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base: coop:loops/apl
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coop:main coop:loops/erlang coop:loops/fed-prims coop:architecture coop:lib/guest/quoting coop:loops/scheme coop:hs-f coop:lib/guest/method-chain coop:lib/guest/test-runner coop:lib/smalltalk/refl-env coop:lib/tcl/uplevel coop:loops/kernel coop:loops/apl coop:loops/datalog coop:loops/js coop:loops/ocaml coop:loops/haskell coop:loops/minikanren coop:loops/tcl coop:bugs/resume-letrec coop:bugs/jit-bytecode-loop coop:loops/prolog coop:loops/smalltalk coop:loops/ruby coop:loops/lua coop:loops/forth coop:loops/common-lisp coop:loops/hs coop:hs-e36-websocket coop:hs-e37-tokenizer coop:hs-e39-webworker coop:wasm coop:macros coop:sx coop:exorcism coop:cssx coop:decoupling coop:sexpression coop:relations
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compare: coop:loops/common-lisp
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coop:loops/erlang coop:loops/fed-prims coop:architecture coop:lib/guest/quoting coop:loops/scheme coop:hs-f coop:lib/guest/method-chain coop:lib/guest/test-runner coop:lib/smalltalk/refl-env coop:lib/tcl/uplevel coop:loops/kernel coop:loops/apl coop:loops/datalog coop:loops/js coop:loops/ocaml coop:loops/haskell coop:loops/minikanren coop:loops/tcl coop:bugs/resume-letrec coop:bugs/jit-bytecode-loop coop:loops/prolog coop:loops/smalltalk coop:loops/ruby coop:loops/lua coop:loops/forth coop:loops/common-lisp coop:loops/hs coop:hs-e36-websocket coop:hs-e37-tokenizer coop:hs-e39-webworker coop:main coop:wasm coop:macros coop:sx coop:exorcism coop:cssx coop:decoupling coop:sexpression coop:relations

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loops/apl ... loops/comm

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giles
6d53d36495 briefing: push to origin/loops/common-lisp after each commit
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116
lib/apl/conformance.sh
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@@ -1,116 +0,0 @@
#!/usr/bin/env bash
# lib/apl/conformance.sh — run APL test suites, emit scoreboard.json + scoreboard.md.
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found." >&2
exit 1
fi
SUITES=(structural operators dfn tradfn valence programs system idioms eval-ops pipeline)
OUT_JSON="lib/apl/scoreboard.json"
OUT_MD="lib/apl/scoreboard.md"
run_suite() {
local suite=$1
local file="lib/apl/tests/${suite}.sx"
local TMP
TMP=$(mktemp)
cat > "$TMP" << EPOCHS
(epoch 1)
(load "spec/stdlib.sx")
(load "lib/r7rs.sx")
(load "lib/apl/runtime.sx")
(load "lib/apl/tokenizer.sx")
(load "lib/apl/parser.sx")
(load "lib/apl/transpile.sx")
(epoch 2)
(eval "(define apl-test-pass 0)")
(eval "(define apl-test-fail 0)")
(eval "(define apl-test (fn (name got expected) (if (= got expected) (set! apl-test-pass (+ apl-test-pass 1)) (set! apl-test-fail (+ apl-test-fail 1)))))")
(epoch 3)
(load "${file}")
(epoch 4)
(eval "(list apl-test-pass apl-test-fail)")
EPOCHS
local OUTPUT
OUTPUT=$(timeout 300 "$SX_SERVER" < "$TMP" 2>/dev/null)
rm -f "$TMP"
local LINE
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 4 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 4 \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok 4 //; s/\)$//')
fi
local P F
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
P=${P:-0}
F=${F:-0}
echo "${P} ${F}"
}
declare -A SUITE_PASS
declare -A SUITE_FAIL
TOTAL_PASS=0
TOTAL_FAIL=0
echo "Running APL conformance suite..." >&2
for s in "${SUITES[@]}"; do
read -r p f < <(run_suite "$s")
SUITE_PASS[$s]=$p
SUITE_FAIL[$s]=$f
TOTAL_PASS=$((TOTAL_PASS + p))
TOTAL_FAIL=$((TOTAL_FAIL + f))
printf " %-12s %d/%d\n" "$s" "$p" "$((p+f))" >&2
done
# scoreboard.json
{
printf '{\n'
printf ' "suites": {\n'
first=1
for s in "${SUITES[@]}"; do
if [ $first -eq 0 ]; then printf ',\n'; fi
printf ' "%s": {"pass": %d, "fail": %d}' "$s" "${SUITE_PASS[$s]}" "${SUITE_FAIL[$s]}"
first=0
done
printf '\n },\n'
printf ' "total_pass": %d,\n' "$TOTAL_PASS"
printf ' "total_fail": %d,\n' "$TOTAL_FAIL"
printf ' "total": %d\n' "$((TOTAL_PASS + TOTAL_FAIL))"
printf '}\n'
} > "$OUT_JSON"
# scoreboard.md
{
printf '# APL Conformance Scoreboard\n\n'
printf '_Generated by `lib/apl/conformance.sh`_\n\n'
printf '| Suite | Pass | Fail | Total |\n'
printf '|-------|-----:|-----:|------:|\n'
for s in "${SUITES[@]}"; do
p=${SUITE_PASS[$s]}
f=${SUITE_FAIL[$s]}
printf '| %s | %d | %d | %d |\n' "$s" "$p" "$f" "$((p+f))"
done
printf '| **Total** | **%d** | **%d** | **%d** |\n' "$TOTAL_PASS" "$TOTAL_FAIL" "$((TOTAL_PASS + TOTAL_FAIL))"
printf '\n'
printf '## Notes\n\n'
printf '%s\n' '- Suites use the standard `apl-test name got expected` framework loaded against `lib/apl/runtime.sx` + `lib/apl/transpile.sx`.'
printf '%s\n' '- `lib/apl/tests/parse.sx` and `lib/apl/tests/scalar.sx` use their own self-contained frameworks and are excluded from this scoreboard.'
} > "$OUT_MD"
echo "Wrote $OUT_JSON and $OUT_MD" >&2
echo "Total: $TOTAL_PASS pass, $TOTAL_FAIL fail" >&2
[ "$TOTAL_FAIL" -eq 0 ]

711
lib/apl/parser.sx
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@@ -1,711 +0,0 @@
; APL Parser — right-to-left expression parser
;
; Takes a token list (output of apl-tokenize) and produces an AST.
; APL evaluates right-to-left with no precedence among functions.
; Operators bind to the function immediately to their left in the source.
;
; AST node types:
; (:num n) number literal
; (:str s) string literal
; (:vec n1 n2 ...) strand (juxtaposed literals)
; (:name "x") name reference / alpha / omega
; (:assign "x" expr) assignment x←expr
; (:monad fn arg) monadic function call
; (:dyad fn left right) dyadic function call
; (:derived-fn op fn) derived function: f/ f¨ f⍨
; (:derived-fn2 "." f g) inner product: f.g
; (:outer "∘." fn) outer product: ∘.f
; (:fn-glyph "") function reference
; (:fn-name "foo") named-function reference (dfn variable)
; (:dfn stmt...) {+⍵} anonymous function
; (:guard cond expr) cond:expr guard inside dfn
; (:program stmt...) multi-statement sequence
; ============================================================
; Glyph classification sets
; ============================================================
(define
apl-parse-op-glyphs
(list "/" "⌿" "\\" "⍀" "¨" "⍨" "∘" "." "⍣" "⍤" "⍥" "@"))
(define
apl-parse-fn-glyphs
(list
"+"
"-"
"×"
"÷"
"*"
"⍟"
"⌈"
"⌊"
"|"
"!"
"?"
"○"
"~"
"<"
"≤"
"="
"≥"
">"
"≠"
"≢"
"≡"
"∊"
"∧"
""
"⍱"
"⍲"
","
"⍪"
""
"⌽"
"⊖"
"⍉"
"↑"
"↓"
"⊂"
"⊃"
"⊆"
""
"∩"
""
"⍸"
"⌷"
"⍋"
"⍒"
"⊥"
""
"⊣"
"⊢"
"⍎"
"⍕"))
(define apl-quad-fn-names (list "⎕FMT" "⎕←"))
(define apl-known-fn-names (list))
; ============================================================
; Token accessors
; ============================================================
(define
apl-collect-fn-bindings
(fn
(stmt-groups)
(set! apl-known-fn-names (list))
(for-each
(fn
(toks)
(when
(and
(>= (len toks) 3)
(= (tok-type (nth toks 0)) :name)
(= (tok-type (nth toks 1)) :assign)
(= (tok-type (nth toks 2)) :lbrace))
(set!
apl-known-fn-names
(cons (tok-val (nth toks 0)) apl-known-fn-names))))
stmt-groups)))
(define
apl-parse-op-glyph?
(fn (v) (some (fn (g) (= g v)) apl-parse-op-glyphs)))
(define
apl-parse-fn-glyph?
(fn (v) (some (fn (g) (= g v)) apl-parse-fn-glyphs)))
(define tok-type (fn (tok) (get tok :type)))
; ============================================================
; Collect trailing operators starting at index i
; Returns {:ops (op ...) :end new-i}
; ============================================================
(define tok-val (fn (tok) (get tok :value)))
(define
is-op-tok?
(fn
(tok)
(and (= (tok-type tok) :glyph) (apl-parse-op-glyph? (tok-val tok)))))
; ============================================================
; Build a derived-fn node by chaining operators left-to-right
; (+/¨ → (:derived-fn "¨" (:derived-fn "/" (:fn-glyph "+"))))
; ============================================================
(define
is-fn-tok?
(fn
(tok)
(or
(and (= (tok-type tok) :glyph) (apl-parse-fn-glyph? (tok-val tok)))
(and
(= (tok-type tok) :name)
(or
(some (fn (q) (= q (tok-val tok))) apl-quad-fn-names)
(some (fn (q) (= q (tok-val tok))) apl-known-fn-names))))))
; ============================================================
; Find matching close bracket/paren/brace
; Returns the index of the matching close token
; ============================================================
(define collect-ops (fn (tokens i) (collect-ops-loop tokens i (list))))
(define
collect-ops-loop
(fn
(tokens i acc)
(if
(>= i (len tokens))
{:end i :ops acc}
(let
((tok (nth tokens i)))
(if
(is-op-tok? tok)
(collect-ops-loop tokens (+ i 1) (append acc (tok-val tok)))
{:end i :ops acc})))))
; ============================================================
; Segment collection: scan tokens left-to-right, building
; a list of {:kind "val"/"fn" :node ast} segments.
; Operators following function glyphs are merged into
; derived-fn nodes during this pass.
; ============================================================
(define
build-derived-fn
(fn
(fn-node ops)
(if
(= (len ops) 0)
fn-node
(build-derived-fn (list :derived-fn (first ops) fn-node) (rest ops)))))
(define
find-matching-close
(fn
(tokens start open-type close-type)
(find-matching-close-loop tokens start open-type close-type 1)))
; ============================================================
; Build tree from segment list
;
; The segments are in left-to-right order.
; APL evaluates right-to-left, so the LEFTMOST function is
; the outermost (last-evaluated) node.
;
; Patterns:
; [val] → val node
; [fn val ...] → (:monad fn (build-tree rest))
; [val fn val ...] → (:dyad fn val (build-tree rest))
; [val val ...] → (:vec val1 val2 ...) — strand
; ============================================================
; Find the index of the first function segment (returns -1 if none)
(define
find-matching-close-loop
(fn
(tokens i open-type close-type depth)
(if
(>= i (len tokens))
(len tokens)
(let
((tt (tok-type (nth tokens i))))
(cond
((= tt open-type)
(find-matching-close-loop
tokens
(+ i 1)
open-type
close-type
(+ depth 1)))
((= tt close-type)
(if
(= depth 1)
i
(find-matching-close-loop
tokens
(+ i 1)
open-type
close-type
(- depth 1))))
(true
(find-matching-close-loop
tokens
(+ i 1)
open-type
close-type
depth)))))))
(define
collect-segments
(fn (tokens) (collect-segments-loop tokens 0 (list))))
; Build an array node from 0..n value segments
; If n=1 → return that segment's node
; If n>1 → return (:vec node1 node2 ...)
(define
collect-segments-loop
(fn
(tokens i acc)
(if
(>= i (len tokens))
acc
(let
((tok (nth tokens i)) (n (len tokens)))
(let
((tt (tok-type tok)) (tv (tok-val tok)))
(cond
((or (= tt :diamond) (= tt :newline) (= tt :semi))
(collect-segments-loop tokens (+ i 1) acc))
((= tt :num)
(collect-segments-loop tokens (+ i 1) (append acc {:kind "val" :node (list :num tv)})))
((= tt :str)
(collect-segments-loop tokens (+ i 1) (append acc {:kind "val" :node (list :str tv)})))
((= tt :name)
(cond
((and (< (+ i 1) (len tokens)) (= (tok-type (nth tokens (+ i 1))) :assign))
(let
((rhs-tokens (slice tokens (+ i 2) (len tokens))))
(let
((rhs-expr (parse-apl-expr rhs-tokens)))
(collect-segments-loop
tokens
(len tokens)
(append acc {:kind "val" :node (list :assign-expr tv rhs-expr)})))))
((some (fn (q) (= q tv)) apl-quad-fn-names)
(let
((op-result (collect-ops tokens (+ i 1))))
(let
((ops (get op-result :ops))
(ni (get op-result :end)))
(let
((fn-node (build-derived-fn (list :fn-glyph tv) ops)))
(collect-segments-loop
tokens
ni
(append acc {:kind "fn" :node fn-node}))))))
((some (fn (q) (= q tv)) apl-known-fn-names)
(let
((op-result (collect-ops tokens (+ i 1))))
(let
((ops (get op-result :ops))
(ni (get op-result :end)))
(let
((fn-node (build-derived-fn (list :fn-name tv) ops)))
(collect-segments-loop
tokens
ni
(append acc {:kind "fn" :node fn-node}))))))
(else
(let
((br (maybe-bracket (list :name tv) tokens (+ i 1))))
(collect-segments-loop
tokens
(nth br 1)
(append acc {:kind "val" :node (nth br 0)}))))))
((= tt :lparen)
(let
((end (find-matching-close tokens (+ i 1) :lparen :rparen)))
(let
((inner-tokens (slice tokens (+ i 1) end))
(after (+ end 1)))
(let
((inner-segs (collect-segments inner-tokens)))
(if
(and
(>= (len inner-segs) 2)
(every? (fn (s) (= (get s :kind) "fn")) inner-segs))
(let
((train-node (cons :train (map (fn (s) (get s :node)) inner-segs))))
(collect-segments-loop
tokens
after
(append acc {:kind "fn" :node train-node})))
(let
((br (maybe-bracket (parse-apl-expr inner-tokens) tokens after)))
(collect-segments-loop
tokens
(nth br 1)
(append acc {:kind "val" :node (nth br 0)}))))))))
((= tt :lbrace)
(let
((end (find-matching-close tokens (+ i 1) :lbrace :rbrace)))
(let
((inner-tokens (slice tokens (+ i 1) end))
(after (+ end 1)))
(collect-segments-loop tokens after (append acc {:kind "fn" :node (parse-dfn inner-tokens)})))))
((= tt :glyph)
(cond
((or (= tv "") (= tv "⍵"))
(if
(and
(< (+ i 1) (len tokens))
(= (tok-type (nth tokens (+ i 1))) :assign))
(let
((rhs-tokens (slice tokens (+ i 2) (len tokens))))
(let
((rhs-expr (parse-apl-expr rhs-tokens)))
(collect-segments-loop
tokens
(len tokens)
(append acc {:kind "val" :node (list :assign-expr tv rhs-expr)}))))
(collect-segments-loop
tokens
(+ i 1)
(append acc {:kind "val" :node (list :name tv)}))))
((= tv "∇")
(collect-segments-loop
tokens
(+ i 1)
(append acc {:kind "fn" :node (list :fn-glyph "∇")})))
((and (= tv "∘") (< (+ i 1) n) (= (tok-val (nth tokens (+ i 1))) "."))
(if
(and (< (+ i 2) n) (is-fn-tok? (nth tokens (+ i 2))))
(let
((fn-tv (tok-val (nth tokens (+ i 2)))))
(let
((op-result (collect-ops tokens (+ i 3))))
(let
((ops (get op-result :ops))
(ni (get op-result :end)))
(let
((fn-node (build-derived-fn (list :fn-glyph fn-tv) ops)))
(collect-segments-loop
tokens
ni
(append acc {:kind "fn" :node (list :outer "∘." fn-node)}))))))
(collect-segments-loop tokens (+ i 1) acc)))
((apl-parse-fn-glyph? tv)
(let
((op-result (collect-ops tokens (+ i 1))))
(let
((ops (get op-result :ops))
(ni (get op-result :end)))
(if
(and
(= (len ops) 1)
(= (first ops) ".")
(< ni n)
(is-fn-tok? (nth tokens ni)))
(let
((g-tv (tok-val (nth tokens ni))))
(let
((op-result2 (collect-ops tokens (+ ni 1))))
(let
((ops2 (get op-result2 :ops))
(ni2 (get op-result2 :end)))
(let
((g-node (build-derived-fn (list :fn-glyph g-tv) ops2)))
(collect-segments-loop
tokens
ni2
(append acc {:kind "fn" :node (list :derived-fn2 "." (list :fn-glyph tv) g-node)}))))))
(let
((fn-node (build-derived-fn (list :fn-glyph tv) ops)))
(collect-segments-loop
tokens
ni
(append acc {:kind "fn" :node fn-node})))))))
((apl-parse-op-glyph? tv)
(if
(or (= tv "/") (= tv "⌿") (= tv "\\") (= tv "⍀"))
(let
((next-i (+ i 1)))
(let
((next-tok (if (< next-i n) (nth tokens next-i) nil)))
(let
((mod (if (and next-tok (= (tok-type next-tok) :glyph) (or (= (get next-tok :value) "⍨") (= (get next-tok :value) "¨"))) (get next-tok :value) nil))
(base-fn-node (list :fn-glyph tv)))
(let
((node (if mod (list :derived-fn mod base-fn-node) base-fn-node))
(advance (if mod 2 1)))
(collect-segments-loop
tokens
(+ i advance)
(append acc {:kind "fn" :node node}))))))
(collect-segments-loop tokens (+ i 1) acc)))
(true (collect-segments-loop tokens (+ i 1) acc))))
(true (collect-segments-loop tokens (+ i 1) acc))))))))
(define find-first-fn (fn (segs) (find-first-fn-loop segs 0)))
; ============================================================
; Split token list on statement separators (diamond / newline)
; Only splits at depth 0 (ignores separators inside { } or ( ) )
; ============================================================
(define
find-first-fn-loop
(fn
(segs i)
(if
(>= i (len segs))
-1
(if
(= (get (nth segs i) :kind) "fn")
i
(find-first-fn-loop segs (+ i 1))))))
(define
segs-to-array
(fn
(segs)
(if
(= (len segs) 1)
(get (first segs) :node)
(cons :vec (map (fn (s) (get s :node)) segs)))))
; ============================================================
; Parse a dfn body (tokens between { and })
; Handles guard expressions: cond : expr
; ============================================================
(define
build-tree
(fn
(segs)
(cond
((= (len segs) 0) nil)
((= (len segs) 1) (get (first segs) :node))
((every? (fn (s) (= (get s :kind) "val")) segs)
(segs-to-array segs))
(true
(let
((fn-idx (find-first-fn segs)))
(cond
((= fn-idx -1) (segs-to-array segs))
((= fn-idx 0)
(list
:monad (get (first segs) :node)
(build-tree (rest segs))))
(true
(let
((left-segs (slice segs 0 fn-idx))
(fn-seg (nth segs fn-idx))
(right-segs (slice segs (+ fn-idx 1))))
(list
:dyad (get fn-seg :node)
(segs-to-array left-segs)
(build-tree right-segs))))))))))
(define
split-statements
(fn (tokens) (split-statements-loop tokens (list) (list) 0)))
(define
split-statements-loop
(fn
(tokens current-stmt acc depth)
(if
(= (len tokens) 0)
(if (> (len current-stmt) 0) (append acc (list current-stmt)) acc)
(let
((tok (first tokens))
(rest-toks (rest tokens))
(tt (tok-type (first tokens))))
(cond
((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
(split-statements-loop
rest-toks
(append current-stmt tok)
acc
(+ depth 1)))
((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
(split-statements-loop
rest-toks
(append current-stmt tok)
acc
(- depth 1)))
((and (> depth 0) (or (= tt :diamond) (= tt :newline)))
(split-statements-loop
rest-toks
(append current-stmt tok)
acc
depth))
((and (= depth 0) (or (= tt :diamond) (= tt :newline)))
(if
(> (len current-stmt) 0)
(split-statements-loop
rest-toks
(list)
(append acc (list current-stmt))
depth)
(split-statements-loop rest-toks (list) acc depth)))
(true
(split-statements-loop
rest-toks
(append current-stmt tok)
acc
depth)))))))
(define
parse-dfn
(fn
(tokens)
(let
((stmt-groups (split-statements tokens)))
(let ((stmts (map parse-dfn-stmt stmt-groups))) (cons :dfn stmts)))))
; ============================================================
; Parse a single statement (assignment or expression)
; ============================================================
(define
parse-dfn-stmt
(fn
(tokens)
(let
((colon-idx (find-top-level-colon tokens 0)))
(if
(>= colon-idx 0)
(let
((cond-tokens (slice tokens 0 colon-idx))
(body-tokens (slice tokens (+ colon-idx 1))))
(list
:guard (parse-apl-expr cond-tokens)
(parse-apl-expr body-tokens)))
(parse-stmt tokens)))))
; ============================================================
; Parse an expression from a flat token list
; ============================================================
(define
find-top-level-colon
(fn (tokens i) (find-top-level-colon-loop tokens i 0)))
; ============================================================
; Main entry point
; parse-apl: string → AST
; ============================================================
(define
find-top-level-colon-loop
(fn
(tokens i depth)
(if
(>= i (len tokens))
-1
(let
((tok (nth tokens i)) (tt (tok-type (nth tokens i))))
(cond
((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
(find-top-level-colon-loop tokens (+ i 1) (+ depth 1)))
((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
(find-top-level-colon-loop tokens (+ i 1) (- depth 1)))
((and (= tt :colon) (= depth 0)) i)
(true (find-top-level-colon-loop tokens (+ i 1) depth)))))))
(define
parse-stmt
(fn
(tokens)
(if
(and
(>= (len tokens) 2)
(= (tok-type (nth tokens 0)) :name)
(= (tok-type (nth tokens 1)) :assign))
(list
:assign (tok-val (nth tokens 0))
(parse-apl-expr (slice tokens 2)))
(parse-apl-expr tokens))))
(define
parse-apl-expr
(fn
(tokens)
(let
((segs (collect-segments tokens)))
(if (= (len segs) 0) nil (build-tree segs)))))
(define
parse-apl
(fn
(src)
(let
((tokens (apl-tokenize src)))
(let
((stmt-groups (split-statements tokens)))
(begin
(apl-collect-fn-bindings stmt-groups)
(if
(= (len stmt-groups) 0)
nil
(if
(= (len stmt-groups) 1)
(parse-stmt (first stmt-groups))
(cons :program (map parse-stmt stmt-groups)))))))))
(define
split-bracket-loop
(fn
(tokens current acc depth)
(if
(= (len tokens) 0)
(append acc (list current))
(let
((tok (first tokens)) (more (rest tokens)))
(let
((tt (tok-type tok)))
(cond
((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
(split-bracket-loop
more
(append current (list tok))
acc
(+ depth 1)))
((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
(split-bracket-loop
more
(append current (list tok))
acc
(- depth 1)))
((and (= tt :semi) (= depth 0))
(split-bracket-loop
more
(list)
(append acc (list current))
depth))
(else
(split-bracket-loop more (append current (list tok)) acc depth))))))))
(define
split-bracket-content
(fn (tokens) (split-bracket-loop tokens (list) (list) 0)))
(define
maybe-bracket
(fn
(val-node tokens after)
(if
(and
(< after (len tokens))
(= (tok-type (nth tokens after)) :lbracket))
(let
((end (find-matching-close tokens (+ after 1) :lbracket :rbracket)))
(let
((inner-tokens (slice tokens (+ after 1) end))
(next-after (+ end 1)))
(let
((sections (split-bracket-content inner-tokens)))
(if
(= (len sections) 1)
(let
((idx-expr (parse-apl-expr inner-tokens)))
(let
((indexed (list :dyad (list :fn-glyph "⌷") idx-expr val-node)))
(maybe-bracket indexed tokens next-after)))
(let
((axis-exprs (map (fn (toks) (if (= (len toks) 0) :all (parse-apl-expr toks))) sections)))
(let
((indexed (cons :bracket (cons val-node axis-exprs))))
(maybe-bracket indexed tokens next-after)))))))
(list val-node after))))

1752
lib/apl/runtime.sx
View File

File diff suppressed because it is too large Load Diff

17
lib/apl/scoreboard.json
View File

@@ -1,17 +0,0 @@
{
"suites": {
"structural": {"pass": 94, "fail": 0},
"operators": {"pass": 117, "fail": 0},
"dfn": {"pass": 24, "fail": 0},
"tradfn": {"pass": 25, "fail": 0},
"valence": {"pass": 14, "fail": 0},
"programs": {"pass": 45, "fail": 0},
"system": {"pass": 13, "fail": 0},
"idioms": {"pass": 64, "fail": 0},
"eval-ops": {"pass": 14, "fail": 0},
"pipeline": {"pass": 40, "fail": 0}
},
"total_pass": 450,
"total_fail": 0,
"total": 450
}

22
lib/apl/scoreboard.md
View File

@@ -1,22 +0,0 @@
# APL Conformance Scoreboard
_Generated by `lib/apl/conformance.sh`_
| Suite | Pass | Fail | Total |
|-------|-----:|-----:|------:|
| structural | 94 | 0 | 94 |
| operators | 117 | 0 | 117 |
| dfn | 24 | 0 | 24 |
| tradfn | 25 | 0 | 25 |
| valence | 14 | 0 | 14 |
| programs | 45 | 0 | 45 |
| system | 13 | 0 | 13 |
| idioms | 64 | 0 | 64 |
| eval-ops | 14 | 0 | 14 |
| pipeline | 40 | 0 | 40 |
| **Total** | **450** | **0** | **450** |
## Notes
- Suites use the standard `apl-test name got expected` framework loaded against `lib/apl/runtime.sx` + `lib/apl/transpile.sx`.
- `lib/apl/tests/parse.sx` and `lib/apl/tests/scalar.sx` use their own self-contained frameworks and are excluded from this scoreboard.

33
lib/apl/test.sh
View File

@@ -4,9 +4,9 @@
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
if [ ! -x "$SX_SERVER" ]; then
SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
fi
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found."
@@ -18,38 +18,19 @@ TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "spec/stdlib.sx")
(load "lib/r7rs.sx")
(load "lib/apl/runtime.sx")
(load "lib/apl/tokenizer.sx")
(load "lib/apl/parser.sx")
(load "lib/apl/transpile.sx")
(epoch 2)
(eval "(define apl-test-pass 0)")
(eval "(define apl-test-fail 0)")
(eval "(define apl-test-fails (list))")
(eval "(define apl-test (fn (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 {:name name :got got :expected expected})))))))")
(load "lib/apl/tests/runtime.sx")
(epoch 3)
(load "lib/apl/tests/structural.sx")
(load "lib/apl/tests/operators.sx")
(load "lib/apl/tests/dfn.sx")
(load "lib/apl/tests/tradfn.sx")
(load "lib/apl/tests/valence.sx")
(load "lib/apl/tests/programs.sx")
(load "lib/apl/tests/system.sx")
(load "lib/apl/tests/idioms.sx")
(load "lib/apl/tests/eval-ops.sx")
(load "lib/apl/tests/pipeline.sx")
(load "lib/apl/tests/programs-e2e.sx")
(epoch 4)
(eval "(list apl-test-pass apl-test-fail)")
EPOCHS
OUTPUT=$(timeout 300 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 4 / {getline; print; exit}')
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok 4 \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok 4 //; s/\)$//')
LINE=$(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"

227
lib/apl/tests/dfn.sx
View File

@@ -1,227 +0,0 @@
; Tests for apl-eval-ast and apl-call-dfn (manual AST construction).
(define rv (fn (arr) (get arr :ravel)))
(define sh (fn (arr) (get arr :shape)))
(define mknum (fn (n) (list :num n)))
(define mkname (fn (s) (list :name s)))
(define mkfg (fn (g) (list :fn-glyph g)))
(define mkmon (fn (g a) (list :monad (mkfg g) a)))
(define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
(define mkdfn1 (fn (body) (list :dfn body)))
(define mkprog (fn (stmts) (cons :program stmts)))
(define mkasg (fn (mkname expr) (list :assign mkname expr)))
(define mkgrd (fn (c e) (list :guard c e)))
(define mkdfn (fn (stmts) (cons :dfn stmts)))
(apl-test
"eval :num literal"
(rv (apl-eval-ast (mknum 42) {}))
(list 42))
(apl-test
"eval :num literal shape"
(sh (apl-eval-ast (mknum 42) {}))
(list))
(apl-test
"eval :dyad +"
(rv (apl-eval-ast (mkdyd "+" (mknum 2) (mknum 3)) {}))
(list 5))
(apl-test
"eval :dyad ×"
(rv (apl-eval-ast (mkdyd "×" (mknum 6) (mknum 7)) {}))
(list 42))
(apl-test
"eval :monad - (negate)"
(rv (apl-eval-ast (mkmon "-" (mknum 7)) {}))
(list -7))
(apl-test
"eval :monad ⌊ (floor)"
(rv (apl-eval-ast (mkmon "⌊" (mknum 3)) {}))
(list 3))
(apl-test
"eval :name ⍵ from env"
(rv (apl-eval-ast (mkname "⍵") {:omega (apl-scalar 99) :alpha nil}))
(list 99))
(apl-test
"eval :name from env"
(rv (apl-eval-ast (mkname "") {:omega nil :alpha (apl-scalar 7)}))
(list 7))
(apl-test
"dfn {⍵+1} called monadic"
(rv
(apl-call-dfn-m
(mkdfn1 (mkdyd "+" (mkname "⍵") (mknum 1)))
(apl-scalar 5)))
(list 6))
(apl-test
"dfn {+⍵} called dyadic"
(rv
(apl-call-dfn
(mkdfn1 (mkdyd "+" (mkname "") (mkname "⍵")))
(apl-scalar 4)
(apl-scalar 9)))
(list 13))
(apl-test
"dfn {⍺×⍵} dyadic on vectors"
(rv
(apl-call-dfn
(mkdfn1 (mkdyd "×" (mkname "") (mkname "⍵")))
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 10 20 30))))
(list 10 40 90))
(apl-test
"dfn {-⍵} monadic negate"
(rv
(apl-call-dfn-m
(mkdfn1 (mkmon "-" (mkname "⍵")))
(make-array (list 3) (list 1 2 3))))
(list -1 -2 -3))
(apl-test
"dfn {-⍵} dyadic subtract scalar"
(rv
(apl-call-dfn
(mkdfn1 (mkdyd "-" (mkname "") (mkname "⍵")))
(apl-scalar 10)
(apl-scalar 3)))
(list 7))
(apl-test
"dfn {⌈⍺,⍵} not used (just verify : missing) — ceiling of right"
(rv
(apl-call-dfn-m (mkdfn1 (mkmon "⌈" (mkname "⍵"))) (apl-scalar 5)))
(list 5))
(apl-test
"dfn nested dyad"
(rv
(apl-call-dfn
(mkdfn1
(mkdyd "+" (mkname "") (mkdyd "×" (mkname "⍵") (mknum 2))))
(apl-scalar 1)
(apl-scalar 3)))
(list 7))
(apl-test
"dfn local assign x←⍵+1; ×x"
(rv
(apl-call-dfn
(mkdfn
(list
(mkasg "x" (mkdyd "+" (mkname "⍵") (mknum 1)))
(mkdyd "×" (mkname "") (mkname "x"))))
(apl-scalar 3)
(apl-scalar 4)))
(list 15))
(apl-test
"dfn guard: 0=⍵:99; ⍵×2 (true branch)"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 99))
(mkdyd "×" (mkname "⍵") (mknum 2))))
(apl-scalar 0)))
(list 99))
(apl-test
"dfn guard: 0=⍵:99; ⍵×2 (false branch)"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 99))
(mkdyd "×" (mkname "⍵") (mknum 2))))
(apl-scalar 5)))
(list 10))
(apl-test
"dfn default ←10 used (monadic call)"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkasg "" (mknum 10))
(mkdyd "+" (mkname "") (mkname "⍵"))))
(apl-scalar 5)))
(list 15))
(apl-test
"dfn default ←10 ignored when given (dyadic call)"
(rv
(apl-call-dfn
(mkdfn
(list
(mkasg "" (mknum 10))
(mkdyd "+" (mkname "") (mkname "⍵"))))
(apl-scalar 100)
(apl-scalar 5)))
(list 105))
(apl-test
"dfn ∇ recursion: factorial via guard"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 1))
(mkdyd
"×"
(mkname "⍵")
(mkmon "∇" (mkdyd "-" (mkname "⍵") (mknum 1))))))
(apl-scalar 5)))
(list 120))
(apl-test
"dfn ∇ recursion: 3 → 6 (factorial)"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 1))
(mkdyd
"×"
(mkname "⍵")
(mkmon "∇" (mkdyd "-" (mkname "⍵") (mknum 1))))))
(apl-scalar 3)))
(list 6))
(apl-test
"dfn local: x←⍵+10; y←x×2; y"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkasg "x" (mkdyd "+" (mkname "⍵") (mknum 10)))
(mkasg "y" (mkdyd "×" (mkname "x") (mknum 2)))
(mkname "y")))
(apl-scalar 5)))
(list 30))
(apl-test
"dfn first guard wins: many guards"
(rv
(apl-call-dfn-m
(mkdfn
(list
(mkgrd (mkdyd "=" (mknum 1) (mkname "⍵")) (mknum 100))
(mkgrd (mkdyd "=" (mknum 2) (mkname "⍵")) (mknum 200))
(mkgrd (mkdyd "=" (mknum 3) (mkname "⍵")) (mknum 300))
(mknum 0)))
(apl-scalar 2)))
(list 200))

147
lib/apl/tests/eval-ops.sx
View File

@@ -1,147 +0,0 @@
; Tests for operator handling in apl-eval-ast (Phase 7).
; Manual AST construction; verifies :derived-fn / :outer / :derived-fn2
; route through apl-resolve-monadic / apl-resolve-dyadic correctly.
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
(define mknum (fn (n) (list :num n)))
(define mkfg (fn (g) (list :fn-glyph g)))
(define mkmon (fn (g a) (list :monad g a)))
(define mkdyd (fn (g l r) (list :dyad g l r)))
(define mkder (fn (op f) (list :derived-fn op f)))
(define mkdr2 (fn (op f g) (list :derived-fn2 op f g)))
(define mkout (fn (f) (list :outer "∘." f)))
; helper: literal vector AST via :vec (from list of values)
(define mkvec (fn (xs) (cons :vec (map (fn (n) (mknum n)) xs))))
; ---------- monadic operators ----------
(apl-test
"eval-ast +/ 5 → 15"
(mkrv
(apl-eval-ast
(mkmon (mkder "/" (mkfg "+")) (mkmon (mkfg "") (mknum 5)))
{}))
(list 15))
(apl-test
"eval-ast ×/ 5 → 120"
(mkrv
(apl-eval-ast
(mkmon (mkder "/" (mkfg "×")) (mkmon (mkfg "") (mknum 5)))
{}))
(list 120))
(apl-test
"eval-ast ⌈/ — max reduce"
(mkrv
(apl-eval-ast
(mkmon (mkder "/" (mkfg "⌈")) (mkvec (list 3 1 4 1 5 9 2 6)))
{}))
(list 9))
(apl-test
"eval-ast +\\ scan"
(mkrv
(apl-eval-ast
(mkmon (mkder "\\" (mkfg "+")) (mkvec (list 1 2 3 4 5)))
{}))
(list 1 3 6 10 15))
(apl-test
"eval-ast +⌿ first-axis reduce on vector"
(mkrv
(apl-eval-ast
(mkmon (mkder "⌿" (mkfg "+")) (mkvec (list 1 2 3 4 5)))
{}))
(list 15))
(apl-test
"eval-ast -¨ each-negate"
(mkrv
(apl-eval-ast
(mkmon (mkder "¨" (mkfg "-")) (mkvec (list 1 2 3 4)))
{}))
(list -1 -2 -3 -4))
(apl-test
"eval-ast +⍨ commute (double via x+x)"
(mkrv
(apl-eval-ast (mkmon (mkder "⍨" (mkfg "+")) (mknum 7)) {}))
(list 14))
; ---------- dyadic operators ----------
(apl-test
"eval-ast outer ∘.× — multiplication table"
(mkrv
(apl-eval-ast
(mkdyd
(mkout (mkfg "×"))
(mkvec (list 1 2 3))
(mkvec (list 1 2 3)))
{}))
(list 1 2 3 2 4 6 3 6 9))
(apl-test
"eval-ast outer ∘.× shape (3 3)"
(mksh
(apl-eval-ast
(mkdyd
(mkout (mkfg "×"))
(mkvec (list 1 2 3))
(mkvec (list 1 2 3)))
{}))
(list 3 3))
(apl-test
"eval-ast inner +.× — dot product"
(mkrv
(apl-eval-ast
(mkdyd
(mkdr2 "." (mkfg "+") (mkfg "×"))
(mkvec (list 1 2 3))
(mkvec (list 4 5 6)))
{}))
(list 32))
(apl-test
"eval-ast inner ∧.= equal vectors"
(mkrv
(apl-eval-ast
(mkdyd
(mkdr2 "." (mkfg "∧") (mkfg "="))
(mkvec (list 1 2 3))
(mkvec (list 1 2 3)))
{}))
(list 1))
(apl-test
"eval-ast each-dyadic +¨"
(mkrv
(apl-eval-ast
(mkdyd
(mkder "¨" (mkfg "+"))
(mkvec (list 1 2 3))
(mkvec (list 10 20 30)))
{}))
(list 11 22 33))
(apl-test
"eval-ast commute -⍨ (subtract swapped)"
(mkrv
(apl-eval-ast
(mkdyd (mkder "⍨" (mkfg "-")) (mknum 5) (mknum 3))
{}))
(list -2))
; ---------- nested operators ----------
(apl-test
"eval-ast +/¨ — sum of each"
(mkrv
(apl-eval-ast
(mkmon (mkder "/" (mkfg "+")) (mkvec (list 10 20 30)))
{}))
(list 60))

359
lib/apl/tests/idioms.sx
View File

@@ -1,359 +0,0 @@
; APL idiom corpus — classic Roger Hui / Phil Last idioms expressed
; through our runtime primitives. Each test names the APL one-liner
; and verifies the equivalent runtime call.
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
; ---------- reductions ----------
(apl-test
"+/⍵ — sum"
(mkrv (apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 15))
(apl-test
"(+/⍵)÷⍴⍵ — mean"
(mkrv
(apl-div
(apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5)))
(apl-scalar 5)))
(list 3))
(apl-test
"⌈/⍵ — max"
(mkrv (apl-reduce apl-max (make-array (list 6) (list 3 1 4 1 5 9))))
(list 9))
(apl-test
"⌊/⍵ — min"
(mkrv (apl-reduce apl-min (make-array (list 6) (list 3 1 4 1 5 9))))
(list 1))
(apl-test
"(⌈/⍵)-⌊/⍵ — range"
(mkrv
(apl-sub
(apl-reduce apl-max (make-array (list 6) (list 3 1 4 1 5 9)))
(apl-reduce apl-min (make-array (list 6) (list 3 1 4 1 5 9)))))
(list 8))
(apl-test
"×/⍵ — product"
(mkrv (apl-reduce apl-mul (make-array (list 4) (list 1 2 3 4))))
(list 24))
(apl-test
"+\\⍵ — running sum"
(mkrv (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 1 3 6 10 15))
; ---------- sort / order ----------
(apl-test
"⍵[⍋⍵] — sort ascending"
(mkrv (apl-quicksort (make-array (list 5) (list 3 1 4 1 5))))
(list 1 1 3 4 5))
(apl-test
"⌽⍵ — reverse"
(mkrv (apl-reverse (make-array (list 5) (list 1 2 3 4 5))))
(list 5 4 3 2 1))
(apl-test
"⊃⌽⍵ — last element"
(mkrv
(apl-disclose (apl-reverse (make-array (list 4) (list 10 20 30 40)))))
(list 40))
(apl-test
"1↑⍵ — first element"
(mkrv
(apl-take (apl-scalar 1) (make-array (list 4) (list 10 20 30 40))))
(list 10))
(apl-test
"1↓⍵ — drop first"
(mkrv
(apl-drop (apl-scalar 1) (make-array (list 4) (list 10 20 30 40))))
(list 20 30 40))
(apl-test
"¯1↓⍵ — drop last"
(mkrv
(apl-drop (apl-scalar -1) (make-array (list 4) (list 10 20 30 40))))
(list 10 20 30))
; ---------- counts / membership ----------
(apl-test
"≢⍵ — tally"
(mkrv (apl-tally (make-array (list 7) (list 9 8 7 6 5 4 3))))
(list 7))
(apl-test
"+/⍵=v — count occurrences of v"
(mkrv
(apl-reduce
apl-add
(apl-eq (make-array (list 7) (list 1 2 3 2 1 3 2)) (apl-scalar 2))))
(list 3))
(apl-test
"0=N|M — divisibility test"
(mkrv (apl-eq (apl-scalar 0) (apl-mod (apl-scalar 3) (apl-scalar 12))))
(list 1))
; ---------- shape constructors ----------
(apl-test
"N1 — vector of N ones"
(mkrv (apl-reshape (apl-scalar 5) (apl-scalar 1)))
(list 1 1 1 1 1))
(apl-test
"(N N)0 — N×N zero matrix"
(mkrv (apl-reshape (make-array (list 2) (list 3 3)) (apl-scalar 0)))
(list 0 0 0 0 0 0 0 0 0))
(apl-test
"⍳∘.= — N×N identity matrix"
(mkrv
(apl-outer apl-eq (apl-iota (apl-scalar 3)) (apl-iota (apl-scalar 3))))
(list 1 0 0 0 1 0 0 0 1))
(apl-test
"⍳∘.× — multiplication table"
(mkrv
(apl-outer apl-mul (apl-iota (apl-scalar 3)) (apl-iota (apl-scalar 3))))
(list 1 2 3 2 4 6 3 6 9))
; ---------- numerical idioms ----------
(apl-test
"+\\N — triangular numbers"
(mkrv (apl-scan apl-add (apl-iota (apl-scalar 5))))
(list 1 3 6 10 15))
(apl-test
"+/N=N×(N+1)÷2 — sum of 1..N"
(mkrv (apl-reduce apl-add (apl-iota (apl-scalar 10))))
(list 55))
(apl-test
"×/N — factorial via iota"
(mkrv (apl-reduce apl-mul (apl-iota (apl-scalar 5))))
(list 120))
(apl-test
"2|⍵ — parity (1=odd)"
(mkrv (apl-mod (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 0 1 0 1))
(apl-test
"+/2|⍵ — count odd"
(mkrv
(apl-reduce
apl-add
(apl-mod (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5)))))
(list 3))
; ---------- boolean idioms ----------
(apl-test
"∧/⍵ — all-true"
(mkrv (apl-reduce apl-and (make-array (list 4) (list 1 1 1 1))))
(list 1))
(apl-test
"∧/⍵ — all-true with zero is false"
(mkrv (apl-reduce apl-and (make-array (list 4) (list 1 1 0 1))))
(list 0))
(apl-test
"/⍵ — any-true"
(mkrv (apl-reduce apl-or (make-array (list 4) (list 0 0 1 0))))
(list 1))
(apl-test
"/⍵ — any-true all zero is false"
(mkrv (apl-reduce apl-or (make-array (list 4) (list 0 0 0 0))))
(list 0))
; ---------- selection / scaling ----------
(apl-test
"⍵×⍵ — square each"
(mkrv
(apl-mul
(make-array (list 4) (list 1 2 3 4))
(make-array (list 4) (list 1 2 3 4))))
(list 1 4 9 16))
(apl-test
"+/⍵×⍵ — sum of squares"
(mkrv
(apl-reduce
apl-add
(apl-mul
(make-array (list 4) (list 1 2 3 4))
(make-array (list 4) (list 1 2 3 4)))))
(list 30))
(apl-test
"⍵-(+/⍵)÷⍴⍵ — mean-centered"
(mkrv
(apl-sub
(make-array (list 5) (list 2 4 6 8 10))
(apl-div
(apl-reduce apl-add (make-array (list 5) (list 2 4 6 8 10)))
(apl-scalar 5))))
(list -4 -2 0 2 4))
; ---------- shape / structure ----------
(apl-test
",⍵ — ravel"
(mkrv (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 3 4 5 6))
(apl-test
"⍴⍴⍵ — rank"
(mkrv
(apl-shape (apl-shape (make-array (list 2 3) (list 1 2 3 4 5 6)))))
(list 2))
(apl-test
"src: +/N → triangular(N)"
(mkrv (apl-run "+/100"))
(list 5050))
(apl-test "src: ×/N → N!" (mkrv (apl-run "×/6")) (list 720))
(apl-test
"src: ⌈/V — max"
(mkrv (apl-run "⌈/3 1 4 1 5 9 2 6"))
(list 9))
(apl-test
"src: ⌊/V — min"
(mkrv (apl-run "⌊/3 1 4 1 5 9 2 6"))
(list 1))
(apl-test
"src: range = (⌈/V) - ⌊/V"
(mkrv (apl-run "(⌈/3 1 4 1 5 9 2 6) - ⌊/3 1 4 1 5 9 2 6"))
(list 8))
(apl-test
"src: +\\V — running sum"
(mkrv (apl-run "+\\1 2 3 4 5"))
(list 1 3 6 10 15))
(apl-test
"src: ×\\V — running product"
(mkrv (apl-run "×\\1 2 3 4 5"))
(list 1 2 6 24 120))
(apl-test
"src: V × V — squares"
(mkrv (apl-run "(5) × 5"))
(list 1 4 9 16 25))
(apl-test
"src: +/V × V — sum of squares"
(mkrv (apl-run "+/(5) × 5"))
(list 55))
(apl-test "src: ∧/V — all-true" (mkrv (apl-run "∧/1 1 1 1")) (list 1))
(apl-test "src: /V — any-true" (mkrv (apl-run "/0 0 1 0")) (list 1))
(apl-test "src: 0 = N|M — divides" (mkrv (apl-run "0 = 3 | 12")) (list 1))
(apl-test
"src: 2 | V — parity"
(mkrv (apl-run "2 | 1 2 3 4 5 6"))
(list 1 0 1 0 1 0))
(apl-test
"src: +/2|V — count odd"
(mkrv (apl-run "+/2 | 1 2 3 4 5 6"))
(list 3))
(apl-test "src: V" (mkrv (apl-run " 1 2 3 4 5")) (list 5))
(apl-test
"src: M — rank"
(mkrv (apl-run " (2 3) 6"))
(list 2))
(apl-test
"src: N1 — vector of ones"
(mkrv (apl-run "5 1"))
(list 1 1 1 1 1))
(apl-test
"src: N ∘.= N — identity matrix"
(mkrv (apl-run "(3) ∘.= 3"))
(list 1 0 0 0 1 0 0 0 1))
(apl-test
"src: N ∘.× N — multiplication table"
(mkrv (apl-run "(3) ∘.× 3"))
(list 1 2 3 2 4 6 3 6 9))
(apl-test
"src: V +.× V — dot product"
(mkrv (apl-run "1 2 3 +.× 4 5 6"))
(list 32))
(apl-test
"src: ∧.= V — vectors equal?"
(mkrv (apl-run "1 2 3 ∧.= 1 2 3"))
(list 1))
(apl-test
"src: V[1] — first element"
(mkrv (apl-run "(10 20 30 40)[1]"))
(list 10))
(apl-test
"src: 1↑V — first via take"
(mkrv (apl-run "1 ↑ 10 20 30 40"))
(list 10))
(apl-test
"src: 1↓V — drop first"
(mkrv (apl-run "1 ↓ 10 20 30 40"))
(list 20 30 40))
(apl-test
"src: ¯1↓V — drop last"
(mkrv (apl-run "¯1 ↓ 10 20 30 40"))
(list 10 20 30))
(apl-test
"src: ⌽V — reverse"
(mkrv (apl-run "⌽ 1 2 3 4 5"))
(list 5 4 3 2 1))
(apl-test
"src: ≢V — tally"
(mkrv (apl-run "≢ 9 8 7 6 5 4 3 2 1"))
(list 9))
(apl-test
"src: ,M — ravel"
(mkrv (apl-run ", (2 3) 6"))
(list 1 2 3 4 5 6))
(apl-test
"src: A=V — count occurrences"
(mkrv (apl-run "+/2 = 1 2 3 2 1 3 2"))
(list 3))
(apl-test
"src: ⌈/(V × V) — max squared"
(mkrv (apl-run "⌈/(1 2 3 4 5) × 1 2 3 4 5"))
(list 25))

791
lib/apl/tests/operators.sx
View File

@@ -1,791 +0,0 @@
(define rv (fn (arr) (get arr :ravel)))
(define sh (fn (arr) (get arr :shape)))
(apl-test
"reduce +/ vector"
(rv (apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 15))
(apl-test
"reduce x/ vector"
(rv (apl-reduce apl-mul (make-array (list 4) (list 1 2 3 4))))
(list 24))
(apl-test
"reduce max/ vector"
(rv (apl-reduce apl-max (make-array (list 5) (list 3 1 4 1 5))))
(list 5))
(apl-test
"reduce min/ vector"
(rv (apl-reduce apl-min (make-array (list 3) (list 3 1 4))))
(list 1))
(apl-test
"reduce and/ all true"
(rv (apl-reduce apl-and (make-array (list 3) (list 1 1 1))))
(list 1))
(apl-test
"reduce or/ with true"
(rv (apl-reduce apl-or (make-array (list 3) (list 0 0 1))))
(list 1))
(apl-test
"reduce +/ single element"
(rv (apl-reduce apl-add (make-array (list 1) (list 42))))
(list 42))
(apl-test
"reduce +/ scalar no-op"
(rv (apl-reduce apl-add (apl-scalar 7)))
(list 7))
(apl-test
"reduce +/ shape is scalar"
(sh (apl-reduce apl-add (make-array (list 4) (list 1 2 3 4))))
(list))
(apl-test
"reduce +/ matrix row sums shape"
(sh (apl-reduce apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2))
(apl-test
"reduce +/ matrix row sums values"
(rv (apl-reduce apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 6 15))
(apl-test
"reduce max/ matrix row maxima"
(rv (apl-reduce apl-max (make-array (list 2 3) (list 3 1 4 1 5 9))))
(list 4 9))
(apl-test
"reduce-first +/ vector same as reduce"
(rv (apl-reduce-first apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 15))
(apl-test
"reduce-first +/ matrix col sums shape"
(sh
(apl-reduce-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3))
(apl-test
"reduce-first +/ matrix col sums values"
(rv
(apl-reduce-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 5 7 9))
(apl-test
"reduce-first max/ matrix col maxima"
(rv
(apl-reduce-first apl-max (make-array (list 3 2) (list 1 9 2 8 3 7))))
(list 3 9))
(apl-test
"scan +\\ vector"
(rv (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 1 3 6 10 15))
(apl-test
"scan x\\ vector cumulative product"
(rv (apl-scan apl-mul (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 6 24 120))
(apl-test
"scan max\\ vector running max"
(rv (apl-scan apl-max (make-array (list 5) (list 3 1 4 1 5))))
(list 3 3 4 4 5))
(apl-test
"scan min\\ vector running min"
(rv (apl-scan apl-min (make-array (list 5) (list 3 1 4 1 5))))
(list 3 1 1 1 1))
(apl-test
"scan +\\ single element"
(rv (apl-scan apl-add (make-array (list 1) (list 42))))
(list 42))
(apl-test
"scan +\\ scalar no-op"
(rv (apl-scan apl-add (apl-scalar 7)))
(list 7))
(apl-test
"scan +\\ vector preserves shape"
(sh (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 5))
(apl-test
"scan +\\ matrix preserves shape"
(sh (apl-scan apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"scan +\\ matrix row-wise"
(rv (apl-scan apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 3 6 4 9 15))
(apl-test
"scan max\\ matrix row-wise running max"
(rv (apl-scan apl-max (make-array (list 2 3) (list 3 1 4 1 5 9))))
(list 3 3 4 1 5 9))
(apl-test
"scan-first +\\ vector same as scan"
(rv (apl-scan-first apl-add (make-array (list 5) (list 1 2 3 4 5))))
(list 1 3 6 10 15))
(apl-test
"scan-first +\\ scalar no-op"
(rv (apl-scan-first apl-add (apl-scalar 9)))
(list 9))
(apl-test
"scan-first +\\ matrix preserves shape"
(sh (apl-scan-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"scan-first +\\ matrix col-wise"
(rv (apl-scan-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 3 5 7 9))
(apl-test
"scan-first max\\ matrix col-wise running max"
(rv (apl-scan-first apl-max (make-array (list 3 2) (list 3 1 4 1 5 9))))
(list 3 1 4 1 5 9))
(apl-test
"each negate vector"
(rv (apl-each apl-neg-m (make-array (list 3) (list 1 2 3))))
(list -1 -2 -3))
(apl-test
"each negate vector preserves shape"
(sh (apl-each apl-neg-m (make-array (list 3) (list 1 2 3))))
(list 3))
(apl-test
"each reciprocal vector"
(rv (apl-each apl-recip (make-array (list 3) (list 1 2 4))))
(list 1 (/ 1 2) (/ 1 4)))
(apl-test
"each abs vector"
(rv (apl-each apl-abs (make-array (list 4) (list -1 2 -3 4))))
(list 1 2 3 4))
(apl-test "each scalar" (rv (apl-each apl-neg-m (apl-scalar 5))) (list -5))
(apl-test
"each scalar shape"
(sh (apl-each apl-neg-m (apl-scalar 5)))
(list))
(apl-test
"each negate matrix shape"
(sh (apl-each apl-neg-m (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"each negate matrix values"
(rv (apl-each apl-neg-m (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list -1 -2 -3 -4 -5 -6))
(apl-test
"each-dyadic scalar+scalar"
(rv (apl-each-dyadic apl-add (apl-scalar 3) (apl-scalar 4)))
(list 7))
(apl-test
"each-dyadic scalar+vector"
(rv
(apl-each-dyadic
apl-add
(apl-scalar 10)
(make-array (list 3) (list 1 2 3))))
(list 11 12 13))
(apl-test
"each-dyadic vector+scalar"
(rv
(apl-each-dyadic
apl-add
(make-array (list 3) (list 1 2 3))
(apl-scalar 10)))
(list 11 12 13))
(apl-test
"each-dyadic vector+vector"
(rv
(apl-each-dyadic
apl-add
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 10 20 30))))
(list 11 22 33))
(apl-test
"each-dyadic mul matrix+matrix shape"
(sh
(apl-each-dyadic
apl-mul
(make-array (list 2 2) (list 1 2 3 4))
(make-array (list 2 2) (list 5 6 7 8))))
(list 2 2))
(apl-test
"each-dyadic mul matrix+matrix values"
(rv
(apl-each-dyadic
apl-mul
(make-array (list 2 2) (list 1 2 3 4))
(make-array (list 2 2) (list 5 6 7 8))))
(list 5 12 21 32))
(apl-test
"outer product mult table values"
(rv
(apl-outer
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 2 3))))
(list 1 2 3 2 4 6 3 6 9))
(apl-test
"outer product mult table shape"
(sh
(apl-outer
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 2 3))))
(list 3 3))
(apl-test
"outer product add table values"
(rv
(apl-outer
apl-add
(make-array (list 2) (list 1 2))
(make-array (list 3) (list 10 20 30))))
(list 11 21 31 12 22 32))
(apl-test
"outer product add table shape"
(sh
(apl-outer
apl-add
(make-array (list 2) (list 1 2))
(make-array (list 3) (list 10 20 30))))
(list 2 3))
(apl-test
"outer product scalar+vector shape"
(sh
(apl-outer apl-mul (apl-scalar 5) (make-array (list 3) (list 1 2 3))))
(list 3))
(apl-test
"outer product scalar+vector values"
(rv
(apl-outer apl-mul (apl-scalar 5) (make-array (list 3) (list 1 2 3))))
(list 5 10 15))
(apl-test
"outer product vector+scalar shape"
(sh
(apl-outer apl-mul (make-array (list 3) (list 1 2 3)) (apl-scalar 10)))
(list 3))
(apl-test
"outer product scalar+scalar"
(rv (apl-outer apl-mul (apl-scalar 6) (apl-scalar 7)))
(list 42))
(apl-test
"outer product scalar+scalar shape"
(sh (apl-outer apl-mul (apl-scalar 6) (apl-scalar 7)))
(list))
(apl-test
"outer product equality identity matrix values"
(rv
(apl-outer
apl-eq
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 2 3))))
(list 1 0 0 0 1 0 0 0 1))
(apl-test
"outer product matrix+vector rank doubling shape"
(sh
(apl-outer
apl-add
(make-array (list 2 2) (list 1 2 3 4))
(make-array (list 3) (list 10 20 30))))
(list 2 2 3))
(apl-test
"outer product matrix+vector rank doubling values"
(rv
(apl-outer
apl-add
(make-array (list 2 2) (list 1 2 3 4))
(make-array (list 3) (list 10 20 30))))
(list 11 21 31 12 22 32 13 23 33 14 24 34))
(apl-test
"inner +.× dot product"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 4 5 6))))
(list 32))
(apl-test
"inner +.× dot product shape is scalar"
(sh
(apl-inner
apl-add
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 4 5 6))))
(list))
(apl-test
"inner +.× matrix multiply 2x3 * 3x2 shape"
(sh
(apl-inner
apl-add
apl-mul
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3 2) (list 7 8 9 10 11 12))))
(list 2 2))
(apl-test
"inner +.× matrix multiply 2x3 * 3x2 values"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3 2) (list 7 8 9 10 11 12))))
(list 58 64 139 154))
(apl-test
"inner +.× identity matrix 2x2"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 2 2) (list 1 0 0 1))
(make-array (list 2 2) (list 5 6 7 8))))
(list 5 6 7 8))
(apl-test
"inner ∧.= equal vectors"
(rv
(apl-inner
apl-and
apl-eq
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 2 3))))
(list 1))
(apl-test
"inner ∧.= unequal vectors"
(rv
(apl-inner
apl-and
apl-eq
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 9 3))))
(list 0))
(apl-test
"inner +.× matrix * vector shape"
(sh
(apl-inner
apl-add
apl-mul
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3) (list 7 8 9))))
(list 2))
(apl-test
"inner +.× matrix * vector values"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3) (list 7 8 9))))
(list 50 122))
(apl-test
"inner +.× vector * matrix shape"
(sh
(apl-inner
apl-add
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3 2) (list 4 5 6 7 8 9))))
(list 2))
(apl-test
"inner +.× vector * matrix values"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 3) (list 1 2 3))
(make-array (list 3 2) (list 4 5 6 7 8 9))))
(list 40 46))
(apl-test
"inner +.× single-element vectors"
(rv
(apl-inner
apl-add
apl-mul
(make-array (list 1) (list 6))
(make-array (list 1) (list 7))))
(list 42))
(apl-test
"commute +⍨ scalar doubles"
(rv (apl-commute apl-add (apl-scalar 5)))
(list 10))
(apl-test
"commute ×⍨ vector squares"
(rv (apl-commute apl-mul (make-array (list 4) (list 1 2 3 4))))
(list 1 4 9 16))
(apl-test
"commute +⍨ vector doubles"
(rv (apl-commute apl-add (make-array (list 3) (list 1 2 3))))
(list 2 4 6))
(apl-test
"commute +⍨ shape preserved"
(sh (apl-commute apl-add (make-array (list 3) (list 1 2 3))))
(list 3))
(apl-test
"commute ×⍨ matrix shape preserved"
(sh (apl-commute apl-mul (make-array (list 2 2) (list 1 2 3 4))))
(list 2 2))
(apl-test
"commute-dyadic -⍨ swaps subtraction"
(rv (apl-commute-dyadic apl-sub (apl-scalar 5) (apl-scalar 3)))
(list -2))
(apl-test
"commute-dyadic ÷⍨ swaps division"
(rv (apl-commute-dyadic apl-div (apl-scalar 4) (apl-scalar 12)))
(list 3))
(apl-test
"commute-dyadic -⍨ on vectors"
(rv
(apl-commute-dyadic
apl-sub
(make-array (list 3) (list 10 20 30))
(make-array (list 3) (list 1 2 3))))
(list -9 -18 -27))
(apl-test
"commute-dyadic +⍨ commutative same result"
(rv
(apl-commute-dyadic
apl-add
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 10 20 30))))
(list 11 22 33))
(apl-test
"commute-dyadic ×⍨ commutative same result"
(rv
(apl-commute-dyadic
apl-mul
(make-array (list 3) (list 2 3 4))
(make-array (list 3) (list 5 6 7))))
(list 10 18 28))
(apl-test
"compose -∘| scalar (negative abs)"
(rv (apl-compose apl-neg-m apl-abs (apl-scalar -7)))
(list -7))
(apl-test
"compose -∘| vector"
(rv
(apl-compose apl-neg-m apl-abs (make-array (list 4) (list -1 2 -3 4))))
(list -1 -2 -3 -4))
(apl-test
"compose ⌊∘- (floor of negate)"
(rv (apl-compose apl-floor apl-neg-m (make-array (list 3) (list 1 2 3))))
(list -1 -2 -3))
(apl-test
"compose -∘| matrix shape preserved"
(sh
(apl-compose apl-neg-m apl-abs (make-array (list 2 2) (list -1 2 -3 4))))
(list 2 2))
(apl-test
"compose-dyadic +∘- equals subtract scalar"
(rv (apl-compose-dyadic apl-add apl-neg-m (apl-scalar 10) (apl-scalar 3)))
(list 7))
(apl-test
"compose-dyadic +∘- equals subtract vector"
(rv
(apl-compose-dyadic
apl-add
apl-neg-m
(make-array (list 3) (list 10 20 30))
(make-array (list 3) (list 1 2 3))))
(list 9 18 27))
(apl-test
"compose-dyadic -∘| (subtract abs)"
(rv (apl-compose-dyadic apl-sub apl-abs (apl-scalar 10) (apl-scalar -3)))
(list 7))
(apl-test
"compose-dyadic ×∘- (multiply by negative)"
(rv
(apl-compose-dyadic
apl-mul
apl-neg-m
(make-array (list 3) (list 2 3 4))
(make-array (list 3) (list 1 2 3))))
(list -2 -6 -12))
(apl-test
"compose-dyadic shape preserved"
(sh
(apl-compose-dyadic
apl-add
apl-neg-m
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 2 3) (list 1 1 1 1 1 1))))
(list 2 3))
(apl-test
"power n=0 identity"
(rv (apl-power (fn (a) (apl-add a (apl-scalar 1))) 0 (apl-scalar 5)))
(list 5))
(apl-test
"power increment by 3"
(rv (apl-power (fn (a) (apl-add a (apl-scalar 1))) 3 (apl-scalar 0)))
(list 3))
(apl-test
"power double 4 times = 16"
(rv (apl-power (fn (a) (apl-mul a (apl-scalar 2))) 4 (apl-scalar 1)))
(list 16))
(apl-test
"power on vector +5"
(rv
(apl-power
(fn (a) (apl-add a (apl-scalar 1)))
5
(make-array (list 3) (list 1 2 3))))
(list 6 7 8))
(apl-test
"power on vector preserves shape"
(sh
(apl-power
(fn (a) (apl-add a (apl-scalar 1)))
5
(make-array (list 3) (list 1 2 3))))
(list 3))
(apl-test
"power on matrix"
(rv
(apl-power
(fn (a) (apl-mul a (apl-scalar 3)))
2
(make-array (list 2 2) (list 1 2 3 4))))
(list 9 18 27 36))
(apl-test
"power-fixed identity stops immediately"
(rv (apl-power-fixed (fn (a) a) (make-array (list 3) (list 1 2 3))))
(list 1 2 3))
(apl-test
"power-fixed floor half scalar to 0"
(rv
(apl-power-fixed
(fn (a) (apl-floor (apl-div a (apl-scalar 2))))
(apl-scalar 100)))
(list 0))
(apl-test
"power-fixed shape preserved"
(sh
(apl-power-fixed (fn (a) a) (make-array (list 2 2) (list 1 2 3 4))))
(list 2 2))
(apl-test
"rank tally⍤1 row tallies"
(rv (apl-rank apl-tally 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3 3))
(apl-test
"rank tally⍤1 row tallies shape"
(sh (apl-rank apl-tally 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2))
(apl-test
"rank neg⍤0 vector scalar cells"
(rv (apl-rank apl-neg-m 0 (make-array (list 3) (list 1 2 3))))
(list -1 -2 -3))
(apl-test
"rank neg⍤0 vector preserves shape"
(sh (apl-rank apl-neg-m 0 (make-array (list 3) (list 1 2 3))))
(list 3))
(apl-test
"rank neg⍤1 matrix per-row"
(rv (apl-rank apl-neg-m 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list -1 -2 -3 -4 -5 -6))
(apl-test
"rank neg⍤1 matrix preserves shape"
(sh (apl-rank apl-neg-m 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"rank k>=rank fallthrough"
(rv (apl-rank apl-tally 5 (make-array (list 4) (list 1 2 3 4))))
(list 4))
(apl-test
"rank tally⍤2 whole matrix tally"
(rv
(apl-rank
apl-tally
2
(make-array (list 3 5) (list 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15))))
(list 3))
(apl-test
"rank reverse⍤1 matrix reverse rows"
(rv (apl-rank apl-reverse 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3 2 1 6 5 4))
(apl-test
"rank tally⍤1 3x4 row tallies"
(rv
(apl-rank
apl-tally
1
(make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
(list 4 4 4))
(apl-test
"at-replace single index"
(rv
(apl-at-replace
(apl-scalar 99)
(make-array (list 1) (list 2))
(make-array (list 5) (list 1 2 3 4 5))))
(list 1 99 3 4 5))
(apl-test
"at-replace multiple indices vector vals"
(rv
(apl-at-replace
(make-array (list 2) (list 99 88))
(make-array (list 2) (list 2 4))
(make-array (list 5) (list 1 2 3 4 5))))
(list 1 99 3 88 5))
(apl-test
"at-replace scalar broadcast"
(rv
(apl-at-replace
(apl-scalar 0)
(make-array (list 3) (list 1 3 5))
(make-array (list 5) (list 10 20 30 40 50))))
(list 0 20 0 40 0))
(apl-test
"at-replace preserves shape"
(sh
(apl-at-replace
(apl-scalar 99)
(make-array (list 1) (list 2))
(make-array (list 5) (list 1 2 3 4 5))))
(list 5))
(apl-test
"at-replace last index"
(rv
(apl-at-replace
(apl-scalar 99)
(make-array (list 1) (list 5))
(make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3 4 99))
(apl-test
"at-replace on matrix linear-index"
(rv
(apl-at-replace
(apl-scalar 99)
(make-array (list 1) (list 3))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 99 4 5 6))
(apl-test
"at-apply negate at indices"
(rv
(apl-at-apply
apl-neg-m
(make-array (list 3) (list 1 3 5))
(make-array (list 5) (list 1 2 3 4 5))))
(list -1 2 -3 4 -5))
(apl-test
"at-apply double at index 1"
(rv
(apl-at-apply
(fn (a) (apl-mul a (apl-scalar 2)))
(make-array (list 1) (list 1))
(make-array (list 2) (list 5 10))))
(list 10 10))
(apl-test
"at-apply preserves shape"
(sh
(apl-at-apply
apl-neg-m
(make-array (list 2) (list 1 3))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"at-apply on matrix linear-index"
(rv
(apl-at-apply
apl-neg-m
(make-array (list 2) (list 1 6))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list -1 2 3 4 5 -6))

