jolt/host/chez/compile-eval.ss
Yogthos 33eff7c7d8 Clean up codebase: rename stdlib layer, strip porting residue, fix tooling
Rename src/jolt -> stdlib (the runtime-loaded layer; jolt-core stays the
seed-baked layer) and update the loader / emit-image / doc paths. Drop dead
code: the spike/ experiments, the duplicate clojuredocs-export.edn (json moves
to tools/), the Janet-era jolt.http binding, and the orphaned
persistent_vector.clj whose ns/path didn't even match.

Strip porting residue from comments and docstrings across host/chez, jolt-core,
stdlib, tests, and docs: internal issue ids, "Phase N" markers, and the "vs
Janet" historical exposition, leaving present-tense descriptions and the real
JVM-Clojure semantic contrasts. Same pass over the corpus suite labels. The seed
is unchanged (docstrings/comments aren't emitted), so the self-host fixpoint and
corpus are untouched.

Port tools/spec_coverage.py off the dead janet probe to bin/joltc and regenerate
coverage.md; drop the dead :host/janet rule from certify.clj and regenerate the
conformance profile. Add docs/host-interop.md (the JVM shims and how to register
your own host class from a library) and a writing-style note in CLAUDE.md.

Stabilize the four racy concurrency corpus cases (future-cancel and agent
send/send-off): give the future a sleeping body and the agent a slow action, so
cancel reliably catches an in-flight future and deref reliably reads the
pre-update snapshot. They certify deterministically now, so drop their :flaky
allowlist entries and the orphaned legend.
2026-06-22 22:18:00 -04:00

148 lines
7.4 KiB
Scheme

;; compile-eval.ss — the compile spine.
;;
;; Ties together the cross-compiled compiler image (jolt.ir + jolt.analyzer +
;; jolt.backend-scheme, loaded as def-var! forms) and the host contract
;; (host-contract.ss) into a runtime entry: a Clojure source string is read by the
;; Chez data reader, analyzed by the analyzer to IR, emitted to Scheme by the
;; emitter, and eval'd. This is the spine the stage2==stage3 bootstrap fixpoint
;; closes over.
;;
;; Loaded after host-contract.ss + the compiler image.
(define jolt-ce-analyze (var-deref "jolt.analyzer" "analyze"))
(define jolt-ce-emit (var-deref "jolt.backend-scheme" "emit"))
(define jolt-ce-read (var-deref "clojure.core" "read-string"))
;; 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)
;; (quote X) -> X, else x — unwraps a quoted require spec.
(define (ce-unquote 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)) "quote") (pair? (cdr items)))
(cadr items) x))
x))
;; Pre-register any (require ...)/(use ...) :as aliases under `ns` BEFORE analysis,
;; so a qualified s/foo resolves while compiling (analysis precedes the runtime
;; require). Walks the whole form (a require may be nested in a do/let).
(define (ce-clause-require? cl) ; (:require ...) / (:use ...) ns clause
(and (pair? cl) (keyword? (car cl))
(let ((kn (keyword-t-name (car cl)))) (or (string=? kn "require") (string=? kn "use")))))
(define (ce-scan-requires! form ns)
(when (and (cseq? form) (cseq-list? form))
(let ((items (seq->list form)))
(when (pair? items)
(let* ((h (car items)) (hn (and (symbol-t? h) (symbol-t-name h))))
(cond
;; (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
((and hn (string=? hn "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 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).
;; `ns` is the compile namespace unqualified symbols resolve against.
(define (jolt-analyze-emit-form form ns)
(ce-scan-requires! form ns)
(let* ((ctx (make-analyze-ctx ns))
(ir (jolt-ce-analyze ctx form)))
(jolt-ce-emit ir)))
;; Source string -> Scheme source string (read then analyze -> emit, all on Chez).
(define (jolt-analyze-emit src ns)
(jolt-analyze-emit-form (jolt-ce-read src) ns))
;; --- runtime defmacro -------------------------------------------------------
;; Shared with emit-image.ss (loaded after this). A defmacro lowers to a def of
;; its expander fn + a macro flag, exactly as the prelude emits build-time macros.
;; Is `f` a (defmacro ...) / (definline ...) form?
(define (ce-macro-form? f)
(and (cseq? f) (cseq-list? f)
(let ((items (seq->list f)))
(and (pair? items) (symbol-t? (car items))
(let ((h (symbol-t-name (car items))))
(or (string=? h "defmacro") (string=? h "definline")))))))
;; (defmacro NAME [docstring] [attr-map] params body...) -> (values "NAME" (fn ...)).
;; Strips a leading docstring (native string) + attr-map (a non-symbol pmap), then
;; re-heads the rest with `fn` so a destructured macro arglist desugars. Emits the
;; BARE fn (the caller wraps it in def-var! + mark-macro!), never a (def NAME ...) —
;; interning NAME would make require skip the real macro.
(define (ce-defmacro->fn f)
(let* ((items (seq->list f))
(name-sym (cadr items))
(after-name (cddr items))
(a1 (if (and (pair? after-name) (string? (car after-name)))
(cdr after-name) after-name))
(after-meta (if (and (pair? a1) (pmap? (car a1)))
(cdr a1) a1))
(fn-sym (jolt-symbol #f "fn")))
(values (symbol-t-name name-sym)
(apply jolt-list (cons fn-sym after-meta)))))
;; A bare top-level (do ...) form — head is the unqualified `do` symbol.
(define (ce-top-do? form)
(and (cseq? form) (cseq-list? form)
(let ((h (seq-first form)))
(and (symbol-t? h) (jolt-nil? (hc-sym-ns h))
(string=? (symbol-t-name h) "do")))))
;; Compile + eval ONE already-read form in compile ns `ns`; returns the value.
;; 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.
(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
;; land there and its refs resolve (cross-ns def/require in one program).
((ce-top-do? form)
(let loop ((fs (cdr (seq->list form))) (result jolt-nil) (cur ns))
(if (null? fs)
result
(let ((r (jolt-compile-eval-form (car fs) cur)))
(loop (cdr fs) r (chez-current-ns))))))
;; defmacro is compiled like any other form — the analyzer lowers it to a def
;; of the expander fn + (mark-macro! …) so subsequent forms expand it. One
;; macro-expansion path (no separate spine interception).
(else
(eval (read (open-input-string (jolt-analyze-emit-form form ns)))
(interaction-environment)))))
;; Source string -> value (read one form, compile + eval on Chez, in the
;; top-level environment where rt.ss's runtime procedures live).
(define (jolt-compile-eval src ns)
(jolt-compile-eval-form (jolt-ce-read src) ns))
;; clojure.core/load-string: read every form from the source string and compile+
;; eval each in the current ns, returning the last value (nil for blank input).
(define (jolt-load-string s)
(let loop ((src s) (result jolt-nil))
(let ((pn (jolt-parse-next src)))
(if (jolt-nil? pn)
result
(loop (jolt-nth pn 1)
(jolt-compile-eval-form (jolt-nth pn 0) (chez-current-ns)))))))
;; eval / load-string are FUNCTIONS on the spine (the compiler image is resident
;; at runtime). eval takes an already-read FORM (e.g. from quote / list); it and
;; load-string compile+eval in the current ns. eval is removed from the analyzer's
;; special-symbol lists (host-contract.ss) so it resolves as an ordinary core var.
(def-var! "clojure.core" "eval"
(lambda (form) (jolt-compile-eval-form form (chez-current-ns))))
(def-var! "clojure.core" "load-string" jolt-load-string)