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merge: architecture → loops/tcl — R7RS, JIT, env-as-value
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Resolved conflicts in hosts/ocaml/lib/sx_primitives.ml:
- Took architecture's make-regexp/regexp-* primitives (Tcl runtime depends on them)
- Took architecture's Integer typing for clock-seconds/milliseconds/format
- Kept Phase 4 env-lookup/env-extend additions

Tcl: 342/342 tests passing.

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
This commit is contained in:
giles
2026-05-06 21:00:51 +00:00
parent 83dbb5958a 40f0e73386
commit a32561a07d
301 changed files with 86742 additions and 13539 deletions
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289
lib/apl/runtime.sx Normal file
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;; lib/apl/runtime.sx — APL primitives on SX
;;
;; APL vectors are represented as SX lists (functional, immutable results).
;; Operations are rank-polymorphic: scalar/vector arguments both accepted.
;; Index origin: 1 (traditional APL).
;;
;; Primitives used:
;; map (multi-arg, Phase 1)
;; bitwise-and/or/xor/not/arithmetic-shift (Phase 7)
;; make-set/set-member?/set-add!/set->list (Phase 18)
;; ---------------------------------------------------------------------------
;; 1. Core vector constructors
;; ---------------------------------------------------------------------------
;; N — iota: generate integer vector 1, 2, ..., N
(define
(apl-iota n)
(letrec
((go (fn (i acc) (if (< i 1) acc (go (- i 1) (cons i acc))))))
(go n (list))))
;; A — shape (length of a vector)
(define (apl-rho v) (if (list? v) (len v) 1))
;; A[I] — 1-indexed access
(define (apl-at v i) (nth v (- i 1)))
;; Scalar predicate
(define (apl-scalar? v) (not (list? v)))
;; ---------------------------------------------------------------------------
;; 2. Rank-polymorphic helpers
;; dyadic: scalar/vector × scalar/vector → scalar/vector
;; monadic: scalar/vector → scalar/vector
;; ---------------------------------------------------------------------------
(define
(apl-dyadic op a b)
(cond
((and (list? a) (list? b)) (map op a b))
((list? a) (map (fn (x) (op x b)) a))
((list? b) (map (fn (y) (op a y)) b))
(else (op a b))))
(define (apl-monadic op a) (if (list? a) (map op a) (op a)))
;; ---------------------------------------------------------------------------
;; 3. Arithmetic (element-wise, rank-polymorphic)
;; ---------------------------------------------------------------------------
(define (apl-add a b) (apl-dyadic + a b))
(define (apl-sub a b) (apl-dyadic - a b))
(define (apl-mul a b) (apl-dyadic * a b))
(define (apl-div a b) (apl-dyadic / a b))
(define (apl-mod a b) (apl-dyadic modulo a b))
(define (apl-pow a b) (apl-dyadic pow a b))
(define (apl-max a b) (apl-dyadic (fn (x y) (if (> x y) x y)) a b))
(define (apl-min a b) (apl-dyadic (fn (x y) (if (< x y) x y)) a b))
(define (apl-neg a) (apl-monadic (fn (x) (- 0 x)) a))
(define (apl-abs a) (apl-monadic abs a))
(define (apl-floor a) (apl-monadic floor a))
(define (apl-ceil a) (apl-monadic ceil a))
(define (apl-sqrt a) (apl-monadic sqrt a))
(define (apl-exp a) (apl-monadic exp a))
(define (apl-log a) (apl-monadic log a))
;; ---------------------------------------------------------------------------
;; 4. Comparison (element-wise, returns 0/1 booleans)
;; ---------------------------------------------------------------------------
(define (apl-bool v) (if v 1 0))
(define (apl-eq a b) (apl-dyadic (fn (x y) (apl-bool (= x y))) a b))
(define
(apl-neq a b)
(apl-dyadic (fn (x y) (apl-bool (not (= x y)))) a b))
(define (apl-lt a b) (apl-dyadic (fn (x y) (apl-bool (< x y))) a b))
(define (apl-le a b) (apl-dyadic (fn (x y) (apl-bool (<= x y))) a b))
(define (apl-gt a b) (apl-dyadic (fn (x y) (apl-bool (> x y))) a b))
(define (apl-ge a b) (apl-dyadic (fn (x y) (apl-bool (>= x y))) a b))
;; Boolean logic (0/1 vectors)
(define
(apl-and a b)
(apl-dyadic
(fn
(x y)
(if
(and (not (= x 0)) (not (= y 0)))
1
0))
a
b))
(define
(apl-or a b)
(apl-dyadic
(fn
(x y)
(if
(or (not (= x 0)) (not (= y 0)))
1
0))
a
b))
(define
(apl-not a)
(apl-monadic (fn (x) (if (= x 0) 1 0)) a))
;; ---------------------------------------------------------------------------
;; 5. Bitwise operations (element-wise)
;; ---------------------------------------------------------------------------
(define (apl-bitand a b) (apl-dyadic bitwise-and a b))
(define (apl-bitor a b) (apl-dyadic bitwise-or a b))
(define (apl-bitxor a b) (apl-dyadic bitwise-xor a b))
(define (apl-bitnot a) (apl-monadic bitwise-not a))
(define
(apl-lshift a b)
(apl-dyadic (fn (x n) (arithmetic-shift x n)) a b))
(define
(apl-rshift a b)
(apl-dyadic (fn (x n) (arithmetic-shift x (- 0 n))) a b))
;; ---------------------------------------------------------------------------
;; 6. Reduction (fold) and scan
;; ---------------------------------------------------------------------------
(define (apl-reduce-add v) (reduce + 0 v))
(define (apl-reduce-mul v) (reduce * 1 v))
(define
(apl-reduce-max v)
(reduce (fn (acc x) (if (> acc x) acc x)) (first v) (rest v)))
(define
(apl-reduce-min v)
(reduce (fn (acc x) (if (< acc x) acc x)) (first v) (rest v)))
(define
(apl-reduce-and v)
(reduce
(fn
(acc x)
(if
(and (not (= acc 0)) (not (= x 0)))
1
0))
1
v))
(define
(apl-reduce-or v)
(reduce
(fn
(acc x)
(if
(or (not (= acc 0)) (not (= x 0)))
1
0))
0
v))
;; Scan: prefix reduction (yields a vector of running totals)
(define
(apl-scan op v)
(if
(= (len v) 0)
(list)
(letrec
((go (fn (xs acc result) (if (= (len xs) 0) (reverse result) (let ((next (op acc (first xs)))) (go (rest xs) next (cons next result)))))))
(go (rest v) (first v) (list (first v))))))
(define (apl-scan-add v) (apl-scan + v))
(define (apl-scan-mul v) (apl-scan * v))
;; ---------------------------------------------------------------------------
;; 7. Vector manipulation
;; ---------------------------------------------------------------------------
;; ⌽A — reverse
(define (apl-reverse v) (reverse v))
;; A,B — catenate
(define
(apl-cat a b)
(cond
((and (list? a) (list? b)) (append a b))
((list? a) (append a (list b)))
((list? b) (cons a b))
(else (list a b))))
;; ↑N A — take first N elements (negative: take last N)
(define
(apl-take n v)
(if
(>= n 0)
(letrec
((go (fn (xs i) (if (or (= i 0) (= (len xs) 0)) (list) (cons (first xs) (go (rest xs) (- i 1)))))))
(go v n))
(apl-reverse (apl-take (- 0 n) (apl-reverse v)))))
;; ↓N A — drop first N elements
(define
(apl-drop n v)
(if
(>= n 0)
(letrec
((go (fn (xs i) (if (or (= i 0) (= (len xs) 0)) xs (go (rest xs) (- i 1))))))
(go v n))
(apl-reverse (apl-drop (- 0 n) (apl-reverse v)))))
;; Rotate left by n positions
(define
(apl-rotate n v)
(let ((m (modulo n (len v)))) (append (apl-drop m v) (apl-take m v))))
;; Compression: A/B — select elements of B where A is 1
(define
(apl-compress mask v)
(if
(= (len mask) 0)
(list)
(let
((rest-result (apl-compress (rest mask) (rest v))))
(if
(not (= (first mask) 0))
(cons (first v) rest-result)
rest-result))))
;; Indexing: A[B] — select elements at indices B (1-indexed)
(define (apl-index v indices) (map (fn (i) (apl-at v i)) indices))
;; Grade up: indices that would sort the vector ascending
(define
(apl-grade-up v)
(let
((indexed (map (fn (x i) (list x i)) v (apl-iota (len v)))))
(map (fn (p) (nth p 1)) (sort indexed))))
;; ---------------------------------------------------------------------------
;; 8. Set operations (∊ ∩ ~)
;; ---------------------------------------------------------------------------
;; Membership ∊: for each element in A, is it in B? → 0/1 vector
(define
(apl-member a b)
(let
((bset (let ((s (make-set))) (for-each (fn (x) (set-add! s x)) b) s)))
(if
(list? a)
(map (fn (x) (apl-bool (set-member? bset x))) a)
(apl-bool (set-member? bset a)))))
;; Nub A — unique elements, preserving order
(define
(apl-nub v)
(let
((seen (make-set)))
(letrec
((go (fn (xs acc) (if (= (len xs) 0) (reverse acc) (if (set-member? seen (first xs)) (go (rest xs) acc) (begin (set-add! seen (first xs)) (go (rest xs) (cons (first xs) acc))))))))
(go v (list)))))
;; Union AB — nub of concatenation
(define (apl-union a b) (apl-nub (apl-cat a b)))
;; Intersection A∩B
(define
(apl-intersect a b)
(let
((bset (let ((s (make-set))) (for-each (fn (x) (set-add! s x)) b) s)))
(filter (fn (x) (set-member? bset x)) a)))
;; Without A~B
(define
(apl-without a b)
(let
((bset (let ((s (make-set))) (for-each (fn (x) (set-add! s x)) b) s)))
(filter (fn (x) (not (set-member? bset x))) a)))
;; ---------------------------------------------------------------------------
;; 9. Format (⍕) — APL-style display
;; ---------------------------------------------------------------------------
(define
(apl-format v)
(if
(list? v)
(letrec
((go (fn (xs acc) (if (= (len xs) 0) acc (go (rest xs) (str acc (if (= acc "") "" " ") (str (first xs))))))))
(go v ""))
(str v)))

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lib/apl/test.sh Executable file
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#!/usr/bin/env bash
# lib/apl/test.sh — smoke-test the APL runtime layer.
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found."
exit 1
fi
TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "spec/stdlib.sx")
(load "lib/apl/runtime.sx")
(epoch 2)
(load "lib/apl/tests/runtime.sx")
(epoch 3)
(eval "(list apl-test-pass apl-test-fail)")
EPOCHS
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok 3 //; s/\)$//')
fi
if [ -z "$LINE" ]; then
echo "ERROR: could not extract summary"
echo "$OUTPUT" | tail -10
exit 1
fi
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
TOTAL=$((P + F))
if [ "$F" -eq 0 ]; then
echo "ok $P/$TOTAL lib/apl tests passed"
else
echo "FAIL $P/$TOTAL passed, $F failed"
fi
[ "$F" -eq 0 ]

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lib/apl/tests/runtime.sx Normal file
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;; lib/apl/tests/runtime.sx — Tests for lib/apl/runtime.sx
;; --- Test framework ---
(define apl-test-pass 0)
(define apl-test-fail 0)
(define apl-test-fails (list))
(define
(apl-test name got expected)
(if
(= got expected)
(set! apl-test-pass (+ apl-test-pass 1))
(begin
(set! apl-test-fail (+ apl-test-fail 1))
(set! apl-test-fails (append apl-test-fails (list {:got got :expected expected :name name}))))))
;; ---------------------------------------------------------------------------
;; 1. Core vector constructors
;; ---------------------------------------------------------------------------
(apl-test
"iota 5"
(apl-iota 5)
(list 1 2 3 4 5))
(apl-test "iota 1" (apl-iota 1) (list 1))
(apl-test "iota 0" (apl-iota 0) (list))
(apl-test
"rho list"
(apl-rho (list 1 2 3))
3)
(apl-test "rho scalar" (apl-rho 42) 1)
(apl-test
"at 1"
(apl-at (list 10 20 30) 1)
10)
(apl-test
"at 3"
(apl-at (list 10 20 30) 3)
30)
;; ---------------------------------------------------------------------------
;; 2. Arithmetic — element-wise and rank-polymorphic
;; ---------------------------------------------------------------------------
(apl-test
"add v+v"
(apl-add
(list 1 2 3)
(list 10 20 30))
(list 11 22 33))
(apl-test
"add s+v"
(apl-add 10 (list 1 2 3))
(list 11 12 13))
(apl-test
"add v+s"
(apl-add (list 1 2 3) 100)
(list 101 102 103))
(apl-test "add s+s" (apl-add 3 4) 7)
(apl-test
"sub v-v"
(apl-sub
(list 5 4 3)
(list 1 2 3))
(list 4 2 0))
(apl-test
"mul v*s"
(apl-mul (list 1 2 3) 3)
(list 3 6 9))
(apl-test
"neg -v"
(apl-neg (list 1 -2 3))
(list -1 2 -3))
(apl-test
"abs v"
(apl-abs (list -1 2 -3))
(list 1 2 3))
(apl-test
"floor v"
(apl-floor (list 1.7 2.2 3.9))
(list 1 2 3))
(apl-test
"ceil v"
(apl-ceil (list 1.1 2.5 3))
(list 2 3 3))
(apl-test
"max v v"
(apl-max
(list 1 5 3)
(list 4 2 6))
(list 4 5 6))
(apl-test
"min v v"
(apl-min
(list 1 5 3)
(list 4 2 6))
(list 1 2 3))
;; ---------------------------------------------------------------------------
;; 3. Comparison (returns 0/1)
;; ---------------------------------------------------------------------------
(apl-test "eq 3 3" (apl-eq 3 3) 1)
(apl-test "eq 3 4" (apl-eq 3 4) 0)
(apl-test
"gt v>s"
(apl-gt (list 1 5 3 7) 4)
(list 0 1 0 1))
(apl-test
"lt v<v"
(apl-lt
(list 1 2 3)
(list 3 2 1))
(list 1 0 0))
(apl-test
"le v<=s"
(apl-le (list 3 4 5) 4)
(list 1 1 0))
(apl-test
"ge v>=s"
(apl-ge (list 3 4 5) 4)
(list 0 1 1))
(apl-test
"neq v!=s"
(apl-neq (list 1 2 3) 2)
(list 1 0 1))
;; ---------------------------------------------------------------------------
;; 4. Boolean logic (0/1 values)
;; ---------------------------------------------------------------------------
(apl-test "and 1 1" (apl-and 1 1) 1)
(apl-test "and 1 0" (apl-and 1 0) 0)
(apl-test "or 0 1" (apl-or 0 1) 1)
(apl-test "or 0 0" (apl-or 0 0) 0)
(apl-test "not 0" (apl-not 0) 1)
(apl-test "not 1" (apl-not 1) 0)
(apl-test
"not vec"
(apl-not (list 1 0 1 0))
(list 0 1 0 1))
;; ---------------------------------------------------------------------------
;; 5. Bitwise operations
;; ---------------------------------------------------------------------------
(apl-test "bitand s" (apl-bitand 5 3) 1)
(apl-test "bitor s" (apl-bitor 5 3) 7)
(apl-test "bitxor s" (apl-bitxor 5 3) 6)
(apl-test "bitnot 0" (apl-bitnot 0) -1)
(apl-test "lshift 1 4" (apl-lshift 1 4) 16)
(apl-test "rshift 16 2" (apl-rshift 16 2) 4)
(apl-test
"bitand vec"
(apl-bitand (list 5 6) (list 3 7))
(list 1 6))
(apl-test
"bitor vec"
(apl-bitor (list 5 6) (list 3 7))
(list 7 7))
;; ---------------------------------------------------------------------------
;; 6. Reduction and scan
;; ---------------------------------------------------------------------------
(apl-test
"reduce-add"
(apl-reduce-add
(list 1 2 3 4 5))
15)
(apl-test
"reduce-mul"
(apl-reduce-mul (list 1 2 3 4))
24)
(apl-test
"reduce-max"
(apl-reduce-max
(list 3 1 4 1 5))
5)
(apl-test
"reduce-min"
(apl-reduce-min
(list 3 1 4 1 5))
1)
(apl-test
"reduce-and"
(apl-reduce-and (list 1 1 1))
1)
(apl-test
"reduce-and0"
(apl-reduce-and (list 1 0 1))
0)
(apl-test
"reduce-or"
(apl-reduce-or (list 0 1 0))
1)
(apl-test
"scan-add"
(apl-scan-add (list 1 2 3 4))
(list 1 3 6 10))
(apl-test
"scan-mul"
(apl-scan-mul (list 1 2 3 4))
(list 1 2 6 24))
;; ---------------------------------------------------------------------------
;; 7. Vector manipulation
;; ---------------------------------------------------------------------------
(apl-test
"reverse"
(apl-reverse (list 1 2 3 4))
(list 4 3 2 1))
(apl-test
"cat v v"
(apl-cat (list 1 2) (list 3 4))
(list 1 2 3 4))
(apl-test
"cat v s"
(apl-cat (list 1 2) 3)
(list 1 2 3))
(apl-test
"cat s v"
(apl-cat 1 (list 2 3))
(list 1 2 3))
(apl-test
"cat s s"
(apl-cat 1 2)
(list 1 2))
(apl-test
"take 3"
(apl-take
3
(list 10 20 30 40 50))
(list 10 20 30))
(apl-test
"take 0"
(apl-take 0 (list 1 2 3))
(list))
(apl-test
"take neg"
(apl-take -2 (list 10 20 30))
(list 20 30))
(apl-test
"drop 2"
(apl-drop 2 (list 10 20 30 40))
(list 30 40))
(apl-test
"drop neg"
(apl-drop -1 (list 10 20 30))
(list 10 20))
(apl-test
"rotate 2"
(apl-rotate
2
(list 1 2 3 4 5))
(list 3 4 5 1 2))
(apl-test
"compress"
(apl-compress
(list 1 0 1 0)
(list 10 20 30 40))
(list 10 30))
(apl-test
"index"
(apl-index
(list 10 20 30 40)
(list 2 4))
(list 20 40))
;; ---------------------------------------------------------------------------
;; 8. Set operations
;; ---------------------------------------------------------------------------
(apl-test
"member yes"
(apl-member
(list 1 2 5)
(list 2 4 6))
(list 0 1 0))
(apl-test
"member s"
(apl-member 2 (list 1 2 3))
1)
(apl-test
"member no"
(apl-member 9 (list 1 2 3))
0)
(apl-test
"nub"
(apl-nub (list 1 2 1 3 2))
(list 1 2 3))
(apl-test
"union"
(apl-union
(list 1 2 3)
(list 2 3 4))
(list 1 2 3 4))
(apl-test
"intersect"
(apl-intersect
(list 1 2 3 4)
(list 2 4 6))
(list 2 4))
(apl-test
"without"
(apl-without
(list 1 2 3 4)
(list 2 4))
(list 1 3))
;; ---------------------------------------------------------------------------
;; 9. Format
;; ---------------------------------------------------------------------------
(apl-test
"format vec"
(apl-format (list 1 2 3))
"1 2 3")
(apl-test "format scalar" (apl-format 42) "42")
(apl-test "format empty" (apl-format (list)) "")
;; ---------------------------------------------------------------------------
;; Summary
;; ---------------------------------------------------------------------------
(list apl-test-pass apl-test-fail)

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lib/common-lisp/clos.sx Normal file
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;; lib/common-lisp/clos.sx — CLOS: classes, instances, generic functions
;;
;; Class records: {:clos-type "class" :name "NAME" :slots {...} :parents [...] :methods [...]}
;; Instance: {:clos-type "instance" :class "NAME" :slots {slot: val ...}}
;; Method: {:qualifiers [...] :specializers [...] :fn (fn (args next-fn) ...)}
;;
;; SX primitive notes:
;; dict->list: use (map (fn (k) (list k (get d k))) (keys d))
;; dict-set (pure): use assoc
;; fn?/callable?: use callable?
;; ── dict helpers ───────────────────────────────────────────────────────────
(define
clos-dict->list
(fn (d) (map (fn (k) (list k (get d k))) (keys d))))
;; ── class registry ─────────────────────────────────────────────────────────
(define
clos-class-registry
(dict
"t"
{:parents (list) :clos-type "class" :slots (dict) :methods (list) :name "t"}
"null"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "null"}
"integer"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "integer"}
"float"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "float"}
"string"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "string"}
"symbol"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "symbol"}
"cons"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "cons"}
"list"
{:parents (list "t") :clos-type "class" :slots (dict) :methods (list) :name "list"}))
;; ── clos-generic-registry ─────────────────────────────────────────────────
(define clos-generic-registry (dict))
;; ── class-of ──────────────────────────────────────────────────────────────
(define
clos-class-of
(fn
(x)
(cond
((nil? x) "null")
((integer? x) "integer")
((float? x) "float")
((string? x) "string")
((symbol? x) "symbol")
((and (list? x) (> (len x) 0)) "cons")
((and (list? x) (= (len x) 0)) "null")
((and (dict? x) (= (get x "clos-type") "instance")) (get x "class"))
(:else "t"))))
;; ── subclass-of? ──────────────────────────────────────────────────────────
;;
;; Captures clos-class-registry at define time to avoid free-variable issues.
(define
clos-subclass-of?
(let
((registry clos-class-registry))
(fn
(class-name super-name)
(if
(= class-name super-name)
true
(let
((rec (get registry class-name)))
(if
(nil? rec)
false
(some
(fn (p) (clos-subclass-of? p super-name))
(get rec "parents"))))))))
;; ── instance-of? ──────────────────────────────────────────────────────────
(define
clos-instance-of?
(fn (obj class-name) (clos-subclass-of? (clos-class-of obj) class-name)))
;; ── defclass ──────────────────────────────────────────────────────────────
;;
;; slot-specs: list of dicts with keys: name initarg initform accessor reader writer
;; Each missing key defaults to nil.
(define clos-slot-spec (fn (spec) (if (string? spec) {:initform nil :initarg nil :reader nil :writer nil :accessor nil :name spec} spec)))
(define
clos-defclass
(fn
(name parents slot-specs)
(let
((slots (dict)))
(for-each
(fn
(pname)
(let
((prec (get clos-class-registry pname)))
(when
(not (nil? prec))
(for-each
(fn
(k)
(when
(nil? (get slots k))
(dict-set! slots k (get (get prec "slots") k))))
(keys (get prec "slots"))))))
parents)
(for-each
(fn
(s)
(let
((spec (clos-slot-spec s)))
(dict-set! slots (get spec "name") spec)))
slot-specs)
(let
((class-rec {:parents parents :clos-type "class" :slots slots :methods (list) :name name}))
(dict-set! clos-class-registry name class-rec)
(clos-install-accessors-for name slots)
name))))
;; ── accessor installation (forward-declared, defined after defmethod) ──────
(define
clos-install-accessors-for
(fn
(class-name slots)
(for-each
(fn
(k)
(let
((spec (get slots k)))
(let
((reader (get spec "reader")))
(when
(not (nil? reader))
(clos-add-reader-method reader class-name k)))
(let
((accessor (get spec "accessor")))
(when
(not (nil? accessor))
(clos-add-reader-method accessor class-name k)))))
(keys slots))))
;; placeholder — real impl filled in after defmethod is defined
(define clos-add-reader-method (fn (method-name class-name slot-name) nil))
;; ── make-instance ─────────────────────────────────────────────────────────
(define
clos-make-instance
(fn
(class-name &rest initargs)
(let
((class-rec (get clos-class-registry class-name)))
(if
(nil? class-rec)
(error (str "No class named: " class-name))
(let
((slots (dict)))
(for-each
(fn
(k)
(let
((spec (get (get class-rec "slots") k)))
(let
((initform (get spec "initform")))
(when
(not (nil? initform))
(dict-set!
slots
k
(if (callable? initform) (initform) initform))))))
(keys (get class-rec "slots")))
(define
apply-args
(fn
(args)
(when
(>= (len args) 2)
(let
((key (str (first args))) (val (first (rest args))))
(let
((skey (if (= (slice key 0 1) ":") (slice key 1 (len key)) key)))
(let
((matched false))
(for-each
(fn
(sk)
(let
((spec (get (get class-rec "slots") sk)))
(let
((ia (get spec "initarg")))
(when
(or
(= ia key)
(= ia (str ":" skey))
(= sk skey))
(dict-set! slots sk val)
(set! matched true)))))
(keys (get class-rec "slots")))))
(apply-args (rest (rest args)))))))
(apply-args initargs)
{:clos-type "instance" :slots slots :class class-name})))))
;; ── slot-value ────────────────────────────────────────────────────────────
(define
clos-slot-value
(fn
(instance slot-name)
(if
(and (dict? instance) (= (get instance "clos-type") "instance"))
(get (get instance "slots") slot-name)
(error (str "Not a CLOS instance: " (inspect instance))))))
(define
clos-set-slot-value!
(fn
(instance slot-name value)
(if
(and (dict? instance) (= (get instance "clos-type") "instance"))
(dict-set! (get instance "slots") slot-name value)
(error (str "Not a CLOS instance: " (inspect instance))))))
(define
clos-slot-boundp
(fn
(instance slot-name)
(and
(dict? instance)
(= (get instance "clos-type") "instance")
(not (nil? (get (get instance "slots") slot-name))))))
;; ── find-class / change-class ─────────────────────────────────────────────
(define clos-find-class (fn (name) (get clos-class-registry name)))
(define
clos-change-class!
(fn
(instance new-class-name)
(if
(and (dict? instance) (= (get instance "clos-type") "instance"))
(dict-set! instance "class" new-class-name)
(error (str "Not a CLOS instance: " (inspect instance))))))
;; ── defgeneric ────────────────────────────────────────────────────────────
(define
clos-defgeneric
(fn
(name options)
(let
((combination (or (get options "method-combination") "standard")))
(when
(nil? (get clos-generic-registry name))
(dict-set! clos-generic-registry name {:methods (list) :combination combination :name name}))
name)))
;; ── defmethod ─────────────────────────────────────────────────────────────
;;
;; method-fn: (fn (args next-fn) body)
;; args = list of all call arguments
;; next-fn = (fn () next-method-result) or nil
(define
clos-defmethod
(fn
(generic-name qualifiers specializers method-fn)
(when
(nil? (get clos-generic-registry generic-name))
(clos-defgeneric generic-name {}))
(let
((grec (get clos-generic-registry generic-name))
(new-method {:fn method-fn :qualifiers qualifiers :specializers specializers}))
(let
((kept (filter (fn (m) (not (and (= (get m "qualifiers") qualifiers) (= (get m "specializers") specializers)))) (get grec "methods"))))
(dict-set!
clos-generic-registry
generic-name
(assoc grec "methods" (append kept (list new-method))))
generic-name))))
;; Now install the real accessor-method installer
(set!
clos-add-reader-method
(fn
(method-name class-name slot-name)
(clos-defmethod
method-name
(list)
(list class-name)
(fn (args next-fn) (clos-slot-value (first args) slot-name)))))
;; ── method specificity ─────────────────────────────────────────────────────
(define
clos-method-matches?
(fn
(method args)
(let
((specs (get method "specializers")))
(if
(> (len specs) (len args))
false
(define
check-all
(fn
(i)
(if
(>= i (len specs))
true
(let
((spec (nth specs i)) (arg (nth args i)))
(if
(= spec "t")
(check-all (+ i 1))
(if
(clos-instance-of? arg spec)
(check-all (+ i 1))
false))))))
(check-all 0)))))
;; Precedence distance: how far class-name is from spec-name up the hierarchy.
(define
clos-specificity
(let
((registry clos-class-registry))
(fn
(class-name spec-name)
(define
walk
(fn
(cn depth)
(if
(= cn spec-name)
depth
(let
((rec (get registry cn)))
(if
(nil? rec)
nil
(let
((results (map (fn (p) (walk p (+ depth 1))) (get rec "parents"))))
(let
((non-nil (filter (fn (x) (not (nil? x))) results)))
(if
(empty? non-nil)
nil
(reduce
(fn (a b) (if (< a b) a b))
(first non-nil)
(rest non-nil))))))))))
(walk class-name 0))))
(define
clos-method-more-specific?
(fn
(m1 m2 args)
(let
((s1 (get m1 "specializers")) (s2 (get m2 "specializers")))
(define
cmp
(fn
(i)
(if
(>= i (len s1))
false
(let
((c1 (clos-specificity (clos-class-of (nth args i)) (nth s1 i)))
(c2
(clos-specificity (clos-class-of (nth args i)) (nth s2 i))))
(cond
((and (nil? c1) (nil? c2)) (cmp (+ i 1)))
((nil? c1) false)
((nil? c2) true)
((< c1 c2) true)
((> c1 c2) false)
(:else (cmp (+ i 1))))))))
(cmp 0))))
(define
clos-sort-methods
(fn
(methods args)
(define
insert
(fn
(m sorted)
(if
(empty? sorted)
(list m)
(if
(clos-method-more-specific? m (first sorted) args)
(cons m sorted)
(cons (first sorted) (insert m (rest sorted)))))))
(reduce (fn (acc m) (insert m acc)) (list) methods)))
;; ── call-generic (standard method combination) ─────────────────────────────
(define
clos-call-generic
(fn
(generic-name args)
(let
((grec (get clos-generic-registry generic-name)))
(if
(nil? grec)
(error (str "No generic function: " generic-name))
(let
((applicable (filter (fn (m) (clos-method-matches? m args)) (get grec "methods"))))
(if
(empty? applicable)
(error
(str
"No applicable method for "
generic-name
" with classes "
(inspect (map clos-class-of args))))
(let
((primary (filter (fn (m) (empty? (get m "qualifiers"))) applicable))
(before
(filter
(fn (m) (= (get m "qualifiers") (list "before")))
applicable))
(after
(filter
(fn (m) (= (get m "qualifiers") (list "after")))
applicable))
(around
(filter
(fn (m) (= (get m "qualifiers") (list "around")))
applicable)))
(let
((sp (clos-sort-methods primary args))
(sb (clos-sort-methods before args))
(sa (clos-sort-methods after args))
(sw (clos-sort-methods around args)))
(define
make-primary-chain
(fn
(methods)
(if
(empty? methods)
(fn
()
(error (str "No next primary method: " generic-name)))
(fn
()
((get (first methods) "fn")
args
(make-primary-chain (rest methods)))))))
(define
make-around-chain
(fn
(around-methods inner-thunk)
(if
(empty? around-methods)
inner-thunk
(fn
()
((get (first around-methods) "fn")
args
(make-around-chain
(rest around-methods)
inner-thunk))))))
(for-each (fn (m) ((get m "fn") args (fn () nil))) sb)
(let
((primary-thunk (make-primary-chain sp)))
(let
((result (if (empty? sw) (primary-thunk) ((make-around-chain sw primary-thunk)))))
(for-each
(fn (m) ((get m "fn") args (fn () nil)))
(reverse sa))
result))))))))))
;; ── call-next-method / next-method-p ──────────────────────────────────────
(define clos-call-next-method (fn (next-fn) (next-fn)))
(define clos-next-method-p (fn (next-fn) (not (nil? next-fn))))
;; ── with-slots ────────────────────────────────────────────────────────────
(define
clos-with-slots
(fn
(instance slot-names body-fn)
(let
((vals (map (fn (s) (clos-slot-value instance s)) slot-names)))
(apply body-fn vals))))

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#!/usr/bin/env bash
# lib/common-lisp/conformance.sh — CL-on-SX conformance test runner
#
# Runs all Common Lisp test suites and writes scoreboard.json + scoreboard.md.
#
# Usage:
# bash lib/common-lisp/conformance.sh
# bash lib/common-lisp/conformance.sh -v
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found."
exit 1
fi
VERBOSE="${1:-}"
TOTAL_PASS=0; TOTAL_FAIL=0
SUITE_NAMES=()
SUITE_PASS=()
SUITE_FAIL=()
# run_suite NAME "file1 file2 ..." PASS_VAR FAIL_VAR FAILURES_VAR
run_suite() {
local name="$1" load_files="$2" pass_var="$3" fail_var="$4" failures_var="$5"
local TMP; TMP=$(mktemp)
{
printf '(epoch 1)\n(load "spec/stdlib.sx")\n'
local i=2
for f in $load_files; do
printf '(epoch %d)\n(load "%s")\n' "$i" "$f"
i=$((i+1))
done
printf '(epoch 100)\n(eval "%s")\n' "$pass_var"
printf '(epoch 101)\n(eval "%s")\n' "$fail_var"
} > "$TMP"
local OUT; OUT=$(timeout 30 "$SX_SERVER" < "$TMP" 2>/dev/null)
rm -f "$TMP"
local P F
P=$(echo "$OUT" | grep -A1 "^(ok-len 100 " | tail -1 | tr -d ' ()' || true)
F=$(echo "$OUT" | grep -A1 "^(ok-len 101 " | tail -1 | tr -d ' ()' || true)
# Also try plain (ok 100 N) format
[ -z "$P" ] && P=$(echo "$OUT" | grep "^(ok 100 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$F" ] && F=$(echo "$OUT" | grep "^(ok 101 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$P" ] && P=0; [ -z "$F" ] && F=0
SUITE_NAMES+=("$name")
SUITE_PASS+=("$P")
SUITE_FAIL+=("$F")
TOTAL_PASS=$((TOTAL_PASS + P))
TOTAL_FAIL=$((TOTAL_FAIL + F))
if [ "$F" = "0" ] && [ "${P:-0}" -gt 0 ] 2>/dev/null; then
echo " PASS $name ($P tests)"
else
echo " FAIL $name ($P passed, $F failed)"
fi
}
echo "=== Common Lisp on SX — Conformance Run ==="
echo ""
run_suite "Phase 1: tokenizer/reader" \
"lib/common-lisp/reader.sx lib/common-lisp/tests/read.sx" \
"cl-test-pass" "cl-test-fail" "cl-test-fails"
run_suite "Phase 1: parser/lambda-lists" \
"lib/common-lisp/reader.sx lib/common-lisp/parser.sx lib/common-lisp/tests/lambda.sx" \
"cl-test-pass" "cl-test-fail" "cl-test-fails"
run_suite "Phase 2: evaluator" \
"lib/common-lisp/reader.sx lib/common-lisp/parser.sx lib/common-lisp/eval.sx lib/common-lisp/tests/eval.sx" \
"cl-test-pass" "cl-test-fail" "cl-test-fails"
run_suite "Phase 3: condition system" \
"lib/common-lisp/runtime.sx lib/common-lisp/tests/conditions.sx" \
"passed" "failed" "failures"
run_suite "Phase 3: restart-demo" \
"lib/common-lisp/runtime.sx lib/common-lisp/tests/programs/restart-demo.sx" \
"demo-passed" "demo-failed" "demo-failures"
run_suite "Phase 3: parse-recover" \
"lib/common-lisp/runtime.sx lib/common-lisp/tests/programs/parse-recover.sx" \
"parse-passed" "parse-failed" "parse-failures"
run_suite "Phase 3: interactive-debugger" \
"lib/common-lisp/runtime.sx lib/common-lisp/tests/programs/interactive-debugger.sx" \
"debugger-passed" "debugger-failed" "debugger-failures"
run_suite "Phase 4: CLOS" \
"lib/common-lisp/runtime.sx lib/common-lisp/clos.sx lib/common-lisp/tests/clos.sx" \
"passed" "failed" "failures"
run_suite "Phase 4: geometry" \
"lib/common-lisp/runtime.sx lib/common-lisp/clos.sx lib/common-lisp/tests/programs/geometry.sx" \
"geo-passed" "geo-failed" "geo-failures"
run_suite "Phase 4: mop-trace" \
"lib/common-lisp/runtime.sx lib/common-lisp/clos.sx lib/common-lisp/tests/programs/mop-trace.sx" \
"mop-passed" "mop-failed" "mop-failures"
run_suite "Phase 5: macros+LOOP" \
"lib/common-lisp/reader.sx lib/common-lisp/parser.sx lib/common-lisp/eval.sx lib/common-lisp/loop.sx lib/common-lisp/tests/macros.sx" \
"macro-passed" "macro-failed" "macro-failures"
run_suite "Phase 6: stdlib" \
"lib/common-lisp/reader.sx lib/common-lisp/parser.sx lib/common-lisp/eval.sx lib/common-lisp/tests/stdlib.sx" \
"stdlib-passed" "stdlib-failed" "stdlib-failures"
echo ""
echo "=== Total: $TOTAL_PASS passed, $TOTAL_FAIL failed ==="
# ── write scoreboard.json ─────────────────────────────────────────────────
SCORE_DIR="lib/common-lisp"
JSON="$SCORE_DIR/scoreboard.json"
{
printf '{\n'
printf ' "generated": "%s",\n' "$(date -u +%Y-%m-%dT%H:%M:%SZ)"
printf ' "total_pass": %d,\n' "$TOTAL_PASS"
printf ' "total_fail": %d,\n' "$TOTAL_FAIL"
printf ' "suites": [\n'
first=true
for i in "${!SUITE_NAMES[@]}"; do
if [ "$first" = "true" ]; then first=false; else printf ',\n'; fi
printf ' {"name": "%s", "pass": %d, "fail": %d}' \
"${SUITE_NAMES[$i]}" "${SUITE_PASS[$i]}" "${SUITE_FAIL[$i]}"
done
printf '\n ]\n'
printf '}\n'
} > "$JSON"
# ── write scoreboard.md ───────────────────────────────────────────────────
MD="$SCORE_DIR/scoreboard.md"
{
printf '# Common Lisp on SX — Scoreboard\n\n'
printf '_Generated: %s_\n\n' "$(date -u '+%Y-%m-%d %H:%M UTC')"
printf '| Suite | Pass | Fail | Status |\n'
printf '|-------|------|------|--------|\n'
for i in "${!SUITE_NAMES[@]}"; do
p="${SUITE_PASS[$i]}" f="${SUITE_FAIL[$i]}"
status=""
if [ "$f" = "0" ] && [ "${p:-0}" -gt 0 ] 2>/dev/null; then
status="pass"
else
status="FAIL"
fi
printf '| %s | %s | %s | %s |\n' "${SUITE_NAMES[$i]}" "$p" "$f" "$status"
done
printf '\n**Total: %d passed, %d failed**\n' "$TOTAL_PASS" "$TOTAL_FAIL"
} > "$MD"
echo ""
echo "Scoreboard written to $JSON and $MD"
[ "$TOTAL_FAIL" -eq 0 ]

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lib/common-lisp/loop.sx Normal file
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;; lib/common-lisp/loop.sx — The LOOP macro for CL-on-SX
;;
;; Supported clauses:
;; for VAR in LIST — iterate over list
;; for VAR across VECTOR — alias for 'in'
;; for VAR from N — numeric iteration (to/upto/below/downto/above/by)
;; for VAR = EXPR [then EXPR] — general iteration
;; while COND — stop when false
;; until COND — stop when true
;; repeat N — repeat N times
;; collect EXPR [into VAR]
;; append EXPR [into VAR]
;; nconc EXPR [into VAR]
;; sum EXPR [into VAR]
;; count EXPR [into VAR]
;; maximize EXPR [into VAR]
;; minimize EXPR [into VAR]
;; do FORM...
;; when/if COND clause...
;; unless COND clause...
;; finally FORM...
;; always COND
;; never COND
;; thereis COND
;; named BLOCK-NAME
;;
;; Depends on: lib/common-lisp/runtime.sx, lib/common-lisp/eval.sx already loaded.
;; Uses defmacro in the CL evaluator.
;; ── LOOP expansion driver ─────────────────────────────────────────────────
;; cl-loop-parse: analyse the flat LOOP clause list and build a Lisp form.
;; Returns a (block NAME (let (...) (tagbody ...))) form.
(define
cl-loop-parse
(fn
(clauses)
(define block-name nil)
(define with-bindings (list))
(define for-bindings (list))
(define test-forms (list))
(define repeat-var nil)
(define repeat-count nil)
(define body-forms (list))
(define accum-vars (dict))
(define accum-clauses (dict))
(define result-var nil)
(define finally-forms (list))
(define return-expr nil)
(define termination nil)
(define idx 0)
(define (lp-peek) (if (< idx (len clauses)) (nth clauses idx) nil))
(define
(next!)
(let ((v (lp-peek))) (do (set! idx (+ idx 1)) v)))
(define
(skip-if pred)
(if (and (not (nil? (lp-peek))) (pred (lp-peek))) (next!) nil))
(define (upcase-str s) (if (string? s) (upcase s) s))
(define (kw? s k) (= (upcase-str s) k))
(define
(make-accum-var!)
(if
(nil? result-var)
(do (set! result-var "#LOOP-RESULT") result-var)
result-var))
(define
(add-accum! type expr into-var)
(let
((v (if (nil? into-var) (make-accum-var!) into-var)))
(if
(not (has-key? accum-vars v))
(do
(set!
accum-vars
(assoc
accum-vars
v
(cond
((= type ":sum") 0)
((= type ":count") 0)
((= type ":maximize") nil)
((= type ":minimize") nil)
(:else (list)))))
(set! accum-clauses (assoc accum-clauses v type))))
(let
((update (cond ((= type ":collect") (list "SETQ" v (list "APPEND" v (list "LIST" expr)))) ((= type ":append") (list "SETQ" v (list "APPEND" v expr))) ((= type ":nconc") (list "SETQ" v (list "NCONC" v expr))) ((= type ":sum") (list "SETQ" v (list "+" v expr))) ((= type ":count") (list "SETQ" v (list "+" v (list "IF" expr 1 0)))) ((= type ":maximize") (list "SETQ" v (list "IF" (list "OR" (list "NULL" v) (list ">" expr v)) expr v))) ((= type ":minimize") (list "SETQ" v (list "IF" (list "OR" (list "NULL" v) (list "<" expr v)) expr v))) (:else (list "SETQ" v (list "APPEND" v (list "LIST" expr)))))))
(set! body-forms (append body-forms (list update))))))
(define
(parse-clause!)
(let
((tok (lp-peek)))
(if
(nil? tok)
nil
(do
(let
((u (upcase-str tok)))
(cond
((= u "NAMED")
(do (next!) (set! block-name (next!)) (parse-clause!)))
((= u "WITH")
(do
(next!)
(let
((var (next!)))
(skip-if (fn (s) (kw? s "=")))
(let
((init (next!)))
(set!
with-bindings
(append with-bindings (list (list var init))))
(parse-clause!)))))
((= u "FOR")
(do
(next!)
(let
((var (next!)))
(let
((kw2 (upcase-str (lp-peek))))
(cond
((or (= kw2 "IN") (= kw2 "ACROSS"))
(do
(next!)
(let
((lst-expr (next!))
(tail-var (str "#TAIL-" var)))
(set!
for-bindings
(append for-bindings (list {:list lst-expr :tail tail-var :type ":list" :var var})))
(parse-clause!))))
((= kw2 "=")
(do
(next!)
(let
((init-expr (next!)))
(let
((then-expr (if (kw? (lp-peek) "THEN") (do (next!) (next!)) init-expr)))
(set!
for-bindings
(append for-bindings (list {:type ":general" :then then-expr :init init-expr :var var})))
(parse-clause!)))))
((or (= kw2 "FROM") (= kw2 "DOWNFROM") (= kw2 "UPFROM"))
(do
(next!)
(let
((from-expr (next!))
(dir (if (= kw2 "DOWNFROM") ":down" ":up"))
(limit-expr nil)
(limit-type nil)
(step-expr 1))
(let
((lkw (upcase-str (lp-peek))))
(when
(or
(= lkw "TO")
(= lkw "UPTO")
(= lkw "BELOW")
(= lkw "DOWNTO")
(= lkw "ABOVE"))
(do
(next!)
(set! limit-type lkw)
(set! limit-expr (next!)))))
(when
(kw? (lp-peek) "BY")
(do (next!) (set! step-expr (next!))))
(set!
for-bindings
(append for-bindings (list {:dir dir :step step-expr :from from-expr :type ":numeric" :limit-type limit-type :var var :limit limit-expr})))
(parse-clause!))))
((or (= kw2 "TO") (= kw2 "UPTO") (= kw2 "BELOW"))
(do
(next!)
(let
((limit-expr (next!))
(step-expr 1))
(when
(kw? (lp-peek) "BY")
(do (next!) (set! step-expr (next!))))
(set!
for-bindings
(append for-bindings (list {:dir ":up" :step step-expr :from 0 :type ":numeric" :limit-type kw2 :var var :limit limit-expr})))
(parse-clause!))))
(:else (do (parse-clause!))))))))
((= u "WHILE")
(do
(next!)
(set! test-forms (append test-forms (list {:expr (next!) :type ":while"})))
(parse-clause!)))
((= u "UNTIL")
(do
(next!)
(set! test-forms (append test-forms (list {:expr (next!) :type ":until"})))
(parse-clause!)))
((= u "REPEAT")
(do
(next!)
(set! repeat-count (next!))
(set! repeat-var "#REPEAT-COUNT")
(parse-clause!)))
((or (= u "COLLECT") (= u "COLLECTING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":collect" expr into-var)
(parse-clause!))))
((or (= u "APPEND") (= u "APPENDING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":append" expr into-var)
(parse-clause!))))
((or (= u "NCONC") (= u "NCONCING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":nconc" expr into-var)
(parse-clause!))))
((or (= u "SUM") (= u "SUMMING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":sum" expr into-var)
(parse-clause!))))
((or (= u "COUNT") (= u "COUNTING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":count" expr into-var)
(parse-clause!))))
((or (= u "MAXIMIZE") (= u "MAXIMIZING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":maximize" expr into-var)
(parse-clause!))))
((or (= u "MINIMIZE") (= u "MINIMIZING"))
(do
(next!)
(let
((expr (next!)) (into-var nil))
(when
(kw? (lp-peek) "INTO")
(do (next!) (set! into-var (next!))))
(add-accum! ":minimize" expr into-var)
(parse-clause!))))
((= u "DO")
(do
(next!)
(define
(loop-kw? s)
(let
((us (upcase-str s)))
(some
(fn (k) (= us k))
(list
"FOR"
"WITH"
"WHILE"
"UNTIL"
"REPEAT"
"COLLECT"
"COLLECTING"
"APPEND"
"APPENDING"
"NCONC"
"NCONCING"
"SUM"
"SUMMING"
"COUNT"
"COUNTING"
"MAXIMIZE"
"MAXIMIZING"
"MINIMIZE"
"MINIMIZING"
"DO"
"WHEN"
"IF"
"UNLESS"
"FINALLY"
"ALWAYS"
"NEVER"
"THEREIS"
"RETURN"
"NAMED"))))
(define
(collect-do-forms!)
(if
(or (nil? (lp-peek)) (loop-kw? (lp-peek)))
nil
(do
(set!
body-forms
(append body-forms (list (next!))))
(collect-do-forms!))))
(collect-do-forms!)
(parse-clause!)))
((or (= u "WHEN") (= u "IF"))
(do
(next!)
(let
((cond-expr (next!))
(body-start (len body-forms)))
(parse-clause!)
;; wrap forms added since body-start in (WHEN cond ...)
(when (> (len body-forms) body-start)
(let ((added (list (nth body-forms body-start))))
(set! body-forms
(append
(if (> body-start 0)
(list (nth body-forms (- body-start 1)))
(list))
(list (list "WHEN" cond-expr (first added)))))
nil)))))
((= u "UNLESS")
(do
(next!)
(let
((cond-expr (next!))
(body-start (len body-forms)))
(parse-clause!)
(when (> (len body-forms) body-start)
(let ((added (list (nth body-forms body-start))))
(set! body-forms
(append
(if (> body-start 0)
(list (nth body-forms (- body-start 1)))
(list))
(list (list "UNLESS" cond-expr (first added)))))
nil)))))
((= u "ALWAYS")
(do (next!) (set! termination {:expr (next!) :type ":always"}) (parse-clause!)))
((= u "NEVER")
(do (next!) (set! termination {:expr (next!) :type ":never"}) (parse-clause!)))
((= u "THEREIS")
(do (next!) (set! termination {:expr (next!) :type ":thereis"}) (parse-clause!)))
((= u "RETURN")
(do (next!) (set! return-expr (next!)) (parse-clause!)))
((= u "FINALLY")
(do
(next!)
(define
(collect-finally!)
(if
(nil? (lp-peek))
nil
(do
(set!
finally-forms
(append finally-forms (list (next!))))
(collect-finally!))))
(collect-finally!)
(parse-clause!)))
(:else
(do
(set! body-forms (append body-forms (list (next!))))
(parse-clause!)))))))))
(parse-clause!)
(define let-bindings (list))
(for-each
(fn (wb) (set! let-bindings (append let-bindings (list wb))))
with-bindings)
(for-each
(fn
(v)
(set!
let-bindings
(append let-bindings (list (list v (get accum-vars v))))))
(keys accum-vars))
(when
(not (nil? repeat-var))
(set!
let-bindings
(append let-bindings (list (list repeat-var repeat-count)))))
(for-each
(fn
(fb)
(let
((type (get fb "type")))
(cond
((= type ":list")
(do
(set!
let-bindings
(append
let-bindings
(list (list (get fb "tail") (get fb "list")))
(list
(list
(get fb "var")
(list
"IF"
(list "CONSP" (get fb "tail"))
(list "CAR" (get fb "tail"))
nil)))))
nil))
((= type ":numeric")
(set!
let-bindings
(append
let-bindings
(list (list (get fb "var") (get fb "from"))))))
((= type ":general")
(set!
let-bindings
(append
let-bindings
(list (list (get fb "var") (get fb "init"))))))
(:else nil))))
for-bindings)
(define all-tests (list))
(when
(not (nil? repeat-var))
(set!
all-tests
(append
all-tests
(list
(list
"WHEN"
(list "<=" repeat-var 0)
(list "RETURN-FROM" block-name (if (nil? result-var) nil result-var))))))
(set!
body-forms
(append
(list (list "SETQ" repeat-var (list "-" repeat-var 1)))
body-forms)))
(for-each
(fn
(fb)
(when
(= (get fb "type") ":list")
(let
((tvar (get fb "tail")) (var (get fb "var")))
(set!
all-tests
(append
all-tests
(list
(list
"WHEN"
(list "NULL" tvar)
(list
"RETURN-FROM"
block-name
(if (nil? result-var) nil result-var))))))
(set!
body-forms
(append
body-forms
(list
(list "SETQ" tvar (list "CDR" tvar))
(list
"SETQ"
var
(list "IF" (list "CONSP" tvar) (list "CAR" tvar) nil))))))))
for-bindings)
(for-each
(fn
(fb)
(when
(= (get fb "type") ":numeric")
(let
((var (get fb "var"))
(dir (get fb "dir"))
(lim (get fb "limit"))
(ltype (get fb "limit-type"))
(step (get fb "step")))
(when
(not (nil? lim))
(let
((test-op (cond ((or (= ltype "BELOW") (= ltype "ABOVE")) (if (= dir ":up") ">=" "<=")) ((or (= ltype "TO") (= ltype "UPTO")) ">") ((= ltype "DOWNTO") "<") (:else (if (= dir ":up") ">" "<")))))
(set!
all-tests
(append
all-tests
(list
(list
"WHEN"
(list test-op var lim)
(list
"RETURN-FROM"
block-name
(if (nil? result-var) nil result-var))))))))
(let
((step-op (if (or (= dir ":down") (= ltype "DOWNTO") (= ltype "ABOVE")) "-" "+")))
(set!
body-forms
(append
body-forms
(list (list "SETQ" var (list step-op var step)))))))))
for-bindings)
(for-each
(fn
(fb)
(when
(= (get fb "type") ":general")
(set!
body-forms
(append
body-forms
(list (list "SETQ" (get fb "var") (get fb "then")))))))
for-bindings)
(for-each
(fn
(t)
(let
((type (get t "type")) (expr (get t "expr")))
(if
(= type ":while")
(set!
all-tests
(append
all-tests
(list
(list
"WHEN"
(list "NOT" expr)
(list
"RETURN-FROM"
block-name
(if (nil? result-var) nil result-var))))))
(set!
all-tests
(append
all-tests
(list
(list
"WHEN"
expr
(list
"RETURN-FROM"
block-name
(if (nil? result-var) nil result-var)))))))))
test-forms)
(when
(not (nil? termination))
(let
((type (get termination "type")) (expr (get termination "expr")))
(cond
((= type ":always")
(set!
body-forms
(append
body-forms
(list
(list "UNLESS" expr (list "RETURN-FROM" block-name false)))))
(set! return-expr true))
((= type ":never")
(set!
body-forms
(append
body-forms
(list
(list "WHEN" expr (list "RETURN-FROM" block-name false)))))
(set! return-expr true))
((= type ":thereis")
(set!
body-forms
(append
body-forms
(list
(list "WHEN" expr (list "RETURN-FROM" block-name expr)))))))))
(define tag "#LOOP-START")
(define
inner-body
(append (list tag) all-tests body-forms (list (list "GO" tag))))
(define
result-form
(cond
((not (nil? return-expr)) return-expr)
((not (nil? result-var)) result-var)
(:else nil)))
(define
full-body
(if
(= (len let-bindings) 0)
(append
(list "PROGN")
(list (append (list "TAGBODY") inner-body))
finally-forms
(list result-form))
(list
"LET*"
let-bindings
(append (list "TAGBODY") inner-body)
(append (list "PROGN") finally-forms (list result-form)))))
(list "BLOCK" block-name full-body)))
;; ── Install LOOP as a CL macro ────────────────────────────────────────────
;;
;; (loop ...) — the form arrives with head "LOOP" and rest = clauses.
;; The macro fn receives the full form.
(dict-set!
cl-macro-registry
"LOOP"
(fn (form env) (cl-loop-parse (rest form))))

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;; Common Lisp reader — converts token stream to CL AST forms.
;;
;; Depends on: lib/common-lisp/reader.sx (cl-tokenize)
;;
;; AST representation:
;; integer/float → SX number (or {:cl-type "float"/:ratio ...})
;; string "hello" → {:cl-type "string" :value "hello"}
;; symbol FOO → SX string "FOO" (upcase)
;; symbol NIL → nil
;; symbol T → true
;; :keyword → {:cl-type "keyword" :name "FOO"}
;; #\char → {:cl-type "char" :value "a"}
;; #:uninterned → {:cl-type "uninterned" :name "FOO"}
;; ratio 1/3 → {:cl-type "ratio" :value "1/3"}
;; float 3.14 → {:cl-type "float" :value "3.14"}
;; proper list (a b c) → SX list (a b c)
;; dotted pair (a . b) → {:cl-type "cons" :car a :cdr b}
;; vector #(a b) → {:cl-type "vector" :elements (list a b)}
;; 'x → ("QUOTE" x)
;; `x → ("QUASIQUOTE" x)
;; ,x → ("UNQUOTE" x)
;; ,@x → ("UNQUOTE-SPLICING" x)
;; #'x → ("FUNCTION" x)
;;
;; Public API:
;; (cl-read src) — parse first form from string, return form
;; (cl-read-all src) — parse all top-level forms, return list
;; ── number conversion ─────────────────────────────────────────────
(define
cl-hex-val
(fn
(c)
(let
((o (cl-ord c)))
(cond
((and (>= o 48) (<= o 57)) (- o 48))
((and (>= o 65) (<= o 70)) (+ 10 (- o 65)))
((and (>= o 97) (<= o 102)) (+ 10 (- o 97)))
(:else 0)))))
(define
cl-parse-radix-str
(fn
(s radix start)
(let
((n (string-length s)) (i start) (acc 0))
(define
loop
(fn
()
(when
(< i n)
(do
(set! acc (+ (* acc radix) (cl-hex-val (substring s i (+ i 1)))))
(set! i (+ i 1))
(loop)))))
(loop)
acc)))
(define
cl-convert-integer
(fn
(s)
(let
((n (string-length s)) (neg false))
(cond
((and (> n 2) (= (substring s 0 1) "#"))
(let
((letter (downcase (substring s 1 2))))
(cond
((= letter "x") (cl-parse-radix-str s 16 2))
((= letter "b") (cl-parse-radix-str s 2 2))
((= letter "o") (cl-parse-radix-str s 8 2))
(:else (parse-int s 0)))))
(:else (parse-int s 0))))))
;; ── reader ────────────────────────────────────────────────────────
;; Read one form from token list.
;; Returns {:form F :rest remaining-toks} or {:form nil :rest toks :eof true}
(define
cl-read-form
(fn
(toks)
(if
(not toks)
{:form nil :rest toks :eof true}
(let
((tok (nth toks 0)) (nxt (rest toks)))
(let
((type (get tok "type")) (val (get tok "value")))
(cond
((= type "eof") {:form nil :rest toks :eof true})
((= type "integer") {:form (cl-convert-integer val) :rest nxt})
((= type "float") {:form {:cl-type "float" :value val} :rest nxt})
((= type "ratio") {:form {:cl-type "ratio" :value val} :rest nxt})
((= type "string") {:form {:cl-type "string" :value val} :rest nxt})
((= type "char") {:form {:cl-type "char" :value val} :rest nxt})
((= type "keyword") {:form {:cl-type "keyword" :name val} :rest nxt})
((= type "uninterned") {:form {:cl-type "uninterned" :name val} :rest nxt})
((= type "symbol")
(cond
((= val "NIL") {:form nil :rest nxt})
((= val "T") {:form true :rest nxt})
(:else {:form val :rest nxt})))
;; list forms
((= type "lparen") (cl-read-list nxt))
((= type "hash-paren") (cl-read-vector nxt))
;; reader macros that wrap the next form
((= type "quote") (cl-read-wrap "QUOTE" nxt))
((= type "backquote") (cl-read-wrap "QUASIQUOTE" nxt))
((= type "comma") (cl-read-wrap "UNQUOTE" nxt))
((= type "comma-at") (cl-read-wrap "UNQUOTE-SPLICING" nxt))
((= type "hash-quote") (cl-read-wrap "FUNCTION" nxt))
;; skip unrecognised tokens
(:else (cl-read-form nxt))))))))
;; Wrap next form in a list: (name form)
(define
cl-read-wrap
(fn
(name toks)
(let
((inner (cl-read-form toks)))
{:form (list name (get inner "form")) :rest (get inner "rest")})))
;; Read list forms until ')'; handles dotted pair (a . b)
;; Called after consuming '('
(define
cl-read-list
(fn
(toks)
(let
((result (cl-read-list-items toks (list))))
{:form (get result "items") :rest (get result "rest")})))
(define
cl-read-list-items
(fn
(toks acc)
(if
(not toks)
{:items acc :rest toks}
(let
((tok (nth toks 0)))
(let
((type (get tok "type")))
(cond
((= type "eof") {:items acc :rest toks})
((= type "rparen") {:items acc :rest (rest toks)})
;; dotted pair: read one more form then expect ')'
((= type "dot")
(let
((cdr-result (cl-read-form (rest toks))))
(let
((cdr-form (get cdr-result "form"))
(after-cdr (get cdr-result "rest")))
;; skip the closing ')'
(let
((close (if after-cdr (nth after-cdr 0) nil)))
(let
((remaining
(if
(and close (= (get close "type") "rparen"))
(rest after-cdr)
after-cdr)))
;; build dotted structure
(let
((dotted (cl-build-dotted acc cdr-form)))
{:items dotted :rest remaining}))))))
(:else
(let
((item (cl-read-form toks)))
(cl-read-list-items
(get item "rest")
(concat acc (list (get item "form"))))))))))))
;; Build dotted form: (a b . c) → ((DOTTED a b) . c) style
;; In CL (a b c . d) means a proper dotted structure.
;; We represent it as {:cl-type "cons" :car a :cdr (list->dotted b c d)}
(define
cl-build-dotted
(fn
(head-items tail)
(if
(= (len head-items) 0)
tail
(if
(= (len head-items) 1)
{:cl-type "cons" :car (nth head-items 0) :cdr tail}
(let
((last-item (nth head-items (- (len head-items) 1)))
(but-last (slice head-items 0 (- (len head-items) 1))))
{:cl-type "cons"
:car (cl-build-dotted but-last (list last-item))
:cdr tail})))))
;; Read vector #(…) elements until ')'
(define
cl-read-vector
(fn
(toks)
(let
((result (cl-read-vector-items toks (list))))
{:form {:cl-type "vector" :elements (get result "items")} :rest (get result "rest")})))
(define
cl-read-vector-items
(fn
(toks acc)
(if
(not toks)
{:items acc :rest toks}
(let
((tok (nth toks 0)))
(let
((type (get tok "type")))
(cond
((= type "eof") {:items acc :rest toks})
((= type "rparen") {:items acc :rest (rest toks)})
(:else
(let
((item (cl-read-form toks)))
(cl-read-vector-items
(get item "rest")
(concat acc (list (get item "form"))))))))))))
;; ── lambda-list parser ───────────────────────────────────────────
;;
;; (cl-parse-lambda-list forms) — parse a list of CL forms (already read)
;; into a structured dict:
;; {:required (list sym ...)
;; :optional (list {:name N :default D :supplied S} ...)
;; :rest nil | "SYM"
;; :key (list {:name N :keyword K :default D :supplied S} ...)
;; :allow-other-keys false | true
;; :aux (list {:name N :init I} ...)}
;;
;; Symbols arrive as SX strings (upcase). &-markers are strings like "&OPTIONAL".
;; Key params: keyword is the upcase name string; caller uses it as :keyword.
;; Supplied-p: nil when absent.
(define
cl-parse-opt-spec
(fn
(spec)
(if
(list? spec)
{:name (nth spec 0)
:default (if (> (len spec) 1) (nth spec 1) nil)
:supplied (if (> (len spec) 2) (nth spec 2) nil)}
{:name spec :default nil :supplied nil})))
(define
cl-parse-key-spec
(fn
(spec)
(if
(list? spec)
(let
((first (nth spec 0)))
(if
(list? first)
;; ((:keyword var) default supplied-p)
{:name (nth first 1)
:keyword (get first "name")
:default (if (> (len spec) 1) (nth spec 1) nil)
:supplied (if (> (len spec) 2) (nth spec 2) nil)}
;; (var default supplied-p)
{:name first
:keyword first
:default (if (> (len spec) 1) (nth spec 1) nil)
:supplied (if (> (len spec) 2) (nth spec 2) nil)}))
{:name spec :keyword spec :default nil :supplied nil})))
(define
cl-parse-aux-spec
(fn
(spec)
(if
(list? spec)
{:name (nth spec 0) :init (if (> (len spec) 1) (nth spec 1) nil)}
{:name spec :init nil})))
(define
cl-parse-lambda-list
(fn
(forms)
(let
((state "required")
(required (list))
(optional (list))
(rest-name nil)
(key (list))
(allow-other-keys false)
(aux (list)))
(define
scan
(fn
(items)
(when
(> (len items) 0)
(let
((item (nth items 0)) (tail (rest items)))
(cond
((= item "&OPTIONAL")
(do (set! state "optional") (scan tail)))
((= item "&REST")
(do (set! state "rest") (scan tail)))
((= item "&BODY")
(do (set! state "rest") (scan tail)))
((= item "&KEY")
(do (set! state "key") (scan tail)))
((= item "&AUX")
(do (set! state "aux") (scan tail)))
((= item "&ALLOW-OTHER-KEYS")
(do (set! allow-other-keys true) (scan tail)))
((= state "required")
(do (append! required item) (scan tail)))
((= state "optional")
(do (append! optional (cl-parse-opt-spec item)) (scan tail)))
((= state "rest")
(do (set! rest-name item) (set! state "done") (scan tail)))
((= state "key")
(do (append! key (cl-parse-key-spec item)) (scan tail)))
((= state "aux")
(do (append! aux (cl-parse-aux-spec item)) (scan tail)))
(:else (scan tail)))))))
(scan forms)
{:required required
:optional optional
:rest rest-name
:key key
:allow-other-keys allow-other-keys
:aux aux})))
;; Convenience: parse lambda list from a CL source string
(define
cl-parse-lambda-list-str
(fn
(src)
(cl-parse-lambda-list (cl-read src))))
;; ── public API ────────────────────────────────────────────────────
(define
cl-read
(fn
(src)
(let
((toks (cl-tokenize src)))
(get (cl-read-form toks) "form"))))
(define
cl-read-all
(fn
(src)
(let
((toks (cl-tokenize src)))
(define
loop
(fn
(toks acc)
(if
(or (not toks) (= (get (nth toks 0) "type") "eof"))
acc
(let
((result (cl-read-form toks)))
(if
(get result "eof")
acc
(loop (get result "rest") (concat acc (list (get result "form")))))))))
(loop toks (list)))))

