Replaces the stub sprintf in runtime.sx with a real implementation:
walk fmt char-by-char accumulating a prefix; on recognised %X return a
one-arg fn that formats the arg and recurses on the rest of fmt. The
function self-curries to the spec count — there's no separate arity
machinery, just a closure chain.
Specs: %d (int), %s (string), %f (float), %c (char/string in our model),
%b (bool), %% (literal). Unknown specs pass through.
Same expression returns a string (no specs) or a function (>=1 spec) —
OCaml proper would reject this; works fine in OCaml-on-SX's dynamic
runtime.
Also adds top-level aliases:
string_of_int = _string_of_int
string_of_float = _string_of_float
string_of_bool = if b then "true" else "false"
int_of_string = _int_of_string
Printf.sprintf "x=%d" 42 = "x=42"
Printf.sprintf "%s = %d" "answer" 42 = "answer = 42"
Printf.sprintf "%d%%" 50 = "50%"
Tokenizer already classified 'assert' as a keyword; this commit wires
it through:
parser : parse-prefix dispatches like 'not' — advance, recur, wrap
as (:assert EXPR).
eval : evaluate operand; nil on truthy, host-error 'Assert_failure'
on false. Caught cleanly by existing try/with.
assert true; 42 = 42
let x = 5 in assert (x = 5); x + 1 = 6
try (assert false; 0) with _ -> 99 = 99
Recursive Levenshtein edit distance with no memoization (the test
strings are short enough for the exponential-without-memo version to
fit in <2 minutes on contended hosts). Sums distances for five short
pairs:
('abc','abx') + ('ab','ba') + ('abc','axyc') + ('','abcd') + ('ab','')
= 1 + 2 + 2 + 4 + 2 = 11
Exercises:
* curried four-arg recursion
* s.[i] equality test (char comparison)
* min nested twice for the three-way recurrence
* mixed empty-string base cases
Side-quests required to land caesar.ml:
1. Top-level 'let r = expr in body' is now an expression decl, not a
broken decl-let. ocaml-parse-program's dispatch now checks
has-matching-in? at every top-level let; if matched, slices via
skip-let-rhs-boundary (which already opens depth on a leading let
with matching in) and ocaml-parse on the slice, wrapping as :expr.
2. runtime.sx: added String.make / String.init / String.map. Used by
caesar.ml's encode = String.init n (fun i -> shift_char s.[i] k).
3. baseline run.sh per-program timeout 240->480s (system load on the
shared host frequently exceeds 240s for large baselines).
caesar.ml exercises:
* the new top-level let-in expression dispatch
* s.[i] string indexing
* Char.code / Char.chr round-trip math
* String.init with a closure that captures k
Test value: Char.code r.[0] + Char.code r.[4] after ROT13(ROT13('hello')) = 104 + 111 = 215.
parse-atom-postfix now dispatches three cases after consuming '.':
.field -> existing field/module access
.(EXPR) -> existing local-open
.[EXPR] -> new string-get syntax (this commit)
Eval reduces (:string-get S I) to host (nth S I), which already returns
a one-character string for OCaml's char model.
Lets us write idiomatic OCaml string traversal:
let s = "hi" in
let n = ref 0 in
for i = 0 to String.length s - 1 do
n := !n + Char.code s.[i]
done;
!n (* = 209 *)
Side-quest emerged from adding roman.ml baseline (Roman numeral greedy
encoding): top-level 'let () = expr' was unsupported because
ocaml-parse-program's parse-decl-let consumed an ident strictly. Now
parse-decl-let recognises a leading '()' as a unit binding and
synthesises a __unit_NN name (matching how parse-let already handles
inner-let unit patterns).
roman.ml exercises:
* tuple list literal [(int * string); ...]
* recursive pattern match on tuple-cons
* String.length + List.fold_left
* the new top-level let () support (sanity in a comment, even though
the program ends with a bare expression for the test harness)
Bumped lib/ocaml/test.sh server timeout 180->360s — the recent surge in
test count plus a CPU-contended host was crowding out the sole epoch
reaching the deeper smarts.
Parser hk-parse-parens gains a `::` arm after the first inner expression:
consume `::`, parse a type via the existing hk-parse-type, expect `)`,
emit (:type-ann EXPR TYPE). Sections, tuples, parenthesised expressions
and unit `()` are unchanged.
Desugar drops the annotation — :type-ann E _ → (hk-desugar E) — since
the existing eval path has no type-directed dispatch. Phase 20 will
extend infer.sx to consume the annotation and unify against the
inferred type.
tests/parse-extras.sx (12/12) covers literal, arithmetic, function arg,
string, bool, tuple, nested annotation, function-typed annotation, and
no-regression checks for plain parens / 3-tuples / left+right sections.
eval (66/0), exceptions (14/0), typecheck (15/0), records (14/0), ioref
(13/0) all still clean.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Five "typed ok: …" tests in tests/typecheck.sx compared an unforced thunk
against an integer/list. The untyped-path convention is hk-deep-force on
the result; hk-run-typed follows the same shape but the tests omitted
that wrap. Added hk-deep-force around hk-run-typed in those five tests.
typecheck.sx now 15/15; infer.sx still 75/75.
