Closes the last clojure.core prelude emit gap (parse-uuid): the whole non-macro core now lowers to Scheme (prelude reach 355/355). A #"..." literal analyzes to a :regex IR node. The Chez back end emits a jolt-regex value over irregex (Alex Shinn, BSD), vendored as the vendor/irregex submodule -- a portable Scheme regex with PCRE/Java-style string patterns and first-class Chez support. host/chez/regex.ss wraps jolt's re-* surface over it: irregex-match -> re-matches (anchored), irregex-search -> re-find, groups as Clojure [whole g1 ...] vectors, re-seq as a jolt seq. re-pattern/re-matches/re-find/re-seq/regex? are def-var!'d into clojure.core so prelude / -e code resolves them. They stay OUT of the subset native-ops on purpose: irregex's Unicode/property-class semantics differ from the seed's byte-PEG approximation, so keeping them prelude-only avoids dragging engine-difference divergences into the subset-parity corpus. The Janet back end punts :regex to the interpreter (the seed compiles #"..." to a Janet PEG), so the main language is unchanged. Only two adaptations for Chez's top level: a cond-expand shim (Chez's is library-only) and a normalizing error wrapper (silences irregex's 1-arg error warnings). rt.ss load is ~0.18s. emit-test 131/131 (regex literal + re-* parity vs the CLI oracle); prelude reach 355/355; Chez subset 672/672, 0 divergences; full gate green. |
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|---|---|---|
| .. | ||
| core-prelude-probe.janet | ||
| corpus.edn | ||
| emit-test.janet | ||
| extract-corpus.janet | ||
| known-divergences.edn | ||
| README.md | ||
| run-corpus-chez.janet | ||
| run-corpus.janet | ||
| values-test.ss | ||
Chez port — Phase 0 test contract harness
The host-neutral correctness gate for the Chez re-host (epic jolt-cf1q). The spec corpus is data, so the SAME contract validates every host.
Files
extract-corpus.janet— parsestest/spec/*.janet(defspec …)tables as data and writescorpus.edn(2655[label expected actual]cases). The file is valid as BOTH EDN (a future Chez-jolt runner) and Janet data (the runner below). Regenerate:janet test/chez/extract-corpus.janet.corpus.edn— the extracted contract (generated; checked in for convenience).run-corpus.janet— drives a TARGET jolt binary, one fresh subprocess per case (fresh ctx = per-case isolation), checking(= expected actual)printstrueat the CLI, or that a:throwscase exits non-zero. Pluggable target:janet test/chez/run-corpus.janet# default build/joltJOLT_BIN=build/jolt-chez janet test/chez/run-corpus.janet# Phase 1+JOLT_CORPUS_LIMIT=400 …# every-Nth stride, fast
known-divergences.edn— allowlist of cases that diverge at the CLI boundary. The gate fails only on a NEW divergence; known ones are reported but tolerated.values-test.ss/../../host/chez/values.ss— Phase 0a value model + tests.
The reference baseline (2026-06-17, Janet build/jolt, compile mode)
2641/2655 pass; 14 known divergences. They split into:
- interpret-vs-compile leniency —
:throwscases where interpret mode raises but compile mode returns (< nil,> with nil,neg? keyword,max/min-keyon non-numbers). Several are also non-canonical vs JVM Clojure. - invoke-collection-as-fn — the
transient / invokable lookupsuite invokes transients/collections as fns (((transient {:x 7}) :x)); compile mode (and JVM Clojure) reject it. xml-seq walks— one structural case.
The compile-only Chez host (JVM-canonical oracle) should MATCH OR FIX these. The gate's job is to catch regressions the port introduces, not to bless these.
Why the CLI boundary
The runner tests through jolt -e, exactly how the Chez host will be exercised —
not the in-process eval-string the Janet defspec harness uses. The two differ
on a handful of cases (the allowlist), and the CLI boundary is the portable one.
Phase 1 — first parity number (subset probe)
The full run-corpus.janet gate drives an -e-capable jolt binary; the Chez
host can't answer arbitrary -e until all of clojure.core is bootstrapped onto
Chez (Phase 2). Until then, run-corpus-chez.janet reports parity for the subset
the Phase-1 back end (host/chez/emit.janet) can already compile: each case is
run through the live analyzer → Scheme emitter → Chez via host/chez/driver.