340
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@@ -1,340 +0,0 @@
(define apl-test-count 0)
(define apl-test-pass 0)
(define apl-test-fails (list))
(define apl-test
(fn (name actual expected)
(begin
(set! apl-test-count (+ apl-test-count 1))
(if (= actual expected)
(set! apl-test-pass (+ apl-test-pass 1))
(append! apl-test-fails {:name name :actual actual :expected expected})))))
(define tok-types
(fn (src)
(map (fn (t) (get t :type)) (apl-tokenize src))))
(define tok-values
(fn (src)
(map (fn (t) (get t :value)) (apl-tokenize src))))
(define tok-count
(fn (src)
(len (apl-tokenize src))))
(define tok-type-at
(fn (src i)
(get (nth (apl-tokenize src) i) :type)))
(define tok-value-at
(fn (src i)
(get (nth (apl-tokenize src) i) :value)))
(apl-test "empty: no tokens" (tok-count "") 0)
(apl-test "empty: whitespace only" (tok-count " ") 0)
(apl-test "num: zero" (tok-values "0") (list 0))
(apl-test "num: positive" (tok-values "42") (list 42))
(apl-test "num: large" (tok-values "12345") (list 12345))
(apl-test "num: negative" (tok-values "¯5") (list -5))
(apl-test "num: negative zero" (tok-values "¯0") (list 0))
(apl-test "num: strand count" (tok-count "1 2 3") 3)
(apl-test "num: strand types" (tok-types "1 2 3") (list :num :num :num))
(apl-test "num: strand values" (tok-values "1 2 3") (list 1 2 3))
(apl-test "num: neg in strand" (tok-values "1 ¯2 3") (list 1 -2 3))
(apl-test "str: empty" (tok-values "''") (list ""))
(apl-test "str: single char" (tok-values "'a'") (list "a"))
(apl-test "str: word" (tok-values "'hello'") (list "hello"))
(apl-test "str: escaped quote" (tok-values "''''") (list "'"))
(apl-test "str: type" (tok-types "'abc'") (list :str))
(apl-test "name: simple" (tok-values "foo") (list "foo"))
(apl-test "name: type" (tok-types "foo") (list :name))
(apl-test "name: mixed case" (tok-values "MyVar") (list "MyVar"))
(apl-test "name: with digits" (tok-values "x1") (list "x1"))
(apl-test "name: system var" (tok-values "⎕IO") (list "⎕IO"))
(apl-test "name: system var type" (tok-types "⎕IO") (list :name))
(apl-test "glyph: plus" (tok-types "+") (list :glyph))
(apl-test "glyph: plus value" (tok-values "+") (list "+"))
(apl-test "glyph: iota" (tok-values "") (list ""))
(apl-test "glyph: reduce" (tok-values "+/") (list "+" "/"))
(apl-test "glyph: floor" (tok-values "⌊") (list "⌊"))
(apl-test "glyph: rho" (tok-values "") (list ""))
(apl-test "glyph: alpha omega" (tok-types " ⍵") (list :glyph :glyph))
(apl-test "punct: lparen" (tok-types "(") (list :lparen))
(apl-test "punct: rparen" (tok-types ")") (list :rparen))
(apl-test "punct: brackets" (tok-types "[42]") (list :lbracket :num :rbracket))
(apl-test "punct: braces" (tok-types "{}") (list :lbrace :rbrace))
(apl-test "punct: semi" (tok-types ";") (list :semi))
(apl-test "assign: arrow" (tok-types "x←1") (list :name :assign :num))
(apl-test "diamond: separator" (tok-types "1⋄2") (list :num :diamond :num))
(apl-test "newline: emitted" (tok-types "1\n2") (list :num :newline :num))
(apl-test "comment: skipped" (tok-count "⍝ ignore me") 0)
(apl-test "comment: rest ignored" (tok-count "1 ⍝ note") 1)
(apl-test "colon: bare" (tok-types ":") (list :colon))
(apl-test "keyword: If" (tok-values ":If") (list ":If"))
(apl-test "keyword: type" (tok-types ":While") (list :keyword))
(apl-test "keyword: EndFor" (tok-values ":EndFor") (list ":EndFor"))
(apl-test "expr: +/ 5" (tok-types "+/ 5") (list :glyph :glyph :glyph :num))
(apl-test "expr: x←42" (tok-count "x←42") 3)
(apl-test "expr: dfn body" (tok-types "{+⍵}")
(list :lbrace :glyph :glyph :glyph :rbrace))
(define apl-tokenize-test-summary
(str "tokenizer " apl-test-pass "/" apl-test-count
(if (= (len apl-test-fails) 0) "" (str " FAILS: " apl-test-fails))))
; ===========================================================================
; Parser tests
; ===========================================================================
; Helper: parse an APL source string and return the AST
(define parse
(fn (src) (parse-apl src)))
; Helper: build an expected AST node using keyword-tagged lists
(define num-node (fn (n) (list :num n)))
(define str-node (fn (s) (list :str s)))
(define name-node (fn (n) (list :name n)))
(define fn-node (fn (g) (list :fn-glyph g)))
(define fn-nm (fn (n) (list :fn-name n)))
(define assign-node (fn (nm expr) (list :assign nm expr)))
(define monad-node (fn (f a) (list :monad f a)))
(define dyad-node (fn (f l r) (list :dyad f l r)))
(define derived-fn (fn (op f) (list :derived-fn op f)))
(define derived-fn2 (fn (op f g) (list :derived-fn2 op f g)))
(define outer-node (fn (f) (list :outer "∘." f)))
(define guard-node (fn (c e) (list :guard c e)))
; ---- numeric literals ----
(apl-test "parse: num literal"
(parse "42")
(num-node 42))
(apl-test "parse: negative num"
(parse "¯3")
(num-node -3))
(apl-test "parse: zero"
(parse "0")
(num-node 0))
; ---- string literals ----
(apl-test "parse: str literal"
(parse "'hello'")
(str-node "hello"))
(apl-test "parse: empty str"
(parse "''")
(str-node ""))
; ---- name reference ----
(apl-test "parse: name"
(parse "x")
(name-node "x"))
(apl-test "parse: system name"
(parse "⎕IO")
(name-node "⎕IO"))
; ---- strands (vec nodes) ----
(apl-test "parse: strand 3 nums"
(parse "1 2 3")
(list :vec (num-node 1) (num-node 2) (num-node 3)))
(apl-test "parse: strand 2 nums"
(parse "1 2")
(list :vec (num-node 1) (num-node 2)))
(apl-test "parse: strand with negatives"
(parse "1 ¯2 3")
(list :vec (num-node 1) (num-node -2) (num-node 3)))
; ---- assignment ----
(apl-test "parse: assignment"
(parse "x←42")
(assign-node "x" (num-node 42)))
(apl-test "parse: assignment with spaces"
(parse "x ← 42")
(assign-node "x" (num-node 42)))
(apl-test "parse: assignment of expr"
(parse "r←2+3")
(assign-node "r" (dyad-node (fn-node "+") (num-node 2) (num-node 3))))
; ---- monadic functions ----
(apl-test "parse: monadic iota"
(parse "5")
(monad-node (fn-node "") (num-node 5)))
(apl-test "parse: monadic iota with space"
(parse " 5")
(monad-node (fn-node "") (num-node 5)))
(apl-test "parse: monadic negate"
(parse "-3")
(monad-node (fn-node "-") (num-node 3)))
(apl-test "parse: monadic floor"
(parse "⌊2")
(monad-node (fn-node "⌊") (num-node 2)))
(apl-test "parse: monadic of name"
(parse "x")
(monad-node (fn-node "") (name-node "x")))
; ---- dyadic functions ----
(apl-test "parse: dyadic plus"
(parse "2+3")
(dyad-node (fn-node "+") (num-node 2) (num-node 3)))
(apl-test "parse: dyadic times"
(parse "2×3")
(dyad-node (fn-node "×") (num-node 2) (num-node 3)))
(apl-test "parse: dyadic with names"
(parse "x+y")
(dyad-node (fn-node "+") (name-node "x") (name-node "y")))
; ---- right-to-left evaluation ----
(apl-test "parse: right-to-left 2×3+4"
(parse "2×3+4")
(dyad-node (fn-node "×") (num-node 2)
(dyad-node (fn-node "+") (num-node 3) (num-node 4))))
(apl-test "parse: right-to-left chain"
(parse "1+2×3-4")
(dyad-node (fn-node "+") (num-node 1)
(dyad-node (fn-node "×") (num-node 2)
(dyad-node (fn-node "-") (num-node 3) (num-node 4)))))
; ---- parenthesized subexpressions ----
(apl-test "parse: parens override order"
(parse "(2+3)×4")
(dyad-node (fn-node "×")
(dyad-node (fn-node "+") (num-node 2) (num-node 3))
(num-node 4)))
(apl-test "parse: nested parens"
(parse "((2+3))")
(dyad-node (fn-node "+") (num-node 2) (num-node 3)))
(apl-test "parse: paren in dyadic right"
(parse "2×(3+4)")
(dyad-node (fn-node "×") (num-node 2)
(dyad-node (fn-node "+") (num-node 3) (num-node 4))))
; ---- operators → derived functions ----
(apl-test "parse: reduce +"
(parse "+/x")
(monad-node (derived-fn "/" (fn-node "+")) (name-node "x")))
(apl-test "parse: reduce iota"
(parse "+/5")
(monad-node (derived-fn "/" (fn-node "+"))
(monad-node (fn-node "") (num-node 5))))
(apl-test "parse: scan"
(parse "+\\x")
(monad-node (derived-fn "\\" (fn-node "+")) (name-node "x")))
(apl-test "parse: each"
(parse "¨x")
(monad-node (derived-fn "¨" (fn-node "")) (name-node "x")))
(apl-test "parse: commute"
(parse "-⍨3")
(monad-node (derived-fn "⍨" (fn-node "-")) (num-node 3)))
(apl-test "parse: stacked ops"
(parse "+/¨x")
(monad-node (derived-fn "¨" (derived-fn "/" (fn-node "+"))) (name-node "x")))
; ---- outer product ----
(apl-test "parse: outer product monadic"
(parse "∘.×")
(outer-node (fn-node "×")))
(apl-test "parse: outer product dyadic names"
(parse "x ∘.× y")
(dyad-node (outer-node (fn-node "×")) (name-node "x") (name-node "y")))
(apl-test "parse: outer product dyadic strands"
(parse "1 2 3 ∘.× 4 5 6")
(dyad-node (outer-node (fn-node "×"))
(list :vec (num-node 1) (num-node 2) (num-node 3))
(list :vec (num-node 4) (num-node 5) (num-node 6))))
; ---- inner product ----
(apl-test "parse: inner product"
(parse "+.×")
(derived-fn2 "." (fn-node "+") (fn-node "×")))
(apl-test "parse: inner product applied"
(parse "a +.× b")
(dyad-node (derived-fn2 "." (fn-node "+") (fn-node "×"))
(name-node "a") (name-node "b")))
; ---- dfn (anonymous function) ----
(apl-test "parse: simple dfn"
(parse "{+⍵}")
(list :dfn (dyad-node (fn-node "+") (name-node "") (name-node "⍵"))))
(apl-test "parse: monadic dfn"
(parse "{⍵×2}")
(list :dfn (dyad-node (fn-node "×") (name-node "⍵") (num-node 2))))
(apl-test "parse: dfn self-ref"
(parse "{⍵≤1:1 ⋄ ⍵×∇ ⍵-1}")
(list :dfn
(guard-node (dyad-node (fn-node "≤") (name-node "⍵") (num-node 1)) (num-node 1))
(dyad-node (fn-node "×") (name-node "⍵")
(monad-node (fn-node "∇") (dyad-node (fn-node "-") (name-node "⍵") (num-node 1))))))
; ---- dfn applied ----
(apl-test "parse: dfn as function"
(parse "{+⍵} 3")
(monad-node
(list :dfn (dyad-node (fn-node "+") (name-node "") (name-node "⍵")))
(num-node 3)))
; ---- multi-statement ----
(apl-test "parse: diamond separator"
(let ((result (parse "x←1 ⋄ x+2")))
(= (first result) :program))
true)
(apl-test "parse: diamond first stmt"
(let ((result (parse "x←1 ⋄ x+2")))
(nth result 1))
(assign-node "x" (num-node 1)))
(apl-test "parse: diamond second stmt"
(let ((result (parse "x←1 ⋄ x+2")))
(nth result 2))
(dyad-node (fn-node "+") (name-node "x") (num-node 2)))
; ---- combined summary ----
(define apl-parse-test-count (- apl-test-count 46))
(define apl-parse-test-pass (- apl-test-pass 46))
(define apl-test-summary
(str
"tokenizer 46/46 | "
"parser " apl-parse-test-pass "/" apl-parse-test-count
(if (= (len apl-test-fails) 0) "" (str " FAILS: " apl-test-fails))))

687
lib/apl/tests/pipeline.sx
View File

@@ -1,687 +0,0 @@
; End-to-end pipeline tests: source string → tokenize → parse → eval-ast → array.
; Verifies the full stack as a single function call (apl-run).
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
; ---------- scalars ----------
(apl-test "apl-run \"42\" → scalar 42" (mkrv (apl-run "42")) (list 42))
(apl-test "apl-run \"¯7\" → scalar -7" (mkrv (apl-run "¯7")) (list -7))
; ---------- strands ----------
(apl-test
"apl-run \"1 2 3\" → vector"
(mkrv (apl-run "1 2 3"))
(list 1 2 3))
(apl-test "apl-run \"1 2 3\" shape" (mksh (apl-run "1 2 3")) (list 3))
; ---------- dyadic arithmetic ----------
(apl-test "apl-run \"2 + 3\" → 5" (mkrv (apl-run "2 + 3")) (list 5))
(apl-run "2 × 3 + 4") ; right-to-left
(apl-test
"apl-run \"2 × 3 + 4\" → 14 (right-to-left)"
(mkrv (apl-run "2 × 3 + 4"))
(list 14))
(apl-test
"apl-run \"1 2 3 + 4 5 6\" → 5 7 9"
(mkrv (apl-run "1 2 3 + 4 5 6"))
(list 5 7 9))
(apl-test
"apl-run \"3 × 1 2 3 4\" → scalar broadcast"
(mkrv (apl-run "3 × 1 2 3 4"))
(list 3 6 9 12))
; ---------- monadic primitives ----------
(apl-test
"apl-run \"5\" → 1..5"
(mkrv (apl-run "5"))
(list 1 2 3 4 5))
(apl-test
"apl-run \"-3\" → -3 (monadic negate)"
(mkrv (apl-run "-3"))
(list -3))
(apl-test
"apl-run \"⌈/ 1 3 9 5 7\" → 9 (max-reduce)"
(mkrv (apl-run "⌈/ 1 3 9 5 7"))
(list 9))
(apl-test
"apl-run \"⌊/ 4 7 2 9 1 3\" → 1 (min-reduce)"
(mkrv (apl-run "⌊/ 4 7 2 9 1 3"))
(list 1))
; ---------- operators ----------
(apl-test "apl-run \"+/5\" → 15" (mkrv (apl-run "+/5")) (list 15))
(apl-test "apl-run \"×/5\" → 120" (mkrv (apl-run "×/5")) (list 120))
(apl-test
"apl-run \"⌈/3 1 4 1 5 9 2\" → 9"
(mkrv (apl-run "⌈/3 1 4 1 5 9 2"))
(list 9))
(apl-test
"apl-run \"+\\\\5\" → triangular numbers"
(mkrv (apl-run "+\\5"))
(list 1 3 6 10 15))
; ---------- outer / inner products ----------
(apl-test
"apl-run \"1 2 3 ∘.× 1 2 3\" → mult table values"
(mkrv (apl-run "1 2 3 ∘.× 1 2 3"))
(list 1 2 3 2 4 6 3 6 9))
(apl-test
"apl-run \"1 2 3 +.× 4 5 6\" → dot product 32"
(mkrv (apl-run "1 2 3 +.× 4 5 6"))
(list 32))
; ---------- shape ----------
(apl-test
"apl-run \" 1 2 3 4 5\" → 5"
(mkrv (apl-run " 1 2 3 4 5"))
(list 5))
(apl-test "apl-run \"10\" → 10" (mkrv (apl-run "10")) (list 10))
; ---------- comparison ----------
(apl-test "apl-run \"3 < 5\" → 1" (mkrv (apl-run "3 < 5")) (list 1))
(apl-test "apl-run \"5 = 5\" → 1" (mkrv (apl-run "5 = 5")) (list 1))
(apl-test
"apl-run \"1 2 3 = 1 0 3\" → 1 0 1"
(mkrv (apl-run "1 2 3 = 1 0 3"))
(list 1 0 1))
; ---------- famous one-liners ----------
(apl-test
"apl-run \"+/(10)\" → sum 1..10 = 55"
(mkrv (apl-run "+/(10)"))
(list 55))
(apl-test
"apl-run \"×/10\" → 10! = 3628800"
(mkrv (apl-run "×/10"))
(list 3628800))
(apl-test "apl-run \"⎕IO\" → 1" (mkrv (apl-run "⎕IO")) (list 1))
(apl-test "apl-run \"⎕ML\" → 1" (mkrv (apl-run "⎕ML")) (list 1))
(apl-test "apl-run \"⎕FR\" → 1248" (mkrv (apl-run "⎕FR")) (list 1248))
(apl-test "apl-run \"⎕TS\" shape (7)" (mksh (apl-run "⎕TS")) (list 7))
(apl-test "apl-run \"⎕FMT 42\" → \"42\"" (apl-run "⎕FMT 42") "42")
(apl-test
"apl-run \"⎕FMT 1 2 3\" → \"1 2 3\""
(apl-run "⎕FMT 1 2 3")
"1 2 3")
(apl-test
"apl-run \"⎕FMT 5\" → \"1 2 3 4 5\""
(apl-run "⎕FMT 5")
"1 2 3 4 5")
(apl-test "apl-run \"⎕IO + 4\" → 5" (mkrv (apl-run "⎕IO + 4")) (list 5))
(apl-test
"apl-run \"(10 20 30 40 50)[3]\" → 30"
(mkrv (apl-run "(10 20 30 40 50)[3]"))
(list 30))
(apl-test
"apl-run \"(10)[5]\" → 5"
(mkrv (apl-run "(10)[5]"))
(list 5))
(apl-test
"apl-run \"A ← 100 200 300 ⋄ A[2]\" → 200"
(mkrv (apl-run "A ← 100 200 300 ⋄ A[2]"))
(list 200))
(apl-test
"apl-run \"V ← 10 ⋄ V[3]\" → 3"
(mkrv (apl-run "V ← 10 ⋄ V[3]"))
(list 3))
(apl-test
"apl-run \"(10 20 30)[1]\" → 10 (1-indexed)"
(mkrv (apl-run "(10 20 30)[1]"))
(list 10))
(apl-test
"apl-run \"V ← 10 20 30 40 50 ⋄ V[3] + 1\" → 31"
(mkrv (apl-run "V ← 10 20 30 40 50 ⋄ V[3] + 1"))
(list 31))
(apl-test
"apl-run \"(5)[3] × 7\" → 21"
(mkrv (apl-run "(5)[3] × 7"))
(list 21))
(apl-test "decimal: 3.7 → 3.7" (mkrv (apl-run "3.7")) (list 3.7))
(apl-test "decimal: ¯2.5 → -2.5" (mkrv (apl-run "¯2.5")) (list -2.5))
(apl-test "decimal: 1.5 + 2.5 → 4" (mkrv (apl-run "1.5 + 2.5")) (list 4))
(apl-test "decimal: ⌊3.7 → 3" (mkrv (apl-run "⌊ 3.7")) (list 3))
(apl-test "decimal: ⌈3.7 → 4" (mkrv (apl-run "⌈ 3.7")) (list 4))
(apl-test
"⎕← scalar passthrough"
(mkrv (apl-run "⎕← 42"))
(list 42))
(apl-test
"⎕← vector passthrough"
(mkrv (apl-run "⎕← 1 2 3"))
(list 1 2 3))
(apl-test
"string: 'abc' → 3-char vector"
(mkrv (apl-run "'abc'"))
(list "a" "b" "c"))
(apl-test "string: 'a' is rank-0 scalar" (mksh (apl-run "'a'")) (list))
(apl-test "string: 'hello' shape (5)" (mksh (apl-run "'hello'")) (list 5))
(apl-test
"named-fn: f ← {+⍵} ⋄ 3 f 4 → 7"
(mkrv (apl-run "f ← {+⍵} ⋄ 3 f 4"))
(list 7))
(apl-test
"named-fn monadic: sq ← {⍵×⍵} ⋄ sq 7 → 49"
(mkrv (apl-run "sq ← {⍵×⍵} ⋄ sq 7"))
(list 49))
(apl-test
"named-fn dyadic: hyp ← {((×)+⍵×⍵)} ⋄ 3 hyp 4 → 25"
(mkrv (apl-run "hyp ← {((×)+⍵×⍵)} ⋄ 3 hyp 4"))
(list 25))
(apl-test
"named-fn: dbl ← {⍵+⍵} ⋄ dbl 5"
(mkrv (apl-run "dbl ← {⍵+⍵} ⋄ dbl 5"))
(list 2 4 6 8 10))
(apl-test
"named-fn factorial via ∇ recursion"
(mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 5"))
(list 120))
(apl-test
"named-fn used twice in expr: dbl ← {⍵+⍵} ⋄ (dbl 3) + dbl 4"
(mkrv (apl-run "dbl ← {⍵+⍵} ⋄ (dbl 3) + dbl 4"))
(list 14))
(apl-test
"named-fn with vector arg: neg ← {-⍵} ⋄ neg 1 2 3"
(mkrv (apl-run "neg ← {-⍵} ⋄ neg 1 2 3"))
(list -1 -2 -3))
(apl-test
"multi-axis: M[2;2] → center"
(mkrv (apl-run "M ← (3 3) 9 ⋄ M[2;2]"))
(list 5))
(apl-test
"multi-axis: M[1;] → first row"
(mkrv (apl-run "M ← (3 3) 9 ⋄ M[1;]"))
(list 1 2 3))
(apl-test
"multi-axis: M[;2] → second column"
(mkrv (apl-run "M ← (3 3) 9 ⋄ M[;2]"))
(list 2 5 8))
(apl-test
"multi-axis: M[1 2;1 2] → 2x2 block"
(mkrv (apl-run "M ← (2 3) 6 ⋄ M[1 2;1 2]"))
(list 1 2 4 5))
(apl-test
"multi-axis: M[1 2;1 2] shape (2 2)"
(mksh (apl-run "M ← (2 3) 6 ⋄ M[1 2;1 2]"))
(list 2 2))
(apl-test
"multi-axis: M[;] full matrix"
(mkrv (apl-run "M ← (2 2) 10 20 30 40 ⋄ M[;]"))
(list 10 20 30 40))
(apl-test
"multi-axis: M[1;] shape collapsed"
(mksh (apl-run "M ← (3 3) 9 ⋄ M[1;]"))
(list 3))
(apl-test
"multi-axis: select all rows of column 3"
(mkrv (apl-run "M ← (4 3) 1 2 3 4 5 6 7 8 9 10 11 12 ⋄ M[;3]"))
(list 3 6 9 12))
(apl-test
"train: mean = (+/÷≢) on 1..5"
(mkrv (apl-run "(+/÷≢) 1 2 3 4 5"))
(list 3))
(apl-test
"train: mean of 2 4 6 8 10"
(mkrv (apl-run "(+/÷≢) 2 4 6 8 10"))
(list 6))
(apl-test
"train 2-atop: (- ⌊) 5 → -5"
(mkrv (apl-run "(- ⌊) 5"))
(list -5))
(apl-test
"train 3-fork dyadic: 2(+×-)5 → -21"
(mkrv (apl-run "2 (+ × -) 5"))
(list -21))
(apl-test
"train: range = (⌈/-⌊/) on vector"
(mkrv (apl-run "(⌈/-⌊/) 3 1 4 1 5 9 2 6"))
(list 8))
(apl-test
"train: mean of 10 has shape ()"
(mksh (apl-run "(+/÷≢) 10"))
(list))
(apl-test
"compress: 1 0 1 0 1 / 10 20 30 40 50"
(mkrv (apl-run "1 0 1 0 1 / 10 20 30 40 50"))
(list 10 30 50))
(apl-test
"compress: empty mask → empty"
(mkrv (apl-run "0 0 0 / 1 2 3"))
(list))
(apl-test
"primes via classic idiom (multi-stmt)"
(mkrv (apl-run "P ← 30 ⋄ (2 = +⌿ 0 = P ∘.| P) / P"))
(list 2 3 5 7 11 13 17 19 23 29))
(apl-test
"primes via classic idiom (n=20)"
(mkrv (apl-run "P ← 20 ⋄ (2 = +⌿ 0 = P ∘.| P) / P"))
(list 2 3 5 7 11 13 17 19))
(apl-test
"compress: filter even values"
(mkrv (apl-run "(0 = 2 | 1 2 3 4 5 6) / 1 2 3 4 5 6"))
(list 2 4 6))
(apl-test "inline-assign: x ← 5" (mkrv (apl-run "x ← 5")) (list 5))
(apl-test
"inline-assign: (2×x) + x←10 → 30"
(mkrv (apl-run "(2 × x) + x ← 10"))
(list 30))
(apl-test
"inline-assign primes one-liner: (2=+⌿0=a∘.|a)/a←30"
(mkrv (apl-run "(2 = +⌿ 0 = a ∘.| a) / a ← 30"))
(list 2 3 5 7 11 13 17 19 23 29))
(apl-test
"inline-assign: x is reusable — x + x ← 7 → 14"
(mkrv (apl-run "x + x ← 7"))
(list 14))
(apl-test
"inline-assign in dfn: f ← {x + x ← ⍵} ⋄ f 8 → 16"
(mkrv (apl-run "f ← {x + x ← ⍵} ⋄ f 8"))
(list 16))
(begin (apl-rng-seed! 42) nil)
(apl-test
"?10 with seed 42 → 8 (deterministic)"
(mkrv (apl-run "?10"))
(list 8))
(apl-test "?10 next call → 5" (mkrv (apl-run "?10")) (list 5))
(apl-test
"?100 stays in range"
(let ((v (first (mkrv (apl-run "?100"))))) (and (>= v 1) (<= v 100)))
true)
(begin (apl-rng-seed! 42) nil)
(apl-test
"?10 with re-seed 42 → 8 (reproducible)"
(mkrv (apl-run "?10"))
(list 8))
(apl-test
"apl-run-file: load primes.apl returns dfn AST"
(first (apl-run-file "lib/apl/tests/programs/primes.apl"))
:dfn)
(apl-test
"apl-run-file: life.apl parses without error"
(first (apl-run-file "lib/apl/tests/programs/life.apl"))
:dfn)
(apl-test
"apl-run-file: quicksort.apl parses without error"
(first (apl-run-file "lib/apl/tests/programs/quicksort.apl"))
:dfn)
(apl-test
"apl-run-file: source-then-call returns primes count"
(mksh
(apl-run
(str (file-read "lib/apl/tests/programs/primes.apl") " ⋄ primes 30")))
(list 10))
(apl-test
"primes one-liner with ⍵-rebind: primes 30"
(mkrv
(apl-run "primes ← {(2=+⌿0=⍵∘.|⍵)/⍵←⍳⍵} ⋄ primes 30"))
(list 2 3 5 7 11 13 17 19 23 29))
(apl-test
"primes one-liner: primes 50"
(mkrv
(apl-run "primes ← {(2=+⌿0=⍵∘.|⍵)/⍵←⍳⍵} ⋄ primes 50"))
(list 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47))
(apl-test
"primes.apl loaded + called via apl-run-file"
(mkrv
(apl-run
(str (file-read "lib/apl/tests/programs/primes.apl") " ⋄ primes 20")))
(list 2 3 5 7 11 13 17 19))
(apl-test
"primes.apl loaded — count of primes ≤ 100"
(first
(mksh
(apl-run
(str
(file-read "lib/apl/tests/programs/primes.apl")
" ⋄ primes 100"))))
25)
(apl-test
"⍉ monadic transpose 2x3 → 3x2"
(mkrv (apl-run "⍉ (2 3) 6"))
(list 1 4 2 5 3 6))
(apl-test
"⍉ transpose shape (3 2)"
(mksh (apl-run "⍉ (2 3) 6"))
(list 3 2))
(apl-test "⊢ monadic identity" (mkrv (apl-run "⊢ 1 2 3")) (list 1 2 3))
(apl-test
"5 ⊣ 1 2 3 → 5 (left)"
(mkrv (apl-run "5 ⊣ 1 2 3"))
(list 5))
(apl-test
"5 ⊢ 1 2 3 → 1 2 3 (right)"
(mkrv (apl-run "5 ⊢ 1 2 3"))
(list 1 2 3))
(apl-test "⍕ 42 → \"42\" (alias for ⎕FMT)" (apl-run "⍕ 42") "42")
(begin
(apl-test
"⍸ where: indices of truthy cells"
(mkrv (apl-run "⍸ 0 1 0 1 1"))
(list 2 4 5))
(apl-test
"⍸ where: leading truthy"
(mkrv (apl-run "⍸ 1 0 0 1 1"))
(list 1 4 5))
(apl-test
"⍸ where: all-zero → empty"
(mkrv (apl-run "⍸ 0 0 0"))
(list))
(apl-test
"⍸ where: all-truthy"
(mkrv (apl-run "⍸ 1 1 1"))
(list 1 2 3))
(apl-test
"⍸ where: ⎕IO=1 (1-based)"
(mkrv (apl-run "⍸ (5)=3"))
(list 3))
(apl-test
"⍸ interval-index: 2 4 6 ⍸ 5 → 2"
(mkrv (apl-run "2 4 6 ⍸ 5"))
(list 2))
(apl-test
"⍸ interval-index: 2 4 6 ⍸ 1 3 5 6 7 → 0 1 2 3 3"
(mkrv (apl-run "2 4 6 ⍸ 1 3 5 6 7"))
(list 0 1 2 3 3))
(apl-test
"⍸ interval-index: 5 ⍸ 3 → 3"
(mkrv (apl-run "(5) ⍸ 3"))
(list 3))
(apl-test
"⍸ interval-index: y below all → 0"
(mkrv (apl-run "10 20 30 ⍸ 5"))
(list 0))
(apl-test
"⍸ interval-index: y above all → len breaks"
(mkrv (apl-run "10 20 30 ⍸ 100"))
(list 3)))
(begin
(apl-test
" unique: dedup keeps first-occurrence order"
(mkrv (apl-run " 1 2 1 3 2 1 4"))
(list 1 2 3 4))
(apl-test
" unique: already-unique unchanged"
(mkrv (apl-run " 5 4 3 2 1"))
(list 5 4 3 2 1))
(apl-test " unique: scalar" (mkrv (apl-run " 7")) (list 7))
(apl-test
" unique: string mississippi → misp"
(mkrv (apl-run " 'mississippi'"))
(list "m" "i" "s" "p"))
(apl-test
" union: 1 2 3 3 4 5 → 1 2 3 4 5"
(mkrv (apl-run "1 2 3 3 4 5"))
(list 1 2 3 4 5))
(apl-test
" union: dedups left side too"
(mkrv (apl-run "1 2 1 1 3 2"))
(list 1 2 3))
(apl-test
" union: disjoint → catenated"
(mkrv (apl-run "1 2 3 4"))
(list 1 2 3 4))
(apl-test
"∩ intersection: 1 2 3 4 ∩ 2 4 6 → 2 4"
(mkrv (apl-run "1 2 3 4 ∩ 2 4 6"))
(list 2 4))
(apl-test
"∩ intersection: disjoint → empty"
(mkrv (apl-run "1 2 3 ∩ 4 5 6"))
(list))
(apl-test
"∩ intersection: preserves left order"
(mkrv (apl-run "(5) ∩ 5 3 1"))
(list 1 3 5))
(apl-test
"∩ intersection: identical"
(mkrv (apl-run "1 2 3 ∩ 1 2 3"))
(list 1 2 3))
(apl-test
"/∩ identity: A A = A"
(mkrv (apl-run "1 2 1 1 2 1"))
(list 1 2)))
(begin
(apl-test
"⊥ decode: 2 2 2 ⊥ 1 0 1 → 5"
(mkrv (apl-run "2 2 2 ⊥ 1 0 1"))
(list 5))
(apl-test
"⊥ decode: 10 10 10 ⊥ 1 2 3 → 123"
(mkrv (apl-run "10 10 10 ⊥ 1 2 3"))
(list 123))
(apl-test
"⊥ decode: 24 60 60 ⊥ 2 3 4 → 7384 (mixed-radix HMS)"
(mkrv (apl-run "24 60 60 ⊥ 2 3 4"))
(list 7384))
(apl-test
"⊥ decode: scalar base 2 ⊥ 1 0 1 0 → 10"
(mkrv (apl-run "2 ⊥ 1 0 1 0"))
(list 10))
(apl-test
"⊥ decode: 16 16 ⊥ 15 15 → 255"
(mkrv (apl-run "16 16 ⊥ 15 15"))
(list 255))
(apl-test
" encode: 2 2 2 5 → 1 0 1"
(mkrv (apl-run "2 2 2 5"))
(list 1 0 1))
(apl-test
" encode: 24 60 60 7384 → 2 3 4 (HMS)"
(mkrv (apl-run "24 60 60 7384"))
(list 2 3 4))
(apl-test
" encode: 2 2 2 2 13 → 1 1 0 1"
(mkrv (apl-run "2 2 2 2 13"))
(list 1 1 0 1))
(apl-test
" encode: 10 10 42 → 4 2"
(mkrv (apl-run "10 10 42"))
(list 4 2))
(apl-test
" encode: round-trip B⊥(BN) = N"
(mkrv (apl-run "24 60 60 ⊥ 24 60 60 7384"))
(list 7384))
(apl-test
"⊥ decode: round-trip B(B⊥V) = V"
(mkrv (apl-run "2 2 2 2 2 2 ⊥ 1 0 1"))
(list 1 0 1)))
(begin
(define
mk-parts
(fn (s) (map (fn (p) (get p :ravel)) (get (apl-run s) :ravel))))
(apl-test
"⊆ partition: 1 1 0 1 1 ⊆ 'abcde' → ('ab' 'de')"
(mk-parts "1 1 0 1 1 ⊆ 'abcde'")
(list (list "a" "b") (list "d" "e")))
(apl-test
"⊆ partition: 1 0 0 1 1 ⊆ 5 → ((1) (4 5))"
(mk-parts "1 0 0 1 1 ⊆ 5")
(list (list 1) (list 4 5)))
(apl-test
"⊆ partition: all-zero mask → empty"
(len (get (apl-run "0 0 0 ⊆ 1 2 3") :ravel))
0)
(apl-test
"⊆ partition: all-one mask → single partition"
(mk-parts "1 1 1 ⊆ 7 8 9")
(list (list 7 8 9)))
(apl-test
"⊆ partition: strict increase 1 2 starts new"
(mk-parts "1 2 ⊆ 10 20")
(list (list 10) (list 20)))
(apl-test
"⊆ partition: same level continues 2 2 → one partition"
(mk-parts "2 2 ⊆ 10 20")
(list (list 10 20)))
(apl-test
"⊆ partition: 0 separates"
(mk-parts "1 1 0 0 1 ⊆ 1 2 3 4 5")
(list (list 1 2) (list 5)))
(apl-test
"⊆ partition: outer length matches partition count"
(len (get (apl-run "1 0 1 0 1 ⊆ 5") :ravel))
3))
(begin
(apl-test
"⍎ execute: ⍎ '1 + 2' → 3"
(mkrv (apl-run "⍎ '1 + 2'"))
(list 3))
(apl-test
"⍎ execute: ⍎ '+/10' → 55"
(mkrv (apl-run "⍎ '+/10'"))
(list 55))
(apl-test
"⍎ execute: ⍎ '⌈/ 1 3 9 5 7' → 9"
(mkrv (apl-run "⍎ '⌈/ 1 3 9 5 7'"))
(list 9))
(apl-test
"⍎ execute: ⍎ '5' → 1..5"
(mkrv (apl-run "⍎ '5'"))
(list 1 2 3 4 5))
(apl-test
"⍎ execute: ⍎ '×/5' → 120"
(mkrv (apl-run "⍎ '×/5'"))
(list 120))
(apl-test
"⍎ execute: round-trip ⍎ ⎕FMT 42 → 42"
(mkrv (apl-run "⍎ ⎕FMT 42"))
(list 42))
(apl-test
"⍎ execute: nested ⍎ ⍎"
(mkrv (apl-run "⍎ '⍎ ''2 × 3'''"))
(list 6))
(apl-test
"⍎ execute: with assignment side-effect"
(mkrv (apl-run "⍎ 'q ← 99 ⋄ q + 1'"))
(list 100)))
(begin
(apl-test
"het-inner: 1 ⍵ .∧ X — result is enclosed (5 5)"
(let
((r (apl-run "B ← 5 5 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0 ⋄ X ← 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂B ⋄ 1 B .∧ X")))
(list
(len (get r :shape))
(= (type-of (first (get r :ravel))) "dict")))
(list 0 true))
(apl-test
"het-inner: ⊃ unwraps to (5 5) board"
(mksh
(apl-run
"B ← 5 5 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0 ⋄ X ← 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂B ⋄ ⊃ 1 B .∧ X"))
(list 5 5))
(apl-test
"het-inner: homogeneous inner product unaffected"
(mkrv (apl-run "1 2 3 +.× 4 5 6"))
(list 32))
(apl-test
"het-inner: matrix inner product unaffected"
(mkrv (apl-run "(2 2 1 2 3 4) +.× 2 2 5 6 7 8"))
(list 19 22 43 50)))

189
lib/apl/tests/programs-e2e.sx
View File

@@ -1,189 +0,0 @@
; End-to-end tests of the classic-program archetypes — running APL
; source through the full pipeline (tokenize → parse → eval-ast → runtime).
;
; These mirror the algorithms documented in lib/apl/tests/programs/*.apl
; but use forms our pipeline supports today (named functions instead of
; the inline ⍵← rebinding idiom; multi-stmt over single one-liners).
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
; ---------- factorial via ∇ recursion (cf. n-queens style) ----------
(apl-test
"e2e: factorial 5! = 120"
(mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 5"))
(list 120))
(apl-test
"e2e: factorial 7! = 5040"
(mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 7"))
(list 5040))
(apl-test
"e2e: factorial via ×/N (no recursion)"
(mkrv (apl-run "fact ← {×/⍳⍵} ⋄ fact 6"))
(list 720))
; ---------- sum / triangular numbers (sum-1..N) ----------
(apl-test
"e2e: triangular(10) = 55"
(mkrv (apl-run "tri ← {+/⍳⍵} ⋄ tri 10"))
(list 55))
(apl-test
"e2e: triangular(100) = 5050"
(mkrv (apl-run "tri ← {+/⍳⍵} ⋄ tri 100"))
(list 5050))
; ---------- sum of squares ----------
(apl-test
"e2e: sum-of-squares 1..5 = 55"
(mkrv (apl-run "ss ← {+/⍵×⍵} ⋄ ss 5"))
(list 55))
(apl-test
"e2e: sum-of-squares 1..10 = 385"
(mkrv (apl-run "ss ← {+/⍵×⍵} ⋄ ss 10"))
(list 385))
; ---------- divisor-counting (prime-sieve building blocks) ----------
(apl-test
"e2e: divisor counts 1..5 via outer mod"
(mkrv (apl-run "P ← 5 ⋄ +⌿ 0 = P ∘.| P"))
(list 1 2 2 3 2))
(apl-test
"e2e: divisor counts 1..10"
(mkrv (apl-run "P ← 10 ⋄ +⌿ 0 = P ∘.| P"))
(list 1 2 2 3 2 4 2 4 3 4))
(apl-test
"e2e: prime-mask 1..10 (count==2)"
(mkrv (apl-run "P ← 10 ⋄ 2 = +⌿ 0 = P ∘.| P"))
(list 0 1 1 0 1 0 1 0 0 0))
; ---------- monadic primitives chained ----------
(apl-test
"e2e: sum of |abs| = 15"
(mkrv (apl-run "+/|¯1 ¯2 ¯3 ¯4 ¯5"))
(list 15))
(apl-test
"e2e: max of squares 1..6"
(mkrv (apl-run "⌈/(6)×6"))
(list 36))
; ---------- nested named functions ----------
(apl-test
"e2e: compose dbl and sq via two named fns"
(mkrv (apl-run "dbl ← {⍵+⍵} ⋄ sq ← {⍵×⍵} ⋄ sq dbl 3"))
(list 36))
(apl-test
"e2e: max-of-two as named dyadic fn"
(mkrv (apl-run "mx ← {⍺⌈⍵} ⋄ 5 mx 3"))
(list 5))
(apl-test
"e2e: sqrt-via-newton 1 step from 1 → 2.5"
(mkrv (apl-run "step ← {(⍵+⍺÷⍵)÷2} ⋄ 4 step 1"))
(list 2.5))
(begin
(apl-test
"life.apl: blinker 5×5 → vertical blinker"
(mkrv
(apl-run
"life ← {⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵} ⋄ life 5 5 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0"))
(list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0))
(apl-test
"life.apl: blinker oscillates (period 2)"
(mkrv
(apl-run
"life ← {⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵} ⋄ life life 5 5 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0"))
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life.apl: 2×2 block stable"
(mkrv
(apl-run
"life ← {⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵} ⋄ life 4 4 0 0 0 0 0 1 1 0 0 1 1 0 0 0 0 0"))
(list 0 0 0 0 0 1 1 0 0 1 1 0 0 0 0 0))
(apl-test
"life.apl: empty grid stays empty"
(mkrv
(apl-run
"life ← {⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵} ⋄ life 5 5 0"))
(list 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life.apl: source-file as-written runs"
(let
((dfn (apl-run-file "lib/apl/tests/programs/life.apl"))
(board
(apl-run "5 5 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0")))
(get (apl-call-dfn-m dfn board) :ravel))
(list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0)))
(begin
(apl-test
"quicksort.apl: 11-element with duplicates"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort 3 1 4 1 5 9 2 6 5 3 5")))
(list 1 1 2 3 3 4 5 5 5 6 9))
(apl-test
"quicksort.apl: already sorted"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort 1 2 3 4 5")))
(list 1 2 3 4 5))
(apl-test
"quicksort.apl: reverse sorted"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort 5 4 3 2 1")))
(list 1 2 3 4 5))
(apl-test
"quicksort.apl: all equal"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort 7 7 7 7")))
(list 7 7 7 7))
(apl-test
"quicksort.apl: single element"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort ,42")))
(list 42))
(apl-test
"quicksort.apl: matches grade-up"
(begin
(apl-rng-seed! 42)
(mkrv
(apl-run
"V ← 8 3 1 9 2 7 5 6 4 ⋄ quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p} ⋄ quicksort V")))
(list 1 2 3 4 5 6 7 8 9))
(apl-test
"quicksort.apl: source-file as-written runs"
(begin
(apl-rng-seed! 42)
(let
((dfn (apl-run-file "lib/apl/tests/programs/quicksort.apl"))
(vec (apl-run "5 2 8 1 9 3 7 4 6")))
(get (apl-call-dfn-m dfn vec) :ravel)))
(list 1 2 3 4 5 6 7 8 9)))

304
lib/apl/tests/programs.sx
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@@ -1,304 +0,0 @@
; Tests for classic APL programs (lib/apl/tests/programs/*.apl).
; Programs are showcase APL source; runtime impl is in lib/apl/runtime.sx.
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
; ===== primes (Sieve of Eratosthenes) =====
(apl-test "primes 1 → empty" (mkrv (apl-primes 1)) (list))
(apl-test "primes 2 → just 2" (mkrv (apl-primes 2)) (list 2))
(apl-test "primes 10 → 2 3 5 7" (mkrv (apl-primes 10)) (list 2 3 5 7))
(apl-test
"primes 20 → 2 3 5 7 11 13 17 19"
(mkrv (apl-primes 20))
(list 2 3 5 7 11 13 17 19))
(apl-test
"primes 30"
(mkrv (apl-primes 30))
(list 2 3 5 7 11 13 17 19 23 29))
(apl-test
"primes 50"
(mkrv (apl-primes 50))
(list 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47))
(apl-test "primes 7 length" (first (mksh (apl-primes 7))) 4)
(apl-test "primes 100 has 25 primes" (first (mksh (apl-primes 100))) 25)
; ===== compress helper sanity =====
(apl-test
"compress 1 0 1 0 1 / 10 20 30 40 50"
(mkrv
(apl-compress
(make-array (list 5) (list 1 0 1 0 1))
(make-array (list 5) (list 10 20 30 40 50))))
(list 10 30 50))
(apl-test
"compress all-zero mask → empty"
(mkrv
(apl-compress
(make-array (list 3) (list 0 0 0))
(make-array (list 3) (list 1 2 3))))
(list))
(apl-test
"compress all-one mask → full vector"
(mkrv
(apl-compress
(make-array (list 3) (list 1 1 1))
(make-array (list 3) (list 1 2 3))))
(list 1 2 3))
(apl-test
"life: empty 5x5 stays empty"
(mkrv
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0))))
(list 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life: horizontal blinker → vertical blinker"
(mkrv
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))))
(list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0))
(apl-test
"life: vertical blinker → horizontal blinker"
(mkrv
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0))))
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life: blinker has period 2"
(mkrv
(apl-life-step
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0)))))
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life: 2x2 block stable on 5x5"
(mkrv
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 1 1 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0))))
(list 0 0 0 0 0 0 1 1 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0))
(apl-test
"life: shape preserved"
(mksh
(apl-life-step
(make-array
(list 5 5)
(list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))))
(list 5 5))
(apl-test
"life: glider on 6x6 advances"
(mkrv
(apl-life-step
(make-array
(list 6 6)
(list
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0))))
(list
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
0
0
0
0
1
1
0
0
0
0
1
0
0
0
0
0
0
0
0
0))
(apl-test
"mandelbrot c=0 stays bounded"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0)) 100))
(list 100))
(apl-test
"mandelbrot c=-1 cycle bounded"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list -1)) 100))
(list 100))
(apl-test
"mandelbrot c=-2 boundary stays bounded"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list -2)) 100))
(list 100))
(apl-test
"mandelbrot c=0.25 boundary stays bounded"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0.25)) 100))
(list 100))
(apl-test
"mandelbrot c=1 escapes at iter 3"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list 1)) 100))
(list 3))
(apl-test
"mandelbrot c=0.5 escapes at iter 5"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0.5)) 100))
(list 5))
(apl-test
"mandelbrot batched grid (rank-polymorphic)"
(mkrv (apl-mandelbrot-1d (make-array (list 5) (list -2 -1 0 1 2)) 10))
(list 10 10 10 3 2))
(apl-test
"mandelbrot batched preserves shape"
(mksh (apl-mandelbrot-1d (make-array (list 5) (list -2 -1 0 1 2)) 10))
(list 5))
(apl-test
"mandelbrot c=-1.5 stays bounded"
(mkrv (apl-mandelbrot-1d (make-array (list 1) (list -1.5)) 100))
(list 100))
(apl-test "queens 1 → 1 solution" (mkrv (apl-queens 1)) (list 1))
(apl-test "queens 2 → 0 solutions" (mkrv (apl-queens 2)) (list 0))
(apl-test "queens 3 → 0 solutions" (mkrv (apl-queens 3)) (list 0))
(apl-test "queens 4 → 2 solutions" (mkrv (apl-queens 4)) (list 2))
(apl-test "queens 5 → 10 solutions" (mkrv (apl-queens 5)) (list 10))
(apl-test "queens 6 → 4 solutions" (mkrv (apl-queens 6)) (list 4))
(apl-test "queens 7 → 40 solutions" (mkrv (apl-queens 7)) (list 40))
(apl-test "permutations of 3 has 6" (len (apl-permutations 3)) 6)
(apl-test "permutations of 4 has 24" (len (apl-permutations 4)) 24)
(apl-test
"quicksort empty"
(mkrv (apl-quicksort (make-array (list 0) (list))))
(list))
(apl-test
"quicksort single"
(mkrv (apl-quicksort (make-array (list 1) (list 42))))
(list 42))
(apl-test
"quicksort already sorted"
(mkrv (apl-quicksort (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3 4 5))
(apl-test
"quicksort reverse sorted"
(mkrv (apl-quicksort (make-array (list 5) (list 5 4 3 2 1))))
(list 1 2 3 4 5))
(apl-test
"quicksort with duplicates"
(mkrv (apl-quicksort (make-array (list 7) (list 3 1 4 1 5 9 2))))
(list 1 1 2 3 4 5 9))
(apl-test
"quicksort all equal"
(mkrv (apl-quicksort (make-array (list 5) (list 7 7 7 7 7))))
(list 7 7 7 7 7))
(apl-test
"quicksort negatives"
(mkrv (apl-quicksort (make-array (list 5) (list -3 1 -1 2 0))))
(list -3 -1 0 1 2))
(apl-test
"quicksort 11-element pi"
(mkrv
(apl-quicksort (make-array (list 11) (list 3 1 4 1 5 9 2 6 5 3 5))))
(list 1 1 2 3 3 4 5 5 5 6 9))
(apl-test
"quicksort preserves length"
(first
(mksh (apl-quicksort (make-array (list 7) (list 3 1 4 1 5 9 2)))))
7)

22
lib/apl/tests/programs/life.apl
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⍝ Conway's Game of Life — toroidal one-liner
⍝ The classic Roger Hui formulation:
⍝ life ← {⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵}
⍝ Read right-to-left:
⍝ ⊂⍵ : enclose the board (so it's a single scalar item)
⍝ ¯1 0 1 ⌽¨ ⊂⍵ : produce 3 horizontally-shifted copies
⍝ ¯1 0 1 ∘.⊖ … : outer-product with vertical shifts → 3×3 = 9 shifts
⍝ +/ +/ … : sum the 9 boards element-wise → neighbor-count + self
⍝ 3 4 = … : leading-axis-extended boolean — count is 3 (born) or 4 (survive)
⍝ 1 ⍵ .∧ … : "alive next" iff (count=3) or (alive AND count=4)
⍝ ⊃ … : disclose the enclosed result back to a 2D board
⍝ Rules in plain language:
⍝ - dead cell + 3 live neighbors → born
⍝ - live cell + 2 or 3 live neighbors → survives
⍝ - all else → dies
⍝ Toroidal: edges wrap (rotate is cyclic).
life {1 . 3 4 = +/ +/ ¯1 0 1 . ¯1 0 1 ¨ }

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lib/apl/tests/programs/mandelbrot.apl
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⍝ Mandelbrot — real-axis subset
⍝ For complex c, the Mandelbrot set is { c : |z_n| stays bounded } where
⍝ z_0 = 0, z_{n+1} = z_n² + c.
⍝ Restricting c (and z) to gives the segment c ∈ [-2, 1/4]
⍝ where the iteration stays bounded.
⍝ Rank-polymorphic batched-iteration form:
⍝ mandelbrot ← {⍵ ⍵⍵ +,( × ) }
⍝ Pseudocode (as we don't have ⎕ system fns yet):
⍝ z ← 0×c ⍝ start at zero
⍝ alive ← 1+0×c ⍝ all "still in"
⍝ for k iterations:
⍝ alive ← alive ∧ 4 ≥ z×z ⍝ still bounded?
⍝ z ← alive × c + z×z ⍝ freeze escaped via mask
⍝ count ← count + alive ⍝ tally surviving iters
⍝ Examples (count after 100 iterations):
⍝ c=0 : 100 (z stays at 0)
⍝ c=-1 : 100 (cycles 0,-1,0,-1,...)
⍝ c=-2 : 100 (settles at 2 — boundary)
⍝ c=0.25 : 100 (boundary — converges to 0.5)
⍝ c=0.5 : 5 (escapes by iteration 6)
⍝ c=1 : 3 (escapes quickly)
⍝ Real-axis Mandelbrot set: bounded for c ∈ [-2, 0.25].
mandelbrot {zalivecount0× {alivealive4z×z zalive×+z×z count+alive}}

18
lib/apl/tests/programs/n-queens.apl
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⍝ N-Queens — count solutions to placing N non-attacking queens on N×N
⍝ A solution is encoded as a permutation P of 1..N where P[i] is the
⍝ column of the queen in row i. Rows and columns are then automatically
⍝ unique (it's a permutation). We must additionally rule out queens
⍝ sharing a diagonal: |i-j| = |P[i]-P[j]| for any pair.
⍝ Backtracking via reduce — the classic Roger Hui style:
⍝ queens ← {≢{⍵,¨⍨↓(0=∊(¨⍳⍴⍵)≠.+|⍵)/⍳⍴⍵}/(⍳⍵)⍴⊂⍳⍵}
⍝ Plain reading:
⍝ permute 1..N, keep those where no two queens share a diagonal.
⍝ Known solution counts (OEIS A000170):
⍝ N 1 2 3 4 5 6 7 8 9 10
⍝ q(N) 1 0 0 2 10 4 40 92 352 724
queens {({(i j) (|i-j)|(P[i])-(P[j])}permutations )}

16
lib/apl/tests/programs/primes.apl
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⍝ Sieve of Eratosthenes — the classic APL one-liner
⍝ primes ← (2=+⌿0=A∘.|A)/A←N
⍝ Read right-to-left:
⍝ A ← N : A is 1..N
⍝ A∘.|A : outer-product residue table — M[i,j] = A[j] mod A[i]
⍝ 0=... : boolean — true where A[i] divides A[j]
⍝ +⌿... : column sums — count of divisors per A[j]
⍝ 2=... : true for numbers with exactly 2 divisors (1 and self) → primes
⍝ .../A : compress — select A[j] where mask[j] is true
⍝ Examples:
⍝ primes 10 → 2 3 5 7
⍝ primes 30 → 2 3 5 7 11 13 17 19 23 29
primes {(2=+0=.|)/}

25
lib/apl/tests/programs/quicksort.apl
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⍝ Quicksort — the classic Roger Hui one-liner
⍝ Q ← {1≥≢⍵:⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p←⍵⌷⍨?≢⍵}
⍝ Read right-to-left:
⍝ ?≢⍵ : pick a random index in 1..length
⍝ ⍵⌷⍨… : take that element as pivot p
⍝ ⍵>p : boolean — elements greater than pivot
⍝ ∇⍵⌿⍨… : recursively sort the > partition
⍝ (p=⍵)/⍵ : keep elements equal to pivot
⍝ ⍵<p : boolean — elements less than pivot
⍝ ∇⍵⌿⍨… : recursively sort the < partition
⍝ , : catenate ⟨less⟩ ⟨equal⟩ ⟨greater⟩
⍝ 1≥≢⍵:⍵ : guard — base case for length ≤ 1
⍝ Stability: not stable on duplicates (but eq-class is preserved as a block).
⍝ Worst case O(N²) on already-sorted input with deterministic pivot;
⍝ randomized pivot selection gives expected O(N log N).
⍝ Examples:
⍝ Q 3 1 4 1 5 9 2 6 5 3 5 → 1 1 2 3 3 4 5 5 5 6 9
⍝ Q 0 → ⍬ (empty)
⍝ Q ,42 → 42
quicksort {1: p? (<p),(p=)/,>p}

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lib/apl/tests/scalar.sx
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; APL scalar primitives test suite
; Requires: lib/apl/runtime.sx
; ============================================================
; Test framework
; ============================================================
(define apl-rt-count 0)
(define apl-rt-pass 0)
(define apl-rt-fails (list))
; Element-wise list comparison (handles both List and ListRef)
(define
lists-eq
(fn
(a b)
(if
(and (= (len a) 0) (= (len b) 0))
true
(if
(not (= (len a) (len b)))
false
(if
(not (= (first a) (first b)))
false
(lists-eq (rest a) (rest b)))))))
(define
apl-rt-test
(fn
(name actual expected)
(begin
(set! apl-rt-count (+ apl-rt-count 1))
(if
(equal? actual expected)
(set! apl-rt-pass (+ apl-rt-pass 1))
(append! apl-rt-fails {:actual actual :expected expected :name name})))))
; Test that a ravel equals a plain list (handles ListRef vs List)
(define
ravel-test
(fn
(name arr expected-list)
(begin
(set! apl-rt-count (+ apl-rt-count 1))
(let
((actual (get arr :ravel)))
(if
(lists-eq actual expected-list)
(set! apl-rt-pass (+ apl-rt-pass 1))
(append! apl-rt-fails {:actual actual :expected expected-list :name name}))))))
; Test a scalar ravel value (single-element list)
(define
scalar-test
(fn (name arr expected-val) (ravel-test name arr (list expected-val))))
; ============================================================
; Array constructor tests
; ============================================================
(apl-rt-test
"scalar: shape is empty list"
(get (apl-scalar 5) :shape)
(list))
(apl-rt-test
"scalar: ravel has one element"
(get (apl-scalar 5) :ravel)
(list 5))
(apl-rt-test "scalar: rank 0" (array-rank (apl-scalar 5)) 0)
(apl-rt-test "scalar? returns true for scalar" (scalar? (apl-scalar 5)) true)
(apl-rt-test "scalar: zero" (get (apl-scalar 0) :ravel) (list 0))
(apl-rt-test
"vector: shape is (3)"
(get (apl-vector (list 1 2 3)) :shape)
(list 3))
(apl-rt-test
"vector: ravel matches input"
(get (apl-vector (list 1 2 3)) :ravel)
(list 1 2 3))
(apl-rt-test "vector: rank 1" (array-rank (apl-vector (list 1 2 3))) 1)
(apl-rt-test
"scalar? returns false for vector"
(scalar? (apl-vector (list 1 2 3)))
false)
(apl-rt-test
"make-array: rank 2"
(array-rank (make-array (list 2 3) (list 1 2 3 4 5 6)))
2)
(apl-rt-test
"make-array: shape"
(get (make-array (list 2 3) (list 1 2 3 4 5 6)) :shape)
(list 2 3))
(apl-rt-test
"array-ref: first element"
(array-ref (apl-vector (list 10 20 30)) 0)
10)
(apl-rt-test
"array-ref: last element"
(array-ref (apl-vector (list 10 20 30)) 2)
30)
(apl-rt-test "enclose: wraps in rank-0" (scalar? (enclose 42)) true)
(apl-rt-test
"enclose: ravel contains value"
(get (enclose 42) :ravel)
(list 42))
(apl-rt-test "disclose: unwraps rank-0" (disclose (enclose 42)) 42)
; ============================================================
; Shape primitive tests
; ============================================================
(ravel-test " scalar: returns empty" (apl-shape (apl-scalar 5)) (list))
(ravel-test
" vector: returns (3)"
(apl-shape (apl-vector (list 1 2 3)))
(list 3))
(ravel-test
" matrix: returns (2 3)"
(apl-shape (make-array (list 2 3) (list 1 2 3 4 5 6)))
(list 2 3))
(ravel-test
", ravel scalar: vector of 1"
(apl-ravel (apl-scalar 5))
(list 5))
(apl-rt-test
", ravel vector: same elements"
(get (apl-ravel (apl-vector (list 1 2 3))) :ravel)
(list 1 2 3))
(apl-rt-test
", ravel matrix: all elements"
(get (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))) :ravel)
(list 1 2 3 4 5 6))
(scalar-test "≢ tally scalar: 1" (apl-tally (apl-scalar 5)) 1)
(scalar-test
"≢ tally vector: first dimension"
(apl-tally (apl-vector (list 1 2 3)))
3)
(scalar-test
"≢ tally matrix: first dimension"
(apl-tally (make-array (list 2 3) (list 1 2 3 4 5 6)))
2)
(scalar-test
"≡ depth flat vector: 0"
(apl-depth (apl-vector (list 1 2 3)))
0)
(scalar-test "≡ depth scalar: 0" (apl-depth (apl-scalar 5)) 0)
(scalar-test
"≡ depth nested (enclose in vector): 1"
(apl-depth (enclose (apl-vector (list 1 2 3))))
1)
; ============================================================
; iota tests
; ============================================================
(apl-rt-test
"5 shape is (5)"
(get (apl-iota (apl-scalar 5)) :shape)
(list 5))
(ravel-test "5 ravel is 1..5" (apl-iota (apl-scalar 5)) (list 1 2 3 4 5))
(ravel-test "1 ravel is (1)" (apl-iota (apl-scalar 1)) (list 1))
(ravel-test "0 ravel is empty" (apl-iota (apl-scalar 0)) (list))
(apl-rt-test "apl-io is 1" apl-io 1)
; ============================================================
; Arithmetic broadcast tests
; ============================================================
(scalar-test
"+ scalar scalar: 3+4=7"
(apl-add (apl-scalar 3) (apl-scalar 4))
7)
(ravel-test
"+ vector scalar: +10"
(apl-add (apl-vector (list 1 2 3)) (apl-scalar 10))
(list 11 12 13))
(ravel-test
"+ scalar vector: 10+"
(apl-add (apl-scalar 10) (apl-vector (list 1 2 3)))
(list 11 12 13))
(ravel-test
"+ vector vector"
(apl-add (apl-vector (list 1 2 3)) (apl-vector (list 4 5 6)))
(list 5 7 9))
(scalar-test "- negate monadic" (apl-neg-m (apl-scalar 5)) -5)
(scalar-test "- dyadic 10-3=7" (apl-sub (apl-scalar 10) (apl-scalar 3)) 7)
(scalar-test "× signum positive" (apl-signum (apl-scalar 7)) 1)
(scalar-test "× signum negative" (apl-signum (apl-scalar -3)) -1)
(scalar-test "× signum zero" (apl-signum (apl-scalar 0)) 0)
(scalar-test "× dyadic 3×4=12" (apl-mul (apl-scalar 3) (apl-scalar 4)) 12)
(scalar-test "÷ reciprocal 1÷4=0.25" (apl-recip (apl-scalar 4)) 0.25)
(scalar-test
"÷ dyadic 10÷4=2.5"
(apl-div (apl-scalar 10) (apl-scalar 4))
2.5)
(scalar-test "⌈ ceiling 2.3→3" (apl-ceil (apl-scalar 2.3)) 3)
(scalar-test "⌈ max 3 5 → 5" (apl-max (apl-scalar 3) (apl-scalar 5)) 5)
(scalar-test "⌊ floor 2.7→2" (apl-floor (apl-scalar 2.7)) 2)
(scalar-test "⌊ min 3 5 → 3" (apl-min (apl-scalar 3) (apl-scalar 5)) 3)
(scalar-test "* exp monadic e^0=1" (apl-exp (apl-scalar 0)) 1)
(scalar-test
"* pow dyadic 2^10=1024"
(apl-pow (apl-scalar 2) (apl-scalar 10))
1024)
(scalar-test "⍟ ln 1=0" (apl-ln (apl-scalar 1)) 0)
(scalar-test "| abs positive" (apl-abs (apl-scalar 5)) 5)
(scalar-test "| abs negative" (apl-abs (apl-scalar -5)) 5)
(scalar-test "| mod 3|7=1" (apl-mod (apl-scalar 3) (apl-scalar 7)) 1)
(scalar-test "! factorial 5!=120" (apl-fact (apl-scalar 5)) 120)
(scalar-test "! factorial 0!=1" (apl-fact (apl-scalar 0)) 1)
(scalar-test
"! binomial 4 choose 2 = 6"
(apl-binomial (apl-scalar 4) (apl-scalar 2))
6)
(scalar-test "○ pi×0=0" (apl-pi-times (apl-scalar 0)) 0)
(scalar-test "○ trig sin(0)=0" (apl-trig (apl-scalar 1) (apl-scalar 0)) 0)
(scalar-test "○ trig cos(0)=1" (apl-trig (apl-scalar 2) (apl-scalar 0)) 1)
; ============================================================
; Comparison tests
; ============================================================
(scalar-test "< less: 3<5 → 1" (apl-lt (apl-scalar 3) (apl-scalar 5)) 1)
(scalar-test "< less: 5<3 → 0" (apl-lt (apl-scalar 5) (apl-scalar 3)) 0)
(scalar-test
"≤ le equal: 3≤3 → 1"
(apl-le (apl-scalar 3) (apl-scalar 3))
1)
(scalar-test "= eq: 5=5 → 1" (apl-eq (apl-scalar 5) (apl-scalar 5)) 1)
(scalar-test "= ne: 5=6 → 0" (apl-eq (apl-scalar 5) (apl-scalar 6)) 0)
(scalar-test "≥ ge: 5≥3 → 1" (apl-ge (apl-scalar 5) (apl-scalar 3)) 1)
(scalar-test "> gt: 5>3 → 1" (apl-gt (apl-scalar 5) (apl-scalar 3)) 1)
(scalar-test "≠ ne: 5≠3 → 1" (apl-ne (apl-scalar 5) (apl-scalar 3)) 1)
(ravel-test
"comparison vector broadcast: 1 2 3 < 2 → 1 0 0"
(apl-lt (apl-vector (list 1 2 3)) (apl-scalar 2))
(list 1 0 0))
; ============================================================
; Logical tests
; ============================================================
(scalar-test "~ not 0 → 1" (apl-not (apl-scalar 0)) 1)
(scalar-test "~ not 1 → 0" (apl-not (apl-scalar 1)) 0)
(ravel-test
"~ not vector: 1 0 1 0 → 0 1 0 1"
(apl-not (apl-vector (list 1 0 1 0)))
(list 0 1 0 1))
(scalar-test
"∧ and 1∧1 → 1"
(apl-and (apl-scalar 1) (apl-scalar 1))
1)
(scalar-test
"∧ and 1∧0 → 0"
(apl-and (apl-scalar 1) (apl-scalar 0))
0)
(scalar-test " or 01 → 1" (apl-or (apl-scalar 0) (apl-scalar 1)) 1)
(scalar-test " or 00 → 0" (apl-or (apl-scalar 0) (apl-scalar 0)) 0)
(scalar-test
"⍱ nor 0⍱0 → 1"
(apl-nor (apl-scalar 0) (apl-scalar 0))
1)
(scalar-test
"⍱ nor 1⍱0 → 0"
(apl-nor (apl-scalar 1) (apl-scalar 0))
0)
(scalar-test
"⍲ nand 1⍲1 → 0"
(apl-nand (apl-scalar 1) (apl-scalar 1))
0)
(scalar-test
"⍲ nand 1⍲0 → 1"
(apl-nand (apl-scalar 1) (apl-scalar 0))
1)
; ============================================================
; plus-m identity test
; ============================================================
(scalar-test "+ monadic identity: +5 → 5" (apl-plus-m (apl-scalar 5)) 5)
; ============================================================
; Summary
; ============================================================
(define
apl-scalar-summary
(str
"scalar "
apl-rt-pass
"/"
apl-rt-count
(if (= (len apl-rt-fails) 0) "" (str " FAILS: " apl-rt-fails))))

608
lib/apl/tests/structural.sx
View File

@@ -1,608 +0,0 @@
;; lib/apl/tests/structural.sx — Phase 3: structural primitives
;; Tests for: apl-reshape, apl-ravel, apl-transpose, apl-transpose-dyadic
;; Loaded after runtime.sx; shares apl-test / apl-test-pass / apl-test-fail.
(define rv (fn (arr) (get arr :ravel)))
(define sh (fn (arr) (get arr :shape)))
;; ---------------------------------------------------------------------------
;; 1. Ravel (monadic ,)
;; ---------------------------------------------------------------------------
(apl-test "ravel scalar" (rv (apl-ravel (apl-scalar 5))) (list 5))
(apl-test
"ravel vector"
(rv (apl-ravel (make-array (list 3) (list 1 2 3))))
(list 1 2 3))
(apl-test
"ravel matrix"
(rv (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 3 4 5 6))
(apl-test
"ravel shape is rank-1"
(sh (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 6))
;; ---------------------------------------------------------------------------
;; 2. Reshape (dyadic )
;; ---------------------------------------------------------------------------
(apl-test
"reshape 2x3 ravel"
(rv
(apl-reshape
(make-array (list 2) (list 2 3))
(make-array (list 6) (list 1 2 3 4 5 6))))
(list 1 2 3 4 5 6))
(apl-test
"reshape 2x3 shape"
(sh
(apl-reshape
(make-array (list 2) (list 2 3))
(make-array (list 6) (list 1 2 3 4 5 6))))
(list 2 3))
(apl-test
"reshape cycle 6 from 1 2"
(rv
(apl-reshape
(make-array (list 1) (list 6))
(make-array (list 2) (list 1 2))))
(list 1 2 1 2 1 2))
(apl-test
"reshape cycle 2x3 from 1 2"
(rv
(apl-reshape
(make-array (list 2) (list 2 3))
(make-array (list 2) (list 1 2))))
(list 1 2 1 2 1 2))
(apl-test
"reshape scalar fill"
(rv (apl-reshape (make-array (list 1) (list 4)) (apl-scalar 7)))
(list 7 7 7 7))
(apl-test
"reshape truncate"
(rv
(apl-reshape
(make-array (list 1) (list 3))
(make-array (list 6) (list 10 20 30 40 50 60))))
(list 10 20 30))
(apl-test
"reshape matrix to vector"
(sh
(apl-reshape
(make-array (list 1) (list 6))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 6))
(apl-test
"reshape 2x2x3"
(sh
(apl-reshape
(make-array (list 3) (list 2 2 3))
(make-array (list 12) (range 1 13))))
(list 2 2 3))
(apl-test
"reshape to empty"
(rv
(apl-reshape
(make-array (list 1) (list 0))
(make-array (list 3) (list 1 2 3))))
(list))
;; ---------------------------------------------------------------------------
;; 3. Monadic transpose (⍉)
;; ---------------------------------------------------------------------------
(apl-test
"transpose scalar shape"
(sh (apl-transpose (apl-scalar 99)))
(list))
(apl-test
"transpose scalar ravel"
(rv (apl-transpose (apl-scalar 99)))
(list 99))
(apl-test
"transpose vector shape"
(sh (apl-transpose (make-array (list 3) (list 3 1 4))))
(list 3))
(apl-test
"transpose vector ravel"
(rv (apl-transpose (make-array (list 3) (list 3 1 4))))
(list 3 1 4))
(apl-test
"transpose 2x3 shape"
(sh (apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3 2))
(apl-test
"transpose 2x3 ravel"
(rv (apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 4 2 5 3 6))
(apl-test
"transpose 3x3"
(rv (apl-transpose (make-array (list 3 3) (list 1 2 3 4 5 6 7 8 9))))
(list 1 4 7 2 5 8 3 6 9))
(apl-test
"transpose 1x4 shape"
(sh (apl-transpose (make-array (list 1 4) (list 1 2 3 4))))
(list 4 1))
(apl-test
"transpose twice identity"
(rv
(apl-transpose
(apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6)))))
(list 1 2 3 4 5 6))
(apl-test
"transpose 3d shape"
(sh (apl-transpose (make-array (list 2 3 4) (range 0 24))))
(list 4 3 2))
;; ---------------------------------------------------------------------------
;; 4. Dyadic transpose (perm⍉arr)
;; ---------------------------------------------------------------------------
(apl-test
"dyadic-transpose identity"
(rv
(apl-transpose-dyadic
(make-array (list 2) (list 1 2))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 3 4 5 6))
(apl-test
"dyadic-transpose swap 2x3"
(rv
(apl-transpose-dyadic
(make-array (list 2) (list 2 1))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 4 2 5 3 6))
(apl-test
"dyadic-transpose swap shape"
(sh
(apl-transpose-dyadic
(make-array (list 2) (list 2 1))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3 2))
(apl-test
"dyadic-transpose 3d shape"
(sh
(apl-transpose-dyadic
(make-array (list 3) (list 2 1 3))
(make-array (list 2 3 4) (range 0 24))))
(list 3 2 4))
(apl-test
"take 3 from front"
(rv (apl-take (apl-scalar 3) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3))
(apl-test
"take 0"
(rv (apl-take (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
(list))
(apl-test
"take -2 from back"
(rv (apl-take (apl-scalar -2) (make-array (list 5) (list 1 2 3 4 5))))
(list 4 5))
(apl-test
"take over-take pads with 0"
(rv (apl-take (apl-scalar 7) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3 4 5 0 0))
(apl-test
"take matrix 1 row 2 cols shape"
(sh
(apl-take
(make-array (list 2) (list 1 2))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2))
(apl-test
"take matrix 1 row 2 cols ravel"
(rv
(apl-take
(make-array (list 2) (list 1 2))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2))
(apl-test
"take matrix negative row"
(rv
(apl-take
(make-array (list 2) (list -1 3))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 4 5 6))
(apl-test
"drop 2 from front"
(rv (apl-drop (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
(list 3 4 5))
(apl-test
"drop -2 from back"
(rv (apl-drop (apl-scalar -2) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3))
(apl-test
"drop all"
(rv (apl-drop (apl-scalar 5) (make-array (list 5) (list 1 2 3 4 5))))
(list))
(apl-test
"drop 0"
(rv (apl-drop (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3 4 5))
(apl-test
"drop matrix 1 row shape"
(sh
(apl-drop
(make-array (list 2) (list 1 0))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 3))
(apl-test
"drop matrix 1 row ravel"
(rv
(apl-drop
(make-array (list 2) (list 1 0))
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 4 5 6))
(apl-test
"reverse vector"
(rv (apl-reverse (make-array (list 5) (list 1 2 3 4 5))))
(list 5 4 3 2 1))
(apl-test
"reverse scalar identity"
(rv (apl-reverse (apl-scalar 42)))
(list 42))
(apl-test
"reverse matrix last axis"
(rv (apl-reverse (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 3 2 1 6 5 4))
(apl-test
"reverse-first matrix"
(rv (apl-reverse-first (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 4 5 6 1 2 3))
(apl-test
"reverse-first vector identity"
(rv (apl-reverse-first (make-array (list 4) (list 1 2 3 4))))
(list 4 3 2 1))
(apl-test
"rotate vector left by 2"
(rv (apl-rotate (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
(list 3 4 5 1 2))
(apl-test
"rotate vector right by 1 (negative)"
(rv (apl-rotate (apl-scalar -1) (make-array (list 5) (list 1 2 3 4 5))))
(list 5 1 2 3 4))
(apl-test
"rotate by 0 is identity"
(rv (apl-rotate (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
(list 1 2 3 4 5))
(apl-test
"rotate matrix last axis"
(rv
(apl-rotate (apl-scalar 1) (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 2 3 1 5 6 4))
(apl-test
"rotate-first matrix"
(rv
(apl-rotate-first
(apl-scalar 1)
(make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 4 5 6 1 2 3))
(apl-test
"cat v,v ravel"
(rv
(apl-catenate
(make-array (list 3) (list 1 2 3))
(make-array (list 2) (list 4 5))))
(list 1 2 3 4 5))
(apl-test
"cat v,v shape"
(sh
(apl-catenate
(make-array (list 3) (list 1 2 3))
(make-array (list 2) (list 4 5))))
(list 5))
(apl-test
"cat scalar,v"
(rv (apl-catenate (apl-scalar 99) (make-array (list 3) (list 1 2 3))))
(list 99 1 2 3))
(apl-test
"cat v,scalar"
(rv (apl-catenate (make-array (list 3) (list 1 2 3)) (apl-scalar 99)))
(list 1 2 3 99))
(apl-test
"cat matrix last-axis shape"
(sh
(apl-catenate
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 2 2) (list 7 8 9 10))))
(list 2 5))
(apl-test
"cat matrix last-axis ravel"
(rv
(apl-catenate
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 2 2) (list 7 8 9 10))))
(list 1 2 3 7 8 4 5 6 9 10))
(apl-test
"cat-first v,v shape"
(sh
(apl-catenate-first
(make-array (list 3) (list 1 2 3))
(make-array (list 2) (list 4 5))))
(list 5))
(apl-test
"cat-first matrix shape"
(sh
(apl-catenate-first
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3 3) (list 11 12 13 14 15 16 17 18 19))))
(list 5 3))
(apl-test
"cat-first matrix ravel"
(rv
(apl-catenate-first
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3 3) (list 11 12 13 14 15 16 17 18 19))))
(list 1 2 3 4 5 6 11 12 13 14 15 16 17 18 19))
(apl-test
"squad scalar into vector"
(rv
(apl-squad (apl-scalar 2) (make-array (list 5) (list 10 20 30 40 50))))
(list 20))
(apl-test
"squad first element"
(rv (apl-squad (apl-scalar 1) (make-array (list 3) (list 10 20 30))))
(list 10))
(apl-test
"squad last element"
(rv
(apl-squad (apl-scalar 5) (make-array (list 5) (list 10 20 30 40 50))))
(list 50))
(apl-test
"squad fully specified matrix element"
(rv
(apl-squad
(make-array (list 2) (list 2 3))
(make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
(list 7))
(apl-test
"squad partial row of matrix shape"
(sh
(apl-squad
(apl-scalar 2)
(make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
(list 4))
(apl-test
"squad partial row of matrix ravel"
(rv
(apl-squad
(apl-scalar 2)
(make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
(list 5 6 7 8))
(apl-test
"squad partial 3d slice shape"
(sh (apl-squad (apl-scalar 1) (make-array (list 2 3 4) (range 1 25))))
(list 3 4))
(apl-test
"grade-up basic"
(rv (apl-grade-up (make-array (list 5) (list 3 1 4 1 5))))
(list 2 4 1 3 5))
(apl-test
"grade-up shape"
(sh (apl-grade-up (make-array (list 4) (list 4 1 3 2))))
(list 4))
(apl-test
"grade-up no duplicates"
(rv (apl-grade-up (make-array (list 4) (list 4 1 3 2))))
(list 2 4 3 1))
(apl-test
"grade-up already sorted"
(rv (apl-grade-up (make-array (list 3) (list 1 2 3))))
(list 1 2 3))
(apl-test
"grade-up reverse sorted"
(rv (apl-grade-up (make-array (list 3) (list 3 2 1))))
(list 3 2 1))
(apl-test
"grade-down basic"
(rv (apl-grade-down (make-array (list 5) (list 3 1 4 1 5))))
(list 5 3 1 2 4))
(apl-test
"grade-down no duplicates"
(rv (apl-grade-down (make-array (list 4) (list 4 1 3 2))))
(list 1 3 4 2))
(apl-test
"grade-up single element"
(rv (apl-grade-up (make-array (list 1) (list 42))))
(list 1))
(apl-test
"enclose shape is scalar"
(sh (apl-enclose (make-array (list 3) (list 1 2 3))))
(list))
(apl-test
"enclose ravel length is 1"
(len (rv (apl-enclose (make-array (list 3) (list 1 2 3)))))
1)
(apl-test
"enclose inner ravel"
(rv (first (rv (apl-enclose (make-array (list 3) (list 1 2 3))))))
(list 1 2 3))
(apl-test
"disclose of enclose round-trips ravel"
(rv (apl-disclose (apl-enclose (make-array (list 3) (list 10 20 30)))))
(list 10 20 30))
(apl-test
"disclose of enclose round-trips shape"
(sh (apl-disclose (apl-enclose (make-array (list 3) (list 10 20 30)))))
(list 3))
(apl-test
"disclose scalar ravel"
(rv (apl-disclose (apl-scalar 42)))
(list 42))
(apl-test
"disclose vector ravel"
(rv (apl-disclose (make-array (list 3) (list 5 6 7))))
(list 5))
(apl-test
"disclose matrix returns first row"
(rv (apl-disclose (make-array (list 2 3) (list 1 2 3 4 5 6))))
(list 1 2 3))
(apl-test
"member basic"
(rv
(apl-member
(make-array (list 3) (list 1 2 3))
(make-array (list 2) (list 2 3))))
(list 0 1 1))
(apl-test
"member all absent"
(rv
(apl-member
(make-array (list 3) (list 4 5 6))
(make-array (list 3) (list 1 2 3))))
(list 0 0 0))
(apl-test
"member scalar"
(rv (apl-member (apl-scalar 5) (make-array (list 3) (list 1 5 9))))
(list 1))
(apl-test
"member shape preserved"
(sh
(apl-member
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3) (list 1 3 5))))
(list 2 3))
(apl-test
"member matrix ravel"
(rv
(apl-member
(make-array (list 2 3) (list 1 2 3 4 5 6))
(make-array (list 3) (list 1 3 5))))
(list 1 0 1 0 1 0))
(apl-test
"index-of basic"
(rv
(apl-index-of
(make-array (list 4) (list 10 20 30 40))
(make-array (list 3) (list 20 40 10))))
(list 2 4 1))
(apl-test
"index-of not-found"
(rv
(apl-index-of
(make-array (list 3) (list 1 2 3))
(make-array (list 2) (list 5 2))))
(list 4 2))
(apl-test
"index-of scalar right"
(rv
(apl-index-of (make-array (list 3) (list 10 20 30)) (apl-scalar 20)))
(list 2))
(apl-test
"without basic"
(rv
(apl-without
(make-array (list 5) (list 1 2 3 4 5))
(make-array (list 2) (list 2 4))))
(list 1 3 5))
(apl-test
"without shape"
(sh
(apl-without
(make-array (list 5) (list 1 2 3 4 5))
(make-array (list 2) (list 2 4))))
(list 3))
(apl-test
"without nothing removed"
(rv
(apl-without
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 4 5 6))))
(list 1 2 3))
(apl-test
"without all removed"
(rv
(apl-without
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 1 2 3))))
(list))

