coop/rose-ash
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Compare commits

base: coop:3a268e72773830770620eda7bbed46026ac39af4
Branches Tags
coop:main coop:architecture coop:wasm coop:macros coop:sx coop:exorcism coop:cssx coop:decoupling coop:sexpression coop:relations
...
compare: coop:macros
Branches Tags
coop:architecture coop:main coop:wasm coop:macros coop:sx coop:exorcism coop:cssx coop:decoupling coop:sexpression coop:relations

4 Commits
3a268e7277 ... macros

Author SHA1 Message Date
giles
5ab3ecb7e0 Add OCaml SX kernel build to sx_docs Docker image and enable in production
All checks were successful
Build and Deploy / build-and-deploy (push) Successful in 10m16s
Details 
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-03-15 23:34:50 +00:00
giles
313f7d6be1 OCaml bootstrapper Phase 2: HTML renderer, SX server, Python bridge 
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-03-15 23:28:48 +00:00
giles
16fa813d6d Add hosts/ocaml/_build/ to .gitignore 
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-03-15 20:52:43 +00:00
giles
818e5d53f0 OCaml bootstrapper: transpiler compiles full CEK evaluator (61/61 tests) 
SX-to-OCaml transpiler (transpiler.sx) generates sx_ref.ml (~90KB, ~135
mutually recursive functions) from the spec evaluator. Foundation tests
all pass: parser, primitives, env operations, type system.

Key design decisions:
- Env variant added to value type for CEK state dict storage
- Continuation carries optional data dict for captured frames
- Dynamic var tracking distinguishes OCaml fn calls from SX value dispatch
- Single let rec...and block for forward references between all defines
- Unused ref pre-declarations eliminated via let-bound name detection

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-03-15 20:51:59 +00:00
24 changed files with 5914 additions and 14 deletions
Expand all files Collapse all files

1
.gitignore vendored
View File

@@ -14,3 +14,4 @@ _debug/
sx-haskell/ sx-haskell/
sx-rust/ sx-rust/
shared/static/scripts/sx-full-test.js shared/static/scripts/sx-full-test.js
hosts/ocaml/_build/

4
docker-compose.dev-sx.yml
View File

@@ -13,6 +13,8 @@ services:
ENVIRONMENT: development ENVIRONMENT: development
RELOAD: "true" RELOAD: "true"
SX_USE_REF: "1" SX_USE_REF: "1"
SX_USE_OCAML: "1"
SX_OCAML_BIN: "/app/bin/sx_server"
SX_BOUNDARY_STRICT: "1" SX_BOUNDARY_STRICT: "1"
SX_DEV: "1" SX_DEV: "1"
volumes: volumes:
@@ -26,6 +28,8 @@ services:
- ./sx/sx:/app/sx - ./sx/sx:/app/sx
- ./sx/path_setup.py:/app/path_setup.py - ./sx/path_setup.py:/app/path_setup.py
- ./sx/entrypoint.sh:/usr/local/bin/entrypoint.sh - ./sx/entrypoint.sh:/usr/local/bin/entrypoint.sh
# OCaml SX kernel binary (built with: cd hosts/ocaml && eval $(opam env) && dune build)
- ./hosts/ocaml/_build/default/bin/sx_server.exe:/app/bin/sx_server:ro
- ./sx/__init__.py:/app/__init__.py:ro - ./sx/__init__.py:/app/__init__.py:ro
# sibling models for cross-domain SQLAlchemy imports # sibling models for cross-domain SQLAlchemy imports
- ./blog/__init__.py:/app/blog/__init__.py:ro - ./blog/__init__.py:/app/blog/__init__.py:ro

2
docker-compose.yml
View File

@@ -228,6 +228,8 @@ services:
<<: *app-env <<: *app-env
REDIS_URL: redis://redis:6379/10 REDIS_URL: redis://redis:6379/10
WORKERS: "1" WORKERS: "1"
SX_USE_OCAML: "1"
SX_OCAML_BIN: "/app/bin/sx_server"
db: db:
image: postgres:16 image: postgres:16

36
hosts/ocaml/bin/debug_set.ml Normal file
View File

@@ -0,0 +1,36 @@
module T = Sx.Sx_types
module P = Sx.Sx_parser
module R = Sx.Sx_ref
open T
let () =
let env = T.make_env () in
let eval src =
let exprs = P.parse_all src in
let result = ref Nil in
List.iter (fun e -> result := R.eval_expr e (Env env)) exprs;
!result
in
(* Test 1: basic set! in closure *)
let r = eval "(let ((x 0)) (set! x 42) x)" in
Printf.printf "basic set!: %s (expect 42)\n%!" (T.inspect r);
(* Test 2: set! through lambda call *)
let r = eval "(let ((x 0)) (let ((f (fn () (set! x 99)))) (f) x))" in
Printf.printf "set! via lambda: %s (expect 99)\n%!" (T.inspect r);
(* Test 3: counter pattern *)
let r = eval "(do (define make-counter (fn () (let ((c 0)) (fn () (set! c (+ c 1)) c)))) (let ((counter (make-counter))) (counter) (counter) (counter)))" in
Printf.printf "counter: %s (expect 3)\n%!" (T.inspect r);
(* Test 4: set! in for-each *)
let r = eval "(let ((total 0)) (for-each (fn (n) (set! total (+ total n))) (list 1 2 3 4 5)) total)" in
Printf.printf "set! in for-each: %s (expect 15)\n%!" (T.inspect r);
(* Test 5: append! in for-each *)
ignore (T.env_bind env "append!" (NativeFn ("append!", fun args ->
match args with
| [List items; v] -> List (items @ [v])
| _ -> raise (Eval_error "append!: expected list and value"))));
let r = eval "(let ((log (list))) (for-each (fn (x) (append! log x)) (list 1 2 3)) log)" in
Printf.printf "append! in for-each: %s (expect (1 2 3))\n%!" (T.inspect r)

3
hosts/ocaml/bin/dune Normal file
View File

@@ -0,0 +1,3 @@
(executables
(names run_tests debug_set sx_server)
(libraries sx))

1
hosts/ocaml/bin/dune_debug Normal file
View File

@@ -0,0 +1 @@
(executable (name debug_macro) (libraries sx))