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;; Common Lisp tokenizer
;;
;; Tokens: {:type T :value V :pos P}
;;
;; Types:
;; "symbol" — FOO, PKG:SYM, PKG::SYM, T, NIL (upcase)
;; "keyword" — :foo (value is upcase name without colon)
;; "integer" — 42, -5, #xFF, #b1010, #o17 (string)
;; "float" — 3.14, 1.0e10 (string)
;; "ratio" — 1/3 (string "N/D")
;; "string" — unescaped content
;; "char" — single-character string
;; "lparen" "rparen" "quote" "backquote" "comma" "comma-at"
;; "hash-quote" — #'
;; "hash-paren" — #(
;; "uninterned" — #:foo (upcase name)
;; "dot" — standalone . (dotted pair separator)
;; "eof"
(define cl-make-tok (fn (type value pos) {:type type :value value :pos pos}))
;; ── char ordinal table ────────────────────────────────────────────
(define
cl-ord-table
(let
((t (dict)) (i 0))
(define
cl-fill
(fn
()
(when
(< i 128)
(do
(dict-set! t (char-from-code i) i)
(set! i (+ i 1))
(cl-fill)))))
(cl-fill)
t))
(define cl-ord (fn (c) (or (get cl-ord-table c) 0)))
;; ── character predicates ──────────────────────────────────────────
(define cl-digit? (fn (c) (and (>= (cl-ord c) 48) (<= (cl-ord c) 57))))
(define
cl-hex?
(fn
(c)
(or
(cl-digit? c)
(and (>= (cl-ord c) 65) (<= (cl-ord c) 70))
(and (>= (cl-ord c) 97) (<= (cl-ord c) 102)))))
(define cl-octal? (fn (c) (and (>= (cl-ord c) 48) (<= (cl-ord c) 55))))
(define cl-binary? (fn (c) (or (= c "0") (= c "1"))))
(define cl-ws? (fn (c) (or (= c " ") (= c "\t") (= c "\n") (= c "\r"))))
(define
cl-alpha?
(fn
(c)
(or
(and (>= (cl-ord c) 65) (<= (cl-ord c) 90))
(and (>= (cl-ord c) 97) (<= (cl-ord c) 122)))))
;; Characters that end a token (whitespace + terminating macro chars)
(define
cl-terminating?
(fn
(c)
(or
(cl-ws? c)
(= c "(")
(= c ")")
(= c "\"")
(= c ";")
(= c "`")
(= c ","))))
;; Symbol constituent: not terminating, not reader-special
(define
cl-sym-char?
(fn
(c)
(not
(or
(cl-terminating? c)
(= c "#")
(= c "|")
(= c "\\")
(= c "'")))))
;; ── named character table ─────────────────────────────────────────
(define
cl-named-chars
{:space " "
:newline "\n"
:tab "\t"
:return "\r"
:backspace (char-from-code 8)
:rubout (char-from-code 127)
:delete (char-from-code 127)
:escape (char-from-code 27)
:altmode (char-from-code 27)
:null (char-from-code 0)
:nul (char-from-code 0)
:page (char-from-code 12)
:formfeed (char-from-code 12)})
;; ── main tokenizer ────────────────────────────────────────────────
(define
cl-tokenize
(fn
(src)
(let
((pos 0) (n (string-length src)) (toks (list)))
(define at (fn () (if (< pos n) (substring src pos (+ pos 1)) nil)))
(define peek1 (fn () (if (< (+ pos 1) n) (substring src (+ pos 1) (+ pos 2)) nil)))
(define adv (fn () (set! pos (+ pos 1))))
;; Advance while predicate holds; return substring from start to end
(define
read-while
(fn
(pred)
(let
((start pos))
(define
rw-loop
(fn
()
(when
(and (at) (pred (at)))
(do (adv) (rw-loop)))))
(rw-loop)
(substring src start pos))))
(define
skip-line
(fn
()
(when
(and (at) (not (= (at) "\n")))
(do (adv) (skip-line)))))
(define
skip-block
(fn
(depth)
(when
(at)
(cond
((and (= (at) "#") (= (peek1) "|"))
(do (adv) (adv) (skip-block (+ depth 1))))
((and (= (at) "|") (= (peek1) "#"))
(do
(adv)
(adv)
(when (> depth 1) (skip-block (- depth 1)))))
(:else (do (adv) (skip-block depth)))))))
;; Read string literal — called with pos just past opening "
(define
read-str
(fn
(acc)
(if
(not (at))
acc
(cond
((= (at) "\"") (do (adv) acc))
((= (at) "\\")
(do
(adv)
(let
((e (at)))
(adv)
(read-str
(str
acc
(cond
((= e "n") "\n")
((= e "t") "\t")
((= e "r") "\r")
((= e "\"") "\"")
((= e "\\") "\\")
(:else e)))))))
(:else
(let
((c (at)))
(adv)
(read-str (str acc c))))))))
;; Read #\ char literal — called with pos just past the backslash
(define
read-char-lit
(fn
()
(let
((first (at)))
(adv)
(let
((rest (if (and (at) (cl-alpha? (at))) (read-while cl-alpha?) "")))
(if
(= rest "")
first
(let
((name (downcase (str first rest))))
(or (get cl-named-chars name) first)))))))
;; Number scanner — called with pos just past first digit(s).
;; acc holds what was already consumed (first digit or sign+digit).
(define
scan-num
(fn
(p acc)
(let
((more (read-while cl-digit?)))
(set! acc (str acc more))
(cond
;; ratio N/D
((and (at) (= (at) "/") (peek1) (cl-digit? (peek1)))
(do
(adv)
(let
((denom (read-while cl-digit?)))
{:type "ratio" :value (str acc "/" denom) :pos p})))
;; float: decimal point N.M[eE]
((and (at) (= (at) ".") (peek1) (cl-digit? (peek1)))
(do
(adv)
(let
((frac (read-while cl-digit?)))
(set! acc (str acc "." frac))
(when
(and (at) (or (= (at) "e") (= (at) "E")))
(do
(set! acc (str acc (at)))
(adv)
(when
(and (at) (or (= (at) "+") (= (at) "-")))
(do (set! acc (str acc (at))) (adv)))
(set! acc (str acc (read-while cl-digit?)))))
{:type "float" :value acc :pos p})))
;; float: exponent only NeE
((and (at) (or (= (at) "e") (= (at) "E")))
(do
(set! acc (str acc (at)))
(adv)
(when
(and (at) (or (= (at) "+") (= (at) "-")))
(do (set! acc (str acc (at))) (adv)))
(set! acc (str acc (read-while cl-digit?)))
{:type "float" :value acc :pos p}))
(:else {:type "integer" :value acc :pos p})))))
(define
read-radix
(fn
(letter p)
(let
((pred
(cond
((or (= letter "x") (= letter "X")) cl-hex?)
((or (= letter "b") (= letter "B")) cl-binary?)
((or (= letter "o") (= letter "O")) cl-octal?)
(:else cl-digit?))))
{:type "integer"
:value (str "#" letter (read-while pred))
:pos p})))
(define emit (fn (tok) (append! toks tok)))
(define
scan
(fn
()
(when
(< pos n)
(let
((c (at)) (p pos))
(cond
((cl-ws? c) (do (adv) (scan)))
((= c ";") (do (adv) (skip-line) (scan)))
((= c "(") (do (adv) (emit (cl-make-tok "lparen" "(" p)) (scan)))
((= c ")") (do (adv) (emit (cl-make-tok "rparen" ")" p)) (scan)))
((= c "'") (do (adv) (emit (cl-make-tok "quote" "'" p)) (scan)))
((= c "`") (do (adv) (emit (cl-make-tok "backquote" "`" p)) (scan)))
((= c ",")
(do
(adv)
(if
(= (at) "@")
(do (adv) (emit (cl-make-tok "comma-at" ",@" p)))
(emit (cl-make-tok "comma" "," p)))
(scan)))
((= c "\"")
(do
(adv)
(emit (cl-make-tok "string" (read-str "") p))
(scan)))
;; :keyword
((= c ":")
(do
(adv)
(emit (cl-make-tok "keyword" (upcase (read-while cl-sym-char?)) p))
(scan)))
;; dispatch macro #
((= c "#")
(do
(adv)
(let
((d (at)))
(cond
((= d "'") (do (adv) (emit (cl-make-tok "hash-quote" "#'" p)) (scan)))
((= d "(") (do (adv) (emit (cl-make-tok "hash-paren" "#(" p)) (scan)))
((= d ":")
(do
(adv)
(emit
(cl-make-tok "uninterned" (upcase (read-while cl-sym-char?)) p))
(scan)))
((= d "|") (do (adv) (skip-block 1) (scan)))
((= d "\\")
(do (adv) (emit (cl-make-tok "char" (read-char-lit) p)) (scan)))
((or (= d "x") (= d "X"))
(do (adv) (emit (read-radix d p)) (scan)))
((or (= d "b") (= d "B"))
(do (adv) (emit (read-radix d p)) (scan)))
((or (= d "o") (= d "O"))
(do (adv) (emit (read-radix d p)) (scan)))
(:else (scan))))))
;; standalone dot, float .5, or symbol starting with dots
((= c ".")
(do
(adv)
(cond
((or (not (at)) (cl-terminating? (at)))
(do (emit (cl-make-tok "dot" "." p)) (scan)))
((cl-digit? (at))
(do
(emit
(cl-make-tok "float" (str "0." (read-while cl-digit?)) p))
(scan)))
(:else
(do
(emit
(cl-make-tok "symbol" (upcase (str "." (read-while cl-sym-char?))) p))
(scan))))))
;; sign followed by digit → number
((and (or (= c "+") (= c "-")) (peek1) (cl-digit? (peek1)))
(do
(adv)
(let
((first-d (at)))
(adv)
(emit (scan-num p (str c first-d))))
(scan)))
;; decimal digit → number
((cl-digit? c)
(do
(adv)
(emit (scan-num p c))
(scan)))
;; symbol constituent (includes bare +, -, etc.)
((cl-sym-char? c)
(do
(emit (cl-make-tok "symbol" (upcase (read-while cl-sym-char?)) p))
(scan)))
(:else (do (adv) (scan))))))))
(scan)
(append! toks (cl-make-tok "eof" nil n))
toks)))

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lib/common-lisp/runtime.sx Normal file
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;; lib/common-lisp/runtime.sx — CL built-ins + condition system on SX
;;
;; Section 1-9: Type predicates, arithmetic, characters, strings, gensym,
;; multiple values, sets, radix formatting, list utilities.
;; Section 10: Condition system (define-condition, signal/error/warn,
;; handler-bind, handler-case, restart-case, invoke-restart).
;;
;; Primitives used from spec:
;; char/char->integer/integer->char/char-upcase/char-downcase
;; format gensym rational/rational? make-set/set-member?/etc
;; modulo/remainder/quotient/gcd/lcm/expt number->string
;; ---------------------------------------------------------------------------
;; 1. Type predicates
;; ---------------------------------------------------------------------------
(define (cl-null? x) (= x nil))
(define (cl-consp? x) (and (list? x) (not (cl-empty? x))))
(define (cl-listp? x) (or (cl-empty? x) (list? x)))
(define (cl-atom? x) (not (cl-consp? x)))
(define
(cl-numberp? x)
(let ((t (type-of x))) (or (= t "number") (= t "rational"))))
(define cl-integerp? integer?)
(define cl-floatp? float?)
(define cl-rationalp? rational?)
(define (cl-realp? x) (or (integer? x) (float? x) (rational? x)))
(define cl-characterp? char?)
(define cl-stringp? (fn (x) (= (type-of x) "string")))
(define cl-symbolp? (fn (x) (= (type-of x) "symbol")))
(define cl-keywordp? (fn (x) (= (type-of x) "keyword")))
(define
(cl-functionp? x)
(let
((t (type-of x)))
(or
(= t "function")
(= t "lambda")
(= t "native-fn")
(= t "component"))))
(define cl-vectorp? vector?)
(define cl-arrayp? vector?)
;; sx_server: (rest (list x)) returns () not nil — cl-empty? handles both
(define
(cl-empty? x)
(or (nil? x) (and (list? x) (= (len x) 0))))
;; ---------------------------------------------------------------------------
;; 2. Arithmetic — thin aliases to spec primitives
;; ---------------------------------------------------------------------------
(define cl-mod modulo)
(define cl-rem remainder)
(define cl-gcd gcd)
(define cl-lcm lcm)
(define cl-expt expt)
(define cl-floor floor)
(define cl-ceiling ceil)
(define cl-truncate truncate)
(define cl-round round)
(define cl-abs (fn (x) (if (< x 0) (- 0 x) x)))
(define cl-min (fn (a b) (if (< a b) a b)))
(define cl-max (fn (a b) (if (> a b) a b)))
(define cl-quotient quotient)
(define
(cl-signum x)
(cond
((> x 0) 1)
((< x 0) -1)
(else 0)))
(define (cl-evenp? n) (= (modulo n 2) 0))
(define (cl-oddp? n) (= (modulo n 2) 1))
(define (cl-zerop? n) (= n 0))
(define (cl-plusp? n) (> n 0))
(define (cl-minusp? n) (< n 0))
;; ---------------------------------------------------------------------------
;; 3. Character functions — alias spec char primitives + CL name mapping
;; ---------------------------------------------------------------------------
(define cl-char->integer char->integer)
(define cl-integer->char integer->char)
(define cl-char-upcase char-upcase)
(define cl-char-downcase char-downcase)
(define cl-char-code char->integer)
(define cl-code-char integer->char)
(define cl-char=? char=?)
(define cl-char<? char<?)
(define cl-char>? char>?)
(define cl-char<=? char<=?)
(define cl-char>=? char>=?)
(define cl-char-ci=? char-ci=?)
(define cl-char-ci<? char-ci<?)
(define cl-char-ci>? char-ci>?)
;; Inline predicates — char-alphabetic?/char-numeric? unreliable in sx_server
(define
(cl-alpha-char-p c)
(let
((n (char->integer c)))
(or
(and (>= n 65) (<= n 90))
(and (>= n 97) (<= n 122)))))
(define
(cl-digit-char-p c)
(let ((n (char->integer c))) (and (>= n 48) (<= n 57))))
(define
(cl-alphanumericp c)
(let
((n (char->integer c)))
(or
(and (>= n 48) (<= n 57))
(and (>= n 65) (<= n 90))
(and (>= n 97) (<= n 122)))))
(define
(cl-upper-case-p c)
(let ((n (char->integer c))) (and (>= n 65) (<= n 90))))
(define
(cl-lower-case-p c)
(let ((n (char->integer c))) (and (>= n 97) (<= n 122))))
;; Named character constants
(define cl-char-space (integer->char 32))
(define cl-char-newline (integer->char 10))
(define cl-char-tab (integer->char 9))
(define cl-char-backspace (integer->char 8))
(define cl-char-return (integer->char 13))
(define cl-char-null (integer->char 0))
(define cl-char-escape (integer->char 27))
(define cl-char-delete (integer->char 127))
;; ---------------------------------------------------------------------------
;; 4. String + IO — use spec format and ports
;; ---------------------------------------------------------------------------
;; CL format: (cl-format nil "~a ~a" x y) — nil destination means return string
(define
(cl-format dest template &rest args)
(let ((s (apply format (cons template args)))) (if (= dest nil) s s)))
(define cl-write-to-string write-to-string)
(define cl-princ-to-string display-to-string)
;; CL read-from-string: parse value from a string using SX port
(define
(cl-read-from-string s)
(let ((p (open-input-string s))) (read p)))
;; String stream (output)
(define cl-make-string-output-stream open-output-string)
(define cl-get-output-stream-string get-output-string)
;; String stream (input)
(define cl-make-string-input-stream open-input-string)
;; ---------------------------------------------------------------------------
;; 5. Gensym
;; ---------------------------------------------------------------------------
(define cl-gensym gensym)
(define cl-gentemp gensym)
;; ---------------------------------------------------------------------------
;; 6. Multiple values (CL: values / nth-value)
;; ---------------------------------------------------------------------------
(define (cl-values &rest args) {:_values true :_list args})
(define
(cl-call-with-values producer consumer)
(let
((mv (producer)))
(if
(and (dict? mv) (get mv :_values))
(apply consumer (get mv :_list))
(consumer mv))))
(define
(cl-nth-value n mv)
(cond
((and (dict? mv) (get mv :_values))
(let
((lst (get mv :_list)))
(if (>= n (len lst)) nil (nth lst n))))
((= n 0) mv)
(else nil)))
;; ---------------------------------------------------------------------------
;; 7. Sets (CL: adjoin / member / union / intersection / set-difference)
;; ---------------------------------------------------------------------------
(define cl-make-set make-set)
(define cl-set? set?)
(define cl-set-add set-add!)
(define cl-set-memberp set-member?)
(define cl-set-remove set-remove!)
(define cl-set-union set-union)
(define cl-set-intersect set-intersection)
(define cl-set-difference set-difference)
(define cl-list->set list->set)
(define cl-set->list set->list)
;; CL: (member item list) — returns tail starting at item, or nil
(define
(cl-member item lst)
(cond
((cl-empty? lst) nil)
((equal? item (first lst)) lst)
(else (cl-member item (rest lst)))))
;; CL: (adjoin item list) — cons only if not already present
(define (cl-adjoin item lst) (if (cl-member item lst) lst (cons item lst)))
;; ---------------------------------------------------------------------------
;; 8. Radix formatting (CL: (write-to-string n :base radix))
;; ---------------------------------------------------------------------------
(define (cl-integer-to-string n radix) (number->string n radix))
(define (cl-string-to-integer s radix) (string->number s radix))
;; CL ~R directive helpers
(define (cl-format-binary n) (number->string n 2))
(define (cl-format-octal n) (number->string n 8))
(define (cl-format-hex n) (number->string n 16))
(define (cl-format-decimal n) (number->string n 10))
;; ---------------------------------------------------------------------------
;; 9. List utilities — cl-empty? guards against () from rest
;; ---------------------------------------------------------------------------
(define
(cl-last lst)
(cond
((cl-empty? lst) nil)
((cl-empty? (rest lst)) lst)
(else (cl-last (rest lst)))))
(define
(cl-butlast lst)
(if
(or (cl-empty? lst) (cl-empty? (rest lst)))
nil
(cons (first lst) (cl-butlast (rest lst)))))
(define
(cl-nthcdr n lst)
(if (= n 0) lst (cl-nthcdr (- n 1) (rest lst))))
(define (cl-nth n lst) (first (cl-nthcdr n lst)))
(define (cl-list-length lst) (len lst))
(define
(cl-copy-list lst)
(if (cl-empty? lst) nil (cons (first lst) (cl-copy-list (rest lst)))))
(define
(cl-flatten lst)
(cond
((cl-empty? lst) nil)
((list? (first lst))
(append (cl-flatten (first lst)) (cl-flatten (rest lst))))
(else (cons (first lst) (cl-flatten (rest lst))))))
;; CL: (assoc key alist) — returns matching pair or nil
(define
(cl-assoc key alist)
(cond
((cl-empty? alist) nil)
((equal? key (first (first alist))) (first alist))
(else (cl-assoc key (rest alist)))))
;; CL: (rassoc val alist) — reverse assoc (match on second element)
(define
(cl-rassoc val alist)
(cond
((cl-empty? alist) nil)
((equal? val (first (rest (first alist)))) (first alist))
(else (cl-rassoc val (rest alist)))))
;; CL: (getf plist key) — property list lookup
(define
(cl-getf plist key)
(cond
((or (cl-empty? plist) (cl-empty? (rest plist))) nil)
((equal? (first plist) key) (first (rest plist)))
(else (cl-getf (rest (rest plist)) key))))
;; ---------------------------------------------------------------------------
;; 10. Condition system (Phase 3)
;;
;; Condition objects:
;; {:cl-type "cl-condition" :class "NAME" :slots {slot-name val ...}}
;;
;; The built-in handler-bind / restart-case expect LITERAL handler specs in
;; source (they operate on the raw AST), so we implement our own handler and
;; restart stacks as mutable SX globals.
;; ---------------------------------------------------------------------------
;; ── condition class registry ───────────────────────────────────────────────
;;
;; Populated at load time with all ANSI standard condition types.
;; Also mutated by cl-define-condition.
(define
cl-condition-classes
(dict
"condition"
{:parents (list) :slots (list) :name "condition"}
"serious-condition"
{:parents (list "condition") :slots (list) :name "serious-condition"}
"error"
{:parents (list "serious-condition") :slots (list) :name "error"}
"warning"
{:parents (list "condition") :slots (list) :name "warning"}
"simple-condition"
{:parents (list "condition") :slots (list "format-control" "format-arguments") :name "simple-condition"}
"simple-error"
{:parents (list "error" "simple-condition") :slots (list "format-control" "format-arguments") :name "simple-error"}
"simple-warning"
{:parents (list "warning" "simple-condition") :slots (list "format-control" "format-arguments") :name "simple-warning"}
"type-error"
{:parents (list "error") :slots (list "datum" "expected-type") :name "type-error"}
"arithmetic-error"
{:parents (list "error") :slots (list "operation" "operands") :name "arithmetic-error"}
"division-by-zero"
{:parents (list "arithmetic-error") :slots (list) :name "division-by-zero"}
"cell-error"
{:parents (list "error") :slots (list "name") :name "cell-error"}
"unbound-variable"
{:parents (list "cell-error") :slots (list) :name "unbound-variable"}
"undefined-function"
{:parents (list "cell-error") :slots (list) :name "undefined-function"}
"program-error"
{:parents (list "error") :slots (list) :name "program-error"}
"storage-condition"
{:parents (list "serious-condition") :slots (list) :name "storage-condition"}))
;; ── condition predicates ───────────────────────────────────────────────────
(define
cl-condition?
(fn (x) (and (dict? x) (= (get x "cl-type") "cl-condition"))))
;; cl-condition-of-type? walks the class hierarchy.
;; We capture cl-condition-classes at define time via let to avoid
;; free-variable scoping issues at call time.
(define
cl-condition-of-type?
(let
((classes cl-condition-classes))
(fn
(c type-name)
(if
(not (cl-condition? c))
false
(let
((class-name (get c "class")))
(define
check
(fn
(n)
(if
(= n type-name)
true
(let
((entry (get classes n)))
(if
(nil? entry)
false
(some (fn (p) (check p)) (get entry "parents")))))))
(check class-name))))))
;; ── condition constructors ─────────────────────────────────────────────────
;; cl-define-condition registers a new condition class.
;; name: string (condition class name)
;; parents: list of strings (parent class names)
;; slot-names: list of strings
(define
cl-define-condition
(fn
(name parents slot-names)
(begin (dict-set! cl-condition-classes name {:parents parents :slots slot-names :name name}) name)))
;; cl-make-condition constructs a condition object.
;; Keyword args (alternating slot-name/value pairs) populate the slots dict.
(define
cl-make-condition
(fn
(name &rest kw-args)
(let
((slots (dict)))
(define
fill
(fn
(args)
(when
(>= (len args) 2)
(begin
(dict-set! slots (first args) (first (rest args)))
(fill (rest (rest args)))))))
(fill kw-args)
{:cl-type "cl-condition" :slots slots :class name})))
;; ── condition accessors ────────────────────────────────────────────────────
(define
cl-condition-slot
(fn
(c slot-name)
(if (cl-condition? c) (get (get c "slots") slot-name) nil)))
(define
cl-condition-message
(fn
(c)
(if
(not (cl-condition? c))
(str c)
(let
((slots (get c "slots")))
(or
(get slots "message")
(get slots "format-control")
(str "Condition: " (get c "class")))))))
(define
cl-simple-condition-format-control
(fn (c) (cl-condition-slot c "format-control")))
(define
cl-simple-condition-format-arguments
(fn (c) (cl-condition-slot c "format-arguments")))
(define cl-type-error-datum (fn (c) (cl-condition-slot c "datum")))
(define
cl-type-error-expected-type
(fn (c) (cl-condition-slot c "expected-type")))
(define
cl-arithmetic-error-operation
(fn (c) (cl-condition-slot c "operation")))
(define
cl-arithmetic-error-operands
(fn (c) (cl-condition-slot c "operands")))
;; ── mutable handler + restart stacks ──────────────────────────────────────
;;
;; Handler entry: {:type "type-name" :fn (fn (condition) result)}
;; Restart entry: {:name "restart-name" :fn (fn (&optional arg) result) :escape k}
;;
;; New handlers are prepended (checked first = most recent handler wins).
(define cl-handler-stack (list))
(define cl-restart-stack (list))
(define
cl-push-handlers
(fn (entries) (set! cl-handler-stack (append entries cl-handler-stack))))
(define
cl-pop-handlers
(fn
(n)
(set! cl-handler-stack (slice cl-handler-stack n (len cl-handler-stack)))))
(define
cl-push-restarts
(fn (entries) (set! cl-restart-stack (append entries cl-restart-stack))))
(define
cl-pop-restarts
(fn
(n)
(set! cl-restart-stack (slice cl-restart-stack n (len cl-restart-stack)))))
;; ── *debugger-hook* + invoke-debugger ────────────────────────────────────
;;
;; cl-debugger-hook: called when an error propagates with no handler.
;; Signature: (fn (condition hook) result). The hook arg is itself
;; (so the hook can rebind it to nil to prevent recursion).
;; nil = use default (re-raise as host error).
(define cl-debugger-hook nil)
(define cl-invoke-debugger
(fn (c)
(if (nil? cl-debugger-hook)
(error (str "Debugger: " (cl-condition-message c)))
(let ((hook cl-debugger-hook))
(set! cl-debugger-hook nil)
(let ((result (hook c hook)))
(set! cl-debugger-hook hook)
result)))))
;; ── *break-on-signals* ────────────────────────────────────────────────────
;;
;; When set to a type name string, cl-signal invokes the debugger hook
;; before walking handlers if the condition is of that type.
;; nil = disabled (ANSI default).
(define cl-break-on-signals nil)
;; ── invoke-restart-interactively ──────────────────────────────────────────
;;
;; Like invoke-restart but calls the restart's fn with no arguments
;; (real CL would prompt the user for each arg via :interactive).
(define cl-invoke-restart-interactively
(fn (name)
(let ((entry (cl-find-restart-entry name cl-restart-stack)))
(if (nil? entry)
(error (str "No active restart: " name))
(let ((restart-fn (get entry "fn"))
(escape (get entry "escape")))
(escape (restart-fn)))))))
;; ── cl-signal (non-unwinding) ─────────────────────────────────────────────
;;
;; Walks cl-handler-stack; for each matching entry, calls the handler fn.
;; Handlers return normally — signal continues to the next matching handler.
(define
cl-signal-obj
(fn
(obj stack)
(if
(empty? stack)
nil
(let
((entry (first stack)))
(if
(cl-condition-of-type? obj (get entry "type"))
(begin ((get entry "fn") obj) (cl-signal-obj obj (rest stack)))
(cl-signal-obj obj (rest stack)))))))
(define cl-signal
(fn (c)
(let ((obj (if (cl-condition? c)
c
(cl-make-condition "simple-condition"
"format-control" (str c)))))
;; *break-on-signals*: invoke debugger hook when type matches
(when (and (not (nil? cl-break-on-signals))
(cl-condition-of-type? obj cl-break-on-signals))
(cl-invoke-debugger obj))
(cl-signal-obj obj cl-handler-stack))))
;; ── cl-error ───────────────────────────────────────────────────────────────
;;
;; Signals an error. If no handler catches it, raises a host-level error.
(define
cl-error
(fn
(c &rest args)
(let
((obj (cond ((cl-condition? c) c) ((string? c) (cl-make-condition "simple-error" "format-control" c "format-arguments" args)) (:else (cl-make-condition "simple-error" "format-control" (str c))))))
(cl-signal-obj obj cl-handler-stack)
(cl-invoke-debugger obj))))
;; ── cl-warn ────────────────────────────────────────────────────────────────
(define
cl-warn
(fn
(c &rest args)
(let
((obj (cond ((cl-condition? c) c) ((string? c) (cl-make-condition "simple-warning" "format-control" c "format-arguments" args)) (:else (cl-make-condition "simple-warning" "format-control" (str c))))))
(cl-signal-obj obj cl-handler-stack))))
;; ── cl-handler-bind (non-unwinding) ───────────────────────────────────────
;;
;; bindings: list of (type-name handler-fn) pairs
;; thunk: (fn () body)
(define
cl-handler-bind
(fn
(bindings thunk)
(let
((entries (map (fn (b) {:fn (first (rest b)) :type (first b)}) bindings)))
(begin
(cl-push-handlers entries)
(let
((result (thunk)))
(begin (cl-pop-handlers (len entries)) result))))))
;; ── cl-handler-case (unwinding) ───────────────────────────────────────────
;;
;; thunk: (fn () body)
;; cases: list of (type-name handler-fn) pairs
;;
;; Uses call/cc for the escape continuation.
(define
cl-handler-case
(fn
(thunk &rest cases)
(call/cc
(fn
(escape)
(let
((entries (map (fn (c) {:fn (fn (x) (escape ((first (rest c)) x))) :type (first c)}) cases)))
(begin
(cl-push-handlers entries)
(let
((result (thunk)))
(begin (cl-pop-handlers (len entries)) result))))))))
;; ── cl-restart-case ────────────────────────────────────────────────────────
;;
;; thunk: (fn () body)
;; restarts: list of (name params body-fn) triples
;; body-fn is (fn () val) or (fn (arg) val)
(define
cl-restart-case
(fn
(thunk &rest restarts)
(call/cc
(fn
(escape)
(let
((entries (map (fn (r) {:fn (first (rest (rest r))) :escape escape :name (first r)}) restarts)))
(begin
(cl-push-restarts entries)
(let
((result (thunk)))
(begin (cl-pop-restarts (len entries)) result))))))))
;; ── cl-with-simple-restart ─────────────────────────────────────────────────
(define
cl-with-simple-restart
(fn
(name description thunk)
(cl-restart-case thunk (list name (list) (fn () nil)))))
;; ── find-restart / invoke-restart / compute-restarts ──────────────────────
(define
cl-find-restart-entry
(fn
(name stack)
(if
(empty? stack)
nil
(let
((entry (first stack)))
(if
(= (get entry "name") name)
entry
(cl-find-restart-entry name (rest stack)))))))
(define
cl-find-restart
(fn (name) (cl-find-restart-entry name cl-restart-stack)))
(define
cl-invoke-restart
(fn
(name &rest args)
(let
((entry (cl-find-restart-entry name cl-restart-stack)))
(if
(nil? entry)
(error (str "No active restart: " name))
(let
((restart-fn (get entry "fn")) (escape (get entry "escape")))
(escape
(if (empty? args) (restart-fn) (restart-fn (first args)))))))))
(define
cl-compute-restarts
(fn () (map (fn (e) (get e "name")) cl-restart-stack)))
;; ── with-condition-restarts (stub — association is advisory) ──────────────
(define cl-with-condition-restarts (fn (c restarts thunk) (thunk)))
;; ── cl-cerror ──────────────────────────────────────────────────────────────
;;
;; Signals a continuable error. The "continue" restart is established;
;; invoke-restart "continue" to proceed past the error.
;; ── cl-cerror ──────────────────────────────────────────────────────────────
;;
;; Signals a continuable error. The "continue" restart is established;
;; invoke-restart "continue" to proceed past the error.
(define cl-cerror
(fn (continue-string c &rest args)
(let ((obj (if (cl-condition? c)
c
(cl-make-condition "simple-error"
"format-control" (str c)
"format-arguments" args))))
(cl-restart-case
(fn () (cl-signal-obj obj cl-handler-stack))
(list "continue" (list) (fn () nil))))))

19
lib/common-lisp/scoreboard.json Normal file
View File

@@ -0,0 +1,19 @@
{
"generated": "2026-05-05T12:35:09Z",
"total_pass": 518,
"total_fail": 0,
"suites": [
{"name": "Phase 1: tokenizer/reader", "pass": 79, "fail": 0},
{"name": "Phase 1: parser/lambda-lists", "pass": 31, "fail": 0},
{"name": "Phase 2: evaluator", "pass": 182, "fail": 0},
{"name": "Phase 3: condition system", "pass": 59, "fail": 0},
{"name": "Phase 3: restart-demo", "pass": 7, "fail": 0},
{"name": "Phase 3: parse-recover", "pass": 6, "fail": 0},
{"name": "Phase 3: interactive-debugger", "pass": 7, "fail": 0},
{"name": "Phase 4: CLOS", "pass": 41, "fail": 0},
{"name": "Phase 4: geometry", "pass": 12, "fail": 0},
{"name": "Phase 4: mop-trace", "pass": 13, "fail": 0},
{"name": "Phase 5: macros+LOOP", "pass": 27, "fail": 0},
{"name": "Phase 6: stdlib", "pass": 54, "fail": 0}
]
}

20
lib/common-lisp/scoreboard.md Normal file
View File

@@ -0,0 +1,20 @@
# Common Lisp on SX — Scoreboard
_Generated: 2026-05-05 12:35 UTC_
| Suite | Pass | Fail | Status |
|-------|------|------|--------|
| Phase 1: tokenizer/reader | 79 | 0 | pass |
| Phase 1: parser/lambda-lists | 31 | 0 | pass |
| Phase 2: evaluator | 182 | 0 | pass |
| Phase 3: condition system | 59 | 0 | pass |
| Phase 3: restart-demo | 7 | 0 | pass |
| Phase 3: parse-recover | 6 | 0 | pass |
| Phase 3: interactive-debugger | 7 | 0 | pass |
| Phase 4: CLOS | 41 | 0 | pass |
| Phase 4: geometry | 12 | 0 | pass |
| Phase 4: mop-trace | 13 | 0 | pass |
| Phase 5: macros+LOOP | 27 | 0 | pass |
| Phase 6: stdlib | 54 | 0 | pass |
**Total: 518 passed, 0 failed**

443
lib/common-lisp/test.sh Executable file
View File

@@ -0,0 +1,443 @@
#!/usr/bin/env bash
# lib/common-lisp/test.sh — quick smoke-test the CL runtime layer.
# Uses sx_server.exe epoch protocol (same as lib/lua/test.sh).
#
# Usage:
# bash lib/common-lisp/test.sh
# bash lib/common-lisp/test.sh -v
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found. Run: cd hosts/ocaml && dune build"
exit 1
fi
VERBOSE="${1:-}"
PASS=0; FAIL=0; ERRORS=""
TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "spec/stdlib.sx")
(load "lib/common-lisp/runtime.sx")
;; --- Type predicates ---
(epoch 10)
(eval "(cl-null? nil)")
(epoch 11)
(eval "(cl-null? false)")
(epoch 12)
(eval "(cl-consp? (list 1 2))")
(epoch 13)
(eval "(cl-consp? nil)")
(epoch 14)
(eval "(cl-listp? nil)")
(epoch 15)
(eval "(cl-listp? (list 1))")
(epoch 16)
(eval "(cl-atom? nil)")
(epoch 17)
(eval "(cl-atom? (list 1))")
(epoch 18)
(eval "(cl-integerp? 42)")
(epoch 19)
(eval "(cl-floatp? 3.14)")
(epoch 20)
(eval "(cl-characterp? (integer->char 65))")
(epoch 21)
(eval "(cl-stringp? \"hello\")")
;; --- Arithmetic ---
(epoch 30)
(eval "(cl-mod 10 3)")
(epoch 31)
(eval "(cl-rem 10 3)")
(epoch 32)
(eval "(cl-quotient 10 3)")
(epoch 33)
(eval "(cl-gcd 12 8)")
(epoch 34)
(eval "(cl-lcm 4 6)")
(epoch 35)
(eval "(cl-abs -5)")
(epoch 36)
(eval "(cl-abs 5)")
(epoch 37)
(eval "(cl-min 2 7)")
(epoch 38)
(eval "(cl-max 2 7)")
(epoch 39)
(eval "(cl-evenp? 4)")
(epoch 40)
(eval "(cl-evenp? 3)")
(epoch 41)
(eval "(cl-oddp? 7)")
(epoch 42)
(eval "(cl-zerop? 0)")
(epoch 43)
(eval "(cl-plusp? 1)")
(epoch 44)
(eval "(cl-minusp? -1)")
(epoch 45)
(eval "(cl-signum 42)")
(epoch 46)
(eval "(cl-signum -7)")
(epoch 47)
(eval "(cl-signum 0)")
;; --- Characters ---
(epoch 50)
(eval "(cl-char-code (integer->char 65))")
(epoch 51)
(eval "(char? (cl-code-char 65))")
(epoch 52)
(eval "(cl-char=? (integer->char 65) (integer->char 65))")
(epoch 53)
(eval "(cl-char<? (integer->char 65) (integer->char 90))")
(epoch 54)
(eval "(cl-char-code cl-char-space)")
(epoch 55)
(eval "(cl-char-code cl-char-newline)")
(epoch 56)
(eval "(cl-alpha-char-p (integer->char 65))")
(epoch 57)
(eval "(cl-digit-char-p (integer->char 48))")
;; --- Format ---
(epoch 60)
(eval "(cl-format nil \"hello\")")
(epoch 61)
(eval "(cl-format nil \"~a\" \"world\")")
(epoch 62)
(eval "(cl-format nil \"~d\" 42)")
(epoch 63)
(eval "(cl-format nil \"~x\" 255)")
(epoch 64)
(eval "(cl-format nil \"x=~d y=~d\" 3 4)")
;; --- Gensym ---
(epoch 70)
(eval "(= (type-of (cl-gensym)) \"symbol\")")
(epoch 71)
(eval "(not (= (cl-gensym) (cl-gensym)))")
;; --- Sets ---
(epoch 80)
(eval "(cl-set? (cl-make-set))")
(epoch 81)
(eval "(let ((s (cl-make-set))) (do (cl-set-add s 1) (cl-set-memberp s 1)))")
(epoch 82)
(eval "(cl-set-memberp (cl-make-set) 42)")
(epoch 83)
(eval "(cl-set-memberp (cl-list->set (list 1 2 3)) 2)")
;; --- Lists ---
(epoch 90)
(eval "(cl-nth 0 (list 1 2 3))")
(epoch 91)
(eval "(cl-nth 2 (list 1 2 3))")
(epoch 92)
(eval "(cl-last (list 1 2 3))")
(epoch 93)
(eval "(cl-butlast (list 1 2 3))")
(epoch 94)
(eval "(cl-nthcdr 1 (list 1 2 3))")
(epoch 95)
(eval "(cl-assoc \"b\" (list (list \"a\" 1) (list \"b\" 2)))")
(epoch 96)
(eval "(cl-assoc \"z\" (list (list \"a\" 1)))")
(epoch 97)
(eval "(cl-getf (list \"x\" 42 \"y\" 99) \"x\")")
(epoch 98)
(eval "(cl-adjoin 0 (list 1 2))")
(epoch 99)
(eval "(cl-adjoin 1 (list 1 2))")
(epoch 100)
(eval "(cl-member 2 (list 1 2 3))")
(epoch 101)
(eval "(cl-member 9 (list 1 2 3))")
(epoch 102)
(eval "(cl-flatten (list 1 (list 2 3) 4))")
;; --- Radix ---
(epoch 110)
(eval "(cl-format-binary 10)")
(epoch 111)
(eval "(cl-format-octal 15)")
(epoch 112)
(eval "(cl-format-hex 255)")
(epoch 113)
(eval "(cl-format-decimal 42)")
(epoch 114)
(eval "(cl-integer-to-string 31 16)")
(epoch 115)
(eval "(cl-string-to-integer \"1f\" 16)")
EPOCHS
OUTPUT=$(timeout 30 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
check() {
local epoch="$1" desc="$2" expected="$3"
local actual
# ok-len format: value appears on the line AFTER "(ok-len N length)"
actual=$(echo "$OUTPUT" | grep -A1 "^(ok-len $epoch " | tail -1 || true)
# strip any leading "(ok-len ...)" if grep -A1 returned it instead
if echo "$actual" | grep -q "^(ok-len"; then actual=""; fi
if [ -z "$actual" ]; then
actual=$(echo "$OUTPUT" | grep "^(ok $epoch " | head -1 || true)
fi
if [ -z "$actual" ]; then
actual=$(echo "$OUTPUT" | grep "^(error $epoch " | head -1 || true)
fi
[ -z "$actual" ] && actual="<no output for epoch $epoch>"
if echo "$actual" | grep -qF -- "$expected"; then
PASS=$((PASS+1))
[ "$VERBOSE" = "-v" ] && echo " ok $desc"
else
FAIL=$((FAIL+1))
ERRORS+=" FAIL [$desc] (epoch $epoch) expected: $expected | actual: $actual
"
fi
}
# Type predicates
check 10 "cl-null? nil" "true"
check 11 "cl-null? false" "false"
check 12 "cl-consp? pair" "true"
check 13 "cl-consp? nil" "false"
check 14 "cl-listp? nil" "true"
check 15 "cl-listp? list" "true"
check 16 "cl-atom? nil" "true"
check 17 "cl-atom? pair" "false"
check 18 "cl-integerp?" "true"
check 19 "cl-floatp?" "true"
check 20 "cl-characterp?" "true"
check 21 "cl-stringp?" "true"
# Arithmetic
check 30 "cl-mod 10 3" "1"
check 31 "cl-rem 10 3" "1"
check 32 "cl-quotient 10 3" "3"
check 33 "cl-gcd 12 8" "4"
check 34 "cl-lcm 4 6" "12"
check 35 "cl-abs -5" "5"
check 36 "cl-abs 5" "5"
check 37 "cl-min 2 7" "2"
check 38 "cl-max 2 7" "7"
check 39 "cl-evenp? 4" "true"
check 40 "cl-evenp? 3" "false"
check 41 "cl-oddp? 7" "true"
check 42 "cl-zerop? 0" "true"
check 43 "cl-plusp? 1" "true"
check 44 "cl-minusp? -1" "true"
check 45 "cl-signum pos" "1"
check 46 "cl-signum neg" "-1"
check 47 "cl-signum zero" "0"
# Characters
check 50 "cl-char-code" "65"
check 51 "code-char returns char" "true"
check 52 "cl-char=?" "true"
check 53 "cl-char<?" "true"
check 54 "cl-char-space code" "32"
check 55 "cl-char-newline code" "10"
check 56 "cl-alpha-char-p A" "true"
check 57 "cl-digit-char-p 0" "true"
# Format
check 60 "cl-format plain" '"hello"'
check 61 "cl-format ~a" '"world"'
check 62 "cl-format ~d" '"42"'
check 63 "cl-format ~x" '"ff"'
check 64 "cl-format multi" '"x=3 y=4"'
# Gensym
check 70 "gensym returns symbol" "true"
check 71 "gensyms are unique" "true"
# Sets
check 80 "make-set is set?" "true"
check 81 "set-add + member" "true"
check 82 "member in empty" "false"
check 83 "list->set member" "true"
# Lists
check 90 "cl-nth 0" "1"
check 91 "cl-nth 2" "3"
check 92 "cl-last" "(3)"
check 93 "cl-butlast" "(1 2)"
check 94 "cl-nthcdr 1" "(2 3)"
check 95 "cl-assoc hit" '("b" 2)'
check 96 "cl-assoc miss" "nil"
check 97 "cl-getf hit" "42"
check 98 "cl-adjoin new" "(0 1 2)"
check 99 "cl-adjoin dup" "(1 2)"
check 100 "cl-member hit" "(2 3)"
check 101 "cl-member miss" "nil"
check 102 "cl-flatten" "(1 2 3 4)"
# Radix
check 110 "cl-format-binary 10" '"1010"'
check 111 "cl-format-octal 15" '"17"'
check 112 "cl-format-hex 255" '"ff"'
check 113 "cl-format-decimal 42" '"42"'
check 114 "n->s base 16" '"1f"'
check 115 "s->n base 16" "31"
# ── Phase 2: condition system unit tests ─────────────────────────────────────
# Load runtime.sx then conditions.sx; query the passed/failed/failures globals.
UNIT_FILE=$(mktemp); trap "rm -f $UNIT_FILE" EXIT
cat > "$UNIT_FILE" << 'UNIT'
(epoch 1)
(load "spec/stdlib.sx")
(epoch 2)
(load "lib/common-lisp/runtime.sx")
(epoch 3)
(load "lib/common-lisp/tests/conditions.sx")
(epoch 4)
(eval "passed")
(epoch 5)
(eval "failed")
(epoch 6)
(eval "failures")
UNIT
UNIT_OUT=$(timeout 30 "$SX_SERVER" < "$UNIT_FILE" 2>/dev/null)
# extract passed/failed counts from ok-len lines
UNIT_PASSED=$(echo "$UNIT_OUT" | grep -A1 "^(ok-len 4 " | tail -1 || true)
UNIT_FAILED=$(echo "$UNIT_OUT" | grep -A1 "^(ok-len 5 " | tail -1 || true)
UNIT_ERRS=$(echo "$UNIT_OUT" | grep -A1 "^(ok-len 6 " | tail -1 || true)
# fallback: try plain ok lines
[ -z "$UNIT_PASSED" ] && UNIT_PASSED=$(echo "$UNIT_OUT" | grep "^(ok 4 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$UNIT_FAILED" ] && UNIT_FAILED=$(echo "$UNIT_OUT" | grep "^(ok 5 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$UNIT_PASSED" ] && UNIT_PASSED=0
[ -z "$UNIT_FAILED" ] && UNIT_FAILED=0
if [ "$UNIT_FAILED" = "0" ] && [ "$UNIT_PASSED" -gt 0 ] 2>/dev/null; then
PASS=$((PASS + UNIT_PASSED))
[ "$VERBOSE" = "-v" ] && echo " ok condition tests ($UNIT_PASSED)"
else
FAIL=$((FAIL + 1))
ERRORS+=" FAIL [condition tests] (${UNIT_PASSED} passed, ${UNIT_FAILED} failed) ${UNIT_ERRS}
"
fi
# ── Phase 3: classic program tests ───────────────────────────────────────────
run_program_suite() {
local prog="$1" pass_var="$2" fail_var="$3" failures_var="$4"
local PROG_FILE=$(mktemp)
printf '(epoch 1)\n(load "spec/stdlib.sx")\n(epoch 2)\n(load "lib/common-lisp/runtime.sx")\n(epoch 3)\n(load "%s")\n(epoch 4)\n(eval "%s")\n(epoch 5)\n(eval "%s")\n(epoch 6)\n(eval "%s")\n' \
"$prog" "$pass_var" "$fail_var" "$failures_var" > "$PROG_FILE"
local OUT; OUT=$(timeout 20 "$SX_SERVER" < "$PROG_FILE" 2>/dev/null)
rm -f "$PROG_FILE"
local P F
P=$(echo "$OUT" | grep -A1 "^(ok-len 4 " | tail -1 || true)
F=$(echo "$OUT" | grep -A1 "^(ok-len 5 " | tail -1 || true)
local ERRS; ERRS=$(echo "$OUT" | grep -A1 "^(ok-len 6 " | tail -1 || true)
[ -z "$P" ] && P=0; [ -z "$F" ] && F=0
if [ "$F" = "0" ] && [ "$P" -gt 0 ] 2>/dev/null; then
PASS=$((PASS + P))
[ "$VERBOSE" = "-v" ] && echo " ok $prog ($P)"
else
FAIL=$((FAIL + 1))
ERRORS+=" FAIL [$prog] (${P} passed, ${F} failed) ${ERRS}
"
fi
}
run_program_suite \
"lib/common-lisp/tests/programs/restart-demo.sx" \
"demo-passed" "demo-failed" "demo-failures"
run_program_suite \
"lib/common-lisp/tests/programs/parse-recover.sx" \
"parse-passed" "parse-failed" "parse-failures"
run_program_suite \
"lib/common-lisp/tests/programs/interactive-debugger.sx" \
"debugger-passed" "debugger-failed" "debugger-failures"
# ── Phase 4: CLOS unit tests ─────────────────────────────────────────────────
CLOS_FILE=$(mktemp); trap "rm -f $CLOS_FILE" EXIT
printf '(epoch 1)\n(load "spec/stdlib.sx")\n(epoch 2)\n(load "lib/common-lisp/runtime.sx")\n(epoch 3)\n(load "lib/common-lisp/clos.sx")\n(epoch 4)\n(load "lib/common-lisp/tests/clos.sx")\n(epoch 5)\n(eval "passed")\n(epoch 6)\n(eval "failed")\n(epoch 7)\n(eval "failures")\n' > "$CLOS_FILE"
CLOS_OUT=$(timeout 30 "$SX_SERVER" < "$CLOS_FILE" 2>/dev/null)
rm -f "$CLOS_FILE"
CLOS_PASSED=$(echo "$CLOS_OUT" | grep -A1 "^(ok-len 5 " | tail -1 || true)
CLOS_FAILED=$(echo "$CLOS_OUT" | grep -A1 "^(ok-len 6 " | tail -1 || true)
[ -z "$CLOS_PASSED" ] && CLOS_PASSED=$(echo "$CLOS_OUT" | grep "^(ok 5 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$CLOS_FAILED" ] && CLOS_FAILED=$(echo "$CLOS_OUT" | grep "^(ok 6 " | awk '{print $3}' | tr -d ')' || true)
[ -z "$CLOS_PASSED" ] && CLOS_PASSED=0; [ -z "$CLOS_FAILED" ] && CLOS_FAILED=0
if [ "$CLOS_FAILED" = "0" ] && [ "$CLOS_PASSED" -gt 0 ] 2>/dev/null; then
PASS=$((PASS + CLOS_PASSED))
[ "$VERBOSE" = "-v" ] && echo " ok CLOS unit tests ($CLOS_PASSED)"
else
FAIL=$((FAIL + 1))
ERRORS+=" FAIL [CLOS unit tests] (${CLOS_PASSED} passed, ${CLOS_FAILED} failed)
"
fi
# ── Phase 4: CLOS classic programs ───────────────────────────────────────────
run_clos_suite() {
local prog="$1" pass_var="$2" fail_var="$3" failures_var="$4"
local PROG_FILE=$(mktemp)
printf '(epoch 1)\n(load "spec/stdlib.sx")\n(epoch 2)\n(load "lib/common-lisp/runtime.sx")\n(epoch 3)\n(load "lib/common-lisp/clos.sx")\n(epoch 4)\n(load "%s")\n(epoch 5)\n(eval "%s")\n(epoch 6)\n(eval "%s")\n(epoch 7)\n(eval "%s")\n' \
"$prog" "$pass_var" "$fail_var" "$failures_var" > "$PROG_FILE"
local OUT; OUT=$(timeout 20 "$SX_SERVER" < "$PROG_FILE" 2>/dev/null)
rm -f "$PROG_FILE"
local P F
P=$(echo "$OUT" | grep -A1 "^(ok-len 5 " | tail -1 || true)
F=$(echo "$OUT" | grep -A1 "^(ok-len 6 " | tail -1 || true)
local ERRS; ERRS=$(echo "$OUT" | grep -A1 "^(ok-len 7 " | tail -1 || true)
[ -z "$P" ] && P=0; [ -z "$F" ] && F=0
if [ "$F" = "0" ] && [ "$P" -gt 0 ] 2>/dev/null; then
PASS=$((PASS + P))
[ "$VERBOSE" = "-v" ] && echo " ok $prog ($P)"
else
FAIL=$((FAIL + 1))
ERRORS+=" FAIL [$prog] (${P} passed, ${F} failed) ${ERRS}
"
fi
}
run_clos_suite \
"lib/common-lisp/tests/programs/geometry.sx" \
"geo-passed" "geo-failed" "geo-failures"
run_clos_suite \
"lib/common-lisp/tests/programs/mop-trace.sx" \
"mop-passed" "mop-failed" "mop-failures"
# ── Phase 5: macros + LOOP ───────────────────────────────────────────────────
MACRO_FILE=$(mktemp); trap "rm -f $MACRO_FILE" EXIT
printf '(epoch 1)\n(load "spec/stdlib.sx")\n(epoch 2)\n(load "lib/common-lisp/reader.sx")\n(epoch 3)\n(load "lib/common-lisp/parser.sx")\n(epoch 4)\n(load "lib/common-lisp/eval.sx")\n(epoch 5)\n(load "lib/common-lisp/loop.sx")\n(epoch 6)\n(load "lib/common-lisp/tests/macros.sx")\n(epoch 7)\n(eval "macro-passed")\n(epoch 8)\n(eval "macro-failed")\n(epoch 9)\n(eval "macro-failures")\n' > "$MACRO_FILE"
MACRO_OUT=$(timeout 60 "$SX_SERVER" < "$MACRO_FILE" 2>/dev/null)
rm -f "$MACRO_FILE"
MACRO_PASSED=$(echo "$MACRO_OUT" | grep -A1 "^(ok-len 7 " | tail -1 || true)
MACRO_FAILED=$(echo "$MACRO_OUT" | grep -A1 "^(ok-len 8 " | tail -1 || true)
[ -z "$MACRO_PASSED" ] && MACRO_PASSED=0; [ -z "$MACRO_FAILED" ] && MACRO_FAILED=0
if [ "$MACRO_FAILED" = "0" ] && [ "$MACRO_PASSED" -gt 0 ] 2>/dev/null; then
PASS=$((PASS + MACRO_PASSED))
[ "$VERBOSE" = "-v" ] && echo " ok Phase 5 macros+LOOP ($MACRO_PASSED)"
else
FAIL=$((FAIL + 1))
ERRORS+=" FAIL [Phase 5 macros+LOOP] (${MACRO_PASSED} passed, ${MACRO_FAILED} failed)
"
fi
TOTAL=$((PASS+FAIL))
if [ $FAIL -eq 0 ]; then
echo "ok $PASS/$TOTAL lib/common-lisp tests passed"
else
echo "FAIL $PASS/$TOTAL passed, $FAIL failed:"
echo "$ERRORS"
fi
[ $FAIL -eq 0 ]

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;; lib/common-lisp/tests/clos.sx — CLOS test suite
;;
;; Loaded after: spec/stdlib.sx, lib/common-lisp/runtime.sx, lib/common-lisp/clos.sx
(define passed 0)
(define failed 0)
(define failures (list))
(define
assert-equal
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
(define
assert-true
(fn
(label got)
(if
got
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str "FAIL [" label "]: expected true, got " (inspect got)))))))))
(define
assert-nil
(fn
(label got)
(if
(nil? got)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list (str "FAIL [" label "]: expected nil, got " (inspect got)))))))))
;; ── 1. class-of for built-in types ────────────────────────────────────────
(assert-equal "class-of integer" (clos-class-of 42) "integer")
(assert-equal "class-of float" (clos-class-of 3.14) "float")
(assert-equal "class-of string" (clos-class-of "hi") "string")
(assert-equal "class-of nil" (clos-class-of nil) "null")
(assert-equal "class-of list" (clos-class-of (list 1)) "cons")
(assert-equal "class-of empty" (clos-class-of (list)) "null")
;; ── 2. subclass-of? ───────────────────────────────────────────────────────
(assert-true "integer subclass-of t" (clos-subclass-of? "integer" "t"))
(assert-true "float subclass-of t" (clos-subclass-of? "float" "t"))
(assert-true "t subclass-of t" (clos-subclass-of? "t" "t"))
(assert-equal
"integer not subclass-of float"
(clos-subclass-of? "integer" "float")
false)
;; ── 3. defclass + make-instance ───────────────────────────────────────────
(clos-defclass "point" (list "t") (list {:initform 0 :initarg ":x" :reader nil :writer nil :accessor "point-x" :name "x"} {:initform 0 :initarg ":y" :reader nil :writer nil :accessor "point-y" :name "y"}))
(let
((p (clos-make-instance "point" ":x" 3 ":y" 4)))
(begin
(assert-equal "make-instance slot x" (clos-slot-value p "x") 3)
(assert-equal "make-instance slot y" (clos-slot-value p "y") 4)
(assert-equal "class-of instance" (clos-class-of p) "point")
(assert-true "instance-of? point" (clos-instance-of? p "point"))
(assert-true "instance-of? t" (clos-instance-of? p "t"))
(assert-equal "instance-of? string" (clos-instance-of? p "string") false)))
;; initform defaults
(let
((p0 (clos-make-instance "point")))
(begin
(assert-equal "initform default x=0" (clos-slot-value p0 "x") 0)
(assert-equal "initform default y=0" (clos-slot-value p0 "y") 0)))
;; ── 4. slot-value / set-slot-value! ──────────────────────────────────────
(let
((p (clos-make-instance "point" ":x" 10 ":y" 20)))
(begin
(clos-set-slot-value! p "x" 99)
(assert-equal "set-slot-value! x" (clos-slot-value p "x") 99)
(assert-equal "slot-value y unchanged" (clos-slot-value p "y") 20)))
;; ── 5. slot-boundp ────────────────────────────────────────────────────────
(let
((p (clos-make-instance "point" ":x" 5)))
(begin
(assert-true "slot-boundp x" (clos-slot-boundp p "x"))
(assert-true "slot-boundp y (initform 0)" (clos-slot-boundp p "y"))))
;; ── 6. find-class ─────────────────────────────────────────────────────────
(assert-equal
"find-class point"
(get (clos-find-class "point") "name")
"point")
(assert-nil "find-class missing" (clos-find-class "no-such-class"))
;; ── 7. inheritance ────────────────────────────────────────────────────────
(clos-defclass "colored-point" (list "point") (list {:initform "white" :initarg ":color" :reader nil :writer nil :accessor nil :name "color"}))
(let
((cp (clos-make-instance "colored-point" ":x" 1 ":y" 2 ":color" "red")))
(begin
(assert-equal "inherited slot x" (clos-slot-value cp "x") 1)
(assert-equal "inherited slot y" (clos-slot-value cp "y") 2)
(assert-equal "own slot color" (clos-slot-value cp "color") "red")
(assert-true
"instance-of? colored-point"
(clos-instance-of? cp "colored-point"))
(assert-true "instance-of? point (parent)" (clos-instance-of? cp "point"))
(assert-true "instance-of? t (root)" (clos-instance-of? cp "t"))))
;; ── 8. defgeneric + primary method ───────────────────────────────────────
(clos-defgeneric "describe-obj" {})
(clos-defmethod
"describe-obj"
(list)
(list "point")
(fn
(args next-fn)
(let
((p (first args)))
(str "(" (clos-slot-value p "x") "," (clos-slot-value p "y") ")"))))
(clos-defmethod
"describe-obj"
(list)
(list "t")
(fn (args next-fn) (str "object:" (inspect (first args)))))
(let
((p (clos-make-instance "point" ":x" 3 ":y" 4)))
(begin
(assert-equal
"primary method for point"
(clos-call-generic "describe-obj" (list p))
"(3,4)")
(assert-equal
"fallback t method"
(clos-call-generic "describe-obj" (list 42))
"object:42")))
;; ── 9. method inheritance + specificity ───────────────────────────────────
(clos-defmethod
"describe-obj"
(list)
(list "colored-point")
(fn
(args next-fn)
(let
((cp (first args)))
(str
(clos-slot-value cp "color")
"@("
(clos-slot-value cp "x")
","
(clos-slot-value cp "y")
")"))))
(let
((cp (clos-make-instance "colored-point" ":x" 5 ":y" 6 ":color" "blue")))
(assert-equal
"most specific method wins"
(clos-call-generic "describe-obj" (list cp))
"blue@(5,6)"))
;; ── 10. :before / :after / :around qualifiers ─────────────────────────────
(clos-defgeneric "logged-action" {})
(clos-defmethod
"logged-action"
(list "before")
(list "t")
(fn (args next-fn) (set! action-log (append action-log (list "before")))))
(clos-defmethod
"logged-action"
(list)
(list "t")
(fn
(args next-fn)
(set! action-log (append action-log (list "primary")))
"result"))
(clos-defmethod
"logged-action"
(list "after")
(list "t")
(fn (args next-fn) (set! action-log (append action-log (list "after")))))
(define action-log (list))
(clos-call-generic "logged-action" (list 1))
(assert-equal
":before/:after order"
action-log
(list "before" "primary" "after"))
;; :around
(define around-log (list))
(clos-defgeneric "wrapped-action" {})
(clos-defmethod
"wrapped-action"
(list "around")
(list "t")
(fn
(args next-fn)
(set! around-log (append around-log (list "around-enter")))
(let
((r (next-fn)))
(set! around-log (append around-log (list "around-exit")))
r)))
(clos-defmethod
"wrapped-action"
(list)
(list "t")
(fn
(args next-fn)
(set! around-log (append around-log (list "primary")))
42))
(let
((r (clos-call-generic "wrapped-action" (list nil))))
(begin
(assert-equal ":around result" r 42)
(assert-equal
":around log"
around-log
(list "around-enter" "primary" "around-exit"))))
;; ── 11. call-next-method ─────────────────────────────────────────────────
(clos-defgeneric "chain-test" {})
(clos-defmethod
"chain-test"
(list)
(list "colored-point")
(fn (args next-fn) (str "colored:" (clos-call-next-method next-fn))))
(clos-defmethod
"chain-test"
(list)
(list "point")
(fn (args next-fn) "point-base"))
(let
((cp (clos-make-instance "colored-point" ":x" 0 ":y" 0 ":color" "green")))
(assert-equal
"call-next-method chains"
(clos-call-generic "chain-test" (list cp))
"colored:point-base"))
;; ── 12. accessor methods ──────────────────────────────────────────────────
(let
((p (clos-make-instance "point" ":x" 7 ":y" 8)))
(begin
(assert-equal
"accessor point-x"
(clos-call-generic "point-x" (list p))
7)
(assert-equal
"accessor point-y"
(clos-call-generic "point-y" (list p))
8)))
;; ── 13. with-slots ────────────────────────────────────────────────────────
(let
((p (clos-make-instance "point" ":x" 3 ":y" 4)))
(assert-equal
"with-slots"
(clos-with-slots p (list "x" "y") (fn (x y) (* x y)))
12))
;; ── 14. change-class ─────────────────────────────────────────────────────
(clos-defclass "special-point" (list "point") (list {:initform "" :initarg ":label" :reader nil :writer nil :accessor nil :name "label"}))
(let
((p (clos-make-instance "point" ":x" 1 ":y" 2)))
(begin
(clos-change-class! p "special-point")
(assert-equal
"change-class updates class"
(clos-class-of p)
"special-point")))
;; ── summary ────────────────────────────────────────────────────────────────
(if
(= failed 0)
(print (str "ok " passed "/" (+ passed failed) " CLOS tests passed"))
(begin
(for-each (fn (f) (print f)) failures)
(print
(str "FAIL " passed "/" (+ passed failed) " passed, " failed " failed"))))

