emit-loop compiled every loop/recur to a self-recursive local closure called once per iteration — relying on Janet TCO for stack safety but paying a fn frame + arg bind each iteration. The jolt-5vsp spike localized the whole ~1.43x jolt-over-hand-Janet gap on compute loops to exactly this. Lower instead to a Janet `while` + state vars: the loop bindings become vars carried across iterations, a recur writes them and raises a continue flag, and a non-recur tail value falls out through a result var. recur-name routing in emit-recur picks the while-set lowering for loops and leaves the fn-arity self-call path untouched. The one subtlety is closure capture: Janet closures capture vars BY REFERENCE, so a closure built in the body over a shared mutable loop var would see the final value ([3 3 3]) instead of its iteration's ([0 1 2]). Each iteration rebinds the loop names into a fresh immutable `let` before running the body, which restores per-iteration capture. recur reads those immutable bindings and writes the state vars, so cross-referencing args (swap, fib) need no temps. mandelbrot 218 -> 164 ms (~11.2x JVM, from 15x). fib is unaffected — it's fn-arity recursion, not a loop. Regression spec in control-flow-spec covers closure capture, no-clobber recur, nested loops, sequential init, recur through let, and that fn-arity recur still works. Gate green (conformance x3, full suite). Note: validating this after a rebuild needs JOLT_NO_DEPS_CACHE=1 — the deps-image cache keys on the version string, not build identity, so it served stale codegen (filed separately). Co-authored-by: Yogthos <yogthos@gmail.com>
108 lines
6.9 KiB
Text
108 lines
6.9 KiB
Text
# Specification: control flow & binding forms.
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(use ../support/harness)
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(defspec "control / conditionals"
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["if true" "1" "(if true 1 2)"]
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["if false" "2" "(if false 1 2)"]
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["if nil is false" "2" "(if nil 1 2)"]
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["if no else" "nil" "(if false 1)"]
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["when true" "3" "(when true 1 2 3)"]
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["when false" "nil" "(when false 1)"]
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["when-not" "1" "(when-not false 1)"]
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["cond" ":b" "(cond false :a true :b :else :c)"]
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["cond :else" ":c" "(cond false :a false :b :else :c)"]
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["cond no match" "nil" "(cond false :a)"]
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["condp" "\"two\"" "(condp = 2 1 \"one\" 2 \"two\" \"other\")"]
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["case" ":b" "(case 2 1 :a 2 :b :default)"]
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["case default" ":d" "(case 9 1 :a 2 :b :d)"]
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["case multi" ":ab" "(case 2 (1 2) :ab 3 :c)"]
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["case symbol const" ":s" "(case 'foo foo :s :default)"]
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["case vector const" ":v" "(case [1 2] [1 2] :v :default)"]
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["case map const" ":m" "(case {:a 1} {:a 1} :m :default)"]
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["case list const" ":l" "(case '(a b) (quote (a b)) :l :default)"]
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["case keyword" ":k" "(case :x :x :k :default)"])
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(defspec "control / logic"
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["and all true" "3" "(and 1 2 3)"]
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["and short circuits" "nil" "(and 1 nil 3)"]
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["and empty" "true" "(and)"]
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["or first truthy" "1" "(or nil 1 2)"]
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["or all false" "false" "(or nil false)"]
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["or empty" "nil" "(or)"]
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["not" "false" "(not true)"])
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(defspec "control / let & loop"
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["let" "3" "(let [a 1 b 2] (+ a b))"]
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["let sequential" "3" "(let [a 1 b (+ a 2)] b)"]
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["let shadowing" "2" "(let [a 1] (let [a 2] a))"]
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["letfn mutual" "true" "(letfn [(ev? [n] (if (zero? n) true (od? (dec n)))) (od? [n] (if (zero? n) false (ev? (dec n))))] (ev? 10))"]
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["loop/recur" "15" "(loop [i 1 acc 0] (if (> i 5) acc (recur (inc i) (+ acc i))))"]
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["when-let" "2" "(when-let [x 1] (inc x))"]
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["when-let nil" "nil" "(when-let [x nil] (inc x))"]
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["if-let" "2" "(if-let [x 1] (inc x) :none)"]
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["if-let else" ":none" "(if-let [x nil] (inc x) :none)"]
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["if-some zero" "1" "(if-some [x 0] (inc x) :none)"]
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["when-some nil" "nil" "(when-some [x nil] x)"])
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# Regression: if-let/when-let/if-some/when-some bind the name ONLY in the
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# then/body branch. The else branch (and a falsy when-let body, which there is
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# none of) must see the surrounding scope, not the binding — so the else of
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# (let [x 5] (if-let [x nil] ...)) sees x=5, like Clojure. (Previously the macros
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# wrapped the whole `if` in the binding's let*, leaking it into the else.)
