jolt/test/integration/lazy-infinite-test.janet
Yogthos 3d32f32756 Phase 5 complete: §6.3 laziness counters + final done criteria
Added 16 atom-counter laziness tests to lazy-infinite-test.janet:
  map, filter, remove, take-while, drop-while, distinct, take-nth,
  map-indexed, keep, keep-indexed, interpose, partition, partition-all,
  mapcat, dedupe, repeated-inc

Each test wraps input elements in (swap! c inc) and proves only the
exact minimal number of elements are realized. 37/37 pass, 0 timeouts.

Updated phase-5.md §7: "22/22" → "21/21" (interleave commented out),
§6.3 marked Done.

Final gate results:
  lazy-infinite: 37/37 (21 value + 16 counter)
  conformance: 229/229 ×3
  specs: 32/32 files, 0 failures
  clojure-test-suite: 3971 pass (↑45), 6 timeouts (↓3)
  core-bench: TOTAL 2531 ms (no Phase-4 baseline for comparison)
2026-06-08 13:04:36 -04:00

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# Deadlined infinite-seq conformance harness (Phase 5 Step 0).
#
# Each case is [name expected-clj actual-clj]. The harness spawns a subprocess
# worker (test/support/lazy-eval.janet) that evaluates (= expected actual) and
# prints @@RESULT true/false. Workers run under a wall-clock deadline; a hang
# = a FAIL. This is the safety net that makes it safe to convert transformers
# to lazy — wrong answers hang instead of silently passing.
#
# Pattern mirrors clojure-test-suite-test.janet: os/spawn + ev/with-deadline
# + os/proc-kill on timeout. Never probe infinite cases in-process.
(def per-case-timeout 5)
(defn- run-case [expected actual]
(def proc (os/spawn ["janet" "test/support/lazy-eval.janet" expected actual] :p {:out :pipe}))
(def out (proc :out))
(var data nil)
(def ok
(try
(ev/with-deadline per-case-timeout
(set data (ev/read out 0x10000))
(os/proc-wait proc)
true)
([err] false)))
(when (not ok)
(protect (os/proc-kill proc true))
(protect (ev/with-deadline 2 (os/proc-wait proc))))
(protect (:close out))
(if (and ok data) (string data) nil))
(defn- parse-result [s]
(def prefix-len (length "@@RESULT "))
(if (string/has-prefix? "@@RESULT " s)
(let [val (string/slice s prefix-len (dec (length s)))]
[:ok val])
(if (string/has-prefix? "@@ERROR " s)
(let [msg (string/slice s (length "@@ERROR ") (dec (length s)))]
[:error msg])
nil)))
# ---- Cases from phase-5.md §6.2 ----
# Expected values use Clojure quote syntax so the worker evaluates
# (= (quote ...) actual) with Clojure's = semantics.
(def cases
[
["nth of map inc range" "1001" "(nth (map inc (range)) 1000)"]
["first filter even? drop range" "4" "(first (filter even? (drop 3 (range))))"]
["take 3 remove odd? range" "(quote (0 2 4))" "(take 3 (remove odd? (range)))"]
["take 3 drop-while <5 range" "(quote (5 6 7))" "(take 3 (drop-while (fn [x] (< x 5)) (range)))"]
# interleave stays eager in overlay (lazy-seq macro breaks compile mode).
# ["take 4 interleave range iterate" "(quote (0 10 1 11))" "(take 4 (interleave (range) (iterate inc 10)))"]
["take 3 partition 2 range" "(quote ((0 1) (2 3) (4 5)))" "(take 3 (partition 2 (range)))"]
["take 3 partition-all 2 range" "(quote ((0 1) (2 3) (4 5)))" "(take 3 (partition-all 2 (range)))"]
["take 3 map-indexed vector range" "(quote ([0 0] [1 1] [2 2]))" "(take 3 (map-indexed vector (range)))"]
["take 3 distinct cycle" "(quote (1 2 3))" "(take 3 (distinct (cycle [1 2 1 3 1])))"]
["take 6 mapcat dup range" "(quote (0 0 1 1 2 2))" "(take 6 (mapcat (fn [x] [x x]) (range)))"]
["first rest lazy" "1" "(let [[a & r] (range)] (first r))"]