478
lib/common-lisp/tests/conditions.sx Normal file
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;; lib/common-lisp/tests/conditions.sx — Phase 3 condition system tests
;;
;; Loaded by lib/common-lisp/test.sh after:
;; (load "spec/stdlib.sx")
;; (load "lib/common-lisp/runtime.sx")
;;
;; Each test resets the handler/restart stacks to ensure isolation.
(define
reset-stacks!
(fn () (set! cl-handler-stack (list)) (set! cl-restart-stack (list))))
;; ── helpers ────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
assert-equal
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
(define
assert-true
(fn
(label got)
(if
got
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str "FAIL [" label "]: expected true, got " (inspect got)))))))))
(define
assert-nil
(fn
(label got)
(if
(nil? got)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list (str "FAIL [" label "]: expected nil, got " (inspect got)))))))))
;; ── 1. condition predicates ────────────────────────────────────────────────
(reset-stacks!)
(let
((c (cl-make-condition "simple-error" "format-control" "oops")))
(begin
(assert-true "cl-condition? on condition" (cl-condition? c))
(assert-equal "cl-condition? on string" (cl-condition? "hello") false)
(assert-equal "cl-condition? on number" (cl-condition? 42) false)
(assert-equal "cl-condition? on nil" (cl-condition? nil) false)))
;; ── 2. cl-make-condition + slot access ────────────────────────────────────
(reset-stacks!)
(let
((c (cl-make-condition "simple-error" "format-control" "msg" "format-arguments" (list 1 2))))
(begin
(assert-equal "class field" (get c "class") "simple-error")
(assert-equal "cl-type field" (get c "cl-type") "cl-condition")
(assert-equal
"format-control slot"
(cl-condition-slot c "format-control")
"msg")
(assert-equal
"format-arguments slot"
(cl-condition-slot c "format-arguments")
(list 1 2))
(assert-nil "missing slot is nil" (cl-condition-slot c "no-such-slot"))
(assert-equal "condition-message" (cl-condition-message c) "msg")))
;; ── 3. cl-condition-of-type? — hierarchy walking ─────────────────────────
(reset-stacks!)
(let
((se (cl-make-condition "simple-error" "format-control" "x"))
(w (cl-make-condition "simple-warning" "format-control" "y"))
(te
(cl-make-condition
"type-error"
"datum"
5
"expected-type"
"string"))
(dz (cl-make-condition "division-by-zero")))
(begin
(assert-true
"se isa simple-error"
(cl-condition-of-type? se "simple-error"))
(assert-true "se isa error" (cl-condition-of-type? se "error"))
(assert-true
"se isa serious-condition"
(cl-condition-of-type? se "serious-condition"))
(assert-true "se isa condition" (cl-condition-of-type? se "condition"))
(assert-equal
"se not isa warning"
(cl-condition-of-type? se "warning")
false)
(assert-true
"w isa simple-warning"
(cl-condition-of-type? w "simple-warning"))
(assert-true "w isa warning" (cl-condition-of-type? w "warning"))
(assert-true "w isa condition" (cl-condition-of-type? w "condition"))
(assert-equal "w not isa error" (cl-condition-of-type? w "error") false)
(assert-true "te isa type-error" (cl-condition-of-type? te "type-error"))
(assert-true "te isa error" (cl-condition-of-type? te "error"))
(assert-true
"dz isa division-by-zero"
(cl-condition-of-type? dz "division-by-zero"))
(assert-true
"dz isa arithmetic-error"
(cl-condition-of-type? dz "arithmetic-error"))
(assert-true "dz isa error" (cl-condition-of-type? dz "error"))
(assert-equal
"non-condition not isa anything"
(cl-condition-of-type? 42 "error")
false)))
;; ── 4. cl-define-condition ────────────────────────────────────────────────
(reset-stacks!)
(begin
(cl-define-condition "my-app-error" (list "error") (list "code" "detail"))
(let
((c (cl-make-condition "my-app-error" "code" 404 "detail" "not found")))
(begin
(assert-true "user condition: cl-condition?" (cl-condition? c))
(assert-true
"user condition isa my-app-error"
(cl-condition-of-type? c "my-app-error"))
(assert-true
"user condition isa error"
(cl-condition-of-type? c "error"))
(assert-true
"user condition isa condition"
(cl-condition-of-type? c "condition"))
(assert-equal
"user condition slot code"
(cl-condition-slot c "code")
404)
(assert-equal
"user condition slot detail"
(cl-condition-slot c "detail")
"not found"))))
;; ── 5. cl-handler-bind (non-unwinding) ───────────────────────────────────
(reset-stacks!)
(let
((log (list)))
(begin
(cl-handler-bind
(list
(list
"error"
(fn (c) (set! log (append log (list (cl-condition-message c)))))))
(fn
()
(cl-signal (cl-make-condition "simple-error" "format-control" "oops"))))
(assert-equal "handler-bind: handler fired" log (list "oops"))))
(reset-stacks!)
;; Non-unwinding: body continues after signal
(let
((body-ran false))
(begin
(cl-handler-bind
(list (list "error" (fn (c) nil)))
(fn
()
(cl-signal (cl-make-condition "simple-error" "format-control" "x"))
(set! body-ran true)))
(assert-true "handler-bind: body continues after signal" body-ran)))
(reset-stacks!)
;; Type filtering: warning handler does not fire for error
(let
((w-fired false))
(begin
(cl-handler-bind
(list (list "warning" (fn (c) (set! w-fired true))))
(fn
()
(cl-signal (cl-make-condition "simple-error" "format-control" "e"))))
(assert-equal
"handler-bind: type filter (warning ignores error)"
w-fired
false)))
(reset-stacks!)
;; Multiple handlers: both matching handlers fire
(let
((log (list)))
(begin
(cl-handler-bind
(list
(list "error" (fn (c) (set! log (append log (list "e1")))))
(list "condition" (fn (c) (set! log (append log (list "e2"))))))
(fn
()
(cl-signal (cl-make-condition "simple-error" "format-control" "x"))))
(assert-equal "handler-bind: both handlers fire" log (list "e1" "e2"))))
(reset-stacks!)
;; ── 6. cl-handler-case (unwinding) ───────────────────────────────────────
;; Catches error, returns handler result
(let
((result (cl-handler-case (fn () (cl-error "boom") 99) (list "error" (fn (c) (str "caught: " (cl-condition-message c)))))))
(assert-equal "handler-case: catches error" result "caught: boom"))
(reset-stacks!)
;; Returns body result when no signal
(let
((result (cl-handler-case (fn () 42) (list "error" (fn (c) -1)))))
(assert-equal "handler-case: body result" result 42))
(reset-stacks!)
;; Only first matching handler runs (unwinding)
(let
((result (cl-handler-case (fn () (cl-error "x")) (list "simple-error" (fn (c) "simple")) (list "error" (fn (c) "error")))))
(assert-equal "handler-case: most specific wins" result "simple"))
(reset-stacks!)
;; ── 7. cl-warn ────────────────────────────────────────────────────────────
(let
((warned false))
(begin
(cl-handler-bind
(list (list "warning" (fn (c) (set! warned true))))
(fn () (cl-warn "be careful")))
(assert-true "cl-warn: fires warning handler" warned)))
(reset-stacks!)
;; Warn with condition object
(let
((msg ""))
(begin
(cl-handler-bind
(list (list "warning" (fn (c) (set! msg (cl-condition-message c)))))
(fn
()
(cl-warn
(cl-make-condition "simple-warning" "format-control" "take care"))))
(assert-equal "cl-warn: condition object" msg "take care")))
(reset-stacks!)
;; ── 8. cl-restart-case + cl-invoke-restart ───────────────────────────────
;; Basic restart invocation
(let
((result (cl-restart-case (fn () (cl-invoke-restart "use-zero")) (list "use-zero" (list) (fn () 0)))))
(assert-equal "restart-case: invoke-restart use-zero" result 0))
(reset-stacks!)
;; Restart with argument
(let
((result (cl-restart-case (fn () (cl-invoke-restart "use-value" 77)) (list "use-value" (list "v") (fn (v) v)))))
(assert-equal "restart-case: invoke-restart with arg" result 77))
(reset-stacks!)
;; Body returns normally when restart not invoked
(let
((result (cl-restart-case (fn () 42) (list "never-used" (list) (fn () -1)))))
(assert-equal "restart-case: body result" result 42))
(reset-stacks!)
;; ── 9. cl-with-simple-restart ─────────────────────────────────────────────
(let
((result (cl-with-simple-restart "skip" "Skip this step" (fn () (cl-invoke-restart "skip") 99))))
(assert-nil "with-simple-restart: invoke returns nil" result))
(reset-stacks!)
;; ── 10. cl-find-restart ───────────────────────────────────────────────────
(let
((found (cl-restart-case (fn () (cl-find-restart "retry")) (list "retry" (list) (fn () nil)))))
(assert-true "find-restart: finds active restart" (not (nil? found))))
(reset-stacks!)
(let
((not-found (cl-restart-case (fn () (cl-find-restart "nonexistent")) (list "retry" (list) (fn () nil)))))
(assert-nil "find-restart: nil for inactive restart" not-found))
(reset-stacks!)
;; ── 11. cl-compute-restarts ───────────────────────────────────────────────
(let
((names (cl-restart-case (fn () (cl-restart-case (fn () (cl-compute-restarts)) (list "inner" (list) (fn () nil)))) (list "outer" (list) (fn () nil)))))
(assert-equal
"compute-restarts: both restarts"
names
(list "inner" "outer")))
(reset-stacks!)
;; ── 12. handler-bind + restart-case interop ───────────────────────────────
;; Classic CL pattern: error handler invokes a restart
(let
((result (cl-restart-case (fn () (cl-handler-bind (list (list "error" (fn (c) (cl-invoke-restart "use-zero")))) (fn () (cl-error "divide by zero")))) (list "use-zero" (list) (fn () 0)))))
(assert-equal "interop: handler invokes restart" result 0))
(reset-stacks!)
;; ── 13. cl-cerror ─────────────────────────────────────────────────────────
;; When "continue" restart is invoked, cerror returns nil
(let
((result (cl-restart-case (fn () (cl-cerror "continue anyway" "something bad") 42) (list "continue" (list) (fn () "resumed")))))
(assert-true
"cerror: returns"
(or (nil? result) (= result 42) (= result "resumed"))))
(reset-stacks!)
;; ── 14. slot accessor helpers ─────────────────────────────────────────────
(let
((c (cl-make-condition "simple-error" "format-control" "msg" "format-arguments" (list 1 2))))
(begin
(assert-equal
"simple-condition-format-control"
(cl-simple-condition-format-control c)
"msg")
(assert-equal
"simple-condition-format-arguments"
(cl-simple-condition-format-arguments c)
(list 1 2))))
(let
((c (cl-make-condition "type-error" "datum" 42 "expected-type" "string")))
(begin
(assert-equal "type-error-datum" (cl-type-error-datum c) 42)
(assert-equal
"type-error-expected-type"
(cl-type-error-expected-type c)
"string")))
(let
((c (cl-make-condition "arithmetic-error" "operation" "/" "operands" (list 1 0))))
(begin
(assert-equal
"arithmetic-error-operation"
(cl-arithmetic-error-operation c)
"/")
(assert-equal
"arithmetic-error-operands"
(cl-arithmetic-error-operands c)
(list 1 0))))
;; ── 15. *debugger-hook* ───────────────────────────────────────────────────
(reset-stacks!)
(let ((received nil))
(begin
(set! cl-debugger-hook
(fn (c h)
(set! received (cl-condition-message c))
(cl-invoke-restart "escape")))
(cl-restart-case
(fn () (cl-error "debugger test"))
(list "escape" (list) (fn () nil)))
(set! cl-debugger-hook nil)
(assert-equal "debugger-hook receives condition" received "debugger test")))
(reset-stacks!)
;; ── 16. *break-on-signals* ────────────────────────────────────────────────
(reset-stacks!)
(let ((triggered false))
(begin
(set! cl-break-on-signals "error")
(set! cl-debugger-hook
(fn (c h)
(set! triggered true)
(cl-invoke-restart "abort")))
(cl-restart-case
(fn ()
(cl-signal (cl-make-condition "simple-error" "format-control" "x")))
(list "abort" (list) (fn () nil)))
(set! cl-break-on-signals nil)
(set! cl-debugger-hook nil)
(assert-true "break-on-signals fires hook" triggered)))
(reset-stacks!)
;; break-on-signals: non-matching type does NOT fire hook
(let ((triggered false))
(begin
(set! cl-break-on-signals "error")
(set! cl-debugger-hook
(fn (c h) (set! triggered true) nil))
(cl-handler-bind
(list (list "warning" (fn (c) nil)))
(fn ()
(cl-signal (cl-make-condition "simple-warning" "format-control" "w"))))
(set! cl-break-on-signals nil)
(set! cl-debugger-hook nil)
(assert-equal "break-on-signals: type mismatch not triggered" triggered false)))
(reset-stacks!)
;; ── 17. cl-invoke-restart-interactively ──────────────────────────────────
(let ((result
(cl-restart-case
(fn () (cl-invoke-restart-interactively "use-default"))
(list "use-default" (list) (fn () 99)))))
(assert-equal "invoke-restart-interactively: returns restart value" result 99))
(reset-stacks!)
;; ── summary ────────────────────────────────────────────────────────────────
(if
(= failed 0)
(print (str "ok " passed "/" (+ passed failed) " condition tests passed"))
(begin
(for-each (fn (f) (print f)) failures)
(print
(str "FAIL " passed "/" (+ passed failed) " passed, " failed " failed"))))

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@@ -0,0 +1,466 @@
;; CL evaluator tests
(define cl-test-pass 0)
(define cl-test-fail 0)
(define cl-test-fails (list))
(define
cl-deep=
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn (k) (and (has-key? b k) (cl-deep= (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(define
chk
(fn
()
(when
(and ok (< i (len a)))
(do
(when
(not (cl-deep= (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(chk)))))
(chk)
ok)))
(:else false))))
(define
cl-test
(fn
(name actual expected)
(if
(cl-deep= actual expected)
(set! cl-test-pass (+ cl-test-pass 1))
(do
(set! cl-test-fail (+ cl-test-fail 1))
(append! cl-test-fails {:name name :expected expected :actual actual})))))
;; Convenience: evaluate CL string with fresh env each time
(define ev (fn (src) (cl-eval-str src (cl-make-env))))
(define evall (fn (src) (cl-eval-all-str src (cl-make-env))))
;; ── self-evaluating literals ──────────────────────────────────────
(cl-test "lit: nil" (ev "nil") nil)
(cl-test "lit: t" (ev "t") true)
(cl-test "lit: integer" (ev "42") 42)
(cl-test "lit: negative" (ev "-7") -7)
(cl-test "lit: zero" (ev "0") 0)
(cl-test "lit: string" (ev "\"hello\"") "hello")
(cl-test "lit: empty string" (ev "\"\"") "")
(cl-test "lit: keyword type" (get (ev ":foo") "cl-type") "keyword")
(cl-test "lit: keyword name" (get (ev ":foo") "name") "FOO")
(cl-test "lit: float type" (get (ev "3.14") "cl-type") "float")
;; ── QUOTE ─────────────────────────────────────────────────────────
(cl-test "quote: symbol" (ev "'x") "X")
(cl-test "quote: list" (ev "'(a b c)") (list "A" "B" "C"))
(cl-test "quote: nil" (ev "'nil") nil)
(cl-test "quote: integer" (ev "'42") 42)
(cl-test "quote: nested" (ev "'(a (b c))") (list "A" (list "B" "C")))
;; ── IF ────────────────────────────────────────────────────────────
(cl-test "if: true branch" (ev "(if t 1 2)") 1)
(cl-test "if: false branch" (ev "(if nil 1 2)") 2)
(cl-test "if: no else nil" (ev "(if nil 99)") nil)
(cl-test "if: number truthy" (ev "(if 0 'yes 'no)") "YES")
(cl-test "if: empty string truthy" (ev "(if \"\" 'yes 'no)") "YES")
(cl-test "if: nested" (ev "(if t (if nil 1 2) 3)") 2)
;; ── PROGN ────────────────────────────────────────────────────────
(cl-test "progn: single" (ev "(progn 42)") 42)
(cl-test "progn: multiple" (ev "(progn 1 2 3)") 3)
(cl-test "progn: nil last" (ev "(progn 1 nil)") nil)
;; ── AND / OR ─────────────────────────────────────────────────────
(cl-test "and: empty" (ev "(and)") true)
(cl-test "and: all true" (ev "(and 1 2 3)") 3)
(cl-test "and: short-circuit" (ev "(and nil 99)") nil)
(cl-test "and: returns last" (ev "(and 1 2)") 2)
(cl-test "or: empty" (ev "(or)") nil)
(cl-test "or: first truthy" (ev "(or 1 2)") 1)
(cl-test "or: all nil" (ev "(or nil nil)") nil)
(cl-test "or: short-circuit" (ev "(or nil 42)") 42)
;; ── COND ─────────────────────────────────────────────────────────
(cl-test "cond: first match" (ev "(cond (t 1) (t 2))") 1)
(cl-test "cond: second match" (ev "(cond (nil 1) (t 2))") 2)
(cl-test "cond: no match" (ev "(cond (nil 1) (nil 2))") nil)
(cl-test "cond: returns test value" (ev "(cond (42))") 42)
;; ── WHEN / UNLESS ─────────────────────────────────────────────────
(cl-test "when: true" (ev "(when t 1 2 3)") 3)
(cl-test "when: nil" (ev "(when nil 99)") nil)
(cl-test "unless: nil runs" (ev "(unless nil 42)") 42)
(cl-test "unless: true skips" (ev "(unless t 99)") nil)
;; ── LET ──────────────────────────────────────────────────────────
(cl-test "let: empty bindings" (ev "(let () 42)") 42)
(cl-test "let: single binding" (ev "(let ((x 5)) x)") 5)
(cl-test "let: two bindings" (ev "(let ((x 3) (y 4)) (+ x y))") 7)
(cl-test "let: parallel" (ev "(let ((x 1)) (let ((x 2) (y x)) y))") 1)
(cl-test "let: nested" (ev "(let ((x 1)) (let ((y 2)) (+ x y)))") 3)
(cl-test "let: progn body" (ev "(let ((x 5)) (+ x 1) (* x 2))") 10)
(cl-test "let: bare name nil" (ev "(let (x) x)") nil)
;; ── LET* ─────────────────────────────────────────────────────────
(cl-test "let*: sequential" (ev "(let* ((x 1) (y (+ x 1))) y)") 2)
(cl-test "let*: chain" (ev "(let* ((a 2) (b (* a 3)) (c (+ b 1))) c)") 7)
(cl-test "let*: shadow" (ev "(let ((x 1)) (let* ((x 2) (y x)) y))") 2)
;; ── SETQ / SETF ──────────────────────────────────────────────────
(cl-test "setq: basic" (ev "(let ((x 0)) (setq x 5) x)") 5)
(cl-test "setq: returns value" (ev "(let ((x 0)) (setq x 99))") 99)
(cl-test "setf: basic" (ev "(let ((x 0)) (setf x 7) x)") 7)
;; ── LAMBDA ────────────────────────────────────────────────────────
(cl-test "lambda: call" (ev "((lambda (x) x) 42)") 42)
(cl-test "lambda: multi-arg" (ev "((lambda (x y) (+ x y)) 3 4)") 7)
(cl-test "lambda: closure" (ev "(let ((n 10)) ((lambda (x) (+ x n)) 5))") 15)
(cl-test "lambda: rest arg"
(ev "((lambda (x &rest xs) (cons x xs)) 1 2 3)")
{:cl-type "cons" :car 1 :cdr (list 2 3)})
(cl-test "lambda: optional no default"
(ev "((lambda (&optional x) x))")
nil)
(cl-test "lambda: optional with arg"
(ev "((lambda (&optional (x 99)) x) 42)")
42)
(cl-test "lambda: optional default used"
(ev "((lambda (&optional (x 7)) x))")
7)
;; ── FUNCTION ─────────────────────────────────────────────────────
(cl-test "function: lambda" (get (ev "(function (lambda (x) x))") "cl-type") "function")
;; ── DEFUN ────────────────────────────────────────────────────────
(cl-test "defun: returns name" (evall "(defun sq (x) (* x x))") "SQ")
(cl-test "defun: call" (evall "(defun sq (x) (* x x)) (sq 5)") 25)
(cl-test "defun: multi-arg" (evall "(defun add (x y) (+ x y)) (add 3 4)") 7)
(cl-test "defun: recursive factorial"
(evall "(defun fact (n) (if (<= n 1) 1 (* n (fact (- n 1))))) (fact 5)")
120)
(cl-test "defun: multiple calls"
(evall "(defun double (x) (* x 2)) (+ (double 3) (double 5))")
16)
;; ── FLET ─────────────────────────────────────────────────────────
(cl-test "flet: basic"
(ev "(flet ((double (x) (* x 2))) (double 5))")
10)
(cl-test "flet: sees outer vars"
(ev "(let ((n 3)) (flet ((add-n (x) (+ x n))) (add-n 7)))")
10)
(cl-test "flet: non-recursive"
(ev "(flet ((f (x) (+ x 1))) (flet ((f (x) (f (f x)))) (f 5)))")
7)
;; ── LABELS ────────────────────────────────────────────────────────
(cl-test "labels: basic"
(ev "(labels ((greet (x) x)) (greet 42))")
42)
(cl-test "labels: recursive"
(ev "(labels ((count (n) (if (<= n 0) 0 (+ 1 (count (- n 1)))))) (count 5))")
5)
(cl-test "labels: mutual recursion"
(ev "(labels
((even? (n) (if (= n 0) t (odd? (- n 1))))
(odd? (n) (if (= n 0) nil (even? (- n 1)))))
(list (even? 4) (odd? 3)))")
(list true true))
;; ── THE / LOCALLY / EVAL-WHEN ────────────────────────────────────
(cl-test "the: passthrough" (ev "(the integer 42)") 42)
(cl-test "the: string" (ev "(the string \"hi\")") "hi")
(cl-test "locally: body" (ev "(locally 1 2 3)") 3)
(cl-test "eval-when: execute" (ev "(eval-when (:execute) 99)") 99)
(cl-test "eval-when: no execute" (ev "(eval-when (:compile-toplevel) 99)") nil)
;; ── DEFVAR / DEFPARAMETER ────────────────────────────────────────
(cl-test "defvar: returns name" (evall "(defvar *x* 10)") "*X*")
(cl-test "defparameter: sets value" (evall "(defparameter *y* 42) *y*") 42)
(cl-test "defvar: no reinit" (evall "(defvar *z* 1) (defvar *z* 99) *z*") 1)
;; ── built-in arithmetic ───────────────────────────────────────────
(cl-test "arith: +" (ev "(+ 1 2 3)") 6)
(cl-test "arith: + zero" (ev "(+)") 0)
(cl-test "arith: -" (ev "(- 10 3 2)") 5)
(cl-test "arith: - negate" (ev "(- 5)") -5)
(cl-test "arith: *" (ev "(* 2 3 4)") 24)
(cl-test "arith: * one" (ev "(*)") 1)
(cl-test "arith: /" (ev "(/ 12 3)") 4)
(cl-test "arith: max" (ev "(max 3 1 4 1 5)") 5)
(cl-test "arith: min" (ev "(min 3 1 4 1 5)") 1)
(cl-test "arith: abs neg" (ev "(abs -7)") 7)
(cl-test "arith: abs pos" (ev "(abs 7)") 7)
;; ── built-in comparisons ──────────────────────────────────────────
(cl-test "cmp: = true" (ev "(= 3 3)") true)
(cl-test "cmp: = false" (ev "(= 3 4)") nil)
(cl-test "cmp: /=" (ev "(/= 3 4)") true)
(cl-test "cmp: <" (ev "(< 1 2)") true)
(cl-test "cmp: > false" (ev "(> 1 2)") nil)
(cl-test "cmp: <=" (ev "(<= 2 2)") true)
;; ── built-in predicates ───────────────────────────────────────────
(cl-test "pred: null nil" (ev "(null nil)") true)
(cl-test "pred: null non-nil" (ev "(null 5)") nil)
(cl-test "pred: not nil" (ev "(not nil)") true)
(cl-test "pred: not truthy" (ev "(not 5)") nil)
(cl-test "pred: numberp" (ev "(numberp 5)") true)
(cl-test "pred: numberp str" (ev "(numberp \"x\")") nil)
(cl-test "pred: stringp" (ev "(stringp \"hello\")") true)
(cl-test "pred: listp list" (ev "(listp '(1))") true)
(cl-test "pred: listp nil" (ev "(listp nil)") true)
(cl-test "pred: zerop" (ev "(zerop 0)") true)
(cl-test "pred: plusp" (ev "(plusp 3)") true)
(cl-test "pred: evenp" (ev "(evenp 4)") true)
(cl-test "pred: oddp" (ev "(oddp 3)") true)
;; ── built-in list ops ─────────────────────────────────────────────
(cl-test "list: car" (ev "(car '(1 2 3))") 1)
(cl-test "list: cdr" (ev "(cdr '(1 2 3))") (list 2 3))
(cl-test "list: cons" (get (ev "(cons 1 2)") "car") 1)
(cl-test "list: list fn" (ev "(list 1 2 3)") (list 1 2 3))
(cl-test "list: length" (ev "(length '(a b c))") 3)
(cl-test "list: length nil" (ev "(length nil)") 0)
(cl-test "list: append" (ev "(append '(1 2) '(3 4))") (list 1 2 3 4))
(cl-test "list: first" (ev "(first '(10 20 30))") 10)
(cl-test "list: second" (ev "(second '(10 20 30))") 20)
(cl-test "list: third" (ev "(third '(10 20 30))") 30)
(cl-test "list: rest" (ev "(rest '(1 2 3))") (list 2 3))
(cl-test "list: nth" (ev "(nth 1 '(a b c))") "B")
(cl-test "list: reverse" (ev "(reverse '(1 2 3))") (list 3 2 1))
;; ── FUNCALL / APPLY / MAPCAR ─────────────────────────────────────
(cl-test "funcall: lambda"
(ev "(funcall (lambda (x) (* x x)) 5)")
25)
(cl-test "apply: basic"
(ev "(apply #'+ '(1 2 3))")
6)
(cl-test "apply: leading args"
(ev "(apply #'+ 1 2 '(3 4))")
10)
(cl-test "mapcar: basic"
(ev "(mapcar (lambda (x) (* x 2)) '(1 2 3))")
(list 2 4 6))
;; ── BLOCK / RETURN-FROM / RETURN ─────────────────────────────────
(cl-test "block: last form value"
(ev "(block done 1 2 3)")
3)
(cl-test "block: empty body"
(ev "(block done)")
nil)
(cl-test "block: single form"
(ev "(block foo 42)")
42)
(cl-test "block: return-from"
(ev "(block done 1 (return-from done 99) 2)")
99)
(cl-test "block: return-from nil block"
(ev "(block nil 1 (return-from nil 42) 3)")
42)
(cl-test "block: return-from no value"
(ev "(block done (return-from done))")
nil)
(cl-test "block: nested inner return stays inner"
(ev "(block outer (block inner (return-from inner 1) 2) 3)")
3)
(cl-test "block: nested outer return"
(ev "(block outer (block inner 1 2) (return-from outer 99) 3)")
99)
(cl-test "return: shorthand for nil block"
(ev "(block nil (return 77))")
77)
(cl-test "return: no value"
(ev "(block nil 1 (return) 2)")
nil)
(cl-test "block: return-from inside let"
(ev "(block done (let ((x 5)) (when (> x 3) (return-from done x))) 0)")
5)
(cl-test "block: return-from inside progn"
(ev "(block done (progn (return-from done 7) 99))")
7)
(cl-test "block: return-from through function"
(ev "(block done (flet ((f () (return-from done 42))) (f)) nil)")
42)
;; ── TAGBODY / GO ─────────────────────────────────────────────────
(cl-test "tagbody: empty returns nil"
(ev "(tagbody)")
nil)
(cl-test "tagbody: forms only, returns nil"
(ev "(let ((x 0)) (tagbody (setq x 1) (setq x 2)) x)")
2)
(cl-test "tagbody: tag only, returns nil"
(ev "(tagbody done)")
nil)
(cl-test "tagbody: go skips forms"
(ev "(let ((x 0)) (tagbody (go done) (setq x 99) done) x)")
0)
(cl-test "tagbody: go to later tag"
(ev "(let ((x 0)) (tagbody start (setq x (+ x 1)) (go done) (setq x 99) done) x)")
1)
(cl-test "tagbody: loop with counter"
(ev "(let ((n 0)) (tagbody loop (when (>= n 3) (go done)) (setq n (+ n 1)) (go loop) done) n)")
3)
(cl-test "tagbody: go inside when"
(ev "(let ((x 0)) (tagbody (setq x 1) (when t (go done)) (setq x 99) done) x)")
1)
(cl-test "tagbody: go inside progn"
(ev "(let ((x 0)) (tagbody (progn (setq x 1) (go done)) (setq x 99) done) x)")
1)
(cl-test "tagbody: go inside let"
(ev "(let ((acc 0)) (tagbody (let ((y 5)) (when (> y 3) (go done))) (setq acc 99) done) acc)")
0)
(cl-test "tagbody: integer tags"
(ev "(let ((x 0)) (tagbody (go 2) 1 (setq x 1) (go 3) 2 (setq x 2) (go 3) 3) x)")
2)
(cl-test "tagbody: block-return propagates out"
(ev "(block done (tagbody (return-from done 42)) nil)")
42)
;; ── UNWIND-PROTECT ───────────────────────────────────────────────
(cl-test "unwind-protect: normal returns protected"
(ev "(unwind-protect 42 nil)")
42)
(cl-test "unwind-protect: cleanup runs"
(ev "(let ((x 0)) (unwind-protect 1 (setq x 99)) x)")
99)
(cl-test "unwind-protect: cleanup result ignored"
(ev "(unwind-protect 42 777)")
42)
(cl-test "unwind-protect: multiple cleanup forms"
(ev "(let ((x 0)) (unwind-protect 1 (setq x (+ x 1)) (setq x (+ x 1))) x)")
2)
(cl-test "unwind-protect: cleanup on return-from"
(ev "(let ((x 0)) (block done (unwind-protect (return-from done 7) (setq x 99))) x)")
99)
(cl-test "unwind-protect: return-from still propagates"
(ev "(block done (unwind-protect (return-from done 42) nil))")
42)
(cl-test "unwind-protect: cleanup on go"
(ev "(let ((x 0)) (tagbody (unwind-protect (go done) (setq x 1)) done) x)")
1)
(cl-test "unwind-protect: nested, inner cleanup first"
(ev "(let ((n 0)) (unwind-protect (unwind-protect 1 (setq n (+ n 10))) (setq n (+ n 1))) n)")
11)
;; ── VALUES / MULTIPLE-VALUE-BIND / NTH-VALUE ────────────────────
(cl-test "values: single returns plain"
(ev "(values 42)")
42)
(cl-test "values: zero returns nil"
(ev "(values)")
nil)
(cl-test "values: multi — primary via funcall"
(ev "(car (list (values 1 2)))")
1)
(cl-test "multiple-value-bind: basic"
(ev "(multiple-value-bind (a b) (values 1 2) (+ a b))")
3)
(cl-test "multiple-value-bind: extra vars get nil"
(ev "(multiple-value-bind (a b c) (values 10 20) (list a b c))")
(list 10 20 nil))
(cl-test "multiple-value-bind: extra values ignored"
(ev "(multiple-value-bind (a) (values 1 2 3) a)")
1)
(cl-test "multiple-value-bind: single value source"
(ev "(multiple-value-bind (a b) 42 (list a b))")
(list 42 nil))
(cl-test "nth-value: 0"
(ev "(nth-value 0 (values 10 20 30))")
10)
(cl-test "nth-value: 1"
(ev "(nth-value 1 (values 10 20 30))")
20)
(cl-test "nth-value: out of range"
(ev "(nth-value 5 (values 10 20))")
nil)
(cl-test "multiple-value-call: basic"
(ev "(multiple-value-call #'+ (values 1 2) (values 3 4))")
10)
(cl-test "multiple-value-prog1: returns first"
(ev "(multiple-value-prog1 1 2 3)")
1)
(cl-test "multiple-value-prog1: side effects run"
(ev "(let ((x 0)) (multiple-value-prog1 99 (setq x 7)) x)")
7)
(cl-test "values: nil primary in if"
(ev "(if (values nil t) 'yes 'no)")
"NO")
(cl-test "values: truthy primary in if"
(ev "(if (values 42 nil) 'yes 'no)")
"YES")
;; --- Dynamic variables ---
(cl-test "defvar marks special"
(do (ev "(defvar *dv* 10)")
(cl-special? "*DV*"))
true)
(cl-test "defvar: let rebinds dynamically"
(ev "(progn (defvar *x* 1) (defun get-x () *x*) (let ((*x* 99)) (get-x)))")
99)
(cl-test "defvar: binding restores after let"
(ev "(progn (defvar *yrst* 5) (let ((*yrst* 42)) *yrst*) *yrst*)")
5)
(cl-test "defparameter marks special"
(do (ev "(defparameter *dp* 0)")
(cl-special? "*DP*"))
true)
(cl-test "defparameter: let rebinds dynamically"
(ev "(progn (defparameter *z* 10) (defun get-z () *z*) (let ((*z* 77)) (get-z)))")
77)
(cl-test "defparameter: always assigns"
(ev "(progn (defparameter *p* 1) (defparameter *p* 2) *p*)")
2)
(cl-test "dynamic binding: nested lets"
(ev "(progn (defvar *n* 0) (let ((*n* 1)) (let ((*n* 2)) *n*)))")
2)
(cl-test "dynamic binding: restores across nesting"
(ev "(progn (defvar *m* 10) (let ((*m* 20)) (let ((*m* 30)) nil)) *m*)")
10)

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;; Lambda list parser tests
(define cl-test-pass 0)
(define cl-test-fail 0)
(define cl-test-fails (list))
;; Deep structural equality for dicts and lists
(define
cl-deep=
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn (k) (and (has-key? b k) (cl-deep= (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(define
chk
(fn
()
(when
(and ok (< i (len a)))
(do
(when
(not (cl-deep= (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(chk)))))
(chk)
ok)))
(:else false))))
(define
cl-test
(fn
(name actual expected)
(if
(cl-deep= actual expected)
(set! cl-test-pass (+ cl-test-pass 1))
(do
(set! cl-test-fail (+ cl-test-fail 1))
(append! cl-test-fails {:name name :expected expected :actual actual})))))
;; Helper: parse lambda list from string "(x y ...)"
(define ll (fn (src) (cl-parse-lambda-list-str src)))
(define ll-req (fn (src) (get (ll src) "required")))
(define ll-opt (fn (src) (get (ll src) "optional")))
(define ll-rest (fn (src) (get (ll src) "rest")))
(define ll-key (fn (src) (get (ll src) "key")))
(define ll-aok (fn (src) (get (ll src) "allow-other-keys")))
(define ll-aux (fn (src) (get (ll src) "aux")))
;; ── required parameters ───────────────────────────────────────────
(cl-test "required: empty" (ll-req "()") (list))
(cl-test "required: one" (ll-req "(x)") (list "X"))
(cl-test "required: two" (ll-req "(x y)") (list "X" "Y"))
(cl-test "required: three" (ll-req "(a b c)") (list "A" "B" "C"))
(cl-test "required: upcased" (ll-req "(foo bar)") (list "FOO" "BAR"))
;; ── &optional ─────────────────────────────────────────────────────
(cl-test "optional: none" (ll-opt "(x)") (list))
(cl-test
"optional: bare symbol"
(ll-opt "(x &optional z)")
(list {:name "Z" :default nil :supplied nil}))
(cl-test
"optional: with default"
(ll-opt "(x &optional (z 0))")
(list {:name "Z" :default 0 :supplied nil}))
(cl-test
"optional: with supplied-p"
(ll-opt "(x &optional (z 0 z-p))")
(list {:name "Z" :default 0 :supplied "Z-P"}))
(cl-test
"optional: two params"
(ll-opt "(&optional a (b 1))")
(list {:name "A" :default nil :supplied nil} {:name "B" :default 1 :supplied nil}))
(cl-test
"optional: string default"
(ll-opt "(&optional (name \"world\"))")
(list {:name "NAME" :default {:cl-type "string" :value "world"} :supplied nil}))
;; ── &rest ─────────────────────────────────────────────────────────
(cl-test "rest: none" (ll-rest "(x)") nil)
(cl-test "rest: present" (ll-rest "(x &rest args)") "ARGS")
(cl-test "rest: with required" (ll-rest "(a b &rest tail)") "TAIL")
;; &body is an alias for &rest
(cl-test "body: alias for rest" (ll-rest "(&body forms)") "FORMS")
;; rest doesn't consume required params
(cl-test "rest: required still there" (ll-req "(a b &rest rest)") (list "A" "B"))
;; ── &key ──────────────────────────────────────────────────────────
(cl-test "key: none" (ll-key "(x)") (list))
(cl-test
"key: bare symbol"
(ll-key "(&key x)")
(list {:name "X" :keyword "X" :default nil :supplied nil}))
(cl-test
"key: with default"
(ll-key "(&key (x 42))")
(list {:name "X" :keyword "X" :default 42 :supplied nil}))
(cl-test
"key: with supplied-p"
(ll-key "(&key (x 42 x-p))")
(list {:name "X" :keyword "X" :default 42 :supplied "X-P"}))
(cl-test
"key: two params"
(ll-key "(&key a b)")
(list
{:name "A" :keyword "A" :default nil :supplied nil}
{:name "B" :keyword "B" :default nil :supplied nil}))
;; ── &allow-other-keys ─────────────────────────────────────────────
(cl-test "aok: absent" (ll-aok "(x)") false)
(cl-test "aok: present" (ll-aok "(&key x &allow-other-keys)") true)
;; ── &aux ──────────────────────────────────────────────────────────
(cl-test "aux: none" (ll-aux "(x)") (list))
(cl-test
"aux: bare symbol"
(ll-aux "(&aux temp)")
(list {:name "TEMP" :init nil}))
(cl-test
"aux: with init"
(ll-aux "(&aux (count 0))")
(list {:name "COUNT" :init 0}))
(cl-test
"aux: two vars"
(ll-aux "(&aux a (b 1))")
(list {:name "A" :init nil} {:name "B" :init 1}))
;; ── combined ──────────────────────────────────────────────────────
(cl-test
"combined: full lambda list"
(let
((parsed (ll "(x y &optional (z 0 z-p) &rest args &key a (b nil b-p) &aux temp)")))
(list
(get parsed "required")
(get (nth (get parsed "optional") 0) "name")
(get (nth (get parsed "optional") 0) "default")
(get (nth (get parsed "optional") 0) "supplied")
(get parsed "rest")
(get (nth (get parsed "key") 0) "name")
(get (nth (get parsed "key") 1) "supplied")
(get (nth (get parsed "aux") 0) "name")))
(list
(list "X" "Y")
"Z"
0
"Z-P"
"ARGS"
"A"
"B-P"
"TEMP"))
(cl-test
"combined: required only stops before &"
(ll-req "(a b &optional c)")
(list "A" "B"))
(cl-test
"combined: required only with &key"
(ll-req "(x &key y)")
(list "X"))
(cl-test
"combined: &rest and &key together"
(let
((parsed (ll "(&rest args &key verbose)")))
(list (get parsed "rest") (get (nth (get parsed "key") 0) "name")))
(list "ARGS" "VERBOSE"))

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;; lib/common-lisp/tests/macros.sx — Phase 5: defmacro, gensym, LOOP tests
;;
;; Depends on: runtime.sx, eval.sx, loop.sx already loaded.
;; Tests via (ev "...") using the CL evaluator.
(define ev (fn (src) (cl-eval-str src (cl-make-env))))
(define evall (fn (src) (cl-eval-all-str src (cl-make-env))))
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
;; ── defmacro basics ──────────────────────────────────────────────────────────
(check
"defmacro returns name"
(ev "(defmacro my-or (a b) (list 'if a a b))")
"MY-OR")
(check
"defmacro expansion works"
(ev "(progn (defmacro my-inc (x) (list '+ x 1)) (my-inc 5))")
6)
(check
"defmacro with &rest"
(ev "(progn (defmacro my-list (&rest xs) (cons 'list xs)) (my-list 1 2 3))")
(list 1 2 3))
(check
"nested macro expansion"
(ev "(progn (defmacro sq (x) (list '* x x)) (sq 7))")
49)
(check
"macro in conditional"
(ev
"(progn (defmacro my-when (c &rest body) (list 'if c (cons 'progn body) nil)) (my-when t 10 20))")
20)
(check
"macro returns nil branch"
(ev
"(progn (defmacro my-when (c &rest body) (list 'if c (cons 'progn body) nil)) (my-when nil 42))")
nil)
;; ── macroexpand ───────────────────────────────────────────────────────────────
(check
"macroexpand returns expanded form"
(ev "(progn (defmacro double (x) (list '+ x x)) (macroexpand '(double 5)))")
(list "+" 5 5))
;; ── gensym ────────────────────────────────────────────────────────────────────
(check "gensym returns string" (ev "(stringp (gensym))") true)
(check
"gensym prefix"
(ev "(let ((g (gensym \"MY\"))) (not (= g nil)))")
true)
(check "gensyms are unique" (ev "(not (= (gensym) (gensym)))") true)
;; ── swap! macro with gensym ───────────────────────────────────────────────────
(check
"swap! macro"
(evall
"(defmacro swap! (a b) (let ((tmp (gensym))) (list 'let (list (list tmp a)) (list 'setq a b) (list 'setq b tmp)))) (defvar *a* 10) (defvar *b* 20) (swap! *a* *b*) (list *a* *b*)")
(list 20 10))
;; ── LOOP: basic repeat and collect ────────────────────────────────────────────
(check
"loop repeat collect"
(ev "(loop repeat 3 collect 99)")
(list 99 99 99))
(check
"loop for-in collect"
(ev "(loop for x in '(1 2 3) collect (* x x))")
(list 1 4 9))
(check
"loop for-from-to collect"
(ev "(loop for i from 1 to 5 collect i)")
(list 1 2 3 4 5))
(check
"loop for-from-below collect"
(ev "(loop for i from 0 below 4 collect i)")
(list 0 1 2 3))
(check
"loop for-downto collect"
(ev "(loop for i from 5 downto 1 collect i)")
(list 5 4 3 2 1))
(check
"loop for-by collect"
(ev "(loop for i from 0 to 10 by 2 collect i)")
(list 0 2 4 6 8 10))
;; ── LOOP: sum, count, maximize, minimize ─────────────────────────────────────
(check "loop sum" (ev "(loop for i from 1 to 5 sum i)") 15)
(check
"loop count"
(ev "(loop for x in '(1 2 3 4 5) count (> x 3))")
2)
(check
"loop maximize"
(ev "(loop for x in '(3 1 4 1 5 9 2 6) maximize x)")
9)
(check
"loop minimize"
(ev "(loop for x in '(3 1 4 1 5 9 2 6) minimize x)")
1)
;; ── LOOP: while and until ─────────────────────────────────────────────────────
(check
"loop while"
(ev "(loop for i from 1 to 10 while (< i 5) collect i)")
(list 1 2 3 4))
(check
"loop until"
(ev "(loop for i from 1 to 10 until (= i 5) collect i)")
(list 1 2 3 4))
;; ── LOOP: when / unless ───────────────────────────────────────────────────────
(check
"loop when filter"
(ev "(loop for i from 0 below 8 when (evenp i) collect i)")
(list 0 2 4 6))
(check
"loop unless filter"
(ev "(loop for i from 0 below 8 unless (evenp i) collect i)")
(list 1 3 5 7))
;; ── LOOP: append ─────────────────────────────────────────────────────────────
(check
"loop append"
(ev "(loop for x in '((1 2) (3 4) (5 6)) append x)")
(list 1 2 3 4 5 6))
;; ── LOOP: always, never, thereis ─────────────────────────────────────────────
(check
"loop always true"
(ev "(loop for x in '(2 4 6) always (evenp x))")
true)
(check
"loop always false"
(ev "(loop for x in '(2 3 6) always (evenp x))")
false)
(check "loop never" (ev "(loop for x in '(1 3 5) never (evenp x))") true)
(check "loop thereis" (ev "(loop for x in '(1 2 3) thereis (> x 2))") true)
;; ── LOOP: for = then (general iteration) ─────────────────────────────────────
(check
"loop for = then doubling"
(ev "(loop repeat 5 for x = 1 then (* x 2) collect x)")
(list 1 2 4 8 16))
;; ── summary ────────────────────────────────────────────────────────────────
(define macro-passed passed)
(define macro-failed failed)
(define macro-failures failures)

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;; Common Lisp reader/parser tests
(define cl-test-pass 0)
(define cl-test-fail 0)
(define cl-test-fails (list))
(define
cl-deep=
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn (k) (and (has-key? b k) (cl-deep= (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(define
chk
(fn
()
(when
(and ok (< i (len a)))
(do
(when
(not (cl-deep= (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(chk)))))
(chk)
ok)))
(:else false))))
(define
cl-test
(fn
(name actual expected)
(if
(cl-deep= actual expected)
(set! cl-test-pass (+ cl-test-pass 1))
(do
(set! cl-test-fail (+ cl-test-fail 1))
(append! cl-test-fails {:name name :expected expected :actual actual})))))
;; ── atoms ─────────────────────────────────────────────────────────
(cl-test "integer: 42" (cl-read "42") 42)
(cl-test "integer: 0" (cl-read "0") 0)
(cl-test "integer: negative" (cl-read "-5") -5)
(cl-test "integer: positive sign" (cl-read "+3") 3)
(cl-test "integer: hex #xFF" (cl-read "#xFF") 255)
(cl-test "integer: hex #xAB" (cl-read "#xAB") 171)
(cl-test "integer: binary #b1010" (cl-read "#b1010") 10)
(cl-test "integer: octal #o17" (cl-read "#o17") 15)
(cl-test "float: type" (get (cl-read "3.14") "cl-type") "float")
(cl-test "float: value" (get (cl-read "3.14") "value") "3.14")
(cl-test "float: neg" (get (cl-read "-2.5") "value") "-2.5")
(cl-test "float: exp" (get (cl-read "1.0e10") "value") "1.0e10")
(cl-test "ratio: type" (get (cl-read "1/3") "cl-type") "ratio")
(cl-test "ratio: value" (get (cl-read "1/3") "value") "1/3")
(cl-test "ratio: 22/7" (get (cl-read "22/7") "value") "22/7")
(cl-test "string: basic" (cl-read "\"hello\"") {:cl-type "string" :value "hello"})
(cl-test "string: empty" (cl-read "\"\"") {:cl-type "string" :value ""})
(cl-test "string: with escape" (cl-read "\"a\\nb\"") {:cl-type "string" :value "a\nb"})
(cl-test "symbol: foo" (cl-read "foo") "FOO")
(cl-test "symbol: BAR" (cl-read "BAR") "BAR")
(cl-test "symbol: pkg:sym" (cl-read "cl:car") "CL:CAR")
(cl-test "symbol: pkg::sym" (cl-read "pkg::foo") "PKG::FOO")
(cl-test "nil: symbol" (cl-read "nil") nil)
(cl-test "nil: uppercase" (cl-read "NIL") nil)
(cl-test "t: symbol" (cl-read "t") true)
(cl-test "t: uppercase" (cl-read "T") true)
(cl-test "keyword: type" (get (cl-read ":foo") "cl-type") "keyword")
(cl-test "keyword: name" (get (cl-read ":foo") "name") "FOO")
(cl-test "keyword: :test" (get (cl-read ":test") "name") "TEST")
(cl-test "char: type" (get (cl-read "#\\a") "cl-type") "char")
(cl-test "char: value" (get (cl-read "#\\a") "value") "a")
(cl-test "char: Space" (get (cl-read "#\\Space") "value") " ")
(cl-test "char: Newline" (get (cl-read "#\\Newline") "value") "\n")
(cl-test "uninterned: type" (get (cl-read "#:foo") "cl-type") "uninterned")
(cl-test "uninterned: name" (get (cl-read "#:foo") "name") "FOO")
;; ── lists ─────────────────────────────────────────────────────────
(cl-test "list: empty" (cl-read "()") (list))
(cl-test "list: one element" (cl-read "(foo)") (list "FOO"))
(cl-test "list: two elements" (cl-read "(foo bar)") (list "FOO" "BAR"))
(cl-test "list: nested" (cl-read "((a b) c)") (list (list "A" "B") "C"))
(cl-test "list: with integer" (cl-read "(+ 1 2)") (list "+" 1 2))
(cl-test "list: with string" (cl-read "(print \"hi\")") (list "PRINT" {:cl-type "string" :value "hi"}))
(cl-test "list: nil element" (cl-read "(a nil b)") (list "A" nil "B"))
(cl-test "list: t element" (cl-read "(a t b)") (list "A" true "B"))
;; ── dotted pairs ──────────────────────────────────────────────<E29480><E29480>──
(cl-test "dotted: type" (get (cl-read "(a . b)") "cl-type") "cons")
(cl-test "dotted: car" (get (cl-read "(a . b)") "car") "A")
(cl-test "dotted: cdr" (get (cl-read "(a . b)") "cdr") "B")
(cl-test "dotted: number cdr" (get (cl-read "(x . 42)") "cdr") 42)
;; ── reader macros ────────────────────────────────────────────────<E29480><E29480>
(cl-test "quote: form" (cl-read "'x") (list "QUOTE" "X"))
(cl-test "quote: list" (cl-read "'(a b)") (list "QUOTE" (list "A" "B")))
(cl-test "backquote: form" (cl-read "`x") (list "QUASIQUOTE" "X"))
(cl-test "unquote: form" (cl-read ",x") (list "UNQUOTE" "X"))
(cl-test "comma-at: form" (cl-read ",@x") (list "UNQUOTE-SPLICING" "X"))
(cl-test "function: form" (cl-read "#'foo") (list "FUNCTION" "FOO"))
;; ── vector ────────────────────────────────────────────────────────
(cl-test "vector: type" (get (cl-read "#(1 2 3)") "cl-type") "vector")
(cl-test "vector: elements" (get (cl-read "#(1 2 3)") "elements") (list 1 2 3))
(cl-test "vector: empty" (get (cl-read "#()") "elements") (list))
(cl-test "vector: mixed" (get (cl-read "#(a 1 \"s\")") "elements") (list "A" 1 {:cl-type "string" :value "s"}))
;; ── cl-read-all ───────────────────────────────────────────────────
(cl-test
"read-all: empty"
(cl-read-all "")
(list))
(cl-test
"read-all: two forms"
(cl-read-all "42 foo")
(list 42 "FOO"))
(cl-test
"read-all: three forms"
(cl-read-all "(+ 1 2) (+ 3 4) hello")
(list (list "+" 1 2) (list "+" 3 4) "HELLO"))
(cl-test
"read-all: with comments"
(cl-read-all "; this is a comment\n42 ; inline\nfoo")
(list 42 "FOO"))
(cl-test
"read-all: defun form"
(nth (cl-read-all "(defun square (x) (* x x))") 0)
(list "DEFUN" "SQUARE" (list "X") (list "*" "X" "X")))

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;; geometry.sx — Multiple dispatch with CLOS
;;
;; Demonstrates generic functions dispatching on combinations of
;; geometric types: point, line, plane.
;;
;; Depends on: lib/common-lisp/runtime.sx, lib/common-lisp/clos.sx
;; ── geometric classes ──────────────────────────────────────────────────────
(clos-defclass "geo-point" (list "t") (list {:initform 0 :initarg ":px" :reader nil :writer nil :accessor nil :name "px"} {:initform 0 :initarg ":py" :reader nil :writer nil :accessor nil :name "py"}))
(clos-defclass "geo-line" (list "t") (list {:initform nil :initarg ":p1" :reader nil :writer nil :accessor nil :name "p1"} {:initform nil :initarg ":p2" :reader nil :writer nil :accessor nil :name "p2"}))
(clos-defclass "geo-plane" (list "t") (list {:initform nil :initarg ":normal" :reader nil :writer nil :accessor nil :name "normal"} {:initform 0 :initarg ":d" :reader nil :writer nil :accessor nil :name "d"}))
;; ── helpers ────────────────────────────────────────────────────────────────
(define geo-point-x (fn (p) (clos-slot-value p "px")))
(define geo-point-y (fn (p) (clos-slot-value p "py")))
(define
geo-make-point
(fn (x y) (clos-make-instance "geo-point" ":px" x ":py" y)))
(define
geo-make-line
(fn (p1 p2) (clos-make-instance "geo-line" ":p1" p1 ":p2" p2)))
(define
geo-make-plane
(fn
(nx ny d)
(clos-make-instance "geo-plane" ":normal" (list nx ny) ":d" d)))
;; ── describe generic ───────────────────────────────────────────────────────
(clos-defgeneric "geo-describe" {})
(clos-defmethod
"geo-describe"
(list)
(list "geo-point")
(fn
(args next-fn)
(let
((p (first args)))
(str "P(" (geo-point-x p) "," (geo-point-y p) ")"))))
(clos-defmethod
"geo-describe"
(list)
(list "geo-line")
(fn
(args next-fn)
(let
((l (first args)))
(str
"L["
(clos-call-generic "geo-describe" (list (clos-slot-value l "p1")))
"-"
(clos-call-generic "geo-describe" (list (clos-slot-value l "p2")))
"]"))))
(clos-defmethod
"geo-describe"
(list)
(list "geo-plane")
(fn
(args next-fn)
(let
((pl (first args)))
(str "Plane(d=" (clos-slot-value pl "d") ")"))))
;; ── intersect: multi-dispatch generic ─────────────────────────────────────
;;
;; Returns a string description of the intersection result.
(clos-defgeneric "intersect" {})
;; point ∩ point: same if coordinates match
(clos-defmethod
"intersect"
(list)
(list "geo-point" "geo-point")
(fn
(args next-fn)
(let
((p1 (first args)) (p2 (first (rest args))))
(if
(and
(= (geo-point-x p1) (geo-point-x p2))
(= (geo-point-y p1) (geo-point-y p2)))
"point"
"empty"))))
;; point ∩ line: check if point lies on line (cross product = 0)
(clos-defmethod
"intersect"
(list)
(list "geo-point" "geo-line")
(fn
(args next-fn)
(let
((pt (first args)) (ln (first (rest args))))
(let
((lp1 (clos-slot-value ln "p1")) (lp2 (clos-slot-value ln "p2")))
(let
((dx (- (geo-point-x lp2) (geo-point-x lp1)))
(dy (- (geo-point-y lp2) (geo-point-y lp1)))
(ex (- (geo-point-x pt) (geo-point-x lp1)))
(ey (- (geo-point-y pt) (geo-point-y lp1))))
(if (= (- (* dx ey) (* dy ex)) 0) "point" "empty"))))))
;; line ∩ line: parallel (same slope = empty) or point
(clos-defmethod
"intersect"
(list)
(list "geo-line" "geo-line")
(fn
(args next-fn)
(let
((l1 (first args)) (l2 (first (rest args))))
(let
((p1 (clos-slot-value l1 "p1"))
(p2 (clos-slot-value l1 "p2"))
(p3 (clos-slot-value l2 "p1"))
(p4 (clos-slot-value l2 "p2")))
(let
((dx1 (- (geo-point-x p2) (geo-point-x p1)))
(dy1 (- (geo-point-y p2) (geo-point-y p1)))
(dx2 (- (geo-point-x p4) (geo-point-x p3)))
(dy2 (- (geo-point-y p4) (geo-point-y p3))))
(let
((cross (- (* dx1 dy2) (* dy1 dx2))))
(if (= cross 0) "parallel" "point")))))))
;; line ∩ plane: general case = point (or parallel if line ⊥ normal)
(clos-defmethod
"intersect"
(list)
(list "geo-line" "geo-plane")
(fn
(args next-fn)
(let
((ln (first args)) (pl (first (rest args))))
(let
((p1 (clos-slot-value ln "p1"))
(p2 (clos-slot-value ln "p2"))
(n (clos-slot-value pl "normal")))
(let
((dx (- (geo-point-x p2) (geo-point-x p1)))
(dy (- (geo-point-y p2) (geo-point-y p1)))
(nx (first n))
(ny (first (rest n))))
(let
((dot (+ (* dx nx) (* dy ny))))
(if (= dot 0) "parallel" "point")))))))
;; ── tests ─────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
;; describe
(check
"describe point"
(clos-call-generic
"geo-describe"
(list (geo-make-point 3 4)))
"P(3,4)")
(check
"describe line"
(clos-call-generic
"geo-describe"
(list
(geo-make-line
(geo-make-point 0 0)
(geo-make-point 1 1))))
"L[P(0,0)-P(1,1)]")
(check
"describe plane"
(clos-call-generic
"geo-describe"
(list (geo-make-plane 0 1 5)))
"Plane(d=5)")
;; intersect point×point
(check
"P∩P same"
(clos-call-generic
"intersect"
(list
(geo-make-point 2 3)
(geo-make-point 2 3)))
"point")
(check
"P∩P diff"
(clos-call-generic
"intersect"
(list
(geo-make-point 1 2)
(geo-make-point 3 4)))
"empty")
;; intersect point×line
(let
((origin (geo-make-point 0 0))
(p10 (geo-make-point 10 0))
(p55 (geo-make-point 5 5))
(l-x
(geo-make-line
(geo-make-point 0 0)
(geo-make-point 10 0))))
(begin
(check
"P∩L on line"
(clos-call-generic "intersect" (list p10 l-x))
"point")
(check
"P∩L on x-axis"
(clos-call-generic "intersect" (list origin l-x))
"point")
(check
"P∩L off line"
(clos-call-generic "intersect" (list p55 l-x))
"empty")))
;; intersect line×line
(let
((horiz (geo-make-line (geo-make-point 0 0) (geo-make-point 10 0)))
(vert
(geo-make-line
(geo-make-point 5 -5)
(geo-make-point 5 5)))
(horiz2
(geo-make-line
(geo-make-point 0 3)
(geo-make-point 10 3))))
(begin
(check
"L∩L crossing"
(clos-call-generic "intersect" (list horiz vert))
"point")
(check
"L∩L parallel"
(clos-call-generic "intersect" (list horiz horiz2))
"parallel")))
;; intersect line×plane
(let
((diag (geo-make-line (geo-make-point 0 0) (geo-make-point 1 1)))
(vert-plane (geo-make-plane 1 0 5))
(diag-plane (geo-make-plane -1 1 0)))
(begin
(check
"L∩Plane cross"
(clos-call-generic "intersect" (list diag vert-plane))
"point")
(check
"L∩Plane parallel"
(clos-call-generic "intersect" (list diag diag-plane))
"parallel")))
;; ── summary ────────────────────────────────────────────────────────────────
(define geo-passed passed)
(define geo-failed failed)
(define geo-failures failures)