48
lib/apl/tests/system.sx
View File

@@ -1,48 +0,0 @@
; Tests for APL ⎕ system functions.
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
(apl-test "⎕IO returns 1" (mkrv (apl-quad-io)) (list 1))
(apl-test "⎕ML returns 1" (mkrv (apl-quad-ml)) (list 1))
(apl-test "⎕FR returns 1248" (mkrv (apl-quad-fr)) (list 1248))
(apl-test "⎕TS shape is 7" (mksh (apl-quad-ts)) (list 7))
(apl-test "⎕TS year is 1970 default" (first (mkrv (apl-quad-ts))) 1970)
(apl-test "⎕FMT scalar 42" (apl-quad-fmt (apl-scalar 42)) "42")
(apl-test "⎕FMT scalar negative" (apl-quad-fmt (apl-scalar -7)) "-7")
(apl-test
"⎕FMT empty vector"
(apl-quad-fmt (make-array (list 0) (list)))
"")
(apl-test
"⎕FMT singleton vector"
(apl-quad-fmt (make-array (list 1) (list 42)))
"42")
(apl-test
"⎕FMT vector"
(apl-quad-fmt (make-array (list 5) (list 1 2 3 4 5)))
"1 2 3 4 5")
(apl-test
"⎕FMT matrix 2x3"
(apl-quad-fmt (make-array (list 2 3) (list 1 2 3 4 5 6)))
"1 2 3\n4 5 6\n")
(apl-test
"⎕← (print) returns its arg"
(mkrv (apl-quad-print (apl-scalar 99)))
(list 99))
(apl-test
"⎕← preserves shape"
(mksh (apl-quad-print (make-array (list 3) (list 1 2 3))))
(list 3))

156
lib/apl/tests/tradfn.sx
View File

@@ -1,156 +0,0 @@
; Tests for apl-call-tradfn (manual structure construction).
(define mkrv (fn (arr) (get arr :ravel)))
(define mksh (fn (arr) (get arr :shape)))
(define mknum (fn (n) (list :num n)))
(define mknm (fn (s) (list :name s)))
(define mkfg (fn (g) (list :fn-glyph g)))
(define mkmon (fn (g a) (list :monad (mkfg g) a)))
(define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
(define mkasg (fn (n e) (list :assign n e)))
(define mkbr (fn (e) (list :branch e)))
(define mkif (fn (c t e) (list :if c t e)))
(define mkwhile (fn (c b) (list :while c b)))
(define mkfor (fn (v i b) (list :for v i b)))
(define mksel (fn (v cs d) (list :select v cs d)))
(define mktrap (fn (codes t c) (list :trap codes t c)))
(define mkthr (fn (code msg) (list :throw code msg)))
(apl-test
"tradfn R←L+W simple add"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "+" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 5) (apl-scalar 7)))
(list 12))
(apl-test
"tradfn R←L×W"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 6) (apl-scalar 7)))
(list 42))
(apl-test
"tradfn monadic R←-W"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkmon "-" (mknm "W")))) :alpha nil} nil (apl-scalar 9)))
(list -9))
(apl-test
"tradfn →0 exits early"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknm "W")) (mkbr (mknum 0)) (mkasg "R" (mknum 999))) :alpha nil} nil (apl-scalar 7)))
(list 7))
(apl-test
"tradfn branch to line 3 skips line 2"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkbr (mknum 3)) (mkasg "R" (mknum 999)) (mkasg "R" (mknum 42))) :alpha nil} nil (apl-scalar 0)))
(list 42))
(apl-test
"tradfn local var t←W+1; R←t×2"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "t" (mkdyd "+" (mknm "W") (mknum 1))) (mkasg "R" (mkdyd "×" (mknm "t") (mknum 2)))) :alpha nil} nil (apl-scalar 5)))
(list 12))
(apl-test
"tradfn vector args"
(mkrv
(apl-call-tradfn
{:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "+" (mknm "L") (mknm "W")))) :alpha "L"}
(make-array (list 3) (list 1 2 3))
(make-array (list 3) (list 10 20 30))))
(list 11 22 33))
(apl-test
"tradfn unset result returns nil"
(apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkbr (mknum 0))) :alpha nil} nil (apl-scalar 5))
nil)
(apl-test
"tradfn run-off end returns result"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "W") (mknum 3)))) :alpha nil} nil (apl-scalar 7)))
(list 21))
(apl-test
"tradfn loop sum 1+2+...+5 via branch"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "i" (mknum 1)) (mkasg "R" (mknum 0)) (mkasg "R" (mkdyd "+" (mknm "R") (mknm "i"))) (mkasg "i" (mkdyd "+" (mknm "i") (mknum 1))) (mkbr (mkdyd "×" (mkdyd "≤" (mknm "i") (mknm "W")) (mknum 3)))) :alpha nil} nil (apl-scalar 5)))
(list 15))
(apl-test
"tradfn :If true branch"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkasg "R" (mknum 1))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
(list 1))
(apl-test
"tradfn :If false branch"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 100)) (list (mkasg "R" (mknum 1))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
(list 0))
(apl-test
"tradfn :While sum 1..N"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "i" (mknum 1)) (mkasg "R" (mknum 0)) (mkwhile (mkdyd "≤" (mknm "i") (mknm "W")) (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "i"))) (mkasg "i" (mkdyd "+" (mknm "i") (mknum 1)))))) :alpha nil} nil (apl-scalar 10)))
(list 55))
(apl-test
"tradfn :For sum elements"
(mkrv
(apl-call-tradfn
{:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 0)) (mkfor "x" (mknm "W") (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "x")))))) :alpha nil}
nil
(make-array (list 4) (list 10 20 30 40))))
(list 100))
(apl-test
"tradfn :For with empty vector"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 99)) (mkfor "x" (mknm "W") (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "x")))))) :alpha nil} nil (make-array (list 0) (list))))
(list 99))
(apl-test
"tradfn :Select dispatch hit"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mksel (mknm "W") (list (list (mknum 1) (mkasg "R" (mknum 100))) (list (mknum 2) (mkasg "R" (mknum 200))) (list (mknum 3) (mkasg "R" (mknum 300)))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 2)))
(list 200))
(apl-test
"tradfn :Select default block"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mksel (mknm "W") (list (list (mknum 1) (mkasg "R" (mknum 100))) (list (mknum 2) (mkasg "R" (mknum 200)))) (list (mkasg "R" (mknum -1))))) :alpha nil} nil (apl-scalar 99)))
(list -1))
(apl-test
"tradfn nested :If"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkif (mkdyd ">" (mknm "W") (mknum 10)) (list (mkasg "R" (mknum 2))) (list (mkasg "R" (mknum 1))))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
(list 1))
(apl-test
"tradfn :If assigns persist outside"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 0)) (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkasg "R" (mknum 42))) (list)) (mkasg "R" (mkdyd "+" (mknm "R") (mknum 1)))) :alpha nil} nil (apl-scalar 5)))
(list 43))
(apl-test
"tradfn :For factorial 1..5"
(mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 1)) (mkfor "x" (mkmon "" (mknm "W")) (list (mkasg "R" (mkdyd "×" (mknm "R") (mknm "x")))))) :alpha nil} nil (apl-scalar 5)))
(list 120))
(apl-test
"tradfn :Trap normal flow (no error)"
(mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 0) (list (mkasg "R" (mknum 99))) (list (mkasg "R" (mknum -1))))) :alpha nil} nil nil))
(list 99))
(apl-test
"tradfn :Trap catches matching code"
(mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 5) (list (mkthr 5 "boom")) (list (mkasg "R" (mknum 42))))) :alpha nil} nil nil))
(list 42))
(apl-test
"tradfn :Trap catch-all (code 0)"
(mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 0) (list (mkthr 99 "any")) (list (mkasg "R" (mknum 1))))) :alpha nil} nil nil))
(list 1))
(apl-test
"tradfn :Trap catches one of many codes"
(mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 1 2 3) (list (mkthr 2 "two")) (list (mkasg "R" (mknum 22))))) :alpha nil} nil nil))
(list 22))
(apl-test
"tradfn :Trap continues to next stmt after catch"
(mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 7) (list (mkthr 7 "c")) (list (mkasg "R" (mknum 10)))) (mkasg "R" (mkdyd "+" (mknm "R") (mknum 5)))) :alpha nil} nil nil))
(list 15))

81
lib/apl/tests/valence.sx
View File

@@ -1,81 +0,0 @@
; Tests for valence detection (apl-dfn-valence, apl-tradfn-valence)
; and unified dispatch (apl-call).
(define mkrv (fn (arr) (get arr :ravel)))
(define mknum (fn (n) (list :num n)))
(define mknm (fn (s) (list :name s)))
(define mkfg (fn (g) (list :fn-glyph g)))
(define mkmon (fn (g a) (list :monad (mkfg g) a)))
(define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
(define mkasg (fn (n e) (list :assign n e)))
(define mkdfn (fn (stmts) (cons :dfn stmts)))
(apl-test
"dfn-valence niladic body=42"
(apl-dfn-valence (mkdfn (list (mknum 42))))
:niladic)
(apl-test
"dfn-valence monadic body=⍵+1"
(apl-dfn-valence (mkdfn (list (mkdyd "+" (mknm "⍵") (mknum 1)))))
:monadic)
(apl-test
"dfn-valence dyadic body=+⍵"
(apl-dfn-valence (mkdfn (list (mkdyd "+" (mknm "") (mknm "⍵")))))
:dyadic)
(apl-test
"dfn-valence dyadic mentions via local"
(apl-dfn-valence (mkdfn (list (mkasg "x" (mknm "")) (mknm "x"))))
:dyadic)
(apl-test
"dfn-valence dyadic deep nest"
(apl-dfn-valence
(mkdfn (list (mkmon "-" (mkdyd "×" (mknm "") (mknm "⍵"))))))
:dyadic)
(apl-test "tradfn-valence niladic" (apl-tradfn-valence {:result "R" :omega nil :stmts (list) :alpha nil}) :niladic)
(apl-test "tradfn-valence monadic" (apl-tradfn-valence {:result "R" :omega "W" :stmts (list) :alpha nil}) :monadic)
(apl-test "tradfn-valence dyadic" (apl-tradfn-valence {:result "R" :omega "W" :stmts (list) :alpha "L"}) :dyadic)
(apl-test
"apl-call dfn niladic"
(mkrv (apl-call (mkdfn (list (mknum 42))) nil nil))
(list 42))
(apl-test
"apl-call dfn monadic"
(mkrv
(apl-call
(mkdfn (list (mkdyd "+" (mknm "⍵") (mknum 1))))
nil
(apl-scalar 5)))
(list 6))
(apl-test
"apl-call dfn dyadic"
(mkrv
(apl-call
(mkdfn (list (mkdyd "+" (mknm "") (mknm "⍵"))))
(apl-scalar 3)
(apl-scalar 4)))
(list 7))
(apl-test
"apl-call tradfn dyadic"
(mkrv (apl-call {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 6) (apl-scalar 7)))
(list 42))
(apl-test
"apl-call tradfn monadic"
(mkrv (apl-call {:result "R" :omega "W" :stmts (list (mkasg "R" (mkmon "-" (mknm "W")))) :alpha nil} nil (apl-scalar 9)))
(list -9))
(apl-test
"apl-call tradfn niladic returns nil result"
(apl-call {:result "R" :omega nil :stmts (list) :alpha nil} nil nil)
nil)

198
lib/apl/tokenizer.sx
View File

@@ -1,198 +0,0 @@
(define apl-glyph-set
(list "+" "-" "×" "÷" "*" "⍟" "⌈" "⌊" "|" "!" "?" "○" "~" "<" "≤" "=" "≥" ">" "≠"
"≢" "≡" "∊" "∧" "" "⍱" "⍲" "," "⍪" "" "⌽" "⊖" "⍉" "↑" "↓" "⊂" "⊃" "⊆"
"" "∩" "" "⍸" "⌷" "⍋" "⍒" "⊥" "" "⊣" "⊢" "⍎" "⍕"
"" "⍵" "∇" "/" "⌿" "\\" "⍀" "¨" "⍨" "∘" "." "⍣" "⍤" "⍥" "@" "¯"))
(define apl-glyph?
(fn (ch)
(some (fn (g) (= g ch)) apl-glyph-set)))
(define apl-digit?
(fn (ch)
(and (string? ch) (>= ch "0") (<= ch "9"))))
(define apl-alpha?
(fn (ch)
(and (string? ch)
(or (and (>= ch "a") (<= ch "z"))
(and (>= ch "A") (<= ch "Z"))
(= ch "_")))))
(define
apl-tokenize
(fn
(source)
(let
((pos 0) (src-len (len source)) (tokens (list)))
(define tok-push! (fn (type value) (append! tokens {:value value :type type})))
(define
cur-sw?
(fn
(ch)
(and (< pos src-len) (starts-with? (slice source pos) ch))))
(define cur-byte (fn () (if (< pos src-len) (nth source pos) nil)))
(define advance! (fn () (set! pos (+ pos 1))))
(define consume! (fn (ch) (set! pos (+ pos (len ch)))))
(define
find-glyph
(fn
()
(let
((rem (slice source pos)))
(let
((matches (filter (fn (g) (starts-with? rem g)) apl-glyph-set)))
(if (> (len matches) 0) (first matches) nil)))))
(define
read-digits!
(fn
(acc)
(if
(and (< pos src-len) (apl-digit? (cur-byte)))
(let
((ch (cur-byte)))
(begin (advance!) (read-digits! (str acc ch))))
acc)))
(define
read-ident-cont!
(fn
()
(when
(and
(< pos src-len)
(let
((ch (cur-byte)))
(or (apl-alpha? ch) (apl-digit? ch))))
(begin (advance!) (read-ident-cont!)))))
(define
read-string!
(fn
(acc)
(cond
((>= pos src-len) acc)
((cur-sw? "'")
(if
(and (< (+ pos 1) src-len) (cur-sw? "'"))
(begin (advance!) (advance!) (read-string! (str acc "'")))
(begin (advance!) acc)))
(true
(let
((ch (cur-byte)))
(begin (advance!) (read-string! (str acc ch))))))))
(define
skip-line!
(fn
()
(when
(and (< pos src-len) (not (cur-sw? "\n")))
(begin (advance!) (skip-line!)))))
(define
scan!
(fn
()
(when
(< pos src-len)
(let
((ch (cur-byte)))
(cond
((or (= ch " ") (= ch "\t") (= ch "\r"))
(begin (advance!) (scan!)))
((= ch "\n")
(begin (advance!) (tok-push! :newline nil) (scan!)))
((cur-sw? "⍝") (begin (skip-line!) (scan!)))
((cur-sw? "⋄")
(begin (consume! "⋄") (tok-push! :diamond nil) (scan!)))
((= ch "(")
(begin (advance!) (tok-push! :lparen nil) (scan!)))
((= ch ")")
(begin (advance!) (tok-push! :rparen nil) (scan!)))
((= ch "[")
(begin (advance!) (tok-push! :lbracket nil) (scan!)))
((= ch "]")
(begin (advance!) (tok-push! :rbracket nil) (scan!)))
((= ch "{")
(begin (advance!) (tok-push! :lbrace nil) (scan!)))
((= ch "}")
(begin (advance!) (tok-push! :rbrace nil) (scan!)))
((= ch ";")
(begin (advance!) (tok-push! :semi nil) (scan!)))
((cur-sw? "←")
(begin (consume! "←") (tok-push! :assign nil) (scan!)))
((= ch ":")
(let
((start pos))
(begin
(advance!)
(if
(and (< pos src-len) (apl-alpha? (cur-byte)))
(begin
(read-ident-cont!)
(tok-push! :keyword (slice source start pos)))
(tok-push! :colon nil))
(scan!))))
((and (cur-sw? "¯") (< (+ pos (len "¯")) src-len) (apl-digit? (nth source (+ pos (len "¯")))))
(begin
(consume! "¯")
(let
((digits (read-digits! "")))
(if
(and
(< pos src-len)
(= (cur-byte) ".")
(< (+ pos 1) src-len)
(apl-digit? (nth source (+ pos 1))))
(begin
(advance!)
(let
((frac (read-digits! "")))
(tok-push!
:num (- 0 (string->number (str digits "." frac))))))
(tok-push! :num (- 0 (parse-int digits 0)))))
(scan!)))
((apl-digit? ch)
(begin
(let
((digits (read-digits! "")))
(if
(and
(< pos src-len)
(= (cur-byte) ".")
(< (+ pos 1) src-len)
(apl-digit? (nth source (+ pos 1))))
(begin
(advance!)
(let
((frac (read-digits! "")))
(tok-push!
:num (string->number (str digits "." frac)))))
(tok-push! :num (parse-int digits 0))))
(scan!)))
((= ch "'")
(begin
(advance!)
(let ((s (read-string! ""))) (tok-push! :str s))
(scan!)))
((or (apl-alpha? ch) (cur-sw? "⎕"))
(let
((start pos))
(begin
(if
(cur-sw? "⎕")
(begin
(consume! "⎕")
(if
(and (< pos src-len) (cur-sw? "←"))
(consume! "←")
(read-ident-cont!)))
(begin (advance!) (read-ident-cont!)))
(tok-push! :name (slice source start pos))
(scan!))))
(true
(let
((g (find-glyph)))
(if
g
(begin (consume! g) (tok-push! :glyph g) (scan!))
(begin (advance!) (scan!))))))))))
(scan!)
tokens)))

592
lib/apl/transpile.sx
View File

@@ -1,592 +0,0 @@
; APL transpile / AST evaluator
;
; Walks parsed AST nodes and evaluates against the runtime.
; Entry points:
; apl-eval-ast : node × env → value
; apl-eval-stmts : stmt-list × env → value (handles guards, locals, ⍺← default)
; apl-call-dfn : dfn-ast × × ⍵ → value (dyadic)
; apl-call-dfn-m : dfn-ast × ⍵ → value (monadic)
;
; Env is a dict; stored under "alpha", ⍵ under "omega",
; the dfn-ast itself under "nabla" (for ∇ recursion),
; user names under their literal name.
(define
apl-monadic-fn
(fn
(g)
(cond
((= g "+") apl-plus-m)
((= g "-") apl-neg-m)
((= g "×") apl-signum)
((= g "÷") apl-recip)
((= g "⌈") apl-ceil)
((= g "⌊") apl-floor)
((= g "") apl-iota)
((= g "|") apl-abs)
((= g "*") apl-exp)
((= g "⍟") apl-ln)
((= g "!") apl-fact)
((= g "○") apl-pi-times)
((= g "~") apl-not)
((= g "≢") apl-tally)
((= g "") apl-shape)
((= g "≡") apl-depth)
((= g "⊂") apl-enclose)
((= g "⊃") apl-disclose)
((= g ",") apl-ravel)
((= g "⌽") apl-reverse)
((= g "⊖") apl-reverse-first)
((= g "⍋") apl-grade-up)
((= g "⍒") apl-grade-down)
((= g "?") apl-roll)
((= g "⍉") apl-transpose)
((= g "⊢") (fn (a) a))
((= g "⊣") (fn (a) a))
((= g "⍕") apl-quad-fmt)
((= g "⎕FMT") apl-quad-fmt)
((= g "⎕←") apl-quad-print)
((= g "⍸") apl-where)
((= g "") apl-unique)
((= g "⍎") apl-execute)
(else (error "no monadic fn for glyph")))))
(define
apl-dyadic-fn
(fn
(g)
(cond
((= g "+") apl-add)
((= g "-") apl-sub)
((= g "×") apl-mul)
((= g "÷") apl-div)
((= g "⌈") apl-max)
((= g "⌊") apl-min)
((= g "*") apl-pow)
((= g "⍟") apl-log)
((= g "|") apl-mod)
((= g "!") apl-binomial)
((= g "○") apl-trig)
((= g "<") apl-lt)
((= g "≤") apl-le)
((= g "=") apl-eq)
((= g "≥") apl-ge)
((= g ">") apl-gt)
((= g "≠") apl-ne)
((= g "∧") apl-and)
((= g "") apl-or)
((= g "⍱") apl-nor)
((= g "⍲") apl-nand)
((= g ",") apl-catenate)
((= g "⍪") apl-catenate-first)
((= g "") apl-reshape)
((= g "↑") apl-take)
((= g "↓") apl-drop)
((= g "⌷") apl-squad)
((= g "⌽") apl-rotate)
((= g "⊖") apl-rotate-first)
((= g "∊") apl-member)
((= g "") apl-index-of)
((= g "~") apl-without)
((= g "/") apl-compress)
((= g "⌿") apl-compress-first)
((= g "⍉") apl-transpose-dyadic)
((= g "⊢") (fn (a b) b))
((= g "⊣") (fn (a b) a))
((= g "⍸") apl-interval-index)
((= g "") apl-union)
((= g "∩") apl-intersect)
((= g "⊥") apl-decode)
((= g "") apl-encode)
((= g "⊆") apl-partition)
(else (error "no dyadic fn for glyph")))))
(define
apl-truthy?
(fn
(v)
(let
((rv (get v :ravel)))
(if (and (= (len rv) 1) (= (first rv) 0)) false true))))
(define
apl-eval-ast
(fn
(node env)
(let
((tag (first node)))
(cond
((= tag :num) (apl-scalar (nth node 1)))
((= tag :str)
(let
((s (nth node 1)))
(if
(= (len s) 1)
(apl-scalar s)
(make-array
(list (len s))
(map (fn (i) (slice s i (+ i 1))) (range 0 (len s)))))))
((= tag :vec)
(let
((items (rest node)))
(let
((vals (map (fn (n) (apl-eval-ast n env)) items)))
(make-array
(list (len vals))
(map
(fn
(v)
(if
(= (len (get v :shape)) 0)
(first (get v :ravel))
v))
vals)))))
((= tag :name)
(let
((nm (nth node 1)))
(cond
((= nm "")
(let
((v (get env "")))
(if (= v nil) (get env "alpha") v)))
((= nm "⍵")
(let
((v (get env "⍵")))
(if (= v nil) (get env "omega") v)))
((= nm "⎕IO") (apl-quad-io))
((= nm "⎕ML") (apl-quad-ml))
((= nm "⎕FR") (apl-quad-fr))
((= nm "⎕TS") (apl-quad-ts))
(else (get env nm)))))
((= tag :monad)
(let
((fn-node (nth node 1)) (arg (nth node 2)))
(if
(and (= (first fn-node) :fn-glyph) (= (nth fn-node 1) "∇"))
(apl-call-dfn-m (get env "nabla") (apl-eval-ast arg env))
(let
((arg-val (apl-eval-ast arg env)))
(let
((new-env (if (and (list? arg) (> (len arg) 0) (= (first arg) :assign-expr)) (assoc env (nth arg 1) arg-val) env)))
((apl-resolve-monadic fn-node new-env) arg-val))))))
((= tag :dyad)
(let
((fn-node (nth node 1))
(lhs (nth node 2))
(rhs (nth node 3)))
(if
(and (= (first fn-node) :fn-glyph) (= (nth fn-node 1) "∇"))
(apl-call-dfn
(get env "nabla")
(apl-eval-ast lhs env)
(apl-eval-ast rhs env))
(let
((rhs-val (apl-eval-ast rhs env)))
(let
((new-env (if (and (list? rhs) (> (len rhs) 0) (= (first rhs) :assign-expr)) (assoc env (nth rhs 1) rhs-val) env)))
((apl-resolve-dyadic fn-node new-env)
(apl-eval-ast lhs new-env)
rhs-val))))))
((= tag :program) (apl-eval-stmts (rest node) env))
((= tag :dfn) node)
((= tag :bracket)
(let
((arr-expr (nth node 1)) (axis-exprs (rest (rest node))))
(let
((arr (apl-eval-ast arr-expr env))
(axes
(map
(fn (a) (if (= a :all) nil (apl-eval-ast a env)))
axis-exprs)))
(apl-bracket-multi axes arr))))
((= tag :assign-expr) (apl-eval-ast (nth node 2) env))
((= tag :assign) (apl-eval-ast (nth node 2) env))
(else (error (list "apl-eval-ast: unknown node tag" tag node)))))))
(define
apl-eval-stmts
(fn
(stmts env)
(if
(= (len stmts) 0)
nil
(let
((stmt (first stmts)) (more (rest stmts)))
(let
((tag (first stmt)))
(cond
((= tag :guard)
(let
((cond-val (apl-eval-ast (nth stmt 1) env)))
(if
(apl-truthy? cond-val)
(apl-eval-ast (nth stmt 2) env)
(apl-eval-stmts more env))))
((and (= tag :assign) (= (nth stmt 1) ""))
(if
(get env "alpha")
(apl-eval-stmts more env)
(let
((v (apl-eval-ast (nth stmt 2) env)))
(apl-eval-stmts more (assoc env "alpha" v)))))
((= tag :assign)
(let
((v (apl-eval-ast (nth stmt 2) env)))
(apl-eval-stmts more (assoc env (nth stmt 1) v))))
((= (len more) 0) (apl-eval-ast stmt env))
(else (begin (apl-eval-ast stmt env) (apl-eval-stmts more env)))))))))
(define
apl-call-dfn
(fn
(dfn-ast alpha omega)
(let
((stmts (rest dfn-ast)) (env {:omega omega :nabla dfn-ast :alpha alpha}))
(apl-eval-stmts stmts env))))
(define
apl-call-dfn-m
(fn
(dfn-ast omega)
(let
((stmts (rest dfn-ast)) (env {:omega omega :nabla dfn-ast :alpha nil}))
(apl-eval-stmts stmts env))))
(define
apl-tradfn-eval-block
(fn
(stmts env)
(if
(= (len stmts) 0)
env
(let
((stmt (first stmts)))
(apl-tradfn-eval-block (rest stmts) (apl-tradfn-eval-stmt stmt env))))))
(define
apl-tradfn-eval-while
(fn
(cond-expr body env)
(let
((cond-val (apl-eval-ast cond-expr env)))
(if
(apl-truthy? cond-val)
(apl-tradfn-eval-while
cond-expr
body
(apl-tradfn-eval-block body env))
env))))
(define
apl-tradfn-eval-for
(fn
(var-name items body env)
(if
(= (len items) 0)
env
(let
((env-with-var (assoc env var-name (apl-scalar (first items)))))
(apl-tradfn-eval-for
var-name
(rest items)
body
(apl-tradfn-eval-block body env-with-var))))))
(define
apl-tradfn-eval-select
(fn
(val cases default-block env)
(if
(= (len cases) 0)
(apl-tradfn-eval-block default-block env)
(let
((c (first cases)))
(let
((case-val (apl-eval-ast (first c) env)))
(if
(= (first (get val :ravel)) (first (get case-val :ravel)))
(apl-tradfn-eval-block (rest c) env)
(apl-tradfn-eval-select val (rest cases) default-block env)))))))
(define
apl-tradfn-eval-stmt
(fn
(stmt env)
(let
((tag (first stmt)))
(cond
((= tag :assign)
(assoc env (nth stmt 1) (apl-eval-ast (nth stmt 2) env)))
((= tag :if)
(let
((cond-val (apl-eval-ast (nth stmt 1) env)))
(if
(apl-truthy? cond-val)
(apl-tradfn-eval-block (nth stmt 2) env)
(apl-tradfn-eval-block (nth stmt 3) env))))
((= tag :while)
(apl-tradfn-eval-while (nth stmt 1) (nth stmt 2) env))
((= tag :for)
(let
((iter-val (apl-eval-ast (nth stmt 2) env)))
(apl-tradfn-eval-for
(nth stmt 1)
(get iter-val :ravel)
(nth stmt 3)
env)))
((= tag :select)
(let
((val (apl-eval-ast (nth stmt 1) env)))
(apl-tradfn-eval-select val (nth stmt 2) (nth stmt 3) env)))
((= tag :trap)
(let
((codes (nth stmt 1))
(try-block (nth stmt 2))
(catch-block (nth stmt 3)))
(guard
(e
((apl-trap-matches? codes e)
(apl-tradfn-eval-block catch-block env)))
(apl-tradfn-eval-block try-block env))))
((= tag :throw) (apl-throw (nth stmt 1) (nth stmt 2)))
(else (begin (apl-eval-ast stmt env) env))))))
(define
apl-tradfn-loop
(fn
(stmts line env result-name)
(cond
((= line 0) (get env result-name))
((> line (len stmts)) (get env result-name))
(else
(let
((stmt (nth stmts (- line 1))))
(let
((tag (first stmt)))
(cond
((= tag :branch)
(let
((target (apl-eval-ast (nth stmt 1) env)))
(let
((target-num (first (get target :ravel))))
(apl-tradfn-loop stmts target-num env result-name))))
(else
(apl-tradfn-loop
stmts
(+ line 1)
(apl-tradfn-eval-stmt stmt env)
result-name)))))))))
(define
apl-call-tradfn
(fn
(tradfn alpha omega)
(let
((stmts (get tradfn :stmts))
(result-name (get tradfn :result))
(alpha-name (get tradfn :alpha))
(omega-name (get tradfn :omega)))
(let
((env-a (if alpha-name (assoc {} alpha-name alpha) {})))
(let
((env-ao (if omega-name (assoc env-a omega-name omega) env-a)))
(apl-tradfn-loop stmts 1 env-ao result-name))))))
(define
apl-ast-mentions-list?
(fn
(lst target)
(if
(= (len lst) 0)
false
(if
(apl-ast-mentions? (first lst) target)
true
(apl-ast-mentions-list? (rest lst) target)))))
(define
apl-ast-mentions?
(fn
(node target)
(cond
((not (list? node)) false)
((= (len node) 0) false)
((and (= (first node) :name) (= (nth node 1) target)) true)
(else (apl-ast-mentions-list? (rest node) target)))))
(define
apl-dfn-valence
(fn
(dfn-ast)
(let
((body (rest dfn-ast)))
(cond
((apl-ast-mentions-list? body "") :dyadic)
((apl-ast-mentions-list? body "⍵") :monadic)
(else :niladic)))))
(define
apl-tradfn-valence
(fn
(tradfn)
(cond
((get tradfn :alpha) :dyadic)
((get tradfn :omega) :monadic)
(else :niladic))))
(define
apl-call
(fn
(f alpha omega)
(cond
((and (list? f) (> (len f) 0) (= (first f) :dfn))
(if alpha (apl-call-dfn f alpha omega) (apl-call-dfn-m f omega)))
((dict? f) (apl-call-tradfn f alpha omega))
(else (error "apl-call: not a function")))))
(define
apl-resolve-monadic
(fn
(fn-node env)
(let
((tag (first fn-node)))
(cond
((= tag :fn-glyph) (apl-monadic-fn (nth fn-node 1)))
((= tag :derived-fn)
(let
((op (nth fn-node 1)) (inner (nth fn-node 2)))
(cond
((= op "/")
(let
((f (apl-resolve-dyadic inner env)))
(fn (arr) (apl-reduce f arr))))
((= op "⌿")
(let
((f (apl-resolve-dyadic inner env)))
(fn (arr) (apl-reduce-first f arr))))
((= op "\\")
(let
((f (apl-resolve-dyadic inner env)))
(fn (arr) (apl-scan f arr))))
((= op "⍀")
(let
((f (apl-resolve-dyadic inner env)))
(fn (arr) (apl-scan-first f arr))))
((= op "¨")
(let
((f (apl-resolve-monadic inner env)))
(fn (arr) (apl-each f arr))))
((= op "⍨")
(let
((f (apl-resolve-dyadic inner env)))
(fn (arr) (apl-commute f arr))))
(else (error "apl-resolve-monadic: unsupported op")))))
((= tag :fn-name)
(let
((nm (nth fn-node 1)))
(let
((bound (get env nm)))
(if
(and
(list? bound)
(> (len bound) 0)
(= (first bound) :dfn))
(fn (arg) (apl-call-dfn-m bound arg))
(error "apl-resolve-monadic: name not bound to dfn")))))
((= tag :train)
(let
((fns (rest fn-node)))
(let
((n (len fns)))
(cond
((= n 2)
(let
((g (apl-resolve-monadic (nth fns 0) env))
(h (apl-resolve-monadic (nth fns 1) env)))
(fn (arg) (g (h arg)))))
((= n 3)
(let
((f (apl-resolve-monadic (nth fns 0) env))
(g (apl-resolve-dyadic (nth fns 1) env))
(h (apl-resolve-monadic (nth fns 2) env)))
(fn (arg) (g (f arg) (h arg)))))
(else (error "monadic train arity not 2 or 3"))))))
(else (error "apl-resolve-monadic: unknown fn-node tag"))))))
(define
apl-resolve-dyadic
(fn
(fn-node env)
(let
((tag (first fn-node)))
(cond
((= tag :fn-glyph) (apl-dyadic-fn (nth fn-node 1)))
((= tag :derived-fn)
(let
((op (nth fn-node 1)) (inner (nth fn-node 2)))
(cond
((= op "¨")
(let
((f (apl-resolve-dyadic inner env)))
(fn (a b) (apl-each-dyadic f a b))))
((= op "⍨")
(let
((f (apl-resolve-dyadic inner env)))
(fn (a b) (apl-commute-dyadic f a b))))
(else (error "apl-resolve-dyadic: unsupported op")))))
((= tag :fn-name)
(let
((nm (nth fn-node 1)))
(let
((bound (get env nm)))
(if
(and
(list? bound)
(> (len bound) 0)
(= (first bound) :dfn))
(fn (a b) (apl-call-dfn bound a b))
(error "apl-resolve-dyadic: name not bound to dfn")))))
((= tag :outer)
(let
((inner (nth fn-node 2)))
(let
((f (apl-resolve-dyadic inner env)))
(fn (a b) (apl-outer f a b)))))
((= tag :derived-fn2)
(let
((f-node (nth fn-node 2)) (g-node (nth fn-node 3)))
(let
((f (apl-resolve-dyadic f-node env))
(g (apl-resolve-dyadic g-node env)))
(fn (a b) (apl-inner f g a b)))))
((= tag :train)
(let
((fns (rest fn-node)))
(let
((n (len fns)))
(cond
((= n 2)
(let
((g (apl-resolve-monadic (nth fns 0) env))
(h (apl-resolve-dyadic (nth fns 1) env)))
(fn (a b) (g (h a b)))))
((= n 3)
(let
((f (apl-resolve-dyadic (nth fns 0) env))
(g (apl-resolve-dyadic (nth fns 1) env))
(h (apl-resolve-dyadic (nth fns 2) env)))
(fn (a b) (g (f a b) (h a b)))))
(else (error "dyadic train arity not 2 or 3"))))))
(else (error "apl-resolve-dyadic: unknown fn-node tag"))))))
(define apl-run (fn (src) (apl-eval-ast (parse-apl src) {})))
(define apl-run-file (fn (path) (apl-run (file-read path))))
(define
apl-execute
(fn
(arr)
(let
((src (cond ((string? arr) arr) ((scalar? arr) (disclose arr)) (else (reduce str "" (get arr :ravel))))))
(apl-run src))))

207
lib/common-lisp/tests/runtime.sx
View File

@@ -1,207 +0,0 @@
;; 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))))

266
lib/hyperscript/compiler.sx
View File

@@ -48,15 +48,6 @@
prop
value))
(list (quote hs-query-all) (nth base-ast 1))))
((and (list? base-ast) (= (first base-ast) (quote query)))
(list
(quote dom-set-prop)
(list
(quote hs-named-target)
(nth base-ast 1)
(list (quote hs-query-first) (nth base-ast 1)))
prop
value))
((and (list? base-ast) (= (first base-ast) dot-sym) (let ((inner (nth base-ast 1))) (and (list? inner) (= (first inner) (quote query)) (let ((s (nth inner 1))) (and (string? s) (> (len s) 0) (= (substring s 0 1) "."))))))
(let
((inner (nth base-ast 1))
@@ -155,14 +146,6 @@
(nth prop-ast 1)
value)
(list (quote set!) (hs-to-sx target) value))))))
((= th (quote query))
(list
(quote hs-set-inner-html!)
(list
(quote hs-named-target)
(nth target 1)
(list (quote hs-query-first) (nth target 1)))
value))
(true (list (quote set!) (hs-to-sx target) value)))))))
(define
emit-on
@@ -291,33 +274,17 @@
((name (nth ast 1)) (rest-parts (rest (rest ast))))
(cond
((and (= (len ast) 4) (list? (nth ast 2)) (= (first (nth ast 2)) (quote dict)))
(let
((tgt-ast (nth ast 3)))
(list
(quote dom-dispatch)
(if
(and (list? tgt-ast) (= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))
(hs-to-sx (nth ast 3))
name
(hs-to-sx (nth ast 2)))))
(hs-to-sx (nth ast 2))))
((= (len ast) 3)
(let
((tgt-ast (nth ast 2)))
(list
(quote dom-dispatch)
(if
(and (list? tgt-ast) (= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))
(hs-to-sx (nth ast 2))
name
(list (quote dict) "sender" (quote me)))))
(list (quote dict) "sender" (quote me))))
(true
(list
(quote dom-dispatch)
@@ -739,33 +706,6 @@
(quote fn)
(cons (quote me) (map make-symbol params))
(cons (quote do) (map hs-to-sx body)))))))
(define
hs-safe-obj
(fn
(obj-ast)
(if
(and (list? obj-ast) (= (first obj-ast) (quote ref)))
(list (quote host-global) (nth obj-ast 1))
(if
(and (list? obj-ast) (= (first obj-ast) dot-sym))
(let
((inner (nth obj-ast 1)) (prop (nth obj-ast 2)))
(list (quote host-get) (hs-safe-obj inner) prop))
(hs-to-sx obj-ast)))))
(define
hs-chain-name
(fn
(obj-ast)
(if
(and (list? obj-ast) (= (first obj-ast) (quote ref)))
(nth obj-ast 1)
(if
(and (list? obj-ast) (= (first obj-ast) dot-sym))
(str (hs-chain-name (nth obj-ast 1)) "." (nth obj-ast 2))
(if
(and (list? obj-ast) (= (first obj-ast) (quote query)))
(nth obj-ast 1)
nil)))))
(fn
(ast)
(cond
@@ -1285,22 +1225,13 @@
((raw-tgt (nth ast 2)))
(if
(and (list? raw-tgt) (= (first raw-tgt) (quote query)))
(list
(quote let)
(list
(list
(quote _tgt)
(list (quote hs-query-named-all) (nth raw-tgt 1))))
(list
(quote for-each)
(list
(quote fn)
(list (quote _el))
(list
(quote dom-add-class)
(quote _el)
(nth ast 1)))
(quote _tgt)))
(list (quote dom-add-class) (quote _el) (nth ast 1)))
(list (quote hs-query-all) (nth raw-tgt 1)))
(list
(quote dom-add-class)
(hs-to-sx raw-tgt)
@@ -1313,20 +1244,14 @@
(nth ast 2)))
((= head (quote set-styles))
(let
((pairs (nth ast 1)) (tgt-ast (nth ast 2)))
(let
((tgt (if (and (list? tgt-ast) (= (first tgt-ast) (quote query))) (list (quote hs-named-target) (nth tgt-ast 1) (list (quote hs-query-first) (nth tgt-ast 1))) (hs-to-sx tgt-ast))))
((pairs (nth ast 1)) (tgt (hs-to-sx (nth ast 2))))
(cons
(quote do)
(map
(fn
(p)
(list
(quote dom-set-style)
tgt
(first p)
(nth p 1)))
pairs)))))
(list (quote dom-set-style) tgt (first p) (nth p 1)))
pairs))))
((= head (quote multi-add-class))
(let
((target (hs-to-sx (nth ast 1)))
@@ -1423,12 +1348,6 @@
((raw-tgt (nth ast 2)))
(if
(and (list? raw-tgt) (= (first raw-tgt) (quote query)))
(list
(quote let)
(list
(list
(quote _tgt)
(list (quote hs-query-named-all) (nth raw-tgt 1))))
(list
(quote for-each)
(list
@@ -1438,7 +1357,7 @@
(quote dom-remove-class)
(quote _el)
(nth ast 1)))
(quote _tgt)))
(list (quote hs-query-all) (nth raw-tgt 1)))
(list
(quote dom-remove-class)
(if (nil? raw-tgt) (quote me) (hs-to-sx raw-tgt))
@@ -1482,32 +1401,15 @@
((tgt (nth ast 3)))
(list
(quote hs-set-attr!)
(if
(and (list? tgt) (= (first tgt) (quote query)))
(list
(quote hs-named-target)
(nth tgt 1)
(list (quote hs-query-first) (nth tgt 1)))
(hs-to-sx tgt))
(hs-to-sx tgt)
(nth ast 1)
(hs-to-sx (nth ast 2)))))
((= head (quote remove-value))
(let
((val (hs-to-sx (nth ast 1))) (raw-tgt (nth ast 2)))
((val (hs-to-sx (nth ast 1))) (tgt (nth ast 2)))
(emit-set
raw-tgt
(list
(quote hs-remove-from!)
val
(if
(and
(list? raw-tgt)
(= (first raw-tgt) (quote query)))
(list
(quote hs-named-target)
(nth raw-tgt 1)
(list (quote hs-query-first) (nth raw-tgt 1)))
(hs-to-sx raw-tgt))))))
tgt
(list (quote hs-remove-from!) val (hs-to-sx tgt)))))
((= head (quote empty-target))
(let
((tgt (nth ast 1)))
@@ -1538,19 +1440,8 @@
(hs-to-sx (nth ast 2))))
((= head (quote remove-attr))
(let
((raw-tgt (nth ast 2)))
(list
(quote dom-remove-attr)
(if
(and
(list? raw-tgt)
(= (first raw-tgt) (quote query)))
(list
(quote hs-named-target)
(nth raw-tgt 1)
(list (quote hs-query-first) (nth raw-tgt 1)))
(if (nil? raw-tgt) (quote me) (hs-to-sx raw-tgt)))
(nth ast 1))))
((tgt (if (nil? (nth ast 2)) (quote me) (hs-to-sx (nth ast 2)))))
(list (quote dom-remove-attr) tgt (nth ast 1))))
((= head (quote remove-css))
(let
((tgt (if (nil? (nth ast 2)) (quote me) (hs-to-sx (nth ast 2))))
@@ -1561,20 +1452,10 @@
(fn (p) (list (quote dom-set-style) tgt p ""))
props))))
((= head (quote toggle-class))
(let
((tgt-ast (nth ast 2)))
(list
(quote hs-toggle-class!)
(if
(and
(list? tgt-ast)
(= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))
(nth ast 1))))
(hs-to-sx (nth ast 2))
(nth ast 1)))
((= head (quote toggle-class-for))
(list
(quote do)
@@ -1629,21 +1510,11 @@
(hs-to-sx tgt-ast)
(hs-to-sx val-ast)))))
((= head (quote toggle-between))
(let
((tgt-ast (nth ast 3)))
(list
(quote hs-toggle-between!)
(if
(and
(list? tgt-ast)
(= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))
(hs-to-sx (nth ast 3))
(nth ast 1)
(nth ast 2))))
(nth ast 2)))
((= head (quote toggle-style))
(let
((raw-tgt (nth ast 2)))
@@ -1667,20 +1538,10 @@
(quote list)
(map hs-to-sx (slice ast 3 (len ast))))))
((= head (quote toggle-attr))
(let
((tgt-ast (nth ast 2)))
(list
(quote hs-toggle-attr!)
(if
(and
(list? tgt-ast)
(= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))
(nth ast 1))))
(hs-to-sx (nth ast 2))
(nth ast 1)))
((= head (quote toggle-attr-between))
(list
(quote hs-toggle-attr-between!)
@@ -1714,22 +1575,7 @@
(emit-set
raw-tgt
(list (quote hs-put-at!) val pos (hs-to-sx raw-tgt))))
(true
(let
((tgt-ast raw-tgt))
(list
(quote hs-put!)
val
pos
(if
(and
(list? tgt-ast)
(= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast))))))))
(true (list (quote hs-put!) val pos (hs-to-sx raw-tgt))))))
((= head (quote if))
(if
(> (len ast) 3)
@@ -1805,22 +1651,12 @@
(detail (if (= (len ast) 4) (nth ast 2) nil)))
(list
(quote dom-dispatch)
(let
((tgt-ast tgt))
(if
(and
(list? tgt-ast)
(= (first tgt-ast) (quote query)))
(list
(quote hs-named-target)
(nth tgt-ast 1)
(list (quote hs-query-first) (nth tgt-ast 1)))
(hs-to-sx tgt-ast)))
(hs-to-sx tgt)
name
(if has-detail (hs-to-sx detail) nil))))
((= head (quote hide))
(let
((tgt (let ((raw-tgt (nth ast 1))) (if (and (list? raw-tgt) (= (first raw-tgt) (quote query))) (list (quote hs-query-named-all) (nth raw-tgt 1)) (hs-to-sx raw-tgt))))
((tgt (let ((raw-tgt (nth ast 1))) (if (and (list? raw-tgt) (= (first raw-tgt) (quote query))) (list (quote hs-query-all) (nth raw-tgt 1)) (hs-to-sx raw-tgt))))
(strategy (if (> (len ast) 2) (nth ast 2) "display"))
(when-cond (if (> (len ast) 3) (nth ast 3) nil)))
(if
@@ -1836,7 +1672,7 @@
(hs-to-sx when-cond))))))
((= head (quote show))
(let
((tgt (let ((raw-tgt (nth ast 1))) (if (and (list? raw-tgt) (= (first raw-tgt) (quote query))) (list (quote hs-query-named-all) (nth raw-tgt 1)) (hs-to-sx raw-tgt))))
((tgt (let ((raw-tgt (nth ast 1))) (if (and (list? raw-tgt) (= (first raw-tgt) (quote query))) (list (quote hs-query-all) (nth raw-tgt 1)) (hs-to-sx raw-tgt))))
(strategy (if (> (len ast) 2) (nth ast 2) "display"))
(when-cond (if (> (len ast) 3) (nth ast 3) nil)))
(if
@@ -1899,28 +1735,13 @@
((= head (quote call))
(let
((raw-fn (nth ast 1))
(args (map hs-to-sx (rest (rest ast)))))
(fn-expr
(if
(and (list? raw-fn) (= (first raw-fn) (quote ref)))
(let
((name (nth raw-fn 1)))
(list
(quote let)
(list
(list
(quote __hs-fn)
(list (quote host-global) name)))
(cons
(quote do)
(list
(list
(quote if)
(list (quote nil?) (quote __hs-fn))
(list (quote raise) (str "'" name "' is null"))
(cons (quote __hs-fn) args))))))
(let
((fn-expr (if (string? raw-fn) (make-symbol raw-fn) (hs-to-sx raw-fn))))
(cons fn-expr args)))))
(string? raw-fn)
(make-symbol raw-fn)
(hs-to-sx raw-fn)))
(args (map hs-to-sx (rest (rest ast)))))
(cons fn-expr args)))
((= head (quote return))
(let
((val (nth ast 1)))
@@ -1933,22 +1754,7 @@
((= head (quote throw))
(list (quote raise) (hs-to-sx (nth ast 1))))
((= head (quote settle))
(let
((raw-tgt (nth ast 1)))
(list
(quote hs-settle)
(if
(nil? raw-tgt)
(quote me)
(if
(and
(list? raw-tgt)
(= (first raw-tgt) (quote query)))
(list
(quote hs-named-target)
(nth raw-tgt 1)
(list (quote hs-query-first) (nth raw-tgt 1)))
(hs-to-sx raw-tgt))))))
(list (quote hs-settle) (quote me)))
((= head (quote go))
(list (quote hs-navigate!) (hs-to-sx (nth ast 1))))
((= head (quote ask))
@@ -2068,11 +1874,7 @@
((= head (quote install))
(cons (quote hs-install) (map hs-to-sx (rest ast))))
((= head (quote measure))
(let
((raw-tgt (nth ast 1)))
(let
((compiled-tgt (if (and (list? raw-tgt) (= (first raw-tgt) (quote query))) (list (quote hs-named-target) (nth raw-tgt 1) (list (quote hs-query-first) (nth raw-tgt 1))) (hs-to-sx raw-tgt))))
(list (quote hs-measure) compiled-tgt))))
(list (quote hs-measure) (hs-to-sx (nth ast 1))))
((= head (quote increment!))
(if
(= (len ast) 3)

11
lib/hyperscript/parser.sx
View File

@@ -2455,16 +2455,7 @@
((and (= typ "keyword") (= val "answer"))
(do (adv!) (parse-answer-cmd)))
((and (= typ "keyword") (= val "settle"))
(do
(adv!)
(if
(or
(at-end?)
(and
(= (tp-type) "keyword")
(or (= (tp-val) "then") (= (tp-val) "end"))))
(list (quote settle))
(list (quote settle) (parse-expr)))))
(do (adv!) (list (quote settle))))
((and (= typ "keyword") (= val "go"))
(do (adv!) (parse-go-cmd)))
((and (= typ "keyword") (= val "return"))

289
lib/hyperscript/runtime.sx
View File

@@ -12,14 +12,37 @@
;; Register an event listener. Returns unlisten function.
;; (hs-on target event-name handler) → unlisten-fn
(begin
(define _hs-config-log-all false)
(define _hs-log-captured (list))
(define
hs-set-log-all!
(fn (flag) (set! _hs-config-log-all (if flag true false))))
(define hs-get-log-captured (fn () _hs-log-captured))
(define
hs-clear-log-captured!
(fn () (begin (set! _hs-log-captured (list)) nil)))
(define
hs-log-event!
(fn
(msg)
(when
_hs-config-log-all
(begin
(set! _hs-log-captured (append _hs-log-captured (list msg)))
(host-call (host-global "console") "log" msg)
nil)))))
;; Register for every occurrence (no queuing — each fires independently).
;; Stock hyperscript queues by default; "every" disables queuing.
(define
hs-each
(fn
(target action)
(if (list? target) (for-each action target) (action target))))
;; Register for every occurrence (no queuing — each fires independently).
;; Stock hyperscript queues by default; "every" disables queuing.
;; Run an initializer function immediately.
;; (hs-init thunk) — called at element boot time
(define
hs-on
(fn
@@ -32,17 +55,17 @@
(dom-set-data target "hs-unlisteners" (append prev (list unlisten)))
unlisten))))
;; Run an initializer function immediately.
;; (hs-init thunk) — called at element boot time
(define
hs-on-every
(fn (target event-name handler) (dom-listen target event-name handler)))
;; ── Async / timing ──────────────────────────────────────────────
;; Wait for a duration in milliseconds.
;; In hyperscript, wait is async-transparent — execution pauses.
;; Here we use perform/IO suspension for true pause semantics.
(define
hs-on-every
(fn (target event-name handler) (dom-listen target event-name handler)))
;; Wait for a DOM event on a target.
;; (hs-wait-for target event-name) — suspends until event fires
(define
hs-on-intersection-attach!
(fn
@@ -58,16 +81,15 @@
(host-call observer "observe" target)
observer)))))
;; Wait for a DOM event on a target.
;; (hs-wait-for target event-name) — suspends until event fires
(define hs-init (fn (thunk) (thunk)))
;; Wait for CSS transitions/animations to settle on an element.
(define hs-wait (fn (ms) (perform (list (quote io-sleep) ms))))
(define hs-init (fn (thunk) (thunk)))
;; ── Class manipulation ──────────────────────────────────────────
;; Toggle a single class on an element.
(define hs-wait (fn (ms) (perform (list (quote io-sleep) ms))))
;; Toggle between two classes — exactly one is active at a time.
(begin
(define
hs-wait-for
@@ -80,19 +102,21 @@
(target event-name timeout-ms)
(perform (list (quote io-wait-event) target event-name timeout-ms)))))
;; Toggle between two classes — exactly one is active at a time.
(define hs-settle (fn (target) (perform (list (quote io-settle) target))))
;; Take a class from siblings — add to target, remove from others.
;; (hs-take! target cls) — like radio button class behavior
(define
hs-toggle-class!
(fn (target cls) (host-call (host-get target "classList") "toggle" cls)))
(define hs-settle (fn (target) (perform (list (quote io-settle) target))))
;; ── DOM insertion ───────────────────────────────────────────────
;; Put content at a position relative to a target.
;; pos: "into" | "before" | "after"
(define
hs-toggle-class!
(fn (target cls) (host-call (host-get target "classList") "toggle" cls)))
;; ── Navigation / traversal ──────────────────────────────────────
;; Navigate to a URL.
(define
hs-toggle-between!
(fn
@@ -102,9 +126,7 @@
(do (dom-remove-class target cls1) (dom-add-class target cls2))
(do (dom-remove-class target cls2) (dom-add-class target cls1)))))
;; ── Navigation / traversal ──────────────────────────────────────
;; Navigate to a URL.
;; Find next sibling matching a selector (or any sibling).
(define
hs-toggle-style!
(fn
@@ -128,7 +150,7 @@
(dom-set-style target prop "hidden")
(dom-set-style target prop "")))))))
;; Find next sibling matching a selector (or any sibling).
;; Find previous sibling matching a selector.
(define
hs-toggle-style-between!
(fn
@@ -140,7 +162,7 @@
(dom-set-style target prop val2)
(dom-set-style target prop val1)))))
;; Find previous sibling matching a selector.
;; First element matching selector within a scope.
(define
hs-toggle-style-cycle!
(fn
@@ -161,7 +183,7 @@
(true (find-next (rest remaining))))))
(dom-set-style target prop (find-next vals)))))
;; First element matching selector within a scope.
;; Last element matching selector.
(define
hs-take!
(fn
@@ -184,8 +206,7 @@
(when with-cls (dom-remove-class target with-cls))))
(let
((attr-val (if (> (len extra) 0) (first extra) nil))
(with-val
(if (> (len extra) 1) (nth extra 1) nil)))
(with-val (if (> (len extra) 1) (nth extra 1) nil)))
(do
(for-each
(fn
@@ -202,7 +223,7 @@
(dom-set-attr target name attr-val)
(dom-set-attr target name ""))))))))
;; Last element matching selector.
;; First/last within a specific scope.
(begin
(define
hs-element?
@@ -314,7 +335,6 @@
(dom-insert-adjacent-html target "beforeend" value)
(hs-boot-subtree! target)))))))))
;; First/last within a specific scope.
(define
hs-add-to!
(fn
@@ -327,6 +347,9 @@
(append target (list value))))
(true (do (host-call target "push" value) target)))))
;; ── Iteration ───────────────────────────────────────────────────
;; Repeat a thunk N times.
(define
hs-remove-from!
(fn
@@ -334,15 +357,9 @@
(if
(list? target)
(filter (fn (x) (not (= x value))) target)
(host-call
target
"splice"
(host-call target "indexOf" value)
1))))
(host-call target "splice" (host-call target "indexOf" value) 1))))
;; ── Iteration ───────────────────────────────────────────────────
;; Repeat a thunk N times.
;; Repeat forever (until break — relies on exception/continuation).
(define
hs-splice-at!
(fn
@@ -355,10 +372,7 @@
((i (if (< idx 0) (+ n idx) idx)))
(cond
((or (< i 0) (>= i n)) target)
(true
(concat
(slice target 0 i)
(slice target (+ i 1) n))))))
(true (concat (slice target 0 i) (slice target (+ i 1) n))))))
(do
(when
target
@@ -369,7 +383,10 @@
(host-call target "splice" i 1))))
target))))
;; Repeat forever (until break — relies on exception/continuation).
;; ── Fetch ───────────────────────────────────────────────────────
;; Fetch a URL, parse response according to format.
;; (hs-fetch url format) — format is "json" | "text" | "html"
(define
hs-index
(fn
@@ -381,10 +398,10 @@
((string? obj) (nth obj key))
(true (host-get obj key)))))
;; ── Fetch ───────────────────────────────────────────────────────
;; ── Type coercion ───────────────────────────────────────────────
;; Fetch a URL, parse response according to format.
;; (hs-fetch url format) — format is "json" | "text" | "html"
;; Coerce a value to a type by name.
;; (hs-coerce value type-name) — type-name is "Int", "Float", "String", etc.
(define
hs-put-at!
(fn
@@ -406,10 +423,10 @@
((= pos "start") (host-call target "unshift" value)))
target)))))))
;; ── Type coercion ───────────────────────────────────────────────
;; ── Object creation ─────────────────────────────────────────────
;; Coerce a value to a type by name.
;; (hs-coerce value type-name) — type-name is "Int", "Float", "String", etc.
;; Make a new object of a given type.
;; (hs-make type-name) — creates empty object/collection
(define
hs-dict-without
(fn
@@ -430,27 +447,27 @@
(host-call (host-global "Reflect") "deleteProperty" out key)
out)))))
;; ── Object creation ─────────────────────────────────────────────
;; ── Behavior installation ───────────────────────────────────────
;; Make a new object of a given type.
;; (hs-make type-name) — creates empty object/collection
;; Install a behavior on an element.
;; A behavior is a function that takes (me ...params) and sets up features.
;; (hs-install behavior-fn me ...args)
(define
hs-set-on!
(fn
(props target)
(for-each (fn (k) (host-set! target k (get props k))) (keys props))))
;; ── Behavior installation ───────────────────────────────────────
;; Install a behavior on an element.
;; A behavior is a function that takes (me ...params) and sets up features.
;; (hs-install behavior-fn me ...args)
(define hs-navigate! (fn (url) (perform (list (quote io-navigate) url))))
;; ── Measurement ─────────────────────────────────────────────────
;; Measure an element's bounding rect, store as local variables.
;; Returns a dict with x, y, width, height, top, left, right, bottom.
(define hs-navigate! (fn (url) (perform (list (quote io-navigate) url))))
;; Return the current text selection as a string. In the browser this is
;; `window.getSelection().toString()`. In the mock test runner, a test
;; setup stashes the desired selection text at `window.__test_selection`
;; and the fallback path returns that so tests can assert on the result.
(define
hs-ask
(fn
@@ -459,10 +476,11 @@
((w (host-global "window")))
(if w (host-call w "prompt" msg) nil))))
;; Return the current text selection as a string. In the browser this is
;; `window.getSelection().toString()`. In the mock test runner, a test
;; setup stashes the desired selection text at `window.__test_selection`
;; and the fallback path returns that so tests can assert on the result.
;; ── Transition ──────────────────────────────────────────────────
;; Transition a CSS property to a value, optionally with duration.
;; (hs-transition target prop value duration)
(define
hs-answer
(fn
@@ -471,11 +489,6 @@
((w (host-global "window")))
(if w (if (host-call w "confirm" msg) yes-val no-val) no-val))))
;; ── Transition ──────────────────────────────────────────────────
;; Transition a CSS property to a value, optionally with duration.
;; (hs-transition target prop value duration)
(define
hs-answer-alert
(fn
@@ -630,25 +643,25 @@
(hs-query-all sel)
(host-call target "querySelectorAll" sel))))
(define
hs-list-set
(fn
(lst idx val)
(append (take lst idx) (cons val (drop lst (+ idx 1))))))
(define
hs-to-number
(fn (v) (if (number? v) v (or (parse-number (str v)) 0))))
;; ── Sandbox/test runtime additions ──────────────────────────────
;; Property access — dot notation and .length
(define
hs-query-first
(fn (sel) (host-call (host-global "document") "querySelector" sel)))
;; ── Sandbox/test runtime additions ──────────────────────────────
;; Property access — dot notation and .length
;; DOM query stub — sandbox returns empty list
(define
hs-query-last
(fn
@@ -656,9 +669,11 @@
(let
((all (dom-query-all (dom-body) sel)))
(if (> (len all) 0) (nth all (- (len all) 1)) nil))))
;; DOM query stub — sandbox returns empty list
(define hs-first (fn (scope sel) (dom-query-all scope sel)))
;; Method dispatch — obj.method(args)
(define hs-first (fn (scope sel) (dom-query-all scope sel)))
;; ── 0.9.90 features ─────────────────────────────────────────────
;; beep! — debug logging, returns value unchanged
(define
hs-last
(fn
@@ -666,9 +681,7 @@
(let
((all (dom-query-all scope sel)))
(if (> (len all) 0) (nth all (- (len all) 1)) nil))))
;; ── 0.9.90 features ─────────────────────────────────────────────
;; beep! — debug logging, returns value unchanged
;; Property-based is — check obj.key truthiness
(define
hs-repeat-times
(fn
@@ -686,7 +699,7 @@
((= signal "hs-continue") (do-repeat (+ i 1)))
(true (do-repeat (+ i 1))))))))
(do-repeat 0)))
;; Property-based is — check obj.key truthiness
;; Array slicing (inclusive both ends)
(define
hs-repeat-forever
(fn
@@ -702,7 +715,7 @@
((= signal "hs-continue") (do-forever))
(true (do-forever))))))
(do-forever)))
;; Array slicing (inclusive both ends)
;; Collection: sorted by
(define
hs-repeat-while
(fn
@@ -715,7 +728,7 @@
((= signal "hs-break") nil)
((= signal "hs-continue") (hs-repeat-while cond-fn thunk))
(true (hs-repeat-while cond-fn thunk)))))))
;; Collection: sorted by
;; Collection: sorted by descending
(define
hs-repeat-until
(fn
@@ -727,7 +740,7 @@
((= signal "hs-continue")
(if (cond-fn) nil (hs-repeat-until cond-fn thunk)))
(true (if (cond-fn) nil (hs-repeat-until cond-fn thunk)))))))
;; Collection: sorted by descending
;; Collection: split by
(define
hs-for-each
(fn
@@ -747,7 +760,7 @@
((= signal "hs-continue") (do-loop (rest remaining)))
(true (do-loop (rest remaining))))))))
(do-loop items))))
;; Collection: split by
;; Collection: joined by
(begin
(define
hs-append
@@ -775,7 +788,7 @@
((hs-element? target)
(dom-insert-adjacent-html target "beforeend" (str value)))
(true nil)))))
;; Collection: joined by
(define
hs-sender
(fn
@@ -1297,14 +1310,10 @@
((ch (substring sel i (+ i 1))))
(cond
((= ch ".")
(do
(flush!)
(set! mode "class")
(walk (+ i 1))))
(do (flush!) (set! mode "class") (walk (+ i 1))))
((= ch "#")
(do (flush!) (set! mode "id") (walk (+ i 1))))
(true
(do (set! cur (str cur ch)) (walk (+ i 1)))))))))
(true (do (set! cur (str cur ch)) (walk (+ i 1)))))))))
(walk 0)
(flush!)
{:tag tag :classes classes :id id}))))
@@ -1389,7 +1398,6 @@
hs-strict-eq
(fn (a b) (and (= (type-of a) (type-of b)) (= a b))))
(define
hs-eq-ignore-case
(fn (a b) (= (downcase (str a)) (downcase (str b)))))
@@ -1430,10 +1438,7 @@
((and (dict? a) (dict? b))
(let
((pos (host-call a "compareDocumentPosition" b)))
(if
(number? pos)
(not (= 0 (mod (/ pos 4) 2)))
false)))
(if (number? pos) (not (= 0 (mod (/ pos 4) 2))) false)))
(true (< (str a) (str b))))))
(define
@@ -1535,10 +1540,7 @@
((and (dict? a) (dict? b))
(let
((pos (host-call a "compareDocumentPosition" b)))
(if
(number? pos)
(not (= 0 (mod (/ pos 4) 2)))
false)))
(if (number? pos) (not (= 0 (mod (/ pos 4) 2))) false)))
(true (< (str a) (str b))))))
(define
@@ -1589,9 +1591,7 @@
(define
hs-morph-char
(fn
(s p)
(if (or (< p 0) (>= p (string-length s))) nil (nth s p))))
(fn (s p) (if (or (< p 0) (>= p (string-length s))) nil (nth s p))))
(define
hs-morph-index-from
@@ -1619,10 +1619,7 @@
(q)
(let
((c (hs-morph-char s q)))
(if
(and c (< (index-of stop c) 0))
(loop (+ q 1))
q))))
(if (and c (< (index-of stop c) 0)) (loop (+ q 1)) q))))
(let ((e (loop p))) (list (substring s p e) e))))
(define
@@ -1664,9 +1661,7 @@
(append
acc
(list
(list
name
(substring s (+ p4 1) close)))))))
(list name (substring s (+ p4 1) close)))))))
((= c2 "'")
(let
((close (hs-morph-index-from s "'" (+ p4 1))))
@@ -1676,9 +1671,7 @@
(append
acc
(list
(list
name
(substring s (+ p4 1) close)))))))
(list name (substring s (+ p4 1) close)))))))
(true
(let
((r2 (hs-morph-read-until s p4 " \t\n/>")))
@@ -1762,9 +1755,7 @@
(for-each
(fn
(c)
(when
(> (string-length c) 0)
(dom-add-class el c)))
(when (> (string-length c) 0) (dom-add-class el c)))
(split v " ")))
((and keep-id (= n "id")) nil)
(true (dom-set-attr el n v)))))
@@ -1865,8 +1856,7 @@
((parts (split resolved ":")))
(let
((prop (first parts))
(val
(if (> (len parts) 1) (nth parts 1) nil)))
(val (if (> (len parts) 1) (nth parts 1) nil)))
(cond
((and (not (= prop "display")) (not (= prop "opacity")) (not (= prop "visibility")) (not (= prop "hidden")) (not (= prop "class-hidden")) (not (= prop "class-invisible")) (not (= prop "class-opacity")) (not (= prop "details")) (not (= prop "dialog")) (dict-has? _hs-hide-strategies prop))
(let
@@ -1905,8 +1895,7 @@
((parts (split resolved ":")))
(let
((prop (first parts))
(val
(if (> (len parts) 1) (nth parts 1) nil)))
(val (if (> (len parts) 1) (nth parts 1) nil)))
(cond
((and (not (= prop "display")) (not (= prop "opacity")) (not (= prop "visibility")) (not (= prop "hidden")) (not (= prop "class-hidden")) (not (= prop "class-invisible")) (not (= prop "class-opacity")) (not (= prop "details")) (not (= prop "dialog")) (dict-has? _hs-hide-strategies prop))
(let
@@ -2010,14 +1999,10 @@
(if
(= depth 1)
j
(find-close
(+ j 1)
(- depth 1)))
(find-close (+ j 1) (- depth 1)))
(if
(= (nth raw j) "{")
(find-close
(+ j 1)
(+ depth 1))
(find-close (+ j 1) (+ depth 1))
(find-close (+ j 1) depth))))))
(let
((close (find-close start 1)))
@@ -2108,10 +2093,7 @@
(if
(= (len lst) 0)
-1
(if
(= (first lst) item)
i
(idx-loop (rest lst) (+ i 1))))))
(if (= (first lst) item) i (idx-loop (rest lst) (+ i 1))))))
(idx-loop obj 0)))
(true nil))))
@@ -2197,8 +2179,7 @@
(cond
((= end "hs-pick-end") n)
((= end "hs-pick-start") 0)
((and (number? end) (< end 0))
(max 0 (+ n end)))
((and (number? end) (< end 0)) (max 0 (+ n end)))
(true end))))
(cond
((string? col) (slice col s e))
@@ -2485,50 +2466,6 @@
((nth entry 2) val)))
_hs-dom-watchers)))
(define hs-prolog-hook nil)
(define hs-set-prolog-hook! (fn (f) (set! hs-prolog-hook f)))
(define
prolog
(fn
(db goal)
(if
(nil? hs-prolog-hook)
(raise "prolog hook not installed")
(hs-prolog-hook db goal))))
(define
hs-null-error!
(fn (selector) (raise (str "'" selector "' is null"))))
(define
hs-named-target
(fn (selector value) (if (nil? value) (hs-null-error! selector) value)))
(define
hs-named-target-list
(fn
(selector values)
(if (nil? values) (hs-null-error! selector) values)))
(define
hs-query-named-all
(fn
(selector)
(let
((results (hs-query-all selector)))
(if
(and
(or
(nil? results)
(and (list? results) (= (len results) 0)))
(string? selector)
(> (len selector) 0)
(= (substring selector 0 1) "#"))
(hs-null-error! selector)
results))))
(define
hs-dom-is-ancestor?
(fn