701
hosts/ocaml/bin/run_tests.ml Normal file
View File

@@ -0,0 +1,701 @@
(** Test runner — runs the SX spec test suite against the transpiled CEK evaluator.
Provides the 5 platform functions required by test-framework.sx:
try-call, report-pass, report-fail, push-suite, pop-suite
Plus test helpers: sx-parse, cek-eval, env-*, equal?, etc.
Usage:
dune exec bin/run_tests.exe # foundation + spec tests
dune exec bin/run_tests.exe -- test-primitives # specific test
dune exec bin/run_tests.exe -- --foundation # foundation only *)
module Sx_types = Sx.Sx_types
module Sx_parser = Sx.Sx_parser
module Sx_primitives = Sx.Sx_primitives
module Sx_runtime = Sx.Sx_runtime
module Sx_ref = Sx.Sx_ref
module Sx_render = Sx.Sx_render
open Sx_types
open Sx_parser
open Sx_primitives
open Sx_runtime
open Sx_ref
(* ====================================================================== *)
(* Test state *)
(* ====================================================================== *)
let pass_count = ref 0
let fail_count = ref 0
let suite_stack : string list ref = ref []
(* ====================================================================== *)
(* Deep equality — SX structural comparison *)
(* ====================================================================== *)
let rec deep_equal a b =
match a, b with
| Nil, Nil -> true
| Bool a, Bool b -> a = b
| Number a, Number b -> a = b
| String a, String b -> a = b
| Symbol a, Symbol b -> a = b
| Keyword a, Keyword b -> a = b
| (List a | ListRef { contents = a }), (List b | ListRef { contents = b }) ->
List.length a = List.length b &&
List.for_all2 deep_equal a b
| Dict a, Dict b ->
let ka = Hashtbl.fold (fun k _ acc -> k :: acc) a [] in
let kb = Hashtbl.fold (fun k _ acc -> k :: acc) b [] in
List.length ka = List.length kb &&
List.for_all (fun k ->
Hashtbl.mem b k &&
deep_equal
(match Hashtbl.find_opt a k with Some v -> v | None -> Nil)
(match Hashtbl.find_opt b k with Some v -> v | None -> Nil)) ka
| Lambda _, Lambda _ -> a == b (* identity *)
| NativeFn _, NativeFn _ -> a == b
| _ -> false
(* ====================================================================== *)
(* Build evaluator environment with test platform functions *)
(* ====================================================================== *)
let make_test_env () =
let env = Sx_types.make_env () in
let bind name fn =
ignore (Sx_types.env_bind env name (NativeFn (name, fn)))
in
(* --- 5 platform functions required by test-framework.sx --- *)
bind "try-call" (fun args ->
match args with
| [thunk] ->
(try
(* Call the thunk: it's a lambda with no params *)
let result = eval_expr (List [thunk]) (Env env) in
ignore result;
let d = Hashtbl.create 2 in
Hashtbl.replace d "ok" (Bool true);
Dict d
with
| Eval_error msg ->
let d = Hashtbl.create 2 in
Hashtbl.replace d "ok" (Bool false);
Hashtbl.replace d "error" (String msg);
Dict d
| exn ->
let d = Hashtbl.create 2 in
Hashtbl.replace d "ok" (Bool false);
Hashtbl.replace d "error" (String (Printexc.to_string exn));
Dict d)
| _ -> raise (Eval_error "try-call: expected 1 arg"));
bind "report-pass" (fun args ->
match args with
| [String name] ->
incr pass_count;
let ctx = String.concat " > " (List.rev !suite_stack) in
Printf.printf " PASS: %s > %s\n%!" ctx name;
Nil
| [v] ->
incr pass_count;
let ctx = String.concat " > " (List.rev !suite_stack) in
Printf.printf " PASS: %s > %s\n%!" ctx (Sx_types.inspect v);
Nil
| _ -> raise (Eval_error "report-pass: expected 1 arg"));
bind "report-fail" (fun args ->
match args with
| [String name; String error] ->
incr fail_count;
let ctx = String.concat " > " (List.rev !suite_stack) in
Printf.printf " FAIL: %s > %s: %s\n%!" ctx name error;
Nil
| [name_v; error_v] ->
incr fail_count;
let ctx = String.concat " > " (List.rev !suite_stack) in
Printf.printf " FAIL: %s > %s: %s\n%!" ctx
(Sx_types.value_to_string name_v)
(Sx_types.value_to_string error_v);
Nil
| _ -> raise (Eval_error "report-fail: expected 2 args"));
bind "push-suite" (fun args ->
match args with
| [String name] ->
suite_stack := name :: !suite_stack;
let indent = String.make ((List.length !suite_stack - 1) * 2) ' ' in
Printf.printf "%sSuite: %s\n%!" indent name;
Nil
| [v] ->
let name = Sx_types.value_to_string v in
suite_stack := name :: !suite_stack;
let indent = String.make ((List.length !suite_stack - 1) * 2) ' ' in
Printf.printf "%sSuite: %s\n%!" indent name;
Nil
| _ -> raise (Eval_error "push-suite: expected 1 arg"));
bind "pop-suite" (fun _args ->
suite_stack := (match !suite_stack with _ :: t -> t | [] -> []);
Nil);
(* --- Test helpers --- *)
bind "sx-parse" (fun args ->
match args with
| [String s] -> List (parse_all s)
| _ -> raise (Eval_error "sx-parse: expected string"));
bind "sx-parse-one" (fun args ->
match args with
| [String s] ->
let exprs = parse_all s in
(match exprs with e :: _ -> e | [] -> Nil)
| _ -> raise (Eval_error "sx-parse-one: expected string"));
bind "cek-eval" (fun args ->
match args with
| [String s] ->
let exprs = parse_all s in
(match exprs with
| e :: _ -> eval_expr e (Env env)
| [] -> Nil)
| _ -> raise (Eval_error "cek-eval: expected string"));
bind "eval-expr-cek" (fun args ->
match args with
| [expr; e] -> eval_expr expr e
| [expr] -> eval_expr expr (Env env)
| _ -> raise (Eval_error "eval-expr-cek: expected 1-2 args"));
bind "test-env" (fun _args -> Env (Sx_types.env_extend env));
(* --- Environment operations --- *)
bind "env-get" (fun args ->
match args with
| [Env e; String k] -> Sx_types.env_get e k
| [Env e; Keyword k] -> Sx_types.env_get e k
| _ -> raise (Eval_error "env-get: expected env and string"));
bind "env-has?" (fun args ->
match args with
| [Env e; String k] -> Bool (Sx_types.env_has e k)
| [Env e; Keyword k] -> Bool (Sx_types.env_has e k)
| _ -> raise (Eval_error "env-has?: expected env and string"));
bind "env-bind!" (fun args ->
match args with
| [Env e; String k; v] -> Sx_types.env_bind e k v
| [Env e; Keyword k; v] -> Sx_types.env_bind e k v
| _ -> raise (Eval_error "env-bind!: expected env, key, value"));
bind "env-set!" (fun args ->
match args with
| [Env e; String k; v] -> Sx_types.env_set e k v
| [Env e; Keyword k; v] -> Sx_types.env_set e k v
| _ -> raise (Eval_error "env-set!: expected env, key, value"));
bind "env-extend" (fun args ->
match args with
| [Env e] -> Env (Sx_types.env_extend e)
| _ -> raise (Eval_error "env-extend: expected env"));
bind "env-merge" (fun args ->
match args with
| [Env a; Env b] -> Env (Sx_types.env_merge a b)
| _ -> raise (Eval_error "env-merge: expected 2 envs"));
(* --- Equality --- *)
bind "equal?" (fun args ->
match args with
| [a; b] -> Bool (deep_equal a b)
| _ -> raise (Eval_error "equal?: expected 2 args"));
bind "identical?" (fun args ->
match args with
| [a; b] -> Bool (a == b)
| _ -> raise (Eval_error "identical?: expected 2 args"));
(* --- Continuation support --- *)
bind "make-continuation" (fun args ->
match args with
| [f] ->
let k v = sx_call f [v] in
Continuation (k, None)
| _ -> raise (Eval_error "make-continuation: expected 1 arg"));
bind "continuation?" (fun args ->
match args with
| [Continuation _] -> Bool true
| [_] -> Bool false
| _ -> raise (Eval_error "continuation?: expected 1 arg"));
bind "continuation-fn" (fun args ->
match args with
| [Continuation (f, _)] -> NativeFn ("continuation-fn-result", fun args ->
match args with [v] -> f v | _ -> f Nil)
| _ -> raise (Eval_error "continuation-fn: expected continuation"));
(* --- Core builtins used by test framework / test code --- *)
bind "assert" (fun args ->
match args with
| [cond] ->
if not (sx_truthy cond) then raise (Eval_error "Assertion failed");
Bool true
| [cond; String msg] ->
if not (sx_truthy cond) then raise (Eval_error ("Assertion error: " ^ msg));
Bool true
| [cond; msg] ->
if not (sx_truthy cond) then
raise (Eval_error ("Assertion error: " ^ Sx_types.value_to_string msg));
Bool true
| _ -> raise (Eval_error "assert: expected 1-2 args"));
bind "append!" (fun args ->
match args with
| [ListRef r; v] -> r := !r @ [v]; ListRef r (* mutate in place *)
| [List items; v] -> List (items @ [v]) (* immutable fallback *)
| _ -> raise (Eval_error "append!: expected list and value"));
(* --- HTML Renderer (from sx_render.ml library module) --- *)
Sx.Sx_render.setup_render_env env;
(* --- Missing primitives referenced by tests --- *)
bind "upcase" (fun args ->
match args with
| [String s] -> String (String.uppercase_ascii s)
| _ -> raise (Eval_error "upcase: expected string"));
bind "downcase" (fun args ->
match args with
| [String s] -> String (String.lowercase_ascii s)
| _ -> raise (Eval_error "downcase: expected string"));
bind "make-keyword" (fun args ->
match args with
| [String s] -> Keyword s
| _ -> raise (Eval_error "make-keyword: expected string"));
bind "string-length" (fun args ->
match args with
| [String s] -> Number (float_of_int (String.length s))
| _ -> raise (Eval_error "string-length: expected string"));
bind "dict-get" (fun args ->
match args with
| [Dict d; String k] -> Sx_types.dict_get d k
| [Dict d; Keyword k] -> Sx_types.dict_get d k
| _ -> raise (Eval_error "dict-get: expected dict and key"));
bind "apply" (fun args ->
match args with
| f :: rest ->
let all_args = match List.rev rest with
| List last :: prefix -> List.rev prefix @ last
| _ -> rest
in
sx_call f all_args
| _ -> raise (Eval_error "apply: expected function and args"));
(* --- Type system helpers (for --full tests) --- *)
bind "test-prim-types" (fun _args ->
let d = Hashtbl.create 40 in
List.iter (fun (k, v) -> Hashtbl.replace d k (String v)) [
"+", "number"; "-", "number"; "*", "number"; "/", "number";
"mod", "number"; "inc", "number"; "dec", "number";
"abs", "number"; "min", "number"; "max", "number";
"floor", "number"; "ceil", "number"; "round", "number";
"str", "string"; "upper", "string"; "lower", "string";
"trim", "string"; "join", "string"; "replace", "string";
"format", "string"; "substr", "string";
"=", "boolean"; "<", "boolean"; ">", "boolean";
"<=", "boolean"; ">=", "boolean"; "!=", "boolean";
"not", "boolean"; "nil?", "boolean"; "empty?", "boolean";
"number?", "boolean"; "string?", "boolean"; "boolean?", "boolean";
"list?", "boolean"; "dict?", "boolean"; "symbol?", "boolean";
"keyword?", "boolean"; "contains?", "boolean"; "has-key?", "boolean";
"starts-with?", "boolean"; "ends-with?", "boolean";
"len", "number"; "first", "any"; "rest", "list";
"last", "any"; "nth", "any"; "cons", "list";
"append", "list"; "concat", "list"; "reverse", "list";
"sort", "list"; "slice", "list"; "range", "list";
"flatten", "list"; "keys", "list"; "vals", "list";
"map-dict", "dict"; "assoc", "dict"; "dissoc", "dict";
"merge", "dict"; "dict", "dict";
"get", "any"; "type-of", "string";
];
Dict d);
bind "test-prim-param-types" (fun _args ->
let d = Hashtbl.create 10 in
let pos name typ =
let d2 = Hashtbl.create 2 in
Hashtbl.replace d2 "positional" (List [List [String name; String typ]]);
Hashtbl.replace d2 "rest-type" Nil;
Dict d2
in
let pos_rest name typ rt =
let d2 = Hashtbl.create 2 in
Hashtbl.replace d2 "positional" (List [List [String name; String typ]]);
Hashtbl.replace d2 "rest-type" (String rt);
Dict d2
in
Hashtbl.replace d "+" (pos_rest "a" "number" "number");
Hashtbl.replace d "-" (pos_rest "a" "number" "number");
Hashtbl.replace d "*" (pos_rest "a" "number" "number");
Hashtbl.replace d "/" (pos_rest "a" "number" "number");
Hashtbl.replace d "inc" (pos "n" "number");
Hashtbl.replace d "dec" (pos "n" "number");
Hashtbl.replace d "upper" (pos "s" "string");
Hashtbl.replace d "lower" (pos "s" "string");
Hashtbl.replace d "keys" (pos "d" "dict");
Hashtbl.replace d "vals" (pos "d" "dict");
Dict d);
(* --- Component accessors --- *)
bind "component-param-types" (fun _args -> Nil);
bind "component-set-param-types!" (fun _args -> Nil);
bind "component-params" (fun args ->
match args with
| [Component c] -> List (List.map (fun s -> String s) c.c_params)
| _ -> Nil);
bind "component-body" (fun args ->
match args with
| [Component c] -> c.c_body
| _ -> Nil);
bind "component-has-children" (fun args ->
match args with
| [Component c] -> Bool c.c_has_children
| _ -> Bool false);
bind "component-affinity" (fun args ->
match args with
| [Component c] -> String c.c_affinity
| _ -> String "auto");
(* --- Parser test helpers --- *)
bind "keyword-name" (fun args ->
match args with
| [Keyword k] -> String k
| _ -> raise (Eval_error "keyword-name: expected keyword"));
bind "symbol-name" (fun args ->
match args with
| [Symbol s] -> String s
| _ -> raise (Eval_error "symbol-name: expected symbol"));
bind "sx-serialize" (fun args ->
match args with
| [v] -> String (Sx_types.inspect v)
| _ -> raise (Eval_error "sx-serialize: expected 1 arg"));
(* --- make-symbol --- *)
bind "make-symbol" (fun args ->
match args with
| [String s] -> Symbol s
| [v] -> Symbol (Sx_types.value_to_string v)
| _ -> raise (Eval_error "make-symbol: expected 1 arg"));
(* --- CEK stepping / introspection --- *)
bind "make-cek-state" (fun args ->
match args with
| [ctrl; env'; kont] -> Sx_ref.make_cek_state ctrl env' kont
| _ -> raise (Eval_error "make-cek-state: expected 3 args"));
bind "cek-step" (fun args ->
match args with
| [state] -> Sx_ref.cek_step state
| _ -> raise (Eval_error "cek-step: expected 1 arg"));
bind "cek-phase" (fun args ->
match args with
| [state] -> Sx_ref.cek_phase state
| _ -> raise (Eval_error "cek-phase: expected 1 arg"));
bind "cek-value" (fun args ->
match args with
| [state] -> Sx_ref.cek_value state
| _ -> raise (Eval_error "cek-value: expected 1 arg"));
bind "cek-terminal?" (fun args ->
match args with
| [state] -> Sx_ref.cek_terminal_p state
| _ -> raise (Eval_error "cek-terminal?: expected 1 arg"));
bind "cek-kont" (fun args ->
match args with
| [state] -> Sx_ref.cek_kont state
| _ -> raise (Eval_error "cek-kont: expected 1 arg"));
bind "frame-type" (fun args ->
match args with
| [frame] -> Sx_ref.frame_type frame
| _ -> raise (Eval_error "frame-type: expected 1 arg"));
(* --- Strict mode --- *)
(* *strict* is a plain value in the env, mutated via env_set by set-strict! *)
ignore (Sx_types.env_bind env "*strict*" (Bool false));
ignore (Sx_types.env_bind env "*prim-param-types*" Nil);
bind "set-strict!" (fun args ->
match args with
| [v] ->
Sx_ref._strict_ref := v;
ignore (Sx_types.env_set env "*strict*" v); Nil
| _ -> raise (Eval_error "set-strict!: expected 1 arg"));
bind "set-prim-param-types!" (fun args ->
match args with
| [v] ->
Sx_ref._prim_param_types_ref := v;
ignore (Sx_types.env_set env "*prim-param-types*" v); Nil
| _ -> raise (Eval_error "set-prim-param-types!: expected 1 arg"));
bind "value-matches-type?" (fun args ->
match args with
| [v; String expected] -> Sx_ref.value_matches_type_p v (String expected)
| _ -> raise (Eval_error "value-matches-type?: expected value and type string"));
env
(* ====================================================================== *)
(* Foundation tests (direct, no evaluator) *)
(* ====================================================================== *)
let run_foundation_tests () =
Printf.printf "=== SX OCaml Foundation Tests ===\n\n";
let assert_eq name expected actual =
if deep_equal expected actual then begin
incr pass_count;
Printf.printf " PASS: %s\n" name
end else begin
incr fail_count;
Printf.printf " FAIL: %s — expected %s, got %s\n" name
(Sx_types.inspect expected) (Sx_types.inspect actual)
end
in
let assert_true name v =
if sx_truthy v then begin
incr pass_count;
Printf.printf " PASS: %s\n" name
end else begin
incr fail_count;
Printf.printf " FAIL: %s — expected truthy, got %s\n" name (Sx_types.inspect v)
end
in
let call name args =
match Hashtbl.find_opt primitives name with
| Some f -> f args
| None -> failwith ("Unknown primitive: " ^ name)
in
Printf.printf "Suite: parser\n";
assert_eq "number" (Number 42.0) (List.hd (parse_all "42"));
assert_eq "string" (String "hello") (List.hd (parse_all "\"hello\""));
assert_eq "bool true" (Bool true) (List.hd (parse_all "true"));
assert_eq "nil" Nil (List.hd (parse_all "nil"));
assert_eq "keyword" (Keyword "class") (List.hd (parse_all ":class"));
assert_eq "symbol" (Symbol "foo") (List.hd (parse_all "foo"));
assert_eq "list" (List [Symbol "+"; Number 1.0; Number 2.0]) (List.hd (parse_all "(+ 1 2)"));
(match List.hd (parse_all "(div :class \"card\" (p \"hi\"))") with
| List [Symbol "div"; Keyword "class"; String "card"; List [Symbol "p"; String "hi"]] ->
incr pass_count; Printf.printf " PASS: nested list\n"
| v -> incr fail_count; Printf.printf " FAIL: nested list — got %s\n" (Sx_types.inspect v));
(match List.hd (parse_all "'(1 2 3)") with
| List [Symbol "quote"; List [Number 1.0; Number 2.0; Number 3.0]] ->
incr pass_count; Printf.printf " PASS: quote sugar\n"
| v -> incr fail_count; Printf.printf " FAIL: quote sugar — got %s\n" (Sx_types.inspect v));
(match List.hd (parse_all "{:a 1 :b 2}") with
| Dict d when dict_has d "a" && dict_has d "b" ->
incr pass_count; Printf.printf " PASS: dict literal\n"
| v -> incr fail_count; Printf.printf " FAIL: dict literal — got %s\n" (Sx_types.inspect v));
assert_eq "comment" (Number 42.0) (List.hd (parse_all ";; comment\n42"));
assert_eq "string escape" (String "hello\nworld") (List.hd (parse_all "\"hello\\nworld\""));
assert_eq "multiple exprs" (Number 2.0) (Number (float_of_int (List.length (parse_all "(1 2 3) (4 5)"))));
Printf.printf "\nSuite: primitives\n";
assert_eq "+" (Number 6.0) (call "+" [Number 1.0; Number 2.0; Number 3.0]);
assert_eq "-" (Number 3.0) (call "-" [Number 5.0; Number 2.0]);
assert_eq "*" (Number 12.0) (call "*" [Number 3.0; Number 4.0]);
assert_eq "/" (Number 2.5) (call "/" [Number 5.0; Number 2.0]);
assert_eq "mod" (Number 1.0) (call "mod" [Number 5.0; Number 2.0]);
assert_eq "inc" (Number 6.0) (call "inc" [Number 5.0]);
assert_eq "abs" (Number 5.0) (call "abs" [Number (-5.0)]);
assert_true "=" (call "=" [Number 1.0; Number 1.0]);
assert_true "!=" (call "!=" [Number 1.0; Number 2.0]);
assert_true "<" (call "<" [Number 1.0; Number 2.0]);
assert_true ">" (call ">" [Number 2.0; Number 1.0]);
assert_true "nil?" (call "nil?" [Nil]);
assert_true "number?" (call "number?" [Number 1.0]);
assert_true "string?" (call "string?" [String "hi"]);
assert_true "list?" (call "list?" [List [Number 1.0]]);
assert_true "empty? list" (call "empty?" [List []]);
assert_true "empty? string" (call "empty?" [String ""]);
assert_eq "str" (String "hello42") (call "str" [String "hello"; Number 42.0]);
assert_eq "upper" (String "HI") (call "upper" [String "hi"]);
assert_eq "trim" (String "hi") (call "trim" [String " hi "]);
assert_eq "join" (String "a,b,c") (call "join" [String ","; List [String "a"; String "b"; String "c"]]);
assert_true "starts-with?" (call "starts-with?" [String "hello"; String "hel"]);
assert_true "contains?" (call "contains?" [List [Number 1.0; Number 2.0; Number 3.0]; Number 2.0]);
assert_eq "list" (List [Number 1.0; Number 2.0]) (call "list" [Number 1.0; Number 2.0]);
assert_eq "len" (Number 3.0) (call "len" [List [Number 1.0; Number 2.0; Number 3.0]]);
assert_eq "first" (Number 1.0) (call "first" [List [Number 1.0; Number 2.0]]);
assert_eq "rest" (List [Number 2.0; Number 3.0]) (call "rest" [List [Number 1.0; Number 2.0; Number 3.0]]);
assert_eq "nth" (Number 2.0) (call "nth" [List [Number 1.0; Number 2.0]; Number 1.0]);
assert_eq "cons" (List [Number 0.0; Number 1.0]) (call "cons" [Number 0.0; List [Number 1.0]]);
assert_eq "append" (List [Number 1.0; Number 2.0; Number 3.0])
(call "append" [List [Number 1.0]; List [Number 2.0; Number 3.0]]);
assert_eq "reverse" (List [Number 3.0; Number 2.0; Number 1.0])
(call "reverse" [List [Number 1.0; Number 2.0; Number 3.0]]);
assert_eq "range" (List [Number 0.0; Number 1.0; Number 2.0]) (call "range" [Number 3.0]);
assert_eq "slice" (List [Number 2.0; Number 3.0])
(call "slice" [List [Number 1.0; Number 2.0; Number 3.0]; Number 1.0]);
assert_eq "type-of" (String "number") (call "type-of" [Number 1.0]);
assert_eq "type-of nil" (String "nil") (call "type-of" [Nil]);
Printf.printf "\nSuite: env\n";
let e = Sx_types.make_env () in
ignore (Sx_types.env_bind e "x" (Number 42.0));
assert_eq "env-bind + get" (Number 42.0) (Sx_types.env_get e "x");
assert_true "env-has" (Bool (Sx_types.env_has e "x"));
let child = Sx_types.env_extend e in
ignore (Sx_types.env_bind child "y" (Number 10.0));
assert_eq "child sees parent" (Number 42.0) (Sx_types.env_get child "x");
assert_eq "child own binding" (Number 10.0) (Sx_types.env_get child "y");
ignore (Sx_types.env_set child "x" (Number 99.0));
assert_eq "set! walks chain" (Number 99.0) (Sx_types.env_get e "x");
Printf.printf "\nSuite: types\n";
assert_true "sx_truthy true" (Bool (sx_truthy (Bool true)));
assert_true "sx_truthy 0" (Bool (sx_truthy (Number 0.0)));
assert_true "sx_truthy \"\"" (Bool (sx_truthy (String "")));
assert_eq "not truthy nil" (Bool false) (Bool (sx_truthy Nil));
assert_eq "not truthy false" (Bool false) (Bool (sx_truthy (Bool false)));
let l = { l_params = ["x"]; l_body = Symbol "x"; l_closure = Sx_types.make_env (); l_name = None } in
assert_true "is_lambda" (Bool (Sx_types.is_lambda (Lambda l)));
ignore (Sx_types.set_lambda_name (Lambda l) "my-fn");
assert_eq "lambda name mutated" (String "my-fn") (lambda_name (Lambda l))
(* ====================================================================== *)
(* Spec test runner *)
(* ====================================================================== *)
let run_spec_tests env test_files =
(* Find project root: walk up from cwd until we find spec/tests *)
let rec find_root dir =
let candidate = Filename.concat dir "spec/tests" in
if Sys.file_exists candidate then dir
else
let parent = Filename.dirname dir in
if parent = dir then Sys.getcwd () (* reached filesystem root *)
else find_root parent
in
let project_dir = find_root (Sys.getcwd ()) in
let spec_tests_dir = Filename.concat project_dir "spec/tests" in
let framework_path = Filename.concat spec_tests_dir "test-framework.sx" in
if not (Sys.file_exists framework_path) then begin
Printf.eprintf "test-framework.sx not found at %s\n" framework_path;
Printf.eprintf "Run from the project root directory.\n";
exit 1
end;
let load_and_eval path =
let ic = open_in path in
let n = in_channel_length ic in
let s = Bytes.create n in
really_input ic s 0 n;
close_in ic;
let src = Bytes.to_string s in
let exprs = parse_all src in
List.iter (fun expr ->
ignore (eval_expr expr (Env env))
) exprs
in
Printf.printf "\nLoading test framework...\n%!";
load_and_eval framework_path;
(* Determine test files *)
let files = if test_files = [] then begin
let entries = Sys.readdir spec_tests_dir in
Array.sort String.compare entries;
let requires_full = ["test-continuations.sx"; "test-types.sx"; "test-freeze.sx";
"test-continuations-advanced.sx"; "test-signals-advanced.sx"] in
Array.to_list entries
|> List.filter (fun f ->
String.length f > 5 &&
String.sub f 0 5 = "test-" &&
Filename.check_suffix f ".sx" &&
f <> "test-framework.sx" &&
not (List.mem f requires_full))
end else
List.map (fun name ->
if Filename.check_suffix name ".sx" then name
else name ^ ".sx") test_files
in
List.iter (fun name ->
let path = Filename.concat spec_tests_dir name in
if Sys.file_exists path then begin
Printf.printf "\n%s\n" (String.make 60 '=');
Printf.printf "Running %s\n" name;
Printf.printf "%s\n%!" (String.make 60 '=');
(try
load_and_eval path
with
| Eval_error msg ->
incr fail_count;
Printf.printf " ERROR in %s: %s\n%!" name msg
| exn ->
incr fail_count;
Printf.printf " ERROR in %s: %s\n%!" name (Printexc.to_string exn))
end else
Printf.eprintf "Test file not found: %s\n" path
) files
(* ====================================================================== *)
(* Main *)
(* ====================================================================== *)
let () =
let args = Array.to_list Sys.argv |> List.tl in
let foundation_only = List.mem "--foundation" args in
let test_files = List.filter (fun a -> not (String.length a > 0 && a.[0] = '-')) args in
(* Always run foundation tests *)
run_foundation_tests ();
if not foundation_only then begin
Printf.printf "\n=== SX Spec Tests (CEK Evaluator) ===\n%!";
let env = make_test_env () in
run_spec_tests env test_files
end;
(* Summary *)
Printf.printf "\n%s\n" (String.make 60 '=');
Printf.printf "Results: %d passed, %d failed\n" !pass_count !fail_count;
Printf.printf "%s\n" (String.make 60 '=');
if !fail_count > 0 then exit 1