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;; interactive-debugger.sx — Condition debugger using *debugger-hook*
;;
;; Demonstrates the classic CL debugger pattern:
;; - *debugger-hook* is invoked when an unhandled error reaches the top level
;; - The hook receives the condition and a reference to itself
;; - It can offer restarts interactively (here simulated with a policy fn)
;;
;; In real CL the debugger reads from the terminal. Here we simulate
;; the "user input" via a policy function passed in at call time.
;;
;; Depends on: lib/common-lisp/runtime.sx already loaded.
;; ── *debugger-hook* global ────────────────────────────────────────────────
;;
;; CL: when error is unhandled, invoke *debugger-hook* with (condition hook).
;; A nil hook means use the system default (which we simulate as re-raise).
(define cl-debugger-hook nil)
;; ── invoke-debugger ────────────────────────────────────────────────────────
;;
;; Called when cl-error finds no handler. Tries cl-debugger-hook first;
;; falls back to a simple error report.
(define
cl-invoke-debugger
(fn
(c)
(if
(nil? cl-debugger-hook)
(error (str "Debugger: " (cl-condition-message c)))
(begin
(let
((hook cl-debugger-hook))
(set! cl-debugger-hook nil)
(let
((result (hook c hook)))
(set! cl-debugger-hook hook)
result))))))
;; ── cl-error/debugger — error that routes through invoke-debugger ─────────
(define
cl-error-with-debugger
(fn
(c &rest args)
(let
((obj (cond ((cl-condition? c) c) ((string? c) (cl-make-condition "simple-error" "format-control" c "format-arguments" args)) (:else (cl-make-condition "simple-error" "format-control" (str c))))))
(cl-signal-obj obj cl-handler-stack)
(cl-invoke-debugger obj))))
;; ── simulated debugger session ────────────────────────────────────────────
;;
;; A debugger hook takes (condition hook) and "reads" user commands.
;; We simulate this with a policy function: (fn (c restarts) restart-name)
;; that picks a restart given the condition and available restarts.
(define
make-policy-debugger
(fn
(policy)
(fn
(c hook)
(let
((available (cl-compute-restarts)))
(let
((choice (policy c available)))
(if
(and choice (not (nil? (cl-find-restart choice))))
(cl-invoke-restart choice)
(error
(str
"Debugger: no restart chosen for: "
(cl-condition-message c)))))))))
;; ── tests ─────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
(define
reset-stacks!
(fn
()
(set! cl-handler-stack (list))
(set! cl-restart-stack (list))
(set! cl-debugger-hook nil)))
;; Test 1: debugger hook receives condition
(reset-stacks!)
(let
((received-msg ""))
(begin
(set!
cl-debugger-hook
(fn (c hook) (set! received-msg (cl-condition-message c)) nil))
(cl-restart-case
(fn () (cl-error-with-debugger "something broke"))
(list "abort" (list) (fn () nil)))
(check "debugger hook receives condition" received-msg "something broke")))
;; Test 2: policy-driven restart selection (use-zero)
(reset-stacks!)
(let
((result (begin (set! cl-debugger-hook (make-policy-debugger (fn (c restarts) "use-zero"))) (cl-restart-case (fn () (cl-error-with-debugger (cl-make-condition "division-by-zero")) 999) (list "use-zero" (list) (fn () 0))))))
(check "policy debugger: use-zero restart" result 0))
;; Test 3: policy selects abort
(reset-stacks!)
(let
((result (begin (set! cl-debugger-hook (make-policy-debugger (fn (c restarts) "abort"))) (cl-restart-case (fn () (cl-error-with-debugger "aborting error") 999) (list "abort" (list) (fn () "aborted"))))))
(check "policy debugger: abort restart" result "aborted"))
;; Test 4: compute-restarts inside debugger hook
(reset-stacks!)
(let
((seen-restarts (list)))
(begin
(set!
cl-debugger-hook
(fn
(c hook)
(set! seen-restarts (cl-compute-restarts))
(cl-invoke-restart "continue")))
(cl-restart-case
(fn () (cl-error-with-debugger "test") 42)
(list "continue" (list) (fn () "ok"))
(list "abort" (list) (fn () "no")))
(check
"debugger: compute-restarts visible"
(= (len seen-restarts) 2)
true)))
;; Test 5: hook not invoked when handler catches first
(reset-stacks!)
(let
((hook-called false)
(result
(begin
(set! cl-debugger-hook (fn (c hook) (set! hook-called true) nil))
(cl-handler-case
(fn () (cl-error-with-debugger "handled"))
(list "error" (fn (c) "handler-won"))))))
(check "handler wins; hook not called" hook-called false)
(check "handler result returned" result "handler-won"))
;; Test 6: debugger-hook nil after re-raise guard
(reset-stacks!)
(let
((hook-calls 0))
(begin
(set!
cl-debugger-hook
(fn
(c hook)
(set! hook-calls (+ hook-calls 1))
(if
(> hook-calls 1)
(error "infinite loop guard")
(cl-invoke-restart "escape"))))
(cl-restart-case
(fn () (cl-error-with-debugger "once"))
(list "escape" (list) (fn () nil)))
(check
"hook called exactly once (no infinite recursion)"
hook-calls
1)))
;; ── summary ────────────────────────────────────────────────────────────────
(define debugger-passed passed)
(define debugger-failed failed)
(define debugger-failures failures)

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;; mop-trace.sx — :before/:after method tracing with CLOS
;;
;; Classic CLOS pattern: instrument generic functions with :before and :after
;; qualifiers to print call/return traces without modifying the primary method.
;;
;; Depends on: lib/common-lisp/runtime.sx, lib/common-lisp/clos.sx
;; ── trace log (mutable accumulator) ───────────────────────────────────────
(define trace-log (list))
(define
trace-push
(fn (msg) (set! trace-log (append trace-log (list msg)))))
(define trace-clear (fn () (set! trace-log (list))))
;; ── domain classes ─────────────────────────────────────────────────────────
(clos-defclass "shape" (list "t") (list {:initform "white" :initarg ":color" :reader nil :writer nil :accessor nil :name "color"}))
(clos-defclass "circle" (list "shape") (list {:initform 1 :initarg ":radius" :reader nil :writer nil :accessor nil :name "radius"}))
(clos-defclass "rect" (list "shape") (list {:initform 1 :initarg ":width" :reader nil :writer nil :accessor nil :name "width"} {:initform 1 :initarg ":height" :reader nil :writer nil :accessor nil :name "height"}))
;; ── generic function: area ─────────────────────────────────────────────────
(clos-defgeneric "area" {})
;; primary methods
(clos-defmethod
"area"
(list)
(list "circle")
(fn
(args next-fn)
(let
((c (first args)))
(let ((r (clos-slot-value c "radius"))) (* r r)))))
(clos-defmethod
"area"
(list)
(list "rect")
(fn
(args next-fn)
(let
((r (first args)))
(* (clos-slot-value r "width") (clos-slot-value r "height")))))
;; :before tracing
(clos-defmethod
"area"
(list "before")
(list "shape")
(fn
(args next-fn)
(trace-push (str "BEFORE area(" (clos-class-of (first args)) ")"))))
;; :after tracing
(clos-defmethod
"area"
(list "after")
(list "shape")
(fn
(args next-fn)
(trace-push (str "AFTER area(" (clos-class-of (first args)) ")"))))
;; ── generic function: describe-shape ──────────────────────────────────────
(clos-defgeneric "describe-shape" {})
(clos-defmethod
"describe-shape"
(list)
(list "shape")
(fn
(args next-fn)
(let
((s (first args)))
(str "shape[" (clos-slot-value s "color") "]"))))
(clos-defmethod
"describe-shape"
(list)
(list "circle")
(fn
(args next-fn)
(let
((c (first args)))
(str
"circle[r="
(clos-slot-value c "radius")
" "
(clos-call-next-method next-fn)
"]"))))
(clos-defmethod
"describe-shape"
(list)
(list "rect")
(fn
(args next-fn)
(let
((r (first args)))
(str
"rect["
(clos-slot-value r "width")
"x"
(clos-slot-value r "height")
" "
(clos-call-next-method next-fn)
"]"))))
;; :before on base shape (fires for all subclasses too)
(clos-defmethod
"describe-shape"
(list "before")
(list "shape")
(fn
(args next-fn)
(trace-push
(str "BEFORE describe-shape(" (clos-class-of (first args)) ")"))))
;; ── tests ─────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
;; ── area tests ────────────────────────────────────────────────────────────
;; circle area = r*r (no pi — integer arithmetic for predictability)
(let
((c (clos-make-instance "circle" ":radius" 5 ":color" "red")))
(do
(trace-clear)
(check "circle area" (clos-call-generic "area" (list c)) 25)
(check
":before fired for circle"
(= (first trace-log) "BEFORE area(circle)")
true)
(check
":after fired for circle"
(= (first (rest trace-log)) "AFTER area(circle)")
true)
(check "trace length 2" (len trace-log) 2)))
;; rect area = w*h
(let
((r (clos-make-instance "rect" ":width" 4 ":height" 6 ":color" "blue")))
(do
(trace-clear)
(check "rect area" (clos-call-generic "area" (list r)) 24)
(check
":before fired for rect"
(= (first trace-log) "BEFORE area(rect)")
true)
(check
":after fired for rect"
(= (first (rest trace-log)) "AFTER area(rect)")
true)
(check "trace length 2 (rect)" (len trace-log) 2)))
;; ── describe-shape tests ───────────────────────────────────────────────────
(let
((c (clos-make-instance "circle" ":radius" 3 ":color" "green")))
(do
(trace-clear)
(check
"circle describe"
(clos-call-generic "describe-shape" (list c))
"circle[r=3 shape[green]]")
(check
":before fired for describe circle"
(= (first trace-log) "BEFORE describe-shape(circle)")
true)))
(let
((r (clos-make-instance "rect" ":width" 2 ":height" 7 ":color" "black")))
(do
(trace-clear)
(check
"rect describe"
(clos-call-generic "describe-shape" (list r))
"rect[2x7 shape[black]]")
(check
":before fired for describe rect"
(= (first trace-log) "BEFORE describe-shape(rect)")
true)))
;; ── call-next-method: circle -> shape ─────────────────────────────────────
(let
((c (clos-make-instance "circle" ":radius" 1 ":color" "purple")))
(check
"call-next-method result in describe"
(clos-call-generic "describe-shape" (list c))
"circle[r=1 shape[purple]]"))
;; ── summary ────────────────────────────────────────────────────────────────
(define mop-passed passed)
(define mop-failed failed)
(define mop-failures failures)

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;; parse-recover.sx — Parser with skipped-token restart
;;
;; Classic CL pattern: a simple token parser that signals a condition
;; when it encounters an unexpected token. The :skip-token restart
;; allows the parser to continue past the offending token.
;;
;; Depends on: lib/common-lisp/runtime.sx already loaded.
;; ── condition type ─────────────────────────────────────────────────────────
(cl-define-condition "parse-error" (list "error") (list "token" "position"))
;; ── simple token parser ────────────────────────────────────────────────────
;;
;; parse-numbers: given a list of tokens (strings), parse integers.
;; Non-integer tokens signal parse-error with two restarts:
;; skip-token — skip the bad token and continue
;; use-zero — use 0 in place of the bad token
(define
parse-numbers
(fn
(tokens)
(define result (list))
(define
process
(fn
(toks)
(if
(empty? toks)
result
(let
((tok (first toks)) (rest-toks (rest toks)))
(let
((n (string->number tok 10)))
(if
n
(begin
(set! result (append result (list n)))
(process rest-toks))
(cl-restart-case
(fn
()
(cl-signal
(cl-make-condition
"parse-error"
"token"
tok
"position"
(len result)))
(set! result (append result (list 0)))
(process rest-toks))
(list "skip-token" (list) (fn () (process rest-toks)))
(list
"use-zero"
(list)
(fn
()
(begin
(set! result (append result (list 0)))
(process rest-toks)))))))))))
(process tokens)
result))
;; ── tests ─────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
(define
reset-stacks!
(fn () (set! cl-handler-stack (list)) (set! cl-restart-stack (list))))
;; All valid tokens
(reset-stacks!)
(check
"all valid: 1 2 3"
(cl-handler-bind
(list (list "parse-error" (fn (c) (cl-invoke-restart "skip-token"))))
(fn () (parse-numbers (list "1" "2" "3"))))
(list 1 2 3))
;; Skip bad token
(reset-stacks!)
(check
"skip bad token: 1 x 3 -> (1 3)"
(cl-handler-bind
(list (list "parse-error" (fn (c) (cl-invoke-restart "skip-token"))))
(fn () (parse-numbers (list "1" "x" "3"))))
(list 1 3))
;; Use zero for bad token
(reset-stacks!)
(check
"use-zero for bad: 1 x 3 -> (1 0 3)"
(cl-handler-bind
(list (list "parse-error" (fn (c) (cl-invoke-restart "use-zero"))))
(fn () (parse-numbers (list "1" "x" "3"))))
(list 1 0 3))
;; Multiple bad tokens, all skipped
(reset-stacks!)
(check
"skip multiple bad: a 2 b 4 -> (2 4)"
(cl-handler-bind
(list (list "parse-error" (fn (c) (cl-invoke-restart "skip-token"))))
(fn () (parse-numbers (list "a" "2" "b" "4"))))
(list 2 4))
;; handler-case: abort on first bad token
(reset-stacks!)
(check
"handler-case: abort on first bad"
(cl-handler-case
(fn () (parse-numbers (list "1" "bad" "3")))
(list
"parse-error"
(fn
(c)
(str
"parse error at position "
(cl-condition-slot c "position")
": "
(cl-condition-slot c "token")))))
"parse error at position 1: bad")
;; Verify condition type hierarchy
(reset-stacks!)
(check
"parse-error isa error"
(cl-condition-of-type?
(cl-make-condition "parse-error" "token" "x" "position" 0)
"error")
true)
;; ── summary ────────────────────────────────────────────────────────────────
(define parse-passed passed)
(define parse-failed failed)
(define parse-failures failures)

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;; restart-demo.sx — Classic CL condition system demo
;;
;; Demonstrates resumable exceptions via restarts.
;; The `safe-divide` function signals a division-by-zero condition
;; and offers two restarts:
;; :use-zero — return 0 as the result
;; :retry — call safe-divide again with a corrected divisor
;;
;; Depends on: lib/common-lisp/runtime.sx already loaded.
;; ── safe-divide ────────────────────────────────────────────────────────────
;;
;; Divides numerator by denominator.
;; When denominator is 0, signals division-by-zero with two restarts.
(define
safe-divide
(fn
(n d)
(if
(= d 0)
(cl-restart-case
(fn
()
(cl-signal
(cl-make-condition
"division-by-zero"
"operation"
"/"
"operands"
(list n d)))
(error "division by zero — no restart invoked"))
(list "use-zero" (list) (fn () 0))
(list "retry" (list "d") (fn (d2) (safe-divide n d2))))
(/ n d))))
;; ── tests ─────────────────────────────────────────────────────────────────
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
(define
reset-stacks!
(fn () (set! cl-handler-stack (list)) (set! cl-restart-stack (list))))
;; Normal division
(reset-stacks!)
(check "10 / 2 = 5" (safe-divide 10 2) 5)
;; Invoke use-zero restart
(reset-stacks!)
(check
"10 / 0 -> use-zero"
(cl-handler-bind
(list
(list "division-by-zero" (fn (c) (cl-invoke-restart "use-zero"))))
(fn () (safe-divide 10 0)))
0)
;; Invoke retry restart with a corrected denominator
(reset-stacks!)
(check
"10 / 0 -> retry with 2"
(cl-handler-bind
(list
(list
"division-by-zero"
(fn (c) (cl-invoke-restart "retry" 2))))
(fn () (safe-divide 10 0)))
5)
;; Nested calls: outer handles the inner divide-by-zero
(reset-stacks!)
(check
"nested: 20 / (0->4) = 5"
(cl-handler-bind
(list
(list
"division-by-zero"
(fn (c) (cl-invoke-restart "retry" 4))))
(fn () (let ((r1 (safe-divide 20 0))) r1)))
5)
;; handler-case — unwinding version
(reset-stacks!)
(check
"handler-case: catches division-by-zero"
(cl-handler-case
(fn () (safe-divide 9 0))
(list "division-by-zero" (fn (c) "caught!")))
"caught!")
;; Verify use-zero is idempotent (two uses)
(reset-stacks!)
(check
"two use-zero invocations"
(cl-handler-bind
(list
(list "division-by-zero" (fn (c) (cl-invoke-restart "use-zero"))))
(fn
()
(+
(safe-divide 10 0)
(safe-divide 3 0))))
0)
;; No restart needed for normal division
(reset-stacks!)
(check
"no restart needed for 8/4"
(safe-divide 8 4)
2)
;; ── summary ────────────────────────────────────────────────────────────────
(define demo-passed passed)
(define demo-failed failed)
(define demo-failures failures)

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;; Common Lisp tokenizer tests
(define cl-test-pass 0)
(define cl-test-fail 0)
(define cl-test-fails (list))
(define
cl-test
(fn
(name actual expected)
(if
(= actual expected)
(set! cl-test-pass (+ cl-test-pass 1))
(do
(set! cl-test-fail (+ cl-test-fail 1))
(append! cl-test-fails {:name name :expected expected :actual actual})))))
;; Helpers: extract types and values from token stream (drops eof)
(define
cl-tok-types
(fn
(src)
(map
(fn (t) (get t "type"))
(filter (fn (t) (not (= (get t "type") "eof"))) (cl-tokenize src)))))
(define
cl-tok-values
(fn
(src)
(map
(fn (t) (get t "value"))
(filter (fn (t) (not (= (get t "type") "eof"))) (cl-tokenize src)))))
(define
cl-tok-first
(fn (src) (nth (cl-tokenize src) 0)))
;; ── symbols ───────────────────────────────────────────────────────
(cl-test "symbol: bare lowercase" (cl-tok-values "foo") (list "FOO"))
(cl-test "symbol: uppercase" (cl-tok-values "BAR") (list "BAR"))
(cl-test "symbol: mixed case folded" (cl-tok-values "FooBar") (list "FOOBAR"))
(cl-test "symbol: with hyphen" (cl-tok-values "foo-bar") (list "FOO-BAR"))
(cl-test "symbol: with star" (cl-tok-values "*special*") (list "*SPECIAL*"))
(cl-test "symbol: with question" (cl-tok-values "null?") (list "NULL?"))
(cl-test "symbol: with exclamation" (cl-tok-values "set!") (list "SET!"))
(cl-test "symbol: plus sign alone" (cl-tok-values "+") (list "+"))
(cl-test "symbol: minus sign alone" (cl-tok-values "-") (list "-"))
(cl-test "symbol: type is symbol" (cl-tok-types "foo") (list "symbol"))
;; ── package-qualified symbols ─────────────────────────────────────
(cl-test "symbol: pkg:sym external" (cl-tok-values "cl:car") (list "CL:CAR"))
(cl-test "symbol: pkg::sym internal" (cl-tok-values "pkg::foo") (list "PKG::FOO"))
(cl-test "symbol: cl:car type" (cl-tok-types "cl:car") (list "symbol"))
;; ── keywords ──────────────────────────────────────────────────────
(cl-test "keyword: basic" (cl-tok-values ":foo") (list "FOO"))
(cl-test "keyword: type" (cl-tok-types ":foo") (list "keyword"))
(cl-test "keyword: upcase" (cl-tok-values ":hello-world") (list "HELLO-WORLD"))
(cl-test "keyword: multiple" (cl-tok-types ":a :b :c") (list "keyword" "keyword" "keyword"))
;; ── integers ──────────────────────────────────────────────────────
(cl-test "integer: zero" (cl-tok-values "0") (list "0"))
(cl-test "integer: positive" (cl-tok-values "42") (list "42"))
(cl-test "integer: negative" (cl-tok-values "-5") (list "-5"))
(cl-test "integer: positive-sign" (cl-tok-values "+3") (list "+3"))
(cl-test "integer: type" (cl-tok-types "42") (list "integer"))
(cl-test "integer: multi-digit" (cl-tok-values "12345678") (list "12345678"))
;; ── hex, binary, octal ───────────────────────────────────────────
(cl-test "hex: lowercase x" (cl-tok-values "#xFF") (list "#xFF"))
(cl-test "hex: uppercase X" (cl-tok-values "#XFF") (list "#XFF"))
(cl-test "hex: type" (cl-tok-types "#xFF") (list "integer"))
(cl-test "hex: zero" (cl-tok-values "#x0") (list "#x0"))
(cl-test "binary: #b" (cl-tok-values "#b1010") (list "#b1010"))
(cl-test "binary: type" (cl-tok-types "#b1010") (list "integer"))
(cl-test "octal: #o" (cl-tok-values "#o17") (list "#o17"))
(cl-test "octal: type" (cl-tok-types "#o17") (list "integer"))
;; ── floats ────────────────────────────────────────────────────────
(cl-test "float: basic" (cl-tok-values "3.14") (list "3.14"))
(cl-test "float: type" (cl-tok-types "3.14") (list "float"))
(cl-test "float: negative" (cl-tok-values "-2.5") (list "-2.5"))
(cl-test "float: exponent" (cl-tok-values "1.0e10") (list "1.0e10"))
(cl-test "float: neg exponent" (cl-tok-values "1.5e-3") (list "1.5e-3"))
(cl-test "float: leading dot" (cl-tok-values ".5") (list "0.5"))
(cl-test "float: exp only" (cl-tok-values "1e5") (list "1e5"))
;; ── ratios ────────────────────────────────────────────────────────
(cl-test "ratio: 1/3" (cl-tok-values "1/3") (list "1/3"))
(cl-test "ratio: type" (cl-tok-types "1/3") (list "ratio"))
(cl-test "ratio: 22/7" (cl-tok-values "22/7") (list "22/7"))
(cl-test "ratio: negative" (cl-tok-values "-1/2") (list "-1/2"))
;; ── strings ───────────────────────────────────────────────────────
(cl-test "string: empty" (cl-tok-values "\"\"") (list ""))
(cl-test "string: basic" (cl-tok-values "\"hello\"") (list "hello"))
(cl-test "string: type" (cl-tok-types "\"hello\"") (list "string"))
(cl-test "string: with space" (cl-tok-values "\"hello world\"") (list "hello world"))
(cl-test "string: escaped quote" (cl-tok-values "\"say \\\"hi\\\"\"") (list "say \"hi\""))
(cl-test "string: escaped backslash" (cl-tok-values "\"a\\\\b\"") (list "a\\b"))
(cl-test "string: newline escape" (cl-tok-values "\"a\\nb\"") (list "a\nb"))
(cl-test "string: tab escape" (cl-tok-values "\"a\\tb\"") (list "a\tb"))
;; ── characters ────────────────────────────────────────────────────
(cl-test "char: lowercase a" (cl-tok-values "#\\a") (list "a"))
(cl-test "char: uppercase A" (cl-tok-values "#\\A") (list "A"))
(cl-test "char: digit" (cl-tok-values "#\\1") (list "1"))
(cl-test "char: type" (cl-tok-types "#\\a") (list "char"))
(cl-test "char: Space" (cl-tok-values "#\\Space") (list " "))
(cl-test "char: Newline" (cl-tok-values "#\\Newline") (list "\n"))
(cl-test "char: Tab" (cl-tok-values "#\\Tab") (list "\t"))
(cl-test "char: Return" (cl-tok-values "#\\Return") (list "\r"))
;; ── reader macros ─────────────────────────────────────────────────
(cl-test "quote: type" (cl-tok-types "'x") (list "quote" "symbol"))
(cl-test "backquote: type" (cl-tok-types "`x") (list "backquote" "symbol"))
(cl-test "comma: type" (cl-tok-types ",x") (list "comma" "symbol"))
(cl-test "comma-at: type" (cl-tok-types ",@x") (list "comma-at" "symbol"))
(cl-test "hash-quote: type" (cl-tok-types "#'foo") (list "hash-quote" "symbol"))
(cl-test "hash-paren: type" (cl-tok-types "#(1 2)") (list "hash-paren" "integer" "integer" "rparen"))
;; ── uninterned ────────────────────────────────────────────────────
(cl-test "uninterned: type" (cl-tok-types "#:foo") (list "uninterned"))
(cl-test "uninterned: value upcase" (cl-tok-values "#:foo") (list "FOO"))
(cl-test "uninterned: compound" (cl-tok-values "#:my-sym") (list "MY-SYM"))
;; ── parens and structure ──────────────────────────────────────────
(cl-test "paren: empty list" (cl-tok-types "()") (list "lparen" "rparen"))
(cl-test "paren: nested" (cl-tok-types "((a))") (list "lparen" "lparen" "symbol" "rparen" "rparen"))
(cl-test "dot: standalone" (cl-tok-types "(a . b)") (list "lparen" "symbol" "dot" "symbol" "rparen"))
;; ── comments ──────────────────────────────────────────────────────
(cl-test "comment: line" (cl-tok-types "; comment\nfoo") (list "symbol"))
(cl-test "comment: inline" (cl-tok-values "foo ; bar\nbaz") (list "FOO" "BAZ"))
(cl-test "block-comment: basic" (cl-tok-types "#| hello |# foo") (list "symbol"))
(cl-test "block-comment: nested" (cl-tok-types "#| a #| b |# c |# x") (list "symbol"))
;; ── combined ──────────────────────────────────────────────────────
(cl-test
"combined: defun skeleton"
(cl-tok-types "(defun foo (x) x)")
(list "lparen" "symbol" "symbol" "lparen" "symbol" "rparen" "symbol" "rparen"))
(cl-test
"combined: let form"
(cl-tok-types "(let ((x 1)) x)")
(list
"lparen"
"symbol"
"lparen"
"lparen"
"symbol"
"integer"
"rparen"
"rparen"
"symbol"
"rparen"))
(cl-test
"combined: whitespace skip"
(cl-tok-values " foo bar baz ")
(list "FOO" "BAR" "BAZ"))
(cl-test "eof: present" (get (nth (cl-tokenize "") 0) "type") "eof")
(cl-test "eof: at end of tokens" (get (nth (cl-tokenize "x") 1) "type") "eof")

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;; lib/common-lisp/tests/runtime.sx — tests for CL runtime layer
(load "lib/common-lisp/runtime.sx")
(defsuite
"cl-types"
(deftest "cl-null? nil" (assert= true (cl-null? nil)))
(deftest "cl-null? false" (assert= false (cl-null? false)))
(deftest
"cl-consp? pair"
(assert= true (cl-consp? (list 1 2))))
(deftest "cl-consp? nil" (assert= false (cl-consp? nil)))
(deftest "cl-listp? nil" (assert= true (cl-listp? nil)))
(deftest
"cl-listp? list"
(assert= true (cl-listp? (list 1 2))))
(deftest "cl-atom? nil" (assert= true (cl-atom? nil)))
(deftest "cl-atom? pair" (assert= false (cl-atom? (list 1))))
(deftest "cl-integerp?" (assert= true (cl-integerp? 42)))
(deftest "cl-floatp?" (assert= true (cl-floatp? 3.14)))
(deftest
"cl-characterp?"
(assert= true (cl-characterp? (integer->char 65))))
(deftest "cl-stringp?" (assert= true (cl-stringp? "hello")))
(deftest "cl-symbolp?" (assert= true (cl-symbolp? (quote foo)))))
(defsuite
"cl-arithmetic"
(deftest "cl-mod" (assert= 1 (cl-mod 10 3)))
(deftest "cl-rem" (assert= 1 (cl-rem 10 3)))
(deftest
"cl-quotient"
(assert= 3 (cl-quotient 10 3)))
(deftest "cl-gcd" (assert= 4 (cl-gcd 12 8)))
(deftest "cl-lcm" (assert= 12 (cl-lcm 4 6)))
(deftest "cl-abs pos" (assert= 5 (cl-abs 5)))
(deftest "cl-abs neg" (assert= 5 (cl-abs -5)))
(deftest "cl-min" (assert= 2 (cl-min 2 7)))
(deftest "cl-max" (assert= 7 (cl-max 2 7)))
(deftest "cl-evenp? t" (assert= true (cl-evenp? 4)))
(deftest "cl-evenp? f" (assert= false (cl-evenp? 3)))
(deftest "cl-oddp? t" (assert= true (cl-oddp? 7)))
(deftest "cl-zerop?" (assert= true (cl-zerop? 0)))
(deftest "cl-plusp?" (assert= true (cl-plusp? 1)))
(deftest "cl-minusp?" (assert= true (cl-minusp? -1)))
(deftest "cl-signum pos" (assert= 1 (cl-signum 42)))
(deftest "cl-signum neg" (assert= -1 (cl-signum -7)))
(deftest "cl-signum zero" (assert= 0 (cl-signum 0))))
(defsuite
"cl-chars"
(deftest
"cl-char-code"
(assert= 65 (cl-char-code (integer->char 65))))
(deftest "cl-code-char" (assert= true (char? (cl-code-char 65))))
(deftest
"cl-char-upcase"
(assert=
(integer->char 65)
(cl-char-upcase (integer->char 97))))
(deftest
"cl-char-downcase"
(assert=
(integer->char 97)
(cl-char-downcase (integer->char 65))))
(deftest
"cl-alpha-char-p"
(assert= true (cl-alpha-char-p (integer->char 65))))
(deftest
"cl-digit-char-p"
(assert= true (cl-digit-char-p (integer->char 48))))
(deftest
"cl-char=?"
(assert=
true
(cl-char=? (integer->char 65) (integer->char 65))))
(deftest
"cl-char<?"
(assert=
true
(cl-char<? (integer->char 65) (integer->char 90))))
(deftest
"cl-char space"
(assert= (integer->char 32) cl-char-space))
(deftest
"cl-char newline"
(assert= (integer->char 10) cl-char-newline)))
(defsuite
"cl-format"
(deftest
"cl-format nil basic"
(assert= "hello" (cl-format nil "~a" "hello")))
(deftest
"cl-format nil number"
(assert= "42" (cl-format nil "~d" 42)))
(deftest
"cl-format nil hex"
(assert= "ff" (cl-format nil "~x" 255)))
(deftest
"cl-format nil template"
(assert= "x=3 y=4" (cl-format nil "x=~d y=~d" 3 4)))
(deftest "cl-format nil tilde" (assert= "a~b" (cl-format nil "a~~b"))))
(defsuite
"cl-gensym"
(deftest
"cl-gensym returns symbol"
(assert= "symbol" (type-of (cl-gensym))))
(deftest "cl-gensym unique" (assert= false (= (cl-gensym) (cl-gensym)))))
(defsuite
"cl-sets"
(deftest "cl-make-set empty" (assert= true (cl-set? (cl-make-set))))
(deftest
"cl-set-add/member"
(let
((s (cl-make-set)))
(do
(cl-set-add s 1)
(assert= true (cl-set-memberp s 1)))))
(deftest
"cl-set-memberp false"
(assert= false (cl-set-memberp (cl-make-set) 42)))
(deftest
"cl-list->set"
(let
((s (cl-list->set (list 1 2 3))))
(assert= true (cl-set-memberp s 2)))))
(defsuite
"cl-lists"
(deftest
"cl-nth 0"
(assert=
1
(cl-nth 0 (list 1 2 3))))
(deftest
"cl-nth 2"
(assert=
3
(cl-nth 2 (list 1 2 3))))
(deftest
"cl-last"
(assert=
(list 3)
(cl-last (list 1 2 3))))
(deftest
"cl-butlast"
(assert=
(list 1 2)
(cl-butlast (list 1 2 3))))
(deftest
"cl-nthcdr 1"
(assert=
(list 2 3)
(cl-nthcdr 1 (list 1 2 3))))
(deftest
"cl-assoc hit"
(assert=
(list "b" 2)
(cl-assoc "b" (list (list "a" 1) (list "b" 2)))))
(deftest
"cl-assoc miss"
(assert= nil (cl-assoc "z" (list (list "a" 1)))))
(deftest
"cl-getf hit"
(assert= 42 (cl-getf (list "x" 42 "y" 99) "x")))
(deftest "cl-getf miss" (assert= nil (cl-getf (list "x" 42) "z")))
(deftest
"cl-adjoin new"
(assert=
(list 0 1 2)
(cl-adjoin 0 (list 1 2))))
(deftest
"cl-adjoin dup"
(assert=
(list 1 2)
(cl-adjoin 1 (list 1 2))))
(deftest
"cl-flatten"
(assert=
(list 1 2 3 4)
(cl-flatten (list 1 (list 2 3) 4))))
(deftest
"cl-member hit"
(assert=
(list 2 3)
(cl-member 2 (list 1 2 3))))
(deftest
"cl-member miss"
(assert=
nil
(cl-member 9 (list 1 2 3)))))
(defsuite
"cl-radix"
(deftest "binary" (assert= "1010" (cl-format-binary 10)))
(deftest "octal" (assert= "17" (cl-format-octal 15)))
(deftest "hex" (assert= "ff" (cl-format-hex 255)))
(deftest "decimal" (assert= "42" (cl-format-decimal 42)))
(deftest
"n->s r16"
(assert= "1f" (cl-integer-to-string 31 16)))
(deftest
"s->n r16"
(assert= 31 (cl-string-to-integer "1f" 16))))

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;; lib/common-lisp/tests/stdlib.sx — Phase 6: sequence, list, string functions
(define ev (fn (src) (cl-eval-str src (cl-make-env))))
(define passed 0)
(define failed 0)
(define failures (list))
(define
check
(fn
(label got expected)
(if
(= got expected)
(set! passed (+ passed 1))
(begin
(set! failed (+ failed 1))
(set!
failures
(append
failures
(list
(str
"FAIL ["
label
"]: got="
(inspect got)
" expected="
(inspect expected)))))))))
;; ── mapc ─────────────────────────────────────────────────────────
(check "mapc returns list"
(ev "(mapc #'1+ '(1 2 3))")
(list 1 2 3))
;; ── mapcan ───────────────────────────────────────────────────────
(check "mapcan basic"
(ev "(mapcan (lambda (x) (list x (* x x))) '(1 2 3))")
(list 1 1 2 4 3 9))
(check "mapcan filter-like"
(ev "(mapcan (lambda (x) (if (evenp x) (list x) nil)) '(1 2 3 4 5 6))")
(list 2 4 6))
;; ── reduce ───────────────────────────────────────────────────────
(check "reduce sum"
(ev "(reduce #'+ '(1 2 3 4 5))")
15)
(check "reduce with initial-value"
(ev "(reduce #'+ '(1 2 3) :initial-value 10)")
16)
(check "reduce max"
(ev "(reduce (lambda (a b) (if (> a b) a b)) '(3 1 4 1 5 9 2 6))")
9)
;; ── find ─────────────────────────────────────────────────────────
(check "find present"
(ev "(find 3 '(1 2 3 4 5))")
3)
(check "find absent"
(ev "(find 9 '(1 2 3))")
nil)
(check "find-if present"
(ev "(find-if #'evenp '(1 3 4 7))")
4)
(check "find-if absent"
(ev "(find-if #'evenp '(1 3 5))")
nil)
(check "find-if-not"
(ev "(find-if-not #'evenp '(2 4 5 6))")
5)
;; ── position ─────────────────────────────────────────────────────
(check "position found"
(ev "(position 3 '(1 2 3 4 5))")
2)
(check "position not found"
(ev "(position 9 '(1 2 3))")
nil)
(check "position-if"
(ev "(position-if #'evenp '(1 3 4 8))")
2)
;; ── count ────────────────────────────────────────────────────────
(check "count"
(ev "(count 2 '(1 2 3 2 4 2))")
3)
(check "count-if"
(ev "(count-if #'evenp '(1 2 3 4 5 6))")
3)
;; ── every / some / notany / notevery ─────────────────────────────
(check "every true"
(ev "(every #'evenp '(2 4 6))")
true)
(check "every false"
(ev "(every #'evenp '(2 3 6))")
nil)
(check "every empty"
(ev "(every #'evenp '())")
true)
(check "some truthy"
(ev "(some #'evenp '(1 3 4))")
true)
(check "some nil"
(ev "(some #'evenp '(1 3 5))")
nil)
(check "notany true"
(ev "(notany #'evenp '(1 3 5))")
true)
(check "notany false"
(ev "(notany #'evenp '(1 2 5))")
nil)
(check "notevery false"
(ev "(notevery #'evenp '(2 4 6))")
nil)
(check "notevery true"
(ev "(notevery #'evenp '(2 3 6))")
true)
;; ── remove ───────────────────────────────────────────────────────
(check "remove"
(ev "(remove 3 '(1 2 3 4 3 5))")
(list 1 2 4 5))
(check "remove-if"
(ev "(remove-if #'evenp '(1 2 3 4 5 6))")
(list 1 3 5))
(check "remove-if-not"
(ev "(remove-if-not #'evenp '(1 2 3 4 5 6))")
(list 2 4 6))
;; ── member ───────────────────────────────────────────────────────
(check "member found"
(ev "(member 3 '(1 2 3 4 5))")
(list 3 4 5))
(check "member not found"
(ev "(member 9 '(1 2 3))")
nil)
;; ── subst ────────────────────────────────────────────────────────
(check "subst flat"
(ev "(subst 'b 'a '(a b c a))")
(list "B" "B" "C" "B"))
(check "subst nested"
(ev "(subst 99 1 '(1 (2 1) 3))")
(list 99 (list 2 99) 3))
;; ── assoc ────────────────────────────────────────────────────────
(check "assoc found"
(ev "(assoc 'b '((a 1) (b 2) (c 3)))")
(list "B" 2))
(check "assoc not found"
(ev "(assoc 'z '((a 1) (b 2)))")
nil)
;; ── list ops ─────────────────────────────────────────────────────
(check "last"
(ev "(last '(1 2 3 4))")
(list 4))
(check "butlast"
(ev "(butlast '(1 2 3 4))")
(list 1 2 3))
(check "nthcdr"
(ev "(nthcdr 2 '(a b c d))")
(list "C" "D"))
(check "list*"
(ev "(list* 1 2 '(3 4))")
(list 1 2 3 4))
(check "cadr"
(ev "(cadr '(1 2 3))")
2)
(check "caddr"
(ev "(caddr '(1 2 3))")
3)
(check "cadddr"
(ev "(cadddr '(1 2 3 4))")
4)
(check "cddr"
(ev "(cddr '(1 2 3 4))")
(list 3 4))
;; ── subseq ───────────────────────────────────────────────────────
(check "subseq string"
(ev "(subseq \"hello\" 1 3)")
"el")
(check "subseq list"
(ev "(subseq '(a b c d) 1 3)")
(list "B" "C"))
(check "subseq no end"
(ev "(subseq \"hello\" 2)")
"llo")
;; ── FORMAT ─────────────────────────────────────────────────────────
(check "format ~A"
(ev "(format nil \"hello ~A\" \"world\")")
"hello world")
(check "format ~D"
(ev "(format nil \"~D items\" 42)")
"42 items")
(check "format two args"
(ev "(format nil \"~A ~A\" 1 2)")
"1 2")
(check "format ~A+~A=~A"
(ev "(format nil \"~A + ~A = ~A\" 1 2 3)")
"1 + 2 = 3")
(check "format iterate"
(ev "(format nil \"~{~A~}\" (quote (1 2 3)))")
"123")
(check "format iterate with space"
(ev "(format nil \"(~{~A ~})\" (quote (1 2 3)))")
"(1 2 3 )")
;; ── packages ─────────────────────────────────────────────────────
(check "defpackage returns name"
(ev "(defpackage :my-pkg (:use :cl))")
"MY-PKG")
(check "in-package"
(ev "(progn (defpackage :test-pkg) (in-package :test-pkg) (package-name))")
"TEST-PKG")
(check "package-qualified function"
(ev "(cl:car (quote (1 2 3)))")
1)
(check "package-qualified function 2"
(ev "(cl:mapcar (function evenp) (quote (2 3 4)))")
(list true nil true))
;; ── summary ──────────────────────────────────────────────────────
(define stdlib-passed passed)
(define stdlib-failed failed)
(define stdlib-failures failures)

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#!/usr/bin/env bash
# Erlang-on-SX ring benchmark.
#
# Spawns N processes in a ring, passes a token N hops (one full round),
# and reports wall-clock time + throughput. Aspirational target from
# the plan is 1M processes; current sync-scheduler architecture caps out
# orders of magnitude lower — this script measures honestly across a
# range of N so the result/scaling is recorded.
#
# Usage:
# bash lib/erlang/bench_ring.sh # default ladder
# bash lib/erlang/bench_ring.sh 100 1000 5000 # custom Ns
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found." >&2
exit 1
fi
if [ "$#" -gt 0 ]; then
NS=("$@")
else
NS=(10 100 500 1000)
fi
TMPFILE=$(mktemp)
trap "rm -f $TMPFILE" EXIT
# One-line Erlang program. Replaces __N__ with the size for each run.
PROGRAM='Me = self(), N = __N__, Spawner = fun () -> receive {setup, Next} -> Loop = fun () -> receive {token, 0, Parent} -> Parent ! done; {token, K, Parent} -> Next ! {token, K-1, Parent}, Loop() end end, Loop() end end, BuildRing = fun (K, Acc) -> if K =:= 0 -> Acc; true -> BuildRing(K-1, [spawn(Spawner) | Acc]) end end, Pids = BuildRing(N, []), Wire = fun (Ps) -> case Ps of [P, Q | _] -> P ! {setup, Q}, Wire(tl(Ps)); [Last] -> Last ! {setup, hd(Pids)} end end, Wire(Pids), hd(Pids) ! {token, N, Me}, receive done -> done end'
run_n() {
local n="$1"
local prog="${PROGRAM//__N__/$n}"
cat > "$TMPFILE" <<EPOCHS
(epoch 1)
(load "lib/erlang/tokenizer.sx")
(load "lib/erlang/parser.sx")
(load "lib/erlang/parser-core.sx")
(load "lib/erlang/parser-expr.sx")
(load "lib/erlang/parser-module.sx")
(load "lib/erlang/transpile.sx")
(load "lib/erlang/runtime.sx")
(epoch 2)
(eval "(erlang-eval-ast \"${prog//\"/\\\"}\")")
EPOCHS
local start_s start_ns end_s end_ns elapsed_ms
start_s=$(date +%s)
start_ns=$(date +%N)
out=$(timeout 300 "$SX_SERVER" < "$TMPFILE" 2>&1)
end_s=$(date +%s)
end_ns=$(date +%N)
local ok="false"
if echo "$out" | grep -q ':name "done"'; then ok="true"; fi
# ms = (end_s - start_s)*1000 + (end_ns - start_ns)/1e6
elapsed_ms=$(awk -v s1="$start_s" -v n1="$start_ns" -v s2="$end_s" -v n2="$end_ns" \
'BEGIN { printf "%d", (s2 - s1) * 1000 + (n2 - n1) / 1000000 }')
if [ "$ok" = "true" ]; then
local hops_per_s
hops_per_s=$(awk -v n="$n" -v ms="$elapsed_ms" \
'BEGIN { if (ms == 0) ms = 1; printf "%.0f", n * 1000 / ms }')
printf " N=%-8s hops=%-8s %sms (%s hops/s)\n" "$n" "$n" "$elapsed_ms" "$hops_per_s"
else
printf " N=%-8s FAILED %sms\n" "$n" "$elapsed_ms"
fi
}
echo "Ring benchmark — sx_server.exe (synchronous scheduler)"
echo
for n in "${NS[@]}"; do
run_n "$n"
done
echo
echo "Note: 1M-process target from the plan is aspirational; the synchronous"
echo "scheduler with shift-based suspension and dict-based env copies is not"
echo "engineered for that scale. Numbers above are honest baselines."

35
lib/erlang/bench_ring_results.md Normal file
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@@ -0,0 +1,35 @@
# Ring Benchmark Results
Generated by `lib/erlang/bench_ring.sh` against `sx_server.exe` on the
synchronous Erlang-on-SX scheduler.
| N (processes) | Hops | Wall-clock | Throughput |
|---|---|---|---|
| 10 | 10 | 907ms | 11 hops/s |
| 50 | 50 | 2107ms | 24 hops/s |
| 100 | 100 | 3827ms | 26 hops/s |
| 500 | 500 | 17004ms | 29 hops/s |
| 1000 | 1000 | 29832ms | 34 hops/s |
(Each `Nm` row spawns N processes connected in a ring and passes a
single token N hops total — i.e. the token completes one full lap.)
## Status of the 1M-process target
Phase 3's stretch goal in `plans/erlang-on-sx.md` is a million-process
ring benchmark. **That target is not met** in the current synchronous
scheduler; extrapolating from the table above, 1M hops would take
~30 000 s. Correctness is fine — the program runs at every measured
size — but throughput is bound by per-hop overhead.
Per-hop cost is dominated by:
- `er-env-copy` per fun clause attempt (whole-dict copy each time)
- `call/cc` capture + `raise`/`guard` unwind on every `receive`
- `er-q-delete-at!` rebuilds the mailbox backing list on every match
- `dict-set!`/`dict-has?` lookups in the global processes table
To reach 1M-process throughput in this architecture would need at
least: persistent (path-copying) envs, an inline scheduler that
doesn't call/cc on the common path (msg-already-in-mailbox), and a
linked-list mailbox. None of those are in scope for the Phase 3
checkbox — captured here as the floor we're starting from.

153
lib/erlang/conformance.sh Executable file
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@@ -0,0 +1,153 @@
#!/usr/bin/env bash
# Erlang-on-SX conformance runner.
#
# Loads every erlang test suite via the epoch protocol, collects
# pass/fail counts, and writes lib/erlang/scoreboard.json + .md.
#
# Usage:
# bash lib/erlang/conformance.sh # run all suites
# bash lib/erlang/conformance.sh -v # verbose per-suite
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found." >&2
exit 1
fi
VERBOSE="${1:-}"
TMPFILE=$(mktemp)
OUTFILE=$(mktemp)
trap "rm -f $TMPFILE $OUTFILE" EXIT
# Each suite: name | counter pass | counter total
SUITES=(
"tokenize|er-test-pass|er-test-count"
"parse|er-parse-test-pass|er-parse-test-count"
"eval|er-eval-test-pass|er-eval-test-count"
"runtime|er-rt-test-pass|er-rt-test-count"
"ring|er-ring-test-pass|er-ring-test-count"
"ping-pong|er-pp-test-pass|er-pp-test-count"
"bank|er-bank-test-pass|er-bank-test-count"
"echo|er-echo-test-pass|er-echo-test-count"
"fib|er-fib-test-pass|er-fib-test-count"
)
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "lib/erlang/tokenizer.sx")
(load "lib/erlang/parser.sx")
(load "lib/erlang/parser-core.sx")
(load "lib/erlang/parser-expr.sx")
(load "lib/erlang/parser-module.sx")
(load "lib/erlang/transpile.sx")
(load "lib/erlang/runtime.sx")
(load "lib/erlang/tests/tokenize.sx")
(load "lib/erlang/tests/parse.sx")
(load "lib/erlang/tests/eval.sx")
(load "lib/erlang/tests/runtime.sx")
(load "lib/erlang/tests/programs/ring.sx")
(load "lib/erlang/tests/programs/ping_pong.sx")
(load "lib/erlang/tests/programs/bank.sx")
(load "lib/erlang/tests/programs/echo.sx")
(load "lib/erlang/tests/programs/fib_server.sx")
(epoch 100)
(eval "(list er-test-pass er-test-count)")
(epoch 101)
(eval "(list er-parse-test-pass er-parse-test-count)")
(epoch 102)
(eval "(list er-eval-test-pass er-eval-test-count)")
(epoch 103)
(eval "(list er-rt-test-pass er-rt-test-count)")
(epoch 104)
(eval "(list er-ring-test-pass er-ring-test-count)")
(epoch 105)
(eval "(list er-pp-test-pass er-pp-test-count)")
(epoch 106)
(eval "(list er-bank-test-pass er-bank-test-count)")
(epoch 107)
(eval "(list er-echo-test-pass er-echo-test-count)")
(epoch 108)
(eval "(list er-fib-test-pass er-fib-test-count)")
EPOCHS
timeout 120 "$SX_SERVER" < "$TMPFILE" > "$OUTFILE" 2>&1
# Parse "(N M)" from the line after each "(ok-len <epoch> ...)" marker.
parse_pair() {
local epoch="$1"
local line
line=$(grep -A1 "^(ok-len $epoch " "$OUTFILE" | tail -1)
echo "$line" | sed -E 's/[()]//g'
}
TOTAL_PASS=0
TOTAL_COUNT=0
JSON_SUITES=""
MD_ROWS=""
idx=0
for entry in "${SUITES[@]}"; do
name="${entry%%|*}"
epoch=$((100 + idx))
pair=$(parse_pair "$epoch")
pass=$(echo "$pair" | awk '{print $1}')
count=$(echo "$pair" | awk '{print $2}')
if [ -z "$pass" ] || [ -z "$count" ]; then
pass=0
count=0
fi
TOTAL_PASS=$((TOTAL_PASS + pass))
TOTAL_COUNT=$((TOTAL_COUNT + count))
status="ok"
marker="✅"
if [ "$pass" != "$count" ]; then
status="fail"
marker="❌"
fi
if [ "$VERBOSE" = "-v" ]; then
printf " %-12s %s/%s\n" "$name" "$pass" "$count"
fi
if [ -n "$JSON_SUITES" ]; then JSON_SUITES+=","; fi
JSON_SUITES+=$'\n '
JSON_SUITES+="{\"name\":\"$name\",\"pass\":$pass,\"total\":$count,\"status\":\"$status\"}"
MD_ROWS+="| $marker | $name | $pass | $count |"$'\n'
idx=$((idx + 1))
done
printf '\nErlang-on-SX conformance: %d / %d\n' "$TOTAL_PASS" "$TOTAL_COUNT"
# scoreboard.json
cat > lib/erlang/scoreboard.json <<JSON
{
"language": "erlang",
"total_pass": $TOTAL_PASS,
"total": $TOTAL_COUNT,
"suites": [$JSON_SUITES
]
}
JSON
# scoreboard.md
cat > lib/erlang/scoreboard.md <<MD
# Erlang-on-SX Scoreboard
**Total: ${TOTAL_PASS} / ${TOTAL_COUNT} tests passing**
| | Suite | Pass | Total |
|---|---|---|---|
$MD_ROWS
Generated by \`lib/erlang/conformance.sh\`.
MD
if [ "$TOTAL_PASS" -eq "$TOTAL_COUNT" ]; then
exit 0
else
exit 1
fi

114
lib/erlang/parser-expr.sx
View File

@@ -237,6 +237,8 @@
(er-parse-fun-expr st)
(er-is? st "keyword" "try")
(er-parse-try st)
(er-is? st "punct" "<<")
(er-parse-binary st)
:else (error
(str
"Erlang parse: unexpected "
@@ -281,12 +283,56 @@
(fn
(st)
(er-expect! st "punct" "[")
(if
(cond
(er-is? st "punct" "]")
(do (er-advance! st) {:type "nil"})
(let
((elems (list (er-parse-expr-prec st 0))))
(er-parse-list-tail st elems)))))
:else (let
((first (er-parse-expr-prec st 0)))
(cond
(er-is? st "punct" "||") (er-parse-list-comp st first)
:else (er-parse-list-tail st (list first)))))))
(define
er-parse-list-comp
(fn
(st head)
(er-advance! st)
(let
((quals (list (er-parse-lc-qualifier st))))
(er-parse-list-comp-tail st head quals))))
(define
er-parse-list-comp-tail
(fn
(st head quals)
(cond
(er-is? st "punct" ",")
(do
(er-advance! st)
(append! quals (er-parse-lc-qualifier st))
(er-parse-list-comp-tail st head quals))
(er-is? st "punct" "]")
(do (er-advance! st) {:head head :qualifiers quals :type "lc"})
:else (error
(str
"Erlang parse: expected ',' or ']' in list comprehension, got '"
(er-cur-value st)
"'")))))
(define
er-parse-lc-qualifier
(fn
(st)
(let
((e (er-parse-expr-prec st 0)))
(cond
(er-is? st "punct" "<-")
(do
(er-advance! st)
(let
((source (er-parse-expr-prec st 0)))
{:kind "gen" :pattern e :source source}))
:else {:kind "filter" :expr e}))))
(define
er-parse-list-tail
@@ -532,3 +578,63 @@
((guards (if (er-is? st "keyword" "when") (do (er-advance! st) (er-parse-guards st)) (list))))
(er-expect! st "punct" "->")
(let ((body (er-parse-body st))) {:pattern pat :body body :class klass :guards guards}))))))
;; ── binary literals / patterns ────────────────────────────────
;; `<< [Seg {, Seg}] >>` where Seg = Value [: Size] [/ Spec]. Size is
;; a literal integer (multiple of 8 supported); Spec is `integer`
;; (default) or `binary` (rest-of-binary tail). Sufficient for the
;; common `<<A:8, B:16, Rest/binary>>` patterns.
(define
er-parse-binary
(fn
(st)
(er-expect! st "punct" "<<")
(cond
(er-is? st "punct" ">>")
(do (er-advance! st) {:segments (list) :type "binary"})
:else (let
((segs (list (er-parse-binary-segment st))))
(er-parse-binary-tail st segs)))))
(define
er-parse-binary-tail
(fn
(st segs)
(cond
(er-is? st "punct" ",")
(do
(er-advance! st)
(append! segs (er-parse-binary-segment st))
(er-parse-binary-tail st segs))
(er-is? st "punct" ">>")
(do (er-advance! st) {:segments segs :type "binary"})
:else (error
(str
"Erlang parse: expected ',' or '>>' in binary, got '"
(er-cur-value st)
"'")))))
(define
er-parse-binary-segment
(fn
(st)
;; Use `er-parse-primary` for the value so a leading `:` falls
;; through to the segment's size suffix instead of being eaten
;; by `er-parse-postfix-loop` as a `Mod:Fun` remote call.
(let
((v (er-parse-primary st)))
(let
((size (cond
(er-is? st "punct" ":")
(do (er-advance! st) (er-parse-primary st))
:else nil))
(spec (cond
(er-is? st "op" "/")
(do
(er-advance! st)
(let
((tok (er-cur st)))
(er-advance! st)
(get tok :value)))
:else "integer")))
{:size size :spec spec :value v}))))

1204
lib/erlang/runtime.sx Normal file
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16
lib/erlang/scoreboard.json Normal file
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@@ -0,0 +1,16 @@
{
"language": "erlang",
"total_pass": 530,
"total": 530,
"suites": [
{"name":"tokenize","pass":62,"total":62,"status":"ok"},
{"name":"parse","pass":52,"total":52,"status":"ok"},
{"name":"eval","pass":346,"total":346,"status":"ok"},
{"name":"runtime","pass":39,"total":39,"status":"ok"},
{"name":"ring","pass":4,"total":4,"status":"ok"},
{"name":"ping-pong","pass":4,"total":4,"status":"ok"},
{"name":"bank","pass":8,"total":8,"status":"ok"},
{"name":"echo","pass":7,"total":7,"status":"ok"},
{"name":"fib","pass":8,"total":8,"status":"ok"}
]
}

18
lib/erlang/scoreboard.md Normal file
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@@ -0,0 +1,18 @@
# Erlang-on-SX Scoreboard
**Total: 530 / 530 tests passing**
| | Suite | Pass | Total |
|---|---|---|---|
| ✅ | tokenize | 62 | 62 |
| ✅ | parse | 52 | 52 |
| ✅ | eval | 346 | 346 |
| ✅ | runtime | 39 | 39 |
| ✅ | ring | 4 | 4 |
| ✅ | ping-pong | 4 | 4 |
| ✅ | bank | 8 | 8 |
| ✅ | echo | 7 | 7 |
| ✅ | fib | 8 | 8 |
Generated by `lib/erlang/conformance.sh`.

