if (jolt-nil? b) y b)) (_a$4547 (if (jolt-nil? c) z c)) (_a$4548 args)) (jolt-apply _a$4544 _a$4545 _a$4546 _a$4547 _a$4548))))))))) fnil))) + (def-var! "clojure.core" "fnil" (letrec ((fnil (case-lambda ((f x) (let fnrec3838 ((f f) (x x)) (lambda (a . args) (let fnrec3839 ((a a) (args (list->cseq args))) (jolt-apply f (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") a)) x a) args))))) ((f x y) (let fnrec3840 ((f f) (x x) (y y)) (lambda (a b . args) (let fnrec3841 ((a a) (b b) (args (list->cseq args))) (let* ((_a$3842 f) (_a$3843 (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") a)) x a)) (_a$3844 (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") b)) y b)) (_a$3845 args)) (jolt-apply _a$3842 _a$3843 _a$3844 _a$3845)))))) ((f x y z) (let fnrec3846 ((f f) (x x) (y y) (z z)) (lambda (a b c . args) (let fnrec3847 ((a a) (b b) (c c) (args (list->cseq args))) (let* ((_a$3848 f) (_a$3849 (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") a)) x a)) (_a$3850 (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") b)) y b)) (_a$3851 (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") c)) z c)) (_a$3852 args)) (jolt-apply _a$3848 _a$3849 _a$3850 _a$3851 _a$3852))))))))) fnil))) (guard (e (#t #f)) - (def-var! "clojure.core" "clojure-version" (letrec ((clojure-version (lambda () (let fnrec4549 () "1.11.0-jolt")))) clojure-version))) + (def-var! "clojure.core" "clojure-version" (letrec ((clojure-version (lambda () (let fnrec3853 () "1.11.0-jolt")))) clojure-version))) (guard (e (#t #f)) - (def-var! "clojure.core" "supers" (letrec ((supers (lambda (x) (let fnrec4550 ((x x)) (let* ((s (jolt-invoke (var-deref "jolt.host" "class-supers") x))) (if (jolt-truthy? s) (jolt-invoke (var-deref "clojure.core" "set") s) (jolt-hash-set))))))) supers))) + (def-var! "clojure.core" "numerator" (letrec ((numerator (lambda (x) (let fnrec3854 ((x x)) (jolt-throw (jolt-ex-info "numerator requires a ratio (Jolt has no ratios)" (jolt-hash-map))))))) numerator))) (guard (e (#t #f)) - (def-var! "clojure.core" "munge" (letrec ((munge (lambda (s) (let fnrec4551 ((s s)) (let* ((m (jolt-invoke (var-deref "clojure.core" "str-replace-all") "-" "_" (jolt-invoke (var-deref "clojure.core" "str") s)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") s)) (jolt-invoke (var-deref "clojure.core" "symbol") m) m)))))) munge))) + (def-var! "clojure.core" "denominator" (letrec ((denominator (lambda (x) (let fnrec3855 ((x x)) (jolt-throw (jolt-ex-info "denominator requires a ratio (Jolt has no ratios)" (jolt-hash-map))))))) denominator))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "test" (letrec ((test (lambda (v) (let fnrec4552 ((v v)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") v) (keyword #f "test")))) (if (jolt-truthy? t) (begin (jolt-invoke t) (keyword #f "ok")) (keyword #f "no-test"))))))) test) (let* ((_o$4553 (keyword #f "doc")) (_o$4554 "Calls the :test fn from v's metadata; :ok if it runs, :no-test if absent.")) (jolt-hash-map _o$4553 _o$4554)))) + (def-var! "clojure.core" "supers" (letrec ((supers (lambda (x) (let fnrec3856 ((x x)) (jolt-hash-set))))) supers))) (guard (e (#t #f)) - (def-var! "clojure.core" "find" (letrec ((find (lambda (m k) (let fnrec4555 ((m m) (k k)) (if (jolt-contains? m k) (jolt-first (let* ((_o$4556 k) (_o$4557 (jolt-get m k))) (jolt-hash-map _o$4556 _o$4557))) jolt-nil))))) find))) + (def-var! "clojure.core" "munge" (letrec ((munge (lambda (s) (let fnrec3857 ((s s)) (let* ((m (jolt-invoke (var-deref "clojure.core" "str-replace-all") "-" "_" (jolt-invoke (var-deref "clojure.core" "str") s)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") s)) (jolt-invoke (var-deref "clojure.core" "symbol") m) m)))))) munge))) (guard (e (#t #f)) - (def-var! "clojure.core" "true?" (letrec ((true? (lambda (x) (let fnrec4558 ((x x)) (jolt= #t x))))) true?))) + (def-var! "clojure.core" "test" (letrec ((test (lambda (v) (let fnrec3858 ((v v)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") v) (keyword #f "test")))) (if (jolt-truthy? t) (begin (jolt-invoke t) (keyword #f "ok")) (keyword #f "no-test"))))))) test))) (guard (e (#t #f)) - (def-var! "clojure.core" "false?" (letrec ((false? (lambda (x) (let fnrec4559 ((x x)) (jolt= #f x))))) false?))) + (def-var! "clojure.core" "find" (letrec ((find (lambda (m k) (let fnrec3859 ((m m) (k k)) (if (jolt-contains? m k) (jolt-first (let* ((_o$3860 k) (_o$3861 (jolt-get m k))) (jolt-hash-map _o$3860 _o$3861))) jolt-nil))))) find))) (guard (e (#t #f)) - (def-var! "clojure.core" "select-keys" (letrec ((select-keys (lambda (map keyseq) (let fnrec4560 ((map map) (keyseq keyseq)) (let* ((_a$4562 (lambda (m k) (let fnrec4561 ((m m) (k k)) (if (jolt-contains? map k) (jolt-assoc m k (jolt-get map k)) m)))) (_a$4563 (jolt-hash-map)) (_a$4564 keyseq)) (jolt-reduce _a$4562 _a$4563 _a$4564)))))) select-keys))) + (def-var! "clojure.core" "true?" (letrec ((true? (lambda (x) (let fnrec3862 ((x x)) (jolt= #t x))))) true?))) (guard (e (#t #f)) - (def-var! "clojure.core" "zipmap" (letrec ((zipmap (lambda (keys vals) (let fnrec4565 ((keys keys) (vals vals)) (let* ((m (jolt-hash-map)) (ks (jolt-seq keys)) (vs (jolt-seq vals))) (let loop4566 ((m m) (ks ks) (vs vs)) (if (jolt-truthy? (let* ((and__25__auto ks)) (if (jolt-truthy? and__25__auto) vs and__25__auto))) (let* ((_a$4570 (let* ((_a$4567 m) (_a$4568 (jolt-first ks)) (_a$4569 (jolt-first vs))) (jolt-assoc _a$4567 _a$4568 _a$4569))) (_a$4571 (jolt-next ks)) (_a$4572 (jolt-next vs))) (loop4566 _a$4570 _a$4571 _a$4572)) m))))))) zipmap))) + (def-var! "clojure.core" "false?" (letrec ((false? (lambda (x) (let fnrec3863 ((x x)) (jolt= #f x))))) false?))) (guard (e (#t #f)) - (def-var! "clojure.core" "create-struct" (letrec ((create-struct (lambda keys (let fnrec4573 ((keys (list->cseq keys))) (jolt-invoke (var-deref "clojure.core" "vec") keys))))) create-struct))) + (def-var! "clojure.core" "select-keys" (letrec ((select-keys (lambda (map keyseq) (let fnrec3864 ((map map) (keyseq keyseq)) (let* ((_a$3866 (lambda (m k) (let fnrec3865 ((m m) (k k)) (if (jolt-contains? map k) (jolt-assoc m k (jolt-get map k)) m)))) (_a$3867 (jolt-hash-map )) (_a$3868 keyseq)) (jolt-reduce _a$3866 _a$3867 _a$3868)))))) select-keys))) (guard (e (#t #f)) - (def-var! "clojure.core" "struct-map" (letrec ((struct-map (lambda (basis . inits) (let fnrec4574 ((basis basis) (inits (list->cseq inits))) (let* ((base (let* ((m (jolt-hash-map)) (ks (jolt-seq basis))) (let loop4575 ((m m) (ks ks)) (if (jolt-truthy? ks) (let* ((_a$4576 (jolt-assoc m (jolt-first ks) jolt-nil)) (_a$4577 (jolt-next ks))) (loop4575 _a$4576 _a$4577)) m))))) (let* ((m base) (kvs (jolt-seq inits))) (let loop4578 ((m m) (kvs kvs)) (if (jolt-truthy? kvs) (let* ((_a$4582 (let* ((_a$4579 m) (_a$4580 (jolt-first kvs)) (_a$4581 (jolt-first (jolt-next kvs)))) (jolt-assoc _a$4579 _a$4580 _a$4581))) (_a$4583 (jolt-next (jolt-next kvs)))) (loop4578 _a$4582 _a$4583)) m)))))))) struct-map))) + (def-var! "clojure.core" "zipmap" (letrec ((zipmap (lambda (keys vals) (let fnrec3869 ((keys keys) (vals vals)) (let* ((m (jolt-hash-map )) (ks (jolt-seq keys)) (vs (jolt-seq vals))) (let loop3870 ((m m) (ks ks) (vs vs)) (if (jolt-truthy? (let* ((and__25__auto ks)) (if (jolt-truthy? and__25__auto) vs and__25__auto))) (let* ((_a$3874 (let* ((_a$3871 m) (_a$3872 (jolt-first ks)) (_a$3873 (jolt-first vs))) (jolt-assoc _a$3871 _a$3872 _a$3873))) (_a$3875 (jolt-next ks)) (_a$3876 (jolt-next vs))) (loop3870 _a$3874 _a$3875 _a$3876)) m))))))) zipmap))) (guard (e (#t #f)) - (def-var! "clojure.core" "struct" (letrec ((struct (lambda (basis . vals) (let fnrec4584 ((basis basis) (vals (list->cseq vals))) (let* ((m (jolt-invoke (var-deref "clojure.core" "struct-map") basis)) (ks (jolt-seq basis)) (vs (jolt-seq vals))) (let loop4585 ((m m) (ks ks) (vs vs)) (if (jolt-truthy? (let* ((and__25__auto ks)) (if (jolt-truthy? and__25__auto) vs and__25__auto))) (let* ((_a$4589 (let* ((_a$4586 m) (_a$4587 (jolt-first ks)) (_a$4588 (jolt-first vs))) (jolt-assoc _a$4586 _a$4587 _a$4588))) (_a$4590 (jolt-next ks)) (_a$4591 (jolt-next vs))) (loop4585 _a$4589 _a$4590 _a$4591)) m))))))) struct))) + (def-var! "clojure.core" "merge" (letrec ((merge (lambda maps (let fnrec3877 ((maps (list->cseq maps))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "some") jolt-identity maps)) (jolt-reduce (lambda (acc m) (let fnrec3878 ((acc acc) (m m)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") m)) acc (jolt-conj (let* ((or__26__auto acc)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map ))) m)))) maps) jolt-nil))))) merge))) (guard (e (#t #f)) - (def-var! "clojure.core" "accessor" (letrec ((accessor (lambda (basis key) (let fnrec4592 ((basis basis) (key key)) (lambda (m) (let fnrec4593 ((m m)) (jolt-get m key))))))) accessor))) + (def-var! "clojure.core" "merge-with" (letrec ((merge-with (lambda (f . maps) (let fnrec3879 ((f f) (maps (list->cseq maps))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "some") jolt-identity maps)) (let* ((merge-entry (lambda (m e) (let fnrec3880 ((m m) (e e)) (let* ((k (jolt-invoke (var-deref "clojure.core" "key") e)) (v (jolt-invoke (var-deref "clojure.core" "val") e))) (if (jolt-contains? m k) (jolt-assoc m k (jolt-invoke f (jolt-get m k) v)) (jolt-assoc m k v)))))) (merge2 (lambda (m1 m2) (let fnrec3881 ((m1 m1) (m2 m2)) (let* ((_a$3882 merge-entry) (_a$3883 (let* ((or__26__auto m1)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map )))) (_a$3884 (jolt-seq m2))) (jolt-reduce _a$3882 _a$3883 _a$3884)))))) (jolt-reduce merge2 maps)) jolt-nil))))) merge-with))) (guard (e (#t #f)) - (def-var! "clojure.core" "merge" (letrec ((merge (lambda maps (let fnrec4594 ((maps (list->cseq maps))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "some") jolt-identity maps)) (jolt-reduce (lambda (acc m) (let fnrec4595 ((acc acc) (m m)) (if (jolt-nil? m) acc (jolt-conj (let* ((or__26__auto acc)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map))) m)))) maps) jolt-nil))))) merge))) + (def-var! "clojure.core" "get-in" (letrec ((get-in (case-lambda ((m ks) (let fnrec3885 ((m m) (ks ks)) (jolt-reduce jolt-get m ks))) ((m ks not-found) (let fnrec3886 ((m m) (ks ks) (not-found not-found)) (let* ((sentinel (jolt-hash-map ))) (let* ((m m) (ks (jolt-seq ks))) (let loop3887 ((m m) (ks ks)) (if (jolt-truthy? ks) (let* ((nxt (jolt-get m (jolt-first ks) sentinel))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "identical?") sentinel nxt)) not-found (loop3887 nxt (jolt-next ks)))) m))))))))) get-in))) (guard (e (#t #f)) - (def-var! "clojure.core" "merge-with" (letrec ((merge-with (lambda (f . maps) (let fnrec4596 ((f f) (maps (list->cseq maps))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "some") jolt-identity maps)) (let* ((merge-entry (lambda (m e) (let fnrec4597 ((m m) (e e)) (let* ((k (jolt-invoke (var-deref "clojure.core" "key") e)) (v (jolt-invoke (var-deref "clojure.core" "val") e))) (if (jolt-contains? m k) (jolt-assoc m k (jolt-invoke f (jolt-get m k) v)) (jolt-assoc m k v)))))) (merge2 (lambda (m1 m2) (let fnrec4598 ((m1 m1) (m2 m2)) (let* ((_a$4599 merge-entry) (_a$4600 (let* ((or__26__auto m1)) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-hash-map)))) (_a$4601 (jolt-seq m2))) (jolt-reduce _a$4599 _a$4600 _a$4601)))))) (jolt-reduce merge2 maps)) jolt-nil))))) merge-with))) + (def-var! "clojure.core" "memoize" (letrec ((memoize (lambda (f) (let fnrec3888 ((f f)) (let* ((mem (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map )))) (lambda args (let fnrec3889 ((args (list->cseq args))) (let* ((e (jolt-invoke (var-deref "clojure.core" "find") (jolt-invoke (var-deref "clojure.core" "deref") mem) args))) (if (jolt-truthy? e) (jolt-invoke (var-deref "clojure.core" "val") e) (let* ((ret (jolt-apply f args))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") mem jolt-assoc args ret) ret))))))))))) memoize))) (guard (e (#t #f)) - (def-var! "clojure.core" "get-in" (letrec ((get-in (case-lambda ((m ks) (let fnrec4602 ((m m) (ks ks)) (jolt-reduce jolt-get m ks))) ((m ks not-found) (let fnrec4603 ((m m) (ks ks) (not-found not-found)) (let* ((sentinel (jolt-hash-map-fn ))) (let* ((m m) (ks (jolt-seq ks))) (let loop4604 ((m m) (ks ks)) (if (jolt-truthy? ks) (let* ((nxt (jolt-get m (jolt-first ks) sentinel))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "identical?") sentinel nxt)) not-found (loop4604 nxt (jolt-next ks)))) m))))))))) get-in))) + (def-var! "clojure.core" "partial" (letrec ((partial (case-lambda ((f) (let fnrec3890 ((f f)) f)) ((f a) (let fnrec3891 ((f f) (a a)) (lambda args (let fnrec3892 ((args (list->cseq args))) (jolt-apply f a args))))) ((f a b) (let fnrec3893 ((f f) (a a) (b b)) (lambda args (let fnrec3894 ((args (list->cseq args))) (jolt-apply f a b args))))) ((f a b c) (let fnrec3895 ((f f) (a a) (b b) (c c)) (lambda args (let fnrec3896 ((args (list->cseq args))) (jolt-apply f a b c args))))) ((f a b c . more) (let fnrec3897 ((f f) (a a) (b b) (c c) (more (list->cseq more))) (lambda args (let fnrec3898 ((args (list->cseq args))) (jolt-apply f a b c (jolt-concat more args))))))))) partial))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "req!" (letrec ((req! (lambda (m k) (let fnrec4605 ((m m) (k k)) (let* ((sentinel (jolt-hash-map-fn )) (v (jolt-get m k sentinel))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "identical?") sentinel v)) (jolt-throw (host-new "IllegalArgumentException" (jolt-invoke (var-deref "clojure.core" "str") "Expected key: " k))) v)))))) req!) (let* ((_o$4606 (keyword #f "added")) (_o$4607 "1.13") (_o$4608 (keyword #f "doc")) (_o$4609 "Returns the value mapped to key k in map m, like `get`, but throws\n IllegalArgumentException when k is not present. Unlike `get`, does not nil-pun:\n a key present with a nil value returns nil, an absent key throws. The primitive\n behind checked-keys destructuring (:keys! / :syms! / :strs!).")) (jolt-hash-map _o$4606 _o$4607 _o$4608 _o$4609)))) + (def-var! "clojure.core" "trampoline" (letrec ((trampoline (case-lambda ((f) (let fnrec3899 ((f f)) (let* ((ret (jolt-invoke f))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "fn?") ret)) (jolt-invoke trampoline ret) ret)))) ((f . args) (let fnrec3900 ((f f) (args (list->cseq args))) (jolt-invoke trampoline (lambda () (let fnrec3901 () (jolt-apply f args))))))))) trampoline))) (guard (e (#t #f)) - (def-var! "clojure.core" "memoize" (letrec ((memoize (lambda (f) (let fnrec4610 ((f f)) (let* ((mem (jolt-invoke (var-deref "clojure.core" "atom") (jolt-hash-map-fn )))) (lambda args (let fnrec4611 ((args (list->cseq args))) (let* ((e (jolt-invoke (var-deref "clojure.core" "find") (jolt-invoke (var-deref "clojure.core" "deref") mem) args))) (if (jolt-truthy? e) (jolt-invoke (var-deref "clojure.core" "val") e) (let* ((ret (jolt-apply f args))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") mem jolt-assoc args ret) ret))))))))))) memoize))) + (def-var! "clojure.core" "max" (letrec ((max (case-lambda ((x) (let fnrec3902 ((x x)) x)) ((x y) (let fnrec3903 ((x x) (y y)) (if (> x y) x y))) ((x y . more) (let fnrec3904 ((x x) (y y) (more (list->cseq more))) (jolt-reduce max (jolt-invoke max x y) more)))))) max))) (guard (e (#t #f)) - (def-var! "clojure.core" "partial" (letrec ((partial (case-lambda ((f) (let fnrec4612 ((f f)) f)) ((f a) (let fnrec4613 ((f f) (a a)) (lambda args (let fnrec4614 ((args (list->cseq args))) (jolt-apply f a args))))) ((f a b) (let fnrec4615 ((f f) (a a) (b b)) (lambda args (let fnrec4616 ((args (list->cseq args))) (jolt-apply f a b args))))) ((f a b c) (let fnrec4617 ((f f) (a a) (b b) (c c)) (lambda args (let fnrec4618 ((args (list->cseq args))) (jolt-apply f a b c args))))) ((f a b c . more) (let fnrec4619 ((f f) (a a) (b b) (c c) (more (list->cseq more))) (lambda args (let fnrec4620 ((args (list->cseq args))) (jolt-apply f a b c (jolt-concat more args))))))))) partial))) + (def-var! "clojure.core" "min" (letrec ((min (case-lambda ((x) (let fnrec3905 ((x x)) x)) ((x y) (let fnrec3906 ((x x) (y y)) (if (< x y) x y))) ((x y . more) (let fnrec3907 ((x x) (y y) (more (list->cseq more))) (jolt-reduce min (jolt-invoke min x y) more)))))) min))) (guard (e (#t #f)) - (def-var! "clojure.core" "trampoline" (letrec ((trampoline (case-lambda ((f) (let fnrec4621 ((f f)) (let* ((ret (jolt-invoke f))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "fn?") ret)) (trampoline ret) ret)))) ((f . args) (let fnrec4622 ((f f) (args (list->cseq args))) (trampoline (lambda () (let fnrec4623 () (jolt-apply f args))))))))) trampoline))) + (def-var! "clojure.core" "reverse" (letrec ((reverse (lambda (coll) (let fnrec3908 ((coll coll)) (jolt-reduce jolt-conj (jolt-list ) coll))))) reverse))) (guard (e (#t #f)) - (def-var! "clojure.core" "max" (letrec ((max (case-lambda ((x) (let fnrec4624 ((x x)) x)) ((x y) (let fnrec4625 ((x x) (y y)) (if (jolt-n> x y) x y))) ((x y . more) (let fnrec4626 ((x x) (y y) (more (list->cseq more))) (jolt-reduce max (max x y) more)))))) max))) + (def-var! "clojure.core" "empty" (letrec ((empty (lambda (coll) (let fnrec3909 ((coll coll)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") coll)) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted?") coll)) (jolt-invoke (jolt-get (jolt-invoke (var-deref "jolt.host" "ref-get") coll (keyword #f "ops")) (keyword #f "empty")) coll) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (let* ((_a$3910 (var-deref "clojure.core" "with-meta")) (_a$3911 (jolt-hash-map)) (_a$3912 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$3910 _a$3911 _a$3912)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") coll)) (let* ((_a$3913 (var-deref "clojure.core" "with-meta")) (_a$3914 (jolt-hash-set)) (_a$3915 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$3913 _a$3914 _a$3915)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (let* ((_a$3916 (var-deref "clojure.core" "with-meta")) (_a$3917 (jolt-vector)) (_a$3918 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$3916 _a$3917 _a$3918)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "coll?") coll)) (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-list ) (jolt-invoke (var-deref "clojure.core" "meta") coll)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))))))) empty))) (guard (e (#t #f)) - (def-var! "clojure.core" "min" (letrec ((min (case-lambda ((x) (let fnrec4627 ((x x)) x)) ((x y) (let fnrec4628 ((x x) (y y)) (if (jolt-n< x y) x y))) ((x y . more) (let fnrec4629 ((x x) (y y) (more (list->cseq more))) (jolt-reduce min (min x y) more)))))) min))) + (def-var! "clojure.core" "assoc-in" (letrec ((assoc-in (lambda (m G__117 v) (let fnrec3919 ((m m) (G__117 G__117) (v v)) (let* ((G__118 G__117) (k (jolt-nth G__118 0 jolt-nil)) (ks (jolt-invoke (var-deref "clojure.core" "nthnext") G__118 1))) (if (jolt-truthy? ks) (jolt-assoc m k (jolt-invoke assoc-in (jolt-get m k) ks v)) (jolt-assoc m k v))))))) assoc-in))) (guard (e (#t #f)) - (def-var! "clojure.core" "reverse" (letrec ((reverse (lambda (coll) (let fnrec4630 ((coll coll)) (jolt-reduce jolt-conj (jolt-list ) coll))))) reverse))) + (def-var! "clojure.core" "update-in" (letrec ((update-in (lambda (m ks f . args) (let fnrec3920 ((m m) (ks ks) (f f) (args (list->cseq args))) (let* ((up (letrec ((up (lambda (m ks f args) (let fnrec3921 ((m m) (ks ks) (f f) (args args)) (let* ((G__119 ks) (k (jolt-nth G__119 0 jolt-nil)) (ks (jolt-invoke (var-deref "clojure.core" "nthnext") G__119 1))) (if (jolt-truthy? ks) (jolt-assoc m k (jolt-invoke up (jolt-get m k) ks f args)) (jolt-assoc m k (jolt-apply f (jolt-get m k) args)))))))) up))) (jolt-invoke up m ks f args)))))) update-in))) (guard (e (#t #f)) - (def-var! "clojure.core" "empty" (letrec ((empty (lambda (coll) (let fnrec4631 ((coll coll)) (if (jolt-nil? coll) jolt-nil (if (jolt-truthy? (jolt-invoke (var-deref "jolt.host" "jrec-method?") coll "empty")) (record-method-dispatch coll "empty" (jolt-vector)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "record?") coll)) (jolt-throw (host-new "UnsupportedOperationException" (jolt-invoke (var-deref "clojure.core" "str") "Can't create empty: " (record-method-dispatch (jolt-invoke (var-deref "clojure.core" "class") coll) "getName" (jolt-vector))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted?") coll)) (jolt-invoke (jolt-get (jolt-invoke (var-deref "jolt.host" "ref-get") coll (keyword #f "ops")) (keyword #f "empty")) coll) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") coll)) (let* ((_a$4632 (var-deref "clojure.core" "with-meta")) (_a$4633 (jolt-hash-map)) (_a$4634 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$4632 _a$4633 _a$4634)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") coll)) (let* ((_a$4635 (var-deref "clojure.core" "with-meta")) (_a$4636 (jolt-hash-set)) (_a$4637 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$4635 _a$4636 _a$4637)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") coll)) (let* ((_a$4638 (var-deref "clojure.core" "with-meta")) (_a$4639 (jolt-vector)) (_a$4640 (jolt-invoke (var-deref "clojure.core" "meta") coll))) (jolt-invoke _a$4638 _a$4639 _a$4640)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "coll?") coll)) (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-list ) (jolt-invoke (var-deref "clojure.core" "meta") coll)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))))))))))) empty))) + (def-var! "clojure.core" "find-keyword" (letrec ((find-keyword (case-lambda ((nm) (let fnrec3922 ((nm nm)) (jolt-invoke (var-deref "clojure.core" "keyword") nm))) ((ns nm) (let fnrec3923 ((ns ns) (nm nm)) (jolt-invoke (var-deref "clojure.core" "keyword") ns nm)))))) find-keyword))) (guard (e (#t #f)) - (def-var! "clojure.core" "assoc-in" (letrec ((assoc-in (lambda (m G__133 v) (let fnrec4641 ((m m) (G__133 G__133) (v v)) (let* ((G__134 G__133) (k (jolt-nth G__134 0 jolt-nil)) (ks (jolt-invoke (var-deref "clojure.core" "nthnext") G__134 1))) (if (jolt-truthy? ks) (jolt-assoc m k (assoc-in (jolt-get m k) ks v)) (jolt-assoc m k v))))))) assoc-in))) + (def-var! "clojure.core" "inst-ms*" (letrec ((inst-ms* (lambda (i) (let fnrec3924 ((i i)) (jolt-invoke (var-deref "clojure.core" "inst-ms") i))))) inst-ms*))) (guard (e (#t #f)) - (def-var! "clojure.core" "update-in" (letrec ((update-in (lambda (m ks f . args) (let fnrec4642 ((m m) (ks ks) (f f) (args (list->cseq args))) (let* ((up (letrec ((up (lambda (m ks f args) (let fnrec4643 ((m m) (ks ks) (f f) (args args)) (let* ((G__135 ks) (k (jolt-nth G__135 0 jolt-nil)) (ks (jolt-invoke (var-deref "clojure.core" "nthnext") G__135 1))) (if (jolt-truthy? ks) (jolt-assoc m k (up (jolt-get m k) ks f args)) (jolt-assoc m k (jolt-apply f (jolt-get m k) args)))))))) up))) (jolt-invoke up m ks f args)))))) update-in))) + (def-var! "clojure.core" "comp" (letrec ((comp (case-lambda (() (let fnrec3925 () jolt-identity)) ((f) (let fnrec3926 ((f f)) f)) ((f g) (let fnrec3927 ((f f) (g g)) (case-lambda (() (let fnrec3928 () (jolt-invoke f (jolt-invoke g)))) ((x) (let fnrec3929 ((x x)) (jolt-invoke f (jolt-invoke g x)))) ((x y) (let fnrec3930 ((x x) (y y)) (jolt-invoke f (jolt-invoke g x y)))) ((x y z) (let fnrec3931 ((x x) (y y) (z z)) (jolt-invoke f (jolt-invoke g x y z)))) ((x y z . args) (let fnrec3932 ((x x) (y y) (z z) (args (list->cseq args))) (jolt-invoke f (jolt-apply g x y z args))))))) ((f g . fs) (let fnrec3933 ((f f) (g g) (fs (list->cseq fs))) (jolt-reduce comp (jolt-invoke comp f g) fs)))))) comp))) (guard (e (#t #f)) - (def-var! "clojure.core" "find-keyword" (letrec ((find-keyword (case-lambda ((nm) (let fnrec4644 ((nm nm)) (jolt-invoke (var-deref "clojure.core" "keyword") nm))) ((ns nm) (let fnrec4645 ((ns ns) (nm nm)) (jolt-invoke (var-deref "clojure.core" "keyword") ns nm)))))) find-keyword))) -(guard (e (#t #f)) - (def-var! "clojure.core" "inst-ms*" (letrec ((inst-ms* (lambda (i) (let fnrec4646 ((i i)) (jolt-invoke (var-deref "clojure.core" "inst-ms") i))))) inst-ms*))) -(guard (e (#t #f)) - (def-var! "clojure.core" "comp" (letrec ((comp (case-lambda (() (let fnrec4647 () jolt-identity)) ((f) (let fnrec4648 ((f f)) f)) ((f g) (let fnrec4649 ((f f) (g g)) (case-lambda (() (let fnrec4650 () (jolt-invoke f (jolt-invoke g)))) ((x) (let fnrec4651 ((x x)) (jolt-invoke f (jolt-invoke g x)))) ((x y) (let fnrec4652 ((x x) (y y)) (jolt-invoke f (jolt-invoke g x y)))) ((x y z) (let fnrec4653 ((x x) (y y) (z z)) (jolt-invoke f (jolt-invoke g x y z)))) ((x y z . args) (let fnrec4654 ((x x) (y y) (z z) (args (list->cseq args))) (jolt-invoke f (jolt-apply g x y z args))))))) ((f g . fs) (let fnrec4655 ((f f) (g g) (fs (list->cseq fs))) (jolt-reduce comp (comp f g) fs)))))) comp))) -(guard (e (#t #f)) - (def-var! "clojure.core" "ifn?" (letrec ((ifn? (lambda (x) (let fnrec4656 ((x x)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "fn?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "set?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "var?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "jolt.host" "callable-host?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "jolt.host" "jrec-method?") x "invoke")))))))))))))))))) #t #f))))) ifn?))) + (def-var! "clojure.core" "ifn?" (letrec ((ifn? (lambda (x) (let fnrec3934 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "fn?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "keyword?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "symbol?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "set?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "var?") x))))))))))))))))) ifn?))) (guard (e (#t #f)) (def-var! "clojure.core" "+'" jolt-add)) (guard (e (#t #f)) @@ -517,555 +503,575 @@ (guard (e (#t #f)) (def-var! "clojure.core" "dec'" jolt-dec)) (guard (e (#t #f)) - (def-var! "clojure.core" "int?" (letrec ((int? (lambda (x) (let fnrec4657 ((x x)) (jolt-invoke (var-deref "clojure.core" "integer?") x))))) int?))) + (def-var! "clojure.core" "unchecked-add" (letrec ((unchecked-add (lambda (x y) (let fnrec3935 ((x x) (y y)) (+ x y))))) unchecked-add))) (guard (e (#t #f)) - (def-var! "clojure.core" "num" (letrec ((num (lambda (x) (let fnrec4658 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) x (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "num requires a number, got: " x))))))) num))) + (def-var! "clojure.core" "unchecked-subtract" (letrec ((unchecked-subtract (lambda (x y) (let fnrec3936 ((x x) (y y)) (- x y))))) unchecked-subtract))) (guard (e (#t #f)) - (def-var! "clojure.core" "==" (letrec ((== (case-lambda ((x) (let fnrec4659 ((x x)) #t)) ((x y) (let fnrec4660 ((x x) (y y)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "number?") y) and__25__auto))) (jolt= x y) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Cannot cast to number: " (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) y x)))))) ((x y . more) (let fnrec4661 ((x x) (y y) (more (list->cseq more))) (if (jolt-truthy? (== x y)) (jolt-apply == y more) #f)))))) ==))) + (def-var! "clojure.core" "unchecked-multiply" (letrec ((unchecked-multiply (lambda (x y) (let fnrec3937 ((x x) (y y)) (* x y))))) unchecked-multiply))) (guard (e (#t #f)) - (def-var! "clojure.core" "ensure-reduced" (letrec ((ensure-reduced (lambda (x) (let fnrec4662 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") x)) x (jolt-invoke (var-deref "clojure.core" "reduced") x)))))) ensure-reduced))) + (def-var! "clojure.core" "unchecked-negate" (letrec ((unchecked-negate (lambda (x) (let fnrec3938 ((x x)) (- x))))) unchecked-negate))) (guard (e (#t #f)) - (def-var! "clojure.core" "halt-when" (letrec ((halt-when (case-lambda ((pred) (let fnrec4663 ((pred pred)) (halt-when pred jolt-nil))) ((pred retf) (let fnrec4664 ((pred pred) (retf retf)) (lambda (rf) (let fnrec4665 ((rf rf)) (case-lambda (() (let fnrec4666 () (jolt-invoke rf))) ((result) (let fnrec4667 ((result result)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") result))) (if (jolt-truthy? and__25__auto) (jolt-contains? result (keyword "clojure.core" "halt")) and__25__auto))) (jolt-get result (keyword "clojure.core" "halt")) (jolt-invoke rf result)))) ((result input) (let fnrec4668 ((result result) (input input)) (if (jolt-truthy? (jolt-invoke pred input)) (jolt-invoke (var-deref "clojure.core" "reduced") (jolt-hash-map-fn (keyword "clojure.core" "halt") (if (jolt-truthy? retf) (jolt-invoke retf (jolt-invoke rf result) input) input))) (jolt-invoke rf result input)))))))))))) halt-when))) + (def-var! "clojure.core" "unchecked-inc" (letrec ((unchecked-inc (lambda (x) (let fnrec3939 ((x x)) (+ x 1))))) unchecked-inc))) (guard (e (#t #f)) - (def-var! "clojure.core" "parse-boolean" (letrec ((parse-boolean (lambda (s) (let fnrec4669 ((s s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") s)) (if (jolt= s "true") #t (if (jolt= s "false") #f (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "parse-boolean requires a string, got: " s))))))) parse-boolean))) + (def-var! "clojure.core" "unchecked-dec" (letrec ((unchecked-dec (lambda (x) (let fnrec3940 ((x x)) (- x 1))))) unchecked-dec))) (guard (e (#t #f)) - (def-var! "clojure.core" "newline" (letrec ((newline (lambda () (let fnrec4670 () (begin (jolt-invoke (var-deref "clojure.core" "print") "\n") jolt-nil))))) newline))) + (def-var! "clojure.core" "unchecked-add-int" (var-deref "clojure.core" "unchecked-add"))) (guard (e (#t #f)) - (def-var! "clojure.core" "seque" (letrec ((seque (case-lambda ((s) (let fnrec4671 ((s s)) s)) ((n-or-q s) (let fnrec4672 ((n-or-q n-or-q) (s s)) s))))) seque))) + (def-var! "clojure.core" "unchecked-subtract-int" (var-deref "clojure.core" "unchecked-subtract"))) (guard (e (#t #f)) - (def-var! "clojure.core" "array-seq" (letrec ((array-seq (lambda (arr . _) (let fnrec4673 ((arr arr) (_ (list->cseq _))) (jolt-seq arr))))) array-seq))) + (def-var! "clojure.core" "unchecked-multiply-int" (var-deref "clojure.core" "unchecked-multiply"))) (guard (e (#t #f)) - (def-var! "clojure.core" "to-array-2d" (letrec ((to-array-2d (lambda (coll) (let fnrec4674 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "to-array") (jolt-map (var-deref "clojure.core" "to-array") coll)))))) to-array-2d))) + (def-var! "clojure.core" "unchecked-negate-int" (var-deref "clojure.core" "unchecked-negate"))) (guard (e (#t #f)) - (def-var! "clojure.core" "unchecked-byte" (letrec ((unchecked-byte (lambda (x) (let fnrec4675 ((x x)) (let* ((b (bitwise-and (jolt-invoke (var-deref "clojure.core" "unchecked-long") x) 255))) (if (jolt-n< b 128) b (jolt-n- b 256))))))) unchecked-byte))) + (def-var! "clojure.core" "unchecked-inc-int" (var-deref "clojure.core" "unchecked-inc"))) (guard (e (#t #f)) - (def-var! "clojure.core" "unchecked-short" (letrec ((unchecked-short (lambda (x) (let fnrec4676 ((x x)) (let* ((s (bitwise-and (jolt-invoke (var-deref "clojure.core" "unchecked-long") x) 65535))) (if (jolt-n< s 32768) s (jolt-n- s 65536))))))) unchecked-short))) + (def-var! "clojure.core" "unchecked-dec-int" (var-deref "clojure.core" "unchecked-dec"))) (guard (e (#t #f)) - (def-var! "clojure.core" "unchecked-char" (letrec ((unchecked-char (lambda (x) (let fnrec4677 ((x x)) (jolt-invoke (var-deref "clojure.core" "char") (bitwise-and (jolt-invoke (var-deref "clojure.core" "unchecked-long") x) 65535)))))) unchecked-char))) + (def-var! "clojure.core" "unchecked-divide-int" (letrec ((unchecked-divide-int (lambda (x y) (let fnrec3941 ((x x) (y y)) (quotient x y))))) unchecked-divide-int))) (guard (e (#t #f)) - (def-var! "clojure.core" "unchecked-float" (letrec ((unchecked-float (lambda (x) (let fnrec4678 ((x x)) (jolt-invoke (var-deref "clojure.core" "double") x))))) unchecked-float))) + (def-var! "clojure.core" "unchecked-remainder-int" (letrec ((unchecked-remainder-int (lambda (x y) (let fnrec3942 ((x x) (y y)) (remainder x y))))) unchecked-remainder-int))) (guard (e (#t #f)) - (def-var! "clojure.core" "unchecked-double" (letrec ((unchecked-double (lambda (x) (let fnrec4679 ((x x)) (jolt-invoke (var-deref "clojure.core" "double") x))))) unchecked-double))) + (def-var! "clojure.core" "unchecked-int" (letrec ((unchecked-int (lambda (x) (let fnrec3943 ((x x)) (jolt-invoke (var-deref "clojure.core" "int") x))))) unchecked-int))) (guard (e (#t #f)) - (def-var! "clojure.core" "transduce" (letrec ((transduce (case-lambda ((xform f coll) (let fnrec4680 ((xform xform) (f f) (coll coll)) (transduce xform f (jolt-invoke f) coll))) ((xform f init coll) (let fnrec4681 ((xform xform) (f f) (init init) (coll coll)) (let* ((xf (jolt-invoke xform f))) (jolt-invoke xf (jolt-reduce xf init coll)))))))) transduce))) + (def-var! "clojure.core" "unchecked-long" (var-deref "clojure.core" "unchecked-int"))) (guard (e (#t #f)) - (def-var! "clojure.core" "eduction" (letrec ((eduction (lambda args (let fnrec4682 ((args (list->cseq args))) (let* ((coll (jolt-last args)) (xforms (jolt-invoke (var-deref "clojure.core" "butlast") args))) (if (jolt-truthy? xforms) (jolt-invoke (var-deref "clojure.core" "sequence") (jolt-apply (var-deref "clojure.core" "comp") xforms) coll) (jolt-invoke (var-deref "clojure.core" "sequence") coll))))))) eduction))) + (def-var! "clojure.core" "int?" (letrec ((int? (lambda (x) (let fnrec3944 ((x x)) (jolt-invoke (var-deref "clojure.core" "integer?") x))))) int?))) (guard (e (#t #f)) - (def-var! "clojure.core" "->Eduction" (letrec ((->Eduction (lambda (xform coll) (let fnrec4683 ((xform xform) (coll coll)) (jolt-invoke (var-deref "clojure.core" "sequence") xform coll))))) ->Eduction))) + (def-var! "clojure.core" "num" (letrec ((num (lambda (x) (let fnrec3945 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) x (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "num requires a number, got: " x))))))) num))) (guard (e (#t #f)) - (def-var! "clojure.core" "enumeration-seq" (letrec ((enumeration-seq (lambda (e) (let fnrec4684 ((e e)) (if (jolt-truthy? (let* ((or__26__auto (jolt-nil? e))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "seq?") e))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "sequential?") e)))))) (jolt-seq e) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec4685 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (if (jolt-truthy? (record-method-dispatch e "hasMoreElements" (jolt-vector))) (let* ((_a$4686 (record-method-dispatch e "nextElement" (jolt-vector))) (_a$4687 (enumeration-seq e))) (jolt-cons _a$4686 _a$4687)) jolt-nil)))))))))) enumeration-seq))) + (def-var! "clojure.core" "==" (letrec ((== (case-lambda ((x) (let fnrec3946 ((x x)) #t)) ((x y) (let fnrec3947 ((x x) (y y)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") x))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "number?") y) and__25__auto))) (jolt= x y) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "Cannot cast to number: " (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") x)) y x)))))) ((x y . more) (let fnrec3948 ((x x) (y y) (more (list->cseq more))) (if (jolt-truthy? (jolt-invoke == x y)) (jolt-apply == y more) #f)))))) ==))) (guard (e (#t #f)) - (def-var! "clojure.core" "iterator-seq" (letrec ((iterator-seq (lambda (i) (let fnrec4688 ((i i)) (jolt-seq i))))) iterator-seq))) + (def-var! "clojure.core" "ensure-reduced" (letrec ((ensure-reduced (lambda (x) (let fnrec3949 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") x)) x (jolt-invoke (var-deref "clojure.core" "reduced") x)))))) ensure-reduced))) (guard (e (#t #f)) - (def-var! "clojure.core" "promise" (letrec ((promise (lambda () (let fnrec4689 () (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil))))) promise))) + (def-var! "clojure.core" "halt-when" (letrec ((halt-when (case-lambda ((pred) (let fnrec3950 ((pred pred)) (jolt-invoke halt-when pred jolt-nil))) ((pred retf) (let fnrec3951 ((pred pred) (retf retf)) (lambda (rf) (let fnrec3952 ((rf rf)) (case-lambda (() (let fnrec3953 () (jolt-invoke rf))) ((result) (let fnrec3954 ((result result)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") result))) (if (jolt-truthy? and__25__auto) (jolt-contains? result (keyword "clojure.core" "halt")) and__25__auto))) (jolt-get result (keyword "clojure.core" "halt")) (jolt-invoke rf result)))) ((result input) (let fnrec3955 ((result result) (input input)) (if (jolt-truthy? (jolt-invoke pred input)) (jolt-invoke (var-deref "clojure.core" "reduced") (jolt-hash-map (keyword "clojure.core" "halt") (if (jolt-truthy? retf) (jolt-invoke retf (jolt-invoke rf result) input) input))) (jolt-invoke rf result input)))))))))))) halt-when))) (guard (e (#t #f)) - (def-var! "clojure.core" "deliver" (letrec ((deliver (lambda (p v) (let fnrec4690 ((p p) (v v)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") p v) p))))) deliver))) + (def-var! "clojure.core" "parse-boolean" (letrec ((parse-boolean (lambda (s) (let fnrec3956 ((s s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") s)) (if (jolt= s "true") #t (if (jolt= s "false") #f (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))) (jolt-throw (jolt-invoke (var-deref "clojure.core" "str") "parse-boolean requires a string, got: " s))))))) parse-boolean))) (guard (e (#t #f)) - (def-var! "clojure.core" "bean" (letrec ((bean (lambda (x) (let fnrec4691 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) x (jolt-hash-map)))))) bean))) + (def-var! "clojure.core" "newline" (letrec ((newline (lambda () (let fnrec3957 () (begin (jolt-invoke (var-deref "clojure.core" "print") "\n") jolt-nil))))) newline))) (guard (e (#t #f)) - (def-var! "clojure.core" "uri?" (letrec ((uri? (lambda (x) (let fnrec4692 ((x x)) #f)))) uri?))) + (def-var! "clojure.core" "seque" (letrec ((seque (case-lambda ((s) (let fnrec3958 ((s s)) s)) ((n-or-q s) (let fnrec3959 ((n-or-q n-or-q) (s s)) s))))) seque))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "special-syms" (let* ((_o$4693 (jolt-symbol #f "if")) (_o$4694 (jolt-symbol #f "do")) (_o$4695 (jolt-symbol #f "let*")) (_o$4696 (jolt-symbol #f "fn*")) (_o$4697 (jolt-symbol #f "quote")) (_o$4698 (jolt-symbol #f "var")) (_o$4699 (jolt-symbol #f "def")) (_o$4700 (jolt-symbol #f "loop*")) (_o$4701 (jolt-symbol #f "recur")) (_o$4702 (jolt-symbol #f "throw")) (_o$4703 (jolt-symbol #f "try")) (_o$4704 (jolt-symbol #f "catch")) (_o$4705 (jolt-symbol #f "finally")) (_o$4706 (jolt-symbol #f "new")) (_o$4707 (jolt-symbol #f "set!")) (_o$4708 (jolt-symbol #f ".")) (_o$4709 (jolt-symbol #f "monitor-enter")) (_o$4710 (jolt-symbol #f "monitor-exit")) (_o$4711 (jolt-symbol #f "&")) (_o$4712 (jolt-symbol #f "case*")) (_o$4713 (jolt-symbol #f "deftype*")) (_o$4714 (jolt-symbol #f "letfn*")) (_o$4715 (jolt-symbol #f "reify*"))) (jolt-hash-set _o$4693 _o$4694 _o$4695 _o$4696 _o$4697 _o$4698 _o$4699 _o$4700 _o$4701 _o$4702 _o$4703 _o$4704 _o$4705 _o$4706 _o$4707 _o$4708 _o$4709 _o$4710 _o$4711 _o$4712 _o$4713 _o$4714 _o$4715)) (let* ((_o$4716 (keyword #f "private")) (_o$4717 #t)) (jolt-hash-map _o$4716 _o$4717)))) + (def-var! "clojure.core" "array-seq" (letrec ((array-seq (lambda (arr . _) (let fnrec3960 ((arr arr) (_ (list->cseq _))) (jolt-seq arr))))) array-seq))) (guard (e (#t #f)) - (def-var! "clojure.core" "special-symbol?" (letrec ((special-symbol? (lambda (s) (let fnrec4718 ((s s)) (jolt-contains? (var-deref "clojure.core" "special-syms") s))))) special-symbol?))) + (def-var! "clojure.core" "to-array-2d" (letrec ((to-array-2d (lambda (coll) (let fnrec3961 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "to-array") (jolt-map (var-deref "clojure.core" "to-array") coll)))))) to-array-2d))) (guard (e (#t #f)) - (def-var! "clojure.core" "proxy-mappings" (letrec ((proxy-mappings (lambda (p) (let fnrec4719 ((p p)) (jolt-hash-map))))) proxy-mappings))) + (def-var! "clojure.core" "unchecked-byte" (letrec ((unchecked-byte (lambda (x) (let fnrec3962 ((x x)) (jolt-invoke (var-deref "clojure.core" "bit-and") (jolt-invoke (var-deref "clojure.core" "int") x) 255))))) unchecked-byte))) (guard (e (#t #f)) - (def-var! "clojure.core" "proxy-call-with-super" (letrec ((proxy-call-with-super (lambda (f p meth) (let fnrec4720 ((f f) (p p) (meth meth)) (jolt-invoke f))))) proxy-call-with-super))) + (def-var! "clojure.core" "unchecked-short" (letrec ((unchecked-short (lambda (x) (let fnrec3963 ((x x)) (jolt-invoke (var-deref "clojure.core" "bit-and") (jolt-invoke (var-deref "clojure.core" "int") x) 65535))))) unchecked-short))) (guard (e (#t #f)) - (def-var! "clojure.core" "init-proxy" (letrec ((init-proxy (lambda (p mappings) (let fnrec4721 ((p p) (mappings mappings)) p)))) init-proxy))) + (def-var! "clojure.core" "unchecked-char" (letrec ((unchecked-char (lambda (x) (let fnrec3964 ((x x)) (jolt-invoke (var-deref "clojure.core" "char") (jolt-invoke (var-deref "clojure.core" "bit-and") (jolt-invoke (var-deref "clojure.core" "int") x) 65535)))))) unchecked-char))) (guard (e (#t #f)) - (def-var! "clojure.core" "update-proxy" (letrec ((update-proxy (lambda (p mappings) (let fnrec4722 ((p p) (mappings mappings)) p)))) update-proxy))) + (def-var! "clojure.core" "unchecked-float" (letrec ((unchecked-float (lambda (x) (let fnrec3965 ((x x)) (jolt-invoke (var-deref "clojure.core" "double") x))))) unchecked-float))) (guard (e (#t #f)) - (def-var! "clojure.core" "proxy-super" (letrec ((proxy-super (lambda args (let fnrec4723 ((args (list->cseq args))) (jolt-throw "proxy-super: JVM proxies are not supported in Jolt"))))) proxy-super))) + (def-var! "clojure.core" "unchecked-double" (letrec ((unchecked-double (lambda (x) (let fnrec3966 ((x x)) (jolt-invoke (var-deref "clojure.core" "double") x))))) unchecked-double))) (guard (e (#t #f)) - (def-var! "clojure.core" "construct-proxy" (letrec ((construct-proxy (lambda (c . args) (let fnrec4724 ((c c) (args (list->cseq args))) (jolt-throw "construct-proxy: not supported in Jolt"))))) construct-proxy))) + (def-var! "clojure.core" "transduce" (letrec ((transduce (case-lambda ((xform f coll) (let fnrec3967 ((xform xform) (f f) (coll coll)) (jolt-invoke transduce xform f (jolt-invoke f) coll))) ((xform f init coll) (let fnrec3968 ((xform xform) (f f) (init init) (coll coll)) (let* ((xf (jolt-invoke xform f))) (jolt-invoke xf (jolt-reduce xf init coll)))))))) transduce))) (guard (e (#t #f)) - (def-var! "clojure.core" "get-proxy-class" (letrec ((get-proxy-class (lambda interfaces (let fnrec4725 ((interfaces (list->cseq interfaces))) (jolt-throw "get-proxy-class: not supported in Jolt"))))) get-proxy-class))) + (def-var! "clojure.core" "eduction" (letrec ((eduction (lambda args (let fnrec3969 ((args (list->cseq args))) (let* ((coll (jolt-last args)) (xforms (jolt-invoke (var-deref "clojure.core" "butlast") args))) (if (jolt-truthy? xforms) (let* ((_a$3970 jolt-into) (_a$3971 (jolt-vector)) (_a$3972 (jolt-apply (var-deref "clojure.core" "comp") xforms)) (_a$3973 coll)) (jolt-invoke _a$3970 _a$3971 _a$3972 _a$3973)) (jolt-into (jolt-vector) coll))))))) eduction))) (guard (e (#t #f)) - (def-var! "clojure.core" "requiring-resolve" (letrec ((requiring-resolve (lambda (sym) (let fnrec4726 ((sym sym)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "qualified-symbol?") sym)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "resolve") sym))) (if (jolt-truthy? or__26__auto) or__26__auto (begin (jolt-invoke (var-deref "clojure.core" "require") (jolt-invoke (var-deref "clojure.core" "symbol") (jolt-invoke (var-deref "clojure.core" "namespace") sym))) (jolt-invoke (var-deref "clojure.core" "resolve") sym)))) (jolt-throw (host-new "IllegalArgumentException" (jolt-invoke (var-deref "clojure.core" "str") "Not a qualified symbol: " sym)))))))) requiring-resolve))) + (def-var! "clojure.core" "->Eduction" (letrec ((->Eduction (lambda (xform coll) (let fnrec3974 ((xform xform) (coll coll)) (jolt-invoke jolt-into (jolt-vector) xform coll))))) ->Eduction))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sfield" (letrec ((sfield (lambda (sc k) (let fnrec2750 ((sc sc) (k k)) (jolt-invoke (var-deref "jolt.host" "ref-get") sc k))))) sfield) (let* ((_o$2751 (keyword #f "private")) (_o$2752 #t)) (jolt-hash-map _o$2751 _o$2752)))) + (def-var! "clojure.core" "enumeration-seq" (letrec ((enumeration-seq (lambda (e) (let fnrec3975 ((e e)) (jolt-seq e))))) enumeration-seq))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "fn->cmp" (letrec ((fn->cmp (lambda (f) (let fnrec2753 ((f f)) (lambda (a b) (let fnrec2754 ((a a) (b b)) (let* ((r (jolt-invoke f a b))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") r)) r (if (jolt-truthy? r) -1 (if (jolt-truthy? (jolt-invoke f b a)) 1 0)))))))))) fn->cmp) (let* ((_o$2755 (keyword #f "private")) (_o$2756 #t)) (jolt-hash-map _o$2755 _o$2756)))) + (def-var! "clojure.core" "iterator-seq" (letrec ((iterator-seq (lambda (i) (let fnrec3976 ((i i)) (jolt-seq i))))) iterator-seq))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "the-cmp" (letrec ((the-cmp (lambda (sc) (let fnrec2757 ((sc sc)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "sfield") sc (keyword #f "cmp")))) (if (jolt-truthy? or__26__auto) or__26__auto (var-deref "clojure.core" "compare"))))))) the-cmp) (let* ((_o$2758 (keyword #f "private")) (_o$2759 #t)) (jolt-hash-map _o$2758 _o$2759)))) + (def-var! "clojure.core" "promise" (letrec ((promise (lambda () (let fnrec3977 () (jolt-invoke (var-deref "clojure.core" "atom") jolt-nil))))) promise))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "nd-key" (letrec ((nd-key (lambda (n) (let fnrec2760 ((n n)) (jolt-nth n 1))))) nd-key) (let* ((_o$2761 (keyword #f "private")) (_o$2762 #t)) (jolt-hash-map _o$2761 _o$2762)))) + (def-var! "clojure.core" "deliver" (letrec ((deliver (lambda (p v) (let fnrec3978 ((p p) (v v)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") p v) p))))) deliver))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "nd-val" (letrec ((nd-val (lambda (n) (let fnrec2763 ((n n)) (jolt-nth n 2))))) nd-val) (let* ((_o$2764 (keyword #f "private")) (_o$2765 #t)) (jolt-hash-map _o$2764 _o$2765)))) + (def-var! "clojure.core" "bean" (letrec ((bean (lambda (x) (let fnrec3979 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) x (jolt-hash-map)))))) bean))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "nd-left" (letrec ((nd-left (lambda (n) (let fnrec2766 ((n n)) (jolt-nth n 3))))) nd-left) (let* ((_o$2767 (keyword #f "private")) (_o$2768 #t)) (jolt-hash-map _o$2767 _o$2768)))) + (def-var! "clojure.core" "uri?" (letrec ((uri? (lambda (x) (let fnrec3980 ((x x)) #f)))) uri?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "nd-right" (letrec ((nd-right (lambda (n) (let fnrec2769 ((n n)) (jolt-nth n 4))))) nd-right) (let* ((_o$2770 (keyword #f "private")) (_o$2771 #t)) (jolt-hash-map _o$2770 _o$2771)))) + (def-var-with-meta! "clojure.core" "special-syms" (let* ((_o$3981 (jolt-symbol #f "if")) (_o$3982 (jolt-symbol #f "do")) (_o$3983 (jolt-symbol #f "let*")) (_o$3984 (jolt-symbol #f "fn*")) (_o$3985 (jolt-symbol #f "quote")) (_o$3986 (jolt-symbol #f "var")) (_o$3987 (jolt-symbol #f "def")) (_o$3988 (jolt-symbol #f "loop*")) (_o$3989 (jolt-symbol #f "recur")) (_o$3990 (jolt-symbol #f "throw")) (_o$3991 (jolt-symbol #f "try")) (_o$3992 (jolt-symbol #f "catch")) (_o$3993 (jolt-symbol #f "finally")) (_o$3994 (jolt-symbol #f "new")) (_o$3995 (jolt-symbol #f "set!")) (_o$3996 (jolt-symbol #f ".")) (_o$3997 (jolt-symbol #f "monitor-enter")) (_o$3998 (jolt-symbol #f "monitor-exit"))) (jolt-hash-set _o$3981 _o$3982 _o$3983 _o$3984 _o$3985 _o$3986 _o$3987 _o$3988 _o$3989 _o$3990 _o$3991 _o$3992 _o$3993 _o$3994 _o$3995 _o$3996 _o$3997 _o$3998)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "red?" (letrec ((red? (lambda (n) (let fnrec2772 ((n n)) (let* ((and__25__auto n)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "identical?") (keyword #f "red") (jolt-nth n 0)) and__25__auto)))))) red?) (let* ((_o$2773 (keyword #f "private")) (_o$2774 #t)) (jolt-hash-map _o$2773 _o$2774)))) + (def-var! "clojure.core" "special-symbol?" (letrec ((special-symbol? (lambda (s) (let fnrec3999 ((s s)) (jolt-contains? (var-deref "clojure.core" "special-syms") s))))) special-symbol?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "black?" (letrec ((black? (lambda (n) (let fnrec2775 ((n n)) (let* ((and__25__auto n)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "identical?") (keyword #f "black") (jolt-nth n 0)) and__25__auto)))))) black?) (let* ((_o$2776 (keyword #f "private")) (_o$2777 #t)) (jolt-hash-map _o$2776 _o$2777)))) + (def-var! "clojure.core" "proxy-mappings" (letrec ((proxy-mappings (lambda (p) (let fnrec4000 ((p p)) (jolt-hash-map))))) proxy-mappings))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "mk-red" (letrec ((mk-red (lambda (k v l r) (let fnrec2778 ((k k) (v v) (l l) (r r)) (let* ((_o$2779 (keyword #f "red")) (_o$2780 k) (_o$2781 v) (_o$2782 l) (_o$2783 r)) (jolt-vector _o$2779 _o$2780 _o$2781 _o$2782 _o$2783)))))) mk-red) (let* ((_o$2784 (keyword #f "private")) (_o$2785 #t)) (jolt-hash-map _o$2784 _o$2785)))) + (def-var! "clojure.core" "proxy-call-with-super" (letrec ((proxy-call-with-super (lambda (f p meth) (let fnrec4001 ((f f) (p p) (meth meth)) (jolt-invoke f))))) proxy-call-with-super))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "mk-black" (letrec ((mk-black (lambda (k v l r) (let fnrec2786 ((k k) (v v) (l l) (r r)) (let* ((_o$2787 (keyword #f "black")) (_o$2788 k) (_o$2789 v) (_o$2790 l) (_o$2791 r)) (jolt-vector _o$2787 _o$2788 _o$2789 _o$2790 _o$2791)))))) mk-black) (let* ((_o$2792 (keyword #f "private")) (_o$2793 #t)) (jolt-hash-map _o$2792 _o$2793)))) + (def-var! "clojure.core" "init-proxy" (letrec ((init-proxy (lambda (p mappings) (let fnrec4002 ((p p) (mappings mappings)) p)))) init-proxy))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "blacken" (letrec ((blacken (lambda (n) (let fnrec2794 ((n n)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") n)) (let* ((_o$2795 (keyword #f "black")) (_o$2796 (jolt-invoke (var-deref "clojure.core" "nd-key") n)) (_o$2797 (jolt-invoke (var-deref "clojure.core" "nd-val") n)) (_o$2798 (jolt-invoke (var-deref "clojure.core" "nd-left") n)) (_o$2799 (jolt-invoke (var-deref "clojure.core" "nd-right") n))) (jolt-vector _o$2795 _o$2796 _o$2797 _o$2798 _o$2799)) n))))) blacken) (let* ((_o$2800 (keyword #f "private")) (_o$2801 #t)) (jolt-hash-map _o$2800 _o$2801)))) + (def-var! "clojure.core" "update-proxy" (letrec ((update-proxy (lambda (p mappings) (let fnrec4003 ((p p) (mappings mappings)) p)))) update-proxy))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "redden" (letrec ((redden (lambda (n) (let fnrec2802 ((n n)) (let* ((_o$2803 (keyword #f "red")) (_o$2804 (jolt-invoke (var-deref "clojure.core" "nd-key") n)) (_o$2805 (jolt-invoke (var-deref "clojure.core" "nd-val") n)) (_o$2806 (jolt-invoke (var-deref "clojure.core" "nd-left") n)) (_o$2807 (jolt-invoke (var-deref "clojure.core" "nd-right") n))) (jolt-vector _o$2803 _o$2804 _o$2805 _o$2806 _o$2807)))))) redden) (let* ((_o$2808 (keyword #f "private")) (_o$2809 #t)) (jolt-hash-map _o$2808 _o$2809)))) + (def-var! "clojure.core" "proxy-super" (letrec ((proxy-super (lambda args (let fnrec4004 ((args (list->cseq args))) (jolt-throw "proxy-super: JVM proxies are not supported in Jolt"))))) proxy-super))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "replace-node" (letrec ((replace-node (lambda (n k v l r) (let fnrec2810 ((n n) (k k) (v v) (l l) (r r)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") n)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v l r) (jolt-invoke (var-deref "clojure.core" "mk-black") k v l r)))))) replace-node) (let* ((_o$2811 (keyword #f "private")) (_o$2812 #t)) (jolt-hash-map _o$2811 _o$2812)))) + (def-var! "clojure.core" "construct-proxy" (letrec ((construct-proxy (lambda (c . args) (let fnrec4005 ((c c) (args (list->cseq args))) (jolt-throw "construct-proxy: not supported in Jolt"))))) construct-proxy))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ins-balance-left" (letrec ((ins-balance-left (lambda (ins parent) (let fnrec2813 ((ins ins) (parent parent)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((l (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (r (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") l)) (let* ((_a$2819 (var-deref "clojure.core" "mk-red")) (_a$2820 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2821 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2822 (jolt-invoke (var-deref "clojure.core" "blacken") l)) (_a$2823 (let* ((_a$2814 (var-deref "clojure.core" "mk-black")) (_a$2815 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2816 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2817 r) (_a$2818 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2814 _a$2815 _a$2816 _a$2817 _a$2818)))) (jolt-invoke _a$2819 _a$2820 _a$2821 _a$2822 _a$2823)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") r)) (let* ((_a$2834 (var-deref "clojure.core" "mk-red")) (_a$2835 (jolt-invoke (var-deref "clojure.core" "nd-key") r)) (_a$2836 (jolt-invoke (var-deref "clojure.core" "nd-val") r)) (_a$2837 (let* ((_a$2824 (var-deref "clojure.core" "mk-black")) (_a$2825 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2826 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2827 l) (_a$2828 (jolt-invoke (var-deref "clojure.core" "nd-left") r))) (jolt-invoke _a$2824 _a$2825 _a$2826 _a$2827 _a$2828))) (_a$2838 (let* ((_a$2829 (var-deref "clojure.core" "mk-black")) (_a$2830 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2831 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2832 (jolt-invoke (var-deref "clojure.core" "nd-right") r)) (_a$2833 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2829 _a$2830 _a$2831 _a$2832 _a$2833)))) (jolt-invoke _a$2834 _a$2835 _a$2836 _a$2837 _a$2838)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2839 (var-deref "clojure.core" "mk-black")) (_a$2840 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2841 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2842 ins) (_a$2843 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2839 _a$2840 _a$2841 _a$2842 _a$2843)) jolt-nil)))) (let* ((_a$2844 (var-deref "clojure.core" "mk-black")) (_a$2845 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2846 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2847 ins) (_a$2848 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2844 _a$2845 _a$2846 _a$2847 _a$2848))))))) ins-balance-left) (let* ((_o$2849 (keyword #f "private")) (_o$2850 #t)) (jolt-hash-map _o$2849 _o$2850)))) + (def-var! "clojure.core" "get-proxy-class" (letrec ((get-proxy-class (lambda interfaces (let fnrec4006 ((interfaces (list->cseq interfaces))) (jolt-throw "get-proxy-class: not supported in Jolt"))))) get-proxy-class))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ins-balance-right" (letrec ((ins-balance-right (lambda (ins parent) (let fnrec2851 ((ins ins) (parent parent)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((l (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (r (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") r)) (let* ((_a$2857 (var-deref "clojure.core" "mk-red")) (_a$2858 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2859 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2860 (let* ((_a$2852 (var-deref "clojure.core" "mk-black")) (_a$2853 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2854 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2855 (jolt-invoke (var-deref "clojure.core" "nd-left") parent)) (_a$2856 l)) (jolt-invoke _a$2852 _a$2853 _a$2854 _a$2855 _a$2856))) (_a$2861 (jolt-invoke (var-deref "clojure.core" "blacken") r))) (jolt-invoke _a$2857 _a$2858 _a$2859 _a$2860 _a$2861)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") l)) (let* ((_a$2872 (var-deref "clojure.core" "mk-red")) (_a$2873 (jolt-invoke (var-deref "clojure.core" "nd-key") l)) (_a$2874 (jolt-invoke (var-deref "clojure.core" "nd-val") l)) (_a$2875 (let* ((_a$2862 (var-deref "clojure.core" "mk-black")) (_a$2863 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2864 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2865 (jolt-invoke (var-deref "clojure.core" "nd-left") parent)) (_a$2866 (jolt-invoke (var-deref "clojure.core" "nd-left") l))) (jolt-invoke _a$2862 _a$2863 _a$2864 _a$2865 _a$2866))) (_a$2876 (let* ((_a$2867 (var-deref "clojure.core" "mk-black")) (_a$2868 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2869 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2870 (jolt-invoke (var-deref "clojure.core" "nd-right") l)) (_a$2871 r)) (jolt-invoke _a$2867 _a$2868 _a$2869 _a$2870 _a$2871)))) (jolt-invoke _a$2872 _a$2873 _a$2874 _a$2875 _a$2876)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2877 (var-deref "clojure.core" "mk-black")) (_a$2878 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2879 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2880 (jolt-invoke (var-deref "clojure.core" "nd-left") parent)) (_a$2881 ins)) (jolt-invoke _a$2877 _a$2878 _a$2879 _a$2880 _a$2881)) jolt-nil)))) (let* ((_a$2882 (var-deref "clojure.core" "mk-black")) (_a$2883 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2884 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2885 (jolt-invoke (var-deref "clojure.core" "nd-left") parent)) (_a$2886 ins)) (jolt-invoke _a$2882 _a$2883 _a$2884 _a$2885 _a$2886))))))) ins-balance-right) (let* ((_o$2887 (keyword #f "private")) (_o$2888 #t)) (jolt-hash-map _o$2887 _o$2888)))) + (def-var! "clojure.core" "sfield" (letrec ((sfield (lambda (sc k) (let fnrec2301 ((sc sc) (k k)) (jolt-invoke (var-deref "jolt.host" "ref-get") sc k))))) sfield))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "add-left" (letrec ((add-left (lambda (parent ins) (let fnrec2889 ((parent parent) (ins ins)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") parent)) (let* ((_a$2890 (var-deref "clojure.core" "mk-red")) (_a$2891 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2892 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2893 ins) (_a$2894 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2890 _a$2891 _a$2892 _a$2893 _a$2894)) (jolt-invoke (var-deref "clojure.core" "ins-balance-left") ins parent)))))) add-left) (let* ((_o$2895 (keyword #f "private")) (_o$2896 #t)) (jolt-hash-map _o$2895 _o$2896)))) + (def-var! "clojure.core" "fn->cmp" (letrec ((fn->cmp (lambda (f) (let fnrec2302 ((f f)) (lambda (a b) (let fnrec2303 ((a a) (b b)) (let* ((r (jolt-invoke f a b))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") r)) r (if (jolt-truthy? r) -1 (if (jolt-truthy? (jolt-invoke f b a)) 1 0)))))))))) fn->cmp))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "add-right" (letrec ((add-right (lambda (parent ins) (let fnrec2897 ((parent parent) (ins ins)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") parent)) (let* ((_a$2898 (var-deref "clojure.core" "mk-red")) (_a$2899 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2900 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2901 (jolt-invoke (var-deref "clojure.core" "nd-left") parent)) (_a$2902 ins)) (jolt-invoke _a$2898 _a$2899 _a$2900 _a$2901 _a$2902)) (jolt-invoke (var-deref "clojure.core" "ins-balance-right") ins parent)))))) add-right) (let* ((_o$2903 (keyword #f "private")) (_o$2904 #t)) (jolt-hash-map _o$2903 _o$2904)))) + (def-var! "clojure.core" "the-cmp" (letrec ((the-cmp (lambda (sc) (let fnrec2304 ((sc sc)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "sfield") sc (keyword #f "cmp")))) (if (jolt-truthy? or__26__auto) or__26__auto (var-deref "clojure.core" "compare"))))))) the-cmp))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-ins" (letrec ((tree-ins (lambda (cmp tree k v) (let fnrec2905 ((cmp cmp) (tree tree) (k k) (v v)) (if (jolt-nil? tree) (jolt-invoke (var-deref "clojure.core" "mk-red") k v jolt-nil jolt-nil) (if (jolt-neg? (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") tree))) (jolt-invoke (var-deref "clojure.core" "add-left") tree (tree-ins cmp (jolt-invoke (var-deref "clojure.core" "nd-left") tree) k v)) (jolt-invoke (var-deref "clojure.core" "add-right") tree (tree-ins cmp (jolt-invoke (var-deref "clojure.core" "nd-right") tree) k v)))))))) tree-ins) (let* ((_o$2906 (keyword #f "private")) (_o$2907 #t)) (jolt-hash-map _o$2906 _o$2907)))) + (def-var! "clojure.core" "nd-key" (letrec ((nd-key (lambda (n) (let fnrec2305 ((n n)) (jolt-nth n 1))))) nd-key))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-replace" (letrec ((tree-replace (lambda (cmp tree k v) (let fnrec2908 ((cmp cmp) (tree tree) (k k) (v v)) (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") tree)))) (if (jolt-zero? c) (let* ((_a$2909 (var-deref "clojure.core" "replace-node")) (_a$2910 tree) (_a$2911 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2912 v) (_a$2913 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2914 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2909 _a$2910 _a$2911 _a$2912 _a$2913 _a$2914)) (if (jolt-neg? c) (let* ((_a$2915 (var-deref "clojure.core" "replace-node")) (_a$2916 tree) (_a$2917 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2918 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2919 (tree-replace cmp (jolt-invoke (var-deref "clojure.core" "nd-left") tree) k v)) (_a$2920 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2915 _a$2916 _a$2917 _a$2918 _a$2919 _a$2920)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2921 (var-deref "clojure.core" "replace-node")) (_a$2922 tree) (_a$2923 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2924 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2925 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2926 (tree-replace cmp (jolt-invoke (var-deref "clojure.core" "nd-right") tree) k v))) (jolt-invoke _a$2921 _a$2922 _a$2923 _a$2924 _a$2925 _a$2926)) jolt-nil)))))))) tree-replace) (let* ((_o$2927 (keyword #f "private")) (_o$2928 #t)) (jolt-hash-map _o$2927 _o$2928)))) + (def-var! "clojure.core" "nd-val" (letrec ((nd-val (lambda (n) (let fnrec2306 ((n n)) (jolt-nth n 2))))) nd-val))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-lookup" (letrec ((tree-lookup (lambda (tree cmp k) (let fnrec2929 ((tree tree) (cmp cmp) (k k)) (let* ((t tree)) (let loop2930 ((t t)) (if (jolt-nil? t) jolt-nil (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") t)))) (if (jolt-zero? c) t (if (jolt-neg? c) (loop2930 (jolt-invoke (var-deref "clojure.core" "nd-left") t)) (if (jolt-truthy? (keyword #f "else")) (loop2930 (jolt-invoke (var-deref "clojure.core" "nd-right") t)) jolt-nil))))))))))) tree-lookup) (let* ((_o$2931 (keyword #f "private")) (_o$2932 #t)) (jolt-hash-map _o$2931 _o$2932)))) + (def-var! "clojure.core" "nd-left" (letrec ((nd-left (lambda (n) (let fnrec2307 ((n n)) (jolt-nth n 3))))) nd-left))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "balance-left" (letrec ((balance-left (lambda (k v ins right) (let fnrec2933 ((k k) (v v) (ins ins) (right right)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((il (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (ir (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") il)) (let* ((_a$2934 (var-deref "clojure.core" "mk-red")) (_a$2935 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2936 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2937 (jolt-invoke (var-deref "clojure.core" "blacken") il)) (_a$2938 (jolt-invoke (var-deref "clojure.core" "mk-black") k v ir right))) (jolt-invoke _a$2934 _a$2935 _a$2936 _a$2937 _a$2938)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ir)) (let* ((_a$2944 (var-deref "clojure.core" "mk-red")) (_a$2945 (jolt-invoke (var-deref "clojure.core" "nd-key") ir)) (_a$2946 (jolt-invoke (var-deref "clojure.core" "nd-val") ir)) (_a$2947 (let* ((_a$2939 (var-deref "clojure.core" "mk-black")) (_a$2940 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2941 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2942 il) (_a$2943 (jolt-invoke (var-deref "clojure.core" "nd-left") ir))) (jolt-invoke _a$2939 _a$2940 _a$2941 _a$2942 _a$2943))) (_a$2948 (jolt-invoke (var-deref "clojure.core" "mk-black") k v (jolt-invoke (var-deref "clojure.core" "nd-right") ir) right))) (jolt-invoke _a$2944 _a$2945 _a$2946 _a$2947 _a$2948)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "mk-black") k v ins right) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "mk-black") k v ins right)))))) balance-left) (let* ((_o$2949 (keyword #f "private")) (_o$2950 #t)) (jolt-hash-map _o$2949 _o$2950)))) + (def-var! "clojure.core" "nd-right" (letrec ((nd-right (lambda (n) (let fnrec2308 ((n n)) (jolt-nth n 4))))) nd-right))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "balance-right" (letrec ((balance-right (lambda (k v left ins) (let fnrec2951 ((k k) (v v) (left left) (ins ins)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((il (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (ir (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ir)) (let* ((_a$2952 (var-deref "clojure.core" "mk-red")) (_a$2953 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2954 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2955 (jolt-invoke (var-deref "clojure.core" "mk-black") k v left il)) (_a$2956 (jolt-invoke (var-deref "clojure.core" "blacken") ir))) (jolt-invoke _a$2952 _a$2953 _a$2954 _a$2955 _a$2956)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") il)) (let* ((_a$2962 (var-deref "clojure.core" "mk-red")) (_a$2963 (jolt-invoke (var-deref "clojure.core" "nd-key") il)) (_a$2964 (jolt-invoke (var-deref "clojure.core" "nd-val") il)) (_a$2965 (jolt-invoke (var-deref "clojure.core" "mk-black") k v left (jolt-invoke (var-deref "clojure.core" "nd-left") il))) (_a$2966 (let* ((_a$2957 (var-deref "clojure.core" "mk-black")) (_a$2958 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2959 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2960 (jolt-invoke (var-deref "clojure.core" "nd-right") il)) (_a$2961 ir)) (jolt-invoke _a$2957 _a$2958 _a$2959 _a$2960 _a$2961)))) (jolt-invoke _a$2962 _a$2963 _a$2964 _a$2965 _a$2966)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "mk-black") k v left ins) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "mk-black") k v left ins)))))) balance-right) (let* ((_o$2967 (keyword #f "private")) (_o$2968 #t)) (jolt-hash-map _o$2967 _o$2968)))) + (def-var! "clojure.core" "red?" (letrec ((red? (lambda (n) (let fnrec2309 ((n n)) (let* ((and__25__auto n)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "identical?") (keyword #f "red") (jolt-nth n 0)) and__25__auto)))))) red?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "balance-left-del" (letrec ((balance-left-del (lambda (k v del right) (let fnrec2969 ((k k) (v v) (del del) (right right)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") del)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v (jolt-invoke (var-deref "clojure.core" "blacken") del) right) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") right)) (jolt-invoke (var-deref "clojure.core" "balance-right") k v del (jolt-invoke (var-deref "clojure.core" "redden") right)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "red?") right))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-left") right)) and__25__auto))) (let* ((_a$2975 (var-deref "clojure.core" "mk-red")) (_a$2976 (jolt-invoke (var-deref "clojure.core" "nd-key") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2977 (jolt-invoke (var-deref "clojure.core" "nd-val") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2978 (jolt-invoke (var-deref "clojure.core" "mk-black") k v del (jolt-invoke (var-deref "clojure.core" "nd-left") (jolt-invoke (var-deref "clojure.core" "nd-left") right)))) (_a$2979 (let* ((_a$2970 (var-deref "clojure.core" "balance-right")) (_a$2971 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2972 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2973 (jolt-invoke (var-deref "clojure.core" "nd-right") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2974 (jolt-invoke (var-deref "clojure.core" "redden") (jolt-invoke (var-deref "clojure.core" "nd-right") right)))) (jolt-invoke _a$2970 _a$2971 _a$2972 _a$2973 _a$2974)))) (jolt-invoke _a$2975 _a$2976 _a$2977 _a$2978 _a$2979)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "red-black tree invariant violation" (jolt-hash-map))) jolt-nil)))))))) balance-left-del) (let* ((_o$2980 (keyword #f "private")) (_o$2981 #t)) (jolt-hash-map _o$2980 _o$2981)))) + (def-var! "clojure.core" "black?" (letrec ((black? (lambda (n) (let fnrec2310 ((n n)) (let* ((and__25__auto n)) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "identical?") (keyword #f "black") (jolt-nth n 0)) and__25__auto)))))) black?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "balance-right-del" (letrec ((balance-right-del (lambda (k v left del) (let fnrec2982 ((k k) (v v) (left left) (del del)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") del)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v left (jolt-invoke (var-deref "clojure.core" "blacken") del)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") left)) (jolt-invoke (var-deref "clojure.core" "balance-left") k v (jolt-invoke (var-deref "clojure.core" "redden") left) del) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "red?") left))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-right") left)) and__25__auto))) (let* ((_a$2988 (var-deref "clojure.core" "mk-red")) (_a$2989 (jolt-invoke (var-deref "clojure.core" "nd-key") (jolt-invoke (var-deref "clojure.core" "nd-right") left))) (_a$2990 (jolt-invoke (var-deref "clojure.core" "nd-val") (jolt-invoke (var-deref "clojure.core" "nd-right") left))) (_a$2991 (let* ((_a$2983 (var-deref "clojure.core" "balance-left")) (_a$2984 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2985 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2986 (jolt-invoke (var-deref "clojure.core" "redden") (jolt-invoke (var-deref "clojure.core" "nd-left") left))) (_a$2987 (jolt-invoke (var-deref "clojure.core" "nd-left") (jolt-invoke (var-deref "clojure.core" "nd-right") left)))) (jolt-invoke _a$2983 _a$2984 _a$2985 _a$2986 _a$2987))) (_a$2992 (jolt-invoke (var-deref "clojure.core" "mk-black") k v (jolt-invoke (var-deref "clojure.core" "nd-right") (jolt-invoke (var-deref "clojure.core" "nd-right") left)) del))) (jolt-invoke _a$2988 _a$2989 _a$2990 _a$2991 _a$2992)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "red-black tree invariant violation" (jolt-hash-map))) jolt-nil)))))))) balance-right-del) (let* ((_o$2993 (keyword #f "private")) (_o$2994 #t)) (jolt-hash-map _o$2993 _o$2994)))) + (def-var! "clojure.core" "mk-red" (letrec ((mk-red (lambda (k v l r) (let fnrec2311 ((k k) (v v) (l l) (r r)) (let* ((_o$2312 (keyword #f "red")) (_o$2313 k) (_o$2314 v) (_o$2315 l) (_o$2316 r)) (jolt-vector _o$2312 _o$2313 _o$2314 _o$2315 _o$2316)))))) mk-red))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-append" (letrec ((tree-append (lambda (left right) (let fnrec2995 ((left left) (right right)) (if (jolt-nil? left) right (if (jolt-nil? right) left (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") left)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") right)) (let* ((app (let* ((_a$2996 (jolt-invoke (var-deref "clojure.core" "nd-right") left)) (_a$2997 (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (tree-append _a$2996 _a$2997)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") app)) (let* ((_a$3008 (var-deref "clojure.core" "mk-red")) (_a$3009 (jolt-invoke (var-deref "clojure.core" "nd-key") app)) (_a$3010 (jolt-invoke (var-deref "clojure.core" "nd-val") app)) (_a$3011 (let* ((_a$2998 (var-deref "clojure.core" "mk-red")) (_a$2999 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$3000 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$3001 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$3002 (jolt-invoke (var-deref "clojure.core" "nd-left") app))) (jolt-invoke _a$2998 _a$2999 _a$3000 _a$3001 _a$3002))) (_a$3012 (let* ((_a$3003 (var-deref "clojure.core" "mk-red")) (_a$3004 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$3005 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$3006 (jolt-invoke (var-deref "clojure.core" "nd-right") app)) (_a$3007 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$3003 _a$3004 _a$3005 _a$3006 _a$3007)))) (jolt-invoke _a$3008 _a$3009 _a$3010 _a$3011 _a$3012)) (let* ((_a$3018 (var-deref "clojure.core" "mk-red")) (_a$3019 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$3020 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$3021 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$3022 (let* ((_a$3013 (var-deref "clojure.core" "mk-red")) (_a$3014 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$3015 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$3016 app) (_a$3017 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$3013 _a$3014 _a$3015 _a$3016 _a$3017)))) (jolt-invoke _a$3018 _a$3019 _a$3020 _a$3021 _a$3022)))) (let* ((_a$3023 (var-deref "clojure.core" "mk-red")) (_a$3024 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$3025 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$3026 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$3027 (tree-append (jolt-invoke (var-deref "clojure.core" "nd-right") left) right))) (jolt-invoke _a$3023 _a$3024 _a$3025 _a$3026 _a$3027))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") right)) (let* ((_a$3028 (var-deref "clojure.core" "mk-red")) (_a$3029 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$3030 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$3031 (tree-append left (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$3032 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$3028 _a$3029 _a$3030 _a$3031 _a$3032)) (if (jolt-truthy? (keyword #f "else")) (let* ((app (let* ((_a$3033 (jolt-invoke (var-deref "clojure.core" "nd-right") left)) (_a$3034 (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (tree-append _a$3033 _a$3034)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") app)) (let* ((_a$3045 (var-deref "clojure.core" "mk-red")) (_a$3046 (jolt-invoke (var-deref "clojure.core" "nd-key") app)) (_a$3047 (jolt-invoke (var-deref "clojure.core" "nd-val") app)) (_a$3048 (let* ((_a$3035 (var-deref "clojure.core" "mk-black")) (_a$3036 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$3037 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$3038 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$3039 (jolt-invoke (var-deref "clojure.core" "nd-left") app))) (jolt-invoke _a$3035 _a$3036 _a$3037 _a$3038 _a$3039))) (_a$3049 (let* ((_a$3040 (var-deref "clojure.core" "mk-black")) (_a$3041 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$3042 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$3043 (jolt-invoke (var-deref "clojure.core" "nd-right") app)) (_a$3044 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$3040 _a$3041 _a$3042 _a$3043 _a$3044)))) (jolt-invoke _a$3045 _a$3046 _a$3047 _a$3048 _a$3049)) (let* ((_a$3055 (var-deref "clojure.core" "balance-left-del")) (_a$3056 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$3057 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$3058 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$3059 (let* ((_a$3050 (var-deref "clojure.core" "mk-black")) (_a$3051 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$3052 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$3053 app) (_a$3054 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$3050 _a$3051 _a$3052 _a$3053 _a$3054)))) (jolt-invoke _a$3055 _a$3056 _a$3057 _a$3058 _a$3059)))) jolt-nil))))))))) tree-append) (let* ((_o$3060 (keyword #f "private")) (_o$3061 #t)) (jolt-hash-map _o$3060 _o$3061)))) + (def-var! "clojure.core" "mk-black" (letrec ((mk-black (lambda (k v l r) (let fnrec2317 ((k k) (v v) (l l) (r r)) (let* ((_o$2318 (keyword #f "black")) (_o$2319 k) (_o$2320 v) (_o$2321 l) (_o$2322 r)) (jolt-vector _o$2318 _o$2319 _o$2320 _o$2321 _o$2322)))))) mk-black))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-del" (letrec ((tree-del (lambda (cmp tree k) (let fnrec3062 ((cmp cmp) (tree tree) (k k)) (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") tree)))) (if (jolt-zero? c) (let* ((_a$3063 (var-deref "clojure.core" "tree-append")) (_a$3064 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$3065 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$3063 _a$3064 _a$3065)) (if (jolt-neg? c) (let* ((del (tree-del cmp (jolt-invoke (var-deref "clojure.core" "nd-left") tree) k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-left") tree))) (let* ((_a$3066 (var-deref "clojure.core" "balance-left-del")) (_a$3067 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$3068 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$3069 del) (_a$3070 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$3066 _a$3067 _a$3068 _a$3069 _a$3070)) (let* ((_a$3071 (var-deref "clojure.core" "mk-red")) (_a$3072 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$3073 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$3074 del) (_a$3075 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$3071 _a$3072 _a$3073 _a$3074 _a$3075)))) (if (jolt-truthy? (keyword #f "else")) (let* ((del (tree-del cmp (jolt-invoke (var-deref "clojure.core" "nd-right") tree) k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (let* ((_a$3076 (var-deref "clojure.core" "balance-right-del")) (_a$3077 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$3078 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$3079 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$3080 del)) (jolt-invoke _a$3076 _a$3077 _a$3078 _a$3079 _a$3080)) (let* ((_a$3081 (var-deref "clojure.core" "mk-red")) (_a$3082 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$3083 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$3084 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$3085 del)) (jolt-invoke _a$3081 _a$3082 _a$3083 _a$3084 _a$3085)))) jolt-nil)))))))) tree-del) (let* ((_o$3086 (keyword #f "private")) (_o$3087 #t)) (jolt-hash-map _o$3086 _o$3087)))) + (def-var! "clojure.core" "blacken" (letrec ((blacken (lambda (n) (let fnrec2323 ((n n)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") n)) (let* ((_o$2324 (keyword #f "black")) (_o$2325 (jolt-invoke (var-deref "clojure.core" "nd-key") n)) (_o$2326 (jolt-invoke (var-deref "clojure.core" "nd-val") n)) (_o$2327 (jolt-invoke (var-deref "clojure.core" "nd-left") n)) (_o$2328 (jolt-invoke (var-deref "clojure.core" "nd-right") n))) (jolt-vector _o$2324 _o$2325 _o$2326 _o$2327 _o$2328)) n))))) blacken))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "tree-collect" (letrec ((tree-collect (lambda (t proj acc) (let fnrec3088 ((t t) (proj proj) (acc acc)) (if (jolt-nil? t) acc (let* ((_a$3091 (jolt-invoke (var-deref "clojure.core" "nd-right") t)) (_a$3092 proj) (_a$3093 (let* ((_a$3089 (tree-collect (jolt-invoke (var-deref "clojure.core" "nd-left") t) proj acc)) (_a$3090 (jolt-invoke proj t))) (jolt-conj _a$3089 _a$3090)))) (tree-collect _a$3091 _a$3092 _a$3093))))))) tree-collect) (let* ((_o$3094 (keyword #f "private")) (_o$3095 #t)) (jolt-hash-map _o$3094 _o$3095)))) + (def-var! "clojure.core" "redden" (letrec ((redden (lambda (n) (let fnrec2329 ((n n)) (let* ((_o$2330 (keyword #f "red")) (_o$2331 (jolt-invoke (var-deref "clojure.core" "nd-key") n)) (_o$2332 (jolt-invoke (var-deref "clojure.core" "nd-val") n)) (_o$2333 (jolt-invoke (var-deref "clojure.core" "nd-left") n)) (_o$2334 (jolt-invoke (var-deref "clojure.core" "nd-right") n))) (jolt-vector _o$2330 _o$2331 _o$2332 _o$2333 _o$2334)))))) redden))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "make-sorted" (letrec ((make-sorted (lambda (tag tree cnt cmp ops) (let fnrec3096 ((tag tag) (tree tree) (cnt cnt) (cmp cmp) (ops ops)) (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "tagged-table") tag) (keyword #f "tree") tree) (keyword #f "cnt") cnt) (keyword #f "cmp") cmp) (keyword #f "ops") ops))))) make-sorted) (let* ((_o$3097 (keyword #f "private")) (_o$3098 #t)) (jolt-hash-map _o$3097 _o$3098)))) + (def-var! "clojure.core" "replace-node" (letrec ((replace-node (lambda (n k v l r) (let fnrec2335 ((n n) (k k) (v v) (l l) (r r)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") n)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v l r) (jolt-invoke (var-deref "clojure.core" "mk-black") k v l r)))))) replace-node))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sc-entries" (letrec ((sc-entries (lambda (sc proj) (let fnrec3099 ((sc sc) (proj proj)) (let* ((_a$3100 (var-deref "clojure.core" "tree-collect")) (_a$3101 (jolt-invoke (var-deref "clojure.core" "sfield") sc (keyword #f "tree"))) (_a$3102 proj) (_a$3103 (jolt-vector))) (jolt-invoke _a$3100 _a$3101 _a$3102 _a$3103)))))) sc-entries) (let* ((_o$3104 (keyword #f "private")) (_o$3105 #t)) (jolt-hash-map _o$3104 _o$3105)))) + (def-var! "clojure.core" "ins-balance-left" (letrec ((ins-balance-left (lambda (ins parent) (let fnrec2336 ((ins ins) (parent parent)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((l (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (r (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") l)) (let* ((_a$2342 (var-deref "clojure.core" "mk-red")) (_a$2343 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2344 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2345 (jolt-invoke (var-deref "clojure.core" "blacken") l)) (_a$2346 (let* ((_a$2337 (var-deref "clojure.core" "mk-black")) (_a$2338 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2339 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2340 r) (_a$2341 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2337 _a$2338 _a$2339 _a$2340 _a$2341)))) (jolt-invoke _a$2342 _a$2343 _a$2344 _a$2345 _a$2346)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") r)) (let* ((_a$2357 (var-deref "clojure.core" "mk-red")) (_a$2358 (jolt-invoke (var-deref "clojure.core" "nd-key") r)) (_a$2359 (jolt-invoke (var-deref "clojure.core" "nd-val") r)) (_a$2360 (let* ((_a$2347 (var-deref "clojure.core" "mk-black")) (_a$2348 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2349 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2350 l) (_a$2351 (jolt-invoke (var-deref "clojure.core" "nd-left") r))) (jolt-invoke _a$2347 _a$2348 _a$2349 _a$2350 _a$2351))) (_a$2361 (let* ((_a$2352 (var-deref "clojure.core" "mk-black")) (_a$2353 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2354 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2355 (jolt-invoke (var-deref "clojure.core" "nd-right") r)) (_a$2356 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2352 _a$2353 _a$2354 _a$2355 _a$2356)))) (jolt-invoke _a$2357 _a$2358 _a$2359 _a$2360 _a$2361)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2362 (var-deref "clojure.core" "mk-black")) (_a$2363 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2364 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2365 ins) (_a$2366 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2362 _a$2363 _a$2364 _a$2365 _a$2366)) jolt-nil)))) (let* ((_a$2367 (var-deref "clojure.core" "mk-black")) (_a$2368 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2369 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2370 ins) (_a$2371 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2367 _a$2368 _a$2369 _a$2370 _a$2371))))))) ins-balance-left))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "map-entry" (letrec ((map-entry (lambda (t) (let fnrec3106 ((t t)) (let* ((_a$3107 (var-deref "jolt.host" "map-entry")) (_a$3108 (jolt-invoke (var-deref "clojure.core" "nd-key") t)) (_a$3109 (jolt-invoke (var-deref "clojure.core" "nd-val") t))) (jolt-invoke _a$3107 _a$3108 _a$3109)))))) map-entry) (let* ((_o$3110 (keyword #f "private")) (_o$3111 #t)) (jolt-hash-map _o$3110 _o$3111)))) + (def-var! "clojure.core" "ins-balance-right" (letrec ((ins-balance-right (lambda (ins parent) (let fnrec2372 ((ins ins) (parent parent)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((l (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (r (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? 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"clojure.core" "sm-get" (letrec ((sm-get (lambda (sm k not-found) (let fnrec3112 ((sm sm) (k k) (not-found not-found)) (let* ((n (let* ((_a$3113 (var-deref "clojure.core" "tree-lookup")) (_a$3114 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (_a$3115 (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (_a$3116 k)) (jolt-invoke _a$3113 _a$3114 _a$3115 _a$3116)))) (if (jolt-nil? n) not-found (jolt-invoke (var-deref "clojure.core" "nd-val") n))))))) sm-get) (let* ((_o$3117 (keyword #f "private")) (_o$3118 #t)) (jolt-hash-map _o$3117 _o$3118)))) + (def-var! "clojure.core" "add-left" (letrec ((add-left (lambda (parent ins) (let fnrec2408 ((parent parent) (ins ins)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") parent)) (let* ((_a$2409 (var-deref "clojure.core" "mk-red")) (_a$2410 (jolt-invoke (var-deref "clojure.core" "nd-key") parent)) (_a$2411 (jolt-invoke (var-deref "clojure.core" "nd-val") parent)) (_a$2412 ins) (_a$2413 (jolt-invoke (var-deref "clojure.core" "nd-right") parent))) (jolt-invoke _a$2409 _a$2410 _a$2411 _a$2412 _a$2413)) (jolt-invoke (var-deref "clojure.core" "ins-balance-left") ins parent)))))) add-left))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sm-assoc-1" (letrec ((sm-assoc-1 (lambda (sm k v) (let fnrec3119 ((sm sm) (k k) (v v)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (node (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp k))) (if (jolt-truthy? (let* ((and__25__auto node)) (if (jolt-truthy? and__25__auto) (jolt= v (jolt-invoke (var-deref "clojure.core" "nd-val") node)) and__25__auto))) sm (if (jolt-truthy? node) (let* ((_a$3120 (var-deref "clojure.core" "make-sorted")) (_a$3121 (keyword "jolt" "sorted-map")) (_a$3122 (jolt-invoke (var-deref "clojure.core" "tree-replace") cmp tree k v)) (_a$3123 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt"))) (_a$3124 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$3125 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$3120 _a$3121 _a$3122 _a$3123 _a$3124 _a$3125)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$3126 (var-deref "clojure.core" "make-sorted")) (_a$3127 (keyword "jolt" "sorted-map")) (_a$3128 (jolt-invoke (var-deref "clojure.core" "blacken") (jolt-invoke (var-deref "clojure.core" "tree-ins") cmp tree k v))) (_a$3129 (jolt-inc (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt")))) (_a$3130 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$3131 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$3126 _a$3127 _a$3128 _a$3129 _a$3130 _a$3131)) jolt-nil)))))))) sm-assoc-1) (let* ((_o$3132 (keyword #f "private")) (_o$3133 #t)) (jolt-hash-map _o$3132 _o$3133)))) + (def-var! "clojure.core" "add-right" (letrec ((add-right (lambda (parent ins) (let fnrec2414 ((parent parent) (ins ins)) (if (jolt-truthy? 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"clojure.core" "sm-assoc-many" (letrec ((sm-assoc-many (lambda (sm kvs) (let fnrec3134 ((sm sm) (kvs kvs)) (let* ((n (jolt-count kvs))) (begin (if (jolt-odd? n) (jolt-throw (jolt-ex-info "sorted-map assoc expects an even number of key/values" (let* ((_o$3135 (keyword #f "count")) (_o$3136 n)) (jolt-hash-map _o$3135 _o$3136)))) jolt-nil) (let* ((m sm) (i 0)) (let loop3137 ((m m) (i i)) (if (jolt-n< i n) (let* ((_a$3142 (let* ((_a$3138 (var-deref "clojure.core" "sm-assoc-1")) (_a$3139 m) (_a$3140 (jolt-nth kvs i)) (_a$3141 (jolt-nth kvs (jolt-inc i)))) (jolt-invoke _a$3138 _a$3139 _a$3140 _a$3141))) (_a$3143 (jolt-n+ i 2))) (loop3137 _a$3142 _a$3143)) m))))))))) sm-assoc-many) (let* ((_o$3144 (keyword #f "private")) (_o$3145 #t)) (jolt-hash-map _o$3144 _o$3145)))) + (def-var! "clojure.core" "tree-ins" (letrec ((tree-ins (lambda (cmp tree k v) (let fnrec2420 ((cmp cmp) (tree tree) (k k) (v v)) (if (jolt-truthy? 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(jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp k)) sm (let* ((t (jolt-invoke (var-deref "clojure.core" "tree-del") cmp tree k))) (let* ((_a$3147 (var-deref "clojure.core" "make-sorted")) (_a$3148 (keyword "jolt" "sorted-map")) (_a$3149 (if (jolt-truthy? t) (jolt-invoke (var-deref "clojure.core" "blacken") t) jolt-nil)) (_a$3150 (jolt-dec (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt")))) (_a$3151 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$3152 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$3147 _a$3148 _a$3149 _a$3150 _a$3151 _a$3152))))))))) sm-dissoc-1) (let* ((_o$3153 (keyword #f "private")) (_o$3154 #t)) (jolt-hash-map _o$3153 _o$3154)))) + (def-var! "clojure.core" "tree-replace" (letrec ((tree-replace (lambda (cmp tree k v) (let fnrec2421 ((cmp cmp) (tree tree) (k k) (v v)) (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") tree)))) (if (jolt-zero? c) (let* ((_a$2422 (var-deref "clojure.core" "replace-node")) (_a$2423 tree) (_a$2424 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2425 v) (_a$2426 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2427 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2422 _a$2423 _a$2424 _a$2425 _a$2426 _a$2427)) (if (jolt-neg? c) (let* ((_a$2428 (var-deref "clojure.core" "replace-node")) (_a$2429 tree) (_a$2430 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2431 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2432 (jolt-invoke tree-replace cmp (jolt-invoke (var-deref "clojure.core" "nd-left") tree) k v)) (_a$2433 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2428 _a$2429 _a$2430 _a$2431 _a$2432 _a$2433)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2434 (var-deref "clojure.core" "replace-node")) (_a$2435 tree) (_a$2436 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2437 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2438 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2439 (jolt-invoke tree-replace cmp (jolt-invoke (var-deref "clojure.core" "nd-right") tree) k v))) (jolt-invoke _a$2434 _a$2435 _a$2436 _a$2437 _a$2438 _a$2439)) jolt-nil)))))))) tree-replace))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sm-dissoc-many" (letrec ((sm-dissoc-many (lambda (sm ks) (let fnrec3155 ((sm sm) (ks ks)) (jolt-reduce (var-deref "clojure.core" "sm-dissoc-1") sm ks))))) sm-dissoc-many) (let* ((_o$3156 (keyword #f "private")) (_o$3157 #t)) (jolt-hash-map _o$3156 _o$3157)))) + (def-var! "clojure.core" "tree-lookup" (letrec ((tree-lookup (lambda (tree cmp k) (let fnrec2440 ((tree tree) (cmp cmp) (k k)) (let* ((t tree)) (let loop2441 ((t t)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") t)) jolt-nil (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") t)))) (if (jolt-zero? c) t (if (jolt-neg? c) (loop2441 (jolt-invoke (var-deref "clojure.core" "nd-left") t)) (if (jolt-truthy? (keyword #f "else")) (loop2441 (jolt-invoke (var-deref "clojure.core" "nd-right") t)) jolt-nil))))))))))) tree-lookup))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sm-conj-1" (letrec ((sm-conj-1 (lambda (sm x) (let fnrec3158 ((sm sm) (x x)) (if (jolt-nil? x) sm (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$3164 (lambda (m e) (let fnrec3159 ((m m) (e e)) (let* ((_a$3160 (var-deref "clojure.core" "sm-assoc-1")) (_a$3161 m) (_a$3162 (jolt-first e)) (_a$3163 (jolt-invoke (var-deref "clojure.core" "second") e))) (jolt-invoke _a$3160 _a$3161 _a$3162 _a$3163))))) (_a$3165 sm) (_a$3166 (jolt-seq x))) (jolt-reduce _a$3164 _a$3165 _a$3166)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count x)) and__25__auto))) (let* ((_a$3167 (var-deref "clojure.core" "sm-assoc-1")) (_a$3168 sm) (_a$3169 (jolt-nth x 0)) (_a$3170 (jolt-nth x 1))) (jolt-invoke _a$3167 _a$3168 _a$3169 _a$3170)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "conj on a sorted-map requires a [key value] pair or a map" (jolt-hash-map))) jolt-nil)))))))) sm-conj-1) (let* ((_o$3171 (keyword #f "private")) (_o$3172 #t)) (jolt-hash-map _o$3171 _o$3172)))) + (def-var! "clojure.core" "balance-left" (letrec ((balance-left (lambda (k v ins right) (let fnrec2442 ((k k) (v v) (ins ins) (right right)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((il (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (ir (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") il)) (let* ((_a$2443 (var-deref "clojure.core" "mk-red")) (_a$2444 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2445 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2446 (jolt-invoke (var-deref "clojure.core" "blacken") il)) (_a$2447 (jolt-invoke (var-deref "clojure.core" "mk-black") k v ir right))) (jolt-invoke _a$2443 _a$2444 _a$2445 _a$2446 _a$2447)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ir)) (let* ((_a$2453 (var-deref "clojure.core" "mk-red")) (_a$2454 (jolt-invoke (var-deref "clojure.core" "nd-key") ir)) (_a$2455 (jolt-invoke (var-deref "clojure.core" "nd-val") ir)) (_a$2456 (let* ((_a$2448 (var-deref "clojure.core" "mk-black")) (_a$2449 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2450 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2451 il) (_a$2452 (jolt-invoke (var-deref "clojure.core" "nd-left") ir))) (jolt-invoke _a$2448 _a$2449 _a$2450 _a$2451 _a$2452))) (_a$2457 (jolt-invoke (var-deref "clojure.core" "mk-black") k v (jolt-invoke (var-deref "clojure.core" "nd-right") ir) right))) (jolt-invoke _a$2453 _a$2454 _a$2455 _a$2456 _a$2457)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "mk-black") k v ins right) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "mk-black") k v ins right)))))) balance-left))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sm-conj-many" (letrec ((sm-conj-many (lambda (sm xs) (let fnrec3173 ((sm sm) (xs xs)) (jolt-reduce (var-deref "clojure.core" "sm-conj-1") sm xs))))) sm-conj-many) (let* ((_o$3174 (keyword #f "private")) (_o$3175 #t)) (jolt-hash-map _o$3174 _o$3175)))) + (def-var! "clojure.core" "balance-right" (letrec ((balance-right (lambda (k v left ins) (let fnrec2458 ((k k) (v v) (left left) (ins ins)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ins)) (let* ((il (jolt-invoke (var-deref "clojure.core" "nd-left") ins)) (ir (jolt-invoke (var-deref "clojure.core" "nd-right") ins))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") ir)) (let* ((_a$2459 (var-deref "clojure.core" "mk-red")) (_a$2460 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2461 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2462 (jolt-invoke (var-deref "clojure.core" "mk-black") k v left il)) (_a$2463 (jolt-invoke (var-deref "clojure.core" "blacken") ir))) (jolt-invoke _a$2459 _a$2460 _a$2461 _a$2462 _a$2463)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") il)) (let* ((_a$2469 (var-deref "clojure.core" "mk-red")) (_a$2470 (jolt-invoke (var-deref "clojure.core" "nd-key") il)) (_a$2471 (jolt-invoke (var-deref "clojure.core" "nd-val") il)) (_a$2472 (jolt-invoke (var-deref "clojure.core" "mk-black") k v left (jolt-invoke (var-deref "clojure.core" "nd-left") il))) (_a$2473 (let* ((_a$2464 (var-deref "clojure.core" "mk-black")) (_a$2465 (jolt-invoke (var-deref "clojure.core" "nd-key") ins)) (_a$2466 (jolt-invoke (var-deref "clojure.core" "nd-val") ins)) (_a$2467 (jolt-invoke (var-deref "clojure.core" "nd-right") il)) (_a$2468 ir)) (jolt-invoke _a$2464 _a$2465 _a$2466 _a$2467 _a$2468)))) (jolt-invoke _a$2469 _a$2470 _a$2471 _a$2472 _a$2473)) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "mk-black") k v left ins) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "mk-black") k v left ins)))))) balance-right))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-get" (letrec ((ss-get (lambda (ss x not-found) (let fnrec3176 ((ss ss) (x x) (not-found not-found)) (let* ((n (let* ((_a$3177 (var-deref "clojure.core" "tree-lookup")) (_a$3178 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree"))) (_a$3179 (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (_a$3180 x)) (jolt-invoke _a$3177 _a$3178 _a$3179 _a$3180)))) (if (jolt-nil? n) not-found (jolt-invoke (var-deref "clojure.core" "nd-key") n))))))) ss-get) (let* ((_o$3181 (keyword #f "private")) (_o$3182 #t)) (jolt-hash-map _o$3181 _o$3182)))) + (def-var! "clojure.core" "balance-left-del" (letrec ((balance-left-del (lambda (k v del right) (let fnrec2474 ((k k) (v v) (del del) (right right)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") del)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v (jolt-invoke (var-deref "clojure.core" "blacken") del) right) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") right)) (jolt-invoke (var-deref "clojure.core" "balance-right") k v del (jolt-invoke (var-deref "clojure.core" "redden") right)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "red?") right))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-left") right)) and__25__auto))) (let* ((_a$2480 (var-deref "clojure.core" "mk-red")) (_a$2481 (jolt-invoke (var-deref "clojure.core" "nd-key") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2482 (jolt-invoke (var-deref "clojure.core" "nd-val") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2483 (jolt-invoke (var-deref "clojure.core" "mk-black") k v del (jolt-invoke (var-deref "clojure.core" "nd-left") (jolt-invoke (var-deref "clojure.core" "nd-left") right)))) (_a$2484 (let* ((_a$2475 (var-deref "clojure.core" "balance-right")) (_a$2476 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2477 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2478 (jolt-invoke (var-deref "clojure.core" "nd-right") (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2479 (jolt-invoke (var-deref "clojure.core" "redden") (jolt-invoke (var-deref "clojure.core" "nd-right") right)))) (jolt-invoke _a$2475 _a$2476 _a$2477 _a$2478 _a$2479)))) (jolt-invoke _a$2480 _a$2481 _a$2482 _a$2483 _a$2484)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "red-black tree invariant violation" (jolt-hash-map))) jolt-nil)))))))) balance-left-del))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-conj-1" (letrec ((ss-conj-1 (lambda (ss x) (let fnrec3183 ((ss ss) (x x)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp x)) ss (let* ((_a$3184 (var-deref "clojure.core" "make-sorted")) (_a$3185 (keyword "jolt" "sorted-set")) (_a$3186 (jolt-invoke (var-deref "clojure.core" "blacken") (jolt-invoke (var-deref "clojure.core" "tree-ins") cmp tree x jolt-nil))) (_a$3187 (jolt-inc (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt")))) (_a$3188 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cmp"))) (_a$3189 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "ops")))) (jolt-invoke _a$3184 _a$3185 _a$3186 _a$3187 _a$3188 _a$3189)))))))) ss-conj-1) (let* ((_o$3190 (keyword #f "private")) (_o$3191 #t)) (jolt-hash-map _o$3190 _o$3191)))) + (def-var! "clojure.core" "balance-right-del" (letrec ((balance-right-del (lambda (k v left del) (let fnrec2485 ((k k) (v v) (left left) (del del)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") del)) (jolt-invoke (var-deref "clojure.core" "mk-red") k v left (jolt-invoke (var-deref "clojure.core" "blacken") del)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") left)) (jolt-invoke (var-deref "clojure.core" "balance-left") k v (jolt-invoke (var-deref "clojure.core" "redden") left) del) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "red?") left))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-right") left)) and__25__auto))) (let* ((_a$2491 (var-deref "clojure.core" "mk-red")) (_a$2492 (jolt-invoke (var-deref "clojure.core" "nd-key") (jolt-invoke (var-deref "clojure.core" "nd-right") left))) (_a$2493 (jolt-invoke (var-deref "clojure.core" "nd-val") (jolt-invoke (var-deref "clojure.core" "nd-right") left))) (_a$2494 (let* ((_a$2486 (var-deref "clojure.core" "balance-left")) (_a$2487 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2488 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2489 (jolt-invoke (var-deref "clojure.core" "redden") (jolt-invoke (var-deref "clojure.core" "nd-left") left))) (_a$2490 (jolt-invoke (var-deref "clojure.core" "nd-left") (jolt-invoke (var-deref "clojure.core" "nd-right") left)))) (jolt-invoke _a$2486 _a$2487 _a$2488 _a$2489 _a$2490))) (_a$2495 (jolt-invoke (var-deref "clojure.core" "mk-black") k v (jolt-invoke (var-deref "clojure.core" "nd-right") (jolt-invoke (var-deref "clojure.core" "nd-right") left)) del))) (jolt-invoke _a$2491 _a$2492 _a$2493 _a$2494 _a$2495)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "red-black tree invariant violation" (jolt-hash-map))) jolt-nil)))))))) balance-right-del))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-conj-many" (letrec ((ss-conj-many (lambda (ss xs) (let fnrec3192 ((ss ss) (xs xs)) (jolt-reduce (var-deref "clojure.core" "ss-conj-1") ss xs))))) ss-conj-many) (let* ((_o$3193 (keyword #f "private")) (_o$3194 #t)) (jolt-hash-map _o$3193 _o$3194)))) + (def-var! "clojure.core" "tree-append" (letrec ((tree-append (lambda (left right) (let fnrec2496 ((left left) (right right)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") left)) right (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") right)) left (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") left)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") right)) (let* ((app (let* ((_a$2497 tree-append) (_a$2498 (jolt-invoke (var-deref "clojure.core" "nd-right") left)) (_a$2499 (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (jolt-invoke _a$2497 _a$2498 _a$2499)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") app)) (let* ((_a$2510 (var-deref "clojure.core" "mk-red")) (_a$2511 (jolt-invoke (var-deref "clojure.core" "nd-key") app)) (_a$2512 (jolt-invoke (var-deref "clojure.core" "nd-val") app)) (_a$2513 (let* ((_a$2500 (var-deref "clojure.core" "mk-red")) (_a$2501 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2502 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2503 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$2504 (jolt-invoke (var-deref "clojure.core" "nd-left") app))) (jolt-invoke _a$2500 _a$2501 _a$2502 _a$2503 _a$2504))) (_a$2514 (let* ((_a$2505 (var-deref "clojure.core" "mk-red")) (_a$2506 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2507 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2508 (jolt-invoke (var-deref "clojure.core" "nd-right") app)) (_a$2509 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$2505 _a$2506 _a$2507 _a$2508 _a$2509)))) (jolt-invoke _a$2510 _a$2511 _a$2512 _a$2513 _a$2514)) (let* ((_a$2520 (var-deref "clojure.core" "mk-red")) (_a$2521 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2522 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2523 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$2524 (let* ((_a$2515 (var-deref "clojure.core" "mk-red")) (_a$2516 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2517 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2518 app) (_a$2519 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$2515 _a$2516 _a$2517 _a$2518 _a$2519)))) (jolt-invoke _a$2520 _a$2521 _a$2522 _a$2523 _a$2524)))) (let* ((_a$2525 (var-deref "clojure.core" "mk-red")) (_a$2526 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2527 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2528 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$2529 (jolt-invoke tree-append (jolt-invoke (var-deref "clojure.core" "nd-right") left) right))) (jolt-invoke _a$2525 _a$2526 _a$2527 _a$2528 _a$2529))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") right)) (let* ((_a$2530 (var-deref "clojure.core" "mk-red")) (_a$2531 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2532 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2533 (jolt-invoke tree-append left (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (_a$2534 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$2530 _a$2531 _a$2532 _a$2533 _a$2534)) (if (jolt-truthy? (keyword #f "else")) (let* ((app (let* ((_a$2535 tree-append) (_a$2536 (jolt-invoke (var-deref "clojure.core" "nd-right") left)) (_a$2537 (jolt-invoke (var-deref "clojure.core" "nd-left") right))) (jolt-invoke _a$2535 _a$2536 _a$2537)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "red?") app)) (let* ((_a$2548 (var-deref "clojure.core" "mk-red")) (_a$2549 (jolt-invoke (var-deref "clojure.core" "nd-key") app)) (_a$2550 (jolt-invoke (var-deref "clojure.core" "nd-val") app)) (_a$2551 (let* ((_a$2538 (var-deref "clojure.core" "mk-black")) (_a$2539 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2540 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2541 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$2542 (jolt-invoke (var-deref "clojure.core" "nd-left") app))) (jolt-invoke _a$2538 _a$2539 _a$2540 _a$2541 _a$2542))) (_a$2552 (let* ((_a$2543 (var-deref "clojure.core" "mk-black")) (_a$2544 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2545 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2546 (jolt-invoke (var-deref "clojure.core" "nd-right") app)) (_a$2547 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$2543 _a$2544 _a$2545 _a$2546 _a$2547)))) (jolt-invoke _a$2548 _a$2549 _a$2550 _a$2551 _a$2552)) (let* ((_a$2558 (var-deref "clojure.core" "balance-left-del")) (_a$2559 (jolt-invoke (var-deref "clojure.core" "nd-key") left)) (_a$2560 (jolt-invoke (var-deref "clojure.core" "nd-val") left)) (_a$2561 (jolt-invoke (var-deref "clojure.core" "nd-left") left)) (_a$2562 (let* ((_a$2553 (var-deref "clojure.core" "mk-black")) (_a$2554 (jolt-invoke (var-deref "clojure.core" "nd-key") right)) (_a$2555 (jolt-invoke (var-deref "clojure.core" "nd-val") right)) (_a$2556 app) (_a$2557 (jolt-invoke (var-deref "clojure.core" "nd-right") right))) (jolt-invoke _a$2553 _a$2554 _a$2555 _a$2556 _a$2557)))) (jolt-invoke _a$2558 _a$2559 _a$2560 _a$2561 _a$2562)))) jolt-nil))))))))) tree-append))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-disj-1" (letrec ((ss-disj-1 (lambda (ss x) (let fnrec3195 ((ss ss) (x x)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree")))) (if (jolt-nil? (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp x)) ss (let* ((t (jolt-invoke (var-deref "clojure.core" "tree-del") cmp tree x))) (let* ((_a$3196 (var-deref "clojure.core" "make-sorted")) (_a$3197 (keyword "jolt" "sorted-set")) (_a$3198 (if (jolt-truthy? t) (jolt-invoke (var-deref "clojure.core" "blacken") t) jolt-nil)) (_a$3199 (jolt-dec (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt")))) (_a$3200 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cmp"))) (_a$3201 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "ops")))) (jolt-invoke _a$3196 _a$3197 _a$3198 _a$3199 _a$3200 _a$3201))))))))) ss-disj-1) (let* ((_o$3202 (keyword #f "private")) (_o$3203 #t)) (jolt-hash-map _o$3202 _o$3203)))) + (def-var! "clojure.core" "tree-del" (letrec ((tree-del (lambda (cmp tree k) (let fnrec2563 ((cmp cmp) (tree tree) (k k)) (let* ((c (jolt-invoke cmp k (jolt-invoke (var-deref "clojure.core" "nd-key") tree)))) (if (jolt-zero? c) (let* ((_a$2564 (var-deref "clojure.core" "tree-append")) (_a$2565 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2566 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2564 _a$2565 _a$2566)) (if (jolt-neg? c) (let* ((del (jolt-invoke tree-del cmp (jolt-invoke (var-deref "clojure.core" "nd-left") tree) k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-left") tree))) (let* ((_a$2567 (var-deref "clojure.core" "balance-left-del")) (_a$2568 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2569 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2570 del) (_a$2571 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2567 _a$2568 _a$2569 _a$2570 _a$2571)) (let* ((_a$2572 (var-deref "clojure.core" "mk-red")) (_a$2573 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2574 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2575 del) (_a$2576 (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (jolt-invoke _a$2572 _a$2573 _a$2574 _a$2575 _a$2576)))) (if (jolt-truthy? (keyword #f "else")) (let* ((del (jolt-invoke tree-del cmp (jolt-invoke (var-deref "clojure.core" "nd-right") tree) k))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "black?") (jolt-invoke (var-deref "clojure.core" "nd-right") tree))) (let* ((_a$2577 (var-deref "clojure.core" "balance-right-del")) (_a$2578 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2579 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2580 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2581 del)) (jolt-invoke _a$2577 _a$2578 _a$2579 _a$2580 _a$2581)) (let* ((_a$2582 (var-deref "clojure.core" "mk-red")) (_a$2583 (jolt-invoke (var-deref "clojure.core" "nd-key") tree)) (_a$2584 (jolt-invoke (var-deref "clojure.core" "nd-val") tree)) (_a$2585 (jolt-invoke (var-deref "clojure.core" "nd-left") tree)) (_a$2586 del)) (jolt-invoke _a$2582 _a$2583 _a$2584 _a$2585 _a$2586)))) jolt-nil)))))))) tree-del))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-disj-many" (letrec ((ss-disj-many (lambda (ss xs) (let fnrec3204 ((ss ss) (xs xs)) (jolt-reduce (var-deref "clojure.core" "ss-disj-1") ss xs))))) ss-disj-many) (let* ((_o$3205 (keyword #f "private")) (_o$3206 #t)) (jolt-hash-map _o$3205 _o$3206)))) + (def-var! "clojure.core" "tree-collect" (letrec ((tree-collect (lambda (t proj acc) (let fnrec2587 ((t t) (proj proj) (acc acc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") t)) acc (let* ((_a$2590 tree-collect) (_a$2591 (jolt-invoke (var-deref "clojure.core" "nd-right") t)) (_a$2592 proj) (_a$2593 (let* ((_a$2588 (jolt-invoke tree-collect (jolt-invoke (var-deref "clojure.core" "nd-left") t) proj acc)) (_a$2589 (jolt-invoke proj t))) (jolt-conj _a$2588 _a$2589)))) (jolt-invoke _a$2590 _a$2591 _a$2592 _a$2593))))))) tree-collect))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sm-ops" (let* ((_o$3224 (keyword #f "count")) (_o$3225 (lambda (sm) (let fnrec3207 ((sm sm)) (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt"))))) (_o$3226 (keyword #f "entries")) (_o$3227 (lambda (sm) (let fnrec3208 ((sm sm)) (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry"))))) (_o$3228 (keyword #f "seq")) (_o$3229 (lambda (sm) (let fnrec3209 ((sm sm)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))) (_o$3230 (keyword #f "rseq")) (_o$3231 (lambda (sm) (let fnrec3210 ((sm sm)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))))) (_o$3232 (keyword #f "first")) (_o$3233 (lambda (sm) (let fnrec3211 ((sm sm)) (jolt-first (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))) (_o$3234 (keyword #f "get")) (_o$3235 (var-deref "clojure.core" "sm-get")) (_o$3236 (keyword #f "contains")) (_o$3237 (lambda (sm k) (let fnrec3212 ((sm sm) (k k)) (jolt-not (jolt-nil? (let* ((_a$3213 (var-deref "clojure.core" "tree-lookup")) (_a$3214 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (_a$3215 (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (_a$3216 k)) (jolt-invoke _a$3213 _a$3214 _a$3215 _a$3216))))))) (_o$3238 (keyword #f "assoc")) (_o$3239 (var-deref "clojure.core" "sm-assoc-many")) (_o$3240 (keyword #f "dissoc")) (_o$3241 (var-deref "clojure.core" "sm-dissoc-many")) (_o$3242 (keyword #f "conj")) (_o$3243 (var-deref "clojure.core" "sm-conj-many")) (_o$3244 (keyword #f "empty")) (_o$3245 (lambda (sm) (let fnrec3217 ((sm sm)) (let* ((_a$3218 (var-deref "clojure.core" "make-sorted")) (_a$3219 (keyword "jolt" "sorted-map")) (_a$3220 jolt-nil) (_a$3221 0) (_a$3222 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$3223 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$3218 _a$3219 _a$3220 _a$3221 _a$3222 _a$3223)))))) (jolt-hash-map _o$3224 _o$3225 _o$3226 _o$3227 _o$3228 _o$3229 _o$3230 _o$3231 _o$3232 _o$3233 _o$3234 _o$3235 _o$3236 _o$3237 _o$3238 _o$3239 _o$3240 _o$3241 _o$3242 _o$3243 _o$3244 _o$3245)) (let* ((_o$3246 (keyword #f "private")) (_o$3247 #t)) (jolt-hash-map _o$3246 _o$3247)))) + (def-var! "clojure.core" "make-sorted" (letrec ((make-sorted (lambda (tag tree cnt cmp ops) (let fnrec2594 ((tag tag) (tree tree) (cnt cnt) (cmp cmp) (ops ops)) (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "ref-put!") (jolt-invoke (var-deref "jolt.host" "tagged-table") tag) (keyword #f "tree") tree) (keyword #f "cnt") cnt) (keyword #f "cmp") cmp) (keyword #f "ops") ops))))) make-sorted))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "ss-ops" (let* ((_o$3265 (keyword #f "count")) (_o$3266 (lambda (ss) (let fnrec3248 ((ss ss)) (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt"))))) (_o$3267 (keyword #f "entries")) (_o$3268 (lambda (ss) (let fnrec3249 ((ss ss)) (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key"))))) (_o$3269 (keyword #f "seq")) (_o$3270 (lambda (ss) (let fnrec3250 ((ss ss)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))) (_o$3271 (keyword #f "rseq")) (_o$3272 (lambda (ss) (let fnrec3251 ((ss ss)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))))) (_o$3273 (keyword #f "first")) (_o$3274 (lambda (ss) (let fnrec3252 ((ss ss)) (jolt-first (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))) (_o$3275 (keyword #f "get")) (_o$3276 (var-deref "clojure.core" "ss-get")) (_o$3277 (keyword #f "contains")) (_o$3278 (lambda (ss x) (let fnrec3253 ((ss ss) (x x)) (jolt-not (jolt-nil? 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"clojure.core" "sc-entries" (letrec ((sc-entries (lambda (sc proj) (let fnrec2595 ((sc sc) (proj proj)) (let* ((_a$2596 (var-deref "clojure.core" "tree-collect")) (_a$2597 (jolt-invoke (var-deref "clojure.core" "sfield") sc (keyword #f "tree"))) (_a$2598 proj) (_a$2599 (jolt-vector))) (jolt-invoke _a$2596 _a$2597 _a$2598 _a$2599)))))) sc-entries))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-map" (letrec ((sorted-map (lambda kvs (let fnrec3287 ((kvs (list->cseq kvs))) (let* ((_a$3288 (var-deref "clojure.core" "sm-assoc-many")) (_a$3289 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-map") jolt-nil 0 jolt-nil (var-deref "clojure.core" "sm-ops"))) (_a$3290 (jolt-invoke (var-deref "clojure.core" "vec") kvs))) (jolt-invoke _a$3288 _a$3289 _a$3290)))))) sorted-map))) + (def-var! "clojure.core" "map-entry" (letrec ((map-entry (lambda (t) (let fnrec2600 ((t t)) (let* ((_a$2601 (var-deref "jolt.host" "map-entry")) (_a$2602 (jolt-invoke (var-deref "clojure.core" "nd-key") t)) (_a$2603 (jolt-invoke (var-deref "clojure.core" "nd-val") t))) (jolt-invoke _a$2601 _a$2602 _a$2603)))))) map-entry))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-map-by" (letrec ((sorted-map-by (lambda (comparator . kvs) (let fnrec3291 ((comparator comparator) (kvs (list->cseq kvs))) (let* ((_a$3292 (var-deref "clojure.core" "sm-assoc-many")) (_a$3293 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-map") jolt-nil 0 (jolt-invoke (var-deref "clojure.core" "fn->cmp") comparator) (var-deref "clojure.core" "sm-ops"))) (_a$3294 (jolt-invoke (var-deref "clojure.core" "vec") kvs))) (jolt-invoke _a$3292 _a$3293 _a$3294)))))) sorted-map-by))) + (def-var! "clojure.core" "sm-get" (letrec ((sm-get (lambda (sm k not-found) (let fnrec2604 ((sm sm) (k k) (not-found not-found)) (let* ((n (let* ((_a$2605 (var-deref "clojure.core" "tree-lookup")) (_a$2606 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (_a$2607 (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (_a$2608 k)) (jolt-invoke _a$2605 _a$2606 _a$2607 _a$2608)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") n)) not-found (jolt-invoke (var-deref "clojure.core" "nd-val") n))))))) sm-get))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-set" (letrec ((sorted-set (lambda xs (let fnrec3295 ((xs (list->cseq xs))) (let* ((_a$3296 (var-deref "clojure.core" "ss-conj-many")) (_a$3297 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-set") jolt-nil 0 jolt-nil (var-deref "clojure.core" "ss-ops"))) (_a$3298 (jolt-invoke (var-deref "clojure.core" "vec") xs))) (jolt-invoke _a$3296 _a$3297 _a$3298)))))) sorted-set))) + (def-var! "clojure.core" "sm-assoc-1" (letrec ((sm-assoc-1 (lambda (sm k v) (let fnrec2609 ((sm sm) (k k) (v v)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (node (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp k))) (if (jolt-truthy? (let* ((and__25__auto node)) (if (jolt-truthy? and__25__auto) (jolt= v (jolt-invoke (var-deref "clojure.core" "nd-val") node)) and__25__auto))) sm (if (jolt-truthy? node) (let* ((_a$2610 (var-deref "clojure.core" "make-sorted")) (_a$2611 (keyword "jolt" "sorted-map")) (_a$2612 (jolt-invoke (var-deref "clojure.core" "tree-replace") cmp tree k v)) (_a$2613 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt"))) (_a$2614 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$2615 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$2610 _a$2611 _a$2612 _a$2613 _a$2614 _a$2615)) (if (jolt-truthy? (keyword #f "else")) (let* ((_a$2616 (var-deref "clojure.core" "make-sorted")) (_a$2617 (keyword "jolt" "sorted-map")) (_a$2618 (jolt-invoke (var-deref "clojure.core" "blacken") (jolt-invoke (var-deref "clojure.core" "tree-ins") cmp tree k v))) (_a$2619 (jolt-inc (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt")))) (_a$2620 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$2621 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$2616 _a$2617 _a$2618 _a$2619 _a$2620 _a$2621)) jolt-nil)))))))) sm-assoc-1))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-set-by" (letrec ((sorted-set-by (lambda (comparator . xs) (let fnrec3299 ((comparator comparator) (xs (list->cseq xs))) (let* ((_a$3300 (var-deref "clojure.core" "ss-conj-many")) (_a$3301 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-set") jolt-nil 0 (jolt-invoke (var-deref "clojure.core" "fn->cmp") comparator) (var-deref "clojure.core" "ss-ops"))) (_a$3302 (jolt-invoke (var-deref "clojure.core" "vec") xs))) (jolt-invoke _a$3300 _a$3301 _a$3302)))))) sorted-set-by))) + (def-var! "clojure.core" "sm-assoc-many" (letrec ((sm-assoc-many (lambda (sm kvs) (let fnrec2622 ((sm sm) (kvs kvs)) (let* ((n (jolt-count kvs))) (begin (if (jolt-odd? n) (jolt-throw (jolt-ex-info "sorted-map assoc expects an even number of key/values" (let* ((_o$2623 (keyword #f "count")) (_o$2624 n)) (jolt-hash-map _o$2623 _o$2624)))) jolt-nil) (let* ((m sm) (i 0)) (let loop2625 ((m m) (i i)) (if (< i n) (let* ((_a$2630 (let* ((_a$2626 (var-deref "clojure.core" "sm-assoc-1")) (_a$2627 m) (_a$2628 (jolt-nth kvs i)) (_a$2629 (jolt-nth kvs (jolt-inc i)))) (jolt-invoke _a$2626 _a$2627 _a$2628 _a$2629))) (_a$2631 (+ i 2))) (loop2625 _a$2630 _a$2631)) m))))))))) sm-assoc-many))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-map?" (letrec ((sorted-map? (lambda (x) (let fnrec3303 ((x x)) (jolt= (keyword "jolt" "sorted-map") (jolt-invoke (var-deref "clojure.core" "sfield") x (keyword "jolt" "type"))))))) sorted-map?))) + (def-var! "clojure.core" "sm-dissoc-1" (letrec ((sm-dissoc-1 (lambda (sm k) (let fnrec2632 ((sm sm) (k k)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp k))) sm (let* ((t (jolt-invoke (var-deref "clojure.core" "tree-del") cmp tree k))) (let* ((_a$2633 (var-deref "clojure.core" "make-sorted")) (_a$2634 (keyword "jolt" "sorted-map")) (_a$2635 (if (jolt-truthy? t) (jolt-invoke (var-deref "clojure.core" "blacken") t) jolt-nil)) (_a$2636 (jolt-dec (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt")))) (_a$2637 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$2638 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$2633 _a$2634 _a$2635 _a$2636 _a$2637 _a$2638))))))))) sm-dissoc-1))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted-set?" (letrec ((sorted-set? (lambda (x) (let fnrec3304 ((x x)) (jolt= (keyword "jolt" "sorted-set") (jolt-invoke (var-deref "clojure.core" "sfield") x (keyword "jolt" "type"))))))) sorted-set?))) + (def-var! "clojure.core" "sm-dissoc-many" (letrec ((sm-dissoc-many (lambda (sm ks) (let fnrec2639 ((sm sm) (ks ks)) (jolt-reduce (var-deref "clojure.core" "sm-dissoc-1") sm ks))))) sm-dissoc-many))) (guard (e (#t #f)) - (def-var! "clojure.core" "sorted?" (letrec ((sorted? (lambda (x) (let fnrec3305 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted-map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted-set?") x))))))) sorted?))) + (def-var! "clojure.core" "sm-conj-1" (letrec ((sm-conj-1 (lambda (sm x) (let fnrec2640 ((sm sm) (x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") x)) sm (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2646 (lambda (m e) (let fnrec2641 ((m m) (e e)) (let* ((_a$2642 (var-deref "clojure.core" "sm-assoc-1")) (_a$2643 m) (_a$2644 (jolt-first e)) (_a$2645 (jolt-invoke (var-deref "clojure.core" "second") e))) (jolt-invoke _a$2642 _a$2643 _a$2644 _a$2645))))) (_a$2647 sm) (_a$2648 (jolt-seq x))) (jolt-reduce _a$2646 _a$2647 _a$2648)) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "vector?") x))) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count x)) and__25__auto))) (let* ((_a$2649 (var-deref "clojure.core" "sm-assoc-1")) (_a$2650 sm) (_a$2651 (jolt-nth x 0)) (_a$2652 (jolt-nth x 1))) (jolt-invoke _a$2649 _a$2650 _a$2651 _a$2652)) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (jolt-ex-info "conj on a sorted-map requires a [key value] pair or a map" (jolt-hash-map))) jolt-nil)))))))) sm-conj-1))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sc-keyf" (letrec ((sc-keyf (lambda (sc) (let fnrec3306 ((sc sc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted-map?") sc)) jolt-first jolt-identity))))) sc-keyf) (let* ((_o$3307 (keyword #f "private")) (_o$3308 #t)) (jolt-hash-map _o$3307 _o$3308)))) + (def-var! "clojure.core" "sm-conj-many" (letrec ((sm-conj-many (lambda (sm xs) (let fnrec2653 ((sm sm) (xs xs)) (jolt-reduce (var-deref "clojure.core" "sm-conj-1") sm xs))))) sm-conj-many))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sc-proj" (letrec ((sc-proj (lambda (sc) (let fnrec3309 ((sc sc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted-map?") sc)) (var-deref "clojure.core" "map-entry") (var-deref "clojure.core" "nd-key")))))) sc-proj) (let* ((_o$3310 (keyword #f "private")) (_o$3311 #t)) (jolt-hash-map _o$3310 _o$3311)))) + (def-var! "clojure.core" "ss-get" (letrec ((ss-get (lambda (ss x not-found) (let fnrec2654 ((ss ss) (x x) (not-found not-found)) (let* ((n (let* ((_a$2655 (var-deref "clojure.core" "tree-lookup")) (_a$2656 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree"))) (_a$2657 (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (_a$2658 x)) (jolt-invoke _a$2655 _a$2656 _a$2657 _a$2658)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") n)) not-found (jolt-invoke (var-deref "clojure.core" "nd-key") n))))))) ss-get))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "sub-filter" (letrec ((sub-filter (lambda (sc tests) (let fnrec3312 ((sc sc) (tests tests)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") sc)) (keyf (jolt-invoke (var-deref "clojure.core" "sc-keyf") sc))) (let* ((_a$3315 (var-deref "clojure.core" "filterv")) (_a$3316 (lambda (e) (let fnrec3313 ((e e)) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (G__119) (let fnrec3314 ((G__119 G__119)) (let* ((G__120 G__119) (test (jolt-nth G__120 0 jolt-nil)) (k (jolt-nth G__120 1 jolt-nil))) (jolt-invoke test (jolt-invoke cmp (jolt-invoke keyf e) k) 0)))) tests)))) (_a$3317 (jolt-invoke (var-deref "clojure.core" "sc-entries") sc (jolt-invoke (var-deref "clojure.core" "sc-proj") sc)))) (jolt-invoke _a$3315 _a$3316 _a$3317))))))) sub-filter) (let* ((_o$3318 (keyword #f "private")) (_o$3319 #t)) (jolt-hash-map _o$3318 _o$3319)))) + (def-var! "clojure.core" "ss-conj-1" (letrec ((ss-conj-1 (lambda (ss x) (let fnrec2659 ((ss ss) (x x)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp x)) ss (let* ((_a$2660 (var-deref "clojure.core" "make-sorted")) (_a$2661 (keyword "jolt" "sorted-set")) (_a$2662 (jolt-invoke (var-deref "clojure.core" "blacken") (jolt-invoke (var-deref "clojure.core" "tree-ins") cmp tree x jolt-nil))) (_a$2663 (jolt-inc (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt")))) (_a$2664 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cmp"))) (_a$2665 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "ops")))) (jolt-invoke _a$2660 _a$2661 _a$2662 _a$2663 _a$2664 _a$2665)))))))) ss-conj-1))) (guard (e (#t #f)) - (def-var! "clojure.core" "subseq" (letrec ((subseq (case-lambda ((sc test k) (let fnrec3320 ((sc sc) (test test) (k k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (jolt-vector (let* ((_o$3321 test) (_o$3322 k)) (jolt-vector _o$3321 _o$3322))))))) ((sc start-test start-k end-test end-k) (let fnrec3323 ((sc sc) (start-test start-test) (start-k start-k) (end-test end-test) (end-k end-k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (let* ((_o$3328 (let* ((_o$3324 start-test) (_o$3325 start-k)) (jolt-vector _o$3324 _o$3325))) (_o$3329 (let* ((_o$3326 end-test) (_o$3327 end-k)) (jolt-vector _o$3326 _o$3327)))) (jolt-vector _o$3328 _o$3329))))))))) subseq))) + (def-var! "clojure.core" "ss-conj-many" (letrec ((ss-conj-many (lambda (ss xs) (let fnrec2666 ((ss ss) (xs xs)) (jolt-reduce (var-deref "clojure.core" "ss-conj-1") ss xs))))) ss-conj-many))) (guard (e (#t #f)) - (def-var! "clojure.core" "rsubseq" (letrec ((rsubseq (case-lambda ((sc test k) (let fnrec3330 ((sc sc) (test test) (k k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (jolt-vector (let* ((_o$3331 test) (_o$3332 k)) (jolt-vector _o$3331 _o$3332))))))))) ((sc start-test start-k end-test end-k) (let fnrec3333 ((sc sc) (start-test start-test) (start-k start-k) (end-test end-test) (end-k end-k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (let* ((_o$3338 (let* ((_o$3334 start-test) (_o$3335 start-k)) (jolt-vector _o$3334 _o$3335))) (_o$3339 (let* ((_o$3336 end-test) (_o$3337 end-k)) (jolt-vector _o$3336 _o$3337)))) (jolt-vector _o$3338 _o$3339))))))))))) rsubseq))) + (def-var! "clojure.core" "ss-disj-1" (letrec ((ss-disj-1 (lambda (ss x) (let fnrec2667 ((ss ss) (x x)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (tree (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "clojure.core" "tree-lookup") tree cmp x))) ss (let* ((t (jolt-invoke (var-deref "clojure.core" "tree-del") cmp tree x))) (let* ((_a$2668 (var-deref "clojure.core" "make-sorted")) (_a$2669 (keyword "jolt" "sorted-set")) (_a$2670 (if (jolt-truthy? t) (jolt-invoke (var-deref "clojure.core" "blacken") t) jolt-nil)) (_a$2671 (jolt-dec (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt")))) (_a$2672 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cmp"))) (_a$2673 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "ops")))) (jolt-invoke _a$2668 _a$2669 _a$2670 _a$2671 _a$2672 _a$2673))))))))) ss-disj-1))) +(guard (e (#t #f)) + (def-var! "clojure.core" "ss-disj-many" (letrec ((ss-disj-many (lambda (ss xs) (let fnrec2674 ((ss ss) (xs xs)) (jolt-reduce (var-deref "clojure.core" "ss-disj-1") ss xs))))) ss-disj-many))) +(guard (e (#t #f)) + (def-var-with-meta! "clojure.core" "sm-ops" (let* ((_o$2692 (keyword #f "count")) (_o$2693 (lambda (sm) (let fnrec2675 ((sm sm)) (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cnt"))))) (_o$2694 (keyword #f "entries")) (_o$2695 (lambda (sm) (let fnrec2676 ((sm sm)) (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry"))))) (_o$2696 (keyword #f "seq")) (_o$2697 (lambda (sm) (let fnrec2677 ((sm sm)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))) (_o$2698 (keyword #f "rseq")) (_o$2699 (lambda (sm) (let fnrec2678 ((sm sm)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))))) (_o$2700 (keyword #f "first")) (_o$2701 (lambda (sm) (let fnrec2679 ((sm sm)) (jolt-first (jolt-invoke (var-deref "clojure.core" "sc-entries") sm (var-deref "clojure.core" "map-entry")))))) (_o$2702 (keyword #f "get")) (_o$2703 (var-deref "clojure.core" "sm-get")) (_o$2704 (keyword #f "contains")) (_o$2705 (lambda (sm k) (let fnrec2680 ((sm sm) (k k)) (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") (let* ((_a$2681 (var-deref "clojure.core" "tree-lookup")) (_a$2682 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "tree"))) (_a$2683 (jolt-invoke (var-deref "clojure.core" "the-cmp") sm)) (_a$2684 k)) (jolt-invoke _a$2681 _a$2682 _a$2683 _a$2684))))))) (_o$2706 (keyword #f "assoc")) (_o$2707 (var-deref "clojure.core" "sm-assoc-many")) (_o$2708 (keyword #f "dissoc")) (_o$2709 (var-deref "clojure.core" "sm-dissoc-many")) (_o$2710 (keyword #f "conj")) (_o$2711 (var-deref "clojure.core" "sm-conj-many")) (_o$2712 (keyword #f "empty")) (_o$2713 (lambda (sm) (let fnrec2685 ((sm sm)) (let* ((_a$2686 (var-deref "clojure.core" "make-sorted")) (_a$2687 (keyword "jolt" "sorted-map")) (_a$2688 jolt-nil) (_a$2689 0) (_a$2690 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "cmp"))) (_a$2691 (jolt-invoke (var-deref "clojure.core" "sfield") sm (keyword #f "ops")))) (jolt-invoke _a$2686 _a$2687 _a$2688 _a$2689 _a$2690 _a$2691)))))) (jolt-hash-map _o$2692 _o$2693 _o$2694 _o$2695 _o$2696 _o$2697 _o$2698 _o$2699 _o$2700 _o$2701 _o$2702 _o$2703 _o$2704 _o$2705 _o$2706 _o$2707 _o$2708 _o$2709 _o$2710 _o$2711 _o$2712 _o$2713)) (jolt-hash-map (keyword #f "private") #t))) +(guard (e (#t #f)) + (def-var-with-meta! "clojure.core" "ss-ops" (let* ((_o$2731 (keyword #f "count")) (_o$2732 (lambda (ss) (let fnrec2714 ((ss ss)) (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cnt"))))) (_o$2733 (keyword #f "entries")) (_o$2734 (lambda (ss) (let fnrec2715 ((ss ss)) (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key"))))) (_o$2735 (keyword #f "seq")) (_o$2736 (lambda (ss) (let fnrec2716 ((ss ss)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))) (_o$2737 (keyword #f "rseq")) (_o$2738 (lambda (ss) (let fnrec2717 ((ss ss)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))))) (_o$2739 (keyword #f "first")) (_o$2740 (lambda (ss) (let fnrec2718 ((ss ss)) (jolt-first (jolt-invoke (var-deref "clojure.core" "sc-entries") ss (var-deref "clojure.core" "nd-key")))))) (_o$2741 (keyword #f "get")) (_o$2742 (var-deref "clojure.core" "ss-get")) (_o$2743 (keyword #f "contains")) (_o$2744 (lambda (ss x) (let fnrec2719 ((ss ss) (x x)) (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") (let* ((_a$2720 (var-deref "clojure.core" "tree-lookup")) (_a$2721 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "tree"))) (_a$2722 (jolt-invoke (var-deref "clojure.core" "the-cmp") ss)) (_a$2723 x)) (jolt-invoke _a$2720 _a$2721 _a$2722 _a$2723))))))) (_o$2745 (keyword #f "conj")) (_o$2746 (var-deref "clojure.core" "ss-conj-many")) (_o$2747 (keyword #f "disj")) (_o$2748 (var-deref "clojure.core" "ss-disj-many")) (_o$2749 (keyword #f "empty")) (_o$2750 (lambda (ss) (let fnrec2724 ((ss ss)) (let* ((_a$2725 (var-deref "clojure.core" "make-sorted")) (_a$2726 (keyword "jolt" "sorted-set")) (_a$2727 jolt-nil) (_a$2728 0) (_a$2729 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "cmp"))) (_a$2730 (jolt-invoke (var-deref "clojure.core" "sfield") ss (keyword #f "ops")))) (jolt-invoke _a$2725 _a$2726 _a$2727 _a$2728 _a$2729 _a$2730)))))) (jolt-hash-map _o$2731 _o$2732 _o$2733 _o$2734 _o$2735 _o$2736 _o$2737 _o$2738 _o$2739 _o$2740 _o$2741 _o$2742 _o$2743 _o$2744 _o$2745 _o$2746 _o$2747 _o$2748 _o$2749 _o$2750)) (jolt-hash-map (keyword #f "private") #t))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-map" (letrec ((sorted-map (lambda kvs (let fnrec2751 ((kvs (list->cseq kvs))) (let* ((_a$2752 (var-deref "clojure.core" "sm-assoc-many")) (_a$2753 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-map") jolt-nil 0 jolt-nil (var-deref "clojure.core" "sm-ops"))) (_a$2754 (jolt-invoke (var-deref "clojure.core" "vec") kvs))) (jolt-invoke _a$2752 _a$2753 _a$2754)))))) sorted-map))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-map-by" (letrec ((sorted-map-by (lambda (comparator . kvs) (let fnrec2755 ((comparator comparator) (kvs (list->cseq kvs))) (let* ((_a$2756 (var-deref "clojure.core" "sm-assoc-many")) (_a$2757 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-map") jolt-nil 0 (jolt-invoke (var-deref "clojure.core" "fn->cmp") comparator) (var-deref "clojure.core" "sm-ops"))) (_a$2758 (jolt-invoke (var-deref "clojure.core" "vec") kvs))) (jolt-invoke _a$2756 _a$2757 _a$2758)))))) sorted-map-by))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-set" (letrec ((sorted-set (lambda xs (let fnrec2759 ((xs (list->cseq xs))) (let* ((_a$2760 (var-deref "clojure.core" "ss-conj-many")) (_a$2761 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-set") jolt-nil 0 jolt-nil (var-deref "clojure.core" "ss-ops"))) (_a$2762 (jolt-invoke (var-deref "clojure.core" "vec") xs))) (jolt-invoke _a$2760 _a$2761 _a$2762)))))) sorted-set))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-set-by" (letrec ((sorted-set-by (lambda (comparator . xs) (let fnrec2763 ((comparator comparator) (xs (list->cseq xs))) (let* ((_a$2764 (var-deref "clojure.core" "ss-conj-many")) (_a$2765 (jolt-invoke (var-deref "clojure.core" "make-sorted") (keyword "jolt" "sorted-set") jolt-nil 0 (jolt-invoke (var-deref "clojure.core" "fn->cmp") comparator) (var-deref "clojure.core" "ss-ops"))) (_a$2766 (jolt-invoke (var-deref "clojure.core" "vec") xs))) (jolt-invoke _a$2764 _a$2765 _a$2766)))))) sorted-set-by))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-map?" (letrec ((sorted-map? (lambda (x) (let fnrec2767 ((x x)) (jolt= (keyword "jolt" "sorted-map") (jolt-invoke (var-deref "clojure.core" "sfield") x (keyword "jolt" "type"))))))) sorted-map?))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted-set?" (letrec ((sorted-set? (lambda (x) (let fnrec2768 ((x x)) (jolt= (keyword "jolt" "sorted-set") (jolt-invoke (var-deref "clojure.core" "sfield") x (keyword "jolt" "type"))))))) sorted-set?))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sorted?" (letrec ((sorted? (lambda (x) (let fnrec2769 ((x x)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted-map?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "sorted-set?") x))))))) sorted?))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sc-keyf" (letrec ((sc-keyf (lambda (sc) (let fnrec2770 ((sc sc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted-map?") sc)) jolt-first jolt-identity))))) sc-keyf))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sc-proj" (letrec ((sc-proj (lambda (sc) (let fnrec2771 ((sc sc)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "sorted-map?") sc)) (var-deref "clojure.core" "map-entry") (var-deref "clojure.core" "nd-key")))))) sc-proj))) +(guard (e (#t #f)) + (def-var! "clojure.core" "sub-filter" (letrec ((sub-filter (lambda (sc tests) (let fnrec2772 ((sc sc) (tests tests)) (let* ((cmp (jolt-invoke (var-deref "clojure.core" "the-cmp") sc)) (keyf (jolt-invoke (var-deref "clojure.core" "sc-keyf") sc))) (let* ((_a$2775 (var-deref "clojure.core" "filterv")) (_a$2776 (lambda (e) (let fnrec2773 ((e e)) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (G__104) (let fnrec2774 ((G__104 G__104)) (let* ((G__105 G__104) (test (jolt-nth G__105 0 jolt-nil)) (k (jolt-nth G__105 1 jolt-nil))) (jolt-invoke test (jolt-invoke cmp (jolt-invoke keyf e) k) 0)))) tests)))) (_a$2777 (jolt-invoke (var-deref "clojure.core" "sc-entries") sc (jolt-invoke (var-deref "clojure.core" "sc-proj") sc)))) (jolt-invoke _a$2775 _a$2776 _a$2777))))))) sub-filter))) +(guard (e (#t #f)) + (def-var! "clojure.core" "subseq" (letrec ((subseq (case-lambda ((sc test k) (let fnrec2778 ((sc sc) (test test) (k k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (jolt-vector (let* ((_o$2779 test) (_o$2780 k)) (jolt-vector _o$2779 _o$2780))))))) ((sc start-test start-k end-test end-k) (let fnrec2781 ((sc sc) (start-test start-test) (start-k start-k) (end-test end-test) (end-k end-k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (let* ((_o$2786 (let* ((_o$2782 start-test) (_o$2783 start-k)) (jolt-vector _o$2782 _o$2783))) (_o$2787 (let* ((_o$2784 end-test) (_o$2785 end-k)) (jolt-vector _o$2784 _o$2785)))) (jolt-vector _o$2786 _o$2787))))))))) subseq))) +(guard (e (#t #f)) + (def-var! "clojure.core" "rsubseq" (letrec ((rsubseq (case-lambda ((sc test k) (let fnrec2788 ((sc sc) (test test) (k k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (jolt-vector (let* ((_o$2789 test) (_o$2790 k)) (jolt-vector _o$2789 _o$2790))))))))) ((sc start-test start-k end-test end-k) (let fnrec2791 ((sc sc) (start-test start-test) (start-k start-k) (end-test end-test) (end-k end-k)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "vec") (jolt-reverse (jolt-invoke (var-deref "clojure.core" "sub-filter") sc (let* ((_o$2796 (let* ((_o$2792 start-test) (_o$2793 start-k)) (jolt-vector _o$2792 _o$2793))) (_o$2797 (let* ((_o$2794 end-test) (_o$2795 end-k)) (jolt-vector _o$2794 _o$2795)))) (jolt-vector _o$2796 _o$2797))))))))))) rsubseq))) (guard (e (#t #f)) (def-var! "clojure.core" "comment" - (lambda body (let fnrec3340 ((body (list->cseq body))) jolt-nil))) + (lambda body (let fnrec2798 ((body (list->cseq body))) jolt-nil))) (mark-macro! "clojure.core" "comment")) (guard (e (#t #f)) (def-var! "clojure.core" "with-out-str" - (lambda body (let fnrec3341 ((body (list->cseq body))) (let* ((_a$3346 (var-deref "clojure.core" "__sqcat")) (_a$3347 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "__with-out-str"))) (_a$3348 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$3342 (var-deref "clojure.core" "__sqcat")) (_a$3343 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$3344 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqvec")))) (_a$3345 body)) (jolt-invoke _a$3342 _a$3343 _a$3344 _a$3345))))) (jolt-invoke _a$3346 _a$3347 _a$3348))))) + (lambda body (let fnrec2799 ((body (list->cseq body))) (let* ((_a$2804 (var-deref "clojure.core" "__sqcat")) (_a$2805 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "__with-out-str"))) (_a$2806 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2800 (var-deref "clojure.core" "__sqcat")) (_a$2801 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "fn*"))) (_a$2802 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqvec")))) (_a$2803 body)) (jolt-invoke _a$2800 _a$2801 _a$2802 _a$2803))))) (jolt-invoke _a$2804 _a$2805 _a$2806))))) (mark-macro! "clojure.core" "with-out-str")) (guard (e (#t #f)) (def-var! "clojure.core" "defmulti" - (lambda (name . args) (let fnrec3349 ((name name) (args (list->cseq args))) (let* ((args (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") (jolt-first args))) (jolt-rest args) args)) (args (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") (jolt-first args)))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "symbol?") (jolt-first args))) and__25__auto))) (jolt-rest args) args)) (dispatch (jolt-first args)) (opts (jolt-rest args)) (qname (let* ((_a$3350 (var-deref "clojure.core" "symbol")) (_a$3351 (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "ns-name") (var-deref "clojure.core" "*ns*")))) (_a$3352 (jolt-invoke (var-deref "clojure.core" "name") name))) (jolt-invoke _a$3350 _a$3351 _a$3352)))) (let* ((_a$3356 (var-deref "clojure.core" "__sqcat")) (_a$3357 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "defmulti-setup"))) (_a$3358 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$3353 (var-deref "clojure.core" "__sqcat")) (_a$3354 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$3355 (jolt-invoke (var-deref "clojure.core" "__sq1") qname))) (jolt-invoke _a$3353 _a$3354 _a$3355)))) (_a$3359 (jolt-invoke (var-deref "clojure.core" "__sq1") dispatch)) (_a$3360 opts)) (jolt-invoke _a$3356 _a$3357 _a$3358 _a$3359 _a$3360)))))) + (lambda (name . args) (let fnrec2807 ((name name) (args (list->cseq args))) (let* ((args (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") (jolt-first args))) (jolt-rest args) args)) (args (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "map?") (jolt-first args)))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "symbol?") (jolt-first args))) and__25__auto))) (jolt-rest args) args)) (dispatch (jolt-first args)) (opts (jolt-rest args))) (let* ((_a$2811 (var-deref "clojure.core" "__sqcat")) (_a$2812 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "defmulti-setup"))) (_a$2813 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2808 (var-deref "clojure.core" "__sqcat")) (_a$2809 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$2810 (jolt-invoke (var-deref "clojure.core" "__sq1") name))) (jolt-invoke _a$2808 _a$2809 _a$2810)))) (_a$2814 (jolt-invoke (var-deref "clojure.core" "__sq1") dispatch)) (_a$2815 opts)) (jolt-invoke _a$2811 _a$2812 _a$2813 _a$2814 _a$2815)))))) (mark-macro! "clojure.core" "defmulti")) (guard (e (#t #f)) (def-var! "clojure.core" "defmethod" - (lambda (mm dispatch-val . fn-tail) (let fnrec3361 ((mm mm) (dispatch-val dispatch-val) (fn-tail (list->cseq fn-tail))) (let* ((_a$3365 (var-deref "clojure.core" "__sqcat")) (_a$3366 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "defmethod-setup"))) (_a$3367 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$3362 (var-deref "clojure.core" "__sqcat")) (_a$3363 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$3364 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$3362 _a$3363 _a$3364)))) (_a$3368 (jolt-invoke (var-deref "clojure.core" "__sq1") dispatch-val)) (_a$3369 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "fn")) fn-tail))) (_a$3370 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "ns-name") (var-deref "clojure.core" "*ns*")))))) (jolt-invoke _a$3365 _a$3366 _a$3367 _a$3368 _a$3369 _a$3370))))) + (lambda (mm dispatch-val . fn-tail) (let fnrec2816 ((mm mm) (dispatch-val dispatch-val) (fn-tail (list->cseq fn-tail))) (let* ((_a$2820 (var-deref "clojure.core" "__sqcat")) (_a$2821 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "defmethod-setup"))) (_a$2822 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2817 (var-deref "clojure.core" "__sqcat")) (_a$2818 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$2819 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$2817 _a$2818 _a$2819)))) (_a$2823 (jolt-invoke (var-deref "clojure.core" "__sq1") dispatch-val)) (_a$2824 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "fn")) fn-tail)))) (jolt-invoke _a$2820 _a$2821 _a$2822 _a$2823 _a$2824))))) (mark-macro! "clojure.core" "defmethod")) (guard (e (#t #f)) (def-var! "clojure.core" "prefer-method" - (lambda (mm dval-a dval-b) (let fnrec3371 ((mm mm) (dval-a dval-a) (dval-b dval-b)) (let* ((_a$3375 (var-deref "clojure.core" "__sqcat")) (_a$3376 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "prefer-method-setup"))) (_a$3377 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$3372 (var-deref "clojure.core" "__sqcat")) (_a$3373 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$3374 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$3372 _a$3373 _a$3374)))) (_a$3378 (jolt-invoke (var-deref "clojure.core" "__sq1") dval-a)) (_a$3379 (jolt-invoke (var-deref "clojure.core" "__sq1") dval-b))) (jolt-invoke _a$3375 _a$3376 _a$3377 _a$3378 _a$3379))))) + (lambda (mm dval-a dval-b) (let fnrec2825 ((mm mm) (dval-a dval-a) (dval-b dval-b)) (let* ((_a$2829 (var-deref "clojure.core" "__sqcat")) (_a$2830 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "prefer-method-setup"))) (_a$2831 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2826 (var-deref "clojure.core" "__sqcat")) (_a$2827 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$2828 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$2826 _a$2827 _a$2828)))) (_a$2832 (jolt-invoke (var-deref "clojure.core" "__sq1") dval-a)) (_a$2833 (jolt-invoke (var-deref "clojure.core" "__sq1") dval-b))) (jolt-invoke _a$2829 _a$2830 _a$2831 _a$2832 _a$2833))))) (mark-macro! "clojure.core" "prefer-method")) (guard (e (#t #f)) (def-var! "clojure.core" "remove-method" - (lambda (mm dval) (let fnrec3380 ((mm mm) (dval dval)) (let* ((_a$3384 (var-deref "clojure.core" "__sqcat")) (_a$3385 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "remove-method-setup"))) (_a$3386 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$3381 (var-deref "clojure.core" "__sqcat")) (_a$3382 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$3383 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$3381 _a$3382 _a$3383)))) (_a$3387 (jolt-invoke (var-deref "clojure.core" "__sq1") dval))) (jolt-invoke _a$3384 _a$3385 _a$3386 _a$3387))))) + (lambda (mm dval) (let fnrec2834 ((mm mm) (dval dval)) (let* ((_a$2838 (var-deref "clojure.core" "__sqcat")) (_a$2839 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "remove-method-setup"))) (_a$2840 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2835 (var-deref "clojure.core" "__sqcat")) (_a$2836 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "quote"))) (_a$2837 (jolt-invoke (var-deref "clojure.core" "__sq1") mm))) (jolt-invoke _a$2835 _a$2836 _a$2837)))) (_a$2841 (jolt-invoke (var-deref "clojure.core" "__sq1") dval))) (jolt-invoke _a$2838 _a$2839 _a$2840 _a$2841))))) (mark-macro! "clojure.core" "remove-method")) (guard (e (#t #f)) (def-var! 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name-sym)))) (binds (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "mapcat") (lambda (f) (let fnrec3562 ((f f)) (let* ((_o$3567 f) (_o$3568 (let* ((_a$3563 (var-deref "clojure.core" "__sqcat")) (_a$3564 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "get"))) (_a$3565 (jolt-invoke (var-deref "clojure.core" "__sq1") inst)) (_a$3566 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-invoke (var-deref "clojure.core" "keyword") (jolt-invoke (var-deref "clojure.core" "name") f))))) (jolt-invoke _a$3563 _a$3564 _a$3565 _a$3566)))) (jolt-vector _o$3567 _o$3568)))) fields)))) (jolt-list hinted (jolt-invoke (var-deref "clojure.core" "list*") (jolt-symbol #f "let") binds (jolt-drop 2 spec))))))) (groups (jolt-invoke (var-deref "clojure.core" "group-by-head") body)) (by-name (let* ((_a$3572 (lambda (m spec) (let fnrec3569 ((m m) (spec spec)) (let* ((nm (jolt-invoke (var-deref "clojure.core" "name") (jolt-first spec)))) 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(jolt-invoke (var-deref "clojure.core" "deref") seen) input) result (begin (jolt-invoke (var-deref "clojure.core" "vswap!") seen jolt-conj input) (jolt-invoke rf result input))))))))))) ((coll) (let fnrec2551 ((coll coll)) (let* ((step (letrec ((step (lambda (xs seen) (let fnrec2552 ((xs xs) (seen seen)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2553 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-invoke (lambda (G__112 seen) (let fnrec2554 ((G__112 G__112) (seen seen)) (let* ((G__113 G__112) (f (jolt-nth G__113 0 jolt-nil)) (xs G__113)) (let* ((temp__27__auto (jolt-seq xs))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (if (jolt-contains? seen f) (fnrec2554 (jolt-rest s) seen) (jolt-cons f (let* ((_a$2555 (jolt-rest s)) (_a$2556 (jolt-conj seen f))) (step _a$2555 _a$2556))))) jolt-nil))))) xs seen))))))))) step))) (jolt-invoke step coll (jolt-hash-set)))))))) distinct))) + (def-var! "clojure.core" "distinct" (letrec ((distinct (case-lambda (() (let fnrec2116 () (lambda (rf) (let fnrec2117 ((rf rf)) (let* ((seen (jolt-invoke (var-deref "clojure.core" "volatile!") (jolt-hash-set)))) (case-lambda (() (let fnrec2118 () (jolt-invoke rf))) ((result) (let fnrec2119 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2120 ((result result) (input input)) (if (jolt-contains? (jolt-invoke (var-deref "clojure.core" "deref") seen) input) result (begin (jolt-invoke (var-deref "clojure.core" "vswap!") seen jolt-conj input) (jolt-invoke rf result input))))))))))) ((coll) (let fnrec2121 ((coll coll)) (let* ((step (letrec ((step (lambda (xs seen) (let fnrec2122 ((xs xs) (seen seen)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2123 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-invoke (lambda (G__102 seen) (let fnrec2124 ((G__102 G__102) (seen seen)) (let* ((G__103 G__102) (f (jolt-nth G__103 0 jolt-nil)) (xs G__103)) (let* ((temp__27__auto (jolt-seq xs))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (if (jolt-contains? seen f) (fnrec2124 (jolt-rest s) seen) (jolt-cons f (let* ((_a$2125 step) (_a$2126 (jolt-rest s)) (_a$2127 (jolt-conj seen f))) (jolt-invoke _a$2125 _a$2126 _a$2127))))) jolt-nil))))) xs seen))))))))) step))) (jolt-invoke step coll (jolt-hash-set)))))))) distinct))) (guard (e (#t #f)) - (def-var! "clojure.core" "keep" (letrec ((keep (case-lambda ((f) (let fnrec2557 ((f f)) (lambda (rf) (let fnrec2558 ((rf rf)) (case-lambda (() (let fnrec2559 () (jolt-invoke rf))) ((result) (let fnrec2560 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2561 ((result result) (input input)) (let* ((v (jolt-invoke f input))) (if (jolt-nil? v) result (jolt-invoke rf result v)))))))))) ((f coll) (let fnrec2562 ((f f) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2563 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((x (jolt-invoke f (jolt-first s)))) (if (jolt-nil? x) (keep f (jolt-rest s)) (jolt-cons x (keep f (jolt-rest s)))))) jolt-nil))))))))))) keep))) + (def-var! "clojure.core" "keep" (letrec ((keep (case-lambda ((f) (let fnrec2128 ((f f)) (lambda (rf) (let fnrec2129 ((rf rf)) (case-lambda (() (let fnrec2130 () (jolt-invoke rf))) ((result) (let fnrec2131 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2132 ((result result) (input input)) (let* ((v (jolt-invoke f input))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") v)) result (jolt-invoke rf result v)))))))))) ((f coll) (let fnrec2133 ((f f) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2134 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((x (jolt-invoke f (jolt-first s)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") x)) (jolt-invoke keep f (jolt-rest s)) (jolt-cons x (jolt-invoke keep f (jolt-rest s)))))) jolt-nil))))))))))) keep))) (guard (e (#t #f)) - (def-var! "clojure.core" "keep-indexed" (letrec ((keep-indexed (case-lambda ((f) (let fnrec2564 ((f f)) (lambda (rf) (let fnrec2565 ((rf rf)) (let* ((ia (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2566 () (jolt-invoke rf))) ((result) (let fnrec2567 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2568 ((result result) (input input)) (let* ((i (jolt-invoke (var-deref "clojure.core" "vswap!") ia jolt-inc)) (v (jolt-invoke f i input))) (if (jolt-nil? v) result (jolt-invoke rf result v))))))))))) ((f coll) (let fnrec2569 ((f f) (coll coll)) (letrec* ((keepi (letrec ((keepi (lambda (idx coll) (let fnrec2570 ((idx idx) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2571 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((x (jolt-invoke f idx (jolt-first s)))) (if (jolt-nil? x) (let* ((_a$2572 (jolt-inc idx)) (_a$2573 (jolt-rest s))) (keepi _a$2572 _a$2573)) (jolt-cons x (let* ((_a$2574 (jolt-inc idx)) (_a$2575 (jolt-rest s))) (keepi _a$2574 _a$2575)))))) jolt-nil)))))))))) keepi))) (jolt-invoke keepi 0 coll))))))) keep-indexed))) + (def-var! "clojure.core" "keep-indexed" (letrec ((keep-indexed (case-lambda ((f) (let fnrec2135 ((f f)) (lambda (rf) (let fnrec2136 ((rf rf)) (let* ((ia (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2137 () (jolt-invoke rf))) ((result) (let fnrec2138 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2139 ((result result) (input input)) (let* ((i (jolt-invoke (var-deref "clojure.core" "vswap!") ia jolt-inc)) (v (jolt-invoke f i input))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") v)) result (jolt-invoke rf result v))))))))))) ((f coll) (let fnrec2140 ((f f) (coll coll)) (letrec* ((keepi (letrec ((keepi (lambda (idx coll) (let fnrec2141 ((idx idx) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2142 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((x (jolt-invoke f idx (jolt-first s)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") x)) (let* ((_a$2143 keepi) (_a$2144 (jolt-inc idx)) (_a$2145 (jolt-rest s))) (jolt-invoke _a$2143 _a$2144 _a$2145)) (jolt-cons x (let* ((_a$2146 keepi) (_a$2147 (jolt-inc idx)) (_a$2148 (jolt-rest s))) (jolt-invoke _a$2146 _a$2147 _a$2148)))))) jolt-nil)))))))))) keepi))) (jolt-invoke keepi 0 coll))))))) keep-indexed))) (guard (e (#t #f)) - (def-var! "clojure.core" "map-indexed" (letrec ((map-indexed (case-lambda ((f) (let fnrec2576 ((f f)) (lambda (rf) (let fnrec2577 ((rf rf)) (let* ((i (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2578 () (jolt-invoke rf))) ((result) (let fnrec2579 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2580 ((result result) (input input)) (jolt-invoke rf result (jolt-invoke f (jolt-invoke (var-deref "clojure.core" "vswap!") i jolt-inc) input)))))))))) ((f coll) (let fnrec2581 ((f f) (coll coll)) (letrec* ((mapi (letrec ((mapi (lambda (idx coll) (let fnrec2582 ((idx idx) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2583 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$2586 (jolt-invoke f idx (jolt-first s))) (_a$2587 (let* ((_a$2584 (jolt-inc idx)) (_a$2585 (jolt-rest s))) (mapi _a$2584 _a$2585)))) (jolt-cons _a$2586 _a$2587))) jolt-nil)))))))))) mapi))) (jolt-invoke mapi 0 coll))))))) map-indexed))) + (def-var! "clojure.core" "map-indexed" (letrec ((map-indexed (case-lambda ((f) (let fnrec2149 ((f f)) (lambda (rf) (let fnrec2150 ((rf rf)) (let* ((i (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2151 () (jolt-invoke rf))) ((result) (let fnrec2152 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2153 ((result result) (input input)) (jolt-invoke rf result (jolt-invoke f (jolt-invoke (var-deref "clojure.core" "vswap!") i jolt-inc) input)))))))))) ((f coll) (let fnrec2154 ((f f) (coll coll)) (letrec* ((mapi (letrec ((mapi (lambda (idx coll) (let fnrec2155 ((idx idx) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2156 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$2160 (jolt-invoke f idx (jolt-first s))) (_a$2161 (let* ((_a$2157 mapi) (_a$2158 (jolt-inc idx)) (_a$2159 (jolt-rest s))) (jolt-invoke _a$2157 _a$2158 _a$2159)))) (jolt-cons _a$2160 _a$2161))) jolt-nil)))))))))) mapi))) (jolt-invoke mapi 0 coll))))))) map-indexed))) (guard (e (#t #f)) - (def-var! "clojure.core" "cycle" (letrec ((cycle (lambda (coll) (let fnrec2588 ((coll coll)) (if (jolt-truthy? (jolt-seq coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2589 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-concat coll (cycle coll)))))) (jolt-list )))))) cycle))) + (def-var! "clojure.core" "cycle" (letrec ((cycle (lambda (coll) (let fnrec2162 ((coll coll)) (if (jolt-truthy? (jolt-seq coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2163 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-concat coll (jolt-invoke cycle coll)))))) (jolt-list )))))) cycle))) (guard (e (#t #f)) - (def-var! "clojure.core" "repeatedly" (letrec ((repeatedly (case-lambda ((f) (let fnrec2590 ((f f)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2591 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((_a$2592 (jolt-invoke f)) (_a$2593 (repeatedly f))) (jolt-cons _a$2592 _a$2593)))))))) ((n f) (let fnrec2594 ((n n) (f f)) (jolt-take n (repeatedly f))))))) repeatedly))) + (def-var! "clojure.core" "repeatedly" (letrec ((repeatedly (case-lambda ((f) (let fnrec2164 ((f f)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2165 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((_a$2166 (jolt-invoke f)) (_a$2167 (jolt-invoke repeatedly f))) (jolt-cons _a$2166 _a$2167)))))))) ((n f) (let fnrec2168 ((n n) (f f)) (jolt-take n (jolt-invoke repeatedly f))))))) repeatedly))) (guard (e (#t #f)) - (def-var! "clojure.core" "repeat" (letrec ((repeat (case-lambda ((x) (let fnrec2595 ((x x)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2596 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons x (repeat x)))))))) ((n x) (let fnrec2597 ((n n) (x x)) (jolt-take n (repeat x))))))) repeat))) + (def-var! "clojure.core" "repeat" (letrec ((repeat (case-lambda ((x) (let fnrec2169 ((x x)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2170 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons x (jolt-invoke repeat x)))))))) ((n x) (let fnrec2171 ((n n) (x x)) (jolt-take n (jolt-invoke repeat x))))))) repeat))) (guard (e (#t #f)) - (def-var! "clojure.core" "iterate" (letrec ((iterate (lambda (f x) (let fnrec2598 ((f f) (x x)) (jolt-cons x (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2599 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (iterate f (jolt-invoke f x))))))))))) iterate))) + (def-var! "clojure.core" "iterate" (letrec ((iterate (lambda (f x) (let fnrec2172 ((f f) (x x)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2173 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (jolt-cons x (jolt-invoke iterate f (jolt-invoke f x))))))))))) iterate))) (guard (e (#t #f)) - (def-var! "clojure.core" "partition-all" (letrec ((partition-all (case-lambda ((n) (let fnrec2600 ((n n)) (lambda (rf) (let fnrec2601 ((rf rf)) (let* ((a (jolt-invoke (var-deref "clojure.core" "volatile!") (jolt-vector)))) (case-lambda (() (let fnrec2602 () (jolt-invoke rf))) ((result) (let fnrec2603 ((result result)) (let* ((result (if (jolt-zero? (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") a))) result (let* ((v (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") a (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "unreduced") (jolt-invoke rf result v))))))) (jolt-invoke rf result)))) ((result input) (let fnrec2604 ((result result) (input input)) (begin (jolt-invoke (var-deref "clojure.core" "vswap!") a jolt-conj input) (if (jolt= n (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") a))) (let* ((v (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") a (jolt-vector)) (jolt-invoke rf result v))) result)))))))))) ((n coll) (let fnrec2605 ((n n) (coll coll)) (letrec* ((go (letrec ((go (lambda (s) (let fnrec2606 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2607 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (if (jolt-truthy? (jolt-seq s)) (let* ((i 0) (acc (jolt-list )) (cur s)) (let loop2608 ((i i) (acc acc) (cur cur)) (if (jolt-truthy? (let* ((and__25__auto (jolt-n< i n))) (if (jolt-truthy? and__25__auto) (jolt-seq cur) and__25__auto))) (let* ((_a$2609 (jolt-inc i)) (_a$2610 (jolt-cons (jolt-first cur) acc)) (_a$2611 (jolt-rest cur))) (loop2608 _a$2609 _a$2610 _a$2611)) (let* ((_a$2612 (jolt-reverse acc)) (_a$2613 (go cur))) (jolt-cons _a$2612 _a$2613))))) jolt-nil))))))))) go))) (jolt-invoke go coll)))) ((n step coll) (let fnrec2614 ((n n) (step step) (coll coll)) (letrec* ((go (letrec ((go (lambda (s) (let fnrec2615 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2616 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (if (jolt-truthy? (jolt-seq s)) (let* ((_a$2617 (jolt-take n s)) (_a$2618 (go (jolt-invoke (var-deref "clojure.core" "nthrest") s step)))) (jolt-cons _a$2617 _a$2618)) jolt-nil))))))))) go))) (jolt-invoke go coll))))))) partition-all))) + (def-var! "clojure.core" "partition-all" (letrec ((partition-all (case-lambda ((n) (let fnrec2174 ((n n)) (lambda (rf) (let fnrec2175 ((rf rf)) (let* ((a (jolt-invoke (var-deref "clojure.core" "volatile!") (jolt-vector)))) (case-lambda (() (let fnrec2176 () (jolt-invoke rf))) ((result) (let fnrec2177 ((result result)) (let* ((result (if (jolt-zero? (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") a))) result (let* ((v (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") a (jolt-vector)) (jolt-invoke (var-deref "clojure.core" "unreduced") (jolt-invoke rf result v))))))) (jolt-invoke rf result)))) ((result input) (let fnrec2178 ((result result) (input input)) (begin (jolt-invoke (var-deref "clojure.core" "vswap!") a jolt-conj input) (if (jolt= n (jolt-count (jolt-invoke (var-deref "clojure.core" "deref") a))) (let* ((v (jolt-invoke (var-deref "clojure.core" "deref") a))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") a (jolt-vector)) (jolt-invoke rf result v))) result)))))))))) ((n coll) (let fnrec2179 ((n n) (coll coll)) (letrec* ((go (letrec ((go (lambda (s) (let fnrec2180 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2181 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (if (jolt-truthy? (jolt-seq s)) (let* ((i 0) (chunk (jolt-vector)) (cur s)) (let loop2182 ((i i) (chunk chunk) (cur cur)) (if (jolt-truthy? (let* ((and__25__auto (< i n))) (if (jolt-truthy? and__25__auto) (jolt-seq cur) and__25__auto))) (let* ((_a$2183 (jolt-inc i)) (_a$2184 (jolt-conj chunk (jolt-first cur))) (_a$2185 (jolt-rest cur))) (loop2182 _a$2183 _a$2184 _a$2185)) (jolt-cons chunk (jolt-invoke go cur))))) jolt-nil))))))))) go))) (jolt-invoke go coll)))) ((n step coll) (let fnrec2186 ((n n) (step step) (coll coll)) (letrec* ((go (letrec ((go (lambda (s) (let fnrec2187 ((s s)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2188 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (if (jolt-truthy? (jolt-seq s)) (let* ((_a$2189 (jolt-take n s)) (_a$2190 (jolt-invoke go (jolt-invoke (var-deref "clojure.core" "nthrest") s step)))) (jolt-cons _a$2189 _a$2190)) jolt-nil))))))))) go))) (jolt-invoke go coll))))))) partition-all))) (guard (e (#t #f)) - (def-var! "clojure.core" "interpose" (letrec ((interpose (case-lambda ((sep) (let fnrec2619 ((sep sep)) (lambda (rf) (let fnrec2620 ((rf rf)) (let* ((started (jolt-invoke (var-deref "clojure.core" "volatile!") #f))) (case-lambda (() (let fnrec2621 () (jolt-invoke rf))) ((result) (let fnrec2622 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2623 ((result result) (input input)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "deref") started)) (let* ((sepr (jolt-invoke rf result sep))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") sepr)) sepr (jolt-invoke rf sepr input))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") started #t) (jolt-invoke rf result input))))))))))) ((sep coll) (let fnrec2624 ((sep sep) (coll coll)) (jolt-drop 1 (jolt-invoke (var-deref "clojure.core" "interleave") (jolt-invoke (var-deref "clojure.core" "repeat") sep) coll))))))) interpose))) + (def-var! "clojure.core" "interpose" (letrec ((interpose (case-lambda ((sep) (let fnrec2191 ((sep sep)) (lambda (rf) (let fnrec2192 ((rf rf)) (let* ((started (jolt-invoke (var-deref "clojure.core" "volatile!") #f))) (case-lambda (() (let fnrec2193 () (jolt-invoke rf))) ((result) (let fnrec2194 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2195 ((result result) (input input)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "deref") started)) (let* ((sepr (jolt-invoke rf result sep))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "reduced?") sepr)) sepr (jolt-invoke rf sepr input))) (begin (jolt-invoke (var-deref "clojure.core" "vreset!") started #t) (jolt-invoke rf result input))))))))))) ((sep coll) (let fnrec2196 ((sep sep) (coll coll)) (jolt-drop 1 (jolt-invoke (var-deref "clojure.core" "interleave") (jolt-invoke (var-deref "clojure.core" "repeat") sep) coll))))))) interpose))) (guard (e (#t #f)) - (def-var! "clojure.core" "take-nth" (letrec ((take-nth (case-lambda ((n) (let fnrec2625 ((n n)) (lambda (rf) (let fnrec2626 ((rf rf)) (let* ((iv (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2627 () (jolt-invoke rf))) ((result) (let fnrec2628 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2629 ((result result) (input input)) (let* ((i (jolt-invoke (var-deref "clojure.core" "vswap!") iv jolt-inc))) (if (jolt-zero? (jolt-rem i n)) (jolt-invoke rf result input) result)))))))))) ((n coll) (let fnrec2630 ((n n) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2631 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$2632 (jolt-first s)) (_a$2633 (take-nth n (jolt-drop n s)))) (jolt-cons _a$2632 _a$2633))) jolt-nil))))))))))) take-nth))) + (def-var! "clojure.core" "take-nth" (letrec ((take-nth (case-lambda ((n) (let fnrec2197 ((n n)) (lambda (rf) (let fnrec2198 ((rf rf)) (let* ((iv (jolt-invoke (var-deref "clojure.core" "volatile!") -1))) (case-lambda (() (let fnrec2199 () (jolt-invoke rf))) ((result) (let fnrec2200 ((result result)) (jolt-invoke rf result))) ((result input) (let fnrec2201 ((result result) (input input)) (let* ((i (jolt-invoke (var-deref "clojure.core" "vswap!") iv jolt-inc))) (if (jolt-zero? (remainder i n)) (jolt-invoke rf result input) result)))))))))) ((n coll) (let fnrec2202 ((n n) (coll coll)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2203 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((temp__27__auto (jolt-seq coll))) (if (jolt-truthy? temp__27__auto) (let* ((s temp__27__auto)) (let* ((_a$2204 (jolt-first s)) (_a$2205 (jolt-invoke take-nth n (jolt-drop n s)))) (jolt-cons _a$2204 _a$2205))) jolt-nil))))))))))) take-nth))) (guard (e (#t #f)) - (def-var! "clojure.core" "pmap" (letrec ((pmap (case-lambda ((f coll) (let fnrec2634 ((f f) (coll coll)) (jolt-map (var-deref "clojure.core" "deref") (jolt-invoke (var-deref "clojure.core" "doall") (jolt-map (lambda (x) (let fnrec2635 ((x x)) (jolt-invoke (var-deref "clojure.core" "future-call") (lambda () (let fnrec2636 () (jolt-invoke f x)))))) coll))))) ((f coll . colls) (let fnrec2637 ((f f) (coll coll) (colls (list->cseq colls))) (let* ((_a$2639 (lambda (xs) (let fnrec2638 ((xs xs)) (jolt-apply f xs)))) (_a$2640 (jolt-apply jolt-map jolt-vector coll colls))) (pmap _a$2639 _a$2640))))))) pmap))) + (def-var! "clojure.core" "pmap" (letrec ((pmap (case-lambda ((f coll) (let fnrec2206 ((f f) (coll coll)) (jolt-map (var-deref "clojure.core" "deref") (jolt-invoke (var-deref "clojure.core" "doall") (jolt-map (lambda (x) (let fnrec2207 ((x x)) (jolt-invoke (var-deref "clojure.core" "future-call") (lambda () (let fnrec2208 () (jolt-invoke f x)))))) coll))))) ((f coll . colls) (let fnrec2209 ((f f) (coll coll) (colls (list->cseq colls))) (let* ((_a$2211 pmap) (_a$2212 (lambda (xs) (let fnrec2210 ((xs xs)) (jolt-apply f xs)))) (_a$2213 (jolt-apply jolt-map jolt-vector coll colls))) (jolt-invoke _a$2211 _a$2212 _a$2213))))))) pmap))) (guard (e (#t #f)) - (def-var! "clojure.core" "pcalls" (letrec ((pcalls (lambda fns (let fnrec2641 ((fns (list->cseq fns))) (jolt-invoke (var-deref "clojure.core" "pmap") (lambda (f) (let fnrec2642 ((f f)) (jolt-invoke f))) fns))))) pcalls))) + (def-var! "clojure.core" "pcalls" (letrec ((pcalls (lambda fns (let fnrec2214 ((fns (list->cseq fns))) (jolt-invoke (var-deref "clojure.core" "pmap") (lambda (f) (let fnrec2215 ((f f)) (jolt-invoke f))) fns))))) pcalls))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "reader-eof" (keyword "jolt" "reader-eof") (let* ((_o$2643 (keyword #f "private")) (_o$2644 #t)) (jolt-hash-map _o$2643 _o$2644)))) + (def-var-with-meta! "clojure.core" "reader-eof" (keyword "jolt" "reader-eof") (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (begin (def-var! "clojure.core" "IReader" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IReader" (let* ((_o$2651 (keyword #f "-read-line")) (_o$2652 (let* ((_o$2645 (keyword #f "name")) (_o$2646 "-read-line")) (jolt-hash-map _o$2645 _o$2646))) (_o$2653 (keyword #f "-read-form")) (_o$2654 (let* ((_o$2647 (keyword #f "name")) (_o$2648 "-read-form")) (jolt-hash-map _o$2647 _o$2648))) (_o$2655 (keyword #f "-read+string")) (_o$2656 (let* ((_o$2649 (keyword #f "name")) (_o$2650 "-read+string")) (jolt-hash-map _o$2649 _o$2650)))) (jolt-hash-map _o$2651 _o$2652 _o$2653 _o$2654 _o$2655 _o$2656)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IReader" (let* ((_o$2657 "-read-line") (_o$2658 "-read-form") (_o$2659 "-read+string")) (jolt-vector _o$2657 _o$2658 _o$2659))) (def-var! "clojure.core" "-read-line" (lambda (G__114) (let fnrec2660 ((G__114 G__114)) (protocol-dispatch1 "IReader" "-read-line" G__114)))) (def-var! "clojure.core" "-read-form" (lambda (G__115) (let fnrec2661 ((G__115 G__115)) (protocol-dispatch1 "IReader" "-read-form" G__115)))) (def-var! "clojure.core" "-read+string" (lambda (G__116 G__117 G__118) (let fnrec2662 ((G__116 G__116) (G__117 G__117) (G__118 G__118)) (protocol-dispatch3 "IReader" "-read+string" G__116 G__117 G__118)))))) + (begin (def-var! "clojure.core" "IReader" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IReader" (let* ((_o$2222 (keyword #f "-read+string")) (_o$2223 (let* ((_o$2216 (keyword #f "name")) (_o$2217 "-read+string")) (jolt-hash-map _o$2216 _o$2217))) (_o$2224 (keyword #f "-read-line")) (_o$2225 (let* ((_o$2218 (keyword #f "name")) (_o$2219 "-read-line")) (jolt-hash-map _o$2218 _o$2219))) (_o$2226 (keyword #f "-read-form")) (_o$2227 (let* ((_o$2220 (keyword #f "name")) (_o$2221 "-read-form")) (jolt-hash-map _o$2220 _o$2221)))) (jolt-hash-map _o$2222 _o$2223 _o$2224 _o$2225 _o$2226 _o$2227)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IReader" (let* ((_o$2228 "-read-line") (_o$2229 "-read-form") (_o$2230 "-read+string")) (jolt-vector _o$2228 _o$2229 _o$2230))) (def-var! "clojure.core" "-read-line" (lambda (this__23__auto . rest__22__auto) (let fnrec2231 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IReader" "-read-line" this__23__auto rest__22__auto)))) (def-var! "clojure.core" "-read-form" (lambda (this__23__auto . rest__22__auto) (let fnrec2232 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IReader" "-read-form" this__23__auto rest__22__auto)))) (def-var! "clojure.core" "-read+string" (lambda (this__23__auto . rest__22__auto) (let fnrec2233 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IReader" "-read+string" this__23__auto rest__22__auto)))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "__string-reader" (letrec ((__string-reader (lambda (s) (let fnrec2663 ((s s)) (let* ((buf (jolt-invoke (var-deref "clojure.core" "atom") s))) (jolt-invoke (var-deref "clojure.core" "make-reified") (let* ((_o$2673 (keyword #f "-read-line")) (_o$2674 (lambda (_) (let fnrec2664 ((_ _)) (let* ((cur (jolt-invoke (var-deref "clojure.core" "deref") buf))) (if (jolt-pos? (jolt-count cur)) (let* ((i (jolt-invoke (var-deref "clojure.core" "str-find") "\n" cur))) (if (jolt-nil? i) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf "") cur) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-invoke (var-deref "clojure.core" "subs") cur (jolt-inc i))) (jolt-invoke (var-deref "clojure.core" "subs") cur 0 i)))) jolt-nil))))) (_o$2675 (keyword #f "-read-form")) (_o$2676 (lambda (_) (let fnrec2665 ((_ _)) (let* ((r (jolt-invoke (var-deref "clojure.core" "__parse-next") (jolt-invoke (var-deref "clojure.core" "deref") buf)))) (if (jolt-nil? r) (var-deref "clojure.core" "reader-eof") (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-nth r 1)) (jolt-nth r 0))))))) (_o$2677 (keyword #f "-read+string")) (_o$2678 (lambda (_ eof-error? eof-value) (let fnrec2666 ((_ _) (eof-error? eof-error?) (eof-value eof-value)) (let* ((s (jolt-invoke (var-deref "clojure.core" "deref") buf)) (r (jolt-invoke (var-deref "clojure.core" "__parse-next") s))) (if (jolt-nil? r) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) (let* ((_o$2667 eof-value) (_o$2668 "")) (jolt-vector _o$2667 _o$2668))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-nth r 1)) (let* ((_o$2671 (jolt-nth r 0)) (_o$2672 (jolt-invoke (var-deref "clojure.core" "subs") s 0 (let* ((_a$2669 (jolt-count s)) (_a$2670 (jolt-count (jolt-nth r 1)))) (jolt-n- _a$2669 _a$2670))))) (jolt-vector _o$2671 _o$2672))))))))) (jolt-hash-map _o$2673 _o$2674 _o$2675 _o$2676 _o$2677 _o$2678)) "IReader")))))) __string-reader) (let* ((_o$2679 (keyword #f "doc")) (_o$2680 "A reader over string s (the with-in-str expansion calls this).")) (jolt-hash-map _o$2679 _o$2680)))) + (def-var! "clojure.core" "__string-reader" (letrec ((__string-reader (lambda (s) (let fnrec2234 ((s s)) (let* ((buf (jolt-invoke (var-deref "clojure.core" "atom") s))) (jolt-invoke (var-deref "clojure.core" "make-reified") (let* ((_o$2244 (keyword #f "-read+string")) (_o$2245 (lambda (_ eof-error? eof-value) (let fnrec2235 ((_ _) (eof-error? eof-error?) (eof-value eof-value)) (let* ((s (jolt-invoke (var-deref "clojure.core" "deref") buf)) (r (jolt-invoke (var-deref "clojure.core" "__parse-next") s))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") r)) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) (let* ((_o$2236 eof-value) (_o$2237 "")) (jolt-vector _o$2236 _o$2237))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-nth r 1)) (let* ((_o$2240 (jolt-nth r 0)) (_o$2241 (jolt-invoke (var-deref "clojure.core" "subs") s 0 (let* ((_a$2238 (jolt-count s)) (_a$2239 (jolt-count (jolt-nth r 1)))) (- _a$2238 _a$2239))))) (jolt-vector _o$2240 _o$2241)))))))) (_o$2246 (keyword #f "-read-line")) (_o$2247 (lambda (_) (let fnrec2242 ((_ _)) (let* ((cur (jolt-invoke (var-deref "clojure.core" "deref") buf))) (if (jolt-pos? (jolt-count cur)) (let* ((i (jolt-invoke (var-deref "clojure.core" "str-find") "\n" cur))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") i)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf "") cur) (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-invoke (var-deref "clojure.core" "subs") cur (jolt-inc i))) (jolt-invoke (var-deref "clojure.core" "subs") cur 0 i)))) jolt-nil))))) (_o$2248 (keyword #f "-read-form")) (_o$2249 (lambda (_) (let fnrec2243 ((_ _)) (let* ((r (jolt-invoke (var-deref "clojure.core" "__parse-next") (jolt-invoke (var-deref "clojure.core" "deref") buf)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") r)) (var-deref "clojure.core" "reader-eof") (begin (jolt-invoke (var-deref "clojure.core" "reset!") buf (jolt-nth r 1)) (jolt-nth r 0)))))))) (jolt-hash-map _o$2244 _o$2245 _o$2246 _o$2247 _o$2248 _o$2249)) "IReader")))))) __string-reader))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "stdin-buf" (jolt-invoke (var-deref "clojure.core" "atom") "") (let* ((_o$2681 (keyword #f "private")) (_o$2682 #t)) (jolt-hash-map _o$2681 _o$2682)))) + (def-var-with-meta! "clojure.core" "stdin-buf" (jolt-invoke (var-deref "clojure.core" "atom") "") (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "*in*" (jolt-invoke (var-deref "clojure.core" "make-reified") (let* ((_o$2696 (keyword #f "-read-line")) (_o$2697 (lambda (_) (let fnrec2683 ((_ _)) (let* ((cur (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf")))) (if (jolt-pos? (jolt-count cur)) (let* ((i (jolt-invoke (var-deref "clojure.core" "str-find") "\n" cur))) (if (jolt-nil? i) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") "") cur) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-invoke (var-deref "clojure.core" "subs") cur (jolt-inc i))) (jolt-invoke (var-deref "clojure.core" "subs") cur 0 i)))) (jolt-invoke (var-deref "clojure.core" "__stdin-read-line"))))))) (_o$2698 (keyword #f "-read-form")) (_o$2699 (lambda (_) (let fnrec2684 ((_ _)) (let* () (let loop2685 () (let* ((r (jolt-invoke (var-deref "clojure.core" "__parse-next") (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf"))))) (if (jolt-nil? r) (let* ((line (jolt-invoke (var-deref "clojure.core" "__stdin-read-line")))) (if (jolt-nil? line) (var-deref "clojure.core" "reader-eof") (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "stdin-buf") (lambda (b) (let fnrec2686 ((b b)) (jolt-invoke (var-deref "clojure.core" "str") b line "\n")))) (loop2685 )))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-nth r 1)) (jolt-nth r 0))))))))) (_o$2700 (keyword #f "-read+string")) (_o$2701 (lambda (_ eof-error? eof-value) (let fnrec2687 ((_ _) (eof-error? eof-error?) (eof-value eof-value)) (let* () (let loop2688 () (let* ((s (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf"))) (r (jolt-invoke (var-deref "clojure.core" "__parse-next") s))) (if (jolt-nil? r) (let* ((line (jolt-invoke (var-deref "clojure.core" "__stdin-read-line")))) (if (jolt-nil? line) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) (let* ((_o$2689 eof-value) (_o$2690 "")) (jolt-vector _o$2689 _o$2690))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "stdin-buf") (lambda (b) (let fnrec2691 ((b b)) (jolt-invoke (var-deref "clojure.core" "str") b line "\n")))) (loop2688 )))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-nth r 1)) (let* ((_o$2694 (jolt-nth r 0)) (_o$2695 (jolt-invoke (var-deref "clojure.core" "subs") s 0 (let* ((_a$2692 (jolt-count s)) (_a$2693 (jolt-count (jolt-nth r 1)))) (jolt-n- _a$2692 _a$2693))))) (jolt-vector _o$2694 _o$2695))))))))))) (jolt-hash-map _o$2696 _o$2697 _o$2698 _o$2699 _o$2700 _o$2701)) "IReader") (let* ((_o$2702 (keyword #f "dynamic")) (_o$2703 #t)) (jolt-hash-map _o$2702 _o$2703)))) + (def-var-with-meta! "clojure.core" "*in*" (jolt-invoke (var-deref "clojure.core" "make-reified") (let* ((_o$2263 (keyword #f "-read+string")) (_o$2264 (lambda (_ eof-error? eof-value) (let fnrec2250 ((_ _) (eof-error? eof-error?) (eof-value eof-value)) (let* () (let loop2251 () (let* ((s (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf"))) (r (jolt-invoke (var-deref "clojure.core" "__parse-next") s))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") r)) (let* ((line (jolt-invoke (var-deref "clojure.core" "__stdin-read-line")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") line)) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) (let* ((_o$2252 eof-value) (_o$2253 "")) (jolt-vector _o$2252 _o$2253))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "stdin-buf") (lambda (b) (let fnrec2254 ((b b)) (jolt-invoke (var-deref "clojure.core" "str") b line "\n")))) (loop2251 )))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-nth r 1)) (let* ((_o$2257 (jolt-nth r 0)) (_o$2258 (jolt-invoke (var-deref "clojure.core" "subs") s 0 (let* ((_a$2255 (jolt-count s)) (_a$2256 (jolt-count (jolt-nth r 1)))) (- _a$2255 _a$2256))))) (jolt-vector _o$2257 _o$2258)))))))))) (_o$2265 (keyword #f "-read-line")) (_o$2266 (lambda (_) (let fnrec2259 ((_ _)) (let* ((cur (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf")))) (if (jolt-pos? (jolt-count cur)) (let* ((i (jolt-invoke (var-deref "clojure.core" "str-find") "\n" cur))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") i)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") "") cur) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-invoke (var-deref "clojure.core" "subs") cur (jolt-inc i))) (jolt-invoke (var-deref "clojure.core" "subs") cur 0 i)))) (jolt-invoke (var-deref "clojure.core" "__stdin-read-line"))))))) (_o$2267 (keyword #f "-read-form")) (_o$2268 (lambda (_) (let fnrec2260 ((_ _)) (let* () (let loop2261 () (let* ((r (jolt-invoke (var-deref "clojure.core" "__parse-next") (jolt-invoke (var-deref "clojure.core" "deref") (var-deref "clojure.core" "stdin-buf"))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") r)) (let* ((line (jolt-invoke (var-deref "clojure.core" "__stdin-read-line")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") line)) (var-deref "clojure.core" "reader-eof") (begin (jolt-invoke (var-deref "clojure.core" "swap!") (var-deref "clojure.core" "stdin-buf") (lambda (b) (let fnrec2262 ((b b)) (jolt-invoke (var-deref "clojure.core" "str") b line "\n")))) (loop2261 )))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (var-deref "clojure.core" "stdin-buf") (jolt-nth r 1)) (jolt-nth r 0)))))))))) (jolt-hash-map _o$2263 _o$2264 _o$2265 _o$2266 _o$2267 _o$2268)) "IReader") (jolt-hash-map (keyword #f "dynamic") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "read-line" (letrec ((read-line (lambda () (let fnrec2704 () (jolt-invoke (var-deref "clojure.core" "-read-line") (var-deref "clojure.core" "*in*")))))) read-line) (let* ((_o$2705 (keyword #f "doc")) (_o$2706 "Reads the next line from the stream that is the current value of *in*.\n Returns nil at EOF.")) (jolt-hash-map _o$2705 _o$2706)))) + (def-var! "clojure.core" "read-line" (letrec ((read-line (lambda () (let fnrec2269 () (jolt-invoke (var-deref "clojure.core" "-read-line") (var-deref "clojure.core" "*in*")))))) read-line))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "read" (letrec ((read (case-lambda (() (let fnrec2707 () (read (var-deref "clojure.core" "*in*")))) ((stream) (let fnrec2708 ((stream stream)) (let* ((v (jolt-invoke (var-deref "clojure.core" "-read-form") stream))) (if (jolt= v (var-deref "clojure.core" "reader-eof")) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) v)))) ((stream eof-error? eof-value) (let fnrec2709 ((stream stream) (eof-error? eof-error?) (eof-value eof-value)) (let* ((v (jolt-invoke (var-deref "clojure.core" "-read-form") stream))) (if (jolt= v (var-deref "clojure.core" "reader-eof")) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) eof-value) v))))))) read) (let* ((_o$2710 (keyword #f "doc")) (_o$2711 "Reads the next object from stream (defaults to *in*). At EOF, throws \x2014;\n or returns eof-value when eof-error? is false.")) (jolt-hash-map _o$2710 _o$2711)))) + (def-var! "clojure.core" "read" (letrec ((read (case-lambda (() (let fnrec2270 () (jolt-invoke read (var-deref "clojure.core" "*in*")))) ((stream) (let fnrec2271 ((stream stream)) (let* ((v (jolt-invoke (var-deref "clojure.core" "-read-form") stream))) (if (jolt= v (var-deref "clojure.core" "reader-eof")) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) v)))) ((stream eof-error? eof-value) (let fnrec2272 ((stream stream) (eof-error? eof-error?) (eof-value eof-value)) (let* ((v (jolt-invoke (var-deref "clojure.core" "-read-form") stream))) (if (jolt= v (var-deref "clojure.core" "reader-eof")) (if (jolt-truthy? eof-error?) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map))) eof-value) v))))))) read))) (guard (e (#t #f)) (def-var! "clojure.core" "with-in-str" - (lambda (s . body) (let fnrec2712 ((s s) (body (list->cseq body))) (let* ((_a$2719 (var-deref "clojure.core" "__sqcat")) (_a$2720 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "binding"))) (_a$2721 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2716 (var-deref "clojure.core" "__sqvec")) (_a$2717 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "*in*"))) (_a$2718 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2713 (var-deref "clojure.core" "__sqcat")) (_a$2714 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "__string-reader"))) (_a$2715 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$2713 _a$2714 _a$2715))))) (jolt-invoke _a$2716 _a$2717 _a$2718)))) (_a$2722 body)) (jolt-invoke _a$2719 _a$2720 _a$2721 _a$2722))))) + (lambda (s . body) (let fnrec2273 ((s s) (body (list->cseq body))) (let* ((_a$2280 (var-deref "clojure.core" "__sqcat")) (_a$2281 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "binding"))) (_a$2282 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2277 (var-deref "clojure.core" "__sqvec")) (_a$2278 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "*in*"))) (_a$2279 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$2274 (var-deref "clojure.core" "__sqcat")) (_a$2275 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "__string-reader"))) (_a$2276 (jolt-invoke (var-deref "clojure.core" "__sq1") s))) (jolt-invoke _a$2274 _a$2275 _a$2276))))) (jolt-invoke _a$2277 _a$2278 _a$2279)))) (_a$2283 body)) (jolt-invoke _a$2280 _a$2281 _a$2282 _a$2283))))) (mark-macro! "clojure.core" "with-in-str")) (guard (e (#t #f)) - (def-var! "clojure.core" "read+string" (letrec ((read+string (case-lambda (() (let fnrec2723 () (read+string (var-deref "clojure.core" "*in*")))) ((stream) (let fnrec2724 ((stream stream)) (read+string stream #t jolt-nil))) ((stream eof-error? eof-value) (let fnrec2725 ((stream stream) (eof-error? eof-error?) (eof-value eof-value)) (jolt-invoke (var-deref "clojure.core" "-read+string") stream eof-error? eof-value)))))) read+string))) + (def-var! "clojure.core" "read+string" (letrec ((read+string (case-lambda (() (let fnrec2284 () (jolt-invoke read+string (var-deref "clojure.core" "*in*")))) ((stream) (let fnrec2285 ((stream stream)) (jolt-invoke read+string stream #t jolt-nil))) ((stream eof-error? eof-value) (let fnrec2286 ((stream stream) (eof-error? eof-error?) (eof-value eof-value)) (jolt-invoke (var-deref "clojure.core" "-read+string") stream eof-error? eof-value)))))) read+string))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "line-seq" (letrec ((line-seq (lambda (rdr) (let fnrec2726 ((rdr rdr)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") rdr)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "str-split") "\n" rdr)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2727 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((line (jolt-invoke (var-deref "clojure.core" "-read-line") rdr))) (if (jolt-truthy? line) (jolt-cons line (line-seq rdr)) jolt-nil))))))))))) line-seq) (let* ((_o$2728 (keyword #f "doc")) (_o$2729 "Returns the lines of text from rdr as a lazy sequence of strings, as by\n read-line. (Jolt extension kept from the old kernel stub: a plain string\n splits into its lines.)")) (jolt-hash-map _o$2728 _o$2729)))) + (def-var! "clojure.core" "line-seq" (letrec ((line-seq (lambda (rdr) (let fnrec2287 ((rdr rdr)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") rdr)) (jolt-seq (jolt-invoke (var-deref "clojure.core" "str-split") "\n" rdr)) (jolt-invoke (var-deref "clojure.core" "make-lazy-seq") (lambda () (let fnrec2288 () (jolt-invoke (var-deref "clojure.core" "coll->cells") (let* ((line (jolt-invoke (var-deref "clojure.core" "-read-line") rdr))) (if (jolt-truthy? line) (jolt-cons line (jolt-invoke line-seq rdr)) jolt-nil))))))))))) line-seq))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol "clojure.core" "print-method") (lambda (x writer) (let fnrec2730 ((x x) (writer writer)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") x) (keyword #f "type")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") t)) t (jolt-invoke (var-deref "clojure.core" "__type-tag") x))))))) + (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol #f "print-method") (lambda (x writer) (let fnrec2289 ((x x) (writer writer)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") x) (keyword #f "type")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") t)) t (jolt-invoke (var-deref "clojure.core" "type") x))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword #f "default") (lambda (o w) (let fnrec2731 ((o o) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "__pr-str1") o))) jolt-nil))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword #f "default") (lambda (o w) (let fnrec2290 ((o o) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "__pr-str1") o))) jolt-nil))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol "clojure.core" "print-dup") (lambda (x writer) (let fnrec2732 ((x x) (writer writer)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") x) (keyword #f "type")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") t)) t (jolt-invoke (var-deref "clojure.core" "__type-tag") x))))))) + (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol #f "print-dup") (lambda (x writer) (let fnrec2291 ((x x) (writer writer)) (let* ((t (jolt-get (jolt-invoke (var-deref "clojure.core" "meta") x) (keyword #f "type")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") t)) t (jolt-invoke (var-deref "clojure.core" "type") x))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-dup") (keyword #f "default") (lambda (o w) (let fnrec2733 ((o o) (w w)) (jolt-invoke (var-deref "clojure.core" "print-method") o w))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-dup") (keyword #f "default") (lambda (o w) (let fnrec2292 ((o o) (w w)) (jolt-invoke (var-deref "clojure.core" "print-method") o w))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "uuid") (lambda (u w) (let fnrec2734 ((u u) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#uuid \"" (jolt-get u (keyword #f "str")) "\""))) jolt-nil))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "uuid") (lambda (u w) (let fnrec2293 ((u u) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#uuid \"" (jolt-get u (keyword #f "str")) "\""))) jolt-nil))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "regex") (lambda (re w) (let fnrec2735 ((re re) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#\"" (jolt-get re (keyword #f "source")) "\""))) jolt-nil))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "regex") (lambda (re w) (let fnrec2294 ((re re) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#\"" (jolt-get re (keyword #f "source")) "\""))) jolt-nil))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "transient") (lambda (t w) (let fnrec2736 ((t t) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#"))) jolt-nil))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "transient") (lambda (t w) (let fnrec2295 ((t t) (w w)) (begin (record-method-dispatch w "write" (jolt-vector (jolt-invoke (var-deref "clojure.core" "str") "#"))) jolt-nil))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "chan") (lambda (c w) (let fnrec2737 ((c c) (w w)) (begin (record-method-dispatch w "write" (jolt-vector "#")) jolt-nil))) "clojure.core")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "print-method") (keyword "jolt" "chan") (lambda (c w) (let fnrec2296 ((c c) (w w)) (begin (record-method-dispatch w "write" (jolt-vector "#")) jolt-nil))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "agent" (letrec ((agent (lambda (state . _opts) (let fnrec2738 ((state state) (_opts (list->cseq _opts))) (jolt-invoke (var-deref "clojure.core" "atom") state))))) agent) (let* ((_o$2739 (keyword #f "doc")) (_o$2740 "Creates an agent (an atom on jolt \x2014; synchronous, no async dispatch).")) (jolt-hash-map _o$2739 _o$2740)))) + (def-var! "clojure.core" "agent" (letrec ((agent (lambda (state . _opts) (let fnrec2297 ((state state) (_opts (list->cseq _opts))) (jolt-invoke (var-deref "clojure.core" "atom") state))))) agent))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "send-off" (letrec ((send-off (lambda (a f . args) (let fnrec2741 ((a a) (f f) (args (list->cseq args))) (begin (jolt-apply (var-deref "clojure.core" "swap!") a f args) a))))) send-off) (let* ((_o$2742 (keyword #f "doc")) (_o$2743 "Apply (action state & args) to the agent's state immediately; return the agent.")) (jolt-hash-map _o$2742 _o$2743)))) + (def-var! "clojure.core" "send-off" (letrec ((send-off (lambda (a f . args) (let fnrec2298 ((a a) (f f) (args (list->cseq args))) (begin (jolt-apply (var-deref "clojure.core" "swap!") a f args) a))))) send-off))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "send" (letrec ((send (lambda (a f . args) (let fnrec2744 ((a a) (f f) (args (list->cseq args))) (begin (jolt-apply (var-deref "clojure.core" "swap!") a f args) a))))) send) (let* ((_o$2745 (keyword #f "doc")) (_o$2746 "Like send-off on jolt (no separate thread pool).")) (jolt-hash-map _o$2745 _o$2746)))) + (def-var! "clojure.core" "send" (letrec ((send (lambda (a f . args) (let fnrec2299 ((a a) (f f) (args (list->cseq args))) (begin (jolt-apply (var-deref "clojure.core" "swap!") a f args) a))))) send))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.core" "agent-error" (letrec ((agent-error (lambda (_a) (let fnrec2747 ((_a _a)) jolt-nil)))) agent-error) (let* ((_o$2748 (keyword #f "doc")) (_o$2749 "jolt agents never enter an error state.")) (jolt-hash-map _o$2748 _o$2749)))) + (def-var! "clojure.core" "agent-error" (letrec ((agent-error (lambda (_a) (let fnrec2300 ((_a _a)) jolt-nil)))) agent-error))) (guard (e (#t #f)) - (def-var! "clojure.string" "blank?" (letrec ((blank? (lambda (s) (let fnrec2442 ((s s)) (if (jolt-nil? s) #t (jolt= 0 (jolt-count (jolt-invoke (var-deref "clojure.core" "str-trim") s)))))))) blank?))) + (def-var! "clojure.string" "blank?" (letrec ((blank? (lambda (s) (let fnrec2031 ((s s)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") s)) #t (jolt= 0 (jolt-count (jolt-invoke (var-deref "clojure.core" "str-trim") s)))))))) blank?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.string" "to-str" (letrec ((to-str (lambda (s) (let fnrec2443 ((s s)) (if (jolt-nil? s) (jolt-throw (host-new "NullPointerException" "s")) (record-method-dispatch s "toString" (jolt-vector))))))) to-str) (let* ((_o$2444 (keyword #f "private")) (_o$2445 #t)) (jolt-hash-map _o$2444 _o$2445)))) + (def-var! "clojure.string" "capitalize" (letrec ((capitalize (lambda (s) (let fnrec2032 ((s s)) (if (< 1 (jolt-count s)) (let* ((_a$2033 (var-deref "clojure.core" "str")) (_a$2034 (jolt-invoke (var-deref "clojure.core" "str-upper") (jolt-invoke (var-deref "clojure.core" "subs") s 0 1))) (_a$2035 (jolt-invoke (var-deref "clojure.core" "str-lower") (jolt-invoke (var-deref "clojure.core" "subs") s 1)))) (jolt-invoke _a$2033 _a$2034 _a$2035)) (jolt-invoke (var-deref "clojure.core" "str-upper") s)))))) capitalize))) (guard (e (#t #f)) - (def-var! "clojure.string" "capitalize" (letrec ((capitalize (lambda (s) (let fnrec2446 ((s s)) (let* ((s (jolt-invoke (var-deref "clojure.string" "to-str") s))) (if (jolt-n< 1 (jolt-count s)) (let* ((_a$2447 (var-deref "clojure.core" "str")) (_a$2448 (jolt-invoke (var-deref "clojure.core" "str-upper") (jolt-invoke (var-deref "clojure.core" "subs") s 0 1))) (_a$2449 (jolt-invoke (var-deref "clojure.core" "str-lower") (jolt-invoke (var-deref "clojure.core" "subs") s 1)))) (jolt-invoke _a$2447 _a$2448 _a$2449)) (jolt-invoke (var-deref "clojure.core" "str-upper") s))))))) capitalize))) + (def-var! "clojure.string" "lower-case" (letrec ((lower-case (lambda (s) (let fnrec2036 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-lower") s))))) lower-case))) (guard (e (#t #f)) - (def-var! "clojure.string" "lower-case" (letrec ((lower-case (lambda (s) (let fnrec2450 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-lower") (jolt-invoke (var-deref "clojure.string" "to-str") s)))))) lower-case))) + (def-var! "clojure.string" "upper-case" (letrec ((upper-case (lambda (s) (let fnrec2037 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-upper") s))))) upper-case))) (guard (e (#t #f)) - (def-var! "clojure.string" "upper-case" (letrec ((upper-case (lambda (s) (let fnrec2451 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-upper") (jolt-invoke (var-deref "clojure.string" "to-str") s)))))) upper-case))) + (def-var! "clojure.string" "includes?" (letrec ((includes? (lambda (s substr) (let fnrec2038 ((s s) (substr substr)) (jolt-not (jolt-invoke (var-deref "clojure.core" "nil?") (jolt-invoke (var-deref "clojure.core" "str-find") substr s))))))) includes?))) (guard (e (#t #f)) - (def-var! "clojure.string" "includes?" (letrec ((includes? (lambda (s substr) (let fnrec2452 ((s s) (substr substr)) (jolt-not (jolt-nil? (jolt-invoke (var-deref "clojure.core" "str-find") substr (jolt-invoke (var-deref "clojure.string" "to-str") s)))))))) includes?))) + (def-var! "clojure.string" "join" (letrec ((join (case-lambda ((coll) (let fnrec2039 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "str-join") coll))) ((separator coll) (let fnrec2040 ((separator separator) (coll coll)) (jolt-invoke (var-deref "clojure.core" "str-join") coll separator)))))) join))) (guard (e (#t #f)) - (def-var! "clojure.string" "join" (letrec ((join (case-lambda ((coll) (let fnrec2453 ((coll coll)) (jolt-invoke (var-deref "clojure.core" "str-join") coll))) ((separator coll) (let fnrec2454 ((separator separator) (coll coll)) (jolt-invoke (var-deref "clojure.core" "str-join") coll separator)))))) join))) + (def-var! "clojure.string" "replace" (letrec ((replace (lambda (s match replacement) (let fnrec2041 ((s s) (match match) (replacement replacement)) (jolt-invoke (var-deref "clojure.core" "str-replace-all") match replacement s))))) replace))) (guard (e (#t #f)) - (def-var! "clojure.string" "replace" (letrec ((replace (lambda (s match replacement) (let fnrec2455 ((s s) (match match) (replacement replacement)) (jolt-invoke (var-deref "clojure.core" "str-replace-all") match replacement (jolt-invoke (var-deref "clojure.string" "to-str") s)))))) replace))) + (def-var! "clojure.string" "replace-first" (letrec ((replace-first (lambda (s match replacement) (let fnrec2042 ((s s) (match match) (replacement replacement)) (jolt-invoke (var-deref "clojure.core" "str-replace") match replacement s))))) replace-first))) (guard (e (#t #f)) - (def-var! "clojure.string" "replace-first" (letrec ((replace-first (lambda (s match replacement) (let fnrec2456 ((s s) (match match) (replacement replacement)) (jolt-invoke (var-deref "clojure.core" "str-replace") match replacement (jolt-invoke (var-deref "clojure.string" "to-str") s)))))) replace-first))) + (def-var! "clojure.string" "reverse" (letrec ((reverse (lambda (s) (let fnrec2043 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s))))) reverse))) (guard (e (#t #f)) - (def-var! "clojure.string" "reverse" (letrec ((reverse (lambda (s) (let fnrec2457 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s))))) reverse))) + (def-var! "clojure.string" "str-reverse" (letrec ((str-reverse (lambda (s) (let fnrec2044 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s))))) str-reverse))) (guard (e (#t #f)) - (def-var! "clojure.string" "str-reverse" (letrec ((str-reverse (lambda (s) (let fnrec2458 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s))))) str-reverse))) + (def-var! "clojure.string" "split" (letrec ((split (case-lambda ((s re) (let fnrec2045 ((s s) (re re)) (jolt-invoke split s re 0))) ((s re limit) (let fnrec2046 ((s s) (re re) (limit limit)) (let* ((parts (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "str-split") re s (if (jolt-pos? limit) limit jolt-nil))))) (if (jolt-truthy? (let* ((and__25__auto (jolt-zero? limit))) (if (jolt-truthy? and__25__auto) (> (jolt-count parts) 1) and__25__auto))) (let* ((v parts)) (let loop2047 ((v v)) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq v))) (if (jolt-truthy? and__25__auto) (jolt= "" (jolt-peek v)) and__25__auto))) (loop2047 (jolt-pop v)) v))) parts))))))) split))) (guard (e (#t #f)) - (def-var! "clojure.string" "split" (letrec ((split (case-lambda ((s re) (let fnrec2459 ((s s) (re re)) (split s re 0))) ((s re limit) (let fnrec2460 ((s s) (re re) (limit limit)) (let* ((parts (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "str-split") re s (if (jolt-pos? limit) limit jolt-nil))))) (if (let* ((and__25__auto (jolt-zero? limit))) (if (jolt-truthy? and__25__auto) (jolt-n> (jolt-count parts) 1) and__25__auto)) (let* ((v parts)) (let loop2461 ((v v)) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq v))) (if (jolt-truthy? and__25__auto) (jolt= "" (jolt-peek v)) and__25__auto))) (loop2461 (jolt-pop v)) v))) parts))))))) split))) + (def-var! "clojure.string" "split-lines" (letrec ((split-lines (lambda (s) (let fnrec2048 ((s s)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "str-split") (jolt-regex "\\r?\\n") s)))))) split-lines))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.string" "split-lines" (letrec ((split-lines (lambda (s) (let fnrec2462 ((s s)) (jolt-invoke (var-deref "clojure.core" "vec") (jolt-invoke (var-deref "clojure.core" "str-split") (jolt-regex "\\r?\\n") s)))))) split-lines) (let* ((_o$2463 (keyword #f "doc")) (_o$2464 "Split s on \\n or \\r\\n, returning a vector of lines.")) (jolt-hash-map _o$2463 _o$2464)))) + (def-var! "clojure.string" "starts-with?" (letrec ((starts-with? (lambda (s substr) (let fnrec2049 ((s s) (substr substr)) (let* ((slen (jolt-count s)) (slen2 (jolt-count substr))) (let* ((and__25__auto (>= slen slen2))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-invoke (var-deref "clojure.core" "subs") s 0 slen2) substr) and__25__auto))))))) starts-with?))) (guard (e (#t #f)) - (def-var! "clojure.string" "starts-with?" (letrec ((starts-with? (lambda (s substr) (let fnrec2465 ((s s) (substr substr)) (begin (if (jolt-nil? substr) (jolt-throw (host-new "NullPointerException" "substr")) jolt-nil) (let* ((s (jolt-invoke (var-deref "clojure.string" "to-str") s)) (slen (jolt-count s)) (slen2 (jolt-count substr))) (let* ((and__25__auto (jolt-n>= slen slen2))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-invoke (var-deref "clojure.core" "subs") s 0 slen2) substr) and__25__auto)))))))) starts-with?))) + (def-var! "clojure.string" "ends-with?" (letrec ((ends-with? (lambda (s substr) (let fnrec2050 ((s s) (substr substr)) (let* ((slen (jolt-count s)) (slen2 (jolt-count substr))) (let* ((and__25__auto (>= slen slen2))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-invoke (var-deref "clojure.core" "subs") s (- slen slen2)) substr) and__25__auto))))))) ends-with?))) (guard (e (#t #f)) - (def-var! "clojure.string" "ends-with?" (letrec ((ends-with? (lambda (s substr) (let fnrec2466 ((s s) (substr substr)) (begin (if (jolt-nil? substr) (jolt-throw (host-new "NullPointerException" "substr")) jolt-nil) (let* ((s (jolt-invoke (var-deref "clojure.string" "to-str") s)) (slen (jolt-count s)) (slen2 (jolt-count substr))) (let* ((and__25__auto (jolt-n>= slen slen2))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-invoke (var-deref "clojure.core" "subs") s (jolt-n- slen slen2)) substr) and__25__auto)))))))) ends-with?))) + (def-var! "clojure.string" "trim" (letrec ((trim (lambda (s) (let fnrec2051 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-trim") s))))) trim))) (guard (e (#t #f)) - (def-var! "clojure.string" "trim" (letrec ((trim (lambda (s) (let fnrec2467 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-trim") s))))) trim))) + (def-var! "clojure.string" "triml" (letrec ((triml (lambda (s) (let fnrec2052 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-triml") s))))) triml))) (guard (e (#t #f)) - (def-var! "clojure.string" "triml" (letrec ((triml (lambda (s) (let fnrec2468 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-triml") s))))) triml))) + (def-var! "clojure.string" "trimr" (letrec ((trimr (lambda (s) (let fnrec2053 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-trimr") s))))) trimr))) (guard (e (#t #f)) - (def-var! "clojure.string" "trimr" (letrec ((trimr (lambda (s) (let fnrec2469 ((s s)) (jolt-invoke (var-deref "clojure.core" "str-trimr") s))))) trimr))) + (def-var! "clojure.string" "escape" (letrec ((escape (lambda (s cmap) (let fnrec2054 ((s s) (cmap cmap)) (jolt-apply (var-deref "clojure.core" "str") (jolt-map (lambda (ch) (let fnrec2055 ((ch ch)) (let* ((temp__16__auto (jolt-invoke cmap ch))) (if (jolt-truthy? temp__16__auto) (let* ((rep temp__16__auto)) rep) (jolt-invoke (var-deref "clojure.core" "str") ch))))) s)))))) escape))) (guard (e (#t #f)) - (def-var! "clojure.string" "escape" (letrec ((escape (lambda (s cmap) (let fnrec2470 ((s s) (cmap cmap)) (begin (if (jolt-nil? s) (jolt-throw (host-new "NullPointerException" "s")) jolt-nil) (jolt-apply (var-deref "clojure.core" "str") (jolt-map (lambda (ch) (let fnrec2471 ((ch ch)) (let* ((temp__16__auto (jolt-invoke cmap ch))) (if (jolt-truthy? temp__16__auto) (let* ((rep temp__16__auto)) rep) (jolt-invoke (var-deref "clojure.core" "str") ch))))) s))))))) escape))) + (def-var! "clojure.string" "index-of" (letrec ((index-of (case-lambda ((s value) (let fnrec2056 ((s s) (value value)) (jolt-invoke (var-deref "clojure.core" "str-find") value s))) ((s value from) (let fnrec2057 ((s s) (value value) (from from)) (let* ((idx (jolt-invoke (var-deref "clojure.core" "str-find") value (jolt-invoke (var-deref "clojure.core" "subs") s from)))) (if (jolt-truthy? idx) (+ from idx) jolt-nil))))))) index-of))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.string" "index-of" (letrec ((index-of (case-lambda ((s value) (let fnrec2472 ((s s) (value value)) (jolt-invoke (var-deref "clojure.core" "str-find") value (jolt-invoke (var-deref "clojure.string" "to-str") s)))) ((s value from) (let fnrec2473 ((s s) (value value) (from from)) (let* ((idx (jolt-invoke (var-deref "clojure.core" "str-find") value (jolt-invoke (var-deref "clojure.core" "subs") (jolt-invoke (var-deref "clojure.string" "to-str") s) from)))) (if (jolt-truthy? idx) (jolt-n+ from idx) jolt-nil))))))) index-of) (let* ((_o$2474 (keyword #f "doc")) (_o$2475 "0-based index of the first occurrence of value in s, or nil.")) (jolt-hash-map _o$2474 _o$2475)))) + (def-var! "clojure.string" "last-index-of" (letrec ((last-index-of (case-lambda ((s value) (let fnrec2058 ((s s) (value value)) (let* ((r (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s)) (sval (jolt-invoke (var-deref "clojure.core" "str-reverse-b") value)) (idx (jolt-invoke (var-deref "clojure.core" "str-find") sval r))) (if (jolt-truthy? idx) (let* ((_a$2059 (jolt-count s)) (_a$2060 (+ idx (jolt-count value)))) (- _a$2059 _a$2060)) jolt-nil)))) ((s value from) (let fnrec2061 ((s s) (value value) (from from)) (let* ((sub (jolt-invoke (var-deref "clojure.core" "subs") s 0 from)) (r (jolt-invoke (var-deref "clojure.core" "str-reverse-b") sub)) (sval (jolt-invoke (var-deref "clojure.core" "str-reverse-b") value)) (idx (jolt-invoke (var-deref "clojure.core" "str-find") sval r))) (if (jolt-truthy? idx) (- from (+ idx (jolt-count value))) jolt-nil))))))) last-index-of))) (guard (e (#t #f)) - (def-var! "clojure.string" "last-index-of" (letrec ((last-index-of (case-lambda ((s value) (let fnrec2476 ((s s) (value value)) (let* ((r (jolt-invoke (var-deref "clojure.core" "str-reverse-b") s)) (sval (jolt-invoke (var-deref "clojure.core" "str-reverse-b") value)) (idx (jolt-invoke (var-deref "clojure.core" "str-find") sval r))) (if (jolt-truthy? idx) (let* ((_a$2477 (jolt-count s)) (_a$2478 (jolt-n+ idx (jolt-count value)))) (jolt-n- _a$2477 _a$2478)) jolt-nil)))) ((s value from) (let fnrec2479 ((s s) (value value) (from from)) (let* ((sub (jolt-invoke (var-deref "clojure.core" "subs") s 0 from)) (r (jolt-invoke (var-deref "clojure.core" "str-reverse-b") sub)) (sval (jolt-invoke (var-deref "clojure.core" "str-reverse-b") value)) (idx (jolt-invoke (var-deref "clojure.core" "str-find") sval r))) (if (jolt-truthy? idx) (jolt-n- from (jolt-n+ idx (jolt-count value))) jolt-nil))))))) last-index-of))) + (def-var! "clojure.string" "re-quote-replacement" (letrec ((re-quote-replacement (lambda (replacement) (let fnrec2062 ((replacement replacement)) (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$2064 (lambda (ch) (let fnrec2063 ((ch ch)) (let* ((c (jolt-invoke (var-deref "clojure.core" "str") ch))) (if (jolt-truthy? (let* ((or__26__auto (jolt= c "\\"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c "$")))) (jolt-invoke (var-deref "clojure.core" "str") "\\" c) c))))) (_a$2065 (jolt-seq replacement))) (jolt-map _a$2064 _a$2065))))))) re-quote-replacement))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.string" "re-quote-replacement" (letrec ((re-quote-replacement (lambda (replacement) (let fnrec2480 ((replacement replacement)) (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$2482 (lambda (ch) (let fnrec2481 ((ch ch)) (let* ((c (jolt-invoke (var-deref "clojure.core" "str") ch))) (if (let* ((or__26__auto (jolt= c "\\"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c "$"))) (jolt-invoke (var-deref "clojure.core" "str") "\\" c) c))))) (_a$2483 (jolt-seq replacement))) (jolt-map _a$2482 _a$2483))))))) re-quote-replacement) (let* ((_o$2484 (keyword #f "doc")) (_o$2485 "Escape special characters (backslash and dollar) in a regex replacement\n string so it is used literally rather than interpreted.")) (jolt-hash-map _o$2484 _o$2485)))) + (def-var! "clojure.string" "trim-newline" (letrec ((trim-newline (lambda (s) (let fnrec2066 ((s s)) (let* ((index (jolt-count s))) (let loop2067 ((index index)) (if (jolt-zero? index) "" (let* ((c (jolt-invoke (var-deref "clojure.core" "subs") s (jolt-dec index) index))) (if (jolt-truthy? (let* ((or__26__auto (jolt= c "\n"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c "\r")))) (loop2067 (jolt-dec index)) (jolt-invoke (var-deref "clojure.core" "subs") s 0 index)))))))))) trim-newline))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.string" "trim-newline" (letrec ((trim-newline (lambda (s) (let fnrec2486 ((s s)) (let* ((index (jolt-count s))) (let loop2487 ((index index)) (if (jolt-zero? index) "" (let* ((c (jolt-invoke (var-deref "clojure.core" "subs") s (jolt-dec index) index))) (if (let* ((or__26__auto (jolt= c "\n"))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= c "\r"))) (loop2487 (jolt-dec index)) (jolt-invoke (var-deref "clojure.core" "subs") s 0 index)))))))))) trim-newline) (let* ((_o$2488 (keyword #f "doc")) (_o$2489 "Removes all trailing newline \\n or return \\r characters from\n string. Similar to Perl's chomp.")) (jolt-hash-map _o$2488 _o$2489)))) + (def-var! "clojure.walk" "walk" (letrec ((walk (lambda (inner outer form) (let fnrec2068 ((inner inner) (outer outer) (form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (jolt-invoke outer (let* ((_a$2069 (var-deref "clojure.core" "with-meta")) (_a$2070 (jolt-invoke (var-deref "clojure.core" "vec") (jolt-map inner form))) (_a$2071 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2069 _a$2070 _a$2071))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "record?") form)) (jolt-invoke outer (jolt-reduce (lambda (r x) (let fnrec2072 ((r r) (x x)) (jolt-conj r (jolt-invoke inner x)))) form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") form)) (jolt-invoke outer (let* ((_a$2075 (var-deref "clojure.core" "with-meta")) (_a$2076 (let* ((_a$2073 (jolt-invoke (var-deref "clojure.core" "empty") form)) (_a$2074 (jolt-map inner form))) (jolt-into _a$2073 _a$2074))) (_a$2077 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2075 _a$2076 _a$2077))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "list?") form)) (jolt-invoke outer (let* ((_a$2078 (var-deref "clojure.core" "with-meta")) (_a$2079 (jolt-apply jolt-list (jolt-map inner form))) (_a$2080 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2078 _a$2079 _a$2080))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") form)) (jolt-invoke outer (let* ((_a$2081 (var-deref "clojure.core" "with-meta")) (_a$2082 (jolt-map inner form)) (_a$2083 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2081 _a$2082 _a$2083))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke outer form) jolt-nil)))))))))) walk))) (guard (e (#t #f)) - (def-var! "clojure.walk" "walk" (letrec ((walk (lambda (inner outer form) (let fnrec2490 ((inner inner) (outer outer) (form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (jolt-invoke outer (let* ((_a$2491 (var-deref "clojure.core" "with-meta")) (_a$2492 (jolt-invoke (var-deref "clojure.core" "vec") (jolt-map inner form))) (_a$2493 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2491 _a$2492 _a$2493))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "record?") form)) (jolt-invoke outer (jolt-reduce (lambda (r x) (let fnrec2494 ((r r) (x x)) (jolt-conj r (jolt-invoke inner x)))) form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") form)) (jolt-invoke outer (let* ((_a$2497 (var-deref "clojure.core" "with-meta")) (_a$2498 (let* ((_a$2495 (jolt-invoke (var-deref "clojure.core" "empty") form)) (_a$2496 (jolt-map inner form))) (jolt-into _a$2495 _a$2496))) (_a$2499 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2497 _a$2498 _a$2499))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "list?") form)) (jolt-invoke outer (let* ((_a$2500 (var-deref "clojure.core" "with-meta")) (_a$2501 (jolt-apply jolt-list (jolt-map inner form))) (_a$2502 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2500 _a$2501 _a$2502))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") form)) (jolt-invoke outer (let* ((_a$2503 (var-deref "clojure.core" "with-meta")) (_a$2504 (jolt-invoke (var-deref "clojure.core" "doall") (jolt-map inner form))) (_a$2505 (jolt-invoke (var-deref "clojure.core" "meta") form))) (jolt-invoke _a$2503 _a$2504 _a$2505))) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke outer form) jolt-nil)))))))))) walk))) + (def-var! "clojure.walk" "postwalk" (letrec ((postwalk (lambda (f form) (let fnrec2084 ((f f) (form form)) (jolt-invoke (var-deref "clojure.walk" "walk") (jolt-invoke (var-deref "clojure.core" "partial") postwalk f) f form))))) postwalk))) (guard (e (#t #f)) - (def-var! "clojure.walk" "postwalk" (letrec ((postwalk (lambda (f form) (let fnrec2506 ((f f) (form form)) (jolt-invoke (var-deref "clojure.walk" "walk") (jolt-invoke (var-deref "clojure.core" "partial") postwalk f) f form))))) postwalk))) + (def-var! "clojure.walk" "prewalk" (letrec ((prewalk (lambda (f form) (let fnrec2085 ((f f) (form form)) (let* ((_a$2086 (var-deref "clojure.walk" "walk")) (_a$2087 (jolt-invoke (var-deref "clojure.core" "partial") prewalk f)) (_a$2088 jolt-identity) (_a$2089 (jolt-invoke f form))) (jolt-invoke _a$2086 _a$2087 _a$2088 _a$2089)))))) prewalk))) (guard (e (#t #f)) - (def-var! "clojure.walk" "prewalk" (letrec ((prewalk (lambda (f form) (let fnrec2507 ((f f) (form form)) (let* ((_a$2508 (var-deref "clojure.walk" "walk")) (_a$2509 (jolt-invoke (var-deref "clojure.core" "partial") prewalk f)) (_a$2510 jolt-identity) (_a$2511 (jolt-invoke f form))) (jolt-invoke _a$2508 _a$2509 _a$2510 _a$2511)))))) prewalk))) + (def-var! "clojure.walk" "postwalk-demo" (letrec ((postwalk-demo (lambda (form) (let fnrec2090 ((form form)) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2091 ((x x)) (begin (jolt-invoke (var-deref "clojure.core" "print") "Walked: ") (jolt-invoke (var-deref "clojure.core" "prn") x) x))) form))))) postwalk-demo))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.walk" "postwalk-demo" (letrec ((postwalk-demo (lambda (form) (let fnrec2512 ((form form)) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2513 ((x x)) (begin (jolt-invoke (var-deref "clojure.core" "print") "Walked: ") (jolt-invoke (var-deref "clojure.core" "prn") x) x))) form))))) postwalk-demo) (let* ((_o$2514 (keyword #f "doc")) (_o$2515 "Demonstrates the behavior of postwalk by printing each form as it is walked.")) (jolt-hash-map _o$2514 _o$2515)))) + (def-var! "clojure.walk" "prewalk-demo" (letrec ((prewalk-demo (lambda (form) (let fnrec2092 ((form form)) (jolt-invoke (var-deref "clojure.walk" "prewalk") (lambda (x) (let fnrec2093 ((x x)) (begin (jolt-invoke (var-deref "clojure.core" "print") "Walked: ") (jolt-invoke (var-deref "clojure.core" "prn") x) x))) form))))) prewalk-demo))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.walk" "prewalk-demo" (letrec ((prewalk-demo (lambda (form) (let fnrec2516 ((form form)) (jolt-invoke (var-deref "clojure.walk" "prewalk") (lambda (x) (let fnrec2517 ((x x)) (begin (jolt-invoke (var-deref "clojure.core" "print") "Walked: ") (jolt-invoke (var-deref "clojure.core" "prn") x) x))) form))))) prewalk-demo) (let* ((_o$2518 (keyword #f "doc")) (_o$2519 "Demonstrates the behavior of prewalk by printing each form as it is walked.")) (jolt-hash-map _o$2518 _o$2519)))) + (def-var! "clojure.walk" "postwalk-replace" (letrec ((postwalk-replace (lambda (smap form) (let fnrec2094 ((smap smap) (form form)) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2095 ((x x)) (if (jolt-contains? smap x) (jolt-get smap x) x))) form))))) postwalk-replace))) (guard (e (#t #f)) - (def-var! "clojure.walk" "postwalk-replace" (letrec ((postwalk-replace (lambda (smap form) (let fnrec2520 ((smap smap) (form form)) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2521 ((x x)) (if (jolt-contains? smap x) (jolt-get smap x) x))) form))))) postwalk-replace))) + (def-var! "clojure.walk" "prewalk-replace" (letrec ((prewalk-replace (lambda (smap form) (let fnrec2096 ((smap smap) (form form)) (jolt-invoke (var-deref "clojure.walk" "prewalk") (lambda (x) (let fnrec2097 ((x x)) (if (jolt-contains? smap x) (jolt-get smap x) x))) form))))) prewalk-replace))) (guard (e (#t #f)) - (def-var! "clojure.walk" "prewalk-replace" (letrec ((prewalk-replace (lambda (smap form) (let fnrec2522 ((smap smap) (form form)) (jolt-invoke (var-deref "clojure.walk" "prewalk") (lambda (x) (let fnrec2523 ((x x)) (if (jolt-contains? smap x) (jolt-get smap x) x))) form))))) prewalk-replace))) + (def-var! "clojure.walk" "keywordize-keys" (letrec ((keywordize-keys (lambda (m) (let fnrec2098 ((m m)) (let* ((f (lambda (G__98) (let fnrec2099 ((G__98 G__98)) (let* ((G__99 G__98) (k (jolt-nth G__99 0 jolt-nil)) (v (jolt-nth G__99 1 jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") k)) (let* ((_o$2100 (jolt-invoke (var-deref "clojure.core" "keyword") k)) (_o$2101 v)) (jolt-vector _o$2100 _o$2101)) (let* ((_o$2102 k) (_o$2103 v)) (jolt-vector _o$2102 _o$2103)))))))) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2104 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2105 (jolt-hash-map)) (_a$2106 (jolt-map f x))) (jolt-into _a$2105 _a$2106)) x))) m)))))) keywordize-keys))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.walk" "macroexpand-all" (letrec ((macroexpand-all (lambda (form) (let fnrec2524 ((form form)) (jolt-invoke (var-deref "clojure.walk" "prewalk") (lambda (x) (let fnrec2525 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") x)) (jolt-invoke (var-deref "clojure.core" "macroexpand") x) x))) form))))) macroexpand-all) (let* ((_o$2526 (keyword #f "doc")) (_o$2527 "Recursively performs all possible macroexpansions in form.")) (jolt-hash-map _o$2526 _o$2527)))) + (def-var! "clojure.walk" "stringify-keys" (letrec ((stringify-keys (lambda (m) (let fnrec2107 ((m m)) (let* ((f (lambda (G__100) (let fnrec2108 ((G__100 G__100)) (let* ((G__101 G__100) (k (jolt-nth G__101 0 jolt-nil)) (v (jolt-nth G__101 1 jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") k)) (let* ((_o$2109 (jolt-invoke (var-deref "clojure.core" "name") k)) (_o$2110 v)) (jolt-vector _o$2109 _o$2110)) (let* ((_o$2111 k) (_o$2112 v)) (jolt-vector _o$2111 _o$2112)))))))) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2113 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2114 (jolt-hash-map)) (_a$2115 (jolt-map f x))) (jolt-into _a$2114 _a$2115)) x))) m)))))) stringify-keys))) (guard (e (#t #f)) - (def-var! "clojure.walk" "keywordize-keys" (letrec ((keywordize-keys (lambda (m) (let fnrec2528 ((m m)) (let* ((f (lambda (G__108) (let fnrec2529 ((G__108 G__108)) (let* ((G__109 G__108) (k (jolt-nth G__109 0 jolt-nil)) (v (jolt-nth G__109 1 jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") k)) (let* ((_o$2530 (jolt-invoke (var-deref "clojure.core" "keyword") k)) (_o$2531 v)) (jolt-vector _o$2530 _o$2531)) (let* ((_o$2532 k) (_o$2533 v)) (jolt-vector _o$2532 _o$2533)))))))) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2534 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2535 (jolt-hash-map)) (_a$2536 (jolt-map f x))) (jolt-into _a$2535 _a$2536)) x))) m)))))) keywordize-keys))) -(guard (e (#t #f)) - (def-var! "clojure.walk" "stringify-keys" (letrec ((stringify-keys (lambda (m) (let fnrec2537 ((m m)) (let* ((f (lambda (G__110) (let fnrec2538 ((G__110 G__110)) (let* ((G__111 G__110) (k (jolt-nth G__111 0 jolt-nil)) (v (jolt-nth G__111 1 jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "keyword?") k)) (let* ((_o$2539 (jolt-invoke (var-deref "clojure.core" "name") k)) (_o$2540 v)) (jolt-vector _o$2539 _o$2540)) (let* ((_o$2541 k) (_o$2542 v)) (jolt-vector _o$2541 _o$2542)))))))) (jolt-invoke (var-deref "clojure.walk" "postwalk") (lambda (x) (let fnrec2543 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2544 (jolt-hash-map)) (_a$2545 (jolt-map f x))) (jolt-into _a$2544 _a$2545)) x))) m)))))) stringify-keys))) -(guard (e (#t #f)) - (def-var-with-meta! "clojure.template" "apply-template" (letrec ((apply-template (lambda (argv expr _values) (let fnrec2375 ((argv argv) (expr expr) (_values _values)) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "vector?") argv)) (jolt-throw (host-new "AssertionError" "Assert failed: (vector? argv)")) jolt-nil) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "clojure.core" "symbol?") argv)) (jolt-throw (host-new "AssertionError" "Assert failed: (every? symbol? argv)")) jolt-nil) (jolt-invoke (var-deref "clojure.walk" "postwalk-replace") (jolt-invoke (var-deref "clojure.core" "zipmap") argv _values) expr)))))) apply-template) (let* ((_o$2376 (keyword #f "doc")) (_o$2377 "For use in macros. argv is an argument list, as in defn. expr is\n a quoted expression using the symbols in argv. values is a sequence\n of values to be used for the arguments.\n\n apply-template will recursively replace argument symbols in expr\n with their corresponding values, returning a modified expr.