Cases that reference unimplemented stdlib/host fns fail to EMIT (a clean
compile-time signal) and are counted "out of subset", not as divergences.
JOLT_CHEZ_CORPUS=1 janet test/chez/run-corpus-chez.janet
Baseline after inc 3g (letfn + declare): 672/672 compiled cases pass, 0
divergences; 1986/2658 out of subset (await clojure.core on Chez). Inc 3e
(throw/try + ex-info) was 632/632; inc 3f's quote support + a seq.ss fix (empty
map/filter results are () not nil, matching Clojure) reached 664/664; inc 3g
(letfn -> Scheme letrec*, declare/def-no-init -> a reserved var cell) pulled 8
more corpus cases into the subset. emit-fn lowers multi-arity fns to a Scheme
case-lambda and variadic fns to a rest-arg lambda (rest list coerced to a jolt
seq, nil when empty).
Phase 1 — clojure.core prelude emission (inc 3d, jolt-ocvi)
The -e-capable jolt-chez path: emit the clojure.core tiers
(jolt-core/clojure/core/NN-*.clj) through the same analyzer → emit pipeline as a
Scheme PRELUDE of def-var! forms, so user code's (var-deref "clojure.core" …)
resolves the fn at runtime. emit/set-prelude-mode! flips a switch: in the default
(subset) mode a non-native clojure.core ref is rejected ("out of subset"); in
prelude mode it lowers to a runtime var-deref so core fns chain through each
other. Host interop (:host) and unhandled IR ops still error in both modes —
those are the real gaps that need a hand-written RT shim or new emit support.
core-prelude-probe.janet (gated behind JOLT_CHEZ_PRELUDE=1) measures reach and
catalogs the gaps; macros are skipped (analyze-time only, not a runtime value):
JOLT_CHEZ_PRELUDE=1 janet test/chez/core-prelude-probe.janet
Baseline after inc 3i (regex): 355/355 non-macro core forms emit to Scheme —
the whole non-macro clojure.core now lowers. inc 3i closed the last gap, the regex
literal in parse-uuid: a #"…" literal lowers to a :regex IR node and the Chez
emitter emits a jolt-regex value over vendored irregex (Alex Shinn, BSD,
vendor/irregex submodule) — a portable Scheme regex with PCRE/Java-style string
patterns. re-pattern/re-matches/re-find/re-seq/regex? are def-var!'d
into clojure.core (host/chez/regex.ss); they stay OUT of the subset native-ops
(irregex's Unicode/property-class semantics differ from the seed's byte-PEG
approximation), so they resolve in prelude mode — the path the assembled prelude
takes — without dragging engine-difference divergences into the subset corpus. The
Janet back end punts :regex to the interpreter (the seed compiles #"…" to a
Janet PEG). Prior incs: inc 3h .method → :host-call (jolt-host-call for
.write/.isDirectory/.listFiles); :quote, :throw, :try, ex-info,
letfn → letrec*, declare/def-no-init → reserved var cell. The probe has a
regression floor (355) — every non-macro core form must keep emitting.
Prior, inc 3b (seq tier + dynamic IFn, jolt-5pso): 595/595 compiled, 0 divergences,
2060/2655 out of subset. The seq tier brought up a list/lazy-seq type with
first/rest/next/seq/cons/list, map/filter/reduce/into/remove,
range/take/drop/concat/apply, keys/vals, and nth/peek/pop over seqs; dynamic IFn
dispatch (a keyword/vector/coll held in a local and called as a fn) routes through
the jolt-invoke fallback, closing the 3 ex-known divergences. The probe exits
non-zero on any NEW divergence.
(Prior, inc 3a: 433/436 compiled, 3 known IFn divergences, 2219 out of subset. Inc 2: 182/182 compiled, 0 divergences, 2473 out of subset.)
It's a slow report (a Chez subprocess per case), so it's gated behind
JOLT_CHEZ_CORPUS out of the default suite, like the benches.
test/chez/emit-test.janet is the fast Phase-1 unit gate (real analyzer → Chez
parity for fib/mandelbrot + collections + regressions); both skip cleanly when
chez isn't on PATH.