260
lib/erlang/test.sh Executable file
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@@ -0,0 +1,260 @@
#!/usr/bin/env bash
# lib/erlang/test.sh — smoke-test the Erlang runtime layer.
# Uses sx_server.exe epoch protocol.
#
# Usage:
# bash lib/erlang/test.sh
# bash lib/erlang/test.sh -v
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found. Run: cd hosts/ocaml && dune build"
exit 1
fi
VERBOSE="${1:-}"
PASS=0; FAIL=0; ERRORS=""
TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "lib/erlang/runtime.sx")
;; --- Numeric tower ---
(epoch 10)
(eval "(er-is-integer? 42)")
(epoch 11)
(eval "(er-is-integer? 3.14)")
(epoch 12)
(eval "(er-is-float? 3.14)")
(epoch 13)
(eval "(er-is-float? 42)")
(epoch 14)
(eval "(er-is-number? 42)")
(epoch 15)
(eval "(er-is-number? 3.14)")
(epoch 16)
(eval "(er-float 5)")
(epoch 17)
(eval "(er-trunc 3.9)")
(epoch 18)
(eval "(er-round 3.5)")
(epoch 19)
(eval "(er-abs -7)")
(epoch 20)
(eval "(er-max 3 7)")
(epoch 21)
(eval "(er-min 3 7)")
;; --- div + rem ---
(epoch 30)
(eval "(er-div 10 3)")
(epoch 31)
(eval "(er-div -10 3)")
(epoch 32)
(eval "(er-rem 10 3)")
(epoch 33)
(eval "(er-rem -10 3)")
(epoch 34)
(eval "(er-gcd 12 8)")
;; --- Bitwise ---
(epoch 40)
(eval "(er-band 12 10)")
(epoch 41)
(eval "(er-bor 12 10)")
(epoch 42)
(eval "(er-bxor 12 10)")
(epoch 43)
(eval "(er-bnot 0)")
(epoch 44)
(eval "(er-bsl 1 4)")
(epoch 45)
(eval "(er-bsr 16 2)")
;; --- Sets ---
(epoch 50)
(eval "(er-sets-is-set? (er-sets-new))")
(epoch 51)
(eval "(let ((s (er-sets-new))) (do (er-sets-add-element s 1) (er-sets-is-element s 1)))")
(epoch 52)
(eval "(er-sets-is-element (er-sets-new) 42)")
(epoch 53)
(eval "(er-sets-is-element (er-sets-from-list (list 1 2 3)) 2)")
(epoch 54)
(eval "(er-sets-size (er-sets-from-list (list 1 2 3)))")
(epoch 55)
(eval "(len (er-sets-to-list (er-sets-from-list (list 1 2 3))))")
;; --- Regexp ---
(epoch 60)
(eval "(not (= (er-re-run \"hello\" \"ll\") nil))")
(epoch 61)
(eval "(= (er-re-run \"hello\" \"xyz\") nil)")
(epoch 62)
(eval "(get (er-re-run \"hello\" \"ll\") :match)")
(epoch 63)
(eval "(er-re-replace \"hello\" \"l\" \"r\")")
(epoch 64)
(eval "(er-re-replace-all \"hello\" \"l\" \"r\")")
(epoch 65)
(eval "(er-re-match-groups (er-re-run \"hello world\" \"(\\w+)\\s+(\\w+)\"))")
(epoch 66)
(eval "(len (er-re-split \"a,b,c\" \",\"))")
;; --- List BIFs ---
(epoch 70)
(eval "(er-hd (list 1 2 3))")
(epoch 71)
(eval "(er-tl (list 1 2 3))")
(epoch 72)
(eval "(er-length (list 1 2 3))")
(epoch 73)
(eval "(er-lists-member 2 (list 1 2 3))")
(epoch 74)
(eval "(er-lists-member 9 (list 1 2 3))")
(epoch 75)
(eval "(er-lists-reverse (list 1 2 3))")
(epoch 76)
(eval "(er-lists-nth 2 (list 10 20 30))")
(epoch 77)
(eval "(er-lists-foldl + 0 (list 1 2 3 4 5))")
(epoch 78)
(eval "(er-lists-seq 1 5)")
(epoch 79)
(eval "(er-lists-flatten (list 1 (list 2 3) (list 4 (list 5))))")
;; --- Type conversions ---
(epoch 80)
(eval "(er-integer-to-list 42)")
(epoch 81)
(eval "(er-list-to-integer \"42\")")
(epoch 82)
(eval "(er-integer-to-list-radix 255 16)")
(epoch 83)
(eval "(er-atom-to-list (make-symbol \"hello\"))")
(epoch 84)
(eval "(= (type-of (er-list-to-atom \"foo\")) \"symbol\")")
;; --- ok/error tuples ---
(epoch 90)
(eval "(er-is-ok? (er-ok 42))")
(epoch 91)
(eval "(er-is-error? (er-error \"reason\"))")
(epoch 92)
(eval "(er-unwrap (er-ok 42))")
(epoch 93)
(eval "(er-is-ok? (er-error \"bad\"))")
EPOCHS
OUTPUT=$(timeout 30 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
check() {
local epoch="$1" desc="$2" expected="$3"
local actual
actual=$(echo "$OUTPUT" | grep -A1 "^(ok-len $epoch " | tail -1 || true)
if echo "$actual" | grep -q "^(ok-len"; then actual=""; fi
if [ -z "$actual" ]; then
actual=$(echo "$OUTPUT" | grep "^(ok $epoch " | head -1 || true)
fi
if [ -z "$actual" ]; then
actual=$(echo "$OUTPUT" | grep "^(error $epoch " | head -1 || true)
fi
[ -z "$actual" ] && actual="<no output for epoch $epoch>"
if echo "$actual" | grep -qF -- "$expected"; then
PASS=$((PASS+1))
[ "$VERBOSE" = "-v" ] && echo " ok $desc"
else
FAIL=$((FAIL+1))
ERRORS+=" FAIL [$desc] (epoch $epoch) expected: $expected | actual: $actual
"
fi
}
# Numeric tower
check 10 "is-integer? 42" "true"
check 11 "is-integer? float" "false"
check 12 "is-float? 3.14" "true"
check 13 "is-float? int" "false"
check 14 "is-number? int" "true"
check 15 "is-number? float" "true"
check 16 "float 5" "5"
check 17 "trunc 3.9" "3"
check 18 "round 3.5" "4"
check 19 "abs -7" "7"
check 20 "max 3 7" "7"
check 21 "min 3 7" "3"
# div + rem
check 30 "div 10 3" "3"
check 31 "div -10 3" "-3"
check 32 "rem 10 3" "1"
check 33 "rem -10 3" "-1"
check 34 "gcd 12 8" "4"
# Bitwise
check 40 "band 12 10" "8"
check 41 "bor 12 10" "14"
check 42 "bxor 12 10" "6"
check 43 "bnot 0" "-1"
check 44 "bsl 1 4" "16"
check 45 "bsr 16 2" "4"
# Sets
check 50 "sets-new is-set?" "true"
check 51 "sets add+member" "true"
check 52 "member empty" "false"
check 53 "from-list member" "true"
check 54 "sets-size" "3"
check 55 "sets-to-list len" "3"
# Regexp
check 60 "re-run match" "true"
check 61 "re-run no match" "true"
check 62 "re-run match text" '"ll"'
check 63 "re-replace first" '"herlo"'
check 64 "re-replace-all" '"herro"'
check 65 "re-match-groups" '"hello"'
check 66 "re-split count" "3"
# List BIFs
check 70 "hd" "1"
check 71 "tl" "(2 3)"
check 72 "length" "3"
check 73 "member hit" "true"
check 74 "member miss" "false"
check 75 "reverse" "(3 2 1)"
check 76 "nth 2" "20"
check 77 "foldl sum" "15"
check 78 "seq 1..5" "(1 2 3 4 5)"
check 79 "flatten" "(1 2 3 4 5)"
# Type conversions
check 80 "integer-to-list" '"42"'
check 81 "list-to-integer" "42"
check 82 "integer-to-list hex" '"ff"'
check 83 "atom-to-list" '"hello"'
check 84 "list-to-atom" "true"
# ok/error
check 90 "ok? ok-tuple" "true"
check 91 "error? error-tuple" "true"
check 92 "unwrap ok" "42"
check 93 "ok? error-tuple" "false"
TOTAL=$((PASS+FAIL))
if [ $FAIL -eq 0 ]; then
echo "ok $PASS/$TOTAL lib/erlang tests passed"
else
echo "FAIL $PASS/$TOTAL passed, $FAIL failed:"
echo "$ERRORS"
fi
[ $FAIL -eq 0 ]

1130
lib/erlang/tests/eval.sx Normal file
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159
lib/erlang/tests/programs/bank.sx Normal file
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@@ -0,0 +1,159 @@
;; Bank account server — stateful process, balance threaded through
;; recursive loop. Handles {deposit, Amt, From}, {withdraw, Amt, From},
;; {balance, From}, stop. Tests stateful process patterns.
(define er-bank-test-count 0)
(define er-bank-test-pass 0)
(define er-bank-test-fails (list))
(define
er-bank-test
(fn
(name actual expected)
(set! er-bank-test-count (+ er-bank-test-count 1))
(if
(= actual expected)
(set! er-bank-test-pass (+ er-bank-test-pass 1))
(append! er-bank-test-fails {:actual actual :expected expected :name name}))))
(define bank-ev erlang-eval-ast)
;; Server fun shared by all tests — threaded via the program string.
(define
er-bank-server-src
"Server = fun (Balance) ->
receive
{deposit, Amt, From} -> From ! ok, Server(Balance + Amt);
{withdraw, Amt, From} ->
if Amt > Balance -> From ! insufficient, Server(Balance);
true -> From ! ok, Server(Balance - Amt)
end;
{balance, From} -> From ! Balance, Server(Balance);
stop -> ok
end
end")
;; Open account, deposit, check balance.
(er-bank-test
"deposit 100 -> balance 100"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(0) end),
Bank ! {deposit, 100, Me},
receive ok -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
100)
;; Multiple deposits accumulate.
(er-bank-test
"deposits accumulate"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(0) end),
Bank ! {deposit, 50, Me}, receive ok -> ok end,
Bank ! {deposit, 25, Me}, receive ok -> ok end,
Bank ! {deposit, 10, Me}, receive ok -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
85)
;; Withdraw within balance succeeds; insufficient gets rejected.
(er-bank-test
"withdraw within balance"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(100) end),
Bank ! {withdraw, 30, Me}, receive ok -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
70)
(er-bank-test
"withdraw insufficient"
(get
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(20) end),
Bank ! {withdraw, 100, Me},
receive R -> Bank ! stop, R end"))
:name)
"insufficient")
;; State preserved across an insufficient withdrawal.
(er-bank-test
"state preserved on rejection"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(50) end),
Bank ! {withdraw, 1000, Me}, receive _ -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
50)
;; Mixed deposits and withdrawals.
(er-bank-test
"mixed transactions"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(100) end),
Bank ! {deposit, 50, Me}, receive ok -> ok end,
Bank ! {withdraw, 30, Me}, receive ok -> ok end,
Bank ! {deposit, 10, Me}, receive ok -> ok end,
Bank ! {withdraw, 5, Me}, receive ok -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
125)
;; Server.stop terminates the bank cleanly — main can verify by
;; sending stop and then exiting normally.
(er-bank-test
"server stops cleanly"
(get
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(0) end),
Bank ! stop,
done"))
:name)
"done")
;; Two clients sharing one bank — interleaved transactions.
(er-bank-test
"two clients share bank"
(bank-ev
(str
er-bank-server-src
", Me = self(),
Bank = spawn(fun () -> Server(0) end),
Client = fun (Amt) ->
spawn(fun () ->
Bank ! {deposit, Amt, self()},
receive ok -> Me ! deposited end
end)
end,
Client(40),
Client(60),
receive deposited -> ok end,
receive deposited -> ok end,
Bank ! {balance, Me},
receive B -> Bank ! stop, B end"))
100)
(define
er-bank-test-summary
(str "bank " er-bank-test-pass "/" er-bank-test-count))

140
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;; Echo server — minimal classic Erlang server. Receives {From, Msg}
;; and sends Msg back to From, then loops. `stop` ends the server.
(define er-echo-test-count 0)
(define er-echo-test-pass 0)
(define er-echo-test-fails (list))
(define
er-echo-test
(fn
(name actual expected)
(set! er-echo-test-count (+ er-echo-test-count 1))
(if
(= actual expected)
(set! er-echo-test-pass (+ er-echo-test-pass 1))
(append! er-echo-test-fails {:actual actual :expected expected :name name}))))
(define echo-ev erlang-eval-ast)
(define
er-echo-server-src
"EchoSrv = fun () ->
Loop = fun () ->
receive
{From, Msg} -> From ! Msg, Loop();
stop -> ok
end
end,
Loop()
end")
;; Single round-trip with an atom.
(er-echo-test
"atom round-trip"
(get
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Echo ! {Me, hello},
receive R -> Echo ! stop, R end"))
:name)
"hello")
;; Number round-trip.
(er-echo-test
"number round-trip"
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Echo ! {Me, 42},
receive R -> Echo ! stop, R end"))
42)
;; Tuple round-trip — pattern-match the reply to extract V.
(er-echo-test
"tuple round-trip"
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Echo ! {Me, {ok, 7}},
receive {ok, V} -> Echo ! stop, V end"))
7)
;; List round-trip.
(er-echo-test
"list round-trip"
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Echo ! {Me, [1, 2, 3]},
receive [H | _] -> Echo ! stop, H end"))
1)
;; Multiple sequential round-trips.
(er-echo-test
"three round-trips"
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Echo ! {Me, 10}, A = receive Ra -> Ra end,
Echo ! {Me, 20}, B = receive Rb -> Rb end,
Echo ! {Me, 30}, C = receive Rc -> Rc end,
Echo ! stop,
A + B + C"))
60)
;; Two clients sharing one echo server. Each gets its own reply.
(er-echo-test
"two clients"
(get
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Client = fun (Tag) ->
spawn(fun () ->
Echo ! {self(), Tag},
receive R -> Me ! {got, R} end
end)
end,
Client(a),
Client(b),
receive {got, _} -> ok end,
receive {got, _} -> ok end,
Echo ! stop,
finished"))
:name)
"finished")
;; Echo via io trace — verify each message round-trips through.
(er-echo-test
"trace 4 messages"
(do
(er-io-flush!)
(echo-ev
(str
er-echo-server-src
", Me = self(),
Echo = spawn(EchoSrv),
Send = fun (V) -> Echo ! {Me, V}, receive R -> io:format(\"~p \", [R]) end end,
Send(1), Send(2), Send(3), Send(4),
Echo ! stop,
done"))
(er-io-buffer-content))
"1 2 3 4 ")
(define
er-echo-test-summary
(str "echo " er-echo-test-pass "/" er-echo-test-count))

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;; Fib server — long-lived process that computes fibonacci numbers on
;; request. Tests recursive function evaluation inside a server loop.
(define er-fib-test-count 0)
(define er-fib-test-pass 0)
(define er-fib-test-fails (list))
(define
er-fib-test
(fn
(name actual expected)
(set! er-fib-test-count (+ er-fib-test-count 1))
(if
(= actual expected)
(set! er-fib-test-pass (+ er-fib-test-pass 1))
(append! er-fib-test-fails {:actual actual :expected expected :name name}))))
(define fib-ev erlang-eval-ast)
;; Fib + server-loop source. Standalone so each test can chain queries.
(define
er-fib-server-src
"Fib = fun (0) -> 0; (1) -> 1; (N) -> Fib(N-1) + Fib(N-2) end,
FibSrv = fun () ->
Loop = fun () ->
receive
{fib, N, From} -> From ! Fib(N), Loop();
stop -> ok
end
end,
Loop()
end")
;; Base cases.
(er-fib-test
"fib(0)"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 0, Me},
receive R -> Srv ! stop, R end"))
0)
(er-fib-test
"fib(1)"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 1, Me},
receive R -> Srv ! stop, R end"))
1)
;; Larger values.
(er-fib-test
"fib(10) = 55"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 10, Me},
receive R -> Srv ! stop, R end"))
55)
(er-fib-test
"fib(15) = 610"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 15, Me},
receive R -> Srv ! stop, R end"))
610)
;; Multiple sequential queries to one server. Sum to avoid dict-equality.
(er-fib-test
"sequential fib(5..8) sum"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 5, Me}, A = receive Ra -> Ra end,
Srv ! {fib, 6, Me}, B = receive Rb -> Rb end,
Srv ! {fib, 7, Me}, C = receive Rc -> Rc end,
Srv ! {fib, 8, Me}, D = receive Rd -> Rd end,
Srv ! stop,
A + B + C + D"))
47)
;; Verify Fib obeys the recurrence — fib(n) = fib(n-1) + fib(n-2).
(er-fib-test
"fib recurrence at n=12"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Srv ! {fib, 10, Me}, A = receive Ra -> Ra end,
Srv ! {fib, 11, Me}, B = receive Rb -> Rb end,
Srv ! {fib, 12, Me}, C = receive Rc -> Rc end,
Srv ! stop,
C - (A + B)"))
0)
;; Two clients each get their own answer; main sums the results.
(er-fib-test
"two clients sum"
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Client = fun (N) ->
spawn(fun () ->
Srv ! {fib, N, self()},
receive R -> Me ! {result, R} end
end)
end,
Client(7),
Client(9),
{result, A} = receive M1 -> M1 end,
{result, B} = receive M2 -> M2 end,
Srv ! stop,
A + B"))
47)
;; Trace queries via io-buffer.
(er-fib-test
"trace fib 0..6"
(do
(er-io-flush!)
(fib-ev
(str
er-fib-server-src
", Me = self(),
Srv = spawn(FibSrv),
Ask = fun (N) -> Srv ! {fib, N, Me}, receive R -> io:format(\"~p \", [R]) end end,
Ask(0), Ask(1), Ask(2), Ask(3), Ask(4), Ask(5), Ask(6),
Srv ! stop,
done"))
(er-io-buffer-content))
"0 1 1 2 3 5 8 ")
(define
er-fib-test-summary
(str "fib " er-fib-test-pass "/" er-fib-test-count))

127
lib/erlang/tests/programs/ping_pong.sx Normal file
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;; Ping-pong program — two processes exchange N messages, then signal
;; main via separate `ping_done` / `pong_done` notifications.
(define er-pp-test-count 0)
(define er-pp-test-pass 0)
(define er-pp-test-fails (list))
(define
er-pp-test
(fn
(name actual expected)
(set! er-pp-test-count (+ er-pp-test-count 1))
(if
(= actual expected)
(set! er-pp-test-pass (+ er-pp-test-pass 1))
(append! er-pp-test-fails {:actual actual :expected expected :name name}))))
(define pp-ev erlang-eval-ast)
;; Three rounds of ping-pong, then stop. Main receives ping_done and
;; pong_done in arrival order (Ping finishes first because Pong exits
;; only after receiving stop).
(define
er-pp-program
"Me = self(),
Pong = spawn(fun () ->
Loop = fun () ->
receive
{ping, From} -> From ! pong, Loop();
stop -> Me ! pong_done
end
end,
Loop()
end),
Ping = fun (Target, K) ->
if K =:= 0 -> Target ! stop, Me ! ping_done;
true -> Target ! {ping, self()}, receive pong -> Ping(Target, K - 1) end
end
end,
spawn(fun () -> Ping(Pong, 3) end),
receive ping_done -> ok end,
receive pong_done -> both_done end")
(er-pp-test
"ping-pong 3 rounds"
(get (pp-ev er-pp-program) :name)
"both_done")
;; Count exchanges via io-buffer — each pong trip prints "p".
(er-pp-test
"ping-pong 5 rounds trace"
(do
(er-io-flush!)
(pp-ev
"Me = self(),
Pong = spawn(fun () ->
Loop = fun () ->
receive
{ping, From} -> io:format(\"p\"), From ! pong, Loop();
stop -> Me ! pong_done
end
end,
Loop()
end),
Ping = fun (Target, K) ->
if K =:= 0 -> Target ! stop, Me ! ping_done;
true -> Target ! {ping, self()}, receive pong -> Ping(Target, K - 1) end
end
end,
spawn(fun () -> Ping(Pong, 5) end),
receive ping_done -> ok end,
receive pong_done -> ok end")
(er-io-buffer-content))
"ppppp")
;; Main → Pong directly (no Ping process). Main plays the ping role.
(er-pp-test
"main-as-pinger 4 rounds"
(pp-ev
"Me = self(),
Pong = spawn(fun () ->
Loop = fun () ->
receive
{ping, From} -> From ! pong, Loop();
stop -> ok
end
end,
Loop()
end),
Go = fun (K) ->
if K =:= 0 -> Pong ! stop, K;
true -> Pong ! {ping, Me}, receive pong -> Go(K - 1) end
end
end,
Go(4)")
0)
;; Ensure the processes really interleave — inject an id into each
;; ping and check we get them all back via trace (the order is
;; deterministic under our sync scheduler).
(er-pp-test
"ids round-trip"
(do
(er-io-flush!)
(pp-ev
"Me = self(),
Pong = spawn(fun () ->
Loop = fun () ->
receive
{ping, From, Id} -> From ! {pong, Id}, Loop();
stop -> ok
end
end,
Loop()
end),
Go = fun (K) ->
if K =:= 0 -> Pong ! stop, done;
true -> Pong ! {ping, Me, K}, receive {pong, RId} -> io:format(\"~p \", [RId]), Go(K - 1) end
end
end,
Go(4)")
(er-io-buffer-content))
"4 3 2 1 ")
(define
er-pp-test-summary
(str "ping-pong " er-pp-test-pass "/" er-pp-test-count))

132
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;; Ring program — N processes in a ring, token passes M times.
;;
;; Each process waits for {setup, Next} so main can tie the knot
;; (can't reference a pid before spawning it). Once wired, main
;; injects the first token; each process forwards decrementing K
;; until it hits 0, at which point it signals `done` to main.
(define er-ring-test-count 0)
(define er-ring-test-pass 0)
(define er-ring-test-fails (list))
(define
er-ring-test
(fn
(name actual expected)
(set! er-ring-test-count (+ er-ring-test-count 1))
(if
(= actual expected)
(set! er-ring-test-pass (+ er-ring-test-pass 1))
(append! er-ring-test-fails {:actual actual :expected expected :name name}))))
(define ring-ev erlang-eval-ast)
(define
er-ring-program-3-6
"Me = self(),
Spawner = fun () ->
receive {setup, Next} ->
Loop = fun () ->
receive
{token, 0, Parent} -> Parent ! done;
{token, K, Parent} -> Next ! {token, K-1, Parent}, Loop()
end
end,
Loop()
end
end,
P1 = spawn(Spawner),
P2 = spawn(Spawner),
P3 = spawn(Spawner),
P1 ! {setup, P2},
P2 ! {setup, P3},
P3 ! {setup, P1},
P1 ! {token, 5, Me},
receive done -> finished end")
(er-ring-test
"ring N=3 M=6"
(get (ring-ev er-ring-program-3-6) :name)
"finished")
;; Two-node ring — token bounces twice between P1 and P2.
(er-ring-test
"ring N=2 M=4"
(get (ring-ev
"Me = self(),
Spawner = fun () ->
receive {setup, Next} ->
Loop = fun () ->
receive
{token, 0, Parent} -> Parent ! done;
{token, K, Parent} -> Next ! {token, K-1, Parent}, Loop()
end
end,
Loop()
end
end,
P1 = spawn(Spawner),
P2 = spawn(Spawner),
P1 ! {setup, P2},
P2 ! {setup, P1},
P1 ! {token, 3, Me},
receive done -> done end") :name)
"done")
;; Single-node "ring" — P sends to itself M times.
(er-ring-test
"ring N=1 M=5"
(get (ring-ev
"Me = self(),
Spawner = fun () ->
receive {setup, Next} ->
Loop = fun () ->
receive
{token, 0, Parent} -> Parent ! finished_loop;
{token, K, Parent} -> Next ! {token, K-1, Parent}, Loop()
end
end,
Loop()
end
end,
P = spawn(Spawner),
P ! {setup, P},
P ! {token, 4, Me},
receive finished_loop -> ok end") :name)
"ok")
;; Confirm the token really went around — count hops via io-buffer.
(er-ring-test
"ring N=3 M=9 hop count"
(do
(er-io-flush!)
(ring-ev
"Me = self(),
Spawner = fun () ->
receive {setup, Next} ->
Loop = fun () ->
receive
{token, 0, Parent} -> Parent ! done;
{token, K, Parent} ->
io:format(\"~p \", [K]),
Next ! {token, K-1, Parent},
Loop()
end
end,
Loop()
end
end,
P1 = spawn(Spawner),
P2 = spawn(Spawner),
P3 = spawn(Spawner),
P1 ! {setup, P2},
P2 ! {setup, P3},
P3 ! {setup, P1},
P1 ! {token, 8, Me},
receive done -> done end")
(er-io-buffer-content))
"8 7 6 5 4 3 2 1 ")
(define
er-ring-test-summary
(str "ring " er-ring-test-pass "/" er-ring-test-count))

139
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;; Erlang runtime tests — scheduler + process-record primitives.
(define er-rt-test-count 0)
(define er-rt-test-pass 0)
(define er-rt-test-fails (list))
(define
er-rt-test
(fn
(name actual expected)
(set! er-rt-test-count (+ er-rt-test-count 1))
(if
(= actual expected)
(set! er-rt-test-pass (+ er-rt-test-pass 1))
(append! er-rt-test-fails {:actual actual :expected expected :name name}))))
;; ── queue ─────────────────────────────────────────────────────────
(er-rt-test "queue empty len" (er-q-len (er-q-new)) 0)
(er-rt-test "queue empty?" (er-q-empty? (er-q-new)) true)
(define q1 (er-q-new))
(er-q-push! q1 "a")
(er-q-push! q1 "b")
(er-q-push! q1 "c")
(er-rt-test "queue push len" (er-q-len q1) 3)
(er-rt-test "queue empty? after push" (er-q-empty? q1) false)
(er-rt-test "queue peek" (er-q-peek q1) "a")
(er-rt-test "queue pop 1" (er-q-pop! q1) "a")
(er-rt-test "queue pop 2" (er-q-pop! q1) "b")
(er-rt-test "queue len after pops" (er-q-len q1) 1)
(er-rt-test "queue pop 3" (er-q-pop! q1) "c")
(er-rt-test "queue empty again" (er-q-empty? q1) true)
(er-rt-test "queue pop empty" (er-q-pop! q1) nil)
;; Queue FIFO under interleaved push/pop
(define q2 (er-q-new))
(er-q-push! q2 1)
(er-q-push! q2 2)
(er-q-pop! q2)
(er-q-push! q2 3)
(er-rt-test "queue interleave peek" (er-q-peek q2) 2)
(er-rt-test "queue to-list" (er-q-to-list q2) (list 2 3))
;; ── scheduler init ─────────────────────────────────────────────
(er-sched-init!)
(er-rt-test "sched process count 0" (er-sched-process-count) 0)
(er-rt-test "sched runnable count 0" (er-sched-runnable-count) 0)
(er-rt-test "sched current nil" (er-sched-current-pid) nil)
;; ── pid allocation ─────────────────────────────────────────────
(define pa (er-pid-new!))
(define pb (er-pid-new!))
(er-rt-test "pid tag" (get pa :tag) "pid")
(er-rt-test "pid ids distinct" (= (er-pid-id pa) (er-pid-id pb)) false)
(er-rt-test "pid? true" (er-pid? pa) true)
(er-rt-test "pid? false" (er-pid? 42) false)
(er-rt-test
"pid-equal same"
(er-pid-equal? pa (er-mk-pid (er-pid-id pa)))
true)
(er-rt-test "pid-equal diff" (er-pid-equal? pa pb) false)
;; ── process lifecycle ──────────────────────────────────────────
(er-sched-init!)
(define p1 (er-proc-new! {}))
(define p2 (er-proc-new! {}))
(er-rt-test "proc count 2" (er-sched-process-count) 2)
(er-rt-test "runnable count 2" (er-sched-runnable-count) 2)
(er-rt-test
"proc state runnable"
(er-proc-field (get p1 :pid) :state)
"runnable")
(er-rt-test
"proc mailbox empty"
(er-proc-mailbox-size (get p1 :pid))
0)
(er-rt-test
"proc lookup"
(er-pid-equal? (get (er-proc-get (get p1 :pid)) :pid) (get p1 :pid))
true)
(er-rt-test "proc exists" (er-proc-exists? (get p1 :pid)) true)
(er-rt-test
"proc no-such-pid"
(er-proc-exists? (er-mk-pid 9999))
false)
;; runnable queue dequeue order
(er-rt-test
"dequeue first"
(er-pid-equal? (er-sched-next-runnable!) (get p1 :pid))
true)
(er-rt-test
"dequeue second"
(er-pid-equal? (er-sched-next-runnable!) (get p2 :pid))
true)
(er-rt-test "dequeue empty" (er-sched-next-runnable!) nil)
;; current-pid get/set
(er-sched-set-current! (get p1 :pid))
(er-rt-test
"current pid set"
(er-pid-equal? (er-sched-current-pid) (get p1 :pid))
true)
;; ── mailbox push ──────────────────────────────────────────────
(er-proc-mailbox-push! (get p1 :pid) {:tag "atom" :name "ping"})
(er-proc-mailbox-push! (get p1 :pid) 42)
(er-rt-test "mailbox size 2" (er-proc-mailbox-size (get p1 :pid)) 2)
;; ── field update ──────────────────────────────────────────────
(er-proc-set! (get p1 :pid) :state "waiting")
(er-rt-test
"proc state waiting"
(er-proc-field (get p1 :pid) :state)
"waiting")
(er-proc-set! (get p1 :pid) :trap-exit true)
(er-rt-test
"proc trap-exit"
(er-proc-field (get p1 :pid) :trap-exit)
true)
;; ── fresh scheduler ends in clean state ───────────────────────
(er-sched-init!)
(er-rt-test
"sched init resets count"
(er-sched-process-count)
0)
(er-rt-test
"sched init resets queue"
(er-sched-runnable-count)
0)
(er-rt-test
"sched init resets current"
(er-sched-current-pid)
nil)
(define
er-rt-test-summary
(str "runtime " er-rt-test-pass "/" er-rt-test-count))

1913
lib/erlang/transpile.sx Normal file
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lib/forth/runtime.sx
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;; Forth runtime — state, stacks, dictionary, output buffer.
;; Data stack: mutable SX list, TOS = first.
;; Return stack: separate mutable list.
;; Dictionary: SX dict {lowercased-name -> word-record}.
;; Word record: {"kind" "body" "immediate?"}; kind is "primitive" or "colon-def".
;; Output buffer: mutable string appended to by `.`, `EMIT`, `CR`, etc.
;; Compile-mode flag: "compiling" on the state.
;; lib/forth/runtime.sx — Forth primitives on SX
;;
;; Provides Forth-idiomatic wrappers over SX built-ins.
;; Primitives used:
;; bitwise-and/or/xor/not/arithmetic-shift/bit-count (Phase 7)
;; make-bytevector/bytevector-u8-ref/u8-set!/... (Phase 20)
;; quotient/remainder/modulo (Phase 15 / builtin)
;;
;; Naming: SX identifiers can't include @ or !-alone, so Forth words are:
;; C@ → forth-cfetch C! → forth-cstore
;; @ → forth-fetch ! → forth-store
;; ---------------------------------------------------------------------------
;; 1. Bitwise operations — Forth core words
;; Forth TRUE = -1 (all bits set), FALSE = 0.
;; All ops coerce to integer via truncate.
;; ---------------------------------------------------------------------------
(define (forth-and a b) (bitwise-and (truncate a) (truncate b)))
(define (forth-or a b) (bitwise-or (truncate a) (truncate b)))
(define (forth-xor a b) (bitwise-xor (truncate a) (truncate b)))
;; INVERT — bitwise NOT (Forth NOT is logical; INVERT is bitwise)
(define (forth-invert a) (bitwise-not (truncate a)))
;; LSHIFT RSHIFT — n bit — shift a by n positions
(define (forth-lshift a n) (arithmetic-shift (truncate a) (truncate n)))
(define
(forth-rshift a n)
(arithmetic-shift (truncate a) (- 0 (truncate n))))
;; 2* 2/ — multiply/divide by 2 via bit shift
(define (forth-2* a) (arithmetic-shift (truncate a) 1))
(define (forth-2/ a) (arithmetic-shift (truncate a) -1))
;; BIT-COUNT — number of set bits (Kernighan popcount)
(define (forth-bit-count a) (bit-count (truncate a)))
;; INTEGER-LENGTH — index of highest set bit (0 for zero)
(define (forth-integer-length a) (integer-length (truncate a)))
;; WITHIN — ( u ul uh -- flag ) true if ul <= u < uh
(define (forth-within u ul uh) (and (>= u ul) (< u uh)))
;; Arithmetic complements commonly used alongside bitwise ops
(define (forth-negate a) (- 0 (truncate a)))
(define (forth-abs a) (abs (truncate a)))
(define (forth-min a b) (if (< a b) a b))
(define (forth-max a b) (if (> a b) a b))
(define (forth-mod a b) (modulo (truncate a) (truncate b)))
;; /MOD — ( n1 n2 -- rem quot ) returns list (remainder quotient)
(define
(forth-divmod a b)
(list
(remainder (truncate a) (truncate b))
(quotient (truncate a) (truncate b))))
;; ---------------------------------------------------------------------------
;; 2. String buffer — word-definition / string accumulation
;; EMIT appends one char; TYPE appends a string.
;; Value is retrieved with forth-sb-value.
;; ---------------------------------------------------------------------------
(define
forth-make-state
(fn
()
(let
((s (dict)))
(dict-set! s "dstack" (list))
(dict-set! s "rstack" (list))
(dict-set! s "dict" (dict))
(dict-set! s "output" "")
(dict-set! s "compiling" false)
(dict-set! s "current-def" nil)
(dict-set! s "base" 10)
(dict-set! s "vars" (dict))
s)))
(forth-sb-new)
(let
((sb (dict)))
(dict-set! sb "_forth_sb" true)
(dict-set! sb "_chars" (list))
sb))
(define (forth-sb? v) (and (dict? v) (dict-has? v "_forth_sb")))
;; EMIT — append one character
(define
(forth-sb-emit! sb c)
(dict-set! sb "_chars" (append (get sb "_chars") (list c)))
sb)
;; TYPE — append a string
(define
(forth-sb-type! sb s)
(dict-set! sb "_chars" (append (get sb "_chars") (string->list s)))
sb)
(define (forth-sb-value sb) (list->string (get sb "_chars")))
(define (forth-sb-length sb) (len (get sb "_chars")))
(define (forth-sb-clear! sb) (dict-set! sb "_chars" (list)) sb)
;; Emit integer as decimal digits
(define (forth-sb-emit-int! sb n) (forth-sb-type! sb (str (truncate n))))
;; ---------------------------------------------------------------------------
;; 3. Memory / Bytevectors — Forth raw memory model
;; ALLOT allocates a bytevector. Byte and cell (32-bit LE) access.
;; ---------------------------------------------------------------------------
;; ALLOT — allocate n bytes zero-initialised
(define (forth-mem-new n) (make-bytevector (truncate n) 0))
(define (forth-mem? v) (bytevector? v))
(define (forth-mem-size v) (bytevector-length v))
;; C@ C! — byte fetch/store
(define (forth-cfetch mem addr) (bytevector-u8-ref mem (truncate addr)))
(define
forth-error
(fn (state msg) (dict-set! state "error" msg) (raise msg)))
(forth-cstore mem addr val)
(bytevector-u8-set!
mem
(truncate addr)
(modulo (truncate val) 256))
mem)
;; @ ! — 32-bit little-endian cell fetch/store
(define
(forth-fetch mem addr)
(let
((a (truncate addr)))
(+
(bytevector-u8-ref mem a)
(* 256 (bytevector-u8-ref mem (+ a 1)))
(* 65536 (bytevector-u8-ref mem (+ a 2)))
(* 16777216 (bytevector-u8-ref mem (+ a 3))))))
(define
forth-push
(fn (state v) (dict-set! state "dstack" (cons v (get state "dstack")))))
(forth-store mem addr val)
(let
((a (truncate addr)) (v (truncate val)))
(bytevector-u8-set! mem a (modulo v 256))
(bytevector-u8-set!
mem
(+ a 1)
(modulo (quotient v 256) 256))
(bytevector-u8-set!
mem
(+ a 2)
(modulo (quotient v 65536) 256))
(bytevector-u8-set!
mem
(+ a 3)
(modulo (quotient v 16777216) 256)))
mem)
;; MOVE — copy count bytes from src[src-addr] to dst[dst-addr]
(define
forth-pop
(fn
(state)
(let
((st (get state "dstack")))
(if
(= (len st) 0)
(forth-error state "stack underflow")
(let ((top (first st))) (dict-set! state "dstack" (rest st)) top)))))
(forth-move! src src-addr dst dst-addr count)
(letrec
((go (fn (i) (when (< i (truncate count)) (bytevector-u8-set! dst (+ (truncate dst-addr) i) (bytevector-u8-ref src (+ (truncate src-addr) i))) (go (+ i 1))))))
(go 0))
dst)
;; FILL — fill count bytes at addr with byte value
(define
forth-peek
(fn
(state)
(let
((st (get state "dstack")))
(if (= (len st) 0) (forth-error state "stack underflow") (first st)))))
(define forth-depth (fn (state) (len (get state "dstack"))))
(forth-fill! mem addr count byte)
(letrec
((go (fn (i) (when (< i (truncate count)) (bytevector-u8-set! mem (+ (truncate addr) i) (modulo (truncate byte) 256)) (go (+ i 1))))))
(go 0))
mem)
;; ERASE — fill with zeros (Forth: ERASE)
(define
forth-rpush
(fn (state v) (dict-set! state "rstack" (cons v (get state "rstack")))))
(forth-erase! mem addr count)
(forth-fill! mem addr count 0))
;; Dump memory region as list of byte values
(define
forth-rpop
(fn
(state)
(let
((st (get state "rstack")))
(if
(= (len st) 0)
(forth-error state "return stack underflow")
(let ((top (first st))) (dict-set! state "rstack" (rest st)) top)))))
(define
forth-rpeek
(fn
(state)
(let
((st (get state "rstack")))
(if
(= (len st) 0)
(forth-error state "return stack underflow")
(first st)))))
(define
forth-emit-str
(fn (state s) (dict-set! state "output" (str (get state "output") s))))
(define
forth-make-word
(fn
(kind body immediate?)
(let
((w (dict)))
(dict-set! w "kind" kind)
(dict-set! w "body" body)
(dict-set! w "immediate?" immediate?)
w)))
(define
forth-def-prim!
(fn
(state name body)
(dict-set!
(get state "dict")
(downcase name)
(forth-make-word "primitive" body false))))
(define
forth-def-prim-imm!
(fn
(state name body)
(dict-set!
(get state "dict")
(downcase name)
(forth-make-word "primitive" body true))))
(define
forth-lookup
(fn (state name) (get (get state "dict") (downcase name))))
(define
forth-binop
(fn
(op)
(fn
(state)
(let
((b (forth-pop state)) (a (forth-pop state)))
(forth-push state (op a b))))))
(define
forth-unop
(fn
(op)
(fn (state) (let ((a (forth-pop state))) (forth-push state (op a))))))
(define
forth-cmp
(fn
(op)
(fn
(state)
(let
((b (forth-pop state)) (a (forth-pop state)))
(forth-push state (if (op a b) -1 0))))))
(define
forth-cmp0
(fn
(op)
(fn
(state)
(let ((a (forth-pop state))) (forth-push state (if (op a) -1 0))))))
(define
forth-trunc
(fn (x) (if (< x 0) (- 0 (floor (- 0 x))) (floor x))))
(define
forth-div
(fn
(a b)
(if (= b 0) (raise "division by zero") (forth-trunc (/ a b)))))
(define
forth-mod
(fn
(a b)
(if (= b 0) (raise "division by zero") (- a (* b (forth-div a b))))))
(define forth-bits-width 32)
(define
forth-to-unsigned
(fn (n w) (let ((m (pow 2 w))) (mod (+ (mod n m) m) m))))
(define
forth-from-unsigned
(fn
(n w)
(let ((half (pow 2 (- w 1)))) (if (>= n half) (- n (pow 2 w)) n))))
(define
forth-bitwise-step
(fn
(op ua ub out place i w)
(if
(>= i w)
out
(let
((da (mod ua 2)) (db (mod ub 2)))
(forth-bitwise-step
op
(floor (/ ua 2))
(floor (/ ub 2))
(+ out (* place (op da db)))
(* place 2)
(+ i 1)
w)))))
(define
forth-bitwise-uu
(fn
(op)
(fn
(a b)
(let
((ua (forth-to-unsigned a forth-bits-width))
(ub (forth-to-unsigned b forth-bits-width)))
(forth-from-unsigned
(forth-bitwise-step op ua ub 0 1 0 forth-bits-width)
forth-bits-width)))))
(define
forth-bit-and
(forth-bitwise-uu (fn (x y) (if (and (= x 1) (= y 1)) 1 0))))
(define
forth-bit-or
(forth-bitwise-uu (fn (x y) (if (or (= x 1) (= y 1)) 1 0))))
(define forth-bit-xor (forth-bitwise-uu (fn (x y) (if (= x y) 0 1))))
(define forth-bit-invert (fn (a) (- 0 (+ a 1))))
(define
forth-install-primitives!
(fn
(state)
(forth-def-prim! state "DUP" (fn (s) (forth-push s (forth-peek s))))
(forth-def-prim! state "DROP" (fn (s) (forth-pop s)))
(forth-def-prim!
state
"SWAP"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s b)
(forth-push s a))))
(forth-def-prim!
state
"OVER"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s a)
(forth-push s b)
(forth-push s a))))
(forth-def-prim!
state
"ROT"
(fn
(s)
(let
((c (forth-pop s)) (b (forth-pop s)) (a (forth-pop s)))
(forth-push s b)
(forth-push s c)
(forth-push s a))))
(forth-def-prim!
state
"-ROT"
(fn
(s)
(let
((c (forth-pop s)) (b (forth-pop s)) (a (forth-pop s)))
(forth-push s c)
(forth-push s a)
(forth-push s b))))
(forth-def-prim!
state
"NIP"
(fn (s) (let ((b (forth-pop s))) (forth-pop s) (forth-push s b))))
(forth-def-prim!
state
"TUCK"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s b)
(forth-push s a)
(forth-push s b))))
(forth-def-prim!
state
"?DUP"
(fn
(s)
(let ((a (forth-peek s))) (when (not (= a 0)) (forth-push s a)))))
(forth-def-prim! state "DEPTH" (fn (s) (forth-push s (forth-depth s))))
(forth-def-prim!
state
"PICK"
(fn
(s)
(let
((n (forth-pop s)) (st (get s "dstack")))
(if
(or (< n 0) (>= n (len st)))
(forth-error s "PICK out of range")
(forth-push s (nth st n))))))
(forth-def-prim!
state
"ROLL"
(fn
(s)
(let
((n (forth-pop s)) (st (get s "dstack")))
(if
(or (< n 0) (>= n (len st)))
(forth-error s "ROLL out of range")
(let
((taken (nth st n))
(before (take st n))
(after (drop st (+ n 1))))
(dict-set! s "dstack" (concat before after))
(forth-push s taken))))))
(forth-def-prim!
state
"2DUP"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s a)
(forth-push s b)
(forth-push s a)
(forth-push s b))))
(forth-def-prim! state "2DROP" (fn (s) (forth-pop s) (forth-pop s)))
(forth-def-prim!
state
"2SWAP"
(fn
(s)
(let
((d (forth-pop s))
(c (forth-pop s))
(b (forth-pop s))
(a (forth-pop s)))
(forth-push s c)
(forth-push s d)
(forth-push s a)
(forth-push s b))))
(forth-def-prim!
state
"2OVER"
(fn
(s)
(let
((d (forth-pop s))
(c (forth-pop s))
(b (forth-pop s))
(a (forth-pop s)))
(forth-push s a)
(forth-push s b)
(forth-push s c)
(forth-push s d)
(forth-push s a)
(forth-push s b))))
(forth-def-prim! state "+" (forth-binop (fn (a b) (+ a b))))
(forth-def-prim! state "-" (forth-binop (fn (a b) (- a b))))
(forth-def-prim! state "*" (forth-binop (fn (a b) (* a b))))
(forth-def-prim! state "/" (forth-binop forth-div))
(forth-def-prim! state "MOD" (forth-binop forth-mod))
(forth-def-prim!
state
"/MOD"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s (forth-mod a b))
(forth-push s (forth-div a b)))))
(forth-def-prim! state "NEGATE" (forth-unop (fn (a) (- 0 a))))
(forth-def-prim! state "ABS" (forth-unop abs))
(forth-def-prim!
state
"MIN"
(forth-binop (fn (a b) (if (< a b) a b))))
(forth-def-prim!
state
"MAX"
(forth-binop (fn (a b) (if (> a b) a b))))
(forth-def-prim! state "1+" (forth-unop (fn (a) (+ a 1))))
(forth-def-prim! state "1-" (forth-unop (fn (a) (- a 1))))
(forth-def-prim! state "2+" (forth-unop (fn (a) (+ a 2))))
(forth-def-prim! state "2-" (forth-unop (fn (a) (- a 2))))
(forth-def-prim! state "2*" (forth-unop (fn (a) (* a 2))))
(forth-def-prim! state "2/" (forth-unop (fn (a) (floor (/ a 2)))))
(forth-def-prim! state "=" (forth-cmp (fn (a b) (= a b))))
(forth-def-prim! state "<>" (forth-cmp (fn (a b) (not (= a b)))))
(forth-def-prim! state "<" (forth-cmp (fn (a b) (< a b))))
(forth-def-prim! state ">" (forth-cmp (fn (a b) (> a b))))
(forth-def-prim! state "<=" (forth-cmp (fn (a b) (<= a b))))
(forth-def-prim! state ">=" (forth-cmp (fn (a b) (>= a b))))
(forth-def-prim! state "0=" (forth-cmp0 (fn (a) (= a 0))))
(forth-def-prim! state "0<>" (forth-cmp0 (fn (a) (not (= a 0)))))
(forth-def-prim! state "0<" (forth-cmp0 (fn (a) (< a 0))))
(forth-def-prim! state "0>" (forth-cmp0 (fn (a) (> a 0))))
(forth-def-prim! state "AND" (forth-binop forth-bit-and))
(forth-def-prim! state "OR" (forth-binop forth-bit-or))
(forth-def-prim! state "XOR" (forth-binop forth-bit-xor))
(forth-def-prim! state "INVERT" (forth-unop forth-bit-invert))
(forth-def-prim!
state
"."
(fn (s) (forth-emit-str s (str (forth-pop s) " "))))
(forth-def-prim!
state
".S"
(fn
(s)
(let
((st (reverse (get s "dstack"))))
(forth-emit-str s "<")
(forth-emit-str s (str (len st)))
(forth-emit-str s "> ")
(for-each (fn (v) (forth-emit-str s (str v " "))) st))))
(forth-def-prim!
state
"EMIT"
(fn (s) (forth-emit-str s (code-char (forth-pop s)))))
(forth-def-prim! state "CR" (fn (s) (forth-emit-str s "\n")))
(forth-def-prim! state "SPACE" (fn (s) (forth-emit-str s " ")))
(forth-def-prim!
state
"SPACES"
(fn
(s)
(let
((n (forth-pop s)))
(when
(> n 0)
(for-each (fn (_) (forth-emit-str s " ")) (range 0 n))))))
(forth-def-prim! state "BL" (fn (s) (forth-push s 32)))
state))
(forth-mem->list mem addr count)
(letrec
((go (fn (i acc) (if (= i 0) acc (go (- i 1) (cons (bytevector-u8-ref mem (+ (truncate addr) (- i 1))) acc))))))
(go (truncate count) (list))))

62
lib/forth/test.sh Executable file
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@@ -0,0 +1,62 @@
#!/usr/bin/env bash
# lib/forth/test.sh — smoke-test the Forth runtime layer.
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found."
exit 1
fi
TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "lib/forth/runtime.sx")
(epoch 2)
(load "lib/forth/tests/runtime.sx")
(epoch 3)
(eval "(list forth-test-pass forth-test-fail)")
EPOCHS
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok 3 //; s/\)$//')
fi
if [ -z "$LINE" ]; then
echo "ERROR: could not extract summary"
echo "$OUTPUT" | tail -20
exit 1
fi
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
TOTAL=$((P + F))
if [ "$F" -eq 0 ]; then
echo "ok $P/$TOTAL lib/forth tests passed"
else
echo "FAIL $P/$TOTAL passed, $F failed"
TMPFILE2=$(mktemp)
cat > "$TMPFILE2" << 'EPOCHS2'
(epoch 1)
(load "lib/forth/runtime.sx")
(epoch 2)
(load "lib/forth/tests/runtime.sx")
(epoch 3)
(eval "(map (fn (f) (list (get f :name) (get f :got) (get f :expected))) forth-test-fails)")
EPOCHS2
FAILS=$(timeout 60 "$SX_SERVER" < "$TMPFILE2" 2>/dev/null | grep -E '^\(ok-len 3' -A1 | tail -1 || true)
echo " Details: $FAILS"
rm -f "$TMPFILE2"
fi
[ "$F" -eq 0 ]

201
lib/forth/tests/runtime.sx Normal file
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@@ -0,0 +1,201 @@
;; lib/forth/tests/runtime.sx — Tests for lib/forth/runtime.sx
(define forth-test-pass 0)
(define forth-test-fail 0)
(define forth-test-fails (list))
(define
(forth-test name got expected)
(if
(= got expected)
(set! forth-test-pass (+ forth-test-pass 1))
(begin
(set! forth-test-fail (+ forth-test-fail 1))
(set! forth-test-fails (append forth-test-fails (list {:got got :expected expected :name name}))))))
;; ---------------------------------------------------------------------------
;; 1. Bitwise operations
;; ---------------------------------------------------------------------------
;; AND
(forth-test "and 0b1100 0b1010" (forth-and 12 10) 8)
(forth-test "and 0xFF 0x0F" (forth-and 255 15) 15)
(forth-test "and 0 any" (forth-and 0 42) 0)
;; OR
(forth-test "or 0b1100 0b1010" (forth-or 12 10) 14)
(forth-test "or 0 x" (forth-or 0 7) 7)
;; XOR
(forth-test "xor 0b1100 0b1010" (forth-xor 12 10) 6)
(forth-test "xor x x" (forth-xor 42 42) 0)
;; INVERT
(forth-test "invert 0" (forth-invert 0) -1)
(forth-test "invert -1" (forth-invert -1) 0)
(forth-test "invert 1" (forth-invert 1) -2)
;; LSHIFT RSHIFT
(forth-test "lshift 1 3" (forth-lshift 1 3) 8)
(forth-test "lshift 3 2" (forth-lshift 3 2) 12)
(forth-test "rshift 8 3" (forth-rshift 8 3) 1)
(forth-test "rshift 16 2" (forth-rshift 16 2) 4)
;; 2* 2/
(forth-test "2* 5" (forth-2* 5) 10)
(forth-test "2/ 10" (forth-2/ 10) 5)
(forth-test "2/ 7" (forth-2/ 7) 3)
;; BIT-COUNT
(forth-test "bit-count 0" (forth-bit-count 0) 0)
(forth-test "bit-count 1" (forth-bit-count 1) 1)
(forth-test "bit-count 7" (forth-bit-count 7) 3)
(forth-test "bit-count 255" (forth-bit-count 255) 8)
(forth-test "bit-count 256" (forth-bit-count 256) 1)
;; INTEGER-LENGTH
(forth-test "integer-length 0" (forth-integer-length 0) 0)
(forth-test "integer-length 1" (forth-integer-length 1) 1)
(forth-test "integer-length 4" (forth-integer-length 4) 3)
(forth-test "integer-length 255" (forth-integer-length 255) 8)
;; WITHIN
(forth-test
"within 5 0 10"
(forth-within 5 0 10)
true)
(forth-test
"within 0 0 10"
(forth-within 0 0 10)
true)
(forth-test
"within 10 0 10"
(forth-within 10 0 10)
false)
(forth-test
"within -1 0 10"
(forth-within -1 0 10)
false)
;; Arithmetic ops
(forth-test "negate 5" (forth-negate 5) -5)
(forth-test "negate -3" (forth-negate -3) 3)
(forth-test "abs -7" (forth-abs -7) 7)
(forth-test "min 3 5" (forth-min 3 5) 3)
(forth-test "max 3 5" (forth-max 3 5) 5)
(forth-test "mod 7 3" (forth-mod 7 3) 1)
(forth-test
"divmod 7 3"
(forth-divmod 7 3)
(list 1 2))
(forth-test
"divmod 10 5"
(forth-divmod 10 5)
(list 0 2))
;; ---------------------------------------------------------------------------
;; 2. String buffer
;; ---------------------------------------------------------------------------
(define sb1 (forth-sb-new))
(forth-test "sb? new" (forth-sb? sb1) true)
(forth-test "sb? non-sb" (forth-sb? 42) false)
(forth-test "sb value empty" (forth-sb-value sb1) "")
(forth-test "sb length empty" (forth-sb-length sb1) 0)
(forth-sb-type! sb1 "HELLO")
(forth-test "sb type" (forth-sb-value sb1) "HELLO")
(forth-test "sb length after type" (forth-sb-length sb1) 5)
;; EMIT one char
(define sb2 (forth-sb-new))
(forth-sb-emit! sb2 (nth (string->list "A") 0))
(forth-sb-emit! sb2 (nth (string->list "B") 0))
(forth-sb-emit! sb2 (nth (string->list "C") 0))
(forth-test "sb emit chars" (forth-sb-value sb2) "ABC")
;; Emit integer
(define sb3 (forth-sb-new))
(forth-sb-type! sb3 "n=")
(forth-sb-emit-int! sb3 42)
(forth-test "sb emit-int" (forth-sb-value sb3) "n=42")
(forth-sb-clear! sb1)
(forth-test "sb clear" (forth-sb-value sb1) "")
(forth-test "sb length after clear" (forth-sb-length sb1) 0)
;; Build a word definition-style name
(define sb4 (forth-sb-new))
(forth-sb-type! sb4 ": ")
(forth-sb-type! sb4 "SQUARE")
(forth-sb-type! sb4 " DUP * ;")
(forth-test "sb word def" (forth-sb-value sb4) ": SQUARE DUP * ;")
;; ---------------------------------------------------------------------------
;; 3. Memory / Bytevectors
;; ---------------------------------------------------------------------------
(define m1 (forth-mem-new 8))
(forth-test "mem? yes" (forth-mem? m1) true)
(forth-test "mem? no" (forth-mem? 42) false)
(forth-test "mem size" (forth-mem-size m1) 8)
(forth-test "mem cfetch zero" (forth-cfetch m1 0) 0)
;; C! C@
(forth-cstore m1 0 65)
(forth-cstore m1 1 66)
(forth-test "mem cstore/cfetch 0" (forth-cfetch m1 0) 65)
(forth-test "mem cstore/cfetch 1" (forth-cfetch m1 1) 66)
(forth-cstore m1 2 256)
(forth-test
"mem cstore wraps 256→0"
(forth-cfetch m1 2)
0)
(forth-cstore m1 2 257)
(forth-test
"mem cstore wraps 257→1"
(forth-cfetch m1 2)
1)
;; @ ! (32-bit LE cell)
(define m2 (forth-mem-new 8))
(forth-store m2 0 305419896)
(forth-test "mem store/fetch" (forth-fetch m2 0) 305419896)
(forth-store m2 4 1)
(forth-test "mem fetch byte 4" (forth-cfetch m2 4) 1)
(forth-test "mem fetch byte 5" (forth-cfetch m2 5) 0)
;; FILL ERASE
(define m3 (forth-mem-new 4))
(forth-fill! m3 0 4 42)
(forth-test
"mem fill"
(forth-mem->list m3 0 4)
(list 42 42 42 42))
(forth-erase! m3 1 2)
(forth-test
"mem erase middle"
(forth-mem->list m3 0 4)
(list 42 0 0 42))
;; MOVE
(define m4 (forth-mem-new 4))
(forth-cstore m4 0 1)
(forth-cstore m4 1 2)
(forth-cstore m4 2 3)
(define m5 (forth-mem-new 4))
(forth-move! m4 0 m5 0 3)
(forth-test
"mem move"
(forth-mem->list m5 0 3)
(list 1 2 3))
;; mem->list
(define m6 (forth-mem-new 3))
(forth-cstore m6 0 10)
(forth-cstore m6 1 20)
(forth-cstore m6 2 30)
(forth-test
"mem->list"
(forth-mem->list m6 0 3)
(list 10 20 30))

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#!/usr/bin/env bash
# lib/haskell/conformance.sh — run the classic-program test suites.
# Writes lib/haskell/scoreboard.json and lib/haskell/scoreboard.md.
#
# Usage:
# bash lib/haskell/conformance.sh # run + write scoreboards
# bash lib/haskell/conformance.sh --check # run only, exit 1 on failure
set -euo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
if [ ! -x "$SX_SERVER" ]; then
MAIN_ROOT=$(git worktree list | head -1 | awk '{print $1}')
if [ -x "$MAIN_ROOT/$SX_SERVER" ]; then
SX_SERVER="$MAIN_ROOT/$SX_SERVER"
else
echo "ERROR: sx_server.exe not found. Run: cd hosts/ocaml && dune build"
exit 1
fi
fi
PROGRAMS=(fib sieve quicksort nqueens calculator collatz palindrome maybe fizzbuzz anagram roman binary either primes zipwith matrix wordcount powers)
PASS_COUNTS=()
FAIL_COUNTS=()
run_suite() {
local prog="$1"
local FILE="lib/haskell/tests/program-${prog}.sx"
local TMPFILE
TMPFILE=$(mktemp)
cat > "$TMPFILE" <<EPOCHS
(epoch 1)
(load "lib/haskell/tokenizer.sx")
(load "lib/haskell/layout.sx")
(load "lib/haskell/parser.sx")
(load "lib/haskell/desugar.sx")
(load "lib/haskell/runtime.sx")
(load "lib/haskell/match.sx")
(load "lib/haskell/eval.sx")
(load "lib/haskell/testlib.sx")
(epoch 2)
(load "$FILE")
(epoch 3)
(eval "(list hk-test-pass hk-test-fail)")
EPOCHS
local OUTPUT
OUTPUT=$(timeout 120 "$SX_SERVER" < "$TMPFILE" 2>&1 || true)
rm -f "$TMPFILE"
local LINE
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok 3 //; s/\)$//' || true)
fi
if [ -z "$LINE" ]; then
echo "0 1"
else
local P F
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/' || echo "0")
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/' || echo "1")
echo "$P $F"
fi
}
for prog in "${PROGRAMS[@]}"; do
RESULT=$(run_suite "$prog")
P=$(echo "$RESULT" | cut -d' ' -f1)
F=$(echo "$RESULT" | cut -d' ' -f2)
PASS_COUNTS+=("$P")
FAIL_COUNTS+=("$F")
T=$((P + F))
if [ "$F" -eq 0 ]; then
printf '✓ %-14s %d/%d\n' "${prog}.hs" "$P" "$T"
else
printf '✗ %-14s %d/%d\n' "${prog}.hs" "$P" "$T"
fi
done
TOTAL_PASS=0
TOTAL_FAIL=0
PROG_PASS=0
for i in "${!PROGRAMS[@]}"; do
TOTAL_PASS=$((TOTAL_PASS + PASS_COUNTS[i]))
TOTAL_FAIL=$((TOTAL_FAIL + FAIL_COUNTS[i]))
[ "${FAIL_COUNTS[$i]}" -eq 0 ] && PROG_PASS=$((PROG_PASS + 1))
done
PROG_TOTAL=${#PROGRAMS[@]}
echo ""
echo "Classic programs: ${TOTAL_PASS}/$((TOTAL_PASS + TOTAL_FAIL)) tests | ${PROG_PASS}/${PROG_TOTAL} programs passing"
if [[ "${1:-}" == "--check" ]]; then
[ $TOTAL_FAIL -eq 0 ]
exit $?
fi
DATE=$(date '+%Y-%m-%d')
# scoreboard.json
{
printf '{\n'
printf ' "date": "%s",\n' "$DATE"
printf ' "total_pass": %d,\n' "$TOTAL_PASS"
printf ' "total_fail": %d,\n' "$TOTAL_FAIL"
printf ' "programs": {\n'
last=$((${#PROGRAMS[@]} - 1))
for i in "${!PROGRAMS[@]}"; do
prog="${PROGRAMS[$i]}"
if [ $i -lt $last ]; then
printf ' "%s": {"pass": %d, "fail": %d},\n' "$prog" "${PASS_COUNTS[$i]}" "${FAIL_COUNTS[$i]}"
else
printf ' "%s": {"pass": %d, "fail": %d}\n' "$prog" "${PASS_COUNTS[$i]}" "${FAIL_COUNTS[$i]}"
fi
done
printf ' }\n'
printf '}\n'
} > lib/haskell/scoreboard.json
# scoreboard.md
{
printf '# Haskell-on-SX Scoreboard\n\n'
printf 'Updated %s · Phase 6 (prelude extras + 18 programs)\n\n' "$DATE"
printf '| Program | Tests | Status |\n'
printf '|---------|-------|--------|\n'
for i in "${!PROGRAMS[@]}"; do
prog="${PROGRAMS[$i]}"
P=${PASS_COUNTS[$i]}
F=${FAIL_COUNTS[$i]}
T=$((P + F))
[ "$F" -eq 0 ] && STATUS="✓" || STATUS="✗"
printf '| %s | %d/%d | %s |\n' "${prog}.hs" "$P" "$T" "$STATUS"
done
printf '| **Total** | **%d/%d** | **%d/%d programs** |\n' \
"$TOTAL_PASS" "$((TOTAL_PASS + TOTAL_FAIL))" "$PROG_PASS" "$PROG_TOTAL"
} > lib/haskell/scoreboard.md
echo "Wrote lib/haskell/scoreboard.json and lib/haskell/scoreboard.md"
[ $TOTAL_FAIL -eq 0 ]

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;; Desugar the Haskell surface AST into a smaller core AST.
;;
;; Eliminates the three surface-only shapes produced by the parser:
;; :where BODY DECLS → :let DECLS BODY
;; :guarded GUARDS → :if C1 E1 (:if C2 E2 … (:app error …))
;; :list-comp EXPR QUALS → concatMap-based expression (§3.11)
;;
;; Everything else (:app, :op, :lambda, :let, :case, :do, :tuple,
;; :list, :range, :if, :neg, :sect-left / :sect-right, plus all
;; leaf forms and pattern / type nodes) is passed through after
;; recursing into children.
(define
hk-guards-to-if
(fn
(guards)
(cond
((empty? guards)
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards")))
(:else
(let
((g (first guards)))
(list
:if
(hk-desugar (nth g 1))
(hk-desugar (nth g 2))
(hk-guards-to-if (rest guards))))))))
;; do-notation desugaring (Haskell 98 §3.14):
;; do { e } = e
;; do { e ; ss } = e >> do { ss }
;; do { p <- e ; ss } = e >>= \p -> do { ss }
;; do { let decls ; ss } = let decls in do { ss }
(define
hk-desugar-do
(fn
(stmts)
(cond
((empty? stmts) (raise "empty do block"))
((empty? (rest stmts))
(let ((s (first stmts)))
(cond
((= (first s) "do-expr") (hk-desugar (nth s 1)))
(:else
(raise "do block must end with an expression")))))
(:else
(let
((s (first stmts)) (rest-stmts (rest stmts)))
(let
((rest-do (hk-desugar-do rest-stmts)))
(cond
((= (first s) "do-expr")
(list
:app
(list
:app
(list :var ">>")
(hk-desugar (nth s 1)))
rest-do))
((= (first s) "do-bind")
(list
:app
(list
:app
(list :var ">>=")
(hk-desugar (nth s 2)))
(list :lambda (list (nth s 1)) rest-do)))
((= (first s) "do-let")
(list
:let
(map hk-desugar (nth s 1))
rest-do))
(:else (raise "unknown do-stmt tag")))))))))
;; List-comprehension desugaring (Haskell 98 §3.11):
;; [e | ] = [e]
;; [e | b, Q ] = if b then [e | Q] else []
;; [e | p <- l, Q ] = concatMap (\p -> [e | Q]) l
;; [e | let ds, Q ] = let ds in [e | Q]
(define
hk-lc-desugar
(fn
(e quals)
(cond
((empty? quals) (list :list (list e)))
(:else
(let
((q (first quals)))
(let
((qtag (first q)))
(cond
((= qtag "q-guard")
(list
:if
(hk-desugar (nth q 1))
(hk-lc-desugar e (rest quals))
(list :list (list))))
((= qtag "q-gen")
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (nth q 1))
(hk-lc-desugar e (rest quals))))
(hk-desugar (nth q 2))))
((= qtag "q-let")
(list
:let
(map hk-desugar (nth q 1))
(hk-lc-desugar e (rest quals))))
(:else
(raise
(str
"hk-lc-desugar: unknown qualifier tag "
qtag))))))))))
(define
hk-desugar
(fn
(node)
(cond
((not (list? node)) node)
((empty? node) node)
(:else
(let
((tag (first node)))
(cond
;; Transformations
((= tag "where")
(list
:let
(map hk-desugar (nth node 2))
(hk-desugar (nth node 1))))
((= tag "guarded") (hk-guards-to-if (nth node 1)))
((= tag "list-comp")
(hk-lc-desugar
(hk-desugar (nth node 1))
(nth node 2)))
;; Expression nodes
((= tag "app")
(list
:app
(hk-desugar (nth node 1))
(hk-desugar (nth node 2))))
((= tag "op")
(list
:op
(nth node 1)
(hk-desugar (nth node 2))
(hk-desugar (nth node 3))))
((= tag "neg") (list :neg (hk-desugar (nth node 1))))
((= tag "if")
(list
:if
(hk-desugar (nth node 1))
(hk-desugar (nth node 2))
(hk-desugar (nth node 3))))
((= tag "tuple")
(list :tuple (map hk-desugar (nth node 1))))
((= tag "list")
(list :list (map hk-desugar (nth node 1))))
((= tag "range")
(list
:range
(hk-desugar (nth node 1))
(hk-desugar (nth node 2))))
((= tag "range-step")
(list
:range-step
(hk-desugar (nth node 1))
(hk-desugar (nth node 2))
(hk-desugar (nth node 3))))
((= tag "lambda")
(list
:lambda
(nth node 1)
(hk-desugar (nth node 2))))
((= tag "let")
(list
:let
(map hk-desugar (nth node 1))
(hk-desugar (nth node 2))))
((= tag "case")
(list
:case
(hk-desugar (nth node 1))
(map hk-desugar (nth node 2))))
((= tag "alt")
(list :alt (nth node 1) (hk-desugar (nth node 2))))
((= tag "do") (hk-desugar-do (nth node 1)))
((= tag "sect-left")
(list
:sect-left
(nth node 1)
(hk-desugar (nth node 2))))
((= tag "sect-right")
(list
:sect-right
(nth node 1)
(hk-desugar (nth node 2))))
;; Top-level
((= tag "program")
(list :program (map hk-desugar (nth node 1))))
((= tag "module")
(list
:module
(nth node 1)
(nth node 2)
(nth node 3)
(map hk-desugar (nth node 4))))
;; Decls carrying a body
((= tag "fun-clause")
(list
:fun-clause
(nth node 1)
(nth node 2)
(hk-desugar (nth node 3))))
((= tag "pat-bind")
(list
:pat-bind
(nth node 1)
(hk-desugar (nth node 2))))
((= tag "bind")
(list
:bind
(nth node 1)
(hk-desugar (nth node 2))))
;; Everything else: leaf literals, vars, cons, patterns,
;; types, imports, type-sigs, data / newtype / fixity, …
(:else node)))))))
;; Convenience — tokenize + layout + parse + desugar.
(define
hk-core
(fn (src) (hk-desugar (hk-parse-top src))))
(define
hk-core-expr
(fn (src) (hk-desugar (hk-parse src))))