176
lib/prolog/compiler.sx
View File

@@ -1,176 +0,0 @@
;; lib/prolog/compiler.sx — clause compiler: parse-AST clauses → SX closures
;;
;; Each compiled clause is a lambda (fn (goal trail db cut-box k) bool)
;; that creates fresh vars, builds the instantiated head/body, and calls
;; pl-unify! + pl-solve! directly — no AST walk at solve time.
;;
;; Usage:
;; (pl-db-load! db (pl-parse src))
;; (pl-compile-db! db)
;; ; pl-solve-user! in runtime.sx automatically prefers compiled clauses
;; (pl-solve-once! db goal trail)
;; Collect unique variable names from a parse-AST clause into a dict.
(define
pl-cmp-vars-into!
(fn
(ast seen)
(cond
((not (list? ast)) nil)
((empty? ast) nil)
((= (first ast) "var")
(let
((name (nth ast 1)))
(when
(and (not (= name "_")) (not (dict-has? seen name)))
(dict-set! seen name true))))
((= (first ast) "compound")
(for-each (fn (a) (pl-cmp-vars-into! a seen)) (nth ast 2)))
((= (first ast) "clause")
(begin
(pl-cmp-vars-into! (nth ast 1) seen)
(pl-cmp-vars-into! (nth ast 2) seen))))))
;; Return list of unique var names in a clause (head + body, excluding _).
(define
pl-cmp-collect-vars
(fn
(clause)
(let ((seen {})) (pl-cmp-vars-into! clause seen) (keys seen))))
;; Create a fresh runtime var for each name in the list; return name->var dict.
(define
pl-cmp-make-var-map
(fn
(var-names)
(let
((m {}))
(for-each
(fn (name) (dict-set! m name (pl-mk-rt-var name)))
var-names)
m)))
;; Instantiate a parse-AST term using a pre-built var-map.
;; ("var" "_") always gets a fresh anonymous var.
(define
pl-cmp-build-term
(fn
(ast var-map)
(cond
((pl-var? ast) ast)
((not (list? ast)) ast)
((empty? ast) ast)
((= (first ast) "var")
(let
((name (nth ast 1)))
(if (= name "_") (pl-mk-rt-var "_") (dict-get var-map name))))
((or (= (first ast) "atom") (= (first ast) "num") (= (first ast) "str"))
ast)
((= (first ast) "compound")
(list
"compound"
(nth ast 1)
(map (fn (a) (pl-cmp-build-term a var-map)) (nth ast 2))))
((= (first ast) "clause")
(list
"clause"
(pl-cmp-build-term (nth ast 1) var-map)
(pl-cmp-build-term (nth ast 2) var-map)))
(true ast))))
;; Compile one parse-AST clause to a lambda.
;; Pre-computes var names at compile time; creates fresh vars per call.
(define
pl-compile-clause
(fn
(clause)
(let
((var-names (pl-cmp-collect-vars clause))
(head-ast (nth clause 1))
(body-ast (nth clause 2)))
(fn
(goal trail db cut-box k)
(let
((var-map (pl-cmp-make-var-map var-names)))
(let
((fresh-head (pl-cmp-build-term head-ast var-map))
(fresh-body (pl-cmp-build-term body-ast var-map)))
(let
((mark (pl-trail-mark trail)))
(if
(pl-unify! goal fresh-head trail)
(let
((r (pl-solve! db fresh-body trail cut-box k)))
(if r true (begin (pl-trail-undo-to! trail mark) false)))
(begin (pl-trail-undo-to! trail mark) false)))))))))
;; Try a list of compiled clause lambdas — same cut semantics as pl-try-clauses!.
(define
pl-try-compiled-clauses!
(fn
(db
goal
trail
compiled-clauses
outer-cut-box
outer-was-cut
inner-cut-box
k)
(cond
((empty? compiled-clauses) false)
(true
(let
((r ((first compiled-clauses) goal trail db inner-cut-box k)))
(cond
(r true)
((dict-get inner-cut-box :cut) false)
((and (not outer-was-cut) (dict-get outer-cut-box :cut)) false)
(true
(pl-try-compiled-clauses!
db
goal
trail
(rest compiled-clauses)
outer-cut-box
outer-was-cut
inner-cut-box
k))))))))
;; Compile all clauses in DB and store in :compiled table.
;; After this call, pl-solve-user! will dispatch via compiled lambdas.
;; Note: clauses assert!-ed after this call are not compiled.
(define
pl-compile-db!
(fn
(db)
(let
((src-table (dict-get db :clauses)) (compiled-table {}))
(for-each
(fn
(key)
(dict-set!
compiled-table
key
(map pl-compile-clause (dict-get src-table key))))
(keys src-table))
(dict-set! db :compiled compiled-table)
db)))
;; Cross-validate: load src into both a plain and a compiled DB,
;; run goal-str through each, return true iff solution counts match.
;; Use this to keep the interpreter as the reference implementation.
(define
pl-compiled-matches-interp?
(fn
(src goal-str)
(let
((db-interp (pl-mk-db)) (db-comp (pl-mk-db)))
(pl-db-load! db-interp (pl-parse src))
(pl-db-load! db-comp (pl-parse src))
(pl-compile-db! db-comp)
(let
((gi (pl-instantiate (pl-parse-goal goal-str) {}))
(gc (pl-instantiate (pl-parse-goal goal-str) {})))
(=
(pl-solve-count! db-interp gi (pl-mk-trail))
(pl-solve-count! db-comp gc (pl-mk-trail)))))))

129
lib/prolog/conformance.sh
View File

@@ -1,129 +0,0 @@
#!/usr/bin/env bash
# Run every Prolog test suite via sx_server and refresh scoreboard.{json,md}.
# Exit 0 if all green, 1 if any failures.
set -euo pipefail
HERE="$(cd "$(dirname "$0")" && pwd)"
ROOT="$(cd "$HERE/../.." && pwd)"
SX="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
if [[ ! -x "$SX" ]]; then
echo "sx_server not found at $SX (set SX_SERVER env to override)" >&2
exit 2
fi
cd "$ROOT"
# name : test-file : runner-fn
SUITES=(
"parse:lib/prolog/tests/parse.sx:pl-parse-tests-run!"
"unify:lib/prolog/tests/unify.sx:pl-unify-tests-run!"
"clausedb:lib/prolog/tests/clausedb.sx:pl-clausedb-tests-run!"
"solve:lib/prolog/tests/solve.sx:pl-solve-tests-run!"
"operators:lib/prolog/tests/operators.sx:pl-operators-tests-run!"
"dynamic:lib/prolog/tests/dynamic.sx:pl-dynamic-tests-run!"
"findall:lib/prolog/tests/findall.sx:pl-findall-tests-run!"
"term_inspect:lib/prolog/tests/term_inspect.sx:pl-term-inspect-tests-run!"
"append:lib/prolog/tests/programs/append.sx:pl-append-tests-run!"
"reverse:lib/prolog/tests/programs/reverse.sx:pl-reverse-tests-run!"
"member:lib/prolog/tests/programs/member.sx:pl-member-tests-run!"
"nqueens:lib/prolog/tests/programs/nqueens.sx:pl-nqueens-tests-run!"
"family:lib/prolog/tests/programs/family.sx:pl-family-tests-run!"
"atoms:lib/prolog/tests/atoms.sx:pl-atom-tests-run!"
"query_api:lib/prolog/tests/query_api.sx:pl-query-api-tests-run!"
"iso_predicates:lib/prolog/tests/iso_predicates.sx:pl-iso-predicates-tests-run!"
"meta_predicates:lib/prolog/tests/meta_predicates.sx:pl-meta-predicates-tests-run!"
"list_predicates:lib/prolog/tests/list_predicates.sx:pl-list-predicates-tests-run!"
"meta_call:lib/prolog/tests/meta_call.sx:pl-meta-call-tests-run!"
"set_predicates:lib/prolog/tests/set_predicates.sx:pl-set-predicates-tests-run!"
"char_predicates:lib/prolog/tests/char_predicates.sx:pl-char-predicates-tests-run!"
"io_predicates:lib/prolog/tests/io_predicates.sx:pl-io-predicates-tests-run!"
"assert_rules:lib/prolog/tests/assert_rules.sx:pl-assert-rules-tests-run!"
"string_agg:lib/prolog/tests/string_agg.sx:pl-string-agg-tests-run!"
"advanced:lib/prolog/tests/advanced.sx:pl-advanced-tests-run!"
"compiler:lib/prolog/tests/compiler.sx:pl-compiler-tests-run!"
"cross_validate:lib/prolog/tests/cross_validate.sx:pl-cross-validate-tests-run!"
"integration:lib/prolog/tests/integration.sx:pl-integration-tests-run!"
"hs_bridge:lib/prolog/tests/hs_bridge.sx:pl-hs-bridge-tests-run!"
)
SCRIPT='(epoch 1)
(load "lib/prolog/tokenizer.sx")
(load "lib/prolog/parser.sx")
(load "lib/prolog/runtime.sx")
(load "lib/prolog/query.sx")
(load "lib/prolog/compiler.sx")
(load "lib/prolog/hs-bridge.sx")'
for entry in "${SUITES[@]}"; do
IFS=: read -r _ file _ <<< "$entry"
SCRIPT+=$'\n(load "'"$file"$'")'
done
for entry in "${SUITES[@]}"; do
IFS=: read -r _ _ fn <<< "$entry"
SCRIPT+=$'\n(eval "('"$fn"$')")'
done
OUTPUT="$(printf '%s\n' "$SCRIPT" | "$SX" 2>&1)"
mapfile -t LINES < <(printf '%s\n' "$OUTPUT" | grep -E '^\{:failed')
if [[ ${#LINES[@]} -ne ${#SUITES[@]} ]]; then
echo "Expected ${#SUITES[@]} suite results, got ${#LINES[@]}" >&2
echo "---- raw output ----" >&2
printf '%s\n' "$OUTPUT" >&2
exit 3
fi
TOTAL_PASS=0
TOTAL_FAIL=0
TOTAL=0
JSON_SUITES=""
MD_ROWS=""
for i in "${!SUITES[@]}"; do
IFS=: read -r name _ _ <<< "${SUITES[$i]}"
line="${LINES[$i]}"
passed=$(grep -oE ':passed [0-9]+' <<< "$line" | grep -oE '[0-9]+')
total=$(grep -oE ':total [0-9]+' <<< "$line" | grep -oE '[0-9]+')
failed=$(grep -oE ':failed [0-9]+' <<< "$line" | grep -oE '[0-9]+')
TOTAL_PASS=$((TOTAL_PASS + passed))
TOTAL_FAIL=$((TOTAL_FAIL + failed))
TOTAL=$((TOTAL + total))
status="ok"
[[ "$failed" -gt 0 ]] && status="FAIL"
[[ -n "$JSON_SUITES" ]] && JSON_SUITES+=","
JSON_SUITES+="\"$name\":{\"passed\":$passed,\"total\":$total,\"failed\":$failed}"
MD_ROWS+="| $name | $passed | $total | $status |"$'\n'
done
WHEN="$(date -Iseconds 2>/dev/null || date)"
cat > "$HERE/scoreboard.json" <<JSON
{
"total_passed": $TOTAL_PASS,
"total_failed": $TOTAL_FAIL,
"total": $TOTAL,
"suites": {$JSON_SUITES},
"generated": "$WHEN"
}
JSON
cat > "$HERE/scoreboard.md" <<MD
# Prolog scoreboard
**$TOTAL_PASS / $TOTAL passing** ($TOTAL_FAIL failure(s)).
Generated $WHEN.
| Suite | Passed | Total | Status |
|-------|--------|-------|--------|
$MD_ROWS
Run \`bash lib/prolog/conformance.sh\` to refresh. Override the binary
with \`SX_SERVER=path/to/sx_server.exe bash …\`.
MD
if [[ "$TOTAL_FAIL" -gt 0 ]]; then
echo "$TOTAL_FAIL failure(s) across $TOTAL tests" >&2
exit 1
fi
echo "All $TOTAL tests pass."

84
lib/prolog/hs-bridge.sx
View File

@@ -1,84 +0,0 @@
;; lib/prolog/hs-bridge.sx — Prolog ↔ Hyperscript bridge
;;
;; Two complementary integration styles:
;;
;; 1. Hook style — for `prolog(db, "goal(args)")` call syntax in Hyperscript:
;; (pl-install-hs-hook!) ;; call once at startup
;; Requires lib/hyperscript/runtime.sx (provides hs-set-prolog-hook!)
;;
;; 2. Factory style — for named conditions like `when allowed(user, action)`:
;; (define allowed (pl-hs-predicate/2 pl-db "allowed"))
;; No parser/compiler changes needed: Hyperscript compiles
;; `allowed(user, action)` to `(allowed user action)` — a plain SX call.
;;
;; Requires tokenizer.sx, parser.sx, runtime.sx, query.sx loaded first.
;; --- Hook style ---
(define
pl-install-hs-hook!
(fn
()
(hs-set-prolog-hook!
(fn (db goal) (not (= nil (pl-query-one db goal)))))))
;; --- Factory style ---
;; Test whether a ground Prolog goal succeeds against db.
;; Returns true/false (not a solution dict).
(define
pl-hs-query
(fn (db goal-str) (not (nil? (pl-query-one db goal-str)))))
;; Build a Prolog goal string from a predicate name and arg list.
;; SX values: strings/keywords pass through; numbers are stringified via str.
(define
pl-hs-build-goal
(fn
(pred-name args)
(str pred-name "(" (join ", " (map (fn (a) (str a)) args)) ")")))
;; Return a 1-arg SX function that succeeds iff pred(a) holds in db.
(define
pl-hs-predicate/1
(fn
(db pred-name)
(fn (a) (pl-hs-query db (pl-hs-build-goal pred-name (list a))))))
;; Return a 2-arg SX function that succeeds iff pred(a, b) holds in db.
(define
pl-hs-predicate/2
(fn
(db pred-name)
(fn (a b) (pl-hs-query db (pl-hs-build-goal pred-name (list a b))))))
;; Return a 3-arg SX function that succeeds iff pred(a, b, c) holds in db.
(define
pl-hs-predicate/3
(fn
(db pred-name)
(fn (a b c) (pl-hs-query db (pl-hs-build-goal pred-name (list a b c))))))
;; Install every predicate in install-list as a named SX function backed by db.
;; install-list: list of (name arity) pairs.
;; Returns a dict {name → fn} for the caller to destructure.
(define
pl-hs-install
(fn
(db install-list)
(reduce
(fn
(acc entry)
(let
((pred-name (first entry)) (arity (nth entry 1)))
(dict-set!
acc
pred-name
(cond
((= arity 1) (pl-hs-predicate/1 db pred-name))
((= arity 2) (pl-hs-predicate/2 db pred-name))
((= arity 3) (pl-hs-predicate/3 db pred-name))
(true (fn (a b) false))))
acc))
{}
install-list)))

195
lib/prolog/parser.sx
View File

@@ -1,20 +1,28 @@
;; lib/prolog/parser.sx — tokens → Prolog AST
;;
;; Phase 4 grammar (with operator table):
;; Phase 1 grammar (NO operator table yet):
;; Program := Clause* EOF
;; Clause := Term[999] "." | Term[999] ":-" Term[1200] "."
;; Term[Pmax] uses precedence climbing on the operator table:
;; primary = Atom | Var | Number | String | Compound | List | "(" Term[1200] ")"
;; while next token is infix op `op` with prec(op) ≤ Pmax:
;; consume op; parse rhs at right-prec(op); fold into compound(op-name,[lhs,rhs])
;; Clause := Term "." | Term ":-" Term "."
;; Term := Atom | Var | Number | String | Compound | List
;; Compound := atom "(" ArgList ")"
;; ArgList := Term ("," Term)*
;; List := "[" "]" | "[" Term ("," Term)* ("|" Term)? "]"
;;
;; Op type → right-prec for op at precedence P:
;; xfx → P-1 strict-both
;; xfy → P right-associative
;; yfx → P-1 left-associative
;; Term AST shapes (all tagged lists for uniform dispatch):
;; ("atom" name) — atom
;; ("var" name) — variable template (parser-time only)
;; ("num" value) — integer or float
;; ("str" value) — string literal
;; ("compound" functor args) — compound term, args is list of term-ASTs
;; ("cut") — the cut atom !
;;
;; AST shapes are unchanged — operators just become compound terms.
;; A clause is (list "clause" head body). A fact is head with body = ("atom" "true").
;;
;; The empty list is (atom "[]"). Cons is compound "." with two args:
;; [1, 2, 3] → .(1, .(2, .(3, [])))
;; [H|T] → .(H, T)
;; ── Parser state helpers ────────────────────────────────────────────
(define
pp-peek
(fn
@@ -58,6 +66,7 @@
(if (= (get t :value) nil) "" (get t :value))
"'"))))))
;; ── AST constructors ────────────────────────────────────────────────
(define pl-mk-atom (fn (name) (list "atom" name)))
(define pl-mk-var (fn (name) (list "var" name)))
(define pl-mk-num (fn (n) (list "num" n)))
@@ -65,14 +74,18 @@
(define pl-mk-compound (fn (f args) (list "compound" f args)))
(define pl-mk-cut (fn () (list "cut")))
;; Term tag extractors
(define pl-term-tag (fn (t) (if (list? t) (first t) nil)))
(define pl-term-val (fn (t) (nth t 1)))
(define pl-compound-functor (fn (t) (nth t 1)))
(define pl-compound-args (fn (t) (nth t 2)))
;; Empty-list atom and cons helpers
(define pl-nil-term (fn () (pl-mk-atom "[]")))
(define pl-mk-cons (fn (h t) (pl-mk-compound "." (list h t))))
;; Build cons list from a list of terms + optional tail
(define
pl-mk-list-term
(fn
@@ -82,61 +95,9 @@
tail
(pl-mk-cons (first items) (pl-mk-list-term (rest items) tail)))))
;; ── Operator table (Phase 4) ──────────────────────────────────────
;; Each entry: (name precedence type). Type ∈ "xfx" "xfy" "yfx".
(define
pl-op-table
(list
(list "," 1000 "xfy")
(list ";" 1100 "xfy")
(list "->" 1050 "xfy")
(list "=" 700 "xfx")
(list "\\=" 700 "xfx")
(list "is" 700 "xfx")
(list "<" 700 "xfx")
(list ">" 700 "xfx")
(list "=<" 700 "xfx")
(list ">=" 700 "xfx")
(list "+" 500 "yfx")
(list "-" 500 "yfx")
(list "*" 400 "yfx")
(list "/" 400 "yfx")
(list ":-" 1200 "xfx")
(list "mod" 400 "yfx")))
(define
pl-op-find
(fn
(name table)
(cond
((empty? table) nil)
((= (first (first table)) name) (rest (first table)))
(true (pl-op-find name (rest table))))))
(define pl-op-lookup (fn (name) (pl-op-find name pl-op-table)))
;; Token → (name prec type) for known infix ops, else nil.
(define
pl-token-op
(fn
(t)
(let
((ty (get t :type)) (vv (get t :value)))
(cond
((and (= ty "punct") (= vv ","))
(let
((info (pl-op-lookup ",")))
(if (nil? info) nil (cons "," info))))
((or (= ty "atom") (= ty "op"))
(let
((info (pl-op-lookup vv)))
(if (nil? info) nil (cons vv info))))
(true nil)))))
;; ── Term parser ─────────────────────────────────────────────────────
;; Primary term: atom, var, num, str, compound (atom + paren), list, cut, parens.
(define
pp-parse-primary
pp-parse-term
(fn
(st)
(let
@@ -150,12 +111,6 @@
((and (= ty "op") (= vv "!"))
(do (pp-advance! st) (pl-mk-cut)))
((and (= ty "punct") (= vv "[")) (pp-parse-list st))
((and (= ty "punct") (= vv "("))
(do
(pp-advance! st)
(let
((inner (pp-parse-term-prec st 1200)))
(do (pp-expect! st "punct" ")") inner))))
((= ty "atom")
(do
(pp-advance! st)
@@ -178,51 +133,13 @@
(if (= vv nil) "" vv)
"'"))))))))
;; Operator-aware term parser: precedence climbing.
(define
pp-parse-term-prec
(fn
(st max-prec)
(let ((left (pp-parse-primary st))) (pp-parse-op-rhs st left max-prec))))
(define
pp-parse-op-rhs
(fn
(st left max-prec)
(let
((op-info (pl-token-op (pp-peek st))))
(cond
((nil? op-info) left)
(true
(let
((name (first op-info))
(prec (nth op-info 1))
(ty (nth op-info 2)))
(cond
((> prec max-prec) left)
(true
(let
((right-prec (if (= ty "xfy") prec (- prec 1))))
(do
(pp-advance! st)
(let
((right (pp-parse-term-prec st right-prec)))
(pp-parse-op-rhs
st
(pl-mk-compound name (list left right))
max-prec))))))))))))
;; Backwards-compat alias.
(define pp-parse-term (fn (st) (pp-parse-term-prec st 999)))
;; Args inside parens: parse at prec 999 so comma-as-operator (1000)
;; is not consumed; the explicit comma loop handles separation.
;; Parse one or more comma-separated terms (arguments).
(define
pp-parse-arg-list
(fn
(st)
(let
((first-arg (pp-parse-term-prec st 999)) (args (list)))
((first-arg (pp-parse-term st)) (args (list)))
(do
(append! args first-arg)
(define
@@ -233,12 +150,12 @@
(pp-at? st "punct" ",")
(do
(pp-advance! st)
(append! args (pp-parse-term-prec st 999))
(append! args (pp-parse-term st))
(loop)))))
(loop)
args))))
;; List literal.
;; Parse a [ ... ] list literal. Consumes the "[".
(define
pp-parse-list
(fn
@@ -251,7 +168,7 @@
(let
((items (list)))
(do
(append! items (pp-parse-term-prec st 999))
(append! items (pp-parse-term st))
(define
comma-loop
(fn
@@ -260,17 +177,52 @@
(pp-at? st "punct" ",")
(do
(pp-advance! st)
(append! items (pp-parse-term-prec st 999))
(append! items (pp-parse-term st))
(comma-loop)))))
(comma-loop)
(let
((tail (if (pp-at? st "punct" "|") (do (pp-advance! st) (pp-parse-term-prec st 999)) (pl-nil-term))))
((tail (if (pp-at? st "punct" "|") (do (pp-advance! st) (pp-parse-term st)) (pl-nil-term))))
(do (pp-expect! st "punct" "]") (pl-mk-list-term items tail)))))))))
;; ── Body parsing ────────────────────────────────────────────────────
;; A body is a single term parsed at prec 1200 — operator parser folds
;; `,`, `;`, `->` automatically into right-associative compounds.
(define pp-parse-body (fn (st) (pp-parse-term-prec st 1200)))
;; A clause body is a comma-separated list of goals. We flatten into a
;; right-associative `,` compound: (A, B, C) → ','(A, ','(B, C))
;; If only one goal, it's that goal directly.
(define
pp-parse-body
(fn
(st)
(let
((first-goal (pp-parse-term st)) (rest-goals (list)))
(do
(define
gloop
(fn
()
(when
(pp-at? st "punct" ",")
(do
(pp-advance! st)
(append! rest-goals (pp-parse-term st))
(gloop)))))
(gloop)
(if
(= (len rest-goals) 0)
first-goal
(pp-build-conj first-goal rest-goals))))))
(define
pp-build-conj
(fn
(first-goal rest-goals)
(if
(= (len rest-goals) 0)
first-goal
(pl-mk-compound
","
(list
first-goal
(pp-build-conj (first rest-goals) (rest rest-goals)))))))
;; ── Clause parsing ──────────────────────────────────────────────────
(define
@@ -278,11 +230,12 @@
(fn
(st)
(let
((head (pp-parse-term-prec st 999)))
((head (pp-parse-term st)))
(let
((body (if (pp-at? st "op" ":-") (do (pp-advance! st) (pp-parse-body st)) (pl-mk-atom "true"))))
(do (pp-expect! st "punct" ".") (list "clause" head body))))))
;; Parse an entire program — returns list of clauses.
(define
pl-parse-program
(fn
@@ -300,9 +253,13 @@
(ploop)
clauses))))
;; Parse a single query term (no trailing "."). Returns the term.
(define
pl-parse-query
(fn (tokens) (let ((st {:idx 0 :tokens tokens})) (pp-parse-body st))))
;; Convenience: source → clauses
(define pl-parse (fn (src) (pl-parse-program (pl-tokenize src))))
;; Convenience: source → query term
(define pl-parse-goal (fn (src) (pl-parse-query (pl-tokenize src))))

114
lib/prolog/query.sx
View File

@@ -1,114 +0,0 @@
;; lib/prolog/query.sx — high-level Prolog query API for SX/Hyperscript callers.
;;
;; Requires tokenizer.sx, parser.sx, runtime.sx to be loaded first.
;;
;; Public API:
;; (pl-load source-str) → db
;; (pl-query-all db query-str) → list of solution dicts {var-name → term-string}
;; (pl-query-one db query-str) → first solution dict or nil
;; (pl-query source-str query-str) → list of solution dicts (convenience)
;; Collect variable name strings from a parse-time AST (pre-instantiation).
;; Returns list of unique strings, excluding anonymous "_".
(define
pl-query-extract-vars
(fn
(ast)
(let
((seen {}))
(let
((collect!
(fn
(t)
(cond
((not (list? t)) nil)
((empty? t) nil)
((= (first t) "var")
(if
(not (= (nth t 1) "_"))
(dict-set! seen (nth t 1) true)
nil))
((= (first t) "compound")
(for-each collect! (nth t 2)))
(true nil)))))
(collect! ast)
(keys seen)))))
;; Build a solution dict from a var-env after a successful solve.
;; Maps each variable name string to its formatted term value.
(define
pl-query-solution-dict
(fn
(var-names var-env)
(let
((d {}))
(for-each
(fn (name) (dict-set! d name (pl-format-term (dict-get var-env name))))
var-names)
d)))
;; Parse source-str and load clauses into a fresh DB.
;; Returns the DB for reuse across multiple queries.
(define
pl-load
(fn
(source-str)
(let
((db (pl-mk-db)))
(if
(and (string? source-str) (not (= source-str "")))
(pl-db-load! db (pl-parse source-str))
nil)
db)))
;; Run query-str against db, returning a list of solution dicts.
;; Each dict maps variable name strings to their formatted term values.
;; Returns an empty list if no solutions.
(define
pl-query-all
(fn
(db query-str)
(let
((parsed (pl-parse (str "q_ :- " query-str "."))))
(let
((body-ast (nth (first parsed) 2)))
(let
((var-names (pl-query-extract-vars body-ast))
(var-env {}))
(let
((goal (pl-instantiate body-ast var-env))
(trail (pl-mk-trail))
(solutions (list)))
(let
((mark (pl-trail-mark trail)))
(pl-solve!
db
goal
trail
{:cut false}
(fn
()
(begin
(append!
solutions
(pl-query-solution-dict var-names var-env))
false)))
(pl-trail-undo-to! trail mark)
solutions)))))))
;; Return the first solution dict, or nil if no solutions.
(define
pl-query-one
(fn
(db query-str)
(let
((all (pl-query-all db query-str)))
(if (empty? all) nil (first all)))))
;; Convenience: parse source-str, then run query-str against it.
;; Returns a list of solution dicts. Creates a fresh DB each call.
(define
pl-query
(fn
(source-str query-str)
(pl-query-all (pl-load source-str) query-str)))

2562
lib/prolog/runtime.sx
View File

File diff suppressed because it is too large Load Diff

7
lib/prolog/scoreboard.json
View File

@@ -1,7 +0,0 @@
{
"total_passed": 590,
"total_failed": 0,
"total": 590,
"suites": {"parse":{"passed":25,"total":25,"failed":0},"unify":{"passed":47,"total":47,"failed":0},"clausedb":{"passed":14,"total":14,"failed":0},"solve":{"passed":62,"total":62,"failed":0},"operators":{"passed":19,"total":19,"failed":0},"dynamic":{"passed":11,"total":11,"failed":0},"findall":{"passed":11,"total":11,"failed":0},"term_inspect":{"passed":14,"total":14,"failed":0},"append":{"passed":6,"total":6,"failed":0},"reverse":{"passed":6,"total":6,"failed":0},"member":{"passed":7,"total":7,"failed":0},"nqueens":{"passed":6,"total":6,"failed":0},"family":{"passed":10,"total":10,"failed":0},"atoms":{"passed":34,"total":34,"failed":0},"query_api":{"passed":16,"total":16,"failed":0},"iso_predicates":{"passed":29,"total":29,"failed":0},"meta_predicates":{"passed":25,"total":25,"failed":0},"list_predicates":{"passed":33,"total":33,"failed":0},"meta_call":{"passed":15,"total":15,"failed":0},"set_predicates":{"passed":15,"total":15,"failed":0},"char_predicates":{"passed":27,"total":27,"failed":0},"io_predicates":{"passed":24,"total":24,"failed":0},"assert_rules":{"passed":15,"total":15,"failed":0},"string_agg":{"passed":25,"total":25,"failed":0},"advanced":{"passed":21,"total":21,"failed":0},"compiler":{"passed":17,"total":17,"failed":0},"cross_validate":{"passed":17,"total":17,"failed":0},"integration":{"passed":20,"total":20,"failed":0},"hs_bridge":{"passed":19,"total":19,"failed":0}},
"generated": "2026-05-06T08:29:09+00:00"
}

39
lib/prolog/scoreboard.md
View File

@@ -1,39 +0,0 @@
# Prolog scoreboard
**590 / 590 passing** (0 failure(s)).
Generated 2026-05-06T08:29:09+00:00.
| Suite | Passed | Total | Status |
|-------|--------|-------|--------|
| parse | 25 | 25 | ok |
| unify | 47 | 47 | ok |
| clausedb | 14 | 14 | ok |
| solve | 62 | 62 | ok |
| operators | 19 | 19 | ok |
| dynamic | 11 | 11 | ok |
| findall | 11 | 11 | ok |
| term_inspect | 14 | 14 | ok |
| append | 6 | 6 | ok |
| reverse | 6 | 6 | ok |
| member | 7 | 7 | ok |
| nqueens | 6 | 6 | ok |
| family | 10 | 10 | ok |
| atoms | 34 | 34 | ok |
| query_api | 16 | 16 | ok |
| iso_predicates | 29 | 29 | ok |
| meta_predicates | 25 | 25 | ok |
| list_predicates | 33 | 33 | ok |
| meta_call | 15 | 15 | ok |
| set_predicates | 15 | 15 | ok |
| char_predicates | 27 | 27 | ok |
| io_predicates | 24 | 24 | ok |
| assert_rules | 15 | 15 | ok |
| string_agg | 25 | 25 | ok |
| advanced | 21 | 21 | ok |
| compiler | 17 | 17 | ok |
| cross_validate | 17 | 17 | ok |
| integration | 20 | 20 | ok |
| hs_bridge | 19 | 19 | ok |
Run `bash lib/prolog/conformance.sh` to refresh. Override the binary
with `SX_SERVER=path/to/sx_server.exe bash …`.

254
lib/prolog/tests/advanced.sx
View File

@@ -1,254 +0,0 @@
;; lib/prolog/tests/advanced.sx — predsort/3, term_variables/2, arith extensions
(define pl-adv-test-count 0)
(define pl-adv-test-pass 0)
(define pl-adv-test-fail 0)
(define pl-adv-test-failures (list))
(define
pl-adv-test!
(fn
(name got expected)
(begin
(set! pl-adv-test-count (+ pl-adv-test-count 1))
(if
(= got expected)
(set! pl-adv-test-pass (+ pl-adv-test-pass 1))
(begin
(set! pl-adv-test-fail (+ pl-adv-test-fail 1))
(append!
pl-adv-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-adv-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-adv-db (pl-mk-db))
;; Load a numeric comparator for predsort tests
(pl-db-load!
pl-adv-db
(pl-parse
"cmp_num(Order, X, Y) :- (X < Y -> Order = '<' ; (X > Y -> Order = '>' ; Order = '='))."))
;; ── Arithmetic extensions ──────────────────────────────────────────
(define pl-adv-arith-env-1 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is floor(3.7)" pl-adv-arith-env-1)
(pl-mk-trail))
(pl-adv-test!
"floor(3.7) = 3"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-1 "X")))
3)
(define pl-adv-arith-env-2 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is ceiling(3.2)" pl-adv-arith-env-2)
(pl-mk-trail))
(pl-adv-test!
"ceiling(3.2) = 4"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-2 "X")))
4)
(define pl-adv-arith-env-3 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is truncate(3.9)" pl-adv-arith-env-3)
(pl-mk-trail))
(pl-adv-test!
"truncate(3.9) = 3"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-3 "X")))
3)
(define pl-adv-arith-env-4 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is truncate(0 - 3.9)" pl-adv-arith-env-4)
(pl-mk-trail))
(pl-adv-test!
"truncate(0-3.9) = -3"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-4 "X")))
-3)
(define pl-adv-arith-env-5 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is round(3.5)" pl-adv-arith-env-5)
(pl-mk-trail))
(pl-adv-test!
"round(3.5) = 4"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-5 "X")))
4)
(define pl-adv-arith-env-6 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is sqrt(4.0)" pl-adv-arith-env-6)
(pl-mk-trail))
(pl-adv-test!
"sqrt(4.0) = 2"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-6 "X")))
2)
(define pl-adv-arith-env-7 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is sign(0 - 5)" pl-adv-arith-env-7)
(pl-mk-trail))
(pl-adv-test!
"sign(0-5) = -1"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-7 "X")))
-1)
(define pl-adv-arith-env-8 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is sign(0)" pl-adv-arith-env-8)
(pl-mk-trail))
(pl-adv-test!
"sign(0) = 0"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-8 "X")))
0)
(define pl-adv-arith-env-9 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is sign(3)" pl-adv-arith-env-9)
(pl-mk-trail))
(pl-adv-test!
"sign(3) = 1"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-9 "X")))
1)
(define pl-adv-arith-env-10 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is pow(2, 3)" pl-adv-arith-env-10)
(pl-mk-trail))
(pl-adv-test!
"pow(2,3) = 8"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-10 "X")))
8)
(define pl-adv-arith-env-11 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is floor(0 - 3.7)" pl-adv-arith-env-11)
(pl-mk-trail))
(pl-adv-test!
"floor(0-3.7) = -4"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-11 "X")))
-4)
(define pl-adv-arith-env-12 {:X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "X is ceiling(0 - 3.2)" pl-adv-arith-env-12)
(pl-mk-trail))
(pl-adv-test!
"ceiling(0-3.2) = -3"
(pl-num-val (pl-walk-deep (dict-get pl-adv-arith-env-12 "X")))
-3)
;; ── term_variables/2 ──────────────────────────────────────────────
(define pl-adv-tv-env-1 {:Vs (pl-mk-rt-var "Vs")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "term_variables(hello, Vs)" pl-adv-tv-env-1)
(pl-mk-trail))
(pl-adv-test!
"term_variables(hello,Vs) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-adv-tv-env-1 "Vs")))
"[]")
(define pl-adv-tv-env-2 {:Vs (pl-mk-rt-var "Vs")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "term_variables(f(a, g(b)), Vs)" pl-adv-tv-env-2)
(pl-mk-trail))
(pl-adv-test!
"term_variables(f(a,g(b)),Vs) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-adv-tv-env-2 "Vs")))
"[]")
(define pl-adv-tv-env-3 {:Y (pl-mk-rt-var "Y") :Vs (pl-mk-rt-var "Vs") :X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "term_variables(f(X, Y), Vs)" pl-adv-tv-env-3)
(pl-mk-trail))
(pl-adv-test!
"term_variables(f(X,Y),Vs) has 2 vars"
(pl-list-length (pl-walk-deep (dict-get pl-adv-tv-env-3 "Vs")))
2)
(define pl-adv-tv-env-4 {:Vs (pl-mk-rt-var "Vs") :X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "term_variables(X, Vs)" pl-adv-tv-env-4)
(pl-mk-trail))
(pl-adv-test!
"term_variables(X,Vs) has 1 var"
(pl-list-length (pl-walk-deep (dict-get pl-adv-tv-env-4 "Vs")))
1)
(define pl-adv-tv-env-5 {:Y (pl-mk-rt-var "Y") :Vs (pl-mk-rt-var "Vs") :X (pl-mk-rt-var "X")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "term_variables(foo(X, Y, X), Vs)" pl-adv-tv-env-5)
(pl-mk-trail))
(pl-adv-test!
"term_variables(foo(X,Y,X),Vs) deduplicates X -> 2 vars"
(pl-list-length (pl-walk-deep (dict-get pl-adv-tv-env-5 "Vs")))
2)
;; ── predsort/3 ────────────────────────────────────────────────────
(define pl-adv-ps-env-1 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "predsort(cmp_num, [], R)" pl-adv-ps-env-1)
(pl-mk-trail))
(pl-adv-test!
"predsort([]) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-adv-ps-env-1 "R")))
"[]")
(define pl-adv-ps-env-2 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "predsort(cmp_num, [1], R)" pl-adv-ps-env-2)
(pl-mk-trail))
(pl-adv-test!
"predsort([1]) -> [1]"
(pl-format-term (pl-walk-deep (dict-get pl-adv-ps-env-2 "R")))
".(1, [])")
(define pl-adv-ps-env-3 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "predsort(cmp_num, [3,1,2], R)" pl-adv-ps-env-3)
(pl-mk-trail))
(pl-adv-test!
"predsort([3,1,2]) -> [1,2,3]"
(pl-format-term (pl-walk-deep (dict-get pl-adv-ps-env-3 "R")))
".(1, .(2, .(3, [])))")
(define pl-adv-ps-env-4 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-adv-db
(pl-adv-goal "predsort(cmp_num, [3,1,2,1,3], R)" pl-adv-ps-env-4)
(pl-mk-trail))
(pl-adv-test!
"predsort([3,1,2,1,3]) dedup -> [1,2,3]"
(pl-format-term (pl-walk-deep (dict-get pl-adv-ps-env-4 "R")))
".(1, .(2, .(3, [])))")
;; ── Runner ─────────────────────────────────────────────────────────
(define pl-advanced-tests-run! (fn () {:failed pl-adv-test-fail :passed pl-adv-test-pass :total pl-adv-test-count :failures pl-adv-test-failures}))

215
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;; lib/prolog/tests/assert_rules.sx — assert/assertz/asserta with rule terms (head :- body)
;; Tests that :- is in the op table (prec 1200 xfx) and pl-build-clause handles rule form.
(define pl-ar-test-count 0)
(define pl-ar-test-pass 0)
(define pl-ar-test-fail 0)
(define pl-ar-test-failures (list))
(define
pl-ar-test!
(fn
(name got expected)
(begin
(set! pl-ar-test-count (+ pl-ar-test-count 1))
(if
(= got expected)
(set! pl-ar-test-pass (+ pl-ar-test-pass 1))
(begin
(set! pl-ar-test-fail (+ pl-ar-test-fail 1))
(append!
pl-ar-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-ar-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
;; ── DB1: assertz a simple rule then query ──────────────────────────
(define pl-ar-db1 (pl-mk-db))
(pl-solve-once!
pl-ar-db1
(pl-ar-goal "assertz((double(X, Y) :- Y is X * 2))" {})
(pl-mk-trail))
(pl-ar-test!
"assertz rule: double(3, Y) succeeds"
(pl-solve-once!
pl-ar-db1
(pl-ar-goal "double(3, Y)" {})
(pl-mk-trail))
true)
(define pl-ar-env1 {})
(pl-solve-once!
pl-ar-db1
(pl-ar-goal "double(3, Y)" pl-ar-env1)
(pl-mk-trail))
(pl-ar-test!
"assertz rule: double(3, Y) binds Y to 6"
(pl-num-val (pl-walk-deep (dict-get pl-ar-env1 "Y")))
6)
(define pl-ar-env1b {})
(pl-solve-once!
pl-ar-db1
(pl-ar-goal "double(10, Y)" pl-ar-env1b)
(pl-mk-trail))
(pl-ar-test!
"assertz rule: double(10, Y) yields 20"
(pl-num-val (pl-walk-deep (dict-get pl-ar-env1b "Y")))
20)
;; ── DB2: assert a rule with multiple facts, count solutions ─────────
(define pl-ar-db2 (pl-mk-db))
(pl-solve-once!
pl-ar-db2
(pl-ar-goal "assert(fact(a))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db2
(pl-ar-goal "assert(fact(b))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db2
(pl-ar-goal "assertz((copy(X) :- fact(X)))" {})
(pl-mk-trail))
(pl-ar-test!
"rule copy/1 using fact/1: 2 solutions"
(pl-solve-count! pl-ar-db2 (pl-ar-goal "copy(X)" {}) (pl-mk-trail))
2)
(define pl-ar-env2a {})
(pl-solve-once! pl-ar-db2 (pl-ar-goal "copy(X)" pl-ar-env2a) (pl-mk-trail))
(pl-ar-test!
"rule copy/1: first solution is a"
(pl-atom-name (pl-walk-deep (dict-get pl-ar-env2a "X")))
"a")
;; ── DB3: asserta rule is tried before existing clauses ─────────────
(define pl-ar-db3 (pl-mk-db))
(pl-solve-once!
pl-ar-db3
(pl-ar-goal "assert(ord(a))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db3
(pl-ar-goal "asserta((ord(b) :- true))" {})
(pl-mk-trail))
(define pl-ar-env3 {})
(pl-solve-once! pl-ar-db3 (pl-ar-goal "ord(X)" pl-ar-env3) (pl-mk-trail))
(pl-ar-test!
"asserta rule ord(b) is tried before ord(a)"
(pl-atom-name (pl-walk-deep (dict-get pl-ar-env3 "X")))
"b")
(pl-ar-test!
"asserta: total solutions for ord/1 is 2"
(pl-solve-count! pl-ar-db3 (pl-ar-goal "ord(X)" {}) (pl-mk-trail))
2)
;; ── DB4: rule with conjunction in body ─────────────────────────────
(define pl-ar-db4 (pl-mk-db))
(pl-solve-once!
pl-ar-db4
(pl-ar-goal "assert(num(1))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db4
(pl-ar-goal "assert(num(2))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db4
(pl-ar-goal "assertz((big(X) :- num(X), X > 1))" {})
(pl-mk-trail))
(pl-ar-test!
"conjunction in rule body: big(1) fails"
(pl-solve-once! pl-ar-db4 (pl-ar-goal "big(1)" {}) (pl-mk-trail))
false)
(pl-ar-test!
"conjunction in rule body: big(2) succeeds"
(pl-solve-once! pl-ar-db4 (pl-ar-goal "big(2)" {}) (pl-mk-trail))
true)
;; ── DB5: recursive rule ─────────────────────────────────────────────
(define pl-ar-db5 (pl-mk-db))
(pl-solve-once!
pl-ar-db5
(pl-ar-goal "assert((nat(0) :- true))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db5
(pl-ar-goal "assertz((nat(s(X)) :- nat(X)))" {})
(pl-mk-trail))
(pl-ar-test!
"recursive rule: nat(0) succeeds"
(pl-solve-once! pl-ar-db5 (pl-ar-goal "nat(0)" {}) (pl-mk-trail))
true)
(pl-ar-test!
"recursive rule: nat(s(0)) succeeds"
(pl-solve-once!
pl-ar-db5
(pl-ar-goal "nat(s(0))" {})
(pl-mk-trail))
true)
(pl-ar-test!
"recursive rule: nat(s(s(0))) succeeds"
(pl-solve-once!
pl-ar-db5
(pl-ar-goal "nat(s(s(0)))" {})
(pl-mk-trail))
true)
(pl-ar-test!
"recursive rule: nat(bad) fails"
(pl-solve-once! pl-ar-db5 (pl-ar-goal "nat(bad)" {}) (pl-mk-trail))
false)
;; ── DB6: rule with true body (explicit) ────────────────────────────
(define pl-ar-db6 (pl-mk-db))
(pl-solve-once!
pl-ar-db6
(pl-ar-goal "assertz((always(X) :- true))" {})
(pl-mk-trail))
(pl-solve-once!
pl-ar-db6
(pl-ar-goal "assert(always(extra))" {})
(pl-mk-trail))
(pl-ar-test!
"rule body=true: always(foo) succeeds"
(pl-solve-once!
pl-ar-db6
(pl-ar-goal "always(foo)" {})
(pl-mk-trail))
true)
(pl-ar-test!
"rule body=true: always/1 has 2 clauses (1 rule + 1 fact)"
(pl-solve-count!
pl-ar-db6
(pl-ar-goal "always(X)" {})
(pl-mk-trail))
2)
;; ── Runner ──────────────────────────────────────────────────────────
(define pl-assert-rules-tests-run! (fn () {:failed pl-ar-test-fail :passed pl-ar-test-pass :total pl-ar-test-count :failures pl-ar-test-failures}))

305
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;; lib/prolog/tests/atoms.sx — type predicates + string/atom built-ins
(define pl-at-test-count 0)
(define pl-at-test-pass 0)
(define pl-at-test-fail 0)
(define pl-at-test-failures (list))
(define
pl-at-test!
(fn
(name got expected)
(begin
(set! pl-at-test-count (+ pl-at-test-count 1))
(if
(= got expected)
(set! pl-at-test-pass (+ pl-at-test-pass 1))
(begin
(set! pl-at-test-fail (+ pl-at-test-fail 1))
(append!
pl-at-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-at-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-at-db (pl-mk-db))
;; ── var/1 + nonvar/1 ──
(pl-at-test!
"var(X) for unbound var"
(pl-solve-once! pl-at-db (pl-at-goal "var(X)" {}) (pl-mk-trail))
true)
(pl-at-test!
"var(foo) fails"
(pl-solve-once! pl-at-db (pl-at-goal "var(foo)" {}) (pl-mk-trail))
false)
(pl-at-test!
"nonvar(foo) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "nonvar(foo)" {})
(pl-mk-trail))
true)
(pl-at-test!
"nonvar(X) for unbound var fails"
(pl-solve-once! pl-at-db (pl-at-goal "nonvar(X)" {}) (pl-mk-trail))
false)
;; ── atom/1 ──
(pl-at-test!
"atom(foo) succeeds"
(pl-solve-once! pl-at-db (pl-at-goal "atom(foo)" {}) (pl-mk-trail))
true)
(pl-at-test!
"atom([]) succeeds"
(pl-solve-once! pl-at-db (pl-at-goal "atom([])" {}) (pl-mk-trail))
true)
(pl-at-test!
"atom(42) fails"
(pl-solve-once! pl-at-db (pl-at-goal "atom(42)" {}) (pl-mk-trail))
false)
(pl-at-test!
"atom(f(x)) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "atom(f(x))" {})
(pl-mk-trail))
false)
;; ── number/1 + integer/1 ──
(pl-at-test!
"number(42) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "number(42)" {})
(pl-mk-trail))
true)
(pl-at-test!
"number(foo) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "number(foo)" {})
(pl-mk-trail))
false)
(pl-at-test!
"integer(7) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "integer(7)" {})
(pl-mk-trail))
true)
;; ── compound/1 + callable/1 + atomic/1 ──
(pl-at-test!
"compound(f(x)) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "compound(f(x))" {})
(pl-mk-trail))
true)
(pl-at-test!
"compound(foo) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "compound(foo)" {})
(pl-mk-trail))
false)
(pl-at-test!
"callable(foo) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "callable(foo)" {})
(pl-mk-trail))
true)
(pl-at-test!
"callable(f(x)) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "callable(f(x))" {})
(pl-mk-trail))
true)
(pl-at-test!
"callable(42) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "callable(42)" {})
(pl-mk-trail))
false)
(pl-at-test!
"atomic(foo) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "atomic(foo)" {})
(pl-mk-trail))
true)
(pl-at-test!
"atomic(42) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "atomic(42)" {})
(pl-mk-trail))
true)
(pl-at-test!
"atomic(f(x)) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "atomic(f(x))" {})
(pl-mk-trail))
false)
;; ── is_list/1 ──
(pl-at-test!
"is_list([]) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "is_list([])" {})
(pl-mk-trail))
true)
(pl-at-test!
"is_list([1,2,3]) succeeds"
(pl-solve-once!
pl-at-db
(pl-at-goal "is_list([1,2,3])" {})
(pl-mk-trail))
true)
(pl-at-test!
"is_list(foo) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "is_list(foo)" {})
(pl-mk-trail))
false)
;; ── atom_length/2 ──
(define pl-at-env-al {})
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_length(hello, N)" pl-at-env-al)
(pl-mk-trail))
(pl-at-test!
"atom_length(hello, N) -> N=5"
(pl-num-val (pl-walk-deep (dict-get pl-at-env-al "N")))
5)
(pl-at-test!
"atom_length empty atom"
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_length('', 0)" {})
(pl-mk-trail))
true)
;; ── atom_concat/3 ──
(define pl-at-env-ac {})
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_concat(foo, bar, X)" pl-at-env-ac)
(pl-mk-trail))
(pl-at-test!
"atom_concat(foo, bar, X) -> X=foobar"
(pl-atom-name (pl-walk-deep (dict-get pl-at-env-ac "X")))
"foobar")
(pl-at-test!
"atom_concat(foo, bar, foobar) check"
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_concat(foo, bar, foobar)" {})
(pl-mk-trail))
true)
(pl-at-test!
"atom_concat(foo, bar, foobaz) fails"
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_concat(foo, bar, foobaz)" {})
(pl-mk-trail))
false)
(define pl-at-env-ac2 {})
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_concat(foo, Y, foobar)" pl-at-env-ac2)
(pl-mk-trail))
(pl-at-test!
"atom_concat(foo, Y, foobar) -> Y=bar"
(pl-atom-name (pl-walk-deep (dict-get pl-at-env-ac2 "Y")))
"bar")
;; ── atom_chars/2 ──
(define pl-at-env-ach {})
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_chars(cat, Cs)" pl-at-env-ach)
(pl-mk-trail))
(pl-at-test!
"atom_chars(cat, Cs) -> Cs=[c,a,t]"
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_chars(cat, [c,a,t])" {})
(pl-mk-trail))
true)
(define pl-at-env-ach2 {})
(pl-solve-once!
pl-at-db
(pl-at-goal "atom_chars(A, [h,i])" pl-at-env-ach2)
(pl-mk-trail))
(pl-at-test!
"atom_chars(A, [h,i]) -> A=hi"
(pl-atom-name (pl-walk-deep (dict-get pl-at-env-ach2 "A")))
"hi")
;; ── char_code/2 ──
(define pl-at-env-cc {})
(pl-solve-once!
pl-at-db
(pl-at-goal "char_code(a, N)" pl-at-env-cc)
(pl-mk-trail))
(pl-at-test!
"char_code(a, N) -> N=97"
(pl-num-val (pl-walk-deep (dict-get pl-at-env-cc "N")))
97)
(define pl-at-env-cc2 {})
(pl-solve-once!
pl-at-db
(pl-at-goal "char_code(C, 65)" pl-at-env-cc2)
(pl-mk-trail))
(pl-at-test!
"char_code(C, 65) -> C='A'"
(pl-atom-name (pl-walk-deep (dict-get pl-at-env-cc2 "C")))
"A")
;; ── number_codes/2 ──
(pl-at-test!
"number_codes(42, [52,50])"
(pl-solve-once!
pl-at-db
(pl-at-goal "number_codes(42, [52,50])" {})
(pl-mk-trail))
true)
;; ── number_chars/2 ──
(pl-at-test!
"number_chars(42, ['4','2'])"
(pl-solve-once!
pl-at-db
(pl-at-goal "number_chars(42, ['4','2'])" {})
(pl-mk-trail))
true)
(define pl-atom-tests-run! (fn () {:failed pl-at-test-fail :passed pl-at-test-pass :total pl-at-test-count :failures pl-at-test-failures}))

290
lib/prolog/tests/char_predicates.sx
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@@ -1,290 +0,0 @@
;; lib/prolog/tests/char_predicates.sx — char_type/2, upcase_atom/2, downcase_atom/2,
;; string_upper/2, string_lower/2
(define pl-cp-test-count 0)
(define pl-cp-test-pass 0)
(define pl-cp-test-fail 0)
(define pl-cp-test-failures (list))
(define
pl-cp-test!
(fn
(name got expected)
(begin
(set! pl-cp-test-count (+ pl-cp-test-count 1))
(if
(= got expected)
(set! pl-cp-test-pass (+ pl-cp-test-pass 1))
(begin
(set! pl-cp-test-fail (+ pl-cp-test-fail 1))
(append!
pl-cp-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-cp-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-cp-db (pl-mk-db))
;; ─── char_type/2 — alpha ──────────────────────────────────────────
(pl-cp-test!
"char_type(a, alpha) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, alpha)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type('1', alpha) fails"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('1', alpha)" {})
(pl-mk-trail))
false)
(pl-cp-test!
"char_type('A', alpha) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('A', alpha)" {})
(pl-mk-trail))
true)
;; ─── char_type/2 — alnum ─────────────────────────────────────────
(pl-cp-test!
"char_type('5', alnum) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('5', alnum)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type(a, alnum) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, alnum)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type(' ', alnum) fails"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(' ', alnum)" {})
(pl-mk-trail))
false)
;; ─── char_type/2 — digit ─────────────────────────────────────────
(pl-cp-test!
"char_type('5', digit) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('5', digit)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type(a, digit) fails"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, digit)" {})
(pl-mk-trail))
false)
;; ─── char_type/2 — digit(Weight) ─────────────────────────────────
(define pl-cp-env-dw {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('5', digit(N))" pl-cp-env-dw)
(pl-mk-trail))
(pl-cp-test!
"char_type('5', digit(N)) -> N=5"
(pl-num-val (pl-walk-deep (dict-get pl-cp-env-dw "N")))
5)
(define pl-cp-env-dw0 {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('0', digit(N))" pl-cp-env-dw0)
(pl-mk-trail))
(pl-cp-test!
"char_type('0', digit(N)) -> N=0"
(pl-num-val (pl-walk-deep (dict-get pl-cp-env-dw0 "N")))
0)
;; ─── char_type/2 — space/white ───────────────────────────────────
(pl-cp-test!
"char_type(' ', space) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(' ', space)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type(a, space) fails"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, space)" {})
(pl-mk-trail))
false)
;; ─── char_type/2 — upper(Lower) ──────────────────────────────────
(define pl-cp-env-ul {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('A', upper(L))" pl-cp-env-ul)
(pl-mk-trail))
(pl-cp-test!
"char_type('A', upper(L)) -> L=a"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-ul "L")))
"a")
(pl-cp-test!
"char_type(a, upper(L)) fails — not uppercase"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, upper(_))" {})
(pl-mk-trail))
false)
;; ─── char_type/2 — lower(Upper) ──────────────────────────────────
(define pl-cp-env-lu {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, lower(U))" pl-cp-env-lu)
(pl-mk-trail))
(pl-cp-test!
"char_type(a, lower(U)) -> U='A'"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-lu "U")))
"A")
;; ─── char_type/2 — ascii(Code) ───────────────────────────────────
(define pl-cp-env-as {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, ascii(C))" pl-cp-env-as)
(pl-mk-trail))
(pl-cp-test!
"char_type(a, ascii(C)) -> C=97"
(pl-num-val (pl-walk-deep (dict-get pl-cp-env-as "C")))
97)
;; ─── char_type/2 — punct ─────────────────────────────────────────
(pl-cp-test!
"char_type('.', punct) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type('.', punct)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"char_type(a, punct) fails"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "char_type(a, punct)" {})
(pl-mk-trail))
false)
;; ─── upcase_atom/2 ───────────────────────────────────────────────
(define pl-cp-env-ua {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "upcase_atom(hello, X)" pl-cp-env-ua)
(pl-mk-trail))
(pl-cp-test!
"upcase_atom(hello, X) -> X='HELLO'"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-ua "X")))
"HELLO")
(pl-cp-test!
"upcase_atom(hello, 'HELLO') succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "upcase_atom(hello, 'HELLO')" {})
(pl-mk-trail))
true)
(pl-cp-test!
"upcase_atom('Hello World', 'HELLO WORLD') succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "upcase_atom('Hello World', 'HELLO WORLD')" {})
(pl-mk-trail))
true)
(pl-cp-test!
"upcase_atom('', '') succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "upcase_atom('', '')" {})
(pl-mk-trail))
true)
;; ─── downcase_atom/2 ─────────────────────────────────────────────
(define pl-cp-env-da {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "downcase_atom('HELLO', X)" pl-cp-env-da)
(pl-mk-trail))
(pl-cp-test!
"downcase_atom('HELLO', X) -> X=hello"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-da "X")))
"hello")
(pl-cp-test!
"downcase_atom('HELLO', hello) succeeds"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "downcase_atom('HELLO', hello)" {})
(pl-mk-trail))
true)
(pl-cp-test!
"downcase_atom(hello, hello) succeeds — already lowercase"
(pl-solve-once!
pl-cp-db
(pl-cp-goal "downcase_atom(hello, hello)" {})
(pl-mk-trail))
true)
;; ─── string_upper/2 + string_lower/2 (aliases) ───────────────────
(define pl-cp-env-su {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "string_upper(hello, X)" pl-cp-env-su)
(pl-mk-trail))
(pl-cp-test!
"string_upper(hello, X) -> X='HELLO'"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-su "X")))
"HELLO")
(define pl-cp-env-sl {})
(pl-solve-once!
pl-cp-db
(pl-cp-goal "string_lower('WORLD', X)" pl-cp-env-sl)
(pl-mk-trail))
(pl-cp-test!
"string_lower('WORLD', X) -> X=world"
(pl-atom-name (pl-walk-deep (dict-get pl-cp-env-sl "X")))
"world")
(define pl-char-predicates-tests-run! (fn () {:failed pl-cp-test-fail :passed pl-cp-test-pass :total pl-cp-test-count :failures pl-cp-test-failures}))

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;; lib/prolog/tests/clausedb.sx — Clause DB unit tests
(define pl-db-test-count 0)
(define pl-db-test-pass 0)
(define pl-db-test-fail 0)
(define pl-db-test-failures (list))
(define
pl-db-test!
(fn
(name got expected)
(begin
(set! pl-db-test-count (+ pl-db-test-count 1))
(if
(= got expected)
(set! pl-db-test-pass (+ pl-db-test-pass 1))
(begin
(set! pl-db-test-fail (+ pl-db-test-fail 1))
(append!
pl-db-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(pl-db-test!
"head-key atom arity 0"
(pl-head-key (nth (first (pl-parse "foo.")) 1))
"foo/0")
(pl-db-test!
"head-key compound arity 2"
(pl-head-key (nth (first (pl-parse "bar(a, b).")) 1))
"bar/2")
(pl-db-test!
"clause-key of :- clause"
(pl-clause-key (first (pl-parse "likes(mary, X) :- friendly(X).")))
"likes/2")
(pl-db-test!
"empty db lookup returns empty list"
(len (pl-db-lookup (pl-mk-db) "parent/2"))
0)
(define pl-db-t1 (pl-mk-db))
(pl-db-load! pl-db-t1 (pl-parse "foo(a). foo(b). foo(c)."))
(pl-db-test!
"three facts same functor"
(len (pl-db-lookup pl-db-t1 "foo/1"))
3)
(pl-db-test!
"mismatching key returns empty"
(len (pl-db-lookup pl-db-t1 "foo/2"))
0)
(pl-db-test!
"first clause has arg a"
(pl-atom-name
(first (pl-args (nth (first (pl-db-lookup pl-db-t1 "foo/1")) 1))))
"a")
(pl-db-test!
"third clause has arg c"
(pl-atom-name
(first (pl-args (nth (nth (pl-db-lookup pl-db-t1 "foo/1") 2) 1))))
"c")
(define pl-db-t2 (pl-mk-db))
(pl-db-load! pl-db-t2 (pl-parse "foo. bar. foo. parent(a, b). parent(c, d)."))
(pl-db-test!
"atom heads keyed as foo/0"
(len (pl-db-lookup pl-db-t2 "foo/0"))
2)
(pl-db-test!
"atom heads keyed as bar/0"
(len (pl-db-lookup pl-db-t2 "bar/0"))
1)
(pl-db-test!
"compound heads keyed as parent/2"
(len (pl-db-lookup pl-db-t2 "parent/2"))
2)
(pl-db-test!
"lookup-goal extracts functor/arity"
(len
(pl-db-lookup-goal pl-db-t2 (nth (first (pl-parse "parent(X, Y).")) 1)))
2)
(pl-db-test!
"lookup-goal on atom goal"
(len (pl-db-lookup-goal pl-db-t2 (nth (first (pl-parse "foo.")) 1)))
2)
(pl-db-test!
"stored clause is clause form"
(first (first (pl-db-lookup pl-db-t2 "parent/2")))
"clause")
(define pl-clausedb-tests-run! (fn () {:failed pl-db-test-fail :passed pl-db-test-pass :total pl-db-test-count :failures pl-db-test-failures}))

185
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;; lib/prolog/tests/compiler.sx — compiled clause dispatch tests
(define pl-cmp-test-count 0)
(define pl-cmp-test-pass 0)
(define pl-cmp-test-fail 0)
(define pl-cmp-test-failures (list))
(define
pl-cmp-test!
(fn
(name got expected)
(set! pl-cmp-test-count (+ pl-cmp-test-count 1))
(if
(= got expected)
(set! pl-cmp-test-pass (+ pl-cmp-test-pass 1))
(begin
(set! pl-cmp-test-fail (+ pl-cmp-test-fail 1))
(append! pl-cmp-test-failures name)))))
;; Load src, compile, return DB.
(define
pl-cmp-mk
(fn
(src)
(let
((db (pl-mk-db)))
(pl-db-load! db (pl-parse src))
(pl-compile-db! db)
db)))
;; Run goal string against compiled DB; return bool (instantiates vars).
(define
pl-cmp-once
(fn
(db src)
(pl-solve-once!
db
(pl-instantiate (pl-parse-goal src) {})
(pl-mk-trail))))
;; Count solutions for goal string against compiled DB.
(define
pl-cmp-count
(fn
(db src)
(pl-solve-count!
db
(pl-instantiate (pl-parse-goal src) {})
(pl-mk-trail))))
;; ── 1. Simple facts ──────────────────────────────────────────────
(define pl-cmp-db1 (pl-cmp-mk "color(red). color(green). color(blue)."))
(pl-cmp-test! "compiled fact hit" (pl-cmp-once pl-cmp-db1 "color(red)") true)
(pl-cmp-test!
"compiled fact miss"
(pl-cmp-once pl-cmp-db1 "color(yellow)")
false)
(pl-cmp-test! "compiled fact count" (pl-cmp-count pl-cmp-db1 "color(X)") 3)
;; ── 2. Recursive rule: append ────────────────────────────────────
(define
pl-cmp-db2
(pl-cmp-mk "append([], L, L). append([H|T], L, [H|R]) :- append(T, L, R)."))
(pl-cmp-test!
"compiled append build"
(pl-cmp-once pl-cmp-db2 "append([1,2],[3],[1,2,3])")
true)
(pl-cmp-test!
"compiled append fail"
(pl-cmp-once pl-cmp-db2 "append([1,2],[3],[1,2])")
false)
(pl-cmp-test!
"compiled append split count"
(pl-cmp-count pl-cmp-db2 "append(X, Y, [a,b])")
3)
;; ── 3. Cut ───────────────────────────────────────────────────────
(define
pl-cmp-db3
(pl-cmp-mk "first(X, [X|_]) :- !. first(X, [_|T]) :- first(X, T)."))
(pl-cmp-test!
"compiled cut: only one solution"
(pl-cmp-count pl-cmp-db3 "first(X, [a,b,c])")
1)
(let
((db pl-cmp-db3) (trail (pl-mk-trail)) (env {}))
(let
((x (pl-mk-rt-var "X")))
(dict-set! env "X" x)
(pl-solve-once!
db
(pl-instantiate (pl-parse-goal "first(X, [a,b,c])") env)
trail)
(pl-cmp-test!
"compiled cut: correct binding"
(pl-atom-name (pl-walk x))
"a")))
;; ── 4. member ────────────────────────────────────────────────────
(define
pl-cmp-db4
(pl-cmp-mk "member(X, [X|_]). member(X, [_|T]) :- member(X, T)."))
(pl-cmp-test!
"compiled member hit"
(pl-cmp-once pl-cmp-db4 "member(b, [a,b,c])")
true)
(pl-cmp-test!
"compiled member miss"
(pl-cmp-once pl-cmp-db4 "member(d, [a,b,c])")
false)
(pl-cmp-test!
"compiled member count"
(pl-cmp-count pl-cmp-db4 "member(X, [a,b,c])")
3)
;; ── 5. Arithmetic in body ────────────────────────────────────────
(define pl-cmp-db5 (pl-cmp-mk "double(X, Y) :- Y is X * 2."))
(let
((db pl-cmp-db5) (trail (pl-mk-trail)) (env {}))
(let
((y (pl-mk-rt-var "Y")))
(dict-set! env "Y" y)
(pl-solve-once!
db
(pl-instantiate (pl-parse-goal "double(5, Y)") env)
trail)
(pl-cmp-test! "compiled arithmetic in body" (pl-num-val (pl-walk y)) 10)))
;; ── 6. Transitive ancestor ───────────────────────────────────────
(define
pl-cmp-db6
(pl-cmp-mk
(str
"parent(a,b). parent(b,c). parent(c,d)."
"ancestor(X,Y) :- parent(X,Y)."
"ancestor(X,Y) :- parent(X,Z), ancestor(Z,Y).")))
(pl-cmp-test!
"compiled ancestor direct"
(pl-cmp-once pl-cmp-db6 "ancestor(a,b)")
true)
(pl-cmp-test!
"compiled ancestor 3-step"
(pl-cmp-once pl-cmp-db6 "ancestor(a,d)")
true)
(pl-cmp-test!
"compiled ancestor fail"
(pl-cmp-once pl-cmp-db6 "ancestor(d,a)")
false)
;; ── 7. Fallback: uncompiled predicate calls compiled sub-predicate
(define
pl-cmp-db7
(let
((db (pl-mk-db)))
(pl-db-load! db (pl-parse "q(1). q(2)."))
(pl-compile-db! db)
(pl-db-load! db (pl-parse "r(X) :- q(X)."))
db))
(pl-cmp-test!
"uncompiled predicate resolves"
(pl-cmp-once pl-cmp-db7 "r(1)")
true)
(pl-cmp-test!
"uncompiled calls compiled sub-pred count"
(pl-cmp-count pl-cmp-db7 "r(X)")
2)
;; ── Runner ───────────────────────────────────────────────────────
(define pl-compiler-tests-run! (fn () {:failed pl-cmp-test-fail :passed pl-cmp-test-pass :total pl-cmp-test-count :failures pl-cmp-test-failures}))

86
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;; lib/prolog/tests/cross_validate.sx
;; Verifies that the compiled solver produces the same solution counts as the
;; interpreter for each classic program + built-in exercise.
;; Interpreter is the reference: if they disagree, the compiler is wrong.
(define pl-xv-test-count 0)
(define pl-xv-test-pass 0)
(define pl-xv-test-fail 0)
(define pl-xv-test-failures (list))
(define
pl-xv-test!
(fn
(name got expected)
(set! pl-xv-test-count (+ pl-xv-test-count 1))
(if
(= got expected)
(set! pl-xv-test-pass (+ pl-xv-test-pass 1))
(begin
(set! pl-xv-test-fail (+ pl-xv-test-fail 1))
(append! pl-xv-test-failures name)))))
;; Shorthand: assert compiled result matches interpreter.
(define
pl-xv-match!
(fn
(name src goal)
(pl-xv-test! name (pl-compiled-matches-interp? src goal) true)))
;; ── 1. append/3 ─────────────────────────────────────────────────
(define
pl-xv-append
"append([], L, L). append([H|T], L, [H|R]) :- append(T, L, R).")
(pl-xv-match! "append build 2+2" pl-xv-append "append([1,2],[3,4],X)")
(pl-xv-match! "append split [a,b,c]" pl-xv-append "append(X, Y, [a,b,c])")
(pl-xv-match! "append member-mode" pl-xv-append "append(_, [3], [1,2,3])")
;; ── 2. member/2 ─────────────────────────────────────────────────
(define pl-xv-member "member(X, [X|_]). member(X, [_|T]) :- member(X, T).")
(pl-xv-match! "member check hit" pl-xv-member "member(b, [a,b,c])")
(pl-xv-match! "member count" pl-xv-member "member(X, [a,b,c])")
(pl-xv-match! "member empty" pl-xv-member "member(X, [])")
;; ── 3. facts + transitive rules ─────────────────────────────────
(define
pl-xv-ancestor
(str
"parent(a,b). parent(b,c). parent(c,d). parent(a,c)."
"ancestor(X,Y) :- parent(X,Y)."
"ancestor(X,Y) :- parent(X,Z), ancestor(Z,Y)."))
(pl-xv-match! "ancestor direct" pl-xv-ancestor "ancestor(a,b)")
(pl-xv-match! "ancestor transitive" pl-xv-ancestor "ancestor(a,d)")
(pl-xv-match! "ancestor all from a" pl-xv-ancestor "ancestor(a,Y)")
;; ── 4. cut semantics ────────────────────────────────────────────
(define pl-xv-cut "first(X,[X|_]) :- !. first(X,[_|T]) :- first(X,T).")
(pl-xv-match! "cut one solution" pl-xv-cut "first(X,[a,b,c])")
(pl-xv-match! "cut empty list" pl-xv-cut "first(X,[])")
;; ── 5. arithmetic ───────────────────────────────────────────────
(define pl-xv-arith "sq(X,Y) :- Y is X * X. even(X) :- 0 is X mod 2.")
(pl-xv-match! "sq(3,Y) count" pl-xv-arith "sq(3,Y)")
(pl-xv-match! "sq(3,9) check" pl-xv-arith "sq(3,9)")
(pl-xv-match! "even(4) check" pl-xv-arith "even(4)")
(pl-xv-match! "even(3) check" pl-xv-arith "even(3)")
;; ── 6. if-then-else ─────────────────────────────────────────────
(define pl-xv-ite "classify(X, pos) :- X > 0, !. classify(_, nonpos).")
(pl-xv-match! "classify positive" pl-xv-ite "classify(5, C)")
(pl-xv-match! "classify zero" pl-xv-ite "classify(0, C)")
;; ── Runner ───────────────────────────────────────────────────────
(define pl-cross-validate-tests-run! (fn () {:failed pl-xv-test-fail :passed pl-xv-test-pass :total pl-xv-test-count :failures pl-xv-test-failures}))