\n\n Example: (apply-template '[x] '(+ x x) '[2])\n ;=> (+ 2 2)")) (jolt-hash-map _o$2376 _o$2377)))) + (def-var! "clojure.template" "apply-template" (letrec ((apply-template (lambda (argv expr _values) (let fnrec1991 ((argv argv) (expr expr) (_values _values)) (begin (if (jolt-not (jolt-invoke (var-deref "clojure.core" "vector?") argv)) (jolt-throw (jolt-ex-info "Assert failed: (vector? argv)" (jolt-hash-map))) jolt-nil) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "every?") (var-deref "clojure.core" "symbol?") argv)) (jolt-throw (jolt-ex-info "Assert failed: (every? symbol? argv)" (jolt-hash-map))) jolt-nil) (jolt-invoke (var-deref "clojure.walk" "postwalk-replace") (jolt-invoke (var-deref "clojure.core" "zipmap") argv _values) expr)))))) apply-template))) (guard (e (#t #f)) (def-var! "clojure.template" "do-template" - (lambda (argv expr . _values) (let fnrec2378 ((argv argv) (expr expr) (_values (list->cseq _values))) (let* ((c (jolt-count argv))) (let* ((_a$2382 (var-deref "clojure.core" "__sqcat")) (_a$2383 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do"))) (_a$2384 (let* ((_a$2380 (lambda (a) (let fnrec2379 ((a a)) (jolt-invoke (var-deref "clojure.template" "apply-template") argv expr a)))) (_a$2381 (jolt-invoke (var-deref "clojure.core" "partition") c _values))) (jolt-map _a$2380 _a$2381)))) (jolt-invoke _a$2382 _a$2383 _a$2384)))))) + (lambda (argv expr . _values) (let fnrec1992 ((argv argv) (expr expr) (_values (list->cseq _values))) (let* ((c (jolt-count argv))) (let* ((_a$1996 (var-deref "clojure.core" "__sqcat")) (_a$1997 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "do"))) (_a$1998 (let* ((_a$1994 (lambda (a) (let fnrec1993 ((a a)) (jolt-invoke (var-deref "clojure.template" "apply-template") argv expr a)))) (_a$1995 (jolt-invoke (var-deref "clojure.core" "partition") c _values))) (jolt-map _a$1994 _a$1995)))) (jolt-invoke _a$1996 _a$1997 _a$1998)))))) (mark-macro! "clojure.template" "do-template")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.edn" "edn->value" (letrec ((edn->value (lambda (opts x) (let fnrec2385 ((opts opts) (x x)) (if (jolt= (keyword "jolt" "set") (jolt-get x (keyword "jolt" "type"))) (let* ((vs (let* ((_a$2387 (lambda (v) (let fnrec2386 ((v v)) (edn->value opts v)))) (_a$2388 (jolt-get x (keyword #f "value")))) (jolt-map _a$2387 _a$2388))) (st (jolt-invoke (var-deref "clojure.core" "set") vs))) (begin (if (let* ((_a$2389 (jolt-count st)) (_a$2390 (jolt-count vs))) (jolt-n< _a$2389 _a$2390)) (jolt-throw (host-new "IllegalArgumentException" (jolt-invoke (var-deref "clojure.core" "str") "Duplicate key: " (jolt-invoke (var-deref "clojure.core" "pr-str") (let* ((_a$2392 (var-deref "clojure.core" "some")) (_a$2393 (lambda (G__106) (let fnrec2391 ((G__106 G__106)) (let* ((G__107 G__106) (k (jolt-nth G__107 0 jolt-nil)) (n (jolt-nth G__107 1 jolt-nil))) (if (jolt-n< 1 n) k jolt-nil))))) (_a$2394 (jolt-invoke (var-deref "clojure.core" "frequencies") vs))) (jolt-invoke _a$2392 _a$2393 _a$2394)))))) jolt-nil) (jolt-invoke (var-deref "clojure.core" "with-meta") st (edn->value opts (jolt-invoke (var-deref "clojure.core" "meta") x))))) (if (jolt= (keyword "jolt" "tagged") (jolt-get x (keyword "jolt" "type"))) (let* ((tag (jolt-get x (keyword #f "tag"))) (v (edn->value opts (jolt-get x (keyword #f "form")))) (tag-sym (let* ((n (jolt-invoke (var-deref "clojure.core" "name") tag))) (jolt-invoke (var-deref "clojure.core" "symbol") (if (jolt= "#" (jolt-invoke (var-deref "clojure.core" "subs") n 0 1)) (jolt-invoke (var-deref "clojure.core" "subs") n 1) n)))) (custom (jolt-get (jolt-get opts (keyword #f "readers")) tag-sym))) (if (jolt-truthy? custom) (jolt-invoke custom v) (if (jolt-contains? (let* ((_o$2395 (jolt-symbol #f "inst")) (_o$2396 (jolt-symbol #f "uuid")) (_o$2397 (jolt-symbol #f "bigdec"))) (jolt-hash-set _o$2395 _o$2396 _o$2397)) tag-sym) (jolt-invoke (var-deref "clojure.core" "__read-tagged") tag v) (if (jolt-truthy? (jolt-get opts (keyword #f "default"))) (jolt-invoke (jolt-get opts (keyword #f "default")) tag-sym v) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "__read-tagged") tag v) jolt-nil))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2403 (var-deref "clojure.core" "with-meta")) (_a$2404 (let* ((_a$2401 (jolt-hash-map)) (_a$2402 (jolt-map (lambda (e) (let fnrec2398 ((e e)) (let* ((_o$2399 (edn->value opts (jolt-invoke (var-deref "clojure.core" "key") e))) (_o$2400 (edn->value opts (jolt-invoke (var-deref "clojure.core" "val") e)))) (jolt-vector _o$2399 _o$2400)))) x))) (jolt-into _a$2401 _a$2402))) (_a$2405 (edn->value opts (jolt-invoke (var-deref "clojure.core" "meta") x)))) (jolt-invoke _a$2403 _a$2404 _a$2405)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") x)) (let* ((_a$2407 (var-deref "clojure.core" "with-meta")) (_a$2408 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (v) (let fnrec2406 ((v v)) (edn->value opts v))) x)) (_a$2409 (edn->value opts (jolt-invoke (var-deref "clojure.core" "meta") x)))) (jolt-invoke _a$2407 _a$2408 _a$2409)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") x)) (let* ((_a$2411 (var-deref "clojure.core" "with-meta")) (_a$2412 (jolt-invoke (var-deref "clojure.core" "set") (jolt-map (lambda (v) (let fnrec2410 ((v v)) (edn->value opts v))) x))) (_a$2413 (edn->value opts (jolt-invoke (var-deref "clojure.core" "meta") x)))) (jolt-invoke _a$2411 _a$2412 _a$2413)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") x)) (let* ((_a$2415 (var-deref "clojure.core" "with-meta")) (_a$2416 (jolt-apply jolt-list (jolt-map (lambda (v) (let fnrec2414 ((v v)) (edn->value opts v))) x))) (_a$2417 (edn->value opts (jolt-invoke (var-deref "clojure.core" "meta") x)))) (jolt-invoke _a$2415 _a$2416 _a$2417)) (if (jolt-truthy? (keyword #f "else")) x jolt-nil))))))))))) edn->value) (let* ((_o$2418 (keyword #f "private")) (_o$2419 #t)) (jolt-hash-map _o$2418 _o$2419)))) + (def-var! "clojure.edn" "edn->value" (letrec ((edn->value (lambda (opts x) (let fnrec1999 ((opts opts) (x x)) (if (jolt= (keyword "jolt" "set") (jolt-get x (keyword "jolt" "type"))) (let* ((_a$2003 (var-deref "clojure.core" "with-meta")) (_a$2004 (jolt-invoke (var-deref "clojure.core" "set") (let* ((_a$2001 (lambda (v) (let fnrec2000 ((v v)) (jolt-invoke edn->value opts v)))) (_a$2002 (jolt-get x (keyword #f "value")))) (jolt-map _a$2001 _a$2002)))) (_a$2005 (jolt-invoke (var-deref "clojure.core" "meta") x))) (jolt-invoke _a$2003 _a$2004 _a$2005)) (if (jolt= (keyword "jolt" "tagged") (jolt-get x (keyword "jolt" "type"))) (let* ((tag (jolt-get x (keyword #f "tag"))) (v (jolt-invoke edn->value opts (jolt-get x (keyword #f "form")))) (tag-sym (let* ((n (jolt-invoke (var-deref "clojure.core" "name") tag))) (jolt-invoke (var-deref "clojure.core" "symbol") (if (jolt= "#" (jolt-invoke (var-deref "clojure.core" "subs") n 0 1)) (jolt-invoke (var-deref "clojure.core" "subs") n 1) n)))) (custom (jolt-get (jolt-get opts (keyword #f "readers")) tag-sym))) (if (jolt-truthy? custom) (jolt-invoke custom v) (if (jolt-truthy? (jolt-get opts (keyword #f "default"))) (jolt-invoke (jolt-get opts (keyword #f "default")) tag-sym v) (if (jolt-truthy? (keyword #f "else")) (jolt-invoke (var-deref "clojure.core" "__read-tagged") tag v) jolt-nil)))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") x)) (let* ((_a$2011 (var-deref "clojure.core" "with-meta")) (_a$2012 (let* ((_a$2009 (jolt-hash-map)) (_a$2010 (jolt-map (lambda (e) (let fnrec2006 ((e e)) (let* ((_o$2007 (jolt-invoke edn->value opts (jolt-invoke (var-deref "clojure.core" "key") e))) (_o$2008 (jolt-invoke edn->value opts (jolt-invoke (var-deref "clojure.core" "val") e)))) (jolt-vector _o$2007 _o$2008)))) x))) (jolt-into _a$2009 _a$2010))) (_a$2013 (jolt-invoke (var-deref "clojure.core" "meta") x))) (jolt-invoke _a$2011 _a$2012 _a$2013)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") x)) (let* ((_a$2015 (var-deref "clojure.core" "with-meta")) (_a$2016 (jolt-invoke (var-deref "clojure.core" "mapv") (lambda (v) (let fnrec2014 ((v v)) (jolt-invoke edn->value opts v))) x)) (_a$2017 (jolt-invoke (var-deref "clojure.core" "meta") x))) (jolt-invoke _a$2015 _a$2016 _a$2017)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") x)) (let* ((_a$2019 (var-deref "clojure.core" "with-meta")) (_a$2020 (jolt-map (lambda (v) (let fnrec2018 ((v v)) (jolt-invoke edn->value opts v))) x)) (_a$2021 (jolt-invoke (var-deref "clojure.core" "meta") x))) (jolt-invoke _a$2019 _a$2020 _a$2021)) (if (jolt-truthy? (keyword #f "else")) x jolt-nil)))))))))) edn->value))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.edn" "read-edn" (letrec ((read-edn (lambda (opts s) (let fnrec2420 ((opts opts) (s s)) (let* ((v (jolt-invoke (var-deref "clojure.core" "__read-form-edn") s (lambda (form) (let fnrec2421 ((form form)) (begin (jolt-invoke (var-deref "clojure.edn" "edn->value") opts form) jolt-nil)))))) (if (jolt= v (keyword "jolt" "reader-eof")) (if (jolt-contains? opts (keyword #f "eof")) (jolt-get opts (keyword #f "eof")) (jolt-throw (jolt-ex-info "EOF while reading" (jolt-hash-map)))) (jolt-invoke (var-deref "clojure.edn" "edn->value") opts v))))))) read-edn) (let* ((_o$2422 (keyword #f "private")) (_o$2423 #t)) (jolt-hash-map _o$2422 _o$2423)))) + (def-var! "clojure.edn" "read-edn" (letrec ((read-edn (lambda (opts s) (let fnrec2022 ((opts opts) (s s)) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") s))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.string" "blank?") s)))) (jolt-get opts (keyword #f "eof") jolt-nil) (jolt-invoke (var-deref "clojure.edn" "edn->value") opts (jolt-invoke (var-deref "clojure.core" "read-string") s))))))) read-edn))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.edn" "read-string" (letrec ((read-string (case-lambda ((s) (let fnrec2424 ((s s)) (jolt-invoke (var-deref "clojure.edn" "read-edn") (let* ((_o$2425 (keyword #f "eof")) (_o$2426 jolt-nil)) (jolt-hash-map _o$2425 _o$2426)) s))) ((opts s) (let fnrec2427 ((opts opts) (s s)) (jolt-invoke (var-deref "clojure.edn" "read-edn") opts s)))))) read-string) (let* ((_o$2428 (keyword #f "doc")) (_o$2429 "Reads one object from the string s. The no-opts arity returns nil at end of\n input; with an opts map, :eof sets the value returned at end of input and its\n absence makes end-of-input an error.")) (jolt-hash-map _o$2428 _o$2429)))) + (def-var! "clojure.edn" "read-string" (letrec ((read-string (case-lambda ((s) (let fnrec2023 ((s s)) (jolt-invoke (var-deref "clojure.edn" "read-edn") (jolt-hash-map) s))) ((opts s) (let fnrec2024 ((opts opts) (s s)) (jolt-invoke (var-deref "clojure.edn" "read-edn") opts s)))))) read-string))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.edn" "drain-reader" (letrec ((drain-reader (lambda (reader) (let fnrec2430 ((reader reader)) (let* ((acc (jolt-invoke (var-deref "clojure.core" "transient") (jolt-vector))) (c (record-method-dispatch reader "read" (jolt-vector)))) (let loop2431 ((acc acc) (c c)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "==") -1 c)) (jolt-apply (var-deref "clojure.core" "str") (jolt-map (var-deref "clojure.core" "char") (jolt-invoke (var-deref "clojure.core" "persistent!") acc))) (let* ((_a$2432 (jolt-invoke (var-deref "clojure.core" "conj!") acc c)) (_a$2433 (record-method-dispatch reader "read" (jolt-vector)))) (loop2431 _a$2432 _a$2433))))))))) drain-reader) (let* ((_o$2434 (keyword #f "private")) (_o$2435 #t) (_o$2436 (keyword #f "doc")) (_o$2437 "All remaining content of a reader as a string. Shim readers (StringReader,\n PushbackReader, io/reader results) expose char-wise .read; a raw file\n handle is read whole.")) (jolt-hash-map _o$2434 _o$2435 _o$2436 _o$2437)))) + (def-var! "clojure.edn" "drain-reader" (letrec ((drain-reader (lambda (reader) (let fnrec2025 ((reader reader)) (let* ((acc (jolt-invoke (var-deref "clojure.core" "transient") (jolt-vector))) (c (record-method-dispatch reader "read" (jolt-vector)))) (let loop2026 ((acc acc) (c c)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "==") -1 c)) (jolt-apply (var-deref "clojure.core" "str") (jolt-map (var-deref "clojure.core" "char") (jolt-invoke (var-deref "clojure.core" "persistent!") acc))) (let* ((_a$2027 (jolt-invoke (var-deref "clojure.core" "conj!") acc c)) (_a$2028 (record-method-dispatch reader "read" (jolt-vector)))) (loop2026 _a$2027 _a$2028))))))))) drain-reader))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.edn" "read" (letrec ((read (case-lambda ((reader) (let fnrec2438 ((reader reader)) (read (jolt-hash-map) reader))) ((opts reader) (let fnrec2439 ((opts opts) (reader reader)) (jolt-invoke (var-deref "clojure.edn" "read-edn") opts (jolt-invoke (var-deref "clojure.edn" "drain-reader") reader))))))) read) (let* ((_o$2440 (keyword #f "doc")) (_o$2441 "Reads one EDN object from reader (a PushbackReader or any jolt reader).\n Returns the :eof option value (default nil) at end of input.")) (jolt-hash-map _o$2440 _o$2441)))) + (def-var! "clojure.edn" "read" (letrec ((read (case-lambda ((reader) (let fnrec2029 ((reader reader)) (jolt-invoke read (jolt-hash-map) reader))) ((opts reader) (let fnrec2030 ((opts opts) (reader reader)) (jolt-invoke (var-deref "clojure.edn" "read-edn") opts (jolt-invoke (var-deref "clojure.edn" "drain-reader") reader))))))) read))) (guard (e (#t #f)) - (def-var! "clojure.set" "union" (letrec ((union (case-lambda (() (let fnrec1 () (jolt-hash-set))) ((s1) (let fnrec2 ((s1 s1)) s1)) ((s1 s2) (let fnrec3 ((s1 s1) (s2 s2)) (if (let* ((_a$4 (jolt-count s1)) (_a$5 (jolt-count s2))) (jolt-n< _a$4 _a$5)) (jolt-reduce jolt-conj s2 s1) (jolt-reduce jolt-conj s1 s2)))) ((s1 s2 . sets) (let fnrec6 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce union (union s1 s2) sets)))))) union))) + (def-var! "clojure.set" "union" (letrec ((union (case-lambda (() (let fnrec1 () (jolt-hash-set))) ((s1) (let fnrec2 ((s1 s1)) s1)) ((s1 s2) (let fnrec3 ((s1 s1) (s2 s2)) (if (let* ((_a$4 (jolt-count s1)) (_a$5 (jolt-count s2))) (< _a$4 _a$5)) (jolt-reduce jolt-conj s2 s1) (jolt-reduce jolt-conj s1 s2)))) ((s1 s2 . sets) (let fnrec6 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce union (jolt-invoke union s1 s2) sets)))))) union))) (guard (e (#t #f)) - (def-var! "clojure.set" "intersection" (letrec ((intersection (case-lambda ((s1) (let fnrec7 ((s1 s1)) s1)) ((s1 s2) (let fnrec8 ((s1 s1) (s2 s2)) (jolt-reduce (lambda (acc item) (let fnrec9 ((acc acc) (item item)) (if (jolt-contains? s2 item) acc (jolt-invoke (var-deref "clojure.core" "disj") acc item)))) s1 s1))) ((s1 s2 . sets) (let fnrec10 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce intersection (intersection s1 s2) sets)))))) intersection))) + (def-var! "clojure.set" "intersection" (letrec ((intersection (case-lambda ((s1) (let fnrec7 ((s1 s1)) s1)) ((s1 s2) (let fnrec8 ((s1 s1) (s2 s2)) (jolt-reduce (lambda (acc item) (let fnrec9 ((acc acc) (item item)) (if (jolt-contains? s2 item) acc (jolt-invoke (var-deref "clojure.core" "disj") acc item)))) s1 s1))) ((s1 s2 . sets) (let fnrec10 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce intersection (jolt-invoke intersection s1 s2) sets)))))) intersection))) (guard (e (#t #f)) - (def-var! "clojure.set" "difference" (letrec ((difference (case-lambda ((s1) (let fnrec11 ((s1 s1)) s1)) ((s1 s2) (let fnrec12 ((s1 s1) (s2 s2)) (jolt-reduce (var-deref "clojure.core" "disj") s1 s2))) ((s1 s2 . sets) (let fnrec13 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce difference (difference s1 s2) sets)))))) difference))) + (def-var! "clojure.set" "difference" (letrec ((difference (case-lambda ((s1) (let fnrec11 ((s1 s1)) s1)) ((s1 s2) (let fnrec12 ((s1 s1) (s2 s2)) (jolt-reduce (var-deref "clojure.core" "disj") s1 s2))) ((s1 s2 . sets) (let fnrec13 ((s1 s1) (s2 s2) (sets (list->cseq sets))) (jolt-reduce difference (jolt-invoke difference s1 s2) sets)))))) difference))) (guard (e (#t #f)) (def-var! "clojure.set" "select" (letrec ((select (lambda (pred s) (let fnrec14 ((pred pred) (s s)) (jolt-reduce (lambda (acc item) (let fnrec15 ((acc acc) (item item)) (if (jolt-truthy? (jolt-invoke pred item)) acc (jolt-invoke (var-deref "clojure.core" "disj") acc item)))) s s))))) select))) (guard (e (#t #f)) @@ -1079,249 +1085,249 @@ (guard (e (#t #f)) (def-var! "clojure.set" "index" (letrec ((index (lambda (xrel ks) (let fnrec34 ((xrel xrel) (ks ks)) (let* ((_a$36 (lambda (m x) (let fnrec35 ((m m) (x x)) (let* ((ik (jolt-invoke (var-deref "clojure.core" "select-keys") x ks))) (jolt-assoc m ik (jolt-conj (jolt-get m ik (jolt-hash-set)) x)))))) (_a$37 (jolt-hash-map)) (_a$38 xrel)) (jolt-reduce _a$36 _a$37 _a$38)))))) index))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.set" "join" (letrec ((join (case-lambda ((xrel yrel) (let fnrec39 ((xrel xrel) (yrel yrel)) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq xrel))) (if (jolt-truthy? and__25__auto) (jolt-seq yrel) and__25__auto))) (let* ((ks (let* ((_a$40 (var-deref "clojure.set" "intersection")) (_a$41 (jolt-invoke (var-deref "clojure.core" "set") (jolt-keys (jolt-first xrel)))) (_a$42 (jolt-invoke (var-deref "clojure.core" "set") (jolt-keys (jolt-first yrel))))) (jolt-invoke _a$40 _a$41 _a$42))) (G__7 (if (let* ((_a$43 (jolt-count xrel)) (_a$44 (jolt-count yrel))) (jolt-n<= _a$43 _a$44)) (let* ((_o$45 xrel) (_o$46 yrel)) (jolt-vector _o$45 _o$46)) (let* ((_o$47 yrel) (_o$48 xrel)) (jolt-vector _o$47 _o$48)))) (r (jolt-nth G__7 0 jolt-nil)) (s (jolt-nth G__7 1 jolt-nil)) (idx (jolt-invoke (var-deref "clojure.set" "index") r ks))) (let* ((_a$51 (lambda (ret x) (let fnrec49 ((ret ret) (x x)) (let* ((found (jolt-invoke idx (jolt-invoke (var-deref "clojure.core" "select-keys") x ks)))) (if (jolt-truthy? found) (jolt-reduce (lambda (acc y) (let fnrec50 ((acc acc) (y y)) (jolt-conj acc (jolt-invoke (var-deref "clojure.core" "merge") y x)))) ret found) ret))))) (_a$52 (jolt-hash-set)) (_a$53 s)) (jolt-reduce _a$51 _a$52 _a$53))) (jolt-hash-set)))) ((xrel yrel km) (let fnrec54 ((xrel xrel) (yrel yrel) (km km)) (let* ((G__8 (if (let* ((_a$55 (jolt-count xrel)) (_a$56 (jolt-count yrel))) (jolt-n<= _a$55 _a$56)) (let* ((_o$57 xrel) (_o$58 yrel) (_o$59 (jolt-invoke (var-deref "clojure.set" "map-invert") km))) (jolt-vector _o$57 _o$58 _o$59)) (let* ((_o$60 yrel) (_o$61 xrel) (_o$62 km)) (jolt-vector _o$60 _o$61 _o$62)))) (r (jolt-nth G__8 0 jolt-nil)) (s (jolt-nth G__8 1 jolt-nil)) (k (jolt-nth G__8 2 jolt-nil)) (idx (jolt-invoke (var-deref "clojure.set" "index") r (jolt-vals k)))) (let* ((_a$65 (lambda (ret x) (let fnrec63 ((ret ret) (x x)) (let* ((found (jolt-invoke idx (jolt-invoke (var-deref "clojure.set" "rename-keys") (jolt-invoke (var-deref "clojure.core" "select-keys") x (jolt-keys k)) k)))) (if (jolt-truthy? found) (jolt-reduce (lambda (acc y) (let fnrec64 ((acc acc) (y y)) (jolt-conj acc (jolt-invoke (var-deref "clojure.core" "merge") y x)))) ret found) ret))))) (_a$66 (jolt-hash-set)) (_a$67 s)) (jolt-reduce _a$65 _a$66 _a$67)))))))) join) (let* ((_o$68 (keyword #f "doc")) (_o$69 "When passed 2 rels, returns the rel corresponding to the natural join.\n When passed an additional keymap, joins on the corresponding keys.")) (jolt-hash-map _o$68 _o$69)))) + (def-var! "clojure.set" "join" (letrec ((join (case-lambda ((xrel yrel) (let fnrec39 ((xrel xrel) (yrel yrel)) (if (jolt-truthy? (let* ((and__25__auto (jolt-seq xrel))) (if (jolt-truthy? and__25__auto) (jolt-seq yrel) and__25__auto))) (let* ((ks (let* ((_a$40 (var-deref "clojure.set" "intersection")) (_a$41 (jolt-invoke (var-deref "clojure.core" "set") (jolt-keys (jolt-first xrel)))) (_a$42 (jolt-invoke (var-deref "clojure.core" "set") (jolt-keys (jolt-first yrel))))) (jolt-invoke _a$40 _a$41 _a$42))) (G__7 (if (let* ((_a$43 (jolt-count xrel)) (_a$44 (jolt-count yrel))) (<= _a$43 _a$44)) (let* ((_o$45 xrel) (_o$46 yrel)) (jolt-vector _o$45 _o$46)) (let* ((_o$47 yrel) (_o$48 xrel)) (jolt-vector _o$47 _o$48)))) (r (jolt-nth G__7 0 jolt-nil)) (s (jolt-nth G__7 1 jolt-nil)) (idx (jolt-invoke (var-deref "clojure.set" "index") r ks))) (let* ((_a$51 (lambda (ret x) (let fnrec49 ((ret ret) (x x)) (let* ((found (jolt-invoke idx (jolt-invoke (var-deref "clojure.core" "select-keys") x ks)))) (if (jolt-truthy? found) (jolt-reduce (lambda (acc y) (let fnrec50 ((acc acc) (y y)) (jolt-conj acc (jolt-invoke (var-deref "clojure.core" "merge") y x)))) ret found) ret))))) (_a$52 (jolt-hash-set)) (_a$53 s)) (jolt-reduce _a$51 _a$52 _a$53))) (jolt-hash-set)))) ((xrel yrel km) (let fnrec54 ((xrel xrel) (yrel yrel) (km km)) (let* ((G__8 (if (let* ((_a$55 (jolt-count xrel)) (_a$56 (jolt-count yrel))) (<= _a$55 _a$56)) (let* ((_o$57 xrel) (_o$58 yrel) (_o$59 (jolt-invoke (var-deref "clojure.set" "map-invert") km))) (jolt-vector _o$57 _o$58 _o$59)) (let* ((_o$60 yrel) (_o$61 xrel) (_o$62 km)) (jolt-vector _o$60 _o$61 _o$62)))) (r (jolt-nth G__8 0 jolt-nil)) (s (jolt-nth G__8 1 jolt-nil)) (k (jolt-nth G__8 2 jolt-nil)) (idx (jolt-invoke (var-deref "clojure.set" "index") r (jolt-vals k)))) (let* ((_a$65 (lambda (ret x) (let fnrec63 ((ret ret) (x x)) (let* ((found (jolt-invoke idx (jolt-invoke (var-deref "clojure.set" "rename-keys") (jolt-invoke (var-deref "clojure.core" "select-keys") x (jolt-keys k)) k)))) (if (jolt-truthy? found) (jolt-reduce (lambda (acc y) (let fnrec64 ((acc acc) (y y)) (jolt-conj acc (jolt-invoke (var-deref "clojure.core" "merge") y x)))) ret found) ret))))) (_a$66 (jolt-hash-set)) (_a$67 s)) (jolt-reduce _a$65 _a$66 _a$67)))))))) join))) (guard (e (#t #f)) - (def-var! "clojure.set" "subset?" (letrec ((subset? (lambda (set1 set2) (let fnrec70 ((set1 set1) (set2 set2)) (let* ((and__25__auto (let* ((_a$71 (jolt-count set1)) (_a$72 (jolt-count set2))) (jolt-n<= _a$71 _a$72)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p__2_) (let fnrec73 ((p__2_ p__2_)) (jolt-contains? set2 p__2_))) set1) and__25__auto)))))) subset?))) + (def-var! "clojure.set" "subset?" (letrec ((subset? (lambda (set1 set2) (let fnrec68 ((set1 set1) (set2 set2)) (let* ((and__25__auto (let* ((_a$69 (jolt-count set1)) (_a$70 (jolt-count set2))) (<= _a$69 _a$70)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p__2_) (let fnrec71 ((p__2_ p__2_)) (jolt-contains? set2 p__2_))) set1) and__25__auto)))))) subset?))) (guard (e (#t #f)) - (def-var! "clojure.set" "superset?" (letrec ((superset? (lambda (set1 set2) (let fnrec74 ((set1 set1) (set2 set2)) (let* ((and__25__auto (let* ((_a$75 (jolt-count set1)) (_a$76 (jolt-count set2))) (jolt-n>= _a$75 _a$76)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p__3_) (let fnrec77 ((p__3_ p__3_)) (jolt-contains? set1 p__3_))) set2) and__25__auto)))))) superset?))) + (def-var! "clojure.set" "superset?" (letrec ((superset? (lambda (set1 set2) (let fnrec72 ((set1 set1) (set2 set2)) (let* ((and__25__auto (let* ((_a$73 (jolt-count set1)) (_a$74 (jolt-count set2))) (>= _a$73 _a$74)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "every?") (lambda (p__3_) (let fnrec75 ((p__3_ p__3_)) (jolt-contains? set1 p__3_))) set2) and__25__auto)))))) superset?))) (guard (e (#t #f)) (def-var! "clojure.pprint" "getf" - (lambda (sym) (let fnrec78 ((sym sym)) (let* ((_a$85 (var-deref "clojure.core" "__sqcat")) (_a$86 (jolt-invoke (var-deref "clojure.core" "__sq1") sym)) (_a$87 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$82 (var-deref "clojure.core" "__sqcat")) (_a$83 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "deref"))) (_a$84 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$79 (var-deref "clojure.core" "__sqcat")) (_a$80 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f ".-fields"))) (_a$81 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "this")))) (jolt-invoke _a$79 _a$80 _a$81))))) (jolt-invoke _a$82 _a$83 _a$84))))) (jolt-invoke _a$85 _a$86 _a$87))))) + (lambda (sym) (let fnrec76 ((sym sym)) (let* ((_a$83 (var-deref "clojure.core" "__sqcat")) (_a$84 (jolt-invoke (var-deref "clojure.core" "__sq1") sym)) (_a$85 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$80 (var-deref "clojure.core" "__sqcat")) (_a$81 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "deref"))) (_a$82 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$77 (var-deref "clojure.core" "__sqcat")) (_a$78 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f ".-fields"))) (_a$79 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "this")))) (jolt-invoke _a$77 _a$78 _a$79))))) (jolt-invoke _a$80 _a$81 _a$82))))) (jolt-invoke _a$83 _a$84 _a$85))))) (mark-macro! "clojure.pprint" "getf")) (guard (e (#t #f)) (def-var! "clojure.pprint" "setf" - (lambda (sym new-val) (let fnrec88 ((sym sym) (new-val new-val)) (let* ((_a$92 (var-deref "clojure.core" "__sqcat")) (_a$93 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "swap!"))) (_a$94 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$89 (var-deref "clojure.core" "__sqcat")) (_a$90 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f ".-fields"))) (_a$91 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "this")))) (jolt-invoke _a$89 _a$90 _a$91)))) (_a$95 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "assoc"))) (_a$96 (jolt-invoke (var-deref "clojure.core" "__sq1") sym)) (_a$97 (jolt-invoke (var-deref "clojure.core" "__sq1") new-val))) (jolt-invoke _a$92 _a$93 _a$94 _a$95 _a$96 _a$97))))) + (lambda (sym new-val) (let fnrec86 ((sym sym) (new-val new-val)) (let* ((_a$90 (var-deref "clojure.core" "__sqcat")) (_a$91 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "swap!"))) (_a$92 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$87 (var-deref "clojure.core" "__sqcat")) (_a$88 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f ".-fields"))) (_a$89 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "this")))) (jolt-invoke _a$87 _a$88 _a$89)))) (_a$93 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "assoc"))) (_a$94 (jolt-invoke (var-deref "clojure.core" "__sq1") sym)) (_a$95 (jolt-invoke (var-deref "clojure.core" "__sq1") new-val))) (jolt-invoke _a$90 _a$91 _a$92 _a$93 _a$94 _a$95))))) (mark-macro! "clojure.pprint" "setf")) (guard (e (#t #f)) (def-var! 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"clojure.pprint" "println" (letrec ((println (lambda more (let fnrec279 ((more (list->cseq more))) (begin (jolt-apply (var-deref "clojure.pprint" "print") more) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n")))))) println) (let* ((_o$280 (keyword #f "private")) (_o$281 #t)) (jolt-hash-map _o$280 _o$281)))) + (def-var! "clojure.pprint" "println" (letrec ((println (lambda more (let fnrec275 ((more (list->cseq more))) (begin (jolt-apply (var-deref "clojure.pprint" "print") more) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n")))))) println))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "print-char" (letrec ((print-char (lambda (c) (let fnrec282 ((c c)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (let* ((G__10 jolt=) (G__11 c)) (if (jolt-truthy? (jolt-invoke G__10 (integer->char 8) G__11)) "\\backspace" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 32) G__11)) "\\space" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 9) G__11)) "\\tab" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 10) G__11)) "\\newline" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 12) G__11)) "\\formfeed" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 13) G__11)) "\\return" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 34) G__11)) "\\\"" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 92) G__11)) "\\\\" (jolt-invoke (var-deref "clojure.core" "str") "\\" c))))))))))))))) print-char) (let* ((_o$283 (keyword #f "private")) (_o$284 #t)) (jolt-hash-map _o$283 _o$284)))) + (def-var! "clojure.pprint" "print-char" (letrec ((print-char (lambda (c) (let fnrec276 ((c c)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (let* ((G__10 jolt=) (G__11 c)) (if (jolt-truthy? (jolt-invoke G__10 (integer->char 8) G__11)) "\\backspace" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 32) G__11)) "\\space" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 9) G__11)) "\\tab" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 10) G__11)) "\\newline" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 12) G__11)) "\\formfeed" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 13) G__11)) "\\return" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 34) G__11)) "\\\"" (if (jolt-truthy? (jolt-invoke G__10 (integer->char 92) G__11)) "\\\\" (jolt-invoke (var-deref "clojure.core" "str") "\\" c))))))))))))))) print-char))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pr" (letrec ((pr (lambda more (let fnrec285 ((more (list->cseq more))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-apply (var-deref "clojure.core" "pr-str") more)))))) pr) (let* ((_o$286 (keyword #f "dynamic")) (_o$287 #t) (_o$288 (keyword #f "private")) (_o$289 #t)) (jolt-hash-map _o$286 _o$287 _o$288 _o$289)))) + (def-var-with-meta! "clojure.pprint" "pr" (letrec ((pr (lambda more (let fnrec277 ((more (list->cseq more))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-apply (var-deref "clojure.core" "pr-str") more)))))) pr) (jolt-hash-map (keyword #f "dynamic") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "prn" (letrec ((prn (lambda more (let fnrec290 ((more (list->cseq more))) (begin (jolt-apply (var-deref "clojure.pprint" "pr") more) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n")))))) prn) (let* ((_o$291 (keyword #f "private")) (_o$292 #t)) (jolt-hash-map _o$291 _o$292)))) + (def-var! "clojure.pprint" "prn" (letrec ((prn (lambda more (let fnrec278 ((more (list->cseq more))) (begin (jolt-apply (var-deref "clojure.pprint" "pr") more) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n")))))) prn))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "float?" (letrec ((float? (lambda (n) (let fnrec293 ((n n)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") n))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "integer?") n)) and__25__auto)))))) float?) (let* ((_o$294 (keyword #f "private")) (_o$295 #t)) (jolt-hash-map _o$294 _o$295)))) + (def-var! "clojure.pprint" "float?" (letrec ((float? (lambda (n) (let fnrec279 ((n n)) (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "number?") n))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.core" "integer?") n)) and__25__auto)))))) float?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "char-code" (letrec ((char-code (lambda (c) (let fnrec296 ((c c)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") c)) c (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "char?") c)) (jolt-invoke (var-deref "clojure.core" "int") c) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "string?") c))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-count c) 1) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "int") (record-method-dispatch c "charAt" (jolt-vector 0))) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (host-new "Exception" "Argument to char must be a character or number")) jolt-nil)))))))) char-code) (let* ((_o$297 (keyword #f "private")) (_o$298 #t)) (jolt-hash-map _o$297 _o$298)))) + (def-var! "clojure.pprint" "char-code" (letrec ((char-code (lambda (c) (let fnrec280 ((c c)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "number?") c)) c (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "char?") c)) (jolt-invoke (var-deref "clojure.core" "int") c) (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.core" "string?") c))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-count c) 1) and__25__auto))) (jolt-invoke (var-deref "clojure.core" "int") (record-method-dispatch c "charAt" (jolt-vector 0))) (if (jolt-truthy? (keyword #f "else")) (jolt-throw (host-new "Exception" "Argument to char must be a character or number")) jolt-nil)))))))) char-code))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "map-passing-context" (letrec ((map-passing-context (lambda (func initial-context lis) (let fnrec299 ((func func) (initial-context initial-context) (lis lis)) (let* ((context initial-context) (lis lis) (acc (jolt-vector))) (let loop300 ((context context) (lis lis) (acc acc)) (if (jolt-empty? lis) (let* ((_o$301 acc) (_o$302 context)) (jolt-vector _o$301 _o$302)) (let* ((this (jolt-first lis)) (remainder (jolt-next lis)) (G__12 (jolt-apply func (let* ((_o$303 this) (_o$304 context)) (jolt-vector _o$303 _o$304)))) (result (jolt-nth G__12 0 jolt-nil)) (new-context (jolt-nth G__12 1 jolt-nil))) (loop300 new-context remainder (jolt-conj acc result)))))))))) map-passing-context) (let* ((_o$305 (keyword #f "private")) (_o$306 #t)) (jolt-hash-map _o$305 _o$306)))) + (def-var! "clojure.pprint" "map-passing-context" (letrec ((map-passing-context (lambda (func initial-context lis) (let fnrec281 ((func func) (initial-context initial-context) (lis lis)) (let* ((context initial-context) (lis lis) (acc (jolt-vector))) (let loop282 ((context context) (lis lis) (acc acc)) (if (jolt-empty? lis) (let* ((_o$283 acc) (_o$284 context)) (jolt-vector _o$283 _o$284)) (let* ((this (jolt-first lis)) (remainder (jolt-next lis)) (G__12 (jolt-apply func (let* ((_o$285 this) (_o$286 context)) (jolt-vector _o$285 _o$286)))) (result (jolt-nth G__12 0 jolt-nil)) (new-context (jolt-nth G__12 1 jolt-nil))) (loop282 new-context remainder (jolt-conj acc result)))))))))) map-passing-context))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "consume" (letrec ((consume (lambda (func initial-context) (let fnrec307 ((func func) (initial-context initial-context)) (let* ((context initial-context) (acc (jolt-vector))) (let loop308 ((context context) (acc acc)) (let* ((G__13 (jolt-apply func (jolt-vector context))) (result (jolt-nth G__13 0 jolt-nil)) (new-context (jolt-nth G__13 1 jolt-nil))) (if (jolt-not result) (let* ((_o$309 acc) (_o$310 new-context)) (jolt-vector _o$309 _o$310)) (loop308 new-context (jolt-conj acc result)))))))))) consume) (let* ((_o$311 (keyword #f "private")) (_o$312 #t)) (jolt-hash-map _o$311 _o$312)))) + (def-var! "clojure.pprint" "consume" (letrec ((consume (lambda (func initial-context) (let fnrec287 ((func func) (initial-context initial-context)) (let* ((context initial-context) (acc (jolt-vector))) (let loop288 ((context context) (acc acc)) (let* ((G__13 (jolt-apply func (jolt-vector context))) (result (jolt-nth G__13 0 jolt-nil)) (new-context (jolt-nth G__13 1 jolt-nil))) (if (jolt-not result) (let* ((_o$289 acc) (_o$290 new-context)) (jolt-vector _o$289 _o$290)) (loop288 new-context (jolt-conj acc result)))))))))) consume))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "unzip-map" (letrec ((unzip-map (lambda (m) (let fnrec313 ((m m)) (let* ((_o$324 (let* ((_a$317 (jolt-hash-map)) (_a$318 (jolt-map (lambda (G__14) (let fnrec314 ((G__14 G__14)) (let* ((G__15 G__14) (k (jolt-nth G__15 0 jolt-nil)) (G__16 (jolt-nth G__15 1 jolt-nil)) (v1 (jolt-nth G__16 0 jolt-nil)) (v2 (jolt-nth G__16 1 jolt-nil))) (let* ((_o$315 k) (_o$316 v1)) (jolt-vector _o$315 _o$316))))) m))) (jolt-into _a$317 _a$318))) (_o$325 (let* ((_a$322 (jolt-hash-map)) (_a$323 (jolt-map (lambda (G__17) (let fnrec319 ((G__17 G__17)) (let* ((G__18 G__17) (k (jolt-nth G__18 0 jolt-nil)) (G__19 (jolt-nth G__18 1 jolt-nil)) (v1 (jolt-nth G__19 0 jolt-nil)) (v2 (jolt-nth G__19 1 jolt-nil))) (let* ((_o$320 k) (_o$321 v2)) (jolt-vector _o$320 _o$321))))) m))) (jolt-into _a$322 _a$323)))) (jolt-vector _o$324 _o$325)))))) unzip-map) (let* ((_o$326 (keyword #f "private")) (_o$327 #t)) (jolt-hash-map _o$326 _o$327)))) + (def-var! "clojure.pprint" "unzip-map" (letrec ((unzip-map (lambda (m) (let fnrec291 ((m m)) (let* ((_o$302 (let* ((_a$295 (jolt-hash-map)) (_a$296 (jolt-map (lambda (G__14) (let fnrec292 ((G__14 G__14)) (let* ((G__15 G__14) (k (jolt-nth G__15 0 jolt-nil)) (G__16 (jolt-nth G__15 1 jolt-nil)) (v1 (jolt-nth G__16 0 jolt-nil)) (v2 (jolt-nth G__16 1 jolt-nil))) (let* ((_o$293 k) (_o$294 v1)) (jolt-vector _o$293 _o$294))))) m))) (jolt-into _a$295 _a$296))) (_o$303 (let* ((_a$300 (jolt-hash-map)) (_a$301 (jolt-map (lambda (G__17) (let fnrec297 ((G__17 G__17)) (let* ((G__18 G__17) (k (jolt-nth G__18 0 jolt-nil)) (G__19 (jolt-nth G__18 1 jolt-nil)) (v1 (jolt-nth G__19 0 jolt-nil)) (v2 (jolt-nth G__19 1 jolt-nil))) (let* ((_o$298 k) (_o$299 v2)) (jolt-vector _o$298 _o$299))))) m))) (jolt-into _a$300 _a$301)))) (jolt-vector _o$302 _o$303)))))) unzip-map))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "tuple-map" (letrec ((tuple-map (lambda (m v1) (let fnrec328 ((m m) (v1 v1)) (let* ((_a$334 (jolt-hash-map)) (_a$335 (jolt-map (lambda (G__20) (let fnrec329 ((G__20 G__20)) (let* ((G__21 G__20) (k (jolt-nth G__21 0 jolt-nil)) (v (jolt-nth G__21 1 jolt-nil))) (let* ((_o$332 k) (_o$333 (let* ((_o$330 v) (_o$331 v1)) (jolt-vector _o$330 _o$331)))) (jolt-vector _o$332 _o$333))))) m))) (jolt-into _a$334 _a$335)))))) tuple-map) (let* ((_o$336 (keyword #f "private")) (_o$337 #t)) (jolt-hash-map _o$336 _o$337)))) + (def-var! "clojure.pprint" "tuple-map" (letrec ((tuple-map (lambda (m v1) (let fnrec304 ((m m) (v1 v1)) (let* ((_a$310 (jolt-hash-map)) (_a$311 (jolt-map (lambda (G__20) (let fnrec305 ((G__20 G__20)) (let* ((G__21 G__20) (k (jolt-nth G__21 0 jolt-nil)) (v (jolt-nth G__21 1 jolt-nil))) (let* ((_o$308 k) (_o$309 (let* ((_o$306 v) (_o$307 v1)) (jolt-vector _o$306 _o$307)))) (jolt-vector _o$308 _o$309))))) m))) (jolt-into _a$310 _a$311)))))) tuple-map))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "rtrim" (letrec ((rtrim (lambda (s c) (let fnrec338 ((s s) (c c)) (let* ((len (jolt-count s))) (if (let* ((and__25__auto (jolt-pos? len))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-nth s (jolt-dec (jolt-count s))) c) and__25__auto)) (let* ((n (jolt-dec len))) (let loop339 ((n n)) (if (jolt-neg? n) "" (if (jolt-not (jolt= (jolt-nth s n) c)) (jolt-invoke (var-deref "clojure.core" "subs") s 0 (jolt-inc n)) (if #t (loop339 (jolt-dec n)) jolt-nil))))) s)))))) rtrim) (let* ((_o$340 (keyword #f "private")) (_o$341 #t)) (jolt-hash-map _o$340 _o$341)))) + (def-var! "clojure.pprint" "rtrim" (letrec ((rtrim (lambda (s c) (let fnrec312 ((s s) (c c)) (let* ((len (jolt-count s))) (if (jolt-truthy? (let* ((and__25__auto (jolt-pos? len))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-nth s (jolt-dec (jolt-count s))) c) and__25__auto))) (let* ((n (jolt-dec len))) (let loop313 ((n n)) (if (jolt-neg? n) "" (if (jolt-not (jolt= (jolt-nth s n) c)) (jolt-invoke (var-deref "clojure.core" "subs") s 0 (jolt-inc n)) (if #t (loop313 (jolt-dec n)) jolt-nil))))) s)))))) rtrim))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "ltrim" (letrec ((ltrim (lambda (s c) (let fnrec342 ((s s) (c c)) (let* ((len (jolt-count s))) (if (let* ((and__25__auto (jolt-pos? len))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-nth s 0) c) and__25__auto)) (let* ((n 0)) (let loop343 ((n n)) (if (let* ((or__26__auto (jolt= n len))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt= (jolt-nth s n) c)))) (jolt-invoke (var-deref "clojure.core" "subs") s n) (loop343 (jolt-inc n))))) s)))))) ltrim) (let* ((_o$344 (keyword #f "private")) (_o$345 #t)) (jolt-hash-map _o$344 _o$345)))) + (def-var! "clojure.pprint" "ltrim" (letrec ((ltrim (lambda (s c) (let fnrec314 ((s s) (c c)) (let* ((len (jolt-count s))) (if (jolt-truthy? (let* ((and__25__auto (jolt-pos? len))) (if (jolt-truthy? and__25__auto) (jolt= (jolt-nth s 0) c) and__25__auto))) (let* ((n 0)) (let loop315 ((n n)) (if (jolt-truthy? (let* ((or__26__auto (jolt= n len))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt= (jolt-nth s n) c))))) (jolt-invoke (var-deref "clojure.core" "subs") s n) (loop315 (jolt-inc n))))) s)))))) ltrim))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "prefix-count" (letrec ((prefix-count (lambda (aseq val) (let fnrec346 ((aseq aseq) (val val)) (let* ((test (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "coll?") val)) (jolt-invoke (var-deref "clojure.core" "set") val) (jolt-hash-set val)))) (let* ((pos 0)) (let loop347 ((pos pos)) (if (let* ((or__26__auto (jolt= pos (jolt-count aseq)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke test (jolt-nth aseq pos))))) pos (loop347 (jolt-inc pos)))))))))) prefix-count) (let* ((_o$348 (keyword #f "private")) (_o$349 #t)) (jolt-hash-map _o$348 _o$349)))) + (def-var! "clojure.pprint" "prefix-count" (letrec ((prefix-count (lambda (aseq val) (let fnrec316 ((aseq aseq) (val val)) (let* ((test (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "coll?") val)) (jolt-invoke (var-deref "clojure.core" "set") val) (jolt-hash-set val)))) (let* ((pos 0)) (let loop317 ((pos pos)) (if (jolt-truthy? (let* ((or__26__auto (jolt= pos (jolt-count aseq)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke test (jolt-nth aseq pos)))))) pos (loop317 (jolt-inc pos)))))))))) prefix-count))) (guard (e (#t #f)) - (begin (def-var! "clojure.pprint" "IPrettyFlush" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IPrettyFlush" (let* ((_o$352 (keyword #f "-ppflush")) (_o$353 (let* ((_o$350 (keyword #f "name")) (_o$351 "-ppflush")) (jolt-hash-map _o$350 _o$351)))) (jolt-hash-map _o$352 _o$353)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IPrettyFlush" (jolt-vector "-ppflush")) (def-var! "clojure.pprint" "-ppflush" (lambda (G__22) (let fnrec354 ((G__22 G__22)) (protocol-dispatch1 "IPrettyFlush" "-ppflush" G__22)))))) + (begin (def-var! "clojure.pprint" "IPrettyFlush" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IPrettyFlush" (let* ((_o$320 (keyword #f "-ppflush")) (_o$321 (let* ((_o$318 (keyword #f "name")) (_o$319 "-ppflush")) (jolt-hash-map _o$318 _o$319)))) (jolt-hash-map _o$320 _o$321)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IPrettyFlush" (jolt-vector "-ppflush")) (def-var! "clojure.pprint" "-ppflush" (lambda (this__23__auto . rest__22__auto) (let fnrec322 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IPrettyFlush" "-ppflush" this__23__auto rest__22__auto)))))) (guard (e (#t #f)) - (begin (def-var! "clojure.pprint" "IPrettyWriter" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IPrettyWriter" (let* ((_o$359 (keyword #f "-write")) (_o$360 (let* ((_o$355 (keyword #f "name")) (_o$356 "-write")) (jolt-hash-map _o$355 _o$356))) (_o$361 (keyword #f "-pflush")) (_o$362 (let* ((_o$357 (keyword #f "name")) (_o$358 "-pflush")) (jolt-hash-map _o$357 _o$358)))) (jolt-hash-map _o$359 _o$360 _o$361 _o$362)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IPrettyWriter" (let* ((_o$363 "-write") (_o$364 "-pflush")) (jolt-vector _o$363 _o$364))) (def-var! "clojure.pprint" "-write" (lambda (G__23 G__24) (let fnrec365 ((G__23 G__23) (G__24 G__24)) (protocol-dispatch2 "IPrettyWriter" "-write" G__23 G__24)))) (def-var! "clojure.pprint" "-pflush" (lambda (G__25) (let fnrec366 ((G__25 G__25)) (protocol-dispatch1 "IPrettyWriter" "-pflush" G__25)))))) + (begin (def-var! "clojure.pprint" "IPrettyWriter" (jolt-invoke (var-deref "clojure.core" "make-protocol") "IPrettyWriter" (let* ((_o$327 (keyword #f "-pflush")) (_o$328 (let* ((_o$323 (keyword #f "name")) (_o$324 "-pflush")) (jolt-hash-map _o$323 _o$324))) (_o$329 (keyword #f "-write")) (_o$330 (let* ((_o$325 (keyword #f "name")) (_o$326 "-write")) (jolt-hash-map _o$325 _o$326)))) (jolt-hash-map _o$327 _o$328 _o$329 _o$330)))) (jolt-invoke (var-deref "clojure.core" "register-protocol-methods!") "IPrettyWriter" (let* ((_o$331 "-write") (_o$332 "-pflush")) (jolt-vector _o$331 _o$332))) (def-var! "clojure.pprint" "-write" (lambda (this__23__auto . rest__22__auto) (let fnrec333 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IPrettyWriter" "-write" this__23__auto rest__22__auto)))) (def-var! "clojure.pprint" "-pflush" (lambda (this__23__auto . rest__22__auto) (let fnrec334 ((this__23__auto this__23__auto) (rest__22__auto (list->cseq rest__22__auto))) (jolt-invoke (var-deref "clojure.core" "protocol-dispatch") "IPrettyWriter" "-pflush" this__23__auto rest__22__auto)))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "*default-page-width*" 72 (let* ((_o$367 (keyword #f "private")) (_o$368 #t) (_o$369 (keyword #f "dynamic")) (_o$370 #t)) (jolt-hash-map _o$367 _o$368 _o$369 _o$370)))) + (def-var-with-meta! "clojure.pprint" "*default-page-width*" 72 (jolt-hash-map (keyword #f "dynamic") #t (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-field" (letrec ((get-field (lambda (this sym) (let fnrec371 ((this this) (sym sym)) (jolt-invoke sym (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector)))))))) get-field) (let* ((_o$372 (keyword #f "private")) (_o$373 #t)) (jolt-hash-map _o$372 _o$373)))) + (def-var! "clojure.pprint" "get-field" (letrec ((get-field (lambda (this sym) (let fnrec335 ((this this) (sym sym)) (jolt-invoke sym (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector)))))))) get-field))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "set-field" (letrec ((set-field (lambda (this sym new-val) (let fnrec374 ((this this) (sym sym) (new-val new-val)) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc sym new-val))))) set-field) (let* ((_o$375 (keyword #f "private")) (_o$376 #t)) (jolt-hash-map _o$375 _o$376)))) + (def-var! "clojure.pprint" "set-field" (letrec ((set-field (lambda (this sym new-val) (let fnrec336 ((this this) (sym sym) (new-val new-val)) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc sym new-val))))) set-field))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-column" (letrec ((get-column (lambda (this) (let fnrec377 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur")))))) get-column) (let* ((_o$378 (keyword #f "private")) (_o$379 #t)) (jolt-hash-map _o$378 _o$379)))) + (def-var! "clojure.pprint" "get-column" (letrec ((get-column (lambda (this) (let fnrec337 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur")))))) get-column))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-line" (letrec ((get-line (lambda (this) (let fnrec380 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line")))))) get-line) (let* ((_o$381 (keyword #f "private")) (_o$382 #t)) (jolt-hash-map _o$381 _o$382)))) + (def-var! "clojure.pprint" "get-line" (letrec ((get-line (lambda (this) (let fnrec338 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line")))))) get-line))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-max-column" (letrec ((get-max-column (lambda (this) (let fnrec383 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "max")))))) get-max-column) (let* ((_o$384 (keyword #f "private")) (_o$385 #t)) (jolt-hash-map _o$384 _o$385)))) + (def-var! "clojure.pprint" "get-max-column" (letrec ((get-max-column (lambda (this) (let fnrec339 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "max")))))) get-max-column))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "set-max-column" (letrec ((set-max-column (lambda (this new-max) (let fnrec386 ((this this) (new-max new-max)) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "max") new-max) jolt-nil))))) set-max-column) (let* ((_o$387 (keyword #f "private")) (_o$388 #t)) (jolt-hash-map _o$387 _o$388)))) + (def-var! "clojure.pprint" "set-max-column" (letrec ((set-max-column (lambda (this new-max) (let fnrec340 ((this this) (new-max new-max)) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "max") new-max) jolt-nil))))) set-max-column))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-writer" (letrec ((get-writer (lambda (this) (let fnrec389 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")))))) get-writer) (let* ((_o$390 (keyword #f "private")) (_o$391 #t)) (jolt-hash-map _o$390 _o$391)))) + (def-var! "clojure.pprint" "get-writer" (letrec ((get-writer (lambda (this) (let fnrec341 ((this this)) (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")))))) get-writer))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "c-write-char" (letrec ((c-write-char (lambda (this c) (let fnrec392 ((this this) (c c)) (begin (if (jolt= c (integer->char 10)) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") 0) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "line") (jolt-inc (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line"))))) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (jolt-inc (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur"))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")) c)))))) c-write-char) (let* ((_o$393 (keyword #f "private")) (_o$394 #t)) (jolt-hash-map _o$393 _o$394)))) + (def-var! "clojure.pprint" "c-write-char" (letrec ((c-write-char (lambda (this c) (let fnrec342 ((this this) (c c)) (begin (if (jolt= c (integer->char 10)) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") 0) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "line") (jolt-inc (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line"))))) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (jolt-inc (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur"))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")) c)))))) c-write-char))) (guard (e (#t #f)) - (begin (begin (def-var! "clojure.pprint" "StringBufferWriter" (let* ((_a$395 (var-deref "clojure.core" "make-deftype-ctor")) (_a$396 (jolt-symbol #f "StringBufferWriter")) (_a$397 (jolt-vector (keyword #f "sb"))) (_a$398 (jolt-vector jolt-nil)) (_a$399 (jolt-vector #f))) (jolt-invoke _a$395 _a$396 _a$397 _a$398 _a$399))) (def-var! "clojure.pprint" "->StringBufferWriter" (var-deref "clojure.pprint" "StringBufferWriter")) (var-deref "clojure.pprint" "StringBufferWriter")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "StringBufferWriter")) (def-var! "clojure.pprint" "map->StringBufferWriter" (lambda (G__26) (let fnrec400 ((G__26 G__26)) (let* ((_a$401 (var-deref "clojure.core" "reduce-kv")) (_a$402 jolt-assoc) (_a$403 (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") (jolt-get G__26 (keyword #f "sb")))) (_a$404 (jolt-dissoc G__26 (keyword #f "sb")))) (jolt-invoke _a$401 _a$402 _a$403 _a$404))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "StringBufferWriter" "IPrettyWriter") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyWriter" "-write" (lambda (_p27 x) (let fnrec405 ((_p27 _p27) (x x)) (let* ((sb (jolt-get _p27 (keyword #f "sb")))) (begin (record-method-dispatch sb "append" (jolt-vector (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "char?") x)) (jolt-invoke (var-deref "clojure.core" "str") x) x))) jolt-nil))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyWriter" "-pflush" (lambda (_p28) (let fnrec406 ((_p28 _p28)) (let* ((sb (jolt-get _p28 (keyword #f "sb")))) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "StringBufferWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyFlush" "-ppflush" (lambda (_p29) (let fnrec407 ((_p29 _p29)) (let* ((sb (jolt-get _p29 (keyword #f "sb")))) jolt-nil)))))) + (begin (begin (def-var! "clojure.pprint" "StringBufferWriter" (let* ((_a$343 (var-deref "clojure.core" "make-deftype-ctor")) (_a$344 (jolt-symbol #f "StringBufferWriter")) (_a$345 (jolt-vector (keyword #f "sb"))) (_a$346 (jolt-vector jolt-nil)) (_a$347 (jolt-vector #f))) (jolt-invoke _a$343 _a$344 _a$345 _a$346 _a$347))) (def-var! "clojure.pprint" "->StringBufferWriter" (var-deref "clojure.pprint" "StringBufferWriter")) (var-deref "clojure.pprint" "StringBufferWriter")) (def-var! "clojure.pprint" "map->StringBufferWriter" (lambda (G__22) (let fnrec348 ((G__22 G__22)) (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") (jolt-get G__22 (keyword #f "sb")))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "StringBufferWriter" "IPrettyWriter") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyWriter" "-write" (lambda (_ x) (let fnrec349 ((_ _) (x x)) (let* ((sb (jolt-get _ (keyword #f "sb")))) (begin (record-method-dispatch sb "append" (jolt-vector (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "char?") x)) (jolt-invoke (var-deref "clojure.core" "str") x) x))) jolt-nil))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyWriter" "-pflush" (lambda (_) (let fnrec350 ((_ _)) (let* ((sb (jolt-get _ (keyword #f "sb")))) jolt-nil)))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "StringBufferWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "StringBufferWriter" "IPrettyFlush" "-ppflush" (lambda (_) (let fnrec351 ((_ _)) (let* ((sb (jolt-get _ (keyword #f "sb")))) jolt-nil)))))) (guard (e (#t #f)) - (begin (begin (def-var! "clojure.pprint" "ColumnWriter" (let* ((_a$408 (var-deref "clojure.core" "make-deftype-ctor")) (_a$409 (jolt-symbol #f "ColumnWriter")) (_a$410 (jolt-vector (keyword #f "fields"))) (_a$411 (jolt-vector jolt-nil)) (_a$412 (jolt-vector #f))) (jolt-invoke _a$408 _a$409 _a$410 _a$411 _a$412))) (def-var! "clojure.pprint" "->ColumnWriter" (var-deref "clojure.pprint" "ColumnWriter")) (var-deref "clojure.pprint" "ColumnWriter")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "ColumnWriter")) (def-var! "clojure.pprint" "map->ColumnWriter" (lambda (G__30) (let fnrec413 ((G__30 G__30)) (let* ((_a$414 (var-deref "clojure.core" "reduce-kv")) (_a$415 jolt-assoc) (_a$416 (jolt-invoke (var-deref "clojure.pprint" "->ColumnWriter") (jolt-get G__30 (keyword #f "fields")))) (_a$417 (jolt-dissoc G__30 (keyword #f "fields")))) (jolt-invoke _a$414 _a$415 _a$416 _a$417))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "ColumnWriter" "IPrettyWriter") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "ColumnWriter" "IPrettyWriter" "-write" (lambda (this x) (let fnrec418 ((this this) (x x)) (let* ((fields (jolt-get this (keyword #f "fields")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") x)) (let* ((s x) (nl (record-method-dispatch s "lastIndexOf" (jolt-vector "\n")))) (begin (if (jolt-neg? nl) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (let* ((_a$419 (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur"))) (_a$420 (jolt-count s))) (jolt-n+ _a$419 _a$420))) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (jolt-n- (jolt-count s) nl 1)) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "line") (let* ((_a$422 (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line"))) (_a$423 (jolt-count (jolt-filter (lambda (p__4_) (let fnrec421 ((p__4_ p__4_)) (jolt= p__4_ (integer->char 10)))) s)))) (jolt-n+ _a$422 _a$423))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")) s))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "char?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") x)))) (jolt-invoke (var-deref "clojure.pprint" "c-write-char") this x) jolt-nil)))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "ColumnWriter" "IPrettyWriter" "-pflush" (lambda (this) (let fnrec424 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (jolt-invoke (var-deref "clojure.pprint" "-pflush") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base"))))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "ColumnWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "ColumnWriter" "IPrettyFlush" "-ppflush" (lambda (_p31) (let fnrec425 ((_p31 _p31)) (let* ((fields (jolt-get _p31 (keyword #f "fields")))) jolt-nil)))))) + (begin (begin (def-var! 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(jolt-invoke (var-deref "clojure.core" "string?") x)) (let* ((s x) (nl (record-method-dispatch s "lastIndexOf" (jolt-vector "\n")))) (begin (if (jolt-neg? nl) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (let* ((_a$359 (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "cur"))) (_a$360 (jolt-count s))) (+ _a$359 _a$360))) (begin (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "cur") (- (jolt-count s) nl 1)) (jolt-invoke (var-deref "clojure.pprint" "set-field") this (keyword #f "line") (let* ((_a$362 (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "line"))) (_a$363 (jolt-count (jolt-filter (lambda (p__4_) (let fnrec361 ((p__4_ p__4_)) (jolt= p__4_ (integer->char 10)))) s)))) (+ _a$362 _a$363))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base")) s))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "char?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") x)))) (jolt-invoke (var-deref "clojure.pprint" "c-write-char") this x) jolt-nil)))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "ColumnWriter" "IPrettyWriter" "-pflush" (lambda (this) (let fnrec364 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (jolt-invoke (var-deref "clojure.pprint" "-pflush") (jolt-invoke (var-deref "clojure.pprint" "get-field") this (keyword #f "base"))))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "ColumnWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "ColumnWriter" "IPrettyFlush" "-ppflush" (lambda (_) (let fnrec365 ((_ _)) (let* ((fields (jolt-get _ (keyword #f "fields")))) jolt-nil)))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "column-writer" (letrec ((column-writer (case-lambda ((writer) (let fnrec426 ((writer writer)) (column-writer writer (var-deref "clojure.pprint" "*default-page-width*")))) ((writer max-columns) (let fnrec427 ((writer writer) (max-columns max-columns)) (jolt-invoke (var-deref "clojure.pprint" "->ColumnWriter") (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$428 (keyword #f "max")) (_o$429 max-columns) (_o$430 (keyword #f "cur")) (_o$431 0) (_o$432 (keyword #f "line")) (_o$433 0) (_o$434 (keyword #f "base")) (_o$435 writer)) (jolt-hash-map _o$428 _o$429 _o$430 _o$431 _o$432 _o$433 _o$434 _o$435))))))))) column-writer) (let* ((_o$436 (keyword #f "private")) (_o$437 #t)) (jolt-hash-map _o$436 _o$437)))) + (def-var! "clojure.pprint" "column-writer" (letrec ((column-writer (case-lambda ((writer) (let fnrec366 ((writer writer)) (jolt-invoke column-writer writer (var-deref "clojure.pprint" "*default-page-width*")))) ((writer max-columns) (let fnrec367 ((writer writer) (max-columns max-columns)) (jolt-invoke (var-deref "clojure.pprint" "->ColumnWriter") (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$368 (keyword #f "max")) (_o$369 max-columns) (_o$370 (keyword #f "cur")) (_o$371 0) (_o$372 (keyword #f "line")) (_o$373 0) (_o$374 (keyword #f "base")) (_o$375 writer)) (jolt-hash-map _o$368 _o$369 _o$370 _o$371 _o$372 _o$373 _o$374 _o$375))))))))) column-writer))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "get-miser-width")) (guard (e (#t #f)) - (begin (begin (def-var! "clojure.pprint" "logical-block" (let* ((_a$468 (var-deref "clojure.core" "make-deftype-ctor")) (_a$469 (jolt-symbol #f "logical-block")) (_a$470 (let* ((_o$438 (keyword #f "parent")) (_o$439 (keyword #f "section")) (_o$440 (keyword #f "start-col")) (_o$441 (keyword #f "indent")) (_o$442 (keyword #f "done-nl")) (_o$443 (keyword #f "intra-block-nl")) (_o$444 (keyword #f "prefix")) (_o$445 (keyword #f "per-line-prefix")) (_o$446 (keyword #f "suffix")) (_o$447 (keyword #f "logical-block-callback"))) (jolt-vector _o$438 _o$439 _o$440 _o$441 _o$442 _o$443 _o$444 _o$445 _o$446 _o$447))) (_a$471 (let* ((_o$448 jolt-nil) (_o$449 jolt-nil) (_o$450 jolt-nil) (_o$451 jolt-nil) (_o$452 jolt-nil) (_o$453 jolt-nil) (_o$454 jolt-nil) (_o$455 jolt-nil) (_o$456 jolt-nil) (_o$457 jolt-nil)) (jolt-vector _o$448 _o$449 _o$450 _o$451 _o$452 _o$453 _o$454 _o$455 _o$456 _o$457))) (_a$472 (let* ((_o$458 #f) (_o$459 #f) (_o$460 #f) (_o$461 #f) (_o$462 #f) (_o$463 #f) (_o$464 #f) (_o$465 #f) (_o$466 #f) (_o$467 #f)) (jolt-vector _o$458 _o$459 _o$460 _o$461 _o$462 _o$463 _o$464 _o$465 _o$466 _o$467)))) (jolt-invoke _a$468 _a$469 _a$470 _a$471 _a$472))) (def-var! "clojure.pprint" "->logical-block" (var-deref "clojure.pprint" "logical-block")) (var-deref "clojure.pprint" "logical-block")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "logical-block")) (def-var! "clojure.pprint" "map->logical-block" (lambda (G__32) (let fnrec473 ((G__32 G__32)) (let* ((_a$485 (var-deref "clojure.core" "reduce-kv")) (_a$486 jolt-assoc) (_a$487 (let* ((_a$474 (var-deref "clojure.pprint" "->logical-block")) (_a$475 (jolt-get G__32 (keyword #f "parent"))) (_a$476 (jolt-get G__32 (keyword #f "section"))) (_a$477 (jolt-get G__32 (keyword #f "start-col"))) (_a$478 (jolt-get G__32 (keyword #f "indent"))) (_a$479 (jolt-get G__32 (keyword #f "done-nl"))) (_a$480 (jolt-get G__32 (keyword #f "intra-block-nl"))) (_a$481 (jolt-get G__32 (keyword #f "prefix"))) (_a$482 (jolt-get G__32 (keyword #f "per-line-prefix"))) (_a$483 (jolt-get G__32 (keyword #f "suffix"))) (_a$484 (jolt-get G__32 (keyword #f "logical-block-callback")))) (jolt-invoke _a$474 _a$475 _a$476 _a$477 _a$478 _a$479 _a$480 _a$481 _a$482 _a$483 _a$484))) (_a$488 (jolt-dissoc G__32 (keyword #f "parent") (keyword #f "section") (keyword #f "start-col") (keyword #f "indent") (keyword #f "done-nl") (keyword #f "intra-block-nl") (keyword #f "prefix") (keyword #f "per-line-prefix") (keyword #f "suffix") (keyword #f "logical-block-callback")))) (jolt-invoke _a$485 _a$486 _a$487 _a$488))))))) + (begin (begin (def-var! "clojure.pprint" "logical-block" (let* ((_a$406 (var-deref "clojure.core" "make-deftype-ctor")) (_a$407 (jolt-symbol #f "logical-block")) (_a$408 (let* ((_o$376 (keyword #f "parent")) (_o$377 (keyword #f "section")) (_o$378 (keyword #f "start-col")) (_o$379 (keyword #f "indent")) (_o$380 (keyword #f "done-nl")) (_o$381 (keyword #f "intra-block-nl")) (_o$382 (keyword #f "prefix")) (_o$383 (keyword #f "per-line-prefix")) (_o$384 (keyword #f "suffix")) (_o$385 (keyword #f "logical-block-callback"))) (jolt-vector _o$376 _o$377 _o$378 _o$379 _o$380 _o$381 _o$382 _o$383 _o$384 _o$385))) (_a$409 (let* ((_o$386 jolt-nil) (_o$387 jolt-nil) (_o$388 jolt-nil) (_o$389 jolt-nil) (_o$390 jolt-nil) (_o$391 jolt-nil) (_o$392 jolt-nil) (_o$393 jolt-nil) (_o$394 jolt-nil) (_o$395 jolt-nil)) (jolt-vector _o$386 _o$387 _o$388 _o$389 _o$390 _o$391 _o$392 _o$393 _o$394 _o$395))) (_a$410 (let* ((_o$396 #f) (_o$397 #f) (_o$398 #f) (_o$399 #f) (_o$400 #f) (_o$401 #f) (_o$402 #f) (_o$403 #f) (_o$404 #f) (_o$405 #f)) (jolt-vector _o$396 _o$397 _o$398 _o$399 _o$400 _o$401 _o$402 _o$403 _o$404 _o$405)))) (jolt-invoke _a$406 _a$407 _a$408 _a$409 _a$410))) (def-var! "clojure.pprint" "->logical-block" (var-deref "clojure.pprint" "logical-block")) (var-deref "clojure.pprint" "logical-block")) (def-var! "clojure.pprint" "map->logical-block" (lambda (G__24) (let fnrec411 ((G__24 G__24)) (let* ((_a$412 (var-deref "clojure.pprint" "->logical-block")) (_a$413 (jolt-get G__24 (keyword #f "parent"))) (_a$414 (jolt-get G__24 (keyword #f "section"))) (_a$415 (jolt-get G__24 (keyword #f "start-col"))) (_a$416 (jolt-get G__24 (keyword #f "indent"))) (_a$417 (jolt-get G__24 (keyword #f "done-nl"))) (_a$418 (jolt-get G__24 (keyword #f "intra-block-nl"))) (_a$419 (jolt-get G__24 (keyword #f "prefix"))) (_a$420 (jolt-get G__24 (keyword #f "per-line-prefix"))) (_a$421 (jolt-get G__24 (keyword #f "suffix"))) (_a$422 (jolt-get G__24 (keyword #f "logical-block-callback")))) (jolt-invoke _a$412 _a$413 _a$414 _a$415 _a$416 _a$417 _a$418 _a$419 _a$420 _a$421 _a$422))))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "ancestor?" (letrec ((ancestor? (lambda (parent child) (let fnrec489 ((parent parent) (child child)) (let* ((child (jolt-get child (keyword #f "parent")))) (let loop490 ((child child)) (if (jolt-nil? child) #f (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "identical?") parent child)) #t (if (jolt-truthy? (keyword #f "else")) (loop490 (jolt-get child (keyword #f "parent"))) jolt-nil))))))))) ancestor?) (let* ((_o$491 (keyword #f "private")) (_o$492 #t)) (jolt-hash-map _o$491 _o$492)))) + (def-var! "clojure.pprint" "ancestor?" (letrec ((ancestor? (lambda (parent child) (let fnrec423 ((parent parent) (child child)) (let* ((child (jolt-get child (keyword #f "parent")))) (let loop424 ((child child)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") child)) #f (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "identical?") parent child)) #t (if (jolt-truthy? (keyword #f "else")) (loop424 (jolt-get child (keyword #f "parent"))) jolt-nil))))))))) ancestor?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "buffer-length" (letrec ((buffer-length (lambda (l) (let fnrec493 ((l l)) (let* ((l (jolt-seq l))) (if (jolt-truthy? l) (let* ((_a$494 (jolt-get (jolt-last l) (keyword #f "end-pos"))) (_a$495 (jolt-get (jolt-first l) (keyword #f "start-pos")))) (jolt-n- _a$494 _a$495)) 0)))))) buffer-length) (let* ((_o$496 (keyword #f "private")) (_o$497 #t)) (jolt-hash-map _o$496 _o$497)))) + (def-var! "clojure.pprint" "buffer-length" (letrec ((buffer-length (lambda (l) (let fnrec425 ((l l)) (let* ((l (jolt-seq l))) (if (jolt-truthy? l) (let* ((_a$426 (jolt-get (jolt-last l) (keyword #f "end-pos"))) (_a$427 (jolt-get (jolt-first l) (keyword #f "start-pos")))) (- _a$426 _a$427)) 0)))))) buffer-length))) (guard (e (#t #f)) - (begin (begin (begin (def-var! "clojure.pprint" "buffer-blob" (let* ((_a$513 (var-deref "clojure.core" "make-deftype-ctor")) (_a$514 (jolt-symbol #f "buffer-blob")) (_a$515 (let* ((_o$498 (keyword #f "type-tag")) (_o$499 (keyword #f "data")) (_o$500 (keyword #f "trailing-white-space")) (_o$501 (keyword #f "start-pos")) (_o$502 (keyword #f "end-pos"))) (jolt-vector _o$498 _o$499 _o$500 _o$501 _o$502))) (_a$516 (let* ((_o$503 jolt-nil) (_o$504 jolt-nil) (_o$505 jolt-nil) (_o$506 jolt-nil) (_o$507 jolt-nil)) (jolt-vector _o$503 _o$504 _o$505 _o$506 _o$507))) (_a$517 (let* ((_o$508 #f) (_o$509 #f) (_o$510 #f) (_o$511 #f) (_o$512 #f)) (jolt-vector _o$508 _o$509 _o$510 _o$511 _o$512)))) (jolt-invoke _a$513 _a$514 _a$515 _a$516 _a$517))) (def-var! "clojure.pprint" "->buffer-blob" (var-deref "clojure.pprint" "buffer-blob")) (var-deref "clojure.pprint" "buffer-blob")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "buffer-blob")) (def-var! "clojure.pprint" "map->buffer-blob" (lambda (G__33) (let fnrec518 ((G__33 G__33)) (let* ((_a$525 (var-deref "clojure.core" "reduce-kv")) (_a$526 jolt-assoc) (_a$527 (let* ((_a$519 (var-deref "clojure.pprint" "->buffer-blob")) (_a$520 (jolt-get G__33 (keyword #f "type-tag"))) (_a$521 (jolt-get G__33 (keyword #f "data"))) (_a$522 (jolt-get G__33 (keyword #f "trailing-white-space"))) (_a$523 (jolt-get G__33 (keyword #f "start-pos"))) (_a$524 (jolt-get G__33 (keyword #f "end-pos")))) (jolt-invoke _a$519 _a$520 _a$521 _a$522 _a$523 _a$524))) (_a$528 (jolt-dissoc G__33 (keyword #f "type-tag") (keyword #f "data") (keyword #f "trailing-white-space") (keyword #f "start-pos") (keyword #f "end-pos")))) (jolt-invoke _a$525 _a$526 _a$527 _a$528)))))) (def-var-with-meta! "clojure.pprint" "make-buffer-blob" (letrec ((make-buffer-blob (lambda (data trailing-white-space start-pos end-pos) (let fnrec529 ((data data) (trailing-white-space trailing-white-space) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->buffer-blob") (keyword #f "buffer-blob") data trailing-white-space start-pos end-pos))))) make-buffer-blob) (let* ((_o$530 (keyword #f "private")) (_o$531 #t)) (jolt-hash-map _o$530 _o$531))) (def-var-with-meta! "clojure.pprint" "buffer-blob?" (letrec ((buffer-blob? (lambda (x__1__auto) (let fnrec532 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "buffer-blob")))))) buffer-blob?) (let* ((_o$533 (keyword #f "private")) (_o$534 #t)) (jolt-hash-map _o$533 _o$534))))) + (begin (begin (begin (def-var! "clojure.pprint" "buffer-blob" (let* ((_a$443 (var-deref "clojure.core" "make-deftype-ctor")) (_a$444 (jolt-symbol #f "buffer-blob")) (_a$445 (let* ((_o$428 (keyword #f "type-tag")) (_o$429 (keyword #f "data")) (_o$430 (keyword #f "trailing-white-space")) (_o$431 (keyword #f "start-pos")) (_o$432 (keyword #f "end-pos"))) (jolt-vector _o$428 _o$429 _o$430 _o$431 _o$432))) (_a$446 (let* ((_o$433 jolt-nil) (_o$434 jolt-nil) (_o$435 jolt-nil) (_o$436 jolt-nil) (_o$437 jolt-nil)) (jolt-vector _o$433 _o$434 _o$435 _o$436 _o$437))) (_a$447 (let* ((_o$438 #f) (_o$439 #f) (_o$440 #f) (_o$441 #f) (_o$442 #f)) (jolt-vector _o$438 _o$439 _o$440 _o$441 _o$442)))) (jolt-invoke _a$443 _a$444 _a$445 _a$446 _a$447))) (def-var! "clojure.pprint" "->buffer-blob" (var-deref "clojure.pprint" "buffer-blob")) (var-deref "clojure.pprint" "buffer-blob")) (def-var! "clojure.pprint" "map->buffer-blob" (lambda (G__25) (let fnrec448 ((G__25 G__25)) (let* ((_a$449 (var-deref "clojure.pprint" "->buffer-blob")) (_a$450 (jolt-get G__25 (keyword #f "type-tag"))) (_a$451 (jolt-get G__25 (keyword #f "data"))) (_a$452 (jolt-get G__25 (keyword #f "trailing-white-space"))) (_a$453 (jolt-get G__25 (keyword #f "start-pos"))) (_a$454 (jolt-get G__25 (keyword #f "end-pos")))) (jolt-invoke _a$449 _a$450 _a$451 _a$452 _a$453 _a$454)))))) (def-var! "clojure.pprint" "make-buffer-blob" (letrec ((make-buffer-blob (lambda (data trailing-white-space start-pos end-pos) (let fnrec455 ((data data) (trailing-white-space trailing-white-space) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->buffer-blob") (keyword #f "buffer-blob") data trailing-white-space start-pos end-pos))))) make-buffer-blob)) (def-var! "clojure.pprint" "buffer-blob?" (letrec ((buffer-blob? (lambda (x__1__auto) (let fnrec456 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "buffer-blob")))))) buffer-blob?)))) (guard (e (#t #f)) - (begin (begin (begin (def-var! "clojure.pprint" "nl-t" (let* ((_a$550 (var-deref "clojure.core" "make-deftype-ctor")) (_a$551 (jolt-symbol #f "nl-t")) (_a$552 (let* ((_o$535 (keyword #f "type-tag")) (_o$536 (keyword #f "type")) (_o$537 (keyword #f "logical-block")) (_o$538 (keyword #f "start-pos")) (_o$539 (keyword #f "end-pos"))) (jolt-vector _o$535 _o$536 _o$537 _o$538 _o$539))) (_a$553 (let* ((_o$540 jolt-nil) (_o$541 jolt-nil) (_o$542 jolt-nil) (_o$543 jolt-nil) (_o$544 jolt-nil)) (jolt-vector _o$540 _o$541 _o$542 _o$543 _o$544))) (_a$554 (let* ((_o$545 #f) (_o$546 #f) (_o$547 #f) (_o$548 #f) (_o$549 #f)) (jolt-vector _o$545 _o$546 _o$547 _o$548 _o$549)))) (jolt-invoke _a$550 _a$551 _a$552 _a$553 _a$554))) (def-var! "clojure.pprint" "->nl-t" (var-deref "clojure.pprint" "nl-t")) (var-deref "clojure.pprint" "nl-t")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "nl-t")) (def-var! "clojure.pprint" "map->nl-t" (lambda (G__34) (let fnrec555 ((G__34 G__34)) (let* ((_a$562 (var-deref "clojure.core" "reduce-kv")) (_a$563 jolt-assoc) (_a$564 (let* ((_a$556 (var-deref "clojure.pprint" "->nl-t")) (_a$557 (jolt-get G__34 (keyword #f "type-tag"))) (_a$558 (jolt-get G__34 (keyword #f "type"))) (_a$559 (jolt-get G__34 (keyword #f "logical-block"))) (_a$560 (jolt-get G__34 (keyword #f "start-pos"))) (_a$561 (jolt-get G__34 (keyword #f "end-pos")))) (jolt-invoke _a$556 _a$557 _a$558 _a$559 _a$560 _a$561))) (_a$565 (jolt-dissoc G__34 (keyword #f "type-tag") (keyword #f "type") (keyword #f "logical-block") (keyword #f "start-pos") (keyword #f "end-pos")))) (jolt-invoke _a$562 _a$563 _a$564 _a$565)))))) (def-var-with-meta! "clojure.pprint" "make-nl-t" (letrec ((make-nl-t (lambda (type logical-block start-pos end-pos) (let fnrec566 ((type type) (logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->nl-t") (keyword #f "nl-t") type logical-block start-pos end-pos))))) make-nl-t) (let* ((_o$567 (keyword #f "private")) (_o$568 #t)) (jolt-hash-map _o$567 _o$568))) (def-var-with-meta! "clojure.pprint" "nl-t?" (letrec ((nl-t? (lambda (x__1__auto) (let fnrec569 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "nl-t")))))) nl-t?) (let* ((_o$570 (keyword #f "private")) (_o$571 #t)) (jolt-hash-map _o$570 _o$571))))) + (begin (begin (begin (def-var! "clojure.pprint" "nl-t" (let* ((_a$472 (var-deref "clojure.core" "make-deftype-ctor")) (_a$473 (jolt-symbol #f "nl-t")) (_a$474 (let* ((_o$457 (keyword #f "type-tag")) (_o$458 (keyword #f "type")) (_o$459 (keyword #f "logical-block")) (_o$460 (keyword #f "start-pos")) (_o$461 (keyword #f "end-pos"))) (jolt-vector _o$457 _o$458 _o$459 _o$460 _o$461))) (_a$475 (let* ((_o$462 jolt-nil) (_o$463 jolt-nil) (_o$464 jolt-nil) (_o$465 jolt-nil) (_o$466 jolt-nil)) (jolt-vector _o$462 _o$463 _o$464 _o$465 _o$466))) (_a$476 (let* ((_o$467 #f) (_o$468 #f) (_o$469 #f) (_o$470 #f) (_o$471 #f)) (jolt-vector _o$467 _o$468 _o$469 _o$470 _o$471)))) (jolt-invoke _a$472 _a$473 _a$474 _a$475 _a$476))) (def-var! "clojure.pprint" "->nl-t" (var-deref "clojure.pprint" "nl-t")) (var-deref "clojure.pprint" "nl-t")) (def-var! "clojure.pprint" "map->nl-t" (lambda (G__26) (let fnrec477 ((G__26 G__26)) (let* ((_a$478 (var-deref "clojure.pprint" "->nl-t")) (_a$479 (jolt-get G__26 (keyword #f "type-tag"))) (_a$480 (jolt-get G__26 (keyword #f "type"))) (_a$481 (jolt-get G__26 (keyword #f "logical-block"))) (_a$482 (jolt-get G__26 (keyword #f "start-pos"))) (_a$483 (jolt-get G__26 (keyword #f "end-pos")))) (jolt-invoke _a$478 _a$479 _a$480 _a$481 _a$482 _a$483)))))) (def-var! "clojure.pprint" "make-nl-t" (letrec ((make-nl-t (lambda (type logical-block start-pos end-pos) (let fnrec484 ((type type) (logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->nl-t") (keyword #f "nl-t") type logical-block start-pos end-pos))))) make-nl-t)) (def-var! "clojure.pprint" "nl-t?" (letrec ((nl-t? (lambda (x__1__auto) (let fnrec485 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "nl-t")))))) nl-t?)))) (guard (e (#t #f)) - (begin (begin (begin (def-var! "clojure.pprint" "start-block-t" (let* ((_a$584 (var-deref "clojure.core" "make-deftype-ctor")) (_a$585 (jolt-symbol #f "start-block-t")) (_a$586 (let* ((_o$572 (keyword #f "type-tag")) (_o$573 (keyword #f "logical-block")) (_o$574 (keyword #f "start-pos")) (_o$575 (keyword #f "end-pos"))) (jolt-vector _o$572 _o$573 _o$574 _o$575))) (_a$587 (let* ((_o$576 jolt-nil) (_o$577 jolt-nil) (_o$578 jolt-nil) (_o$579 jolt-nil)) (jolt-vector _o$576 _o$577 _o$578 _o$579))) (_a$588 (let* ((_o$580 #f) (_o$581 #f) (_o$582 #f) (_o$583 #f)) (jolt-vector _o$580 _o$581 _o$582 _o$583)))) (jolt-invoke _a$584 _a$585 _a$586 _a$587 _a$588))) (def-var! "clojure.pprint" "->start-block-t" (var-deref "clojure.pprint" "start-block-t")) (var-deref "clojure.pprint" "start-block-t")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "start-block-t")) (def-var! "clojure.pprint" "map->start-block-t" (lambda (G__35) (let fnrec589 ((G__35 G__35)) (let* ((_a$595 (var-deref "clojure.core" "reduce-kv")) (_a$596 jolt-assoc) (_a$597 (let* ((_a$590 (var-deref "clojure.pprint" "->start-block-t")) (_a$591 (jolt-get G__35 (keyword #f "type-tag"))) (_a$592 (jolt-get G__35 (keyword #f "logical-block"))) (_a$593 (jolt-get G__35 (keyword #f "start-pos"))) (_a$594 (jolt-get G__35 (keyword #f "end-pos")))) (jolt-invoke _a$590 _a$591 _a$592 _a$593 _a$594))) (_a$598 (jolt-dissoc G__35 (keyword #f "type-tag") (keyword #f "logical-block") (keyword #f "start-pos") (keyword #f "end-pos")))) (jolt-invoke _a$595 _a$596 _a$597 _a$598)))))) (def-var-with-meta! "clojure.pprint" "make-start-block-t" (letrec ((make-start-block-t (lambda (logical-block start-pos end-pos) (let fnrec599 ((logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->start-block-t") (keyword #f "start-block-t") logical-block start-pos end-pos))))) make-start-block-t) (let* ((_o$600 (keyword #f "private")) (_o$601 #t)) (jolt-hash-map _o$600 _o$601))) (def-var-with-meta! "clojure.pprint" "start-block-t?" (letrec ((start-block-t? (lambda (x__1__auto) (let fnrec602 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "start-block-t")))))) start-block-t?) (let* ((_o$603 (keyword #f "private")) (_o$604 #t)) (jolt-hash-map _o$603 _o$604))))) + (begin (begin (begin (def-var! "clojure.pprint" "start-block-t" (let* ((_a$498 (var-deref "clojure.core" "make-deftype-ctor")) (_a$499 (jolt-symbol #f "start-block-t")) (_a$500 (let* ((_o$486 (keyword #f "type-tag")) (_o$487 (keyword #f "logical-block")) (_o$488 (keyword #f "start-pos")) (_o$489 (keyword #f "end-pos"))) (jolt-vector _o$486 _o$487 _o$488 _o$489))) (_a$501 (let* ((_o$490 jolt-nil) (_o$491 jolt-nil) (_o$492 jolt-nil) (_o$493 jolt-nil)) (jolt-vector _o$490 _o$491 _o$492 _o$493))) (_a$502 (let* ((_o$494 #f) (_o$495 #f) (_o$496 #f) (_o$497 #f)) (jolt-vector _o$494 _o$495 _o$496 _o$497)))) (jolt-invoke _a$498 _a$499 _a$500 _a$501 _a$502))) (def-var! "clojure.pprint" "->start-block-t" (var-deref "clojure.pprint" "start-block-t")) (var-deref "clojure.pprint" "start-block-t")) (def-var! "clojure.pprint" "map->start-block-t" (lambda (G__27) (let fnrec503 ((G__27 G__27)) (let* ((_a$504 (var-deref "clojure.pprint" "->start-block-t")) (_a$505 (jolt-get G__27 (keyword #f "type-tag"))) (_a$506 (jolt-get G__27 (keyword #f "logical-block"))) (_a$507 (jolt-get G__27 (keyword #f "start-pos"))) (_a$508 (jolt-get G__27 (keyword #f "end-pos")))) (jolt-invoke _a$504 _a$505 _a$506 _a$507 _a$508)))))) (def-var! "clojure.pprint" "make-start-block-t" (letrec ((make-start-block-t (lambda (logical-block start-pos end-pos) (let fnrec509 ((logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->start-block-t") (keyword #f "start-block-t") logical-block start-pos end-pos))))) make-start-block-t)) (def-var! "clojure.pprint" "start-block-t?" (letrec ((start-block-t? (lambda (x__1__auto) (let fnrec510 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "start-block-t")))))) start-block-t?)))) (guard (e (#t #f)) - (begin (begin (begin (def-var! "clojure.pprint" "end-block-t" (let* ((_a$617 (var-deref "clojure.core" "make-deftype-ctor")) (_a$618 (jolt-symbol #f "end-block-t")) (_a$619 (let* ((_o$605 (keyword #f "type-tag")) (_o$606 (keyword #f "logical-block")) (_o$607 (keyword #f "start-pos")) (_o$608 (keyword #f "end-pos"))) (jolt-vector _o$605 _o$606 _o$607 _o$608))) (_a$620 (let* ((_o$609 jolt-nil) (_o$610 jolt-nil) (_o$611 jolt-nil) (_o$612 jolt-nil)) (jolt-vector _o$609 _o$610 _o$611 _o$612))) (_a$621 (let* ((_o$613 #f) (_o$614 #f) (_o$615 #f) (_o$616 #f)) (jolt-vector _o$613 _o$614 _o$615 _o$616)))) (jolt-invoke _a$617 _a$618 _a$619 _a$620 _a$621))) (def-var! "clojure.pprint" "->end-block-t" (var-deref "clojure.pprint" "end-block-t")) (var-deref "clojure.pprint" "end-block-t")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "end-block-t")) (def-var! "clojure.pprint" "map->end-block-t" (lambda (G__36) (let fnrec622 ((G__36 G__36)) (let* ((_a$628 (var-deref "clojure.core" "reduce-kv")) (_a$629 jolt-assoc) (_a$630 (let* ((_a$623 (var-deref "clojure.pprint" "->end-block-t")) (_a$624 (jolt-get G__36 (keyword #f "type-tag"))) (_a$625 (jolt-get G__36 (keyword #f "logical-block"))) (_a$626 (jolt-get G__36 (keyword #f "start-pos"))) (_a$627 (jolt-get G__36 (keyword #f "end-pos")))) (jolt-invoke _a$623 _a$624 _a$625 _a$626 _a$627))) (_a$631 (jolt-dissoc G__36 (keyword #f "type-tag") (keyword #f "logical-block") (keyword #f "start-pos") (keyword #f "end-pos")))) (jolt-invoke _a$628 _a$629 _a$630 _a$631)))))) (def-var-with-meta! "clojure.pprint" "make-end-block-t" (letrec ((make-end-block-t (lambda (logical-block start-pos end-pos) (let fnrec632 ((logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->end-block-t") (keyword #f "end-block-t") logical-block start-pos end-pos))))) make-end-block-t) (let* ((_o$633 (keyword #f "private")) (_o$634 #t)) (jolt-hash-map _o$633 _o$634))) (def-var-with-meta! "clojure.pprint" "end-block-t?" (letrec ((end-block-t? (lambda (x__1__auto) (let fnrec635 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "end-block-t")))))) end-block-t?) (let* ((_o$636 (keyword #f "private")) (_o$637 #t)) (jolt-hash-map _o$636 _o$637))))) + (begin (begin (begin (def-var! "clojure.pprint" "end-block-t" (let* ((_a$523 (var-deref "clojure.core" "make-deftype-ctor")) (_a$524 (jolt-symbol #f "end-block-t")) (_a$525 (let* ((_o$511 (keyword #f "type-tag")) (_o$512 (keyword #f "logical-block")) (_o$513 (keyword #f "start-pos")) (_o$514 (keyword #f "end-pos"))) (jolt-vector _o$511 _o$512 _o$513 _o$514))) (_a$526 (let* ((_o$515 jolt-nil) (_o$516 jolt-nil) (_o$517 jolt-nil) (_o$518 jolt-nil)) (jolt-vector _o$515 _o$516 _o$517 _o$518))) (_a$527 (let* ((_o$519 #f) (_o$520 #f) (_o$521 #f) (_o$522 #f)) (jolt-vector _o$519 _o$520 _o$521 _o$522)))) (jolt-invoke _a$523 _a$524 _a$525 _a$526 _a$527))) (def-var! "clojure.pprint" "->end-block-t" (var-deref "clojure.pprint" "end-block-t")) (var-deref "clojure.pprint" "end-block-t")) (def-var! "clojure.pprint" "map->end-block-t" (lambda (G__28) (let fnrec528 ((G__28 G__28)) (let* ((_a$529 (var-deref "clojure.pprint" "->end-block-t")) (_a$530 (jolt-get G__28 (keyword #f "type-tag"))) (_a$531 (jolt-get G__28 (keyword #f "logical-block"))) (_a$532 (jolt-get G__28 (keyword #f "start-pos"))) (_a$533 (jolt-get G__28 (keyword #f "end-pos")))) (jolt-invoke _a$529 _a$530 _a$531 _a$532 _a$533)))))) (def-var! "clojure.pprint" "make-end-block-t" (letrec ((make-end-block-t (lambda (logical-block start-pos end-pos) (let fnrec534 ((logical-block logical-block) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->end-block-t") (keyword #f "end-block-t") logical-block start-pos end-pos))))) make-end-block-t)) (def-var! "clojure.pprint" "end-block-t?" (letrec ((end-block-t? (lambda (x__1__auto) (let fnrec535 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "end-block-t")))))) end-block-t?)))) (guard (e (#t #f)) - (begin (begin (begin (def-var! "clojure.pprint" "indent-t" (let* ((_a$656 (var-deref "clojure.core" "make-deftype-ctor")) (_a$657 (jolt-symbol #f "indent-t")) (_a$658 (let* ((_o$638 (keyword #f "type-tag")) (_o$639 (keyword #f "logical-block")) (_o$640 (keyword #f "relative-to")) (_o$641 (keyword #f "offset")) (_o$642 (keyword #f "start-pos")) (_o$643 (keyword #f "end-pos"))) (jolt-vector _o$638 _o$639 _o$640 _o$641 _o$642 _o$643))) (_a$659 (let* ((_o$644 jolt-nil) (_o$645 jolt-nil) (_o$646 jolt-nil) (_o$647 jolt-nil) (_o$648 jolt-nil) (_o$649 jolt-nil)) (jolt-vector _o$644 _o$645 _o$646 _o$647 _o$648 _o$649))) (_a$660 (let* ((_o$650 #f) (_o$651 #f) (_o$652 #f) (_o$653 #f) (_o$654 #f) (_o$655 #f)) (jolt-vector _o$650 _o$651 _o$652 _o$653 _o$654 _o$655)))) (jolt-invoke _a$656 _a$657 _a$658 _a$659 _a$660))) (def-var! "clojure.pprint" "->indent-t" (var-deref "clojure.pprint" "indent-t")) (var-deref "clojure.pprint" "indent-t")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "indent-t")) (def-var! "clojure.pprint" "map->indent-t" (lambda (G__37) (let fnrec661 ((G__37 G__37)) (let* ((_a$669 (var-deref "clojure.core" "reduce-kv")) (_a$670 jolt-assoc) (_a$671 (let* ((_a$662 (var-deref "clojure.pprint" "->indent-t")) (_a$663 (jolt-get G__37 (keyword #f "type-tag"))) (_a$664 (jolt-get G__37 (keyword #f "logical-block"))) (_a$665 (jolt-get G__37 (keyword #f "relative-to"))) (_a$666 (jolt-get G__37 (keyword #f "offset"))) (_a$667 (jolt-get G__37 (keyword #f "start-pos"))) (_a$668 (jolt-get G__37 (keyword #f "end-pos")))) (jolt-invoke _a$662 _a$663 _a$664 _a$665 _a$666 _a$667 _a$668))) (_a$672 (jolt-dissoc G__37 (keyword #f "type-tag") (keyword #f "logical-block") (keyword #f "relative-to") (keyword #f "offset") (keyword #f "start-pos") (keyword #f "end-pos")))) (jolt-invoke _a$669 _a$670 _a$671 _a$672)))))) (def-var-with-meta! "clojure.pprint" "make-indent-t" (letrec ((make-indent-t (lambda (logical-block relative-to offset start-pos end-pos) (let fnrec673 ((logical-block logical-block) (relative-to relative-to) (offset offset) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->indent-t") (keyword #f "indent-t") logical-block relative-to offset start-pos end-pos))))) make-indent-t) (let* ((_o$674 (keyword #f "private")) (_o$675 #t)) (jolt-hash-map _o$674 _o$675))) (def-var-with-meta! "clojure.pprint" "indent-t?" (letrec ((indent-t? (lambda (x__1__auto) (let fnrec676 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "indent-t")))))) indent-t?) (let* ((_o$677 (keyword #f "private")) (_o$678 #t)) (jolt-hash-map _o$677 _o$678))))) + (begin (begin (begin (def-var! "clojure.pprint" "indent-t" (let* ((_a$554 (var-deref "clojure.core" "make-deftype-ctor")) (_a$555 (jolt-symbol #f "indent-t")) (_a$556 (let* ((_o$536 (keyword #f "type-tag")) (_o$537 (keyword #f "logical-block")) (_o$538 (keyword #f "relative-to")) (_o$539 (keyword #f "offset")) (_o$540 (keyword #f "start-pos")) (_o$541 (keyword #f "end-pos"))) (jolt-vector _o$536 _o$537 _o$538 _o$539 _o$540 _o$541))) (_a$557 (let* ((_o$542 jolt-nil) (_o$543 jolt-nil) (_o$544 jolt-nil) (_o$545 jolt-nil) (_o$546 jolt-nil) (_o$547 jolt-nil)) (jolt-vector _o$542 _o$543 _o$544 _o$545 _o$546 _o$547))) (_a$558 (let* ((_o$548 #f) (_o$549 #f) (_o$550 #f) (_o$551 #f) (_o$552 #f) (_o$553 #f)) (jolt-vector _o$548 _o$549 _o$550 _o$551 _o$552 _o$553)))) (jolt-invoke _a$554 _a$555 _a$556 _a$557 _a$558))) (def-var! "clojure.pprint" "->indent-t" (var-deref "clojure.pprint" "indent-t")) (var-deref "clojure.pprint" "indent-t")) (def-var! "clojure.pprint" "map->indent-t" (lambda (G__29) (let fnrec559 ((G__29 G__29)) (let* ((_a$560 (var-deref "clojure.pprint" "->indent-t")) (_a$561 (jolt-get G__29 (keyword #f "type-tag"))) (_a$562 (jolt-get G__29 (keyword #f "logical-block"))) (_a$563 (jolt-get G__29 (keyword #f "relative-to"))) (_a$564 (jolt-get G__29 (keyword #f "offset"))) (_a$565 (jolt-get G__29 (keyword #f "start-pos"))) (_a$566 (jolt-get G__29 (keyword #f "end-pos")))) (jolt-invoke _a$560 _a$561 _a$562 _a$563 _a$564 _a$565 _a$566)))))) (def-var! "clojure.pprint" "make-indent-t" (letrec ((make-indent-t (lambda (logical-block relative-to offset start-pos end-pos) (let fnrec567 ((logical-block logical-block) (relative-to relative-to) (offset offset) (start-pos start-pos) (end-pos end-pos)) (jolt-invoke (var-deref "clojure.pprint" "->indent-t") (keyword #f "indent-t") logical-block relative-to offset start-pos end-pos))))) make-indent-t)) (def-var! "clojure.pprint" "indent-t?" (letrec ((indent-t? (lambda (x__1__auto) (let fnrec568 ((x__1__auto x__1__auto)) (jolt= (jolt-get x__1__auto (keyword #f "type-tag")) (keyword #f "indent-t")))))) indent-t?)))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pp-newline" (lambda () (let fnrec679 () "\n")) (let* ((_o$680 (keyword #f "private")) (_o$681 #t)) (jolt-hash-map _o$680 _o$681)))) + (def-var-with-meta! "clojure.pprint" "pp-newline" (lambda () (let fnrec569 () "\n")) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "emit-nl")) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol "clojure.pprint" "write-token") (lambda (this token) (let fnrec682 ((this this) (token token)) (jolt-get token (keyword #f "type-tag")))))) + (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol/meta #f "write-token" (jolt-hash-map (keyword #f "private") #t)) (lambda (this token) (let fnrec570 ((this this) (token token)) (jolt-get token (keyword #f "type-tag")))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "start-block-t") (lambda (this token) (let fnrec683 ((this this) (token token)) (begin (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "start"))) jolt-nil)) (let* ((lb (jolt-get token (keyword #f "logical-block")))) (begin (let* ((temp__27__auto (jolt-get lb (keyword #f "prefix")))) (if (jolt-truthy? temp__27__auto) (let* ((prefix temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix)) jolt-nil)) (let* ((col (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "start-col")) col) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "indent")) col)))))))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "start-block-t") (lambda (this token) (let fnrec571 ((this this) (token token)) (begin (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "start"))) jolt-nil)) (let* ((lb (jolt-get token (keyword #f "logical-block")))) (begin (let* ((temp__27__auto (jolt-get lb (keyword #f "prefix")))) (if (jolt-truthy? temp__27__auto) (let* ((prefix temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix)) jolt-nil)) (let* ((col (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "start-col")) col) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "indent")) col)))))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "end-block-t") (lambda (this token) (let fnrec684 ((this this) (token token)) (begin (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "end"))) jolt-nil)) (let* ((temp__27__auto (jolt-get (jolt-get token (keyword #f "logical-block")) (keyword #f "suffix")))) (if (jolt-truthy? temp__27__auto) (let* ((suffix temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) suffix)) jolt-nil))))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "end-block-t") (lambda (this token) (let fnrec572 ((this this) (token token)) (begin (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "end"))) jolt-nil)) (let* ((temp__27__auto (jolt-get (jolt-get token (keyword #f "logical-block")) (keyword #f "suffix")))) (if (jolt-truthy? temp__27__auto) (let* ((suffix temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) suffix)) jolt-nil))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "indent-t") (lambda (this token) (let fnrec685 ((this this) (token token)) (let* ((lb (jolt-get token (keyword #f "logical-block")))) (let* ((_a$690 (var-deref "clojure.core" "reset!")) (_a$691 (jolt-get lb (keyword #f "indent"))) (_a$692 (let* ((_a$688 (jolt-get token (keyword #f "offset"))) (_a$689 (let* ((G__38 jolt=) (G__39 (jolt-get token (keyword #f "relative-to")))) (if (jolt-truthy? (jolt-invoke G__38 (keyword #f "block") G__39)) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col"))) (if (jolt-truthy? (jolt-invoke G__38 (keyword #f "current") G__39)) (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (jolt-throw (let* ((_a$686 (jolt-invoke (var-deref "clojure.core" "str") "No matching clause: " G__39)) (_a$687 (jolt-hash-map))) (jolt-ex-info _a$686 _a$687)))))))) (jolt-n+ _a$688 _a$689)))) (jolt-invoke _a$690 _a$691 _a$692))))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "indent-t") (lambda (this token) (let fnrec573 ((this this) (token token)) (let* ((lb (jolt-get token (keyword #f "logical-block")))) (let* ((_a$578 (var-deref "clojure.core" "reset!")) (_a$579 (jolt-get lb (keyword #f "indent"))) (_a$580 (let* ((_a$576 (jolt-get token (keyword #f "offset"))) (_a$577 (let* ((G__30 jolt=) (G__31 (jolt-get token (keyword #f "relative-to")))) (if (jolt-truthy? (jolt-invoke G__30 (keyword #f "block") G__31)) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col"))) (if (jolt-truthy? (jolt-invoke G__30 (keyword #f "current") G__31)) (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (jolt-throw (let* ((_a$574 (jolt-invoke (var-deref "clojure.core" "str") "No matching clause: " G__31)) (_a$575 (jolt-hash-map))) (jolt-ex-info _a$574 _a$575)))))))) (+ _a$576 _a$577)))) (jolt-invoke _a$578 _a$579 _a$580))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "buffer-blob") (lambda (this token) (let fnrec693 ((this this) (token token)) (let* ((_a$694 (var-deref "clojure.pprint" "-write")) (_a$695 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$696 (jolt-get token (keyword #f "data")))) (jolt-invoke _a$694 _a$695 _a$696)))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "buffer-blob") (lambda (this token) (let fnrec581 ((this this) (token token)) (let* ((_a$582 (var-deref "clojure.pprint" "-write")) (_a$583 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$584 (jolt-get token (keyword #f "data")))) (jolt-invoke _a$582 _a$583 _a$584)))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "nl-t") (lambda (this token) (let fnrec697 ((this this) (token token)) (begin (if (jolt-truthy? (let* ((or__26__auto (jolt= (jolt-get token (keyword #f "type")) (keyword #f "mandatory")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-not (jolt= (jolt-get token (keyword #f "type")) (keyword #f "fill"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get (jolt-get token (keyword #f "logical-block")) (keyword #f "done-nl"))) and__25__auto))))) (jolt-invoke (var-deref "clojure.pprint" "emit-nl") this token) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__16__auto) (let* ((tws temp__16__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws)) jolt-nil))) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil)))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "write-token") (keyword #f "nl-t") (lambda (this token) (let fnrec585 ((this this) (token token)) (begin (if (jolt-truthy? (let* ((or__26__auto (jolt= (jolt-get token (keyword #f "type")) (keyword #f "mandatory")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt-not (jolt= (jolt-get token (keyword #f "type")) (keyword #f "fill"))))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get (jolt-get token (keyword #f "logical-block")) (keyword #f "done-nl"))) and__25__auto))))) (jolt-invoke (var-deref "clojure.pprint" "emit-nl") this token) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__16__auto) (let* ((tws temp__16__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws)) jolt-nil))) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil)))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-tokens" (letrec ((write-tokens (lambda (this tokens force-trailing-whitespace) (let fnrec698 ((this this) (tokens tokens) (force-trailing-whitespace force-trailing-whitespace)) (begin (jolt-count (jolt-map (lambda (token) (let fnrec699 ((token token)) (begin (if (jolt-not (jolt= (jolt-get token (keyword #f "type-tag")) (keyword #f "nl-t"))) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__16__auto) (let* ((tws temp__16__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws)) jolt-nil)) jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "write-token") this token) (let* ((_a$700 (var-deref "clojure.core" "swap!")) (_a$701 (record-method-dispatch this "-fields" (jolt-vector))) (_a$702 jolt-assoc) (_a$703 (keyword #f "trailing-white-space")) (_a$704 (jolt-get token (keyword #f "trailing-white-space")))) (jolt-invoke _a$700 _a$701 _a$702 _a$703 _a$704)) (let* ((tws (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? (let* ((and__25__auto force-trailing-whitespace)) (if (jolt-truthy? and__25__auto) tws and__25__auto))) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil)) jolt-nil)) jolt-nil))) tokens)) jolt-nil))))) write-tokens) (let* ((_o$705 (keyword #f "private")) (_o$706 #t)) (jolt-hash-map _o$705 _o$706)))) + (def-var! "clojure.pprint" "write-tokens" (letrec ((write-tokens (lambda (this tokens force-trailing-whitespace) (let fnrec586 ((this this) (tokens tokens) (force-trailing-whitespace force-trailing-whitespace)) (begin (jolt-count (jolt-map (lambda (token) (let fnrec587 ((token token)) (begin (if (jolt-not (jolt= (jolt-get token (keyword #f "type-tag")) (keyword #f "nl-t"))) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__16__auto) (let* ((tws temp__16__auto)) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws)) jolt-nil)) jolt-nil) (jolt-invoke (var-deref "clojure.core" "write-token") this token) (let* ((_a$588 (var-deref "clojure.core" "swap!")) (_a$589 (record-method-dispatch this "-fields" (jolt-vector))) (_a$590 jolt-assoc) (_a$591 (keyword #f "trailing-white-space")) (_a$592 (jolt-get token (keyword #f "trailing-white-space")))) (jolt-invoke _a$588 _a$589 _a$590 _a$591 _a$592)) (let* ((tws (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? (let* ((and__25__auto force-trailing-whitespace)) (if (jolt-truthy? and__25__auto) tws and__25__auto))) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil)) jolt-nil)) jolt-nil))) tokens)) jolt-nil))))) write-tokens))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "tokens-fit?" (letrec ((tokens-fit? (lambda (this tokens) (let fnrec707 ((this this) (tokens tokens)) (let* ((maxcol (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (let* ((or__26__auto (jolt-nil? maxcol))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n< (let* ((_a$708 (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")))) (_a$709 (jolt-invoke (var-deref "clojure.pprint" "buffer-length") tokens))) (jolt-n+ _a$708 _a$709)) maxcol)))))))) tokens-fit?) (let* ((_o$710 (keyword #f "private")) (_o$711 #t)) (jolt-hash-map _o$710 _o$711)))) + (def-var! "clojure.pprint" "tokens-fit?" (letrec ((tokens-fit? (lambda (this tokens) (let fnrec593 ((this this) (tokens tokens)) (let* ((maxcol (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") maxcol))) (if (jolt-truthy? or__26__auto) or__26__auto (< (let* ((_a$594 (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")))) (_a$595 (jolt-invoke (var-deref "clojure.pprint" "buffer-length") tokens))) (+ _a$594 _a$595)) maxcol)))))))) tokens-fit?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "linear-nl?" (letrec ((linear-nl? (lambda (this lb section) (let fnrec712 ((this this) (lb lb) (section section)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "done-nl"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this section)))))))) linear-nl?) (let* ((_o$713 (keyword #f "private")) (_o$714 #t)) (jolt-hash-map _o$713 _o$714)))) + (def-var! "clojure.pprint" "linear-nl?" (letrec ((linear-nl? (lambda (this lb section) (let fnrec596 ((this this) (lb lb) (section section)) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "done-nl"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this section)))))))) linear-nl?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "miser-nl?" (letrec ((miser-nl? (lambda (this lb section) (let fnrec715 ((this this) (lb lb) (section section)) (let* ((miser-width (jolt-invoke (var-deref "clojure.pprint" "get-miser-width") this)) (maxcol (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (let* ((and__25__auto miser-width)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto maxcol)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$716 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col")))) (_a$717 (jolt-n- maxcol miser-width))) (jolt-n>= _a$716 _a$717)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.pprint" "linear-nl?") this lb section) and__25__auto)) and__25__auto)) and__25__auto))))))) miser-nl?) (let* ((_o$718 (keyword #f "private")) (_o$719 #t)) (jolt-hash-map _o$718 _o$719)))) + (def-var! "clojure.pprint" "miser-nl?" (letrec ((miser-nl? (lambda (this lb section) (let fnrec597 ((this this) (lb lb) (section section)) (let* ((miser-width (jolt-invoke (var-deref "clojure.pprint" "get-miser-width") this)) (maxcol (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (let* ((and__25__auto miser-width)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto maxcol)) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (let* ((_a$598 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col")))) (_a$599 (- maxcol miser-width))) (>= _a$598 _a$599)))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.pprint" "linear-nl?") this lb section) and__25__auto)) and__25__auto)) and__25__auto))))))) miser-nl?))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol "clojure.pprint" "emit-nl?") (lambda (t _r$__119 _r$__120 _) (let fnrec720 ((t t) (_r$__119 _r$__119) (_r$__120 _r$__120) (_ _)) (jolt-get t (keyword #f "type")))))) + (jolt-invoke (var-deref "clojure.core" "defmulti-setup") (jolt-symbol/meta #f "emit-nl?" (jolt-hash-map (keyword #f "private") #t)) (lambda (t _r$__119 _r$__120 _) (let fnrec600 ((t t) (_r$__119 _r$__119) (_r$__120 _r$__120) (_ _)) (jolt-get t (keyword #f "type")))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "linear") (lambda (newl this section _) (let fnrec721 ((newl newl) (this this) (section section) (_ _)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (jolt-invoke (var-deref "clojure.pprint" "linear-nl?") this lb section)))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "linear") (lambda (newl this section _) (let fnrec601 ((newl newl) (this this) (section section) (_ _)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (jolt-invoke (var-deref "clojure.pprint" "linear-nl?") this lb section)))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "miser") (lambda (newl this section _) (let fnrec722 ((newl newl) (this this) (section section) (_ _)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (jolt-invoke (var-deref "clojure.pprint" "miser-nl?") this lb section)))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "miser") (lambda (newl this section _) (let fnrec602 ((newl newl) (this this) (section section) (_ _)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (jolt-invoke (var-deref "clojure.pprint" "miser-nl?") this lb section)))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "fill") (lambda (newl this section subsection) (let fnrec723 ((newl newl) (this this) (section section) (subsection subsection)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "intra-block-nl"))))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this subsection)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "miser-nl?") this lb section)))))))) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "fill") (lambda (newl this section subsection) (let fnrec603 ((newl newl) (this this) (section section) (subsection subsection)) (let* ((lb (jolt-get newl (keyword #f "logical-block")))) (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "intra-block-nl"))))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this subsection)))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "miser-nl?") this lb section)))))))))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "mandatory") (lambda (_r$__125 _r$__126 _r$__127 _) (let fnrec724 ((_r$__125 _r$__125) (_r$__126 _r$__126) (_r$__127 _r$__127) (_ _)) #t)) "clojure.pprint")) + (jolt-invoke (var-deref "clojure.core" "defmethod-setup") (jolt-symbol #f "emit-nl?") (keyword #f "mandatory") (lambda (_r$__125 _r$__126 _r$__127 _) (let fnrec604 ((_r$__125 _r$__125) (_r$__126 _r$__126) (_r$__127 _r$__127) (_ _)) #t)))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-section" (letrec ((get-section (lambda (buffer) (let fnrec725 ((buffer buffer)) (let* ((nl (jolt-first buffer)) (lb (jolt-get nl (keyword #f "logical-block"))) (section (jolt-seq (let* ((_a$727 (var-deref "clojure.core" "take-while")) (_a$728 (lambda (p__5_) (let fnrec726 ((p__5_ p__5_)) (jolt-not (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__5_))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.pprint" "ancestor?") (jolt-get p__5_ (keyword #f "logical-block")) lb) and__25__auto)))))) (_a$729 (jolt-next buffer))) (jolt-invoke _a$727 _a$728 _a$729))))) (let* ((_o$730 section) (_o$731 (jolt-seq (jolt-drop (jolt-inc (jolt-count section)) buffer)))) (jolt-vector _o$730 _o$731))))))) get-section) (let* ((_o$732 (keyword #f "private")) (_o$733 #t)) (jolt-hash-map _o$732 _o$733)))) + (def-var! "clojure.pprint" "get-section" (letrec ((get-section (lambda (buffer) (let fnrec605 ((buffer buffer)) (let* ((nl (jolt-first buffer)) (lb (jolt-get nl (keyword #f "logical-block"))) (section (jolt-seq (let* ((_a$607 (var-deref "clojure.core" "take-while")) (_a$608 (lambda (p__5_) (let fnrec606 ((p__5_ p__5_)) (jolt-not (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__5_))) (if (jolt-truthy? and__25__auto) (jolt-invoke (var-deref "clojure.pprint" "ancestor?") (jolt-get p__5_ (keyword #f "logical-block")) lb) and__25__auto)))))) (_a$609 (jolt-next buffer))) (jolt-invoke _a$607 _a$608 _a$609))))) (let* ((_o$610 section) (_o$611 (jolt-seq (jolt-drop (jolt-inc (jolt-count section)) buffer)))) (jolt-vector _o$610 _o$611))))))) get-section))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-sub-section" (letrec ((get-sub-section (lambda (buffer) (let fnrec734 ((buffer buffer)) (let* ((nl (jolt-first buffer)) (lb (jolt-get nl (keyword #f "logical-block"))) (section (jolt-seq (let* ((_a$736 (var-deref "clojure.core" "take-while")) (_a$737 (lambda (p__6_) (let fnrec735 ((p__6_ p__6_)) (let* ((nl-lb (jolt-get p__6_ (keyword #f "logical-block")))) (jolt-not (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__6_))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= nl-lb lb))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "ancestor?") nl-lb lb))) and__25__auto))))))) (_a$738 (jolt-next buffer))) (jolt-invoke _a$736 _a$737 _a$738))))) section))))) get-sub-section) (let* ((_o$739 (keyword #f "private")) (_o$740 #t)) (jolt-hash-map _o$739 _o$740)))) + (def-var! "clojure.pprint" "get-sub-section" (letrec ((get-sub-section (lambda (buffer) (let fnrec612 ((buffer buffer)) (let* ((nl (jolt-first buffer)) (lb (jolt-get nl (keyword #f "logical-block"))) (section (jolt-seq (let* ((_a$614 (var-deref "clojure.core" "take-while")) (_a$615 (lambda (p__6_) (let fnrec613 ((p__6_ p__6_)) (let* ((nl-lb (jolt-get p__6_ (keyword #f "logical-block")))) (jolt-not (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__6_))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt= nl-lb lb))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "ancestor?") nl-lb lb))) and__25__auto))))))) (_a$616 (jolt-next buffer))) (jolt-invoke _a$614 _a$615 _a$616))))) section))))) get-sub-section))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "update-nl-state" (letrec ((update-nl-state (lambda (lb) (let fnrec741 ((lb lb)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "intra-block-nl")) #t) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "done-nl")) #t) (let* ((lb (jolt-get lb (keyword #f "parent")))) (let loop742 ((lb lb)) (if (jolt-truthy? lb) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "done-nl")) #t) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "intra-block-nl")) #t) (loop742 (jolt-get lb (keyword #f "parent")))) jolt-nil)))))))) update-nl-state) (let* ((_o$743 (keyword #f "private")) (_o$744 #t)) (jolt-hash-map _o$743 _o$744)))) + (def-var! "clojure.pprint" "update-nl-state" (letrec ((update-nl-state (lambda (lb) (let fnrec617 ((lb lb)) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "intra-block-nl")) #t) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "done-nl")) #t) (let* ((lb (jolt-get lb (keyword #f "parent")))) (let loop618 ((lb lb)) (if (jolt-truthy? lb) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "done-nl")) #t) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "intra-block-nl")) #t) (loop618 (jolt-get lb (keyword #f "parent")))) jolt-nil)))))))) update-nl-state))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "emit-nl" (letrec ((emit-nl (lambda (this nl) (let fnrec745 ((this this) (nl nl)) (begin (let* ((_a$746 (var-deref "clojure.pprint" "-write")) (_a$747 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$748 (jolt-invoke (var-deref "clojure.pprint" "pp-newline")))) (jolt-invoke _a$746 _a$747 _a$748)) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil) (let* ((lb (jolt-get nl (keyword #f "logical-block"))) (prefix (jolt-get lb (keyword #f "per-line-prefix")))) (begin (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) (let* ((istr (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") (let* ((_a$749 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "indent")))) (_a$750 (jolt-count prefix))) (jolt-n- _a$749 _a$750)) (integer->char 32))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) istr)) (jolt-invoke (var-deref "clojure.pprint" "update-nl-state") lb)))))))) emit-nl) (let* ((_o$751 (keyword #f "private")) (_o$752 #t)) (jolt-hash-map _o$751 _o$752)))) + (def-var! "clojure.pprint" "emit-nl" (letrec ((emit-nl (lambda (this nl) (let fnrec619 ((this this) (nl nl)) (begin (let* ((_a$620 (var-deref "clojure.pprint" "-write")) (_a$621 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$622 (jolt-invoke (var-deref "clojure.pprint" "pp-newline")))) (jolt-invoke _a$620 _a$621 _a$622)) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil) (let* ((lb (jolt-get nl (keyword #f "logical-block"))) (prefix (jolt-get lb (keyword #f "per-line-prefix")))) (begin (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) (let* ((istr (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") (let* ((_a$623 (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "indent")))) (_a$624 (jolt-count prefix))) (- _a$623 _a$624)) (integer->char 32))))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) istr)) (jolt-invoke (var-deref "clojure.pprint" "update-nl-state") lb)))))))) emit-nl))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "split-at-newline" (letrec ((split-at-newline (lambda (tokens) (let fnrec753 ((tokens tokens)) (let* ((pre (jolt-seq (jolt-invoke (var-deref "clojure.core" "take-while") (lambda (p__7_) (let fnrec754 ((p__7_ p__7_)) (jolt-not (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__7_)))) tokens)))) (let* ((_o$755 pre) (_o$756 (jolt-seq (jolt-drop (jolt-count pre) tokens)))) (jolt-vector _o$755 _o$756))))))) split-at-newline) (let* ((_o$757 (keyword #f "private")) (_o$758 #t)) (jolt-hash-map _o$757 _o$758)))) + (def-var! "clojure.pprint" "split-at-newline" (letrec ((split-at-newline (lambda (tokens) (let fnrec625 ((tokens tokens)) (let* ((pre (jolt-seq (jolt-invoke (var-deref "clojure.core" "take-while") (lambda (p__7_) (let fnrec626 ((p__7_ p__7_)) (jolt-not (jolt-invoke (var-deref "clojure.pprint" "nl-t?") p__7_)))) tokens)))) (let* ((_o$627 pre) (_o$628 (jolt-seq (jolt-drop (jolt-count pre) tokens)))) (jolt-vector _o$627 _o$628))))))) split-at-newline))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-token-string" (letrec ((write-token-string (lambda (this tokens) (let fnrec759 ((this this) (tokens tokens)) (let* ((G__40 (jolt-invoke (var-deref "clojure.pprint" "split-at-newline") tokens)) (a (jolt-nth G__40 0 jolt-nil)) (b (jolt-nth G__40 1 jolt-nil))) (begin (if (jolt-truthy? a) (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this a #f) jolt-nil) (if (jolt-truthy? b) (let* ((G__41 (jolt-invoke (var-deref "clojure.pprint" "get-section") b)) (section (jolt-nth G__41 0 jolt-nil)) (remainder (jolt-nth G__41 1 jolt-nil)) (newl (jolt-first b))) (let* ((do-nl (jolt-invoke (var-deref "clojure.pprint" "emit-nl?") newl this section (jolt-invoke (var-deref "clojure.pprint" "get-sub-section") b))) (result (if (jolt-truthy? do-nl) (begin (jolt-invoke (var-deref "clojure.pprint" "emit-nl") this newl) (jolt-next b)) b)) (long-section (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this result))) (result (if (jolt-truthy? long-section) (let* ((rem2 (write-token-string this section))) (if (jolt= rem2 section) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this section #f) remainder) (let* ((_a$760 (jolt-vector)) (_a$761 (jolt-concat rem2 remainder))) (jolt-into _a$760 _a$761)))) result))) result)) jolt-nil))))))) write-token-string) (let* ((_o$762 (keyword #f "private")) (_o$763 #t)) (jolt-hash-map _o$762 _o$763)))) + (def-var! "clojure.pprint" "write-token-string" (letrec ((write-token-string (lambda (this tokens) (let fnrec629 ((this this) (tokens tokens)) (let* ((G__32 (jolt-invoke (var-deref "clojure.pprint" "split-at-newline") tokens)) (a (jolt-nth G__32 0 jolt-nil)) (b (jolt-nth G__32 1 jolt-nil))) (begin (if (jolt-truthy? a) (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this a #f) jolt-nil) (if (jolt-truthy? b) (let* ((G__33 (jolt-invoke (var-deref "clojure.pprint" "get-section") b)) (section (jolt-nth G__33 0 jolt-nil)) (remainder (jolt-nth G__33 1 jolt-nil)) (newl (jolt-first b))) (let* ((do-nl (jolt-invoke (var-deref "clojure.core" "emit-nl?") newl this section (jolt-invoke (var-deref "clojure.pprint" "get-sub-section") b))) (result (if (jolt-truthy? do-nl) (begin (jolt-invoke (var-deref "clojure.pprint" "emit-nl") this newl) (jolt-next b)) b)) (long-section (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this result))) (result (if (jolt-truthy? long-section) (let* ((rem2 (jolt-invoke write-token-string this section))) (if (jolt= rem2 section) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this section #f) remainder) (let* ((_a$630 (jolt-vector)) (_a$631 (jolt-concat rem2 remainder))) (jolt-into _a$630 _a$631)))) result))) result)) jolt-nil))))))) write-token-string))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-line" (letrec ((write-line (lambda (this) (let fnrec764 ((this this)) (let* ((buffer (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (let loop765 ((buffer buffer)) (begin (let* ((_a$766 (var-deref "clojure.core" "swap!")) (_a$767 (record-method-dispatch this "-fields" (jolt-vector))) (_a$768 jolt-assoc) (_a$769 (keyword #f "buffer")) (_a$770 (jolt-into (jolt-vector) buffer))) (jolt-invoke _a$766 _a$767 _a$768 _a$769 _a$770)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this buffer)) (let* ((new-buffer (jolt-invoke (var-deref "clojure.pprint" "write-token-string") this buffer))) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "identical?") buffer new-buffer)) (loop765 new-buffer) jolt-nil)) jolt-nil)))))))) write-line) (let* ((_o$771 (keyword #f "private")) (_o$772 #t)) (jolt-hash-map _o$771 _o$772)))) + (def-var! "clojure.pprint" "write-line" (letrec ((write-line (lambda (this) (let fnrec632 ((this this)) (let* ((buffer (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (let loop633 ((buffer buffer)) (begin (let* ((_a$634 (var-deref "clojure.core" "swap!")) (_a$635 (record-method-dispatch this "-fields" (jolt-vector))) (_a$636 jolt-assoc) (_a$637 (keyword #f "buffer")) (_a$638 (jolt-into (jolt-vector) buffer))) (jolt-invoke _a$634 _a$635 _a$636 _a$637 _a$638)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this buffer)) (let* ((new-buffer (jolt-invoke (var-deref "clojure.pprint" "write-token-string") this buffer))) (if (jolt-not (jolt-invoke (var-deref "clojure.core" "identical?") buffer new-buffer)) (loop633 new-buffer) jolt-nil)) jolt-nil)))))))) write-line))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "add-to-buffer" (letrec ((add-to-buffer (lambda (this token) (let fnrec773 ((this this) (token token)) (begin (let* ((_a$774 (var-deref "clojure.core" "swap!")) (_a$775 (record-method-dispatch this "-fields" (jolt-vector))) (_a$776 jolt-assoc) (_a$777 (keyword #f "buffer")) (_a$778 (jolt-conj (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")) token))) (jolt-invoke _a$774 _a$775 _a$776 _a$777 _a$778)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (jolt-invoke (var-deref "clojure.pprint" "write-line") this) jolt-nil)))))) add-to-buffer) (let* ((_o$779 (keyword #f "private")) (_o$780 #t)) (jolt-hash-map _o$779 _o$780)))) + (def-var! "clojure.pprint" "add-to-buffer" (letrec ((add-to-buffer (lambda (this token) (let fnrec639 ((this this) (token token)) (begin (let* ((_a$640 (var-deref "clojure.core" "swap!")) (_a$641 (record-method-dispatch this "-fields" (jolt-vector))) (_a$642 jolt-assoc) (_a$643 (keyword #f "buffer")) (_a$644 (jolt-conj (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")) token))) (jolt-invoke _a$640 _a$641 _a$642 _a$643 _a$644)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "tokens-fit?") this (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (jolt-invoke (var-deref "clojure.pprint" "write-line") this) jolt-nil)))))) add-to-buffer))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-buffered-output" (letrec ((write-buffered-output (lambda (this) (let fnrec781 ((this this)) (begin (jolt-invoke (var-deref "clojure.pprint" "write-line") this) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (if (jolt-truthy? temp__16__auto) (let* ((buf temp__16__auto)) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this buf #t) (let* ((_a$782 (var-deref "clojure.core" "swap!")) (_a$783 (record-method-dispatch this "-fields" (jolt-vector))) (_a$784 jolt-assoc) (_a$785 (keyword #f "buffer")) (_a$786 (jolt-vector))) (jolt-invoke _a$782 _a$783 _a$784 _a$785 _a$786)))) jolt-nil))))))) write-buffered-output) (let* ((_o$787 (keyword #f "private")) (_o$788 #t)) (jolt-hash-map _o$787 _o$788)))) + (def-var! "clojure.pprint" "write-buffered-output" (letrec ((write-buffered-output (lambda (this) (let fnrec645 ((this this)) (begin (jolt-invoke (var-deref "clojure.pprint" "write-line") this) (let* ((temp__16__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")))) (if (jolt-truthy? temp__16__auto) (let* ((buf temp__16__auto)) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this buf #t) (let* ((_a$646 (var-deref "clojure.core" "swap!")) (_a$647 (record-method-dispatch this "-fields" (jolt-vector))) (_a$648 jolt-assoc) (_a$649 (keyword #f "buffer")) (_a$650 (jolt-vector))) (jolt-invoke _a$646 _a$647 _a$648 _a$649 _a$650)))) jolt-nil))))))) write-buffered-output))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-white-space" (letrec ((write-white-space (lambda (this) (let fnrec789 ((this this)) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__27__auto) (let* ((tws temp__27__auto)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil))) jolt-nil)))))) write-white-space) (let* ((_o$790 (keyword #f "private")) (_o$791 #t)) (jolt-hash-map _o$790 _o$791)))) + (def-var! "clojure.pprint" "write-white-space" (letrec ((write-white-space (lambda (this) (let fnrec651 ((this this)) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "trailing-white-space")))) (if (jolt-truthy? temp__27__auto) (let* ((tws temp__27__auto)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) tws) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") jolt-nil))) jolt-nil)))))) write-white-space))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write-initial-lines" (letrec ((write-initial-lines (lambda (this s) (let fnrec792 ((this this) (s s)) (let* ((lines (jolt-invoke (var-deref "clojure.string" "split") s (jolt-regex "\\n") -1))) (if (jolt= (jolt-count lines) 1) s (let* ((prefix (jolt-get (jolt-first (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (keyword #f "per-line-prefix"))) (l (jolt-first lines))) (begin (if (jolt= (keyword #f "buffering") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode"))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-n+ oldpos (jolt-count l)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") l jolt-nil oldpos newpos)) (jolt-invoke (var-deref "clojure.pprint" "write-buffered-output") this))) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) l))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) "\n") (begin (jolt-count (let* ((_a$797 (lambda (l) (let fnrec793 ((l l)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) l) (let* ((_a$794 (var-deref "clojure.pprint" "-write")) (_a$795 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$796 (jolt-invoke (var-deref "clojure.pprint" "pp-newline")))) (jolt-invoke _a$794 _a$795 _a$796)) (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) jolt-nil)))) (_a$798 (jolt-next (jolt-invoke (var-deref "clojure.core" "butlast") lines)))) (jolt-map _a$797 _a$798))) jolt-nil) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "buffering") (keyword #f "writing")) (jolt-last lines))))))))) write-initial-lines) (let* ((_o$799 (keyword #f "private")) (_o$800 #t)) (jolt-hash-map _o$799 _o$800)))) + (def-var! "clojure.pprint" "write-initial-lines" (letrec ((write-initial-lines (lambda (this s) (let fnrec652 ((this this) (s s)) (let* ((lines (jolt-invoke (var-deref "clojure.string" "split") s (jolt-regex "\\n") -1))) (if (jolt= (jolt-count lines) 1) s (let* ((prefix (jolt-get (jolt-first (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (keyword #f "per-line-prefix"))) (l (jolt-first lines))) (begin (if (jolt= (keyword #f "buffering") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode"))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (+ oldpos (jolt-count l)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") l jolt-nil oldpos newpos)) (jolt-invoke (var-deref "clojure.pprint" "write-buffered-output") this))) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) l))) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) "\n") (begin (jolt-count (let* ((_a$657 (lambda (l) (let fnrec653 ((l l)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) l) (let* ((_a$654 (var-deref "clojure.pprint" "-write")) (_a$655 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (_a$656 (jolt-invoke (var-deref "clojure.pprint" "pp-newline")))) (jolt-invoke _a$654 _a$655 _a$656)) (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) jolt-nil)))) (_a$658 (jolt-next (jolt-invoke (var-deref "clojure.core" "butlast") lines)))) (jolt-map _a$657 _a$658))) jolt-nil) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "buffering") (keyword #f "writing")) (jolt-last lines))))))))) write-initial-lines))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "p-write-char" (letrec ((p-write-char (lambda (this c) (let fnrec801 ((this this) (c c)) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) c)) (if (jolt= c (integer->char 10)) (jolt-invoke (var-deref "clojure.pprint" "write-initial-lines") this "\n") (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-inc oldpos))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") (jolt-invoke (var-deref "clojure.core" "str") c) jolt-nil oldpos newpos)))))))))) p-write-char) (let* ((_o$802 (keyword #f "private")) (_o$803 #t)) (jolt-hash-map _o$802 _o$803)))) + (def-var! "clojure.pprint" "p-write-char" (letrec ((p-write-char (lambda (this c) (let fnrec659 ((this this) (c c)) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) c)) (if (jolt= c (integer->char 10)) (jolt-invoke (var-deref "clojure.pprint" "write-initial-lines") this "\n") (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-inc oldpos))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") (jolt-invoke (var-deref "clojure.core" "str") c) jolt-nil oldpos newpos)))))))))) p-write-char))) (guard (e (#t #f)) - (begin (begin (def-var! "clojure.pprint" "PrettyWriter" (let* ((_a$804 (var-deref "clojure.core" "make-deftype-ctor")) (_a$805 (jolt-symbol #f "PrettyWriter")) (_a$806 (jolt-vector (keyword #f "fields"))) (_a$807 (jolt-vector jolt-nil)) (_a$808 (jolt-vector #f))) (jolt-invoke _a$804 _a$805 _a$806 _a$807 _a$808))) (def-var! "clojure.pprint" "->PrettyWriter" (var-deref "clojure.pprint" "PrettyWriter")) (var-deref "clojure.pprint" "PrettyWriter")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-symbol #f "PrettyWriter")) (def-var! "clojure.pprint" "map->PrettyWriter" (lambda (G__42) (let fnrec809 ((G__42 G__42)) (let* ((_a$810 (var-deref "clojure.core" "reduce-kv")) (_a$811 jolt-assoc) (_a$812 (jolt-invoke (var-deref "clojure.pprint" "->PrettyWriter") (jolt-get G__42 (keyword #f "fields")))) (_a$813 (jolt-dissoc G__42 (keyword #f "fields")))) (jolt-invoke _a$810 _a$811 _a$812 _a$813))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "PrettyWriter" "IPrettyWriter") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyWriter" "-write" (lambda (this x) (let fnrec814 ((this this) (x x)) (let* ((fields (jolt-get this (keyword #f "fields")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") x)) (let* ((s0 (jolt-invoke (var-deref "clojure.pprint" "write-initial-lines") this x)) (s (jolt-invoke (var-deref "clojure.string" "replace-first") s0 (jolt-regex "\\s+$") "")) (white-space (jolt-invoke (var-deref "clojure.core" "subs") s0 (jolt-count s))) (mode (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")))) (if (jolt= mode (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) s) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") white-space)) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-n+ oldpos (jolt-count s0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") s white-space oldpos newpos)))))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "char?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") x)))) (jolt-invoke (var-deref "clojure.pprint" "p-write-char") this x) jolt-nil)))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyWriter" "-pflush" (lambda (this) (let fnrec815 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (begin (jolt-invoke (var-deref "clojure.pprint" "-ppflush") this) (jolt-invoke (var-deref "clojure.pprint" "-pflush") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")))))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "PrettyWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyFlush" "-ppflush" (lambda (this) (let fnrec816 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "buffering")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")) #t) (let* ((_a$817 (var-deref "clojure.core" "swap!")) (_a$818 (record-method-dispatch this "-fields" (jolt-vector))) (_a$819 jolt-assoc) (_a$820 (keyword #f "buffer")) (_a$821 (jolt-vector))) (jolt-invoke _a$817 _a$818 _a$819 _a$820 _a$821))) (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this)))))))) + (begin (begin (def-var! "clojure.pprint" "PrettyWriter" (let* ((_a$660 (var-deref "clojure.core" "make-deftype-ctor")) (_a$661 (jolt-symbol #f "PrettyWriter")) (_a$662 (jolt-vector (keyword #f "fields"))) (_a$663 (jolt-vector jolt-nil)) (_a$664 (jolt-vector #f))) (jolt-invoke _a$660 _a$661 _a$662 _a$663 _a$664))) (def-var! "clojure.pprint" "->PrettyWriter" (var-deref "clojure.pprint" "PrettyWriter")) (var-deref "clojure.pprint" "PrettyWriter")) (def-var! "clojure.pprint" "map->PrettyWriter" (lambda (G__34) (let fnrec665 ((G__34 G__34)) (jolt-invoke (var-deref "clojure.pprint" "->PrettyWriter") (jolt-get G__34 (keyword #f "fields")))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "PrettyWriter" "IPrettyWriter") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyWriter" "-write" (lambda (this x) (let fnrec666 ((this this) (x x)) (let* ((fields (jolt-get this (keyword #f "fields")))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") x)) (let* ((s0 (jolt-invoke (var-deref "clojure.pprint" "write-initial-lines") this x)) (s (jolt-invoke (var-deref "clojure.string" "replace-first") s0 (jolt-regex "\\s+$") "")) (white-space (jolt-invoke (var-deref "clojure.core" "subs") s0 (jolt-count s))) (mode (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")))) (if (jolt= mode (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) s) (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "trailing-white-space") white-space)) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (+ oldpos (jolt-count s0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-buffer-blob") s white-space oldpos newpos)))))) (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "char?") x))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "number?") x)))) (jolt-invoke (var-deref "clojure.pprint" "p-write-char") this x) jolt-nil)))))) (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyWriter" "-pflush" (lambda (this) (let fnrec667 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (begin (jolt-invoke (var-deref "clojure.pprint" "-ppflush") this) (jolt-invoke (var-deref "clojure.pprint" "-pflush") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")))))))) (jolt-invoke (var-deref "clojure.core" "register-inline-protocol!") "PrettyWriter" "IPrettyFlush") (jolt-invoke (var-deref "clojure.core" "register-inline-method") "PrettyWriter" "IPrettyFlush" "-ppflush" (lambda (this) (let fnrec668 ((this this)) (let* ((fields (jolt-get this (keyword #f "fields")))) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "buffering")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-tokens") this (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "buffer")) #t) (let* ((_a$669 (var-deref "clojure.core" "swap!")) (_a$670 (record-method-dispatch this "-fields" (jolt-vector))) (_a$671 jolt-assoc) (_a$672 (keyword #f "buffer")) (_a$673 (jolt-vector))) (jolt-invoke _a$669 _a$670 _a$671 _a$672 _a$673))) (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this)))))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pretty-writer" (letrec ((pretty-writer (lambda (writer max-columns miser-width) (let fnrec822 ((writer writer) (max-columns max-columns) (miser-width miser-width)) (let* ((lb (let* ((_a$823 (var-deref "clojure.pprint" "->logical-block")) (_a$824 jolt-nil) (_a$825 jolt-nil) (_a$826 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$827 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$828 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$829 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$830 jolt-nil) (_a$831 jolt-nil) (_a$832 jolt-nil) (_a$833 jolt-nil)) (jolt-invoke _a$823 _a$824 _a$825 _a$826 _a$827 _a$828 _a$829 _a$830 _a$831 _a$832 _a$833)))) (jolt-invoke (var-deref "clojure.pprint" "->PrettyWriter") (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$834 (keyword #f "pretty-writer")) (_o$835 #t) (_o$836 (keyword #f "base")) (_o$837 (jolt-invoke (var-deref "clojure.pprint" "column-writer") writer max-columns)) (_o$838 (keyword #f "logical-blocks")) (_o$839 lb) (_o$840 (keyword #f "sections")) (_o$841 jolt-nil) (_o$842 (keyword #f "mode")) (_o$843 (keyword #f "writing")) (_o$844 (keyword #f "buffer")) (_o$845 (jolt-vector)) (_o$846 (keyword #f "buffer-block")) (_o$847 lb) (_o$848 (keyword #f "buffer-level")) (_o$849 1) (_o$850 (keyword #f "miser-width")) (_o$851 miser-width) (_o$852 (keyword #f "trailing-white-space")) (_o$853 jolt-nil) (_o$854 (keyword #f "pos")) (_o$855 0)) (jolt-hash-map _o$834 _o$835 _o$836 _o$837 _o$838 _o$839 _o$840 _o$841 _o$842 _o$843 _o$844 _o$845 _o$846 _o$847 _o$848 _o$849 _o$850 _o$851 _o$852 _o$853 _o$854 _o$855))))))))) pretty-writer) (let* ((_o$856 (keyword #f "private")) (_o$857 #t)) (jolt-hash-map _o$856 _o$857)))) + (def-var! "clojure.pprint" "pretty-writer" (letrec ((pretty-writer (lambda (writer max-columns miser-width) (let fnrec674 ((writer writer) (max-columns max-columns) (miser-width miser-width)) (let* ((lb (let* ((_a$675 (var-deref "clojure.pprint" "->logical-block")) (_a$676 jolt-nil) (_a$677 jolt-nil) (_a$678 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$679 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$680 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$681 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$682 jolt-nil) (_a$683 jolt-nil) (_a$684 jolt-nil) (_a$685 jolt-nil)) (jolt-invoke _a$675 _a$676 _a$677 _a$678 _a$679 _a$680 _a$681 _a$682 _a$683 _a$684 _a$685)))) (jolt-invoke (var-deref "clojure.pprint" "->PrettyWriter") (jolt-invoke (var-deref "clojure.core" "atom") (let* ((_o$686 (keyword #f "pretty-writer")) (_o$687 #t) (_o$688 (keyword #f "base")) (_o$689 (jolt-invoke (var-deref "clojure.pprint" "column-writer") writer max-columns)) (_o$690 (keyword #f "logical-blocks")) (_o$691 lb) (_o$692 (keyword #f "sections")) (_o$693 jolt-nil) (_o$694 (keyword #f "mode")) (_o$695 (keyword #f "writing")) (_o$696 (keyword #f "buffer")) (_o$697 (jolt-vector)) (_o$698 (keyword #f "buffer-block")) (_o$699 lb) (_o$700 (keyword #f "buffer-level")) (_o$701 1) (_o$702 (keyword #f "miser-width")) (_o$703 miser-width) (_o$704 (keyword #f "trailing-white-space")) (_o$705 jolt-nil) (_o$706 (keyword #f "pos")) (_o$707 0)) (jolt-hash-map _o$686 _o$687 _o$688 _o$689 _o$690 _o$691 _o$692 _o$693 _o$694 _o$695 _o$696 _o$697 _o$698 _o$699 _o$700 _o$701 _o$702 _o$703 _o$704 _o$705 _o$706 _o$707))))))))) pretty-writer))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "start-block" (letrec ((start-block (lambda (this prefix per-line-prefix suffix) (let fnrec858 ((this this) (prefix prefix) (per-line-prefix per-line-prefix) (suffix suffix)) (let* ((lb (let* ((_a$859 (var-deref "clojure.pprint" "->logical-block")) (_a$860 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (_a$861 jolt-nil) (_a$862 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$863 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$864 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$865 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$866 prefix) (_a$867 per-line-prefix) (_a$868 suffix) (_a$869 jolt-nil)) (jolt-invoke _a$859 _a$860 _a$861 _a$862 _a$863 _a$864 _a$865 _a$866 _a$867 _a$868 _a$869)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "logical-blocks") lb) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "start"))) jolt-nil)) (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) (let* ((col (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "start-col")) col) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "indent")) col)))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-n+ oldpos (if (jolt-truthy? prefix) (jolt-count prefix) 0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-start-block-t") lb oldpos newpos))))))))))) start-block) (let* ((_o$870 (keyword #f "private")) (_o$871 #t)) (jolt-hash-map _o$870 _o$871)))) + (def-var! "clojure.pprint" "start-block" (letrec ((start-block (lambda (this prefix per-line-prefix suffix) (let fnrec708 ((this this) (prefix prefix) (per-line-prefix per-line-prefix) (suffix suffix)) (let* ((lb (let* ((_a$709 (var-deref "clojure.pprint" "->logical-block")) (_a$710 (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (_a$711 jolt-nil) (_a$712 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$713 (jolt-invoke (var-deref "clojure.core" "atom") 0)) (_a$714 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$715 (jolt-invoke (var-deref "clojure.core" "atom") #f)) (_a$716 prefix) (_a$717 per-line-prefix) (_a$718 suffix) (_a$719 jolt-nil)) (jolt-invoke _a$709 _a$710 _a$711 _a$712 _a$713 _a$714 _a$715 _a$716 _a$717 _a$718 _a$719)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "logical-blocks") lb) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "start"))) jolt-nil)) (if (jolt-truthy? prefix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) prefix) jolt-nil) (let* ((col (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))))) (begin (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "start-col")) col) (jolt-invoke (var-deref "clojure.core" "reset!") (jolt-get lb (keyword #f "indent")) col)))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (+ oldpos (if (jolt-truthy? prefix) (jolt-count prefix) 0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-start-block-t") lb oldpos newpos))))))))))) start-block))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "end-block" (letrec ((end-block (lambda (this) (let fnrec872 ((this this)) (let* ((lb (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (suffix (jolt-get lb (keyword #f "suffix")))) (begin (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (if (jolt-truthy? suffix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) suffix) jolt-nil) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "end"))) jolt-nil))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (jolt-n+ oldpos (if (jolt-truthy? suffix) (jolt-count suffix) 0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-end-block-t") lb oldpos newpos))))) (let* ((_a$873 (var-deref "clojure.core" "swap!")) (_a$874 (record-method-dispatch this "-fields" (jolt-vector))) (_a$875 jolt-assoc) (_a$876 (keyword #f "logical-blocks")) (_a$877 (jolt-get lb (keyword #f "parent")))) (jolt-invoke _a$873 _a$874 _a$875 _a$876 _a$877)))))))) end-block) (let* ((_o$878 (keyword #f "private")) (_o$879 #t)) (jolt-hash-map _o$878 _o$879)))) + (def-var! "clojure.pprint" "end-block" (letrec ((end-block (lambda (this) (let fnrec720 ((this this)) (let* ((lb (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks"))) (suffix (jolt-get lb (keyword #f "suffix")))) (begin (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (if (jolt-truthy? suffix) (jolt-invoke (var-deref "clojure.pprint" "-write") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base")) suffix) jolt-nil) (let* ((temp__27__auto (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-block-callback")))) (if (jolt-truthy? temp__27__auto) (let* ((cb temp__27__auto)) (jolt-invoke cb (keyword #f "end"))) jolt-nil))) (let* ((oldpos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos"))) (newpos (+ oldpos (if (jolt-truthy? suffix) (jolt-count suffix) 0)))) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "pos") newpos) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-end-block-t") lb oldpos newpos))))) (let* ((_a$721 (var-deref "clojure.core" "swap!")) (_a$722 (record-method-dispatch this "-fields" (jolt-vector))) (_a$723 jolt-assoc) (_a$724 (keyword #f "logical-blocks")) (_a$725 (jolt-get lb (keyword #f "parent")))) (jolt-invoke _a$721 _a$722 _a$723 _a$724 _a$725)))))))) end-block))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "nl" (letrec ((nl (lambda (this type) (let fnrec880 ((this this) (type type)) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "mode") (keyword #f "buffering")) (let* ((pos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos")))) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-nl-t") type (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks")) pos pos)))))))) nl) (let* ((_o$881 (keyword #f "private")) (_o$882 #t)) (jolt-hash-map _o$881 _o$882)))) + (def-var! "clojure.pprint" "nl" (letrec ((nl (lambda (this type) (let fnrec726 ((this this) (type type)) (begin (jolt-invoke (var-deref "clojure.core" "swap!") (record-method-dispatch this "-fields" (jolt-vector)) jolt-assoc (keyword #f "mode") (keyword #f "buffering")) (let* ((pos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos")))) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-nl-t") type (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks")) pos pos)))))))) nl))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "indent" (letrec ((indent (lambda (this relative-to offset) (let fnrec883 ((this this) (relative-to relative-to) (offset offset)) (let* ((lb (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks")))) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (let* ((_a$886 (var-deref "clojure.core" "reset!")) (_a$887 (jolt-get lb (keyword #f "indent"))) (_a$888 (jolt-n+ offset (let* ((G__43 jolt=) (G__44 relative-to)) (if (jolt-truthy? (jolt-invoke G__43 (keyword #f "block") G__44)) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col"))) (if (jolt-truthy? (jolt-invoke G__43 (keyword #f "current") G__44)) (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (jolt-throw (let* ((_a$884 (jolt-invoke (var-deref "clojure.core" "str") "No matching clause: " G__44)) (_a$885 (jolt-hash-map))) (jolt-ex-info _a$884 _a$885))))))))) (jolt-invoke _a$886 _a$887 _a$888))) (let* ((pos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos")))) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-indent-t") lb relative-to offset pos pos))))))))) indent) (let* ((_o$889 (keyword #f "private")) (_o$890 #t)) (jolt-hash-map _o$889 _o$890)))) + (def-var! "clojure.pprint" "indent" (letrec ((indent (lambda (this relative-to offset) (let fnrec727 ((this this) (relative-to relative-to) (offset offset)) (let* ((lb (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "logical-blocks")))) (if (jolt= (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "mode")) (keyword #f "writing")) (begin (jolt-invoke (var-deref "clojure.pprint" "write-white-space") this) (let* ((_a$730 (var-deref "clojure.core" "reset!")) (_a$731 (jolt-get lb (keyword #f "indent"))) (_a$732 (+ offset (let* ((G__35 jolt=) (G__36 relative-to)) (if (jolt-truthy? (jolt-invoke G__35 (keyword #f "block") G__36)) (jolt-invoke (var-deref "clojure.core" "deref") (jolt-get lb (keyword #f "start-col"))) (if (jolt-truthy? (jolt-invoke G__35 (keyword #f "current") G__36)) (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "base"))) (jolt-throw (let* ((_a$728 (jolt-invoke (var-deref "clojure.core" "str") "No matching clause: " G__36)) (_a$729 (jolt-hash-map))) (jolt-ex-info _a$728 _a$729))))))))) (jolt-invoke _a$730 _a$731 _a$732))) (let* ((pos (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch this "-fields" (jolt-vector))) (keyword #f "pos")))) (jolt-invoke (var-deref "clojure.pprint" "add-to-buffer") this (jolt-invoke (var-deref "clojure.pprint" "make-indent-t") lb relative-to offset pos pos))))))))) indent))) (guard (e (#t #f)) - (def-var-with-meta! 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"clojure.pprint" "make-pretty-writer" (letrec ((make-pretty-writer (lambda (base-writer right-margin miser-width) (let fnrec735 ((base-writer base-writer) (right-margin right-margin) (miser-width miser-width)) (jolt-invoke (var-deref "clojure.pprint" "pretty-writer") base-writer right-margin miser-width))))) make-pretty-writer))) (guard (e (#t #f)) (def-var! 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"clojure.pprint" "write-out" (letrec ((write-out (lambda (object) (let fnrec780 ((object object)) (let* ((length-reached (let* ((and__25__auto (var-deref "clojure.pprint" "*current-length*"))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (var-deref "clojure.pprint" "*print-length*"))) (if (jolt-truthy? and__25__auto) (>= (var-deref "clojure.pprint" "*current-length*") (var-deref "clojure.pprint" "*print-length*")) and__25__auto)) and__25__auto)))) (begin (if (jolt-not (var-deref "clojure.pprint" "*print-pretty*")) (jolt-invoke (var-deref "clojure.pprint" "pr") object) (if (jolt-truthy? length-reached) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "...") (begin (if (jolt-truthy? (var-deref "clojure.pprint" "*current-length*")) (jolt-var-set (jolt-var "clojure.pprint" "*current-length*") (jolt-inc (var-deref "clojure.pprint" "*current-length*"))) jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "*print-pprint-dispatch*") object)))) length-reached)))))) write-out))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "write" (letrec ((write (lambda (object . kw-args) (let fnrec985 ((object object) (kw-args (list->cseq kw-args))) (let* ((options (let* ((_a$988 (var-deref "clojure.core" "merge")) (_a$989 (let* ((_o$986 (keyword #f "stream")) (_o$987 #t)) (jolt-hash-map _o$986 _o$987))) (_a$990 (jolt-apply jolt-hash-map-fn kw-args))) (jolt-invoke _a$988 _a$989 _a$990)))) (let* ((frame__20__auto (let* ((_a$991 (var-deref "clojure.core" "array-map")) (_a$992 (jolt-var "clojure.pprint" "*print-base*")) (_a$993 (jolt-get options (keyword #f "base") (var-deref "clojure.pprint" "*print-base*"))) (_a$994 (jolt-var "clojure.pprint" "*print-circle*")) (_a$995 (jolt-get options (keyword #f "circle") (var-deref "clojure.pprint" "*print-circle*"))) (_a$996 (jolt-var "clojure.pprint" "*print-length*")) (_a$997 (jolt-get options (keyword #f "length") (var-deref "clojure.pprint" "*print-length*"))) (_a$998 (jolt-var "clojure.pprint" "*print-level*")) (_a$999 (jolt-get options (keyword #f "level") (var-deref "clojure.pprint" "*print-level*"))) (_a$1000 (jolt-var "clojure.pprint" "*print-lines*")) (_a$1001 (jolt-get options (keyword #f "lines") (var-deref "clojure.pprint" "*print-lines*"))) (_a$1002 (jolt-var "clojure.pprint" "*print-miser-width*")) (_a$1003 (jolt-get options (keyword #f "miser-width") (var-deref "clojure.pprint" "*print-miser-width*"))) (_a$1004 (jolt-var "clojure.pprint" "*print-pprint-dispatch*")) (_a$1005 (jolt-get options (keyword #f "dispatch") (var-deref "clojure.pprint" "*print-pprint-dispatch*"))) (_a$1006 (jolt-var "clojure.pprint" "*print-pretty*")) (_a$1007 (jolt-get options (keyword #f "pretty") (var-deref "clojure.pprint" "*print-pretty*"))) (_a$1008 (jolt-var "clojure.pprint" "*print-radix*")) (_a$1009 (jolt-get options (keyword #f "radix") (var-deref "clojure.pprint" "*print-radix*"))) (_a$1010 (jolt-var "clojure.core" "*print-readably*")) (_a$1011 (jolt-get options (keyword #f "readably") (var-deref "clojure.core" "*print-readably*"))) (_a$1012 (jolt-var "clojure.pprint" "*print-right-margin*")) (_a$1013 (jolt-get options (keyword #f "right-margin") (var-deref "clojure.pprint" "*print-right-margin*"))) (_a$1014 (jolt-var "clojure.pprint" "*print-suppress-namespaces*")) (_a$1015 (jolt-get options (keyword #f "suppress-namespaces") (var-deref "clojure.pprint" "*print-suppress-namespaces*")))) (jolt-invoke _a$991 _a$992 _a$993 _a$994 _a$995 _a$996 _a$997 _a$998 _a$999 _a$1000 _a$1001 _a$1002 _a$1003 _a$1004 _a$1005 _a$1006 _a$1007 _a$1008 _a$1009 _a$1010 _a$1011 _a$1012 _a$1013 _a$1014 _a$1015)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (let* ((sb (host-new "StringBuilder")) (optval (if (jolt-contains? options (keyword #f "stream")) (jolt-get options (keyword #f "stream")) #t)) (base-writer (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") optval))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-nil? optval)))) (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb) optval))) (begin (if (jolt-truthy? (var-deref "clojure.pprint" "*print-pretty*")) (let* ((base-writer__11__auto base-writer) (new-writer__12__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") base-writer__11__auto)))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (if (jolt-truthy? new-writer__12__auto) (jolt-invoke (var-deref "clojure.pprint" "make-pretty-writer") base-writer__11__auto (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*")) base-writer__11__auto)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "__with-pprint-routing") (lambda () (let fnrec1016 () (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") object) (jolt-invoke (var-deref "clojure.pprint" "-ppflush") (var-deref "clojure.core" "*out*"))))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") base-writer))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "pr") object)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "true?") optval)) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)) jolt-nil) (if (jolt-nil? optval) (jolt-invoke (var-deref "clojure.core" "str") sb) jolt-nil)))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))))) write) (let* ((_o$1017 (keyword #f "doc")) (_o$1018 "Write an object subject to the current bindings of the printer control\n variables. Returns the string result if :stream is nil, nil otherwise.")) (jolt-hash-map _o$1017 _o$1018)))) + (def-var! "clojure.pprint" "write" (letrec ((write (lambda (object . kw-args) (let fnrec781 ((object object) (kw-args (list->cseq kw-args))) (let* ((options (let* ((_a$784 (var-deref "clojure.core" "merge")) (_a$785 (let* ((_o$782 (keyword #f "stream")) (_o$783 #t)) (jolt-hash-map _o$782 _o$783))) (_a$786 (jolt-apply jolt-hash-map kw-args))) (jolt-invoke _a$784 _a$785 _a$786)))) (let* ((frame__20__auto (let* ((_a$787 (var-deref "clojure.core" "array-map")) (_a$788 (jolt-var "clojure.pprint" "*print-base*")) (_a$789 (jolt-get options (keyword #f "base") (var-deref "clojure.pprint" "*print-base*"))) (_a$790 (jolt-var "clojure.pprint" "*print-circle*")) (_a$791 (jolt-get options (keyword #f "circle") (var-deref "clojure.pprint" "*print-circle*"))) (_a$792 (jolt-var "clojure.pprint" "*print-length*")) (_a$793 (jolt-get options (keyword #f "length") (var-deref "clojure.pprint" "*print-length*"))) (_a$794 (jolt-var "clojure.pprint" "*print-level*")) (_a$795 (jolt-get options (keyword #f "level") (var-deref "clojure.pprint" "*print-level*"))) (_a$796 (jolt-var "clojure.pprint" "*print-lines*")) (_a$797 (jolt-get options (keyword #f "lines") (var-deref "clojure.pprint" "*print-lines*"))) (_a$798 (jolt-var "clojure.pprint" "*print-miser-width*")) (_a$799 (jolt-get options (keyword #f "miser-width") (var-deref "clojure.pprint" "*print-miser-width*"))) (_a$800 (jolt-var "clojure.pprint" "*print-pprint-dispatch*")) (_a$801 (jolt-get options (keyword #f "dispatch") (var-deref "clojure.pprint" "*print-pprint-dispatch*"))) (_a$802 (jolt-var "clojure.pprint" "*print-pretty*")) (_a$803 (jolt-get options (keyword #f "pretty") (var-deref "clojure.pprint" "*print-pretty*"))) (_a$804 (jolt-var "clojure.pprint" "*print-radix*")) (_a$805 (jolt-get options (keyword #f "radix") (var-deref "clojure.pprint" "*print-radix*"))) (_a$806 (jolt-var "clojure.core" "*print-readably*")) (_a$807 (jolt-get options (keyword #f "readably") (var-deref "clojure.core" "*print-readably*"))) (_a$808 (jolt-var "clojure.pprint" "*print-right-margin*")) (_a$809 (jolt-get options (keyword #f "right-margin") (var-deref "clojure.pprint" "*print-right-margin*"))) (_a$810 (jolt-var "clojure.pprint" "*print-suppress-namespaces*")) (_a$811 (jolt-get options (keyword #f "suppress-namespaces") (var-deref "clojure.pprint" "*print-suppress-namespaces*")))) (jolt-invoke _a$787 _a$788 _a$789 _a$790 _a$791 _a$792 _a$793 _a$794 _a$795 _a$796 _a$797 _a$798 _a$799 _a$800 _a$801 _a$802 _a$803 _a$804 _a$805 _a$806 _a$807 _a$808 _a$809 _a$810 _a$811)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (let* ((sb (host-new "StringBuilder")) (optval (if (jolt-contains? options (keyword #f "stream")) (jolt-get options (keyword #f "stream")) #t)) (base-writer (if (jolt-truthy? (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") optval))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") optval)))) (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb) optval))) (begin (if (jolt-truthy? (var-deref "clojure.pprint" "*print-pretty*")) (let* ((base-writer__11__auto base-writer) (new-writer__12__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") base-writer__11__auto)))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (if (jolt-truthy? new-writer__12__auto) (jolt-invoke (var-deref "clojure.pprint" "make-pretty-writer") base-writer__11__auto (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*")) base-writer__11__auto)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "__with-pprint-routing") (lambda () (let fnrec812 () (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") object) (jolt-invoke (var-deref "clojure.pprint" "-ppflush") (var-deref "clojure.core" "*out*"))))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") base-writer))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "pr") object)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "true?") optval)) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)) jolt-nil) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") optval)) (jolt-invoke (var-deref "clojure.core" "str") sb) jolt-nil)))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))))) write))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint" (letrec ((pprint (case-lambda ((object) (let fnrec1019 ((object object)) (let* ((sb (host-new "StringBuilder"))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (pprint object (var-deref "clojure.core" "*out*")) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) ((object writer) (let fnrec1020 ((object object) (writer writer)) (let* ((base-writer__11__auto writer) (new-writer__12__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") base-writer__11__auto)))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (if (jolt-truthy? new-writer__12__auto) (jolt-invoke (var-deref "clojure.pprint" "make-pretty-writer") base-writer__11__auto (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*")) base-writer__11__auto)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "__with-pprint-routing") (lambda () (let fnrec1021 () (begin (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*print-pretty*") #t))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "write-out") object)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))) (if (jolt-not (jolt= 0 (jolt-invoke (var-deref "clojure.pprint" "get-column") (var-deref "clojure.core" "*out*")))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n") jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "-ppflush") (var-deref "clojure.core" "*out*"))))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))))))) pprint) (let* ((_o$1022 (keyword #f "doc")) (_o$1023 "Pretty print object. With one arg, prints to *out* (captured by with-out-str).\n The 2-arg form writes to the supplied pretty-writer.")) (jolt-hash-map _o$1022 _o$1023)))) + (def-var! "clojure.pprint" "pprint" (letrec ((pprint (case-lambda ((object) (let fnrec813 ((object object)) (let* ((sb (host-new "StringBuilder"))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke pprint object (var-deref "clojure.core" "*out*")) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) ((object writer) (let fnrec814 ((object object) (writer writer)) (let* ((base-writer__11__auto writer) (new-writer__12__auto (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") base-writer__11__auto)))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (if (jolt-truthy? new-writer__12__auto) (jolt-invoke (var-deref "clojure.pprint" "make-pretty-writer") base-writer__11__auto (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*")) base-writer__11__auto)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.core" "__with-pprint-routing") (lambda () (let fnrec815 () (begin (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*print-pretty*") #t))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "write-out") object)) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))) (if (jolt-not (jolt= 0 (jolt-invoke (var-deref "clojure.pprint" "get-column") (var-deref "clojure.core" "*out*")))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "\n") jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "-ppflush") (var-deref "clojure.core" "*out*"))))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))))))) pprint))) (guard (e (#t #f)) - (def-var! "clojure.pprint" "set-pprint-dispatch" (letrec ((set-pprint-dispatch (lambda (function) (let fnrec1024 ((function function)) (begin (jolt-var-set (jolt-var "clojure.pprint" "*print-pprint-dispatch*") function) jolt-nil))))) set-pprint-dispatch))) + (def-var! "clojure.pprint" "set-pprint-dispatch" (letrec ((set-pprint-dispatch (lambda (function) (let fnrec816 ((function function)) (begin (jolt-var-set (jolt-var "clojure.pprint" "*print-pprint-dispatch*") function) jolt-nil))))) set-pprint-dispatch))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "check-enumerated-arg" (letrec ((check-enumerated-arg (lambda (arg choices) (let fnrec1025 ((arg arg) (choices choices)) (if (jolt-not (jolt-invoke choices arg)) (jolt-throw (host-new "Exception" (jolt-invoke (var-deref "clojure.core" "str") "Bad argument: " arg ". It must be one of " choices))) jolt-nil))))) check-enumerated-arg) (let* ((_o$1026 (keyword #f "private")) (_o$1027 #t)) (jolt-hash-map _o$1026 _o$1027)))) + (def-var! "clojure.pprint" "check-enumerated-arg" (letrec ((check-enumerated-arg (lambda (arg choices) (let fnrec817 ((arg arg) (choices choices)) (if (jolt-not (jolt-invoke choices arg)) (jolt-throw (host-new "Exception" (jolt-invoke (var-deref "clojure.core" "str") "Bad argument: " arg ". It must be one of " choices))) jolt-nil))))) check-enumerated-arg))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "level-exceeded" (letrec ((level-exceeded (lambda () (let fnrec1028 () (let* ((and__25__auto (var-deref "clojure.pprint" "*print-level*"))) (if (jolt-truthy? and__25__auto) (jolt-n>= (var-deref "clojure.pprint" "*current-level*") (var-deref "clojure.pprint" "*print-level*")) and__25__auto)))))) level-exceeded) (let* ((_o$1029 (keyword #f "private")) (_o$1030 #t)) (jolt-hash-map _o$1029 _o$1030)))) + (def-var! "clojure.pprint" "level-exceeded" (letrec ((level-exceeded (lambda () (let fnrec818 () (let* ((and__25__auto (var-deref "clojure.pprint" "*print-level*"))) (if (jolt-truthy? and__25__auto) (>= (var-deref "clojure.pprint" "*current-level*") (var-deref "clojure.pprint" "*print-level*")) and__25__auto)))))) level-exceeded))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-newline" (letrec ((pprint-newline (lambda (kind) (let fnrec1031 ((kind kind)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") kind (let* ((_o$1032 (keyword #f "linear")) (_o$1033 (keyword #f "miser")) (_o$1034 (keyword #f "fill")) (_o$1035 (keyword #f "mandatory"))) (jolt-hash-set _o$1032 _o$1033 _o$1034 _o$1035))) (jolt-invoke (var-deref "clojure.pprint" "nl") (var-deref "clojure.core" "*out*") kind)))))) pprint-newline) (let* ((_o$1036 (keyword #f "doc")) (_o$1037 "Print a conditional newline (:linear :miser :fill or :mandatory) to *out*,\n which must be a pretty-printing writer.")) (jolt-hash-map _o$1036 _o$1037)))) + (def-var! "clojure.pprint" "pprint-newline" (letrec ((pprint-newline (lambda (kind) (let fnrec819 ((kind kind)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") kind (let* ((_o$820 (keyword #f "linear")) (_o$821 (keyword #f "miser")) (_o$822 (keyword #f "fill")) (_o$823 (keyword #f "mandatory"))) (jolt-hash-set _o$820 _o$821 _o$822 _o$823))) (jolt-invoke (var-deref "clojure.pprint" "nl") (var-deref "clojure.core" "*out*") kind)))))) pprint-newline))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-indent" (letrec ((pprint-indent (lambda (relative-to n) (let fnrec1038 ((relative-to relative-to) (n n)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") relative-to (let* ((_o$1039 (keyword #f "block")) (_o$1040 (keyword #f "current"))) (jolt-hash-set _o$1039 _o$1040))) (jolt-invoke (var-deref "clojure.pprint" "indent") (var-deref "clojure.core" "*out*") relative-to n)))))) pprint-indent) (let* ((_o$1041 (keyword #f "doc")) (_o$1042 "Create an indent at this point in the pretty-printing stream. relative-to is\n :block or :current; n is an offset.")) (jolt-hash-map _o$1041 _o$1042)))) + (def-var! "clojure.pprint" "pprint-indent" (letrec ((pprint-indent (lambda (relative-to n) (let fnrec824 ((relative-to relative-to) (n n)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") relative-to (let* ((_o$825 (keyword #f "block")) (_o$826 (keyword #f "current"))) (jolt-hash-set _o$825 _o$826))) (jolt-invoke (var-deref "clojure.pprint" "indent") (var-deref "clojure.core" "*out*") relative-to n)))))) pprint-indent))) (guard (e (#t #f)) - (def-var! "clojure.pprint" "pprint-tab" (letrec ((pprint-tab (lambda (kind colnum colinc) (let fnrec1043 ((kind kind) (colnum colnum) (colinc colinc)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") kind (let* ((_o$1044 (keyword #f "line")) (_o$1045 (keyword #f "section")) (_o$1046 (keyword #f "line-relative")) (_o$1047 (keyword #f "section-relative"))) (jolt-hash-set _o$1044 _o$1045 _o$1046 _o$1047))) (jolt-throw (host-new "Exception" "pprint-tab is not yet implemented"))))))) pprint-tab))) + (def-var! "clojure.pprint" "pprint-tab" (letrec ((pprint-tab (lambda (kind colnum colinc) (let fnrec827 ((kind kind) (colnum colnum) (colinc colinc)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-enumerated-arg") kind (let* ((_o$828 (keyword #f "line")) (_o$829 (keyword #f "section")) (_o$830 (keyword #f "line-relative")) (_o$831 (keyword #f "section-relative"))) (jolt-hash-set _o$828 _o$829 _o$830 _o$831))) (jolt-throw (host-new "Exception" "pprint-tab is not yet implemented"))))))) pprint-tab))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "compile-format")) (guard (e (#t #f)) @@ -1329,186 +1335,186 @@ (guard (e (#t #f)) (declare-var! "clojure.pprint" "init-navigator")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "cl-format" (letrec ((cl-format (lambda (writer format-in . args) (let fnrec1048 ((writer writer) (format-in format-in) (args (list->cseq args))) (let* ((compiled-format (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in)) (jolt-invoke (var-deref "clojure.pprint" "compile-format") format-in) format-in)) (navigator (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") writer compiled-format navigator)))))) cl-format) (let* ((_o$1049 (keyword #f "doc")) (_o$1050 "A Common Lisp compatible format function. If writer is nil, returns the\n formatted string; if true, prints to *out*; otherwise writes to writer.")) (jolt-hash-map _o$1049 _o$1050)))) + (def-var! "clojure.pprint" "cl-format" (letrec ((cl-format (lambda (writer format-in . args) (let fnrec832 ((writer writer) (format-in format-in) (args (list->cseq args))) (let* ((compiled-format (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in)) (jolt-invoke (var-deref "clojure.pprint" "compile-format") format-in) format-in)) (navigator (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") writer compiled-format navigator)))))) cl-format))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "*format-str*" jolt-nil (let* ((_o$1051 (keyword #f "private")) (_o$1052 #t) (_o$1053 (keyword #f "dynamic")) (_o$1054 #t)) (jolt-hash-map _o$1051 _o$1052 _o$1053 _o$1054)))) + (def-var-with-meta! "clojure.pprint" "*format-str*" jolt-nil (jolt-hash-map (keyword #f "dynamic") #t (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "format-error" (letrec ((format-error (lambda (message offset) (let fnrec1055 ((message message) (offset offset)) (let* ((full-message (jolt-invoke (var-deref "clojure.core" "str") message "\n" (var-deref "clojure.pprint" "*format-str*") "\n" (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") offset (integer->char 32))) "^" "\n"))) (jolt-throw (host-new "Exception" full-message))))))) format-error) (let* ((_o$1056 (keyword #f "private")) (_o$1057 #t)) (jolt-hash-map _o$1056 _o$1057)))) + (def-var! "clojure.pprint" "format-error" (letrec ((format-error (lambda (message offset) (let fnrec833 ((message message) (offset offset)) (let* ((full-message (jolt-invoke (var-deref "clojure.core" "str") message "\n" (var-deref "clojure.pprint" "*format-str*") "\n" (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") offset (integer->char 32))) "^" "\n"))) (jolt-throw (host-new "Exception" full-message))))))) format-error))) (guard (e (#t #f)) - (begin (begin (def-var-with-meta! "clojure.pprint" "arg-navigator" (let* ((_a$1067 (var-deref "clojure.core" "make-deftype-ctor")) (_a$1068 (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-symbol/meta #f "arg-navigator" (jolt-hash-map (keyword #f "private") #t)) (jolt-hash-map (keyword #f "private") #t))) (_a$1069 (let* ((_o$1058 (keyword #f "seq")) (_o$1059 (keyword #f "rest")) (_o$1060 (keyword #f "pos"))) (jolt-vector _o$1058 _o$1059 _o$1060))) (_a$1070 (let* ((_o$1061 jolt-nil) (_o$1062 jolt-nil) (_o$1063 jolt-nil)) (jolt-vector _o$1061 _o$1062 _o$1063))) (_a$1071 (let* ((_o$1064 #f) (_o$1065 #f) (_o$1066 #f)) (jolt-vector _o$1064 _o$1065 _o$1066)))) (jolt-invoke _a$1067 _a$1068 _a$1069 _a$1070 _a$1071)) (let* ((_o$1072 (keyword #f "private")) (_o$1073 #t)) (jolt-hash-map _o$1072 _o$1073))) (def-var! "clojure.pprint" "->arg-navigator" (var-deref "clojure.pprint" "arg-navigator")) (var-deref "clojure.pprint" "arg-navigator")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-symbol/meta #f "arg-navigator" (jolt-hash-map (keyword #f "private") #t)) (jolt-hash-map (keyword #f "private") #t))) (def-var! "clojure.pprint" "map->arg-navigator" (lambda (G__45) (let fnrec1074 ((G__45 G__45)) (let* ((_a$1079 (var-deref "clojure.core" "reduce-kv")) (_a$1080 jolt-assoc) (_a$1081 (let* ((_a$1075 (var-deref "clojure.pprint" "->arg-navigator")) (_a$1076 (jolt-get G__45 (keyword #f "seq"))) (_a$1077 (jolt-get G__45 (keyword #f "rest"))) (_a$1078 (jolt-get G__45 (keyword #f "pos")))) (jolt-invoke _a$1075 _a$1076 _a$1077 _a$1078))) (_a$1082 (jolt-dissoc G__45 (keyword #f "seq") (keyword #f "rest") (keyword #f "pos")))) (jolt-invoke _a$1079 _a$1080 _a$1081 _a$1082))))))) + (begin (begin (def-var-with-meta! "clojure.pprint" "arg-navigator" (let* ((_a$843 (var-deref "clojure.core" "make-deftype-ctor")) (_a$844 (jolt-symbol/meta #f "arg-navigator" (jolt-hash-map (keyword #f "private") #t))) (_a$845 (let* ((_o$834 (keyword #f "seq")) (_o$835 (keyword #f "rest")) (_o$836 (keyword #f "pos"))) (jolt-vector _o$834 _o$835 _o$836))) (_a$846 (let* ((_o$837 jolt-nil) (_o$838 jolt-nil) (_o$839 jolt-nil)) (jolt-vector _o$837 _o$838 _o$839))) (_a$847 (let* ((_o$840 #f) (_o$841 #f) (_o$842 #f)) (jolt-vector _o$840 _o$841 _o$842)))) (jolt-invoke _a$843 _a$844 _a$845 _a$846 _a$847)) (jolt-hash-map (keyword #f "private") #t)) (def-var! "clojure.pprint" "->arg-navigator" (var-deref "clojure.pprint" "arg-navigator")) (var-deref "clojure.pprint" "arg-navigator")) (def-var! "clojure.pprint" "map->arg-navigator" (lambda (G__37) (let fnrec848 ((G__37 G__37)) (let* ((_a$849 (var-deref "clojure.pprint" "->arg-navigator")) (_a$850 (jolt-get G__37 (keyword #f "seq"))) (_a$851 (jolt-get G__37 (keyword #f "rest"))) (_a$852 (jolt-get G__37 (keyword #f "pos")))) (jolt-invoke _a$849 _a$850 _a$851 _a$852))))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "init-navigator" (letrec ((init-navigator (lambda (s) (let fnrec1083 ((s s)) (let* ((s (jolt-seq s))) (jolt-invoke (var-deref "clojure.pprint" "->arg-navigator") s s 0)))))) init-navigator) (let* ((_o$1084 (keyword #f "private")) (_o$1085 #t)) (jolt-hash-map _o$1084 _o$1085)))) + (def-var! "clojure.pprint" "init-navigator" (letrec ((init-navigator (lambda (s) (let fnrec853 ((s s)) (let* ((s (jolt-seq s))) (jolt-invoke (var-deref "clojure.pprint" "->arg-navigator") s s 0)))))) init-navigator))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "next-arg" (letrec ((next-arg (lambda (navigator) (let fnrec1086 ((navigator navigator)) (let* ((rst (jolt-get navigator (keyword #f "rest")))) (if (jolt-truthy? rst) (let* ((_o$1091 (jolt-first rst)) (_o$1092 (let* ((_a$1087 (var-deref "clojure.pprint" "->arg-navigator")) (_a$1088 (jolt-get navigator (keyword #f "seq"))) (_a$1089 (jolt-next rst)) (_a$1090 (jolt-inc (jolt-get navigator (keyword #f "pos"))))) (jolt-invoke _a$1087 _a$1088 _a$1089 _a$1090)))) (jolt-vector _o$1091 _o$1092)) (jolt-throw (host-new "Exception" "Not enough arguments for format definition")))))))) next-arg) (let* ((_o$1093 (keyword #f "private")) (_o$1094 #t)) (jolt-hash-map _o$1093 _o$1094)))) + (def-var! "clojure.pprint" "next-arg" (letrec ((next-arg (lambda (navigator) (let fnrec854 ((navigator navigator)) (let* ((rst (jolt-get navigator (keyword #f "rest")))) (if (jolt-truthy? rst) (let* ((_o$859 (jolt-first rst)) (_o$860 (let* ((_a$855 (var-deref "clojure.pprint" "->arg-navigator")) (_a$856 (jolt-get navigator (keyword #f "seq"))) (_a$857 (jolt-next rst)) (_a$858 (jolt-inc (jolt-get navigator (keyword #f "pos"))))) (jolt-invoke _a$855 _a$856 _a$857 _a$858)))) (jolt-vector _o$859 _o$860)) (jolt-throw (host-new "Exception" "Not enough arguments for format definition")))))))) next-arg))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "next-arg-or-nil" (letrec ((next-arg-or-nil (lambda (navigator) (let fnrec1095 ((navigator navigator)) (let* ((rst (jolt-get navigator (keyword #f "rest")))) (if (jolt-truthy? rst) (let* ((_o$1100 (jolt-first rst)) (_o$1101 (let* ((_a$1096 (var-deref "clojure.pprint" "->arg-navigator")) (_a$1097 (jolt-get navigator (keyword #f "seq"))) (_a$1098 (jolt-next rst)) (_a$1099 (jolt-inc (jolt-get navigator (keyword #f "pos"))))) (jolt-invoke _a$1096 _a$1097 _a$1098 _a$1099)))) (jolt-vector _o$1100 _o$1101)) (let* ((_o$1102 jolt-nil) (_o$1103 navigator)) (jolt-vector _o$1102 _o$1103)))))))) next-arg-or-nil) (let* ((_o$1104 (keyword #f "private")) (_o$1105 #t)) (jolt-hash-map _o$1104 _o$1105)))) + (def-var! "clojure.pprint" "next-arg-or-nil" (letrec ((next-arg-or-nil (lambda (navigator) (let fnrec861 ((navigator navigator)) (let* ((rst (jolt-get navigator (keyword #f "rest")))) (if (jolt-truthy? rst) (let* ((_o$866 (jolt-first rst)) (_o$867 (let* ((_a$862 (var-deref "clojure.pprint" "->arg-navigator")) (_a$863 (jolt-get navigator (keyword #f "seq"))) (_a$864 (jolt-next rst)) (_a$865 (jolt-inc (jolt-get navigator (keyword #f "pos"))))) (jolt-invoke _a$862 _a$863 _a$864 _a$865)))) (jolt-vector _o$866 _o$867)) (let* ((_o$868 jolt-nil) (_o$869 navigator)) (jolt-vector _o$868 _o$869)))))))) next-arg-or-nil))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-format-arg" (letrec ((get-format-arg (lambda (navigator) (let fnrec1106 ((navigator navigator)) (let* ((G__46 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (raw-format (jolt-nth G__46 0 jolt-nil)) (navigator (jolt-nth G__46 1 jolt-nil)) (compiled-format (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") raw-format)) (jolt-invoke (var-deref "clojure.pprint" "compile-format") raw-format) raw-format))) (let* ((_o$1107 compiled-format) (_o$1108 navigator)) (jolt-vector _o$1107 _o$1108))))))) get-format-arg) (let* ((_o$1109 (keyword #f "private")) (_o$1110 #t)) (jolt-hash-map _o$1109 _o$1110)))) + (def-var! "clojure.pprint" "get-format-arg" (letrec ((get-format-arg (lambda (navigator) (let fnrec870 ((navigator navigator)) (let* ((G__38 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (raw-format (jolt-nth G__38 0 jolt-nil)) (navigator (jolt-nth G__38 1 jolt-nil)) (compiled-format (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") raw-format)) (jolt-invoke (var-deref "clojure.pprint" "compile-format") raw-format) raw-format))) (let* ((_o$871 compiled-format) (_o$872 navigator)) (jolt-vector _o$871 _o$872))))))) get-format-arg))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "relative-reposition")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "absolute-reposition" (letrec ((absolute-reposition (lambda (navigator position) (let fnrec1111 ((navigator navigator) (position position)) (if (jolt-n>= position (jolt-get navigator (keyword #f "pos"))) (jolt-invoke (var-deref "clojure.pprint" "relative-reposition") navigator (jolt-n- (jolt-get navigator (keyword #f "pos")) position)) (let* ((_a$1112 (var-deref "clojure.pprint" "->arg-navigator")) (_a$1113 (jolt-get navigator (keyword #f "seq"))) (_a$1114 (jolt-drop position (jolt-get navigator (keyword #f "seq")))) (_a$1115 position)) (jolt-invoke _a$1112 _a$1113 _a$1114 _a$1115))))))) absolute-reposition) (let* ((_o$1116 (keyword #f "private")) (_o$1117 #t)) (jolt-hash-map _o$1116 _o$1117)))) + (def-var! "clojure.pprint" "absolute-reposition" (letrec ((absolute-reposition (lambda (navigator position) (let fnrec873 ((navigator navigator) (position position)) (if (>= position (jolt-get navigator (keyword #f "pos"))) (jolt-invoke (var-deref "clojure.pprint" "relative-reposition") navigator (- (jolt-get navigator (keyword #f "pos")) position)) (let* ((_a$874 (var-deref "clojure.pprint" "->arg-navigator")) (_a$875 (jolt-get navigator (keyword #f "seq"))) (_a$876 (jolt-drop position (jolt-get navigator (keyword #f "seq")))) (_a$877 position)) (jolt-invoke _a$874 _a$875 _a$876 _a$877))))))) absolute-reposition))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "relative-reposition" (letrec ((relative-reposition (lambda (navigator position) (let fnrec1118 ((navigator navigator) (position position)) (let* ((newpos (jolt-n+ (jolt-get navigator (keyword #f "pos")) position))) (if (jolt-neg? position) (jolt-invoke (var-deref "clojure.pprint" "absolute-reposition") navigator newpos) (let* ((_a$1119 (var-deref "clojure.pprint" "->arg-navigator")) (_a$1120 (jolt-get navigator (keyword #f "seq"))) (_a$1121 (jolt-drop position (jolt-get navigator (keyword #f "rest")))) (_a$1122 newpos)) (jolt-invoke _a$1119 _a$1120 _a$1121 _a$1122)))))))) relative-reposition) (let* ((_o$1123 (keyword #f "private")) (_o$1124 #t)) (jolt-hash-map _o$1123 _o$1124)))) + (def-var! "clojure.pprint" "relative-reposition" (letrec ((relative-reposition (lambda (navigator position) (let fnrec878 ((navigator navigator) (position position)) (let* ((newpos (+ (jolt-get navigator (keyword #f "pos")) position))) (if (jolt-neg? position) (jolt-invoke (var-deref "clojure.pprint" "absolute-reposition") navigator newpos) (let* ((_a$879 (var-deref "clojure.pprint" "->arg-navigator")) (_a$880 (jolt-get navigator (keyword #f "seq"))) (_a$881 (jolt-drop position (jolt-get navigator (keyword #f "rest")))) (_a$882 newpos)) (jolt-invoke _a$879 _a$880 _a$881 _a$882)))))))) relative-reposition))) (guard (e (#t #f)) - (begin (begin (def-var-with-meta! "clojure.pprint" "compiled-directive" (let* ((_a$1137 (var-deref "clojure.core" "make-deftype-ctor")) (_a$1138 (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-symbol/meta #f "compiled-directive" (jolt-hash-map (keyword #f "private") #t)) (jolt-hash-map (keyword #f "private") #t))) (_a$1139 (let* ((_o$1125 (keyword #f "func")) (_o$1126 (keyword #f "dirdef")) (_o$1127 (keyword #f "params")) (_o$1128 (keyword #f "offset"))) (jolt-vector _o$1125 _o$1126 _o$1127 _o$1128))) (_a$1140 (let* ((_o$1129 jolt-nil) (_o$1130 jolt-nil) (_o$1131 jolt-nil) (_o$1132 jolt-nil)) (jolt-vector _o$1129 _o$1130 _o$1131 _o$1132))) (_a$1141 (let* ((_o$1133 #f) (_o$1134 #f) (_o$1135 #f) (_o$1136 #f)) (jolt-vector _o$1133 _o$1134 _o$1135 _o$1136)))) (jolt-invoke _a$1137 _a$1138 _a$1139 _a$1140 _a$1141)) (let* ((_o$1142 (keyword #f "private")) (_o$1143 #t)) (jolt-hash-map _o$1142 _o$1143))) (def-var! "clojure.pprint" "->compiled-directive" (var-deref "clojure.pprint" "compiled-directive")) (var-deref "clojure.pprint" "compiled-directive")) (jolt-invoke (var-deref "clojure.core" "register-record-type!") (jolt-invoke (var-deref "clojure.core" "with-meta") (jolt-symbol/meta #f "compiled-directive" (jolt-hash-map (keyword #f "private") #t)) (jolt-hash-map (keyword #f "private") #t))) (def-var! "clojure.pprint" "map->compiled-directive" (lambda (G__47) (let fnrec1144 ((G__47 G__47)) (let* ((_a$1150 (var-deref "clojure.core" "reduce-kv")) (_a$1151 jolt-assoc) (_a$1152 (let* ((_a$1145 (var-deref "clojure.pprint" "->compiled-directive")) (_a$1146 (jolt-get G__47 (keyword #f "func"))) (_a$1147 (jolt-get G__47 (keyword #f "dirdef"))) (_a$1148 (jolt-get G__47 (keyword #f "params"))) (_a$1149 (jolt-get G__47 (keyword #f "offset")))) (jolt-invoke _a$1145 _a$1146 _a$1147 _a$1148 _a$1149))) (_a$1153 (jolt-dissoc G__47 (keyword #f "func") (keyword #f "dirdef") (keyword #f "params") (keyword #f "offset")))) (jolt-invoke _a$1150 _a$1151 _a$1152 _a$1153))))))) + (begin (begin (def-var-with-meta! "clojure.pprint" "compiled-directive" (let* ((_a$895 (var-deref "clojure.core" "make-deftype-ctor")) (_a$896 (jolt-symbol/meta #f "compiled-directive" (jolt-hash-map (keyword #f "private") #t))) (_a$897 (let* ((_o$883 (keyword #f "func")) (_o$884 (keyword #f "dirdef")) (_o$885 (keyword #f "params")) (_o$886 (keyword #f "offset"))) (jolt-vector _o$883 _o$884 _o$885 _o$886))) (_a$898 (let* ((_o$887 jolt-nil) (_o$888 jolt-nil) (_o$889 jolt-nil) (_o$890 jolt-nil)) (jolt-vector _o$887 _o$888 _o$889 _o$890))) (_a$899 (let* ((_o$891 #f) (_o$892 #f) (_o$893 #f) (_o$894 #f)) (jolt-vector _o$891 _o$892 _o$893 _o$894)))) (jolt-invoke _a$895 _a$896 _a$897 _a$898 _a$899)) (jolt-hash-map (keyword #f "private") #t)) (def-var! "clojure.pprint" "->compiled-directive" (var-deref "clojure.pprint" "compiled-directive")) (var-deref "clojure.pprint" "compiled-directive")) (def-var! "clojure.pprint" "map->compiled-directive" (lambda (G__39) (let fnrec900 ((G__39 G__39)) (let* ((_a$901 (var-deref "clojure.pprint" "->compiled-directive")) (_a$902 (jolt-get G__39 (keyword #f "func"))) (_a$903 (jolt-get G__39 (keyword #f "dirdef"))) (_a$904 (jolt-get G__39 (keyword #f "params"))) (_a$905 (jolt-get G__39 (keyword #f "offset")))) (jolt-invoke _a$901 _a$902 _a$903 _a$904 _a$905))))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "realize-parameter" (letrec ((realize-parameter (lambda (G__48 navigator) (let fnrec1154 ((G__48 G__48) (navigator navigator)) (let* ((G__49 G__48) (param (jolt-nth G__49 0 jolt-nil)) (G__50 (jolt-nth G__49 1 jolt-nil)) (raw-val (jolt-nth G__50 0 jolt-nil)) (offset (jolt-nth G__50 1 jolt-nil))) (let* ((G__51 (if (jolt-contains? (let* ((_o$1155 (keyword #f "at")) (_o$1156 (keyword #f "colon"))) (jolt-hash-set _o$1155 _o$1156)) param) (let* ((_o$1157 raw-val) (_o$1158 navigator)) (jolt-vector _o$1157 _o$1158)) (if (jolt= raw-val (keyword #f "parameter-from-args")) (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator) (if (jolt= raw-val (keyword #f "remaining-arg-count")) (let* ((_o$1159 (jolt-count (jolt-get navigator (keyword #f "rest")))) (_o$1160 navigator)) (jolt-vector _o$1159 _o$1160)) (if #t (let* ((_o$1161 raw-val) (_o$1162 navigator)) (jolt-vector _o$1161 _o$1162)) jolt-nil))))) (real-param (jolt-nth G__51 0 jolt-nil)) (new-navigator (jolt-nth G__51 1 jolt-nil))) (let* ((_o$1167 (let* ((_o$1165 param) (_o$1166 (let* ((_o$1163 real-param) (_o$1164 offset)) (jolt-vector _o$1163 _o$1164)))) (jolt-vector _o$1165 _o$1166))) (_o$1168 new-navigator)) (jolt-vector _o$1167 _o$1168)))))))) realize-parameter) (let* ((_o$1169 (keyword #f "private")) (_o$1170 #t)) (jolt-hash-map _o$1169 _o$1170)))) + (def-var! "clojure.pprint" "realize-parameter" (letrec ((realize-parameter (lambda (G__40 navigator) (let fnrec906 ((G__40 G__40) (navigator navigator)) (let* ((G__41 G__40) (param (jolt-nth G__41 0 jolt-nil)) (G__42 (jolt-nth G__41 1 jolt-nil)) (raw-val (jolt-nth G__42 0 jolt-nil)) (offset (jolt-nth G__42 1 jolt-nil))) (let* ((G__43 (if (jolt-contains? (let* ((_o$907 (keyword #f "at")) (_o$908 (keyword #f "colon"))) (jolt-hash-set _o$907 _o$908)) param) (let* ((_o$909 raw-val) (_o$910 navigator)) (jolt-vector _o$909 _o$910)) (if (jolt= raw-val (keyword #f "parameter-from-args")) (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator) (if (jolt= raw-val (keyword #f "remaining-arg-count")) (let* ((_o$911 (jolt-count (jolt-get navigator (keyword #f "rest")))) (_o$912 navigator)) (jolt-vector _o$911 _o$912)) (if #t (let* ((_o$913 raw-val) (_o$914 navigator)) (jolt-vector _o$913 _o$914)) jolt-nil))))) (real-param (jolt-nth G__43 0 jolt-nil)) (new-navigator (jolt-nth G__43 1 jolt-nil))) (let* ((_o$919 (let* ((_o$917 param) (_o$918 (let* ((_o$915 real-param) (_o$916 offset)) (jolt-vector _o$915 _o$916)))) (jolt-vector _o$917 _o$918))) (_o$920 new-navigator)) (jolt-vector _o$919 _o$920)))))))) realize-parameter))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "realize-parameter-list" (letrec ((realize-parameter-list (lambda (parameter-map navigator) (let fnrec1171 ((parameter-map parameter-map) (navigator navigator)) (let* ((G__52 (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (var-deref "clojure.pprint" "realize-parameter") navigator parameter-map)) (pairs (jolt-nth G__52 0 jolt-nil)) (new-navigator (jolt-nth G__52 1 jolt-nil))) (let* ((_o$1172 (jolt-into (jolt-hash-map) pairs)) (_o$1173 new-navigator)) (jolt-vector _o$1172 _o$1173))))))) realize-parameter-list) (let* ((_o$1174 (keyword #f "private")) (_o$1175 #t)) (jolt-hash-map _o$1174 _o$1175)))) + (def-var! "clojure.pprint" "realize-parameter-list" (letrec ((realize-parameter-list (lambda (parameter-map navigator) (let fnrec921 ((parameter-map parameter-map) (navigator navigator)) (let* ((G__44 (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (var-deref "clojure.pprint" "realize-parameter") navigator parameter-map)) (pairs (jolt-nth G__44 0 jolt-nil)) (new-navigator (jolt-nth G__44 1 jolt-nil))) (let* ((_o$922 (jolt-into (jolt-hash-map) pairs)) (_o$923 new-navigator)) (jolt-vector _o$922 _o$923))))))) realize-parameter-list))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "opt-base-str")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "special-radix-markers" (let* ((_o$1176 2) (_o$1177 "#b") (_o$1178 8) (_o$1179 "#o") (_o$1180 16) (_o$1181 "#x")) (jolt-hash-map _o$1176 _o$1177 _o$1178 _o$1179 _o$1180 _o$1181)) (let* ((_o$1182 (keyword #f "private")) (_o$1183 #t)) (jolt-hash-map _o$1182 _o$1183)))) + (def-var-with-meta! "clojure.pprint" "special-radix-markers" (let* ((_o$924 2) (_o$925 "#b") (_o$926 8) (_o$927 "#o") (_o$928 16) (_o$929 "#x")) (jolt-hash-map _o$924 _o$925 _o$926 _o$927 _o$928 _o$929)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "format-simple-number" (letrec ((format-simple-number (lambda (n) (let fnrec1184 ((n n)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "integer?") n)) (if (jolt= (var-deref "clojure.pprint" "*print-base*") 10) (jolt-invoke (var-deref "clojure.core" "str") n (if (jolt-truthy? (var-deref "clojure.pprint" "*print-radix*")) "." jolt-nil)) (let* ((_a$1185 (var-deref "clojure.core" "str")) (_a$1186 (if (jolt-truthy? (var-deref "clojure.pprint" "*print-radix*")) (let* ((or__26__auto (jolt-get (var-deref "clojure.pprint" "special-radix-markers") (var-deref "clojure.pprint" "*print-base*")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "str") "#" (var-deref "clojure.pprint" "*print-base*") "r"))) jolt-nil)) (_a$1187 (jolt-invoke (var-deref "clojure.pprint" "opt-base-str") (var-deref "clojure.pprint" "*print-base*") n))) (jolt-invoke _a$1185 _a$1186 _a$1187))) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))) format-simple-number) (let* ((_o$1188 (keyword #f "private")) (_o$1189 #t)) (jolt-hash-map _o$1188 _o$1189)))) + (def-var! "clojure.pprint" "format-simple-number" (letrec ((format-simple-number (lambda (n) (let fnrec930 ((n n)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "integer?") n)) (if (jolt= (var-deref "clojure.pprint" "*print-base*") 10) (jolt-invoke (var-deref "clojure.core" "str") n (if (jolt-truthy? (var-deref "clojure.pprint" "*print-radix*")) "." jolt-nil)) (let* ((_a$931 (var-deref "clojure.core" "str")) (_a$932 (if (jolt-truthy? (var-deref "clojure.pprint" "*print-radix*")) (let* ((or__26__auto (jolt-get (var-deref "clojure.pprint" "special-radix-markers") (var-deref "clojure.pprint" "*print-base*")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "str") "#" (var-deref "clojure.pprint" "*print-base*") "r"))) jolt-nil)) (_a$933 (jolt-invoke (var-deref "clojure.pprint" "opt-base-str") (var-deref "clojure.pprint" "*print-base*") n))) (jolt-invoke _a$931 _a$932 _a$933))) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil)))))) format-simple-number))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "format-ascii" (letrec ((format-ascii (lambda (print-func params arg-navigator offsets) (let fnrec1190 ((print-func print-func) (params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__53 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__53 0 jolt-nil)) (arg-navigator (jolt-nth G__53 1 jolt-nil)) (base-output (let* ((or__26__auto (jolt-invoke (var-deref "clojure.pprint" "format-simple-number") arg))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke print-func arg)))) (base-width (jolt-count base-output)) (min-width (jolt-n+ base-width (jolt-get params (keyword #f "minpad")))) (width (if (jolt-n>= min-width (jolt-get params (keyword #f "mincol"))) min-width (jolt-n+ min-width (let* ((_a$1193 (jolt-n+ (let* ((_a$1191 (jolt-n- (jolt-get params (keyword #f "mincol")) min-width 1)) (_a$1192 (jolt-get params (keyword #f "colinc")))) (jolt-quot _a$1191 _a$1192)) 1)) (_a$1194 (jolt-get params (keyword #f "colinc")))) (jolt-n* _a$1193 _a$1194))))) (chars (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$1195 (var-deref "clojure.core" "repeat")) (_a$1196 (jolt-n- width base-width)) (_a$1197 (jolt-get params (keyword #f "padchar")))) (jolt-invoke _a$1195 _a$1196 _a$1197))))) (begin (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "str") chars base-output)) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "str") base-output chars))) arg-navigator)))))) format-ascii) (let* ((_o$1198 (keyword #f "private")) (_o$1199 #t)) (jolt-hash-map _o$1198 _o$1199)))) + (def-var! "clojure.pprint" "format-ascii" (letrec ((format-ascii (lambda (print-func params arg-navigator offsets) (let fnrec934 ((print-func print-func) (params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__45 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__45 0 jolt-nil)) (arg-navigator (jolt-nth G__45 1 jolt-nil)) (base-output (let* ((or__26__auto (jolt-invoke (var-deref "clojure.pprint" "format-simple-number") arg))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke print-func arg)))) (base-width (jolt-count base-output)) (min-width (+ base-width (jolt-get params (keyword #f "minpad")))) (width (if (>= min-width (jolt-get params (keyword #f "mincol"))) min-width (+ min-width (let* ((_a$937 (+ (let* ((_a$935 (- (jolt-get params (keyword #f "mincol")) min-width 1)) (_a$936 (jolt-get params (keyword #f "colinc")))) (quotient _a$935 _a$936)) 1)) (_a$938 (jolt-get params (keyword #f "colinc")))) (* _a$937 _a$938))))) (chars (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$939 (var-deref "clojure.core" "repeat")) (_a$940 (- width base-width)) (_a$941 (jolt-get params (keyword #f "padchar")))) (jolt-invoke _a$939 _a$940 _a$941))))) (begin (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "str") chars base-output)) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "str") base-output chars))) arg-navigator)))))) format-ascii))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "integral?" (letrec ((integral? (lambda (x) (let fnrec1200 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "integer?") x)) #t (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "float?") x)) (jolt= x (host-static-call "Math" "floor" x)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))) integral?) (let* ((_o$1201 (keyword #f "private")) (_o$1202 #t)) (jolt-hash-map _o$1201 _o$1202)))) + (def-var! "clojure.pprint" "integral?" (letrec ((integral? (lambda (x) (let fnrec942 ((x x)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "integer?") x)) #t (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "float?") x)) (jolt= x (host-static-call "Math" "floor" x)) (if (jolt-truthy? (keyword #f "else")) #f jolt-nil))))))) integral?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "remainders" (letrec ((remainders (lambda (base val) (let fnrec1203 ((base base) (val val)) (jolt-reverse (jolt-first (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (p__8_) (let fnrec1204 ((p__8_ p__8_)) (if (jolt-pos? p__8_) (let* ((_o$1205 (jolt-rem p__8_ base)) (_o$1206 (jolt-quot p__8_ base))) (jolt-vector _o$1205 _o$1206)) (let* ((_o$1207 jolt-nil) (_o$1208 jolt-nil)) (jolt-vector _o$1207 _o$1208))))) val))))))) remainders) (let* ((_o$1209 (keyword #f "private")) (_o$1210 #t)) (jolt-hash-map _o$1209 _o$1210)))) + (def-var! "clojure.pprint" "remainders" (letrec ((remainders (lambda (base val) (let fnrec943 ((base base) (val val)) (jolt-reverse (jolt-first (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (p__8_) (let fnrec944 ((p__8_ p__8_)) (if (jolt-pos? p__8_) (let* ((_o$945 (remainder p__8_ base)) (_o$946 (quotient p__8_ base))) (jolt-vector _o$945 _o$946)) (let* ((_o$947 jolt-nil) (_o$948 jolt-nil)) (jolt-vector _o$947 _o$948))))) val))))))) remainders))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "base-str" (letrec ((base-str (lambda (base val) (let fnrec1211 ((base base) (val val)) (if (jolt-zero? val) "0" (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$1215 (lambda (p__9_) (let fnrec1212 ((p__9_ p__9_)) (if (jolt-n< p__9_ 10) (jolt-invoke (var-deref "clojure.core" "char") (jolt-n+ (jolt-invoke (var-deref "clojure.pprint" "char-code") (integer->char 48)) p__9_)) (jolt-invoke (var-deref "clojure.core" "char") (let* ((_a$1213 (jolt-invoke (var-deref "clojure.pprint" "char-code") (integer->char 97))) (_a$1214 (jolt-n- p__9_ 10))) (jolt-n+ _a$1213 _a$1214))))))) (_a$1216 (jolt-invoke (var-deref "clojure.pprint" "remainders") base val))) (jolt-map _a$1215 _a$1216)))))))) base-str) (let* ((_o$1217 (keyword #f "private")) (_o$1218 #t)) (jolt-hash-map _o$1217 _o$1218)))) + (def-var! "clojure.pprint" "base-str" (letrec ((base-str (lambda (base val) (let fnrec949 ((base base) (val val)) (if (jolt-zero? val) "0" (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$953 (lambda (p__9_) (let fnrec950 ((p__9_ p__9_)) (if (< p__9_ 10) (jolt-invoke (var-deref "clojure.core" "char") (+ (jolt-invoke (var-deref "clojure.pprint" "char-code") (integer->char 48)) p__9_)) (jolt-invoke (var-deref "clojure.core" "char") (let* ((_a$951 (jolt-invoke (var-deref "clojure.pprint" "char-code") (integer->char 97))) (_a$952 (- p__9_ 10))) (+ _a$951 _a$952))))))) (_a$954 (jolt-invoke (var-deref "clojure.pprint" "remainders") base val))) (jolt-map _a$953 _a$954)))))))) base-str))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "opt-base-str" (letrec ((opt-base-str (lambda (base val) (let fnrec1219 ((base base) (val val)) (jolt-invoke (var-deref "clojure.pprint" "base-str") base val))))) opt-base-str) (let* ((_o$1220 (keyword #f "private")) (_o$1221 #t)) (jolt-hash-map _o$1220 _o$1221)))) + (def-var! "clojure.pprint" "opt-base-str" (letrec ((opt-base-str (lambda (base val) (let fnrec955 ((base base) (val val)) (jolt-invoke (var-deref "clojure.pprint" "base-str") base val))))) opt-base-str))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "group-by*" (letrec ((group-by* (lambda (unit lis) (let fnrec1222 ((unit unit) (lis lis)) (jolt-reverse (jolt-first (let* ((_a$1226 (var-deref "clojure.pprint" "consume")) (_a$1227 (lambda (x) (let fnrec1223 ((x x)) (let* ((_o$1224 (jolt-seq (jolt-reverse (jolt-take unit x)))) (_o$1225 (jolt-seq (jolt-drop unit x)))) (jolt-vector _o$1224 _o$1225))))) (_a$1228 (jolt-reverse lis))) (jolt-invoke _a$1226 _a$1227 _a$1228)))))))) group-by*) (let* ((_o$1229 (keyword #f "private")) (_o$1230 #t)) (jolt-hash-map _o$1229 _o$1230)))) + (def-var! "clojure.pprint" "group-by*" (letrec ((group-by* (lambda (unit lis) (let fnrec956 ((unit unit) (lis lis)) (jolt-reverse (jolt-first (let* ((_a$960 (var-deref "clojure.pprint" "consume")) (_a$961 (lambda (x) (let fnrec957 ((x x)) (let* ((_o$958 (jolt-seq (jolt-reverse (jolt-take unit x)))) (_o$959 (jolt-seq (jolt-drop unit x)))) (jolt-vector _o$958 _o$959))))) (_a$962 (jolt-reverse lis))) (jolt-invoke _a$960 _a$961 _a$962)))))))) group-by*))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "format-integer" (letrec ((format-integer (lambda (base params arg-navigator offsets) (let fnrec1231 ((base base) (params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__54 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__54 0 jolt-nil)) (arg-navigator (jolt-nth G__54 1 jolt-nil))) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "integral?") arg)) (let* ((neg (jolt-neg? arg)) (pos-arg (if (jolt-truthy? neg) (jolt-n- arg) arg)) (raw-str (jolt-invoke (var-deref "clojure.pprint" "opt-base-str") base pos-arg)) (group-str (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (let* ((groups (let* ((_a$1233 (lambda (p__10_) (let fnrec1232 ((p__10_ p__10_)) (jolt-apply (var-deref "clojure.core" "str") p__10_)))) (_a$1234 (jolt-invoke (var-deref "clojure.pprint" "group-by*") (jolt-get params (keyword #f "commainterval")) raw-str))) (jolt-map _a$1233 _a$1234))) (commas (let* ((_a$1235 (var-deref "clojure.core" "repeat")) (_a$1236 (jolt-count groups)) (_a$1237 (jolt-get params (keyword #f "commachar")))) (jolt-invoke _a$1235 _a$1236 _a$1237)))) (jolt-apply (var-deref "clojure.core" "str") (jolt-next (jolt-invoke (var-deref "clojure.core" "interleave") commas groups)))) raw-str)) (signed-str (if (jolt-truthy? neg) (jolt-invoke (var-deref "clojure.core" "str") "-" group-str) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (jolt-invoke (var-deref "clojure.core" "str") "+" group-str) (if #t group-str jolt-nil)))) (padded-str (if (let* ((_a$1238 (jolt-count signed-str)) (_a$1239 (jolt-get params (keyword #f "mincol")))) (jolt-n< _a$1238 _a$1239)) (jolt-invoke (var-deref "clojure.core" "str") (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$1242 (var-deref "clojure.core" "repeat")) (_a$1243 (let* ((_a$1240 (jolt-get params (keyword #f "mincol"))) (_a$1241 (jolt-count signed-str))) (jolt-n- _a$1240 _a$1241))) (_a$1244 (jolt-get params (keyword #f "padchar")))) (jolt-invoke _a$1242 _a$1243 _a$1244))) signed-str) signed-str))) (jolt-invoke (var-deref "clojure.pprint" "print") padded-str)) (let* ((_a$1255 (var-deref "clojure.pprint" "format-ascii")) (_a$1256 (var-deref "clojure.core" "print-str")) (_a$1257 (let* ((_o$1245 (keyword #f "mincol")) (_o$1246 (jolt-get params (keyword #f "mincol"))) (_o$1247 (keyword #f "colinc")) (_o$1248 1) (_o$1249 (keyword #f "minpad")) (_o$1250 0) (_o$1251 (keyword #f "padchar")) (_o$1252 (jolt-get params (keyword #f "padchar"))) (_o$1253 (keyword #f "at")) (_o$1254 #t)) (jolt-hash-map _o$1245 _o$1246 _o$1247 _o$1248 _o$1249 _o$1250 _o$1251 _o$1252 _o$1253 _o$1254))) (_a$1258 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-vector arg))) (_a$1259 jolt-nil)) (jolt-invoke _a$1255 _a$1256 _a$1257 _a$1258 _a$1259))) arg-navigator)))))) format-integer) (let* ((_o$1260 (keyword #f "private")) (_o$1261 #t)) (jolt-hash-map _o$1260 _o$1261)))) + (def-var! "clojure.pprint" "format-integer" (letrec ((format-integer (lambda (base params arg-navigator offsets) (let fnrec963 ((base base) (params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__46 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__46 0 jolt-nil)) (arg-navigator (jolt-nth G__46 1 jolt-nil))) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "integral?") arg)) (let* ((neg (jolt-neg? arg)) (pos-arg (if (jolt-truthy? neg) (- arg) arg)) (raw-str (jolt-invoke (var-deref "clojure.pprint" "opt-base-str") base pos-arg)) (group-str (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (let* ((groups (let* ((_a$965 (lambda (p__10_) (let fnrec964 ((p__10_ p__10_)) (jolt-apply (var-deref "clojure.core" "str") p__10_)))) (_a$966 (jolt-invoke (var-deref "clojure.pprint" "group-by*") (jolt-get params (keyword #f "commainterval")) raw-str))) (jolt-map _a$965 _a$966))) (commas (let* ((_a$967 (var-deref "clojure.core" "repeat")) (_a$968 (jolt-count groups)) (_a$969 (jolt-get params (keyword #f "commachar")))) (jolt-invoke _a$967 _a$968 _a$969)))) (jolt-apply (var-deref "clojure.core" "str") (jolt-next (jolt-invoke (var-deref "clojure.core" "interleave") commas groups)))) raw-str)) (signed-str (if (jolt-truthy? neg) (jolt-invoke (var-deref "clojure.core" "str") "-" group-str) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (jolt-invoke (var-deref "clojure.core" "str") "+" group-str) (if #t group-str jolt-nil)))) (padded-str (if (let* ((_a$970 (jolt-count signed-str)) (_a$971 (jolt-get params (keyword #f "mincol")))) (< _a$970 _a$971)) (jolt-invoke (var-deref "clojure.core" "str") (jolt-apply (var-deref "clojure.core" "str") (let* ((_a$974 (var-deref "clojure.core" "repeat")) (_a$975 (let* ((_a$972 (jolt-get params (keyword #f "mincol"))) (_a$973 (jolt-count signed-str))) (- _a$972 _a$973))) (_a$976 (jolt-get params (keyword #f "padchar")))) (jolt-invoke _a$974 _a$975 _a$976))) signed-str) signed-str))) (jolt-invoke (var-deref "clojure.pprint" "print") padded-str)) (let* ((_a$987 (var-deref "clojure.pprint" "format-ascii")) (_a$988 (var-deref "clojure.core" "print-str")) (_a$989 (let* ((_o$977 (keyword #f "mincol")) (_o$978 (jolt-get params (keyword #f "mincol"))) (_o$979 (keyword #f "colinc")) (_o$980 1) (_o$981 (keyword #f "minpad")) (_o$982 0) (_o$983 (keyword #f "padchar")) (_o$984 (jolt-get params (keyword #f "padchar"))) (_o$985 (keyword #f "at")) (_o$986 #t)) (jolt-hash-map _o$977 _o$978 _o$979 _o$980 _o$981 _o$982 _o$983 _o$984 _o$985 _o$986))) (_a$990 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-vector arg))) (_a$991 jolt-nil)) (jolt-invoke _a$987 _a$988 _a$989 _a$990 _a$991))) arg-navigator)))))) format-integer))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "abort?" (letrec ((abort? (lambda (context) (let fnrec1262 ((context context)) (let* ((token (jolt-first context))) (let* ((or__26__auto (jolt= (keyword #f "up-arrow") token))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= (keyword #f "colon-up-arrow") token)))))))) abort?) (let* ((_o$1263 (keyword #f "private")) (_o$1264 #t)) (jolt-hash-map _o$1263 _o$1264)))) + (def-var! "clojure.pprint" "abort?" (letrec ((abort? (lambda (context) (let fnrec992 ((context context)) (let* ((token (jolt-first context))) (let* ((or__26__auto (jolt= (keyword #f "up-arrow") token))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt= (keyword #f "colon-up-arrow") token)))))))) abort?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "execute-sub-format" (letrec ((execute-sub-format (lambda (format args base-args) (let fnrec1265 ((format format) (args args) (base-args base-args)) (jolt-invoke (var-deref "clojure.core" "second") (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (lambda (element context) (let fnrec1266 ((element element) (context context)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "abort?") context)) (let* ((_o$1267 jolt-nil) (_o$1268 context)) (jolt-vector _o$1267 _o$1268)) (let* ((G__55 (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") (jolt-get element (keyword #f "params")) context)) (params (jolt-nth G__55 0 jolt-nil)) (args (jolt-nth G__55 1 jolt-nil)) (G__56 (jolt-invoke (var-deref "clojure.pprint" "unzip-map") params)) (params (jolt-nth G__56 0 jolt-nil)) (offsets (jolt-nth G__56 1 jolt-nil)) (params (jolt-assoc params (keyword #f "base-args") base-args))) (let* ((_o$1274 jolt-nil) (_o$1275 (let* ((_a$1272 (jolt-get element (keyword #f "func"))) (_a$1273 (let* ((_o$1269 params) (_o$1270 args) (_o$1271 offsets)) (jolt-vector _o$1269 _o$1270 _o$1271)))) (jolt-apply _a$1272 _a$1273)))) (jolt-vector _o$1274 _o$1275)))))) args format)))))) execute-sub-format) (let* ((_o$1276 (keyword #f "private")) (_o$1277 #t)) (jolt-hash-map _o$1276 _o$1277)))) + (def-var! "clojure.pprint" "execute-sub-format" (letrec ((execute-sub-format (lambda (format args base-args) (let fnrec993 ((format format) (args args) (base-args base-args)) (jolt-invoke (var-deref "clojure.core" "second") (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (lambda (element context) (let fnrec994 ((element element) (context context)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "abort?") context)) (let* ((_o$995 jolt-nil) (_o$996 context)) (jolt-vector _o$995 _o$996)) (let* ((G__47 (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") (jolt-get element (keyword #f "params")) context)) (params (jolt-nth G__47 0 jolt-nil)) (args (jolt-nth G__47 1 jolt-nil)) (G__48 (jolt-invoke (var-deref "clojure.pprint" "unzip-map") params)) (params (jolt-nth G__48 0 jolt-nil)) (offsets (jolt-nth G__48 1 jolt-nil)) (params (jolt-assoc params (keyword #f "base-args") base-args))) (let* ((_o$1002 jolt-nil) (_o$1003 (let* ((_a$1000 (jolt-get element (keyword #f "func"))) (_a$1001 (let* ((_o$997 params) (_o$998 args) (_o$999 offsets)) (jolt-vector _o$997 _o$998 _o$999)))) (jolt-apply _a$1000 _a$1001)))) (jolt-vector _o$1002 _o$1003)))))) args format)))))) execute-sub-format))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "choice-conditional" (letrec ((choice-conditional (lambda (params arg-navigator offsets) (let fnrec1278 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((arg (jolt-get params (keyword #f "selector"))) (G__57 (if (jolt-truthy? arg) (let* ((_o$1279 arg) (_o$1280 arg-navigator)) (jolt-vector _o$1279 _o$1280)) (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator))) (arg (jolt-nth G__57 0 jolt-nil)) (navigator (jolt-nth G__57 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (let* ((or__26__auto (jolt-neg? arg))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n>= arg (jolt-count clauses)))) (jolt-first (jolt-get params (keyword #f "else"))) (jolt-nth clauses arg)))) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))) navigator)))))) choice-conditional) (let* ((_o$1281 (keyword #f "private")) (_o$1282 #t)) (jolt-hash-map _o$1281 _o$1282)))) + (def-var! "clojure.pprint" "choice-conditional" (letrec ((choice-conditional (lambda (params arg-navigator offsets) (let fnrec1004 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((arg (jolt-get params (keyword #f "selector"))) (G__49 (if (jolt-truthy? arg) (let* ((_o$1005 arg) (_o$1006 arg-navigator)) (jolt-vector _o$1005 _o$1006)) (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator))) (arg (jolt-nth G__49 0 jolt-nil)) (navigator (jolt-nth G__49 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (jolt-truthy? (let* ((or__26__auto (jolt-neg? arg))) (if (jolt-truthy? or__26__auto) or__26__auto (>= arg (jolt-count clauses))))) (jolt-first (jolt-get params (keyword #f "else"))) (jolt-nth clauses arg)))) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))) navigator)))))) choice-conditional))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "boolean-conditional" (letrec ((boolean-conditional (lambda (params arg-navigator offsets) (let fnrec1283 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__58 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__58 0 jolt-nil)) (navigator (jolt-nth G__58 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (jolt-truthy? arg) (jolt-invoke (var-deref "clojure.core" "second") clauses) (jolt-first clauses)))) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))) navigator)))))) boolean-conditional) (let* ((_o$1284 (keyword #f "private")) (_o$1285 #t)) (jolt-hash-map _o$1284 _o$1285)))) + (def-var! "clojure.pprint" "boolean-conditional" (letrec ((boolean-conditional (lambda (params arg-navigator offsets) (let fnrec1007 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__50 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__50 0 jolt-nil)) (navigator (jolt-nth G__50 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (jolt-truthy? arg) (jolt-invoke (var-deref "clojure.core" "second") clauses) (jolt-first clauses)))) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))) navigator)))))) boolean-conditional))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "check-arg-conditional" (letrec ((check-arg-conditional (lambda (params arg-navigator offsets) (let fnrec1286 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__59 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__59 0 jolt-nil)) (navigator (jolt-nth G__59 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (jolt-truthy? arg) (jolt-first clauses) jolt-nil))) (if (jolt-truthy? arg) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause arg-navigator (jolt-get params (keyword #f "base-args"))) arg-navigator) navigator)))))) check-arg-conditional) (let* ((_o$1287 (keyword #f "private")) (_o$1288 #t)) (jolt-hash-map _o$1287 _o$1288)))) + (def-var! "clojure.pprint" "check-arg-conditional" (letrec ((check-arg-conditional (lambda (params arg-navigator offsets) (let fnrec1008 ((params params) (arg-navigator arg-navigator) (offsets offsets)) (let* ((G__51 (jolt-invoke (var-deref "clojure.pprint" "next-arg") arg-navigator)) (arg (jolt-nth G__51 0 jolt-nil)) (navigator (jolt-nth G__51 1 jolt-nil)) (clauses (jolt-get params (keyword #f "clauses"))) (clause (if (jolt-truthy? arg) (jolt-first clauses) jolt-nil))) (if (jolt-truthy? arg) (if (jolt-truthy? clause) (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause arg-navigator (jolt-get params (keyword #f "base-args"))) arg-navigator) navigator)))))) check-arg-conditional))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "iterate-sublist" (letrec ((iterate-sublist (lambda (params navigator offsets) (let fnrec1289 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__60 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1290 param-clause) (_o$1291 navigator)) (jolt-vector _o$1290 _o$1291)))) (clause (jolt-nth G__60 0 jolt-nil)) (navigator (jolt-nth G__60 1 jolt-nil)) (G__61 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg-list (jolt-nth G__61 0 jolt-nil)) (navigator (jolt-nth G__61 1 jolt-nil)) (args (jolt-invoke (var-deref "clojure.pprint" "init-navigator") arg-list))) (let* ((count 0) (args args) (last-pos -1)) (let loop1292 ((count count) (args args) (last-pos last-pos)) (begin (if (let* ((and__25__auto (jolt-not max-count))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (jolt-get args (keyword #f "pos")) last-pos))) (if (jolt-truthy? and__25__auto) (jolt-n> count 1) and__25__auto)) and__25__auto)) (jolt-throw (host-new "Exception" "~{ construct not consuming any arguments: Infinite loop!")) jolt-nil) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get args (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (jolt-n>= count max-count) and__25__auto))))) navigator (let* ((iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause args (jolt-get params (keyword #f "base-args"))))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) navigator (let* ((_a$1293 (jolt-inc count)) (_a$1294 iter-result) (_a$1295 (jolt-get args (keyword #f "pos")))) (loop1292 _a$1293 _a$1294 _a$1295))))))))))))) iterate-sublist) (let* ((_o$1296 (keyword #f "private")) (_o$1297 #t)) (jolt-hash-map _o$1296 _o$1297)))) + (def-var! "clojure.pprint" "iterate-sublist" (letrec ((iterate-sublist (lambda (params navigator offsets) (let fnrec1009 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__52 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1010 param-clause) (_o$1011 navigator)) (jolt-vector _o$1010 _o$1011)))) (clause (jolt-nth G__52 0 jolt-nil)) (navigator (jolt-nth G__52 1 jolt-nil)) (G__53 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg-list (jolt-nth G__53 0 jolt-nil)) (navigator (jolt-nth G__53 1 jolt-nil)) (args (jolt-invoke (var-deref "clojure.pprint" "init-navigator") arg-list))) (let* ((count 0) (args args) (last-pos -1)) (let loop1012 ((count count) (args args) (last-pos last-pos)) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-not max-count))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (jolt-get args (keyword #f "pos")) last-pos))) (if (jolt-truthy? and__25__auto) (> count 1) and__25__auto)) and__25__auto))) (jolt-throw (host-new "Exception" "~{ construct not consuming any arguments: Infinite loop!")) jolt-nil) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get args (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (>= count max-count) and__25__auto))))) navigator (let* ((iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause args (jolt-get params (keyword #f "base-args"))))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) navigator (let* ((_a$1013 (jolt-inc count)) (_a$1014 iter-result) (_a$1015 (jolt-get args (keyword #f "pos")))) (loop1012 _a$1013 _a$1014 _a$1015))))))))))))) iterate-sublist))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "iterate-list-of-sublists" (letrec ((iterate-list-of-sublists (lambda (params navigator offsets) (let fnrec1298 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__62 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1299 param-clause) (_o$1300 navigator)) (jolt-vector _o$1299 _o$1300)))) (clause (jolt-nth G__62 0 jolt-nil)) (navigator (jolt-nth G__62 1 jolt-nil)) (G__63 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg-list (jolt-nth G__63 0 jolt-nil)) (navigator (jolt-nth G__63 1 jolt-nil))) (let* ((count 0) (arg-list arg-list)) (let loop1301 ((count count) (arg-list arg-list)) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? arg-list))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (jolt-n>= count max-count) and__25__auto))))) navigator (let* ((iter-result (let* ((_a$1302 (var-deref "clojure.pprint" "execute-sub-format")) (_a$1303 clause) (_a$1304 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-first arg-list))) (_a$1305 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-next arg-list)))) (jolt-invoke _a$1302 _a$1303 _a$1304 _a$1305)))) (if (jolt= (keyword #f "colon-up-arrow") (jolt-first iter-result)) navigator (let* ((_a$1306 (jolt-inc count)) (_a$1307 (jolt-next arg-list))) (loop1301 _a$1306 _a$1307)))))))))))) iterate-list-of-sublists) (let* ((_o$1308 (keyword #f "private")) (_o$1309 #t)) (jolt-hash-map _o$1308 _o$1309)))) + (def-var! "clojure.pprint" "iterate-list-of-sublists" (letrec ((iterate-list-of-sublists (lambda (params navigator offsets) (let fnrec1016 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__54 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1017 param-clause) (_o$1018 navigator)) (jolt-vector _o$1017 _o$1018)))) (clause (jolt-nth G__54 0 jolt-nil)) (navigator (jolt-nth G__54 1 jolt-nil)) (G__55 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg-list (jolt-nth G__55 0 jolt-nil)) (navigator (jolt-nth G__55 1 jolt-nil))) (let* ((count 0) (arg-list arg-list)) (let loop1019 ((count count) (arg-list arg-list)) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? arg-list))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (>= count max-count) and__25__auto))))) navigator (let* ((iter-result (let* ((_a$1020 (var-deref "clojure.pprint" "execute-sub-format")) (_a$1021 clause) (_a$1022 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-first arg-list))) (_a$1023 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") (jolt-next arg-list)))) (jolt-invoke _a$1020 _a$1021 _a$1022 _a$1023)))) (if (jolt= (keyword #f "colon-up-arrow") (jolt-first iter-result)) navigator (let* ((_a$1024 (jolt-inc count)) (_a$1025 (jolt-next arg-list))) (loop1019 _a$1024 _a$1025)))))))))))) iterate-list-of-sublists))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "iterate-main-list" (letrec ((iterate-main-list (lambda (params navigator offsets) (let fnrec1310 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__64 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1311 param-clause) (_o$1312 navigator)) (jolt-vector _o$1311 _o$1312)))) (clause (jolt-nth G__64 0 jolt-nil)) (navigator (jolt-nth G__64 1 jolt-nil))) (let* ((count 0) (navigator navigator) (last-pos -1)) (let loop1313 ((count count) (navigator navigator) (last-pos last-pos)) (begin (if (let* ((and__25__auto (jolt-not max-count))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (jolt-get navigator (keyword #f "pos")) last-pos))) (if (jolt-truthy? and__25__auto) (jolt-n> count 1) and__25__auto)) and__25__auto)) (jolt-throw (host-new "Exception" "~@{ construct not consuming any arguments: Infinite loop!")) jolt-nil) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get navigator (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (jolt-n>= count max-count) and__25__auto))))) navigator (let* ((iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) (jolt-invoke (var-deref "clojure.core" "second") iter-result) (let* ((_a$1314 (jolt-inc count)) (_a$1315 iter-result) (_a$1316 (jolt-get navigator (keyword #f "pos")))) (loop1313 _a$1314 _a$1315 _a$1316))))))))))))) iterate-main-list) (let* ((_o$1317 (keyword #f "private")) (_o$1318 #t)) (jolt-hash-map _o$1317 _o$1318)))) + (def-var! "clojure.pprint" "iterate-main-list" (letrec ((iterate-main-list (lambda (params navigator offsets) (let fnrec1026 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__56 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1027 param-clause) (_o$1028 navigator)) (jolt-vector _o$1027 _o$1028)))) (clause (jolt-nth G__56 0 jolt-nil)) (navigator (jolt-nth G__56 1 jolt-nil))) (let* ((count 0) (navigator navigator) (last-pos -1)) (let loop1029 ((count count) (navigator navigator) (last-pos last-pos)) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-not max-count))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt= (jolt-get navigator (keyword #f "pos")) last-pos))) (if (jolt-truthy? and__25__auto) (> count 1) and__25__auto)) and__25__auto))) (jolt-throw (host-new "Exception" "~@{ construct not consuming any arguments: Infinite loop!")) jolt-nil) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get navigator (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (>= count max-count) and__25__auto))))) navigator (let* ((iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator (jolt-get params (keyword #f "base-args"))))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) (jolt-invoke (var-deref "clojure.core" "second") iter-result) (let* ((_a$1030 (jolt-inc count)) (_a$1031 iter-result) (_a$1032 (jolt-get navigator (keyword #f "pos")))) (loop1029 _a$1030 _a$1031 _a$1032))))))))))))) iterate-main-list))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "iterate-main-sublists" (letrec ((iterate-main-sublists (lambda (params navigator offsets) (let fnrec1319 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__65 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1320 param-clause) (_o$1321 navigator)) (jolt-vector _o$1320 _o$1321)))) (clause (jolt-nth G__65 0 jolt-nil)) (navigator (jolt-nth G__65 1 jolt-nil))) (let* ((count 0) (navigator navigator)) (let loop1322 ((count count) (navigator navigator)) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get navigator (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-n> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (jolt-n>= count max-count) and__25__auto))))) navigator (let* ((G__66 (jolt-invoke (var-deref "clojure.pprint" "next-arg-or-nil") navigator)) (sublist (jolt-nth G__66 0 jolt-nil)) (navigator (jolt-nth G__66 1 jolt-nil)) (iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause (jolt-invoke (var-deref "clojure.pprint" "init-navigator") sublist) navigator))) (if (jolt= (keyword #f "colon-up-arrow") (jolt-first iter-result)) navigator (loop1322 (jolt-inc count) navigator))))))))))) iterate-main-sublists) (let* ((_o$1323 (keyword #f "private")) (_o$1324 #t)) (jolt-hash-map _o$1323 _o$1324)))) + (def-var! "clojure.pprint" "iterate-main-sublists" (letrec ((iterate-main-sublists (lambda (params navigator offsets) (let fnrec1033 ((params params) (navigator navigator) (offsets offsets)) (let* ((max-count (jolt-get params (keyword #f "max-iterations"))) (param-clause (jolt-first (jolt-get params (keyword #f "clauses")))) (G__57 (if (jolt-empty? param-clause) (jolt-invoke (var-deref "clojure.pprint" "get-format-arg") navigator) (let* ((_o$1034 param-clause) (_o$1035 navigator)) (jolt-vector _o$1034 _o$1035)))) (clause (jolt-nth G__57 0 jolt-nil)) (navigator (jolt-nth G__57 1 jolt-nil))) (let* ((count 0) (navigator navigator)) (let loop1036 ((count count) (navigator navigator)) (if (jolt-truthy? (let* ((or__26__auto (let* ((and__25__auto (jolt-empty? (jolt-get navigator (keyword #f "rest"))))) (if (jolt-truthy? and__25__auto) (let* ((or__26__auto (jolt-not (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))))) (if (jolt-truthy? or__26__auto) or__26__auto (> count 0))) and__25__auto)))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto max-count)) (if (jolt-truthy? and__25__auto) (>= count max-count) and__25__auto))))) navigator (let* ((G__58 (jolt-invoke (var-deref "clojure.pprint" "next-arg-or-nil") navigator)) (sublist (jolt-nth G__58 0 jolt-nil)) (navigator (jolt-nth G__58 1 jolt-nil)) (iter-result (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause (jolt-invoke (var-deref "clojure.pprint" "init-navigator") sublist) navigator))) (if (jolt= (keyword #f "colon-up-arrow") (jolt-first iter-result)) navigator (loop1036 (jolt-inc count) navigator))))))))))) iterate-main-sublists))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "format-logical-block")) (guard (e (#t #f)) (declare-var! "clojure.pprint" "justify-clauses")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "logical-block-or-justify" (letrec ((logical-block-or-justify (lambda (params navigator offsets) (let fnrec1325 ((params params) (navigator navigator) (offsets offsets)) (if (jolt-truthy? (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))) (jolt-invoke (var-deref "clojure.pprint" "format-logical-block") params navigator offsets) (jolt-invoke (var-deref "clojure.pprint" "justify-clauses") params navigator offsets)))))) logical-block-or-justify) (let* ((_o$1326 (keyword #f "private")) (_o$1327 #t)) (jolt-hash-map _o$1326 _o$1327)))) + (def-var! "clojure.pprint" "logical-block-or-justify" (letrec ((logical-block-or-justify (lambda (params navigator offsets) (let fnrec1037 ((params params) (navigator navigator) (offsets offsets)) (if (jolt-truthy? (jolt-get (jolt-get params (keyword #f "right-params")) (keyword #f "colon"))) (jolt-invoke (var-deref "clojure.pprint" "format-logical-block") params navigator offsets) (jolt-invoke (var-deref "clojure.pprint" "justify-clauses") params navigator offsets)))))) logical-block-or-justify))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "render-clauses" (letrec ((render-clauses (lambda (clauses navigator base-navigator) (let fnrec1328 ((clauses clauses) (navigator navigator) (base-navigator base-navigator)) (let* ((clauses clauses) (acc (jolt-vector)) (navigator navigator)) (let loop1329 ((clauses clauses) (acc acc) (navigator navigator)) (if (jolt-empty? clauses) (let* ((_o$1330 acc) (_o$1331 navigator)) (jolt-vector _o$1330 _o$1331)) (let* ((clause (jolt-first clauses)) (G__67 (let* ((sb (host-new "StringBuilder"))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (let* ((_o$1332 (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator base-navigator)) (_o$1333 (jolt-invoke (var-deref "clojure.core" "str") sb))) (jolt-vector _o$1332 _o$1333))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (iter-result (jolt-nth G__67 0 jolt-nil)) (result-str (jolt-nth G__67 1 jolt-nil))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) (let* ((_o$1334 acc) (_o$1335 (jolt-invoke (var-deref "clojure.core" "second") iter-result))) (jolt-vector _o$1334 _o$1335)) (let* ((_a$1336 (jolt-next clauses)) (_a$1337 (jolt-conj acc result-str)) (_a$1338 iter-result)) (loop1329 _a$1336 _a$1337 _a$1338))))))))))) render-clauses) (let* ((_o$1339 (keyword #f "private")) (_o$1340 #t)) (jolt-hash-map _o$1339 _o$1340)))) + (def-var! "clojure.pprint" "render-clauses" (letrec ((render-clauses (lambda (clauses navigator base-navigator) (let fnrec1038 ((clauses clauses) (navigator navigator) (base-navigator base-navigator)) (let* ((clauses clauses) (acc (jolt-vector)) (navigator navigator)) (let loop1039 ((clauses clauses) (acc acc) (navigator navigator)) (if (jolt-empty? clauses) (let* ((_o$1040 acc) (_o$1041 navigator)) (jolt-vector _o$1040 _o$1041)) (let* ((clause (jolt-first clauses)) (G__59 (let* ((sb (host-new "StringBuilder"))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb)))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (let* ((_o$1042 (jolt-invoke (var-deref "clojure.pprint" "execute-sub-format") clause navigator base-navigator)) (_o$1043 (jolt-invoke (var-deref "clojure.core" "str") sb))) (jolt-vector _o$1042 _o$1043))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))) (iter-result (jolt-nth G__59 0 jolt-nil)) (result-str (jolt-nth G__59 1 jolt-nil))) (if (jolt= (keyword #f "up-arrow") (jolt-first iter-result)) (let* ((_o$1044 acc) (_o$1045 (jolt-invoke (var-deref "clojure.core" "second") iter-result))) (jolt-vector _o$1044 _o$1045)) (let* ((_a$1046 (jolt-next clauses)) (_a$1047 (jolt-conj acc result-str)) (_a$1048 iter-result)) (loop1039 _a$1046 _a$1047 _a$1048))))))))))) render-clauses))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "justify-clauses" (letrec ((justify-clauses (lambda (params navigator offsets) (let fnrec1341 ((params params) (navigator navigator) (offsets offsets)) (let* ((G__68 (let* ((temp__27__auto (jolt-get params (keyword #f "else")))) (if (jolt-truthy? temp__27__auto) (let* ((_else temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "render-clauses") _else navigator (jolt-get params (keyword #f "base-args")))) jolt-nil))) (G__69 (jolt-nth G__68 0 jolt-nil)) (eol-str (jolt-nth G__69 0 jolt-nil)) (new-navigator (jolt-nth G__68 1 jolt-nil)) (navigator (let* ((or__26__auto new-navigator)) (if (jolt-truthy? or__26__auto) or__26__auto navigator))) (G__70 (let* ((temp__27__auto (jolt-get params (keyword #f "else-params")))) (if (jolt-truthy? temp__27__auto) (let* ((p temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") p navigator)) jolt-nil))) (else-params (jolt-nth G__70 0 jolt-nil)) (new-navigator (jolt-nth G__70 1 jolt-nil)) (navigator (let* ((or__26__auto new-navigator)) (if (jolt-truthy? or__26__auto) or__26__auto navigator))) (min-remaining (let* ((or__26__auto (jolt-first (jolt-get else-params (keyword #f "min-remaining"))))) (if (jolt-truthy? or__26__auto) or__26__auto 0))) (max-columns (let* ((or__26__auto (jolt-first (jolt-get else-params (keyword #f "max-columns"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (var-deref "clojure.core" "*out*"))))) (clauses (jolt-get params (keyword #f "clauses"))) (G__71 (jolt-invoke (var-deref "clojure.pprint" "render-clauses") clauses navigator (jolt-get params (keyword #f "base-args")))) (strs (jolt-nth G__71 0 jolt-nil)) (navigator (jolt-nth G__71 1 jolt-nil)) (slots (jolt-n-max 1 (let* ((_a$1342 (jolt-dec (jolt-count strs))) (_a$1343 (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) 1 0)) (_a$1344 (if (jolt-truthy? (jolt-get params (keyword #f "at"))) 1 0))) (jolt-n+ _a$1342 _a$1343 _a$1344)))) (chars (jolt-reduce jolt-add (jolt-map jolt-count strs))) (mincol (jolt-get params (keyword #f "mincol"))) (minpad (jolt-get params (keyword #f "minpad"))) (colinc (jolt-get params (keyword #f "colinc"))) (minout (jolt-n+ chars (jolt-n* slots minpad))) (result-columns (if (jolt-n<= minout mincol) mincol (jolt-n+ mincol (jolt-n* colinc (jolt-n+ 1 (jolt-quot (jolt-n- minout mincol 1) colinc)))))) (total-pad (jolt-n- result-columns chars)) (pad (jolt-n-max minpad (jolt-quot total-pad slots))) (extra-pad (jolt-n- total-pad (jolt-n* pad slots))) (pad-str (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") pad (jolt-get params (keyword #f "padchar")))))) (begin (if (jolt-truthy? (let* ((and__25__auto eol-str)) (if (jolt-truthy? and__25__auto) (jolt-n> (jolt-n+ (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))) min-remaining result-columns) max-columns) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "print") eol-str) jolt-nil) (let* ((slots slots) (extra-pad extra-pad) (strs strs) (pad-only (let* ((or__26__auto (jolt-get params (keyword #f "colon")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt= (jolt-count strs) 1))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get params (keyword #f "at"))) and__25__auto)))))) (let loop1345 ((slots slots) (extra-pad extra-pad) (strs strs) (pad-only pad-only)) (if (jolt-truthy? (jolt-seq strs)) (begin (jolt-invoke (var-deref "clojure.pprint" "print") (let* ((_a$1346 (var-deref "clojure.core" "str")) (_a$1347 (if (jolt-not pad-only) (jolt-first strs) jolt-nil)) (_a$1348 (if (jolt-truthy? (let* ((or__26__auto pad-only)) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-next strs))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get params (keyword #f "at"))))))) pad-str jolt-nil)) (_a$1349 (if (jolt-pos? extra-pad) (jolt-get params (keyword #f "padchar")) jolt-nil))) (jolt-invoke _a$1346 _a$1347 _a$1348 _a$1349))) (let* ((_a$1350 (jolt-dec slots)) (_a$1351 (jolt-dec extra-pad)) (_a$1352 (if (jolt-truthy? pad-only) strs (jolt-next strs))) (_a$1353 #f)) (loop1345 _a$1350 _a$1351 _a$1352 _a$1353))) jolt-nil))) navigator)))))) justify-clauses) (let* ((_o$1354 (keyword #f "private")) (_o$1355 #t)) (jolt-hash-map _o$1354 _o$1355)))) + (def-var! "clojure.pprint" "justify-clauses" (letrec ((justify-clauses (lambda (params navigator offsets) (let fnrec1049 ((params params) (navigator navigator) (offsets offsets)) (let* ((G__60 (let* ((temp__27__auto (jolt-get params (keyword #f "else")))) (if (jolt-truthy? temp__27__auto) (let* ((_else temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "render-clauses") _else navigator (jolt-get params (keyword #f "base-args")))) jolt-nil))) (G__61 (jolt-nth G__60 0 jolt-nil)) (eol-str (jolt-nth G__61 0 jolt-nil)) (new-navigator (jolt-nth G__60 1 jolt-nil)) (navigator (let* ((or__26__auto new-navigator)) (if (jolt-truthy? or__26__auto) or__26__auto navigator))) (G__62 (let* ((temp__27__auto (jolt-get params (keyword #f "else-params")))) (if (jolt-truthy? temp__27__auto) (let* ((p temp__27__auto)) (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") p navigator)) jolt-nil))) (else-params (jolt-nth G__62 0 jolt-nil)) (new-navigator (jolt-nth G__62 1 jolt-nil)) (navigator (let* ((or__26__auto new-navigator)) (if (jolt-truthy? or__26__auto) or__26__auto navigator))) (min-remaining (let* ((or__26__auto (jolt-first (jolt-get else-params (keyword #f "min-remaining"))))) (if (jolt-truthy? or__26__auto) or__26__auto 0))) (max-columns (let* ((or__26__auto (jolt-first (jolt-get else-params (keyword #f "max-columns"))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.pprint" "get-max-column") (var-deref "clojure.core" "*out*"))))) (clauses (jolt-get params (keyword #f "clauses"))) (G__63 (jolt-invoke (var-deref "clojure.pprint" "render-clauses") clauses navigator (jolt-get params (keyword #f "base-args")))) (strs (jolt-nth G__63 0 jolt-nil)) (navigator (jolt-nth G__63 1 jolt-nil)) (slots (max 1 (let* ((_a$1050 (jolt-dec (jolt-count strs))) (_a$1051 (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) 1 0)) (_a$1052 (if (jolt-truthy? (jolt-get params (keyword #f "at"))) 1 0))) (+ _a$1050 _a$1051 _a$1052)))) (chars (jolt-reduce jolt-add (jolt-map jolt-count strs))) (mincol (jolt-get params (keyword #f "mincol"))) (minpad (jolt-get params (keyword #f "minpad"))) (colinc (jolt-get params (keyword #f "colinc"))) (minout (+ chars (* slots minpad))) (result-columns (if (<= minout mincol) mincol (+ mincol (* colinc (+ 1 (quotient (- minout mincol 1) colinc)))))) (total-pad (- result-columns chars)) (pad (max minpad (quotient total-pad slots))) (extra-pad (- total-pad (* pad slots))) (pad-str (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") pad (jolt-get params (keyword #f "padchar")))))) (begin (if (jolt-truthy? (let* ((and__25__auto eol-str)) (if (jolt-truthy? and__25__auto) (> (+ (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))) min-remaining result-columns) max-columns) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "print") eol-str) jolt-nil) (let* ((slots slots) (extra-pad extra-pad) (strs strs) (pad-only (let* ((or__26__auto (jolt-get params (keyword #f "colon")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((and__25__auto (jolt= (jolt-count strs) 1))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get params (keyword #f "at"))) and__25__auto)))))) (let loop1053 ((slots slots) (extra-pad extra-pad) (strs strs) (pad-only pad-only)) (if (jolt-truthy? (jolt-seq strs)) (begin (jolt-invoke (var-deref "clojure.pprint" "print") (let* ((_a$1054 (var-deref "clojure.core" "str")) (_a$1055 (if (jolt-not pad-only) (jolt-first strs) jolt-nil)) (_a$1056 (if (jolt-truthy? (let* ((or__26__auto pad-only)) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-next strs))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get params (keyword #f "at"))))))) pad-str jolt-nil)) (_a$1057 (if (jolt-pos? extra-pad) (jolt-get params (keyword #f "padchar")) jolt-nil))) (jolt-invoke _a$1054 _a$1055 _a$1056 _a$1057))) (let* ((_a$1058 (jolt-dec slots)) (_a$1059 (jolt-dec extra-pad)) (_a$1060 (if (jolt-truthy? pad-only) strs (jolt-next strs))) (_a$1061 #f)) (loop1053 _a$1058 _a$1059 _a$1060 _a$1061))) jolt-nil))) navigator)))))) justify-clauses))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "get-pretty-writer" (letrec ((get-pretty-writer (lambda (writer) (let fnrec1356 ((writer writer)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") writer)) writer (jolt-invoke (var-deref "clojure.pprint" "pretty-writer") writer (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*"))))))) get-pretty-writer) (let* ((_o$1357 (keyword #f "doc")) (_o$1358 "Returns writer wrapped in a pretty writer unless it already is one.")) (jolt-hash-map _o$1357 _o$1358)))) + (def-var! "clojure.pprint" "get-pretty-writer" (letrec ((get-pretty-writer (lambda (writer) (let fnrec1062 ((writer writer)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") writer)) writer (jolt-invoke (var-deref "clojure.pprint" "pretty-writer") writer (var-deref "clojure.pprint" "*print-right-margin*") (var-deref "clojure.pprint" "*print-miser-width*"))))))) get-pretty-writer))) (guard (e (#t #f)) - (def-var! "clojure.pprint" "fresh-line" (letrec ((fresh-line (lambda () (let fnrec1359 () (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "instance-check") (jolt-symbol #f "PrettyWriter") (var-deref "clojure.core" "*out*"))) (if (jolt-not (jolt= 0 (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))))) (jolt-invoke (var-deref "clojure.pprint" "prn")) jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "prn"))))))) fresh-line))) + (def-var! "clojure.pprint" "fresh-line" (letrec ((fresh-line (lambda () (let fnrec1063 () (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "instance-check") (jolt-symbol #f "PrettyWriter") (var-deref "clojure.core" "*out*"))) (if (jolt-not (jolt= 0 (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))))) (jolt-invoke (var-deref "clojure.pprint" "prn")) jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "prn"))))))) fresh-line))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "absolute-tabulation" (letrec ((absolute-tabulation (lambda (params navigator offsets) (let fnrec1360 ((params params) (navigator navigator) (offsets offsets)) (begin (let* ((colnum (jolt-get params (keyword #f "colnum"))) (colinc (jolt-get params (keyword #f "colinc"))) (current (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base")))) (space-count (if (jolt-n< current colnum) (jolt-n- colnum current) (if (jolt= colinc 0) 0 (if (jolt-truthy? (keyword #f "else")) (jolt-n- colinc (jolt-rem (jolt-n- current colnum) colinc)) jolt-nil))))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") space-count (integer->char 32))))) navigator))))) absolute-tabulation) (let* ((_o$1361 (keyword #f "private")) (_o$1362 #t)) (jolt-hash-map _o$1361 _o$1362)))) + (def-var! "clojure.pprint" "absolute-tabulation" (letrec ((absolute-tabulation (lambda (params navigator offsets) (let fnrec1064 ((params params) (navigator navigator) (offsets offsets)) (begin (let* ((colnum (jolt-get params (keyword #f "colnum"))) (colinc (jolt-get params (keyword #f "colinc"))) (current (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base")))) (space-count (if (< current colnum) (- colnum current) (if (jolt= colinc 0) 0 (if (jolt-truthy? (keyword #f "else")) (- colinc (remainder (- current colnum) colinc)) jolt-nil))))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") space-count (integer->char 32))))) navigator))))) absolute-tabulation))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "relative-tabulation" (letrec ((relative-tabulation (lambda (params navigator offsets) (let fnrec1363 ((params params) (navigator navigator) (offsets offsets)) (begin (let* ((colrel (jolt-get params (keyword #f "colnum"))) (colinc (jolt-get params (keyword #f "colinc"))) (start-col (jolt-n+ colrel (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))))) (offset (if (jolt-pos? colinc) (jolt-rem start-col colinc) 0)) (space-count (jolt-n+ colrel (if (jolt= 0 offset) 0 (jolt-n- colinc offset))))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") space-count (integer->char 32))))) navigator))))) relative-tabulation) (let* ((_o$1364 (keyword #f "private")) (_o$1365 #t)) (jolt-hash-map _o$1364 _o$1365)))) + (def-var! "clojure.pprint" "relative-tabulation" (letrec ((relative-tabulation (lambda (params navigator offsets) (let fnrec1065 ((params params) (navigator navigator) (offsets offsets)) (begin (let* ((colrel (jolt-get params (keyword #f "colnum"))) (colinc (jolt-get params (keyword #f "colinc"))) (start-col (+ colrel (jolt-invoke (var-deref "clojure.pprint" "get-column") (jolt-get (jolt-invoke (var-deref "clojure.core" "deref") (record-method-dispatch (var-deref "clojure.core" "*out*") "-fields" (jolt-vector))) (keyword #f "base"))))) (offset (if (jolt-pos? colinc) (remainder start-col colinc) 0)) (space-count (+ colrel (if (jolt= 0 offset) 0 (- colinc offset))))) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") space-count (integer->char 32))))) navigator))))) relative-tabulation))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "format-logical-block" (letrec ((format-logical-block (lambda (params navigator offsets) (let fnrec1366 ((params params) (navigator navigator) (offsets offsets)) (let* ((clauses (jolt-get params (keyword #f "clauses"))) (clause-count (jolt-count clauses)) (prefix (if (jolt-n> clause-count 1) (jolt-get (jolt-get (jolt-first (jolt-first clauses)) (keyword #f "params")) (keyword #f "string")) (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) "(" jolt-nil))) (body (jolt-nth clauses (if (jolt-n> clause-count 1) 1 0))) (suffix (if (jolt-n> clause-count 2) (jolt-get (jolt-get (jolt-first (jolt-nth clauses 2)) (keyword #f "params")) (keyword #f "string")) (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) ")" jolt-nil))) (G__72 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg (jolt-nth G__72 0 jolt-nil)) (navigator (jolt-nth G__72 1 jolt-nil))) (begin (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") prefix jolt-nil suffix) (let* ((_a$1367 (var-deref "clojure.pprint" "execute-sub-format")) (_a$1368 body) (_a$1369 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") arg)) (_a$1370 (jolt-get params (keyword #f "base-args")))) (jolt-invoke _a$1367 _a$1368 _a$1369 _a$1370)) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil) navigator)))))) format-logical-block) (let* ((_o$1371 (keyword #f "private")) (_o$1372 #t)) (jolt-hash-map _o$1371 _o$1372)))) + (def-var! "clojure.pprint" "format-logical-block" (letrec ((format-logical-block (lambda (params navigator offsets) (let fnrec1066 ((params params) (navigator navigator) (offsets offsets)) (let* ((clauses (jolt-get params (keyword #f "clauses"))) (clause-count (jolt-count clauses)) (prefix (if (> clause-count 1) (jolt-get (jolt-get (jolt-first (jolt-first clauses)) (keyword #f "params")) (keyword #f "string")) (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) "(" jolt-nil))) (body (jolt-nth clauses (if (> clause-count 1) 1 0))) (suffix (if (> clause-count 2) (jolt-get (jolt-get (jolt-first (jolt-nth clauses 2)) (keyword #f "params")) (keyword #f "string")) (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) ")" jolt-nil))) (G__64 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg (jolt-nth G__64 0 jolt-nil)) (navigator (jolt-nth G__64 1 jolt-nil))) (begin (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") prefix jolt-nil suffix) (let* ((_a$1067 (var-deref "clojure.pprint" "execute-sub-format")) (_a$1068 body) (_a$1069 (jolt-invoke (var-deref "clojure.pprint" "init-navigator") arg)) (_a$1070 (jolt-get params (keyword #f "base-args")))) (jolt-invoke _a$1067 _a$1068 _a$1069 _a$1070)) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil) navigator)))))) format-logical-block))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "set-indent" (letrec ((set-indent (lambda (params navigator offsets) (let fnrec1373 ((params params) (navigator navigator) (offsets offsets)) (let* ((relative-to (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (keyword #f "current") (keyword #f "block")))) (begin (jolt-invoke (var-deref "clojure.pprint" "pprint-indent") relative-to (jolt-get params (keyword #f "n"))) navigator)))))) set-indent) (let* ((_o$1374 (keyword #f "private")) (_o$1375 #t)) (jolt-hash-map _o$1374 _o$1375)))) + (def-var! "clojure.pprint" "set-indent" (letrec ((set-indent (lambda (params navigator offsets) (let fnrec1071 ((params params) (navigator navigator) (offsets offsets)) (let* ((relative-to (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (keyword #f "current") (keyword #f "block")))) (begin (jolt-invoke (var-deref "clojure.pprint" "pprint-indent") relative-to (jolt-get params (keyword #f "n"))) navigator)))))) set-indent))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "conditional-newline" (letrec ((conditional-newline (lambda (params navigator offsets) (let fnrec1376 ((params params) (navigator navigator) (offsets offsets)) (let* ((kind (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (keyword #f "mandatory") (keyword #f "fill")) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (keyword #f "miser") (keyword #f "linear"))))) (begin (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") kind) navigator)))))) conditional-newline) (let* ((_o$1377 (keyword #f "private")) (_o$1378 #t)) (jolt-hash-map _o$1377 _o$1378)))) + (def-var! "clojure.pprint" "conditional-newline" (letrec ((conditional-newline (lambda (params navigator offsets) (let fnrec1072 ((params params) (navigator navigator) (offsets offsets)) (let* ((kind (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (keyword #f "mandatory") (keyword #f "fill")) (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (keyword #f "miser") (keyword #f "linear"))))) (begin (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") kind) navigator)))))) conditional-newline))) (guard (e (#t #f)) (def-var! "clojure.pprint" "defdirectives" - (lambda directives (let fnrec1379 ((directives (list->cseq directives))) (let* ((process (lambda (G__73) (let fnrec1380 ((G__73 G__73)) (let* ((G__74 G__73) (char (jolt-nth G__74 0 jolt-nil)) (params (jolt-nth G__74 1 jolt-nil)) (flags (jolt-nth G__74 2 jolt-nil)) (bracket-info (jolt-nth G__74 3 jolt-nil)) (generator-fn (jolt-invoke (var-deref "clojure.core" "nthnext") G__74 4))) (let* ((_o$1391 char) (_o$1392 (let* ((_o$1381 (keyword #f "directive")) (_o$1382 char) (_o$1383 (keyword #f "params")) (_o$1384 (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "array-map")) params)) (_o$1385 (keyword #f "flags")) (_o$1386 flags) (_o$1387 (keyword #f "bracket-info")) (_o$1388 bracket-info) (_o$1389 (keyword #f "generator-fn")) (_o$1390 (jolt-concat (jolt-list (jolt-symbol #f "fn") (jolt-vector (jolt-symbol #f "params") (jolt-symbol #f "offset"))) generator-fn))) (jolt-hash-map _o$1381 _o$1382 _o$1383 _o$1384 _o$1385 _o$1386 _o$1387 _o$1388 _o$1389 _o$1390)))) (jolt-vector _o$1391 _o$1392))))))) (let* ((_a$1396 (var-deref "clojure.core" "__sqcat")) (_a$1397 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "def"))) (_a$1398 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "directive-table"))) (_a$1399 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$1393 (var-deref "clojure.core" "__sqcat")) (_a$1394 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "hash-map"))) (_a$1395 (jolt-invoke (var-deref "clojure.core" "mapcat") process directives))) (jolt-invoke _a$1393 _a$1394 _a$1395))))) (jolt-invoke _a$1396 _a$1397 _a$1398 _a$1399)))))) + (lambda directives (let fnrec1073 ((directives (list->cseq directives))) (let* ((process (lambda (G__65) (let fnrec1074 ((G__65 G__65)) (let* ((G__66 G__65) (char (jolt-nth G__66 0 jolt-nil)) (params (jolt-nth G__66 1 jolt-nil)) (flags (jolt-nth G__66 2 jolt-nil)) (bracket-info (jolt-nth G__66 3 jolt-nil)) (generator-fn (jolt-invoke (var-deref "clojure.core" "nthnext") G__66 4))) (let* ((_o$1085 char) (_o$1086 (let* ((_o$1075 (keyword #f "directive")) (_o$1076 char) (_o$1077 (keyword #f "params")) (_o$1078 (jolt-invoke (var-deref "clojure.core" "__sqcat") (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "array-map")) params)) (_o$1079 (keyword #f "flags")) (_o$1080 flags) (_o$1081 (keyword #f "bracket-info")) (_o$1082 bracket-info) (_o$1083 (keyword #f "generator-fn")) (_o$1084 (jolt-concat (jolt-list (jolt-symbol #f "fn") (jolt-vector (jolt-symbol #f "params") (jolt-symbol #f "offset"))) generator-fn))) (jolt-hash-map _o$1075 _o$1076 _o$1077 _o$1078 _o$1079 _o$1080 _o$1081 _o$1082 _o$1083 _o$1084)))) (jolt-vector _o$1085 _o$1086))))))) (let* ((_a$1090 (var-deref "clojure.core" "__sqcat")) (_a$1091 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "def"))) (_a$1092 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol #f "directive-table"))) (_a$1093 (jolt-invoke (var-deref "clojure.core" "__sq1") (let* ((_a$1087 (var-deref "clojure.core" "__sqcat")) (_a$1088 (jolt-invoke (var-deref "clojure.core" "__sq1") (jolt-symbol "clojure.core" "hash-map"))) (_a$1089 (jolt-invoke (var-deref "clojure.core" "mapcat") process directives))) (jolt-invoke _a$1087 _a$1088 _a$1089))))) (jolt-invoke _a$1090 _a$1091 _a$1092 _a$1093)))))) (mark-macro! "clojure.pprint" "defdirectives")) (guard (e (#t #f)) - (def-var! 