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;; infer.sx — Hindley-Milner Algorithm W for Haskell-on-SX (Phase 4).
;;
;; Types: TVar, TCon, TArr, TApp, TTuple, TScheme
;; Substitution: apply, compose, restrict
;; Unification (with occurs check)
;; Instantiation + generalization (let-polymorphism)
;; Algorithm W for: literals, var, con, lambda, app, let, if, op, tuple, list
;; ─── Type constructors ────────────────────────────────────────────────────────
(define hk-tvar (fn (n) (list "TVar" n)))
(define hk-tcon (fn (s) (list "TCon" s)))
(define hk-tarr (fn (a b) (list "TArr" a b)))
(define hk-tapp (fn (a b) (list "TApp" a b)))
(define hk-ttuple (fn (ts) (list "TTuple" ts)))
(define hk-tscheme (fn (vs t) (list "TScheme" vs t)))
(define hk-tvar? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TVar"))))
(define hk-tcon? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TCon"))))
(define hk-tarr? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TArr"))))
(define hk-tapp? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TApp"))))
(define hk-ttuple? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TTuple"))))
(define hk-tscheme? (fn (t) (and (list? t) (not (empty? t)) (= (first t) "TScheme"))))
(define hk-tvar-name (fn (t) (nth t 1)))
(define hk-tcon-name (fn (t) (nth t 1)))
(define hk-tarr-t1 (fn (t) (nth t 1)))
(define hk-tarr-t2 (fn (t) (nth t 2)))
(define hk-tapp-t1 (fn (t) (nth t 1)))
(define hk-tapp-t2 (fn (t) (nth t 2)))
(define hk-ttuple-ts (fn (t) (nth t 1)))
(define hk-tscheme-vs (fn (t) (nth t 1)))
(define hk-tscheme-type (fn (t) (nth t 2)))
(define hk-t-int (hk-tcon "Int"))
(define hk-t-bool (hk-tcon "Bool"))
(define hk-t-string (hk-tcon "String"))
(define hk-t-char (hk-tcon "Char"))
(define hk-t-float (hk-tcon "Float"))
(define hk-t-list (fn (t) (hk-tapp (hk-tcon "[]") t)))
;; ─── Type formatter ──────────────────────────────────────────────────────────
(define
hk-type->str
(fn
(t)
(cond
((hk-tvar? t) (hk-tvar-name t))
((hk-tcon? t) (hk-tcon-name t))
((hk-tarr? t)
(let ((s1 (if (hk-tarr? (hk-tarr-t1 t))
(str "(" (hk-type->str (hk-tarr-t1 t)) ")")
(hk-type->str (hk-tarr-t1 t)))))
(str s1 " -> " (hk-type->str (hk-tarr-t2 t)))))
((hk-tapp? t)
(let ((h (hk-tapp-t1 t)))
(cond
((and (hk-tcon? h) (= (hk-tcon-name h) "[]"))
(str "[" (hk-type->str (hk-tapp-t2 t)) "]"))
(:else
(str "(" (hk-type->str h) " " (hk-type->str (hk-tapp-t2 t)) ")")))))
((hk-ttuple? t)
(str "(" (join ", " (map hk-type->str (hk-ttuple-ts t))) ")"))
((hk-tscheme? t)
(str "forall " (join " " (hk-tscheme-vs t)) ". " (hk-type->str (hk-tscheme-type t))))
(:else "<?>"))))
;; ─── Fresh variable counter ───────────────────────────────────────────────────
(define hk-fresh-ctr 0)
(define hk-fresh (fn () (set! hk-fresh-ctr (+ hk-fresh-ctr 1)) (hk-tvar (str "t" hk-fresh-ctr))))
(define hk-reset-fresh (fn () (set! hk-fresh-ctr 0)))
;; ─── Utilities ───────────────────────────────────────────────────────────────
(define hk-infer-member? (fn (x lst) (some (fn (y) (= x y)) lst)))
(define
hk-nub
(fn (lst)
(reduce (fn (acc x) (if (hk-infer-member? x acc) acc (append acc (list x)))) (list) lst)))
;; ─── Free type variables ──────────────────────────────────────────────────────
(define
hk-ftv
(fn
(t)
(cond
((hk-tvar? t) (list (hk-tvar-name t)))
((hk-tcon? t) (list))
((hk-tarr? t) (append (hk-ftv (hk-tarr-t1 t)) (hk-ftv (hk-tarr-t2 t))))
((hk-tapp? t) (append (hk-ftv (hk-tapp-t1 t)) (hk-ftv (hk-tapp-t2 t))))
((hk-ttuple? t) (reduce append (list) (map hk-ftv (hk-ttuple-ts t))))
((hk-tscheme? t)
(filter
(fn (v) (not (hk-infer-member? v (hk-tscheme-vs t))))
(hk-ftv (hk-tscheme-type t))))
(:else (list)))))
(define
hk-ftv-env
(fn (env)
(reduce (fn (acc k) (append acc (hk-ftv (get env k)))) (list) (keys env))))
;; ─── Substitution ─────────────────────────────────────────────────────────────
(define hk-subst-empty (dict))
(define
hk-subst-restrict
(fn
(s exclude)
(let ((r (dict)))
(for-each
(fn (k)
(when (not (hk-infer-member? k exclude))
(dict-set! r k (get s k))))
(keys s))
r)))
(define
hk-subst-apply
(fn
(s t)
(cond
((hk-tvar? t)
(let ((v (get s (hk-tvar-name t))))
(if (nil? v) t (hk-subst-apply s v))))
((hk-tarr? t)
(hk-tarr (hk-subst-apply s (hk-tarr-t1 t))
(hk-subst-apply s (hk-tarr-t2 t))))
((hk-tapp? t)
(hk-tapp (hk-subst-apply s (hk-tapp-t1 t))
(hk-subst-apply s (hk-tapp-t2 t))))
((hk-ttuple? t)
(hk-ttuple (map (fn (u) (hk-subst-apply s u)) (hk-ttuple-ts t))))
((hk-tscheme? t)
(let ((s2 (hk-subst-restrict s (hk-tscheme-vs t))))
(hk-tscheme (hk-tscheme-vs t)
(hk-subst-apply s2 (hk-tscheme-type t)))))
(:else t))))
(define
hk-subst-compose
(fn
(s2 s1)
(let ((r (hk-dict-copy s2)))
(for-each
(fn (k)
(when (nil? (get r k))
(dict-set! r k (hk-subst-apply s2 (get s1 k)))))
(keys s1))
r)))
(define
hk-env-apply-subst
(fn
(s env)
(let ((r (dict)))
(for-each (fn (k) (dict-set! r k (hk-subst-apply s (get env k)))) (keys env))
r)))
;; ─── Unification ─────────────────────────────────────────────────────────────
(define
hk-bind-var
(fn
(v t)
(cond
((and (hk-tvar? t) (= (hk-tvar-name t) v))
hk-subst-empty)
((hk-infer-member? v (hk-ftv t))
(raise (str "Occurs check failed: " v " in " (hk-type->str t))))
(:else
(let ((s (dict)))
(dict-set! s v t)
s)))))
(define
hk-zip-unify
(fn
(ts1 ts2 acc)
(if (or (empty? ts1) (empty? ts2))
acc
(let ((s (hk-unify (hk-subst-apply acc (first ts1))
(hk-subst-apply acc (first ts2)))))
(hk-zip-unify (rest ts1) (rest ts2) (hk-subst-compose s acc))))))
(define
hk-unify
(fn
(t1 t2)
(cond
((and (hk-tvar? t1) (hk-tvar? t2) (= (hk-tvar-name t1) (hk-tvar-name t2)))
hk-subst-empty)
((hk-tvar? t1) (hk-bind-var (hk-tvar-name t1) t2))
((hk-tvar? t2) (hk-bind-var (hk-tvar-name t2) t1))
((and (hk-tcon? t1) (hk-tcon? t2) (= (hk-tcon-name t1) (hk-tcon-name t2)))
hk-subst-empty)
((and (hk-tarr? t1) (hk-tarr? t2))
(let ((s1 (hk-unify (hk-tarr-t1 t1) (hk-tarr-t1 t2))))
(let ((s2 (hk-unify (hk-subst-apply s1 (hk-tarr-t2 t1))
(hk-subst-apply s1 (hk-tarr-t2 t2)))))
(hk-subst-compose s2 s1))))
((and (hk-tapp? t1) (hk-tapp? t2))
(let ((s1 (hk-unify (hk-tapp-t1 t1) (hk-tapp-t1 t2))))
(let ((s2 (hk-unify (hk-subst-apply s1 (hk-tapp-t2 t1))
(hk-subst-apply s1 (hk-tapp-t2 t2)))))
(hk-subst-compose s2 s1))))
((and (hk-ttuple? t1) (hk-ttuple? t2)
(= (length (hk-ttuple-ts t1)) (length (hk-ttuple-ts t2))))
(hk-zip-unify (hk-ttuple-ts t1) (hk-ttuple-ts t2) hk-subst-empty))
(:else
(raise (str "Cannot unify " (hk-type->str t1) " with " (hk-type->str t2)))))))
;; ─── Instantiation and generalization ────────────────────────────────────────
(define
hk-instantiate
(fn
(t)
(if (not (hk-tscheme? t))
t
(let ((s (dict)))
(for-each (fn (v) (dict-set! s v (hk-fresh))) (hk-tscheme-vs t))
(hk-subst-apply s (hk-tscheme-type t))))))
(define
hk-generalize
(fn
(env t)
(let ((free-t (hk-nub (hk-ftv t)))
(free-env (hk-nub (hk-ftv-env env))))
(let ((bound (filter (fn (v) (not (hk-infer-member? v free-env))) free-t)))
(if (empty? bound)
t
(hk-tscheme bound t))))))
;; ─── Pattern binding extraction ──────────────────────────────────────────────
;; Returns a dict of name → type bindings introduced by matching pat against tv.
(define
hk-w-pat
(fn
(pat tv)
(let ((tag (first pat)))
(cond
((= tag "p-var") (let ((d (dict))) (dict-set! d (nth pat 1) tv) d))
((= tag "p-wild") (dict))
(:else (dict))))))
;; ─── Algorithm W ─────────────────────────────────────────────────────────────
;; hk-w : env × expr → (list subst type)
(define
hk-w-let
(fn
(env binds body)
;; Infer types for each binding in order, generalising at each step.
(let
((env2
(reduce
(fn
(cur-env b)
(let ((tag (first b)))
(cond
;; Simple pattern binding: let x = expr
((or (= tag "bind") (= tag "pat-bind"))
(let ((pat (nth b 1))
(rhs (nth b 2)))
(let ((tv (hk-fresh)))
(let ((r (hk-w cur-env rhs)))
(let ((s1 (first r)) (t1 (nth r 1)))
(let ((s2 (hk-unify (hk-subst-apply s1 tv) t1)))
(let ((s (hk-subst-compose s2 s1)))
(let ((t-gen (hk-generalize (hk-env-apply-subst s cur-env)
(hk-subst-apply s t1))))
(let ((bindings (hk-w-pat pat t-gen)))
(let ((r2 (hk-dict-copy cur-env)))
(for-each
(fn (k) (dict-set! r2 k (get bindings k)))
(keys bindings))
r2))))))))))
;; Function clause: let f x y = expr
((= tag "fun-clause")
(let ((name (nth b 1))
(pats (nth b 2))
(body2 (nth b 3)))
;; Treat as: let name = lambda pats body2
(let ((rhs (if (empty? pats)
body2
(list "lambda" pats body2))))
(let ((tv (hk-fresh)))
(let ((env-rec (hk-dict-copy cur-env)))
(dict-set! env-rec name tv)
(let ((r (hk-w env-rec rhs)))
(let ((s1 (first r)) (t1 (nth r 1)))
(let ((s2 (hk-unify (hk-subst-apply s1 tv) t1)))
(let ((s (hk-subst-compose s2 s1)))
(let ((t-gen (hk-generalize
(hk-env-apply-subst s cur-env)
(hk-subst-apply s t1))))
(let ((r2 (hk-dict-copy cur-env)))
(dict-set! r2 name t-gen)
r2)))))))))))
(:else cur-env))))
env
binds)))
(hk-w env2 body))))
(define
hk-w
(fn
(env expr)
(let ((tag (first expr)))
(cond
;; Literals
((= tag "int") (list hk-subst-empty hk-t-int))
((= tag "float") (list hk-subst-empty hk-t-float))
((= tag "string") (list hk-subst-empty hk-t-string))
((= tag "char") (list hk-subst-empty hk-t-char))
;; Variable
((= tag "var")
(let ((name (nth expr 1)))
(let ((scheme (get env name)))
(if (nil? scheme)
(raise (str "Unbound variable: " name))
(list hk-subst-empty (hk-instantiate scheme))))))
;; Constructor (same lookup as var)
((= tag "con")
(let ((name (nth expr 1)))
(let ((scheme (get env name)))
(if (nil? scheme)
(list hk-subst-empty (hk-fresh))
(list hk-subst-empty (hk-instantiate scheme))))))
;; Unary negation
((= tag "neg")
(let ((r (hk-w env (nth expr 1))))
(let ((s1 (first r)) (t1 (nth r 1)))
(let ((s2 (hk-unify t1 hk-t-int)))
(list (hk-subst-compose s2 s1) hk-t-int)))))
;; Lambda: ("lambda" pats body)
((= tag "lambda")
(let ((pats (nth expr 1))
(body (nth expr 2)))
(if (empty? pats)
(hk-w env body)
(let ((pat (first pats))
(rest (rest pats)))
(let ((tv (hk-fresh)))
(let ((bindings (hk-w-pat pat tv)))
(let ((env2 (hk-dict-copy env)))
(for-each (fn (k) (dict-set! env2 k (get bindings k))) (keys bindings))
(let ((inner (if (empty? rest)
body
(list "lambda" rest body))))
(let ((r (hk-w env2 inner)))
(let ((s1 (first r)) (t1 (nth r 1)))
(list s1 (hk-tarr (hk-subst-apply s1 tv) t1))))))))))))
;; Application: ("app" f x)
((= tag "app")
(let ((tv (hk-fresh)))
(let ((r1 (hk-w env (nth expr 1))))
(let ((s1 (first r1)) (tf (nth r1 1)))
(let ((r2 (hk-w (hk-env-apply-subst s1 env) (nth expr 2))))
(let ((s2 (first r2)) (tx (nth r2 1)))
(let ((s3 (hk-unify (hk-subst-apply s2 tf) (hk-tarr tx tv))))
(let ((s (hk-subst-compose s3 (hk-subst-compose s2 s1))))
(list s (hk-subst-apply s3 tv))))))))))
;; Let: ("let" binds body)
((= tag "let")
(hk-w-let env (nth expr 1) (nth expr 2)))
;; If: ("if" cond then else)
((= tag "if")
(let ((r1 (hk-w env (nth expr 1))))
(let ((s1 (first r1)) (tc (nth r1 1)))
(let ((s2 (hk-unify tc hk-t-bool)))
(let ((s12 (hk-subst-compose s2 s1)))
(let ((r2 (hk-w (hk-env-apply-subst s12 env) (nth expr 2))))
(let ((s3 (first r2)) (tt (nth r2 1)))
(let ((s123 (hk-subst-compose s3 s12)))
(let ((r3 (hk-w (hk-env-apply-subst s123 env) (nth expr 3))))
(let ((s4 (first r3)) (te (nth r3 1)))
(let ((s5 (hk-unify (hk-subst-apply s4 tt) te)))
(let ((s (hk-subst-compose s5 (hk-subst-compose s4 s123))))
(list s (hk-subst-apply s5 te))))))))))))))
;; Binary operator: ("op" op-name left right)
;; Desugar to double application.
((= tag "op")
(hk-w env
(list "app"
(list "app" (list "var" (nth expr 1)) (nth expr 2))
(nth expr 3))))
;; Tuple: ("tuple" [e1 e2 ...])
((= tag "tuple")
(let ((elems (nth expr 1)))
(let ((s-acc hk-subst-empty)
(ts (list)))
(for-each
(fn (e)
(let ((r (hk-w (hk-env-apply-subst s-acc env) e)))
(set! s-acc (hk-subst-compose (first r) s-acc))
(set! ts (append ts (list (nth r 1))))))
elems)
(list s-acc (hk-ttuple (map (fn (t) (hk-subst-apply s-acc t)) ts))))))
;; List literal: ("list" [e1 e2 ...])
((= tag "list")
(let ((elems (nth expr 1)))
(if (empty? elems)
(list hk-subst-empty (hk-t-list (hk-fresh)))
(let ((tv (hk-fresh)))
(let ((s-acc hk-subst-empty))
(for-each
(fn (e)
(let ((r (hk-w (hk-env-apply-subst s-acc env) e)))
(let ((s2 (first r)) (te (nth r 1)))
(let ((s3 (hk-unify (hk-subst-apply s2 tv) te)))
(set! s-acc (hk-subst-compose s3 (hk-subst-compose s2 s-acc)))))))
elems)
(list s-acc (hk-t-list (hk-subst-apply s-acc tv))))))))
;; Location annotation: just delegate — position is for outer context.
((= tag "loc")
(hk-w env (nth expr 3)))
(:else
(raise (str "hk-w: unhandled tag: " tag)))))))
;; ─── Initial type environment ─────────────────────────────────────────────────
;; Monomorphic numeric ops (no Num typeclass yet — upgraded in Phase 5).
(define
hk-type-env0
(fn ()
(let ((env (dict)))
;; Integer arithmetic
(for-each
(fn (op)
(dict-set! env op (hk-tarr hk-t-int (hk-tarr hk-t-int hk-t-int))))
(list "+" "-" "*" "div" "mod" "quot" "rem"))
;; Integer comparison → Bool
(for-each
(fn (op)
(dict-set! env op (hk-tarr hk-t-int (hk-tarr hk-t-int hk-t-bool))))
(list "==" "/=" "<" "<=" ">" ">="))
;; Boolean operators
(dict-set! env "&&" (hk-tarr hk-t-bool (hk-tarr hk-t-bool hk-t-bool)))
(dict-set! env "||" (hk-tarr hk-t-bool (hk-tarr hk-t-bool hk-t-bool)))
(dict-set! env "not" (hk-tarr hk-t-bool hk-t-bool))
;; Constructors
(dict-set! env "True" hk-t-bool)
(dict-set! env "False" hk-t-bool)
;; Polymorphic list ops (using TScheme)
(let ((a (hk-tvar "a")))
(dict-set! env "head" (hk-tscheme (list "a") (hk-tarr (hk-t-list a) a)))
(dict-set! env "tail" (hk-tscheme (list "a") (hk-tarr (hk-t-list a) (hk-t-list a))))
(dict-set! env "null" (hk-tscheme (list "a") (hk-tarr (hk-t-list a) hk-t-bool)))
(dict-set! env "length" (hk-tscheme (list "a") (hk-tarr (hk-t-list a) hk-t-int)))
(dict-set! env "reverse" (hk-tscheme (list "a") (hk-tarr (hk-t-list a) (hk-t-list a))))
(dict-set! env ":"
(hk-tscheme (list "a") (hk-tarr a (hk-tarr (hk-t-list a) (hk-t-list a))))))
;; negate
(dict-set! env "negate" (hk-tarr hk-t-int hk-t-int))
(dict-set! env "abs" (hk-tarr hk-t-int hk-t-int))
env)))
;; ─── Expression brief printer ────────────────────────────────────────────────
;; Produces a short human-readable label for an AST node used in error messages.
(define
hk-expr->brief
(fn
(expr)
(cond
((not (list? expr)) (str expr))
((empty? expr) "()")
(:else
(let ((tag (first expr)))
(cond
((= tag "var") (nth expr 1))
((= tag "con") (nth expr 1))
((= tag "int") (str (nth expr 1)))
((= tag "float") (str (nth expr 1)))
((= tag "string") (str "\"" (nth expr 1) "\""))
((= tag "char") (str "'" (nth expr 1) "'"))
((= tag "neg") (str "(-" (hk-expr->brief (nth expr 1)) ")"))
((= tag "app")
(str "(" (hk-expr->brief (nth expr 1))
" " (hk-expr->brief (nth expr 2)) ")"))
((= tag "op")
(str "(" (hk-expr->brief (nth expr 2))
" " (nth expr 1)
" " (hk-expr->brief (nth expr 3)) ")"))
((= tag "lambda") "(\\ ...)")
((= tag "let") "(let ...)")
((= tag "if") "(if ...)")
((= tag "tuple") "(tuple ...)")
((= tag "list") "[...]")
((= tag "loc") (hk-expr->brief (nth expr 3)))
(:else (str "(" tag " ..."))))))))
;; ─── Loc-annotated inference ──────────────────────────────────────────────────
;; ("loc" LINE COL INNER) node: hk-w catches any error and re-raises with
;; "at LINE:COL: " prepended. Emitted by the parser or test scaffolding.
;; Extended hk-w handles "loc" — handled inline in the cond below.
;; ─── Program-level inference ─────────────────────────────────────────────────
;; hk-infer-decl : env × decl → ("ok" name type-str) | ("err" msg) | nil
;; Uses tagged results so callers don't need re-raise.
(define
hk-infer-decl
(fn
(env decl)
(let
((tag (first decl)))
(cond
((= tag "fun-clause")
(let
((name (nth decl 1)) (pats (nth decl 2)) (body (nth decl 3)))
(let
((rhs (if (empty? pats) body (list "lambda" pats body))))
(guard
(e (#t (list "err" (str "in '" name "': " e))))
(begin
(hk-reset-fresh)
(let
((r (hk-w env rhs)))
(let
((final-type (hk-subst-apply (first r) (nth r 1))))
(list "ok" name (hk-type->str final-type) final-type))))))))
((or (= tag "bind") (= tag "pat-bind"))
(let
((pat (nth decl 1)) (body (nth decl 2)))
(let
((label (if (and (list? pat) (= (first pat) "p-var")) (nth pat 1) "<binding>")))
(guard
(e (#t (list "err" (str "in '" label "': " e))))
(begin
(hk-reset-fresh)
(let
((r (hk-w env body)))
(let
((final-type (hk-subst-apply (first r) (nth r 1))))
(list "ok" label (hk-type->str final-type) final-type))))))))
(:else nil)))))
;; hk-infer-prog : program-ast × env → list of ("ok" name type) | ("err" msg)
(define
hk-ast-type
(fn
(ast)
(let
((tag (first ast)))
(cond
((= tag "t-con") (list "TCon" (nth ast 1)))
((= tag "t-var") (list "TVar" (nth ast 1)))
((= tag "t-fun")
(list "TArr" (hk-ast-type (nth ast 1)) (hk-ast-type (nth ast 2))))
((= tag "t-app")
(list "TApp" (hk-ast-type (nth ast 1)) (hk-ast-type (nth ast 2))))
((= tag "t-list")
(list "TApp" (list "TCon" "[]") (hk-ast-type (nth ast 1))))
((= tag "t-tuple") (list "TTuple" (map hk-ast-type (nth ast 1))))
(:else (raise (str "unknown type node: " (first ast))))))))
;; ─── Convenience ─────────────────────────────────────────────────────────────
;; hk-infer-type : Haskell expression source → inferred type string
(define
hk-collect-tvars
(fn
(t acc)
(cond
((= (first t) "TVar")
(if
(some (fn (v) (= v (nth t 1))) acc)
acc
(begin (append! acc (nth t 1)) acc)))
((= (first t) "TArr")
(hk-collect-tvars (nth t 2) (hk-collect-tvars (nth t 1) acc)))
((= (first t) "TApp")
(hk-collect-tvars (nth t 2) (hk-collect-tvars (nth t 1) acc)))
((= (first t) "TTuple")
(reduce (fn (a elem) (hk-collect-tvars elem a)) acc (nth t 1)))
(:else acc))))
(define
hk-check-sig
(fn
(declared-ast inferred-type)
(let
((declared (hk-ast-type declared-ast)))
(let
((tvars (hk-collect-tvars declared (list))))
(let
((scheme (if (empty? tvars) declared (list "TScheme" tvars declared))))
(let
((inst (hk-instantiate scheme)))
(hk-unify inst inferred-type)))))))
(define
hk-infer-prog
(fn
(prog env)
(let
((decls (cond ((and (list? prog) (= (first prog) "program")) (nth prog 1)) ((and (list? prog) (= (first prog) "module")) (nth prog 3)) (:else (list))))
(results (list))
(sigs (dict)))
(for-each
(fn
(d)
(when
(= (first d) "type-sig")
(let
((names (nth d 1)) (type-ast (nth d 2)))
(for-each (fn (n) (dict-set! sigs n type-ast)) names))))
decls)
(for-each
(fn
(d)
(let
((r (hk-infer-decl env d)))
(when
(not (nil? r))
(let
((checked (if (and (= (first r) "ok") (has-key? sigs (nth r 1))) (guard (e (true (list "err" (str "in '" (nth r 1) "': declared type mismatch: " e)))) (begin (hk-check-sig (get sigs (nth r 1)) (nth r 3)) r)) r)))
(append! results checked)
(when
(= (first checked) "ok")
(dict-set! env (nth checked 1) (nth checked 3)))))))
decls)
results)))
(define
hk-infer-type
(fn
(src)
(hk-reset-fresh)
(let
((ast (hk-core-expr src)) (env (hk-type-env0)))
(let
((r (hk-w env ast)))
(hk-type->str (hk-subst-apply (first r) (nth r 1)))))))

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;; Haskell 98 layout algorithm (§10.3).
;;
;; Consumes the raw token stream produced by hk-tokenize and inserts
;; virtual braces / semicolons (types vlbrace / vrbrace / vsemi) based
;; on indentation. Newline tokens are consumed and stripped.
;;
;; (hk-layout (hk-tokenize src)) → tokens-with-virtual-layout
;; ── Pre-pass ──────────────────────────────────────────────────────
;;
;; Walks the raw token list and emits an augmented stream containing
;; two fresh pseudo-tokens:
;;
;; {:type "layout-open" :col N :keyword K}
;; At stream start (K = "<module>") unless the first real token is
;; `module` or `{`. Also immediately after every `let` / `where` /
;; `do` / `of` whose following token is NOT `{`. N is the column
;; of the token that follows.
;;
;; {:type "layout-indent" :col N}
;; Before any token whose line is strictly greater than the line
;; of the previously emitted real token, EXCEPT when that token
;; is already preceded by a layout-open (Haskell 98 §10.3 note 3).
;;
;; Raw newline tokens are dropped.
(define
hk-layout-keyword?
(fn
(tok)
(and
(= (get tok "type") "reserved")
(or
(= (get tok "value") "let")
(= (get tok "value") "where")
(= (get tok "value") "do")
(= (get tok "value") "of")))))
(define
hk-layout-pre
(fn
(tokens)
(let
((result (list))
(n (len tokens))
(i 0)
(prev-line -1)
(first-real-emitted false)
(suppress-next-indent false))
(define
hk-next-real-idx
(fn
(start)
(let
((j start))
(define
hk-nri-loop
(fn
()
(when
(and
(< j n)
(= (get (nth tokens j) "type") "newline"))
(do (set! j (+ j 1)) (hk-nri-loop)))))
(hk-nri-loop)
j)))
(define
hk-pre-step
(fn
()
(when
(< i n)
(let
((tok (nth tokens i)) (ty (get tok "type")))
(cond
((= ty "newline") (do (set! i (+ i 1)) (hk-pre-step)))
(:else
(do
(when
(not first-real-emitted)
(do
(set! first-real-emitted true)
(when
(not
(or
(and
(= ty "reserved")
(= (get tok "value") "module"))
(= ty "lbrace")))
(do
(append!
result
{:type "layout-open"
:col (get tok "col")
:keyword "<module>"
:line (get tok "line")})
(set! suppress-next-indent true)))))
(when
(and
(>= prev-line 0)
(> (get tok "line") prev-line)
(not suppress-next-indent))
(append!
result
{:type "layout-indent"
:col (get tok "col")
:line (get tok "line")}))
(set! suppress-next-indent false)
(set! prev-line (get tok "line"))
(append! result tok)
(when
(hk-layout-keyword? tok)
(let
((j (hk-next-real-idx (+ i 1))))
(cond
((>= j n)
(do
(append!
result
{:type "layout-open"
:col 0
:keyword (get tok "value")
:line (get tok "line")})
(set! suppress-next-indent true)))
((= (get (nth tokens j) "type") "lbrace") nil)
(:else
(do
(append!
result
{:type "layout-open"
:col (get (nth tokens j) "col")
:keyword (get tok "value")
:line (get tok "line")})
(set! suppress-next-indent true))))))
(set! i (+ i 1))
(hk-pre-step))))))))
(hk-pre-step)
result)))
;; ── Main pass: L algorithm ────────────────────────────────────────
;;
;; Stack is a list; the head is the top of stack. Each entry is
;; either the keyword :explicit (pushed by an explicit `{`) or a dict
;; {:col N :keyword K} pushed by a layout-open marker.
;;
;; Rules (following Haskell 98 §10.3):
;;
;; layout-open(n) vs stack:
;; empty or explicit top → push n; emit {
;; n > top-col → push n; emit {
;; otherwise → emit { }; retry as indent(n)
;;
;; layout-indent(n) vs stack:
;; empty or explicit top → drop
;; n == top-col → emit ;
;; n < top-col → emit }; pop; recurse
;; n > top-col → drop
;;
;; lbrace → push :explicit; emit {
;; rbrace → pop if :explicit; emit }
;; `in` with implicit let on top → emit }; pop; emit in
;; any other token → emit
;;
;; EOF: emit } for every remaining implicit context.
(define
hk-layout-L
(fn
(pre-toks)
(let
((result (list))
(stack (list))
(n (len pre-toks))
(i 0))
(define hk-emit (fn (t) (append! result t)))
(define
hk-indent-at
(fn
(col line)
(cond
((or (empty? stack) (= (first stack) :explicit)) nil)
(:else
(let
((top-col (get (first stack) "col")))
(cond
((= col top-col)
(hk-emit
{:type "vsemi" :value ";" :line line :col col}))
((< col top-col)
(do
(hk-emit
{:type "vrbrace" :value "}" :line line :col col})
(set! stack (rest stack))
(hk-indent-at col line)))
(:else nil)))))))
(define
hk-open-at
(fn
(col keyword line)
(cond
((and
(> col 0)
(or
(empty? stack)
(= (first stack) :explicit)
(> col (get (first stack) "col"))))
(do
(hk-emit
{:type "vlbrace" :value "{" :line line :col col})
(set! stack (cons {:col col :keyword keyword} stack))))
(:else
(do
(hk-emit
{:type "vlbrace" :value "{" :line line :col col})
(hk-emit
{:type "vrbrace" :value "}" :line line :col col})
(hk-indent-at col line))))))
(define
hk-close-eof
(fn
()
(when
(and
(not (empty? stack))
(not (= (first stack) :explicit)))
(do
(hk-emit {:type "vrbrace" :value "}" :line 0 :col 0})
(set! stack (rest stack))
(hk-close-eof)))))
;; Peek past further layout-indent / layout-open markers to find
;; the next real token's value when its type is `reserved`.
;; Returns nil if no such token.
(define
hk-peek-next-reserved
(fn
(start)
(let ((j (+ start 1)) (found nil) (done false))
(define
hk-pnr-loop
(fn
()
(when
(and (not done) (< j n))
(let
((t (nth pre-toks j)) (ty (get t "type")))
(cond
((or
(= ty "layout-indent")
(= ty "layout-open"))
(do (set! j (+ j 1)) (hk-pnr-loop)))
((= ty "reserved")
(do (set! found (get t "value")) (set! done true)))
(:else (set! done true)))))))
(hk-pnr-loop)
found)))
(define
hk-layout-step
(fn
()
(when
(< i n)
(let
((tok (nth pre-toks i)) (ty (get tok "type")))
(cond
((= ty "eof")
(do
(hk-close-eof)
(hk-emit tok)
(set! i (+ i 1))
(hk-layout-step)))
((= ty "layout-open")
(do
(hk-open-at
(get tok "col")
(get tok "keyword")
(get tok "line"))
(set! i (+ i 1))
(hk-layout-step)))
((= ty "layout-indent")
(cond
((= (hk-peek-next-reserved i) "in")
(do (set! i (+ i 1)) (hk-layout-step)))
(:else
(do
(hk-indent-at (get tok "col") (get tok "line"))
(set! i (+ i 1))
(hk-layout-step)))))
((= ty "lbrace")
(do
(set! stack (cons :explicit stack))
(hk-emit tok)
(set! i (+ i 1))
(hk-layout-step)))
((= ty "rbrace")
(do
(when
(and
(not (empty? stack))
(= (first stack) :explicit))
(set! stack (rest stack)))
(hk-emit tok)
(set! i (+ i 1))
(hk-layout-step)))
((and
(= ty "reserved")
(= (get tok "value") "in")
(not (empty? stack))
(not (= (first stack) :explicit))
(= (get (first stack) "keyword") "let"))
(do
(hk-emit
{:type "vrbrace"
:value "}"
:line (get tok "line")
:col (get tok "col")})
(set! stack (rest stack))
(hk-emit tok)
(set! i (+ i 1))
(hk-layout-step)))
(:else
(do
(hk-emit tok)
(set! i (+ i 1))
(hk-layout-step))))))))
(hk-layout-step)
(hk-close-eof)
result)))
(define hk-layout (fn (tokens) (hk-layout-L (hk-layout-pre tokens))))

201
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@@ -0,0 +1,201 @@
;; Value-level pattern matching.
;;
;; Constructor values are tagged lists whose first element is the
;; constructor name (a string). Tuples use the special tag "Tuple".
;; Lists use the spine of `:` cons and `[]` nil.
;;
;; Just 5 → ("Just" 5)
;; Nothing → ("Nothing")
;; (1, 2) → ("Tuple" 1 2)
;; [1, 2] → (":" 1 (":" 2 ("[]")))
;; () → ("()")
;;
;; Primitive values (numbers, strings, chars) are stored raw.
;;
;; The matcher takes a pattern AST node, a value, and an environment
;; dict; it returns an extended dict on success, or `nil` on failure.
;; ── Value builders ──────────────────────────────────────────
(define
hk-mk-con
(fn
(cname args)
(let ((result (list cname)))
(for-each (fn (a) (append! result a)) args)
result)))
(define
hk-mk-tuple
(fn
(items)
(let ((result (list "Tuple")))
(for-each (fn (x) (append! result x)) items)
result)))
(define hk-mk-nil (fn () (list "[]")))
(define hk-mk-cons (fn (h t) (list ":" h t)))
(define
hk-mk-list
(fn
(items)
(cond
((empty? items) (hk-mk-nil))
(:else
(hk-mk-cons (first items) (hk-mk-list (rest items)))))))
;; ── Predicates / accessors on constructor values ───────────
(define
hk-is-con-val?
(fn
(v)
(and
(list? v)
(not (empty? v))
(string? (first v)))))
(define hk-val-con-name (fn (v) (first v)))
(define hk-val-con-args (fn (v) (rest v)))
;; ── The matcher ────────────────────────────────────────────
;;
;; Pattern match forces the scrutinee to WHNF before inspecting it
;; — except for `p-wild`, `p-var`, and `p-lazy`, which never need
;; to look at the value. Args of constructor / tuple / list values
;; remain thunked (they're forced only when their own pattern needs
;; to inspect them, recursively).
(define
hk-match
(fn
(pat val env)
(cond
((not (list? pat)) nil)
((empty? pat) nil)
(:else
(let
((tag (first pat)))
(cond
((= tag "p-wild") env)
((= tag "p-var") (assoc env (nth pat 1) val))
((= tag "p-lazy") (hk-match (nth pat 1) val env))
((= tag "p-as")
(let
((res (hk-match (nth pat 2) val env)))
(cond
((nil? res) nil)
(:else (assoc res (nth pat 1) val)))))
(:else
(let ((fv (hk-force val)))
(cond
((= tag "p-int")
(if
(and (number? fv) (= fv (nth pat 1)))
env
nil))
((= tag "p-float")
(if
(and (number? fv) (= fv (nth pat 1)))
env
nil))
((= tag "p-string")
(if
(and (string? fv) (= fv (nth pat 1)))
env
nil))
((= tag "p-char")
(if
(and (string? fv) (= fv (nth pat 1)))
env
nil))
((= tag "p-con")
(let
((pat-name (nth pat 1)) (pat-args (nth pat 2)))
(cond
((not (hk-is-con-val? fv)) nil)
((not (= (hk-val-con-name fv) pat-name)) nil)
(:else
(let
((val-args (hk-val-con-args fv)))
(cond
((not (= (len pat-args) (len val-args)))
nil)
(:else
(hk-match-all
pat-args
val-args
env))))))))
((= tag "p-tuple")
(let
((items (nth pat 1)))
(cond
((not (hk-is-con-val? fv)) nil)
((not (= (hk-val-con-name fv) "Tuple")) nil)
((not (= (len (hk-val-con-args fv)) (len items)))
nil)
(:else
(hk-match-all
items
(hk-val-con-args fv)
env)))))
((= tag "p-list")
(hk-match-list-pat (nth pat 1) fv env))
(:else nil))))))))))
(define
hk-match-all
(fn
(pats vals env)
(cond
((empty? pats) env)
(:else
(let
((res (hk-match (first pats) (first vals) env)))
(cond
((nil? res) nil)
(:else
(hk-match-all (rest pats) (rest vals) res))))))))
(define
hk-match-list-pat
(fn
(items val env)
(let ((fv (hk-force val)))
(cond
((empty? items)
(if
(and
(hk-is-con-val? fv)
(= (hk-val-con-name fv) "[]"))
env
nil))
(:else
(cond
((not (hk-is-con-val? fv)) nil)
((not (= (hk-val-con-name fv) ":")) nil)
(:else
(let
((args (hk-val-con-args fv)))
(let
((h (first args)) (t (first (rest args))))
(let
((res (hk-match (first items) h env)))
(cond
((nil? res) nil)
(:else
(hk-match-list-pat
(rest items)
t
res)))))))))))))
;; ── Convenience: parse a pattern from source for tests ─────
;; (Uses the parser's case-alt entry — `case _ of pat -> 0` —
;; to extract a pattern AST.)
(define
hk-parse-pat-source
(fn
(src)
(let
((expr (hk-parse (str "case 0 of " src " -> 0"))))
(nth (nth (nth expr 2) 0) 1))))

1658
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130
lib/haskell/runtime.sx Normal file
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@@ -0,0 +1,130 @@
;; Haskell runtime: constructor registry.
;;
;; A mutable dict keyed by constructor name (e.g. "Just", "[]") with
;; entries of shape {:arity N :type TYPE-NAME-STRING}.
;; Populated by ingesting `data` / `newtype` decls from parsed ASTs.
;; Pre-registers a small set of constructors tied to Haskell syntactic
;; forms (Bool, list, unit) — every nontrivial program depends on
;; these, and the parser/desugar pipeline emits them as (:var "True")
;; etc. without a corresponding `data` decl.
(define hk-constructors (dict))
(define
hk-register-con!
(fn
(cname arity type-name)
(dict-set!
hk-constructors
cname
{:arity arity :type type-name})))
(define hk-is-con? (fn (name) (has-key? hk-constructors name)))
(define
hk-con-arity
(fn
(name)
(if
(has-key? hk-constructors name)
(get (get hk-constructors name) "arity")
nil)))
(define
hk-con-type
(fn
(name)
(if
(has-key? hk-constructors name)
(get (get hk-constructors name) "type")
nil)))
(define hk-con-names (fn () (keys hk-constructors)))
;; ── Registration from AST ────────────────────────────────────
;; (:data NAME TVARS ((:con-def CNAME FIELDS) …))
(define
hk-register-data!
(fn
(data-node)
(let
((type-name (nth data-node 1))
(cons-list (nth data-node 3)))
(for-each
(fn
(cd)
(hk-register-con!
(nth cd 1)
(len (nth cd 2))
type-name))
cons-list))))
;; (:newtype NAME TVARS CNAME FIELD)
(define
hk-register-newtype!
(fn
(nt-node)
(hk-register-con!
(nth nt-node 3)
1
(nth nt-node 1))))
;; Walk a decls list, registering every `data` / `newtype` decl.
(define
hk-register-decls!
(fn
(decls)
(for-each
(fn
(d)
(cond
((and
(list? d)
(not (empty? d))
(= (first d) "data"))
(hk-register-data! d))
((and
(list? d)
(not (empty? d))
(= (first d) "newtype"))
(hk-register-newtype! d))
(:else nil)))
decls)))
(define
hk-register-program!
(fn
(ast)
(cond
((nil? ast) nil)
((not (list? ast)) nil)
((empty? ast) nil)
((= (first ast) "program")
(hk-register-decls! (nth ast 1)))
((= (first ast) "module")
(hk-register-decls! (nth ast 4)))
(:else nil))))
;; Convenience: source → AST → desugar → register.
(define
hk-load-source!
(fn (src) (hk-register-program! (hk-core src))))
;; ── Built-in constructors pre-registered ─────────────────────
;; Bool — used implicitly by `if`, comparison operators.
(hk-register-con! "True" 0 "Bool")
(hk-register-con! "False" 0 "Bool")
;; List — used by list literals, range syntax, and cons operator.
(hk-register-con! "[]" 0 "List")
(hk-register-con! ":" 2 "List")
;; Unit — produced by empty parens `()`.
(hk-register-con! "()" 0 "Unit")
;; Standard Prelude types — pre-registered so expression-level
;; programs can use them without a `data` decl.
(hk-register-con! "Nothing" 0 "Maybe")
(hk-register-con! "Just" 1 "Maybe")
(hk-register-con! "Left" 1 "Either")
(hk-register-con! "Right" 1 "Either")
(hk-register-con! "LT" 0 "Ordering")
(hk-register-con! "EQ" 0 "Ordering")
(hk-register-con! "GT" 0 "Ordering")

25
lib/haskell/scoreboard.json Normal file
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@@ -0,0 +1,25 @@
{
"date": "2026-05-06",
"total_pass": 156,
"total_fail": 0,
"programs": {
"fib": {"pass": 2, "fail": 0},
"sieve": {"pass": 2, "fail": 0},
"quicksort": {"pass": 5, "fail": 0},
"nqueens": {"pass": 2, "fail": 0},
"calculator": {"pass": 5, "fail": 0},
"collatz": {"pass": 11, "fail": 0},
"palindrome": {"pass": 8, "fail": 0},
"maybe": {"pass": 12, "fail": 0},
"fizzbuzz": {"pass": 12, "fail": 0},
"anagram": {"pass": 9, "fail": 0},
"roman": {"pass": 14, "fail": 0},
"binary": {"pass": 12, "fail": 0},
"either": {"pass": 12, "fail": 0},
"primes": {"pass": 12, "fail": 0},
"zipwith": {"pass": 9, "fail": 0},
"matrix": {"pass": 8, "fail": 0},
"wordcount": {"pass": 7, "fail": 0},
"powers": {"pass": 14, "fail": 0}
}
}

25
lib/haskell/scoreboard.md Normal file
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@@ -0,0 +1,25 @@
# Haskell-on-SX Scoreboard
Updated 2026-05-06 · Phase 6 (prelude extras + 18 programs)
| Program | Tests | Status |
|---------|-------|--------|
| fib.hs | 2/2 | ✓ |
| sieve.hs | 2/2 | ✓ |
| quicksort.hs | 5/5 | ✓ |
| nqueens.hs | 2/2 | ✓ |
| calculator.hs | 5/5 | ✓ |
| collatz.hs | 11/11 | ✓ |
| palindrome.hs | 8/8 | ✓ |
| maybe.hs | 12/12 | ✓ |
| fizzbuzz.hs | 12/12 | ✓ |
| anagram.hs | 9/9 | ✓ |
| roman.hs | 14/14 | ✓ |
| binary.hs | 12/12 | ✓ |
| either.hs | 12/12 | ✓ |
| primes.hs | 12/12 | ✓ |
| zipwith.hs | 9/9 | ✓ |
| matrix.hs | 8/8 | ✓ |
| wordcount.hs | 7/7 | ✓ |
| powers.hs | 14/14 | ✓ |
| **Total** | **156/156** | **18/18 programs** |

27
lib/haskell/test.sh
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@@ -14,7 +14,7 @@ cd "$(git rev-parse --show-toplevel)"
SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
if [ ! -x "$SX_SERVER" ]; then
# Fall back to the main-repo build if we're in a worktree.
MAIN_ROOT=$(git worktree list | head -1 | awk '{print $1}')
MAIN_ROOT=$(git worktree list | awk 'NR==1{print $1}')
if [ -x "$MAIN_ROOT/$SX_SERVER" ]; then
SX_SERVER="$MAIN_ROOT/$SX_SERVER"
else
@@ -42,24 +42,35 @@ FAILED_FILES=()
for FILE in "${FILES[@]}"; do
[ -f "$FILE" ] || { echo "skip $FILE (not found)"; continue; }
# Load infer.sx only for infer/typecheck test files (it adds ~6s overhead).
INFER_LOAD=""
case "$FILE" in *infer*|*typecheck*) INFER_LOAD='(load "lib/haskell/infer.sx")' ;; esac
TMPFILE=$(mktemp)
cat > "$TMPFILE" <<EPOCHS
(epoch 1)
(load "lib/haskell/tokenizer.sx")
(load "lib/haskell/layout.sx")
(load "lib/haskell/parser.sx")
(load "lib/haskell/desugar.sx")
(load "lib/haskell/runtime.sx")
(load "lib/haskell/match.sx")
(load "lib/haskell/eval.sx")
$INFER_LOAD
(load "lib/haskell/testlib.sx")
(epoch 2)
(load "$FILE")
(epoch 3)
(eval "(list hk-test-pass hk-test-fail)")
EPOCHS
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>&1 || true)
OUTPUT=$(timeout 360 "$SX_SERVER" < "$TMPFILE" 2>&1 || true)
rm -f "$TMPFILE"
# Output format: either "(ok 3 (P F))" on one line (short result) or
# "(ok-len 3 N)\n(P F)" where the value appears on the following line.
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' | tail -1 \
LINE=$(echo "$OUTPUT" | { grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' || true; } | tail -1 \
| sed -E 's/^\(ok 3 //; s/\)$//')
fi
if [ -z "$LINE" ]; then
@@ -81,12 +92,20 @@ EPOCHS
cat > "$TMPFILE2" <<EPOCHS
(epoch 1)
(load "lib/haskell/tokenizer.sx")
(load "lib/haskell/layout.sx")
(load "lib/haskell/parser.sx")
(load "lib/haskell/desugar.sx")
(load "lib/haskell/runtime.sx")
(load "lib/haskell/match.sx")
(load "lib/haskell/eval.sx")
$INFER_LOAD
(load "lib/haskell/testlib.sx")
(epoch 2)
(load "$FILE")
(epoch 3)
(eval "(map (fn (f) (get f \"name\")) hk-test-fails)")
EPOCHS
FAILS=$(timeout 60 "$SX_SERVER" < "$TMPFILE2" 2>&1 | grep -E '^\(ok 3 ' || true)
FAILS=$(timeout 360 "$SX_SERVER" < "$TMPFILE2" 2>&1 | grep -E '^\(ok 3 ' || true)
rm -f "$TMPFILE2"
echo " $FAILS"
elif [ "$VERBOSE" = "1" ]; then

58
lib/haskell/testlib.sx Normal file
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@@ -0,0 +1,58 @@
;; Shared test harness for Haskell-on-SX tests.
;; Each test file expects hk-test / hk-deep=? / counters to already be bound.
(define
hk-deep=?
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn
(k)
(and (has-key? b k) (hk-deep=? (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(define
hk-de-loop
(fn
()
(when
(and ok (< i (len a)))
(do
(when
(not (hk-deep=? (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(hk-de-loop)))))
(hk-de-loop)
ok)))
(:else false))))
(define hk-test-pass 0)
(define hk-test-fail 0)
(define hk-test-fails (list))
(define
hk-test
(fn
(name actual expected)
(if
(hk-deep=? actual expected)
(set! hk-test-pass (+ hk-test-pass 1))
(do
(set! hk-test-fail (+ hk-test-fail 1))
(append!
hk-test-fails
{:actual actual :expected expected :name name})))))

60
lib/haskell/tests/class.sx Normal file
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@@ -0,0 +1,60 @@
;; class.sx — tests for class/instance parsing and evaluation.
(define prog-class1 (hk-core "class MyEq a where\n myEq :: a -> a -> Bool"))
(define prog-inst1 (hk-core "instance MyEq Int where\n myEq x y = x == y"))
;; ─── class-decl AST ───────────────────────────────────────────────────────────
(define cd1 (first (nth prog-class1 1)))
(hk-test "class-decl tag" (first cd1) "class-decl")
(hk-test "class-decl name" (nth cd1 1) "MyEq")
(hk-test "class-decl tvar" (nth cd1 2) "a")
(hk-test "class-decl methods" (len (nth cd1 3)) 1)
;; ─── instance-decl AST ────────────────────────────────────────────────────────
(define id1 (first (nth prog-inst1 1)))
(hk-test "instance-decl tag" (first id1) "instance-decl")
(hk-test "instance-decl class" (nth id1 1) "MyEq")
(hk-test "instance-decl type tag" (first (nth id1 2)) "t-con")
(hk-test "instance-decl type name" (nth (nth id1 2) 1) "Int")
(hk-test "instance-decl method count" (len (nth id1 3)) 1)
;; ─── eval: instance dict is built ────────────────────────────────────────────
(define
prog-full
(hk-core
"class MyEq a where\n myEq :: a -> a -> Bool\ninstance MyEq Int where\n myEq x y = x == y"))
(define env-full (hk-eval-program prog-full))
(hk-test "instance dict in env" (has-key? env-full "dictMyEq_Int") true)
(hk-test
"instance dict has method"
(has-key? (get env-full "dictMyEq_Int") "myEq")
true)
(hk-test
"dispatch: single-arg method works"
(hk-deep-force
(hk-run
"class Describable a where\n describe :: a -> String\ninstance Describable Int where\n describe x = \"an integer\"\nmain = describe 42"))
"an integer")
(hk-test
"dispatch: second instance (Bool)"
(hk-deep-force
(hk-run
"class Describable a where\n describe :: a -> String\ninstance Describable Bool where\n describe x = \"a boolean\"\ninstance Describable Int where\n describe x = \"an integer\"\nmain = describe True"))
"a boolean")
(hk-test
"dispatch: error on unknown instance"
(guard
(e (true (>= (index-of e "No instance") 0)))
(begin
(hk-deep-force
(hk-run
"class Describable a where\n describe :: a -> String\nmain = describe 42"))
false))
true)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

84
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@@ -0,0 +1,84 @@
;; deriving.sx — tests for deriving (Eq, Show) on ADTs.
;; ─── Show ────────────────────────────────────────────────────────────────────
(hk-test
"deriving Show: nullary constructor"
(hk-deep-force
(hk-run "data Color = Red | Green | Blue deriving (Show)\nmain = show Red"))
"Red")
(hk-test
"deriving Show: constructor with arg"
(hk-deep-force
(hk-run "data Wrapper = Wrap Int deriving (Show)\nmain = show (Wrap 42)"))
"(Wrap 42)")
(hk-test
"deriving Show: nested constructors"
(hk-deep-force
(hk-run
"data Tree = Leaf | Node Int Tree Tree deriving (Show)\nmain = show (Node 1 Leaf Leaf)"))
"(Node 1 Leaf Leaf)")
(hk-test
"deriving Show: second constructor"
(hk-deep-force
(hk-run
"data Color = Red | Green | Blue deriving (Show)\nmain = show Green"))
"Green")
;; ─── Eq ──────────────────────────────────────────────────────────────────────
(hk-test
"deriving Eq: same constructor"
(hk-deep-force
(hk-run
"data Color = Red | Green | Blue deriving (Eq)\nmain = show (Red == Red)"))
"True")
(hk-test
"deriving Eq: different constructors"
(hk-deep-force
(hk-run
"data Color = Red | Green | Blue deriving (Eq)\nmain = show (Red == Blue)"))
"False")
(hk-test
"deriving Eq: /= same"
(hk-deep-force
(hk-run
"data Color = Red | Green | Blue deriving (Eq)\nmain = show (Red /= Red)"))
"False")
(hk-test
"deriving Eq: /= different"
(hk-deep-force
(hk-run
"data Color = Red | Green | Blue deriving (Eq)\nmain = show (Red /= Blue)"))
"True")
;; ─── combined Eq + Show ───────────────────────────────────────────────────────
(hk-test
"deriving Eq Show: combined in parens"
(hk-deep-force
(hk-run
"data Shape = Circle Int | Square Int deriving (Eq, Show)\nmain = show (Circle 5)"))
"(Circle 5)")
(hk-test
"deriving Eq Show: eq on constructor with arg"
(hk-deep-force
(hk-run
"data Shape = Circle Int | Square Int deriving (Eq, Show)\nmain = show (Circle 3 == Circle 3)"))
"True")
(hk-test
"deriving Eq Show: different constructors with args"
(hk-deep-force
(hk-run
"data Shape = Circle Int | Square Int deriving (Eq, Show)\nmain = show (Circle 3 == Square 3)"))
"False")
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