427
hosts/ocaml/bin/sx_server.ml Normal file
View File

@@ -0,0 +1,427 @@
(** SX coroutine subprocess server.
Persistent process that accepts commands on stdin and writes
responses on stdout. All messages are single-line SX expressions,
newline-delimited.
Protocol:
Python → OCaml: (ping), (load path), (load-source src),
(eval src), (render src), (reset),
(io-response value)
OCaml → Python: (ready), (ok), (ok value), (error msg),
(io-request name args...)
IO primitives (query, action, request-arg, request-method, ctx)
yield (io-request ...) and block on stdin for (io-response ...). *)
module Sx_types = Sx.Sx_types
module Sx_parser = Sx.Sx_parser
module Sx_primitives = Sx.Sx_primitives
module Sx_runtime = Sx.Sx_runtime
module Sx_ref = Sx.Sx_ref
module Sx_render = Sx.Sx_render
open Sx_types
(* ====================================================================== *)
(* Output helpers *)
(* ====================================================================== *)
(** Escape a string for embedding in an SX string literal. *)
let escape_sx_string s =
let buf = Buffer.create (String.length s + 16) in
String.iter (function
| '"' -> Buffer.add_string buf "\\\""
| '\\' -> Buffer.add_string buf "\\\\"
| '\n' -> Buffer.add_string buf "\\n"
| '\r' -> Buffer.add_string buf "\\r"
| '\t' -> Buffer.add_string buf "\\t"
| c -> Buffer.add_char buf c) s;
Buffer.contents buf
(** Serialize a value to SX text (for io-request args). *)
let rec serialize_value = function
| Nil -> "nil"
| Bool true -> "true"
| Bool false -> "false"
| Number n ->
if Float.is_integer n then string_of_int (int_of_float n)
else Printf.sprintf "%g" n
| String s -> "\"" ^ escape_sx_string s ^ "\""
| Symbol s -> s
| Keyword k -> ":" ^ k
| List items | ListRef { contents = items } ->
"(list " ^ String.concat " " (List.map serialize_value items) ^ ")"
| Dict d ->
let pairs = Hashtbl.fold (fun k v acc ->
(Printf.sprintf ":%s %s" k (serialize_value v)) :: acc) d [] in
"{" ^ String.concat " " pairs ^ "}"
| RawHTML s -> "\"" ^ escape_sx_string s ^ "\""
| _ -> "nil"
let send line =
print_string line;
print_char '\n';
flush stdout
let send_ok () = send "(ok)"
let send_ok_value v = send (Printf.sprintf "(ok %s)" (serialize_value v))
let send_ok_string s = send (Printf.sprintf "(ok \"%s\")" (escape_sx_string s))
let send_error msg = send (Printf.sprintf "(error \"%s\")" (escape_sx_string msg))
(* ====================================================================== *)
(* IO bridge — primitives that yield to Python *)
(* ====================================================================== *)
(** Read a line from stdin (blocking). *)
let read_line_blocking () =
try Some (input_line stdin)
with End_of_file -> None
(** Send an io-request and block until io-response arrives. *)
let io_request name args =
let args_str = String.concat " " (List.map serialize_value args) in
send (Printf.sprintf "(io-request \"%s\" %s)" name args_str);
(* Block on stdin for io-response *)
match read_line_blocking () with
| None -> raise (Eval_error "IO bridge: stdin closed while waiting for io-response")
| Some line ->
let exprs = Sx_parser.parse_all line in
match exprs with
| [List [Symbol "io-response"; value]] -> value
| [List (Symbol "io-response" :: values)] ->
(match values with
| [v] -> v
| _ -> List values)
| _ -> raise (Eval_error ("IO bridge: unexpected response: " ^ line))
(** Bind IO primitives into the environment. *)
let setup_io_env env =
let bind name fn =
ignore (env_bind env name (NativeFn (name, fn)))
in
bind "query" (fun args ->
match args with
| service :: query_name :: rest ->
io_request "query" (service :: query_name :: rest)
| _ -> raise (Eval_error "query: expected (query service name ...)"));
bind "action" (fun args ->
match args with
| service :: action_name :: rest ->
io_request "action" (service :: action_name :: rest)
| _ -> raise (Eval_error "action: expected (action service name ...)"));
bind "request-arg" (fun args ->
match args with
| [name] -> io_request "request-arg" [name]
| _ -> raise (Eval_error "request-arg: expected 1 arg"));
bind "request-method" (fun _args ->
io_request "request-method" []);
bind "ctx" (fun args ->
match args with
| [key] -> io_request "ctx" [key]
| _ -> raise (Eval_error "ctx: expected 1 arg"))
(* ====================================================================== *)
(* Environment setup *)
(* ====================================================================== *)
let make_server_env () =
let env = make_env () in
(* Evaluator bindings — same as run_tests.ml's make_test_env,
but only the ones needed for rendering (not test helpers). *)
let bind name fn =
ignore (env_bind env name (NativeFn (name, fn)))
in
bind "assert" (fun args ->
match args with
| [cond] ->
if not (sx_truthy cond) then raise (Eval_error "Assertion failed");
Bool true
| [cond; String msg] ->
if not (sx_truthy cond) then raise (Eval_error ("Assertion error: " ^ msg));
Bool true
| [cond; msg] ->
if not (sx_truthy cond) then
raise (Eval_error ("Assertion error: " ^ value_to_string msg));
Bool true
| _ -> raise (Eval_error "assert: expected 1-2 args"));
bind "append!" (fun args ->
match args with
| [ListRef r; v] -> r := !r @ [v]; ListRef r
| [List items; v] -> List (items @ [v])
| _ -> raise (Eval_error "append!: expected list and value"));
(* HTML renderer *)
Sx_render.setup_render_env env;
(* Missing primitives that may be referenced *)
bind "upcase" (fun args ->
match args with
| [String s] -> String (String.uppercase_ascii s)
| _ -> raise (Eval_error "upcase: expected string"));
bind "downcase" (fun args ->
match args with
| [String s] -> String (String.lowercase_ascii s)
| _ -> raise (Eval_error "downcase: expected string"));
bind "make-keyword" (fun args ->
match args with
| [String s] -> Keyword s
| _ -> raise (Eval_error "make-keyword: expected string"));
bind "string-length" (fun args ->
match args with
| [String s] -> Number (float_of_int (String.length s))
| _ -> raise (Eval_error "string-length: expected string"));
bind "dict-get" (fun args ->
match args with
| [Dict d; String k] -> dict_get d k
| [Dict d; Keyword k] -> dict_get d k
| _ -> raise (Eval_error "dict-get: expected dict and key"));
bind "apply" (fun args ->
match args with
| f :: rest ->
let all_args = match List.rev rest with
| List last :: prefix -> List.rev prefix @ last
| _ -> rest
in
Sx_runtime.sx_call f all_args
| _ -> raise (Eval_error "apply: expected function and args"));
bind "equal?" (fun args ->
match args with
| [a; b] -> Bool (a = b)
| _ -> raise (Eval_error "equal?: expected 2 args"));
bind "identical?" (fun args ->
match args with
| [a; b] -> Bool (a == b)
| _ -> raise (Eval_error "identical?: expected 2 args"));
bind "make-continuation" (fun args ->
match args with
| [f] ->
let k v = Sx_runtime.sx_call f [v] in
Continuation (k, None)
| _ -> raise (Eval_error "make-continuation: expected 1 arg"));
bind "continuation?" (fun args ->
match args with
| [Continuation _] -> Bool true
| [_] -> Bool false
| _ -> raise (Eval_error "continuation?: expected 1 arg"));
bind "make-symbol" (fun args ->
match args with
| [String s] -> Symbol s
| [v] -> Symbol (value_to_string v)
| _ -> raise (Eval_error "make-symbol: expected 1 arg"));
bind "sx-serialize" (fun args ->
match args with
| [v] -> String (inspect v)
| _ -> raise (Eval_error "sx-serialize: expected 1 arg"));
(* Env operations *)
bind "env-get" (fun args ->
match args with
| [Env e; String k] -> env_get e k
| [Env e; Keyword k] -> env_get e k
| _ -> raise (Eval_error "env-get: expected env and string"));
bind "env-has?" (fun args ->
match args with
| [Env e; String k] -> Bool (env_has e k)
| [Env e; Keyword k] -> Bool (env_has e k)
| _ -> raise (Eval_error "env-has?: expected env and string"));
bind "env-bind!" (fun args ->
match args with
| [Env e; String k; v] -> env_bind e k v
| [Env e; Keyword k; v] -> env_bind e k v
| _ -> raise (Eval_error "env-bind!: expected env, key, value"));
bind "env-set!" (fun args ->
match args with
| [Env e; String k; v] -> env_set e k v
| [Env e; Keyword k; v] -> env_set e k v
| _ -> raise (Eval_error "env-set!: expected env, key, value"));
bind "env-extend" (fun args ->
match args with
| [Env e] -> Env (env_extend e)
| _ -> raise (Eval_error "env-extend: expected env"));
bind "env-merge" (fun args ->
match args with
| [Env a; Env b] -> Env (env_merge a b)
| _ -> raise (Eval_error "env-merge: expected 2 envs"));
(* Strict mode state *)
ignore (env_bind env "*strict*" (Bool false));
ignore (env_bind env "*prim-param-types*" Nil);
bind "set-strict!" (fun args ->
match args with
| [v] ->
Sx_ref._strict_ref := v;
ignore (env_set env "*strict*" v); Nil
| _ -> raise (Eval_error "set-strict!: expected 1 arg"));
bind "set-prim-param-types!" (fun args ->
match args with
| [v] ->
Sx_ref._prim_param_types_ref := v;
ignore (env_set env "*prim-param-types*" v); Nil
| _ -> raise (Eval_error "set-prim-param-types!: expected 1 arg"));
bind "component-param-types" (fun _args -> Nil);
bind "component-set-param-types!" (fun _args -> Nil);
bind "component-params" (fun args ->
match args with
| [Component c] -> List (List.map (fun s -> String s) c.c_params)
| _ -> Nil);
bind "component-body" (fun args ->
match args with
| [Component c] -> c.c_body
| _ -> Nil);
bind "component-has-children" (fun args ->
match args with
| [Component c] -> Bool c.c_has_children
| _ -> Bool false);
bind "component-affinity" (fun args ->
match args with
| [Component c] -> String c.c_affinity
| _ -> String "auto");
bind "keyword-name" (fun args ->
match args with
| [Keyword k] -> String k
| _ -> raise (Eval_error "keyword-name: expected keyword"));
bind "symbol-name" (fun args ->
match args with
| [Symbol s] -> String s
| _ -> raise (Eval_error "symbol-name: expected symbol"));
(* IO primitives *)
setup_io_env env;
env
(* ====================================================================== *)
(* Command dispatch *)
(* ====================================================================== *)
let dispatch env cmd =
match cmd with
| List [Symbol "ping"] ->
send_ok_string "ocaml-cek"
| List [Symbol "load"; String path] ->
(try
let exprs = Sx_parser.parse_file path in
let count = ref 0 in
List.iter (fun expr ->
ignore (Sx_ref.eval_expr expr (Env env));
incr count
) exprs;
send_ok_value (Number (float_of_int !count))
with
| Eval_error msg -> send_error msg
| Sys_error msg -> send_error ("File error: " ^ msg)
| exn -> send_error (Printexc.to_string exn))
| List [Symbol "load-source"; String src] ->
(try
let exprs = Sx_parser.parse_all src in
let count = ref 0 in
List.iter (fun expr ->
ignore (Sx_ref.eval_expr expr (Env env));
incr count
) exprs;
send_ok_value (Number (float_of_int !count))
with
| Eval_error msg -> send_error msg
| exn -> send_error (Printexc.to_string exn))
| List [Symbol "eval"; String src] ->
(try
let exprs = Sx_parser.parse_all src in
let result = List.fold_left (fun _acc expr ->
Sx_ref.eval_expr expr (Env env)
) Nil exprs in
send_ok_value result
with
| Eval_error msg -> send_error msg
| exn -> send_error (Printexc.to_string exn))
| List [Symbol "render"; String src] ->
(try
let exprs = Sx_parser.parse_all src in
let expr = match exprs with
| [e] -> e
| [] -> Nil
| _ -> List (Symbol "do" :: exprs)
in
let html = Sx_render.render_to_html expr env in
send_ok_string html
with
| Eval_error msg -> send_error msg
| exn -> send_error (Printexc.to_string exn))
| List [Symbol "reset"] ->
(* Clear all bindings and rebuild env.
We can't reassign env, so clear and re-populate. *)
Hashtbl.clear env.bindings;
let fresh = make_server_env () in
Hashtbl.iter (fun k v -> Hashtbl.replace env.bindings k v) fresh.bindings;
send_ok ()
| _ ->
send_error ("Unknown command: " ^ inspect cmd)
(* ====================================================================== *)
(* Main loop *)
(* ====================================================================== *)
let () =
let env = make_server_env () in
send "(ready)";
(* Main command loop *)
try
while true do
match read_line_blocking () with
| None -> exit 0 (* stdin closed *)
| Some line ->
let line = String.trim line in
if line = "" then () (* skip blank lines *)
else begin
let exprs = Sx_parser.parse_all line in
match exprs with
| [cmd] -> dispatch env cmd
| _ -> send_error ("Expected single command, got " ^ string_of_int (List.length exprs))
end
done
with
| End_of_file -> ()

150
hosts/ocaml/bootstrap.py Normal file
View File

@@ -0,0 +1,150 @@
#!/usr/bin/env python3
"""
Bootstrap compiler: SX spec -> OCaml.
Loads the SX-to-OCaml transpiler (transpiler.sx), feeds it the spec files,
and produces sx_ref.ml — the transpiled evaluator as native OCaml.
Usage:
python3 hosts/ocaml/bootstrap.py --output hosts/ocaml/lib/sx_ref.ml
"""
from __future__ import annotations
import os
import sys
_HERE = os.path.dirname(os.path.abspath(__file__))
_PROJECT = os.path.abspath(os.path.join(_HERE, "..", ".."))
sys.path.insert(0, _PROJECT)
from shared.sx.parser import parse_all
from shared.sx.types import Symbol
def extract_defines(source: str) -> list[tuple[str, list]]:
"""Parse .sx source, return list of (name, define-expr) for top-level defines."""
exprs = parse_all(source)
defines = []
for expr in exprs:
if isinstance(expr, list) and expr and isinstance(expr[0], Symbol):
if expr[0].name == "define":
name = expr[1].name if isinstance(expr[1], Symbol) else str(expr[1])
defines.append((name, expr))
return defines
# OCaml preamble — opens and runtime helpers
PREAMBLE = """\
(* sx_ref.ml — Auto-generated from SX spec by hosts/ocaml/bootstrap.py *)
(* Do not edit — regenerate with: python3 hosts/ocaml/bootstrap.py *)
[@@@warning "-26-27"]
open Sx_types
open Sx_runtime
(* Trampoline — evaluates thunks via the CEK machine.
eval_expr is defined in the transpiled block below. *)
let trampoline v = v (* CEK machine doesn't produce thunks *)
"""
# OCaml fixups — override iterative CEK run
FIXUPS = """\
(* Override recursive cek_run with iterative loop *)
let cek_run_iterative state =
let s = ref state in
while not (match cek_terminal_p !s with Bool true -> true | _ -> false) do
s := cek_step !s
done;
cek_value !s
"""
def compile_spec_to_ml(spec_dir: str | None = None) -> str:
"""Compile the SX spec to OCaml source."""
from shared.sx.ref.sx_ref import eval_expr, trampoline, make_env, sx_parse
if spec_dir is None:
spec_dir = os.path.join(_PROJECT, "spec")
# Load the transpiler
env = make_env()
transpiler_path = os.path.join(_HERE, "transpiler.sx")
with open(transpiler_path) as f:
transpiler_src = f.read()
for expr in sx_parse(transpiler_src):
trampoline(eval_expr(expr, env))
# Spec files to transpile (in dependency order)
sx_files = [
("evaluator.sx", "evaluator (frames + eval + CEK)"),
]
parts = [PREAMBLE]
for filename, label in sx_files:
filepath = os.path.join(spec_dir, filename)
if not os.path.exists(filepath):
print(f"Warning: {filepath} not found, skipping", file=sys.stderr)
continue
with open(filepath) as f:
src = f.read()
defines = extract_defines(src)
# Skip defines provided by preamble or fixups
skip = {"trampoline"}
defines = [(n, e) for n, e in defines if n not in skip]
# Deduplicate — keep last definition for each name (CEK overrides tree-walk)
seen = {}
for i, (n, e) in enumerate(defines):
seen[n] = i
defines = [(n, e) for i, (n, e) in enumerate(defines) if seen[n] == i]
# Build the defines list for the transpiler
defines_list = [[name, expr] for name, expr in defines]
env["_defines"] = defines_list
# Pass known define names so the transpiler can distinguish
# static (OCaml fn) calls from dynamic (SX value) calls
env["_known_defines"] = [name for name, _ in defines]
# Call ml-translate-file — emits as single let rec block
translate_expr = sx_parse("(ml-translate-file _defines)")[0]
result = trampoline(eval_expr(translate_expr, env))
parts.append(f"\n(* === Transpiled from {label} === *)\n")
parts.append(result)
parts.append(FIXUPS)
return "\n".join(parts)
def main():
import argparse
parser = argparse.ArgumentParser(description="Bootstrap SX spec -> OCaml")
parser.add_argument(
"--output", "-o",
default=None,
help="Output file (default: stdout)",
)
args = parser.parse_args()
result = compile_spec_to_ml()
if args.output:
with open(args.output, "w") as f:
f.write(result)
size = os.path.getsize(args.output)
print(f"Wrote {args.output} ({size} bytes)", file=sys.stderr)
else:
print(result)
if __name__ == "__main__":
main()

2
hosts/ocaml/dune-project Normal file
View File

@@ -0,0 +1,2 @@
(lang dune 3.0)
(name sx)

2
hosts/ocaml/lib/dune Normal file
View File

@@ -0,0 +1,2 @@
(library
(name sx))

206
hosts/ocaml/lib/sx_parser.ml Normal file
View File

@@ -0,0 +1,206 @@
(** S-expression parser.
Recursive descent over a string, producing [Sx_types.value list].
Supports: lists, dicts, symbols, keywords, strings (with escapes),
numbers, booleans, nil, comments, quote/quasiquote/unquote sugar. *)
open Sx_types
type state = {
src : string;
len : int;
mutable pos : int;
}
let make_state src = { src; len = String.length src; pos = 0 }
let peek s = if s.pos < s.len then Some s.src.[s.pos] else None
let advance s = s.pos <- s.pos + 1
let at_end s = s.pos >= s.len
let skip_whitespace_and_comments s =
let rec go () =
if at_end s then ()
else match s.src.[s.pos] with
| ' ' | '\t' | '\n' | '\r' -> advance s; go ()
| ';' ->
while s.pos < s.len && s.src.[s.pos] <> '\n' do advance s done;
if s.pos < s.len then advance s;
go ()
| _ -> ()
in go ()
let is_symbol_char = function
| '(' | ')' | '[' | ']' | '{' | '}' | '"' | '\'' | '`'
| ' ' | '\t' | '\n' | '\r' | ',' | ';' -> false
| _ -> true
let read_string s =
(* s.pos is on the opening quote *)
advance s;
let buf = Buffer.create 64 in
let rec go () =
if at_end s then raise (Parse_error "Unterminated string");
let c = s.src.[s.pos] in
advance s;
if c = '"' then Buffer.contents buf
else if c = '\\' then begin
if at_end s then raise (Parse_error "Unterminated string escape");
let esc = s.src.[s.pos] in
advance s;
(match esc with
| 'n' -> Buffer.add_char buf '\n'
| 't' -> Buffer.add_char buf '\t'
| 'r' -> Buffer.add_char buf '\r'
| '"' -> Buffer.add_char buf '"'
| '\\' -> Buffer.add_char buf '\\'
| 'u' ->
(* \uXXXX — read 4 hex digits, encode as UTF-8 *)
if s.pos + 4 > s.len then raise (Parse_error "Incomplete \\u escape");
let hex = String.sub s.src s.pos 4 in
s.pos <- s.pos + 4;
let code = int_of_string ("0x" ^ hex) in
let ubuf = Buffer.create 4 in
Buffer.add_utf_8_uchar ubuf (Uchar.of_int code);
Buffer.add_string buf (Buffer.contents ubuf)
| '`' -> Buffer.add_char buf '`'
| _ -> Buffer.add_char buf '\\'; Buffer.add_char buf esc);
go ()
end else begin
Buffer.add_char buf c;
go ()
end
in go ()
let read_symbol s =
let start = s.pos in
while s.pos < s.len && is_symbol_char s.src.[s.pos] do advance s done;
String.sub s.src start (s.pos - start)
let try_number str =
match float_of_string_opt str with
| Some n -> Some (Number n)
| None -> None
let rec read_value s : value =
skip_whitespace_and_comments s;
if at_end s then raise (Parse_error "Unexpected end of input");
match s.src.[s.pos] with
| '(' -> read_list s ')'
| '[' -> read_list s ']'
| '{' -> read_dict s
| '"' -> String (read_string s)
| '\'' -> advance s; List [Symbol "quote"; read_value s]
| '`' -> advance s; List [Symbol "quasiquote"; read_value s]
| '#' when s.pos + 1 < s.len && s.src.[s.pos + 1] = ';' ->
(* Datum comment: #; discards next expression *)
advance s; advance s;
ignore (read_value s);
read_value s
| '#' when s.pos + 1 < s.len && s.src.[s.pos + 1] = '\'' ->
(* Quote shorthand: #'expr -> (quote expr) *)
advance s; advance s;
List [Symbol "quote"; read_value s]
| '#' when s.pos + 1 < s.len && s.src.[s.pos + 1] = '|' ->
(* Raw string: #|...| — ends at next | *)
advance s; advance s;
let buf = Buffer.create 64 in
let rec go () =
if at_end s then raise (Parse_error "Unterminated raw string");
let c = s.src.[s.pos] in
advance s;
if c = '|' then
String (Buffer.contents buf)
else begin
Buffer.add_char buf c;
go ()
end
in go ()
| '~' when s.pos + 1 < s.len && s.src.[s.pos + 1] = '@' ->
advance s; advance s; (* skip ~@ *)
List [Symbol "splice-unquote"; read_value s]
| _ ->
(* Check for unquote: , followed by non-whitespace *)
if s.src.[s.pos] = ',' && s.pos + 1 < s.len &&
s.src.[s.pos + 1] <> ' ' && s.src.[s.pos + 1] <> '\n' then begin
advance s;
if s.pos < s.len && s.src.[s.pos] = '@' then begin
advance s;
List [Symbol "splice-unquote"; read_value s]
end else
List [Symbol "unquote"; read_value s]
end else begin
(* Symbol, keyword, number, or boolean *)
let token = read_symbol s in
if token = "" then raise (Parse_error ("Unexpected char: " ^ String.make 1 s.src.[s.pos]));
match token with
| "true" -> Bool true
| "false" -> Bool false
| "nil" -> Nil
| _ when token.[0] = ':' ->
Keyword (String.sub token 1 (String.length token - 1))
| _ ->
match try_number token with
| Some n -> n
| None -> Symbol token
end
and read_list s close_char =
advance s; (* skip opening paren/bracket *)
let items = ref [] in
let rec go () =
skip_whitespace_and_comments s;
if at_end s then raise (Parse_error "Unterminated list");
if s.src.[s.pos] = close_char then begin
advance s;
List (List.rev !items)
end else begin
items := read_value s :: !items;
go ()
end
in go ()
and read_dict s =
advance s; (* skip { *)
let d = make_dict () in
let rec go () =
skip_whitespace_and_comments s;
if at_end s then raise (Parse_error "Unterminated dict");
if s.src.[s.pos] = '}' then begin
advance s;
Dict d
end else begin
let key = read_value s in
let key_str = match key with
| Keyword k -> k
| String k -> k
| Symbol k -> k
| _ -> raise (Parse_error "Dict key must be keyword, string, or symbol")
in
let v = read_value s in
dict_set d key_str v;
go ()
end
in go ()
(** Parse a string into a list of SX values. *)
let parse_all src =
let s = make_state src in
let results = ref [] in
let rec go () =
skip_whitespace_and_comments s;
if at_end s then List.rev !results
else begin
results := read_value s :: !results;
go ()
end
in go ()
(** Parse a file into a list of SX values. *)
let parse_file path =
let ic = open_in path in
let n = in_channel_length ic in
let src = really_input_string ic n in
close_in ic;
parse_all src