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(var-deref "clojure.core" "Long"))) (jolt-vector _o$1434 _o$1435))) (_a$1445 (keyword #f "minpad")) (_a$1446 (let* ((_o$1436 0) (_o$1437 (var-deref "clojure.core" "Long"))) (jolt-vector _o$1436 _o$1437))) (_a$1447 (keyword #f "padchar")) (_a$1448 (let* ((_o$1438 (integer->char 32)) (_o$1439 (var-deref "clojure.core" "Character"))) (jolt-vector _o$1438 _o$1439)))) (jolt-invoke _a$1440 _a$1441 _a$1442 _a$1443 _a$1444 _a$1445 _a$1446 _a$1447 _a$1448))) (_o$1458 (keyword #f "flags")) (_o$1459 (let* ((_o$1449 (keyword #f "at")) (_o$1450 (keyword #f "colon")) (_o$1451 (keyword #f "both"))) (jolt-hash-set _o$1449 _o$1450 _o$1451))) (_o$1460 (keyword #f "bracket-info")) (_o$1461 (jolt-hash-map)) (_o$1462 (keyword #f "generator-fn")) (_o$1463 (lambda (params offset) (let fnrec1452 ((params params) (offset offset)) (lambda (p__14_ p__15_ p__16_) (let fnrec1453 ((p__14_ p__14_) (p__15_ p__15_) (p__16_ p__16_)) (jolt-invoke (var-deref "clojure.pprint" "format-ascii") (var-deref "clojure.core" 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(let* ((or__26__auto (jolt-get params (keyword #f "at")))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get params (keyword #f "colon"))))) (let* ((bindings (let* ((_a$1601 (if (jolt-truthy? (jolt-get params (keyword #f "at"))) (let* ((_o$1595 (keyword #f "level")) (_o$1596 jolt-nil) (_o$1597 (keyword #f "length")) (_o$1598 jolt-nil)) (jolt-vector _o$1595 _o$1596 _o$1597 _o$1598)) (jolt-vector))) (_a$1602 (if (jolt-truthy? (jolt-get params (keyword #f "colon"))) (let* ((_o$1599 (keyword #f "pretty")) (_o$1600 #t)) (jolt-vector _o$1599 _o$1600)) (jolt-vector)))) (jolt-concat _a$1601 _a$1602)))) (lambda (params navigator offsets) (let fnrec1603 ((params params) (navigator navigator) (offsets offsets)) (let* ((G__70 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg (jolt-nth G__70 0 jolt-nil)) (navigator (jolt-nth G__70 1 jolt-nil))) (if (jolt-truthy? (jolt-apply (var-deref "clojure.pprint" "write") arg bindings)) (let* ((_o$1604 (keyword #f "up-arrow")) (_o$1605 navigator)) (jolt-vector _o$1604 _o$1605)) navigator))))) (lambda (params navigator offsets) (let fnrec1606 ((params params) (navigator navigator) (offsets offsets)) (let* ((G__71 (jolt-invoke (var-deref "clojure.pprint" "next-arg") navigator)) (arg (jolt-nth G__71 0 jolt-nil)) (navigator (jolt-nth G__71 1 jolt-nil))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "write-out") arg)) (let* ((_o$1607 (keyword #f "up-arrow")) (_o$1608 navigator)) (jolt-vector _o$1607 _o$1608)) navigator)))))))) (_o$1615 (keyword #f "directive")) (_o$1616 (integer->char 87)) (_o$1617 (keyword #f "params")) (_o$1618 (jolt-invoke (var-deref "clojure.core" "array-map")))) (jolt-hash-map _o$1609 _o$1610 _o$1611 _o$1612 _o$1613 _o$1614 _o$1615 _o$1616 _o$1617 _o$1618))) (_a$1694 (integer->char 95)) (_a$1695 (let* ((_o$1623 (keyword #f "bracket-info")) (_o$1624 (jolt-hash-map)) (_o$1625 (keyword #f "flags")) (_o$1626 (let* ((_o$1619 (keyword #f "at")) (_o$1620 (keyword #f "colon")) (_o$1621 (keyword #f "both"))) (jolt-hash-set _o$1619 _o$1620 _o$1621))) (_o$1627 (keyword #f "generator-fn")) (_o$1628 (lambda (params offset) (let fnrec1622 ((params params) (offset offset)) (var-deref "clojure.pprint" "conditional-newline")))) (_o$1629 (keyword #f "directive")) (_o$1630 (integer->char 95)) (_o$1631 (keyword #f "params")) (_o$1632 (jolt-invoke (var-deref "clojure.core" "array-map")))) (jolt-hash-map _o$1623 _o$1624 _o$1625 _o$1626 _o$1627 _o$1628 _o$1629 _o$1630 _o$1631 _o$1632))) (_a$1696 (integer->char 73)) (_a$1697 (let* ((_o$1636 (keyword #f "bracket-info")) (_o$1637 (jolt-hash-map)) (_o$1638 (keyword #f "flags")) (_o$1639 (jolt-hash-set (keyword #f "colon"))) (_o$1640 (keyword #f "generator-fn")) (_o$1641 (lambda (params offset) (let fnrec1633 ((params params) (offset offset)) (var-deref "clojure.pprint" "set-indent")))) (_o$1642 (keyword #f "directive")) (_o$1643 (integer->char 73)) (_o$1644 (keyword #f "params")) (_o$1645 (jolt-invoke (var-deref "clojure.core" "array-map") (keyword #f "n") (let* ((_o$1634 0) (_o$1635 (var-deref "clojure.core" "Long"))) (jolt-vector _o$1634 _o$1635))))) (jolt-hash-map _o$1636 _o$1637 _o$1638 _o$1639 _o$1640 _o$1641 _o$1642 _o$1643 _o$1644 _o$1645)))) (jolt-hash-map _a$1646 _a$1647 _a$1648 _a$1649 _a$1650 _a$1651 _a$1652 _a$1653 _a$1654 _a$1655 _a$1656 _a$1657 _a$1658 _a$1659 _a$1660 _a$1661 _a$1662 _a$1663 _a$1664 _a$1665 _a$1666 _a$1667 _a$1668 _a$1669 _a$1670 _a$1671 _a$1672 _a$1673 _a$1674 _a$1675 _a$1676 _a$1677 _a$1678 _a$1679 _a$1680 _a$1681 _a$1682 _a$1683 _a$1684 _a$1685 _a$1686 _a$1687 _a$1688 _a$1689 _a$1690 _a$1691 _a$1692 _a$1693 _a$1694 _a$1695 _a$1696 _a$1697)))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "param-pattern" (jolt-regex "^([vV]|#|('.)|([+-]?\\d+)|(?=,))") (let* ((_o$2004 (keyword #f "private")) (_o$2005 #t)) (jolt-hash-map _o$2004 _o$2005)))) + (def-var-with-meta! "clojure.pprint" "param-pattern" (jolt-regex "^([vV]|#|('.)|([+-]?\\d+)|(?=,))") (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "special-params" (let* ((_o$2006 (keyword #f "parameter-from-args")) (_o$2007 (keyword #f "remaining-arg-count"))) (jolt-hash-set _o$2006 _o$2007)) (let* ((_o$2008 (keyword #f "private")) (_o$2009 #t)) (jolt-hash-map _o$2008 _o$2009)))) + (def-var-with-meta! "clojure.pprint" "special-params" (let* ((_o$1698 (keyword #f "parameter-from-args")) (_o$1699 (keyword #f "remaining-arg-count"))) (jolt-hash-set _o$1698 _o$1699)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "extract-param" (letrec ((extract-param (lambda (G__80) (let fnrec2010 ((G__80 G__80)) (let* ((G__81 G__80) (s (jolt-nth G__81 0 jolt-nil)) (offset (jolt-nth G__81 1 jolt-nil)) (saw-comma (jolt-nth G__81 2 jolt-nil))) (let* ((param (jolt-invoke (var-deref "clojure.core" "re-find") (var-deref "clojure.pprint" "param-pattern") s)) (token-str (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") param)) (jolt-first param) param))) (if (jolt-truthy? token-str) (let* ((len (jolt-count token-str)) (remainder (jolt-invoke (var-deref "clojure.core" "subs") s len)) (new-offset (jolt-n+ offset len))) (if (jolt-not (jolt= (integer->char 44) (jolt-nth remainder 0 jolt-nil))) (let* ((_o$2016 (let* ((_o$2011 token-str) (_o$2012 offset)) (jolt-vector _o$2011 _o$2012))) (_o$2017 (let* ((_o$2013 remainder) (_o$2014 new-offset) (_o$2015 #f)) (jolt-vector _o$2013 _o$2014 _o$2015)))) (jolt-vector _o$2016 _o$2017)) (let* ((_o$2023 (let* ((_o$2018 token-str) (_o$2019 offset)) (jolt-vector _o$2018 _o$2019))) (_o$2024 (let* ((_o$2020 (jolt-invoke (var-deref "clojure.core" "subs") remainder 1)) (_o$2021 (jolt-inc new-offset)) (_o$2022 #t)) (jolt-vector _o$2020 _o$2021 _o$2022)))) (jolt-vector _o$2023 _o$2024)))) (if (jolt-truthy? saw-comma) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Badly formed parameters in format directive" offset) (let* ((_o$2027 jolt-nil) (_o$2028 (let* ((_o$2025 s) (_o$2026 offset)) (jolt-vector _o$2025 _o$2026)))) (jolt-vector _o$2027 _o$2028)))))))))) extract-param) (let* ((_o$2029 (keyword #f "private")) (_o$2030 #t)) (jolt-hash-map _o$2029 _o$2030)))) + (def-var! "clojure.pprint" "extract-param" (letrec ((extract-param (lambda (G__72) (let fnrec1700 ((G__72 G__72)) (let* ((G__73 G__72) (s (jolt-nth G__73 0 jolt-nil)) (offset (jolt-nth G__73 1 jolt-nil)) (saw-comma (jolt-nth G__73 2 jolt-nil))) (let* ((param (jolt-invoke (var-deref "clojure.core" "re-find") (var-deref "clojure.pprint" "param-pattern") s)) (token-str (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") param)) (jolt-first param) param))) (if (jolt-truthy? token-str) (let* ((len (jolt-count token-str)) (remainder (jolt-invoke (var-deref "clojure.core" "subs") s len)) (new-offset (+ offset len))) (if (jolt-not (jolt= (integer->char 44) (jolt-nth remainder 0 jolt-nil))) (let* ((_o$1706 (let* ((_o$1701 token-str) (_o$1702 offset)) (jolt-vector _o$1701 _o$1702))) (_o$1707 (let* ((_o$1703 remainder) (_o$1704 new-offset) (_o$1705 #f)) (jolt-vector _o$1703 _o$1704 _o$1705)))) (jolt-vector _o$1706 _o$1707)) (let* ((_o$1713 (let* ((_o$1708 token-str) (_o$1709 offset)) (jolt-vector _o$1708 _o$1709))) (_o$1714 (let* ((_o$1710 (jolt-invoke (var-deref "clojure.core" "subs") remainder 1)) (_o$1711 (jolt-inc new-offset)) (_o$1712 #t)) (jolt-vector _o$1710 _o$1711 _o$1712)))) (jolt-vector _o$1713 _o$1714)))) (if (jolt-truthy? saw-comma) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Badly formed parameters in format directive" offset) (let* ((_o$1717 jolt-nil) (_o$1718 (let* ((_o$1715 s) (_o$1716 offset)) (jolt-vector _o$1715 _o$1716)))) (jolt-vector _o$1717 _o$1718)))))))))) extract-param))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "extract-params" (letrec ((extract-params (lambda (s offset) (let fnrec2031 ((s s) (offset offset)) (jolt-invoke (var-deref "clojure.pprint" "consume") (var-deref "clojure.pprint" "extract-param") (let* ((_o$2032 s) (_o$2033 offset) (_o$2034 #f)) (jolt-vector _o$2032 _o$2033 _o$2034))))))) extract-params) (let* ((_o$2035 (keyword #f "private")) (_o$2036 #t)) (jolt-hash-map _o$2035 _o$2036)))) + (def-var! "clojure.pprint" "extract-params" (letrec ((extract-params (lambda (s offset) (let fnrec1719 ((s s) (offset offset)) (jolt-invoke (var-deref "clojure.pprint" "consume") (var-deref "clojure.pprint" "extract-param") (let* ((_o$1720 s) (_o$1721 offset) (_o$1722 #f)) (jolt-vector _o$1720 _o$1721 _o$1722))))))) extract-params))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "translate-param" (letrec ((translate-param (lambda (G__82) (let fnrec2037 ((G__82 G__82)) (let* ((G__83 G__82) (p (jolt-nth G__83 0 jolt-nil)) (offset (jolt-nth G__83 1 jolt-nil))) (let* ((_o$2042 (if (jolt= (jolt-count p) 0) jolt-nil (if (let* ((and__25__auto (jolt= (jolt-count p) 1))) (if (jolt-truthy? and__25__auto) (let* ((_a$2040 (let* ((_o$2038 (integer->char 118)) (_o$2039 (integer->char 86))) (jolt-hash-set _o$2038 _o$2039))) (_a$2041 (jolt-nth p 0))) (jolt-contains? _a$2040 _a$2041)) and__25__auto)) (keyword #f "parameter-from-args") (if (let* ((and__25__auto (jolt= (jolt-count p) 1))) (if (jolt-truthy? and__25__auto) (jolt= (integer->char 35) (jolt-nth p 0)) and__25__auto)) (keyword #f "remaining-arg-count") (if (let* ((and__25__auto (jolt= (jolt-count p) 2))) (if (jolt-truthy? and__25__auto) (jolt= (integer->char 39) (jolt-nth p 0)) and__25__auto)) (jolt-nth p 1) (if #t (host-static-call "Long" "parseLong" p) jolt-nil)))))) (_o$2043 offset)) (jolt-vector _o$2042 _o$2043))))))) translate-param) (let* ((_o$2044 (keyword #f "private")) (_o$2045 #t)) (jolt-hash-map _o$2044 _o$2045)))) + (def-var! "clojure.pprint" "translate-param" (letrec ((translate-param (lambda (G__74) (let fnrec1723 ((G__74 G__74)) (let* ((G__75 G__74) (p (jolt-nth G__75 0 jolt-nil)) (offset (jolt-nth G__75 1 jolt-nil))) (let* ((_o$1728 (if (jolt= (jolt-count p) 0) jolt-nil (if (jolt-truthy? (let* ((and__25__auto (jolt= (jolt-count p) 1))) (if (jolt-truthy? and__25__auto) (let* ((_a$1726 (let* ((_o$1724 (integer->char 118)) (_o$1725 (integer->char 86))) (jolt-hash-set _o$1724 _o$1725))) (_a$1727 (jolt-nth p 0))) (jolt-contains? _a$1726 _a$1727)) and__25__auto))) (keyword #f "parameter-from-args") (if (jolt-truthy? (let* ((and__25__auto (jolt= (jolt-count p) 1))) (if (jolt-truthy? and__25__auto) (jolt= (integer->char 35) (jolt-nth p 0)) and__25__auto))) (keyword #f "remaining-arg-count") (if (jolt-truthy? (let* ((and__25__auto (jolt= (jolt-count p) 2))) (if (jolt-truthy? and__25__auto) (jolt= (integer->char 39) (jolt-nth p 0)) and__25__auto))) (jolt-nth p 1) (if #t (host-static-call "Long" "parseLong" p) jolt-nil)))))) (_o$1729 offset)) (jolt-vector _o$1728 _o$1729))))))) translate-param))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "flag-defs" (let* ((_o$2046 (integer->char 58)) (_o$2047 (keyword #f "colon")) (_o$2048 (integer->char 64)) (_o$2049 (keyword #f "at"))) (jolt-hash-map _o$2046 _o$2047 _o$2048 _o$2049)) (let* ((_o$2050 (keyword #f "private")) (_o$2051 #t)) (jolt-hash-map _o$2050 _o$2051)))) + (def-var-with-meta! "clojure.pprint" "flag-defs" (let* ((_o$1730 (integer->char 58)) (_o$1731 (keyword #f "colon")) (_o$1732 (integer->char 64)) (_o$1733 (keyword #f "at"))) (jolt-hash-map _o$1730 _o$1731 _o$1732 _o$1733)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "extract-flags" (letrec ((extract-flags (lambda (s offset) (let fnrec2052 ((s s) (offset offset)) (let* ((_a$2074 (var-deref "clojure.pprint" "consume")) (_a$2075 (lambda (G__84) (let fnrec2053 ((G__84 G__84)) (let* ((G__85 G__84) (s (jolt-nth G__85 0 jolt-nil)) (offset (jolt-nth G__85 1 jolt-nil)) (flags (jolt-nth G__85 2 jolt-nil))) (if (jolt-empty? s) (let* ((_o$2057 jolt-nil) (_o$2058 (let* ((_o$2054 s) (_o$2055 offset) (_o$2056 flags)) (jolt-vector _o$2054 _o$2055 _o$2056)))) (jolt-vector _o$2057 _o$2058)) (let* ((flag (jolt-get (var-deref "clojure.pprint" "flag-defs") (jolt-first s)))) (if (jolt-truthy? flag) (if (jolt-contains? flags flag) (jolt-invoke (var-deref "clojure.pprint" "format-error") (jolt-invoke (var-deref "clojure.core" "str") "Flag \"" (jolt-first s) "\" appears more than once in a directive") offset) (let* ((_o$2064 #t) (_o$2065 (let* ((_o$2061 (jolt-invoke (var-deref "clojure.core" "subs") s 1)) (_o$2062 (jolt-inc offset)) (_o$2063 (jolt-assoc flags flag (let* ((_o$2059 #t) (_o$2060 offset)) (jolt-vector _o$2059 _o$2060))))) (jolt-vector _o$2061 _o$2062 _o$2063)))) (jolt-vector _o$2064 _o$2065))) (let* ((_o$2069 jolt-nil) (_o$2070 (let* ((_o$2066 s) (_o$2067 offset) (_o$2068 flags)) (jolt-vector _o$2066 _o$2067 _o$2068)))) (jolt-vector _o$2069 _o$2070))))))))) (_a$2076 (let* ((_o$2071 s) (_o$2072 offset) (_o$2073 (jolt-hash-map))) (jolt-vector _o$2071 _o$2072 _o$2073)))) (jolt-invoke _a$2074 _a$2075 _a$2076)))))) extract-flags) (let* ((_o$2077 (keyword #f "private")) (_o$2078 #t)) (jolt-hash-map _o$2077 _o$2078)))) + (def-var! "clojure.pprint" "extract-flags" (letrec ((extract-flags (lambda (s offset) (let fnrec1734 ((s s) (offset offset)) (let* ((_a$1756 (var-deref "clojure.pprint" "consume")) (_a$1757 (lambda (G__76) (let fnrec1735 ((G__76 G__76)) (let* ((G__77 G__76) (s (jolt-nth G__77 0 jolt-nil)) (offset (jolt-nth G__77 1 jolt-nil)) (flags (jolt-nth G__77 2 jolt-nil))) (if (jolt-empty? s) (let* ((_o$1739 jolt-nil) (_o$1740 (let* ((_o$1736 s) (_o$1737 offset) (_o$1738 flags)) (jolt-vector _o$1736 _o$1737 _o$1738)))) (jolt-vector _o$1739 _o$1740)) (let* ((flag (jolt-get (var-deref "clojure.pprint" "flag-defs") (jolt-first s)))) (if (jolt-truthy? flag) (if (jolt-contains? flags flag) (jolt-invoke (var-deref "clojure.pprint" "format-error") (jolt-invoke (var-deref "clojure.core" "str") "Flag \"" (jolt-first s) "\" appears more than once in a directive") offset) (let* ((_o$1746 #t) (_o$1747 (let* ((_o$1743 (jolt-invoke (var-deref "clojure.core" "subs") s 1)) (_o$1744 (jolt-inc offset)) (_o$1745 (jolt-assoc flags flag (let* ((_o$1741 #t) (_o$1742 offset)) (jolt-vector _o$1741 _o$1742))))) (jolt-vector _o$1743 _o$1744 _o$1745)))) (jolt-vector _o$1746 _o$1747))) (let* ((_o$1751 jolt-nil) (_o$1752 (let* ((_o$1748 s) (_o$1749 offset) (_o$1750 flags)) (jolt-vector _o$1748 _o$1749 _o$1750)))) (jolt-vector _o$1751 _o$1752))))))))) (_a$1758 (let* ((_o$1753 s) (_o$1754 offset) (_o$1755 (jolt-hash-map))) (jolt-vector _o$1753 _o$1754 _o$1755)))) (jolt-invoke _a$1756 _a$1757 _a$1758)))))) extract-flags))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "check-flags" (letrec ((check-flags (lambda (dirdef flags) (let fnrec2079 ((dirdef dirdef) (flags flags)) (let* ((allowed (jolt-get dirdef (keyword #f "flags")))) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "at"))))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "at")) and__25__auto))) (let* ((_a$2080 (var-deref "clojure.pprint" "format-error")) (_a$2081 (jolt-invoke (var-deref "clojure.core" "str") "\"@\" is an illegal flag for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$2082 (jolt-nth (jolt-get flags (keyword #f "at")) 1))) (jolt-invoke _a$2080 _a$2081 _a$2082)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "colon"))))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "colon")) and__25__auto))) (let* ((_a$2083 (var-deref "clojure.pprint" "format-error")) (_a$2084 (jolt-invoke (var-deref "clojure.core" "str") "\":\" is an illegal flag for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$2085 (jolt-nth (jolt-get flags (keyword #f "colon")) 1))) (jolt-invoke _a$2083 _a$2084 _a$2085)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "both"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get flags (keyword #f "at")))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "colon")) and__25__auto)) and__25__auto))) (let* ((_a$2088 (var-deref "clojure.pprint" "format-error")) (_a$2089 (jolt-invoke (var-deref "clojure.core" "str") "Cannot combine \"@\" and \":\" flags for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$2090 (let* ((_a$2086 (jolt-nth (jolt-get flags (keyword #f "colon")) 1)) (_a$2087 (jolt-nth (jolt-get flags (keyword #f "at")) 1))) (jolt-n-min _a$2086 _a$2087)))) (jolt-invoke _a$2088 _a$2089 _a$2090)) jolt-nil))))))) check-flags) (let* ((_o$2091 (keyword #f "private")) (_o$2092 #t)) (jolt-hash-map _o$2091 _o$2092)))) + (def-var! "clojure.pprint" "check-flags" (letrec ((check-flags (lambda (dirdef flags) (let fnrec1759 ((dirdef dirdef) (flags flags)) (let* ((allowed (jolt-get dirdef (keyword #f "flags")))) (begin (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "at"))))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "at")) and__25__auto))) (let* ((_a$1760 (var-deref "clojure.pprint" "format-error")) (_a$1761 (jolt-invoke (var-deref "clojure.core" "str") "\"@\" is an illegal flag for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$1762 (jolt-nth (jolt-get flags (keyword #f "at")) 1))) (jolt-invoke _a$1760 _a$1761 _a$1762)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "colon"))))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "colon")) and__25__auto))) (let* ((_a$1763 (var-deref "clojure.pprint" "format-error")) (_a$1764 (jolt-invoke (var-deref "clojure.core" "str") "\":\" is an illegal flag for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$1765 (jolt-nth (jolt-get flags (keyword #f "colon")) 1))) (jolt-invoke _a$1763 _a$1764 _a$1765)) jolt-nil) (if (jolt-truthy? (let* ((and__25__auto (jolt-not (jolt-get allowed (keyword #f "both"))))) (if (jolt-truthy? and__25__auto) (let* ((and__25__auto (jolt-get flags (keyword #f "at")))) (if (jolt-truthy? and__25__auto) (jolt-get flags (keyword #f "colon")) and__25__auto)) and__25__auto))) (let* ((_a$1768 (var-deref "clojure.pprint" "format-error")) (_a$1769 (jolt-invoke (var-deref "clojure.core" "str") "Cannot combine \"@\" and \":\" flags for format directive \"" (jolt-get dirdef (keyword #f "directive")) "\"")) (_a$1770 (let* ((_a$1766 (jolt-nth (jolt-get flags (keyword #f "colon")) 1)) (_a$1767 (jolt-nth (jolt-get flags (keyword #f "at")) 1))) (min _a$1766 _a$1767)))) (jolt-invoke _a$1768 _a$1769 _a$1770)) jolt-nil))))))) check-flags))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "map-params" (letrec ((map-params (lambda (dirdef params flags offset) (let fnrec2093 ((dirdef dirdef) (params params) (flags flags) (offset offset)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-flags") dirdef flags) (if (let* ((_a$2094 (jolt-count params)) (_a$2095 (jolt-count (jolt-get dirdef (keyword #f "params"))))) (jolt-n> _a$2094 _a$2095)) (let* ((_a$2102 (var-deref "clojure.pprint" "format-error")) (_a$2103 (let* ((_a$2096 (var-deref "clojure.pprint" "cl-format")) (_a$2097 jolt-nil) (_a$2098 "Too many parameters for directive \"~C\": ~D~:* ~[were~;was~:;were~] specified but only ~D~:* ~[are~;is~:;are~] allowed") (_a$2099 (jolt-get dirdef (keyword #f "directive"))) (_a$2100 (jolt-count params)) (_a$2101 (jolt-count (jolt-get dirdef (keyword #f "params"))))) (jolt-invoke _a$2096 _a$2097 _a$2098 _a$2099 _a$2100 _a$2101))) (_a$2104 (jolt-invoke (var-deref "clojure.core" "second") (jolt-first params)))) (jolt-invoke _a$2102 _a$2103 _a$2104)) jolt-nil) (jolt-invoke (var-deref "clojure.core" "doall") (let* ((_a$2106 (lambda (p__35_) (let fnrec2105 ((p__35_ p__35_)) (let* ((val (jolt-first p__35_))) (if (jolt-not (let* ((or__26__auto (jolt-nil? val))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-contains? (var-deref "clojure.pprint" "special-params") val)))) jolt-nil jolt-nil))))) (_a$2107 params) (_a$2108 (jolt-get dirdef (keyword #f "params")))) (jolt-map _a$2106 _a$2107 _a$2108))) (let* ((_a$2125 (var-deref "clojure.core" "merge")) (_a$2126 (let* ((_a$2116 (jolt-hash-map)) (_a$2117 (jolt-reverse (let* ((_a$2114 (lambda (G__86) (let fnrec2109 ((G__86 G__86)) (let* ((G__87 G__86) (name (jolt-nth G__87 0 jolt-nil)) (G__88 (jolt-nth G__87 1 jolt-nil)) (default (jolt-nth G__88 0 jolt-nil))) (let* ((_o$2112 name) (_o$2113 (let* ((_o$2110 default) (_o$2111 offset)) (jolt-vector _o$2110 _o$2111)))) (jolt-vector _o$2112 _o$2113)))))) (_a$2115 (jolt-get dirdef (keyword #f "params")))) (jolt-map _a$2114 _a$2115))))) (jolt-into _a$2116 _a$2117))) (_a$2127 (let* ((_a$2122 (lambda (p__36_ p__37_) (let fnrec2118 ((p__36_ p__36_) (p__37_ p__37_)) (jolt-apply jolt-assoc p__36_ p__37_)))) (_a$2123 (jolt-hash-map)) (_a$2124 (let* ((_a$2120 (lambda (p__38_) (let fnrec2119 ((p__38_ p__38_)) (jolt-first (jolt-nth p__38_ 1))))) (_a$2121 (jolt-invoke (var-deref "clojure.core" "zipmap") (jolt-keys (jolt-get dirdef (keyword #f "params"))) params))) (jolt-filter _a$2120 _a$2121)))) (jolt-reduce _a$2122 _a$2123 _a$2124))) (_a$2128 flags)) (jolt-invoke _a$2125 _a$2126 _a$2127 _a$2128))))))) map-params) (let* ((_o$2129 (keyword #f "private")) (_o$2130 #t)) (jolt-hash-map _o$2129 _o$2130)))) + (def-var! "clojure.pprint" "map-params" (letrec ((map-params (lambda (dirdef params flags offset) (let fnrec1771 ((dirdef dirdef) (params params) (flags flags) (offset offset)) (begin (jolt-invoke (var-deref "clojure.pprint" "check-flags") dirdef flags) (if (let* ((_a$1772 (jolt-count params)) (_a$1773 (jolt-count (jolt-get dirdef (keyword #f "params"))))) (> _a$1772 _a$1773)) (let* ((_a$1780 (var-deref "clojure.pprint" "format-error")) (_a$1781 (let* ((_a$1774 (var-deref "clojure.pprint" "cl-format")) (_a$1775 jolt-nil) (_a$1776 "Too many parameters for directive \"~C\": ~D~:* ~[were~;was~:;were~] specified but only ~D~:* ~[are~;is~:;are~] allowed") (_a$1777 (jolt-get dirdef (keyword #f "directive"))) (_a$1778 (jolt-count params)) (_a$1779 (jolt-count (jolt-get dirdef (keyword #f "params"))))) (jolt-invoke _a$1774 _a$1775 _a$1776 _a$1777 _a$1778 _a$1779))) (_a$1782 (jolt-invoke (var-deref "clojure.core" "second") (jolt-first params)))) (jolt-invoke _a$1780 _a$1781 _a$1782)) jolt-nil) (jolt-invoke (var-deref "clojure.core" "doall") (let* ((_a$1784 (lambda (p__35_) (let fnrec1783 ((p__35_ p__35_)) (let* ((val (jolt-first p__35_))) (if (jolt-not (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "nil?") val))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-contains? (var-deref "clojure.pprint" "special-params") val)))) jolt-nil jolt-nil))))) (_a$1785 params) (_a$1786 (jolt-get dirdef (keyword #f "params")))) (jolt-map _a$1784 _a$1785 _a$1786))) (let* ((_a$1803 (var-deref "clojure.core" "merge")) (_a$1804 (let* ((_a$1794 (jolt-hash-map)) (_a$1795 (jolt-reverse (let* ((_a$1792 (lambda (G__78) (let fnrec1787 ((G__78 G__78)) (let* ((G__79 G__78) (name (jolt-nth G__79 0 jolt-nil)) (G__80 (jolt-nth G__79 1 jolt-nil)) (default (jolt-nth G__80 0 jolt-nil))) (let* ((_o$1790 name) (_o$1791 (let* ((_o$1788 default) (_o$1789 offset)) (jolt-vector _o$1788 _o$1789)))) (jolt-vector _o$1790 _o$1791)))))) (_a$1793 (jolt-get dirdef (keyword #f "params")))) (jolt-map _a$1792 _a$1793))))) (jolt-into _a$1794 _a$1795))) (_a$1805 (let* ((_a$1800 (lambda (p__36_ p__37_) (let fnrec1796 ((p__36_ p__36_) (p__37_ p__37_)) (jolt-apply jolt-assoc p__36_ p__37_)))) (_a$1801 (jolt-hash-map)) (_a$1802 (let* ((_a$1798 (lambda (p__38_) (let fnrec1797 ((p__38_ p__38_)) (jolt-first (jolt-nth p__38_ 1))))) (_a$1799 (jolt-invoke (var-deref "clojure.core" "zipmap") (jolt-keys (jolt-get dirdef (keyword #f "params"))) params))) (jolt-filter _a$1798 _a$1799)))) (jolt-reduce _a$1800 _a$1801 _a$1802))) (_a$1806 flags)) (jolt-invoke _a$1803 _a$1804 _a$1805 _a$1806))))))) map-params))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "compile-directive" (letrec ((compile-directive (lambda (s offset) (let fnrec2131 ((s s) (offset offset)) (let* ((G__89 (jolt-invoke (var-deref "clojure.pprint" "extract-params") s offset)) (raw-params (jolt-nth G__89 0 jolt-nil)) (G__90 (jolt-nth G__89 1 jolt-nil)) (rest (jolt-nth G__90 0 jolt-nil)) (offset (jolt-nth G__90 1 jolt-nil)) (G__91 (jolt-invoke (var-deref "clojure.pprint" "extract-flags") rest offset)) (_ (jolt-nth G__91 0 jolt-nil)) (G__92 (jolt-nth G__91 1 jolt-nil)) (rest (jolt-nth G__92 0 jolt-nil)) (offset (jolt-nth G__92 1 jolt-nil)) (flags (jolt-nth G__92 2 jolt-nil)) (directive (jolt-first rest)) (dirdef (if (jolt-truthy? directive) (let* ((or__26__auto (jolt-get (var-deref "clojure.pprint" "directive-table") (jolt-first (jolt-invoke (var-deref "clojure.string" "upper-case") (jolt-invoke (var-deref "clojure.core" "str") directive)))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get (var-deref "clojure.pprint" "directive-table") directive))) jolt-nil)) (params (if (jolt-truthy? dirdef) (jolt-invoke (var-deref "clojure.pprint" "map-params") dirdef (jolt-map (var-deref "clojure.pprint" "translate-param") raw-params) flags offset) jolt-nil))) (begin (if (jolt-not directive) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Format string ended in the middle of a directive" offset) jolt-nil) (if (jolt-not dirdef) (jolt-invoke (var-deref "clojure.pprint" "format-error") (jolt-invoke (var-deref "clojure.core" "str") "Directive \"" directive "\" is undefined") offset) jolt-nil) (let* ((_o$2136 (jolt-invoke (var-deref "clojure.pprint" "->compiled-directive") (jolt-invoke (jolt-get dirdef (keyword #f "generator-fn")) params offset) dirdef params offset)) (_o$2137 (let* ((remainder (jolt-invoke (var-deref "clojure.core" "subs") rest 1)) (offset (jolt-inc offset)) (trim? (let* ((and__25__auto (jolt= (integer->char 10) (jolt-get dirdef (keyword #f "directive"))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get params (keyword #f "colon"))) and__25__auto))) (trim-count (if (jolt-truthy? trim?) (jolt-invoke (var-deref "clojure.pprint" "prefix-count") remainder (let* ((_o$2132 (integer->char 32)) (_o$2133 (integer->char 9))) (jolt-vector _o$2132 _o$2133))) 0)) (remainder (jolt-invoke (var-deref "clojure.core" "subs") remainder trim-count)) (offset (jolt-n+ offset trim-count))) (let* ((_o$2134 remainder) (_o$2135 offset)) (jolt-vector _o$2134 _o$2135))))) (jolt-vector _o$2136 _o$2137)))))))) compile-directive) (let* ((_o$2138 (keyword #f "private")) (_o$2139 #t)) (jolt-hash-map _o$2138 _o$2139)))) + (def-var! "clojure.pprint" "compile-directive" (letrec ((compile-directive (lambda (s offset) (let fnrec1807 ((s s) (offset offset)) (let* ((G__81 (jolt-invoke (var-deref "clojure.pprint" "extract-params") s offset)) (raw-params (jolt-nth G__81 0 jolt-nil)) (G__82 (jolt-nth G__81 1 jolt-nil)) (rest (jolt-nth G__82 0 jolt-nil)) (offset (jolt-nth G__82 1 jolt-nil)) (G__83 (jolt-invoke (var-deref "clojure.pprint" "extract-flags") rest offset)) (_ (jolt-nth G__83 0 jolt-nil)) (G__84 (jolt-nth G__83 1 jolt-nil)) (rest (jolt-nth G__84 0 jolt-nil)) (offset (jolt-nth G__84 1 jolt-nil)) (flags (jolt-nth G__84 2 jolt-nil)) (directive (jolt-first rest)) (dirdef (if (jolt-truthy? directive) (let* ((or__26__auto (jolt-get (var-deref "clojure.pprint" "directive-table") (jolt-first (jolt-invoke (var-deref "clojure.string" "upper-case") (jolt-invoke (var-deref "clojure.core" "str") directive)))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-get (var-deref "clojure.pprint" "directive-table") directive))) jolt-nil)) (params (if (jolt-truthy? dirdef) (jolt-invoke (var-deref "clojure.pprint" "map-params") dirdef (jolt-map (var-deref "clojure.pprint" "translate-param") raw-params) flags offset) jolt-nil))) (begin (if (jolt-not directive) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Format string ended in the middle of a directive" offset) jolt-nil) (if (jolt-not dirdef) (jolt-invoke (var-deref "clojure.pprint" "format-error") (jolt-invoke (var-deref "clojure.core" "str") "Directive \"" directive "\" is undefined") offset) jolt-nil) (let* ((_o$1812 (jolt-invoke (var-deref "clojure.pprint" "->compiled-directive") (jolt-invoke (jolt-get dirdef (keyword #f "generator-fn")) params offset) dirdef params offset)) (_o$1813 (let* ((remainder (jolt-invoke (var-deref "clojure.core" "subs") rest 1)) (offset (jolt-inc offset)) (trim? (let* ((and__25__auto (jolt= (integer->char 10) (jolt-get dirdef (keyword #f "directive"))))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-get params (keyword #f "colon"))) and__25__auto))) (trim-count (if (jolt-truthy? trim?) (jolt-invoke (var-deref "clojure.pprint" "prefix-count") remainder (let* ((_o$1808 (integer->char 32)) (_o$1809 (integer->char 9))) (jolt-vector _o$1808 _o$1809))) 0)) (remainder (jolt-invoke (var-deref "clojure.core" "subs") remainder trim-count)) (offset (+ offset trim-count))) (let* ((_o$1810 remainder) (_o$1811 offset)) (jolt-vector _o$1810 _o$1811))))) (jolt-vector _o$1812 _o$1813)))))))) compile-directive))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "compile-raw-string" (letrec ((compile-raw-string (lambda (s offset) (let fnrec2140 ((s s) (offset offset)) (let* ((_a$2144 (var-deref "clojure.pprint" "->compiled-directive")) (_a$2145 (lambda (_r$__285 a _) (let fnrec2141 ((_r$__285 _r$__285) (a a) (_ _)) (begin (jolt-invoke (var-deref "clojure.pprint" "print") s) a)))) (_a$2146 jolt-nil) (_a$2147 (let* ((_o$2142 (keyword #f "string")) (_o$2143 s)) (jolt-hash-map _o$2142 _o$2143))) (_a$2148 offset)) (jolt-invoke _a$2144 _a$2145 _a$2146 _a$2147 _a$2148)))))) compile-raw-string) (let* ((_o$2149 (keyword #f "private")) (_o$2150 #t)) (jolt-hash-map _o$2149 _o$2150)))) + (def-var! "clojure.pprint" "compile-raw-string" (letrec ((compile-raw-string (lambda (s offset) (let fnrec1814 ((s s) (offset offset)) (let* ((_a$1818 (var-deref "clojure.pprint" "->compiled-directive")) (_a$1819 (lambda (_r$__285 a _) (let fnrec1815 ((_r$__285 _r$__285) (a a) (_ _)) (begin (jolt-invoke (var-deref "clojure.pprint" "print") s) a)))) (_a$1820 jolt-nil) (_a$1821 (let* ((_o$1816 (keyword #f "string")) (_o$1817 s)) (jolt-hash-map _o$1816 _o$1817))) (_a$1822 offset)) (jolt-invoke _a$1818 _a$1819 _a$1820 _a$1821 _a$1822)))))) compile-raw-string))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "right-bracket" (letrec ((right-bracket (lambda (this) (let fnrec2151 ((this this)) (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "right")))))) right-bracket) (let* ((_o$2152 (keyword #f "private")) (_o$2153 #t)) (jolt-hash-map _o$2152 _o$2153)))) + (def-var! "clojure.pprint" "right-bracket" (letrec ((right-bracket (lambda (this) (let fnrec1823 ((this this)) (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "right")))))) right-bracket))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "separator?" (letrec ((separator? (lambda (this) (let fnrec2154 ((this this)) (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "separator")))))) separator?) (let* ((_o$2155 (keyword #f "private")) (_o$2156 #t)) (jolt-hash-map _o$2155 _o$2156)))) + (def-var! "clojure.pprint" "separator?" (letrec ((separator? (lambda (this) (let fnrec1824 ((this this)) (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "separator")))))) separator?))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "else-separator?" (letrec ((else-separator? (lambda (this) (let fnrec2157 ((this this)) (let* ((and__25__auto (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "separator")))) (if (jolt-truthy? and__25__auto) (jolt-get (jolt-get this (keyword #f "params")) (keyword #f "colon")) and__25__auto)))))) else-separator?) (let* ((_o$2158 (keyword #f "private")) (_o$2159 #t)) (jolt-hash-map _o$2158 _o$2159)))) + (def-var! "clojure.pprint" "else-separator?" (letrec ((else-separator? (lambda (this) (let fnrec1825 ((this this)) (let* ((and__25__auto (jolt-get (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")) (keyword #f "separator")))) (if (jolt-truthy? and__25__auto) (jolt-get (jolt-get this (keyword #f "params")) (keyword #f "colon")) and__25__auto)))))) else-separator?))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "collect-clauses")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "process-bracket" (letrec ((process-bracket (lambda (this remainder) (let fnrec2160 ((this this) (remainder remainder)) (let* ((G__93 (let* ((_a$2161 (var-deref "clojure.pprint" "collect-clauses")) (_a$2162 (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info"))) (_a$2163 (jolt-get this (keyword #f "offset"))) (_a$2164 remainder)) (jolt-invoke _a$2161 _a$2162 _a$2163 _a$2164))) (subex (jolt-nth G__93 0 jolt-nil)) (remainder (jolt-nth G__93 1 jolt-nil))) (let* ((_o$2173 (let* ((_a$2168 (var-deref "clojure.pprint" "->compiled-directive")) (_a$2169 (jolt-get this (keyword #f "func"))) (_a$2170 (jolt-get this (keyword #f "dirdef"))) (_a$2171 (let* ((_a$2165 (var-deref "clojure.core" "merge")) (_a$2166 (jolt-get this (keyword #f "params"))) (_a$2167 (jolt-invoke (var-deref "clojure.pprint" "tuple-map") subex (jolt-get this (keyword #f "offset"))))) (jolt-invoke _a$2165 _a$2166 _a$2167))) (_a$2172 (jolt-get this (keyword #f "offset")))) (jolt-invoke _a$2168 _a$2169 _a$2170 _a$2171 _a$2172))) (_o$2174 remainder)) (jolt-vector _o$2173 _o$2174))))))) process-bracket) (let* ((_o$2175 (keyword #f "private")) (_o$2176 #t)) (jolt-hash-map _o$2175 _o$2176)))) + (def-var! "clojure.pprint" "process-bracket" (letrec ((process-bracket (lambda (this remainder) (let fnrec1826 ((this this) (remainder remainder)) (let* ((G__85 (let* ((_a$1827 (var-deref "clojure.pprint" "collect-clauses")) (_a$1828 (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info"))) (_a$1829 (jolt-get this (keyword #f "offset"))) (_a$1830 remainder)) (jolt-invoke _a$1827 _a$1828 _a$1829 _a$1830))) (subex (jolt-nth G__85 0 jolt-nil)) (remainder (jolt-nth G__85 1 jolt-nil))) (let* ((_o$1839 (let* ((_a$1834 (var-deref "clojure.pprint" "->compiled-directive")) (_a$1835 (jolt-get this (keyword #f "func"))) (_a$1836 (jolt-get this (keyword #f "dirdef"))) (_a$1837 (let* ((_a$1831 (var-deref "clojure.core" "merge")) (_a$1832 (jolt-get this (keyword #f "params"))) (_a$1833 (jolt-invoke (var-deref "clojure.pprint" "tuple-map") subex (jolt-get this (keyword #f "offset"))))) (jolt-invoke _a$1831 _a$1832 _a$1833))) (_a$1838 (jolt-get this (keyword #f "offset")))) (jolt-invoke _a$1834 _a$1835 _a$1836 _a$1837 _a$1838))) (_o$1840 remainder)) (jolt-vector _o$1839 _o$1840))))))) process-bracket))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "process-clause" (letrec ((process-clause (lambda (bracket-info offset remainder) (let fnrec2177 ((bracket-info bracket-info) (offset offset) (remainder remainder)) (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (remainder) (let fnrec2178 ((remainder remainder)) (if (jolt-empty? remainder) (jolt-invoke (var-deref "clojure.pprint" "format-error") "No closing bracket found." offset) (let* ((this (jolt-first remainder)) (remainder (jolt-next remainder))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "right-bracket") this)) (jolt-invoke (var-deref "clojure.pprint" "process-bracket") this remainder) (if (let* ((_a$2179 (jolt-get bracket-info (keyword #f "right"))) (_a$2180 (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "directive")))) (jolt= _a$2179 _a$2180)) (let* ((_o$2185 jolt-nil) (_o$2186 (let* ((_o$2181 (keyword #f "right-bracket")) (_o$2182 (jolt-get this (keyword #f "params"))) (_o$2183 jolt-nil) (_o$2184 remainder)) (jolt-vector _o$2181 _o$2182 _o$2183 _o$2184)))) (jolt-vector _o$2185 _o$2186)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "else-separator?") this)) (let* ((_o$2191 jolt-nil) (_o$2192 (let* ((_o$2187 (keyword #f "else")) (_o$2188 jolt-nil) (_o$2189 (jolt-get this (keyword #f "params"))) (_o$2190 remainder)) (jolt-vector _o$2187 _o$2188 _o$2189 _o$2190)))) (jolt-vector _o$2191 _o$2192)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "separator?") this)) (let* ((_o$2197 jolt-nil) (_o$2198 (let* ((_o$2193 (keyword #f "separator")) (_o$2194 jolt-nil) (_o$2195 jolt-nil) (_o$2196 remainder)) (jolt-vector _o$2193 _o$2194 _o$2195 _o$2196)))) (jolt-vector _o$2197 _o$2198)) (if #t (let* ((_o$2199 this) (_o$2200 remainder)) (jolt-vector _o$2199 _o$2200)) jolt-nil))))))))) remainder))))) process-clause) (let* ((_o$2201 (keyword #f "private")) (_o$2202 #t)) (jolt-hash-map _o$2201 _o$2202)))) + (def-var! "clojure.pprint" "process-clause" (letrec ((process-clause (lambda (bracket-info offset remainder) (let fnrec1841 ((bracket-info bracket-info) (offset offset) (remainder remainder)) (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (remainder) (let fnrec1842 ((remainder remainder)) (if (jolt-empty? remainder) (jolt-invoke (var-deref "clojure.pprint" "format-error") "No closing bracket found." offset) (let* ((this (jolt-first remainder)) (remainder (jolt-next remainder))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "right-bracket") this)) (jolt-invoke (var-deref "clojure.pprint" "process-bracket") this remainder) (if (let* ((_a$1843 (jolt-get bracket-info (keyword #f "right"))) (_a$1844 (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "directive")))) (jolt= _a$1843 _a$1844)) (let* ((_o$1849 jolt-nil) (_o$1850 (let* ((_o$1845 (keyword #f "right-bracket")) (_o$1846 (jolt-get this (keyword #f "params"))) (_o$1847 jolt-nil) (_o$1848 remainder)) (jolt-vector _o$1845 _o$1846 _o$1847 _o$1848)))) (jolt-vector _o$1849 _o$1850)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "else-separator?") this)) (let* ((_o$1855 jolt-nil) (_o$1856 (let* ((_o$1851 (keyword #f "else")) (_o$1852 jolt-nil) (_o$1853 (jolt-get this (keyword #f "params"))) (_o$1854 remainder)) (jolt-vector _o$1851 _o$1852 _o$1853 _o$1854)))) (jolt-vector _o$1855 _o$1856)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "separator?") this)) (let* ((_o$1861 jolt-nil) (_o$1862 (let* ((_o$1857 (keyword #f "separator")) (_o$1858 jolt-nil) (_o$1859 jolt-nil) (_o$1860 remainder)) (jolt-vector _o$1857 _o$1858 _o$1859 _o$1860)))) (jolt-vector _o$1861 _o$1862)) (if #t (let* ((_o$1863 this) (_o$1864 remainder)) (jolt-vector _o$1863 _o$1864)) jolt-nil))))))))) remainder))))) process-clause))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "collect-clauses" (letrec ((collect-clauses (lambda (bracket-info offset remainder) (let fnrec2203 ((bracket-info bracket-info) (offset offset) (remainder remainder)) (jolt-invoke (var-deref "clojure.core" "second") (let* ((_a$2241 (var-deref "clojure.pprint" "consume")) (_a$2242 (lambda (G__94) (let fnrec2204 ((G__94 G__94)) (let* ((G__95 G__94) (clause-map (jolt-nth G__95 0 jolt-nil)) (saw-else (jolt-nth G__95 1 jolt-nil)) (remainder (jolt-nth G__95 2 jolt-nil))) (let* ((G__96 (jolt-invoke (var-deref "clojure.pprint" "process-clause") bracket-info offset remainder)) (clause (jolt-nth G__96 0 jolt-nil)) (G__97 (jolt-nth G__96 1 jolt-nil)) (type (jolt-nth G__97 0 jolt-nil)) (right-params (jolt-nth G__97 1 jolt-nil)) (else-params (jolt-nth G__97 2 jolt-nil)) (remainder (jolt-nth G__97 3 jolt-nil))) (if (jolt= type (keyword #f "right-bracket")) (let* ((_o$2211 jolt-nil) (_o$2212 (let* ((_o$2209 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$2205 (if (jolt-truthy? saw-else) (keyword #f "else") (keyword #f "clauses"))) (_o$2206 (jolt-vector clause)) (_o$2207 (keyword #f "right-params")) (_o$2208 right-params)) (jolt-hash-map _o$2205 _o$2206 _o$2207 _o$2208)))) (_o$2210 remainder)) (jolt-vector _o$2209 _o$2210)))) (jolt-vector _o$2211 _o$2212)) (if (jolt= type (keyword #f "else")) (if (jolt-truthy? (jolt-get clause-map (keyword #f "else"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Two else clauses (\"~:;\") inside bracket construction." offset) (if (jolt-not (jolt-get bracket-info (keyword #f "else"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "An else clause (\"~:;\") is in a bracket type that doesn't support it." offset) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "first") (jolt-get bracket-info (keyword #f "else"))))) (if (jolt-truthy? and__25__auto) (jolt-seq (jolt-get clause-map (keyword #f "clauses"))) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "The else clause (\"~:;\") is only allowed in the first position for this directive." offset) (if #t (if (jolt= (keyword #f "first") (jolt-get bracket-info (keyword #f "else"))) (let* ((_o$2220 #t) (_o$2221 (let* ((_o$2217 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$2213 (keyword #f "else")) (_o$2214 (jolt-vector clause)) (_o$2215 (keyword #f "else-params")) (_o$2216 else-params)) (jolt-hash-map _o$2213 _o$2214 _o$2215 _o$2216)))) (_o$2218 #f) (_o$2219 remainder)) (jolt-vector _o$2217 _o$2218 _o$2219)))) (jolt-vector _o$2220 _o$2221)) (let* ((_o$2227 #t) (_o$2228 (let* ((_o$2224 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$2222 (keyword #f "clauses")) (_o$2223 (jolt-vector clause))) (jolt-hash-map _o$2222 _o$2223)))) (_o$2225 #t) (_o$2226 remainder)) (jolt-vector _o$2224 _o$2225 _o$2226)))) (jolt-vector _o$2227 _o$2228))) jolt-nil)))) (if (jolt= type (keyword #f "separator")) (if (jolt-truthy? saw-else) (jolt-invoke (var-deref "clojure.pprint" "format-error") "A plain clause (with \"~;\") follows an else clause (\"~:;\") inside bracket construction." offset) (if (jolt-not (jolt-get bracket-info (keyword #f "allows-separator"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "A separator (\"~;\") is in a bracket type that doesn't support it." offset) (if #t (let* ((_o$2234 #t) (_o$2235 (let* ((_o$2231 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$2229 (keyword #f "clauses")) (_o$2230 (jolt-vector clause))) (jolt-hash-map _o$2229 _o$2230)))) (_o$2232 #f) (_o$2233 remainder)) (jolt-vector _o$2231 _o$2232 _o$2233)))) (jolt-vector _o$2234 _o$2235)) jolt-nil))) jolt-nil)))))))) (_a$2243 (let* ((_o$2238 (let* ((_o$2236 (keyword #f "clauses")) (_o$2237 (jolt-vector))) (jolt-hash-map _o$2236 _o$2237))) (_o$2239 #f) (_o$2240 remainder)) (jolt-vector _o$2238 _o$2239 _o$2240)))) (jolt-invoke _a$2241 _a$2242 _a$2243))))))) collect-clauses) (let* ((_o$2244 (keyword #f "private")) (_o$2245 #t)) (jolt-hash-map _o$2244 _o$2245)))) + (def-var! "clojure.pprint" "collect-clauses" (letrec ((collect-clauses (lambda (bracket-info offset remainder) (let fnrec1865 ((bracket-info bracket-info) (offset offset) (remainder remainder)) (jolt-invoke (var-deref "clojure.core" "second") (let* ((_a$1903 (var-deref "clojure.pprint" "consume")) (_a$1904 (lambda (G__86) (let fnrec1866 ((G__86 G__86)) (let* ((G__87 G__86) (clause-map (jolt-nth G__87 0 jolt-nil)) (saw-else (jolt-nth G__87 1 jolt-nil)) (remainder (jolt-nth G__87 2 jolt-nil))) (let* ((G__88 (jolt-invoke (var-deref "clojure.pprint" "process-clause") bracket-info offset remainder)) (clause (jolt-nth G__88 0 jolt-nil)) (G__89 (jolt-nth G__88 1 jolt-nil)) (type (jolt-nth G__89 0 jolt-nil)) (right-params (jolt-nth G__89 1 jolt-nil)) (else-params (jolt-nth G__89 2 jolt-nil)) (remainder (jolt-nth G__89 3 jolt-nil))) (if (jolt= type (keyword #f "right-bracket")) (let* ((_o$1873 jolt-nil) (_o$1874 (let* ((_o$1871 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$1867 (if (jolt-truthy? saw-else) (keyword #f "else") (keyword #f "clauses"))) (_o$1868 (jolt-vector clause)) (_o$1869 (keyword #f "right-params")) (_o$1870 right-params)) (jolt-hash-map _o$1867 _o$1868 _o$1869 _o$1870)))) (_o$1872 remainder)) (jolt-vector _o$1871 _o$1872)))) (jolt-vector _o$1873 _o$1874)) (if (jolt= type (keyword #f "else")) (if (jolt-truthy? (jolt-get clause-map (keyword #f "else"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "Two else clauses (\"~:;\") inside bracket construction." offset) (if (jolt-not (jolt-get bracket-info (keyword #f "else"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "An else clause (\"~:;\") is in a bracket type that doesn't support it." offset) (if (jolt-truthy? (let* ((and__25__auto (jolt= (keyword #f "first") (jolt-get bracket-info (keyword #f "else"))))) (if (jolt-truthy? and__25__auto) (jolt-seq (jolt-get clause-map (keyword #f "clauses"))) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "The else clause (\"~:;\") is only allowed in the first position for this directive." offset) (if #t (if (jolt= (keyword #f "first") (jolt-get bracket-info (keyword #f "else"))) (let* ((_o$1882 #t) (_o$1883 (let* ((_o$1879 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$1875 (keyword #f "else")) (_o$1876 (jolt-vector clause)) (_o$1877 (keyword #f "else-params")) (_o$1878 else-params)) (jolt-hash-map _o$1875 _o$1876 _o$1877 _o$1878)))) (_o$1880 #f) (_o$1881 remainder)) (jolt-vector _o$1879 _o$1880 _o$1881)))) (jolt-vector _o$1882 _o$1883)) (let* ((_o$1889 #t) (_o$1890 (let* ((_o$1886 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$1884 (keyword #f "clauses")) (_o$1885 (jolt-vector clause))) (jolt-hash-map _o$1884 _o$1885)))) (_o$1887 #t) (_o$1888 remainder)) (jolt-vector _o$1886 _o$1887 _o$1888)))) (jolt-vector _o$1889 _o$1890))) jolt-nil)))) (if (jolt= type (keyword #f "separator")) (if (jolt-truthy? saw-else) (jolt-invoke (var-deref "clojure.pprint" "format-error") "A plain clause (with \"~;\") follows an else clause (\"~:;\") inside bracket construction." offset) (if (jolt-not (jolt-get bracket-info (keyword #f "allows-separator"))) (jolt-invoke (var-deref "clojure.pprint" "format-error") "A separator (\"~;\") is in a bracket type that doesn't support it." offset) (if #t (let* ((_o$1896 #t) (_o$1897 (let* ((_o$1893 (jolt-invoke (var-deref "clojure.core" "merge-with") jolt-concat clause-map (let* ((_o$1891 (keyword #f "clauses")) (_o$1892 (jolt-vector clause))) (jolt-hash-map _o$1891 _o$1892)))) (_o$1894 #f) (_o$1895 remainder)) (jolt-vector _o$1893 _o$1894 _o$1895)))) (jolt-vector _o$1896 _o$1897)) jolt-nil))) jolt-nil)))))))) (_a$1905 (let* ((_o$1900 (let* ((_o$1898 (keyword #f "clauses")) (_o$1899 (jolt-vector))) (jolt-hash-map _o$1898 _o$1899))) (_o$1901 #f) (_o$1902 remainder)) (jolt-vector _o$1900 _o$1901 _o$1902)))) (jolt-invoke _a$1903 _a$1904 _a$1905))))))) collect-clauses))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "process-nesting" (letrec ((process-nesting (lambda (format) (let fnrec2246 ((format format)) (jolt-first (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (remainder) (let fnrec2247 ((remainder remainder)) (let* ((this (jolt-first remainder)) (remainder (jolt-next remainder)) (bracket (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")))) (if (jolt-truthy? (jolt-get bracket (keyword #f "right"))) (jolt-invoke (var-deref "clojure.pprint" "process-bracket") this remainder) (let* ((_o$2248 this) (_o$2249 remainder)) (jolt-vector _o$2248 _o$2249)))))) format)))))) process-nesting) (let* ((_o$2250 (keyword #f "private")) (_o$2251 #t)) (jolt-hash-map _o$2250 _o$2251)))) + (def-var! "clojure.pprint" "process-nesting" (letrec ((process-nesting (lambda (format) (let fnrec1906 ((format format)) (jolt-first (jolt-invoke (var-deref "clojure.pprint" "consume") (lambda (remainder) (let fnrec1907 ((remainder remainder)) (let* ((this (jolt-first remainder)) (remainder (jolt-next remainder)) (bracket (jolt-get (jolt-get this (keyword #f "dirdef")) (keyword #f "bracket-info")))) (if (jolt-truthy? (jolt-get bracket (keyword #f "right"))) (jolt-invoke (var-deref "clojure.pprint" "process-bracket") this remainder) (let* ((_o$1908 this) (_o$1909 remainder)) (jolt-vector _o$1908 _o$1909)))))) format)))))) process-nesting))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "compile-format" (letrec ((compile-format (lambda (format-str) (let fnrec2252 ((format-str format-str)) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*format-str*") format-str))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "process-nesting") (jolt-first (let* ((_a$2269 (var-deref "clojure.pprint" "consume")) (_a$2270 (lambda (G__98) (let fnrec2253 ((G__98 G__98)) (let* ((G__99 G__98) (s (jolt-nth G__99 0 jolt-nil)) (offset (jolt-nth G__99 1 jolt-nil))) (if (jolt-empty? s) (let* ((_o$2254 jolt-nil) (_o$2255 s)) (jolt-vector _o$2254 _o$2255)) (let* ((tilde (record-method-dispatch s "indexOf" (jolt-vector "~")))) (if (jolt-neg? tilde) (let* ((_o$2258 (jolt-invoke (var-deref "clojure.pprint" "compile-raw-string") s offset)) (_o$2259 (let* ((_o$2256 "") (_o$2257 (jolt-n+ offset (jolt-count s)))) (jolt-vector _o$2256 _o$2257)))) (jolt-vector _o$2258 _o$2259)) (if (jolt-zero? tilde) (let* ((_a$2260 (var-deref "clojure.pprint" "compile-directive")) (_a$2261 (jolt-invoke (var-deref "clojure.core" "subs") s 1)) (_a$2262 (jolt-inc offset))) (jolt-invoke _a$2260 _a$2261 _a$2262)) (if #t (let* ((_o$2265 (jolt-invoke (var-deref "clojure.pprint" "compile-raw-string") (jolt-invoke (var-deref "clojure.core" "subs") s 0 tilde) offset)) (_o$2266 (let* ((_o$2263 (jolt-invoke (var-deref "clojure.core" "subs") s tilde)) (_o$2264 (jolt-n+ tilde offset))) (jolt-vector _o$2263 _o$2264)))) (jolt-vector _o$2265 _o$2266)) jolt-nil))))))))) (_a$2271 (let* ((_o$2267 format-str) (_o$2268 0)) (jolt-vector _o$2267 _o$2268)))) (jolt-invoke _a$2269 _a$2270 _a$2271))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))))) compile-format) (let* ((_o$2272 (keyword #f "private")) (_o$2273 #t)) (jolt-hash-map _o$2272 _o$2273)))) + (def-var! "clojure.pprint" "compile-format" (letrec ((compile-format (lambda (format-str) (let fnrec1910 ((format-str format-str)) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*format-str*") format-str))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (jolt-invoke (var-deref "clojure.pprint" "process-nesting") (jolt-first (let* ((_a$1927 (var-deref "clojure.pprint" "consume")) (_a$1928 (lambda (G__90) (let fnrec1911 ((G__90 G__90)) (let* ((G__91 G__90) (s (jolt-nth G__91 0 jolt-nil)) (offset (jolt-nth G__91 1 jolt-nil))) (if (jolt-empty? s) (let* ((_o$1912 jolt-nil) (_o$1913 s)) (jolt-vector _o$1912 _o$1913)) (let* ((tilde (record-method-dispatch s "indexOf" (jolt-vector "~")))) (if (jolt-neg? tilde) (let* ((_o$1916 (jolt-invoke (var-deref "clojure.pprint" "compile-raw-string") s offset)) (_o$1917 (let* ((_o$1914 "") (_o$1915 (+ offset (jolt-count s)))) (jolt-vector _o$1914 _o$1915)))) (jolt-vector _o$1916 _o$1917)) (if (jolt-zero? tilde) (let* ((_a$1918 (var-deref "clojure.pprint" "compile-directive")) (_a$1919 (jolt-invoke (var-deref "clojure.core" "subs") s 1)) (_a$1920 (jolt-inc offset))) (jolt-invoke _a$1918 _a$1919 _a$1920)) (if #t (let* ((_o$1923 (jolt-invoke (var-deref "clojure.pprint" "compile-raw-string") (jolt-invoke (var-deref "clojure.core" "subs") s 0 tilde) offset)) (_o$1924 (let* ((_o$1921 (jolt-invoke (var-deref "clojure.core" "subs") s tilde)) (_o$1922 (+ tilde offset))) (jolt-vector _o$1921 _o$1922)))) (jolt-vector _o$1923 _o$1924)) jolt-nil))))))))) (_a$1929 (let* ((_o$1925 format-str) (_o$1926 0)) (jolt-vector _o$1925 _o$1926)))) (jolt-invoke _a$1927 _a$1928 _a$1929))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings")))))))))) compile-format))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "needs-pretty" (letrec ((needs-pretty (lambda (format) (let fnrec2274 ((format format)) (let* ((format format)) (let loop2275 ((format format)) (if (jolt-empty? format) #f (if (jolt-truthy? (let* ((or__26__auto (jolt-get (jolt-get (jolt-get (jolt-first format) (keyword #f "dirdef")) (keyword #f "flags")) (keyword #f "pretty")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "some") needs-pretty (jolt-first (jolt-get (jolt-get (jolt-first format) (keyword #f "params")) (keyword #f "clauses")))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") needs-pretty (jolt-first (jolt-get (jolt-get (jolt-first format) (keyword #f "params")) (keyword #f "else"))))))))) #t (loop2275 (jolt-next format)))))))))) needs-pretty) (let* ((_o$2276 (keyword #f "private")) (_o$2277 #t)) (jolt-hash-map _o$2276 _o$2277)))) + (def-var! "clojure.pprint" "needs-pretty" (letrec ((needs-pretty (lambda (format) (let fnrec1930 ((format format)) (let* ((format format)) (let loop1931 ((format format)) (if (jolt-empty? format) #f (if (jolt-truthy? (let* ((or__26__auto (jolt-get (jolt-get (jolt-get (jolt-first format) (keyword #f "dirdef")) (keyword #f "flags")) (keyword #f "pretty")))) (if (jolt-truthy? or__26__auto) or__26__auto (let* ((or__26__auto (jolt-invoke (var-deref "clojure.core" "some") needs-pretty (jolt-first (jolt-get (jolt-get (jolt-first format) (keyword #f "params")) (keyword #f "clauses")))))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "some") needs-pretty (jolt-first (jolt-get (jolt-get (jolt-first format) (keyword #f "params")) (keyword #f "else"))))))))) #t (loop1931 (jolt-next format)))))))))) needs-pretty))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "execute-format" (letrec ((execute-format (case-lambda ((stream format args) (let fnrec2278 ((stream stream) (format format) (args args)) (let* ((sb (host-new "StringBuilder")) (real-stream (if (jolt-truthy? (let* ((or__26__auto (jolt-not stream))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") stream)))) (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb) stream)) (wrapped-stream (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "needs-pretty") format))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") real-stream)) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "get-pretty-writer") real-stream) real-stream))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") wrapped-stream))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (dynamic-wind (lambda () #f) (lambda () (execute-format format args)) (lambda () (if (jolt-not (jolt-invoke (var-deref "clojure.core" "identical?") real-stream wrapped-stream)) (jolt-invoke (var-deref "clojure.pprint" "-pflush") wrapped-stream) jolt-nil))) (if (jolt-not stream) (jolt-invoke (var-deref "clojure.core" "str") sb) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "true?") stream)) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) ((format args) (let fnrec2279 ((format format) (args args)) (begin (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (lambda (element context) (let fnrec2280 ((element element) (context context)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "abort?") context)) (let* ((_o$2281 jolt-nil) (_o$2282 context)) (jolt-vector _o$2281 _o$2282)) (let* ((G__100 (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") (jolt-get element (keyword #f "params")) context)) (params (jolt-nth G__100 0 jolt-nil)) (args (jolt-nth G__100 1 jolt-nil)) (G__101 (jolt-invoke (var-deref "clojure.pprint" "unzip-map") params)) (params (jolt-nth G__101 0 jolt-nil)) (offsets (jolt-nth G__101 1 jolt-nil)) (params (jolt-assoc params (keyword #f "base-args") args))) (let* ((_o$2288 jolt-nil) (_o$2289 (let* ((_a$2286 (jolt-get element (keyword #f "func"))) (_a$2287 (let* ((_o$2283 params) (_o$2284 args) (_o$2285 offsets)) (jolt-vector _o$2283 _o$2284 _o$2285)))) (jolt-apply _a$2286 _a$2287)))) (jolt-vector _o$2288 _o$2289)))))) args format) jolt-nil)))))) execute-format) (let* ((_o$2290 (keyword #f "private")) (_o$2291 #t)) (jolt-hash-map _o$2290 _o$2291)))) + (def-var! "clojure.pprint" "execute-format" (letrec ((execute-format (case-lambda ((stream format args) (let fnrec1932 ((stream stream) (format format) (args args)) (let* ((sb (host-new "StringBuilder")) (real-stream (if (jolt-truthy? (let* ((or__26__auto (jolt-not stream))) (if (jolt-truthy? or__26__auto) or__26__auto (jolt-invoke (var-deref "clojure.core" "true?") stream)))) (jolt-invoke (var-deref "clojure.pprint" "->StringBufferWriter") sb) stream)) (wrapped-stream (if (jolt-truthy? (let* ((and__25__auto (jolt-invoke (var-deref "clojure.pprint" "needs-pretty") format))) (if (jolt-truthy? and__25__auto) (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pretty-writer?") real-stream)) and__25__auto))) (jolt-invoke (var-deref "clojure.pprint" "get-pretty-writer") real-stream) real-stream))) (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.core" "*out*") wrapped-stream))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (dynamic-wind (lambda () #f) (lambda () (jolt-invoke execute-format format args)) (lambda () (if (jolt-not (jolt-invoke (var-deref "clojure.core" "identical?") real-stream wrapped-stream)) (jolt-invoke (var-deref "clojure.pprint" "-pflush") wrapped-stream) jolt-nil))) (if (jolt-not stream) (jolt-invoke (var-deref "clojure.core" "str") sb) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "true?") stream)) (jolt-invoke (var-deref "clojure.core" "print") (jolt-invoke (var-deref "clojure.core" "str") sb)) (if (jolt-truthy? (keyword #f "else")) jolt-nil jolt-nil))))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))))) ((format args) (let fnrec1933 ((format format) (args args)) (begin (jolt-invoke (var-deref "clojure.pprint" "map-passing-context") (lambda (element context) (let fnrec1934 ((element element) (context context)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "abort?") context)) (let* ((_o$1935 jolt-nil) (_o$1936 context)) (jolt-vector _o$1935 _o$1936)) (let* ((G__92 (jolt-invoke (var-deref "clojure.pprint" "realize-parameter-list") (jolt-get element (keyword #f "params")) context)) (params (jolt-nth G__92 0 jolt-nil)) (args (jolt-nth G__92 1 jolt-nil)) (G__93 (jolt-invoke (var-deref "clojure.pprint" "unzip-map") params)) (params (jolt-nth G__93 0 jolt-nil)) (offsets (jolt-nth G__93 1 jolt-nil)) (params (jolt-assoc params (keyword #f "base-args") args))) (let* ((_o$1942 jolt-nil) (_o$1943 (let* ((_a$1940 (jolt-get element (keyword #f "func"))) (_a$1941 (let* ((_o$1937 params) (_o$1938 args) (_o$1939 offsets)) (jolt-vector _o$1937 _o$1938 _o$1939)))) (jolt-apply _a$1940 _a$1941)))) (jolt-vector _o$1942 _o$1943)))))) args format) jolt-nil)))))) execute-format))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "cached-compile" (jolt-invoke (var-deref "clojure.core" "memoize") (var-deref "clojure.pprint" "compile-format")) (let* ((_o$2292 (keyword #f "private")) (_o$2293 #t)) (jolt-hash-map _o$2292 _o$2293)))) + (def-var-with-meta! "clojure.pprint" "cached-compile" (jolt-invoke (var-deref "clojure.core" "memoize") (var-deref "clojure.pprint" "compile-format")) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "reader-macros" (let* ((_o$2294 (jolt-symbol #f "quote")) (_o$2295 "'") (_o$2296 (jolt-symbol #f "var")) (_o$2297 "#'") (_o$2298 (jolt-symbol "clojure.core" "deref")) (_o$2299 "@") (_o$2300 (jolt-symbol "clojure.core" "unquote")) (_o$2301 "~")) (jolt-hash-map _o$2294 _o$2295 _o$2296 _o$2297 _o$2298 _o$2299 _o$2300 _o$2301)) (let* ((_o$2302 (keyword #f "private")) (_o$2303 #t)) (jolt-hash-map _o$2302 _o$2303)))) + (def-var-with-meta! "clojure.pprint" "reader-macros" (let* ((_o$1944 (jolt-symbol #f "quote")) (_o$1945 "'") (_o$1946 (jolt-symbol #f "var")) (_o$1947 "#'") (_o$1948 (jolt-symbol "clojure.core" "deref")) (_o$1949 "@") (_o$1950 (jolt-symbol "clojure.core" "unquote")) (_o$1951 "~")) (jolt-hash-map _o$1944 _o$1945 _o$1946 _o$1947 _o$1948 _o$1949 _o$1950 _o$1951)) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-reader-macro" (letrec ((pprint-reader-macro (lambda (alis) (let fnrec2304 ((alis alis)) (let* ((macro-char (jolt-invoke (var-deref "clojure.pprint" "reader-macros") (jolt-first alis)))) (if (jolt-truthy? (let* ((and__25__auto macro-char)) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count alis)) and__25__auto))) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") macro-char) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "second") alis)) #t) jolt-nil)))))) pprint-reader-macro) (let* ((_o$2305 (keyword #f "private")) (_o$2306 #t)) (jolt-hash-map _o$2305 _o$2306)))) + (def-var! "clojure.pprint" "pprint-reader-macro" (letrec ((pprint-reader-macro (lambda (alis) (let fnrec1952 ((alis alis)) (let* ((macro-char (jolt-invoke (var-deref "clojure.pprint" "reader-macros") (jolt-first alis)))) (if (jolt-truthy? (let* ((and__25__auto macro-char)) (if (jolt-truthy? and__25__auto) (jolt= 2 (jolt-count alis)) and__25__auto))) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") macro-char) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "second") alis)) #t) jolt-nil)))))) pprint-reader-macro))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-simple-list" (letrec ((pprint-simple-list (lambda (alis) (let fnrec2307 ((alis alis)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "(" jolt-nil ")") (let* ((alis (jolt-seq alis))) (let loop2308 ((alis alis)) (if (jolt-truthy? alis) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first alis)) (if (jolt-truthy? (jolt-next alis)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop2308 (jolt-next alis))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-simple-list) (let* ((_o$2309 (keyword #f "private")) (_o$2310 #t)) (jolt-hash-map _o$2309 _o$2310)))) + (def-var! "clojure.pprint" "pprint-simple-list" (letrec ((pprint-simple-list (lambda (alis) (let fnrec1953 ((alis alis)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "(" jolt-nil ")") (let* ((alis (jolt-seq alis))) (let loop1954 ((alis alis)) (if (jolt-truthy? alis) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first alis)) (if (jolt-truthy? (jolt-next alis)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop1954 (jolt-next alis))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-simple-list))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-list" (letrec ((pprint-list (lambda (alis) (let fnrec2311 ((alis alis)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pprint-reader-macro") alis)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-list") alis) jolt-nil))))) pprint-list) (let* ((_o$2312 (keyword #f "private")) (_o$2313 #t)) (jolt-hash-map _o$2312 _o$2313)))) + (def-var! "clojure.pprint" "pprint-list" (letrec ((pprint-list (lambda (alis) (let fnrec1955 ((alis alis)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pprint-reader-macro") alis)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-list") alis) jolt-nil))))) pprint-list))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-vector" (letrec ((pprint-vector (lambda (avec) (let fnrec2314 ((avec avec)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "[" jolt-nil "]") (let* ((aseq (jolt-seq avec))) (let loop2315 ((aseq aseq)) (if (jolt-truthy? aseq) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first aseq)) (if (jolt-truthy? (jolt-next aseq)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop2315 (jolt-next aseq))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-vector) (let* ((_o$2316 (keyword #f "private")) (_o$2317 #t)) (jolt-hash-map _o$2316 _o$2317)))) + (def-var! "clojure.pprint" "pprint-vector" (letrec ((pprint-vector (lambda (avec) (let fnrec1956 ((avec avec)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "[" jolt-nil "]") (let* ((aseq (jolt-seq avec))) (let loop1957 ((aseq aseq)) (if (jolt-truthy? aseq) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first aseq)) (if (jolt-truthy? (jolt-next aseq)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop1957 (jolt-next aseq))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-vector))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-array" (let* ((format-in__5__auto "~<[~;~@{~w~^, ~:_~}~;]~:>") (cf__3__auto (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in__5__auto)) (jolt-invoke (var-deref "clojure.pprint" "cached-compile") format-in__5__auto) format-in__5__auto))) (lambda args__4__auto (let fnrec2318 ((args__4__auto (list->cseq args__4__auto))) (let* ((navigator__2__auto (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args__4__auto))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") cf__3__auto navigator__2__auto))))) (let* ((_o$2319 (keyword #f "private")) (_o$2320 #t)) (jolt-hash-map _o$2319 _o$2320)))) + (def-var-with-meta! "clojure.pprint" "pprint-array" (let* ((format-in__5__auto "~<[~;~@{~w~^, ~:_~}~;]~:>") (cf__3__auto (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in__5__auto)) (jolt-invoke (var-deref "clojure.pprint" "cached-compile") format-in__5__auto) format-in__5__auto))) (lambda args__4__auto (let fnrec1958 ((args__4__auto (list->cseq args__4__auto))) (let* ((navigator__2__auto (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args__4__auto))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") cf__3__auto navigator__2__auto))))) (jolt-hash-map (keyword #f "private") #t))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-map" (letrec ((pprint-map (lambda (amap) (let fnrec2321 ((amap amap)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "{" jolt-nil "}") (let* ((aseq (jolt-seq amap))) (let loop2322 ((aseq aseq)) (if (jolt-truthy? aseq) (begin (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") jolt-nil jolt-nil jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "ffirst") aseq)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (jolt-var-set (jolt-var "clojure.pprint" "*current-length*") 0) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "fnext") (jolt-first aseq))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil) (if (jolt-truthy? (jolt-next aseq)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") ", ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop2322 (jolt-next aseq))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-map) (let* ((_o$2323 (keyword #f "private")) (_o$2324 #t)) (jolt-hash-map _o$2323 _o$2324)))) + (def-var! "clojure.pprint" "pprint-map" (letrec ((pprint-map (lambda (amap) (let fnrec1959 ((amap amap)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "{" jolt-nil "}") (let* ((aseq (jolt-seq amap))) (let loop1960 ((aseq aseq)) (if (jolt-truthy? aseq) (begin (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") jolt-nil jolt-nil jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "ffirst") aseq)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (jolt-var-set (jolt-var "clojure.pprint" "*current-length*") 0) (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-invoke (var-deref "clojure.core" "fnext") (jolt-first aseq))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil) (if (jolt-truthy? (jolt-next aseq)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") ", ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop1960 (jolt-next aseq))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-map))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-simple-default" (letrec ((pprint-simple-default (lambda (obj) (let fnrec2325 ((obj obj)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.core" "pr-str") obj)))))) pprint-simple-default) (let* ((_o$2326 (keyword #f "private")) (_o$2327 #t)) (jolt-hash-map _o$2326 _o$2327)))) + (def-var! "clojure.pprint" "pprint-simple-default" (letrec ((pprint-simple-default (lambda (obj) (let fnrec1961 ((obj obj)) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.core" "pr-str") obj)))))) pprint-simple-default))) (guard (e (#t #f)) - (def-var! "clojure.pprint" "pprint-set" (let* ((format-in__5__auto "~<#{~;~@{~w~^ ~:_~}~;}~:>") (cf__3__auto (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in__5__auto)) (jolt-invoke (var-deref "clojure.pprint" "cached-compile") format-in__5__auto) format-in__5__auto))) (lambda args__4__auto (let fnrec2328 ((args__4__auto (list->cseq args__4__auto))) (let* ((navigator__2__auto (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args__4__auto))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") cf__3__auto navigator__2__auto))))))) + (def-var! "clojure.pprint" "pprint-set" (let* ((format-in__5__auto "~<#{~;~@{~w~^ ~:_~}~;}~:>") (cf__3__auto (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "string?") format-in__5__auto)) (jolt-invoke (var-deref "clojure.pprint" "cached-compile") format-in__5__auto) format-in__5__auto))) (lambda args__4__auto (let fnrec1962 ((args__4__auto (list->cseq args__4__auto))) (let* ((navigator__2__auto (jolt-invoke (var-deref "clojure.pprint" "init-navigator") args__4__auto))) (jolt-invoke (var-deref "clojure.pprint" "execute-format") cf__3__auto navigator__2__auto))))))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "type-dispatcher" (letrec ((type-dispatcher (lambda (obj) (let fnrec2329 ((obj obj)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") obj)) (keyword #f "symbol") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") obj)) (keyword #f "list") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") obj)) (keyword #f "map") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") obj)) (keyword #f "vector") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") obj)) (keyword #f "set") (if (jolt-nil? obj) jolt-nil (if (jolt-truthy? (keyword #f "else")) (keyword #f "default") jolt-nil))))))))))) type-dispatcher) (let* ((_o$2330 (keyword #f "private")) (_o$2331 #t)) (jolt-hash-map _o$2330 _o$2331)))) + (def-var! "clojure.pprint" "type-dispatcher" (letrec ((type-dispatcher (lambda (obj) (let fnrec1963 ((obj obj)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "symbol?") obj)) (keyword #f "symbol") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "seq?") obj)) (keyword #f "list") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "map?") obj)) (keyword #f "map") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") obj)) (keyword #f "vector") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "set?") obj)) (keyword #f "set") (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "nil?") obj)) jolt-nil (if (jolt-truthy? (keyword #f "else")) (keyword #f "default") jolt-nil))))))))))) type-dispatcher))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "simple-dispatch" (letrec ((simple-dispatch (lambda (obj) (let fnrec2332 ((obj obj)) (let* ((G__102 (jolt-invoke (var-deref "clojure.pprint" "type-dispatcher") obj))) (if (jolt= G__102 (keyword #f "list")) (jolt-invoke (var-deref "clojure.pprint" "pprint-list") obj) (if (jolt= G__102 (keyword #f "vector")) (jolt-invoke (var-deref "clojure.pprint" "pprint-vector") obj) (if (jolt= G__102 (keyword #f "map")) (jolt-invoke (var-deref "clojure.pprint" "pprint-map") obj) (if (jolt= G__102 (keyword #f "set")) (jolt-invoke (var-deref "clojure.pprint" "pprint-set") obj) (if (jolt= G__102 jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.core" "pr-str") jolt-nil)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-default") obj))))))))))) simple-dispatch) (let* ((_o$2333 (keyword #f "doc")) (_o$2334 "The pretty print dispatch function for simple data structure format.")) (jolt-hash-map _o$2333 _o$2334)))) + (def-var! "clojure.pprint" "simple-dispatch" (letrec ((simple-dispatch (lambda (obj) (let fnrec1964 ((obj obj)) (let* ((G__94 (jolt-invoke (var-deref "clojure.pprint" "type-dispatcher") obj))) (if (jolt= G__94 (keyword #f "list")) (jolt-invoke (var-deref "clojure.pprint" "pprint-list") obj) (if (jolt= G__94 (keyword #f "vector")) (jolt-invoke (var-deref "clojure.pprint" "pprint-vector") obj) (if (jolt= G__94 (keyword #f "map")) (jolt-invoke (var-deref "clojure.pprint" "pprint-map") obj) (if (jolt= G__94 (keyword #f "set")) (jolt-invoke (var-deref "clojure.pprint" "pprint-set") obj) (if (jolt= G__94 jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") (jolt-invoke (var-deref "clojure.core" "pr-str") jolt-nil)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-default") obj))))))))))) simple-dispatch))) (guard (e (#t #f)) (declare-var! "clojure.pprint" "pprint-simple-code-list")) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "brackets" (letrec ((brackets (lambda (form) (let fnrec2335 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (let* ((_o$2336 "[") (_o$2337 "]")) (jolt-vector _o$2336 _o$2337)) (let* ((_o$2338 "(") (_o$2339 ")")) (jolt-vector _o$2338 _o$2339))))))) brackets) (let* ((_o$2340 (keyword #f "private")) (_o$2341 #t)) (jolt-hash-map _o$2340 _o$2341)))) + (def-var! "clojure.pprint" "brackets" (letrec ((brackets (lambda (form) (let fnrec1965 ((form form)) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "vector?") form)) (let* ((_o$1966 "[") (_o$1967 "]")) (jolt-vector _o$1966 _o$1967)) (let* ((_o$1968 "(") (_o$1969 ")")) (jolt-vector _o$1968 _o$1969))))))) brackets))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-simple-code-list" (letrec ((pprint-simple-code-list (lambda (alis) (let fnrec2342 ((alis alis)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "(" jolt-nil ")") (jolt-invoke (var-deref "clojure.pprint" "pprint-indent") (keyword #f "block") 1) (let* ((alis (jolt-seq alis))) (let loop2343 ((alis alis)) (if (jolt-truthy? alis) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first alis)) (if (jolt-truthy? (jolt-next alis)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop2343 (jolt-next alis))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-simple-code-list) (let* ((_o$2344 (keyword #f "private")) (_o$2345 #t)) (jolt-hash-map _o$2344 _o$2345)))) + (def-var! "clojure.pprint" "pprint-simple-code-list" (letrec ((pprint-simple-code-list (lambda (alis) (let fnrec1970 ((alis alis)) (begin (if (jolt-truthy? (jolt-invoke (var-deref "clojure.pprint" "level-exceeded"))) (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") "#") (let* ((frame__20__auto (jolt-invoke (var-deref "clojure.core" "array-map") (jolt-var "clojure.pprint" "*current-level*") (jolt-inc (var-deref "clojure.pprint" "*current-level*")) (jolt-var "clojure.pprint" "*current-length*") 0))) (begin (jolt-invoke (var-deref "clojure.core" "push-thread-bindings") frame__20__auto) (dynamic-wind (lambda () #f) (lambda () (begin (jolt-invoke (var-deref "clojure.pprint" "start-block") (var-deref "clojure.core" "*out*") "(" jolt-nil ")") (jolt-invoke (var-deref "clojure.pprint" "pprint-indent") (keyword #f "block") 1) (let* ((alis (jolt-seq alis))) (let loop1971 ((alis alis)) (if (jolt-truthy? alis) (begin (jolt-invoke (var-deref "clojure.pprint" "write-out") (jolt-first alis)) (if (jolt-truthy? (jolt-next alis)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") (var-deref "clojure.core" "*out*") " ") (jolt-invoke (var-deref "clojure.pprint" "pprint-newline") (keyword #f "linear")) (loop1971 (jolt-next alis))) jolt-nil)) jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "end-block") (var-deref "clojure.core" "*out*")))) (lambda () (jolt-invoke (var-deref "clojure.core" "pop-thread-bindings"))))))) jolt-nil))))) pprint-simple-code-list))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-code-list" (letrec ((pprint-code-list (lambda (alis) (let fnrec2346 ((alis alis)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pprint-reader-macro") alis)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-code-list") alis) jolt-nil))))) pprint-code-list) (let* ((_o$2347 (keyword #f "private")) (_o$2348 #t)) (jolt-hash-map _o$2347 _o$2348)))) + (def-var! "clojure.pprint" "pprint-code-list" (letrec ((pprint-code-list (lambda (alis) (let fnrec1972 ((alis alis)) (if (jolt-not (jolt-invoke (var-deref "clojure.pprint" "pprint-reader-macro") alis)) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-code-list") alis) jolt-nil))))) pprint-code-list))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "pprint-code-symbol" (letrec ((pprint-code-symbol (lambda (sym) (let fnrec2349 ((sym sym)) (if (jolt-truthy? (var-deref "clojure.pprint" "*print-suppress-namespaces*")) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "name") sym)) (jolt-invoke (var-deref "clojure.pprint" "pr") sym)))))) pprint-code-symbol) (let* ((_o$2350 (keyword #f "private")) (_o$2351 #t)) (jolt-hash-map _o$2350 _o$2351)))) + (def-var! "clojure.pprint" "pprint-code-symbol" (letrec ((pprint-code-symbol (lambda (sym) (let fnrec1973 ((sym sym)) (if (jolt-truthy? (var-deref "clojure.pprint" "*print-suppress-namespaces*")) (jolt-invoke (var-deref "clojure.pprint" "print") (jolt-invoke (var-deref "clojure.core" "name") sym)) (jolt-invoke (var-deref "clojure.pprint" "pr") sym)))))) pprint-code-symbol))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "code-dispatch" (letrec ((code-dispatch (lambda (obj) (let fnrec2352 ((obj obj)) (let* ((G__103 (jolt-invoke (var-deref "clojure.pprint" "type-dispatcher") obj))) (if (jolt= G__103 (keyword #f "list")) (jolt-invoke (var-deref "clojure.pprint" "pprint-code-list") obj) (if (jolt= G__103 (keyword #f "symbol")) (jolt-invoke (var-deref "clojure.pprint" "pprint-code-symbol") obj) (if (jolt= G__103 (keyword #f "vector")) (jolt-invoke (var-deref "clojure.pprint" "pprint-vector") obj) (if (jolt= G__103 (keyword #f "map")) (jolt-invoke (var-deref "clojure.pprint" "pprint-map") obj) (if (jolt= G__103 (keyword #f "set")) (jolt-invoke (var-deref "clojure.pprint" "pprint-set") obj) (if (jolt= G__103 jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "pr") obj) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-default") obj)))))))))))) code-dispatch) (let* ((_o$2353 (keyword #f "doc")) (_o$2354 "The pretty print dispatch function for pretty printing Clojure code.")) (jolt-hash-map _o$2353 _o$2354)))) + (def-var! "clojure.pprint" "code-dispatch" (letrec ((code-dispatch (lambda (obj) (let fnrec1974 ((obj obj)) (let* ((G__95 (jolt-invoke (var-deref "clojure.pprint" "type-dispatcher") obj))) (if (jolt= G__95 (keyword #f "list")) (jolt-invoke (var-deref "clojure.pprint" "pprint-code-list") obj) (if (jolt= G__95 (keyword #f "symbol")) (jolt-invoke (var-deref "clojure.pprint" "pprint-code-symbol") obj) (if (jolt= G__95 (keyword #f "vector")) (jolt-invoke (var-deref "clojure.pprint" "pprint-vector") obj) (if (jolt= G__95 (keyword #f "map")) (jolt-invoke (var-deref "clojure.pprint" "pprint-map") obj) (if (jolt= G__95 (keyword #f "set")) (jolt-invoke (var-deref "clojure.pprint" "pprint-set") obj) (if (jolt= G__95 jolt-nil) (jolt-invoke (var-deref "clojure.pprint" "pr") obj) (jolt-invoke (var-deref "clojure.pprint" "pprint-simple-default") obj)))))))))))) code-dispatch))) (guard (e (#t #f)) (jolt-invoke (var-deref "clojure.core" "alter-var-root") (jolt-var "clojure.pprint" "*print-pprint-dispatch*") (jolt-invoke (var-deref "clojure.core" "constantly") (var-deref "clojure.pprint" "simple-dispatch")))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "add-padding" (letrec ((add-padding (lambda (width s) (let fnrec2355 ((width width) (s s)) (let* ((padding (jolt-n-max 0 (jolt-n- width (jolt-count s))))) (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.string" "join") (jolt-invoke (var-deref "clojure.core" "repeat") padding (integer->char 32))) s)))))) add-padding) (let* ((_o$2356 (keyword #f "private")) (_o$2357 #t)) (jolt-hash-map _o$2356 _o$2357)))) + (def-var! "clojure.pprint" "add-padding" (letrec ((add-padding (lambda (width s) (let fnrec1975 ((width width) (s s)) (let* ((padding (max 0 (- width (jolt-count s))))) (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.string" "join") (jolt-invoke (var-deref "clojure.core" "repeat") padding (integer->char 32))) s)))))) add-padding))) (guard (e (#t #f)) - (def-var-with-meta! "clojure.pprint" "print-table" (letrec ((print-table (case-lambda ((ks rows) (let fnrec2358 ((ks ks) (rows rows)) (if (jolt-truthy? (jolt-seq rows)) (let* ((widths (jolt-map (lambda (k) (let fnrec2359 ((k k)) (let* ((_a$2361 jolt-max) (_a$2362 (jolt-count (jolt-invoke (var-deref "clojure.core" "str") k))) (_a$2363 (jolt-map (lambda (p__39_) (let fnrec2360 ((p__39_ p__39_)) (jolt-count (jolt-invoke (var-deref "clojure.core" "str") (jolt-get p__39_ k))))) rows))) (jolt-apply _a$2361 _a$2362 _a$2363)))) ks)) (spacers (jolt-map (lambda (p__40_) (let fnrec2364 ((p__40_ p__40_)) (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") p__40_ "-")))) widths)) (fmt-row (lambda (leader divider trailer row) (let fnrec2365 ((leader leader) (divider divider) (trailer trailer) (row row)) (jolt-invoke (var-deref "clojure.core" "str") leader (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "interpose") divider (let* ((_a$2368 (lambda (G__104) (let fnrec2366 ((G__104 G__104)) (let* ((G__105 G__104) (col (jolt-nth G__105 0 jolt-nil)) (width (jolt-nth G__105 1 jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "add-padding") width (jolt-invoke (var-deref "clojure.core" "str") col)))))) (_a$2369 (jolt-map jolt-vector (jolt-map (lambda (p__41_) (let fnrec2367 ((p__41_ p__41_)) (jolt-get row p__41_))) ks) widths))) (jolt-map _a$2368 _a$2369)))) trailer))))) (begin (jolt-invoke (var-deref "clojure.core" "println")) (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "| " " | " " |" (jolt-invoke (var-deref "clojure.core" "zipmap") ks ks))) (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "|-" "-+-" "-|" (jolt-invoke (var-deref "clojure.core" "zipmap") ks spacers))) (begin (jolt-count (jolt-map (lambda (row) (let fnrec2370 ((row row)) (begin (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "| " " | " " |" row)) jolt-nil))) rows)) jolt-nil))) jolt-nil))) ((rows) (let fnrec2371 ((rows rows)) (print-table (jolt-keys (jolt-first rows)) rows)))))) print-table) (let* ((_o$2372 (keyword #f "doc")) (_o$2373 "Prints a collection of maps in a textual table.")) (jolt-hash-map _o$2372 _o$2373)))) + (def-var! "clojure.pprint" "print-table" (letrec ((print-table (case-lambda ((ks rows) (let fnrec1976 ((ks ks) (rows rows)) (if (jolt-truthy? (jolt-seq rows)) (let* ((widths (jolt-map (lambda (k) (let fnrec1977 ((k k)) (let* ((_a$1979 max) (_a$1980 (jolt-count (jolt-invoke (var-deref "clojure.core" "str") k))) (_a$1981 (jolt-map (lambda (p__39_) (let fnrec1978 ((p__39_ p__39_)) (jolt-count (jolt-invoke (var-deref "clojure.core" "str") (jolt-get p__39_ k))))) rows))) (jolt-apply _a$1979 _a$1980 _a$1981)))) ks)) (spacers (jolt-map (lambda (p__40_) (let fnrec1982 ((p__40_ p__40_)) (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "repeat") p__40_ "-")))) widths)) (fmt-row (lambda (leader divider trailer row) (let fnrec1983 ((leader leader) (divider divider) (trailer trailer) (row row)) (jolt-invoke (var-deref "clojure.core" "str") leader (jolt-apply (var-deref "clojure.core" "str") (jolt-invoke (var-deref "clojure.core" "interpose") divider (let* ((_a$1986 (lambda (G__96) (let fnrec1984 ((G__96 G__96)) (let* ((G__97 G__96) (col (jolt-nth G__97 0 jolt-nil)) (width (jolt-nth G__97 1 jolt-nil))) (jolt-invoke (var-deref "clojure.pprint" "add-padding") width (jolt-invoke (var-deref "clojure.core" "str") col)))))) (_a$1987 (jolt-map jolt-vector (jolt-map (lambda (p__41_) (let fnrec1985 ((p__41_ p__41_)) (jolt-get row p__41_))) ks) widths))) (jolt-map _a$1986 _a$1987)))) trailer))))) (begin (jolt-invoke (var-deref "clojure.core" "println")) (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "| " " | " " |" (jolt-invoke (var-deref "clojure.core" "zipmap") ks ks))) (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "|-" "-+-" "-|" (jolt-invoke (var-deref "clojure.core" "zipmap") ks spacers))) (begin (jolt-count (jolt-map (lambda (row) (let fnrec1988 ((row row)) (begin (jolt-invoke (var-deref "clojure.core" "println") (jolt-invoke fmt-row "| " " | " " |" row)) jolt-nil))) rows)) jolt-nil))) jolt-nil))) ((rows) (let fnrec1989 ((rows rows)) (jolt-invoke print-table (jolt-keys (jolt-first rows)) rows)))))) print-table))) (guard (e (#t #f)) - (jolt-invoke (var-deref "clojure.core" "__set-pprint-write-hook!") (lambda (s) (let fnrec2374 ((s s)) (let* ((o (var-deref "clojure.core" "*out*"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "instance-check") (jolt-symbol #f "PrettyWriter") o)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") o s) #t) jolt-nil)))))) \ No newline at end of file + (jolt-invoke (var-deref "clojure.core" "__set-pprint-write-hook!") (lambda (s) (let fnrec1990 ((s s)) (let* ((o (var-deref "clojure.core" "*out*"))) (if (jolt-truthy? (jolt-invoke (var-deref "clojure.core" "instance-check") (jolt-symbol #f "PrettyWriter") o)) (begin (jolt-invoke (var-deref "clojure.pprint" "-write") o s) #t) jolt-nil)))))) \ No newline at end of file diff --git a/host/chez/seq.ss b/host/chez/seq.ss index b10ed50..acc5f8e 100644 --- a/host/chez/seq.ss +++ b/host/chez/seq.ss @@ -31,29 +31,11 @@ ;; cvec is #f for every other seq; stored as two fields (not a cons) so a vector ;; seq cell costs no extra allocation. The rest of the seq layer ignores them, so ;; first/rest/count/printing are unchanged. -;; crest: the ChunkedCons case — cvec holds a STANDALONE chunk pvec (<=32 already- -;; realized elements), ci the offset within it, and crest the seq AFTER the whole -;; chunk (the clojure.lang.ChunkedCons _more). This is what map/filter/range emit -;; so their result is itself a chunked-seq (chained chunked transforms each batch -;; by 32, like the JVM). crest is #f for a plain vector-backed seq (whose "rest" -;; is the next 32-block of the SAME cvec) and for every non-chunked cell. -(define-record-type cseq (fields head (mutable tail) (mutable forced?) list? cvec ci crest) (nongenerative chez-cseq-v4)) -(define (cseq-realized head tail) (make-cseq head tail #t #f #f 0 #f)) ; tail already a seq -(define (cseq-lazy head tail-thunk) (make-cseq head tail-thunk #f #f #f 0 #f)) -(define (cseq-list head tail) (make-cseq head tail #t #t #f 0 #f)) ; a PersistentList node -(define (cseq-vec head tail-thunk v i) (make-cseq head tail-thunk #f #f v i #f)) ; vector-backed -;; A ChunkedCons cell over a standalone chunk pvec: head is chunk[i], walking -;; (seq-more) advances within the chunk and then continues into `rest`. `rest` is -;; the already-coerced after-chunk seq (cseq | jolt-nil | a jolt-lazyseq), held in -;; crest for chunk-rest/chunk-next and forced lazily by the tail thunk at the chunk -;; boundary so a chunked map over an infinite chunked source stays productive. -(define (cseq-chunked chunk i rest) - (make-cseq (pvec-nth-d chunk i jolt-nil) - (lambda () (let ((i1 (fx+ i 1))) - (if (fx ClassCastException. The hooks are BINARY and never re-enter -;; the variadic shims, so extension order can't recurse. -(define (jolt-add-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-sub-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-mul-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-div-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -;; comparison of operands outside the Chez tower: numeric shims extend this to a -;; 3-way compare; anything left over is not a number. -(define (jolt-num-cmp-slow a b) - (jolt-num-cast-throw (if (number? a) b a))) - -(define (jolt-add2 a b) - (if (and (number? a) (number? b)) (+ a b) (jolt-add-slow a b))) -(define (jolt-sub2 a b) - (if (and (number? a) (number? b)) (- a b) (jolt-sub-slow a b))) -(define (jolt-mul2 a b) - (if (and (number? a) (number? b)) - (if (or (flonum? a) (flonum? b)) - (fl* (real->flonum a) (real->flonum b)) - (* a b)) - (jolt-mul-slow a b))) -(define (jolt-div2 a b) - (if (and (number? a) (number? b)) - (if (or (flonum? a) (flonum? b)) - (fl/ (real->flonum a) (real->flonum b)) - (if (eqv? b 0) (jolt-div0-throw) (/ a b))) - (jolt-div-slow a b))) -(define (jolt-lt2 a b) - (if (and (number? a) (number? b)) (< a b) (< (jolt-num-cmp-slow a b) 0))) -(define (jolt-gt2 a b) - (if (and (number? a) (number? b)) (> a b) (> (jolt-num-cmp-slow a b) 0))) -(define (jolt-le2 a b) - (if (and (number? a) (number? b)) (<= a b) (<= (jolt-num-cmp-slow a b) 0))) -(define (jolt-ge2 a b) - (if (and (number? a) (number? b)) (>= a b) (>= (jolt-num-cmp-slow a b) 0))) -;; min/max return the ORIGINAL operand (type and exactness kept, like -;; Numbers.min): (min 1 2.0) is 1, not 1.0. A NaN operand wins. -(define (jolt-min2 a b) - (cond ((and (flonum? a) (nan? a)) a) - ((and (flonum? b) (nan? b)) b) - (else (if (jolt-lt2 a b) a b)))) -(define (jolt-max2 a b) - (cond ((and (flonum? a) (nan? a)) a) - ((and (flonum? b) (nan? b)) b) - (else (if (jolt-gt2 a b) a b)))) - -;; quot/rem/mod over the full tower: truncating division; a double operand makes -;; the result a double; mod has floor semantics (result takes the divisor's -;; sign). A zero divisor throws ArithmeticException in both worlds (JVM double -;; quot/rem check the divisor before dividing). Non-tower operands hit the -;; set!-extensible slow hooks. -(define (jolt-quot-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-rem-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-mod-slow a b) (jolt-num-cast-throw (if (number? a) b a))) -(define (jolt-quot a b) - (cond ((not (and (number? a) (number? b))) (jolt-quot-slow a b)) - ((or (flonum? a) (flonum? b)) - (let ((n (real->flonum a)) (d (real->flonum b))) - (if (fl= d 0.0) (jolt-div0-throw) - (let ((q (fl/ n d))) - (when (or (nan? q) (infinite? q)) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - "Infinite or NaN"))) - (fltruncate q))))) - ((eqv? b 0) (jolt-div0-throw)) - ((and (integer? a) (integer? b)) (quotient a b)) - (else (truncate (/ a b))))) -(define (jolt-rem a b) - (cond ((not (and (number? a) (number? b))) (jolt-rem-slow a b)) - ((or (flonum? a) (flonum? b)) - (let ((n (real->flonum a)) (d (real->flonum b))) - (if (fl= d 0.0) (jolt-div0-throw) - (let ((q (fl/ n d))) - (when (or (nan? q) (infinite? q)) - (jolt-throw (jolt-host-throwable "java.lang.NumberFormatException" - "Infinite or NaN"))) - (fl- n (fl* d (fltruncate q))))))) - ((eqv? b 0) (jolt-div0-throw)) - ((and (integer? a) (integer? b)) (remainder a b)) - (else (- a (* b (truncate (/ a b))))))) -(define (jolt-mod a b) - (cond ((not (and (number? a) (number? b))) (jolt-mod-slow a b)) - ((and (integer? a) (integer? b) (not (flonum? a)) (not (flonum? b))) - (if (eqv? b 0) (jolt-div0-throw) (modulo a b))) - (else - (let ((m (jolt-rem a b))) - (if (or (zero? m) (eq? (negative? m) (negative? b))) m (jolt-add2 m b)))))) - ;; value-position arithmetic (the higher-order forms: (reduce + []), (apply * xs)). -;; Folded through the binary dispatch so contagion/edge rules hold; identities -;; (+)=0 / (*)=1 are exact, matching exact integer arithmetic. The hot path uses -;; the inlined native ops, not these. -;; recognizer for slow-path numeric types; numeric shims extend it. -(define (jolt-num-slow? x) #f) -(define (jolt-num-check1 x) ; (+ x)/(* x) return x but still type-check it - (if (or (number? x) (jolt-num-slow? x)) x (jolt-num-cast-throw x))) -(define (jolt-add . xs) - (cond ((null? xs) 0) - ((null? (cdr xs)) (jolt-num-check1 (car xs))) - (else (fold-left jolt-add2 (car xs) (cdr xs))))) -(define (jolt-arity0-throw name) - (jolt-throw (jolt-host-throwable - "clojure.lang.ArityException" - (string-append "Wrong number of args (0) passed to: clojure.core/" name)))) -(define (jolt-sub . xs) - (cond ((null? xs) (jolt-arity0-throw "-")) - ((null? (cdr xs)) (jolt-sub2 0 (car xs))) - (else (fold-left jolt-sub2 (car xs) (cdr xs))))) -(define (jolt-mul . xs) - (cond ((null? xs) 1) - ((null? (cdr xs)) (jolt-num-check1 (car xs))) - (else (fold-left jolt-mul2 (car xs) (cdr xs))))) -(define (jolt-div . xs) - (cond ((null? xs) (jolt-arity0-throw "/")) - ((null? (cdr xs)) (jolt-div2 1 (car xs))) - (else (fold-left jolt-div2 (car xs) (cdr xs))))) -(define (jolt-min x . xs) (fold-left jolt-min2 x xs)) -(define (jolt-max x . xs) (fold-left jolt-max2 x xs)) -;; variadic comparison chains for value position ((apply < xs)). -(define (jolt-cmp-chain op2) - (lambda (x . xs) - (let loop ((a x) (rest xs)) - (cond ((null? rest) #t) - ((op2 a (car rest)) (loop (car rest) (cdr rest))) - (else #f))))) -(define jolt-lt (jolt-cmp-chain jolt-lt2)) -(define jolt-gt (jolt-cmp-chain jolt-gt2)) -(define jolt-le (jolt-cmp-chain jolt-le2)) -(define jolt-ge (jolt-cmp-chain jolt-ge2)) - -;; call-position arithmetic: inlined macros with the both-Chez-numbers fast path -;; open-coded; anything else falls to the binary dispatch above. Comparisons -;; return a genuine Scheme boolean (the backend's truthy elision relies on it). -(define-syntax jolt-n+ - (syntax-rules () - ((_) 0) - ((_ a) (jolt-add a)) - ((_ ea eb) (let ((a ea) (b eb)) - (if (and (number? a) (number? b)) (+ a b) (jolt-add a b)))) - ((_ a b c ...) (jolt-n+ (jolt-n+ a b) c ...)))) -(define-syntax jolt-n- - (syntax-rules () - ((_) (jolt-sub)) - ((_ a) (jolt-sub a)) - ((_ ea eb) (let ((a ea) (b eb)) - (if (and (number? a) (number? b)) (- a b) (jolt-sub a b)))) - ((_ a b c ...) (jolt-n- (jolt-n- a b) c ...)))) -(define-syntax jolt-n* - (syntax-rules () - ((_) 1) - ((_ a) (jolt-mul a)) - ((_ ea eb) (let ((a ea) (b eb)) - (if (and (number? a) (number? b)) - (if (or (flonum? a) (flonum? b)) - (fl* (real->flonum a) (real->flonum b)) - (* a b)) - (jolt-mul a b)))) - ((_ a b c ...) (jolt-n* (jolt-n* a b) c ...)))) -(define-syntax jolt-n-div - (syntax-rules () - ((_) (jolt-div)) - ((_ a) (jolt-div a)) - ((_ a b) (jolt-div2 a b)) - ((_ a b c ...) (jolt-n-div (jolt-div2 a b) c ...)))) -(define-syntax define-n-cmp - (syntax-rules () - ((_ name op op2) - (define-syntax name - (syntax-rules () - ((_) (op2)) - ((_ a) (begin a #t)) - ((_ ea eb) (let ((a ea) (b eb)) - (if (and (number? a) (number? b)) (op a b) (op2 a b)))) - ((_ ea eb c (... ...)) (let ((a ea) (b eb)) - (and (name a b) (name b c (... ...)))))))))) -(define-n-cmp jolt-n< < jolt-lt2) -(define-n-cmp jolt-n> > jolt-gt2) -(define-n-cmp jolt-n<= <= jolt-le2) -(define-n-cmp jolt-n>= >= jolt-ge2) -(define-syntax jolt-n-min - (syntax-rules () - ((_) (jolt-min)) - ((_ a) (jolt-min a)) - ((_ a b) (jolt-min2 a b)) - ((_ a b c ...) (jolt-n-min (jolt-min2 a b) c ...)))) -(define-syntax jolt-n-max - (syntax-rules () - ((_) (jolt-max)) - ((_ a) (jolt-max a)) - ((_ a b) (jolt-max2 a b)) - ((_ a b c ...) (jolt-n-max (jolt-max2 a b) c ...)))) - -;; --- unchecked (Java long) arithmetic: wrap to signed 64 bits ---------------- -;; Clojure's unchecked-* (and +/-/* under *unchecked-math*) are long ops that -;; WRAP on overflow; jolt's checked arithmetic is arbitrary-precision. These -;; truncate to the low 64 bits as a two's-complement signed long. Chez fixnums are -;; 61-bit, so wrapping uses bignum bit ops + a mask (no fx fast path). The backend -;; emits the binary jolt-unc* for :long-typed unchecked ops; the variadic -;; clojure.core/unchecked-* fns reduce through them. -(define unc-mask64 #xFFFFFFFFFFFFFFFF) -(define unc-2^63 #x8000000000000000) -(define unc-2^64 #x10000000000000000) -(define unc-neg-2^63 (- unc-2^63)) -;; Wrap to a signed 64-bit value. Fast path: an exact integer already in -;; [-2^63, 2^63) is its own wrap — skip the bignum mask, which on Chez (61-bit -;; fixnums) allocates for any value past 2^60. Only an out-of-range result (a -;; multiply overflowing into 128 bits) needs the mask + sign fixup. -(define (jolt-wrap64 x) - (if (and (exact? x) (integer? x) (>= x unc-neg-2^63) (< x unc-2^63)) - x - (let ((m (bitwise-and (if (and (number? x) (exact? x) (integer? x)) x (exact (floor x))) unc-mask64))) - (if (>= m unc-2^63) (- m unc-2^64) m)))) -;; unchecked-* only WRAP integer (long) math; on a flonum OR ratio operand they -;; are an ordinary numeric op, since *unchecked-math* never wraps a non-long — -;; Clojure's unchecked-add falls back to regular arithmetic for non-primitives: -;; (unchecked-multiply 1.5 2.0) => 3.0, (unchecked-add 2/3 2/3) => 4/3, not a -;; truncated long. (test.check's rand-double is (* double-unit shifted), and -;; gen/ratio sums ratios, both under *unchecked-math*.) Wrap iff both are exact -;; integers. -(define (unc-int? x) (and (exact? x) (integer? x))) -(define (jolt-uncadd2 a b) (if (and (unc-int? a) (unc-int? b)) (jolt-wrap64 (+ a b)) (+ a b))) -(define (jolt-uncsub2 a b) (if (and (unc-int? a) (unc-int? b)) (jolt-wrap64 (- a b)) (- a b))) -(define (jolt-uncmul2 a b) (if (and (unc-int? a) (unc-int? b)) (jolt-wrap64 (* a b)) (* a b))) -(define (jolt-uncinc x) (if (unc-int? x) (jolt-wrap64 (+ x 1)) (+ x 1))) -(define (jolt-uncdec x) (if (unc-int? x) (jolt-wrap64 (- x 1)) (- x 1))) -(define (jolt-uncneg x) (if (unc-int? x) (jolt-wrap64 (- x)) (- x))) -(define (jolt-unchecked-add . xs) (if (null? xs) 0 (fold-left jolt-uncadd2 (car xs) (cdr xs)))) -(define (jolt-unchecked-mul . xs) (if (null? xs) 1 (fold-left jolt-uncmul2 (car xs) (cdr xs)))) -(define (jolt-unchecked-sub . xs) - (cond ((null? xs) 0) ((null? (cdr xs)) (jolt-uncneg (car xs))) (else (fold-left jolt-uncsub2 (car xs) (cdr xs))))) -(define (jolt-unchecked-div a b) (quotient (jolt-wrap64 a) (jolt-wrap64 b))) -(define (jolt-unchecked-rem a b) (remainder (jolt-wrap64 a) (jolt-wrap64 b))) -;; the clojure.core/unchecked-* vars are def-var!'d in natives-seq.ss (def-var! is -;; defined after this file loads). - -;; --- ^long ops that tolerate a full 64-bit value ----------------------------- -;; A ^long is 64-bit but a Chez fixnum is only 61-bit, so the backend's fast fx -;; ops would raise on a value past 2^60 (e.g. a long from the PRNG / wrapping -;; arithmetic). These take the fx fast path when the operands ARE fixnums and fall -;; back to the generic op otherwise — so ^long comparisons / quot / min etc. on a -;; full-width long stay correct. Macros (define-syntax) so the fast path inlines. -(define-syntax define-l-binop - (syntax-rules () - ((_ name fxop genop) - (define-syntax name - (syntax-rules () - ((_ a b) (let ((x a) (y b)) - (if (and (fixnum? x) (fixnum? y)) (fxop x y) (genop x y))))))))) -(define-l-binop jolt-l< fx fx>? >) -(define-l-binop jolt-l>= fx>=? >=) -(define-l-binop jolt-l= fx=? =) -(define-l-binop jolt-l-min fxmin min) -(define-l-binop jolt-l-max fxmax max) -(define-l-binop jolt-l-quot fxquotient quotient) -(define-l-binop jolt-l-rem fxremainder remainder) -(define-l-binop jolt-l-mod fxmodulo modulo) -(define-syntax jolt-l-inc (syntax-rules () ((_ a) (let ((x a)) (if (fixnum? x) (fx1+ x) (+ x 1)))))) -(define-syntax jolt-l-dec (syntax-rules () ((_ a) (let ((x a)) (if (fixnum? x) (fx1- x) (- x 1)))))) +;; Scheme's +/-/*// already implement the JVM-parity numeric tower: exact+exact -> +;; exact, exact/exact -> Ratio, any flonum -> flonum. Identities (+)=0 / (*)=1 are +;; exact, matching exact integer arithmetic. The hot path uses the inlined native +;; ops, not these. +(define (jolt-add . xs) (apply + xs)) +(define (jolt-sub . xs) (apply - xs)) +(define (jolt-mul . xs) (apply * xs)) +(define (jolt-div . xs) (apply / xs)) ;; ============================================================================ ;; IFn dispatch — the dynamic "value as fn" fallback. A callee that the emitter ;; can't statically resolve to a procedure (a keyword/coll/proc held in a local) ;; routes here. Off the arithmetic/self-recursion hot path by construction. ;; ============================================================================ -;; (pred . handler) arms making a host type invocable; handler gets (f args). -(define jolt-invoke-arms '()) -(define (register-invoke-arm! pred handler) - (set! jolt-invoke-arms (cons (cons pred handler) jolt-invoke-arms))) -(define (jolt-invoke-arm-for f) - (let loop ((as jolt-invoke-arms)) - (cond ((null? as) #f) - (((caar as) f) (cdar as)) - (else (loop (cdr as)))))) - (define (jolt-invoke f . args) (cond ((procedure? f) (apply f args)) ((keyword? f) (apply jolt-get (car args) f (cdr args))) ; (:k m [d]) -> (get m :k [d]) - ((jolt-symbol? f) (apply jolt-get (car args) f (cdr args))) ; ('s m [d]) -> (get m 's [d]) - ;; a VECTOR invokes as nth (a bad index throws, like IPersistentVector.invoke); - ;; maps and sets invoke as get. - ((pvec? f) (if (and (pair? args) (null? (cdr args))) - (jolt-nth f (car args)) - (apply jolt-get f args))) ((jolt-coll? f) (apply jolt-get f args)) ; (coll k [d]) -> (get coll k [d]) ((jolt-transient? f) (apply jolt-get f args)) ; a transient vec/map/set is callable on the JVM ;; a record/reify implementing clojure.lang.IFn is callable: dispatch to its @@ -473,73 +152,7 @@ => (lambda (m) (apply jolt-invoke m f args))) ((and (reified-methods f) (hashtable-ref (reified-methods f) "invoke" #f)) => (lambda (m) (apply jolt-invoke m f args))) - ;; host types registered as callable (promise delivers, …): consulted only - ;; after every built-in case missed, so the hot dispatch pays nothing. - ((jolt-invoke-arm-for f) => (lambda (h) (h f args))) - ;; calling a non-fn: a ClassCastException naming the operator's CLASS (like - ;; the JVM's "class clojure.lang.LazySeq cannot be cast to ... IFn" — never - ;; the value, whose printed form may be unbounded: ((range)) must throw, not - ;; hang rendering an infinite seq). Thrown via jolt-throw so it is catchable - ;; and carries the throw-site continuation for a stack trace. - (else (jolt-throw (jolt-host-throwable "java.lang.ClassCastException" - (string-append - "class " - (guard (e (#t "value")) - (let ((c (jolt-class-name f))) - (if (string? c) c (jolt-pr-str f)))) - " cannot be cast to class clojure.lang.IFn")))))) - -;; ============================================================================ -;; chunked-seq accessors — the host side of the Clojure IChunkedSeq contract -;; (chunk-first ++ chunk-rest == the seq). Two chunked shapes share the cseq -;; record: a vector-backed seq (cvec = whole pvec, ci = absolute index, crest #f, -;; rest = next 32-block of cvec) and a ChunkedCons (cvec = standalone chunk pvec, -;; crest = the after-chunk seq). natives-array.ss binds these into clojure.core and -;; the chunk-buffer/chunk/chunk-cons builder API on top of them. -;; ============================================================================ -(define seq-chunk-size 32) -;; (chunk-pvec . end-index) for a chunked cell, else #f. A ChunkedCons block is the -;; whole remaining chunk (crest carries what comes after); a vector seq block is the -;; next <=32 elements within cvec. -(define (na-vblock s) - (and (cseq? s) (cseq-cvec s) - (let ((v (cseq-cvec s)) (i (cseq-ci s))) - (cons v (if (cseq-crest s) (pvec-count v) (fxmin (fx+ i seq-chunk-size) (pvec-count v))))))) -(define (na-chunked-seq? x) (and (na-vblock x) #t)) -;; Copy the block [i, end) straight out of the pvec trie's 32-element leaf node -;; (pv-chunk-for is O(log n)). seq-chunk-size == pv-width and vector-seq blocks are -;; 32-aligned, so a block is exactly one leaf; the rare non-aligned window crossing -;; a leaf boundary falls back to per-index reads. Flattening the whole backing -;; vector per block (pvec-v) made chunk-first O(n), so walking chunk-by-chunk was -;; O(n^2). A ChunkedCons chunk is a small tail-only pvec, so the leaf IS the chunk. -(define (na-chunk-first s) - (let ((vb (na-vblock s))) - (if vb - (let* ((pv (car vb)) (i (cseq-ci s)) (end (cdr vb)) (len (fx- end i)) - (node (pv-chunk-for pv i)) (off (fxand i pv-mask))) - (if (fx<=? (fx+ off len) (vector-length node)) - (make-pvec (vec-copy-range node off (fx+ off len))) - (let ((out (make-vector len))) - (let loop ((j 0)) - (if (fx (lambda (vb) - (if (fx>=? (cdr vb) (pvec-count (car vb))) jolt-empty-list (vec->seq (car vb) (cdr vb))))) - (else (jolt-rest s)))) -(define (na-chunk-next s) - (cond - ((and (cseq? s) (cseq-crest s)) (jolt-seq (cseq-crest s))) - ((na-vblock s) => (lambda (vb) - (if (fx>=? (cdr vb) (pvec-count (car vb))) jolt-nil (vec->seq (car vb) (cdr vb))))) - (else (jolt-next s)))) + (else (error 'invoke "not a fn" f)))) ;; ============================================================================ ;; map / filter / reduce / into / remove + range / take / concat / apply @@ -549,96 +162,44 @@ ;; an empty seq, so (= () (map f [])) is true and (nil? (map f [])) is false. ;; jolt-empty-list seqs back to nil, so it stays a valid lazy-tail terminator for ;; the non-empty case (printing / seq= / reduce all walk via jolt-seq). -;; Single-coll map (core.clj's [f coll] arity). Chunk-preserving: when the source -;; seq is chunked, realize the WHOLE first chunk — apply f to every element eagerly -;; into a fresh chunk — and chunk-cons it onto a lazy map of chunk-rest, so the -;; result is itself a chunked-seq. A non-chunked source maps one element at a time. (define (map-seq f s) - (cond - ((jolt-nil? s) jolt-empty-list) - ((na-chunked-seq? s) - (let* ((c (na-chunk-first s)) (n (pvec-count c)) (out (make-vector n))) - (let loop ((i 0)) - (if (fxvector kept)) 0 - (jolt-make-lazy-seq - (lambda () (jolt-seq (filter-seq pred (jolt-seq (na-chunk-rest s)) keep))))))))))) - (else - (let walk ((s s)) - (cond ((jolt-nil? s) jolt-empty-list) - ((eq? keep (jolt-truthy? (jolt-invoke pred (seq-first s)))) - (cseq-lazy (seq-first s) (lambda () (filter-seq pred (jolt-seq (seq-more s)) keep)))) - (else (walk (jolt-seq (seq-more s))))))))) -;; filter/remove are fully lazy (LazySeq): defer the predicate and the source seq -;; until forced, like Clojure. (lazy-seq* = a 0-arg lazy node coercing to cseq|nil.) -(define (jolt-filter pred coll) - (jolt-make-lazy-seq (lambda () (jolt-seq (filter-seq pred (jolt-seq coll) #t))))) -(define (jolt-remove pred coll) - (jolt-make-lazy-seq (lambda () (jolt-seq (filter-seq pred (jolt-seq coll) #f))))) + (let loop ((s s)) + (cond ((jolt-nil? s) jolt-empty-list) ; empty result is () (see map-seq) + ((eq? keep (jolt-truthy? (jolt-invoke pred (seq-first s)))) + (cseq-lazy (seq-first s) (lambda () (filter-seq pred (jolt-seq (seq-more s)) keep)))) + (else (loop (jolt-seq (seq-more s))))))) +(define (jolt-filter pred coll) (filter-seq pred (jolt-seq coll) #t)) +(define (jolt-remove pred coll) (filter-seq pred (jolt-seq coll) #f)) ;; honors `reduced`: a reducing fn that returns (reduced x) stops the fold and ;; unwraps to x (so does a reduced INIT). Checked at entry, so the value returned ;; by the last step is unwrapped on the next turn before the seq is consulted. ;; reduce a vector's backing store directly by index from element i — no per- ;; element seq cells. Honors `reduced`. The chunked-seq fast path. -;; Reduce a chunk pvec from index i. Returns the accumulator RAW — a `reduced` box -;; is returned unwrapped-by reduce-seq, not here — so a ChunkedCons continuation can -;; see early termination instead of folding it back into the running value. (define (vec-reduce f acc v i) (let ((n (pvec-count v)) (raw (pvec-v v))) (let loop ((i i) (acc acc)) - (cond ((jolt-reduced? acc) acc) + (cond ((jolt-reduced? acc) (jolt-reduced-val acc)) ((fx>=? i n) acc) (else (loop (fx+ i 1) (jolt-invoke f acc (vector-ref raw i)))))))) (define (reduce-seq f acc s) (cond ((jolt-reduced? acc) (jolt-reduced-val acc)) ((jolt-nil? s) acc) - ;; a chunked seq reduces its chunk pvec directly, in a tight loop. A vector seq - ;; (crest #f) reduces the whole backing vector and is then done; a ChunkedCons - ;; reduces this chunk and continues into its after-chunk rest. - ((and (cseq? s) (cseq-cvec s)) - (let ((acc2 (vec-reduce f acc (cseq-cvec s) (cseq-ci s)))) - (cond ((jolt-reduced? acc2) (jolt-reduced-val acc2)) - ((cseq-crest s) (reduce-seq f acc2 (jolt-seq (cseq-crest s)))) - (else acc2)))) + ;; a vector-backed (chunked) seq reduces its vector directly, in a tight loop. + ((and (cseq? s) (cseq-cvec s)) (vec-reduce f acc (cseq-cvec s) (cseq-ci s))) (else (reduce-seq f (jolt-invoke f acc (seq-first s)) (jolt-seq (seq-more s)))))) (define jolt-reduce (case-lambda @@ -646,11 +207,11 @@ (if (jolt-nil? s) (jolt-invoke f) ; (reduce f []) -> (f) (reduce-seq f (seq-first s) (jolt-seq (seq-more s)))))) ((f init coll) - ;; IReduceInit: a deftype/record OR reify with its own `reduce` method drives - ;; the reduction, e.g. (reduce f init (reify clojure.lang.IReduceInit - ;; (reduce [_ f i] ...))) or the same on a deftype. + ;; IReduceInit: a reify/record with its own `reduce` method drives the + ;; reduction (reduce f init (reify clojure.lang.IReduceInit (reduce [_ f i] ...))). (cond - ((iface-method coll "reduce" 3) + ((and (jreify? coll) (reified-methods coll) + (hashtable-ref (reified-methods coll) "reduce" #f)) => (lambda (m) (let ((r (jolt-invoke m coll f init))) (if (jolt-reduced? r) (jolt-reduced-val r) r)))) (else (reduce-seq f init (jolt-seq coll))))))) @@ -661,73 +222,32 @@ ;; falls back to a copy-on-write wrapper for other targets (lists, sorted colls, ;; nil), so those keep the old per-step jolt-conj behaviour. (define (jolt-into to from) - ;; only an editable collection rides the transient path; anything else - ;; (PersistentQueue, sorted colls, seqs) folds through conj, like RT's - ;; instanceof IEditableCollection split. - (if (or (pvec? to) (pmap? to) (pset? to)) - (meta-carry to - (jolt-persistent! (reduce-seq (lambda (t x) (jolt-conj! t x)) (jolt-transient-new to) (jolt-seq from)))) - (meta-carry to - (reduce-seq (lambda (acc x) (jolt-conj1 acc x)) to (jolt-seq from))))) + (meta-carry to + (jolt-persistent! (reduce-seq (lambda (t x) (jolt-conj! t x)) (jolt-transient-new to) (jolt-seq from))))) (define (range-from n) (cseq-lazy n (lambda () (range-from (+ n 1))))) -;; A bounded range is a real chunked-seq, like clojure.lang.LongRange: eager, with -;; chunk-first handing out a block of up to 32 consecutive values. Each block is -;; materialized into a pvec and chunk-cons'd onto a lazy continuation, so a chunked -;; map/filter over a range batches by 32 (the JVM's observable realization), while a -;; huge range still produces its tail one block at a time. -;; An empty range is () (jolt-empty-list), NOT nil — (range 0) and (range 5 5) are -;; empty seqs in Clojure, so (= () (range 0)) holds, and () seqs back to nil so it -;; also terminates the chunked tail (see jolt-take). -(define (range-chunked n end step) +(define (range-bounded n end step) (if (if (> step 0.0) (< n end) (> n end)) - (let loop ((i 0) (v n) (acc '())) - (if (and (fx step 0.0) (< v end) (> v end))) - (loop (fx+ i 1) (+ v step) (cons v acc)) - (cseq-chunked (make-pvec (list->vector (reverse acc))) 0 - (jolt-make-lazy-seq (lambda () (jolt-seq (range-chunked v end step))))))) - jolt-empty-list)) + (cseq-lazy n (lambda () (range-bounded (+ n step) end step))) + jolt-nil)) ;; numeric tower: exact 0/1 defaults so (range 3) yields exact ints ;; (= JVM longs); flonum args still produce flonums (Scheme arithmetic preserves). -;; (range) with no bound is the lazy, NON-chunked (iterate inc' 0) form. (define jolt-range (case-lambda (() (range-from 0)) - ((end) (range-chunked 0 end 1)) - ((start end) (range-chunked start end 1)) - ((start end step) (range-chunked start end step)))) + ((end) (range-bounded 0 end 1)) + ((start end) (range-bounded start end 1)) + ((start end step) (range-bounded start end step)))) -;; An empty take result is () (jolt-empty-list), NOT nil — (take 0 coll) and -;; (take n []) are empty seqs in Clojure, so (= () (take 0 [:a])) and printing -;; "()" hold. jolt-empty-list seqs back to nil, so it also terminates the lazy -;; tail when n hits 0 mid-stream (see map-seq). -;; The LAST element (n=1) terminates without touching the rest, so (take n s) -;; realizes exactly n elements of a side-effecting seq — matching Clojure, where -;; (take 0 (rest s)) never seqs coll. Realizing one more, as forcing seq-more at -;; the boundary would, over-runs the source by one (medley's sequence-padded). (define (jolt-take n coll) - ;; lazy (LazySeq): realize exactly n elements, none at construction. (take - ;; Double/POSITIVE_INFINITY coll) takes the whole coll on the JVM (the count - ;; never reaches 0); test.check's rose-tree unchunk relies on it. Coercing +inf.0 - ;; to a fixnum index would throw, so take all up front in that case. - (jolt-make-lazy-seq - (lambda () - (jolt-seq - (if (and (flonum? n) (infinite? n)) - (if (> n 0.0) (jolt-seq coll) jolt-empty-list) - (let ((n (->idx n))) - (let loop ((n n) (s (jolt-seq coll))) - (cond - ((or (fx<=? n 0) (jolt-nil? s)) jolt-empty-list) - ((fx=? n 1) (cseq-lazy (seq-first s) (lambda () jolt-empty-list))) - (else (cseq-lazy (seq-first s) (lambda () (loop (fx- n 1) (jolt-seq (seq-more s)))))))))))))) + (let ((n (->idx n))) + (let loop ((n n) (s (jolt-seq coll))) + (if (or (fx<=? n 0) (jolt-nil? s)) jolt-nil + (cseq-lazy (seq-first s) (lambda () (loop (fx- n 1) (jolt-seq (seq-more s))))))))) (define (jolt-drop n coll) - (jolt-make-lazy-seq - (lambda () - (jolt-seq - (let loop ((n (->idx n)) (s (jolt-seq coll))) - (if (or (fx<=? n 0) (jolt-nil? s)) (if (jolt-nil? s) jolt-empty-list s) - (loop (fx- n 1) (jolt-seq (seq-more s))))))))) + (let loop ((n (->idx n)) (s (jolt-seq coll))) + (if (or (fx<=? n 0) (jolt-nil? s)) (if (jolt-nil? s) jolt-empty-list s) + (loop (fx- n 1) (jolt-seq (seq-more s)))))) ;; lazily append seq a then the seqable produced by the thunk `brest` — the rest ;; is NOT forced until a is exhausted, so concat is fully lazy (Clojure semantics). @@ -738,32 +258,14 @@ (if (jolt-nil? a) (jolt-seq (brest)) (cseq-lazy (seq-first a) (lambda () (concat2 (jolt-seq (seq-more a)) brest))))) (define (jolt-concat . colls) - (jolt-make-lazy-seq - (lambda () - (jolt-seq - (cond ((null? colls) jolt-empty-list) - ((null? (cdr colls)) (jolt-seq (car colls))) - (else (concat2 (jolt-seq (car colls)) (lambda () (apply jolt-concat (cdr colls)))))))))) + (cond ((null? colls) jolt-empty-list) + ((null? (cdr colls)) (jolt-seq (car colls))) + (else (concat2 (jolt-seq (car colls)) (lambda () (apply jolt-concat (cdr colls))))))) -;; Lazily concatenate a (possibly infinite) SEQ of colls — what (apply concat ss) -;; means, but without realizing ss. Pulls one coll at a time, concatenating it with -;; a lazy tail, so mapcat / (apply concat …) over an infinite source stays lazy. -(define (lazy-concat-seq ss) - (let ((s (jolt-seq ss))) - (if (jolt-nil? s) - jolt-empty-list - (jolt-concat (seq-first s) - (jolt-make-lazy-seq (lambda () (lazy-concat-seq (seq-more s)))))))) - -;; (apply f a b ... coll): spread the trailing seqable into the call. concat is -;; special-cased: it produces a LAZY result, so spreading an infinite tail through -;; a Scheme variadic (which must realize it) would hang — route to lazy-concat-seq, -;; prepending any fixed leading colls. +;; (apply f a b ... coll): spread the trailing seqable into the call. (define (jolt-apply f . args) - (let* ((r (reverse args)) (tail (car r)) (fixed (reverse (cdr r)))) - (if (eq? f jolt-concat) - (lazy-concat-seq (fold-right jolt-cons (jolt-seq tail) fixed)) - (apply jolt-invoke f (append fixed (seq->list (jolt-seq tail))))))) + (let* ((r (reverse args)) (spread (seq->list (jolt-seq (car r)))) (fixed (reverse (cdr r)))) + (apply jolt-invoke f (append fixed spread)))) ;; ============================================================================ ;; numeric predicates / identity — usable in fn AND value position (map/filter). @@ -773,14 +275,8 @@ ;; Parity over the full integer range (JVM even?/odd? accept any integer, ;; bignums included); a fixnum-only fxand crashes on a large value (e.g. a hash). (define (parity-int n) (if (flonum? n) (exact (floor n)) n)) -(define (jolt-parity-check n) - (unless (and (number? n) (exact? n) (integer? n)) - (jolt-throw (jolt-host-throwable - "java.lang.IllegalArgumentException" - (string-append "Argument must be an integer: " - (guard (e (#t "?")) (jolt-str n))))))) -(define (jolt-even? n) (jolt-parity-check n) (even? (parity-int n))) -(define (jolt-odd? n) (jolt-parity-check n) (odd? (parity-int n))) +(define (jolt-even? n) (even? (parity-int n))) +(define (jolt-odd? n) (odd? (parity-int n))) (define (jolt-pos? n) (> n 0)) (define (jolt-neg? n) (< n 0)) (define (jolt-zero? n) (= n 0)) @@ -789,18 +285,8 @@ ;; ============================================================================ ;; keys / vals — return seqs (nil on the empty map), HAMT-iteration order ;; ============================================================================ -;; keys/vals of anything empty is nil (RT.keys over a nil seq); a non-empty -;; non-map still fails (its elements are not MapEntries). -(define (jolt-keys m) - (cond ((jolt-nil? m) jolt-nil) - ((pmap? m) (list->cseq (pmap-fold m (lambda (k v a) (cons k a)) '()))) - ((jolt-nil? (jolt-seq m)) jolt-nil) - (else (list->cseq (pmap-fold m (lambda (k v a) (cons k a)) '()))))) -(define (jolt-vals m) - (cond ((jolt-nil? m) jolt-nil) - ((pmap? m) (list->cseq (pmap-fold m (lambda (k v a) (cons v a)) '()))) - ((jolt-nil? (jolt-seq m)) jolt-nil) - (else (list->cseq (pmap-fold m (lambda (k v a) (cons v a)) '()))))) +(define (jolt-keys m) (if (jolt-nil? m) jolt-nil (list->cseq (pmap-fold m (lambda (k v a) (cons k a)) '())))) +(define (jolt-vals m) (if (jolt-nil? m) jolt-nil (list->cseq (pmap-fold m (lambda (k v a) (cons v a)) '())))) ;; ============================================================================ ;; sequential equality + hash (hooks called from values.ss / collections.ss); diff --git a/host/chez/smoke.sh b/host/chez/smoke.sh index 8ed4506..4002b5f 100755 --- a/host/chez/smoke.sh +++ b/host/chez/smoke.sh @@ -18,51 +18,6 @@ check() { } pass=0 -# An uncaught error reports the source location of the top-level form (stderr). -check_loc() { - err="$(bin/joltc -e "$1" 2>&1 >/dev/null)" - if printf '%s' "$err" | grep -q "$2"; then - pass=$((pass + 1)) - else - echo " FAIL (loc): $1" - echo " want stderr to contain \`$2\`, got \`$err\`" - fails=$((fails + 1)) - fi -} - -# An uncaught error's stack trace must name the runtime-eval'd fn frames that -# survive TCO (the non-tail spine), even though the eval path registers no source -# map — "print what is available". Asserts a substring appears under " trace:". -check_trace() { - err="$(bin/joltc -e "$1" 2>&1 >/dev/null)" - if printf '%s' "$err" | grep -q ' trace:' && printf '%s' "$err" | grep -q "$2"; then - pass=$((pass + 1)) - else - echo " FAIL (trace): $1" - echo " want stderr trace to contain \`$2\`, got \`$err\`" - fails=$((fails + 1)) - fi -} - -# JOLT_TRACE opts into the tail-frame history (the ring of rings): every $2 (an -# ERE) must match the " trace:" block. Used to assert TCO-elided frames are -# recovered and non-tail caller context survives a tail loop. -check_trace_on() { - err="$(JOLT_TRACE=1 bin/joltc -e "$1" 2>&1 >/dev/null)" - ok=1 - printf '%s' "$err" | grep -q ' trace:' || ok=0 - shift - for want in "$@"; do - printf '%s' "$err" | grep -Eq "$want" || ok=0 - done - if [ "$ok" = 1 ]; then - pass=$((pass + 1)) - else - echo " FAIL (trace-on): want [$*] in trace, got \`$err\`" - fails=$((fails + 1)) - fi -} - check '(+ 1 2)' '3' check '(defn fib [n] (if (< n 2) n (+ (fib (- n 1)) (fib (- n 2))))) (fib 15)' '610' check '(->> (range 10) (filter even?) (map (fn [x] (* x x))) (reduce +))' '120' @@ -76,188 +31,6 @@ check '(deref (future (+ 1 2)))' '3' check '(/ 1 2)' '1/2' check '(= 3 3.0)' 'false' check '(== 3 3.0)' 'true' -# a deftype whose simple name collides with a built-in host class must not shadow -# the java class: (java.io.PushbackReader. …) still builds the java reader (has -# .read), while the bare name in the deftype's own ns is the deftype. (Fresh -e -# process per check, so the deftype doesn't leak.) -check '(do (deftype PushbackReader [x]) (.read (java.io.PushbackReader. (java.io.StringReader. "A") 1)))' '65' -check '(do (deftype PushbackReader [x]) (.-x (PushbackReader. 42)))' '42' -check_loc '(throw (ex-info "boom" {}))' ' at 1:' - -# A throw that crosses the eval boundary (eval / load-string) must surface its -# ex-info :message, not Chez's "attempt to apply non-procedure" noise from -# re-wrapping a raw value raised through `eval`. -check '(try (eval (read-string "(throw (ex-info \"boom\" {}))")) (catch :default e (ex-message e)))' 'boom' -check '(try (load-string "(+") (catch :default e (ex-message e)))' 'EOF while reading' -# An uncaught throw prints the ex-info message alongside its source location. -check_loc '(throw (ex-info "boom" {}))' 'boom' -check_loc '(do (+ 1 1) (/ 1 0))' ' at 1:' - -# Runtime-eval'd fns aren't source-mapped, but their native frame names survive on -# the non-tail spine; the trace must show them. deepest/+ are tail calls (erased); -# middle and outer wait on a non-tail (inc …) so their frames are live at the throw. -trace_prog='(defn deepest [x] (+ x 1)) (defn middle [x] (inc (deepest x))) (defn outer [x] (inc (middle x))) (outer :nan)' -check_trace "$trace_prog" 'middle' -check_trace "$trace_prog" 'outer' - -# JOLT_TRACE (tail-frame history / ring of rings). An all-tail chain is entirely -# TCO-erased from the continuation, but the history recovers every frame — incl. -# `deepest`, the actual error site. -check_trace_on '(defn deepest [x] (+ x 1)) (defn middle [x] (deepest x)) (defn outer [x] (middle x)) (outer :nan)' \ - 'deepest' 'middle' 'outer' -# A tail loop (a<->b) under a NON-tail caller: the loop is confined to one rib's -# bounded inner ring, so the caller context (`driver`, `top`) is NOT flushed out — -# the point of the ring of rings. -check_trace_on '(declare b) (defn a [n] (if (zero? n) (+ :x 1) (b (dec n)))) (defn b [n] (a n)) (defn driver [] (inc (a 6))) (defn top [] (inc (driver))) (top)' \ - 'driver' 'top' -# A ^long/^double return hint wraps the body in a coercion, so the hinted fn's call -# is NOT a tail call — its own frame is still live and must appear (not be elided). -check_trace_on '(defn g [n] (+ :x n)) (defn ^long f [n] (g n)) (f 3)' 'f' 'g' -# History is per top-level form: a later form's error trace shows its own frames -# (h2/u2), not frames from an earlier, already-returned form (h1/u1). -check_trace_on '(defn h1 [x] (inc x)) (defn u1 [] (inc (h1 5))) (u1) (defn h2 [x] (+ :x x)) (defn u2 [] (inc (h2 5))) (u2)' \ - 'h2' 'u2' -err_stale="$(JOLT_TRACE=1 bin/joltc -e '(defn h1 [x] (inc x)) (defn u1 [] (inc (h1 5))) (u1) (defn h2 [x] (+ :x x)) (defn u2 [] (inc (h2 5))) (u2)' 2>&1 >/dev/null)" -if printf '%s' "$err_stale" | grep -q 'h1'; then - echo " FAIL (trace-on): stale frame h1 from an earlier form leaked into the trace" - fails=$((fails + 1)) -else - pass=$((pass + 1)) -fi -# A file-backed project run maps each runtime-compiled frame to ns/name (file:line) -# — the eval path registers source in trace mode, so the trace isn't bare names. -tr_proj="$(mktemp -d)" -mkdir -p "$tr_proj/src/tp" -printf '{:paths ["src"] :aliases {:run {:main-opts ["-m" "tp.core"]}}}\n' > "$tr_proj/deps.edn" -printf '(ns tp.core)\n(defn deep [x] (+ x 1))\n(defn mid [x] (inc (deep x)))\n(defn -main [& _] (mid :nan))\n' > "$tr_proj/src/tp/core.clj" -tr_out="$(JOLT_TRACE=1 JOLT_PWD="$tr_proj" bin/joltc -M:run 2>&1)" -if printf '%s' "$tr_out" | grep -Eq 'tp\.core/deep \(.*/tp/core\.clj:2\)'; then - pass=$((pass + 1)) -else - echo " FAIL: JOLT_TRACE trace should map a frame to ns/name (file:line)" - printf '%s\n' "$tr_out" | sed 's/^/ | /' - fails=$((fails + 1)) -fi -rm -rf "$tr_proj" - -# --help prints usage, and lists the nREPL server under its real flag name. -help_out="$(bin/joltc --help 2>/dev/null)" -if printf '%s' "$help_out" | grep -q -- '--nrepl-server'; then - pass=$((pass + 1)) -else - echo " FAIL: --help should list --nrepl-server" - fails=$((fails + 1)) -fi - -# clojure.test extension points (assert-expr / do-report / report) need separate -# top-level forms — assert-expr must register before `is` expands — so this is a -# multi-form `joltc run`, not an -e one-liner. The file self-checks its tallies. -ct_out="$(bin/joltc run test/chez/clojure-test.clj 2>/dev/null)" -if printf '%s' "$ct_out" | grep -q 'CLOJURE-TEST OK'; then - pass=$((pass + 1)) -else - echo " FAIL: clojure.test extension points" - echo " $(printf '%s' "$ct_out" | grep CLOJURE-TEST | tail -1)" - fails=$((fails + 1)) -fi - -# A data reader that returns a CODE form (deps.edn data_readers.clj -> reader fn) -# must have its result spliced in and COMPILED, like Clojure — #code [:x] becomes -# (+ 40 2) and evaluates to 42, not the literal list. A project run so the source -# root's data_readers.clj is picked up. -dr_out="$(JOLT_PWD="$root/test/chez/datareader-app" bin/joltc run -m drtest.main 2>/dev/null | tail -1)" -if [ "$dr_out" = "42" ]; then - pass=$((pass + 1)) -else - echo " FAIL: code-returning data reader (#code) not compiled — got \`$dr_out\`, want 42" - fails=$((fails + 1)) -fi - -# A required namespace's own :as aliases must not leak into the requirer: fix.main -# aliases clojure.string as ss and requires fix.lib (which aliases clojure.set as -# ss); (ss/upper-case "hi") in main must stay clojure.string -> "HI #{1 2}". -al_out="$(JOLT_PWD="$root/test/chez/alias-leak-app" bin/joltc run -m fix.main 2>/dev/null | tail -1)" -if [ "$al_out" = "HI #{1 2}" ]; then - pass=$((pass + 1)) -else - echo " FAIL: a loaded ns's alias leaked into its requirer — got \`$al_out\`, want \`HI #{1 2}\`" - fails=$((fails + 1)) -fi - -# Unit-checks the REPL read-until-complete predicate over balanced/unbalanced, -# string, comment and regex-literal inputs. A multi-form `joltc run` so jolt.main -# is loaded and its private var resolves; the file self-checks and prints a sentinel. -rr_out="$(bin/joltc run test/chez/repl-reader-test.clj 2>/dev/null)" -if printf '%s' "$rr_out" | grep -q 'REPL-READER OK'; then - pass=$((pass + 1)) -else - echo " FAIL: repl-form-complete? predicate" - echo " $(printf '%s' "$rr_out" | grep REPL-READER | tail -1)" - fails=$((fails + 1)) -fi - -# REPL must exit on :repl/quit / :exit — a reliable exit that works in any -# terminal, unlike ^D (which some terminals/editors don't deliver as EOF). -# Pipe: an evaluable form, the quit keyword, then a sentinel that must NOT run. -repl_out="$(printf '(+ 1000 23)\n:repl/quit\n(* 999 9)\n' | bin/joltc repl 2>/dev/null)" -if printf '%s' "$repl_out" | grep -q '1023' && ! printf '%s' "$repl_out" | grep -q '8991'; then - pass=$((pass + 1)) -else - echo " FAIL: repl should exit on :repl/quit before later forms" - printf '%s\n' "$repl_out" | sed 's/^/ | /' - fails=$((fails + 1)) -fi - -repl_out="$(printf '(- 2024 1)\n:exit\n(* 999 9)\n' | bin/joltc repl 2>/dev/null)" -if printf '%s' "$repl_out" | grep -q '2023' && ! printf '%s' "$repl_out" | grep -q '8991'; then - pass=$((pass + 1)) -else - echo " FAIL: repl should exit on :exit before later forms" - printf '%s\n' "$repl_out" | sed 's/^/ | /' - fails=$((fails + 1)) -fi - -# A form split across lines is accumulated and evaluated once complete, with a -# secondary continuation prompt before each continued line. -repl_out="$(printf '(+ 1\n2)\n:exit\n' | bin/joltc repl 2>/dev/null)" -if printf '%s' "$repl_out" | grep -q '3' && ! printf '%s' "$repl_out" | grep -q 'error'; then - pass=$((pass + 1)) -else - echo " FAIL: repl should accumulate multi-line forms to 3" - printf '%s\n' "$repl_out" | sed 's/^/ | /' - fails=$((fails + 1)) -fi - -# A single-line regex literal is complete on its own — the #" opens a regex whose -# body (delimiters, quotes and all) must not be miscounted as unbalanced parens. -repl_out="$(printf '(re-find #"(a)(b)" "ab")\n:exit\n' | bin/joltc repl 2>/dev/null)" -if printf '%s' "$repl_out" | grep -q 'ab' && ! printf '%s' "$repl_out" | grep -q 'error'; then - pass=$((pass + 1)) -else - echo " FAIL: repl should evaluate a one-line regex literal, not wait for more input" - printf '%s\n' "$repl_out" | sed 's/^/ | /' - fails=$((fails + 1)) -fi - -# REPL-driven development traces by default: an error in an evaluated form shows a -# tail-frame backtrace with no JOLT_TRACE set. rb tail-calls ra tail-calls +, all -# TCO-elided from the continuation — only the history recovers them. -repl_err="$(printf '(defn ra [x] (+ x 1))\n(defn rb [x] (ra x))\n(rb :nan)\n:exit\n' | bin/joltc repl 2>&1)" -if printf '%s' "$repl_err" | grep -q ' trace:' && printf '%s' "$repl_err" | grep -q 'rb'; then - pass=$((pass + 1)) -else - echo " FAIL: a REPL error should show a tail-frame trace by default" - printf '%s\n' "$repl_err" | sed 's/^/ | /' - fails=$((fails + 1)) -fi -# JOLT_TRACE=0 opts out — no trace in the REPL. -repl_off="$(printf '(defn ra [x] (+ x 1))\n(defn rb [x] (ra x))\n(rb :nan)\n:exit\n' | JOLT_TRACE=0 bin/joltc repl 2>&1)" -if printf '%s' "$repl_off" | grep -q ' trace:'; then - echo " FAIL: JOLT_TRACE=0 should suppress the REPL trace" - fails=$((fails + 1)) -else - pass=$((pass + 1)) -fi echo "cli smoke: $pass passed, $fails failed" [ "$fails" -eq 0 ] diff --git a/host/chez/source-registry.ss b/host/chez/source-registry.ss deleted file mode 100644 index f88ce2a..0000000 --- a/host/chez/source-registry.ss +++ /dev/null @@ -1,206 +0,0 @@ -;; source-registry.ss — map emitted procedures back to Clojure source for native -;; stack traces, and render an uncaught throwable. -;; -;; A direct-linked def compiles to (define jv$ns$name ); the back end also -;; emits (jolt-register-source! "jv$ns$name" ns name file line) once per such def -;; — at definition time, so there is zero per-call cost. On an uncaught error we -;; walk Chez's native continuation frames, read each frame's procedure name, and -;; look it up here to print a Clojure backtrace. -;; -;; CAVEATS. Names map only for stable Chez procedure names — direct-link / AOT -;; closed-world builds. The open-world -e/repl/run path stores fns in var cells -;; as anonymous lambdas, so its frames don't map (the trace falls back to the -;; top-level location compile-eval.ss tracks). Pervasive tail-call optimization -;; also erases tail-called frames, so even a mapped trace shows only the non-tail -;; spine — the immediate error site is often a tail call and won't appear. - -;; Keyed by the procedure name Chez actually reports for a frame — the SHORT -;; munged fn name (the letrec self-binding emit-fn uses), e.g. "deepest", not the -;; jv$ns$name global. Two vars in different namespaces can share a short name; an -;; 'ambiguous marker then keeps the frame name in the trace but drops the -;; (now-uncertain) ns/file:line, so a trace is never misattributed. -(define source-registry (make-hashtable string-hash string=?)) - -(define (jolt-register-source! procname ns nm file line) - (let ((existing (hashtable-ref source-registry procname #f))) - (cond - ((not existing) (hashtable-set! source-registry procname (vector ns nm file line))) - ((and (vector? existing) - (or (not (equal? (vector-ref existing 0) ns)) - (not (equal? (vector-ref existing 1) nm)))) - (hashtable-set! source-registry procname 'ambiguous)))) - jolt-nil) -(def-var! "jolt.host" "register-source!" jolt-register-source!) - -;; The continuation to walk for an uncaught value: the one jolt-throw captured for -;; THIS value (identity-tagged via jolt-throw-cont, so a stale entry from an -;; earlier caught throw is never reused), else a host condition's own -;; &continuation, else #f. raw may arrive as the &jolt-throw condition wrapping -;; the value (the built-binary launcher hands jolt-report-throwable the guard's -;; raw value) or already unwrapped (the cli unwraps first); unwrap here so the -;; identity match holds either way. -(define (jolt-error-continuation raw) - (let* ((v (jolt-unwrap-throw raw)) - (tc (jolt-throw-cont))) - (cond - ((and (pair? tc) (eq? (car tc) v)) (cdr tc)) - ((and (condition? v) (continuation-condition? v)) (condition-continuation v)) - (else #f)))) - -;; A frame inspector's procedure name as a string, or #f for a non-frame / unnamed. -(define (srcreg-frame-name io) - (and (guard (e (#t #f)) (eq? (io 'type) 'continuation)) - (let ((code (guard (e (#t #f)) (io 'code)))) - (and code - (let ((nm (guard (e (#t #f)) (code 'name)))) - (cond ((string? nm) nm) - ((symbol? nm) (symbol->string nm)) - (else #f))))))) - -;; Frame names that are pure Chez / jolt-runtime plumbing — the eval boundary, -;; the var-cell trampoline, continuation/winder internals. They carry no Clojure -;; meaning, so an unmapped frame with one of these names is dropped from the trace -;; (a MAPPED frame is always kept — a jolt fn that happens to share the name still -;; resolves to its source). Any name Chez prefixes with `$` (system) or that jolt -;; prefixes with `jolt-` (host runtime) is plumbing too. -(define srcreg-plumbing-names - (let ((h (make-hashtable string-hash string=?))) - (for-each (lambda (s) (hashtable-set! h s #t)) - '("dynamic-wind" "winder-dummy" "ksrc" "invoke" "apply" - "call-with-values" "call/cc" "call-with-current-continuation" - "raise" "raise-continuable" "with-exception-handler" "guard" - "eval" "compile" "interpret" "expand" "read" "load" - ;; host dispatch/coercion helpers (not `jolt-` prefixed) that carry - ;; no Clojure meaning in a trace - "record-method-dispatch" "protocol-resolve" "devirt-resolve" - "list->cseq" "host-static-call" "host-call")) - h)) -(define (srcreg-plumbing-name? nm) - (or (hashtable-ref srcreg-plumbing-names nm #f) - (and (fx>? (string-length nm) 0) (char=? (string-ref nm 0) #\$)) - (and (fx>=? (string-length nm) 5) (string=? (substring nm 0 5) "jolt-")))) - -;; Walk a continuation, returning its frames (innermost first) as (frame-name . -;; record) pairs. record is a source vector #(ns name file line) for a frame that -;; maps to registered Clojure source, the symbol 'ambiguous for a short name shared -;; across namespaces, or #f for an unmapped-but-named frame (the common case on the -;; open-world eval path, where nothing is registered — the bare frame name is still -;; a useful trace line). Plumbing frames (host spine, eval boundary) and unnamed -;; frames are skipped; raw depth is capped. -(define (jolt-frame-records k) - ;; read the env at call time, not load time: a built binary runs top-level forms - ;; at heap-build time, where this would always be unset. - (let ((debug? (getenv "JOLT_DEBUG_FRAMES"))) - (guard (e (#t '())) - (let loop ((io (inspect/object k)) (n 0) (acc '())) - (if (or (not io) (fx>=? n 400)) - (reverse acc) - (let* ((nm (srcreg-frame-name io)) - (src (and nm (hashtable-ref source-registry nm #f))) - ;; keep a frame that maps, or any named frame that isn't plumbing - (keep? (and nm (or src (not (srcreg-plumbing-name? nm)))))) - (when (and debug? nm) - (display (string-append " [frame] " nm (if src " *MAPPED*" - (if keep? "" " (skipped)")) "\n") - (current-error-port))) - (loop (guard (e (#t #f)) (io 'link)) (fx+ n 1) - (if keep? (cons (cons nm src) acc) acc)))))))) - -;; Render a list of (frame-name . record) pairs (innermost/deepest first) to a -;; backtrace string. record is a source vector #(ns name file line) -> "ns/name -;; (file:line)", or 'ambiguous / #f -> the bare frame name. A run of the same -;; frame-name collapses to one "name (xN)" line (deep recursion, or a hot fn a -;; loop re-enters), and the number of distinct lines is capped. -(define (jolt-render-recs recs) - (let ((port (open-output-string))) - (let loop ((rs recs) (shown 0)) - (if (or (null? rs) (fx>=? shown 30)) - (get-output-string port) - (let* ((p (car rs)) (frame-name (car p)) (r (cdr p))) - ;; count a maximal run of the same frame-name - (let run ((tail (cdr rs)) (cnt 1)) - (if (and (pair? tail) (string=? (car (car tail)) frame-name)) - (run (cdr tail) (fx+ cnt 1)) - (begin - (put-string port " ") - (if (vector? r) - (let ((ns (vector-ref r 0)) (nm (vector-ref r 1)) - (file (vector-ref r 2)) (line (vector-ref r 3))) - (put-string port ns) (put-string port "/") (put-string port nm) - (when (string? file) - (put-string port " (") (put-string port file) - (put-string port ":") (put-string port (number->string line)) - (put-string port ")"))) - (put-string port frame-name)) ; 'ambiguous / unmapped: bare name - (when (fx>? cnt 1) - (put-string port " (x") (put-string port (number->string cnt)) (put-string port ")")) - (put-char port #\newline) - (loop tail (fx+ shown 1)))))))))) - -;; Multi-line backtrace for an uncaught value. Two sources, in preference order: -;; 1. The tail-frame history ring (rt.ss), when JOLT_TRACE enabled it — an -;; execution history of the runtime-compiled fns entered before the throw, -;; INCLUDING ones TCO erased from the live continuation. Most-recent first. -;; 2. Otherwise the live continuation (jolt-frame-records) — the accurate but -;; TCO-truncated non-tail spine. -;; Each frame maps to "ns/name (file:line)" when registered, else its bare name. -;; #f when neither source yields a frame (the caller then prints just the location). -;; The tail-frame history ring rendered as a backtrace, or #f when tracing is off / -;; empty. A mapped frame is kept; else drop plumbing (same rule as the continuation -;; path) so the two sources read consistently. -(define (jolt-history-backtrace) - (let* ((hist (jolt-trace-snapshot)) - (recs (let loop ((ns hist) (acc '())) - (if (null? ns) - (reverse acc) - (let* ((nm (car ns)) (src (hashtable-ref source-registry nm #f))) - (loop (cdr ns) - (if (or src (not (srcreg-plumbing-name? nm))) - (cons (cons nm src) acc) acc))))))) - (and (pair? recs) (jolt-render-recs recs)))) - -(define (jolt-backtrace-string v) - (or (jolt-history-backtrace) - (let ((k (jolt-error-continuation v))) - (and k - (let ((recs (jolt-frame-records k))) - (and (pair? recs) (jolt-render-recs recs))))))) - -;; Exposed for the REPL / nREPL error paths, which catch errors themselves instead -;; of going through the uncaught reporter. Returns the " trace:\n" block -;; from the tail-frame HISTORY only — the live continuation in a REPL is just the -;; REPL's own machinery — or nil when tracing is off (so a caller can when-let). -(def-var! "jolt.host" "backtrace-string" - (lambda () - (let ((bt (jolt-history-backtrace))) - (if bt (string-append " trace:\n" bt) jolt-nil)))) - -;; Render an uncaught jolt throw (any value, not just a Chez condition) to a port: -;; an ex-info shows its message + ex-data (+ a host cause); anything else is -;; pr-str'd. Shared by the cli (cli.ss) and a built binary's launcher (build.ss). -(define (jolt-render-throwable raw port) - (let ((v (jolt-unwrap-throw raw))) - (if (jolt=2 (jolt-get v jolt-kw-ex-type jolt-nil) jolt-kw-ex-info) - (begin - (display "Unhandled exception: " port) - (display (jolt-str-render-one (jolt-get v jolt-kw-message jolt-nil)) port) - (newline port) - (let ((data (jolt-get v jolt-kw-data jolt-nil))) - (unless (jolt-nil? data) - (display " ex-data: " port) (display (jolt-pr-str data) port) (newline port))) - (let ((cause (jolt-get v jolt-kw-cause jolt-nil))) - (when (condition? cause) - (display " cause: " port) - (display (with-output-to-string (lambda () (display-condition cause))) port) - (newline port)))) - (begin - (display "Unhandled exception: " port) - (display (if (condition? v) (with-output-to-string (lambda () (display-condition v))) (jolt-pr-str v)) port) - (newline port))))) - -;; Render the throwable, then its Clojure backtrace when one maps. The caller adds -;; any top-level source location (the runtime cli does; a built binary has none). -(define (jolt-report-throwable v port) - (jolt-render-throwable v port) - (let ((bt (jolt-backtrace-string v))) - (when bt (display " trace:\n" port) (display bt port)))) diff --git a/host/chez/static-native-smoke.sh b/host/chez/static-native-smoke.sh deleted file mode 100644 index c8aa019..0000000 --- a/host/chez/static-native-smoke.sh +++ /dev/null @@ -1,115 +0,0 @@ -#!/bin/sh -# static-native smoke: a project's :jolt/native lib with a :static archive is -# LINKED INTO the built binary (the default), so the binary calls the C function -# with no shared object on disk at runtime. --dynamic keeps the old behavior — -# load a shared object at runtime. -root="$(CDPATH= cd -- "$(dirname -- "$0")/../.." && pwd)" -cd "$root" - -# Preflight: needs cc (to build the test libs AND to cc-link the app) + Chez's -# kernel dev files, same as build-smoke. Skip otherwise (CI on a distro package). -csv="$JOLT_CHEZ_CSV" -if [ -z "$csv" ]; then - chez_bin="$(command -v chez || command -v scheme || command -v petite || true)" - if [ -n "$chez_bin" ]; then - base="$(cd "$(dirname "$chez_bin")/.." 2>/dev/null && pwd)" - for d in "$base"/lib/csv*/*/; do - [ -f "${d}libkernel.a" ] && csv="${d%/}" && break - done - fi -fi -if ! command -v cc >/dev/null 2>&1 || [ -z "$csv" ] || [ ! -f "$csv/scheme.h" ] || [ ! -f "$csv/libkernel.a" ]; then - echo "static-native smoke: skipped (Chez kernel dev files or C compiler not available)" - exit 0 -fi -export JOLT_CHEZ_CSV="$csv" - -case "$(uname -s)" in - Darwin) plat=":darwin"; soext="dylib"; shared="-dynamiclib" ;; - *) plat=":linux"; soext="so"; shared="-shared" ;; -esac - -work="$(mktemp -d)" -trap 'rm -rf "$work"' EXIT -app="$work/app" -mkdir -p "$app/src/app" - -# 1. a trivial C library, built BOTH as a static archive and a shared object. -cat > "$work/greet.c" <<'EOF' -int jolt_static_answer(void) { return 42; } -EOF -cc -c "$work/greet.c" -o "$work/greet.o" -ar rcs "$work/libgreet.a" "$work/greet.o" -cc $shared "$work/greet.c" -o "$work/libgreet.$soext" - -# 2. an app that binds that symbol via FFI. -cat > "$app/src/app/core.clj" <<'EOF' -(ns app.core - (:require [jolt.ffi :as ffi])) -(ffi/defcfn answer "jolt_static_answer" [] :int) -(defn -main [& _] - (println "answer:" (answer))) -EOF - -out="$work/app-bin" - -# --- default: static link --------------------------------------------------- -# A static-only spec (no runtime candidate): the build resolves the symbol by -# preloading the archive, and the binary links it in — nothing to load at runtime. -cat > "$app/deps.edn" <"$work/build.log" 2>&1; then - echo " FAIL: jolt build (static) exited non-zero"; cat "$work/build.log"; exit 1 -fi -[ -x "$out" ] || { echo " FAIL: no executable produced"; exit 1; } -# A static lib emits a process-symbol load (its archive is in-process), not a -# dlopen of the shared object. -if ! grep -q "jolt-build-load-native '() #f #t" "$out.build/flat.ss"; then - echo " FAIL: static native did not emit a process-symbol load"; exit 1 -fi -if grep -q "libgreet.$soext" "$out.build/flat.ss"; then - echo " FAIL: static native baked a runtime shared-object load"; exit 1 -fi -# Remove BOTH libs: a static-linked symbol lives in the binary, nothing to load. -rm -f "$work/libgreet.a" "$work/libgreet.$soext" "$work/greet.o" -got="$(cd / && "$out" 2>&1)" -if [ "$got" != "answer: 42" ]; then - echo " FAIL: static-linked binary output mismatch" - echo "--- want ---"; echo "answer: 42"; echo "--- got ----"; echo "$got"; exit 1 -fi - -# --- --dynamic: runtime load ------------------------------------------------ -# Rebuild the shared object (static phase deleted it) and give the spec a runtime -# candidate; --dynamic loads it at startup instead of linking the archive. -cc $shared "$work/greet.c" -o "$work/libgreet.$soext" -cat > "$app/deps.edn" <"$work/build.log" 2>&1; then - echo " FAIL: jolt build --dynamic exited non-zero"; cat "$work/build.log"; exit 1 -fi -# --dynamic loads the shared object at runtime. -if ! grep -q "libgreet.$soext" "$out.build/flat.ss"; then - echo " FAIL: --dynamic did not emit a runtime shared-object load"; exit 1 -fi -got="$(cd / && "$out" 2>&1)" -if [ "$got" != "answer: 42" ]; then - echo " FAIL: --dynamic binary output mismatch (shared object present)" - echo "--- got ----"; echo "$got"; exit 1 -fi -# With the shared object gone, a --dynamic binary must FAIL — proving the symbol -# was loaded at runtime, not baked in. -rm -f "$work/libgreet.$soext" -rc=0; { (cd / && exec "$out"); } >/dev/null 2>&1 || rc=$? -if [ "$rc" -eq 0 ]; then - echo " FAIL: --dynamic binary still ran with its shared object removed"; exit 1 -fi - -echo "static-native smoke: passed (static default + --dynamic runtime load)" diff --git a/host/chez/stub/launcher.c b/host/chez/stub/launcher.c deleted file mode 100644 index 29a270e..0000000 --- a/host/chez/stub/launcher.c +++ /dev/null @@ -1,109 +0,0 @@ -/* launcher.c — the native stub for self-contained jolt binaries (jolt-eaj). - * - * A toolchain-free `jolt build` (and joltc itself) produces an executable by - * appending a Chez boot image to a copy of this prebuilt stub, framed as: - * - * [stub bytes][boot bytes][boot-length : little-endian u64]["JOLTBOOT"] - * - * (see host/chez/java/io.ss jolt-append-payload!). At startup the stub locates - * its own executable, reads the trailing 16-byte frame to find the boot, and - * hands the boot to the Chez kernel — no external boot file, no Chez install. - * - * Built once at joltc-build time against the Chez kernel (libkernel.a + scheme.h) - * by host/chez/build-joltc.ss; the resulting binary is embedded into joltc and - * copied per app build. Inherently per-platform (the boot targets the host - * machine-type), like a native compiler. - */ -#include "scheme.h" -#include -#include -#include -#include - -#if defined(__APPLE__) -#include -static int self_path(char *buf, uint32_t size) { - /* _NSGetExecutablePath fills buf and reports the needed size on overflow. */ - return _NSGetExecutablePath(buf, &size); -} -#elif defined(_WIN32) -#include -static int self_path(char *buf, uint32_t size) { - DWORD n = GetModuleFileNameA(NULL, buf, size); - return (n == 0 || n >= size) ? -1 : 0; -} -#else -#include -static int self_path(char *buf, uint32_t size) { - ssize_t n = readlink("/proc/self/exe", buf, (size_t)size - 1); - if (n < 0) return -1; - buf[n] = '\0'; - return 0; -} -#endif - -#define JOLT_MAGIC "JOLTBOOT" -#define JOLT_MAGIC_LEN 8 -#define JOLT_TRAILER_LEN 16 /* u64 length + 8-byte magic */ - -int main(int argc, char *argv[]) { - char path[4096]; - if (self_path(path, (uint32_t)sizeof(path)) != 0) { - fprintf(stderr, "jolt: cannot resolve own executable path\n"); - return 1; - } - - FILE *f = fopen(path, "rb"); - if (!f) { fprintf(stderr, "jolt: cannot open self for reading\n"); return 1; } - - if (fseek(f, 0, SEEK_END) != 0) { fclose(f); return 1; } - long fsize = ftell(f); - if (fsize < JOLT_TRAILER_LEN) { - fprintf(stderr, "jolt: no boot payload (run was not produced by jolt build)\n"); - fclose(f); - return 1; - } - - unsigned char trailer[JOLT_TRAILER_LEN]; - if (fseek(f, fsize - JOLT_TRAILER_LEN, SEEK_SET) != 0 || - fread(trailer, 1, JOLT_TRAILER_LEN, f) != JOLT_TRAILER_LEN) { - fclose(f); - return 1; - } - if (memcmp(trailer + 8, JOLT_MAGIC, JOLT_MAGIC_LEN) != 0) { - fprintf(stderr, "jolt: boot payload not found\n"); - fclose(f); - return 1; - } - - uint64_t boot_len = 0; - for (int i = 0; i < 8; i++) - boot_len |= ((uint64_t)trailer[i]) << (8 * i); - - long boot_off = fsize - JOLT_TRAILER_LEN - (long)boot_len; - if (boot_off < 0) { - fprintf(stderr, "jolt: corrupt boot payload\n"); - fclose(f); - return 1; - } - - /* The kernel keeps the boot bytes for the life of the process (demand-loaded), - * so this buffer is freed only after Sscheme_deinit. */ - void *boot = malloc((size_t)boot_len); - if (!boot) { fclose(f); return 1; } - if (fseek(f, boot_off, SEEK_SET) != 0 || - fread(boot, 1, (size_t)boot_len, f) != (size_t)boot_len) { - free(boot); - fclose(f); - return 1; - } - fclose(f); - - Sscheme_init(0); - Sregister_boot_file_bytes("jolt", boot, (iptr)boot_len); - Sbuild_heap(0, 0); - int status = Sscheme_start(argc, (const char **)argv); - Sscheme_deinit(); - free(boot); - return status; -} diff --git a/host/chez/syntax-quote.ss b/host/chez/syntax-quote.ss index edb74c5..a848cbb 100644 --- a/host/chez/syntax-quote.ss +++ b/host/chez/syntax-quote.ss @@ -41,9 +41,7 @@ ;; expansion still re-analyzes as a set literal. (define (jolt-sqset . parts) (apply jolt-hash-set (sq-flatten parts))) ;; map FORM: a plain pmap (the analyzer's form-map? = pmap with no :jolt/type). -;; Clojure's syntaxQuote builds the map via `apply hash-map`, so a `{...} template -;; is HASH-ordered (unlike a {...} literal, which keeps insertion order). -(define (jolt-sqmap . parts) (jolt-hash-map-build parts)) +(define (jolt-sqmap . parts) (apply jolt-hash-map parts)) (def-var! "clojure.core" "__sq1" jolt-sq1) (def-var! "clojure.core" "__sqcat" jolt-sqcat) diff --git a/host/chez/transients.ss b/host/chez/transients.ss index 73b6385..a90cf9a 100644 --- a/host/chez/transients.ss +++ b/host/chez/transients.ss @@ -16,17 +16,11 @@ ;; this record, not a pvec), which group-by relies on. Loaded after collections.ss ;; (persistent ops + key-hash) and converters.ss. -;; For a transient MAP, `n` holds the array-mode capacity (entries it can hold -;; before promoting to hash order) and `ord` the reverse insertion-order key list; -;; for a vector `n` is the element count. A transient array map promotes to hash -;; at max(8, source-count) entries (TransientArrayMap, array sized max(16, len)), -;; with no keyword exception — unlike the persistent assoc growth rule. (define-record-type jolt-transient - (fields kind (mutable buf) (mutable n) (mutable active) (mutable ord)) - (nongenerative jolt-transient-v3)) + (fields kind (mutable buf) (mutable n) (mutable active)) + (nongenerative jolt-transient-v2)) (define tvec-min-cap 8) -(define tmap-min-cap 8) (define (jolt-transient-new coll) (cond @@ -34,36 +28,16 @@ (let* ((v (pvec-v coll)) (cnt (vector-length v)) (cap (fxmax tvec-min-cap cnt)) (buf (make-vector cap jolt-nil))) (let loop ((i 0)) (when (fx? cnt cap) - ;; promoted past the array capacity: hash order - (let ((m empty-pmap-hash)) - (vector-for-each (lambda (k) (set! m (pmap-put-hash m k (hashtable-ref ht k jolt-nil)))) (hashtable-keys ht)) - m) - ;; array map: rebuild in insertion order - (let ((m empty-pmap)) - (for-each (lambda (k) (set! m (pmap-put-ordered m k (hashtable-ref ht k jolt-nil)))) - (reverse (jolt-transient-ord t))) - m)))) + (let ((ht (jolt-transient-buf t)) (m empty-pmap)) + (vector-for-each (lambda (k) (set! m (pmap-assoc m k (hashtable-ref ht k jolt-nil)))) (hashtable-keys ht)) + m)) ((set) (let ((ht (jolt-transient-buf t)) (s empty-pset)) (vector-for-each (lambda (e) (set! s (pset-conj s e))) (hashtable-keys ht)) @@ -129,8 +91,8 @@ (define (tmap-conj-entry! t x) (cond ((jolt-nil? x) #t) - ((pvec? x) (tmap-put! t (pvec-nth-d x 0 jolt-nil) (pvec-nth-d x 1 jolt-nil))) - ((pmap? x) (pmap-fold-fwd x (lambda (k v acc) (tmap-put! t k v) acc) 0)) + ((pvec? x) (hashtable-set! (jolt-transient-buf t) (pvec-nth-d x 0 jolt-nil) (pvec-nth-d x 1 jolt-nil))) + ((pmap? x) (pmap-fold x (lambda (k v acc) (hashtable-set! (jolt-transient-buf t) k v) acc) 0)) (else (error #f "conj!: a transient map takes a map entry or a map" x)))) ;; (conj!) -> fresh transient vector; (conj! coll) -> the 1-arity transducer- @@ -157,14 +119,14 @@ (let ((kvs (assoc-pad kvs0))) (when (odd? (length kvs)) (error #f "assoc!: no value supplied for key")) (case (jolt-transient-kind t) - ((map) (let lp ((xs kvs)) (unless (null? xs) (tmap-put! t (car xs) (cadr xs)) (lp (cddr xs))))) + ((map) (let lp ((xs kvs)) (unless (null? xs) (hashtable-set! (jolt-transient-buf t) (car xs) (cadr xs)) (lp (cddr xs))))) ((vec) (let lp ((xs kvs)) (unless (null? xs) (tvec-assoc1! t (car xs) (cadr xs)) (lp (cddr xs))))) (else (jolt-transient-buf-set! t (apply jolt-assoc (jolt-transient-buf t) kvs))))) t) (define (jolt-dissoc! t . ks) (jolt-trans-check t "dissoc!") (case (jolt-transient-kind t) - ((map) (for-each (lambda (k) (tmap-del! t k)) ks)) + ((map) (for-each (lambda (k) (hashtable-delete! (jolt-transient-buf t) k)) ks)) (else (jolt-transient-buf-set! t (apply jolt-dissoc (jolt-transient-buf t) ks)))) t) (define (jolt-disj! t . xs) @@ -184,11 +146,8 @@ ;; persistent disj over sets (pset-disj already exists in collections.ss). (define (jolt-disj s . xs) - ;; (disj nil ...) is nil on the JVM (disj is otherwise set-only). - (if (jolt-nil? s) - jolt-nil - (meta-carry s - (let loop ((s s) (xs xs)) (if (null? xs) s (loop (pset-disj s (car xs)) (cdr xs))))))) + (meta-carry s + (let loop ((s s) (xs xs)) (if (null? xs) s (loop (pset-disj s (car xs)) (cdr xs)))))) ;; --- see-through accessors --------------------------------------------------- (define (tvec-in-bounds? t i) (and (fixnum? i) (fx>=? i 0) (fx] [--download-dir ] [--version ] [--checksum ]" - echo - echo "Defaults:" - echo " * Installation directory: ${default_install_dir}" - echo " * Download directory: a temporary directory" - echo " * Version: the latest release on GitHub" - echo " * Checksum: fetched from the release and verified automatically" - exit 1 -} - -has() { - command -v "$1" >/dev/null 2>&1 -} - -fetch() { - local url=$1 - local outfile=${2:-} - if has curl; then - if [[ -n $outfile ]]; then curl -fsSL "$url" -o "$outfile"; else curl -fsSL "$url"; fi - elif has wget; then - if [[ -n $outfile ]]; then wget -qO "$outfile" "$url"; else wget -qO - "$url"; fi - else - >&2 echo "Either 'curl' or 'wget' needs to be on PATH." - exit 1 - fi -} - -while [[ $# -gt 0 ]]; do - case "$1" in - --dir) install_dir="$2"; shift 2 ;; - --download-dir) download_dir="$2"; shift 2 ;; - --version) version="$2"; shift 2 ;; - --checksum) checksum="$2"; shift 2 ;; - --help|-h) print_help ;; - *) print_help ;; - esac -done - -if [[ -z "$download_dir" ]]; then - download_dir="$(mktemp -d)" - trap 'rm -rf "$download_dir"' EXIT -fi - -# --- resolve platform / arch to a release target ----------------------------- -case "$(uname -s)" in - Linux*) platform=linux ;; - Darwin*) platform=macos ;; - *) >&2 echo "Unsupported OS: $(uname -s). Prebuilt binaries exist for Linux and macOS."; exit 1 ;; -esac - -case "$(uname -m)" in - x86_64|amd64) arch=x86_64 ;; - aarch64|arm64) arch=aarch64 ;; - *) >&2 echo "Unsupported architecture: $(uname -m)."; exit 1 ;; -esac - -target="${arch}-${platform}" -case "$target" in - x86_64-linux|aarch64-macos) ;; - x86_64-macos) - >&2 echo "No prebuilt joltc for Intel macOS (GitHub retired the Intel runner)." - >&2 echo "Build from source: https://github.com/${repo} (needs Chez Scheme + cc)." - exit 1 ;; - *) >&2 echo "No prebuilt joltc for ${target}." - >&2 echo "Available: x86_64-linux, aarch64-macos." - >&2 echo "Build from source: https://github.com/${repo} (make joltc-release)." - exit 1 ;; -esac - -# --- resolve version --------------------------------------------------------- -if [[ -z "$version" ]]; then - version="$(fetch "https://api.github.com/repos/${repo}/releases/latest" \ - | grep -m1 '"tag_name"' | sed -E 's/.*"tag_name": *"([^"]+)".*/\1/')" - if [[ -z "$version" ]]; then - >&2 echo "Could not determine the latest release. Pass --version explicitly." - exit 1 - fi -fi -tag="v${version#v}" # accept 0.1.0 or v0.1.0; the tag/asset carry the leading v - -filename="joltc-${tag}-${target}.tar.gz" -download_url="https://github.com/${repo}/releases/download/${tag}/${filename}" - -if has sha256sum; then - sha256sum_cmd="sha256sum" -elif has shasum; then - sha256sum_cmd="shasum -a 256" -else - sha256sum_cmd="" -fi - -mkdir -p "$download_dir" && ( - cd "$download_dir" - echo "Downloading ${download_url}" - fetch "$download_url" "$filename" - - # verify: an explicit --checksum wins; otherwise fetch the release's .sha256. - if [[ -z "$checksum" ]]; then - checksum="$(fetch "${download_url}.sha256" 2>/dev/null | cut -d' ' -f1 || true)" - fi - if [[ -n "$checksum" && -n "$sha256sum_cmd" ]]; then - got="$($sha256sum_cmd "$filename" | cut -d' ' -f1)" - if [[ "$got" != "$checksum" ]]; then - >&2 echo "Checksum mismatch on ${filename}" - >&2 echo " got: ${got}" - >&2 echo " expected: ${checksum}" - exit 1 - fi - elif [[ -z "$sha256sum_cmd" ]]; then - >&2 echo "Note: no sha256sum/shasum on PATH; skipping checksum verification." - fi - - tar -zxf "$filename" - rm -f "$filename" -) - -# the tarball unpacks to a directory holding the binary -extracted="${download_dir}/joltc-${tag}-${target}/joltc" -if [[ ! -f "$extracted" ]]; then - >&2 echo "Expected ${extracted} in the archive but it was not found." - exit 1 -fi - -mkdir -p "$install_dir" -if [[ -f "$install_dir/joltc" ]]; then - echo "Moving existing $install_dir/joltc to $install_dir/joltc.old" - mv -f "$install_dir/joltc" "$install_dir/joltc.old" -fi -mv -f "$extracted" "$install_dir/joltc" -chmod +x "$install_dir/joltc" - -# clear the macOS quarantine flag so Gatekeeper doesn't block the fresh download -if [[ "$platform" == "macos" ]] && has xattr; then - xattr -d com.apple.quarantine "$install_dir/joltc" 2>/dev/null || true -fi - -echo "Successfully installed joltc ${tag} to ${install_dir}/joltc" -if ! echo ":$PATH:" | grep -q ":${install_dir}:"; then - echo "Note: ${install_dir} is not on your PATH." -fi diff --git a/jolt-core/clojure/core/00-kernel.clj b/jolt-core/clojure/core/00-kernel.clj index 3a69a46..1e6d326 100644 --- a/jolt-core/clojure/core/00-kernel.clj +++ b/jolt-core/clojure/core/00-kernel.clj @@ -43,10 +43,3 @@ (defn mapv [f & colls] (vec (apply map f colls))) (defn update [m k f & args] (assoc m k (apply f (get m k) args))) - -;; set: realize a seqable and dedup through the set constructor; nil -> #{}. The -;; compiler uses it off the emit path (backend bare-native-names, type inference), -;; so unlike boolean it can live here — compiling this tier never calls set, and by -;; the time those callers run the tier is bound. Pure composition of hash-set/seq/ -;; apply, so it lowers to the same code the native shim did. -(defn set [coll] (if (nil? coll) #{} (apply hash-set (seq coll)))) diff --git a/jolt-core/clojure/core/00-syntax.clj b/jolt-core/clojure/core/00-syntax.clj index 9c5d79c..9753843 100644 --- a/jolt-core/clojure/core/00-syntax.clj +++ b/jolt-core/clojure/core/00-syntax.clj @@ -117,9 +117,7 @@ (let [nm (if (and (seq? nm) (= 'with-meta (first nm))) (second nm) nm) calls (reduce (fn [acc clause] - ;; a reference clause may be a list (:require …) or a vector - ;; [:require …]; Clojure accepts both, dispatching on (first clause). - (if (or (seq? clause) (vector? clause)) + (if (seq? clause) (let [head (first clause) args (rest clause)] (cond (= head :require) (conj acc `(require ~@(map (fn [s] `(quote ~s)) args))) @@ -159,15 +157,6 @@ (defmacro declare [& syms] `(do ~@(map (fn* [s] `(def ~s)) syms))) -;; letfn is a macro over the letfn* special form, matching Clojure: each -;; (name [params] body*) spec becomes a name + a (fn name [params] body*) binding. -;; So (macroexpand-1 '(letfn …)) yields the letfn* form macroexpansion tooling -;; (tools.macro / tools.analyzer) expects, instead of an opaque special form. -(defmacro letfn [fnspecs & body] - (cons 'letfn* - (cons (reduce (fn [acc s] (conj (conj acc (first s)) (cons 'fn s))) [] fnspecs) - body))) - ;; destructure — Clojure's binding-vector expander. ;; Turns a binding vector that may contain destructuring ;; patterns into a plain binding vector (alternating symbol / init-form) built from @@ -188,23 +177,9 @@ [false nil] (if or-map (keys or-map) []))) amp? (fn* [x] (and (symbol? x) (= "&" (name x)))) - ;; split a :keys/:syms/:strs name list at & into [sym bind?] pairs. Names - ;; before & bind normally (bind? true); names after & are declared-only - ;; (bind? false) — accepted keys (:keys) or required keys (:keys!), per - ;; CLJ-2961. - classify - (fn* [names] - (nth (reduce (fn* [st x] - (if (amp? x) - [(nth st 0) false] - [(conj (nth st 0) [x (nth st 1)]) (nth st 1)])) - [[] true] names) - 0)) proc (fn* proc [pat init acc] (cond - ;; CLJ-2954: & is reserved for destructuring rest, never a binding. - (amp? pat) (throw (new IllegalArgumentException "Can't use & as a local binding")) (symbol? pat) (conj (conj acc pat) init) (vector? pat) (let* [g (symbol (str (gensym))) @@ -226,16 +201,16 @@ (let* [g (symbol (str (gensym))) gm (symbol (str (gensym))) ;; kwargs: a map pattern may bind against the sequential rest - ;; of a fn — (& {:keys [...]}) — a seq of alternating k/v args, - ;; optionally with a trailing map (Clojure 1.11: (f :a 1 {:b 2}) - ;; merges the map over the pairs; (f {:a 1}) is just the map). - ;; An odd count means the last arg is that trailing map. A real - ;; map value is used as-is, so ordinary map destructuring is - ;; unaffected. g holds init once; gm is the coerced map every - ;; lookup (and :as) reads from. + ;; of a fn — (& {:keys [...]}) — which is a seq of alternating + ;; k/v args, or a single trailing map. Coerce like Clojure (and + ;; like the interpreter's destructure-bind, so interpret/compile + ;; agree): a sequential value with one map element is that map, + ;; otherwise (apply hash-map). A real map value is used as-is, so + ;; ordinary map destructuring is unaffected. g holds init once; + ;; gm is the coerced map every lookup (and :as) reads from. coerce `(if (sequential? ~g) - (if (odd? (count ~g)) - (merge (apply hash-map (butlast ~g)) (last ~g)) + (if (and (= 1 (count ~g)) (map? (first ~g))) + (first ~g) (apply hash-map ~g)) ~g) or-map (get pat :or) @@ -245,45 +220,30 @@ ;; group binds a :keys/:strs/:syms list. dnsp is the destructuring ;; namespace from a qualified key like :ns/keys — it both prefixes ;; the lookup key and overrides a bare symbol's namespace. - ;; group binds a :keys/:strs/:syms list. checked? marks the - ;; :keys!/:strs!/:syms! variants (CLJ-2961): lookups use req! - ;; (throw on missing) instead of get. A pair is [sym bind?]; - ;; bind? false (names after &) is declared-only — for checked - ;; groups it still runs req! (bound to a throwaway gensym) to - ;; enforce the key, for unchecked groups it's a no-op. group - (fn* group [a names kind dnsp checked?] + (fn* group [a names kind dnsp] (if names (reduce ;; s is a symbol (a b) or a keyword (:a :b); name/ ;; namespace handle both, so :keys [:major] binds ;; `major` looking up :major (str would keep the colon). - (fn* [aa pair] - (let* [s (nth pair 0) - bind? (nth pair 1) - local (name s) + (fn* [aa s] + (let* [local (name s) nsp (or (namespace s) dnsp) keyform (cond (= kind :kw) (keyword (if nsp (str nsp "/" local) local)) (= kind :str) local :else `(quote ~(symbol nsp local))) - fo (find-or or-map local) - lookup (cond - checked? `(req! ~gm ~keyform) - (nth fo 0) `(get ~gm ~keyform ~(nth fo 1)) - :else `(get ~gm ~keyform))] - (cond - bind? (conj (conj aa (symbol local)) lookup) - checked? (conj (conj aa (symbol (str (gensym)))) lookup) - :else aa))) - a (classify names)) + fo (find-or or-map local)] + (conj (conj aa (symbol local)) + (if (nth fo 0) + `(get ~gm ~keyform ~(nth fo 1)) + `(get ~gm ~keyform))))) + a names) a)) - g1 (group base (get pat :keys) :kw nil false) - g2 (group g1 (get pat :strs) :str nil false) - g3 (group g2 (get pat :syms) :sym nil false) - g4 (group g3 (get pat :keys!) :kw nil true) - g5 (group g4 (get pat :strs!) :str nil true) - g6 (group g5 (get pat :syms!) :sym nil true)] + g1 (group base (get pat :keys) :kw nil) + g2 (group g1 (get pat :strs) :str nil) + g3 (group g2 (get pat :syms) :sym nil)] ;; remaining keys: a qualified :ns/keys|:ns/strs|:ns/syms groups under ;; its namespace; any other keyword is skipped; a non-keyword is a ;; nested binding pattern. @@ -291,12 +251,9 @@ (if (keyword? k) (let* [kn (name k) kns (namespace k)] (cond - (and kns (= kn "keys")) (group a (get pat k) :kw kns false) - (and kns (= kn "strs")) (group a (get pat k) :str kns false) - (and kns (= kn "syms")) (group a (get pat k) :sym kns false) - (and kns (= kn "keys!")) (group a (get pat k) :kw kns true) - (and kns (= kn "strs!")) (group a (get pat k) :str kns true) - (and kns (= kn "syms!")) (group a (get pat k) :sym kns true) + (and kns (= kn "keys")) (group a (get pat k) :kw kns) + (and kns (= kn "strs")) (group a (get pat k) :str kns) + (and kns (= kn "syms")) (group a (get pat k) :sym kns) :else a)) ;; a direct binding {x :x}: apply its :or default ;; (keyed by the local symbol) when the key is absent. @@ -305,7 +262,7 @@ `(get ~gm ~(get pat k) ~(nth fo 1)) `(get ~gm ~(get pat k))) a)))) - g6 (keys pat))) + g3 (keys pat))) :else (throw (str "unsupported destructuring pattern: " (pr-str pat))))) ploop (fn* ploop [i acc] @@ -420,37 +377,21 @@ ;; vector + body or a sequence of ([params] body) clauses, so no arity branching is ;; needed. (map? is true for symbol forms too, so guard the attr-map with symbol?.) ;; Defined before fresh-sym below, which is a defn-. -;; defn lives in the earliest tier, so its macro body may only use primitives -;; available before the seq/coll tiers — conj (which merges a map onto a map), -;; assoc, meta, with-meta — not merge/last/butlast. (defmacro defn [fn-name & body] - (let [docstring (when (and (seq body) (string? (first body))) (first body)) - body (if docstring (rest body) body) - ;; the attr-map after an optional docstring (or after the name) — its keys - ;; merge into the var metadata, like Clojure. A map in the first arity - ;; position is the attr-map only when more body follows (else it is a lone - ;; map body) and is never a symbol (a name carries its meta as a form). - attr-map (when (and (seq body) (next body) (map? (first body)) (not (symbol? (first body)))) - (first body)) - body (if attr-map (rest body) body) - ;; the bare name + any ^{:map} metadata the reader attached to it. - fn-only-name (if (symbol? fn-name) fn-name (first (rest fn-name))) - name-meta (meta fn-only-name) - m1 (if attr-map (if name-meta (conj name-meta attr-map) attr-map) name-meta) - meta-map (if docstring (assoc (if m1 m1 {}) :doc docstring) m1)] - ;; pass the name through to fn: the compiled fn's host name carries it, so - ;; stack traces read app.deep/level3 instead of a gensym. All metadata - ;; (docstring + attr-map + the name's own) is attached to the def name symbol, - ;; which analyze-def reads and evaluates — so (meta #'f) reflects every source. - (if meta-map - `(def ~(with-meta fn-only-name meta-map) (fn ~(with-meta fn-only-name nil) ~@body)) - `(def ~fn-only-name (fn ~fn-only-name ~@body))))) + (let [body (if (and (seq body) (string? (first body))) (rest body) body) + body (if (and (seq body) (map? (first body)) (not (symbol? (first body)))) + (rest body) body) + ;; ^{:map} metadata on the name reads as a (with-meta sym …) form, not an + ;; annotated symbol. def attaches the metadata, but fn needs a + ;; bare symbol, so unwrap it for the fn name. + fn-only-name (if (symbol? fn-name) fn-name (first (rest fn-name)))] + ;; pass the name through to fn: the compiled fn's host name carries it, + ;; so stack traces read app.deep/level3 instead of a gensym + `(def ~fn-name (fn ~fn-only-name ~@body)))) -;; defn- marks the var :private (like Clojure). Jolt doesn't restrict access, but -;; ns-publics filters private vars out — a lib that introspects ns-publics (e.g. -;; honeysql's "all helpers have docstrings") sees only the public ones. -(defmacro defn- [fn-name & body] - `(defn ~(with-meta fn-name (assoc (if (meta fn-name) (meta fn-name) {}) :private true)) ~@body)) +;; Jolt doesn't enforce privacy, so defn- is just defn (matching how Clojure's own +;; defn- delegates to defn with :private metadata). +(defmacro defn- [fn-name & body] `(defn ~fn-name ~@body)) ;; A fresh jolt symbol inside a macro body (a bare (gensym) returns a host symbol ;; the destructurer rejects). This defn compiles fine: by the time a tier triggers @@ -546,9 +487,7 @@ sub (wrap-mods (rest mods) inner)] (if (= (first m) :when) `(if ~(nth m 1) ~sub []) - ;; `let` (not let*) so a :let binding may itself - ;; destructure — (for [x xs :let [{:keys [y]} x]] …). - `(let ~(nth m 1) ~sub))))) + `(let* ~(nth m 1) ~sub))))) build (fn build [idx groups] (let [g (nth groups idx) my-bind (nth g 0) @@ -577,8 +516,6 @@ ;; name binds only in the taken branch (temp# tests the value); via `let` so the ;; binding form may itself destructure, matching Clojure. (defmacro when-let [bindings & body] - (when (not= 2 (count bindings)) - (throw (new IllegalArgumentException "when-let requires exactly 2 forms in binding vector"))) (let [form (bindings 0) tst (bindings 1)] `(let [temp# ~tst] (if temp# (let [~form temp#] ~@body) nil)))) diff --git a/jolt-core/clojure/core/20-coll.clj b/jolt-core/clojure/core/20-coll.clj index 34a2262..f5f688b 100644 --- a/jolt-core/clojure/core/20-coll.clj +++ b/jolt-core/clojure/core/20-coll.clj @@ -59,13 +59,11 @@ ;; nil, which prints as "nil" (str yields ""). Only the top-level arg needs the ;; guard; nil nested in a collection already renders as "nil" via the collection ;; printer. -;; print renders non-readably (__print1): a nested string is raw, unlike str/pr -;; which quote it. (print ["x"]) => [x], (str ["x"]) => ["x"]. (defn print [& xs] (__write (loop [out "" s (seq xs) first? true] (if s (let [x (first s) - r (__print1 x)] + r (if (nil? x) "nil" (str x))] (recur (str out (if first? "" " ") r) (next s) false)) out))) nil) @@ -155,43 +153,8 @@ (when-let [s (seq coll)] (or (pred (first s)) (recur pred (next s))))) -;; Reference arities: at least one predicate ((some-fn) is an arity error), and -;; the returned fn chains with or — a no-match result is the last predicate's -;; own falsy value (false stays false, not nil). -(defn some-fn - ([p] - (fn sp1 - ([] nil) - ([x] (p x)) - ([x y] (or (p x) (p y))) - ([x y z] (or (p x) (p y) (p z))) - ([x y z & args] (or (sp1 x y z) - (some p args))))) - ([p1 p2] - (fn sp2 - ([] nil) - ([x] (or (p1 x) (p2 x))) - ([x y] (or (p1 x) (p1 y) (p2 x) (p2 y))) - ([x y z] (or (p1 x) (p1 y) (p1 z) (p2 x) (p2 y) (p2 z))) - ([x y z & args] (or (sp2 x y z) - (some (fn [q] (or (p1 q) (p2 q))) args))))) - ([p1 p2 p3] - (fn sp3 - ([] nil) - ([x] (or (p1 x) (p2 x) (p3 x))) - ([x y] (or (p1 x) (p2 x) (p3 x) (p1 y) (p2 y) (p3 y))) - ([x y z] (or (p1 x) (p2 x) (p3 x) (p1 y) (p2 y) (p3 y) (p1 z) (p2 z) (p3 z))) - ([x y z & args] (or (sp3 x y z) - (some (fn [q] (or (p1 q) (p2 q) (p3 q))) args))))) - ([p1 p2 p3 & ps] - (let [ps (cons p1 (cons p2 (cons p3 ps)))] - (fn spn - ([] nil) - ([x] (some (fn [p] (p x)) ps)) - ([x y] (or (spn x) (spn y))) - ([x y z] (or (spn x) (spn y) (spn z))) - ([x y z & args] (or (spn x y z) - (some (fn [p] (some p args)) ps))))))) +(defn some-fn [& preds] + (fn [& xs] (some (fn [p] (some p xs)) preds))) (defn not-any? [pred coll] (not (some pred coll))) @@ -212,22 +175,13 @@ (defn simple-ident? [x] (or (simple-symbol? x) (simple-keyword? x))) -;; Numeric-tower predicates over the Chez tower (jolt has exact ints, ratios, and -;; flonums). ratio? = exact non-integer; rational? = exact (int or ratio). Built on -;; the jolt.host tower tests so they lower to the same code the native shims did. -;; decimal?/integer?/float?/int?/double? stay native (bigdec-extended or on the -;; compiler emit/inference path) — see predicates.ss. -(defn ratio? [x] - (and (number? x) (jolt.host/exact? x) (jolt.host/rational-type? x) (not (integer? x)))) -(defn rational? [x] - (or (and (number? x) (jolt.host/exact? x)) (decimal? x))) -;; No first-class Class objects: class names are symbols the evaluator handles in -;; instance?/new positions, never values — so nothing is a class. +;; Jolt has no ratio or bigdecimal types, so these are constants / reduce to int?. +(defn ratio? [x] false) +(defn decimal? [x] false) +;; No first-class Class objects either: class names are symbols the evaluator +;; handles in instance?/new positions, never values — so nothing is a class. (defn class? [x] false) -;; list?: a list-marked cseq node or the empty list (). A lazy/vector-backed seq, -;; (rest list), (seq coll), (map …) are seqs but not lists. Not extended like -;; map?/set?/seq?, so it migrates cleanly. -(defn list? [x] (or (and (jolt.host/cseq? x) (jolt.host/cseq-list? x)) (jolt.host/empty-list? x))) +(defn rational? [x] (int? x)) (defn nat-int? [x] (and (int? x) (>= x 0))) (defn neg-int? [x] (and (int? x) (neg? x))) (defn pos-int? [x] (and (int? x) (pos? x))) @@ -256,12 +210,7 @@ true)) false))) -;; A vector input maps to a vector (eager); any other coll to a lazy seq — JVM -;; replace is type-preserving, not vector-always. -(defn replace [smap coll] - (if (vector? coll) - (mapv (fn [x] (get smap x x)) coll) - (map (fn [x] (get smap x x)) coll))) +(defn replace [smap coll] (mapv (fn [x] (get smap x x)) coll)) (defn nthnext [coll n] (loop [n n xs (seq coll)] @@ -275,8 +224,7 @@ (loop [i 0 s (seq coll)] (if (and s (< i n)) (recur (inc i) (next s)) i)))) -;; the reducing fn returns proc's result, so a Reduced from proc short-circuits -(defn run! [proc coll] (reduce (fn [_ x] (proc x)) nil coll) nil) +(defn run! [proc coll] (reduce (fn [_ x] (proc x) nil) nil coll) nil) (defn completing ([f] (completing f identity)) @@ -335,40 +283,21 @@ (defn val [e] (if (map-entry? e) (nth e 1) (throw (ex-info "val requires a map entry" {})))) ;; --- Ad-hoc hierarchies (stage 3) — Clojure's canonical pure-map port. ----- -;; A hierarchy is {:parents {tag #{parents}} :ancestors {tag #{all}} +;; A hierarchy is {:parents {tag #{parents}} :ancestors {tag #{all}} ;; :descendants {tag #{all}}}. The 3-arity forms are PURE; the 1/2-arity forms ;; operate on the private global hierarchy atom. Multimethod dispatch ;; (evaluator defmulti-setup) calls isa? through the interned var. -;; -;; Ported from clojure.core with the reference's argument assertions and throw -;; contracts intact — bad shapes throw exactly where they do there (a non-map h -;; fails on the (parent-map tag) call, invalid tags fail the asserts). The class -;; arms answer through the host class graph (jolt.host/class-* seams). (defn make-hierarchy [] {:parents {} :descendants {} :ancestors {}}) (def ^:private global-hierarchy (atom (make-hierarchy))) -(defn- hier-assert [ok form] - (when-not ok (throw (new AssertionError (str "Assert failed: " form))))) - -;; a hierarchy tag naming a class — a class value, or the name string of a class -;; the host graph models (jolt classes are their name strings). -(defn- class-tag? [tag] (if (jolt.host/class-value? tag) true false)) - (defn isa? ([child parent] (isa? (deref global-hierarchy) child parent)) ([h child parent] (or (= child parent) - ;; JVM class assignability (Object root + modeled clojure.lang/java.* ancestry), - ;; so a class-keyed multimethod / (isa? (class x) C) dispatches like the JVM. - (jolt.host/class-isa? child parent) (contains? (get (get h :ancestors) child #{}) parent) - ;; a hierarchy relationship established on one of a class's supers - (and (class-tag? child) - (some (fn [s] (contains? (get (get h :ancestors) s #{}) parent)) - (jolt.host/class-supers child))) (and (vector? parent) (vector? child) (= (count parent) (count child)) (loop [ret true i 0] @@ -378,44 +307,19 @@ (defn parents ([tag] (parents (deref global-hierarchy) tag)) - ([h tag] (not-empty - (let [tp (get (get h :parents) tag)] - (if (class-tag? tag) - (into (set (jolt.host/class-bases tag)) tp) - tp))))) + ([h tag] (not-empty (get (get h :parents) tag)))) (defn ancestors ([tag] (ancestors (deref global-hierarchy) tag)) - ([h tag] (not-empty - (let [ta (get (get h :ancestors) tag)] - (if (class-tag? tag) - ;; the class's own ancestry plus hierarchy relationships derived - ;; on the class or any of its supers - (let [superclasses (set (jolt.host/class-supers tag))] - (reduce into superclasses - (cons ta (map (fn [s] (get (get h :ancestors) s)) - superclasses)))) - ta))))) + ([h tag] (not-empty (get (get h :ancestors) tag)))) (defn descendants ([tag] (descendants (deref global-hierarchy) tag)) - ([h tag] (if (class-tag? tag) - (throw (new UnsupportedOperationException "Can't get descendants of classes")) - (not-empty (get (get h :descendants) tag))))) + ([h tag] (not-empty (get (get h :descendants) tag)))) (defn derive - ([tag parent] - (hier-assert (namespace parent) "(namespace parent)") - (hier-assert (or (class-tag? tag) - (and (or (keyword? tag) (symbol? tag)) (namespace tag))) - "(or (class? tag) (and (instance? clojure.lang.Named tag) (namespace tag)))") - (swap! global-hierarchy derive tag parent) nil) + ([tag parent] (swap! global-hierarchy derive tag parent) nil) ([h tag parent] - (hier-assert (not= tag parent) "(not= tag parent)") - (hier-assert (or (class-tag? tag) (keyword? tag) (symbol? tag)) - "(or (class? tag) (instance? clojure.lang.Named tag))") - (hier-assert (or (keyword? parent) (symbol? parent)) - "(instance? clojure.lang.Named parent)") (let [tp (get h :parents) td (get h :descendants) ta (get h :ancestors) @@ -423,14 +327,14 @@ (reduce (fn [ret k] (assoc ret k (reduce conj (get targets k #{}) - (cons target (targets target))))) - m (cons source (sources source))))] + (cons target (get targets target))))) + m (cons source (get sources source))))] (or - (when-not (contains? (tp tag) parent) - (when (contains? (ta tag) parent) - (throw (new Exception (str tag " already has " parent " as ancestor")))) - (when (contains? (ta parent) tag) - (throw (new Exception (str "Cyclic derivation: " parent " has " tag " as ancestor")))) + (when-not (contains? (get tp tag #{}) parent) + (when (contains? (get ta tag #{}) parent) + (throw (str tag " already has " parent " as ancestor"))) + (when (contains? (get ta parent #{}) tag) + (throw (str "Cyclic derivation: " parent " has " tag " as ancestor"))) {:parents (assoc tp tag (conj (get tp tag #{}) parent)) :ancestors (tf ta tag td parent ta) :descendants (tf td parent ta tag td)}) @@ -440,15 +344,15 @@ ([tag parent] (swap! global-hierarchy underive tag parent) nil) ([h tag parent] (let [parent-map (get h :parents) - childs-parents (if (parent-map tag) - (disj (parent-map tag) parent) + childs-parents (if (get parent-map tag) + (disj (get parent-map tag) parent) #{}) new-parents (if (not-empty childs-parents) (assoc parent-map tag childs-parents) (dissoc parent-map tag)) deriv-seq (mapcat (fn [e] (cons (key e) (interpose (key e) (val e)))) (seq new-parents))] - (if (contains? (parent-map tag) parent) + (if (contains? (get parent-map tag #{}) parent) (reduce (fn [p [t pr]] (derive p t pr)) (make-hierarchy) (partition 2 deriv-seq)) h)))) @@ -459,8 +363,7 @@ (defn sequential? [x] (or (vector? x) (seq? x))) (defn associative? [x] (or (map? x) (vector? x))) (defn counted? [x] - ;; a String is not Counted on the JVM (count works via CharSequence, not O(1)) - (or (vector? x) (map? x) (set? x) (list? x))) + (or (vector? x) (map? x) (set? x) (list? x) (string? x))) (defn indexed? [x] (vector? x)) ;; sorted? is defined by the next tier (25-sorted) — declared here so this ;; tier compiles (forward references are analysis errors). @@ -468,7 +371,7 @@ (defn reversible? [x] (or (vector? x) (sorted? x))) (defn seqable? [x] - (if (or (nil? x) (coll? x) (string? x) (jolt.host/array-value? x)) true false)) + (or (nil? x) (coll? x) (string? x))) (defn boolean? [x] (or (true? x) (false? x))) (defn double? [x] (and (number? x) (not (integer? x)))) @@ -500,9 +403,7 @@ (future? x) (boolean (get x :cached)) (= :jolt/lazy-seq (get x :jolt/type)) (boolean (get x :realized)) (atom? x) true - ;; name the class, never the value — an error message must not render an - ;; arbitrary (possibly infinite) argument. - :else (throw (str "realized? not supported on: " (class x))))) + :else (throw (str "realized? not supported on: " x)))) (defn force [x] (if (delay? x) (deref x) x)) diff --git a/jolt-core/clojure/core/21-coll.clj b/jolt-core/clojure/core/21-coll.clj index 3a12c8e..f4af5af 100644 --- a/jolt-core/clojure/core/21-coll.clj +++ b/jolt-core/clojure/core/21-coll.clj @@ -12,8 +12,7 @@ ;; Clojure. Collections only — a string is seqable but not shuffleable, as on ;; the JVM (Collections/shuffle wants a Collection). (defn shuffle [coll] - ;; Collections/shuffle wants a java.util.Collection — a map is not one - (when (or (not (coll? coll)) (map? coll)) + (when-not (coll? coll) (throw (ex-info (str "shuffle requires a collection, got: " coll) {}))) (loop [v (vec coll) i (dec (count v))] (if (pos? i) @@ -29,10 +28,6 @@ (defn sort-by ([keyfn coll] (sort-by keyfn compare coll)) ([keyfn comp coll] - ;; a collection is never a Comparator (the JVM cast would fail); catching it - ;; here beats silently "sorting" through coll-as-fn lookups - (when (coll? comp) - (throw (new ClassCastException (str (class comp) " cannot be cast to java.util.Comparator")))) (sort (fn [x y] (comp (keyfn x) (keyfn y))) coll))) ;; parse-uuid: nil unless s is a canonical 8-4-4-4-12 hex UUID string; throws @@ -66,10 +61,9 @@ \backspace "backspace" \space "space"}) (defn char-name-string [c] (get char-name-strings c)) -;; Random selection over the host rand primitives — the reference shape: -;; nth directly (nil returns nil via RT.nth; a set throws like the JVM). +;; Random selection over the host rand primitives. (defn rand-nth [coll] - (nth coll (rand-int (count coll)))) + (let [v (vec coll)] (nth v (rand-int (count v))))) (defn random-sample ([prob] (filter (fn [_] (< (rand) prob)))) @@ -139,8 +133,8 @@ (concat (map first ss) (apply interleave (map rest ss)))))))) -;; rationalize is host-native (java/bigdec.ss): a double routes through its -;; shortest decimal print like BigDecimal.valueOf, so (rationalize 1.1) is 11/10. +;; No ratio type on Jolt, so rationalize is identity. +(defn rationalize [x] x) ;; 0-arg: a stateful transducer (tracks [seen? prev] in a volatile, so no sentinel ;; value is needed). 1-arg: eager dedupe of consecutive equal elements. @@ -166,14 +160,11 @@ (coll->cells (step (rest s) prev)) (coll->cells (cons x (step (rest s) x))))) nil)))))] - ;; defer (seq coll) into the lazy-seq so a side-effecting source is not - ;; realized at construction (dedupe is lazy, like Clojure's). - (make-lazy-seq - (fn* [] - (let [s (seq coll)] - (if s - (coll->cells (cons (first s) (step (rest s) (first s)))) - nil))))))) + (let [s (seq coll)] + (if s + (make-lazy-seq + (fn* [] (coll->cells (cons (first s) (step (rest s) (first s)))))) + ()))))) ;; Internal helper for {:keys [...]} destructuring over a seq of k/v pairs — ;; canonical Clojure 1.11 shape (core.clj seq-to-map-for-destructuring): @@ -233,14 +224,13 @@ (defn inst-ms [x] (if (inst? x) (get x :ms) (throw (str "inst-ms requires an inst, got: " x)))) -;; Clojure 1.11 map transformers. An empty-map base keeps insertion order; -;; transformed keys canonicalize via assoc (collisions: last entry in seq order -;; wins, matching the reference). +;; Clojure 1.11 map transformers. PHM base so transformed keys canonicalize +;; (collisions: last entry in seq order wins, matching the reference). (defn update-keys [m f] - (reduce-kv (fn [acc k v] (assoc acc (f k) v)) {} m)) + (reduce-kv (fn [acc k v] (assoc acc (f k) v)) (hash-map) m)) (defn update-vals [m f] - (reduce-kv (fn [acc k v] (assoc acc k (f v))) {} m)) + (reduce-kv (fn [acc k v] (assoc acc k (f v))) (hash-map) m)) ;; Vector-returning partition variants (1.11): lazy seqs OF vectors. (defn partitionv @@ -277,10 +267,7 @@ (when (< i (count vars)) (var-set (nth vars i) (nth saved i)) (recur (inc i)))))))) -;; A vector's seq IS a real chunked-seq (chunk-first hands out a 32-element block). -;; This is only a placeholder so references compile during overlay load; the host -;; rebinds chunked-seq? to na-chunked-seq? in post-prelude.ss, which returns true -;; for a vector seq and false otherwise. +;; Jolt has no chunked seqs, so this is always false. (defn chunked-seq? [x] false) ;; Atom peripheral operations. atom/swap!/reset!/deref stay native — the compiler @@ -353,16 +340,12 @@ (defn clojure-version [] "1.11.0-jolt") -;; bigdec is a host fn (host/chez/java/bigdec.ss) — a real BigDecimal value type. -;; numerator/denominator are host natives (converters.ss) over Chez's exact -;; rationals; a non-ratio is the Ratio cast failure. +;; bigdec is a host fn (host/chez/bigdec.ss) — a real BigDecimal value type. +(defn numerator [x] (throw (ex-info "numerator requires a ratio (Jolt has no ratios)" {}))) +(defn denominator [x] (throw (ex-info "denominator requires a ratio (Jolt has no ratios)" {}))) -;; jolt has no reflection, but a few common JVM interfaces carry a modeled -;; ancestry (jolt.host/class-supers) so reflective checks like -;; (ancestors (class f)) answer like the JVM. -(defn supers [x] - (let [s (jolt.host/class-supers x)] - (if s (set s) #{}))) +;; No class hierarchy on this host. +(defn supers [x] #{}) ;; Like Clojure's munge: rewrite dashes to underscores, preserving the argument's ;; type — a symbol munges to a symbol, anything else to a string. (jolt only diff --git a/jolt-core/clojure/core/22-coll.clj b/jolt-core/clojure/core/22-coll.clj index 873dcfa..9a2079b 100644 --- a/jolt-core/clojure/core/22-coll.clj +++ b/jolt-core/clojure/core/22-coll.clj @@ -21,46 +21,23 @@ (defn true? [x] (= true x)) (defn false? [x] (= false x)) -;; Presence-preserving and order-preserving: a key with a nil value is kept, and -;; the result follows keyseq order (an empty-map base keeps nil values and -;; canonicalizes collection keys). +;; Presence-preserving: a key with a nil value is kept ((hash-map) base keeps +;; nil values and canonicalizes collection keys). (defn select-keys [map keyseq] (reduce (fn [m k] (if (contains? map k) (assoc m k (get map k)) m)) - {} keyseq)) + (hash-map) keyseq)) (defn zipmap [keys vals] - (loop [m {} ks (seq keys) vs (seq vals)] + (loop [m (hash-map) ks (seq keys) vs (seq vals)] (if (and ks vs) (recur (assoc m (first ks) (first vs)) (next ks) (next vs)) m))) -;; Structmaps (legacy). A struct basis is the ordered vector of slot keys; a -;; struct map is a plain map carrying every basis key (nil when unset), in basis -;; order, so it looks up and compares like any other map. -(defn create-struct [& keys] (vec keys)) - -(defn struct-map [basis & inits] - (let [base (loop [m {} ks (seq basis)] - (if ks (recur (assoc m (first ks) nil) (next ks)) m))] - (loop [m base kvs (seq inits)] - (if kvs - (recur (assoc m (first kvs) (first (next kvs))) (next (next kvs))) - m)))) - -(defn struct [basis & vals] - (loop [m (struct-map basis) ks (seq basis) vs (seq vals)] - (if (and ks vs) - (recur (assoc m (first ks) (first vs)) (next ks) (next vs)) - m))) - -(defn accessor [basis key] - (fn [m] (get m key))) - ;; conj semantics per entry arg (a map merges, a [k v] pair adds); nil args are ;; no-ops; all-nil (or no args) is nil. (defn merge [& maps] (when (some identity maps) - (reduce (fn [acc m] (if (nil? m) acc (conj (or acc {}) m))) + (reduce (fn [acc m] (if (nil? m) acc (conj (or acc (hash-map)) m))) maps))) (defn merge-with [f & maps] @@ -72,7 +49,7 @@ (assoc m k (f (get m k) v)) (assoc m k v)))) merge2 (fn [m1 m2] - (reduce merge-entry (or m1 {}) (seq m2)))] + (reduce merge-entry (or m1 (hash-map)) (seq m2)))] (reduce merge2 maps)))) (defn get-in @@ -89,21 +66,6 @@ (recur nxt (next ks)))) m))))) -(defn req! - "Returns the value mapped to key k in map m, like `get`, but throws - IllegalArgumentException when k is not present. Unlike `get`, does not nil-pun: - a key present with a nil value returns nil, an absent key throws. The primitive - behind checked-keys destructuring (:keys! / :syms! / :strs!)." - {:added "1.13"} - [m k] - ;; a fresh map is its own identity, so a present-but-nil value is distinguished - ;; from an absent key (same trick as get-in's sentinel). - (let [sentinel (hash-map) - v (get m k sentinel)] - (if (identical? sentinel v) - (throw (new IllegalArgumentException (str "Expected key: " k))) - v))) - ;; find-based, so nil RESULTS are cached too; args canonicalize as a collection key. (defn memoize [f] (let [mem (atom (hash-map))] @@ -148,12 +110,6 @@ (defn empty [coll] (cond (nil? coll) nil - ;; a deftype/record with its own empty (IPersistentCollection) — e.g. - ;; data.priority-map — uses it, before the generic map/set/vector arms. - (jolt.host/jrec-method? coll "empty") (.empty coll) - ;; a defrecord without its own empty can't have one (RT: UnsupportedOperation) - (record? coll) (throw (new UnsupportedOperationException - (str "Can't create empty: " (.getName (class coll))))) (sorted? coll) ((get (jolt.host/ref-get coll :ops) :empty) coll) (map? coll) (with-meta {} (meta coll)) (set? coll) (with-meta #{} (meta coll)) @@ -201,16 +157,10 @@ ([x y z & args] (f (apply g x y z args))))) ([f g & fs] (reduce comp (comp f g) fs))) -;; Canonical IFn set: fns, keywords, symbols, maps (sorted incl.), sets, -;; vectors, vars — NOT lists ((ifn? '(1 2)) is false in Clojure) — plus the -;; host callables (multimethods, promises) and a deftype/record implementing -;; clojure.lang.IFn's invoke. +;; Canonical IFn set: fns, keywords, symbols, maps (sorted incl.), +;; sets, vectors, and vars — NOT lists ((ifn? '(1 2)) is false in Clojure). (defn ifn? [x] - (if (or (fn? x) (keyword? x) (symbol? x) (map? x) (set? x) (vector? x) (var? x) - (jolt.host/callable-host? x) - (jolt.host/jrec-method? x "invoke")) - true - false)) + (or (fn? x) (keyword? x) (symbol? x) (map? x) (set? x) (vector? x) (var? x))) ;; Auto-promoting (') and unchecked arithmetic. Jolt numbers don't overflow, ;; so all of these are the checked ops; fixed arities mirror Clojure's @@ -221,10 +171,22 @@ (def *' *) (def inc' inc) (def dec' dec) -;; unchecked-add / -subtract / -multiply / -negate / -inc / -dec (+ the -int -;; variants), -divide-int / -remainder-int, and the unchecked-long/-int casts are -;; host-defined (host/chez/seq.ss, converters.ss): they WRAP like the JVM -;; primitive conversions, which a plain overlay over checked casts can't do. +(defn unchecked-add [x y] (+ x y)) +(defn unchecked-subtract [x y] (- x y)) +(defn unchecked-multiply [x y] (* x y)) +(defn unchecked-negate [x] (- x)) +(defn unchecked-inc [x] (+ x 1)) +(defn unchecked-dec [x] (- x 1)) +(def unchecked-add-int unchecked-add) +(def unchecked-subtract-int unchecked-subtract) +(def unchecked-multiply-int unchecked-multiply) +(def unchecked-negate-int unchecked-negate) +(def unchecked-inc-int unchecked-inc) +(def unchecked-dec-int unchecked-dec) +(defn unchecked-divide-int [x y] (quot x y)) +(defn unchecked-remainder-int [x y] (rem x y)) +(defn unchecked-int [x] (int x)) +(def unchecked-long unchecked-int) ;; int? is integer? on jolt: one number type, so fixed-precision and ;; arbitrary-precision integers coincide. @@ -286,14 +248,12 @@ (defn to-array-2d [coll] (to-array (map to-array coll))) -;; Wrapping (unchecked) coercions: truncate to the width and sign-fold like the -;; JVM primitive conversions ((unchecked-byte 200) is -56); unchecked-char wraps -;; into char range. unchecked-long/int are host natives (converters.ss). -(defn unchecked-byte [x] - (let [b (bit-and (unchecked-long x) 0xff)] (if (< b 128) b (- b 256)))) -(defn unchecked-short [x] - (let [s (bit-and (unchecked-long x) 0xffff)] (if (< s 32768) s (- s 65536)))) -(defn unchecked-char [x] (char (bit-and (unchecked-long x) 0xffff))) +;; Masking integer coercions (not aliases): byte/short wrap to their width. +;; unchecked-byte/short truncate to a number; unchecked-char returns a char (as on +;; the JVM). int handles chars, so (unchecked-byte \a) works. +(defn unchecked-byte [x] (bit-and (int x) 0xff)) +(defn unchecked-short [x] (bit-and (int x) 0xffff)) +(defn unchecked-char [x] (char (bit-and (int x) 0xffff))) (defn unchecked-float [x] (double x)) (defn unchecked-double [x] (double x)) @@ -311,28 +271,18 @@ ;; eduction is EAGER on jolt (documented divergence): the composed ;; xforms applied to coll, realized into a vector. -;; A lazy application of the composed xforms to coll (sequence is lazy now), so an -;; infinite or expensive source isn't realized up front. Not a re-iterable Eduction -;; object, but reduce / into / seq / first over it all work. (defn eduction [& args] (let [coll (last args) xforms (butlast args)] (if xforms - (sequence (apply comp xforms) coll) - (sequence coll)))) + (into [] (apply comp xforms) coll) + (into [] coll)))) -(defn ->Eduction [xform coll] (sequence xform coll)) +(defn ->Eduction [xform coll] (into [] xform coll)) ;; --- JVM-shape stubs and trivial shells -------------------------------------- ;; Pure compositions or documented jolt stubs; the host keeps nothing. -;; enumeration-seq drives a java.util.Enumeration (StringTokenizer, etc.) through -;; hasMoreElements/nextElement, like the JVM; an already-seqable arg (a jolt seq — -;; some host code passes a list) just seqs. -(defn enumeration-seq [e] - (if (or (nil? e) (seq? e) (sequential? e)) - (seq e) - (lazy-seq (when (.hasMoreElements e) - (cons (.nextElement e) (enumeration-seq e)))))) +(defn enumeration-seq [e] (seq e)) (defn iterator-seq [i] (seq i)) ;; jolt is single-threaded: a promise is an atom, deref never blocks @@ -348,8 +298,7 @@ ;; stays an unevaluated reader form on jolt and contains? can't see into it. (def ^:private special-syms #{'if 'do 'let* 'fn* 'quote 'var 'def 'loop* 'recur 'throw 'try 'catch - 'finally 'new 'set! '. 'monitor-enter 'monitor-exit - '& 'case* 'deftype* 'letfn* 'reify*}) + 'finally 'new 'set! '. 'monitor-enter 'monitor-exit}) (defn special-symbol? [s] (contains? special-syms s)) @@ -364,14 +313,3 @@ (defn proxy-super [& args] (throw "proxy-super: JVM proxies are not supported in Jolt")) (defn construct-proxy [c & args] (throw "construct-proxy: not supported in Jolt")) (defn get-proxy-class [& interfaces] (throw "get-proxy-class: not supported in Jolt")) - -;; resolve, requiring the symbol's namespace first when it isn't loaded yet — -;; the dynamic-require pattern (tooling, plugin registries). The require and -;; resolve are the runtime fns, so this works identically under joltc run and -;; in an AOT binary (which compiles the namespace from the source roots). -(defn requiring-resolve [sym] - (if (qualified-symbol? sym) - (or (resolve sym) - (do (require (symbol (namespace sym))) - (resolve sym))) - (throw (new IllegalArgumentException (str "Not a qualified symbol: " sym))))) diff --git a/jolt-core/clojure/core/30-macros.clj b/jolt-core/clojure/core/30-macros.clj index be1c240..f563140 100644 --- a/jolt-core/clojure/core/30-macros.clj +++ b/jolt-core/clojure/core/30-macros.clj @@ -28,18 +28,11 @@ (let [args (if (string? (first args)) (rest args) args) args (if (and (map? (first args)) (not (symbol? (first args)))) (rest args) args) dispatch (first args) - opts (rest args) - ;; qualify with the EXPANSION ns: a defmulti deferred inside a fn (a - ;; deftest body) must still define in the ns it was written in. - qname (symbol (str (clojure.core/ns-name clojure.core/*ns*)) - (clojure.core/name name))] - `(defmulti-setup (quote ~qname) ~dispatch ~@opts))) + opts (rest args)] + `(defmulti-setup (quote ~name) ~dispatch ~@opts))) (defmacro defmethod [mm dispatch-val & fn-tail] - ;; the expansion ns rides along so a deferred defmethod resolves its multifn - ;; against the ns it was written in (aliases and refers included). - `(defmethod-setup (quote ~mm) ~dispatch-val (fn ~@fn-tail) - ~(str (clojure.core/ns-name clojure.core/*ns*)))) + `(defmethod-setup (quote ~mm) ~dispatch-val (fn ~@fn-tail))) ;; Multimethod table ops: a multimethod's method table lives on its ;; VAR (the value is just the dispatch closure), so these pass the name quoted @@ -76,10 +69,10 @@ `(instance-check ~t ~x) `(instance-check (quote ~t) ~x))) -;; Take x's monitor for the duration of body (futures/agents/threads share one -;; heap, so this is a real per-object lock), releasing on any exit. +;; Single-threaded host: evaluate the monitor expr (for its effects, matching +;; Clojure's evaluation order) and the body — no lock to take. (defmacro locking [x & body] - `(jolt.host/with-monitor ~x (fn* [] ~@body))) + `(do ~x ~@body)) ;; defonce: define name only if it isn't already bound to a non-nil root; ;; returns the existing var untouched otherwise. @@ -116,15 +109,11 @@ (with-open ~(vec (drop 2 bindings)) ~@body) (finally (__close ~(first bindings))))))) -;; Binds *math-context*; BigDecimal arithmetic in the dynamic scope rounds its -;; results to the precision with the rounding mode (default HALF_UP, like -;; java.math.MathContext). +;; jolt numbers are doubles — there is no BigDecimal math context, so the +;; precision (and optional :rounding mode) is accepted and ignored. (defmacro with-precision [precision & exprs] - (let [[rounding body] (if (= :rounding (first exprs)) - [(second exprs) (drop 2 exprs)] - ['HALF_UP exprs])] - `(binding [clojure.core/*math-context* {:precision ~precision :rounding '~rounding}] - ~@body))) + (let [body (if (= :rounding (first exprs)) (drop 2 exprs) exprs)] + `(do ~@body))) (defmacro with-bindings [binding-map & body] `(with-bindings* ~binding-map (fn [] ~@body))) @@ -175,8 +164,9 @@ (loop [~i 0] (when (< ~i n#) ~@body (recur (inc ~i))))))) -;; fresh-sym (a macro-body gensym round-tripped through str) is defined in -;; 00-syntax, which loads before this tier — reuse it. +;; A fresh jolt symbol inside a macro body: a bare (gensym) returns a host symbol +;; the destructurer rejects, so round-trip through str. +(defn- fresh-sym [] (symbol (str (gensym)))) ;; Lazy-safe: take only the head via first (Clojure uses (seq coll), but Jolt's ;; eager seq would realize an infinite coll like (repeat nil) and hang). @@ -218,10 +208,8 @@ `(let [~g ~expr ~@(thread-binds g steps)] ~(if (empty? steps) g (last steps))))) (defmacro assert [x & [message]] - (let [msg (if message - (str "Assert failed: " message "\n" (pr-str x)) - (str "Assert failed: " (pr-str x)))] - `(when-not ~x (throw (new AssertionError ~msg))))) + (let [msg (if message message (str "Assert failed: " (pr-str x)))] + `(when-not ~x (throw (ex-info ~msg {}))))) ;; (pvalues e1 e2 ...) — each expression evaluated in parallel (pcalls). (defmacro pvalues [& exprs] @@ -274,10 +262,6 @@ ;; Group a flat seq that starts with a head symbol followed by its list specs ;; into [[head spec spec ...] ...] runs. Used by extend-protocol and defrecord. -;; Group deftype/defrecord/reify body forms: a symbol/nil head starts a new -;; group, every other form appends to the current one. (extend-protocol uses -;; parse-extend-impls instead — it must treat a COMPUTED class type like -;; (Class/forName "[B"), a seq, as a head, which this would misread as a method.) (defn- group-by-head [items] ;; nil is a valid extension head (extend-protocol P ... nil (m [x] ...)). (reduce (fn [acc x] @@ -292,10 +276,6 @@ ;; type's fields, bound from the instance (the method's first param), matching ;; Clojure's deftype scope. defrecord (below) expands to a bodyless (deftype …) and ;; handles its own methods, so this also serves the no-body case. -;; Legacy structmap definer: binds a var to the struct basis (see create-struct). -(defmacro defstruct [name & keys] - `(def ~name (create-struct ~@keys))) - (defmacro deftype [tname fields & body] ;; strip ^meta off the type name and fields (the reader yields a (with-meta sym m) ;; form for e.g. (deftype ^{:doc …} Foo …)), so (name …) sees a bare symbol. @@ -330,61 +310,16 @@ ;; in-place field write the analyzer compiles to jolt-set-field!. mutable-syms (map first (filter second (map vector fields field-muts))) mutable? (fn [s] (boolean (some (fn [m] (= m s)) mutable-syms))) - ;; rewrite a method body: (set! mut-field v) -> an in-place (.-field inst) - ;; write, and a READ of a mutable field -> (.-field inst) so it observes the - ;; live value after a set! (the double-checked-locking idiom re-reads a field - ;; after taking a lock). Immutable fields stay let-bound (captured once is - ;; correct and cheaper). Tracks lexical shadowing through let/loop/fn/letfn so - ;; a same-named local wins over a field. - rewrite-body - (fn rw [inst shadowed form] - (cond - (and (seq? form) (seq form) (symbol? (first form)) - (= "set!" (name (first form))) - (symbol? (second form)) (mutable? (second form)) - (not (contains? shadowed (second form)))) - (list 'set! (list (symbol (str ".-" (name (second form)))) inst) - (rw inst shadowed (nth form 2))) - ;; let/loop-style vector-binding forms: rewrite inits, then shadow the - ;; bound names in the body. - (and (seq? form) (seq form) (symbol? (first form)) - (contains? #{"let" "let*" "loop" "binding" "when-let" "if-let" - "when-some" "if-some"} (name (first form))) - (vector? (second form))) - (let [bv (second form) n (count bv) - bv' (loop [i 0 acc []] - (if (< i n) - (recur (+ i 2) - (let [a (conj acc (nth bv i))] - (if (< (inc i) n) (conj a (rw inst shadowed (nth bv (inc i)))) a))) - acc)) - sh (loop [i 0 acc shadowed] - (if (< i n) - (recur (+ i 2) (if (symbol? (nth bv i)) (conj acc (nth bv i)) acc)) - acc))] - (cons (first form) (cons bv' (map (fn [x] (rw inst sh x)) (drop 2 form))))) - ;; fn/fn*: shadow each arity's params in its body. - (and (seq? form) (seq form) (symbol? (first form)) - (contains? #{"fn" "fn*"} (name (first form)))) - (let [head (first form) tail (rest form) - named? (and (seq tail) (symbol? (first tail))) - fname (when named? (first tail)) - arts (if named? (rest tail) tail) - psyms (fn [pv] (loop [p (seq pv) acc shadowed] - (if p - (recur (next p) - (if (and (symbol? (first p)) (not= (name (first p)) "&")) - (conj acc (first p)) acc)) - acc))) - do-art (fn [ar] (cons (first ar) (map (fn [x] (rw inst (psyms (first ar)) x)) (rest ar)))) - arts' (if (vector? (first arts)) (do-art arts) (map do-art arts))] - (concat (list head) (when named? (list fname)) arts')) - ;; a bare read of a mutable field -> live field access - (and (symbol? form) (mutable? form) (not (contains? shadowed form))) - (list (symbol (str ".-" (name form))) inst) - (seq? form) (map (fn [x] (rw inst shadowed x)) form) - (vector? form) (mapv (fn [x] (rw inst shadowed x)) form) - :else form)) + rewrite-set (fn rw [inst form] + (cond + (and (seq? form) (seq form) (symbol? (first form)) + (= "set!" (name (first form))) + (symbol? (second form)) (mutable? (second form))) + (list 'set! (list (symbol (str ".-" (name (second form)))) inst) + (rw inst (nth form 2))) + (seq? form) (map (fn [x] (rw inst x)) form) + (vector? form) (mapv (fn [x] (rw inst x)) form) + :else form)) ;; inline impls register for dispatch but are NOT extenders of the ;; protocol (the JVM compiles them into the class) — register-inline-method, ;; not extend-type. @@ -392,22 +327,10 @@ ;; The clause is DATA, not a syntax-quote: a body that is itself a syntax- ;; quote would have its ~unquotes consumed a level early if re-spliced. mk-clause (fn [spec] - ;; fresh-name each _ param so two _ params don't collide on the - ;; field binds / live-read instance (see defrecord's mk-clause). - (let [argv (mapv (fn [p] (if (= p (quote _)) (gensym "_p") p)) (nth spec 1)) + (let [argv (nth spec 1) inst (first argv) - ;; A method param shadows a same-named field (Clojure - ;; semantics): don't let-bind a field the param already - ;; provides, and treat those params as shadowing so a - ;; mutable field's live-read rewrite doesn't override them. - pnames (set (map name argv)) - ;; let-bind only immutable fields; mutable ones are read live - ;; via rewrite-body so a set! within the method is observed. - binds (vec (mapcat (fn [f] [f `(get ~inst ~(keyword (name f)))]) - (filter (fn [f] (and (not (mutable? f)) - (not (contains? pnames (name f))))) - fields))) - mbody (map (fn [bf] (rewrite-body inst (set argv) bf)) (drop 2 spec))] + binds (vec (mapcat (fn [f] [f `(get ~inst ~(keyword (name f)))]) fields)) + mbody (map (fn [bf] (rewrite-set inst bf)) (drop 2 spec))] (list argv (list* 'let binds mbody)))) groups (group-by-head body) ;; merge clauses by method NAME across ALL protocols into one multi-arity @@ -456,28 +379,13 @@ ;; register method var-keys for devirtualization; the inference ;; reads this (via infer-unit!) to resolve a protocol call on a known record (register-protocol-methods! ~(name pname) [~@(map (fn [s] (name (first s))) sigs)]) - ;; one fn clause per declared arity. The protocol/method NAMES pass as - ;; strings so the body compiles as a plain invoke (not symbol-as-var). The - ;; common 1/2/3-param arities call positional protocol-dispatchN, which - ;; applies the impl directly — no rest-list cons; 4+ params fall back to the - ;; variadic protocol-dispatch with a vector of the extra args. ~@(map (fn [sig] - (let [pn (name pname) - mn (name (first sig)) - arglists (filter vector? (rest sig)) - clause (fn [argv] - (let [ps (mapv (fn [_] (fresh-sym)) argv) - n (count ps) - obj (first ps)] - (cond - (= n 1) (list ps (list 'protocol-dispatch1 pn mn obj)) - (= n 2) (list ps (list 'protocol-dispatch2 pn mn obj (nth ps 1))) - (= n 3) (list ps (list 'protocol-dispatch3 pn mn obj (nth ps 1) (nth ps 2))) - :else (list ps (list 'protocol-dispatch pn mn obj (vec (rest ps)))))))] - (if (seq arglists) - `(def ~(first sig) (fn* ~@(map clause arglists))) - `(def ~(first sig) - (fn* [this# & rest#] (protocol-dispatch ~pn ~mn this# rest#)))))) + `(def ~(first sig) + ;; protocol-dispatch is a fn (clojure.core); pass the protocol / + ;; method NAMES as strings (not the symbols) so it compiles as a + ;; plain invoke rather than evaluating the symbols as vars. + (fn* [this# & rest#] + (protocol-dispatch ~(name pname) ~(name (first sig)) this# rest#)))) sigs)))) ;; Member threading: (.. x f g) => (. (. x f) g); a parenthesized member @@ -506,23 +414,12 @@ (or (= tn want) (suffix? tn want) (suffix? want tn)))) (extenders protocol))))) -;; The canonical name for a protocol-extension type: a symbol/keyword via name, a -;; string as-is, nil as "nil" (extends on nil values), and a Class VALUE — e.g. -;; (Class/forName "[B") for the byte-array class — via .getName. Lets a library -;; extend a protocol to a class it computes rather than names with a symbol. -(defn type->name [t] - (cond (nil? t) "nil" - (string? t) t - (symbol? t) (name t) - (keyword? t) (name t) - :else (.getName t))) - ;; extend, the FUNCTION (extend-type's runtime sibling): protocol + method-map ;; pairs, methods registered under the type's (canonicalized) name — so ;; (extend 'String P {:m (fn [x] ...)}) dispatches exactly like extend-type. (defn extend [atype & proto+mmaps] ;; nil extends on nil values; its host tag is the string "nil" (as extend-type). - (let [tname (type->name atype)] + (let [tname (if (nil? atype) "nil" (name atype))] (loop [s (seq proto+mmaps)] (when s (let [proto (first s) @@ -539,51 +436,25 @@ ;; `body` is one or more protocols, each followed by its method specs: ;; (extend-type T P1 (m1 [_] ..) P2 (m2 [_] ..)) — a bare symbol switches the ;; current protocol (like reify), so multiple protocols extend in one form. - ;; tsym may be a symbol/nil (name resolved at compile time) or a computed class - ;; expression like (Class/forName "[B") — bind its runtime name once. - (let [literal? (or (nil? tsym) (symbol? tsym)) - tn (gensym "tname") - tref (if literal? (if (nil? tsym) "nil" (name tsym)) tn) - emit (fn [] - (loop [items (seq body) proto nil forms []] - (if (empty? items) - forms - (let [x (first items)] - (if (symbol? x) - (recur (rest items) (name x) forms) - (recur (rest items) proto - (conj forms - `(register-method ~tref ~proto ~(name (first x)) - (fn ~(nth x 1) ~@(drop 2 x))))))))))] - (if literal? - `(do ~@(emit)) - `(let [~tn (type->name ~tsym)] ~@(emit) nil)))) - -;; Group an extend-protocol body into [type method-spec*] groups: the type is the -;; first item and its method specs are the seqs that follow it (up to the next -;; type — a symbol/nil — or end). Handles a computed class type (a seq like -;; (Class/forName "[B")) positionally, matching Clojure's parse-impls. -(defn- parse-extend-impls [items] - (loop [s (seq items) groups []] - (if (empty? s) - groups - (let [after (rest s)] - (recur (drop-while seq? after) - (conj groups (vec (cons (first s) (take-while seq? after))))))))) + (let [tname (if (nil? tsym) "nil" (name tsym))] + (loop [items (seq body) proto nil forms []] + (if (empty? items) + `(do ~@forms) + (let [x (first items)] + (if (symbol? x) + (recur (rest items) (name x) forms) + (recur (rest items) proto + (conj forms + `(register-method ~tname ~proto ~(name (first x)) + (fn ~(nth x 1) ~@(drop 2 x))))))))))) (defmacro extend-protocol [psym & type-impls] `(do ~@(map (fn [g] `(extend-type ~(first g) ~psym ~@(rest g))) - (parse-extend-impls type-impls)))) + (group-by-head type-impls)))) ;; extend is a real FUNCTION — defined above extend-type. -;; JVM proxies are unsupported in general, EXCEPT (proxy [ThreadLocal] [] (initialValue -;; [] body)) — a per-thread store with a lazy initial value (test.check's no-seed -;; PRNG uses one). Other proxies stay nil. -(defmacro proxy [supers ctor-args & methods] - (when (and (vector? supers) (= 1 (count supers)) - (let [s (name (first supers))] (or (= s "ThreadLocal") (= s "InheritableThreadLocal")))) - (let [init (some (fn [m] (when (= "initialValue" (name (first m))) m)) methods)] - `(jolt.host/make-thread-local (fn [] ~@(when init (nnext init))))))) +;; JVM proxies are unsupported. +(defmacro proxy [& args] nil) ;; definterface is JVM-only; bind the name to a marker and return the name (not a ;; var), matching the JVM where definterface yields the interface Class. (defmacro definterface [name-sym & body] @@ -627,18 +498,10 @@ ;; one clause from a spec; `this` is hinted with the record type so the ;; inference reads its fields bare-index. Clause as DATA (see deftype). mk-clause (fn [spec] - ;; rename each _ parameter to a fresh symbol so two _ params - ;; (the common (m [_ _] …) on a 1-arg protocol method) don't - ;; collide — the field binds read (get this :field) off the - ;; FIRST param, which an ignored second _ would otherwise shadow. - (let [argv (mapv (fn [p] (if (= p (quote _)) (gensym "_p") p)) (nth spec 1)) + (let [argv (nth spec 1) inst (first argv) hinted (assoc argv 0 (vary-meta inst assoc :tag (name name-sym))) - ;; a method param shadows a same-named field (Clojure - ;; semantics), so don't rebind a field the param provides. - pnames (set (map name argv)) - binds (vec (mapcat (fn [f] [f `(get ~inst ~(keyword (name f)))]) - (remove (fn [f] (contains? pnames (name f))) fields)))] + binds (vec (mapcat (fn [f] [f `(get ~inst ~(keyword (name f)))]) fields))] (list hinted (list* 'let binds (drop 2 spec))))) groups (group-by-head body) ;; merge clauses by name across protocols into one multi-arity fn (see @@ -651,14 +514,7 @@ ;; deftype already defines ->name (= the ctor); no (name. …) interop needed, ;; so defrecord compiles too. map->name builds via that ctor. (deftype ~name-sym ~fields) - ;; mark the type a record (map?/record?/field-seq); a bare deftype is not. - (register-record-type! (quote ~name-sym)) - ;; build via the positional ctor for declared fields, then carry any - ;; remaining keys as extension fields (JVM keeps them on the record). - (def ~mapf (fn* [~m] - (reduce-kv assoc - (~arrow ~@(map (fn [f] `(get ~m ~(keyword (name f)))) fields)) - (dissoc ~m ~@(map (fn [f] (keyword (name f))) fields))))) + (def ~mapf (fn* [~m] (~arrow ~@(map (fn [f] `(get ~m ~(keyword (name f)))) fields)))) ~@(mapcat (fn [g] (let [proto (first g) names (distinct (map (fn [spec] (name (first spec))) (rest g)))] diff --git a/jolt-core/clojure/core/40-lazy.clj b/jolt-core/clojure/core/40-lazy.clj index 880fb48..3a2ef16 100644 --- a/jolt-core/clojure/core/40-lazy.clj +++ b/jolt-core/clojure/core/40-lazy.clj @@ -96,12 +96,8 @@ ([n x] (take n (repeat x)))) ;; --- iterate --- -;; f is applied lazily, inside the tail thunk — (first (iterate f x)) is x with no -;; call to f, matching clojure.lang.Iterate. Wrapping the whole body in lazy-seq -;; instead would force (f x) the moment the head realizes (it is an eager argument -;; to cons), realizing one step ahead. (defn iterate [f x] - (cons x (lazy-seq (iterate f (f x))))) + (lazy-seq (cons x (iterate f (f x))))) ;; --- partition-all --- (transducer + [n coll] + [n step coll]) @@ -129,13 +125,10 @@ (letfn [(go [s] (lazy-seq (when (seq s) - ;; realize exactly n via first/rest (minimal realization), but emit - ;; the chunk as a SEQ — JVM partition-all chunks are seqs, not - ;; vectors (partitionv-all is the vector variant). - (loop [i 0 acc () cur s] + (loop [i 0 chunk [] cur s] (if (and (< i n) (seq cur)) - (recur (inc i) (cons (first cur) acc) (rest cur)) - (cons (reverse acc) (go cur)))))))] + (recur (inc i) (conj chunk (first cur)) (rest cur)) + (cons chunk (go cur)))))))] (go coll))) ([n step coll] (letfn [(go [s] diff --git a/jolt-core/clojure/core/50-io.clj b/jolt-core/clojure/core/50-io.clj index 2d80196..d4941c9 100644 --- a/jolt-core/clojure/core/50-io.clj +++ b/jolt-core/clojure/core/50-io.clj @@ -150,7 +150,7 @@ ;; documented jolt divergence). (defmulti print-method (fn [x writer] (let [t (get (meta x) :type)] - (if (keyword? t) t (__type-tag x))))) + (if (keyword? t) t (type x))))) (defmethod print-method :default [o w] (.write w (__pr-str1 o)) @@ -160,7 +160,7 @@ ;; (as Clojure's default does for most types). (defmulti print-dup (fn [x writer] (let [t (get (meta x) :type)] - (if (keyword? t) t (__type-tag x))))) + (if (keyword? t) t (type x))))) (defmethod print-dup :default [o w] (print-method o w)) diff --git a/jolt-core/jolt/analyzer.clj b/jolt-core/jolt/analyzer.clj index b8c2016..2e87391 100644 --- a/jolt-core/jolt/analyzer.clj +++ b/jolt-core/jolt/analyzer.clj @@ -25,11 +25,9 @@ form-inst? form-inst-source form-uuid? form-uuid-source form-bigdec? form-bigdec-source form-ns-value? form-ns-value-name - form-var-value? form-var-value-ns form-var-value-name - unchecked-math? form-macro? form-expand-1 resolve-global form-sym-meta form-coll-meta host-intern! form-syntax-quote-lower - record-type? record-ctor-key deftype-ctor-class form-position late-bind? + record-type? record-ctor-key form-position late-bind? resolve-class-hint]])) (declare analyze) @@ -40,7 +38,7 @@ ;; analyzed in analyze-list), so keep them in sync by intent, not by equality. (def ^:private handled #{"quote" "if" "do" "def" "fn*" "let*" "loop*" "recur" "throw" "try" - "syntax-quote" "var" "letfn*" "set!" "defmacro"}) + "syntax-quote" "var" "letfn" "set!" "defmacro"}) (defn- uncompilable [why] (throw (str "jolt/uncompilable: " why))) @@ -54,11 +52,6 @@ (defn- empty-env [] {:locals #{} :hints {}}) (defn- local? [env nm] (contains? (:locals env) nm)) (defn- add-locals [env names] (update env :locals #(reduce conj % names))) -;; &env value handed to a macro: a map of each in-scope local SYMBOL to nil -;; (Clojure's &env maps locals to compiler binding objects; consumers like -;; core.logic's matche only read its keys to tell locals from fresh pattern vars). -(defn- amp-env-map [env] - (reduce (fn [m n] (assoc m (symbol n) nil)) {} (:locals env))) (defn- with-recur [env name] (assoc env :recur name)) ;; Type hints. The reader keeps ^hint metadata on the binding symbol. @@ -222,14 +215,11 @@ rest-items)) :else (uncompilable "fn: bad params")))) -;; class names that catch everything (the JVM root types); a (catch Throwable e …) -;; clause matches any thrown value unconditionally. -(def ^:private catch-all-names #{"Throwable" "java.lang.Throwable" "Object" "java.lang.Object"}) - (defn- analyze-try [ctx items env] (let [clauses (rest items) body (atom []) - catches (atom []) ; ordered vector of (catch class binding body*) clauses + catch-sym (atom nil) + catch-body (atom nil) finally-body (atom nil)] (doseq [c clauses] (let [head (when (form-list? c) (first (vec (form-elements c)))) @@ -243,66 +233,48 @@ ;; form-sym-name crash on a non-symbol. (when (or (< (count cl) 3) (not (form-sym? (nth cl 2)))) (throw "Unable to parse catch clause; expected (catch class binding body*)")) - (swap! catches conj cl)) + (reset! catch-sym (form-sym-name (nth cl 2))) + (reset! catch-body (drop 3 cl))) (= hname "finally") (reset! finally-body (rest (vec (form-elements c)))) :else (swap! body conj c)))) - ;; Multiple catch clauses dispatch on the thrown value's class, in order. Lower - ;; them to ONE guard binding a fresh local, then a nested-if chain testing each - ;; clause's class with (instance? C e) — which respects the exception supertype - ;; hierarchy — plus __catch-broad? for an untyped host condition. No match - ;; re-throws. (The earlier single-catch IR ignored the class and caught - ;; everything; this gives real per-class dispatch.) :catch-sym/:catch-body/ - ;; :finally are added only when present — an absent key must stay absent (a - ;; nil-valued key would make the node a phm and force back-end densification). + ;; Add :catch-sym/:catch-body/:finally ONLY when present (same discipline as + ;; the arity :rest key above). Assoc'ing them nil-when-absent would give the + ;; node a nil-valued key, which makes it a phm in jolt's map representation + ;; and forces the back end to densify it (norm-node) before reading :op — the + ;; map-nil-representation trap, also avoided for def/fn/arity nodes. The + ;; back end reads each key with a nil-safe (node :k) and gates on it, so an + ;; absent key is indistinguishable from a present-nil one. (let [n {:op :try :body (analyze-seq ctx @body env)} - n (if (seq @catches) - (let [evar-name (gen-name "catch") - raw-name (gen-name "catch-raw") - evar (symbol evar-name) - dispatch - (reduce - (fn [else cl] - (let [cform (nth cl 1) - bindsym (nth cl 2) - bodyf (drop 3 cl) - letform (cons 'let (cons (vector bindsym evar) bodyf)) - fullname (when (form-sym? cform) (form-sym-name cform)) - catch-all? (or (not (form-sym? cform)) - (contains? catch-all-names fullname))] - (if catch-all? - letform - (list 'if (list 'or - (list 'instance? cform evar) - (list '__catch-broad? fullname evar)) - letform else)))) - (list 'throw evar) - (reverse @catches))] - (assoc n :catch-sym evar-name - :catch-raw-sym raw-name - :catch-body (analyze-seq ctx (list dispatch) - (add-locals env [evar-name])))) + n (if @catch-body + (assoc n :catch-sym @catch-sym + :catch-body (analyze-seq ctx @catch-body (add-locals env [@catch-sym]))) n) n (if @finally-body (assoc n :finally (analyze-seq ctx @finally-body env)) n)] n))) -;; letfn*: (letfn* [name1 fn1 name2 fn2 …] body*) — the special form Clojure's -;; letfn macro expands to (flat name/fn-form pairs, the fn forms already named). -;; The named local fns are MUTUALLY recursive, so bind every name into the env -;; BEFORE analyzing any fn form — each then resolves its siblings (and itself) as -;; locals. Emitted as a :let flagged :letrec so the back end lowers it to -;; `letrec*`; the interpreter's shared mutable env gives the same semantics. -(defn- analyze-letfn* [ctx items env] - (let [bvec (vec (form-vec-items (nth items 1))) - n (quot (count bvec) 2) - names (mapv (fn [i] (form-sym-name (nth bvec (* 2 i)))) (range n)) - env* (add-locals env names) - binds (mapv (fn [i] - [(nth names i) - (analyze ctx (nth bvec (inc (* 2 i))) env*)]) - (range n))] +;; letfn: (letfn [(name [params] body*)...] body*). The named local fns are +;; MUTUALLY recursive, so bind every name into the env BEFORE analyzing any spec +;; — each spec then resolves its siblings (and itself) as locals. Emitted as a +;; :let flagged :letrec so the back end knows the bindings forward-reference each +;; other: Chez lowers it to `letrec*`. The interpreter's shared mutable env already +;; gives the letrec semantics that a +;; compiled sequential let* lacks — the reason letfn was uncompilable before. +(defn- analyze-letfn [ctx items env] + (let [specs (vec (form-vec-items (nth items 1))) + names (mapv #(form-sym-name (first (vec (form-elements %)))) specs) + env* (add-locals env names) + binds (mapv (fn [spec] + (let [cl (vec (form-elements spec))] + ;; Build (fn name [params] body*) and analyze through the fn + ;; MACRO so destructuring params desugar (the fn* primitive + ;; would not — same trick defmacro uses). The named fn means + ;; self- and sibling-calls resolve and it carries its own name. + [(form-sym-name (first cl)) + (analyze ctx (cons (symbol "fn") cl) env*)])) + specs)] {:op :let :letrec true :bindings binds :body (analyze-seq ctx (drop 2 items) env*)})) @@ -312,22 +284,6 @@ (defn- field-head? [nm] (and (> (count nm) 2) (= ".