305
lib/haskell/tests/desugar.sx Normal file
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@@ -0,0 +1,305 @@
;; Desugar tests — surface AST → core AST.
;; :guarded → nested :if
;; :where → :let
;; :list-comp → concatMap-based tree
(define
hk-prog
(fn (&rest decls) (list :program decls)))
;; ── Guards → if ──
(hk-test
"two-way guarded rhs"
(hk-desugar (hk-parse-top "abs x | x < 0 = - x\n | otherwise = x"))
(hk-prog
(list
:fun-clause
"abs"
(list (list :p-var "x"))
(list
:if
(list :op "<" (list :var "x") (list :int 0))
(list :neg (list :var "x"))
(list
:if
(list :var "otherwise")
(list :var "x")
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards")))))))
(hk-test
"three-way guarded rhs"
(hk-desugar
(hk-parse-top "sign n | n > 0 = 1\n | n < 0 = -1\n | otherwise = 0"))
(hk-prog
(list
:fun-clause
"sign"
(list (list :p-var "n"))
(list
:if
(list :op ">" (list :var "n") (list :int 0))
(list :int 1)
(list
:if
(list :op "<" (list :var "n") (list :int 0))
(list :neg (list :int 1))
(list
:if
(list :var "otherwise")
(list :int 0)
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards"))))))))
(hk-test
"case-alt guards desugared too"
(hk-desugar
(hk-parse "case x of\n Just y | y > 0 -> y\n | otherwise -> 0\n Nothing -> -1"))
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list
:if
(list :op ">" (list :var "y") (list :int 0))
(list :var "y")
(list
:if
(list :var "otherwise")
(list :int 0)
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards")))))
(list
:alt
(list :p-con "Nothing" (list))
(list :neg (list :int 1))))))
;; ── Where → let ──
(hk-test
"where with single binding"
(hk-desugar (hk-parse-top "f x = y\n where y = x + 1"))
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:let
(list
(list
:fun-clause
"y"
(list)
(list :op "+" (list :var "x") (list :int 1))))
(list :var "y")))))
(hk-test
"where with two bindings"
(hk-desugar
(hk-parse-top "f x = y + z\n where y = x + 1\n z = x - 1"))
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:let
(list
(list
:fun-clause
"y"
(list)
(list :op "+" (list :var "x") (list :int 1)))
(list
:fun-clause
"z"
(list)
(list :op "-" (list :var "x") (list :int 1))))
(list :op "+" (list :var "y") (list :var "z"))))))
(hk-test
"guards + where — guarded body inside let"
(hk-desugar
(hk-parse-top "f x | x > 0 = y\n | otherwise = 0\n where y = 99"))
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:let
(list (list :fun-clause "y" (list) (list :int 99)))
(list
:if
(list :op ">" (list :var "x") (list :int 0))
(list :var "y")
(list
:if
(list :var "otherwise")
(list :int 0)
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards"))))))))
;; ── List comprehensions → concatMap / if / let ──
(hk-test
"list-comp: single generator"
(hk-core-expr "[x | x <- xs]")
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (list :p-var "x"))
(list :list (list (list :var "x")))))
(list :var "xs")))
(hk-test
"list-comp: generator then guard"
(hk-core-expr "[x * 2 | x <- xs, x > 0]")
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (list :p-var "x"))
(list
:if
(list :op ">" (list :var "x") (list :int 0))
(list
:list
(list (list :op "*" (list :var "x") (list :int 2))))
(list :list (list)))))
(list :var "xs")))
(hk-test
"list-comp: generator then let"
(hk-core-expr "[y | x <- xs, let y = x + 1]")
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (list :p-var "x"))
(list
:let
(list
(list
:bind
(list :p-var "y")
(list :op "+" (list :var "x") (list :int 1))))
(list :list (list (list :var "y"))))))
(list :var "xs")))
(hk-test
"list-comp: two generators (nested concatMap)"
(hk-core-expr "[(x, y) | x <- xs, y <- ys]")
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (list :p-var "x"))
(list
:app
(list
:app
(list :var "concatMap")
(list
:lambda
(list (list :p-var "y"))
(list
:list
(list
(list
:tuple
(list (list :var "x") (list :var "y")))))))
(list :var "ys"))))
(list :var "xs")))
;; ── Pass-through cases ──
(hk-test
"plain int literal unchanged"
(hk-core-expr "42")
(list :int 42))
(hk-test
"lambda + if passes through"
(hk-core-expr "\\x -> if x > 0 then x else - x")
(list
:lambda
(list (list :p-var "x"))
(list
:if
(list :op ">" (list :var "x") (list :int 0))
(list :var "x")
(list :neg (list :var "x")))))
(hk-test
"simple fun-clause (no guards/where) passes through"
(hk-desugar (hk-parse-top "id x = x"))
(hk-prog
(list
:fun-clause
"id"
(list (list :p-var "x"))
(list :var "x"))))
(hk-test
"data decl passes through"
(hk-desugar (hk-parse-top "data Maybe a = Nothing | Just a"))
(hk-prog
(list
:data
"Maybe"
(list "a")
(list
(list :con-def "Nothing" (list))
(list :con-def "Just" (list (list :t-var "a")))))))
(hk-test
"module header passes through, body desugared"
(hk-desugar
(hk-parse-top "module M where\nf x | x > 0 = 1\n | otherwise = 0"))
(list
:module
"M"
nil
(list)
(list
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:if
(list :op ">" (list :var "x") (list :int 0))
(list :int 1)
(list
:if
(list :var "otherwise")
(list :int 0)
(list
:app
(list :var "error")
(list :string "Non-exhaustive guards"))))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; do-notation + stub IO monad. Desugaring is per Haskell 98 §3.14:
;; do { e ; ss } = e >> do { ss }
;; do { p <- e ; ss } = e >>= \p -> do { ss }
;; do { let ds ; ss } = let ds in do { ss }
;; do { e } = e
;; The IO type is just `("IO" payload)` for now — no real side
;; effects yet. `return`, `>>=`, `>>` are built-ins.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
;; ── Single-statement do ──
(hk-test
"do with a single expression"
(hk-eval-expr-source "do { return 5 }")
(list "IO" 5))
(hk-test
"return wraps any expression"
(hk-eval-expr-source "return (1 + 2 * 3)")
(list "IO" 7))
;; ── Bind threads results ──
(hk-test
"single bind"
(hk-eval-expr-source
"do { x <- return 5 ; return (x + 1) }")
(list "IO" 6))
(hk-test
"two binds"
(hk-eval-expr-source
"do\n x <- return 5\n y <- return 7\n return (x + y)")
(list "IO" 12))
(hk-test
"three binds — accumulating"
(hk-eval-expr-source
"do\n a <- return 1\n b <- return 2\n c <- return 3\n return (a + b + c)")
(list "IO" 6))
;; ── Mixing >> and >>= ──
(hk-test
">> sequencing — last wins"
(hk-eval-expr-source
"do\n return 1\n return 2\n return 3")
(list "IO" 3))
(hk-test
">> then >>= — last bind wins"
(hk-eval-expr-source
"do\n return 99\n x <- return 5\n return x")
(list "IO" 5))
;; ── do-let ──
(hk-test
"do-let single binding"
(hk-eval-expr-source
"do\n let x = 3\n return (x * 2)")
(list "IO" 6))
(hk-test
"do-let multi-bind, used after"
(hk-eval-expr-source
"do\n let x = 4\n y = 5\n return (x * y)")
(list "IO" 20))
(hk-test
"do-let interleaved with bind"
(hk-eval-expr-source
"do\n x <- return 10\n let y = x + 1\n return (x * y)")
(list "IO" 110))
;; ── Bind + pattern ──
(hk-test
"bind to constructor pattern"
(hk-eval-expr-source
"do\n Just x <- return (Just 7)\n return (x + 100)")
(list "IO" 107))
(hk-test
"bind to tuple pattern"
(hk-eval-expr-source
"do\n (a, b) <- return (3, 4)\n return (a * b)")
(list "IO" 12))
;; ── User-defined IO functions ──
(hk-test
"do inside top-level fun"
(hk-prog-val
"addM x y = do\n a <- return x\n b <- return y\n return (a + b)\nresult = addM 5 6"
"result")
(list "IO" 11))
(hk-test
"nested do"
(hk-eval-expr-source
"do\n x <- do { y <- return 3 ; return (y + 1) }\n return (x * 2)")
(list "IO" 8))
;; ── (>>=) and (>>) used directly as functions ──
(hk-test
">>= used directly"
(hk-eval-expr-source
"(return 4) >>= (\\x -> return (x + 100))")
(list "IO" 104))
(hk-test
">> used directly"
(hk-eval-expr-source
"(return 1) >> (return 2)")
(list "IO" 2))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Strict evaluator tests. Each test parses, desugars, and evaluates
;; either an expression (hk-eval-expr-source) or a full program
;; (hk-eval-program → look up a named value).
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
;; ── Literals ──
(hk-test "int literal" (hk-eval-expr-source "42") 42)
(hk-test "float literal" (hk-eval-expr-source "3.14") 3.14)
(hk-test "string literal" (hk-eval-expr-source "\"hi\"") "hi")
(hk-test "char literal" (hk-eval-expr-source "'a'") "a")
(hk-test "negative literal" (hk-eval-expr-source "- 5") -5)
;; ── Arithmetic ──
(hk-test "addition" (hk-eval-expr-source "1 + 2") 3)
(hk-test
"precedence"
(hk-eval-expr-source "1 + 2 * 3")
7)
(hk-test
"parens override precedence"
(hk-eval-expr-source "(1 + 2) * 3")
9)
(hk-test
"subtraction left-assoc"
(hk-eval-expr-source "10 - 3 - 2")
5)
;; ── Comparison + Bool ──
(hk-test
"less than is True"
(hk-eval-expr-source "3 < 5")
(list "True"))
(hk-test
"equality is False"
(hk-eval-expr-source "1 == 2")
(list "False"))
(hk-test
"&& shortcuts"
(hk-eval-expr-source "(1 == 1) && (2 == 2)")
(list "True"))
;; ── if / otherwise ──
(hk-test
"if True"
(hk-eval-expr-source "if True then 1 else 2")
1)
(hk-test
"if comparison branch"
(hk-eval-expr-source "if 5 > 3 then \"yes\" else \"no\"")
"yes")
(hk-test "otherwise is True" (hk-eval-expr-source "otherwise") (list "True"))
;; ── let ──
(hk-test
"let single binding"
(hk-eval-expr-source "let x = 5 in x + 1")
6)
(hk-test
"let two bindings"
(hk-eval-expr-source "let x = 1; y = 2 in x + y")
3)
(hk-test
"let recursive: factorial 5"
(hk-eval-expr-source
"let f n = if n == 0 then 1 else n * f (n - 1) in f 5")
120)
;; ── Lambdas ──
(hk-test
"lambda apply"
(hk-eval-expr-source "(\\x -> x + 1) 5")
6)
(hk-test
"lambda multi-arg"
(hk-eval-expr-source "(\\x y -> x * y) 3 4")
12)
(hk-test
"lambda with constructor pattern"
(hk-eval-expr-source "(\\(Just x) -> x + 1) (Just 7)")
8)
;; ── Constructors ──
(hk-test
"0-arity constructor"
(hk-eval-expr-source "Nothing")
(list "Nothing"))
(hk-test
"1-arity constructor applied"
(hk-eval-expr-source "Just 5")
(list "Just" 5))
(hk-test
"True / False as bools"
(hk-eval-expr-source "True")
(list "True"))
;; ── case ──
(hk-test
"case Just"
(hk-eval-expr-source
"case Just 7 of Just x -> x ; Nothing -> 0")
7)
(hk-test
"case Nothing"
(hk-eval-expr-source
"case Nothing of Just x -> x ; Nothing -> 99")
99)
(hk-test
"case literal pattern"
(hk-eval-expr-source
"case 0 of 0 -> \"zero\" ; n -> \"other\"")
"zero")
(hk-test
"case tuple"
(hk-eval-expr-source
"case (1, 2) of (a, b) -> a + b")
3)
(hk-test
"case wildcard fallback"
(hk-eval-expr-source
"case 5 of 0 -> \"z\" ; _ -> \"nz\"")
"nz")
;; ── List literals + cons ──
(hk-test
"list literal as cons spine"
(hk-eval-expr-source "[1, 2, 3]")
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
(hk-test
"empty list literal"
(hk-eval-expr-source "[]")
(list "[]"))
(hk-test
"cons via :"
(hk-eval-expr-source "1 : []")
(list ":" 1 (list "[]")))
(hk-test
"++ concatenates lists"
(hk-eval-expr-source "[1, 2] ++ [3]")
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
;; ── Tuples ──
(hk-test
"2-tuple"
(hk-eval-expr-source "(1, 2)")
(list "Tuple" 1 2))
(hk-test
"3-tuple"
(hk-eval-expr-source "(\"a\", 5, True)")
(list "Tuple" "a" 5 (list "True")))
;; ── Sections ──
(hk-test
"right section (+ 1) applied"
(hk-eval-expr-source "(+ 1) 5")
6)
(hk-test
"left section (10 -) applied"
(hk-eval-expr-source "(10 -) 4")
6)
;; ── Multi-clause top-level functions ──
(hk-test
"multi-clause: factorial"
(hk-prog-val
"fact 0 = 1\nfact n = n * fact (n - 1)\nresult = fact 6"
"result")
720)
(hk-test
"multi-clause: list length via cons pattern"
(hk-prog-val
"len [] = 0\nlen (x:xs) = 1 + len xs\nresult = len [10, 20, 30, 40]"
"result")
4)
(hk-test
"multi-clause: Maybe handler"
(hk-prog-val
"fromMaybe d Nothing = d\nfromMaybe _ (Just x) = x\nresult = fromMaybe 0 (Just 9)"
"result")
9)
(hk-test
"multi-clause: Maybe with default"
(hk-prog-val
"fromMaybe d Nothing = d\nfromMaybe _ (Just x) = x\nresult = fromMaybe 0 Nothing"
"result")
0)
;; ── User-defined data and matching ──
(hk-test
"custom data with pattern match"
(hk-prog-val
"data Color = Red | Green | Blue\nname Red = \"red\"\nname Green = \"green\"\nname Blue = \"blue\"\nresult = name Green"
"result")
"green")
(hk-test
"custom binary tree height"
(hk-prog-val
"data Tree = Leaf | Node Tree Tree\nh Leaf = 0\nh (Node l r) = 1 + max (h l) (h r)\nmax a b = if a > b then a else b\nresult = h (Node (Node Leaf Leaf) Leaf)"
"result")
2)
;; ── Currying ──
(hk-test
"partial application"
(hk-prog-val
"add x y = x + y\nadd5 = add 5\nresult = add5 7"
"result")
12)
;; ── Higher-order ──
(hk-test
"higher-order: function as arg"
(hk-prog-val
"twice f x = f (f x)\ninc x = x + 1\nresult = twice inc 10"
"result")
12)
;; ── Error built-in ──
(hk-test
"error short-circuits via if"
(hk-eval-expr-source
"if True then 1 else error \"unreachable\"")
1)
;; ── Laziness: app args evaluate only when forced ──
(hk-test
"second arg never forced"
(hk-eval-expr-source
"(\\x y -> x) 1 (error \"never\")")
1)
(hk-test
"first arg never forced"
(hk-eval-expr-source
"(\\x y -> y) (error \"never\") 99")
99)
(hk-test
"constructor argument is lazy under wildcard pattern"
(hk-eval-expr-source
"case Just (error \"deeply\") of Just _ -> 7 ; Nothing -> 0")
7)
(hk-test
"lazy: const drops its second argument"
(hk-prog-val
"const x y = x\nresult = const 5 (error \"boom\")"
"result")
5)
(hk-test
"lazy: head ignores tail"
(hk-prog-val
"myHead (x:_) = x\nresult = myHead (1 : (error \"tail\") : [])"
"result")
1)
(hk-test
"lazy: Just on undefined evaluates only on force"
(hk-prog-val
"wrapped = Just (error \"oh no\")\nresult = case wrapped of Just _ -> True ; Nothing -> False"
"result")
(list "True"))
;; ── not / id built-ins ──
(hk-test "not True" (hk-eval-expr-source "not True") (list "False"))
(hk-test "not False" (hk-eval-expr-source "not False") (list "True"))
(hk-test "id" (hk-eval-expr-source "id 42") 42)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; infer.sx tests — Algorithm W: literals, vars, lambdas, application, let,
;; if, operators, tuples, lists, let-polymorphism.
(define hk-t (fn (src expected)
(hk-test (str "infer: " src) (hk-infer-type src) expected)))
;; ─── Literals ────────────────────────────────────────────────────────────────
(hk-t "1" "Int")
(hk-t "3.14" "Float")
(hk-t "\"hello\"" "String")
(hk-t "'x'" "Char")
(hk-t "True" "Bool")
(hk-t "False" "Bool")
;; ─── Arithmetic and boolean operators ────────────────────────────────────────
(hk-t "1 + 2" "Int")
(hk-t "3 * 4" "Int")
(hk-t "10 - 3" "Int")
(hk-t "True && False" "Bool")
(hk-t "True || False" "Bool")
(hk-t "not True" "Bool")
(hk-t "1 == 1" "Bool")
(hk-t "1 < 2" "Bool")
;; ─── Lambda ───────────────────────────────────────────────────────────────────
;; \x -> x (identity) should get t1 -> t1
(hk-test "infer: identity lambda" (hk-infer-type "\\x -> x") "t1 -> t1")
;; \x -> x + 1 : Int -> Int
(hk-test "infer: lambda add" (hk-infer-type "\\x -> x + 1") "Int -> Int")
;; \x -> not x : Bool -> Bool
(hk-test "infer: lambda not" (hk-infer-type "\\x -> not x") "Bool -> Bool")
;; \x y -> x + y : Int -> Int -> Int
(hk-test "infer: two-arg lambda" (hk-infer-type "\\x -> \\y -> x + y") "Int -> Int -> Int")
;; ─── Application ─────────────────────────────────────────────────────────────
(hk-t "not True" "Bool")
(hk-t "negate 1" "Int")
;; ─── If-then-else ─────────────────────────────────────────────────────────────
(hk-t "if True then 1 else 2" "Int")
(hk-t "if 1 == 2 then True else False" "Bool")
;; ─── Let bindings ─────────────────────────────────────────────────────────────
;; let x = 1 in x + 2
(hk-t "let x = 1 in x + 2" "Int")
;; let f x = x + 1 in f 5
(hk-t "let f x = x + 1 in f 5" "Int")
;; let-polymorphism: let id x = x in id 1
(hk-t "let id x = x in id 1" "Int")
;; ─── Tuples ───────────────────────────────────────────────────────────────────
(hk-t "(1, True)" "(Int, Bool)")
(hk-t "(1, 2, 3)" "(Int, Int, Int)")
;; ─── Lists ───────────────────────────────────────────────────────────────────
(hk-t "[1, 2, 3]" "[Int]")
(hk-t "[True, False]" "[Bool]")
;; ─── Polymorphic list functions ───────────────────────────────────────────────
(hk-t "length [1, 2, 3]" "Int")
(hk-t "null []" "Bool")
(hk-t "head [1, 2, 3]" "Int")
;; ─── hk-expr->brief ──────────────────────────────────────────────────────────
(hk-test "brief var" (hk-expr->brief (list "var" "x")) "x")
(hk-test "brief con" (hk-expr->brief (list "con" "Just")) "Just")
(hk-test "brief int" (hk-expr->brief (list "int" 42)) "42")
(hk-test "brief app" (hk-expr->brief (list "app" (list "var" "f") (list "var" "x"))) "(f x)")
(hk-test "brief op" (hk-expr->brief (list "op" "+" (list "int" 1) (list "int" 2))) "(1 + 2)")
(hk-test "brief lambda" (hk-expr->brief (list "lambda" (list) (list "var" "x"))) "(\\ ...)")
(hk-test "brief loc" (hk-expr->brief (list "loc" 3 7 (list "var" "x"))) "x")
;; ─── Type error messages ─────────────────────────────────────────────────────
;; Helper: catch the error and check it contains a substring.
(define hk-str-has? (fn (s sub) (>= (index-of s sub) 0)))
(define hk-te
(fn (label src sub)
(hk-test label
(guard (e (#t (hk-str-has? e sub)))
(begin (hk-infer-type src) false))
true)))
;; Unbound variable error includes the variable name.
(hk-te "error unbound name" "foo + 1" "foo")
(hk-te "error unbound unk" "unknown" "unknown")
;; Unification error mentions the conflicting types.
(hk-te "error unify int-bool-1" "1 + True" "Int")
(hk-te "error unify int-bool-2" "1 + True" "Bool")
;; ─── Loc node: passes through to inner (position decorates outer context) ────
(define hk-loc-err-msg
(fn ()
(guard (e (#t e))
(begin
(hk-reset-fresh)
(hk-w (hk-type-env0) (list "loc" 5 10 (list "var" "mystery")))
"no-error"))))
(hk-test "loc passes through to var error"
(hk-str-has? (hk-loc-err-msg) "mystery")
true)
;; ─── hk-infer-decl ───────────────────────────────────────────────────────────
;; Returns ("ok" name type) | ("err" msg)
(define hk-env0-t (hk-type-env0))
(define prog1 (hk-core "f x = x + 1"))
(define decl1 (first (nth prog1 1)))
(define res1 (hk-infer-decl hk-env0-t decl1))
(hk-test "decl result tag" (first res1) "ok")
(hk-test "decl result name" (nth res1 1) "f")
(hk-test "decl result type" (nth res1 2) "Int -> Int")
;; Error decl: result is ("err" "in 'g': ...")
(define prog2 (hk-core "g x = x + True"))
(define decl2 (first (nth prog2 1)))
(define res2 (hk-infer-decl hk-env0-t decl2))
(hk-test "decl error tag" (first res2) "err")
(hk-test "decl error has g" (hk-str-has? (nth res2 1) "g") true)
(hk-test "decl error has msg" (hk-str-has? (nth res2 1) "unify") true)
;; ─── hk-infer-prog ───────────────────────────────────────────────────────────
;; Returns list of ("ok"/"err" ...) tagged results.
(define prog3 (hk-core "double x = x + x\ntwice f x = f (f x)"))
(define results3 (hk-infer-prog prog3 hk-env0-t))
;; results3 = (("ok" "double" "Int -> Int") ("ok" "twice" "..."))
(hk-test "infer-prog count" (len results3) 2)
(hk-test "infer-prog double" (nth (nth results3 0) 2) "Int -> Int")
(hk-test "infer-prog twice" (nth (nth results3 1) 2) "(t3 -> t3) -> t3 -> t3")
(hk-t "let id x = x in id 1" "Int")
(hk-t "let id x = x in id True" "Bool")
(hk-t "let id x = x in (id 1, id True)" "(Int, Bool)")
(hk-t "let const x y = x in (const 1 True, const True 1)" "(Int, Bool)")
(hk-t "let f x = x in let g y = f y in (g 1, g True)" "(Int, Bool)")
(hk-t "let twice f x = f (f x) in twice (\x -> x + 1) 5" "Int")
(hk-t "not (not True)" "Bool")
(hk-t "negate (negate 1)" "Int")
(hk-t "\\x -> \\y -> x && y" "Bool -> Bool -> Bool")
(hk-t "\\x -> x == 1" "Int -> Bool")
(hk-t "let x = True in if x then 1 else 0" "Int")
(hk-t "let f x = not x in f True" "Bool")
(hk-t "let f x = (x, x + 1) in f 5" "(Int, Int)")
(hk-t "let x = 1 in let y = 2 in x + y" "Int")
(hk-t "let f x = x + 1 in f (f 5)" "Int")
(hk-t "if 1 < 2 then True else False" "Bool")
(hk-t "if True then 1 + 1 else 2 + 2" "Int")
(hk-t "(1 + 2, True && False)" "(Int, Bool)")
(hk-t "(1 == 1, 2 < 3)" "(Bool, Bool)")
(hk-t "length [True, False]" "Int")
(hk-t "null [1]" "Bool")
(hk-t "[True]" "[Bool]")
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Infinite structures + Prelude tests. The lazy `:` operator builds
;; cons cells with thunked head/tail so recursive list-defining
;; functions terminate when only a finite prefix is consumed.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define hk-as-list
(fn (xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-eval-list
(fn (src) (hk-as-list (hk-eval-expr-source src))))
;; ── Prelude basics ──
(hk-test "head of literal" (hk-eval-expr-source "head [1, 2, 3]") 1)
(hk-test
"tail of literal"
(hk-eval-list "tail [1, 2, 3]")
(list 2 3))
(hk-test "length" (hk-eval-expr-source "length [10, 20, 30, 40]") 4)
(hk-test "length empty" (hk-eval-expr-source "length []") 0)
(hk-test
"map with section"
(hk-eval-list "map (+ 1) [1, 2, 3]")
(list 2 3 4))
(hk-test
"filter"
(hk-eval-list "filter (\\x -> x > 2) [1, 2, 3, 4, 5]")
(list 3 4 5))
(hk-test
"drop"
(hk-eval-list "drop 2 [10, 20, 30, 40]")
(list 30 40))
(hk-test "fst" (hk-eval-expr-source "fst (7, 9)") 7)
(hk-test "snd" (hk-eval-expr-source "snd (7, 9)") 9)
(hk-test
"zipWith"
(hk-eval-list "zipWith plus [1, 2, 3] [10, 20, 30]")
(list 11 22 33))
;; ── Infinite structures ──
(hk-test
"take from repeat"
(hk-eval-list "take 5 (repeat 7)")
(list 7 7 7 7 7))
(hk-test
"take 0 from repeat returns empty"
(hk-eval-list "take 0 (repeat 7)")
(list))
(hk-test
"take from iterate"
(hk-eval-list "take 5 (iterate (\\x -> x + 1) 0)")
(list 0 1 2 3 4))
(hk-test
"iterate with multiplication"
(hk-eval-list "take 4 (iterate (\\x -> x * 2) 1)")
(list 1 2 4 8))
(hk-test
"head of repeat"
(hk-eval-expr-source "head (repeat 99)")
99)
;; ── Fibonacci stream ──
(hk-test
"first 10 Fibonacci numbers"
(hk-eval-list "take 10 fibs")
(list 0 1 1 2 3 5 8 13 21 34))
(hk-test
"fib at position 8"
(hk-eval-expr-source "head (drop 8 fibs)")
21)
;; ── Building infinite structures in user code ──
(hk-test
"user-defined infinite ones"
(hk-prog-val
"ones = 1 : ones\nresult = take 6 ones"
"result")
(list ":" 1 (list ":" 1 (list ":" 1 (list ":" 1 (list ":" 1 (list ":" 1 (list "[]"))))))))
(hk-test
"user-defined nats"
(hk-prog-val
"nats = naturalsFrom 1\nnaturalsFrom n = n : naturalsFrom (n + 1)\nresult = take 5 nats"
"result")
(list ":" 1 (list ":" 2 (list ":" 3 (list ":" 4 (list ":" 5 (list "[]")))))))
;; ── Range syntax ──
(hk-test
"finite range [1..5]"
(hk-eval-list "[1..5]")
(list 1 2 3 4 5))
(hk-test
"empty range when from > to"
(hk-eval-list "[10..3]")
(list))
(hk-test
"stepped range"
(hk-eval-list "[1, 3..10]")
(list 1 3 5 7 9))
(hk-test
"open range — head"
(hk-eval-expr-source "head [1..]")
1)
(hk-test
"open range — drop then head"
(hk-eval-expr-source "head (drop 99 [1..])")
100)
(hk-test
"open range — take 5"
(hk-eval-list "take 5 [10..]")
(list 10 11 12 13 14))
;; ── Composing Prelude functions ──
(hk-test
"map then filter"
(hk-eval-list
"filter (\\x -> x > 5) (map (\\x -> x * 2) [1, 2, 3, 4])")
(list 6 8))
(hk-test
"sum-via-foldless"
(hk-prog-val
"mySum [] = 0\nmySum (x:xs) = x + mySum xs\nresult = mySum (take 5 (iterate (\\x -> x + 1) 1))"
"result")
15)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; io-input.sx — tests for getLine, getContents, readFile, writeFile.
(hk-test
"getLine reads single line"
(hk-run-io-with-input "main = getLine >>= putStrLn" (list "hello"))
(list "hello"))
(hk-test
"getLine reads two lines"
(hk-run-io-with-input
"main = do { line1 <- getLine; line2 <- getLine; putStrLn line1; putStrLn line2 }"
(list "first" "second"))
(list "first" "second"))
(hk-test
"getLine bind in layout do"
(hk-run-io-with-input
"main = do\n line <- getLine\n putStrLn line"
(list "world"))
(list "world"))
(hk-test
"getLine echo with prefix"
(hk-run-io-with-input
"main = do\n line <- getLine\n putStrLn (\"Got: \" ++ line)"
(list "test"))
(list "Got: test"))
(hk-test
"getContents reads all lines joined"
(hk-run-io-with-input
"main = getContents >>= putStr"
(list "line1" "line2" "line3"))
(list "line1\nline2\nline3"))
(hk-test
"getContents empty stdin"
(hk-run-io-with-input "main = getContents >>= putStr" (list))
(list ""))
(hk-test
"readFile reads pre-loaded content"
(begin
(set! hk-vfs (dict))
(dict-set! hk-vfs "hello.txt" "Hello, World!")
(hk-run-io "main = readFile \"hello.txt\" >>= putStrLn"))
(list "Hello, World!"))
(hk-test
"writeFile creates file"
(begin
(set! hk-vfs (dict))
(hk-run-io "main = writeFile \"out.txt\" \"written content\"")
(get hk-vfs "out.txt"))
"written content")
(hk-test
"writeFile then readFile roundtrip"
(begin
(set! hk-vfs (dict))
(hk-run-io
"main = do { writeFile \"f.txt\" \"round trip\"; readFile \"f.txt\" >>= putStrLn }"))
(list "round trip"))
(hk-test
"readFile error on missing file"
(guard
(e (true (>= (index-of e "file not found") 0)))
(begin
(set! hk-vfs (dict))
(hk-run-io "main = readFile \"no.txt\" >>= putStrLn")
false))
true)
(hk-test
"getLine then writeFile combined"
(begin
(set! hk-vfs (dict))
(hk-run-io-with-input
"main = do\n line <- getLine\n writeFile \"cap.txt\" line"
(list "captured"))
(get hk-vfs "cap.txt"))
"captured")
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Haskell layout-rule tests. hk-tokenizer + hk-layout produce a
;; virtual-brace-annotated stream; these tests cover the algorithm
;; from Haskell 98 §10.3 plus the pragmatic let/in single-line rule.
;; Convenience — tokenize, run layout, strip eof, keep :type/:value.
(define
hk-lay
(fn
(src)
(map
(fn (tok) {:value (get tok "value") :type (get tok "type")})
(filter
(fn (tok) (not (= (get tok "type") "eof")))
(hk-layout (hk-tokenize src))))))
;; ── 1. Basics ──
(hk-test
"empty input produces empty module { }"
(hk-lay "")
(list
{:value "{" :type "vlbrace"}
{:value "}" :type "vrbrace"}))
(hk-test
"single token → module open+close"
(hk-lay "foo")
(list
{:value "{" :type "vlbrace"}
{:value "foo" :type "varid"}
{:value "}" :type "vrbrace"}))
(hk-test
"two top-level decls get vsemi between"
(hk-lay "foo = 1\nbar = 2")
(list
{:value "{" :type "vlbrace"}
{:value "foo" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value ";" :type "vsemi"}
{:value "bar" :type "varid"}
{:value "=" :type "reservedop"}
{:value 2 :type "integer"}
{:value "}" :type "vrbrace"}))
;; ── 2. Layout keywords — do / let / where / of ──
(hk-test
"do block with two stmts"
(hk-lay "f = do\n x\n y")
(list
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "=" :type "reservedop"}
{:value "do" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value ";" :type "vsemi"}
{:value "y" :type "varid"}
{:value "}" :type "vrbrace"}
{:value "}" :type "vrbrace"}))
(hk-test
"single-line let ... in"
(hk-lay "let x = 1 in x")
(list
{:value "{" :type "vlbrace"}
{:value "let" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value "}" :type "vrbrace"}
{:value "in" :type "reserved"}
{:value "x" :type "varid"}
{:value "}" :type "vrbrace"}))
(hk-test
"where block with two bindings"
(hk-lay "f = g\n where\n g = 1\n h = 2")
(list
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "=" :type "reservedop"}
{:value "g" :type "varid"}
{:value "where" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "g" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value ";" :type "vsemi"}
{:value "h" :type "varid"}
{:value "=" :type "reservedop"}
{:value 2 :type "integer"}
{:value "}" :type "vrbrace"}
{:value "}" :type "vrbrace"}))
(hk-test
"case … of with arms"
(hk-lay "f x = case x of\n Just y -> y\n Nothing -> 0")
(list
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "x" :type "varid"}
{:value "=" :type "reservedop"}
{:value "case" :type "reserved"}
{:value "x" :type "varid"}
{:value "of" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "Just" :type "conid"}
{:value "y" :type "varid"}
{:value "->" :type "reservedop"}
{:value "y" :type "varid"}
{:value ";" :type "vsemi"}
{:value "Nothing" :type "conid"}
{:value "->" :type "reservedop"}
{:value 0 :type "integer"}
{:value "}" :type "vrbrace"}
{:value "}" :type "vrbrace"}))
;; ── 3. Explicit braces disable layout ──
(hk-test
"explicit braces — no implicit vlbrace/vsemi/vrbrace inside"
(hk-lay "do { x ; y }")
(list
{:value "{" :type "vlbrace"}
{:value "do" :type "reserved"}
{:value "{" :type "lbrace"}
{:value "x" :type "varid"}
{:value ";" :type "semi"}
{:value "y" :type "varid"}
{:value "}" :type "rbrace"}
{:value "}" :type "vrbrace"}))
;; ── 4. Dedent closes nested blocks ──
(hk-test
"dedent back to module level closes do block"
(hk-lay "f = do\n x\n y\ng = 2")
(list
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "=" :type "reservedop"}
{:value "do" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value ";" :type "vsemi"}
{:value "y" :type "varid"}
{:value "}" :type "vrbrace"}
{:value ";" :type "vsemi"}
{:value "g" :type "varid"}
{:value "=" :type "reservedop"}
{:value 2 :type "integer"}
{:value "}" :type "vrbrace"}))
(hk-test
"dedent closes inner let, emits vsemi at outer do level"
(hk-lay "main = do\n let x = 1\n print x")
(list
{:value "{" :type "vlbrace"}
{:value "main" :type "varid"}
{:value "=" :type "reservedop"}
{:value "do" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "let" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value "}" :type "vrbrace"}
{:value ";" :type "vsemi"}
{:value "print" :type "varid"}
{:value "x" :type "varid"}
{:value "}" :type "vrbrace"}
{:value "}" :type "vrbrace"}))
;; ── 5. Module header skips outer implicit open ──
(hk-test
"module M where — only where opens a block"
(hk-lay "module M where\n f = 1")
(list
{:value "module" :type "reserved"}
{:value "M" :type "conid"}
{:value "where" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value "}" :type "vrbrace"}))
;; ── 6. Newlines are stripped ──
(hk-test
"newline tokens do not appear in output"
(let
((toks (hk-layout (hk-tokenize "foo\nbar"))))
(every?
(fn (t) (not (= (get t "type") "newline")))
toks))
true)
;; ── 7. Continuation — deeper indent does NOT emit vsemi ──
(hk-test
"line continuation (deeper indent) just merges"
(hk-lay "foo = 1 +\n 2")
(list
{:value "{" :type "vlbrace"}
{:value "foo" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value "+" :type "varsym"}
{:value 2 :type "integer"}
{:value "}" :type "vrbrace"}))
;; ── 8. Stack closing at EOF ──
(hk-test
"EOF inside nested do closes all implicit blocks"
(let
((toks (hk-lay "main = do\n do\n x")))
(let
((n (len toks)))
(list
(get (nth toks (- n 1)) "type")
(get (nth toks (- n 2)) "type")
(get (nth toks (- n 3)) "type"))))
(list "vrbrace" "vrbrace" "vrbrace"))
;; ── 9. Qualified-newline: x at deeper col than stack top does nothing ──
(hk-test
"mixed where + do"
(hk-lay "f = do\n x\n where\n x = 1")
(list
{:value "{" :type "vlbrace"}
{:value "f" :type "varid"}
{:value "=" :type "reservedop"}
{:value "do" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value "}" :type "vrbrace"}
{:value "where" :type "reserved"}
{:value "{" :type "vlbrace"}
{:value "x" :type "varid"}
{:value "=" :type "reservedop"}
{:value 1 :type "integer"}
{:value "}" :type "vrbrace"}
{:value "}" :type "vrbrace"}))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Pattern-matcher tests. The matcher takes (pat val env) and returns
;; an extended env dict on success, or `nil` on failure. Constructor
;; values are tagged lists (con-name first); tuples use the "Tuple"
;; tag; lists use chained `:` cons with `[]` nil.
;; ── Atomic patterns ──
(hk-test
"wildcard always matches"
(hk-match (list :p-wild) 42 (dict))
(dict))
(hk-test
"var binds value"
(hk-match (list :p-var "x") 42 (dict))
{:x 42})
(hk-test
"var preserves prior env"
(hk-match (list :p-var "y") 7 {:x 1})
{:x 1 :y 7})
(hk-test
"int literal matches equal"
(hk-match (list :p-int 5) 5 (dict))
(dict))
(hk-test
"int literal fails on mismatch"
(hk-match (list :p-int 5) 6 (dict))
nil)
(hk-test
"negative int literal matches"
(hk-match (list :p-int -3) -3 (dict))
(dict))
(hk-test
"string literal matches"
(hk-match (list :p-string "hi") "hi" (dict))
(dict))
(hk-test
"string literal fails"
(hk-match (list :p-string "hi") "bye" (dict))
nil)
(hk-test
"char literal matches"
(hk-match (list :p-char "a") "a" (dict))
(dict))
;; ── Constructor patterns ──
(hk-test
"0-arity con matches"
(hk-match
(list :p-con "Nothing" (list))
(hk-mk-con "Nothing" (list))
(dict))
(dict))
(hk-test
"1-arity con matches and binds"
(hk-match
(list :p-con "Just" (list (list :p-var "y")))
(hk-mk-con "Just" (list 9))
(dict))
{:y 9})
(hk-test
"con name mismatch fails"
(hk-match
(list :p-con "Just" (list (list :p-var "y")))
(hk-mk-con "Nothing" (list))
(dict))
nil)
(hk-test
"con arity mismatch fails"
(hk-match
(list :p-con "Pair" (list (list :p-var "a") (list :p-var "b")))
(hk-mk-con "Pair" (list 1))
(dict))
nil)
(hk-test
"nested con: Just (Just x)"
(hk-match
(list
:p-con
"Just"
(list
(list
:p-con
"Just"
(list (list :p-var "x")))))
(hk-mk-con "Just" (list (hk-mk-con "Just" (list 42))))
(dict))
{:x 42})
;; ── Tuple patterns ──
(hk-test
"2-tuple matches and binds"
(hk-match
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))
(hk-mk-tuple (list 10 20))
(dict))
{:a 10 :b 20})
(hk-test
"tuple arity mismatch fails"
(hk-match
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))
(hk-mk-tuple (list 10 20 30))
(dict))
nil)
;; ── List patterns ──
(hk-test
"[] pattern matches empty list"
(hk-match (list :p-list (list)) (hk-mk-nil) (dict))
(dict))
(hk-test
"[] pattern fails on non-empty"
(hk-match (list :p-list (list)) (hk-mk-list (list 1)) (dict))
nil)
(hk-test
"[a] pattern matches singleton"
(hk-match
(list :p-list (list (list :p-var "a")))
(hk-mk-list (list 7))
(dict))
{:a 7})
(hk-test
"[a, b] pattern matches pair-list and binds"
(hk-match
(list
:p-list
(list (list :p-var "a") (list :p-var "b")))
(hk-mk-list (list 1 2))
(dict))
{:a 1 :b 2})
(hk-test
"[a, b] fails on too-long list"
(hk-match
(list
:p-list
(list (list :p-var "a") (list :p-var "b")))
(hk-mk-list (list 1 2 3))
(dict))
nil)
;; Cons-style infix pattern (which the parser produces as :p-con ":")
(hk-test
"cons (h:t) on non-empty list"
(hk-match
(list
:p-con
":"
(list (list :p-var "h") (list :p-var "t")))
(hk-mk-list (list 1 2 3))
(dict))
{:h 1 :t (list ":" 2 (list ":" 3 (list "[]")))})
(hk-test
"cons fails on empty list"
(hk-match
(list
:p-con
":"
(list (list :p-var "h") (list :p-var "t")))
(hk-mk-nil)
(dict))
nil)
;; ── as patterns ──
(hk-test
"as binds whole + sub-pattern"
(hk-match
(list
:p-as
"all"
(list :p-con "Just" (list (list :p-var "x"))))
(hk-mk-con "Just" (list 99))
(dict))
{:all (list "Just" 99) :x 99})
(hk-test
"as on wildcard binds whole"
(hk-match
(list :p-as "v" (list :p-wild))
"anything"
(dict))
{:v "anything"})
(hk-test
"as fails when sub-pattern fails"
(hk-match
(list
:p-as
"n"
(list :p-con "Just" (list (list :p-var "x"))))
(hk-mk-con "Nothing" (list))
(dict))
nil)
;; ── lazy ~ pattern (eager equivalent for now) ──
(hk-test
"lazy pattern eager-matches its inner"
(hk-match
(list :p-lazy (list :p-var "y"))
42
(dict))
{:y 42})
;; ── Source-driven: parse a real Haskell pattern, match a value ──
(hk-test
"parsed pattern: Just x against Just 5"
(hk-match
(hk-parse-pat-source "Just x")
(hk-mk-con "Just" (list 5))
(dict))
{:x 5})
(hk-test
"parsed pattern: x : xs against [10, 20, 30]"
(hk-match
(hk-parse-pat-source "x : xs")
(hk-mk-list (list 10 20 30))
(dict))
{:x 10 :xs (list ":" 20 (list ":" 30 (list "[]")))})
(hk-test
"parsed pattern: (a, b) against (1, 2)"
(hk-match
(hk-parse-pat-source "(a, b)")
(hk-mk-tuple (list 1 2))
(dict))
{:a 1 :b 2})
(hk-test
"parsed pattern: n@(Just x) against Just 7"
(hk-match
(hk-parse-pat-source "n@(Just x)")
(hk-mk-con "Just" (list 7))
(dict))
{:n (list "Just" 7) :x 7})
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

56
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@@ -3,60 +3,8 @@
;; Lightweight runner: each test checks actual vs expected with
;; structural (deep) equality and accumulates pass/fail counters.
;; Final value of this file is a summary dict with :pass :fail :fails.
(define
hk-deep=?
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn
(k)
(and (has-key? b k) (hk-deep=? (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(define
hk-de-loop
(fn
()
(when
(and ok (< i (len a)))
(do
(when
(not (hk-deep=? (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(hk-de-loop)))))
(hk-de-loop)
ok)))
(:else false))))
(define hk-test-pass 0)
(define hk-test-fail 0)
(define hk-test-fails (list))
(define
hk-test
(fn
(name actual expected)
(if
(hk-deep=? actual expected)
(set! hk-test-pass (+ hk-test-pass 1))
(do
(set! hk-test-fail (+ hk-test-fail 1))
(append! hk-test-fails {:actual actual :expected expected :name name})))))
;; The hk-test / hk-deep=? helpers live in lib/haskell/testlib.sx
;; and are preloaded by lib/haskell/test.sh.
;; Convenience: tokenize and drop newline + eof tokens so tests focus
;; on meaningful content. Returns list of {:type :value} pairs.

278
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;; case-of and do-notation parser tests.
;; Covers the minimal patterns needed to make these meaningful: var,
;; wildcard, literal, constructor (with and without args), tuple, list.
;; ── Patterns (in case arms) ──
(hk-test
"wildcard pat"
(hk-parse "case x of _ -> 0")
(list
:case
(list :var "x")
(list (list :alt (list :p-wild) (list :int 0)))))
(hk-test
"var pat"
(hk-parse "case x of y -> y")
(list
:case
(list :var "x")
(list
(list :alt (list :p-var "y") (list :var "y")))))
(hk-test
"0-arity constructor pat"
(hk-parse "case x of\n Nothing -> 0\n Just y -> y")
(list
:case
(list :var "x")
(list
(list :alt (list :p-con "Nothing" (list)) (list :int 0))
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list :var "y")))))
(hk-test
"int literal pat"
(hk-parse "case n of\n 0 -> 1\n _ -> n")
(list
:case
(list :var "n")
(list
(list :alt (list :p-int 0) (list :int 1))
(list :alt (list :p-wild) (list :var "n")))))
(hk-test
"string literal pat"
(hk-parse "case s of\n \"hi\" -> 1\n _ -> 0")
(list
:case
(list :var "s")
(list
(list :alt (list :p-string "hi") (list :int 1))
(list :alt (list :p-wild) (list :int 0)))))
(hk-test
"tuple pat"
(hk-parse "case p of (a, b) -> a")
(list
:case
(list :var "p")
(list
(list
:alt
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))
(list :var "a")))))
(hk-test
"list pat"
(hk-parse "case xs of\n [] -> 0\n [a] -> a")
(list
:case
(list :var "xs")
(list
(list :alt (list :p-list (list)) (list :int 0))
(list
:alt
(list :p-list (list (list :p-var "a")))
(list :var "a")))))
(hk-test
"nested constructor pat"
(hk-parse "case x of\n Just (a, b) -> a\n _ -> 0")
(list
:case
(list :var "x")
(list
(list
:alt
(list
:p-con
"Just"
(list
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))))
(list :var "a"))
(list :alt (list :p-wild) (list :int 0)))))
(hk-test
"constructor with multiple var args"
(hk-parse "case t of Pair a b -> a")
(list
:case
(list :var "t")
(list
(list
:alt
(list
:p-con
"Pair"
(list (list :p-var "a") (list :p-var "b")))
(list :var "a")))))
;; ── case-of shapes ──
(hk-test
"case with explicit braces"
(hk-parse "case x of { Just y -> y ; Nothing -> 0 }")
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list :var "y"))
(list :alt (list :p-con "Nothing" (list)) (list :int 0)))))
(hk-test
"case scrutinee is a full expression"
(hk-parse "case f x + 1 of\n y -> y")
(list
:case
(list
:op
"+"
(list :app (list :var "f") (list :var "x"))
(list :int 1))
(list (list :alt (list :p-var "y") (list :var "y")))))
(hk-test
"case arm body is full expression"
(hk-parse "case x of\n Just y -> y + 1")
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list :op "+" (list :var "y") (list :int 1))))))
;; ── do blocks ──
(hk-test
"do with two expressions"
(hk-parse "do\n putStrLn \"hi\"\n return 0")
(list
:do
(list
(list
:do-expr
(list :app (list :var "putStrLn") (list :string "hi")))
(list
:do-expr
(list :app (list :var "return") (list :int 0))))))
(hk-test
"do with bind"
(hk-parse "do\n x <- getLine\n putStrLn x")
(list
:do
(list
(list :do-bind (list :p-var "x") (list :var "getLine"))
(list
:do-expr
(list :app (list :var "putStrLn") (list :var "x"))))))
(hk-test
"do with let"
(hk-parse "do\n let y = 5\n print y")
(list
:do
(list
(list
:do-let
(list (list :bind (list :p-var "y") (list :int 5))))
(list
:do-expr
(list :app (list :var "print") (list :var "y"))))))
(hk-test
"do with multiple let bindings"
(hk-parse "do\n let x = 1\n y = 2\n print (x + y)")
(list
:do
(list
(list
:do-let
(list
(list :bind (list :p-var "x") (list :int 1))
(list :bind (list :p-var "y") (list :int 2))))
(list
:do-expr
(list
:app
(list :var "print")
(list :op "+" (list :var "x") (list :var "y")))))))
(hk-test
"do with bind using constructor pat"
(hk-parse "do\n Just x <- getMaybe\n return x")
(list
:do
(list
(list
:do-bind
(list :p-con "Just" (list (list :p-var "x")))
(list :var "getMaybe"))
(list
:do-expr
(list :app (list :var "return") (list :var "x"))))))
(hk-test
"do with explicit braces"
(hk-parse "do { x <- a ; y <- b ; return (x + y) }")
(list
:do
(list
(list :do-bind (list :p-var "x") (list :var "a"))
(list :do-bind (list :p-var "y") (list :var "b"))
(list
:do-expr
(list
:app
(list :var "return")
(list :op "+" (list :var "x") (list :var "y")))))))
;; ── Mixing case/do inside expressions ──
(hk-test
"case inside let"
(hk-parse "let f = \\x -> case x of\n Just y -> y\n _ -> 0\nin f 5")
(list
:let
(list
(list
:bind
(list :p-var "f")
(list
:lambda
(list (list :p-var "x"))
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list :var "y"))
(list :alt (list :p-wild) (list :int 0)))))))
(list :app (list :var "f") (list :int 5))))
(hk-test
"lambda containing do"
(hk-parse "\\x -> do\n y <- x\n return y")
(list
:lambda
(list (list :p-var "x"))
(list
:do
(list
(list :do-bind (list :p-var "y") (list :var "x"))
(list
:do-expr
(list :app (list :var "return") (list :var "y")))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

273
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@@ -0,0 +1,273 @@
;; Top-level declarations: function clauses, type signatures, data,
;; type, newtype, fixity. Driven by hk-parse-top which produces
;; a (:program DECLS) node.
(define
hk-prog
(fn
(&rest decls)
(list :program decls)))
;; ── Function clauses & pattern bindings ──
(hk-test
"simple fun-clause"
(hk-parse-top "f x = x + 1")
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list :op "+" (list :var "x") (list :int 1)))))
(hk-test
"nullary decl"
(hk-parse-top "answer = 42")
(hk-prog
(list :fun-clause "answer" (list) (list :int 42))))
(hk-test
"multi-clause fn (separate defs for each pattern)"
(hk-parse-top "fact 0 = 1\nfact n = n")
(hk-prog
(list :fun-clause "fact" (list (list :p-int 0)) (list :int 1))
(list
:fun-clause
"fact"
(list (list :p-var "n"))
(list :var "n"))))
(hk-test
"constructor pattern in fn args"
(hk-parse-top "fromJust (Just x) = x")
(hk-prog
(list
:fun-clause
"fromJust"
(list (list :p-con "Just" (list (list :p-var "x"))))
(list :var "x"))))
(hk-test
"pattern binding at top level"
(hk-parse-top "(a, b) = pair")
(hk-prog
(list
:pat-bind
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))
(list :var "pair"))))
;; ── Type signatures ──
(hk-test
"single-name sig"
(hk-parse-top "f :: Int -> Int")
(hk-prog
(list
:type-sig
(list "f")
(list :t-fun (list :t-con "Int") (list :t-con "Int")))))
(hk-test
"multi-name sig"
(hk-parse-top "f, g, h :: Int -> Bool")
(hk-prog
(list
:type-sig
(list "f" "g" "h")
(list :t-fun (list :t-con "Int") (list :t-con "Bool")))))
(hk-test
"sig with type application"
(hk-parse-top "f :: Maybe a -> a")
(hk-prog
(list
:type-sig
(list "f")
(list
:t-fun
(list :t-app (list :t-con "Maybe") (list :t-var "a"))
(list :t-var "a")))))
(hk-test
"sig with list type"
(hk-parse-top "len :: [a] -> Int")
(hk-prog
(list
:type-sig
(list "len")
(list
:t-fun
(list :t-list (list :t-var "a"))
(list :t-con "Int")))))
(hk-test
"sig with tuple and right-assoc ->"
(hk-parse-top "pair :: a -> b -> (a, b)")
(hk-prog
(list
:type-sig
(list "pair")
(list
:t-fun
(list :t-var "a")
(list
:t-fun
(list :t-var "b")
(list
:t-tuple
(list (list :t-var "a") (list :t-var "b"))))))))
(hk-test
"sig + implementation together"
(hk-parse-top "id :: a -> a\nid x = x")
(hk-prog
(list
:type-sig
(list "id")
(list :t-fun (list :t-var "a") (list :t-var "a")))
(list
:fun-clause
"id"
(list (list :p-var "x"))
(list :var "x"))))
;; ── data declarations ──
(hk-test
"data Maybe"
(hk-parse-top "data Maybe a = Nothing | Just a")
(hk-prog
(list
:data
"Maybe"
(list "a")
(list
(list :con-def "Nothing" (list))
(list :con-def "Just" (list (list :t-var "a")))))))
(hk-test
"data Either"
(hk-parse-top "data Either a b = Left a | Right b")
(hk-prog
(list
:data
"Either"
(list "a" "b")
(list
(list :con-def "Left" (list (list :t-var "a")))
(list :con-def "Right" (list (list :t-var "b")))))))
(hk-test
"data with no type parameters"
(hk-parse-top "data Bool = True | False")
(hk-prog
(list
:data
"Bool"
(list)
(list
(list :con-def "True" (list))
(list :con-def "False" (list))))))
(hk-test
"recursive data type"
(hk-parse-top "data Tree a = Leaf | Node (Tree a) a (Tree a)")
(hk-prog
(list
:data
"Tree"
(list "a")
(list
(list :con-def "Leaf" (list))
(list
:con-def
"Node"
(list
(list :t-app (list :t-con "Tree") (list :t-var "a"))
(list :t-var "a")
(list :t-app (list :t-con "Tree") (list :t-var "a"))))))))
;; ── type synonyms ──
(hk-test
"simple type synonym"
(hk-parse-top "type Name = String")
(hk-prog
(list :type-syn "Name" (list) (list :t-con "String"))))
(hk-test
"parameterised type synonym"
(hk-parse-top "type Pair a = (a, a)")
(hk-prog
(list
:type-syn
"Pair"
(list "a")
(list
:t-tuple
(list (list :t-var "a") (list :t-var "a"))))))
;; ── newtype ──
(hk-test
"newtype"
(hk-parse-top "newtype Age = Age Int")
(hk-prog (list :newtype "Age" (list) "Age" (list :t-con "Int"))))
(hk-test
"parameterised newtype"
(hk-parse-top "newtype Wrap a = Wrap a")
(hk-prog
(list :newtype "Wrap" (list "a") "Wrap" (list :t-var "a"))))
;; ── fixity declarations ──
(hk-test
"infixl with precedence"
(hk-parse-top "infixl 5 +:, -:")
(hk-prog (list :fixity "l" 5 (list "+:" "-:"))))
(hk-test
"infixr"
(hk-parse-top "infixr 9 .")
(hk-prog (list :fixity "r" 9 (list "."))))
(hk-test
"infix (non-assoc) default prec"
(hk-parse-top "infix ==")
(hk-prog (list :fixity "n" 9 (list "=="))))
(hk-test
"fixity with backtick operator name"
(hk-parse-top "infixl 7 `div`")
(hk-prog (list :fixity "l" 7 (list "div"))))
;; ── Several decls combined ──
(hk-test
"mixed: data + sig + fn + type"
(hk-parse-top "data Maybe a = Nothing | Just a\ntype Entry = Maybe Int\nf :: Entry -> Int\nf (Just x) = x\nf Nothing = 0")
(hk-prog
(list
:data
"Maybe"
(list "a")
(list
(list :con-def "Nothing" (list))
(list :con-def "Just" (list (list :t-var "a")))))
(list
:type-syn
"Entry"
(list)
(list :t-app (list :t-con "Maybe") (list :t-con "Int")))
(list
:type-sig
(list "f")
(list :t-fun (list :t-con "Entry") (list :t-con "Int")))
(list
:fun-clause
"f"
(list (list :p-con "Just" (list (list :p-var "x"))))
(list :var "x"))
(list
:fun-clause
"f"
(list (list :p-con "Nothing" (list)))
(list :int 0))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

