;; The seq tier on the Chez RT. ;; ;; One lazy-capable node (cseq) models Clojure's list, cons, and lazy seq — all ;; print as (...), all sequential-= to each other AND to vectors. `jolt-seq` ;; coerces any seqable (vector/map/set/string/list/seq/nil) to a cseq or nil. ;; The empty seq is a distinct value (jolt-empty-list) that prints "()" — Clojure ;; (rest [1]) is () not nil, (seq []) is nil. The higher-order fns ;; (map/filter/reduce/into/remove) apply their fn argument through `jolt-invoke`, ;; so a procedure, a keyword, or a collection all work as the fn (IFn dispatch). ;; ;; Loaded by rt.ss after collections.ss. values.ss / collections.ss reach the ;; jolt-sequential? / seq=? / seq-hash hooks defined here as forward refs (nothing ;; is CALLED during load). ;; ============================================================================ ;; the seq node + the empty-seq sentinel ;; ============================================================================ ;; head : the realized first element. tail : EITHER a realized seq (cseq | ;; jolt-nil) when forced? is #t, OR a 0-arg thunk producing one when forced? is ;; #f. Forcing memoizes (set the tail to the produced seq, flip forced?). ;; list? : #t when this cell is a PersistentList node (list literal / (list ...) ;; / cons / reverse / conj-onto-list) vs a lazy or vector-backed seq cell — the ;; only thing that distinguishes a list from any other realized seq on this host, ;; since one record type backs both (clojure.core/list?). The marker ;; lives on the cell, so (rest a-list) / (seq a-vector) / (map …) yield plain seq ;; cells and are not list?. ;; cvec/ci: for a vector-backed seq cell, the backing vector and this cell's ;; element index — so it is a real chunked-seq (chunked-seq? true, chunk-first ;; hands out a 32-element block, chunk-rest is the seq at the next block) and ;; reduce iterates the vector directly with no per-element cells. ;; 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. (define-record-type cseq (fields head (mutable tail) (mutable forced?) list? cvec ci) (nongenerative chez-cseq-v3)) (define (cseq-realized head tail) (make-cseq head tail #t #f #f 0)) ; tail already a seq (define (cseq-lazy head tail-thunk) (make-cseq head tail-thunk #f #f #f 0)) (define (cseq-list head tail) (make-cseq head tail #t #t #f 0)) ; a PersistentList node (define (cseq-vec head tail-thunk v i) (make-cseq head tail-thunk #f #f v i)) ; vector-backed (define (seq-first s) (cseq-head s)) (define (seq-more s) ; force the tail; returns a seq (cseq | jolt-nil) (if (cseq-forced? s) (cseq-tail s) (let ((t ((cseq-tail s)))) (cseq-tail-set! s t) (cseq-forced?-set! s #t) t))) ;; The empty seq (Clojure's empty list ()), distinct from nil. The (unused) field ;; defeats Chez's interning of fieldless records, so an empty list carrying ;; metadata (an `empty`/`pop`/`with-meta` result) is a distinct identity from the ;; shared jolt-empty-list — otherwise its meta would leak onto every (). (define-record-type empty-list-t (fields _) (nongenerative empty-list-v2)) (define (fresh-empty-list) (make-empty-list-t #f)) (define jolt-empty-list (fresh-empty-list)) ;; reduced: a box a reducing fn returns to stop reduce early. The ;; reduce machinery below unwraps it; (deref a-reduced) / unreduced also read it. ;; reduced?/reduced are def-var!'d into clojure.core in natives-seq.ss. (define-record-type jolt-reduced (fields val) (nongenerative jolt-reduced-v1)) ;; ============================================================================ ;; jolt-seq — coerce a seqable to a non-empty seq, or jolt-nil when empty ;; ============================================================================ (define (list->cseq xs) ; Scheme list -> realized cseq chain (jolt-nil if empty) (if (null? xs) jolt-nil (cseq-realized (car xs) (list->cseq (cdr xs))))) (define (vec->seq v i) ; chunked index seq over a persistent vector (if (fx>=? i (pvec-count v)) jolt-nil (cseq-vec (pvec-nth-d v i jolt-nil) (lambda () (vec->seq v (fx+ i 1))) v i))) (define (str->seq s i) (if (fx>=? i (string-length s)) jolt-nil (cseq-lazy (string-ref s i) (lambda () (str->seq s (fx+ i 1)))))) (define (jolt-seq x) (cond ((jolt-nil? x) jolt-nil) ((empty-list-t? x) jolt-nil) ((cseq? x) x) ((pvec? x) (vec->seq x 0)) ((pmap? x) (list->cseq (pmap-fold x (lambda (k v a) (cons (make-map-entry k