578
hosts/ocaml/lib/sx_primitives.ml Normal file
View File

@@ -0,0 +1,578 @@
(** Built-in primitive functions (~80 pure functions).
Registered in a global table; the evaluator checks this table
when a symbol isn't found in the lexical environment. *)
open Sx_types
let primitives : (string, value list -> value) Hashtbl.t = Hashtbl.create 128
let register name fn = Hashtbl.replace primitives name fn
let is_primitive name = Hashtbl.mem primitives name
let get_primitive name =
match Hashtbl.find_opt primitives name with
| Some fn -> NativeFn (name, fn)
| None -> raise (Eval_error ("Unknown primitive: " ^ name))
(* --- Helpers --- *)
let as_number = function
| Number n -> n
| Bool true -> 1.0
| Bool false -> 0.0
| Nil -> 0.0
| String s -> (match float_of_string_opt s with Some n -> n | None -> Float.nan)
| v -> raise (Eval_error ("Expected number, got " ^ type_of v))
let as_string = function
| String s -> s
| v -> raise (Eval_error ("Expected string, got " ^ type_of v))
let as_list = function
| List l -> l
| ListRef r -> !r
| Nil -> []
| v -> raise (Eval_error ("Expected list, got " ^ type_of v))
let as_bool = function
| Bool b -> b
| v -> sx_truthy v
let to_string = function
| String s -> s
| Number n ->
if Float.is_integer n then string_of_int (int_of_float n)
else Printf.sprintf "%g" n
| Bool true -> "true"
| Bool false -> "false"
| Nil -> ""
| Symbol s -> s
| Keyword k -> k
| v -> inspect v
let () =
(* === Arithmetic === *)
register "+" (fun args ->
Number (List.fold_left (fun acc a -> acc +. as_number a) 0.0 args));
register "-" (fun args ->
match args with
| [] -> Number 0.0
| [a] -> Number (-. (as_number a))
| a :: rest -> Number (List.fold_left (fun acc x -> acc -. as_number x) (as_number a) rest));
register "*" (fun args ->
Number (List.fold_left (fun acc a -> acc *. as_number a) 1.0 args));
register "/" (fun args ->
match args with
| [a; b] -> Number (as_number a /. as_number b)
| _ -> raise (Eval_error "/: expected 2 args"));
register "mod" (fun args ->
match args with
| [a; b] -> Number (Float.rem (as_number a) (as_number b))
| _ -> raise (Eval_error "mod: expected 2 args"));
register "inc" (fun args ->
match args with [a] -> Number (as_number a +. 1.0) | _ -> raise (Eval_error "inc: 1 arg"));
register "dec" (fun args ->
match args with [a] -> Number (as_number a -. 1.0) | _ -> raise (Eval_error "dec: 1 arg"));
register "abs" (fun args ->
match args with [a] -> Number (Float.abs (as_number a)) | _ -> raise (Eval_error "abs: 1 arg"));
register "floor" (fun args ->
match args with [a] -> Number (Float.of_int (int_of_float (Float.round (as_number a -. 0.5))))
| _ -> raise (Eval_error "floor: 1 arg"));
register "ceil" (fun args ->
match args with [a] -> Number (Float.of_int (int_of_float (Float.round (as_number a +. 0.5))))
| _ -> raise (Eval_error "ceil: 1 arg"));
register "round" (fun args ->
match args with
| [a] -> Number (Float.round (as_number a))
| [a; b] ->
let n = as_number a and places = int_of_float (as_number b) in
let factor = 10.0 ** float_of_int places in
Number (Float.round (n *. factor) /. factor)
| _ -> raise (Eval_error "round: 1-2 args"));
register "min" (fun args ->
match args with
| [] -> raise (Eval_error "min: at least 1 arg")
| _ -> Number (List.fold_left (fun acc a -> Float.min acc (as_number a)) Float.infinity args));
register "max" (fun args ->
match args with
| [] -> raise (Eval_error "max: at least 1 arg")
| _ -> Number (List.fold_left (fun acc a -> Float.max acc (as_number a)) Float.neg_infinity args));
register "sqrt" (fun args ->
match args with [a] -> Number (Float.sqrt (as_number a)) | _ -> raise (Eval_error "sqrt: 1 arg"));
register "pow" (fun args ->
match args with [a; b] -> Number (as_number a ** as_number b)
| _ -> raise (Eval_error "pow: 2 args"));
register "clamp" (fun args ->
match args with
| [x; lo; hi] ->
let x = as_number x and lo = as_number lo and hi = as_number hi in
Number (Float.max lo (Float.min hi x))
| _ -> raise (Eval_error "clamp: 3 args"));
register "parse-int" (fun args ->
match args with
| [String s] -> (match int_of_string_opt s with Some n -> Number (float_of_int n) | None -> Nil)
| [Number n] -> Number (float_of_int (int_of_float n))
| _ -> Nil);
register "parse-float" (fun args ->
match args with
| [String s] -> (match float_of_string_opt s with Some n -> Number n | None -> Nil)
| [Number n] -> Number n
| _ -> Nil);
(* === Comparison === *)
(* Normalize ListRef to List for structural equality *)
let rec normalize_for_eq = function
| ListRef { contents = items } -> List (List.map normalize_for_eq items)
| List items -> List (List.map normalize_for_eq items)
| v -> v
in
register "=" (fun args ->
match args with
| [a; b] -> Bool (normalize_for_eq a = normalize_for_eq b)
| _ -> raise (Eval_error "=: 2 args"));
register "!=" (fun args ->
match args with
| [a; b] -> Bool (normalize_for_eq a <> normalize_for_eq b)
| _ -> raise (Eval_error "!=: 2 args"));
register "<" (fun args ->
match args with
| [String a; String b] -> Bool (a < b)
| [a; b] -> Bool (as_number a < as_number b)
| _ -> raise (Eval_error "<: 2 args"));
register ">" (fun args ->
match args with
| [String a; String b] -> Bool (a > b)
| [a; b] -> Bool (as_number a > as_number b)
| _ -> raise (Eval_error ">: 2 args"));
register "<=" (fun args ->
match args with
| [String a; String b] -> Bool (a <= b)
| [a; b] -> Bool (as_number a <= as_number b)
| _ -> raise (Eval_error "<=: 2 args"));
register ">=" (fun args ->
match args with
| [String a; String b] -> Bool (a >= b)
| [a; b] -> Bool (as_number a >= as_number b)
| _ -> raise (Eval_error ">=: 2 args"));
(* === Logic === *)
register "not" (fun args ->
match args with [a] -> Bool (not (sx_truthy a)) | _ -> raise (Eval_error "not: 1 arg"));
(* === Predicates === *)
register "nil?" (fun args ->
match args with [a] -> Bool (is_nil a) | _ -> raise (Eval_error "nil?: 1 arg"));
register "number?" (fun args ->
match args with [Number _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "number?: 1 arg"));
register "string?" (fun args ->
match args with [String _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "string?: 1 arg"));
register "boolean?" (fun args ->
match args with [Bool _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "boolean?: 1 arg"));
register "list?" (fun args ->
match args with [List _] | [ListRef _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "list?: 1 arg"));
register "dict?" (fun args ->
match args with [Dict _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "dict?: 1 arg"));
register "symbol?" (fun args ->
match args with [Symbol _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "symbol?: 1 arg"));
register "keyword?" (fun args ->
match args with [Keyword _] -> Bool true | [_] -> Bool false | _ -> raise (Eval_error "keyword?: 1 arg"));
register "empty?" (fun args ->
match args with
| [List []] | [ListRef { contents = [] }] -> Bool true
| [List _] | [ListRef _] -> Bool false
| [String ""] -> Bool true | [String _] -> Bool false
| [Dict d] -> Bool (Hashtbl.length d = 0)
| [Nil] -> Bool true
| [_] -> Bool false
| _ -> raise (Eval_error "empty?: 1 arg"));
register "odd?" (fun args ->
match args with [a] -> Bool (int_of_float (as_number a) mod 2 <> 0) | _ -> raise (Eval_error "odd?: 1 arg"));
register "even?" (fun args ->
match args with [a] -> Bool (int_of_float (as_number a) mod 2 = 0) | _ -> raise (Eval_error "even?: 1 arg"));
register "zero?" (fun args ->
match args with [a] -> Bool (as_number a = 0.0) | _ -> raise (Eval_error "zero?: 1 arg"));
(* === Strings === *)
register "str" (fun args -> String (String.concat "" (List.map to_string args)));
register "upper" (fun args ->
match args with [a] -> String (String.uppercase_ascii (as_string a)) | _ -> raise (Eval_error "upper: 1 arg"));
register "upcase" (fun args ->
match args with [a] -> String (String.uppercase_ascii (as_string a)) | _ -> raise (Eval_error "upcase: 1 arg"));
register "lower" (fun args ->
match args with [a] -> String (String.lowercase_ascii (as_string a)) | _ -> raise (Eval_error "lower: 1 arg"));
register "downcase" (fun args ->
match args with [a] -> String (String.lowercase_ascii (as_string a)) | _ -> raise (Eval_error "downcase: 1 arg"));
register "trim" (fun args ->
match args with [a] -> String (String.trim (as_string a)) | _ -> raise (Eval_error "trim: 1 arg"));
register "string-length" (fun args ->
match args with [a] -> Number (float_of_int (String.length (as_string a)))
| _ -> raise (Eval_error "string-length: 1 arg"));
register "string-contains?" (fun args ->
match args with
| [String haystack; String needle] ->
let rec find i =
if i + String.length needle > String.length haystack then false
else if String.sub haystack i (String.length needle) = needle then true
else find (i + 1)
in Bool (find 0)
| _ -> raise (Eval_error "string-contains?: 2 string args"));
register "starts-with?" (fun args ->
match args with
| [String s; String prefix] ->
Bool (String.length s >= String.length prefix &&
String.sub s 0 (String.length prefix) = prefix)
| _ -> raise (Eval_error "starts-with?: 2 string args"));
register "ends-with?" (fun args ->
match args with
| [String s; String suffix] ->
let sl = String.length s and xl = String.length suffix in
Bool (sl >= xl && String.sub s (sl - xl) xl = suffix)
| _ -> raise (Eval_error "ends-with?: 2 string args"));
register "index-of" (fun args ->
match args with
| [String haystack; String needle] ->
let nl = String.length needle and hl = String.length haystack in
let rec find i =
if i + nl > hl then Number (-1.0)
else if String.sub haystack i nl = needle then Number (float_of_int i)
else find (i + 1)
in find 0
| _ -> raise (Eval_error "index-of: 2 string args"));
register "substring" (fun args ->
match args with
| [String s; Number start; Number end_] ->
let i = int_of_float start and j = int_of_float end_ in
let len = String.length s in
let i = max 0 (min i len) and j = max 0 (min j len) in
String (String.sub s i (max 0 (j - i)))
| _ -> raise (Eval_error "substring: 3 args"));
register "substr" (fun args ->
match args with
| [String s; Number start; Number len] ->
let i = int_of_float start and n = int_of_float len in
let sl = String.length s in
let i = max 0 (min i sl) in
let n = max 0 (min n (sl - i)) in
String (String.sub s i n)
| [String s; Number start] ->
let i = int_of_float start in
let sl = String.length s in
let i = max 0 (min i sl) in
String (String.sub s i (sl - i))
| _ -> raise (Eval_error "substr: 2-3 args"));
register "split" (fun args ->
match args with
| [String s; String sep] ->
List (List.map (fun p -> String p) (String.split_on_char sep.[0] s))
| _ -> raise (Eval_error "split: 2 args"));
register "join" (fun args ->
match args with
| [String sep; (List items | ListRef { contents = items })] ->
String (String.concat sep (List.map to_string items))
| _ -> raise (Eval_error "join: 2 args"));
register "replace" (fun args ->
match args with
| [String s; String old_s; String new_s] ->
let ol = String.length old_s in
if ol = 0 then String s
else begin
let buf = Buffer.create (String.length s) in
let rec go i =
if i >= String.length s then ()
else if i + ol <= String.length s && String.sub s i ol = old_s then begin
Buffer.add_string buf new_s;
go (i + ol)
end else begin
Buffer.add_char buf s.[i];
go (i + 1)
end
in go 0;
String (Buffer.contents buf)
end
| _ -> raise (Eval_error "replace: 3 string args"));
register "char-from-code" (fun args ->
match args with
| [Number n] ->
let buf = Buffer.create 4 in
Buffer.add_utf_8_uchar buf (Uchar.of_int (int_of_float n));
String (Buffer.contents buf)
| _ -> raise (Eval_error "char-from-code: 1 arg"));
(* === Collections === *)
register "list" (fun args -> ListRef (ref args));
register "len" (fun args ->
match args with
| [List l] | [ListRef { contents = l }] -> Number (float_of_int (List.length l))
| [String s] -> Number (float_of_int (String.length s))
| [Dict d] -> Number (float_of_int (Hashtbl.length d))
| [Nil] -> Number 0.0
| _ -> raise (Eval_error "len: 1 arg"));
register "first" (fun args ->
match args with
| [List (x :: _)] | [ListRef { contents = x :: _ }] -> x
| [List []] | [ListRef { contents = [] }] -> Nil | [Nil] -> Nil
| _ -> raise (Eval_error "first: 1 list arg"));
register "rest" (fun args ->
match args with
| [List (_ :: xs)] | [ListRef { contents = _ :: xs }] -> List xs
| [List []] | [ListRef { contents = [] }] -> List [] | [Nil] -> List []
| _ -> raise (Eval_error "rest: 1 list arg"));
register "last" (fun args ->
match args with
| [List l] | [ListRef { contents = l }] ->
(match List.rev l with x :: _ -> x | [] -> Nil)
| _ -> raise (Eval_error "last: 1 list arg"));
register "nth" (fun args ->
match args with
| [List l; Number n] | [ListRef { contents = l }; Number n] ->
(try List.nth l (int_of_float n) with _ -> Nil)
| _ -> raise (Eval_error "nth: list and number"));
register "cons" (fun args ->
match args with
| [x; List l] | [x; ListRef { contents = l }] -> List (x :: l)
| [x; Nil] -> List [x]
| _ -> raise (Eval_error "cons: value and list"));
register "append" (fun args ->
let all = List.concat_map (fun a -> as_list a) args in
List all);
register "reverse" (fun args ->
match args with
| [List l] | [ListRef { contents = l }] -> List (List.rev l)
| _ -> raise (Eval_error "reverse: 1 list"));
register "flatten" (fun args ->
let rec flat = function
| List items | ListRef { contents = items } -> List.concat_map flat items
| x -> [x]
in
match args with
| [List l] | [ListRef { contents = l }] -> List (List.concat_map flat l)
| _ -> raise (Eval_error "flatten: 1 list"));
register "concat" (fun args -> List (List.concat_map as_list args));
register "contains?" (fun args ->
match args with
| [List l; item] | [ListRef { contents = l }; item] -> Bool (List.mem item l)
| [String s; String sub] ->
let rec find i =
if i + String.length sub > String.length s then false
else if String.sub s i (String.length sub) = sub then true
else find (i + 1)
in Bool (find 0)
| _ -> raise (Eval_error "contains?: 2 args"));
register "range" (fun args ->
match args with
| [Number stop] ->
let n = int_of_float stop in
List (List.init (max 0 n) (fun i -> Number (float_of_int i)))
| [Number start; Number stop] ->
let s = int_of_float start and e = int_of_float stop in
let len = max 0 (e - s) in
List (List.init len (fun i -> Number (float_of_int (s + i))))
| [Number start; Number stop; Number step] ->
let s = start and e = stop and st = step in
if st = 0.0 then List []
else
let items = ref [] in
let i = ref s in
if st > 0.0 then
(while !i < e do items := Number !i :: !items; i := !i +. st done)
else
(while !i > e do items := Number !i :: !items; i := !i +. st done);
List (List.rev !items)
| _ -> raise (Eval_error "range: 1-3 args"));
register "slice" (fun args ->
match args with
| [(List l | ListRef { contents = l }); Number start] ->
let i = max 0 (int_of_float start) in
let rec drop n = function _ :: xs when n > 0 -> drop (n-1) xs | l -> l in
List (drop i l)
| [(List l | ListRef { contents = l }); Number start; Number end_] ->
let i = max 0 (int_of_float start) and j = int_of_float end_ in
let len = List.length l in
let j = min j len in
let rec take_range idx = function
| [] -> []
| x :: xs ->
if idx >= j then []
else if idx >= i then x :: take_range (idx+1) xs
else take_range (idx+1) xs
in List (take_range 0 l)
| [String s; Number start] ->
let i = max 0 (int_of_float start) in
String (String.sub s i (max 0 (String.length s - i)))
| [String s; Number start; Number end_] ->
let i = max 0 (int_of_float start) and j = int_of_float end_ in
let sl = String.length s in
let j = min j sl in
String (String.sub s i (max 0 (j - i)))
| _ -> raise (Eval_error "slice: 2-3 args"));
register "sort" (fun args ->
match args with
| [List l] | [ListRef { contents = l }] -> List (List.sort compare l)
| _ -> raise (Eval_error "sort: 1 list"));
register "zip" (fun args ->
match args with
| [a; b] ->
let la = as_list a and lb = as_list b in
let rec go l1 l2 acc = match l1, l2 with
| x :: xs, y :: ys -> go xs ys (List [x; y] :: acc)
| _ -> List.rev acc
in List (go la lb [])
| _ -> raise (Eval_error "zip: 2 lists"));
register "zip-pairs" (fun args ->
match args with
| [v] ->
let l = as_list v in
let rec go = function
| a :: b :: rest -> List [a; b] :: go rest
| _ -> []
in List (go l)
| _ -> raise (Eval_error "zip-pairs: 1 list"));
register "take" (fun args ->
match args with
| [(List l | ListRef { contents = l }); Number n] ->
let rec take_n i = function
| x :: xs when i > 0 -> x :: take_n (i-1) xs
| _ -> []
in List (take_n (int_of_float n) l)
| _ -> raise (Eval_error "take: list and number"));
register "drop" (fun args ->
match args with
| [(List l | ListRef { contents = l }); Number n] ->
let rec drop_n i = function
| _ :: xs when i > 0 -> drop_n (i-1) xs
| l -> l
in List (drop_n (int_of_float n) l)
| _ -> raise (Eval_error "drop: list and number"));
register "chunk-every" (fun args ->
match args with
| [(List l | ListRef { contents = l }); Number n] ->
let size = int_of_float n in
let rec go = function
| [] -> []
| l ->
let rec take_n i = function
| x :: xs when i > 0 -> x :: take_n (i-1) xs
| _ -> []
in
let rec drop_n i = function
| _ :: xs when i > 0 -> drop_n (i-1) xs
| l -> l
in
List (take_n size l) :: go (drop_n size l)
in List (go l)
| _ -> raise (Eval_error "chunk-every: list and number"));
register "unique" (fun args ->
match args with
| [(List l | ListRef { contents = l })] ->
let seen = Hashtbl.create 16 in
let result = List.filter (fun x ->
let key = inspect x in
if Hashtbl.mem seen key then false
else (Hashtbl.replace seen key true; true)
) l in
List result
| _ -> raise (Eval_error "unique: 1 list"));
(* === Dict === *)
register "dict" (fun args ->
let d = make_dict () in
let rec go = function
| [] -> Dict d
| Keyword k :: v :: rest -> dict_set d k v; go rest
| String k :: v :: rest -> dict_set d k v; go rest
| _ -> raise (Eval_error "dict: pairs of key value")
in go args);
register "get" (fun args ->
match args with
| [Dict d; String k] -> dict_get d k
| [Dict d; Keyword k] -> dict_get d k
| [List l; Number n] | [ListRef { contents = l }; Number n] ->
(try List.nth l (int_of_float n) with _ -> Nil)
| _ -> raise (Eval_error "get: dict+key or list+index"));
register "has-key?" (fun args ->
match args with
| [Dict d; String k] -> Bool (dict_has d k)
| [Dict d; Keyword k] -> Bool (dict_has d k)
| _ -> raise (Eval_error "has-key?: dict and key"));
register "assoc" (fun args ->
match args with
| Dict d :: rest ->
let d2 = Hashtbl.copy d in
let rec go = function
| [] -> Dict d2
| String k :: v :: rest -> Hashtbl.replace d2 k v; go rest
| Keyword k :: v :: rest -> Hashtbl.replace d2 k v; go rest
| _ -> raise (Eval_error "assoc: pairs")
in go rest
| _ -> raise (Eval_error "assoc: dict + pairs"));
register "dissoc" (fun args ->
match args with
| Dict d :: keys ->
let d2 = Hashtbl.copy d in
List.iter (fun k -> Hashtbl.remove d2 (to_string k)) keys;
Dict d2
| _ -> raise (Eval_error "dissoc: dict + keys"));
register "merge" (fun args ->
let d = make_dict () in
List.iter (function
| Dict src -> Hashtbl.iter (fun k v -> Hashtbl.replace d k v) src
| _ -> raise (Eval_error "merge: all args must be dicts")
) args;
Dict d);
register "keys" (fun args ->
match args with [Dict d] -> List (dict_keys d) | _ -> raise (Eval_error "keys: 1 dict"));
register "vals" (fun args ->
match args with [Dict d] -> List (dict_vals d) | _ -> raise (Eval_error "vals: 1 dict"));
register "dict-set!" (fun args ->
match args with
| [Dict d; String k; v] -> dict_set d k v; v
| [Dict d; Keyword k; v] -> dict_set d k v; v
| _ -> raise (Eval_error "dict-set!: dict key val"));
register "dict-get" (fun args ->
match args with
| [Dict d; String k] -> dict_get d k
| [Dict d; Keyword k] -> dict_get d k
| _ -> raise (Eval_error "dict-get: dict and key"));
register "dict-has?" (fun args ->
match args with
| [Dict d; String k] -> Bool (dict_has d k)
| _ -> raise (Eval_error "dict-has?: dict and key"));
register "dict-delete!" (fun args ->
match args with
| [Dict d; String k] -> dict_delete d k; Nil
| _ -> raise (Eval_error "dict-delete!: dict and key"));
(* === Misc === *)
register "type-of" (fun args ->
match args with [a] -> String (type_of a) | _ -> raise (Eval_error "type-of: 1 arg"));
register "inspect" (fun args ->
match args with [a] -> String (inspect a) | _ -> raise (Eval_error "inspect: 1 arg"));
register "error" (fun args ->
match args with [String msg] -> raise (Eval_error msg)
| [a] -> raise (Eval_error (to_string a))
| _ -> raise (Eval_error "error: 1 arg"));
register "apply" (fun args ->
match args with
| [NativeFn (_, f); List a] -> f a
| _ -> raise (Eval_error "apply: function and list"));
register "identical?" (fun args ->
match args with [a; b] -> Bool (a == b) | _ -> raise (Eval_error "identical?: 2 args"));
register "make-spread" (fun args ->
match args with
| [Dict d] ->
let pairs = Hashtbl.fold (fun k v acc -> (k, v) :: acc) d [] in
Spread pairs
| _ -> raise (Eval_error "make-spread: 1 dict"));
register "spread?" (fun args ->
match args with [Spread _] -> Bool true | [_] -> Bool false
| _ -> raise (Eval_error "spread?: 1 arg"));
register "spread-attrs" (fun args ->
match args with
| [Spread pairs] ->
let d = make_dict () in
List.iter (fun (k, v) -> dict_set d k v) pairs;
Dict d
| _ -> raise (Eval_error "spread-attrs: 1 spread"));
()

