jolt/jolt-core/clojure/core/40-lazy.clj
Yogthos 14547bd1d5 JVM-semantics fixes and small cleanups
- take-last / drop-last return seqs, not vectors: take-last wraps in seq; drop-last
  is the JVM (map (fn [x _] x) coll (drop n coll)) form (lazy, () when empty).
- cycle is lazy ((lazy-seq (concat coll (cycle coll)))) so it no longer counts its
  argument and terminates on a lazy/infinite input.
- fold's foldable-call catch uses :default, matching the rest of jolt-core and
  also catching a raw host condition from a folding primitive.
- alts! rejects non-channel ports with a clear error (put specs / :default are
  unsupported) instead of crashing inside ac-poll!.
- Misc: drop the unreachable second getCause clause; jolt-nth on a string raises
  'nth "index out of bounds" like the vector branch; name the inline fixpoint cap;
  bld-sh-capture rejoins lines with newlines; clarify a couple of comments.
2026-06-23 01:36:51 -04:00

189 lines
5.6 KiB
Clojure

;; clojure.core — lazy tier. Canonical CLJS-based lazy seq fns.
;; Loaded after 30-macros.clj, so lazy-seq macro is available.
;;
;; Each fn ported from CLJS core.cljs, stripped of chunked-seq branches.
;; --- distinct --- (transducer + lazy collection arity; value-based dedup)
(defn distinct
([]
(fn [rf]
(let [seen (volatile! #{})]
(fn ([] (rf)) ([result] (rf result))
([result input]
(if (contains? @seen input)
result
(do (vswap! seen conj input) (rf result input))))))))
([coll]
(let [step (fn step [xs seen]
(lazy-seq
((fn [[f :as xs] seen]
(when-let [s (seq xs)]
(if (contains? seen f)
(recur (rest s) seen)
(cons f (step (rest s) (conj seen f))))))
xs seen)))]
(step coll #{}))))
;; --- keep ---
(defn keep
([f]
(fn [rf]
(fn ([] (rf)) ([result] (rf result))
([result input]
(let [v (f input)]
(if (nil? v) result (rf result v)))))))
([f coll]
(lazy-seq
(when-let [s (seq coll)]
(let [x (f (first s))]
(if (nil? x)
(keep f (rest s))
(cons x (keep f (rest s)))))))))
;; --- keep-indexed ---
(defn keep-indexed
([f]
(fn [rf]
(let [ia (volatile! -1)]
(fn ([] (rf)) ([result] (rf result))
([result input]
(let [i (vswap! ia inc)
v (f i input)]
(if (nil? v) result (rf result v))))))))
([f coll]
(letfn [(keepi [idx coll]
(lazy-seq
(when-let [s (seq coll)]
(let [x (f idx (first s))]
(if (nil? x)
(keepi (inc idx) (rest s))
(cons x (keepi (inc idx) (rest s))))))))]
(keepi 0 coll))))
;; --- map-indexed ---
(defn map-indexed
([f]
(fn [rf]
(let [i (volatile! -1)]
(fn ([] (rf)) ([result] (rf result))
([result input] (rf result (f (vswap! i inc) input)))))))
([f coll]
(letfn [(mapi [idx coll]
(lazy-seq
(when-let [s (seq coll)]
(cons (f idx (first s)) (mapi (inc idx) (rest s))))))]
(mapi 0 coll))))
;; --- cycle ---
;; Lazy, like the JVM: never counts coll, so it terminates on a lazy/infinite
;; argument instead of forcing it.
(defn cycle [coll]
(if (seq coll)
(lazy-seq (concat coll (cycle coll)))
()))
;; --- repeatedly --- ((f) throws on a non-fn; (take n …) throws on a non-number
;; count — both enforced by the host (jolt-call / take), so the canonical
;; CLJ form matches the repeatedly.cljc exception cases.)
(defn repeatedly
([f] (lazy-seq (cons (f) (repeatedly f))))
([n f] (take n (repeatedly f))))
;; --- repeat ---
(defn repeat
([x] (lazy-seq (cons x (repeat x))))
([n x] (take n (repeat x))))
;; --- iterate ---
(defn iterate [f x]
(lazy-seq (cons x (iterate f (f x)))))
;; --- partition-all --- (transducer + [n coll] + [n step coll])
;; The collection arities realize EXACTLY n per chunk via a first/rest loop and
;; continue from the advanced cursor (not a re-drop / nthrest), so they realize
;; minimally — the laziness counters depend on this.
;; (A take/nthrest form is correct but over-realizes.)
(defn partition-all
([n]
(fn [rf]
(let [a (volatile! [])]
(fn
([] (rf))
([result]
(let [result (if (zero? (count @a))
result
(let [v @a] (vreset! a []) (unreduced (rf result v))))]
(rf result)))
([result input]
(vswap! a conj input)
(if (= n (count @a))
(let [v @a] (vreset! a []) (rf result v))
result))))))
([n coll]
(letfn [(go [s]
(lazy-seq
(when (seq s)
(loop [i 0 chunk [] cur s]
(if (and (< i n) (seq cur))
(recur (inc i) (conj chunk (first cur)) (rest cur))
(cons chunk (go cur)))))))]
(go coll)))
([n step coll]
(letfn [(go [s]
(lazy-seq
(when (seq s)
(cons (take n s) (go (nthrest s step))))))]
(go coll))))
;; --- canonical lazy + transducer arities -------------------------------------
(defn interpose
([sep]
(fn [rf]
(let [started (volatile! false)]
(fn
([] (rf))
([result] (rf result))
([result input]
(if (deref started)
(let [sepr (rf result sep)]
(if (reduced? sepr)
sepr
(rf sepr input)))
(do (vreset! started true)
(rf result input))))))))
([sep coll]
(drop 1 (interleave (repeat sep) coll))))
(defn take-nth
([n]
(fn [rf]
(let [iv (volatile! -1)]
(fn
([] (rf))
([result] (rf result))
([result input]
(let [i (vswap! iv inc)]
(if (zero? (rem i n))
(rf result input)
result)))))))
([n coll]
(lazy-seq
(when-let [s (seq coll)]
(cons (first s) (take-nth n (drop n s)))))))
;; --- pmap family: parallel map over real-thread futures ----------------------
;; Each element's work runs on its own OS thread with SNAPSHOT semantics
;; (futures marshal captured state — pure fns only, mutations don't propagate
;; back). All futures are spawned up front (doall), then derefed in order:
;; coarse-grained work only, as with Clojure's pmap.
(defn pmap
([f coll]
(map deref (doall (map (fn [x] (future (f x))) coll))))
([f coll & colls]
(pmap (fn [xs] (apply f xs)) (apply map vector coll colls))))
(defn pcalls [& fns] (pmap (fn [f] (f)) fns))