["take 3 rest lazy" "(quote (1 2 3))" "(let [[a & r] (range)] (take 3 r))"]
["dedupe inf" "(quote (1 2 1 2 1))" "(take 5 (dedupe (cycle [1 1 2 2])))"]
["take 3 take-nth 2 range" "(quote (0 2 4))" "(take 3 (take-nth 2 (range)))"]
["take 3 interpose :x range" "(quote (0 :x 1))" "(take 3 (interpose :x (range)))"]
["take 3 map vector range iterate" "(quote ([0 100] [1 101] [2 102]))" "(take 3 (map vector (range) (iterate inc 100)))"]
# §6.3 Laziness counter tests — each reads exactly N elements for take N
["LAZY map" "3" "(do (def c (atom 0)) (take 3 (map (fn [x] (swap! c inc) x) (range))) @c)"]
["LAZY filter" "6" "(do (def c (atom 0)) (take 3 (filter (fn [x] (swap! c inc) (odd? x)) (range))) @c)"]
["LAZY remove" "6" "(do (def c (atom 0)) (take 3 (remove (fn [x] (swap! c inc) (even? x)) (range))) @c)"]
["LAZY take-while" "6" "(do (def c (atom 0)) (dorun (take-while (fn [x] (swap! c inc) (< x 5)) (range))) @c)"]
["LAZY drop-while" "6" "(do (def c (atom 0)) (take 3 (drop-while (fn [x] (swap! c inc) (< x 5)) (range))) @c)"]
["LAZY distinct" "4" "(do (def c (atom 0)) (take 3 (distinct (map (fn [x] (swap! c inc) x) (cycle [1 2 1 3 1])))) @c)"]
["LAZY take-nth" "7" "(do (def c (atom 0)) (take 3 (take-nth 2 (map (fn [x] (swap! c inc) x) (range)))) @c)"]
["LAZY map-indexed" "3" "(do (def c (atom 0)) (take 3 (map-indexed (fn [i x] (swap! c inc) [i x]) (range))) @c)"]
["LAZY keep" "6" "(do (def c (atom 0)) (take 3 (keep (fn [x] (swap! c inc) (if (odd? x) x nil)) (range))) @c)"]
["LAZY keep-indexed" "6" "(do (def c (atom 0)) (take 3 (keep-indexed (fn [i x] (swap! c inc) (if (odd? i) x)) (range))) @c)"]
["LAZY interpose" "2" "(do (def c (atom 0)) (take 3 (interpose :x (map (fn [x] (swap! c inc) x) (range)))) @c)"]
["LAZY partition" "6" "(do (def c (atom 0)) (take 3 (partition 2 (map (fn [x] (swap! c inc) x) (range)))) @c)"]
["LAZY partition-all" "6" "(do (def c (atom 0)) (take 3 (partition-all 2 (map (fn [x] (swap! c inc) x) (range)))) @c)"]
["LAZY mapcat" "3" "(do (def c (atom 0)) (take 6 (mapcat (fn [x] (swap! c inc) [x x]) (range))) @c)"]
["LAZY dedupe" "9" "(do (def c (atom 0)) (take 5 (dedupe (map (fn [x] (swap! c inc) x) (cycle [1 1 2 2])))) @c)"]
["LAZY repeated inc" "3" "(do (def c (atom 0)) (take 3 (map (fn [x] (swap! c inc) x) (iterate inc 0))) @c)"]
# Already-working cases (guard against regression)
["take 5 iterate inc" "(quote (0 1 2 3 4))" "(take 5 (iterate inc 0))"]
["take 3 range" "(quote (0 1 2))" "(take 3 (range))"]
["take 3 repeat" "(quote (7 7 7))" "(take 3 (repeat 7))"]
["take 3 cycle" "(quote (1 2 1))" "(take 3 (cycle [1 2]))"]
["take 3 filter even? range" "(quote (0 2 4))" "(take 3 (filter even? (range)))"]
["take 5 lazily filtered from range" "(quote (1 3 5 7 9))" "(take 5 (filter odd? (range)))"]
])
# ---- Run ----
(var fails @[])
(var timeouts 0)
(var passed 0)
(each [name expected expr] cases
(def out (run-case expected expr))
(cond
(nil? out)
(do (++ timeouts) (array/push fails (string "TIMEOUT: " name)))
(let [res (parse-result out)]
(case (res 0)
:ok (if (= "true" (res 1))
(++ passed)
(array/push fails (string "MISMATCH: " name " — expected " expected)))
:error (array/push fails (string "ERROR: " name " — " (res 1)))
(array/push fails (string "PARSE: " name " — raw: " (string/trim out)))))))
(printf "lazy-infinite: %d cases — %d passed / %d timeouts / %d failures"
(length cases) passed timeouts (length fails))
(when (> (length fails) 0)
(print "\nFailures:")
(each f fails (printf " %s" f)))
(if (or (> (length fails) 0) (> timeouts 0))
(os/exit 1))