-" (subs nm 0 2)))) -;; Clojure evaluates def metadata values as expressions: ^{:k (f)} stores the -;; result of (f), ^{:a some-fn} stores the fn value. Build an IR map that evaluates -;; each value at def time. :tag keeps the resolved class-name string (jolt models a -;; type hint as its class name, not a runtime expression). nil when there's no -;; metadata, so a plain def keeps the cheap static path. -(defn- def-meta-expr [ctx base env] - (when (pos? (count base)) - (map-node (mapv (fn [p] - (let [k (first p) v (second p)] - ;; :tag stays a literal (a resolved class-name string or a - ;; primitive-hint symbol like `double`) — quote it rather - ;; than evaluate it. Everything else is evaluated. - [(const k) - (if (= k :tag) (quote-node v) (analyze ctx v env))])) - (seq base))))) - (defn- analyze-def [ctx items env] (let [name-sym (nth items 1)] ;; ^{:map} metadata reads as (def (with-meta name m) v): the metadata is a @@ -360,9 +316,7 @@ node-meta (if has-doc (assoc base-meta :doc (nth items 2)) base-meta)] (host-intern! ctx cur nm) ;; a ^double/^long return hint on the name applies to all arities of the fn. - (let [node (def-node cur nm (with-ret-nhint (analyze ctx val-form env) (tag->nkind tag)) node-meta) - me (def-meta-expr ctx node-meta env)] - (if me (assoc node :meta-expr me) node)))))) + (def-node cur nm (with-ret-nhint (analyze ctx val-form env) (tag->nkind tag)) node-meta))))) ;; (set! (.-field obj) v) mutates a deftype instance field in place; (set! *var* v) ;; sets the var's innermost thread binding, else its root. A local target (jolt @@ -394,18 +348,7 @@ (defn- analyze-special [ctx op items env] (case op - ;; A quoted collection keeps its USER metadata (rewrite-clj coerces - ;; '^:x (4 5 6) and expects the meta back), but not the reader's location keys - ;; (:line/:column/:file) — like Clojure, which strips those from a quoted - ;; constant. The kept metadata is itself part of the literal, so quote it. - "quote" (let [qf (second items) - m (form-coll-meta qf) - m (when (map? m) - (let [u (dissoc m :line :column :end-line :end-column :file)] - (when (seq u) u)))] - (if (nil? m) - (quote-node qf) - (invoke (var-ref "clojure.core" "with-meta") [(quote-node qf) (quote-node m)]))) + "quote" (quote-node (second items)) "if" (do ;; 2 or 3 argument forms only (spec 03-special-forms X1) (when (or (< (count items) 3) (> (count items) 4)) @@ -432,7 +375,7 @@ {:op :recur :recur-name rt :args (mapv #(analyze ctx % env) (rest items))}) "try" (analyze-try ctx items env) - "letfn*" (analyze-letfn* ctx items env) + "letfn" (analyze-letfn ctx items env) "fn*" (analyze-fn ctx items env) ;; Lower the backtick to construction code (zero runtime cost), then analyze ;; it — the macroexpand/compile-time step, per read -> macroexpand -> compile. @@ -493,12 +436,7 @@ ;; token and the analyzed args. The Chez back end lowers it to a runtime ;; constructor dispatch. (defn- analyze-ctor [ctx class args env] - ;; Qualify a bare (Name. …) to its deftype's FQN when THIS ns defined the deftype, - ;; so a deftype named like a built-in host class (tools.reader's PushbackReader) - ;; resolves to the deftype here while an unrelated ns's bare (PushbackReader. …) - ;; still reaches java.io.PushbackReader. - (host-new (or (deftype-ctor-class ctx class) class) - (mapv #(analyze ctx % env) args))) + (host-new class (mapv #(analyze ctx % env) args))) ;; jolt.ffi/__cfn: the low-level foreign-function form a jolt library ;; uses (via the jolt.ffi/foreign-fn macro) to bind native code. Shape: @@ -548,14 +486,7 @@ (defn- analyze-dot [ctx items env] (when (< (count items) 3) (throw (str "Malformed (. target member ...) form"))) - (let [member0 (nth items 2) - ;; (. target (member arg*)) is sugar for (. target member arg*) — - ;; flatten the list-member form so the rest of the dispatch is uniform. - items (if (form-list? member0) - (let [ml (vec (form-elements member0))] - (into [(nth items 0) (nth items 1) (first ml)] (rest ml))) - items) - target (nth items 1) + (let [target (nth items 1) member (nth items 2) ;; (. Class method args*) with a class target is a static call — ;; equivalent to (Class/method args*). resolve-global tags a class @@ -625,60 +556,22 @@ (var-ref (compile-ns ctx) nm) (uncompilable (str "Unable to resolve symbol: " nm " in this context")))))))) -;; The wrapping unchecked-* name a core arithmetic op rewrites to under -;; *unchecked-math*, or nil. n is the full item count (head + args); unary - is a -;; negate. -(defn- unchecked-arith [hname n] - (cond - (= hname "+") "unchecked-add" - (= hname "*") "unchecked-multiply" - (= hname "-") (if (= n 2) "unchecked-negate" "unchecked-subtract") - (= hname "inc") "unchecked-inc" - (= hname "dec") "unchecked-dec" - :else nil)) - (defn- analyze-list [ctx form env] (let [items (vec (form-elements form))] (if (zero? (count items)) (quote-node form) (let [head (first items) hname (when (and (form-sym? head) (nil? (form-sym-ns head))) (form-sym-name head)) - ;; a special-form head may arrive clojure.core-qualified: syntax-quote - ;; namespace-qualifies a macro like `letfn` to `clojure.core/letfn` - ;; (matching Clojure, where it is a macro), so a macro-emitted - ;; (clojure.core/letfn …) must still dispatch to the special form. - sf-name (or hname - (when (and (form-sym? head) - (= "clojure.core" (form-sym-ns head)) - (contains? handled (form-sym-name head))) - (form-sym-name head))) - shadowed (and hname (local? env hname)) - ;; under *unchecked-math*, a core +/-/*/inc/dec becomes its wrapping - ;; unchecked-* (computed once; nil when off or not such an op). The op - ;; may arrive bare (+) or clojure.core-qualified (clojure.core/*), the - ;; latter from a macro's syntax-quote — both must wrap. - unm (when (unchecked-math?) - (let [opn (cond (and hname (not shadowed)) hname - (and (form-sym? head) (= "clojure.core" (form-sym-ns head))) - (form-sym-name head))] - (when opn (unchecked-arith opn (count items)))))] + shadowed (and hname (local? env hname))] (cond - ;; *unchecked-math* rewrite, before macro/special dispatch (these are - ;; ordinary core fns). The unchecked-* form re-analyzes normally. - unm (analyze ctx (cons (symbol unm) (rest items)) env) ;; Canonical order (Clojure/CLJS analyze-seq): macroexpand FIRST, then ;; dispatch special forms / interop / invoke. A local shadows the macro. ;; A true special form is NOT shadowable by a same-named macro, matching ;; the reference macroexpand1's isSpecial check — so a ns that redefs a ;; macro `def`/`and`/`or` (clojure.spec.alpha) keeps the special form `def`. (and (form-sym? head) (not shadowed) - (not (contains? handled sf-name)) (form-macro? ctx head)) - ;; defn/defn- expand to (def name (fn …)); carry the ORIGINAL form's - ;; source offset onto the resulting def, since the macro builds a fresh - ;; (def …) with no metadata. So the back end can register fn defs. - (let [node (analyze ctx (form-expand-1 ctx form (amp-env-map env)) env) - p (form-position form)] - (if (and p (= :def (:op node))) (assoc node :pos p) node)) + (not (contains? handled hname)) (form-macro? ctx head)) + (analyze ctx (form-expand-1 ctx form) env) ;; jolt.ffi/__cfn — the foreign-function special form (always emitted ;; fully-qualified by the jolt.ffi/foreign-fn macro, so aliases resolve). (and (form-sym? head) (= "jolt.ffi" (form-sym-ns head)) @@ -692,12 +585,8 @@ ;; special-form heads are NOT shadowable (unlike macros): a local named ;; `if` does not change the meaning of (if …) in operator position, per ;; spec §3 and the reference. No (not shadowed) guard here. - (and sf-name (contains? handled sf-name)) - ;; stamp the form's source offset onto a top-level def so the back end - ;; can register it (jv$ns$name -> source) for native stack traces. - (let [node (analyze-special ctx sf-name items env) - p (form-position form)] - (if (and p (= :def (:op node))) (assoc node :pos p) node)) + (and hname (contains? handled hname)) + (analyze-special ctx hname items env) (and hname (not shadowed) (method-head? hname)) (analyze-host-call ctx hname items env) ;; (Class. args*) — trailing-dot constructor sugar. @@ -754,7 +643,7 @@ ;; jolt-regex value over the vendored irregex. (form-regex? form) {:op :regex :source (form-regex-source form)} ;; #inst / #uuid literals -> :inst / :uuid IR leaves. The Chez back - ;; end emits a runtime inst/uuid value (host/chez/java/inst-time.ss). + ;; end emits a runtime inst/uuid value (host/chez/inst-time.ss). (form-inst? form) {:op :inst :source (form-inst-source form)} (form-uuid? form) {:op :uuid :source (form-uuid-source form)} ;; bigdecimal literal (1.5M) -> a :bigdec leaf; the back end emits a runtime @@ -763,8 +652,4 @@ ;; a live namespace value spliced into a form (~*ns* in a macro) -> a ;; :the-ns leaf the back end reconstructs by name at the call site. (form-ns-value? form) {:op :the-ns :name (form-ns-value-name form)} - ;; a live Var value spliced into a form (a macro that resolves a var and - ;; splices it, e.g. core.contracts' defcurry-from) -> a :the-var reference, - ;; same as (var ns/name); the back end emits (jolt-var ns name). - (form-var-value? form) (the-var (form-var-value-ns form) (form-var-value-name form)) :else (uncompilable "unsupported form")))) diff --git a/jolt-core/jolt/backend_scheme.clj b/jolt-core/jolt/backend_scheme.clj index 473f36c..abce8af 100644 --- a/jolt-core/jolt/backend_scheme.clj +++ b/jolt-core/jolt/backend_scheme.clj @@ -12,23 +12,18 @@ form-list? form-vec? form-map? form-set? form-char? form-literal? form-elements form-vec-items form-map-pairs form-set-items form-char-code - form-regex? form-regex-source - form-inst? form-inst-source form-uuid? form-uuid-source]])) + form-regex? form-regex-source]])) ;; Hot clojure.core primitives lowered to native Scheme. ;; `=` is the exactness-aware jolt= from values.ss; inc/dec/ -;; not are rt shims. Arithmetic and comparisons lower to the jolt-n* checked -;; macros (host/chez/seq.ss): the both-Chez-numbers fast path is open-coded and -;; anything else (BigDecimal, a non-number) takes the Numbers.ops-style category -;; dispatch, with JVM contagion (a double operand wins; an exact zero divisor is -;; ArithmeticException; a double zero divisor is ##Inf/##NaN). +;; not are rt shims; mod/rem/quot map to Scheme's (Scheme has all three). (def ^:private native-ops - {"+" "jolt-n+" "-" "jolt-n-" "*" "jolt-n*" "/" "jolt-n-div" - "<" "jolt-n<" ">" "jolt-n>" "<=" "jolt-n<=" ">=" "jolt-n>=" + {"+" "+" "-" "-" "*" "*" "/" "/" + "<" "<" ">" ">" "<=" "<=" ">=" ">=" "=" "jolt=" "inc" "jolt-inc" "dec" "jolt-dec" "not" "jolt-not" - "min" "jolt-n-min" "max" "jolt-n-max" - "mod" "jolt-mod" "rem" "jolt-rem" "quot" "jolt-quot" - "vector" "jolt-vector" "hash-map" "jolt-hash-map-fn" "hash-set" "jolt-hash-set" + "min" "min" "max" "max" + "mod" "modulo" "rem" "remainder" "quot" "quotient" + "vector" "jolt-vector" "hash-map" "jolt-hash-map" "hash-set" "jolt-hash-set" "conj" "jolt-conj" "get" "jolt-get" "nth" "jolt-nth" "count" "jolt-count" "assoc" "jolt-assoc" "dissoc" "jolt-dissoc" "contains?" "jolt-contains?" "empty?" "jolt-empty?" "peek" "jolt-peek" "pop" "jolt-pop" @@ -39,30 +34,15 @@ "range" "jolt-range" "take" "jolt-take" "drop" "jolt-drop" "keys" "jolt-keys" "vals" "jolt-vals" "even?" "jolt-even?" "odd?" "jolt-odd?" "pos?" "jolt-pos?" "neg?" "jolt-neg?" - "zero?" "jolt-zero?" "identity" "jolt-identity" "nil?" "jolt-nil?" "some?" "jolt-some?" - "ex-info" "jolt-ex-info" - ;; bit ops: and/or/xor/not are Chez bitwise primitives (inlined to native code, - ;; no helper call); operands must be integers (a non-integer errors, like the - ;; JVM). The shifts keep their helpers (Java >>> masking / arithmetic shift) but - ;; emit a direct call instead of var-deref + the variadic overlay. - ;; and/or/xor/not map to variadic Chez bitwise prims (safe as a value at any - ;; arity). bit-and-not is left to its overlay: its only Scheme impl is 2-arg, so - ;; a value-position arity-3 use (via the variadic overlay) would mis-emit. - "bit-and" "bitwise-and" "bit-or" "bitwise-ior" "bit-xor" "bitwise-xor" "bit-not" "bitwise-not" - "bit-shift-left" "jolt-bit-shift-left" "bit-shift-right" "jolt-bit-shift-right" - "unsigned-bit-shift-right" "jolt-unsigned-bit-shift-right" - ;; positional protocol-method dispatch (defprotocol-emitted shims) — bind - ;; directly to the records.ss entry points so a protocol call doesn't var-deref. - "protocol-dispatch1" "protocol-dispatch1" "protocol-dispatch2" "protocol-dispatch2" - "protocol-dispatch3" "protocol-dispatch3"}) + "zero?" "jolt-zero?" "identity" "jolt-identity" + "ex-info" "jolt-ex-info"}) ;; Value-position resolution for a clojure.core ref passed AS A VALUE (to map / -;; filter / reduce / apply). The jolt-n* call-position forms are macros, so value -;; position substitutes the variadic procedures over the same binary dispatch. +;; filter / reduce / apply). Arithmetic is the exception — Scheme's +/-/*// return +;; EXACT results for exact/zero-arg inputs, breaking the all-double model in +;; higher-order use, so value-position arithmetic routes to the flonum wrappers. (def ^:private core-value-procs - (merge native-ops {"+" "jolt-add" "-" "jolt-sub" "*" "jolt-mul" "/" "jolt-div" - "min" "jolt-min" "max" "jolt-max" - "<" "jolt-lt" ">" "jolt-gt" "<=" "jolt-le" ">=" "jolt-ge"})) + (merge native-ops {"+" "jolt-add" "-" "jolt-sub" "*" "jolt-mul" "/" "jolt-div"})) ;; Per-op arity gate: only lower when the Scheme prim and the jolt fn agree at ;; this arity. Ops absent from the table are variadic (legal at any arity). @@ -75,19 +55,15 @@ "first" #(= % 1) "rest" #(= % 1) "next" #(= % 1) "seq" #(= % 1) "reverse" #(= % 1) "last" #(= % 1) "keys" #(= % 1) "vals" #(= % 1) "even?" #(= % 1) "odd?" #(= % 1) "pos?" #(= % 1) "neg?" #(= % 1) - "zero?" #(= % 1) "identity" #(= % 1) "nil?" #(= % 1) "some?" #(= % 1) - "protocol-dispatch1" #(= % 3) "protocol-dispatch2" #(= % 4) "protocol-dispatch3" #(= % 5) + "zero?" #(= % 1) "identity" #(= % 1) "cons" #(= % 2) "filter" #(= % 2) "remove" #(= % 2) "into" #(= % 2) "take" #(= % 2) "drop" #(= % 2) "map" #(>= % 2) "apply" #(>= % 2) "reduce" #(or (= % 2) (= % 3)) "range" #(and (>= % 0) (<= % 3)) - "ex-info" #(or (= % 2) (= % 3)) - "bit-and" #(= % 2) "bit-or" #(= % 2) "bit-xor" #(= % 2) "bit-not" #(= % 1) - "bit-shift-left" #(= % 2) "bit-shift-right" #(= % 2) - "unsigned-bit-shift-right" #(= % 2)}) + "ex-info" #(or (= % 2) (= % 3))}) ;; jolt's comparison ops are vacuously true at arity 1 and DON'T inspect the arg, ;; but Scheme's < demands a number even there — special-case. -(def ^:private cmp1-ops #{"jolt-n<" "jolt-n>" "jolt-n<=" "jolt-n>="}) +(def ^:private cmp1-ops #{"<" ">" "<=" ">="}) ;; Host interop methods with a Chez RT shim (rt.ss jolt-host-call). A `.method` ;; call on any other method routes to record-method-dispatch (a reify/record @@ -97,9 +73,9 @@ ;; Native-op Scheme procedures that return a genuine Scheme boolean (#t/#f), so an ;; :if test built from them needs no jolt-truthy? wrapper. (def ^:private bool-returning-ops - #{"jolt-n<" "jolt-n<=" "jolt-n>" "jolt-n>=" "jolt=" "jolt-not" + #{"<" "<=" ">" ">=" "jolt=" "jolt-not" "jolt-even?" "jolt-odd?" "jolt-pos?" "jolt-neg?" - "jolt-zero?" "jolt-empty?" "jolt-contains?" "jolt-nil?" "jolt-some?"}) + "jolt-zero?" "jolt-empty?" "jolt-contains?"}) ;; Numeric-specialized op strings. jolt.passes.numeric tags an arithmetic invoke ;; :num-kind :double|:long when every operand is that kind; these are the Chez @@ -112,30 +88,11 @@ (def ^:private dbl-ops {"+" "fl+" "-" "fl-" "*" "fl*" "/" "fl/" "min" "flmin" "max" "flmax" "<" "fl" "fl>?" "<=" "fl<=?" ">=" "fl>=?" "=" "fl=?" "==" "fl=?"}) -;; A ^long is 64-bit; a Chez fixnum is only 61-bit. Arithmetic +/-/* keep the raw -;; fx ops (the fast-arith path; under *unchecked-math* they're already rewritten to -;; the wrapping unchecked-*). The comparisons / min/max / quot/rem/mod use the -;; jolt-l* fast-path-with-fallback macros (host/chez/seq.ss) so a full 64-bit -;; operand falls back to the generic op instead of raising. (def ^:private lng-ops - {"+" "fx+" "-" "fx-" "*" "fx*" "min" "jolt-l-min" "max" "jolt-l-max" - ;; unchecked-* WRAP to signed 64 bits (Java long), so they can't use the raising - ;; fx ops — the backend emits the wrapping jolt-unc* helpers (host/chez/seq.ss). - "unchecked-add" "jolt-uncadd2" "unchecked-subtract" "jolt-uncsub2" "unchecked-multiply" "jolt-uncmul2" - "quot" "jolt-l-quot" "rem" "jolt-l-rem" "mod" "jolt-l-mod" - "<" "jolt-l<" ">" "jolt-l>" "<=" "jolt-l<=" ">=" "jolt-l>=" "=" "jolt-l=" "==" "jolt-l="}) - -;; BigDecimal ops. jolt.passes.numeric tags an arithmetic/comparison invoke -;; :num-kind :bigdec when every operand is a bigdec (or an integer literal); these -;; are the bigdec.ss engine procedures it lowers to. Variadic where the source op -;; is; an integer-literal operand is coerced to a bigdec at runtime, so unlike the -;; flonum path no literal rewrite is needed. -(def ^:private bd-ops - {"+" "jbd-add" "-" "jbd-sub" "*" "jbd-mul" "/" "jbd-div" - "min" "jbd-min" "max" "jbd-max" - "quot" "jbd-quot" "rem" "jbd-rem" - "<" "jbd-lt?" ">" "jbd-gt?" "<=" "jbd-le?" ">=" "jbd-ge?" - "zero?" "jbd-zero?" "pos?" "jbd-pos?" "neg?" "jbd-neg?"}) + {"+" "fx+" "-" "fx-" "*" "fx*" "min" "fxmin" "max" "fxmax" + "unchecked-add" "fx+" "unchecked-subtract" "fx-" "unchecked-multiply" "fx*" + "quot" "fxquotient" "rem" "fxremainder" "mod" "fxmodulo" + "<" "fx" "fx>?" "<=" "fx<=?" ">=" "fx>=?" "=" "fx=?" "==" "fx=?"}) ;; PRELUDE MODE. The default (subset) mode rejects any clojure.core ref ;; that isn't a native-op — a clean "out of subset" signal for user-facing `-e`. @@ -164,22 +121,6 @@ (def direct-link-fns (atom #{})) (defn direct-link-reset! [] (reset! direct-link-defined #{}) (reset! direct-link-fns #{})) -;; Cache a resolved var cell in a per-site cell so a non-direct-linked var -;; reference skips the name lookup (string-append + hash) after the first use. -;; OFF during the seed mint (the seed must stay a byte-fixpoint, and caching the -;; compiler's own refs shifts the gensym-numbered cell names every pass); the -;; runtime eval path turns it on for user code, where it's the big win. -(def var-cache? (atom false)) -(defn set-var-cache! [on] (reset! var-cache? on)) - -;; Opt-in tail-frame history (JOLT_TRACE): emit a (jolt-trace-push! "name") at the -;; head of every named fn body, so an entry records the frame into the runtime ring -;; buffer (rt.ss) and a TCO-elided frame still shows in an error's backtrace. OFF -;; during the seed mint and `jolt build` (byte-determinism + no runtime cost); -;; compile-eval.ss turns it on for runtime-eval'd user code when JOLT_TRACE is set. -(def trace-frames? (atom false)) -(defn set-trace-frames! [on] (reset! trace-frames? on)) - ;; A direct-link Scheme binding name for a var. The fqn maps to a unique identifier ;; jv$$; chars that break a Scheme identifier or the `$` separator are ;; escaped so distinct vars never collide. @@ -199,41 +140,10 @@ ;; recursion auto-restores them (no manual save/restore, no throw-leak). (def ^:dynamic *recur-target* nil) (def ^:dynamic *known-procs* #{}) -;; True while emitting a node in TAIL position. Only used, in trace mode, to mark a -;; tail call so the runtime routes its callee into the current history rib instead -;; of a new one (rt.ss). It never affects semantics — a wrong value only mislabels -;; a debug trace line — so partial propagation is safe. `emit` (the wrapper below) -;; clears it by default; the tail-transparent forms (fn body, if/do/let/loop) pass -;; it to their tail child. Default false so a top-level form is treated non-tail. -(def ^:dynamic *tail?* false) (def ^:private gensym-counter (atom 0)) (defn- fresh-label [prefix] (str prefix (swap! gensym-counter inc))) -;; Per-site cache cells collected while emitting one top-level def. A site that -;; resolves a STABLE value — a devirtualized impl (constant tag/proto/method) or a -;; var cell (interned, so the cell never changes even when the var is redefined) — -;; resolves it once, not per call, the inline cache the JVM gets for free. When a -;; def init is being emitted this holds an atom; each site appends a fresh cell name -;; (bound to #f in a let wrapping the def, so it persists across calls and is shared -;; by every invocation) and resolves into it on first use. nil outside a def (a site -;; there falls back to a per-call resolve). -(def ^:private cache-cells (atom nil)) - -;; Emit a def's init (via the supplied thunk) under a fresh cache-cell collector, -;; then wrap the result in a let binding any cells its body registered so they -;; persist in the def's closure. Saves/restores the outer collector for nested -;; defs. Used by both the runtime def emit and the direct-link top-level emit. -(defn- emit-with-cells [emit-thunk] - (let [cells (atom []) - prev @cache-cells - _ (reset! cache-cells cells) - raw (emit-thunk) - _ (reset! cache-cells prev)] - (if (seq @cells) - (str "(let (" (str/join " " (map (fn [c] (str "(" c " #f)")) @cells)) ") " raw ")") - raw))) - ;; Scheme syntactic keywords. A jolt local with one of these names would, when ;; emitted verbatim, shadow the Scheme form in operator position (a local named ;; `if` would turn the special form (if …) the back end emits into a call), so @@ -244,19 +154,10 @@ "unquote" "set!" "define" "define-syntax" "cond" "case" "when" "unless" "and" "or" "do" "else" "guard" "parameterize" "delay" "values"}) -;; clojure.core ops emitted as a BARE Scheme name (where native-ops maps the op -;; to itself: + - * / < > min max …). A local binding with one of these names -;; would otherwise shadow the emitted prim — e.g. (fn [max] (clojure.core/max …)) -;; emits (max …) calling the param — so such locals are prefixed, like reserved -;; words. Derived from native-ops so the two never drift. -(def ^:private bare-native-names - (set (keep (fn [[k v]] (when (= k v) k)) native-ops))) - ;; Most jolt names are already valid Scheme identifiers. The one that isn't is ;; `#`, which jolt auto-gensyms use as a suffix (p1__0000X4# from #(...)) — `#` ;; starts a datum in Scheme, so replace it with `_`. A name that collides with a -;; Scheme keyword OR a bare-emitted native op is prefixed with `_` so it can never -;; shadow the emitted form. +;; Scheme keyword is prefixed with `_` so it can never shadow the emitted form. (defn- munge-name [s] ;; A Clojure symbol may contain chars that break a Scheme identifier: ' is the ;; quote reader macro (a bare f' would read as f then 'rest), # already maps to @@ -265,20 +166,9 @@ (let [s (-> s (str/replace "#" "_") (str/replace "'" "_PRIME_"))] - (if (or (contains? scheme-reserved s) (contains? bare-native-names s)) (str "_" s) s))) + (if (contains? scheme-reserved s) (str "_" s) s))) (declare emit) -(declare emit*) -;; Ops that pass tail position through to a child (the child can itself be a tail -;; call): if/do carry it to their tail branch/last form, let/loop to their body, -;; and invoke reads it to decide whether the call is tail. Every other op's -;; children are non-tail, so `emit` clears *tail?* before dispatching them — that -;; way a stray true can't leak into, say, a call sitting in a vector literal. -(def ^:private tail-transparent-ops #{:if :do :let :loop :invoke}) -(defn emit [node] - (if (and *tail?* (not (tail-transparent-ops (:op node)))) - (binding [*tail?* false] (emit* node)) - (emit* node))) ;; A Chez string literal. Every char outside printable ASCII becomes a ;; codepoint hex escape \x; ; the named escapes (\n \t \r \" \\) match what @@ -402,19 +292,6 @@ (form-map? form) (emit-quoted-map (form-map-pairs form)) ;; a quoted #"…" regex value -> reconstruct it (same as the :regex IR leaf). (form-regex? form) (str "(jolt-regex " (chez-str-lit (form-regex-source form)) ")") - ;; quoted #inst / #uuid literals construct their value, like the JVM reader - ;; (which builds the Date/UUID at read time, so a quoted/macro form carries the - ;; value, not the raw tagged form). Same emit as the :inst / :uuid IR leaves. - (form-inst? form) (str "(jolt-inst-from-string " (chez-str-lit (form-inst-source form)) ")") - (form-uuid? form) (str "(jolt-uuid-from-string " (chez-str-lit (form-uuid-source form)) ")") - ;; a quoted custom #tag with no registered reader -> a tagged-literal value - ;; (Clojure's reader builds a TaggedLiteral), not the raw reader map. The tag is - ;; stored as a :#name keyword; strip the leading # to the bare symbol. - (and (map? form) (= :jolt/tagged (get form :jolt/type))) - (let [nm (name (get form :tag)) - tsym (if (= \# (first nm)) (subs nm 1) nm)] - (str "(jolt-tagged-literal (jolt-symbol #f " (chez-str-lit tsym) ") " - (emit-quoted (get form :form)) ")")) ;; plain jolt VALUES (metadata maps and anything nested in them) (map? form) (emit-quoted-map-value form) (vector? form) (str "(jolt-vector " (str/join " " (map emit-quoted form)) ")") @@ -425,24 +302,15 @@ ;; A def's :meta is a jolt map value. Non-empty? (a plain def carries {}). (defn- jmeta-nonempty? [m] (and (map? m) (pos? (count m)))) -;; The meta argument to def-var-with-meta!. When the analyzer attached a -;; :meta-expr (metadata with values to evaluate, e.g. ^{:a some-fn}), emit it as a -;; runtime expression; otherwise the static :meta map as quoted data. -(defn- emit-def-meta [node] - (if (:meta-expr node) - (emit (:meta-expr node)) - (emit-quoted (:meta node)))) - (defn- emit-binding [b] (str "(" (munge-name (nth b 0)) " " (emit (nth b 1)) ")")) ;; letfn lowers to a :let flagged :letrec (mutually-recursive named local fns): ;; Scheme `letrec*` binds them so each sees its siblings. A plain let uses let*. (defn- emit-let [node] - (let [kw (if (:letrec node) "letrec*" "let*") - ;; bindings are non-tail; the body inherits the let's tail position - binds (binding [*tail?* false] (str/join " " (mapv emit-binding (:bindings node))))] - (str "(" kw " (" binds ") " (emit (:body node)) ")"))) + (let [kw (if (:letrec node) "letrec*" "let*")] + (str "(" kw " (" (str/join " " (map emit-binding (:bindings node))) ") " + (emit (:body node)) ")"))) (defn- emit-loop [node] (let [label (fresh-label "loop") @@ -450,10 +318,9 @@ names (map #(munge-name (nth % 0)) pairs) ;; inits evaluate in the OUTER scope (recur-target unchanged) and, like ;; Clojure loop/let, SEQUENTIALLY — wrap a let* around the named let. - inits (binding [*tail?* false] (mapv #(emit (nth % 1)) pairs)) + inits (map #(emit (nth % 1)) pairs) seq-bs (str/join " " (map (fn [n i] (str "(" n " " i ")")) names inits)) rebinds (str/join " " (map (fn [n] (str "(" n " " n ")")) names)) - ;; the loop body inherits the loop's tail position body (binding [*recur-target* label] (emit (:body node)))] (str "(let* (" seq-bs ") (let " label " (" rebinds ") " body "))"))) @@ -475,7 +342,7 @@ (ffi-type->chez (:rettype node)) ")")) ;; jolt.ffi/__ccallable -> a Chez foreign-callable wrapping the emitted jolt fn, -;; locked + registered (jolt-ffi-register-callable!, host/chez/java/ffi.ss) so the +;; locked + registered (jolt-ffi-register-callable!, host/chez/ffi.ss) so the ;; collector neither moves nor reclaims it while C may still call through it. The ;; expression evaluates to the entry-point address — a jolt pointer the caller ;; hands to C. :collect-safe emits the convention that reactivates the thread on @@ -514,11 +381,7 @@ params (map munge-name orig) restp (when-let [r (:rest a)] (munge-name r)) label (fresh-label "fnrec") - ret (:ret-nhint a) - ;; the body is the fn's tail position — UNLESS a ^double/^long return hint - ;; wraps it in a coercion below, which puts the body back in non-tail. - body-tail? (not (or (= ret :double) (= ret :long))) - body (binding [*recur-target* label *tail?* body-tail?] (emit (:body a))) + body (binding [*recur-target* label] (emit (:body a))) paramlist (cond (and restp (empty? params)) restp restp (str "(" (str/join " " params) " . " restp ")") @@ -543,16 +406,6 @@ self (when-let [nm (:name node)] (munge-name nm)) clauses (binding [*known-procs* (if self (conj *known-procs* self) *known-procs*)] (mapv emit-arity-clause arities)) - ;; trace mode: record this frame on entry (before the body), so a frame - ;; the body then tail-calls away is still in the ring at throw time. A - ;; `recur` re-enters via the named-let, not the lambda, so a tight loop - ;; records once, not per iteration. - clauses (if (and @trace-frames? self) - (mapv (fn [c] [(nth c 0) - (str "(begin (jolt-trace-push! " (chez-str-lit self) ") " - (nth c 1) ")")]) - clauses) - clauses) lambda (if (= 1 (count clauses)) (let [c (first clauses)] (str "(lambda " (nth c 0) " " (nth c 1) ")")) (str "(case-lambda " @@ -597,49 +450,14 @@ (cond (and (= kind :double) (= nm "inc")) (str "(fl+ " (first args) " 1.0)") (and (= kind :double) (= nm "dec")) (str "(fl- " (first args) " 1.0)") - ;; inc/dec tolerate a 64-bit operand (jolt-l-inc/dec fall back past fixnum range); - ;; unchecked-inc/dec wrap (Java long). Neither can use the raising fx1+/fx1-. - (and (= kind :long) (= nm "inc")) (str "(jolt-l-inc " (first args) ")") - (and (= kind :long) (= nm "dec")) (str "(jolt-l-dec " (first args) ")") - (and (= kind :long) (= nm "unchecked-inc")) (str "(jolt-uncinc " (first args) ")") - (and (= kind :long) (= nm "unchecked-dec")) (str "(jolt-uncdec " (first args) ")") + (and (= kind :long) (or (= nm "inc") (= nm "unchecked-inc"))) (str "(fx1+ " (first args) ")") + (and (= kind :long) (or (= nm "dec") (= nm "unchecked-dec"))) (str "(fx1- " (first args) ")") :else - (let [op (case kind :double (dbl-ops nm) :long (lng-ops nm) :bigdec (bd-ops nm))] + (let [op (if (= kind :double) (dbl-ops nm) (lng-ops nm))] (order-args (fn [as] (str "(" op " " (str/join " " as) ")")))))) -;; slot of a declared field key in a record's field-order shape, or nil. -(defn- struct-field-index [shape kw] - (when shape - (loop [i 0] - (cond (>= i (count shape)) nil - (= (nth shape i) kw) i - :else (recur (inc i)))))) - -;; A plain Scheme application: (callee op ...). -(defn- plain-call [callee operand-strs] - (str "(" callee (if (seq operand-strs) (str " " (str/join " " operand-strs)) "") ")")) -;; A tail call in trace mode. Force-bind the operands to temps FIRST (so any -;; operand whose own evaluation records a trace entry runs before our mark), THEN -;; set the tail mark, THEN apply — the callee's entry prologue consumes the mark -;; with nothing in between, so it can't be clobbered. Still a tail call: the let*'s -;; last form is the application, so TCO is preserved. -(defn- tail-marked-call [callee operand-strs] - (let [tmps (mapv (fn [_] (fresh-label "_tt$")) operand-strs) - binds (str/join " " (map (fn [t a] (str "(" t " " a ")")) tmps operand-strs))] - (str "(let* (" binds ") (jolt-trace-mark! #t) " (plain-call callee tmps) ")"))) -;; Emit a call, tail-marked when we're in tail position and tracing is on; a plain -;; application otherwise. The mark is consumed by the callee's entry prologue — -;; direct calls (:local known-proc, direct-link) always have one; a jolt-invoke -;; call usually reaches one but not always (see the best-effort note in rt.ss). -(defn- emit-call [tail? callee operand-strs] - (if (and @trace-frames? tail?) - (tail-marked-call callee operand-strs) - (plain-call callee operand-strs))) - (defn- emit-invoke [node] - (let [tail? *tail?*] ; capture: children below emit non-tail - (binding [*tail?* false] - (let [fnode (:fn node) + (let [fnode (:fn node) arg-nodes (:args node) args (mapv emit arg-nodes) nop (native-op fnode (count args)) @@ -651,34 +469,9 @@ ;; order [callee & args] together when ordering is observable. invoke (fn [] (ordered-call (cons fnode arg-nodes) (cons (emit fnode) args) - (fn [operands] (emit-call tail? "jolt-invoke" operands))))] + (fn [[f & as]] + (str "(jolt-invoke " f (if (seq as) (str " " (str/join " " as)) "") ")"))))] (cond - ;; devirtualized protocol call: the inference proved the receiver (arg 0) is - ;; one record type, so resolve the impl by that static tag instead of routing - ;; through the protocol var -> jolt-invoke -> protocol-resolve (which recomputes - ;; the tag and walks the type table). devirt-resolve does the same table lookup - ;; the dispatch would, but with no var-deref and no receiver-type computation; - ;; it falls back to ordinary dispatch when the static tag has no direct impl (a - ;; record satisfying the protocol via an Object/host-tag default). Fires only on - ;; a monomorphic site (a megamorphic receiver joins to :any, no :devirt-type). - ;; The receiver is bound once — it feeds both the resolve and the application. - (:devirt-type node) - (order-args (fn [as] - (let [r (fresh-label "_r$") - dv (str "(devirt-resolve " (chez-str-lit (:devirt-type node)) " " - (chez-str-lit (:devirt-proto node)) " " (chez-str-lit (:devirt-method node)) - " " r ")") - cells @cache-cells - ;; cache the resolved impl in a per-site cell when inside a - ;; def (resolved once on first call, then reused); else - ;; resolve per call. - resolver (if cells - (let [c (fresh-label "_dvc$")] - (swap! cells conj c) - (str "(or " c " (let ((_f " dv ")) (set! " c " _f) _f))")) - dv)] - (str "(let* ((" r " " (first as) ")) (" - resolver " " (str/join " " (cons r (rest as))) "))")))) ;; hint-directed fast arithmetic: jolt.passes.numeric proved every operand a ;; flonum (^double) or fixnum (^long), so emit the Chez fl*/fx* op. (:num-kind node) (emit-numeric (:num-kind node) (:name fnode) args order-args) @@ -688,28 +481,14 @@ (and nop (= 1 (count args)) (cmp1-ops nop)) (str "(begin " (first args) " #t)") nop (order-args (fn [as] (str "(" nop " " (str/join " " as) ")"))) ;; (:k coll [default]) -> (jolt-get coll :k [default]) — the key (fnode) is a - ;; const, so only the coll/default args carry order. When the inference typed - ;; the receiver as a record whose declared fields include :k (it carries the - ;; field-order :shape), read the field by its static slot — no field-key - ;; lookup, no jolt-get dispatch. Only the no-default form (a declared field is - ;; always present, so a default is never taken). + ;; const, so only the coll/default args carry order. (= kind :keyword) - (let [recv (first arg-nodes) - idx (when (and (= :struct (:hint recv)) (= 1 (count arg-nodes))) - (struct-field-index (:shape recv) (:val fnode)))] - (if idx - (order-args (fn [as] (str "(jrec-field-at " (first as) " " idx " " (emit fnode) ")"))) - (order-args (fn [as] (str "(jolt-get " (first as) " " (emit fnode) (defstr as) ")"))))) - ;; (coll k [default]) -> lookup — coll (fnode) is the callee, evaluated - ;; before the key/default args. A VECTOR literal invokes as nth (a bad - ;; index throws, IPersistentVector.invoke); maps/sets invoke as get. + (order-args (fn [as] (str "(jolt-get " (first as) " " (emit fnode) (defstr as) ")"))) + ;; (coll k [default]) -> (jolt-get coll k [default]) — coll (fnode) is the + ;; callee, evaluated before the key/default args. (= kind :coll) (ordered-call (cons fnode arg-nodes) (cons (emit fnode) args) - (fn [[c & as]] - (str (if (and (= :vector (:op fnode)) (= 1 (count as))) - "(jolt-nth " - "(jolt-get ") - c " " (str/join " " as) ")"))) + (fn [[c & as]] (str "(jolt-get " c " " (str/join " " as) ")"))) (and (stdlib-var? fnode) (not (deref prelude-mode?))) (throw (ex-info (str "emit: unsupported stdlib fn `" (:ns fnode) "/" (:name fnode) "` (no core on Chez yet)") {})) @@ -720,14 +499,9 @@ (if (empty? as) "" (str " " (str/join " " as))) ")"))) (= :host (:op fnode)) (throw (ex-info (str "emit: unsupported host call `" (:name fnode) "`") {})) - ;; a :local callee: a known procedure (the letrec-bound self-name of a named - ;; fn — i.e. self-recursion) is a real Scheme proc, so call it directly with - ;; no jolt-invoke / arg consing; case-lambda handles arity. Any other local - ;; holds an arbitrary IFn -> dynamic dispatch. - (= :local (:op fnode)) - (if (*known-procs* (munge-name (:name fnode))) - (order-args (fn [as] (emit-call tail? (munge-name (:name fnode)) as))) - (invoke)) + ;; a :local callee that isn't a known procedure -> dynamic IFn dispatch. + (and (= :local (:op fnode)) (not (*known-procs* (munge-name (:name fnode))))) + (invoke) ;; closed-world direct call: the callee var is an app fn def already emitted ;; with a Scheme binding — apply it directly, no var lookup, no jolt-invoke. ;; Only fn-valued defs qualify; a non-fn invokable value (a map/set/keyword @@ -735,7 +509,8 @@ ;; below (which still uses the direct binding as the invoke target). (and (= :var (:op fnode)) (direct-linkable? (:ns fnode) (:name fnode)) (direct-link-fn? (:ns fnode) (:name fnode))) - (order-args (fn [as] (emit-call tail? (dl-name (:ns fnode) (:name fnode)) as))) + (order-args (fn [as] (str "(" (dl-name (:ns fnode) (:name fnode)) + (if (seq as) (str " " (str/join " " as)) "") ")"))) ;; a late-bound :var call head can hold a procedure OR a non-applicable ;; value the RT dispatches (multimethod, keyword/coll IFn) — route via ;; jolt-invoke (transparent for a procedure). @@ -743,69 +518,32 @@ (invoke) ;; a computed callee can yield ANY IFn — route through jolt-invoke. :else - (invoke)))))) + (invoke)))) -;; try/catch/finally. throw raises a Chez condition wrapping the jolt value -;; (jolt-throw = Scheme `raise` of a &jolt-throw condition); catch lowers to -;; `guard`, whose raw binding is unwrapped via jolt-unwrap-throw so the catch var -;; receives the jolt value (preserving ex-data/ex-message and the backtrace -;; identity tag). finally lowers to `dynamic-wind`'s after-thunk (runs on -;; success, catch and escape — Clojure finally semantics). Both keys optional. +;; try/catch/finally. throw raises the jolt value RAW (jolt-throw = +;; Scheme `raise`); catch lowers to `guard` with an `else` clause (the IR drops +;; the class), finally to `dynamic-wind`'s after-thunk (runs on success, catch and +;; escape — Clojure finally semantics). Both keys optional on the node. (defn- emit-try [node] (let [core (if-let [cs (:catch-sym node)] - (let [raw (munge-name (:catch-raw-sym node))] - (str "(guard (" raw " (else (let ((" (munge-name cs) " (jolt-unwrap-throw " raw "))) " - (emit (:catch-body node)) "))) " - (emit (:body node)) ")")) + (str "(guard (" (munge-name cs) " (else " (emit (:catch-body node)) ")) " + (emit (:body node)) ")") (emit (:body node)))] (if-let [fin (:finally node)] (str "(dynamic-wind (lambda () #f) (lambda () " core ") (lambda () " (emit fin) "))") core))) ;; Does this IR node emit to an expression that yields a Scheme boolean? Used to -;; drop the redundant jolt-truthy? on an :if test. Sees through the let*/if an -;; (or ...)/(and ...) of bool-returning ops desugars to: `or` is -;; (let* [g E1] (if (truthy? g) g E2)), `and` is (let* [g E1] (if (truthy? g) E2 g)) -;; — both return a Scheme boolean when E1/E2 are bool ops, since the value yielded -;; is always one of the (boolean) operand results. `bools` tracks let-bound locals -;; proven to hold a Scheme boolean. -(defn- returns-scheme-bool? - ([node] (returns-scheme-bool? node #{})) - ([node bools] - (cond - (and (= :const (:op node)) (boolean? (:val node))) true - (= :invoke (:op node)) - (let [nop (native-op (:fn node) (count (:args node)))] - (boolean (and nop (bool-returning-ops nop)))) - (= :local (:op node)) (contains? bools (:name node)) - (= :if (:op node)) - (and (returns-scheme-bool? (:then node) bools) - (returns-scheme-bool? (:else node) bools)) - (= :let (:op node)) - (let [bools' (reduce (fn [s b] - (if (returns-scheme-bool? (nth b 1) s) - (conj s (nth b 0)) - (disj s (nth b 0)))) - bools (:bindings node))] - (returns-scheme-bool? (:body node) bools')) - :else false))) +;; drop the redundant jolt-truthy? on an :if test. +(defn- returns-scheme-bool? [node] + (cond + (and (= :const (:op node)) (boolean? (:val node))) true + (= :invoke (:op node)) + (let [nop (native-op (:fn node) (count (:args node)))] + (if (and nop (bool-returning-ops nop)) true false)) + :else false)) -;; In trace mode, a fn def also registers its source so the tail-frame history maps -;; the recorded frame-name to "ns/name (file:line)" instead of a bare name. Keyed by -;; the SAME munged name the entry push records (emit-fn's letrec self-binding = the -;; fn's own name). Returns "" when off / not a positioned fn def, so trace-off output -;; (seed mint, `jolt build`) is byte-identical. Direct-link builds already register -;; via emit-def-cached; this covers the open-world eval path. -(defn- trace-source-reg [node] - (let [init (:init node) pos (:pos node)] - (if (and @trace-frames? (= :fn (:op init)) (:name init) pos) - (str " (jolt-register-source! " (chez-str-lit (munge-name (:name init))) " " - (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) " " - (if (:file pos) (chez-str-lit (:file pos)) "jolt-nil") " " - (or (:line pos) 0) ")") - ""))) - -(defn emit* [node] +(defn emit [node] (case (:op node) :const (emit-const (:val node)) :local (munge-name (:name node)) @@ -820,22 +558,7 @@ (and (stdlib-var? node) (not (deref prelude-mode?))) (throw (ex-info (str "emit: unsupported stdlib ref `" (:ns node) "/" (:name node) "` (no core on Chez yet)") {})) - ;; inside a def, cache the interned var cell in a per-site cell so the - ;; name lookup (string-append + hash) runs once, not per access; the - ;; cell is stable and def-var! mutates its root in place, so this stays - ;; correct under redefinition. Read through var-cell-deref — the - ;; cell-based var-deref: binding-aware (a thread-bound dynamic var - ;; resolves to its binding) AND lenient on an unbound root (the strict - ;; jolt-var-get throws on a forward-declared var). Outside a def, - ;; resolve per access. - :else - (let [cells @cache-cells - nslit (chez-str-lit (:ns node)) nmlit (chez-str-lit (:name node))] - (if (and @var-cache? cells) - (let [c (fresh-label "_vc$")] - (swap! cells conj c) - (str "(var-cell-deref (or " c " (let ((_v (jolt-var " nslit " " nmlit "))) (set! " c " _v) _v)))")) - (str "(var-deref " nslit " " nmlit ")"))))) + :else (str "(var-deref " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) ")"))) :the-var (str "(jolt-var " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) ")") ;; (set! *var* val) -> set the var's innermost binding (else root); returns val. :set-var (str "(jolt-var-set " (emit (:the-var node)) " " (emit (:val node)) ")") @@ -853,14 +576,11 @@ :host-new (str "(host-new " (chez-str-lit (:class node)) (let [args (map emit (:args node))] (if (empty? args) "" (str " " (str/join " " args)))) ")") - ;; the test is non-tail; then/else inherit the if's tail position :if (let [test (:test node) - t (binding [*tail?* false] - (if (returns-scheme-bool? test) (emit test) - (str "(jolt-truthy? " (emit test) ")")))] + t (if (returns-scheme-bool? test) (emit test) + (str "(jolt-truthy? " (emit test) ")"))] (str "(if " t " " (emit (:then node)) " " (emit (:else node)) ")")) - ;; non-last statements are non-tail; the ret inherits the do's tail position - :do (str "(begin " (binding [*tail?* false] (str/join " " (mapv emit (:statements node)))) + :do (str "(begin " (str/join " " (map emit (:statements node))) (if (empty? (:statements node)) "" " ") (emit (:ret node)) ")") :invoke (emit-invoke node) ;; collection literals -> rt constructors (collections.ss). Elements are @@ -904,17 +624,15 @@ :fn (emit-fn node) ;; (def name) with no init (declare): reserve the cell. A def with non-empty ;; reader metadata lowers to def-var-with-meta! (ported in a later increment). - :def (let [reg (trace-source-reg node) - d (cond - (:no-init node) - (str "(declare-var! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) ")") - (jmeta-nonempty? (:meta node)) - (str "(def-var-with-meta! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) " " - (emit-with-cells #(emit (:init node))) " " (emit-def-meta node) ")") - :else - (str "(def-var! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) " " - (emit-with-cells #(emit (:init node))) ")"))] - (if (= reg "") d (str "(begin " d reg ")"))) + :def (cond + (:no-init node) + (str "(declare-var! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) ")") + (jmeta-nonempty? (:meta node)) + (str "(def-var-with-meta! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) " " + (emit (:init node)) " " (emit-quoted (:meta node)) ")") + :else + (str "(def-var! " (chez-str-lit (:ns node)) " " (chez-str-lit (:name node)) " " + (emit (:init node)) ")")) (throw (ex-info (str "emit: op not yet ported / unhandled: " (pr-str (:op node))) {})))) ;; ^:dynamic / ^:redef on a def opts it out of direct-linking: it stays redefinable, @@ -927,53 +645,22 @@ ;; Off direct-link mode this is exactly `emit`, so the seed mint and runtime eval are ;; byte-unchanged. Nested defs (a defonce's inner def) never reach a top-level branch ;; here, so they stay indirect — a `define` would be illegal in their position. -;; Emit a def, wrapping its init in a let that binds each per-site cache cell -;; (var-ref + devirt) so a hot loop's lookups resolve once into the def's closure. -;; Runs in BOTH modes; in direct-link mode a non-opt-out def also binds jv$ -;; and registers it for app->app direct linking + a source-map frame. -(defn- emit-def-cached [node] - (let [ns (:ns node) nm (:name node) - dl? (and @direct-link? (not (dl-opt-out? (:meta node)))) - b (dl-name ns nm) - fn? (= :fn (:op (:init node))) - ;; A fn def gets a source-registry entry so a native backtrace can map its - ;; frame to ns/name (file:line). Chez names the frame by whatever emit-fn - ;; binds the lambda to: a NAMED fn (defn, or (fn foo …)) gets a letrec - ;; self-binding = munge-name of the fn's own name; an ANONYMOUS fn def has - ;; no letrec, so the lambda sits directly under (define jv$ns$name …) and - ;; takes that name. Register under whichever Chez will report. - pos (:pos node) - frame-name (when fn? (if-let [fnm (:name (:init node))] (munge-name fnm) b)) - reg (when (and dl? fn? pos) - (str " (jolt-register-source! " (chez-str-lit frame-name) " " - (chez-str-lit ns) " " (chez-str-lit nm) " " - (if (get pos :file) (chez-str-lit (get pos :file)) "jolt-nil") " " - (or (get pos :line) 0) ")")) - ;; register before emitting the init so a self-referential body direct-links. - _ (when dl? (swap! direct-link-defined conj (dl-fqn ns nm)) - (when fn? (swap! direct-link-fns conj (dl-fqn ns nm)))) - init (emit-with-cells #(emit (:init node)))] - (cond - dl? - (if (jmeta-nonempty? (:meta node)) - (str "(begin (define " b " " init ") (def-var-with-meta! " - (chez-str-lit ns) " " (chez-str-lit nm) " " b " " (emit-def-meta node) ")" (or reg "") ")") - (str "(begin (define " b " " init ") (def-var! " - (chez-str-lit ns) " " (chez-str-lit nm) " " b ")" (or reg "") ")")) - (jmeta-nonempty? (:meta node)) - (str "(def-var-with-meta! " (chez-str-lit ns) " " (chez-str-lit nm) " " init " " (emit-def-meta node) ")") - :else - (str "(def-var! " (chez-str-lit ns) " " (chez-str-lit nm) " " init ")")))) - (defn emit-top-form [node] (cond - ;; off direct-link (the seed mint + runtime-via-image) this is exactly `emit`, - ;; whose :def case already wraps cache cells, so the seed stays byte-unchanged. (not @direct-link?) (emit node) ;; top-level do splices: each statement/ret is itself a top-level form. (= :do (:op node)) (str "(begin " (str/join " " (map emit-top-form (:statements node))) (if (empty? (:statements node)) "" " ") (emit-top-form (:ret node)) ")") (and (= :def (:op node)) (not (:no-init node)) (not (dl-opt-out? (:meta node)))) - (emit-def-cached node) + (let [ns (:ns node) nm (:name node) b (dl-name ns nm)] + ;; register before emitting the init so a self-referential body direct-links. + (swap! direct-link-defined conj (dl-fqn ns nm)) + (when (= :fn (:op (:init node))) (swap! direct-link-fns conj (dl-fqn ns nm))) + (let [init (emit (:init node))] + (if (jmeta-nonempty? (:meta node)) + (str "(begin (define " b " " init ") (def-var-with-meta! " + (chez-str-lit ns) " " (chez-str-lit nm) " " b " " (emit-quoted (:meta node)) "))") + (str "(begin (define " b " " init ") (def-var! " + (chez-str-lit ns) " " (chez-str-lit nm) " " b "))")))) :else (emit node))) diff --git a/jolt-core/jolt/deps.clj b/jolt-core/jolt/deps.clj index f7c6799..4ca6cc2 100644 --- a/jolt-core/jolt/deps.clj +++ b/jolt-core/jolt/deps.clj @@ -66,10 +66,6 @@ (if-let [root (:deps/root spec)] (str checkout "/" root) checkout)) (:jolt/module spec) (do (warn "skipping janet dependency " coord " (:jolt/module is obsolete on Chez)") nil) - ;; jolt IS Clojure — a dependency on org.clojure/clojure is satisfied - ;; intrinsically, so skip it silently rather than warning about the (unusable) - ;; :mvn/version coordinate. - (= coord 'org.clojure/clojure) nil :else (do (warn "skipping unsupported coordinate " coord " " (pr-str spec)) nil))) diff --git a/jolt-core/jolt/ir.clj b/jolt-core/jolt/ir.clj index 2ae650d..fa08d7d 100644 --- a/jolt-core/jolt/ir.clj +++ b/jolt-core/jolt/ir.clj @@ -118,10 +118,7 @@ (= op :recur) (assoc node :args (mapv f (get node :args))) (= op :fn) (assoc node :arities (mapv (fn [a] (assoc a :body (f (get a :body)))) (get node :arities))) - (= op :def) (let [n (assoc node :init (f (get node :init)))] - (if (get node :meta-expr) - (assoc n :meta-expr (f (get node :meta-expr))) - n)) + (= op :def) (assoc node :init (f (get node :init))) (= op :host-call) (assoc node :target (f (get node :target)) :args (mapv f (get node :args))) (= op :host-new) (assoc node :args (mapv f (get node :args))) @@ -162,8 +159,7 @@ (= op :loop) (f (reduce (fn [a b] (f a (nth b 1))) acc (get node :bindings)) (get node :body)) (= op :recur) (reduce f acc (get node :args)) (= op :fn) (reduce (fn [a ar] (f a (get ar :body))) acc (get node :arities)) - (= op :def) (let [a (if (get node :init) (f acc (get node :init)) acc)] - (if (get node :meta-expr) (f a (get node :meta-expr)) a)) + (= op :def) (if (get node :init) (f acc (get node :init)) acc) (= op :host-call) (reduce f (f acc (get node :target)) (get node :args)) (= op :host-new) (reduce f acc (get node :args)) (= op :try) diff --git a/jolt-core/jolt/main.clj b/jolt-core/jolt/main.clj index 9254099..d0f5d59 100644 --- a/jolt-core/jolt/main.clj +++ b/jolt-core/jolt/main.clj @@ -8,8 +8,6 @@ (defn- project-dir [] (or (jolt.host/getenv "JOLT_PWD") ".")) -(defn- version [] (jolt.host/jolt-version)) - (defn- current-platform [] (let [os (str/lower-case (or (System/getProperty "os.name") ""))] (cond (str/includes? os "mac") :darwin @@ -30,11 +28,7 @@ (let [c (get spec plat) cands (if (string? c) [c] (vec c)) hit (some #(when (jolt.ffi/loaded? %) %) cands)] - ;; A :static spec has no runtime shared object (it's linked into a - ;; built binary), so an interpreted `run`/`repl` has nothing to load — - ;; skip it rather than fail. Its foreign calls only resolve in a static - ;; build; document a dynamic candidate too to use it under `run`. - (when (and (nil? hit) (not (:optional spec)) (not (:static spec))) + (when (and (nil? hit) (not (:optional spec))) (throw (ex-info (str "required native library " (or (:name spec) (first cands) "?") " not found — tried " (pr-str cands) " for " (name plat)) @@ -94,79 +88,22 @@ (let [{:keys [roots]} (deps/resolve-project (project-dir))] (println (str/join ":" roots)))) -(defn- repl-form-complete? - "True when `s` has balanced ()/[]/{}, no open string/char/regex, and at most - a trailing comment past the last form. Drives the REPL's read-until-complete - decision so a form split across lines is accumulated, not evaluated half-read." - [s] - (let [n (count s)] - (loop [i 0 depth 0 state :code] ; state: :code :string :regex :comment - (if (>= i n) - (and (<= depth 0) (#{:code :comment} state)) - (let [c (get s i)] - (case state - :code (cond - (= c \;) (recur (inc i) depth :comment) - (= c \\) (recur (+ i 2) depth :code) ; char literal: \( - (= c \") (recur (inc i) depth :string) - (= c \#) (if (= (get s (inc i)) \") - (recur (+ i 2) depth :regex) ; consume the #" together - (recur (inc i) depth :code)) - (#{\( \[ \{} c) (recur (inc i) (inc depth) :code) - (#{\) \] \}} c) (recur (inc i) (dec depth) :code) - :else (recur (inc i) depth :code)) - :string (cond - (= c \\) (recur (+ i 2) depth :string) ; escaped char - (= c \") (recur (inc i) depth :code) - :else (recur (inc i) depth :string)) - :regex (cond - (= c \\) (recur (+ i 2) depth :regex) - (= c \") (recur (inc i) depth :code) - :else (recur (inc i) depth :regex)) - :comment (recur (inc i) depth - (if (#{\newline \return} c) :code :comment)))))))) - -(defn- repl-read-form [] - ;; Read lines — printing a secondary prompt for continuations — until the - ;; accumulated buffer is a complete form. Returns the (possibly multi-line) - ;; buffer, or nil on EOF at the primary prompt. - (loop [buf nil] - (print (if buf "... " "user=> ")) (flush) - (let [line (read-line)] - (cond - (nil? line) buf ; EOF: nil at primary, partial mid-form - (nil? buf) (cond - (str/blank? line) (recur nil) ; skip a blank first line - (repl-form-complete? line) line - :else (recur line)) - :else (let [nb (str buf "\n" line)] - (if (repl-form-complete? nb) nb (recur nb))))))) - (defn- repl [] ;; resolve the project so deps (git libs) are on the roots and native libs are ;; loaded — same context a run gets, so (require '[some.lib]) works in the REPL. (try (apply-project! (deps/resolve-project (project-dir))) (catch :default _ nil)) - ;; REPL-driven development: trace by default so an uncaught error in evaluated - ;; code shows a tail-frame backtrace, no JOLT_TRACE needed (JOLT_TRACE=0 opts out). - (jolt.host/enable-trace!) - (println (str ";; jolt " (version) " repl — :repl/quit or ^D to exit")) + (println ";; jolt repl — ^D to exit") (loop [] - (let [form (repl-read-form)] - (when form - ;; :repl/quit / :exit exit the loop — a reliable gesture that works in any - ;; terminal, unlike ^D (some terminals/editors don't deliver it as EOF). - (if (#{:repl/quit :exit} (try (read-string form) (catch :default _ nil))) - nil - (do - (try (println (pr-str (load-string form))) - (catch :default e - (println "error:" (or (ex-message e) - (try ((resolve 'jolt.host/condition-message) e) (catch :default _ nil)) - (pr-str e))) - (when-let [bt (jolt.host/backtrace-string)] - (print bt)))) - (recur))))))) + (print "user=> ") (flush) + (let [line (read-line)] + (when line + (try (println (pr-str (load-string line))) + (catch :default e + (println "error:" (or (ex-message e) + (try ((resolve 'jolt.host/condition-message) e) (catch :default _ nil)) + (pr-str e))))) + (recur))))) ;; A deps.edn :tasks entry: a string is a shell command; a map is {:main-opts …}. (defn- run-task [name more] @@ -185,38 +122,18 @@ ;; --direct-link (or deps.edn :jolt/build {:direct-link true}) opts into closed-world ;; direct-linking: app->app calls bind directly, giving up runtime redefinition of ;; those vars and eval/load-string. Off by default — release stays dynamically linked. -;; The static-link description of a :jolt/native spec for this platform, or nil. -;; :static may be flat ({:archive "…"} / {:lib "z" :libdir "…"}) or per-platform -;; ({:darwin {…} :linux {…}}). Returns a vector build.ss reads and wraps in the -;; platform's force-load flags: ["archive" abspath] or ["lib" name libdir]. -(defn- static-link-spec [spec plat] - (when-let [s (:static spec)] - (let [p (get s plat) - s (if (map? p) p s)] - (cond - (:archive s) ["archive" (:archive s)] - (:lib s) ["lib" (:lib s) (or (:libdir s) "")] - :else nil)))) - ;; Encode a deps.edn :jolt/native spec for the build launcher, resolving the ;; current platform's candidate list now (the binary runs on this OS). Each entry -;; becomes a vector the launcher (build.ss) reads: -;; ["process"] — the running binary's own symbols (libc) -;; ["static" form …] — the lib's archive, cc-linked into the binary; its -;; symbols load from the process (default when :static -;; is present and --dynamic wasn't passed) -;; ["req"|"opt" cand…] — load a shared object at runtime, trying each in turn -;; dynamic? forces the runtime path for every lib (the --dynamic build flag). -(defn- encode-natives [natives dynamic?] +;; becomes a vector the launcher (build.ss) reads: ["process"] for the running +;; binary's own symbols, else ["req"|"opt" cand…] to try in turn. +(defn- encode-natives [natives] (let [plat (current-platform)] (vec (for [spec natives] - (let [static (and (not dynamic?) (static-link-spec spec plat))] - (cond - (:process spec) ["process"] - static (into ["static"] static) - :else (let [c (get spec plat) - cands (if (string? c) [c] (vec c))] - (into [(if (:optional spec) "opt" "req")] cands)))))))) + (if (:process spec) + ["process"] + (let [c (get spec plat) + cands (if (string? c) [c] (vec c))] + (into [(if (:optional spec) "opt" "req")] cands))))))) (defn- cmd-build [more] (let [{:keys [project-paths embed-dirs build] :as resolved} @@ -250,11 +167,7 @@ (nil? o) (str pdir "/target/" (if (= mode "dev") "debug" "release") "/" proj) (str/starts-with? o "/") o :else (str pdir "/" o))) - ;; :jolt/native libs with a :static archive are cc-linked into the - ;; binary by default; --dynamic (or deps.edn :jolt/build {:dynamic-natives - ;; true}) keeps the old behavior — load a shared object at runtime. - dynamic-natives? (boolean (or (some #{"--dynamic"} more) (:dynamic-natives build))) - natives (encode-natives (:natives resolved) dynamic-natives?) + natives (encode-natives (:natives resolved)) ;; closed-world direct-linking is opt-in: the --direct-link flag or a ;; deps.edn :jolt/build {:direct-link true}. Off otherwise. direct-link? (boolean (or (some #{"--direct-link"} more) (:direct-link build))) @@ -275,57 +188,27 @@ (let [port (or (some-> (first (filter #(not (str/starts-with? % "-")) more)) parse-long) (parse-long (or (jolt.host/getenv "JOLT_NREPL_PORT") "7888")))] (require 'jolt.nrepl) - ;; start binds the socket synchronously on this (primordial) thread, so a - ;; failure like the port already being in use surfaces here and exits rather - ;; than being swallowed by a background thread. It then runs the accept loop - ;; on a worker thread and returns a stop fn, leaving this thread free to own - ;; the GUI main loop: glimmer's run marshals its startup here via - ;; jolt.host/call-on-main-thread — on macOS GTK quartz, g_application_run - ;; must run on the main thread or AppKit aborts when it sets the main menu. - ;; Block SIGINT in this (primordial) thread before starting the server so the - ;; accept-loop future — and the conn-handler futures it spawns — inherit a - ;; blocked SIGINT mask. Without this, ^C lands on the accept loop blocked in - ;; c-accept (a foreign call), where Chez can't fire the keyboard-interrupt - ;; handler, and the server hangs. park-until-interrupt unblocks SIGINT here - ;; once its own ^C handler is installed, so ^C reaches this thread and the - ;; shutdown hooks run cleanly. - (jolt.host/block-sigint) - (let [stop ((resolve 'jolt.nrepl/start) port (:nrepl-middleware resolved))] - ;; register stop so ^C (handled by park-until-interrupt) closes the socket - ;; and drops .nrepl-port on the way out. - (jolt.host/add-shutdown-hook stop) - ;; park here until ^C (handled by park-until-interrupt's keyboard-interrupt- - ;; handler, which runs the shutdown hooks and exits). The accept loop - ;; inherited SIGINT-blocked above, so ^C is delivered to this thread. - (jolt.host/park-until-interrupt) - (when stop (stop)))))) + ((resolve 'jolt.nrepl/start) port (:nrepl-middleware resolved))))) (defn- usage [] - (println (str "jolt " (version))) (println "usage: jolt [args]") - (println " -e EXPR evaluate EXPR and print the result") - (println " run -m NS [args] resolve deps.edn, load NS, call its -main") - (println " run FILE load a Clojure file") - (println " build -m NS [-o OUT] [--opt|--dev] [--direct-link] [--tree-shake] [--dynamic] compile a standalone binary") - (println " -M:alias [args] run the alias's :main-opts") - (println " -A:alias [args] add the alias's paths/deps") - (println " repl start a line REPL") - (println " --nrepl-server [port] start an nREPL server (default 7888) for editors") - (println " path print the resolved source roots") - (println " run a deps.edn :tasks entry") - (println " --version print the jolt version") - (println " --help print this message")) + (println " run -m NS [args] resolve deps.edn, load NS, call its -main") + (println " run FILE load a Clojure file") + (println " build -m NS [-o OUT] [--opt|--dev] [--direct-link] [--tree-shake] compile a standalone binary") + (println " -M:alias [args] run the alias's :main-opts") + (println " -A:alias [args] add the alias's paths/deps") + (println " repl start a line REPL") + (println " nrepl [port] start an nREPL server (default 7888) for editors") + (println " path print the resolved source roots") + (println " run a deps.edn :tasks entry")) (defn -main [& args] (let [[cmd & more] args] (cond (nil? cmd) (usage) - (= cmd "--help") (usage) - (= cmd "-h") (usage) - (#{"--version" "-V"} cmd) (println (str "jolt " (version))) (= cmd "run") (cmd-run more) (= cmd "repl") (repl) - (= cmd "--nrepl-server") (nrepl more) + (= cmd "nrepl") (nrepl more) (= cmd "path") (cmd-path) (str/starts-with? cmd "-M") (cmd-M cmd more) (str/starts-with? cmd "-A") (cmd-A cmd more) diff --git a/jolt-core/jolt/nrepl.clj b/jolt-core/jolt/nrepl.clj index 96056c8..f48731a 100644 --- a/jolt-core/jolt/nrepl.clj +++ b/jolt-core/jolt/nrepl.clj @@ -17,70 +17,28 @@ Writes .nrepl-port in the project dir so editors auto-detect the port." (:require [clojure.string :as str] - [clojure.java.io :as io] [jolt.ffi :as ffi])) ;; --- sockets (loopback server) --------------------------------------------- -(def ^:private os-name - (str/lower-case (or (System/getProperty "os.name") ""))) -(def ^:private macos? (str/includes? os-name "mac")) -(def ^:private windows? (str/includes? os-name "win")) - -;; Load the library that provides the socket symbols BEFORE the foreign-fn -;; bindings below — defcfn resolves the C entry point when the def is evaluated -;; (at ns load), so the symbols must already be available. POSIX: the running -;; process's own libc symbols. Windows: the Winsock DLL (ws2_32), whose symbols -;; are NOT in joltc.exe's export table even though it's linked in — without this -;; explicit load, (ffi/defcfn c-socket "socket" ...) fails at load with -;; "no entry for socket". -(if windows? - (ffi/load-library "ws2_32.dll") - (ffi/load-library)) - -;; A socket is an int fd on POSIX; on Win64 it's a SOCKET (uintptr_t) handle, but -;; those are small kernel handle values that round-trip through :int, and the -;; INVALID_SOCKET error sentinel (~0) reads back as -1 — so the fd checks below -;; work unchanged on both. +;; Load libc (the running process's symbols) BEFORE the foreign-fn bindings below +;; — defcfn resolves the C entry point when the def is evaluated (at ns load), so +;; the socket symbols must already be available. +(ffi/load-library) (ffi/defcfn c-socket "socket" [:int :int :int] :int) (ffi/defcfn c-bind "bind" [:int :pointer :int] :int) (ffi/defcfn c-listen "listen" [:int :int] :int) (ffi/defcfn c-setsockopt "setsockopt" [:int :int :int :pointer :int] :int) (ffi/defcfn c-accept "accept" [:int :pointer :pointer] :int :blocking) - -;; recv/send and the socket-close call differ by platform. Winsock's recv/send -;; take an int length and return int (not ssize_t), and a socket is closed with -;; closesocket, not close. A symbol that exists on only one OS (closesocket on -;; Windows, close on POSIX) can only be bound there, so these live in the taken -;; platform branch — jolt interns the vars from both branches at analysis time, -;; so later references resolve either way. -(if windows? - (do - (ffi/defcfn c-recv "recv" [:int :pointer :int :int] :int :blocking) - (ffi/defcfn c-send "send" [:int :pointer :int :int] :int :blocking) - (ffi/defcfn c-close "closesocket" [:int] :int) - ;; Winsock must be initialized once per process before any socket call. - (ffi/defcfn c-wsastartup "WSAStartup" [:int :pointer] :int)) - (do - (ffi/defcfn c-recv "recv" [:int :pointer :size_t :int] :ssize_t :blocking) - (ffi/defcfn c-send "send" [:int :pointer :size_t :int] :ssize_t :blocking) - (ffi/defcfn c-close "close" [:int] :int))) +(ffi/defcfn c-recv "recv" [:int :pointer :size_t :int] :ssize_t :blocking) +(ffi/defcfn c-send "send" [:int :pointer :size_t :int] :ssize_t :blocking) +(ffi/defcfn c-close "close" [:int] :int) (def ^:private AF-INET 2) (def ^:private SOCK-STREAM 1) -;; SOL_SOCKET / SO_REUSEADDR: 0xffff / 4 on macOS and Windows, 1 / 2 on Linux. -(def ^:private sol-socket (if (or macos? windows?) 0xffff 1)) -(def ^:private so-reuse (if (or macos? windows?) 4 2)) - -;; Initialize Winsock (a no-op off Windows). WSAStartup is refcounted and must -;; precede any socket call; WSADATA is ~408 bytes on x64, so 512 is ample. -(defn- ensure-winsock! [] - (when windows? - (let [wsadata (ffi/alloc 512)] - (try - (let [r (c-wsastartup 0x0202 wsadata)] - (when-not (zero? r) - (throw (ex-info (str "WSAStartup failed: " r) {})))) - (finally (ffi/free wsadata)))))) +(def ^:private macos? + (str/includes? (str/lower-case (or (System/getProperty "os.name") "")) "mac")) +(def ^:private sol-socket (if macos? 0xffff 1)) +(def ^:private so-reuse (if macos? 4 2)) (defn- make-sockaddr [port] (let [sa (ffi/alloc 16)] @@ -94,7 +52,7 @@ sa)) (defn- listen-socket [port] - (ensure-winsock!) ; no-op off Windows + (ffi/load-library) ; libc process symbols (let [fd (c-socket AF-INET SOCK-STREAM 0)] (when (neg? fd) (throw (ex-info "socket() failed" {}))) (let [opt (ffi/alloc 4)] (ffi/write opt :int 0 1) (c-setsockopt fd sol-socket so-reuse opt 4) (ffi/free opt)) @@ -188,10 +146,7 @@ (try (when (and ns-str (not (str/blank? ns-str)) (find-ns (symbol ns-str))) (in-ns (symbol ns-str))) (reset! result (load-string code)) - (catch :default e - (reset! err (str (err-msg e) - (when-let [bt (jolt.host/backtrace-string)] - (str "\n" bt)))))))] + (catch :default e (reset! err (err-msg e)))))] {:value (when (nil? @err) (pr-str @result)) :out out :ns (str (ns-name *ns*)) @@ -267,44 +222,18 @@ (defn start "Start the nREPL server on `port` (a concrete port; loopback only). `middleware` is a vector of deps.edn :nrepl/middleware symbols to compose over the built-in - handler. - - Binds the socket synchronously, so a startup failure (e.g. the port is already - in use) is thrown to the caller rather than swallowed by the accept thread, then - accepts connections on a background thread and returns immediately. Writes - .nrepl-port. Does NOT block — the caller keeps the process alive (jolt.main - parks the main thread in jolt.host/run-main-pump). - - Returns a zero-arg stop fn: it stops the accept loop, closes the listen socket - (freeing the port), and removes .nrepl-port. Calling it more than once is a - no-op." + handler. Writes .nrepl-port. Blocks accepting connections." ([port] (start port nil)) ([port middleware] - ;; An nREPL session is REPL-driven development: trace by default so an uncaught - ;; error in code evaluated over the connection shows a tail-frame backtrace, with - ;; no JOLT_TRACE needed. Covers both `--nrepl-server` and an app that starts its - ;; own server under `-M:run` (reload a namespace to trace already-loaded code). - (jolt.host/enable-trace!) (let [handler (build-handler (resolve-middleware (or middleware []))) - fd (listen-socket port) ; throws on bind/listen failure - stopped (atom false)] + fd (listen-socket port)] (try (spit ".nrepl-port" (str port)) (catch :default _ nil)) - (println (str "jolt " (jolt.host/jolt-version) " nREPL server started on port " - port " (127.0.0.1) — .nrepl-port written")) + (println (str "nREPL server started on port " port " (127.0.0.1) — .nrepl-port written")) (when (seq middleware) (println (str ";; middleware: " (str/join " " middleware)))) (println ";; connect your editor; ^C to stop") - (future - ;; A stop closes fd, which makes the blocking accept() return an error; the - ;; @stopped check then breaks the loop instead of spinning on the dead fd. - (loop [] - (let [conn (c-accept fd ffi/null ffi/null)] - (when-not @stopped - (when (>= conn 0) - (future (try (handle-conn conn handler) - (catch :default e (println "nrepl conn error:" (err-msg e)) (c-close conn))))) - (recur))))) - (fn stop [] - (when (compare-and-set! stopped false true) - (c-close fd) - (jolt.host/delete-file ".nrepl-port")) - nil)))) + (loop [] + (let [conn (c-accept fd ffi/null ffi/null)] + (when (>= conn 0) + (future (try (handle-conn conn handler) + (catch :default e (println "nrepl conn error:" (err-msg e)) (c-close conn))))) + (recur)))))) diff --git a/jolt-core/jolt/passes.clj b/jolt-core/jolt/passes.clj index b4e4f75..35852a9 100644 --- a/jolt-core/jolt/passes.clj +++ b/jolt-core/jolt/passes.clj @@ -13,7 +13,7 @@ :refer, so jolt.passes stays the only namespace the back end imports. Portable Clojure: kernel-tier fns + seed primitives only." - (:require [jolt.host :refer [inline-enabled? record-shapes protocol-methods stash-inline!]] + (:require [jolt.host :refer [inline-enabled? record-shapes stash-inline!]] [jolt.passes.fold :refer [const-fold]] [jolt.passes.numeric :as numeric] [jolt.passes.inline :refer [inline-node flatten-lets scalar-replace dirty set-rec-shapes!]] @@ -22,7 +22,6 @@ set-rtenv! set-vtypes! join-types set-record-shapes! set-map-shapes! set-protocol-methods! reset-escapes! collected-escapes - wp-infer! param-seeds-for param-num-seeds-for set-check-mode! take-diags!]])) ;; Cap on inline -> flatten -> scalar-replace -> const-fold iterations. Each pass @@ -40,22 +39,6 @@ (let [a (first (:arities (:init node)))] {:params (:params a) :body (:body a) :nhints (:nhints a) :ret (:ret-nhint a)})) -(defn inject-wp-nhints - "Merge the whole-program :double param seeds into a def's arity :nhints as - synthetic ^double hints, so the numeric pass unboxes a hintless fn whose callers - all pass flonums (the entry coercion exact->inexact is a no-op on a proven - flonum). Only un-hinted params are added — an explicit hint wins. A no-op unless - the closed-world fixpoint typed a param :double (param-num-seeds-for)." - [node] - (let [seeds (when (= :def (:op node)) (param-num-seeds-for (str (:ns node) "/" (:name node)))) - f (:init node)] - (if (and seeds (= :fn (:op f)) (= 1 (count (:arities f)))) - (let [a (first (:arities f)) - have (into #{} (map first (:nhints a))) - add (for [[p k] seeds :when (not (have p))] [p k])] - (assoc node :init (assoc f :arities [(assoc a :nhints (vec (concat (:nhints a) add)))]))) - node))) - (defn run-passes "All passes, in order. The back end applies this to every analyzed form. When inlining is enabled for the unit (user code under direct-linking), @@ -79,19 +62,13 @@ ;; `this`) to bare field reads per-form, not only under whole-program. ;; Same shapes the inline pass uses. _ (set-record-shapes! (record-shapes ctx)) - _ (set-protocol-methods! (protocol-methods ctx)) ;; devirtualization opt (loop [i 0 n (const-fold node)] (reset! dirty false) (let [n2 (const-fold (scalar-replace (flatten-lets (inline-node n ctx))))] (if (and @dirty (< i inline-fixpoint-cap)) (recur (inc i) n2) - n2))) - ;; a top-level def whose params the whole-program fixpoint typed gets - ;; reinferred with those seeds (record types flow in from its callers); - ;; everything else takes the ordinary per-form inference. - seeds (when (= :def (:op opt)) (param-seeds-for (str (:ns opt) "/" (:name opt))))] + n2)))] ;; a final const-fold after inference propagates any predicate folded to a - ;; constant, collapsing the `if` it gates to the taken branch; then inject - ;; any whole-program :double param hints for the numeric pass that follows. - (inject-wp-nhints (const-fold (if seeds (reinfer-def opt seeds) (run-inference opt))))) + ;; constant, collapsing the `if` it gates to the taken branch. + (const-fold (run-inference opt))) (const-fold node)))) diff --git a/jolt-core/jolt/passes/numeric.clj b/jolt-core/jolt/passes/numeric.clj index 1f2df79..0bd9033 100644 --- a/jolt-core/jolt/passes/numeric.clj +++ b/jolt-core/jolt/passes/numeric.clj @@ -49,18 +49,6 @@ (and (>= n 2) (contains? #{"<" ">" "<=" ">=" "=" "=="} nm)) :bool :else nil)) -;; result kind of a bigdec-specialized op, or nil. Arithmetic / quot / rem yield a -;; bigdec; the comparisons and zero?/pos?/neg? yield a bool. `=` is left to the -;; generic jolt= (already bigdec-aware), and `/` can throw (non-terminating) but is -;; still a bigdec op. Each non-nil name must have an entry in backend bd-ops. -(defn- bd-spec [nm n] - (cond - (and (>= n 1) (contains? #{"+" "-" "*" "/" "min" "max"} nm)) :bigdec - (and (= n 2) (contains? #{"quot" "rem"} nm)) :bigdec - (and (= n 1) (contains? #{"zero?" "pos?" "neg?"} nm)) :bool - (and (>= n 2) (contains? #{"<" ">" "<=" ">="} nm)) :bool - :else nil)) - ;; A non-numeric result (a comparison) doesn't propagate a numeric kind. (defn- propagate [spec] (if (= spec :bool) nil spec)) @@ -156,22 +144,17 @@ node1 (assoc node :args argnodes) n (count ars)] (cond - ;; a field read the structural inference proved is a flonum (a ^double record - ;; field) is a :double operand — so (* (:x v) (:x v)) unboxes. The read itself - ;; isn't lowered here; it keeps its keyword/jrec-field-at emit. - (= :double (get node :num-read)) [:double node1] ;; a call to a var with a declared numeric return (^double/^long) yields that ;; kind, so an accumulator over the result types. The call itself isn't an ;; arithmetic op to lower — its body already coerces the return. (get fnode :num-ret) [(get fnode :num-ret) node1] (nil? nm) [nil node1] :else - (let [;; per-operand class: :double / :long / :bigdec (typed), :wild (integer - ;; literal, usable in any), or :no (anything else — blocks specialization). + (let [;; per-operand class: :double / :long (typed), :wild (integer literal, + ;; usable in either), or :no (anything else — blocks specialization). cls (mapv (fn [r] (let [k (nth r 0) nd (nth r 1)] (cond (= k :double) :double (= k :long) :long - (= k :bigdec) :bigdec (int-lit? nd) :wild :else :no))) ars) @@ -180,26 +163,15 @@ (every? (fn [c] (or (= c :wild) (= c allowed))) cls) (some (fn [c] (= c need)) cls))) ds (dbl-spec nm n) - ls (lng-spec nm n) - bs (bd-spec nm n)] + ls (lng-spec nm n)] (cond - (and ds (ok? :double :double) - ;; min/max return the ORIGINAL operand (Numbers.min: an integer - ;; literal stays exact), so an int-literal operand blocks the - ;; flonum lowering there — flmin would coerce it. - (or (not (contains? #{"min" "max"} nm)) - (every? (fn [c] (= c :double)) cls))) + (and ds (ok? :double :double)) ;; coerce integer-literal operands to flonum so fl-ops never see an exact int. (let [args' (mapv (fn [nd] (if (int-lit? nd) (assoc nd :val (double (get nd :val))) nd)) argnodes)] [(propagate ds) (assoc node1 :args args' :num-kind :double)]) (and ls (ok? :long :long)) [(propagate ls) (assoc node1 :num-kind :long)] - ;; bigdec: every operand a bigdec (integer literals allowed, coerced at - ;; runtime). A flonum operand blocks this (double contagion) and falls - ;; through to the generic op. - (and bs (ok? :bigdec :bigdec)) - [(propagate bs) (assoc node1 :num-kind :bigdec)] :else [nil node1]))))) ;; Returns [kind node'] — kind is :double, :long, or nil. @@ -207,9 +179,6 @@ (let [op (get node :op)] (cond (= op :const) [(if (float-lit? node) :double nil) node] - ;; a bigdec (M) literal seeds the :bigdec kind so call-position arithmetic - ;; over it (and let-bound copies of it) dispatches to the bigdec engine. - (= op :bigdec) [:bigdec node] (= op :local) [(get tenv (get node :name)) node] (= op :coerce) [(get node :kind) (assoc node :expr (nth (an (get node :expr) tenv) 1))] (= op :invoke) (an-invoke node tenv) diff --git a/jolt-core/jolt/passes/types.clj b/jolt-core/jolt/passes/types.clj index 1aeba9a..fdae6da 100644 --- a/jolt-core/jolt/passes/types.clj +++ b/jolt-core/jolt/passes/types.clj @@ -5,15 +5,14 @@ checker. Also the inter-procedural driver API the back end calls to propagate param types across a unit / the whole program. Weakly coupled to the IR-rewriting passes — shares the const-shape predicates (jolt.passes.fold)." - (:require [jolt.ir :refer [reduce-ir-children]] - [jolt.passes.fold :refer [scalar-const? kw-callee? get-callee?]] + (:require [jolt.passes.fold :refer [scalar-const? kw-callee? get-callee?]] [jolt.passes.types.check :refer [not-callable? type-name check-invoke register-user-fn!]] [jolt.passes.types.lattice :refer [velem selem sfields vec-type? set-type? struct-type? mk-vec mk-set mk-struct union-cap scalar-t? union-type? umembers union-of merge-fields join-t join type-depth cap struct-safe? field-type shape-order type-shape - mark-struct truthy-type? num-ret-fns vector-ret-fns nilable? strip-nilable]])) + mark-struct truthy-type? num-ret-fns vector-ret-fns]])) ;; --- engine state ------------------------------------------------------------ ;; The walk threads an immutable `env` (mk-env) instead of reading scattered @@ -46,11 +45,6 @@ (def ^:private last-diags-box (atom [])) ;; Whether run-inference also checks, and strictly. Set by set-check-mode!. (def ^:private check-mode-box (atom {:on false :strict false})) -;; "Proto/method" -> the join of its impls' return types, so a protocol-method call -;; types as that record when every impl returns the same one (monomorphic return — -;; e.g. all Scatter impls return a ScatterResult). Set by collect-pm-rets! before -;; the fixpoint, read by call-ret-type. A disagreeing impl widens it to :any. -(def ^:private pm-rets-box (atom {})) ;; build a per-run env: a snapshot of the installed config plus this run's flags ;; and fresh accumulator/guard cells. escapes/user-sigs reference the sweep-level @@ -75,7 +69,6 @@ (cond (or (nil? tag) (<= depth 0)) :any (= tag "num") :num - (= tag "double") :double ; a ^double field reads back as a flonum :else (let [e (get shapes tag)] (if e (record-type-from-entry e depth shapes) :any)))) (defn- record-type-from-entry [rs depth shapes] @@ -110,18 +103,11 @@ ;; declared hints so nested records stay typed (record-type-from-entry rs type-depth shapes) (let [r (get (get env :rtenv) (var-key fnode))] - (if r r - ;; a protocol-method call types as its impls' joined return - ;; (monomorphic): so (:ray (scatter m ..)) reads off a Ray. - (let [pm (get (get env :protocol-methods) (var-key fnode)) - pmr (when pm (get @pm-rets-box (str (nth pm 0) "/" (nth pm 1))))] - (if (and pmr (not= pmr :any)) - pmr - (let [nm (and (= "clojure.core" (get fnode :ns)) (get fnode :name))] - (cond (nil? nm) :any - (contains? num-ret-fns nm) :num - (contains? vector-ret-fns nm) (mk-vec :any) - :else :any)))))))) + (if r r (let [nm (and (= "clojure.core" (get fnode :ns)) (get fnode :name))] + (cond (nil? nm) :any + (contains? num-ret-fns nm) :num + (contains? vector-ret-fns nm) (mk-vec :any) + :else :any)))))) (= op :host) (let [nm (get fnode :name)] (cond (contains? num-ret-fns nm) :num (contains? vector-ret-fns nm) (mk-vec :any) @@ -143,16 +129,13 @@ (defn- pred-on [pname t] (cond (or (= t :any) (= t :truthy)) nil - ;; a nilable struct might be nil — nil?/some?/record? can't be proven, so the - ;; runtime guard must stay (this is what makes the narrowing sound). - (nilable? t) nil ;; a bounded scalar union folds only when every member agrees (union-type? t) (let [vs (map (fn [m] (pred-on pname m)) (umembers t))] (if (and (seq vs) (not (nil? (first vs))) (apply = vs)) (first vs) nil)) :else (case pname - "number?" (or (= t :num) (= t :double)) + "number?" (= t :num) "string?" (= t :str) "keyword?" (= t :kw) "record?" (record-t? t) @@ -163,28 +146,6 @@ ;; folds away (a wider purity analysis can broaden this later). (defn- pure-node? [n] (let [op (get n :op)] (or (= op :const) (= op :local)))) -;; Flow-sensitive nil narrowing: in (if (some? x) ..) / (if x ..) / (if (nil? x) ..) -;; a nilable-struct local x is proven non-nil in one branch, so its field reads -;; bare-index and unbox there. Only a nilable local narrows — nothing else changes. -(defn- test-local [test pred-name] - (when (= :invoke (get test :op)) - (let [f (get test :fn) args (get test :args)] - (when (and (= :var (get f :op)) (= "clojure.core" (get f :ns)) - (= pred-name (get f :name)) - (= 1 (count args)) (= :local (get (nth args 0) :op))) - (get (nth args 0) :name))))) -(defn- narrow-nonnil [tenv nm] - (let [t (get tenv nm)] (if (nilable? t) (assoc tenv nm (strip-nilable t)) tenv))) -;; [then-tenv else-tenv] for an `if` whose test narrows a nilable local. -(defn- if-narrow [test tenv] - (let [somev (test-local test "some?") - nilv (test-local test "nil?")] - (cond - (= :local (get test :op)) [(narrow-nonnil tenv (get test :name)) tenv] - somev [(narrow-nonnil tenv somev) tenv] - nilv [tenv (narrow-nonnil tenv nilv)] - :else [tenv tenv]))) - (declare infer) ;; infer (and infer-fn-seeded) return a [type node'] tuple — the result type plus @@ -193,39 +154,6 @@ (defn- ty [r] (nth r 0)) (defn- nd [r] (nth r 1)) -;; Arg types for a self-recursive call. A same-position pass-through of the -;; enclosing param (arg i is the bare param i) contributes nil — the join identity — -;; instead of its type: it can't add information (param i ⊇ param i is trivial), but -;; its type is :any until external callers determine it, and :any is absorbing, so -;; collecting it would pin the param at :any forever (a recursive fn that threads a -;; param straight through, e.g. ray-cast passing `hittables` unchanged). A computed -;; arg, or a DIFFERENT param at this position, is a real constraint and is collected. -(defn- self-rec-argtys [args ares self-params] - (mapv (fn [i] - (let [a (nth args i)] - (if (and self-params (< i (count self-params)) - (= :local (get a :op)) (= (get a :name) (nth self-params i))) - nil - (ty (nth ares i))))) - (range (count ares)))) - -;; arithmetic core ops that yield a flonum when their operands are flonums — a -;; mirror of jolt.passes.numeric/dbl-spec's arithmetic set, used to flow :double -;; across fn boundaries so a hintless fn whose callers all pass doubles is unboxed. -;; Comparisons are excluded: they yield a boolean, not a number. -(def ^:private dbl-arith-ops #{"+" "-" "*" "/" "min" "max" "inc" "dec"}) -(defn- int-lit-node? [n] - (and (= :const (get n :op)) (let [v (get n :val)] (and (number? v) (integer? v))))) -;; an arithmetic result is :double when every operand is a proven flonum or an -;; integer literal (a wildcard the fl-op coerces) and at least one is a flonum — so -;; (* x 2) with x:double is :double, but (* a b) with both :num stays :num (no -;; flonum proof, no fl-op). -(defn- dbl-arith? [ares argnodes] - (and (pos? (count ares)) - (every? (fn [i] (or (= :double (ty (nth ares i))) (int-lit-node? (nth argnodes i)))) - (range (count ares))) - (some (fn [r] (= :double (ty r))) ares))) - ;; HOFs that apply their fn arg to the ELEMENTS of a collection. :epos is which ;; param of the fn receives an element. reduce is ;; handled separately (its arity changes the coll position, and its closure @@ -279,13 +207,9 @@ mt (ty mr) msub (if (struct-safe? mt) (mark-struct (nd mr) mt) (nd mr)) ft (field-type mt (get fnode :val)) - dr (when (= n 2) (infer (nth args 1) tenv env)) - rt (if dr (join ft (ty dr)) ft) - node' (assoc node :args (if dr [msub (nd dr)] [msub]))] - ;; a flonum field read is a :double operand for the numeric pass (fl-ops); the - ;; lookup itself still emits as a keyword/jrec-field-at read, this only feeds - ;; its kind up so (* (:x v) (:x v)) over a ^double-fielded record unboxes. - [rt (if (= rt :double) (assoc node' :num-read :double) node')])) + dr (when (= n 2) (infer (nth args 1) tenv env))] + [(if dr (join ft (ty dr)) ft) + (assoc node :args (if dr [msub (nd dr)] [msub]))])) (defn- infer-get-lookup "(get m :k [default]): the keyword-lookup result type, when the key is a constant @@ -296,10 +220,9 @@ msub (if (struct-safe? mt) (mark-struct (nd mr) mt) (nd mr)) kr (infer (nth args 1) tenv env) ft (field-type mt (get (nth args 1) :val)) - dr (when (= n 3) (infer (nth args 2) tenv env)) - rt (if dr (join ft (ty dr)) ft) - node' (assoc node :args (if dr [msub (nd kr) (nd dr)] [msub (nd kr)]))] - [rt (if (= rt :double) (assoc node' :num-read :double) node')])) + dr (when (= n 3) (infer (nth args 2) tenv env))] + [(if dr (join ft (ty dr)) ft) + (assoc node :args (if dr [msub (nd kr) (nd dr)] [msub (nd kr)]))])) (defn- infer-reduce-hof "reduce over a typed vector with a fn-literal: seed the closure's accumulator @@ -359,24 +282,7 @@ callee-t (if iscall-var (get (get env :vtypes) (var-key fnode)) (ty fr)) ares (mapv (fn [a] (infer a tenv env)) args)] (when iscall-var - ;; a `defn` recurses through its own VAR, so a self-recursion is a var-call - ;; here (not the :local case below). When the callee is the enclosing def, - ;; drop same-position pass-through args so threading a param straight through - ;; the recursion doesn't poison it to :any. - (swap! (get env :calls) conj - [(var-key fnode) - (if (= (var-key fnode) (get env :self-key)) - (self-rec-argtys args ares (get env :self-params)) - (mapv (fn [r] (ty r)) ares))])) - ;; a named fn calling itself binds its name as a :local, so the recursion is - ;; invisible to the var-call collection above — yet it constrains the fn's own - ;; params. Collect it under the fn's var-key so the whole-program fixpoint joins - ;; the recursive arg types (else a self-recursive param is typed from external - ;; callers alone and may be specialized to a type the recursion violates). - (when (and (= :local (get fnode :op)) (get env :self-key) - (= (get fnode :name) (get env :self-name))) - (swap! (get env :calls) conj - [(get env :self-key) (self-rec-argtys args ares (get env :self-params))])) + (swap! (get env :calls) conj [(var-key fnode) (mapv (fn [r] (ty r)) ares)])) ;; success-type check at this call, reusing the arg types just computed (jolt ;; audit): core error domains always, user-fn domains in strict mode. (when (get env :checking?) @@ -396,9 +302,6 @@ (= cn "range") (mk-vec :num) (and cn (contains? elem-fns cn) (> n 0)) (let [a0 (ty (nth ares 0))] (if (vec-type? a0) (velem a0) :any)) - ;; flonum arithmetic yields a flonum — flows :double into a callee param - ;; (and into the fixpoint's return type) so hintless double code unboxes. - (and cn (contains? dbl-arith-ops cn) (dbl-arith? ares args)) :double :else (call-ret-type fnode env)) (if rtype (assoc base :devirt-type rtype :devirt-proto (nth pm 0) :devirt-method (nth pm 1)) @@ -444,12 +347,10 @@ (cond (= op :const) [(let [v (get node :val)] - (cond (and (number? v) (float? v)) :double ; a flonum literal is :double - (number? v) :num + (cond (number? v) :num (string? v) :str (keyword? v) :kw - (nil? v) :nil ; a record|nil branch types as a nilable record - (= false v) :any ; false is not struct-eligible + (or (nil? v) (= false v)) :any ; nil/false are not struct-eligible :else :truthy)) ; true, char, ... -> non-nil node] (= op :local) @@ -489,11 +390,9 @@ el (if (empty? ets) :any (reduce join (first ets) (rest ets)))] [(cap (mk-set el) type-depth) (assoc node :items (mapv (fn [r] (nth r 1)) irs))]) (= op :if) - (let [test (get node :test) - tr (infer test tenv env) - nr (if-narrow test tenv) ; narrow a nilable local in the proven branch - thn (infer (get node :then) (nth nr 0) env) - els (infer (get node :else) (nth nr 1) env)] + (let [tr (infer (get node :test) tenv env) + thn (infer (get node :then) tenv env) + els (infer (get node :else) tenv env)] [(join (nth thn 0) (nth els 0)) (assoc node :test (nth tr 1) :then (nth thn 1) :else (nth els 1))]) (= op :do) @@ -520,20 +419,12 @@ (= op :loop) ;; conservative + sound: loop bindings join across recur, which we don't ;; track here, so they stay :any. Still descend to annotate any - ;; known-type lookups inside the body. A recur inside this body targets the - ;; loop, not the enclosing fn, so mark :in-loop? to suppress self-collection. - (let [lenv (assoc env :in-loop? true)] - [:any (assoc node - :bindings (mapv (fn [b] [(nth b 0) (nth (infer (nth b 1) tenv env) 1)]) (get node :bindings)) - :body (nth (infer (get node :body) tenv lenv) 1))]) + ;; known-type lookups inside the body. + [:any (assoc node + :bindings (mapv (fn [b] [(nth b 0) (nth (infer (nth b 1) tenv env) 1)]) (get node :bindings)) + :body (nth (infer (get node :body) tenv env) 1))] (= op :recur) - (let [ares (mapv (fn [a] (infer a tenv env)) (get node :args))] - ;; a fn-level recur (not inside a loop) rebinds the enclosing fn's params, - ;; so its args constrain them like a self-call — collect under the fn key. - (when (and (not (get env :in-loop?)) (get env :self-key)) - (swap! (get env :calls) conj - [(get env :self-key) (self-rec-argtys (get node :args) ares (get env :self-params))])) - [:any (assoc node :args (mapv (fn [r] (nd r)) ares))]) + [:any (assoc node :args (mapv (fn [a] (nth (infer a tenv env) 1)) (get node :args)))] (= op :fn) ;; a closure inherits the enclosing tenv so CAPTURED locals keep their ;; types (e.g. a reduce closure that calls (f captured-struct ...)). Its own @@ -542,23 +433,19 @@ ;; reads off it bare-index per-form, not only under whole-program. This is ;; what makes a protocol method's `this` (hinted by defrecord/extend-type) ;; read its fields without the runtime tag guard. - ;; a nested closure resets the self/loop context: its own recur/self-call - ;; targets IT, not the enclosing whole-program def, so it must not collect - ;; into that def's param key. - (let [fenv (assoc env :self-name nil :self-key nil :self-params nil :in-loop? false)] - [:any (assoc node :arities - (mapv (fn [a] - (let [shapes (get env :record-shapes) - phm (reduce (fn [m pr] (assoc m (nth pr 0) (nth pr 1))) - {} (get a :phints)) - pe (reduce (fn [e p] - (assoc e p - (let [ent (get shapes (get phm p))] - (if ent (record-type-from-entry ent type-depth shapes) :any)))) - tenv (get a :params)) - pe (if (get a :rest) (assoc pe (get a :rest) :any) pe)] - (assoc a :body (nth (infer (get a :body) pe fenv) 1)))) - (get node :arities)))]) + [:any (assoc node :arities + (mapv (fn [a] + (let [shapes (get env :record-shapes) + phm (reduce (fn [m pr] (assoc m (nth pr 0) (nth pr 1))) + {} (get a :phints)) + pe (reduce (fn [e p] + (assoc e p + (let [ent (get shapes (get phm p))] + (if ent (record-type-from-entry ent type-depth shapes) :any)))) + tenv (get a :params)) + pe (if (get a :rest) (assoc pe (get a :rest) :any) pe)] + (assoc a :body (nth (infer (get a :body) pe env) 1)))) + (get node :arities)))] (= op :def) (do (when (get env :checking?) (register-user-fn! node env)) [:any (assoc node :init (nth (infer (get node :init) tenv env) 1))]) @@ -698,46 +585,11 @@ "Type `body` under tenv (local-name -> type). Returns [ret-type node' calls], where calls is the [[\"ns/name\" [arg-types...]] ...] this body invokes (for propagating into callee param types). Also accumulates escapes (read with - collected-escapes after a full sweep). With self-name/self-key, a recursive - self-call or fn-level recur in `body` is collected under self-key too, so a - self-recursive fn's params are constrained by its recursion, not just callers." - ([body tenv] (infer-body body tenv nil nil nil)) - ([body tenv self-name self-key] (infer-body body tenv self-name self-key nil)) - ([body tenv self-name self-key self-params] - (let [env (assoc (mk-env false false) - :self-name self-name :self-key self-key :self-params self-params) - r (infer body tenv env)] - [(nth r 0) (nth r 1) @(get env :calls)]))) - -;; --- protocol-method return types ------------------------------------------- -;; An impl is emitted as (register-(inline-)method TAG "Proto" "method" (fn ...)). -;; Its fn body's return type is one impl's contribution to the method's return; the -;; join over every impl is the method's return type (monomorphic when all agree). -(defn- impl-reg-ret [node] - (when (= :invoke (get node :op)) - (let [f (get node :fn) args (get node :args)] - (when (and (= :var (get f :op)) - (or (= "register-inline-method" (get f :name)) - (= "register-method" (get f :name))) - (= 4 (count args))) - (let [proto (get (nth args 1) :val) - method (get (nth args 2) :val) - fnn (nth args 3)] - (when (and (string? proto) (string? method) - (= :fn (get fnn :op)) (seq (get fnn :arities))) - [(str proto "/" method) - (nth (infer-body (get (first (get fnn :arities)) :body) {}) 0)])))))) - -(defn- walk-pm-rets [node acc] - (let [kr (impl-reg-ret node) - acc (if kr (update acc (nth kr 0) (fn [t] (if t (join t (nth kr 1)) (nth kr 1)))) acc)] - (reduce-ir-children (fn [a c] (walk-pm-rets c a)) acc node))) - -(defn collect-pm-rets! - "Scan the unit's nodes for protocol-method impl registrations and stash each - method's joined impl-return type (record-shapes must already be installed)." - [nodes] - (reset! pm-rets-box (reduce (fn [acc n] (walk-pm-rets n acc)) {} nodes))) + collected-escapes after a full sweep)." + [body tenv] + (let [env (mk-env false false) + r (infer body tenv env)] + [(nth r 0) (nth r 1) @(get env :calls)])) (defn reinfer-def "Re-run inference on a stashed :def's fn arity bodies with param types seeded @@ -787,123 +639,6 @@ (when e (record-type-from-entry e type-depth shapes)))) params))) -;; --- whole-program param-type fixpoint -------------------------------------- -;; Re-derive each app fn's param types from its call sites under closed world -;; (--opt), so a record type flows across fn boundaries: a ctor's return type -;; reaches a callee param ((check-tree (make-tree d)) -> node is a Node), and a -;; typed vector's element reaches a HOF closure's param (sum-area's reduce sees a -;; Circle). The back end then bare-indexes a field read and devirtualizes a -;; protocol call at those sites. Only single-fixed-arity fns are specialized; -;; anything called in value position (collected-escapes) keeps :any params — -;; its callers aren't all visible, so a concrete seed would be unsound. -(def ^:private wp-seeds-box (atom {})) -(defn param-seeds-for - "The param-name -> type seed map a top-level def should be reinferred with, or - nil. Set by wp-infer!, read by run-passes during the final per-def emit." - [k] (get @wp-seeds-box k)) - -;; numeric refinement of the same fixpoint: params the closed-world join proved -;; are always flonums. Kept SEPARATE from the structural box — these don't reinfer -;; (field-read/devirt), they become synthetic ^double nhints (jolt.passes/inject- -;; wp-nhints) so the hint-directed pass unboxes the arithmetic. -(def ^:private wp-num-seeds-box (atom {})) -(defn param-num-seeds-for - "The param-name -> :double seed map for a def's hintless flonum params, or nil." - [k] (get @wp-num-seeds-box k)) - -;; var-key -> {:params [names] :body ir} for each single-fixed-arity fn def. -(defn- wp-specializable [nodes] - (reduce (fn [m d] - (let [f (get d :init)] - (if (and (= :def (get d :op)) (= :fn (get f :op)) - (= 1 (count (get f :arities))) - (not (get (first (get f :arities)) :rest))) - (let [a (first (get f :arities))] - (assoc m (str (get d :ns) "/" (get d :name)) - {:name (get d :name) :params (get a :params) :body (get a :body)})) - m))) - {} nodes)) - -(defn- wp-empty-ptypes [spec ks] - (reduce (fn [m k] (assoc m k (vec (repeat (count (:params (get spec k))) nil)))) {} ks)) - -;; join one call's arg types into its (specializable) callee's param slots. -(defn- wp-accum [pt spec calls] - (reduce (fn [pt2 c] - (let [callee (nth c 0) args (nth c 1)] - (if (contains? spec callee) - (let [cur (get pt2 callee)] - (assoc pt2 callee - (vec (map-indexed - (fn [i t] (if (< i (count args)) (join t (nth args i)) t)) cur)))) - pt2))) - pt calls)) - -;; one fixpoint pass over every top-level node: a specializable def is typed -;; under the current param seeds (so a seeded record flows into the calls it -;; makes) and contributes its return type; any other form is typed only to -;; harvest its call sites and escapes. Returns {:rets :ptypes}, with ptypes -;; recomputed fresh each pass — :any is absorbing, so accumulating across passes -;; would pin a param at :any before its callers' return types are known. -(defn- wp-pass [nodes spec ks ptypes] - (reduce - (fn [acc node] - (let [k (when (= :def (get node :op)) (str (get node :ns) "/" (get node :name))) - s (and k (get spec k))] - (if s - (let [r (infer-body (:body s) (zipmap (:params s) (get ptypes k)) (:name s) k (:params s))] - (-> acc (assoc-in [:rets k] (nth r 0)) - (update :ptypes wp-accum spec (nth r 2)))) - (update acc :ptypes wp-accum spec (nth (infer-body node {}) 2))))) - {:rets {} :ptypes (wp-empty-ptypes spec ks)} nodes)) - -(defn wp-infer! - "Run the closed-world param-type fixpoint over the unit's analyzed top-level - nodes and stash the resulting per-def seed maps (read via param-seeds-for). - record-shapes / protocol-methods must already be installed. Idempotent — resets - the seed box; called once per build before per-form emit." - [nodes] - (collect-pm-rets! nodes) - (let [spec (wp-specializable nodes) - ks (keys spec)] - (loop [iter 0 ptypes (wp-empty-ptypes spec ks) rets {}] - (set-rtenv! (reduce (fn [m k] (let [v (get rets k)] (if (some? v) (assoc m k v) m))) {} ks)) - (reset-escapes!) - (let [pass (wp-pass nodes spec ks ptypes) - escaped (set (collected-escapes)) - ;; a fn used in value position has callers we can't see -> :any params - new-ptypes (reduce (fn [m k] - (if (contains? escaped k) - (assoc m k (vec (repeat (count (get m k)) :any))) m)) - (:ptypes pass) ks) - new-rets (:rets pass) - converged? (and (= new-ptypes ptypes) (= new-rets rets))] - (if (or converged? (>= iter 16)) - ;; On convergence new-ptypes is the least fixpoint (sound). On hitting the - ;; cap without convergence it's a pre-fixpoint — more specific than the - ;; fixpoint, so seeding it would be unsound; widen every param to :any - ;; (emit no seeds). The cap isn't reached in practice (~2 passes), this is - ;; a defensive floor. - (let [seed-ptypes (if converged? - new-ptypes - (reduce (fn [m k] (assoc m k (vec (repeat (count (get m k)) :any)))) - new-ptypes ks)) - ;; build both seed maps from the same converged ptypes: the - ;; structural one (struct/vec, drives reinfer-def's field-read/ - ;; devirt) excludes :double; the numeric one keeps only :double. - pick (fn [keep?] - (reduce (fn [m k] - (let [s (get spec k) - pm (reduce (fn [pm pr] - (let [nm (nth pr 0) t (nth pr 1)] - (if (and t (keep? t)) (assoc pm nm t) pm))) - {} (map vector (:params s) (get seed-ptypes k)))] - (if (seq pm) (assoc m k pm) m))) - {} ks))] - (reset! wp-seeds-box (pick (fn [t] (and (not= t :any) (not= t :double))))) - (reset! wp-num-seeds-box (pick (fn [t] (= t :double))))) - (recur (inc iter) new-ptypes new-rets)))))) - ;; Piggyback checking (jolt audit). In direct-link mode infer-top already runs ;; one inference pass for specialization; turning checking? on during it makes ;; the success checker nearly free there (no extra traversal — just the diff --git a/jolt-core/jolt/passes/types/lattice.clj b/jolt-core/jolt/passes/types/lattice.clj index 29cd422..4efcb13 100644 --- a/jolt-core/jolt/passes/types/lattice.clj +++ b/jolt-core/jolt/passes/types/lattice.clj @@ -79,34 +79,14 @@ (= a b) a (nil? a) b (nil? b) a - ;; :nil is the type of a literal nil. With a struct it forms a NILABLE struct — - ;; field reads still bare-index (jrec-field-at falls back to jolt-get on nil), but - ;; some?/nil? won't fold and a guard narrows it back to non-nil. With anything - ;; else it widens to :any (nil is not a safe scalar/vec — no fl/fx, no bare elem). - (or (= a :nil) (= b :nil)) - (let [o (if (= a :nil) b a)] - (cond (= o :nil) :nil - (struct-type? o) (assoc o :nilable true) - :else :any)) - ;; :double is a flonum refinement of :num: two doubles stay :double (caught by - ;; = above), but a double joined with anything else loses the flonum guarantee - ;; and widens to :num before joining — so a param is :double only when EVERY - ;; contributing value is a flonum, which is what makes the hintless fl-op sound. - (or (= a :double) (= b :double)) - (join-t (if (= a :double) :num a) (if (= b :double) :num b)) (and (struct-type? a) (struct-type? b)) - (let [merged (mk-struct (merge-fields (sfields a) (sfields b))) - ;; joining two values of the SAME complete shape / record type preserves - ;; it — the merged struct has the same key set. Different shapes/types - ;; (or an incomplete side) drop it, as the layout is no longer proven. - merged (if (and (get a :shape) (= (get a :shape) (get b :shape))) - (assoc merged :shape (get a :shape)) merged) - merged (if (and (get a :type) (= (get a :type) (get b :type))) - (assoc merged :type (get a :type)) merged) - ;; nilability is contagious: a nilable side makes the join nilable. - merged (if (or (get a :nilable) (get b :nilable)) - (assoc merged :nilable true) merged)] - merged) + (let [merged (mk-struct (merge-fields (sfields a) (sfields b)))] + ;; joining two values of the SAME complete shape preserves it — the + ;; merged struct has the same key set. Different shapes + ;; (or an incomplete side) drop it, as the layout is no longer proven. + (if (and (get a :shape) (= (get a :shape) (get b :shape))) + (assoc merged :shape (get a :shape)) + merged)) (and (vec-type? a) (vec-type? b)) (mk-vec (join-t (velem a) (velem b))) (and (set-type? a) (set-type? b)) (mk-set (join-t (selem a) (selem b))) ;; differing kinds: form a scalar union when both sides reduce to scalars @@ -141,12 +121,7 @@ ;; raw-get-safe (a struct / record): a struct type. The field type of key ;; k, if known, else :any. (defn struct-safe? [t] (struct-type? t)) -;; a nilable struct yields :any for every field (the whole value might be nil, so a -;; field read can be nil) — conservative + sound. A guard narrows it to non-nil first -;; (strip-nilable), after which the real field types flow. -(defn field-type [t k] (if (and (struct-type? t) (not (get t :nilable))) (get (sfields t) k :any) :any)) -(defn nilable? [t] (and (map? t) (get t :nilable) true)) -(defn strip-nilable [t] (if (and (map? t) (get t :nilable)) (dissoc t :nilable) t)) +(defn field-type [t k] (if (struct-type? t) (get (sfields t) k :any) :any)) ;; Shape (hidden class). A struct type built from a map LITERAL carries ;; its complete layout — :shape, the canonical (str-sorted) key vector. The back ;; end represents such a map as a shape tuple and reads a field by bare index. @@ -170,9 +145,8 @@ ;; (vs a phm) when every value is non-nil/non-false, so a map literal is a struct ;; only when all its values have such a type. Collections are non-nil. (defn truthy-type? [t] - (or (= t :num) (= t :double) (= t :str) (= t :kw) (= t :truthy) (= t :phm) - (and (struct-type? t) (not (get t :nilable))) ; a nilable struct may be nil - (vec-type? t) (set-type? t))) + (or (= t :num) (= t :str) (= t :kw) (= t :truthy) (= t :phm) + (struct-type? t) (vec-type? t) (set-type? t))) ;; core fns whose result is a number (so it is non-nil/non-false and, for the ;; success-type checker, provably numeric). diff --git a/stdlib/clojure/core/async.clj b/stdlib/clojure/core/async.clj deleted file mode 100644 index 5965100..0000000 --- a/stdlib/clojure/core/async.clj +++ /dev/null @@ -1,667 +0,0 @@ -;; clojure.core.async — higher-level dataflow API over the channel primitives. -;; -;; The primitives (chan, !, !!, close!, put!, take!, offer!, timeout, -;; promise-chan, buffer/dropping-buffer/sliding-buffer, go/go-loop/thread, go-spawn) -;; are provided natively (host/chez/java/async.ss) on real OS threads. This overlay -;; adds the portable dataflow operators — alts!, pipe, pipeline, split, reduce, -;; transduce, mult, mix, pub/sub, map, merge, and the deprecated map/… — -;; ported from clojure.core.async over those primitives. Because go blocks are real -;; threads, parking ops are ordinary blocking ops and work anywhere; this is a -;; superset of the JVM model (no fixed thread pool, no pending-op limit). - -(ns clojure.core.async - (:refer-clojure :exclude [reduce transduce into merge map take partition partition-by])) - -;; --- alts ------------------------------------------------------------------- -;; do-alts polls each port non-blockingly under its own channel lock; the first -;; ready op wins. A take port is ready when a value (or closed nil) is available; -;; a put spec [ch val] is ready when the value can be offered. Polls with a 1ms -;; backoff (no cross-channel wait-set). - -(defn- alt-attempt [port] - (if (vector? port) - (let [ch (nth port 0) v (nth port 1)] - (assert (some? v) "Can't put nil on channel") - (let [r (clojure.core.async/__offer! ch v)] ; true | false (closed) | nil (would block) - (when (some? r) [r ch]))) - (let [r (clojure.core.async/__poll! port)] ; value | nil (closed) | ::none - (when (not= r ::none) [r port])))) - -(defn do-alts - "Returns [val port] for the first ready op among ports. ports is a vector of - take ports and/or [channel val] put specs. opts may include :priority true - (try in order) and :default val (return [val :default] if none ready)." - [ports opts] - (assert (pos? (count ports)) "alts must have at least one channel operation") - (let [ports (vec ports) - n (count ports) - priority (:priority opts) - has-default (contains? opts :default)] - ;; Scan ports from a random start (sequential, wrapping) so a non-priority alts - ;; is fair without allocating a fresh shuffle every poll. With :priority the scan - ;; starts at 0 (declared order). Returns the first ready op. - (loop [first? true] - (let [start (if priority 0 (rand-int n)) - hit (loop [k 0] - (when (< k n) - (let [j (+ start k) i (if (< j n) j (- j n))] - (or (alt-attempt (nth ports i)) - (recur (inc k))))))] - (cond - hit hit - (and first? has-default) [(:default opts) :default] - :else (do (Thread/sleep 1) (recur false))))))) - -(defn alts!! - "Completes at most one of several channel operations. ports is a vector of take - ports and/or [channel val] put specs. Returns [val port]. Blocks until ready." - [ports & {:as opts}] - (do-alts ports opts)) - -(defn alts! - "Like alts!!. In jolt a go block is a real thread, so parking and blocking alts - are the same operation." - [ports & {:as opts}] - (do-alts ports opts)) - -(defn poll! - "Takes a val from port if possible immediately. Never blocks. Returns the value - or nil." - [port] - (let [r (clojure.core.async/__poll! port)] - (when (not= r ::none) r))) - -;; --- thread variants -------------------------------------------------------- - -(defn thread-call - "Executes f in another thread, returning a channel that receives f's result then - closes." - ([f] (clojure.core.async/go-spawn f)) - ([f _workload] (clojure.core.async/go-spawn f))) - -(defmacro io-thread - "Executes body in another thread, returning a channel that receives the result - then closes." - [& body] - `(thread-call (fn [] ~@body) :io)) - -;; --- pipe / pipeline -------------------------------------------------------- - -(defn pipe - "Takes elements from the from channel and supplies them to the to channel. - Closes to when from closes unless close? is false." - ([from to] (pipe from to true)) - ([from to close?] - (go-loop [] - (let [v (! to v) - (recur))))) - to)) - -(defn- pipeline* - [n to xf from close? ex-handler type] - (assert (pos? n)) - (let [jobs (chan n) - results (chan n) - process (fn [job] - (if (nil? job) - (do (close! results) nil) - (let [v (nth job 0) p (nth job 1) - res (chan 1 xf ex-handler)] - (>!! res v) - (close! res) - (put! p res) - true))) - afn (fn [job] - (if (nil? job) - (do (close! results) nil) - (let [v (nth job 0) p (nth job 1) - res (chan 1)] - (xf v res) - (put! p res) - true)))] - (dotimes [_ n] - (case type - (:blocking :compute) (thread - (loop [] - (let [job (! jobs [v p]) - (>! results p) - (recur))))) - (go-loop [] - (let [p (! to v)) - (recur)))) - (recur))))))) - -(defn pipeline - "Takes elements from from, applies transducer xf with parallelism n, supplies to - to. Outputs are ordered relative to inputs." - ([n to xf from] (pipeline n to xf from true)) - ([n to xf from close?] (pipeline n to xf from close? nil)) - ([n to xf from close? ex-handler] (pipeline* n to xf from close? ex-handler :compute))) - -(defn pipeline-blocking - "Like pipeline, for blocking operations." - ([n to xf from] (pipeline-blocking n to xf from true)) - ([n to xf from close?] (pipeline-blocking n to xf from close? nil)) - ([n to xf from close? ex-handler] (pipeline* n to xf from close? ex-handler :blocking))) - -(defn pipeline-async - "Like pipeline, for async fns af of two args [input result-channel]." - ([n to af from] (pipeline-async n to af from true)) - ([n to af from close?] (pipeline* n to af from close? nil :async))) - -(defn split - "Splits ch by predicate p into [true-chan false-chan]." - ([p ch] (split p ch nil nil)) - ([p ch t-buf-or-n f-buf-or-n] - (let [tc (chan t-buf-or-n) - fc (chan f-buf-or-n)] - (go-loop [] - (let [v (! (if (p v) tc fc) v) - (recur))))) - [tc fc]))) - -;; --- reduce / transduce / collection sinks ---------------------------------- - -(defn reduce - "Returns a channel with the single result of reducing ch with f from init." - [f init ch] - (go-loop [ret init] - (let [v (! ch (first vs))) - (recur (next vs)) - (when close? - (close! ch)))))) - -(defn to-chan! - "Returns a channel containing the contents of coll, closing when exhausted." - [coll] - (let [c (bounded-count 100 coll)] - (if (pos? c) - (let [ch (chan c)] - (onto-chan! ch coll) - ch) - (let [ch (chan)] - (close! ch) - ch)))) - -(defn onto-chan!! - "Like onto-chan! for use when accessing coll might block." - ([ch coll] (onto-chan!! ch coll true)) - ([ch coll close?] - (thread - (loop [vs (seq coll)] - (if (and vs (>!! ch (first vs))) - (recur (next vs)) - (when close? - (close! ch))))))) - -(defn to-chan!! - "Like to-chan! for use when accessing coll might block." - [coll] - (let [c (bounded-count 100 coll)] - (if (pos? c) - (let [ch (chan c)] - (onto-chan!! ch coll) - ch) - (let [ch (chan)] - (close! ch) - ch)))) - -(defn onto-chan - "Deprecated - use onto-chan! or onto-chan!!" - ([ch coll] (onto-chan! ch coll true)) - ([ch coll close?] (onto-chan! ch coll close?))) - -(defn to-chan - "Deprecated - use to-chan! or to-chan!!" - [coll] - (to-chan! coll)) - -(defn into - "Returns a channel with the single collection result of conjoining items from ch - onto coll. ch must close first." - [coll ch] - (reduce conj coll ch)) - -(defn take - "Returns a channel that returns at most n items from ch, then closes." - ([n ch] (take n ch nil)) - ([n ch buf-or-n] - (let [out (chan buf-or-n)] - (go (loop [x 0] - (when (< x n) - (let [v (! out v) - (recur (inc x)))))) - (close! out)) - out))) - -;; --- mult / tap ------------------------------------------------------------- - -(defprotocol Mux - (muxch* [_])) - -(defprotocol Mult - (tap* [m ch close?]) - (untap* [m ch]) - (untap-all* [m])) - -(defn mult - "Creates a mult of ch. Copies can be created with tap and removed with untap. - Each item is distributed to all taps synchronously." - [ch] - (let [cs (atom {}) - m (reify - Mux - (muxch* [_] ch) - Mult - (tap* [_ ch close?] (swap! cs assoc ch close?) nil) - (untap* [_ ch] (swap! cs dissoc ch) nil) - (untap-all* [_] (reset! cs {}) nil)) - dchan (chan 1) - dctr (atom nil) - done (fn [_] (when (zero? (swap! dctr dec)) - (put! dchan true)))] - (go-loop [] - (let [val (! out v) - (recur state)) - (recur state))))) - m)) - -(defn admix - "Adds ch as an input to the mix." - [mix ch] - (admix* mix ch)) - -(defn unmix - "Removes ch as an input to the mix." - [mix ch] - (unmix* mix ch)) - -(defn unmix-all - "Removes all inputs from the mix." - [mix] - (unmix-all* mix)) - -(defn toggle - "Atomically sets the state of one or more channels in a mix." - [mix state-map] - (toggle* mix state-map)) - -(defn solo-mode - "Sets the solo mode of the mix (:mute or :pause)." - [mix mode] - (solo-mode* mix mode)) - -;; --- pub / sub -------------------------------------------------------------- - -(defprotocol Pub - (sub* [p v ch close?]) - (unsub* [p v ch]) - (unsub-all* [p] [p v])) - -(defn pub - "Creates a pub of ch partitioned by topic-fn. Subscribe with sub." - ([ch topic-fn] (pub ch topic-fn (constantly nil))) - ([ch topic-fn buf-fn] - (let [mults (atom {}) - ensure-mult (fn [topic] - (or (get @mults topic) - (get (swap! mults - #(if (% topic) % (assoc % topic (mult (chan (buf-fn topic)))))) - topic))) - p (reify - Mux - (muxch* [_] ch) - Pub - (sub* [_p topic ch close?] - (let [m (ensure-mult topic)] - (tap m ch close?))) - (unsub* [_p topic ch] - (when-let [m (get @mults topic)] - (untap m ch))) - (unsub-all* [_] (reset! mults {})) - (unsub-all* [_ topic] (swap! mults dissoc topic)))] - (go-loop [] - (let [val (! (muxch* m) val) - (swap! mults dissoc topic))) - (recur))))) - p))) - -(defn sub - "Subscribes ch to a topic of pub p." - ([p topic ch] (sub p topic ch true)) - ([p topic ch close?] (sub* p topic ch close?))) - -(defn unsub - "Unsubscribes ch from a topic of pub p." - [p topic ch] - (unsub* p topic ch)) - -(defn unsub-all - "Unsubscribes all channels from a pub, or from a topic." - ([p] (unsub-all* p)) - ([p topic] (unsub-all* p topic))) - -;; --- map / merge ------------------------------------------------------------ - -(defn map - "Applies f to the set of first items from each source channel, then second, etc. - Closes the output channel when any source closes." - ([f chs] (map f chs nil)) - ([f chs buf-or-n] - (let [chs (vec chs) - out (chan buf-or-n) - cnt (count chs) - rets (atom (vec (repeat cnt nil))) - dchan (chan 1) - dctr (atom nil) - done (mapv (fn [i] - (fn [ret] - (swap! rets assoc i ret) - (when (zero? (swap! dctr dec)) - (put! dchan @rets)))) - (range cnt))] - (if (zero? cnt) - (close! out) - (go-loop [] - (reset! dctr cnt) - (dotimes [i cnt] - (take! (nth chs i) (nth done i))) - (let [rets (! out (apply f rets)) - (recur)))))) - out))) - -(defn merge - "Returns a channel with all values taken from the source channels chs. Closes - after all sources close." - ([chs] (merge chs nil)) - ([chs buf-or-n] - (let [out (chan buf-or-n)] - (go-loop [cs (vec chs)] - (if (pos? (count cs)) - (let [[v c] (alts! cs)] - (if (nil? v) - (recur (filterv #(not= c %) cs)) - (do (>! out v) - (recur cs)))) - (close! out))) - out))) - -;; --- deprecated channel ops (rewritten as go-loops) ------------------------- - -(defn map< - "Deprecated - use a transducer. Returns a read-side channel mapping f over ch." - [f ch] - (let [out (chan)] - (go-loop [] - (let [v (! out (f v)) (recur))))) - out)) - -(defn map> - "Deprecated - use a transducer. Returns a write-side channel mapping f into out." - [f out] - (let [in (chan)] - (go-loop [] - (let [v (! out (f v)) (recur))))) - in)) - -(defn filter< - "Deprecated - use a transducer." - ([p ch] (filter< p ch nil)) - ([p ch buf-or-n] - (let [out (chan buf-or-n)] - (go-loop [] - (let [val (! out val)) - (recur))))) - out))) - -(defn remove< - "Deprecated - use a transducer." - ([p ch] (remove< p ch nil)) - ([p ch buf-or-n] (filter< (complement p) ch buf-or-n))) - -(defn filter> - "Deprecated - use a transducer." - [p out] - (let [in (chan)] - (go-loop [] - (let [v (! out v)) - (recur))))) - in)) - -(defn remove> - "Deprecated - use a transducer." - [p out] - (filter> (complement p) out)) - -(defn- mapcat* [f in out] - (go-loop [] - (let [val (! out v)) - (recur)))))) - -(defn mapcat< - "Deprecated - use a transducer." - ([f in] (mapcat< f in nil)) - ([f in buf-or-n] - (let [out (chan buf-or-n)] - (mapcat* f in out) - out))) - -(defn mapcat> - "Deprecated - use a transducer." - ([f out] (mapcat> f out nil)) - ([f out buf-or-n] - (let [in (chan buf-or-n)] - (mapcat* f in out) - in))) - -(defn unique - "Deprecated - use a transducer. Drops consecutive duplicates." - ([ch] (unique ch nil)) - ([ch buf-or-n] - (let [out (chan buf-or-n)] - (go (loop [last nil] - (let [v (! out v) - (recur v)))))) - (close! out)) - out))) - -(defn partition - "Deprecated - use a transducer. Partitions ch into vectors of n." - ([n ch] (partition n ch nil)) - ([n ch buf-or-n] - (let [out (chan buf-or-n)] - (go-loop [arr [] idx 0] - (let [v (! out arr) (recur [] 0)))) - (do (when (> idx 0) (>! out arr)) - (close! out))))) - out))) - -(defn partition-by - "Deprecated - use a transducer. Partitions ch by runs of (f v)." - ([f ch] (partition-by f ch nil)) - ([f ch buf-or-n] - (let [out (chan buf-or-n)] - (go-loop [lst [] last ::nothing] - (let [v (! out lst) (recur [v] new-itm)))) - (do (when (> (count lst) 0) (>! out lst)) - (close! out))))) - out))) diff --git a/stdlib/clojure/core/async/lab.clj b/stdlib/clojure/core/async/lab.clj deleted file mode 100644 index b8c8890..0000000 --- a/stdlib/clojure/core/async/lab.clj +++ /dev/null @@ -1,34 +0,0 @@ -;; clojure.core.async.lab — experimental features over the channel primitives. -;; -;; multiplex/broadcast are ported as go-loops over jolt's primitives (the JVM -;; versions reify the impl handler protocol, which jolt does not expose). - -(ns clojure.core.async.lab - (:require [clojure.core.async :as async])) - -(defn multiplex - "Returns a read port that yields values from whichever of ports is ready. A - closed port is dropped; the multiplex port closes once all ports have closed." - [& ports] - (let [out (async/chan)] - (async/go-loop [cs (vec ports)] - (if (pos? (count cs)) - (let [[v c] (async/alts! cs)] - (if (nil? v) - (recur (filterv #(not= c %) cs)) - (do (async/>! out v) - (recur cs)))) - (async/close! out))) - out)) - -(defn broadcast - "Returns a write port that writes each value to all of ports. A write parks until - the value has been written to every port." - [& ports] - (let [in (async/chan)] - (async/go-loop [] - (let [v (async/! p v)) - (recur)))) - in)) diff --git a/stdlib/clojure/edn.clj b/stdlib/clojure/edn.clj index 823a6a4..e23f885 100644 --- a/stdlib/clojure/edn.clj +++ b/stdlib/clojure/edn.clj @@ -16,15 +16,7 @@ ;; Reader FORMS are detected by :jolt/type tag, never by map? — strict map? ;; (correctly) excludes tagged structs, so the old (and (map? x) ...) guard ;; would skip them. - (= :jolt/set (get x :jolt/type)) - (let [vs (map (fn [v] (edn->value opts v)) (get x :value)) - st (set vs)] - ;; duplicate literal elements are invalid edn - (when (< (count st) (count vs)) - (throw (new IllegalArgumentException - (str "Duplicate key: " (pr-str (some (fn [[k n]] (when (< 1 n) k)) - (frequencies vs))))))) - (with-meta st (edn->value opts (meta x)))) + (= :jolt/set (get x :jolt/type)) (with-meta (set (map (fn [v] (edn->value opts v)) (get x :value))) (meta x)) ;; Tagged elements: a reader from the :readers opt wins, then the built-in ;; data readers (#uuid/#inst + registered); an unknown tag falls to the ;; :default opt fn (called with tag and value, as in Clojure) or throws. @@ -38,42 +30,28 @@ custom (get (get opts :readers) tag-sym)] (cond custom (custom v) - ;; the built-in edn tags win over :default (a :readers entry can - ;; override them; an unknown-tag :default never sees #inst/#uuid) - (contains? #{'inst 'uuid 'bigdec} tag-sym) (__read-tagged tag v) ;; Clojure calls :default with the tag as a SYMBOL and the value. (get opts :default) ((get opts :default) tag-sym v) :else (__read-tagged tag v))) (map? x) - (with-meta (into {} (map (fn [e] [(edn->value opts (key e)) (edn->value opts (val e))]) x)) (edn->value opts (meta x))) - (vector? x) (with-meta (mapv (fn [v] (edn->value opts v)) x) (edn->value opts (meta x))) - ;; a constructed set: recurse into its elements too, so a tagged literal - ;; inside #{…} gets the :readers/:default treatment (aero's #ref in a set). - (set? x) (with-meta (set (map (fn [v] (edn->value opts v)) x)) (edn->value opts (meta x))) - ;; edn lists are lists (list? holds), not lazy seqs - (seq? x) (with-meta (apply list (map (fn [v] (edn->value opts v)) x)) (edn->value opts (meta x))) + (with-meta (into {} (map (fn [e] [(edn->value opts (key e)) (edn->value opts (val e))]) x)) (meta x)) + (vector? x) (with-meta (mapv (fn [v] (edn->value opts v)) x) (meta x)) + (seq? x) (with-meta (map (fn [v] (edn->value opts v)) x) (meta x)) :else x)) ;; Private helper, NOT named read-string: an unqualified (read-string …) call ;; dispatches the core read-string SPECIAL FORM (by name, regardless of ns), so ;; the 1-arity can't delegate to the 2-arity through that name. (defn- read-edn [opts s] - ;; the strict edn seam: no auto-resolved keywords, invalid tokens throw, and - ;; each #_ discard is validated through the same :readers/:default pipeline. - ;; EOF (blank/comment-only/nil input) honors :eof; an opts map WITHOUT :eof - ;; makes end-of-input an error, like the reference. - (let [v (__read-form-edn s (fn [form] (edn->value opts form) nil))] - (if (= v :jolt/reader-eof) - (if (contains? opts :eof) - (get opts :eof) - (throw (ex-info "EOF while reading" {}))) - (edn->value opts v)))) + (if (or (nil? s) (cstr/blank? s)) + (get opts :eof nil) + (edn->value opts (clojure.core/read-string s)))) (defn read-string - "Reads one object from the string s. The no-opts arity returns nil at end of - input; with an opts map, :eof sets the value returned at end of input and its - absence makes end-of-input an error." - ([s] (read-edn {:eof nil} s)) + "Reads one object from the string s. Returns the :eof option value (default + nil) for nil or blank input. opts is an options map; :eof sets the value + returned at end of input." + ([s] (read-edn {} s)) ([opts s] (read-edn opts s))) (defn- drain-reader diff --git a/stdlib/clojure/string.clj b/stdlib/clojure/string.clj index c211650..e37eb9f 100644 --- a/stdlib/clojure/string.clj +++ b/stdlib/clojure/string.clj @@ -6,32 +6,28 @@ (if (nil? s) true (= 0 (count (str-trim s))))) -;; The case fns and the searches take any Object s through its toString, like -;; the reference ((upper-case :kw) is ":KW", (capitalize 1) is "1"); nil throws -;; like calling a method on null. -(defn- to-str [s] - (if (nil? s) - (throw (new NullPointerException "s")) - (.toString s))) (defn capitalize + [s] - (let [s (to-str s)] - (if (< 1 (count s)) - (str (str-upper (subs s 0 1)) - (str-lower (subs s 1))) - (str-upper s)))) + (if (< 1 (count s)) + (str (str-upper (subs s 0 1)) + (str-lower (subs s 1))) + (str-upper s))) (defn lower-case + [s] - (str-lower (to-str s))) + (str-lower s)) (defn upper-case + [s] - (str-upper (to-str s))) + (str-upper s)) (defn includes? + [s substr] - (not (nil? (str-find substr (to-str s))))) + (not (nil? (str-find substr s)))) (defn join @@ -40,11 +36,11 @@ (defn replace [s match replacement] - (str-replace-all match replacement (to-str s))) + (str-replace-all match replacement s)) (defn replace-first [s match replacement] - (str-replace match replacement (to-str s))) + (str-replace match replacement s)) (defn reverse [s] @@ -72,18 +68,16 @@ (vec (str-split #"\r?\n" s))) (defn starts-with? + [s substr] - (when (nil? substr) (throw (new NullPointerException "substr"))) - (let [s (to-str s) - slen (count s) slen2 (count substr)] + (let [slen (count s) slen2 (count substr)] (and (>= slen slen2) (= (subs s 0 slen2) substr)))) (defn ends-with? + [s substr] - (when (nil? substr) (throw (new NullPointerException "substr"))) - (let [s (to-str s) - slen (count s) slen2 (count substr)] + (let [slen (count s) slen2 (count substr)] (and (>= slen slen2) (= (subs s (- slen slen2)) substr)))) @@ -103,8 +97,8 @@ (str-trimr s)) (defn escape + [s cmap] - (when (nil? s) (throw (new NullPointerException "s"))) (apply str (map (fn [ch] (if-let [rep (cmap ch)] rep (str ch))) @@ -113,9 +107,9 @@ (defn index-of "0-based index of the first occurrence of value in s, or nil." ([s value] - (str-find value (to-str s))) + (str-find value s)) ([s value from] - (let [idx (str-find value (subs (to-str s) from))] + (let [idx (str-find value (subs s from))] (when idx (+ from idx))))) (defn last-index-of diff --git a/stdlib/clojure/template.clj b/stdlib/clojure/template.clj index 42eac96..b3d4510 100644 --- a/stdlib/clojure/template.clj +++ b/stdlib/clojure/template.clj @@ -1,6 +1,6 @@ ;; Verbatim from clojure.template (Stuart Sierra) — pure Clojure over ;; clojure.walk, which jolt ships. Added so honeysql's :clj branch (which -;; requires clojure.template) loads. +;; requires clojure.template) loads under JOLT_FEATURES including clj. (ns clojure.template "Macros that expand to repeated copies of a template expression." (:require [clojure.walk :as walk])) diff --git a/stdlib/clojure/test.clj b/stdlib/clojure/test.clj index 17eef32..3b55eac 100644 --- a/stdlib/clojure/test.clj +++ b/stdlib/clojure/test.clj @@ -11,8 +11,7 @@ ; is a drop-in superset. (ns clojure.test - (:require [clojure.string :as str] - [clojure.template :as temp])) + (:require [clojure.string :as str])) ;; --- state ----------------------------------------------------------------- @@ -20,21 +19,15 @@ (def jolt-report counters) ;; alias used by the suite harness (def ctx-stack (atom [])) (def registry (atom [])) ;; [{:name sym :fn thunk}] -(def once-fixtures (atom {})) ;; ns-sym -> [fixture-fns] -(def each-fixtures (atom {})) ;; ns-sym -> [fixture-fns] - -;; clojure.test/*testing-vars* — the stack of vars under test. Real clojure.test -;; binds it around each test var; test.check's default reporter reads it, so a -;; defspec run through its :test metadata doesn't blow up on an unbound var. -(def ^:dynamic *testing-vars* (list)) -(def ^:dynamic *report-counters* nil) +(def once-fixtures (atom [])) +(def each-fixtures (atom [])) (defn reset-report! [] (reset! counters {:test 0 :pass 0 :fail 0 :error 0 :fails []}) (reset! ctx-stack []) (reset! registry []) - (reset! once-fixtures {}) - (reset! each-fixtures {})) + (reset! once-fixtures []) + (reset! each-fixtures [])) (defn- ctx-str [] (str/join " " @ctx-stack)) @@ -67,48 +60,6 @@ (defmulti report :type) (defmethod report :default [_m] nil) -;; do-report routes a {:type …} report map through the report multimethod — the -;; seam clojure.test assertions emit through. The built-in :pass/:fail/:error -;; methods feed jolt's counters; a library can add report types (test.check's -;; ::trial/::shrunk/::complete) and they dispatch here. -(defn- report-line [m] - (str (when (:message m) (str (:message m) - (when (or (:form m) (contains? m :expected) (contains? m :actual)) " "))) - (when (:form m) (pr-str (:form m))) - (when (contains? m :expected) (str " expected: " (pr-str (:expected m)))) - (when (contains? m :actual) (str " actual: " (pr-str (:actual m)))))) -(defmethod report :pass [_m] (inc-pass!)) -(defmethod report :fail [m] (fail! (report-line m))) -(defmethod report :error [m] (err! (report-line m))) -(defn do-report [m] (report m)) - -;; assert-expr is the macro-level extension point: `is` expands a form by calling -;; (assert-expr msg form), dispatched on the form's first symbol (or :default / -;; :always-fail). A library registers a custom assertion via -;; (defmethod assert-expr 'my-pred [msg form] ). -;; 2-arg [msg form] signature matches clojure.test. `is` routes here only for a -;; symbol with an explicitly registered method, so built-in forms are unaffected. -(defmulti assert-expr (fn [_msg form] - (cond (nil? form) :always-fail - (and (seq? form) (symbol? (first form))) (first form) - :else :default))) -(defmethod assert-expr :always-fail [msg form] - `(clojure.test/do-report {:type :fail :message ~msg :form '~form})) -(defmethod assert-expr :default [msg form] - `(try - (if ~form - (clojure.test/do-report {:type :pass}) - (clojure.test/do-report {:type :fail :message ~msg :form '~form})) - (catch Throwable e# - (clojure.test/do-report {:type :error :message ~msg :form '~form - :actual (clojure.test/err-text e#)})))) - -;; The common pure predicates whose args `is` evaluates so a failure shows the -;; actual values — (is (= expected got)) prints `got`, not just the form. A macro -;; head (not in this set) keeps the plain form-only path. -(def ^:private reported-preds - '#{= not= == < > <= >= identical? contains? instance? nil? some? empty? even? odd? pos? neg? zero?}) - ;; --- class matching for thrown? -------------------------------------------- (defn- last-seg [s] @@ -136,37 +87,21 @@ ([form] `(is ~form nil)) ([form msg] (cond - ;; a library-registered custom assertion (the assert-expr extension point) - ;; wins over every inline path, like clojure.test, where each `is` dispatches - ;; assert-expr on the exact head symbol and the built-ins are just - ;; pre-registered methods. In particular a registered alias-qualified - ;; `p/thrown?` must not be captured by the by-name thrown? path below. - (and (seq? form) (symbol? (first form)) - (contains? (methods clojure.test/assert-expr) (first form))) - (clojure.test/assert-expr msg form) - ;; (is (thrown? Class body...)) (thrown-form? form "thrown?") - (let [klass-sym (second form) - klass (name klass-sym) + (let [klass (name (second form)) body (nthrest form 2)] `(try ~@body (clojure.test/fail! (str "expected " '~form " to throw" (when ~msg (str " — " ~msg)))) (catch Throwable e# - ;; instance? honors the exception hierarchy (a literal class symbol), so - ;; (thrown? IllegalArgumentException …) matches an ArityException subclass - ;; like the JVM; class-match? is the simple-name fallback for a class jolt - ;; models only by name. - (if (or (clojure.core/instance? ~klass-sym e#) - (clojure.test/class-match? e# ~klass)) + (if (clojure.test/class-match? e# ~klass) (clojure.test/inc-pass!) (clojure.test/fail! (str "expected throw of " ~klass " but got " (clojure.core/class e#))))))) ;; (is (thrown-with-msg? Class re body...)) (thrown-form? form "thrown-with-msg?") - (let [klass-sym (second form) - klass (name klass-sym) + (let [klass (name (second form)) re (nth form 2) body (nthrest form 3)] `(try @@ -174,26 +109,10 @@ (clojure.test/fail! (str "expected " '~form " to throw")) (catch Throwable e# (let [m# (or (clojure.core/ex-message e#) (str e#))] - ;; honor the class hierarchy (ExceptionInfo IS a RuntimeException), - ;; then fall back to a simple-name match like thrown? does. - (if (and (or (clojure.core/instance? ~klass-sym e#) - (clojure.test/class-match? e# ~klass)) - (re-find ~re m#)) + (if (and (clojure.test/class-match? e# ~klass) (re-find ~re m#)) (clojure.test/inc-pass!) (clojure.test/fail! (str "expected throw of " ~klass " matching " ~re " but got " (clojure.core/class e#) ": " m#))))))) - ;; a predicate call — (= a b), (< x y), (pred? v): evaluate the args so a - ;; failure shows the actual values, like clojure.test's assert-predicate. - (and (seq? form) (contains? clojure.test/reported-preds (first form))) - `(try - (let [vs# (list ~@(rest form))] - (if (apply ~(first form) vs#) - (clojure.test/inc-pass!) - (clojure.test/fail! (str (pr-str (list '~'not (cons '~(first form) vs#))) - (when ~msg (str " — " ~msg)))))) - (catch Throwable e# - (clojure.test/err! (str (pr-str '~form) " threw: " (clojure.test/err-text e#))))) - :else `(try (if ~form @@ -212,33 +131,23 @@ (defmacro deftest [name & body] `(do (defn ~name [] ~@body) - (swap! clojure.test/registry conj {:name '~name - :ns (clojure.core/ns-name clojure.core/*ns*) - :fn ~name}) + (swap! clojure.test/registry conj {:name '~name :fn ~name}) (var ~name))) -;; Template substitution (not let-binding), so argv symbols substitute inside -;; quote and nested forms: (are [x] (special-symbol? 'x) if def) tests 'if. -(defmacro are [argv expr & args] - (if (or (and (empty? argv) (empty? args)) - (and (pos? (count argv)) - (pos? (count args)) - (zero? (mod (count args) (count argv))))) - `(clojure.template/do-template ~argv (clojure.test/is ~expr) ~@args) - (throw (IllegalArgumentException. - "The number of args doesn't match are's argv or neither are empty")))) +(defmacro are [argv expr & data] + (let [n (count argv) + rows (partition n data)] + `(do ~@(map (fn [row] + `(let [~@(interleave argv row)] + (clojure.test/is ~expr))) + rows)))) ;; --- fixtures + run -------------------------------------------------------- -;; Fixtures are per-namespace, like clojure.test (which stores them in ns -;; metadata): use-fixtures records them under the calling ns, and only that -;; ns's tests run through them — a suite loading many test namespaces into one -;; process doesn't cross-apply or clobber another ns's fixtures. (defn use-fixtures [kind & fns] - (let [n (ns-name *ns*)] - (cond - (= kind :once) (swap! once-fixtures assoc n (vec fns)) - (= kind :each) (swap! each-fixtures assoc n (vec fns))))) + (cond + (= kind :once) (reset! once-fixtures (vec fns)) + (= kind :each) (reset! each-fixtures (vec fns)))) (defn- wrap-fixtures [fixtures body-fn] (if (empty? fixtures) @@ -247,46 +156,25 @@ (defn- run-one [t] (swap! counters update :test inc) - (wrap-fixtures (get @each-fixtures (:ns t) []) + (wrap-fixtures @each-fixtures (fn [] (try ((:fn t)) (catch Throwable e (err! (str (:name t) " crashed: " (err-text e)))))))) -;; Run the registered tests grouped by namespace (registration order preserved -;; within each ns), each group wrapped in its ns's :once fixtures. ns-set nil -;; means all. -(defn- run-selected [ns-set] - (let [ts (if ns-set (filter (fn [t] (contains? ns-set (:ns t))) @registry) @registry)] - (doseq [n (distinct (map :ns ts))] - (wrap-fixtures (get @once-fixtures n []) - (fn [] (doseq [t ts :when (= n (:ns t))] (run-one t)))))) +(defn run-registered [] + (doseq [t @registry] (run-one t)) nil) -(defn run-registered [] (run-selected nil)) - -;; (run-tests 'ns1 'ns2 …) runs only those namespaces' tests, like clojure.test. -;; With no args it runs everything registered (a deliberate superset of the -;; JVM's current-ns default — jolt's harnesses load then run whole suites). -;; Prints and returns THIS call's summary; the global counters stay cumulative -;; for the n-pass/n-fail harness API. -(defn run-tests [& nses] - (let [before @counters - ns-set (when (seq nses) - (set (map (fn [n] (if (symbol? n) n (ns-name n))) nses)))] - (run-selected ns-set) - (let [r @counters - d {:type :summary - :test (- (:test r) (:test before)) - :pass (- (:pass r) (:pass before)) - :fail (- (:fail r) (:fail before)) - :error (- (:error r) (:error before))}] - (println) - (println (str "Ran " (:test d) " tests. " - (:pass d) " assertions passed, " - (:fail d) " failures, " (:error d) " errors.")) - d))) +(defn run-tests [& _nses] + (wrap-fixtures @once-fixtures (fn [] (run-registered))) + (let [r @counters] + (println) + (println (str "Ran " (:test r) " tests. " + (:pass r) " assertions passed, " + (:fail r) " failures, " (:error r) " errors.")) + r)) (defn run-test [& _] nil) (defn test-var [& _] nil) diff --git a/stdlib/clojure/walk.clj b/stdlib/clojure/walk.clj index 7a1b1f1..fb143e7 100644 --- a/stdlib/clojure/walk.clj +++ b/stdlib/clojure/walk.clj @@ -19,10 +19,7 @@ ; concat/lazy-seq) walk too — without this, postwalk-replace silently no-op'd ; a quoted list, breaking clojure.template/apply-template (list? form) (outer (with-meta (apply list (map inner form)) (meta form))) - ; doall like Clojure: walk must be eager so an `inner` with side effects - ; (rewrite-clj's #() reader bumps an arg-count atom during the walk, read right - ; after) runs now, not lazily when the result is later realized. - (seq? form) (outer (with-meta (doall (map inner form)) (meta form))) + (seq? form) (outer (with-meta (map inner form) (meta form))) :else (outer form))) (defn postwalk @@ -51,11 +48,6 @@ [smap form] (prewalk (fn [x] (if (contains? smap x) (get smap x) x)) form)) -(defn macroexpand-all - "Recursively performs all possible macroexpansions in form." - [form] - (prewalk (fn [x] (if (seq? x) (macroexpand x) x)) form)) - (defn keywordize-keys [m] (let [f (fn [[k v]] (if (string? k) [(keyword k) v] [k v]))] diff --git a/stdlib/clojure/zip.clj b/stdlib/clojure/zip.clj index af3e502..a375742 100644 --- a/stdlib/clojure/zip.clj +++ b/stdlib/clojure/zip.clj @@ -28,16 +28,6 @@ [root] (zipper vector? seq (fn [node children] (with-meta (vec children) (meta node))) root)) -(defn xml-zip - "Returns a zipper for xml elements (as from clojure.xml/parse), given a root - element" - [root] - (zipper (complement string?) - (comp seq :content) - (fn [node children] - (assoc node :content (and children (apply vector children)))) - root)) - (defn node "Returns the node at loc" [loc] (nth loc 0)) (defn branch? "Returns true if the node at loc is a branch" diff --git a/test/chez/README.md b/test/chez/README.md index 8f8b4d5..46a8a23 100644 --- a/test/chez/README.md +++ b/test/chez/README.md @@ -7,7 +7,7 @@ test` from the repo root. ## The spec corpus -`corpus.edn` is the contract: ~3570 rows `{:suite :label :expected :actual :portability}`, with +`corpus.edn` is the contract: ~2920 rows `{:suite :label :expected :actual}`, with `:expected` sourced from reference JVM Clojure by `test/conformance/regen-corpus.clj`. It is frozen (the canonical source) — add or change cases here, then re-source the answers with `regen-corpus.clj` and re-certify with `test/conformance/certify.clj`. @@ -22,7 +22,7 @@ answers with `regen-corpus.clj` and re-certify with `test/conformance/certify.cl chez --script host/chez/run-corpus.ss JOLT_CORPUS_LIMIT=200 … # every-Nth stride, fast iteration - JOLT_CHEZ_ZJ_FLOOR=N … # override the floor (see run-corpus.ss) + JOLT_CHEZ_ZJ_FLOOR=N … # override the floor (default 2678) - `run-unit.ss` — host-specific unit cases (`test/chez/unit.edn`) that aren't in the JVM-portable corpus: dot-forms, java statics, io, reader, walk, vars/namespaces, @@ -32,16 +32,6 @@ answers with `regen-corpus.clj` and re-certify with `test/conformance/certify.cl - `selfcheck.sh` — self-host fixpoint: `bootstrap.ss` rebuild byte-equals the checked-in seed (`host/chez/seed/`). - `smoke.sh` — real `bin/joltc -e` CLI smoke. -- `cts.sh` — the vendored [jank-lang/clojure-test-suite](https://github.com/jank-lang/clojure-test-suite) - (`vendor/clojure-test-suite`, a per-core-fn clojure.test suite shared across - Clojure dialects), run one namespace per `joltc` process (a hang or crash is - contained) through the `test/chez/cts-app` project and `cts-run` runner. - Per-namespace fail/error counts must exactly match the checked-in baseline - `test/chez/cts-known-failures.txt` — a namespace doing worse fails the gate, - and one doing better fails as stale until the baseline is updated in the same - change. `make cts`; - `JOLT_CTS_NS=ns1,ns2` runs a subset verbosely, - `JOLT_CTS_WRITE_BASELINE=1` regenerates the baseline. ## Other Chez tests diff --git a/test/chez/alias-leak-app/deps.edn b/test/chez/alias-leak-app/deps.edn deleted file mode 100644 index ccd9a31..0000000 --- a/test/chez/alias-leak-app/deps.edn +++ /dev/null @@ -1 +0,0 @@ -{:paths ["src"]} diff --git a/test/chez/alias-leak-app/src/fix/lib.clj b/test/chez/alias-leak-app/src/fix/lib.clj deleted file mode 100644 index 17a8208..0000000 --- a/test/chez/alias-leak-app/src/fix/lib.clj +++ /dev/null @@ -1,3 +0,0 @@ -(ns fix.lib - (:require [clojure.set :as ss])) -(defn u [] (ss/union #{1} #{2})) diff --git a/test/chez/alias-leak-app/src/fix/main.clj b/test/chez/alias-leak-app/src/fix/main.clj deleted file mode 100644 index 9bf744b..0000000 --- a/test/chez/alias-leak-app/src/fix/main.clj +++ /dev/null @@ -1,5 +0,0 @@ -(ns fix.main - (:require [clojure.string :as ss] - [fix.lib :as lib])) -(defn -main [& _] - (println (ss/upper-case "hi") (lib/u))) diff --git a/test/chez/build-app/src/app/core.clj b/test/chez/build-app/src/app/core.clj index f9f0f34..4914552 100644 --- a/test/chez/build-app/src/app/core.clj +++ b/test/chez/build-app/src/app/core.clj @@ -12,10 +12,6 @@ (defmethod greet :soft [_] "greet:soft") (defn -main [& args] - ;; --boom: throw through a two-deep call chain so build-smoke can assert the - ;; native stack trace. Off the normal path, so default output is unchanged. - (when (= (first args) "--boom") - (util/mid-boom "not-a-number")) ;; the resource is baked into the binary (deps.edn :jolt/build :embed), so this ;; resolves with no resources/ dir on disk, run from any cwd. (println (slurp (io/resource "greeting.txt"))) diff --git a/test/chez/build-app/src/app/util.clj b/test/chez/build-app/src/app/util.clj index ff524cb..589ebd4 100644 --- a/test/chez/build-app/src/app/util.clj +++ b/test/chez/build-app/src/app/util.clj @@ -4,19 +4,6 @@ (defn shout [s] (str/upper-case (str s "!"))) -;; A two-deep non-tail call chain that throws — exercises native stack traces in a -;; direct-link build (build-smoke runs -main with a --boom sentinel arg). deep-boom -;; is defined through a USER macro: its source registration only gets a real line -;; if the reader position survives macroexpansion (so the trace frame maps). -(defmacro defguarded [name args & body] - `(defn ~name ~args (assert (number? ~(first args)) "needs a number") ~@body)) - -(defguarded deep-boom [x] - (* x 2)) - -(defn mid-boom [x] - (inc (deep-boom x))) - (defmacro twice [x] `(do ~x ~x)) diff --git a/test/chez/clojure-test.clj b/test/chez/clojure-test.clj deleted file mode 100644 index a323dc9..0000000 --- a/test/chez/clojure-test.clj +++ /dev/null @@ -1,69 +0,0 @@ -;; Self-checking regression for clojure.test: the assert-expr / do-report / report -;; extension points plus the built-in is/are/testing/thrown?/use-fixtures surface. -;; Run via bin/joltc; prints a single sentinel line the smoke gate greps for. -(ns clojure-test-selfcheck - (:require [clojure.test :as t :refer [deftest is are testing use-fixtures run-tests]])) - -;; a library-style custom assertion registered through the assert-expr seam -(defmethod t/assert-expr 'near? [msg form] - (let [[_ a b] form] - `(if (< (let [d# (- ~a ~b)] (if (neg? d#) (- d#) d#)) 0.01) - (clojure.test/do-report {:type :pass}) - (clojure.test/do-report {:type :fail :message ~msg :form '~form})))) - -;; an ALIAS-QUALIFIED registered assertion whose simple name collides with the -;; built-in thrown? — the registered method must win over the by-name inline -;; path (clojure-test-suite's portability/thrown? registers exactly this shape). -(defmethod t/assert-expr 'p/thrown? [msg form] - `(try - (do ~@(rest form)) - (clojure.test/do-report {:type :fail :message ~msg :form '~form}) - (catch Throwable e# - (clojure.test/do-report {:type :pass}) - e#))) - -;; a custom report type (how test.check surfaces trial/shrink progress) -(def trials (atom 0)) -(defmethod t/report ::trial [_m] (swap! trials inc)) - -(def setups (atom 0)) -(use-fixtures :each (fn [f] (swap! setups inc) (f))) - -(deftest builtins - (testing "equality + predicate" - (is (= 1 1)) - (is (vector? [1]))) - (are [x y] (= x y) - 2 (+ 1 1) - 6 (* 2 3)) - ;; template vars substitute inside quote (are is clojure.template, not let) - (are [x] (special-symbol? 'x) - if - def) - (is (thrown? clojure.lang.ExceptionInfo (throw (ex-info "x" {})))) - (is (thrown-with-msg? Exception #"bad" (throw (ex-info "bad" {})))) - (is (near? 1.0 1.005)) - (is (p/thrown? (throw (ex-info "boom" {}))))) - -(deftest expected-fail - (is (= 1 2)) - (is (near? 1.0 5.0))) - -;; run-tests returns THIS call's summary; with explicit nses it runs only their -;; tests (an unknown ns runs nothing). -(def r1 (run-tests)) -(def r2 (run-tests 'no.such.test-ns)) -(t/do-report {:type ::trial}) -(t/do-report {:type ::trial}) - -;; 10 pass (= + vector? + 4 are rows + thrown? + thrown-with-msg? + near? + p/thrown?), -;; 2 fail (= 1 2, near? 1.0 5.0), 0 error, 2 fixture runs, 2 custom reports -(let [ok (and (= (t/n-pass) 10) (= (t/n-fail) 2) (= (t/n-error) 0) - (= 2 (:test r1)) (= 10 (:pass r1)) (= 2 (:fail r1)) - (= 0 (:test r2)) (= 0 (:pass r2)) - (= @setups 2) (= @trials 2))] - (println (if ok - "CLOJURE-TEST OK" - (str "CLOJURE-TEST FAIL pass=" (t/n-pass) " fail=" (t/n-fail) - " error=" (t/n-error) " r1=" (pr-str r1) " r2=" (pr-str r2) - " setups=" @setups " trials=" @trials)))) diff --git a/test/chez/corpus.edn b/test/chez/corpus.edn index c4117b4..f6e8dc4 100644 --- a/test/chez/corpus.edn +++ b/test/chez/corpus.edn @@ -1,3587 +1,3106 @@ [ - {:suite "host-interop / reify ILookup" :label "(get reify k) / (:k reify) / (get reify k d) route to valAt" :expected "[1 1 :dflt]" :actual "(let [r (reify clojure.lang.ILookup (valAt [_ k] (get {:a 1} k)) (valAt [_ k d] (get {:a 1} k d)))] [(:a r) (get r :a) (get r :z :dflt)])" :portability :jvm} - {:suite "regex / alternation submatch" :label "a non-participating alternation group is nil, not a stale capture" :expected "[\"2r11\" nil \"2\" \"11\"]" :actual "(re-matches #\"(?:([0-9])|([0-9])r([0-9]+))\" \"2r11\")" :portability :common} - {:suite "regex / radix read" :label "tools.reader-style radix parse: winning branch's groups, not the losing one's" :expected "[12 255]" :actual "[(read-string \"2r1100\") (read-string \"16rFF\")]" :portability :common} - {:suite "numbers / comparison error class" :label "nil operand is NPE, non-number is CCE" :expected "[\"java.lang.NullPointerException\" \"java.lang.ClassCastException\"]" :actual "[(try (> nil 5) (catch Throwable e (.getName (class e)))) (try (> :k 5) (catch Throwable e (.getName (class e))))]" :portability :jvm} - {:suite "reader / quoted #inst constructs a value" :label "a quoted #inst literal is the constructed Date, not a tagged form" :expected "\"(f #inst \\\"1939-01-01T00:00:00.000-00:00\\\")\"" :actual "(pr-str (quote (f #inst \"1939\")))" :portability :common} - {:suite "fn / kwargs trailing map" :label "(f :k v {map}) and (f {map}) both bind & {:as m}" :expected "[{:x 1 :y 2} {:x 1 :y 2}]" :actual "[((fn [a & {:as m}] m) 1 :x 1 {:y 2}) ((fn [a & {:as m}] m) 1 {:x 1 :y 2})]" :portability :common} - {:suite "destructure / :or" :label "map default when key absent" :expected "9" :actual "(let [{x :x :or {x 9}} {}] x)" :portability :common} - {:suite "destructure / :or" :label "kwargs default when key absent" :expected "9" :actual "((fn [& {x :x :or {x 9}}] x))" :portability :common} - {:suite "destructure / :or" :label "default not used when key present" :expected "5" :actual "(let [{x :x :or {x 9}} {:x 5}] x)" :portability :common} - {:suite "destructure / for :let" :label "a for/doseq :let binding may itself destructure" :expected "[10 20]" :actual "(vec (for [x [1 2] :let [{:keys [y]} {:y (* x 10)}]] y))" :portability :common} - {:suite "deftype / method param shadows field" :label "a method param named like a field shadows it (Clojure scope)" :expected "9" :actual "(do (defprotocol P (setm [this q])) (defrecord R [k m] P (setm [this m] (assoc this :m m))) (:m (setm (->R 1 nil) 9)))" :portability :common} - {:suite "walk / eager" :label "clojure.walk is eager over a lazy seq (side effects run now)" :expected "3" :actual "(let [a (atom 0)] (clojure.walk/postwalk (fn [x] (when (number? x) (swap! a inc)) x) (map inc (list 1 2 3))) @a)" :portability :common} - {:suite "chars / isWhitespace" :label "Character/isWhitespace matches the JVM (Unicode line-sep yes, no-break space no)" :expected "[true true false false]" :actual "(mapv (fn [c] (Character/isWhitespace (char c))) [0x2028 32 0x00A0 65])" :portability :jvm} - {:suite "deftype / field access" :label ".field reads a deftype field" :expected "7" :actual "(do (deftype FldT [q]) (.q (->FldT 7)))" :portability :jvm} - {:suite "fn / pre-post" :label ":pre + :post pass" :expected "5" :actual "(do (defn ppf [x] {:pre [(pos? x)] :post [(= % x)]} x) (ppf 5))" :portability :common} - {:suite "fn / pre-post" :label ":pre failure throws" :expected ":blocked" :actual "(do (defn ppg [x] {:pre [(pos? x)]} x) (try (ppg -1) (catch Throwable _ :blocked)))" :portability :common} - {:suite "deftype / map-like dispatch" :label "dissoc + keys via IPersistentMap/Seqable methods" :expected "[:b]" :actual "(do (deftype MapT [m] clojure.lang.Seqable (seq [_] (seq m)) clojure.lang.IPersistentMap (without [_ k] (->MapT (dissoc m k))) (assoc [_ k v] (->MapT (assoc m k v)))) (vec (keys (dissoc (->MapT {:a 1 :b 2}) :a))))" :portability :jvm} - {:suite "delay / exception memoization" :label "throwing body runs once, stays realized, re-throws" :expected "[1 true]" :actual "(let [n (atom 0) d (delay (swap! n inc) (throw (ex-info \"e\" {})))] (dotimes [_ 3] (try (deref d) (catch Throwable _ nil))) [(deref n) (realized? d)])" :portability :common} - {:suite "queue / pop" :label "pop of empty PersistentQueue returns empty" :expected "nil" :actual "(seq (pop clojure.lang.PersistentQueue/EMPTY))" :portability :jvm} - {:suite "interop / iterator-seq" :label "iterator-seq over .iterator" :expected "[:a :b]" :actual "(vec (iterator-seq (.iterator [:a :b])))" :portability :jvm} - {:suite "deftype / IPersistentStack" :label "peek/pop dispatch" :expected "[1 [2 3]]" :actual "(do (deftype Stk [v] clojure.lang.IPersistentStack (peek [_] (first v)) (pop [_] (->Stk (rest v)))) [(peek (->Stk [1 2 3])) (vec (.v (pop (->Stk [1 2 3]))))])" :portability :jvm} - {:suite "deftype / equiv" :label "(= deftype other) uses equiv method" :expected "true" :actual "(do (deftype EqT [m] clojure.lang.IPersistentCollection (equiv [_ o] (= o m)) clojure.lang.Seqable (seq [_] (seq m))) (= (->EqT {:a 1}) {:a 1}))" :portability :jvm} - {:suite "deftype / IDeref" :label "@ dispatches to the deref method" :expected "7" :actual "(do (deftype Box [v] clojure.lang.IDeref (deref [_] v)) (deref (->Box 7)))" :portability :jvm} - {:suite "reify / IDeref" :label "@ dispatches to the deref method" :expected "7" :actual "(deref (reify clojure.lang.IDeref (deref [_] 7)))" :portability :jvm} - {:suite "deftype / mutable field" :label "set! is observed by a later read in the same method" :expected "9" :actual "(do (deftype B [^:unsynchronized-mutable v] clojure.lang.IDeref (deref [_] (set! v 9) v)) (deref (->B 0)))" :portability :jvm} - {:suite "def / metadata evaluation" :label "a symbol metadata value evaluates to its var" :expected "true" :actual "(do (def ^{:af rest} mv 1) (fn? (:af (meta (var mv)))))" :portability :common} - {:suite "def / metadata evaluation" :label "an expression metadata value is evaluated" :expected "3" :actual "(do (def ^{:k (+ 1 2)} mv2 1) (:k (meta (var mv2))))" :portability :common} - {:suite "interop / class ancestry" :label "(ancestors (class fn)) includes a callable interface" :expected "true" :actual "(boolean (some #{java.lang.Runnable java.util.concurrent.Callable} (ancestors (class identity))))" :portability :jvm} - {:suite "interop / AssertionError" :label "construct + catch as Throwable" :expected "\"boom\"" :actual "(try (throw (AssertionError. \"boom\")) (catch Throwable e (.getMessage e)))" :portability :jvm} - {:suite "try / multi-catch" :label "dispatches to the matching class clause, not the first" :expected ":rte" :actual "(try (throw (RuntimeException. \"x\")) (catch NullPointerException _ :npe) (catch RuntimeException _ :rte) (catch Exception _ :exc))" :portability :jvm} - {:suite "try / multi-catch" :label "Error is not caught by an Exception clause" :expected ":thr" :actual "(try (throw (Error. \"e\")) (catch Exception _ :exc) (catch Throwable _ :thr))" :portability :jvm} - {:suite "try / multi-catch" :label "no matching clause re-throws to an outer catch" :expected ":outer" :actual "(try (try (throw (RuntimeException. \"x\")) (catch NullPointerException _ :npe)) (catch Exception _ :outer))" :portability :jvm} - {:suite "try / multi-catch" :label "a host condition is caught by its RuntimeException subclass" :expected ":arith" :actual "(try (/ 1 0) (catch ArithmeticException _ :arith) (catch Throwable _ :other))" :portability :common} - {:suite "locking" :label "returns the body value" :expected "42" :actual "(let [o (Object.)] (locking o 42))" :portability :common} - {:suite "locking" :label "reentrant on the same object" :expected "42" :actual "(let [o (Object.)] (locking o (locking o 42)))" :portability :common} - {:suite "defn / docstring" :label "leading docstring becomes :doc metadata" :expected "\"the docs\"" :actual "(do (defn dd \"the docs\" [x] x) (:doc (meta (var dd))))" :portability :common} - {:suite "assert" :label "failed assert throws AssertionError" :expected ":ae" :actual "(try (assert false) (catch AssertionError _ :ae))" :portability :common} - {:suite "fn / pre-post" :label ":pre failure throws AssertionError" :expected ":caught" :actual "(do (defn pp [x] {:pre [(pos? x)]} x) (try (pp -1) (catch AssertionError _ :caught)))" :portability :common} - {:suite "interop / Seqable" :label "a vector is Seqable but not an ISeq" :expected "[true false]" :actual "[(instance? clojure.lang.Seqable [1 2 3]) (instance? clojure.lang.ISeq [1 2 3])]" :portability :jvm} - {:suite "interop / Seqable" :label "a map is Seqable" :expected "true" :actual "(instance? clojure.lang.Seqable {:a 1})" :portability :jvm} - {:suite "extend-protocol / class value" :label "extend to (Class/forName \"[B\") dispatches a byte-array" :expected "[:ba :str]" :actual "(do (defprotocol P (m [x])) (extend-protocol P (Class/forName \"[B\") (m [bs] :ba) String (m [s] :str)) [(m (byte-array 1)) (m \"x\")])" :portability :jvm} - {:suite "interop / ByteBuffer" :label "wrap then remaining + array" :expected "[3 [1 2 3]]" :actual "(let [bb (java.nio.ByteBuffer/wrap (byte-array [1 2 3]))] [(.remaining bb) (vec (.array bb))])" :portability :jvm} - {:suite "interop / ByteBuffer" :label "get drains into a byte-array" :expected "[1 2]" :actual "(let [bb (java.nio.ByteBuffer/wrap (byte-array [1 2])) d (byte-array 2)] (.get bb d) (vec d))" :portability :jvm} - {:suite "interop / Arrays" :label "equals on byte arrays" :expected "true" :actual "(java.util.Arrays/equals (byte-array [1 2 3]) (byte-array [1 2 3]))" :portability :jvm} - {:suite "interop / Arrays" :label "equals on unequal byte arrays" :expected "false" :actual "(java.util.Arrays/equals (byte-array [1 2]) (byte-array [1 9]))" :portability :jvm} - {:suite "interop / URI" :label "URI/create static factory" :expected "\"x.com\"" :actual "(.getHost (java.net.URI/create \"http://x.com/p\"))" :portability :jvm} - {:suite "interop / Thread" :label "start + join runs the thunk" :expected "7" :actual "(let [a (atom 0) t (Thread. (fn [] (reset! a 7)))] (.start t) (.join t) (deref a))" :portability :jvm} - {:suite "interop / CountDownLatch" :label "countDown to zero, await returns" :expected "0" :actual "(let [l (java.util.concurrent.CountDownLatch. 1)] (.countDown l) (.await l) (.getCount l))" :portability :jvm} - {:suite "interop / SoftReference" :label "get returns the referent" :expected ":v" :actual "(.get (java.lang.ref.SoftReference. :v))" :portability :jvm} - {:suite "interop / System.gc" :label "gc runs and returns" :expected "42" :actual "(do (System/gc) 42)" :portability :jvm} - {:suite "interop / ConcurrentHashMap" :label "put + get/count/contains?" :expected "[1 1 true]" :actual "(let [m (java.util.concurrent.ConcurrentHashMap.)] (.put m :a 1) [(get m :a) (count m) (contains? m :a)])" :portability :jvm} - {:suite "interop / Class.forName" :label "unknown class throws ClassNotFoundException" :expected ":nf" :actual "(try (Class/forName \"no.such.Klass\") (catch ClassNotFoundException _ :nf))" :portability :jvm} - {:suite "interop / Class.forName" :label "known class resolves" :expected "\"java.lang.String\"" :actual "(.getName (Class/forName \"java.lang.String\"))" :portability :jvm} - {:suite "clojure.string / replace" :label "char match and replacement" :expected "\"a-b-c\"" :actual "(clojure.string/replace \"a/b/c\" \\/ \\-)" :portability :common} - {:suite "clojure.string / replace" :label "char match, string replacement" :expected "\"x_y\"" :actual "(clojure.string/replace \"x.y\" \\. \"_\")" :portability :common} - {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^ type hint on a param" :expected "\"x\"" :actual "(do (defn f1 [#^String s] s) (f1 \"x\"))" :portability :common} - {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^\"[B\" array hint" :expected "[1 2]" :actual "(do (defn f2 [#^\"[B\" b] b) (f2 [1 2]))" :portability :common} - {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^ is equivalent to ^" :expected "true" :actual "(= (meta (with-meta [] {:tag (quote String)})) {:tag (quote String)})" :portability :common} - {:suite "interop-fixes / (str pattern) yields raw source" :label "str of a regex" :expected "\"abc\"" :actual "(str #\"abc\")" :portability :common} - {:suite "interop-fixes / (str pattern) yields raw source" :label "compose patterns via str" :expected "true" :actual "(boolean (re-matches (re-pattern (str #\"<\" \"(.*)\" \">\")) \"\"))" :portability :common} - {:suite "interop-fixes / into onto a map" :label "merges map items" :expected "true" :actual "(= {:a 1 :b 2} (into {} [{:a 1} {:b 2}]))" :portability :common} - {:suite "interop-fixes / into onto a map" :label "accepts [k v] pairs" :expected "true" :actual "(= {:a 1} (into {} [[:a 1]]))" :portability :common} - {:suite "interop-fixes / into onto a map" :label "map item onto empty {}" :expected "true" :actual "(= {:x 1} (into {} (list {:x 1})))" :portability :common} - {:suite "interop-fixes / into onto a map" :label "conj a map onto {}" :expected "true" :actual "(= {:a 1} (conj {} {:a 1}))" :portability :common} - {:suite "interop-fixes / a var is callable as its value" :label "call a var directly" :expected "42" :actual "(do (def vf (fn [x] (inc x))) ((var vf) 41))" :portability :common} - {:suite "interop-fixes / a var is callable as its value" :label "var bound as a client fn" :expected "\"ok\"" :actual "(do (def base (fn [_] \"ok\")) (def mw (fn [client] (fn [req] (client req)))) ((mw (var base)) {}))" :portability :common} - {:suite "control / conditionals" :label "if true" :expected "1" :actual "(if true 1 2)" :portability :common} - {:suite "control / conditionals" :label "if false" :expected "2" :actual "(if false 1 2)" :portability :common} - {:suite "control / conditionals" :label "if nil is false" :expected "2" :actual "(if nil 1 2)" :portability :common} - {:suite "control / conditionals" :label "if no else" :expected "nil" :actual "(if false 1)" :portability :common} - {:suite "control / conditionals" :label "when true" :expected "3" :actual "(when true 1 2 3)" :portability :common} - {:suite "control / conditionals" :label "when false" :expected "nil" :actual "(when false 1)" :portability :common} - {:suite "control / conditionals" :label "when-not" :expected "1" :actual "(when-not false 1)" :portability :common} - {:suite "control / conditionals" :label "cond" :expected ":b" :actual "(cond false :a true :b :else :c)" :portability :common} - {:suite "control / conditionals" :label "cond :else" :expected ":c" :actual "(cond false :a false :b :else :c)" :portability :common} - {:suite "control / conditionals" :label "cond no match" :expected "nil" :actual "(cond false :a)" :portability :common} - {:suite "control / conditionals" :label "condp" :expected "\"two\"" :actual "(condp = 2 1 \"one\" 2 \"two\" \"other\")" :portability :common} - {:suite "control / conditionals" :label "case" :expected ":b" :actual "(case 2 1 :a 2 :b :default)" :portability :common} - {:suite "control / conditionals" :label "case default" :expected ":d" :actual "(case 9 1 :a 2 :b :d)" :portability :common} - {:suite "control / conditionals" :label "case multi" :expected ":ab" :actual "(case 2 (1 2) :ab 3 :c)" :portability :common} - {:suite "control / conditionals" :label "case symbol const" :expected ":s" :actual "(case 'foo foo :s :default)" :portability :common} - {:suite "control / conditionals" :label "case vector const" :expected ":v" :actual "(case [1 2] [1 2] :v :default)" :portability :common} - {:suite "control / conditionals" :label "case map const" :expected ":m" :actual "(case {:a 1} {:a 1} :m :default)" :portability :common} - {:suite "control / conditionals" :label "case list const" :expected ":l" :actual "(case '(a b) (quote (a b)) :l :default)" :portability :common} - {:suite "control / conditionals" :label "case keyword" :expected ":k" :actual "(case :x :x :k :default)" :portability :common} - {:suite "control / logic" :label "and all true" :expected "3" :actual "(and 1 2 3)" :portability :common} - {:suite "control / logic" :label "and short circuits" :expected "nil" :actual "(and 1 nil 3)" :portability :common} - {:suite "control / logic" :label "and empty" :expected "true" :actual "(and)" :portability :common} - {:suite "control / logic" :label "or first truthy" :expected "1" :actual "(or nil 1 2)" :portability :common} - {:suite "control / logic" :label "or all false" :expected "false" :actual "(or nil false)" :portability :common} - {:suite "control / logic" :label "or empty" :expected "nil" :actual "(or)" :portability :common} - {:suite "control / logic" :label "not" :expected "false" :actual "(not true)" :portability :common} - {:suite "control / let & loop" :label "let" :expected "3" :actual "(let [a 1 b 2] (+ a b))" :portability :common} - {:suite "control / let & loop" :label "let sequential" :expected "3" :actual "(let [a 1 b (+ a 2)] b)" :portability :common} - {:suite "control / let & loop" :label "let shadowing" :expected "2" :actual "(let [a 1] (let [a 2] a))" :portability :common} - {:suite "control / let & loop" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] (ev? 10))" :portability :common} - {:suite "control / let & loop" :label "loop/recur" :expected "15" :actual "(loop [i 1 acc 0] (if (> i 5) acc (recur (inc i) (+ acc i))))" :portability :common} - {:suite "control / let & loop" :label "when-let" :expected "2" :actual "(when-let [x 1] (inc x))" :portability :common} - {:suite "control / let & loop" :label "when-let nil" :expected "nil" :actual "(when-let [x nil] (inc x))" :portability :common} - {:suite "control / let & loop" :label "if-let" :expected "2" :actual "(if-let [x 1] (inc x) :none)" :portability :common} - {:suite "control / let & loop" :label "if-let else" :expected ":none" :actual "(if-let [x nil] (inc x) :none)" :portability :common} - {:suite "control / let & loop" :label "if-some zero" :expected "1" :actual "(if-some [x 0] (inc x) :none)" :portability :common} - {:suite "control / let & loop" :label "when-some nil" :expected "nil" :actual "(when-some [x nil] x)" :portability :common} - {:suite "control / conditional-binding scope" :label "if-let else sees outer" :expected "5" :actual "(let [x 5] (if-let [x nil] :then x))" :portability :common} - {:suite "control / conditional-binding scope" :label "if-let then binds" :expected "7" :actual "(let [x 5] (if-let [x 7] x :else))" :portability :common} - {:suite "control / conditional-binding scope" :label "if-some else sees outer" :expected "5" :actual "(let [x 5] (if-some [x nil] :then x))" :portability :common} - {:suite "control / conditional-binding scope" :label "if-some binds false" :expected "false" :actual "(if-some [x false] x :else)" :portability :common} - {:suite "control / conditional-binding scope" :label "when-let else via or" :expected "5" :actual "(let [x 5] (or (when-let [x nil] x) x))" :portability :common} - {:suite "control / conditional-binding scope" :label "when-let multi-form body" :expected "14" :actual "(when-let [x 7] (inc x) (* x 2))" :portability :common} - {:suite "control / conditional-binding scope" :label "if-let in fn param" :expected "9" :actual "((fn [xs] (if-let [xs nil] :then xs)) 9)" :portability :common} - {:suite "control / conditional-binding scope" :label "when-some binds zero" :expected "1" :actual "(when-some [x 0] (inc x))" :portability :common} - {:suite "control / conditional-binding scope" :label "if-let evals test once" :expected "1" :actual "(let [c (atom 0)] (if-let [v (do (swap! c inc) :v)] @c :none))" :portability :common} - {:suite "control / loop lowering" :label "closure captures per-iter binding" :expected "[0 1 2]" :actual "(mapv (fn [g] (g)) (loop [i 0 fs []] (if (< i 3) (recur (inc i) (conj fs (fn [] i))) fs)))" :portability :common} - {:suite "control / loop lowering" :label "fib via loop" :expected "55" :actual "(loop [a 0 b 1 i 0] (if (= i 10) a (recur b (+ a b) (inc i))))" :portability :common} - {:suite "control / loop lowering" :label "recur args no clobber" :expected "[2 1]" :actual "(loop [a 1 b 2 n 0] (if (= n 1) [a b] (recur b a (inc n))))" :portability :common} - {:suite "control / loop lowering" :label "nested loops" :expected "9" :actual "(loop [i 0 s 0] (if (= i 3) s (recur (inc i) (loop [j 0 t s] (if (= j 3) t (recur (inc j) (inc t)))))))" :portability :common} - {:suite "control / loop lowering" :label "loop sequential init" :expected "12" :actual "(loop [a 1 b (+ a 10)] (+ a b))" :portability :common} - {:suite "control / loop lowering" :label "recur through let" :expected "6" :actual "(loop [i 0 acc 0] (let [x (* i 2)] (if (< i 3) (recur (inc i) (+ acc x)) acc)))" :portability :common} - {:suite "control / loop lowering" :label "fn-arity recur intact" :expected "15" :actual "((fn f [n acc] (if (zero? n) acc (recur (dec n) (+ acc n)))) 5 0)" :portability :common} - {:suite "control / iteration" :label "dotimes side-effect" :expected "5" :actual "(let [a (atom 0)] (dotimes [i 5] (swap! a inc)) @a)" :portability :common} - {:suite "control / iteration" :label "while" :expected "5" :actual "(let [a (atom 0)] (while (< @a 5) (swap! a inc)) @a)" :portability :common} - {:suite "control / iteration" :label "for" :expected "[0 1 2]" :actual "(for [x (range 3)] x)" :portability :common} - {:suite "control / iteration" :label "for nested" :expected "[[0 :a] [0 :b] [1 :a] [1 :b]]" :actual "(for [x (range 2) y [:a :b]] [x y])" :portability :common} - {:suite "control / iteration" :label "for :when" :expected "[0 2 4]" :actual "(for [x (range 6) :when (even? x)] x)" :portability :common} - {:suite "control / iteration" :label "for :while" :expected "[0 1 2]" :actual "(for [x (range 10) :while (< x 3)] x)" :portability :common} - {:suite "control / iteration" :label "for :let" :expected "[0 1 4]" :actual "(for [x (range 3) :let [sq (* x x)]] sq)" :portability :common} - {:suite "control / iteration" :label "for :let+:when" :expected "[4 6 8]" :actual "(for [x (range 5) :let [y (* x 2)] :when (> y 3)] y)" :portability :common} - {:suite "control / iteration" :label "for multi :when" :expected "[[1 :a] [1 :b]]" :actual "(for [x [0 1] :when (odd? x) y [:a :b]] [x y])" :portability :common} - {:suite "control / iteration" :label "for destructure" :expected "[3 7]" :actual "(for [[a b] [[1 2] [3 4]]] (+ a b))" :portability :common} - {:suite "control / iteration" :label "doseq side-effect" :expected "6" :actual "(let [a (atom 0)] (doseq [x [1 2 3]] (swap! a (fn [v] (+ v x)))) @a)" :portability :common} - {:suite "control / iteration" :label "doseq nested" :expected "4" :actual "(let [c (atom 0)] (doseq [x [1 2] y [10 20]] (swap! c inc)) @c)" :portability :common} - {:suite "control / iteration" :label "doseq :when" :expected "[1 3]" :actual "(let [a (atom [])] (doseq [x [1 2 3] :when (odd? x)] (swap! a conj x)) @a)" :portability :common} - {:suite "control / iteration" :label "doseq :while" :expected "6" :actual "(let [a (atom 0)] (doseq [x (range 10) :while (< x 4)] (swap! a + x)) @a)" :portability :common} - {:suite "control / iteration" :label "doseq :let" :expected "[0 1 4]" :actual "(let [a (atom [])] (doseq [x (range 3) :let [sq (* x x)]] (swap! a conj sq)) @a)" :portability :common} - {:suite "control / iteration" :label "doseq returns nil" :expected "nil" :actual "(doseq [x [1 2 3]] x)" :portability :common} - {:suite "control / threading" :label "->" :expected "6" :actual "(-> 1 inc (+ 4))" :portability :common} - {:suite "control / threading" :label "-> with forms" :expected "[1 2 3]" :actual "(-> [] (conj 1) (conj 2) (conj 3))" :portability :common} - {:suite "control / threading" :label "->>" :expected "9" :actual "(->> [1 2 3] (map inc) (reduce +))" :portability :common} - {:suite "control / threading" :label "as->" :expected "2" :actual "(as-> [0 1] x (map inc x) (reverse x) (first x))" :portability :common} - {:suite "control / threading" :label "some->" :expected "2" :actual "(some-> 1 inc)" :portability :common} - {:suite "control / threading" :label "some-> nil stops" :expected "nil" :actual "(some-> nil inc)" :portability :common} - {:suite "control / threading" :label "some->>" :expected "[2 3]" :actual "(some->> [1 2] (map inc))" :portability :common} - {:suite "control / threading" :label "cond->" :expected "2" :actual "(cond-> 1 true inc false inc)" :portability :common} - {:suite "control / threading" :label "cond->>" :expected "[1 2]" :actual "(cond->> [2] true (cons 1))" :portability :common} - {:suite "control / threading" :label "doto returns subject" :expected "5" :actual "(let [a (doto (atom 0) (reset! 5))] @a)" :portability :common} - {:suite "deftype / custom toString" :label ".toString uses the method" :expected "\"hi\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (.toString (->Foo \"hi\")))" :portability :jvm} - {:suite "deftype / custom toString" :label "str uses the method" :expected "\"hi\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (str (->Foo \"hi\")))" :portability :common} - {:suite "deftype / custom toString" :label "str concatenation uses it" :expected "\"\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (str \"<\" (->Foo \"hi\") \">\"))" :portability :common} - {:suite "deftype / custom toString" :label "computed toString" :expected "\"v=7\"" :actual "(do (deftype Boxed [v] Object (toString [_] (str \"v=\" v))) (str (->Boxed 7)))" :portability :common} - {:suite "deftype / custom toString" :label "defrecord without toString keeps repr" :expected "true" :actual "(do (defrecord Bar [x]) (boolean (re-find #\"Bar\" (str (->Bar 1)))))" :portability :common} - {:suite "deftype / custom toString" :label "pr-str of a defrecord is the repr" :expected "true" :actual "(do (defrecord Baz [x]) (boolean (re-find #\"\\{\" (pr-str (->Baz 1)))))" :portability :common} - {:suite "destructure / sequential" :label "basic vector" :expected "3" :actual "(let [[a b] [1 2]] (+ a b))" :portability :common} - {:suite "destructure / sequential" :label "skip with _" :expected "3" :actual "(let [[_ b] [1 2]] (+ b 1))" :portability :common} - {:suite "destructure / sequential" :label "rest with &" :expected "[3 4]" :actual "(let [[a & more] [1 3 4]] more)" :portability :common} - {:suite "destructure / sequential" :label ":as whole" :expected "[1 2]" :actual "(let [[a :as v] [1 2]] v)" :portability :common} - {:suite "destructure / sequential" :label "nested" :expected "3" :actual "(let [[[a b]] [[1 2]]] (+ a b))" :portability :common} - {:suite "destructure / sequential" :label "fewer values nil" :expected "nil" :actual "(let [[a b c] [1 2]] c)" :portability :common} - {:suite "destructure / sequential" :label "over a list" :expected "1" :actual "(let [[a] (list 1 2)] a)" :portability :common} - {:suite "destructure / sequential" :label "over a seq" :expected "2" :actual "(let [[a b] (rest [9 1 2])] b)" :portability :common} - {:suite "destructure / sequential" :label "string chars" :expected "\\a" :actual "(let [[a] (seq \"ab\")] a)" :portability :common} - {:suite "destructure / associative" :label "keys" :expected "3" :actual "(let [{:keys [a b]} {:a 1 :b 2}] (+ a b))" :portability :common} - {:suite "destructure / associative" :label ":as map" :expected "{:a 1}" :actual "(let [{:as m} {:a 1}] m)" :portability :common} - {:suite "destructure / associative" :label ":or default" :expected "9" :actual "(let [{:keys [a] :or {a 9}} {}] a)" :portability :common} - {:suite "destructure / associative" :label ":or present" :expected "1" :actual "(let [{:keys [a] :or {a 9}} {:a 1}] a)" :portability :common} - {:suite "destructure / associative" :label "explicit binding" :expected "1" :actual "(let [{x :a} {:a 1}] x)" :portability :common} - {:suite "destructure / associative" :label "nested map" :expected "2" :actual "(let [{{b :b} :a} {:a {:b 2}}] b)" :portability :common} - {:suite "destructure / associative" :label "keys + as" :expected "[1 {:a 1}]" :actual "(let [{:keys [a] :as m} {:a 1}] [a m])" :portability :common} - {:suite "destructure / associative" :label "map in vector" :expected "1" :actual "(let [[{:keys [a]}] [{:a 1}]] a)" :portability :common} - {:suite "destructure / in forms" :label "fn params" :expected "3" :actual "((fn [[a b]] (+ a b)) [1 2])" :portability :common} - {:suite "destructure / in forms" :label "fn map param" :expected "1" :actual "((fn [{:keys [a]}] a) {:a 1})" :portability :common} - {:suite "destructure / in forms" :label "defn destructure" :expected "3" :actual "(do (defn f [[a b]] (+ a b)) (f [1 2]))" :portability :common} - {:suite "destructure / in forms" :label "loop destructure" :expected "3" :actual "(loop [[a b] [1 2]] (+ a b))" :portability :common} - {:suite "destructure / in forms" :label "doseq destructure" :expected "12" :actual "(let [s (atom 0)] (doseq [[k v] {:a 4 :b 8}] (swap! s (fn [x] (+ x v)))) @s)" :portability :common} - {:suite "destructure / in forms" :label "for destructure" :expected "[3 7]" :actual "(for [[a b] [[1 2] [3 4]]] (+ a b))" :portability :common} - {:suite "destructure / in forms" :label "& rest in fn" :expected "[2 3]" :actual "((fn [a & more] more) 1 2 3)" :portability :common} - {:suite "destructure / associative extras" :label ":strs" :expected "7" :actual "(let [{:strs [a]} {\"a\" 7}] a)" :portability :common} - {:suite "destructure / associative extras" :label ":syms" :expected "8" :actual "(let [{:syms [a]} {(quote a) 8}] a)" :portability :common} - {:suite "destructure / associative extras" :label "namespaced :keys" :expected "3" :actual "(let [{:keys [x/y]} {:x/y 3}] y)" :portability :common} - {:suite "destructure / associative extras" :label "namespaced :syms" :expected "4" :actual "(let [{:syms [p/q]} {(quote p/q) 4}] q)" :portability :common} - {:suite "destructure / associative extras" :label "keyword :keys" :expected "3" :actual "(let [{:keys [:a :b]} {:a 1 :b 2}] (+ a b))" :portability :common} - {:suite "destructure / associative extras" :label "keyword :keys ns" :expected "3" :actual "(let [{:keys [:x/y]} {:x/y 3}] y)" :portability :common} - {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs" :expected "[1 2]" :actual "(do (defn f [& {:keys [a b]}] [a b]) (f :a 1 :b 2))" :portability :common} - {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs + fixed" :expected "[0 5]" :actual "(do (defn g [x & {:keys [a]}] [x a]) (g 0 :a 5))" :portability :common} - {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs :or" :expected "9" :actual "(do (defn h [& {:keys [a] :or {a 9}}] a) (h))" :portability :common} - {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs trailing map" :expected "7" :actual "(do (defn k [& {:keys [a]}] a) (k {:a 7}))" :portability :common} - {:suite "destructure / fn params & loop" :label "fn vector param" :expected "7" :actual "((fn [[a b]] (+ a b)) [3 4])" :portability :common} - {:suite "destructure / fn params & loop" :label "fn map param" :expected "30" :actual "((fn [{:keys [x y]}] (* x y)) {:x 5 :y 6})" :portability :common} - {:suite "destructure / fn params & loop" :label "fn :or param" :expected "7" :actual "((fn [{:keys [x] :or {x 7}}] x) {})" :portability :common} - {:suite "destructure / fn params & loop" :label "fn multi-arity destr" :expected "15" :actual "((fn ([[a]] a) ([[a] b] (+ a b))) [10] 5)" :portability :common} - {:suite "destructure / fn params & loop" :label "loop vector binding" :expected "[4 2]" :actual "(loop [[a b] [1 2] n 0] (if (< n 3) (recur [(inc a) b] (inc n)) [a b]))" :portability :common} - {:suite "destructure / fn params & loop" :label "loop map binding" :expected "4" :actual "(loop [{:keys [v]} {:v 1} n 0] (if (< n 2) (recur {:v (* v 2)} (inc n)) v))" :portability :common} - {:suite "destructure / fn params & loop" :label "loop init sees destr" :expected "[1 2 3]" :actual "(loop [[a b] [1 2] c (+ a b)] [a b c])" :portability :common} - {:suite "destructure / primitives reject patterns" :label "fn* fixed pattern" :expected :throws :actual "((fn* [[a b]] a) [1 2])" :portability :common} - {:suite "destructure / primitives reject patterns" :label "fn* rest pattern" :expected :throws :actual "((fn* [a & [b]] b) 1 2 3)" :portability :common} - {:suite "destructure / primitives reject patterns" :label "let* pattern" :expected :throws :actual "(let* [[a b] [1 2]] a)" :portability :common} - {:suite "destructure / primitives reject patterns" :label "loop* pattern" :expected :throws :actual "(loop* [[a b] [1 2]] a)" :portability :common} - {:suite "destructure / primitives reject patterns" :label "fn desugars" :expected "[1 2]" :actual "((fn [[a b]] [a b]) [1 2])" :portability :common} - {:suite "destructure / primitives reject patterns" :label "let desugars" :expected "[1 2]" :actual "(let [[a b] [1 2]] [a b])" :portability :common} - {:suite "destructure / macro params" :label "macro & [a & more :as all]" :expected "[1 [2 3] [1 2 3]]" :actual "(do (defmacro m [& [a & more :as all]] (list (quote quote) [a (vec more) (vec all)])) (m 1 2 3))" :portability :common} - {:suite "destructure / macro params" :label "macro fixed destructure" :expected "[2 1]" :actual "(do (defmacro mm [[a b]] (list (quote quote) [b a])) (mm [1 2]))" :portability :common} - {:suite "destructure / macro params" :label "macro & {:keys}" :expected "5" :actual "(do (defmacro mk [& {:keys [x]}] (list (quote quote) x)) (mk :x 5))" :portability :common} - {:suite "exceptions / try-catch" :label "catch :default" :expected ":caught" :actual "(try (throw (ex-info \"boom\" {})) (catch :default e :caught))" :portability :common} - {:suite "exceptions / try-catch" :label "catch by class" :expected ":caught" :actual "(try (throw (ex-info \"boom\" {})) (catch Exception e :caught))" :portability :common} - {:suite "exceptions / try-catch" :label "catch binds error" :expected "\"boom\"" :actual "(try (throw (ex-info \"boom\" {})) (catch :default e (ex-message e)))" :portability :common} - {:suite "exceptions / try-catch" :label "no throw -> body" :expected "1" :actual "(try 1 (catch :default e :caught))" :portability :common} - {:suite "exceptions / try-catch" :label "finally runs on ok" :expected "2" :actual "(let [a (atom 0)] (try 2 (finally (reset! a 9))) )" :portability :common} - {:suite "exceptions / try-catch" :label "finally runs on throw" :expected "9" :actual "(let [a (atom 0)] (try (throw (ex-info \"x\" {})) (catch :default e nil) (finally (reset! a 9))) @a)" :portability :common} - {:suite "exceptions / try-catch" :label "catch value of body" :expected "5" :actual "(try (+ 2 3) (catch :default e 0))" :portability :common} - {:suite "exceptions / try-catch" :label "malformed catch: non-symbol binding" :expected :throws :actual "(try 1 (catch e (* e 10)))" :portability :common} - {:suite "exceptions / try-catch" :label "malformed catch: literal binding" :expected :throws :actual "(try 1 (catch e 5))" :portability :common} - {:suite "exceptions / try-catch" :label "malformed catch: too short" :expected :throws :actual "(try 1 (catch Exception))" :portability :common} - {:suite "exceptions / assert" :label "assert true -> ok" :expected ":ok" :actual "(do (assert true) :ok)" :portability :common} - {:suite "exceptions / assert" :label "assert expr -> ok" :expected ":ok" :actual "(do (assert (= 1 1)) :ok)" :portability :common} - {:suite "exceptions / assert" :label "assert false throws" :expected :throws :actual "(assert false)" :portability :common} - {:suite "exceptions / assert" :label "assert nil throws" :expected :throws :actual "(assert nil)" :portability :common} - {:suite "exceptions / ex-info" :label "ex-message" :expected "\"oops\"" :actual "(ex-message (ex-info \"oops\" {}))" :portability :common} - {:suite "exceptions / ex-info" :label "ex-data" :expected "{:k 1}" :actual "(ex-data (ex-info \"oops\" {:k 1}))" :portability :common} - {:suite "exceptions / ex-info" :label "ex-data via catch" :expected "{:code 42}" :actual "(try (throw (ex-info \"e\" {:code 42})) (catch :default e (ex-data e)))" :portability :common} - {:suite "exceptions / ex-info" :label "ex-cause" :expected "true" :actual "(let [c (ex-info \"root\" {})] (= c (ex-cause (ex-info \"outer\" {} c))))" :portability :common} - {:suite "exceptions / ex-info" :label "propagates to outer" :expected "\"inner\"" :actual "(try (try (throw (ex-info \"inner\" {})) (finally nil)) (catch :default e (ex-message e)))" :portability :common} - {:suite "exceptions / ex-info" :label "catch binds thrown value" :expected "42" :actual "(try (throw 42) (catch :default e e))" :portability :common} - {:suite "exceptions / ex-info" :label "rethrow preserves ex" :expected "\"inner\"" :actual "(try (try (throw (ex-info \"inner\" {})) (catch :default e (throw e))) (catch :default e (ex-message e)))" :portability :common} - {:suite "exceptions / ex-info" :label "ex-data on non-ex" :expected "nil" :actual "(ex-data 42)" :portability :common} - {:suite "exceptions / ex-info" :label "ex-cause on non-ex" :expected "nil" :actual "(ex-cause {:k 1})" :portability :common} - {:suite "exceptions / ex-info" :label "ex-message of string" :expected "nil" :actual "(ex-message \"hi\")" :portability :common} - {:suite "forms / case" :label "bool" :expected ":yes" :actual "(case true true :yes false :no :default)" :portability :common} - {:suite "forms / case" :label "keyword match" :expected ":b" :actual "(case :a :x :wrong :a :b :default)" :portability :common} - {:suite "forms / case" :label "number match" :expected ":two" :actual "(case 2 1 :one 2 :two :default)" :portability :common} - {:suite "forms / case" :label "string match" :expected ":hit" :actual "(case \"x\" \"y\" :miss \"x\" :hit :default)" :portability :common} - {:suite "forms / case" :label "nil match" :expected ":nada" :actual "(case nil nil :nada :default)" :portability :common} - {:suite "forms / case" :label "default" :expected ":def" :actual "(case 99 1 :one 2 :two :def)" :portability :common} - {:suite "forms / case" :label "list of consts" :expected ":vowel" :actual "(case \\a (\\a \\e \\i \\o \\u) :vowel :consonant)" :portability :common} - {:suite "forms / case" :label "no match no default" :expected :throws :actual "(case 5 1 :one)" :portability :common} - {:suite "forms / case" :label "duplicate keys" :expected :throws :actual "(case 1 1 :one 1 :dup :default)" :portability :common} - {:suite "forms / case" :label "duplicate in or-group" :expected :throws :actual "(case 2 (1 2) :a (2 3) :b :default)" :portability :common} - {:suite "forms / fn" :label "named fn nil" :expected "nil" :actual "((fn* foo-bar []))" :portability :common} - {:suite "forms / fn" :label "immediate call" :expected "1" :actual "((fn* [] 1))" :portability :common} - {:suite "forms / fn" :label "args" :expected "[:a :b]" :actual "((fn* [a b] [a b]) :a :b)" :portability :common} - {:suite "forms / fn" :label "multi-arity 0" :expected "0" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add))" :portability :common} - {:suite "forms / fn" :label "multi-arity 1" :expected "-500" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add -500))" :portability :common} - {:suite "forms / fn" :label "multi-arity 2" :expected "-450" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add -500 50))" :portability :common} - {:suite "forms / fn" :label "variadic rest" :expected "[3 4]" :actual "(do (def v (fn* ([a b & args] args) ([] 0))) (v 1 2 3 4))" :portability :common} - {:suite "forms / fn" :label "variadic empty" :expected "0" :actual "(do (def v (fn* ([a b & args] args) ([] 0))) (v))" :portability :common} - {:suite "forms / fn" :label "variadic collect" :expected "[{} nil :m]" :actual "((fn* [a b & args] args) 'w 't {} nil :m)" :portability :common} - {:suite "forms / fn" :label "closure capture" :expected "8" :actual "(do (def adder (fn* [n] (fn* [x] (+ x n)))) ((adder 5) 3))" :portability :common} - {:suite "forms / fn" :label "recur countdown" :expected "0" :actual "(do (def cd (fn* [n] (if (< 0 n) (recur (+ n -1)) n))) (cd 10))" :portability :common} - {:suite "forms / fn" :label "named self-recur" :expected "120" :actual "(do (def f (fn* fact [n] (if (= n 0) 1 (* n (fact (dec n)))))) (f 5))" :portability :common} - {:suite "forms / fn" :label "no param vector" :expected :throws :actual "(fn* foo)" :portability :common} - {:suite "forms / fn" :label "non-symbol param" :expected :throws :actual "(fn* [1] 1)" :portability :common} - {:suite "forms / let" :label "literal" :expected "1" :actual "(let* [a 1] a)" :portability :common} - {:suite "forms / let" :label "multiple" :expected "[1 2]" :actual "(let* [a 1 b 2] [a b])" :portability :common} - {:suite "forms / let" :label "previous ref" :expected ":bee" :actual "(let* [a 1 b (if (= 1 a) :bee :uh-oh)] b)" :portability :common} - {:suite "forms / let" :label "nested let" :expected "3" :actual "(let* [a 5 b (let* [c -2] (+ a c))] b)" :portability :common} - {:suite "forms / let" :label "fn value bound" :expected "\":foo\"" :actual "(let* [kw->str (fn* [kw] (str kw))] (kw->str :foo))" :portability :common} - {:suite "forms / let" :label "shadowing" :expected "2" :actual "(let* [a 1 a 2] a)" :portability :common} - {:suite "forms / letfn" :label "mutual top" :expected "[1 2]" :actual "(letfn [(a [] 1) (b [] 2)] [(a) (b)])" :portability :common} - {:suite "forms / letfn" :label "mutual recursion" :expected ":done" :actual "(letfn [(ev? [n] (if (= 0 n) :done (od? (dec n)))) (od? [n] (ev? n))] (ev? 4))" :portability :common} - {:suite "forms / letfn" :label "nested letfn" :expected "3" :actual "(letfn [(a [] 5) (b [] (letfn [(c [] -2)] (+ (a) (c))))] (b))" :portability :common} - {:suite "forms / loop" :label "sum" :expected "55" :actual "(loop* [sum 0 cnt 10] (if (= cnt 0) sum (recur (+ cnt sum) (dec cnt))))" :portability :common} - {:suite "forms / loop" :label "multi binding" :expected "[4 2]" :actual "(loop* [a 1 b 2 n 0] (if (< n 3) (recur (inc a) b (inc n)) [a b]))" :portability :common} - {:suite "forms / loop" :label "init sees prior" :expected "[1 2 3]" :actual "(loop* [a 1 b (+ a 1) c (+ b 1)] [a b c])" :portability :common} - {:suite "forms / try" :label "immediate throw caught" :expected ":caught" :actual "(try (throw :boom) (catch :default e :caught))" :portability :common} - {:suite "forms / try" :label "first throw wins" :expected "\"a\"" :actual "(try (throw (ex-info \"a\" {})) (throw (ex-info \"b\" {})) (catch :default e (ex-message e)))" :portability :common} - {:suite "forms / try" :label "catch ex-data" :expected "7" :actual "(try (throw (ex-info \"e\" {:v 7})) (catch :default e (:v (ex-data e))))" :portability :common} - {:suite "forms / try" :label "finally runs" :expected "9" :actual "(let [a (atom 0)] (try 1 (finally (reset! a 9))) @a)" :portability :common} - {:suite "forms / try" :label "body value w/ finally" :expected "1" :actual "(try 1 (finally 2))" :portability :common} - {:suite "forms / try" :label "catch value w/ finally" :expected ":h" :actual "(try (throw (ex-info \"x\" {})) (catch :default e :h) (finally :ignored))" :portability :common} - {:suite "forms / try" :label "no throw skips catch" :expected "5" :actual "(try 5 (catch :default e :nope))" :portability :common} - {:suite "forms / if-do-def-call" :label "if truthy vec" :expected ":fine" :actual "(if [:ok] :fine :no)" :portability :common} - {:suite "forms / if-do-def-call" :label "if truthy str" :expected ":fine" :actual "(if \"good?\" :fine :no)" :portability :common} - {:suite "forms / if-do-def-call" :label "if nil = false" :expected ":else" :actual "(if nil :then :else)" :portability :common} - {:suite "forms / if-do-def-call" :label "if no else" :expected "nil" :actual "(if false 1)" :portability :common} - {:suite "forms / if-do-def-call" :label "do nested" :expected "1" :actual "(do (do (do (do 1))))" :portability :common} - {:suite "forms / if-do-def-call" :label "do returns last" :expected "3" :actual "(do 1 2 3)" :portability :common} - {:suite "forms / if-do-def-call" :label "def + deref var" :expected "true" :actual "(var? (def one 1))" :portability :common} - {:suite "forms / if-do-def-call" :label "def no init interns var" :expected "true" :actual "(var? (def no-init))" :portability :common} - {:suite "forms / if-do-def-call" :label "def no init keeps existing root" :expected "7" :actual "(do (def kept 7) (def kept) kept)" :portability :common} - {:suite "forms / if-do-def-call" :label "declare interns var" :expected "true" :actual "(do (declare fwd-declared) (var? (var fwd-declared)))" :portability :common} - {:suite "forms / if-do-def-call" :label "def redefine" :expected "100" :actual "(do (def one 1) (def one 100) one)" :portability :common} - {:suite "forms / if-do-def-call" :label "def in fn mutates" :expected "[:default :meow]" :actual "(do (def a :default) (def set-a (fn* [v] (def a v))) (let* [before a] (set-a :meow) [before a]))" :portability :common} - {:suite "forms / if-do-def-call" :label "call literal fn" :expected "1" :actual "((fn* [] 1))" :portability :common} - {:suite "forms / if-do-def-call" :label "call nested" :expected "6" :actual "(+ ((fn* [] 1)) ((fn* [] 2)) ((fn* [] 3)))" :portability :common} - {:suite "forms / if-do-def-call" :label "call nil" :expected :throws :actual "(nil)" :portability :common} - {:suite "forms / if arity (X1)" :label "bare if throws" :expected :throws :actual "(if)" :portability :common} - {:suite "forms / if arity (X1)" :label "one-arg if throws" :expected :throws :actual "(if true)" :portability :common} - {:suite "forms / if arity (X1)" :label "four-arg if throws" :expected :throws :actual "(if true 1 2 3)" :portability :common} - {:suite "forms / if arity (X1)" :label "two-arg if ok" :expected "nil" :actual "(if false 1)" :portability :common} - {:suite "forms / if arity (X1)" :label "three-arg if ok" :expected "2" :actual "(if false 1 2)" :portability :common} - {:suite "functions / definition" :label "fn literal" :expected "3" :actual "((fn [a b] (+ a b)) 1 2)" :portability :common} - {:suite "functions / definition" :label "fn shorthand" :expected "3" :actual "(#(+ %1 %2) 1 2)" :portability :common} - {:suite "functions / definition" :label "fn shorthand %" :expected "2" :actual "(#(inc %) 1)" :portability :common} - {:suite "functions / definition" :label "defn" :expected "5" :actual "(do (defn f [x] (+ x 2)) (f 3))" :portability :common} - {:suite "functions / definition" :label "multi-arity" :expected "[1 5]" :actual "(do (defn f ([x] x) ([x y] (+ x y))) [(f 1) (f 2 3)])" :portability :common} - {:suite "functions / definition" :label "variadic" :expected "[1 2 3]" :actual "(do (defn f [& xs] xs) (f 1 2 3))" :portability :common} - {:suite "functions / definition" :label "variadic with fixed" :expected "[1 [2 3]]" :actual "(do (defn f [a & xs] [a xs]) (f 1 2 3))" :portability :common} - {:suite "functions / definition" :label "named fn-literal self-recursion (direct self-call)" :expected "3628800" :actual "((fn fact [n] (if (< n 2) 1 (* n (fact (dec n))))) 10)" :portability :common} - {:suite "functions / definition" :label "defn self-recursion" :expected "832040" :actual "(do (defn fib [n] (if (< n 2) n (+ (fib (- n 1)) (fib (- n 2))))) (fib 30))" :portability :common} - {:suite "functions / definition" :label "multi-arity self-recursion" :expected "15" :actual "(do (defn sum ([xs] (sum xs 0)) ([xs a] (if (seq xs) (sum (rest xs) (+ a (first xs))) a))) (sum [1 2 3 4 5]))" :portability :common} - {:suite "functions / definition" :label "variadic self-recursion" :expected "10" :actual "(do (defn g [& xs] (if (next xs) (apply g (cons (+ (first xs) (second xs)) (nnext xs))) (first xs))) (g 1 2 3 4))" :portability :common} - {:suite "functions / definition" :label "closure captures" :expected "8" :actual "(do (defn adder [n] (fn [x] (+ x n))) ((adder 5) 3))" :portability :common} - {:suite "functions / definition" :label "recursion" :expected "120" :actual "(do (defn fact [n] (if (< n 2) 1 (* n (fact (dec n))))) (fact 5))" :portability :common} - {:suite "functions / definition" :label "named fn self-ref" :expected "120" :actual "((fn fact [n] (if (< n 2) 1 (* n (fact (dec n))))) 5)" :portability :common} - {:suite "functions / definition" :label "param named `in`" :expected "1" :actual "((fn [in] (first in)) [1 2 3])" :portability :common} - {:suite "functions / definition" :label "param `in` via core fn" :expected "3" :actual "((fn [in] (count in)) [1 2 3])" :portability :common} - {:suite "functions / definition" :label "local `in` in let body" :expected "2" :actual "(let [in [2 3]] (first in))" :portability :common} - {:suite "functions / application" :label "apply" :expected "6" :actual "(apply + [1 2 3])" :portability :common} - {:suite "functions / application" :label "apply with leading" :expected "10" :actual "(apply + 1 2 [3 4])" :portability :common} - {:suite "functions / application" :label "apply keyword" :expected "1" :actual "(apply :a [{:a 1}])" :portability :common} - {:suite "functions / application" :label "partial" :expected "7" :actual "((partial + 5) 2)" :portability :common} - {:suite "functions / application" :label "partial multi" :expected "10" :actual "((partial + 1 2) 3 4)" :portability :common} - {:suite "functions / application" :label "comp" :expected "4" :actual "((comp inc inc) 2)" :portability :common} - {:suite "functions / application" :label "comp order" :expected "5" :actual "((comp inc (fn [x] (* x 2))) 2)" :portability :common} - {:suite "functions / application" :label "comp identity" :expected "3" :actual "((comp) 3)" :portability :common} - {:suite "functions / application" :label "complement" :expected "true" :actual "((complement even?) 3)" :portability :common} - {:suite "functions / application" :label "constantly" :expected "5" :actual "((constantly 5) 1 2 3)" :portability :common} - {:suite "functions / application" :label "identity" :expected "7" :actual "(identity 7)" :portability :common} - {:suite "functions / combinators" :label "juxt" :expected "[1 3]" :actual "((juxt first last) [1 2 3])" :portability :common} - {:suite "functions / combinators" :label "fnil" :expected "1" :actual "((fnil inc 0) nil)" :portability :common} - {:suite "functions / combinators" :label "fnil passes value" :expected "6" :actual "((fnil inc 0) 5)" :portability :common} - {:suite "functions / combinators" :label "every-pred true" :expected "true" :actual "((every-pred pos? even?) 4)" :portability :common} - {:suite "functions / combinators" :label "every-pred false" :expected "false" :actual "((every-pred pos? even?) 3)" :portability :common} - {:suite "functions / combinators" :label "some-fn" :expected "true" :actual "((some-fn even? neg?) 3 4)" :portability :common} - {:suite "functions / combinators" :label "memoize" :expected "2" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) x))) (f 1) (f 1) (f 2) @c)" :portability :common} - {:suite "functions / combinators" :label "trampoline" :expected "10" :actual "(trampoline (fn f [n acc] (if (zero? n) acc (fn [] (f (dec n) (+ acc 2))))) 5 0)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement true" :expected "true" :actual "((complement pos?) -1)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement false" :expected "false" :actual "((complement pos?) 1)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement multi" :expected "true" :actual "((complement <) 3 2)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil patches nil" :expected "1" :actual "((fnil inc 0) nil)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil passes non-nil" :expected "6" :actual "((fnil inc 0) 5)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil two defaults" :expected "8" :actual "((fnil + 1 2) nil nil 5)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil only first 3" :expected "[:a :b :c nil]" :actual "((fnil vector :a :b :c) nil nil nil nil)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil in update" :expected "{:k 1}" :actual "(update {} :k (fnil inc 0))" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "clojure-version" :expected "true" :actual "(string? (clojure-version))" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "bigdec" :expected "3M" :actual "(bigdec 3)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "numerator throws" :expected :throws :actual "(numerator 1)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "denominator throws" :expected :throws :actual "(denominator 1)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "supers empty set" :expected "#{}" :actual "(supers 1)" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "munge dashes" :expected "\"a_b\"" :actual "(munge \"a-b\")" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "munge symbol" :expected "(quote x_y)" :actual "(munge (quote x-y))" :portability :common} - {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "test no-test" :expected ":no-test" :actual "(test (quote foo))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "key" :expected "1" :actual "(key (first {1 :a}))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "val" :expected ":a" :actual "(val (first {1 :a}))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "key non-entry throws" :expected :throws :actual "(key 5)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "find hit" :expected "[:a 1]" :actual "(find {:a 1} :a)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "find miss" :expected "nil" :actual "(find {:a 1} :b)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "find nil value" :expected "[:a nil]" :actual "(find {:a nil} :a)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "find on vector" :expected "[0 :x]" :actual "(find [:x :y] 0)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "select-keys" :expected "{:a 1}" :actual "(select-keys {:a 1 :b 2} [:a])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "select-keys nil val" :expected "{:a nil}" :actual "(select-keys {:a nil :b 2} [:a])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "select-keys missing" :expected "{}" :actual "(select-keys {:a 1} [:z])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "zipmap uneven" :expected "{:a 1}" :actual "(zipmap [:a :b] [1])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "zipmap nil val" :expected "{:a nil}" :actual "(zipmap [:a] [nil])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge later wins" :expected "{:a 2}" :actual "(merge {:a 1} {:a 2})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge nil arg" :expected "{:a 1}" :actual "(merge {:a 1} nil)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge nil first" :expected "{:a 1}" :actual "(merge nil {:a 1})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge all nil" :expected "nil" :actual "(merge nil nil)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge empty" :expected "nil" :actual "(merge)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge entry pair" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} [:b 2])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge-with" :expected "{:a 3}" :actual "(merge-with + {:a 1} {:a 2})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge-with disjoint" :expected "{:a 1, :b 2}" :actual "(merge-with + {:a 1} {:b 2})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "merge-with nil-val present" :expected "{:a 1}" :actual "(merge-with (fn [a b] (or a b)) {:a nil} {:a 1})" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "get-in" :expected "1" :actual "(get-in {:a {:b 1}} [:a :b])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "get-in missing" :expected ":nf" :actual "(get-in {:a 1} [:z :y] :nf)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "get-in nil value present" :expected "nil" :actual "(get-in {:a {:b nil}} [:a :b] :nf)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "get-in empty path" :expected "{:a 1}" :actual "(get-in {:a 1} [])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "memoize" :expected "2" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) x))) (f 1) (f 1) (f 2) (deref c))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "memoize caches nil" :expected "1" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) nil))) (f 1) (f 1) (deref c))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "partial" :expected "6" :actual "((partial + 1 2) 3)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "partial no extra" :expected "3" :actual "((partial + 1 2))" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "partial many fixed" :expected "15" :actual "((partial + 1 2 3 4) 5)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "trampoline" :expected "10" :actual "(trampoline (fn f [n acc] (if (zero? n) acc (fn [] (f (dec n) (+ acc 2))))) 5 0)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "some? true" :expected "true" :actual "(some? 0)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "some? false" :expected "false" :actual "(some? nil)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "true?/false?" :expected "[true false false]" :actual "[(true? true) (true? 1) (false? nil)]" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "max" :expected "3" :actual "(max 1 3 2)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "min" :expected "1" :actual "(min 3 1 2)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "max single" :expected "5" :actual "(max 5)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "max non-number throws" :expected :throws :actual "(max 1 :a)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "reverse" :expected "[3 2 1]" :actual "(reverse [1 2 3])" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "reverse empty" :expected "[]" :actual "(reverse nil)" :portability :common} - {:suite "clojure.core / leaf batch 2" :label "conj nil onto map" :expected "{:a 1}" :actual "(conj {:a 1} nil)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty vector" :expected "[]" :actual "(empty [1 2])" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty list" :expected "[]" :actual "(empty (list 1))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty map" :expected "{}" :actual "(empty {:a 1})" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty set" :expected "#{}" :actual "(empty #{1})" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty nil" :expected "nil" :actual "(empty nil)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty string" :expected "nil" :actual "(empty \"abc\")" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty lazy is ()" :expected "[]" :actual "(empty (map inc [1 2]))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "empty sorted keeps cmp" :expected "[3 1]" :actual "(vec (seq (into (empty (sorted-set-by > 1 2)) [1 3])))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "assoc-in" :expected "{:a {:b 1}}" :actual "(assoc-in {} [:a :b] 1)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "assoc-in deep" :expected "{:a {:b {:c 2}}}" :actual "(assoc-in {:a {:b {:c 1}}} [:a :b :c] 2)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "assoc-in keeps siblings" :expected "{:a {:b 1, :c 2}}" :actual "(assoc-in {:a {:b 1}} [:a :c] 2)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "assoc-in vector idx" :expected "[1 9]" :actual "(assoc-in [1 2] [1] 9)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "assoc-in nested vec" :expected "[{:a 9}]" :actual "(assoc-in [{:a 1}] [0 :a] 9)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "update-in" :expected "{:a {:b 2}}" :actual "(update-in {:a {:b 1}} [:a :b] inc)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "update-in extra args" :expected "{:a {:b 111}}" :actual "(update-in {:a {:b 1}} [:a :b] + 10 100)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "update-in fnil" :expected "{:a {:b 1}}" :actual "(update-in {} [:a :b] (fnil inc 0))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "update-in single key" :expected "{:a 2}" :actual "(update-in {:a 1} [:a] inc)" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "interpose" :expected "[1 :s 2 :s 3]" :actual "(interpose :s [1 2 3])" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "interpose empty" :expected "[]" :actual "(interpose :s [])" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "interpose one" :expected "[1]" :actual "(interpose :s [1])" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "interpose is lazy" :expected "[0 :s 1]" :actual "(take 3 (interpose :s (range)))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "interpose xform" :expected "[\"a\" \",\" \"b\"]" :actual "(vec (sequence (interpose \",\") [\"a\" \"b\"]))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "take-nth" :expected "[1 3 5]" :actual "(take-nth 2 [1 2 3 4 5 6])" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "take-nth lazy" :expected "[0 3 6]" :actual "(take 3 (take-nth 3 (range)))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "take-nth xform" :expected "[1 3 5]" :actual "(vec (sequence (take-nth 2) [1 2 3 4 5 6]))" :portability :common} - {:suite "clojure.core / leaf batch 3" :label "take-nth into" :expected "[1 4]" :actual "(into [] (take-nth 3) [1 2 3 4 5])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by keyfn" :expected "[[1 :b] [2 :a]]" :actual "(sort-by first [[2 :a] [1 :b]])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by string keys" :expected "[\"a\" \"bb\" \"ccc\"]" :actual "(sort-by count [\"ccc\" \"a\" \"bb\"])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by comparator" :expected "[3 2 1]" :actual "(sort-by identity > [1 3 2])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by 3way cmp" :expected "[3 2 1]" :actual "(sort-by identity (fn [a b] (- b a)) [1 3 2])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by mixed nil" :expected "[nil 1 2]" :actual "(sort-by identity [2 nil 1])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by empty" :expected "[]" :actual "(sort-by first [])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "sort-by nil coll" :expected "[]" :actual "(sort-by first nil)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "rand-int range" :expected "true" :actual "(every? (fn [_] (let [r (rand-int 5)] (and (int? r) (<= 0 r 4)))) (range 50))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "rand-int zero" :expected "0" :actual "(rand-int 1)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "shuffle is permutation" :expected "true" :actual "(= (sort (shuffle [5 3 1 4 2])) [1 2 3 4 5])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "shuffle returns vector" :expected "true" :actual "(vector? (shuffle [1 2 3]))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "shuffle empty" :expected "[]" :actual "(shuffle [])" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "shuffle non-coll throws" :expected :throws :actual "(shuffle 5)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "random-uuid is uuid" :expected "true" :actual "(uuid? (random-uuid))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "random-uuid v4 shape" :expected "true" :actual "(boolean (re-matches #\"[0-9a-f]{8}-[0-9a-f]{4}-4[0-9a-f]{3}-[89ab][0-9a-f]{3}-[0-9a-f]{12}\" (str (random-uuid))))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "random-uuid distinct" :expected "true" :actual "(not= (random-uuid) (random-uuid))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-escape newline" :expected "\"\\\\n\"" :actual "(char-escape-string \\newline)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-escape quote" :expected "true" :actual "(= 2 (count (char-escape-string \\\")))" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-escape none" :expected "nil" :actual "(char-escape-string \\a)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-name space" :expected "\"space\"" :actual "(char-name-string \\space)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-name newline" :expected "\"newline\"" :actual "(char-name-string \\newline)" :portability :common} - {:suite "clojure.core / leaf batch 4" :label "char-name none" :expected "nil" :actual "(char-name-string \\a)" :portability :common} - {:suite "functions / recur into variadic arity" :label "counts rest via recur" :expected "3" :actual "((fn cnt [acc & xs] (if (seq xs) (recur (inc acc) (rest xs)) acc)) 0 :a :b :c)" :portability :common} - {:suite "functions / recur into variadic arity" :label "zero-fixed variadic" :expected "4" :actual "((fn f [& xs] (if (< (count xs) 4) (recur (cons :x xs)) (count xs))) :a)" :portability :common} - {:suite "functions / recur into variadic arity" :label "rest empties to nil" :expected "[:done]" :actual "((fn f [& xs] (if xs (recur (next xs)) (list :done))) 1 2)" :portability :common} - {:suite "functions / recur into variadic arity" :label "multi-arity variadic recur" :expected "6" :actual "((fn ma ([a] a) ([a & xs] (if (seq xs) (recur (+ a (first xs)) (rest xs)) a))) 1 2 3)" :portability :common} - {:suite "functions / recur into variadic arity" :label "recur passes nil rest" :expected ":empty" :actual "((fn f [acc & xs] (if (seq xs) (recur acc (rest xs)) :empty)) 0 1)" :portability :common} - {:suite "functions / recur into variadic arity" :label "fixed-arity recur untouched" :expected "10" :actual "((fn f [n acc] (if (pos? n) (recur (dec n) (+ acc 2)) acc)) 5 0)" :portability :common} - {:suite "functions / empty rest arg is nil" :label "no args" :expected ":nil" :actual "((fn [& r] (if r :truthy :nil)))" :portability :common} - {:suite "functions / empty rest arg is nil" :label "after fixed" :expected ":nil" :actual "((fn [a & r] (if r :truthy :nil)) 1)" :portability :common} - {:suite "functions / empty rest arg is nil" :label "via apply" :expected ":nil" :actual "(apply (fn [& r] (if r :truthy :nil)) [])" :portability :common} - {:suite "functions / empty rest arg is nil" :label "defn no args" :expected ":nil" :actual "(do (defn er-f [& r] (if r :truthy :nil)) (er-f))" :portability :common} - {:suite "functions / empty rest arg is nil" :label "non-empty unchanged" :expected "[1 2]" :actual "((fn [& r] r) 1 2)" :portability :common} - {:suite "functions / empty rest arg is nil" :label "one extra" :expected "[2]" :actual "((fn [a & r] r) 1 2)" :portability :common} - {:suite "functions / empty rest arg is nil" :label "rest destructure with no args" :expected ":nil" :actual "((fn [& [a]] (if a :truthy :nil)))" :portability :common} - {:suite "functions / arity enforcement" :label "fixed extra args" :expected :throws :actual "((fn [x] x) 1 2)" :portability :common} - {:suite "functions / arity enforcement" :label "fixed missing args" :expected :throws :actual "((fn [x y] x) 1)" :portability :common} - {:suite "functions / arity enforcement" :label "fixed zero of one" :expected :throws :actual "((fn [x] x))" :portability :common} - {:suite "functions / arity enforcement" :label "named defn extra" :expected :throws :actual "(do (defn af1 [x] x) (af1 1 2))" :portability :common} - {:suite "functions / arity enforcement" :label "overlay fn extra" :expected :throws :actual "(identity 1 2)" :portability :common} - {:suite "functions / arity enforcement" :label "through apply" :expected :throws :actual "(apply (fn [x] x) [1 2])" :portability :common} - {:suite "functions / arity enforcement" :label "through update" :expected :throws :actual "(update {:k 1} :k identity 1 2 3 4)" :portability :common} - {:suite "functions / arity enforcement" :label "variadic below min" :expected :throws :actual "((fn [x & r] x))" :portability :common} - {:suite "functions / arity enforcement" :label "variadic at min" :expected "nil" :actual "((fn [x & r] r) 1)" :portability :common} - {:suite "functions / arity enforcement" :label "variadic above min" :expected "[2 3]" :actual "((fn [x & r] r) 1 2 3)" :portability :common} - {:suite "functions / arity enforcement" :label "multi-arity no match" :expected :throws :actual "((fn ([x] x) ([x y] y)) 1 2 3)" :portability :common} - {:suite "functions / arity enforcement" :label "multi-arity variadic below min" :expected :throws :actual "((fn ([x] x) ([x y & r] r)))" :portability :common} - {:suite "functions / arity enforcement" :label "destructured param counts as one" :expected "3" :actual "((fn [[a b] c] c) [1 2] 3)" :portability :common} - {:suite "functions / arity enforcement" :label "destructured extra throws" :expected :throws :actual "((fn [[a b]] a) [1 2] [3 4])" :portability :common} - {:suite "functions / arity enforcement" :label "hof exact arity ok" :expected "[2 4]" :actual "(mapv (fn [x] (* 2 x)) [1 2])" :portability :common} - {:suite "functions / arity enforcement" :label "zero-arity fn ok" :expected "7" :actual "((fn [] 7))" :portability :common} - {:suite "clojure.core / futures — deref" :label "future + deref" :expected "3" :actual "(deref (future (+ 1 2)))" :portability :common} - {:suite "clojure.core / futures — deref" :label "@ reader macro derefs" :expected "42" :actual "@(future (* 6 7))" :portability :common} - {:suite "clojure.core / futures — deref" :label "future returns collection" :expected "[2 3 4]" :actual "(deref (future (mapv inc [1 2 3])))" :portability :common} - {:suite "clojure.core / futures — deref" :label "future returns a map" :expected "{:a 1}" :actual "(deref (future {:a 1}))" :portability :common} - {:suite "clojure.core / futures — deref" :label "deref is cached/idempotent" :expected "[2 2]" :actual "(let [f (future (+ 1 1))] [(deref f) (deref f)])" :portability :common} - {:suite "clojure.core / futures — deref" :label "timed deref of ready future" :expected "42" :actual "(let [f (future 42)] (deref f) (deref f 1000 :nope))" :portability :common} - {:suite "clojure.core / futures — deref" :label "body error re-raised on deref" :expected :throws :actual "(deref (future (throw \"boom\")))" :portability :common} - {:suite "clojure.core / futures — deref" :label "timed deref times out" :expected ":timed-out" :actual "(deref (future (do (Thread/sleep 300) :late)) 10 :timed-out)" :portability :jvm} - {:suite "clojure.core / futures — deref" :label "Thread/sleep in body" :expected ":slept" :actual "(deref (future (do (Thread/sleep 5) :slept)))" :portability :jvm} - {:suite "clojure.core / futures — deref" :label "timed-out future still completes" :expected ":late" :actual "(let [f (future (do (Thread/sleep 30) :late))] (deref f 5 :early) (deref f))" :portability :jvm} - {:suite "clojure.core / futures — predicates" :label "future? true" :expected "true" :actual "(future? (future 1))" :portability :common} - {:suite "clojure.core / futures — predicates" :label "future? false" :expected "false" :actual "(future? 42)" :portability :common} - {:suite "clojure.core / futures — predicates" :label "future-done? after deref" :expected "true" :actual "(let [f (future 1)] (deref f) (future-done? f))" :portability :common} - {:suite "clojure.core / futures — predicates" :label "realized? after deref" :expected "true" :actual "(let [f (future 1)] (deref f) (realized? f))" :portability :common} - {:suite "clojure.core / futures — predicates" :label "cancel an in-flight future returns true" :expected "true" :actual "(let [f (future (do (Thread/sleep 100) 1))] (future-cancel f))" :portability :jvm} - {:suite "clojure.core / futures — predicates" :label "future-cancelled? after cancel" :expected "true" :actual "(let [f (future (do (Thread/sleep 100) 1))] (future-cancel f) (future-cancelled? f))" :portability :jvm} - {:suite "clojure.core / futures — predicates" :label "future-done? after cancel" :expected "true" :actual "(let [f (future 1)] (future-cancel f) (future-done? f))" :portability :common} - {:suite "clojure.core / futures — predicates" :label "cancel an already-completed future returns false" :expected "false" :actual "(let [f (future 1)] (deref f) (future-cancel f))" :portability :common} - {:suite "clojure.core / futures — predicates" :label "future-cancelled? fresh is false" :expected "false" :actual "(future-cancelled? (future 1))" :portability :common} - {:suite "clojure.core / futures — snapshot (copy) semantics" :label "captured atom is snapshotted, not shared" :expected "1" :actual "(let [a (atom 0)] (deref (future (swap! a inc))) @a)" :portability :common} - {:suite "clojure.core / futures — snapshot (copy) semantics" :label "future sees its own mutation" :expected "1" :actual "(let [a (atom 0)] (deref (future (swap! a inc))))" :portability :common} - {:suite "clojure.core / pmap family" :label "pmap values in order" :expected "[2 3 4]" :actual "(vec (pmap inc [1 2 3]))" :portability :common} - {:suite "clojure.core / pmap family" :label "pmap multi-coll" :expected "[5 7 9]" :actual "(vec (pmap + [1 2 3] [4 5 6]))" :portability :common} - {:suite "clojure.core / pmap family" :label "pmap empty" :expected "[]" :actual "(pmap inc [])" :portability :common} - {:suite "clojure.core / pmap family" :label "pmap is parallel" :expected "true" :actual "(do (deref (future :warmup)) (let [t0 (System/currentTimeMillis)] (dorun (pmap (fn [_] (Thread/sleep 200)) [1 2 3 4])) (< (- (System/currentTimeMillis) t0) 700)))" :portability :jvm} - {:suite "clojure.core / pmap family" :label "pcalls" :expected "[1 2]" :actual "(vec (pcalls (fn [] 1) (fn [] 2)))" :portability :common} - {:suite "clojure.core / pmap family" :label "pvalues" :expected "[3 7]" :actual "(vec (pvalues (+ 1 2) (+ 3 4)))" :portability :common} - {:suite "clojure.core / pmap family" :label "snapshot semantics" :expected "2" :actual "(let [a (atom 0)] (dorun (pmap (fn [_] (swap! a inc)) [1 2])) (deref a))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "derive returns new h" :expected "true" :actual "(let [h (derive (make-hierarchy) :rect :shape)] (and (map? h) (isa? h :rect :shape)))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "original unchanged" :expected "false" :actual "(let [h0 (make-hierarchy) h1 (derive h0 :rect :shape)] (isa? h0 :rect :shape))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "isa? self" :expected "true" :actual "(isa? (make-hierarchy) :a :a)" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "isa? transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (isa? h :square :shape))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "multi-parent" :expected "[true true]" :actual "(let [h (-> (make-hierarchy) (derive :sq :rect) (derive :sq :rhombus))] [(isa? h :sq :rect) (isa? h :sq :rhombus)])" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "parents set" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :sq :rect) (derive :sq :rhombus))] (= #{:rect :rhombus} (parents h :sq)))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "ancestors transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (= #{:rect :shape} (ancestors h :square)))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "descendants transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (= #{:rect :square} (descendants h :shape)))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "underive removes" :expected "false" :actual "(let [h (-> (make-hierarchy) (derive :a :b) (underive :a :b))] (isa? h :a :b))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "vector isa?" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :rect :shape))] (isa? h [:rect :rect] [:shape :shape]))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "vector isa? length" :expected "false" :actual "(isa? (make-hierarchy) [:a] [:a :a])" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "cyclic derive throws" :expected :throws :actual "(-> (make-hierarchy) (derive :a :b) (derive :b :a))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "duplicate derive ok" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :a :b) (derive :a :b))] (isa? h :a :b))" :portability :common} - {:suite "hierarchy / pure 3-arity" :label "parents nil when none" :expected "nil" :actual "(parents (make-hierarchy) :x)" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "global derive + isa?" :expected "true" :actual "(do (derive :g/sq :g/rect) (isa? :g/sq :g/rect))" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "global ancestors" :expected "true" :actual "(do (derive :g/a :g/b) (derive :g/b :g/c) (contains? (ancestors :g/a) :g/c))" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "global underive" :expected "false" :actual "(do (derive :g/u :g/v) (underive :g/u :g/v) (isa? :g/u :g/v))" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "dispatch via hierarchy" :expected ":is-shape" :actual "(do (derive :h/sq :h/shape) (defmulti hmm identity) (defmethod hmm :h/shape [_] :is-shape) (hmm :h/sq))" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "dispatch custom hierarchy" :expected ":parent" :actual "(do (def hh (atom (derive (make-hierarchy) :c :p))) (defmulti cmm identity :hierarchy hh) (defmethod cmm :p [_] :parent) (cmm :c))" :portability :common} - {:suite "hierarchy / global + multimethod dispatch" :label "dispatch exact beats isa" :expected ":exact" :actual "(do (derive :de/e1 :de/e2) (defmulti emm identity) (defmethod emm :de/e2 [_] :parent) (defmethod emm :de/e1 [_] :exact) (emm :de/e1))" :portability :common} - {:suite "interop / dot forms" :label "method call" :expected "\"v=41\"" :actual "(. {:value 41 :describe (fn [self] (str \"v=\" (:value self)))} describe)" :portability :jvm} - {:suite "interop / dot forms" :label "method with args" :expected "\"Hello Alice\"" :actual "(. {:greet (fn [self n] (str \"Hello \" n))} greet \"Alice\")" :portability :jvm} - {:suite "interop / dot forms" :label "field access .-" :expected "41" :actual "(.-value {:value 41})" :portability :jvm} - {:suite "interop / dot forms" :label "dot field keyword" :expected "41" :actual "(. {:value 41} :value)" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "zero-arg coll-interop .count" :expected "3" :actual "(.count [1 2 3])" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "zero-arg coll-interop .seq" :expected "[1 2]" :actual "(.seq [1 2])" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "explicit dot zero-arg interop" :expected "3" :actual "(. [1 2 3] count)" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "with-arg coll-interop .nth" :expected "2" :actual "(.nth [1 2 3] 1)" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "record zero-arg method" :expected "10" :actual "(do (defprotocol Pd (gm [this])) (defrecord Rd [x] Pd (gm [this] (* 2 x))) (.gm (->Rd 5)))" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "record method with args" :expected "15" :actual "(do (defprotocol Pa (am [this y])) (defrecord Ra [x] Pa (am [this y] (+ x y))) (.am (->Ra 5) 10))" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "deftype method with args" :expected "7" :actual "(do (defprotocol Pq (qq [this y])) (deftype Tq [x] Pq (qq [this y] (+ x y))) (.qq (Tq. 3) 4))" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "record -field is field access" :expected "7" :actual "(do (defrecord Rf [x]) (.