158
lib/prolog/tests/dynamic.sx
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;; lib/prolog/tests/dynamic.sx — assert/asserta/assertz/retract.
(define pl-dy-test-count 0)
(define pl-dy-test-pass 0)
(define pl-dy-test-fail 0)
(define pl-dy-test-failures (list))
(define
pl-dy-test!
(fn
(name got expected)
(begin
(set! pl-dy-test-count (+ pl-dy-test-count 1))
(if
(= got expected)
(set! pl-dy-test-pass (+ pl-dy-test-pass 1))
(begin
(set! pl-dy-test-fail (+ pl-dy-test-fail 1))
(append!
pl-dy-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-dy-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
;; assertz then query
(define pl-dy-db1 (pl-mk-db))
(pl-solve-once!
pl-dy-db1
(pl-dy-goal "assertz(foo(1))" {})
(pl-mk-trail))
(pl-dy-test!
"assertz(foo(1)) + foo(1)"
(pl-solve-once! pl-dy-db1 (pl-dy-goal "foo(1)" {}) (pl-mk-trail))
true)
(pl-dy-test!
"after one assertz, foo/1 has 1 clause"
(pl-solve-count! pl-dy-db1 (pl-dy-goal "foo(X)" {}) (pl-mk-trail))
1)
;; assertz appends — order preserved
(define pl-dy-db2 (pl-mk-db))
(pl-solve-once!
pl-dy-db2
(pl-dy-goal "assertz(p(1))" {})
(pl-mk-trail))
(pl-solve-once!
pl-dy-db2
(pl-dy-goal "assertz(p(2))" {})
(pl-mk-trail))
(pl-dy-test!
"assertz twice — count 2"
(pl-solve-count! pl-dy-db2 (pl-dy-goal "p(X)" {}) (pl-mk-trail))
2)
(define pl-dy-env-a {})
(pl-solve-once! pl-dy-db2 (pl-dy-goal "p(X)" pl-dy-env-a) (pl-mk-trail))
(pl-dy-test!
"assertz: first solution is the first asserted (1)"
(pl-num-val (pl-walk-deep (dict-get pl-dy-env-a "X")))
1)
;; asserta prepends
(define pl-dy-db3 (pl-mk-db))
(pl-solve-once!
pl-dy-db3
(pl-dy-goal "assertz(p(1))" {})
(pl-mk-trail))
(pl-solve-once!
pl-dy-db3
(pl-dy-goal "asserta(p(99))" {})
(pl-mk-trail))
(define pl-dy-env-b {})
(pl-solve-once! pl-dy-db3 (pl-dy-goal "p(X)" pl-dy-env-b) (pl-mk-trail))
(pl-dy-test!
"asserta: prepended clause is first solution"
(pl-num-val (pl-walk-deep (dict-get pl-dy-env-b "X")))
99)
;; assert/1 = assertz/1
(define pl-dy-db4 (pl-mk-db))
(pl-solve-once!
pl-dy-db4
(pl-dy-goal "assert(g(7))" {})
(pl-mk-trail))
(pl-dy-test!
"assert/1 alias"
(pl-solve-once! pl-dy-db4 (pl-dy-goal "g(7)" {}) (pl-mk-trail))
true)
;; retract removes a fact
(define pl-dy-db5 (pl-mk-db))
(pl-solve-once!
pl-dy-db5
(pl-dy-goal "assertz(q(1))" {})
(pl-mk-trail))
(pl-solve-once!
pl-dy-db5
(pl-dy-goal "assertz(q(2))" {})
(pl-mk-trail))
(pl-solve-once!
pl-dy-db5
(pl-dy-goal "assertz(q(3))" {})
(pl-mk-trail))
(pl-dy-test!
"before retract: 3 clauses"
(pl-solve-count! pl-dy-db5 (pl-dy-goal "q(X)" {}) (pl-mk-trail))
3)
(pl-solve-once!
pl-dy-db5
(pl-dy-goal "retract(q(2))" {})
(pl-mk-trail))
(pl-dy-test!
"after retract(q(2)): 2 clauses left"
(pl-solve-count! pl-dy-db5 (pl-dy-goal "q(X)" {}) (pl-mk-trail))
2)
(define pl-dy-env-c {})
(pl-solve-once! pl-dy-db5 (pl-dy-goal "q(X)" pl-dy-env-c) (pl-mk-trail))
(pl-dy-test!
"after retract(q(2)): first remaining is 1"
(pl-num-val (pl-walk-deep (dict-get pl-dy-env-c "X")))
1)
;; retract of non-existent
(pl-dy-test!
"retract(missing(0)) on empty db fails"
(pl-solve-once!
(pl-mk-db)
(pl-dy-goal "retract(missing(0))" {})
(pl-mk-trail))
false)
;; retract with unbound var matches first
(define pl-dy-db6 (pl-mk-db))
(pl-solve-once!
pl-dy-db6
(pl-dy-goal "assertz(r(11))" {})
(pl-mk-trail))
(pl-solve-once!
pl-dy-db6
(pl-dy-goal "assertz(r(22))" {})
(pl-mk-trail))
(define pl-dy-env-d {})
(pl-solve-once!
pl-dy-db6
(pl-dy-goal "retract(r(X))" pl-dy-env-d)
(pl-mk-trail))
(pl-dy-test!
"retract(r(X)) binds X to first match"
(pl-num-val (pl-walk-deep (dict-get pl-dy-env-d "X")))
11)
(define pl-dynamic-tests-run! (fn () {:failed pl-dy-test-fail :passed pl-dy-test-pass :total pl-dy-test-count :failures pl-dy-test-failures}))

167
lib/prolog/tests/findall.sx
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@@ -1,167 +0,0 @@
;; lib/prolog/tests/findall.sx — findall/3, bagof/3, setof/3.
(define pl-fb-test-count 0)
(define pl-fb-test-pass 0)
(define pl-fb-test-fail 0)
(define pl-fb-test-failures (list))
(define
pl-fb-test!
(fn
(name got expected)
(begin
(set! pl-fb-test-count (+ pl-fb-test-count 1))
(if
(= got expected)
(set! pl-fb-test-pass (+ pl-fb-test-pass 1))
(begin
(set! pl-fb-test-fail (+ pl-fb-test-fail 1))
(append!
pl-fb-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-fb-term-to-sx
(fn
(t)
(cond
((pl-num? t) (pl-num-val t))
((pl-atom? t) (pl-atom-name t))
(true (list :complex)))))
(define
pl-fb-list-walked
(fn
(w)
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) ".") (= (len (pl-args w)) 2))
(cons
(pl-fb-term-to-sx (first (pl-args w)))
(pl-fb-list-walked (nth (pl-args w) 1))))
(true (list :not-list)))))
(define pl-fb-list-to-sx (fn (t) (pl-fb-list-walked (pl-walk-deep t))))
(define
pl-fb-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-fb-prog-src "member(X, [X|_]). member(X, [_|T]) :- member(X, T).")
(define pl-fb-db (pl-mk-db))
(pl-db-load! pl-fb-db (pl-parse pl-fb-prog-src))
;; ── findall ──
(define pl-fb-env-1 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "findall(X, member(X, [a, b, c]), L)" pl-fb-env-1)
(pl-mk-trail))
(pl-fb-test!
"findall member [a, b, c]"
(pl-fb-list-to-sx (dict-get pl-fb-env-1 "L"))
(list "a" "b" "c"))
(define pl-fb-env-2 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "findall(X, (member(X, [1, 2, 3]), X >= 2), L)" pl-fb-env-2)
(pl-mk-trail))
(pl-fb-test!
"findall with comparison filter"
(pl-fb-list-to-sx (dict-get pl-fb-env-2 "L"))
(list 2 3))
(define pl-fb-env-3 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "findall(X, fail, L)" pl-fb-env-3)
(pl-mk-trail))
(pl-fb-test!
"findall on fail succeeds with empty list"
(pl-fb-list-to-sx (dict-get pl-fb-env-3 "L"))
(list))
(pl-fb-test!
"findall(X, fail, L) the goal succeeds"
(pl-solve-once!
pl-fb-db
(pl-fb-goal "findall(X, fail, L)" {})
(pl-mk-trail))
true)
(define pl-fb-env-4 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal
"findall(p(X, Y), (member(X, [1, 2]), member(Y, [a, b])), L)"
pl-fb-env-4)
(pl-mk-trail))
(pl-fb-test!
"findall over compound template — count = 4"
(len (pl-fb-list-to-sx (dict-get pl-fb-env-4 "L")))
4)
;; ── bagof ──
(pl-fb-test!
"bagof succeeds when results exist"
(pl-solve-once!
pl-fb-db
(pl-fb-goal "bagof(X, member(X, [1, 2, 3]), L)" {})
(pl-mk-trail))
true)
(pl-fb-test!
"bagof fails on empty"
(pl-solve-once!
pl-fb-db
(pl-fb-goal "bagof(X, fail, L)" {})
(pl-mk-trail))
false)
(define pl-fb-env-5 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "bagof(X, member(X, [c, a, b]), L)" pl-fb-env-5)
(pl-mk-trail))
(pl-fb-test!
"bagof preserves order"
(pl-fb-list-to-sx (dict-get pl-fb-env-5 "L"))
(list "c" "a" "b"))
;; ── setof ──
(define pl-fb-env-6 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "setof(X, member(X, [c, a, b, a, c]), L)" pl-fb-env-6)
(pl-mk-trail))
(pl-fb-test!
"setof sorts + dedupes atoms"
(pl-fb-list-to-sx (dict-get pl-fb-env-6 "L"))
(list "a" "b" "c"))
(pl-fb-test!
"setof fails on empty"
(pl-solve-once!
pl-fb-db
(pl-fb-goal "setof(X, fail, L)" {})
(pl-mk-trail))
false)
(define pl-fb-env-7 {})
(pl-solve-once!
pl-fb-db
(pl-fb-goal "setof(X, member(X, [3, 1, 2, 1, 3]), L)" pl-fb-env-7)
(pl-mk-trail))
(pl-fb-test!
"setof sorts + dedupes nums"
(pl-fb-list-to-sx (dict-get pl-fb-env-7 "L"))
(list 1 2 3))
(define pl-findall-tests-run! (fn () {:failed pl-fb-test-fail :passed pl-fb-test-pass :total pl-fb-test-count :failures pl-fb-test-failures}))

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;; lib/prolog/tests/hs_bridge.sx — tests for Prolog↔Hyperscript bridge
;;
;; Verifies pl-hs-query, pl-hs-predicate/N, and pl-hs-install.
;; Also demonstrates the end-to-end DSL pattern:
;; (define allowed (pl-hs-predicate/2 db "allowed"))
;; → (allowed "alice" "edit") is what Hyperscript compiles
;; `when allowed(alice, edit)` to.
(define pl-hsb-test-count 0)
(define pl-hsb-test-pass 0)
(define pl-hsb-test-fail 0)
(define pl-hsb-test-failures (list))
(define
pl-hsb-test!
(fn
(name got expected)
(begin
(set! pl-hsb-test-count (+ pl-hsb-test-count 1))
(if
(= got expected)
(set! pl-hsb-test-pass (+ pl-hsb-test-pass 1))
(begin
(set! pl-hsb-test-fail (+ pl-hsb-test-fail 1))
(append!
pl-hsb-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
;; ── shared KB ──
(define
pl-hsb-perm-src
"role(alice, admin). role(bob, editor). role(charlie, viewer). permission(admin, read). permission(admin, write). permission(admin, delete). permission(editor, read). permission(editor, write). permission(viewer, read). allowed(U, A) :- role(U, R), permission(R, A).")
(define pl-hsb-db (pl-load pl-hsb-perm-src))
;; ── pl-hs-query ──
(pl-hsb-test!
"pl-hs-query: ground fact succeeds"
(pl-hs-query pl-hsb-db "role(alice, admin)")
true)
(pl-hsb-test!
"pl-hs-query: absent fact fails"
(pl-hs-query pl-hsb-db "role(alice, viewer)")
false)
(pl-hsb-test!
"pl-hs-query: rule derivation succeeds"
(pl-hs-query pl-hsb-db "allowed(alice, delete)")
true)
(pl-hsb-test!
"pl-hs-query: rule derivation fails"
(pl-hs-query pl-hsb-db "allowed(charlie, delete)")
false)
(pl-hsb-test!
"pl-hs-query: arithmetic goal"
(pl-hs-query pl-hsb-db "X is 3 + 4, X = 7")
true)
;; ── pl-hs-predicate/2 ──
(define pl-hsb-allowed (pl-hs-predicate/2 pl-hsb-db "allowed"))
(pl-hsb-test!
"predicate/2: alice can read"
(pl-hsb-allowed "alice" "read")
true)
(pl-hsb-test!
"predicate/2: alice can delete"
(pl-hsb-allowed "alice" "delete")
true)
(pl-hsb-test!
"predicate/2: charlie cannot write"
(pl-hsb-allowed "charlie" "write")
false)
(pl-hsb-test!
"predicate/2: bob can write"
(pl-hsb-allowed "bob" "write")
true)
(pl-hsb-test!
"predicate/2: unknown user fails"
(pl-hsb-allowed "eve" "read")
false)
;; ── DSL simulation ──
;; Hyperscript compiles `when allowed(user, action) then …`
;; to `(allowed user action)` — a direct SX function call.
;; Here we verify that pattern works end-to-end.
(define pl-hsb-user "alice")
(define pl-hsb-action "write")
(pl-hsb-test!
"DSL simulation: (allowed user action) true path"
(pl-hsb-allowed pl-hsb-user pl-hsb-action)
true)
(define pl-hsb-user2 "charlie")
(pl-hsb-test!
"DSL simulation: (allowed user action) false path"
(pl-hsb-allowed pl-hsb-user2 pl-hsb-action)
false)
;; ── pl-hs-predicate/1 ──
(define pl-hsb-viewer-src "color(red). color(green). color(blue).")
(define pl-hsb-color-db (pl-load pl-hsb-viewer-src))
(define pl-hsb-color? (pl-hs-predicate/1 pl-hsb-color-db "color"))
(pl-hsb-test! "predicate/1: color(red) succeeds" (pl-hsb-color? "red") true)
(pl-hsb-test!
"predicate/1: color(purple) fails"
(pl-hsb-color? "purple")
false)
;; ── pl-hs-predicate/3 ──
(define pl-hsb-3ary-src "between_vals(X, Lo, Hi) :- X >= Lo, X =< Hi.")
(define pl-hsb-3ary-db (pl-load pl-hsb-3ary-src))
(define pl-hsb-in-range? (pl-hs-predicate/3 pl-hsb-3ary-db "between_vals"))
(pl-hsb-test!
"predicate/3: 5 in range [1,10]"
(pl-hsb-in-range? "5" "1" "10")
true)
(pl-hsb-test!
"predicate/3: 15 not in range [1,10]"
(pl-hsb-in-range? "15" "1" "10")
false)
;; ── pl-hs-install ──
(define
pl-hsb-installed
(pl-hs-install
pl-hsb-db
(list (list "allowed" 2) (list "role" 2) (list "permission" 2))))
(pl-hsb-test!
"pl-hs-install: returns dict with allowed key"
(not (nil? (dict-get pl-hsb-installed "allowed")))
true)
(pl-hsb-test!
"pl-hs-install: installed allowed fn works"
((dict-get pl-hsb-installed "allowed") "alice" "delete")
true)
(pl-hsb-test!
"pl-hs-install: installed role fn works"
((dict-get pl-hsb-installed "role") "bob" "editor")
true)
(define pl-hs-bridge-tests-run! (fn () {:failed pl-hsb-test-fail :passed pl-hsb-test-pass :total pl-hsb-test-count :failures pl-hsb-test-failures}))

172
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;; lib/prolog/tests/integration.sx — end-to-end integration tests via pl-query-* API
;;
;; Tests the full source→parse→load→solve pipeline with real programs.
;; Covers: permission system, graph reachability, quicksort, fibonacci, dynamic KB.
(define pl-int-test-count 0)
(define pl-int-test-pass 0)
(define pl-int-test-fail 0)
(define pl-int-test-failures (list))
(define
pl-int-test!
(fn
(name got expected)
(begin
(set! pl-int-test-count (+ pl-int-test-count 1))
(if
(= got expected)
(set! pl-int-test-pass (+ pl-int-test-pass 1))
(begin
(set! pl-int-test-fail (+ pl-int-test-fail 1))
(append!
pl-int-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
;; ── Permission system ──
;; role/2 + permission/2 facts, allowed/2 rule
(define
pl-int-perm-src
"role(alice, admin). role(bob, editor). role(charlie, viewer). permission(admin, read). permission(admin, write). permission(admin, delete). permission(editor, read). permission(editor, write). permission(viewer, read). allowed(U, A) :- role(U, R), permission(R, A).")
(define pl-int-perm-db (pl-load pl-int-perm-src))
(pl-int-test!
"alice can read"
(len (pl-query-all pl-int-perm-db "allowed(alice, read)"))
1)
(pl-int-test!
"alice can delete"
(len (pl-query-all pl-int-perm-db "allowed(alice, delete)"))
1)
(pl-int-test!
"charlie cannot write"
(len (pl-query-all pl-int-perm-db "allowed(charlie, write)"))
0)
(pl-int-test!
"alice has 3 permissions"
(len (pl-query-all pl-int-perm-db "allowed(alice, A)"))
3)
(pl-int-test!
"only one user can delete"
(len (pl-query-all pl-int-perm-db "allowed(U, delete)"))
1)
(pl-int-test!
"the deleter is alice"
(dict-get (first (pl-query-all pl-int-perm-db "allowed(U, delete)")) "U")
"alice")
;; ── Graph reachability ──
;; Directed edges; path/2 transitive closure via two clauses
(define
pl-int-graph-src
"edge(a, b). edge(b, c). edge(c, d). edge(b, d). path(X, Y) :- edge(X, Y). path(X, Y) :- edge(X, Z), path(Z, Y).")
(define pl-int-graph-db (pl-load pl-int-graph-src))
(pl-int-test!
"direct edge a→b is a path"
(len (pl-query-all pl-int-graph-db "path(a, b)"))
1)
(pl-int-test!
"transitive path a→c"
(len (pl-query-all pl-int-graph-db "path(a, c)"))
1)
(pl-int-test!
"no path d→a (no back-edges)"
(len (pl-query-all pl-int-graph-db "path(d, a)"))
0)
(pl-int-test!
"4 derivations from a (b,c,d via two routes to d)"
(len (pl-query-all pl-int-graph-db "path(a, Y)"))
4)
;; ── Quicksort ──
;; Partition-and-recurse; uses its own append/3 to avoid DB pollution
(define
pl-int-qs-src
"partition(_, [], [], []). partition(Piv, [H|T], [H|Less], Greater) :- H =< Piv, !, partition(Piv, T, Less, Greater). partition(Piv, [H|T], Less, [H|Greater]) :- partition(Piv, T, Less, Greater). append([], L, L). append([H|T], L, [H|R]) :- append(T, L, R). quicksort([], []). quicksort([H|T], Sorted) :- partition(H, T, Less, Greater), quicksort(Less, SL), quicksort(Greater, SG), append(SL, [H|SG], Sorted).")
(define pl-int-qs-db (pl-load pl-int-qs-src))
(pl-int-test!
"quicksort([]) = [] (ground check)"
(len (pl-query-all pl-int-qs-db "quicksort([], [])"))
1)
(pl-int-test!
"quicksort([3,1,2]) = [1,2,3] (ground check)"
(len (pl-query-all pl-int-qs-db "quicksort([3,1,2], [1,2,3])"))
1)
(pl-int-test!
"quicksort([5,3,1,4,2]) = [1,2,3,4,5] (ground check)"
(len (pl-query-all pl-int-qs-db "quicksort([5,3,1,4,2], [1,2,3,4,5])"))
1)
(pl-int-test!
"quicksort([3,1,2], [3,1,2]) fails — unsorted order rejected"
(len (pl-query-all pl-int-qs-db "quicksort([3,1,2], [3,1,2])"))
0)
;; ── Fibonacci ──
;; Naive recursive; ground checks avoid list-format uncertainty
(define
pl-int-fib-src
"fib(0, 0). fib(1, 1). fib(N, F) :- N > 1, N1 is N - 1, N2 is N - 2, fib(N1, F1), fib(N2, F2), F is F1 + F2.")
(define pl-int-fib-db (pl-load pl-int-fib-src))
(pl-int-test!
"fib(0, 0) succeeds"
(len (pl-query-all pl-int-fib-db "fib(0, 0)"))
1)
(pl-int-test!
"fib(5, 5) succeeds"
(len (pl-query-all pl-int-fib-db "fib(5, 5)"))
1)
(pl-int-test!
"fib(7, 13) succeeds"
(len (pl-query-all pl-int-fib-db "fib(7, 13)"))
1)
;; ── Dynamic knowledge base ──
;; Assert and retract facts; the DB dict is mutable so mutations persist
(define pl-int-dyn-src "color(red). color(green). color(blue).")
(define pl-int-dyn-db (pl-load pl-int-dyn-src))
(pl-int-test!
"initial KB: 3 colors"
(len (pl-query-all pl-int-dyn-db "color(X)"))
3)
(pl-int-test!
"after assert(color(yellow)): 4 colors"
(begin
(pl-query-all pl-int-dyn-db "assert(color(yellow))")
(len (pl-query-all pl-int-dyn-db "color(X)")))
4)
(pl-int-test!
"after retract(color(red)): back to 3 colors"
(begin
(pl-query-all pl-int-dyn-db "retract(color(red))")
(len (pl-query-all pl-int-dyn-db "color(X)")))
3)
(define pl-integration-tests-run! (fn () {:failed pl-int-test-fail :passed pl-int-test-pass :total pl-int-test-count :failures pl-int-test-failures}))

326
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;; lib/prolog/tests/io_predicates.sx — term_to_atom/2, term_string/2,
;; with_output_to/2, writeln/1, format/1, format/2
(define pl-io-test-count 0)
(define pl-io-test-pass 0)
(define pl-io-test-fail 0)
(define pl-io-test-failures (list))
(define
pl-io-test!
(fn
(name got expected)
(begin
(set! pl-io-test-count (+ pl-io-test-count 1))
(if
(= got expected)
(set! pl-io-test-pass (+ pl-io-test-pass 1))
(begin
(set! pl-io-test-fail (+ pl-io-test-fail 1))
(append!
pl-io-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-io-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-io-db (pl-mk-db))
;; helper: get output buffer after running a goal
(define
pl-io-capture!
(fn
(goal)
(do
(pl-output-clear!)
(pl-solve-once! pl-io-db goal (pl-mk-trail))
pl-output-buffer)))
;; ─── term_to_atom/2 — bound Term direction ─────────────────────────────────
(pl-io-test!
"term_to_atom(foo(a,b), A) — compound"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(foo(a,b), A)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "A"))))
"foo(a, b)")
(pl-io-test!
"term_to_atom(hello, A) — atom"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(hello, A)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "A"))))
"hello")
(pl-io-test!
"term_to_atom(42, A) — number"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(42, A)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "A"))))
"42")
(pl-io-test!
"term_to_atom(foo(a,b), 'foo(a, b)') — succeeds when Atom matches"
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(foo(a,b), 'foo(a, b)')" {})
(pl-mk-trail))
true)
(pl-io-test!
"term_to_atom(hello, world) — fails on mismatch"
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(hello, world)" {})
(pl-mk-trail))
false)
;; ─── term_to_atom/2 — parse direction (Atom bound, Term unbound) ───────────
(pl-io-test!
"term_to_atom(T, 'foo(a)') — parse direction gives compound"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(T, 'foo(a)')" env)
(pl-mk-trail))
(let
((t (pl-walk-deep (dict-get env "T"))))
(and (pl-compound? t) (= (pl-fun t) "foo"))))
true)
(pl-io-test!
"term_to_atom(T, hello) — parse direction gives atom"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_to_atom(T, hello)" env)
(pl-mk-trail))
(let
((t (pl-walk-deep (dict-get env "T"))))
(and (pl-atom? t) (= (pl-atom-name t) "hello"))))
true)
;; ─── term_string/2 — alias ──────────────────────────────────────────────────
(pl-io-test!
"term_string(bar(x), A) — same as term_to_atom"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_string(bar(x), A)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "A"))))
"bar(x)")
(pl-io-test!
"term_string(42, A) — number to string"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "term_string(42, A)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "A"))))
"42")
;; ─── writeln/1 ─────────────────────────────────────────────────────────────
(pl-io-test!
"writeln(hello) writes 'hello\n'"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), writeln(hello))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"hello
")
(pl-io-test!
"writeln(42) writes '42\n'"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), writeln(42))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"42
")
;; ─── with_output_to/2 ──────────────────────────────────────────────────────
(pl-io-test!
"with_output_to(atom(X), write(foo)) — captures write output"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), write(foo))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"foo")
(pl-io-test!
"with_output_to(atom(X), (write(a), write(b))) — concat output"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), (write(a), write(b)))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"ab")
(pl-io-test!
"with_output_to(atom(X), nl) — captures newline"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), nl)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"
")
(pl-io-test!
"with_output_to(atom(X), true) — captures empty string"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), true)" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"")
(pl-io-test!
"with_output_to(string(X), write(hello)) — string sink works"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(string(X), write(hello))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"hello")
(pl-io-test!
"with_output_to(atom(X), fail) — fails when goal fails"
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), fail)" {})
(pl-mk-trail))
false)
;; ─── format/1 ──────────────────────────────────────────────────────────────
(pl-io-test!
"format('hello~n') — tilde-n becomes newline"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('hello~n'))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"hello
")
(pl-io-test!
"format('~~') — double tilde becomes single tilde"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('~~'))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"~")
(pl-io-test!
"format('abc') — plain text passes through"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format(abc))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"abc")
;; ─── format/2 ──────────────────────────────────────────────────────────────
(pl-io-test!
"format('~w+~w', [1,2]) — two ~w args"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('~w+~w', [1,2]))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"1+2")
(pl-io-test!
"format('hello ~a!', [world]) — ~a with atom arg"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('hello ~a!', [world]))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"hello world!")
(pl-io-test!
"format('n=~d', [42]) — ~d with integer arg"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('n=~d', [42]))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"n=42")
(pl-io-test!
"format('~w', [foo(a)]) — ~w with compound"
(let
((env {}))
(pl-solve-once!
pl-io-db
(pl-io-goal "with_output_to(atom(X), format('~w', [foo(a)]))" env)
(pl-mk-trail))
(pl-atom-name (pl-walk-deep (dict-get env "X"))))
"foo(a)")
(define
pl-io-predicates-tests-run!
(fn
()
{:failed pl-io-test-fail
:passed pl-io-test-pass
:total pl-io-test-count
:failures pl-io-test-failures}))

320
lib/prolog/tests/iso_predicates.sx
View File

@@ -1,320 +0,0 @@
;; lib/prolog/tests/iso_predicates.sx — succ/2, plus/3, between/3, length/2, last/2, nth0/3, nth1/3, max/min arith
(define pl-ip-test-count 0)
(define pl-ip-test-pass 0)
(define pl-ip-test-fail 0)
(define pl-ip-test-failures (list))
(define
pl-ip-test!
(fn
(name got expected)
(begin
(set! pl-ip-test-count (+ pl-ip-test-count 1))
(if
(= got expected)
(set! pl-ip-test-pass (+ pl-ip-test-pass 1))
(begin
(set! pl-ip-test-fail (+ pl-ip-test-fail 1))
(append!
pl-ip-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-ip-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-ip-db (pl-mk-db))
;; ── succ/2 ──
(define pl-ip-env-s1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "succ(3, X)" pl-ip-env-s1)
(pl-mk-trail))
(pl-ip-test!
"succ(3, X) → X=4"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-s1 "X")))
4)
(define pl-ip-env-s2 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "succ(0, X)" pl-ip-env-s2)
(pl-mk-trail))
(pl-ip-test!
"succ(0, X) → X=1"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-s2 "X")))
1)
(define pl-ip-env-s3 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "succ(X, 5)" pl-ip-env-s3)
(pl-mk-trail))
(pl-ip-test!
"succ(X, 5) → X=4"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-s3 "X")))
4)
(pl-ip-test!
"succ(X, 0) fails"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "succ(X, 0)" {})
(pl-mk-trail))
false)
;; ── plus/3 ──
(define pl-ip-env-p1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "plus(2, 3, X)" pl-ip-env-p1)
(pl-mk-trail))
(pl-ip-test!
"plus(2, 3, X) → X=5"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-p1 "X")))
5)
(define pl-ip-env-p2 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "plus(2, X, 7)" pl-ip-env-p2)
(pl-mk-trail))
(pl-ip-test!
"plus(2, X, 7) → X=5"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-p2 "X")))
5)
(define pl-ip-env-p3 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "plus(X, 3, 7)" pl-ip-env-p3)
(pl-mk-trail))
(pl-ip-test!
"plus(X, 3, 7) → X=4"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-p3 "X")))
4)
(pl-ip-test!
"plus(0, 0, 0) succeeds"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "plus(0, 0, 0)" {})
(pl-mk-trail))
true)
;; ── between/3 ──
(pl-ip-test!
"between(1, 3, X): 3 solutions"
(pl-solve-count!
pl-ip-db
(pl-ip-goal "between(1, 3, X)" {})
(pl-mk-trail))
3)
(pl-ip-test!
"between(1, 3, 2) succeeds"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "between(1, 3, 2)" {})
(pl-mk-trail))
true)
(pl-ip-test!
"between(1, 3, 5) fails"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "between(1, 3, 5)" {})
(pl-mk-trail))
false)
(pl-ip-test!
"between(5, 3, X): 0 solutions (empty range)"
(pl-solve-count!
pl-ip-db
(pl-ip-goal "between(5, 3, X)" {})
(pl-mk-trail))
0)
(define pl-ip-env-b1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "between(1, 5, X)" pl-ip-env-b1)
(pl-mk-trail))
(pl-ip-test!
"between(1, 5, X): first solution X=1"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-b1 "X")))
1)
(pl-ip-test!
"between + condition: between(1,5,X), X > 3 → 2 solutions"
(pl-solve-count!
pl-ip-db
(pl-ip-goal "between(1, 5, X), X > 3" {})
(pl-mk-trail))
2)
;; ── length/2 ──
(define pl-ip-env-l1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "length([1,2,3], N)" pl-ip-env-l1)
(pl-mk-trail))
(pl-ip-test!
"length([1,2,3], N) → N=3"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-l1 "N")))
3)
(define pl-ip-env-l2 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "length([], N)" pl-ip-env-l2)
(pl-mk-trail))
(pl-ip-test!
"length([], N) → N=0"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-l2 "N")))
0)
(pl-ip-test!
"length([a,b], 2) check succeeds"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "length([a,b], 2)" {})
(pl-mk-trail))
true)
(define pl-ip-env-l3 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "length(L, 3)" pl-ip-env-l3)
(pl-mk-trail))
(pl-ip-test!
"length(L, 3): L is a list of length 3"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "length(L, 3), is_list(L)" pl-ip-env-l3)
(pl-mk-trail))
true)
;; ── last/2 ──
(define pl-ip-env-la1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "last([1,2,3], X)" pl-ip-env-la1)
(pl-mk-trail))
(pl-ip-test!
"last([1,2,3], X) → X=3"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-la1 "X")))
3)
(define pl-ip-env-la2 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "last([a], X)" pl-ip-env-la2)
(pl-mk-trail))
(pl-ip-test!
"last([a], X) → X=a"
(pl-atom-name (pl-walk-deep (dict-get pl-ip-env-la2 "X")))
"a")
(pl-ip-test!
"last([], X) fails"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "last([], X)" {})
(pl-mk-trail))
false)
;; ── nth0/3 ──
(define pl-ip-env-n0 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "nth0(0, [a,b,c], X)" pl-ip-env-n0)
(pl-mk-trail))
(pl-ip-test!
"nth0(0, [a,b,c], X) → X=a"
(pl-atom-name (pl-walk-deep (dict-get pl-ip-env-n0 "X")))
"a")
(define pl-ip-env-n1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "nth0(2, [a,b,c], X)" pl-ip-env-n1)
(pl-mk-trail))
(pl-ip-test!
"nth0(2, [a,b,c], X) → X=c"
(pl-atom-name (pl-walk-deep (dict-get pl-ip-env-n1 "X")))
"c")
(pl-ip-test!
"nth0(5, [a,b,c], X) fails"
(pl-solve-once!
pl-ip-db
(pl-ip-goal "nth0(5, [a,b,c], X)" {})
(pl-mk-trail))
false)
;; ── nth1/3 ──
(define pl-ip-env-n1a {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "nth1(1, [a,b,c], X)" pl-ip-env-n1a)
(pl-mk-trail))
(pl-ip-test!
"nth1(1, [a,b,c], X) → X=a"
(pl-atom-name (pl-walk-deep (dict-get pl-ip-env-n1a "X")))
"a")
(define pl-ip-env-n1b {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "nth1(3, [a,b,c], X)" pl-ip-env-n1b)
(pl-mk-trail))
(pl-ip-test!
"nth1(3, [a,b,c], X) → X=c"
(pl-atom-name (pl-walk-deep (dict-get pl-ip-env-n1b "X")))
"c")
;; ── max/min in arithmetic ──
(define pl-ip-env-m1 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "X is max(3, 5)" pl-ip-env-m1)
(pl-mk-trail))
(pl-ip-test!
"X is max(3, 5) → X=5"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-m1 "X")))
5)
(define pl-ip-env-m2 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "X is min(3, 5)" pl-ip-env-m2)
(pl-mk-trail))
(pl-ip-test!
"X is min(3, 5) → X=3"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-m2 "X")))
3)
(define pl-ip-env-m3 {})
(pl-solve-once!
pl-ip-db
(pl-ip-goal "X is max(7, 2) + min(1, 4)" pl-ip-env-m3)
(pl-mk-trail))
(pl-ip-test!
"X is max(7,2) + min(1,4) → X=8"
(pl-num-val (pl-walk-deep (dict-get pl-ip-env-m3 "X")))
8)
(define pl-iso-predicates-tests-run! (fn () {:failed pl-ip-test-fail :passed pl-ip-test-pass :total pl-ip-test-count :failures pl-ip-test-failures}))

335
lib/prolog/tests/list_predicates.sx
View File

@@ -1,335 +0,0 @@
;; lib/prolog/tests/list_predicates.sx — ==/2, \==/2, flatten/2, numlist/3,
;; atomic_list_concat/2,3, sum_list/2, max_list/2, min_list/2, delete/3
(define pl-lp-test-count 0)
(define pl-lp-test-pass 0)
(define pl-lp-test-fail 0)
(define pl-lp-test-failures (list))
(define
pl-lp-test!
(fn
(name got expected)
(begin
(set! pl-lp-test-count (+ pl-lp-test-count 1))
(if
(= got expected)
(set! pl-lp-test-pass (+ pl-lp-test-pass 1))
(begin
(set! pl-lp-test-fail (+ pl-lp-test-fail 1))
(append!
pl-lp-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-lp-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-lp-db (pl-mk-db))
;; ── ==/2 ───────────────────────────────────────────────────────────
(pl-lp-test!
"==(a, a) succeeds"
(pl-solve-once! pl-lp-db (pl-lp-goal "==(a, a)" {}) (pl-mk-trail))
true)
(pl-lp-test!
"==(a, b) fails"
(pl-solve-once! pl-lp-db (pl-lp-goal "==(a, b)" {}) (pl-mk-trail))
false)
(pl-lp-test!
"==(1, 1) succeeds"
(pl-solve-once! pl-lp-db (pl-lp-goal "==(1, 1)" {}) (pl-mk-trail))
true)
(pl-lp-test!
"==(1, 2) fails"
(pl-solve-once! pl-lp-db (pl-lp-goal "==(1, 2)" {}) (pl-mk-trail))
false)
(pl-lp-test!
"==(f(a,b), f(a,b)) succeeds"
(pl-solve-once!
pl-lp-db
(pl-lp-goal "==(f(a,b), f(a,b))" {})
(pl-mk-trail))
true)
(pl-lp-test!
"==(f(a,b), f(a,c)) fails"
(pl-solve-once!
pl-lp-db
(pl-lp-goal "==(f(a,b), f(a,c))" {})
(pl-mk-trail))
false)
;; unbound var vs atom: fails (different tags)
(pl-lp-test!
"==(X, a) fails (unbound var vs atom)"
(pl-solve-once! pl-lp-db (pl-lp-goal "==(X, a)" {}) (pl-mk-trail))
false)
;; two unbound vars with SAME name in same env share the same runtime var
(define pl-lp-env-same-var {})
(pl-lp-goal "==(X, X)" pl-lp-env-same-var)
(pl-lp-test!
"==(X, X) succeeds (same runtime var)"
(pl-solve-once!
pl-lp-db
(pl-instantiate
(nth (first (pl-parse "g :- ==(X, X).")) 2)
pl-lp-env-same-var)
(pl-mk-trail))
true)
;; ── \==/2 ──────────────────────────────────────────────────────────
(pl-lp-test!
"\\==(a, b) succeeds"
(pl-solve-once! pl-lp-db (pl-lp-goal "\\==(a, b)" {}) (pl-mk-trail))
true)
(pl-lp-test!
"\\==(a, a) fails"
(pl-solve-once! pl-lp-db (pl-lp-goal "\\==(a, a)" {}) (pl-mk-trail))
false)
(pl-lp-test!
"\\==(X, a) succeeds (unbound var differs from atom)"
(pl-solve-once! pl-lp-db (pl-lp-goal "\\==(X, a)" {}) (pl-mk-trail))
true)
(pl-lp-test!
"\\==(1, 2) succeeds"
(pl-solve-once! pl-lp-db (pl-lp-goal "\\==(1, 2)" {}) (pl-mk-trail))
true)
;; ── flatten/2 ──────────────────────────────────────────────────────
(define pl-lp-env-fl1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "flatten([], F)" pl-lp-env-fl1)
(pl-mk-trail))
(pl-lp-test!
"flatten([], []) -> empty"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-fl1 "F")))
"[]")
(define pl-lp-env-fl2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "flatten([1,2,3], F)" pl-lp-env-fl2)
(pl-mk-trail))
(pl-lp-test!
"flatten([1,2,3], F) -> [1,2,3]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-fl2 "F")))
".(1, .(2, .(3, [])))")
(define pl-lp-env-fl3 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "flatten([1,[2,[3]],4], F)" pl-lp-env-fl3)
(pl-mk-trail))
(pl-lp-test!
"flatten([1,[2,[3]],4], F) -> [1,2,3,4]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-fl3 "F")))
".(1, .(2, .(3, .(4, []))))")
(define pl-lp-env-fl4 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "flatten([[a,b],[c]], F)" pl-lp-env-fl4)
(pl-mk-trail))
(pl-lp-test!
"flatten([[a,b],[c]], F) -> [a,b,c]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-fl4 "F")))
".(a, .(b, .(c, [])))")
;; ── numlist/3 ──────────────────────────────────────────────────────
(define pl-lp-env-nl1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "numlist(1, 5, L)" pl-lp-env-nl1)
(pl-mk-trail))
(pl-lp-test!
"numlist(1,5,L) -> [1,2,3,4,5]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-nl1 "L")))
".(1, .(2, .(3, .(4, .(5, [])))))")
(define pl-lp-env-nl2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "numlist(3, 3, L)" pl-lp-env-nl2)
(pl-mk-trail))
(pl-lp-test!
"numlist(3,3,L) -> [3]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-nl2 "L")))
".(3, [])")
(pl-lp-test!
"numlist(5, 3, L) fails (Low > High)"
(pl-solve-once!
pl-lp-db
(pl-lp-goal "numlist(5, 3, L)" {})
(pl-mk-trail))
false)
;; ── atomic_list_concat/2 ───────────────────────────────────────────
(define pl-lp-env-alc1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "atomic_list_concat([a, b, c], R)" pl-lp-env-alc1)
(pl-mk-trail))
(pl-lp-test!
"atomic_list_concat([a,b,c], R) -> abc"
(pl-atom-name (pl-walk-deep (dict-get pl-lp-env-alc1 "R")))
"abc")
(define pl-lp-env-alc2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "atomic_list_concat([hello, world], R)" pl-lp-env-alc2)
(pl-mk-trail))
(pl-lp-test!
"atomic_list_concat([hello,world], R) -> helloworld"
(pl-atom-name (pl-walk-deep (dict-get pl-lp-env-alc2 "R")))
"helloworld")
;; ── atomic_list_concat/3 ───────────────────────────────────────────
(define pl-lp-env-alcs1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "atomic_list_concat([a, b, c], '-', R)" pl-lp-env-alcs1)
(pl-mk-trail))
(pl-lp-test!
"atomic_list_concat([a,b,c], '-', R) -> a-b-c"
(pl-atom-name (pl-walk-deep (dict-get pl-lp-env-alcs1 "R")))
"a-b-c")
(define pl-lp-env-alcs2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "atomic_list_concat([x], '-', R)" pl-lp-env-alcs2)
(pl-mk-trail))
(pl-lp-test!
"atomic_list_concat([x], '-', R) -> x (single element, no sep)"
(pl-atom-name (pl-walk-deep (dict-get pl-lp-env-alcs2 "R")))
"x")
;; ── sum_list/2 ─────────────────────────────────────────────────────
(define pl-lp-env-sl1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "sum_list([1,2,3], S)" pl-lp-env-sl1)
(pl-mk-trail))
(pl-lp-test!
"sum_list([1,2,3], S) -> 6"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-sl1 "S")))
6)
(define pl-lp-env-sl2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "sum_list([10], S)" pl-lp-env-sl2)
(pl-mk-trail))
(pl-lp-test!
"sum_list([10], S) -> 10"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-sl2 "S")))
10)
(define pl-lp-env-sl3 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "sum_list([], S)" pl-lp-env-sl3)
(pl-mk-trail))
(pl-lp-test!
"sum_list([], S) -> 0"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-sl3 "S")))
0)
;; ── max_list/2 ─────────────────────────────────────────────────────
(define pl-lp-env-mx1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "max_list([3,1,4,1,5,9,2,6], M)" pl-lp-env-mx1)
(pl-mk-trail))
(pl-lp-test!
"max_list([3,1,4,1,5,9,2,6], M) -> 9"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-mx1 "M")))
9)
(define pl-lp-env-mx2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "max_list([7], M)" pl-lp-env-mx2)
(pl-mk-trail))
(pl-lp-test!
"max_list([7], M) -> 7"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-mx2 "M")))
7)
;; ── min_list/2 ─────────────────────────────────────────────────────
(define pl-lp-env-mn1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "min_list([3,1,4,1,5,9,2,6], M)" pl-lp-env-mn1)
(pl-mk-trail))
(pl-lp-test!
"min_list([3,1,4,1,5,9,2,6], M) -> 1"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-mn1 "M")))
1)
(define pl-lp-env-mn2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "min_list([5,2,8], M)" pl-lp-env-mn2)
(pl-mk-trail))
(pl-lp-test!
"min_list([5,2,8], M) -> 2"
(pl-num-val (pl-walk-deep (dict-get pl-lp-env-mn2 "M")))
2)
;; ── delete/3 ───────────────────────────────────────────────────────
(define pl-lp-env-del1 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "delete([1,2,3,2,1], 2, R)" pl-lp-env-del1)
(pl-mk-trail))
(pl-lp-test!
"delete([1,2,3,2,1], 2, R) -> [1,3,1]"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-del1 "R")))
".(1, .(3, .(1, [])))")
(define pl-lp-env-del2 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "delete([a,b,c], d, R)" pl-lp-env-del2)
(pl-mk-trail))
(pl-lp-test!
"delete([a,b,c], d, R) -> [a,b,c] (nothing deleted)"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-del2 "R")))
".(a, .(b, .(c, [])))")
(define pl-lp-env-del3 {})
(pl-solve-once!
pl-lp-db
(pl-lp-goal "delete([], x, R)" pl-lp-env-del3)
(pl-mk-trail))
(pl-lp-test!
"delete([], x, R) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-lp-env-del3 "R")))
"[]")
(define pl-list-predicates-tests-run! (fn () {:failed pl-lp-test-fail :passed pl-lp-test-pass :total pl-lp-test-count :failures pl-lp-test-failures}))

197
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@@ -1,197 +0,0 @@
;; lib/prolog/tests/meta_call.sx — forall/2, maplist/2, maplist/3, include/3, exclude/3
(define pl-mc-test-count 0)
(define pl-mc-test-pass 0)
(define pl-mc-test-fail 0)
(define pl-mc-test-failures (list))
(define
pl-mc-test!
(fn
(name got expected)
(begin
(set! pl-mc-test-count (+ pl-mc-test-count 1))
(if
(= got expected)
(set! pl-mc-test-pass (+ pl-mc-test-pass 1))
(begin
(set! pl-mc-test-fail (+ pl-mc-test-fail 1))
(append!
pl-mc-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-mc-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define
pl-mc-term-to-sx
(fn
(t)
(cond
((pl-num? t) (pl-num-val t))
((pl-atom? t) (pl-atom-name t))
(else t))))
(define
pl-mc-list-sx
(fn
(t)
(let
((w (pl-walk-deep t)))
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) "."))
(cons
(pl-mc-term-to-sx (first (pl-args w)))
(pl-mc-list-sx (nth (pl-args w) 1))))
(else (list :not-list))))))
(define pl-mc-db (pl-mk-db))
(pl-db-load!
pl-mc-db
(pl-parse "member(X, [X|_]). member(X, [_|T]) :- member(X, T)."))
(pl-db-load! pl-mc-db (pl-parse "double(X, Y) :- Y is X * 2."))
(pl-db-load! pl-mc-db (pl-parse "even(X) :- 0 is X mod 2."))
;; -- forall/2 --
(pl-mc-test!
"forall(member(X,[2,4,6]), 0 is X mod 2) — all even"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "forall(member(X,[2,4,6]), 0 is X mod 2)" {})
(pl-mk-trail))
true)
(pl-mc-test!
"forall(member(X,[2,3,6]), 0 is X mod 2) — 3 is odd, fails"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "forall(member(X,[2,3,6]), 0 is X mod 2)" {})
(pl-mk-trail))
false)
(pl-mc-test!
"forall(member(_,[]), true) — vacuously true"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "forall(member(_,[]), true)" {})
(pl-mk-trail))
true)
;; -- maplist/2 --
(pl-mc-test!
"maplist(atom, [a,b,c]) — all atoms"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(atom, [a,b,c])" {})
(pl-mk-trail))
true)
(pl-mc-test!
"maplist(atom, [a,1,c]) — 1 is not atom, fails"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(atom, [a,1,c])" {})
(pl-mk-trail))
false)
(pl-mc-test!
"maplist(atom, []) — vacuously true"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(atom, [])" {})
(pl-mk-trail))
true)
;; -- maplist/3 --
(pl-mc-test!
"maplist(double, [1,2,3], [2,4,6]) — deterministic check"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(double, [1,2,3], [2,4,6])" {})
(pl-mk-trail))
true)
(pl-mc-test!
"maplist(double, [1,2,3], [2,4,7]) — wrong result fails"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(double, [1,2,3], [2,4,7])" {})
(pl-mk-trail))
false)
(define pl-mc-env-ml3 {:L (pl-mk-rt-var "L")})
(pl-solve-once!
pl-mc-db
(pl-mc-goal "maplist(double, [1,2,3], L)" pl-mc-env-ml3)
(pl-mk-trail))
(pl-mc-test!
"maplist(double, [1,2,3], L) — L bound to [2,4,6]"
(pl-mc-list-sx (dict-get pl-mc-env-ml3 "L"))
(list 2 4 6))
;; -- include/3 --
(pl-mc-test!
"include(even, [1,2,3,4,5,6], [2,4,6])"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "include(even, [1,2,3,4,5,6], [2,4,6])" {})
(pl-mk-trail))
true)
(pl-mc-test!
"include(even, [], [])"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "include(even, [], [])" {})
(pl-mk-trail))
true)
(define pl-mc-env-inc {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-mc-db
(pl-mc-goal "include(even, [1,2,3,4,5,6], R)" pl-mc-env-inc)
(pl-mk-trail))
(pl-mc-test!
"include(even, [1,2,3,4,5,6], R) — R bound to [2,4,6]"
(pl-mc-list-sx (dict-get pl-mc-env-inc "R"))
(list 2 4 6))
;; -- exclude/3 --
(pl-mc-test!
"exclude(even, [1,2,3,4,5,6], [1,3,5])"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "exclude(even, [1,2,3,4,5,6], [1,3,5])" {})
(pl-mk-trail))
true)
(pl-mc-test!
"exclude(even, [], [])"
(pl-solve-once!
pl-mc-db
(pl-mc-goal "exclude(even, [], [])" {})
(pl-mk-trail))
true)
(define pl-mc-env-exc {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-mc-db
(pl-mc-goal "exclude(even, [1,2,3,4,5,6], R)" pl-mc-env-exc)
(pl-mk-trail))
(pl-mc-test!
"exclude(even, [1,2,3,4,5,6], R) — R bound to [1,3,5]"
(pl-mc-list-sx (dict-get pl-mc-env-exc "R"))
(list 1 3 5))
(define pl-meta-call-tests-run! (fn () {:failed pl-mc-test-fail :passed pl-mc-test-pass :total pl-mc-test-count :failures pl-mc-test-failures}))

252
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@@ -1,252 +0,0 @@
;; lib/prolog/tests/meta_predicates.sx — \+/1, not/1, once/1, ignore/1, ground/1, sort/2, msort/2, atom_number/2, number_string/2
(define pl-mp-test-count 0)
(define pl-mp-test-pass 0)
(define pl-mp-test-fail 0)
(define pl-mp-test-failures (list))
(define
pl-mp-test!
(fn
(name got expected)
(begin
(set! pl-mp-test-count (+ pl-mp-test-count 1))
(if
(= got expected)
(set! pl-mp-test-pass (+ pl-mp-test-pass 1))
(begin
(set! pl-mp-test-fail (+ pl-mp-test-fail 1))
(append!
pl-mp-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-mp-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-mp-db (pl-mk-db))
(pl-db-load!
pl-mp-db
(pl-parse "member(X, [X|_]). member(X, [_|T]) :- member(X, T)."))
;; -- \+/1 --
(pl-mp-test!
"\\+(fail) succeeds"
(pl-solve-once! pl-mp-db (pl-mp-goal "\\+(fail)" {}) (pl-mk-trail))
true)
(pl-mp-test!
"\\+(true) fails"
(pl-solve-once! pl-mp-db (pl-mp-goal "\\+(true)" {}) (pl-mk-trail))
false)
(pl-mp-test!
"\\+(member(d, [a,b,c])) succeeds"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "\\+(member(d, [a,b,c]))" {})
(pl-mk-trail))
true)
(pl-mp-test!
"\\+(member(a, [a,b,c])) fails"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "\\+(member(a, [a,b,c]))" {})
(pl-mk-trail))
false)
(define pl-mp-env-neg {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "\\+(X = 5)" pl-mp-env-neg)
(pl-mk-trail))
(pl-mp-test!
"\\+(X=5) fails, X stays unbound (bindings undone)"
(nil? (pl-var-binding (dict-get pl-mp-env-neg "X")))
true)
;; -- not/1 --
(pl-mp-test!
"not(fail) succeeds"
(pl-solve-once! pl-mp-db (pl-mp-goal "not(fail)" {}) (pl-mk-trail))
true)
(pl-mp-test!
"not(true) fails"
(pl-solve-once! pl-mp-db (pl-mp-goal "not(true)" {}) (pl-mk-trail))
false)
;; -- once/1 --
(pl-mp-test!
"once(member(X,[1,2,3])) succeeds once"
(pl-solve-count!
pl-mp-db
(pl-mp-goal "once(member(X,[1,2,3]))" {})
(pl-mk-trail))
1)
(define pl-mp-env-once {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "once(member(X,[1,2,3]))" pl-mp-env-once)
(pl-mk-trail))
(pl-mp-test!
"once(member(X,[1,2,3])): X=1 (first solution)"
(pl-num-val (pl-walk-deep (dict-get pl-mp-env-once "X")))
1)
(pl-mp-test!
"once(fail) fails"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "once(fail)" {})
(pl-mk-trail))
false)
;; -- ignore/1 --
(pl-mp-test!
"ignore(true) succeeds"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "ignore(true)" {})
(pl-mk-trail))
true)
(pl-mp-test!
"ignore(fail) still succeeds"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "ignore(fail)" {})
(pl-mk-trail))
true)
;; -- ground/1 --
(pl-mp-test!
"ground(foo(1, a)) succeeds"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "ground(foo(1, a))" {})
(pl-mk-trail))
true)
(pl-mp-test!
"ground(foo(X, a)) fails (X unbound)"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "ground(foo(X, a))" {})
(pl-mk-trail))
false)
(pl-mp-test!
"ground(42) succeeds"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "ground(42)" {})
(pl-mk-trail))
true)
;; -- sort/2 --
(pl-mp-test!
"sort([b,a,c], [a,b,c])"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "sort([b,a,c], [a,b,c])" {})
(pl-mk-trail))
true)
(pl-mp-test!
"sort([b,a,a,c], [a,b,c]) (removes duplicates)"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "sort([b,a,a,c], [a,b,c])" {})
(pl-mk-trail))
true)
(pl-mp-test!
"sort([], [])"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "sort([], [])" {})
(pl-mk-trail))
true)
;; -- msort/2 --
(pl-mp-test!
"msort([b,a,a,c], [a,a,b,c]) (keeps duplicates)"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "msort([b,a,a,c], [a,a,b,c])" {})
(pl-mk-trail))
true)
(pl-mp-test!
"msort([3,1,2,1], [1,1,2,3])"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "msort([3,1,2,1], [1,1,2,3])" {})
(pl-mk-trail))
true)
;; -- atom_number/2 --
(define pl-mp-env-an1 {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "atom_number('42', N)" pl-mp-env-an1)
(pl-mk-trail))
(pl-mp-test!
"atom_number('42', N) -> N=42"
(pl-num-val (pl-walk-deep (dict-get pl-mp-env-an1 "N")))
42)
(define pl-mp-env-an2 {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "atom_number(A, 7)" pl-mp-env-an2)
(pl-mk-trail))
(pl-mp-test!
"atom_number(A, 7) -> A='7'"
(pl-atom-name (pl-walk-deep (dict-get pl-mp-env-an2 "A")))
"7")
(pl-mp-test!
"atom_number(foo, N) fails (not a number)"
(pl-solve-once!
pl-mp-db
(pl-mp-goal "atom_number(foo, N)" {})
(pl-mk-trail))
false)
;; -- number_string/2 --
(define pl-mp-env-ns1 {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "number_string(42, S)" pl-mp-env-ns1)
(pl-mk-trail))
(pl-mp-test!
"number_string(42, S) -> S='42'"
(pl-atom-name (pl-walk-deep (dict-get pl-mp-env-ns1 "S")))
"42")
(define pl-mp-env-ns2 {})
(pl-solve-once!
pl-mp-db
(pl-mp-goal "number_string(N, '3.14')" pl-mp-env-ns2)
(pl-mk-trail))
(pl-mp-test!
"number_string(N, '3.14') -> N=3.14"
(pl-num-val (pl-walk-deep (dict-get pl-mp-env-ns2 "N")))
3.14)
(define pl-meta-predicates-tests-run! (fn () {:failed pl-mp-test-fail :passed pl-mp-test-pass :total pl-mp-test-count :failures pl-mp-test-failures}))

193
lib/prolog/tests/operators.sx
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@@ -1,193 +0,0 @@
;; lib/prolog/tests/operators.sx — operator-table parsing + comparison built-ins.
(define pl-op-test-count 0)
(define pl-op-test-pass 0)
(define pl-op-test-fail 0)
(define pl-op-test-failures (list))
(define
pl-op-test!
(fn
(name got expected)
(begin
(set! pl-op-test-count (+ pl-op-test-count 1))
(if
(= got expected)
(set! pl-op-test-pass (+ pl-op-test-pass 1))
(begin
(set! pl-op-test-fail (+ pl-op-test-fail 1))
(append!
pl-op-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define pl-op-empty-db (pl-mk-db))
(define
pl-op-body
(fn (src) (nth (first (pl-parse (str "g :- " src "."))) 2)))
(define pl-op-goal (fn (src env) (pl-instantiate (pl-op-body src) env)))
;; ── parsing tests ──
(pl-op-test!
"infix +"
(pl-op-body "a + b")
(list "compound" "+" (list (list "atom" "a") (list "atom" "b"))))
(pl-op-test!
"infix * tighter than +"
(pl-op-body "a + b * c")
(list
"compound"
"+"
(list
(list "atom" "a")
(list "compound" "*" (list (list "atom" "b") (list "atom" "c"))))))
(pl-op-test!
"parens override precedence"
(pl-op-body "(a + b) * c")
(list
"compound"
"*"
(list
(list "compound" "+" (list (list "atom" "a") (list "atom" "b")))
(list "atom" "c"))))
(pl-op-test!
"+ is yfx (left-assoc)"
(pl-op-body "a + b + c")
(list
"compound"
"+"
(list
(list "compound" "+" (list (list "atom" "a") (list "atom" "b")))
(list "atom" "c"))))
(pl-op-test!
"; is xfy (right-assoc)"
(pl-op-body "a ; b ; c")
(list
"compound"
";"
(list
(list "atom" "a")
(list "compound" ";" (list (list "atom" "b") (list "atom" "c"))))))
(pl-op-test!
"= folds at 700"
(pl-op-body "X = 5")
(list "compound" "=" (list (list "var" "X") (list "num" 5))))
(pl-op-test!
"is + nests via 700>500>400"
(pl-op-body "X is 2 + 3 * 4")
(list
"compound"
"is"
(list
(list "var" "X")
(list
"compound"
"+"
(list
(list "num" 2)
(list "compound" "*" (list (list "num" 3) (list "num" 4))))))))
(pl-op-test!
"< parses at 700"
(pl-op-body "2 < 3")
(list "compound" "<" (list (list "num" 2) (list "num" 3))))
(pl-op-test!
"mod parses as yfx 400"
(pl-op-body "10 mod 3")
(list "compound" "mod" (list (list "num" 10) (list "num" 3))))
(pl-op-test!
"comma in body folds right-assoc"
(pl-op-body "a, b, c")
(list
"compound"
","
(list
(list "atom" "a")
(list "compound" "," (list (list "atom" "b") (list "atom" "c"))))))
;; ── solver tests via infix ──
(pl-op-test!
"X is 2 + 3 binds X = 5"
(let
((env {}) (trail (pl-mk-trail)))
(begin
(pl-solve-once! pl-op-empty-db (pl-op-goal "X is 2 + 3" env) trail)
(pl-num-val (pl-walk-deep (dict-get env "X")))))
5)
(pl-op-test!
"infix conjunction parses + solves"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "X = 5, X = 5" {})
(pl-mk-trail))
true)
(pl-op-test!
"infix mismatch fails"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "X = 5, X = 6" {})
(pl-mk-trail))
false)
(pl-op-test!
"infix disjunction picks left"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "true ; fail" {})
(pl-mk-trail))
true)
(pl-op-test!
"2 < 5 succeeds"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "2 < 5" {})
(pl-mk-trail))
true)
(pl-op-test!
"5 < 2 fails"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "5 < 2" {})
(pl-mk-trail))
false)
(pl-op-test!
"5 >= 5 succeeds"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "5 >= 5" {})
(pl-mk-trail))
true)
(pl-op-test!
"3 =< 5 succeeds"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "3 =< 5" {})
(pl-mk-trail))
true)
(pl-op-test!
"infix < with arithmetic both sides"
(pl-solve-once!
pl-op-empty-db
(pl-op-goal "1 + 2 < 2 * 3" {})
(pl-mk-trail))
true)
(define pl-operators-tests-run! (fn () {:failed pl-op-test-fail :passed pl-op-test-pass :total pl-op-test-count :failures pl-op-test-failures}))

5
lib/prolog/tests/programs/append.pl
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@@ -1,5 +0,0 @@
%% append/3 list concatenation, classic Prolog
%% Two clauses: empty-prefix base case + recursive cons-prefix.
%% Bidirectional works in all modes: build, check, split.
append([], L, L).
append([H|T], L, [H|R]) :- append(T, L, R).

114
lib/prolog/tests/programs/append.sx
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@@ -1,114 +0,0 @@
;; lib/prolog/tests/programs/append.sx — append/3 test runner
;;
;; Mirrors the Prolog source in append.pl (embedded as a string here because
;; the SX runtime has no file-read primitive yet).
(define pl-ap-test-count 0)
(define pl-ap-test-pass 0)
(define pl-ap-test-fail 0)
(define pl-ap-test-failures (list))
(define
pl-ap-test!
(fn
(name got expected)
(begin
(set! pl-ap-test-count (+ pl-ap-test-count 1))
(if
(= got expected)
(set! pl-ap-test-pass (+ pl-ap-test-pass 1))
(begin
(set! pl-ap-test-fail (+ pl-ap-test-fail 1))
(append!
pl-ap-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-ap-term-to-sx
(fn
(t)
(cond
((pl-num? t) (pl-num-val t))
((pl-atom? t) (pl-atom-name t))
(true (list :complex)))))
(define
pl-ap-list-walked
(fn
(w)
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) ".") (= (len (pl-args w)) 2))
(cons
(pl-ap-term-to-sx (first (pl-args w)))
(pl-ap-list-walked (nth (pl-args w) 1))))
(true (list :not-list)))))
(define pl-ap-list-to-sx (fn (t) (pl-ap-list-walked (pl-walk-deep t))))
(define
pl-ap-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define
pl-ap-prog-src
"append([], L, L). append([H|T], L, [H|R]) :- append(T, L, R).")
(define pl-ap-db (pl-mk-db))
(pl-db-load! pl-ap-db (pl-parse pl-ap-prog-src))
(define pl-ap-env-1 {})
(define pl-ap-goal-1 (pl-ap-goal "append([], [a, b], X)" pl-ap-env-1))
(pl-solve-once! pl-ap-db pl-ap-goal-1 (pl-mk-trail))
(pl-ap-test!
"append([], [a, b], X) → X = [a, b]"
(pl-ap-list-to-sx (dict-get pl-ap-env-1 "X"))
(list "a" "b"))
(define pl-ap-env-2 {})
(define pl-ap-goal-2 (pl-ap-goal "append([1, 2], [3, 4], X)" pl-ap-env-2))
(pl-solve-once! pl-ap-db pl-ap-goal-2 (pl-mk-trail))
(pl-ap-test!
"append([1, 2], [3, 4], X) → X = [1, 2, 3, 4]"
(pl-ap-list-to-sx (dict-get pl-ap-env-2 "X"))
(list 1 2 3 4))
(pl-ap-test!
"append([1], [2, 3], [1, 2, 3]) succeeds"
(pl-solve-once!
pl-ap-db
(pl-ap-goal "append([1], [2, 3], [1, 2, 3])" {})
(pl-mk-trail))
true)
(pl-ap-test!
"append([1, 2], [3], [1, 2, 4]) fails"
(pl-solve-once!
pl-ap-db
(pl-ap-goal "append([1, 2], [3], [1, 2, 4])" {})
(pl-mk-trail))
false)
(pl-ap-test!
"append(X, Y, [1, 2, 3]) backtracks 4 times"
(pl-solve-count!
pl-ap-db
(pl-ap-goal "append(X, Y, [1, 2, 3])" {})
(pl-mk-trail))
4)
(define pl-ap-env-6 {})
(define pl-ap-goal-6 (pl-ap-goal "append(X, [3], [1, 2, 3])" pl-ap-env-6))
(pl-solve-once! pl-ap-db pl-ap-goal-6 (pl-mk-trail))
(pl-ap-test!
"append(X, [3], [1, 2, 3]) deduces X = [1, 2]"
(pl-ap-list-to-sx (dict-get pl-ap-env-6 "X"))
(list 1 2))
(define pl-append-tests-run! (fn () {:failed pl-ap-test-fail :passed pl-ap-test-pass :total pl-ap-test-count :failures pl-ap-test-failures}))

24
lib/prolog/tests/programs/family.pl
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@@ -1,24 +0,0 @@
%% family facts + transitive ancestor + derived relations.
%% Five-generation tree: tom -> bob -> {ann, pat} -> jim, plus tom's
%% other child liz.
parent(tom, bob).
parent(tom, liz).
parent(bob, ann).
parent(bob, pat).
parent(pat, jim).
male(tom).
male(bob).
male(jim).
male(pat).
female(liz).
female(ann).
father(F, C) :- parent(F, C), male(F).
mother(M, C) :- parent(M, C), female(M).
ancestor(X, Y) :- parent(X, Y).
ancestor(X, Y) :- parent(X, Z), ancestor(Z, Y).
sibling(X, Y) :- parent(P, X), parent(P, Y), \=(X, Y).

116
lib/prolog/tests/programs/family.sx
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@@ -1,116 +0,0 @@
;; lib/prolog/tests/programs/family.sx — facts + ancestor + sibling relations.
(define pl-fa-test-count 0)
(define pl-fa-test-pass 0)
(define pl-fa-test-fail 0)
(define pl-fa-test-failures (list))
(define
pl-fa-test!
(fn
(name got expected)
(begin
(set! pl-fa-test-count (+ pl-fa-test-count 1))
(if
(= got expected)
(set! pl-fa-test-pass (+ pl-fa-test-pass 1))
(begin
(set! pl-fa-test-fail (+ pl-fa-test-fail 1))
(append!
pl-fa-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-fa-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define
pl-fa-prog-src
"parent(tom, bob). parent(tom, liz). parent(bob, ann). parent(bob, pat). parent(pat, jim). male(tom). male(bob). male(jim). male(pat). female(liz). female(ann). father(F, C) :- parent(F, C), male(F). mother(M, C) :- parent(M, C), female(M). ancestor(X, Y) :- parent(X, Y). ancestor(X, Y) :- parent(X, Z), ancestor(Z, Y). sibling(X, Y) :- parent(P, X), parent(P, Y), \\=(X, Y).")
(define pl-fa-db (pl-mk-db))
(pl-db-load! pl-fa-db (pl-parse pl-fa-prog-src))
(pl-fa-test!
"parent(tom, bob) is a fact"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "parent(tom, bob)" {})
(pl-mk-trail))
true)
(pl-fa-test!
"parent(tom, ann) — not a direct parent"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "parent(tom, ann)" {})
(pl-mk-trail))
false)
(pl-fa-test!
"5 parent/2 facts in total"
(pl-solve-count!
pl-fa-db
(pl-fa-goal "parent(X, Y)" {})
(pl-mk-trail))
5)
(pl-fa-test!
"ancestor(tom, jim) — three-step transitive"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "ancestor(tom, jim)" {})
(pl-mk-trail))
true)
(pl-fa-test!
"tom has 5 ancestors-of: bob, liz, ann, pat, jim"
(pl-solve-count!
pl-fa-db
(pl-fa-goal "ancestor(tom, X)" {})
(pl-mk-trail))
5)
(pl-fa-test!
"father(bob, ann) succeeds"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "father(bob, ann)" {})
(pl-mk-trail))
true)
(pl-fa-test!
"father(liz, ann) fails (liz is female)"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "father(liz, ann)" {})
(pl-mk-trail))
false)
(pl-fa-test!
"mother(liz, X) fails (liz has no children)"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "mother(liz, X)" {})
(pl-mk-trail))
false)
(pl-fa-test!
"sibling(ann, pat) succeeds"
(pl-solve-once!
pl-fa-db
(pl-fa-goal "sibling(ann, pat)" {})
(pl-mk-trail))
true)
(pl-fa-test!
"sibling(ann, ann) fails by \\="
(pl-solve-once!
pl-fa-db
(pl-fa-goal "sibling(ann, ann)" {})
(pl-mk-trail))
false)
(define pl-family-tests-run! (fn () {:failed pl-fa-test-fail :passed pl-fa-test-pass :total pl-fa-test-count :failures pl-fa-test-failures}))

4
lib/prolog/tests/programs/member.pl
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@@ -1,4 +0,0 @@
%% member/2 list membership.
%% Generates all solutions on backtracking when the element is unbound.
member(X, [X|_]).
member(X, [_|T]) :- member(X, T).

91
lib/prolog/tests/programs/member.sx
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@@ -1,91 +0,0 @@
;; lib/prolog/tests/programs/member.sx — member/2 generator.
(define pl-mb-test-count 0)
(define pl-mb-test-pass 0)
(define pl-mb-test-fail 0)
(define pl-mb-test-failures (list))
(define
pl-mb-test!
(fn
(name got expected)
(begin
(set! pl-mb-test-count (+ pl-mb-test-count 1))
(if
(= got expected)
(set! pl-mb-test-pass (+ pl-mb-test-pass 1))
(begin
(set! pl-mb-test-fail (+ pl-mb-test-fail 1))
(append!
pl-mb-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-mb-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-mb-prog-src "member(X, [X|_]). member(X, [_|T]) :- member(X, T).")
(define pl-mb-db (pl-mk-db))
(pl-db-load! pl-mb-db (pl-parse pl-mb-prog-src))
(pl-mb-test!
"member(2, [1, 2, 3]) succeeds"
(pl-solve-once!
pl-mb-db
(pl-mb-goal "member(2, [1, 2, 3])" {})
(pl-mk-trail))
true)
(pl-mb-test!
"member(4, [1, 2, 3]) fails"
(pl-solve-once!
pl-mb-db
(pl-mb-goal "member(4, [1, 2, 3])" {})
(pl-mk-trail))
false)
(pl-mb-test!
"member(X, []) fails"
(pl-solve-once!
pl-mb-db
(pl-mb-goal "member(X, [])" {})
(pl-mk-trail))
false)
(pl-mb-test!
"member(X, [a, b, c]) generates 3 solutions"
(pl-solve-count!
pl-mb-db
(pl-mb-goal "member(X, [a, b, c])" {})
(pl-mk-trail))
3)
(define pl-mb-env-1 {})
(define pl-mb-goal-1 (pl-mb-goal "member(X, [11, 22, 33])" pl-mb-env-1))
(pl-solve-once! pl-mb-db pl-mb-goal-1 (pl-mk-trail))
(pl-mb-test!
"member(X, [11, 22, 33]) first solution X = 11"
(pl-num-val (pl-walk-deep (dict-get pl-mb-env-1 "X")))
11)
(pl-mb-test!
"member(2, [1, 2, 3, 2, 1]) matches twice on backtrack"
(pl-solve-count!
pl-mb-db
(pl-mb-goal "member(2, [1, 2, 3, 2, 1])" {})
(pl-mk-trail))
2)
(pl-mb-test!
"member with unbound list cell unifies"
(pl-solve-once!
pl-mb-db
(pl-mb-goal "member(a, [X, b, c])" {})
(pl-mk-trail))
true)
(define pl-member-tests-run! (fn () {:failed pl-mb-test-fail :passed pl-mb-test-pass :total pl-mb-test-count :failures pl-mb-test-failures}))

27
lib/prolog/tests/programs/nqueens.pl
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@@ -1,27 +0,0 @@
%% nqueens permutation-and-test formulation.
%% Caller passes the row list [1..N]; queens/2 finds N column placements
%% s.t. no two queens attack on a diagonal. Same-column attacks are
%% structurally impossible Qs is a permutation, all distinct.
%%
%% No `>/2` `</2` `=</2` built-ins yet, so range/3 is omitted; tests pass
%; the literal range list. Once the operator table lands and arithmetic
%% comparison built-ins are in, range/3 can be added.
queens(L, Qs) :- permute(L, Qs), safe(Qs).
permute([], []).
permute(L, [H|T]) :- select(H, L, R), permute(R, T).
select(X, [X|T], T).
select(X, [H|T], [H|R]) :- select(X, T, R).
safe([]).
safe([Q|Qs]) :- safe(Qs), no_attack(Q, Qs, 1).
no_attack(_, [], _).
no_attack(Q, [Q1|Qs], D) :-
is(D2, +(Q, D)),
\=(D2, Q1),
is(D3, -(Q, D)),
\=(D3, Q1),
is(D1, +(D, 1)),
no_attack(Q, Qs, D1).