v) a)) '()))) ((pset? x) (list->cseq (pset-fold x cons '()))) ((string? x) (str->seq x 0)) (else (error 'seq "not seqable" x)))) (define (jolt-sequential? x) (or (pvec? x) (cseq? x) (empty-list-t? x))) (define (seq->list s) ; force a finite seq to a Scheme list (let loop ((s (jolt-seq s)) (acc '())) (if (jolt-nil? s) (reverse acc) (loop (jolt-seq (seq-more s)) (cons (seq-first s) acc))))) ;; ============================================================================ ;; the seq leaf ops the emitter lowers core fns to ;; ============================================================================ (define (jolt-first x) (let ((s (jolt-seq x))) (if (jolt-nil? s) jolt-nil (seq-first s)))) ;; rest = Clojure's more(): the tail as a (possibly empty) seq, NOT nil, and ;; WITHOUT realizing it. A forced cseq (list / realized chain) hands back its tail ;; directly. An UNFORCED tail (vector / string / lazy-seq cell) is returned as a ;; deferred seq so (rest s) does not realize the next node — matching Clojure, ;; where (rest (iterate f x)) does not call f and a side-effecting lazy seq is ;; realized one element at a time. next = (seq (rest s)) still realizes one. ;; jolt-make-lazy-seq (lazy-bridge.ss) resolves at call time. (define (jolt-rest x) (let ((s (jolt-seq x))) (cond ((jolt-nil? s) jolt-empty-list) ((cseq-forced? s) (let ((m (cseq-tail s))) (if (jolt-nil? m) jolt-empty-list m))) ;; the lazyseq forces to a seq (cseq | nil); an empty realized lazyseq is ;; still a sequence value, printing "()" (see lazy-bridge.ss), so (rest s) ;; is never nil even when the tail is empty. jolt-seq coerces seq-more's ;; result (which may be jolt-empty-list, e.g. map's tail) back to cseq | nil, ;; the contract force-lazyseq relies on — else (seq (rest s)) of an empty ;; tail yields a truthy empty-list and walkers (distinct, dedupe) overrun. (else (jolt-make-lazy-seq (lambda () (jolt-seq (seq-more s)))))))) (define (jolt-next x) ; nil when the rest is empty ;; next = (seq (rest x)): the rest must be RE-SEQ'd so an empty tail collapses to ;; nil. seq-more on a lazy seq (e.g. map's) forces to jolt-empty-list, which is ;; truthy — returning it raw made (next 1-elem-lazy-seq) non-nil, so butlast and ;; other (if (next s) ...) loops over a lazy seq ran one step too far. (let ((s (jolt-seq x))) (if (jolt-nil? s) jolt-nil (jolt-seq (seq-more s))))) ;; Only the HEAD cell carries the list marker — (rest a-list)/(next a-list) return ;; the unmarked tail, so they are seqs and not list? (rest-of-a-list is a non-list ;; seq). cons/list/reverse/conj therefore mark ;; just the cell they create. ;; ;; cons always yields a list — (list? (cons x anything)) is true (cons ;; onto a vector/seq/nil all report list?). (define (jolt-cons x coll) (cseq-list x (jolt-seq coll))) ;; Scheme list -> a jolt PersistentList: head is a list cell, the tail chain is ;; plain seq cells. For (list …) and quoted list literals (the emitter lowers ;; '(a b) to (jolt-list a b)). (define (jolt-list . xs) (if (null? xs) jolt-empty-list (cseq-list (car xs) (list->cseq (cdr xs))))) ;; reverse yields a list (seed: (list? (reverse coll)) is always true). Build a ;; plain seq chain, then mark its head as a list cell. (define (jolt-reverse coll) (let loop ((s (jolt-seq coll)) (acc jolt-empty-list)) (if (jolt-nil? s) (if (empty-list-t? acc) acc (cseq-list (seq-first acc) (seq-more acc))) (loop (jolt-seq (seq-more s)) (cseq-realized (seq-first s) (if (empty-list-t? acc) jolt-nil acc)))))) (define (jolt-last coll) (let loop ((s (jolt-seq coll)) (last jolt-nil)) (if (jolt-nil? s) last (loop (jolt-seq (seq-more s)) (seq-first s))))) ;; nth over a seq (walks; forces lazily). default? selects the 3-arg behavior. (define (seq-nth coll i default? d) (if (fx ;; 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)) (define (jolt-min . xs) (apply min xs)) (define (jolt-max . xs) (apply max 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. ;; ============================================================================ (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-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 ;; inline `invoke` method with the value itself as the leading `this`. ((and (jrec? f) (find-method-any-protocol (jrec-tag f) "invoke")) => (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))) ;; calling a non-fn: a ClassCastException naming the operator, 