573
hosts/ocaml/lib/sx_ref.ml Normal file
View File

File diff suppressed because one or more lines are too long

435
hosts/ocaml/lib/sx_render.ml Normal file
View File

@@ -0,0 +1,435 @@
(** HTML renderer for SX values.
Extracted from run_tests.ml — renders an SX expression tree to an
HTML string, expanding components and macros along the way.
Depends on [Sx_ref.eval_expr] for evaluating sub-expressions
during rendering (keyword arg values, conditionals, etc.). *)
open Sx_types
(* ====================================================================== *)
(* Tag / attribute registries *)
(* ====================================================================== *)
let html_tags = [
"html"; "head"; "body"; "title"; "meta"; "link"; "script"; "style"; "noscript";
"header"; "nav"; "main"; "section"; "article"; "aside"; "footer";
"h1"; "h2"; "h3"; "h4"; "h5"; "h6"; "hgroup";
"div"; "p"; "blockquote"; "pre"; "figure"; "figcaption"; "address"; "hr";
"ul"; "ol"; "li"; "dl"; "dt"; "dd"; "menu";
"a"; "span"; "em"; "strong"; "small"; "b"; "i"; "u"; "s"; "sub"; "sup";
"mark"; "del"; "ins"; "q"; "cite"; "dfn"; "abbr"; "code"; "var"; "samp";
"kbd"; "data"; "time"; "ruby"; "rt"; "rp"; "bdi"; "bdo"; "wbr"; "br";
"table"; "thead"; "tbody"; "tfoot"; "tr"; "th"; "td"; "caption"; "colgroup"; "col";
"form"; "input"; "textarea"; "select"; "option"; "optgroup"; "button"; "label";
"fieldset"; "legend"; "datalist"; "output"; "progress"; "meter";
"details"; "summary"; "dialog";
"img"; "video"; "audio"; "source"; "picture"; "canvas"; "iframe"; "embed"; "object"; "param";
"svg"; "path"; "circle"; "rect"; "line"; "polyline"; "polygon"; "ellipse";
"g"; "defs"; "use"; "text"; "tspan"; "clipPath"; "mask"; "pattern";
"linearGradient"; "radialGradient"; "stop"; "filter"; "feBlend"; "feFlood";
"feGaussianBlur"; "feOffset"; "feMerge"; "feMergeNode"; "feComposite";
"template"; "slot";
]
let void_elements = [
"area"; "base"; "br"; "col"; "embed"; "hr"; "img"; "input";
"link"; "meta"; "param"; "source"; "track"; "wbr"
]
let boolean_attrs = [
"async"; "autofocus"; "autoplay"; "checked"; "controls"; "default";
"defer"; "disabled"; "formnovalidate"; "hidden"; "inert"; "ismap";
"loop"; "multiple"; "muted"; "nomodule"; "novalidate"; "open";
"playsinline"; "readonly"; "required"; "reversed"; "selected"
]
let is_html_tag name = List.mem name html_tags
let is_void name = List.mem name void_elements
let is_boolean_attr name = List.mem name boolean_attrs
(* ====================================================================== *)
(* HTML escaping *)
(* ====================================================================== *)
let escape_html s =
let buf = Buffer.create (String.length s) in
String.iter (function
| '&' -> Buffer.add_string buf "&amp;"
| '<' -> Buffer.add_string buf "&lt;"
| '>' -> Buffer.add_string buf "&gt;"
| '"' -> Buffer.add_string buf "&quot;"
| c -> Buffer.add_char buf c) s;
Buffer.contents buf
(* ====================================================================== *)
(* Attribute rendering *)
(* ====================================================================== *)
let render_attrs attrs =
let buf = Buffer.create 64 in
Hashtbl.iter (fun k v ->
if is_boolean_attr k then begin
if sx_truthy v then begin
Buffer.add_char buf ' ';
Buffer.add_string buf k
end
end else if not (is_nil v) then begin
Buffer.add_char buf ' ';
Buffer.add_string buf k;
Buffer.add_string buf "=\"";
Buffer.add_string buf (escape_html (value_to_string v));
Buffer.add_char buf '"'
end) attrs;
Buffer.contents buf
(* ====================================================================== *)
(* HTML renderer *)
(* ====================================================================== *)
(* Forward ref — resolved at setup time *)
let render_to_html_ref : (value -> env -> string) ref =
ref (fun _expr _env -> "")
let render_to_html expr env = !render_to_html_ref expr env
let render_children children env =
String.concat "" (List.map (fun c -> render_to_html c env) children)
(** Parse keyword attrs and positional children from an element call's args.
Attrs are evaluated; children are returned UNEVALUATED for render dispatch. *)
let parse_element_args args env =
let attrs = Hashtbl.create 8 in
let children = ref [] in
let skip = ref false in
let len = List.length args in
List.iteri (fun idx arg ->
if !skip then skip := false
else match arg with
| Keyword k when idx + 1 < len ->
let v = Sx_ref.eval_expr (List.nth args (idx + 1)) (Env env) in
Hashtbl.replace attrs k v;
skip := true
| Spread pairs ->
List.iter (fun (k, v) -> Hashtbl.replace attrs k v) pairs
| _ ->
children := arg :: !children
) args;
(attrs, List.rev !children)
let render_html_element tag args env =
let (attrs, children) = parse_element_args args env in
let attr_str = render_attrs attrs in
if is_void tag then
"<" ^ tag ^ attr_str ^ " />"
else
let content = String.concat ""
(List.map (fun c -> render_to_html c env) children) in
"<" ^ tag ^ attr_str ^ ">" ^ content ^ "</" ^ tag ^ ">"
let render_component comp args env =
match comp with
| Component c ->
let kwargs = Hashtbl.create 8 in
let children_exprs = ref [] in
let skip = ref false in
let len = List.length args in
List.iteri (fun idx arg ->
if !skip then skip := false
else match arg with
| Keyword k when idx + 1 < len ->
let v = Sx_ref.eval_expr (List.nth args (idx + 1)) (Env env) in
Hashtbl.replace kwargs k v;
skip := true
| _ ->
children_exprs := arg :: !children_exprs
) args;
let children = List.rev !children_exprs in
let local = env_merge c.c_closure env in
List.iter (fun p ->
let v = match Hashtbl.find_opt kwargs p with Some v -> v | None -> Nil in
ignore (env_bind local p v)
) c.c_params;
if c.c_has_children then begin
let rendered_children = String.concat ""
(List.map (fun c -> render_to_html c env) children) in
ignore (env_bind local "children" (RawHTML rendered_children))
end;
render_to_html c.c_body local
| _ -> ""
let expand_macro (m : macro) args _env =
let local = env_extend m.m_closure in
let params = m.m_params in
let rec bind_params ps as' =
match ps, as' with
| [], rest ->
(match m.m_rest_param with
| Some rp -> ignore (env_bind local rp (List rest))
| None -> ())
| p :: ps_rest, a :: as_rest ->
ignore (env_bind local p a);
bind_params ps_rest as_rest
| _ :: _, [] ->
List.iter (fun p -> ignore (env_bind local p Nil)) (List.rev ps)
in
bind_params params args;
Sx_ref.eval_expr m.m_body (Env local)
let rec do_render_to_html (expr : value) (env : env) : string =
match expr with
| Nil -> ""
| Bool true -> "true"
| Bool false -> "false"
| Number n ->
if Float.is_integer n then string_of_int (int_of_float n)
else Printf.sprintf "%g" n
| String s -> escape_html s
| Keyword k -> escape_html k
| RawHTML s -> s
| Symbol s ->
let v = Sx_ref.eval_expr (Symbol s) (Env env) in
do_render_to_html v env
| List [] | ListRef { contents = [] } -> ""
| List (head :: args) | ListRef { contents = head :: args } ->
render_list_to_html head args env
| _ ->
let v = Sx_ref.eval_expr expr (Env env) in
do_render_to_html v env
and render_list_to_html head args env =
match head with
| Symbol "<>" ->
render_children args env
| Symbol tag when is_html_tag tag ->
render_html_element tag args env
| Symbol "if" ->
let cond_val = Sx_ref.eval_expr (List.hd args) (Env env) in
if sx_truthy cond_val then
(if List.length args > 1 then do_render_to_html (List.nth args 1) env else "")
else
(if List.length args > 2 then do_render_to_html (List.nth args 2) env else "")
| Symbol "when" ->
let cond_val = Sx_ref.eval_expr (List.hd args) (Env env) in
if sx_truthy cond_val then
String.concat "" (List.map (fun e -> do_render_to_html e env) (List.tl args))
else ""
| Symbol "cond" ->
render_cond args env
| Symbol "case" ->
let v = Sx_ref.eval_expr (List (head :: args)) (Env env) in
do_render_to_html v env
| Symbol ("let" | "let*") ->
render_let args env
| Symbol ("begin" | "do") ->
let rec go = function
| [] -> ""
| [last] -> do_render_to_html last env
| e :: rest ->
ignore (Sx_ref.eval_expr e (Env env));
go rest
in go args
| Symbol ("define" | "defcomp" | "defmacro" | "defisland") ->
ignore (Sx_ref.eval_expr (List (head :: args)) (Env env));
""
| Symbol "map" ->
render_map args env false
| Symbol "map-indexed" ->
render_map args env true
| Symbol "filter" ->
let v = Sx_ref.eval_expr (List (head :: args)) (Env env) in
do_render_to_html v env
| Symbol "for-each" ->
render_for_each args env
| Symbol name ->
(try
let v = env_get env name in
(match v with
| Component _ -> render_component v args env
| Macro m ->
let expanded = expand_macro m args env in
do_render_to_html expanded env
| _ ->
let result = Sx_ref.eval_expr (List (head :: args)) (Env env) in
do_render_to_html result env)
with Eval_error _ ->
let result = Sx_ref.eval_expr (List (head :: args)) (Env env) in
do_render_to_html result env)
| _ ->
let result = Sx_ref.eval_expr (List (head :: args)) (Env env) in
do_render_to_html result env
and render_cond args env =
let as_list = function List l | ListRef { contents = l } -> Some l | _ -> None in
let is_scheme = List.for_all (fun a -> match as_list a with
| Some items when List.length items = 2 -> true
| _ -> false) args
in
if is_scheme then begin
let rec go = function
| [] -> ""
| clause :: rest ->
(match as_list clause with
| Some [test; body] ->
let is_else = match test with
| Keyword "else" -> true
| Symbol "else" | Symbol ":else" -> true
| _ -> false
in
if is_else then do_render_to_html body env
else
let v = Sx_ref.eval_expr test (Env env) in
if sx_truthy v then do_render_to_html body env
else go rest
| _ -> "")
in go args
end else begin
let rec go = function
| [] -> ""
| [_] -> ""
| test :: body :: rest ->
let is_else = match test with
| Keyword "else" -> true
| Symbol "else" | Symbol ":else" -> true
| _ -> false
in
if is_else then do_render_to_html body env
else
let v = Sx_ref.eval_expr test (Env env) in
if sx_truthy v then do_render_to_html body env
else go rest
in go args
end
and render_let args env =
let as_list = function List l | ListRef { contents = l } -> Some l | _ -> None in
let bindings_expr = List.hd args in
let body = List.tl args in
let local = env_extend env in
let bindings = match as_list bindings_expr with Some l -> l | None -> [] in
let is_scheme = match bindings with
| (List _ :: _) | (ListRef _ :: _) -> true
| _ -> false
in
if is_scheme then
List.iter (fun b ->
match as_list b with
| Some [Symbol name; expr] | Some [String name; expr] ->
let v = Sx_ref.eval_expr expr (Env local) in
ignore (env_bind local name v)
| _ -> ()
) bindings
else begin
let rec go = function
| [] -> ()
| (Symbol name) :: expr :: rest | (String name) :: expr :: rest ->
let v = Sx_ref.eval_expr expr (Env local) in
ignore (env_bind local name v);
go rest
| _ -> ()
in go bindings
end;
let rec render_body = function
| [] -> ""
| [last] -> do_render_to_html last local
| e :: rest ->
ignore (Sx_ref.eval_expr e (Env local));
render_body rest
in render_body body
and render_map args env indexed =
let (fn_val, coll_val) = match args with
| [a; b] ->
let va = Sx_ref.eval_expr a (Env env) in
let vb = Sx_ref.eval_expr b (Env env) in
(match va, vb with
| (Lambda _ | NativeFn _), _ -> (va, vb)
| _, (Lambda _ | NativeFn _) -> (vb, va)
| _ -> (va, vb))
| _ -> (Nil, Nil)
in
let items = match coll_val with List l | ListRef { contents = l } -> l | _ -> [] in
String.concat "" (List.mapi (fun i item ->
let call_args = if indexed then [Number (float_of_int i); item] else [item] in
match fn_val with
| Lambda l ->
let local = env_extend l.l_closure in
List.iter2 (fun p a -> ignore (env_bind local p a))
l.l_params call_args;
do_render_to_html l.l_body local
| _ ->
let result = Sx_runtime.sx_call fn_val call_args in
do_render_to_html result env
) items)
and render_for_each args env =
let (fn_val, coll_val) = match args with
| [a; b] ->
let va = Sx_ref.eval_expr a (Env env) in
let vb = Sx_ref.eval_expr b (Env env) in
(match va, vb with
| (Lambda _ | NativeFn _), _ -> (va, vb)
| _, (Lambda _ | NativeFn _) -> (vb, va)
| _ -> (va, vb))
| _ -> (Nil, Nil)
in
let items = match coll_val with List l | ListRef { contents = l } -> l | _ -> [] in
String.concat "" (List.map (fun item ->
match fn_val with
| Lambda l ->
let local = env_extend l.l_closure in
List.iter2 (fun p a -> ignore (env_bind local p a))
l.l_params [item];
do_render_to_html l.l_body local
| _ ->
let result = Sx_runtime.sx_call fn_val [item] in
do_render_to_html result env
) items)
(* ====================================================================== *)
(* Setup — bind render primitives in an env and wire up the ref *)
(* ====================================================================== *)
let setup_render_env env =
render_to_html_ref := do_render_to_html;
let bind name fn =
ignore (env_bind env name (NativeFn (name, fn)))
in
bind "render-html" (fun args ->
match args with
| [String src] ->
let exprs = Sx_parser.parse_all src in
let expr = match exprs with
| [e] -> e
| [] -> Nil
| _ -> List (Symbol "do" :: exprs)
in
String (render_to_html expr env)
| [expr] ->
String (render_to_html expr env)
| [expr; Env e] ->
String (render_to_html expr e)
| _ -> String "");
bind "render-to-html" (fun args ->
match args with
| [String src] ->
let exprs = Sx_parser.parse_all src in
let expr = match exprs with
| [e] -> e
| [] -> Nil
| _ -> List (Symbol "do" :: exprs)
in
String (render_to_html expr env)
| [expr] ->
String (render_to_html expr env)
| [expr; Env e] ->
String (render_to_html expr e)
| _ -> String "")