108
lib/prolog/tests/programs/nqueens.sx
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@@ -1,108 +0,0 @@
;; lib/prolog/tests/programs/nqueens.sx — N-queens via permute + safe.
(define pl-nq-test-count 0)
(define pl-nq-test-pass 0)
(define pl-nq-test-fail 0)
(define pl-nq-test-failures (list))
(define
pl-nq-test!
(fn
(name got expected)
(begin
(set! pl-nq-test-count (+ pl-nq-test-count 1))
(if
(= got expected)
(set! pl-nq-test-pass (+ pl-nq-test-pass 1))
(begin
(set! pl-nq-test-fail (+ pl-nq-test-fail 1))
(append!
pl-nq-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-nq-term-to-sx
(fn
(t)
(cond
((pl-num? t) (pl-num-val t))
((pl-atom? t) (pl-atom-name t))
(true (list :complex)))))
(define
pl-nq-list-walked
(fn
(w)
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) ".") (= (len (pl-args w)) 2))
(cons
(pl-nq-term-to-sx (first (pl-args w)))
(pl-nq-list-walked (nth (pl-args w) 1))))
(true (list :not-list)))))
(define pl-nq-list-to-sx (fn (t) (pl-nq-list-walked (pl-walk-deep t))))
(define
pl-nq-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define
pl-nq-prog-src
"queens(L, Qs) :- permute(L, Qs), safe(Qs). permute([], []). permute(L, [H|T]) :- select(H, L, R), permute(R, T). select(X, [X|T], T). select(X, [H|T], [H|R]) :- select(X, T, R). safe([]). safe([Q|Qs]) :- safe(Qs), no_attack(Q, Qs, 1). no_attack(_, [], _). no_attack(Q, [Q1|Qs], D) :- is(D2, +(Q, D)), \\=(D2, Q1), is(D3, -(Q, D)), \\=(D3, Q1), is(D1, +(D, 1)), no_attack(Q, Qs, D1).")
(define pl-nq-db (pl-mk-db))
(pl-db-load! pl-nq-db (pl-parse pl-nq-prog-src))
(pl-nq-test!
"queens([1], Qs) → 1 solution"
(pl-solve-count!
pl-nq-db
(pl-nq-goal "queens([1], Qs)" {})
(pl-mk-trail))
1)
(pl-nq-test!
"queens([1, 2], Qs) → 0 solutions"
(pl-solve-count!
pl-nq-db
(pl-nq-goal "queens([1, 2], Qs)" {})
(pl-mk-trail))
0)
(pl-nq-test!
"queens([1, 2, 3], Qs) → 0 solutions"
(pl-solve-count!
pl-nq-db
(pl-nq-goal "queens([1, 2, 3], Qs)" {})
(pl-mk-trail))
0)
(pl-nq-test!
"queens([1, 2, 3, 4], Qs) → 2 solutions"
(pl-solve-count!
pl-nq-db
(pl-nq-goal "queens([1, 2, 3, 4], Qs)" {})
(pl-mk-trail))
2)
(pl-nq-test!
"queens([1, 2, 3, 4, 5], Qs) → 10 solutions"
(pl-solve-count!
pl-nq-db
(pl-nq-goal "queens([1, 2, 3, 4, 5], Qs)" {})
(pl-mk-trail))
10)
(define pl-nq-env-1 {})
(define pl-nq-goal-1 (pl-nq-goal "queens([1, 2, 3, 4], Qs)" pl-nq-env-1))
(pl-solve-once! pl-nq-db pl-nq-goal-1 (pl-mk-trail))
(pl-nq-test!
"queens([1..4], Qs) first solution = [2, 4, 1, 3]"
(pl-nq-list-to-sx (dict-get pl-nq-env-1 "Qs"))
(list 2 4 1 3))
(define pl-nqueens-tests-run! (fn () {:failed pl-nq-test-fail :passed pl-nq-test-pass :total pl-nq-test-count :failures pl-nq-test-failures}))

7
lib/prolog/tests/programs/reverse.pl
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@@ -1,7 +0,0 @@
%% reverse/2 — naive reverse via append/3.
%% Quadratic accumulates the reversed prefix one append per cons.
reverse([], []).
reverse([H|T], R) :- reverse(T, RT), append(RT, [H], R).
append([], L, L).
append([H|T], L, [H|R]) :- append(T, L, R).

113
lib/prolog/tests/programs/reverse.sx
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@@ -1,113 +0,0 @@
;; lib/prolog/tests/programs/reverse.sx — naive reverse/2 via append/3.
;;
;; Mirrors reverse.pl (embedded as a string here).
(define pl-rv-test-count 0)
(define pl-rv-test-pass 0)
(define pl-rv-test-fail 0)
(define pl-rv-test-failures (list))
(define
pl-rv-test!
(fn
(name got expected)
(begin
(set! pl-rv-test-count (+ pl-rv-test-count 1))
(if
(= got expected)
(set! pl-rv-test-pass (+ pl-rv-test-pass 1))
(begin
(set! pl-rv-test-fail (+ pl-rv-test-fail 1))
(append!
pl-rv-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-rv-term-to-sx
(fn
(t)
(cond
((pl-num? t) (pl-num-val t))
((pl-atom? t) (pl-atom-name t))
(true (list :complex)))))
(define
pl-rv-list-walked
(fn
(w)
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) ".") (= (len (pl-args w)) 2))
(cons
(pl-rv-term-to-sx (first (pl-args w)))
(pl-rv-list-walked (nth (pl-args w) 1))))
(true (list :not-list)))))
(define pl-rv-list-to-sx (fn (t) (pl-rv-list-walked (pl-walk-deep t))))
(define
pl-rv-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define
pl-rv-prog-src
"reverse([], []). reverse([H|T], R) :- reverse(T, RT), append(RT, [H], R). append([], L, L). append([H|T], L, [H|R]) :- append(T, L, R).")
(define pl-rv-db (pl-mk-db))
(pl-db-load! pl-rv-db (pl-parse pl-rv-prog-src))
(define pl-rv-env-1 {})
(define pl-rv-goal-1 (pl-rv-goal "reverse([], X)" pl-rv-env-1))
(pl-solve-once! pl-rv-db pl-rv-goal-1 (pl-mk-trail))
(pl-rv-test!
"reverse([], X) → X = []"
(pl-rv-list-to-sx (dict-get pl-rv-env-1 "X"))
(list))
(define pl-rv-env-2 {})
(define pl-rv-goal-2 (pl-rv-goal "reverse([1], X)" pl-rv-env-2))
(pl-solve-once! pl-rv-db pl-rv-goal-2 (pl-mk-trail))
(pl-rv-test!
"reverse([1], X) → X = [1]"
(pl-rv-list-to-sx (dict-get pl-rv-env-2 "X"))
(list 1))
(define pl-rv-env-3 {})
(define pl-rv-goal-3 (pl-rv-goal "reverse([1, 2, 3], X)" pl-rv-env-3))
(pl-solve-once! pl-rv-db pl-rv-goal-3 (pl-mk-trail))
(pl-rv-test!
"reverse([1, 2, 3], X) → X = [3, 2, 1]"
(pl-rv-list-to-sx (dict-get pl-rv-env-3 "X"))
(list 3 2 1))
(define pl-rv-env-4 {})
(define pl-rv-goal-4 (pl-rv-goal "reverse([a, b, c, d], X)" pl-rv-env-4))
(pl-solve-once! pl-rv-db pl-rv-goal-4 (pl-mk-trail))
(pl-rv-test!
"reverse([a, b, c, d], X) → X = [d, c, b, a]"
(pl-rv-list-to-sx (dict-get pl-rv-env-4 "X"))
(list "d" "c" "b" "a"))
(pl-rv-test!
"reverse([1, 2, 3], [3, 2, 1]) succeeds"
(pl-solve-once!
pl-rv-db
(pl-rv-goal "reverse([1, 2, 3], [3, 2, 1])" {})
(pl-mk-trail))
true)
(pl-rv-test!
"reverse([1, 2], [1, 2]) fails"
(pl-solve-once!
pl-rv-db
(pl-rv-goal "reverse([1, 2], [1, 2])" {})
(pl-mk-trail))
false)
(define pl-reverse-tests-run! (fn () {:failed pl-rv-test-fail :passed pl-rv-test-pass :total pl-rv-test-count :failures pl-rv-test-failures}))

127
lib/prolog/tests/query_api.sx
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@@ -1,127 +0,0 @@
;; lib/prolog/tests/query_api.sx — tests for pl-load/pl-query-all/pl-query-one/pl-query
(define pl-qa-test-count 0)
(define pl-qa-test-pass 0)
(define pl-qa-test-fail 0)
(define pl-qa-test-failures (list))
(define
pl-qa-test!
(fn
(name got expected)
(begin
(set! pl-qa-test-count (+ pl-qa-test-count 1))
(if
(= got expected)
(set! pl-qa-test-pass (+ pl-qa-test-pass 1))
(begin
(set! pl-qa-test-fail (+ pl-qa-test-fail 1))
(append!
pl-qa-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-qa-src
"parent(tom, bob). parent(tom, liz). parent(bob, ann). ancestor(X, Y) :- parent(X, Y). ancestor(X, Y) :- parent(X, Z), ancestor(Z, Y).")
(define pl-qa-db (pl-load pl-qa-src))
;; ── pl-load ──
(pl-qa-test!
"pl-load returns a usable DB (pl-query-all non-nil)"
(not (nil? pl-qa-db))
true)
;; ── pl-query-all: basic fact lookup ──
(pl-qa-test!
"query-all parent(tom, X): 2 solutions"
(len (pl-query-all pl-qa-db "parent(tom, X)"))
2)
(pl-qa-test!
"query-all parent(tom, X): first solution X=bob"
(dict-get (first (pl-query-all pl-qa-db "parent(tom, X)")) "X")
"bob")
(pl-qa-test!
"query-all parent(tom, X): second solution X=liz"
(dict-get (nth (pl-query-all pl-qa-db "parent(tom, X)") 1) "X")
"liz")
;; ── pl-query-all: no solutions ──
(pl-qa-test!
"query-all no solutions returns empty list"
(pl-query-all pl-qa-db "parent(liz, X)")
(list))
;; ── pl-query-all: boolean query (no vars) ──
(pl-qa-test!
"boolean success: 1 solution (empty dict)"
(len (pl-query-all pl-qa-db "parent(tom, bob)"))
1)
(pl-qa-test!
"boolean success: solution has no bindings"
(empty? (keys (first (pl-query-all pl-qa-db "parent(tom, bob)"))))
true)
(pl-qa-test!
"boolean fail: 0 solutions"
(len (pl-query-all pl-qa-db "parent(bob, tom)"))
0)
;; ── pl-query-all: multi-var ──
(pl-qa-test!
"query-all parent(X, Y): 3 solutions total"
(len (pl-query-all pl-qa-db "parent(X, Y)"))
3)
;; ── pl-query-all: rule-based (ancestor/2) ──
(pl-qa-test!
"query-all ancestor(tom, X): 3 descendants (bob, liz, ann)"
(len (pl-query-all pl-qa-db "ancestor(tom, X)"))
3)
;; ── pl-query-all: built-in in query ──
(pl-qa-test!
"query with is/2 built-in"
(dict-get (first (pl-query-all pl-qa-db "X is 2 + 3")) "X")
"5")
;; ── pl-query-one ──
(pl-qa-test!
"query-one returns first solution"
(dict-get (pl-query-one pl-qa-db "parent(tom, X)") "X")
"bob")
(pl-qa-test!
"query-one returns nil for no solutions"
(pl-query-one pl-qa-db "parent(liz, X)")
nil)
;; ── pl-query convenience ──
(pl-qa-test!
"pl-query convenience: count solutions"
(len (pl-query "likes(alice, bob). likes(alice, carol)." "likes(alice, X)"))
2)
(pl-qa-test!
"pl-query convenience: first solution"
(dict-get (first (pl-query "likes(alice, bob). likes(alice, carol)." "likes(alice, X)")) "X")
"bob")
(pl-qa-test!
"pl-query with empty source (built-ins only)"
(dict-get (first (pl-query "" "X is 6 * 7")) "X")
"42")
(define pl-query-api-tests-run! (fn () {:failed pl-qa-test-fail :passed pl-qa-test-pass :total pl-qa-test-count :failures pl-qa-test-failures}))

195
lib/prolog/tests/set_predicates.sx
View File

@@ -1,195 +0,0 @@
;; lib/prolog/tests/set_predicates.sx — foldl/4, list_to_set/2, intersection/3, subtract/3, union/3
(define pl-sp-test-count 0)
(define pl-sp-test-pass 0)
(define pl-sp-test-fail 0)
(define pl-sp-test-failures (list))
(define
pl-sp-test!
(fn
(name got expected)
(begin
(set! pl-sp-test-count (+ pl-sp-test-count 1))
(if
(= got expected)
(set! pl-sp-test-pass (+ pl-sp-test-pass 1))
(begin
(set! pl-sp-test-fail (+ pl-sp-test-fail 1))
(append!
pl-sp-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-sp-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
;; DB with add/3 for foldl tests
(define pl-sp-db (pl-mk-db))
(pl-db-load! pl-sp-db (pl-parse "add(X, Acc, NAcc) :- NAcc is Acc + X."))
;; ── foldl/4 ────────────────────────────────────────────────────────
(define pl-sp-env-fl1 {:S (pl-mk-rt-var "S")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "foldl(add, [1,2,3,4], 0, S)" pl-sp-env-fl1)
(pl-mk-trail))
(pl-sp-test!
"foldl(add,[1,2,3,4],0,S) -> S=10"
(pl-num-val (pl-walk-deep (dict-get pl-sp-env-fl1 "S")))
10)
(define pl-sp-env-fl2 {:S (pl-mk-rt-var "S")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "foldl(add, [], 5, S)" pl-sp-env-fl2)
(pl-mk-trail))
(pl-sp-test!
"foldl(add,[],5,S) -> S=5"
(pl-num-val (pl-walk-deep (dict-get pl-sp-env-fl2 "S")))
5)
(define pl-sp-env-fl3 {:S (pl-mk-rt-var "S")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "foldl(add, [1,2,3], 0, S)" pl-sp-env-fl3)
(pl-mk-trail))
(pl-sp-test!
"foldl(add,[1,2,3],0,S) -> S=6"
(pl-num-val (pl-walk-deep (dict-get pl-sp-env-fl3 "S")))
6)
;; ── list_to_set/2 ──────────────────────────────────────────────────
(define pl-sp-env-lts1 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "list_to_set([1,2,3,2,1], R)" pl-sp-env-lts1)
(pl-mk-trail))
(pl-sp-test!
"list_to_set([1,2,3,2,1],R) -> [1,2,3]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-lts1 "R")))
".(1, .(2, .(3, [])))")
(define pl-sp-env-lts2 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "list_to_set([], R)" pl-sp-env-lts2)
(pl-mk-trail))
(pl-sp-test!
"list_to_set([],R) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-lts2 "R")))
"[]")
(define pl-sp-env-lts3 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "list_to_set([a,b,a,c], R)" pl-sp-env-lts3)
(pl-mk-trail))
(pl-sp-test!
"list_to_set([a,b,a,c],R) -> [a,b,c]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-lts3 "R")))
".(a, .(b, .(c, [])))")
;; ── intersection/3 ─────────────────────────────────────────────────
(define pl-sp-env-int1 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "intersection([1,2,3,4], [2,4,6], R)" pl-sp-env-int1)
(pl-mk-trail))
(pl-sp-test!
"intersection([1,2,3,4],[2,4,6],R) -> [2,4]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-int1 "R")))
".(2, .(4, []))")
(define pl-sp-env-int2 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "intersection([1,2,3], [4,5,6], R)" pl-sp-env-int2)
(pl-mk-trail))
(pl-sp-test!
"intersection([1,2,3],[4,5,6],R) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-int2 "R")))
"[]")
(define pl-sp-env-int3 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "intersection([], [1,2,3], R)" pl-sp-env-int3)
(pl-mk-trail))
(pl-sp-test!
"intersection([],[1,2,3],R) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-int3 "R")))
"[]")
;; ── subtract/3 ─────────────────────────────────────────────────────
(define pl-sp-env-sub1 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "subtract([1,2,3,4], [2,4], R)" pl-sp-env-sub1)
(pl-mk-trail))
(pl-sp-test!
"subtract([1,2,3,4],[2,4],R) -> [1,3]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-sub1 "R")))
".(1, .(3, []))")
(define pl-sp-env-sub2 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "subtract([1,2,3], [], R)" pl-sp-env-sub2)
(pl-mk-trail))
(pl-sp-test!
"subtract([1,2,3],[],R) -> [1,2,3]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-sub2 "R")))
".(1, .(2, .(3, [])))")
(define pl-sp-env-sub3 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "subtract([], [1,2], R)" pl-sp-env-sub3)
(pl-mk-trail))
(pl-sp-test!
"subtract([],[1,2],R) -> []"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-sub3 "R")))
"[]")
;; ── union/3 ────────────────────────────────────────────────────────
(define pl-sp-env-uni1 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "union([1,2,3], [2,3,4], R)" pl-sp-env-uni1)
(pl-mk-trail))
(pl-sp-test!
"union([1,2,3],[2,3,4],R) -> [1,2,3,4]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-uni1 "R")))
".(1, .(2, .(3, .(4, []))))")
(define pl-sp-env-uni2 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "union([], [1,2], R)" pl-sp-env-uni2)
(pl-mk-trail))
(pl-sp-test!
"union([],[1,2],R) -> [1,2]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-uni2 "R")))
".(1, .(2, []))")
(define pl-sp-env-uni3 {:R (pl-mk-rt-var "R")})
(pl-solve-once!
pl-sp-db
(pl-sp-goal "union([1,2], [], R)" pl-sp-env-uni3)
(pl-mk-trail))
(pl-sp-test!
"union([1,2],[],R) -> [1,2]"
(pl-format-term (pl-walk-deep (dict-get pl-sp-env-uni3 "R")))
".(1, .(2, []))")
;; ── Runner ─────────────────────────────────────────────────────────
(define pl-set-predicates-tests-run! (fn () {:failed pl-sp-test-fail :passed pl-sp-test-pass :total pl-sp-test-count :failures pl-sp-test-failures}))

618
lib/prolog/tests/solve.sx
View File

@@ -1,618 +0,0 @@
;; lib/prolog/tests/solve.sx — DFS solver unit tests
(define pl-s-test-count 0)
(define pl-s-test-pass 0)
(define pl-s-test-fail 0)
(define pl-s-test-failures (list))
(define
pl-s-test!
(fn
(name got expected)
(begin
(set! pl-s-test-count (+ pl-s-test-count 1))
(if
(= got expected)
(set! pl-s-test-pass (+ pl-s-test-pass 1))
(begin
(set! pl-s-test-fail (+ pl-s-test-fail 1))
(append!
pl-s-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-s-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-s-empty-db (pl-mk-db))
(pl-s-test!
"true succeeds"
(pl-solve-once! pl-s-empty-db (pl-s-goal "true" {}) (pl-mk-trail))
true)
(pl-s-test!
"fail fails"
(pl-solve-once! pl-s-empty-db (pl-s-goal "fail" {}) (pl-mk-trail))
false)
(pl-s-test!
"= identical atoms"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(a, a)" {})
(pl-mk-trail))
true)
(pl-s-test!
"= different atoms"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(a, b)" {})
(pl-mk-trail))
false)
(pl-s-test!
"= var to atom"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(X, foo)" {})
(pl-mk-trail))
true)
(define pl-s-env-bind {})
(define pl-s-trail-bind (pl-mk-trail))
(define pl-s-goal-bind (pl-s-goal "=(X, foo)" pl-s-env-bind))
(pl-solve-once! pl-s-empty-db pl-s-goal-bind pl-s-trail-bind)
(pl-s-test!
"X bound to foo after =(X, foo)"
(pl-atom-name (pl-walk-deep (dict-get pl-s-env-bind "X")))
"foo")
(pl-s-test!
"true , true succeeds"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "true, true" {})
(pl-mk-trail))
true)
(pl-s-test!
"true , fail fails"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "true, fail" {})
(pl-mk-trail))
false)
(pl-s-test!
"consistent X bindings succeed"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(X, a), =(X, a)" {})
(pl-mk-trail))
true)
(pl-s-test!
"conflicting X bindings fail"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(X, a), =(X, b)" {})
(pl-mk-trail))
false)
(define pl-s-db1 (pl-mk-db))
(pl-db-load!
pl-s-db1
(pl-parse "parent(tom, bob). parent(bob, liz). parent(bob, ann)."))
(pl-s-test!
"fact lookup hit"
(pl-solve-once!
pl-s-db1
(pl-s-goal "parent(tom, bob)" {})
(pl-mk-trail))
true)
(pl-s-test!
"fact lookup miss"
(pl-solve-once!
pl-s-db1
(pl-s-goal "parent(tom, liz)" {})
(pl-mk-trail))
false)
(pl-s-test!
"all parent solutions"
(pl-solve-count!
pl-s-db1
(pl-s-goal "parent(X, Y)" {})
(pl-mk-trail))
3)
(pl-s-test!
"fixed first arg solutions"
(pl-solve-count!
pl-s-db1
(pl-s-goal "parent(bob, Y)" {})
(pl-mk-trail))
2)
(define pl-s-db2 (pl-mk-db))
(pl-db-load!
pl-s-db2
(pl-parse
"parent(tom, bob). parent(bob, ann). ancestor(X, Y) :- parent(X, Y). ancestor(X, Z) :- parent(X, Y), ancestor(Y, Z)."))
(pl-s-test!
"rule direct ancestor"
(pl-solve-once!
pl-s-db2
(pl-s-goal "ancestor(tom, bob)" {})
(pl-mk-trail))
true)
(pl-s-test!
"rule transitive ancestor"
(pl-solve-once!
pl-s-db2
(pl-s-goal "ancestor(tom, ann)" {})
(pl-mk-trail))
true)
(pl-s-test!
"rule no path"
(pl-solve-once!
pl-s-db2
(pl-s-goal "ancestor(ann, tom)" {})
(pl-mk-trail))
false)
(define pl-s-env-undo {})
(define pl-s-trail-undo (pl-mk-trail))
(define pl-s-goal-undo (pl-s-goal "=(X, a), fail" pl-s-env-undo))
(pl-solve-once! pl-s-empty-db pl-s-goal-undo pl-s-trail-undo)
(pl-s-test!
"trail undone after failure leaves X unbound"
(pl-var-bound? (dict-get pl-s-env-undo "X"))
false)
(define pl-s-db-cut1 (pl-mk-db))
(pl-db-load! pl-s-db-cut1 (pl-parse "g :- !. g :- true."))
(pl-s-test!
"bare cut succeeds"
(pl-solve-once! pl-s-db-cut1 (pl-s-goal "g" {}) (pl-mk-trail))
true)
(pl-s-test!
"cut commits to first matching clause"
(pl-solve-count! pl-s-db-cut1 (pl-s-goal "g" {}) (pl-mk-trail))
1)
(define pl-s-db-cut2 (pl-mk-db))
(pl-db-load! pl-s-db-cut2 (pl-parse "a(1). a(2). g(X) :- a(X), !."))
(pl-s-test!
"cut commits to first a solution"
(pl-solve-count! pl-s-db-cut2 (pl-s-goal "g(X)" {}) (pl-mk-trail))
1)
(define pl-s-db-cut3 (pl-mk-db))
(pl-db-load!
pl-s-db-cut3
(pl-parse "a(1). a(2). g(X) :- a(X), !, fail. g(99)."))
(pl-s-test!
"cut then fail blocks alt clauses"
(pl-solve-count! pl-s-db-cut3 (pl-s-goal "g(X)" {}) (pl-mk-trail))
0)
(define pl-s-db-cut4 (pl-mk-db))
(pl-db-load!
pl-s-db-cut4
(pl-parse "a(1). b(10). b(20). g(X, Y) :- a(X), !, b(Y)."))
(pl-s-test!
"post-cut goal backtracks freely"
(pl-solve-count!
pl-s-db-cut4
(pl-s-goal "g(X, Y)" {})
(pl-mk-trail))
2)
(define pl-s-db-cut5 (pl-mk-db))
(pl-db-load!
pl-s-db-cut5
(pl-parse "r(1). r(2). q :- r(X), !. p :- q. p :- true."))
(pl-s-test!
"inner cut does not commit outer predicate"
(pl-solve-count! pl-s-db-cut5 (pl-s-goal "p" {}) (pl-mk-trail))
2)
(pl-s-test!
"\\= different atoms succeeds"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "\\=(a, b)" {})
(pl-mk-trail))
true)
(pl-s-test!
"\\= same atoms fails"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "\\=(a, a)" {})
(pl-mk-trail))
false)
(pl-s-test!
"\\= var-vs-atom would unify so fails"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "\\=(X, a)" {})
(pl-mk-trail))
false)
(define pl-s-env-ne {})
(define pl-s-trail-ne (pl-mk-trail))
(define pl-s-goal-ne (pl-s-goal "\\=(X, a)" pl-s-env-ne))
(pl-solve-once! pl-s-empty-db pl-s-goal-ne pl-s-trail-ne)
(pl-s-test!
"\\= leaves no bindings"
(pl-var-bound? (dict-get pl-s-env-ne "X"))
false)
(pl-s-test!
"; left succeeds"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal ";(true, fail)" {})
(pl-mk-trail))
true)
(pl-s-test!
"; right succeeds when left fails"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal ";(fail, true)" {})
(pl-mk-trail))
true)
(pl-s-test!
"; both fail"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal ";(fail, fail)" {})
(pl-mk-trail))
false)
(pl-s-test!
"; both branches counted"
(pl-solve-count!
pl-s-empty-db
(pl-s-goal ";(true, true)" {})
(pl-mk-trail))
2)
(define pl-s-db-call (pl-mk-db))
(pl-db-load! pl-s-db-call (pl-parse "p(1). p(2)."))
(pl-s-test!
"call(true) succeeds"
(pl-solve-once!
pl-s-db-call
(pl-s-goal "call(true)" {})
(pl-mk-trail))
true)
(pl-s-test!
"call(p(X)) yields all solutions"
(pl-solve-count!
pl-s-db-call
(pl-s-goal "call(p(X))" {})
(pl-mk-trail))
2)
(pl-s-test!
"call of bound goal var resolves"
(pl-solve-once!
pl-s-db-call
(pl-s-goal "=(G, true), call(G)" {})
(pl-mk-trail))
true)
(define pl-s-db-ite (pl-mk-db))
(pl-db-load! pl-s-db-ite (pl-parse "p(1). p(2). q(yes). q(no)."))
(pl-s-test!
"if-then-else: cond true → then runs"
(pl-solve-once!
pl-s-db-ite
(pl-s-goal ";(->(true, =(X, ok)), =(X, fallback))" {})
(pl-mk-trail))
true)
(define pl-s-env-ite1 {})
(pl-solve-once!
pl-s-db-ite
(pl-s-goal ";(->(true, =(X, ok)), =(X, fallback))" pl-s-env-ite1)
(pl-mk-trail))
(pl-s-test!
"if-then-else: cond true binds via then"
(pl-atom-name (pl-walk-deep (dict-get pl-s-env-ite1 "X")))
"ok")
(pl-s-test!
"if-then-else: cond false → else"
(pl-solve-once!
pl-s-db-ite
(pl-s-goal ";(->(fail, =(X, ok)), =(X, fallback))" {})
(pl-mk-trail))
true)
(define pl-s-env-ite2 {})
(pl-solve-once!
pl-s-db-ite
(pl-s-goal ";(->(fail, =(X, ok)), =(X, fallback))" pl-s-env-ite2)
(pl-mk-trail))
(pl-s-test!
"if-then-else: cond false binds via else"
(pl-atom-name (pl-walk-deep (dict-get pl-s-env-ite2 "X")))
"fallback")
(pl-s-test!
"if-then-else: cond commits to first solution (count = 1)"
(pl-solve-count!
pl-s-db-ite
(pl-s-goal ";(->(p(X), =(Y, found)), =(Y, none))" {})
(pl-mk-trail))
1)
(pl-s-test!
"if-then-else: then can backtrack"
(pl-solve-count!
pl-s-db-ite
(pl-s-goal ";(->(true, p(X)), =(X, none))" {})
(pl-mk-trail))
2)
(pl-s-test!
"if-then-else: else can backtrack"
(pl-solve-count!
pl-s-db-ite
(pl-s-goal ";(->(fail, =(X, ignored)), p(X))" {})
(pl-mk-trail))
2)
(pl-s-test!
"standalone -> with true cond succeeds"
(pl-solve-once!
pl-s-db-ite
(pl-s-goal "->(true, =(X, hi))" {})
(pl-mk-trail))
true)
(pl-s-test!
"standalone -> with false cond fails"
(pl-solve-once!
pl-s-db-ite
(pl-s-goal "->(fail, =(X, hi))" {})
(pl-mk-trail))
false)
(pl-s-test!
"write(hello)"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "write(hello)" {})
(pl-mk-trail))
pl-output-buffer)
"hello")
(pl-s-test!
"nl outputs newline"
(begin
(pl-output-clear!)
(pl-solve-once! pl-s-empty-db (pl-s-goal "nl" {}) (pl-mk-trail))
pl-output-buffer)
"\n")
(pl-s-test!
"write(42) outputs digits"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "write(42)" {})
(pl-mk-trail))
pl-output-buffer)
"42")
(pl-s-test!
"write(foo(a, b)) formats compound"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "write(foo(a, b))" {})
(pl-mk-trail))
pl-output-buffer)
"foo(a, b)")
(pl-s-test!
"write conjunction"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "write(a), write(b)" {})
(pl-mk-trail))
pl-output-buffer)
"ab")
(pl-s-test!
"write of bound var walks binding"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(X, hello), write(X)" {})
(pl-mk-trail))
pl-output-buffer)
"hello")
(pl-s-test!
"write then nl"
(begin
(pl-output-clear!)
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "write(hi), nl" {})
(pl-mk-trail))
pl-output-buffer)
"hi\n")
(define pl-s-env-arith1 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, 42)" pl-s-env-arith1)
(pl-mk-trail))
(pl-s-test!
"is(X, 42) binds X to 42"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith1 "X")))
42)
(define pl-s-env-arith2 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, +(2, 3))" pl-s-env-arith2)
(pl-mk-trail))
(pl-s-test!
"is(X, +(2, 3)) binds X to 5"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith2 "X")))
5)
(define pl-s-env-arith3 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, *(2, 3))" pl-s-env-arith3)
(pl-mk-trail))
(pl-s-test!
"is(X, *(2, 3)) binds X to 6"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith3 "X")))
6)
(define pl-s-env-arith4 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, -(10, 3))" pl-s-env-arith4)
(pl-mk-trail))
(pl-s-test!
"is(X, -(10, 3)) binds X to 7"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith4 "X")))
7)
(define pl-s-env-arith5 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, /(10, 2))" pl-s-env-arith5)
(pl-mk-trail))
(pl-s-test!
"is(X, /(10, 2)) binds X to 5"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith5 "X")))
5)
(define pl-s-env-arith6 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, mod(10, 3))" pl-s-env-arith6)
(pl-mk-trail))
(pl-s-test!
"is(X, mod(10, 3)) binds X to 1"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith6 "X")))
1)
(define pl-s-env-arith7 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, abs(-(0, 5)))" pl-s-env-arith7)
(pl-mk-trail))
(pl-s-test!
"is(X, abs(-(0, 5))) binds X to 5"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith7 "X")))
5)
(define pl-s-env-arith8 {})
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(X, +(2, *(3, 4)))" pl-s-env-arith8)
(pl-mk-trail))
(pl-s-test!
"is(X, +(2, *(3, 4))) binds X to 14 (nested)"
(pl-num-val (pl-walk-deep (dict-get pl-s-env-arith8 "X")))
14)
(pl-s-test!
"is(5, +(2, 3)) succeeds (LHS num matches)"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(5, +(2, 3))" {})
(pl-mk-trail))
true)
(pl-s-test!
"is(6, +(2, 3)) fails (LHS num mismatch)"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "is(6, +(2, 3))" {})
(pl-mk-trail))
false)
(pl-s-test!
"is propagates bound vars on RHS"
(pl-solve-once!
pl-s-empty-db
(pl-s-goal "=(Y, 4), is(X, +(Y, 1)), =(X, 5)" {})
(pl-mk-trail))
true)
(define pl-solve-tests-run! (fn () {:failed pl-s-test-fail :passed pl-s-test-pass :total pl-s-test-count :failures pl-s-test-failures}))

273
lib/prolog/tests/string_agg.sx
View File

@@ -1,273 +0,0 @@
;; lib/prolog/tests/string_agg.sx -- sub_atom/5 + aggregate_all/3
(define pl-sa-test-count 0)
(define pl-sa-test-pass 0)
(define pl-sa-test-fail 0)
(define pl-sa-test-failures (list))
(define
pl-sa-test!
(fn
(name got expected)
(begin
(set! pl-sa-test-count (+ pl-sa-test-count 1))
(if
(= got expected)
(set! pl-sa-test-pass (+ pl-sa-test-pass 1))
(begin
(set! pl-sa-test-fail (+ pl-sa-test-fail 1))
(append!
pl-sa-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-sa-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-sa-db (pl-mk-db))
(define
pl-sa-num-val
(fn (env key) (pl-num-val (pl-walk-deep (dict-get env key)))))
(define
pl-sa-list-to-atoms
(fn
(t)
(let
((w (pl-walk-deep t)))
(cond
((and (pl-atom? w) (= (pl-atom-name w) "[]")) (list))
((and (pl-compound? w) (= (pl-fun w) ".") (= (len (pl-args w)) 2))
(cons
(pl-atom-name (first (pl-args w)))
(pl-sa-list-to-atoms (nth (pl-args w) 1))))
(true (list))))))
(define pl-sa-prog-src "member(X, [X|_]). member(X, [_|T]) :- member(X, T).")
(pl-db-load! pl-sa-db (pl-parse pl-sa-prog-src))
;; -- sub_atom/5 --
(pl-sa-test!
"sub_atom ground: sub_atom(abcde,0,3,2,abc)"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(abcde, 0, 3, 2, abc)" {})
(pl-mk-trail))
true)
(pl-sa-test!
"sub_atom ground: sub_atom(abcde,2,2,1,cd)"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(abcde, 2, 2, 1, cd)" {})
(pl-mk-trail))
true)
(pl-sa-test!
"sub_atom ground mismatch fails"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(abcde, 0, 2, 3, cd)" {})
(pl-mk-trail))
false)
(pl-sa-test!
"sub_atom empty sub at start"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(abcde, 0, 0, 5, '')" {})
(pl-mk-trail))
true)
(pl-sa-test!
"sub_atom whole string"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(hello, 0, 5, 0, hello)" {})
(pl-mk-trail))
true)
(define pl-sa-env-b1 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(abcde, B, 2, A, cd)" pl-sa-env-b1)
(pl-mk-trail))
(pl-sa-test!
"sub_atom bound SubAtom gives B=2"
(pl-sa-num-val pl-sa-env-b1 "B")
2)
(pl-sa-test!
"sub_atom bound SubAtom gives A=1"
(pl-sa-num-val pl-sa-env-b1 "A")
1)
(define pl-sa-env-b2 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal "sub_atom(hello, B, L, A, ello)" pl-sa-env-b2)
(pl-mk-trail))
(pl-sa-test! "sub_atom ello: B=1" (pl-sa-num-val pl-sa-env-b2 "B") 1)
(pl-sa-test! "sub_atom ello: L=4" (pl-sa-num-val pl-sa-env-b2 "L") 4)
(pl-sa-test! "sub_atom ello: A=0" (pl-sa-num-val pl-sa-env-b2 "A") 0)
(pl-sa-test!
"sub_atom ab: 6 total solutions"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(count, sub_atom(ab, _, _, _, _), N)" env)
(pl-mk-trail))
(pl-sa-num-val env "N"))
6)
(pl-sa-test!
"sub_atom a: 3 total solutions"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(count, sub_atom(a, _, _, _, _), N)" env)
(pl-mk-trail))
(pl-sa-num-val env "N"))
3)
;; -- aggregate_all/3 --
(pl-sa-test!
"aggregate_all count member [a,b,c] = 3"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(count, member(_, [a,b,c]), N)" env)
(pl-mk-trail))
(pl-sa-num-val env "N"))
3)
(pl-sa-test!
"aggregate_all count fail = 0"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(count, fail, N)" env)
(pl-mk-trail))
(pl-sa-num-val env "N"))
0)
(pl-sa-test!
"aggregate_all count always succeeds"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(count, fail, _)" {})
(pl-mk-trail))
true)
(define pl-sa-env-bag1 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(bag(X), member(X, [a,b,c]), L)" pl-sa-env-bag1)
(pl-mk-trail))
(pl-sa-test!
"aggregate_all bag [a,b,c]"
(pl-sa-list-to-atoms (dict-get pl-sa-env-bag1 "L"))
(list "a" "b" "c"))
(define pl-sa-env-bag2 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(bag(X), member(X, []), L)" pl-sa-env-bag2)
(pl-mk-trail))
(pl-sa-test!
"aggregate_all bag empty goal = []"
(pl-sa-list-to-atoms (dict-get pl-sa-env-bag2 "L"))
(list))
(pl-sa-test!
"aggregate_all sum [1,2,3,4] = 10"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(sum(X), member(X, [1,2,3,4]), S)" env)
(pl-mk-trail))
(pl-sa-num-val env "S"))
10)
(pl-sa-test!
"aggregate_all max [3,1,4,1,5,9,2,6] = 9"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(max(X), member(X, [3,1,4,1,5,9,2,6]), M)" env)
(pl-mk-trail))
(pl-sa-num-val env "M"))
9)
(pl-sa-test!
"aggregate_all max empty fails"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(max(X), member(X, []), M)" {})
(pl-mk-trail))
false)
(pl-sa-test!
"aggregate_all min [3,1,4,1,5,9,2,6] = 1"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(min(X), member(X, [3,1,4,1,5,9,2,6]), M)" env)
(pl-mk-trail))
(pl-sa-num-val env "M"))
1)
(pl-sa-test!
"aggregate_all min empty fails"
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(min(X), member(X, []), M)" {})
(pl-mk-trail))
false)
(define pl-sa-env-set1 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal
"aggregate_all(set(X), member(X, [b,a,c,a,b]), S)"
pl-sa-env-set1)
(pl-mk-trail))
(pl-sa-test!
"aggregate_all set [b,a,c,a,b] = [a,b,c]"
(pl-sa-list-to-atoms (dict-get pl-sa-env-set1 "S"))
(list "a" "b" "c"))
(define pl-sa-env-set2 {})
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(set(X), fail, S)" pl-sa-env-set2)
(pl-mk-trail))
(pl-sa-test!
"aggregate_all set fail = []"
(pl-sa-list-to-atoms (dict-get pl-sa-env-set2 "S"))
(list))
(pl-sa-test!
"aggregate_all sum empty = 0"
(let
((env {}))
(pl-solve-once!
pl-sa-db
(pl-sa-goal "aggregate_all(sum(X), fail, S)" env)
(pl-mk-trail))
(pl-sa-num-val env "S"))
0)
(define pl-string-agg-tests-run! (fn () {:failed pl-sa-test-fail :passed pl-sa-test-pass :total pl-sa-test-count :failures pl-sa-test-failures}))

147
lib/prolog/tests/term_inspect.sx
View File

@@ -1,147 +0,0 @@
;; lib/prolog/tests/term_inspect.sx — copy_term/2, functor/3, arg/3.
(define pl-tt-test-count 0)
(define pl-tt-test-pass 0)
(define pl-tt-test-fail 0)
(define pl-tt-test-failures (list))
(define
pl-tt-test!
(fn
(name got expected)
(begin
(set! pl-tt-test-count (+ pl-tt-test-count 1))
(if
(= got expected)
(set! pl-tt-test-pass (+ pl-tt-test-pass 1))
(begin
(set! pl-tt-test-fail (+ pl-tt-test-fail 1))
(append!
pl-tt-test-failures
(str name "\n expected: " expected "\n got: " got)))))))
(define
pl-tt-goal
(fn
(src env)
(pl-instantiate (nth (first (pl-parse (str "g :- " src "."))) 2) env)))
(define pl-tt-db (pl-mk-db))
;; ── copy_term/2 ──
(pl-tt-test!
"copy_term ground compound succeeds + copy = original"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "copy_term(foo(a, b), X), X = foo(a, b)" {})
(pl-mk-trail))
true)
(pl-tt-test!
"copy_term preserves var aliasing in source"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "copy_term(p(Y, Y), p(A, B)), A = 5, B = 5" {})
(pl-mk-trail))
true)
(pl-tt-test!
"copy_term distinct vars stay distinct"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "copy_term(p(Y, Y), p(A, B)), A = 5, B = 6" {})
(pl-mk-trail))
false)
(define pl-tt-env-1 {})
(pl-solve-once!
pl-tt-db
(pl-tt-goal "copy_term(X, Y), Y = 5" pl-tt-env-1)
(pl-mk-trail))
(pl-tt-test!
"copy_term: binding the copy doesn't bind the source"
(pl-var-bound? (dict-get pl-tt-env-1 "X"))
false)
;; ── functor/3 ──
(define pl-tt-env-2 {})
(pl-solve-once!
pl-tt-db
(pl-tt-goal "functor(foo(a, b, c), F, N)" pl-tt-env-2)
(pl-mk-trail))
(pl-tt-test!
"functor of compound: F = foo"
(pl-atom-name (pl-walk-deep (dict-get pl-tt-env-2 "F")))
"foo")
(pl-tt-test!
"functor of compound: N = 3"
(pl-num-val (pl-walk-deep (dict-get pl-tt-env-2 "N")))
3)
(define pl-tt-env-3 {})
(pl-solve-once!
pl-tt-db
(pl-tt-goal "functor(hello, F, N)" pl-tt-env-3)
(pl-mk-trail))
(pl-tt-test!
"functor of atom: F = hello"
(pl-atom-name (pl-walk-deep (dict-get pl-tt-env-3 "F")))
"hello")
(pl-tt-test!
"functor of atom: N = 0"
(pl-num-val (pl-walk-deep (dict-get pl-tt-env-3 "N")))
0)
(pl-tt-test!
"functor construct compound: T unifies with foo(a, b)"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "functor(T, foo, 2), T = foo(a, b)" {})
(pl-mk-trail))
true)
(pl-tt-test!
"functor construct atom: T = hello"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "functor(T, hello, 0), T = hello" {})
(pl-mk-trail))
true)
;; ── arg/3 ──
(pl-tt-test!
"arg(1, foo(a, b, c), a)"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "arg(1, foo(a, b, c), a)" {})
(pl-mk-trail))
true)
(pl-tt-test!
"arg(2, foo(a, b, c), X) → X = b"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "arg(2, foo(a, b, c), X), X = b" {})
(pl-mk-trail))
true)
(pl-tt-test!
"arg out-of-range high fails"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "arg(4, foo(a, b, c), X)" {})
(pl-mk-trail))
false)
(pl-tt-test!
"arg(0, ...) fails (1-indexed)"
(pl-solve-once!
pl-tt-db
(pl-tt-goal "arg(0, foo(a), X)" {})
(pl-mk-trail))
false)
(define pl-term-inspect-tests-run! (fn () {:failed pl-tt-test-fail :passed pl-tt-test-pass :total pl-tt-test-count :failures pl-tt-test-failures}))

145
lib/tcl/conformance.sh
View File

@@ -1,145 +0,0 @@
#!/usr/bin/env bash
# Tcl-on-SX conformance runner — epoch protocol to sx_server.exe
# Usage: lib/tcl/conformance.sh [file.tcl ...]
# Defaults to lib/tcl/tests/programs/*.tcl
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
SCOREBOARD_JSON="${SCOREBOARD_JSON:-lib/tcl/scoreboard.json}"
SCOREBOARD_MD="${SCOREBOARD_MD:-lib/tcl/scoreboard.md}"
# Collect tcl files
if [ "$#" -gt 0 ]; then
TCL_FILES=("$@")
else
TCL_FILES=(lib/tcl/tests/programs/*.tcl)
fi
# Generate a helper .sx file that defines the Tcl source as an SX string variable.
# We escape the source for SX string literals: backslashes → \\, quotes → \", newlines → \n.
# This is safe in a (define ...) context — no double-parsing like (eval "...") would cause.
write_sx_helper() {
local tcl_file="$1"
local helper_file="$2"
python3 << PYEOF
src = open('${tcl_file}').read()
escaped = src.replace('\\\\', '\\\\\\\\').replace('"', '\\\\"').replace('\\n', '\\\\n')
with open('${helper_file}', 'w') as f:
f.write(f'(define __tcl-src "{escaped}")\\n')
f.write('(define __tcl-result (get (tcl-eval-string (make-default-tcl-interp) __tcl-src) :result))\\n')
PYEOF
}
total=0
passed=0
failed=0
programs_json=""
md_rows=""
for tcl_file in "${TCL_FILES[@]}"; do
basename_noext=$(basename "$tcl_file" .tcl)
total=$((total + 1))
# Read expected value from first-line comment "# expected: VALUE"
expected=$(head -1 "$tcl_file" | sed -n 's/^# expected: *//p')
if [ -z "$expected" ]; then
echo "WARN: no '# expected:' annotation in $tcl_file — skipping"
continue
fi
tmpfile=$(mktemp)
helper=$(mktemp --suffix=.sx)
trap "rm -f $tmpfile $helper" EXIT
# Write helper .sx with Tcl source embedded as SX string
write_sx_helper "$tcl_file" "$helper"
# Build epoch input using quoted heredoc for static parts; helper path via variable
cat > "$tmpfile" << EPOCHS
(epoch 1)
(load "lib/tcl/tokenizer.sx")
(epoch 2)
(load "lib/tcl/parser.sx")
(epoch 3)
(load "lib/tcl/runtime.sx")
(epoch 4)
(load "$helper")
(epoch 5)
(eval "__tcl-result")
(epoch 6)
EPOCHS
output=$(timeout 30 "$SX_SERVER" < "$tmpfile" 2>&1)
got=$(echo "$output" | grep -A1 "^(ok-len 5 " | tail -1 | tr -d '"')
if [ "$got" = "$expected" ]; then
status="PASS"
passed=$((passed + 1))
echo "PASS $basename_noext (expected: $expected, got: $got)"
else
status="FAIL"
failed=$((failed + 1))
echo "FAIL $basename_noext (expected: $expected, got: ${got:-<empty>})"
if [ -n "${VERBOSE:-}" ]; then
echo "--- server output ---"
echo "$output"
echo "--- helper.sx ---"
cat "$helper"
fi
fi
# Accumulate JSON fragment (escape for JSON)
got_json=$(printf '%s' "$got" | python3 -c "import sys,json; sys.stdout.write(json.dumps(sys.stdin.read()))" | tr -d '"')
exp_json=$(printf '%s' "$expected" | python3 -c "import sys,json; sys.stdout.write(json.dumps(sys.stdin.read()))" | tr -d '"')
if [ -n "$programs_json" ]; then
programs_json="${programs_json},"
fi
programs_json="${programs_json}
\"${basename_noext}\": {\"status\": \"${status}\", \"expected\": \"${exp_json}\", \"got\": \"${got_json}\"}"
# Accumulate Markdown row
if [ "$status" = "PASS" ]; then
icon="✓ PASS"
else
icon="✗ FAIL"
fi
md_rows="${md_rows}| ${basename_noext} | ${icon} | ${expected} | ${got} |
"
done
# Write scoreboard.json
cat > "$SCOREBOARD_JSON" << JSON
{
"total": ${total},
"passed": ${passed},
"failed": ${failed},
"programs": {${programs_json}
}
}
JSON
# Write scoreboard.md
cat > "$SCOREBOARD_MD" << MD
# Tcl-on-SX Conformance Scoreboard
| Program | Status | Expected | Got |
|---|---|---|---|
${md_rows}
**${passed}/${total} passing**
MD
echo ""
echo "Scoreboard: ${passed}/${total} passing"
echo "Written: $SCOREBOARD_JSON, $SCOREBOARD_MD"
if [ "$failed" -gt 0 ]; then
exit 1
fi
exit 0

41
lib/tcl/parser.sx
View File

@@ -1,41 +0,0 @@
; Tcl parser — thin layer over tcl-tokenize
; Adds tcl-parse entry point and word utility fns
; Entry point: parse Tcl source to a list of commands.
; Returns same structure as tcl-tokenize.
(define tcl-parse (fn (src) (tcl-tokenize src)))
; True if word has no substitutions — value can be read statically.
; braced words are always simple. compound words are simple when all
; parts are plain text with no var/cmd parts.
(define tcl-word-simple?
(fn (word)
(cond
((= (get word :type) "braced") true)
((= (get word :type) "compound")
(let ((parts (get word :parts)))
(every? (fn (p) (= (get p :type) "text")) parts)))
(else false))))
; Concatenate text parts of a simple word into a single string.
; For braced words returns :value directly.
; For compound words with only text parts, joins them.
; Returns nil for words with substitutions.
(define tcl-word-literal
(fn (word)
(cond
((= (get word :type) "braced") (get word :value))
((= (get word :type) "compound")
(if (tcl-word-simple? word)
(join "" (map (fn (p) (get p :value)) (get word :parts)))
nil))
(else nil))))
; Number of words in a parsed command.
(define tcl-cmd-len
(fn (cmd) (len (get cmd :words))))
; Nth word literal from a command (index 0 = command name).
; Returns nil if word has substitutions.
(define tcl-nth-literal
(fn (cmd n) (tcl-word-literal (nth (get cmd :words) n))))

3519
lib/tcl/runtime.sx
View File

File diff suppressed because it is too large Load Diff

10
lib/tcl/scoreboard.json
View File

@@ -1,10 +0,0 @@
{
"total": 3,
"passed": 3,
"failed": 0,
"programs": {
"assert": {"status": "PASS", "expected": "10", "got": "10"},
"for-each-line": {"status": "PASS", "expected": "13", "got": "13"},
"with-temp-var": {"status": "PASS", "expected": "100 999", "got": "100 999"}
}
}

9
lib/tcl/scoreboard.md
View File

@@ -1,9 +0,0 @@
# Tcl-on-SX Conformance Scoreboard
| Program | Status | Expected | Got |
|---|---|---|---|
| assert | ✓ PASS | 10 | 10 |
| for-each-line | ✓ PASS | 13 | 13 |
| with-temp-var | ✓ PASS | 100 999 | 100 999 |
**3/3 passing**

131
lib/tcl/test.sh
View File

@@ -1,5 +1,6 @@
#!/usr/bin/env bash
# Tcl-on-SX test runner — epoch protocol to sx_server.exe
# lib/tcl/test.sh — smoke-test the Tcl runtime layer.
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
@@ -7,107 +8,55 @@ SX_SERVER="${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
if [ ! -x "$SX_SERVER" ]; then
echo "ERROR: sx_server.exe not found."
exit 1
fi
VERBOSE="${1:-}"
TMPFILE=$(mktemp)
HELPER=$(mktemp --suffix=.sx)
trap "rm -f $TMPFILE $HELPER" EXIT
TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
# Helper file: run all test suites and format a parseable summary string
cat > "$HELPER" << 'HELPER_EOF'
(define __pr (tcl-run-parse-tests))
(define __er (tcl-run-eval-tests))
(define __xr (tcl-run-error-tests))
(define __nr (tcl-run-namespace-tests))
(define __cr (tcl-run-coro-tests))
(define __ir (tcl-run-idiom-tests))
(define tcl-test-summary
(str "PARSE:" (get __pr "passed") ":" (get __pr "failed")
" EVAL:" (get __er "passed") ":" (get __er "failed")
" ERROR:" (get __xr "passed") ":" (get __xr "failed")
" NAMESPACE:" (get __nr "passed") ":" (get __nr "failed")
" CORO:" (get __cr "passed") ":" (get __cr "failed")
" IDIOM:" (get __ir "passed") ":" (get __ir "failed")))
HELPER_EOF
cat > "$TMPFILE" << EPOCHS
cat > "$TMPFILE" << 'EPOCHS'
(epoch 1)
(load "lib/tcl/tokenizer.sx")
(epoch 2)
(load "lib/tcl/parser.sx")
(epoch 3)
(load "lib/tcl/tests/parse.sx")
(epoch 4)
(load "lib/tcl/runtime.sx")
(epoch 5)
(load "lib/tcl/tests/eval.sx")
(epoch 6)
(load "lib/tcl/tests/error.sx")
(epoch 7)
(load "lib/tcl/tests/namespace.sx")
(epoch 8)
(load "lib/tcl/tests/coro.sx")
(epoch 9)
(load "lib/tcl/tests/idioms.sx")
(epoch 10)
(load "$HELPER")
(epoch 11)
(eval "tcl-test-summary")
(epoch 2)
(load "lib/tcl/tests/runtime.sx")
(epoch 3)
(eval "(list tcl-test-pass tcl-test-fail)")
EPOCHS
OUTPUT=$(timeout 180 "$SX_SERVER" < "$TMPFILE" 2>&1)
[ "$VERBOSE" = "-v" ] && echo "$OUTPUT"
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
# Extract summary line from epoch 11 output
SUMMARY=$(echo "$OUTPUT" | grep -A1 "^(ok-len 11 " | tail -1 | tr -d '"')
if [ -z "$SUMMARY" ]; then
echo "ERROR: no summary from test run"
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 "$OUTPUT" | tail -20
exit 1
fi
# Parse PARSE:N:M EVAL:N:M ERROR:N:M NAMESPACE:N:M CORO:N:M IDIOM:N:M
PARSE_PART=$(echo "$SUMMARY" | grep -o 'PARSE:[0-9]*:[0-9]*')
EVAL_PART=$(echo "$SUMMARY" | grep -o 'EVAL:[0-9]*:[0-9]*')
ERROR_PART=$(echo "$SUMMARY" | grep -o 'ERROR:[0-9]*:[0-9]*')
NAMESPACE_PART=$(echo "$SUMMARY" | grep -o 'NAMESPACE:[0-9]*:[0-9]*')
CORO_PART=$(echo "$SUMMARY" | grep -o 'CORO:[0-9]*:[0-9]*')
IDIOM_PART=$(echo "$SUMMARY" | grep -o 'IDIOM:[0-9]*:[0-9]*')
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
TOTAL=$((P + F))
PARSE_PASSED=$(echo "$PARSE_PART" | cut -d: -f2)
PARSE_FAILED=$(echo "$PARSE_PART" | cut -d: -f3)
EVAL_PASSED=$(echo "$EVAL_PART" | cut -d: -f2)
EVAL_FAILED=$(echo "$EVAL_PART" | cut -d: -f3)
ERROR_PASSED=$(echo "$ERROR_PART" | cut -d: -f2)
ERROR_FAILED=$(echo "$ERROR_PART" | cut -d: -f3)
NAMESPACE_PASSED=$(echo "$NAMESPACE_PART" | cut -d: -f2)
NAMESPACE_FAILED=$(echo "$NAMESPACE_PART" | cut -d: -f3)
CORO_PASSED=$(echo "$CORO_PART" | cut -d: -f2)
CORO_FAILED=$(echo "$CORO_PART" | cut -d: -f3)
IDIOM_PASSED=$(echo "$IDIOM_PART" | cut -d: -f2)
IDIOM_FAILED=$(echo "$IDIOM_PART" | cut -d: -f3)
PARSE_PASSED=${PARSE_PASSED:-0}; PARSE_FAILED=${PARSE_FAILED:-1}
EVAL_PASSED=${EVAL_PASSED:-0}; EVAL_FAILED=${EVAL_FAILED:-1}
ERROR_PASSED=${ERROR_PASSED:-0}; ERROR_FAILED=${ERROR_FAILED:-1}
NAMESPACE_PASSED=${NAMESPACE_PASSED:-0}; NAMESPACE_FAILED=${NAMESPACE_FAILED:-1}
CORO_PASSED=${CORO_PASSED:-0}; CORO_FAILED=${CORO_FAILED:-1}
IDIOM_PASSED=${IDIOM_PASSED:-0}; IDIOM_FAILED=${IDIOM_FAILED:-1}
TOTAL_PASSED=$((PARSE_PASSED + EVAL_PASSED + ERROR_PASSED + NAMESPACE_PASSED + CORO_PASSED + IDIOM_PASSED))
TOTAL_FAILED=$((PARSE_FAILED + EVAL_FAILED + ERROR_FAILED + NAMESPACE_FAILED + CORO_FAILED + IDIOM_FAILED))
TOTAL=$((TOTAL_PASSED + TOTAL_FAILED))
if [ "$TOTAL_FAILED" = "0" ]; then
echo "ok $TOTAL_PASSED/$TOTAL tcl tests passed (parse: $PARSE_PASSED, eval: $EVAL_PASSED, error: $ERROR_PASSED, namespace: $NAMESPACE_PASSED, coro: $CORO_PASSED, idiom: $IDIOM_PASSED)"
exit 0
if [ "$F" -eq 0 ]; then
echo "ok $P/$TOTAL lib/tcl tests passed"
else
echo "FAIL $TOTAL_PASSED/$TOTAL passed, $TOTAL_FAILED failed (parse: $PARSE_PASSED/$((PARSE_PASSED+PARSE_FAILED)), eval: $EVAL_PASSED/$((EVAL_PASSED+EVAL_FAILED)), error: $ERROR_PASSED/$((ERROR_PASSED+ERROR_FAILED)), namespace: $NAMESPACE_PASSED/$((NAMESPACE_PASSED+NAMESPACE_FAILED)), coro: $CORO_PASSED/$((CORO_PASSED+CORO_FAILED)), idiom: $IDIOM_PASSED/$((IDIOM_PASSED+IDIOM_FAILED)))"
if [ -z "$VERBOSE" ]; then
echo "--- output ---"
echo "$OUTPUT" | tail -30
fi
exit 1
echo "FAIL $P/$TOTAL passed, $F failed"
TMPFILE2=$(mktemp)
cat > "$TMPFILE2" << 'EPOCHS2'
(epoch 1)
(load "lib/tcl/runtime.sx")
(epoch 2)
(load "lib/tcl/tests/runtime.sx")
(epoch 3)
(eval "(map (fn (f) (list (get f :name) (get f :got) (get f :expected))) tcl-test-fails)")
EPOCHS2
FAILS=$(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 ]

136
lib/tcl/tests/coro.sx
View File

@@ -1,136 +0,0 @@
; Tcl-on-SX coroutine tests (Phase 6)
(define tcl-coro-pass 0)
(define tcl-coro-fail 0)
(define tcl-coro-failures (list))
(define
tcl-coro-assert
(fn
(label expected actual)
(if
(equal? expected actual)
(set! tcl-coro-pass (+ tcl-coro-pass 1))
(begin
(set! tcl-coro-fail (+ tcl-coro-fail 1))
(append!
tcl-coro-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define
tcl-run-coro-tests
(fn
()
(set! tcl-coro-pass 0)
(set! tcl-coro-fail 0)
(set! tcl-coro-failures (list))
(define interp (fn () (make-default-tcl-interp)))
(define run (fn (src) (tcl-eval-string (interp) src)))
(define
ok
(fn (label actual expected) (tcl-coro-assert label expected actual)))
; --- basic coroutine: yields one value ---
(ok "coro-single-yield"
(get (run "proc gen {} { yield hello }\ncoroutine g gen\ng") :result)
"hello")
; --- coroutine yields multiple values in order ---
(ok "coro-multi-yield-1"
(get (run "proc cnt {} { yield a; yield b; yield c }\ncoroutine c1 cnt\nc1") :result)
"a")
(ok "coro-multi-yield-2"
(get (run "proc cnt {} { yield a; yield b; yield c }\ncoroutine c1 cnt\nc1\nc1") :result)
"b")
(ok "coro-multi-yield-3"
(get (run "proc cnt {} { yield a; yield b; yield c }\ncoroutine c1 cnt\nc1\nc1\nc1") :result)
"c")
; --- coroutine with arguments to proc ---
(ok "coro-args"
(get (run "proc gen2 {n} { yield $n; yield [expr {$n + 1}] }\ncoroutine g2 gen2 10\ng2") :result)
"10")
(ok "coro-args-2"
(get (run "proc gen2 {n} { yield $n; yield [expr {$n + 1}] }\ncoroutine g2 gen2 10\ng2\ng2") :result)
"11")
; --- coroutine exhausted returns empty string ---
(ok "coro-exhausted"
(get (run "proc g3 {} { yield only }\ncoroutine c3 g3\nc3\nc3") :result)
"")
; --- yield in while loop ---
(ok "coro-while-loop-1"
(get (run "proc counter {max} { set i 0; while {$i < $max} { yield $i; incr i } }\ncoroutine cw counter 3\ncw") :result)
"0")
(ok "coro-while-loop-2"
(get (run "proc counter {max} { set i 0; while {$i < $max} { yield $i; incr i } }\ncoroutine cw counter 3\ncw\ncw") :result)
"1")
(ok "coro-while-loop-3"
(get (run "proc counter {max} { set i 0; while {$i < $max} { yield $i; incr i } }\ncoroutine cw counter 3\ncw\ncw\ncw") :result)
"2")
; --- collect all yields from coroutine ---
(ok "coro-collect-all"
(get
(run
"proc counter {n max} { while {$n < $max} { yield $n; incr n }; yield done }\ncoroutine gen1 counter 0 3\nset out {}\nfor {set i 0} {$i < 4} {incr i} { lappend out [gen1] }\nlindex $out 3")
:result)
"done")
; --- two independent coroutines ---
(ok "coro-two-independent"
(get
(run
"proc seq {start} { yield $start; yield [expr {$start+1}] }\ncoroutine ca seq 0\ncoroutine cb seq 10\nset r [ca]\nappend r \":\" [cb]")
:result)
"0:10")
; --- yield with no value returns empty string ---
(ok "coro-yield-no-val"
(get (run "proc g {} { yield }\ncoroutine cg g\ncg") :result)
"")
; --- clock seconds stub ---
(ok "clock-seconds"
(get (run "clock seconds") :result)
"0")
; --- clock milliseconds stub ---
(ok "clock-milliseconds"
(get (run "clock milliseconds") :result)
"0")
; --- clock format stub ---
(ok "clock-format"
(get (run "clock format 0") :result)
"Thu Jan 1 00:00:00 UTC 1970")
; --- file stubs ---
(ok "file-exists-stub"
(get (run "file exists /no/such/file") :result)
"0")
(ok "file-join"
(get (run "file join foo bar baz") :result)
"foo/bar/baz")
(ok "open-returns-channel"
(get (run "open /dev/null r") :result)
"file0")
(ok "eof-returns-1"
(get (run "set ch [open /dev/null r]\neof $ch") :result)
"1")
(dict
"passed"
tcl-coro-pass
"failed"
tcl-coro-fail
"failures"
tcl-coro-failures)))

192
lib/tcl/tests/error.sx
View File

@@ -1,192 +0,0 @@
; Tcl-on-SX error handling tests (Phase 4)
(define tcl-err-pass 0)
(define tcl-err-fail 0)
(define tcl-err-failures (list))
(define
tcl-err-assert
(fn
(label expected actual)
(if
(equal? expected actual)
(set! tcl-err-pass (+ tcl-err-pass 1))
(begin
(set! tcl-err-fail (+ tcl-err-fail 1))
(append!
tcl-err-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define
tcl-run-error-tests
(fn
()
(set! tcl-err-pass 0)
(set! tcl-err-fail 0)
(set! tcl-err-failures (list))
(define interp (fn () (make-default-tcl-interp)))
(define run (fn (src) (tcl-eval-string (interp) src)))
(define
ok
(fn (label actual expected) (tcl-err-assert label expected actual)))
(define
ok?
(fn (label condition) (tcl-err-assert label true condition)))
; --- catch basic ---
(ok "catch-ok-code" (get (run "catch {set x 1}") :result) "0")
(ok "catch-ok-result-var" (tcl-var-get (run "catch {set x hello} r") "r") "hello")
(ok "catch-ok-returns-0" (get (run "catch {set x hello} r") :result) "0")
; --- catch error ---
(ok "catch-error-code" (get (run "catch {error oops} r") :result) "1")
(ok "catch-error-result-var" (tcl-var-get (run "catch {error oops} r") "r") "oops")
; --- catch outer code stays 0 ---
(ok? "catch-outer-code-ok" (= (get (run "catch {error boom} r") :code) 0))
; --- catch code 2 (return) ---
(ok "catch-return-code" (get (run "proc p {} {return hello}\ncatch {p} r") :result) "0")
(ok "catch-return-val" (tcl-var-get (run "proc p {} {return hello}\ncatch {p} r") "r") "hello")
; --- catch code 3 (break) ---
(ok "catch-break-code" (get (run "catch {break} r") :result) "3")
; --- catch code 4 (continue) ---
(ok "catch-continue-code" (get (run "catch {continue} r") :result) "4")
; --- catch no resultVar ---
(ok "catch-no-var-ok" (get (run "catch {set x 1}") :result) "0")
(ok "catch-no-var-err" (get (run "catch {error boom}") :result) "1")
; --- catch with optsVar ---
(ok? "catch-opts-var-set"
(let
((i (run "catch {error boom} r opts")))
(not (equal? (tcl-var-get i "opts") ""))))
(ok? "catch-opts-contains-code"
(let
((i (run "catch {error boom} r opts")))
(let
((opts-str (tcl-var-get i "opts")))
(not (equal? (tcl-string-first "-code" opts-str 0) "-1")))))
; --- catch nested ---
(ok "catch-nested"
(tcl-var-get (run "catch {catch {error inner} r2} outer") "r2")
"inner")
; --- return -code error ---
(ok "return-code-error-code"
(get (run "catch {return -code error oops} r") :result)
"1")
(ok "return-code-error-val"
(tcl-var-get (run "catch {return -code error oops} r") "r")
"oops")
; --- return -code ok ---
(ok "return-code-ok"
(get (run "catch {return -code ok hello} r") :result)
"0")
(ok "return-code-ok-val"
(tcl-var-get (run "catch {return -code ok hello} r") "r")
"hello")
; --- return -code break ---
(ok "return-code-break"
(get (run "catch {return -code break} r") :result)
"3")
; --- return -code continue ---
(ok "return-code-continue"
(get (run "catch {return -code continue} r") :result)
"4")
; --- return -code numeric ---
(ok "return-code-numeric-5"
(get (run "catch {return -code 5 msg} r") :result)
"5")
; --- return plain still code 2 (catch sees raw return code) ---
(ok "return-plain-code"
(get (run "catch {return hello} r") :result)
"2")
(ok "return-plain-val"
(tcl-var-get (run "catch {return hello} r") "r")
"hello")
; --- proc return -code error ---
(ok "proc-return-code-error"
(get (run "proc p {} {return -code error bad}\ncatch {p} r") :result)
"1")
(ok "proc-return-code-error-val"
(tcl-var-get (run "proc p {} {return -code error bad}\ncatch {p} r") "r")
"bad")
; --- error with info/code args ---
(ok? "error-errorinfo-stored"
(let
((i (run "catch {error msg myinfo mycode} r")))
(= (get i :code) 0)))
; --- throw ---
(ok "throw-code" (get (run "catch {throw MYERR something} r") :result) "1")
(ok "throw-msg" (tcl-var-get (run "catch {throw MYERR something} r") "r") "something")
; --- try basic ok ---
(ok "try-ok-result"
(get (run "try {set x hello} on ok {r} {set r2 $r}") :result)
"hello")
; --- try on error ---
(ok "try-on-error-handled"
(get (run "try {error boom} on error {e} {set caught $e}") :result)
"boom")
(ok "try-on-error-var"
(tcl-var-get (run "try {error boom} on error {e} {set caught $e}") "caught")
"boom")
; --- try finally always runs ---
(ok "try-finally-ok"
(tcl-var-get (run "try {set x 1} finally {set done yes}") "done")
"yes")
(ok "try-finally-error"
(tcl-var-get (run "catch {try {error boom} finally {set done yes}} r") "done")
"yes")
; --- try on error + finally ---
(ok "try-error-finally"
(tcl-var-get
(run "try {error oops} on error {e} {set caught $e} finally {set cleaned yes}")
"cleaned")
"yes")
(ok "try-error-finally-caught"
(tcl-var-get
(run "try {error oops} on error {e} {set caught $e} finally {set cleaned yes}")
"caught")
"oops")
; --- try on ok and on error ---
(ok "try-multi-clause-ok"
(tcl-var-get
(run "try {set x 1} on ok {r} {set which ok} on error {e} {set which err}")
"which")
"ok")
(ok "try-multi-clause-err"
(tcl-var-get
(run "try {error boom} on ok {r} {set which ok} on error {e} {set which err}")
"which")
"err")
; --- catch preserves output ---
(ok "catch-output-preserved"
(get (run "puts -nonewline before\ncatch {puts -nonewline inside\nerror oops}\nputs -nonewline after")
:output)
"beforeinsideafter")
(dict
"passed"
tcl-err-pass
"failed"
tcl-err-fail
"failures"
tcl-err-failures)))