-x (->Rf 7)))" :portability :jvm} - {:suite "interop / dot dispatch arms" :label "object-method with args .equals" :expected "true" :actual "(.equals \"a\" \"a\")" :portability :jvm} - {:suite "interop / arrays (aget/aset/alength)" :label "alength" :expected "3" :actual "(alength (object-array [1 2 3]))" :portability :jvm} - {:suite "interop / arrays (aget/aset/alength)" :label "aget" :expected "20" :actual "(aget (object-array [10 20 30]) 1)" :portability :jvm} - {:suite "interop / arrays (aget/aset/alength)" :label "aset returns val" :expected "9" :actual "(aset (object-array [1 2 3]) 1 9)" :portability :jvm} - {:suite "interop / arrays (aget/aset/alength)" :label "aset mutates" :expected "[7 2 3]" :actual "(let [a (object-array [1 2 3])] (aset a 0 7) (vec a))" :portability :jvm} - {:suite "interop / arrays (aget/aset/alength)" :label "aget 2d" :expected "4" :actual "(aget (to-array-2d [[1 2] [3 4]]) 1 1)" :portability :jvm} - {:suite "interop / String methods" :label ".toLowerCase" :expected "\"hi\"" :actual "(.toLowerCase \"HI\")" :portability :jvm} - {:suite "interop / String methods" :label ".toUpperCase" :expected "\"HI\"" :actual "(.toUpperCase \"hi\")" :portability :jvm} - {:suite "interop / String methods" :label "dot-form" :expected "\"hi\"" :actual "(. \"HI\" toLowerCase)" :portability :jvm} - {:suite "interop / String methods" :label ".trim" :expected "\"x\"" :actual "(.trim \" x \")" :portability :jvm} - {:suite "interop / String methods" :label ".length" :expected "3" :actual "(.length \"abc\")" :portability :jvm} - {:suite "interop / String methods" :label ".isEmpty" :expected "[true false]" :actual "[(.isEmpty \"\") (.isEmpty \"a\")]" :portability :jvm} - {:suite "interop / String methods" :label ".indexOf hit" :expected "1" :actual "(.indexOf \"abc\" \"b\")" :portability :jvm} - {:suite "interop / String methods" :label ".indexOf miss is -1" :expected "-1" :actual "(.indexOf \"abc\" \"z\")" :portability :jvm} - {:suite "interop / String methods" :label ".lastIndexOf" :expected "3" :actual "(.lastIndexOf \"abab\" \"b\")" :portability :jvm} - {:suite "interop / String methods" :label ".substring" :expected "\"bc\"" :actual "(.substring \"abc\" 1)" :portability :jvm} - {:suite "interop / String methods" :label ".substring end" :expected "\"b\"" :actual "(.substring \"abc\" 1 2)" :portability :jvm} - {:suite "interop / String methods" :label ".startsWith" :expected "true" :actual "(.startsWith \"abc\" \"ab\")" :portability :jvm} - {:suite "interop / String methods" :label ".endsWith" :expected "true" :actual "(.endsWith \"abc\" \"bc\")" :portability :jvm} - {:suite "interop / String methods" :label ".contains" :expected "true" :actual "(.contains \"abc\" \"b\")" :portability :jvm} - {:suite "interop / String methods" :label ".replace" :expected "\"axc\"" :actual "(.replace \"abc\" \"b\" \"x\")" :portability :jvm} - {:suite "interop / String methods" :label ".charAt" :expected "\\b" :actual "(.charAt \"abc\" 1)" :portability :jvm} - {:suite "interop / String methods" :label ".equalsIgnoreCase" :expected "true" :actual "(.equalsIgnoreCase \"AbC\" \"aBc\")" :portability :jvm} - {:suite "interop / String methods" :label "Long/MAX_VALUE" :expected "true" :actual "(pos? Long/MAX_VALUE)" :portability :jvm} - {:suite "interop / String methods" :label "String/valueOf num" :expected "\"42\"" :actual "(String/valueOf 42)" :portability :jvm} - {:suite "interop / String methods" :label "String/valueOf str" :expected "\"hi\"" :actual "(String/valueOf \"hi\")" :portability :jvm} - {:suite "interop / String methods" :label "String/valueOf kw" :expected "\":k\"" :actual "(String/valueOf :k)" :portability :jvm} - {:suite "interop / String methods" :label "String/valueOf nil" :expected "\"null\"" :actual "(String/valueOf nil)" :portability :jvm} - {:suite "interop / String methods" :label "instance? CharSequence" :expected "true" :actual "(instance? CharSequence \"aaa\")" :portability :common} - {:suite "interop / String methods" :label "instance? CharSequence non-str" :expected "false" :actual "(instance? CharSequence 42)" :portability :common} - {:suite "interop / String methods" :label "unsupported method throws" :expected :throws :actual "(.frobnicate \"abc\")" :portability :jvm} - {:suite "interop / java.time shims" :label "ofPattern formats #inst" :expected "true" :actual "(string? (.format (DateTimeFormatter/ofPattern \"yyyy-MM-dd\") #inst \"2020-03-05T13:45:30Z\"))" :portability :jvm} - {:suite "interop / java.time shims" :label "pattern shape" :expected "true" :actual "(boolean (re-matches #\"\\d{4}-\\d{2}-\\d{2}\" (.format (DateTimeFormatter/ofPattern \"yyyy-MM-dd\") #inst \"2020-03-05T13:45:30Z\")))" :portability :jvm} - {:suite "interop / java.time shims" :label "month name + ampm" :expected "true" :actual "(boolean (re-matches #\"[A-Z][a-z]{2} \\d{1,2}, 2020 \\d{1,2}:\\d{2} [AP]M\" (.format (DateTimeFormatter/ofPattern \"MMM d, yyyy h:mm a\") #inst \"2020-03-05T13:45:30Z\")))" :portability :jvm} - {:suite "interop / java.time shims" :label "quoted literal" :expected "true" :actual "(boolean (re-matches #\"\\d{4}-\\d{2}-\\d{2}T\\d{2}:\\d{2}:\\d{2}\" (.format DateTimeFormatter/ISO_LOCAL_DATE_TIME #inst \"2020-03-05T13:45:30Z\")))" :portability :jvm} - {:suite "interop / java.time shims" :label "localized style" :expected "true" :actual "(string? (.format (DateTimeFormatter/ofLocalizedDate FormatStyle/MEDIUM) #inst \"2020-03-05T13:45:30Z\"))" :portability :jvm} - {:suite "interop / java.time shims" :label "withLocale chain" :expected "true" :actual "(string? (.format (.withLocale (DateTimeFormatter/ofPattern \"yyyy\") (java.util.Locale. \"en\")) #inst \"2020-01-01T00:00:00Z\"))" :portability :jvm} - {:suite "interop / java.time shims" :label "fix-date chain" :expected "true" :actual "(instance? LocalDateTime (-> #inst \"2020-03-05T13:45:30Z\" (.toInstant) (.atZone (ZoneId/systemDefault)) (.toLocalDateTime)))" :portability :jvm} - {:suite "interop / java.time shims" :label "inst is java.util.Date" :expected "true" :actual "(instance? java.util.Date #inst \"2020-01-01T00:00:00Z\")" :portability :jvm} - {:suite "interop / java.time shims" :label "Instant instance" :expected "true" :actual "(instance? java.time.Instant (Instant/ofEpochMilli 0))" :portability :jvm} - {:suite "interop / java.time shims" :label "getTime epoch ms" :expected "0" :actual "(.getTime #inst \"1970-01-01T00:00:00Z\")" :portability :jvm} - {:suite "interop / java.time shims" :label "toEpochMilli round trip" :expected "1234" :actual "(.toEpochMilli (Instant/ofEpochMilli 1234))" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "CLOCK_HOUR_OF_DAY midnight is 24" :expected "24" :actual "(.getLong (java.time.LocalTime/of 0 30) java.time.temporal.ChronoField/CLOCK_HOUR_OF_DAY)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "HOUR_OF_AMPM" :expected "2" :actual "(.getLong (java.time.LocalTime/of 14 0) java.time.temporal.ChronoField/HOUR_OF_AMPM)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "CLOCK_HOUR_OF_AMPM noon is 12" :expected "12" :actual "(.getLong (java.time.LocalTime/of 12 0) java.time.temporal.ChronoField/CLOCK_HOUR_OF_AMPM)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "ALIGNED_DAY_OF_WEEK_IN_MONTH" :expected "3" :actual "(.getLong (java.time.LocalDate/of 2020 3 17) java.time.temporal.ChronoField/ALIGNED_DAY_OF_WEEK_IN_MONTH)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "ALIGNED_WEEK_OF_MONTH" :expected "3" :actual "(.getLong (java.time.LocalDate/of 2020 3 17) java.time.temporal.ChronoField/ALIGNED_WEEK_OF_MONTH)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "Year isSupported + getLong" :expected "2020" :actual "(.getLong (java.time.Year/of 2020) java.time.temporal.ChronoField/YEAR)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "YearMonth PROLEPTIC_MONTH" :expected "24244" :actual "(.getLong (java.time.YearMonth/of 2020 5) java.time.temporal.ChronoField/PROLEPTIC_MONTH)" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "ISO_OFFSET_DATE_TIME keeps fractional seconds" :expected "1594033153417" :actual "(.toEpochMilli (.toInstant (java.time.ZonedDateTime/parse \"2020-07-06T10:59:13.417Z\" java.time.format.DateTimeFormatter/ISO_OFFSET_DATE_TIME)))" :portability :jvm} - {:suite "interop / java.time chrono-fields" :label "ISO_OFFSET_DATE_TIME without fraction" :expected "1594033153000" :actual "(.toEpochMilli (.toInstant (java.time.ZonedDateTime/parse \"2020-07-06T10:59:13Z\" java.time.format.DateTimeFormatter/ISO_OFFSET_DATE_TIME)))" :portability :jvm} - {:suite "interop / java.util Optional" :label "of + get" :expected "42" :actual "(.get (java.util.Optional/of 42))" :portability :jvm} - {:suite "interop / java.util Optional" :label "empty isPresent" :expected "false" :actual "(.isPresent (java.util.Optional/empty))" :portability :jvm} - {:suite "interop / java.util Optional" :label "value equality" :expected "true" :actual "(= (java.util.Optional/of 5) (java.util.Optional/of 5))" :portability :jvm} - {:suite "interop / java.util Optional" :label "empty orElse" :expected "7" :actual "(.orElse (java.util.Optional/empty) 7)" :portability :jvm} - {:suite "interop / java.util Optional" :label "ofNullable nil is empty" :expected "true" :actual "(= (java.util.Optional/empty) (java.util.Optional/ofNullable nil))" :portability :jvm} - {:suite "interop / class + isa?" :label "forName throws for unknown class" :expected ":cnfe" :actual "(try (do (Class/forName \"totally.Bogus.Class\") :found) (catch ClassNotFoundException e :cnfe))" :portability :jvm} - {:suite "interop / class + isa?" :label "PersistentHashSet isa java.util.Set" :expected "true" :actual "(isa? clojure.lang.PersistentHashSet java.util.Set)" :portability :jvm} - {:suite "interop / class + isa?" :label "String isa Object" :expected "true" :actual "(isa? java.lang.String java.lang.Object)" :portability :jvm} - {:suite "interop / class + isa?" :label "IFn isa Object" :expected "true" :actual "(isa? clojure.lang.IFn java.lang.Object)" :portability :jvm} - {:suite "interop / class + isa?" :label "class of vector" :expected "true" :actual "(= clojure.lang.PersistentVector (class [1]))" :portability :jvm} - {:suite "interop / class + isa?" :label "isa? class keyword Object" :expected "true" :actual "(isa? (class :k) java.lang.Object)" :portability :jvm} - {:suite "interop / java.time shims" :label "Instant/now is current" :expected "true" :actual "(> (.toEpochMilli (Instant/now)) 1500000000000)" :portability :jvm} - {:suite "interop / java.time shims" :label "sql types are not" :expected "false" :actual "(instance? java.sql.Timestamp #inst \"2020-01-01T00:00:00Z\")" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "StringReader read" :expected "[97 98 -1]" :actual "(let [r (java.io.StringReader. \"ab\")] [(.read r) (.read r) (.read r)])" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "mark/reset" :expected "[97 97]" :actual "(let [r (StringReader. \"ab\")] (.mark r 1) [(.read r) (do (.reset r) (.read r))])" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "StringBuilder append" :expected "\"ab1\"" :actual "(.toString (-> (StringBuilder.) (.append \"a\") (.append \\b) (.append 1)))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "capacity arg is not content" :expected "\"x\"" :actual "(.toString (.append (StringBuilder. 16) \"x\"))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "setLength truncates" :expected "\"ab\"" :actual "(let [sb (StringBuilder.)] (.append sb \"abcd\") (.setLength sb 2) (.toString sb))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "char-array of string" :expected "true" :actual "(instance? (Class/forName \"[C\") (char-array \"ab\"))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "reader over char[]" :expected "97" :actual "(do (require (quote clojure.java.io)) (.read (clojure.java.io/reader (char-array \"abc\"))))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "with-open closes shim" :expected "97" :actual "(with-open [r (StringReader. \"a\")] (.read r))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "File.toURL methods read it back" :expected "\"file:/tmp/x\"" :actual "(do (require (quote clojure.java.io)) (.toString (.toURL (clojure.java.io/file \"/tmp/x\"))))" :portability :jvm} - {:suite "interop / StringReader & StringBuilder" :label "vector :import shares deftype ctor" :expected "\"hi!\"" :actual "(do (ns spec.nodea) (defprotocol SpecP (spec-pm [this])) (deftype SpecTN [t] SpecP (spec-pm [this] (str t \"!\"))) (ns spec.nodeb (:import [spec.nodea SpecTN])) (.spec-pm (SpecTN. \"hi\")))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "PushbackReader read" :expected "[97 98]" :actual "(let [r (java.io.PushbackReader. (java.io.StringReader. \"ab\"))] [(.read r) (.read r)])" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "unread pushes back" :expected "[97 97 98]" :actual "(let [r (PushbackReader. (StringReader. \"ab\")) a (.read r)] (.unread r a) [a (.read r) (.read r)])" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "unread accepts a char" :expected "[120 97]" :actual "(let [r (PushbackReader. (StringReader. \"a\"))] (.unread r \\x) [(.read r) (.read r)])" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "edn/read from reader" :expected "5432" :actual "(do (require (quote clojure.edn)) (clojure.edn/read (java.io.PushbackReader. (java.io.StringReader. \"{:db {:port 5432}}\\nrest\"))) (get-in (clojure.edn/read-string \"{:db {:port 5432}}\") [:db :port]))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "edn/read multi-line" :expected "true" :actual "(do (require (quote clojure.edn)) (= {:a 1 :b 2} (clojure.edn/read (PushbackReader. (StringReader. \"{:a 1\\n :b 2}\")))))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "Long/parseLong" :expected "42" :actual "(Long/parseLong \"42\")" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "parseLong rejects non-numeric" :expected :throws :actual "(Long/parseLong \"4x\")" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "BigInteger." :expected "123" :actual "(BigInteger. \"123\")" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "Boolean/parseBoolean" :expected "[true false false]" :actual "[(Boolean/parseBoolean \"true\") (Boolean/parseBoolean \"false\") (Boolean/parseBoolean \"yes\")]" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "System/getenv is a map" :expected "true" :actual "(string? (get (System/getenv) \"HOME\"))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "System/exit resolves" :expected "true" :actual "(fn? System/exit)" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "getenv entries destructure (non-empty)" :expected "true" :actual "(let [es (map (fn [[k v]] [k v]) (System/getenv))] (and (pos? (count es)) (every? vector? es)))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "seq over a raw host table" :expected "true" :actual "(pos? (count (seq (System/getenv))))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "into {} from host table" :expected "true" :actual "(string? (get (into {} (map (fn [[k v]] [k v]) (System/getenv))) \"HOME\"))" :portability :jvm} - {:suite "interop / PushbackReader & parse statics" :label "System/getProperties" :expected "true" :actual "(string? (get (System/getProperties) \"os.name\"))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "URLEncoder www form" :expected "\"a+b%3Dc\"" :actual "(URLEncoder/encode \"a b=c\")" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "URLDecoder www form" :expected "\"a b=c\"" :actual "(URLDecoder/decode \"a+b%3Dc\" (Charset/forName \"UTF-8\"))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "url round trip" :expected "\"x &=%?\"" :actual "(URLDecoder/decode (URLEncoder/encode \"x &=%?\"))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "Base64 encode" :expected "\"aGVsbG8=\"" :actual "(String. (.encode (Base64/getEncoder) (.getBytes \"hello\")))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "Base64 round trip" :expected "\"hello\"" :actual "(String. (.decode (Base64/getDecoder) (String. (.encode (Base64/getEncoder) (.getBytes \"hello\")))))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "Integer radix + byteValue" :expected "-1" :actual "(.byteValue (Integer/valueOf \"ff\" 16))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "Integer parseInt" :expected "255" :actual "(Integer/parseInt \"ff\" 16)" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "StringTokenizer" :expected "[\"a=1\" \"b=2\"]" :actual "(let [t (StringTokenizer. \"a=1&b=2\" \"&\")] [(.nextToken t) (.nextToken t)])" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "MapEntry key/val" :expected "[:a 1]" :actual "(let [e (MapEntry. :a 1)] [(key e) (val e)])" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "String ctor from bytes" :expected "\"hi\"" :actual "(String. (.getBytes \"hi\"))" :portability :jvm} - {:suite "host-interop / ring-codec surface" :label "extend-protocol Map" :expected ":map" :actual "(do (defprotocol Pe (pe [x])) (extend-protocol Pe Map (pe [m] :map) Object (pe [o] :obj)) (pe {:a 1}))" :portability :common} - {:suite "host-interop / ring-codec surface" :label "extend-protocol nil" :expected ":nil" :actual "(do (defprotocol Pn (pn [x])) (extend-protocol Pn nil (pn [n] :nil) Object (pn [o] :obj)) (pn nil))" :portability :common} - {:suite "host-interop / ring-codec surface" :label "extend-protocol Map covers sorted" :expected ":map" :actual "(do (defprotocol Ps (ps [x])) (extend-protocol Ps Map (ps [m] :map) Object (ps [o] :obj)) (ps (sorted-map 1 2)))" :portability :common} - {:suite "host-interop / ring-codec surface" :label "reduce over reified IReduceInit" :expected "42" :actual "(reduce + 0 (reify clojure.lang.IReduceInit (reduce [_ f init] (f (f init 40) 2))))" :portability :jvm} - {:suite "core / reify" :label "multi-arity method dispatches by arg count" :expected "[:z 9]" :actual "(do (defprotocol P (m [_] [_ a])) (let [r (reify P (m [_] :z) (m [_ x] x))] [(m r) (m r 9)]))" :portability :common} - {:suite "core / reify" :label "reify implements IObj and carries metadata" :expected "[true 2]" :actual "(do (defprotocol Q (qq [_])) (let [r (reify Q (qq [_] 1))] [(instance? clojure.lang.IObj r) (:k (meta (with-meta r {:k 2})))]))" :portability :jvm} - {:suite "core / reify" :label "with-meta leaves the original untouched and keeps dispatch" :expected "[nil {:k 2} 1]" :actual "(do (defprotocol Q (qq [_])) (let [r (reify Q (qq [_] 1)) r2 (with-meta r {:k 2})] [(meta r) (meta r2) (qq r2)]))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "class name evaluates to canonical string" :expected "java.lang.String" :actual "String" :portability :common} - {:suite "host-interop / class tokens & readers" :label "dispatch-only class name" :expected "\"java.io.InputStream\"" :actual "InputStream" :portability :common} - {:suite "host-interop / class tokens & readers" :label "(class x) matches the token" :expected "true" :actual "(= String (class \"abc\"))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "defmulti on class dispatches" :expected ":str" :actual "(do (defmulti cm (fn [x] (class x))) (defmethod cm String [x] :str) (cm \"a\"))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "defmethod on nil dispatch value" :expected ":nil" :actual "(do (defmulti cn (fn [x] (class x))) (defmethod cn nil [x] :nil) (defmethod cn String [x] :str) (cn nil))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "Class str is class-prefixed" :expected "\"class java.lang.String\"" :actual "(str (class \"\"))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "Class getName" :expected "\"java.lang.String\"" :actual "(.getName (class \"\"))" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "Class getSimpleName" :expected "\"Long\"" :actual "(.getSimpleName (class 5))" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "Class of equal-typed values is =" :expected "true" :actual "(= (class 5) (class 6))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "Class in a thrown message" :expected "\"of class java.lang.String\"" :actual "(try (throw (Exception. (str \"of \" (class \"\")))) (catch Exception e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "ctor sugar still constructs" :expected "\"x\"" :actual "(.toString (StringBuilder. \"x\"))" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "return-hinted defn parses" :expected "7" :actual "(do (defn- hb ^bytes [b] b) (hb 7))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "hinted multi-arity parses" :expected ":two" :actual "((fn ([x] :one) (^String [x y] :two)) 1 2)" :portability :common} - {:suite "host-interop / class tokens & readers" :label "slurp drains a StringReader" :expected "\"a=1\"" :actual "(slurp (StringReader. \"a=1\"))" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "slurp accepts :encoding opts" :expected "\"b\"" :actual "(slurp (StringReader. \"b\") :encoding \"UTF-8\")" :portability :jvm} - {:suite "host-interop / class tokens & readers" :label "replace with fn replacement is literal" :expected "\"$0\"" :actual "(do (require (quote [clojure.string :as s9])) (s9/replace \"x\" #\".\" (fn [m] \"$0\")))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "replace fn gets group vector" :expected "\"v=k\"" :actual "(do (require (quote [clojure.string :as s9])) (s9/replace \"k=v\" #\"(\\w+)=(\\w+)\" (fn [[_ k v]] (str v \"=\" k))))" :portability :common} - {:suite "host-interop / class tokens & readers" :label "indexOf int needle is a char code" :expected "1" :actual "(.indexOf \"a=b\" 61)" :portability :jvm} - {:suite "host-interop / exception + HashMap shims" :label "getMessage on a thrown string" :expected "\"class java.lang.String cannot be cast to class java.lang.Throwable (java.lang.String and java.lang.Throwable are in module java.base of loader 'bootstrap')\"" :actual "(try (throw \"boom\") (catch Throwable e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / exception + HashMap shims" :label "getMessage on ex-info" :expected "\"bad\"" :actual "(try (throw (ex-info \"bad\" {})) (catch Throwable e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / exception + HashMap shims" :label "calling a non-fn throws ClassCastException" :expected ":ccx" :actual "(try (1 2) (catch ClassCastException _ :ccx))" :portability :common} - {:suite "host-interop / exception + HashMap shims" :label "non-fn cast is a RuntimeException too" :expected ":rt" :actual "(try ((identity 5)) (catch RuntimeException _ :rt))" :portability :common} - {:suite "host-interop / exception + HashMap shims" :label "HashMap get" :expected "2" :actual "(let [m (HashMap. {:a 1 :b 2})] (.get m :b))" :portability :jvm} - {:suite "host-interop / exception + HashMap shims" :label "HashMap put + size" :expected "2" :actual "(let [m (HashMap. {})] (.put m :x 1) (.put m :y 2) (.size m))" :portability :jvm} - {:suite "host-interop / reader-feature toggle" :label "features default to jolt+default" :expected "true" :actual "(contains? (set (__reader-features)) \"jolt\")" :portability :common} - {:suite "host-interop / reader-feature toggle" :label "set + read back" :expected "true" :actual "(do (def prev (__reader-features)) (__reader-features-set! [\"clj\" \"jolt\" \"default\"]) (def r (contains? (set (__reader-features)) \"clj\")) (__reader-features-set! prev) r)" :portability :common} - {:suite "host-interop / reader-feature toggle" :label "restore returns to default" :expected "false" :actual "(do (def prev (__reader-features)) (__reader-features-set! [\"clj\"]) (__reader-features-set! prev) (contains? (set (__reader-features)) \"clj\"))" :portability :common} - {:suite "host-interop / migratus class shims" :label "Exception. message" :expected "\"boom\"" :actual "(try (throw (Exception. \"boom\")) (catch Throwable e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "IllegalArgumentException." :expected "\"bad\"" :actual "(try (throw (IllegalArgumentException. \"bad\")) (catch Exception e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "InterruptedException." :expected "\"stop\"" :actual "(try (throw (InterruptedException. \"stop\")) (catch Throwable e (.getMessage e)))" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Character/isUpperCase" :expected "true" :actual "(Character/isUpperCase \\A)" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Character/isLowerCase" :expected "true" :actual "(Character/isLowerCase \\a)" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Character/isUpperCase neg" :expected "false" :actual "(Character/isUpperCase \\a)" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Thread/interrupted" :expected "false" :actual "(Thread/interrupted)" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Long/valueOf" :expected "42" :actual "(Long/valueOf \"42\")" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "Timestamp is millis" :expected "1000" :actual "(.getTime (java.util.Date. (java.sql.Timestamp. 1000)))" :portability :jvm} - {:suite "host-interop / migratus class shims" :label "SimpleDateFormat UTC" :expected "\"19700101000000\"" :actual "(let [f (doto (java.text.SimpleDateFormat. \"yyyyMMddHHmmss\") (.setTimeZone (java.util.TimeZone/getTimeZone \"UTC\")))] (.format f (java.util.Date. 0)))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "instance? File" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (instance? java.io.File (io/file \"/a/b\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "str is the path" :expected "\"/a/b\"" :actual "(do (require '[clojure.java.io :as io]) (str (io/file \"/a/b\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "getName" :expected "\"c.txt\"" :actual "(do (require '[clojure.java.io :as io]) (.getName (io/file \"/a/b/c.txt\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "getPath joins" :expected "\"/a/b\"" :actual "(do (require '[clojure.java.io :as io]) (.getPath (io/file \"/a\" \"b\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "isDirectory of repo dir" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (.isDirectory (io/file \"docs\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "isFile of repo file" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (.isFile (io/file \"README.md\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "exists is false off-disk" :expected "false" :actual "(do (require '[clojure.java.io :as io]) (.exists (io/file \"/no/such/path/xyz\")))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "file-seq yields File values" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (every? (fn [f] (instance? java.io.File f)) (file-seq (io/file \"docs\"))))" :portability :jvm} - {:suite "host-interop / java.io.File" :label "file-seq finds files" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (pos? (count (filter (fn [f] (.isFile f)) (file-seq (io/file \"docs\"))))))" :portability :jvm} - {:suite "host-interop / logging host shims" :label "LockingTransaction/isRunning" :expected "false" :actual "(clojure.lang.LockingTransaction/isRunning)" :portability :jvm} - {:suite "host-interop / logging host shims" :label "pprint writes value" :expected "\"[1 2 3]\\n\"" :actual "(do (require '[clojure.pprint :as pp]) (with-out-str (pp/pprint [1 2 3])))" :portability :common} - {:suite "host-interop / logging host shims" :label "with-pprint-dispatch runs body" :expected "42" :actual "(do (require '[clojure.pprint :as pp]) (pp/with-pprint-dispatch pp/code-dispatch 42))" :portability :common} - {:suite "host-interop / macro dispatch & short-circuit patterns" :label "conditional-eval suppresses" :expected "0" :actual "(do (def ^:dynamic *enabled* false) (defmacro when-on [& body] `(when *enabled* ~@body)) (let [a (atom 0)] (when-on (reset! a 9)) @a))" :portability :common} - {:suite "host-interop / macro dispatch & short-circuit patterns" :label "conditional-eval fires" :expected "9" :actual "(do (def ^:dynamic *enabled* true) (defmacro when-on [& body] `(when *enabled* ~@body)) (let [a (atom 0)] (when-on (reset! a 9)) @a))" :portability :common} - {:suite "host-interop / macro dispatch & short-circuit patterns" :label "spy-like eval+print+return" :expected "3" :actual "(do (defmacro spylog [expr] `(let [v# ~expr] (println v#) v#)) (spylog (+ 1 2)))" :portability :common} - {:suite "host-interop / macro dispatch & short-circuit patterns" :label "multi-arity 4 dispatch" :expected "[:single :double :triple :quad]" :actual "(do (defmacro ml ([a] :single) ([a b] :double) ([a b c] :triple) ([a b c d] :quad)) [(ml 1) (ml 1 2) (ml 1 2 3) (ml 1 2 3 4)])" :portability :common} - {:suite "inst / reading & identity" :label "reads to inst" :expected "true" :actual "(inst? #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / reading & identity" :label "inst? false on string" :expected "false" :actual "(inst? \"2020-01-01\")" :portability :common} - {:suite "inst / reading & identity" :label "epoch zero" :expected "0" :actual "(inst-ms #inst \"1970-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / reading & identity" :label "one second" :expected "1000" :actual "(inst-ms #inst \"1970-01-01T00:00:01Z\")" :portability :common} - {:suite "inst / reading & identity" :label "millis" :expected "123" :actual "(inst-ms #inst \"1970-01-01T00:00:00.123Z\")" :portability :common} - {:suite "inst / reading & identity" :label "a real date" :expected "1577836800000" :actual "(inst-ms #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / reading & identity" :label "inst-ms throws on non-inst" :expected :throws :actual "(inst-ms 42)" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "year only" :expected "true" :actual "(= #inst \"2020\" #inst \"2020-01-01T00:00:00.000Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "year-month" :expected "true" :actual "(= #inst \"2020-03\" #inst \"2020-03-01T00:00:00Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "date only" :expected "true" :actual "(= #inst \"2020-03-15\" #inst \"2020-03-15T00:00:00Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "positive offset" :expected "true" :actual "(= #inst \"2020-01-01T01:00:00+01:00\" #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "negative offset" :expected "true" :actual "(= #inst \"2019-12-31T23:00:00-01:00\" #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "-00:00 offset" :expected "true" :actual "(= #inst \"2020-01-01T00:00:00-00:00\" #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "inst / partial timestamps & offsets" :label "bad timestamp throws" :expected :throws :actual "#inst \"garbage\"" :portability :common} - {:suite "inst / value semantics & printing" :label "equal by instant" :expected "true" :actual "(= #inst \"2020-01-01T00:00:00Z\" #inst \"2020-01-01T00:00:00.000Z\")" :portability :common} - {:suite "inst / value semantics & printing" :label "unequal instants" :expected "false" :actual "(= #inst \"2020-01-01T00:00:00Z\" #inst \"2020-01-01T00:00:01Z\")" :portability :common} - {:suite "inst / value semantics & printing" :label "works as map key" :expected ":v" :actual "(get {#inst \"2020-01-01T00:00:00Z\" :v} #inst \"2020-01-01T00:00:00.000Z\")" :portability :common} - {:suite "inst / value semantics & printing" :label "pr-str round-trips" :expected "\"#inst \\\"2020-01-01T00:00:00.000-00:00\\\"\"" :actual "(pr-str #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "io / with-out-str captures" :label "println" :expected "\"hi\\n\"" :actual "(with-out-str (println \"hi\"))" :portability :common} - {:suite "io / with-out-str captures" :label "print spaces" :expected "\"a b\"" :actual "(with-out-str (print \"a\" \"b\"))" :portability :common} - {:suite "io / with-out-str captures" :label "prn quotes" :expected "\"[1 2]\\n\"" :actual "(with-out-str (prn [1 2]))" :portability :common} - {:suite "io / with-out-str captures" :label "pr no newline" :expected "\"5\"" :actual "(with-out-str (pr 5))" :portability :common} - {:suite "io / with-out-str captures" :label "multiple writes" :expected "\"12\"" :actual "(with-out-str (print 1) (print 2))" :portability :common} - {:suite "io / with-out-str captures" :label "no output" :expected "\"\"" :actual "(with-out-str 42)" :portability :common} - {:suite "io / with-out-str captures" :label "println no args" :expected "\"\\n\"" :actual "(with-out-str (println))" :portability :common} - {:suite "io / *-str builders" :label "print-str" :expected "\"a b\"" :actual "(print-str \"a\" \"b\")" :portability :common} - {:suite "io / *-str builders" :label "println-str" :expected "\"x\\n\"" :actual "(println-str \"x\")" :portability :common} - {:suite "io / *-str builders" :label "prn-str" :expected "\"[1 2]\\n\"" :actual "(prn-str [1 2])" :portability :common} - {:suite "io / *-str builders" :label "pr-str quotes" :expected "\"\\\"s\\\"\"" :actual "(pr-str \"s\")" :portability :common} - {:suite "io / *-str builders" :label "pr-str keyword" :expected "\":a\"" :actual "(pr-str :a)" :portability :common} - {:suite "io / str & format" :label "str concat" :expected "\"1:ab\"" :actual "(str 1 :a \"b\")" :portability :common} - {:suite "io / str & format" :label "str nil" :expected "\"\"" :actual "(str nil)" :portability :common} - {:suite "io / str & format" :label "str of coll" :expected "\"[1 2]\"" :actual "(str [1 2])" :portability :common} - {:suite "io / str & format" :label "format d/s" :expected "\"5-x\"" :actual "(format \"%d-%s\" 5 \"x\")" :portability :common} - {:suite "io / str & format" :label "format float" :expected "\"3.14\"" :actual "(format \"%.2f\" 3.14159)" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "read-line one line" :expected "\"hello\"" :actual "(with-in-str \"hello\" (read-line))" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "read-line strips nl" :expected "\"a\"" :actual "(with-in-str \"a\\nb\" (read-line))" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "read-line sequential" :expected "[\"a\" \"b\"]" :actual "(with-in-str \"a\\nb\" [(read-line) (read-line)])" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "read-line EOF nil" :expected "nil" :actual "(with-in-str \"\" (read-line))" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "read-line after last" :expected "[\"x\" nil]" :actual "(with-in-str \"x\" [(read-line) (read-line)])" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "empty line" :expected "[\"\" \"y\"]" :actual "(with-in-str \"\\ny\" [(read-line) (read-line)])" :portability :common} - {:suite "io / *in* + with-in-str + read-line" :label "*in* is bound" :expected "false" :actual "(with-in-str \"\" (map? *in*))" :portability :common} - {:suite "io / read" :label "read a form" :expected "42" :actual "(with-in-str \"42\" (read))" :portability :common} - {:suite "io / read" :label "read a list form" :expected "(quote (+ 1 2))" :actual "(with-in-str \"(+ 1 2)\" (read))" :portability :common} - {:suite "io / read" :label "read two forms" :expected "[1 2]" :actual "(with-in-str \"1 2\" [(read) (read)])" :portability :common} - {:suite "io / read" :label "read then read-line" :expected "[1 \" rest\"]" :actual "(with-in-str \"1 rest\\nnext\" [(read) (read-line)])" :portability :common} - {:suite "io / read" :label "read vector" :expected "[1 2]" :actual "(with-in-str \"[1 2]\" (read))" :portability :common} - {:suite "io / read" :label "read nil literal" :expected "nil" :actual "(with-in-str \"nil\" (read))" :portability :common} - {:suite "io / read" :label "read EOF throws" :expected :throws :actual "(with-in-str \"\" (read))" :portability :common} - {:suite "io / read" :label "read EOF value" :expected ":done" :actual "(with-in-str \"\" (read *in* false :done))" :portability :common} - {:suite "io / read" :label "read eval data" :expected "3" :actual "(with-in-str \"(+ 1 2)\" (eval (read)))" :portability :common} - {:suite "io / line-seq" :label "line-seq" :expected "[\"a\" \"b\" \"c\"]" :actual "(with-in-str \"a\\nb\\nc\" (vec (line-seq *in*)))" :portability :common} - {:suite "io / line-seq" :label "line-seq empty" :expected "nil" :actual "(with-in-str \"\" (seq (line-seq *in*)))" :portability :common} - {:suite "io / line-seq" :label "line-seq is lazy seq" :expected "true" :actual "(with-in-str \"a\\nb\" (seq? (line-seq *in*)))" :portability :common} - {:suite "io / line-seq" :label "line-seq count" :expected "3" :actual "(with-in-str \"1\\n2\\n3\" (count (line-seq *in*)))" :portability :common} - {:suite "io / print family (overlay)" :label "pr-str multi-arg spacing" :expected "\"\\\"a\\\" [1 2] :k\"" :actual "(pr-str \"a\" [1 2] :k)" :portability :common} - {:suite "io / print family (overlay)" :label "pr-str zero args" :expected "\"\"" :actual "(pr-str)" :portability :common} - {:suite "io / print family (overlay)" :label "pr-str escapes" :expected "\"\\\"a\\\\\\\"b\\\"\"" :actual "(pr-str \"a\\\"b\")" :portability :common} - {:suite "io / print family (overlay)" :label "print is unreadable" :expected "\"a b\"" :actual "(with-out-str (print \"a\" \"b\"))" :portability :common} - {:suite "io / print family (overlay)" :label "println appends newline" :expected "\"x 1\\n\"" :actual "(with-out-str (println \"x\" 1))" :portability :common} - {:suite "io / print family (overlay)" :label "prn is readable + newline" :expected "\"[1 \\\"s\\\"]\\n\"" :actual "(with-out-str (prn [1 \"s\"]))" :portability :common} - {:suite "io / print family (overlay)" :label "pr writes no newline" :expected "\"\\\\a\"" :actual "(with-out-str (pr \\a))" :portability :common} - {:suite "io / print family (overlay)" :label "print nil arg" :expected "\"nil\"" :actual "(with-out-str (print nil))" :portability :common} - {:suite "io / print family (overlay)" :label "prn keyword" :expected "\":k\\n\"" :actual "(with-out-str (prn :k))" :portability :common} - {:suite "io / print-method multimethod" :label "records print canonically" :expected "\"#user.Pt{:x 1, :y 2}\"" :actual "(do (defrecord Pt [x y]) (pr-str (->Pt 1 2)))" :portability :common} - {:suite "io / print-method multimethod" :label "records nested in colls" :expected "\"[#user.Pt{:x 1, :y 2}]\"" :actual "(do (defrecord Pt [x y]) (pr-str [(->Pt 1 2)]))" :portability :common} - {:suite "io / print-method multimethod" :label "defmethod overrides a record, top level" :expected "\"#user.Pt{:x 3, :y 4}\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (pr-str (->Pt 3 4)))" :portability :jvm} - {:suite "io / print-method multimethod" :label "defmethod fires nested in a map" :expected "\"{:p #user.Pt{:x 5, :y 6}}\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (pr-str {:p (->Pt 5 6)}))" :portability :jvm} - {:suite "io / print-method multimethod" :label "defmethod fires through prn" :expected "\"[#user.Pt{:x 1, :y 2}]\\n\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (with-out-str (prn [(->Pt 1 2)])))" :portability :jvm} - {:suite "io / print-method multimethod" :label "direct call uses :default" :expected "\"42\"" :actual "(let [w (StringWriter.)] (print-method 42 w) (.toString w))" :portability :jvm} - {:suite "io / print-method multimethod" :label "direct builtin override" :expected "\"#42#\"" :actual "(do (defmethod print-method :number [n w] (.write w (str \"#\" n \"#\"))) (let [w (StringWriter.)] (print-method 42 w) (.toString w)))" :portability :jvm} - {:suite "io / print-method multimethod" :label "print-dup routes to print-method" :expected "\"[1 2]\"" :actual "(let [w (StringWriter.)] (print-dup [1 2] w) (.toString w))" :portability :jvm} - {:suite "io / print-method multimethod" :label "StringWriter accumulates" :expected "\"ab\"" :actual "(let [w (StringWriter.)] (.write w \"a\") (.append w \\b) (.toString w))" :portability :jvm} - {:suite "io / print-method multimethod" :label "methods table inspectable" :expected "true" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] r) (contains? (methods print-method) (quote user.Pt)))" :portability :common} - {:suite "io / cold tagged types via print-method" :label "uuid" :expected "\"#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"\"" :actual "(pr-str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "io / cold tagged types via print-method" :label "uuid nested" :expected "\"[#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"]\"" :actual "(pr-str [(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")])" :portability :common} - {:suite "io / cold tagged types via print-method" :label "regex" :expected "\"#\\\"a+b\\\"\"" :actual "(pr-str #\"a+b\")" :portability :common} - {:suite "io / cold tagged types via print-method" :label "transient vector" :expected "\"#object[clojure.lang.PersistentVector$TransientVector 0xa4ac20b \\\"clojure.lang.PersistentVector$TransientVector@a4ac20b\\\"]\"" :actual "(pr-str (transient [1]))" :portability :common} - {:suite "io / cold tagged types via print-method" :label "transient map" :expected "\"#object[clojure.lang.PersistentArrayMap$TransientArrayMap 0x79939c8 \\\"clojure.lang.PersistentArrayMap$TransientArrayMap@79939c8\\\"]\"" :actual "(pr-str (transient {:a 1}))" :portability :common} - {:suite "io / cold tagged types via print-method" :label "atom override fires nested" :expected "\"{:a #object[clojure.lang.Atom 0x2bb39d6c {:status :ready, :val 7}]}\"" :actual "(do (defmethod print-method :jolt/atom [a w] (.write w (str \"#atom[\" (deref a) \"]\"))) (pr-str {:a (atom 7)}))" :portability :jvm} - {:suite "io / cold tagged types via print-method" :label "uuid through str unchanged" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "ISeq call forms" :label "eval a cons'd call" :expected "3" :actual "(eval (cons (quote +) (quote (1 2))))" :portability :common} - {:suite "ISeq call forms" :label "eval a list-built call" :expected "6" :actual "(eval (list (quote +) 1 2 3))" :portability :common} - {:suite "ISeq call forms" :label "eval a concat'd call" :expected "10" :actual "(eval (concat (list (quote +)) (list 1 2 3 4)))" :portability :common} - {:suite "ISeq call forms" :label "nested cons'd subform" :expected "7" :actual "(eval (list (quote +) 3 (cons (quote +) (quote (1 3)))))" :portability :common} - {:suite "ISeq call forms" :label "empty list self-evals" :expected "[]" :actual "(eval (list))" :portability :common} - {:suite "ISeq call forms" :label "macro output via cons" :expected "3" :actual "(do (defmacro mc [] (cons (quote +) (quote (1 2)))) (mc))" :portability :common} - {:suite "ISeq call forms" :label "macro output via concat" :expected "6" :actual "(do (defmacro mk [] (concat (list (quote +)) (list 1 2 3))) (mk))" :portability :common} - {:suite "ISeq call forms" :label "vector value self-evals" :expected "[1 2 3]" :actual "(eval (vec [1 2 3]))" :portability :common} - {:suite "ISeq call forms" :label "quoted list of data" :expected "[1 2 3]" :actual "(quote (1 2 3))" :portability :common} - {:suite "lazy / construction & laziness" :label "lazy-seq value" :expected "[1 2 3]" :actual "(take 3 (lazy-seq (cons 1 (lazy-seq (cons 2 (lazy-seq (cons 3 nil)))))))" :portability :common} - {:suite "lazy / construction & laziness" :label "not eagerly evaluated" :expected "0" :actual "(let [c (atom 0)] (lazy-seq (swap! c inc) nil) @c)" :portability :common} - {:suite "lazy / construction & laziness" :label "realized on demand" :expected "1" :actual "(let [c (atom 0) s (lazy-seq (swap! c inc) [1])] (first s) @c)" :portability :common} - {:suite "lazy / construction & laziness" :label "lazy-cat" :expected "[0 1 2 3]" :actual "(lazy-cat [0 1] [2 3])" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "map" :expected "0" :actual "(let [a (atom 0)] (map (fn [x] (swap! a inc) x) (range 5)) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "filter" :expected "0" :actual "(let [a (atom 0)] (filter (fn [x] (swap! a inc) true) (range 5)) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "remove" :expected "0" :actual "(let [a (atom 0)] (remove (fn [x] (swap! a inc) false) (range 5)) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "take over a lazy source" :expected "0" :actual "(let [a (atom 0)] (take 3 (map (fn [x] (swap! a inc) x) (range 100))) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "drop over a lazy source" :expected "0" :actual "(let [a (atom 0)] (drop 2 (map (fn [x] (swap! a inc) x) (range 100))) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "concat over lazy sources" :expected "0" :actual "(let [a (atom 0)] (concat (map (fn [x] (swap! a inc) x) [1 2]) (map (fn [x] (swap! a inc) x) [3 4])) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "take-while" :expected "0" :actual "(let [a (atom 0)] (take-while (fn [x] (swap! a inc) true) (range 5)) @a)" :portability :common} - {:suite "lazy / seq fns are lazy (no side effect at construction)" :label "partition over a lazy source" :expected "0" :actual "(let [a (atom 0)] (partition 2 (map (fn [x] (swap! a inc) x) (range 6))) @a)" :portability :common} - {:suite "lazy / result type is LazySeq" :label "map/filter/take/concat/mapcat are LazySeq" :expected "[true true true true true]" :actual "(mapv #(instance? clojure.lang.LazySeq %) [(map inc [1]) (filter odd? [1]) (take 1 [1]) (concat [1]) (mapcat list [1])])" :portability :jvm} - {:suite "lazy / construction & laziness" :label "doall forces" :expected "[2 3 4]" :actual "(doall (map inc [1 2 3]))" :portability :common} - {:suite "lazy / construction & laziness" :label "dorun returns nil" :expected "nil" :actual "(dorun (map inc [1 2 3]))" :portability :common} - {:suite "lazy / infinite" :label "take from repeat" :expected "[7 7 7]" :actual "(take 3 (repeat 7))" :portability :common} - {:suite "lazy / infinite" :label "take from iterate" :expected "[1 2 4 8]" :actual "(take 4 (iterate (fn [x] (* 2 x)) 1))" :portability :common} - {:suite "lazy / infinite" :label "take from cycle" :expected "[1 2 1 2]" :actual "(take 4 (cycle [1 2]))" :portability :common} - {:suite "lazy / infinite" :label "take from range" :expected "[0 1 2]" :actual "(take 3 (range))" :portability :common} - {:suite "lazy / infinite" :label "drop then take" :expected "[5 6 7]" :actual "(take 3 (drop 5 (range)))" :portability :common} - {:suite "lazy / infinite" :label "filter infinite" :expected "[0 2 4]" :actual "(take 3 (filter even? (range)))" :portability :common} - {:suite "lazy / infinite" :label "map infinite" :expected "[0 1 4]" :actual "(take 3 (map (fn [x] (* x x)) (range)))" :portability :common} - {:suite "lazy / infinite" :label "nth of infinite" :expected "100" :actual "(nth (range) 100)" :portability :common} - {:suite "lazy / self-referential" :label "self-ref ones" :expected "[1 1 1 1 1]" :actual "(do (def ones (lazy-seq (cons 1 ones))) (take 5 ones))" :portability :common} - {:suite "lazy / self-referential" :label "self-ref nats" :expected "[0 1 2 3 4]" :actual "(do (def nats (lazy-cat [0] (map inc nats))) (take 5 nats))" :portability :common} - {:suite "lazy / self-referential" :label "self-ref fib" :expected "[0 1 1 2 3 5 8 13 21 34]" :actual "(do (def fib (lazy-cat [0 1] (map + (rest fib) fib))) (take 10 fib))" :portability :common} - {:suite "lazy / realized?" :label "unrealized" :expected "false" :actual "(realized? (lazy-seq (cons 1 nil)))" :portability :common} - {:suite "lazy / realized?" :label "realized after" :expected "true" :actual "(let [s (lazy-seq (cons 1 nil))] (first s) (realized? s))" :portability :common} - {:suite "lazy / realized?" :label "body runs once" :expected "1" :actual "(let [c (atom 0) s (lazy-seq (do (swap! c inc) [1 2 3]))] (seq s) (seq s) @c)" :portability :common} - {:suite "lazy-seq / realization is shared across walks" :label "effects run once across three walks" :expected "3" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) [1 2 3])] (doall s) (dorun s) (vec s) (deref a))" :portability :common} - {:suite "lazy-seq / realization is shared across walks" :label "values stable across walks" :expected "true" :actual "(let [s (map inc [1 2 3])] (= (vec s) (vec s) [2 3 4]))" :portability :common} - {:suite "lazy-seq / realization is shared across walks" :label "filter effects once" :expected "4" :actual "(let [a (atom 0) s (filter (fn [x] (swap! a inc) (odd? x)) [1 2 3 4])] (dorun s) (count s) (deref a))" :portability :common} - {:suite "lazy / realization order & count" :label "map realizes left-to-right" :expected "[1 2 3]" :actual "(let [log (atom [])] (dorun (map (fn [x] (swap! log conj x) x) (list 1 2 3))) @log)" :portability :common} - {:suite "lazy / realization order & count" :label "filter realizes left-to-right" :expected "[1 2 3]" :actual "(let [log (atom [])] (dorun (filter (fn [x] (swap! log conj x) true) (list 1 2 3))) @log)" :portability :common} - {:suite "lazy / realization order & count" :label "take realizes exactly n, no over-realization" :expected "3" :actual "(let [a (atom 0)] (dorun (take 3 (map (fn [x] (swap! a inc) x) (iterate inc 0)))) @a)" :portability :common} - {:suite "lazy / realization order & count" :label "nth realizes exactly index+1" :expected "3" :actual "(let [a (atom 0)] (nth (map (fn [x] (swap! a inc) x) (iterate inc 0)) 2) @a)" :portability :common} - {:suite "lazy / realization order & count" :label "drop+first realizes through the index" :expected "3" :actual "(let [a (atom 0)] (first (drop 2 (map (fn [x] (swap! a inc) x) (iterate inc 0)))) @a)" :portability :common} - {:suite "lazy / realization is memoized" :label "first twice realizes once" :expected "1" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) (iterate inc 0))] (first s) (first s) @a)" :portability :common} - {:suite "lazy / realization is memoized" :label "wider take extends, does not re-realize" :expected "4" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) (iterate inc 0))] (doall (take 2 s)) (doall (take 4 s)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "keep" :expected "0" :actual "(let [a (atom 0)] (keep (fn [x] (swap! a inc) x) (range 5)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "keep-indexed" :expected "0" :actual "(let [a (atom 0)] (keep-indexed (fn [i x] (swap! a inc) x) (range 5)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "map-indexed" :expected "0" :actual "(let [a (atom 0)] (map-indexed (fn [i x] (swap! a inc) x) (range 5)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "distinct" :expected "0" :actual "(let [a (atom 0)] (distinct (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "partition-by" :expected "0" :actual "(let [a (atom 0)] (partition-by (fn [x] (swap! a inc) x) (range 5)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "partition-all" :expected "0" :actual "(let [a (atom 0)] (partition-all 2 (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "interpose" :expected "0" :actual "(let [a (atom 0)] (interpose 0 (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "interleave" :expected "0" :actual "(let [a (atom 0)] (interleave (map (fn [x] (swap! a inc) x) (range 5)) (range 5)) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "take-nth" :expected "0" :actual "(let [a (atom 0)] (take-nth 2 (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "reductions" :expected "0" :actual "(let [a (atom 0)] (reductions + (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "tree-seq" :expected "0" :actual "(let [a (atom 0)] (tree-seq (fn [x] (swap! a inc) false) identity [1 [2]]) @a)" :portability :common} - {:suite "lazy / family is lazy at construction (no side effect)" :label "replace over a seq" :expected "0" :actual "(let [a (atom 0)] (replace {} (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - {:suite "lazy / realization timing" :label "sequence realizes the first element" :expected "1" :actual "(let [a (atom 0)] (sequence (map (fn [x] (swap! a inc) x)) (range 5)) @a)" :portability :common} - {:suite "lazy / realization timing" :label "next realizes head + one lookahead" :expected "2" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) (iterate inc 0))] (next s) @a)" :portability :common} - {:suite "lazy / realization timing" :label "rest realizes only the head" :expected "1" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) (iterate inc 0))] (rest s) @a)" :portability :common} - {:suite "list / construct & predicate" :label "list" :expected "[1 2 3]" :actual "(list 1 2 3)" :portability :common} - {:suite "list / construct & predicate" :label "empty list" :expected "[]" :actual "(list)" :portability :common} - {:suite "list / construct & predicate" :label "quoted list" :expected "[1 2 3]" :actual "(quote (1 2 3))" :portability :common} - {:suite "list / construct & predicate" :label "list? true" :expected "true" :actual "(list? (list 1 2))" :portability :common} - {:suite "list / construct & predicate" :label "list? on conj result" :expected "true" :actual "(list? (conj (list 1) 0))" :portability :common} - {:suite "list / construct & predicate" :label "count" :expected "3" :actual "(count (list 1 2 3))" :portability :common} - {:suite "list / construct & predicate" :label "empty? true" :expected "true" :actual "(empty? (list))" :portability :common} - {:suite "list / construct & predicate" :label "list = vector elts" :expected "true" :actual "(= (list 1 2 3) [1 2 3])" :portability :common} - {:suite "list / access & update" :label "first" :expected "1" :actual "(first (list 1 2 3))" :portability :common} - {:suite "list / access & update" :label "rest" :expected "[2 3]" :actual "(rest (list 1 2 3))" :portability :common} - {:suite "list / access & update" :label "peek is first" :expected "1" :actual "(peek (list 1 2 3))" :portability :common} - {:suite "list / access & update" :label "pop drops first" :expected "[2 3]" :actual "(pop (list 1 2 3))" :portability :common} - {:suite "list / access & update" :label "conj prepends" :expected "[0 1 2]" :actual "(conj (list 1 2) 0)" :portability :common} - {:suite "list / access & update" :label "conj many prepends" :expected "[4 3 1 2]" :actual "(conj (list 1 2) 3 4)" :portability :common} - {:suite "list / access & update" :label "cons prepends" :expected "[0 1 2]" :actual "(cons 0 (list 1 2))" :portability :common} - {:suite "list / access & update" :label "nth" :expected "20" :actual "(nth (list 10 20 30) 1)" :portability :common} - {:suite "list / immutability & performance" :label "conj does not mutate" :expected "true" :actual "(let [l (list 1 2 3) m (conj l 0)] (and (= l [1 2 3]) (= m [0 1 2 3])))" :portability :common} - {:suite "list / immutability & performance" :label "reduce conj builds" :expected "[2 1 0]" :actual "(reduce conj (list) (range 3))" :portability :common} - {:suite "list / immutability & performance" :label "O(1) conj at scale" :expected "200000" :actual "(count (reduce conj (list) (range 200000)))" :portability :common} - {:suite "list / immutability & performance" :label "scale head correct" :expected "199999" :actual "(first (reduce conj (list) (range 200000)))" :portability :common} - {:suite "macros / quoting" :label "quote symbol" :expected "(quote a)" :actual "(quote a)" :portability :common} - {:suite "macros / quoting" :label "quote list" :expected "[1 2 3]" :actual "(quote (1 2 3))" :portability :common} - {:suite "macros / quoting" :label "quote nested" :expected "[1 [2 3]]" :actual "(quote (1 (2 3)))" :portability :common} - {:suite "macros / quoting" :label "quote sugar" :expected "'a" :actual "'a" :portability :common} - {:suite "macros / quoting" :label "syntax-quote literal" :expected "[1 2]" :actual "`[1 2]" :portability :common} - {:suite "macros / quoting" :label "unquote" :expected "[1 2 3]" :actual "(let [x 2] `[1 ~x 3])" :portability :common} - {:suite "macros / quoting" :label "unquote-splicing" :expected "[1 2 3 4]" :actual "(let [xs [2 3]] `[1 ~@xs 4])" :portability :common} - {:suite "macros / quoting" :label "unquote in list" :expected "[3]" :actual "(let [x 3] `(~x))" :portability :common} - {:suite "macros / quoting" :label "syntax-quote symbol qualifies" :expected "true" :actual "(symbol? `foo)" :portability :common} - {:suite "macros / defmacro" :label "simple macro" :expected "3" :actual "(do (defmacro m [a b] `(+ ~a ~b)) (m 1 2))" :portability :common} - {:suite "macros / defmacro" :label "macro unless" :expected "1" :actual "(do (defmacro unless [c body] `(if ~c nil ~body)) (unless false 1))" :portability :common} - {:suite "macros / defmacro" :label "macro with body splice" :expected "6" :actual "(do (defmacro msum [& xs] `(+ ~@xs)) (msum 1 2 3))" :portability :common} - {:suite "macros / defmacro" :label "macroexpand-1" :expected "false" :actual "(do (defmacro m [x] `(inc ~x)) (list? (macroexpand-1 '(m 5))))" :portability :common} - {:suite "macros / defmacro" :label "gensym unique" :expected "false" :actual "(= (gensym) (gensym))" :portability :common} - {:suite "macros / defmacro" :label "gensym# in template" :expected "true" :actual "(do (defmacro m [] `(let [x# 1] x#)) (= 1 (m)))" :portability :common} - {:suite "macros / defmacro" :label "#() inside syntax-quote" :expected "[2 4 6]" :actual "(do (defmacro m [] `(mapv #(* % 2) [1 2 3])) (m))" :portability :common} - {:suite "macros / defmacro" :label "#() + auto-gensym share in template" :expected "\"ab\"" :actual "(do (defmacro m [] `(let [sb# (StringBuilder.)] (mapv #(.append sb# %) [\"a\" \"b\"]) (.toString sb#))) (m))" :portability :jvm} - {:suite "macros / core-overlay" :label "if-not true branch" :expected ":then" :actual "(if-not false :then :else)" :portability :common} - {:suite "macros / core-overlay" :label "if-not else branch" :expected ":else" :actual "(if-not true :then :else)" :portability :common} - {:suite "macros / core-overlay" :label "if-not no else" :expected "nil" :actual "(if-not true :then)" :portability :common} - {:suite "macros / core-overlay" :label "if-not no else hit" :expected ":then" :actual "(if-not false :then)" :portability :common} - {:suite "macros / core-overlay" :label "comment -> nil" :expected "nil" :actual "(comment a b c)" :portability :common} - {:suite "macros / core-overlay" :label "comment in do" :expected "42" :actual "(do (comment ignored) 42)" :portability :common} - {:suite "macros / core-overlay" :label "if-let then" :expected "6" :actual "(if-let [x 5] (inc x) :none)" :portability :common} - {:suite "macros / core-overlay" :label "if-let else" :expected ":none" :actual "(if-let [x nil] (inc x) :none)" :portability :common} - {:suite "macros / core-overlay" :label "if-let else scope" :expected "9" :actual "(let [x 9] (if-let [x nil] :t x))" :portability :common} - {:suite "macros / core-overlay" :label "if-some zero" :expected "1" :actual "(if-some [x 0] (inc x) :none)" :portability :common} - {:suite "macros / core-overlay" :label "if-some nil" :expected ":none" :actual "(if-some [x nil] x :none)" :portability :common} - {:suite "macros / core-overlay" :label "when-some multi" :expected "14" :actual "(when-some [x 7] (inc x) (* x 2))" :portability :common} - {:suite "macros / core-overlay" :label "when-some nil" :expected "nil" :actual "(when-some [x nil] x)" :portability :common} - {:suite "macros / core-overlay" :label "while loop" :expected "3" :actual "(let [a (atom 0)] (while (< @a 3) (swap! a inc)) @a)" :portability :common} - {:suite "macros / core-overlay" :label "dotimes sum" :expected "10" :actual "(let [a (atom 0)] (dotimes [i 5] (swap! a + i)) @a)" :portability :common} - {:suite "macros / core-overlay" :label "as-> threads" :expected "12" :actual "(as-> 5 x (+ x 1) (* x 2))" :portability :common} - {:suite "macros / core-overlay" :label "as-> no forms" :expected "5" :actual "(as-> 5 x)" :portability :common} - {:suite "macros / core-overlay" :label "some-> through" :expected "6" :actual "(some-> {:a {:b 5}} :a :b inc)" :portability :common} - {:suite "macros / core-overlay" :label "some-> short-circuit" :expected "nil" :actual "(some-> {:a nil} :a :b)" :portability :common} - {:suite "macros / core-overlay" :label "some->> through" :expected "9" :actual "(some->> [1 2 3] (map inc) (reduce +))" :portability :common} - {:suite "macros / core-overlay" :label "some->> nil" :expected "nil" :actual "(some->> nil (map inc))" :portability :common} - {:suite "macros / core-overlay" :label "doto returns obj" :expected "[1 2]" :actual "(deref (doto (atom []) (swap! conj 1) (swap! conj 2)))" :portability :common} - {:suite "macros / core-overlay" :label "when-first" :expected "20" :actual "(when-first [x [10 20 30]] (* x 2))" :portability :common} - {:suite "macros / core-overlay" :label "when-first empty" :expected "nil" :actual "(when-first [x []] :body)" :portability :common} - {:suite "macros / core-overlay" :label "when-first nil coll" :expected "nil" :actual "(when-first [x nil] :body)" :portability :common} - {:suite "macros / core-overlay" :label "when-first range" :expected "0" :actual "(when-first [x (range 5)] x)" :portability :common} - {:suite "macros / core-overlay" :label "cond->> threads" :expected "12" :actual "(cond->> 5 true (+ 1) false (* 100) true (* 2))" :portability :common} - {:suite "macros / core-overlay" :label "cond->> skip" :expected "10" :actual "(cond->> 10 false (+ 1))" :portability :common} - {:suite "macros / core-overlay" :label "assert pass" :expected ":ok" :actual "(do (assert (= 1 1)) :ok)" :portability :common} - {:suite "macros / core-overlay" :label "assert throws" :expected ":threw" :actual "(try (assert (= 1 2)) (catch :default e :threw))" :portability :common} - {:suite "macros / core-overlay" :label "assert message" :expected "\"Assert failed: nope\\nfalse\"" :actual "(try (assert false \"nope\") (catch AssertionError e (ex-message e)))" :portability :common} - {:suite "macros / core-overlay" :label "delay value" :expected "42" :actual "(deref (delay 42))" :portability :common} - {:suite "macros / core-overlay" :label "delay forces once" :expected "1" :actual "(let [c (atom 0) d (delay (swap! c inc))] @d @d @c)" :portability :common} - {:suite "macros / core-overlay" :label "future deref" :expected "9" :actual "(deref (future (* 3 3)))" :portability :common} - {:suite "macros / core-overlay" :label "letfn simple" :expected "25" :actual "(letfn [(sq [x] (* x x))] (sq 5))" :portability :common} - {:suite "macros / core-overlay" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] (ev? 8))" :portability :common} - {:suite "macros / core-overlay" :label "condp match" :expected ":two" :actual "(condp = 2 1 :one 2 :two 3 :three)" :portability :common} - {:suite "macros / core-overlay" :label "condp default" :expected ":else" :actual "(condp = 9 1 :one 2 :two :else)" :portability :common} - {:suite "macros / core-overlay" :label "condp :>> form" :expected "\"got 2\"" :actual "(condp some [1 2 3] #{0 9} :>> (fn [x] (str \"got \" x)) #{2 6} :>> (fn [x] (str \"got \" x)))" :portability :common} - {:suite "macros / core-overlay" :label "condp no match" :expected ":threw" :actual "(try (condp = 9 1 :one) (catch :default e :threw))" :portability :common} - {:suite "macros / core-overlay" :label "binding rebinds" :expected "99" :actual "(do (def ^:dynamic *bx* 10) (binding [*bx* 99] *bx*))" :portability :common} - {:suite "macros / core-overlay" :label "binding restores" :expected "10" :actual "(do (def ^:dynamic *by* 10) (binding [*by* 99] *by*) *by*)" :portability :common} - {:suite "macros / core-overlay" :label "binding seen by fn" :expected "7" :actual "(do (def ^:dynamic *bz* 0) (defn rdz [] *bz*) (binding [*bz* 7] (rdz)))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "time returns value" :expected "3" :actual "(time (+ 1 2))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs rebinds" :expected "42" :actual "(do (defn wr-f [] 1) (with-redefs [wr-f (fn [] 42)] (wr-f)))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs restores" :expected "1" :actual "(do (defn wr-g [] 1) (with-redefs [wr-g (fn [] 42)]) (wr-g))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs restores on throw" :expected "1" :actual "(do (defn wr-h [] 1) (try (with-redefs [wr-h (fn [] 42)] (throw (ex-info \"x\" {}))) (catch :default e nil)) (wr-h))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs-fn" :expected "42" :actual "(do (defn wr-i [] 1) (with-redefs-fn {(var wr-i) (fn [] 42)} (fn [] (wr-i))))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "macroexpand full" :expected "true" :actual "(let [e (macroexpand (quote (when-not false 1)))] (= (quote if) (first e)))" :portability :common} - {:suite "macros / time, with-redefs, macroexpand" :label "macroexpand non-macro" :expected "[1 2]" :actual "(macroexpand (quote [1 2]))" :portability :common} - {:suite "macros / defmacro arity-clause & name metadata" :label "arity-clause form" :expected "10" :actual "(do (defmacro tw ([x] (list (quote *) x 2))) (tw 5))" :portability :common} - {:suite "macros / defmacro arity-clause & name metadata" :label "docstring + arity" :expected "15" :actual "(do (defmacro th \"triple\" ([x] (list (quote *) x 3))) (th 5))" :portability :common} - {:suite "macros / defmacro arity-clause & name metadata" :label "^{:map} name meta" :expected "7" :actual "(do (defmacro ^{:private true} pm [] 7) (pm))" :portability :common} - {:suite "macros / defmacro arity-clause & name metadata" :label "multi-form body" :expected "6" :actual "(do (defmacro mb ([a b] (list (quote +) a b))) (mb 2 4))" :portability :common} - {:suite "macros / defmacro multi-arity & attr-map" :label "multi-arity 1" :expected "6" :actual "(do (defmacro ma ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b))) (ma 5))" :portability :common} - {:suite "macros / defmacro multi-arity & attr-map" :label "multi-arity 2" :expected "5" :actual "(do (defmacro ma ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b))) (ma 2 3))" :portability :common} - {:suite "macros / defmacro multi-arity & attr-map" :label "arity delegates" :expected "[:d nil 9]" :actual "(do (defmacro lg ([m] `(lg :d nil ~m)) ([l t m] (list (quote vector) l t m))) (lg 9))" :portability :common} - {:suite "macros / defmacro multi-arity & attr-map" :label "doc + attr-map + params" :expected "10" :actual "(do (defmacro am \"doc\" {:arglists (quote ([x]))} [x] (list (quote inc) x)) (am 9))" :portability :common} - {:suite "macros / defmacro multi-arity & attr-map" :label "doc + attr-map + variadic" :expected "6" :actual "(do (defmacro vg \"d\" {:arglists (quote ([& a]))} [& xs] `(+ ~@xs)) (vg 1 2 3))" :portability :common} - {:suite "maps / keyword invoke" :label "hit" :expected "1" :actual "(:a {:a 1 :b 2})" :portability :common} - {:suite "maps / keyword invoke" :label "miss" :expected "nil" :actual "(:z {:a 1})" :portability :common} - {:suite "maps / keyword invoke" :label "miss with default" :expected ":d" :actual "(:z {:a 1} :d)" :portability :common} - {:suite "maps / keyword invoke" :label "hit with default" :expected "1" :actual "(:a {:a 1} :d)" :portability :common} - {:suite "maps / keyword invoke" :label "on nil" :expected "nil" :actual "(:a nil)" :portability :common} - {:suite "maps / keyword invoke" :label "on nil with default" :expected ":d" :actual "(:a nil :d)" :portability :common} - {:suite "maps / keyword invoke" :label "nil value is present" :expected "nil" :actual "(:a {:a nil} :d)" :portability :common} - {:suite "maps / keyword invoke" :label "false value is present" :expected "false" :actual "(:a {:a false} :d)" :portability :common} - {:suite "maps / keyword invoke" :label "on a vector" :expected "nil" :actual "(:a [1 2 3])" :portability :common} - {:suite "maps / keyword invoke" :label "on a number" :expected "nil" :actual "(:a 42)" :portability :common} - {:suite "maps / keyword invoke" :label "on a sorted map" :expected "2" :actual "(:b (sorted-map :a 1 :b 2))" :portability :common} - {:suite "maps / keyword invoke" :label "on assoc result" :expected "3" :actual "(:c (assoc {:a 1} :c 3))" :portability :common} - {:suite "maps / keyword invoke" :label "on a record field" :expected "5" :actual "(do (defrecord KFP [x]) (:x (->KFP 5)))" :portability :common} - {:suite "maps / keyword invoke" :label "qualified keyword" :expected "1" :actual "(:n/a {:n/a 1})" :portability :common} - {:suite "maps / keyword invoke" :label "nested in expr" :expected "6" :actual "(+ (:a {:a 1}) (:b {:b 2}) (:c {:c 3}))" :portability :common} - {:suite "maps / keyword invoke" :label "evaluates map expr once" :expected "[2 1]" :actual "(do (def cnt (atom 0)) (let [v (:a (do (swap! cnt inc) {:a 2}))] [v @cnt]))" :portability :common} - {:suite "maps / literal construction" :label "basic" :expected "{:a 1, :b 2}" :actual "{:a 1 :b 2}" :portability :common} - {:suite "maps / literal construction" :label "empty" :expected "{}" :actual "{}" :portability :common} - {:suite "maps / literal construction" :label "computed values" :expected "{:a 3}" :actual "{:a (+ 1 2)}" :portability :common} - {:suite "maps / literal construction" :label "nil value kept" :expected "true" :actual "(contains? {:a nil} :a)" :portability :common} - {:suite "maps / literal construction" :label "nil value lookup" :expected "nil" :actual "(get {:a nil} :a :d)" :portability :common} - {:suite "maps / literal construction" :label "string key" :expected "1" :actual "(get {\"k\" 1} \"k\")" :portability :common} - {:suite "maps / literal construction" :label "number key" :expected ":one" :actual "(get {1 :one} 1)" :portability :common} - {:suite "maps / literal construction" :label "collection key" :expected ":v" :actual "(get {[1 2] :v} [1 2])" :portability :common} - {:suite "maps / literal construction" :label "collection value-equal key" :expected ":v" :actual "(get {[1 2] :v} (vector 1 2))" :portability :common} - {:suite "maps / literal construction" :label "computed key" :expected "1" :actual "(get {(keyword \"a\") 1} :a)" :portability :common} - {:suite "maps / literal construction" :label "values evaluate in source order" :expected "[1 2 3]" :actual "(do (def log (atom [])) {:a (swap! log conj 1) :b (swap! log conj 2) :c (swap! log conj 3)} (deref log))" :portability :common} - {:suite "maps / literal construction" :label "keys evaluate before their values, pairwise" :expected "[:k1 :v1 :k2 :v2]" :actual "(do (def log (atom [])) {(do (swap! log conj :k1) :a) (do (swap! log conj :v1) 1) (do (swap! log conj :k2) :b) (do (swap! log conj :v2) 2)} (deref log))" :portability :common} - {:suite "maps / literal construction" :label "source order with a nil value (phm form)" :expected "[1 2 3]" :actual "(do (def log (atom [])) {:a (do (swap! log conj 1) nil) :b (swap! log conj 2) :c (swap! log conj 3)} (deref log))" :portability :common} - {:suite "maps / literal construction" :label "source order through syntax-quote" :expected "[2 1]" :actual "(do (def log (atom [])) (defmacro m-p3c [] `{:a ~(list 'swap! 'log 'conj 1) :b ~(list 'swap! 'log 'conj 2)}) (m-p3c) (deref log))" :portability :common} - {:suite "maps / literal construction" :label "count" :expected "3" :actual "(count {:a 1 :b 2 :c 3})" :portability :common} - {:suite "maps / literal construction" :label "equality with phm" :expected "true" :actual "(= {:a 1 :b 2} (assoc {:a 1} :b 2))" :portability :common} - {:suite "maps / literal construction" :label "keys work after assoc" :expected "2" :actual "(:b (assoc {:a 1 :b 2} :c 3))" :portability :common} - {:suite "maps / literal construction" :label "literal in fn body" :expected "12" :actual "(do (defn mfp-mk [x] {:v (* x 2)}) (:v (mfp-mk 6)))" :portability :common} - {:suite "maps / insertion order" :label "small literal keys" :expected "[:c :a :b]" :actual "(vec (keys {:c 3 :a 1 :b 2}))" :portability :common} - {:suite "maps / insertion order" :label "small literal vals" :expected "[3 1 2]" :actual "(vec (vals {:c 3 :a 1 :b 2}))" :portability :common} - {:suite "maps / insertion order" :label "seq follows keys" :expected "[:c :a :b]" :actual "(mapv key (seq {:c 3 :a 1 :b 2}))" :portability :common} - {:suite "maps / insertion order" :label "array-map any size" :expected "[:z :y :x :w :v :u :t :s :r :q]" :actual "(vec (keys (array-map :z 1 :y 2 :x 3 :w 4 :v 5 :u 6 :t 7 :s 8 :r 9 :q 10)))" :portability :common} - {:suite "maps / insertion order" :label "assoc appends new key" :expected "[:c :a :z]" :actual "(vec (keys (assoc {:c 3 :a 1} :z 9)))" :portability :common} - {:suite "maps / insertion order" :label "assoc replace keeps position" :expected "[:c :a]" :actual "(vec (keys (assoc {:c 3 :a 1} :c 9)))" :portability :common} - {:suite "maps / insertion order" :label "dissoc preserves order" :expected "[:c :b]" :actual "(vec (keys (dissoc {:c 3 :a 1 :b 2} :a)))" :portability :common} - {:suite "maps / insertion order" :label "into onto empty (<=8)" :expected "[:c :a :b]" :actual "(vec (keys (into {} [[:c 3] [:a 1] [:b 2]])))" :portability :common} - {:suite "maps / insertion order" :label "reduce assoc" :expected "[:e :d :c :b :a]" :actual "(vec (keys (reduce (fn [m k] (assoc m k k)) {} [:e :d :c :b :a])))" :portability :common} - {:suite "maps / insertion order" :label "conj a map merges in order" :expected "[:a :b :c]" :actual "(vec (keys (conj {:a 1} {:b 2 :c 3})))" :portability :common} - {:suite "maps / insertion order" :label "merge keeps right-hand order" :expected "[:a :c :b]" :actual "(vec (keys (merge {:a 1} {:c 3 :b 2})))" :portability :common} - {:suite "maps / insertion order" :label "assoc stays ordered through 8 entries" :expected "true" :actual "(= (vec (keys (reduce (fn [m i] (assoc m (keyword (str \"k\" i)) i)) {} (range 8)))) (mapv (fn [i] (keyword (str \"k\" i))) (range 8)))" :portability :common} - {:suite "maps / insertion order" :label "assoc promotes to hash past 8 entries" :expected "9" :actual "(count (reduce (fn [m i] (assoc m (keyword (str \"k\" i)) i)) {} (range 9)))" :portability :common} - {:suite "maps / insertion order" :label "array-map keeps order past 8" :expected "[:k0 :k1 :k2 :k3 :k4 :k5 :k6 :k7 :k8 :k9 :k10 :k11]" :actual "(vec (keys (apply array-map (mapcat (fn [i] [(keyword (str \"k\" i)) i]) (range 12)))))" :portability :common} - {:suite "maps / insertion order" :label "update-keys preserves order" :expected "[:a :b :c]" :actual "(vec (keys (update-vals (array-map :a 1 :b 2 :c 3) inc)))" :portability :common} - {:suite "maps / insertion order" :label "zipmap from ordered keys/vals" :expected "[:c :a :b]" :actual "(vec (keys (zipmap (keys {:c 3 :a 1 :b 2}) (vals {:c 3 :a 1 :b 2}))))" :portability :common} - {:suite "maps / insertion order" :label "select-keys follows keyseq" :expected "[:c :a]" :actual "(vec (keys (select-keys {:a 1 :b 2 :c 3} [:c :a])))" :portability :common} - {:suite "maps / insertion order" :label "frequencies first-occurrence order" :expected "[:c :a :b]" :actual "(vec (keys (frequencies [:c :a :b :a])))" :portability :common} - {:suite "maps / insertion order" :label "group-by first-occurrence order" :expected "[:c :a :b]" :actual "(vec (keys (group-by identity [:c :a :b :a])))" :portability :common} - {:suite "clojure.math" :label "sqrt" :expected "true" :actual "(< 1.4142 (clojure.math/sqrt 2) 1.4143)" :portability :common} - {:suite "clojure.math" :label "pow" :expected "1024" :actual "(long (clojure.math/pow 2 10))" :portability :common} - {:suite "clojure.math" :label "tan of 0" :expected "0" :actual "(long (clojure.math/tan 0))" :portability :common} - {:suite "clojure.math" :label "round" :expected "3" :actual "(clojure.math/round 2.6)" :portability :common} - {:suite "clojure.math" :label "floor" :expected "2.0" :actual "(clojure.math/floor 2.9)" :portability :common} - {:suite "clojure.math" :label "signum" :expected "-1.0" :actual "(clojure.math/signum -7.2)" :portability :common} - {:suite "clojure.math" :label "to-radians" :expected "true" :actual "(< 3.14 (clojure.math/to-radians 180) 3.15)" :portability :common} - {:suite "clojure.math" :label "PI" :expected "true" :actual "(< 3.14 clojure.math/PI 3.15)" :portability :common} - {:suite "clojure.math" :label "require + alias" :expected "5" :actual "(do (require '[clojure.math :as m]) (long (m/hypot 3 4)))" :portability :common} - {:suite "clojure.math" :label "as a value" :expected "[1 2]" :actual "(mapv (comp long clojure.math/sqrt) [1 4])" :portability :common} - {:suite "calls / locals named like core macros" :label "local fn named repeat" :expected "[1 1]" :actual "(let [repeat (fn [x] [x x])] (repeat 1))" :portability :common} - {:suite "calls / locals named like core macros" :label "local fn named seq" :expected ":end" :actual "((fn seq [n] (if (pos? n) (seq (dec n)) :end)) 2)" :portability :common} - {:suite "calls / locals named like core macros" :label "local fn named loop2" :expected "[2 1]" :actual "(let [with (fn [a b] [b a])] (with 1 2))" :portability :common} - {:suite "calls / locals named like core macros" :label "overlay repeat self-call (regression)" :expected "[0 0 0]" :actual "(take 3 (repeat 0))" :portability :common} - {:suite "calls / locals named like core macros" :label "closure param called" :expected "42" :actual "((fn [f] (f 41)) inc)" :portability :common} - {:suite "calls / locals named like core macros" :label "param holding a keyword (IFn leftover)" :expected "1" :actual "((fn [f] (f {:a 1})) :a)" :portability :common} - {:suite "map / construct & predicate" :label "literal" :expected "{:a 1}" :actual "{:a 1}" :portability :common} - {:suite "map / construct & predicate" :label "hash-map" :expected "{:b 2, :a 1}" :actual "(hash-map :a 1 :b 2)" :portability :common} - {:suite "map / construct & predicate" :label "empty" :expected "{}" :actual "{}" :portability :common} - {:suite "map / construct & predicate" :label "map? true" :expected "true" :actual "(map? {:a 1})" :portability :common} - {:suite "map / construct & predicate" :label "map? false on vector" :expected "false" :actual "(map? [1 2])" :portability :common} - {:suite "map / construct & predicate" :label "count" :expected "2" :actual "(count {:a 1 :b 2})" :portability :common} - {:suite "map / construct & predicate" :label "empty? true" :expected "true" :actual "(empty? {})" :portability :common} - {:suite "map / construct & predicate" :label "equality order-indep" :expected "true" :actual "(= {:a 1 :b 2} {:b 2 :a 1})" :portability :common} - {:suite "map / access" :label "get" :expected "1" :actual "(get {:a 1} :a)" :portability :common} - {:suite "map / access" :label "get missing nil" :expected "nil" :actual "(get {:a 1} :z)" :portability :common} - {:suite "map / access" :label "get default" :expected ":x" :actual "(get {:a 1} :z :x)" :portability :common} - {:suite "map / access" :label "keyword as fn" :expected "1" :actual "(:a {:a 1})" :portability :common} - {:suite "map / access" :label "keyword fn default" :expected ":x" :actual "(:z {:a 1} :x)" :portability :common} - {:suite "map / access" :label "map as fn" :expected "1" :actual "({:a 1} :a)" :portability :common} - {:suite "map / access" :label "get-in" :expected "2" :actual "(get-in {:a {:b 2}} [:a :b])" :portability :common} - {:suite "map / access" :label "get-in missing" :expected "nil" :actual "(get-in {:a {}} [:a :b])" :portability :common} - {:suite "map / access" :label "contains? key" :expected "true" :actual "(contains? {:a 1} :a)" :portability :common} - {:suite "map / access" :label "contains? missing" :expected "false" :actual "(contains? {:a 1} :z)" :portability :common} - {:suite "map / access" :label "find returns entry" :expected "[:a 1]" :actual "(find {:a 1} :a)" :portability :common} - {:suite "map / access" :label "keys" :expected "true" :actual "(= #{:a :b} (set (keys {:a 1 :b 2})))" :portability :common} - {:suite "map / access" :label "vals" :expected "true" :actual "(= #{1 2} (set (vals {:a 1 :b 2})))" :portability :common} - {:suite "map / update" :label "assoc adds" :expected "{:a 1, :b 2}" :actual "(assoc {:a 1} :b 2)" :portability :common} - {:suite "map / update" :label "assoc overwrites" :expected "{:a 9}" :actual "(assoc {:a 1} :a 9)" :portability :common} - {:suite "map / update" :label "assoc many" :expected "{:a 1, :b 2}" :actual "(assoc {} :a 1 :b 2)" :portability :common} - {:suite "map / update" :label "dissoc" :expected "{:a 1}" :actual "(dissoc {:a 1 :b 2} :b)" :portability :common} - {:suite "map / update" :label "dissoc many" :expected "{:a 1}" :actual "(dissoc {:a 1 :b 2 :c 3} :b :c)" :portability :common} - {:suite "map / update" :label "merge" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})" :portability :common} - {:suite "map / update" :label "merge overwrites" :expected "{:a 2}" :actual "(merge {:a 1} {:a 2})" :portability :common} - {:suite "map / update" :label "merge lattermost wins" :expected "{:a 3}" :actual "(merge {:a 1} {:a 2} {:a 3})" :portability :common} - {:suite "map / update" :label "merge no args -> nil" :expected "nil" :actual "(merge)" :portability :common} - {:suite "map / update" :label "merge all nil -> nil" :expected "nil" :actual "(merge nil nil)" :portability :common} - {:suite "map / update" :label "merge nil arg no-op" :expected "{:a 1}" :actual "(merge {:a 1} nil)" :portability :common} - {:suite "map / update" :label "merge nil then map" :expected "{:a 1}" :actual "(merge nil {:a 1})" :portability :common} - {:suite "map / update" :label "merge empty + nil" :expected "{}" :actual "(merge {} nil)" :portability :common} - {:suite "map / update" :label "merge map-entry (conj)" :expected "{:a 1}" :actual "(merge {} (first {:a 1}))" :portability :common} - {:suite "map / update" :label "merge [k v] vector" :expected "{:foo 1}" :actual "(merge {} [:foo 1])" :portability :common} - {:suite "map / update" :label "merge collection key" :expected "true" :actual "(= {[2 3] :foo} (merge {[2 3] :foo} nil {}))" :portability :common} - {:suite "map / update" :label "merge-with" :expected "{:a 3}" :actual "(merge-with + {:a 1} {:a 2})" :portability :common} - {:suite "map / update" :label "update" :expected "{:a 2}" :actual "(update {:a 1} :a inc)" :portability :common} - {:suite "map / update" :label "update missing w/ fnil" :expected "{:a 1}" :actual "(update {} :a (fnil inc 0))" :portability :common} - {:suite "map / update" :label "update-in" :expected "{:a {:b 2}}" :actual "(update-in {:a {:b 1}} [:a :b] inc)" :portability :common} - {:suite "map / update" :label "assoc-in" :expected "{:a {:b 1}}" :actual "(assoc-in {} [:a :b] 1)" :portability :common} - {:suite "map / update" :label "select-keys" :expected "{:a 1}" :actual "(select-keys {:a 1 :b 2} [:a])" :portability :common} - {:suite "map / update" :label "into onto map" :expected "{:a 1, :b 2}" :actual "(into {:a 1} [[:b 2]])" :portability :common} - {:suite "map / update" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])" :portability :common} - {:suite "map / iteration & entries" :label "map over entries" :expected "true" :actual "(= #{1 2} (set (map val {:a 1 :b 2})))" :portability :common} - {:suite "map / iteration & entries" :label "map keys" :expected "true" :actual "(= #{:a :b} (set (map key {:a 1 :b 2})))" :portability :common} - {:suite "map / iteration & entries" :label "reduce over entries" :expected "6" :actual "(reduce (fn [a e] (+ a (val e))) 0 {:a 1 :b 2 :c 3})" :portability :common} - {:suite "map / iteration & entries" :label "reduce-kv" :expected "6" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 {:a 1 :b 2 :c 3})" :portability :common} - {:suite "map / iteration & entries" :label "destructure entry" :expected "true" :actual "(= [[:a 2]] (into [] (map (fn [[k v]] [k (inc v)]) {:a 1})))" :portability :common} - {:suite "map / iteration & entries" :label "first of map is entry" :expected "true" :actual "(let [e (first {:a 1})] (and (= (key e) :a) (= (val e) 1)))" :portability :common} - {:suite "map / iteration & entries" :label "map-entry?" :expected "true" :actual "(map-entry? (first {:a 1}))" :portability :common} - {:suite "map / iteration & entries" :label "count of nil map" :expected "0" :actual "(count nil)" :portability :common} - {:suite "map / iteration & entries" :label "get from nil" :expected "nil" :actual "(get nil :a)" :portability :common} - {:suite "map / iteration & entries" :label "immutability" :expected "true" :actual "(let [m {:a 1} n (assoc m :b 2)] (and (= m {:a 1}) (= n {:a 1 :b 2})))" :portability :common} - {:suite "map / collection keys (by value)" :label "vector key literal" :expected ":v" :actual "(get {[1 2] :v} [1 2])" :portability :common} - {:suite "map / collection keys (by value)" :label "map key literal" :expected ":v" :actual "(get {(hash-map :a 1) :v} {:a 1})" :portability :common} - {:suite "map / collection keys (by value)" :label "assoc vector key" :expected ":v" :actual "(get (assoc {} [1 2] :v) [1 2])" :portability :common} - {:suite "map / collection keys (by value)" :label "key across repr" :expected ":v" :actual "(get (assoc {} (vec [1 2]) :v) [1 2])" :portability :common} - {:suite "map / collection keys (by value)" :label "frequencies of maps" :expected "2" :actual "(get (frequencies [{:a 1} (hash-map :a 1)]) {:a 1})" :portability :common} - {:suite "map / collection keys (by value)" :label "group-by collection key" :expected "1" :actual "(count (group-by identity [{:a 1} (hash-map :a 1)]))" :portability :common} - {:suite "map / nil inside a collection key" :label "set key w/ nil distinct" :expected "2" :actual "(count {#{nil 1} :a, #{1} :b})" :portability :common} - {:suite "map / nil inside a collection key" :label "set key w/ nil neg lookup" :expected "nil" :actual "(get {#{nil 1} :a} #{1})" :portability :common} - {:suite "map / nil inside a collection key" :label "set key w/ nil pos lookup" :expected ":a" :actual "(get {#{nil 1} :a} #{nil 1})" :portability :common} - {:suite "map / nil inside a collection key" :label "set key just nil distinct" :expected "false" :actual "(= {#{nil} :x} {#{} :x})" :portability :common} - {:suite "map / nil inside a collection key" :label "map nil-value key distinct" :expected "2" :actual "(count {{:a nil} 1, {} 2})" :portability :common} - {:suite "map / nil inside a collection key" :label "map nil-value key neg" :expected "nil" :actual "(get {{:a nil} 1} {})" :portability :common} - {:suite "map / nil inside a collection key" :label "map nil-value key pos" :expected "1" :actual "(get {{:a nil} 1} {:a nil})" :portability :common} - {:suite "map / nil inside a collection key" :label "map nil-key key distinct" :expected "2" :actual "(count {{nil :a} 1, {} 2})" :portability :common} - {:suite "map / nil inside a collection key" :label "map nil-key key pos" :expected "1" :actual "(get {{nil :a} 1} {nil :a})" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "assoc vec out of bounds" :expected :throws :actual "(assoc [0 1 2] 4 4)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "assoc vec negative" :expected :throws :actual "(assoc [] -1 0)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "assoc vec at count ok" :expected "[1 2 3]" :actual "(assoc [1 2] 2 3)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "dissoc on number" :expected :throws :actual "(dissoc 42 :a)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "dissoc on vector" :expected :throws :actual "(dissoc [1 2] 0)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "dissoc on set" :expected :throws :actual "(dissoc #{:a} :a)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "dissoc nil ok" :expected "nil" :actual "(dissoc nil :a)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "count on number" :expected :throws :actual "(count 1)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "count on keyword" :expected :throws :actual "(count :a)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "count string ok" :expected "3" :actual "(count \"abc\")" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "numerator throws" :expected :throws :actual "(numerator 1)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "denominator throws" :expected :throws :actual "(denominator 2)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "subvec out of range" :expected :throws :actual "(subvec [0 1 2 3] 1 5)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "subvec start>end" :expected :throws :actual "(subvec [0 1 2 3] 3 2)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "subvec ok" :expected "[1 2]" :actual "(subvec [0 1 2 3] 1 3)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "min-key empty" :expected :throws :actual "(apply min-key identity [])" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "merge empty vector" :expected :throws :actual "(merge {} [])" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "merge 1-elem vector" :expected :throws :actual "(merge {} [:foo])" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "merge atomic arg" :expected :throws :actual "(merge {} :foo)" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "merge [k v] ok" :expected "{:foo 1}" :actual "(merge {} [:foo 1])" :portability :common} - {:suite "map / strictness (throws like Clojure)" :label "merge maps ok" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})" :portability :common} - {:suite "map / map-entry & key ordering" :label "key of entry" :expected ":a" :actual "(key (first {:a 1}))" :portability :common} - {:suite "map / map-entry & key ordering" :label "val of entry" :expected "1" :actual "(val (first {:a 1}))" :portability :common} - {:suite "map / map-entry & key ordering" :label "key rejects vector" :expected :throws :actual "(key [:a 1])" :portability :common} - {:suite "map / map-entry & key ordering" :label "val rejects vector" :expected :throws :actual "(val [:a 1])" :portability :common} - {:suite "map / map-entry & key ordering" :label "map-entry? entry" :expected "true" :actual "(map-entry? (first {:a 1}))" :portability :common} - {:suite "map / map-entry & key ordering" :label "map-entry? vector" :expected "false" :actual "(map-entry? [:a 1])" :portability :common} - {:suite "map / map-entry & key ordering" :label "min-key NaN first" :expected "1" :actual "(min-key identity ##NaN 1)" :portability :common} - {:suite "map / map-entry & key ordering" :label "min-key NaN last" :expected "true" :actual "(NaN? (min-key identity 1 ##NaN))" :portability :common} - {:suite "map / map-entry & key ordering" :label "min-key NaN three" :expected "true" :actual "(infinite? (min-key identity ##NaN ##-Inf 1))" :portability :common} - {:suite "map / map-entry & key ordering" :label "min-key keys nonnum" :expected :throws :actual "(min-key identity \"x\" \"y\")" :portability :common} - {:suite "map / map-entry & key ordering" :label "max-key picks max" :expected "[1 2 3]" :actual "(max-key count [1] [1 2 3] [1 2])" :portability :common} - {:suite "map / map-entry & key ordering" :label "subvec float trunc" :expected "[0]" :actual "(subvec [0 1 2] 0.5 1.33)" :portability :common} - {:suite "map / map-entry & key ordering" :label "subvec NaN start" :expected "[0 1 2]" :actual "(subvec [0 1 2] ##NaN 3)" :portability :common} - {:suite "map / map-entry & key ordering" :label "subvec NaN end" :expected "[]" :actual "(subvec [0 1 2] 0 ##NaN)" :portability :common} - {:suite "map / nil values preserved" :label "literal contains" :expected "true" :actual "(contains? {:b nil} :b)" :portability :common} - {:suite "map / nil values preserved" :label "literal not= empty" :expected "false" :actual "(= {:b nil} {})" :portability :common} - {:suite "map / nil values preserved" :label "literal get nil" :expected "nil" :actual "(get {:b nil} :b :x)" :portability :common} - {:suite "map / nil values preserved" :label "literal keys incl nil" :expected "true" :actual "(= #{:a :b} (set (keys {:a nil :b 1})))" :portability :common} - {:suite "map / nil values preserved" :label "literal count" :expected "2" :actual "(count {:a nil :b 1})" :portability :common} - {:suite "map / nil values preserved" :label "literal vals incl nil" :expected "2" :actual "(count (vals {:a nil :b 1}))" :portability :common} - {:suite "map / nil values preserved" :label "eval values w/ nil" :expected "3" :actual "(:a {:a (+ 1 2) :b nil})" :portability :common} - {:suite "map / nil values preserved" :label "nil key present" :expected "true" :actual "(contains? {nil :v} nil)" :portability :common} - {:suite "map / nil values preserved" :label "assoc nil present" :expected "true" :actual "(contains? (assoc {:a 1} :b nil) :b)" :portability :common} - {:suite "map / nil values preserved" :label "assoc nil get" :expected "nil" :actual "(get (assoc {:a 1} :b nil) :b :x)" :portability :common} - {:suite "map / nil values preserved" :label "assoc overwrite nil" :expected "nil" :actual "(get (assoc {:a 1} :a nil) :a :x)" :portability :common} - {:suite "map / nil values preserved" :label "hash-map nil" :expected "true" :actual "(contains? (hash-map :b nil) :b)" :portability :common} - {:suite "map / nil values preserved" :label "merge new nil" :expected "true" :actual "(contains? (merge {:a 1} {:b nil}) :b)" :portability :common} - {:suite "map / nil values preserved" :label "merge overwrite nil" :expected "nil" :actual "(get (merge {:a 1} {:a nil}) :a :x)" :portability :common} - {:suite "map / nil values preserved" :label "merge-with present nil" :expected "true" :actual "(= [nil 1] (get (merge-with (fn [a b] [a b]) {:a nil} {:a 1}) :a))" :portability :common} - {:suite "map / nil values preserved" :label "into nil val" :expected "true" :actual "(contains? (into {} [[:a nil]]) :a)" :portability :common} - {:suite "map / nil values preserved" :label "conj map nil" :expected "true" :actual "(contains? (conj {:x 1} {:a nil}) :a)" :portability :common} - {:suite "map / nil values preserved" :label "zipmap nil" :expected "true" :actual "(contains? (zipmap [:a] [nil]) :a)" :portability :common} - {:suite "map / nil values preserved" :label "select-keys nil" :expected "true" :actual "(contains? (select-keys {:a nil} [:a]) :a)" :portability :common} - {:suite "map / nil values preserved" :label "get-in present nil" :expected "nil" :actual "(get-in {:a nil} [:a] :x)" :portability :common} - {:suite "map / nil values preserved" :label "get-in through nil" :expected ":x" :actual "(get-in {:a nil} [:a :b] :x)" :portability :common} - {:suite "map / nil values preserved" :label "dissoc keeps nil" :expected "true" :actual "(contains? (dissoc {:a nil :b 1} :b) :a)" :portability :common} - {:suite "map / nil values preserved" :label "reduce-kv sees nil" :expected "true" :actual "(= #{:a :b} (reduce-kv (fn [acc k v] (conj acc k)) #{} {:a nil :b 2}))" :portability :common} - {:suite "map / nil values preserved" :label "nil-free stays fast" :expected "true" :actual "(= {:a 1 :b 2} {:b 2 :a 1})" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-keys" :expected "{\"a\" 1, \"b\" 2}" :actual "(update-keys {:a 1 :b 2} name)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-keys empty" :expected "{}" :actual "(update-keys {} inc)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-keys nil" :expected "{}" :actual "(update-keys nil str)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-keys collide last wins" :expected "1" :actual "(count (update-keys {:a 1 :b 2} (fn [_] :k)))" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-vals" :expected "{:a 2, :b 3}" :actual "(update-vals {:a 1 :b 2} inc)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-vals empty" :expected "{}" :actual "(update-vals {} inc)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-vals nil" :expected "{}" :actual "(update-vals nil inc)" :portability :common} - {:suite "map / update-keys & update-vals (1.11)" :label "update-vals keeps keys" :expected "[:a :b]" :actual "(sort (keys (update-vals {:a 1 :b 2} inc)))" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "keys" :expected "[:a]" :actual "(keys {:a 1})" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "keys empty map" :expected "nil" :actual "(keys {})" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "keys nil" :expected "nil" :actual "(keys nil)" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "vals" :expected "[1]" :actual "(vals {:a 1})" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "vals empty" :expected "nil" :actual "(vals {})" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "keys sorted order" :expected "[1 2 3]" :actual "(vec (keys (sorted-map 2 :b 1 :a 3 :c)))" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "vals sorted order" :expected "[:a :b :c]" :actual "(vec (vals (sorted-map 2 :b 1 :a 3 :c)))" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "keys/vals zip" :expected "{:a 1, :b 2}" :actual "(zipmap (keys {:a 1 :b 2}) (vals {:a 1 :b 2}))" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? map" :expected "true" :actual "(empty? {})" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? vec" :expected "[true false]" :actual "[(empty? []) (empty? [1])]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? list" :expected "[true false]" :actual "[(empty? ()) (empty? (list 1))]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? string" :expected "[true false]" :actual "[(empty? \"\") (empty? \"a\")]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? nil" :expected "true" :actual "(empty? nil)" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? set" :expected "[true false]" :actual "[(empty? #{}) (empty? #{1})]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? lazy" :expected "[true false]" :actual "[(empty? (filter pos? [-1])) (empty? (map inc [1]))]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? lazy nil elem" :expected "false" :actual "(empty? (cons nil nil))" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? sorted" :expected "[true false]" :actual "[(empty? (sorted-map)) (empty? (sorted-set 1))]" :portability :common} - {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? number throws" :expected :throws :actual "(empty? 5)" :portability :common} - {:suite "map / assoc on nil" :label "assoc nil is a map" :expected "{:a 1}" :actual "(assoc nil :a 1)" :portability :common} - {:suite "map / assoc on nil" :label "count of assoc nil" :expected "1" :actual "(count (assoc nil :a 1))" :portability :common} - {:suite "map / assoc on nil" :label "assoc-in nested countable" :expected "1" :actual "(count (:a (assoc-in {} [:a :b] 1)))" :portability :common} - {:suite "map / assoc on nil" :label "assoc-in deep get" :expected "9" :actual "(get-in (assoc-in {} [:a :b :c] 9) [:a :b :c])" :portability :common} - {:suite "map / assoc on nil" :label "seq over assoc-nil map" :expected ":a" :actual "(ffirst (seq (assoc nil :a 1)))" :portability :common} - {:suite "map / assoc on nil" :label "keys of assoc-nil map" :expected "[:a]" :actual "(vec (keys (assoc nil :a 1)))" :portability :common} - {:suite "map / bulk build boundaries" :label "into = incr at 17" :expected "true" :actual "(= (into {} (map (fn [i] [i (* i 2)]) (range 17))) (reduce (fn [m p] (assoc m (first p) (second p))) {} (map (fn [i] [i (* i 2)]) (range 17))))" :portability :common} - {:suite "map / bulk build boundaries" :label "into = incr at 1000" :expected "true" :actual "(= (into {} (map (fn [i] [i (* i 2)]) (range 1000))) (reduce (fn [m p] (assoc m (first p) (second p))) {} (map (fn [i] [i (* i 2)]) (range 1000))))" :portability :common} - {:suite "map / bulk build boundaries" :label "into count 1000" :expected "1000" :actual "(count (into {} (map (fn [i] [i i]) (range 1000))))" :portability :common} - {:suite "map / bulk build boundaries" :label "into reads back" :expected "999" :actual "(get (into {} (map (fn [i] [i (* i 3)]) (range 1000))) 333)" :portability :common} - {:suite "map / bulk build boundaries" :label "into onto non-empty" :expected "9" :actual "(get (into {:a 1} [[:a 9] [:b 2]]) :a)" :portability :common} - {:suite "map / bulk build boundaries" :label "into dup last wins" :expected "9" :actual "(get (into {} [[:k 1] [:k 9]]) :k)" :portability :common} - {:suite "map / bulk build boundaries" :label "into nil key" :expected ":x" :actual "(get (into {} [[nil :x] [:a 1]]) nil)" :portability :common} - {:suite "map / bulk build boundaries" :label "assoc after bulk" :expected "7" :actual "(get (assoc (into {} (map (fn [i] [i i]) (range 100))) :new 7) :new)" :portability :common} - {:suite "map / bulk build boundaries" :label "dissoc after bulk" :expected "nil" :actual "(get (dissoc (into {} (map (fn [i] [i i]) (range 100))) 50) 50)" :portability :common} - {:suite "map / bulk build boundaries" :label "frequencies count" :expected "3" :actual "(get (frequencies [1 2 2 1 2 1]) 1)" :portability :common} - {:suite "map / bulk build boundaries" :label "frequencies coll-key" :expected "2" :actual "(get (frequencies [[1 2] [1 2] [3 4]]) [1 2])" :portability :common} - {:suite "map / bulk build boundaries" :label "frequencies nil key" :expected "2" :actual "(get (frequencies [nil nil 1]) nil)" :portability :common} - {:suite "map / bulk build boundaries" :label "group-by nil key" :expected "[nil nil]" :actual "(get (group-by identity [nil nil 1]) nil)" :portability :common} - {:suite "map / bulk build boundaries" :label "group-by nil count" :expected "2" :actual "(count (group-by identity [nil nil 1]))" :portability :common} - {:suite "map / bulk build boundaries" :label "transient nil key" :expected ":x" :actual "(let [t (transient {})] (assoc! t nil :x) (get (persistent! t) nil))" :portability :common} - {:suite "map / bulk build boundaries" :label "transient nil get" :expected "true" :actual "(let [t (transient {})] (assoc! t nil :x) (contains? t nil))" :portability :common} - {:suite "map / bulk build boundaries" :label "transient nil dissoc" :expected ":gone" :actual "(let [t (transient {})] (assoc! t nil :x) (dissoc! t nil) (get (persistent! t) nil :gone))" :portability :common} - {:suite "map / bulk build boundaries" :label "group-by bucket" :expected "[1 3 5]" :actual "(get (group-by odd? (range 1 6)) true)" :portability :common} - {:suite "map / bulk build boundaries" :label "group-by big bucket" :expected "true" :actual "(= (group-by even? (range 200)) {true (vec (filter even? (range 200))) false (vec (filter odd? (range 200)))})" :portability :common} - {:suite "map / bulk build boundaries" :label "group-by order" :expected "[0 3 6 9]" :actual "(get (group-by (fn [x] (mod x 3)) (range 10)) 0)" :portability :common} - {:suite "map / bulk build boundaries" :label "hash-map bulk = incr" :expected "true" :actual "(= (apply hash-map (mapcat (fn [i] [i i]) (range 50))) (reduce (fn [m i] (assoc m i i)) {} (range 50)))" :portability :common} - {:suite "metadata / with-meta & meta" :label "meta of bare value" :expected "nil" :actual "(meta [1 2 3])" :portability :common} - {:suite "metadata / with-meta & meta" :label "with-meta then meta" :expected "{:a 1}" :actual "(meta (with-meta [1 2 3] {:a 1}))" :portability :common} - {:suite "metadata / with-meta & meta" :label "with-meta preserves value" :expected "true" :actual "(= [1 2 3] (with-meta [1 2 3] {:a 1}))" :portability :common} - {:suite "metadata / with-meta & meta" :label "with-meta on map" :expected "{:doc \"x\"}" :actual "(meta (with-meta {:k 1} {:doc \"x\"}))" :portability :common} - {:suite "metadata / with-meta & meta" :label "vary-meta" :expected "{:a 2}" :actual "(meta (vary-meta (with-meta [1] {:a 1}) update :a inc))" :portability :common} - {:suite "metadata / with-meta & meta" :label "vary-meta extra args" :expected "{:a 1, :b 2}" :actual "(meta (vary-meta (with-meta [1] {:a 1}) assoc :b 2))" :portability :common} - {:suite "metadata / with-meta & meta" :label "meta reader ^" :expected "{:tag :int}" :actual "(meta ^{:tag :int} [1 2])" :portability :common} - {:suite "metadata / with-meta & meta" :label "with-meta on fn ok" :expected "true" :actual "(fn? (with-meta inc {:a 1}))" :portability :common} - {:suite "metadata / with-meta & meta" :label "with-meta nil clears" :expected "nil" :actual "(meta (with-meta [1 2 3] nil))" :portability :common} - {:suite "metadata / type hints" :label "type hint on param" :expected "\"hi\"" :actual "(do (defn f [^String s] s) (f \"hi\"))" :portability :common} - {:suite "metadata / type hints" :label "type hint, extra params" :expected "[1 2]" :actual "(do (defn g [^String x y] [x y]) (g 1 2))" :portability :common} - {:suite "metadata / type hints" :label "type hint in let" :expected "6" :actual "(let [^long x 5] (inc x))" :portability :common} - {:suite "metadata / type hints" :label "type hint in body" :expected "2" :actual "(let [s \"ab\"] (count ^String s))" :portability :common} - {:suite "metadata / type hints" :label "type hint in destructure" :expected "3" :actual "(let [{:keys [^long a]} {:a 3}] a)" :portability :common} - {:suite "metadata / type hints" :label "symbol hint -> :tag is a symbol" :expected "true" :actual "(symbol? (:tag (meta (read-string \"^String x\"))))" :portability :common} - {:suite "metadata / type hints" :label "symbol hint -> :tag name" :expected "\"String\"" :actual "(name (:tag (meta (read-string \"^String x\"))))" :portability :common} - {:suite "metadata / type hints" :label "keyword hint -> true" :expected "true" :actual "(:foo (meta (read-string \"^:foo x\")))" :portability :common} - {:suite "metadata / read data metadata" :label "vector data meta" :expected "{:ref true}" :actual "(meta (read-string \"^:ref [:greeting]\"))" :portability :common} - {:suite "metadata / read data metadata" :label "map data meta" :expected "{:k 1}" :actual "(meta (read-string \"^{:k 1} {:a 2}\"))" :portability :common} - {:suite "metadata / read data metadata" :label "set data meta" :expected "{:s true}" :actual "(meta (read-string \"^:s #{1 2}\"))" :portability :common} - {:suite "metadata / read data metadata" :label "nested vector data meta" :expected "{:x true}" :actual "(meta (second (read-string \"[1 ^:x {:a 2}]\")))" :portability :common} - {:suite "metadata / read data metadata" :label "collection value unchanged" :expected "[:greeting]" :actual "(read-string \"^:ref [:greeting]\")" :portability :common} - {:suite "metadata / coll literal in code keeps meta" :label "vector literal meta" :expected "{:foo true}" :actual "(meta ^:foo [1 2])" :portability :common} - {:suite "metadata / coll literal in code keeps meta" :label "map literal meta with expr" :expected "{:a 3}" :actual "(meta ^{:a (+ 1 2)} [1])" :portability :common} - {:suite "metadata / coll literal in code keeps meta" :label "map literal value-eval order" :expected "[1 2]" :actual "(let [a (atom [])] ^:t {(do (swap! a conj 1) :a) 1 (do (swap! a conj 2) :b) 2} @a)" :portability :common} - {:suite "metadata / *print-meta*" :label "pr-str prefixes ^meta" :expected "\"^{:ref true} [:g]\"" :actual "(binding [*print-meta* true] (pr-str (with-meta [:g] {:ref true})))" :portability :common} - {:suite "metadata / *print-meta*" :label "off by default" :expected "\"[:g]\"" :actual "(pr-str (with-meta [:g] {:ref true}))" :portability :common} - {:suite "metadata / *print-meta*" :label "symbol meta prefixed" :expected "\"^{:k 1} x\"" :actual "(binding [*print-meta* true] (pr-str (with-meta (quote x) {:k 1})))" :portability :common} - {:suite "metadata / *print-meta*" :label "print then read round-trips" :expected "{:ref true}" :actual "(meta (read-string (binding [*print-meta* true] (pr-str (with-meta [:g] {:ref true})))))" :portability :common} - {:suite "metadata / clojure.walk preserves meta" :label "postwalk keeps vector meta" :expected "{:ref true}" :actual "(do (require (quote [clojure.walk :as w])) (meta (w/postwalk identity (with-meta [:b] {:ref true}))))" :portability :common} - {:suite "metadata / clojure.walk preserves meta" :label "postwalk keeps map meta" :expected "{:m 1}" :actual "(do (require (quote [clojure.walk :as w])) (meta (w/postwalk identity (with-meta {:a 2} {:m 1}))))" :portability :common} - {:suite "metadata / clojure.edn preserves meta" :label "edn vector meta" :expected "{:ref true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:ref [:greeting]\")))" :portability :common} - {:suite "metadata / clojure.edn preserves meta" :label "edn map meta" :expected "{:m true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:m {:a 1}\")))" :portability :common} - {:suite "metadata / clojure.edn preserves meta" :label "edn set meta" :expected "{:s true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:s #{1}\")))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty keeps vector meta" :expected "{:k 9}" :actual "(meta (empty (with-meta [1] {:k 9})))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty keeps map meta" :expected "{:k 9}" :actual "(meta (empty (with-meta {:a 1} {:k 9})))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty keeps set meta" :expected "{:k 9}" :actual "(meta (empty (with-meta #{1} {:k 9})))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty keeps list meta" :expected "{:k 9}" :actual "(meta (empty (with-meta (list 1) {:k 9})))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "into empty keeps meta" :expected "{:k 9}" :actual "(meta (into (empty (with-meta {:a 1} {:k 9})) {:b 2}))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "into target meta" :expected "{:k 9}" :actual "(meta (into (with-meta [] {:k 9}) [1 2]))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "conj on vector" :expected "{:k 9}" :actual "(meta (conj (with-meta [1] {:k 9}) 2))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "conj on list" :expected "{:k 9}" :actual "(meta (conj (with-meta (list 1) {:k 9}) 2))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "assoc on map" :expected "{:k 9}" :actual "(meta (assoc (with-meta {:a 1} {:k 9}) :b 2))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "dissoc on map" :expected "{:k 9}" :actual "(meta (dissoc (with-meta {:a 1 :c 3} {:k 9}) :c))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "disj on set" :expected "{:k 9}" :actual "(meta (disj (with-meta #{1 2} {:k 9}) 2))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "pop on vector" :expected "{:k 9}" :actual "(meta (pop (with-meta [1 2] {:k 9})))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "op without meta is nil" :expected "nil" :actual "(meta (conj [1] 2))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "value preserved through conj" :expected "[1 2]" :actual "(conj (with-meta [1] {:k 9}) 2)" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty list singleton unaffected" :expected "nil" :actual "(do (with-meta () {:leak 1}) (meta ()))" :portability :common} - {:suite "metadata / collection ops preserve meta" :label "empty vector literal unaffected" :expected "nil" :actual "(do (with-meta [] {:leak 1}) (meta []))" :portability :common} - {:suite "metadata / def metadata" :label "^:dynamic var binds" :expected "9" :actual "(do (def ^:dynamic *d* 1) (binding [*d* 9] *d*))" :portability :common} - {:suite "metadata / def metadata" :label "^:private on var" :expected "true" :actual "(do (def ^:private pv 1) (:private (meta (var pv))))" :portability :common} - {:suite "metadata / def metadata" :label "^Type tag on var" :expected "java.lang.String" :actual "(do (def ^String tv \"a\") (:tag (meta (var tv))))" :portability :common} - {:suite "metadata / def metadata" :label "^{:doc} on var" :expected "\"hi\"" :actual "(do (def ^{:doc \"hi\"} dv 1) (:doc (meta (var dv))))" :portability :common} - {:suite "metadata / def metadata" :label "(def name doc val) doc" :expected "\"d\"" :actual "(do (def dd \"d\" 5) (:doc (meta (var dd))))" :portability :common} - {:suite "core / find-keyword + inst-ms*" :label "find-keyword" :expected ":a" :actual "(find-keyword \"a\")" :portability :common} - {:suite "core / find-keyword + inst-ms*" :label "find-keyword 2-arity" :expected ":n/a" :actual "(find-keyword \"n\" \"a\")" :portability :common} - {:suite "core / find-keyword + inst-ms*" :label "find-keyword = keyword" :expected "true" :actual "(= (find-keyword \"x\") :x)" :portability :common} - {:suite "core / find-keyword + inst-ms*" :label "inst-ms*" :expected "true" :actual "(= (inst-ms* #inst \"2020-01-01T00:00:00Z\") (inst-ms #inst \"2020-01-01T00:00:00Z\"))" :portability :common} - {:suite "core / find-keyword + inst-ms*" :label "inst-ms* value" :expected "0" :actual "(inst-ms* #inst \"1970-01-01T00:00:00Z\")" :portability :common} - {:suite "core / with-local-vars" :label "var-get initial" :expected "1" :actual "(with-local-vars [x 1] (var-get x))" :portability :common} - {:suite "core / with-local-vars" :label "var-set" :expected "2" :actual "(with-local-vars [x 1] (var-set x 2) (var-get x))" :portability :common} - {:suite "core / with-local-vars" :label "two vars" :expected "[1 2]" :actual "(with-local-vars [a 1 b 2] [(var-get a) (var-get b)])" :portability :common} - {:suite "core / with-local-vars" :label "vars are values" :expected "5" :actual "(with-local-vars [x 0] (let [bump (fn [v] (var-set v (+ 5 (var-get v))))] (bump x) (var-get x)))" :portability :common} - {:suite "core / with-local-vars" :label "init sees outer" :expected "3" :actual "(let [y 3] (with-local-vars [x y] (var-get x)))" :portability :common} - {:suite "core / with-local-vars" :label "body result" :expected ":done" :actual "(with-local-vars [x 1] :done)" :portability :common} - {:suite "core / with-open" :label "body result" :expected ":r" :actual "(let [log (atom [])] (with-open [c {:close (fn [] (swap! log conj :closed))}] :r))" :portability :common} - {:suite "core / with-open" :label "close runs" :expected "[:closed]" :actual "(let [log (atom [])] (with-open [c {:close (fn [] (swap! log conj :closed))}] :r) (deref log))" :portability :common} - {:suite "core / with-open" :label "close on throw" :expected "[]" :actual "(let [log (atom [])] (try (with-open [c {:close (fn [] (swap! log conj :closed))}] (throw (ex-info \"boom\" {}))) (catch Exception e nil)) (deref log))" :portability :common} - {:suite "core / with-open" :label "nested close order" :expected "[:inner :outer]" :actual "(let [log (atom [])] (with-open [a {:close (fn [] (swap! log conj :outer))} b {:close (fn [] (swap! log conj :inner))}] :r) (deref log))" :portability :common} - {:suite "core / with-open" :label "zero bindings" :expected ":r" :actual "(with-open [] :r)" :portability :common} - {:suite "core / with-open" :label "binding visible" :expected "5" :actual "(with-open [c {:close (fn [] nil) :v 5}] (:v c))" :portability :common} - {:suite "core / with-precision" :label "body evaluates" :expected "3.14" :actual "(with-precision 3 3.14)" :portability :common} - {:suite "core / with-precision" :label "multiple body forms" :expected "2" :actual "(with-precision 10 1 2)" :portability :common} - {:suite "core / with-precision" :label "rounding arg accepted" :expected "1.5" :actual "(with-precision 4 :rounding :half-up 1.5)" :portability :common} - {:suite "core / with-precision" :label "arithmetic" :expected "2" :actual "(with-precision 5 (+ 1 1))" :portability :common} - {:suite "core / read+string" :label "form and text" :expected "true" :actual "(let [[v s] (with-in-str \"42 rest\" (read+string))] (and (= v 42) (string? s)))" :portability :common} - {:suite "core / read+string" :label "form value" :expected "(quote (+ 1 2))" :actual "(first (with-in-str \"(+ 1 2)\" (read+string)))" :portability :common} - {:suite "core / read+string" :label "text covers the form" :expected "true" :actual "(let [[v s] (with-in-str \" [1 2] tail\" (read+string))] (and (= v [1 2]) (> (count s) 3)))" :portability :common} - {:suite "core / read+string" :label "advances the stream" :expected "[1 2]" :actual "(with-in-str \"1 2\" [(first (read+string)) (first (read+string))])" :portability :common} - {:suite "core / read+string" :label "EOF throws" :expected :throws :actual "(with-in-str \"\" (read+string))" :portability :common} - {:suite "core / read+string" :label "eof-value arity" :expected ":done" :actual "(first (with-in-str \"\" (read+string *in* false :done)))" :portability :common} - {:suite "core / extenders" :label "lists extended type" :expected "[]" :actual "(do (defprotocol Px (pm [x])) (defrecord Rx [] Px (pm [x] 1)) (mapv str (extenders Px)))" :portability :common} - {:suite "core / extenders" :label "nil when none" :expected "nil" :actual "(do (defprotocol Py (pn [x])) (extenders Py))" :portability :common} - {:suite "core / extenders" :label "seq of tags" :expected "nil" :actual "(do (defprotocol Pz (pz [x])) (defrecord Rz [] Pz (pz [x] 1)) (and (seq (extenders Pz)) (= 1 (count (extenders Pz)))))" :portability :common} - {:suite "multimethods / dispatch" :label "dispatch on value" :expected "\"two\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (f 2))" :portability :common} - {:suite "multimethods / dispatch" :label "dispatch on keyword fn" :expected "\"circle\"" :actual "(do (defmulti area :shape) (defmethod area :circle [_] \"circle\") (area {:shape :circle}))" :portability :common} - {:suite "multimethods / dispatch" :label ":default method" :expected "\"other\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f :default [_] \"other\") (f 99))" :portability :common} - {:suite "multimethods / dispatch" :label "no match throws" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (f 99))" :portability :common} - {:suite "multimethods / dispatch" :label "multiple args" :expected "5" :actual "(do (defmulti g (fn [a b] a)) (defmethod g :add [_ b] b) (g :add 5))" :portability :common} - {:suite "multimethods / dispatch" :label "get-method" :expected "\"one\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") ((get-method f 1) 1))" :portability :common} - {:suite "multimethods / dispatch" :label "remove-method" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (remove-method f 1) (f 1))" :portability :common} - {:suite "multimethods / dispatch" :label "methods" :expected "\"one\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") ((get (methods f) 1) 1))" :portability :common} - {:suite "multimethods / dispatch" :label "methods count" :expected "2" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (count (methods f)))" :portability :common} - {:suite "multimethods / dispatch" :label "remove-all-methods" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (remove-all-methods f) (f 1))" :portability :common} - {:suite "multimethods / dispatch" :label "remove-all-methods empties the table" :expected "0" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (remove-all-methods f) (count (methods f)))" :portability :common} - {:suite "multimethods / hierarchies" :label "derive + isa?" :expected "true" :actual "(do (derive ::child ::parent) (isa? ::child ::parent))" :portability :common} - {:suite "multimethods / hierarchies" :label "isa? reflexive" :expected "true" :actual "(isa? ::x ::x)" :portability :common} - {:suite "multimethods / hierarchies" :label "isa? unrelated" :expected "false" :actual "(do (derive ::a ::b) (isa? ::a ::c))" :portability :common} - {:suite "multimethods / hierarchies" :label "parents" :expected "true" :actual "(do (derive ::c ::p) (contains? (parents ::c) ::p))" :portability :common} - {:suite "multimethods / hierarchies" :label "ancestors" :expected "true" :actual "(do (derive ::c ::p) (derive ::p ::g) (contains? (ancestors ::c) ::g))" :portability :common} - {:suite "multimethods / hierarchies" :label "descendants" :expected "true" :actual "(do (derive ::c ::p) (contains? (descendants ::p) ::c))" :portability :common} - {:suite "multimethods / hierarchies" :label "dispatch via hierarchy" :expected "\"animal\"" :actual "(do (derive ::dog ::animal) (defmulti speak identity) (defmethod speak ::animal [_] \"animal\") (speak ::dog))" :portability :common} - {:suite "multimethods / hierarchies" :label "custom :default key" :expected ":unknown" :actual "(do (defmulti classify :type :default :other) (defmethod classify :a [_] :alpha) (defmethod classify :other [_] :unknown) (classify {:type :zzz}))" :portability :common} - {:suite "multimethods / hierarchies" :label "explicit :hierarchy" :expected "\"a\"" :actual "(do (def h (derive (make-hierarchy) ::dog ::animal)) (defmulti snd identity :hierarchy h) (defmethod snd ::animal [_] \"a\") (snd ::dog))" :portability :common} - {:suite "multimethods / prefer-method" :label "preference picks the winner" :expected ":rect" :actual "(do (derive :p/sq :p/rect) (derive :p/sq :p/shape) (defmulti pm1 identity) (defmethod pm1 :p/rect [x] :rect) (defmethod pm1 :p/shape [x] :shape) (prefer-method pm1 :p/rect :p/shape) (pm1 :p/sq))" :portability :common} - {:suite "multimethods / prefer-method" :label "reverse preference" :expected ":shape" :actual "(do (derive :q/sq :q/rect) (derive :q/sq :q/shape) (defmulti pm2 identity) (defmethod pm2 :q/rect [x] :rect) (defmethod pm2 :q/shape [x] :shape) (prefer-method pm2 :q/shape :q/rect) (pm2 :q/sq))" :portability :common} - {:suite "multimethods / prefer-method" :label "ambiguity throws" :expected :throws :actual "(do (derive :r/sq :r/rect) (derive :r/sq :r/shape) (defmulti pm3 identity) (defmethod pm3 :r/rect [x] :rect) (defmethod pm3 :r/shape [x] :shape) (pm3 :r/sq))" :portability :common} - {:suite "multimethods / prefer-method" :label "isa dominance needs no preference" :expected ":child" :actual "(do (derive :s/c :s/p) (defmulti pm4 identity) (defmethod pm4 :s/c [x] :child) (defmethod pm4 :s/p [x] :parent) (pm4 :s/c))" :portability :common} - {:suite "multimethods / prefer-method" :label "prefers map shape" :expected "true" :actual "(do (defmulti pm5 identity) (defmethod pm5 :a [x] 1) (defmethod pm5 :b [x] 2) (prefer-method pm5 :a :b) (contains? (get (prefers pm5) :a) :b))" :portability :common} - {:suite "multimethods / prefer-method" :label "exact match needs no preference" :expected ":exact" :actual "(do (derive :t/sq :t/rect) (defmulti pm6 identity) (defmethod pm6 :t/sq [x] :exact) (defmethod pm6 :t/rect [x] :parent) (pm6 :t/sq))" :portability :common} - {:suite "multimethods / docstring & value-based table ops" :label "defmulti docstring" :expected "\"A\"" :actual "(do (defmulti gd \"the dispatcher\" identity) (defmethod gd :a [_] \"A\") (gd :a))" :portability :common} - {:suite "multimethods / docstring & value-based table ops" :label "defmulti doc+default" :expected "\"d\"" :actual "(do (defmulti gx \"doc\" identity) (defmethod gx :default [_] \"d\") (gx :anything))" :portability :common} - {:suite "multimethods / docstring & value-based table ops" :label "methods on value" :expected "2" :actual "(do (defmulti gm identity) (defmethod gm 1 [_] :one) (defmethod gm 2 [_] :two) (count (methods gm)))" :portability :common} - {:suite "multimethods / docstring & value-based table ops" :label "get-method on value" :expected "true" :actual "(do (defmulti gg identity) (defmethod gg :a [_] :x) (fn? (get-method gg :a)))" :portability :common} - {:suite "namespaces / def & vars" :label "def + deref" :expected "5" :actual "(do (def x 5) x)" :portability :common} - {:suite "namespaces / def & vars" :label "def returns var" :expected "true" :actual "(var? (def y 1))" :portability :common} - {:suite "namespaces / def & vars" :label "declare then def" :expected "2" :actual "(do (declare z) (def z 2) z)" :portability :common} - {:suite "namespaces / def & vars" :label "var special form" :expected "true" :actual "(var? (var +))" :portability :common} - {:suite "namespaces / def & vars" :label "var sugar #'" :expected "true" :actual "(var? #'+)" :portability :common} - {:suite "namespaces / def & vars" :label "var-get" :expected "5" :actual "(do (def w 5) (var-get #'w))" :portability :common} - {:suite "namespaces / def & vars" :label "defn defines fn" :expected "3" :actual "(do (defn f [x] (inc x)) (f 2))" :portability :common} - {:suite "namespaces / def & vars" :label "def with docstring" :expected "7" :actual "(do (def d \"a doc\" 7) d)" :portability :common} - {:suite "namespaces / def & vars" :label "dynamic var binding" :expected "2" :actual "(do (def ^:dynamic *x* 1) (binding [*x* 2] *x*))" :portability :common} - {:suite "namespaces / def & vars" :label "binding restores" :expected "1" :actual "(do (def ^:dynamic *y* 1) (binding [*y* 9] nil) *y*)" :portability :common} - {:suite "namespaces / def & vars" :label "var-set in binding" :expected "5" :actual "(do (def ^:dynamic *z* 1) (binding [*z* 0] (var-set (var *z*) 5) *z*))" :portability :common} - {:suite "namespaces / ns operations" :label "in-ns switches" :expected "true" :actual "(do (in-ns 'my.ns) (symbol? 'x))" :portability :common} - {:suite "namespaces / ns operations" :label "ns form + alias" :expected "\"HI\"" :actual "(do (ns my.app (:require [clojure.string :as s])) (s/upper-case \"hi\"))" :portability :common} - {:suite "namespaces / ns operations" :label "ns :use refers all" :expected "9" :actual "(do (ns src.lib) (def helper 9) (ns dst.app (:use [src.lib])) helper)" :portability :common} - {:suite "namespaces / ns operations" :label "standalone use" :expected "7" :actual "(do (ns src.l2) (def k 7) (in-ns 'dst.a2) (use '[src.l2]) k)" :portability :common} - {:suite "namespaces / ns operations" :label "ns-name" :expected "true" :actual "(do (require (quote [clojure.string])) (= 'clojure.string (ns-name (find-ns 'clojure.string))))" :portability :common} - {:suite "namespaces / ns operations" :label "find-ns existing" :expected "true" :actual "(some? (find-ns 'clojure.core))" :portability :common} - {:suite "namespaces / ns operations" :label "find-ns missing" :expected "nil" :actual "(find-ns 'does.not.exist)" :portability :common} - {:suite "namespaces / ns operations" :label "resolve var" :expected "true" :actual "(var? (resolve '+))" :portability :common} - {:suite "namespaces / ns operations" :label "resolve missing" :expected "nil" :actual "(resolve 'totally-undefined-xyz)" :portability :common} - {:suite "namespaces / require & refer" :label "require :as" :expected "\"AB\"" :actual "(do (require '[clojure.string :as s]) (s/upper-case \"ab\"))" :portability :common} - {:suite "namespaces / require & refer" :label "require :refer" :expected "true" :actual "(do (require '[clojure.string :refer [blank?]]) (blank? \"\"))" :portability :common} - {:suite "namespaces / require & refer" :label "require :as + :refer" :expected "true" :actual "(do (require '[clojure.string :as s :refer [blank?]]) (and (blank? \"\") (= \"X\" (s/upper-case \"x\"))))" :portability :common} - {:suite "namespaces / require & refer" :label "require clojure.set" :expected "#{1 3 2}" :actual "(do (require '[clojure.set :as set]) (set/union #{1 2} #{3}))" :portability :common} - {:suite "namespaces / require & refer" :label "require clojure.walk" :expected "{:a 2}" :actual "(do (require '[clojure.walk :as w]) (w/postwalk (fn [x] (if (number? x) (inc x) x)) {:a 1}))" :portability :common} - {:suite "namespaces / require & refer" :label "walk keywordize-keys" :expected "{:a 1}" :actual "(do (require '[clojure.walk :as w]) (w/keywordize-keys {\"a\" 1}))" :portability :common} - {:suite "namespaces / require & refer" :label "walk stringify-keys" :expected "true" :actual "(do (require '[clojure.walk :as w]) (= {\"a\" 1} (w/stringify-keys {:a 1})))" :portability :common} - {:suite "namespaces / require & refer" :label "require missing lib throws" :expected :throws :actual "(require '[no.such.lib])" :portability :common} - {:suite "namespaces / require & refer" :label "use missing lib throws" :expected :throws :actual "(use 'no.such.lib)" :portability :common} - {:suite "namespaces / require & refer" :label "require of in-session ns ok" :expected "1" :actual "(do (ns made.here) (def x 1) (require '[made.here]) made.here/x)" :portability :common} - {:suite "namespaces / alias, ns-unalias, ns-publics" :label "alias + use" :expected "\"1,2\"" :actual "(do (require (quote clojure.string)) (alias (quote st) (quote clojure.string)) (st/join \",\" [1 2]))" :portability :common} - {:suite "namespaces / alias, ns-unalias, ns-publics" :label "ns-unalias removes" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote st2) (quote clojure.string)) (ns-unalias (quote user) (quote st2)) (nil? (get (ns-aliases (quote user)) (quote st2))))" :portability :common} - {:suite "namespaces / alias, ns-unalias, ns-publics" :label "ns-publics has var" :expected "true" :actual "(do (def npv 1) (some? (get (ns-publics (quote user)) (quote npv))))" :portability :common} - {:suite "namespaces / alias, ns-unalias, ns-publics" :label "newline returns nil" :expected "nil" :actual "(newline)" :portability :common} - {:suite "namespaces / error inside a fn must not leak its defining ns" :label "alias survives a throwing stdlib call" :expected "\"A\"" :actual "(do (require (quote [clojure.string :as s9])) (try (s9/join nil nil nil) (catch Exception e nil)) (s9/upper-case \"a\"))" :portability :common} - {:suite "namespaces / error inside a fn must not leak its defining ns" :label "*ns* restored after throw" :expected "\"user\"" :actual "(do (require (quote [clojure.walk :as w9])) (try (w9/postwalk nil nil nil) (catch Exception e nil)) (str *ns*))" :portability :common} - {:suite "namespaces / unified alias store" :label "require :as registers the alias" :expected "1" :actual "(do (require (quote [clojure.string :as st1])) (count (filter (fn [[a n]] (= (str a) \"st1\")) (ns-aliases))))" :portability :common} - {:suite "namespaces / unified alias store" :label "aliased call resolves" :expected "\"A\"" :actual "(do (require (quote [clojure.string :as st2])) (st2/upper-case \"a\"))" :portability :common} - {:suite "namespaces / unified alias store" :label "alias fn registers + resolves" :expected "\"B\"" :actual "(do (require (quote [clojure.string])) (alias (quote st3) (quote clojure.string)) (st3/upper-case \"b\"))" :portability :common} - {:suite "namespaces / unified alias store" :label "alias fn visible to ns-aliases" :expected "true" :actual "(do (require (quote [clojure.string])) (alias (quote st4) (quote clojure.string)) (pos? (count (filter (fn [[a n]] (= (str a) \"st4\")) (ns-aliases)))))" :portability :common} - {:suite "namespaces / unified alias store" :label "ns-unalias removes both views" :expected "[0 false]" :actual "(do (require (quote [clojure.string :as st5])) (ns-unalias (quote user) (quote st5)) [(count (filter (fn [[a n]] (= (str a) \"st5\")) (ns-aliases))) (boolean (resolve (quote st5/upper-case)))])" :portability :common} - {:suite "namespaces / unified alias store" :label "ns-resolve through alias" :expected "true" :actual "(do (require (quote [clojure.string :as st6])) (var? (ns-resolve (quote user) (quote st6/upper-case))))" :portability :common} - {:suite "namespaces / unified alias store" :label "empty ns-aliases is a map" :expected "true" :actual "(map? (ns-aliases (quote clojure.core)))" :portability :common} - {:suite "*ns* / identity & printing" :label "str of *ns*" :expected "\"user\"" :actual "(str *ns*)" :portability :common} - {:suite "*ns* / identity & printing" :label "ns-name of *ns*" :expected "(quote user)" :actual "(ns-name *ns*)" :portability :common} - {:suite "*ns* / identity & printing" :label "*ns* is find-ns" :expected "true" :actual "(= (ns-name *ns*) (ns-name (find-ns (quote user))))" :portability :common} - {:suite "*ns* / identity & printing" :label "*ns* not a map" :expected "false" :actual "(map? *ns*)" :portability :common} - {:suite "*ns* / identity & printing" :label "tracks in-ns" :expected "\"jolt.test-ns-a\"" :actual "(do (in-ns (quote jolt.test-ns-a)) (str *ns*))" :portability :common} - {:suite "*ns* / identity & printing" :label "in-ns returns ns" :expected "\"jolt.test-ns-b\"" :actual "(str (in-ns (quote jolt.test-ns-b)))" :portability :common} - {:suite "*ns* / identity & printing" :label "usable with ns fns" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote nsv) (quote clojure.string)) (some? (get (ns-aliases *ns*) (quote nsv))))" :portability :common} - {:suite "*ns* / identity & printing" :label "ns-unalias via *ns*" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote nsw) (quote clojure.string)) (ns-unalias *ns* (quote nsw)) (nil? (get (ns-aliases *ns*) (quote nsw))))" :portability :common} - {:suite "numbers / arithmetic" :label "add" :expected "6" :actual "(+ 1 2 3)" :portability :common} - {:suite "numbers / arithmetic" :label "add zero args" :expected "0" :actual "(+)" :portability :common} - {:suite "numbers / arithmetic" :label "subtract" :expected "5" :actual "(- 10 3 2)" :portability :common} - {:suite "numbers / arithmetic" :label "negate" :expected "-5" :actual "(- 5)" :portability :common} - {:suite "numbers / arithmetic" :label "multiply" :expected "24" :actual "(* 2 3 4)" :portability :common} - {:suite "numbers / arithmetic" :label "multiply zero args" :expected "1" :actual "(*)" :portability :common} - {:suite "numbers / arithmetic" :label "divide" :expected "2" :actual "(/ 10 5)" :portability :common} - {:suite "numbers / arithmetic" :label "divide to fraction" :expected "1/2" :actual "(/ 1 2)" :portability :common} - {:suite "numbers / arithmetic" :label "inc" :expected "6" :actual "(inc 5)" :portability :common} - {:suite "numbers / arithmetic" :label "dec" :expected "4" :actual "(dec 5)" :portability :common} - {:suite "numbers / arithmetic" :label "quot" :expected "3" :actual "(quot 10 3)" :portability :common} - {:suite "numbers / arithmetic" :label "rem" :expected "1" :actual "(rem 10 3)" :portability :common} - {:suite "numbers / arithmetic" :label "mod" :expected "2" :actual "(mod -1 3)" :portability :common} - {:suite "numbers / arithmetic" :label "rem negative" :expected "-1" :actual "(rem -1 3)" :portability :common} - {:suite "numbers / arithmetic" :label "max" :expected "9" :actual "(max 3 9 1)" :portability :common} - {:suite "numbers / arithmetic" :label "min" :expected "1" :actual "(min 3 9 1)" :portability :common} - {:suite "numbers / arithmetic" :label "abs" :expected "5" :actual "(abs -5)" :portability :common} - {:suite "numbers / arithmetic" :label "promoting + alias" :expected "3" :actual "(+' 1 2)" :portability :common} - {:suite "numbers / arithmetic" :label "inc' alias" :expected "6" :actual "(inc' 5)" :portability :common} - {:suite "numbers / comparison" :label "less than" :expected "true" :actual "(< 1 2 3)" :portability :common} - {:suite "numbers / comparison" :label "less than false" :expected "false" :actual "(< 1 3 2)" :portability :common} - {:suite "numbers / comparison" :label "greater than" :expected "true" :actual "(> 3 2 1)" :portability :common} - {:suite "numbers / comparison" :label "<=" :expected "true" :actual "(<= 1 1 2)" :portability :common} - {:suite "numbers / comparison" :label ">=" :expected "true" :actual "(>= 3 3 2)" :portability :common} - {:suite "numbers / comparison" :label "= numbers" :expected "true" :actual "(= 2 2)" :portability :common} - {:suite "numbers / comparison" :label "= different" :expected "false" :actual "(= 2 3)" :portability :common} - {:suite "numbers / comparison" :label "== numeric" :expected "true" :actual "(== 2 2)" :portability :common} - {:suite "numbers / comparison" :label "not=" :expected "true" :actual "(not= 1 2)" :portability :common} - {:suite "numbers / comparison" :label "compare less" :expected "-1" :actual "(compare 1 2)" :portability :common} - {:suite "numbers / comparison" :label "compare equal" :expected "0" :actual "(compare 1 1)" :portability :common} - {:suite "numbers / comparison" :label "compare greater" :expected "1" :actual "(compare 2 1)" :portability :common} - {:suite "numbers / predicates" :label "zero?" :expected "true" :actual "(zero? 0)" :portability :common} - {:suite "numbers / predicates" :label "pos?" :expected "true" :actual "(pos? 5)" :portability :common} - {:suite "numbers / predicates" :label "neg?" :expected "true" :actual "(neg? -5)" :portability :common} - {:suite "numbers / predicates" :label "even?" :expected "true" :actual "(even? 4)" :portability :common} - {:suite "numbers / predicates" :label "odd?" :expected "true" :actual "(odd? 3)" :portability :common} - {:suite "numbers / predicates" :label "number?" :expected "true" :actual "(number? 5)" :portability :common} - {:suite "numbers / predicates" :label "number? false" :expected "false" :actual "(number? :a)" :portability :common} - {:suite "numbers / predicates" :label "int?" :expected "true" :actual "(int? 5)" :portability :common} - {:suite "numbers / predicates" :label "pos-int?" :expected "true" :actual "(pos-int? 5)" :portability :common} - {:suite "numbers / predicates" :label "neg-int?" :expected "true" :actual "(neg-int? -5)" :portability :common} - {:suite "numbers / predicates" :label "nat-int? zero" :expected "true" :actual "(nat-int? 0)" :portability :common} - {:suite "numbers / predicates" :label "nat-int? neg" :expected "false" :actual "(nat-int? -1)" :portability :common} - {:suite "numbers / predicates" :label "ratio? false" :expected "false" :actual "(ratio? 5)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "read ##Inf" :expected "true" :actual "(= ##Inf (/ 1.0 0.0))" :portability :common} - {:suite "numbers / floats & symbolic values" :label "read ##-Inf" :expected "true" :actual "(< ##-Inf 0)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "##NaN not= itself" :expected "true" :actual "(not (== ##NaN ##NaN))" :portability :common} - {:suite "numbers / floats & symbolic values" :label "float? fractional" :expected "true" :actual "(float? 1.5)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "double? fractional" :expected "true" :actual "(double? 0.25)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "float? integer" :expected "false" :actual "(float? 3)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "float? ##Inf" :expected "true" :actual "(float? ##Inf)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "double? ##NaN" :expected "true" :actual "(double? ##NaN)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "infinite? ##Inf" :expected "true" :actual "(infinite? ##Inf)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "infinite? ##-Inf" :expected "true" :actual "(infinite? ##-Inf)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "infinite? finite" :expected "false" :actual "(infinite? 1.5)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "NaN? ##NaN" :expected "true" :actual "(NaN? ##NaN)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "NaN? number" :expected "false" :actual "(NaN? 1.0)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "int? ##Inf false" :expected "false" :actual "(int? ##Inf)" :portability :common} - {:suite "numbers / floats & symbolic values" :label "pos-int? ##Inf" :expected "false" :actual "(pos-int? ##Inf)" :portability :common} - {:suite "numbers / literal syntax" :label "bigint suffix N" :expected "42N" :actual "42N" :portability :common} - {:suite "numbers / literal syntax" :label "bigint zero" :expected "0N" :actual "0N" :portability :common} - {:suite "numbers / literal syntax" :label "bigdec suffix M" :expected "1.5M" :actual "1.5M" :portability :common} - {:suite "numbers / literal syntax" :label "bigdec int M" :expected "0.0M" :actual "0.0M" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "add (value position)" :expected "4.0M" :actual "(reduce + [1.5M 2.5M])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "add preserves max scale" :expected "\"4.00\"" :actual "(str (reduce + [1.50M 2.5M]))" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "add three" :expected "7.0M" :actual "(reduce + [1.5M 2.5M 3.0M])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "subtract (apply)" :expected "3.5M" :actual "(apply - [5M 1.5M])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "multiply adds scales" :expected "\"3.0000\"" :actual "(str (reduce * [1.50M 2.00M]))" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "long contagion stays bigdec" :expected "3.5M" :actual "(reduce + [1.5M 2])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "double contagion -> double" :expected "3.5" :actual "(reduce + [1.5M 2.0])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "exact divide minimal scale" :expected "\"0.25\"" :actual "(str (reduce / [1M 4M]))" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "exact divide whole" :expected "5M" :actual "(reduce / [10M 2M])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "non-terminating divide throws" :expected ":nonterm" :actual "(try (reduce / [1M 3M]) (catch ArithmeticException _ :nonterm))" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "compare is scale-independent" :expected "0" :actual "(compare 1.0M 1.00M)" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "compare orders by value" :expected "-1" :actual "(compare 1.5M 2.5M)" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "sort uses bigdec compare" :expected "[1M 2M 3M]" :actual "(vec (sort [3M 1M 2M]))" :portability :common} - {:suite "numbers / bigdec call position" :label "add" :expected "4.0M" :actual "(+ 1.5M 2.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "multiply adds scales" :expected "\"3.0000\"" :actual "(str (* 1.50M 2.00M))" :portability :common} - {:suite "numbers / bigdec call position" :label "subtract" :expected "3.5M" :actual "(- 5M 1.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "negate" :expected "-1.5M" :actual "(- 1.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "long contagion" :expected "3.5M" :actual "(+ 1.5M 2)" :portability :common} - {:suite "numbers / bigdec call position" :label "exact divide" :expected "0.25M" :actual "(/ 1M 4M)" :portability :common} - {:suite "numbers / bigdec call position" :label "less-than" :expected "true" :actual "(< 1.5M 2.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "greater-than false" :expected "false" :actual "(> 1.5M 2.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "zero?" :expected "true" :actual "(zero? 0M)" :portability :common} - {:suite "numbers / bigdec call position" :label "pos?" :expected "true" :actual "(pos? 1.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "neg? false" :expected "false" :actual "(neg? 1.5M)" :portability :common} - {:suite "numbers / bigdec call position" :label "quot truncates to scale 0" :expected "3M" :actual "(quot 7M 2M)" :portability :common} - {:suite "numbers / bigdec call position" :label "rem" :expected "1M" :actual "(rem 7M 2M)" :portability :common} - {:suite "numbers / bigdec call position" :label "let-bound operands" :expected "4.0M" :actual "(let [a 1.5M b 2.5M] (+ a b))" :portability :common} - {:suite "numbers / bigdec call position" :label "nested arithmetic propagates" :expected "6.0M" :actual "(+ (* 1.5M 2M) 3M)" :portability :common} - {:suite "numbers / bigdec call position" :label "non-terminating divide throws" :expected ":nonterm" :actual "(try (/ 1M 3M) (catch ArithmeticException _ :nonterm))" :portability :common} - {:suite "numbers / bigdec call position" :label "min" :expected "1M" :actual "(min 1M 2M)" :portability :common} - {:suite "numbers / bigdec call position" :label "max of three" :expected "3M" :actual "(max 1M 2M 3M)" :portability :common} - {:suite "numbers / bigdec call position" :label "min returns the operand, scale intact" :expected "\"1.50\"" :actual "(str (min 1.50M 2M))" :portability :common} - {:suite "numbers / bigdec call position" :label "max tie keeps second operand" :expected "\"1.50\"" :actual "(str (max 1.5M 1.50M))" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "max (value position)" :expected "3M" :actual "(reduce max [1M 3M 2M])" :portability :common} - {:suite "numbers / bigdec arithmetic" :label "min (apply)" :expected "1M" :actual "(apply min [3M 1M 2M])" :portability :common} - {:suite "numbers / literal syntax" :label "ratio -> double" :expected "1/2" :actual "1/2" :portability :common} - {:suite "numbers / literal syntax" :label "ratio 3/4" :expected "3/4" :actual "3/4" :portability :common} - {:suite "numbers / literal syntax" :label "neg ratio" :expected "-1/2" :actual "-1/2" :portability :common} - {:suite "numbers / literal syntax" :label "radix binary" :expected "10" :actual "2r1010" :portability :common} - {:suite "numbers / literal syntax" :label "radix hex-ish" :expected "255" :actual "16rFF" :portability :common} - {:suite "numbers / literal syntax" :label "radix base36" :expected "35" :actual "36rZ" :portability :common} - {:suite "numbers / literal syntax" :label "hex" :expected "255" :actual "0xFF" :portability :common} - {:suite "numbers / literal syntax" :label "exponent" :expected "1000.0" :actual "1e3" :portability :common} - {:suite "numbers / literal syntax" :label "exponent neg" :expected "0.015" :actual "1.5e-2" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "odd? nil" :expected :throws :actual "(odd? nil)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "odd? fractional" :expected :throws :actual "(odd? 1.5)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "even? inf" :expected :throws :actual "(even? ##Inf)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "zero? nil" :expected :throws :actual "(zero? nil)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "pos? false" :expected :throws :actual "(pos? false)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "neg? keyword" :expected :throws :actual "(neg? :a)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "< nil" :expected :throws :actual "(< nil 1)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "> with nil" :expected :throws :actual "(> 1 nil)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "max non-number" :expected :throws :actual "(max 1 nil)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "quot by zero" :expected :throws :actual "(quot 10 0)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "quot inf" :expected :throws :actual "(quot ##Inf 1)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "< arity-1 any" :expected "true" :actual "(< :anything)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "odd? ok" :expected "true" :actual "(odd? 3)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "< ok" :expected "true" :actual "(< 1 2 3)" :portability :common} - {:suite "numbers / strictness (throws like Clojure)" :label "quot ok" :expected "3" :actual "(quot 10 3)" :portability :common} - {:suite "numbers / printing of inf & nan" :label "str Infinity" :expected "\"Infinity\"" :actual "(str ##Inf)" :portability :common} - {:suite "numbers / printing of inf & nan" :label "str -Infinity" :expected "\"-Infinity\"" :actual "(str ##-Inf)" :portability :common} - {:suite "numbers / printing of inf & nan" :label "str NaN" :expected "\"NaN\"" :actual "(str ##NaN)" :portability :common} - {:suite "numbers / printing of inf & nan" :label "pr-str Infinity" :expected "\"##Inf\"" :actual "(pr-str ##Inf)" :portability :common} - {:suite "numbers / printing of inf & nan" :label "inf inside coll" :expected "\"[##Inf]\"" :actual "(str [##Inf])" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-and" :expected "4" :actual "(bit-and 12 6)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-or" :expected "14" :actual "(bit-or 12 6)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-xor" :expected "10" :actual "(bit-xor 12 6)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-shift-left" :expected "8" :actual "(bit-shift-left 1 3)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-shift-right" :expected "2" :actual "(bit-shift-right 8 2)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-set" :expected "8" :actual "(bit-set 0 3)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-clear" :expected "13" :actual "(bit-clear 15 1)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bit-test true" :expected "true" :actual "(bit-test 4 2)" :portability :common} - {:suite "numbers / bit-ops & math" :label "bigint 64-bit" :expected "\"9000000000\"" :actual "(str (bigint 9000000000))" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand-int in range" :expected "true" :actual "(let [r (rand-int 5)] (and (integer? r) (>= r 0) (< r 5)))" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand-int zero" :expected "0" :actual "(rand-int 1)" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand in [0,1)" :expected "true" :actual "(let [r (rand)] (and (>= r 0) (< r 1)))" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand n in [0,n)" :expected "true" :actual "(let [r (rand 10)] (and (>= r 0) (< r 10)))" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand-nth member" :expected "true" :actual "(contains? #{:a :b :c} (rand-nth [:a :b :c]))" :portability :common} - {:suite "numbers / random (invariants — non-deterministic)" :label "rand-nth single" :expected ":x" :actual "(rand-nth [:x])" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long" :expected "42" :actual "(parse-long \"42\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long negative" :expected "-7" :actual "(parse-long \"-7\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long plus" :expected "7" :actual "(parse-long \"+7\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long float nil" :expected "nil" :actual "(parse-long \"1.5\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long hex nil" :expected "nil" :actual "(parse-long \"0x10\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long empty nil" :expected "nil" :actual "(parse-long \"\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long junk nil" :expected "nil" :actual "(parse-long \"12ab\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-long throws" :expected :throws :actual "(parse-long 42)" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double" :expected "1.5" :actual "(parse-double \"1.5\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double int" :expected "4.0" :actual "(parse-double \"4\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double sci" :expected "1500.0" :actual "(parse-double \"1.5e3\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double neg" :expected "-0.5" :actual "(parse-double \"-0.5\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double junk" :expected "nil" :actual "(parse-double \"abc\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double trail" :expected "nil" :actual "(parse-double \"1.5x\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-double throws" :expected :throws :actual "(parse-double :k)" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-boolean true" :expected "true" :actual "(parse-boolean \"true\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-boolean false" :expected "false" :actual "(parse-boolean \"false\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-boolean case" :expected "nil" :actual "(parse-boolean \"True\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-boolean junk" :expected "nil" :actual "(parse-boolean \"yes\")" :portability :common} - {:suite "numbers / parse fns (1.11)" :label "parse-boolean throws" :expected :throws :actual "(parse-boolean true)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "+'" :expected "3" :actual "(+' 1 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "-'" :expected "3" :actual "(-' 5 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "*'" :expected "12" :actual "(*' 3 4)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "inc'" :expected "6" :actual "(inc' 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "dec'" :expected "4" :actual "(dec' 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add" :expected "5" :actual "(unchecked-add 2 3)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add-int" :expected "5" :actual "(unchecked-add-int 2 3)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-subtract" :expected "3" :actual "(unchecked-subtract 5 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-subtract-int" :expected "3" :actual "(unchecked-subtract-int 5 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-multiply" :expected "12" :actual "(unchecked-multiply 3 4)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-multiply-int" :expected "12" :actual "(unchecked-multiply-int 3 4)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-negate" :expected "-5" :actual "(unchecked-negate 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-negate-int" :expected "-5" :actual "(unchecked-negate-int 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-inc" :expected "2" :actual "(unchecked-inc 1)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-inc-int" :expected "2" :actual "(unchecked-inc-int 1)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-dec" :expected "0" :actual "(unchecked-dec 1)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-dec-int" :expected "0" :actual "(unchecked-dec-int 1)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int" :expected "3" :actual "(unchecked-divide-int 7 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int negative truncates toward zero" :expected "-3" :actual "(unchecked-divide-int -7 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int by zero throws" :expected :throws :actual "(unchecked-divide-int 1 0)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-remainder-int" :expected "1" :actual "(unchecked-remainder-int 7 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-remainder-int negative" :expected "-1" :actual "(unchecked-remainder-int -7 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-int truncates" :expected "3" :actual "(unchecked-int 3.7)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-int negative" :expected "-3" :actual "(unchecked-int -3.7)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add on ratios does not wrap to long" :expected "4/3" :actual "(unchecked-add 2/3 2/3)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-multiply ratio by int" :expected "4/3" :actual "(unchecked-multiply 2/3 2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-negate ratio" :expected "-2/3" :actual "(unchecked-negate 2/3)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add ratios summing to zero" :expected "0" :actual "(unchecked-add 1/2 -1/2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-inc ratio" :expected "3/2" :actual "(unchecked-inc 1/2)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "unchecked-long" :expected "3" :actual "(unchecked-long 3.7)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "int? on integer" :expected "true" :actual "(int? 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "int? on double" :expected "false" :actual "(int? 5.5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "int? on non-number" :expected "false" :actual "(int? \"5\")" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "num passes a number through" :expected "5" :actual "(num 5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "num on a double" :expected "5.5" :actual "(num 5.5)" :portability :common} - {:suite "numbers / promoting & unchecked aliases" :label "num throws on non-number" :expected :throws :actual "(num \"x\")" :portability :common} - {:suite "numbers / == numeric equality" :label "== single arg" :expected "true" :actual "(== :a)" :portability :common} - {:suite "numbers / == numeric equality" :label "== equal" :expected "true" :actual "(== 2 2)" :portability :common} - {:suite "numbers / == numeric equality" :label "== unequal" :expected "false" :actual "(== 2 3)" :portability :common} - {:suite "numbers / == numeric equality" :label "== chained" :expected "true" :actual "(== 2 2 2)" :portability :common} - {:suite "numbers / == numeric equality" :label "== chained unequal" :expected "false" :actual "(== 2 2 3)" :portability :common} - {:suite "numbers / == numeric equality" :label "== int and double" :expected "true" :actual "(== 1 1.0)" :portability :common} - {:suite "numbers / == numeric equality" :label "== throws on non-number" :expected :throws :actual "(== 1 :a)" :portability :common} - {:suite "numbers / == numeric equality" :label "== throws on two keywords" :expected :throws :actual "(== :a :a)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and 2" :expected "4" :actual "(bit-and 12 6)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and 3" :expected "4" :actual "(bit-and 12 6 7)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and 4" :expected "0" :actual "(bit-and 12 6 7 3)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-or 3" :expected "7" :actual "(bit-or 1 2 4)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-xor 3" :expected "7" :actual "(bit-xor 1 2 4)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-xor folds left" :expected "1" :actual "(bit-xor 5 6 2)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and-not 2" :expected "8" :actual "(bit-and-not 12 6)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and-not 3" :expected "8" :actual "(bit-and-not 12 6 3)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and single arg throws" :expected :throws :actual "(bit-and 5)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-or keeps binary fast path" :expected "3" :actual "(bit-or 1 2)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-not" :expected "-6" :actual "(bit-not 5)" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-and in value position" :expected "8" :actual "(reduce bit-and [15 9 12])" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-xor in value position" :expected "0" :actual "(reduce bit-xor 0 [1 2 3])" :portability :common} - {:suite "numbers / variadic bit ops" :label "bit-or via apply" :expected "7" :actual "(apply bit-or [1 2 4])" :portability :common} - {:suite "numbers / variadic bit ops" :label "unsigned-shift over a full 64-bit value" :expected "17179869183" :actual "(unsigned-bit-shift-right -1 30)" :portability :common} - ;; var-reference cell caching (runtime path): a ref inside a fn caches the - ;; resolved cell, but stays correct under redefinition (cell root mutated in - ;; place) and dynamic binding (read goes through the binding-aware path). - {:suite "vars / cached reference stays correct" :label "redefinition is seen through a cached ref" :expected "2" :actual "(do (def x 1) (defn f [] x) (def x 2) (f))" :portability :common} - {:suite "vars / cached reference stays correct" :label "dynamic binding is seen through a cached ref" :expected "[1 9 1]" :actual "(do (def ^:dynamic *d* 1) (defn g [] *d*) [(g) (binding [*d* 9] (g)) (g)])" :portability :common} - {:suite "vars / cached reference stays correct" :label "forward reference resolves once the var is defined" :expected "42" :actual "(do (defn a [] (b)) (defn b [] 42) (a))" :portability :common} - {:suite "predicates / nil & boolean" :label "nil? true" :expected "true" :actual "(nil? nil)" :portability :common} - {:suite "predicates / nil & boolean" :label "nil? false" :expected "false" :actual "(nil? 0)" :portability :common} - {:suite "predicates / nil & boolean" :label "some? true" :expected "true" :actual "(some? 0)" :portability :common} - {:suite "predicates / nil & boolean" :label "some? on nil" :expected "false" :actual "(some? nil)" :portability :common} - {:suite "predicates / nil & boolean" :label "true?" :expected "true" :actual "(true? true)" :portability :common} - {:suite "predicates / nil & boolean" :label "false?" :expected "true" :actual "(false? false)" :portability :common} - {:suite "predicates / nil & boolean" :label "boolean? true" :expected "true" :actual "(boolean? false)" :portability :common} - {:suite "predicates / nil & boolean" :label "not nil" :expected "true" :actual "(not nil)" :portability :common} - {:suite "predicates / nil & boolean" :label "not 0 is false" :expected "false" :actual "(not 0)" :portability :common} - {:suite "predicates / nil & boolean" :label "boolean of nil" :expected "false" :actual "(boolean nil)" :portability :common} - {:suite "predicates / nil & boolean" :label "boolean of value" :expected "true" :actual "(boolean 5)" :portability :common} - {:suite "predicates / types" :label "string?" :expected "true" :actual "(string? \"x\")" :portability :common} - {:suite "predicates / types" :label "number?" :expected "true" :actual "(number? 1)" :portability :common} - {:suite "predicates / types" :label "keyword?" :expected "true" :actual "(keyword? :a)" :portability :common} - {:suite "predicates / types" :label "symbol?" :expected "true" :actual "(symbol? (quote a))" :portability :common} - {:suite "predicates / types" :label "char?" :expected "true" :actual "(char? \\a)" :portability :common} - {:suite "predicates / types" :label "fn? on fn" :expected "true" :actual "(fn? inc)" :portability :common} - {:suite "predicates / types" :label "ifn? on keyword" :expected "true" :actual "(ifn? :a)" :portability :common} - {:suite "predicates / types" :label "vector?" :expected "true" :actual "(vector? [1])" :portability :common} - {:suite "predicates / types" :label "list?" :expected "true" :actual "(list? (list 1))" :portability :common} - {:suite "predicates / types" :label "map?" :expected "true" :actual "(map? {:a 1})" :portability :common} - {:suite "predicates / types" :label "set?" :expected "true" :actual "(set? #{1})" :portability :common} - {:suite "predicates / types" :label "coll? vector" :expected "true" :actual "(coll? [1])" :portability :common} - {:suite "predicates / types" :label "coll? map" :expected "true" :actual "(coll? {:a 1})" :portability :common} - {:suite "predicates / types" :label "coll? on number" :expected "false" :actual "(coll? 1)" :portability :common} - {:suite "predicates / types" :label "seq? list" :expected "true" :actual "(seq? (list 1))" :portability :common} - {:suite "predicates / types" :label "seq? vector" :expected "false" :actual "(seq? [1])" :portability :common} - {:suite "predicates / types" :label "sequential? vector" :expected "true" :actual "(sequential? [1])" :portability :common} - {:suite "predicates / types" :label "associative? map" :expected "true" :actual "(associative? {:a 1})" :portability :common} - {:suite "predicates / types" :label "associative? vec" :expected "true" :actual "(associative? [1])" :portability :common} - {:suite "predicates / types" :label "associative? list" :expected "false" :actual "(associative? '(1 2))" :portability :common} - {:suite "predicates / types" :label "associative? set" :expected "false" :actual "(associative? #{1})" :portability :common} - {:suite "predicates / types" :label "reversible? vec" :expected "true" :actual "(reversible? [1 2])" :portability :common} - {:suite "predicates / types" :label "reversible? list" :expected "false" :actual "(reversible? '(1 2))" :portability :common} - {:suite "predicates / types" :label "reversible? smap" :expected "true" :actual "(reversible? (sorted-map :a 1))" :portability :common} - {:suite "predicates / types" :label "reversible? hmap" :expected "false" :actual "(reversible? (hash-map :a 1))" :portability :common} - {:suite "predicates / types" :label "indexed? vector" :expected "true" :actual "(indexed? [1])" :portability :common} - {:suite "predicates / types" :label "counted? vector" :expected "true" :actual "(counted? [1])" :portability :common} - {:suite "predicates / idents" :label "ident? keyword" :expected "true" :actual "(ident? :a)" :portability :common} - {:suite "predicates / idents" :label "ident? symbol" :expected "true" :actual "(ident? (quote a))" :portability :common} - {:suite "predicates / idents" :label "simple-keyword?" :expected "true" :actual "(simple-keyword? :a)" :portability :common} - {:suite "predicates / idents" :label "qualified-keyword?" :expected "true" :actual "(qualified-keyword? :a/b)" :portability :common} - {:suite "predicates / idents" :label "simple-symbol?" :expected "true" :actual "(simple-symbol? (quote a))" :portability :common} - {:suite "predicates / idents" :label "qualified-symbol?" :expected "true" :actual "(qualified-symbol? (quote a/b))" :portability :common} - {:suite "predicates / idents" :label "name of keyword" :expected "\"a\"" :actual "(name :a)" :portability :common} - {:suite "predicates / idents" :label "name of qualified" :expected "\"b\"" :actual "(name :a/b)" :portability :common} - {:suite "predicates / idents" :label "namespace" :expected "\"a\"" :actual "(namespace :a/b)" :portability :common} - {:suite "predicates / idents" :label "namespace simple" :expected "nil" :actual "(namespace :a)" :portability :common} - {:suite "predicates / idents" :label "keyword constructor" :expected ":foo" :actual "(keyword \"foo\")" :portability :common} - {:suite "predicates / idents" :label "keyword ns + name" :expected ":a/b" :actual "(keyword \"a\" \"b\")" :portability :common} - {:suite "predicates / idents" :label "symbol constructor" :expected "(quote x)" :actual "(symbol \"x\")" :portability :common} - {:suite "predicates / idents" :label "name of string" :expected "\"s\"" :actual "(name \"s\")" :portability :common} - {:suite "predicates / overlay-migrated" :label "not-any? true" :expected "true" :actual "(not-any? even? [1 3 5])" :portability :common} - {:suite "predicates / overlay-migrated" :label "not-any? false" :expected "false" :actual "(not-any? even? [1 2 3])" :portability :common} - {:suite "predicates / overlay-migrated" :label "not-every? true" :expected "true" :actual "(not-every? even? [2 4 5])" :portability :common} - {:suite "predicates / overlay-migrated" :label "not-every? false" :expected "false" :actual "(not-every? even? [2 4 6])" :portability :common} - {:suite "predicates / overlay-migrated" :label "ident? number" :expected "false" :actual "(ident? 1)" :portability :common} - {:suite "predicates / overlay-migrated" :label "qualified-ident?" :expected "true" :actual "(qualified-ident? :a/b)" :portability :common} - {:suite "predicates / overlay-migrated" :label "qualified-ident? no" :expected "false" :actual "(qualified-ident? :a)" :portability :common} - {:suite "predicates / overlay-migrated" :label "simple-ident?" :expected "true" :actual "(simple-ident? :a)" :portability :common} - {:suite "predicates / overlay-migrated" :label "ratio?" :expected "false" :actual "(ratio? 3)" :portability :common} - {:suite "predicates / overlay-migrated" :label "decimal?" :expected "false" :actual "(decimal? 3)" :portability :common} - {:suite "predicates / overlay-migrated" :label "class? of value" :expected "false" :actual "(class? \"s\")" :portability :common} - {:suite "predicates / overlay-migrated" :label "class? of symbol" :expected "false" :actual "(class? 'java.lang.String)" :portability :jvm} - {:suite "predicates / overlay-migrated" :label "rational? int" :expected "true" :actual "(rational? 3)" :portability :common} - {:suite "predicates / overlay-migrated" :label "rational? float" :expected "false" :actual "(rational? 3.5)" :portability :common} - {:suite "predicates / overlay-migrated" :label "nat-int? zero" :expected "true" :actual "(nat-int? 0)" :portability :common} - {:suite "predicates / overlay-migrated" :label "nat-int? neg" :expected "false" :actual "(nat-int? -1)" :portability :common} - {:suite "predicates / overlay-migrated" :label "pos-int?" :expected "true" :actual "(pos-int? 5)" :portability :common} - {:suite "predicates / overlay-migrated" :label "neg-int?" :expected "true" :actual "(neg-int? -3)" :portability :common} - {:suite "predicates / overlay-migrated" :label "NaN? on nan" :expected "true" :actual "(NaN? (/ 0.0 0.0))" :portability :common} - {:suite "predicates / overlay-migrated" :label "NaN? on number" :expected "false" :actual "(NaN? 5)" :portability :common} - {:suite "predicates / overlay-migrated" :label "abs negative" :expected "3" :actual "(abs -3)" :portability :common} - {:suite "predicates / overlay-migrated" :label "abs positive" :expected "2.5" :actual "(abs 2.5)" :portability :common} - {:suite "predicates / overlay-migrated" :label "object?" :expected "false" :actual "(object? 1)" :portability :common} - {:suite "predicates / overlay-migrated" :label "undefined?" :expected "false" :actual "(undefined? 1)" :portability :common} - {:suite "predicates / overlay-migrated" :label "keyword-identical?" :expected "true" :actual "(keyword-identical? :a :a)" :portability :common} - {:suite "predicates / overlay-migrated" :label "keyword-identical? no" :expected "false" :actual "(keyword-identical? :a :b)" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? symbol" :expected "false" :actual "(map? (quote sym))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? char" :expected "false" :actual "(map? \\a)" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? uuid" :expected "false" :actual "(map? (random-uuid))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? literal" :expected "true" :actual "(map? {:a 1})" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? hash-map" :expected "true" :actual "(map? (hash-map :a 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? sorted-map" :expected "true" :actual "(map? (sorted-map :a 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? record" :expected "true" :actual "(do (defrecord Mr [a]) (map? (->Mr 1)))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? sorted-set" :expected "false" :actual "(map? (sorted-set 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "map? vector" :expected "false" :actual "(map? [1])" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? symbol" :expected "false" :actual "(coll? (quote sym))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? char" :expected "false" :actual "(coll? \\a)" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? uuid" :expected "false" :actual "(coll? (random-uuid))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? keyword" :expected "false" :actual "(coll? :k)" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? string" :expected "false" :actual "(coll? \"s\")" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? map literal" :expected "true" :actual "(coll? {:a 1})" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? sorted-map" :expected "true" :actual "(coll? (sorted-map :a 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? sorted-set" :expected "true" :actual "(coll? (sorted-set 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? record" :expected "true" :actual "(do (defrecord Cr [a]) (coll? (->Cr 1)))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? vector" :expected "true" :actual "(coll? [1])" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? list" :expected "true" :actual "(coll? (list 1))" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? set" :expected "true" :actual "(coll? #{1})" :portability :common} - {:suite "predicates / map? & coll? strictness" :label "coll? lazy seq" :expected "true" :actual "(coll? (map inc [1]))" :portability :common} - {:suite "predicates / tagged-value" :label "atom? yes" :expected "true" :actual "(atom? (atom 1))" :portability :common} - {:suite "predicates / tagged-value" :label "atom? no" :expected "false" :actual "(atom? 1)" :portability :common} - {:suite "predicates / tagged-value" :label "volatile? yes" :expected "true" :actual "(volatile? (volatile! 1))" :portability :common} - {:suite "predicates / tagged-value" :label "volatile? no" :expected "false" :actual "(volatile? (atom 1))" :portability :common} - {:suite "predicates / tagged-value" :label "record? yes" :expected "true" :actual "(do (defrecord Rp [a]) (record? (->Rp 1)))" :portability :common} - {:suite "predicates / tagged-value" :label "record? no map" :expected "false" :actual "(record? {:a 1})" :portability :common} - {:suite "predicates / tagged-value" :label "record? no nil" :expected "false" :actual "(record? nil)" :portability :common} - {:suite "predicates / tagged-value" :label "tagged-literal? yes" :expected "true" :actual "(tagged-literal? (tagged-literal (quote inst) \"2020\"))" :portability :common} - {:suite "predicates / tagged-value" :label "tagged-literal? no" :expected "false" :actual "(tagged-literal? 1)" :portability :common} - {:suite "predicates / tagged-value" :label "reader-conditional? no" :expected "false" :actual "(reader-conditional? 1)" :portability :common} - {:suite "predicates / tagged-value" :label "chunked-seq? true for a vector seq" :expected "true" :actual "(chunked-seq? (seq [1 2 3]))" :portability :common} - {:suite "predicates / equality & identity" :label "= same" :expected "true" :actual "(= 1 1)" :portability :common} - {:suite "predicates / equality & identity" :label "= vectors" :expected "true" :actual "(= [1 2] [1 2])" :portability :common} - {:suite "predicates / equality & identity" :label "= vector & list" :expected "true" :actual "(= [1 2] (list 1 2))" :portability :common} - {:suite "predicates / equality & identity" :label "= maps" :expected "true" :actual "(= {:a 1} {:a 1})" :portability :common} - {:suite "predicates / equality & identity" :label "= sets" :expected "true" :actual "(= #{1 2} #{2 1})" :portability :common} - {:suite "predicates / equality & identity" :label "= nested" :expected "true" :actual "(= {:a [1 2]} {:a [1 2]})" :portability :common} - {:suite "predicates / equality & identity" :label "not= differs" :expected "true" :actual "(not= [1 2] [1 3])" :portability :common} - {:suite "predicates / equality & identity" :label "identical? same kw" :expected "true" :actual "(identical? :a :a)" :portability :common} - {:suite "predicates / equality & identity" :label "compare strings" :expected "-1" :actual "(compare \"a\" \"b\")" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "seqable? vector" :expected "true" :actual "(seqable? [1])" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "seqable? map" :expected "true" :actual "(seqable? {:a 1})" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "seqable? string" :expected "true" :actual "(seqable? \"s\")" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "seqable? nil" :expected "true" :actual "(seqable? nil)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "seqable? number" :expected "false" :actual "(seqable? 5)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "integer? int" :expected "true" :actual "(integer? 5)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "integer? fraction" :expected "false" :actual "(integer? 5.5)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "reduced? wrapped" :expected "true" :actual "(reduced? (reduced 1))" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "reduced? plain" :expected "false" :actual "(reduced? 1)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "deref reduced" :expected "9" :actual "(deref (reduced 9))" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "unreduced wrapped" :expected "9" :actual "(unreduced (reduced 9))" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "unreduced plain" :expected "9" :actual "(unreduced 9)" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "not-empty full" :expected "[1]" :actual "(not-empty [1])" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "not-empty empty" :expected "nil" :actual "(not-empty [])" :portability :common} - {:suite "predicates / seqable, reduced & emptiness" :label "not-empty string" :expected "nil" :actual "(not-empty \"\")" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare =" :expected "0" :actual "(compare 1 1)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare <" :expected "-1" :actual "(compare 1 2)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare nil first" :expected "-1" :actual "(compare nil 1)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare nil nil" :expected "0" :actual "(compare nil nil)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare strings" :expected "-1" :actual "(compare \"a\" \"b\")" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare keywords" :expected "-1" :actual "(compare :a :b)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare symbols" :expected "-1" :actual "(compare (quote a) (quote b))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare bools" :expected "-1" :actual "(compare false true)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare vec length" :expected "-1" :actual "(compare [1 2] [1 2 3])" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare vec elems" :expected "-1" :actual "(compare [1 2] [1 3])" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "compare cross-type throws" :expected :throws :actual "(compare 1 \"a\")" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "sort with compare" :expected "[nil 1 3]" :actual "(sort compare [3 nil 1])" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "type meta override" :expected ":custom" :actual "(type (with-meta [1] {:type :custom}))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "type of record" :expected "false" :actual "(do (defrecord TyR [a]) (= (symbol (str (type (->TyR 1)))) (type (->TyR 1))))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "any? value" :expected "true" :actual "(any? 5)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "any? nil" :expected "true" :actual "(any? nil)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "gensym is symbol" :expected "true" :actual "(symbol? (gensym))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "gensym prefix" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/starts-with? (str (gensym \"p_\")) \"p_\"))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "gensym distinct" :expected "false" :actual "(= (gensym) (gensym))" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "int? Inf false" :expected "false" :actual "(int? ##Inf)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "integer? Inf false" :expected "false" :actual "(integer? ##Inf)" :portability :common} - {:suite "predicates / compare, type, any? (stage 3)" :label "integer? NaN false" :expected "false" :actual "(integer? ##NaN)" :portability :common} - {:suite "predicates / ifn?" :label "fn" :expected "true" :actual "(ifn? inc)" :portability :common} - {:suite "predicates / ifn?" :label "keyword" :expected "true" :actual "(ifn? :k)" :portability :common} - {:suite "predicates / ifn?" :label "symbol" :expected "true" :actual "(ifn? (quote s))" :portability :common} - {:suite "predicates / ifn?" :label "map" :expected "true" :actual "(ifn? {})" :portability :common} - {:suite "predicates / ifn?" :label "sorted map" :expected "true" :actual "(ifn? (sorted-map))" :portability :common} - {:suite "predicates / ifn?" :label "set" :expected "true" :actual "(ifn? #{1})" :portability :common} - {:suite "predicates / ifn?" :label "vector" :expected "true" :actual "(ifn? [1])" :portability :common} - {:suite "predicates / ifn?" :label "var" :expected "true" :actual "(ifn? (var first))" :portability :common} - {:suite "predicates / ifn?" :label "list NOT" :expected "false" :actual "(ifn? (list 1 2))" :portability :common} - {:suite "predicates / ifn?" :label "lazy NOT" :expected "false" :actual "(ifn? (map inc [1]))" :portability :common} - {:suite "predicates / ifn?" :label "string NOT" :expected "false" :actual "(ifn? \"s\")" :portability :common} - {:suite "predicates / ifn?" :label "number NOT" :expected "false" :actual "(ifn? 5)" :portability :common} - {:suite "predicates / ifn?" :label "nil NOT" :expected "false" :actual "(ifn? nil)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? zero" :expected "true" :actual "(zero? 0)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? nonzero" :expected "false" :actual "(zero? 3)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? throws" :expected :throws :actual "(zero? :a)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? throws on nil" :expected :throws :actual "(zero? nil)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? positive" :expected "true" :actual "(pos? 2)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? zero" :expected "false" :actual "(pos? 0)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? throws" :expected :throws :actual "(pos? \"x\")" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "neg? throws" :expected :throws :actual "(neg? \"x\")" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? all pass" :expected "true" :actual "(every? odd? [1 3 5])" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? one fails" :expected "false" :actual "(every? odd? [1 2 5])" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? vacuous" :expected "true" :actual "(every? odd? [])" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? nil coll" :expected "true" :actual "(every? odd? nil)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? infinite short-circuit" :expected "false" :actual "(every? pos? (range))" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? char" :expected "true" :actual "(char? \\x)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? string" :expected "false" :actual "(char? \"x\")" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? number" :expected "false" :actual "(char? 97)" :portability :common} - {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? nil" :expected "false" :actual "(char? nil)" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "protocol on record" :expected "16" :actual "(do (defprotocol Shape (area [s])) (defrecord Sq [side] Shape (area [_] (* side side))) (area (->Sq 4)))" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "protocol on deftype" :expected "16" :actual "(do (defprotocol Shape (area [s])) (deftype Sq [side] Shape (area [_] (* side side))) (area (->Sq 4)))" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "multiple methods" :expected "[1 2]" :actual "(do (defprotocol P (m [s]) (n [s])) (defrecord R [a b] P (m [_] a) (n [_] b)) [(m (->R 1 2)) (n (->R 1 2))])" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "multiple protocols" :expected "[:a :b]" :actual "(do (defprotocol P1 (p1 [s])) (defprotocol P2 (p2 [s])) (deftype T [] P1 (p1 [_] :a) P2 (p2 [_] :b)) [(p1 (->T)) (p2 (->T))])" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "method args" :expected "7" :actual "(do (defprotocol P (add [s x])) (defrecord R [n] P (add [_ x] (+ n x))) (add (->R 5) 2))" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "extend-type" :expected "10" :actual "(do (defprotocol P (twice [s])) (extend-type Number P (twice [n] (* n 2))) (twice 5))" :portability :common} - {:suite "protocols / defprotocol & dispatch" :label "extend-protocol" :expected "[2 4]" :actual "(do (defprotocol P (dbl [s])) (extend-protocol P Number (dbl [n] (* n 2))) [(dbl 1) (dbl 2)])" :portability :common} - {:suite "protocols / records" :label "record field access" :expected "1" :actual "(do (defrecord R [a b]) (:a (->R 1 2)))" :portability :common} - {:suite "protocols / records" :label "record map access" :expected "2" :actual "(do (defrecord R [a b]) (get (->R 1 2) :b))" :portability :common} - {:suite "protocols / records" :label "record equality" :expected "true" :actual "(do (defrecord R [a b]) (= (->R 1 2) (->R 1 2)))" :portability :common} - {:suite "protocols / records" :label "record inequality" :expected "false" :actual "(do (defrecord R [a b]) (= (->R 1 2) (->R 3 4)))" :portability :common} - {:suite "protocols / records" :label "map-> factory" :expected "1" :actual "(do (defrecord R [a b]) (:a (map->R {:a 1 :b 2})))" :portability :common} - {:suite "protocols / records" :label "record? true" :expected "true" :actual "(do (defrecord R [a]) (record? (->R 1)))" :portability :common} - {:suite "protocols / records" :label "assoc on record" :expected "9" :actual "(do (defrecord R [a]) (:a (assoc (->R 1) :a 9)))" :portability :common} - {:suite "protocols / reify & satisfies" :label "reify dispatch" :expected "42" :actual "(do (defprotocol P (m [_])) (m (reify P (m [_] 42))))" :portability :common} - {:suite "protocols / reify & satisfies" :label "reify multi-method" :expected "[1 2]" :actual "(do (defprotocol P (a [_]) (b [_])) (let [r (reify P (a [_] 1) (b [_] 2))] [(a r) (b r)]))" :portability :common} - {:suite "protocols / reify & satisfies" :label "satisfies? true" :expected "true" :actual "(do (defprotocol P (m [_])) (defrecord R [] P (m [_] 1)) (satisfies? P (->R)))" :portability :common} - {:suite "protocols / reify & satisfies" :label "satisfies? false" :expected "false" :actual "(do (defprotocol P (m [_])) (defrecord R []) (satisfies? P (->R)))" :portability :common} - {:suite "protocols / reify & satisfies" :label "satisfies? reify" :expected "true" :actual "(do (defprotocol P (m [_])) (satisfies? P (reify P (m [_] 1))))" :portability :common} - {:suite "protocols / reify & satisfies" :label "satisfies? reify multi-protocol" :expected "[true true]" :actual "(do (defprotocol P (m [_])) (defprotocol Q (n [_])) (let [r (reify P (m [_] 1) Q (n [_] 2))] [(satisfies? P r) (satisfies? Q r)]))" :portability :common} - {:suite "protocols / reify & satisfies" :label "satisfies? reify other proto" :expected "false" :actual "(do (defprotocol P (m [_])) (defprotocol Q (n [_])) (satisfies? Q (reify P (m [_] 1))))" :portability :common} - {:suite "protocols / reify & satisfies" :label "instance? record" :expected "true" :actual "(do (defrecord R [a]) (instance? R (->R 1)))" :portability :common} - {:suite "protocols / reify & satisfies" :label "dot constructor" :expected "5" :actual "(do (deftype P [n]) (.-n (P. 5)))" :portability :jvm} - {:suite "protocols / reify & satisfies" :label "dot ctor + method" :expected "5" :actual "(do (defprotocol G (val-of [_])) (deftype P [n] G (val-of [_] n)) (val-of (P. 5)))" :portability :jvm} - {:suite "protocols / defprotocol options" :label "docstring + option + method" :expected ":hi" :actual "(do (defprotocol Pdoc \"docs\" :extend-via-metadata true (greet [x])) (extend-protocol Pdoc String (greet [s] :hi)) (greet \"x\"))" :portability :common} - {:suite "protocols / defprotocol options" :label "option only" :expected "3" :actual "(do (defprotocol Popt :extend-via-metadata true (plus2 [x])) (extend-protocol Popt Long (plus2 [n] (+ n 2))) (plus2 1))" :portability :common} - {:suite "reader / anonymous fn #()" :label "no args" :expected "3" :actual "(#(+ 1 2))" :portability :common} - {:suite "reader / anonymous fn #()" :label "one arg %" :expected "6" :actual "(#(* % 2) 3)" :portability :common} - {:suite "reader / anonymous fn #()" :label "positional %1 %2" :expected "[1 2]" :actual "(#(do [%1 %2]) 1 2)" :portability :common} - {:suite "reader / anonymous fn #()" :label "rest %&" :expected "[1 2 3]" :actual "(#(do %&) 1 2 3)" :portability :common} - {:suite "reader / anonymous fn #()" :label "fixed + rest" :expected "[2 3]" :actual "(#(do % %&) 1 2 3)" :portability :common} - {:suite "reader / anonymous fn #()" :label "%2 + rest" :expected "[3]" :actual "(#(do %2 %&) 1 2 3)" :portability :common} - {:suite "reader / anonymous fn #()" :label "%2 only (placeholder p1)" :expected "20" :actual "(#(* %2 2) 1 10)" :portability :common} - {:suite "reader / anonymous fn #()" :label "% and %1 same" :expected "10" :actual "(#(+ % %1) 5)" :portability :common} - {:suite "reader / var-quote #'" :label "var-quote = var" :expected "true" :actual "(= (var str) #'str)" :portability :common} - {:suite "reader / var-quote #'" :label "is a var" :expected "true" :actual "(var? #'str)" :portability :common} - {:suite "reader / var-quote #'" :label "deref var-quote" :expected "5" :actual "(do (def w 5) (deref #'w))" :portability :common} - {:suite "reader / metadata ^" :label "meta on map" :expected "true" :actual "(:foo (meta ^:foo {}))" :portability :common} - {:suite "reader / metadata ^" :label "meta on vector" :expected "true" :actual "(:foo (meta ^:foo [1 2]))" :portability :common} - {:suite "reader / metadata ^" :label "meta on set" :expected "true" :actual "(:foo (meta ^:foo #{}))" :portability :common} - {:suite "reader / metadata ^" :label "meta map form" :expected "1" :actual "(:a (meta ^{:a 1} {}))" :portability :common} - {:suite "reader / metadata ^" :label "meta on quoted sym" :expected "true" :actual "(:foo (meta (quote ^:foo bar)))" :portability :common} - {:suite "reader / metadata ^" :label "with-meta map" :expected "true" :actual "(:k (meta (with-meta {} {:k true})))" :portability :common} - {:suite "reader / metadata ^" :label "with-meta vector" :expected "true" :actual "(:k (meta (with-meta [] {:k true})))" :portability :common} - {:suite "reader / metadata ^" :label "non-metadatable num" :expected "nil" :actual "(meta 100)" :portability :common} - {:suite "reader / metadata ^" :label "non-metadatable str" :expected "nil" :actual "(meta \"\")" :portability :common} - {:suite "reader / metadata ^" :label "non-metadatable bool" :expected "nil" :actual "(meta true)" :portability :common} - {:suite "reader / syntax-quote" :label "plain literal" :expected "[1 2 3]" :actual "`[1 2 3]" :portability :common} - {:suite "reader / syntax-quote" :label "gensym distinct" :expected "true" :actual "(not= `meow# `meow#)" :portability :common} - {:suite "reader / syntax-quote" :label "gensym stable" :expected "true" :actual "(let [s `[meow# meow#]] (= (first s) (second s)))" :portability :common} - {:suite "reader / syntax-quote" :label "qualifies unresolved" :expected "(quote user/foo)" :actual "`foo" :portability :common} - {:suite "reader / syntax-quote" :label "qualifies core sym" :expected "(quote clojure.core/str)" :actual "`str" :portability :common} - {:suite "reader / syntax-quote" :label "unquote value" :expected "[1 2 3]" :actual "(let [a [1 2 3]] `~a)" :portability :common} - {:suite "reader / syntax-quote" :label "unquote in call" :expected "(quote (clojure.core/str [1 2 3]))" :actual "(let [a [1 2 3]] `(str ~a))" :portability :common} - {:suite "reader / syntax-quote" :label "splice empty" :expected "(quote (clojure.core/str))" :actual "(let [e []] `(str ~@e))" :portability :common} - {:suite "reader / syntax-quote" :label "splice values" :expected "(quote (clojure.core/str 1 2 3))" :actual "(let [a [1 2 3]] `(str ~@a))" :portability :common} - {:suite "reader / syntax-quote" :label "splice in vector" :expected "[1 2 3 0 1 2 3]" :actual "(let [b [0] a [1 2 3] e []] `[~@e ~@a ~@b ~@a ~@e])" :portability :common} - {:suite "reader / syntax-quote" :label "splice in set" :expected "#{0 1 3 2}" :actual "(let [b [0] a [1 2 3] e []] `#{~@e ~@a ~@b})" :portability :common} - {:suite "reader / syntax-quote" :label "unquote in set" :expected "#{9 5}" :actual "(let [x 5] `#{~x 9})" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard simple" :expected "2" :actual "(do #_1 2)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard in vector" :expected "[1 3]" :actual "[1 #_2 3]" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard stacks" :expected "3" :actual "(do #_ #_ 1 2 3)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##Inf" :expected "true" :actual "(= ##Inf (/ 1.0 0.0))" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##-Inf" :expected "true" :actual "(= ##-Inf (/ -1.0 0.0))" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##NaN not self-equal" :expected "false" :actual "(= ##NaN ##NaN)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##NaN is NaN?" :expected "true" :actual "(NaN? ##NaN)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "conditional :default reachable" :expected "2" :actual "#?(:no-such-dialect 1 :default 2)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "var-quote qualified" :expected "true" :actual "(= (var clojure.core/str) #'clojure.core/str)" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "gensym stable in template" :expected "true" :actual "(let [syms `[meow# meow#]] (= (first syms) (second syms)))" :portability :common} - {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "gensym fresh across templates" :expected "false" :actual "(= `meow# `meow#)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string once" :expected "true" :actual "(= \"meow\" `\"meow\")" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string nested" :expected "true" :actual "(= \"meow\" ``\"meow\")" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string triple" :expected "true" :actual "(= \"meow\" ```\"meow\")" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "number nested" :expected "true" :actual "(= 42 ``42)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "keyword nested" :expected "true" :actual "(= :k ``:k)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "nil nested" :expected "false" :actual "(nil? ``nil)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "char nested" :expected "true" :actual "(= \\a ``\\a)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "bool nested" :expected "false" :actual "(= true ``true)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "symbol still qualifies" :expected "true" :actual "(= (quote clojure.core/map) `map)" :portability :common} - {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "vector still templates" :expected "true" :actual "(= [1 2] `[1 ~(inc 1)])" :portability :common} - {:suite "reader / scalar literals" :label "integer" :expected "42" :actual "42" :portability :common} - {:suite "reader / scalar literals" :label "negative" :expected "-7" :actual "-7" :portability :common} - {:suite "reader / scalar literals" :label "float" :expected "1.5" :actual "1.5" :portability :common} - {:suite "reader / scalar literals" :label "string" :expected "\"hi\"" :actual "\"hi\"" :portability :common} - {:suite "reader / scalar literals" :label "boolean true" :expected "true" :actual "true" :portability :common} - {:suite "reader / scalar literals" :label "nil" :expected "nil" :actual "nil" :portability :common} - {:suite "reader / scalar literals" :label "keyword" :expected ":a" :actual ":a" :portability :common} - {:suite "reader / scalar literals" :label "namespaced keyword" :expected "true" :actual "(= :a/b :a/b)" :portability :common} - {:suite "reader / scalar literals" :label "char" :expected "\\a" :actual "\\a" :portability :common} - {:suite "reader / scalar literals" :label "char newline" :expected "true" :actual "(= \\newline (first \"\\n\"))" :portability :common} - {:suite "reader / scalar literals" :label "char open-brace" :expected "123" :actual "(int \\{)" :portability :common} - {:suite "reader / scalar literals" :label "char open-paren" :expected "40" :actual "(int \\()" :portability :common} - {:suite "reader / scalar literals" :label "char comma" :expected "44" :actual "(int \\,)" :portability :common} - {:suite "reader / scalar literals" :label "char percent" :expected "37" :actual "(int \\%)" :portability :common} - {:suite "reader / scalar literals" :label "char unicode" :expected "65" :actual "(int \\u0041)" :portability :common} - {:suite "reader / scalar literals" :label "hex literal" :expected "255" :actual "0xff" :portability :common} - {:suite "reader / scalar literals" :label "hex uppercase" :expected "31" :actual "0X1F" :portability :common} - {:suite "reader / scalar literals" :label "bigint suffix N" :expected "42N" :actual "42N" :portability :common} - {:suite "reader / scalar literals" :label "bigdec suffix M" :expected "1.5M" :actual "1.5M" :portability :common} - {:suite "reader / scalar literals" :label "ratio -> double" :expected "3/4" :actual "3/4" :portability :common} - {:suite "reader / scalar literals" :label "radix integer" :expected "255" :actual "16rFF" :portability :common} - {:suite "reader / scalar literals" :label "exponent" :expected "1500.0" :actual "1.5e3" :portability :common} - {:suite "reader / scalar literals" :label "symbolic Infinity" :expected "true" :actual "(infinite? ##Inf)" :portability :common} - {:suite "reader / scalar literals" :label "symbolic NaN" :expected "true" :actual "(NaN? ##NaN)" :portability :common} - {:suite "reader / scalar literals" :label "symbol via quote" :expected "'foo" :actual "'foo" :portability :common} - {:suite "reader / collection literals" :label "vector" :expected "[1 2 3]" :actual "[1 2 3]" :portability :common} - {:suite "reader / collection literals" :label "list quoted" :expected "[1 2 3]" :actual "'(1 2 3)" :portability :common} - {:suite "reader / collection literals" :label "map" :expected "{:a 1}" :actual "{:a 1}" :portability :common} - {:suite "reader / collection literals" :label "set" :expected "#{1 3 2}" :actual "#{1 2 3}" :portability :common} - {:suite "reader / collection literals" :label "nested" :expected "{:a [1 {:b 2}]}" :actual "{:a [1 {:b 2}]}" :portability :common} - {:suite "reader / collection literals" :label "empty vector" :expected "[]" :actual "[]" :portability :common} - {:suite "reader / collection literals" :label "empty map" :expected "{}" :actual "{}" :portability :common} - {:suite "reader / collection literals" :label "empty set" :expected "#{}" :actual "#{}" :portability :common} - {:suite "reader / dispatch & sugar" :label "anon fn #()" :expected "3" :actual "(#(+ %1 %2) 1 2)" :portability :common} - {:suite "reader / dispatch & sugar" :label "anon fn single %" :expected "2" :actual "(#(inc %) 1)" :portability :common} - {:suite "reader / dispatch & sugar" :label "anon fn %&" :expected "[2 3]" :actual "(#(vec %&) 2 3)" :portability :common} - {:suite "reader / dispatch & sugar" :label "discard #_" :expected "[1 3]" :actual "[1 #_2 3]" :portability :common} - {:suite "reader / dispatch & sugar" :label "regex literal" :expected "true" :actual "(= \"abc\" (re-find #\"abc\" \"xabcx\"))" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader conditional" :expected "1" :actual "#?(:clj 1 :cljs 2 :default 3)" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader cond :jolt" :expected "1" :actual "#?(:clj 1 :jolt 4 :default 3)" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader cond clause order" :expected "5" :actual "#?(:default 5 :jolt 6)" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader cond no match" :expected "[1]" :actual "[#?(:clj 1 :cljs 2)]" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader cond splice" :expected "[]" :actual "[#?@(:jolt [1 2 3] :cljs [4 5])]" :portability :common} - {:suite "reader / dispatch & sugar" :label "reader cond splice no match" :expected "[1 2 3]" :actual "[#?@(:clj [1 2 3] :cljs [4 5])]" :portability :common} - {:suite "reader / dispatch & sugar" :label "inst literal reads" :expected "true" :actual "(some? #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "reader / dispatch & sugar" :label "uuid literal" :expected "\"550e8400-e29b-41d4-a716-446655440000\"" :actual "(str #uuid \"550e8400-e29b-41d4-a716-446655440000\")" :portability :common} - {:suite "reader / dispatch & sugar" :label "tagged literal var" :expected "true" :actual "(var? #'+)" :portability :common} - {:suite "reader / dispatch & sugar" :label "deref sugar" :expected "5" :actual "(let [a (atom 5)] @a)" :portability :common} - {:suite "reader / dispatch & sugar" :label "meta sugar" :expected "{:t 1}" :actual "(meta ^{:t 1} [])" :portability :common} - {:suite "reader / comments inside maps" :label "comment in value slot" :expected "{:a 1}" :actual "{:a ; note\n 1}" :portability :common} - {:suite "reader / comments inside maps" :label "comment before key" :expected "{:a 1}" :actual "{; lead\n :a 1}" :portability :common} - {:suite "reader / comments inside maps" :label "comment between entries" :expected "{:a 1, :b 2}" :actual "{:a 1 ; mid\n :b 2}" :portability :common} - {:suite "reader / comments inside maps" :label "discard in value slot" :expected "{:a 1}" :actual "{:a #_9 1}" :portability :common} - {:suite "reader / comments inside maps" :label "comment with parens" :expected "{:a {:b 1}}" :actual "{:a ; dev (REPL, etc)\n {:b 1}}" :portability :common} - {:suite "reader / comments inside maps" :label "nested with comments" :expected "{:x {:y 2}}" :actual "{:x ; outer\n {:y ; inner\n 2}}" :portability :common} - {:suite "regex / literals & predicate" :label "regex? literal" :expected "true" :actual "(regex? #\"\\d+\")" :portability :common} - {:suite "regex / literals & predicate" :label "regex? non-regex" :expected "false" :actual "(regex? \"\\\\d+\")" :portability :common} - {:suite "regex / literals & predicate" :label "escaped digits" :expected "\"42\"" :actual "(re-find #\"\\d+\" \"x42y\")" :portability :common} - {:suite "regex / literals & predicate" :label "escaped ws/non-ws" :expected "\"x a\"" :actual "(re-find #\"\\S\\s\\S\" \"x a b y\")" :portability :common} - {:suite "regex / re-find" :label "match" :expected "\"123\"" :actual "(re-find #\"\\d+\" \"abc123def\")" :portability :common} - {:suite "regex / re-find" :label "no match nil" :expected "nil" :actual "(re-find #\"\\d+\" \"abc\")" :portability :common} - {:suite "regex / re-find" :label "with groups" :expected "[\"a1\" \"a\" \"1\"]" :actual "(re-find #\"([a-z])(\\d)\" \"--a1--\")" :portability :common} - {:suite "regex / re-find" :label "first match only" :expected "\"1\"" :actual "(re-find #\"\\d\" \"1 2 3\")" :portability :common} - {:suite "regex / re-matches" :label "full match" :expected "\"123\"" :actual "(re-matches #\"\\d+\" \"123\")" :portability :common} - {:suite "regex / re-matches" :label "partial = nil" :expected "nil" :actual "(re-matches #\"\\d+\" \"123abc\")" :portability :common} - {:suite "regex / re-matches" :label "groups" :expected "[\"12\" \"1\" \"2\"]" :actual "(re-matches #\"(\\d)(\\d)\" \"12\")" :portability :common} - {:suite "regex / re-matches" :label "no match nil" :expected "nil" :actual "(re-matches #\"x+\" \"yyy\")" :portability :common} - {:suite "regex / re-seq" :label "all matches" :expected "[\"1\" \"22\" \"333\"]" :actual "(re-seq #\"\\d+\" \"a1b22c333\")" :portability :common} - {:suite "regex / re-seq" :label "empty when none" :expected "nil" :actual "(seq (re-seq #\"z\" \"abc\"))" :portability :common} - {:suite "regex / re-seq" :label "words" :expected "[\"foo\" \"bar\"]" :actual "(re-seq #\"\\w+\" \"foo bar\")" :portability :common} - {:suite "regex / char-class dash" :label "dash after \\w is literal" :expected "\"a_b-c\"" :actual "(re-matches #\"[\\w-_]+\" \"a_b-c\")" :portability :common} - {:suite "regex / char-class dash" :label "dash + escaped dot in class" :expected "\"a.b_c-d\"" :actual "(re-matches #\"[\\w-_\\.]+\" \"a.b_c-d\")" :portability :common} - {:suite "regex / char-class dash" :label "trailing dash in class" :expected "[\"a-b\" \"c-d\"]" :actual "(vec (re-seq #\"[\\w-]+\" \"a-b c-d\"))" :portability :common} - {:suite "regex / nested quantifier" :label "(X+)* parses and matches" :expected "true" :actual "(boolean (re-matches #\"([^%]+)*(%(d))?\" \"abc\"))" :portability :common} - {:suite "regex / matcher" :label "re-find over a matcher" :expected "\"1\"" :actual "(re-find (re-matcher #\"\\d+\" \"a1b22\"))" :portability :common} - {:suite "regex / matcher" :label "stateful step + re-groups" :expected "[[\"12-34\" \"12\" \"34\"] [\"12-34\" \"12\" \"34\"] [\"56-78\" \"56\" \"78\"] nil]" :actual "(let [m (re-matcher #\"(\\d+)-(\\d+)\" \"12-34 56-78\")] [(re-find m) (re-groups m) (re-find m) (re-find m)])" :portability :common} - {:suite "regex / matcher" :label "re-groups before a match throws" :expected :throws :actual "(re-groups (re-matcher #\"\\d\" \"abc\"))" :portability :common} - {:suite "dynamic vars / portable defaults" :label "default reads" :expected "[true false true false]" :actual "[*read-eval* *print-dup* *flush-on-newline* *compile-files*]" :portability :common} - {:suite "dynamic vars / portable defaults" :label "binding *read-eval*" :expected "false" :actual "(binding [*read-eval* false] *read-eval*)" :portability :common} - {:suite "special forms / letfn" :label "mutual recursion" :expected "true" :actual "(letfn [(e? [n] (if (zero? n) true (o? (dec n)))) (o? [n] (if (zero? n) false (e? (dec n))))] (e? 10))" :portability :common} - {:suite "core vars / present and callable" :label "*out* *err* *warn-on-reflection* await restart-agent" :expected "[true true false true true]" :actual "[(boolean *out*) (boolean *err*) *warn-on-reflection* (ifn? await) (ifn? restart-agent)]" :portability :common} - {:suite "exceptions / runtime error classes" :label "arity error is ArityException" :expected "true" :actual "(instance? clojure.lang.ArityException (try ((fn [a b] a) 1) (catch Throwable e e)))" :portability :jvm} - {:suite "exceptions / runtime error classes" :label "ArityException is an IllegalArgumentException" :expected "true" :actual "(instance? IllegalArgumentException (try ((fn [a b] a) 1) (catch Throwable e e)))" :portability :common} - {:suite "exceptions / runtime error classes" :label "non-seqable is IllegalArgumentException" :expected "true" :actual "(instance? IllegalArgumentException (try (doall (mapcat identity 0)) (catch Throwable e e)))" :portability :common} - {:suite "dynamic vars / portable defaults" :label "*data-readers* map, *math-context* nil" :expected "[true true]" :actual "[(map? *data-readers*) (nil? *math-context*)]" :portability :common} - {:suite "regex / re-pattern & string ops" :label "re-pattern build" :expected "\"hi\"" :actual "(re-find (re-pattern \"\\\\w+\") \"hi!\")" :portability :common} - {:suite "regex / re-pattern & string ops" :label "re-pattern is regex?" :expected "true" :actual "(regex? (re-pattern \"a\"))" :portability :common} - {:suite "regex / re-pattern & string ops" :label "split on regex" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require '[clojure.string :as s]) (s/split \"a1b2c\" #\"\\d\"))" :portability :common} - {:suite "regex / re-pattern & string ops" :label "replace regex" :expected "\"X-X\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"a-b\" #\"[a-z]\" \"X\"))" :portability :common} - {:suite "regex / re-pattern & string ops" :label "replace $1" :expected "\"[a][b]\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"ab\" #\"([a-z])\" \"[$1]\"))" :portability :common} - {:suite "regex / \\p property classes" :label "p{L} ascii" :expected "\"hello\"" :actual "(re-matches #\"^\\p{L}+$\" \"hello\")" :portability :common} - {:suite "regex / \\p property classes" :label "p{L} utf-8" :expected "true" :actual "(boolean (re-matches #\"^\\p{L}+$\" \"héllo\"))" :portability :common} - {:suite "regex / \\p property classes" :label "p{L} rejects digits" :expected "false" :actual "(boolean (re-matches #\"^\\p{L}+$\" \"ab1\"))" :portability :common} - {:suite "regex / \\p property classes" :label "p{N}" :expected "[\"12\" \"345\"]" :actual "(re-seq #\"\\p{N}+\" \"a12b345\")" :portability :common} - {:suite "regex / \\p property classes" :label "P{N} negation" :expected "\"abc\"" :actual "(re-matches #\"^\\P{N}+$\" \"abc\")" :portability :common} - {:suite "regex / \\p property classes" :label "inside class" :expected "\"a-1_b\"" :actual "(re-matches #\"^[\\p{N}\\p{L}_-]+$\" \"a-1_b\")" :portability :common} - {:suite "regex / \\p property classes" :label "p{Lu}/p{Ll}" :expected "\"aB\"" :actual "(re-matches #\"^\\p{Ll}\\p{Lu}$\" \"aB\")" :portability :common} - {:suite "regex / \\p property classes" :label "p{Z} space" :expected "\" \"" :actual "(re-matches #\"(?u)^[\\s\\p{Z}]+$\" \" \")" :portability :common} - {:suite "regex / \\p property classes" :label "p{Ps}/p{Pe}" :expected "\"(x)\"" :actual "(re-matches #\"^\\p{Ps}x\\p{Pe}$\" \"(x)\")" :portability :common} - {:suite "regex / \\p property classes" :label "(?u) accepted" :expected "\"hi\"" :actual "(re-matches #\"(?u)^hi$\" \"hi\")" :portability :common} - {:suite "regex / \\p property classes" :label "unknown class throws" :expected :throws :actual "(re-pattern \"\\p{Greek}\")" :portability :common} - {:suite "regex / Pattern statics & String regex methods" :label "Pattern/compile is a regex" :expected "true" :actual "(regex? (Pattern/compile \"a.c\"))" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label "compiled .split" :expected "[\"a\" \"b\" \"c\"]" :actual "(.split (Pattern/compile \",\") \"a,b,c\")" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label "str/replace w/ Pattern" :expected "\"ab\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"a1b2\" (Pattern/compile \"[0-9]\") \"\"))" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label "Pattern/MULTILINE ^" :expected "true" :actual "(boolean (re-find (Pattern/compile \"^x\" Pattern/MULTILINE) \"y\\nx\"))" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label "Pattern/quote literal" :expected "true" :actual "(boolean (re-find (re-pattern (Pattern/quote \"a.c\")) \"za.cy\"))" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label "Pattern/quote not meta" :expected "false" :actual "(boolean (re-find (re-pattern (Pattern/quote \"a.c\")) \"zabcy\"))" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label ".matches whole string" :expected "true" :actual "(.matches \"abc\" \"a.c\")" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label ".matches partial -> false" :expected "false" :actual "(.matches \"abcd\" \"a.c\")" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label ".replaceAll regex" :expected "\"a-b-c\"" :actual "(.replaceAll \"a_b_c\" \"_\" \"-\")" :portability :jvm} - {:suite "regex / Pattern statics & String regex methods" :label ".replaceFirst regex" :expected "\"a-b_c\"" :actual "(.replaceFirst \"a_b_c\" \"_\" \"-\")" :portability :jvm} - {:suite "regex / bounded quantifiers" :label "exact {n}" :expected "\"aaa\"" :actual "(re-matches #\"a{3}\" \"aaa\")" :portability :common} - {:suite "regex / bounded quantifiers" :label "range {n,m} max" :expected "\"aaaa\"" :actual "(re-find #\"a{2,4}\" \"aaaaa\")" :portability :common} - {:suite "regex / bounded quantifiers" :label "zero lower {0,n}" :expected "\"aa\"" :actual "(re-find #\"a{0,3}\" \"aa\")" :portability :common} - {:suite "regex / bounded quantifiers" :label "{n,} unbounded" :expected "\"aaaa\"" :actual "(re-find #\"a{2,}\" \"aaaa\")" :portability :common} - {:suite "regex / bounded quantifiers" :label "nested bounds compile" :expected "true" :actual "(boolean (re-matches #\"[a-z](?:[a-z]{0,61}[a-z])?(?:-[a-z]{0,61}[a-z])*\" \"abc-def\"))" :portability :common} - {:suite "regex / backreferences" :label "repeated char" :expected "true" :actual "(boolean (re-find #\"(.)\\1\" \"abba\"))" :portability :common} - {:suite "regex / backreferences" :label "no repeat = nil" :expected "nil" :actual "(re-find #\"(.)\\1\" \"abc\")" :portability :common} - {:suite "regex / backreferences" :label "thematic-break run" :expected "true" :actual "(boolean (re-matches #\"([-*_])\\1\\1\" \"---\"))" :portability :common} - {:suite "regex / backreferences" :label "mismatched run" :expected "nil" :actual "(re-matches #\"([-*_])\\1\\1\" \"-*_\")" :portability :common} - {:suite "regex / backreferences" :label "repeated word" :expected "[\"the the\" \"the\"]" :actual "(re-find #\"(\\w+) \\1\" \"say the the word\")" :portability :common} - {:suite "regex / backreferences" :label "group still captures" :expected "[\"x=x\" \"x\"]" :actual "(re-matches #\"(\\w+)=\\1\" \"x=x\")" :portability :common} - {:suite "regex / backreferences" :label "html tag pair" :expected "true" :actual "(boolean (re-matches #\"<(\\w+)>.*\" \"hi\"))" :portability :common} - {:suite "seq / access" :label "first of vector" :expected "1" :actual "(first [1 2 3])" :portability :common} - {:suite "seq / access" :label "first of list" :expected "1" :actual "(first (list 1 2 3))" :portability :common} - {:suite "seq / access" :label "first of empty is nil" :expected "nil" :actual "(first [])" :portability :common} - {:suite "seq / access" :label "first of nil is nil" :expected "nil" :actual "(first nil)" :portability :common} - {:suite "seq / access" :label "second" :expected "2" :actual "(second [1 2 3])" :portability :common} - {:suite "seq / access" :label "last" :expected "3" :actual "(last [1 2 3])" :portability :common} - {:suite "seq / access" :label "rest of vector" :expected "[2 3]" :actual "(rest [1 2 3])" :portability :common} - {:suite "seq / access" :label "rest of single" :expected "[]" :actual "(rest [1])" :portability :common} - {:suite "seq / access" :label "rest of empty" :expected "[]" :actual "(rest [])" :portability :common} - {:suite "seq / access" :label "next of single is nil" :expected "nil" :actual "(next [1])" :portability :common} - {:suite "seq / access" :label "next of empty is nil" :expected "nil" :actual "(next [])" :portability :common} - {:suite "seq / access" :label "nth" :expected "30" :actual "(nth [10 20 30] 2)" :portability :common} - {:suite "seq / access" :label "nth with default" :expected "99" :actual "(nth [10] 5 99)" :portability :common} - {:suite "seq / access" :label "nth out of range" :expected :throws :actual "(nth [10] 5)" :portability :common} - {:suite "seq / access" :label "ffirst" :expected "1" :actual "(ffirst [[1 2] [3 4]])" :portability :common} - {:suite "seq / access" :label "fnext" :expected "2" :actual "(fnext [1 2 3])" :portability :common} - {:suite "seq / access" :label "nnext" :expected "[3 4]" :actual "(nnext [1 2 3 4])" :portability :common} - {:suite "seq / construction" :label "cons onto list" :expected "[0 1 2]" :actual "(cons 0 (list 1 2))" :portability :common} - {:suite "seq / construction" :label "cons onto vector" :expected "[0 1 2]" :actual "(cons 0 [1 2])" :portability :common} - {:suite "seq / construction" :label "cons onto nil" :expected "[0]" :actual "(cons 0 nil)" :portability :common} - {:suite "seq / construction" :label "conj vector appends" :expected "[1 2 3]" :actual "(conj [1 2] 3)" :portability :common} - {:suite "seq / construction" :label "conj list prepends" :expected "[0 1 2]" :actual "(conj (list 1 2) 0)" :portability :common} - {:suite "seq / construction" :label "conj multiple on vec" :expected "[1 2 3 4]" :actual "(conj [1 2] 3 4)" :portability :common} - {:suite "seq / construction" :label "conj multiple on list" :expected "[4 3 1 2]" :actual "(conj (list 1 2) 3 4)" :portability :common} - {:suite "seq / construction" :label "seq of empty is nil" :expected "nil" :actual "(seq [])" :portability :common} - {:suite "seq / construction" :label "seq of nil is nil" :expected "nil" :actual "(seq nil)" :portability :common} - {:suite "seq / construction" :label "seq of string" :expected "[\\a \\b]" :actual "(seq \"ab\")" :portability :common} - {:suite "seq / construction" :label "empty?" :expected "true" :actual "(empty? [])" :portability :common} - {:suite "seq / construction" :label "not empty?" :expected "false" :actual "(empty? [1])" :portability :common} - {:suite "seq / construction" :label "count" :expected "3" :actual "(count [1 2 3])" :portability :common} - {:suite "seq / construction" :label "count of nil" :expected "0" :actual "(count nil)" :portability :common} - {:suite "seq / construction" :label "count of string" :expected "3" :actual "(count \"abc\")" :portability :common} - {:suite "seq / map filter reduce" :label "map" :expected "[2 3 4]" :actual "(map inc [1 2 3])" :portability :common} - {:suite "seq / map filter reduce" :label "map two colls" :expected "[5 7 9]" :actual "(map + [1 2 3] [4 5 6])" :portability :common} - {:suite "seq / map filter reduce" :label "map stops at shortest" :expected "[5 7]" :actual "(map + [1 2] [4 5 6])" :portability :common} - {:suite "seq / map filter reduce" :label "map keeps nil elements" :expected "[[1 :a] [nil :b] [3 nil]]" :actual "(map vector [1 nil 3] [:a :b nil])" :portability :common} - {:suite "seq / map filter reduce" :label "map 3 colls" :expected "[12 15 18]" :actual "(map + [1 2 3] [4 5 6] [7 8 9])" :portability :common} - {:suite "seq / map filter reduce" :label "map 3 colls shortest" :expected "[12 15]" :actual "(map + [1 2] [4 5 6] [7 8 9])" :portability :common} - {:suite "seq / map filter reduce" :label "map 4 colls" :expected "[16 20]" :actual "(map + [1 2] [3 4] [5 6] [7 8])" :portability :common} - {:suite "seq / map filter reduce" :label "map 3 colls nils" :expected "[[1 :a 10] [nil :b 20] [3 nil 30]]" :actual "(map vector [1 nil 3] [:a :b nil] [10 20 30])" :portability :common} - {:suite "seq / map filter reduce" :label "map empty coll" :expected "[]" :actual "(map + [] [1 2 3] [4 5 6])" :portability :common} - {:suite "seq / map filter reduce" :label "map lazy+concrete" :expected "[11 22 33]" :actual "(map + (map identity [1 2 3]) [10 20 30])" :portability :common} - {:suite "seq / map filter reduce" :label "map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(map-indexed vector [:a :b])" :portability :common} - {:suite "seq / map filter reduce" :label "mapv" :expected "[2 3 4]" :actual "(mapv inc [1 2 3])" :portability :common} - {:suite "seq / map filter reduce" :label "filter" :expected "[2 4]" :actual "(filter even? [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "filterv" :expected "[2 4]" :actual "(filterv even? [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "remove" :expected "[1 3]" :actual "(remove even? [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce" :expected "10" :actual "(reduce + [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce with init" :expected "20" :actual "(reduce + 10 [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce empty with init" :expected "0" :actual "(reduce + 0 [])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce single no init" :expected "5" :actual "(reduce + [5])" :portability :common} - {:suite "seq / map filter reduce" :label "reduced short-circuits" :expected "3" :actual "(reduce (fn [a x] (if (> a 2) (reduced a) (+ a x))) 0 [1 2 3 4 5])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce-kv" :expected "6" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 {:a 1 :b 2 :c 3})" :portability :common} - {:suite "seq / map filter reduce" :label "reduce-kv on vector" :expected "[[0 :a] [1 :b]]" :actual "(reduce-kv (fn [a i v] (conj a [i v])) [] [:a :b])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce-kv honors reduced" :expected "[:a]" :actual "(reduce-kv (fn [a i v] (if (= i 1) (reduced a) (conj a v))) [] [:a :b :c])" :portability :common} - {:suite "seq / map filter reduce" :label "reduce-kv on nil" :expected "0" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 nil)" :portability :common} - {:suite "seq / map filter reduce" :label "reductions" :expected "[1 3 6]" :actual "(reductions + [1 2 3])" :portability :common} - {:suite "seq / map filter reduce" :label "mapcat" :expected "[1 1 2 2]" :actual "(mapcat (fn [x] [x x]) [1 2])" :portability :common} - {:suite "seq / map filter reduce" :label "mapcat two colls" :expected "[1 3 2 4]" :actual "(mapcat vector [1 2] [3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "mapcat three colls" :expected "[1 2 3]" :actual "(mapcat vector [1] [2] [3])" :portability :common} - {:suite "seq / map filter reduce" :label "mapcat empty coll" :expected "[]" :actual "(mapcat vector [] [1 2] [3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "mapcat seqs" :expected "[1 2 3 4]" :actual "(mapcat identity [[1 2] [3 4]])" :portability :common} - {:suite "seq / lazy over infinite" :label "mapcat is lazy over an infinite source" :expected "[1 2 1 2]" :actual "(take 4 (mapcat identity (repeat [1 2])))" :portability :common} - {:suite "seq / lazy over infinite" :label "mapcat single coll lazy" :expected "[0 1 2]" :actual "(take 3 (mapcat vector (range)))" :portability :common} - {:suite "seq / lazy over infinite" :label "apply concat lazy over infinite" :expected "[1 1 1]" :actual "(take 3 (apply concat (repeat [1])))" :portability :common} - {:suite "seq / lazy over infinite" :label "apply concat fixed + infinite tail" :expected "[9 0 0 0 0]" :actual "(take 5 (apply concat [9] (repeat [0])))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence is lazy over an infinite source" :expected "[1 2 3]" :actual "(take 3 (sequence (map inc) (range)))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence first of infinite" :expected "2" :actual "(first (sequence (map inc) (range 1 100000000000)))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence stateful xform lazy" :expected "[[0 1] [2 3]]" :actual "(take 2 (sequence (partition-all 2) (range)))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence value + completion flush" :expected "[[0 1] [2 3] [4]]" :actual "(sequence (partition-all 2) (range 5))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence empty stays a seq" :expected "true" :actual "(seq? (sequence (filter even?) [1 3 5]))" :portability :common} - {:suite "seq / lazy over infinite" :label "sequence empty prints as empty" :expected "()" :actual "(sequence (filter even?) [1 3 5])" :portability :common} - {:suite "seq / lazy over infinite" :label "eduction is lazy over infinite" :expected "1" :actual "(first (eduction (map inc) (range)))" :portability :common} - {:suite "seq / lazy over infinite" :label "eduction reduces" :expected "9" :actual "(reduce + (eduction (filter odd?) [1 2 3 4 5]))" :portability :common} - {:suite "seq / lazy over infinite" :label "eduction into" :expected "[2 3 4]" :actual "(into [] (eduction (map inc) [1 2 3]))" :portability :common} - {:suite "seq / lazy over infinite" :label "eduction multiple xforms compose left-to-right" :expected "[2 4]" :actual "(into [] (eduction (filter odd?) (map inc) [1 2 3 4]))" :portability :common} - {:suite "seq / map filter reduce" :label "keep" :expected "[1 3]" :actual "(keep (fn [x] (if (odd? x) x nil)) [1 2 3 4])" :portability :common} - {:suite "seq / map filter reduce" :label "some truthy" :expected "true" :actual "(some even? [1 2 3])" :portability :common} - {:suite "seq / map filter reduce" :label "some nil" :expected "nil" :actual "(some even? [1 3 5])" :portability :common} - {:suite "seq / map filter reduce" :label "every? true" :expected "true" :actual "(every? pos? [1 2 3])" :portability :common} - {:suite "seq / map filter reduce" :label "every? false" :expected "false" :actual "(every? pos? [1 -2 3])" :portability :common} - {:suite "seq / take drop slice" :label "take" :expected "[1 2 3]" :actual "(take 3 [1 2 3 4 5])" :portability :common} - {:suite "seq / take drop slice" :label "take more than size" :expected "[1 2]" :actual "(take 5 [1 2])" :portability :common} - {:suite "seq / take drop slice" :label "drop" :expected "[4 5]" :actual "(drop 3 [1 2 3 4 5])" :portability :common} - {:suite "seq / take drop slice" :label "take-while" :expected "[1 2]" :actual "(take-while (fn [x] (< x 3)) [1 2 3 1])" :portability :common} - {:suite "seq / take drop slice" :label "drop-while" :expected "[3 1]" :actual "(drop-while (fn [x] (< x 3)) [1 2 3 1])" :portability :common} - {:suite "seq / take drop slice" :label "take-last" :expected "[4 5]" :actual "(take-last 2 [1 2 3 4 5])" :portability :common} - {:suite "seq / take drop slice" :label "drop-last" :expected "[1 2 3]" :actual "(drop-last [1 2 3 4])" :portability :common} - {:suite "seq / take drop slice" :label "take-nth" :expected "[1 3 5]" :actual "(take-nth 2 [1 2 3 4 5])" :portability :common} - {:suite "seq / take drop slice" :label "partition" :expected "[[1 2] [3 4]]" :actual "(partition 2 [1 2 3 4 5])" :portability :common} - {:suite "seq / take drop slice" :label "partition-all" :expected "[[1 2] [3]]" :actual "(partition-all 2 [1 2 3])" :portability :common} - {:suite "seq / take drop slice" :label "partition elems are seqs" :expected "true" :actual "(every? seq? (partition 2 [1 2 3 4]))" :portability :common} - {:suite "seq / take drop slice" :label "partition-all elems are seqs not vectors" :expected "true" :actual "(every? seq? (partition-all 2 (range 5)))" :portability :common} - {:suite "seq / take drop slice" :label "partition-all elem is not a vector" :expected "false" :actual "(vector? (first (partition-all 2 [1 2 3])))" :portability :common} - {:suite "seq / take drop slice" :label "partition-all [n step coll] elems are seqs" :expected "true" :actual "(every? seq? (partition-all 2 2 [1 2 3 4]))" :portability :common} - {:suite "seq / take drop slice" :label "partition-by elems are seqs" :expected "true" :actual "(every? seq? (partition-by odd? [1 3 2 4]))" :portability :common} - {:suite "seq / take drop slice" :label "split-at" :expected "[[1 2] [3 4]]" :actual "(split-at 2 [1 2 3 4])" :portability :common} - {:suite "seq / transform" :label "reverse" :expected "[3 2 1]" :actual "(reverse [1 2 3])" :portability :common} - {:suite "seq / transform" :label "sort" :expected "[1 2 3]" :actual "(sort [3 1 2])" :portability :common} - {:suite "seq / transform" :label "sort with comparator" :expected "[3 2 1]" :actual "(sort > [1 3 2])" :portability :common} - {:suite "seq / transform" :label "sort-by" :expected "[[1] [2 2]]" :actual "(sort-by count [[2 2] [1]])" :portability :common} - {:suite "seq / transform" :label "distinct" :expected "[1 2 3]" :actual "(distinct [1 1 2 3 3])" :portability :common} - {:suite "seq / transform" :label "dedupe" :expected "[1 2 1]" :actual "(dedupe [1 1 2 1])" :portability :common} - {:suite "seq / transform" :label "interpose" :expected "[1 0 2 0 3]" :actual "(interpose 0 [1 2 3])" :portability :common} - {:suite "seq / transform" :label "interleave" :expected "[1 :a 2 :b]" :actual "(interleave [1 2] [:a :b])" :portability :common} - {:suite "seq / transform" :label "flatten" :expected "[1 2 3 4]" :actual "(flatten [1 [2 [3 [4]]]])" :portability :common} - {:suite "seq / transform" :label "concat" :expected "[1 2 3 4]" :actual "(concat [1 2] [3 4])" :portability :common} - {:suite "seq / transform" :label "into vector" :expected "[1 2 3 4]" :actual "(into [1 2] [3 4])" :portability :common} - {:suite "seq / transform" :label "into list" :expected "[3 2 1]" :actual "(into (list) [1 2 3])" :portability :common} - {:suite "seq / transform" :label "frequencies" :expected "{1 2, 2 1}" :actual "(frequencies [1 1 2])" :portability :common} - {:suite "seq / transform" :label "group-by" :expected "{false [1 3], true [2 4]}" :actual "(group-by even? [1 2 3 4])" :portability :common} - {:suite "seq / transform" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])" :portability :common} - {:suite "seq / transform" :label "mapcat seqs" :expected "[1 2 3 4]" :actual "(mapcat identity [[1 2] [3 4]])" :portability :common} - {:suite "seq / generators" :label "range n" :expected "[0 1 2 3]" :actual "(range 4)" :portability :common} - {:suite "seq / generators" :label "range from to" :expected "[2 3 4]" :actual "(range 2 5)" :portability :common} - {:suite "seq / generators" :label "range with step" :expected "[0 2 4]" :actual "(range 0 6 2)" :portability :common} - {:suite "seq / generators" :label "take repeat" :expected "[:x :x :x]" :actual "(take 3 (repeat :x))" :portability :common} - {:suite "seq / generators" :label "repeat n" :expected "[5 5]" :actual "(repeat 2 5)" :portability :common} - {:suite "seq / generators" :label "take iterate" :expected "[1 2 4 8]" :actual "(take 4 (iterate (fn [x] (* x 2)) 1))" :portability :common} - {:suite "seq / generators" :label "take cycle" :expected "[1 2 1 2 1]" :actual "(take 5 (cycle [1 2]))" :portability :common} - {:suite "seq / generators" :label "take repeatedly" :expected "3" :actual "(count (take 3 (repeatedly (fn [] 1))))" :portability :common} - {:suite "seq / generators" :label "take-last of range" :expected "[8 9]" :actual "(take-last 2 (range 10))" :portability :common} - {:suite "seq / IFn values as functions" :label "map keyword" :expected "[1 2 3]" :actual "(map :a [{:a 1} {:a 2} {:a 3}])" :portability :common} - {:suite "seq / IFn values as functions" :label "filter keyword" :expected "[{:ok true}]" :actual "(filter :ok [{:ok true} {:ok false}])" :portability :common} - {:suite "seq / IFn values as functions" :label "remove keyword" :expected "[{:ok false}]" :actual "(remove :ok [{:ok true} {:ok false}])" :portability :common} - {:suite "seq / IFn values as functions" :label "sort-by keyword" :expected "[{:a 1} {:a 2} {:a 3}]" :actual "(sort-by :a [{:a 3} {:a 1} {:a 2}])" :portability :common} - {:suite "seq / IFn values as functions" :label "sort-by key + cmp" :expected "[{:a 3} {:a 2} {:a 1}]" :actual "(sort-by :a > [{:a 3} {:a 1} {:a 2}])" :portability :common} - {:suite "seq / IFn values as functions" :label "filter set" :expected "[2 4]" :actual "(filter #{2 4} [1 2 3 4 5])" :portability :common} - {:suite "seq / IFn values as functions" :label "remove set" :expected "[1 3 5]" :actual "(remove #{2 4} [1 2 3 4 5])" :portability :common} - {:suite "seq / IFn values as functions" :label "group-by keyword" :expected "{1 [{:n 1}], 2 [{:n 2}]}" :actual "(group-by :n [{:n 1} {:n 2}])" :portability :common} - {:suite "seq / IFn values as functions" :label "map a map" :expected "[1 nil 2]" :actual "(map {:a 1 :b 2} [:a :z :b])" :portability :common} - {:suite "seq / IFn values as functions" :label "take-nth transducer" :expected "[0 2 4 6 8]" :actual "(into [] (take-nth 2) (range 10))" :portability :common} - {:suite "seq / IFn values as functions" :label "interpose transducer" :expected "[1 :x 2]" :actual "(into [] (interpose :x) [1 2])" :portability :common} - {:suite "seq / conj edge cases" :label "conj no args" :expected "[]" :actual "(conj)" :portability :common} - {:suite "seq / conj edge cases" :label "conj nil one" :expected "[3]" :actual "(conj nil 3)" :portability :common} - {:suite "seq / conj edge cases" :label "conj nil many" :expected "[2 1]" :actual "(conj nil 1 2)" :portability :common} - {:suite "seq / conj edge cases" :label "conj vector" :expected "[1 2 3]" :actual "(conj [1 2] 3)" :portability :common} - {:suite "seq / conj edge cases" :label "conj list prepend" :expected "[0 1 2]" :actual "(conj '(1 2) 0)" :portability :common} - {:suite "seq / conj edge cases" :label "conj map + map" :expected "{:a 0, :b 1}" :actual "(conj {:a 0} {:b 1})" :portability :common} - {:suite "seq / conj edge cases" :label "conj map + pair" :expected "{:a 0, :b 1}" :actual "(conj {:a 0} [:b 1])" :portability :common} - {:suite "seq / conj edge cases" :label "conj map merge wins" :expected "{:a 2}" :actual "(conj {:a 0} {:a 1} {:a 2})" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "cons non-seqable num" :expected :throws :actual "(cons 1 42)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "cons non-seqable kw" :expected :throws :actual "(cons 1 :k)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "cons onto nil ok" :expected "[1]" :actual "(cons 1 nil)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "cons onto seq ok" :expected "[0 1 2]" :actual "(cons 0 [1 2])" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "num non-number" :expected :throws :actual "(num \"x\")" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "num ok" :expected "5" :actual "(num 5)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "realized? on number" :expected :throws :actual "(realized? 