Plan adds three phases capturing the remaining type-system work:
- Phase 20: Algorithm W gaps (case, do, record accessors, expression
annotations).
- Phase 21: type classes with qualified types ([Eq a] => …) and
constraint propagation, integrated with the existing dict-passing
evaluator.
- Phase 22: typecheck-then-run as the default conformance path, with a
≥ 30/36 typechecking threshold before swap.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
In parse-atom-postfix, after consuming '.', if the next token is '(',
parse the inner expression and emit (:let-open M EXPR) instead of
:field. Cleanly composes with the existing :let-open evaluator and
loops to allow chained dot postfixes.
List.(length [1;2;3]) = 3
List.(map (fun x -> x + 1) [1;2;3]) = [2;3;4]
Option.(map (fun x -> x * 10) (Some 4)) = Some 40
Parser detects 'let open' as a separate let-form, parses M as a path
(Ctor(.Ctor)*) directly via inline AST construction (no source slicing
since cur-pos is only available in ocaml-parse-program), and emits
(:let-open PATH BODY).
Eval resolves the path to a module dict and merges its bindings into
the env for body evaluation. Now:
let open List in map (fun x -> x * 2) [1;2;3] = [2;4;6]
let open Option in map (fun x -> x + 1) (Some 5) = Some 6
ocaml-eval-module now handles :def-mut and :def-rec-mut decls so
'module M = struct let rec a n = ... and b n = ... end' works. The
def-rec-mut version uses cell-based mutual recursion exactly as the
top-level version.
Graph BFS using Queue + Hashtbl visited-set + List.assoc_opt + List.iter.
Returns 6 for a graph where A reaches B/C/D/E/F. Demonstrates 4 stdlib
modules (Queue, Hashtbl, List) cooperating in a real algorithm.
let NAME [PARAMS] : T = expr and (expr : T) parse and skip the type
source. Runtime no-op since SX is dynamic. Works in inline let,
top-level let, and parenthesised expressions:
let x : int = 5 ;; x + 1 -> 6
let f (x : int) : int = x + 1 in f 41 -> 42
(5 : int) -> 5
((1 + 2) : int) * 3 -> 9
Parser: in parse-decl-type, dispatch on the post-= token:
'|' or Ctor -> sum type
'{' -> record type
otherwise -> type alias (skip to boundary)
AST (:type-alias NAME PARAMS) with body discarded. Runtime no-op since
SX has no nominal types.
poly_stack.ml baseline exercises:
module type ELEMENT = sig type t val show : t -> string end
module IntElem = struct type t = int let show x = ... end
module Make (E : ELEMENT) = struct ... use E.show ... end
module IntStack = Make(IntElem)
Demonstrates the substrate handles signature decls + abstract types +
functor parameter with sig constraint.
parse-try now consumes optional 'when GUARD-EXPR' before -> and emits
(:case-when PAT GUARD BODY). Eval try clause loop dispatches on case /
case-when and falls through on guard false — same semantics as match.
Examples:
try raise (E 5) with | E n when n > 0 -> n | _ -> 0 = 5
try raise (E (-3)) with | E n when n > 0 -> n | _ -> 0 = 0
try raise (E 5) with | E n when n > 100 -> n | E n -> n + 1000 = 1005
parse-function now consumes optional 'when GUARD-EXPR' before -> and
emits (:case-when PAT GUARD BODY) — same handling as match clauses.
function-style sign extraction now works:
(function | n when n > 0 -> 1 | n when n < 0 -> -1 | _ -> 0)
Group anagrams by canonical (sorted-chars) key using Hashtbl +
List.sort. Demonstrates char-by-char traversal via String.get + for-loop +
ref accumulator + Hashtbl as a multi-valued counter.
Untyped lambda calculus interpreter inside OCaml-on-SX:
type term = Var | Abs of string * term | App | Num of int
type value = VNum of int | VClos of string * term * env
let rec eval env t = match t with ...
(\x.\y.x) 7 99 = 7. The substrate handles two ADTs, recursive eval,
closure-based env, and pattern matching all written as a single
self-contained OCaml program — strong validation.
ocaml-type-of-program now handles :def-mut (sequential generalize) and
:def-rec-mut (pre-bind tvs, infer rhs, unify, generalize all, infer
body — same algorithm as the inline let-rec-mut version).