356
hosts/ocaml/lib/sx_runtime.ml Normal file
View File

@@ -0,0 +1,356 @@
(** Runtime helpers for transpiled code.
These bridge the gap between the transpiler's output and the
foundation types/primitives. The transpiled evaluator calls these
functions directly. *)
open Sx_types
(** Call a registered primitive by name. *)
let prim_call name args =
match Hashtbl.find_opt Sx_primitives.primitives name with
| Some f -> f args
| None -> raise (Eval_error ("Unknown primitive: " ^ name))
(** Convert any SX value to an OCaml string (internal). *)
let value_to_str = function
| String s -> s
| Number n ->
if Float.is_integer n then string_of_int (int_of_float n)
else Printf.sprintf "%g" n
| Bool true -> "true"
| Bool false -> "false"
| Nil -> ""
| Symbol s -> s
| Keyword k -> k
| v -> inspect v
(** sx_to_string returns a value (String) for transpiled code. *)
let sx_to_string v = String (value_to_str v)
(** String concatenation helper — [sx_str] takes a list of values. *)
let sx_str args =
String.concat "" (List.map value_to_str args)
(** Convert a value to a list. *)
let sx_to_list = function
| List l -> l
| ListRef r -> !r
| Nil -> []
| v -> raise (Eval_error ("Expected list, got " ^ type_of v))
(** Call an SX callable (lambda, native fn, continuation). *)
let sx_call f args =
match f with
| NativeFn (_, fn) -> fn args
| Lambda l ->
let local = Sx_types.env_extend l.l_closure in
List.iter2 (fun p a -> ignore (Sx_types.env_bind local p a)) l.l_params args;
(* Return the body + env for the trampoline to evaluate *)
Thunk (l.l_body, local)
| Continuation (k, _) ->
k (match args with x :: _ -> x | [] -> Nil)
| _ -> raise (Eval_error ("Not callable: " ^ inspect f))
(** Apply a function to a list of args. *)
let sx_apply f args_list =
sx_call f (sx_to_list args_list)
(** Mutable append — add item to a list ref or accumulator.
In transpiled code, lists that get appended to are mutable refs. *)
let sx_append_b lst item =
match lst with
| List items -> List (items @ [item])
| ListRef r -> r := !r @ [item]; lst (* mutate in place, return same ref *)
| _ -> raise (Eval_error ("append!: expected list, got " ^ type_of lst))
(** Mutable dict-set — set key in dict, return value. *)
let sx_dict_set_b d k v =
match d, k with
| Dict tbl, String key -> Hashtbl.replace tbl key v; v
| Dict tbl, Keyword key -> Hashtbl.replace tbl key v; v
| _ -> raise (Eval_error "dict-set!: expected dict and string key")
(** Get from dict or list. *)
let get_val container key =
match container, key with
| Dict d, String k -> dict_get d k
| Dict d, Keyword k -> dict_get d k
| (List l | ListRef { contents = l }), Number n ->
(try List.nth l (int_of_float n) with _ -> Nil)
| _ -> raise (Eval_error ("get: unsupported " ^ type_of container ^ " / " ^ type_of key))
(** Register get as a primitive override — transpiled code calls (get d k). *)
let () =
Sx_primitives.register "get" (fun args ->
match args with
| [c; k] -> get_val c k
| [c; k; default] ->
(try
let v = get_val c k in
if v = Nil then default else v
with _ -> default)
| _ -> raise (Eval_error "get: 2-3 args"))
(* ====================================================================== *)
(* Primitive aliases — top-level functions called by transpiled code *)
(* ====================================================================== *)
(** The transpiled evaluator calls primitives directly by their mangled
OCaml name. These aliases delegate to the primitives table so the
transpiled code compiles without needing [prim_call] everywhere. *)
let _prim name = match Hashtbl.find_opt Sx_primitives.primitives name with
| Some f -> f | None -> (fun _ -> raise (Eval_error ("Missing prim: " ^ name)))
(* Collection ops *)
let first args = _prim "first" [args]
let rest args = _prim "rest" [args]
let last args = _prim "last" [args]
let nth coll i = _prim "nth" [coll; i]
let cons x l = _prim "cons" [x; l]
let append a b = _prim "append" [a; b]
let reverse l = _prim "reverse" [l]
let flatten l = _prim "flatten" [l]
let concat a b = _prim "concat" [a; b]
let slice a b = _prim "slice" [a; b]
let len a = _prim "len" [a]
let get a b = get_val a b
let sort' a = _prim "sort" [a]
let range' a = _prim "range" [a]
let unique a = _prim "unique" [a]
let zip a b = _prim "zip" [a; b]
let zip_pairs a = _prim "zip-pairs" [a]
let take a b = _prim "take" [a; b]
let drop a b = _prim "drop" [a; b]
let chunk_every a b = _prim "chunk-every" [a; b]
(* Predicates *)
let empty_p a = _prim "empty?" [a]
let nil_p a = _prim "nil?" [a]
let number_p a = _prim "number?" [a]
let string_p a = _prim "string?" [a]
let boolean_p a = _prim "boolean?" [a]
let list_p a = _prim "list?" [a]
let dict_p a = _prim "dict?" [a]
let symbol_p a = _prim "symbol?" [a]
let keyword_p a = _prim "keyword?" [a]
let contains_p a b = _prim "contains?" [a; b]
let has_key_p a b = _prim "has-key?" [a; b]
let starts_with_p a b = _prim "starts-with?" [a; b]
let ends_with_p a b = _prim "ends-with?" [a; b]
let string_contains_p a b = _prim "string-contains?" [a; b]
let odd_p a = _prim "odd?" [a]
let even_p a = _prim "even?" [a]
let zero_p a = _prim "zero?" [a]
(* String ops *)
let str' args = String (sx_str args)
let upper a = _prim "upper" [a]
let upcase a = _prim "upcase" [a]
let lower a = _prim "lower" [a]
let downcase a = _prim "downcase" [a]
let trim a = _prim "trim" [a]
let split a b = _prim "split" [a; b]
let join a b = _prim "join" [a; b]
let replace a b c = _prim "replace" [a; b; c]
let index_of a b = _prim "index-of" [a; b]
let substring a b c = _prim "substring" [a; b; c]
let string_length a = _prim "string-length" [a]
let char_from_code a = _prim "char-from-code" [a]
(* Dict ops *)
let assoc d k v = _prim "assoc" [d; k; v]
let dissoc d k = _prim "dissoc" [d; k]
let merge' a b = _prim "merge" [a; b]
let keys a = _prim "keys" [a]
let vals a = _prim "vals" [a]
let dict_set a b c = _prim "dict-set!" [a; b; c]
let dict_get a b = _prim "dict-get" [a; b]
let dict_has_p a b = _prim "dict-has?" [a; b]
let dict_delete a b = _prim "dict-delete!" [a; b]
(* Math *)
let abs' a = _prim "abs" [a]
let sqrt' a = _prim "sqrt" [a]
let pow' a b = _prim "pow" [a; b]
let floor' a = _prim "floor" [a]
let ceil' a = _prim "ceil" [a]
let round' a = _prim "round" [a]
let min' a b = _prim "min" [a; b]
let max' a b = _prim "max" [a; b]
let clamp a b c = _prim "clamp" [a; b; c]
let parse_int a = _prim "parse-int" [a]
let parse_float a = _prim "parse-float" [a]
(* Misc *)
let error msg = raise (Eval_error (value_to_str msg))
(* inspect wrapper — returns String value instead of OCaml string *)
let inspect v = String (Sx_types.inspect v)
let apply' f args = sx_apply f args
let identical_p a b = _prim "identical?" [a; b]
let _is_spread_prim a = _prim "spread?" [a]
let spread_attrs a = _prim "spread-attrs" [a]
let make_spread a = _prim "make-spread" [a]
(* Scope primitives — delegate to sx_ref.py's shared scope stacks *)
let sx_collect a b = prim_call "collect!" [a; b]
let sx_collected a = prim_call "collected" [a]
let sx_clear_collected a = prim_call "clear-collected!" [a]
let sx_emit a b = prim_call "emit!" [a; b]
let sx_emitted a = prim_call "emitted" [a]
let sx_context a b = prim_call "context" [a; b]
(* Trampoline — forward-declared in sx_ref.ml, delegates to CEK eval_expr *)
(* This is a stub; the real trampoline is wired up in sx_ref.ml after eval_expr is defined *)
let trampoline v = v
(* Value-returning type predicates — the transpiled code passes these through
sx_truthy, so they need to return Bool, not OCaml bool. *)
(* type_of returns value, not string *)
let type_of v = String (Sx_types.type_of v)
(* Env operations — accept Env-wrapped values and value keys.
The transpiled CEK machine stores envs in dicts as Env values. *)
let unwrap_env = function
| Env e -> e
| _ -> raise (Eval_error "Expected env")
let env_has e name = Bool (Sx_types.env_has (unwrap_env e) (value_to_str name))
let env_get e name = Sx_types.env_get (unwrap_env e) (value_to_str name)
let env_bind e name v = Sx_types.env_bind (unwrap_env e) (value_to_str name) v
let env_set e name v = Sx_types.env_set (unwrap_env e) (value_to_str name) v
let make_env () = Env (Sx_types.make_env ())
let env_extend e = Env (Sx_types.env_extend (unwrap_env e))
let env_merge a b = Env (Sx_types.env_merge (unwrap_env a) (unwrap_env b))
(* set_lambda_name wrapper — accepts value, extracts string *)
let set_lambda_name l n = Sx_types.set_lambda_name l (value_to_str n)
let is_nil v = Bool (Sx_types.is_nil v)
let is_thunk v = Bool (Sx_types.is_thunk v)
let is_lambda v = Bool (Sx_types.is_lambda v)
let is_component v = Bool (Sx_types.is_component v)
let is_island v = Bool (Sx_types.is_island v)
let is_macro v = Bool (Sx_types.is_macro v)
let is_signal v = Bool (Sx_types.is_signal v)
let is_callable v = Bool (Sx_types.is_callable v)
let is_identical a b = Bool (a == b)
let is_primitive name = Bool (Sx_primitives.is_primitive (value_to_str name))
let get_primitive name = Sx_primitives.get_primitive (value_to_str name)
let is_spread v = match v with Spread _ -> Bool true | _ -> Bool false
(* Stubs for functions defined in sx_ref.ml — resolved at link time *)
(* These are forward-declared here; sx_ref.ml defines the actual implementations *)
(* strip-prefix *)
(* Stubs for evaluator functions — defined in sx_ref.ml but
sometimes referenced before their definition via forward calls.
These get overridden by the actual transpiled definitions. *)
let map_indexed fn coll =
List (List.mapi (fun i x -> sx_call fn [Number (float_of_int i); x]) (sx_to_list coll))
let map_dict fn d =
match d with
| Dict tbl ->
let result = Hashtbl.create (Hashtbl.length tbl) in
Hashtbl.iter (fun k v -> Hashtbl.replace result k (sx_call fn [String k; v])) tbl;
Dict result
| _ -> raise (Eval_error "map-dict: expected dict")
let for_each fn coll =
List.iter (fun x -> ignore (sx_call fn [x])) (sx_to_list coll);
Nil
let for_each_indexed fn coll =
List.iteri (fun i x -> ignore (sx_call fn [Number (float_of_int i); x])) (sx_to_list coll);
Nil
(* Continuation support *)
let continuation_p v = match v with Continuation (_, _) -> Bool true | _ -> Bool false
let make_cek_continuation captured rest_kont =
let data = Hashtbl.create 2 in
Hashtbl.replace data "captured" captured;
Hashtbl.replace data "rest-kont" rest_kont;
Continuation ((fun v -> v), Some data)
let continuation_data v = match v with
| Continuation (_, Some d) -> Dict d
| Continuation (_, None) -> Dict (Hashtbl.create 0)
| _ -> raise (Eval_error "not a continuation")
(* Dynamic wind — simplified for OCaml (no async) *)
let dynamic_wind_call before body after _env =
ignore (sx_call before []);
let result = sx_call body [] in
ignore (sx_call after []);
result
(* Scope stack stubs — delegated to primitives when available *)
let scope_push name value = prim_call "collect!" [name; value]
let scope_pop _name = Nil
let provide_push name value = ignore name; ignore value; Nil
let provide_pop _name = Nil
(* Render mode stubs *)
let render_active_p () = Bool false
let render_expr _expr _env = Nil
let is_render_expr _expr = Bool false
(* Signal accessors *)
let signal_value s = match s with Signal sig' -> sig'.s_value | _ -> raise (Eval_error "not a signal")
let signal_set_value s v = match s with Signal sig' -> sig'.s_value <- v; v | _ -> raise (Eval_error "not a signal")
let signal_subscribers s = match s with Signal sig' -> List (List.map (fun _ -> Nil) sig'.s_subscribers) | _ -> List []
let signal_add_sub_b _s _f = Nil
let signal_remove_sub_b _s _f = Nil
let signal_deps _s = List []
let signal_set_deps _s _d = Nil
let notify_subscribers _s = Nil
let flush_subscribers _s = Nil
let dispose_computed _s = Nil
(* Island scope stubs — accept OCaml functions from transpiled code *)
let with_island_scope _register_fn body_fn = body_fn ()
let register_in_scope _dispose_fn = Nil
(* Component type annotation stub *)
let component_set_param_types_b _comp _types = Nil
(* Parse keyword args from a call — this is defined in evaluator.sx,
the transpiled version will override this stub. *)
(* Forward-reference stubs for evaluator functions used before definition *)
let parse_comp_params _params = List [List []; Nil; Bool false]
let parse_macro_params _params = List [List []; Nil]
let parse_keyword_args _raw_args _env =
(* Stub — the real implementation is transpiled from evaluator.sx *)
List [Dict (Hashtbl.create 0); List []]
(* Make handler/query/action/page def stubs *)
let make_handler_def name params body _env = Dict (let d = Hashtbl.create 4 in Hashtbl.replace d "type" (String "handler"); Hashtbl.replace d "name" name; Hashtbl.replace d "params" params; Hashtbl.replace d "body" body; d)
let make_query_def name params body _env = make_handler_def name params body _env
let make_action_def name params body _env = make_handler_def name params body _env
let make_page_def name _opts = Dict (let d = Hashtbl.create 4 in Hashtbl.replace d "type" (String "page"); Hashtbl.replace d "name" name; d)
(* sf-def* stubs — platform-specific def-forms, not in the SX spec *)
let sf_defhandler args env =
let name = first args in let rest_args = rest args in
make_handler_def name (first rest_args) (nth rest_args (Number 1.0)) env
let sf_defquery args env = sf_defhandler args env
let sf_defaction args env = sf_defhandler args env
let sf_defpage args _env =
let name = first args in make_page_def name (rest args)
let strip_prefix s prefix =
match s, prefix with
| String s, String p ->
let pl = String.length p in
if String.length s >= pl && String.sub s 0 pl = p
then String (String.sub s pl (String.length s - pl))
else String s
| _ -> s