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(defspec "control / conditional-binding scope"
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["if-let else sees outer" "5" "(let [x 5] (if-let [x nil] :then x))"]
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["if-let then binds" "7" "(let [x 5] (if-let [x 7] x :else))"]
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["if-some else sees outer" "5" "(let [x 5] (if-some [x nil] :then x))"]
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["if-some binds false" "false" "(if-some [x false] x :else)"]
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["when-let else via or" "5" "(let [x 5] (or (when-let [x nil] x) x))"]
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["when-let multi-form body" "14" "(when-let [x 7] (inc x) (* x 2))"]
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["if-let in fn param" "9" "((fn [xs] (if-let [xs nil] :then xs)) 9)"]
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["when-some binds zero" "1" "(when-some [x 0] (inc x))"]
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["if-let evals test once" "1" "(let [c (atom 0)] (if-let [v (do (swap! c inc) :v)] @c :none))"])
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# Regression: loop/recur lowering (jolt-v28u). The backend lowers tail loop/recur
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# to a Janet while + state vars with a fresh per-iteration `let` rebinding of the
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# loop names. The let rebinding is load-bearing: a closure created in the body
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# must capture THAT iteration's value (Clojure semantics), not a shared mutable
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# var — Janet closures capture vars by reference, so a naive while+var would give
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# [3 3 3]. recur reads the (immutable) iteration bindings and writes the state
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# vars, so cross-referencing args don't clobber (swap, fib).
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(defspec "control / loop lowering (jolt-v28u)"
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["closure captures per-iter binding" "[0 1 2]"
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"(mapv (fn [g] (g)) (loop [i 0 fs []] (if (< i 3) (recur (inc i) (conj fs (fn [] i))) fs)))"]
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["fib via loop" "55" "(loop [a 0 b 1 i 0] (if (= i 10) a (recur b (+ a b) (inc i))))"]
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["recur args no clobber" "[2 1]" "(loop [a 1 b 2 n 0] (if (= n 1) [a b] (recur b a (inc n))))"]
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["nested loops" "9" "(loop [i 0 s 0] (if (= i 3) s (recur (inc i) (loop [j 0 t s] (if (= j 3) t (recur (inc j) (inc t)))))))"]
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["loop sequential init" "12" "(loop [a 1 b (+ a 10)] (+ a b))"]
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["recur through let" "6" "(loop [i 0 acc 0] (let [x (* i 2)] (if (< i 3) (recur (inc i) (+ acc x)) acc)))"]
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["fn-arity recur intact" "15" "((fn f [n acc] (if (zero? n) acc (recur (dec n) (+ acc n)))) 5 0)"])
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(defspec "control / iteration"
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["dotimes side-effect" "5" "(let [a (atom 0)] (dotimes [i 5] (swap! a inc)) @a)"]
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["while" "5" "(let [a (atom 0)] (while (< @a 5) (swap! a inc)) @a)"]
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["for" "[0 1 2]" "(for [x (range 3)] x)"]
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["for nested" "[[0 :a] [0 :b] [1 :a] [1 :b]]" "(for [x (range 2) y [:a :b]] [x y])"]
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["for :when" "[0 2 4]" "(for [x (range 6) :when (even? x)] x)"]
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["for :while" "[0 1 2]" "(for [x (range 10) :while (< x 3)] x)"]
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["for :let" "[0 1 4]" "(for [x (range 3) :let [sq (* x x)]] sq)"]
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["for :let+:when" "[4 6 8]" "(for [x (range 5) :let [y (* x 2)] :when (> y 3)] y)"]
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["for multi :when" "[[1 :a] [1 :b]]" "(for [x [0 1] :when (odd? x) y [:a :b]] [x y])"]
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["for destructure" "[3 7]" "(for [[a b] [[1 2] [3 4]]] (+ a b))"]
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["doseq side-effect" "6" "(let [a (atom 0)] (doseq [x [1 2 3]] (swap! a (fn [v] (+ v x)))) @a)"]
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["doseq nested" "4" "(let [c (atom 0)] (doseq [x [1 2] y [10 20]] (swap! c inc)) @c)"]
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["doseq :when" "[1 3]" "(let [a (atom [])] (doseq [x [1 2 3] :when (odd? x)] (swap! a conj x)) @a)"]
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["doseq :while" "6" "(let [a (atom 0)] (doseq [x (range 10) :while (< x 4)] (swap! a + x)) @a)"]
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["doseq :let" "[0 1 4]" "(let [a (atom [])] (doseq [x (range 3) :let [sq (* x x)]] (swap! a conj sq)) @a)"]
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["doseq returns nil" "nil" "(doseq [x [1 2 3]] x)"])
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(defspec "control / threading"
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["->" "6" "(-> 1 inc (+ 4))"]
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["-> with forms" "[1 2 3]" "(-> [] (conj 1) (conj 2) (conj 3))"]
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["->>" "9" "(->> [1 2 3] (map inc) (reduce +))"]
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["as->" "2" "(as-> [0 1] x (map inc x) (reverse x) (first x))"]
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["some->" "2" "(some-> 1 inc)"]
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["some-> nil stops" "nil" "(some-> nil inc)"]
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["some->>" "[2 3]" "(some->> [1 2] (map inc))"]
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["cond->" "2" "(cond-> 1 true inc false inc)"]
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["cond->>" "[1 2]" "(cond->> [2] true (cons 1))"]
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["doto returns subject" "5" "(let [a (doto (atom 0) (reset! 5))] @a)"])
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