Mutual top-level recursion now type-checks:
let rec even n = ... and odd n = ...;; even 10 : Bool
let rec map f xs = ... and length lst = ...;; map :
('a -> 'b) -> 'a list -> 'b list
Memoized fibonacci using Hashtbl.find_opt + Hashtbl.add.
fib(25) = 75025. Demonstrates mutable Hashtbl through the OCaml
stdlib API in real recursive code.
4-queens via recursive backtracking + List.fold_left. Returns 2 (the
two solutions of 4-queens). Per-program timeout in run.sh bumped to
240s — the tree-walking interpreter is slow on heavy recursion but
correct.
The substrate handles full backtracking + safe-check recursion +
list-driven candidate enumeration end-to-end.
Counter-style record with two mutable fields. Validates the new
r.f <- v field mutation end-to-end through type decl + record literal
+ field access + field assignment + sequence operator.
type counter = { mutable count : int; mutable last : int }
let bump c = c.count <- c.count + 1 ; c.last <- c.count
After 5 bumps: count=5, last=5, sum=10.
<- added to op-table at level 1 (same as :=). Eval short-circuits on
<- to mutate the lhs's field via host SX dict-set!. The lhs must be a
:field expression; otherwise raises.
Tested:
let r = { x = 1; y = 2 } in r.x <- 5; r.x (5)
let r = { x = 0 } in for i = 1 to 5 do r.x <- r.x + i done; r.x (15)
let r = { name = ...; age = 30 } in r.name <- "Alice"; r.name
The 'mutable' keyword in record type decls is parsed-and-discarded;
runtime semantics: every field is mutable. Phase 2 closes this gap
without changing the dict-based record representation.
type r = { x : int; mutable y : string } parses to
(:type-def-record NAME PARAMS FIELDS) with FIELDS each (NAME) or
(:mutable NAME). Parser dispatches on { after = to parse field list.
Field-type sources are skipped (HM registration TBD). Runtime no-op
since records already work as dynamic dicts.
Polymorphic binary search tree with insert + in-order traversal.
Exercises parametric ADT (type 'a tree = Leaf | Node of 'a * 'a tree
* 'a tree), recursive match, List.append, List.fold_left.
Classic fizzbuzz using ref-cell accumulator, for-loop, mod, if/elseif
chain, String.concat, Int.to_string. Output verified via String.length
of the comma-joined result for n=15: 57.
print_string / print_endline / print_int / print_newline now route to
SX display primitive (not the non-existent print/println). print_endline
appends '\n'.
let _ = expr ;; at top level confirmed working via the
wildcard-param parser.
ocaml-infer-let-mut: each rhs inferred in parent env, generalized
sequentially before adding to body env.
ocaml-infer-let-rec-mut: pre-bind all names with fresh tvs; infer
each rhs against the joint env, unify each with its tv, then
generalize all and infer body.
Mutual recursion now type-checks:
let rec even n = if n = 0 then true else odd (n - 1)
and odd n = if n = 0 then false else even (n - 1)
in even : Int -> Bool
Option: join, to_result, some, none.
Result: value, iter, fold.
Bytes: length, get, of_string, to_string, concat, sub — thin alias of
String (SX has no separate immutable byte type).
Ordering fix: Bytes module placed after String so its closures capture
String in scope. Earlier draft put Bytes before String which made
String.* lookups fail with 'not a record/module' (treated as nullary
ctor).
Recursive-descent calculator parses '(1 + 2) * 3 + 4' = 13. Two parser
bugs fixed:
1. parse-let now handles inline 'let rec a () = ... and b () = ... in
body' via new (:let-rec-mut BINDINGS BODY) and (:let-mut BINDINGS
BODY) AST shapes; eval handles both.
2. has-matching-in? lookahead no longer stops at 'and' — 'and' is
internal to let-rec, not a decl boundary. Without this fix, the
inner 'let rec a () = ... and b () = ...' inside a let-decl rhs
would have been treated as the start of a new top-level decl.
Baseline exercises mutually-recursive functions, while-loops, ref-cell
imperative parsing, and ADT-based AST construction.
Parser fix: at-app-start? and parse-app's loop recognise prefix !
as a deref of the next app arg. So 'List.rev !b' parses as
'(:app List.rev (:deref b))' instead of stalling at !.
Buffer module backed by a ref holding string list:
create _ = ref []
add_string b s = b := s :: !b
contents b = String.concat "" (List.rev !b)
add_char/length/clear/reset
Uses Map.Make(StrOrd) + List.fold_left to count word frequencies;
exercises the full functor pipeline with a real-world idiom:
let inc_count m word =
match StrMap.find_opt word m with
| None -> StrMap.add word 1 m
| Some n -> StrMap.add word (n + 1) m
let count words = List.fold_left inc_count StrMap.empty words
10/10 baseline programs pass.