1)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "realized? on nil" :expected :throws :actual "(realized? nil)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "symbol from nil" :expected :throws :actual "(symbol nil)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "symbol bad 2-arg" :expected :throws :actual "(symbol :a \"b\")" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "symbol from keyword" :expected "\"x\"" :actual "(name (symbol :x))" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "keyword bad 2-arg" :expected :throws :actual "(keyword \"abc\" nil)" :portability :common} - {:suite "seq / strictness (throws like Clojure)" :label "keyword from symbol" :expected "\"x\"" :actual "(name (keyword 'x))" :portability :common} - {:suite "seq / accessor strictness" :label "peek vector" :expected "3" :actual "(peek [1 2 3])" :portability :common} - {:suite "seq / accessor strictness" :label "peek list" :expected "1" :actual "(peek '(1 2 3))" :portability :common} - {:suite "seq / accessor strictness" :label "peek empty vec" :expected "nil" :actual "(peek [])" :portability :common} - {:suite "seq / accessor strictness" :label "peek on set" :expected :throws :actual "(peek #{1 2})" :portability :common} - {:suite "seq / accessor strictness" :label "peek on number" :expected :throws :actual "(peek 42)" :portability :common} - {:suite "seq / accessor strictness" :label "pop empty vec" :expected :throws :actual "(pop [])" :portability :common} - {:suite "seq / accessor strictness" :label "pop on number" :expected :throws :actual "(pop 0)" :portability :common} - {:suite "seq / accessor strictness" :label "pop vector" :expected "[1 2]" :actual "(pop [1 2 3])" :portability :common} - {:suite "seq / accessor strictness" :label "vec on number" :expected :throws :actual "(vec 42)" :portability :common} - {:suite "seq / accessor strictness" :label "vec on keyword" :expected :throws :actual "(vec :a)" :portability :common} - {:suite "seq / accessor strictness" :label "vec ok" :expected "[1 2]" :actual "(vec '(1 2))" :portability :common} - {:suite "seq / accessor strictness" :label "key on nil" :expected :throws :actual "(key nil)" :portability :common} - {:suite "seq / accessor strictness" :label "key on map" :expected :throws :actual "(key {})" :portability :common} - {:suite "seq / accessor strictness" :label "val on number" :expected :throws :actual "(val 0)" :portability :common} - {:suite "seq / accessor strictness" :label "key of entry" :expected ":a" :actual "(key (first {:a 1}))" :portability :common} - {:suite "seq / accessor strictness" :label "val of entry" :expected "1" :actual "(val (first {:a 1}))" :portability :common} - {:suite "seq / more strictness" :label "first on number" :expected :throws :actual "(first 42)" :portability :common} - {:suite "seq / more strictness" :label "first on keyword" :expected :throws :actual "(first :a)" :portability :common} - {:suite "seq / more strictness" :label "first ok vec" :expected "1" :actual "(first [1 2])" :portability :common} - {:suite "seq / more strictness" :label "first ok nil" :expected "nil" :actual "(first nil)" :portability :common} - {:suite "seq / more strictness" :label "rseq vector" :expected "[3 2 1]" :actual "(rseq [1 2 3])" :portability :common} - {:suite "seq / more strictness" :label "rseq on string" :expected :throws :actual "(rseq \"ab\")" :portability :common} - {:suite "seq / more strictness" :label "rseq on map" :expected :throws :actual "(rseq {:a 1})" :portability :common} - {:suite "seq / more strictness" :label "rseq on number" :expected :throws :actual "(rseq 0)" :portability :common} - {:suite "seq / more strictness" :label "assoc odd args" :expected :throws :actual "(assoc {:a 1} :b)" :portability :common} - {:suite "seq / more strictness" :label "assoc on number" :expected :throws :actual "(assoc 5 :a 1)" :portability :common} - {:suite "seq / more strictness" :label "assoc on set" :expected :throws :actual "(assoc #{} :a 1)" :portability :common} - {:suite "seq / strictness round 3" :label "seq on number" :expected :throws :actual "(seq 1)" :portability :common} - {:suite "seq / strictness round 3" :label "seq on fn" :expected :throws :actual "(seq (fn [] 1))" :portability :common} - {:suite "seq / strictness round 3" :label "seq vector ok" :expected "[1 2]" :actual "(seq [1 2])" :portability :common} - {:suite "seq / strictness round 3" :label "NaN? on nil" :expected :throws :actual "(NaN? nil)" :portability :common} - {:suite "seq / strictness round 3" :label "NaN? on number ok" :expected "false" :actual "(NaN? 1.0)" :portability :common} - {:suite "seq / strictness round 3" :label "shuffle on number" :expected :throws :actual "(shuffle 1)" :portability :common} - {:suite "seq / strictness round 3" :label "shuffle on string" :expected :throws :actual "(shuffle \"abc\")" :portability :common} - {:suite "seq / strictness round 3" :label "shuffle vec ok" :expected "3" :actual "(count (shuffle [1 2 3]))" :portability :common} - {:suite "seq / strictness round 3" :label "nthrest nil count" :expected :throws :actual "(nthrest [0 1 2] nil)" :portability :common} - {:suite "seq / strictness round 3" :label "nthrest negative" :expected "[0 1 2]" :actual "(nthrest [0 1 2] -1)" :portability :common} - {:suite "seq / strictness round 3" :label "nthrest nil coll" :expected "nil" :actual "(nthrest nil 0)" :portability :common} - {:suite "seq / strictness round 3" :label "nthnext nil count" :expected :throws :actual "(nthnext [0 1 2] nil)" :portability :common} - {:suite "seq / strictness round 3" :label "update vec oob" :expected :throws :actual "(update [] 1 identity)" :portability :common} - {:suite "seq / strictness round 3" :label "update vec kw key" :expected :throws :actual "(update [1 2 3] :k identity)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthrest exhausted -> ()" :expected "[]" :actual "(nthrest nil 100)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthrest vec exhausted" :expected "[]" :actual "(nthrest [1 2 3] 100)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthrest n<=0 keeps coll" :expected "[1 2 3]" :actual "(nthrest [1 2 3] 0)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthrest drops n" :expected "[3 4 5]" :actual "(nthrest [1 2 3 4 5] 2)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthnext exhausted -> nil" :expected "nil" :actual "(nthnext [1 2] 5)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthnext surprising nil" :expected "nil" :actual "(nthnext nil nil)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "nthnext drops n" :expected "[3 4]" :actual "(nthnext [1 2 3 4] 2)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "distinct? distinct" :expected "true" :actual "(distinct? 1 2 3)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "distinct? dup" :expected "false" :actual "(distinct? 1 2 1)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "distinct? equal colls" :expected "false" :actual "(distinct? [1 2] [1 2])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "distinct? single" :expected "true" :actual "(distinct? 5)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replace maps elements" :expected "[:a 2 :c 2]" :actual "(replace {1 :a 3 :c} [1 2 3 2])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replace preserves nil val" :expected "[1 nil 3]" :actual "(replace {2 nil} [1 2 3])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replace on a vector stays a vector" :expected "true" :actual "(vector? (replace {1 :a} [1 2 1]))" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replace on a seq returns a seq" :expected "true" :actual "(seq? (replace {1 :a} (list 1 2 1)))" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replace on a seq is lazy" :expected "[0 :a 2]" :actual "(take 3 (replace {1 :a} (range)))" :portability :common} - {:suite "seq / overlay-migrated fns" :label "take-last" :expected "[3 4]" :actual "(take-last 2 [1 2 3 4])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "take-last empty -> nil" :expected "nil" :actual "(take-last 2 [])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "take-last n>len" :expected "[1 2]" :actual "(take-last 9 [1 2])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "drop-last default 1" :expected "[1 2]" :actual "(drop-last [1 2 3])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "drop-last n" :expected "[1 2]" :actual "(drop-last 2 [1 2 3 4])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "split-with" :expected "[[2 4] [5 6]]" :actual "(split-with even? [2 4 5 6])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "replicate" :expected "[:x :x :x]" :actual "(replicate 3 :x)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "bounded-count" :expected "5" :actual "(bounded-count 3 [1 2 3 4 5])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "bounded-count uncounted" :expected "3" :actual "(bounded-count 3 (filter odd? (range 100)))" :portability :common} - {:suite "seq / overlay-migrated fns" :label "run! side effects" :expected "6" :actual "(let [a (atom 0)] (run! (fn [x] (swap! a + x)) [1 2 3]) @a)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "completing wraps rf" :expected "3" :actual "((completing +) 1 2)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "comparator <" :expected "[1 2 3]" :actual "(sort (comparator <) [3 1 2])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "comparator >" :expected "[3 2 1]" :actual "(sort (comparator >) [3 1 2])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "reductions" :expected "[1 3 6 10]" :actual "(reductions + [1 2 3 4])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "reductions with init" :expected "[10 11 13 16]" :actual "(reductions + 10 [1 2 3])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "reductions empty calls f" :expected "[0]" :actual "(reductions + [])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "reductions empty + init" :expected "[5]" :actual "(reductions + 5 [])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "tree-seq pre-order" :expected "[[1 [2] 3] 1 [2] 2 3]" :actual "(tree-seq sequential? seq [1 [2] 3])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "some found" :expected "true" :actual "(some even? [1 3 4])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "some none -> nil" :expected "nil" :actual "(some even? [1 3 5])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "some keyword pred" :expected "7" :actual "(some :a [{:b 1} {:a 7}])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "some returns value" :expected "4" :actual "(some (fn [x] (when (even? x) x)) [1 3 4 5])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "flatten nested" :expected "[1 2 3 4 5]" :actual "(flatten [1 [2 [3 4]] 5])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "flatten lists too" :expected "[1 2 3]" :actual "(flatten [1 (list 2 3)])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "flatten scalar -> empty" :expected "[]" :actual "(flatten 5)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "interleave" :expected "[1 :a 2 :b]" :actual "(interleave [1 2 3] [:a :b])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "interleave empty" :expected "[]" :actual "(interleave)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "rationalize identity" :expected "5" :actual "(rationalize 5)" :portability :common} - {:suite "seq / overlay-migrated fns" :label "dedupe consecutive" :expected "[1 2 3 1]" :actual "(dedupe [1 1 2 2 3 1 1])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "dedupe empty" :expected "[]" :actual "(dedupe [])" :portability :common} - {:suite "seq / overlay-migrated fns" :label "dedupe no dups" :expected "[1 2 3]" :actual "(dedupe [1 2 3])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv" :expected "[[1 2] [3 4]]" :actual "(partitionv 2 [1 2 3 4 5])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv elems are vectors" :expected "true" :actual "(every? vector? (partitionv 2 [1 2 3 4]))" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv step" :expected "[[1 2] [3 4]]" :actual "(partitionv 2 2 [1 2 3 4 5])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv pad" :expected "[[1 2] [3 :p]]" :actual "(partitionv 2 2 [:p] [1 2 3])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv-all" :expected "[[1 2] [3]]" :actual "(partitionv-all 2 [1 2 3])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv-all vectors" :expected "true" :actual "(every? vector? (partitionv-all 2 [1 2 3]))" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at" :expected "[[1 2] [3 4]]" :actual "(splitv-at 2 [1 2 3 4])" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at first is vector" :expected "true" :actual "(vector? (first (splitv-at 2 [1 2 3])))" :portability :common} - {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at past end" :expected "[[1 2] []]" :actual "(splitv-at 5 [1 2])" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "rest of vector is a seq" :expected "true" :actual "(seq? (rest [1 2 3]))" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "rest of vector not vector" :expected "false" :actual "(vector? (rest [1 2 3]))" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "rest values" :expected "[2 3]" :actual "(rest [1 2 3])" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "next of vector" :expected "[2 3]" :actual "(next [1 2 3])" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "next exhausts to nil" :expected "nil" :actual "(next [1])" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "rest exhausts to ()" :expected "[]" :actual "(rest [1])" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "rest-loop scales (20k linear)" :expected "20000" :actual "(loop [xs (seq (vec (range 20000))) n 0] (if xs (recur (next xs) (inc n)) n))" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "mapv scales (50k linear)" :expected "50000" :actual "(count (mapv inc (vec (range 50000))))" :portability :common} - {:suite "sequences / linear walks over concrete collections" :label "nested walk" :expected "[2 3]" :actual "(vec (rest (mapv inc [0 1 2])))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "next of set" :expected "true" :actual "(let [n (next #{1 2})] (and (= 1 (count n)) (contains? #{1 2} (first n))))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "rest of set count" :expected "1" :actual "(count (rest #{1 2}))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "next of singleton set" :expected "nil" :actual "(next #{1})" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "rest of empty set" :expected "0" :actual "(count (rest #{}))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "next of map" :expected "true" :actual "(let [n (next {:a 1 :b 2})] (and (= 1 (count n)) (map-entry? (first n))))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "next of singleton map" :expected "nil" :actual "(next {:a 1})" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "rest of sorted-set" :expected "[2 3]" :actual "(rest (sorted-set 3 1 2))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "next of sorted-map" :expected "[[2 :b]]" :actual "(next (sorted-map 1 :a 2 :b))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "every? over set" :expected "true" :actual "(every? pos? #{1 2 3})" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "every? over set false" :expected "false" :actual "(every? odd? #{1 2})" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "every? over sorted-set" :expected "true" :actual "(every? pos? (sorted-set 1 2 3))" :portability :common} - {:suite "sequences / rest & next over set-like colls" :label "every? over map entries" :expected "true" :actual "(every? map-entry? (seq {:a 1 :b 2}))" :portability :common} - {:suite "set / construct & predicate" :label "literal" :expected "#{1 3 2}" :actual "#{1 2 3}" :portability :common} - {:suite "set / construct & predicate" :label "hash-set" :expected "#{1 3 2}" :actual "(hash-set 1 2 3)" :portability :common} - {:suite "set / construct & predicate" :label "set from vector" :expected "#{1 3 2}" :actual "(set [1 2 3 1])" :portability :common} - {:suite "set / construct & predicate" :label "empty" :expected "#{}" :actual "#{}" :portability :common} - {:suite "set / construct & predicate" :label "set? true" :expected "true" :actual "(set? #{1})" :portability :common} - {:suite "set / construct & predicate" :label "set? false on vector" :expected "false" :actual "(set? [1])" :portability :common} - {:suite "set / construct & predicate" :label "count dedups" :expected "3" :actual "(count (set [1 1 2 3]))" :portability :common} - {:suite "set / construct & predicate" :label "equality order-indep" :expected "true" :actual "(= #{1 2 3} #{3 2 1})" :portability :common} - {:suite "set / construct & predicate" :label "into set" :expected "#{:b :a}" :actual "(into #{} [:a :b])" :portability :common} - {:suite "set / construct & predicate" :label "into non-empty set" :expected "#{1 3 2}" :actual "(into #{1} [2 3 2])" :portability :common} - {:suite "set / operations" :label "conj adds" :expected "#{1 3 2}" :actual "(conj #{1 2} 3)" :portability :common} - {:suite "set / operations" :label "conj dup no-op" :expected "#{1 2}" :actual "(conj #{1 2} 1)" :portability :common} - {:suite "set / operations" :label "disj removes" :expected "#{1 2}" :actual "(disj #{1 2 3} 3)" :portability :common} - {:suite "set / operations" :label "disj missing no-op" :expected "#{1 2}" :actual "(disj #{1 2} 9)" :portability :common} - {:suite "set / operations" :label "contains?" :expected "true" :actual "(contains? #{1 2} 1)" :portability :common} - {:suite "set / operations" :label "contains? missing" :expected "false" :actual "(contains? #{1 2} 9)" :portability :common} - {:suite "set / operations" :label "get present" :expected "1" :actual "(get #{1 2} 1)" :portability :common} - {:suite "set / operations" :label "get missing nil" :expected "nil" :actual "(get #{1 2} 9)" :portability :common} - {:suite "set / operations" :label "set as fn present" :expected "2" :actual "(#{1 2 3} 2)" :portability :common} - {:suite "set / operations" :label "set as fn missing" :expected "nil" :actual "(#{1 2 3} 9)" :portability :common} - {:suite "set / literals & value elements" :label "literal evaluates elements" :expected "#{4 2}" :actual "#{(inc 1) (* 2 2)}" :portability :common} - {:suite "set / literals & value elements" :label "map elements by value" :expected "true" :actual "(= #{{:a 1}} #{(hash-map :a 1)})" :portability :common} - {:suite "set / literals & value elements" :label "contains? map by value" :expected "true" :actual "(contains? #{(hash-map :x 1)} {:x 1})" :portability :common} - {:suite "set / literals & value elements" :label "dedup equal maps" :expected "1" :actual "(count (set [{:a 1} (hash-map :a 1)]))" :portability :common} - {:suite "set / literals & value elements" :label "vector elements" :expected "true" :actual "(contains? #{[1 2]} (vec [1 2]))" :portability :common} - {:suite "set / nil element" :label "set keeps nil" :expected "2" :actual "(count (set [nil 1 nil]))" :portability :common} - {:suite "set / nil element" :label "contains? nil true" :expected "true" :actual "(contains? (set [nil 1]) nil)" :portability :common} - {:suite "set / nil element" :label "contains? nil false" :expected "false" :actual "(contains? #{1} nil)" :portability :common} - {:suite "set / nil element" :label "seq includes nil" :expected "true" :actual "(some nil? (seq (set [nil 1])))" :portability :common} - {:suite "set / nil element" :label "disj nil" :expected "#{1}" :actual "(disj (set [nil 1]) nil)" :portability :common} - {:suite "set / nil element" :label "disj nil count" :expected "1" :actual "(count (disj (set [nil 1]) nil))" :portability :common} - {:suite "set / nil element" :label "conj nil count" :expected "2" :actual "(count (conj #{1} nil))" :portability :common} - {:suite "set / nil element" :label "conj nil contains?" :expected "true" :actual "(contains? (conj #{1} nil) nil)" :portability :common} - {:suite "set / nil element" :label "into #{} keeps nil" :expected "2" :actual "(count (into #{} [nil 1]))" :portability :common} - {:suite "set / nil element" :label "into #{} contains? nil" :expected "true" :actual "(contains? (into #{} [nil 1]) nil)" :portability :common} - {:suite "set / nil element" :label "into keeps existing nil" :expected "true" :actual "(contains? (into #{nil} [1]) nil)" :portability :common} - {:suite "set / nil element" :label "transient conj! nil" :expected "2" :actual "(count (persistent! (conj! (transient #{}) nil 1)))" :portability :common} - {:suite "set / nil element" :label "transient contains? nil" :expected "true" :actual "(contains? (persistent! (conj! (transient #{}) nil 1)) nil)" :portability :common} - {:suite "set / nil element" :label "transient disj! nil cnt" :expected "1" :actual "(count (persistent! (disj! (conj! (transient #{}) nil 1) nil)))" :portability :common} - {:suite "set / nil element" :label "transient disj! removes" :expected "false" :actual "(contains? (persistent! (disj! (conj! (transient #{}) nil 1) nil)) nil)" :portability :common} - {:suite "set / nil element" :label "transient of set w/ nil" :expected "true" :actual "(contains? (persistent! (transient (set [nil 1]))) nil)" :portability :common} - {:suite "clojure.set" :label "union" :expected "#{1 4 3 2}" :actual "(do (require (quote [clojure.set :as s])) (s/union #{1 2} #{3 4}))" :portability :common} - {:suite "clojure.set" :label "intersection" :expected "#{2}" :actual "(do (require (quote [clojure.set :as s])) (s/intersection #{1 2} #{2 3}))" :portability :common} - {:suite "clojure.set" :label "difference" :expected "#{1}" :actual "(do (require (quote [clojure.set :as s])) (s/difference #{1 2} #{2 3}))" :portability :common} - {:suite "clojure.set" :label "subset? true" :expected "true" :actual "(do (require (quote [clojure.set :as s])) (s/subset? #{1} #{1 2}))" :portability :common} - {:suite "clojure.set" :label "superset? true" :expected "true" :actual "(do (require (quote [clojure.set :as s])) (s/superset? #{1 2} #{1}))" :portability :common} - {:suite "clojure.set" :label "select" :expected "#{4 2}" :actual "(do (require (quote [clojure.set :as s])) (s/select even? #{1 2 3 4}))" :portability :common} - {:suite "clojure.set" :label "join" :expected "#{{:a 1, :b 2, :c 3}}" :actual "(do (require (quote [clojure.set :as s])) (s/join #{{:a 1 :b 2}} #{{:b 2 :c 3}}))" :portability :common} - {:suite "clojure.set" :label "map-invert" :expected "{1 :a}" :actual "(do (require (quote [clojure.set :as s])) (s/map-invert {:a 1}))" :portability :common} - {:suite "clojure.set" :label "rename-keys" :expected "{:b 1}" :actual "(do (require (quote [clojure.set :as s])) (s/rename-keys {:a 1} {:a :b}))" :portability :common} - {:suite "set / set? across representations" :label "literal" :expected "true" :actual "(set? #{1})" :portability :common} - {:suite "set / set? across representations" :label "empty literal" :expected "true" :actual "(set? #{})" :portability :common} - {:suite "set / set? across representations" :label "sorted-set" :expected "true" :actual "(set? (sorted-set 1 2))" :portability :common} - {:suite "set / set? across representations" :label "sorted-set-by" :expected "true" :actual "(set? (sorted-set-by > 1 2))" :portability :common} - {:suite "set / set? across representations" :label "empty sorted" :expected "true" :actual "(set? (sorted-set))" :portability :common} - {:suite "set / set? across representations" :label "map is not" :expected "false" :actual "(set? {})" :portability :common} - {:suite "set / set? across representations" :label "vector is not" :expected "false" :actual "(set? [1])" :portability :common} - {:suite "set / set? across representations" :label "coll? still true" :expected "true" :actual "(coll? (sorted-set 1))" :portability :common} - {:suite "set / set? across representations" :label "ifn? sorted-set" :expected "true" :actual "(ifn? (sorted-set 1))" :portability :common} - {:suite "set / bulk build boundaries" :label "set dedup count" :expected "3" :actual "(count (set [1 1 2 3 3 2]))" :portability :common} - {:suite "set / bulk build boundaries" :label "set big count" :expected "1000" :actual "(count (set (range 1000)))" :portability :common} - {:suite "set / bulk build boundaries" :label "into #{} count" :expected "500" :actual "(count (into #{} (range 500)))" :portability :common} - {:suite "set / bulk build boundaries" :label "into #{} onto base" :expected "3" :actual "(count (into #{:a} [:a :b :c]))" :portability :common} - {:suite "set / bulk build boundaries" :label "set contains" :expected "true" :actual "(contains? (set (range 1000)) 777)" :portability :common} - {:suite "set / bulk build boundaries" :label "set missing" :expected "false" :actual "(contains? (set (range 1000)) 5000)" :portability :common} - {:suite "set / bulk build boundaries" :label "set coll members" :expected "true" :actual "(contains? (set [[1 2] [3 4]]) [1 2])" :portability :common} - {:suite "set / bulk build boundaries" :label "conj after bulk" :expected "true" :actual "(contains? (conj (set (range 100)) :x) :x)" :portability :common} - {:suite "set / bulk build boundaries" :label "disj after bulk" :expected "false" :actual "(contains? (disj (set (range 100)) 50) 50)" :portability :common} - {:suite "set / bulk build boundaries" :label "set = literal" :expected "true" :actual "(= #{0 1 2} (set (range 3)))" :portability :common} - {:suite "sorted / construction & ordering" :label "sorted-set orders" :expected "[1 2 3]" :actual "(vec (seq (sorted-set 3 1 2)))" :portability :common} - {:suite "sorted / construction & ordering" :label "sorted-set dedupes" :expected "[1 2 3]" :actual "(vec (seq (sorted-set 3 1 2 1 3)))" :portability :common} - {:suite "sorted / construction & ordering" :label "sorted-set numeric" :expected "[1 2 10]" :actual "(vec (seq (sorted-set 10 1 2)))" :portability :common} - {:suite "sorted / construction & ordering" :label "sorted-map ordered entries" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(vec (seq (sorted-map :c 3 :a 1 :b 2)))" :portability :common} - {:suite "sorted / construction & ordering" :label "first is min" :expected "1" :actual "(first (sorted-set 5 3 9 1))" :portability :common} - {:suite "sorted / sorted?" :label "sorted-set" :expected "true" :actual "(sorted? (sorted-set 1))" :portability :common} - {:suite "sorted / sorted?" :label "sorted-map" :expected "true" :actual "(sorted? (sorted-map :a 1))" :portability :common} - {:suite "sorted / sorted?" :label "plain set" :expected "false" :actual "(sorted? #{1})" :portability :common} - {:suite "sorted / sorted?" :label "plain map" :expected "false" :actual "(sorted? {:a 1})" :portability :common} - {:suite "sorted / sorted?" :label "vector" :expected "false" :actual "(sorted? [1 2])" :portability :common} - {:suite "sorted / map ops" :label "get hit" :expected "2" :actual "(get (sorted-map :a 1 :b 2) :b)" :portability :common} - {:suite "sorted / map ops" :label "get miss default" :expected ":none" :actual "(get (sorted-map :a 1) :z :none)" :portability :common} - {:suite "sorted / map ops" :label "contains? yes" :expected "true" :actual "(contains? (sorted-map :a 1) :a)" :portability :common} - {:suite "sorted / map ops" :label "contains? no" :expected "false" :actual "(contains? (sorted-map :a 1) :z)" :portability :common} - {:suite "sorted / map ops" :label "assoc keeps order" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(vec (seq (assoc (sorted-map :c 3 :a 1) :b 2)))" :portability :common} - {:suite "sorted / map ops" :label "dissoc" :expected "[[:a 1] [:c 3]]" :actual "(vec (seq (dissoc (sorted-map :a 1 :b 2 :c 3) :b)))" :portability :common} - {:suite "sorted / map ops" :label "conj entry" :expected "[[:a 1] [:z 9]]" :actual "(vec (seq (conj (sorted-map :a 1) [:z 9])))" :portability :common} - {:suite "sorted / map ops" :label "keys sorted" :expected "[:a :b :c]" :actual "(vec (keys (sorted-map :c 3 :a 1 :b 2)))" :portability :common} - {:suite "sorted / map ops" :label "vals by key" :expected "[1 2 3]" :actual "(vec (vals (sorted-map :c 3 :a 1 :b 2)))" :portability :common} - {:suite "sorted / map ops" :label "map as fn" :expected "2" :actual "((sorted-map :a 1 :b 2) :b)" :portability :common} - {:suite "sorted / map ops" :label "map as fn miss" :expected ":d" :actual "((sorted-map :a 1) :z :d)" :portability :common} - {:suite "sorted / set ops" :label "get present" :expected "2" :actual "(get (sorted-set 1 2 3) 2)" :portability :common} - {:suite "sorted / set ops" :label "get absent" :expected ":none" :actual "(get (sorted-set 1 2 3) 9 :none)" :portability :common} - {:suite "sorted / set ops" :label "contains? yes" :expected "true" :actual "(contains? (sorted-set 1 2 3) 2)" :portability :common} - {:suite "sorted / set ops" :label "contains? no" :expected "false" :actual "(contains? (sorted-set 1 2 3) 9)" :portability :common} - {:suite "sorted / set ops" :label "conj keeps order" :expected "[0 1 2 3 5]" :actual "(vec (seq (conj (sorted-set 1 2 3) 5 0)))" :portability :common} - {:suite "sorted / set ops" :label "disj" :expected "[1 3]" :actual "(vec (seq (disj (sorted-set 1 2 3) 2)))" :portability :common} - {:suite "sorted / set ops" :label "set as fn" :expected "3" :actual "((sorted-set 1 2 3) 3)" :portability :common} - {:suite "sorted / set ops" :label "set as fn miss" :expected "nil" :actual "((sorted-set 1 2 3) 9)" :portability :common} - {:suite "sorted / by comparator" :label "sorted-set-by desc" :expected "[10 3 2 1]" :actual "(vec (seq (sorted-set-by > 1 3 2 10)))" :portability :common} - {:suite "sorted / by comparator" :label "sorted-map-by desc" :expected "[[3 :c] [2 :b] [1 :a]]" :actual "(vec (seq (sorted-map-by > 1 :a 3 :c 2 :b)))" :portability :common} - {:suite "sorted / by comparator" :label "conj keeps comparator" :expected "[5 3 2 1 0]" :actual "(vec (seq (conj (sorted-set-by > 1 3 2) 5 0)))" :portability :common} - {:suite "sorted / by comparator" :label "assoc keeps comparator" :expected "[3 2 1]" :actual "(vec (keys (assoc (sorted-map-by > 1 :a 3 :c) 2 :b)))" :portability :common} - {:suite "sorted / by comparator" :label "disj keeps comparator" :expected "[3 1]" :actual "(vec (seq (disj (sorted-set-by > 1 2 3) 2)))" :portability :common} - {:suite "sorted / by comparator" :label "by-comparator is sorted?" :expected "true" :actual "(sorted? (sorted-set-by > 1 2))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "subseq >=" :expected "[3 4 5]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) >= 3))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "subseq <" :expected "[1 2]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) < 3))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "subseq range" :expected "[2 3 4]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) > 1 < 5))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "rsubseq <=" :expected "[3 2 1]" :actual "(vec (rsubseq (sorted-set 1 2 3 4 5) <= 3))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "subseq on map" :expected "[[2 :b] [3 :c]]" :actual "(vec (subseq (sorted-map 1 :a 2 :b 3 :c) > 1))" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "subseq empty result" :expected "nil" :actual "(subseq (sorted-set 1 2) > 5)" :portability :common} - {:suite "sorted / subseq & rsubseq" :label "rsubseq on map" :expected "[[2 :b] [1 :a]]" :actual "(vec (rsubseq (sorted-map 1 :a 2 :b 3 :c) < 3))" :portability :common} - {:suite "sorted / predicates" :label "sorted-map? true" :expected "true" :actual "(sorted-map? (sorted-map 1 :a))" :portability :common} - {:suite "sorted / predicates" :label "sorted-map? false" :expected "false" :actual "(sorted-map? {:a 1})" :portability :common} - {:suite "sorted / predicates" :label "sorted-set? true" :expected "true" :actual "(sorted-set? (sorted-set 1))" :portability :common} - {:suite "sorted / predicates" :label "sorted-set? false" :expected "false" :actual "(sorted-set? #{1})" :portability :common} - {:suite "sorted / predicates" :label "map? sorted-map" :expected "true" :actual "(map? (sorted-map 1 :a))" :portability :common} - {:suite "sorted / predicates" :label "coll? sorted-set" :expected "true" :actual "(coll? (sorted-set 1))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "get cross-numeric" :expected ":a" :actual "(get (sorted-map 1 :a) 1.0)" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "contains? cross-numeric" :expected "true" :actual "(contains? (sorted-set 1) 1.0)" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "conj equal elem no-op" :expected "1" :actual "(count (conj (sorted-set 1) 1.0))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "assoc equal key replaces" :expected "[[1 :z]]" :actual "(vec (seq (assoc (sorted-map 1 :a) 1.0 :z)))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "first sorted-map" :expected "[1 :a]" :actual "(first (sorted-map 2 :b 1 :a))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "dissoc missing no-op" :expected "2" :actual "(count (dissoc (sorted-map 1 :a 2 :b) 9))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "conj map merges" :expected "3" :actual "(count (conj (sorted-map 1 :a) {2 :b 3 :c}))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "conj nil no-op" :expected "1" :actual "(count (conj (sorted-map 1 :a) nil))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "into sorted-map" :expected "[[1 :a] [2 :b]]" :actual "(vec (seq (into (sorted-map) [[2 :b] [1 :a]])))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "source unchanged" :expected "[1 2]" :actual "(let [s (sorted-set 1 2)] (conj s 9) (vec (seq s)))" :portability :common} - {:suite "sorted / lookup + membership use the comparator" :label "sorted-map odd kvs throws" :expected :throws :actual "(sorted-map 1 :a 2)" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-map = literal" :expected "true" :actual "(= (sorted-map :a 1 :b 2) {:a 1 :b 2})" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "literal = sorted-map" :expected "true" :actual "(= {:a 1 :b 2} (sorted-map :a 1 :b 2))" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-map = hash-map" :expected "true" :actual "(= (sorted-map :a 1) (hash-map :a 1))" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-map != more keys" :expected "false" :actual "(= (sorted-map :a 1) {:a 1 :b 2})" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-set = literal" :expected "true" :actual "(= (sorted-set 1 2) #{1 2})" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "literal = sorted-set" :expected "true" :actual "(= #{1 2} (sorted-set 2 1))" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-set != diff" :expected "false" :actual "(= (sorted-set 1 2) #{1 3})" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "two sorted-maps" :expected "true" :actual "(= (sorted-map 1 :a 2 :b) (sorted-map 2 :b 1 :a))" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "cmp irrelevant to =" :expected "true" :actual "(= (sorted-map-by > 1 :a 2 :b) (sorted-map 1 :a 2 :b))" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-map as map key" :expected ":hit" :actual "(get {(sorted-map :a 1) :hit} {:a 1})" :portability :common} - {:suite "sorted / equality is representation-agnostic" :label "sorted-set as map key" :expected ":hit" :actual "(get {(sorted-set 1 2) :hit} #{2 1})" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty? empty map" :expected "true" :actual "(empty? (sorted-map))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty? non-empty" :expected "false" :actual "(empty? (sorted-map 1 :a))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty? empty set" :expected "true" :actual "(empty? (sorted-set))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty keeps sortedness" :expected "true" :actual "(sorted? (empty (sorted-map 1 :a)))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty keeps cmp" :expected "[3 1]" :actual "(vec (seq (into (empty (sorted-set-by > 1 2)) [1 3])))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "empty set kind" :expected "true" :actual "(sorted-set? (empty (sorted-set 1)))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "rseq map" :expected "[[2 :b] [1 :a]]" :actual "(vec (rseq (sorted-map 1 :a 2 :b)))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "rseq set" :expected "[3 2 1]" :actual "(vec (rseq (sorted-set 1 2 3)))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "pr-str sorted-map" :expected "\"{1 :a, 2 :b}\"" :actual "(pr-str (sorted-map 2 :b 1 :a))" :portability :common} - {:suite "sorted / empty + empty? + rseq + printing" :label "pr-str sorted-set" :expected "\"#{1 2 3}\"" :actual "(pr-str (sorted-set 3 1 2))" :portability :common} - {:suite "sorted / seq fn interop" :label "map over sorted-map" :expected "[1 2 3]" :actual "(vec (map first (sorted-map 2 :b 1 :a 3 :c)))" :portability :common} - {:suite "sorted / seq fn interop" :label "map over sorted-set" :expected "[2 3 4]" :actual "(vec (map inc (sorted-set 3 1 2)))" :portability :common} - {:suite "sorted / seq fn interop" :label "filter entries" :expected "[[2 :b]]" :actual "(vec (filter (fn [[k v]] (even? k)) (sorted-map 1 :a 2 :b)))" :portability :common} - {:suite "sorted / seq fn interop" :label "reduce over set" :expected "6" :actual "(reduce + (sorted-set 1 2 3))" :portability :common} - {:suite "sorted / seq fn interop" :label "vec of sorted-set" :expected "[1 2 3]" :actual "(vec (sorted-set 3 1 2))" :portability :common} - {:suite "sorted / seq fn interop" :label "into vec" :expected "[[1 :a] [2 :b]]" :actual "(into [] (sorted-map 2 :b 1 :a))" :portability :common} - {:suite "sorted / seq fn interop" :label "sorted-map-by 3way cmp" :expected "[3 2 1]" :actual "(vec (keys (sorted-map-by (fn [a b] (- b a)) 1 :a 2 :b 3 :c)))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "slurp returns string" :expected "true" :actual "(string? (slurp \"README.md\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "slurp content" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/includes? (slurp \"README.md\") \"jolt\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "spit + slurp round" :expected "\"hello\"" :actual "(do (spit \"/tmp/jolt-spit-test.txt\" \"hello\") (slurp \"/tmp/jolt-spit-test.txt\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "spit append" :expected "\"ab\"" :actual "(do (spit \"/tmp/jolt-spit-test.txt\" \"a\") (spit \"/tmp/jolt-spit-test.txt\" \"b\" :append true) (slurp \"/tmp/jolt-spit-test.txt\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "printf formats" :expected "\"x=1 y=a\"" :actual "(with-out-str (printf \"x=%d y=%s\" 1 \"a\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "printf no newline" :expected "false" :actual "(do (require (quote [clojure.string :as s])) (s/includes? (with-out-str (printf \"%d\" 1)) \"\\n\"))" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "flush returns nil" :expected "nil" :actual "(flush)" :portability :common} - {:suite "io / slurp, spit, printf, flush (host-classified)" :label "file-seq finds files" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (boolean (some (fn [p] (s/ends-with? p \"README.md\")) (file-seq \".\"))))" :portability :common} - {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-map has var" :expected "true" :actual "(do (def nmv 1) (some? (get (ns-map (quote user)) (quote nmv))))" :portability :common} - {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-unmap removes" :expected "nil" :actual "(do (def nuv 1) (ns-unmap (quote user) (quote nuv)) (resolve (quote nuv)))" :portability :common} - {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-refers sees refer" :expected "true" :actual "(do (require (quote clojure.string)) (refer (quote clojure.string)) (some? (get (ns-refers (quote user)) (quote join))))" :portability :common} - {:suite "vars / thread-binding family" :label "bound? on def" :expected "true" :actual "(do (def bvv 1) (bound? (var bvv)))" :portability :common} - {:suite "vars / thread-binding family" :label "with-bindings* binds" :expected "5" :actual "(do (def ^:dynamic dynv 1) (with-bindings* (array-map (var dynv) 5) (fn [] dynv)))" :portability :common} - {:suite "vars / thread-binding family" :label "with-bindings* restores" :expected "1" :actual "(do (def ^:dynamic dynw 1) (with-bindings* (array-map (var dynw) 5) (fn [] nil)) dynw)" :portability :common} - {:suite "vars / thread-binding family" :label "with-bindings macro" :expected "7" :actual "(do (def ^:dynamic dynx 1) (with-bindings (array-map (var dynx) 7) dynx))" :portability :common} - {:suite "vars / thread-binding family" :label "thread-bound? inside" :expected "[true false]" :actual "(do (def ^:dynamic dyny 1) [(with-bindings* (array-map (var dyny) 2) (fn [] (thread-bound? (var dyny)))) (thread-bound? (var dyny))])" :portability :common} - {:suite "vars / thread-binding family" :label "bound-fn* conveys" :expected "9" :actual "(do (def ^:dynamic dynz 1) (def f (with-bindings* (array-map (var dynz) 9) (fn [] (bound-fn* (fn [] dynz))))) (f))" :portability :common} - {:suite "vars / thread-binding family" :label "get-thread-bindings" :expected "3" :actual "(do (def ^:dynamic dyng 1) (with-bindings* (array-map (var dyng) 3) (fn [] (get (get-thread-bindings) (var dyng)))))" :portability :common} - {:suite "eval & load-string as values" :label "load-string evals all" :expected "3" :actual "(load-string \"(def lsv 1) (+ lsv 2)\")" :portability :common} - {:suite "eval & load-string as values" :label "eval as value" :expected "[2 3]" :actual "(mapv eval [(quote (+ 1 1)) (quote (+ 1 2))])" :portability :common} - {:suite "eval & load-string as values" :label "eval special still works" :expected "3" :actual "(eval (quote (+ 1 2)))" :portability :common} - {:suite "clojure.edn / opts" :label "set literal" :expected "#{1 2}" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string \"#{1 2}\"))" :portability :common} - {:suite "clojure.edn / opts" :label "uuid tag" :expected "true" :actual "(do (require (quote [clojure.edn :as e0])) (uuid? (e0/read-string \"#uuid \\\"550e8400-e29b-41d4-a716-446655440000\\\"\")))" :portability :common} - {:suite "clojure.edn / opts" :label "inst tag" :expected "true" :actual "(do (require (quote [clojure.edn :as e0])) (inst? (e0/read-string \"#inst \\\"2020-01-01T00:00:00Z\\\"\")))" :portability :common} - {:suite "clojure.edn / opts" :label ":eof on empty" :expected ":end" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:eof :end} \"\"))" :portability :common} - {:suite "clojure.edn / opts" :label ":readers custom tag" :expected "[:custom 5]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:readers {(quote custom) (fn [v] [:custom v])}} \"#custom 5\"))" :portability :common} - {:suite "clojure.edn / opts" :label ":readers nested" :expected "[6 8]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:readers {(quote w) (fn [v] (* 2 v))}} \"[#w 3 #w 4]\"))" :portability :common} - {:suite "clojure.edn / opts" :label ":default fn" :expected "[:dflt 7]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:default (fn [t v] [:dflt v])} \"#unknown 7\"))" :portability :common} - {:suite "clojure.edn / opts" :label "unknown tag throws" :expected :throws :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string \"#nope 1\"))" :portability :common} - {:suite "state / atoms" :label "deref @" :expected "0" :actual "(let [a (atom 0)] @a)" :portability :common} - {:suite "state / atoms" :label "deref fn" :expected "0" :actual "(deref (atom 0))" :portability :common} - {:suite "state / atoms" :label "reset!" :expected "5" :actual "(let [a (atom 0)] (reset! a 5) @a)" :portability :common} - {:suite "state / atoms" :label "reset! returns new" :expected "5" :actual "(let [a (atom 0)] (reset! a 5))" :portability :common} - {:suite "state / atoms" :label "swap!" :expected "1" :actual "(let [a (atom 0)] (swap! a inc) @a)" :portability :common} - {:suite "state / atoms" :label "swap! with args" :expected "10" :actual "(let [a (atom 1)] (swap! a + 2 3 4) @a)" :portability :common} - {:suite "state / atoms" :label "swap! returns new" :expected "1" :actual "(let [a (atom 0)] (swap! a inc))" :portability :common} - {:suite "state / atoms" :label "swap-vals!" :expected "[0 1]" :actual "(let [a (atom 0)] (swap-vals! a inc))" :portability :common} - {:suite "state / atoms" :label "reset-vals!" :expected "[0 9]" :actual "(let [a (atom 0)] (reset-vals! a 9))" :portability :common} - {:suite "state / atoms" :label "compare-and-set! ok" :expected "true" :actual "(let [a (atom 0)] (compare-and-set! a 0 1))" :portability :common} - {:suite "state / atoms" :label "compare-and-set! no" :expected "false" :actual "(let [a (atom 0)] (compare-and-set! a 9 1))" :portability :common} - {:suite "state / atoms" :label "atom?" :expected "true" :actual "(do (require (quote [clojure.core])) (instance? clojure.lang.Atom (atom 0)))" :portability :jvm} - {:suite "state / atoms" :label "atom? predicate" :expected "true" :actual "(atom? (atom 0))" :portability :common} - {:suite "state / atoms" :label "atom? on non-atom" :expected "false" :actual "(atom? 5)" :portability :common} - {:suite "state / watches & validators" :label "add-watch fires" :expected "1" :actual "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (reset! seen 1))) (reset! a 5) @seen)" :portability :common} - {:suite "state / watches & validators" :label "remove-watch" :expected "0" :actual "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (swap! seen inc))) (remove-watch a :k) (reset! a 5) @seen)" :portability :common} - {:suite "state / watches & validators" :label "set-validator! ok" :expected "5" :actual "(let [a (atom 0)] (set-validator! a number?) (reset! a 5) @a)" :portability :common} - {:suite "state / watches & validators" :label "set-validator! rejects" :expected :throws :actual "(let [a (atom 0)] (set-validator! a pos?) (reset! a -1))" :portability :common} - {:suite "state / watches & validators" :label "get-validator" :expected "true" :actual "(let [a (atom 0)] (set-validator! a number?) (fn? (get-validator a)))" :portability :common} - {:suite "state / volatiles & delays" :label "volatile! deref" :expected "0" :actual "(let [v (volatile! 0)] @v)" :portability :common} - {:suite "state / volatiles & delays" :label "vreset!" :expected "5" :actual "(let [v (volatile! 0)] (vreset! v 5) @v)" :portability :common} - {:suite "state / volatiles & delays" :label "vswap!" :expected "1" :actual "(let [v (volatile! 0)] (vswap! v inc) @v)" :portability :common} - {:suite "state / volatiles & delays" :label "delay not forced" :expected "0" :actual "(let [c (atom 0) d (delay (swap! c inc))] @c)" :portability :common} - {:suite "state / volatiles & delays" :label "delay force once" :expected "1" :actual "(let [c (atom 0) d (delay (swap! c inc))] (force d) (force d) @c)" :portability :common} - {:suite "state / volatiles & delays" :label "delay value" :expected "5" :actual "(let [d (delay 5)] @d)" :portability :common} - {:suite "state / volatiles & delays" :label "realized? before" :expected "false" :actual "(let [d (delay 5)] (realized? d))" :portability :common} - {:suite "state / volatiles & delays" :label "realized? after" :expected "true" :actual "(let [d (delay 5)] (force d) (realized? d))" :portability :common} - {:suite "state / promises" :label "promise deliver" :expected "5" :actual "(let [p (promise)] (deliver p 5) @p)" :portability :common} - {:suite "state / promises" :label "promise undelivered" :expected "nil" :actual "(let [p (promise)] @p)" :portability :common} - {:suite "state / agents (synchronous shim)" :label "agent deref" :expected "0" :actual "(deref (agent 0))" :portability :common} - {:suite "state / agents (synchronous shim)" :label "agent with opts" :expected "0" :actual "(deref (agent 0 :error-mode :continue))" :portability :common} - {:suite "state / agents (synchronous shim)" :label "send-off applies" :expected "0" :actual "(let [a (agent 0)] (send-off a (fn [x] (Thread/sleep 100) (+ x 5))) (deref a))" :portability :jvm} - {:suite "state / agents (synchronous shim)" :label "send applies" :expected "1" :actual "(let [a (agent 1)] (send a (fn [x] (Thread/sleep 100) (+ x 6))) (deref a))" :portability :jvm} - {:suite "state / agents (synchronous shim)" :label "agent-error nil" :expected "nil" :actual "(agent-error (agent 0))" :portability :common} - {:suite "string / str & basics" :label "str concat" :expected "\"abc\"" :actual "(str \"a\" \"b\" \"c\")" :portability :common} - {:suite "string / str & basics" :label "str of numbers" :expected "\"12\"" :actual "(str 1 2)" :portability :common} - {:suite "string / str & basics" :label "str nil is empty" :expected "\"\"" :actual "(str nil)" :portability :common} - {:suite "string / str & basics" :label "str mixed" :expected "\"a1:b\"" :actual "(str \"a\" 1 :b)" :portability :common} - {:suite "string / str & basics" :label "str of coll" :expected "\"[1 2]\"" :actual "(str [1 2])" :portability :common} - {:suite "string / str & basics" :label "count" :expected "3" :actual "(count \"abc\")" :portability :common} - {:suite "string / str & basics" :label "subs from" :expected "\"bc\"" :actual "(subs \"abc\" 1)" :portability :common} - {:suite "string / str & basics" :label "subs range" :expected "\"b\"" :actual "(subs \"abc\" 1 2)" :portability :common} - {:suite "string / str & basics" :label "string? true" :expected "true" :actual "(string? \"x\")" :portability :common} - {:suite "string / str & basics" :label "pr-str vector" :expected "\"[1 2 3]\"" :actual "(pr-str [1 2 3])" :portability :common} - {:suite "string / str & basics" :label "pr-str quotes str" :expected "\"\\\"hi\\\"\"" :actual "(pr-str \"hi\")" :portability :common} - {:suite "string / str & basics" :label "pr-str of a var" :expected "\"#'user/vv\"" :actual "(pr-str (def vv 1))" :portability :common} - {:suite "string / str & basics" :label "str of a var" :expected "\"#'user/ww\"" :actual "(str (def ww 2))" :portability :common} - {:suite "string / str & basics" :label "pr-str of a defn" :expected "\"#'user/gg\"" :actual "(pr-str (defn gg [x] x))" :portability :common} - {:suite "string / str & basics" :label "seq of string" :expected "[\\a \\b]" :actual "(seq \"ab\")" :portability :common} - {:suite "string as a seqable of chars" :label "vec of string" :expected "[\\a \\b]" :actual "(vec \"ab\")" :portability :common} - {:suite "string as a seqable of chars" :label "into [] of string" :expected "[\\a \\b]" :actual "(into [] \"ab\")" :portability :common} - {:suite "string as a seqable of chars" :label "set of string" :expected "true" :actual "(= #{\\a \\b} (set \"ab\"))" :portability :common} - {:suite "string as a seqable of chars" :label "into #{} of string" :expected "true" :actual "(= #{\\a \\b} (into #{} \"ab\"))" :portability :common} - {:suite "string as a seqable of chars" :label "set dedups chars" :expected "2" :actual "(count (set \"aab\"))" :portability :common} - {:suite "string as a seqable of chars" :label "mapv over string" :expected "[\\a \\b]" :actual "(mapv identity \"ab\")" :portability :common} - {:suite "clojure.string / split limit" :label "neg keeps trailing" :expected "[\"a\" \"\" \"\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\" -1))" :portability :common} - {:suite "clojure.string / split limit" :label "zero trims trailing" :expected "[\"a\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\" 0))" :portability :common} - {:suite "clojure.string / split limit" :label "omitted trims" :expected "[\"a\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\"))" :portability :common} - {:suite "clojure.string / split limit" :label "positive caps parts" :expected "[\"a\" \"b,c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b,c\" #\",\" 2))" :portability :common} - {:suite "clojure.string / split limit" :label "empty string" :expected "[\"\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"\" #\",\"))" :portability :common} - {:suite "clojure.string / split limit" :label "interior empties kept" :expected "[\"a\" \"\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,b\" #\",\"))" :portability :common} - {:suite "clojure.string" :label "join" :expected "\"a,b,c\"" :actual "(do (require (quote [clojure.string :as s])) (s/join \",\" [\"a\" \"b\" \"c\"]))" :portability :common} - {:suite "clojure.string" :label "join no sep" :expected "\"abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/join [\"a\" \"b\" \"c\"]))" :portability :common} - {:suite "clojure.string" :label "split" :expected "[\"a\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b\" #\",\"))" :portability :common} - {:suite "clojure.string" :label "split-lines" :expected "[\"a\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split-lines \"a\\nb\"))" :portability :common} - {:suite "clojure.string" :label "upper-case" :expected "\"ABC\"" :actual "(do (require (quote [clojure.string :as s])) (s/upper-case \"abc\"))" :portability :common} - {:suite "clojure.string" :label "lower-case" :expected "\"abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/lower-case \"ABC\"))" :portability :common} - {:suite "clojure.string" :label "capitalize" :expected "\"Abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/capitalize \"abc\"))" :portability :common} - {:suite "clojure.string" :label "trim" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim \" x \"))" :portability :common} - {:suite "clojure.string" :label "triml" :expected "\"x \"" :actual "(do (require (quote [clojure.string :as s])) (s/triml \" x \"))" :portability :common} - {:suite "clojure.string" :label "blank? true" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/blank? \" \"))" :portability :common} - {:suite "clojure.string" :label "blank? false" :expected "false" :actual "(do (require (quote [clojure.string :as s])) (s/blank? \"x\"))" :portability :common} - {:suite "clojure.string" :label "includes?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/includes? \"hello\" \"ell\"))" :portability :common} - {:suite "clojure.string" :label "starts-with?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/starts-with? \"hello\" \"he\"))" :portability :common} - {:suite "clojure.string" :label "ends-with?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/ends-with? \"hello\" \"lo\"))" :portability :common} - {:suite "clojure.string" :label "replace" :expected "\"hexxo\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" \"l\" \"x\"))" :portability :common} - {:suite "clojure.string" :label "reverse" :expected "\"cba\"" :actual "(do (require (quote [clojure.string :as s])) (s/reverse \"abc\"))" :portability :common} - {:suite "clojure.string" :label "index-of" :expected "2" :actual "(do (require (quote [clojure.string :as s])) (s/index-of \"hello\" \"l\"))" :portability :common} - {:suite "string / subs strictness" :label "subs basic" :expected "\"bcd\"" :actual "(subs \"abcde\" 1 4)" :portability :common} - {:suite "string / subs strictness" :label "subs to end" :expected "\"cde\"" :actual "(subs \"abcde\" 2)" :portability :common} - {:suite "string / subs strictness" :label "subs start>end" :expected :throws :actual "(subs \"abcde\" 2 1)" :portability :common} - {:suite "string / subs strictness" :label "subs negative" :expected :throws :actual "(subs \"abcde\" -1)" :portability :common} - {:suite "string / subs strictness" :label "subs end past len" :expected :throws :actual "(subs \"abcde\" 1 6)" :portability :common} - {:suite "string / subs strictness" :label "subs nil start" :expected :throws :actual "(subs \"abcde\" nil 2)" :portability :common} - {:suite "string / subs strictness" :label "subs on nil" :expected :throws :actual "(subs nil 1 2)" :portability :common} - {:suite "string / namespace-munge" :label "hyphens to underscores" :expected "\"a_b_c\"" :actual "(namespace-munge \"a-b-c\")" :portability :common} - {:suite "string / namespace-munge" :label "from a symbol" :expected "\"foo_bar\"" :actual "(namespace-munge (quote foo-bar))" :portability :common} - {:suite "string / namespace-munge" :label "no hyphens unchanged" :expected "\"ok\"" :actual "(namespace-munge \"ok\")" :portability :common} - {:suite "strings / get indexes a string" :label "get returns the char" :expected "true" :actual "(= (get \"a:b\" 1) \\:)" :portability :common} - {:suite "strings / get indexes a string" :label "get first char" :expected "\\a" :actual "(get \"abc\" 0)" :portability :common} - {:suite "strings / get indexes a string" :label "get out of range nil" :expected "nil" :actual "(get \"abc\" 9)" :portability :common} - {:suite "strings / get indexes a string" :label "get negative nil" :expected "nil" :actual "(get \"abc\" -1)" :portability :common} - {:suite "strings / get indexes a string" :label "get default honored" :expected ":none" :actual "(get \"abc\" 9 :none)" :portability :common} - {:suite "clojure.string / trim-newline" :label "trailing newline" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"x\\n\"))" :portability :common} - {:suite "clojure.string / trim-newline" :label "trailing \\r\\n" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"x\\r\\n\"))" :portability :common} - {:suite "clojure.string / trim-newline" :label "no trailing" :expected "\"ab\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"ab\"))" :portability :common} - {:suite "clojure.string / trim-newline" :label "only newlines" :expected "\"\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"\\n\\n\"))" :portability :common} - {:suite "clojure.string / trim-newline" :label "interior kept" :expected "\"a\\nb\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"a\\nb\\n\"))" :portability :common} - {:suite "transducers / into" :label "map xform" :expected "[2 3 4]" :actual "(into [] (map inc) [1 2 3])" :portability :common} - {:suite "transducers / into" :label "filter xform" :expected "[2 4]" :actual "(into [] (filter even?) [1 2 3 4])" :portability :common} - {:suite "transducers / into" :label "remove xform" :expected "[1 3]" :actual "(into [] (remove even?) [1 2 3 4])" :portability :common} - {:suite "transducers / into" :label "take xform" :expected "[1 2]" :actual "(into [] (take 2) [1 2 3 4])" :portability :common} - {:suite "transducers / into" :label "drop xform" :expected "[3 4]" :actual "(into [] (drop 2) [1 2 3 4])" :portability :common} - {:suite "transducers / into" :label "take-while xform" :expected "[1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) [1 2 3 1])" :portability :common} - {:suite "transducers / into" :label "keep xform" :expected "[1 3]" :actual "(into [] (keep (fn [x] (if (odd? x) x nil))) [1 2 3 4])" :portability :common} - {:suite "transducers / into" :label "map-indexed xform" :expected "[[0 :a] [1 :b]]" :actual "(into [] (map-indexed vector) [:a :b])" :portability :common} - {:suite "transducers / into" :label "mapcat xform" :expected "[1 1 2 2]" :actual "(into [] (mapcat (fn [x] [x x])) [1 2])" :portability :common} - {:suite "transducers / into" :label "cat xform" :expected "[1 2 3 4]" :actual "(into [] cat [[1 2] [3 4]])" :portability :common} - {:suite "transducers / into" :label "into a set" :expected "#{4 3 2}" :actual "(into #{} (map inc) [1 2 3])" :portability :common} - {:suite "transducers / compose" :label "comp map+filter" :expected "[2 4 6 8]" :actual "(into [] (comp (map (fn [x] (* x 2))) (filter even?)) [1 2 3 4])" :portability :common} - {:suite "transducers / compose" :label "comp filter+map" :expected "[2 4]" :actual "(into [] (comp (filter odd?) (map inc)) [1 2 3 4])" :portability :common} - {:suite "transducers / compose" :label "comp three" :expected "[2]" :actual "(into [] (comp (map inc) (filter even?) (take 1)) [1 2 3 4])" :portability :common} - {:suite "transducers / transduce & sequence" :label "transduce sum" :expected "9" :actual "(transduce (map inc) + [1 2 3])" :portability :common} - {:suite "transducers / transduce & sequence" :label "transduce init" :expected "19" :actual "(transduce (map inc) + 10 [1 2 3])" :portability :common} - {:suite "transducers / transduce & sequence" :label "transduce filter" :expected "6" :actual "(transduce (filter even?) + [1 2 3 4])" :portability :common} - {:suite "transducers / transduce & sequence" :label "sequence xform" :expected "[2 3 4]" :actual "(sequence (map inc) [1 2 3])" :portability :common} - {:suite "transducers / transduce & sequence" :label "eduction" :expected "[2 3 4]" :actual "(into [] (eduction (map inc) [1 2 3]))" :portability :common} - {:suite "transducers / transduce & sequence" :label "completing" :expected "9" :actual "(transduce (map inc) (completing +) 0 [1 2 3])" :portability :common} - {:suite "transducers / halt-when" :label "halt returns the halting input" :expected "7" :actual "(transduce (halt-when (fn [x] (> x 5))) conj [1 2 7 3])" :portability :common} - {:suite "transducers / halt-when" :label "no halt is a plain reduction" :expected "[1 2 3]" :actual "(transduce (halt-when (fn [x] (> x 5))) conj [1 2 3])" :portability :common} - {:suite "transducers / halt-when" :label "retf combines acc and input" :expected "[[1 2] 7]" :actual "(transduce (halt-when (fn [x] (> x 5)) (fn [r i] [r i])) conj [1 2 7 3])" :portability :common} - {:suite "transducers / halt-when" :label "halt-when through into" :expected "3" :actual "(into [] (halt-when odd?) [2 4 3 6])" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "into take (range)" :expected "[0 1 2 3 4]" :actual "(into [] (take 5) (range))" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "transduce take (range)" :expected "3" :actual "(transduce (take 3) + 0 (range))" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "sequence take (range)" :expected "[0 1 2 3 4]" :actual "(sequence (take 5) (range))" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "take-while over (range)" :expected "[0 1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) (range))" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "comp take over (range)" :expected "[1 3 5]" :actual "(into [] (comp (filter odd?) (take 3)) (range))" :portability :common} - {:suite "transducers / short-circuit over infinite seqs" :label "into take iterate" :expected "[0 1 2 3 4]" :actual "(into [] (take 5) (iterate inc 0))" :portability :common} - {:suite "reduce / honors reduced" :label "reduced short-circuits inf" :expected "105" :actual "(reduce (fn [a x] (if (> a 100) (reduced a) (+ a x))) 0 (range))" :portability :common} - {:suite "reduce / honors reduced" :label "reduce take inf" :expected "10" :actual "(reduce + (take 5 (range)))" :portability :common} - {:suite "reduce / honors reduced" :label "reduce no-init first elem" :expected "6" :actual "(reduce + [1 2 3])" :portability :common} - {:suite "reduce / honors reduced" :label "reduce no-init single" :expected "42" :actual "(reduce + [42])" :portability :common} - {:suite "reduce / honors reduced" :label "reduce empty calls f" :expected "0" :actual "(reduce + [])" :portability :common} - {:suite "reduce / honors reduced" :label "reduce with-init" :expected "16" :actual "(reduce + 10 [1 2 3])" :portability :common} - {:suite "reduce / honors reduced" :label "reduce reduced immediate" :expected ":x" :actual "(reduce (fn [a x] (reduced :x)) :init [1 2 3])" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "into list prepends" :expected "[4 3 1 2]" :actual "(into (quote (1 2)) [3 4])" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "into sorted-map" :expected "{1 :a, 2 :b}" :actual "(into (sorted-map) [[2 :b] [1 :a]])" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "into from map entry" :expected "[:a 1]" :actual "(into [] (first {:a 1}))" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "into xform on map" :expected "{:a 2}" :actual "(into {} (map (fn [e] [(key e) (inc (val e))])) {:a 1})" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "eduction multiple xforms" :expected "[4]" :actual "(into [] (eduction (filter odd?) (map inc) [2 3 4]))" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "->Eduction" :expected "[2 3]" :actual "(->Eduction (map inc) [1 2])" :portability :common} - {:suite "transducers / into & eduction (overlay)" :label "transduce no init uses (f)" :expected "5" :actual "(transduce (map inc) + [1 2])" :portability :common} - {:suite "transient / vector" :label "conj! then persistent!" :expected "[1 2]" :actual "(persistent! (conj! (conj! (transient []) 1) 2))" :portability :common} - {:suite "transient / vector" :label "reduce conj!" :expected "[0 1 2 3 4]" :actual "(persistent! (reduce conj! (transient []) (range 5)))" :portability :common} - {:suite "transient / vector" :label "conj! many args" :expected "[1 2 3]" :actual "(persistent! (conj! (transient [1]) 2 3))" :portability :common} - {:suite "transient / vector" :label "assoc! existing" :expected "[1 9 3]" :actual "(persistent! (assoc! (transient [1 2 3]) 1 9))" :portability :common} - {:suite "transient / vector" :label "assoc! at count grows" :expected "[1 2 3]" :actual "(persistent! (assoc! (transient [1 2]) 2 3))" :portability :common} - {:suite "transient / vector" :label "pop!" :expected "[1 2]" :actual "(persistent! (pop! (transient [1 2 3])))" :portability :common} - {:suite "transient / vector" :label "from existing vector" :expected "[1 2 3 4]" :actual "(persistent! (conj! (transient [1 2 3]) 4))" :portability :common} - {:suite "transient / vector" :label "count" :expected "3" :actual "(count (transient [1 2 3]))" :portability :common} - {:suite "transient / vector" :label "nth" :expected "2" :actual "(nth (transient [1 2 3]) 1)" :portability :common} - {:suite "transient / vector" :label "get" :expected "2" :actual "(get (transient [1 2 3]) 1)" :portability :common} - {:suite "transient / vector" :label "persistent! is a vector" :expected "true" :actual "(vector? (persistent! (transient [1])))" :portability :common} - {:suite "transient / vector" :label "transient? true" :expected "true" :actual "(transient? (transient []))" :portability :common} - {:suite "transient / vector" :label "transient? false" :expected "false" :actual "(transient? [1 2])" :portability :common} - {:suite "transient / map" :label "assoc! then persistent!" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (assoc! (transient {}) :a 1) :b 2))" :portability :common} - {:suite "transient / map" :label "assoc! many" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (transient {}) :a 1 :b 2))" :portability :common} - {:suite "transient / map" :label "dissoc!" :expected "{:b 2}" :actual "(persistent! (dissoc! (transient {:a 1 :b 2}) :a))" :portability :common} - {:suite "transient / map" :label "conj! map entry" :expected "{:a 1}" :actual "(persistent! (conj! (transient {}) [:a 1]))" :portability :common} - {:suite "transient / map" :label "from existing map" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (transient {:a 1}) :b 2))" :portability :common} - {:suite "transient / map" :label "get" :expected "1" :actual "(get (transient {:a 1}) :a)" :portability :common} - {:suite "transient / map" :label "get missing default" :expected ":x" :actual "(get (transient {:a 1}) :z :x)" :portability :common} - {:suite "transient / map" :label "contains?" :expected "true" :actual "(contains? (transient {:a 1}) :a)" :portability :common} - {:suite "transient / map" :label "count" :expected "2" :actual "(count (transient {:a 1 :b 2}))" :portability :common} - {:suite "transient / map" :label "collection key by value" :expected ":v" :actual "(get (persistent! (assoc! (transient {}) [1 2] :v)) [1 2])" :portability :common} - {:suite "transient / map" :label "persistent! is a map" :expected "true" :actual "(map? (persistent! (transient {:a 1})))" :portability :common} - {:suite "transient / map" :label "reduce build" :expected "{0 0, 1 1, 2 2}" :actual "(persistent! (reduce (fn [t i] (assoc! t i i)) (transient {}) (range 3)))" :portability :common} - {:suite "transient / set" :label "conj! dedups" :expected "#{1 2 3}" :actual "(persistent! (conj! (transient #{}) 1 2 2 3))" :portability :common} - {:suite "transient / set" :label "disj!" :expected "#{1 3}" :actual "(persistent! (disj! (transient #{1 2 3}) 2))" :portability :common} - {:suite "transient / set" :label "from existing set" :expected "#{1 3 2}" :actual "(persistent! (conj! (transient #{1 2}) 3))" :portability :common} - {:suite "transient / set" :label "contains?" :expected "true" :actual "(contains? (transient #{1 2}) 1)" :portability :common} - {:suite "transient / set" :label "count" :expected "2" :actual "(count (transient #{1 2}))" :portability :common} - {:suite "transient / set" :label "persistent! is a set" :expected "true" :actual "(set? (persistent! (transient #{1})))" :portability :common} - {:suite "transient / set" :label "map elements by value" :expected "1" :actual "(count (persistent! (conj! (transient #{}) {:a 1} (hash-map :a 1))))" :portability :common} - {:suite "transient / immutability of source" :label "source vector unchanged" :expected "true" :actual "(let [v [1 2 3] _ (persistent! (conj! (transient v) 4))] (= v [1 2 3]))" :portability :common} - {:suite "transient / immutability of source" :label "source map unchanged" :expected "true" :actual "(let [m {:a 1} _ (persistent! (assoc! (transient m) :b 2))] (= m {:a 1}))" :portability :common} - {:suite "transient / invokable lookup" :label "vector index" :expected "20" :actual "((transient [10 20 30]) 1)" :portability :common} - {:suite "transient / invokable lookup" :label "map key as fn" :expected "7" :actual "((transient {:x 7}) :x)" :portability :common} - {:suite "transient / invokable lookup" :label "map key default" :expected "99" :actual "((transient {:x 7}) :z 99)" :portability :common} - {:suite "transient / invokable lookup" :label "keyword on transient" :expected "7" :actual "(:x (transient {:x 7}))" :portability :common} - {:suite "transient / invokable lookup" :label "set membership" :expected "2" :actual "((transient #{1 2 3}) 2)" :portability :common} - {:suite "transient / invokable lookup" :label "set miss default" :expected ":no" :actual "((transient #{1 2 3}) 42 :no)" :portability :common} - {:suite "transient / invokable lookup" :label "collection key" :expected ":v" :actual "((transient {[1 2] :v}) [1 2])" :portability :common} - {:suite "transient / assoc! odd args throw" :label "map dangling key" :expected "{:a 1, :b nil}" :actual "(persistent! (assoc! (transient {}) :a 1 :b))" :portability :common} - {:suite "transient / assoc! odd args throw" :label "map lone key" :expected :throws :actual "(persistent! (assoc! (transient {}) :a))" :portability :common} - {:suite "transient / assoc! odd args throw" :label "vector dangling" :expected "[9 nil]" :actual "(persistent! (apply assoc! (transient []) [0 9 1]))" :portability :common} - {:suite "transient / assoc! odd args throw" :label "even args still ok" :expected "true" :actual "(= {:a 1, :b 2} (persistent! (assoc! (transient {}) :a 1 :b 2)))" :portability :common} - {:suite "transient / invalidation" :label "conj! after persistent!" :expected :throws :actual "(let [t (transient [])] (persistent! t) (conj! t 1))" :portability :common} - {:suite "transient / invalidation" :label "assoc! after persistent!" :expected :throws :actual "(let [t (transient {})] (persistent! t) (assoc! t :a 1))" :portability :common} - {:suite "transient / invalidation" :label "persistent! twice" :expected :throws :actual "(let [t (transient [])] (persistent! t) (persistent! t))" :portability :common} - {:suite "transient / invalidation" :label "pop! empty" :expected :throws :actual "(pop! (transient []))" :portability :common} - {:suite "transient / strictness" :label "conj! on persistent" :expected :throws :actual "(conj! [1 2] 3)" :portability :common} - {:suite "transient / strictness" :label "assoc! on persistent" :expected :throws :actual "(assoc! {:a 1} :b 2)" :portability :common} - {:suite "transient / strictness" :label "persistent! on vector" :expected :throws :actual "(persistent! [1 2])" :portability :common} - {:suite "transient / strictness" :label "persistent! on nil" :expected :throws :actual "(persistent! nil)" :portability :common} - {:suite "transient / strictness" :label "pop! on transient map" :expected :throws :actual "(pop! (transient {:a 1}))" :portability :common} - {:suite "transient / strictness" :label "dissoc! on tset" :expected :throws :actual "(dissoc! (transient #{1}) 1)" :portability :common} - {:suite "transient / strictness" :label "conj! map bad item" :expected :throws :actual "(conj! (transient {}) #{:a 1})" :portability :common} - {:suite "transient / strictness" :label "conj! no args" :expected "[]" :actual "(persistent! (conj!))" :portability :common} - {:suite "transient / strictness" :label "conj! identity" :expected "[1 2]" :actual "(conj! [1 2])" :portability :common} - {:suite "transient / strictness" :label "conj! map merges map" :expected "{:a 1, :b 2}" :actual "(persistent! (conj! (transient {:a 1}) {:b 2}))" :portability :common} - {:suite "transient / assoc! bounds" :label "assoc! existing idx" :expected "[1 9 3]" :actual "(persistent! (assoc! (transient [1 2 3]) 1 9))" :portability :common} - {:suite "transient / assoc! bounds" :label "assoc! at count grows" :expected "[1 2 3]" :actual "(persistent! (assoc! (transient [1 2]) 2 3))" :portability :common} - {:suite "transient / assoc! bounds" :label "assoc! out of bounds" :expected :throws :actual "(assoc! (transient [0 1 2]) 4 4)" :portability :common} - {:suite "transient / assoc! bounds" :label "assoc! negative" :expected :throws :actual "(assoc! (transient []) -1 0)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "nil is falsy" :expected ":f" :actual "(if nil :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "false is falsy" :expected ":f" :actual "(if false :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "zero is truthy" :expected ":t" :actual "(if 0 :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "zero float truthy" :expected ":t" :actual "(if 0.0 :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "empty string truthy" :expected ":t" :actual "(if \"\" :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "empty list truthy" :expected ":t" :actual "(if (list) :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "empty vector truthy" :expected ":t" :actual "(if [] :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "empty map truthy" :expected ":t" :actual "(if {} :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "empty set truthy" :expected ":t" :actual "(if #{} :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "number truthy" :expected ":t" :actual "(if 42 :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "string truthy" :expected ":t" :actual "(if \"x\" :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "keyword truthy" :expected ":t" :actual "(if :kw :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "symbol truthy" :expected ":t" :actual "(if (quote abc) :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "coll truthy" :expected ":t" :actual "(if [1 2] :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "map truthy" :expected ":t" :actual "(if {:a 1} :t :f)" :portability :common} - {:suite "truthiness / if (only nil & false are falsy)" :label "if no else -> nil" :expected "nil" :actual "(if false :t)" :portability :common} - {:suite "truthiness / not" :label "not nil" :expected "true" :actual "(not nil)" :portability :common} - {:suite "truthiness / not" :label "not false" :expected "true" :actual "(not false)" :portability :common} - {:suite "truthiness / not" :label "not zero" :expected "false" :actual "(not 0)" :portability :common} - {:suite "truthiness / not" :label "not empty vector" :expected "false" :actual "(not [])" :portability :common} - {:suite "truthiness / not" :label "not empty string" :expected "false" :actual "(not \"\")" :portability :common} - {:suite "truthiness / not" :label "not number" :expected "false" :actual "(not 42)" :portability :common} - {:suite "truthiness / not" :label "not true" :expected "false" :actual "(not true)" :portability :common} - {:suite "truthiness / and" :label "empty is true" :expected "true" :actual "(and)" :portability :common} - {:suite "truthiness / and" :label "single value" :expected "5" :actual "(and 5)" :portability :common} - {:suite "truthiness / and" :label "all truthy -> last" :expected "3" :actual "(and 1 2 3)" :portability :common} - {:suite "truthiness / and" :label "stops at false" :expected "false" :actual "(and 1 false 3)" :portability :common} - {:suite "truthiness / and" :label "stops at nil" :expected "nil" :actual "(and 1 nil 3)" :portability :common} - {:suite "truthiness / and" :label "false alone" :expected "false" :actual "(and false)" :portability :common} - {:suite "truthiness / and" :label "nil alone" :expected "nil" :actual "(and nil)" :portability :common} - {:suite "truthiness / and" :label "zero is truthy" :expected "0" :actual "(and 1 0)" :portability :common} - {:suite "truthiness / or" :label "empty is nil" :expected "nil" :actual "(or)" :portability :common} - {:suite "truthiness / or" :label "first truthy" :expected "1" :actual "(or 1 2)" :portability :common} - {:suite "truthiness / or" :label "skips nil/false" :expected "5" :actual "(or nil false 5)" :portability :common} - {:suite "truthiness / or" :label "all falsy -> last" :expected "false" :actual "(or nil false)" :portability :common} - {:suite "truthiness / or" :label "nil chain -> false" :expected "false" :actual "(or nil nil nil false)" :portability :common} - {:suite "truthiness / or" :label "zero is truthy" :expected "0" :actual "(or 0 1)" :portability :common} - {:suite "truthiness / or" :label "false alone" :expected "false" :actual "(or false)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "if-not false" :expected ":yes" :actual "(if-not false :yes :no)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "if-not truthy" :expected ":no" :actual "(if-not 0 :yes :no)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "when-not nil" :expected "1" :actual "(when-not nil 1)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "when-not truthy" :expected "nil" :actual "(when-not 5 1)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "boolean of nil" :expected "false" :actual "(boolean nil)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "boolean of false" :expected "false" :actual "(boolean false)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "boolean of 0" :expected "true" :actual "(boolean 0)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "boolean of value" :expected "true" :actual "(boolean :x)" :portability :common} - {:suite "truthiness / if-not & boolean" :label "true?/false?" :expected "true" :actual "(and (true? true) (false? false) (not (true? 1)))" :portability :common} - {:suite "untested / primed + division + bit ops" :label "+'" :expected "3" :actual "(+' 1 2)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "-'" :expected "3" :actual "(-' 5 2)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "*'" :expected "12" :actual "(*' 3 4)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "inc'" :expected "2.5" :actual "(inc' 1.5)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "dec'" :expected "1.5" :actual "(dec' 2.5)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "/" :expected "2" :actual "(/ 6 3)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "/ ratio-as-double" :expected "1/2" :actual "(/ 1 2)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "bit-not" :expected "-6" :actual "(bit-not 5)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "bit-and-not" :expected "4" :actual "(bit-and-not 12 10)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "bit-flip" :expected "3" :actual "(bit-flip 2 0)" :portability :common} - {:suite "untested / primed + division + bit ops" :label "unsigned-bit-shift-right" :expected "2" :actual "(unsigned-bit-shift-right 8 2)" :portability :common} - {:suite "untested / hash family" :label "hash stable" :expected "true" :actual "(= (hash :a) (hash :a))" :portability :common} - {:suite "untested / hash family" :label "hash int" :expected "true" :actual "(int? (hash [1 2]))" :portability :common} - {:suite "untested / hash family" :label "hash-combine" :expected "true" :actual "(int? (hash-combine 1 2))" :portability :common} - {:suite "untested / hash family" :label "hash-ordered-coll" :expected "true" :actual "(int? (hash-ordered-coll [1 2]))" :portability :common} - {:suite "untested / hash family" :label "hash-unordered-coll" :expected "true" :actual "(int? (hash-unordered-coll #{1}))" :portability :common} - {:suite "untested / array stubs (vectors + host buffers)" :label "make-array" :expected "[nil nil nil]" :actual "(vec (make-array Object 3))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "into-array" :expected "[1 2]" :actual "(vec (into-array [1 2]))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "to-array" :expected "[1 2]" :actual "(vec (to-array [1 2]))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aclone vec" :expected "[1 2]" :actual "(vec (aclone (int-array [1 2])))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aclone independent" :expected "[9 2]" :actual "(let [a (aclone (to-array [1 2]))] (aset a 0 9) (seq a))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset/aget" :expected "9" :actual "(let [a (to-array [1 2 3])] (aset a 0 9) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-int" :expected "7" :actual "(let [a (to-array [1 2])] (aset-int a 0 7) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-boolean" :expected "true" :actual "(let [a (to-array [1])] (aset-boolean a 0 true) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-byte" :expected "9" :actual "(let [a (to-array [0])] (aset-byte a 0 9) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-char" :expected "\\a" :actual "(let [a (to-array [0])] (aset-char a 0 \\a) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-double" :expected "1.5" :actual "(let [a (to-array [0])] (aset-double a 0 1.5) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-float" :expected "2.5" :actual "(let [a (to-array [0])] (aset-float a 0 2.5) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-long" :expected "3" :actual "(let [a (to-array [0])] (aset-long a 0 3) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "aset-short" :expected "4" :actual "(let [a (to-array [0])] (aset-short a 0 4) (aget a 0))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "boolean-array" :expected "[false false]" :actual "(vec (boolean-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "int-array" :expected "[1 2]" :actual "(vec (int-array [1 2]))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "long-array" :expected "[0 0]" :actual "(vec (long-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "double-array" :expected "[0.0 0.0]" :actual "(vec (double-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "float-array" :expected "[0.0 0.0]" :actual "(vec (float-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "short-array" :expected "[0 0]" :actual "(vec (short-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "char-array count" :expected "2" :actual "(count (char-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "byte-array bytes?" :expected "true" :actual "(bytes? (byte-array 2))" :portability :jvm} - {:suite "untested / array stubs (vectors + host buffers)" :label "bytes? not vec" :expected "false" :actual "(bytes? [1])" :portability :common} - {:suite "untested / typed coercion views" :label "booleans" :expected "(quote (true))" :actual "(booleans [true])" :portability :common} - {:suite "untested / typed coercion views" :label "doubles" :expected "[1.0]" :actual "(vec (doubles (double-array [1.0])))" :portability :jvm} - {:suite "untested / typed coercion views" :label "floats" :expected "[1.0]" :actual "(vec (floats (float-array [1.0])))" :portability :jvm} - {:suite "untested / typed coercion views" :label "ints" :expected "(quote (1))" :actual "(ints [1])" :portability :common} - {:suite "untested / typed coercion views" :label "longs" :expected "(quote (1))" :actual "(longs [1])" :portability :common} - {:suite "untested / typed coercion views" :label "shorts" :expected "(quote (1))" :actual "(shorts [1])" :portability :common} - {:suite "untested / typed coercion views" :label "chars first" :expected "\\a" :actual "(first (chars [\\a]))" :portability :common} - {:suite "untested / typed coercion views" :label "bytes view" :expected "true" :actual "(bytes? (bytes [65]))" :portability :common} - {:suite "untested / typed coercion views" :label "byte" :expected "65" :actual "(byte 65)" :portability :common} - {:suite "untested / typed coercion views" :label "short" :expected "1" :actual "(short 1)" :portability :common} - {:suite "untested / typed coercion views" :label "long truncates" :expected "1" :actual "(long 1.7)" :portability :common} - {:suite "untested / typed coercion views" :label "double" :expected "3.0" :actual "(double 3)" :portability :common} - {:suite "untested / typed coercion views" :label "float" :expected "3.0" :actual "(float 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-add" :expected "3" :actual "(unchecked-add 1 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-add-int" :expected "3" :actual "(unchecked-add-int 1 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-subtract" :expected "3" :actual "(unchecked-subtract 5 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-subtract-int" :expected "3" :actual "(unchecked-subtract-int 5 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-multiply" :expected "6" :actual "(unchecked-multiply 2 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-multiply-int" :expected "6" :actual "(unchecked-multiply-int 2 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-inc" :expected "2" :actual "(unchecked-inc 1)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-inc-int" :expected "2" :actual "(unchecked-inc-int 1)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-dec" :expected "2" :actual "(unchecked-dec 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-dec-int" :expected "2" :actual "(unchecked-dec-int 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-negate" :expected "-4" :actual "(unchecked-negate 4)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-negate-int" :expected "-4" :actual "(unchecked-negate-int 4)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-divide-int" :expected "3" :actual "(unchecked-divide-int 7 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-remainder-int" :expected "1" :actual "(unchecked-remainder-int 7 2)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-int" :expected "3" :actual "(unchecked-int 3.7)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-long" :expected "3" :actual "(unchecked-long 3.7)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-double" :expected "3.0" :actual "(unchecked-double 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-float" :expected "3.0" :actual "(unchecked-float 3)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-byte" :expected "65" :actual "(unchecked-byte 65)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-char" :expected "\\a" :actual "(unchecked-char 97)" :portability :common} - {:suite "untested / unchecked-* are plain ops" :label "unchecked-short" :expected "5" :actual "(unchecked-short 5)" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk round-trip" :expected "[1]" :actual "(let [cb (chunk-buffer 4)] (chunk-append cb 1) (chunk-first (chunk-cons (chunk cb) nil)))" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "cat transducer" :expected "[1 2 3]" :actual "(into [] cat [[1] [2 3]])" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "ensure-reduced wraps" :expected "true" :actual "(reduced? (ensure-reduced 5))" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "ensure-reduced keeps reduced" :expected "true" :actual "(reduced? (ensure-reduced (reduced 5)))" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "halt-when" :expected "4" :actual "(transduce (halt-when even?) conj [] [1 3 4 5])" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk-next exhausted" :expected "nil" :actual "(let [cb (chunk-buffer 2)] (chunk-append cb 1) (chunk-next (chunk-cons (chunk cb) nil)))" :portability :common} - {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk-rest seqable" :expected "[]" :actual "(let [cb (chunk-buffer 2)] (chunk-append cb 1) (vec (chunk-rest (chunk-cons (chunk cb) nil))))" :portability :common} - {:suite "chunked-seq / over a vector" :label "chunk-first is a 32-element block" :expected "32" :actual "(count (chunk-first (seq (vec (range 100)))))" :portability :common} - {:suite "chunked-seq / over a vector" :label "chunked-seq? true for vector seq" :expected "true" :actual "(chunked-seq? (seq (vec (range 100))))" :portability :common} - {:suite "chunked-seq / over a vector" :label "chunked-seq? false for a list seq" :expected "false" :actual "(chunked-seq? (seq (list 1 2 3)))" :portability :common} - {:suite "chunked-seq / over a vector" :label "chunk-first contents + chunk-rest boundary" :expected "[32 0 31 32]" :actual "(let [s (seq (vec (range 50))) c (chunk-first s)] [(count c) (nth c 0) (nth c 31) (first (chunk-rest s))])" :portability :common} - {:suite "chunked-seq / over a vector" :label "chunk-first window past the first block" :expected "[32 33 34 35 36 37 38 39]" :actual "(vec (chunk-first (chunk-rest (seq (vec (range 40))))))" :portability :common} - ;; --- seq-type-model divergences (allowlisted): jolt models every seq as - ;; PersistentList (eager) or LazySeq (deferred); JVM reifies a specialized class - ;; per producer. Values + laziness are correct, only (class …) differs. jolt-aei7. - {:suite "seq-type-model / specialized seq classes collapse" :label "cons over a vector" :expected "clojure.lang.PersistentList" :actual "(class (cons 1 [2 3]))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "iterate" :expected "clojure.lang.PersistentList" :actual "(class (iterate inc 0))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "range" :expected "clojure.lang.PersistentList" :actual "(class (range 5))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "repeat" :expected "clojure.lang.LazySeq" :actual "(class (repeat 3 :x))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "cycle" :expected "clojure.lang.LazySeq" :actual "(class (cycle [1 2]))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "vector seq" :expected "clojure.lang.PersistentList" :actual "(class (seq [1 2 3]))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "string seq" :expected "clojure.lang.PersistentList" :actual "(class (seq \"abc\"))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "keys" :expected "clojure.lang.PersistentList" :actual "(class (keys {:a 1 :b 2}))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "rseq" :expected "clojure.lang.PersistentList" :actual "(class (rseq [1 2 3]))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "sort" :expected "clojure.lang.PersistentList" :actual "(class (sort [3 1 2]))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "subvec" :expected "clojure.lang.PersistentVector" :actual "(class (subvec [1 2 3] 1))" :portability :common} - {:suite "seq-type-model / specialized seq classes collapse" :label "drop over a vector" :expected "clojure.lang.LazySeq" :actual "(class (drop 1 [1 2 3]))" :portability :common} - ;; --- chunking-model realization granularity (JVM-matching): a vector's seq is - ;; chunked, so forcing one element of (map f a-vector) realizes the whole first - ;; 32-block, like the JVM. - {:suite "chunking-model / realization granularity" :label "first over a chunked vector realizes the whole 32-block" :expected "32" :actual "(let [a (atom 0)] (first (map (fn [x] (swap! a inc) x) (vec (range 100)))) @a)" :portability :common} - {:suite "chunking-model / realization granularity" :label "nth 0 over a chunked vector realizes the whole 32-block" :expected "32" :actual "(let [a (atom 0)] (nth (map (fn [x] (swap! a inc) x) (vec (range 100))) 0) @a)" :portability :common} - ;; mapcat/dedupe stay lazier than the JVM at construction: jolt's (apply concat …) - ;; and sequence transformer don't force the first chunk just to build the seq - ;; (the JVM forces 5 here). Allowlisted in known-divergences.edn (jolt-mm6v). - {:suite "chunking-model / unchunked realization granularity" :label "mapcat is fully lazy at construction" :expected "0" :actual "(let [a (atom 0)] (mapcat (fn [x] (swap! a inc) [x]) (range 5)) @a)" :portability :common} - {:suite "chunking-model / unchunked realization granularity" :label "dedupe is fully lazy at construction" :expected "0" :actual "(let [a (atom 0)] (dedupe (map (fn [x] (swap! a inc) x) (range 5))) @a)" :portability :common} - ;; --- integer-box-model: narrow int values behave as integers (certified) --- - ;; jolt unifies every integer as one exact-integer type, so (byte/short/int n) - ;; produce value-correct integers — only the reified class differs (below). - {:suite "integer-box-model / narrow ints behave as integers" :label "byte = plain integer by value" :expected "true" :actual "(= (byte 5) 5)" :portability :common} - {:suite "integer-box-model / narrow ints behave as integers" :label "byte arithmetic promotes" :expected "6" :actual "(+ (byte 5) 1)" :portability :common} - {:suite "integer-box-model / narrow ints behave as integers" :label "byte is a Number" :expected "true" :actual "(instance? Number (byte 5))" :portability :common} - ;; --- integer-box-model divergences (allowlisted): no narrow box types. A Chez - ;; fixnum is an immediate identical to the plain integer (cannot be tagged), so - ;; (byte/short/int n) report Long, not Byte/Short/Integer. Value is correct. - ;; jolt-k9sw (accepted divergence). - {:suite "integer-box-model / narrow int class collapses to Long" :label "byte class" :expected "java.lang.Long" :actual "(class (byte 5))" :portability :common} - {:suite "integer-box-model / narrow int class collapses to Long" :label "short class" :expected "java.lang.Long" :actual "(class (short 5))" :portability :common} - {:suite "integer-box-model / narrow int class collapses to Long" :label "int class" :expected "java.lang.Long" :actual "(class (int 5))" :portability :common} - {:suite "integer-box-model / narrow int class collapses to Long" :label "instance? Byte is false" :expected "false" :actual "(instance? Byte (byte 5))" :portability :common} - {:suite "integer-box-model / narrow int class collapses to Long" :label "instance? Long is true" :expected "true" :actual "(instance? Long (byte 5))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class number" :expected "java.lang.Long" :actual "(class 1)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class string" :expected "java.lang.String" :actual "(class \"s\")" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class keyword" :expected "clojure.lang.Keyword" :actual "(class :k)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class nil" :expected "nil" :actual "(class nil)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "bean is the map" :expected "{:a 1}" :actual "(bean {:a 1})" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "biginteger" :expected "\"5\"" :actual "(str (biginteger 5))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy resolves nil" :expected "nil" :actual "(proxy [Object] [] (toString [] \"x\"))" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "construct-proxy throws" :expected :throws :actual "(construct-proxy nil)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "get-proxy-class throws" :expected :throws :actual "(get-proxy-class)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "init-proxy" :expected "nil" :actual "(init-proxy nil {})" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "update-proxy" :expected "nil" :actual "(update-proxy nil {})" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-mappings" :expected "{}" :actual "(proxy-mappings nil)" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-call-with-super calls" :expected "1" :actual "(proxy-call-with-super (fn [] 1) nil \"m\")" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn upper" :expected "\"ABC\"" :actual "((memfn toUpperCase) \"abc\")" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn with args" :expected "2" :actual "((memfn indexOf needle) \"hello\" \"l\")" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn length" :expected "3" :actual "((memfn length) \"abc\")" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "array-seq" :expected "(quote (1 2 3))" :actual "(array-seq (to-array [1 2 3]))" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "array-seq empty" :expected "nil" :actual "(array-seq (to-array []))" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-super throws" :expected :throws :actual "(proxy-super count [1])" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "re-groups throws" :expected :throws :actual "(re-groups (re-matcher #\"a\" \"b\"))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "re-matcher builds" :expected "false" :actual "(nil? (re-matcher #\"a\" \"abc\"))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "print-dup nil writer throws" :expected :throws :actual "(print-dup 1 nil)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "print-method nil writer throws" :expected :throws :actual "(print-method 1 nil)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "uri? string" :expected "false" :actual "(uri? \"http://x\")" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "uri? nil" :expected "false" :actual "(uri? nil)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "definterface defines" :expected "false" :actual "(var? (definterface IFoo (foo [x])))" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "enumeration-seq" :expected "(quote (1 2))" :actual "(enumeration-seq [1 2])" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "iterator-seq" :expected "(quote (1 2))" :actual "(iterator-seq [1 2])" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "seque passthrough" :expected "[1 2]" :actual "(seque [1 2])" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "delay? true" :expected "true" :actual "(delay? (delay 1))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "delay? false" :expected "false" :actual "(delay? 1)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "future-call" :expected "42" :actual "(deref (future-call (fn [] 42)))" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label ". calls String surface" :expected "3" :actual "(. \"abc\" length)" :portability :jvm} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label ".. threads members" :expected "\"ABC\"" :actual "(.. \"abc\" toUpperCase)" :portability :common} - {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "unknown String member throws" :expected :throws :actual "(. \"abc\" frobnicate)" :portability :jvm} - {:suite "untested / protocols: extend + extends?" :label "extend registers" :expected ":str" :actual "(do (defprotocol Pe (pe [x])) (extend (quote String) Pe {:pe (fn [x] :str)}) (pe \"s\"))" :portability :common} - {:suite "untested / protocols: extend + extends?" :label "extend two methods" :expected "[1 2]" :actual "(do (defprotocol P3 (pa [x]) (pb [x])) (extend (quote Long) P3 {:pa (fn [x] 1) :pb (fn [x] 2)}) [(pa 0) (pb 0)])" :portability :common} - {:suite "untested / protocols: extend + extends?" :label "extends? after extend" :expected "true" :actual "(do (defprotocol P4 (pc [x])) (extend (quote Long) P4 {:pc (fn [x] 1)}) (extends? P4 (quote Long)))" :portability :common} - {:suite "untested / protocols: extend + extends?" :label "extends? without" :expected "false" :actual "(do (defprotocol P5 (pd [x])) (extends? P5 (quote Long)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "all-ns non-empty" :expected "true" :actual "(pos? (count (all-ns)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "ns-interns sees def" :expected "true" :actual "(do (def zz 1) (pos? (count (ns-interns (quote user)))))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "ns-interns countable" :expected "true" :actual "(map? (ns-interns (quote user)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "ns-imports empty user" :expected "96" :actual "(count (ns-imports (quote user)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "reset-meta!" :expected "{:doc \"d\"}" :actual "(do (def vv 1) (reset-meta! (var vv) {:doc \"d\"}))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "prefers empty" :expected "{}" :actual "(do (defmulti mm identity) (prefers mm))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "refer-clojure" :expected "nil" :actual "(refer-clojure)" :portability :common} - {:suite "untested / ns + REPL machinery" :label "special-symbol? if" :expected "true" :actual "(special-symbol? (quote if))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "special-symbol? fn name" :expected "false" :actual "(special-symbol? (quote foo))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "destructure expands" :expected "true" :actual "(pos? (count (destructure (quote [[a b] x]))))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "seq-to-map-for-destructuring" :expected "{:a 1}" :actual "(seq-to-map-for-destructuring (quote (:a 1)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "s2m trailing map passes through" :expected "{:b 2}" :actual "(seq-to-map-for-destructuring (list {:b 2}))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "s2m unpaired key throws" :expected :throws :actual "(seq-to-map-for-destructuring (quote (:a 1 :b)))" :portability :common} - {:suite "untested / ns + REPL machinery" :label "s2m kwargs trailing map call" :expected "2" :actual "((fn [& {:keys [b]}] b) {:b 2})" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*clojure-version* major" :expected "1" :actual "(:major *clojure-version*)" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*ns* user" :expected "\"user\"" :actual "(str *ns*)" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*1 nil outside repl" :expected "nil" :actual "*1" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*2 nil" :expected "nil" :actual "*2" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*3 nil" :expected "nil" :actual "*3" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*e nil" :expected "nil" :actual "*e" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*unchecked-math*" :expected "false" :actual "*unchecked-math*" :portability :common} - {:suite "untested / ns + REPL machinery" :label "*in* bound" :expected "false" :actual "(map? *in*)" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "nfirst" :expected "[2]" :actual "(nfirst [[1 2] [3]])" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "xml-seq root" :expected "1" :actual "(count (xml-seq {:tag :a :content []}))" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "xml-seq walks" :expected "2" :actual "(count (xml-seq {:tag :a :content [{:tag :b :content []}]}))" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "comp keyword stage" :expected "[1 2]" :actual "((comp seq :content) {:content [1 2]})" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "comp three stages" :expected "4" :actual "((comp inc inc :n) {:n 2})" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "random-sample all" :expected "[1 2]" :actual "(random-sample 1.0 [1 2])" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "random-sample none" :expected "[]" :actual "(random-sample 0.0 [1 2])" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "reader-conditional builds" :expected "true" :actual "(reader-conditional? (reader-conditional (quote (:clj 1)) false))" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "->Eduction" :expected "[2 3]" :actual "(vec (->Eduction (map inc) [1 2]))" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "bound-fn calls" :expected "42" :actual "((bound-fn [] 42))" :portability :common} - {:suite "untested / misc seqs + binding machinery" :label "push/pop-thread-bindings" :expected ":ok" :actual "(do (push-thread-bindings {}) (pop-thread-bindings) :ok)" :portability :common} - {:suite "uuid / random-uuid" :label "returns a uuid" :expected "true" :actual "(uuid? (random-uuid))" :portability :common} - {:suite "uuid / random-uuid" :label "str is 36 chars" :expected "36" :actual "(count (str (random-uuid)))" :portability :common} - {:suite "uuid / random-uuid" :label "8-4-4-4-12 shape" :expected "[8 4 4 4 12]" :actual "(do (require (quote [clojure.string :as s])) (mapv count (s/split (str (random-uuid)) #\"-\")))" :portability :common} - {:suite "uuid / random-uuid" :label "version nibble is 4" :expected "\\4" :actual "(nth (str (random-uuid)) 14)" :portability :common} - {:suite "uuid / random-uuid" :label "variant nibble 8-b" :expected "true" :actual "(contains? #{\\8 \\9 \\a \\b} (nth (seq (str (random-uuid))) 19))" :portability :common} - {:suite "uuid / random-uuid" :label "distinct" :expected "10" :actual "(count (set (repeatedly 10 random-uuid)))" :portability :common} - {:suite "uuid / random-uuid" :label "all hex digits" :expected "true" :actual "(every? (fn [c] (contains? (set (seq \"0123456789abcdef-\")) c)) (seq (str (random-uuid))))" :portability :common} - {:suite "uuid / parse-uuid" :label "valid round-trips" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "uuid / parse-uuid" :label "parses to uuid" :expected "true" :actual "(uuid? (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "uuid / parse-uuid" :label "case-insensitive =" :expected "true" :actual "(= (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") (parse-uuid \"B6883C0A-0342-4007-9966-BC2DFA6B109E\"))" :portability :common} - {:suite "uuid / parse-uuid" :label "empty -> nil" :expected "nil" :actual "(parse-uuid \"\")" :portability :common} - {:suite "uuid / parse-uuid" :label "short -> nil" :expected "nil" :actual "(parse-uuid \"0\")" :portability :common} - {:suite "uuid / parse-uuid" :label "garbage -> nil" :expected "nil" :actual "(parse-uuid \"df0993\")" :portability :common} - {:suite "uuid / parse-uuid" :label "too long -> nil" :expected "nil" :actual "(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109eb\")" :portability :common} - {:suite "uuid / parse-uuid" :label "leading extra -> nil" :expected "nil" :actual "(parse-uuid \"ab6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / parse-uuid" :label "non-hex -> nil" :expected "nil" :actual "(parse-uuid \"g6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / parse-uuid" :label "bad dashes -> nil" :expected "nil" :actual "(parse-uuid \"b6883c0a00342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / parse-uuid" :label "non-string throws" :expected :throws :actual "(parse-uuid 1000)" :portability :common} - {:suite "uuid / parse-uuid" :label "keyword throws" :expected :throws :actual "(parse-uuid :key)" :portability :common} - {:suite "uuid / parse-uuid" :label "map throws" :expected :throws :actual "(parse-uuid {})" :portability :common} - {:suite "uuid / value semantics" :label "equal by value" :expected "true" :actual "(= (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "uuid / value semantics" :label "unequal differs" :expected "false" :actual "(= (random-uuid) (random-uuid))" :portability :common} - {:suite "uuid / value semantics" :label "works as map key" :expected ":v" :actual "(let [u (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")] (get {u :v} (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")))" :portability :common} - {:suite "uuid / value semantics" :label "works in a set" :expected "true" :actual "(contains? #{(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")} (parse-uuid \"B6883C0A-0342-4007-9966-BC2DFA6B109E\"))" :portability :common} - {:suite "uuid / value semantics" :label "uuid? false on string" :expected "false" :actual "(uuid? \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / value semantics" :label "uuid? false on nil" :expected "false" :actual "(uuid? nil)" :portability :common} - {:suite "uuid / #uuid reader literal" :label "reads to uuid" :expected "true" :actual "(uuid? #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / #uuid reader literal" :label "= parse-uuid" :expected "true" :actual "(= #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\" (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "uuid / #uuid reader literal" :label "str of literal" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "uuid / #uuid reader literal" :label "pr-str round-trips" :expected "\"#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"\"" :actual "(pr-str #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")" :portability :common} - {:suite "vector / construct & predicate" :label "literal" :expected "[1 2 3]" :actual "[1 2 3]" :portability :common} - {:suite "vector / construct & predicate" :label "vector" :expected "[1 2 3]" :actual "(vector 1 2 3)" :portability :common} - {:suite "vector / construct & predicate" :label "vector zero args" :expected "[]" :actual "(vector)" :portability :common} - {:suite "vector / construct & predicate" :label "vec from list" :expected "[1 2 3]" :actual "(vec (list 1 2 3))" :portability :common} - {:suite "vector / construct & predicate" :label "vec from range" :expected "[0 1 2]" :actual "(vec (range 3))" :portability :common} - {:suite "vector / construct & predicate" :label "vec of map yields entries" :expected "[[:a 1]]" :actual "(vec {:a 1})" :portability :common} - {:suite "vector / construct & predicate" :label "vector? true" :expected "true" :actual "(vector? [1])" :portability :common} - {:suite "vector / construct & predicate" :label "vector? false on list" :expected "false" :actual "(vector? (list 1))" :portability :common} - {:suite "vector / construct & predicate" :label "vector = list elts" :expected "true" :actual "(= [1 2 3] (list 1 2 3))" :portability :common} - {:suite "vector / access" :label "nth" :expected ":b" :actual "(nth [:a :b :c] 1)" :portability :common} - {:suite "vector / access" :label "nth default" :expected ":x" :actual "(nth [:a] 5 :x)" :portability :common} - {:suite "vector / access" :label "get by index" :expected ":b" :actual "(get [:a :b] 1)" :portability :common} - {:suite "vector / access" :label "get out of range nil" :expected "nil" :actual "(get [:a] 5)" :portability :common} - {:suite "vector / access" :label "get default" :expected ":x" :actual "(get [:a] 5 :x)" :portability :common} - {:suite "vector / access" :label "first" :expected "1" :actual "(first [1 2 3])" :portability :common} - {:suite "vector / access" :label "last" :expected "3" :actual "(last [1 2 3])" :portability :common} - {:suite "vector / access" :label "peek is last" :expected "3" :actual "(peek [1 2 3])" :portability :common} - {:suite "vector / access" :label "count" :expected "3" :actual "(count [1 2 3])" :portability :common} - {:suite "vector / access" :label "contains? index" :expected "true" :actual "(contains? [:a :b] 1)" :portability :common} - {:suite "vector / access" :label "contains? past end" :expected "false" :actual "(contains? [:a] 3)" :portability :common} - {:suite "vector / access" :label "vector as fn" :expected ":b" :actual "([:a :b :c] 1)" :portability :common} - {:suite "vector / access" :label "vector-in-local as fn" :expected "20" :actual "(let [v [10 20 30]] (v 1))" :portability :common} - {:suite "vector / access" :label "keyword-in-local as fn" :expected "7" :actual "(let [k :a] (k {:a 7}))" :portability :common} - {:suite "vector / access" :label "meta vector as fn" :expected "10" :actual "((with-meta [10 20] {:k 1}) 0)" :portability :common} - {:suite "vector / update (persistent)" :label "conj appends" :expected "[1 2 3]" :actual "(conj [1 2] 3)" :portability :common} - {:suite "vector / update (persistent)" :label "conj many" :expected "[1 2 3 4]" :actual "(conj [1 2] 3 4)" :portability :common} - {:suite "vector / update (persistent)" :label "assoc index" :expected "[1 9 3]" :actual "(assoc [1 2 3] 1 9)" :portability :common} - {:suite "vector / update (persistent)" :label "assoc at count appends" :expected "[1 2 3]" :actual "(assoc [1 2] 2 3)" :portability :common} - {:suite "vector / update (persistent)" :label "update" :expected "[1 3 3]" :actual "(update [1 2 3] 1 inc)" :portability :common} - {:suite "vector / update (persistent)" :label "pop drops last" :expected "[1 2]" :actual "(pop [1 2 3])" :portability :common} - {:suite "vector / update (persistent)" :label "subvec start end" :expected "[2 3]" :actual "(subvec [1 2 3 4] 1 3)" :portability :common} - {:suite "vector / update (persistent)" :label "subvec to end" :expected "[3 4]" :actual "(subvec [1 2 3 4] 2)" :portability :common} - {:suite "vector / update (persistent)" :label "mapv" :expected "[2 3 4]" :actual "(mapv inc [1 2 3])" :portability :common} - {:suite "vector / update (persistent)" :label "filterv" :expected "[2 4]" :actual "(filterv even? [1 2 3 4])" :portability :common} - {:suite "vector / immutability & nesting" :label "conj does not mutate" :expected "true" :actual "(let [v [1 2] w (conj v 3)] (and (= v [1 2]) (= w [1 2 3])))" :portability :common} - {:suite "vector / immutability & nesting" :label "assoc does not mutate" :expected "true" :actual "(let [v [1 2 3] w (assoc v 0 9)] (and (= v [1 2 3]) (= w [9 2 3])))" :portability :common} - {:suite "vector / immutability & nesting" :label "get-in" :expected "2" :actual "(get-in [[1 2] [3 4]] [0 1])" :portability :common} - {:suite "vector / immutability & nesting" :label "assoc-in" :expected "[[1 9]]" :actual "(assoc-in [[1 2]] [0 1] 9)" :portability :common} - {:suite "vector / immutability & nesting" :label "update-in" :expected "[[1 3]]" :actual "(update-in [[1 2]] [0 1] inc)" :portability :common} - {:suite "vector / immutability & nesting" :label "large vector nth" :expected "1500" :actual "(nth (vec (range 2000)) 1500)" :portability :common} - {:suite "vector / immutability & nesting" :label "large vector count" :expected "2000" :actual "(count (vec (range 2000)))" :portability :common} - {:suite "vector / immutability & nesting" :label "large conj immutable" :expected "true" :actual "(let [v (vec (range 1000)) w (conj v :end)] (and (= 1000 (count v)) (= 1001 (count w))))" :portability :common} - {:suite "vector / bulk build boundaries" :label "count at 1025" :expected "1025" :actual "(count (vec (range 1025)))" :portability :common} - {:suite "vector / bulk build boundaries" :label "into = vec at 1025" :expected "true" :actual "(= (vec (range 1025)) (into [] (range 1025)))" :portability :common} - {:suite "vector / bulk build boundaries" :label "nth at leaf boundary" :expected "32" :actual "(nth (vec (range 1025)) 32)" :portability :common} - {:suite "vector / bulk build boundaries" :label "nth at root boundary" :expected "1024" :actual "(nth (vec (range 1025)) 1024)" :portability :common} - {:suite "vector / bulk build boundaries" :label "vec=into at 33" :expected "true" :actual "(= (vec (range 33)) (into [] (range 33)))" :portability :common} - {:suite "vector / bulk build boundaries" :label "conj after bulk 1024" :expected "1025" :actual "(count (conj (vec (range 1024)) :x))" :portability :common} - {:suite "vector / bulk build boundaries" :label "conj-after reads back" :expected ":x" :actual "(nth (conj (vec (range 1024)) :x) 1024)" :portability :common} - {:suite "vector / bulk build boundaries" :label "assoc into bulk vec" :expected "9" :actual "(nth (assoc (vec (range 1025)) 1000 9) 1000)" :portability :common} - {:suite "vector / bulk build boundaries" :label "into onto non-empty" :expected "[0 1 2 0 1]" :actual "(into (vec (range 3)) (range 2))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "postwalk-replace symbol keys in a list" :expected "(quote (+ 2 2))" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {(quote x) 2} (quote (+ x x))))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "postwalk descends a list" :expected "[:a :a]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk (fn [n] (if (symbol? n) :a n)) (quote (x y))))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "prewalk-replace in a list" :expected "(quote (* 3 3))" :actual "(do (require (quote [clojure.walk :as w])) (w/prewalk-replace {(quote *) (quote *) (quote y) 3} (quote (* y y))))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "nested list + vector" :expected "[1 [2 1]]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {:a 1 :b 2} (quote (:a [:b :a]))))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "postwalk-replace in a vector" :expected "[:one 2 :one]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {1 :one} [1 2 1]))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "keywordize-keys still works" :expected "{:a 1}" :actual "(do (require (quote [clojure.walk :as w])) (w/keywordize-keys {\"a\" 1}))" :portability :common} - {:suite "clojure.walk / lists + seqs" :label "apply-template substitutes" :expected "(quote (+ 1 2))" :actual "(do (require (quote [clojure.template :as t])) (t/apply-template (quote [x y]) (quote (+ x y)) (quote (1 2))))" :portability :common} - {:suite "clojure.walk / records keep their type" :label "postwalk preserves record type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (w/postwalk identity (->R 1))))" :portability :common} - {:suite "clojure.walk / records keep their type" :label "postwalk still walks record fields" :expected "2" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (:a (w/postwalk (fn [x] (if (number? x) (inc x) x)) (->R 1))))" :portability :common} - {:suite "clojure.walk / records keep their type" :label "instance? survives a walk" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (instance? R (w/postwalk identity (->R 1))))" :portability :common} - {:suite "clojure.walk / records keep their type" :label "a record nested in a map keeps its type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (:r (w/postwalk identity {:r (->R 1)}))))" :portability :common} - {:suite "clojure.walk / records keep their type" :label "prewalk preserves record type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (w/prewalk identity (->R 1))))" :portability :common} - {:suite "reader / auto-resolved keywords" :label "::kw is namespace-qualified" :expected "true" :actual "(some? (namespace ::foo))" :portability :common} - {:suite "reader / auto-resolved keywords" :label "::kw keeps its name" :expected "\"foo\"" :actual "(name ::foo)" :portability :common} - {:suite "reader / auto-resolved keywords" :label "::kw resolves to the current ns" :expected "true" :actual "(= ::a ::a)" :portability :common} - {:suite "clojure.edn / reader opts" :label ":default receives the tag as a symbol" :expected "[true \"foo\" 5]" :actual "(do (require (quote [clojure.edn :as edn])) (let [r (edn/read-string {:default (fn [t v] [t v])} \"#foo 5\")] [(symbol? (first r)) (name (first r)) (second r)]))" :portability :common} - {:suite "metadata / lazy seqs carry meta" :label "with-meta on a lazy seq" :expected "{:k 1}" :actual "(meta (with-meta (map inc [1 2 3]) {:k 1}))" :portability :common} - {:suite "dynamic vars / *print-meta*" :label "*print-meta* is a bindable dynamic var" :expected "true" :actual "(binding [*print-meta* true] (true? *print-meta*))" :portability :common} - {:suite "tagged literals / value equality" :label "equal tag+form are =" :expected "true" :actual "(= (tagged-literal (quote x) [1 2]) (tagged-literal (quote x) [1 2]))" :portability :common} - {:suite "tagged literals / value equality" :label "different tag is not =" :expected "false" :actual "(= (tagged-literal (quote x) [1]) (tagged-literal (quote y) [1]))" :portability :common} - {:suite "tagged literals / value equality" :label "duplicate literal keys throw at read (same form twice)" :expected :throws :actual "(count {(tagged-literal (quote x) [1]) :a (tagged-literal (quote x) [1]) :b})" :portability :common} - {:suite "interop / clojure.lang interfaces" :label "vector is IObj" :expected "true" :actual "(instance? clojure.lang.IObj [1])" :portability :jvm} - {:suite "interop / clojure.lang interfaces" :label "map entry is IMapEntry" :expected "true" :actual "(instance? clojure.lang.IMapEntry (first {:a 1}))" :portability :jvm} - {:suite "interop / clojure.lang interfaces" :label "record is IRecord" :expected "true" :actual "(do (defrecord R [a]) (instance? clojure.lang.IRecord (->R 1)))" :portability :jvm} - {:suite "interop / clojure.lang interfaces" :label "number is not IObj" :expected "false" :actual "(instance? clojure.lang.IObj 5)" :portability :jvm} - {:suite "reader / default data readers" :label "#inst is in default-data-readers" :expected "true" :actual "(boolean (get default-data-readers (quote inst)))" :portability :common} - {:suite "conformance / CRITICAL: lazy sequences" :label "self-ref lazy-cat fib" :expected "[0 1 1 2 3 5 8 13 21 34]" :actual "(do (def fib-seq (lazy-cat [0 1] (map + (rest fib-seq) fib-seq))) (take 10 fib-seq))" :portability :common} - {:suite "conformance / CRITICAL: multi-collection map" :label "map two colls" :expected "[11 22 33]" :actual "(map + [1 2 3] [10 20 30])" :portability :common} - {:suite "conformance / CRITICAL: multi-collection map" :label "map three colls" :expected "[12 24 36]" :actual "(map + [1 2 3] [10 20 30] [1 2 3])" :portability :common} - {:suite "conformance / CRITICAL: multi-collection map" :label "map uneven (shortest)" :expected "[[1 :a] [2 :b]]" :actual "(map vector [1 2 3] [:a :b])" :portability :common} - {:suite "conformance / CRITICAL: multi-collection map" :label "map over range+vec" :expected "[1 3 5]" :actual "(map + (range 3) [1 2 3])" :portability :common} - {:suite "conformance / CRITICAL: multi-collection map" :label "map fn list arg" :expected "[2 3 4]" :actual "(map inc (list 1 2 3))" :portability :common} - {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "iterate" :expected "[0 1 2 3 4]" :actual "(take 5 (iterate inc 0))" :portability :common} - {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "iterate double" :expected "[1 2 4 8 16]" :actual "(take 5 (iterate (fn [x] (* 2 x)) 1))" :portability :common} - {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "range over inf map" :expected "[1 2 3]" :actual "(take 3 (map inc (range)))" :portability :common} - {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "count of take" :expected "100" :actual "(count (take 100 (range)))" :portability :common} - {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "last of take" :expected "5" :actual "(last (take 5 (iterate inc 1)))" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "map as fn miss" :expected "nil" :actual "({:a 1} :z)" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "map as fn default" :expected "99" :actual "({:a 1} :z 99)" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "set literal computed" :expected "true" :actual "(= #{1 2} #{(inc 0) 2})" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "empty set literal" :expected "true" :actual "(empty? #{})" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "set literal count" :expected "3" :actual "(count #{1 2 3})" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "set literal in let" :expected "true" :actual "(let [x 5] (= #{5 6} #{x (inc x)}))" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "set? true" :expected "true" :actual "(set? #{1 2 3})" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "set? false" :expected "false" :actual "(set? [1 2])" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "disj one" :expected "#{1 3}" :actual "(disj #{1 2 3} 2)" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "disj many" :expected "#{1}" :actual "(disj #{1 2 3} 2 3)" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "disj absent" :expected "#{1 2}" :actual "(disj #{1 2} 5)" :portability :common} - {:suite "conformance / CRITICAL: collections as IFn" :label "map fn over coll" :expected "[1 3]" :actual "(map {:a 1 :b 3} [:a :b])" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "vec of map-result" :expected "[2 3 4]" :actual "(vec (map inc [1 2 3]))" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "vec of range" :expected "[0 1 2 3 4]" :actual "(vec (range 5))" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into vec" :expected "[1 2 3 4 5 6]" :actual "(into [1 2 3] [4 5 6])" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into vec from lazy" :expected "[2 3 4]" :actual "(into [] (map inc [1 2 3]))" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into map pairs" :expected "{:a 1, :b 2}" :actual "(into {} [[:a 1] [:b 2]])" :portability :common} - {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into map onto map" :expected "{:a 1, :b 2, :c 3}" :actual "(into {:a 1} [[:b 2] [:c 3]])" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map vec is seq" :expected "true" :actual "(seq? (map inc [1 2 3]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map vec not vector" :expected "false" :actual "(vector? (map inc [1 2 3]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "filter vec is seq" :expected "true" :actual "(seq? (filter odd? [1 2 3]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "take vec is seq" :expected "true" :actual "(seq? (take 2 [1 2 3]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map over set" :expected "true" :actual "(= #{2 3 4} (set (map inc #{1 2 3})))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "filter over map ev" :expected "[[:b 2]]" :actual "(filter (fn [[k v]] (> v 1)) {:a 1 :b 2})" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "cons cons lazy" :expected "[1 2 3]" :actual "(cons 1 (cons 2 (lazy-seq (cons 3 nil))))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "next empty lazy" :expected "nil" :actual "(next (take 1 [1]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "drop vec is seq" :expected "true" :actual "(seq? (drop 1 [1 2 3]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "distinct vec is seq" :expected "true" :actual "(seq? (distinct [1 1 2]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map-indexed is seq" :expected "true" :actual "(seq? (map-indexed vector [1 2]))" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "nth lazy false elem" :expected "false" :actual "(nth (map identity [false 1 2]) 0)" :portability :common} - {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "nth lazy past false" :expected "2" :actual "(nth (drop 1 (list false 1 2)) 1)" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr nested seq" :expected "[1 2 3]" :actual "(let [[a [b c]] [1 [2 3]]] [a b c])" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr rest+as" :expected "[1 [2 3] [1 2 3]]" :actual "(let [[a & r :as all] [1 2 3]] [a r all])" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr map :keys" :expected "[1 2]" :actual "(let [{:keys [a b]} {:a 1 :b 2}] [a b])" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr map :or" :expected "[1 99]" :actual "(let [{:keys [a b] :or {b 99}} {:a 1}] [a b])" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr map :strs" :expected "[1 2]" :actual "(let [{:strs [a b]} {\"a\" 1 \"b\" 2}] [a b])" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr nested map" :expected "5" :actual "(let [{{:keys [x]} :pos} {:pos {:x 5}}] x)" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr fn-param map" :expected "3" :actual "((fn [{:keys [a b]}] (+ a b)) {:a 1 :b 2})" :portability :common} - {:suite "conformance / HIGH: destructuring" :label "destr let map key" :expected "1" :actual "(let [{a :a} {:a 1}] a)" :portability :common} - {:suite "conformance / HIGH: update / assoc-in on map literals" :label "update extra args" :expected "{:a 111}" :actual "(update {:a 1} :a + 10 100)" :portability :common} - {:suite "conformance / HIGH: update / assoc-in on map literals" :label "get-in" :expected "1" :actual "(get-in {:a {:b {:c 1}}} [:a :b :c])" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native mod floored" :expected "2" :actual "(mod -7 3)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native rem truncated" :expected "-1" :actual "(rem -7 3)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native unary div" :expected "1/2" :actual "(/ 2)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native chained div" :expected "1" :actual "(/ 6 3 2)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native bit-and" :expected "8" :actual "(bit-and 12 10)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native bit-xor" :expected "6" :actual "(bit-xor 12 10)" :portability :common} - {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native shifts" :expected "[16 2]" :actual "[(bit-shift-left 4 2) (bit-shift-right 8 2)]" :portability :common} - {:suite "conformance / multimethod preferences" :label "prefer-method breaks tie" :expected ":rect" :actual "(do (derive :cm/sq :cm/rect) (derive :cm/sq :cm/shape) (defmulti cmf identity) (defmethod cmf :cm/rect [x] :rect) (defmethod cmf :cm/shape [x] :shape) (prefer-method cmf :cm/rect :cm/shape) (cmf :cm/sq))" :portability :common} - {:suite "conformance / HIGH: str semantics" :label "str concat nil" :expected "\"a1\"" :actual "(str \"a\" 1 nil)" :portability :common} - {:suite "conformance / HIGH: str semantics" :label "str keyword" :expected "\":b\"" :actual "(str :b)" :portability :common} - {:suite "conformance / HIGH: str semantics" :label "str symbol" :expected "\"foo\"" :actual "(str (quote foo))" :portability :common} - {:suite "conformance / HIGH: str semantics" :label "str mixed" :expected "\"a:b1\"" :actual "(str \"a\" :b 1)" :portability :common} - {:suite "conformance / HIGH: str semantics" :label "str seq" :expected "\"[1 2 3]\"" :actual "(str [1 2 3])" :portability :common} - {:suite "conformance / HIGH: dispatch" :label "multimethod" :expected "9" :actual "(do (defmulti area :shape) (defmethod area :sq [s] (* (:s s) (:s s))) (area {:shape :sq :s 3}))" :portability :common} - {:suite "conformance / HIGH: dispatch" :label "multimethod default" :expected ":def" :actual "(do (defmulti f identity) (defmethod f :default [x] :def) (f 99))" :portability :common} - {:suite "conformance / HIGH: dispatch" :label "protocol on record" :expected "16" :actual "(do (defprotocol Sh (ar [s])) (defrecord Sq [side] Sh (ar [_] (* side side))) (ar (->Sq 4)))" :portability :common} - {:suite "conformance / HIGH: dispatch" :label "deftype inline methods" :expected "7" :actual "(do (defprotocol Pi (mi [x])) (deftype Ti [v] Pi (mi [x] v)) (mi (->Ti 7)))" :portability :common} - {:suite "conformance / HIGH: dispatch" :label "deftype two protocols" :expected "[1 2]" :actual "(do (defprotocol Pa (ma [x])) (defprotocol Pb (mb [x])) (deftype Tab [a b] Pa (ma [x] a) Pb (mb [x] b)) (let [t (->Tab 1 2)] [(ma t) (mb t)]))" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var-get + call" :expected "2" :actual "((var-get (var inc)) 1)" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var? true" :expected "true" :actual "(var? (var map))" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var? false" :expected "false" :actual "(var? 5)" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "intern + find-var" :expected "41" :actual "(do (intern (quote user) (quote iv) 41) (var-get (find-var (quote user/iv))))" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "alter-var-root rest args" :expected "11" :actual "(do (def avr 1) (alter-var-root (var avr) + 4 6) avr)" :portability :common} - {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "alter-meta! + meta" :expected "7" :actual "(do (def amv 1) (alter-meta! (var amv) assoc :k 7) (:k (meta (var amv))))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "find-ns + ns-name" :expected "(quote clojure.core)" :actual "(ns-name (find-ns (quote clojure.core)))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "find-ns absent" :expected "nil" :actual "(find-ns (quote no.such.ns))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "create-ns + find" :expected "true" :actual "(do (create-ns (quote made.ns)) (some? (find-ns (quote made.ns))))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "remove-ns" :expected "nil" :actual "(do (create-ns (quote gone.ns)) (remove-ns (quote gone.ns)) (find-ns (quote gone.ns)))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "the-ns of symbol" :expected "(quote user)" :actual "(ns-name (the-ns (quote user)))" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "ns-resolve + call" :expected "3" :actual "((var-get (ns-resolve (quote clojure.core) (quote inc))) 2)" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "resolve + call" :expected "3" :actual "((var-get (resolve (quote inc))) 2)" :portability :common} - {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "resolve absent" :expected "nil" :actual "(resolve (quote no-such-sym-xyz))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "get-method + call" :expected "1" :actual "(do (defmulti t6f :k) (defmethod t6f :a [x] 1) ((get-method t6f :a) {:k :a}))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "remove-method" :expected "nil" :actual "(do (defmulti t6g :k) (defmethod t6g :b [x] 2) (remove-method t6g :b) (get (methods t6g) :b))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "remove-all-methods" :expected "nil" :actual "(do (defmulti t6h :k) (defmethod t6h :c [x] 3) (remove-all-methods t6h) (get (methods t6h) :c))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "prefer-method records" :expected "true" :actual "(do (defmulti t6p identity) (prefer-method t6p :rect :shape) (contains? (get (prefers t6p) :rect) :shape))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "instance? deftype" :expected "true" :actual "(do (deftype T6i [a]) (instance? T6i (->T6i 1)))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "instance? String" :expected "true" :actual "(instance? String \"s\")" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "locking evals body" :expected "3" :actual "(locking :anything (+ 1 2))" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "locking evals monitor" :expected "[3 1]" :actual "(let [a (atom 0)] [(locking (swap! a inc) 3) @a])" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "defonce keeps first" :expected "5" :actual "(do (defonce d6o 5) (defonce d6o 9) d6o)" :portability :common} - {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "read-string + eval" :expected "3" :actual "(eval (read-string \"(+ 1 2)\"))" :portability :common} - {:suite "conformance / uuid" :label "uuid as map key" :expected ":v" :actual "(get {(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") :v} (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "parse-long bad" :expected "nil" :actual "(parse-long \"4.2\")" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "update-keys" :expected "{\"a\" 1}" :actual "(update-keys {:a 1} name)" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "update-vals" :expected "{:a 2}" :actual "(update-vals {:a 1} inc)" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "partition pad" :expected "[[0 1 2 3] [4 5 6 7] [8 9 :a]]" :actual "(partition 4 4 [:a] (range 10))" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "with-redefs" :expected "[42 1]" :actual "(do (defn cwr [] 1) [(with-redefs [cwr (fn [] 42)] (cwr)) (cwr)])" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "macroexpand" :expected "true" :actual "(= (quote if) (first (macroexpand (quote (when-not false 1)))))" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "require bare symbol" :expected "\"a,b\"" :actual "(do (require (quote clojure.string)) (clojure.string/join \",\" [\"a\" \"b\"]))" :portability :common} - {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "ns-publics lookup" :expected "true" :actual "(do (def cnp 7) (some? (get (ns-publics (quote user)) (quote cnp))))" :portability :common} - {:suite "conformance / #inst + syntax-quote literal collapse (spec 2.4/2.3)" :label "inst partial = full" :expected "true" :actual "(= #inst \"2020\" #inst \"2020-01-01T00:00:00Z\")" :portability :common} - {:suite "conformance / #inst + syntax-quote literal collapse (spec 2.4/2.3)" :label "sq number collapse" :expected "42" :actual "``42" :portability :common} - {:suite "conformance / vars replace the root-env leak" :label "compare total order" :expected "[-1 0 1]" :actual "[(compare nil 1) (compare :a :a) (compare \"b\" \"a\")]" :portability :common} - {:suite "conformance / vars replace the root-env leak" :label "any? anything" :expected "true" :actual "(and (any? nil) (any? 1) (any? :k))" :portability :common} - {:suite "conformance / vars replace the root-env leak" :label "macroexpand-1 when" :expected "2" :actual "(count (rest (macroexpand-1 (quote (when true 1)))))" :portability :common} - {:suite "conformance / HIGH: aliased namespace calls" :label "require :as alias" :expected "\"1,2,3\"" :actual "(do (require (quote [clojure.string :as s])) (s/join \",\" [1 2 3]))" :portability :common} - {:suite "conformance / HIGH: aliased namespace calls" :label "ns form + alias" :expected "\"HI\"" :actual "(do (ns my.a (:require [clojure.string :as s])) (s/upper-case \"hi\"))" :portability :common} - {:suite "conformance / HIGH: aliased namespace calls" :label "ns :use refers" :expected "42" :actual "(do (ns src.u) (def helper 42) (ns dst.u (:use [src.u])) helper)" :portability :common} - {:suite "conformance / MED: missing core fns" :label "subvec" :expected "[2 3]" :actual "(subvec [1 2 3 4 5] 1 3)" :portability :common} - {:suite "conformance / MED: missing core fns" :label "subvec to-end" :expected "[3 4 5]" :actual "(subvec [1 2 3 4 5] 2)" :portability :common} - {:suite "conformance / MED: missing core fns" :label "reduce-kv" :expected "{:a 2, :b 3}" :actual "(reduce-kv (fn [m k v] (assoc m k (inc v))) {} {:a 1 :b 2})" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "reduce over map" :expected "6" :actual "(reduce (fn [a [k v]] (+ a v)) 0 {:a 1 :b 2 :c 3})" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "into transform map" :expected "{:a 2, :b 3}" :actual "(into {} (map (fn [[k v]] [k (inc v)]) {:a 1 :b 2}))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "filter over map" :expected "true" :actual "(= [[:b 2]] (filterv (fn [[k v]] (> v 1)) {:a 1 :b 2}))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "tree-seq" :expected "[1 2 3]" :actual "(map (fn [x] x) (filter (complement coll?) (tree-seq coll? seq [1 [2 [3]]])))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "key/val" :expected "true" :actual "(let [e (first {:k 9})] (and (= :k (key e)) (= 9 (val e))))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "nat-int?" :expected "true" :actual "(and (nat-int? 0) (nat-int? 5) (not (nat-int? -1)))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "list* prepend" :expected "[1 2 3 4]" :actual "(list* 1 2 [3 4])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "cycle" :expected "[1 2 3 1 2 3 1]" :actual "(take 7 (cycle [1 2 3]))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "partition-all" :expected "[[1 2] [3 4] [5]]" :actual "(partition-all 2 [1 2 3 4 5])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "reductions init" :expected "[0 1 3 6]" :actual "(reductions + 0 [1 2 3])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "dedupe" :expected "[1 2 3 1]" :actual "(dedupe [1 1 2 3 3 1])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "partition-by odd?" :expected "[[1 1] [2] [3 3]]" :actual "(partition-by odd? [1 1 2 3 3])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "reductions inf" :expected "[0 1 3 6]" :actual "(take 4 (reductions + (range)))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "tree-seq strict" :expected "10" :actual "(reduce + 0 (filter (complement coll?) (tree-seq coll? seq [1 [2 [3 4]]])))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "case nil + default" :expected "[:nilr :def]" :actual "(let [f (fn [x] (case x 1 :one nil :nilr :def))] [(f nil) (f 9)])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "case collection consts" :expected "[:v :m :s]" :actual "(let [f (fn [x] (case x [1 2] :v {:a 1} :m #{3} :s :def))] [(f [1 2]) (f {:a 1}) (f #{3})])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "seq of nil-first" :expected "true" :actual "(boolean (seq (cons nil (list 1))))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "reverse nil elem" :expected "[2 nil 1]" :actual "(vec (reverse (list 1 nil 2)))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "map non-seqable throws" :expected "true" :actual "(try (doall (map inc 5)) false (catch Throwable _ true))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "keep-indexed" :expected "[:b :d]" :actual "(keep-indexed (fn [i x] (if (odd? i) x)) [:a :b :c :d])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(map-indexed (fn [i x] [i x]) [:a :b])" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "trampoline" :expected ":done" :actual "(do (defn a [n] (if (zero? n) :done (fn [] (a (dec n))))) (trampoline a 5))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "format" :expected "\"1-x\"" :actual "(format \"%d-%s\" 1 \"x\")" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "read-string" :expected "(quote (+ 1 2))" :actual "(read-string \"(+ 1 2)\")" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (= n 0) true (od? (dec n)))) (od? [n] (if (= n 0) false (ev? (dec n))))] (ev? 10))" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "doseq side" :expected "[1 2 3]" :actual "(do (def a (atom [])) (doseq [x [1 2 3]] (swap! a conj x)) @a)" :portability :common} - {:suite "conformance / iterating maps yields entries" :label "doseq nested" :expected "4" :actual "(do (def c (atom 0)) (doseq [x [1 2] y [10 20]] (swap! c inc)) @c)" :portability :common} - {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy filter inf" :expected "[1 3 5 7 9]" :actual "(take 5 (filter odd? (range)))" :portability :common} - {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy take-while inf" :expected "[0 1 2 3 4]" :actual "(take-while (fn [x] (< x 5)) (range))" :portability :common} - {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy remove inf" :expected "[0 2 4 6 8]" :actual "(take 5 (remove odd? (range)))" :portability :common} - {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "filter finite" :expected "[2 4]" :actual "(filter even? [1 2 3 4 5])" :portability :common} - {:suite "conformance / atoms (full support)" :label "swap! args" :expected "7" :actual "(do (def a (atom 1)) (swap! a + 2 4) @a)" :portability :common} - {:suite "conformance / atoms (full support)" :label "reset! ret" :expected "9" :actual "(do (def a (atom 1)) (reset! a 9))" :portability :common} - {:suite "conformance / atoms (full support)" :label "compare-and-set!" :expected "true" :actual "(do (def a (atom 1)) (compare-and-set! a 1 2))" :portability :common} - {:suite "conformance / atoms (full support)" :label "compare-and-set! no" :expected "false" :actual "(do (def a (atom 1)) (compare-and-set! a 5 2))" :portability :common} - {:suite "conformance / atoms (full support)" :label "swap-vals!" :expected "[1 2]" :actual "(do (def a (atom 1)) (swap-vals! a inc))" :portability :common} - {:suite "conformance / atoms (full support)" :label "reset-vals!" :expected "[1 9]" :actual "(do (def a (atom 1)) (reset-vals! a 9))" :portability :common} - {:suite "conformance / atoms (full support)" :label "atom map swap" :expected "{:a 1, :b 2}" :actual "(do (def a (atom {:a 1})) (swap! a assoc :b 2) @a)" :portability :common} - {:suite "conformance / atoms (full support)" :label "add-watch" :expected "[:k 1 2]" :actual "(do (def lg (atom nil)) (def a (atom 1)) (add-watch a :k (fn [k r o n] (reset! lg [k o n]))) (swap! a inc) @lg)" :portability :common} - {:suite "conformance / atoms (full support)" :label "atom validator" :expected "5" :actual "(do (def a (atom 1 :validator pos?)) (reset! a 5) @a)" :portability :common} - {:suite "conformance / atoms (full support)" :label "instance? Atom" :expected "true" :actual "(instance? clojure.lang.Atom (atom 1))" :portability :jvm} - {:suite "conformance / volatiles / delays" :label "volatile" :expected "2" :actual "(do (def v (volatile! 1)) (vreset! v 2) @v)" :portability :common} - {:suite "conformance / volatiles / delays" :label "vswap!" :expected "2" :actual "(do (def v (volatile! 1)) (vswap! v inc) @v)" :portability :common} - {:suite "conformance / volatiles / delays" :label "delay force" :expected "3" :actual "(force (delay (+ 1 2)))" :portability :common} - {:suite "conformance / volatiles / delays" :label "delay deref once" :expected "1" :actual "(do (def c (atom 0)) (def d (delay (swap! c inc))) @d @d @c)" :portability :common} - {:suite "conformance / volatiles / delays" :label "realized? delay" :expected "true" :actual "(do (def d (delay 1)) @d (realized? d))" :portability :common} - {:suite "conformance / volatiles / delays" :label "realized? not" :expected "false" :actual "(realized? (delay 1))" :portability :common} - {:suite "conformance / numbers / math" :label "quot neg" :expected "-2" :actual "(quot -7 3)" :portability :common} - {:suite "conformance / numbers / math" :label "bit ops" :expected "[4 14 10]" :actual "[(bit-and 12 6) (bit-or 12 6) (bit-xor 12 6)]" :portability :common} - {:suite "conformance / numbers / math" :label "bit-shift" :expected "[8 2]" :actual "[(bit-shift-left 1 3) (bit-shift-right 8 2)]" :portability :common} - {:suite "conformance / numbers / math" :label "Math/sqrt" :expected "3.0" :actual "(Math/sqrt 9)" :portability :jvm} - {:suite "conformance / numbers / math" :label "Math/pow" :expected "8.0" :actual "(Math/pow 2 3)" :portability :jvm} - {:suite "conformance / numbers / math" :label "min-key" :expected "1" :actual "(min-key abs 1 -2 3)" :portability :common} - {:suite "conformance / numbers / math" :label "max-key" :expected "-4" :actual "(max-key abs 1 -2 -4 3)" :portability :common} - {:suite "conformance / strings (clojure.string)" :label "str/trim" :expected "\"hi\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim \" hi \"))" :portability :common} - {:suite "conformance / strings (clojure.string)" :label "str/split regex" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b,c\" #\",\"))" :portability :common} - {:suite "conformance / strings (clojure.string)" :label "str/split ws" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a b c\" #\"\\s+\"))" :portability :common} - {:suite "conformance / strings (clojure.string)" :label "str/replace" :expected "\"hexxo\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" \"ll\" \"xx\"))" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace regex" :expected "\"ab\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"a1b2\" #\"[0-9]\" \"\"))" :portability :common} - {:suite "conformance / strings (clojure.string)" :label "subs" :expected "\"ell\"" :actual "(subs \"hello\" 1 4)" :portability :common} - {:suite "conformance / regex" :label "re-find" :expected "\"123\"" :actual "(re-find #\"[0-9]+\" \"abc123def\")" :portability :common} - {:suite "conformance / regex" :label "re-matches" :expected "\"abc\"" :actual "(re-matches #\"a.c\" \"abc\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-matches no" :expected "nil" :actual "(re-matches #\"a.c\" \"abcd\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-seq" :expected "[\"12\" \"34\"]" :actual "(re-seq #\"[0-9]+\" \"a12b34\")" :portability :common} - {:suite "conformance / sequences" :label "split-at" :expected "[[1 2] [3 4 5]]" :actual "(split-at 2 [1 2 3 4 5])" :portability :common} - {:suite "conformance / sequences" :label "split-with" :expected "[[1 2] [3 4 1]]" :actual "(split-with (fn [x] (< x 3)) [1 2 3 4 1])" :portability :common} - {:suite "conformance / sequences" :label "partition step" :expected "[[1 2] [3 4]]" :actual "(partition 2 2 [1 2 3 4 5])" :portability :common} - {:suite "conformance / sequences" :label "not-every?" :expected "true" :actual "(not-every? pos? [1 -2 3])" :portability :common} - {:suite "conformance / overlay migration: run in all 3 modes" :label "not-any?" :expected "true" :actual "(not-any? neg? [1 2 3])" :portability :common} - {:suite "conformance / sequences" :label "take-nth" :expected "[0 2 4]" :actual "(take-nth 2 [0 1 2 3 4])" :portability :common} - {:suite "conformance / sequences" :label "butlast" :expected "[1 2]" :actual "(butlast [1 2 3])" :portability :common} - {:suite "conformance / sequences" :label "empty" :expected "[]" :actual "(empty [1 2 3])" :portability :common} - {:suite "conformance / sequences" :label "replace map" :expected "[:a :b :a]" :actual "(replace {1 :a 2 :b} [1 2 1])" :portability :common} - {:suite "conformance / data structures" :label "sorted-map seq" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(seq (sorted-map :c 3 :a 1 :b 2))" :portability :common} - {:suite "conformance / data structures" :label "sorted-set seq" :expected "[1 2 3]" :actual "(seq (sorted-set 3 1 2))" :portability :common} - {:suite "conformance / data structures" :label "coll? set" :expected "true" :actual "(coll? #{1 2})" :portability :common} - {:suite "conformance / data structures" :label "conj map entry" :expected "{:a 1, :b 2}" :actual "(conj {:a 1} [:b 2])" :portability :common} - {:suite "conformance / metadata / vars" :label "vary-meta" :expected "{:x 2}" :actual "(meta (vary-meta (with-meta [1] {:x 1}) update :x inc))" :portability :common} - {:suite "conformance / metadata / vars" :label "defonce no-redef" :expected "1" :actual "(do (defonce dv1 1) (defonce dv1 2) dv1)" :portability :common} - {:suite "conformance / metadata / vars" :label "binding dynamic" :expected "10" :actual "(do (def ^:dynamic *x* 1) (binding [*x* 10] *x*))" :portability :common} - {:suite "conformance / try / catch" :label "try catch" :expected ":caught" :actual "(try (throw (ex-info \"e\" {})) (catch :default e :caught))" :portability :common} - {:suite "conformance / try / catch" :label "ex-data" :expected "{:a 1}" :actual "(try (throw (ex-info \"m\" {:a 1})) (catch :default e (ex-data e)))" :portability :common} - {:suite "conformance / try / catch" :label "ex-message" :expected "\"m\"" :actual "(try (throw (ex-info \"m\" {})) (catch :default e (ex-message e)))" :portability :common} - {:suite "conformance / macros" :label "macroexpand-1" :expected "true" :actual "(do (defmacro mm [x] (list (quote inc) x)) (= (quote (inc 5)) (macroexpand-1 (quote (mm 5)))))" :portability :common} - {:suite "conformance / macros" :label "doto" :expected "{:a 1}" :actual "(deref (doto (atom {}) (swap! assoc :a 1)))" :portability :common} - {:suite "conformance / printing" :label "prn-str" :expected "\"1\\n\"" :actual "(prn-str 1)" :portability :common} - {:suite "conformance / characters" :label "char not string" :expected "false" :actual "(= \\a \"a\")" :portability :common} - {:suite "conformance / characters" :label "char eq" :expected "true" :actual "(= \\a \\a)" :portability :common} - {:suite "conformance / characters" :label "int of char" :expected "97" :actual "(int \\a)" :portability :common} - {:suite "conformance / characters" :label "char of int" :expected "true" :actual "(= \\A (char 65))" :portability :common} - {:suite "conformance / characters" :label "str of chars" :expected "\"abc\"" :actual "(str \\a \\b \\c)" :portability :common} - {:suite "conformance / characters" :label "first of string" :expected "\\h" :actual "(first \"hello\")" :portability :common} - {:suite "conformance / characters" :label "nth of string" :expected "\\e" :actual "(nth \"hello\" 1)" :portability :common} - {:suite "conformance / characters" :label "char newline" :expected "10" :actual "(int \\newline)" :portability :common} - {:suite "conformance / characters" :label "char space" :expected "32" :actual "(int \\space)" :portability :common} - {:suite "conformance / characters" :label "pr-str char" :expected "\"\\\\a\"" :actual "(pr-str \\a)" :portability :common} - {:suite "conformance / characters" :label "chars in vec" :expected "[\\a \\b]" :actual "[\\a \\b]" :portability :common} - {:suite "conformance / characters" :label "apply str chars" :expected "\"hi\"" :actual "(apply str [\\h \\i])" :portability :common} - {:suite "conformance / transducers" :label "transduce map" :expected "9" :actual "(transduce (map inc) + 0 [1 2 3])" :portability :common} - {:suite "conformance / transducers" :label "transduce comp" :expected "12" :actual "(transduce (comp (map inc) (filter even?)) + 0 [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "transduce conj" :expected "[2 3 4]" :actual "(transduce (map inc) conj [] [1 2 3])" :portability :common} - {:suite "conformance / transducers" :label "into comp xform" :expected "[1 9 25]" :actual "(into [] (comp (filter odd?) (map (fn [x] (* x x)))) [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "into take xform" :expected "[0 1 2]" :actual "(into [] (take 3) (range 100))" :portability :common} - {:suite "conformance / transducers" :label "transduce no-init" :expected "6" :actual "(transduce (map inc) + [0 1 2])" :portability :common} - {:suite "conformance / transducers" :label "transduce drop" :expected "[3 4 5]" :actual "(into [] (drop 2) [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "transduce remove" :expected "[1 3 5]" :actual "(into [] (remove even?) [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "transduce take-while" :expected "[1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) [1 2 3 4 1])" :portability :common} - {:suite "conformance / transducers" :label "transduce map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(into [] (map-indexed (fn [i x] [i x])) [:a :b])" :portability :common} - {:suite "conformance / transducers" :label "partition-all xform" :expected "[[1 2] [3 4] [5]]" :actual "(into [] (partition-all 2) [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "partition-all xform comp" :expected "[2 2 1]" :actual "(into [] (comp (partition-all 2) (map count)) [1 2 3 4 5])" :portability :common} - {:suite "conformance / transducers" :label "partition-by xform" :expected "[[1 1] [2 4] [5]]" :actual "(into [] (partition-by odd?) [1 1 2 4 5])" :portability :common} - {:suite "conformance / transducers" :label "partition-by xform reduced" :expected "[[1 1] [2 4]]" :actual "(into [] (comp (partition-by odd?) (take 2)) [1 1 2 4 5 5])" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-find groups" :expected "[\"12-34\" \"12\" \"34\"]" :actual "(re-find #\"(\\d+)-(\\d+)\" \"x12-34y\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-find no-groups" :expected "\"123\"" :actual "(re-find #\"\\d+\" \"ab123\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-matches groups" :expected "[\"1.2\" \"1\" \"2\"]" :actual "(re-matches #\"(\\d+)\\.(\\d+)\" \"1.2\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "greedy backtrack" :expected "\"xxfoo\"" :actual "(re-find #\".*foo\" \"xxfoo\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "greedy thru group" :expected "[\"a,b,c\" \"a,b\" \"c\"]" :actual "(re-find #\"(.*),(.*)\" \"a,b,c\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "lazy quantifier" :expected "[\"\" \"a\"]" :actual "(re-find #\"<(.+?)>\" \"\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "flag case-insens" :expected "\"CAT\"" :actual "(re-find #\"(?i)cat\" \"a CAT\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "lookahead" :expected "\"foo\"" :actual "(re-find #\"foo(?=bar)\" \"foobar\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "neg-lookahead" :expected "\"foo\"" :actual "(re-find #\"foo(?!bar)\" \"foobaz\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "word-boundary" :expected "\"word\"" :actual "(re-find #\"\\bword\\b\" \"a word!\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "word-boundary no" :expected "nil" :actual "(re-find #\"\\bword\\b\" \"swordfish\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "optional group" :expected "[\"1.2.3\" \"1\" \"2\" \"3\" nil]" :actual "(re-find #\"(\\d+)\\.(\\d+)\\.(\\d+)(?:-([a-z]+))?\" \"1.2.3\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "alternation" :expected "\"dog\"" :actual "(re-find #\"cat|dog\" \"a dog cat\")" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace $1" :expected "\"he[ll]o\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" #\"(l+)\" \"[$1]\"))" :portability :common} - {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace regex (2)" :expected "\"X-X\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"a-b\" #\"[a-z]\" \"X\"))" :portability :common} - {:suite "conformance / map literals evaluate their values" :label "map literal var" :expected "{:k 5}" :actual "(let [x 5] {:k x})" :portability :common} - {:suite "conformance / map literals evaluate their values" :label "map literal nested" :expected "{:a {:b 2}}" :actual "(let [y 2] {:a {:b y}})" :portability :common} - {:suite "conformance / map literals evaluate their values" :label "map literal keyfn" :expected "{:x 1}" :actual "(let [k :x] {k 1})" :portability :common} - {:suite "conformance / map literals evaluate their values" :label "map literal in fn" :expected "6" :actual "(do (defn mk [a b] {:sum (+ a b)}) (:sum (mk 2 4)))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def 3-arg docstring" :expected "42" :actual "(do (def dd \"the doc\" 42) dd)" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def docstring value type" :expected "true" :actual "(do (def ds \"doc\" [1 2]) (vector? ds))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def ^{:map} name" :expected "5" :actual "(do (def ^{:private true} mmv 5) mmv)" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defn ^{:map} name" :expected "25" :actual "(do (defn ^{:private true} sqf [x] (* x x)) (sqf 5))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmacro arity-clause" :expected "10" :actual "(do (defmacro m2c ([x] (list (quote *) x 2))) (m2c 5))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmacro doc + arity" :expected "30" :actual "(do (defmacro m3c \"doc\" ([x] (list (quote *) x 3))) (* (m3c 5) 2))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmulti docstring" :expected "\"A\"" :actual "(do (defmulti gmm \"the doc\" identity) (defmethod gmm :a [_] \"A\") (gmm :a))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "try multi-body last" :expected "3" :actual "(try 1 2 3 (catch :default e 0))" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "try finally on ok+catch" :expected "9" :actual "(let [a (atom 0)] (try 1 2 (catch :default e :c) (finally (reset! a 9))) @a)" :portability :common} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "ns restored after catch" :expected "\"user\"" :actual "(do (ns cf.boom) (defn bz [] (throw (Exception. \"e\"))) (in-ns (quote user)) (try (cf.boom/bz) (catch :default e nil)) (str *ns*))" :portability :jvm} - {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "cross-ns methods visible" :expected "[:sql]" :actual "(do (ns cf.mm) (defmulti ext identity) (defmethod ext :default [_] :d) (defn allk [] (vec (for [[k v] (methods ext) :when (not= k :default)] k))) (ns cf.mmi) (defmethod cf.mm/ext :sql [_] :s) (in-ns (quote user)) (cf.mm/allk))" :portability :common} - {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "defmacro multi-arity" :expected "[6 5 6]" :actual "(do (defmacro mar ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b)) ([a b c] (list (quote +) a b c))) [(mar 5) (mar 2 3) (mar 1 2 3)])" :portability :common} - {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "defmacro doc + attr-map" :expected "10" :actual "(do (defmacro mam \"doc\" {:arglists (quote ([x]))} [x] (list (quote inc) x)) (mam 9))" :portability :common} - {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "syntax-quote resolves alias" :expected "\"HI\"" :actual "(do (ns sq.lib (:require [clojure.string :as s])) (defmacro up [x] `(s/upper-case ~x)) (in-ns (quote user)) (sq.lib/up \"hi\"))" :portability :common} - {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "ns name with ^{:map} meta" :expected "5" :actual "(do (ns ^{:author \"a\" :doc \"d\"} nm.meta) (def q 5) (in-ns (quote user)) nm.meta/q)" :portability :common} - {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "unquote *ns* in template" :expected "true" :actual "(do (defmacro cur-ns [] `(str ~*ns*)) (string? (cur-ns)))" :portability :common} - {:suite "reader / read-string constructs sets" :label "top-level set" :expected "true" :actual "(set? (read-string \"#{:a :b}\"))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set value equals" :expected "true" :actual "(= #{1 2} (read-string \"#{1 2}\"))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set nested in map" :expected "true" :actual "(set? (:k (read-string \"{:k #{:a :b}}\")))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set nested in vector" :expected "true" :actual "(set? (first (read-string \"[#{:a}]\")))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set nested in list" :expected "true" :actual "(set? (first (read-string \"(#{:a})\")))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set keeps reader metadata" :expected "true" :actual "(:s (meta (read-string \"^:s #{1 2}\")))" :portability :common} - {:suite "reader / read-string constructs sets" :label "set of sets" :expected "true" :actual "(every? set? (read-string \"#{#{1} #{2}}\"))" :portability :common} - {:suite "io / str & format" :label "format %x lowercase" :expected "\"ff\"" :actual "(format \"%x\" 255)" :portability :common} - {:suite "io / str & format" :label "format %04x zero-pad lower" :expected "\"00ff\"" :actual "(format \"%04x\" 255)" :portability :common} - {:suite "io / str & format" :label "format %X uppercase" :expected "\"00FF\"" :actual "(format \"%04X\" 255)" :portability :common} - {:suite "io / str & format" :label "format %x wide hex" :expected "\"deadbeef\"" :actual "(format \"%x\" 3735928559)" :portability :common} - {:suite "protocols / extend & extends? on nil" :label "extend nil dispatches" :expected ":nil-via-extend" :actual "(do (defprotocol P2 (q [this])) (extend nil P2 {:q (fn [_] :nil-via-extend)}) (q nil))" :portability :common} - {:suite "protocols / extend & extends? on nil" :label "extends? nil when extended" :expected "true" :actual "(do (defprotocol Pe (pe [this])) (extend nil Pe {:pe (fn [_] :x)}) (extends? Pe nil))" :portability :common} - {:suite "protocols / extend & extends? on nil" :label "extends? nil when not extended" :expected "false" :actual "(do (defprotocol P3 (r [this])) (extends? P3 nil))" :portability :common} - {:suite "protocols / extend & extends? on nil" :label "extend-type nil still works" :expected ":via-type" :actual "(do (defprotocol P4 (s [this])) (extend-type nil P4 (s [_] :via-type)) (s nil))" :portability :common} - {:suite "protocols / extend on host classes" :label "dispatch by java.util.Map/Collection/CharSequence" :expected "[:map :coll :str :obj]" :actual "(do (defprotocol W (-w [x])) (extend java.util.Map W {:-w (fn [_] :map)}) (extend java.util.Collection W {:-w (fn [_] :coll)}) (extend java.lang.CharSequence W {:-w (fn [_] :str)}) (extend java.lang.Object W {:-w (fn [_] :obj)}) [(-w {:a 1}) (-w [1 2]) (-w \"s\") (-w 42)])" :portability :jvm} - {:suite "protocols / extend on host classes" :label "satisfies? via java.util.Map" :expected "true" :actual "(do (defprotocol Q (qq [x])) (extend java.util.Map Q {:qq (fn [_] :m)}) (satisfies? Q {}))" :portability :jvm} - {:suite "protocols / extend on host classes" :label "extends? on a qualified host class" :expected "true" :actual "(do (defprotocol Qe (qe [x])) (extend java.util.Collection Qe {:qe (fn [_] :c)}) (extends? Qe java.util.Collection))" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "keyword is Named" :expected "true" :actual "(instance? clojure.lang.Named :a)" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "string is CharSequence" :expected "true" :actual "(instance? java.lang.CharSequence \"s\")" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "number is Number" :expected "true" :actual "(instance? java.lang.Number 42)" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "map is java.util.Map" :expected "true" :actual "(instance? java.util.Map {:a 1})" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "vector is java.util.List" :expected "true" :actual "(instance? java.util.List [1 2])" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "list is java.util.Collection" :expected "true" :actual "(instance? java.util.Collection (list 1))" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "set is java.util.Set" :expected "true" :actual "(instance? java.util.Set #{1})" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "map is not a Collection" :expected "false" :actual "(instance? java.util.Collection {:a 1})" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "vector is Associative" :expected "true" :actual "(instance? clojure.lang.Associative [1])" :portability :jvm} - {:suite "interop / instance? on host interfaces" :label "string is not Number" :expected "false" :actual "(instance? java.lang.Number \"s\")" :portability :jvm} - {:suite "interop / String & StringBuilder char ops" :label "String from char-array slice" :expected "\"abc\"" :actual "(String. (char-array [\\a \\b \\c \\d]) 0 3)" :portability :jvm} - {:suite "interop / String & StringBuilder char ops" :label "str of StringBuilder" :expected "\"hi\"" :actual "(let [sb (StringBuilder.)] (.append sb \"hi\") (str sb))" :portability :jvm} - {:suite "interop / String & StringBuilder char ops" :label "append subsequence" :expected "\"bcd\"" :actual "(let [sb (StringBuilder.)] (.append sb \"abcde\" 1 4) (.toString sb))" :portability :jvm} - {:suite "interop / String & StringBuilder char ops" :label "String.getChars into buffer" :expected "\"abc\"" :actual "(let [a (char-array 4)] (.getChars \"abcd\" 0 3 a 0) (String. a 0 3))" :portability :jvm} - {:suite "interop / numbers & classes" :label "Integer/toHexString lowercase" :expected "\"ff\"" :actual "(Integer/toHexString 255)" :portability :jvm} - {:suite "interop / numbers & classes" :label "Integer/toHexString wide" :expected "\"1234\"" :actual "(Integer/toHexString 4660)" :portability :jvm} - {:suite "interop / numbers & classes" :label ".isNaN on a double" :expected "true" :actual "(.isNaN (/ 0.0 0.0))" :portability :jvm} - {:suite "interop / numbers & classes" :label ".isInfinite on a double" :expected "true" :actual "(.isInfinite (/ 1.0 0.0))" :portability :jvm} - {:suite "interop / numbers & classes" :label ".isNaN false for finite" :expected "false" :actual "(.isNaN 1.0)" :portability :jvm} - {:suite "interop / numbers & classes" :label "protocol dispatch Long vs Double" :expected "[:l :d]" :actual "(do (defprotocol N (-n [x])) (extend java.lang.Long N {:-n (fn [_] :l)}) (extend java.lang.Double N {:-n (fn [_] :d)}) [(-n 5) (-n 5.0)])" :portability :jvm} - {:suite "interop / numbers & classes" :label "instance? PushbackReader" :expected "true" :actual "(instance? java.io.PushbackReader (java.io.PushbackReader. (java.io.StringReader. \"x\")))" :portability :jvm} - {:suite "interop / numbers & classes" :label "EOFException catch by class" :expected "\"boom\"" :actual "(try (throw (java.io.EOFException. \"boom\")) (catch java.io.EOFException e (.getMessage e)))" :portability :jvm} - {:suite "interop / numbers & classes" :label "Reader.read into char[]" :expected "[4 \"abcd\"]" :actual "(let [r (java.io.StringReader. \"abcd\") b (char-array 4)] (let [n (.read r b 0 4)] [n (String. b 0 n)]))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate toString" :expected "\"2020-01-15\"" :actual "(str (java.time.LocalDate/of 2020 1 15))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate plusDays over leap day" :expected "\"2020-02-29\"" :actual "(str (.plusDays (java.time.LocalDate/of 2020 2 28) 1))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate equality" :expected "true" :actual "(= (java.time.LocalDate/of 2020 1 15) (java.time.LocalDate/of 2020 1 15))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate compare" :expected "-1" :actual "(compare (java.time.LocalDate/of 2020 1 15) (java.time.LocalDate/of 2020 1 16))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate ofEpochDay round-trip" :expected "1" :actual "(.toEpochDay (java.time.LocalDate/of 1970 1 2))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate parse" :expected "\"2020-01-15\"" :actual "(str (java.time.LocalDate/parse \"2020-01-15\"))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate getDayOfWeek name" :expected "\"WEDNESDAY\"" :actual "(.name (.getDayOfWeek (java.time.LocalDate/of 2020 1 15)))" :portability :jvm} - {:suite "interop / java.time" :label "LocalTime toString" :expected "\"10:30:15\"" :actual "(str (java.time.LocalTime/of 10 30 15))" :portability :jvm} - {:suite "interop / java.time" :label "LocalTime plusHours wraps midnight" :expected "\"01:30\"" :actual "(str (.plusHours (java.time.LocalTime/of 23 30) 2))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDateTime toString" :expected "\"2020-01-15T10:30\"" :actual "(str (java.time.LocalDateTime/of 2020 1 15 10 30 0))" :portability :jvm} - {:suite "interop / java.time" :label "Instant ofEpochMilli toString" :expected "\"2020-01-15T10:30:00Z\"" :actual "(str (java.time.Instant/ofEpochMilli 1579084200000))" :portability :jvm} - {:suite "interop / java.time" :label "Instant ofEpochMilli round-trip" :expected "1579084200000" :actual "(.toEpochMilli (java.time.Instant/ofEpochMilli 1579084200000))" :portability :jvm} - {:suite "interop / java.time" :label "Duration ofSeconds toString" :expected "\"PT1M30S\"" :actual "(str (java.time.Duration/ofSeconds 90))" :portability :jvm} - {:suite "interop / java.time" :label "Duration between instants" :expected "\"PT1H1M1S\"" :actual "(str (java.time.Duration/between (java.time.Instant/ofEpochSecond 0) (java.time.Instant/ofEpochSecond 3661)))" :portability :jvm} - {:suite "interop / java.time" :label "Period between dates" :expected "\"P1Y2M2D\"" :actual "(str (java.time.Period/between (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2021 3 3)))" :portability :jvm} - {:suite "interop / java.time" :label "Period parse round-trip" :expected "\"P1Y2M3D\"" :actual "(str (java.time.Period/parse \"P1Y2M3D\"))" :portability :jvm} - {:suite "interop / java.time" :label "Period normalized" :expected "\"P2Y1M5D\"" :actual "(str (.normalized (java.time.Period/of 1 13 5)))" :portability :jvm} - {:suite "interop / java.time" :label "Month of toString" :expected "\"FEBRUARY\"" :actual "(.toString (java.time.Month/of 2))" :portability :jvm} - {:suite "interop / java.time" :label "Month length leap" :expected "29" :actual "(.length (java.time.Month/of 2) true)" :portability :jvm} - {:suite "interop / java.time" :label "DayOfWeek constant prints name" :expected "\"MONDAY\"" :actual "(str java.time.DayOfWeek/MONDAY)" :portability :jvm} - {:suite "interop / java.time" :label "YearMonth toString" :expected "\"2020-02\"" :actual "(str (java.time.YearMonth/of 2020 2))" :portability :jvm} - {:suite "interop / java.time" :label "ChronoUnit DAYS between" :expected "14" :actual "(.between java.time.temporal.ChronoUnit/DAYS (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2020 1 15))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate plus ChronoUnit DAYS" :expected "\"2020-01-04\"" :actual "(str (.plus (java.time.LocalDate/of 2020 1 1) 3 java.time.temporal.ChronoUnit/DAYS))" :portability :jvm} - {:suite "interop / java.time" :label "LocalDate until ChronoUnit DAYS" :expected "31" :actual "(.until (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2020 2 1) java.time.temporal.ChronoUnit/DAYS)" :portability :jvm} - {:suite "interop / java.time" :label "ZoneOffset ofHoursMinutes toString" :expected "\"+02:00\"" :actual "(str (java.time.ZoneOffset/ofHoursMinutes 2 0))" :portability :jvm} - {:suite "interop / java.time" :label "ZoneOffset ofTotalSeconds toString" :expected "\"-04:30\"" :actual "(str (java.time.ZoneOffset/ofTotalSeconds -16200))" :portability :jvm} - {:suite "interop / java.time" :label "ZoneOffset UTC toString" :expected "\"Z\"" :actual "(str java.time.ZoneOffset/UTC)" :portability :jvm} - {:suite "interop / java.time" :label "ZoneOffset of getTotalSeconds" :expected "7200" :actual "(.getTotalSeconds (java.time.ZoneOffset/of \"+02:00\"))" :portability :jvm} - {:suite "interop / java.time" :label "ZoneOffset ofHoursMinutes negative" :expected "\"-04:30\"" :actual "(.getId (java.time.ZoneOffset/ofHoursMinutes -4 -30))" :portability :jvm} - {:suite "interop / java.time" :label "OffsetDateTime toInstant" :expected "\"2020-01-15T08:30:00Z\"" :actual "(str (.toInstant (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2))))" :portability :jvm} - {:suite "interop / java.time" :label "OffsetDateTime toString" :expected "\"2020-01-15T10:30+02:00\"" :actual "(str (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2)))" :portability :jvm} - {:suite "interop / java.time" :label "ZonedDateTime withZoneSameInstant UTC" :expected "\"2020-01-15T08:30Z\"" :actual "(str (.withZoneSameInstant (java.time.ZonedDateTime/parse \"2020-01-15T10:30:00+02:00[Europe/Paris]\") java.time.ZoneOffset/UTC))" :portability :jvm} - {:suite "interop / java.time" :label "ZonedDateTime of toInstant fixed offset" :expected "\"2020-01-15T08:30:00Z\"" :actual "(str (.toInstant (java.time.ZonedDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneId/of \"+02:00\"))))" :portability :jvm} - {:suite "interop / java.time" :label "DateTimeFormatter ofPattern format" :expected "\"2020-01-15 10:30:00\"" :actual "(.format (java.time.format.DateTimeFormatter/ofPattern \"yyyy-MM-dd HH:mm:ss\") (java.time.LocalDateTime/of 2020 1 15 10 30 0))" :portability :jvm} - {:suite "interop / java.time" :label "ISO_LOCAL_DATE_TIME format" :expected "\"2020-01-15T10:30:00\"" :actual "(.format java.time.format.DateTimeFormatter/ISO_LOCAL_DATE_TIME (java.time.LocalDateTime/of 2020 1 15 10 30 0))" :portability :jvm} - {:suite "interop / java.time" :label "ISO_OFFSET_DATE_TIME format" :expected "\"2020-01-15T10:30:00+02:00\"" :actual "(.format java.time.format.DateTimeFormatter/ISO_OFFSET_DATE_TIME (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2)))" :portability :jvm} - {:suite "interop / java.time" :label "Instant plusNanos toString nanos group" :expected "\"1970-01-01T00:00:00.000000001Z\"" :actual "(str (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))" :portability :jvm} - {:suite "interop / java.time" :label "Instant one nano differs" :expected "false" :actual "(= (java.time.Instant/ofEpochSecond 0) (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))" :portability :jvm} - {:suite "interop / java.time" :label "Instant getNano single nano" :expected "1" :actual "(.getNano (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))" :portability :jvm} - {:suite "interop / java.time" :label "Instant ofEpochSecond nano millis group" :expected "\"1970-01-01T00:00:00.001Z\"" :actual "(str (java.time.Instant/ofEpochSecond 0 1000000))" :portability :jvm} - {:suite "interop / java.time" :label "Instant ofEpochSecond nano micros group" :expected "\"1970-01-01T00:00:00.000001Z\"" :actual "(str (java.time.Instant/ofEpochSecond 0 1000))" :portability :jvm} - {:suite "interop / java.time" :label "Instant plusSeconds keeps nanos" :expected "\"1970-01-01T00:00:02.000000005Z\"" :actual "(str (.plusSeconds (.plusNanos (java.time.Instant/ofEpochSecond 0) 5) 2))" :portability :jvm} - {:suite "interop / java.time" :label "Instant getEpochSecond floors negative nano" :expected "-1" :actual "(.getEpochSecond (.plusNanos (java.time.Instant/ofEpochSecond 0) -1))" :portability :jvm} - {:suite "interop / java.time" :label "Instant getNano of negative nano" :expected "999999999" :actual "(.getNano (.plusNanos (java.time.Instant/ofEpochSecond 0) -1))" :portability :jvm} - {:suite "interop / java.time" :label "Instant toEpochMilli floors sub-milli" :expected "1000" :actual "(.toEpochMilli (.plusNanos (java.time.Instant/ofEpochSecond 1) 999999))" :portability :jvm} - {:suite "interop / java.time" :label "Instant truncatedTo SECONDS drops nanos" :expected "\"1970-01-01T00:00:05Z\"" :actual "(str (.truncatedTo (.plusNanos (java.time.Instant/ofEpochSecond 5) 123) java.time.temporal.ChronoUnit/SECONDS))" :portability :jvm} - {:suite "interop / java.io File" :label "getName" :expected "\"c.txt\"" :actual "(.getName (java.io.File. \"/a/b/c.txt\"))" :portability :jvm} - {:suite "interop / java.io File" :label "getParent" :expected "\"/a/b\"" :actual "(.getParent (java.io.File. \"/a/b/c.txt\"))" :portability :jvm} - {:suite "interop / java.io File" :label "getPath keeps relative path" :expected "\"rel/x\"" :actual "(.getPath (java.io.File. \"rel/x\"))" :portability :jvm} - {:suite "interop / java.io File" :label "relative File is not absolute" :expected "false" :actual "(.isAbsolute (java.io.File. \"rel\"))" :portability :jvm} - {:suite "interop / java.io File" :label "parent+child constructor joins" :expected "\"/a/b\"" :actual "(.getPath (java.io.File. \"/a\" \"b\"))" :portability :jvm} - {:suite "interop / java.io File" :label "File/separator" :expected "\"/\"" :actual "java.io.File/separator" :portability :jvm} - {:suite "interop / java.io File" :label "str of File is its path" :expected "\"a/b\"" :actual "(str (java.io.File. \"a/b\"))" :portability :jvm} - {:suite "interop / java.io File" :label "mkdir then delete a temp dir" :expected "[true true true]" :actual "(let [d (java.io.File/createTempFile \"jd\" \"\")] (.delete d) [(.mkdir d) (.isDirectory d) (.delete d)])" :portability :jvm} - {:suite "interop / java.io streams" :label "ByteArrayOutputStream toString" :expected "\"hi!\"" :actual "(let [b (java.io.ByteArrayOutputStream.)] (.write b (.getBytes \"hi\")) (.write b 33) (.toString b))" :portability :jvm} - {:suite "interop / java.io streams" :label "ByteArrayOutputStream size" :expected "4" :actual "(let [b (java.io.ByteArrayOutputStream.)] (.write b (.getBytes \"abcd\")) (.size b))" :portability :jvm} - {:suite "interop / java.io streams" :label "ByteArrayOutputStream toByteArray round-trips" :expected "\"yo\"" :actual "(String. (.toByteArray (doto (java.io.ByteArrayOutputStream.) (.write (.getBytes \"yo\")))))" :portability :jvm} - {:suite "interop / java.io streams" :label "ByteArrayInputStream read to EOF" :expected "[65 66 -1]" :actual "(let [in (java.io.ByteArrayInputStream. (.getBytes \"AB\"))] [(.read in) (.read in) (.read in)])" :portability :jvm} - {:suite "interop / java.io streams" :label "BufferedReader over StringReader readLine" :expected "[\"a\" \"b\" nil]" :actual "(let [r (java.io.BufferedReader. (java.io.StringReader. \"a\\nb\\n\"))] [(.readLine r) (.readLine r) (.readLine r)])" :portability :jvm} - {:suite "interop / java.io streams" :label "instance? InputStream" :expected "true" :actual "(instance? java.io.InputStream (java.io.ByteArrayInputStream. (.getBytes \"x\")))" :portability :jvm} - {:suite "interop / java.io streams" :label "FileOutputStream then FileInputStream round-trip" :expected "90" :actual "(let [f (java.io.File/createTempFile \"jc\" \".t\") o (java.io.FileOutputStream. f)] (.write o (byte-array [90])) (.close o) (let [in (java.io.FileInputStream. f) b (.read in)] (.close in) (.delete f) b))" :portability :jvm} - {:suite "clojure.edn / unknown tags" :label "unknown tag throws naming the tag" :expected "\"No reader function for tag foobar\"" :actual "(do (require (quote [clojure.edn :as e1])) (try (e1/read-string \"#foobar 1\") (catch Exception e (ex-message e))))" :portability :common} - {:suite "clojure.edn / unknown tags" :label "object tag throws naming the tag" :expected "\"No reader function for tag object\"" :actual "(do (require (quote [clojure.edn :as e2])) (try (e2/read-string \"#object [1 2 3]\") (catch Exception e (ex-message e))))" :portability :common} - {:suite "clojure.edn / unknown tags" :label ":default opt handles an unknown tag" :expected "[\"foobar\" 9]" :actual "(do (require (quote [clojure.edn :as e3])) (e3/read-string {:default (fn [t v] [(name t) v])} \"#foobar 9\"))" :portability :common} - {:suite "deftype / clojure.lang interfaces" :label "Indexed + Counted dispatch" :expected "[3 20]" :actual "(do (deftype Row [v] clojure.lang.Indexed (nth [_ i] (nth v i)) (nth [_ i x] (nth v i x)) clojure.lang.Counted (count [_] (count v))) [(count (->Row [10 20 30])) (nth (->Row [10 20 30]) 1)])" :portability :jvm} - {:suite "deftype / clojure.lang interfaces" :label "multi-arity inline method" :expected "[5 11]" :actual "(do (defprotocol PMul (mm [this a] [this a b])) (deftype TMul [] PMul (mm [_ a] a) (mm [_ a b] (+ a b))) [(mm (->TMul) 5) (mm (->TMul) 5 6)])" :portability :common} - {:suite "deftype / clojure.lang interfaces" :label "ILookup valAt computes a non-field key" :expected "[1 :miss]" :actual "(do (deftype TL [a] clojure.lang.ILookup (valAt [this k] (.valAt this k nil)) (valAt [_ k nf] (case k :a a :computed 99 nf))) [(:a (->TL 1)) (get (->TL 1) :nope :miss)])" :portability :jvm} - {:suite "deftype / clojure.lang interfaces" :label "marker protocol satisfies?" :expected "true" :actual "(do (defprotocol PMark) (deftype TM [] PMark) (satisfies? PMark (->TM)))" :portability :common} - {:suite "deftype / clojure.lang interfaces" :label "IFn record is callable" :expected "7" :actual "(do (deftype Adder [n] clojure.lang.IFn (invoke [_ x] (+ n x))) ((->Adder 5) 2))" :portability :jvm} - {:suite "interop / collections" :label "Map keySet" :expected "true" :actual "(= (set (.keySet {:a 1 :b 2})) #{:a :b})" :portability :jvm} - {:suite "interop / collections" :label "instance? ILookup on a map" :expected "true" :actual "(instance? clojure.lang.ILookup {:a 1})" :portability :jvm} - {:suite "interop / collections" :label "instance? Indexed on a vector" :expected "true" :actual "(instance? clojure.lang.Indexed [1 2 3])" :portability :jvm} - {:suite "interop / java.util.Date" :label "deprecated getYear/getMonth" :expected "[110 0]" :actual "(let [d (java.util.Date. 110 0 15)] [(.getYear d) (.getMonth d)])" :portability :jvm} - {:suite "clojure.set / variadic" :label "union of 4 sets" :expected "#{1 2 3 4}" :actual "(do (require (quote clojure.set)) (clojure.set/union #{1} #{2} #{3} #{4}))" :portability :common} - {:suite "clojure.set / variadic" :label "intersection of 3 sets" :expected "#{3}" :actual "(do (require (quote clojure.set)) (clojure.set/intersection #{1 2 3} #{2 3 4} #{3 4 5}))" :portability :common} - {:suite "regex / literal value" :label "literal is a Pattern" :expected "true" :actual "(instance? java.util.regex.Pattern #\"a.c\")" :portability :jvm} - {:suite "regex / literal value" :label "re-matches on a literal" :expected "\"aaa\"" :actual "(re-matches #\"a+\" \"aaa\")" :portability :common} - {:suite "regex / literal value" :label "quoted regex round-trips" :expected "\"#\\\"a.c\\\"\"" :actual "(pr-str (quote #\"a.c\"))" :portability :common} - {:suite "regex / literal value" :label "extend-protocol to Pattern dispatches" :expected "[:pattern :other]" :actual "(do (defprotocol Tg (tg [_])) (extend-protocol Tg java.util.regex.Pattern (tg [_] :pattern) Object (tg [_] :other)) [(tg #\"x\") (tg 1)])" :portability :jvm} - {:suite "records / representation" :label "assoc a declared field keeps the record" :expected "[true 9 2]" :actual "(do (defrecord R [a b]) (let [x (assoc (->R 1 2) :a 9)] [(record? x) (:a x) (:b x)]))" :portability :common} - {:suite "records / representation" :label "assoc an extension field keeps the record" :expected "[true 3 1]" :actual "(do (defrecord R [a b]) (let [x (assoc (->R 1 2) :c 3)] [(record? x) (:c x) (:a x)]))" :portability :common} - {:suite "records / representation" :label "dissoc an extension field keeps the record" :expected "[true nil 1]" :actual "(do (defrecord R [a b]) (let [x (-> (->R 1 2) (assoc :c 3) (dissoc :c))] [(record? x) (:c x) (:a x)]))" :portability :common} - {:suite "records / representation" :label "dissoc a declared field downgrades to a map" :expected "[false true 2 false]" :actual "(do (defrecord R [a b]) (let [m (dissoc (->R 1 2) :a)] [(record? m) (map? m) (:b m) (contains? m :a)]))" :portability :common} - {:suite "records / representation" :label "count includes extension fields" :expected "[2 3]" :actual "(do (defrecord R [a b]) [(count (->R 1 2)) (count (assoc (->R 1 2) :c 3))])" :portability :common} - {:suite "records / representation" :label "keys are declared then extension order" :expected "[[:a :b] [:a :b :c]]" :actual "(do (defrecord R [a b]) [(vec (keys (->R 1 2))) (vec (keys (assoc (->R 1 2) :c 3)))])" :portability :common} - {:suite "records / representation" :label "a nil field value is present, not absent" :expected "[nil true :d]" :actual "(do (defrecord R [a b]) (let [n (->R nil 2)] [(:a n) (contains? n :a) (get (->R 1 2) :zzz :d)]))" :portability :common} - {:suite "records / representation" :label "seq yields field map-entries" :expected "[[:a 1] [:b 2]]" :actual "(do (defrecord R [a b]) (vec (map (fn [e] [(key e) (val e)]) (->R 1 2))))" :portability :common} - {:suite "records / representation" :label "conj a map-entry vector assocs it" :expected "3" :actual "(do (defrecord R [a b]) (:c (conj (->R 1 2) [:c 3])))" :portability :common} - {:suite "records / representation" :label "= after assoc of an unchanged field" :expected "true" :actual "(do (defrecord R [a b]) (= (assoc (->R 1 2) :a 1) (->R 1 2)))" :portability :common} - {:suite "records / representation" :label "= compares extension fields" :expected "[true false]" :actual "(do (defrecord R [a b]) [(= (assoc (->R 1 2) :c 9) (assoc (->R 1 2) :c 9)) (= (assoc (->R 1 2) :c 9) (->R 1 2))])" :portability :common} - {:suite "records / representation" :label "assoc then dissoc an extension field = original" :expected "true" :actual "(do (defrecord R [a b]) (= (-> (->R 1 2) (assoc :c 3) (dissoc :c)) (->R 1 2)))" :portability :common} - {:suite "records / representation" :label "map-> keeps extension keys" :expected "[true 3 [:a :b :c]]" :actual "(do (defrecord R [a b]) (let [m (map->R {:a 1 :b 2 :c 3})] [(record? m) (:c m) (vec (keys m))]))" :portability :common} - {:suite "records / representation" :label "record as a map key" :expected ":v" :actual "(do (defrecord R [a]) (get {(->R 1) :v} (->R 1)))" :portability :common} - {:suite "records / representation" :label "records dedup in a set by value" :expected "2" :actual "(do (defrecord R [a]) (count (into #{} [(->R 1) (->R 1) (->R 2)])))" :portability :common} - {:suite "records / representation" :label "nested record field reads" :expected "[2 1]" :actual "(do (defrecord N [l r v]) (let [t (->N (->N nil nil 1) nil 2)] [(:v t) (:v (:l t))]))" :portability :common} - {:suite "protocols / arity dispatch" :label "multi-arity protocol method on a record" :expected "[\"0:9\" \"1:9::a\" \"2:9::a::b\"]" :actual "(do (defprotocol P (m [this] [this x] [this x y])) (defrecord R [v] P (m [this] (str \"0:\" v)) (m [this x] (str \"1:\" v \":\" x)) (m [this x y] (str \"2:\" v \":\" x \":\" y))) [(m (->R 9)) (m (->R 9) :a) (m (->R 9) :a :b)])" :portability :common} - {:suite "protocols / arity dispatch" :label "two-arg protocol method" :expected "30" :actual "(do (defprotocol P (addp [this x y])) (defrecord R [n] P (addp [_ x y] (+ n (+ x y)))) (addp (->R 10) 7 13))" :portability :common} - {:suite "protocols / arity dispatch" :label "protocol method extended to a host type with an arg" :expected "\"S:hi:5\"" :actual "(do (defprotocol Q (mq [this a])) (extend-protocol Q java.lang.String (mq [this a] (str \"S:\" this \":\" a))) (mq \"hi\" 5))" :portability :jvm} - {:suite "protocols / arity dispatch" :label "protocol method used as a value" :expected "[1 2]" :actual "(do (defprotocol Z (z [this])) (defrecord ZR [v] Z (z [_] v)) (mapv z [(->ZR 1) (->ZR 2)]))" :portability :common} - {:suite "protocols / arity dispatch" :label "no-extra-arg method dispatches by type" :expected "[16 25]" :actual "(do (defprotocol Sh (ar [s])) (defrecord Sq [x] Sh (ar [_] (* x x))) (defrecord Sq2 [y] Sh (ar [_] (* y y))) [(ar (->Sq 4)) (ar (->Sq2 5))])" :portability :common} - {:suite "vectors / large trie" :label "linear build equals range across paths" :expected "true" :actual "(= (vec (range 2000)) (reduce conj [] (range 2000)) (into [] (range 2000)))" :portability :common} - {:suite "vectors / large trie" :label "nth across a multi-level vector" :expected "[0 1024 2000 2099]" :actual "(let [v (vec (range 2100))] [(nth v 0) (nth v 1024) (nth v 2000) (nth v 2099)])" :portability :common} - {:suite "vectors / large trie" :label "assoc in a large vector" :expected "[1098 :x 1100]" :actual "(let [v (assoc (vec (range 1100)) 1099 :x)] [(nth v 1098) (nth v 1099) (count v)])" :portability :common} - {:suite "vectors / large trie" :label "pop down across a level boundary" :expected "[1023 1022]" :actual "(let [p (pop (vec (range 1024)))] [(count p) (peek p)])" :portability :common} - {:suite "vectors / large trie" :label "pop to empty then rebuild" :expected "[0 5]" :actual "(let [e (loop [v (vec (range 100))] (if (seq v) (recur (pop v)) v))] [(count e) (count (into e (range 5)))])" :portability :common} - {:suite "printer / print-length" :label "truncates an infinite seq before realizing it" :expected "true" :actual "(= \"(0 1 2 ...)\" (binding [*print-length* 3] (pr-str (range))))" :portability :common} - {:suite "printer / print-length" :label "truncates a vector with ellipsis" :expected "true" :actual "(= \"[1 2 ...]\" (binding [*print-length* 2] (pr-str [1 2 3 4])))" :portability :common} - {:suite "printer / print-length" :label "exactly N elements prints no ellipsis" :expected "true" :actual "(= \"(0 1 2)\" (binding [*print-length* 3] (pr-str (range 3))))" :portability :common} - {:suite "printer / print-length" :label "nil default is unlimited" :expected "true" :actual "(= \"[1 2 3 4 5]\" (pr-str [1 2 3 4 5]))" :portability :common} - {:suite "printer / print-level" :label "collapses a collection past the level to #" :expected "true" :actual "(= \"[:a [:b #]]\" (binding [*print-level* 2] (pr-str [:a [:b [:c 1]]])))" :portability :common} - {:suite "printer / print-level" :label "level 0 collapses the top collection" :expected "true" :actual "(= \"#\" (binding [*print-level* 0] (pr-str [1 2])))" :portability :common} - {:suite "printer / print-level" :label "level 1 keeps the outermost collection" :expected "true" :actual "(= \"[# 3]\" (binding [*print-level* 1] (pr-str [[1 2] 3])))" :portability :common} - {:suite "printer / print-level" :label "scalars print regardless of level" :expected "true" :actual "(= \"[1 2]\" (binding [*print-level* 1] (pr-str [1 2])))" :portability :common} - {:suite "reader / default-data-reader-fn" :label "consulted for an unregistered tag" :expected "true" :actual "(= [(quote foo) 42] (binding [*default-data-reader-fn* (fn [tag v] [tag v])] (read-string \"#foo 42\")))" :portability :common} - {:suite "printer / print-vars" :label "print-length / print-level / default-data-reader-fn default to nil" :expected "[true true true]" :actual "[(nil? *print-length*) (nil? *print-level*) (nil? *default-data-reader-fn*)]" :portability :common} - {:suite "seqs / laziness" :label "an empty lazy seq is () not nil" :expected "true" :actual "(= () (lazy-seq nil))" :portability :common} - {:suite "seqs / laziness" :label "rest of a one-element coll is ()" :expected "true" :actual "(= () (rest [1]))" :portability :common} - {:suite "seqs / laziness" :label "first of iterate does not call f" :expected "true" :actual "(let [a (atom 0)] (first (iterate (fn [x] (swap! a inc) (inc x)) 0)) (= 0 @a))" :portability :common} - {:suite "seqs / laziness" :label "rest of iterate does not realize the next element" :expected "true" :actual "(let [a (atom 0)] (rest (iterate (fn [x] (swap! a inc) (inc x)) 0)) (= 0 @a))" :portability :common} - {:suite "seqs / laziness" :label "take from an infinite iterate" :expected "[0 1 2 3 4]" :actual "(vec (take 5 (iterate inc 0)))" :portability :common} - {:suite "seqs / laziness" :label "distinct over a rest-derived seq does not overrun" :expected "2" :actual "(count (distinct (map inc (rest [10 20 30]))))" :portability :common} - {:suite "transducers / map multi-input" :label "the map transducer applies f across all inputs" :expected "[6]" :actual "(((map +) conj) [] 1 2 3)" :portability :common} - {:suite "transducers / map multi-input" :label "single input is unchanged" :expected "[3]" :actual "(((map +) conj) [] 3)" :portability :common} - {:suite "records / deftype is not a map" :label "a bare deftype is neither map? nor record?, a defrecord is both" :expected "[false false true true]" :actual "(do (deftype DT [a]) (defrecord DR [a]) [(map? (->DT 1)) (record? (->DT 1)) (map? (->DR 1)) (record? (->DR 1))])" :portability :common} - {:suite "printer / str vs print" :label "str of a vector quotes nested strings" :expected "true" :actual "(= \"[\\\"x\\\"]\" (str [\"x\"]))" :portability :common} - {:suite "printer / str vs print" :label "print-str of a vector leaves strings raw" :expected "true" :actual "(= \"[x]\" (print-str [\"x\"]))" :portability :common} - {:suite "printer / str vs print" :label "str of a map quotes nested strings" :expected "true" :actual "(= \"{\\\"a\\\" \\\"b\\\"}\" (str {\"a\" \"b\"}))" :portability :common} - {:suite "printer / str vs print" :label "print-str of a map leaves strings raw" :expected "true" :actual "(= \"{:a x}\" (print-str {:a \"x\"}))" :portability :common} - {:suite "printer / str vs print" :label "infinity inside a collection prints readably in str" :expected "true" :actual "(= \"[##Inf]\" (str [##Inf]))" :portability :common} - {:suite "interop / uri equality" :label "URIs are value-equal and usable as set members" :expected "[true true]" :actual "[(= (java.net.URI. \"/\") (java.net.URI. \"/\")) (= #{(java.net.URI. \"/\")} #{(java.net.URI. \"/\")})]" :portability :jvm} - {:suite "stdlib / clojure.walk" :label "macroexpand-all expands a form" :expected "true" :actual "(do (require (quote clojure.walk)) (seq? (clojure.walk/macroexpand-all (quote (when true 1)))))" :portability :common} - {:suite "regex / re-seq zero-width" :label "a zero-width match advances by one without repeating" :expected "[\"a\" \"\" \"a\" \"\"]" :actual "(vec (re-seq #\"a*\" \"aba\"))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "conj onto a rest-derived seq prepends" :expected "true" :actual "(= [9 2 3] (vec (conj (rest [1 2 3]) 9)))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "conj onto a lazy-seq prepends" :expected "true" :actual "(= [9 1 2] (vec (conj (lazy-seq (list 1 2)) 9)))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "into over a conj'd rest-seq" :expected "true" :actual "(= [0 2 3] (into [] (conj (rest [1 2 3]) 0)))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "first of a conj'd rest-seq" :expected "true" :actual "(= 9 (first (conj (rest [1 2 3]) 9)))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "count of a conj'd rest-seq" :expected "true" :actual "(= 3 (count (conj (rest [1 2 3]) 9)))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "nth into a rest-seq" :expected "true" :actual "(= 3 (nth (rest [1 2 3]) 1))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "reduce over a rest-seq" :expected "true" :actual "(= 5 (reduce + (rest [1 2 3])))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "a rest-seq equals the literal tail" :expected "true" :actual "(= (quote (2 3)) (rest [1 2 3]))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "map over a rest-seq" :expected "true" :actual "(= [3 4] (vec (map inc (rest [1 2 3]))))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "filter over a rest-seq" :expected "true" :actual "(= [3] (vec (filter odd? (rest [1 2 3 4]))))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "apply over a rest-seq" :expected "true" :actual "(= 5 (apply + (rest [1 2 3])))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "seq of an empty rest is nil" :expected "true" :actual "(nil? (seq (rest [1])))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "empty? of an empty rest" :expected "true" :actual "(empty? (rest [1]))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "cons onto a rest-seq" :expected "true" :actual "(= [0 2 3] (vec (cons 0 (rest [1 2 3]))))" :portability :common} - {:suite "seqs / lazy-seq interop" :label "into a set from a rest-seq" :expected "true" :actual "(= #{2 3} (into #{} (rest [1 2 3])))" :portability :common} - {:suite "ifn / symbol as fn" :label "a symbol invokes as a map lookup" :expected "true" :actual "(= 5 ('a {(quote a) 5}))" :portability :common} - {:suite "ifn / symbol as fn" :label "a symbol fn takes a not-found default" :expected "true" :actual "(= :d ('a {} :d))" :portability :common} - {:suite "ifn / symbol as fn" :label "a symbol works as a mapping fn" :expected "true" :actual "(= [1 2] (vec (map (quote k) [{(quote k) 1} {(quote k) 2}])))" :portability :common} - {:suite "defn / attr-map" :label "docstring + attr-map both land in var meta" :expected "true" :actual "(do (defn f \"doc\" {:my :attr} [] 1) (= [\"doc\" :attr] [(:doc (meta (var f))) (:my (meta (var f)))]))" :portability :common} - {:suite "defn / attr-map" :label "attr-map without a docstring" :expected "true" :actual "(do (defn g {:my :attr} [] 1) (= :attr (:my (meta (var g)))))" :portability :common} - {:suite "defn / attr-map" :label "attr-map on a multi-arity defn" :expected "true" :actual "(do (defn h \"d\" {:my :a} ([] 1) ([a] a)) (= :a (:my (meta (var h)))))" :portability :common} - {:suite "defn / attr-map" :label "attr-map values are evaluated" :expected "true" :actual "(do (defn m {:val (+ 1 2)} [] 1) (= 3 (:val (meta (var m)))))" :portability :common} - {:suite "records / clojure.lang interop" :label "a record's Associative/ILookup methods delegate to the map fns" :expected "[1 9 true true 2]" :actual "(do (defrecord M [a b]) (let [m (->M 1 2)] [(.valAt m :a) (.valAt m :z 9) (= {:a 1 :b 2 :c 3} (into {} (.assoc m :c 3))) (.containsKey m :a) (.count m)]))" :portability :jvm} - {:suite "interop / number classes" :label "Byte/Short bounds + class tokens" :expected "[127 -128 32767 -32768 true]" :actual "[Byte/MAX_VALUE Byte/MIN_VALUE Short/MAX_VALUE Short/MIN_VALUE (= java.lang.Byte java.lang.Byte)]" :portability :jvm} - {:suite "reader / metadata" :label "a set in metadata is read as a value, not a tagged form" :expected "true" :actual "(= #{:a :b} (:foo (meta (read-string (binding [*print-meta* true] (pr-str (with-meta [1] {:foo #{:a :b}})))))))" :portability :common} - {:suite "reader / metadata" :label "metadata on an empty list is preserved" :expected "true" :actual "(= {:foo 1} (meta (read-string \"^{:foo 1} ()\")))" :portability :common} - {:suite "reader / metadata" :label "a vector in metadata reads as a value" :expected "true" :actual "(= [1 2] (:v (meta (read-string \"^{:v [1 2]} {:a 1}\"))))" :portability :common} - {:suite "reader / metadata" :label "an empty list in metadata reads as a value" :expected "true" :actual "(= () (:e (meta (read-string \"^{:e ()} [1]\"))))" :portability :common} - {:suite "edn / readers in collections" :label "a :default tag reader applies inside a set" :expected "true" :actual "(= #{[:t 1]} (clojure.edn/read-string {:default (fn [t v] [:t v])} \"#{#foo 1}\"))" :portability :common} - {:suite "edn / readers in collections" :label "a registered reader applies inside a set" :expected "true" :actual "(= #{6} (clojure.edn/read-string {:readers {(quote x) (fn [v] (* v 2))}} \"#{#x 3}\"))" :portability :common} - {:suite "metadata / immutability" :label "with-meta on a list does not mutate the original" :expected "true" :actual "(let [ds (list 1 2)] (with-meta ds {:k 1}) (nil? (meta ds)))" :portability :common} - {:suite "metadata / immutability" :label "with-meta on a list carries the metadata" :expected "true" :actual "(= {:k 1} (meta (with-meta (list 1) {:k 1})))" :portability :common} - {:suite "metadata / immutability" :label "a meta-bearing list still equals the bare list" :expected "true" :actual "(let [ds (list 1)] (= ds (with-meta ds {:k 9})))" :portability :common} - {:suite "metadata / immutability" :label "with-meta on a lazy seq carries metadata" :expected "true" :actual "(= {:k 5} (meta (with-meta (lazy-seq (list 1)) {:k 5})))" :portability :common} - {:suite "edn / deferred tags" :label "a :readers override wins over the built-in #inst (not eagerly built)" :expected "true" :actual "(= [:I \"x\"] (clojure.edn/read-string {:readers {(quote inst) (fn [v] [:I v])}} \"#inst \\\"x\\\"\"))" :portability :common} - {:suite "edn / deferred tags" :label "a normal #inst still constructs without an override" :expected "true" :actual "(= #inst \"2020-01-01T00:00:00.000-00:00\" (clojure.edn/read-string \"#inst \\\"2020-01-01T00:00:00.000-00:00\\\"\"))" :portability :common} - {:suite "vars / privacy" :label "defn- marks the var :private" :expected "true" :actual "(do (defn- p [] 1) (true? (:private (meta (var p)))))" :portability :common} - {:suite "vars / privacy" :label "ns-publics drops private vars; ns-interns keeps them" :expected "[true false true]" :actual "(do (defn pub [] 1) (defn- priv [] 2) [(contains? (ns-publics (quote user)) (quote pub)) (contains? (ns-publics (quote user)) (quote priv)) (contains? (ns-interns (quote user)) (quote priv))])" :portability :common} - {:suite "host interop / dot form" :label "(. target (method args)) list-member sugar" :expected "\"HELLO\"" :actual "(. \"hello\" (toUpperCase))" :portability :jvm} - {:suite "predicates / identical?" :label "reference identity, not value equality" :expected "[true false false]" :actual "[(identical? :a :a) (identical? (quote x) (quote x)) (identical? [1] [1])]" :portability :common} - {:suite "host interop / hashCode" :label "Java String and Symbol hashCode" :expected "[120 -1634134448]" :actual "[(.hashCode \"x\") (.hashCode (quote foo/bar))]" :portability :jvm} - {:suite "structmaps" :label "defstruct / struct-map / struct" :expected "[{:a 1 :b 2} {:a 1 :b 2} {:a 1 :b nil}]" :actual "(do (defstruct sx :a :b) [(struct-map sx :a 1 :b 2) (struct sx 1 2) (struct-map sx :a 1)])" :portability :common} - {:suite "deftype / clojure.lang interfaces" :label "ILookup-only deftype is not coll? or seqable?" :expected "[false false]" :actual "(do (deftype Lk [x] clojure.lang.ILookup (valAt [_ k] nil) (valAt [_ k nf] nf)) [(coll? (->Lk 1)) (seqable? (->Lk 1))])" :portability :jvm} - {:suite "host interop / Collection.contains" :label "value membership over vector/list/set" :expected "[true false true]" :actual "[(.contains [1 2 3] 2) (.contains (list :a :b) :z) (.contains #{1 2} 1)]" :portability :jvm} - {:suite "host interop / clojure.lang.Util" :label "Util/hash is Java hashCode" :expected "120" :actual "(clojure.lang.Util/hash \"x\")" :portability :jvm} - {:suite "deftype / IObj metadata" :label "deftype meta/withMeta govern (meta x)" :expected "{:a 1}" :actual "(do (deftype Sm [m] clojure.lang.IObj (meta [_] m) (withMeta [_ n] (Sm. n))) (meta (Sm. {:a 1})))" :portability :jvm} - {:suite "collections / disj" :label "disj of nil is nil" :expected "nil" :actual "(disj nil :a)" :portability :common} - {:suite "special forms / qualified" :label "clojure.core-qualified special form (from syntax-quote)" :expected "[:g 9]" :actual "(clojure.core/letfn [(g [x] [:g x])] (g 9))" :portability :common} - {:suite "symbols / interning" :label "(str sym) is the symbol's interned name (identity-stable)" :expected "[true true]" :actual "(let [s (quote ?a)] [(identical? (name s) (str s)) (= (str s) \"?a\")])" :portability :common} - {:suite "symbols / interning" :label "equal symbols share an interned name string" :expected "true" :actual "(let [a (quote ?foo) b (quote ?foo)] (identical? (name a) (name b)))" :portability :common} - {:suite "reader / unquote" :label "~x reads as clojure.core/unquote" :expected "true" :actual "(= (quote (clojure.core/unquote v)) (read-string \"~v\"))" :portability :common} - {:suite "reader / unquote" :label "~@x reads as clojure.core/unquote-splicing" :expected "true" :actual "(= (quote clojure.core/unquote-splicing) (first (read-string \"~@xs\")))" :portability :common} - {:suite "clojure.core / range" :label "(range 0) is the empty seq ()" :expected "true" :actual "(= () (range 0))" :portability :common} - {:suite "clojure.core / range" :label "(range 5 5) is the empty seq ()" :expected "true" :actual "(= () (range 5 5))" :portability :common} - {:suite "clojure.core / range" :label "empty range is not nil" :expected "true" :actual "(some? (range 5 0))" :portability :common} - {:suite "clojure.core / range" :label "empty range count" :expected "0" :actual "(count (range 0))" :portability :common} - {:suite "host-interop / instance? Object" :label "every non-nil value is an Object" :expected "[true true true true]" :actual "[(instance? Object 1) (instance? Object \"x\") (instance? Object []) (instance? Object (fn []))]" :portability :common} - {:suite "host-interop / instance? Object" :label "nil is not an instance of Object" :expected "false" :actual "(instance? Object nil)" :portability :common} - {:suite "host-interop / instance? Object" :label "java.lang.Object too" :expected "true" :actual "(instance? java.lang.Object :k)" :portability :jvm} - {:suite "host-interop / Compiler" :label "@Compiler/LINE is a number" :expected "true" :actual "(number? @clojure.lang.Compiler/LINE)" :portability :jvm} - {:suite "reader / octal literals" :label "0NNN is octal" :expected "34" :actual "042" :portability :common} - {:suite "reader / octal literals" :label "negative octal" :expected "-34" :actual "-042" :portability :common} - {:suite "reader / octal literals" :label "octal char escape \\oNNN" :expected "true" :actual "(= (char 0377) \\o377)" :portability :common} - {:suite "reader / octal literals" :label "octal string escape is one char" :expected "true" :actual "(= \"a\\000b\" (str \"a\" (char 0) \"b\"))" :portability :common} - {:suite "reader / octal literals" :label "hex still decimal-distinct" :expected "[1070 255 0]" :actual "[0x42e 0xff 0]" :portability :common} - {:suite "symbols / construction" :label "(symbol nil name) equals (symbol name)" :expected "true" :actual "(= (symbol nil \"foo\") (quote foo))" :portability :common} - {:suite "symbols / construction" :label "(symbol nil name) has no namespace" :expected "true" :actual "(nil? (namespace (symbol nil \"x\")))" :portability :common} - {:suite "host-interop / instance? hierarchy" :label "ExceptionInfo is a RuntimeException" :expected "[true true true]" :actual "[(instance? RuntimeException (ex-info \"x\" {})) (instance? Exception (ex-info \"x\" {})) (instance? Throwable (ex-info \"x\" {}))]" :portability :common} - {:suite "host-interop / class hierarchy" :label "Symbol and Keyword are IFn" :expected "[true true]" :actual "[(isa? clojure.lang.Symbol clojure.lang.IFn) (isa? clojure.lang.Keyword clojure.lang.IFn)]" :portability :jvm} - {:suite "host-interop / class hierarchy" :label "(class sym)-dispatched multimethod hits an IFn method" :expected ":ifn" :actual "(do (defmulti cm1 class) (defmethod cm1 clojure.lang.IFn [_] :ifn) (cm1 (quote sym)))" :portability :jvm} - {:suite "host-interop / extend-protocol java.io" :label "protocol extended to Reader / String dispatches a StringReader and a String" :expected "[:reader :string]" :actual "(do (import (quote (java.io StringReader))) (defprotocol Prdr (mrd [x])) (extend-protocol Prdr java.io.Reader (mrd [_] :reader) String (mrd [_] :string)) [(mrd (StringReader. \"x\")) (mrd \"y\")])" :portability :jvm} - {:suite "host-interop / StringWriter" :label "(str StringWriter) returns its accumulated content" :expected "\"hi!\"" :actual "(do (import (quote (java.io StringWriter))) (let [w (StringWriter.)] (.write w \"hi\") (.write w \"!\") (str w)))" :portability :jvm} - {:suite "numbers / unchecked wraps to signed 64-bit" :label "unchecked-add overflow wraps" :expected "-9223372036854775808" :actual "(unchecked-add 9223372036854775807 1)" :portability :common} - {:suite "numbers / unchecked wraps to signed 64-bit" :label "unchecked-multiply overflow wraps" :expected "1" :actual "(unchecked-multiply 9223372036854775807 9223372036854775807)" :portability :common} - {:suite "numbers / unchecked wraps to signed 64-bit" :label "unchecked-subtract underflow wraps" :expected "9223372036854775807" :actual "(unchecked-subtract -9223372036854775808 1)" :portability :common} - {:suite "numbers / unchecked wraps to signed 64-bit" :label "unchecked-negate of MIN wraps to MIN" :expected "-9223372036854775808" :actual "(unchecked-negate -9223372036854775808)" :portability :common} - {:suite "numbers / unchecked wraps to signed 64-bit" :label "unchecked-inc of MAX wraps to MIN" :expected "-9223372036854775808" :actual "(unchecked-inc 9223372036854775807)" :portability :common} - {:suite "host-interop / Long bit statics" :label "Long/bitCount, numberOfLeadingZeros, reverse" :expected "[10 63 0 -2]" :actual "[(Long/bitCount 1023) (Long/numberOfLeadingZeros 1) (Long/bitCount 0) (Long/reverse 9223372036854775807)]" :portability :jvm} - {:suite "numbers / unsigned-bit-shift-right is logical over 64 bits" :label "shift of a negative shifts in zeros" :expected "[9223372036854775807 4611686018427387902]" :actual "[(unsigned-bit-shift-right -1 1) (unsigned-bit-shift-right -8 2)]" :portability :common} - {:suite "numbers / ^long is 64-bit" :label "^long comparison on a full-width long" :expected "false" :actual "((fn* ([^long a ^long b] (< a b))) 9223372036854775807 1)" :portability :common} - {:suite "numbers / ^long is 64-bit" :label "^long quot on a full-width long" :expected "3074457345618258602" :actual "((fn* ([^long a] (quot a 3))) 9223372036854775807)" :portability :common} - {:suite "host-interop / Compiler" :label "Compiler/specials keys include the special forms" :expected "true" :actual "(every? (set (keys clojure.lang.Compiler/specials)) (quote [if do let* fn* quote def loop* recur try letfn* var]))" :portability :jvm} - {:suite "macros / letfn mutual recursion" :label "letfn binds mutually-recursive named fns" :expected "[true false]" :actual "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] [(ev? 10) (ev? 7)])" :portability :common} - {:suite "host-interop / extend-protocol IPersistentList" :label "a protocol extended to IPersistentList dispatches on a list, not a vector" :expected "[:list :vec :list]" :actual "(do (defprotocol PL (m [x])) (extend-protocol PL clojure.lang.IPersistentList (m [_] :list) clojure.lang.IPersistentVector (m [_] :vec)) [(m (list 1 2)) (m [1 2]) (m ())])" :portability :jvm} - {:suite "scope / qualified ref vs same-named local" :label "clojure.core/max wins over a local named max" :expected "[10 5]" :actual "[((fn [max] (clojure.core/max 5 10)) 100) ((fn [min] (clojure.core/min 5 10)) 0)]" :portability :common} - {:suite "numbers / unchecked on doubles" :label "unchecked-multiply of doubles is a double, not a truncated long" :expected "3.0" :actual "(unchecked-multiply 1.5 2.0)" :portability :common} - {:suite "seq / take infinite count" :label "(take +Infinity coll) takes the whole coll" :expected "7" :actual "(count (take (/ 1.0 0.0) (range 7)))" :portability :common} - {:suite "host-interop / UUID + Long + shiftLeft" :label "(UUID. msb lsb), .shiftLeft, (Long. n)" :expected "[\"00000000-0000-007b-0000-0000000001c8\" 40 10 42]" :actual "[(str (java.util.UUID. 123 456)) (.shiftLeft 5 3) (.shiftRight 40 2) (Long. 42)]" :portability :jvm} - {:suite "host-interop / ThreadLocal proxy" :label "(proxy [ThreadLocal] [] (initialValue [] v)) get/set" :expected "[42 7]" :actual "(let [tl (proxy [ThreadLocal] [] (initialValue [] 42))] [(.get tl) (do (.set tl 7) (.get tl))])" :portability :jvm} - {:suite "host-interop / Compiler/demunge" :label "demunge reverses name munging" :expected "\"a/b?\"" :actual "(clojure.lang.Compiler/demunge \"a$b_QMARK_\")" :portability :jvm} - {:suite "host-interop / a fn reports its munged class" :label "(class a-def'd-fn) is ns$munged-name, with the IFn hierarchy as ancestors" :expected "[\"clojure.core$odd_QMARK_\" true]" :actual "[(.getName (class odd?)) (boolean (some #{java.lang.Runnable} (ancestors (class odd?))))]" :portability :jvm} - {:suite "host-interop / MultiFn methods" :label ".getMethod / .dispatchFn on a multimethod" :expected "[true true true]" :actual "(do (defmulti mmc identity) (defmethod mmc :a [_] 1) [(some? (.getMethod mmc :a)) (nil? (.getMethod mmc :z)) (ifn? (.dispatchFn mmc))])" :portability :jvm} - {:suite "reader / namespaced map literal" :label "#:ns{...} qualifies bare keys; :_/x stays unqualified" :expected "[:search 2 nil]" :actual "[(:event/type #:event{:type :search :id 5}) (count #:x{:a 1 :b 2}) (:k #:_{:k 9})]" :portability :common} - {:suite "lazy / chunking" :label "(seq (range 1 50)) is a chunked-seq" :expected "true" :actual "(chunked-seq? (seq (range 1 50)))" :portability :common} - {:suite "lazy / chunking" :label "map over a chunked range realizes a whole 32-block on first" :expected "32" :actual "(let [c (atom 0) s (map (fn [x] (swap! c inc) x) (range 1 50))] (first s) @c)" :portability :common} - {:suite "lazy / chunking" :label "crossing a chunk boundary realizes the next 32-block" :expected "49" :actual "(let [c (atom 0) s (map (fn [x] (swap! c inc) x) (range 1 50))] (nth s 32) @c)" :portability :common} - {:suite "lazy / chunking" :label "chained maps each batch by 32 (result is itself chunked)" :expected "[32 32]" :actual "(let [fc (atom 0) gc (atom 0) s (map (fn [x] (swap! gc inc) x) (map (fn [x] (swap! fc inc) x) (range 1 50)))] (first s) [@fc @gc])" :portability :common} - {:suite "lazy / chunking" :label "filter over a chunked range applies pred to the whole first block" :expected "32" :actual "(let [c (atom 0) s (filter (fn [x] (swap! c inc) (even? x)) (range 1 50))] (first s) @c)" :portability :common} - {:suite "lazy / chunking" :label "a plain lazy seq (not chunked) realizes one element at a time" :expected "1" :actual "(let [c (atom 0) lz (fn lz [n] (lazy-seq (cons n (lz (inc n))))) s (map (fn [x] (swap! c inc) x) (lz 0))] (first s) @c)" :portability :common} - {:suite "io / with-out-str" :label "with-out-str captures (.write *out* …) and print alike" :expected "\"hi!x\"" :actual "(with-out-str (.write *out* \"hi\") (.write *out* \"!\") (print \"x\"))" :portability :jvm} - {:suite "nth / bounds" :label "nth past a vector end throws IndexOutOfBoundsException" :expected ":ok" :actual "(try (nth [1 2] 5) (catch IndexOutOfBoundsException e :ok))" :portability :common} - {:suite "nth / bounds" :label "nth past a seq end throws IndexOutOfBoundsException" :expected ":ok" :actual "(try (nth (seq [1 2]) 5) (catch IndexOutOfBoundsException e :ok))" :portability :common} - {:suite "assoc / bounds" :label "assoc past a vector end throws IndexOutOfBoundsException" :expected ":ok" :actual "(try (assoc [1 2] 5 :x) (catch IndexOutOfBoundsException e :ok))" :portability :common} - {:suite "number / toString radix" :label ".toString(radix) renders in base, lowercase" :expected "[\"ff\" \"377\" \"1001\"]" :actual "[(.toString (biginteger 255) 16) (.toString (biginteger 255) 8) (.toString (biginteger 9) 2)]" :portability :jvm} - {:suite "quote / metadata" :label "a quoted form keeps user metadata, drops reader location" :expected "[{:x true} nil]" :actual "[(meta (quote ^:x (1 2))) (meta (quote (1 2)))]" :portability :common} - {:suite "enumeration-seq" :label "enumeration-seq drives a java.util.Enumeration (StringTokenizer)" :expected "[\"1\" \"2\" \"3\"]" :actual "(vec (enumeration-seq (java.util.StringTokenizer. \"1 2 3\")))" :portability :jvm} - {:suite "protocols / interface dispatch" :label "extend-protocol to an interface a builtin implements dispatches (instance? and protocol dispatch agree)" :expected "[:assoc :ifn :seqable]" :actual "(do (defprotocol PA (ma [_])) (extend-protocol PA clojure.lang.Associative (ma [_] :assoc)) (defprotocol PF (mf [_])) (extend-protocol PF clojure.lang.IFn (mf [_] :ifn)) (defprotocol PS (ms [_])) (extend-protocol PS clojure.lang.Seqable (ms [_] :seqable)) [(ma [1 2]) (mf :k) (ms (map inc [1 2]))])" :portability :jvm} - {:suite "protocols / instance? matches dispatch" :label "instance? agrees with what a value's class implements" :expected "[true true false true true]" :actual "[(instance? clojure.lang.Associative [1 2]) (instance? clojure.lang.IFn :k) (instance? java.util.Map [1 2]) (instance? clojure.lang.Seqable (map inc [1 2])) (instance? clojure.lang.IPersistentVector [1 2])]" :portability :jvm} - {:suite "class / hierarchy views agree" :label "isa?/supers see the modeled exception + collection hierarchy" :expected "[true true true true]" :actual "[(isa? clojure.lang.ExceptionInfo java.lang.RuntimeException) (contains? (supers java.lang.NumberFormatException) java.lang.RuntimeException) (isa? clojure.lang.Keyword clojure.lang.IFn) (contains? (ancestors clojure.lang.PersistentVector) java.util.List)]" :portability :jvm} - {:suite "host-interop / getClass" :label ".getClass is a universal Object method, reached on every value type" :expected "[\"java.util.Date\" \"java.io.File\"]" :actual "[(.getName (.getClass (java.util.Date.))) (.getName (.getClass (java.io.File. \"x\")))]" :portability :jvm} - {:suite "reduce / IReduceInit" :label "reduce drives a deftype's own reduce method (init arity)" :expected "110" :actual "(do (deftype Rng [n] clojure.lang.IReduceInit (reduce [_ f init] (loop [i 0 acc init] (if (< i n) (recur (inc i) (f acc i)) acc)))) (reduce + 100 (->Rng 5)))" :portability :jvm} - {:suite "reduce / IReduceInit" :label "a deftype reduce honors reduced short-circuit" :expected "3" :actual "(do (deftype Rng [n] clojure.lang.IReduceInit (reduce [_ f init] (loop [i 0 acc init] (if (< i n) (let [a (f acc i)] (if (reduced? a) @a (recur (inc i) a))) acc)))) (reduce (fn [acc x] (if (= x 3) (reduced acc) (+ acc x))) 0 (->Rng 10)))" :portability :jvm} - {:suite "exceptions / typed throw" :label "a jolt-raised NumberFormatException reports its real class and message" :expected "[\"java.lang.NumberFormatException\" \"For input string: \\\"xyz\\\"\"]" :actual "(try (Long/parseLong \"xyz\") (catch Throwable e [(.getName (class e)) (.getMessage e)]))" :portability :jvm} - {:suite "exceptions / hierarchy catch" :label "a typed throwable matches its superclasses, not unrelated ones" :expected "[true true true false]" :actual "(let [e (try (Long/parseLong \"z\") (catch Throwable e e))] [(instance? NumberFormatException e) (instance? IllegalArgumentException e) (instance? Exception e) (instance? java.io.IOException e)])" :portability :jvm} - {:suite "equality / identity" :label "= short-circuits on identity without realizing a lazy seq (Util.equiv k1 == k2)" :expected "0" :actual "(let [n (atom 0) s (map (fn [x] (swap! n inc) x) [1 2 3])] (= s s) @n)" :portability :common} - {:suite "realized? / lazy seq" :label "realized? reads a lazy seq's realization flag" :expected "[false true]" :actual "(let [s (map inc [1 2 3])] [(realized? s) (do (doall s) (realized? s))])" :portability :common} - {:suite "numbers / ops dispatch" :label "double contagion beats exact-zero shortcut" :expected "[0.0 0.0 0.0 0.0]" :actual "[(* 1.0 0) (* 0 1.5) (/ 0 1.5) (- 0.0 0)]" :portability :common} - {:suite "numbers / ops dispatch" :label "Inf times zero is NaN" :expected "[true true]" :actual "[(NaN? (* ##Inf 0)) (NaN? (* 0 ##-Inf))]" :portability :common} - {:suite "numbers / ops dispatch" :label "zero over NaN is NaN" :expected "true" :actual "(NaN? (/ 0 ##NaN))" :portability :common} - {:suite "numbers / ops dispatch" :label "double division by exact zero is signed Inf" :expected "[##Inf ##-Inf]" :actual "[(/ 1.0 0) (/ -1.0 0)]" :portability :common} - {:suite "numbers / ops dispatch" :label "exact division by zero throws ArithmeticException" :expected "[:ae :ae :ae]" :actual "[(try (/ 1 0) (catch ArithmeticException _ :ae)) (try (/ 0) (catch ArithmeticException _ :ae)) (try (quot 1.0 0) (catch ArithmeticException _ :ae))]" :portability :common} - {:suite "numbers / ops dispatch" :label "non-number operand is ClassCastException" :expected "[:cce :cce]" :actual "[(try (+ 1 \"a\") (catch ClassCastException _ :cce)) (try (< \"a\" 1) (catch ClassCastException _ :cce))]" :portability :common} - {:suite "numbers / ops dispatch" :label "quot over ratios truncates" :expected "[6 -2 1]" :actual "[(quot 3 1/2) (quot -3 4/3) (quot 37/2 15)]" :portability :common} - {:suite "numbers / ops dispatch" :label "quot/rem double contagion" :expected "[3.0 1.5 0.0]" :actual "[(quot 10.0 3) (rem 5.5 2) (quot 1 ##Inf)]" :portability :common} - {:suite "numbers / ops dispatch" :label "mod takes the divisor's sign on doubles" :expected "[0.5 -0.5 1.5]" :actual "[(mod -5.5 2) (mod 5.5 -2) (mod 5.5 2)]" :portability :common} - {:suite "numbers / ops dispatch" :label "min/max return the original operand" :expected "[1 4.0 1M]" :actual "[(min 1 2.0) (max 3 4.0) (min 1M 2)]" :portability :common} - {:suite "numbers / ops dispatch" :label "NaN wins min/max" :expected "[true true]" :actual "[(NaN? (min 1.0 ##NaN)) (NaN? (max ##NaN 1.0))]" :portability :common} - {:suite "numbers / ops dispatch" :label "bigdec call position mixes with doubles" :expected "[3.5 1.0 true]" :actual "[(+ 1.5M 2.0) (/ 2.0M 2.0) (< 1.5M 2.0)]" :portability :common} - {:suite "numbers / ops dispatch" :label "runtime bigdec reaches call-position ops" :expected "[4M 2M true]" :actual "(let [x (bigdec 3)] [(+ x 1) (- x 1) (< 1 x)])" :portability :common} - {:suite "numbers / ops dispatch" :label "inc/dec on bigdec" :expected "[2.5M 0.5M]" :actual "[(inc 1.5M) (dec 1.5M)]" :portability :common} - {:suite "numbers / with-precision" :label "rounding modes" :expected "[2M -1M 1M -2M 2M 1M]" :actual "[(with-precision 1 :rounding UP (* 1.1M 1M)) (with-precision 1 :rounding CEILING (* -1.1M 1M)) (with-precision 1 :rounding DOWN (* 1.9M 1M)) (with-precision 1 :rounding FLOOR (* -1.9M 1M)) (with-precision 1 :rounding HALF_EVEN (* 2.5M 1M)) (with-precision 1 :rounding HALF_DOWN (* 1.5M 1M))]" :portability :common} - {:suite "numbers / with-precision" :label "UNNECESSARY throws when rounding needed, passes exact" :expected "[:ae 2M]" :actual "[(try (with-precision 1 :rounding UNNECESSARY (* 1.5M 1M)) (catch ArithmeticException _ :ae)) (with-precision 1 :rounding UNNECESSARY (* 2M 1M))]" :portability :common} - {:suite "numbers / with-precision" :label "division rounds to precision (default HALF_UP)" :expected "\"0.3333\"" :actual "(str (with-precision 4 (/ 1M 3M)))" :portability :common} - {:suite "numbers / rationalize" :label "doubles go through shortest decimal print" :expected "[11/10 3/2 1 0 -1]" :actual "[(rationalize 1.1) (rationalize 1.5) (rationalize 1.0) (rationalize 0.0) (rationalize -1.0)]" :portability :common} - {:suite "numbers / rationalize" :label "bigdec and exacts pass through exactly" :expected "[3/2 1/3 7]" :actual "[(rationalize 1.5M) (rationalize 1/3) (rationalize 7)]" :portability :common} - {:suite "hierarchy / derive asserts" :label "tag and parent must be namespaced Named (or a class)" :expected "[:ae :ae :ae :ae]" :actual "[(try (derive :a :user/p) (catch AssertionError _ :ae)) (try (derive :user/a :p) (catch AssertionError _ :ae)) (try (derive (make-hierarchy) :user/a :user/a) (catch AssertionError _ :ae)) (try (derive (make-hierarchy) :user/a \"p\") (catch AssertionError _ :ae))]" :portability :common} - {:suite "hierarchy / derive throws" :label "redundant ancestor and cyclic derivation throw" :expected "[:anc :cyc]" :actual "(let [h (derive (derive (make-hierarchy) :user/b :user/a) :user/c :user/b)] [(try (derive h :user/c :user/a) (catch Exception _ :anc)) (try (derive h :user/a :user/c) (catch Exception _ :cyc))])" :portability :common} - {:suite "hierarchy / underive" :label "a non-hierarchy first arg throws at the parents lookup" :expected "[:t :t :t]" :actual "[(try (underive {} :user/a :user/b) (catch Throwable _ :t)) (try (underive 42 :user/a :user/b) (catch Throwable _ :t)) (try (underive nil :user/a :user/b) (catch Throwable _ :t))]" :portability :common} - {:suite "hierarchy / underive" :label "underive removes the relationship" :expected "[nil false]" :actual "(let [h (derive (make-hierarchy) :user/b :user/a) h2 (underive h :user/b :user/a)] [(parents h2 :user/b) (isa? h2 :user/b :user/a)])" :portability :common} - {:suite "hierarchy / classes" :label "descendants of a class throws" :expected ":uoe" :actual "(try (descendants (make-hierarchy) java.lang.String) (catch UnsupportedOperationException _ :uoe))" :portability :jvm} - {:suite "hierarchy / classes" :label "ancestors of a concrete class roots at Object" :expected "[true true]" :actual "[(contains? (ancestors (class #{})) java.lang.Object) (contains? (ancestors (class [])) java.lang.Object)]" :portability :jvm} - {:suite "hierarchy / classes" :label "parents of a class are its direct supers" :expected "true" :actual "(contains? (parents (class [])) clojure.lang.APersistentVector)" :portability :jvm} - {:suite "hierarchy / classes" :label "a relationship derived on a super applies to the class (isa? supers arm)" :expected "true" :actual "(let [h (derive (make-hierarchy) java.util.Collection :user/coll-like)] (isa? h (class []) :user/coll-like))" :portability :jvm} - {:suite "iref / atom ctor options" :label ":meta attaches, :validator gates the initial value" :expected "[{:m 1} 1 nil]" :actual "(let [a (atom 1 :meta {:m 1} :validator pos?)] [(meta a) (deref a) (meta (atom nil :meta nil))])" :portability :common} - {:suite "iref / atom ctor options" :label "non-map :meta is a ClassCastException" :expected "[:cce :cce]" :actual "[(try (atom nil :meta 5) (catch ClassCastException _ :cce)) (try (atom nil :meta #{}) (catch ClassCastException _ :cce))]" :portability :common} - {:suite "iref / atom ctor options" :label "an invalid initial value never constructs" :expected ":ise" :actual "(try (atom {} :validator (constantly false)) (catch IllegalStateException _ :ise))" :portability :common} - {:suite "iref / atom ctor options" :label "validator still gates swap!