338
lib/tcl/tests/eval.sx
View File

@@ -1,338 +0,0 @@
; Tcl-on-SX eval tests
(define tcl-eval-pass 0)
(define tcl-eval-fail 0)
(define tcl-eval-failures (list))
(define
tcl-eval-assert
(fn
(label expected actual)
(if
(equal? expected actual)
(set! tcl-eval-pass (+ tcl-eval-pass 1))
(begin
(set! tcl-eval-fail (+ tcl-eval-fail 1))
(append!
tcl-eval-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define
tcl-run-eval-tests
(fn
()
(set! tcl-eval-pass 0)
(set! tcl-eval-fail 0)
(set! tcl-eval-failures (list))
(define interp (fn () (make-default-tcl-interp)))
(define run (fn (src) (tcl-eval-string (interp) src)))
(define
ok
(fn (label actual expected) (tcl-eval-assert label expected actual)))
(define
ok?
(fn (label condition) (tcl-eval-assert label true condition)))
(tcl-eval-assert "set-result" "hello" (get (run "set x hello") :result))
(tcl-eval-assert
"set-stored"
"hello"
(tcl-var-get (run "set x hello") "x"))
(tcl-eval-assert
"var-sub"
"hello"
(tcl-var-get (run "set x hello\nset y $x") "y"))
(tcl-eval-assert
"puts"
"world\n"
(get (run "set x world\nputs $x") :output))
(tcl-eval-assert
"puts-nonewline"
"hi"
(get (run "puts -nonewline hi") :output))
(tcl-eval-assert "incr" "6" (tcl-var-get (run "set x 5\nincr x") "x"))
(tcl-eval-assert
"incr-delta"
"8"
(tcl-var-get (run "set x 5\nincr x 3") "x"))
(tcl-eval-assert
"incr-neg"
"7"
(tcl-var-get (run "set x 10\nincr x -3") "x"))
(tcl-eval-assert
"append"
"foobar"
(tcl-var-get (run "set x foo\nappend x bar") "x"))
(tcl-eval-assert
"append-new"
"hello"
(tcl-var-get (run "append x hello") "x"))
(tcl-eval-assert
"cmdsub-result"
"6"
(get (run "set x 5\nset y [incr x]") :result))
(tcl-eval-assert
"cmdsub-y"
"6"
(tcl-var-get (run "set x 5\nset y [incr x]") "y"))
(tcl-eval-assert
"cmdsub-x"
"6"
(tcl-var-get (run "set x 5\nset y [incr x]") "x"))
(tcl-eval-assert
"multi-cmd"
"second"
(get (run "set x first\nset x second") :result))
(tcl-eval-assert "semi-x" "1" (tcl-var-get (run "set x 1; set y 2") "x"))
(tcl-eval-assert "semi-y" "2" (tcl-var-get (run "set x 1; set y 2") "y"))
(tcl-eval-assert
"braced-nosub"
"$x"
(tcl-var-get (run "set x 42\nset y {$x}") "y"))
(tcl-eval-assert
"concat-word"
"foobar"
(tcl-var-get (run "set x foo\nset y ${x}bar") "y"))
(tcl-eval-assert
"set-get"
"world"
(get (run "set x world\nset x") :result))
(tcl-eval-assert
"puts-channel"
"hello\n"
(get (run "puts stdout hello") :output))
(ok "if-true" (get (run "set x 0\nif {1} {set x 1}") :result) "1")
(ok "if-false" (get (run "set x 0\nif {0} {set x 1}") :result) "0")
(ok
"if-else-t"
(tcl-var-get (run "if {1} {set x yes} else {set x no}") "x")
"yes")
(ok
"if-else-f"
(tcl-var-get (run "if {0} {set x yes} else {set x no}") "x")
"no")
(ok
"if-cmp"
(tcl-var-get
(run "set x 5\nif {$x > 3} {set r big} else {set r small}")
"r")
"big")
(ok
"while"
(tcl-var-get
(run "set i 0\nset s 0\nwhile {$i < 5} {incr i\nincr s $i}")
"s")
"15")
(ok
"while-break"
(tcl-var-get
(run "set i 0\nwhile {1} {incr i\nif {$i == 3} {break}}")
"i")
"3")
(ok
"for"
(tcl-var-get
(run "set s 0\nfor {set i 1} {$i <= 5} {incr i} {incr s $i}")
"s")
"15")
(ok
"foreach"
(tcl-var-get (run "set s 0\nforeach x {1 2 3 4 5} {incr s $x}") "s")
"15")
(ok
"foreach-list"
(get (run "set acc \"\"\nforeach w {hello world} {append acc $w}") :result)
"helloworld")
(ok
"lappend"
(tcl-var-get (run "lappend lst a\nlappend lst b\nlappend lst c") "lst")
"a b c")
(ok?
"unset-gone"
(let
((i (run "set x 42\nunset x")))
(let
((frame (get i :frame)))
(nil? (get (get frame :locals) "x")))))
(ok "eval" (tcl-var-get (run "eval {set x hello}") "x") "hello")
(ok "expr-precedence" (get (run "expr {3 + 4 * 2}") :result) "11")
(ok "expr-parens" (get (run "expr {(3 + 4) * 2}") :result) "14")
(ok "expr-unary-minus" (get (run "expr {-5}") :result) "-5")
(ok "expr-unary-not-0" (get (run "expr {!0}") :result) "1")
(ok "expr-unary-not-1" (get (run "expr {!1}") :result) "0")
(ok "expr-power" (get (run "expr {2 ** 10}") :result) "1024")
(ok "expr-le" (get (run "expr {3 <= 3}") :result) "1")
(ok "expr-ge" (get (run "expr {4 >= 5}") :result) "0")
(ok "expr-and" (get (run "expr {1 && 1}") :result) "1")
(ok "expr-or" (get (run "expr {0 || 1}") :result) "1")
(ok "expr-var-sub" (get (run "set x 7\nexpr {$x * 3}") :result) "21")
(ok "expr-abs-neg" (get (run "expr {abs(-3)}") :result) "3")
(ok "expr-abs-pos" (get (run "expr {abs(5)}") :result) "5")
(ok "expr-pow-fn" (get (run "expr {pow(2, 8)}") :result) "256")
(ok "expr-max" (get (run "expr {max(3, 7)}") :result) "7")
(ok "expr-min" (get (run "expr {min(3, 7)}") :result) "3")
(ok "expr-sqrt-9" (get (run "expr {sqrt(9)}") :result) "3")
(ok "expr-sqrt-16" (get (run "expr {sqrt(16)}") :result) "4")
(ok "expr-mod" (get (run "expr {17 % 5}") :result) "2")
(ok "expr-nospace" (get (run "expr {3+4*2}") :result) "11")
(ok "expr-add" (get (run "expr {3 + 4}") :result) "7")
(ok "expr-cmp" (get (run "expr {5 > 3}") :result) "1")
(ok
"break-stops"
(tcl-var-get (run "set x 0\nwhile {1} {set x 1\nbreak\nset x 99}") "x")
"1")
(ok
"continue"
(tcl-var-get
(run
"set s 0\nfor {set i 1} {$i <= 5} {incr i} {if {$i == 3} {continue}\nincr s $i}")
"s")
"12")
(ok
"switch"
(tcl-var-get
(run "set x foo\nswitch $x {{foo} {set r yes} {bar} {set r no}}")
"r")
"yes")
(ok
"switch-default"
(tcl-var-get
(run "set x baz\nswitch $x {{foo} {set r yes} default {set r other}}")
"r")
"other")
(ok
"nested-if"
(tcl-var-get
(run
"set x 5\nif {$x > 10} {set r big} elseif {$x > 3} {set r mid} else {set r small}")
"r")
"mid")
(ok "str-length" (get (run "string length hello") :result) "5")
(ok "str-length-empty" (get (run "string length {}") :result) "0")
(ok "str-index" (get (run "string index hello 1") :result) "e")
(ok "str-index-oob" (get (run "string index hello 99") :result) "")
(ok "str-range" (get (run "string range hello 1 3") :result) "ell")
(ok "str-range-clamp" (get (run "string range hello 3 99") :result) "lo")
(ok "str-compare-eq" (get (run "string compare abc abc") :result) "0")
(ok "str-compare-lt" (get (run "string compare abc abd") :result) "-1")
(ok "str-compare-gt" (get (run "string compare b a") :result) "1")
(ok "str-match-star" (get (run "string match h*o hello") :result) "1")
(ok "str-match-q" (get (run "string match h?llo hello") :result) "1")
(ok "str-match-no" (get (run "string match h*x hello") :result) "0")
(ok "str-toupper" (get (run "string toupper hello") :result) "HELLO")
(ok "str-tolower" (get (run "string tolower WORLD") :result) "world")
(ok "str-trim" (get (run "string trim { hi }") :result) "hi")
(ok "str-trimleft" (get (run "string trimleft { hi }") :result) "hi ")
(ok "str-trimright" (get (run "string trimright { hi }") :result) " hi")
(ok "str-trim-chars" (get (run "string trim {xxhelloxx} x") :result) "hello")
(ok "str-map" (get (run "string map {a X b Y} {abc}") :result) "XYc")
(ok "str-repeat" (get (run "string repeat ab 3") :result) "ababab")
(ok "str-first" (get (run "string first ll hello") :result) "2")
(ok "str-first-miss" (get (run "string first z hello") :result) "-1")
(ok "str-last" (get (run "string last l hello") :result) "3")
(ok "str-is-int" (get (run "string is integer 42") :result) "1")
(ok "str-is-not-int" (get (run "string is integer foo") :result) "0")
(ok "str-is-alpha" (get (run "string is alpha hello") :result) "1")
(ok "str-is-alpha-no" (get (run "string is alpha hello1") :result) "0")
(ok "str-is-boolean" (get (run "string is boolean true") :result) "1")
(ok "str-cat" (get (run "string cat foo bar baz") :result) "foobarbaz")
; --- list command tests ---
(ok "list-simple" (get (run "list a b c") :result) "a b c")
(ok "list-brace-elem" (get (run "list {a b} c") :result) "{a b} c")
(ok "list-empty" (get (run "list") :result) "")
(ok "lindex-1" (get (run "lindex {a b c} 1") :result) "b")
(ok "lindex-0" (get (run "lindex {a b c} 0") :result) "a")
(ok "lindex-oob" (get (run "lindex {a b c} 5") :result) "")
(ok "lrange" (get (run "lrange {a b c d} 1 2") :result) "b c")
(ok "lrange-full" (get (run "lrange {a b c} 0 end") :result) "a b c")
(ok "llength" (get (run "llength {a b c}") :result) "3")
(ok "llength-empty" (get (run "llength {}") :result) "0")
(ok "lreverse" (get (run "lreverse {1 2 3}") :result) "3 2 1")
(ok "lsearch-found" (get (run "lsearch {a b c} b") :result) "1")
(ok "lsearch-missing" (get (run "lsearch {a b c} z") :result) "-1")
(ok "lsearch-exact" (get (run "lsearch -exact {foo bar} foo") :result) "0")
(ok "lsort-asc" (get (run "lsort {banana apple cherry}") :result) "apple banana cherry")
(ok "lsort-int" (get (run "lsort -integer {10 2 30 5}") :result) "2 5 10 30")
(ok "lsort-dec" (get (run "lsort -decreasing {c a b}") :result) "c b a")
(ok "lreplace" (get (run "lreplace {a b c d} 1 2 X Y") :result) "a X Y d")
(ok "linsert" (get (run "linsert {a b c} 1 X Y") :result) "a X Y b c")
(ok "linsert-end" (get (run "linsert {a b} end Z") :result) "a b Z")
(ok "concat" (get (run "concat {a b} {c d}") :result) "a b c d")
(ok "split-sep" (get (run "split {a:b:c} :") :result) "a b c")
(ok "split-ws" (get (run "split {a b c}") :result) "a b c")
(ok "join-sep" (get (run "join {a b c} -") :result) "a-b-c")
(ok "join-default" (get (run "join {a b c}") :result) "a b c")
(ok "list-var" (get (run "set L {x y z}\nllength $L") :result) "3")
; --- dict command tests ---
(ok "dict-create" (get (run "dict create a 1 b 2") :result) "a 1 b 2")
(ok "dict-create-empty" (get (run "dict create") :result) "")
(ok "dict-get" (get (run "dict get {a 1 b 2} a") :result) "1")
(ok "dict-get-b" (get (run "dict get {a 1 b 2} b") :result) "2")
(ok "dict-exists-yes" (get (run "dict exists {a 1 b 2} a") :result) "1")
(ok "dict-exists-no" (get (run "dict exists {a 1 b 2} z") :result) "0")
(ok "dict-set-new" (get (run "set d {}\ndict set d x 42") :result) "x 42")
(ok "dict-set-update" (get (run "set d {a 1 b 2}\ndict set d a 99") :result) "a 99 b 2")
(ok "dict-set-stored" (tcl-var-get (run "set d {a 1}\ndict set d b 2") "d") "a 1 b 2")
(ok "dict-unset" (get (run "set d {a 1 b 2}\ndict unset d a") :result) "b 2")
(ok "dict-unset-stored" (tcl-var-get (run "set d {a 1 b 2}\ndict unset d a") "d") "b 2")
(ok "dict-keys" (get (run "dict keys {a 1 b 2}") :result) "a b")
(ok "dict-keys-pattern" (get (run "dict keys {abc 1 abd 2 xyz 3} ab*") :result) "abc abd")
(ok "dict-values" (get (run "dict values {a 1 b 2}") :result) "1 2")
(ok "dict-size" (get (run "dict size {a 1 b 2 c 3}") :result) "3")
(ok "dict-size-empty" (get (run "dict size {}") :result) "0")
(ok "dict-for" (tcl-var-get (run "set acc {}\ndict for {k v} {a 1 b 2} {append acc $k$v}") "acc") "a1b2")
(ok "dict-merge-disjoint" (get (run "dict merge {a 1} {b 2}") :result) "a 1 b 2")
(ok "dict-merge-overlap" (get (run "dict merge {a 1 b 2} {b 99}") :result) "a 1 b 99")
(ok "dict-incr-existing" (get (run "set d {x 5}\ndict incr d x") :result) "x 6")
(ok "dict-incr-delta" (get (run "set d {x 5}\ndict incr d x 3") :result) "x 8")
(ok "dict-incr-missing" (get (run "set d {}\ndict incr d n") :result) "n 1")
(ok "dict-append" (get (run "set d {x hello}\ndict append d x _hi") :result) "x hello_hi")
(ok "dict-append-new" (get (run "set d {}\ndict append d k val") :result) "k val")
; --- proc tests ---
(ok "proc-basic" (get (run "proc add {a b} {expr {$a + $b}}\nadd 3 4") :result) "7")
(ok "proc-return" (get (run "proc greet {name} {set msg \"hi $name\"\nreturn $msg}\ngreet World") :result) "hi World")
(ok "proc-factorial" (get (run "proc factorial {n} {if {$n <= 1} {return 1}\nexpr {$n * [factorial [expr {$n - 1}]]}}\nfactorial 5") :result) "120")
(ok "proc-args" (get (run "proc sum args {set t 0\nforeach x $args {incr t $x}\nreturn $t}\nsum 1 2 3 4") :result) "10")
(ok "proc-isolated" (get (run "set x outer\nproc p {} {set x inner\nreturn $x}\np") :result) "inner")
(ok "proc-caller-unchanged" (tcl-var-get (run "set x outer\nproc p {} {set x inner\nreturn $x}\np\nset dummy 1") "x") "outer")
(ok "proc-output" (get (run "proc hello {} {puts -nonewline hi}\nhello") :output) "hi")
; --- upvar tests ---
(ok "upvar-incr" (tcl-var-get (run "proc incr2 {varname} {upvar 1 $varname v\nincr v}\nset counter 10\nincr2 counter\nset counter") "counter") "11")
(ok "upvar-double" (tcl-var-get (run "proc double-it {varname} {upvar 1 $varname x\nset x [expr {$x * 2}]}\nset val 5\ndouble-it val\nset val") "val") "10")
(ok "upvar-result" (get (run "proc double-it {varname} {upvar 1 $varname x\nset x [expr {$x * 2}]}\nset val 5\ndouble-it val\nset val") :result) "10")
; --- uplevel tests ---
(ok "uplevel-set" (tcl-var-get (run "proc setvar {name val} {uplevel 1 \"set $name $val\"}\nsetvar x 99\nset x") "x") "99")
(ok "uplevel-get" (get (run "proc getvar {name} {uplevel 1 \"set $name\"}\nset y 77\ngetvar y") :result) "77")
; --- global tests ---
(ok "global-read" (get (run "set g 100\nproc getg {} {global g\nreturn $g}\ngetg") :result) "100")
(ok "global-write" (tcl-var-get (run "set g 0\nproc bumping {} {global g\nincr g}\nbumping\nbumping\nset g") "g") "2")
; --- info tests ---
(ok "info-level-0" (get (run "info level") :result) "0")
(ok "info-level-proc" (get (run "proc p {} {info level}\np") :result) "1")
(ok "info-procs" (let ((r (get (run "proc myfn {} {}\ninfo procs") :result))) (contains? (tcl-list-split r) "myfn")) true)
(ok "info-args" (get (run "proc add {a b} {expr {$a+$b}}\ninfo args add") :result) "a b")
(ok "info-commands-has-set" (let ((r (get (run "info commands") :result))) (contains? (tcl-list-split r) "set")) true)
; --- classic programs ---
(ok
"classic-for-each-line"
(get
(run "proc for-each-line {var lines body} {\n foreach item $lines {\n uplevel 1 [list set $var $item]\n uplevel 1 $body\n }\n}\nset total 0\nfor-each-line line {hello world foo} {\n incr total [string length $line]\n}\nset total")
:result)
"13")
(ok
"classic-assert"
(get
(run "proc assert {expr_str} {\n set result [uplevel 1 [list expr $expr_str]]\n if {!$result} {\n error \"Assertion failed: $expr_str\"\n }\n}\nset x 42\nassert {$x == 42}\nassert {$x > 0}\nset x 10\nassert {$x < 100}\nset x")
:result)
"10")
(ok
"classic-with-temp-var"
(get
(run "proc with-temp-var {varname tempval body} {\n upvar 1 $varname v\n set saved $v\n set v $tempval\n uplevel 1 $body\n set v $saved\n}\nset x 100\nwith-temp-var x 999 {\n set captured $x\n}\nlist $x $captured")
:result)
"100 999")
(dict
"passed"
tcl-eval-pass
"failed"
tcl-eval-fail
"failures"
tcl-eval-failures)))

193
lib/tcl/tests/idioms.sx
View File

@@ -1,193 +0,0 @@
; Tcl-on-SX idiom corpus (Phase 6)
; Classic Tcl idioms covering lists, dicts, procs, patterns
(define tcl-idiom-pass 0)
(define tcl-idiom-fail 0)
(define tcl-idiom-failures (list))
(define
tcl-idiom-assert
(fn
(label expected actual)
(if
(equal? expected actual)
(set! tcl-idiom-pass (+ tcl-idiom-pass 1))
(begin
(set! tcl-idiom-fail (+ tcl-idiom-fail 1))
(append!
tcl-idiom-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define
tcl-run-idiom-tests
(fn
()
(set! tcl-idiom-pass 0)
(set! tcl-idiom-fail 0)
(set! tcl-idiom-failures (list))
(define interp (fn () (make-default-tcl-interp)))
(define run (fn (src) (tcl-eval-string (interp) src)))
(define
ok
(fn (label actual expected) (tcl-idiom-assert label expected actual)))
; 1. lmap idiom: accumulate mapped values with foreach+lappend
(ok "idiom-lmap"
(get
(run "set result {}\nforeach x {1 2 3} { lappend result [expr {$x * $x}] }\nset result")
:result)
"1 4 9")
; 2. Recursive list flatten
(ok "idiom-flatten"
(get
(run
"proc flatten {lst} { set out {}\n foreach item $lst {\n if {[llength $item] > 1} {\n foreach sub [flatten $item] { lappend out $sub }\n } else {\n lappend out $item\n }\n }\n return $out\n}\nflatten {1 {2 3} {4 {5 6}}}")
:result)
"1 2 3 4 5 6")
; 3. String builder accumulator
(ok "idiom-string-builder"
(get
(run "set buf \"\"\nforeach w {Hello World Tcl} { append buf $w \" \" }\nstring trimright $buf")
:result)
"Hello World Tcl")
; 4. Default parameter via info exists
(ok "idiom-default-param"
(get
(run "if {![info exists x]} { set x 42 }\nset x")
:result)
"42")
; 5. Association list lookup (parallel key/value lists)
(ok "idiom-alist-lookup"
(get
(run
"set keys {a b c}\nset vals {10 20 30}\nset idx [lsearch $keys b]\nlindex $vals $idx")
:result)
"20")
; 6. Proc with optional args via args
(ok "idiom-optional-args"
(get
(run
"proc greet {name args} {\n set greeting \"Hello\"\n if {[llength $args] > 0} { set greeting [lindex $args 0] }\n return \"$greeting $name\"\n}\ngreet World Hi")
:result)
"Hi World")
; 7. Builder pattern: dict create from args
(ok "idiom-dict-builder"
(get
(run
"proc build-dict {args} { dict create {*}$args }\ndict get [build-dict name Alice age 30] name")
:result)
"Alice")
; 8. Loop with index using array
(ok "idiom-loop-with-index"
(get
(run
"set i 0\nforeach x {a b c} { set arr($i) $x; incr i }\nset arr(1)")
:result)
"b")
; 9. String reverse via split+lreverse+join
(ok "idiom-string-reverse"
(get
(run
"set s hello\nset chars [split $s \"\"]\nset rev [lreverse $chars]\njoin $rev \"\"")
:result)
"olleh")
; 10. Number to padded string
(ok "idiom-number-format"
(get (run "format \"%05d\" 42") :result)
"00042")
; 11. Dict comprehension pattern
(ok "idiom-dict-comprehension"
(get
(run
"set squares {}\nforeach n {1 2 3 4} { dict set squares $n [expr {$n * $n}] }\ndict get $squares 3")
:result)
"9")
; 12. Stack ADT using list: push/pop
(ok "idiom-stack"
(get
(run
"proc stack-push {stackvar val} { upvar $stackvar s; lappend s $val }\nproc stack-pop {stackvar} { upvar $stackvar s; set val [lindex $s end]; set s [lrange $s 0 end-1]; return $val }\nset stk {}\nstack-push stk 10\nstack-push stk 20\nstack-push stk 30\nstack-pop stk")
:result)
"30")
; 13. Queue ADT using list: enqueue/dequeue
(ok "idiom-queue"
(get
(run
"proc q-enq {qvar val} { upvar $qvar q; lappend q $val }\nproc q-deq {qvar} { upvar $qvar q; set val [lindex $q 0]; set q [lrange $q 1 end]; return $val }\nset q {}\nq-enq q alpha\nq-enq q beta\nq-enq q gamma\nq-deq q")
:result)
"alpha")
; 14. Pipeline via proc chaining
(ok "idiom-pipeline"
(get
(run
"proc double {x} { expr {$x * 2} }\nproc add1 {x} { expr {$x + 1} }\nproc pipeline {val procs} { foreach p $procs { set val [$p $val] }; return $val }\npipeline 5 {double add1 double}")
:result)
"22")
; 15. Memoize pattern using dict (simple cache, not recursive)
(ok "idiom-memoize"
(get
(run
"set cache {}\nproc cached-square {n} { global cache\n if {[dict exists $cache $n]} { return [dict get $cache $n] }\n set r [expr {$n * $n}]\n dict set cache $n $r\n return $r\n}\nset a [cached-square 7]\nset b [cached-square 7]\nset c [cached-square 8]\nexpr {$a == $b && $c == 64}")
:result)
"1")
; 16. Simple expression evaluator in Tcl (recursive descent)
(ok "idiom-recursive-eval"
(get
(run
"proc calc {expr} { return [::tcl::mathop::+ 0 [expr $expr]] }\nexpr {3 + 4 * 2}")
:result)
"11")
; 17. Apply proc to each pair in a dict
(ok "idiom-dict-for"
(get
(run
"set d [dict create a 1 b 2 c 3]\nset total 0\ndict for {k v} $d { incr total $v }\nset total")
:result)
"6")
; 18. Find max in list
(ok "idiom-find-max"
(get
(run
"proc list-max {lst} {\n set m [lindex $lst 0]\n foreach x $lst { if {$x > $m} { set m $x } }\n return $m\n}\nlist-max {3 1 4 1 5 9 2 6}")
:result)
"9")
; 19. Filter list by predicate
(ok "idiom-filter-list"
(get
(run
"proc list-filter {lst pred} {\n set out {}\n foreach x $lst { if {[$pred $x]} { lappend out $x } }\n return $out\n}\nproc is-even {n} { expr {$n % 2 == 0} }\nlist-filter {1 2 3 4 5 6} is-even")
:result)
"2 4 6")
; 20. Zip two lists
(ok "idiom-zip"
(get
(run
"proc zip {a b} {\n set out {}\n set n [llength $a]\n for {set i 0} {$i < $n} {incr i} {\n lappend out [lindex $a $i]\n lappend out [lindex $b $i]\n }\n return $out\n}\nzip {1 2 3} {a b c}")
:result)
"1 a 2 b 3 c")
(dict
"passed"
tcl-idiom-pass
"failed"
tcl-idiom-fail
"failures"
tcl-idiom-failures)))

147
lib/tcl/tests/namespace.sx
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@@ -1,147 +0,0 @@
; Tcl-on-SX namespace tests (Phase 5)
(define tcl-ns-pass 0)
(define tcl-ns-fail 0)
(define tcl-ns-failures (list))
(define
tcl-ns-assert
(fn
(label expected actual)
(if
(equal? expected actual)
(set! tcl-ns-pass (+ tcl-ns-pass 1))
(begin
(set! tcl-ns-fail (+ tcl-ns-fail 1))
(append!
tcl-ns-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define
tcl-run-namespace-tests
(fn
()
(set! tcl-ns-pass 0)
(set! tcl-ns-fail 0)
(set! tcl-ns-failures (list))
(define interp (fn () (make-default-tcl-interp)))
(define run (fn (src) (tcl-eval-string (interp) src)))
(define
ok
(fn (label actual expected) (tcl-ns-assert label expected actual)))
(define
ok?
(fn (label condition) (tcl-ns-assert label true condition)))
; --- namespace current ---
(ok "ns-current-global"
(get (run "namespace current") :result)
"::")
; --- namespace eval defines proc ---
(ok "ns-eval-proc-result"
(get (run "namespace eval myns { proc foo {} { return bar } }\nmyns::foo") :result)
"bar")
; --- fully qualified call ---
(ok "ns-qualified-call"
(get (run "namespace eval myns { proc greet {name} { return \"hello $name\" } }\n::myns::greet World") :result)
"hello World")
; --- namespace current inside eval ---
(ok "ns-current-inside"
(get (run "namespace eval myns { namespace current }") :result)
"::myns")
; --- namespace current restored after eval ---
(ok "ns-current-restored"
(get (run "namespace eval myns { set x 1 }\nnamespace current") :result)
"::")
; --- relative call from within namespace ---
(ok "ns-relative-call"
(get (run "namespace eval math {\n proc double {x} { expr {$x * 2} }\n proc quad {x} { double [double $x] }\n}\nmath::quad 3") :result)
"12")
; --- proc defined as qualified name inside namespace eval ---
(ok "ns-qualified-proc-name"
(get (run "namespace eval utils { proc ::utils::helper {x} { return $x } }\n::utils::helper done") :result)
"done")
; --- namespace exists ---
(ok "ns-exists-yes"
(get (run "namespace eval testns { proc p {} {} }\nnamespace exists testns") :result)
"1")
(ok "ns-exists-no"
(get (run "namespace exists nosuchns") :result)
"0")
(ok "ns-exists-global"
(get (run "proc top {} {}\nnamespace exists ::") :result)
"1")
; --- namespace delete ---
(ok "ns-delete-removes"
(get (run "namespace eval todel { proc pp {} { return yes } }\nnamespace delete todel\nnamespace exists todel") :result)
"0")
; --- namespace which ---
(ok "ns-which-found"
(get (run "namespace eval wns { proc wfn {} {} }\nnamespace which -command wns::wfn") :result)
"::wns::wfn")
(ok "ns-which-not-found"
(get (run "namespace which -command nosuchfn") :result)
"")
; --- namespace ensemble create auto-map ---
(ok "ns-ensemble-add"
(get (run "namespace eval mymath {\n proc add {a b} { expr {$a + $b} }\n proc mul {a b} { expr {$a * $b} }\n namespace ensemble create\n}\nmymath add 3 4") :result)
"7")
(ok "ns-ensemble-mul"
(get (run "namespace eval mymath {\n proc add {a b} { expr {$a + $b} }\n proc mul {a b} { expr {$a * $b} }\n namespace ensemble create\n}\nmymath mul 3 4") :result)
"12")
; --- namespace ensemble with -map ---
(ok "ns-ensemble-map"
(get (run "namespace eval ops {\n proc do-add {a b} { expr {$a + $b} }\n namespace ensemble create -map {plus ::ops::do-add}\n}\nops plus 5 6") :result)
"11")
; --- proc inside namespace eval with args ---
(ok "ns-proc-args"
(get (run "namespace eval calc {\n proc sum {a b c} { expr {$a + $b + $c} }\n}\ncalc::sum 1 2 3") :result)
"6")
; --- info procs inside namespace ---
(ok? "ns-info-procs-in-ns"
(let
((r (get (run "namespace eval foo { proc bar {} {} }\nnamespace eval foo { info procs }") :result)))
(contains? (tcl-list-split r) "bar")))
; --- variable inside namespace eval ---
(ok "ns-variable-inside"
(get (run "namespace eval storage {\n variable count 0\n proc bump {} { global count\n incr count\n return $count }\n}\n::storage::bump\n::storage::bump") :result)
"2")
; --- nested namespaces ---
(ok "ns-nested"
(get (run "namespace eval outer {\n namespace eval inner {\n proc greet {} { return nested }\n }\n}\n::outer::inner::greet") :result)
"nested")
; --- namespace eval accumulates procs ---
(ok "ns-eval-accumulate"
(get (run "namespace eval acc { proc f1 {} { return one } }\nnamespace eval acc { proc f2 {} { return two } }\nacc::f1") :result)
"one")
(ok "ns-eval-accumulate-2"
(get (run "namespace eval acc { proc f1 {} { return one } }\nnamespace eval acc { proc f2 {} { return two } }\nacc::f2") :result)
"two")
(dict
"passed"
tcl-ns-pass
"failed"
tcl-ns-fail
"failures"
tcl-ns-failures)))

186
lib/tcl/tests/parse.sx
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@@ -1,186 +0,0 @@
(define tcl-parse-pass 0)
(define tcl-parse-fail 0)
(define tcl-parse-failures (list))
(define tcl-assert
(fn (label expected actual)
(if (= expected actual)
(set! tcl-parse-pass (+ tcl-parse-pass 1))
(begin
(set! tcl-parse-fail (+ tcl-parse-fail 1))
(append! tcl-parse-failures
(str label ": expected=" (str expected) " got=" (str actual)))))))
(define tcl-first-cmd
(fn (src) (nth (tcl-tokenize src) 0)))
(define tcl-cmd-words
(fn (src) (get (tcl-first-cmd src) :words)))
(define tcl-word
(fn (src wi) (nth (tcl-cmd-words src) wi)))
(define tcl-parts
(fn (src wi) (get (tcl-word src wi) :parts)))
(define tcl-part
(fn (src wi pi) (nth (tcl-parts src wi) pi)))
(define tcl-run-parse-tests
(fn ()
(set! tcl-parse-pass 0)
(set! tcl-parse-fail 0)
(set! tcl-parse-failures (list))
; empty / whitespace-only
(tcl-assert "empty" 0 (len (tcl-tokenize "")))
(tcl-assert "ws-only" 0 (len (tcl-tokenize " ")))
(tcl-assert "nl-only" 0 (len (tcl-tokenize "\n\n")))
; single command word count
(tcl-assert "1word" 1 (len (tcl-cmd-words "set")))
(tcl-assert "3words" 3 (len (tcl-cmd-words "set x 1")))
(tcl-assert "4words" 4 (len (tcl-cmd-words "set a b c")))
; word type — bare word is compound
(tcl-assert "bare-type" "compound" (get (tcl-word "set x 1" 0) :type))
(tcl-assert "bare-quoted" false (get (tcl-word "set x 1" 0) :quoted))
(tcl-assert "bare-part-type" "text" (get (tcl-part "set x 1" 0 0) :type))
(tcl-assert "bare-part-val" "set" (get (tcl-part "set x 1" 0 0) :value))
(tcl-assert "bare-part2-val" "x" (get (tcl-part "set x 1" 1 0) :value))
(tcl-assert "bare-part3-val" "1" (get (tcl-part "set x 1" 2 0) :value))
; multiple commands
(tcl-assert "semi-sep" 2 (len (tcl-tokenize "set x 1; set y 2")))
(tcl-assert "nl-sep" 2 (len (tcl-tokenize "set x 1\nset y 2")))
(tcl-assert "multi-nl" 3 (len (tcl-tokenize "a\nb\nc")))
; comments
(tcl-assert "comment-only" 0 (len (tcl-tokenize "# comment")))
(tcl-assert "comment-nl" 0 (len (tcl-tokenize "# comment\n")))
(tcl-assert "comment-then-cmd" 1 (len (tcl-tokenize "# comment\nset x 1")))
(tcl-assert "semi-then-comment" 1 (len (tcl-tokenize "set x 1; # comment")))
; brace-quoted words
(tcl-assert "brace-type" "braced" (get (tcl-word "{hello}" 0) :type))
(tcl-assert "brace-value" "hello" (get (tcl-word "{hello}" 0) :value))
(tcl-assert "brace-spaces" "hello world" (get (tcl-word "{hello world}" 0) :value))
(tcl-assert "brace-nested" "a {b} c" (get (tcl-word "{a {b} c}" 0) :value))
(tcl-assert "brace-no-var-sub" "hello $x" (get (tcl-word "{hello $x}" 0) :value))
(tcl-assert "brace-no-cmd-sub" "[expr 1]" (get (tcl-word "{[expr 1]}" 0) :value))
; double-quoted words
(tcl-assert "dq-type" "compound" (get (tcl-word "\"hello\"" 0) :type))
(tcl-assert "dq-quoted" true (get (tcl-word "\"hello\"" 0) :quoted))
(tcl-assert "dq-literal" "hello" (get (tcl-part "\"hello\"" 0 0) :value))
; variable substitution in bare word
(tcl-assert "var-type" "var" (get (tcl-part "$x" 0 0) :type))
(tcl-assert "var-name" "x" (get (tcl-part "$x" 0 0) :name))
(tcl-assert "var-long" "long_name" (get (tcl-part "$long_name" 0 0) :name))
; ${name} form
(tcl-assert "var-brace-type" "var" (get (tcl-part "${x}" 0 0) :type))
(tcl-assert "var-brace-name" "x" (get (tcl-part "${x}" 0 0) :name))
; array variable substitution
(tcl-assert "arr-type" "var-arr" (get (tcl-part "$arr(key)" 0 0) :type))
(tcl-assert "arr-name" "arr" (get (tcl-part "$arr(key)" 0 0) :name))
(tcl-assert "arr-key-len" 1 (len (get (tcl-part "$arr(key)" 0 0) :key)))
(tcl-assert "arr-key-text" "key"
(get (nth (get (tcl-part "$arr(key)" 0 0) :key) 0) :value))
; command substitution
(tcl-assert "cmd-type" "cmd" (get (tcl-part "[expr 1+1]" 0 0) :type))
(tcl-assert "cmd-src" "expr 1+1" (get (tcl-part "[expr 1+1]" 0 0) :src))
; nested command substitution
(tcl-assert "cmd-nested-src" "expr [string length x]"
(get (tcl-part "[expr [string length x]]" 0 0) :src))
; backslash substitution in double-quoted word
(let ((ps (tcl-parts "\"a\\nb\"" 0)))
(begin
(tcl-assert "bs-n-part0" "a" (get (nth ps 0) :value))
(tcl-assert "bs-n-part1" "\n" (get (nth ps 1) :value))
(tcl-assert "bs-n-part2" "b" (get (nth ps 2) :value))))
(let ((ps (tcl-parts "\"a\\tb\"" 0)))
(tcl-assert "bs-t-part1" "\t" (get (nth ps 1) :value)))
(let ((ps (tcl-parts "\"a\\\\b\"" 0)))
(tcl-assert "bs-bs-part1" "\\" (get (nth ps 1) :value)))
; mixed word: text + var + text in double-quoted
(let ((ps (tcl-parts "\"hello $name!\"" 0)))
(begin
(tcl-assert "mixed-text0" "hello " (get (nth ps 0) :value))
(tcl-assert "mixed-var1-type" "var" (get (nth ps 1) :type))
(tcl-assert "mixed-var1-name" "name" (get (nth ps 1) :name))
(tcl-assert "mixed-text2" "!" (get (nth ps 2) :value))))
; {*} expansion
(tcl-assert "expand-type" "expand" (get (tcl-word "{*}$list" 0) :type))
; line continuation between words
(tcl-assert "cont-words" 3 (len (tcl-cmd-words "set x \\\n 1")))
; continuation — third command word is correct
(tcl-assert "cont-word2-val" "1"
(get (tcl-part "set x \\\n 1" 2 0) :value))
; --- parser helpers ---
; tcl-parse is an alias for tcl-tokenize
(tcl-assert "parse-cmd-count" 1 (len (tcl-parse "set x 1")))
(tcl-assert "parse-2cmds" 2 (len (tcl-parse "set x 1; set y 2")))
; tcl-cmd-len
(tcl-assert "cmd-len-3" 3 (tcl-cmd-len (nth (tcl-parse "set x 1") 0)))
(tcl-assert "cmd-len-1" 1 (tcl-cmd-len (nth (tcl-parse "puts") 0)))
; tcl-word-simple? on braced word
(tcl-assert "simple-braced" true
(tcl-word-simple? (nth (get (nth (tcl-parse "{hello}") 0) :words) 0)))
; tcl-word-simple? on bare word with no subs
(tcl-assert "simple-bare" true
(tcl-word-simple? (nth (get (nth (tcl-parse "hello") 0) :words) 0)))
; tcl-word-simple? on word containing a var sub — false
(tcl-assert "simple-var-false" false
(tcl-word-simple? (nth (get (nth (tcl-parse "$x") 0) :words) 0)))
; tcl-word-simple? on word containing a cmd sub — false
(tcl-assert "simple-cmd-false" false
(tcl-word-simple? (nth (get (nth (tcl-parse "[expr 1]") 0) :words) 0)))
; tcl-word-literal on braced word
(tcl-assert "lit-braced" "hello world"
(tcl-word-literal (nth (get (nth (tcl-parse "{hello world}") 0) :words) 0)))
; tcl-word-literal on bare word
(tcl-assert "lit-bare" "hello"
(tcl-word-literal (nth (get (nth (tcl-parse "hello") 0) :words) 0)))
; tcl-word-literal on word with var sub returns nil
(tcl-assert "lit-var-nil" nil
(tcl-word-literal (nth (get (nth (tcl-parse "$x") 0) :words) 0)))
; tcl-nth-literal
(tcl-assert "nth-lit-0" "set"
(tcl-nth-literal (nth (tcl-parse "set x 1") 0) 0))
(tcl-assert "nth-lit-1" "x"
(tcl-nth-literal (nth (tcl-parse "set x 1") 0) 1))
(tcl-assert "nth-lit-2" "1"
(tcl-nth-literal (nth (tcl-parse "set x 1") 0) 2))
; tcl-nth-literal returns nil when word has subs
(tcl-assert "nth-lit-nil" nil
(tcl-nth-literal (nth (tcl-parse "set x $y") 0) 2))
(dict
"passed" tcl-parse-pass
"failed" tcl-parse-fail
"failures" tcl-parse-failures)))

14
lib/tcl/tests/programs/assert.tcl
View File

@@ -1,14 +0,0 @@
# expected: 10
proc assert {expr_str} {
set result [uplevel 1 [list expr $expr_str]]
if {!$result} {
error "Assertion failed: $expr_str"
}
}
set x 42
assert {$x == 42}
assert {$x > 0}
set x 10
assert {$x < 100}
set x

22
lib/tcl/tests/programs/event-loop.tcl
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@@ -1,22 +0,0 @@
# expected: done
# Cooperative scheduler demo using coroutines (generator style)
# coroutine eagerly collects all yields; invoking the coroutine name pops values
proc counter {n max} {
while {$n < $max} {
yield $n
incr n
}
yield done
}
coroutine gen1 counter 0 3
# gen1 yields: 0 1 2 done
set out {}
for {set i 0} {$i < 4} {incr i} {
lappend out [gen1]
}
# last val is "done"
lindex $out 3

14
lib/tcl/tests/programs/for-each-line.tcl
View File

@@ -1,14 +0,0 @@
# expected: 13
proc for-each-line {var lines body} {
foreach item $lines {
uplevel 1 [list set $var $item]
uplevel 1 $body
}
}
# Usage: accumulate lengths of each "line"
set total 0
for-each-line line {hello world foo} {
incr total [string length $line]
}
set total

14
lib/tcl/tests/programs/with-temp-var.tcl
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@@ -1,14 +0,0 @@
# expected: 100 999
proc with-temp-var {varname tempval body} {
upvar 1 $varname v
set saved $v
set v $tempval
uplevel 1 $body
set v $saved
}
set x 100
with-temp-var x 999 {
set captured $x
}
list $x $captured

308
lib/tcl/tokenizer.sx
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@@ -1,308 +0,0 @@
(define tcl-ws? (fn (c) (or (= c " ") (= c "\t") (= c "\r"))))
(define tcl-alpha?
(fn (c)
(and
(not (= c nil))
(or (and (>= c "a") (<= c "z")) (and (>= c "A") (<= c "Z"))))))
(define tcl-digit?
(fn (c) (and (not (= c nil)) (>= c "0") (<= c "9"))))
(define tcl-ident-start?
(fn (c) (or (tcl-alpha? c) (= c "_"))))
(define tcl-ident-char?
(fn (c) (or (tcl-ident-start? c) (tcl-digit? c))))
(define tcl-tokenize
(fn (src)
(let ((pos 0) (src-len (len src)) (commands (list)))
(define char-at
(fn (off)
(if (< (+ pos off) src-len) (nth src (+ pos off)) nil)))
(define cur (fn () (char-at 0)))
(define advance! (fn (n) (set! pos (+ pos n))))
(define skip-ws!
(fn ()
(when (tcl-ws? (cur))
(begin (advance! 1) (skip-ws!)))))
(define skip-to-eol!
(fn ()
(when (and (< pos src-len) (not (= (cur) "\n")))
(begin (advance! 1) (skip-to-eol!)))))
(define skip-brace-content!
(fn (d)
(when (and (< pos src-len) (> d 0))
(cond
((= (cur) "{") (begin (advance! 1) (skip-brace-content! (+ d 1))))
((= (cur) "}") (begin (advance! 1) (skip-brace-content! (- d 1))))
(else (begin (advance! 1) (skip-brace-content! d)))))))
(define skip-dquote-content!
(fn ()
(when (and (< pos src-len) (not (= (cur) "\"")))
(begin
(when (= (cur) "\\") (advance! 1))
(when (< pos src-len) (advance! 1))
(skip-dquote-content!)))))
(define parse-bs
(fn ()
(advance! 1)
(let ((c (cur)))
(cond
((= c nil) "\\")
((= c "n") (begin (advance! 1) "\n"))
((= c "t") (begin (advance! 1) "\t"))
((= c "r") (begin (advance! 1) "\r"))
((= c "\\") (begin (advance! 1) "\\"))
((= c "[") (begin (advance! 1) "["))
((= c "]") (begin (advance! 1) "]"))
((= c "{") (begin (advance! 1) "{"))
((= c "}") (begin (advance! 1) "}"))
((= c "$") (begin (advance! 1) "$"))
((= c ";") (begin (advance! 1) ";"))
((= c "\"") (begin (advance! 1) "\""))
((= c "'") (begin (advance! 1) "'"))
((= c " ") (begin (advance! 1) " "))
((= c "\n")
(begin
(advance! 1)
(skip-ws!)
" "))
(else (begin (advance! 1) (str "\\" c)))))))
(define parse-cmd-sub
(fn ()
(advance! 1)
(let ((start pos) (depth 1))
(define scan!
(fn ()
(when (and (< pos src-len) (> depth 0))
(cond
((= (cur) "[")
(begin (set! depth (+ depth 1)) (advance! 1) (scan!)))
((= (cur) "]")
(begin
(set! depth (- depth 1))
(when (> depth 0) (advance! 1))
(scan!)))
((= (cur) "{")
(begin (advance! 1) (skip-brace-content! 1) (scan!)))
((= (cur) "\"")
(begin
(advance! 1)
(skip-dquote-content!)
(when (= (cur) "\"") (advance! 1))
(scan!)))
((= (cur) "\\")
(begin (advance! 1) (when (< pos src-len) (advance! 1)) (scan!)))
(else (begin (advance! 1) (scan!)))))))
(scan!)
(let ((src-text (slice src start pos)))
(begin
(when (= (cur) "]") (advance! 1))
{:type "cmd" :src src-text})))))
(define scan-name!
(fn ()
(when (and (< pos src-len) (not (= (cur) "}")))
(begin (advance! 1) (scan-name!)))))
(define scan-ns-name!
(fn ()
(cond
((tcl-ident-char? (cur))
(begin (advance! 1) (scan-ns-name!)))
((and (= (cur) ":") (= (char-at 1) ":"))
(begin (advance! 2) (scan-ns-name!)))
(else nil))))
(define scan-klit!
(fn ()
(when (and (< pos src-len)
(not (= (cur) ")"))
(not (= (cur) "$"))
(not (= (cur) "["))
(not (= (cur) "\\")))
(begin (advance! 1) (scan-klit!)))))
(define scan-key!
(fn (kp)
(when (and (< pos src-len) (not (= (cur) ")")))
(cond
((= (cur) "$")
(begin (append! kp (parse-var-sub)) (scan-key! kp)))
((= (cur) "[")
(begin (append! kp (parse-cmd-sub)) (scan-key! kp)))
((= (cur) "\\")
(begin
(append! kp {:type "text" :value (parse-bs)})
(scan-key! kp)))
(else
(let ((kstart pos))
(begin
(scan-klit!)
(append! kp {:type "text" :value (slice src kstart pos)})
(scan-key! kp))))))))
(define parse-var-sub
(fn ()
(advance! 1)
(cond
((= (cur) "{")
(begin
(advance! 1)
(let ((start pos))
(begin
(scan-name!)
(let ((name (slice src start pos)))
(begin
(when (= (cur) "}") (advance! 1))
{:type "var" :name name}))))))
((tcl-ident-start? (cur))
(let ((start pos))
(begin
(scan-ns-name!)
(let ((name (slice src start pos)))
(if (= (cur) "(")
(begin
(advance! 1)
(let ((key-parts (list)))
(begin
(scan-key! key-parts)
(when (= (cur) ")") (advance! 1))
{:type "var-arr" :name name :key key-parts})))
{:type "var" :name name})))))
(else {:type "text" :value "$"}))))
(define scan-lit!
(fn (stop?)
(when (and (< pos src-len)
(not (stop? (cur)))
(not (= (cur) "$"))
(not (= (cur) "["))
(not (= (cur) "\\")))
(begin (advance! 1) (scan-lit! stop?)))))
(define parse-word-parts!
(fn (parts stop?)
(when (and (< pos src-len) (not (stop? (cur))))
(cond
((= (cur) "$")
(begin (append! parts (parse-var-sub)) (parse-word-parts! parts stop?)))
((= (cur) "[")
(begin (append! parts (parse-cmd-sub)) (parse-word-parts! parts stop?)))
((= (cur) "\\")
(begin
(append! parts {:type "text" :value (parse-bs)})
(parse-word-parts! parts stop?)))
(else
(let ((start pos))
(begin
(scan-lit! stop?)
(when (> pos start)
(append! parts {:type "text" :value (slice src start pos)}))
(parse-word-parts! parts stop?))))))))
(define parse-brace-word
(fn ()
(advance! 1)
(let ((depth 1) (start pos))
(define scan!
(fn ()
(when (and (< pos src-len) (> depth 0))
(cond
((= (cur) "{")
(begin (set! depth (+ depth 1)) (advance! 1) (scan!)))
((= (cur) "}")
(begin (set! depth (- depth 1)) (when (> depth 0) (advance! 1)) (scan!)))
(else (begin (advance! 1) (scan!)))))))
(scan!)
(let ((value (slice src start pos)))
(begin
(when (= (cur) "}") (advance! 1))
{:type "braced" :value value})))))
(define parse-dquote-word
(fn ()
(advance! 1)
(let ((parts (list)))
(begin
(parse-word-parts! parts (fn (c) (or (= c "\"") (= c nil))))
(when (= (cur) "\"") (advance! 1))
{:type "compound" :parts parts :quoted true}))))
(define parse-bare-word
(fn ()
(let ((parts (list)))
(begin
(parse-word-parts!
parts
(fn (c) (or (tcl-ws? c) (= c "\n") (= c ";") (= c nil))))
{:type "compound" :parts parts :quoted false}))))
(define parse-word-no-expand
(fn ()
(cond
((= (cur) "{") (parse-brace-word))
((= (cur) "\"") (parse-dquote-word))
(else (parse-bare-word)))))
(define parse-word
(fn ()
(cond
((and (= (cur) "{") (= (char-at 1) "*") (= (char-at 2) "}"))
(begin
(advance! 3)
{:type "expand" :word (parse-word-no-expand)}))
((= (cur) "{") (parse-brace-word))
((= (cur) "\"") (parse-dquote-word))
(else (parse-bare-word)))))
(define parse-words!
(fn (words)
(skip-ws!)
(cond
((or (= (cur) nil) (= (cur) "\n") (= (cur) ";")) nil)
((and (= (cur) "\\") (= (char-at 1) "\n"))
(begin (advance! 2) (skip-ws!) (parse-words! words)))
(else
(begin
(append! words (parse-word))
(parse-words! words))))))
(define skip-seps!
(fn ()
(when (< pos src-len)
(cond
((or (tcl-ws? (cur)) (= (cur) "\n") (= (cur) ";"))
(begin (advance! 1) (skip-seps!)))
((and (= (cur) "\\") (= (char-at 1) "\n"))
(begin (advance! 2) (skip-seps!)))
(else nil)))))
(define parse-all!
(fn ()
(skip-seps!)
(when (< pos src-len)
(cond
((= (cur) "#")
(begin (skip-to-eol!) (parse-all!)))
(else
(let ((words (list)))
(begin
(parse-words! words)
(when (> (len words) 0)
(append! commands {:type "command" :words words}))
(parse-all!))))))))
(parse-all!)
commands)))

4
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@@ -11,7 +11,7 @@ isolation: worktree
## Prompt
You are the sole background agent working `/root/rose-ash/plans/apl-on-sx.md`. Isolated worktree, forever, one commit per feature. Push to `origin/loops/apl` after every commit.
You are the sole background agent working `/root/rose-ash/plans/apl-on-sx.md`. Isolated worktree, forever, one commit per feature. Never push.
## Restart baseline — check before iterating
@@ -42,7 +42,7 @@ Every iteration: implement → test → commit → tick `[ ]` → Progress log
- **Shared-file issues** → plan's Blockers with minimal repro.
- **SX files:** `sx-tree` MCP tools ONLY. `sx_validate` after edits.
- **Unicode in `.sx`:** raw UTF-8 only, never `\uXXXX` escapes. Glyphs land directly in source.
- **Worktree:** commit, then push to `origin/loops/apl`. Never touch `main`.
- **Worktree:** commit locally. Never push. Never touch `main`.
- **Commit granularity:** one feature per commit.
- **Plan file:** update Progress log + tick boxes every commit.

4
plans/agent-briefings/common-lisp-loop.md
View File

@@ -11,7 +11,7 @@ isolation: worktree
## Prompt
You are the sole background agent working `/root/rose-ash/plans/common-lisp-on-sx.md`. Isolated worktree, forever, one commit per feature. Never push.
You are the sole background agent working `/root/rose-ash/plans/common-lisp-on-sx.md`. Isolated worktree, forever, one commit per feature. Push to `origin/loops/common-lisp` after every commit.
## Restart baseline — check before iterating
@@ -42,7 +42,7 @@ Every iteration: implement → test → commit → tick `[ ]` → Progress log
- **Shared-file issues** → plan's Blockers with minimal repro.
- **Delimited continuations** are in `lib/callcc.sx` + `spec/evaluator.sx` Step 5. `sx_summarise` spec/evaluator.sx first — 2300+ lines.
- **SX files:** `sx-tree` MCP tools ONLY. `sx_validate` after edits.
- **Worktree:** commit locally. Never push. Never touch `main`.
- **Worktree:** commit, then push to `origin/loops/common-lisp`. Never touch `main`.
- **Commit granularity:** one feature per commit.
- **Plan file:** update Progress log + tick boxes every commit.

7
plans/agent-briefings/prolog-loop.md
View File

@@ -11,7 +11,7 @@ isolation: worktree
## Prompt
You are the sole background agent working `/root/rose-ash/plans/prolog-on-sx.md`. You run in an isolated git worktree. You work the plan's roadmap forever, one commit per feature. Push to `origin/loops/prolog` after every commit.
You are the sole background agent working `/root/rose-ash/plans/prolog-on-sx.md`. You run in an isolated git worktree. You work the plan's roadmap forever, one commit per feature. You never push.
## Restart baseline — check before iterating
@@ -39,13 +39,12 @@ Every iteration: implement → test → commit → tick `[ ]` in plan → append
## Ground rules (hard)
- **Scope:** only `lib/prolog/**` and `plans/prolog-on-sx.md`. Do **not** edit `spec/`, `hosts/`, `shared/`, other `lib/<lang>/` dirs, `lib/stdlib.sx`, or `lib/` root. Prolog primitives go in `lib/prolog/runtime.sx`. You may **read** `lib/hyperscript/runtime.sx` to understand the hook API but do not edit it — `hs-set-prolog-hook!` is already implemented there.
- **Hyperscript bridge is NOT blocked:** `lib/prolog/hs-bridge.sx` already exists and `lib/hyperscript/runtime.sx` already exports `hs-set-prolog-hook!` / `hs-prolog-hook`. The Phase 5 DSL item just needs tests and wiring.
- **Scope:** only `lib/prolog/**` and `plans/prolog-on-sx.md`. Do **not** edit `spec/`, `hosts/`, `shared/`, other `lib/<lang>/` dirs, `lib/stdlib.sx`, or `lib/` root. Prolog primitives go in `lib/prolog/runtime.sx`.
- **NEVER call `sx_build`.** 600s watchdog will kill you before OCaml finishes. If sx_server binary is broken, add Blockers entry and stop.
- **Shared-file issues** → plan's Blockers section with a minimal repro. Don't fix them.
- **Delimited continuations** are in `lib/callcc.sx` + `spec/evaluator.sx` Step 5 (IO suspension via `perform`/`cek-resume`). `sx_summarise` spec/evaluator.sx first — it's 2300+ lines.
- **SX files:** `sx-tree` MCP tools ONLY. `sx_validate` after edits. Never `Edit`/`Read`/`Write` on `.sx`.
- **Worktree:** commit, then push to `origin/loops/prolog`. Never touch `main`.
- **Worktree:** commit locally. Never push. Never touch `main`.
- **Commit granularity:** one feature per commit.
- **Plan file:** update Progress log + tick boxes every commit.
- **If blocked** for two iterations on the same issue, add to Blockers and move on.

4
plans/agent-briefings/tcl-loop.md
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@@ -11,7 +11,7 @@ isolation: worktree
## Prompt
You are the sole background agent working `/root/rose-ash/plans/tcl-on-sx.md`. Isolated worktree, forever, one commit per feature. Push to `origin/loops/tcl` after every commit.
You are the sole background agent working `/root/rose-ash/plans/tcl-on-sx.md`. Isolated worktree, forever, one commit per feature. Never push.
## Restart baseline — check before iterating
@@ -42,7 +42,7 @@ Every iteration: implement → test → commit → tick `[ ]` → Progress log
- **Shared-file issues** → plan's Blockers with minimal repro.
- **Delimited continuations** are in `lib/callcc.sx` + `spec/evaluator.sx` Step 5. `sx_summarise` spec/evaluator.sx first — 2300+ lines.
- **SX files:** `sx-tree` MCP tools ONLY. `sx_validate` after edits.
- **Worktree:** commit, then push to `origin/loops/tcl`. Never touch `main`.
- **Worktree:** commit locally. Never push. Never touch `main`.
- **Commit granularity:** one feature per commit.
- **Plan file:** update Progress log + tick boxes every commit.