392
hosts/ocaml/lib/sx_types.ml Normal file
View File

@@ -0,0 +1,392 @@
(** Core types for the SX language.
The [value] sum type represents every possible SX runtime value.
OCaml's algebraic types make the CEK machine's frame dispatch a
pattern match — exactly what the spec describes. *)
(** {1 Environment} *)
(** Lexical scope chain. Each frame holds a mutable binding table and
an optional parent link for scope-chain lookup. *)
type env = {
bindings : (string, value) Hashtbl.t;
parent : env option;
}
(** {1 Values} *)
and value =
| Nil
| Bool of bool
| Number of float
| String of string
| Symbol of string
| Keyword of string
| List of value list
| Dict of dict
| Lambda of lambda
| Component of component
| Island of island
| Macro of macro
| Thunk of value * env
| Continuation of (value -> value) * dict option
| NativeFn of string * (value list -> value)
| Signal of signal
| RawHTML of string
| Spread of (string * value) list
| SxExpr of string (** Opaque SX wire-format string — aser output. *)
| Env of env (** First-class environment — used by CEK machine state dicts. *)
| ListRef of value list ref (** Mutable list — JS-style array for append! *)
(** Mutable string-keyed table (SX dicts support [dict-set!]). *)
and dict = (string, value) Hashtbl.t
and lambda = {
l_params : string list;
l_body : value;
l_closure : env;
mutable l_name : string option;
}
and component = {
c_name : string;
c_params : string list;
c_has_children : bool;
c_body : value;
c_closure : env;
c_affinity : string; (** "auto" | "client" | "server" *)
}
and island = {
i_name : string;
i_params : string list;
i_has_children : bool;
i_body : value;
i_closure : env;
}
and macro = {
m_params : string list;
m_rest_param : string option;
m_body : value;
m_closure : env;
m_name : string option;
}
and signal = {
mutable s_value : value;
mutable s_subscribers : (unit -> unit) list;
mutable s_deps : signal list;
}
(** {1 Errors} *)
exception Eval_error of string
exception Parse_error of string
(** {1 Environment operations} *)
let make_env () =
{ bindings = Hashtbl.create 16; parent = None }
let env_extend parent =
{ bindings = Hashtbl.create 16; parent = Some parent }
let env_bind env name v =
Hashtbl.replace env.bindings name v; Nil
let rec env_has env name =
Hashtbl.mem env.bindings name ||
match env.parent with Some p -> env_has p name | None -> false
let rec env_get env name =
match Hashtbl.find_opt env.bindings name with
| Some v -> v
| None ->
match env.parent with
| Some p -> env_get p name
| None -> raise (Eval_error ("Undefined symbol: " ^ name))
let rec env_set env name v =
if Hashtbl.mem env.bindings name then
(Hashtbl.replace env.bindings name v; Nil)
else
match env.parent with
| Some p -> env_set p name v
| None -> Hashtbl.replace env.bindings name v; Nil
let env_merge base overlay =
(* If base and overlay are the same env (physical equality) or overlay
is a descendant of base, just extend base — no copying needed.
This prevents set! inside lambdas from modifying shadow copies. *)
if base == overlay then
{ bindings = Hashtbl.create 16; parent = Some base }
else begin
(* Check if overlay is a descendant of base *)
let rec is_descendant e depth =
if depth > 100 then false
else if e == base then true
else match e.parent with Some p -> is_descendant p (depth + 1) | None -> false
in
if is_descendant overlay 0 then
{ bindings = Hashtbl.create 16; parent = Some base }
else begin
(* General case: extend base, copy ONLY overlay bindings that don't
exist anywhere in the base chain (avoids shadowing closure bindings). *)
let e = { bindings = Hashtbl.create 16; parent = Some base } in
Hashtbl.iter (fun k v ->
if not (env_has base k) then Hashtbl.replace e.bindings k v
) overlay.bindings;
e
end
end
(** {1 Value extraction helpers} *)
let value_to_string = function
| String s -> s | Symbol s -> s | Keyword k -> k
| Number n -> if Float.is_integer n then string_of_int (int_of_float n) else Printf.sprintf "%g" n
| Bool true -> "true" | Bool false -> "false"
| Nil -> "" | _ -> "<value>"
let value_to_string_list = function
| List items | ListRef { contents = items } -> List.map value_to_string items
| _ -> []
let value_to_bool = function
| Bool b -> b | Nil -> false | _ -> true
let value_to_string_opt = function
| String s -> Some s | Symbol s -> Some s | Nil -> None | _ -> None
(** {1 Constructors — accept [value] args from transpiled code} *)
let unwrap_env_val = function
| Env e -> e
| _ -> raise (Eval_error "make_lambda: expected env for closure")
let make_lambda params body closure =
let ps = match params with
| List items -> List.map value_to_string items
| _ -> value_to_string_list params
in
Lambda { l_params = ps; l_body = body; l_closure = unwrap_env_val closure; l_name = None }
let make_component name params has_children body closure affinity =
let n = value_to_string name in
let ps = value_to_string_list params in
let hc = value_to_bool has_children in
let aff = match affinity with String s -> s | _ -> "auto" in
Component {
c_name = n; c_params = ps; c_has_children = hc;
c_body = body; c_closure = unwrap_env_val closure; c_affinity = aff;
}
let make_island name params has_children body closure =
let n = value_to_string name in
let ps = value_to_string_list params in
let hc = value_to_bool has_children in
Island {
i_name = n; i_params = ps; i_has_children = hc;
i_body = body; i_closure = unwrap_env_val closure;
}
let make_macro params rest_param body closure name =
let ps = value_to_string_list params in
let rp = value_to_string_opt rest_param in
let n = value_to_string_opt name in
Macro {
m_params = ps; m_rest_param = rp;
m_body = body; m_closure = unwrap_env_val closure; m_name = n;
}
let make_thunk expr env = Thunk (expr, unwrap_env_val env)
let make_symbol name = Symbol (value_to_string name)
let make_keyword name = Keyword (value_to_string name)
(** {1 Type inspection} *)
let type_of = function
| Nil -> "nil"
| Bool _ -> "boolean"
| Number _ -> "number"
| String _ -> "string"
| Symbol _ -> "symbol"
| Keyword _ -> "keyword"
| List _ | ListRef _ -> "list"
| Dict _ -> "dict"
| Lambda _ -> "lambda"
| Component _ -> "component"
| Island _ -> "island"
| Macro _ -> "macro"
| Thunk _ -> "thunk"
| Continuation (_, _) -> "continuation"
| NativeFn _ -> "function"
| Signal _ -> "signal"
| RawHTML _ -> "raw-html"
| Spread _ -> "spread"
| SxExpr _ -> "sx-expr"
| Env _ -> "env"
let is_nil = function Nil -> true | _ -> false
let is_lambda = function Lambda _ -> true | _ -> false
let is_component = function Component _ -> true | _ -> false
let is_island = function Island _ -> true | _ -> false
let is_macro = function Macro _ -> true | _ -> false
let is_thunk = function Thunk _ -> true | _ -> false
let is_signal = function Signal _ -> true | _ -> false
let is_callable = function
| Lambda _ | NativeFn _ | Continuation (_, _) -> true
| _ -> false
(** {1 Truthiness} *)
(** SX truthiness: everything is truthy except [Nil] and [Bool false]. *)
let sx_truthy = function
| Nil | Bool false -> false
| _ -> true
(** {1 Accessors} *)
let symbol_name = function
| Symbol s -> String s
| v -> raise (Eval_error ("Expected symbol, got " ^ type_of v))
let keyword_name = function
| Keyword k -> String k
| v -> raise (Eval_error ("Expected keyword, got " ^ type_of v))
let lambda_params = function
| Lambda l -> List (List.map (fun s -> String s) l.l_params)
| v -> raise (Eval_error ("Expected lambda, got " ^ type_of v))
let lambda_body = function
| Lambda l -> l.l_body
| v -> raise (Eval_error ("Expected lambda, got " ^ type_of v))
let lambda_closure = function
| Lambda l -> Env l.l_closure
| v -> raise (Eval_error ("Expected lambda, got " ^ type_of v))
let lambda_name = function
| Lambda l -> (match l.l_name with Some n -> String n | None -> Nil)
| v -> raise (Eval_error ("Expected lambda, got " ^ type_of v))
let set_lambda_name l n = match l with
| Lambda l -> l.l_name <- Some n; Nil
| _ -> raise (Eval_error "set-lambda-name!: not a lambda")
let component_name = function
| Component c -> String c.c_name
| v -> raise (Eval_error ("Expected component, got " ^ type_of v))
let component_params = function
| Component c -> List (List.map (fun s -> String s) c.c_params)
| v -> raise (Eval_error ("Expected component, got " ^ type_of v))
let component_body = function
| Component c -> c.c_body
| v -> raise (Eval_error ("Expected component, got " ^ type_of v))
let component_closure = function
| Component c -> Env c.c_closure
| v -> raise (Eval_error ("Expected component, got " ^ type_of v))
let component_has_children = function
| Component c -> Bool c.c_has_children
| v -> raise (Eval_error ("Expected component, got " ^ type_of v))
let component_affinity = function
| Component c -> String c.c_affinity
| _ -> String "auto"
let macro_params = function
| Macro m -> List (List.map (fun s -> String s) m.m_params)
| v -> raise (Eval_error ("Expected macro, got " ^ type_of v))
let macro_rest_param = function
| Macro m -> (match m.m_rest_param with Some s -> String s | None -> Nil)
| v -> raise (Eval_error ("Expected macro, got " ^ type_of v))
let macro_body = function
| Macro m -> m.m_body
| v -> raise (Eval_error ("Expected macro, got " ^ type_of v))
let macro_closure = function
| Macro m -> Env m.m_closure
| v -> raise (Eval_error ("Expected macro, got " ^ type_of v))
let thunk_expr = function
| Thunk (e, _) -> e
| v -> raise (Eval_error ("Expected thunk, got " ^ type_of v))
let thunk_env = function
| Thunk (_, e) -> Env e
| v -> raise (Eval_error ("Expected thunk, got " ^ type_of v))
(** {1 Dict operations} *)
let make_dict () : dict = Hashtbl.create 8
let dict_get (d : dict) key =
match Hashtbl.find_opt d key with Some v -> v | None -> Nil
let dict_has (d : dict) key = Hashtbl.mem d key
let dict_set (d : dict) key v = Hashtbl.replace d key v
let dict_delete (d : dict) key = Hashtbl.remove d key
let dict_keys (d : dict) =
Hashtbl.fold (fun k _ acc -> String k :: acc) d []
let dict_vals (d : dict) =
Hashtbl.fold (fun _ v acc -> v :: acc) d []
(** {1 Value display} *)
let rec inspect = function
| Nil -> "nil"
| Bool true -> "true"
| Bool false -> "false"
| Number n ->
if Float.is_integer n then Printf.sprintf "%d" (int_of_float n)
else Printf.sprintf "%g" n
| String s -> Printf.sprintf "%S" s
| Symbol s -> s
| Keyword k -> ":" ^ k
| List items | ListRef { contents = items } ->
"(" ^ String.concat " " (List.map inspect items) ^ ")"
| Dict d ->
let pairs = Hashtbl.fold (fun k v acc ->
(Printf.sprintf ":%s %s" k (inspect v)) :: acc) d [] in
"{" ^ String.concat " " pairs ^ "}"
| Lambda l ->
let tag = match l.l_name with Some n -> n | None -> "lambda" in
Printf.sprintf "<%s(%s)>" tag (String.concat ", " l.l_params)
| Component c ->
Printf.sprintf "<Component ~%s(%s)>" c.c_name (String.concat ", " c.c_params)
| Island i ->
Printf.sprintf "<Island ~%s(%s)>" i.i_name (String.concat ", " i.i_params)
| Macro m ->
let tag = match m.m_name with Some n -> n | None -> "macro" in
Printf.sprintf "<%s(%s)>" tag (String.concat ", " m.m_params)
| Thunk _ -> "<thunk>"
| Continuation (_, _) -> "<continuation>"
| NativeFn (name, _) -> Printf.sprintf "<native:%s>" name
| Signal _ -> "<signal>"
| RawHTML s -> Printf.sprintf "<raw-html:%d chars>" (String.length s)
| Spread _ -> "<spread>"
| SxExpr s -> Printf.sprintf "<sx-expr:%d chars>" (String.length s)
| Env _ -> "<env>"

1230
hosts/ocaml/transpiler.sx Normal file
View File

File diff suppressed because it is too large Load Diff

26
shared/sx/jinja_bridge.py
View File

@@ -31,7 +31,13 @@ from typing import Any
from .types import NIL, Component, Island, Keyword, Lambda, Macro, Symbol from .types import NIL, Component, Island, Keyword, Lambda, Macro, Symbol
from .parser import parse from .parser import parse
import os as _os import os as _os
if _os.environ.get("SX_USE_REF") == "1": if _os.environ.get("SX_USE_OCAML") == "1":
# OCaml kernel bridge — render via persistent subprocess.
# html_render and _render_component are set up lazily since the bridge
# requires an async event loop. The sync sx() function falls back to
# the ref renderer; async callers use ocaml_bridge directly.
from .ref.sx_ref import render as html_render, render_html_component as _render_component
elif _os.environ.get("SX_USE_REF") == "1":
from .ref.sx_ref import render as html_render, render_html_component as _render_component from .ref.sx_ref import render as html_render, render_html_component as _render_component
else: else:
from .html import render as html_render, _render_component from .html import render as html_render, _render_component
@@ -348,6 +354,12 @@ def reload_if_changed() -> None:
reload_logger.info("Reloaded %d file(s), components in %.1fms", reload_logger.info("Reloaded %d file(s), components in %.1fms",
len(changed_files), (t1 - t0) * 1000) len(changed_files), (t1 - t0) * 1000)
# Invalidate OCaml bridge component cache so next render reloads
if _os.environ.get("SX_USE_OCAML") == "1":
from .ocaml_bridge import _bridge
if _bridge is not None:
_bridge._components_loaded = False
# Recompute render plans for all services that have pages # Recompute render plans for all services that have pages
from .pages import _PAGE_REGISTRY, compute_page_render_plans from .pages import _PAGE_REGISTRY, compute_page_render_plans
for svc in _PAGE_REGISTRY: for svc in _PAGE_REGISTRY:
@@ -430,6 +442,9 @@ def finalize_components() -> None:
compute_all_io_refs(_COMPONENT_ENV, get_all_io_names()) compute_all_io_refs(_COMPONENT_ENV, get_all_io_names())
_compute_component_hash() _compute_component_hash()
# OCaml bridge loads components lazily on first render via
# OcamlBridge._ensure_components() — no sync needed here.
# --------------------------------------------------------------------------- # ---------------------------------------------------------------------------
# sx() — render s-expression from Jinja template # sx() — render s-expression from Jinja template
@@ -482,7 +497,16 @@ async def sx_async(source: str, **kwargs: Any) -> str:
Use when the s-expression contains I/O nodes:: Use when the s-expression contains I/O nodes::
{{ sx_async('(frag "blog" "card" :slug "apple")') | safe }} {{ sx_async('(frag "blog" "card" :slug "apple")') | safe }}
When SX_USE_OCAML=1, renders via the OCaml kernel subprocess which
yields io-requests back to Python for async fulfillment.
""" """
if _os.environ.get("SX_USE_OCAML") == "1":
from .ocaml_bridge import get_bridge
bridge = await get_bridge()
ctx = dict(kwargs)
return await bridge.render(source, ctx=ctx)
from .resolver import resolve, RequestContext from .resolver import resolve, RequestContext
env = dict(_COMPONENT_ENV) env = dict(_COMPONENT_ENV)