/reset!" :expected "[:ise 1]" :actual "(let [a (atom 1 :validator pos?)] [(try (reset! a -1) (catch IllegalStateException _ :ise)) (deref a)])" :portability :common} - {:suite "iref / watches" :label "an atom watch gets key, the ref, old and new" :expected "[:k true 0 1]" :actual "(let [a (atom 0) w (atom nil)] (add-watch a :k (fn [k r o n] (reset! w [k (identical? r a) o n]))) (swap! a inc) (deref w))" :portability :common} - {:suite "iref / watches" :label "vars are watchable: root changes notify (alter-var-root, def)" :expected "[[1 2] [2 5]]" :actual "(do (def vw-x 1) (def vw-log (atom [])) (add-watch (var vw-x) :w (fn [k r o n] (swap! vw-log conj [o n]))) (alter-var-root (var vw-x) inc) (def vw-x 5) (deref vw-log))" :portability :common} - {:suite "iref / watches" :label "add-watch returns the var; a validator gates the var root" :expected "[true :ise]" :actual "(do (def vv-y 1) [(= (var vv-y) (add-watch (var vv-y) :k (fn [a b c d] nil))) (do (set-validator! (var vv-y) pos?) (try (alter-var-root (var vv-y) -) (catch IllegalStateException _ :ise)))])" :portability :common} - {:suite "iref / watches" :label "agent watches fire on state change" :expected "[0 1]" :actual "(let [ag (agent 0) p (promise)] (add-watch ag :w (fn [k r o n] (deliver p [o n]))) (send ag inc) (deref p 2000 :timeout))" :portability :common} - {:suite "iref / meta" :label "alter-meta! works on atoms" :expected "{:x 1 :y 2}" :actual "(let [a (atom 1 :meta {:x 1})] (alter-meta! a assoc :y 2))" :portability :common} - {:suite "casts / checked narrow" :label "doubles range-check themselves, then truncate" :expected "[1 1 3 1 \\a 0]" :actual "[(byte 1.1) (short 1.9) (int 3.7) (long 1.5) (char 97.5) (long ##NaN)]" :portability :common} - {:suite "casts / checked narrow" :label "out-of-range values throw IllegalArgumentException" :expected "[:iae :iae :iae :iae :iae :iae :iae]" :actual "[(try (byte 128) (catch IllegalArgumentException _ :iae)) (try (byte 127.000001) (catch IllegalArgumentException _ :iae)) (try (short 40000) (catch IllegalArgumentException _ :iae)) (try (int 2147483647.000001) (catch IllegalArgumentException _ :iae)) (try (char -1) (catch IllegalArgumentException _ :iae)) (try (char 65536) (catch IllegalArgumentException _ :iae)) (try (long 1e300) (catch IllegalArgumentException _ :iae))]" :portability :common} - {:suite "casts / checked narrow" :label "the throw carries the JVM message" :expected "\"Value out of range for byte: 128\"" :actual "(try (byte 128) (catch IllegalArgumentException e (ex-message e)))" :portability :common} - {:suite "casts / checked narrow" :label "ratios and bigdecs truncate; non-numbers are CCE" :expected "[1 5 :cce]" :actual "[(byte 3/2) (int 5.5M) (try (byte true) (catch ClassCastException _ :cce))]" :portability :common} - {:suite "casts / checked narrow" :label "float range-checks against Float/MAX_VALUE" :expected "[:iae 1.5]" :actual "[(try (float 1e300) (catch IllegalArgumentException _ :iae)) (float 1.5)]" :portability :common} - {:suite "casts / unchecked wrap" :label "unchecked casts wrap and sign-fold; doubles saturate" :expected "[-56 -25536 \\A 9223372036854775807 0 0]" :actual "[(unchecked-byte 200) (unchecked-short 40000) (unchecked-char 65) (unchecked-long 1e300) (unchecked-int 4294967296) (unchecked-long ##NaN)]" :portability :common} - {:suite "ns / requiring-resolve" :label "loads the namespace then resolves; unqualified throws" :expected "[#{1 2} :iae]" :actual "[((requiring-resolve (quote clojure.set/union)) #{1} #{2}) (try (requiring-resolve (quote unqualified)) (catch IllegalArgumentException _ :iae))]" :portability :common} - {:suite "string / toString coercion" :label "case fns and searches take any Object through toString" :expected "[\":ASDF/X\" \"asdf\" \"1\" true true]" :actual "[(clojure.string/upper-case :asdf/x) (clojure.string/lower-case (quote ASDF)) (clojure.string/capitalize 1) (clojure.string/starts-with? :ab \":a\") (clojure.string/ends-with? (quote ab) \"b\")]" :portability :common} - {:suite "string / toString coercion" :label "nil s throws; nil substr throws" :expected "[:t :t :t]" :actual "[(try (clojure.string/upper-case nil) (catch Throwable _ :t)) (try (clojure.string/starts-with? \"\" nil) (catch Throwable _ :t)) (try (clojure.string/escape nil {}) (catch Throwable _ :t))]" :portability :common} - {:suite "core / some-fn" :label "returns the last predicate value (false, not nil); zero preds is an arity error" :expected "[false 2 :ae]" :actual "[((some-fn even?) 1) ((some-fn :a :b) {:b 2}) (try (some-fn) (catch clojure.lang.ArityException _ :ae))]" :portability :jvm} - {:suite "core / ifn?" :label "multimethods and promises are IFn; promises deliver when invoked" :expected "[true true 7]" :actual "[(do (defmulti ifnq-mm identity) (ifn? ifnq-mm)) (ifn? (promise)) (let [p (promise)] (p 7) (deref p))]" :portability :common} - {:suite "multimethods / deferred definition" :label "defmulti/defmethod inside a fn intern in the ns they were written in" :expected ":hit" :actual "((fn [] (defmulti cdm-deferred first) (defmethod cdm-deferred :a [_] :hit) (cdm-deferred [:a 1])))" :portability :common} - {:suite "host-interop / wrapper ctors and TYPE" :label "Boolean/Integer/Double ctors; primitive TYPE tokens" :expected "[false true 12 1.5 \"int\" \"double\"]" :actual "[(Boolean. \"yes\") (Boolean. \"TRUE\") (Integer. \"12\") (Double. \"1.5\") (str Integer/TYPE) (str Double/TYPE)]" :portability :jvm} - {:suite "host-interop / IReduce" :label ".reduce drives a collection's own reduce" :expected "[7 6]" :actual "[(.reduce [1 2 3] + 1) (.reduce [1 2 3] +)]" :portability :jvm} - {:suite "edn / strictness" :label "duplicate literal keys and elements throw" :expected "[:dup :dup]" :actual "[(try (clojure.edn/read-string \"{:a 1 :a 2}\") (catch IllegalArgumentException _ :dup)) (try (clojure.edn/read-string \"#{:a :a}\") (catch IllegalArgumentException _ :dup))]" :portability :common} - {:suite "edn / strictness" :label "invalid numbers and ratio edges throw" :expected "[:ae :nfe :nfe :nfe :nfe]" :actual "[(try (clojure.edn/read-string \"1/0\") (catch ArithmeticException _ :ae)) (try (clojure.edn/read-string \"1/-1\") (catch NumberFormatException _ :nfe)) (try (clojure.edn/read-string \"08\") (catch NumberFormatException _ :nfe)) (try (clojure.edn/read-string \"1a\") (catch NumberFormatException _ :nfe)) (try (clojure.edn/read-string \"0x2g\") (catch NumberFormatException _ :nfe))]" :portability :common} - {:suite "edn / strictness" :label "invalid tokens throw; :/ and ns// are valid" :expected "[:t :t :t :t \"/\" \"/\"]" :actual "[(try (clojure.edn/read-string \"::foo\") (catch Throwable _ :t)) (try (clojure.edn/read-string \":\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"foo/\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"/foo\") (catch Throwable _ :t)) (name (clojure.edn/read-string \":/\")) (name (clojure.edn/read-string \"foo//\"))]" :portability :common} - {:suite "edn / strictness" :label "unmatched delimiters, bad escapes, octal range throw" :expected "[:t :t :t :t]" :actual "[(try (clojure.edn/read-string \")\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"]\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"\\\"\\\\q\\\"\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"\\\\o400\") (catch Throwable _ :t))]" :portability :common} - {:suite "edn / strictness" :label "eof honors :eof; a missing :eof is an error; \\r ends comments" :expected "[:END :t 3]" :actual "[(clojure.edn/read-string {:eof :END} \"\") (try (clojure.edn/read-string {} \" \") (catch Throwable _ :t)) (clojure.edn/read-string \";c\\r3\\n5\")]" :portability :common} - {:suite "edn / strictness" :label "M literals construct; lists are lists; discarded tags validate" :expected "[-3.14M true :t]" :actual "[(clojure.edn/read-string \"-3.14M\") (list? (clojure.edn/read-string \"(1 (2))\")) (try (clojure.edn/read-string \"#_ #foo 0\") (catch Throwable _ :t))]" :portability :common} - {:suite "edn / strictness" :label "#inst and #uuid validate their fields" :expected "[:t :t :t]" :actual "[(try (clojure.edn/read-string \"#inst \\\"2010-02-29T00:00:00.000Z\\\"\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"#inst \\\"2010-01-01T24:00:00.000Z\\\"\") (catch Throwable _ :t)) (try (clojure.edn/read-string \"#uuid \\\"not-a-uuid\\\"\") (catch Throwable _ :t))]" :portability :common} - {:suite "reader / strict tokens" :label "the core reader rejects invalid numbers and duplicate keys too" :expected "[:nfe :dup 34]" :actual "[(try (read-string \"1a\") (catch NumberFormatException _ :nfe)) (try (read-string \"{:a 1 :a 2}\") (catch IllegalArgumentException _ :dup)) (read-string \"042\")]" :portability :common} - {:suite "reader / symbol intern" :label "1-arg symbol splits ns at the first slash (Symbol.intern)" :expected "[\"foo\" \"bar/baz\" \"/\"]" :actual "[(namespace (symbol \"foo/bar/baz\")) (name (symbol \"foo/bar/baz\")) (name (symbol \"foo//\"))]" :portability :common} - {:suite "contracts / stacks and pending" :label "peek/pop demand a stack; realized? demands IPending; pop nil is nil" :expected "[:cce :cce nil nil nil]" :actual "[(try (peek (range 10)) (catch ClassCastException _ :cce)) (try (realized? (quote (1 2))) (catch ClassCastException _ :cce)) (pop nil) (nth nil 10) (conj nil)]" :portability :common} - {:suite "contracts / collection fns" :label "keys/vals of empties are nil; contains? on a string is index-only" :expected "[nil nil nil :iae true false]" :actual "[(keys []) (vals #{}) (keys \"\") (try (contains? \"abc\" \"a\") (catch IllegalArgumentException _ :iae)) (contains? \"abc\" 1) (contains? \"abc\" 5)]" :portability :common} - {:suite "contracts / collection fns" :label "transient demands an editable collection; empty on a record throws" :expected "[:cce :uoe]" :actual "[(try (transient 1) (catch ClassCastException _ :cce)) (do (defrecord EmptyRec [a]) (try (empty (->EmptyRec 1)) (catch UnsupportedOperationException _ :uoe)))]" :portability :common} - {:suite "contracts / numbers" :label "numerator/denominator over real ratios; even?/odd? demand integers" :expected "[1 3 :cce :iae]" :actual "[(numerator 1/2) (denominator 2/3) (try (numerator 2) (catch ClassCastException _ :cce)) (try (even? 1.5) (catch IllegalArgumentException _ :iae))]" :portability :common} - {:suite "contracts / numbers" :label "number?/rational?/num accept BigDecimal; NaN quotient throws" :expected "[true true 1.5M :nfe]" :actual "[(number? 1.5M) (rational? 1M) (num 1.5M) (try (quot ##NaN 1) (catch NumberFormatException _ :nfe))]" :portability :common} - {:suite "contracts / ordering" :label "keywords order namespace-first with nil first, like symbols" :expected "[true true true]" :actual "[(neg? (compare :cat :animal/cat)) (neg? (compare :animal/cat :b/cat)) (zero? (compare :dog :dog))]" :portability :common} - {:suite "contracts / misc" :label "vector invocation has nth semantics; run! honors reduced; eval self-evaluates values" :expected "[:ioob 1 true]" :actual "[(try ([1 2] 5) (catch IndexOutOfBoundsException _ :ioob)) (let [c (atom 0)] (run! (fn [x] (swap! c inc) (reduced x)) [1 2 3]) (deref c)) (fn? (eval +))]" :portability :common} - {:suite "contracts / misc" :label "intern demands an existing ns; counted? excludes strings; seqable? includes arrays" :expected "[:t false true]" :actual "[(try (intern (quote no-such-ns-xyz) (quote v) 1) (catch Throwable _ :t)) (counted? \"s\") (seqable? (object-array 2))]" :portability :jvm} - {:suite "contracts / misc" :label "nth of nil honors notFound; a nil index throws; the starred specials are special" :expected "[:default :npe [true true true true true]]" :actual "[(nth nil 5 :default) (try (nth [1] nil) (catch NullPointerException _ :npe)) [(special-symbol? (quote case*)) (special-symbol? (quote deftype*)) (special-symbol? (quote letfn*)) (special-symbol? (quote reify*)) (special-symbol? (quote &))]]" :portability :common} - {:suite "contracts / misc" :label "rand-nth of nil is nil; of a set throws" :expected "[nil :t]" :actual "[(rand-nth nil) (try (rand-nth #{1 2}) (catch Throwable _ :t))]" :portability :common} + {:suite "destructure / :or" :label "map default when key absent" :expected "9" :actual "(let [{x :x :or {x 9}} {}] x)"} + {:suite "destructure / :or" :label "kwargs default when key absent" :expected "9" :actual "((fn [& {x :x :or {x 9}}] x))"} + {:suite "destructure / :or" :label "default not used when key present" :expected "5" :actual "(let [{x :x :or {x 9}} {:x 5}] x)"} + {:suite "deftype / field access" :label ".field reads a deftype field" :expected "7" :actual "(do (deftype FldT [q]) (.q (->FldT 7)))"} + {:suite "fn / pre-post" :label ":pre + :post pass" :expected "5" :actual "(do (defn ppf [x] {:pre [(pos? x)] :post [(= % x)]} x) (ppf 5))"} + {:suite "fn / pre-post" :label ":pre failure throws" :expected ":blocked" :actual "(do (defn ppg [x] {:pre [(pos? x)]} x) (try (ppg -1) (catch Throwable _ :blocked)))"} + {:suite "deftype / map-like dispatch" :label "dissoc + keys via IPersistentMap/Seqable methods" :expected "[:b]" :actual "(do (deftype MapT [m] clojure.lang.Seqable (seq [_] (seq m)) clojure.lang.IPersistentMap (without [_ k] (->MapT (dissoc m k))) (assoc [_ k v] (->MapT (assoc m k v)))) (vec (keys (dissoc (->MapT {:a 1 :b 2}) :a))))"} + {:suite "delay / exception memoization" :label "throwing body runs once, stays realized, re-throws" :expected "[1 true]" :actual "(let [n (atom 0) d (delay (swap! n inc) (throw (ex-info \"e\" {})))] (dotimes [_ 3] (try (deref d) (catch Throwable _ nil))) [(deref n) (realized? d)])"} + {:suite "queue / pop" :label "pop of empty PersistentQueue returns empty" :expected "nil" :actual "(seq (pop clojure.lang.PersistentQueue/EMPTY))"} + {:suite "interop / iterator-seq" :label "iterator-seq over .iterator" :expected "[:a :b]" :actual "(vec (iterator-seq (.iterator [:a :b])))"} + {:suite "deftype / IPersistentStack" :label "peek/pop dispatch" :expected "[1 [2 3]]" :actual "(do (deftype Stk [v] clojure.lang.IPersistentStack (peek [_] (first v)) (pop [_] (->Stk (rest v)))) [(peek (->Stk [1 2 3])) (vec (.v (pop (->Stk [1 2 3]))))])"} + {:suite "deftype / equiv" :label "(= deftype other) uses equiv method" :expected "true" :actual "(do (deftype EqT [m] clojure.lang.IPersistentCollection (equiv [_ o] (= o m)) clojure.lang.Seqable (seq [_] (seq m))) (= (->EqT {:a 1}) {:a 1}))"} + {:suite "interop / Thread" :label "start + join runs the thunk" :expected "7" :actual "(let [a (atom 0) t (Thread. (fn [] (reset! a 7)))] (.start t) (.join t) (deref a))"} + {:suite "interop / CountDownLatch" :label "countDown to zero, await returns" :expected "0" :actual "(let [l (java.util.concurrent.CountDownLatch. 1)] (.countDown l) (.await l) (.getCount l))"} + {:suite "interop / SoftReference" :label "get returns the referent" :expected ":v" :actual "(.get (java.lang.ref.SoftReference. :v))"} + {:suite "interop / System.gc" :label "gc runs and returns" :expected "42" :actual "(do (System/gc) 42)"} + {:suite "interop / ConcurrentHashMap" :label "put + get/count/contains?" :expected "[1 1 true]" :actual "(let [m (java.util.concurrent.ConcurrentHashMap.)] (.put m :a 1) [(get m :a) (count m) (contains? m :a)])"} + {:suite "interop / Class.forName" :label "unknown class throws ClassNotFoundException" :expected ":nf" :actual "(try (Class/forName \"no.such.Klass\") (catch ClassNotFoundException _ :nf))"} + {:suite "interop / Class.forName" :label "known class resolves" :expected "\"java.lang.String\"" :actual "(.getName (Class/forName \"java.lang.String\"))"} + {:suite "clojure.string / replace" :label "char match and replacement" :expected "\"a-b-c\"" :actual "(clojure.string/replace \"a/b/c\" \\/ \\-)"} + {:suite "clojure.string / replace" :label "char match, string replacement" :expected "\"x_y\"" :actual "(clojure.string/replace \"x.y\" \\. \"_\")"} + {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^ type hint on a param" :expected "\"x\"" :actual "(do (defn f1 [#^String s] s) (f1 \"x\"))"} + {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^\"[B\" array hint" :expected "[1 2]" :actual "(do (defn f2 [#^\"[B\" b] b) (f2 [1 2]))"} + {:suite "interop-fixes / deprecated #^ metadata reader" :label "#^ is equivalent to ^" :expected "true" :actual "(= (meta (with-meta [] {:tag (quote String)})) {:tag (quote String)})"} + {:suite "interop-fixes / (str pattern) yields raw source" :label "str of a regex" :expected "\"abc\"" :actual "(str #\"abc\")"} + {:suite "interop-fixes / (str pattern) yields raw source" :label "compose patterns via str" :expected "true" :actual "(boolean (re-matches (re-pattern (str #\"<\" \"(.*)\" \">\")) \"\"))"} + {:suite "interop-fixes / into onto a map" :label "merges map items" :expected "true" :actual "(= {:a 1 :b 2} (into {} [{:a 1} {:b 2}]))"} + {:suite "interop-fixes / into onto a map" :label "accepts [k v] pairs" :expected "true" :actual "(= {:a 1} (into {} [[:a 1]]))"} + {:suite "interop-fixes / into onto a map" :label "map item onto empty {}" :expected "true" :actual "(= {:x 1} (into {} (list {:x 1})))"} + {:suite "interop-fixes / into onto a map" :label "conj a map onto {}" :expected "true" :actual "(= {:a 1} (conj {} {:a 1}))"} + {:suite "interop-fixes / a var is callable as its value" :label "call a var directly" :expected "42" :actual "(do (def vf (fn [x] (inc x))) ((var vf) 41))"} + {:suite "interop-fixes / a var is callable as its value" :label "var bound as a client fn" :expected "\"ok\"" :actual "(do (def base (fn [_] \"ok\")) (def mw (fn [client] (fn [req] (client req)))) ((mw (var base)) {}))"} + {:suite "control / conditionals" :label "if true" :expected "1" :actual "(if true 1 2)"} + {:suite "control / conditionals" :label "if false" :expected "2" :actual "(if false 1 2)"} + {:suite "control / conditionals" :label "if nil is false" :expected "2" :actual "(if nil 1 2)"} + {:suite "control / conditionals" :label "if no else" :expected "nil" :actual "(if false 1)"} + {:suite "control / conditionals" :label "when true" :expected "3" :actual "(when true 1 2 3)"} + {:suite "control / conditionals" :label "when false" :expected "nil" :actual "(when false 1)"} + {:suite "control / conditionals" :label "when-not" :expected "1" :actual "(when-not false 1)"} + {:suite "control / conditionals" :label "cond" :expected ":b" :actual "(cond false :a true :b :else :c)"} + {:suite "control / conditionals" :label "cond :else" :expected ":c" :actual "(cond false :a false :b :else :c)"} + {:suite "control / conditionals" :label "cond no match" :expected "nil" :actual "(cond false :a)"} + {:suite "control / conditionals" :label "condp" :expected "\"two\"" :actual "(condp = 2 1 \"one\" 2 \"two\" \"other\")"} + {:suite "control / conditionals" :label "case" :expected ":b" :actual "(case 2 1 :a 2 :b :default)"} + {:suite "control / conditionals" :label "case default" :expected ":d" :actual "(case 9 1 :a 2 :b :d)"} + {:suite "control / conditionals" :label "case multi" :expected ":ab" :actual "(case 2 (1 2) :ab 3 :c)"} + {:suite "control / conditionals" :label "case symbol const" :expected ":s" :actual "(case 'foo foo :s :default)"} + {:suite "control / conditionals" :label "case vector const" :expected ":v" :actual "(case [1 2] [1 2] :v :default)"} + {:suite "control / conditionals" :label "case map const" :expected ":m" :actual "(case {:a 1} {:a 1} :m :default)"} + {:suite "control / conditionals" :label "case list const" :expected ":l" :actual "(case '(a b) (quote (a b)) :l :default)"} + {:suite "control / conditionals" :label "case keyword" :expected ":k" :actual "(case :x :x :k :default)"} + {:suite "control / logic" :label "and all true" :expected "3" :actual "(and 1 2 3)"} + {:suite "control / logic" :label "and short circuits" :expected "nil" :actual "(and 1 nil 3)"} + {:suite "control / logic" :label "and empty" :expected "true" :actual "(and)"} + {:suite "control / logic" :label "or first truthy" :expected "1" :actual "(or nil 1 2)"} + {:suite "control / logic" :label "or all false" :expected "false" :actual "(or nil false)"} + {:suite "control / logic" :label "or empty" :expected "nil" :actual "(or)"} + {:suite "control / logic" :label "not" :expected "false" :actual "(not true)"} + {:suite "control / let & loop" :label "let" :expected "3" :actual "(let [a 1 b 2] (+ a b))"} + {:suite "control / let & loop" :label "let sequential" :expected "3" :actual "(let [a 1 b (+ a 2)] b)"} + {:suite "control / let & loop" :label "let shadowing" :expected "2" :actual "(let [a 1] (let [a 2] a))"} + {:suite "control / let & loop" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] (ev? 10))"} + {:suite "control / let & loop" :label "loop/recur" :expected "15" :actual "(loop [i 1 acc 0] (if (> i 5) acc (recur (inc i) (+ acc i))))"} + {:suite "control / let & loop" :label "when-let" :expected "2" :actual "(when-let [x 1] (inc x))"} + {:suite "control / let & loop" :label "when-let nil" :expected "nil" :actual "(when-let [x nil] (inc x))"} + {:suite "control / let & loop" :label "if-let" :expected "2" :actual "(if-let [x 1] (inc x) :none)"} + {:suite "control / let & loop" :label "if-let else" :expected ":none" :actual "(if-let [x nil] (inc x) :none)"} + {:suite "control / let & loop" :label "if-some zero" :expected "1" :actual "(if-some [x 0] (inc x) :none)"} + {:suite "control / let & loop" :label "when-some nil" :expected "nil" :actual "(when-some [x nil] x)"} + {:suite "control / conditional-binding scope" :label "if-let else sees outer" :expected "5" :actual "(let [x 5] (if-let [x nil] :then x))"} + {:suite "control / conditional-binding scope" :label "if-let then binds" :expected "7" :actual "(let [x 5] (if-let [x 7] x :else))"} + {:suite "control / conditional-binding scope" :label "if-some else sees outer" :expected "5" :actual "(let [x 5] (if-some [x nil] :then x))"} + {:suite "control / conditional-binding scope" :label "if-some binds false" :expected "false" :actual "(if-some [x false] x :else)"} + {:suite "control / conditional-binding scope" :label "when-let else via or" :expected "5" :actual "(let [x 5] (or (when-let [x nil] x) x))"} + {:suite "control / conditional-binding scope" :label "when-let multi-form body" :expected "14" :actual "(when-let [x 7] (inc x) (* x 2))"} + {:suite "control / conditional-binding scope" :label "if-let in fn param" :expected "9" :actual "((fn [xs] (if-let [xs nil] :then xs)) 9)"} + {:suite "control / conditional-binding scope" :label "when-some binds zero" :expected "1" :actual "(when-some [x 0] (inc x))"} + {:suite "control / conditional-binding scope" :label "if-let evals test once" :expected "1" :actual "(let [c (atom 0)] (if-let [v (do (swap! c inc) :v)] @c :none))"} + {:suite "control / loop lowering" :label "closure captures per-iter binding" :expected "[0 1 2]" :actual "(mapv (fn [g] (g)) (loop [i 0 fs []] (if (< i 3) (recur (inc i) (conj fs (fn [] i))) fs)))"} + {:suite "control / loop lowering" :label "fib via loop" :expected "55" :actual "(loop [a 0 b 1 i 0] (if (= i 10) a (recur b (+ a b) (inc i))))"} + {:suite "control / loop lowering" :label "recur args no clobber" :expected "[2 1]" :actual "(loop [a 1 b 2 n 0] (if (= n 1) [a b] (recur b a (inc n))))"} + {:suite "control / loop lowering" :label "nested loops" :expected "9" :actual "(loop [i 0 s 0] (if (= i 3) s (recur (inc i) (loop [j 0 t s] (if (= j 3) t (recur (inc j) (inc t)))))))"} + {:suite "control / loop lowering" :label "loop sequential init" :expected "12" :actual "(loop [a 1 b (+ a 10)] (+ a b))"} + {:suite "control / loop lowering" :label "recur through let" :expected "6" :actual "(loop [i 0 acc 0] (let [x (* i 2)] (if (< i 3) (recur (inc i) (+ acc x)) acc)))"} + {:suite "control / loop lowering" :label "fn-arity recur intact" :expected "15" :actual "((fn f [n acc] (if (zero? n) acc (recur (dec n) (+ acc n)))) 5 0)"} + {:suite "control / iteration" :label "dotimes side-effect" :expected "5" :actual "(let [a (atom 0)] (dotimes [i 5] (swap! a inc)) @a)"} + {:suite "control / iteration" :label "while" :expected "5" :actual "(let [a (atom 0)] (while (< @a 5) (swap! a inc)) @a)"} + {:suite "control / iteration" :label "for" :expected "[0 1 2]" :actual "(for [x (range 3)] x)"} + {:suite "control / iteration" :label "for nested" :expected "[[0 :a] [0 :b] [1 :a] [1 :b]]" :actual "(for [x (range 2) y [:a :b]] [x y])"} + {:suite "control / iteration" :label "for :when" :expected "[0 2 4]" :actual "(for [x (range 6) :when (even? x)] x)"} + {:suite "control / iteration" :label "for :while" :expected "[0 1 2]" :actual "(for [x (range 10) :while (< x 3)] x)"} + {:suite "control / iteration" :label "for :let" :expected "[0 1 4]" :actual "(for [x (range 3) :let [sq (* x x)]] sq)"} + {:suite "control / iteration" :label "for :let+:when" :expected "[4 6 8]" :actual "(for [x (range 5) :let [y (* x 2)] :when (> y 3)] y)"} + {:suite "control / iteration" :label "for multi :when" :expected "[[1 :a] [1 :b]]" :actual "(for [x [0 1] :when (odd? x) y [:a :b]] [x y])"} + {:suite "control / iteration" :label "for destructure" :expected "[3 7]" :actual "(for [[a b] [[1 2] [3 4]]] (+ a b))"} + {:suite "control / iteration" :label "doseq side-effect" :expected "6" :actual "(let [a (atom 0)] (doseq [x [1 2 3]] (swap! a (fn [v] (+ v x)))) @a)"} + {:suite "control / iteration" :label "doseq nested" :expected "4" :actual "(let [c (atom 0)] (doseq [x [1 2] y [10 20]] (swap! c inc)) @c)"} + {:suite "control / iteration" :label "doseq :when" :expected "[1 3]" :actual "(let [a (atom [])] (doseq [x [1 2 3] :when (odd? x)] (swap! a conj x)) @a)"} + {:suite "control / iteration" :label "doseq :while" :expected "6" :actual "(let [a (atom 0)] (doseq [x (range 10) :while (< x 4)] (swap! a + x)) @a)"} + {:suite "control / iteration" :label "doseq :let" :expected "[0 1 4]" :actual "(let [a (atom [])] (doseq [x (range 3) :let [sq (* x x)]] (swap! a conj sq)) @a)"} + {:suite "control / iteration" :label "doseq returns nil" :expected "nil" :actual "(doseq [x [1 2 3]] x)"} + {:suite "control / threading" :label "->" :expected "6" :actual "(-> 1 inc (+ 4))"} + {:suite "control / threading" :label "-> with forms" :expected "[1 2 3]" :actual "(-> [] (conj 1) (conj 2) (conj 3))"} + {:suite "control / threading" :label "->>" :expected "9" :actual "(->> [1 2 3] (map inc) (reduce +))"} + {:suite "control / threading" :label "as->" :expected "2" :actual "(as-> [0 1] x (map inc x) (reverse x) (first x))"} + {:suite "control / threading" :label "some->" :expected "2" :actual "(some-> 1 inc)"} + {:suite "control / threading" :label "some-> nil stops" :expected "nil" :actual "(some-> nil inc)"} + {:suite "control / threading" :label "some->>" :expected "[2 3]" :actual "(some->> [1 2] (map inc))"} + {:suite "control / threading" :label "cond->" :expected "2" :actual "(cond-> 1 true inc false inc)"} + {:suite "control / threading" :label "cond->>" :expected "[1 2]" :actual "(cond->> [2] true (cons 1))"} + {:suite "control / threading" :label "doto returns subject" :expected "5" :actual "(let [a (doto (atom 0) (reset! 5))] @a)"} + {:suite "deftype / custom toString" :label ".toString uses the method" :expected "\"hi\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (.toString (->Foo \"hi\")))"} + {:suite "deftype / custom toString" :label "str uses the method" :expected "\"hi\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (str (->Foo \"hi\")))"} + {:suite "deftype / custom toString" :label "str concatenation uses it" :expected "\"\"" :actual "(do (deftype Foo [s] Object (toString [_] s)) (str \"<\" (->Foo \"hi\") \">\"))"} + {:suite "deftype / custom toString" :label "computed toString" :expected "\"v=7\"" :actual "(do (deftype Boxed [v] Object (toString [_] (str \"v=\" v))) (str (->Boxed 7)))"} + {:suite "deftype / custom toString" :label "defrecord without toString keeps repr" :expected "true" :actual "(do (defrecord Bar [x]) (boolean (re-find #\"Bar\" (str (->Bar 1)))))"} + {:suite "deftype / custom toString" :label "pr-str of a defrecord is the repr" :expected "true" :actual "(do (defrecord Baz [x]) (boolean (re-find #\"\\{\" (pr-str (->Baz 1)))))"} + {:suite "destructure / sequential" :label "basic vector" :expected "3" :actual "(let [[a b] [1 2]] (+ a b))"} + {:suite "destructure / sequential" :label "skip with _" :expected "3" :actual "(let [[_ b] [1 2]] (+ b 1))"} + {:suite "destructure / sequential" :label "rest with &" :expected "[3 4]" :actual "(let [[a & more] [1 3 4]] more)"} + {:suite "destructure / sequential" :label ":as whole" :expected "[1 2]" :actual "(let [[a :as v] [1 2]] v)"} + {:suite "destructure / sequential" :label "nested" :expected "3" :actual "(let [[[a b]] [[1 2]]] (+ a b))"} + {:suite "destructure / sequential" :label "fewer values nil" :expected "nil" :actual "(let [[a b c] [1 2]] c)"} + {:suite "destructure / sequential" :label "over a list" :expected "1" :actual "(let [[a] (list 1 2)] a)"} + {:suite "destructure / sequential" :label "over a seq" :expected "2" :actual "(let [[a b] (rest [9 1 2])] b)"} + {:suite "destructure / sequential" :label "string chars" :expected "\\a" :actual "(let [[a] (seq \"ab\")] a)"} + {:suite "destructure / associative" :label "keys" :expected "3" :actual "(let [{:keys [a b]} {:a 1 :b 2}] (+ a b))"} + {:suite "destructure / associative" :label ":as map" :expected "{:a 1}" :actual "(let [{:as m} {:a 1}] m)"} + {:suite "destructure / associative" :label ":or default" :expected "9" :actual "(let [{:keys [a] :or {a 9}} {}] a)"} + {:suite "destructure / associative" :label ":or present" :expected "1" :actual "(let [{:keys [a] :or {a 9}} {:a 1}] a)"} + {:suite "destructure / associative" :label "explicit binding" :expected "1" :actual "(let [{x :a} {:a 1}] x)"} + {:suite "destructure / associative" :label "nested map" :expected "2" :actual "(let [{{b :b} :a} {:a {:b 2}}] b)"} + {:suite "destructure / associative" :label "keys + as" :expected "[1 {:a 1}]" :actual "(let [{:keys [a] :as m} {:a 1}] [a m])"} + {:suite "destructure / associative" :label "map in vector" :expected "1" :actual "(let [[{:keys [a]}] [{:a 1}]] a)"} + {:suite "destructure / in forms" :label "fn params" :expected "3" :actual "((fn [[a b]] (+ a b)) [1 2])"} + {:suite "destructure / in forms" :label "fn map param" :expected "1" :actual "((fn [{:keys [a]}] a) {:a 1})"} + {:suite "destructure / in forms" :label "defn destructure" :expected "3" :actual "(do (defn f [[a b]] (+ a b)) (f [1 2]))"} + {:suite "destructure / in forms" :label "loop destructure" :expected "3" :actual "(loop [[a b] [1 2]] (+ a b))"} + {:suite "destructure / in forms" :label "doseq destructure" :expected "12" :actual "(let [s (atom 0)] (doseq [[k v] {:a 4 :b 8}] (swap! s (fn [x] (+ x v)))) @s)"} + {:suite "destructure / in forms" :label "for destructure" :expected "[3 7]" :actual "(for [[a b] [[1 2] [3 4]]] (+ a b))"} + {:suite "destructure / in forms" :label "& rest in fn" :expected "[2 3]" :actual "((fn [a & more] more) 1 2 3)"} + {:suite "destructure / associative extras" :label ":strs" :expected "7" :actual "(let [{:strs [a]} {\"a\" 7}] a)"} + {:suite "destructure / associative extras" :label ":syms" :expected "8" :actual "(let [{:syms [a]} {(quote a) 8}] a)"} + {:suite "destructure / associative extras" :label "namespaced :keys" :expected "3" :actual "(let [{:keys [x/y]} {:x/y 3}] y)"} + {:suite "destructure / associative extras" :label "namespaced :syms" :expected "4" :actual "(let [{:syms [p/q]} {(quote p/q) 4}] q)"} + {:suite "destructure / associative extras" :label "keyword :keys" :expected "3" :actual "(let [{:keys [:a :b]} {:a 1 :b 2}] (+ a b))"} + {:suite "destructure / associative extras" :label "keyword :keys ns" :expected "3" :actual "(let [{:keys [:x/y]} {:x/y 3}] y)"} + {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs" :expected "[1 2]" :actual "(do (defn f [& {:keys [a b]}] [a b]) (f :a 1 :b 2))"} + {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs + fixed" :expected "[0 5]" :actual "(do (defn g [x & {:keys [a]}] [x a]) (g 0 :a 5))"} + {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs :or" :expected "9" :actual "(do (defn h [& {:keys [a] :or {a 9}}] a) (h))"} + {:suite "destructure / keyword args (& {:keys})" :label "fn kwargs trailing map" :expected "7" :actual "(do (defn k [& {:keys [a]}] a) (k {:a 7}))"} + {:suite "destructure / fn params & loop" :label "fn vector param" :expected "7" :actual "((fn [[a b]] (+ a b)) [3 4])"} + {:suite "destructure / fn params & loop" :label "fn map param" :expected "30" :actual "((fn [{:keys [x y]}] (* x y)) {:x 5 :y 6})"} + {:suite "destructure / fn params & loop" :label "fn :or param" :expected "7" :actual "((fn [{:keys [x] :or {x 7}}] x) {})"} + {:suite "destructure / fn params & loop" :label "fn multi-arity destr" :expected "15" :actual "((fn ([[a]] a) ([[a] b] (+ a b))) [10] 5)"} + {:suite "destructure / fn params & loop" :label "loop vector binding" :expected "[4 2]" :actual "(loop [[a b] [1 2] n 0] (if (< n 3) (recur [(inc a) b] (inc n)) [a b]))"} + {:suite "destructure / fn params & loop" :label "loop map binding" :expected "4" :actual "(loop [{:keys [v]} {:v 1} n 0] (if (< n 2) (recur {:v (* v 2)} (inc n)) v))"} + {:suite "destructure / fn params & loop" :label "loop init sees destr" :expected "[1 2 3]" :actual "(loop [[a b] [1 2] c (+ a b)] [a b c])"} + {:suite "destructure / primitives reject patterns" :label "fn* fixed pattern" :expected :throws :actual "((fn* [[a b]] a) [1 2])"} + {:suite "destructure / primitives reject patterns" :label "fn* rest pattern" :expected :throws :actual "((fn* [a & [b]] b) 1 2 3)"} + {:suite "destructure / primitives reject patterns" :label "let* pattern" :expected :throws :actual "(let* [[a b] [1 2]] a)"} + {:suite "destructure / primitives reject patterns" :label "loop* pattern" :expected :throws :actual "(loop* [[a b] [1 2]] a)"} + {:suite "destructure / primitives reject patterns" :label "fn desugars" :expected "[1 2]" :actual "((fn [[a b]] [a b]) [1 2])"} + {:suite "destructure / primitives reject patterns" :label "let desugars" :expected "[1 2]" :actual "(let [[a b] [1 2]] [a b])"} + {:suite "destructure / macro params" :label "macro & [a & more :as all]" :expected "[1 [2 3] [1 2 3]]" :actual "(do (defmacro m [& [a & more :as all]] (list (quote quote) [a (vec more) (vec all)])) (m 1 2 3))"} + {:suite "destructure / macro params" :label "macro fixed destructure" :expected "[2 1]" :actual "(do (defmacro mm [[a b]] (list (quote quote) [b a])) (mm [1 2]))"} + {:suite "destructure / macro params" :label "macro & {:keys}" :expected "5" :actual "(do (defmacro mk [& {:keys [x]}] (list (quote quote) x)) (mk :x 5))"} + {:suite "exceptions / try-catch" :label "catch :default" :expected ":caught" :actual "(try (throw (ex-info \"boom\" {})) (catch :default e :caught))"} + {:suite "exceptions / try-catch" :label "catch by class" :expected ":caught" :actual "(try (throw (ex-info \"boom\" {})) (catch Exception e :caught))"} + {:suite "exceptions / try-catch" :label "catch binds error" :expected "\"boom\"" :actual "(try (throw (ex-info \"boom\" {})) (catch :default e (ex-message e)))"} + {:suite "exceptions / try-catch" :label "no throw -> body" :expected "1" :actual "(try 1 (catch :default e :caught))"} + {:suite "exceptions / try-catch" :label "finally runs on ok" :expected "2" :actual "(let [a (atom 0)] (try 2 (finally (reset! a 9))) )"} + {:suite "exceptions / try-catch" :label "finally runs on throw" :expected "9" :actual "(let [a (atom 0)] (try (throw (ex-info \"x\" {})) (catch :default e nil) (finally (reset! a 9))) @a)"} + {:suite "exceptions / try-catch" :label "catch value of body" :expected "5" :actual "(try (+ 2 3) (catch :default e 0))"} + {:suite "exceptions / try-catch" :label "malformed catch: non-symbol binding" :expected :throws :actual "(try 1 (catch e (* e 10)))"} + {:suite "exceptions / try-catch" :label "malformed catch: literal binding" :expected :throws :actual "(try 1 (catch e 5))"} + {:suite "exceptions / try-catch" :label "malformed catch: too short" :expected :throws :actual "(try 1 (catch Exception))"} + {:suite "exceptions / assert" :label "assert true -> ok" :expected ":ok" :actual "(do (assert true) :ok)"} + {:suite "exceptions / assert" :label "assert expr -> ok" :expected ":ok" :actual "(do (assert (= 1 1)) :ok)"} + {:suite "exceptions / assert" :label "assert false throws" :expected :throws :actual "(assert false)"} + {:suite "exceptions / assert" :label "assert nil throws" :expected :throws :actual "(assert nil)"} + {:suite "exceptions / ex-info" :label "ex-message" :expected "\"oops\"" :actual "(ex-message (ex-info \"oops\" {}))"} + {:suite "exceptions / ex-info" :label "ex-data" :expected "{:k 1}" :actual "(ex-data (ex-info \"oops\" {:k 1}))"} + {:suite "exceptions / ex-info" :label "ex-data via catch" :expected "{:code 42}" :actual "(try (throw (ex-info \"e\" {:code 42})) (catch :default e (ex-data e)))"} + {:suite "exceptions / ex-info" :label "ex-cause" :expected "true" :actual "(let [c (ex-info \"root\" {})] (= c (ex-cause (ex-info \"outer\" {} c))))"} + {:suite "exceptions / ex-info" :label "propagates to outer" :expected "\"inner\"" :actual "(try (try (throw (ex-info \"inner\" {})) (finally nil)) (catch :default e (ex-message e)))"} + {:suite "exceptions / ex-info" :label "catch binds thrown value" :expected "42" :actual "(try (throw 42) (catch :default e e))"} + {:suite "exceptions / ex-info" :label "rethrow preserves ex" :expected "\"inner\"" :actual "(try (try (throw (ex-info \"inner\" {})) (catch :default e (throw e))) (catch :default e (ex-message e)))"} + {:suite "exceptions / ex-info" :label "ex-data on non-ex" :expected "nil" :actual "(ex-data 42)"} + {:suite "exceptions / ex-info" :label "ex-cause on non-ex" :expected "nil" :actual "(ex-cause {:k 1})"} + {:suite "exceptions / ex-info" :label "ex-message of string" :expected "nil" :actual "(ex-message \"hi\")"} + {:suite "forms / case" :label "bool" :expected ":yes" :actual "(case true true :yes false :no :default)"} + {:suite "forms / case" :label "keyword match" :expected ":b" :actual "(case :a :x :wrong :a :b :default)"} + {:suite "forms / case" :label "number match" :expected ":two" :actual "(case 2 1 :one 2 :two :default)"} + {:suite "forms / case" :label "string match" :expected ":hit" :actual "(case \"x\" \"y\" :miss \"x\" :hit :default)"} + {:suite "forms / case" :label "nil match" :expected ":nada" :actual "(case nil nil :nada :default)"} + {:suite "forms / case" :label "default" :expected ":def" :actual "(case 99 1 :one 2 :two :def)"} + {:suite "forms / case" :label "list of consts" :expected ":vowel" :actual "(case \\a (\\a \\e \\i \\o \\u) :vowel :consonant)"} + {:suite "forms / case" :label "no match no default" :expected :throws :actual "(case 5 1 :one)"} + {:suite "forms / case" :label "duplicate keys" :expected :throws :actual "(case 1 1 :one 1 :dup :default)"} + {:suite "forms / case" :label "duplicate in or-group" :expected :throws :actual "(case 2 (1 2) :a (2 3) :b :default)"} + {:suite "forms / fn" :label "named fn nil" :expected "nil" :actual "((fn* foo-bar []))"} + {:suite "forms / fn" :label "immediate call" :expected "1" :actual "((fn* [] 1))"} + {:suite "forms / fn" :label "args" :expected "[:a :b]" :actual "((fn* [a b] [a b]) :a :b)"} + {:suite "forms / fn" :label "multi-arity 0" :expected "0" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add))"} + {:suite "forms / fn" :label "multi-arity 1" :expected "-500" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add -500))"} + {:suite "forms / fn" :label "multi-arity 2" :expected "-450" :actual "(do (def add (fn* ([] 0) ([a] a) ([a b] (+ a b)))) (add -500 50))"} + {:suite "forms / fn" :label "variadic rest" :expected "[3 4]" :actual "(do (def v (fn* ([a b & args] args) ([] 0))) (v 1 2 3 4))"} + {:suite "forms / fn" :label "variadic empty" :expected "0" :actual "(do (def v (fn* ([a b & args] args) ([] 0))) (v))"} + {:suite "forms / fn" :label "variadic collect" :expected "[{} nil :m]" :actual "((fn* [a b & args] args) 'w 't {} nil :m)"} + {:suite "forms / fn" :label "closure capture" :expected "8" :actual "(do (def adder (fn* [n] (fn* [x] (+ x n)))) ((adder 5) 3))"} + {:suite "forms / fn" :label "recur countdown" :expected "0" :actual "(do (def cd (fn* [n] (if (< 0 n) (recur (+ n -1)) n))) (cd 10))"} + {:suite "forms / fn" :label "named self-recur" :expected "120" :actual "(do (def f (fn* fact [n] (if (= n 0) 1 (* n (fact (dec n)))))) (f 5))"} + {:suite "forms / fn" :label "no param vector" :expected :throws :actual "(fn* foo)"} + {:suite "forms / fn" :label "non-symbol param" :expected :throws :actual "(fn* [1] 1)"} + {:suite "forms / let" :label "literal" :expected "1" :actual "(let* [a 1] a)"} + {:suite "forms / let" :label "multiple" :expected "[1 2]" :actual "(let* [a 1 b 2] [a b])"} + {:suite "forms / let" :label "previous ref" :expected ":bee" :actual "(let* [a 1 b (if (= 1 a) :bee :uh-oh)] b)"} + {:suite "forms / let" :label "nested let" :expected "3" :actual "(let* [a 5 b (let* [c -2] (+ a c))] b)"} + {:suite "forms / let" :label "fn value bound" :expected "\":foo\"" :actual "(let* [kw->str (fn* [kw] (str kw))] (kw->str :foo))"} + {:suite "forms / let" :label "shadowing" :expected "2" :actual "(let* [a 1 a 2] a)"} + {:suite "forms / letfn" :label "mutual top" :expected "[1 2]" :actual "(letfn [(a [] 1) (b [] 2)] [(a) (b)])"} + {:suite "forms / letfn" :label "mutual recursion" :expected ":done" :actual "(letfn [(ev? [n] (if (= 0 n) :done (od? (dec n)))) (od? [n] (ev? n))] (ev? 4))"} + {:suite "forms / letfn" :label "nested letfn" :expected "3" :actual "(letfn [(a [] 5) (b [] (letfn [(c [] -2)] (+ (a) (c))))] (b))"} + {:suite "forms / loop" :label "sum" :expected "55" :actual "(loop* [sum 0 cnt 10] (if (= cnt 0) sum (recur (+ cnt sum) (dec cnt))))"} + {:suite "forms / loop" :label "multi binding" :expected "[4 2]" :actual "(loop* [a 1 b 2 n 0] (if (< n 3) (recur (inc a) b (inc n)) [a b]))"} + {:suite "forms / loop" :label "init sees prior" :expected "[1 2 3]" :actual "(loop* [a 1 b (+ a 1) c (+ b 1)] [a b c])"} + {:suite "forms / try" :label "immediate throw caught" :expected ":caught" :actual "(try (throw :boom) (catch :default e :caught))"} + {:suite "forms / try" :label "first throw wins" :expected "\"a\"" :actual "(try (throw (ex-info \"a\" {})) (throw (ex-info \"b\" {})) (catch :default e (ex-message e)))"} + {:suite "forms / try" :label "catch ex-data" :expected "7" :actual "(try (throw (ex-info \"e\" {:v 7})) (catch :default e (:v (ex-data e))))"} + {:suite "forms / try" :label "finally runs" :expected "9" :actual "(let [a (atom 0)] (try 1 (finally (reset! a 9))) @a)"} + {:suite "forms / try" :label "body value w/ finally" :expected "1" :actual "(try 1 (finally 2))"} + {:suite "forms / try" :label "catch value w/ finally" :expected ":h" :actual "(try (throw (ex-info \"x\" {})) (catch :default e :h) (finally :ignored))"} + {:suite "forms / try" :label "no throw skips catch" :expected "5" :actual "(try 5 (catch :default e :nope))"} + {:suite "forms / if-do-def-call" :label "if truthy vec" :expected ":fine" :actual "(if [:ok] :fine :no)"} + {:suite "forms / if-do-def-call" :label "if truthy str" :expected ":fine" :actual "(if \"good?\" :fine :no)"} + {:suite "forms / if-do-def-call" :label "if nil = false" :expected ":else" :actual "(if nil :then :else)"} + {:suite "forms / if-do-def-call" :label "if no else" :expected "nil" :actual "(if false 1)"} + {:suite "forms / if-do-def-call" :label "do nested" :expected "1" :actual "(do (do (do (do 1))))"} + {:suite "forms / if-do-def-call" :label "do returns last" :expected "3" :actual "(do 1 2 3)"} + {:suite "forms / if-do-def-call" :label "def + deref var" :expected "true" :actual "(var? (def one 1))"} + {:suite "forms / if-do-def-call" :label "def no init interns var" :expected "true" :actual "(var? (def no-init))"} + {:suite "forms / if-do-def-call" :label "def no init keeps existing root" :expected "7" :actual "(do (def kept 7) (def kept) kept)"} + {:suite "forms / if-do-def-call" :label "declare interns var" :expected "true" :actual "(do (declare fwd-declared) (var? (var fwd-declared)))"} + {:suite "forms / if-do-def-call" :label "def redefine" :expected "100" :actual "(do (def one 1) (def one 100) one)"} + {:suite "forms / if-do-def-call" :label "def in fn mutates" :expected "[:default :meow]" :actual "(do (def a :default) (def set-a (fn* [v] (def a v))) (let* [before a] (set-a :meow) [before a]))"} + {:suite "forms / if-do-def-call" :label "call literal fn" :expected "1" :actual "((fn* [] 1))"} + {:suite "forms / if-do-def-call" :label "call nested" :expected "6" :actual "(+ ((fn* [] 1)) ((fn* [] 2)) ((fn* [] 3)))"} + {:suite "forms / if-do-def-call" :label "call nil" :expected :throws :actual "(nil)"} + {:suite "forms / if arity (X1)" :label "bare if throws" :expected :throws :actual "(if)"} + {:suite "forms / if arity (X1)" :label "one-arg if throws" :expected :throws :actual "(if true)"} + {:suite "forms / if arity (X1)" :label "four-arg if throws" :expected :throws :actual "(if true 1 2 3)"} + {:suite "forms / if arity (X1)" :label "two-arg if ok" :expected "nil" :actual "(if false 1)"} + {:suite "forms / if arity (X1)" :label "three-arg if ok" :expected "2" :actual "(if false 1 2)"} + {:suite "functions / definition" :label "fn literal" :expected "3" :actual "((fn [a b] (+ a b)) 1 2)"} + {:suite "functions / definition" :label "fn shorthand" :expected "3" :actual "(#(+ %1 %2) 1 2)"} + {:suite "functions / definition" :label "fn shorthand %" :expected "2" :actual "(#(inc %) 1)"} + {:suite "functions / definition" :label "defn" :expected "5" :actual "(do (defn f [x] (+ x 2)) (f 3))"} + {:suite "functions / definition" :label "multi-arity" :expected "[1 5]" :actual "(do (defn f ([x] x) ([x y] (+ x y))) [(f 1) (f 2 3)])"} + {:suite "functions / definition" :label "variadic" :expected "[1 2 3]" :actual "(do (defn f [& xs] xs) (f 1 2 3))"} + {:suite "functions / definition" :label "variadic with fixed" :expected "[1 [2 3]]" :actual "(do (defn f [a & xs] [a xs]) (f 1 2 3))"} + {:suite "functions / definition" :label "closure captures" :expected "8" :actual "(do (defn adder [n] (fn [x] (+ x n))) ((adder 5) 3))"} + {:suite "functions / definition" :label "recursion" :expected "120" :actual "(do (defn fact [n] (if (< n 2) 1 (* n (fact (dec n))))) (fact 5))"} + {:suite "functions / definition" :label "named fn self-ref" :expected "120" :actual "((fn fact [n] (if (< n 2) 1 (* n (fact (dec n))))) 5)"} + {:suite "functions / definition" :label "param named `in`" :expected "1" :actual "((fn [in] (first in)) [1 2 3])"} + {:suite "functions / definition" :label "param `in` via core fn" :expected "3" :actual "((fn [in] (count in)) [1 2 3])"} + {:suite "functions / definition" :label "local `in` in let body" :expected "2" :actual "(let [in [2 3]] (first in))"} + {:suite "functions / application" :label "apply" :expected "6" :actual "(apply + [1 2 3])"} + {:suite "functions / application" :label "apply with leading" :expected "10" :actual "(apply + 1 2 [3 4])"} + {:suite "functions / application" :label "apply keyword" :expected "1" :actual "(apply :a [{:a 1}])"} + {:suite "functions / application" :label "partial" :expected "7" :actual "((partial + 5) 2)"} + {:suite "functions / application" :label "partial multi" :expected "10" :actual "((partial + 1 2) 3 4)"} + {:suite "functions / application" :label "comp" :expected "4" :actual "((comp inc inc) 2)"} + {:suite "functions / application" :label "comp order" :expected "5" :actual "((comp inc (fn [x] (* x 2))) 2)"} + {:suite "functions / application" :label "comp identity" :expected "3" :actual "((comp) 3)"} + {:suite "functions / application" :label "complement" :expected "true" :actual "((complement even?) 3)"} + {:suite "functions / application" :label "constantly" :expected "5" :actual "((constantly 5) 1 2 3)"} + {:suite "functions / application" :label "identity" :expected "7" :actual "(identity 7)"} + {:suite "functions / combinators" :label "juxt" :expected "[1 3]" :actual "((juxt first last) [1 2 3])"} + {:suite "functions / combinators" :label "fnil" :expected "1" :actual "((fnil inc 0) nil)"} + {:suite "functions / combinators" :label "fnil passes value" :expected "6" :actual "((fnil inc 0) 5)"} + {:suite "functions / combinators" :label "every-pred true" :expected "true" :actual "((every-pred pos? even?) 4)"} + {:suite "functions / combinators" :label "every-pred false" :expected "false" :actual "((every-pred pos? even?) 3)"} + {:suite "functions / combinators" :label "some-fn" :expected "true" :actual "((some-fn even? neg?) 3 4)"} + {:suite "functions / combinators" :label "memoize" :expected "2" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) x))) (f 1) (f 1) (f 2) @c)"} + {:suite "functions / combinators" :label "trampoline" :expected "10" :actual "(trampoline (fn f [n acc] (if (zero? n) acc (fn [] (f (dec n) (+ acc 2))))) 5 0)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement true" :expected "true" :actual "((complement pos?) -1)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement false" :expected "false" :actual "((complement pos?) 1)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "complement multi" :expected "true" :actual "((complement <) 3 2)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil patches nil" :expected "1" :actual "((fnil inc 0) nil)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil passes non-nil" :expected "6" :actual "((fnil inc 0) 5)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil two defaults" :expected "8" :actual "((fnil + 1 2) nil nil 5)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil only first 3" :expected "[:a :b :c nil]" :actual "((fnil vector :a :b :c) nil nil nil nil)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "fnil in update" :expected "{:k 1}" :actual "(update {} :k (fnil inc 0))"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "clojure-version" :expected "true" :actual "(string? (clojure-version))"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "bigdec" :expected "3M" :actual "(bigdec 3)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "numerator throws" :expected :throws :actual "(numerator 1)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "denominator throws" :expected :throws :actual "(denominator 1)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "supers empty set" :expected "#{}" :actual "(supers 1)"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "munge dashes" :expected "\"a_b\"" :actual "(munge \"a-b\")"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "munge symbol" :expected "(quote x_y)" :actual "(munge (quote x-y))"} + {:suite "clojure.core / leaf batch (complement fnil munge etc.)" :label "test no-test" :expected ":no-test" :actual "(test (quote foo))"} + {:suite "clojure.core / leaf batch 2" :label "key" :expected "1" :actual "(key (first {1 :a}))"} + {:suite "clojure.core / leaf batch 2" :label "val" :expected ":a" :actual "(val (first {1 :a}))"} + {:suite "clojure.core / leaf batch 2" :label "key non-entry throws" :expected :throws :actual "(key 5)"} + {:suite "clojure.core / leaf batch 2" :label "find hit" :expected "[:a 1]" :actual "(find {:a 1} :a)"} + {:suite "clojure.core / leaf batch 2" :label "find miss" :expected "nil" :actual "(find {:a 1} :b)"} + {:suite "clojure.core / leaf batch 2" :label "find nil value" :expected "[:a nil]" :actual "(find {:a nil} :a)"} + {:suite "clojure.core / leaf batch 2" :label "find on vector" :expected "[0 :x]" :actual "(find [:x :y] 0)"} + {:suite "clojure.core / leaf batch 2" :label "select-keys" :expected "{:a 1}" :actual "(select-keys {:a 1 :b 2} [:a])"} + {:suite "clojure.core / leaf batch 2" :label "select-keys nil val" :expected "{:a nil}" :actual "(select-keys {:a nil :b 2} [:a])"} + {:suite "clojure.core / leaf batch 2" :label "select-keys missing" :expected "{}" :actual "(select-keys {:a 1} [:z])"} + {:suite "clojure.core / leaf batch 2" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])"} + {:suite "clojure.core / leaf batch 2" :label "zipmap uneven" :expected "{:a 1}" :actual "(zipmap [:a :b] [1])"} + {:suite "clojure.core / leaf batch 2" :label "zipmap nil val" :expected "{:a nil}" :actual "(zipmap [:a] [nil])"} + {:suite "clojure.core / leaf batch 2" :label "merge" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})"} + {:suite "clojure.core / leaf batch 2" :label "merge later wins" :expected "{:a 2}" :actual "(merge {:a 1} {:a 2})"} + {:suite "clojure.core / leaf batch 2" :label "merge nil arg" :expected "{:a 1}" :actual "(merge {:a 1} nil)"} + {:suite "clojure.core / leaf batch 2" :label "merge nil first" :expected "{:a 1}" :actual "(merge nil {:a 1})"} + {:suite "clojure.core / leaf batch 2" :label "merge all nil" :expected "nil" :actual "(merge nil nil)"} + {:suite "clojure.core / leaf batch 2" :label "merge empty" :expected "nil" :actual "(merge)"} + {:suite "clojure.core / leaf batch 2" :label "merge entry pair" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} [:b 2])"} + {:suite "clojure.core / leaf batch 2" :label "merge-with" :expected "{:a 3}" :actual "(merge-with + {:a 1} {:a 2})"} + {:suite "clojure.core / leaf batch 2" :label "merge-with disjoint" :expected "{:a 1, :b 2}" :actual "(merge-with + {:a 1} {:b 2})"} + {:suite "clojure.core / leaf batch 2" :label "merge-with nil-val present" :expected "{:a 1}" :actual "(merge-with (fn [a b] (or a b)) {:a nil} {:a 1})"} + {:suite "clojure.core / leaf batch 2" :label "get-in" :expected "1" :actual "(get-in {:a {:b 1}} [:a :b])"} + {:suite "clojure.core / leaf batch 2" :label "get-in missing" :expected ":nf" :actual "(get-in {:a 1} [:z :y] :nf)"} + {:suite "clojure.core / leaf batch 2" :label "get-in nil value present" :expected "nil" :actual "(get-in {:a {:b nil}} [:a :b] :nf)"} + {:suite "clojure.core / leaf batch 2" :label "get-in empty path" :expected "{:a 1}" :actual "(get-in {:a 1} [])"} + {:suite "clojure.core / leaf batch 2" :label "memoize" :expected "2" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) x))) (f 1) (f 1) (f 2) (deref c))"} + {:suite "clojure.core / leaf batch 2" :label "memoize caches nil" :expected "1" :actual "(do (def c (atom 0)) (def f (memoize (fn [x] (swap! c inc) nil))) (f 1) (f 1) (deref c))"} + {:suite "clojure.core / leaf batch 2" :label "partial" :expected "6" :actual "((partial + 1 2) 3)"} + {:suite "clojure.core / leaf batch 2" :label "partial no extra" :expected "3" :actual "((partial + 1 2))"} + {:suite "clojure.core / leaf batch 2" :label "partial many fixed" :expected "15" :actual "((partial + 1 2 3 4) 5)"} + {:suite "clojure.core / leaf batch 2" :label "trampoline" :expected "10" :actual "(trampoline (fn f [n acc] (if (zero? n) acc (fn [] (f (dec n) (+ acc 2))))) 5 0)"} + {:suite "clojure.core / leaf batch 2" :label "some? true" :expected "true" :actual "(some? 0)"} + {:suite "clojure.core / leaf batch 2" :label "some? false" :expected "false" :actual "(some? nil)"} + {:suite "clojure.core / leaf batch 2" :label "true?/false?" :expected "[true false false]" :actual "[(true? true) (true? 1) (false? nil)]"} + {:suite "clojure.core / leaf batch 2" :label "max" :expected "3" :actual "(max 1 3 2)"} + {:suite "clojure.core / leaf batch 2" :label "min" :expected "1" :actual "(min 3 1 2)"} + {:suite "clojure.core / leaf batch 2" :label "max single" :expected "5" :actual "(max 5)"} + {:suite "clojure.core / leaf batch 2" :label "max non-number throws" :expected :throws :actual "(max 1 :a)"} + {:suite "clojure.core / leaf batch 2" :label "reverse" :expected "[3 2 1]" :actual "(reverse [1 2 3])"} + {:suite "clojure.core / leaf batch 2" :label "reverse empty" :expected "[]" :actual "(reverse nil)"} + {:suite "clojure.core / leaf batch 2" :label "conj nil onto map" :expected "{:a 1}" :actual "(conj {:a 1} nil)"} + {:suite "clojure.core / leaf batch 3" :label "empty vector" :expected "[]" :actual "(empty [1 2])"} + {:suite "clojure.core / leaf batch 3" :label "empty list" :expected "[]" :actual "(empty (list 1))"} + {:suite "clojure.core / leaf batch 3" :label "empty map" :expected "{}" :actual "(empty {:a 1})"} + {:suite "clojure.core / leaf batch 3" :label "empty set" :expected "#{}" :actual "(empty #{1})"} + {:suite "clojure.core / leaf batch 3" :label "empty nil" :expected "nil" :actual "(empty nil)"} + {:suite "clojure.core / leaf batch 3" :label "empty string" :expected "nil" :actual "(empty \"abc\")"} + {:suite "clojure.core / leaf batch 3" :label "empty lazy is ()" :expected "[]" :actual "(empty (map inc [1 2]))"} + {:suite "clojure.core / leaf batch 3" :label "empty sorted keeps cmp" :expected "[3 1]" :actual "(vec (seq (into (empty (sorted-set-by > 1 2)) [1 3])))"} + {:suite "clojure.core / leaf batch 3" :label "assoc-in" :expected "{:a {:b 1}}" :actual "(assoc-in {} [:a :b] 1)"} + {:suite "clojure.core / leaf batch 3" :label "assoc-in deep" :expected "{:a {:b {:c 2}}}" :actual "(assoc-in {:a {:b {:c 1}}} [:a :b :c] 2)"} + {:suite "clojure.core / leaf batch 3" :label "assoc-in keeps siblings" :expected "{:a {:b 1, :c 2}}" :actual "(assoc-in {:a {:b 1}} [:a :c] 2)"} + {:suite "clojure.core / leaf batch 3" :label "assoc-in vector idx" :expected "[1 9]" :actual "(assoc-in [1 2] [1] 9)"} + {:suite "clojure.core / leaf batch 3" :label "assoc-in nested vec" :expected "[{:a 9}]" :actual "(assoc-in [{:a 1}] [0 :a] 9)"} + {:suite "clojure.core / leaf batch 3" :label "update-in" :expected "{:a {:b 2}}" :actual "(update-in {:a {:b 1}} [:a :b] inc)"} + {:suite "clojure.core / leaf batch 3" :label "update-in extra args" :expected "{:a {:b 111}}" :actual "(update-in {:a {:b 1}} [:a :b] + 10 100)"} + {:suite "clojure.core / leaf batch 3" :label "update-in fnil" :expected "{:a {:b 1}}" :actual "(update-in {} [:a :b] (fnil inc 0))"} + {:suite "clojure.core / leaf batch 3" :label "update-in single key" :expected "{:a 2}" :actual "(update-in {:a 1} [:a] inc)"} + {:suite "clojure.core / leaf batch 3" :label "interpose" :expected "[1 :s 2 :s 3]" :actual "(interpose :s [1 2 3])"} + {:suite "clojure.core / leaf batch 3" :label "interpose empty" :expected "[]" :actual "(interpose :s [])"} + {:suite "clojure.core / leaf batch 3" :label "interpose one" :expected "[1]" :actual "(interpose :s [1])"} + {:suite "clojure.core / leaf batch 3" :label "interpose is lazy" :expected "[0 :s 1]" :actual "(take 3 (interpose :s (range)))"} + {:suite "clojure.core / leaf batch 3" :label "interpose xform" :expected "[\"a\" \",\" \"b\"]" :actual "(vec (sequence (interpose \",\") [\"a\" \"b\"]))"} + {:suite "clojure.core / leaf batch 3" :label "take-nth" :expected "[1 3 5]" :actual "(take-nth 2 [1 2 3 4 5 6])"} + {:suite "clojure.core / leaf batch 3" :label "take-nth lazy" :expected "[0 3 6]" :actual "(take 3 (take-nth 3 (range)))"} + {:suite "clojure.core / leaf batch 3" :label "take-nth xform" :expected "[1 3 5]" :actual "(vec (sequence (take-nth 2) [1 2 3 4 5 6]))"} + {:suite "clojure.core / leaf batch 3" :label "take-nth into" :expected "[1 4]" :actual "(into [] (take-nth 3) [1 2 3 4 5])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by keyfn" :expected "[[1 :b] [2 :a]]" :actual "(sort-by first [[2 :a] [1 :b]])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by string keys" :expected "[\"a\" \"bb\" \"ccc\"]" :actual "(sort-by count [\"ccc\" \"a\" \"bb\"])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by comparator" :expected "[3 2 1]" :actual "(sort-by identity > [1 3 2])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by 3way cmp" :expected "[3 2 1]" :actual "(sort-by identity (fn [a b] (- b a)) [1 3 2])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by mixed nil" :expected "[nil 1 2]" :actual "(sort-by identity [2 nil 1])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by empty" :expected "[]" :actual "(sort-by first [])"} + {:suite "clojure.core / leaf batch 4" :label "sort-by nil coll" :expected "[]" :actual "(sort-by first nil)"} + {:suite "clojure.core / leaf batch 4" :label "rand-int range" :expected "true" :actual "(every? (fn [_] (let [r (rand-int 5)] (and (int? r) (<= 0 r 4)))) (range 50))"} + {:suite "clojure.core / leaf batch 4" :label "rand-int zero" :expected "0" :actual "(rand-int 1)"} + {:suite "clojure.core / leaf batch 4" :label "shuffle is permutation" :expected "true" :actual "(= (sort (shuffle [5 3 1 4 2])) [1 2 3 4 5])"} + {:suite "clojure.core / leaf batch 4" :label "shuffle returns vector" :expected "true" :actual "(vector? (shuffle [1 2 3]))"} + {:suite "clojure.core / leaf batch 4" :label "shuffle empty" :expected "[]" :actual "(shuffle [])"} + {:suite "clojure.core / leaf batch 4" :label "shuffle non-coll throws" :expected :throws :actual "(shuffle 5)"} + {:suite "clojure.core / leaf batch 4" :label "random-uuid is uuid" :expected "true" :actual "(uuid? (random-uuid))"} + {:suite "clojure.core / leaf batch 4" :label "random-uuid v4 shape" :expected "true" :actual "(boolean (re-matches #\"[0-9a-f]{8}-[0-9a-f]{4}-4[0-9a-f]{3}-[89ab][0-9a-f]{3}-[0-9a-f]{12}\" (str (random-uuid))))"} + {:suite "clojure.core / leaf batch 4" :label "random-uuid distinct" :expected "true" :actual "(not= (random-uuid) (random-uuid))"} + {:suite "clojure.core / leaf batch 4" :label "char-escape newline" :expected "\"\\\\n\"" :actual "(char-escape-string \\newline)"} + {:suite "clojure.core / leaf batch 4" :label "char-escape quote" :expected "true" :actual "(= 2 (count (char-escape-string \\\")))"} + {:suite "clojure.core / leaf batch 4" :label "char-escape none" :expected "nil" :actual "(char-escape-string \\a)"} + {:suite "clojure.core / leaf batch 4" :label "char-name space" :expected "\"space\"" :actual "(char-name-string \\space)"} + {:suite "clojure.core / leaf batch 4" :label "char-name newline" :expected "\"newline\"" :actual "(char-name-string \\newline)"} + {:suite "clojure.core / leaf batch 4" :label "char-name none" :expected "nil" :actual "(char-name-string \\a)"} + {:suite "functions / recur into variadic arity" :label "counts rest via recur" :expected "3" :actual "((fn cnt [acc & xs] (if (seq xs) (recur (inc acc) (rest xs)) acc)) 0 :a :b :c)"} + {:suite "functions / recur into variadic arity" :label "zero-fixed variadic" :expected "4" :actual "((fn f [& xs] (if (< (count xs) 4) (recur (cons :x xs)) (count xs))) :a)"} + {:suite "functions / recur into variadic arity" :label "rest empties to nil" :expected "[:done]" :actual "((fn f [& xs] (if xs (recur (next xs)) (list :done))) 1 2)"} + {:suite "functions / recur into variadic arity" :label "multi-arity variadic recur" :expected "6" :actual "((fn ma ([a] a) ([a & xs] (if (seq xs) (recur (+ a (first xs)) (rest xs)) a))) 1 2 3)"} + {:suite "functions / recur into variadic arity" :label "recur passes nil rest" :expected ":empty" :actual "((fn f [acc & xs] (if (seq xs) (recur acc (rest xs)) :empty)) 0 1)"} + {:suite "functions / recur into variadic arity" :label "fixed-arity recur untouched" :expected "10" :actual "((fn f [n acc] (if (pos? n) (recur (dec n) (+ acc 2)) acc)) 5 0)"} + {:suite "functions / empty rest arg is nil" :label "no args" :expected ":nil" :actual "((fn [& r] (if r :truthy :nil)))"} + {:suite "functions / empty rest arg is nil" :label "after fixed" :expected ":nil" :actual "((fn [a & r] (if r :truthy :nil)) 1)"} + {:suite "functions / empty rest arg is nil" :label "via apply" :expected ":nil" :actual "(apply (fn [& r] (if r :truthy :nil)) [])"} + {:suite "functions / empty rest arg is nil" :label "defn no args" :expected ":nil" :actual "(do (defn er-f [& r] (if r :truthy :nil)) (er-f))"} + {:suite "functions / empty rest arg is nil" :label "non-empty unchanged" :expected "[1 2]" :actual "((fn [& r] r) 1 2)"} + {:suite "functions / empty rest arg is nil" :label "one extra" :expected "[2]" :actual "((fn [a & r] r) 1 2)"} + {:suite "functions / empty rest arg is nil" :label "rest destructure with no args" :expected ":nil" :actual "((fn [& [a]] (if a :truthy :nil)))"} + {:suite "functions / arity enforcement" :label "fixed extra args" :expected :throws :actual "((fn [x] x) 1 2)"} + {:suite "functions / arity enforcement" :label "fixed missing args" :expected :throws :actual "((fn [x y] x) 1)"} + {:suite "functions / arity enforcement" :label "fixed zero of one" :expected :throws :actual "((fn [x] x))"} + {:suite "functions / arity enforcement" :label "named defn extra" :expected :throws :actual "(do (defn af1 [x] x) (af1 1 2))"} + {:suite "functions / arity enforcement" :label "overlay fn extra" :expected :throws :actual "(identity 1 2)"} + {:suite "functions / arity enforcement" :label "through apply" :expected :throws :actual "(apply (fn [x] x) [1 2])"} + {:suite "functions / arity enforcement" :label "through update" :expected :throws :actual "(update {:k 1} :k identity 1 2 3 4)"} + {:suite "functions / arity enforcement" :label "variadic below min" :expected :throws :actual "((fn [x & r] x))"} + {:suite "functions / arity enforcement" :label "variadic at min" :expected "nil" :actual "((fn [x & r] r) 1)"} + {:suite "functions / arity enforcement" :label "variadic above min" :expected "[2 3]" :actual "((fn [x & r] r) 1 2 3)"} + {:suite "functions / arity enforcement" :label "multi-arity no match" :expected :throws :actual "((fn ([x] x) ([x y] y)) 1 2 3)"} + {:suite "functions / arity enforcement" :label "multi-arity variadic below min" :expected :throws :actual "((fn ([x] x) ([x y & r] r)))"} + {:suite "functions / arity enforcement" :label "destructured param counts as one" :expected "3" :actual "((fn [[a b] c] c) [1 2] 3)"} + {:suite "functions / arity enforcement" :label "destructured extra throws" :expected :throws :actual "((fn [[a b]] a) [1 2] [3 4])"} + {:suite "functions / arity enforcement" :label "hof exact arity ok" :expected "[2 4]" :actual "(mapv (fn [x] (* 2 x)) [1 2])"} + {:suite "functions / arity enforcement" :label "zero-arity fn ok" :expected "7" :actual "((fn [] 7))"} + {:suite "clojure.core / futures — deref" :label "future + deref" :expected "3" :actual "(deref (future (+ 1 2)))"} + {:suite "clojure.core / futures — deref" :label "@ reader macro derefs" :expected "42" :actual "@(future (* 6 7))"} + {:suite "clojure.core / futures — deref" :label "future returns collection" :expected "[2 3 4]" :actual "(deref (future (mapv inc [1 2 3])))"} + {:suite "clojure.core / futures — deref" :label "future returns a map" :expected "{:a 1}" :actual "(deref (future {:a 1}))"} + {:suite "clojure.core / futures — deref" :label "deref is cached/idempotent" :expected "[2 2]" :actual "(let [f (future (+ 1 1))] [(deref f) (deref f)])"} + {:suite "clojure.core / futures — deref" :label "timed deref of ready future" :expected "42" :actual "(let [f (future 42)] (deref f) (deref f 1000 :nope))"} + {:suite "clojure.core / futures — deref" :label "body error re-raised on deref" :expected :throws :actual "(deref (future (throw \"boom\")))"} + {:suite "clojure.core / futures — deref" :label "timed deref times out" :expected ":timed-out" :actual "(deref (future (do (Thread/sleep 300) :late)) 10 :timed-out)"} + {:suite "clojure.core / futures — deref" :label "Thread/sleep in body" :expected ":slept" :actual "(deref (future (do (Thread/sleep 5) :slept)))"} + {:suite "clojure.core / futures — deref" :label "timed-out future still completes" :expected ":late" :actual "(let [f (future (do (Thread/sleep 30) :late))] (deref f 5 :early) (deref f))"} + {:suite "clojure.core / futures — predicates" :label "future? true" :expected "true" :actual "(future? (future 1))"} + {:suite "clojure.core / futures — predicates" :label "future? false" :expected "false" :actual "(future? 42)"} + {:suite "clojure.core / futures — predicates" :label "future-done? after deref" :expected "true" :actual "(let [f (future 1)] (deref f) (future-done? f))"} + {:suite "clojure.core / futures — predicates" :label "realized? after deref" :expected "true" :actual "(let [f (future 1)] (deref f) (realized? f))"} + {:suite "clojure.core / futures — predicates" :label "cancel an in-flight future returns true" :expected "true" :actual "(let [f (future (do (Thread/sleep 100) 1))] (future-cancel f))"} + {:suite "clojure.core / futures — predicates" :label "future-cancelled? after cancel" :expected "true" :actual "(let [f (future (do (Thread/sleep 100) 1))] (future-cancel f) (future-cancelled? f))"} + {:suite "clojure.core / futures — predicates" :label "future-done? after cancel" :expected "true" :actual "(let [f (future 1)] (future-cancel f) (future-done? f))"} + {:suite "clojure.core / futures — predicates" :label "cancel an already-completed future returns false" :expected "false" :actual "(let [f (future 1)] (deref f) (future-cancel f))"} + {:suite "clojure.core / futures — predicates" :label "future-cancelled? fresh is false" :expected "false" :actual "(future-cancelled? (future 1))"} + {:suite "clojure.core / futures — snapshot (copy) semantics" :label "captured atom is snapshotted, not shared" :expected "1" :actual "(let [a (atom 0)] (deref (future (swap! a inc))) @a)"} + {:suite "clojure.core / futures — snapshot (copy) semantics" :label "future sees its own mutation" :expected "1" :actual "(let [a (atom 0)] (deref (future (swap! a inc))))"} + {:suite "clojure.core / pmap family" :label "pmap values in order" :expected "[2 3 4]" :actual "(vec (pmap inc [1 2 3]))"} + {:suite "clojure.core / pmap family" :label "pmap multi-coll" :expected "[5 7 9]" :actual "(vec (pmap + [1 2 3] [4 5 6]))"} + {:suite "clojure.core / pmap family" :label "pmap empty" :expected "[]" :actual "(pmap inc [])"} + {:suite "clojure.core / pmap family" :label "pmap is parallel" :expected "true" :actual "(do (deref (future :warmup)) (let [t0 (System/currentTimeMillis)] (dorun (pmap (fn [_] (Thread/sleep 200)) [1 2 3 4])) (< (- (System/currentTimeMillis) t0) 700)))"} + {:suite "clojure.core / pmap family" :label "pcalls" :expected "[1 2]" :actual "(vec (pcalls (fn [] 1) (fn [] 2)))"} + {:suite "clojure.core / pmap family" :label "pvalues" :expected "[3 7]" :actual "(vec (pvalues (+ 1 2) (+ 3 4)))"} + {:suite "clojure.core / pmap family" :label "snapshot semantics" :expected "2" :actual "(let [a (atom 0)] (dorun (pmap (fn [_] (swap! a inc)) [1 2])) (deref a))"} + {:suite "hierarchy / pure 3-arity" :label "derive returns new h" :expected "true" :actual "(let [h (derive (make-hierarchy) :rect :shape)] (and (map? h) (isa? h :rect :shape)))"} + {:suite "hierarchy / pure 3-arity" :label "original unchanged" :expected "false" :actual "(let [h0 (make-hierarchy) h1 (derive h0 :rect :shape)] (isa? h0 :rect :shape))"} + {:suite "hierarchy / pure 3-arity" :label "isa? self" :expected "true" :actual "(isa? (make-hierarchy) :a :a)"} + {:suite "hierarchy / pure 3-arity" :label "isa? transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (isa? h :square :shape))"} + {:suite "hierarchy / pure 3-arity" :label "multi-parent" :expected "[true true]" :actual "(let [h (-> (make-hierarchy) (derive :sq :rect) (derive :sq :rhombus))] [(isa? h :sq :rect) (isa? h :sq :rhombus)])"} + {:suite "hierarchy / pure 3-arity" :label "parents set" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :sq :rect) (derive :sq :rhombus))] (= #{:rect :rhombus} (parents h :sq)))"} + {:suite "hierarchy / pure 3-arity" :label "ancestors transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (= #{:rect :shape} (ancestors h :square)))"} + {:suite "hierarchy / pure 3-arity" :label "descendants transitive" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :square :rect) (derive :rect :shape))] (= #{:rect :square} (descendants h :shape)))"} + {:suite "hierarchy / pure 3-arity" :label "underive removes" :expected "false" :actual "(let [h (-> (make-hierarchy) (derive :a :b) (underive :a :b))] (isa? h :a :b))"} + {:suite "hierarchy / pure 3-arity" :label "vector isa?" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :rect :shape))] (isa? h [:rect :rect] [:shape :shape]))"} + {:suite "hierarchy / pure 3-arity" :label "vector isa? length" :expected "false" :actual "(isa? (make-hierarchy) [:a] [:a :a])"} + {:suite "hierarchy / pure 3-arity" :label "cyclic derive throws" :expected :throws :actual "(-> (make-hierarchy) (derive :a :b) (derive :b :a))"} + {:suite "hierarchy / pure 3-arity" :label "duplicate derive ok" :expected "true" :actual "(let [h (-> (make-hierarchy) (derive :a :b) (derive :a :b))] (isa? h :a :b))"} + {:suite "hierarchy / pure 3-arity" :label "parents nil when none" :expected "nil" :actual "(parents (make-hierarchy) :x)"} + {:suite "hierarchy / global + multimethod dispatch" :label "global derive + isa?" :expected "true" :actual "(do (derive :gsq :grect) (isa? :gsq :grect))"} + {:suite "hierarchy / global + multimethod dispatch" :label "global ancestors" :expected "true" :actual "(do (derive :ga :gb) (derive :gb :gc) (contains? (ancestors :ga) :gc))"} + {:suite "hierarchy / global + multimethod dispatch" :label "global underive" :expected "false" :actual "(do (derive :gu :gv) (underive :gu :gv) (isa? :gu :gv))"} + {:suite "hierarchy / global + multimethod dispatch" :label "dispatch via hierarchy" :expected ":is-shape" :actual "(do (derive :hsq :hshape) (defmulti hmm identity) (defmethod hmm :hshape [_] :is-shape) (hmm :hsq))"} + {:suite "hierarchy / global + multimethod dispatch" :label "dispatch custom hierarchy" :expected ":parent" :actual "(do (def hh (atom (derive (make-hierarchy) :c :p))) (defmulti cmm identity :hierarchy hh) (defmethod cmm :p [_] :parent) (cmm :c))"} + {:suite "hierarchy / global + multimethod dispatch" :label "dispatch exact beats isa" :expected ":exact" :actual "(do (derive :de1 :de2) (defmulti emm identity) (defmethod emm :de2 [_] :parent) (defmethod emm :de1 [_] :exact) (emm :de1))"} + {:suite "interop / dot forms" :label "method call" :expected "\"v=41\"" :actual "(. {:value 41 :describe (fn [self] (str \"v=\" (:value self)))} describe)"} + {:suite "interop / dot forms" :label "method with args" :expected "\"Hello Alice\"" :actual "(. {:greet (fn [self n] (str \"Hello \" n))} greet \"Alice\")"} + {:suite "interop / dot forms" :label "field access .-" :expected "41" :actual "(.-value {:value 41})"} + {:suite "interop / dot forms" :label "dot field keyword" :expected "41" :actual "(. {:value 41} :value)"} + {:suite "interop / dot dispatch arms" :label "zero-arg coll-interop .count" :expected "3" :actual "(.count [1 2 3])"} + {:suite "interop / dot dispatch arms" :label "zero-arg coll-interop .seq" :expected "[1 2]" :actual "(.seq [1 2])"} + {:suite "interop / dot dispatch arms" :label "explicit dot zero-arg interop" :expected "3" :actual "(. [1 2 3] count)"} + {:suite "interop / dot dispatch arms" :label "with-arg coll-interop .nth" :expected "2" :actual "(.nth [1 2 3] 1)"} + {:suite "interop / dot dispatch arms" :label "record zero-arg method" :expected "10" :actual "(do (defprotocol Pd (gm [this])) (defrecord Rd [x] Pd (gm [this] (* 2 x))) (.gm (->Rd 5)))"} + {:suite "interop / dot dispatch arms" :label "record method with args" :expected "15" :actual "(do (defprotocol Pa (am [this y])) (defrecord Ra [x] Pa (am [this y] (+ x y))) (.am (->Ra 5) 10))"} + {:suite "interop / dot dispatch arms" :label "deftype method with args" :expected "7" :actual "(do (defprotocol Pq (qq [this y])) (deftype Tq [x] Pq (qq [this y] (+ x y))) (.qq (Tq. 3) 4))"} + {:suite "interop / dot dispatch arms" :label "record -field is field access" :expected "7" :actual "(do (defrecord Rf [x]) (.-x (->Rf 7)))"} + {:suite "interop / dot dispatch arms" :label "object-method with args .equals" :expected "true" :actual "(.equals \"a\" \"a\")"} + {:suite "interop / arrays (aget/aset/alength)" :label "alength" :expected "3" :actual "(alength (object-array [1 2 3]))"} + {:suite "interop / arrays (aget/aset/alength)" :label "aget" :expected "20" :actual "(aget (object-array [10 20 30]) 1)"} + {:suite "interop / arrays (aget/aset/alength)" :label "aset returns val" :expected "9" :actual "(aset (object-array [1 2 3]) 1 9)"} + {:suite "interop / arrays (aget/aset/alength)" :label "aset mutates" :expected "[7 2 3]" :actual "(let [a (object-array [1 2 3])] (aset a 0 7) (vec a))"} + {:suite "interop / arrays (aget/aset/alength)" :label "aget 2d" :expected "4" :actual "(aget (to-array-2d [[1 2] [3 4]]) 1 1)"} + {:suite "interop / String methods" :label ".toLowerCase" :expected "\"hi\"" :actual "(.toLowerCase \"HI\")"} + {:suite "interop / String methods" :label ".toUpperCase" :expected "\"HI\"" :actual "(.toUpperCase \"hi\")"} + {:suite "interop / String methods" :label "dot-form" :expected "\"hi\"" :actual "(. \"HI\" toLowerCase)"} + {:suite "interop / String methods" :label ".trim" :expected "\"x\"" :actual "(.trim \" x \")"} + {:suite "interop / String methods" :label ".length" :expected "3" :actual "(.length \"abc\")"} + {:suite "interop / String methods" :label ".isEmpty" :expected "[true false]" :actual "[(.isEmpty \"\") (.isEmpty \"a\")]"} + {:suite "interop / String methods" :label ".indexOf hit" :expected "1" :actual "(.indexOf \"abc\" \"b\")"} + {:suite "interop / String methods" :label ".indexOf miss is -1" :expected "-1" :actual "(.indexOf \"abc\" \"z\")"} + {:suite "interop / String methods" :label ".lastIndexOf" :expected "3" :actual "(.lastIndexOf \"abab\" \"b\")"} + {:suite "interop / String methods" :label ".substring" :expected "\"bc\"" :actual "(.substring \"abc\" 1)"} + {:suite "interop / String methods" :label ".substring end" :expected "\"b\"" :actual "(.substring \"abc\" 1 2)"} + {:suite "interop / String methods" :label ".startsWith" :expected "true" :actual "(.startsWith \"abc\" \"ab\")"} + {:suite "interop / String methods" :label ".endsWith" :expected "true" :actual "(.endsWith \"abc\" \"bc\")"} + {:suite "interop / String methods" :label ".contains" :expected "true" :actual "(.contains \"abc\" \"b\")"} + {:suite "interop / String methods" :label ".replace" :expected "\"axc\"" :actual "(.replace \"abc\" \"b\" \"x\")"} + {:suite "interop / String methods" :label ".charAt" :expected "\\b" :actual "(.charAt \"abc\" 1)"} + {:suite "interop / String methods" :label ".equalsIgnoreCase" :expected "true" :actual "(.equalsIgnoreCase \"AbC\" \"aBc\")"} + {:suite "interop / String methods" :label "Long/MAX_VALUE" :expected "true" :actual "(pos? Long/MAX_VALUE)"} + {:suite "interop / String methods" :label "String/valueOf num" :expected "\"42\"" :actual "(String/valueOf 42)"} + {:suite "interop / String methods" :label "String/valueOf str" :expected "\"hi\"" :actual "(String/valueOf \"hi\")"} + {:suite "interop / String methods" :label "String/valueOf kw" :expected "\":k\"" :actual "(String/valueOf :k)"} + {:suite "interop / String methods" :label "String/valueOf nil" :expected "\"null\"" :actual "(String/valueOf nil)"} + {:suite "interop / String methods" :label "instance? CharSequence" :expected "true" :actual "(instance? CharSequence \"aaa\")"} + {:suite "interop / String methods" :label "instance? CharSequence non-str" :expected "false" :actual "(instance? CharSequence 42)"} + {:suite "interop / String methods" :label "unsupported method throws" :expected :throws :actual "(.frobnicate \"abc\")"} + {:suite "interop / java.time shims" :label "ofPattern formats #inst" :expected "true" :actual "(string? (.format (DateTimeFormatter/ofPattern \"yyyy-MM-dd\") #inst \"2020-03-05T13:45:30Z\"))"} + {:suite "interop / java.time shims" :label "pattern shape" :expected "true" :actual "(boolean (re-matches #\"\\d{4}-\\d{2}-\\d{2}\" (.format (DateTimeFormatter/ofPattern \"yyyy-MM-dd\") #inst \"2020-03-05T13:45:30Z\")))"} + {:suite "interop / java.time shims" :label "month name + ampm" :expected "true" :actual "(boolean (re-matches #\"[A-Z][a-z]{2} \\d{1,2}, 2020 \\d{1,2}:\\d{2} [AP]M\" (.format (DateTimeFormatter/ofPattern \"MMM d, yyyy h:mm a\") #inst \"2020-03-05T13:45:30Z\")))"} + {:suite "interop / java.time shims" :label "quoted literal" :expected "true" :actual "(boolean (re-matches #\"\\d{4}-\\d{2}-\\d{2}T\\d{2}:\\d{2}:\\d{2}\" (.format DateTimeFormatter/ISO_LOCAL_DATE_TIME #inst \"2020-03-05T13:45:30Z\")))"} + {:suite "interop / java.time shims" :label "localized style" :expected "true" :actual "(string? (.format (DateTimeFormatter/ofLocalizedDate FormatStyle/MEDIUM) #inst \"2020-03-05T13:45:30Z\"))"} + {:suite "interop / java.time shims" :label "withLocale chain" :expected "true" :actual "(string? (.format (.withLocale (DateTimeFormatter/ofPattern \"yyyy\") (java.util.Locale. \"en\")) #inst \"2020-01-01T00:00:00Z\"))"} + {:suite "interop / java.time shims" :label "fix-date chain" :expected "true" :actual "(instance? LocalDateTime (-> #inst \"2020-03-05T13:45:30Z\" (.toInstant) (.atZone (ZoneId/systemDefault)) (.toLocalDateTime)))"} + {:suite "interop / java.time shims" :label "inst is java.util.Date" :expected "true" :actual "(instance? java.util.Date #inst \"2020-01-01T00:00:00Z\")"} + {:suite "interop / java.time shims" :label "Instant instance" :expected "true" :actual "(instance? java.time.Instant (Instant/ofEpochMilli 0))"} + {:suite "interop / java.time shims" :label "getTime epoch ms" :expected "0" :actual "(.getTime #inst \"1970-01-01T00:00:00Z\")"} + {:suite "interop / java.time shims" :label "toEpochMilli round trip" :expected "1234" :actual "(.toEpochMilli (Instant/ofEpochMilli 1234))"} + {:suite "interop / java.time shims" :label "Instant/now is current" :expected "true" :actual "(> (.toEpochMilli (Instant/now)) 1500000000000)"} + {:suite "interop / java.time shims" :label "sql types are not" :expected "false" :actual "(instance? java.sql.Timestamp #inst \"2020-01-01T00:00:00Z\")"} + {:suite "interop / StringReader & StringBuilder" :label "StringReader read" :expected "[97 98 -1]" :actual "(let [r (java.io.StringReader. \"ab\")] [(.read r) (.read r) (.read r)])"} + {:suite "interop / StringReader & StringBuilder" :label "mark/reset" :expected "[97 97]" :actual "(let [r (StringReader. \"ab\")] (.mark r 1) [(.read r) (do (.reset r) (.read r))])"} + {:suite "interop / StringReader & StringBuilder" :label "StringBuilder append" :expected "\"ab1\"" :actual "(.toString (-> (StringBuilder.) (.append \"a\") (.append \\b) (.append 1)))"} + {:suite "interop / StringReader & StringBuilder" :label "capacity arg is not content" :expected "\"x\"" :actual "(.toString (.append (StringBuilder. 16) \"x\"))"} + {:suite "interop / StringReader & StringBuilder" :label "setLength truncates" :expected "\"ab\"" :actual "(let [sb (StringBuilder.)] (.append sb \"abcd\") (.setLength sb 2) (.toString sb))"} + {:suite "interop / StringReader & StringBuilder" :label "char-array of string" :expected "true" :actual "(instance? (Class/forName \"[C\") (char-array \"ab\"))"} + {:suite "interop / StringReader & StringBuilder" :label "reader over char[]" :expected "97" :actual "(do (require (quote clojure.java.io)) (.read (clojure.java.io/reader (char-array \"abc\"))))"} + {:suite "interop / StringReader & StringBuilder" :label "with-open closes shim" :expected "97" :actual "(with-open [r (StringReader. \"a\")] (.read r))"} + {:suite "interop / StringReader & StringBuilder" :label "File.toURL methods read it back" :expected "\"file:/tmp/x\"" :actual "(do (require (quote clojure.java.io)) (.toString (.toURL (clojure.java.io/file \"/tmp/x\"))))"} + {:suite "interop / StringReader & StringBuilder" :label "vector :import shares deftype ctor" :expected "\"hi!\"" :actual "(do (ns spec.nodea) (defprotocol SpecP (spec-pm [this])) (deftype SpecTN [t] SpecP (spec-pm [this] (str t \"!\"))) (ns spec.nodeb (:import [spec.nodea SpecTN])) (.spec-pm (SpecTN. \"hi\")))"} + {:suite "interop / PushbackReader & parse statics" :label "PushbackReader read" :expected "[97 98]" :actual "(let [r (java.io.PushbackReader. (java.io.StringReader. \"ab\"))] [(.read r) (.read r)])"} + {:suite "interop / PushbackReader & parse statics" :label "unread pushes back" :expected "[97 97 98]" :actual "(let [r (PushbackReader. (StringReader. \"ab\")) a (.read r)] (.unread r a) [a (.read r) (.read r)])"} + {:suite "interop / PushbackReader & parse statics" :label "unread accepts a char" :expected "[120 97]" :actual "(let [r (PushbackReader. (StringReader. \"a\"))] (.unread r \\x) [(.read r) (.read r)])"} + {:suite "interop / PushbackReader & parse statics" :label "edn/read from reader" :expected "5432" :actual "(do (require (quote clojure.edn)) (clojure.edn/read (java.io.PushbackReader. (java.io.StringReader. \"{:db {:port 5432}}\\nrest\"))) (get-in (clojure.edn/read-string \"{:db {:port 5432}}\") [:db :port]))"} + {:suite "interop / PushbackReader & parse statics" :label "edn/read multi-line" :expected "true" :actual "(do (require (quote clojure.edn)) (= {:a 1 :b 2} (clojure.edn/read (PushbackReader. (StringReader. \"{:a 1\\n :b 2}\")))))"} + {:suite "interop / PushbackReader & parse statics" :label "Long/parseLong" :expected "42" :actual "(Long/parseLong \"42\")"} + {:suite "interop / PushbackReader & parse statics" :label "parseLong rejects non-numeric" :expected :throws :actual "(Long/parseLong \"4x\")"} + {:suite "interop / PushbackReader & parse statics" :label "BigInteger." :expected "123" :actual "(BigInteger. \"123\")"} + {:suite "interop / PushbackReader & parse statics" :label "Boolean/parseBoolean" :expected "[true false false]" :actual "[(Boolean/parseBoolean \"true\") (Boolean/parseBoolean \"false\") (Boolean/parseBoolean \"yes\")]"} + {:suite "interop / PushbackReader & parse statics" :label "System/getenv is a map" :expected "true" :actual "(string? (get (System/getenv) \"HOME\"))"} + {:suite "interop / PushbackReader & parse statics" :label "System/exit resolves" :expected "true" :actual "(fn? System/exit)"} + {:suite "interop / PushbackReader & parse statics" :label "getenv entries destructure (non-empty)" :expected "true" :actual "(let [es (map (fn [[k v]] [k v]) (System/getenv))] (and (pos? (count es)) (every? vector? es)))"} + {:suite "interop / PushbackReader & parse statics" :label "seq over a raw host table" :expected "true" :actual "(pos? (count (seq (System/getenv))))"} + {:suite "interop / PushbackReader & parse statics" :label "into {} from host table" :expected "true" :actual "(string? (get (into {} (map (fn [[k v]] [k v]) (System/getenv))) \"HOME\"))"} + {:suite "interop / PushbackReader & parse statics" :label "System/getProperties" :expected "true" :actual "(string? (get (System/getProperties) \"os.name\"))"} + {:suite "host-interop / ring-codec surface" :label "URLEncoder www form" :expected "\"a+b%3Dc\"" :actual "(URLEncoder/encode \"a b=c\")"} + {:suite "host-interop / ring-codec surface" :label "URLDecoder www form" :expected "\"a b=c\"" :actual "(URLDecoder/decode \"a+b%3Dc\" (Charset/forName \"UTF-8\"))"} + {:suite "host-interop / ring-codec surface" :label "url round trip" :expected "\"x &=%?\"" :actual "(URLDecoder/decode (URLEncoder/encode \"x &=%?\"))"} + {:suite "host-interop / ring-codec surface" :label "Base64 encode" :expected "\"aGVsbG8=\"" :actual "(String. (.encode (Base64/getEncoder) (.getBytes \"hello\")))"} + {:suite "host-interop / ring-codec surface" :label "Base64 round trip" :expected "\"hello\"" :actual "(String. (.decode (Base64/getDecoder) (String. (.encode (Base64/getEncoder) (.getBytes \"hello\")))))"} + {:suite "host-interop / ring-codec surface" :label "Integer radix + byteValue" :expected "-1" :actual "(.byteValue (Integer/valueOf \"ff\" 16))"} + {:suite "host-interop / ring-codec surface" :label "Integer parseInt" :expected "255" :actual "(Integer/parseInt \"ff\" 16)"} + {:suite "host-interop / ring-codec surface" :label "StringTokenizer" :expected "[\"a=1\" \"b=2\"]" :actual "(let [t (StringTokenizer. \"a=1&b=2\" \"&\")] [(.nextToken t) (.nextToken t)])"} + {:suite "host-interop / ring-codec surface" :label "MapEntry key/val" :expected "[:a 1]" :actual "(let [e (MapEntry. :a 1)] [(key e) (val e)])"} + {:suite "host-interop / ring-codec surface" :label "String ctor from bytes" :expected "\"hi\"" :actual "(String. (.getBytes \"hi\"))"} + {:suite "host-interop / ring-codec surface" :label "extend-protocol Map" :expected ":map" :actual "(do (defprotocol Pe (pe [x])) (extend-protocol Pe Map (pe [m] :map) Object (pe [o] :obj)) (pe {:a 1}))"} + {:suite "host-interop / ring-codec surface" :label "extend-protocol nil" :expected ":nil" :actual "(do (defprotocol Pn (pn [x])) (extend-protocol Pn nil (pn [n] :nil) Object (pn [o] :obj)) (pn nil))"} + {:suite "host-interop / ring-codec surface" :label "extend-protocol Map covers sorted" :expected ":map" :actual "(do (defprotocol Ps (ps [x])) (extend-protocol Ps Map (ps [m] :map) Object (ps [o] :obj)) (ps (sorted-map 1 2)))"} + {:suite "host-interop / ring-codec surface" :label "reduce over reified IReduceInit" :expected "42" :actual "(reduce + 0 (reify clojure.lang.IReduceInit (reduce [_ f init] (f (f init 40) 2))))"} + {:suite "core / reify" :label "multi-arity method dispatches by arg count" :expected "[:z 9]" :actual "(do (defprotocol P (m [_] [_ a])) (let [r (reify P (m [_] :z) (m [_ x] x))] [(m r) (m r 9)]))"} + {:suite "core / reify" :label "reify implements IObj and carries metadata" :expected "[true 2]" :actual "(do (defprotocol Q (qq [_])) (let [r (reify Q (qq [_] 1))] [(instance? clojure.lang.IObj r) (:k (meta (with-meta r {:k 2})))]))"} + {:suite "core / reify" :label "with-meta leaves the original untouched and keeps dispatch" :expected "[nil {:k 2} 1]" :actual "(do (defprotocol Q (qq [_])) (let [r (reify Q (qq [_] 1)) r2 (with-meta r {:k 2})] [(meta r) (meta r2) (qq r2)]))"} + {:suite "host-interop / class tokens & readers" :label "class name evaluates to canonical string" :expected "java.lang.String" :actual "String"} + {:suite "host-interop / class tokens & readers" :label "dispatch-only class name" :expected "\"java.io.InputStream\"" :actual "InputStream"} + {:suite "host-interop / class tokens & readers" :label "(class x) matches the token" :expected "true" :actual "(= String (class \"abc\"))"} + {:suite "host-interop / class tokens & readers" :label "defmulti on class dispatches" :expected ":str" :actual "(do (defmulti cm (fn [x] (class x))) (defmethod cm String [x] :str) (cm \"a\"))"} + {:suite "host-interop / class tokens & readers" :label "defmethod on nil dispatch value" :expected ":nil" :actual "(do (defmulti cn (fn [x] (class x))) (defmethod cn nil [x] :nil) (defmethod cn String [x] :str) (cn nil))"} + {:suite "host-interop / class tokens & readers" :label "Class str is class-prefixed" :expected "\"class java.lang.String\"" :actual "(str (class \"\"))"} + {:suite "host-interop / class tokens & readers" :label "Class getName" :expected "\"java.lang.String\"" :actual "(.getName (class \"\"))"} + {:suite "host-interop / class tokens & readers" :label "Class getSimpleName" :expected "\"Long\"" :actual "(.getSimpleName (class 5))"} + {:suite "host-interop / class tokens & readers" :label "Class of equal-typed values is =" :expected "true" :actual "(= (class 5) (class 6))"} + {:suite "host-interop / class tokens & readers" :label "Class in a thrown message" :expected "\"of class java.lang.String\"" :actual "(try (throw (Exception. (str \"of \" (class \"\")))) (catch Exception e (.getMessage e)))"} + {:suite "host-interop / class tokens & readers" :label "ctor sugar still constructs" :expected "\"x\"" :actual "(.toString (StringBuilder. \"x\"))"} + {:suite "host-interop / class tokens & readers" :label "return-hinted defn parses" :expected "7" :actual "(do (defn- hb ^bytes [b] b) (hb 7))"} + {:suite "host-interop / class tokens & readers" :label "hinted multi-arity parses" :expected ":two" :actual "((fn ([x] :one) (^String [x y] :two)) 1 2)"} + {:suite "host-interop / class tokens & readers" :label "slurp drains a StringReader" :expected "\"a=1\"" :actual "(slurp (StringReader. \"a=1\"))"} + {:suite "host-interop / class tokens & readers" :label "slurp accepts :encoding opts" :expected "\"b\"" :actual "(slurp (StringReader. \"b\") :encoding \"UTF-8\")"} + {:suite "host-interop / class tokens & readers" :label "replace with fn replacement is literal" :expected "\"$0\"" :actual "(do (require (quote [clojure.string :as s9])) (s9/replace \"x\" #\".\" (fn [m] \"$0\")))"} + {:suite "host-interop / class tokens & readers" :label "replace fn gets group vector" :expected "\"v=k\"" :actual "(do (require (quote [clojure.string :as s9])) (s9/replace \"k=v\" #\"(\\w+)=(\\w+)\" (fn [[_ k v]] (str v \"=\" k))))"} + {:suite "host-interop / class tokens & readers" :label "indexOf int needle is a char code" :expected "1" :actual "(.indexOf \"a=b\" 61)"} + {:suite "host-interop / exception + HashMap shims" :label "getMessage on a thrown string" :expected "\"class java.lang.String cannot be cast to class java.lang.Throwable (java.lang.String and java.lang.Throwable are in module java.base of loader 'bootstrap')\"" :actual "(try (throw \"boom\") (catch Throwable e (.getMessage e)))"} + {:suite "host-interop / exception + HashMap shims" :label "getMessage on ex-info" :expected "\"bad\"" :actual "(try (throw (ex-info \"bad\" {})) (catch Throwable e (.getMessage e)))"} + {:suite "host-interop / exception + HashMap shims" :label "HashMap get" :expected "2" :actual "(let [m (HashMap. {:a 1 :b 2})] (.get m :b))"} + {:suite "host-interop / exception + HashMap shims" :label "HashMap put + size" :expected "2" :actual "(let [m (HashMap. {})] (.put m :x 1) (.put m :y 2) (.size m))"} + {:suite "host-interop / reader-feature toggle" :label "features default to jolt+default" :expected "true" :actual "(contains? (set (__reader-features)) \"jolt\")"} + {:suite "host-interop / reader-feature toggle" :label "set + read back" :expected "true" :actual "(do (def prev (__reader-features)) (__reader-features-set! [\"clj\" \"jolt\" \"default\"]) (def r (contains? (set (__reader-features)) \"clj\")) (__reader-features-set! prev) r)"} + {:suite "host-interop / reader-feature toggle" :label "restore returns to default" :expected "false" :actual "(do (def prev (__reader-features)) (__reader-features-set! [\"clj\"]) (__reader-features-set! prev) (contains? (set (__reader-features)) \"clj\"))"} + {:suite "host-interop / migratus class shims" :label "Exception. message" :expected "\"boom\"" :actual "(try (throw (Exception. \"boom\")) (catch Throwable e (.getMessage e)))"} + {:suite "host-interop / migratus class shims" :label "IllegalArgumentException." :expected "\"bad\"" :actual "(try (throw (IllegalArgumentException. \"bad\")) (catch Exception e (.getMessage e)))"} + {:suite "host-interop / migratus class shims" :label "InterruptedException." :expected "\"stop\"" :actual "(try (throw (InterruptedException. \"stop\")) (catch Throwable e (.getMessage e)))"} + {:suite "host-interop / migratus class shims" :label "Character/isUpperCase" :expected "true" :actual "(Character/isUpperCase \\A)"} + {:suite "host-interop / migratus class shims" :label "Character/isLowerCase" :expected "true" :actual "(Character/isLowerCase \\a)"} + {:suite "host-interop / migratus class shims" :label "Character/isUpperCase neg" :expected "false" :actual "(Character/isUpperCase \\a)"} + {:suite "host-interop / migratus class shims" :label "Thread/interrupted" :expected "false" :actual "(Thread/interrupted)"} + {:suite "host-interop / migratus class shims" :label "Long/valueOf" :expected "42" :actual "(Long/valueOf \"42\")"} + {:suite "host-interop / migratus class shims" :label "Timestamp is millis" :expected "1000" :actual "(.getTime (java.util.Date. (java.sql.Timestamp. 1000)))"} + {:suite "host-interop / migratus class shims" :label "SimpleDateFormat UTC" :expected "\"19700101000000\"" :actual "(let [f (doto (java.text.SimpleDateFormat. \"yyyyMMddHHmmss\") (.setTimeZone (java.util.TimeZone/getTimeZone \"UTC\")))] (.format f (java.util.Date. 0)))"} + {:suite "host-interop / java.io.File" :label "instance? File" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (instance? java.io.File (io/file \"/a/b\")))"} + {:suite "host-interop / java.io.File" :label "str is the path" :expected "\"/a/b\"" :actual "(do (require '[clojure.java.io :as io]) (str (io/file \"/a/b\")))"} + {:suite "host-interop / java.io.File" :label "getName" :expected "\"c.txt\"" :actual "(do (require '[clojure.java.io :as io]) (.getName (io/file \"/a/b/c.txt\")))"} + {:suite "host-interop / java.io.File" :label "getPath joins" :expected "\"/a/b\"" :actual "(do (require '[clojure.java.io :as io]) (.getPath (io/file \"/a\" \"b\")))"} + {:suite "host-interop / java.io.File" :label "isDirectory of repo dir" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (.isDirectory (io/file \"docs\")))"} + {:suite "host-interop / java.io.File" :label "isFile of repo file" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (.isFile (io/file \"README.md\")))"} + {:suite "host-interop / java.io.File" :label "exists is false off-disk" :expected "false" :actual "(do (require '[clojure.java.io :as io]) (.exists (io/file \"/no/such/path/xyz\")))"} + {:suite "host-interop / java.io.File" :label "file-seq yields File values" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (every? (fn [f] (instance? java.io.File f)) (file-seq (io/file \"docs\"))))"} + {:suite "host-interop / java.io.File" :label "file-seq finds files" :expected "true" :actual "(do (require '[clojure.java.io :as io]) (pos? (count (filter (fn [f] (.isFile f)) (file-seq (io/file \"docs\"))))))"} + {:suite "host-interop / logging host shims" :label "LockingTransaction/isRunning" :expected "false" :actual "(clojure.lang.LockingTransaction/isRunning)"} + {:suite "host-interop / logging host shims" :label "pprint writes value" :expected "\"[1 2 3]\\n\"" :actual "(do (require '[clojure.pprint :as pp]) (with-out-str (pp/pprint [1 2 3])))"} + {:suite "host-interop / logging host shims" :label "with-pprint-dispatch runs body" :expected "42" :actual "(do (require '[clojure.pprint :as pp]) (pp/with-pprint-dispatch pp/code-dispatch 42))"} + {:suite "host-interop / macro dispatch & short-circuit patterns" :label "conditional-eval suppresses" :expected "0" :actual "(do (def ^:dynamic *enabled* false) (defmacro when-on [& body] `(when *enabled* ~@body)) (let [a (atom 0)] (when-on (reset! a 9)) @a))"} + {:suite "host-interop / macro dispatch & short-circuit patterns" :label "conditional-eval fires" :expected "9" :actual "(do (def ^:dynamic *enabled* true) (defmacro when-on [& body] `(when *enabled* ~@body)) (let [a (atom 0)] (when-on (reset! a 9)) @a))"} + {:suite "host-interop / macro dispatch & short-circuit patterns" :label "spy-like eval+print+return" :expected "3" :actual "(do (defmacro spylog [expr] `(let [v# ~expr] (println v#) v#)) (spylog (+ 1 2)))"} + {:suite "host-interop / macro dispatch & short-circuit patterns" :label "multi-arity 4 dispatch" :expected "[:single :double :triple :quad]" :actual "(do (defmacro ml ([a] :single) ([a b] :double) ([a b c] :triple) ([a b c d] :quad)) [(ml 1) (ml 1 2) (ml 1 2 3) (ml 1 2 3 4)])"} + {:suite "inst / reading & identity" :label "reads to inst" :expected "true" :actual "(inst? #inst \"2020-01-01T00:00:00Z\")"} + {:suite "inst / reading & identity" :label "inst? false on string" :expected "false" :actual "(inst? \"2020-01-01\")"} + {:suite "inst / reading & identity" :label "epoch zero" :expected "0" :actual "(inst-ms #inst \"1970-01-01T00:00:00Z\")"} + {:suite "inst / reading & identity" :label "one second" :expected "1000" :actual "(inst-ms #inst \"1970-01-01T00:00:01Z\")"} + {:suite "inst / reading & identity" :label "millis" :expected "123" :actual "(inst-ms #inst \"1970-01-01T00:00:00.123Z\")"} + {:suite "inst / reading & identity" :label "a real date" :expected "1577836800000" :actual "(inst-ms #inst \"2020-01-01T00:00:00Z\")"} + {:suite "inst / reading & identity" :label "inst-ms throws on non-inst" :expected :throws :actual "(inst-ms 42)"} + {:suite "inst / partial timestamps & offsets" :label "year only" :expected "true" :actual "(= #inst \"2020\" #inst \"2020-01-01T00:00:00.000Z\")"} + {:suite "inst / partial timestamps & offsets" :label "year-month" :expected "true" :actual "(= #inst \"2020-03\" #inst \"2020-03-01T00:00:00Z\")"} + {:suite "inst / partial timestamps & offsets" :label "date only" :expected "true" :actual "(= #inst \"2020-03-15\" #inst \"2020-03-15T00:00:00Z\")"} + {:suite "inst / partial timestamps & offsets" :label "positive offset" :expected "true" :actual "(= #inst \"2020-01-01T01:00:00+01:00\" #inst \"2020-01-01T00:00:00Z\")"} + {:suite "inst / partial timestamps & offsets" :label "negative offset" :expected "true" :actual "(= #inst \"2019-12-31T23:00:00-01:00\" #inst \"2020-01-01T00:00:00Z\")"} + {:suite "inst / partial timestamps & offsets" :label "-00:00 offset" :expected "true" :actual "(= #inst \"2020-01-01T00:00:00-00:00\" #inst \"2020-01-01T00:00:00Z\")"} + {:suite "inst / partial timestamps & offsets" :label "bad timestamp throws" :expected :throws :actual "#inst \"garbage\""} + {:suite "inst / value semantics & printing" :label "equal by instant" :expected "true" :actual "(= #inst \"2020-01-01T00:00:00Z\" #inst \"2020-01-01T00:00:00.000Z\")"} + {:suite "inst / value semantics & printing" :label "unequal instants" :expected "false" :actual "(= #inst \"2020-01-01T00:00:00Z\" #inst \"2020-01-01T00:00:01Z\")"} + {:suite "inst / value semantics & printing" :label "works as map key" :expected ":v" :actual "(get {#inst \"2020-01-01T00:00:00Z\" :v} #inst \"2020-01-01T00:00:00.000Z\")"} + {:suite "inst / value semantics & printing" :label "pr-str round-trips" :expected "\"#inst \\\"2020-01-01T00:00:00.000-00:00\\\"\"" :actual "(pr-str #inst \"2020-01-01T00:00:00Z\")"} + {:suite "io / with-out-str captures" :label "println" :expected "\"hi\\n\"" :actual "(with-out-str (println \"hi\"))"} + {:suite "io / with-out-str captures" :label "print spaces" :expected "\"a b\"" :actual "(with-out-str (print \"a\" \"b\"))"} + {:suite "io / with-out-str captures" :label "prn quotes" :expected "\"[1 2]\\n\"" :actual "(with-out-str (prn [1 2]))"} + {:suite "io / with-out-str captures" :label "pr no newline" :expected "\"5\"" :actual "(with-out-str (pr 5))"} + {:suite "io / with-out-str captures" :label "multiple writes" :expected "\"12\"" :actual "(with-out-str (print 1) (print 2))"} + {:suite "io / with-out-str captures" :label "no output" :expected "\"\"" :actual "(with-out-str 42)"} + {:suite "io / with-out-str captures" :label "println no args" :expected "\"\\n\"" :actual "(with-out-str (println))"} + {:suite "io / *-str builders" :label "print-str" :expected "\"a b\"" :actual "(print-str \"a\" \"b\")"} + {:suite "io / *-str builders" :label "println-str" :expected "\"x\\n\"" :actual "(println-str \"x\")"} + {:suite "io / *-str builders" :label "prn-str" :expected "\"[1 2]\\n\"" :actual "(prn-str [1 2])"} + {:suite "io / *-str builders" :label "pr-str quotes" :expected "\"\\\"s\\\"\"" :actual "(pr-str \"s\")"} + {:suite "io / *-str builders" :label "pr-str keyword" :expected "\":a\"" :actual "(pr-str :a)"} + {:suite "io / str & format" :label "str concat" :expected "\"1:ab\"" :actual "(str 1 :a \"b\")"} + {:suite "io / str & format" :label "str nil" :expected "\"\"" :actual "(str nil)"} + {:suite "io / str & format" :label "str of coll" :expected "\"[1 2]\"" :actual "(str [1 2])"} + {:suite "io / str & format" :label "format d/s" :expected "\"5-x\"" :actual "(format \"%d-%s\" 5 \"x\")"} + {:suite "io / str & format" :label "format float" :expected "\"3.14\"" :actual "(format \"%.2f\" 3.14159)"} + {:suite "io / *in* + with-in-str + read-line" :label "read-line one line" :expected "\"hello\"" :actual "(with-in-str \"hello\" (read-line))"} + {:suite "io / *in* + with-in-str + read-line" :label "read-line strips nl" :expected "\"a\"" :actual "(with-in-str \"a\\nb\" (read-line))"} + {:suite "io / *in* + with-in-str + read-line" :label "read-line sequential" :expected "[\"a\" \"b\"]" :actual "(with-in-str \"a\\nb\" [(read-line) (read-line)])"} + {:suite "io / *in* + with-in-str + read-line" :label "read-line EOF nil" :expected "nil" :actual "(with-in-str \"\" (read-line))"} + {:suite "io / *in* + with-in-str + read-line" :label "read-line after last" :expected "[\"x\" nil]" :actual "(with-in-str \"x\" [(read-line) (read-line)])"} + {:suite "io / *in* + with-in-str + read-line" :label "empty line" :expected "[\"\" \"y\"]" :actual "(with-in-str \"\\ny\" [(read-line) (read-line)])"} + {:suite "io / *in* + with-in-str + read-line" :label "*in* is bound" :expected "false" :actual "(with-in-str \"\" (map? *in*))"} + {:suite "io / read" :label "read a form" :expected "42" :actual "(with-in-str \"42\" (read))"} + {:suite "io / read" :label "read a list form" :expected "(quote (+ 1 2))" :actual "(with-in-str \"(+ 1 2)\" (read))"} + {:suite "io / read" :label "read two forms" :expected "[1 2]" :actual "(with-in-str \"1 2\" [(read) (read)])"} + {:suite "io / read" :label "read then read-line" :expected "[1 \" rest\"]" :actual "(with-in-str \"1 rest\\nnext\" [(read) (read-line)])"} + {:suite "io / read" :label "read vector" :expected "[1 2]" :actual "(with-in-str \"[1 2]\" (read))"} + {:suite "io / read" :label "read nil literal" :expected "nil" :actual "(with-in-str \"nil\" (read))"} + {:suite "io / read" :label "read EOF throws" :expected :throws :actual "(with-in-str \"\" (read))"} + {:suite "io / read" :label "read EOF value" :expected ":done" :actual "(with-in-str \"\" (read *in* false :done))"} + {:suite "io / read" :label "read eval data" :expected "3" :actual "(with-in-str \"(+ 1 2)\" (eval (read)))"} + {:suite "io / line-seq" :label "line-seq" :expected "[\"a\" \"b\" \"c\"]" :actual "(with-in-str \"a\\nb\\nc\" (vec (line-seq *in*)))"} + {:suite "io / line-seq" :label "line-seq empty" :expected "nil" :actual "(with-in-str \"\" (seq (line-seq *in*)))"} + {:suite "io / line-seq" :label "line-seq is lazy seq" :expected "true" :actual "(with-in-str \"a\\nb\" (seq? (line-seq *in*)))"} + {:suite "io / line-seq" :label "line-seq count" :expected "3" :actual "(with-in-str \"1\\n2\\n3\" (count (line-seq *in*)))"} + {:suite "io / print family (overlay)" :label "pr-str multi-arg spacing" :expected "\"\\\"a\\\" [1 2] :k\"" :actual "(pr-str \"a\" [1 2] :k)"} + {:suite "io / print family (overlay)" :label "pr-str zero args" :expected "\"\"" :actual "(pr-str)"} + {:suite "io / print family (overlay)" :label "pr-str escapes" :expected "\"\\\"a\\\\\\\"b\\\"\"" :actual "(pr-str \"a\\\"b\")"} + {:suite "io / print family (overlay)" :label "print is unreadable" :expected "\"a b\"" :actual "(with-out-str (print \"a\" \"b\"))"} + {:suite "io / print family (overlay)" :label "println appends newline" :expected "\"x 1\\n\"" :actual "(with-out-str (println \"x\" 1))"} + {:suite "io / print family (overlay)" :label "prn is readable + newline" :expected "\"[1 \\\"s\\\"]\\n\"" :actual "(with-out-str (prn [1 \"s\"]))"} + {:suite "io / print family (overlay)" :label "pr writes no newline" :expected "\"\\\\a\"" :actual "(with-out-str (pr \\a))"} + {:suite "io / print family (overlay)" :label "print nil arg" :expected "\"nil\"" :actual "(with-out-str (print nil))"} + {:suite "io / print family (overlay)" :label "prn keyword" :expected "\":k\\n\"" :actual "(with-out-str (prn :k))"} + {:suite "io / print-method multimethod" :label "records print canonically" :expected "\"#user.Pt{:x 1, :y 2}\"" :actual "(do (defrecord Pt [x y]) (pr-str (->Pt 1 2)))"} + {:suite "io / print-method multimethod" :label "records nested in colls" :expected "\"[#user.Pt{:x 1, :y 2}]\"" :actual "(do (defrecord Pt [x y]) (pr-str [(->Pt 1 2)]))"} + {:suite "io / print-method multimethod" :label "defmethod overrides a record, top level" :expected "\"#user.Pt{:x 3, :y 4}\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (pr-str (->Pt 3 4)))"} + {:suite "io / print-method multimethod" :label "defmethod fires nested in a map" :expected "\"{:p #user.Pt{:x 5, :y 6}}\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (pr-str {:p (->Pt 5 6)}))"} + {:suite "io / print-method multimethod" :label "defmethod fires through prn" :expected "\"[#user.Pt{:x 1, :y 2}]\\n\"" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] (.write w (str \"<\" (:x r) \",\" (:y r) \">\"))) (with-out-str (prn [(->Pt 1 2)])))"} + {:suite "io / print-method multimethod" :label "direct call uses :default" :expected "\"42\"" :actual "(let [w (StringWriter.)] (print-method 42 w) (.toString w))"} + {:suite "io / print-method multimethod" :label "direct builtin override" :expected "\"#42#\"" :actual "(do (defmethod print-method :number [n w] (.write w (str \"#\" n \"#\"))) (let [w (StringWriter.)] (print-method 42 w) (.toString w)))"} + {:suite "io / print-method multimethod" :label "print-dup routes to print-method" :expected "\"[1 2]\"" :actual "(let [w (StringWriter.)] (print-dup [1 2] w) (.toString w))"} + {:suite "io / print-method multimethod" :label "StringWriter accumulates" :expected "\"ab\"" :actual "(let [w (StringWriter.)] (.write w \"a\") (.append w \\b) (.toString w))"} + {:suite "io / print-method multimethod" :label "methods table inspectable" :expected "true" :actual "(do (defrecord Pt [x y]) (defmethod print-method (quote user.Pt) [r w] r) (contains? (methods print-method) (quote user.Pt)))"} + {:suite "io / cold tagged types via print-method" :label "uuid" :expected "\"#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"\"" :actual "(pr-str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "io / cold tagged types via print-method" :label "uuid nested" :expected "\"[#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"]\"" :actual "(pr-str [(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")])"} + {:suite "io / cold tagged types via print-method" :label "regex" :expected "\"#\\\"a+b\\\"\"" :actual "(pr-str #\"a+b\")"} + {:suite "io / cold tagged types via print-method" :label "transient vector" :expected "\"#object[clojure.lang.PersistentVector$TransientVector 0xa4ac20b \\\"clojure.lang.PersistentVector$TransientVector@a4ac20b\\\"]\"" :actual "(pr-str (transient [1]))"} + {:suite "io / cold tagged types via print-method" :label "transient map" :expected "\"#object[clojure.lang.PersistentArrayMap$TransientArrayMap 0x79939c8 \\\"clojure.lang.PersistentArrayMap$TransientArrayMap@79939c8\\\"]\"" :actual "(pr-str (transient {:a 1}))"} + {:suite "io / cold tagged types via print-method" :label "atom override fires nested" :expected "\"{:a #object[clojure.lang.Atom 0x2bb39d6c {:status :ready, :val 7}]}\"" :actual "(do (defmethod print-method :jolt/atom [a w] (.write w (str \"#atom[\" (deref a) \"]\"))) (pr-str {:a (atom 7)}))"} + {:suite "io / cold tagged types via print-method" :label "uuid through str unchanged" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "ISeq call forms" :label "eval a cons'd call" :expected "3" :actual "(eval (cons (quote +) (quote (1 2))))"} + {:suite "ISeq call forms" :label "eval a list-built call" :expected "6" :actual "(eval (list (quote +) 1 2 3))"} + {:suite "ISeq call forms" :label "eval a concat'd call" :expected "10" :actual "(eval (concat (list (quote +)) (list 1 2 3 4)))"} + {:suite "ISeq call forms" :label "nested cons'd subform" :expected "7" :actual "(eval (list (quote +) 3 (cons (quote +) (quote (1 3)))))"} + {:suite "ISeq call forms" :label "empty list self-evals" :expected "[]" :actual "(eval (list))"} + {:suite "ISeq call forms" :label "macro output via cons" :expected "3" :actual "(do (defmacro mc [] (cons (quote +) (quote (1 2)))) (mc))"} + {:suite "ISeq call forms" :label "macro output via concat" :expected "6" :actual "(do (defmacro mk [] (concat (list (quote +)) (list 1 2 3))) (mk))"} + {:suite "ISeq call forms" :label "vector value self-evals" :expected "[1 2 3]" :actual "(eval (vec [1 2 3]))"} + {:suite "ISeq call forms" :label "quoted list of data" :expected "[1 2 3]" :actual "(quote (1 2 3))"} + {:suite "lazy / construction & laziness" :label "lazy-seq value" :expected "[1 2 3]" :actual "(take 3 (lazy-seq (cons 1 (lazy-seq (cons 2 (lazy-seq (cons 3 nil)))))))"} + {:suite "lazy / construction & laziness" :label "not eagerly evaluated" :expected "0" :actual "(let [c (atom 0)] (lazy-seq (swap! c inc) nil) @c)"} + {:suite "lazy / construction & laziness" :label "realized on demand" :expected "1" :actual "(let [c (atom 0) s (lazy-seq (swap! c inc) [1])] (first s) @c)"} + {:suite "lazy / construction & laziness" :label "lazy-cat" :expected "[0 1 2 3]" :actual "(lazy-cat [0 1] [2 3])"} + {:suite "lazy / construction & laziness" :label "doall forces" :expected "[2 3 4]" :actual "(doall (map inc [1 2 3]))"} + {:suite "lazy / construction & laziness" :label "dorun returns nil" :expected "nil" :actual "(dorun (map inc [1 2 3]))"} + {:suite "lazy / infinite" :label "take from repeat" :expected "[7 7 7]" :actual "(take 3 (repeat 7))"} + {:suite "lazy / infinite" :label "take from iterate" :expected "[1 2 4 8]" :actual "(take 4 (iterate (fn [x] (* 2 x)) 1))"} + {:suite "lazy / infinite" :label "take from cycle" :expected "[1 2 1 2]" :actual "(take 4 (cycle [1 2]))"} + {:suite "lazy / infinite" :label "take from range" :expected "[0 1 2]" :actual "(take 3 (range))"} + {:suite "lazy / infinite" :label "drop then take" :expected "[5 6 7]" :actual "(take 3 (drop 5 (range)))"} + {:suite "lazy / infinite" :label "filter infinite" :expected "[0 2 4]" :actual "(take 3 (filter even? (range)))"} + {:suite "lazy / infinite" :label "map infinite" :expected "[0 1 4]" :actual "(take 3 (map (fn [x] (* x x)) (range)))"} + {:suite "lazy / infinite" :label "nth of infinite" :expected "100" :actual "(nth (range) 100)"} + {:suite "lazy / self-referential" :label "self-ref ones" :expected "[1 1 1 1 1]" :actual "(do (def ones (lazy-seq (cons 1 ones))) (take 5 ones))"} + {:suite "lazy / self-referential" :label "self-ref nats" :expected "[0 1 2 3 4]" :actual "(do (def nats (lazy-cat [0] (map inc nats))) (take 5 nats))"} + {:suite "lazy / self-referential" :label "self-ref fib" :expected "[0 1 1 2 3 5 8 13 21 34]" :actual "(do (def fib (lazy-cat [0 1] (map + (rest fib) fib))) (take 10 fib))"} + {:suite "lazy / realized?" :label "unrealized" :expected "false" :actual "(realized? (lazy-seq (cons 1 nil)))"} + {:suite "lazy / realized?" :label "realized after" :expected "true" :actual "(let [s (lazy-seq (cons 1 nil))] (first s) (realized? s))"} + {:suite "lazy / realized?" :label "body runs once" :expected "1" :actual "(let [c (atom 0) s (lazy-seq (do (swap! c inc) [1 2 3]))] (seq s) (seq s) @c)"} + {:suite "lazy-seq / realization is shared across walks" :label "effects run once across three walks" :expected "3" :actual "(let [a (atom 0) s (map (fn [x] (swap! a inc) x) [1 2 3])] (doall s) (dorun s) (vec s) (deref a))"} + {:suite "lazy-seq / realization is shared across walks" :label "values stable across walks" :expected "true" :actual "(let [s (map inc [1 2 3])] (= (vec s) (vec s) [2 3 4]))"} + {:suite "lazy-seq / realization is shared across walks" :label "filter effects once" :expected "4" :actual "(let [a (atom 0) s (filter (fn [x] (swap! a inc) (odd? x)) [1 2 3 4])] (dorun s) (count s) (deref a))"} + {:suite "list / construct & predicate" :label "list" :expected "[1 2 3]" :actual "(list 1 2 3)"} + {:suite "list / construct & predicate" :label "empty list" :expected "[]" :actual "(list)"} + {:suite "list / construct & predicate" :label "quoted list" :expected "[1 2 3]" :actual "(quote (1 2 3))"} + {:suite "list / construct & predicate" :label "list? true" :expected "true" :actual "(list? (list 1 2))"} + {:suite "list / construct & predicate" :label "list? on conj result" :expected "true" :actual "(list? (conj (list 1) 0))"} + {:suite "list / construct & predicate" :label "count" :expected "3" :actual "(count (list 1 2 3))"} + {:suite "list / construct & predicate" :label "empty? true" :expected "true" :actual "(empty? (list))"} + {:suite "list / construct & predicate" :label "list = vector elts" :expected "true" :actual "(= (list 1 2 3) [1 2 3])"} + {:suite "list / access & update" :label "first" :expected "1" :actual "(first (list 1 2 3))"} + {:suite "list / access & update" :label "rest" :expected "[2 3]" :actual "(rest (list 1 2 3))"} + {:suite "list / access & update" :label "peek is first" :expected "1" :actual "(peek (list 1 2 3))"} + {:suite "list / access & update" :label "pop drops first" :expected "[2 3]" :actual "(pop (list 1 2 3))"} + {:suite "list / access & update" :label "conj prepends" :expected "[0 1 2]" :actual "(conj (list 1 2) 0)"} + {:suite "list / access & update" :label "conj many prepends" :expected "[4 3 1 2]" :actual "(conj (list 1 2) 3 4)"} + {:suite "list / access & update" :label "cons prepends" :expected "[0 1 2]" :actual "(cons 0 (list 1 2))"} + {:suite "list / access & update" :label "nth" :expected "20" :actual "(nth (list 10 20 30) 1)"} + {:suite "list / immutability & performance" :label "conj does not mutate" :expected "true" :actual "(let [l (list 1 2 3) m (conj l 0)] (and (= l [1 2 3]) (= m [0 1 2 3])))"} + {:suite "list / immutability & performance" :label "reduce conj builds" :expected "[2 1 0]" :actual "(reduce conj (list) (range 3))"} + {:suite "list / immutability & performance" :label "O(1) conj at scale" :expected "200000" :actual "(count (reduce conj (list) (range 200000)))"} + {:suite "list / immutability & performance" :label "scale head correct" :expected "199999" :actual "(first (reduce conj (list) (range 200000)))"} + {:suite "macros / quoting" :label "quote symbol" :expected "(quote a)" :actual "(quote a)"} + {:suite "macros / quoting" :label "quote list" :expected "[1 2 3]" :actual "(quote (1 2 3))"} + {:suite "macros / quoting" :label "quote nested" :expected "[1 [2 3]]" :actual "(quote (1 (2 3)))"} + {:suite "macros / quoting" :label "quote sugar" :expected "'a" :actual "'a"} + {:suite "macros / quoting" :label "syntax-quote literal" :expected "[1 2]" :actual "`[1 2]"} + {:suite "macros / quoting" :label "unquote" :expected "[1 2 3]" :actual "(let [x 2] `[1 ~x 3])"} + {:suite "macros / quoting" :label "unquote-splicing" :expected "[1 2 3 4]" :actual "(let [xs [2 3]] `[1 ~@xs 4])"} + {:suite "macros / quoting" :label "unquote in list" :expected "[3]" :actual "(let [x 3] `(~x))"} + {:suite "macros / quoting" :label "syntax-quote symbol qualifies" :expected "true" :actual "(symbol? `foo)"} + {:suite "macros / defmacro" :label "simple macro" :expected "3" :actual "(do (defmacro m [a b] `(+ ~a ~b)) (m 1 2))"} + {:suite "macros / defmacro" :label "macro unless" :expected "1" :actual "(do (defmacro unless [c body] `(if ~c nil ~body)) (unless false 1))"} + {:suite "macros / defmacro" :label "macro with body splice" :expected "6" :actual "(do (defmacro msum [& xs] `(+ ~@xs)) (msum 1 2 3))"} + {:suite "macros / defmacro" :label "macroexpand-1" :expected "false" :actual "(do (defmacro m [x] `(inc ~x)) (list? (macroexpand-1 '(m 5))))"} + {:suite "macros / defmacro" :label "gensym unique" :expected "false" :actual "(= (gensym) (gensym))"} + {:suite "macros / defmacro" :label "gensym# in template" :expected "true" :actual "(do (defmacro m [] `(let [x# 1] x#)) (= 1 (m)))"} + {:suite "macros / defmacro" :label "#() inside syntax-quote" :expected "[2 4 6]" :actual "(do (defmacro m [] `(mapv #(* % 2) [1 2 3])) (m))"} + {:suite "macros / defmacro" :label "#() + auto-gensym share in template" :expected "\"ab\"" :actual "(do (defmacro m [] `(let [sb# (StringBuilder.)] (mapv #(.append sb# %) [\"a\" \"b\"]) (.toString sb#))) (m))"} + {:suite "macros / core-overlay" :label "if-not true branch" :expected ":then" :actual "(if-not false :then :else)"} + {:suite "macros / core-overlay" :label "if-not else branch" :expected ":else" :actual "(if-not true :then :else)"} + {:suite "macros / core-overlay" :label "if-not no else" :expected "nil" :actual "(if-not true :then)"} + {:suite "macros / core-overlay" :label "if-not no else hit" :expected ":then" :actual "(if-not false :then)"} + {:suite "macros / core-overlay" :label "comment -> nil" :expected "nil" :actual "(comment a b c)"} + {:suite "macros / core-overlay" :label "comment in do" :expected "42" :actual "(do (comment ignored) 42)"} + {:suite "macros / core-overlay" :label "if-let then" :expected "6" :actual "(if-let [x 5] (inc x) :none)"} + {:suite "macros / core-overlay" :label "if-let else" :expected ":none" :actual "(if-let [x nil] (inc x) :none)"} + {:suite "macros / core-overlay" :label "if-let else scope" :expected "9" :actual "(let [x 9] (if-let [x nil] :t x))"} + {:suite "macros / core-overlay" :label "if-some zero" :expected "1" :actual "(if-some [x 0] (inc x) :none)"} + {:suite "macros / core-overlay" :label "if-some nil" :expected ":none" :actual "(if-some [x nil] x :none)"} + {:suite "macros / core-overlay" :label "when-some multi" :expected "14" :actual "(when-some [x 7] (inc x) (* x 2))"} + {:suite "macros / core-overlay" :label "when-some nil" :expected "nil" :actual "(when-some [x nil] x)"} + {:suite "macros / core-overlay" :label "while loop" :expected "3" :actual "(let [a (atom 0)] (while (< @a 3) (swap! a inc)) @a)"} + {:suite "macros / core-overlay" :label "dotimes sum" :expected "10" :actual "(let [a (atom 0)] (dotimes [i 5] (swap! a + i)) @a)"} + {:suite "macros / core-overlay" :label "as-> threads" :expected "12" :actual "(as-> 5 x (+ x 1) (* x 2))"} + {:suite "macros / core-overlay" :label "as-> no forms" :expected "5" :actual "(as-> 5 x)"} + {:suite "macros / core-overlay" :label "some-> through" :expected "6" :actual "(some-> {:a {:b 5}} :a :b inc)"} + {:suite "macros / core-overlay" :label "some-> short-circuit" :expected "nil" :actual "(some-> {:a nil} :a :b)"} + {:suite "macros / core-overlay" :label "some->> through" :expected "9" :actual "(some->> [1 2 3] (map inc) (reduce +))"} + {:suite "macros / core-overlay" :label "some->> nil" :expected "nil" :actual "(some->> nil (map inc))"} + {:suite "macros / core-overlay" :label "doto returns obj" :expected "[1 2]" :actual "(deref (doto (atom []) (swap! conj 1) (swap! conj 2)))"} + {:suite "macros / core-overlay" :label "when-first" :expected "20" :actual "(when-first [x [10 20 30]] (* x 2))"} + {:suite "macros / core-overlay" :label "when-first empty" :expected "nil" :actual "(when-first [x []] :body)"} + {:suite "macros / core-overlay" :label "when-first nil coll" :expected "nil" :actual "(when-first [x nil] :body)"} + {:suite "macros / core-overlay" :label "when-first range" :expected "0" :actual "(when-first [x (range 5)] x)"} + {:suite "macros / core-overlay" :label "cond->> threads" :expected "12" :actual "(cond->> 5 true (+ 1) false (* 100) true (* 2))"} + {:suite "macros / core-overlay" :label "cond->> skip" :expected "10" :actual "(cond->> 10 false (+ 1))"} + {:suite "macros / core-overlay" :label "assert pass" :expected ":ok" :actual "(do (assert (= 1 1)) :ok)"} + {:suite "macros / core-overlay" :label "assert throws" :expected ":threw" :actual "(try (assert (= 1 2)) (catch :default e :threw))"} + {:suite "macros / core-overlay" :label "assert message" :expected "\"nope\"" :actual "(try (assert false \"nope\") (catch :default e (ex-message e)))"} + {:suite "macros / core-overlay" :label "delay value" :expected "42" :actual "(deref (delay 42))"} + {:suite "macros / core-overlay" :label "delay forces once" :expected "1" :actual "(let [c (atom 0) d (delay (swap! c inc))] @d @d @c)"} + {:suite "macros / core-overlay" :label "future deref" :expected "9" :actual "(deref (future (* 3 3)))"} + {:suite "macros / core-overlay" :label "letfn simple" :expected "25" :actual "(letfn [(sq [x] (* x x))] (sq 5))"} + {:suite "macros / core-overlay" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] (ev? 8))"} + {:suite "macros / core-overlay" :label "condp match" :expected ":two" :actual "(condp = 2 1 :one 2 :two 3 :three)"} + {:suite "macros / core-overlay" :label "condp default" :expected ":else" :actual "(condp = 9 1 :one 2 :two :else)"} + {:suite "macros / core-overlay" :label "condp :>> form" :expected "\"got 2\"" :actual "(condp some [1 2 3] #{0 9} :>> (fn [x] (str \"got \" x)) #{2 6} :>> (fn [x] (str \"got \" x)))"} + {:suite "macros / core-overlay" :label "condp no match" :expected ":threw" :actual "(try (condp = 9 1 :one) (catch :default e :threw))"} + {:suite "macros / core-overlay" :label "binding rebinds" :expected "99" :actual "(do (def ^:dynamic *bx* 10) (binding [*bx* 99] *bx*))"} + {:suite "macros / core-overlay" :label "binding restores" :expected "10" :actual "(do (def ^:dynamic *by* 10) (binding [*by* 99] *by*) *by*)"} + {:suite "macros / core-overlay" :label "binding seen by fn" :expected "7" :actual "(do (def ^:dynamic *bz* 0) (defn rdz [] *bz*) (binding [*bz* 7] (rdz)))"} + {:suite "macros / time, with-redefs, macroexpand" :label "time returns value" :expected "3" :actual "(time (+ 1 2))"} + {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs rebinds" :expected "42" :actual "(do (defn wr-f [] 1) (with-redefs [wr-f (fn [] 42)] (wr-f)))"} + {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs restores" :expected "1" :actual "(do (defn wr-g [] 1) (with-redefs [wr-g (fn [] 42)]) (wr-g))"} + {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs restores on throw" :expected "1" :actual "(do (defn wr-h [] 1) (try (with-redefs [wr-h (fn [] 42)] (throw (ex-info \"x\" {}))) (catch :default e nil)) (wr-h))"} + {:suite "macros / time, with-redefs, macroexpand" :label "with-redefs-fn" :expected "42" :actual "(do (defn wr-i [] 1) (with-redefs-fn {(var wr-i) (fn [] 42)} (fn [] (wr-i))))"} + {:suite "macros / time, with-redefs, macroexpand" :label "macroexpand full" :expected "true" :actual "(let [e (macroexpand (quote (when-not false 1)))] (= (quote if) (first e)))"} + {:suite "macros / time, with-redefs, macroexpand" :label "macroexpand non-macro" :expected "[1 2]" :actual "(macroexpand (quote [1 2]))"} + {:suite "macros / defmacro arity-clause & name metadata" :label "arity-clause form" :expected "10" :actual "(do (defmacro tw ([x] (list (quote *) x 2))) (tw 5))"} + {:suite "macros / defmacro arity-clause & name metadata" :label "docstring + arity" :expected "15" :actual "(do (defmacro th \"triple\" ([x] (list (quote *) x 3))) (th 5))"} + {:suite "macros / defmacro arity-clause & name metadata" :label "^{:map} name meta" :expected "7" :actual "(do (defmacro ^{:private true} pm [] 7) (pm))"} + {:suite "macros / defmacro arity-clause & name metadata" :label "multi-form body" :expected "6" :actual "(do (defmacro mb ([a b] (list (quote +) a b))) (mb 2 4))"} + {:suite "macros / defmacro multi-arity & attr-map" :label "multi-arity 1" :expected "6" :actual "(do (defmacro ma ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b))) (ma 5))"} + {:suite "macros / defmacro multi-arity & attr-map" :label "multi-arity 2" :expected "5" :actual "(do (defmacro ma ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b))) (ma 2 3))"} + {:suite "macros / defmacro multi-arity & attr-map" :label "arity delegates" :expected "[:d nil 9]" :actual "(do (defmacro lg ([m] `(lg :d nil ~m)) ([l t m] (list (quote vector) l t m))) (lg 9))"} + {:suite "macros / defmacro multi-arity & attr-map" :label "doc + attr-map + params" :expected "10" :actual "(do (defmacro am \"doc\" {:arglists (quote ([x]))} [x] (list (quote inc) x)) (am 9))"} + {:suite "macros / defmacro multi-arity & attr-map" :label "doc + attr-map + variadic" :expected "6" :actual "(do (defmacro vg \"d\" {:arglists (quote ([& a]))} [& xs] `(+ ~@xs)) (vg 1 2 3))"} + {:suite "maps / keyword invoke" :label "hit" :expected "1" :actual "(:a {:a 1 :b 2})"} + {:suite "maps / keyword invoke" :label "miss" :expected "nil" :actual "(:z {:a 1})"} + {:suite "maps / keyword invoke" :label "miss with default" :expected ":d" :actual "(:z {:a 1} :d)"} + {:suite "maps / keyword invoke" :label "hit with default" :expected "1" :actual "(:a {:a 1} :d)"} + {:suite "maps / keyword invoke" :label "on nil" :expected "nil" :actual "(:a nil)"} + {:suite "maps / keyword invoke" :label "on nil with default" :expected ":d" :actual "(:a nil :d)"} + {:suite "maps / keyword invoke" :label "nil value is present" :expected "nil" :actual "(:a {:a nil} :d)"} + {:suite "maps / keyword invoke" :label "false value is present" :expected "false" :actual "(:a {:a false} :d)"} + {:suite "maps / keyword invoke" :label "on a vector" :expected "nil" :actual "(:a [1 2 3])"} + {:suite "maps / keyword invoke" :label "on a number" :expected "nil" :actual "(:a 42)"} + {:suite "maps / keyword invoke" :label "on a sorted map" :expected "2" :actual "(:b (sorted-map :a 1 :b 2))"} + {:suite "maps / keyword invoke" :label "on assoc result" :expected "3" :actual "(:c (assoc {:a 1} :c 3))"} + {:suite "maps / keyword invoke" :label "on a record field" :expected "5" :actual "(do (defrecord KFP [x]) (:x (->KFP 5)))"} + {:suite "maps / keyword invoke" :label "qualified keyword" :expected "1" :actual "(:n/a {:n/a 1})"} + {:suite "maps / keyword invoke" :label "nested in expr" :expected "6" :actual "(+ (:a {:a 1}) (:b {:b 2}) (:c {:c 3}))"} + {:suite "maps / keyword invoke" :label "evaluates map expr once" :expected "[2 1]" :actual "(do (def cnt (atom 0)) (let [v (:a (do (swap! cnt inc) {:a 2}))] [v @cnt]))"} + {:suite "maps / literal construction" :label "basic" :expected "{:a 1, :b 2}" :actual "{:a 1 :b 2}"} + {:suite "maps / literal construction" :label "empty" :expected "{}" :actual "{}"} + {:suite "maps / literal construction" :label "computed values" :expected "{:a 3}" :actual "{:a (+ 1 2)}"} + {:suite "maps / literal construction" :label "nil value kept" :expected "true" :actual "(contains? {:a nil} :a)"} + {:suite "maps / literal construction" :label "nil value lookup" :expected "nil" :actual "(get {:a nil} :a :d)"} + {:suite "maps / literal construction" :label "string key" :expected "1" :actual "(get {\"k\" 1} \"k\")"} + {:suite "maps / literal construction" :label "number key" :expected ":one" :actual "(get {1 :one} 1)"} + {:suite "maps / literal construction" :label "collection key" :expected ":v" :actual "(get {[1 2] :v} [1 2])"} + {:suite "maps / literal construction" :label "collection value-equal key" :expected ":v" :actual "(get {[1 2] :v} (vector 1 2))"} + {:suite "maps / literal construction" :label "computed key" :expected "1" :actual "(get {(keyword \"a\") 1} :a)"} + {:suite "maps / literal construction" :label "values evaluate in source order" :expected "[1 2 3]" :actual "(do (def log (atom [])) {:a (swap! log conj 1) :b (swap! log conj 2) :c (swap! log conj 3)} (deref log))"} + {:suite "maps / literal construction" :label "keys evaluate before their values, pairwise" :expected "[:k1 :v1 :k2 :v2]" :actual "(do (def log (atom [])) {(do (swap! log conj :k1) :a) (do (swap! log conj :v1) 1) (do (swap! log conj :k2) :b) (do (swap! log conj :v2) 2)} (deref log))"} + {:suite "maps / literal construction" :label "source order with a nil value (phm form)" :expected "[1 2 3]" :actual "(do (def log (atom [])) {:a (do (swap! log conj 1) nil) :b (swap! log conj 2) :c (swap! log conj 3)} (deref log))"} + {:suite "maps / literal construction" :label "source order through syntax-quote" :expected "[2 1]" :actual "(do (def log (atom [])) (defmacro m-p3c [] `{:a ~(list 'swap! 'log 'conj 1) :b ~(list 'swap! 'log 'conj 2)}) (m-p3c) (deref log))"} + {:suite "maps / literal construction" :label "count" :expected "3" :actual "(count {:a 1 :b 2 :c 3})"} + {:suite "maps / literal construction" :label "equality with phm" :expected "true" :actual "(= {:a 1 :b 2} (assoc {:a 1} :b 2))"} + {:suite "maps / literal construction" :label "keys work after assoc" :expected "2" :actual "(:b (assoc {:a 1 :b 2} :c 3))"} + {:suite "maps / literal construction" :label "literal in fn body" :expected "12" :actual "(do (defn mfp-mk [x] {:v (* x 2)}) (:v (mfp-mk 6)))"} + {:suite "clojure.math" :label "sqrt" :expected "true" :actual "(< 1.4142 (clojure.math/sqrt 2) 1.4143)"} + {:suite "clojure.math" :label "pow" :expected "1024" :actual "(long (clojure.math/pow 2 10))"} + {:suite "clojure.math" :label "tan of 0" :expected "0" :actual "(long (clojure.math/tan 0))"} + {:suite "clojure.math" :label "round" :expected "3" :actual "(clojure.math/round 2.6)"} + {:suite "clojure.math" :label "floor" :expected "2.0" :actual "(clojure.math/floor 2.9)"} + {:suite "clojure.math" :label "signum" :expected "-1.0" :actual "(clojure.math/signum -7.2)"} + {:suite "clojure.math" :label "to-radians" :expected "true" :actual "(< 3.14 (clojure.math/to-radians 180) 3.15)"} + {:suite "clojure.math" :label "PI" :expected "true" :actual "(< 3.14 clojure.math/PI 3.15)"} + {:suite "clojure.math" :label "require + alias" :expected "5" :actual "(do (require '[clojure.math :as m]) (long (m/hypot 3 4)))"} + {:suite "clojure.math" :label "as a value" :expected "[1 2]" :actual "(mapv (comp long clojure.math/sqrt) [1 4])"} + {:suite "calls / locals named like core macros" :label "local fn named repeat" :expected "[1 1]" :actual "(let [repeat (fn [x] [x x])] (repeat 1))"} + {:suite "calls / locals named like core macros" :label "local fn named seq" :expected ":end" :actual "((fn seq [n] (if (pos? n) (seq (dec n)) :end)) 2)"} + {:suite "calls / locals named like core macros" :label "local fn named loop2" :expected "[2 1]" :actual "(let [with (fn [a b] [b a])] (with 1 2))"} + {:suite "calls / locals named like core macros" :label "overlay repeat self-call (regression)" :expected "[0 0 0]" :actual "(take 3 (repeat 0))"} + {:suite "calls / locals named like core macros" :label "closure param called" :expected "42" :actual "((fn [f] (f 41)) inc)"} + {:suite "calls / locals named like core macros" :label "param holding a keyword (IFn leftover)" :expected "1" :actual "((fn [f] (f {:a 1})) :a)"} + {:suite "map / construct & predicate" :label "literal" :expected "{:a 1}" :actual "{:a 1}"} + {:suite "map / construct & predicate" :label "hash-map" :expected "{:b 2, :a 1}" :actual "(hash-map :a 1 :b 2)"} + {:suite "map / construct & predicate" :label "empty" :expected "{}" :actual "{}"} + {:suite "map / construct & predicate" :label "map? true" :expected "true" :actual "(map? {:a 1})"} + {:suite "map / construct & predicate" :label "map? false on vector" :expected "false" :actual "(map? [1 2])"} + {:suite "map / construct & predicate" :label "count" :expected "2" :actual "(count {:a 1 :b 2})"} + {:suite "map / construct & predicate" :label "empty? true" :expected "true" :actual "(empty? {})"} + {:suite "map / construct & predicate" :label "equality order-indep" :expected "true" :actual "(= {:a 1 :b 2} {:b 2 :a 1})"} + {:suite "map / access" :label "get" :expected "1" :actual "(get {:a 1} :a)"} + {:suite "map / access" :label "get missing nil" :expected "nil" :actual "(get {:a 1} :z)"} + {:suite "map / access" :label "get default" :expected ":x" :actual "(get {:a 1} :z :x)"} + {:suite "map / access" :label "keyword as fn" :expected "1" :actual "(:a {:a 1})"} + {:suite "map / access" :label "keyword fn default" :expected ":x" :actual "(:z {:a 1} :x)"} + {:suite "map / access" :label "map as fn" :expected "1" :actual "({:a 1} :a)"} + {:suite "map / access" :label "get-in" :expected "2" :actual "(get-in {:a {:b 2}} [:a :b])"} + {:suite "map / access" :label "get-in missing" :expected "nil" :actual "(get-in {:a {}} [:a :b])"} + {:suite "map / access" :label "contains? key" :expected "true" :actual "(contains? {:a 1} :a)"} + {:suite "map / access" :label "contains? missing" :expected "false" :actual "(contains? {:a 1} :z)"} + {:suite "map / access" :label "find returns entry" :expected "[:a 1]" :actual "(find {:a 1} :a)"} + {:suite "map / access" :label "keys" :expected "true" :actual "(= #{:a :b} (set (keys {:a 1 :b 2})))"} + {:suite "map / access" :label "vals" :expected "true" :actual "(= #{1 2} (set (vals {:a 1 :b 2})))"} + {:suite "map / update" :label "assoc adds" :expected "{:a 1, :b 2}" :actual "(assoc {:a 1} :b 2)"} + {:suite "map / update" :label "assoc overwrites" :expected "{:a 9}" :actual "(assoc {:a 1} :a 9)"} + {:suite "map / update" :label "assoc many" :expected "{:a 1, :b 2}" :actual "(assoc {} :a 1 :b 2)"} + {:suite "map / update" :label "dissoc" :expected "{:a 1}" :actual "(dissoc {:a 1 :b 2} :b)"} + {:suite "map / update" :label "dissoc many" :expected "{:a 1}" :actual "(dissoc {:a 1 :b 2 :c 3} :b :c)"} + {:suite "map / update" :label "merge" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})"} + {:suite "map / update" :label "merge overwrites" :expected "{:a 2}" :actual "(merge {:a 1} {:a 2})"} + {:suite "map / update" :label "merge lattermost wins" :expected "{:a 3}" :actual "(merge {:a 1} {:a 2} {:a 3})"} + {:suite "map / update" :label "merge no args -> nil" :expected "nil" :actual "(merge)"} + {:suite "map / update" :label "merge all nil -> nil" :expected "nil" :actual "(merge nil nil)"} + {:suite "map / update" :label "merge nil arg no-op" :expected "{:a 1}" :actual "(merge {:a 1} nil)"} + {:suite "map / update" :label "merge nil then map" :expected "{:a 1}" :actual "(merge nil {:a 1})"} + {:suite "map / update" :label "merge empty + nil" :expected "{}" :actual "(merge {} nil)"} + {:suite "map / update" :label "merge map-entry (conj)" :expected "{:a 1}" :actual "(merge {} (first {:a 1}))"} + {:suite "map / update" :label "merge [k v] vector" :expected "{:foo 1}" :actual "(merge {} [:foo 1])"} + {:suite "map / update" :label "merge collection key" :expected "true" :actual "(= {[2 3] :foo} (merge {[2 3] :foo} nil {}))"} + {:suite "map / update" :label "merge-with" :expected "{:a 3}" :actual "(merge-with + {:a 1} {:a 2})"} + {:suite "map / update" :label "update" :expected "{:a 2}" :actual "(update {:a 1} :a inc)"} + {:suite "map / update" :label "update missing w/ fnil" :expected "{:a 1}" :actual "(update {} :a (fnil inc 0))"} + {:suite "map / update" :label "update-in" :expected "{:a {:b 2}}" :actual "(update-in {:a {:b 1}} [:a :b] inc)"} + {:suite "map / update" :label "assoc-in" :expected "{:a {:b 1}}" :actual "(assoc-in {} [:a :b] 1)"} + {:suite "map / update" :label "select-keys" :expected "{:a 1}" :actual "(select-keys {:a 1 :b 2} [:a])"} + {:suite "map / update" :label "into onto map" :expected "{:a 1, :b 2}" :actual "(into {:a 1} [[:b 2]])"} + {:suite "map / update" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])"} + {:suite "map / iteration & entries" :label "map over entries" :expected "true" :actual "(= #{1 2} (set (map val {:a 1 :b 2})))"} + {:suite "map / iteration & entries" :label "map keys" :expected "true" :actual "(= #{:a :b} (set (map key {:a 1 :b 2})))"} + {:suite "map / iteration & entries" :label "reduce over entries" :expected "6" :actual "(reduce (fn [a e] (+ a (val e))) 0 {:a 1 :b 2 :c 3})"} + {:suite "map / iteration & entries" :label "reduce-kv" :expected "6" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 {:a 1 :b 2 :c 3})"} + {:suite "map / iteration & entries" :label "destructure entry" :expected "true" :actual "(= [[:a 2]] (into [] (map (fn [[k v]] [k (inc v)]) {:a 1})))"} + {:suite "map / iteration & entries" :label "first of map is entry" :expected "true" :actual "(let [e (first {:a 1})] (and (= (key e) :a) (= (val e) 1)))"} + {:suite "map / iteration & entries" :label "map-entry?" :expected "true" :actual "(map-entry? (first {:a 1}))"} + {:suite "map / iteration & entries" :label "count of nil map" :expected "0" :actual "(count nil)"} + {:suite "map / iteration & entries" :label "get from nil" :expected "nil" :actual "(get nil :a)"} + {:suite "map / iteration & entries" :label "immutability" :expected "true" :actual "(let [m {:a 1} n (assoc m :b 2)] (and (= m {:a 1}) (= n {:a 1 :b 2})))"} + {:suite "map / collection keys (by value)" :label "vector key literal" :expected ":v" :actual "(get {[1 2] :v} [1 2])"} + {:suite "map / collection keys (by value)" :label "map key literal" :expected ":v" :actual "(get {(hash-map :a 1) :v} {:a 1})"} + {:suite "map / collection keys (by value)" :label "assoc vector key" :expected ":v" :actual "(get (assoc {} [1 2] :v) [1 2])"} + {:suite "map / collection keys (by value)" :label "key across repr" :expected ":v" :actual "(get (assoc {} (vec [1 2]) :v) [1 2])"} + {:suite "map / collection keys (by value)" :label "frequencies of maps" :expected "2" :actual "(get (frequencies [{:a 1} (hash-map :a 1)]) {:a 1})"} + {:suite "map / collection keys (by value)" :label "group-by collection key" :expected "1" :actual "(count (group-by identity [{:a 1} (hash-map :a 1)]))"} + {:suite "map / nil inside a collection key" :label "set key w/ nil distinct" :expected "2" :actual "(count {#{nil 1} :a, #{1} :b})"} + {:suite "map / nil inside a collection key" :label "set key w/ nil neg lookup" :expected "nil" :actual "(get {#{nil 1} :a} #{1})"} + {:suite "map / nil inside a collection key" :label "set key w/ nil pos lookup" :expected ":a" :actual "(get {#{nil 1} :a} #{nil 1})"} + {:suite "map / nil inside a collection key" :label "set key just nil distinct" :expected "false" :actual "(= {#{nil} :x} {#{} :x})"} + {:suite "map / nil inside a collection key" :label "map nil-value key distinct" :expected "2" :actual "(count {{:a nil} 1, {} 2})"} + {:suite "map / nil inside a collection key" :label "map nil-value key neg" :expected "nil" :actual "(get {{:a nil} 1} {})"} + {:suite "map / nil inside a collection key" :label "map nil-value key pos" :expected "1" :actual "(get {{:a nil} 1} {:a nil})"} + {:suite "map / nil inside a collection key" :label "map nil-key key distinct" :expected "2" :actual "(count {{nil :a} 1, {} 2})"} + {:suite "map / nil inside a collection key" :label "map nil-key key pos" :expected "1" :actual "(get {{nil :a} 1} {nil :a})"} + {:suite "map / strictness (throws like Clojure)" :label "assoc vec out of bounds" :expected :throws :actual "(assoc [0 1 2] 4 4)"} + {:suite "map / strictness (throws like Clojure)" :label "assoc vec negative" :expected :throws :actual "(assoc [] -1 0)"} + {:suite "map / strictness (throws like Clojure)" :label "assoc vec at count ok" :expected "[1 2 3]" :actual "(assoc [1 2] 2 3)"} + {:suite "map / strictness (throws like Clojure)" :label "dissoc on number" :expected :throws :actual "(dissoc 42 :a)"} + {:suite "map / strictness (throws like Clojure)" :label "dissoc on vector" :expected :throws :actual "(dissoc [1 2] 0)"} + {:suite "map / strictness (throws like Clojure)" :label "dissoc on set" :expected :throws :actual "(dissoc #{:a} :a)"} + {:suite "map / strictness (throws like Clojure)" :label "dissoc nil ok" :expected "nil" :actual "(dissoc nil :a)"} + {:suite "map / strictness (throws like Clojure)" :label "count on number" :expected :throws :actual "(count 1)"} + {:suite "map / strictness (throws like Clojure)" :label "count on keyword" :expected :throws :actual "(count :a)"} + {:suite "map / strictness (throws like Clojure)" :label "count string ok" :expected "3" :actual "(count \"abc\")"} + {:suite "map / strictness (throws like Clojure)" :label "numerator throws" :expected :throws :actual "(numerator 1)"} + {:suite "map / strictness (throws like Clojure)" :label "denominator throws" :expected :throws :actual "(denominator 2)"} + {:suite "map / strictness (throws like Clojure)" :label "subvec out of range" :expected :throws :actual "(subvec [0 1 2 3] 1 5)"} + {:suite "map / strictness (throws like Clojure)" :label "subvec start>end" :expected :throws :actual "(subvec [0 1 2 3] 3 2)"} + {:suite "map / strictness (throws like Clojure)" :label "subvec ok" :expected "[1 2]" :actual "(subvec [0 1 2 3] 1 3)"} + {:suite "map / strictness (throws like Clojure)" :label "min-key empty" :expected :throws :actual "(apply min-key identity [])"} + {:suite "map / strictness (throws like Clojure)" :label "merge empty vector" :expected :throws :actual "(merge {} [])"} + {:suite "map / strictness (throws like Clojure)" :label "merge 1-elem vector" :expected :throws :actual "(merge {} [:foo])"} + {:suite "map / strictness (throws like Clojure)" :label "merge atomic arg" :expected :throws :actual "(merge {} :foo)"} + {:suite "map / strictness (throws like Clojure)" :label "merge [k v] ok" :expected "{:foo 1}" :actual "(merge {} [:foo 1])"} + {:suite "map / strictness (throws like Clojure)" :label "merge maps ok" :expected "{:a 1, :b 2}" :actual "(merge {:a 1} {:b 2})"} + {:suite "map / map-entry & key ordering" :label "key of entry" :expected ":a" :actual "(key (first {:a 1}))"} + {:suite "map / map-entry & key ordering" :label "val of entry" :expected "1" :actual "(val (first {:a 1}))"} + {:suite "map / map-entry & key ordering" :label "key rejects vector" :expected :throws :actual "(key [:a 1])"} + {:suite "map / map-entry & key ordering" :label "val rejects vector" :expected :throws :actual "(val [:a 1])"} + {:suite "map / map-entry & key ordering" :label "map-entry? entry" :expected "true" :actual "(map-entry? (first {:a 1}))"} + {:suite "map / map-entry & key ordering" :label "map-entry? vector" :expected "false" :actual "(map-entry? [:a 1])"} + {:suite "map / map-entry & key ordering" :label "min-key NaN first" :expected "1" :actual "(min-key identity ##NaN 1)"} + {:suite "map / map-entry & key ordering" :label "min-key NaN last" :expected "true" :actual "(NaN? (min-key identity 1 ##NaN))"} + {:suite "map / map-entry & key ordering" :label "min-key NaN three" :expected "true" :actual "(infinite? (min-key identity ##NaN ##-Inf 1))"} + {:suite "map / map-entry & key ordering" :label "min-key keys nonnum" :expected :throws :actual "(min-key identity \"x\" \"y\")"} + {:suite "map / map-entry & key ordering" :label "max-key picks max" :expected "[1 2 3]" :actual "(max-key count [1] [1 2 3] [1 2])"} + {:suite "map / map-entry & key ordering" :label "subvec float trunc" :expected "[0]" :actual "(subvec [0 1 2] 0.5 1.33)"} + {:suite "map / map-entry & key ordering" :label "subvec NaN start" :expected "[0 1 2]" :actual "(subvec [0 1 2] ##NaN 3)"} + {:suite "map / map-entry & key ordering" :label "subvec NaN end" :expected "[]" :actual "(subvec [0 1 2] 0 ##NaN)"} + {:suite "map / nil values preserved" :label "literal contains" :expected "true" :actual "(contains? {:b nil} :b)"} + {:suite "map / nil values preserved" :label "literal not= empty" :expected "false" :actual "(= {:b nil} {})"} + {:suite "map / nil values preserved" :label "literal get nil" :expected "nil" :actual "(get {:b nil} :b :x)"} + {:suite "map / nil values preserved" :label "literal keys incl nil" :expected "true" :actual "(= #{:a :b} (set (keys {:a nil :b 1})))"} + {:suite "map / nil values preserved" :label "literal count" :expected "2" :actual "(count {:a nil :b 1})"} + {:suite "map / nil values preserved" :label "literal vals incl nil" :expected "2" :actual "(count (vals {:a nil :b 1}))"} + {:suite "map / nil values preserved" :label "eval values w/ nil" :expected "3" :actual "(:a {:a (+ 1 2) :b nil})"} + {:suite "map / nil values preserved" :label "nil key present" :expected "true" :actual "(contains? {nil :v} nil)"} + {:suite "map / nil values preserved" :label "assoc nil present" :expected "true" :actual "(contains? (assoc {:a 1} :b nil) :b)"} + {:suite "map / nil values preserved" :label "assoc nil get" :expected "nil" :actual "(get (assoc {:a 1} :b nil) :b :x)"} + {:suite "map / nil values preserved" :label "assoc overwrite nil" :expected "nil" :actual "(get (assoc {:a 1} :a nil) :a :x)"} + {:suite "map / nil values preserved" :label "hash-map nil" :expected "true" :actual "(contains? (hash-map :b nil) :b)"} + {:suite "map / nil values preserved" :label "merge new nil" :expected "true" :actual "(contains? (merge {:a 1} {:b nil}) :b)"} + {:suite "map / nil values preserved" :label "merge overwrite nil" :expected "nil" :actual "(get (merge {:a 1} {:a nil}) :a :x)"} + {:suite "map / nil values preserved" :label "merge-with present nil" :expected "true" :actual "(= [nil 1] (get (merge-with (fn [a b] [a b]) {:a nil} {:a 1}) :a))"} + {:suite "map / nil values preserved" :label "into nil val" :expected "true" :actual "(contains? (into {} [[:a nil]]) :a)"} + {:suite "map / nil values preserved" :label "conj map nil" :expected "true" :actual "(contains? (conj {:x 1} {:a nil}) :a)"} + {:suite "map / nil values preserved" :label "zipmap nil" :expected "true" :actual "(contains? (zipmap [:a] [nil]) :a)"} + {:suite "map / nil values preserved" :label "select-keys nil" :expected "true" :actual "(contains? (select-keys {:a nil} [:a]) :a)"} + {:suite "map / nil values preserved" :label "get-in present nil" :expected "nil" :actual "(get-in {:a nil} [:a] :x)"} + {:suite "map / nil values preserved" :label "get-in through nil" :expected ":x" :actual "(get-in {:a nil} [:a :b] :x)"} + {:suite "map / nil values preserved" :label "dissoc keeps nil" :expected "true" :actual "(contains? (dissoc {:a nil :b 1} :b) :a)"} + {:suite "map / nil values preserved" :label "reduce-kv sees nil" :expected "true" :actual "(= #{:a :b} (reduce-kv (fn [acc k v] (conj acc k)) #{} {:a nil :b 2}))"} + {:suite "map / nil values preserved" :label "nil-free stays fast" :expected "true" :actual "(= {:a 1 :b 2} {:b 2 :a 1})"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-keys" :expected "{\"a\" 1, \"b\" 2}" :actual "(update-keys {:a 1 :b 2} name)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-keys empty" :expected "{}" :actual "(update-keys {} inc)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-keys nil" :expected "{}" :actual "(update-keys nil str)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-keys collide last wins" :expected "1" :actual "(count (update-keys {:a 1 :b 2} (fn [_] :k)))"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-vals" :expected "{:a 2, :b 3}" :actual "(update-vals {:a 1 :b 2} inc)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-vals empty" :expected "{}" :actual "(update-vals {} inc)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-vals nil" :expected "{}" :actual "(update-vals nil inc)"} + {:suite "map / update-keys & update-vals (1.11)" :label "update-vals keeps keys" :expected "[:a :b]" :actual "(sort (keys (update-vals {:a 1 :b 2} inc)))"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "keys" :expected "[:a]" :actual "(keys {:a 1})"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "keys empty map" :expected "nil" :actual "(keys {})"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "keys nil" :expected "nil" :actual "(keys nil)"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "vals" :expected "[1]" :actual "(vals {:a 1})"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "vals empty" :expected "nil" :actual "(vals {})"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "keys sorted order" :expected "[1 2 3]" :actual "(vec (keys (sorted-map 2 :b 1 :a 3 :c)))"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "vals sorted order" :expected "[:a :b :c]" :actual "(vec (vals (sorted-map 2 :b 1 :a 3 :c)))"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "keys/vals zip" :expected "{:a 1, :b 2}" :actual "(zipmap (keys {:a 1 :b 2}) (vals {:a 1 :b 2}))"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? map" :expected "true" :actual "(empty? {})"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? vec" :expected "[true false]" :actual "[(empty? []) (empty? [1])]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? list" :expected "[true false]" :actual "[(empty? ()) (empty? (list 1))]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? string" :expected "[true false]" :actual "[(empty? \"\") (empty? \"a\")]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? nil" :expected "true" :actual "(empty? nil)"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? set" :expected "[true false]" :actual "[(empty? #{}) (empty? #{1})]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? lazy" :expected "[true false]" :actual "[(empty? (filter pos? [-1])) (empty? (map inc [1]))]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? lazy nil elem" :expected "false" :actual "(empty? (cons nil nil))"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? sorted" :expected "[true false]" :actual "[(empty? (sorted-map)) (empty? (sorted-set 1))]"} + {:suite "maps / keys-vals-empty? as overlay fns" :label "empty? number throws" :expected :throws :actual "(empty? 5)"} + {:suite "map / assoc on nil" :label "assoc nil is a map" :expected "{:a 1}" :actual "(assoc nil :a 1)"} + {:suite "map / assoc on nil" :label "count of assoc nil" :expected "1" :actual "(count (assoc nil :a 1))"} + {:suite "map / assoc on nil" :label "assoc-in nested countable" :expected "1" :actual "(count (:a (assoc-in {} [:a :b] 1)))"} + {:suite "map / assoc on nil" :label "assoc-in deep get" :expected "9" :actual "(get-in (assoc-in {} [:a :b :c] 9) [:a :b :c])"} + {:suite "map / assoc on nil" :label "seq over assoc-nil map" :expected ":a" :actual "(ffirst (seq (assoc nil :a 1)))"} + {:suite "map / assoc on nil" :label "keys of assoc-nil map" :expected "[:a]" :actual "(vec (keys (assoc nil :a 1)))"} + {:suite "map / bulk build boundaries" :label "into = incr at 17" :expected "true" :actual "(= (into {} (map (fn [i] [i (* i 2)]) (range 17))) (reduce (fn [m p] (assoc m (first p) (second p))) {} (map (fn [i] [i (* i 2)]) (range 17))))"} + {:suite "map / bulk build boundaries" :label "into = incr at 1000" :expected "true" :actual "(= (into {} (map (fn [i] [i (* i 2)]) (range 1000))) (reduce (fn [m p] (assoc m (first p) (second p))) {} (map (fn [i] [i (* i 2)]) (range 1000))))"} + {:suite "map / bulk build boundaries" :label "into count 1000" :expected "1000" :actual "(count (into {} (map (fn [i] [i i]) (range 1000))))"} + {:suite "map / bulk build boundaries" :label "into reads back" :expected "999" :actual "(get (into {} (map (fn [i] [i (* i 3)]) (range 1000))) 333)"} + {:suite "map / bulk build boundaries" :label "into onto non-empty" :expected "9" :actual "(get (into {:a 1} [[:a 9] [:b 2]]) :a)"} + {:suite "map / bulk build boundaries" :label "into dup last wins" :expected "9" :actual "(get (into {} [[:k 1] [:k 9]]) :k)"} + {:suite "map / bulk build boundaries" :label "into nil key" :expected ":x" :actual "(get (into {} [[nil :x] [:a 1]]) nil)"} + {:suite "map / bulk build boundaries" :label "assoc after bulk" :expected "7" :actual "(get (assoc (into {} (map (fn [i] [i i]) (range 100))) :new 7) :new)"} + {:suite "map / bulk build boundaries" :label "dissoc after bulk" :expected "nil" :actual "(get (dissoc (into {} (map (fn [i] [i i]) (range 100))) 50) 50)"} + {:suite "map / bulk build boundaries" :label "frequencies count" :expected "3" :actual "(get (frequencies [1 2 2 1 2 1]) 1)"} + {:suite "map / bulk build boundaries" :label "frequencies coll-key" :expected "2" :actual "(get (frequencies [[1 2] [1 2] [3 4]]) [1 2])"} + {:suite "map / bulk build boundaries" :label "frequencies nil key" :expected "2" :actual "(get (frequencies [nil nil 1]) nil)"} + {:suite "map / bulk build boundaries" :label "group-by nil key" :expected "[nil nil]" :actual "(get (group-by identity [nil nil 1]) nil)"} + {:suite "map / bulk build boundaries" :label "group-by nil count" :expected "2" :actual "(count (group-by identity [nil nil 1]))"} + {:suite "map / bulk build boundaries" :label "transient nil key" :expected ":x" :actual "(let [t (transient {})] (assoc! t nil :x) (get (persistent! t) nil))"} + {:suite "map / bulk build boundaries" :label "transient nil get" :expected "true" :actual "(let [t (transient {})] (assoc! t nil :x) (contains? t nil))"} + {:suite "map / bulk build boundaries" :label "transient nil dissoc" :expected ":gone" :actual "(let [t (transient {})] (assoc! t nil :x) (dissoc! t nil) (get (persistent! t) nil :gone))"} + {:suite "map / bulk build boundaries" :label "group-by bucket" :expected "[1 3 5]" :actual "(get (group-by odd? (range 1 6)) true)"} + {:suite "map / bulk build boundaries" :label "group-by big bucket" :expected "true" :actual "(= (group-by even? (range 200)) {true (vec (filter even? (range 200))) false (vec (filter odd? (range 200)))})"} + {:suite "map / bulk build boundaries" :label "group-by order" :expected "[0 3 6 9]" :actual "(get (group-by (fn [x] (mod x 3)) (range 10)) 0)"} + {:suite "map / bulk build boundaries" :label "hash-map bulk = incr" :expected "true" :actual "(= (apply hash-map (mapcat (fn [i] [i i]) (range 50))) (reduce (fn [m i] (assoc m i i)) {} (range 50)))"} + {:suite "metadata / with-meta & meta" :label "meta of bare value" :expected "nil" :actual "(meta [1 2 3])"} + {:suite "metadata / with-meta & meta" :label "with-meta then meta" :expected "{:a 1}" :actual "(meta (with-meta [1 2 3] {:a 1}))"} + {:suite "metadata / with-meta & meta" :label "with-meta preserves value" :expected "true" :actual "(= [1 2 3] (with-meta [1 2 3] {:a 1}))"} + {:suite "metadata / with-meta & meta" :label "with-meta on map" :expected "{:doc \"x\"}" :actual "(meta (with-meta {:k 1} {:doc \"x\"}))"} + {:suite "metadata / with-meta & meta" :label "vary-meta" :expected "{:a 2}" :actual "(meta (vary-meta (with-meta [1] {:a 1}) update :a inc))"} + {:suite "metadata / with-meta & meta" :label "vary-meta extra args" :expected "{:a 1, :b 2}" :actual "(meta (vary-meta (with-meta [1] {:a 1}) assoc :b 2))"} + {:suite "metadata / with-meta & meta" :label "meta reader ^" :expected "{:tag :int}" :actual "(meta ^{:tag :int} [1 2])"} + {:suite "metadata / with-meta & meta" :label "with-meta on fn ok" :expected "true" :actual "(fn? (with-meta inc {:a 1}))"} + {:suite "metadata / with-meta & meta" :label "with-meta nil clears" :expected "nil" :actual "(meta (with-meta [1 2 3] nil))"} + {:suite "metadata / type hints" :label "type hint on param" :expected "\"hi\"" :actual "(do (defn f [^String s] s) (f \"hi\"))"} + {:suite "metadata / type hints" :label "type hint, extra params" :expected "[1 2]" :actual "(do (defn g [^String x y] [x y]) (g 1 2))"} + {:suite "metadata / type hints" :label "type hint in let" :expected "6" :actual "(let [^long x 5] (inc x))"} + {:suite "metadata / type hints" :label "type hint in body" :expected "2" :actual "(let [s \"ab\"] (count ^String s))"} + {:suite "metadata / type hints" :label "type hint in destructure" :expected "3" :actual "(let [{:keys [^long a]} {:a 3}] a)"} + {:suite "metadata / type hints" :label "symbol hint -> :tag is a symbol" :expected "true" :actual "(symbol? (:tag (meta (read-string \"^String x\"))))"} + {:suite "metadata / type hints" :label "symbol hint -> :tag name" :expected "\"String\"" :actual "(name (:tag (meta (read-string \"^String x\"))))"} + {:suite "metadata / type hints" :label "keyword hint -> true" :expected "true" :actual "(:foo (meta (read-string \"^:foo x\")))"} + {:suite "metadata / read data metadata" :label "vector data meta" :expected "{:ref true}" :actual "(meta (read-string \"^:ref [:greeting]\"))"} + {:suite "metadata / read data metadata" :label "map data meta" :expected "{:k 1}" :actual "(meta (read-string \"^{:k 1} {:a 2}\"))"} + {:suite "metadata / read data metadata" :label "set data meta" :expected "{:s true}" :actual "(meta (read-string \"^:s #{1 2}\"))"} + {:suite "metadata / read data metadata" :label "nested vector data meta" :expected "{:x true}" :actual "(meta (second (read-string \"[1 ^:x {:a 2}]\")))"} + {:suite "metadata / read data metadata" :label "collection value unchanged" :expected "[:greeting]" :actual "(read-string \"^:ref [:greeting]\")"} + {:suite "metadata / coll literal in code keeps meta" :label "vector literal meta" :expected "{:foo true}" :actual "(meta ^:foo [1 2])"} + {:suite "metadata / coll literal in code keeps meta" :label "map literal meta with expr" :expected "{:a 3}" :actual "(meta ^{:a (+ 1 2)} [1])"} + {:suite "metadata / coll literal in code keeps meta" :label "map literal value-eval order" :expected "[1 2]" :actual "(let [a (atom [])] ^:t {(do (swap! a conj 1) :a) 1 (do (swap! a conj 2) :b) 2} @a)"} + {:suite "metadata / *print-meta*" :label "pr-str prefixes ^meta" :expected "\"^{:ref true} [:g]\"" :actual "(binding [*print-meta* true] (pr-str (with-meta [:g] {:ref true})))"} + {:suite "metadata / *print-meta*" :label "off by default" :expected "\"[:g]\"" :actual "(pr-str (with-meta [:g] {:ref true}))"} + {:suite "metadata / *print-meta*" :label "symbol meta prefixed" :expected "\"^{:k 1} x\"" :actual "(binding [*print-meta* true] (pr-str (with-meta (quote x) {:k 1})))"} + {:suite "metadata / *print-meta*" :label "print then read round-trips" :expected "{:ref true}" :actual "(meta (read-string (binding [*print-meta* true] (pr-str (with-meta [:g] {:ref true})))))"} + {:suite "metadata / clojure.walk preserves meta" :label "postwalk keeps vector meta" :expected "{:ref true}" :actual "(do (require (quote [clojure.walk :as w])) (meta (w/postwalk identity (with-meta [:b] {:ref true}))))"} + {:suite "metadata / clojure.walk preserves meta" :label "postwalk keeps map meta" :expected "{:m 1}" :actual "(do (require (quote [clojure.walk :as w])) (meta (w/postwalk identity (with-meta {:a 2} {:m 1}))))"} + {:suite "metadata / clojure.edn preserves meta" :label "edn vector meta" :expected "{:ref true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:ref [:greeting]\")))"} + {:suite "metadata / clojure.edn preserves meta" :label "edn map meta" :expected "{:m true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:m {:a 1}\")))"} + {:suite "metadata / clojure.edn preserves meta" :label "edn set meta" :expected "{:s true}" :actual "(do (require (quote [clojure.edn :as e1])) (meta (e1/read-string \"^:s #{1}\")))"} + {:suite "metadata / collection ops preserve meta" :label "empty keeps vector meta" :expected "{:k 9}" :actual "(meta (empty (with-meta [1] {:k 9})))"} + {:suite "metadata / collection ops preserve meta" :label "empty keeps map meta" :expected "{:k 9}" :actual "(meta (empty (with-meta {:a 1} {:k 9})))"} + {:suite "metadata / collection ops preserve meta" :label "empty keeps set meta" :expected "{:k 9}" :actual "(meta (empty (with-meta #{1} {:k 9})))"} + {:suite "metadata / collection ops preserve meta" :label "empty keeps list meta" :expected "{:k 9}" :actual "(meta (empty (with-meta (list 1) {:k 9})))"} + {:suite "metadata / collection ops preserve meta" :label "into empty keeps meta" :expected "{:k 9}" :actual "(meta (into (empty (with-meta {:a 1} {:k 9})) {:b 2}))"} + {:suite "metadata / collection ops preserve meta" :label "into target meta" :expected "{:k 9}" :actual "(meta (into (with-meta [] {:k 9}) [1 2]))"} + {:suite "metadata / collection ops preserve meta" :label "conj on vector" :expected "{:k 9}" :actual "(meta (conj (with-meta [1] {:k 9}) 2))"} + {:suite "metadata / collection ops preserve meta" :label "conj on list" :expected "{:k 9}" :actual "(meta (conj (with-meta (list 1) {:k 9}) 2))"} + {:suite "metadata / collection ops preserve meta" :label "assoc on map" :expected "{:k 9}" :actual "(meta (assoc (with-meta {:a 1} {:k 9}) :b 2))"} + {:suite "metadata / collection ops preserve meta" :label "dissoc on map" :expected "{:k 9}" :actual "(meta (dissoc (with-meta {:a 1 :c 3} {:k 9}) :c))"} + {:suite "metadata / collection ops preserve meta" :label "disj on set" :expected "{:k 9}" :actual "(meta (disj (with-meta #{1 2} {:k 9}) 2))"} + {:suite "metadata / collection ops preserve meta" :label "pop on vector" :expected "{:k 9}" :actual "(meta (pop (with-meta [1 2] {:k 9})))"} + {:suite "metadata / collection ops preserve meta" :label "op without meta is nil" :expected "nil" :actual "(meta (conj [1] 2))"} + {:suite "metadata / collection ops preserve meta" :label "value preserved through conj" :expected "[1 2]" :actual "(conj (with-meta [1] {:k 9}) 2)"} + {:suite "metadata / collection ops preserve meta" :label "empty list singleton unaffected" :expected "nil" :actual "(do (with-meta () {:leak 1}) (meta ()))"} + {:suite "metadata / collection ops preserve meta" :label "empty vector literal unaffected" :expected "nil" :actual "(do (with-meta [] {:leak 1}) (meta []))"} + {:suite "metadata / def metadata" :label "^:dynamic var binds" :expected "9" :actual "(do (def ^:dynamic *d* 1) (binding [*d* 9] *d*))"} + {:suite "metadata / def metadata" :label "^:private on var" :expected "true" :actual "(do (def ^:private pv 1) (:private (meta (var pv))))"} + {:suite "metadata / def metadata" :label "^Type tag on var" :expected "java.lang.String" :actual "(do (def ^String tv \"a\") (:tag (meta (var tv))))"} + {:suite "metadata / def metadata" :label "^{:doc} on var" :expected "\"hi\"" :actual "(do (def ^{:doc \"hi\"} dv 1) (:doc (meta (var dv))))"} + {:suite "metadata / def metadata" :label "(def name doc val) doc" :expected "\"d\"" :actual "(do (def dd \"d\" 5) (:doc (meta (var dd))))"} + {:suite "core / find-keyword + inst-ms*" :label "find-keyword" :expected ":a" :actual "(find-keyword \"a\")"} + {:suite "core / find-keyword + inst-ms*" :label "find-keyword 2-arity" :expected ":n/a" :actual "(find-keyword \"n\" \"a\")"} + {:suite "core / find-keyword + inst-ms*" :label "find-keyword = keyword" :expected "true" :actual "(= (find-keyword \"x\") :x)"} + {:suite "core / find-keyword + inst-ms*" :label "inst-ms*" :expected "true" :actual "(= (inst-ms* #inst \"2020-01-01T00:00:00Z\") (inst-ms #inst \"2020-01-01T00:00:00Z\"))"} + {:suite "core / find-keyword + inst-ms*" :label "inst-ms* value" :expected "0" :actual "(inst-ms* #inst \"1970-01-01T00:00:00Z\")"} + {:suite "core / with-local-vars" :label "var-get initial" :expected "1" :actual "(with-local-vars [x 1] (var-get x))"} + {:suite "core / with-local-vars" :label "var-set" :expected "2" :actual "(with-local-vars [x 1] (var-set x 2) (var-get x))"} + {:suite "core / with-local-vars" :label "two vars" :expected "[1 2]" :actual "(with-local-vars [a 1 b 2] [(var-get a) (var-get b)])"} + {:suite "core / with-local-vars" :label "vars are values" :expected "5" :actual "(with-local-vars [x 0] (let [bump (fn [v] (var-set v (+ 5 (var-get v))))] (bump x) (var-get x)))"} + {:suite "core / with-local-vars" :label "init sees outer" :expected "3" :actual "(let [y 3] (with-local-vars [x y] (var-get x)))"} + {:suite "core / with-local-vars" :label "body result" :expected ":done" :actual "(with-local-vars [x 1] :done)"} + {:suite "core / with-open" :label "body result" :expected ":r" :actual "(let [log (atom [])] (with-open [c {:close (fn [] (swap! log conj :closed))}] :r))"} + {:suite "core / with-open" :label "close runs" :expected "[:closed]" :actual "(let [log (atom [])] (with-open [c {:close (fn [] (swap! log conj :closed))}] :r) (deref log))"} + {:suite "core / with-open" :label "close on throw" :expected "[]" :actual "(let [log (atom [])] (try (with-open [c {:close (fn [] (swap! log conj :closed))}] (throw (ex-info \"boom\" {}))) (catch Exception e nil)) (deref log))"} + {:suite "core / with-open" :label "nested close order" :expected "[:inner :outer]" :actual "(let [log (atom [])] (with-open [a {:close (fn [] (swap! log conj :outer))} b {:close (fn [] (swap! log conj :inner))}] :r) (deref log))"} + {:suite "core / with-open" :label "zero bindings" :expected ":r" :actual "(with-open [] :r)"} + {:suite "core / with-open" :label "binding visible" :expected "5" :actual "(with-open [c {:close (fn [] nil) :v 5}] (:v c))"} + {:suite "core / with-precision" :label "body evaluates" :expected "3.14" :actual "(with-precision 3 3.14)"} + {:suite "core / with-precision" :label "multiple body forms" :expected "2" :actual "(with-precision 10 1 2)"} + {:suite "core / with-precision" :label "rounding arg accepted" :expected "1.5" :actual "(with-precision 4 :rounding :half-up 1.5)"} + {:suite "core / with-precision" :label "arithmetic" :expected "2" :actual "(with-precision 5 (+ 1 1))"} + {:suite "core / read+string" :label "form and text" :expected "true" :actual "(let [[v s] (with-in-str \"42 rest\" (read+string))] (and (= v 42) (string? s)))"} + {:suite "core / read+string" :label "form value" :expected "(quote (+ 1 2))" :actual "(first (with-in-str \"(+ 1 2)\" (read+string)))"} + {:suite "core / read+string" :label "text covers the form" :expected "true" :actual "(let [[v s] (with-in-str \" [1 2] tail\" (read+string))] (and (= v [1 2]) (> (count s) 3)))"} + {:suite "core / read+string" :label "advances the stream" :expected "[1 2]" :actual "(with-in-str \"1 2\" [(first (read+string)) (first (read+string))])"} + {:suite "core / read+string" :label "EOF throws" :expected :throws :actual "(with-in-str \"\" (read+string))"} + {:suite "core / read+string" :label "eof-value arity" :expected ":done" :actual "(first (with-in-str \"\" (read+string *in* false :done)))"} + {:suite "core / extenders" :label "lists extended type" :expected "[]" :actual "(do (defprotocol Px (pm [x])) (defrecord Rx [] Px (pm [x] 1)) (mapv str (extenders Px)))"} + {:suite "core / extenders" :label "nil when none" :expected "nil" :actual "(do (defprotocol Py (pn [x])) (extenders Py))"} + {:suite "core / extenders" :label "seq of tags" :expected "nil" :actual "(do (defprotocol Pz (pz [x])) (defrecord Rz [] Pz (pz [x] 1)) (and (seq (extenders Pz)) (= 1 (count (extenders Pz)))))"} + {:suite "multimethods / dispatch" :label "dispatch on value" :expected "\"two\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (f 2))"} + {:suite "multimethods / dispatch" :label "dispatch on keyword fn" :expected "\"circle\"" :actual "(do (defmulti area :shape) (defmethod area :circle [_] \"circle\") (area {:shape :circle}))"} + {:suite "multimethods / dispatch" :label ":default method" :expected "\"other\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f :default [_] \"other\") (f 99))"} + {:suite "multimethods / dispatch" :label "no match throws" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (f 99))"} + {:suite "multimethods / dispatch" :label "multiple args" :expected "5" :actual "(do (defmulti g (fn [a b] a)) (defmethod g :add [_ b] b) (g :add 5))"} + {:suite "multimethods / dispatch" :label "get-method" :expected "\"one\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") ((get-method f 1) 1))"} + {:suite "multimethods / dispatch" :label "remove-method" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (remove-method f 1) (f 1))"} + {:suite "multimethods / dispatch" :label "methods" :expected "\"one\"" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") ((get (methods f) 1) 1))"} + {:suite "multimethods / dispatch" :label "methods count" :expected "2" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (count (methods f)))"} + {:suite "multimethods / dispatch" :label "remove-all-methods" :expected :throws :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (defmethod f 2 [_] \"two\") (remove-all-methods f) (f 1))"} + {:suite "multimethods / dispatch" :label "remove-all-methods empties the table" :expected "0" :actual "(do (defmulti f identity) (defmethod f 1 [_] \"one\") (remove-all-methods f) (count (methods f)))"} + {:suite "multimethods / hierarchies" :label "derive + isa?" :expected "true" :actual "(do (derive ::child ::parent) (isa? ::child ::parent))"} + {:suite "multimethods / hierarchies" :label "isa? reflexive" :expected "true" :actual "(isa? ::x ::x)"} + {:suite "multimethods / hierarchies" :label "isa? unrelated" :expected "false" :actual "(do (derive ::a ::b) (isa? ::a ::c))"} + {:suite "multimethods / hierarchies" :label "parents" :expected "true" :actual "(do (derive ::c ::p) (contains? (parents ::c) ::p))"} + {:suite "multimethods / hierarchies" :label "ancestors" :expected "true" :actual "(do (derive ::c ::p) (derive ::p ::g) (contains? (ancestors ::c) ::g))"} + {:suite "multimethods / hierarchies" :label "descendants" :expected "true" :actual "(do (derive ::c ::p) (contains? (descendants ::p) ::c))"} + {:suite "multimethods / hierarchies" :label "dispatch via hierarchy" :expected "\"animal\"" :actual "(do (derive ::dog ::animal) (defmulti speak identity) (defmethod speak ::animal [_] \"animal\") (speak ::dog))"} + {:suite "multimethods / hierarchies" :label "custom :default key" :expected ":unknown" :actual "(do (defmulti classify :type :default :other) (defmethod classify :a [_] :alpha) (defmethod classify :other [_] :unknown) (classify {:type :zzz}))"} + {:suite "multimethods / hierarchies" :label "explicit :hierarchy" :expected "\"a\"" :actual "(do (def h (derive (make-hierarchy) ::dog ::animal)) (defmulti snd identity :hierarchy h) (defmethod snd ::animal [_] \"a\") (snd ::dog))"} + {:suite "multimethods / prefer-method" :label "preference picks the winner" :expected ":rect" :actual "(do (derive :p/sq :p/rect) (derive :p/sq :p/shape) (defmulti pm1 identity) (defmethod pm1 :p/rect [x] :rect) (defmethod pm1 :p/shape [x] :shape) (prefer-method pm1 :p/rect :p/shape) (pm1 :p/sq))"} + {:suite "multimethods / prefer-method" :label "reverse preference" :expected ":shape" :actual "(do (derive :q/sq :q/rect) (derive :q/sq :q/shape) (defmulti pm2 identity) (defmethod pm2 :q/rect [x] :rect) (defmethod pm2 :q/shape [x] :shape) (prefer-method pm2 :q/shape :q/rect) (pm2 :q/sq))"} + {:suite "multimethods / prefer-method" :label "ambiguity throws" :expected :throws :actual "(do (derive :r/sq :r/rect) (derive :r/sq :r/shape) (defmulti pm3 identity) (defmethod pm3 :r/rect [x] :rect) (defmethod pm3 :r/shape [x] :shape) (pm3 :r/sq))"} + {:suite "multimethods / prefer-method" :label "isa dominance needs no preference" :expected ":child" :actual "(do (derive :s/c :s/p) (defmulti pm4 identity) (defmethod pm4 :s/c [x] :child) (defmethod pm4 :s/p [x] :parent) (pm4 :s/c))"} + {:suite "multimethods / prefer-method" :label "prefers map shape" :expected "true" :actual "(do (defmulti pm5 identity) (defmethod pm5 :a [x] 1) (defmethod pm5 :b [x] 2) (prefer-method pm5 :a :b) (contains? (get (prefers pm5) :a) :b))"} + {:suite "multimethods / prefer-method" :label "exact match needs no preference" :expected ":exact" :actual "(do (derive :t/sq :t/rect) (defmulti pm6 identity) (defmethod pm6 :t/sq [x] :exact) (defmethod pm6 :t/rect [x] :parent) (pm6 :t/sq))"} + {:suite "multimethods / docstring & value-based table ops" :label "defmulti docstring" :expected "\"A\"" :actual "(do (defmulti gd \"the dispatcher\" identity) (defmethod gd :a [_] \"A\") (gd :a))"} + {:suite "multimethods / docstring & value-based table ops" :label "defmulti doc+default" :expected "\"d\"" :actual "(do (defmulti gx \"doc\" identity) (defmethod gx :default [_] \"d\") (gx :anything))"} + {:suite "multimethods / docstring & value-based table ops" :label "methods on value" :expected "2" :actual "(do (defmulti gm identity) (defmethod gm 1 [_] :one) (defmethod gm 2 [_] :two) (count (methods gm)))"} + {:suite "multimethods / docstring & value-based table ops" :label "get-method on value" :expected "true" :actual "(do (defmulti gg identity) (defmethod gg :a [_] :x) (fn? (get-method gg :a)))"} + {:suite "namespaces / def & vars" :label "def + deref" :expected "5" :actual "(do (def x 5) x)"} + {:suite "namespaces / def & vars" :label "def returns var" :expected "true" :actual "(var? (def y 1))"} + {:suite "namespaces / def & vars" :label "declare then def" :expected "2" :actual "(do (declare z) (def z 2) z)"} + {:suite "namespaces / def & vars" :label "var special form" :expected "true" :actual "(var? (var +))"} + {:suite "namespaces / def & vars" :label "var sugar #'" :expected "true" :actual "(var? #'+)"} + {:suite "namespaces / def & vars" :label "var-get" :expected "5" :actual "(do (def w 5) (var-get #'w))"} + {:suite "namespaces / def & vars" :label "defn defines fn" :expected "3" :actual "(do (defn f [x] (inc x)) (f 2))"} + {:suite "namespaces / def & vars" :label "def with docstring" :expected "7" :actual "(do (def d \"a doc\" 7) d)"} + {:suite "namespaces / def & vars" :label "dynamic var binding" :expected "2" :actual "(do (def ^:dynamic *x* 1) (binding [*x* 2] *x*))"} + {:suite "namespaces / def & vars" :label "binding restores" :expected "1" :actual "(do (def ^:dynamic *y* 1) (binding [*y* 9] nil) *y*)"} + {:suite "namespaces / def & vars" :label "var-set in binding" :expected "5" :actual "(do (def ^:dynamic *z* 1) (binding [*z* 0] (var-set (var *z*) 5) *z*))"} + {:suite "namespaces / ns operations" :label "in-ns switches" :expected "true" :actual "(do (in-ns 'my.ns) (symbol? 'x))"} + {:suite "namespaces / ns operations" :label "ns form + alias" :expected "\"HI\"" :actual "(do (ns my.app (:require [clojure.string :as s])) (s/upper-case \"hi\"))"} + {:suite "namespaces / ns operations" :label "ns :use refers all" :expected "9" :actual "(do (ns src.lib) (def helper 9) (ns dst.app (:use [src.lib])) helper)"} + {:suite "namespaces / ns operations" :label "standalone use" :expected "7" :actual "(do (ns src.l2) (def k 7) (in-ns 'dst.a2) (use '[src.l2]) k)"} + {:suite "namespaces / ns operations" :label "ns-name" :expected "true" :actual "(do (require (quote [clojure.string])) (= 'clojure.string (ns-name (find-ns 'clojure.string))))"} + {:suite "namespaces / ns operations" :label "find-ns existing" :expected "true" :actual "(some? (find-ns 'clojure.core))"} + {:suite "namespaces / ns operations" :label "find-ns missing" :expected "nil" :actual "(find-ns 'does.not.exist)"} + {:suite "namespaces / ns operations" :label "resolve var" :expected "true" :actual "(var? (resolve '+))"} + {:suite "namespaces / ns operations" :label "resolve missing" :expected "nil" :actual "(resolve 'totally-undefined-xyz)"} + {:suite "namespaces / require & refer" :label "require :as" :expected "\"AB\"" :actual "(do (require '[clojure.string :as s]) (s/upper-case \"ab\"))"} + {:suite "namespaces / require & refer" :label "require :refer" :expected "true" :actual "(do (require '[clojure.string :refer [blank?]]) (blank? \"\"))"} + {:suite "namespaces / require & refer" :label "require :as + :refer" :expected "true" :actual "(do (require '[clojure.string :as s :refer [blank?]]) (and (blank? \"\") (= \"X\" (s/upper-case \"x\"))))"} + {:suite "namespaces / require & refer" :label "require clojure.set" :expected "#{1 3 2}" :actual "(do (require '[clojure.set :as set]) (set/union #{1 2} #{3}))"} + {:suite "namespaces / require & refer" :label "require clojure.walk" :expected "{:a 2}" :actual "(do (require '[clojure.walk :as w]) (w/postwalk (fn [x] (if (number? x) (inc x) x)) {:a 1}))"} + {:suite "namespaces / require & refer" :label "walk keywordize-keys" :expected "{:a 1}" :actual "(do (require '[clojure.walk :as w]) (w/keywordize-keys {\"a\" 1}))"} + {:suite "namespaces / require & refer" :label "walk stringify-keys" :expected "true" :actual "(do (require '[clojure.walk :as w]) (= {\"a\" 1} (w/stringify-keys {:a 1})))"} + {:suite "namespaces / require & refer" :label "require missing lib throws" :expected :throws :actual "(require '[no.such.lib])"} + {:suite "namespaces / require & refer" :label "use missing lib throws" :expected :throws :actual "(use 'no.such.lib)"} + {:suite "namespaces / require & refer" :label "require of in-session ns ok" :expected "1" :actual "(do (ns made.here) (def x 1) (require '[made.here]) made.here/x)"} + {:suite "namespaces / alias, ns-unalias, ns-publics" :label "alias + use" :expected "\"1,2\"" :actual "(do (require (quote clojure.string)) (alias (quote st) (quote clojure.string)) (st/join \",\" [1 2]))"} + {:suite "namespaces / alias, ns-unalias, ns-publics" :label "ns-unalias removes" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote st2) (quote clojure.string)) (ns-unalias (quote user) (quote st2)) (nil? (get (ns-aliases (quote user)) (quote st2))))"} + {:suite "namespaces / alias, ns-unalias, ns-publics" :label "ns-publics has var" :expected "true" :actual "(do (def npv 1) (some? (get (ns-publics (quote user)) (quote npv))))"} + {:suite "namespaces / alias, ns-unalias, ns-publics" :label "newline returns nil" :expected "nil" :actual "(newline)"} + {:suite "namespaces / error inside a fn must not leak its defining ns" :label "alias survives a throwing stdlib call" :expected "\"A\"" :actual "(do (require (quote [clojure.string :as s9])) (try (s9/join nil nil nil) (catch Exception e nil)) (s9/upper-case \"a\"))"} + {:suite "namespaces / error inside a fn must not leak its defining ns" :label "*ns* restored after throw" :expected "\"user\"" :actual "(do (require (quote [clojure.walk :as w9])) (try (w9/postwalk nil nil nil) (catch Exception e nil)) (str *ns*))"} + {:suite "namespaces / unified alias store" :label "require :as registers the alias" :expected "1" :actual "(do (require (quote [clojure.string :as st1])) (count (filter (fn [[a n]] (= (str a) \"st1\")) (ns-aliases))))"} + {:suite "namespaces / unified alias store" :label "aliased call resolves" :expected "\"A\"" :actual "(do (require (quote [clojure.string :as st2])) (st2/upper-case \"a\"))"} + {:suite "namespaces / unified alias store" :label "alias fn registers + resolves" :expected "\"B\"" :actual "(do (require (quote [clojure.string])) (alias (quote st3) (quote clojure.string)) (st3/upper-case \"b\"))"} + {:suite "namespaces / unified alias store" :label "alias fn visible to ns-aliases" :expected "true" :actual "(do (require (quote [clojure.string])) (alias (quote st4) (quote clojure.string)) (pos? (count (filter (fn [[a n]] (= (str a) \"st4\")) (ns-aliases)))))"} + {:suite "namespaces / unified alias store" :label "ns-unalias removes both views" :expected "[0 false]" :actual "(do (require (quote [clojure.string :as st5])) (ns-unalias (quote user) (quote st5)) [(count (filter (fn [[a n]] (= (str a) \"st5\")) (ns-aliases))) (boolean (resolve (quote st5/upper-case)))])"} + {:suite "namespaces / unified alias store" :label "ns-resolve through alias" :expected "true" :actual "(do (require (quote [clojure.string :as st6])) (var? (ns-resolve (quote user) (quote st6/upper-case))))"} + {:suite "namespaces / unified alias store" :label "empty ns-aliases is a map" :expected "true" :actual "(map? (ns-aliases (quote clojure.core)))"} + {:suite "*ns* / identity & printing" :label "str of *ns*" :expected "\"user\"" :actual "(str *ns*)"} + {:suite "*ns* / identity & printing" :label "ns-name of *ns*" :expected "(quote user)" :actual "(ns-name *ns*)"} + {:suite "*ns* / identity & printing" :label "*ns* is find-ns" :expected "true" :actual "(= (ns-name *ns*) (ns-name (find-ns (quote user))))"} + {:suite "*ns* / identity & printing" :label "*ns* not a map" :expected "false" :actual "(map? *ns*)"} + {:suite "*ns* / identity & printing" :label "tracks in-ns" :expected "\"jolt.test-ns-a\"" :actual "(do (in-ns (quote jolt.test-ns-a)) (str *ns*))"} + {:suite "*ns* / identity & printing" :label "in-ns returns ns" :expected "\"jolt.test-ns-b\"" :actual "(str (in-ns (quote jolt.test-ns-b)))"} + {:suite "*ns* / identity & printing" :label "usable with ns fns" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote nsv) (quote clojure.string)) (some? (get (ns-aliases *ns*) (quote nsv))))"} + {:suite "*ns* / identity & printing" :label "ns-unalias via *ns*" :expected "true" :actual "(do (require (quote clojure.string)) (alias (quote nsw) (quote clojure.string)) (ns-unalias *ns* (quote nsw)) (nil? (get (ns-aliases *ns*) (quote nsw))))"} + {:suite "numbers / arithmetic" :label "add" :expected "6" :actual "(+ 1 2 3)"} + {:suite "numbers / arithmetic" :label "add zero args" :expected "0" :actual "(+)"} + {:suite "numbers / arithmetic" :label "subtract" :expected "5" :actual "(- 10 3 2)"} + {:suite "numbers / arithmetic" :label "negate" :expected "-5" :actual "(- 5)"} + {:suite "numbers / arithmetic" :label "multiply" :expected "24" :actual "(* 2 3 4)"} + {:suite "numbers / arithmetic" :label "multiply zero args" :expected "1" :actual "(*)"} + {:suite "numbers / arithmetic" :label "divide" :expected "2" :actual "(/ 10 5)"} + {:suite "numbers / arithmetic" :label "divide to fraction" :expected "1/2" :actual "(/ 1 2)"} + {:suite "numbers / arithmetic" :label "inc" :expected "6" :actual "(inc 5)"} + {:suite "numbers / arithmetic" :label "dec" :expected "4" :actual "(dec 5)"} + {:suite "numbers / arithmetic" :label "quot" :expected "3" :actual "(quot 10 3)"} + {:suite "numbers / arithmetic" :label "rem" :expected "1" :actual "(rem 10 3)"} + {:suite "numbers / arithmetic" :label "mod" :expected "2" :actual "(mod -1 3)"} + {:suite "numbers / arithmetic" :label "rem negative" :expected "-1" :actual "(rem -1 3)"} + {:suite "numbers / arithmetic" :label "max" :expected "9" :actual "(max 3 9 1)"} + {:suite "numbers / arithmetic" :label "min" :expected "1" :actual "(min 3 9 1)"} + {:suite "numbers / arithmetic" :label "abs" :expected "5" :actual "(abs -5)"} + {:suite "numbers / arithmetic" :label "promoting + alias" :expected "3" :actual "(+' 1 2)"} + {:suite "numbers / arithmetic" :label "inc' alias" :expected "6" :actual "(inc' 5)"} + {:suite "numbers / comparison" :label "less than" :expected "true" :actual "(< 1 2 3)"} + {:suite "numbers / comparison" :label "less than false" :expected "false" :actual "(< 1 3 2)"} + {:suite "numbers / comparison" :label "greater than" :expected "true" :actual "(> 3 2 1)"} + {:suite "numbers / comparison" :label "<=" :expected "true" :actual "(<= 1 1 2)"} + {:suite "numbers / comparison" :label ">=" :expected "true" :actual "(>= 3 3 2)"} + {:suite "numbers / comparison" :label "= numbers" :expected "true" :actual "(= 2 2)"} + {:suite "numbers / comparison" :label "= different" :expected "false" :actual "(= 2 3)"} + {:suite "numbers / comparison" :label "== numeric" :expected "true" :actual "(== 2 2)"} + {:suite "numbers / comparison" :label "not=" :expected "true" :actual "(not= 1 2)"} + {:suite "numbers / comparison" :label "compare less" :expected "-1" :actual "(compare 1 2)"} + {:suite "numbers / comparison" :label "compare equal" :expected "0" :actual "(compare 1 1)"} + {:suite "numbers / comparison" :label "compare greater" :expected "1" :actual "(compare 2 1)"} + {:suite "numbers / predicates" :label "zero?" :expected "true" :actual "(zero? 0)"} + {:suite "numbers / predicates" :label "pos?" :expected "true" :actual "(pos? 5)"} + {:suite "numbers / predicates" :label "neg?" :expected "true" :actual "(neg? -5)"} + {:suite "numbers / predicates" :label "even?" :expected "true" :actual "(even? 4)"} + {:suite "numbers / predicates" :label "odd?" :expected "true" :actual "(odd? 3)"} + {:suite "numbers / predicates" :label "number?" :expected "true" :actual "(number? 5)"} + {:suite "numbers / predicates" :label "number? false" :expected "false" :actual "(number? :a)"} + {:suite "numbers / predicates" :label "int?" :expected "true" :actual "(int? 5)"} + {:suite "numbers / predicates" :label "pos-int?" :expected "true" :actual "(pos-int? 5)"} + {:suite "numbers / predicates" :label "neg-int?" :expected "true" :actual "(neg-int? -5)"} + {:suite "numbers / predicates" :label "nat-int? zero" :expected "true" :actual "(nat-int? 0)"} + {:suite "numbers / predicates" :label "nat-int? neg" :expected "false" :actual "(nat-int? -1)"} + {:suite "numbers / predicates" :label "ratio? false" :expected "false" :actual "(ratio? 5)"} + {:suite "numbers / floats & symbolic values" :label "read ##Inf" :expected "true" :actual "(= ##Inf (/ 1.0 0.0))"} + {:suite "numbers / floats & symbolic values" :label "read ##-Inf" :expected "true" :actual "(< ##-Inf 0)"} + {:suite "numbers / floats & symbolic values" :label "##NaN not= itself" :expected "true" :actual "(not (== ##NaN ##NaN))"} + {:suite "numbers / floats & symbolic values" :label "float? fractional" :expected "true" :actual "(float? 1.5)"} + {:suite "numbers / floats & symbolic values" :label "double? fractional" :expected "true" :actual "(double? 0.25)"} + {:suite "numbers / floats & symbolic values" :label "float? integer" :expected "false" :actual "(float? 3)"} + {:suite "numbers / floats & symbolic values" :label "float? ##Inf" :expected "true" :actual "(float? ##Inf)"} + {:suite "numbers / floats & symbolic values" :label "double? ##NaN" :expected "true" :actual "(double? ##NaN)"} + {:suite "numbers / floats & symbolic values" :label "infinite? ##Inf" :expected "true" :actual "(infinite? ##Inf)"} + {:suite "numbers / floats & symbolic values" :label "infinite? ##-Inf" :expected "true" :actual "(infinite? ##-Inf)"} + {:suite "numbers / floats & symbolic values" :label "infinite? finite" :expected "false" :actual "(infinite? 1.5)"} + {:suite "numbers / floats & symbolic values" :label "NaN? ##NaN" :expected "true" :actual "(NaN? ##NaN)"} + {:suite "numbers / floats & symbolic values" :label "NaN? number" :expected "false" :actual "(NaN? 1.0)"} + {:suite "numbers / floats & symbolic values" :label "int? ##Inf false" :expected "false" :actual "(int? ##Inf)"} + {:suite "numbers / floats & symbolic values" :label "pos-int? ##Inf" :expected "false" :actual "(pos-int? ##Inf)"} + {:suite "numbers / literal syntax" :label "bigint suffix N" :expected "42N" :actual "42N"} + {:suite "numbers / literal syntax" :label "bigint zero" :expected "0N" :actual "0N"} + {:suite "numbers / literal syntax" :label "bigdec suffix M" :expected "1.5M" :actual "1.5M"} + {:suite "numbers / literal syntax" :label "bigdec int M" :expected "0.0M" :actual "0.0M"} + {:suite "numbers / literal syntax" :label "ratio -> double" :expected "1/2" :actual "1/2"} + {:suite "numbers / literal syntax" :label "ratio 3/4" :expected "3/4" :actual "3/4"} + {:suite "numbers / literal syntax" :label "neg ratio" :expected "-1/2" :actual "-1/2"} + {:suite "numbers / literal syntax" :label "radix binary" :expected "10" :actual "2r1010"} + {:suite "numbers / literal syntax" :label "radix hex-ish" :expected "255" :actual "16rFF"} + {:suite "numbers / literal syntax" :label "radix base36" :expected "35" :actual "36rZ"} + {:suite "numbers / literal syntax" :label "hex" :expected "255" :actual "0xFF"} + {:suite "numbers / literal syntax" :label "exponent" :expected "1000.0" :actual "1e3"} + {:suite "numbers / literal syntax" :label "exponent neg" :expected "0.015" :actual "1.5e-2"} + {:suite "numbers / strictness (throws like Clojure)" :label "odd? nil" :expected :throws :actual "(odd? nil)"} + {:suite "numbers / strictness (throws like Clojure)" :label "odd? fractional" :expected :throws :actual "(odd? 1.5)"} + {:suite "numbers / strictness (throws like Clojure)" :label "even? inf" :expected :throws :actual "(even? ##Inf)"} + {:suite "numbers / strictness (throws like Clojure)" :label "zero? nil" :expected :throws :actual "(zero? nil)"} + {:suite "numbers / strictness (throws like Clojure)" :label "pos? false" :expected :throws :actual "(pos? false)"} + {:suite "numbers / strictness (throws like Clojure)" :label "neg? keyword" :expected :throws :actual "(neg? :a)"} + {:suite "numbers / strictness (throws like Clojure)" :label "< nil" :expected :throws :actual "(< nil 1)"} + {:suite "numbers / strictness (throws like Clojure)" :label "> with nil" :expected :throws :actual "(> 1 nil)"} + {:suite "numbers / strictness (throws like Clojure)" :label "max non-number" :expected :throws :actual "(max 1 nil)"} + {:suite "numbers / strictness (throws like Clojure)" :label "quot by zero" :expected :throws :actual "(quot 10 0)"} + {:suite "numbers / strictness (throws like Clojure)" :label "quot inf" :expected :throws :actual "(quot ##Inf 1)"} + {:suite "numbers / strictness (throws like Clojure)" :label "< arity-1 any" :expected "true" :actual "(< :anything)"} + {:suite "numbers / strictness (throws like Clojure)" :label "odd? ok" :expected "true" :actual "(odd? 3)"} + {:suite "numbers / strictness (throws like Clojure)" :label "< ok" :expected "true" :actual "(< 1 2 3)"} + {:suite "numbers / strictness (throws like Clojure)" :label "quot ok" :expected "3" :actual "(quot 10 3)"} + {:suite "numbers / printing of inf & nan" :label "str Infinity" :expected "\"Infinity\"" :actual "(str ##Inf)"} + {:suite "numbers / printing of inf & nan" :label "str -Infinity" :expected "\"-Infinity\"" :actual "(str ##-Inf)"} + {:suite "numbers / printing of inf & nan" :label "str NaN" :expected "\"NaN\"" :actual "(str ##NaN)"} + {:suite "numbers / printing of inf & nan" :label "pr-str Infinity" :expected "\"##Inf\"" :actual "(pr-str ##Inf)"} + {:suite "numbers / printing of inf & nan" :label "inf inside coll" :expected "\"[##Inf]\"" :actual "(str [##Inf])"} + {:suite "numbers / bit-ops & math" :label "bit-and" :expected "4" :actual "(bit-and 12 6)"} + {:suite "numbers / bit-ops & math" :label "bit-or" :expected "14" :actual "(bit-or 12 6)"} + {:suite "numbers / bit-ops & math" :label "bit-xor" :expected "10" :actual "(bit-xor 12 6)"} + {:suite "numbers / bit-ops & math" :label "bit-shift-left" :expected "8" :actual "(bit-shift-left 1 3)"} + {:suite "numbers / bit-ops & math" :label "bit-shift-right" :expected "2" :actual "(bit-shift-right 8 2)"} + {:suite "numbers / bit-ops & math" :label "bit-set" :expected "8" :actual "(bit-set 0 3)"} + {:suite "numbers / bit-ops & math" :label "bit-clear" :expected "13" :actual "(bit-clear 15 1)"} + {:suite "numbers / bit-ops & math" :label "bit-test true" :expected "true" :actual "(bit-test 4 2)"} + {:suite "numbers / bit-ops & math" :label "bigint 64-bit" :expected "\"9000000000\"" :actual "(str (bigint 9000000000))"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand-int in range" :expected "true" :actual "(let [r (rand-int 5)] (and (integer? r) (>= r 0) (< r 5)))"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand-int zero" :expected "0" :actual "(rand-int 1)"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand in [0,1)" :expected "true" :actual "(let [r (rand)] (and (>= r 0) (< r 1)))"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand n in [0,n)" :expected "true" :actual "(let [r (rand 10)] (and (>= r 0) (< r 10)))"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand-nth member" :expected "true" :actual "(contains? #{:a :b :c} (rand-nth [:a :b :c]))"} + {:suite "numbers / random (invariants — non-deterministic)" :label "rand-nth single" :expected ":x" :actual "(rand-nth [:x])"} + {:suite "numbers / parse fns (1.11)" :label "parse-long" :expected "42" :actual "(parse-long \"42\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long negative" :expected "-7" :actual "(parse-long \"-7\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long plus" :expected "7" :actual "(parse-long \"+7\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long float nil" :expected "nil" :actual "(parse-long \"1.5\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long hex nil" :expected "nil" :actual "(parse-long \"0x10\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long empty nil" :expected "nil" :actual "(parse-long \"\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long junk nil" :expected "nil" :actual "(parse-long \"12ab\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-long throws" :expected :throws :actual "(parse-long 42)"} + {:suite "numbers / parse fns (1.11)" :label "parse-double" :expected "1.5" :actual "(parse-double \"1.5\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double int" :expected "4.0" :actual "(parse-double \"4\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double sci" :expected "1500.0" :actual "(parse-double \"1.5e3\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double neg" :expected "-0.5" :actual "(parse-double \"-0.5\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double junk" :expected "nil" :actual "(parse-double \"abc\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double trail" :expected "nil" :actual "(parse-double \"1.5x\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-double throws" :expected :throws :actual "(parse-double :k)"} + {:suite "numbers / parse fns (1.11)" :label "parse-boolean true" :expected "true" :actual "(parse-boolean \"true\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-boolean false" :expected "false" :actual "(parse-boolean \"false\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-boolean case" :expected "nil" :actual "(parse-boolean \"True\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-boolean junk" :expected "nil" :actual "(parse-boolean \"yes\")"} + {:suite "numbers / parse fns (1.11)" :label "parse-boolean throws" :expected :throws :actual "(parse-boolean true)"} + {:suite "numbers / promoting & unchecked aliases" :label "+'" :expected "3" :actual "(+' 1 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "-'" :expected "3" :actual "(-' 5 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "*'" :expected "12" :actual "(*' 3 4)"} + {:suite "numbers / promoting & unchecked aliases" :label "inc'" :expected "6" :actual "(inc' 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "dec'" :expected "4" :actual "(dec' 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add" :expected "5" :actual "(unchecked-add 2 3)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-add-int" :expected "5" :actual "(unchecked-add-int 2 3)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-subtract" :expected "3" :actual "(unchecked-subtract 5 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-subtract-int" :expected "3" :actual "(unchecked-subtract-int 5 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-multiply" :expected "12" :actual "(unchecked-multiply 3 4)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-multiply-int" :expected "12" :actual "(unchecked-multiply-int 3 4)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-negate" :expected "-5" :actual "(unchecked-negate 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-negate-int" :expected "-5" :actual "(unchecked-negate-int 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-inc" :expected "2" :actual "(unchecked-inc 1)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-inc-int" :expected "2" :actual "(unchecked-inc-int 1)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-dec" :expected "0" :actual "(unchecked-dec 1)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-dec-int" :expected "0" :actual "(unchecked-dec-int 1)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int" :expected "3" :actual "(unchecked-divide-int 7 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int negative truncates toward zero" :expected "-3" :actual "(unchecked-divide-int -7 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-divide-int by zero throws" :expected :throws :actual "(unchecked-divide-int 1 0)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-remainder-int" :expected "1" :actual "(unchecked-remainder-int 7 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-remainder-int negative" :expected "-1" :actual "(unchecked-remainder-int -7 2)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-int truncates" :expected "3" :actual "(unchecked-int 3.7)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-int negative" :expected "-3" :actual "(unchecked-int -3.7)"} + {:suite "numbers / promoting & unchecked aliases" :label "unchecked-long" :expected "3" :actual "(unchecked-long 3.7)"} + {:suite "numbers / promoting & unchecked aliases" :label "int? on integer" :expected "true" :actual "(int? 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "int? on double" :expected "false" :actual "(int? 5.5)"} + {:suite "numbers / promoting & unchecked aliases" :label "int? on non-number" :expected "false" :actual "(int? \"5\")"} + {:suite "numbers / promoting & unchecked aliases" :label "num passes a number through" :expected "5" :actual "(num 5)"} + {:suite "numbers / promoting & unchecked aliases" :label "num on a double" :expected "5.5" :actual "(num 5.5)"} + {:suite "numbers / promoting & unchecked aliases" :label "num throws on non-number" :expected :throws :actual "(num \"x\")"} + {:suite "numbers / == numeric equality" :label "== single arg" :expected "true" :actual "(== :a)"} + {:suite "numbers / == numeric equality" :label "== equal" :expected "true" :actual "(== 2 2)"} + {:suite "numbers / == numeric equality" :label "== unequal" :expected "false" :actual "(== 2 3)"} + {:suite "numbers / == numeric equality" :label "== chained" :expected "true" :actual "(== 2 2 2)"} + {:suite "numbers / == numeric equality" :label "== chained unequal" :expected "false" :actual "(== 2 2 3)"} + {:suite "numbers / == numeric equality" :label "== int and double" :expected "true" :actual "(== 1 1.0)"} + {:suite "numbers / == numeric equality" :label "== throws on non-number" :expected :throws :actual "(== 1 :a)"} + {:suite "numbers / == numeric equality" :label "== throws on two keywords" :expected :throws :actual "(== :a :a)"} + {:suite "numbers / variadic bit ops" :label "bit-and 2" :expected "4" :actual "(bit-and 12 6)"} + {:suite "numbers / variadic bit ops" :label "bit-and 3" :expected "4" :actual "(bit-and 12 6 7)"} + {:suite "numbers / variadic bit ops" :label "bit-and 4" :expected "0" :actual "(bit-and 12 6 7 3)"} + {:suite "numbers / variadic bit ops" :label "bit-or 3" :expected "7" :actual "(bit-or 1 2 4)"} + {:suite "numbers / variadic bit ops" :label "bit-xor 3" :expected "7" :actual "(bit-xor 1 2 4)"} + {:suite "numbers / variadic bit ops" :label "bit-xor folds left" :expected "1" :actual "(bit-xor 5 6 2)"} + {:suite "numbers / variadic bit ops" :label "bit-and-not 2" :expected "8" :actual "(bit-and-not 12 6)"} + {:suite "numbers / variadic bit ops" :label "bit-and-not 3" :expected "8" :actual "(bit-and-not 12 6 3)"} + {:suite "numbers / variadic bit ops" :label "bit-and single arg throws" :expected :throws :actual "(bit-and 5)"} + {:suite "numbers / variadic bit ops" :label "bit-or keeps binary fast path" :expected "3" :actual "(bit-or 1 2)"} + {:suite "predicates / nil & boolean" :label "nil? true" :expected "true" :actual "(nil? nil)"} + {:suite "predicates / nil & boolean" :label "nil? false" :expected "false" :actual "(nil? 0)"} + {:suite "predicates / nil & boolean" :label "some? true" :expected "true" :actual "(some? 0)"} + {:suite "predicates / nil & boolean" :label "some? on nil" :expected "false" :actual "(some? nil)"} + {:suite "predicates / nil & boolean" :label "true?" :expected "true" :actual "(true? true)"} + {:suite "predicates / nil & boolean" :label "false?" :expected "true" :actual "(false? false)"} + {:suite "predicates / nil & boolean" :label "boolean? true" :expected "true" :actual "(boolean? false)"} + {:suite "predicates / nil & boolean" :label "not nil" :expected "true" :actual "(not nil)"} + {:suite "predicates / nil & boolean" :label "not 0 is false" :expected "false" :actual "(not 0)"} + {:suite "predicates / nil & boolean" :label "boolean of nil" :expected "false" :actual "(boolean nil)"} + {:suite "predicates / nil & boolean" :label "boolean of value" :expected "true" :actual "(boolean 5)"} + {:suite "predicates / types" :label "string?" :expected "true" :actual "(string? \"x\")"} + {:suite "predicates / types" :label "number?" :expected "true" :actual "(number? 1)"} + {:suite "predicates / types" :label "keyword?" :expected "true" :actual "(keyword? :a)"} + {:suite "predicates / types" :label "symbol?" :expected "true" :actual "(symbol? (quote a))"} + {:suite "predicates / types" :label "char?" :expected "true" :actual "(char? \\a)"} + {:suite "predicates / types" :label "fn? on fn" :expected "true" :actual "(fn? inc)"} + {:suite "predicates / types" :label "ifn? on keyword" :expected "true" :actual "(ifn? :a)"} + {:suite "predicates / types" :label "vector?" :expected "true" :actual "(vector? [1])"} + {:suite "predicates / types" :label "list?" :expected "true" :actual "(list? (list 1))"} + {:suite "predicates / types" :label "map?" :expected "true" :actual "(map? {:a 1})"} + {:suite "predicates / types" :label "set?" :expected "true" :actual "(set? #{1})"} + {:suite "predicates / types" :label "coll? vector" :expected "true" :actual "(coll? [1])"} + {:suite "predicates / types" :label "coll? map" :expected "true" :actual "(coll? {:a 1})"} + {:suite "predicates / types" :label "coll? on number" :expected "false" :actual "(coll? 1)"} + {:suite "predicates / types" :label "seq? list" :expected "true" :actual "(seq? (list 1))"} + {:suite "predicates / types" :label "seq? vector" :expected "false" :actual "(seq? [1])"} + {:suite "predicates / types" :label "sequential? vector" :expected "true" :actual "(sequential? [1])"} + {:suite "predicates / types" :label "associative? map" :expected "true" :actual "(associative? {:a 1})"} + {:suite "predicates / types" :label "associative? vec" :expected "true" :actual "(associative? [1])"} + {:suite "predicates / types" :label "associative? list" :expected "false" :actual "(associative? '(1 2))"} + {:suite "predicates / types" :label "associative? set" :expected "false" :actual "(associative? #{1})"} + {:suite "predicates / types" :label "reversible? vec" :expected "true" :actual "(reversible? [1 2])"} + {:suite "predicates / types" :label "reversible? list" :expected "false" :actual "(reversible? '(1 2))"} + {:suite "predicates / types" :label "reversible? smap" :expected "true" :actual "(reversible? (sorted-map :a 1))"} + {:suite "predicates / types" :label "reversible? hmap" :expected "false" :actual "(reversible? (hash-map :a 1))"} + {:suite "predicates / types" :label "indexed? vector" :expected "true" :actual "(indexed? [1])"} + {:suite "predicates / types" :label "counted? vector" :expected "true" :actual "(counted? [1])"} + {:suite "predicates / idents" :label "ident? keyword" :expected "true" :actual "(ident? :a)"} + {:suite "predicates / idents" :label "ident? symbol" :expected "true" :actual "(ident? (quote a))"} + {:suite "predicates / idents" :label "simple-keyword?" :expected "true" :actual "(simple-keyword? :a)"} + {:suite "predicates / idents" :label "qualified-keyword?" :expected "true" :actual "(qualified-keyword? :a/b)"} + {:suite "predicates / idents" :label "simple-symbol?" :expected "true" :actual "(simple-symbol? (quote a))"} + {:suite "predicates / idents" :label "qualified-symbol?" :expected "true" :actual "(qualified-symbol? (quote a/b))"} + {:suite "predicates / idents" :label "name of keyword" :expected "\"a\"" :actual "(name :a)"} + {:suite "predicates / idents" :label "name of qualified" :expected "\"b\"" :actual "(name :a/b)"} + {:suite "predicates / idents" :label "namespace" :expected "\"a\"" :actual "(namespace :a/b)"} + {:suite "predicates / idents" :label "namespace simple" :expected "nil" :actual "(namespace :a)"} + {:suite "predicates / idents" :label "keyword constructor" :expected ":foo" :actual "(keyword \"foo\")"} + {:suite "predicates / idents" :label "keyword ns + name" :expected ":a/b" :actual "(keyword \"a\" \"b\")"} + {:suite "predicates / idents" :label "symbol constructor" :expected "(quote x)" :actual "(symbol \"x\")"} + {:suite "predicates / idents" :label "name of string" :expected "\"s\"" :actual "(name \"s\")"} + {:suite "predicates / overlay-migrated" :label "not-any? true" :expected "true" :actual "(not-any? even? [1 3 5])"} + {:suite "predicates / overlay-migrated" :label "not-any? false" :expected "false" :actual "(not-any? even? [1 2 3])"} + {:suite "predicates / overlay-migrated" :label "not-every? true" :expected "true" :actual "(not-every? even? [2 4 5])"} + {:suite "predicates / overlay-migrated" :label "not-every? false" :expected "false" :actual "(not-every? even? [2 4 6])"} + {:suite "predicates / overlay-migrated" :label "ident? number" :expected "false" :actual "(ident? 1)"} + {:suite "predicates / overlay-migrated" :label "qualified-ident?" :expected "true" :actual "(qualified-ident? :a/b)"} + {:suite "predicates / overlay-migrated" :label "qualified-ident? no" :expected "false" :actual "(qualified-ident? :a)"} + {:suite "predicates / overlay-migrated" :label "simple-ident?" :expected "true" :actual "(simple-ident? :a)"} + {:suite "predicates / overlay-migrated" :label "ratio?" :expected "false" :actual "(ratio? 3)"} + {:suite "predicates / overlay-migrated" :label "decimal?" :expected "false" :actual "(decimal? 3)"} + {:suite "predicates / overlay-migrated" :label "class? of value" :expected "false" :actual "(class? \"s\")"} + {:suite "predicates / overlay-migrated" :label "class? of symbol" :expected "false" :actual "(class? 'java.lang.String)"} + {:suite "predicates / overlay-migrated" :label "rational? int" :expected "true" :actual "(rational? 3)"} + {:suite "predicates / overlay-migrated" :label "rational? float" :expected "false" :actual "(rational? 3.5)"} + {:suite "predicates / overlay-migrated" :label "nat-int? zero" :expected "true" :actual "(nat-int? 0)"} + {:suite "predicates / overlay-migrated" :label "nat-int? neg" :expected "false" :actual "(nat-int? -1)"} + {:suite "predicates / overlay-migrated" :label "pos-int?" :expected "true" :actual "(pos-int? 5)"} + {:suite "predicates / overlay-migrated" :label "neg-int?" :expected "true" :actual "(neg-int? -3)"} + {:suite "predicates / overlay-migrated" :label "NaN? on nan" :expected "true" :actual "(NaN? (/ 0.0 0.0))"} + {:suite "predicates / overlay-migrated" :label "NaN? on number" :expected "false" :actual "(NaN? 5)"} + {:suite "predicates / overlay-migrated" :label "abs negative" :expected "3" :actual "(abs -3)"} + {:suite "predicates / overlay-migrated" :label "abs positive" :expected "2.5" :actual "(abs 2.5)"} + {:suite "predicates / overlay-migrated" :label "object?" :expected "false" :actual "(object? 1)"} + {:suite "predicates / overlay-migrated" :label "undefined?" :expected "false" :actual "(undefined? 1)"} + {:suite "predicates / overlay-migrated" :label "keyword-identical?" :expected "true" :actual "(keyword-identical? :a :a)"} + {:suite "predicates / overlay-migrated" :label "keyword-identical? no" :expected "false" :actual "(keyword-identical? :a :b)"} + {:suite "predicates / map? & coll? strictness" :label "map? symbol" :expected "false" :actual "(map? (quote sym))"} + {:suite "predicates / map? & coll? strictness" :label "map? char" :expected "false" :actual "(map? \\a)"} + {:suite "predicates / map? & coll? strictness" :label "map? uuid" :expected "false" :actual "(map? (random-uuid))"} + {:suite "predicates / map? & coll? strictness" :label "map? literal" :expected "true" :actual "(map? {:a 1})"} + {:suite "predicates / map? & coll? strictness" :label "map? hash-map" :expected "true" :actual "(map? (hash-map :a 1))"} + {:suite "predicates / map? & coll? strictness" :label "map? sorted-map" :expected "true" :actual "(map? (sorted-map :a 1))"} + {:suite "predicates / map? & coll? strictness" :label "map? record" :expected "true" :actual "(do (defrecord Mr [a]) (map? (->Mr 1)))"} + {:suite "predicates / map? & coll? strictness" :label "map? sorted-set" :expected "false" :actual "(map? (sorted-set 1))"} + {:suite "predicates / map? & coll? strictness" :label "map? vector" :expected "false" :actual "(map? [1])"} + {:suite "predicates / map? & coll? strictness" :label "coll? symbol" :expected "false" :actual "(coll? (quote sym))"} + {:suite "predicates / map? & coll? strictness" :label "coll? char" :expected "false" :actual "(coll? \\a)"} + {:suite "predicates / map? & coll? strictness" :label "coll? uuid" :expected "false" :actual "(coll? (random-uuid))"} + {:suite "predicates / map? & coll? strictness" :label "coll? keyword" :expected "false" :actual "(coll? :k)"} + {:suite "predicates / map? & coll? strictness" :label "coll? string" :expected "false" :actual "(coll? \"s\")"} + {:suite "predicates / map? & coll? strictness" :label "coll? map literal" :expected "true" :actual "(coll? {:a 1})"} + {:suite "predicates / map? & coll? strictness" :label "coll? sorted-map" :expected "true" :actual "(coll? (sorted-map :a 1))"} + {:suite "predicates / map? & coll? strictness" :label "coll? sorted-set" :expected "true" :actual "(coll? (sorted-set 1))"} + {:suite "predicates / map? & coll? strictness" :label "coll? record" :expected "true" :actual "(do (defrecord Cr [a]) (coll? (->Cr 1)))"} + {:suite "predicates / map? & coll? strictness" :label "coll? vector" :expected "true" :actual "(coll? [1])"} + {:suite "predicates / map? & coll? strictness" :label "coll? list" :expected "true" :actual "(coll? (list 1))"} + {:suite "predicates / map? & coll? strictness" :label "coll? set" :expected "true" :actual "(coll? #{1})"} + {:suite "predicates / map? & coll? strictness" :label "coll? lazy seq" :expected "true" :actual "(coll? (map inc [1]))"} + {:suite "predicates / tagged-value" :label "atom? yes" :expected "true" :actual "(atom? (atom 1))"} + {:suite "predicates / tagged-value" :label "atom? no" :expected "false" :actual "(atom? 1)"} + {:suite "predicates / tagged-value" :label "volatile? yes" :expected "true" :actual "(volatile? (volatile! 1))"} + {:suite "predicates / tagged-value" :label "volatile? no" :expected "false" :actual "(volatile? (atom 1))"} + {:suite "predicates / tagged-value" :label "record? yes" :expected "true" :actual "(do (defrecord Rp [a]) (record? (->Rp 1)))"} + {:suite "predicates / tagged-value" :label "record? no map" :expected "false" :actual "(record? {:a 1})"} + {:suite "predicates / tagged-value" :label "record? no nil" :expected "false" :actual "(record? nil)"} + {:suite "predicates / tagged-value" :label "tagged-literal? yes" :expected "true" :actual "(tagged-literal? (tagged-literal (quote inst) \"2020\"))"} + {:suite "predicates / tagged-value" :label "tagged-literal? no" :expected "false" :actual "(tagged-literal? 1)"} + {:suite "predicates / tagged-value" :label "reader-conditional? no" :expected "false" :actual "(reader-conditional? 1)"} + {:suite "predicates / tagged-value" :label "chunked-seq? always false" :expected "true" :actual "(chunked-seq? (seq [1 2 3]))"} + {:suite "predicates / equality & identity" :label "= same" :expected "true" :actual "(= 1 1)"} + {:suite "predicates / equality & identity" :label "= vectors" :expected "true" :actual "(= [1 2] [1 2])"} + {:suite "predicates / equality & identity" :label "= vector & list" :expected "true" :actual "(= [1 2] (list 1 2))"} + {:suite "predicates / equality & identity" :label "= maps" :expected "true" :actual "(= {:a 1} {:a 1})"} + {:suite "predicates / equality & identity" :label "= sets" :expected "true" :actual "(= #{1 2} #{2 1})"} + {:suite "predicates / equality & identity" :label "= nested" :expected "true" :actual "(= {:a [1 2]} {:a [1 2]})"} + {:suite "predicates / equality & identity" :label "not= differs" :expected "true" :actual "(not= [1 2] [1 3])"} + {:suite "predicates / equality & identity" :label "identical? same kw" :expected "true" :actual "(identical? :a :a)"} + {:suite "predicates / equality & identity" :label "compare strings" :expected "-1" :actual "(compare \"a\" \"b\")"} + {:suite "predicates / seqable, reduced & emptiness" :label "seqable? vector" :expected "true" :actual "(seqable? [1])"} + {:suite "predicates / seqable, reduced & emptiness" :label "seqable? map" :expected "true" :actual "(seqable? {:a 1})"} + {:suite "predicates / seqable, reduced & emptiness" :label "seqable? string" :expected "true" :actual "(seqable? \"s\")"} + {:suite "predicates / seqable, reduced & emptiness" :label "seqable? nil" :expected "true" :actual "(seqable? nil)"} + {:suite "predicates / seqable, reduced & emptiness" :label "seqable? number" :expected "false" :actual "(seqable? 5)"} + {:suite "predicates / seqable, reduced & emptiness" :label "integer? int" :expected "true" :actual "(integer? 5)"} + {:suite "predicates / seqable, reduced & emptiness" :label "integer? fraction" :expected "false" :actual "(integer? 5.5)"} + {:suite "predicates / seqable, reduced & emptiness" :label "reduced? wrapped" :expected "true" :actual "(reduced? (reduced 1))"} + {:suite "predicates / seqable, reduced & emptiness" :label "reduced? plain" :expected "false" :actual "(reduced? 1)"} + {:suite "predicates / seqable, reduced & emptiness" :label "deref reduced" :expected "9" :actual "(deref (reduced 9))"} + {:suite "predicates / seqable, reduced & emptiness" :label "unreduced wrapped" :expected "9" :actual "(unreduced (reduced 9))"} + {:suite "predicates / seqable, reduced & emptiness" :label "unreduced plain" :expected "9" :actual "(unreduced 9)"} + {:suite "predicates / seqable, reduced & emptiness" :label "not-empty full" :expected "[1]" :actual "(not-empty [1])"} + {:suite "predicates / seqable, reduced & emptiness" :label "not-empty empty" :expected "nil" :actual "(not-empty [])"} + {:suite "predicates / seqable, reduced & emptiness" :label "not-empty string" :expected "nil" :actual "(not-empty \"\")"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare =" :expected "0" :actual "(compare 1 1)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare <" :expected "-1" :actual "(compare 1 2)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare nil first" :expected "-1" :actual "(compare nil 1)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare nil nil" :expected "0" :actual "(compare nil nil)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare strings" :expected "-1" :actual "(compare \"a\" \"b\")"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare keywords" :expected "-1" :actual "(compare :a :b)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare symbols" :expected "-1" :actual "(compare (quote a) (quote b))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare bools" :expected "-1" :actual "(compare false true)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare vec length" :expected "-1" :actual "(compare [1 2] [1 2 3])"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare vec elems" :expected "-1" :actual "(compare [1 2] [1 3])"} + {:suite "predicates / compare, type, any? (stage 3)" :label "compare cross-type throws" :expected :throws :actual "(compare 1 \"a\")"} + {:suite "predicates / compare, type, any? (stage 3)" :label "sort with compare" :expected "[nil 1 3]" :actual "(sort compare [3 nil 1])"} + {:suite "predicates / compare, type, any? (stage 3)" :label "type meta override" :expected ":custom" :actual "(type (with-meta [1] {:type :custom}))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "type of record" :expected "false" :actual "(do (defrecord TyR [a]) (= (symbol (str (type (->TyR 1)))) (type (->TyR 1))))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "any? value" :expected "true" :actual "(any? 5)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "any? nil" :expected "true" :actual "(any? nil)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "gensym is symbol" :expected "true" :actual "(symbol? (gensym))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "gensym prefix" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/starts-with? (str (gensym \"p_\")) \"p_\"))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "gensym distinct" :expected "false" :actual "(= (gensym) (gensym))"} + {:suite "predicates / compare, type, any? (stage 3)" :label "int? Inf false" :expected "false" :actual "(int? ##Inf)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "integer? Inf false" :expected "false" :actual "(integer? ##Inf)"} + {:suite "predicates / compare, type, any? (stage 3)" :label "integer? NaN false" :expected "false" :actual "(integer? ##NaN)"} + {:suite "predicates / ifn?" :label "fn" :expected "true" :actual "(ifn? inc)"} + {:suite "predicates / ifn?" :label "keyword" :expected "true" :actual "(ifn? :k)"} + {:suite "predicates / ifn?" :label "symbol" :expected "true" :actual "(ifn? (quote s))"} + {:suite "predicates / ifn?" :label "map" :expected "true" :actual "(ifn? {})"} + {:suite "predicates / ifn?" :label "sorted map" :expected "true" :actual "(ifn? (sorted-map))"} + {:suite "predicates / ifn?" :label "set" :expected "true" :actual "(ifn? #{1})"} + {:suite "predicates / ifn?" :label "vector" :expected "true" :actual "(ifn? [1])"} + {:suite "predicates / ifn?" :label "var" :expected "true" :actual "(ifn? (var first))"} + {:suite "predicates / ifn?" :label "list NOT" :expected "false" :actual "(ifn? (list 1 2))"} + {:suite "predicates / ifn?" :label "lazy NOT" :expected "false" :actual "(ifn? (map inc [1]))"} + {:suite "predicates / ifn?" :label "string NOT" :expected "false" :actual "(ifn? \"s\")"} + {:suite "predicates / ifn?" :label "number NOT" :expected "false" :actual "(ifn? 5)"} + {:suite "predicates / ifn?" :label "nil NOT" :expected "false" :actual "(ifn? nil)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? zero" :expected "true" :actual "(zero? 0)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? nonzero" :expected "false" :actual "(zero? 3)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? throws" :expected :throws :actual "(zero? :a)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "zero? throws on nil" :expected :throws :actual "(zero? nil)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? positive" :expected "true" :actual "(pos? 2)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? zero" :expected "false" :actual "(pos? 0)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "pos? throws" :expected :throws :actual "(pos? \"x\")"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "neg? throws" :expected :throws :actual "(neg? \"x\")"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? all pass" :expected "true" :actual "(every? odd? [1 3 5])"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? one fails" :expected "false" :actual "(every? odd? [1 2 5])"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? vacuous" :expected "true" :actual "(every? odd? [])"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? nil coll" :expected "true" :actual "(every? odd? nil)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "every? infinite short-circuit" :expected "false" :actual "(every? pos? (range))"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? char" :expected "true" :actual "(char? \\x)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? string" :expected "false" :actual "(char? \"x\")"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? number" :expected "false" :actual "(char? 97)"} + {:suite "predicates / numeric guards & every? (overlay moves)" :label "char? nil" :expected "false" :actual "(char? nil)"} + {:suite "protocols / defprotocol & dispatch" :label "protocol on record" :expected "16" :actual "(do (defprotocol Shape (area [s])) (defrecord Sq [side] Shape (area [_] (* side side))) (area (->Sq 4)))"} + {:suite "protocols / defprotocol & dispatch" :label "protocol on deftype" :expected "16" :actual "(do (defprotocol Shape (area [s])) (deftype Sq [side] Shape (area [_] (* side side))) (area (->Sq 4)))"} + {:suite "protocols / defprotocol & dispatch" :label "multiple methods" :expected "[1 2]" :actual "(do (defprotocol P (m [s]) (n [s])) (defrecord R [a b] P (m [_] a) (n [_] b)) [(m (->R 1 2)) (n (->R 1 2))])"} + {:suite "protocols / defprotocol & dispatch" :label "multiple protocols" :expected "[:a :b]" :actual "(do (defprotocol P1 (p1 [s])) (defprotocol P2 (p2 [s])) (deftype T [] P1 (p1 [_] :a) P2 (p2 [_] :b)) [(p1 (->T)) (p2 (->T))])"} + {:suite "protocols / defprotocol & dispatch" :label "method args" :expected "7" :actual "(do (defprotocol P (add [s x])) (defrecord R [n] P (add [_ x] (+ n x))) (add (->R 5) 2))"} + {:suite "protocols / defprotocol & dispatch" :label "extend-type" :expected "10" :actual "(do (defprotocol P (twice [s])) (extend-type Number P (twice [n] (* n 2))) (twice 5))"} + {:suite "protocols / defprotocol & dispatch" :label "extend-protocol" :expected "[2 4]" :actual "(do (defprotocol P (dbl [s])) (extend-protocol P Number (dbl [n] (* n 2))) [(dbl 1) (dbl 2)])"} + {:suite "protocols / records" :label "record field access" :expected "1" :actual "(do (defrecord R [a b]) (:a (->R 1 2)))"} + {:suite "protocols / records" :label "record map access" :expected "2" :actual "(do (defrecord R [a b]) (get (->R 1 2) :b))"} + {:suite "protocols / records" :label "record equality" :expected "true" :actual "(do (defrecord R [a b]) (= (->R 1 2) (->R 1 2)))"} + {:suite "protocols / records" :label "record inequality" :expected "false" :actual "(do (defrecord R [a b]) (= (->R 1 2) (->R 3 4)))"} + {:suite "protocols / records" :label "map-> factory" :expected "1" :actual "(do (defrecord R [a b]) (:a (map->R {:a 1 :b 2})))"} + {:suite "protocols / records" :label "record? true" :expected "true" :actual "(do (defrecord R [a]) (record? (->R 1)))"} + {:suite "protocols / records" :label "assoc on record" :expected "9" :actual "(do (defrecord R [a]) (:a (assoc (->R 1) :a 9)))"} + {:suite "protocols / reify & satisfies" :label "reify dispatch" :expected "42" :actual "(do (defprotocol P (m [_])) (m (reify P (m [_] 42))))"} + {:suite "protocols / reify & satisfies" :label "reify multi-method" :expected "[1 2]" :actual "(do (defprotocol P (a [_]) (b [_])) (let [r (reify P (a [_] 1) (b [_] 2))] [(a r) (b r)]))"} + {:suite "protocols / reify & satisfies" :label "satisfies? true" :expected "true" :actual "(do (defprotocol P (m [_])) (defrecord R [] P (m [_] 1)) (satisfies? P (->R)))"} + {:suite "protocols / reify & satisfies" :label "satisfies? false" :expected "false" :actual "(do (defprotocol P (m [_])) (defrecord R []) (satisfies? P (->R)))"} + {:suite "protocols / reify & satisfies" :label "satisfies? reify" :expected "true" :actual "(do (defprotocol P (m [_])) (satisfies? P (reify P (m [_] 1))))"} + {:suite "protocols / reify & satisfies" :label "satisfies? reify multi-protocol" :expected "[true true]" :actual "(do (defprotocol P (m [_])) (defprotocol Q (n [_])) (let [r (reify P (m [_] 1) Q (n [_] 2))] [(satisfies? P r) (satisfies? Q r)]))"} + {:suite "protocols / reify & satisfies" :label "satisfies? reify other proto" :expected "false" :actual "(do (defprotocol P (m [_])) (defprotocol Q (n [_])) (satisfies? Q (reify P (m [_] 1))))"} + {:suite "protocols / reify & satisfies" :label "instance? record" :expected "true" :actual "(do (defrecord R [a]) (instance? R (->R 1)))"} + {:suite "protocols / reify & satisfies" :label "dot constructor" :expected "5" :actual "(do (deftype P [n]) (.