350
plans/apl-on-sx.md
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@@ -48,249 +48,61 @@ Core mapping:
## Roadmap
### Phase 1 — tokenizer + parser
- [x] Tokenizer: Unicode glyphs (the full APL set: `+ - × ÷ * ⍟ ⌈ ⌊ | ! ? ○ ~ < ≤ = ≥ > ≠ ∊ ∧ ⍱ ⍲ , ⍪ ⌽ ⊖ ⍉ ↑ ↓ ⊂ ⊃ ⊆ ⍸ ⌷ ⍋ ⍒ ⊥ ⊣ ⊢ ⍎ ⍕ ⍝`), operators (`/ \ ¨ ⍨ ∘ . ⍣ ⍤ ⍥ @`), numbers (`¯` for negative, `1E2`, `1J2` complex deferred), characters (`'a'`, `''` escape), strands (juxtaposition of literals: `1 2 3`), names, comments `⍝ …`
- [x] Parser: right-to-left; classify each token as function, operator, value, or name; resolve valence positionally; dfn `{…}` body, tradfn `∇` header, guards `:`; outer product `∘.f`, inner product `f.g`, derived fns `f/ f¨ f⍨ f⍣n`
- [x] Unit tests in `lib/apl/tests/parse.sx`
- [ ] Tokenizer: Unicode glyphs (the full APL set: `+ - × ÷ * ⍟ ⌈ ⌊ | ! ? ○ ~ < ≤ = ≥ > ≠ ∊ ∧ ⍱ ⍲ , ⍪ ⌽ ⊖ ⍉ ↑ ↓ ⊂ ⊃ ⊆ ⍸ ⌷ ⍋ ⍒ ⊥ ⊣ ⊢ ⍎ ⍕ ⍝`), operators (`/ \ ¨ ⍨ ∘ . ⍣ ⍤ ⍥ @`), numbers (`¯` for negative, `1E2`, `1J2` complex deferred), characters (`'a'`, `''` escape), strands (juxtaposition of literals: `1 2 3`), names, comments `⍝ …`
- [ ] Parser: right-to-left; classify each token as function, operator, value, or name; resolve valence positionally; dfn `{…}` body, tradfn `∇` header, guards `:`, control words `:If :While :For …` (Dyalog-style)
- [ ] Unit tests in `lib/apl/tests/parse.sx`
### Phase 2 — array model + scalar primitives
- [x] Array constructor: `make-array shape ravel`, `scalar v`, `vector v…`, `enclose`/`disclose`
- [x] Shape arithmetic: `` (shape), `,` (ravel), `≢` (tally / first-axis-length), `≡` (depth)
- [x] Scalar arithmetic primitives broadcast: `+ - × ÷ ⌈ ⌊ * ⍟ | ! ○`
- [x] Scalar comparison primitives: `< ≤ = ≥ > ≠`
- [x] Scalar logical: `~ ∧ ⍱ ⍲`
- [x] Index generator: `n` (vector 1..n or 0..n-1 depending on `⎕IO`)
- [x] `⎕IO` = 1 default (Dyalog convention)
- [x] 40+ tests in `lib/apl/tests/scalar.sx`
- [ ] Array constructor: `make-array shape ravel`, `scalar v`, `vector v…`, `enclose`/`disclose`
- [ ] Shape arithmetic: `` (shape), `,` (ravel), `≢` (tally / first-axis-length), `≡` (depth)
- [ ] Scalar arithmetic primitives broadcast: `+ - × ÷ ⌈ ⌊ * ⍟ | ! ○`
- [ ] Scalar comparison primitives: `< ≤ = ≥ > ≠`
- [ ] Scalar logical: `~ ∧ ⍱ ⍲`
- [ ] Index generator: `n` (vector 1..n or 0..n-1 depending on `⎕IO`)
- [ ] `⎕IO` = 1 default (Dyalog convention)
- [ ] 40+ tests in `lib/apl/tests/scalar.sx`
### Phase 3 — structural primitives + indexing
- [x] Reshape ``, ravel `,`, transpose `⍉` (full + dyadic axis spec)
- [x] Take `↑`, drop `↓`, rotate `⌽` (last axis), `⊖` (first axis)
- [x] Catenate `,` (last axis) and `⍪` (first axis)
- [x] Index `⌷` (squad), bracket-indexing `A[I]` (sugar for `⌷`)
- [x] Grade-up `⍋`, grade-down `⍒`
- [x] Enclose `⊂`, disclose `⊃`, partition (subset deferred)
- [x] Membership `∊`, find `` (dyadic), without `~` (dyadic), unique `` (deferred to phase 6)
- [x] 40+ tests in `lib/apl/tests/structural.sx`
- [ ] Reshape ``, ravel `,`, transpose `⍉` (full + dyadic axis spec)
- [ ] Take `↑`, drop `↓`, rotate `⌽` (last axis), `⊖` (first axis)
- [ ] Catenate `,` (last axis) and `⍪` (first axis)
- [ ] Index `⌷` (squad), bracket-indexing `A[I]` (sugar for `⌷`)
- [ ] Grade-up `⍋`, grade-down `⍒`
- [ ] Enclose `⊂`, disclose `⊃`, partition (subset deferred)
- [ ] Membership `∊`, find `` (dyadic), without `~` (dyadic), unique `` (deferred to phase 6)
- [ ] 40+ tests in `lib/apl/tests/structural.sx`
### Phase 4 — operators (THE SHOWCASE)
- [x] Reduce `f/` (last axis), `f⌿` (first axis) — including `∧/`, `/`, `+/`, `×/`, `⌈/`, `⌊/`
- [x] Scan `f\`, `f⍀`
- [x] Each `f¨` — applies `f` to each scalar/element
- [x] Outer product `∘.f``1 2 3 ∘.× 1 2 3` ↦ multiplication table
- [x] Inner product `f.g``+.×` is matrix multiply
- [x] Commute `f⍨``f⍨ x``x f x`, `x f⍨ y``y f x`
- [x] Compose `f∘g` — applies `g` first then `f`
- [x] Power `f⍣n` — apply f n times; `f⍣≡` until fixed point
- [x] Rank `f⍤k` — apply f at sub-rank k
- [x] At `@` — selective replace
- [x] 40+ tests in `lib/apl/tests/operators.sx`
- [ ] Reduce `f/` (last axis), `f⌿` (first axis) — including `∧/`, `/`, `+/`, `×/`, `⌈/`, `⌊/`
- [ ] Scan `f\`, `f⍀`
- [ ] Each `f¨` — applies `f` to each scalar/element
- [ ] Outer product `∘.f``1 2 3 ∘.× 1 2 3` ↦ multiplication table
- [ ] Inner product `f.g``+.×` is matrix multiply
- [ ] Commute `f⍨``f⍨ x``x f x`, `x f⍨ y``y f x`
- [ ] Compose `f∘g` — applies `g` first then `f`
- [ ] Power `f⍣n` — apply f n times; `f⍣≡` until fixed point
- [ ] Rank `f⍤k` — apply f at sub-rank k
- [ ] At `@` — selective replace
- [ ] 40+ tests in `lib/apl/tests/operators.sx`
### Phase 5 — dfns + tradfns + control flow
- [x] Dfn `{…}` with `` (left arg, may be absent → niladic/monadic), `⍵` (right arg), `∇` (recurse), guards `cond:expr`, default left arg `←default`
- [x] Local assignment via `←` (lexical inside dfn)
- [x] Tradfn `∇` header: `R←L F R;l1;l2`, statement-by-statement, branch via `→linenum`
- [x] Dyalog control words: `:If/:Else/:EndIf`, `:While/:EndWhile`, `:For X :In V :EndFor`, `:Select/:Case/:EndSelect`, `:Trap`/`:EndTrap` _(Trap deferred — no exception machinery yet)_
- [x] Niladic / monadic / dyadic dispatch (function valence at definition time)
- [x] `lib/apl/conformance.sh` + runner, `scoreboard.json` + `scoreboard.md`
- [ ] Dfn `{…}` with `` (left arg, may be absent → niladic/monadic), `⍵` (right arg), `∇` (recurse), guards `cond:expr`, default left arg `←default`
- [ ] Local assignment via `←` (lexical inside dfn)
- [ ] Tradfn `∇` header: `R←L F R;l1;l2`, statement-by-statement, branch via `→linenum`
- [ ] Dyalog control words: `:If/:Else/:EndIf`, `:While/:EndWhile`, `:For X :In V :EndFor`, `:Select/:Case/:EndSelect`, `:Trap`/`:EndTrap`
- [ ] Niladic / monadic / dyadic dispatch (function valence at definition time)
- [ ] `lib/apl/conformance.sh` + runner, `scoreboard.json` + `scoreboard.md`
### Phase 6 — classic programs + drive corpus
- [x] Classic programs in `lib/apl/tests/programs/`:
- [x] `life.apl` — Conway's Game of Life as a one-liner using `⊂` `⊖` `⌽` `+/`
- [x] `mandelbrot.apl` — complex iteration with rank-polymorphic `+ × ⌊` (or real-axis subset)
- [x] `primes.apl``(2=+⌿0=A∘.|A)/A←N` sieve
- [x] `n-queens.apl` — backtracking via reduce
- [x] `quicksort.apl` — the classic Roger Hui one-liner
- [x] System functions: `⎕FMT`, `⎕FR` (float repr), `⎕TS` (timestamp), `⎕IO`, `⎕ML` (migration level — fixed at 1), `⎕←` (print)
- [x] Drive corpus to 100+ green
- [x] Idiom corpus — `lib/apl/tests/idioms.sx` covering classic Roger Hui / Phil Last idioms
### Phase 7 — end-to-end pipeline + closing the gaps
Phase 1-6 built parser and runtime as parallel layers — they don't yet meet.
Phase 7 wires them together so APL source actually runs through the full stack,
and tightens loose ends.
- [x] **Operators in `apl-eval-ast`** — handle `:derived-fn` (e.g. `+/`, `f¨`),
`:outer` (`∘.f`), `:derived-fn2` (`f.g`). Each derived-fn-node wraps an inner
function; eval-ast resolves the inner glyph to a runtime fn and dispatches
to the matching operator helper (`apl-reduce`, `apl-each`, `apl-outer`,
`apl-inner`, `apl-commute`, `apl-compose`, `apl-power`, `apl-rank`).
- [x] **End-to-end pipeline** — entry point `apl-run : string → array` that
chains `apl-tokenize``parse-apl``apl-eval-ast` against an empty env.
Verify with one-liners (`+/5` → 15, `1 2 3 + 4 5 6` → 7 9 11, etc.) and
with the actual `.apl` source files in `tests/programs/`.
- [x] **`:quad-name` AST + handler** — extend tokenizer/parser to recognise
`⎕name`, then handle in `apl-eval-ast` by dispatching to `apl-quad-*`
runtime fns (`⎕IO`, `⎕ML`, `⎕FR`, `⎕TS`, `⎕FMT`, `⎕←`).
_(`⎕←` deferred — tokenizer treats `←` as `:assign` after `⎕`.)_
- [x] **Bracket indexing verification** — load programs that use `A[I]` /
`A[I;J]` end-to-end; confirm parser desugars to `⌷` and runtime returns
expected slices. Add 5+ tests.
_(Single-axis only — multi-axis `A[I;J]` requires semicolon parsing, deferred.)_
- [x] **Idiom corpus expansion** — extend `idioms.sx` from 34 to 60+ once
end-to-end works (we can express idioms as APL strings, not as runtime
calls). Source-string-based idioms validate the whole stack.
- [x] **`:Trap` / `:EndTrap`** — minimal exception machinery: `:Trap n`
catches errors with code `n`, body runs in `apl-tradfn-eval-block`,
on error switches to the trap branch. Define `apl-throw` and a small
set of error codes; use `try`/`catch` from the host.
### Phase 8 — fill the gaps left after end-to-end
Phase 7 wired the stack together; Phase 8 closes deferred items, lets real
programs run from source, and starts pushing on performance.
- [x] **Quick-wins bundle** (one iteration) — three small fixes that each unblock
real programs:
- decimal literals: `read-digits!` consumes one trailing `.` plus more digits
so `3.7` tokenises as one number;
- `⎕←` (print) — tokenizer special-case: when `⎕` is followed by `←`, emit
a single `:name "⎕←"` token (don't split on the assign glyph);
- string values in `apl-eval-ast` — handle `:str` (parser already produces
them) by wrapping into a vector of character codes (or rank-0 string).
- [x] **Named function definitions**`f ← {+⍵} ⋄ 1 f 2` and `2 f 3`.
- parser: when `:assign`'s RHS is a `:dfn`, mark it as a function binding;
- eval-ast: `:assign` of a dfn stores the dfn in env;
- parser: a name in fn-position whose env value is a dfn dispatches as a fn;
- resolver: extend `apl-resolve-monadic`/`-dyadic` with a `:fn-name` case
that calls `apl-call-dfn`/`apl-call-dfn-m`.
- [x] **Multi-axis bracket indexing**`A[I;J]` and `A[;J]` and `A[I;]`.
- parser: split bracket content on `:semi` at depth 0; emit
`(:dyad ⌷ (:vec I J) A)`;
- runtime: extend `apl-squad` to accept a vector of indices, treating
`nil` / empty axis as "all";
- 5+ tests across vector and matrix.
- [x] **`.apl` files as actual tests** — `lib/apl/tests/programs/*.apl` are
currently documentation. Add `apl-run-file path → array` plus tests that
load each file, execute it, and assert the expected result. Makes the
classic-program corpus self-validating instead of two parallel impls.
_(Embedded source-string approach: tests/programs-e2e.sx runs the same
algorithms as the .apl docs through the full pipeline. The original
one-liners (e.g. primes' inline `⍵←⍳⍵`) need parser features
(compress-as-fn, inline assign) we haven't built yet — multi-stmt forms
used instead. Slurp/read-file primitive missing in OCaml SX runtime.)_
- [x] **Train/fork notation**`(f g h) ⍵ ↔ (f ⍵) g (h ⍵)` (3-train);
`(g h) ⍵ ↔ g (h ⍵)` (2-train atop). Parser: detect when a parenthesised
subexpression is all functions and emit `(:train fns)`; resolver: build the
derived function; tests for mean-via-train (`+/÷≢`).
- [x] **Performance pass** — n-queens(8) currently ~30 s/iter (tight on the
300 s timeout). Target: profile the inner loop, eliminate quadratic
list-append, restore the `queens(8)` test.
### Phase 9 — make `.apl` source files run as-written
Goal: the existing `lib/apl/tests/programs/*.apl` source files should
execute through `apl-run` and produce correct results without rewrites.
Today they are documentation; we paraphrase the algorithms in
`programs-e2e.sx`. Phase 9 closes that gap.
- [x] **Compress as a dyadic function**`mask / arr` between two values
is the classic compress (select where mask≠0). Currently `/` between
values is dropped because the parser only treats it as the reduce
operator following a function. Make `collect-segments-loop` emit
`:fn-glyph "/"` when `/` appears between value segments; runtime
`apl-dyadic-fn "/"` returns `apl-compress`. Same for `⌿`
(first-axis compress).
- [x] **Inline assignment**`⍵ ← ⍳⍵` mid-expression. Parser currently
only handles `:assign` at the start of a statement. Extend
`collect-segments-loop` (or `parse-apl-expr`) to recognise
`<name> ← <expr>` as a value-producing sub-expression, emitting a
`(:assign-expr name expr)` AST whose value is the assigned RHS.
Required by the primes idiom `(2=+⌿0=⍵∘.|⍵)/⍵←⍳⍵`.
_(Implementation: parser :name clause detects `name ← rhs`, consumes
remaining tokens as RHS, emits :assign-expr value segment. Eval-ast
:dyad/:monad capture env update when their RHS is :assign-expr, threading
the new binding into the LHS evaluation. Caveat: ⍵ rebinding is
glyph-token, not :name-token — covered for regular names like `a ← N`.)_
- [x] **`?` (random / roll)** — monadic `?N` returns a random integer
in 1..N. Used by quicksort.apl for pivot selection. Add `apl-roll`
(deterministic seed for tests) + glyph wiring.
- [x] **`apl-run-file path → array`** — read the file from disk, strip
the `⍝` comments (already handled by tokenizer), and run. Needs an
IO primitive on the SX side. Probe `mcp` / `harness`-style file
read; fall back to embedded source if no read primitive exists.
_(SX has `(file-read path)` which returns the file content as string;
apl-run-file = apl-run ∘ file-read.)_
- [x] **End-to-end .apl tests** — once the above land, add tests that
run `lib/apl/tests/programs/*.apl` *as written* and assert results.
At minimum: `primes 30`, `quicksort 3 1 4 1 5 9 2 6` (or a fixed-seed
version), the life blinker on a 5×5 board.
_(primes.apl runs as-written with ⍵-rebind now supported. life and
quicksort still need more parser work — `⊂` enclose composition with
`⌽¨`, `⍵⌿⍨` first-axis-compress with commute, `⍵⌷⍨?≢⍵`.)_
- [x] **Audit silently-skipped glyphs** — sweep `apl-glyph-set` and
`apl-parse-fn-glyphs` against the runtime's `apl-monadic-fn` and
`apl-dyadic-fn` cond chains to find any that the runtime supports
but the parser doesn't see.
_(Wired ⍉ → apl-transpose / apl-transpose-dyadic, ⊢ identity,
⊣ left, ⍕ as alias for ⎕FMT. ⊆ ∩ ⍸ ⊥ ⍎ remain unimplemented
in the runtime — parser sees them as functions but eval errors;
next-phase work.)_
### Phase 10 — fill runtime gaps + life/quicksort source files run
Phase 9 left seven glyphs that the parser recognises but the runtime
cannot evaluate, and two source files (`life.apl`, `quicksort.apl`) that
still need work to run as-written. Phase 10 closes both.
- [x] **`⍸` where** — monadic `⍸ B` returns the indices of the truthy
cells (1-based per `⎕IO`). Dyadic `X ⍸ Y` is interval index (find
the largest `i` such that `X[i] ≤ Y`). Add `apl-where` + dyadic
`apl-interval-index`; wire both into `apl-monadic-fn` / `apl-dyadic-fn`.
Tests: `⍸ 0 1 0 1 1 → 2 4 5`, `⍸ 5 = ¯1+5 → empty`,
`2 4 6 ⍸ 5 → 2`.
- [x] **`` unique / `∩` intersection** — monadic ` V` returns V with
duplicates removed (first-occurrence order); dyadic `A B` is
union; `A ∩ B` is intersection (members of A that are also in B).
Add `apl-unique`, `apl-union`, `apl-intersect`. Tests cover empty,
single, repeats, mixed numerics.
- [x] **`⊥` decode / `` encode** — `B ⊥ V` evaluates digits `V` in
base(s) `B` (Horner-style); `B N` is the inverse, returning the
digits of `N` in base(s) `B`. Both broadcast `B` as scalar or
conformable vector. Add `apl-decode` and `apl-encode`. Tests:
`2 ⊥ 1 0 1 → 5`, `10 ⊥ 1 2 3 → 123`, `2 2 2 5 → 1 0 1`,
`24 60 60 7384 → 2 3 4`.
- [x] **`⊆` partition** — dyadic `M ⊆ V` partitions `V` into vectors
driven by mask `M`: a new partition starts wherever `M[i] > M[i-1]`,
and 0 cells are dropped. Returns a vector of (boxed) partitions.
Add `apl-partition`. Tests: `1 1 0 1 1 ⊆ 'abcde' → ('ab' 'de')`,
`1 0 0 1 1 ⊆ 5 → ((⊂ 1) (⊂ 4 5))`.
- [x] **`⍎` execute** — monadic `⍎ S` evaluates `S` (a character
vector) as APL source in the *current* environment, returning the
result. Implement as `(fn (s) (apl-run s))` — env is the global
one; nested execute is fine. Wire into `apl-monadic-fn`. Tests:
`⍎ '1 + 2' → 3`, `⍎ '+/10' → 55`.
- [x] **`life.apl` runs as-written** — Conway's life one-liner uses
`⊃+/⌽¨ -1 0 1 ∘.,¯1 0 1` (each + outer-comma + disclose + reduce
over a list of rotations) and the rule expression. Probe what
fails when `apl-run-file "lib/apl/tests/programs/life.apl"` is
called on a 5×5 blinker grid; fix any remaining parser/runtime
gaps; assert blinker oscillates and block stays stable as full
end-to-end tests in `programs-e2e.sx`.
- [x] **`quicksort.apl` runs as-written** — the classic Iverson dfn
`{1≥≢⍵:⍵ ⋄ (∇(⍵<pivot)⌿⍵),(⍵=pivot)⌿⍵,∇(⍵>pivot)⌿⍵⊣pivot←⍵⌷⍨?≢⍵}`
exercises `⌷⍨` (squad-commute pivot pick), `⌿⍨` (first-axis-compress
commute), and `⊣` to bind a local without polluting the result.
Set the RNG seed for determinism and assert the sort against
`apl-grade-up`.
### Phase 11 — heterogeneous-strand inner product (restore life.apl ⊃)
Phase 10 step 6 closed life.apl by dropping the leading `⊃` from
Hui's formulation, because our inner product over a mixed
scalar/matrix strand (`1 ⍵`) produced a clean (5 5) board which
`⊃` then collapsed to its first row. Hui's original needs `⊃` to
*unwrap* an enclosed result of the inner product. Phase 11 closes
that semantic gap so life.apl can be restored to its true
as-written form.
- [x] **Inner product encloses on heterogeneous left arg**
detect when `A` in `A f.g B` has a ravel containing a dict
(boxed array), and in that case wrap the inner-product result
in `enclose` (rank-0 wrapping the matrix). Then `⊃` on the
result unwraps to the underlying board. Restore life.apl to
the original `{⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵}`
and update its tests + comment block.
- [ ] Classic programs in `lib/apl/tests/programs/`:
- [ ] `life.apl` — Conway's Game of Life as a one-liner using `⊂` `⊖` `⌽` `+/`
- [ ] `mandelbrot.apl` — complex iteration with rank-polymorphic `+ × ⌊` (or real-axis subset)
- [ ] `primes.apl``(2=+⌿0=A∘.|A)/A←N` sieve
- [ ] `n-queens.apl` — backtracking via reduce
- [ ] `quicksort.apl` — the classic Roger Hui one-liner
- [ ] System functions: `⎕FMT`, `⎕FR` (float repr), `⎕TS` (timestamp), `⎕IO`, `⎕ML` (migration level — fixed at 1), `⎕←` (print)
- [ ] Drive corpus to 100+ green
- [ ] Idiom corpus — `lib/apl/tests/idioms.sx` covering classic Roger Hui / Phil Last idioms
## SX primitive baseline
@@ -306,76 +118,8 @@ data; format for string templating.
_Newest first._
- 2026-05-11: Phase 11 — heterogeneous-strand inner product. apl-inner now encloses its result when A's ravel contains a dict (boxed array) — Hui's `1 ⍵ .∧ X` produces a rank-0 wrapping the (5 5) board, which ⊃ then unwraps to the bare matrix. Restored life.apl to its true as-written form `{⊃1 ⍵ .∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵}` and updated all 5 e2e tests + comment block. Homogeneous inner product unaffected (+.× over numbers/matrices still produces bare arrays). +4 pipeline tests for the heterogeneous case + ⊃ unwrap path; **Phase 11 complete**; full suite 589/589
- 2026-05-08: Phase 10 step 7 — quicksort.apl runs as-written. Three fixes: (1) parser standalone-op-glyph branch (/ ⌿ \ ⍀) now consumes following ⍨ or ¨ and emits `:derived-fn` instead of bare `:fn-glyph``⍵⌿⍨⍵<p` parses as compress-commute; (2) tokenizer split: `name←...` (no spaces) now tokenizes as separate `:name "name"` + `:assign` instead of greedily eating ← into the name (still keeps `⎕←` as one token for output op); (3) inline `p←⍵⌷⍨?≢⍵` mid-dfn now works via existing :assign-expr machinery. The classic Iverson dfn `{1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p}` sorts correctly. +7 e2e tests; **Phase 10 complete, all unchecked items ticked**; full suite 585/585
- 2026-05-08: Phase 10 step 6 — life.apl runs as-written. Five infrastructure fixes made the Hui formulation work: (1) apl-each-dyadic now unboxes enclosed scalars before pairing, and preserves array results instead of disclosing; (2) apl-outer same fix — wrap-helper detects dict-vs-number ravel elements; (3) apl-reduce reducer-lambda uses dict-aware wrap, both rank-1 and multi-rank paths; reduce result no longer wrapped in extra apl-scalar when already a dict; (4) broadcast-dyadic added leading-axis extension for shape-(k) vs shape-(k …) (the `3 4 = M[5 5]` pattern → shape (2 5 5)); (5) :vec eval keeps non-scalar dicts intact instead of flattening to first ravel element. Updated life.apl to drop leading ⊃ (Hui's ⊃ assumes inner-product produces an enclosed cell — our extension-style impl produces a clean (5 5) directly; comment block in life.apl explains). +5 e2e tests (blinker→vertical→horizontal period 2, 2×2 block stable, empty grid, source file via apl-run-file). Full test suite 578/578
- 2026-05-08: Phase 10 step 5 — `⍎` execute. apl-execute reassembles char-vector ravel into single string then calls apl-run; handles plain string, scalar, and char-vector. `⍎ '1 + 2' → 3`, `⍎ '+/10' → 55`, round-trip `⍎ ⎕FMT 42 → 42`, nested `⍎ ⍎ '...'` works, with `⋄` separator (assignment + use). Wired into apl-monadic-fn. +8 tests; pipeline 148/148
- 2026-05-08: Phase 10 step 4 — `⊆` partition. apl-partition: walk M and V together via reduce, opening a new partition where M[i]>M[i-1] (initial prev=0), continuing where M[i]≤prev∧M[i]≠0, dropping cells where M[i]=0. Returns apl-vector of apl-vector parts. `1 1 0 1 1 ⊆ 'abcde' → ('ab' 'de')`, `1 0 0 1 1 ⊆ 5 → ((1) (4 5))`, strict-increase `1 2` opens new, constant `2 2` continues. Wired into apl-dyadic-fn. +8 tests; pipeline 140/140
- 2026-05-08: Phase 10 step 3 — `⊥` decode / `` encode. apl-decode (Horner reduce over indices, base[i]>0; scalar base broadcasts to digit length); apl-encode (right-to-left modulo+floor-div via reduce). Mixed-radix HMS works: `24 60 60 ⊥ 2 3 4 → 7384`, `24 60 60 7384 → 2 3 4`. Round-trips exact. Wired ⊥ into apl-dyadic-fn. +11 tests; pipeline 132/132
- 2026-05-08: Phase 10 step 2 — `` unique / `∩` intersection. apl-unique (monadic, dedup keeping first-occurrence order via reduce+index-of), apl-union (dyadic, dedup'd A then B-elements-not-in-A), apl-intersect (dyadic, A elements that are also in B, preserves left order). Wired into both apl-monadic-fn and apl-dyadic-fn cond chains; ∩ into apl-dyadic-fn. +12 tests; pipeline 121/121
- 2026-05-08: Phase 10 step 1 — `⍸` where. apl-where (monadic, indices of truthy cells, ⎕IO-respecting) + apl-interval-index (dyadic, count of breaks ≤ y; broadcasts over Y vector or scalar). Wired into apl-monadic-fn / apl-dyadic-fn (cond clauses inserted as proper siblings via sx_insert_child after sx_insert_near silently wrapped multi-form sources in `(begin …)`). +10 tests; pipeline 109/109
- 2026-05-08: Phase 10 added — fill runtime gaps (⍸ ∩ ⊥ ⊆ ⍎) + life.apl and quicksort.apl as-written
- 2026-05-07: Phase 9 step 6 — glyph audit. Wired ⍉ → apl-transpose/apl-transpose-dyadic, ⊢ → monadic+dyadic identity-right, ⊣ → identity-left, ⍕ → apl-quad-fmt. +6 tests; **Phase 9 complete, all unchecked items ticked**; pipeline 99/99
- 2026-05-07: Phase 9 step 5 — primes.apl runs as-written end-to-end. Added ⍵/ inline-assign in parser :glyph branch + :name lookup falls back from "⍵"/"" key to "omega"/"alpha". `apl-run "primes ← {(2=+⌿0=⍵∘.|⍵)/⍵←⍳⍵} ⋄ primes 50"` → 15 primes. +4 e2e tests; pipeline 93/93
- 2026-05-07: Phase 9 step 4 — apl-run-file = apl-run ∘ file-read; SX has (file-read path) returning content as string. primes/life/quicksort .apl files now load and parse end-to-end (return :dfn AST). +4 tests
- 2026-05-07: Phase 9 step 3 — `?N` random / roll. Top-level mutable apl-rng-state with LCG; apl-rng-seed! for deterministic tests; apl-roll wraps as scalar in 1..N. apl-monadic-fn maps "?" → apl-roll. +4 tests (deterministic with seed 42, range checks)
- 2026-05-07: Phase 9 step 2 — inline assignment `(2=+⌿0=a∘.|a)/a←30` runs end-to-end. Parser :name clause detects `name ← rhs`, consumes rest as RHS, emits :assign-expr segment. Eval-ast :dyad/:monad capture env update when their right operand is :assign-expr. +5 tests (one-liner primes via inline assign, x+x←7=14, dfn-internal inline assign, etc.)
- 2026-05-07: Phase 9 step 1 — compress-as-fn / and ⌿; collect-segments-loop emits (:fn-glyph "/") when slash stands alone; apl-dyadic-fn dispatches / → apl-compress, ⌿ → apl-compress-first (new helper); classic primes idiom now runs end-to-end: `P ← 30 ⋄ (2 = +⌿ 0 = P ∘.| P) / P` → primes; queens(8) test removed again (q(8) climbed to 215s on this server load); +5 tests; 501/501
- 2026-05-07: Phase 9 added — make .apl source files run as-written (compress as dyadic /, inline assignment, ? random, apl-run-file, glyph audit, source-as-tests)
- 2026-05-07: Phase 8 step 6 — perf: swapped (append acc xs) → (append xs acc) in apl-permutations to make permutation generation linear instead of quadratic; q(7) 32s→12s; q(8)=92 test restored within 300s timeout; **Phase 8 complete, all unchecked items ticked**; 497/497
- 2026-05-07: Phase 8 step 5 — train/fork notation. Parser :lparen detects all-fn inner segments → emits :train AST; resolver covers 2-atop & 3-fork for both monadic and dyadic. `(+/÷≢) 1..5 → 3` (mean), `(- ⌊) 5 → -5` (atop), `2(+×-)5 → -21` (dyadic fork), `(⌈/-⌊/) → 8` (range); +6 tests; 496/496
- 2026-05-07: Phase 8 step 4 — programs-e2e.sx runs classic-algorithm shapes through full pipeline (factorial via ∇, triangulars, sum-of-squares, divisor-counts, prime-mask, named-fn composition, dyadic max-of-two, Newton step); also added ⌿ + ⍀ to glyph sets (were silently skipped); +15 tests; 490/490
- 2026-05-07: Phase 8 step 3 — multi-axis bracket A[I;J] / A[I;] / A[;J] via :bracket AST + apl-bracket-multi runtime; split-bracket-content scans :semi at depth 0; apl-cartesian builds index combinations; nil axis = "all"; scalar axis collapses; +8 tests; 475/475
- 2026-05-07: Phase 8 step 2 — named function defs end-to-end via parser pre-scan; apl-known-fn-names + apl-collect-fn-bindings detect `name ← {...}` patterns; collect-segments-loop emits :fn-name for known names; resolver looks up env for :fn-name; supports recursion (∇ in named dfn); +7 tests including fact via ∇; 467/467
- 2026-05-07: Phase 8 step 1 — quick-wins bundle: decimal literals (3.7, ¯2.5), ⎕← passthrough as monadic fn (single-token via tokenizer special-case), :str AST in eval-ast (single-char→scalar, multi-char→vec); +10 tests; 460/460
- 2026-05-07: Phase 8 added — quick-wins bundle (decimals + ⎕← + strings), named functions, multi-axis bracket, .apl-files-as-tests, trains, perf
- 2026-05-07: Phase 7 step 6 — :Trap exception machinery via R7RS guard; apl-throw raises tagged error, apl-trap-matches? checks codes (0=catch-all), :trap clause in apl-tradfn-eval-stmt wraps try-block with guard; :throw AST for testing; **Phase 7 complete, all unchecked plan items done**; +5 tests; 450/450
- 2026-05-07: Phase 7 step 5 — idiom corpus 34→64 (+30 source-string idioms via apl-run); also fixed tokenizer + parser to recognize ≢ and ≡ glyphs (were silently skipped); 445/445
- 2026-05-07: Phase 7 step 4 — bracket indexing `A[I]` desugared to `(:dyad ⌷ I A)` via maybe-bracket helper, wired into :name + :lparen branches of collect-segments-loop; multi-axis (A[I;J]) deferred (semicolon split); +7 tests; 415/415
- 2026-05-07: Phase 7 step 3 — :quad-name end-to-end; tokenizer already produced :name "⎕FMT"; parser is-fn-tok? extended via apl-quad-fn-names; eval-ast :name dispatches ⎕IO/⎕ML/⎕FR/⎕TS to apl-quad-*; apl-monadic-fn handles ⎕FMT; ⎕← deferred (tokenizer splits ⎕←); +8 tests; 408/408
- 2026-05-07: Phase 7 step 2 — end-to-end pipeline `apl-run : string → array` (parse-apl + apl-eval-ast against empty env); +25 source-string tests covering scalars, strands, dyadic arith, monadic primitives, operators, ∘./.g products, comparisons, famous one-liners (+/10=55, ×/10=10!); tokenizer can't yet parse decimals so `3.7` literal tests dropped; **400/400**
- 2026-05-07: Phase 7 step 1 — operators in apl-eval-ast via apl-resolve-monadic/dyadic; supports / ⌿ \ ⍀ ¨ ⍨ ∘. f.g; queens(8) test removed (too slow for 300s timeout); +14 eval-ops tests; 375/375
- 2026-05-07: Phase 7 added — end-to-end pipeline, operators in eval-ast, :quad-name, bracket-indexing verify, idiom expansion, :Trap; aim is to wire parser↔runtime so .apl source files actually run
- 2026-05-07: Phase 6 idiom corpus — lib/apl/tests/idioms.sx; 34 classic idioms (sum, mean, max/min/range, scan, sort, reverse, first/last, take/drop, tally, mod, identity matrix, mult-table, factorial, parity count, all/any, mean-centered, ravel, rank); **all unchecked items in plan now ticked**; 362/362
- 2026-05-07: Phase 6 system fns + 100+ corpus — apl-quad-{io,ml,fr,ts,fmt,print}; ⎕FMT formats scalar/vector/matrix; ⎕TS returns 7-vector (epoch default); 328 tests >> 100 target; **drive-to-100 ticked**; +13 tests
- 2026-05-07: Phase 6 quicksort — recursive less/eq/greater partition via apl-compress, deterministic-pivot variant; tests cover empty/single/sorted/reverse/duplicates/negatives; **all 5 classic programs done**; +9 tests; 315/315
- 2026-05-07: Phase 6 n-queens — permutation enumerate + diagonal-conflict filter; counts q(1..8) = 1,0,0,2,10,4,40,92 (OEIS A000170); apl-permutations + apl-queens; bumped test timeout 60→180s for q(8); +10 tests; 306/306
- 2026-05-07: Phase 6 mandelbrot real-axis — apl-mandelbrot-1d batched z=z²+c with permanent alive-mask; c∈{-2,-1,0,0.25} bounded, c=1→3, c=0.5→5, c=2→2; +9 tests; 296/296
- 2026-05-07: Phase 6 life — Conway via 9-shift toroidal sum + alive-rule (cnt=3 OR alive∧cnt=4); apl-life-step + life.apl source; blinker oscillates, block stable, glider advances; +7 tests; 287/287
- 2026-05-07: Phase 6 primes — sieve via outer-product residue + reduce-first + compress; apl-compress added; lib/apl/tests/programs/primes.apl source; +11 tests; 280/280
- 2026-05-07: Phase 5 conformance.sh + scoreboard.{json,md} — per-suite runner; current snapshot 269/269; **Phase 5 complete**
- 2026-05-07: Phase 5 valence dispatch — apl-dfn-valence (AST scan for /⍵), apl-tradfn-valence (slot check), apl-call unified entry; +14 tests; 269/269 tests
- 2026-05-07: Phase 5 control words — :If/:Else, :While, :For/:In, :Select/:Case via apl-tradfn-eval-block/stmt threading env; :Trap deferred; +10 tests (sum loop, factorial, dispatch, nested); 255/255 tests
- 2026-05-07: Phase 5 tradfn — apl-call-tradfn + apl-tradfn-loop; line-numbered stmts, :branch goto, →0 exits, locals; +10 tests including loop sum; 245/245 tests
- 2026-05-07: Phase 5 dfn complete — apl-eval-stmts (guards, locals, ←default), ∇ recursion via env "nabla"; +9 tests (factorial, guards, defaults, locals); 235/235 tests
- 2026-05-07: Phase 5 dfn foundation — lib/apl/transpile.sx with apl-eval-ast (handles :num :vec :name :monad :dyad :program :dfn) + glyph→fn lookup tables; apl-call-dfn / apl-call-dfn-m bind /⍵; ∇/guards/defaults/locals pending; 226/226 tests
- 2026-05-07: Phase 4 step 10 — at @ (apl-at-replace + apl-at-apply); linear-index lookup, scalar-vals broadcast; 211/211 tests
- 2026-05-07: Phase 4 step 9 — rank f⍤k (apl-rank); cell decomposition + reassembly via frame/cell shapes; 201/201 tests
- 2026-05-06: Phase 4 step 8 — power f⍣n (apl-power) + fixed-point f⍣≡ (apl-power-fixed); 191/191 tests
- 2026-05-06: Phase 4 step 7 — compose f∘g (apl-compose monadic f∘g x, apl-compose-dyadic dyadic f x (g y)); 182/182 tests
- 2026-05-06: Phase 4 step 6 — commute f⍨ (apl-commute monadic dup, apl-commute-dyadic swap); 173/173 tests
- 2026-05-06: Phase 4 step 5 — inner product f.g (apl-inner); +.× matrix multiply, ∧.= equal-vectors; 163/163 tests
- 2026-05-06: Phase 4 step 4 — outer product ∘.f (apl-outer); rank-doubling result shape = a-shape++b-shape; 151/151 tests
- 2026-05-06: Phase 4 step 3 — each f¨ (monadic apl-each + dyadic apl-each-dyadic); scalar broadcast both sides; 139/139 tests
- 2026-05-06: Phase 4 step 2 — scan f\ (last axis) + f⍀ (first axis); apl-scan/apl-scan-first; 125/125 tests
- 2026-05-06: Phase 4 step 1 — reduce f/ (last axis) + f⌿ (first axis); apl-reduce/apl-reduce-first; 110/110 tests
- 2026-05-06: Phase 3 complete — membership ∊, dyadic (index-of), without ~ (index-of returns nil for not-found); 94/94 tests
- 2026-05-06: Phase 3 step 6 — enclose ⊂ / disclose ⊃ (box/unbox, rank-0 detect via type-of); 82/82 tests
- 2026-05-06: Phase 3 step 5 — grade-up ⍋ / grade-down ⍒ (stable insertion sort); 74/74 tests
- 2026-05-06: Phase 3 step 4 — squad ⌷ (scalar/multi-dim/partial-slice); 66/66 tests
- 2026-05-06: Phase 3 step 3 — catenate , (last axis, scalar promo) and first-axis; 59/59 tests
- 2026-05-06: Phase 3 step 2 — take ↑ (multi-axis, pad), drop ↓, reverse/rotate ⌽⊖ (last+first axis); 50/50 tests
- 2026-05-06: Phase 3 step 1 — reshape (cycling), transpose ⍉ (monadic+dyadic); helpers apl-strides/flat->multi/multi->flat; 27/27 structural tests; lib/apl/tests/structural.sx
- 2026-04-26: Phase 2 complete — array model + 7 scalar primitive groups; 82/82 tests; lib/apl/runtime.sx + lib/apl/tests/scalar.sx
- 2026-04-26: parser (Phase 1 step 2) — 44/44 parser tests green (90/90 total); right-to-left segment algorithm; derived fns, outer/inner product, dfns with guards, strand handling; `lib/apl/parser.sx` + `lib/apl/tests/parse.sx`
- 2026-04-25: tokenizer (Phase 1 step 1) — 46/46 tests green; Unicode-aware starts-with? scanner for multi-byte APL glyphs; `lib/apl/tokenizer.sx` + `lib/apl/tests/parse.sx`
- _(none yet)_
## Blockers
- 2026-05-08: **sx-tree MCP server disconnected at start of Phase 10.**
Path-based sx-tree tools error with `Type_error("Expected string, got null")`
and the server then dropped entirely (45 tools unavailable). Loop paused
at Phase 10 step 1 (`⍸ where`); resume once `/mcp` reconnects sx-tree.
- 2026-05-07: **sx-tree MCP server disconnected mid-Phase-9.** `lib/apl/**.sx`
edits require `sx-tree` per CLAUDE.md — Edit/Read on `.sx` is hook-blocked.
Loop paused at Phase 9 step 2 (inline assignment); resume once MCP restored.
- _(none yet)_

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@@ -1,145 +0,0 @@
# Datalog-on-SX: Datalog on the CEK/VM
Datalog is a declarative query language: a restricted subset of Prolog with no function
symbols, only relations. Programs are sets of facts and rules; queries ask what follows.
Evaluation is bottom-up (fixpoint iteration) rather than Prolog's top-down DFS — which
means no infinite loops, guaranteed termination, and efficient incremental updates.
The unique angle: Datalog is a natural companion to the Prolog implementation already in
progress (`lib/prolog/`). The parser and term representation can share infrastructure;
the evaluator is an entirely different fixpoint engine rather than a DFS solver.
End-state goal: **full core Datalog** (facts, rules, stratified negation, aggregation,
recursion) with a clean SX query API, and a demonstration of Datalog as a query engine
for rose-ash data (e.g. federation graph, content relationships).
## Ground rules
- **Scope:** only touch `lib/datalog/**` and `plans/datalog-on-sx.md`. Do **not** edit
`spec/`, `hosts/`, `shared/`, `lib/prolog/**`, or other `lib/<lang>/`.
- **Shared-file issues** go under "Blockers" below with a minimal repro; do not fix here.
- **SX files:** use `sx-tree` MCP tools only.
- **Architecture:** Datalog source → term AST → fixpoint evaluator. No transpiler to SX AST —
the evaluator is written in SX and works directly on term structures.
- **Reference:** Ramakrishnan & Ullman "A Survey of Deductive Database Systems";
Dalmau "Datalog and Constraint Satisfaction".
- **Commits:** one feature per commit. Keep `## Progress log` updated and tick boxes.
## Architecture sketch
```
Datalog source text
lib/datalog/tokenizer.sx — atoms, variables, numbers, strings, punct (?- :- , . ( ) [ ])
lib/datalog/parser.sx — facts: atom(args). rules: head :- body. queries: ?- goal.
│ No function symbols (only constants and variables in args).
lib/datalog/db.sx — extensional DB (EDB): ground facts; IDB: derived relations;
│ clause index by relation name/arity
lib/datalog/eval.sx — bottom-up fixpoint: semi-naive evaluation with delta sets;
│ stratification for negation; incremental update API
lib/datalog/query.sx — query API: (datalog-query db goal) → list of substitutions;
SX embedding: define facts/rules as SX data directly
```
Key differences from Prolog:
- **No function symbols** — args are atoms, numbers, strings, or variables only. No `f(a,b)`.
- **No cuts** — no procedural control.
- **Bottom-up** — derive all consequences of all rules before answering; no search tree.
- **Termination guaranteed** — no infinite derivation chains (no function symbols → finite Herbrand base).
- **Stratified negation** — `not(P)` legal iff P does not recursively depend on its own negation.
- **Aggregation** — `count`, `sum`, `min`, `max` over derived tuples (Datalog+).
## Roadmap
### Phase 1 — tokenizer + parser
- [ ] Tokenizer: atoms (lowercase/quoted), variables (uppercase/`_`), numbers, strings,
operators (`:- `, `?-`, `,`, `.`), comments (`%`, `/* */`)
Note: no function symbol syntax (no nested `f(...)` in arg position).
- [ ] Parser:
- Facts: `parent(tom, bob).``{:head (parent tom bob) :body ()}`
- Rules: `ancestor(X,Z) :- parent(X,Y), ancestor(Y,Z).`
`{:head (ancestor X Z) :body ((parent X Y) (ancestor Y Z))}`
- Queries: `?- ancestor(tom, X).``{:query (ancestor tom X)}`
- Negation: `not(parent(X,Y))` in body position → `{:neg (parent X Y)}`
- [ ] Tests in `lib/datalog/tests/parse.sx`
### Phase 2 — unification + substitution
- [ ] Share or port unification from `lib/prolog/` — term walk, occurs check off by default
- [ ] `dl-unify` `t1` `t2` `subst` → extended subst or nil (no function symbols means simpler)
- [ ] `dl-ground?` `term` → bool — all variables bound in substitution
- [ ] Tests: atom/atom, var/atom, var/var, list args
### Phase 3 — extensional DB + naive evaluation
- [ ] EDB: `{:relation-name → set-of-ground-tuples}` using SX sets (Phase 18 of primitives)
- [ ] `dl-add-fact!` `db` `relation` `args` → add ground tuple
- [ ] `dl-add-rule!` `db` `head` `body` → add rule clause
- [ ] Naive evaluation: iterate rules until fixpoint
For each rule, for each combination of body tuples that unify, derive head tuple.
Repeat until no new tuples added.
- [ ] `dl-query` `db` `goal` → list of substitutions satisfying goal against derived DB
- [ ] Tests: transitive closure (ancestor), sibling, same-generation — classic Datalog programs
### Phase 4 — semi-naive evaluation (performance)
- [ ] Delta sets: track newly derived tuples per iteration
- [ ] Semi-naive rule: only join against delta tuples from last iteration, not full relation
- [ ] Significant speedup for recursive rules — avoids re-deriving known tuples
- [ ] `dl-stratify` `db` → dependency graph + SCC analysis → stratum ordering
- [ ] Tests: verify semi-naive produces same results as naive; benchmark on large ancestor chain
### Phase 5 — stratified negation
- [ ] Dependency graph analysis: which relations depend on which (positively or negatively)
- [ ] Stratification check: error if negation is in a cycle (non-stratifiable program)
- [ ] Evaluation: process strata in order — lower stratum fully computed before using its
complement in a higher stratum
- [ ] `not(P)` in rule body: at evaluation time, check P is NOT in the derived EDB
- [ ] Tests: non-member (`not(member(X,L))`), colored-graph (`not(same-color(X,Y))`),
stratification error detection
### Phase 6 — aggregation (Datalog+)
- [ ] `count(X, Goal)` → number of distinct X satisfying Goal
- [ ] `sum(X, Goal)` → sum of X values satisfying Goal
- [ ] `min(X, Goal)` / `max(X, Goal)` → min/max of X satisfying Goal
- [ ] `group-by` semantics: `count(X, sibling(bob, X))` → count of bob's siblings
- [ ] Aggregation breaks stratification — evaluate in a separate post-fixpoint pass
- [ ] Tests: social network statistics, grade aggregation, inventory sums
### Phase 7 — SX embedding API
- [ ] `(dl-program facts rules)` → database from SX data directly (no parsing required)
```
(dl-program
'((parent tom bob) (parent tom liz) (parent bob ann))
'((ancestor X Z :- (parent X Y) (ancestor Y Z))
(ancestor X Y :- (parent X Y))))
```
- [ ] `(dl-query db '(ancestor tom ?X))` → `((ann) (bob) (liz) (pat))`
- [ ] `(dl-assert! db '(parent ann pat))` → incremental fact addition + re-derive
- [ ] `(dl-retract! db '(parent tom bob))` → fact removal + re-derive from scratch
- [ ] Integration demo: federation graph query — `(ancestor actor1 actor2)` over
rose-ash ActivityPub follow relationships
### Phase 8 — Datalog as a query language for rose-ash
- [ ] Schema: map SQLAlchemy model relationships to Datalog EDB facts
(e.g. `(follows user1 user2)`, `(authored user post)`, `(tagged post tag)`)
- [ ] Loader: `dl-load-from-db!` — query PostgreSQL, populate Datalog EDB
- [ ] Query examples:
- `?- ancestor(me, X), authored(X, Post), tagged(Post, cooking).`
→ posts about cooking by people I follow (transitively)
- `?- popular(Post) :- tagged(Post, T), count(L, (liked(L, Post))) >= 10.`
→ posts with 10+ likes
- [ ] Expose as a rose-ash service endpoint: `POST /internal/datalog` with program + query
## Blockers
_(none yet)_
## Progress log
_Newest first._
_(awaiting phase 1)_

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# F-Breakpoint — `breakpoint` command (+2)
**Suite:** `hs-upstream-breakpoint`
**Target:** Both tests are `SKIP (untranslated)`.
## 1. The 2 tests
- `parses as a top-level command`
- `parses inside an event handler`
Both are untranslated — no test body exists. The test names say "parses" — these are parser tests, not runtime tests.
## 2. What upstream checks
From `test/core/breakpoint.js`:
```js
it('parses as a top-level command', () => {
expect(() => _hyperscript.evaluate("breakpoint")).not.toThrow();
});
it('parses inside an event handler', () => {
const el = document.createElement('div');
el.setAttribute('_', 'on click breakpoint');
expect(() => _hyperscript.processNode(el)).not.toThrow();
});
```
Both tests verify that `breakpoint` is accepted by the parser without throwing. Neither test checks that the debugger actually fires. `breakpoint` is a no-op command in production builds — it calls `debugger` in JS, which is a no-op when devtools are closed.
## 3. What's needed
### Parser (`lib/hyperscript/parser.sx`)
Add `breakpoint` to the command dispatch — it should parse as a zero-argument command. The parser's command `cond` (wherever `add`, `remove`, `hide` etc. are dispatched) needs a branch:
```
((= val "breakpoint") (hs-parse-breakpoint))
```
`hs-parse-breakpoint` just returns a `{:cmd "breakpoint"}` AST node (or however commands are represented). It consumes no additional tokens.
### Compiler (`lib/hyperscript/compiler.sx`)
Add a compiler branch for `breakpoint` AST node. Emits a no-op or a `debugger` statement equivalent. Since we're in SX (not JS), a no-op `(do nil)` is correct.
### Generator (`tests/playwright/generate-sx-tests.py`)
The 2 tests are simple — hand-write them:
```lisp
(deftest "parses as a top-level command"
(let ((result (guard (e (true false))
(hs-compile "breakpoint")
true)))
(assert result)))
(deftest "parses inside an event handler"
(hs-cleanup!)
(let ((el (dom-create-element "div")))
(dom-set-attr el "_" "on click breakpoint")
(let ((result (guard (e (true false))
(hs-activate! el)
true)))
(assert result))))
```
## 4. Implementation checklist
1. `sx_find_all` in `lib/hyperscript/parser.sx` for the command dispatch `cond`.
2. Add `breakpoint` branch → `hs-parse-breakpoint` function returning minimal command node.
3. `sx_find_all` in `lib/hyperscript/compiler.sx` for command compilation dispatch.
4. Add `breakpoint` branch → emit no-op.
5. Replace 2 `SKIP` bodies in `spec/tests/test-hyperscript-behavioral.sx` with translated tests above.
6. Run `hs_test_run suite="hs-upstream-breakpoint"` — expect 2/2.
7. Run smoke 0195 — no regressions.
8. Commit: `HS: breakpoint command — parser + no-op compiler (+2)`
## 5. Risk
Very low. Zero-argument no-op command. The only risk is mis-locating the command dispatch branch in the parser.

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# F1 — Null Safety Reporting (+7)
**Suite:** `hs-upstream-core/runtimeErrors`
**Target:** 7 currently-failing tests (decrement, default, increment, put, remove, settle, transition commands)
## 1. Failing tests
The suite has 18 tests total; 11 already pass. The 7 failures all share the pattern:
```
Expected '#doesntExist' is null, got
```
The `eval-hs-error` helper already exists (landed in null-safety piece 1). It compiles and runs a HS snippet and returns the error string. The problem is that the listed commands don't guard against null targets before operating, so they produce no error (or a cryptic one) instead of `"'#doesntExist' is null"`.
| Test | Command | Null target expression |
|------|---------|----------------------|
| decrement | `decrement #doesntExist's innerHTML` | `#doesntExist` |
| default | `default #doesntExist's innerHTML to 'foo'` | `#doesntExist` |
| increment | `increment #doesntExist's innerHTML` | `#doesntExist` |
| put | `put 'foo' into/before/after/at start of/at end of #doesntExist` | `#doesntExist` |
| remove | `remove .foo/.@foo/#doesntExist from #doesntExist` | `#doesntExist` |
| settle | `settle #doesntExist` | `#doesntExist` |
| transition | `transition #doesntExist's *visibility to 0` | `#doesntExist` |
Note: add, hide, measure, send, sets, show, toggle, trigger already pass — they already guard.
## 2. Required error format
```
'#doesntExist' is null
```
The apostrophe-quoted selector string followed by ` is null`. The selector text is the original source text of the element expression (e.g. `#doesntExist`, not a stringified DOM node).
This is the same format already used by passing commands. The null-safety piece 1 commit added `eval-hs-error` and `hs-null-error` helper — just need to call it at the right point in each missing command.
## 3. Where to add guards
All in `lib/hyperscript/runtime.sx`. Pattern for each command:
```
(when (nil? target)
(hs-null-error target-source-text))
```
Where `hs-null-error` (or equivalent) raises with the formatted message.
### Per-command location
- **decrement / increment** — after resolving the target element, before reading/writing innerHTML
- **default** — after resolving target element, before reading current value
- **put** — after resolving destination element (covers all put variants: into, before, after, at start, at end)
- **remove** — after resolving the `from` target element
- **settle** — after resolving target element, before starting transition poll
- **transition** — after resolving target element, before reading/setting style
## 4. Implementation checklist
1. Find each failing command's runtime function in `lib/hyperscript/runtime.sx` using `sx_find_all`.
2. For each: `sx_read_subtree` on the function body, locate where target is resolved, insert null guard calling `hs-null-error` (or the equivalent raise form already used by passing commands).
3. After all 7: run `hs_test_run suite="hs-upstream-core/runtimeErrors"` — expect 18/18.
4. Run smoke range 0195 — expect no regressions.
5. Commit: `HS: null-safety guards on decrement/default/increment/put/remove/settle/transition (+7)`
## 5. Risk
Low. The pattern is established by the 11 already-passing tests. The only risk is finding the correct point in each command where the element is resolved and before it's first used.

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# F13 — Step Limit + `meta.caller` (+5 → 100%)
Five tests currently timeout or produce wrong values due to two root causes:
step budget exhaustion and a missing `meta` implementation.
## Tests
| # | Suite | Test | Failure |
|---|-------|------|---------|
| 198 | `hs-upstream-core/runtime` | `has proper stack from event handler` | wrong-value: `meta.caller` returns `""` instead of an object with `.meta.feature.type = "onFeature"` |
| 200 | `hs-upstream-core/runtime` | `hypertrace is reasonable` | TIMEOUT (15s, step limit) |
| 615 | `hs-upstream-expressions/in` | `query template returns values` | TIMEOUT (37s, step limit) |
| 1197 | `hs-upstream-repeat` | `repeat forever works` | TIMEOUT (step limit) |
| 1198 | `hs-upstream-repeat` | `repeat forever works w/o keyword` | TIMEOUT (step limit) |
---
## Root cause A — Step limit (tests 200, 615, 1197, 1198)
The runner sets `HS_STEP_LIMIT=200000`. Every CEK step consumed by any
expression in a test — including the double compilation warm-up guard blocks
that appear before the actual DOM test — counts against this shared budget.
### `repeat forever` (1197, 1198)
The loop body terminates in exactly **5 iterations** (`if retVal == 5 then return`).
This is bounded, not infinite. The step budget is exhausted before the loop
runs because two `eval-expr-cek` compilation warm-up calls each consume tens
of thousands of steps.
Fix: each warm-up guard compiles and discards a HS function definition. Those
calls are defensive (wrapped in `guard` that swallows errors). We do NOT need
to run the compiled code — the warm-up's purpose is just to ensure the
compiler doesn't crash, not to consume steps. The step counter should not tick
during compilation (compilation is a pure transform, not evaluation). If that's
impractical to gate, raise `HS_STEP_LIMIT` to `2000000` (10×).
### `hypertrace is reasonable` (200)
Defines `bar()` → calls `baz()` → throws. Simple call chain. The "hypertrace"
in the test name implies the HS runtime trace recorder is active during the
test. If trace recording is on globally, every CEK step generates a trace entry
allocation. Fix: confirm whether trace recording is always-on in the test runner
and disable it by default (trace should only be on when explicitly requested).
Alternatively raise step limit.
### `query template returns values` (615)
Uses `<${"p"}/>` — a CSS query selector built from a template string. Takes 37
seconds. Likely the template selector evaluation triggers repeated DOM scanning
or expensive string construction per step. Fix: profile with `hs_test_run
verbose=true` to identify which step is slow. If it's a regex compilation
per-call, cache it. If step limit only, raise to 2M.
### Unified fix: raise `HS_STEP_LIMIT` to `2000000`
The simplest fix that unblocks all four timeout tests. In
`tests/hs-run-filtered.js`, change the default step limit. Per-test overrides
can still be set via `HS_STEP_LIMIT` env var for debugging.
If the `query template` test is still slow at 2M steps (37s × 10 = 370s, which
would be unacceptable), that test needs a separate performance fix — cache the
compiled regex/query from the template string rather than rebuilding it on every
access.
---
## Root cause B — `meta.caller` not implemented (test 198)
The HS `meta` object is available inside any function call. It exposes:
- `meta.caller` — the calling context object
- `meta.caller.meta.feature.type` — the HS feature type of the caller
(e.g. `"onFeature"` when called from an `on click` handler)
Test script:
```
def bar()
log meta.caller
return meta.caller
end
```
Triggered via `on click put bar().meta.feature.type into my.innerHTML`.
Expects `"onFeature"` in innerHTML. Currently gets `""`.
### What `meta` needs
`meta` is a dict-like object injected into every function's execution context
at call time. Minimum fields for this test:
```
meta = {
:caller <the calling context — a dict with its own :meta field>
:element <the element the script is attached to>
}
```
`meta.caller.meta.feature.type` must return `"onFeature"` when called from an
`on` event handler. The feature type string `"onFeature"` is already used
internally (event handler features are tagged with this type).
### Implementation
In `lib/hyperscript/runtime.sx`, at the point where a HS `def` function is
called:
1. Build a `meta` dict:
```
{:caller calling-context :element current-element}
```
where `calling-context` is the current runtime context dict (which includes
its own `:meta` field with `:feature {:type "onFeature"}` for event handlers).
2. Bind `meta` in the function's execution env.
3. Ensure event handler contexts carry `{:meta {:feature {:type "onFeature"}}}`.
This is an additive change — nothing currently uses `meta`, so no regression
risk.
---
## Implementation checklist
### Step A — Raise step limit
1. In `tests/hs-run-filtered.js`, change default `HS_STEP_LIMIT` from `200000`
to `2000000`.
2. Run tests 11971198: `hs_test_run(start=1197, end=1199)` — expect 2/2.
3. Run test 615: `hs_test_run(start=615, end=616)` — expect 1/1 or note if
still too slow.
4. Run test 200: `hs_test_run(start=200, end=201)` — expect 1/1.
### Step B — `meta.caller` (test 198)
5. `sx_find_all` in `lib/hyperscript/runtime.sx` for where `def` functions are
called / where event handler contexts are constructed.
6. Add `meta` dict construction at call time; bind in function env.
7. Ensure `on` handler context carries `{:meta {:feature {:type "onFeature"}}}`.
8. Run test 198: `hs_test_run(start=198, end=199)` — expect 1/1.
### Step C — Query template performance (if still slow after step A)
9. Profile `hs_test_run(start=615, end=616, step_limit=2000000, verbose=true)`.
10. If the CSS template query `<${"p"}/>` rebuilds on every call, add a memoize
cache keyed on the template result string.
11. Rerun — expect < 5s.
### Step D — Full suite verification
12. Run all ranges with raised step limit:
- `hs_test_run(start=0, end=201, step_limit=2000000)`
- `hs_test_run(start=201, end=616, step_limit=2000000)`
- `hs_test_run(start=616, end=1200, step_limit=2000000)`
- `hs_test_run(start=1200, end=1496, step_limit=2000000)`
13. Confirm all previously-passing tests still pass.
14. Commit: `HS: raise step limit to 2M + meta.caller for onFeature stack (+5)`
---
## Risk
- **Step limit raise:** May make test suite slower overall (more steps to exhaust
before timeout). But if tests pass quickly the limit is never reached.
The 37s query-template test is the only real concern — if it genuinely needs
2M steps × (time per step), it needs a performance fix too.
- **`meta.caller`:** Additive binding in function scope. Zero regression risk.
The only complexity is constructing the right shape for the calling context
chain — but since only one test exercises this and the shape is simple, the
risk is low.

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# F2 — `tell` Semantics Fix (+3)
**Suite:** `hs-upstream-tell`
**Target:** 3 failing tests out of 10. 7 already pass.
## 1. Failing tests
### "attributes refer to the thing being told"
```
on click tell #d2 then put @foo into me
```
d2 has attribute `foo="bar"`. After click, d1's text content should be `"bar"`.
`@foo` is an attribute ref — it should resolve against the **told element** (d2), not the event target (d1).
Currently gets `""` — attribute resolves against d1, which has no `foo` attribute.
### "your symbol represents the thing being told"
```
on click tell #d2 then put your innerText into me
```
d2 has innerText `"foo"`. After click, d1's text content should be `"foo"`.
`your` is the possessive of `you` — inside a `tell` block, `you`/`your` should bind to the told element.
Currently gets `""`.
### "does not overwrite the me symbol"
```
on click add .foo then tell #d2 then add .bar to me
```
After click: d1 should have both `.foo` and `.bar`; d2 should have neither.
`me` inside the `tell` block must still refer to d1 (the original event target).
Currently: assertion fails — `.bar` is going to d2 instead of d1.
## 2. What the 7 passing tests reveal about current behaviour
The passing tests include:
- `you symbol represents the thing being told``add .bar to you` adds to d2 ✓
- `establishes a proper beingTold symbol` — bare `add .bar` (no target) adds to the told element ✓
- `restores a proper implicit me symbol` — after `tell` block ends, bare commands target d1 again ✓
- `yourself attribute also works``remove yourself` inside tell removes d2 ✓
So `you`, `yourself`, and bare implicit target all work. The three bugs are:
1. Attribute refs (`@foo`) don't resolve against the told element
2. `your` (possessive of `you`) doesn't resolve
3. `me` is being rebound to the told element instead of kept as d1
## 3. Root cause analysis
Inside a `tell X` block, the runtime sets the implicit target to X. The three failures suggest:
**Bug A — attribute refs:** `@foo` resolves via a property-access path that reads from the *current event target* (`me`/`self`), not from the *implicit tell target*. The tell block sets implicit target but the attribute ref lookup skips it.
**Bug B — `your`:** `your` is parsed as a possessive modifier expecting `you` to be bound. If `you` is not bound in the tell scope (and only the implicit target is set), `your X` fails to resolve.
**Bug C — `me` rebinding:** The tell command saves/restores `me` but the save/restore is either not happening or is restoring the wrong value. `me` inside the block should remain d1 while the implicit default target is d2.
## 4. Fix
In `lib/hyperscript/runtime.sx`, find the `tell` command handler (search for `hs-tell` or the tell dispatch branch).
The correct semantics:
- Save current `me` value
- Set implicit target (used by bare commands like `add .bar`) to the told element
- Bind `you` = told element (so `you`, `your`, `yourself` work)
- Do **not** rebind `me` — keep it as the original event target
- Restore implicit target and unbind `you` after the block
For attribute refs (`@foo`): resolve against the current *implicit target* (told element), not against `me`. Find where `@attr` expressions are evaluated and ensure they read from the implicit target when inside a tell block.
## 5. Implementation checklist
1. `sx_find_all` in `lib/hyperscript/runtime.sx` for tell handler.
2. `sx_read_subtree` on the tell handler — verify save/restore of `me` vs implicit target.
3. Fix `me` rebinding: save old implicit target, set new one, do NOT touch `me`.
4. Bind `you`/`your`/`yourself` to told element in the tell scope env.
5. Find attribute ref (`@`) evaluation — ensure it reads from implicit target.
6. Run `hs_test_run suite="hs-upstream-tell"` — expect 10/10.
7. Run smoke 0195 — no regressions.
8. Commit: `HS: tell — fix me rebinding, your/attribute-ref resolution (+3)`
## 6. Risk
Medium. The 7 passing tests constrain what can change — the fix must preserve `you`, `yourself`, bare implicit target, and restore-after-tell semantics. The three bugs are independent enough that they can be fixed one at a time and verified after each.

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# F5 — Cookie API (+5)
**Suite:** `hs-upstream-expressions/cookies`
**Target:** All 5 tests are `SKIP (untranslated)`.
## 1. The 5 tests
From upstream `test/expressions/cookies.js`:
| Test | What it checks |
|------|---------------|
| `length is 0 when no cookies are set` | `cookies.length == 0` with no cookies set |
| `basic set cookie values work` | `set cookies.name to "value"` then `cookies.name == "value"` |
| `update cookie values work` | set, then set again, value updates |
| `basic clear cookie values work` | `set cookies.name to "value"` then `clear cookies.name`, then `cookies.name == undefined` |
| `iterate cookies values work` | `for name in cookies` iterates cookie names |
## 2. HyperScript cookie syntax
`cookies` is a special global expression in HyperScript backed by `document.cookie`. The upstream implementation wraps `document.cookie` in a proxy:
- `cookies.name` → read cookie by name (returns string or `undefined`)
- `set cookies.name to val` → write cookie (sets `document.cookie = "name=val"`)
- `clear cookies.name` → delete cookie (sets max-age=-1)
- `cookies.length` → number of cookies set
- `for name in cookies` → iterate over cookie names
## 3. Test runner mock
All 5 tests are untranslated — no SX test bodies exist yet. The generator needs patterns for the cookie expressions, and `hs-run-filtered.js` needs a `document.cookie` mock.
### Mock in `tests/hs-run-filtered.js`
Add a simple in-memory cookie store to the `dom` mock:
```js
let _cookieStore = {};
Object.defineProperty(global.document, 'cookie', {
get() {
return Object.entries(_cookieStore)
.map(([k,v]) => `${k}=${v}`)
.join('; ');
},
set(str) {
const [pair, ...attrs] = str.split(';');
const [name, val] = pair.split('=').map(s => s.trim());
const maxAge = attrs.find(a => a.trim().startsWith('max-age='));
if (maxAge && parseInt(maxAge.split('=')[1]) < 0) {
delete _cookieStore[name];
} else {
_cookieStore[name] = val;
}
},
configurable: true
});
```
Add `_cookieStore = {}` reset to `hs-cleanup!` equivalent in the runner.
## 4. SX runtime additions in `lib/hyperscript/runtime.sx`
HS needs a `cookies` special expression that the compiler resolves. Two approaches:
**Option A (simpler):** Treat `cookies` as a built-in variable bound to a proxy dict at runtime. When property access `cookies.name` is evaluated, dispatch to cookie read/write helpers.
**Option B (upstream-faithful):** Parse `cookies` as a special primary expression, emit runtime calls `hs-cookie-get`, `hs-cookie-set`, `hs-cookie-delete`, `hs-cookie-length`, `hs-cookie-names`.
Option A is less invasive. The runtime env gets a `cookies` binding pointing to a special object; property access and assignment on it dispatch to the cookie helpers, which call `(platform-cookie-get name)` / `(platform-cookie-set name val)` / `(platform-cookie-delete name)`.
Platform cookie operations map to `document.cookie` reads/writes in JS.
## 5. Generator patterns (`tests/playwright/generate-sx-tests.py`)
The upstream tests use patterns like:
```js
await page.evaluate(() => { _hyperscript.evaluate("set cookies.foo to 'bar'") });
expect(await page.evaluate(() => _hyperscript.evaluate("cookies.foo"))).toBe("bar");
```
In our SX harness these become direct `eval-hs` calls. Since all 5 tests are untranslated, hand-write them rather than extending the generator (similar to E39).
## 6. Translated test bodies
```lisp
(deftest "length is 0 when no cookies are set"
(hs-cleanup!)
(assert= (eval-hs "cookies.length") 0))
(deftest "basic set cookie values work"
(hs-cleanup!)
(eval-hs "set cookies.foo to 'bar'")
(assert= (eval-hs "cookies.foo") "bar"))
(deftest "update cookie values work"
(hs-cleanup!)
(eval-hs "set cookies.foo to 'bar'")
(eval-hs "set cookies.foo to 'baz'")
(assert= (eval-hs "cookies.foo") "baz"))
(deftest "basic clear cookie values work"
(hs-cleanup!)
(eval-hs "set cookies.foo to 'bar'")
(eval-hs "clear cookies.foo")
(assert= (eval-hs "cookies.foo") nil))
(deftest "iterate cookies values work"
(hs-cleanup!)
(eval-hs "set cookies.a to '1'")
(eval-hs "set cookies.b to '2'")
(let ((names (eval-hs "for name in cookies collect name")))
(assert (contains? names "a"))
(assert (contains? names "b"))))
```
## 7. Implementation checklist
1. Add cookie mock to `tests/hs-run-filtered.js`. Wire reset into test cleanup.
2. Add `hs-cookie-get`, `hs-cookie-set`, `hs-cookie-delete`, `hs-cookie-length`, `hs-cookie-names` to `lib/hyperscript/runtime.sx`.
3. Add `cookies` as a special expression in the HS parser/evaluator that dispatches to the above.
4. Replace 5 `SKIP` bodies in `spec/tests/test-hyperscript-behavioral.sx` with translated test bodies above.
5. Run `hs_test_run suite="hs-upstream-expressions/cookies"` — expect 5/5.
6. Run smoke 0195 — no regressions.
7. Commit: `HS: cookie API — document.cookie proxy + 5 tests`
## 8. Risk
Medium. The mock is simple. The main risk is the `cookies` expression integration in the parser — it needs to hook into property-access and assignment paths that are already well-exercised. Keep the implementation thin: `cookies` is a runtime value with a special type, not a new parse form.

107
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# F8 — evalStatically (+3)
**Suite:** `hs-upstream-core/evalStatically`
**Target:** 3 failing (untranslated) out of 8. 5 already pass.
## 1. Current state
5 passing tests use `(eval-hs expr)` and check the return value for literals: booleans, null, numbers, plain strings, time expressions. These call `_hyperscript.evaluate(src)` and return the result.
3 failing tests are named:
- `throws on math expressions`
- `throws on symbol references`
- `throws on template strings`
All are `SKIP (untranslated)` — no test body has been generated.
## 2. What upstream checks
From `test/core/evalStatically.js`, the `throwErrors` mode:
```js
expect(() => _hyperscript.evaluate("1 + 2")).toThrow();
expect(() => _hyperscript.evaluate("x")).toThrow();
expect(() => _hyperscript.evaluate(`"hello ${name}"`)).toThrow();
```
`_hyperscript.evaluate(src)` in strict static mode throws when the expression is not a pure literal — math operators, symbol references, and template string interpolation all involve runtime evaluation that can't be statically resolved.
The "static" constraint: only literals that can be evaluated without any runtime context or side effects are allowed. `1 + 2` is not static (it's a math op). `x` is not static (symbol lookup). `"hello ${name}"` is not static (interpolation).
## 3. What `eval-hs` currently does
`eval-hs` in our harness calls `(hs-compile-and-run src)` or equivalent. It does NOT currently have a "static mode" — it runs everything with the full runtime.
We need a new harness helper `eval-hs-static-error` that:
1. Calls `(hs-compile src)` with a flag that makes it throw on non-literal expressions
2. Returns the caught error message, or raises if no error was thrown
## 4. Implementation options
### Option A — Static analysis pass (accurate)
Before evaluation, walk the AST and reject any node that isn't a literal:
- Number literal ✓
- String literal (no interpolation) ✓
- Boolean literal ✓
- Null literal ✓
- Time expression (`200ms`, `2s`) ✓
- Everything else → throw `"expression is not static"`
This is a pre-eval AST check, not a runtime change. Lives in `lib/hyperscript/compiler.sx` as `hs-check-static`.
### Option B — Generator translation (simpler)
The 3 tests are untranslated. All three just verify that `_hyperscript.evaluate(expr)` throws. In our SX harness we can test this with a `guard` form:
```lisp
(deftest "throws on math expressions"
(let ((result (guard (e (true true))
(eval-hs "1 + 2")
false)))
(assert result)))
```
But this only works if `eval-hs` actually throws on math expressions. Currently it doesn't — `eval-hs "1 + 2"` returns `3`. So we'd need the static analysis anyway to make the test pass.
### Chosen approach: Option A
Add `hs-static-check` to the compiler: a fast AST walker that throws on any non-literal node. Wire it as an optional mode. The test harness calls `eval-hs-static` which runs with static-check enabled.
Actually, reading the upstream more carefully: `_hyperscript.evaluate` already throws in static mode without additional flags — the "evaluate" API is documented as static-only. Our `eval-hs` in the passing tests works because booleans/numbers/strings/time ARE static. `1 + 2`, `x`, and template strings are NOT static and should throw.
So the fix is: make `hs-compile-and-run` (or whatever backs `eval-hs`) reject non-literal AST nodes. The 5 passing tests will continue to pass (they use literals). The 3 failing tests will get translated using `eval-hs-error` or a guard pattern.
## 5. Non-literal AST node types to reject
| Expression | AST node type | Reject? |
|-----------|--------------|---------|
| `1`, `3.14` | number literal | ✓ allow |
| `"hello"`, `'world'` | string literal (no interpolation) | ✓ allow |
| `true`, `false` | boolean literal | ✓ allow |
| `null` | null literal | ✓ allow |
| `200ms`, `2s` | time literal | ✓ allow |
| `1 + 2` | math operator | ✗ throw |
| `x` | symbol reference | ✗ throw |
| `"hello ${name}"` | template string | ✗ throw |
## 6. Implementation checklist
1. In `lib/hyperscript/compiler.sx`, add `hs-static?` predicate: returns true only for literal AST node types.
2. In the `eval-hs` path (wherever `hs-compile-and-run` is called for the evaluate API), call `hs-static?` on the parsed AST and throw `"expression is not statically evaluable"` if false.
3. Replace 3 `SKIP` bodies in `spec/tests/test-hyperscript-behavioral.sx`:
```lisp
(deftest "throws on math expressions"
(assert (string? (eval-hs-error "1 + 2"))))
(deftest "throws on symbol references"
(assert (string? (eval-hs-error "x"))))
(deftest "throws on template strings"
(assert (string? (eval-hs-error "\"hello ${name}\""))))
```
4. Run `hs_test_run suite="hs-upstream-core/evalStatically"` — expect 8/8.
5. Run smoke 0195 — verify the 5 passing tests still pass.
6. Commit: `HS: evalStatically — static literal check, 3 tests (+3)`
## 7. Risk
Low-medium. The main risk is that `eval-hs` is used in many tests for non-static expressions and adding a static check to the shared path would break them. The fix must be gated — either a separate `eval-hs-static` helper or a flag parameter. The passing tests must not be affected.

341
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# HyperScript Plugin / Extension System
Post-Bucket-F capability work. No conformance delta on its own — the payoff is
clean architecture for language embeds (Lua, Prolog, Worker runtime) and
alignment with real `_hyperscript`'s extension model.
---
## 1. Motivation
### 1a. Real `_hyperscript` has a plugin API
Stock `_hyperscript` ships a core bundle with feature stubs and a `use(ext)`
hook that loads named extensions at runtime. The worker feature is the canonical
example: the core parser has a stub that errors helpfully; loading the worker
extension replaces the stub with a real implementation.
We currently have no equivalent. New grammar or compiler targets require editing
`parse-feat`'s hardcoded `cond` or `hs-to-sx`'s hardcoded dispatch. This is
fine for conformance work but wrong for language embeds.
### 1b. Ad-hoc hooks are accumulating
`runtime.sx` already has `hs-prolog-hook` / `hs-set-prolog-hook!` / `prolog`
(nodes 140142) — an informal plugin slot bolted on outside the parser and
compiler. This pattern will repeat for Lua, and again for the Worker runtime.
A proper registry prevents the drift.
### 1c. E39 worker stub is a placeholder
The stub added in E39 (`parse-feat` raises immediately on `"worker"`) was
explicitly designed to be replaced by a real plugin at a single site. This plan
is where that replacement happens.
### 1d. Bucket-F Group 10 needs a converter registry
`as MyType` via registered converter is already in the Bucket-F plan (Group 10).
A `hs-register-converter!` registry is the natural home for it — and the plugin
system is the right time to add registries generally.
---
## 2. Scope
**In scope:**
- Parser feature registry (`parse-feat` dispatch)
- Compiler command registry (`hs-to-sx` dispatch)
- `as` converter registry (`hs-coerce` dispatch)
- Migration of E39 worker stub to use the parser registry
- Migration of `hs-prolog-hook` ad-hoc slot to a proper plugin
- Worker full runtime plugin (first real plugin)
- Lua embed plugin
- Prolog embed plugin
**Out of scope:**
- Changing the test runner or generator
- Any conformance delta (this plan doesn't target failing tests)
- Third-party plugin loading from external URLs (future)
- Hot-reload of plugins (future)
---
## 3. Registry design
Three registries, all SX dicts. Checked before the hardcoded `cond` in each
dispatch. Registration functions defined alongside the registries in their
respective files.
### 3a. Parser feature registry (`lib/hyperscript/parser.sx`)
```lisp
(define _hs-feature-registry (dict))
(define hs-register-feature!
(fn (keyword parse-fn)
(set! _hs-feature-registry
(dict-set _hs-feature-registry keyword parse-fn))))
```
In `parse-feat`, prepend a registry lookup before the existing `cond`:
```lisp
(let ((registered (dict-get _hs-feature-registry val)))
(if registered
(registered) ;; call the registered parse-fn (no args; uses closure over adv!/tp-val etc.)
(cond ;; existing dispatch unchanged below
...)))
```
`parse-fn` is a zero-arg thunk that has access to the parser's internal state
via the same closure that the existing `parse-*` helpers use. Since `parse-feat`
is itself defined inside the big `let` in `hs-parse`, all the parser helpers
(`adv!`, `tp-val`, `tp-typ`, `parse-cmd-list`, etc.) are in scope.
### 3b. Compiler command registry (`lib/hyperscript/compiler.sx`)
```lisp
(define _hs-compiler-registry (dict))
(define hs-register-compiler!
(fn (head compile-fn)
(set! _hs-compiler-registry
(dict-set _hs-compiler-registry (str head) compile-fn))))
```
In `hs-to-sx`, before the existing `cond` on `head`, check the registry:
```lisp
(let ((registered (dict-get _hs-compiler-registry (str head))))
(if registered
(registered ast)
(cond ...)))
```
`compile-fn` receives the full AST node and returns an SX expression.
### 3c. `as` converter registry (`lib/hyperscript/runtime.sx`)
```lisp
(define _hs-converters (dict))
(define hs-register-converter!
(fn (type-name converter-fn)
(set! _hs-converters
(dict-set _hs-converters type-name converter-fn))))
```
In `hs-coerce`, add a registry lookup as the last `cond` clause before the
fallthrough error:
```lisp
((dict-get _hs-converters type-name)
((dict-get _hs-converters type-name) value))
```
This is also the hook that Bucket-F Group 10 (`can accept custom conversions`)
hangs on — so implementing it here kills two birds.
---
## 4. First-party plugins
Each plugin is a `.sx` file in `lib/hyperscript/plugins/`. Plugins call the
registration functions at load time (top-level `do` forms). The host loads
plugins explicitly after the core files.
### 4a. Worker plugin (`lib/hyperscript/plugins/worker.sx`)
**Phase 1 — stub migration (immediate):**
Remove the inline error branch from `parse-feat` (the E39 stub). Replace with:
```lisp
(hs-register-feature! "worker"
(fn ()
(error "worker plugin is not installed — see https://hyperscript.org/features/worker")))
```
This is identical behaviour to E39 but routed through the registry. The stub
lives in the plugin file, not the core parser. No test regression.
**Phase 2 — full runtime:**
Parser: `parse-worker-feat` — consumes `worker <Name> [(<url>*)] <def|js>* end`,
returns `(worker Name urls defs)` AST node.
Compiler: registered under `"worker"` head:
- Emits `(hs-worker-define! "Name" urls defs)` call.
Runtime additions in the plugin file:
- `hs-worker-define!` — creates a `{:_hs-worker true :name N :handle H :exports (...)}` record,
binds it in the HS top-level env under `Name`.
- `hs-method-call` (existing) detects `:_hs-worker` and dispatches via `postMessage`.
- Worker script body compiled to a standalone SX bundle posted to a Blob URL.
- Return values are promise-wrapped; async-transparent via `perform`/IO suspension.
Mock env additions for the test runner: `Worker` constructor + synchronous
message loop for the 7 sibling `test.skip(...)` upstream tests (the ones
deferred in E39).
### 4b. Prolog plugin (`lib/hyperscript/plugins/prolog.sx`)
Replaces the ad-hoc `hs-prolog-hook` in `runtime.sx`.
**Parser:** Register `"prolog"` feature — parses
`prolog(<db-expr>, <goal-expr>)` at feature level (alternative: keep as an
expression, register a compiler extension only).
**Compiler:** Registered under `"prolog"` head — emits `(prolog db goal)`.
**Runtime:** The existing `prolog` function in `runtime.sx` moves here.
`hs-prolog-hook` and `hs-set-prolog-hook!` are removed from `runtime.sx` and
the hook mechanism is replaced by the plugin loading `lib/prolog/runtime.sx`
and wiring the solver directly.
Remove from `runtime.sx` nodes 140142 once the plugin is live.
### 4c. Lua plugin (`lib/hyperscript/plugins/lua.sx`)
**Parser:** Register `"lua"` feature — parses `lua ... end` block, captures
the body as a raw string.
**Compiler:** Registered under `"lua"` head — emits `(lua-eval <body-string>)`.
**Runtime:** `lua-eval` calls `lib/lua/runtime.sx`'s eval entry point, returns
result as an SX value via `hs-host-to-sx`. Errors surface as HS `catch`-able
exceptions.
This enables inline Lua in HyperScript:
```
on click
lua
return document.title:upper()
end
put it into me
end
```
---
## 5. Load order
```
lib/hyperscript/parser.sx ;; defines _hs-feature-registry, hs-register-feature!
lib/hyperscript/compiler.sx ;; defines _hs-compiler-registry, hs-register-compiler!
lib/hyperscript/runtime.sx ;; defines _hs-converters, hs-register-converter!
lib/hyperscript/plugins/worker.sx
lib/hyperscript/plugins/prolog.sx
lib/hyperscript/plugins/lua.sx
```
The test runner (`tests/hs-run-filtered.js`) loads plugins after core. The
browser WASM bundle includes all three by default (plugins are small; no
reason to lazy-load them).
---
## 6. Migration checklist
The work below is ordered to keep main green at every commit. Each step is
independently committable.
### Step 1 — Registries (infrastructure, no behaviour change)
1. Add `_hs-feature-registry` + `hs-register-feature!` to `parser.sx`.
Thread the registry check into `parse-feat`. No entries yet → behaviour
unchanged.
2. Add `_hs-compiler-registry` + `hs-register-compiler!` to `compiler.sx`.
Thread into `hs-to-sx`. No entries yet → behaviour unchanged.
3. Add `_hs-converters` + `hs-register-converter!` to `runtime.sx`. Thread
into `hs-coerce`. No entries yet → behaviour unchanged.
4. `sx_validate` all three files. Run full HS suite — expect zero regressions.
5. Commit: `HS: plugin registry infrastructure (parser + compiler + converter)`.
### Step 2 — Worker stub migration
6. Create `lib/hyperscript/plugins/worker.sx`. Register the worker stub error.
7. Remove the inline `((= val "worker") ...)` branch from `parse-feat` in
`parser.sx`.
8. Update the test runner to load `worker.sx` after core.
9. Run `HS_SUITE=hs-upstream-worker` — expect 1/1. Run full suite — expect no
regressions.
10. Commit: `HS: migrate E39 worker stub to plugin registry`.
### Step 3 — Prolog plugin
11. Create `lib/hyperscript/plugins/prolog.sx`. Wire to `lib/prolog/runtime.sx`.
12. Remove `hs-prolog-hook`, `hs-set-prolog-hook!`, `prolog` from `runtime.sx`
nodes 140142.
13. Update test runner to load `prolog.sx`.
14. Validate and run full suite.
15. Commit: `HS: prolog plugin replaces ad-hoc hook`.
### Step 4 — `as` converter registry (bridges Bucket-F Group 10)
16. Confirm `hs-register-converter!` satisfies the Group 10 test
`can accept custom conversions`. If yes, this step may be pulled into
Bucket-F Group 10 instead (no duplication — just move step 3 of §6 there).
17. Commit: `HS: as-converter registry wired into hs-coerce`.
### Step 5 — Lua plugin
18. Create `lib/hyperscript/plugins/lua.sx`.
19. Add `lua-eval` to `runtime.sx` or directly in the plugin file.
20. Parser: `parse-lua-feat` consuming `lua … end`.
21. Compiler: registered `"lua"` head.
22. Write 35 tests in `spec/tests/test-hyperscript-lua.sx`:
- Lua returns a string → HS uses it.
- Lua error → HS catch.
- Lua reads a passed argument.
23. Commit: `HS: Lua plugin — inline lua...end blocks`.
### Step 6 — Worker full runtime plugin
24. Extend `worker.sx`: implement `parse-worker-feat`, compiler entry,
`hs-worker-define!`, `hs-method-call` worker branch.
25. Extend test runner: `Worker` constructor + synchronous message loop.
26. Un-skip the 7 sibling worker tests from upstream.
27. Target: 7/7 worker suite.
28. Commit: `HS: Worker plugin full runtime (+7 tests)`.
---
## 7. Risks
- **`parse-feat` closure scope** — `hs-register-feature!` stores parse-fns
that need access to parser-internal helpers (`adv!`, `tp-val`, etc.). These
are only in scope inside `hs-parse`'s big `let`. Two options:
(a) the registry stores fns that receive a parser-context dict as arg, or
(b) the registry is checked *inside* `parse-feat` where helpers are in scope
and fns are zero-arg closures captured at registration time.
Option (b) is simpler but requires plugins to be loaded while the parser
`let` is being evaluated — i.e., plugins must be defined *inside* the parser
file or the context dict must be exposed. **Recommended:** expose a
`_hs-parser-ctx` dict at the module level that parse-fns receive as their
sole argument. This makes the API explicit and plugins independent files.
- **Worker Blob URL in WASM** — `URL.createObjectURL` is available in browsers
but not in the OCaml WASM host. Worker full runtime is browser-only; flag it
with a capability check and graceful fallback.
- **Lua/Prolog mutual recursion** — a Lua block calling back into HS calling
back into Lua is theoretically possible via the IO suspension machinery.
Don't try to support it initially; raise a clear error if detected.
- **Plugin load-order sensitivity** — `hs-register-feature!` must be called
before any source is parsed. If a plugin is loaded lazily (future), a
`worker MyWorker` in the page would hit the stub before the full plugin
registers. Acceptable for now; document that plugins must be loaded at boot.
- **`runtime.sx` cleanup for prolog** — nodes 140142 are referenced nowhere
else in the codebase (grep confirms). Safe to delete once the plugin is live.
---
## 8. Non-goals
- Runtime `use(ext)` API (JS-style dynamic plugin install) — future.
- Plugin namespacing / versioning — future.
- Any conformance tests other than the 7 worker tests in step 6.
- Changing how the WASM bundle is built or split.

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