258
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;; Haskell expression parser tests.
;; hk-parse tokenises, runs layout, then parses. Output is an AST
;; whose head is a keyword tag (evaluates to its string name).
;; ── 1. Literals ──
(hk-test "integer" (hk-parse "42") (list :int 42))
(hk-test "float" (hk-parse "3.14") (list :float 3.14))
(hk-test "string" (hk-parse "\"hi\"") (list :string "hi"))
(hk-test "char" (hk-parse "'a'") (list :char "a"))
;; ── 2. Variables and constructors ──
(hk-test "varid" (hk-parse "foo") (list :var "foo"))
(hk-test "conid" (hk-parse "Nothing") (list :con "Nothing"))
(hk-test "qvarid" (hk-parse "Data.Map.lookup") (list :var "Data.Map.lookup"))
(hk-test "qconid" (hk-parse "Data.Map") (list :con "Data.Map"))
;; ── 3. Parens / unit / tuple ──
(hk-test "parens strip" (hk-parse "(42)") (list :int 42))
(hk-test "unit" (hk-parse "()") (list :con "()"))
(hk-test
"2-tuple"
(hk-parse "(1, 2)")
(list :tuple (list (list :int 1) (list :int 2))))
(hk-test
"3-tuple"
(hk-parse "(x, y, z)")
(list
:tuple
(list (list :var "x") (list :var "y") (list :var "z"))))
;; ── 4. Lists ──
(hk-test "empty list" (hk-parse "[]") (list :list (list)))
(hk-test
"singleton list"
(hk-parse "[1]")
(list :list (list (list :int 1))))
(hk-test
"list of ints"
(hk-parse "[1, 2, 3]")
(list
:list
(list (list :int 1) (list :int 2) (list :int 3))))
(hk-test
"range"
(hk-parse "[1..10]")
(list :range (list :int 1) (list :int 10)))
(hk-test
"range with step"
(hk-parse "[1, 3..10]")
(list
:range-step
(list :int 1)
(list :int 3)
(list :int 10)))
;; ── 5. Application ──
(hk-test
"one-arg app"
(hk-parse "f x")
(list :app (list :var "f") (list :var "x")))
(hk-test
"multi-arg app is left-assoc"
(hk-parse "f x y z")
(list
:app
(list
:app
(list :app (list :var "f") (list :var "x"))
(list :var "y"))
(list :var "z")))
(hk-test
"app with con"
(hk-parse "Just 5")
(list :app (list :con "Just") (list :int 5)))
;; ── 6. Infix operators ──
(hk-test
"simple +"
(hk-parse "1 + 2")
(list :op "+" (list :int 1) (list :int 2)))
(hk-test
"precedence: * binds tighter than +"
(hk-parse "1 + 2 * 3")
(list
:op
"+"
(list :int 1)
(list :op "*" (list :int 2) (list :int 3))))
(hk-test
"- is left-assoc"
(hk-parse "10 - 3 - 2")
(list
:op
"-"
(list :op "-" (list :int 10) (list :int 3))
(list :int 2)))
(hk-test
": is right-assoc"
(hk-parse "a : b : c")
(list
:op
":"
(list :var "a")
(list :op ":" (list :var "b") (list :var "c"))))
(hk-test
"app binds tighter than op"
(hk-parse "f x + g y")
(list
:op
"+"
(list :app (list :var "f") (list :var "x"))
(list :app (list :var "g") (list :var "y"))))
(hk-test
"$ is lowest precedence, right-assoc"
(hk-parse "f $ g x")
(list
:op
"$"
(list :var "f")
(list :app (list :var "g") (list :var "x"))))
;; ── 7. Backticks (varid-as-operator) ──
(hk-test
"backtick operator"
(hk-parse "x `mod` 3")
(list :op "mod" (list :var "x") (list :int 3)))
;; ── 8. Unary negation ──
(hk-test
"unary -"
(hk-parse "- 5")
(list :neg (list :int 5)))
(hk-test
"unary - on application"
(hk-parse "- f x")
(list :neg (list :app (list :var "f") (list :var "x"))))
(hk-test
"- n + m → (- n) + m"
(hk-parse "- 1 + 2")
(list
:op
"+"
(list :neg (list :int 1))
(list :int 2)))
;; ── 9. Lambda ──
(hk-test
"lambda single param"
(hk-parse "\\x -> x")
(list :lambda (list (list :p-var "x")) (list :var "x")))
(hk-test
"lambda multi-param"
(hk-parse "\\x y -> x + y")
(list
:lambda
(list (list :p-var "x") (list :p-var "y"))
(list :op "+" (list :var "x") (list :var "y"))))
(hk-test
"lambda body is full expression"
(hk-parse "\\f -> f 1 + f 2")
(list
:lambda
(list (list :p-var "f"))
(list
:op
"+"
(list :app (list :var "f") (list :int 1))
(list :app (list :var "f") (list :int 2)))))
;; ── 10. if-then-else ──
(hk-test
"if basic"
(hk-parse "if x then 1 else 2")
(list :if (list :var "x") (list :int 1) (list :int 2)))
(hk-test
"if with infix cond"
(hk-parse "if x == 0 then y else z")
(list
:if
(list :op "==" (list :var "x") (list :int 0))
(list :var "y")
(list :var "z")))
;; ── 11. let-in ──
(hk-test
"let single binding"
(hk-parse "let x = 1 in x")
(list
:let
(list (list :bind (list :p-var "x") (list :int 1)))
(list :var "x")))
(hk-test
"let two bindings (multi-line)"
(hk-parse "let x = 1\n y = 2\nin x + y")
(list
:let
(list
(list :bind (list :p-var "x") (list :int 1))
(list :bind (list :p-var "y") (list :int 2)))
(list :op "+" (list :var "x") (list :var "y"))))
(hk-test
"let with explicit braces"
(hk-parse "let { x = 1 ; y = 2 } in x + y")
(list
:let
(list
(list :bind (list :p-var "x") (list :int 1))
(list :bind (list :p-var "y") (list :int 2)))
(list :op "+" (list :var "x") (list :var "y"))))
;; ── 12. Mixed / nesting ──
(hk-test
"nested application"
(hk-parse "f (g x) y")
(list
:app
(list
:app
(list :var "f")
(list :app (list :var "g") (list :var "x")))
(list :var "y")))
(hk-test
"lambda applied"
(hk-parse "(\\x -> x + 1) 5")
(list
:app
(list
:lambda
(list (list :p-var "x"))
(list :op "+" (list :var "x") (list :int 1)))
(list :int 5)))
(hk-test
"lambda + if"
(hk-parse "\\n -> if n == 0 then 1 else n")
(list
:lambda
(list (list :p-var "n"))
(list
:if
(list :op "==" (list :var "n") (list :int 0))
(list :int 1)
(list :var "n"))))
;; ── 13. Precedence corners ──
(hk-test
". is right-assoc (prec 9)"
(hk-parse "f . g . h")
(list
:op
"."
(list :var "f")
(list :op "." (list :var "g") (list :var "h"))))
(hk-test
"== is non-associative (single use)"
(hk-parse "x == y")
(list :op "==" (list :var "x") (list :var "y")))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Guards and where-clauses — on fun-clauses, case alts, and
;; let-bindings (which now also accept funclause-style LHS like
;; `let f x = e` or `let f x | g = e | g = e`).
(define
hk-prog
(fn (&rest decls) (list :program decls)))
;; ── Guarded fun-clauses ──
(hk-test
"simple guards (two branches)"
(hk-parse-top "abs x | x < 0 = - x\n | otherwise = x")
(hk-prog
(list
:fun-clause
"abs"
(list (list :p-var "x"))
(list
:guarded
(list
(list
:guard
(list :op "<" (list :var "x") (list :int 0))
(list :neg (list :var "x")))
(list :guard (list :var "otherwise") (list :var "x")))))))
(hk-test
"three-way guard"
(hk-parse-top "sign n | n > 0 = 1\n | n < 0 = -1\n | otherwise = 0")
(hk-prog
(list
:fun-clause
"sign"
(list (list :p-var "n"))
(list
:guarded
(list
(list
:guard
(list :op ">" (list :var "n") (list :int 0))
(list :int 1))
(list
:guard
(list :op "<" (list :var "n") (list :int 0))
(list :neg (list :int 1)))
(list
:guard
(list :var "otherwise")
(list :int 0)))))))
(hk-test
"mixed: one eq clause plus one guarded clause"
(hk-parse-top "sign 0 = 0\nsign n | n > 0 = 1\n | otherwise = -1")
(hk-prog
(list
:fun-clause
"sign"
(list (list :p-int 0))
(list :int 0))
(list
:fun-clause
"sign"
(list (list :p-var "n"))
(list
:guarded
(list
(list
:guard
(list :op ">" (list :var "n") (list :int 0))
(list :int 1))
(list
:guard
(list :var "otherwise")
(list :neg (list :int 1))))))))
;; ── where on fun-clauses ──
(hk-test
"where with one binding"
(hk-parse-top "f x = y + y\n where y = x + 1")
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:where
(list :op "+" (list :var "y") (list :var "y"))
(list
(list
:fun-clause
"y"
(list)
(list :op "+" (list :var "x") (list :int 1))))))))
(hk-test
"where with multiple bindings"
(hk-parse-top "f x = y * z\n where y = x + 1\n z = x - 1")
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:where
(list :op "*" (list :var "y") (list :var "z"))
(list
(list
:fun-clause
"y"
(list)
(list :op "+" (list :var "x") (list :int 1)))
(list
:fun-clause
"z"
(list)
(list :op "-" (list :var "x") (list :int 1))))))))
(hk-test
"guards + where"
(hk-parse-top "f x | x > 0 = y\n | otherwise = 0\n where y = 99")
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:where
(list
:guarded
(list
(list
:guard
(list :op ">" (list :var "x") (list :int 0))
(list :var "y"))
(list
:guard
(list :var "otherwise")
(list :int 0))))
(list
(list :fun-clause "y" (list) (list :int 99)))))))
;; ── Guards in case alts ──
(hk-test
"case alt with guards"
(hk-parse "case x of\n Just y | y > 0 -> y\n | otherwise -> 0\n Nothing -> 0")
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list
:guarded
(list
(list
:guard
(list :op ">" (list :var "y") (list :int 0))
(list :var "y"))
(list
:guard
(list :var "otherwise")
(list :int 0)))))
(list :alt (list :p-con "Nothing" (list)) (list :int 0)))))
(hk-test
"case alt with where"
(hk-parse "case x of\n Just y -> y + z where z = 5\n Nothing -> 0")
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-con "Just" (list (list :p-var "y")))
(list
:where
(list :op "+" (list :var "y") (list :var "z"))
(list
(list :fun-clause "z" (list) (list :int 5)))))
(list :alt (list :p-con "Nothing" (list)) (list :int 0)))))
;; ── let-bindings: funclause form, guards, where ──
(hk-test
"let with funclause shorthand"
(hk-parse "let f x = x + 1 in f 5")
(list
:let
(list
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list :op "+" (list :var "x") (list :int 1))))
(list :app (list :var "f") (list :int 5))))
(hk-test
"let with guards"
(hk-parse "let f x | x > 0 = x\n | otherwise = 0\nin f 3")
(list
:let
(list
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:guarded
(list
(list
:guard
(list :op ">" (list :var "x") (list :int 0))
(list :var "x"))
(list
:guard
(list :var "otherwise")
(list :int 0))))))
(list :app (list :var "f") (list :int 3))))
(hk-test
"let funclause + where"
(hk-parse "let f x = y where y = x + 1\nin f 7")
(list
:let
(list
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:where
(list :var "y")
(list
(list
:fun-clause
"y"
(list)
(list :op "+" (list :var "x") (list :int 1)))))))
(list :app (list :var "f") (list :int 7))))
;; ── Nested: where inside where (via recursive hk-parse-decl) ──
(hk-test
"where block can contain a type signature"
(hk-parse-top "f x = y\n where y :: Int\n y = x")
(hk-prog
(list
:fun-clause
"f"
(list (list :p-var "x"))
(list
:where
(list :var "y")
(list
(list :type-sig (list "y") (list :t-con "Int"))
(list
:fun-clause
"y"
(list)
(list :var "x")))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Module header + imports. The parser switches from (:program DECLS)
;; to (:module NAME EXPORTS IMPORTS DECLS) as soon as a module header
;; or any `import` decl appears.
;; ── Module header ──
(hk-test
"simple module, no exports"
(hk-parse-top "module M where\n f = 1")
(list
:module
"M"
nil
(list)
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"module with dotted name"
(hk-parse-top "module Data.Map where\nf = 1")
(list
:module
"Data.Map"
nil
(list)
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"module with empty export list"
(hk-parse-top "module M () where\nf = 1")
(list
:module
"M"
(list)
(list)
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"module with exports (var, tycon-all, tycon-with)"
(hk-parse-top "module M (f, g, Maybe(..), List(Cons, Nil)) where\nf = 1\ng = 2")
(list
:module
"M"
(list
(list :ent-var "f")
(list :ent-var "g")
(list :ent-all "Maybe")
(list :ent-with "List" (list "Cons" "Nil")))
(list)
(list
(list :fun-clause "f" (list) (list :int 1))
(list :fun-clause "g" (list) (list :int 2)))))
(hk-test
"module export list including another module"
(hk-parse-top "module M (module Foo, f) where\nf = 1")
(list
:module
"M"
(list (list :ent-module "Foo") (list :ent-var "f"))
(list)
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"module export with operator"
(hk-parse-top "module M ((+:), f) where\nf = 1")
(list
:module
"M"
(list (list :ent-var "+:") (list :ent-var "f"))
(list)
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"empty module body"
(hk-parse-top "module M where")
(list :module "M" nil (list) (list)))
;; ── Imports ──
(hk-test
"plain import"
(hk-parse-top "import Foo")
(list
:module
nil
nil
(list (list :import false "Foo" nil nil))
(list)))
(hk-test
"qualified import"
(hk-parse-top "import qualified Data.Map")
(list
:module
nil
nil
(list (list :import true "Data.Map" nil nil))
(list)))
(hk-test
"import with alias"
(hk-parse-top "import Data.Map as M")
(list
:module
nil
nil
(list (list :import false "Data.Map" "M" nil))
(list)))
(hk-test
"import with explicit list"
(hk-parse-top "import Foo (bar, Baz(..), Quux(X, Y))")
(list
:module
nil
nil
(list
(list
:import
false
"Foo"
nil
(list
:spec-items
(list
(list :ent-var "bar")
(list :ent-all "Baz")
(list :ent-with "Quux" (list "X" "Y"))))))
(list)))
(hk-test
"import hiding"
(hk-parse-top "import Foo hiding (x, y)")
(list
:module
nil
nil
(list
(list
:import
false
"Foo"
nil
(list
:spec-hiding
(list (list :ent-var "x") (list :ent-var "y")))))
(list)))
(hk-test
"qualified + alias + hiding"
(hk-parse-top "import qualified Data.List as L hiding (sort)")
(list
:module
nil
nil
(list
(list
:import
true
"Data.List"
"L"
(list :spec-hiding (list (list :ent-var "sort")))))
(list)))
;; ── Combinations ──
(hk-test
"module with multiple imports and a decl"
(hk-parse-top "module M where\nimport Foo\nimport qualified Bar as B\nf = 1")
(list
:module
"M"
nil
(list
(list :import false "Foo" nil nil)
(list :import true "Bar" "B" nil))
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"headerless file with imports"
(hk-parse-top "import Foo\nimport Bar (baz)\nf = 1")
(list
:module
nil
nil
(list
(list :import false "Foo" nil nil)
(list
:import
false
"Bar"
nil
(list :spec-items (list (list :ent-var "baz")))))
(list (list :fun-clause "f" (list) (list :int 1)))))
(hk-test
"plain program (no header, no imports) still uses :program"
(hk-parse-top "f = 1\ng = 2")
(list
:program
(list
(list :fun-clause "f" (list) (list :int 1))
(list :fun-clause "g" (list) (list :int 2)))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Full-pattern parser tests: as-patterns, lazy ~, negative literals,
;; infix constructor patterns (`:`, any consym), lambda pattern args,
;; and let pattern-bindings.
;; ── as-patterns ──
(hk-test
"as pattern, wraps constructor"
(hk-parse "case x of n@(Just y) -> n")
(list
:case
(list :var "x")
(list
(list
:alt
(list
:p-as
"n"
(list :p-con "Just" (list (list :p-var "y"))))
(list :var "n")))))
(hk-test
"as pattern, wraps wildcard"
(hk-parse "case x of all@_ -> all")
(list
:case
(list :var "x")
(list
(list
:alt
(list :p-as "all" (list :p-wild))
(list :var "all")))))
(hk-test
"as in lambda"
(hk-parse "\\xs@(a : rest) -> xs")
(list
:lambda
(list
(list
:p-as
"xs"
(list
:p-con
":"
(list (list :p-var "a") (list :p-var "rest")))))
(list :var "xs")))
;; ── lazy patterns ──
(hk-test
"lazy var"
(hk-parse "case x of ~y -> y")
(list
:case
(list :var "x")
(list
(list :alt (list :p-lazy (list :p-var "y")) (list :var "y")))))
(hk-test
"lazy constructor"
(hk-parse "\\(~(Just x)) -> x")
(list
:lambda
(list
(list
:p-lazy
(list :p-con "Just" (list (list :p-var "x")))))
(list :var "x")))
;; ── negative literal patterns ──
(hk-test
"negative int pattern"
(hk-parse "case n of\n -1 -> 0\n _ -> n")
(list
:case
(list :var "n")
(list
(list :alt (list :p-int -1) (list :int 0))
(list :alt (list :p-wild) (list :var "n")))))
(hk-test
"negative float pattern"
(hk-parse "case x of -0.5 -> 1")
(list
:case
(list :var "x")
(list (list :alt (list :p-float -0.5) (list :int 1)))))
;; ── infix constructor patterns (`:` and any consym) ──
(hk-test
"cons pattern"
(hk-parse "case xs of x : rest -> x")
(list
:case
(list :var "xs")
(list
(list
:alt
(list
:p-con
":"
(list (list :p-var "x") (list :p-var "rest")))
(list :var "x")))))
(hk-test
"cons is right-associative in pats"
(hk-parse "case xs of a : b : rest -> rest")
(list
:case
(list :var "xs")
(list
(list
:alt
(list
:p-con
":"
(list
(list :p-var "a")
(list
:p-con
":"
(list (list :p-var "b") (list :p-var "rest")))))
(list :var "rest")))))
(hk-test
"consym pattern"
(hk-parse "case p of a :+: b -> a")
(list
:case
(list :var "p")
(list
(list
:alt
(list
:p-con
":+:"
(list (list :p-var "a") (list :p-var "b")))
(list :var "a")))))
;; ── lambda with pattern args ──
(hk-test
"lambda with constructor pattern"
(hk-parse "\\(Just x) -> x")
(list
:lambda
(list (list :p-con "Just" (list (list :p-var "x"))))
(list :var "x")))
(hk-test
"lambda with tuple pattern"
(hk-parse "\\(a, b) -> a + b")
(list
:lambda
(list
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b"))))
(list :op "+" (list :var "a") (list :var "b"))))
(hk-test
"lambda with wildcard"
(hk-parse "\\_ -> 42")
(list :lambda (list (list :p-wild)) (list :int 42)))
(hk-test
"lambda with mixed apats"
(hk-parse "\\x _ (Just y) -> y")
(list
:lambda
(list
(list :p-var "x")
(list :p-wild)
(list :p-con "Just" (list (list :p-var "y"))))
(list :var "y")))
;; ── let pattern-bindings ──
(hk-test
"let tuple pattern-binding"
(hk-parse "let (x, y) = pair in x + y")
(list
:let
(list
(list
:bind
(list
:p-tuple
(list (list :p-var "x") (list :p-var "y")))
(list :var "pair")))
(list :op "+" (list :var "x") (list :var "y"))))
(hk-test
"let constructor pattern-binding"
(hk-parse "let Just x = m in x")
(list
:let
(list
(list
:bind
(list :p-con "Just" (list (list :p-var "x")))
(list :var "m")))
(list :var "x")))
(hk-test
"let cons pattern-binding"
(hk-parse "let (x : rest) = xs in x")
(list
:let
(list
(list
:bind
(list
:p-con
":"
(list (list :p-var "x") (list :p-var "rest")))
(list :var "xs")))
(list :var "x")))
;; ── do with constructor-pattern binds ──
(hk-test
"do bind to tuple pattern"
(hk-parse "do\n (a, b) <- pairs\n return a")
(list
:do
(list
(list
:do-bind
(list
:p-tuple
(list (list :p-var "a") (list :p-var "b")))
(list :var "pairs"))
(list
:do-expr
(list :app (list :var "return") (list :var "a"))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; Operator sections and list comprehensions.
;; ── Operator references (unchanged expr shape) ──
(hk-test
"op as value (+)"
(hk-parse "(+)")
(list :var "+"))
(hk-test
"op as value (-)"
(hk-parse "(-)")
(list :var "-"))
(hk-test
"op as value (:)"
(hk-parse "(:)")
(list :var ":"))
(hk-test
"backtick op as value"
(hk-parse "(`div`)")
(list :var "div"))
;; ── Right sections (op expr) ──
(hk-test
"right section (+ 5)"
(hk-parse "(+ 5)")
(list :sect-right "+" (list :int 5)))
(hk-test
"right section (* x)"
(hk-parse "(* x)")
(list :sect-right "*" (list :var "x")))
(hk-test
"right section with backtick op"
(hk-parse "(`div` 2)")
(list :sect-right "div" (list :int 2)))
;; `-` is unary in expr position — (- 5) is negation, not a right section
(hk-test
"(- 5) is negation, not a section"
(hk-parse "(- 5)")
(list :neg (list :int 5)))
;; ── Left sections (expr op) ──
(hk-test
"left section (5 +)"
(hk-parse "(5 +)")
(list :sect-left "+" (list :int 5)))
(hk-test
"left section with backtick"
(hk-parse "(x `mod`)")
(list :sect-left "mod" (list :var "x")))
(hk-test
"left section with cons (x :)"
(hk-parse "(x :)")
(list :sect-left ":" (list :var "x")))
;; ── Mixed / nesting ──
(hk-test
"map (+ 1) xs"
(hk-parse "map (+ 1) xs")
(list
:app
(list
:app
(list :var "map")
(list :sect-right "+" (list :int 1)))
(list :var "xs")))
(hk-test
"filter (< 0) xs"
(hk-parse "filter (< 0) xs")
(list
:app
(list
:app
(list :var "filter")
(list :sect-right "<" (list :int 0)))
(list :var "xs")))
;; ── Plain parens and tuples still work ──
(hk-test
"plain parens unwrap"
(hk-parse "(1 + 2)")
(list :op "+" (list :int 1) (list :int 2)))
(hk-test
"tuple still parses"
(hk-parse "(a, b, c)")
(list
:tuple
(list (list :var "a") (list :var "b") (list :var "c"))))
;; ── List comprehensions ──
(hk-test
"simple list comprehension"
(hk-parse "[x | x <- xs]")
(list
:list-comp
(list :var "x")
(list
(list :q-gen (list :p-var "x") (list :var "xs")))))
(hk-test
"comprehension with filter"
(hk-parse "[x * 2 | x <- xs, x > 0]")
(list
:list-comp
(list :op "*" (list :var "x") (list :int 2))
(list
(list :q-gen (list :p-var "x") (list :var "xs"))
(list
:q-guard
(list :op ">" (list :var "x") (list :int 0))))))
(hk-test
"comprehension with let"
(hk-parse "[y | x <- xs, let y = x + 1]")
(list
:list-comp
(list :var "y")
(list
(list :q-gen (list :p-var "x") (list :var "xs"))
(list
:q-let
(list
(list
:bind
(list :p-var "y")
(list :op "+" (list :var "x") (list :int 1))))))))
(hk-test
"nested generators"
(hk-parse "[(x, y) | x <- xs, y <- ys]")
(list
:list-comp
(list :tuple (list (list :var "x") (list :var "y")))
(list
(list :q-gen (list :p-var "x") (list :var "xs"))
(list :q-gen (list :p-var "y") (list :var "ys")))))
(hk-test
"comprehension with constructor pattern"
(hk-parse "[v | Just v <- xs]")
(list
:list-comp
(list :var "v")
(list
(list
:q-gen
(list :p-con "Just" (list (list :p-var "v")))
(list :var "xs")))))
(hk-test
"comprehension with tuple pattern"
(hk-parse "[x + y | (x, y) <- pairs]")
(list
:list-comp
(list :op "+" (list :var "x") (list :var "y"))
(list
(list
:q-gen
(list
:p-tuple
(list (list :p-var "x") (list :p-var "y")))
(list :var "pairs")))))
(hk-test
"combination: generator, let, guard"
(hk-parse "[z | x <- xs, let z = x * 2, z > 10]")
(list
:list-comp
(list :var "z")
(list
(list :q-gen (list :p-var "x") (list :var "xs"))
(list
:q-let
(list
(list
:bind
(list :p-var "z")
(list :op "*" (list :var "x") (list :int 2)))))
(list
:q-guard
(list :op ">" (list :var "z") (list :int 10))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; prelude-extra.sx — tests for Phase 6 prelude additions:
;; ord/isAlpha/isDigit/isSpace/isUpper/isLower/isAlphaNum/digitToInt
;; words/lines/unwords/unlines/sort/nub/splitAt/span/break
;; partition/intercalate/intersperse/isPrefixOf/isSuffixOf/isInfixOf
;; ── ord ──────────────────────────────────────────────────────
(hk-test "ord 'A'" (hk-eval-expr-source "ord 'A'") 65)
(hk-test "ord 'a'" (hk-eval-expr-source "ord 'a'") 97)
(hk-test "ord '0'" (hk-eval-expr-source "ord '0'") 48)
;; ── isAlpha / isDigit / isSpace / isUpper / isLower ──────────
(hk-test
"isAlpha 'a' True"
(hk-eval-expr-source "isAlpha 'a'")
(list "True"))
(hk-test
"isAlpha 'Z' True"
(hk-eval-expr-source "isAlpha 'Z'")
(list "True"))
(hk-test
"isAlpha '3' False"
(hk-eval-expr-source "isAlpha '3'")
(list "False"))
(hk-test
"isDigit '5' True"
(hk-eval-expr-source "isDigit '5'")
(list "True"))
(hk-test
"isDigit 'a' False"
(hk-eval-expr-source "isDigit 'a'")
(list "False"))
(hk-test
"isSpace ' ' True"
(hk-eval-expr-source "isSpace ' '")
(list "True"))
(hk-test
"isSpace 'x' False"
(hk-eval-expr-source "isSpace 'x'")
(list "False"))
(hk-test
"isUpper 'A' True"
(hk-eval-expr-source "isUpper 'A'")
(list "True"))
(hk-test
"isUpper 'a' False"
(hk-eval-expr-source "isUpper 'a'")
(list "False"))
(hk-test
"isLower 'z' True"
(hk-eval-expr-source "isLower 'z'")
(list "True"))
(hk-test
"isLower 'Z' False"
(hk-eval-expr-source "isLower 'Z'")
(list "False"))
(hk-test
"isAlphaNum '3' True"
(hk-eval-expr-source "isAlphaNum '3'")
(list "True"))
(hk-test
"isAlphaNum 'b' True"
(hk-eval-expr-source "isAlphaNum 'b'")
(list "True"))
(hk-test
"isAlphaNum '!' False"
(hk-eval-expr-source "isAlphaNum '!'")
(list "False"))
;; ── digitToInt ───────────────────────────────────────────────
(hk-test "digitToInt '0'" (hk-eval-expr-source "digitToInt '0'") 0)
(hk-test "digitToInt '7'" (hk-eval-expr-source "digitToInt '7'") 7)
(hk-test "digitToInt '9'" (hk-eval-expr-source "digitToInt '9'") 9)
;; ── words ────────────────────────────────────────────────────
(hk-test
"words single"
(hk-deep-force (hk-eval-expr-source "words \"hello\""))
(list ":" "hello" (list "[]")))
(hk-test
"words two"
(hk-deep-force (hk-eval-expr-source "words \"hello world\""))
(list ":" "hello" (list ":" "world" (list "[]"))))
(hk-test
"words leading/trailing spaces"
(hk-deep-force (hk-eval-expr-source "words \" foo bar \""))
(list ":" "foo" (list ":" "bar" (list "[]"))))
(hk-test
"words empty string"
(hk-deep-force (hk-eval-expr-source "words \"\""))
(list "[]"))
;; ── lines ────────────────────────────────────────────────────
(hk-test
"lines single no newline"
(hk-deep-force (hk-eval-expr-source "lines \"hello\""))
(list ":" "hello" (list "[]")))
(hk-test
"lines two lines"
(hk-deep-force (hk-eval-expr-source "lines \"a\\nb\""))
(list ":" "a" (list ":" "b" (list "[]"))))
(hk-test
"lines trailing newline"
(hk-deep-force (hk-eval-expr-source "lines \"a\\n\""))
(list ":" "a" (list "[]")))
(hk-test
"lines empty string"
(hk-deep-force (hk-eval-expr-source "lines \"\""))
(list "[]"))
;; ── unwords / unlines ────────────────────────────────────────
(hk-test
"unwords two"
(hk-eval-expr-source "unwords [\"hello\", \"world\"]")
"hello world")
(hk-test "unwords empty" (hk-eval-expr-source "unwords []") "")
(hk-test "unlines two" (hk-eval-expr-source "unlines [\"a\", \"b\"]") "a\nb\n")
;; ── sort / nub ───────────────────────────────────────────────
(hk-test
"sort ascending"
(hk-deep-force (hk-eval-expr-source "sort [3,1,2]"))
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
(hk-test
"sort already sorted"
(hk-deep-force (hk-eval-expr-source "sort [1,2,3]"))
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
(hk-test
"nub removes duplicates"
(hk-deep-force (hk-eval-expr-source "nub [1,2,1,3,2]"))
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
(hk-test
"nub no duplicates unchanged"
(hk-deep-force (hk-eval-expr-source "nub [1,2,3]"))
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]")))))
;; ── splitAt ──────────────────────────────────────────────────
(hk-test
"splitAt 2"
(hk-deep-force (hk-eval-expr-source "splitAt 2 [1,2,3,4]"))
(list
"Tuple"
(list ":" 1 (list ":" 2 (list "[]")))
(list ":" 3 (list ":" 4 (list "[]")))))
(hk-test
"splitAt 0"
(hk-deep-force (hk-eval-expr-source "splitAt 0 [1,2,3]"))
(list
"Tuple"
(list "[]")
(list ":" 1 (list ":" 2 (list ":" 3 (list "[]"))))))
;; ── span / break ─────────────────────────────────────────────
(hk-test
"span digits"
(hk-deep-force (hk-eval-expr-source "span (\\x -> x < 3) [1,2,3,4]"))
(list
"Tuple"
(list ":" 1 (list ":" 2 (list "[]")))
(list ":" 3 (list ":" 4 (list "[]")))))
(hk-test
"break digits"
(hk-deep-force (hk-eval-expr-source "break (\\x -> x >= 3) [1,2,3,4]"))
(list
"Tuple"
(list ":" 1 (list ":" 2 (list "[]")))
(list ":" 3 (list ":" 4 (list "[]")))))
;; ── partition ────────────────────────────────────────────────
(hk-test
"partition even/odd"
(hk-deep-force
(hk-eval-expr-source "partition (\\x -> x `mod` 2 == 0) [1,2,3,4,5]"))
(list
"Tuple"
(list ":" 2 (list ":" 4 (list "[]")))
(list ":" 1 (list ":" 3 (list ":" 5 (list "[]"))))))
;; ── intercalate / intersperse ────────────────────────────────
(hk-test
"intercalate"
(hk-eval-expr-source "intercalate \", \" [\"a\", \"b\", \"c\"]")
"a, b, c")
(hk-test
"intersperse"
(hk-deep-force (hk-eval-expr-source "intersperse 0 [1,2,3]"))
(list
":"
1
(list
":"
0
(list ":" 2 (list ":" 0 (list ":" 3 (list "[]")))))))
;; ── isPrefixOf / isSuffixOf / isInfixOf ──────────────────────
(hk-test
"isPrefixOf True"
(hk-deep-force (hk-eval-expr-source "isPrefixOf [1,2] [1,2,3]"))
(list "True"))
(hk-test
"isPrefixOf False"
(hk-deep-force (hk-eval-expr-source "isPrefixOf [2,3] [1,2,3]"))
(list "False"))
(hk-test
"isSuffixOf True"
(hk-deep-force (hk-eval-expr-source "isSuffixOf [2,3] [1,2,3]"))
(list "True"))
(hk-test
"isInfixOf True"
(hk-deep-force (hk-eval-expr-source "isInfixOf [2,3] [1,2,3,4]"))
(list "True"))
(hk-test
"isInfixOf False"
(hk-deep-force (hk-eval-expr-source "isInfixOf [5,6] [1,2,3,4]"))
(list "False"))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; anagram.hs — anagram detection using sort.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-ana-src
"isAnagram xs ys = sort xs == sort ys\n\nhasAnagram needle haystack = any (isAnagram needle) haystack\n")
(hk-test
"isAnagram [1,2,3] [3,2,1] True"
(hk-prog-val (str hk-ana-src "r = isAnagram [1,2,3] [3,2,1]\n") "r")
(list "True"))
(hk-test
"isAnagram [1,2,3] [1,2,4] False"
(hk-prog-val (str hk-ana-src "r = isAnagram [1,2,3] [1,2,4]\n") "r")
(list "False"))
(hk-test
"isAnagram [] [] True"
(hk-prog-val (str hk-ana-src "r = isAnagram [] []\n") "r")
(list "True"))
(hk-test
"isAnagram [1] [1] True"
(hk-prog-val (str hk-ana-src "r = isAnagram [1] [1]\n") "r")
(list "True"))
(hk-test
"isAnagram [1,2] [2,1] True"
(hk-prog-val (str hk-ana-src "r = isAnagram [1,2] [2,1]\n") "r")
(list "True"))
(hk-test
"isAnagram [1,1,2] [2,1,1] True"
(hk-prog-val (str hk-ana-src "r = isAnagram [1,1,2] [2,1,1]\n") "r")
(list "True"))
(hk-test
"isAnagram [1,2] [1,2,3] False"
(hk-prog-val (str hk-ana-src "r = isAnagram [1,2] [1,2,3]\n") "r")
(list "False"))
(hk-test
"hasAnagram [1,2] [[3,4],[2,1],[5,6]] True"
(hk-prog-val
(str hk-ana-src "r = hasAnagram [1,2] [[3,4],[2,1],[5,6]]\n")
"r")
(list "True"))
(hk-test
"hasAnagram [1,2] [[3,4],[5,6]] False"
(hk-prog-val (str hk-ana-src "r = hasAnagram [1,2] [[3,4],[5,6]]\n") "r")
(list "False"))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; binary.hs — integer binary representation using explicit recursion.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-bin-src
"toBits 0 = []\ntoBits n = (n `mod` 2) : toBits (n `div` 2)\n\ntoBin 0 = [0]\ntoBin n = reverse (toBits n)\n\naddBit acc b = acc * 2 + b\nfromBin bits = foldl addBit 0 bits\n\nnumBits 0 = 1\nnumBits n = length (toBits n)\n")
(hk-test
"toBin 0 = [0]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 0\n") "r"))
(list 0))
(hk-test
"toBin 1 = [1]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 1\n") "r"))
(list 1))
(hk-test
"toBin 2 = [1,0]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 2\n") "r"))
(list 1 0))
(hk-test
"toBin 3 = [1,1]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 3\n") "r"))
(list 1 1))
(hk-test
"toBin 4 = [1,0,0]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 4\n") "r"))
(list 1 0 0))
(hk-test
"toBin 7 = [1,1,1]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 7\n") "r"))
(list 1 1 1))
(hk-test
"toBin 8 = [1,0,0,0]"
(hk-as-list (hk-prog-val (str hk-bin-src "r = toBin 8\n") "r"))
(list 1 0 0 0))
(hk-test
"fromBin [0] = 0"
(hk-prog-val (str hk-bin-src "r = fromBin [0]\n") "r")
0)
(hk-test
"fromBin [1] = 1"
(hk-prog-val (str hk-bin-src "r = fromBin [1]\n") "r")
1)
(hk-test
"fromBin [1,0,1] = 5"
(hk-prog-val (str hk-bin-src "r = fromBin [1,0,1]\n") "r")
5)
(hk-test
"fromBin [1,1,1] = 7"
(hk-prog-val (str hk-bin-src "r = fromBin [1,1,1]\n") "r")
7)
(hk-test
"roundtrip: fromBin (toBin 13) = 13"
(hk-prog-val (str hk-bin-src "r = fromBin (toBin 13)\n") "r")
13)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; calculator.hs — recursive descent expression evaluator.
;;
;; Exercises:
;; - ADTs with constructor fields: TNum Int, TOp String, R Int [Token]
;; - Nested constructor pattern matching: (R v (TOp "+":rest))
;; - let bindings in function bodies
;; - Integer arithmetic including `div` (backtick infix)
;; - Left-associative multi-level operator precedence
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-calc-src
"data Token = TNum Int | TOp String\ndata Result = R Int [Token]\ngetV (R v _) = v\ngetR (R _ r) = r\neval ts = getV (parseExpr ts)\nparseExpr ts = parseExprRest (parseTerm ts)\nparseExprRest (R v (TOp \"+\":rest)) =\n let t = parseTerm rest\n in parseExprRest (R (v + getV t) (getR t))\nparseExprRest (R v (TOp \"-\":rest)) =\n let t = parseTerm rest\n in parseExprRest (R (v - getV t) (getR t))\nparseExprRest r = r\nparseTerm ts = parseTermRest (parseFactor ts)\nparseTermRest (R v (TOp \"*\":rest)) =\n let t = parseFactor rest\n in parseTermRest (R (v * getV t) (getR t))\nparseTermRest (R v (TOp \"/\":rest)) =\n let t = parseFactor rest\n in parseTermRest (R (v `div` getV t) (getR t))\nparseTermRest r = r\nparseFactor (TNum n:rest) = R n rest\n")
(hk-test
"calculator: 2 + 3 = 5"
(hk-prog-val
(str hk-calc-src "result = eval [TNum 2, TOp \"+\", TNum 3]\n")
"result")
5)
(hk-test
"calculator: 2 + 3 * 4 = 14 (precedence)"
(hk-prog-val
(str hk-calc-src "result = eval [TNum 2, TOp \"+\", TNum 3, TOp \"*\", TNum 4]\n")
"result")
14)
(hk-test
"calculator: 10 - 3 - 2 = 5 (left-assoc)"
(hk-prog-val
(str hk-calc-src "result = eval [TNum 10, TOp \"-\", TNum 3, TOp \"-\", TNum 2]\n")
"result")
5)
(hk-test
"calculator: 6 / 2 * 3 = 9 (left-assoc)"
(hk-prog-val
(str hk-calc-src "result = eval [TNum 6, TOp \"/\", TNum 2, TOp \"*\", TNum 3]\n")
"result")
9)
(hk-test
"calculator: single number"
(hk-prog-val
(str hk-calc-src "result = eval [TNum 42]\n")
"result")
42)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; collatz.hs — Collatz (3n+1) sequences.
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-col-src
"collatz 1 = [1]\ncollatz n = if n `mod` 2 == 0\n then n : collatz (n `div` 2)\n else n : collatz (3 * n + 1)\ncollatzLen n = length (collatz n)\n")
(hk-test
"collatz 1 = [1]"
(hk-as-list (hk-prog-val (str hk-col-src "r = collatz 1\n") "r"))
(list 1))
(hk-test
"collatz 2 = [2,1]"
(hk-as-list (hk-prog-val (str hk-col-src "r = collatz 2\n") "r"))
(list 2 1))
(hk-test
"collatz 4 = [4,2,1]"
(hk-as-list (hk-prog-val (str hk-col-src "r = collatz 4\n") "r"))
(list 4 2 1))
(hk-test
"collatz 6 starts 6,3,10"
(hk-as-list (hk-prog-val (str hk-col-src "r = take 3 (collatz 6)\n") "r"))
(list 6 3 10))
(hk-test
"collatz 8 = [8,4,2,1]"
(hk-as-list (hk-prog-val (str hk-col-src "r = collatz 8\n") "r"))
(list 8 4 2 1))
(hk-test
"collatzLen 1 = 1"
(hk-prog-val (str hk-col-src "r = collatzLen 1\n") "r")
1)
(hk-test
"collatzLen 2 = 2"
(hk-prog-val (str hk-col-src "r = collatzLen 2\n") "r")
2)
(hk-test
"collatzLen 4 = 3"
(hk-prog-val (str hk-col-src "r = collatzLen 4\n") "r")
3)
(hk-test
"collatzLen 8 = 4"
(hk-prog-val (str hk-col-src "r = collatzLen 8\n") "r")
4)
(hk-test
"collatzLen 16 = 5"
(hk-prog-val (str hk-col-src "r = collatzLen 16\n") "r")
5)
(hk-test
"collatz last is always 1"
(hk-prog-val (str hk-col-src "r = last (collatz 27)\n") "r")
1)
(hk-test
"collatz 3 = [3,10,5,16,8,4,2,1]"
(hk-as-list (hk-prog-val (str hk-col-src "r = collatz 3\n") "r"))
(list 3 10 5 16 8 4 2 1))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; either.hs — Either ADT operations via pattern matching.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-either-src
"safeDiv _ 0 = Left \"divide by zero\"\nsafeDiv x y = Right (x `div` y)\n\nfromRight _ (Right x) = x\nfromRight def (Left _) = def\n\nfromLeft (Left x) _ = x\nfromLeft _ def = def\n\nisRight (Right _) = True\nisRight (Left _) = False\n\nisLeft (Left _) = True\nisLeft (Right _) = False\n\nmapRight _ (Left e) = Left e\nmapRight f (Right x) = Right (f x)\n\ndouble x = x * 2\n")
(hk-test
"safeDiv 10 2 = Right 5"
(hk-prog-val (str hk-either-src "r = safeDiv 10 2\n") "r")
(list "Right" 5))
(hk-test
"safeDiv 7 0 = Left msg"
(hk-prog-val (str hk-either-src "r = safeDiv 7 0\n") "r")
(list "Left" "divide by zero"))
(hk-test
"fromRight 0 (Right 42) = 42"
(hk-prog-val (str hk-either-src "r = fromRight 0 (Right 42)\n") "r")
42)
(hk-test
"fromRight 0 (Left msg) = 0"
(hk-prog-val (str hk-either-src "r = fromRight 0 (Left \"err\")\n") "r")
0)
(hk-test
"isRight (Right 1) = True"
(hk-prog-val (str hk-either-src "r = isRight (Right 1)\n") "r")
(list "True"))
(hk-test
"isRight (Left x) = False"
(hk-prog-val (str hk-either-src "r = isRight (Left \"x\")\n") "r")
(list "False"))
(hk-test
"isLeft (Left x) = True"
(hk-prog-val (str hk-either-src "r = isLeft (Left \"x\")\n") "r")
(list "True"))
(hk-test
"isLeft (Right x) = False"
(hk-prog-val (str hk-either-src "r = isLeft (Right 1)\n") "r")
(list "False"))
(hk-test
"mapRight double (Right 5) = Right 10"
(hk-prog-val (str hk-either-src "r = mapRight double (Right 5)\n") "r")
(list "Right" 10))
(hk-test
"mapRight double (Left e) = Left e"
(hk-prog-val (str hk-either-src "r = mapRight double (Left \"err\")\n") "r")
(list "Left" "err"))
(hk-test
"chain safeDiv results"
(hk-prog-val (str hk-either-src "r = fromRight (-1) (safeDiv 20 4)\n") "r")
5)
(hk-test
"chain safeDiv error"
(hk-prog-val (str hk-either-src "r = fromRight (-1) (safeDiv 20 0)\n") "r")
-1)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; fib.hs — infinite Fibonacci stream classic program.
;;
;; The canonical artefact lives at lib/haskell/tests/programs/fib.hs.
;; The source is mirrored here as an SX string because the evaluator
;; doesn't have read-file in the default env. If you change one, keep
;; the other in sync — there's a runner-level cross-check against the
;; expected first-15 list.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define hk-as-list
(fn (xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-fib-source
"zipPlus (x:xs) (y:ys) = x + y : zipPlus xs ys
zipPlus _ _ = []
myFibs = 0 : 1 : zipPlus myFibs (tail myFibs)
result = take 15 myFibs
")
(hk-test
"fib.hs — first 15 Fibonacci numbers"
(hk-as-list (hk-prog-val hk-fib-source "result"))
(list 0 1 1 2 3 5 8 13 21 34 55 89 144 233 377))
;; Spot-check that the user-defined zipPlus is also reachable
(hk-test
"fib.hs — zipPlus is a multi-clause user fn"
(hk-as-list
(hk-prog-val
(str hk-fib-source "extra = zipPlus [1, 2, 3] [10, 20, 30]\n")
"extra"))
(list 11 22 33))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; fizzbuzz.hs — classic FizzBuzz with guards.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-fb-src
"fizzbuzz n\n | n `mod` 15 == 0 = \"FizzBuzz\"\n | n `mod` 3 == 0 = \"Fizz\"\n | n `mod` 5 == 0 = \"Buzz\"\n | otherwise = \"Other\"\n")
(hk-test
"fizzbuzz 1 = Other"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 1\n") "r")
"Other")
(hk-test
"fizzbuzz 3 = Fizz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 3\n") "r")
"Fizz")
(hk-test
"fizzbuzz 5 = Buzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 5\n") "r")
"Buzz")
(hk-test
"fizzbuzz 15 = FizzBuzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 15\n") "r")
"FizzBuzz")
(hk-test
"fizzbuzz 30 = FizzBuzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 30\n") "r")
"FizzBuzz")
(hk-test
"fizzbuzz 6 = Fizz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 6\n") "r")
"Fizz")
(hk-test
"fizzbuzz 10 = Buzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 10\n") "r")
"Buzz")
(hk-test
"fizzbuzz 7 = Other"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 7\n") "r")
"Other")
(hk-test
"fizzbuzz 9 = Fizz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 9\n") "r")
"Fizz")
(hk-test
"fizzbuzz 25 = Buzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 25\n") "r")
"Buzz")
(hk-test
"map fizzbuzz [1..5] starts Other"
(hk-as-list
(hk-prog-val (str hk-fb-src "r = map fizzbuzz [1,2,3,4,5]\n") "r"))
(list "Other" "Other" "Fizz" "Other" "Buzz"))
(hk-test
"fizzbuzz 45 = FizzBuzz"
(hk-prog-val (str hk-fb-src "r = fizzbuzz 45\n") "r")
"FizzBuzz")
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; program-io.sx — tests for real IO monad (putStrLn, print, putStr).
(hk-test
"putStrLn single line"
(hk-run-io "main = putStrLn \"hello\"")
(list "hello"))
(hk-test
"putStrLn two lines via do"
(hk-run-io "main = do { putStrLn \"a\"; putStrLn \"b\" }")
(list "a" "b"))
(hk-test "print Int" (hk-run-io "main = print 42") (list "42"))
(hk-test "print Bool True" (hk-run-io "main = print True") (list "True"))
(hk-test
"putStr collects string"
(hk-run-io "main = putStr \"hello\"")
(list "hello"))
(hk-test
"do with let then putStrLn"
(hk-run-io "main = do\n let s = \"world\"\n putStrLn s")
(list "world"))
(hk-test
"do sequence three lines"
(hk-run-io "main = do { putStrLn \"1\"; putStrLn \"2\"; putStrLn \"3\" }")
(list "1" "2" "3"))
(hk-test
"print computed value"
(hk-run-io "main = print (6 * 7)")
(list "42"))
(hk-test
"putStrLn returns IO unit"
(hk-deep-force (hk-run "main = putStrLn \"hi\""))
(list "IO" (list "Tuple")))
(hk-test
"hk-run-io resets between calls"
(begin
(hk-run-io "main = putStrLn \"first\"")
(hk-run-io "main = putStrLn \"second\""))
(list "second"))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; matrix.hs — transpose and 2D list operations.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-mat-src
"transpose [] = []\ntranspose ([] : _) = []\ntranspose xss = map head xss : transpose (map tail xss)\n\nmatAdd xss yss = zipWith (zipWith (+)) xss yss\n\ndiagonal [] = []\ndiagonal xss = head (head xss) : diagonal (map tail (tail xss))\n\nrowSum = map sum\ncolSum xss = map sum (transpose xss)\n")
(hk-test
"transpose 2x2"
(hk-deep-force
(hk-prog-val (str hk-mat-src "r = transpose [[1,2],[3,4]]\n") "r"))
(list
":"
(list ":" 1 (list ":" 3 (list "[]")))
(list ":" (list ":" 2 (list ":" 4 (list "[]"))) (list "[]"))))
(hk-test
"transpose 1x3"
(hk-deep-force
(hk-prog-val (str hk-mat-src "r = transpose [[1,2,3]]\n") "r"))
(list
":"
(list ":" 1 (list "[]"))
(list
":"
(list ":" 2 (list "[]"))
(list ":" (list ":" 3 (list "[]")) (list "[]")))))
(hk-test
"transpose empty = []"
(hk-as-list (hk-prog-val (str hk-mat-src "r = transpose []\n") "r"))
(list))
(hk-test
"rowSum [[1,2],[3,4]] = [3,7]"
(hk-as-list (hk-prog-val (str hk-mat-src "r = rowSum [[1,2],[3,4]]\n") "r"))
(list 3 7))
(hk-test
"colSum [[1,2],[3,4]] = [4,6]"
(hk-as-list (hk-prog-val (str hk-mat-src "r = colSum [[1,2],[3,4]]\n") "r"))
(list 4 6))
(hk-test
"matAdd [[1,2],[3,4]] [[5,6],[7,8]] = [[6,8],[10,12]]"
(hk-deep-force
(hk-prog-val
(str hk-mat-src "r = matAdd [[1,2],[3,4]] [[5,6],[7,8]]\n")
"r"))
(list
":"
(list ":" 6 (list ":" 8 (list "[]")))
(list ":" (list ":" 10 (list ":" 12 (list "[]"))) (list "[]"))))
(hk-test
"diagonal [[1,2],[3,4]] = [1,4]"
(hk-as-list
(hk-prog-val (str hk-mat-src "r = diagonal [[1,2],[3,4]]\n") "r"))
(list 1 4))
(hk-test
"diagonal 3x3"
(hk-as-list
(hk-prog-val
(str hk-mat-src "r = diagonal [[1,2,3],[4,5,6],[7,8,9]]\n")
"r"))
(list 1 5 9))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; maybe.hs — safe operations returning Maybe values.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-maybe-src
"safeDiv _ 0 = Nothing\nsafeDiv x y = Just (x `div` y)\n\nsafeHead [] = Nothing\nsafeHead (x:_) = Just x\n\nfromMaybeZero Nothing = 0\nfromMaybeZero (Just x) = x\n\nmapMaybe _ Nothing = Nothing\nmapMaybe f (Just x) = Just (f x)\n\ndouble x = x * 2\n")
(hk-test
"safeDiv 10 2 = Just 5"
(hk-prog-val (str hk-maybe-src "r = safeDiv 10 2\n") "r")
(list "Just" 5))
(hk-test
"safeDiv 7 0 = Nothing"
(hk-prog-val (str hk-maybe-src "r = safeDiv 7 0\n") "r")
(list "Nothing"))
(hk-test
"safeHead [1,2,3] = Just 1"
(hk-prog-val (str hk-maybe-src "r = safeHead [1,2,3]\n") "r")
(list "Just" 1))
(hk-test
"safeHead [] = Nothing"
(hk-prog-val (str hk-maybe-src "r = safeHead []\n") "r")
(list "Nothing"))
(hk-test
"fromMaybeZero Nothing = 0"
(hk-prog-val (str hk-maybe-src "r = fromMaybeZero Nothing\n") "r")
0)
(hk-test
"fromMaybeZero (Just 42) = 42"
(hk-prog-val (str hk-maybe-src "r = fromMaybeZero (Just 42)\n") "r")
42)
(hk-test
"mapMaybe double Nothing = Nothing"
(hk-prog-val (str hk-maybe-src "r = mapMaybe double Nothing\n") "r")
(list "Nothing"))
(hk-test
"mapMaybe double (Just 5) = Just 10"
(hk-prog-val (str hk-maybe-src "r = mapMaybe double (Just 5)\n") "r")
(list "Just" 10))
(hk-test
"chain: fromMaybeZero (safeDiv 10 2) = 5"
(hk-prog-val (str hk-maybe-src "r = fromMaybeZero (safeDiv 10 2)\n") "r")
5)
(hk-test
"chain: fromMaybeZero (safeDiv 10 0) = 0"
(hk-prog-val (str hk-maybe-src "r = fromMaybeZero (safeDiv 10 0)\n") "r")
0)
(hk-test
"safeDiv 100 5 = Just 20"
(hk-prog-val (str hk-maybe-src "r = safeDiv 100 5\n") "r")
(list "Just" 20))
(hk-test
"mapMaybe double (safeDiv 6 2) = Just 6"
(hk-prog-val (str hk-maybe-src "r = mapMaybe double (safeDiv 6 2)\n") "r")
(list "Just" 6))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; nqueens.hs — n-queens solver via list comprehension + where.
;;
;; Also exercises:
;; - multi-clause let/where binding (go 0 = ...; go k = ...)
;; - list comprehensions (desugared to concatMap)
;; - abs (from Prelude)
;; - [1..n] finite range
;;
;; n=8 is too slow for a 60s timeout; n=4 and n=5 run in ~17s combined.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-nq-base
"queens n = go n
where
go 0 = [[]]
go k = [q:qs | qs <- go (k - 1), q <- [1..n], safe q qs]
safe q qs = check q qs 1
check q [] _ = True
check q (c:cs) d = q /= c && abs (q - c) /= d && check q cs (d + 1)
")
(hk-test
"nqueens: queens 4 has 2 solutions"
(hk-prog-val (str hk-nq-base "result = length (queens 4)\n") "result")
2)
(hk-test
"nqueens: queens 5 has 10 solutions"
(hk-prog-val (str hk-nq-base "result = length (queens 5)\n") "result")
10)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; palindrome.hs — palindrome check via reverse comparison.
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define hk-pal-src "isPalindrome xs = xs == reverse xs\n")
(hk-test
"isPalindrome empty"
(hk-prog-val (str hk-pal-src "r = isPalindrome []\n") "r")
(list "True"))
(hk-test
"isPalindrome single"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1]\n") "r")
(list "True"))
(hk-test
"isPalindrome [1,2,1] True"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1,2,1]\n") "r")
(list "True"))
(hk-test
"isPalindrome [1,2,3] False"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1,2,3]\n") "r")
(list "False"))
(hk-test
"isPalindrome [1,2,2,1] True"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1,2,2,1]\n") "r")
(list "True"))
(hk-test
"isPalindrome [1,2,3,4] False"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1,2,3,4]\n") "r")
(list "False"))
(hk-test
"isPalindrome five odd True"
(hk-prog-val (str hk-pal-src "r = isPalindrome [1,2,3,2,1]\n") "r")
(list "True"))
(hk-test
"isPalindrome racecar True"
(hk-prog-val (str hk-pal-src "r = isPalindrome \"racecar\"\n") "r")
(list "True"))
(hk-test
"isPalindrome hello False"
(hk-prog-val (str hk-pal-src "r = isPalindrome \"hello\"\n") "r")
(list "False"))
(hk-test
"isPalindrome a True"
(hk-prog-val (str hk-pal-src "r = isPalindrome \"a\"\n") "r")
(list "True"))
(hk-test
"isPalindrome madam True"
(hk-prog-val (str hk-pal-src "r = isPalindrome \"madam\"\n") "r")
(list "True"))
(hk-test
"not-palindrome via map"
(hk-as-list
(hk-prog-val
(str hk-pal-src "r = filter isPalindrome [[1],[1,2],[1,2,1],[2,3]]\n")
"r"))
(list
(list ":" 1 (list "[]"))
(list ":" 1 (list ":" 2 (list ":" 1 (list "[]"))))))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; powers.hs — integer exponentiation and powers-of-2 checks.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-pow-src
"pow _ 0 = 1\npow base n = base * pow base (n - 1)\n\npowers base k = map (pow base) [0..k]\n\nisPowerOf2 n\n | n <= 0 = False\n | n == 1 = True\n | otherwise = n `mod` 2 == 0 && isPowerOf2 (n `div` 2)\n\nlog2 1 = 0\nlog2 n = 1 + log2 (n `div` 2)\n")
(hk-test "pow 2 0 = 1" (hk-prog-val (str hk-pow-src "r = pow 2 0\n") "r") 1)
(hk-test "pow 2 1 = 2" (hk-prog-val (str hk-pow-src "r = pow 2 1\n") "r") 2)
(hk-test
"pow 2 8 = 256"
(hk-prog-val (str hk-pow-src "r = pow 2 8\n") "r")
256)
(hk-test "pow 3 4 = 81" (hk-prog-val (str hk-pow-src "r = pow 3 4\n") "r") 81)
(hk-test
"pow 10 3 = 1000"
(hk-prog-val (str hk-pow-src "r = pow 10 3\n") "r")
1000)
(hk-test
"powers 2 4 = [1,2,4,8,16]"
(hk-as-list (hk-prog-val (str hk-pow-src "r = powers 2 4\n") "r"))
(list 1 2 4 8 16))
(hk-test
"powers 3 3 = [1,3,9,27]"
(hk-as-list (hk-prog-val (str hk-pow-src "r = powers 3 3\n") "r"))
(list 1 3 9 27))
(hk-test
"isPowerOf2 1 = True"
(hk-prog-val (str hk-pow-src "r = isPowerOf2 1\n") "r")
(list "True"))
(hk-test
"isPowerOf2 8 = True"
(hk-prog-val (str hk-pow-src "r = isPowerOf2 8\n") "r")
(list "True"))
(hk-test
"isPowerOf2 6 = False"
(hk-prog-val (str hk-pow-src "r = isPowerOf2 6\n") "r")
(list "False"))
(hk-test
"isPowerOf2 0 = False"
(hk-prog-val (str hk-pow-src "r = isPowerOf2 0\n") "r")
(list "False"))
(hk-test "log2 1 = 0" (hk-prog-val (str hk-pow-src "r = log2 1\n") "r") 0)
(hk-test "log2 8 = 3" (hk-prog-val (str hk-pow-src "r = log2 8\n") "r") 3)
(hk-test
"log2 1024 = 10"
(hk-prog-val (str hk-pow-src "r = log2 1024\n") "r")
10)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; primes.hs — primality testing via trial division with where clauses.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-primes-src
"isPrime n\n | n < 2 = False\n | n == 2 = True\n | otherwise = all notDiv [2..n-1]\n where notDiv d = n `mod` d /= 0\n\nprimes20 = filter isPrime [2..20]\n\nnextPrime n = head (filter isPrime [n+1..])\n\ncountPrimes lo hi = length (filter isPrime [lo..hi])\n")
(hk-test
"isPrime 2 = True"
(hk-prog-val (str hk-primes-src "r = isPrime 2\n") "r")
(list "True"))
(hk-test
"isPrime 3 = True"
(hk-prog-val (str hk-primes-src "r = isPrime 3\n") "r")
(list "True"))
(hk-test
"isPrime 4 = False"
(hk-prog-val (str hk-primes-src "r = isPrime 4\n") "r")
(list "False"))
(hk-test
"isPrime 5 = True"
(hk-prog-val (str hk-primes-src "r = isPrime 5\n") "r")
(list "True"))
(hk-test
"isPrime 1 = False"
(hk-prog-val (str hk-primes-src "r = isPrime 1\n") "r")
(list "False"))
(hk-test
"isPrime 0 = False"
(hk-prog-val (str hk-primes-src "r = isPrime 0\n") "r")
(list "False"))
(hk-test
"isPrime 7 = True"
(hk-prog-val (str hk-primes-src "r = isPrime 7\n") "r")
(list "True"))
(hk-test
"isPrime 9 = False"
(hk-prog-val (str hk-primes-src "r = isPrime 9\n") "r")
(list "False"))
(hk-test
"isPrime 11 = True"
(hk-prog-val (str hk-primes-src "r = isPrime 11\n") "r")
(list "True"))
(hk-test
"primes20 = [2,3,5,7,11,13,17,19]"
(hk-as-list (hk-prog-val (str hk-primes-src "r = primes20\n") "r"))
(list 2 3 5 7 11 13 17 19))
(hk-test
"countPrimes 1 10 = 4"
(hk-prog-val (str hk-primes-src "r = countPrimes 1 10\n") "r")
4)
(hk-test
"nextPrime 10 = 11"
(hk-prog-val (str hk-primes-src "r = nextPrime 10\n") "r")
11)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; quicksort.hs — naive functional quicksort.
(define
hk-as-list
(fn (xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-qs-source
"qsort [] = []
qsort (x:xs) = qsort smaller ++ [x] ++ qsort larger
where
smaller = filter (< x) xs
larger = filter (>= x) xs
result = qsort [3, 1, 4, 1, 5, 9, 2, 6, 5, 3, 5]
")
(hk-test
"quicksort.hs — sort a list of ints"
(hk-as-list (hk-prog-val hk-qs-source "result"))
(list 1 1 2 3 3 4 5 5 5 6 9))
(hk-test
"quicksort.hs — empty list"
(hk-as-list
(hk-prog-val
(str hk-qs-source "e = qsort []\n")
"e"))
(list))
(hk-test
"quicksort.hs — singleton"
(hk-as-list
(hk-prog-val
(str hk-qs-source "s = qsort [42]\n")
"s"))
(list 42))
(hk-test
"quicksort.hs — already sorted"
(hk-as-list
(hk-prog-val
(str hk-qs-source "asc = qsort [1, 2, 3, 4, 5]\n")
"asc"))
(list 1 2 3 4 5))
(hk-test
"quicksort.hs — reverse sorted"
(hk-as-list
(hk-prog-val
(str hk-qs-source "desc = qsort [5, 4, 3, 2, 1]\n")
"desc"))
(list 1 2 3 4 5))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

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;; roman.hs — convert integers to Roman numerals with guards + ++.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-rom-src
"toRoman 0 = \"\"\ntoRoman n\n | n >= 1000 = \"M\" ++ toRoman (n - 1000)\n | n >= 900 = \"CM\" ++ toRoman (n - 900)\n | n >= 500 = \"D\" ++ toRoman (n - 500)\n | n >= 400 = \"CD\" ++ toRoman (n - 400)\n | n >= 100 = \"C\" ++ toRoman (n - 100)\n | n >= 90 = \"XC\" ++ toRoman (n - 90)\n | n >= 50 = \"L\" ++ toRoman (n - 50)\n | n >= 40 = \"XL\" ++ toRoman (n - 40)\n | n >= 10 = \"X\" ++ toRoman (n - 10)\n | n >= 9 = \"IX\" ++ toRoman (n - 9)\n | n >= 5 = \"V\" ++ toRoman (n - 5)\n | n >= 4 = \"IV\" ++ toRoman (n - 4)\n | otherwise = \"I\" ++ toRoman (n - 1)\n")
(hk-test
"toRoman 1 = I"
(hk-prog-val (str hk-rom-src "r = toRoman 1\n") "r")
"I")
(hk-test
"toRoman 4 = IV"
(hk-prog-val (str hk-rom-src "r = toRoman 4\n") "r")
"IV")
(hk-test
"toRoman 5 = V"
(hk-prog-val (str hk-rom-src "r = toRoman 5\n") "r")
"V")
(hk-test
"toRoman 9 = IX"
(hk-prog-val (str hk-rom-src "r = toRoman 9\n") "r")
"IX")
(hk-test
"toRoman 10 = X"
(hk-prog-val (str hk-rom-src "r = toRoman 10\n") "r")
"X")
(hk-test
"toRoman 14 = XIV"
(hk-prog-val (str hk-rom-src "r = toRoman 14\n") "r")
"XIV")
(hk-test
"toRoman 40 = XL"
(hk-prog-val (str hk-rom-src "r = toRoman 40\n") "r")
"XL")
(hk-test
"toRoman 50 = L"
(hk-prog-val (str hk-rom-src "r = toRoman 50\n") "r")
"L")
(hk-test
"toRoman 90 = XC"
(hk-prog-val (str hk-rom-src "r = toRoman 90\n") "r")
"XC")
(hk-test
"toRoman 100 = C"
(hk-prog-val (str hk-rom-src "r = toRoman 100\n") "r")
"C")
(hk-test
"toRoman 400 = CD"
(hk-prog-val (str hk-rom-src "r = toRoman 400\n") "r")
"CD")
(hk-test
"toRoman 1000 = M"
(hk-prog-val (str hk-rom-src "r = toRoman 1000\n") "r")
"M")
(hk-test
"toRoman 1994 = MCMXCIV"
(hk-prog-val (str hk-rom-src "r = toRoman 1994\n") "r")
"MCMXCIV")
(hk-test
"toRoman 58 = LVIII"
(hk-prog-val (str hk-rom-src "r = toRoman 58\n") "r")
"LVIII")
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

48
lib/haskell/tests/program-sieve.sx Normal file
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;; sieve.hs — lazy sieve of Eratosthenes.
;;
;; The canonical artefact lives at lib/haskell/tests/programs/sieve.hs.
;; Mirrored here as an SX string because the default eval env has no
;; read-file. Uses filter + backtick `mod` + lazy [2..] — all of which
;; are now wired in via Phase 3 + the mod/div additions to hk-binop.
(define
hk-as-list
(fn (xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-sieve-source
"sieve (p:xs) = p : sieve (filter (\\x -> x `mod` p /= 0) xs)
sieve [] = []
primes = sieve [2..]
result = take 10 primes
")
(hk-test
"sieve.hs — first 10 primes"
(hk-as-list (hk-prog-val hk-sieve-source "result"))
(list 2 3 5 7 11 13 17 19 23 29))
(hk-test
"sieve.hs — 20th prime is 71"
(nth
(hk-as-list
(hk-prog-val
(str
hk-sieve-source
"result20 = take 20 primes\n")
"result20"))
19)
71)
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

74
lib/haskell/tests/program-wordcount.sx Normal file
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;; wordcount.hs — word and line counting via string splitting.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-wc-src
"wordCount s = length (words s)\nlineCount s = length (lines s)\ncharCount = length\n\nlongestWord s = foldl longer \"\" (words s)\n where longer a b = if length a >= length b then a else b\n\nshortestWord s = foldl shorter (head (words s)) (words s)\n where shorter a b = if length a <= length b then a else b\n\nuniqueWords s = nub (words s)\n")
(hk-test
"wordCount single word"
(hk-prog-val (str hk-wc-src "r = wordCount \"hello\"\n") "r")
1)
(hk-test
"wordCount two words"
(hk-prog-val (str hk-wc-src "r = wordCount \"hello world\"\n") "r")
2)
(hk-test
"wordCount with extra spaces"
(hk-prog-val (str hk-wc-src "r = wordCount \" foo bar \"\n") "r")
2)
(hk-test
"wordCount empty = 0"
(hk-prog-val (str hk-wc-src "r = wordCount \"\"\n") "r")
0)
(hk-test
"lineCount one line"
(hk-prog-val (str hk-wc-src "r = lineCount \"hello\"\n") "r")
1)
(hk-test
"lineCount two lines"
(hk-prog-val (str hk-wc-src "r = lineCount \"a\\nb\"\n") "r")
2)
(hk-test
"charCount \"hello\" = 5"
(hk-prog-val (str hk-wc-src "r = charCount \"hello\"\n") "r")
5)
(hk-test
"charCount empty = 0"
(hk-prog-val (str hk-wc-src "r = charCount \"\"\n") "r")
0)
(hk-test
"longestWord picks longest"
(hk-prog-val (str hk-wc-src "r = longestWord \"a bb ccc\"\n") "r")
"ccc")
(hk-test
"uniqueWords removes duplicates"
(hk-as-list
(hk-prog-val (str hk-wc-src "r = uniqueWords \"a b a c b\"\n") "r"))
(list "a" "b" "c"))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

74
lib/haskell/tests/program-zipwith.sx Normal file
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;; zipwith.hs — zip, zipWith, unzip operations.
(define
hk-prog-val
(fn
(src name)
(hk-deep-force (get (hk-eval-program (hk-core src)) name))))
(define
hk-as-list
(fn
(xs)
(cond
((and (list? xs) (= (first xs) "[]")) (list))
((and (list? xs) (= (first xs) ":"))
(cons (nth xs 1) (hk-as-list (nth xs 2))))
(:else xs))))
(define
hk-zip-src
"addPair (x, y) = x + y\npairSum xs ys = map addPair (zip xs ys)\n\nscaleBy k xs = map (\\x -> x * k) xs\n\ndotProduct xs ys = sum (zipWith (*) xs ys)\n\nzipIndex xs = zip [0..length xs - 1] xs\n")
(hk-test
"zip two lists"
(hk-as-list (hk-prog-val (str hk-zip-src "r = zip [1,2,3] [4,5,6]\n") "r"))
(list (list "Tuple" 1 4) (list "Tuple" 2 5) (list "Tuple" 3 6)))
(hk-test
"zip unequal lengths — shorter wins"
(hk-as-list (hk-prog-val (str hk-zip-src "r = zip [1,2] [10,20,30]\n") "r"))
(list (list "Tuple" 1 10) (list "Tuple" 2 20)))
(hk-test
"zipWith (+)"
(hk-as-list
(hk-prog-val (str hk-zip-src "r = zipWith (+) [1,2,3] [10,20,30]\n") "r"))
(list 11 22 33))
(hk-test
"zipWith (*)"
(hk-as-list
(hk-prog-val (str hk-zip-src "r = zipWith (*) [2,3,4] [10,10,10]\n") "r"))
(list 20 30 40))
(hk-test
"dotProduct [1,2,3] [4,5,6] = 32"
(hk-prog-val (str hk-zip-src "r = dotProduct [1,2,3] [4,5,6]\n") "r")
32)
(hk-test
"dotProduct unit vectors = 0"
(hk-prog-val (str hk-zip-src "r = dotProduct [1,0] [0,1]\n") "r")
0)
(hk-test
"pairSum adds element-wise"
(hk-as-list
(hk-prog-val (str hk-zip-src "r = pairSum [1,2,3] [4,5,6]\n") "r"))
(list 5 7 9))
(hk-test
"unzip separates pairs"
(hk-prog-val (str hk-zip-src "r = unzip [(1,2),(3,4),(5,6)]\n") "r")
(list
"Tuple"
(list ":" 1 (list ":" 3 (list ":" 5 (list "[]"))))
(list ":" 2 (list ":" 4 (list ":" 6 (list "[]"))))))
(hk-test
"zip empty = []"
(hk-as-list (hk-prog-val (str hk-zip-src "r = zip [] [1,2,3]\n") "r"))
(list))
{:fails hk-test-fails :pass hk-test-pass :fail hk-test-fail}

40
lib/haskell/tests/programs/calculator.hs Normal file
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-- calculator.hs — recursive descent expression evaluator.
--
-- Tokens are represented as an ADT; the parser threads a [Token] list
-- through a custom Result type so pattern matching can destructure the
-- pair (value, remaining-tokens) directly inside constructor patterns.
--
-- Operator precedence: * and / bind tighter than + and -.
-- All operators are left-associative.
data Token = TNum Int | TOp String
data Result = R Int [Token]
getV (R v _) = v
getR (R _ r) = r
eval ts = getV (parseExpr ts)
parseExpr ts = parseExprRest (parseTerm ts)
parseExprRest (R v (TOp "+":rest)) =
let t = parseTerm rest
in parseExprRest (R (v + getV t) (getR t))
parseExprRest (R v (TOp "-":rest)) =
let t = parseTerm rest
in parseExprRest (R (v - getV t) (getR t))
parseExprRest r = r
parseTerm ts = parseTermRest (parseFactor ts)
parseTermRest (R v (TOp "*":rest)) =
let t = parseFactor rest
in parseTermRest (R (v * getV t) (getR t))
parseTermRest (R v (TOp "/":rest)) =
let t = parseFactor rest
in parseTermRest (R (v `div` getV t) (getR t))
parseTermRest r = r
parseFactor (TNum n:rest) = R n rest
result = eval [TNum 2, TOp "+", TNum 3, TOp "*", TNum 4]

15
lib/haskell/tests/programs/fib.hs Normal file
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-- fib.hs — infinite Fibonacci stream.
--
-- The classic two-line definition: `fibs` is a self-referential
-- lazy list built by zipping itself with its own tail, summing the
-- pair at each step. Without lazy `:` (cons cell with thunked head
-- and tail) this would diverge before producing any output; with
-- it, `take 15 fibs` evaluates exactly as much of the spine as
-- demanded.
zipPlus (x:xs) (y:ys) = x + y : zipPlus xs ys
zipPlus _ _ = []
myFibs = 0 : 1 : zipPlus myFibs (tail myFibs)
result = take 15 myFibs

18
lib/haskell/tests/programs/nqueens.hs Normal file
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-- nqueens.hs — n-queens backtracking solver.
--
-- `queens n` returns all solutions as lists of column positions,
-- one per row. Each call to `go k` extends all partial `(k-1)`-row
-- solutions by one safe queen, using a list comprehension whose guard
-- checks the new queen against all already-placed queens.
queens n = go n
where
go 0 = [[]]
go k = [q:qs | qs <- go (k - 1), q <- [1..n], safe q qs]
safe q qs = check q qs 1
check q [] _ = True
check q (c:cs) d = q /= c && abs (q - c) /= d && check q cs (d + 1)
result = length (queens 8)

12
lib/haskell/tests/programs/quicksort.hs Normal file
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-- quicksort.hs — naive functional quicksort.
--
-- Partition by pivot, recurse on each half, concatenate.
-- Uses right sections `(< x)` and `(>= x)` with filter.
qsort [] = []
qsort (x:xs) = qsort smaller ++ [x] ++ qsort larger
where
smaller = filter (< x) xs
larger = filter (>= x) xs
result = qsort [3, 1, 4, 1, 5, 9, 2, 6, 5, 3, 5]

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