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 (guard (e (#t "value")) (jolt-pr-str f)) " cannot be cast to clojure.lang.IFn")))))) ;; ============================================================================ ;; map / filter / reduce / into / remove + range / take / concat / apply ;; ============================================================================ (define (any-nil? seqs) (and (pair? seqs) (or (jolt-nil? (car seqs)) (any-nil? (cdr seqs))))) ;; An EMPTY seq result is () (jolt-empty-list), NOT nil — Clojure's (map f []) is ;; 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). (define (map-seq f s) (if (jolt-nil? s) jolt-empty-list (cseq-lazy (jolt-invoke f (seq-first s)) (lambda () (map-seq f (jolt-seq (seq-more s))))))) (define (map-seq* f seqs) ; multi-collection map; stops at the shortest (if (any-nil? seqs) jolt-empty-list (cseq-lazy (apply jolt-invoke f (map seq-first seqs)) (lambda () (map-seq* f (map (lambda (s) (jolt-seq (seq-more s))) seqs)))))) (define (jolt-map f . colls) (if (null? (cdr colls)) (map-seq f (jolt-seq (car colls))) (map-seq* f (map jolt-seq colls)))) (define (filter-seq pred s keep) (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. (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) (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 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 ((f coll) (let ((s (jolt-seq coll))) (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 reify/record with its own `reduce` method drives the ;; reduction (reduce f init (reify clojure.lang.IReduceInit (reduce [_ f i] ...))). (cond ((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))))))) ;; Fold through a transient so a pvec/pmap/pset target is built in O(n): a ;; persistent pvec-conj copies its whole backing vector each step, making a naive ;; fold O(n^2) (and into/vec/mapv/filterv all route here). jolt-transient-new ;; 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) (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))))) (define (range-bounded n end step) (if (if (> step 0.0) (< n end) (> n end)) (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). (define jolt-range (case-lambda (() (range-from 0)) ((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) (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)))))))))) (define (jolt-drop n coll) (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). ;; This matters for a self-referential lazy-cat (fib = (lazy-cat [0 1] (map + (rest ;; fib) fib))): forcing the rest eagerly at construction would read fib before its ;; def binds, memoizing the tail as empty. (define (concat2 a brest) (if (jolt-nil? a) (jolt-seq (brest)) (cseq-lazy (seq-first a) (lambda () (concat2 (jolt-seq (seq-more a)) brest))))) (define (jolt-concat . 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. (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))))))) ;; ============================================================================ ;; numeric predicates / identity — usable in fn AND value position (map/filter). ;; Return Scheme #t/#f (= jolt true/false). All-flonum model: coerce to an exact ;; integer for the parity tests. ;; ============================================================================ ;; 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-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)) (define (jolt-identity x) x) ;; ============================================================================ ;; keys / vals — return seqs (nil on the empty map), HAMT-iteration order ;; ============================================================================ (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); ;; consistent with the persistent vector's element-wise =/hash so a vector and a ;; list of the same elements are jolt= and hash alike. ;; ============================================================================ (define (seq=? a b) (let loop ((sa (jolt-seq a)) (sb (jolt-seq b))) (cond ((and (jolt-nil? sa) (jolt-nil? sb)) #t) ((or (jolt-nil? sa) (jolt-nil? sb)) #f) ((jolt= (seq-first sa) (seq-first sb)) (loop (jolt-seq (seq-more sa)) (jolt-seq (seq-more sb)))) (else #f)))) (define (seq-hash x) (let loop ((s (jolt-seq x)) (h 1)) (if (jolt-nil? s) (bitwise-and h hmask) (loop (jolt-seq (seq-more s)) (bitwise-and (+ (* 31 h) (key-hash (seq-first s))) hmask)))))