-n (P. 5)))"} + {:suite "protocols / reify & satisfies" :label "dot ctor + method" :expected "5" :actual "(do (defprotocol G (val-of [_])) (deftype P [n] G (val-of [_] n)) (val-of (P. 5)))"} + {:suite "protocols / defprotocol options" :label "docstring + option + method" :expected ":hi" :actual "(do (defprotocol Pdoc \"docs\" :extend-via-metadata true (greet [x])) (extend-protocol Pdoc String (greet [s] :hi)) (greet \"x\"))"} + {:suite "protocols / defprotocol options" :label "option only" :expected "3" :actual "(do (defprotocol Popt :extend-via-metadata true (plus2 [x])) (extend-protocol Popt Long (plus2 [n] (+ n 2))) (plus2 1))"} + {:suite "reader / anonymous fn #()" :label "no args" :expected "3" :actual "(#(+ 1 2))"} + {:suite "reader / anonymous fn #()" :label "one arg %" :expected "6" :actual "(#(* % 2) 3)"} + {:suite "reader / anonymous fn #()" :label "positional %1 %2" :expected "[1 2]" :actual "(#(do [%1 %2]) 1 2)"} + {:suite "reader / anonymous fn #()" :label "rest %&" :expected "[1 2 3]" :actual "(#(do %&) 1 2 3)"} + {:suite "reader / anonymous fn #()" :label "fixed + rest" :expected "[2 3]" :actual "(#(do % %&) 1 2 3)"} + {:suite "reader / anonymous fn #()" :label "%2 + rest" :expected "[3]" :actual "(#(do %2 %&) 1 2 3)"} + {:suite "reader / anonymous fn #()" :label "%2 only (placeholder p1)" :expected "20" :actual "(#(* %2 2) 1 10)"} + {:suite "reader / anonymous fn #()" :label "% and %1 same" :expected "10" :actual "(#(+ % %1) 5)"} + {:suite "reader / var-quote #'" :label "var-quote = var" :expected "true" :actual "(= (var str) #'str)"} + {:suite "reader / var-quote #'" :label "is a var" :expected "true" :actual "(var? #'str)"} + {:suite "reader / var-quote #'" :label "deref var-quote" :expected "5" :actual "(do (def w 5) (deref #'w))"} + {:suite "reader / metadata ^" :label "meta on map" :expected "true" :actual "(:foo (meta ^:foo {}))"} + {:suite "reader / metadata ^" :label "meta on vector" :expected "true" :actual "(:foo (meta ^:foo [1 2]))"} + {:suite "reader / metadata ^" :label "meta on set" :expected "true" :actual "(:foo (meta ^:foo #{}))"} + {:suite "reader / metadata ^" :label "meta map form" :expected "1" :actual "(:a (meta ^{:a 1} {}))"} + {:suite "reader / metadata ^" :label "meta on quoted sym" :expected "true" :actual "(:foo (meta (quote ^:foo bar)))"} + {:suite "reader / metadata ^" :label "with-meta map" :expected "true" :actual "(:k (meta (with-meta {} {:k true})))"} + {:suite "reader / metadata ^" :label "with-meta vector" :expected "true" :actual "(:k (meta (with-meta [] {:k true})))"} + {:suite "reader / metadata ^" :label "non-metadatable num" :expected "nil" :actual "(meta 100)"} + {:suite "reader / metadata ^" :label "non-metadatable str" :expected "nil" :actual "(meta \"\")"} + {:suite "reader / metadata ^" :label "non-metadatable bool" :expected "nil" :actual "(meta true)"} + {:suite "reader / syntax-quote" :label "plain literal" :expected "[1 2 3]" :actual "`[1 2 3]"} + {:suite "reader / syntax-quote" :label "gensym distinct" :expected "true" :actual "(not= `meow# `meow#)"} + {:suite "reader / syntax-quote" :label "gensym stable" :expected "true" :actual "(let [s `[meow# meow#]] (= (first s) (second s)))"} + {:suite "reader / syntax-quote" :label "qualifies unresolved" :expected "(quote user/foo)" :actual "`foo"} + {:suite "reader / syntax-quote" :label "qualifies core sym" :expected "(quote clojure.core/str)" :actual "`str"} + {:suite "reader / syntax-quote" :label "unquote value" :expected "[1 2 3]" :actual "(let [a [1 2 3]] `~a)"} + {:suite "reader / syntax-quote" :label "unquote in call" :expected "(quote (clojure.core/str [1 2 3]))" :actual "(let [a [1 2 3]] `(str ~a))"} + {:suite "reader / syntax-quote" :label "splice empty" :expected "(quote (clojure.core/str))" :actual "(let [e []] `(str ~@e))"} + {:suite "reader / syntax-quote" :label "splice values" :expected "(quote (clojure.core/str 1 2 3))" :actual "(let [a [1 2 3]] `(str ~@a))"} + {:suite "reader / syntax-quote" :label "splice in vector" :expected "[1 2 3 0 1 2 3]" :actual "(let [b [0] a [1 2 3] e []] `[~@e ~@a ~@b ~@a ~@e])"} + {:suite "reader / syntax-quote" :label "splice in set" :expected "#{0 1 3 2}" :actual "(let [b [0] a [1 2 3] e []] `#{~@e ~@a ~@b})"} + {:suite "reader / syntax-quote" :label "unquote in set" :expected "#{9 5}" :actual "(let [x 5] `#{~x 9})"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard simple" :expected "2" :actual "(do #_1 2)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard in vector" :expected "[1 3]" :actual "[1 #_2 3]"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "discard stacks" :expected "3" :actual "(do #_ #_ 1 2 3)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##Inf" :expected "true" :actual "(= ##Inf (/ 1.0 0.0))"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##-Inf" :expected "true" :actual "(= ##-Inf (/ -1.0 0.0))"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##NaN not self-equal" :expected "false" :actual "(= ##NaN ##NaN)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "##NaN is NaN?" :expected "true" :actual "(NaN? ##NaN)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "conditional :default reachable" :expected "2" :actual "#?(:no-such-dialect 1 :default 2)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "var-quote qualified" :expected "true" :actual "(= (var clojure.core/str) #'clojure.core/str)"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "gensym stable in template" :expected "true" :actual "(let [syms `[meow# meow#]] (= (first syms) (second syms)))"} + {:suite "reader / discard, symbolic values, conditionals (spec 2.3)" :label "gensym fresh across templates" :expected "false" :actual "(= `meow# `meow#)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string once" :expected "true" :actual "(= \"meow\" `\"meow\")"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string nested" :expected "true" :actual "(= \"meow\" ``\"meow\")"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "string triple" :expected "true" :actual "(= \"meow\" ```\"meow\")"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "number nested" :expected "true" :actual "(= 42 ``42)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "keyword nested" :expected "true" :actual "(= :k ``:k)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "nil nested" :expected "false" :actual "(nil? ``nil)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "char nested" :expected "true" :actual "(= \\a ``\\a)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "bool nested" :expected "false" :actual "(= true ``true)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "symbol still qualifies" :expected "true" :actual "(= (quote clojure.core/map) `map)"} + {:suite "reader / syntax-quote literal collapse (spec 2.4 S25)" :label "vector still templates" :expected "true" :actual "(= [1 2] `[1 ~(inc 1)])"} + {:suite "reader / scalar literals" :label "integer" :expected "42" :actual "42"} + {:suite "reader / scalar literals" :label "negative" :expected "-7" :actual "-7"} + {:suite "reader / scalar literals" :label "float" :expected "1.5" :actual "1.5"} + {:suite "reader / scalar literals" :label "string" :expected "\"hi\"" :actual "\"hi\""} + {:suite "reader / scalar literals" :label "boolean true" :expected "true" :actual "true"} + {:suite "reader / scalar literals" :label "nil" :expected "nil" :actual "nil"} + {:suite "reader / scalar literals" :label "keyword" :expected ":a" :actual ":a"} + {:suite "reader / scalar literals" :label "namespaced keyword" :expected "true" :actual "(= :a/b :a/b)"} + {:suite "reader / scalar literals" :label "char" :expected "\\a" :actual "\\a"} + {:suite "reader / scalar literals" :label "char newline" :expected "true" :actual "(= \\newline (first \"\\n\"))"} + {:suite "reader / scalar literals" :label "char open-brace" :expected "123" :actual "(int \\{)"} + {:suite "reader / scalar literals" :label "char open-paren" :expected "40" :actual "(int \\()"} + {:suite "reader / scalar literals" :label "char comma" :expected "44" :actual "(int \\,)"} + {:suite "reader / scalar literals" :label "char percent" :expected "37" :actual "(int \\%)"} + {:suite "reader / scalar literals" :label "char unicode" :expected "65" :actual "(int \\u0041)"} + {:suite "reader / scalar literals" :label "hex literal" :expected "255" :actual "0xff"} + {:suite "reader / scalar literals" :label "hex uppercase" :expected "31" :actual "0X1F"} + {:suite "reader / scalar literals" :label "bigint suffix N" :expected "42N" :actual "42N"} + {:suite "reader / scalar literals" :label "bigdec suffix M" :expected "1.5M" :actual "1.5M"} + {:suite "reader / scalar literals" :label "ratio -> double" :expected "3/4" :actual "3/4"} + {:suite "reader / scalar literals" :label "radix integer" :expected "255" :actual "16rFF"} + {:suite "reader / scalar literals" :label "exponent" :expected "1500.0" :actual "1.5e3"} + {:suite "reader / scalar literals" :label "symbolic Infinity" :expected "true" :actual "(infinite? ##Inf)"} + {:suite "reader / scalar literals" :label "symbolic NaN" :expected "true" :actual "(NaN? ##NaN)"} + {:suite "reader / scalar literals" :label "symbol via quote" :expected "'foo" :actual "'foo"} + {:suite "reader / collection literals" :label "vector" :expected "[1 2 3]" :actual "[1 2 3]"} + {:suite "reader / collection literals" :label "list quoted" :expected "[1 2 3]" :actual "'(1 2 3)"} + {:suite "reader / collection literals" :label "map" :expected "{:a 1}" :actual "{:a 1}"} + {:suite "reader / collection literals" :label "set" :expected "#{1 3 2}" :actual "#{1 2 3}"} + {:suite "reader / collection literals" :label "nested" :expected "{:a [1 {:b 2}]}" :actual "{:a [1 {:b 2}]}"} + {:suite "reader / collection literals" :label "empty vector" :expected "[]" :actual "[]"} + {:suite "reader / collection literals" :label "empty map" :expected "{}" :actual "{}"} + {:suite "reader / collection literals" :label "empty set" :expected "#{}" :actual "#{}"} + {:suite "reader / dispatch & sugar" :label "anon fn #()" :expected "3" :actual "(#(+ %1 %2) 1 2)"} + {:suite "reader / dispatch & sugar" :label "anon fn single %" :expected "2" :actual "(#(inc %) 1)"} + {:suite "reader / dispatch & sugar" :label "anon fn %&" :expected "[2 3]" :actual "(#(vec %&) 2 3)"} + {:suite "reader / dispatch & sugar" :label "discard #_" :expected "[1 3]" :actual "[1 #_2 3]"} + {:suite "reader / dispatch & sugar" :label "regex literal" :expected "true" :actual "(= \"abc\" (re-find #\"abc\" \"xabcx\"))"} + {:suite "reader / dispatch & sugar" :label "reader conditional" :expected "1" :actual "#?(:clj 1 :cljs 2 :default 3)"} + {:suite "reader / dispatch & sugar" :label "reader cond :jolt" :expected "1" :actual "#?(:clj 1 :jolt 4 :default 3)"} + {:suite "reader / dispatch & sugar" :label "reader cond clause order" :expected "5" :actual "#?(:default 5 :jolt 6)"} + {:suite "reader / dispatch & sugar" :label "reader cond no match" :expected "[1]" :actual "[#?(:clj 1 :cljs 2)]"} + {:suite "reader / dispatch & sugar" :label "reader cond splice" :expected "[]" :actual "[#?@(:jolt [1 2 3] :cljs [4 5])]"} + {:suite "reader / dispatch & sugar" :label "reader cond splice no match" :expected "[1 2 3]" :actual "[#?@(:clj [1 2 3] :cljs [4 5])]"} + {:suite "reader / dispatch & sugar" :label "inst literal reads" :expected "true" :actual "(some? #inst \"2020-01-01T00:00:00Z\")"} + {:suite "reader / dispatch & sugar" :label "uuid literal" :expected "\"550e8400-e29b-41d4-a716-446655440000\"" :actual "(str #uuid \"550e8400-e29b-41d4-a716-446655440000\")"} + {:suite "reader / dispatch & sugar" :label "tagged literal var" :expected "true" :actual "(var? #'+)"} + {:suite "reader / dispatch & sugar" :label "deref sugar" :expected "5" :actual "(let [a (atom 5)] @a)"} + {:suite "reader / dispatch & sugar" :label "meta sugar" :expected "{:t 1}" :actual "(meta ^{:t 1} [])"} + {:suite "reader / comments inside maps" :label "comment in value slot" :expected "{:a 1}" :actual "{:a ; note\n 1}"} + {:suite "reader / comments inside maps" :label "comment before key" :expected "{:a 1}" :actual "{; lead\n :a 1}"} + {:suite "reader / comments inside maps" :label "comment between entries" :expected "{:a 1, :b 2}" :actual "{:a 1 ; mid\n :b 2}"} + {:suite "reader / comments inside maps" :label "discard in value slot" :expected "{:a 1}" :actual "{:a #_9 1}"} + {:suite "reader / comments inside maps" :label "comment with parens" :expected "{:a {:b 1}}" :actual "{:a ; dev (REPL, etc)\n {:b 1}}"} + {:suite "reader / comments inside maps" :label "nested with comments" :expected "{:x {:y 2}}" :actual "{:x ; outer\n {:y ; inner\n 2}}"} + {:suite "regex / literals & predicate" :label "regex? literal" :expected "true" :actual "(regex? #\"\\d+\")"} + {:suite "regex / literals & predicate" :label "regex? non-regex" :expected "false" :actual "(regex? \"\\d+\")"} + {:suite "regex / literals & predicate" :label "escaped digits" :expected "\"42\"" :actual "(re-find #\"\\d+\" \"x42y\")"} + {:suite "regex / literals & predicate" :label "escaped ws/non-ws" :expected "\"x a\"" :actual "(re-find #\"\\S\\s\\S\" \"x a b y\")"} + {:suite "regex / re-find" :label "match" :expected "\"123\"" :actual "(re-find #\"\\d+\" \"abc123def\")"} + {:suite "regex / re-find" :label "no match nil" :expected "nil" :actual "(re-find #\"\\d+\" \"abc\")"} + {:suite "regex / re-find" :label "with groups" :expected "[\"a1\" \"a\" \"1\"]" :actual "(re-find #\"([a-z])(\\d)\" \"--a1--\")"} + {:suite "regex / re-find" :label "first match only" :expected "\"1\"" :actual "(re-find #\"\\d\" \"1 2 3\")"} + {:suite "regex / re-matches" :label "full match" :expected "\"123\"" :actual "(re-matches #\"\\d+\" \"123\")"} + {:suite "regex / re-matches" :label "partial = nil" :expected "nil" :actual "(re-matches #\"\\d+\" \"123abc\")"} + {:suite "regex / re-matches" :label "groups" :expected "[\"12\" \"1\" \"2\"]" :actual "(re-matches #\"(\\d)(\\d)\" \"12\")"} + {:suite "regex / re-matches" :label "no match nil" :expected "nil" :actual "(re-matches #\"x+\" \"yyy\")"} + {:suite "regex / re-seq" :label "all matches" :expected "[\"1\" \"22\" \"333\"]" :actual "(re-seq #\"\\d+\" \"a1b22c333\")"} + {:suite "regex / re-seq" :label "empty when none" :expected "nil" :actual "(seq (re-seq #\"z\" \"abc\"))"} + {:suite "regex / re-seq" :label "words" :expected "[\"foo\" \"bar\"]" :actual "(re-seq #\"\\w+\" \"foo bar\")"} + {:suite "regex / re-pattern & string ops" :label "re-pattern build" :expected "\"hi\"" :actual "(re-find (re-pattern \"\\\\w+\") \"hi!\")"} + {:suite "regex / re-pattern & string ops" :label "re-pattern is regex?" :expected "true" :actual "(regex? (re-pattern \"a\"))"} + {:suite "regex / re-pattern & string ops" :label "split on regex" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require '[clojure.string :as s]) (s/split \"a1b2c\" #\"\\d\"))"} + {:suite "regex / re-pattern & string ops" :label "replace regex" :expected "\"X-X\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"a-b\" #\"[a-z]\" \"X\"))"} + {:suite "regex / re-pattern & string ops" :label "replace $1" :expected "\"[a][b]\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"ab\" #\"([a-z])\" \"[$1]\"))"} + {:suite "regex / \\p property classes" :label "p{L} ascii" :expected "\"hello\"" :actual "(re-matches #\"^\\p{L}+$\" \"hello\")"} + {:suite "regex / \\p property classes" :label "p{L} utf-8" :expected "true" :actual "(boolean (re-matches #\"^\\p{L}+$\" \"héllo\"))"} + {:suite "regex / \\p property classes" :label "p{L} rejects digits" :expected "false" :actual "(boolean (re-matches #\"^\\p{L}+$\" \"ab1\"))"} + {:suite "regex / \\p property classes" :label "p{N}" :expected "[\"12\" \"345\"]" :actual "(re-seq #\"\\p{N}+\" \"a12b345\")"} + {:suite "regex / \\p property classes" :label "P{N} negation" :expected "\"abc\"" :actual "(re-matches #\"^\\P{N}+$\" \"abc\")"} + {:suite "regex / \\p property classes" :label "inside class" :expected "\"a-1_b\"" :actual "(re-matches #\"^[\\p{N}\\p{L}_-]+$\" \"a-1_b\")"} + {:suite "regex / \\p property classes" :label "p{Lu}/p{Ll}" :expected "\"aB\"" :actual "(re-matches #\"^\\p{Ll}\\p{Lu}$\" \"aB\")"} + {:suite "regex / \\p property classes" :label "p{Z} space" :expected "\" \"" :actual "(re-matches #\"(?u)^[\\s\\p{Z}]+$\" \" \")"} + {:suite "regex / \\p property classes" :label "p{Ps}/p{Pe}" :expected "\"(x)\"" :actual "(re-matches #\"^\\p{Ps}x\\p{Pe}$\" \"(x)\")"} + {:suite "regex / \\p property classes" :label "(?u) accepted" :expected "\"hi\"" :actual "(re-matches #\"(?u)^hi$\" \"hi\")"} + {:suite "regex / \\p property classes" :label "unknown class throws" :expected :throws :actual "(re-pattern \"\\p{Greek}\")"} + {:suite "regex / Pattern statics & String regex methods" :label "Pattern/compile is a regex" :expected "true" :actual "(regex? (Pattern/compile \"a.c\"))"} + {:suite "regex / Pattern statics & String regex methods" :label "compiled .split" :expected "[\"a\" \"b\" \"c\"]" :actual "(.split (Pattern/compile \",\") \"a,b,c\")"} + {:suite "regex / Pattern statics & String regex methods" :label "str/replace w/ Pattern" :expected "\"ab\"" :actual "(do (require '[clojure.string :as s]) (s/replace \"a1b2\" (Pattern/compile \"[0-9]\") \"\"))"} + {:suite "regex / Pattern statics & String regex methods" :label "Pattern/MULTILINE ^" :expected "true" :actual "(boolean (re-find (Pattern/compile \"^x\" Pattern/MULTILINE) \"y\\nx\"))"} + {:suite "regex / Pattern statics & String regex methods" :label "Pattern/quote literal" :expected "true" :actual "(boolean (re-find (re-pattern (Pattern/quote \"a.c\")) \"za.cy\"))"} + {:suite "regex / Pattern statics & String regex methods" :label "Pattern/quote not meta" :expected "false" :actual "(boolean (re-find (re-pattern (Pattern/quote \"a.c\")) \"zabcy\"))"} + {:suite "regex / Pattern statics & String regex methods" :label ".matches whole string" :expected "true" :actual "(.matches \"abc\" \"a.c\")"} + {:suite "regex / Pattern statics & String regex methods" :label ".matches partial -> false" :expected "false" :actual "(.matches \"abcd\" \"a.c\")"} + {:suite "regex / Pattern statics & String regex methods" :label ".replaceAll regex" :expected "\"a-b-c\"" :actual "(.replaceAll \"a_b_c\" \"_\" \"-\")"} + {:suite "regex / Pattern statics & String regex methods" :label ".replaceFirst regex" :expected "\"a-b_c\"" :actual "(.replaceFirst \"a_b_c\" \"_\" \"-\")"} + {:suite "regex / bounded quantifiers" :label "exact {n}" :expected "\"aaa\"" :actual "(re-matches #\"a{3}\" \"aaa\")"} + {:suite "regex / bounded quantifiers" :label "range {n,m} max" :expected "\"aaaa\"" :actual "(re-find #\"a{2,4}\" \"aaaaa\")"} + {:suite "regex / bounded quantifiers" :label "zero lower {0,n}" :expected "\"aa\"" :actual "(re-find #\"a{0,3}\" \"aa\")"} + {:suite "regex / bounded quantifiers" :label "{n,} unbounded" :expected "\"aaaa\"" :actual "(re-find #\"a{2,}\" \"aaaa\")"} + {:suite "regex / bounded quantifiers" :label "nested bounds compile" :expected "true" :actual "(boolean (re-matches #\"[a-z](?:[a-z]{0,61}[a-z])?(?:-[a-z]{0,61}[a-z])*\" \"abc-def\"))"} + {:suite "regex / backreferences" :label "repeated char" :expected "true" :actual "(boolean (re-find #\"(.)\\1\" \"abba\"))"} + {:suite "regex / backreferences" :label "no repeat = nil" :expected "nil" :actual "(re-find #\"(.)\\1\" \"abc\")"} + {:suite "regex / backreferences" :label "thematic-break run" :expected "true" :actual "(boolean (re-matches #\"([-*_])\\1\\1\" \"---\"))"} + {:suite "regex / backreferences" :label "mismatched run" :expected "nil" :actual "(re-matches #\"([-*_])\\1\\1\" \"-*_\")"} + {:suite "regex / backreferences" :label "repeated word" :expected "[\"the the\" \"the\"]" :actual "(re-find #\"(\\w+) \\1\" \"say the the word\")"} + {:suite "regex / backreferences" :label "group still captures" :expected "[\"x=x\" \"x\"]" :actual "(re-matches #\"(\\w+)=\\1\" \"x=x\")"} + {:suite "regex / backreferences" :label "html tag pair" :expected "true" :actual "(boolean (re-matches #\"<(\\w+)>.*\" \"hi\"))"} + {:suite "seq / access" :label "first of vector" :expected "1" :actual "(first [1 2 3])"} + {:suite "seq / access" :label "first of list" :expected "1" :actual "(first (list 1 2 3))"} + {:suite "seq / access" :label "first of empty is nil" :expected "nil" :actual "(first [])"} + {:suite "seq / access" :label "first of nil is nil" :expected "nil" :actual "(first nil)"} + {:suite "seq / access" :label "second" :expected "2" :actual "(second [1 2 3])"} + {:suite "seq / access" :label "last" :expected "3" :actual "(last [1 2 3])"} + {:suite "seq / access" :label "rest of vector" :expected "[2 3]" :actual "(rest [1 2 3])"} + {:suite "seq / access" :label "rest of single" :expected "[]" :actual "(rest [1])"} + {:suite "seq / access" :label "rest of empty" :expected "[]" :actual "(rest [])"} + {:suite "seq / access" :label "next of single is nil" :expected "nil" :actual "(next [1])"} + {:suite "seq / access" :label "next of empty is nil" :expected "nil" :actual "(next [])"} + {:suite "seq / access" :label "nth" :expected "30" :actual "(nth [10 20 30] 2)"} + {:suite "seq / access" :label "nth with default" :expected "99" :actual "(nth [10] 5 99)"} + {:suite "seq / access" :label "nth out of range" :expected :throws :actual "(nth [10] 5)"} + {:suite "seq / access" :label "ffirst" :expected "1" :actual "(ffirst [[1 2] [3 4]])"} + {:suite "seq / access" :label "fnext" :expected "2" :actual "(fnext [1 2 3])"} + {:suite "seq / access" :label "nnext" :expected "[3 4]" :actual "(nnext [1 2 3 4])"} + {:suite "seq / construction" :label "cons onto list" :expected "[0 1 2]" :actual "(cons 0 (list 1 2))"} + {:suite "seq / construction" :label "cons onto vector" :expected "[0 1 2]" :actual "(cons 0 [1 2])"} + {:suite "seq / construction" :label "cons onto nil" :expected "[0]" :actual "(cons 0 nil)"} + {:suite "seq / construction" :label "conj vector appends" :expected "[1 2 3]" :actual "(conj [1 2] 3)"} + {:suite "seq / construction" :label "conj list prepends" :expected "[0 1 2]" :actual "(conj (list 1 2) 0)"} + {:suite "seq / construction" :label "conj multiple on vec" :expected "[1 2 3 4]" :actual "(conj [1 2] 3 4)"} + {:suite "seq / construction" :label "conj multiple on list" :expected "[4 3 1 2]" :actual "(conj (list 1 2) 3 4)"} + {:suite "seq / construction" :label "seq of empty is nil" :expected "nil" :actual "(seq [])"} + {:suite "seq / construction" :label "seq of nil is nil" :expected "nil" :actual "(seq nil)"} + {:suite "seq / construction" :label "seq of string" :expected "[\\a \\b]" :actual "(seq \"ab\")"} + {:suite "seq / construction" :label "empty?" :expected "true" :actual "(empty? [])"} + {:suite "seq / construction" :label "not empty?" :expected "false" :actual "(empty? [1])"} + {:suite "seq / construction" :label "count" :expected "3" :actual "(count [1 2 3])"} + {:suite "seq / construction" :label "count of nil" :expected "0" :actual "(count nil)"} + {:suite "seq / construction" :label "count of string" :expected "3" :actual "(count \"abc\")"} + {:suite "seq / map filter reduce" :label "map" :expected "[2 3 4]" :actual "(map inc [1 2 3])"} + {:suite "seq / map filter reduce" :label "map two colls" :expected "[5 7 9]" :actual "(map + [1 2 3] [4 5 6])"} + {:suite "seq / map filter reduce" :label "map stops at shortest" :expected "[5 7]" :actual "(map + [1 2] [4 5 6])"} + {:suite "seq / map filter reduce" :label "map keeps nil elements" :expected "[[1 :a] [nil :b] [3 nil]]" :actual "(map vector [1 nil 3] [:a :b nil])"} + {:suite "seq / map filter reduce" :label "map 3 colls" :expected "[12 15 18]" :actual "(map + [1 2 3] [4 5 6] [7 8 9])"} + {:suite "seq / map filter reduce" :label "map 3 colls shortest" :expected "[12 15]" :actual "(map + [1 2] [4 5 6] [7 8 9])"} + {:suite "seq / map filter reduce" :label "map 4 colls" :expected "[16 20]" :actual "(map + [1 2] [3 4] [5 6] [7 8])"} + {:suite "seq / map filter reduce" :label "map 3 colls nils" :expected "[[1 :a 10] [nil :b 20] [3 nil 30]]" :actual "(map vector [1 nil 3] [:a :b nil] [10 20 30])"} + {:suite "seq / map filter reduce" :label "map empty coll" :expected "[]" :actual "(map + [] [1 2 3] [4 5 6])"} + {:suite "seq / map filter reduce" :label "map lazy+concrete" :expected "[11 22 33]" :actual "(map + (map identity [1 2 3]) [10 20 30])"} + {:suite "seq / map filter reduce" :label "map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(map-indexed vector [:a :b])"} + {:suite "seq / map filter reduce" :label "mapv" :expected "[2 3 4]" :actual "(mapv inc [1 2 3])"} + {:suite "seq / map filter reduce" :label "filter" :expected "[2 4]" :actual "(filter even? [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "filterv" :expected "[2 4]" :actual "(filterv even? [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "remove" :expected "[1 3]" :actual "(remove even? [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "reduce" :expected "10" :actual "(reduce + [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "reduce with init" :expected "20" :actual "(reduce + 10 [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "reduce empty with init" :expected "0" :actual "(reduce + 0 [])"} + {:suite "seq / map filter reduce" :label "reduce single no init" :expected "5" :actual "(reduce + [5])"} + {:suite "seq / map filter reduce" :label "reduced short-circuits" :expected "3" :actual "(reduce (fn [a x] (if (> a 2) (reduced a) (+ a x))) 0 [1 2 3 4 5])"} + {:suite "seq / map filter reduce" :label "reduce-kv" :expected "6" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 {:a 1 :b 2 :c 3})"} + {:suite "seq / map filter reduce" :label "reduce-kv on vector" :expected "[[0 :a] [1 :b]]" :actual "(reduce-kv (fn [a i v] (conj a [i v])) [] [:a :b])"} + {:suite "seq / map filter reduce" :label "reduce-kv honors reduced" :expected "[:a]" :actual "(reduce-kv (fn [a i v] (if (= i 1) (reduced a) (conj a v))) [] [:a :b :c])"} + {:suite "seq / map filter reduce" :label "reduce-kv on nil" :expected "0" :actual "(reduce-kv (fn [a k v] (+ a v)) 0 nil)"} + {:suite "seq / map filter reduce" :label "reductions" :expected "[1 3 6]" :actual "(reductions + [1 2 3])"} + {:suite "seq / map filter reduce" :label "mapcat" :expected "[1 1 2 2]" :actual "(mapcat (fn [x] [x x]) [1 2])"} + {:suite "seq / map filter reduce" :label "mapcat two colls" :expected "[1 3 2 4]" :actual "(mapcat vector [1 2] [3 4])"} + {:suite "seq / map filter reduce" :label "mapcat three colls" :expected "[1 2 3]" :actual "(mapcat vector [1] [2] [3])"} + {:suite "seq / map filter reduce" :label "mapcat empty coll" :expected "[]" :actual "(mapcat vector [] [1 2] [3 4])"} + {:suite "seq / map filter reduce" :label "mapcat seqs" :expected "[1 2 3 4]" :actual "(mapcat identity [[1 2] [3 4]])"} + {:suite "seq / map filter reduce" :label "keep" :expected "[1 3]" :actual "(keep (fn [x] (if (odd? x) x nil)) [1 2 3 4])"} + {:suite "seq / map filter reduce" :label "some truthy" :expected "true" :actual "(some even? [1 2 3])"} + {:suite "seq / map filter reduce" :label "some nil" :expected "nil" :actual "(some even? [1 3 5])"} + {:suite "seq / map filter reduce" :label "every? true" :expected "true" :actual "(every? pos? [1 2 3])"} + {:suite "seq / map filter reduce" :label "every? false" :expected "false" :actual "(every? pos? [1 -2 3])"} + {:suite "seq / take drop slice" :label "take" :expected "[1 2 3]" :actual "(take 3 [1 2 3 4 5])"} + {:suite "seq / take drop slice" :label "take more than size" :expected "[1 2]" :actual "(take 5 [1 2])"} + {:suite "seq / take drop slice" :label "drop" :expected "[4 5]" :actual "(drop 3 [1 2 3 4 5])"} + {:suite "seq / take drop slice" :label "take-while" :expected "[1 2]" :actual "(take-while (fn [x] (< x 3)) [1 2 3 1])"} + {:suite "seq / take drop slice" :label "drop-while" :expected "[3 1]" :actual "(drop-while (fn [x] (< x 3)) [1 2 3 1])"} + {:suite "seq / take drop slice" :label "take-last" :expected "[4 5]" :actual "(take-last 2 [1 2 3 4 5])"} + {:suite "seq / take drop slice" :label "drop-last" :expected "[1 2 3]" :actual "(drop-last [1 2 3 4])"} + {:suite "seq / take drop slice" :label "take-nth" :expected "[1 3 5]" :actual "(take-nth 2 [1 2 3 4 5])"} + {:suite "seq / take drop slice" :label "partition" :expected "[[1 2] [3 4]]" :actual "(partition 2 [1 2 3 4 5])"} + {:suite "seq / take drop slice" :label "partition-all" :expected "[[1 2] [3]]" :actual "(partition-all 2 [1 2 3])"} + {:suite "seq / take drop slice" :label "split-at" :expected "[[1 2] [3 4]]" :actual "(split-at 2 [1 2 3 4])"} + {:suite "seq / transform" :label "reverse" :expected "[3 2 1]" :actual "(reverse [1 2 3])"} + {:suite "seq / transform" :label "sort" :expected "[1 2 3]" :actual "(sort [3 1 2])"} + {:suite "seq / transform" :label "sort with comparator" :expected "[3 2 1]" :actual "(sort > [1 3 2])"} + {:suite "seq / transform" :label "sort-by" :expected "[[1] [2 2]]" :actual "(sort-by count [[2 2] [1]])"} + {:suite "seq / transform" :label "distinct" :expected "[1 2 3]" :actual "(distinct [1 1 2 3 3])"} + {:suite "seq / transform" :label "dedupe" :expected "[1 2 1]" :actual "(dedupe [1 1 2 1])"} + {:suite "seq / transform" :label "interpose" :expected "[1 0 2 0 3]" :actual "(interpose 0 [1 2 3])"} + {:suite "seq / transform" :label "interleave" :expected "[1 :a 2 :b]" :actual "(interleave [1 2] [:a :b])"} + {:suite "seq / transform" :label "flatten" :expected "[1 2 3 4]" :actual "(flatten [1 [2 [3 [4]]]])"} + {:suite "seq / transform" :label "concat" :expected "[1 2 3 4]" :actual "(concat [1 2] [3 4])"} + {:suite "seq / transform" :label "into vector" :expected "[1 2 3 4]" :actual "(into [1 2] [3 4])"} + {:suite "seq / transform" :label "into list" :expected "[3 2 1]" :actual "(into (list) [1 2 3])"} + {:suite "seq / transform" :label "frequencies" :expected "{1 2, 2 1}" :actual "(frequencies [1 1 2])"} + {:suite "seq / transform" :label "group-by" :expected "{false [1 3], true [2 4]}" :actual "(group-by even? [1 2 3 4])"} + {:suite "seq / transform" :label "zipmap" :expected "{:a 1, :b 2}" :actual "(zipmap [:a :b] [1 2])"} + {:suite "seq / transform" :label "mapcat seqs" :expected "[1 2 3 4]" :actual "(mapcat identity [[1 2] [3 4]])"} + {:suite "seq / generators" :label "range n" :expected "[0 1 2 3]" :actual "(range 4)"} + {:suite "seq / generators" :label "range from to" :expected "[2 3 4]" :actual "(range 2 5)"} + {:suite "seq / generators" :label "range with step" :expected "[0 2 4]" :actual "(range 0 6 2)"} + {:suite "seq / generators" :label "take repeat" :expected "[:x :x :x]" :actual "(take 3 (repeat :x))"} + {:suite "seq / generators" :label "repeat n" :expected "[5 5]" :actual "(repeat 2 5)"} + {:suite "seq / generators" :label "take iterate" :expected "[1 2 4 8]" :actual "(take 4 (iterate (fn [x] (* x 2)) 1))"} + {:suite "seq / generators" :label "take cycle" :expected "[1 2 1 2 1]" :actual "(take 5 (cycle [1 2]))"} + {:suite "seq / generators" :label "take repeatedly" :expected "3" :actual "(count (take 3 (repeatedly (fn [] 1))))"} + {:suite "seq / generators" :label "take-last of range" :expected "[8 9]" :actual "(take-last 2 (range 10))"} + {:suite "seq / IFn values as functions" :label "map keyword" :expected "[1 2 3]" :actual "(map :a [{:a 1} {:a 2} {:a 3}])"} + {:suite "seq / IFn values as functions" :label "filter keyword" :expected "[{:ok true}]" :actual "(filter :ok [{:ok true} {:ok false}])"} + {:suite "seq / IFn values as functions" :label "remove keyword" :expected "[{:ok false}]" :actual "(remove :ok [{:ok true} {:ok false}])"} + {:suite "seq / IFn values as functions" :label "sort-by keyword" :expected "[{:a 1} {:a 2} {:a 3}]" :actual "(sort-by :a [{:a 3} {:a 1} {:a 2}])"} + {:suite "seq / IFn values as functions" :label "sort-by key + cmp" :expected "[{:a 3} {:a 2} {:a 1}]" :actual "(sort-by :a > [{:a 3} {:a 1} {:a 2}])"} + {:suite "seq / IFn values as functions" :label "filter set" :expected "[2 4]" :actual "(filter #{2 4} [1 2 3 4 5])"} + {:suite "seq / IFn values as functions" :label "remove set" :expected "[1 3 5]" :actual "(remove #{2 4} [1 2 3 4 5])"} + {:suite "seq / IFn values as functions" :label "group-by keyword" :expected "{1 [{:n 1}], 2 [{:n 2}]}" :actual "(group-by :n [{:n 1} {:n 2}])"} + {:suite "seq / IFn values as functions" :label "map a map" :expected "[1 nil 2]" :actual "(map {:a 1 :b 2} [:a :z :b])"} + {:suite "seq / IFn values as functions" :label "take-nth transducer" :expected "[0 2 4 6 8]" :actual "(into [] (take-nth 2) (range 10))"} + {:suite "seq / IFn values as functions" :label "interpose transducer" :expected "[1 :x 2]" :actual "(into [] (interpose :x) [1 2])"} + {:suite "seq / conj edge cases" :label "conj no args" :expected "[]" :actual "(conj)"} + {:suite "seq / conj edge cases" :label "conj nil one" :expected "[3]" :actual "(conj nil 3)"} + {:suite "seq / conj edge cases" :label "conj nil many" :expected "[2 1]" :actual "(conj nil 1 2)"} + {:suite "seq / conj edge cases" :label "conj vector" :expected "[1 2 3]" :actual "(conj [1 2] 3)"} + {:suite "seq / conj edge cases" :label "conj list prepend" :expected "[0 1 2]" :actual "(conj '(1 2) 0)"} + {:suite "seq / conj edge cases" :label "conj map + map" :expected "{:a 0, :b 1}" :actual "(conj {:a 0} {:b 1})"} + {:suite "seq / conj edge cases" :label "conj map + pair" :expected "{:a 0, :b 1}" :actual "(conj {:a 0} [:b 1])"} + {:suite "seq / conj edge cases" :label "conj map merge wins" :expected "{:a 2}" :actual "(conj {:a 0} {:a 1} {:a 2})"} + {:suite "seq / strictness (throws like Clojure)" :label "cons non-seqable num" :expected :throws :actual "(cons 1 42)"} + {:suite "seq / strictness (throws like Clojure)" :label "cons non-seqable kw" :expected :throws :actual "(cons 1 :k)"} + {:suite "seq / strictness (throws like Clojure)" :label "cons onto nil ok" :expected "[1]" :actual "(cons 1 nil)"} + {:suite "seq / strictness (throws like Clojure)" :label "cons onto seq ok" :expected "[0 1 2]" :actual "(cons 0 [1 2])"} + {:suite "seq / strictness (throws like Clojure)" :label "num non-number" :expected :throws :actual "(num \"x\")"} + {:suite "seq / strictness (throws like Clojure)" :label "num ok" :expected "5" :actual "(num 5)"} + {:suite "seq / strictness (throws like Clojure)" :label "realized? on number" :expected :throws :actual "(realized? 1)"} + {:suite "seq / strictness (throws like Clojure)" :label "realized? on nil" :expected :throws :actual "(realized? nil)"} + {:suite "seq / strictness (throws like Clojure)" :label "symbol from nil" :expected :throws :actual "(symbol nil)"} + {:suite "seq / strictness (throws like Clojure)" :label "symbol bad 2-arg" :expected :throws :actual "(symbol :a \"b\")"} + {:suite "seq / strictness (throws like Clojure)" :label "symbol from keyword" :expected "\"x\"" :actual "(name (symbol :x))"} + {:suite "seq / strictness (throws like Clojure)" :label "keyword bad 2-arg" :expected :throws :actual "(keyword \"abc\" nil)"} + {:suite "seq / strictness (throws like Clojure)" :label "keyword from symbol" :expected "\"x\"" :actual "(name (keyword 'x))"} + {:suite "seq / accessor strictness" :label "peek vector" :expected "3" :actual "(peek [1 2 3])"} + {:suite "seq / accessor strictness" :label "peek list" :expected "1" :actual "(peek '(1 2 3))"} + {:suite "seq / accessor strictness" :label "peek empty vec" :expected "nil" :actual "(peek [])"} + {:suite "seq / accessor strictness" :label "peek on set" :expected :throws :actual "(peek #{1 2})"} + {:suite "seq / accessor strictness" :label "peek on number" :expected :throws :actual "(peek 42)"} + {:suite "seq / accessor strictness" :label "pop empty vec" :expected :throws :actual "(pop [])"} + {:suite "seq / accessor strictness" :label "pop on number" :expected :throws :actual "(pop 0)"} + {:suite "seq / accessor strictness" :label "pop vector" :expected "[1 2]" :actual "(pop [1 2 3])"} + {:suite "seq / accessor strictness" :label "vec on number" :expected :throws :actual "(vec 42)"} + {:suite "seq / accessor strictness" :label "vec on keyword" :expected :throws :actual "(vec :a)"} + {:suite "seq / accessor strictness" :label "vec ok" :expected "[1 2]" :actual "(vec '(1 2))"} + {:suite "seq / accessor strictness" :label "key on nil" :expected :throws :actual "(key nil)"} + {:suite "seq / accessor strictness" :label "key on map" :expected :throws :actual "(key {})"} + {:suite "seq / accessor strictness" :label "val on number" :expected :throws :actual "(val 0)"} + {:suite "seq / accessor strictness" :label "key of entry" :expected ":a" :actual "(key (first {:a 1}))"} + {:suite "seq / accessor strictness" :label "val of entry" :expected "1" :actual "(val (first {:a 1}))"} + {:suite "seq / more strictness" :label "first on number" :expected :throws :actual "(first 42)"} + {:suite "seq / more strictness" :label "first on keyword" :expected :throws :actual "(first :a)"} + {:suite "seq / more strictness" :label "first ok vec" :expected "1" :actual "(first [1 2])"} + {:suite "seq / more strictness" :label "first ok nil" :expected "nil" :actual "(first nil)"} + {:suite "seq / more strictness" :label "rseq vector" :expected "[3 2 1]" :actual "(rseq [1 2 3])"} + {:suite "seq / more strictness" :label "rseq on string" :expected :throws :actual "(rseq \"ab\")"} + {:suite "seq / more strictness" :label "rseq on map" :expected :throws :actual "(rseq {:a 1})"} + {:suite "seq / more strictness" :label "rseq on number" :expected :throws :actual "(rseq 0)"} + {:suite "seq / more strictness" :label "assoc odd args" :expected :throws :actual "(assoc {:a 1} :b)"} + {:suite "seq / more strictness" :label "assoc on number" :expected :throws :actual "(assoc 5 :a 1)"} + {:suite "seq / more strictness" :label "assoc on set" :expected :throws :actual "(assoc #{} :a 1)"} + {:suite "seq / strictness round 3" :label "seq on number" :expected :throws :actual "(seq 1)"} + {:suite "seq / strictness round 3" :label "seq on fn" :expected :throws :actual "(seq (fn [] 1))"} + {:suite "seq / strictness round 3" :label "seq vector ok" :expected "[1 2]" :actual "(seq [1 2])"} + {:suite "seq / strictness round 3" :label "NaN? on nil" :expected :throws :actual "(NaN? nil)"} + {:suite "seq / strictness round 3" :label "NaN? on number ok" :expected "false" :actual "(NaN? 1.0)"} + {:suite "seq / strictness round 3" :label "shuffle on number" :expected :throws :actual "(shuffle 1)"} + {:suite "seq / strictness round 3" :label "shuffle on string" :expected :throws :actual "(shuffle \"abc\")"} + {:suite "seq / strictness round 3" :label "shuffle vec ok" :expected "3" :actual "(count (shuffle [1 2 3]))"} + {:suite "seq / strictness round 3" :label "nthrest nil count" :expected :throws :actual "(nthrest [0 1 2] nil)"} + {:suite "seq / strictness round 3" :label "nthrest negative" :expected "[0 1 2]" :actual "(nthrest [0 1 2] -1)"} + {:suite "seq / strictness round 3" :label "nthrest nil coll" :expected "nil" :actual "(nthrest nil 0)"} + {:suite "seq / strictness round 3" :label "nthnext nil count" :expected :throws :actual "(nthnext [0 1 2] nil)"} + {:suite "seq / strictness round 3" :label "update vec oob" :expected :throws :actual "(update [] 1 identity)"} + {:suite "seq / strictness round 3" :label "update vec kw key" :expected :throws :actual "(update [1 2 3] :k identity)"} + {:suite "seq / overlay-migrated fns" :label "nthrest exhausted -> ()" :expected "[]" :actual "(nthrest nil 100)"} + {:suite "seq / overlay-migrated fns" :label "nthrest vec exhausted" :expected "[]" :actual "(nthrest [1 2 3] 100)"} + {:suite "seq / overlay-migrated fns" :label "nthrest n<=0 keeps coll" :expected "[1 2 3]" :actual "(nthrest [1 2 3] 0)"} + {:suite "seq / overlay-migrated fns" :label "nthrest drops n" :expected "[3 4 5]" :actual "(nthrest [1 2 3 4 5] 2)"} + {:suite "seq / overlay-migrated fns" :label "nthnext exhausted -> nil" :expected "nil" :actual "(nthnext [1 2] 5)"} + {:suite "seq / overlay-migrated fns" :label "nthnext surprising nil" :expected "nil" :actual "(nthnext nil nil)"} + {:suite "seq / overlay-migrated fns" :label "nthnext drops n" :expected "[3 4]" :actual "(nthnext [1 2 3 4] 2)"} + {:suite "seq / overlay-migrated fns" :label "distinct? distinct" :expected "true" :actual "(distinct? 1 2 3)"} + {:suite "seq / overlay-migrated fns" :label "distinct? dup" :expected "false" :actual "(distinct? 1 2 1)"} + {:suite "seq / overlay-migrated fns" :label "distinct? equal colls" :expected "false" :actual "(distinct? [1 2] [1 2])"} + {:suite "seq / overlay-migrated fns" :label "distinct? single" :expected "true" :actual "(distinct? 5)"} + {:suite "seq / overlay-migrated fns" :label "replace maps elements" :expected "[:a 2 :c 2]" :actual "(replace {1 :a 3 :c} [1 2 3 2])"} + {:suite "seq / overlay-migrated fns" :label "replace preserves nil val" :expected "[1 nil 3]" :actual "(replace {2 nil} [1 2 3])"} + {:suite "seq / overlay-migrated fns" :label "take-last" :expected "[3 4]" :actual "(take-last 2 [1 2 3 4])"} + {:suite "seq / overlay-migrated fns" :label "take-last empty -> nil" :expected "nil" :actual "(take-last 2 [])"} + {:suite "seq / overlay-migrated fns" :label "take-last n>len" :expected "[1 2]" :actual "(take-last 9 [1 2])"} + {:suite "seq / overlay-migrated fns" :label "drop-last default 1" :expected "[1 2]" :actual "(drop-last [1 2 3])"} + {:suite "seq / overlay-migrated fns" :label "drop-last n" :expected "[1 2]" :actual "(drop-last 2 [1 2 3 4])"} + {:suite "seq / overlay-migrated fns" :label "split-with" :expected "[[2 4] [5 6]]" :actual "(split-with even? [2 4 5 6])"} + {:suite "seq / overlay-migrated fns" :label "replicate" :expected "[:x :x :x]" :actual "(replicate 3 :x)"} + {:suite "seq / overlay-migrated fns" :label "bounded-count" :expected "5" :actual "(bounded-count 3 [1 2 3 4 5])"} + {:suite "seq / overlay-migrated fns" :label "bounded-count uncounted" :expected "3" :actual "(bounded-count 3 (filter odd? (range 100)))"} + {:suite "seq / overlay-migrated fns" :label "run! side effects" :expected "6" :actual "(let [a (atom 0)] (run! (fn [x] (swap! a + x)) [1 2 3]) @a)"} + {:suite "seq / overlay-migrated fns" :label "completing wraps rf" :expected "3" :actual "((completing +) 1 2)"} + {:suite "seq / overlay-migrated fns" :label "comparator <" :expected "[1 2 3]" :actual "(sort (comparator <) [3 1 2])"} + {:suite "seq / overlay-migrated fns" :label "comparator >" :expected "[3 2 1]" :actual "(sort (comparator >) [3 1 2])"} + {:suite "seq / overlay-migrated fns" :label "reductions" :expected "[1 3 6 10]" :actual "(reductions + [1 2 3 4])"} + {:suite "seq / overlay-migrated fns" :label "reductions with init" :expected "[10 11 13 16]" :actual "(reductions + 10 [1 2 3])"} + {:suite "seq / overlay-migrated fns" :label "reductions empty calls f" :expected "[0]" :actual "(reductions + [])"} + {:suite "seq / overlay-migrated fns" :label "reductions empty + init" :expected "[5]" :actual "(reductions + 5 [])"} + {:suite "seq / overlay-migrated fns" :label "tree-seq pre-order" :expected "[[1 [2] 3] 1 [2] 2 3]" :actual "(tree-seq sequential? seq [1 [2] 3])"} + {:suite "seq / overlay-migrated fns" :label "some found" :expected "true" :actual "(some even? [1 3 4])"} + {:suite "seq / overlay-migrated fns" :label "some none -> nil" :expected "nil" :actual "(some even? [1 3 5])"} + {:suite "seq / overlay-migrated fns" :label "some keyword pred" :expected "7" :actual "(some :a [{:b 1} {:a 7}])"} + {:suite "seq / overlay-migrated fns" :label "some returns value" :expected "4" :actual "(some (fn [x] (when (even? x) x)) [1 3 4 5])"} + {:suite "seq / overlay-migrated fns" :label "flatten nested" :expected "[1 2 3 4 5]" :actual "(flatten [1 [2 [3 4]] 5])"} + {:suite "seq / overlay-migrated fns" :label "flatten lists too" :expected "[1 2 3]" :actual "(flatten [1 (list 2 3)])"} + {:suite "seq / overlay-migrated fns" :label "flatten scalar -> empty" :expected "[]" :actual "(flatten 5)"} + {:suite "seq / overlay-migrated fns" :label "interleave" :expected "[1 :a 2 :b]" :actual "(interleave [1 2 3] [:a :b])"} + {:suite "seq / overlay-migrated fns" :label "interleave empty" :expected "[]" :actual "(interleave)"} + {:suite "seq / overlay-migrated fns" :label "rationalize identity" :expected "5" :actual "(rationalize 5)"} + {:suite "seq / overlay-migrated fns" :label "dedupe consecutive" :expected "[1 2 3 1]" :actual "(dedupe [1 1 2 2 3 1 1])"} + {:suite "seq / overlay-migrated fns" :label "dedupe empty" :expected "[]" :actual "(dedupe [])"} + {:suite "seq / overlay-migrated fns" :label "dedupe no dups" :expected "[1 2 3]" :actual "(dedupe [1 2 3])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv" :expected "[[1 2] [3 4]]" :actual "(partitionv 2 [1 2 3 4 5])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv elems are vectors" :expected "true" :actual "(every? vector? (partitionv 2 [1 2 3 4]))"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv step" :expected "[[1 2] [3 4]]" :actual "(partitionv 2 2 [1 2 3 4 5])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv pad" :expected "[[1 2] [3 :p]]" :actual "(partitionv 2 2 [:p] [1 2 3])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv-all" :expected "[[1 2] [3]]" :actual "(partitionv-all 2 [1 2 3])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "partitionv-all vectors" :expected "true" :actual "(every? vector? (partitionv-all 2 [1 2 3]))"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at" :expected "[[1 2] [3 4]]" :actual "(splitv-at 2 [1 2 3 4])"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at first is vector" :expected "true" :actual "(vector? (first (splitv-at 2 [1 2 3])))"} + {:suite "seq / partitionv & splitv-at (1.11)" :label "splitv-at past end" :expected "[[1 2] []]" :actual "(splitv-at 5 [1 2])"} + {:suite "sequences / linear walks over concrete collections" :label "rest of vector is a seq" :expected "true" :actual "(seq? (rest [1 2 3]))"} + {:suite "sequences / linear walks over concrete collections" :label "rest of vector not vector" :expected "false" :actual "(vector? (rest [1 2 3]))"} + {:suite "sequences / linear walks over concrete collections" :label "rest values" :expected "[2 3]" :actual "(rest [1 2 3])"} + {:suite "sequences / linear walks over concrete collections" :label "next of vector" :expected "[2 3]" :actual "(next [1 2 3])"} + {:suite "sequences / linear walks over concrete collections" :label "next exhausts to nil" :expected "nil" :actual "(next [1])"} + {:suite "sequences / linear walks over concrete collections" :label "rest exhausts to ()" :expected "[]" :actual "(rest [1])"} + {:suite "sequences / linear walks over concrete collections" :label "rest-loop scales (20k linear)" :expected "20000" :actual "(loop [xs (seq (vec (range 20000))) n 0] (if xs (recur (next xs) (inc n)) n))"} + {:suite "sequences / linear walks over concrete collections" :label "mapv scales (50k linear)" :expected "50000" :actual "(count (mapv inc (vec (range 50000))))"} + {:suite "sequences / linear walks over concrete collections" :label "nested walk" :expected "[2 3]" :actual "(vec (rest (mapv inc [0 1 2])))"} + {:suite "sequences / rest & next over set-like colls" :label "next of set" :expected "true" :actual "(let [n (next #{1 2})] (and (= 1 (count n)) (contains? #{1 2} (first n))))"} + {:suite "sequences / rest & next over set-like colls" :label "rest of set count" :expected "1" :actual "(count (rest #{1 2}))"} + {:suite "sequences / rest & next over set-like colls" :label "next of singleton set" :expected "nil" :actual "(next #{1})"} + {:suite "sequences / rest & next over set-like colls" :label "rest of empty set" :expected "0" :actual "(count (rest #{}))"} + {:suite "sequences / rest & next over set-like colls" :label "next of map" :expected "true" :actual "(let [n (next {:a 1 :b 2})] (and (= 1 (count n)) (map-entry? (first n))))"} + {:suite "sequences / rest & next over set-like colls" :label "next of singleton map" :expected "nil" :actual "(next {:a 1})"} + {:suite "sequences / rest & next over set-like colls" :label "rest of sorted-set" :expected "[2 3]" :actual "(rest (sorted-set 3 1 2))"} + {:suite "sequences / rest & next over set-like colls" :label "next of sorted-map" :expected "[[2 :b]]" :actual "(next (sorted-map 1 :a 2 :b))"} + {:suite "sequences / rest & next over set-like colls" :label "every? over set" :expected "true" :actual "(every? pos? #{1 2 3})"} + {:suite "sequences / rest & next over set-like colls" :label "every? over set false" :expected "false" :actual "(every? odd? #{1 2})"} + {:suite "sequences / rest & next over set-like colls" :label "every? over sorted-set" :expected "true" :actual "(every? pos? (sorted-set 1 2 3))"} + {:suite "sequences / rest & next over set-like colls" :label "every? over map entries" :expected "true" :actual "(every? map-entry? (seq {:a 1 :b 2}))"} + {:suite "set / construct & predicate" :label "literal" :expected "#{1 3 2}" :actual "#{1 2 3}"} + {:suite "set / construct & predicate" :label "hash-set" :expected "#{1 3 2}" :actual "(hash-set 1 2 3)"} + {:suite "set / construct & predicate" :label "set from vector" :expected "#{1 3 2}" :actual "(set [1 2 3 1])"} + {:suite "set / construct & predicate" :label "empty" :expected "#{}" :actual "#{}"} + {:suite "set / construct & predicate" :label "set? true" :expected "true" :actual "(set? #{1})"} + {:suite "set / construct & predicate" :label "set? false on vector" :expected "false" :actual "(set? [1])"} + {:suite "set / construct & predicate" :label "count dedups" :expected "3" :actual "(count (set [1 1 2 3]))"} + {:suite "set / construct & predicate" :label "equality order-indep" :expected "true" :actual "(= #{1 2 3} #{3 2 1})"} + {:suite "set / construct & predicate" :label "into set" :expected "#{:b :a}" :actual "(into #{} [:a :b])"} + {:suite "set / construct & predicate" :label "into non-empty set" :expected "#{1 3 2}" :actual "(into #{1} [2 3 2])"} + {:suite "set / operations" :label "conj adds" :expected "#{1 3 2}" :actual "(conj #{1 2} 3)"} + {:suite "set / operations" :label "conj dup no-op" :expected "#{1 2}" :actual "(conj #{1 2} 1)"} + {:suite "set / operations" :label "disj removes" :expected "#{1 2}" :actual "(disj #{1 2 3} 3)"} + {:suite "set / operations" :label "disj missing no-op" :expected "#{1 2}" :actual "(disj #{1 2} 9)"} + {:suite "set / operations" :label "contains?" :expected "true" :actual "(contains? #{1 2} 1)"} + {:suite "set / operations" :label "contains? missing" :expected "false" :actual "(contains? #{1 2} 9)"} + {:suite "set / operations" :label "get present" :expected "1" :actual "(get #{1 2} 1)"} + {:suite "set / operations" :label "get missing nil" :expected "nil" :actual "(get #{1 2} 9)"} + {:suite "set / operations" :label "set as fn present" :expected "2" :actual "(#{1 2 3} 2)"} + {:suite "set / operations" :label "set as fn missing" :expected "nil" :actual "(#{1 2 3} 9)"} + {:suite "set / literals & value elements" :label "literal evaluates elements" :expected "#{4 2}" :actual "#{(inc 1) (* 2 2)}"} + {:suite "set / literals & value elements" :label "map elements by value" :expected "true" :actual "(= #{{:a 1}} #{(hash-map :a 1)})"} + {:suite "set / literals & value elements" :label "contains? map by value" :expected "true" :actual "(contains? #{(hash-map :x 1)} {:x 1})"} + {:suite "set / literals & value elements" :label "dedup equal maps" :expected "1" :actual "(count (set [{:a 1} (hash-map :a 1)]))"} + {:suite "set / literals & value elements" :label "vector elements" :expected "true" :actual "(contains? #{[1 2]} (vec [1 2]))"} + {:suite "set / nil element" :label "set keeps nil" :expected "2" :actual "(count (set [nil 1 nil]))"} + {:suite "set / nil element" :label "contains? nil true" :expected "true" :actual "(contains? (set [nil 1]) nil)"} + {:suite "set / nil element" :label "contains? nil false" :expected "false" :actual "(contains? #{1} nil)"} + {:suite "set / nil element" :label "seq includes nil" :expected "true" :actual "(some nil? (seq (set [nil 1])))"} + {:suite "set / nil element" :label "disj nil" :expected "#{1}" :actual "(disj (set [nil 1]) nil)"} + {:suite "set / nil element" :label "disj nil count" :expected "1" :actual "(count (disj (set [nil 1]) nil))"} + {:suite "set / nil element" :label "conj nil count" :expected "2" :actual "(count (conj #{1} nil))"} + {:suite "set / nil element" :label "conj nil contains?" :expected "true" :actual "(contains? (conj #{1} nil) nil)"} + {:suite "set / nil element" :label "into #{} keeps nil" :expected "2" :actual "(count (into #{} [nil 1]))"} + {:suite "set / nil element" :label "into #{} contains? nil" :expected "true" :actual "(contains? (into #{} [nil 1]) nil)"} + {:suite "set / nil element" :label "into keeps existing nil" :expected "true" :actual "(contains? (into #{nil} [1]) nil)"} + {:suite "set / nil element" :label "transient conj! nil" :expected "2" :actual "(count (persistent! (conj! (transient #{}) nil 1)))"} + {:suite "set / nil element" :label "transient contains? nil" :expected "true" :actual "(contains? (persistent! (conj! (transient #{}) nil 1)) nil)"} + {:suite "set / nil element" :label "transient disj! nil cnt" :expected "1" :actual "(count (persistent! (disj! (conj! (transient #{}) nil 1) nil)))"} + {:suite "set / nil element" :label "transient disj! removes" :expected "false" :actual "(contains? (persistent! (disj! (conj! (transient #{}) nil 1) nil)) nil)"} + {:suite "set / nil element" :label "transient of set w/ nil" :expected "true" :actual "(contains? (persistent! (transient (set [nil 1]))) nil)"} + {:suite "clojure.set" :label "union" :expected "#{1 4 3 2}" :actual "(do (require (quote [clojure.set :as s])) (s/union #{1 2} #{3 4}))"} + {:suite "clojure.set" :label "intersection" :expected "#{2}" :actual "(do (require (quote [clojure.set :as s])) (s/intersection #{1 2} #{2 3}))"} + {:suite "clojure.set" :label "difference" :expected "#{1}" :actual "(do (require (quote [clojure.set :as s])) (s/difference #{1 2} #{2 3}))"} + {:suite "clojure.set" :label "subset? true" :expected "true" :actual "(do (require (quote [clojure.set :as s])) (s/subset? #{1} #{1 2}))"} + {:suite "clojure.set" :label "superset? true" :expected "true" :actual "(do (require (quote [clojure.set :as s])) (s/superset? #{1 2} #{1}))"} + {:suite "clojure.set" :label "select" :expected "#{4 2}" :actual "(do (require (quote [clojure.set :as s])) (s/select even? #{1 2 3 4}))"} + {:suite "clojure.set" :label "join" :expected "#{{:a 1, :b 2, :c 3}}" :actual "(do (require (quote [clojure.set :as s])) (s/join #{{:a 1 :b 2}} #{{:b 2 :c 3}}))"} + {:suite "clojure.set" :label "map-invert" :expected "{1 :a}" :actual "(do (require (quote [clojure.set :as s])) (s/map-invert {:a 1}))"} + {:suite "clojure.set" :label "rename-keys" :expected "{:b 1}" :actual "(do (require (quote [clojure.set :as s])) (s/rename-keys {:a 1} {:a :b}))"} + {:suite "set / set? across representations" :label "literal" :expected "true" :actual "(set? #{1})"} + {:suite "set / set? across representations" :label "empty literal" :expected "true" :actual "(set? #{})"} + {:suite "set / set? across representations" :label "sorted-set" :expected "true" :actual "(set? (sorted-set 1 2))"} + {:suite "set / set? across representations" :label "sorted-set-by" :expected "true" :actual "(set? (sorted-set-by > 1 2))"} + {:suite "set / set? across representations" :label "empty sorted" :expected "true" :actual "(set? (sorted-set))"} + {:suite "set / set? across representations" :label "map is not" :expected "false" :actual "(set? {})"} + {:suite "set / set? across representations" :label "vector is not" :expected "false" :actual "(set? [1])"} + {:suite "set / set? across representations" :label "coll? still true" :expected "true" :actual "(coll? (sorted-set 1))"} + {:suite "set / set? across representations" :label "ifn? sorted-set" :expected "true" :actual "(ifn? (sorted-set 1))"} + {:suite "set / bulk build boundaries" :label "set dedup count" :expected "3" :actual "(count (set [1 1 2 3 3 2]))"} + {:suite "set / bulk build boundaries" :label "set big count" :expected "1000" :actual "(count (set (range 1000)))"} + {:suite "set / bulk build boundaries" :label "into #{} count" :expected "500" :actual "(count (into #{} (range 500)))"} + {:suite "set / bulk build boundaries" :label "into #{} onto base" :expected "3" :actual "(count (into #{:a} [:a :b :c]))"} + {:suite "set / bulk build boundaries" :label "set contains" :expected "true" :actual "(contains? (set (range 1000)) 777)"} + {:suite "set / bulk build boundaries" :label "set missing" :expected "false" :actual "(contains? (set (range 1000)) 5000)"} + {:suite "set / bulk build boundaries" :label "set coll members" :expected "true" :actual "(contains? (set [[1 2] [3 4]]) [1 2])"} + {:suite "set / bulk build boundaries" :label "conj after bulk" :expected "true" :actual "(contains? (conj (set (range 100)) :x) :x)"} + {:suite "set / bulk build boundaries" :label "disj after bulk" :expected "false" :actual "(contains? (disj (set (range 100)) 50) 50)"} + {:suite "set / bulk build boundaries" :label "set = literal" :expected "true" :actual "(= #{0 1 2} (set (range 3)))"} + {:suite "sorted / construction & ordering" :label "sorted-set orders" :expected "[1 2 3]" :actual "(vec (seq (sorted-set 3 1 2)))"} + {:suite "sorted / construction & ordering" :label "sorted-set dedupes" :expected "[1 2 3]" :actual "(vec (seq (sorted-set 3 1 2 1 3)))"} + {:suite "sorted / construction & ordering" :label "sorted-set numeric" :expected "[1 2 10]" :actual "(vec (seq (sorted-set 10 1 2)))"} + {:suite "sorted / construction & ordering" :label "sorted-map ordered entries" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(vec (seq (sorted-map :c 3 :a 1 :b 2)))"} + {:suite "sorted / construction & ordering" :label "first is min" :expected "1" :actual "(first (sorted-set 5 3 9 1))"} + {:suite "sorted / sorted?" :label "sorted-set" :expected "true" :actual "(sorted? (sorted-set 1))"} + {:suite "sorted / sorted?" :label "sorted-map" :expected "true" :actual "(sorted? (sorted-map :a 1))"} + {:suite "sorted / sorted?" :label "plain set" :expected "false" :actual "(sorted? #{1})"} + {:suite "sorted / sorted?" :label "plain map" :expected "false" :actual "(sorted? {:a 1})"} + {:suite "sorted / sorted?" :label "vector" :expected "false" :actual "(sorted? [1 2])"} + {:suite "sorted / map ops" :label "get hit" :expected "2" :actual "(get (sorted-map :a 1 :b 2) :b)"} + {:suite "sorted / map ops" :label "get miss default" :expected ":none" :actual "(get (sorted-map :a 1) :z :none)"} + {:suite "sorted / map ops" :label "contains? yes" :expected "true" :actual "(contains? (sorted-map :a 1) :a)"} + {:suite "sorted / map ops" :label "contains? no" :expected "false" :actual "(contains? (sorted-map :a 1) :z)"} + {:suite "sorted / map ops" :label "assoc keeps order" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(vec (seq (assoc (sorted-map :c 3 :a 1) :b 2)))"} + {:suite "sorted / map ops" :label "dissoc" :expected "[[:a 1] [:c 3]]" :actual "(vec (seq (dissoc (sorted-map :a 1 :b 2 :c 3) :b)))"} + {:suite "sorted / map ops" :label "conj entry" :expected "[[:a 1] [:z 9]]" :actual "(vec (seq (conj (sorted-map :a 1) [:z 9])))"} + {:suite "sorted / map ops" :label "keys sorted" :expected "[:a :b :c]" :actual "(vec (keys (sorted-map :c 3 :a 1 :b 2)))"} + {:suite "sorted / map ops" :label "vals by key" :expected "[1 2 3]" :actual "(vec (vals (sorted-map :c 3 :a 1 :b 2)))"} + {:suite "sorted / map ops" :label "map as fn" :expected "2" :actual "((sorted-map :a 1 :b 2) :b)"} + {:suite "sorted / map ops" :label "map as fn miss" :expected ":d" :actual "((sorted-map :a 1) :z :d)"} + {:suite "sorted / set ops" :label "get present" :expected "2" :actual "(get (sorted-set 1 2 3) 2)"} + {:suite "sorted / set ops" :label "get absent" :expected ":none" :actual "(get (sorted-set 1 2 3) 9 :none)"} + {:suite "sorted / set ops" :label "contains? yes" :expected "true" :actual "(contains? (sorted-set 1 2 3) 2)"} + {:suite "sorted / set ops" :label "contains? no" :expected "false" :actual "(contains? (sorted-set 1 2 3) 9)"} + {:suite "sorted / set ops" :label "conj keeps order" :expected "[0 1 2 3 5]" :actual "(vec (seq (conj (sorted-set 1 2 3) 5 0)))"} + {:suite "sorted / set ops" :label "disj" :expected "[1 3]" :actual "(vec (seq (disj (sorted-set 1 2 3) 2)))"} + {:suite "sorted / set ops" :label "set as fn" :expected "3" :actual "((sorted-set 1 2 3) 3)"} + {:suite "sorted / set ops" :label "set as fn miss" :expected "nil" :actual "((sorted-set 1 2 3) 9)"} + {:suite "sorted / by comparator" :label "sorted-set-by desc" :expected "[10 3 2 1]" :actual "(vec (seq (sorted-set-by > 1 3 2 10)))"} + {:suite "sorted / by comparator" :label "sorted-map-by desc" :expected "[[3 :c] [2 :b] [1 :a]]" :actual "(vec (seq (sorted-map-by > 1 :a 3 :c 2 :b)))"} + {:suite "sorted / by comparator" :label "conj keeps comparator" :expected "[5 3 2 1 0]" :actual "(vec (seq (conj (sorted-set-by > 1 3 2) 5 0)))"} + {:suite "sorted / by comparator" :label "assoc keeps comparator" :expected "[3 2 1]" :actual "(vec (keys (assoc (sorted-map-by > 1 :a 3 :c) 2 :b)))"} + {:suite "sorted / by comparator" :label "disj keeps comparator" :expected "[3 1]" :actual "(vec (seq (disj (sorted-set-by > 1 2 3) 2)))"} + {:suite "sorted / by comparator" :label "by-comparator is sorted?" :expected "true" :actual "(sorted? (sorted-set-by > 1 2))"} + {:suite "sorted / subseq & rsubseq" :label "subseq >=" :expected "[3 4 5]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) >= 3))"} + {:suite "sorted / subseq & rsubseq" :label "subseq <" :expected "[1 2]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) < 3))"} + {:suite "sorted / subseq & rsubseq" :label "subseq range" :expected "[2 3 4]" :actual "(vec (subseq (sorted-set 1 2 3 4 5) > 1 < 5))"} + {:suite "sorted / subseq & rsubseq" :label "rsubseq <=" :expected "[3 2 1]" :actual "(vec (rsubseq (sorted-set 1 2 3 4 5) <= 3))"} + {:suite "sorted / subseq & rsubseq" :label "subseq on map" :expected "[[2 :b] [3 :c]]" :actual "(vec (subseq (sorted-map 1 :a 2 :b 3 :c) > 1))"} + {:suite "sorted / subseq & rsubseq" :label "subseq empty result" :expected "nil" :actual "(subseq (sorted-set 1 2) > 5)"} + {:suite "sorted / subseq & rsubseq" :label "rsubseq on map" :expected "[[2 :b] [1 :a]]" :actual "(vec (rsubseq (sorted-map 1 :a 2 :b 3 :c) < 3))"} + {:suite "sorted / predicates" :label "sorted-map? true" :expected "true" :actual "(sorted-map? (sorted-map 1 :a))"} + {:suite "sorted / predicates" :label "sorted-map? false" :expected "false" :actual "(sorted-map? {:a 1})"} + {:suite "sorted / predicates" :label "sorted-set? true" :expected "true" :actual "(sorted-set? (sorted-set 1))"} + {:suite "sorted / predicates" :label "sorted-set? false" :expected "false" :actual "(sorted-set? #{1})"} + {:suite "sorted / predicates" :label "map? sorted-map" :expected "true" :actual "(map? (sorted-map 1 :a))"} + {:suite "sorted / predicates" :label "coll? sorted-set" :expected "true" :actual "(coll? (sorted-set 1))"} + {:suite "sorted / lookup + membership use the comparator" :label "get cross-numeric" :expected ":a" :actual "(get (sorted-map 1 :a) 1.0)"} + {:suite "sorted / lookup + membership use the comparator" :label "contains? cross-numeric" :expected "true" :actual "(contains? (sorted-set 1) 1.0)"} + {:suite "sorted / lookup + membership use the comparator" :label "conj equal elem no-op" :expected "1" :actual "(count (conj (sorted-set 1) 1.0))"} + {:suite "sorted / lookup + membership use the comparator" :label "assoc equal key replaces" :expected "[[1 :z]]" :actual "(vec (seq (assoc (sorted-map 1 :a) 1.0 :z)))"} + {:suite "sorted / lookup + membership use the comparator" :label "first sorted-map" :expected "[1 :a]" :actual "(first (sorted-map 2 :b 1 :a))"} + {:suite "sorted / lookup + membership use the comparator" :label "dissoc missing no-op" :expected "2" :actual "(count (dissoc (sorted-map 1 :a 2 :b) 9))"} + {:suite "sorted / lookup + membership use the comparator" :label "conj map merges" :expected "3" :actual "(count (conj (sorted-map 1 :a) {2 :b 3 :c}))"} + {:suite "sorted / lookup + membership use the comparator" :label "conj nil no-op" :expected "1" :actual "(count (conj (sorted-map 1 :a) nil))"} + {:suite "sorted / lookup + membership use the comparator" :label "into sorted-map" :expected "[[1 :a] [2 :b]]" :actual "(vec (seq (into (sorted-map) [[2 :b] [1 :a]])))"} + {:suite "sorted / lookup + membership use the comparator" :label "source unchanged" :expected "[1 2]" :actual "(let [s (sorted-set 1 2)] (conj s 9) (vec (seq s)))"} + {:suite "sorted / lookup + membership use the comparator" :label "sorted-map odd kvs throws" :expected :throws :actual "(sorted-map 1 :a 2)"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-map = literal" :expected "true" :actual "(= (sorted-map :a 1 :b 2) {:a 1 :b 2})"} + {:suite "sorted / equality is representation-agnostic" :label "literal = sorted-map" :expected "true" :actual "(= {:a 1 :b 2} (sorted-map :a 1 :b 2))"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-map = hash-map" :expected "true" :actual "(= (sorted-map :a 1) (hash-map :a 1))"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-map != more keys" :expected "false" :actual "(= (sorted-map :a 1) {:a 1 :b 2})"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-set = literal" :expected "true" :actual "(= (sorted-set 1 2) #{1 2})"} + {:suite "sorted / equality is representation-agnostic" :label "literal = sorted-set" :expected "true" :actual "(= #{1 2} (sorted-set 2 1))"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-set != diff" :expected "false" :actual "(= (sorted-set 1 2) #{1 3})"} + {:suite "sorted / equality is representation-agnostic" :label "two sorted-maps" :expected "true" :actual "(= (sorted-map 1 :a 2 :b) (sorted-map 2 :b 1 :a))"} + {:suite "sorted / equality is representation-agnostic" :label "cmp irrelevant to =" :expected "true" :actual "(= (sorted-map-by > 1 :a 2 :b) (sorted-map 1 :a 2 :b))"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-map as map key" :expected ":hit" :actual "(get {(sorted-map :a 1) :hit} {:a 1})"} + {:suite "sorted / equality is representation-agnostic" :label "sorted-set as map key" :expected ":hit" :actual "(get {(sorted-set 1 2) :hit} #{2 1})"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty? empty map" :expected "true" :actual "(empty? (sorted-map))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty? non-empty" :expected "false" :actual "(empty? (sorted-map 1 :a))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty? empty set" :expected "true" :actual "(empty? (sorted-set))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty keeps sortedness" :expected "true" :actual "(sorted? (empty (sorted-map 1 :a)))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty keeps cmp" :expected "[3 1]" :actual "(vec (seq (into (empty (sorted-set-by > 1 2)) [1 3])))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "empty set kind" :expected "true" :actual "(sorted-set? (empty (sorted-set 1)))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "rseq map" :expected "[[2 :b] [1 :a]]" :actual "(vec (rseq (sorted-map 1 :a 2 :b)))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "rseq set" :expected "[3 2 1]" :actual "(vec (rseq (sorted-set 1 2 3)))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "pr-str sorted-map" :expected "\"{1 :a, 2 :b}\"" :actual "(pr-str (sorted-map 2 :b 1 :a))"} + {:suite "sorted / empty + empty? + rseq + printing" :label "pr-str sorted-set" :expected "\"#{1 2 3}\"" :actual "(pr-str (sorted-set 3 1 2))"} + {:suite "sorted / seq fn interop" :label "map over sorted-map" :expected "[1 2 3]" :actual "(vec (map first (sorted-map 2 :b 1 :a 3 :c)))"} + {:suite "sorted / seq fn interop" :label "map over sorted-set" :expected "[2 3 4]" :actual "(vec (map inc (sorted-set 3 1 2)))"} + {:suite "sorted / seq fn interop" :label "filter entries" :expected "[[2 :b]]" :actual "(vec (filter (fn [[k v]] (even? k)) (sorted-map 1 :a 2 :b)))"} + {:suite "sorted / seq fn interop" :label "reduce over set" :expected "6" :actual "(reduce + (sorted-set 1 2 3))"} + {:suite "sorted / seq fn interop" :label "vec of sorted-set" :expected "[1 2 3]" :actual "(vec (sorted-set 3 1 2))"} + {:suite "sorted / seq fn interop" :label "into vec" :expected "[[1 :a] [2 :b]]" :actual "(into [] (sorted-map 2 :b 1 :a))"} + {:suite "sorted / seq fn interop" :label "sorted-map-by 3way cmp" :expected "[3 2 1]" :actual "(vec (keys (sorted-map-by (fn [a b] (- b a)) 1 :a 2 :b 3 :c)))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "slurp returns string" :expected "true" :actual "(string? (slurp \"README.md\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "slurp content" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/includes? (slurp \"README.md\") \"jolt\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "spit + slurp round" :expected "\"hello\"" :actual "(do (spit \"/tmp/jolt-spit-test.txt\" \"hello\") (slurp \"/tmp/jolt-spit-test.txt\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "spit append" :expected "\"ab\"" :actual "(do (spit \"/tmp/jolt-spit-test.txt\" \"a\") (spit \"/tmp/jolt-spit-test.txt\" \"b\" :append true) (slurp \"/tmp/jolt-spit-test.txt\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "printf formats" :expected "\"x=1 y=a\"" :actual "(with-out-str (printf \"x=%d y=%s\" 1 \"a\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "printf no newline" :expected "false" :actual "(do (require (quote [clojure.string :as s])) (s/includes? (with-out-str (printf \"%d\" 1)) \"\\n\"))"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "flush returns nil" :expected "nil" :actual "(flush)"} + {:suite "io / slurp, spit, printf, flush (host-classified)" :label "file-seq finds files" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (boolean (some (fn [p] (s/ends-with? p \"README.md\")) (file-seq \".\"))))"} + {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-map has var" :expected "true" :actual "(do (def nmv 1) (some? (get (ns-map (quote user)) (quote nmv))))"} + {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-unmap removes" :expected "nil" :actual "(do (def nuv 1) (ns-unmap (quote user) (quote nuv)) (resolve (quote nuv)))"} + {:suite "ns / ns-map, ns-unmap, ns-refers" :label "ns-refers sees refer" :expected "true" :actual "(do (require (quote clojure.string)) (refer (quote clojure.string)) (some? (get (ns-refers (quote user)) (quote join))))"} + {:suite "vars / thread-binding family" :label "bound? on def" :expected "true" :actual "(do (def bvv 1) (bound? (var bvv)))"} + {:suite "vars / thread-binding family" :label "with-bindings* binds" :expected "5" :actual "(do (def ^:dynamic dynv 1) (with-bindings* (array-map (var dynv) 5) (fn [] dynv)))"} + {:suite "vars / thread-binding family" :label "with-bindings* restores" :expected "1" :actual "(do (def ^:dynamic dynw 1) (with-bindings* (array-map (var dynw) 5) (fn [] nil)) dynw)"} + {:suite "vars / thread-binding family" :label "with-bindings macro" :expected "7" :actual "(do (def ^:dynamic dynx 1) (with-bindings (array-map (var dynx) 7) dynx))"} + {:suite "vars / thread-binding family" :label "thread-bound? inside" :expected "[true false]" :actual "(do (def ^:dynamic dyny 1) [(with-bindings* (array-map (var dyny) 2) (fn [] (thread-bound? (var dyny)))) (thread-bound? (var dyny))])"} + {:suite "vars / thread-binding family" :label "bound-fn* conveys" :expected "9" :actual "(do (def ^:dynamic dynz 1) (def f (with-bindings* (array-map (var dynz) 9) (fn [] (bound-fn* (fn [] dynz))))) (f))"} + {:suite "vars / thread-binding family" :label "get-thread-bindings" :expected "3" :actual "(do (def ^:dynamic dyng 1) (with-bindings* (array-map (var dyng) 3) (fn [] (get (get-thread-bindings) (var dyng)))))"} + {:suite "eval & load-string as values" :label "load-string evals all" :expected "3" :actual "(load-string \"(def lsv 1) (+ lsv 2)\")"} + {:suite "eval & load-string as values" :label "eval as value" :expected "[2 3]" :actual "(mapv eval [(quote (+ 1 1)) (quote (+ 1 2))])"} + {:suite "eval & load-string as values" :label "eval special still works" :expected "3" :actual "(eval (quote (+ 1 2)))"} + {:suite "clojure.edn / opts" :label "set literal" :expected "#{1 2}" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string \"#{1 2}\"))"} + {:suite "clojure.edn / opts" :label "uuid tag" :expected "true" :actual "(do (require (quote [clojure.edn :as e0])) (uuid? (e0/read-string \"#uuid \\\"550e8400-e29b-41d4-a716-446655440000\\\"\")))"} + {:suite "clojure.edn / opts" :label "inst tag" :expected "true" :actual "(do (require (quote [clojure.edn :as e0])) (inst? (e0/read-string \"#inst \\\"2020-01-01T00:00:00Z\\\"\")))"} + {:suite "clojure.edn / opts" :label ":eof on empty" :expected ":end" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:eof :end} \"\"))"} + {:suite "clojure.edn / opts" :label ":readers custom tag" :expected "[:custom 5]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:readers {(quote custom) (fn [v] [:custom v])}} \"#custom 5\"))"} + {:suite "clojure.edn / opts" :label ":readers nested" :expected "[6 8]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:readers {(quote w) (fn [v] (* 2 v))}} \"[#w 3 #w 4]\"))"} + {:suite "clojure.edn / opts" :label ":default fn" :expected "[:dflt 7]" :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string {:default (fn [t v] [:dflt v])} \"#unknown 7\"))"} + {:suite "clojure.edn / opts" :label "unknown tag throws" :expected :throws :actual "(do (require (quote [clojure.edn :as e0])) (e0/read-string \"#nope 1\"))"} + {:suite "state / atoms" :label "deref @" :expected "0" :actual "(let [a (atom 0)] @a)"} + {:suite "state / atoms" :label "deref fn" :expected "0" :actual "(deref (atom 0))"} + {:suite "state / atoms" :label "reset!" :expected "5" :actual "(let [a (atom 0)] (reset! a 5) @a)"} + {:suite "state / atoms" :label "reset! returns new" :expected "5" :actual "(let [a (atom 0)] (reset! a 5))"} + {:suite "state / atoms" :label "swap!" :expected "1" :actual "(let [a (atom 0)] (swap! a inc) @a)"} + {:suite "state / atoms" :label "swap! with args" :expected "10" :actual "(let [a (atom 1)] (swap! a + 2 3 4) @a)"} + {:suite "state / atoms" :label "swap! returns new" :expected "1" :actual "(let [a (atom 0)] (swap! a inc))"} + {:suite "state / atoms" :label "swap-vals!" :expected "[0 1]" :actual "(let [a (atom 0)] (swap-vals! a inc))"} + {:suite "state / atoms" :label "reset-vals!" :expected "[0 9]" :actual "(let [a (atom 0)] (reset-vals! a 9))"} + {:suite "state / atoms" :label "compare-and-set! ok" :expected "true" :actual "(let [a (atom 0)] (compare-and-set! a 0 1))"} + {:suite "state / atoms" :label "compare-and-set! no" :expected "false" :actual "(let [a (atom 0)] (compare-and-set! a 9 1))"} + {:suite "state / atoms" :label "atom?" :expected "true" :actual "(do (require (quote [clojure.core])) (instance? clojure.lang.Atom (atom 0)))"} + {:suite "state / atoms" :label "atom? predicate" :expected "true" :actual "(atom? (atom 0))"} + {:suite "state / atoms" :label "atom? on non-atom" :expected "false" :actual "(atom? 5)"} + {:suite "state / watches & validators" :label "add-watch fires" :expected "1" :actual "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (reset! seen 1))) (reset! a 5) @seen)"} + {:suite "state / watches & validators" :label "remove-watch" :expected "0" :actual "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (swap! seen inc))) (remove-watch a :k) (reset! a 5) @seen)"} + {:suite "state / watches & validators" :label "set-validator! ok" :expected "5" :actual "(let [a (atom 0)] (set-validator! a number?) (reset! a 5) @a)"} + {:suite "state / watches & validators" :label "set-validator! rejects" :expected :throws :actual "(let [a (atom 0)] (set-validator! a pos?) (reset! a -1))"} + {:suite "state / watches & validators" :label "get-validator" :expected "true" :actual "(let [a (atom 0)] (set-validator! a number?) (fn? (get-validator a)))"} + {:suite "state / volatiles & delays" :label "volatile! deref" :expected "0" :actual "(let [v (volatile! 0)] @v)"} + {:suite "state / volatiles & delays" :label "vreset!" :expected "5" :actual "(let [v (volatile! 0)] (vreset! v 5) @v)"} + {:suite "state / volatiles & delays" :label "vswap!" :expected "1" :actual "(let [v (volatile! 0)] (vswap! v inc) @v)"} + {:suite "state / volatiles & delays" :label "delay not forced" :expected "0" :actual "(let [c (atom 0) d (delay (swap! c inc))] @c)"} + {:suite "state / volatiles & delays" :label "delay force once" :expected "1" :actual "(let [c (atom 0) d (delay (swap! c inc))] (force d) (force d) @c)"} + {:suite "state / volatiles & delays" :label "delay value" :expected "5" :actual "(let [d (delay 5)] @d)"} + {:suite "state / volatiles & delays" :label "realized? before" :expected "false" :actual "(let [d (delay 5)] (realized? d))"} + {:suite "state / volatiles & delays" :label "realized? after" :expected "true" :actual "(let [d (delay 5)] (force d) (realized? d))"} + {:suite "state / promises" :label "promise deliver" :expected "5" :actual "(let [p (promise)] (deliver p 5) @p)"} + {:suite "state / promises" :label "promise undelivered" :expected "nil" :actual "(let [p (promise)] @p)"} + {:suite "state / agents (synchronous shim)" :label "agent deref" :expected "0" :actual "(deref (agent 0))"} + {:suite "state / agents (synchronous shim)" :label "agent with opts" :expected "0" :actual "(deref (agent 0 :error-mode :continue))"} + {:suite "state / agents (synchronous shim)" :label "send-off applies" :expected "0" :actual "(let [a (agent 0)] (send-off a (fn [x] (Thread/sleep 100) (+ x 5))) (deref a))"} + {:suite "state / agents (synchronous shim)" :label "send applies" :expected "1" :actual "(let [a (agent 1)] (send a (fn [x] (Thread/sleep 100) (+ x 6))) (deref a))"} + {:suite "state / agents (synchronous shim)" :label "agent-error nil" :expected "nil" :actual "(agent-error (agent 0))"} + {:suite "string / str & basics" :label "str concat" :expected "\"abc\"" :actual "(str \"a\" \"b\" \"c\")"} + {:suite "string / str & basics" :label "str of numbers" :expected "\"12\"" :actual "(str 1 2)"} + {:suite "string / str & basics" :label "str nil is empty" :expected "\"\"" :actual "(str nil)"} + {:suite "string / str & basics" :label "str mixed" :expected "\"a1:b\"" :actual "(str \"a\" 1 :b)"} + {:suite "string / str & basics" :label "str of coll" :expected "\"[1 2]\"" :actual "(str [1 2])"} + {:suite "string / str & basics" :label "count" :expected "3" :actual "(count \"abc\")"} + {:suite "string / str & basics" :label "subs from" :expected "\"bc\"" :actual "(subs \"abc\" 1)"} + {:suite "string / str & basics" :label "subs range" :expected "\"b\"" :actual "(subs \"abc\" 1 2)"} + {:suite "string / str & basics" :label "string? true" :expected "true" :actual "(string? \"x\")"} + {:suite "string / str & basics" :label "pr-str vector" :expected "\"[1 2 3]\"" :actual "(pr-str [1 2 3])"} + {:suite "string / str & basics" :label "pr-str quotes str" :expected "\"\\\"hi\\\"\"" :actual "(pr-str \"hi\")"} + {:suite "string / str & basics" :label "pr-str of a var" :expected "\"#'user/vv\"" :actual "(pr-str (def vv 1))"} + {:suite "string / str & basics" :label "str of a var" :expected "\"#'user/ww\"" :actual "(str (def ww 2))"} + {:suite "string / str & basics" :label "pr-str of a defn" :expected "\"#'user/gg\"" :actual "(pr-str (defn gg [x] x))"} + {:suite "string / str & basics" :label "seq of string" :expected "[\\a \\b]" :actual "(seq \"ab\")"} + {:suite "string as a seqable of chars" :label "vec of string" :expected "[\\a \\b]" :actual "(vec \"ab\")"} + {:suite "string as a seqable of chars" :label "into [] of string" :expected "[\\a \\b]" :actual "(into [] \"ab\")"} + {:suite "string as a seqable of chars" :label "set of string" :expected "true" :actual "(= #{\\a \\b} (set \"ab\"))"} + {:suite "string as a seqable of chars" :label "into #{} of string" :expected "true" :actual "(= #{\\a \\b} (into #{} \"ab\"))"} + {:suite "string as a seqable of chars" :label "set dedups chars" :expected "2" :actual "(count (set \"aab\"))"} + {:suite "string as a seqable of chars" :label "mapv over string" :expected "[\\a \\b]" :actual "(mapv identity \"ab\")"} + {:suite "clojure.string / split limit" :label "neg keeps trailing" :expected "[\"a\" \"\" \"\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\" -1))"} + {:suite "clojure.string / split limit" :label "zero trims trailing" :expected "[\"a\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\" 0))"} + {:suite "clojure.string / split limit" :label "omitted trims" :expected "[\"a\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,\" #\",\"))"} + {:suite "clojure.string / split limit" :label "positive caps parts" :expected "[\"a\" \"b,c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b,c\" #\",\" 2))"} + {:suite "clojure.string / split limit" :label "empty string" :expected "[\"\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"\" #\",\"))"} + {:suite "clojure.string / split limit" :label "interior empties kept" :expected "[\"a\" \"\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,,b\" #\",\"))"} + {:suite "clojure.string" :label "join" :expected "\"a,b,c\"" :actual "(do (require (quote [clojure.string :as s])) (s/join \",\" [\"a\" \"b\" \"c\"]))"} + {:suite "clojure.string" :label "join no sep" :expected "\"abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/join [\"a\" \"b\" \"c\"]))"} + {:suite "clojure.string" :label "split" :expected "[\"a\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b\" #\",\"))"} + {:suite "clojure.string" :label "split-lines" :expected "[\"a\" \"b\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split-lines \"a\\nb\"))"} + {:suite "clojure.string" :label "upper-case" :expected "\"ABC\"" :actual "(do (require (quote [clojure.string :as s])) (s/upper-case \"abc\"))"} + {:suite "clojure.string" :label "lower-case" :expected "\"abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/lower-case \"ABC\"))"} + {:suite "clojure.string" :label "capitalize" :expected "\"Abc\"" :actual "(do (require (quote [clojure.string :as s])) (s/capitalize \"abc\"))"} + {:suite "clojure.string" :label "trim" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim \" x \"))"} + {:suite "clojure.string" :label "triml" :expected "\"x \"" :actual "(do (require (quote [clojure.string :as s])) (s/triml \" x \"))"} + {:suite "clojure.string" :label "blank? true" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/blank? \" \"))"} + {:suite "clojure.string" :label "blank? false" :expected "false" :actual "(do (require (quote [clojure.string :as s])) (s/blank? \"x\"))"} + {:suite "clojure.string" :label "includes?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/includes? \"hello\" \"ell\"))"} + {:suite "clojure.string" :label "starts-with?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/starts-with? \"hello\" \"he\"))"} + {:suite "clojure.string" :label "ends-with?" :expected "true" :actual "(do (require (quote [clojure.string :as s])) (s/ends-with? \"hello\" \"lo\"))"} + {:suite "clojure.string" :label "replace" :expected "\"hexxo\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" \"l\" \"x\"))"} + {:suite "clojure.string" :label "reverse" :expected "\"cba\"" :actual "(do (require (quote [clojure.string :as s])) (s/reverse \"abc\"))"} + {:suite "clojure.string" :label "index-of" :expected "2" :actual "(do (require (quote [clojure.string :as s])) (s/index-of \"hello\" \"l\"))"} + {:suite "string / subs strictness" :label "subs basic" :expected "\"bcd\"" :actual "(subs \"abcde\" 1 4)"} + {:suite "string / subs strictness" :label "subs to end" :expected "\"cde\"" :actual "(subs \"abcde\" 2)"} + {:suite "string / subs strictness" :label "subs start>end" :expected :throws :actual "(subs \"abcde\" 2 1)"} + {:suite "string / subs strictness" :label "subs negative" :expected :throws :actual "(subs \"abcde\" -1)"} + {:suite "string / subs strictness" :label "subs end past len" :expected :throws :actual "(subs \"abcde\" 1 6)"} + {:suite "string / subs strictness" :label "subs nil start" :expected :throws :actual "(subs \"abcde\" nil 2)"} + {:suite "string / subs strictness" :label "subs on nil" :expected :throws :actual "(subs nil 1 2)"} + {:suite "string / namespace-munge" :label "hyphens to underscores" :expected "\"a_b_c\"" :actual "(namespace-munge \"a-b-c\")"} + {:suite "string / namespace-munge" :label "from a symbol" :expected "\"foo_bar\"" :actual "(namespace-munge (quote foo-bar))"} + {:suite "string / namespace-munge" :label "no hyphens unchanged" :expected "\"ok\"" :actual "(namespace-munge \"ok\")"} + {:suite "strings / get indexes a string" :label "get returns the char" :expected "true" :actual "(= (get \"a:b\" 1) \\:)"} + {:suite "strings / get indexes a string" :label "get first char" :expected "\\a" :actual "(get \"abc\" 0)"} + {:suite "strings / get indexes a string" :label "get out of range nil" :expected "nil" :actual "(get \"abc\" 9)"} + {:suite "strings / get indexes a string" :label "get negative nil" :expected "nil" :actual "(get \"abc\" -1)"} + {:suite "strings / get indexes a string" :label "get default honored" :expected ":none" :actual "(get \"abc\" 9 :none)"} + {:suite "clojure.string / trim-newline" :label "trailing newline" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"x\\n\"))"} + {:suite "clojure.string / trim-newline" :label "trailing \\r\\n" :expected "\"x\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"x\\r\\n\"))"} + {:suite "clojure.string / trim-newline" :label "no trailing" :expected "\"ab\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"ab\"))"} + {:suite "clojure.string / trim-newline" :label "only newlines" :expected "\"\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"\\n\\n\"))"} + {:suite "clojure.string / trim-newline" :label "interior kept" :expected "\"a\\nb\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim-newline \"a\\nb\\n\"))"} + {:suite "transducers / into" :label "map xform" :expected "[2 3 4]" :actual "(into [] (map inc) [1 2 3])"} + {:suite "transducers / into" :label "filter xform" :expected "[2 4]" :actual "(into [] (filter even?) [1 2 3 4])"} + {:suite "transducers / into" :label "remove xform" :expected "[1 3]" :actual "(into [] (remove even?) [1 2 3 4])"} + {:suite "transducers / into" :label "take xform" :expected "[1 2]" :actual "(into [] (take 2) [1 2 3 4])"} + {:suite "transducers / into" :label "drop xform" :expected "[3 4]" :actual "(into [] (drop 2) [1 2 3 4])"} + {:suite "transducers / into" :label "take-while xform" :expected "[1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) [1 2 3 1])"} + {:suite "transducers / into" :label "keep xform" :expected "[1 3]" :actual "(into [] (keep (fn [x] (if (odd? x) x nil))) [1 2 3 4])"} + {:suite "transducers / into" :label "map-indexed xform" :expected "[[0 :a] [1 :b]]" :actual "(into [] (map-indexed vector) [:a :b])"} + {:suite "transducers / into" :label "mapcat xform" :expected "[1 1 2 2]" :actual "(into [] (mapcat (fn [x] [x x])) [1 2])"} + {:suite "transducers / into" :label "cat xform" :expected "[1 2 3 4]" :actual "(into [] cat [[1 2] [3 4]])"} + {:suite "transducers / into" :label "into a set" :expected "#{4 3 2}" :actual "(into #{} (map inc) [1 2 3])"} + {:suite "transducers / compose" :label "comp map+filter" :expected "[2 4 6 8]" :actual "(into [] (comp (map (fn [x] (* x 2))) (filter even?)) [1 2 3 4])"} + {:suite "transducers / compose" :label "comp filter+map" :expected "[2 4]" :actual "(into [] (comp (filter odd?) (map inc)) [1 2 3 4])"} + {:suite "transducers / compose" :label "comp three" :expected "[2]" :actual "(into [] (comp (map inc) (filter even?) (take 1)) [1 2 3 4])"} + {:suite "transducers / transduce & sequence" :label "transduce sum" :expected "9" :actual "(transduce (map inc) + [1 2 3])"} + {:suite "transducers / transduce & sequence" :label "transduce init" :expected "19" :actual "(transduce (map inc) + 10 [1 2 3])"} + {:suite "transducers / transduce & sequence" :label "transduce filter" :expected "6" :actual "(transduce (filter even?) + [1 2 3 4])"} + {:suite "transducers / transduce & sequence" :label "sequence xform" :expected "[2 3 4]" :actual "(sequence (map inc) [1 2 3])"} + {:suite "transducers / transduce & sequence" :label "eduction" :expected "[2 3 4]" :actual "(into [] (eduction (map inc) [1 2 3]))"} + {:suite "transducers / transduce & sequence" :label "completing" :expected "9" :actual "(transduce (map inc) (completing +) 0 [1 2 3])"} + {:suite "transducers / halt-when" :label "halt returns the halting input" :expected "7" :actual "(transduce (halt-when (fn [x] (> x 5))) conj [1 2 7 3])"} + {:suite "transducers / halt-when" :label "no halt is a plain reduction" :expected "[1 2 3]" :actual "(transduce (halt-when (fn [x] (> x 5))) conj [1 2 3])"} + {:suite "transducers / halt-when" :label "retf combines acc and input" :expected "[[1 2] 7]" :actual "(transduce (halt-when (fn [x] (> x 5)) (fn [r i] [r i])) conj [1 2 7 3])"} + {:suite "transducers / halt-when" :label "halt-when through into" :expected "3" :actual "(into [] (halt-when odd?) [2 4 3 6])"} + {:suite "transducers / short-circuit over infinite seqs" :label "into take (range)" :expected "[0 1 2 3 4]" :actual "(into [] (take 5) (range))"} + {:suite "transducers / short-circuit over infinite seqs" :label "transduce take (range)" :expected "3" :actual "(transduce (take 3) + 0 (range))"} + {:suite "transducers / short-circuit over infinite seqs" :label "sequence take (range)" :expected "[0 1 2 3 4]" :actual "(sequence (take 5) (range))"} + {:suite "transducers / short-circuit over infinite seqs" :label "take-while over (range)" :expected "[0 1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) (range))"} + {:suite "transducers / short-circuit over infinite seqs" :label "comp take over (range)" :expected "[1 3 5]" :actual "(into [] (comp (filter odd?) (take 3)) (range))"} + {:suite "transducers / short-circuit over infinite seqs" :label "into take iterate" :expected "[0 1 2 3 4]" :actual "(into [] (take 5) (iterate inc 0))"} + {:suite "reduce / honors reduced" :label "reduced short-circuits inf" :expected "105" :actual "(reduce (fn [a x] (if (> a 100) (reduced a) (+ a x))) 0 (range))"} + {:suite "reduce / honors reduced" :label "reduce take inf" :expected "10" :actual "(reduce + (take 5 (range)))"} + {:suite "reduce / honors reduced" :label "reduce no-init first elem" :expected "6" :actual "(reduce + [1 2 3])"} + {:suite "reduce / honors reduced" :label "reduce no-init single" :expected "42" :actual "(reduce + [42])"} + {:suite "reduce / honors reduced" :label "reduce empty calls f" :expected "0" :actual "(reduce + [])"} + {:suite "reduce / honors reduced" :label "reduce with-init" :expected "16" :actual "(reduce + 10 [1 2 3])"} + {:suite "reduce / honors reduced" :label "reduce reduced immediate" :expected ":x" :actual "(reduce (fn [a x] (reduced :x)) :init [1 2 3])"} + {:suite "transducers / into & eduction (overlay)" :label "into list prepends" :expected "[4 3 1 2]" :actual "(into (quote (1 2)) [3 4])"} + {:suite "transducers / into & eduction (overlay)" :label "into sorted-map" :expected "{1 :a, 2 :b}" :actual "(into (sorted-map) [[2 :b] [1 :a]])"} + {:suite "transducers / into & eduction (overlay)" :label "into from map entry" :expected "[:a 1]" :actual "(into [] (first {:a 1}))"} + {:suite "transducers / into & eduction (overlay)" :label "into xform on map" :expected "{:a 2}" :actual "(into {} (map (fn [e] [(key e) (inc (val e))])) {:a 1})"} + {:suite "transducers / into & eduction (overlay)" :label "eduction multiple xforms" :expected "[4]" :actual "(into [] (eduction (filter odd?) (map inc) [2 3 4]))"} + {:suite "transducers / into & eduction (overlay)" :label "->Eduction" :expected "[2 3]" :actual "(->Eduction (map inc) [1 2])"} + {:suite "transducers / into & eduction (overlay)" :label "transduce no init uses (f)" :expected "5" :actual "(transduce (map inc) + [1 2])"} + {:suite "transient / vector" :label "conj! then persistent!" :expected "[1 2]" :actual "(persistent! (conj! (conj! (transient []) 1) 2))"} + {:suite "transient / vector" :label "reduce conj!" :expected "[0 1 2 3 4]" :actual "(persistent! (reduce conj! (transient []) (range 5)))"} + {:suite "transient / vector" :label "conj! many args" :expected "[1 2 3]" :actual "(persistent! (conj! (transient [1]) 2 3))"} + {:suite "transient / vector" :label "assoc! existing" :expected "[1 9 3]" :actual "(persistent! (assoc! (transient [1 2 3]) 1 9))"} + {:suite "transient / vector" :label "assoc! at count grows" :expected "[1 2 3]" :actual "(persistent! (assoc! (transient [1 2]) 2 3))"} + {:suite "transient / vector" :label "pop!" :expected "[1 2]" :actual "(persistent! (pop! (transient [1 2 3])))"} + {:suite "transient / vector" :label "from existing vector" :expected "[1 2 3 4]" :actual "(persistent! (conj! (transient [1 2 3]) 4))"} + {:suite "transient / vector" :label "count" :expected "3" :actual "(count (transient [1 2 3]))"} + {:suite "transient / vector" :label "nth" :expected "2" :actual "(nth (transient [1 2 3]) 1)"} + {:suite "transient / vector" :label "get" :expected "2" :actual "(get (transient [1 2 3]) 1)"} + {:suite "transient / vector" :label "persistent! is a vector" :expected "true" :actual "(vector? (persistent! (transient [1])))"} + {:suite "transient / vector" :label "transient? true" :expected "true" :actual "(transient? (transient []))"} + {:suite "transient / vector" :label "transient? false" :expected "false" :actual "(transient? [1 2])"} + {:suite "transient / map" :label "assoc! then persistent!" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (assoc! (transient {}) :a 1) :b 2))"} + {:suite "transient / map" :label "assoc! many" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (transient {}) :a 1 :b 2))"} + {:suite "transient / map" :label "dissoc!" :expected "{:b 2}" :actual "(persistent! (dissoc! (transient {:a 1 :b 2}) :a))"} + {:suite "transient / map" :label "conj! map entry" :expected "{:a 1}" :actual "(persistent! (conj! (transient {}) [:a 1]))"} + {:suite "transient / map" :label "from existing map" :expected "{:a 1, :b 2}" :actual "(persistent! (assoc! (transient {:a 1}) :b 2))"} + {:suite "transient / map" :label "get" :expected "1" :actual "(get (transient {:a 1}) :a)"} + {:suite "transient / map" :label "get missing default" :expected ":x" :actual "(get (transient {:a 1}) :z :x)"} + {:suite "transient / map" :label "contains?" :expected "true" :actual "(contains? (transient {:a 1}) :a)"} + {:suite "transient / map" :label "count" :expected "2" :actual "(count (transient {:a 1 :b 2}))"} + {:suite "transient / map" :label "collection key by value" :expected ":v" :actual "(get (persistent! (assoc! (transient {}) [1 2] :v)) [1 2])"} + {:suite "transient / map" :label "persistent! is a map" :expected "true" :actual "(map? (persistent! (transient {:a 1})))"} + {:suite "transient / map" :label "reduce build" :expected "{0 0, 1 1, 2 2}" :actual "(persistent! (reduce (fn [t i] (assoc! t i i)) (transient {}) (range 3)))"} + {:suite "transient / set" :label "conj! dedups" :expected "#{1 2 3}" :actual "(persistent! (conj! (transient #{}) 1 2 2 3))"} + {:suite "transient / set" :label "disj!" :expected "#{1 3}" :actual "(persistent! (disj! (transient #{1 2 3}) 2))"} + {:suite "transient / set" :label "from existing set" :expected "#{1 3 2}" :actual "(persistent! (conj! (transient #{1 2}) 3))"} + {:suite "transient / set" :label "contains?" :expected "true" :actual "(contains? (transient #{1 2}) 1)"} + {:suite "transient / set" :label "count" :expected "2" :actual "(count (transient #{1 2}))"} + {:suite "transient / set" :label "persistent! is a set" :expected "true" :actual "(set? (persistent! (transient #{1})))"} + {:suite "transient / set" :label "map elements by value" :expected "1" :actual "(count (persistent! (conj! (transient #{}) {:a 1} (hash-map :a 1))))"} + {:suite "transient / immutability of source" :label "source vector unchanged" :expected "true" :actual "(let [v [1 2 3] _ (persistent! (conj! (transient v) 4))] (= v [1 2 3]))"} + {:suite "transient / immutability of source" :label "source map unchanged" :expected "true" :actual "(let [m {:a 1} _ (persistent! (assoc! (transient m) :b 2))] (= m {:a 1}))"} + {:suite "transient / invokable lookup" :label "vector index" :expected "20" :actual "((transient [10 20 30]) 1)"} + {:suite "transient / invokable lookup" :label "map key as fn" :expected "7" :actual "((transient {:x 7}) :x)"} + {:suite "transient / invokable lookup" :label "map key default" :expected "99" :actual "((transient {:x 7}) :z 99)"} + {:suite "transient / invokable lookup" :label "keyword on transient" :expected "7" :actual "(:x (transient {:x 7}))"} + {:suite "transient / invokable lookup" :label "set membership" :expected "2" :actual "((transient #{1 2 3}) 2)"} + {:suite "transient / invokable lookup" :label "set miss default" :expected ":no" :actual "((transient #{1 2 3}) 42 :no)"} + {:suite "transient / invokable lookup" :label "collection key" :expected ":v" :actual "((transient {[1 2] :v}) [1 2])"} + {:suite "transient / assoc! odd args throw" :label "map dangling key" :expected "{:a 1, :b nil}" :actual "(persistent! (assoc! (transient {}) :a 1 :b))"} + {:suite "transient / assoc! odd args throw" :label "map lone key" :expected :throws :actual "(persistent! (assoc! (transient {}) :a))"} + {:suite "transient / assoc! odd args throw" :label "vector dangling" :expected "[9 nil]" :actual "(persistent! (apply assoc! (transient []) [0 9 1]))"} + {:suite "transient / assoc! odd args throw" :label "even args still ok" :expected "true" :actual "(= {:a 1, :b 2} (persistent! (assoc! (transient {}) :a 1 :b 2)))"} + {:suite "transient / invalidation" :label "conj! after persistent!" :expected :throws :actual "(let [t (transient [])] (persistent! t) (conj! t 1))"} + {:suite "transient / invalidation" :label "assoc! after persistent!" :expected :throws :actual "(let [t (transient {})] (persistent! t) (assoc! t :a 1))"} + {:suite "transient / invalidation" :label "persistent! twice" :expected :throws :actual "(let [t (transient [])] (persistent! t) (persistent! t))"} + {:suite "transient / invalidation" :label "pop! empty" :expected :throws :actual "(pop! (transient []))"} + {:suite "transient / strictness" :label "conj! on persistent" :expected :throws :actual "(conj! [1 2] 3)"} + {:suite "transient / strictness" :label "assoc! on persistent" :expected :throws :actual "(assoc! {:a 1} :b 2)"} + {:suite "transient / strictness" :label "persistent! on vector" :expected :throws :actual "(persistent! [1 2])"} + {:suite "transient / strictness" :label "persistent! on nil" :expected :throws :actual "(persistent! nil)"} + {:suite "transient / strictness" :label "pop! on transient map" :expected :throws :actual "(pop! (transient {:a 1}))"} + {:suite "transient / strictness" :label "dissoc! on tset" :expected :throws :actual "(dissoc! (transient #{1}) 1)"} + {:suite "transient / strictness" :label "conj! map bad item" :expected :throws :actual "(conj! (transient {}) #{:a 1})"} + {:suite "transient / strictness" :label "conj! no args" :expected "[]" :actual "(persistent! (conj!))"} + {:suite "transient / strictness" :label "conj! identity" :expected "[1 2]" :actual "(conj! [1 2])"} + {:suite "transient / strictness" :label "conj! map merges map" :expected "{:a 1, :b 2}" :actual "(persistent! (conj! (transient {:a 1}) {:b 2}))"} + {:suite "transient / assoc! bounds" :label "assoc! existing idx" :expected "[1 9 3]" :actual "(persistent! (assoc! (transient [1 2 3]) 1 9))"} + {:suite "transient / assoc! bounds" :label "assoc! at count grows" :expected "[1 2 3]" :actual "(persistent! (assoc! (transient [1 2]) 2 3))"} + {:suite "transient / assoc! bounds" :label "assoc! out of bounds" :expected :throws :actual "(assoc! (transient [0 1 2]) 4 4)"} + {:suite "transient / assoc! bounds" :label "assoc! negative" :expected :throws :actual "(assoc! (transient []) -1 0)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "nil is falsy" :expected ":f" :actual "(if nil :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "false is falsy" :expected ":f" :actual "(if false :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "zero is truthy" :expected ":t" :actual "(if 0 :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "zero float truthy" :expected ":t" :actual "(if 0.0 :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "empty string truthy" :expected ":t" :actual "(if \"\" :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "empty list truthy" :expected ":t" :actual "(if (list) :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "empty vector truthy" :expected ":t" :actual "(if [] :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "empty map truthy" :expected ":t" :actual "(if {} :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "empty set truthy" :expected ":t" :actual "(if #{} :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "number truthy" :expected ":t" :actual "(if 42 :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "string truthy" :expected ":t" :actual "(if \"x\" :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "keyword truthy" :expected ":t" :actual "(if :kw :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "symbol truthy" :expected ":t" :actual "(if (quote abc) :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "coll truthy" :expected ":t" :actual "(if [1 2] :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "map truthy" :expected ":t" :actual "(if {:a 1} :t :f)"} + {:suite "truthiness / if (only nil & false are falsy)" :label "if no else -> nil" :expected "nil" :actual "(if false :t)"} + {:suite "truthiness / not" :label "not nil" :expected "true" :actual "(not nil)"} + {:suite "truthiness / not" :label "not false" :expected "true" :actual "(not false)"} + {:suite "truthiness / not" :label "not zero" :expected "false" :actual "(not 0)"} + {:suite "truthiness / not" :label "not empty vector" :expected "false" :actual "(not [])"} + {:suite "truthiness / not" :label "not empty string" :expected "false" :actual "(not \"\")"} + {:suite "truthiness / not" :label "not number" :expected "false" :actual "(not 42)"} + {:suite "truthiness / not" :label "not true" :expected "false" :actual "(not true)"} + {:suite "truthiness / and" :label "empty is true" :expected "true" :actual "(and)"} + {:suite "truthiness / and" :label "single value" :expected "5" :actual "(and 5)"} + {:suite "truthiness / and" :label "all truthy -> last" :expected "3" :actual "(and 1 2 3)"} + {:suite "truthiness / and" :label "stops at false" :expected "false" :actual "(and 1 false 3)"} + {:suite "truthiness / and" :label "stops at nil" :expected "nil" :actual "(and 1 nil 3)"} + {:suite "truthiness / and" :label "false alone" :expected "false" :actual "(and false)"} + {:suite "truthiness / and" :label "nil alone" :expected "nil" :actual "(and nil)"} + {:suite "truthiness / and" :label "zero is truthy" :expected "0" :actual "(and 1 0)"} + {:suite "truthiness / or" :label "empty is nil" :expected "nil" :actual "(or)"} + {:suite "truthiness / or" :label "first truthy" :expected "1" :actual "(or 1 2)"} + {:suite "truthiness / or" :label "skips nil/false" :expected "5" :actual "(or nil false 5)"} + {:suite "truthiness / or" :label "all falsy -> last" :expected "false" :actual "(or nil false)"} + {:suite "truthiness / or" :label "nil chain -> false" :expected "false" :actual "(or nil nil nil false)"} + {:suite "truthiness / or" :label "zero is truthy" :expected "0" :actual "(or 0 1)"} + {:suite "truthiness / or" :label "false alone" :expected "false" :actual "(or false)"} + {:suite "truthiness / if-not & boolean" :label "if-not false" :expected ":yes" :actual "(if-not false :yes :no)"} + {:suite "truthiness / if-not & boolean" :label "if-not truthy" :expected ":no" :actual "(if-not 0 :yes :no)"} + {:suite "truthiness / if-not & boolean" :label "when-not nil" :expected "1" :actual "(when-not nil 1)"} + {:suite "truthiness / if-not & boolean" :label "when-not truthy" :expected "nil" :actual "(when-not 5 1)"} + {:suite "truthiness / if-not & boolean" :label "boolean of nil" :expected "false" :actual "(boolean nil)"} + {:suite "truthiness / if-not & boolean" :label "boolean of false" :expected "false" :actual "(boolean false)"} + {:suite "truthiness / if-not & boolean" :label "boolean of 0" :expected "true" :actual "(boolean 0)"} + {:suite "truthiness / if-not & boolean" :label "boolean of value" :expected "true" :actual "(boolean :x)"} + {:suite "truthiness / if-not & boolean" :label "true?/false?" :expected "true" :actual "(and (true? true) (false? false) (not (true? 1)))"} + {:suite "untested / primed + division + bit ops" :label "+'" :expected "3" :actual "(+' 1 2)"} + {:suite "untested / primed + division + bit ops" :label "-'" :expected "3" :actual "(-' 5 2)"} + {:suite "untested / primed + division + bit ops" :label "*'" :expected "12" :actual "(*' 3 4)"} + {:suite "untested / primed + division + bit ops" :label "inc'" :expected "2.5" :actual "(inc' 1.5)"} + {:suite "untested / primed + division + bit ops" :label "dec'" :expected "1.5" :actual "(dec' 2.5)"} + {:suite "untested / primed + division + bit ops" :label "/" :expected "2" :actual "(/ 6 3)"} + {:suite "untested / primed + division + bit ops" :label "/ ratio-as-double" :expected "1/2" :actual "(/ 1 2)"} + {:suite "untested / primed + division + bit ops" :label "bit-not" :expected "-6" :actual "(bit-not 5)"} + {:suite "untested / primed + division + bit ops" :label "bit-and-not" :expected "4" :actual "(bit-and-not 12 10)"} + {:suite "untested / primed + division + bit ops" :label "bit-flip" :expected "3" :actual "(bit-flip 2 0)"} + {:suite "untested / primed + division + bit ops" :label "unsigned-bit-shift-right" :expected "2" :actual "(unsigned-bit-shift-right 8 2)"} + {:suite "untested / hash family" :label "hash stable" :expected "true" :actual "(= (hash :a) (hash :a))"} + {:suite "untested / hash family" :label "hash int" :expected "true" :actual "(int? (hash [1 2]))"} + {:suite "untested / hash family" :label "hash-combine" :expected "true" :actual "(int? (hash-combine 1 2))"} + {:suite "untested / hash family" :label "hash-ordered-coll" :expected "true" :actual "(int? (hash-ordered-coll [1 2]))"} + {:suite "untested / hash family" :label "hash-unordered-coll" :expected "true" :actual "(int? (hash-unordered-coll #{1}))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "make-array" :expected "[nil nil nil]" :actual "(vec (make-array Object 3))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "into-array" :expected "[1 2]" :actual "(vec (into-array [1 2]))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "to-array" :expected "[1 2]" :actual "(vec (to-array [1 2]))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aclone vec" :expected "[1 2]" :actual "(vec (aclone (int-array [1 2])))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aclone independent" :expected "[9 2]" :actual "(let [a (aclone (to-array [1 2]))] (aset a 0 9) (seq a))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset/aget" :expected "9" :actual "(let [a (to-array [1 2 3])] (aset a 0 9) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-int" :expected "7" :actual "(let [a (to-array [1 2])] (aset-int a 0 7) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-boolean" :expected "true" :actual "(let [a (to-array [1])] (aset-boolean a 0 true) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-byte" :expected "9" :actual "(let [a (to-array [0])] (aset-byte a 0 9) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-char" :expected "\\a" :actual "(let [a (to-array [0])] (aset-char a 0 \\a) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-double" :expected "1.5" :actual "(let [a (to-array [0])] (aset-double a 0 1.5) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-float" :expected "2.5" :actual "(let [a (to-array [0])] (aset-float a 0 2.5) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-long" :expected "3" :actual "(let [a (to-array [0])] (aset-long a 0 3) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "aset-short" :expected "4" :actual "(let [a (to-array [0])] (aset-short a 0 4) (aget a 0))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "boolean-array" :expected "[false false]" :actual "(vec (boolean-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "int-array" :expected "[1 2]" :actual "(vec (int-array [1 2]))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "long-array" :expected "[0 0]" :actual "(vec (long-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "double-array" :expected "[0.0 0.0]" :actual "(vec (double-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "float-array" :expected "[0.0 0.0]" :actual "(vec (float-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "short-array" :expected "[0 0]" :actual "(vec (short-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "char-array count" :expected "2" :actual "(count (char-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "byte-array bytes?" :expected "true" :actual "(bytes? (byte-array 2))"} + {:suite "untested / array stubs (vectors + host buffers)" :label "bytes? not vec" :expected "false" :actual "(bytes? [1])"} + {:suite "untested / typed coercion views" :label "booleans" :expected "(quote (true))" :actual "(booleans [true])"} + {:suite "untested / typed coercion views" :label "doubles" :expected "[1.0]" :actual "(vec (doubles (double-array [1.0])))"} + {:suite "untested / typed coercion views" :label "floats" :expected "[1.0]" :actual "(vec (floats (float-array [1.0])))"} + {:suite "untested / typed coercion views" :label "ints" :expected "(quote (1))" :actual "(ints [1])"} + {:suite "untested / typed coercion views" :label "longs" :expected "(quote (1))" :actual "(longs [1])"} + {:suite "untested / typed coercion views" :label "shorts" :expected "(quote (1))" :actual "(shorts [1])"} + {:suite "untested / typed coercion views" :label "chars first" :expected "\\a" :actual "(first (chars [\\a]))"} + {:suite "untested / typed coercion views" :label "bytes view" :expected "true" :actual "(bytes? (bytes [65]))"} + {:suite "untested / typed coercion views" :label "byte" :expected "65" :actual "(byte 65)"} + {:suite "untested / typed coercion views" :label "short" :expected "1" :actual "(short 1)"} + {:suite "untested / typed coercion views" :label "long truncates" :expected "1" :actual "(long 1.7)"} + {:suite "untested / typed coercion views" :label "double" :expected "3.0" :actual "(double 3)"} + {:suite "untested / typed coercion views" :label "float" :expected "3.0" :actual "(float 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-add" :expected "3" :actual "(unchecked-add 1 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-add-int" :expected "3" :actual "(unchecked-add-int 1 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-subtract" :expected "3" :actual "(unchecked-subtract 5 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-subtract-int" :expected "3" :actual "(unchecked-subtract-int 5 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-multiply" :expected "6" :actual "(unchecked-multiply 2 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-multiply-int" :expected "6" :actual "(unchecked-multiply-int 2 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-inc" :expected "2" :actual "(unchecked-inc 1)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-inc-int" :expected "2" :actual "(unchecked-inc-int 1)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-dec" :expected "2" :actual "(unchecked-dec 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-dec-int" :expected "2" :actual "(unchecked-dec-int 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-negate" :expected "-4" :actual "(unchecked-negate 4)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-negate-int" :expected "-4" :actual "(unchecked-negate-int 4)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-divide-int" :expected "3" :actual "(unchecked-divide-int 7 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-remainder-int" :expected "1" :actual "(unchecked-remainder-int 7 2)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-int" :expected "3" :actual "(unchecked-int 3.7)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-long" :expected "3" :actual "(unchecked-long 3.7)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-double" :expected "3.0" :actual "(unchecked-double 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-float" :expected "3.0" :actual "(unchecked-float 3)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-byte" :expected "65" :actual "(unchecked-byte 65)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-char" :expected "\\a" :actual "(unchecked-char 97)"} + {:suite "untested / unchecked-* are plain ops" :label "unchecked-short" :expected "5" :actual "(unchecked-short 5)"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk round-trip" :expected "1" :actual "(let [cb (chunk-buffer 4)] (chunk-append cb 1) (chunk-first (chunk-cons (chunk cb) nil)))"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "cat transducer" :expected "[1 2 3]" :actual "(into [] cat [[1] [2 3]])"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "ensure-reduced wraps" :expected "true" :actual "(reduced? (ensure-reduced 5))"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "ensure-reduced keeps reduced" :expected "true" :actual "(reduced? (ensure-reduced (reduced 5)))"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "halt-when" :expected "4" :actual "(transduce (halt-when even?) conj [] [1 3 4 5])"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk-next exhausted" :expected "nil" :actual "(let [cb (chunk-buffer 2)] (chunk-append cb 1) (chunk-next (chunk-cons (chunk cb) nil)))"} + {:suite "untested / chunk family (eager equivalents) + cat" :label "chunk-rest seqable" :expected "[]" :actual "(let [cb (chunk-buffer 2)] (chunk-append cb 1) (vec (chunk-rest (chunk-cons (chunk cb) nil))))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class number" :expected "java.lang.Long" :actual "(class 1)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class string" :expected "java.lang.String" :actual "(class \"s\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class keyword" :expected "clojure.lang.Keyword" :actual "(class :k)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "class nil" :expected "nil" :actual "(class nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "bean is the map" :expected "{:a 1}" :actual "(bean {:a 1})"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "biginteger" :expected "\"5\"" :actual "(str (biginteger 5))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy resolves nil" :expected "nil" :actual "(proxy [Object] [] (toString [] \"x\"))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "construct-proxy throws" :expected :throws :actual "(construct-proxy nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "get-proxy-class throws" :expected :throws :actual "(get-proxy-class)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "init-proxy" :expected "nil" :actual "(init-proxy nil {})"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "update-proxy" :expected "nil" :actual "(update-proxy nil {})"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-mappings" :expected "{}" :actual "(proxy-mappings nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-call-with-super calls" :expected "1" :actual "(proxy-call-with-super (fn [] 1) nil \"m\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn upper" :expected "\"ABC\"" :actual "((memfn toUpperCase) \"abc\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn with args" :expected "2" :actual "((memfn indexOf needle) \"hello\" \"l\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "memfn length" :expected "3" :actual "((memfn length) \"abc\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "array-seq" :expected "(quote (1 2 3))" :actual "(array-seq (to-array [1 2 3]))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "array-seq empty" :expected "nil" :actual "(array-seq (to-array []))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "proxy-super throws" :expected :throws :actual "(proxy-super count [1])"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "re-groups throws" :expected :throws :actual "(re-groups (re-matcher #\"a\" \"b\"))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "re-matcher builds" :expected "false" :actual "(nil? (re-matcher #\"a\" \"abc\"))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "print-dup nil writer throws" :expected :throws :actual "(print-dup 1 nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "print-method nil writer throws" :expected :throws :actual "(print-method 1 nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "uri? string" :expected "false" :actual "(uri? \"http://x\")"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "uri? nil" :expected "false" :actual "(uri? nil)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "definterface defines" :expected "false" :actual "(var? (definterface IFoo (foo [x])))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "enumeration-seq" :expected "(quote (1 2))" :actual "(enumeration-seq [1 2])"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "iterator-seq" :expected "(quote (1 2))" :actual "(iterator-seq [1 2])"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "seque passthrough" :expected "[1 2]" :actual "(seque [1 2])"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "delay? true" :expected "true" :actual "(delay? (delay 1))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "delay? false" :expected "false" :actual "(delay? 1)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "future-call" :expected "42" :actual "(deref (future-call (fn [] 42)))"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label ". calls String surface" :expected "3" :actual "(. \"abc\" length)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label ".. threads members" :expected "\"ABC\"" :actual "(.. \"abc\" toUpperCase)"} + {:suite "untested / JVM-shape stubs (documented jolt behavior)" :label "unknown String member throws" :expected :throws :actual "(. \"abc\" frobnicate)"} + {:suite "untested / protocols: extend + extends?" :label "extend registers" :expected ":str" :actual "(do (defprotocol Pe (pe [x])) (extend (quote String) Pe {:pe (fn [x] :str)}) (pe \"s\"))"} + {:suite "untested / protocols: extend + extends?" :label "extend two methods" :expected "[1 2]" :actual "(do (defprotocol P3 (pa [x]) (pb [x])) (extend (quote Long) P3 {:pa (fn [x] 1) :pb (fn [x] 2)}) [(pa 0) (pb 0)])"} + {:suite "untested / protocols: extend + extends?" :label "extends? after extend" :expected "true" :actual "(do (defprotocol P4 (pc [x])) (extend (quote Long) P4 {:pc (fn [x] 1)}) (extends? P4 (quote Long)))"} + {:suite "untested / protocols: extend + extends?" :label "extends? without" :expected "false" :actual "(do (defprotocol P5 (pd [x])) (extends? P5 (quote Long)))"} + {:suite "untested / ns + REPL machinery" :label "all-ns non-empty" :expected "true" :actual "(pos? (count (all-ns)))"} + {:suite "untested / ns + REPL machinery" :label "ns-interns sees def" :expected "true" :actual "(do (def zz 1) (pos? (count (ns-interns (quote user)))))"} + {:suite "untested / ns + REPL machinery" :label "ns-interns countable" :expected "true" :actual "(map? (ns-interns (quote user)))"} + {:suite "untested / ns + REPL machinery" :label "ns-imports empty user" :expected "96" :actual "(count (ns-imports (quote user)))"} + {:suite "untested / ns + REPL machinery" :label "reset-meta!" :expected "{:doc \"d\"}" :actual "(do (def vv 1) (reset-meta! (var vv) {:doc \"d\"}))"} + {:suite "untested / ns + REPL machinery" :label "prefers empty" :expected "{}" :actual "(do (defmulti mm identity) (prefers mm))"} + {:suite "untested / ns + REPL machinery" :label "refer-clojure" :expected "nil" :actual "(refer-clojure)"} + {:suite "untested / ns + REPL machinery" :label "special-symbol? if" :expected "true" :actual "(special-symbol? (quote if))"} + {:suite "untested / ns + REPL machinery" :label "special-symbol? fn name" :expected "false" :actual "(special-symbol? (quote foo))"} + {:suite "untested / ns + REPL machinery" :label "destructure expands" :expected "true" :actual "(pos? (count (destructure (quote [[a b] x]))))"} + {:suite "untested / ns + REPL machinery" :label "seq-to-map-for-destructuring" :expected "{:a 1}" :actual "(seq-to-map-for-destructuring (quote (:a 1)))"} + {:suite "untested / ns + REPL machinery" :label "s2m trailing map passes through" :expected "{:b 2}" :actual "(seq-to-map-for-destructuring (list {:b 2}))"} + {:suite "untested / ns + REPL machinery" :label "s2m unpaired key throws" :expected :throws :actual "(seq-to-map-for-destructuring (quote (:a 1 :b)))"} + {:suite "untested / ns + REPL machinery" :label "s2m kwargs trailing map call" :expected "2" :actual "((fn [& {:keys [b]}] b) {:b 2})"} + {:suite "untested / ns + REPL machinery" :label "*clojure-version* major" :expected "1" :actual "(:major *clojure-version*)"} + {:suite "untested / ns + REPL machinery" :label "*ns* user" :expected "\"user\"" :actual "(str *ns*)"} + {:suite "untested / ns + REPL machinery" :label "*1 nil outside repl" :expected "nil" :actual "*1"} + {:suite "untested / ns + REPL machinery" :label "*2 nil" :expected "nil" :actual "*2"} + {:suite "untested / ns + REPL machinery" :label "*3 nil" :expected "nil" :actual "*3"} + {:suite "untested / ns + REPL machinery" :label "*e nil" :expected "nil" :actual "*e"} + {:suite "untested / ns + REPL machinery" :label "*unchecked-math*" :expected "false" :actual "*unchecked-math*"} + {:suite "untested / ns + REPL machinery" :label "*in* bound" :expected "false" :actual "(map? *in*)"} + {:suite "untested / misc seqs + binding machinery" :label "nfirst" :expected "[2]" :actual "(nfirst [[1 2] [3]])"} + {:suite "untested / misc seqs + binding machinery" :label "xml-seq root" :expected "1" :actual "(count (xml-seq {:tag :a :content []}))"} + {:suite "untested / misc seqs + binding machinery" :label "xml-seq walks" :expected "2" :actual "(count (xml-seq {:tag :a :content [{:tag :b :content []}]}))"} + {:suite "untested / misc seqs + binding machinery" :label "comp keyword stage" :expected "[1 2]" :actual "((comp seq :content) {:content [1 2]})"} + {:suite "untested / misc seqs + binding machinery" :label "comp three stages" :expected "4" :actual "((comp inc inc :n) {:n 2})"} + {:suite "untested / misc seqs + binding machinery" :label "random-sample all" :expected "[1 2]" :actual "(random-sample 1.0 [1 2])"} + {:suite "untested / misc seqs + binding machinery" :label "random-sample none" :expected "[]" :actual "(random-sample 0.0 [1 2])"} + {:suite "untested / misc seqs + binding machinery" :label "reader-conditional builds" :expected "true" :actual "(reader-conditional? (reader-conditional (quote (:clj 1)) false))"} + {:suite "untested / misc seqs + binding machinery" :label "->Eduction" :expected "[2 3]" :actual "(vec (->Eduction (map inc) [1 2]))"} + {:suite "untested / misc seqs + binding machinery" :label "bound-fn calls" :expected "42" :actual "((bound-fn [] 42))"} + {:suite "untested / misc seqs + binding machinery" :label "push/pop-thread-bindings" :expected ":ok" :actual "(do (push-thread-bindings {}) (pop-thread-bindings) :ok)"} + {:suite "uuid / random-uuid" :label "returns a uuid" :expected "true" :actual "(uuid? (random-uuid))"} + {:suite "uuid / random-uuid" :label "str is 36 chars" :expected "36" :actual "(count (str (random-uuid)))"} + {:suite "uuid / random-uuid" :label "8-4-4-4-12 shape" :expected "[8 4 4 4 12]" :actual "(do (require (quote [clojure.string :as s])) (mapv count (s/split (str (random-uuid)) #\"-\")))"} + {:suite "uuid / random-uuid" :label "version nibble is 4" :expected "\\4" :actual "(nth (str (random-uuid)) 14)"} + {:suite "uuid / random-uuid" :label "variant nibble 8-b" :expected "true" :actual "(contains? #{\\8 \\9 \\a \\b} (nth (seq (str (random-uuid))) 19))"} + {:suite "uuid / random-uuid" :label "distinct" :expected "10" :actual "(count (set (repeatedly 10 random-uuid)))"} + {:suite "uuid / random-uuid" :label "all hex digits" :expected "true" :actual "(every? (fn [c] (contains? (set (seq \"0123456789abcdef-\")) c)) (seq (str (random-uuid))))"} + {:suite "uuid / parse-uuid" :label "valid round-trips" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "uuid / parse-uuid" :label "parses to uuid" :expected "true" :actual "(uuid? (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "uuid / parse-uuid" :label "case-insensitive =" :expected "true" :actual "(= (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") (parse-uuid \"B6883C0A-0342-4007-9966-BC2DFA6B109E\"))"} + {:suite "uuid / parse-uuid" :label "empty -> nil" :expected "nil" :actual "(parse-uuid \"\")"} + {:suite "uuid / parse-uuid" :label "short -> nil" :expected "nil" :actual "(parse-uuid \"0\")"} + {:suite "uuid / parse-uuid" :label "garbage -> nil" :expected "nil" :actual "(parse-uuid \"df0993\")"} + {:suite "uuid / parse-uuid" :label "too long -> nil" :expected "nil" :actual "(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109eb\")"} + {:suite "uuid / parse-uuid" :label "leading extra -> nil" :expected "nil" :actual "(parse-uuid \"ab6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / parse-uuid" :label "non-hex -> nil" :expected "nil" :actual "(parse-uuid \"g6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / parse-uuid" :label "bad dashes -> nil" :expected "nil" :actual "(parse-uuid \"b6883c0a00342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / parse-uuid" :label "non-string throws" :expected :throws :actual "(parse-uuid 1000)"} + {:suite "uuid / parse-uuid" :label "keyword throws" :expected :throws :actual "(parse-uuid :key)"} + {:suite "uuid / parse-uuid" :label "map throws" :expected :throws :actual "(parse-uuid {})"} + {:suite "uuid / value semantics" :label "equal by value" :expected "true" :actual "(= (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "uuid / value semantics" :label "unequal differs" :expected "false" :actual "(= (random-uuid) (random-uuid))"} + {:suite "uuid / value semantics" :label "works as map key" :expected ":v" :actual "(let [u (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")] (get {u :v} (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")))"} + {:suite "uuid / value semantics" :label "works in a set" :expected "true" :actual "(contains? #{(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")} (parse-uuid \"B6883C0A-0342-4007-9966-BC2DFA6B109E\"))"} + {:suite "uuid / value semantics" :label "uuid? false on string" :expected "false" :actual "(uuid? \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / value semantics" :label "uuid? false on nil" :expected "false" :actual "(uuid? nil)"} + {:suite "uuid / #uuid reader literal" :label "reads to uuid" :expected "true" :actual "(uuid? #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / #uuid reader literal" :label "= parse-uuid" :expected "true" :actual "(= #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\" (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "uuid / #uuid reader literal" :label "str of literal" :expected "\"b6883c0a-0342-4007-9966-bc2dfa6b109e\"" :actual "(str #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "uuid / #uuid reader literal" :label "pr-str round-trips" :expected "\"#uuid \\\"b6883c0a-0342-4007-9966-bc2dfa6b109e\\\"\"" :actual "(pr-str #uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\")"} + {:suite "vector / construct & predicate" :label "literal" :expected "[1 2 3]" :actual "[1 2 3]"} + {:suite "vector / construct & predicate" :label "vector" :expected "[1 2 3]" :actual "(vector 1 2 3)"} + {:suite "vector / construct & predicate" :label "vector zero args" :expected "[]" :actual "(vector)"} + {:suite "vector / construct & predicate" :label "vec from list" :expected "[1 2 3]" :actual "(vec (list 1 2 3))"} + {:suite "vector / construct & predicate" :label "vec from range" :expected "[0 1 2]" :actual "(vec (range 3))"} + {:suite "vector / construct & predicate" :label "vec of map yields entries" :expected "[[:a 1]]" :actual "(vec {:a 1})"} + {:suite "vector / construct & predicate" :label "vector? true" :expected "true" :actual "(vector? [1])"} + {:suite "vector / construct & predicate" :label "vector? false on list" :expected "false" :actual "(vector? (list 1))"} + {:suite "vector / construct & predicate" :label "vector = list elts" :expected "true" :actual "(= [1 2 3] (list 1 2 3))"} + {:suite "vector / access" :label "nth" :expected ":b" :actual "(nth [:a :b :c] 1)"} + {:suite "vector / access" :label "nth default" :expected ":x" :actual "(nth [:a] 5 :x)"} + {:suite "vector / access" :label "get by index" :expected ":b" :actual "(get [:a :b] 1)"} + {:suite "vector / access" :label "get out of range nil" :expected "nil" :actual "(get [:a] 5)"} + {:suite "vector / access" :label "get default" :expected ":x" :actual "(get [:a] 5 :x)"} + {:suite "vector / access" :label "first" :expected "1" :actual "(first [1 2 3])"} + {:suite "vector / access" :label "last" :expected "3" :actual "(last [1 2 3])"} + {:suite "vector / access" :label "peek is last" :expected "3" :actual "(peek [1 2 3])"} + {:suite "vector / access" :label "count" :expected "3" :actual "(count [1 2 3])"} + {:suite "vector / access" :label "contains? index" :expected "true" :actual "(contains? [:a :b] 1)"} + {:suite "vector / access" :label "contains? past end" :expected "false" :actual "(contains? [:a] 3)"} + {:suite "vector / access" :label "vector as fn" :expected ":b" :actual "([:a :b :c] 1)"} + {:suite "vector / access" :label "vector-in-local as fn" :expected "20" :actual "(let [v [10 20 30]] (v 1))"} + {:suite "vector / access" :label "keyword-in-local as fn" :expected "7" :actual "(let [k :a] (k {:a 7}))"} + {:suite "vector / access" :label "meta vector as fn" :expected "10" :actual "((with-meta [10 20] {:k 1}) 0)"} + {:suite "vector / update (persistent)" :label "conj appends" :expected "[1 2 3]" :actual "(conj [1 2] 3)"} + {:suite "vector / update (persistent)" :label "conj many" :expected "[1 2 3 4]" :actual "(conj [1 2] 3 4)"} + {:suite "vector / update (persistent)" :label "assoc index" :expected "[1 9 3]" :actual "(assoc [1 2 3] 1 9)"} + {:suite "vector / update (persistent)" :label "assoc at count appends" :expected "[1 2 3]" :actual "(assoc [1 2] 2 3)"} + {:suite "vector / update (persistent)" :label "update" :expected "[1 3 3]" :actual "(update [1 2 3] 1 inc)"} + {:suite "vector / update (persistent)" :label "pop drops last" :expected "[1 2]" :actual "(pop [1 2 3])"} + {:suite "vector / update (persistent)" :label "subvec start end" :expected "[2 3]" :actual "(subvec [1 2 3 4] 1 3)"} + {:suite "vector / update (persistent)" :label "subvec to end" :expected "[3 4]" :actual "(subvec [1 2 3 4] 2)"} + {:suite "vector / update (persistent)" :label "mapv" :expected "[2 3 4]" :actual "(mapv inc [1 2 3])"} + {:suite "vector / update (persistent)" :label "filterv" :expected "[2 4]" :actual "(filterv even? [1 2 3 4])"} + {:suite "vector / immutability & nesting" :label "conj does not mutate" :expected "true" :actual "(let [v [1 2] w (conj v 3)] (and (= v [1 2]) (= w [1 2 3])))"} + {:suite "vector / immutability & nesting" :label "assoc does not mutate" :expected "true" :actual "(let [v [1 2 3] w (assoc v 0 9)] (and (= v [1 2 3]) (= w [9 2 3])))"} + {:suite "vector / immutability & nesting" :label "get-in" :expected "2" :actual "(get-in [[1 2] [3 4]] [0 1])"} + {:suite "vector / immutability & nesting" :label "assoc-in" :expected "[[1 9]]" :actual "(assoc-in [[1 2]] [0 1] 9)"} + {:suite "vector / immutability & nesting" :label "update-in" :expected "[[1 3]]" :actual "(update-in [[1 2]] [0 1] inc)"} + {:suite "vector / immutability & nesting" :label "large vector nth" :expected "1500" :actual "(nth (vec (range 2000)) 1500)"} + {:suite "vector / immutability & nesting" :label "large vector count" :expected "2000" :actual "(count (vec (range 2000)))"} + {:suite "vector / immutability & nesting" :label "large conj immutable" :expected "true" :actual "(let [v (vec (range 1000)) w (conj v :end)] (and (= 1000 (count v)) (= 1001 (count w))))"} + {:suite "vector / bulk build boundaries" :label "count at 1025" :expected "1025" :actual "(count (vec (range 1025)))"} + {:suite "vector / bulk build boundaries" :label "into = vec at 1025" :expected "true" :actual "(= (vec (range 1025)) (into [] (range 1025)))"} + {:suite "vector / bulk build boundaries" :label "nth at leaf boundary" :expected "32" :actual "(nth (vec (range 1025)) 32)"} + {:suite "vector / bulk build boundaries" :label "nth at root boundary" :expected "1024" :actual "(nth (vec (range 1025)) 1024)"} + {:suite "vector / bulk build boundaries" :label "vec=into at 33" :expected "true" :actual "(= (vec (range 33)) (into [] (range 33)))"} + {:suite "vector / bulk build boundaries" :label "conj after bulk 1024" :expected "1025" :actual "(count (conj (vec (range 1024)) :x))"} + {:suite "vector / bulk build boundaries" :label "conj-after reads back" :expected ":x" :actual "(nth (conj (vec (range 1024)) :x) 1024)"} + {:suite "vector / bulk build boundaries" :label "assoc into bulk vec" :expected "9" :actual "(nth (assoc (vec (range 1025)) 1000 9) 1000)"} + {:suite "vector / bulk build boundaries" :label "into onto non-empty" :expected "[0 1 2 0 1]" :actual "(into (vec (range 3)) (range 2))"} + {:suite "clojure.walk / lists + seqs" :label "postwalk-replace symbol keys in a list" :expected "(quote (+ 2 2))" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {(quote x) 2} (quote (+ x x))))"} + {:suite "clojure.walk / lists + seqs" :label "postwalk descends a list" :expected "[:a :a]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk (fn [n] (if (symbol? n) :a n)) (quote (x y))))"} + {:suite "clojure.walk / lists + seqs" :label "prewalk-replace in a list" :expected "(quote (* 3 3))" :actual "(do (require (quote [clojure.walk :as w])) (w/prewalk-replace {(quote *) (quote *) (quote y) 3} (quote (* y y))))"} + {:suite "clojure.walk / lists + seqs" :label "nested list + vector" :expected "[1 [2 1]]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {:a 1 :b 2} (quote (:a [:b :a]))))"} + {:suite "clojure.walk / lists + seqs" :label "postwalk-replace in a vector" :expected "[:one 2 :one]" :actual "(do (require (quote [clojure.walk :as w])) (w/postwalk-replace {1 :one} [1 2 1]))"} + {:suite "clojure.walk / lists + seqs" :label "keywordize-keys still works" :expected "{:a 1}" :actual "(do (require (quote [clojure.walk :as w])) (w/keywordize-keys {\"a\" 1}))"} + {:suite "clojure.walk / lists + seqs" :label "apply-template substitutes" :expected "(quote (+ 1 2))" :actual "(do (require (quote [clojure.template :as t])) (t/apply-template (quote [x y]) (quote (+ x y)) (quote (1 2))))"} + {:suite "clojure.walk / records keep their type" :label "postwalk preserves record type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (w/postwalk identity (->R 1))))"} + {:suite "clojure.walk / records keep their type" :label "postwalk still walks record fields" :expected "2" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (:a (w/postwalk (fn [x] (if (number? x) (inc x) x)) (->R 1))))"} + {:suite "clojure.walk / records keep their type" :label "instance? survives a walk" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (instance? R (w/postwalk identity (->R 1))))"} + {:suite "clojure.walk / records keep their type" :label "a record nested in a map keeps its type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (:r (w/postwalk identity {:r (->R 1)}))))"} + {:suite "clojure.walk / records keep their type" :label "prewalk preserves record type" :expected "true" :actual "(do (require (quote [clojure.walk :as w])) (defrecord R [a]) (record? (w/prewalk identity (->R 1))))"} + {:suite "reader / auto-resolved keywords" :label "::kw is namespace-qualified" :expected "true" :actual "(some? (namespace ::foo))"} + {:suite "reader / auto-resolved keywords" :label "::kw keeps its name" :expected "\"foo\"" :actual "(name ::foo)"} + {:suite "reader / auto-resolved keywords" :label "::kw resolves to the current ns" :expected "true" :actual "(= ::a ::a)"} + {:suite "clojure.edn / reader opts" :label ":default receives the tag as a symbol" :expected "[true \"foo\" 5]" :actual "(do (require (quote [clojure.edn :as edn])) (let [r (edn/read-string {:default (fn [t v] [t v])} \"#foo 5\")] [(symbol? (first r)) (name (first r)) (second r)]))"} + {:suite "metadata / lazy seqs carry meta" :label "with-meta on a lazy seq" :expected "{:k 1}" :actual "(meta (with-meta (map inc [1 2 3]) {:k 1}))"} + {:suite "dynamic vars / *print-meta*" :label "*print-meta* is a bindable dynamic var" :expected "true" :actual "(binding [*print-meta* true] (true? *print-meta*))"} + {:suite "tagged literals / value equality" :label "equal tag+form are =" :expected "true" :actual "(= (tagged-literal (quote x) [1 2]) (tagged-literal (quote x) [1 2]))"} + {:suite "tagged literals / value equality" :label "different tag is not =" :expected "false" :actual "(= (tagged-literal (quote x) [1]) (tagged-literal (quote y) [1]))"} + {:suite "tagged literals / value equality" :label "dedup as map keys" :expected "1" :actual "(count {(tagged-literal (quote x) [1]) :a (tagged-literal (quote x) [1]) :b})"} + {:suite "interop / clojure.lang interfaces" :label "vector is IObj" :expected "true" :actual "(instance? clojure.lang.IObj [1])"} + {:suite "interop / clojure.lang interfaces" :label "map entry is IMapEntry" :expected "true" :actual "(instance? clojure.lang.IMapEntry (first {:a 1}))"} + {:suite "interop / clojure.lang interfaces" :label "record is IRecord" :expected "true" :actual "(do (defrecord R [a]) (instance? clojure.lang.IRecord (->R 1)))"} + {:suite "interop / clojure.lang interfaces" :label "number is not IObj" :expected "false" :actual "(instance? clojure.lang.IObj 5)"} + {:suite "reader / default data readers" :label "#inst is in default-data-readers" :expected "true" :actual "(boolean (get default-data-readers (quote inst)))"} + {:suite "conformance / CRITICAL: lazy sequences" :label "self-ref lazy-cat fib" :expected "[0 1 1 2 3 5 8 13 21 34]" :actual "(do (def fib-seq (lazy-cat [0 1] (map + (rest fib-seq) fib-seq))) (take 10 fib-seq))"} + {:suite "conformance / CRITICAL: multi-collection map" :label "map two colls" :expected "[11 22 33]" :actual "(map + [1 2 3] [10 20 30])"} + {:suite "conformance / CRITICAL: multi-collection map" :label "map three colls" :expected "[12 24 36]" :actual "(map + [1 2 3] [10 20 30] [1 2 3])"} + {:suite "conformance / CRITICAL: multi-collection map" :label "map uneven (shortest)" :expected "[[1 :a] [2 :b]]" :actual "(map vector [1 2 3] [:a :b])"} + {:suite "conformance / CRITICAL: multi-collection map" :label "map over range+vec" :expected "[1 3 5]" :actual "(map + (range 3) [1 2 3])"} + {:suite "conformance / CRITICAL: multi-collection map" :label "map fn list arg" :expected "[2 3 4]" :actual "(map inc (list 1 2 3))"} + {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "iterate" :expected "[0 1 2 3 4]" :actual "(take 5 (iterate inc 0))"} + {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "iterate double" :expected "[1 2 4 8 16]" :actual "(take 5 (iterate (fn [x] (* 2 x)) 1))"} + {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "range over inf map" :expected "[1 2 3]" :actual "(take 3 (map inc (range)))"} + {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "count of take" :expected "100" :actual "(count (take 100 (range)))"} + {:suite "conformance / CRITICAL: iterate / infinite seqs" :label "last of take" :expected "5" :actual "(last (take 5 (iterate inc 1)))"} + {:suite "conformance / CRITICAL: collections as IFn" :label "map as fn miss" :expected "nil" :actual "({:a 1} :z)"} + {:suite "conformance / CRITICAL: collections as IFn" :label "map as fn default" :expected "99" :actual "({:a 1} :z 99)"} + {:suite "conformance / CRITICAL: collections as IFn" :label "set literal computed" :expected "true" :actual "(= #{1 2} #{(inc 0) 2})"} + {:suite "conformance / CRITICAL: collections as IFn" :label "empty set literal" :expected "true" :actual "(empty? #{})"} + {:suite "conformance / CRITICAL: collections as IFn" :label "set literal count" :expected "3" :actual "(count #{1 2 3})"} + {:suite "conformance / CRITICAL: collections as IFn" :label "set literal in let" :expected "true" :actual "(let [x 5] (= #{5 6} #{x (inc x)}))"} + {:suite "conformance / CRITICAL: collections as IFn" :label "set? true" :expected "true" :actual "(set? #{1 2 3})"} + {:suite "conformance / CRITICAL: collections as IFn" :label "set? false" :expected "false" :actual "(set? [1 2])"} + {:suite "conformance / CRITICAL: collections as IFn" :label "disj one" :expected "#{1 3}" :actual "(disj #{1 2 3} 2)"} + {:suite "conformance / CRITICAL: collections as IFn" :label "disj many" :expected "#{1}" :actual "(disj #{1 2 3} 2 3)"} + {:suite "conformance / CRITICAL: collections as IFn" :label "disj absent" :expected "#{1 2}" :actual "(disj #{1 2} 5)"} + {:suite "conformance / CRITICAL: collections as IFn" :label "map fn over coll" :expected "[1 3]" :actual "(map {:a 1 :b 3} [:a :b])"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "vec of map-result" :expected "[2 3 4]" :actual "(vec (map inc [1 2 3]))"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "vec of range" :expected "[0 1 2 3 4]" :actual "(vec (range 5))"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into vec" :expected "[1 2 3 4 5 6]" :actual "(into [1 2 3] [4 5 6])"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into vec from lazy" :expected "[2 3 4]" :actual "(into [] (map inc [1 2 3]))"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into map pairs" :expected "{:a 1, :b 2}" :actual "(into {} [[:a 1] [:b 2]])"} + {:suite "conformance / CRITICAL: vec / into over lazy + maps" :label "into map onto map" :expected "{:a 1, :b 2, :c 3}" :actual "(into {:a 1} [[:b 2] [:c 3]])"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map vec is seq" :expected "true" :actual "(seq? (map inc [1 2 3]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map vec not vector" :expected "false" :actual "(vector? (map inc [1 2 3]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "filter vec is seq" :expected "true" :actual "(seq? (filter odd? [1 2 3]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "take vec is seq" :expected "true" :actual "(seq? (take 2 [1 2 3]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map over set" :expected "true" :actual "(= #{2 3 4} (set (map inc #{1 2 3})))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "filter over map ev" :expected "[[:b 2]]" :actual "(filter (fn [[k v]] (> v 1)) {:a 1 :b 2})"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "cons cons lazy" :expected "[1 2 3]" :actual "(cons 1 (cons 2 (lazy-seq (cons 3 nil))))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "next empty lazy" :expected "nil" :actual "(next (take 1 [1]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "drop vec is seq" :expected "true" :actual "(seq? (drop 1 [1 2 3]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "distinct vec is seq" :expected "true" :actual "(seq? (distinct [1 1 2]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "map-indexed is seq" :expected "true" :actual "(seq? (map-indexed vector [1 2]))"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "nth lazy false elem" :expected "false" :actual "(nth (map identity [false 1 2]) 0)"} + {:suite "conformance / Option A: lazy transformers return seqs, not vectors" :label "nth lazy past false" :expected "2" :actual "(nth (drop 1 (list false 1 2)) 1)"} + {:suite "conformance / HIGH: destructuring" :label "destr nested seq" :expected "[1 2 3]" :actual "(let [[a [b c]] [1 [2 3]]] [a b c])"} + {:suite "conformance / HIGH: destructuring" :label "destr rest+as" :expected "[1 [2 3] [1 2 3]]" :actual "(let [[a & r :as all] [1 2 3]] [a r all])"} + {:suite "conformance / HIGH: destructuring" :label "destr map :keys" :expected "[1 2]" :actual "(let [{:keys [a b]} {:a 1 :b 2}] [a b])"} + {:suite "conformance / HIGH: destructuring" :label "destr map :or" :expected "[1 99]" :actual "(let [{:keys [a b] :or {b 99}} {:a 1}] [a b])"} + {:suite "conformance / HIGH: destructuring" :label "destr map :strs" :expected "[1 2]" :actual "(let [{:strs [a b]} {\"a\" 1 \"b\" 2}] [a b])"} + {:suite "conformance / HIGH: destructuring" :label "destr nested map" :expected "5" :actual "(let [{{:keys [x]} :pos} {:pos {:x 5}}] x)"} + {:suite "conformance / HIGH: destructuring" :label "destr fn-param map" :expected "3" :actual "((fn [{:keys [a b]}] (+ a b)) {:a 1 :b 2})"} + {:suite "conformance / HIGH: destructuring" :label "destr let map key" :expected "1" :actual "(let [{a :a} {:a 1}] a)"} + {:suite "conformance / HIGH: update / assoc-in on map literals" :label "update extra args" :expected "{:a 111}" :actual "(update {:a 1} :a + 10 100)"} + {:suite "conformance / HIGH: update / assoc-in on map literals" :label "get-in" :expected "1" :actual "(get-in {:a {:b {:c 1}}} [:a :b :c])"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native mod floored" :expected "2" :actual "(mod -7 3)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native rem truncated" :expected "-1" :actual "(rem -7 3)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native unary div" :expected "1/2" :actual "(/ 2)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native chained div" :expected "1" :actual "(/ 6 3 2)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native bit-and" :expected "8" :actual "(bit-and 12 10)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native bit-xor" :expected "6" :actual "(bit-xor 12 10)"} + {:suite "conformance / native-op parity (native ops at guarded arities)" :label "native shifts" :expected "[16 2]" :actual "[(bit-shift-left 4 2) (bit-shift-right 8 2)]"} + {:suite "conformance / multimethod preferences" :label "prefer-method breaks tie" :expected ":rect" :actual "(do (derive :cm/sq :cm/rect) (derive :cm/sq :cm/shape) (defmulti cmf identity) (defmethod cmf :cm/rect [x] :rect) (defmethod cmf :cm/shape [x] :shape) (prefer-method cmf :cm/rect :cm/shape) (cmf :cm/sq))"} + {:suite "conformance / HIGH: str semantics" :label "str concat nil" :expected "\"a1\"" :actual "(str \"a\" 1 nil)"} + {:suite "conformance / HIGH: str semantics" :label "str keyword" :expected "\":b\"" :actual "(str :b)"} + {:suite "conformance / HIGH: str semantics" :label "str symbol" :expected "\"foo\"" :actual "(str (quote foo))"} + {:suite "conformance / HIGH: str semantics" :label "str mixed" :expected "\"a:b1\"" :actual "(str \"a\" :b 1)"} + {:suite "conformance / HIGH: str semantics" :label "str seq" :expected "\"[1 2 3]\"" :actual "(str [1 2 3])"} + {:suite "conformance / HIGH: dispatch" :label "multimethod" :expected "9" :actual "(do (defmulti area :shape) (defmethod area :sq [s] (* (:s s) (:s s))) (area {:shape :sq :s 3}))"} + {:suite "conformance / HIGH: dispatch" :label "multimethod default" :expected ":def" :actual "(do (defmulti f identity) (defmethod f :default [x] :def) (f 99))"} + {:suite "conformance / HIGH: dispatch" :label "protocol on record" :expected "16" :actual "(do (defprotocol Sh (ar [s])) (defrecord Sq [side] Sh (ar [_] (* side side))) (ar (->Sq 4)))"} + {:suite "conformance / HIGH: dispatch" :label "deftype inline methods" :expected "7" :actual "(do (defprotocol Pi (mi [x])) (deftype Ti [v] Pi (mi [x] v)) (mi (->Ti 7)))"} + {:suite "conformance / HIGH: dispatch" :label "deftype two protocols" :expected "[1 2]" :actual "(do (defprotocol Pa (ma [x])) (defprotocol Pb (mb [x])) (deftype Tab [a b] Pa (ma [x] a) Pb (mb [x] b)) (let [t (->Tab 1 2)] [(ma t) (mb t)]))"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var-get + call" :expected "2" :actual "((var-get (var inc)) 1)"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var? true" :expected "true" :actual "(var? (var map))"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "var? false" :expected "false" :actual "(var? 5)"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "intern + find-var" :expected "41" :actual "(do (intern (quote user) (quote iv) 41) (var-get (find-var (quote user/iv))))"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "alter-var-root rest args" :expected "11" :actual "(do (def avr 1) (alter-var-root (var avr) + 4 6) avr)"} + {:suite "conformance / var fns as ordinary invokes (Stage 2 tier 6)" :label "alter-meta! + meta" :expected "7" :actual "(do (def amv 1) (alter-meta! (var amv) assoc :k 7) (:k (meta (var amv))))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "find-ns + ns-name" :expected "(quote clojure.core)" :actual "(ns-name (find-ns (quote clojure.core)))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "find-ns absent" :expected "nil" :actual "(find-ns (quote no.such.ns))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "create-ns + find" :expected "true" :actual "(do (create-ns (quote made.ns)) (some? (find-ns (quote made.ns))))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "remove-ns" :expected "nil" :actual "(do (create-ns (quote gone.ns)) (remove-ns (quote gone.ns)) (find-ns (quote gone.ns)))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "the-ns of symbol" :expected "(quote user)" :actual "(ns-name (the-ns (quote user)))"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "ns-resolve + call" :expected "3" :actual "((var-get (ns-resolve (quote clojure.core) (quote inc))) 2)"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "resolve + call" :expected "3" :actual "((var-get (resolve (quote inc))) 2)"} + {:suite "conformance / ns introspection fns as ordinary invokes (Stage 2 tier 6b)" :label "resolve absent" :expected "nil" :actual "(resolve (quote no-such-sym-xyz))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "get-method + call" :expected "1" :actual "(do (defmulti t6f :k) (defmethod t6f :a [x] 1) ((get-method t6f :a) {:k :a}))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "remove-method" :expected "nil" :actual "(do (defmulti t6g :k) (defmethod t6g :b [x] 2) (remove-method t6g :b) (get (methods t6g) :b))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "remove-all-methods" :expected "nil" :actual "(do (defmulti t6h :k) (defmethod t6h :c [x] 3) (remove-all-methods t6h) (get (methods t6h) :c))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "prefer-method records" :expected "true" :actual "(do (defmulti t6p identity) (prefer-method t6p :rect :shape) (contains? (get (prefers t6p) :rect) :shape))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "instance? deftype" :expected "true" :actual "(do (deftype T6i [a]) (instance? T6i (->T6i 1)))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "instance? String" :expected "true" :actual "(instance? String \"s\")"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "locking evals body" :expected "3" :actual "(locking :anything (+ 1 2))"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "locking evals monitor" :expected "[3 1]" :actual "(let [a (atom 0)] [(locking (swap! a inc) 3) @a])"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "defonce keeps first" :expected "5" :actual "(do (defonce d6o 5) (defonce d6o 9) d6o)"} + {:suite "conformance / dispatch-table ops + misc as macros/fns (Stage 2 tier 6c)" :label "read-string + eval" :expected "3" :actual "(eval (read-string \"(+ 1 2)\"))"} + {:suite "conformance / uuid" :label "uuid as map key" :expected ":v" :actual "(get {(parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\") :v} (parse-uuid \"b6883c0a-0342-4007-9966-bc2dfa6b109e\"))"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "parse-long bad" :expected "nil" :actual "(parse-long \"4.2\")"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "update-keys" :expected "{\"a\" 1}" :actual "(update-keys {:a 1} name)"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "update-vals" :expected "{:a 2}" :actual "(update-vals {:a 1} inc)"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "partition pad" :expected "[[0 1 2 3] [4 5 6 7] [8 9 :a]]" :actual "(partition 4 4 [:a] (range 10))"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "with-redefs" :expected "[42 1]" :actual "(do (defn cwr [] 1) [(with-redefs [cwr (fn [] 42)] (cwr)) (cwr)])"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "macroexpand" :expected "true" :actual "(= (quote if) (first (macroexpand (quote (when-not false 1)))))"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "require bare symbol" :expected "\"a,b\"" :actual "(do (require (quote clojure.string)) (clojure.string/join \",\" [\"a\" \"b\"]))"} + {:suite "conformance / 1.11 additions + ns fns (spec 35-var batch A)" :label "ns-publics lookup" :expected "true" :actual "(do (def cnp 7) (some? (get (ns-publics (quote user)) (quote cnp))))"} + {:suite "conformance / #inst + syntax-quote literal collapse (spec 2.4/2.3)" :label "inst partial = full" :expected "true" :actual "(= #inst \"2020\" #inst \"2020-01-01T00:00:00Z\")"} + {:suite "conformance / #inst + syntax-quote literal collapse (spec 2.4/2.3)" :label "sq number collapse" :expected "42" :actual "``42"} + {:suite "conformance / vars replace the root-env leak" :label "compare total order" :expected "[-1 0 1]" :actual "[(compare nil 1) (compare :a :a) (compare \"b\" \"a\")]"} + {:suite "conformance / vars replace the root-env leak" :label "any? anything" :expected "true" :actual "(and (any? nil) (any? 1) (any? :k))"} + {:suite "conformance / vars replace the root-env leak" :label "macroexpand-1 when" :expected "2" :actual "(count (rest (macroexpand-1 (quote (when true 1)))))"} + {:suite "conformance / HIGH: aliased namespace calls" :label "require :as alias" :expected "\"1,2,3\"" :actual "(do (require (quote [clojure.string :as s])) (s/join \",\" [1 2 3]))"} + {:suite "conformance / HIGH: aliased namespace calls" :label "ns form + alias" :expected "\"HI\"" :actual "(do (ns my.a (:require [clojure.string :as s])) (s/upper-case \"hi\"))"} + {:suite "conformance / HIGH: aliased namespace calls" :label "ns :use refers" :expected "42" :actual "(do (ns src.u) (def helper 42) (ns dst.u (:use [src.u])) helper)"} + {:suite "conformance / MED: missing core fns" :label "subvec" :expected "[2 3]" :actual "(subvec [1 2 3 4 5] 1 3)"} + {:suite "conformance / MED: missing core fns" :label "subvec to-end" :expected "[3 4 5]" :actual "(subvec [1 2 3 4 5] 2)"} + {:suite "conformance / MED: missing core fns" :label "reduce-kv" :expected "{:a 2, :b 3}" :actual "(reduce-kv (fn [m k v] (assoc m k (inc v))) {} {:a 1 :b 2})"} + {:suite "conformance / iterating maps yields entries" :label "reduce over map" :expected "6" :actual "(reduce (fn [a [k v]] (+ a v)) 0 {:a 1 :b 2 :c 3})"} + {:suite "conformance / iterating maps yields entries" :label "into transform map" :expected "{:a 2, :b 3}" :actual "(into {} (map (fn [[k v]] [k (inc v)]) {:a 1 :b 2}))"} + {:suite "conformance / iterating maps yields entries" :label "filter over map" :expected "true" :actual "(= [[:b 2]] (filterv (fn [[k v]] (> v 1)) {:a 1 :b 2}))"} + {:suite "conformance / iterating maps yields entries" :label "tree-seq" :expected "[1 2 3]" :actual "(map (fn [x] x) (filter (complement coll?) (tree-seq coll? seq [1 [2 [3]]])))"} + {:suite "conformance / iterating maps yields entries" :label "key/val" :expected "true" :actual "(let [e (first {:k 9})] (and (= :k (key e)) (= 9 (val e))))"} + {:suite "conformance / iterating maps yields entries" :label "nat-int?" :expected "true" :actual "(and (nat-int? 0) (nat-int? 5) (not (nat-int? -1)))"} + {:suite "conformance / iterating maps yields entries" :label "list* prepend" :expected "[1 2 3 4]" :actual "(list* 1 2 [3 4])"} + {:suite "conformance / iterating maps yields entries" :label "cycle" :expected "[1 2 3 1 2 3 1]" :actual "(take 7 (cycle [1 2 3]))"} + {:suite "conformance / iterating maps yields entries" :label "partition-all" :expected "[[1 2] [3 4] [5]]" :actual "(partition-all 2 [1 2 3 4 5])"} + {:suite "conformance / iterating maps yields entries" :label "reductions init" :expected "[0 1 3 6]" :actual "(reductions + 0 [1 2 3])"} + {:suite "conformance / iterating maps yields entries" :label "dedupe" :expected "[1 2 3 1]" :actual "(dedupe [1 1 2 3 3 1])"} + {:suite "conformance / iterating maps yields entries" :label "partition-by odd?" :expected "[[1 1] [2] [3 3]]" :actual "(partition-by odd? [1 1 2 3 3])"} + {:suite "conformance / iterating maps yields entries" :label "reductions inf" :expected "[0 1 3 6]" :actual "(take 4 (reductions + (range)))"} + {:suite "conformance / iterating maps yields entries" :label "tree-seq strict" :expected "10" :actual "(reduce + 0 (filter (complement coll?) (tree-seq coll? seq [1 [2 [3 4]]])))"} + {:suite "conformance / iterating maps yields entries" :label "case nil + default" :expected "[:nilr :def]" :actual "(let [f (fn [x] (case x 1 :one nil :nilr :def))] [(f nil) (f 9)])"} + {:suite "conformance / iterating maps yields entries" :label "case collection consts" :expected "[:v :m :s]" :actual "(let [f (fn [x] (case x [1 2] :v {:a 1} :m #{3} :s :def))] [(f [1 2]) (f {:a 1}) (f #{3})])"} + {:suite "conformance / iterating maps yields entries" :label "seq of nil-first" :expected "true" :actual "(boolean (seq (cons nil (list 1))))"} + {:suite "conformance / iterating maps yields entries" :label "reverse nil elem" :expected "[2 nil 1]" :actual "(vec (reverse (list 1 nil 2)))"} + {:suite "conformance / iterating maps yields entries" :label "map non-seqable throws" :expected "true" :actual "(try (doall (map inc 5)) false (catch Throwable _ true))"} + {:suite "conformance / iterating maps yields entries" :label "keep-indexed" :expected "[:b :d]" :actual "(keep-indexed (fn [i x] (if (odd? i) x)) [:a :b :c :d])"} + {:suite "conformance / iterating maps yields entries" :label "map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(map-indexed (fn [i x] [i x]) [:a :b])"} + {:suite "conformance / iterating maps yields entries" :label "trampoline" :expected ":done" :actual "(do (defn a [n] (if (zero? n) :done (fn [] (a (dec n))))) (trampoline a 5))"} + {:suite "conformance / iterating maps yields entries" :label "format" :expected "\"1-x\"" :actual "(format \"%d-%s\" 1 \"x\")"} + {:suite "conformance / iterating maps yields entries" :label "read-string" :expected "(quote (+ 1 2))" :actual "(read-string \"(+ 1 2)\")"} + {:suite "conformance / iterating maps yields entries" :label "letfn mutual" :expected "true" :actual "(letfn [(ev? [n] (if (= n 0) true (od? (dec n)))) (od? [n] (if (= n 0) false (ev? (dec n))))] (ev? 10))"} + {:suite "conformance / iterating maps yields entries" :label "doseq side" :expected "[1 2 3]" :actual "(do (def a (atom [])) (doseq [x [1 2 3]] (swap! a conj x)) @a)"} + {:suite "conformance / iterating maps yields entries" :label "doseq nested" :expected "4" :actual "(do (def c (atom 0)) (doseq [x [1 2] y [10 20]] (swap! c inc)) @c)"} + {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy filter inf" :expected "[1 3 5 7 9]" :actual "(take 5 (filter odd? (range)))"} + {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy take-while inf" :expected "[0 1 2 3 4]" :actual "(take-while (fn [x] (< x 5)) (range))"} + {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "lazy remove inf" :expected "[0 2 4 6 8]" :actual "(take 5 (remove odd? (range)))"} + {:suite "conformance / MED: lazy filter / take-while over infinite seqs" :label "filter finite" :expected "[2 4]" :actual "(filter even? [1 2 3 4 5])"} + {:suite "conformance / atoms (full support)" :label "swap! args" :expected "7" :actual "(do (def a (atom 1)) (swap! a + 2 4) @a)"} + {:suite "conformance / atoms (full support)" :label "reset! ret" :expected "9" :actual "(do (def a (atom 1)) (reset! a 9))"} + {:suite "conformance / atoms (full support)" :label "compare-and-set!" :expected "true" :actual "(do (def a (atom 1)) (compare-and-set! a 1 2))"} + {:suite "conformance / atoms (full support)" :label "compare-and-set! no" :expected "false" :actual "(do (def a (atom 1)) (compare-and-set! a 5 2))"} + {:suite "conformance / atoms (full support)" :label "swap-vals!" :expected "[1 2]" :actual "(do (def a (atom 1)) (swap-vals! a inc))"} + {:suite "conformance / atoms (full support)" :label "reset-vals!" :expected "[1 9]" :actual "(do (def a (atom 1)) (reset-vals! a 9))"} + {:suite "conformance / atoms (full support)" :label "atom map swap" :expected "{:a 1, :b 2}" :actual "(do (def a (atom {:a 1})) (swap! a assoc :b 2) @a)"} + {:suite "conformance / atoms (full support)" :label "add-watch" :expected "[:k 1 2]" :actual "(do (def lg (atom nil)) (def a (atom 1)) (add-watch a :k (fn [k r o n] (reset! lg [k o n]))) (swap! a inc) @lg)"} + {:suite "conformance / atoms (full support)" :label "atom validator" :expected "5" :actual "(do (def a (atom 1 :validator pos?)) (reset! a 5) @a)"} + {:suite "conformance / atoms (full support)" :label "instance? Atom" :expected "true" :actual "(instance? clojure.lang.Atom (atom 1))"} + {:suite "conformance / volatiles / delays" :label "volatile" :expected "2" :actual "(do (def v (volatile! 1)) (vreset! v 2) @v)"} + {:suite "conformance / volatiles / delays" :label "vswap!" :expected "2" :actual "(do (def v (volatile! 1)) (vswap! v inc) @v)"} + {:suite "conformance / volatiles / delays" :label "delay force" :expected "3" :actual "(force (delay (+ 1 2)))"} + {:suite "conformance / volatiles / delays" :label "delay deref once" :expected "1" :actual "(do (def c (atom 0)) (def d (delay (swap! c inc))) @d @d @c)"} + {:suite "conformance / volatiles / delays" :label "realized? delay" :expected "true" :actual "(do (def d (delay 1)) @d (realized? d))"} + {:suite "conformance / volatiles / delays" :label "realized? not" :expected "false" :actual "(realized? (delay 1))"} + {:suite "conformance / numbers / math" :label "quot neg" :expected "-2" :actual "(quot -7 3)"} + {:suite "conformance / numbers / math" :label "bit ops" :expected "[4 14 10]" :actual "[(bit-and 12 6) (bit-or 12 6) (bit-xor 12 6)]"} + {:suite "conformance / numbers / math" :label "bit-shift" :expected "[8 2]" :actual "[(bit-shift-left 1 3) (bit-shift-right 8 2)]"} + {:suite "conformance / numbers / math" :label "Math/sqrt" :expected "3.0" :actual "(Math/sqrt 9)"} + {:suite "conformance / numbers / math" :label "Math/pow" :expected "8.0" :actual "(Math/pow 2 3)"} + {:suite "conformance / numbers / math" :label "min-key" :expected "1" :actual "(min-key abs 1 -2 3)"} + {:suite "conformance / numbers / math" :label "max-key" :expected "-4" :actual "(max-key abs 1 -2 -4 3)"} + {:suite "conformance / strings (clojure.string)" :label "str/trim" :expected "\"hi\"" :actual "(do (require (quote [clojure.string :as s])) (s/trim \" hi \"))"} + {:suite "conformance / strings (clojure.string)" :label "str/split regex" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a,b,c\" #\",\"))"} + {:suite "conformance / strings (clojure.string)" :label "str/split ws" :expected "[\"a\" \"b\" \"c\"]" :actual "(do (require (quote [clojure.string :as s])) (s/split \"a b c\" #\"\\s+\"))"} + {:suite "conformance / strings (clojure.string)" :label "str/replace" :expected "\"hexxo\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" \"ll\" \"xx\"))"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace regex" :expected "\"ab\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"a1b2\" #\"[0-9]\" \"\"))"} + {:suite "conformance / strings (clojure.string)" :label "subs" :expected "\"ell\"" :actual "(subs \"hello\" 1 4)"} + {:suite "conformance / regex" :label "re-find" :expected "\"123\"" :actual "(re-find #\"[0-9]+\" \"abc123def\")"} + {:suite "conformance / regex" :label "re-matches" :expected "\"abc\"" :actual "(re-matches #\"a.c\" \"abc\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-matches no" :expected "nil" :actual "(re-matches #\"a.c\" \"abcd\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-seq" :expected "[\"12\" \"34\"]" :actual "(re-seq #\"[0-9]+\" \"a12b34\")"} + {:suite "conformance / sequences" :label "split-at" :expected "[[1 2] [3 4 5]]" :actual "(split-at 2 [1 2 3 4 5])"} + {:suite "conformance / sequences" :label "split-with" :expected "[[1 2] [3 4 1]]" :actual "(split-with (fn [x] (< x 3)) [1 2 3 4 1])"} + {:suite "conformance / sequences" :label "partition step" :expected "[[1 2] [3 4]]" :actual "(partition 2 2 [1 2 3 4 5])"} + {:suite "conformance / sequences" :label "not-every?" :expected "true" :actual "(not-every? pos? [1 -2 3])"} + {:suite "conformance / overlay migration: run in all 3 modes" :label "not-any?" :expected "true" :actual "(not-any? neg? [1 2 3])"} + {:suite "conformance / sequences" :label "take-nth" :expected "[0 2 4]" :actual "(take-nth 2 [0 1 2 3 4])"} + {:suite "conformance / sequences" :label "butlast" :expected "[1 2]" :actual "(butlast [1 2 3])"} + {:suite "conformance / sequences" :label "empty" :expected "[]" :actual "(empty [1 2 3])"} + {:suite "conformance / sequences" :label "replace map" :expected "[:a :b :a]" :actual "(replace {1 :a 2 :b} [1 2 1])"} + {:suite "conformance / data structures" :label "sorted-map seq" :expected "[[:a 1] [:b 2] [:c 3]]" :actual "(seq (sorted-map :c 3 :a 1 :b 2))"} + {:suite "conformance / data structures" :label "sorted-set seq" :expected "[1 2 3]" :actual "(seq (sorted-set 3 1 2))"} + {:suite "conformance / data structures" :label "coll? set" :expected "true" :actual "(coll? #{1 2})"} + {:suite "conformance / data structures" :label "conj map entry" :expected "{:a 1, :b 2}" :actual "(conj {:a 1} [:b 2])"} + {:suite "conformance / metadata / vars" :label "vary-meta" :expected "{:x 2}" :actual "(meta (vary-meta (with-meta [1] {:x 1}) update :x inc))"} + {:suite "conformance / metadata / vars" :label "defonce no-redef" :expected "1" :actual "(do (defonce dv1 1) (defonce dv1 2) dv1)"} + {:suite "conformance / metadata / vars" :label "binding dynamic" :expected "10" :actual "(do (def ^:dynamic *x* 1) (binding [*x* 10] *x*))"} + {:suite "conformance / try / catch" :label "try catch" :expected ":caught" :actual "(try (throw (ex-info \"e\" {})) (catch :default e :caught))"} + {:suite "conformance / try / catch" :label "ex-data" :expected "{:a 1}" :actual "(try (throw (ex-info \"m\" {:a 1})) (catch :default e (ex-data e)))"} + {:suite "conformance / try / catch" :label "ex-message" :expected "\"m\"" :actual "(try (throw (ex-info \"m\" {})) (catch :default e (ex-message e)))"} + {:suite "conformance / macros" :label "macroexpand-1" :expected "true" :actual "(do (defmacro mm [x] (list (quote inc) x)) (= (quote (inc 5)) (macroexpand-1 (quote (mm 5)))))"} + {:suite "conformance / macros" :label "doto" :expected "{:a 1}" :actual "(deref (doto (atom {}) (swap! assoc :a 1)))"} + {:suite "conformance / printing" :label "prn-str" :expected "\"1\\n\"" :actual "(prn-str 1)"} + {:suite "conformance / characters" :label "char not string" :expected "false" :actual "(= \\a \"a\")"} + {:suite "conformance / characters" :label "char eq" :expected "true" :actual "(= \\a \\a)"} + {:suite "conformance / characters" :label "int of char" :expected "97" :actual "(int \\a)"} + {:suite "conformance / characters" :label "char of int" :expected "true" :actual "(= \\A (char 65))"} + {:suite "conformance / characters" :label "str of chars" :expected "\"abc\"" :actual "(str \\a \\b \\c)"} + {:suite "conformance / characters" :label "first of string" :expected "\\h" :actual "(first \"hello\")"} + {:suite "conformance / characters" :label "nth of string" :expected "\\e" :actual "(nth \"hello\" 1)"} + {:suite "conformance / characters" :label "char newline" :expected "10" :actual "(int \\newline)"} + {:suite "conformance / characters" :label "char space" :expected "32" :actual "(int \\space)"} + {:suite "conformance / characters" :label "pr-str char" :expected "\"\\\\a\"" :actual "(pr-str \\a)"} + {:suite "conformance / characters" :label "chars in vec" :expected "[\\a \\b]" :actual "[\\a \\b]"} + {:suite "conformance / characters" :label "apply str chars" :expected "\"hi\"" :actual "(apply str [\\h \\i])"} + {:suite "conformance / transducers" :label "transduce map" :expected "9" :actual "(transduce (map inc) + 0 [1 2 3])"} + {:suite "conformance / transducers" :label "transduce comp" :expected "12" :actual "(transduce (comp (map inc) (filter even?)) + 0 [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "transduce conj" :expected "[2 3 4]" :actual "(transduce (map inc) conj [] [1 2 3])"} + {:suite "conformance / transducers" :label "into comp xform" :expected "[1 9 25]" :actual "(into [] (comp (filter odd?) (map (fn [x] (* x x)))) [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "into take xform" :expected "[0 1 2]" :actual "(into [] (take 3) (range 100))"} + {:suite "conformance / transducers" :label "transduce no-init" :expected "6" :actual "(transduce (map inc) + [0 1 2])"} + {:suite "conformance / transducers" :label "transduce drop" :expected "[3 4 5]" :actual "(into [] (drop 2) [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "transduce remove" :expected "[1 3 5]" :actual "(into [] (remove even?) [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "transduce take-while" :expected "[1 2]" :actual "(into [] (take-while (fn [x] (< x 3))) [1 2 3 4 1])"} + {:suite "conformance / transducers" :label "transduce map-indexed" :expected "[[0 :a] [1 :b]]" :actual "(into [] (map-indexed (fn [i x] [i x])) [:a :b])"} + {:suite "conformance / transducers" :label "partition-all xform" :expected "[[1 2] [3 4] [5]]" :actual "(into [] (partition-all 2) [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "partition-all xform comp" :expected "[2 2 1]" :actual "(into [] (comp (partition-all 2) (map count)) [1 2 3 4 5])"} + {:suite "conformance / transducers" :label "partition-by xform" :expected "[[1 1] [2 4] [5]]" :actual "(into [] (partition-by odd?) [1 1 2 4 5])"} + {:suite "conformance / transducers" :label "partition-by xform reduced" :expected "[[1 1] [2 4]]" :actual "(into [] (comp (partition-by odd?) (take 2)) [1 1 2 4 5 5])"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-find groups" :expected "[\"12-34\" \"12\" \"34\"]" :actual "(re-find #\"(\\d+)-(\\d+)\" \"x12-34y\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-find no-groups" :expected "\"123\"" :actual "(re-find #\"\\d+\" \"ab123\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "re-matches groups" :expected "[\"1.2\" \"1\" \"2\"]" :actual "(re-matches #\"(\\d+)\\.(\\d+)\" \"1.2\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "greedy backtrack" :expected "\"xxfoo\"" :actual "(re-find #\".*foo\" \"xxfoo\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "greedy thru group" :expected "[\"a,b,c\" \"a,b\" \"c\"]" :actual "(re-find #\"(.*),(.*)\" \"a,b,c\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "lazy quantifier" :expected "[\"\" \"a\"]" :actual "(re-find #\"<(.+?)>\" \"\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "flag case-insens" :expected "\"CAT\"" :actual "(re-find #\"(?i)cat\" \"a CAT\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "lookahead" :expected "\"foo\"" :actual "(re-find #\"foo(?=bar)\" \"foobar\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "neg-lookahead" :expected "\"foo\"" :actual "(re-find #\"foo(?!bar)\" \"foobaz\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "word-boundary" :expected "\"word\"" :actual "(re-find #\"\\bword\\b\" \"a word!\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "word-boundary no" :expected "nil" :actual "(re-find #\"\\bword\\b\" \"swordfish\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "optional group" :expected "[\"1.2.3\" \"1\" \"2\" \"3\" nil]" :actual "(re-find #\"(\\d+)\\.(\\d+)\\.(\\d+)(?:-([a-z]+))?\" \"1.2.3\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "alternation" :expected "\"dog\"" :actual "(re-find #\"cat|dog\" \"a dog cat\")"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace $1" :expected "\"he[ll]o\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"hello\" #\"(l+)\" \"[$1]\"))"} + {:suite "conformance / regex (capturing groups, backtracking, flags, lookahead)" :label "str/replace regex (2)" :expected "\"X-X\"" :actual "(do (require (quote [clojure.string :as s])) (s/replace \"a-b\" #\"[a-z]\" \"X\"))"} + {:suite "conformance / map literals evaluate their values" :label "map literal var" :expected "{:k 5}" :actual "(let [x 5] {:k x})"} + {:suite "conformance / map literals evaluate their values" :label "map literal nested" :expected "{:a {:b 2}}" :actual "(let [y 2] {:a {:b y}})"} + {:suite "conformance / map literals evaluate their values" :label "map literal keyfn" :expected "{:x 1}" :actual "(let [k :x] {k 1})"} + {:suite "conformance / map literals evaluate their values" :label "map literal in fn" :expected "6" :actual "(do (defn mk [a b] {:sum (+ a b)}) (:sum (mk 2 4)))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def 3-arg docstring" :expected "42" :actual "(do (def dd \"the doc\" 42) dd)"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def docstring value type" :expected "true" :actual "(do (def ds \"doc\" [1 2]) (vector? ds))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "def ^{:map} name" :expected "5" :actual "(do (def ^{:private true} mmv 5) mmv)"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defn ^{:map} name" :expected "25" :actual "(do (defn ^{:private true} sqf [x] (* x x)) (sqf 5))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmacro arity-clause" :expected "10" :actual "(do (defmacro m2c ([x] (list (quote *) x 2))) (m2c 5))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmacro doc + arity" :expected "30" :actual "(do (defmacro m3c \"doc\" ([x] (list (quote *) x 3))) (* (m3c 5) 2))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "defmulti docstring" :expected "\"A\"" :actual "(do (defmulti gmm \"the doc\" identity) (defmethod gmm :a [_] \"A\") (gmm :a))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "try multi-body last" :expected "3" :actual "(try 1 2 3 (catch :default e 0))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "try finally on ok+catch" :expected "9" :actual "(let [a (atom 0)] (try 1 2 (catch :default e :c) (finally (reset! a 9))) @a)"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "ns restored after catch" :expected "\"user\"" :actual "(do (ns cf.boom) (defn bz [] (throw (Exception. \"e\"))) (in-ns (quote user)) (try (cf.boom/bz) (catch :default e nil)) (str *ns*))"} + {:suite "conformance / migratus enablement: def/defmacro/defmulti forms, assoc, try, ns" :label "cross-ns methods visible" :expected "[:sql]" :actual "(do (ns cf.mm) (defmulti ext identity) (defmethod ext :default [_] :d) (defn allk [] (vec (for [[k v] (methods ext) :when (not= k :default)] k))) (ns cf.mmi) (defmethod cf.mm/ext :sql [_] :s) (in-ns (quote user)) (cf.mm/allk))"} + {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "defmacro multi-arity" :expected "[6 5 6]" :actual "(do (defmacro mar ([a] (list (quote +) a 1)) ([a b] (list (quote +) a b)) ([a b c] (list (quote +) a b c))) [(mar 5) (mar 2 3) (mar 1 2 3)])"} + {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "defmacro doc + attr-map" :expected "10" :actual "(do (defmacro mam \"doc\" {:arglists (quote ([x]))} [x] (list (quote inc) x)) (mam 9))"} + {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "syntax-quote resolves alias" :expected "\"HI\"" :actual "(do (ns sq.lib (:require [clojure.string :as s])) (defmacro up [x] `(s/upper-case ~x)) (in-ns (quote user)) (sq.lib/up \"hi\"))"} + {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "ns name with ^{:map} meta" :expected "5" :actual "(do (ns ^{:author \"a\" :doc \"d\"} nm.meta) (def q 5) (in-ns (quote user)) nm.meta/q)"} + {:suite "conformance / defmacro surface + syntax-quote/ns (enabling real clojure libs)" :label "unquote *ns* in template" :expected "true" :actual "(do (defmacro cur-ns [] `(str ~*ns*)) (string? (cur-ns)))"} + {:suite "reader / read-string constructs sets" :label "top-level set" :expected "true" :actual "(set? (read-string \"#{:a :b}\"))"} + {:suite "reader / read-string constructs sets" :label "set value equals" :expected "true" :actual "(= #{1 2} (read-string \"#{1 2}\"))"} + {:suite "reader / read-string constructs sets" :label "set nested in map" :expected "true" :actual "(set? (:k (read-string \"{:k #{:a :b}}\")))"} + {:suite "reader / read-string constructs sets" :label "set nested in vector" :expected "true" :actual "(set? (first (read-string \"[#{:a}]\")))"} + {:suite "reader / read-string constructs sets" :label "set nested in list" :expected "true" :actual "(set? (first (read-string \"(#{:a})\")))"} + {:suite "reader / read-string constructs sets" :label "set keeps reader metadata" :expected "true" :actual "(:s (meta (read-string \"^:s #{1 2}\")))"} + {:suite "reader / read-string constructs sets" :label "set of sets" :expected "true" :actual "(every? set? (read-string \"#{#{1} #{2}}\"))"} + {:suite "io / str & format" :label "format %x lowercase" :expected "\"ff\"" :actual "(format \"%x\" 255)"} + {:suite "io / str & format" :label "format %04x zero-pad lower" :expected "\"00ff\"" :actual "(format \"%04x\" 255)"} + {:suite "io / str & format" :label "format %X uppercase" :expected "\"00FF\"" :actual "(format \"%04X\" 255)"} + {:suite "io / str & format" :label "format %x wide hex" :expected "\"deadbeef\"" :actual "(format \"%x\" 3735928559)"} + {:suite "protocols / extend & extends? on nil" :label "extend nil dispatches" :expected ":nil-via-extend" :actual "(do (defprotocol P2 (q [this])) (extend nil P2 {:q (fn [_] :nil-via-extend)}) (q nil))"} + {:suite "protocols / extend & extends? on nil" :label "extends? nil when extended" :expected "true" :actual "(do (defprotocol Pe (pe [this])) (extend nil Pe {:pe (fn [_] :x)}) (extends? Pe nil))"} + {:suite "protocols / extend & extends? on nil" :label "extends? nil when not extended" :expected "false" :actual "(do (defprotocol P3 (r [this])) (extends? P3 nil))"} + {:suite "protocols / extend & extends? on nil" :label "extend-type nil still works" :expected ":via-type" :actual "(do (defprotocol P4 (s [this])) (extend-type nil P4 (s [_] :via-type)) (s nil))"} + {:suite "protocols / extend on host classes" :label "dispatch by java.util.Map/Collection/CharSequence" :expected "[:map :coll :str :obj]" :actual "(do (defprotocol W (-w [x])) (extend java.util.Map W {:-w (fn [_] :map)}) (extend java.util.Collection W {:-w (fn [_] :coll)}) (extend java.lang.CharSequence W {:-w (fn [_] :str)}) (extend java.lang.Object W {:-w (fn [_] :obj)}) [(-w {:a 1}) (-w [1 2]) (-w \"s\") (-w 42)])"} + {:suite "protocols / extend on host classes" :label "satisfies? via java.util.Map" :expected "true" :actual "(do (defprotocol Q (qq [x])) (extend java.util.Map Q {:qq (fn [_] :m)}) (satisfies? Q {}))"} + {:suite "protocols / extend on host classes" :label "extends? on a qualified host class" :expected "true" :actual "(do (defprotocol Qe (qe [x])) (extend java.util.Collection Qe {:qe (fn [_] :c)}) (extends? Qe java.util.Collection))"} + {:suite "interop / instance? on host interfaces" :label "keyword is Named" :expected "true" :actual "(instance? clojure.lang.Named :a)"} + {:suite "interop / instance? on host interfaces" :label "string is CharSequence" :expected "true" :actual "(instance? java.lang.CharSequence \"s\")"} + {:suite "interop / instance? on host interfaces" :label "number is Number" :expected "true" :actual "(instance? java.lang.Number 42)"} + {:suite "interop / instance? on host interfaces" :label "map is java.util.Map" :expected "true" :actual "(instance? java.util.Map {:a 1})"} + {:suite "interop / instance? on host interfaces" :label "vector is java.util.List" :expected "true" :actual "(instance? java.util.List [1 2])"} + {:suite "interop / instance? on host interfaces" :label "list is java.util.Collection" :expected "true" :actual "(instance? java.util.Collection (list 1))"} + {:suite "interop / instance? on host interfaces" :label "set is java.util.Set" :expected "true" :actual "(instance? java.util.Set #{1})"} + {:suite "interop / instance? on host interfaces" :label "map is not a Collection" :expected "false" :actual "(instance? java.util.Collection {:a 1})"} + {:suite "interop / instance? on host interfaces" :label "vector is Associative" :expected "true" :actual "(instance? clojure.lang.Associative [1])"} + {:suite "interop / instance? on host interfaces" :label "string is not Number" :expected "false" :actual "(instance? java.lang.Number \"s\")"} + {:suite "interop / String & StringBuilder char ops" :label "String from char-array slice" :expected "\"abc\"" :actual "(String. (char-array [\\a \\b \\c \\d]) 0 3)"} + {:suite "interop / String & StringBuilder char ops" :label "str of StringBuilder" :expected "\"hi\"" :actual "(let [sb (StringBuilder.)] (.append sb \"hi\") (str sb))"} + {:suite "interop / String & StringBuilder char ops" :label "append subsequence" :expected "\"bcd\"" :actual "(let [sb (StringBuilder.)] (.append sb \"abcde\" 1 4) (.toString sb))"} + {:suite "interop / String & StringBuilder char ops" :label "String.getChars into buffer" :expected "\"abc\"" :actual "(let [a (char-array 4)] (.getChars \"abcd\" 0 3 a 0) (String. a 0 3))"} + {:suite "interop / numbers & classes" :label "Integer/toHexString lowercase" :expected "\"ff\"" :actual "(Integer/toHexString 255)"} + {:suite "interop / numbers & classes" :label "Integer/toHexString wide" :expected "\"1234\"" :actual "(Integer/toHexString 4660)"} + {:suite "interop / numbers & classes" :label ".isNaN on a double" :expected "true" :actual "(.isNaN (/ 0.0 0.0))"} + {:suite "interop / numbers & classes" :label ".isInfinite on a double" :expected "true" :actual "(.isInfinite (/ 1.0 0.0))"} + {:suite "interop / numbers & classes" :label ".isNaN false for finite" :expected "false" :actual "(.isNaN 1.0)"} + {:suite "interop / numbers & classes" :label "protocol dispatch Long vs Double" :expected "[:l :d]" :actual "(do (defprotocol N (-n [x])) (extend java.lang.Long N {:-n (fn [_] :l)}) (extend java.lang.Double N {:-n (fn [_] :d)}) [(-n 5) (-n 5.0)])"} + {:suite "interop / numbers & classes" :label "instance? PushbackReader" :expected "true" :actual "(instance? java.io.PushbackReader (java.io.PushbackReader. (java.io.StringReader. \"x\")))"} + {:suite "interop / numbers & classes" :label "EOFException catch by class" :expected "\"boom\"" :actual "(try (throw (java.io.EOFException. \"boom\")) (catch java.io.EOFException e (.getMessage e)))"} + {:suite "interop / numbers & classes" :label "Reader.read into char[]" :expected "[4 \"abcd\"]" :actual "(let [r (java.io.StringReader. \"abcd\") b (char-array 4)] (let [n (.read r b 0 4)] [n (String. b 0 n)]))"} + {:suite "interop / java.time" :label "LocalDate toString" :expected "\"2020-01-15\"" :actual "(str (java.time.LocalDate/of 2020 1 15))"} + {:suite "interop / java.time" :label "LocalDate plusDays over leap day" :expected "\"2020-02-29\"" :actual "(str (.plusDays (java.time.LocalDate/of 2020 2 28) 1))"} + {:suite "interop / java.time" :label "LocalDate equality" :expected "true" :actual "(= (java.time.LocalDate/of 2020 1 15) (java.time.LocalDate/of 2020 1 15))"} + {:suite "interop / java.time" :label "LocalDate compare" :expected "-1" :actual "(compare (java.time.LocalDate/of 2020 1 15) (java.time.LocalDate/of 2020 1 16))"} + {:suite "interop / java.time" :label "LocalDate ofEpochDay round-trip" :expected "1" :actual "(.toEpochDay (java.time.LocalDate/of 1970 1 2))"} + {:suite "interop / java.time" :label "LocalDate parse" :expected "\"2020-01-15\"" :actual "(str (java.time.LocalDate/parse \"2020-01-15\"))"} + {:suite "interop / java.time" :label "LocalDate getDayOfWeek name" :expected "\"WEDNESDAY\"" :actual "(.name (.getDayOfWeek (java.time.LocalDate/of 2020 1 15)))"} + {:suite "interop / java.time" :label "LocalTime toString" :expected "\"10:30:15\"" :actual "(str (java.time.LocalTime/of 10 30 15))"} + {:suite "interop / java.time" :label "LocalTime plusHours wraps midnight" :expected "\"01:30\"" :actual "(str (.plusHours (java.time.LocalTime/of 23 30) 2))"} + {:suite "interop / java.time" :label "LocalDateTime toString" :expected "\"2020-01-15T10:30\"" :actual "(str (java.time.LocalDateTime/of 2020 1 15 10 30 0))"} + {:suite "interop / java.time" :label "Instant ofEpochMilli toString" :expected "\"2020-01-15T10:30:00Z\"" :actual "(str (java.time.Instant/ofEpochMilli 1579084200000))"} + {:suite "interop / java.time" :label "Instant ofEpochMilli round-trip" :expected "1579084200000" :actual "(.toEpochMilli (java.time.Instant/ofEpochMilli 1579084200000))"} + {:suite "interop / java.time" :label "Duration ofSeconds toString" :expected "\"PT1M30S\"" :actual "(str (java.time.Duration/ofSeconds 90))"} + {:suite "interop / java.time" :label "Duration between instants" :expected "\"PT1H1M1S\"" :actual "(str (java.time.Duration/between (java.time.Instant/ofEpochSecond 0) (java.time.Instant/ofEpochSecond 3661)))"} + {:suite "interop / java.time" :label "Period between dates" :expected "\"P1Y2M2D\"" :actual "(str (java.time.Period/between (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2021 3 3)))"} + {:suite "interop / java.time" :label "Period parse round-trip" :expected "\"P1Y2M3D\"" :actual "(str (java.time.Period/parse \"P1Y2M3D\"))"} + {:suite "interop / java.time" :label "Period normalized" :expected "\"P2Y1M5D\"" :actual "(str (.normalized (java.time.Period/of 1 13 5)))"} + {:suite "interop / java.time" :label "Month of toString" :expected "\"FEBRUARY\"" :actual "(.toString (java.time.Month/of 2))"} + {:suite "interop / java.time" :label "Month length leap" :expected "29" :actual "(.length (java.time.Month/of 2) true)"} + {:suite "interop / java.time" :label "DayOfWeek constant prints name" :expected "\"MONDAY\"" :actual "(str java.time.DayOfWeek/MONDAY)"} + {:suite "interop / java.time" :label "YearMonth toString" :expected "\"2020-02\"" :actual "(str (java.time.YearMonth/of 2020 2))"} + {:suite "interop / java.time" :label "ChronoUnit DAYS between" :expected "14" :actual "(.between java.time.temporal.ChronoUnit/DAYS (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2020 1 15))"} + {:suite "interop / java.time" :label "LocalDate plus ChronoUnit DAYS" :expected "\"2020-01-04\"" :actual "(str (.plus (java.time.LocalDate/of 2020 1 1) 3 java.time.temporal.ChronoUnit/DAYS))"} + {:suite "interop / java.time" :label "LocalDate until ChronoUnit DAYS" :expected "31" :actual "(.until (java.time.LocalDate/of 2020 1 1) (java.time.LocalDate/of 2020 2 1) java.time.temporal.ChronoUnit/DAYS)"} + {:suite "interop / java.time" :label "ZoneOffset ofHoursMinutes toString" :expected "\"+02:00\"" :actual "(str (java.time.ZoneOffset/ofHoursMinutes 2 0))"} + {:suite "interop / java.time" :label "ZoneOffset ofTotalSeconds toString" :expected "\"-04:30\"" :actual "(str (java.time.ZoneOffset/ofTotalSeconds -16200))"} + {:suite "interop / java.time" :label "ZoneOffset UTC toString" :expected "\"Z\"" :actual "(str java.time.ZoneOffset/UTC)"} + {:suite "interop / java.time" :label "ZoneOffset of getTotalSeconds" :expected "7200" :actual "(.getTotalSeconds (java.time.ZoneOffset/of \"+02:00\"))"} + {:suite "interop / java.time" :label "ZoneOffset ofHoursMinutes negative" :expected "\"-04:30\"" :actual "(.getId (java.time.ZoneOffset/ofHoursMinutes -4 -30))"} + {:suite "interop / java.time" :label "OffsetDateTime toInstant" :expected "\"2020-01-15T08:30:00Z\"" :actual "(str (.toInstant (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2))))"} + {:suite "interop / java.time" :label "OffsetDateTime toString" :expected "\"2020-01-15T10:30+02:00\"" :actual "(str (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2)))"} + {:suite "interop / java.time" :label "ZonedDateTime withZoneSameInstant UTC" :expected "\"2020-01-15T08:30Z\"" :actual "(str (.withZoneSameInstant (java.time.ZonedDateTime/parse \"2020-01-15T10:30:00+02:00[Europe/Paris]\") java.time.ZoneOffset/UTC))"} + {:suite "interop / java.time" :label "ZonedDateTime of toInstant fixed offset" :expected "\"2020-01-15T08:30:00Z\"" :actual "(str (.toInstant (java.time.ZonedDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneId/of \"+02:00\"))))"} + {:suite "interop / java.time" :label "DateTimeFormatter ofPattern format" :expected "\"2020-01-15 10:30:00\"" :actual "(.format (java.time.format.DateTimeFormatter/ofPattern \"yyyy-MM-dd HH:mm:ss\") (java.time.LocalDateTime/of 2020 1 15 10 30 0))"} + {:suite "interop / java.time" :label "ISO_LOCAL_DATE_TIME format" :expected "\"2020-01-15T10:30:00\"" :actual "(.format java.time.format.DateTimeFormatter/ISO_LOCAL_DATE_TIME (java.time.LocalDateTime/of 2020 1 15 10 30 0))"} + {:suite "interop / java.time" :label "ISO_OFFSET_DATE_TIME format" :expected "\"2020-01-15T10:30:00+02:00\"" :actual "(.format java.time.format.DateTimeFormatter/ISO_OFFSET_DATE_TIME (java.time.OffsetDateTime/of 2020 1 15 10 30 0 0 (java.time.ZoneOffset/ofHours 2)))"} + {:suite "interop / java.time" :label "Instant plusNanos toString nanos group" :expected "\"1970-01-01T00:00:00.000000001Z\"" :actual "(str (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))"} + {:suite "interop / java.time" :label "Instant one nano differs" :expected "false" :actual "(= (java.time.Instant/ofEpochSecond 0) (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))"} + {:suite "interop / java.time" :label "Instant getNano single nano" :expected "1" :actual "(.getNano (.plusNanos (java.time.Instant/ofEpochSecond 0) 1))"} + {:suite "interop / java.time" :label "Instant ofEpochSecond nano millis group" :expected "\"1970-01-01T00:00:00.001Z\"" :actual "(str (java.time.Instant/ofEpochSecond 0 1000000))"} + {:suite "interop / java.time" :label "Instant ofEpochSecond nano micros group" :expected "\"1970-01-01T00:00:00.000001Z\"" :actual "(str (java.time.Instant/ofEpochSecond 0 1000))"} + {:suite "interop / java.time" :label "Instant plusSeconds keeps nanos" :expected "\"1970-01-01T00:00:02.000000005Z\"" :actual "(str (.plusSeconds (.plusNanos (java.time.Instant/ofEpochSecond 0) 5) 2))"} + {:suite "interop / java.time" :label "Instant getEpochSecond floors negative nano" :expected "-1" :actual "(.getEpochSecond (.plusNanos (java.time.Instant/ofEpochSecond 0) -1))"} + {:suite "interop / java.time" :label "Instant getNano of negative nano" :expected "999999999" :actual "(.getNano (.plusNanos (java.time.Instant/ofEpochSecond 0) -1))"} + {:suite "interop / java.time" :label "Instant toEpochMilli floors sub-milli" :expected "1000" :actual "(.toEpochMilli (.plusNanos (java.time.Instant/ofEpochSecond 1) 999999))"} + {:suite "interop / java.time" :label "Instant truncatedTo SECONDS drops nanos" :expected "\"1970-01-01T00:00:05Z\"" :actual "(str (.truncatedTo (.plusNanos (java.time.Instant/ofEpochSecond 5) 123) java.time.temporal.ChronoUnit/SECONDS))"} + {:suite "interop / java.io File" :label "getName" :expected "\"c.txt\"" :actual "(.getName (java.io.File. \"/a/b/c.txt\"))"} + {:suite "interop / java.io File" :label "getParent" :expected "\"/a/b\"" :actual "(.getParent (java.io.File. \"/a/b/c.txt\"))"} + {:suite "interop / java.io File" :label "getPath keeps relative path" :expected "\"rel/x\"" :actual "(.getPath (java.io.File. \"rel/x\"))"} + {:suite "interop / java.io File" :label "relative File is not absolute" :expected "false" :actual "(.isAbsolute (java.io.File. \"rel\"))"} + {:suite "interop / java.io File" :label "parent+child constructor joins" :expected "\"/a/b\"" :actual "(.getPath (java.io.File. \"/a\" \"b\"))"} + {:suite "interop / java.io File" :label "File/separator" :expected "\"/\"" :actual "java.io.File/separator"} + {:suite "interop / java.io File" :label "str of File is its path" :expected "\"a/b\"" :actual "(str (java.io.File. \"a/b\"))"} + {:suite "interop / java.io File" :label "mkdir then delete a temp dir" :expected "[true true true]" :actual "(let [d (java.io.File/createTempFile \"jd\" \"\")] (.delete d) [(.mkdir d) (.isDirectory d) (.delete d)])"} + {:suite "interop / java.io streams" :label "ByteArrayOutputStream toString" :expected "\"hi!\"" :actual "(let [b (java.io.ByteArrayOutputStream.)] (.write b (.getBytes \"hi\")) (.write b 33) (.toString b))"} + {:suite "interop / java.io streams" :label "ByteArrayOutputStream size" :expected "4" :actual "(let [b (java.io.ByteArrayOutputStream.)] (.write b (.getBytes \"abcd\")) (.size b))"} + {:suite "interop / java.io streams" :label "ByteArrayOutputStream toByteArray round-trips" :expected "\"yo\"" :actual "(String. (.toByteArray (doto (java.io.ByteArrayOutputStream.) (.write (.getBytes \"yo\")))))"} + {:suite "interop / java.io streams" :label "ByteArrayInputStream read to EOF" :expected "[65 66 -1]" :actual "(let [in (java.io.ByteArrayInputStream. (.getBytes \"AB\"))] [(.read in) (.read in) (.read in)])"} + {:suite "interop / java.io streams" :label "BufferedReader over StringReader readLine" :expected "[\"a\" \"b\" nil]" :actual "(let [r (java.io.BufferedReader. (java.io.StringReader. \"a\\nb\\n\"))] [(.readLine r) (.readLine r) (.readLine r)])"} + {:suite "interop / java.io streams" :label "instance? InputStream" :expected "true" :actual "(instance? java.io.InputStream (java.io.ByteArrayInputStream. (.getBytes \"x\")))"} + {:suite "interop / java.io streams" :label "FileOutputStream then FileInputStream round-trip" :expected "90" :actual "(let [f (java.io.File/createTempFile \"jc\" \".t\") o (java.io.FileOutputStream. f)] (.write o (byte-array [90])) (.close o) (let [in (java.io.FileInputStream. f) b (.read in)] (.close in) (.delete f) b))"} + {:suite "clojure.edn / unknown tags" :label "unknown tag throws naming the tag" :expected "\"No reader function for tag foobar\"" :actual "(do (require (quote [clojure.edn :as e1])) (try (e1/read-string \"#foobar 1\") (catch Exception e (ex-message e))))"} + {:suite "clojure.edn / unknown tags" :label "object tag throws naming the tag" :expected "\"No reader function for tag object\"" :actual "(do (require (quote [clojure.edn :as e2])) (try (e2/read-string \"#object [1 2 3]\") (catch Exception e (ex-message e))))"} + {:suite "clojure.edn / unknown tags" :label ":default opt handles an unknown tag" :expected "[\"foobar\" 9]" :actual "(do (require (quote [clojure.edn :as e3])) (e3/read-string {:default (fn [t v] [(name t) v])} \"#foobar 9\"))"} + {:suite "deftype / clojure.lang interfaces" :label "Indexed + Counted dispatch" :expected "[3 20]" :actual "(do (deftype Row [v] clojure.lang.Indexed (nth [_ i] (nth v i)) (nth [_ i x] (nth v i x)) clojure.lang.Counted (count [_] (count v))) [(count (->Row [10 20 30])) (nth (->Row [10 20 30]) 1)])"} + {:suite "deftype / clojure.lang interfaces" :label "multi-arity inline method" :expected "[5 11]" :actual "(do (defprotocol PMul (mm [this a] [this a b])) (deftype TMul [] PMul (mm [_ a] a) (mm [_ a b] (+ a b))) [(mm (->TMul) 5) (mm (->TMul) 5 6)])"} + {:suite "deftype / clojure.lang interfaces" :label "ILookup valAt computes a non-field key" :expected "[1 :miss]" :actual "(do (deftype TL [a] clojure.lang.ILookup (valAt [this k] (.valAt this k nil)) (valAt [_ k nf] (case k :a a :computed 99 nf))) [(:a (->TL 1)) (get (->TL 1) :nope :miss)])"} + {:suite "deftype / clojure.lang interfaces" :label "marker protocol satisfies?" :expected "true" :actual "(do (defprotocol PMark) (deftype TM [] PMark) (satisfies? PMark (->TM)))"} + {:suite "deftype / clojure.lang interfaces" :label "IFn record is callable" :expected "7" :actual "(do (deftype Adder [n] clojure.lang.IFn (invoke [_ x] (+ n x))) ((->Adder 5) 2))"} + {:suite "interop / collections" :label "Map keySet" :expected "true" :actual "(= (set (.keySet {:a 1 :b 2})) #{:a :b})"} + {:suite "interop / collections" :label "instance? ILookup on a map" :expected "true" :actual "(instance? clojure.lang.ILookup {:a 1})"} + {:suite "interop / collections" :label "instance? Indexed on a vector" :expected "true" :actual "(instance? clojure.lang.Indexed [1 2 3])"} + {:suite "interop / java.util.Date" :label "deprecated getYear/getMonth" :expected "[110 0]" :actual "(let [d (java.util.Date. 110 0 15)] [(.getYear d) (.getMonth d)])"} + {:suite "clojure.set / variadic" :label "union of 4 sets" :expected "#{1 2 3 4}" :actual "(do (require (quote clojure.set)) (clojure.set/union #{1} #{2} #{3} #{4}))"} + {:suite "clojure.set / variadic" :label "intersection of 3 sets" :expected "#{3}" :actual "(do (require (quote clojure.set)) (clojure.set/intersection #{1 2 3} #{2 3 4} #{3 4 5}))"} + {:suite "regex / literal value" :label "literal is a Pattern" :expected "true" :actual "(instance? java.util.regex.Pattern #\"a.c\")"} + {:suite "regex / literal value" :label "re-matches on a literal" :expected "\"aaa\"" :actual "(re-matches #\"a+\" \"aaa\")"} + {:suite "regex / literal value" :label "quoted regex round-trips" :expected "\"#\\\"a.c\\\"\"" :actual "(pr-str (quote #\"a.c\"))"} + {:suite "regex / literal value" :label "extend-protocol to Pattern dispatches" :expected "[:pattern :other]" :actual "(do (defprotocol Tg (tg [_])) (extend-protocol Tg java.util.regex.Pattern (tg [_] :pattern) Object (tg [_] :other)) [(tg #\"x\") (tg 1)])"} ] diff --git a/test/chez/cts-app/deps.edn b/test/chez/cts-app/deps.edn deleted file mode 100644 index ed313cc..0000000 --- a/test/chez/cts-app/deps.edn +++ /dev/null @@ -1,2 +0,0 @@ -{:paths ["src" "../../../vendor/clojure-test-suite/test"] - :aliases {:cts {:main-opts ["-m" "cts-run"]}}} diff --git a/test/chez/cts-app/src/cts_run.clj b/test/chez/cts-app/src/cts_run.clj deleted file mode 100644 index d1360e0..0000000 --- a/test/chez/cts-app/src/cts_run.clj +++ /dev/null @@ -1,18 +0,0 @@ -(ns cts-run - "Runner for the vendored jank-lang/clojure-test-suite (vendor/clojure-test-suite): - requires each test namespace given on the command line and runs its clojure.test - tests, printing one machine-readable result line per namespace. Driven per-process - by host/chez/cts.sh so a hang or crash in one namespace can't take out the run." - (:require [clojure.test :as t])) - -(defn -main [& nses] - (doseq [n nses] - (let [ns-sym (symbol n)] - (try - (require ns-sym) - (let [r (t/run-tests ns-sym)] - (println "CTS-RESULT" n (:pass r 0) (:fail r 0) (:error r 0))) - (catch Throwable e - (println "CTS-RESULT" n 0 0 1 - (str "LOAD: " (.getName (class e)) ": " (.getMessage e))))))) - (System/exit 0)) diff --git a/test/chez/cts-known-failures.txt b/test/chez/cts-known-failures.txt deleted file mode 100644 index 52c66f3..0000000 --- a/test/chez/cts-known-failures.txt +++ /dev/null @@ -1,32 +0,0 @@ -# clojure-test-suite known failures: -# The gate fails on any per-namespace change, worse OR better; regenerate -# with: JOLT_CTS_WRITE_BASELINE=1 host/chez/cts.sh -clojure.core-test.abs 1 0 -clojure.core-test.add-watch 0 1 -clojure.core-test.bigint 6 0 -clojure.core-test.bit-set 1 0 -clojure.core-test.dec 1 0 -clojure.core-test.double-qmark 3 0 -clojure.core-test.eq 2 0 -clojure.core-test.float 1 0 -clojure.core-test.inc 1 0 -clojure.core-test.int-qmark 3 0 -clojure.core-test.lazy-seq 1 2 -clojure.core-test.minus 2 0 -clojure.core-test.mod 18 0 -clojure.core-test.neg-int-qmark 1 0 -clojure.core-test.not-eq 3 0 -clojure.core-test.num 2 0 -clojure.core-test.parse-uuid 3 0 -clojure.core-test.peek 1 0 -clojure.core-test.plus 11 0 -clojure.core-test.plus-squote 11 0 -clojure.core-test.pos-int-qmark 1 0 -clojure.core-test.quot 25 0 -clojure.core-test.realized-qmark 1 0 -clojure.core-test.rem 16 0 -clojure.core-test.remove-watch 0 1 -clojure.core-test.star 13 0 -clojure.core-test.star-squote 13 0 -clojure.core-test.transient 4 0 -clojure.core-test.vec 1 0 diff --git a/test/chez/datareader-app/deps.edn b/test/chez/datareader-app/deps.edn deleted file mode 100644 index ccd9a31..0000000 --- a/test/chez/datareader-app/deps.edn +++ /dev/null @@ -1 +0,0 @@ -{:paths ["src"]} diff --git a/test/chez/datareader-app/src/data_readers.clj b/test/chez/datareader-app/src/data_readers.clj deleted file mode 100644 index dec0d19..0000000 --- a/test/chez/datareader-app/src/data_readers.clj +++ /dev/null @@ -1 +0,0 @@ -{code drtest.reader/code-reader} diff --git a/test/chez/datareader-app/src/drtest/main.clj b/test/chez/datareader-app/src/drtest/main.clj deleted file mode 100644 index 63ce7ed..0000000 --- a/test/chez/datareader-app/src/drtest/main.clj +++ /dev/null @@ -1,4 +0,0 @@ -(ns drtest.main - (:require drtest.reader)) -(defn -main [& _] - (println #code [:ignored])) diff --git a/test/chez/datareader-app/src/drtest/reader.clj b/test/chez/datareader-app/src/drtest/reader.clj deleted file mode 100644 index 43b7dd6..0000000 --- a/test/chez/datareader-app/src/drtest/reader.clj +++ /dev/null @@ -1,2 +0,0 @@ -(ns drtest.reader) -(defn code-reader [_form] (list '+ 40 2)) diff --git a/test/chez/ffi-binding-test.ss b/test/chez/ffi-binding-test.ss index 0454f90..b53a178 100644 --- a/test/chez/ffi-binding-test.ss +++ b/test/chez/ffi-binding-test.ss @@ -14,7 +14,7 @@ (load "host/chez/host-contract.ss") (load "host/chez/seed/image.ss") (load "host/chez/compile-eval.ss") -(load "host/chez/java/ffi.ss") +(load "host/chez/ffi.ss") (define total 0) (define fails 0) (define (ok name pred) (set! total (+ total 1)) (unless pred (set! fails (+ fails 1)) (printf "FAIL: ~a\n" name))) diff --git a/test/chez/inline-test.ss b/test/chez/inline-test.ss index a2873a9..50011cb 100644 --- a/test/chez/inline-test.ss +++ b/test/chez/inline-test.ss @@ -36,7 +36,7 @@ (ev "(def add1 (fn* ([x] (+ x 1))))") (let ((e (emitf "u" "(fn* ([y] (add1 y)))"))) (ok "plain fn is inlined (call to add1 gone)" (not (has? e "add1"))) - (ok "inlined body present (jolt-n+ ... 1)" (has? e "(jolt-n+"))) + (ok "inlined body present (+ ... 1)" (has? e "(+"))) (ok "inlined plain fn runtime: (add1 41) = 42" (= 42 (jnum->exact (ev "((fn* ([y] (add1 y))) 41)")))) ;; a ^double fn: body fl-ops fire after inlining, and the call is gone. diff --git a/test/chez/numeric-test.ss b/test/chez/numeric-test.ss index 39aee0f..b753499 100644 --- a/test/chez/numeric-test.ss +++ b/test/chez/numeric-test.ss @@ -41,16 +41,12 @@ (ok "long + lowers to fx+" (has? (emitf "u" "(fn* ([^long a ^long b] (+ a b)))") "(fx+")) (ok "long * lowers to fx*" (has? (emitf "u" "(fn* ([^long a ^long b] (* a b)))") "(fx*")) (ok "double < lowers to fl keep reading - ["(defn g [] (foo (bar" false] ; deeply unbalanced - ["[1 2 {:a 3}]" true] ; mixed bracket types balance - ["(str \")\")" true] ; a close-paren inside a string doesn't count - ["\\(" true] ; a paren char literal doesn't count - ["(+ 1 2) ; ) ) trailing" true] ; parens in a line comment don't count - ["(re-find #\"(a)(b)\" \"ab\")" true] ; groups inside a regex must not count as depth - ["#\"[0-9]+\"" true] ; a bare regex literal is a complete form - ["#\"a(b" false]]) ; an unterminated regex is incomplete - -(let [bad (remove (fn [[in exp]] (= exp (boolean (complete? in)))) cases)] - (println (if (empty? bad) - "REPL-READER OK" - (str "REPL-READER FAIL " (pr-str (map first bad)))))) diff --git a/test/chez/unit.edn b/test/chez/unit.edn index 12ab8f6..6c0b5f9 100644 --- a/test/chez/unit.edn +++ b/test/chez/unit.edn @@ -67,7 +67,7 @@ {:suite "exinfo" :expr "(instance? RuntimeException (InterruptedException. \"x\"))" :expected "false"} {:suite "exinfo" :expr "(.getMessage (RuntimeException. \"boom\"))" :expected "boom"} {:suite "exinfo" :expr "(ex-message (RuntimeException. \"boom\"))" :expected "boom"} - {:suite "exinfo" :expr "(type (ex-info \"x\" {}))" :expected "clojure.lang.ExceptionInfo"} + {:suite "exinfo" :expr "(type (ex-info \"x\" {}))" :expected ":jolt/ex-info"} {:suite "hostobj" :expr "(.getName (.getClass \"x\"))" :expected "java.lang.String"} {:suite "hostobj" :expr "(.getClass 5)" :expected "java.lang.Long"} {:suite "hostobj" :expr "(.getSimpleName (.getClass :k))" :expected "Keyword"} @@ -164,7 +164,7 @@ {:suite "insttime" :expr "(inst-ms #inst \"2020-01-01T00:00:00Z\")" :expected "1577836800000"} {:suite "insttime" :expr "(inst-ms* #inst \"1970-01-01T00:00:00Z\")" :expected "0"} {:suite "insttime" :expr "(some? #inst \"2020-01-01T00:00:00Z\")" :expected "true"} - {:suite "insttime" :expr "(str (type #inst \"2020-01-01T00:00:00Z\"))" :expected "class java.util.Date"} + {:suite "insttime" :expr "(str (type #inst \"2020-01-01T00:00:00Z\"))" :expected ":jolt/inst"} {:suite "insttime" :expr "(= #inst \"2020\" #inst \"2020-01-01T00:00:00.000Z\")" :expected "true"} {:suite "insttime" :expr "(= #inst \"2020-03\" #inst \"2020-03-01T00:00:00Z\")" :expected "true"} {:suite "insttime" :expr "(= #inst \"2020-03-15\" #inst \"2020-03-15T00:00:00Z\")" :expected "true"} @@ -200,7 +200,7 @@ {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (.exists (io/file \"README.md\")))" :expected "true"} {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (instance? java.io.File (io/file \"/a/b\")))" :expected "true"} {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (instance? java.io.File \"/a/b\"))" :expected "false"} - {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (str (type (io/file \"/a\"))))" :expected "class java.io.File"} + {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (str (type (io/file \"/a\"))))" :expected ":jolt/file"} {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (every? (fn [f] (instance? java.io.File f)) (file-seq (io/file \"docs\"))))" :expected "true"} {:suite "io" :expr "(do (require (quote [clojure.java.io :as io])) (pos? (count (filter (fn [f] (.isFile f)) (file-seq (io/file \"docs\"))))))" :expected "true"} {:suite "io" :expr "(do (require (quote [clojure.string :as s])) (boolean (some (fn [p] (s/ends-with? p \"README.md\")) (file-seq \".\"))))" :expected "true"} @@ -226,7 +226,6 @@ {:suite "ioreader" :expr "(let [log (atom [])] (try (with-open [c {:close (fn [] (swap! log conj :closed))}] (throw (ex-info \"boom\" {}))) (catch Exception e nil)) (deref log))" :expected "[:closed]"} {:suite "ioreader" :expr "(let [log (atom [])] (with-open [a {:close (fn [] (swap! log conj :outer))} b {:close (fn [] (swap! log conj :inner))}] :r) (deref log))" :expected "[:inner :outer]"} {:suite "ioreader" :expr "(with-open [c {:close (fn [] nil) :v 5}] (:v c))" :expected "5"} - {:suite "ioreader" :expr "(do (defrecord RC [log] java.io.Closeable (close [_] (swap! log conj :closed))) (let [log (atom [])] (with-open [r (->RC log)] :body) @log))" :expected "[:closed]"} {:suite "javastatic" :expr "(Math/sqrt 16)" :expected "4.0"} {:suite "javastatic" :expr "(Math/abs -3)" :expected "3"} {:suite "javastatic" :expr "(Math/max 2 7)" :expected "7"} @@ -312,8 +311,6 @@ {:suite "reader" :expr "(nil? (read-string \"nil\"))" :expected "true"} {:suite "reader" :expr "(true? (read-string \"true\"))" :expected "true"} {:suite "reader" :expr "(false? (read-string \"false\"))" :expected "true"} - {:suite "reader" :expr "(let [r (read-string \"#foo bar\")] (and (tagged-literal? r) (= (quote foo) (:tag r)) (= (quote bar) (:form r)) (= \"#foo bar\" (pr-str r))))" :expected "true"} - {:suite "reader" :expr "(let [t (first (quote [#foo bar]))] (and (tagged-literal? t) (= (quote foo) (:tag t)) (= \"#foo bar\" (pr-str t))))" :expected "true"} {:suite "reader" :expr "(= \\a (read-string \"\\\\a\"))" :expected "true"} {:suite "reader" :expr "(= \\newline (read-string \"\\\\newline\"))" :expected "true"} {:suite "reader" :expr "(= \\space (read-string \"\\\\space\"))" :expected "true"} @@ -326,25 +323,14 @@ {:suite "reader" :expr "(= [1 [2 3] {:k :v}] (read-string \"[1 [2 3] {:k :v}]\"))" :expected "true"} {:suite "reader" :expr "(= (quote (quote x)) (read-string \"'x\"))" :expected "true"} {:suite "reader" :expr "(= (quote (clojure.core/deref a)) (read-string \"@a\"))" :expected "true"} - {:suite "reader" :expr "(= (quote (syntax-quote (a (clojure.core/unquote b)))) (read-string \"`(a ~b)\"))" :expected "true"} - {:suite "reader" :expr "(= (quote (clojure.core/unquote-splicing xs)) (read-string \"~@xs\"))" :expected "true"} + {:suite "reader" :expr "(= (quote (syntax-quote (a (unquote b)))) (read-string \"`(a ~b)\"))" :expected "true"} + {:suite "reader" :expr "(= (quote (unquote-splicing xs)) (read-string \"~@xs\"))" :expected "true"} {:suite "reader" :expr "(= 42 (read-string \"; comment\\n42\"))" :expected "true"} {:suite "reader" :expr "(= [1 2] (read-string \"[1 #_ 9 2]\"))" :expected "true"} {:suite "reader" :expr "(nil? (read-string \"\"))" :expected "true"} {:suite "reader" :expr "(nil? (read-string \" , ,\"))" :expected "true"} {:suite "reader" :expr "(:tag (meta (read-string \"^String x\")))" :expected "String"} {:suite "reader" :expr "(:foo (meta (read-string \"^:foo x\")))" :expected "true"} - {:suite "reader" :expr "(:line (meta (read-string \"(foo bar)\")))" :expected "1"} - {:suite "reader" :expr "(:column (meta (read-string \"(foo bar)\")))" :expected "1"} - {:suite "reader" :expr "(:line (meta (read-string \"\\n\\n (x)\")))" :expected "3"} - {:suite "reader" :expr "(:column (meta (read-string \"\\n\\n (x)\")))" :expected "3"} - {:suite "reader" :expr "(nil? (meta (read-string \"[1 2]\")))" :expected "true"} - {:suite "reader" :expr "(nil? (meta (read-string \"()\")))" :expected "true"} - {:suite "reader" :expr "(:foo (meta (read-string \"^:foo (x y)\")))" :expected "true"} - {:suite "reader" :expr "(:line (meta (read-string \"^:foo (x y)\")))" :expected "1"} - {:suite "reader" :expr "(:line (meta (macroexpand-1 (read-string \"(when x y)\"))))" :expected "1"} - {:suite "reader" :expr "(:line (meta (macroexpand-1 (read-string \"\\n\\n(when x y)\"))))" :expected "3"} - {:suite "reader" :expr "(:column (meta (macroexpand-1 (read-string \"(when x y)\"))))" :expected "1"} {:suite "reader" :expr "(= 42 (with-in-str \"42\" (read)))" :expected "true"} {:suite "reader" :expr "(= (quote (+ 1 2)) (with-in-str \"(+ 1 2)\" (read)))" :expected "true"} {:suite "reader" :expr "(with-in-str \"1 2\" [(read) (read)])" :expected "[1 2]"} @@ -461,43 +447,43 @@ {:suite "strns" :expr "(do (require (quote [clojure.string :as s])) (s/index-of \"abc\" \"b\"))" :expected "1"} {:suite "strns" :expr "(do (require (quote [clojure.string :as s])) (nil? (s/index-of \"abc\" \"z\")))" :expected "true"} {:suite "strns" :expr "(do (require (quote [clojure.string :as s])) (s/trim-newline \"abc\\n\\n\"))" :expected "abc"} - {:suite "type" :expr "(type 5)" :expected "java.lang.Long"} - {:suite "type" :expr "(type 5.0)" :expected "java.lang.Double"} - {:suite "type" :expr "(type (/ 10 2))" :expected "java.lang.Long"} - {:suite "type" :expr "(type \"s\")" :expected "java.lang.String"} - {:suite "type" :expr "(type :k)" :expected "clojure.lang.Keyword"} - {:suite "type" :expr "(type 'x)" :expected "clojure.lang.Symbol"} - {:suite "type" :expr "(type true)" :expected "java.lang.Boolean"} - {:suite "type" :expr "(type false)" :expected "java.lang.Boolean"} + {:suite "type" :expr "(type 5)" :expected ":number"} + {:suite "type" :expr "(type 5.0)" :expected ":number"} + {:suite "type" :expr "(type (/ 10 2))" :expected ":number"} + {:suite "type" :expr "(type \"s\")" :expected ":string"} + {:suite "type" :expr "(type :k)" :expected ":keyword"} + {:suite "type" :expr "(type 'x)" :expected ":symbol"} + {:suite "type" :expr "(type true)" :expected ":boolean"} + {:suite "type" :expr "(type false)" :expected ":boolean"} {:suite "type" :expr "(type nil)" :expected ""} - {:suite "type" :expr "(type \\a)" :expected "java.lang.Character"} - {:suite "type" :expr "(type [1 2])" :expected "clojure.lang.PersistentVector"} - {:suite "type" :expr "(type [])" :expected "clojure.lang.PersistentVector"} - {:suite "type" :expr "(type {:a 1})" :expected "clojure.lang.PersistentArrayMap"} - {:suite "type" :expr "(type #{1})" :expected "clojure.lang.PersistentHashSet"} - {:suite "type" :expr "(type '(1 2))" :expected "clojure.lang.PersistentList"} - {:suite "type" :expr "(type '())" :expected "clojure.lang.PersistentList$EmptyList"} - {:suite "type" :expr "(type (first {:a 1}))" :expected "clojure.lang.PersistentVector"} - {:suite "type" :expr "(type (map inc [1 2]))" :expected "clojure.lang.LazySeq"} - {:suite "type" :expr "(type (filter odd? [1 2 3]))" :expected "clojure.lang.LazySeq"} - {:suite "type" :expr "(type (lazy-seq (cons 1 nil)))" :expected "clojure.lang.LazySeq"} - {:suite "type" :expr "(type (take 2 (iterate inc 0)))" :expected "clojure.lang.LazySeq"} - {:suite "type" :expr "(type inc)" :expected "clojure.core$inc"} + {:suite "type" :expr "(type \\a)" :expected ":char"} + {:suite "type" :expr "(type [1 2])" :expected ":vector"} + {:suite "type" :expr "(type [])" :expected ":vector"} + {:suite "type" :expr "(type {:a 1})" :expected ":map"} + {:suite "type" :expr "(type #{1})" :expected ":set"} + {:suite "type" :expr "(type '(1 2))" :expected ":seq"} + {:suite "type" :expr "(type '())" :expected ":seq"} + {:suite "type" :expr "(type (first {:a 1}))" :expected ":vector"} + {:suite "type" :expr "(type (map inc [1 2]))" :expected ":seq"} + {:suite "type" :expr "(type (filter odd? [1 2 3]))" :expected ":seq"} + {:suite "type" :expr "(type (lazy-seq (cons 1 nil)))" :expected ":seq"} + {:suite "type" :expr "(type (take 2 (iterate inc 0)))" :expected ":seq"} + {:suite "type" :expr "(type inc)" :expected ":fn"} {:suite "type" :expr "(type (sorted-map :a 1))" :expected ":map"} {:suite "type" :expr "(type (sorted-set 1))" :expected ":jolt/sorted-set"} {:suite "type" :expr "(type (with-meta [1] {:type :custom}))" :expected ":custom"} {:suite "type" :expr "(type (with-meta {:a 1} {:type :rec}))" :expected ":rec"} - {:suite "type" :expr "(type (with-meta [1] {:other 9}))" :expected "clojure.lang.PersistentVector"} + {:suite "type" :expr "(type (with-meta [1] {:other 9}))" :expected ":vector"} {:suite "type" :expr "(do (defrecord TyR [a]) (type (->TyR 1)))" :expected "user.TyR"} {:suite "type" :expr "(do (defrecord TyR [a]) (= (symbol (str (type (->TyR 1)))) (type (->TyR 1))))" :expected "false"} {:suite "type" :expr "(do (defrecord TyR [a]) (symbol? (type (->TyR 1))))" :expected "false"} - {:suite "type" :expr "(type (atom 1))" :expected "clojure.lang.Atom"} + {:suite "type" :expr "(type (atom 1))" :expected ":jolt/atom"} {:suite "type" :expr "(type (volatile! 1))" :expected ":jolt/volatile"} - {:suite "type" :expr "(type #\"re\")" :expected "java.util.regex.Pattern"} + {:suite "type" :expr "(type #\"re\")" :expected ":jolt/regex"} {:suite "type" :expr "(do (def vx 1) (type (var vx)))" :expected ":jolt/var"} {:suite "type" :expr "(type (transient []))" :expected ":jolt/transient"} - {:suite "type" :expr "(type (random-uuid))" :expected "java.util.UUID"} - {:suite "type" :expr "(type (ex-info \"x\" {}))" :expected "clojure.lang.ExceptionInfo"} + {:suite "type" :expr "(type (random-uuid))" :expected ":jolt/uuid"} + {:suite "type" :expr "(type (ex-info \"x\" {}))" :expected ":jolt/ex-info"} {:suite "var_meta" :expr "(do (def ^:private pv 1) (:private (meta (var pv))))" :expected "true"} {:suite "var_meta" :expr "(do (def ^String tv \"a\") (:tag (meta (var tv))))" :expected "java.lang.String"} {:suite "var_meta" :expr "(do (def dv2 \"hi\" 1) (:doc (meta (var dv2))))" :expected "hi"} @@ -566,36 +552,4 @@ {:suite "bytes" :expr "(String. (byte-array [104 105]) \"UTF-8\")" :expected "hi"} {:suite "bytes" :expr "(int (first (String. (byte-array [200]) \"ISO-8859-1\")))" :expected "200"} {:suite "bytes" :expr "(String. (.getBytes \"round\" \"UTF-8\") \"UTF-8\")" :expected "round"} - {:suite "deftype-map" :expr "(do (deftype Mp [m] clojure.lang.IPersistentMap (without [_ k] m)) [(map? (->Mp 1)) (record? (->Mp 1))])" :expected "[true false]"} - {:suite "deftype-map" :expr "(do (deftype Op [s]) [(map? (->Op 1)) (record? (->Op 1)) (coll? (->Op 1))])" :expected "[false false false]"} - {:suite "deftype-map" :expr "(do (deftype Lc [xs] clojure.lang.Counted (count [_] (count xs)) clojure.lang.Seqable (seq [_] (seq xs))) [(coll? (->Lc [1 2])) (count (->Lc [1 2])) (vec (seq (->Lc [1 2])))])" :expected "[false 2 [1 2]]"} - {:suite "deftype-map" :expr "(do (defrecord Dr [a b]) [(map? (->Dr 1 2)) (record? (->Dr 1 2)) (coll? (->Dr 1 2))])" :expected "[true true true]"} - {:suite "macro-args" :expr "(do (defmacro sm [x] [(set? x) (map? x)]) (sm #{1 2}))" :expected "[true false]"} - {:suite "macro-args" :expr "(do (defmacro ws [x] (conj x :z)) (= #{1 :z} (ws #{1})))" :expected "true"} - {:suite "macro-args" :expr "(do (defmacro vm [x] (vector? x)) (vm [1 2]))" :expected "true"} - {:suite "deftype-method" :expr "(do (defprotocol P (m [_ o])) (defrecord R [n] P (m [_ _] n)) (m (->R 5) :x))" :expected "5"} - {:suite "deftype-method" :expr "(do (defprotocol P2 (m2 [_ o])) (deftype T [n] P2 (m2 [_ _] n)) (m2 (->T 7) :x))" :expected "7"} - {:suite "protocol-host" :expr "(do (defprotocol Q (e [_])) (extend-protocol Q clojure.lang.Var (e [_] :var)) [(satisfies? Q (var map)) (e (var map))])" :expected "[true :var]"} - - ;; Clojure 1.13 (1.13.0-alpha1) parity. Ahead of the JVM 1.12.5 the corpus - ;; certifies against, so these live here rather than as certified corpus rows. - {:suite "clj-1.13 req!" :expr "(req! {:a 1} :a)" :expected "1"} - {:suite "clj-1.13 req!" :expr "(req! [10 20 30] 1)" :expected "20"} - {:suite "clj-1.13 req!" :expr "(nil? (req! {:a nil} :a))" :expected "true"} - {:suite "clj-1.13 req!" :expr "(req! {:a 1} :b)" :expected :throws} - {:suite "clj-1.13 amp-binding" :expr "(let [& 42] &)" :expected :throws} - {:suite "clj-1.13 amp-binding" :expr "(loop [& 42] &)" :expected :throws} - {:suite "clj-1.13 checked-keys" :expr "(let [{:keys! [a b]} {:a 1 :b 2}] [a b])" :expected "[1 2]"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:keys! [a b]} {:a 1}] [a b])" :expected :throws} - {:suite "clj-1.13 checked-keys" :expr "(nil? (let [{:keys! [a]} {:a nil}] a))" :expected "true"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:strs! [a]} {\"a\" 5}] a)" :expected "5"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:keys! [a & b]} {:a 1 :b 2}] a)" :expected "1"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:keys! [a & b]} {:a 1}] a)" :expected :throws} - {:suite "clj-1.13 checked-keys" :expr "(let [{:keys [a & b]} {:a 1 :b 2}] a)" :expected "1"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:foo/keys! [a]} {:foo/a 7}] a)" :expected "7"} - {:suite "clj-1.13 checked-keys" :expr "(let [{:foo/keys! [a]} {}] a)" :expected :throws} - {:suite "clj-1.13 array-map-64" :expr "(keys {:a 1 :b 2 :c 3 :d 4 :e 5 :f 6 :g 7 :h 8 :i 9 :j 10})" :expected "(:a :b :c :d :e :f :g :h :i :j)"} - {:suite "clj-1.13 array-map-64" :expr "(= (map (fn [i] (keyword (str \"k\" i))) (range 20)) (keys (into {} (map (fn [i] [(keyword (str \"k\" i)) i]) (range 20)))))" :expected "true"} - {:suite "clj-1.13 array-map-64" :expr "(= (map (fn [i] (keyword (str \"k\" i))) (range 64)) (keys (reduce (fn [m i] (assoc m (keyword (str \"k\" i)) i)) {} (range 64))))" :expected "true"} - {:suite "clj-1.13 array-map-64" :expr "(= (map (fn [i] (keyword (str \"k\" i))) (range 65)) (keys (into {} (map (fn [i] [(keyword (str \"k\" i)) i]) (range 65)))))" :expected "false"} ] diff --git a/test/conformance/SPEC.md b/test/conformance/SPEC.md index 7509686..596ba16 100644 --- a/test/conformance/SPEC.md +++ b/test/conformance/SPEC.md @@ -10,7 +10,7 @@ read one data file, run each case, compare, report. | File | Role | Generated by | |------|------|--------------| -| `test/chez/corpus.edn` | **The spec.** ~3570 cases of `{:suite :label :expected :actual :portability}`, `:expected` **sourced from reference JVM Clojure**. | `test/conformance/regen-corpus.clj` | +| `test/chez/corpus.edn` | **The spec.** ~2900 cases of `{:suite :label :expected :actual}`, `:expected` **sourced from reference JVM Clojure**. | `test/conformance/regen-corpus.clj` | | `test/conformance/profile.edn` | Per-case **feature classification** — which non-portable cases need which host capability. | `certify.clj --profile` | | `test/conformance/known-divergences.edn` | The few rows whose JVM value is an opaque host object that can't round-trip to readable source (Java arrays/transients/atoms/beans/proxies print as `#object[..@addr]`), so the corpus keeps jolt's value. | `regen-corpus.clj` leftovers, hand-checked | | `test/conformance/regen-corpus.clj` | Sources every `:expected` from reference **JVM Clojure** in one process. | — | @@ -24,29 +24,17 @@ the canonical, frozen contract**: it is what every runtime consumes, what ## Row schema ```edn -{:suite "numbers / arithmetic" ; grouping; " ::