408
shared/sx/ocaml_bridge.py Normal file
View File

@@ -0,0 +1,408 @@
"""
OCaml SX kernel ↔ Python coroutine bridge.
Manages a persistent OCaml subprocess (sx_server) that evaluates SX
expressions. When the OCaml kernel needs IO (database queries, service
calls), it yields an ``(io-request ...)`` back to Python, which fulfills
it asynchronously and sends an ``(io-response ...)`` back.
Usage::
bridge = OcamlBridge()
await bridge.start()
html = await bridge.render('(div (p "hello"))')
await bridge.stop()
"""
from __future__ import annotations
import asyncio
import logging
import os
from typing import Any
_logger = logging.getLogger("sx.ocaml")
# Default binary path — can be overridden via SX_OCAML_BIN env var
_DEFAULT_BIN = os.path.join(
os.path.dirname(__file__),
"../../hosts/ocaml/_build/default/bin/sx_server.exe",
)
class OcamlBridgeError(Exception):
"""Error from the OCaml SX kernel."""
class OcamlBridge:
"""Async bridge to a persistent OCaml SX subprocess."""
def __init__(self, binary: str | None = None):
self._binary = binary or os.environ.get("SX_OCAML_BIN") or _DEFAULT_BIN
self._proc: asyncio.subprocess.Process | None = None
self._lock = asyncio.Lock()
self._started = False
self._components_loaded = False
async def start(self) -> None:
"""Launch the OCaml subprocess and wait for (ready)."""
if self._started:
return
bin_path = os.path.abspath(self._binary)
if not os.path.isfile(bin_path):
raise FileNotFoundError(
f"OCaml SX server binary not found: {bin_path}\n"
f"Build with: cd hosts/ocaml && eval $(opam env) && dune build"
)
_logger.info("Starting OCaml SX kernel: %s", bin_path)
self._proc = await asyncio.create_subprocess_exec(
bin_path,
stdin=asyncio.subprocess.PIPE,
stdout=asyncio.subprocess.PIPE,
stderr=asyncio.subprocess.PIPE,
)
# Wait for (ready)
line = await self._readline()
if line != "(ready)":
raise OcamlBridgeError(f"Expected (ready), got: {line!r}")
self._started = True
# Verify engine identity
self._send("(ping)")
kind, engine = await self._read_response()
engine_name = engine if kind == "ok" else "unknown"
_logger.info("OCaml SX kernel ready (pid=%d, engine=%s)", self._proc.pid, engine_name)
async def stop(self) -> None:
"""Terminate the subprocess."""
if self._proc and self._proc.returncode is None:
self._proc.stdin.close()
try:
await asyncio.wait_for(self._proc.wait(), timeout=5.0)
except asyncio.TimeoutError:
self._proc.kill()
await self._proc.wait()
_logger.info("OCaml SX kernel stopped")
self._proc = None
self._started = False
async def ping(self) -> str:
"""Health check — returns engine name (e.g. 'ocaml-cek')."""
async with self._lock:
self._send("(ping)")
kind, value = await self._read_response()
return value or "" if kind == "ok" else ""
async def load(self, path: str) -> int:
"""Load an .sx file for side effects (defcomp, define, defmacro)."""
async with self._lock:
self._send(f'(load "{_escape(path)}")')
kind, value = await self._read_response()
if kind == "error":
raise OcamlBridgeError(f"load {path}: {value}")
return int(float(value)) if value else 0
async def load_source(self, source: str) -> int:
"""Evaluate SX source for side effects."""
async with self._lock:
self._send(f'(load-source "{_escape(source)}")')
kind, value = await self._read_response()
if kind == "error":
raise OcamlBridgeError(f"load-source: {value}")
return int(float(value)) if value else 0
async def eval(self, source: str) -> str:
"""Evaluate SX expression, return serialized result."""
async with self._lock:
self._send(f'(eval "{_escape(source)}")')
kind, value = await self._read_response()
if kind == "error":
raise OcamlBridgeError(f"eval: {value}")
return value or ""
async def render(
self,
source: str,
ctx: dict[str, Any] | None = None,
) -> str:
"""Render SX to HTML, handling io-requests via Python async IO."""
await self._ensure_components()
async with self._lock:
self._send(f'(render "{_escape(source)}")')
return await self._read_until_ok(ctx)
async def _ensure_components(self) -> None:
"""Load component definitions into the kernel on first use."""
if self._components_loaded:
return
self._components_loaded = True
try:
from .jinja_bridge import get_component_env, _CLIENT_LIBRARY_SOURCES
from .parser import serialize
from .types import Component, Island, Macro
env = get_component_env()
parts: list[str] = list(_CLIENT_LIBRARY_SOURCES)
for key, val in env.items():
if isinstance(val, Island):
ps = ["&key"] + list(val.params)
if val.has_children:
ps.extend(["&rest", "children"])
parts.append(f"(defisland ~{val.name} ({' '.join(ps)}) {serialize(val.body)})")
elif isinstance(val, Component):
ps = ["&key"] + list(val.params)
if val.has_children:
ps.extend(["&rest", "children"])
parts.append(f"(defcomp ~{val.name} ({' '.join(ps)}) {serialize(val.body)})")
elif isinstance(val, Macro):
ps = list(val.params)
if val.rest_param:
ps.extend(["&rest", val.rest_param])
parts.append(f"(defmacro {val.name} ({' '.join(ps)}) {serialize(val.body)})")
if parts:
source = "\n".join(parts)
await self.load_source(source)
_logger.info("Loaded %d definitions into OCaml kernel", len(parts))
except Exception as e:
_logger.error("Failed to load components into OCaml kernel: %s", e)
self._components_loaded = False # retry next time
async def reset(self) -> None:
"""Reset the kernel environment to pristine state."""
async with self._lock:
self._send("(reset)")
kind, value = await self._read_response()
if kind == "error":
raise OcamlBridgeError(f"reset: {value}")
# ------------------------------------------------------------------
# Internal protocol handling
# ------------------------------------------------------------------
def _send(self, line: str) -> None:
"""Write a line to the subprocess stdin."""
assert self._proc and self._proc.stdin
self._proc.stdin.write((line + "\n").encode())
async def _readline(self) -> str:
"""Read a line from the subprocess stdout."""
assert self._proc and self._proc.stdout
data = await self._proc.stdout.readline()
if not data:
# Process died — collect stderr for diagnostics
stderr = b""
if self._proc.stderr:
stderr = await self._proc.stderr.read()
raise OcamlBridgeError(
f"OCaml subprocess died unexpectedly. stderr: {stderr.decode(errors='replace')}"
)
return data.decode().rstrip("\n")
async def _read_response(self) -> tuple[str, str | None]:
"""Read a single (ok ...) or (error ...) response.
Returns (kind, value) where kind is "ok" or "error".
"""
line = await self._readline()
return _parse_response(line)
async def _read_until_ok(
self,
ctx: dict[str, Any] | None = None,
) -> str:
"""Read lines until (ok ...) or (error ...).
Handles (io-request ...) by fulfilling IO and sending (io-response ...).
"""
while True:
line = await self._readline()
if line.startswith("(io-request "):
result = await self._handle_io_request(line, ctx)
# Send response back to OCaml
self._send(f"(io-response {_serialize_for_ocaml(result)})")
continue
kind, value = _parse_response(line)
if kind == "error":
raise OcamlBridgeError(value or "Unknown error")
# kind == "ok"
return value or ""
async def _handle_io_request(
self,
line: str,
ctx: dict[str, Any] | None,
) -> Any:
"""Dispatch an io-request to the appropriate Python handler."""
from .parser import parse_all
# Parse the io-request
parsed = parse_all(line)
if not parsed or not isinstance(parsed[0], list):
raise OcamlBridgeError(f"Malformed io-request: {line}")
parts = parsed[0]
# parts = [Symbol("io-request"), name_str, ...args]
if len(parts) < 2:
raise OcamlBridgeError(f"Malformed io-request: {line}")
req_name = _to_str(parts[1])
args = parts[2:]
if req_name == "query":
return await self._io_query(args)
elif req_name == "action":
return await self._io_action(args)
elif req_name == "request-arg":
return self._io_request_arg(args)
elif req_name == "request-method":
return self._io_request_method()
elif req_name == "ctx":
return self._io_ctx(args, ctx)
else:
raise OcamlBridgeError(f"Unknown io-request type: {req_name}")
async def _io_query(self, args: list) -> Any:
"""Handle (io-request "query" service name params...)."""
from shared.infrastructure.internal import fetch_data
service = _to_str(args[0]) if len(args) > 0 else ""
query = _to_str(args[1]) if len(args) > 1 else ""
params = _to_dict(args[2]) if len(args) > 2 else {}
return await fetch_data(service, query, params)
async def _io_action(self, args: list) -> Any:
"""Handle (io-request "action" service name payload...)."""
from shared.infrastructure.internal import call_action
service = _to_str(args[0]) if len(args) > 0 else ""
action = _to_str(args[1]) if len(args) > 1 else ""
payload = _to_dict(args[2]) if len(args) > 2 else {}
return await call_action(service, action, payload)
def _io_request_arg(self, args: list) -> Any:
"""Handle (io-request "request-arg" name)."""
try:
from quart import request
name = _to_str(args[0]) if args else ""
return request.args.get(name)
except RuntimeError:
return None
def _io_request_method(self) -> str:
"""Handle (io-request "request-method")."""
try:
from quart import request
return request.method
except RuntimeError:
return "GET"
def _io_ctx(self, args: list, ctx: dict[str, Any] | None) -> Any:
"""Handle (io-request "ctx" key)."""
if ctx is None:
return None
key = _to_str(args[0]) if args else ""
return ctx.get(key)
# ------------------------------------------------------------------
# Module-level singleton
# ------------------------------------------------------------------
_bridge: OcamlBridge | None = None
async def get_bridge() -> OcamlBridge:
"""Get or create the singleton bridge instance."""
global _bridge
if _bridge is None:
_bridge = OcamlBridge()
if not _bridge._started:
await _bridge.start()
return _bridge
# ------------------------------------------------------------------
# Helpers
# ------------------------------------------------------------------
def _escape(s: str) -> str:
"""Escape a string for embedding in an SX string literal."""
return s.replace("\\", "\\\\").replace('"', '\\"').replace("\n", "\\n").replace("\r", "\\r").replace("\t", "\\t")
def _parse_response(line: str) -> tuple[str, str | None]:
"""Parse an (ok ...) or (error ...) response line.
Returns (kind, value) tuple.
"""
line = line.strip()
if line == "(ok)":
return ("ok", None)
if line.startswith("(ok "):
value = line[4:-1] # strip (ok and )
# If the value is a quoted string, unquote it
if value.startswith('"') and value.endswith('"'):
value = _unescape(value[1:-1])
return ("ok", value)
if line.startswith("(error "):
msg = line[7:-1]
if msg.startswith('"') and msg.endswith('"'):
msg = _unescape(msg[1:-1])
return ("error", msg)
return ("error", f"Unexpected response: {line}")
def _unescape(s: str) -> str:
"""Unescape an SX string literal."""
return (
s.replace("\\n", "\n")
.replace("\\r", "\r")
.replace("\\t", "\t")
.replace('\\"', '"')
.replace("\\\\", "\\")
)
def _to_str(val: Any) -> str:
"""Convert an SX parsed value to a Python string."""
if isinstance(val, str):
return val
if hasattr(val, "name"):
return val.name
return str(val)
def _to_dict(val: Any) -> dict:
"""Convert an SX parsed value to a Python dict."""
if isinstance(val, dict):
return val
return {}
def _serialize_for_ocaml(val: Any) -> str:
"""Serialize a Python value to SX text for sending to OCaml."""
if val is None:
return "nil"
if isinstance(val, bool):
return "true" if val else "false"
if isinstance(val, (int, float)):
if isinstance(val, float) and val == int(val):
return str(int(val))
return str(val)
if isinstance(val, str):
return f'"{_escape(val)}"'
if isinstance(val, (list, tuple)):
items = " ".join(_serialize_for_ocaml(v) for v in val)
return f"(list {items})"
if isinstance(val, dict):
pairs = " ".join(
f":{k} {_serialize_for_ocaml(v)}" for k, v in val.items()
)
return "{" + pairs + "}"
return f'"{_escape(str(val))}"'

220
shared/sx/tests/test_ocaml_bridge.py Normal file
View File

@@ -0,0 +1,220 @@
"""Tests for the OCaml SX bridge."""
import asyncio
import os
import sys
import unittest
# Add project root to path
_project_root = os.path.abspath(os.path.join(os.path.dirname(__file__), "../../.."))
if _project_root not in sys.path:
sys.path.insert(0, _project_root)
from shared.sx.ocaml_bridge import OcamlBridge, OcamlBridgeError, _escape, _parse_response, _serialize_for_ocaml
class TestHelpers(unittest.TestCase):
"""Test helper functions (no subprocess needed)."""
def test_escape_basic(self):
self.assertEqual(_escape('hello'), 'hello')
self.assertEqual(_escape('say "hi"'), 'say \\"hi\\"')
self.assertEqual(_escape('a\\b'), 'a\\\\b')
self.assertEqual(_escape('line\nbreak'), 'line\\nbreak')
def test_parse_response_ok_empty(self):
self.assertEqual(_parse_response("(ok)"), ("ok", None))
def test_parse_response_ok_number(self):
self.assertEqual(_parse_response("(ok 3)"), ("ok", "3"))
def test_parse_response_ok_string(self):
kind, val = _parse_response('(ok "<div>hi</div>")')
self.assertEqual(kind, "ok")
self.assertEqual(val, "<div>hi</div>")
def test_parse_response_error(self):
kind, val = _parse_response('(error "something broke")')
self.assertEqual(kind, "error")
self.assertEqual(val, "something broke")
def test_serialize_none(self):
self.assertEqual(_serialize_for_ocaml(None), "nil")
def test_serialize_bool(self):
self.assertEqual(_serialize_for_ocaml(True), "true")
self.assertEqual(_serialize_for_ocaml(False), "false")
def test_serialize_number(self):
self.assertEqual(_serialize_for_ocaml(42), "42")
self.assertEqual(_serialize_for_ocaml(3.14), "3.14")
def test_serialize_string(self):
self.assertEqual(_serialize_for_ocaml("hello"), '"hello"')
self.assertEqual(_serialize_for_ocaml('say "hi"'), '"say \\"hi\\""')
def test_serialize_list(self):
self.assertEqual(_serialize_for_ocaml([1, 2, 3]), "(list 1 2 3)")
def test_serialize_dict(self):
result = _serialize_for_ocaml({"a": 1})
self.assertEqual(result, "{:a 1}")
class TestBridge(unittest.IsolatedAsyncioTestCase):
"""Integration tests — require the OCaml binary to be built."""
@classmethod
def setUpClass(cls):
# Check if binary exists
from shared.sx.ocaml_bridge import _DEFAULT_BIN
bin_path = os.path.abspath(_DEFAULT_BIN)
if not os.path.isfile(bin_path):
raise unittest.SkipTest(
f"OCaml binary not found at {bin_path}. "
f"Build with: cd hosts/ocaml && eval $(opam env) && dune build"
)
async def asyncSetUp(self):
self.bridge = OcamlBridge()
await self.bridge.start()
async def asyncTearDown(self):
await self.bridge.stop()
async def test_ping(self):
self.assertTrue(await self.bridge.ping())
async def test_eval_arithmetic(self):
result = await self.bridge.eval("(+ 1 2)")
self.assertEqual(result, "3")
async def test_eval_string(self):
result = await self.bridge.eval('(str "hello" " " "world")')
self.assertIn("hello world", result)
async def test_render_simple(self):
html = await self.bridge.render('(div (p "hello"))')
self.assertEqual(html, "<div><p>hello</p></div>")
async def test_render_attrs(self):
html = await self.bridge.render('(div :class "card" (p "hi"))')
self.assertIn('class="card"', html)
self.assertIn("<p>hi</p>", html)
async def test_render_void_element(self):
html = await self.bridge.render("(br)")
self.assertEqual(html, "<br />")
async def test_load_source_defcomp(self):
count = await self.bridge.load_source(
'(defcomp ~test-card (&key title) (div :class "card" (h2 title)))'
)
self.assertEqual(count, 1)
html = await self.bridge.render('(~test-card :title "Hello")')
self.assertIn("Hello", html)
self.assertIn("card", html)
async def test_reset(self):
await self.bridge.load_source("(define x 42)")
result = await self.bridge.eval("x")
self.assertEqual(result, "42")
await self.bridge.reset()
with self.assertRaises(OcamlBridgeError):
await self.bridge.eval("x")
async def test_render_conditional(self):
html = await self.bridge.render('(if true (p "yes") (p "no"))')
self.assertEqual(html, "<p>yes</p>")
async def test_render_let(self):
html = await self.bridge.render('(let (x "hi") (p x))')
self.assertEqual(html, "<p>hi</p>")
async def test_render_map(self):
html = await self.bridge.render(
"(map (lambda (x) (li x)) (list \"a\" \"b\" \"c\"))"
)
self.assertEqual(html, "<li>a</li><li>b</li><li>c</li>")
async def test_render_fragment(self):
html = await self.bridge.render('(<> (p "a") (p "b"))')
self.assertEqual(html, "<p>a</p><p>b</p>")
async def test_eval_error(self):
with self.assertRaises(OcamlBridgeError):
await self.bridge.eval("(undefined-symbol-xyz)")
async def test_render_component_with_children(self):
await self.bridge.load_source(
'(defcomp ~wrapper (&rest children) (div :class "wrap" children))'
)
html = await self.bridge.render('(~wrapper (p "inside"))')
self.assertIn("wrap", html)
self.assertIn("<p>inside</p>", html)
async def test_render_macro(self):
await self.bridge.load_source(
"(defmacro unless (cond &rest body) (list 'if (list 'not cond) (cons 'do body)))"
)
html = await self.bridge.render('(unless false (p "shown"))')
self.assertEqual(html, "<p>shown</p>")
# ------------------------------------------------------------------
# ListRef regression tests — the `list` primitive returns ListRef
# (mutable), not List (immutable). Macro expansions that construct
# AST via `list` produce ListRef nodes. The renderer must handle
# both List and ListRef at every structural match point.
# ------------------------------------------------------------------
async def test_render_macro_generates_cond(self):
"""Macro that programmatically builds a (cond ...) with list."""
await self.bridge.load_source(
"(defmacro pick (x) "
" (list 'cond "
" (list (list '= x 1) '(p \"one\")) "
" (list (list '= x 2) '(p \"two\")) "
" (list ':else '(p \"other\"))))"
)
html = await self.bridge.render("(pick 2)")
self.assertEqual(html, "<p>two</p>")
async def test_render_macro_generates_let(self):
"""Macro that programmatically builds a (let ...) with list."""
await self.bridge.load_source(
"(defmacro with-greeting (name &rest body) "
" (list 'let (list (list 'greeting (list 'str \"Hello \" name))) "
" (cons 'do body)))"
)
html = await self.bridge.render('(with-greeting "World" (p greeting))')
self.assertEqual(html, "<p>Hello World</p>")
async def test_render_macro_nested_html_tags(self):
"""Macro expansion containing nested HTML tags via list."""
await self.bridge.load_source(
"(defmacro card (title &rest body) "
" (list 'div ':class \"card\" "
" (list 'h2 title) "
" (cons 'do body)))"
)
html = await self.bridge.render('(card "Title" (p "content"))')
self.assertIn('<div class="card">', html)
self.assertIn("<h2>Title</h2>", html)
self.assertIn("<p>content</p>", html)
async def test_render_eval_returns_listref(self):
"""Values created at runtime via (list ...) are ListRef."""
await self.bridge.load_source(
"(define make-items (lambda () (list "
' (list "a") (list "b") (list "c"))))'
)
html = await self.bridge.render(
"(ul (map (lambda (x) (li (first x))) (make-items)))"
)
self.assertIn("<li>a</li>", html)
self.assertIn("<li>b</li>", html)
self.assertIn("<li>c</li>", html)
if __name__ == "__main__":
unittest.main()

14
sx/Dockerfile
View File

@@ -1,5 +1,16 @@
# syntax=docker/dockerfile:1 # syntax=docker/dockerfile:1
# --- Stage 1: Build OCaml SX kernel ---
FROM ocaml/opam:debian-12-ocaml-5.2 AS ocaml-build
USER opam
WORKDIR /home/opam/sx
COPY --chown=opam:opam hosts/ocaml/dune-project ./
COPY --chown=opam:opam hosts/ocaml/lib/ ./lib/
COPY --chown=opam:opam hosts/ocaml/bin/dune hosts/ocaml/bin/run_tests.ml \
hosts/ocaml/bin/debug_set.ml hosts/ocaml/bin/sx_server.ml ./bin/
RUN eval $(opam env) && dune build bin/sx_server.exe
# --- Stage 2: Python app ---
FROM python:3.11-slim AS base FROM python:3.11-slim AS base
ENV PYTHONDONTWRITEBYTECODE=1 \ ENV PYTHONDONTWRITEBYTECODE=1 \
@@ -49,6 +60,9 @@ COPY likes/models/ ./likes/models/
COPY orders/__init__.py ./orders/__init__.py COPY orders/__init__.py ./orders/__init__.py
COPY orders/models/ ./orders/models/ COPY orders/models/ ./orders/models/
# OCaml SX kernel binary
COPY --from=ocaml-build /home/opam/sx/_build/default/bin/sx_server.exe /app/bin/sx_server
COPY sx/entrypoint.sh /usr/local/bin/entrypoint.sh COPY sx/entrypoint.sh /usr/local/bin/entrypoint.sh
RUN chmod +x /usr/local/bin/entrypoint.sh RUN chmod +x /usr/local/bin/entrypoint.sh

15
sx/app.py
View File

@@ -148,6 +148,21 @@ def create_app() -> "Quart":
target = path + "/" + ("?" + qs if qs else "") target = path + "/" + ("?" + qs if qs else "")
return redirect(target, 301) return redirect(target, 301)
@app.get("/sx/_engine")
async def sx_engine_info():
"""Diagnostic: which SX engine is active."""
import os, json
info = {"engine": "python-ref", "ocaml": False}
if os.environ.get("SX_USE_OCAML") == "1":
try:
from shared.sx.ocaml_bridge import get_bridge
bridge = await get_bridge()
engine = await bridge.ping()
info = {"engine": engine, "ocaml": True, "pid": bridge._proc.pid}
except Exception as e:
info = {"engine": "ocaml-error", "ocaml": False, "error": str(e)}
return json.dumps(info), 200, {"Content-Type": "application/json"}
@app.get("/sx/") @app.get("/sx/")
async def sx_home(): async def sx_home():
"""SX docs home page.""" """SX docs home page."""

146
sx/sx/plans/foundations.sx
View File

@@ -231,15 +231,135 @@
(tr (td :class "pr-4 py-1" "3") (tr (td :class "pr-4 py-1" "3")
(td :class "pr-4" "Content-addressed computation") (td :class "pr-4" "Content-addressed computation")
(td :class "text-emerald-600 font-semibold" "\u2714 Done \u2014 content-hash, freeze-to-cid, thaw-from-cid")) (td :class "text-emerald-600 font-semibold" "\u2714 Done \u2014 content-hash, freeze-to-cid, thaw-from-cid"))
(tr (td :class "pr-4 py-1" "3.5")
(td :class "pr-4" "Data representations")
(td :class "text-stone-400" "Planned — byte buffers + typed structs"))
(tr (td :class "pr-4 py-1" "4") (tr (td :class "pr-4 py-1" "4")
(td :class "pr-4" "Concurrent CEK") (td :class "pr-4" "Concurrent CEK")
(td :class "text-amber-600 font-semibold" "Spec complete \u2014 implementation next")) (td :class "text-amber-600 font-semibold" "Spec complete implementation next"))
(tr (td :class "pr-4 py-1" "5") (tr (td :class "pr-4 py-1" "5")
(td :class "pr-4" "Linear effects") (td :class "pr-4" "Linear effects")
(td :class "text-stone-400" "Future"))))) (td :class "text-stone-400" "Future")))))
;; ----------------------------------------------------------------------- ;; -----------------------------------------------------------------------
;; Step 4: Concurrent CEK \u2014 deep spec ;; Step 3.5: Data Representations
;; -----------------------------------------------------------------------
(h2 :class "text-xl font-bold mt-12 mb-4" "Step 3.5: Data Representations")
(p "Two primitives that sit below concurrency but above the raw CEK machine. "
"Both are about how values are represented — enabling work that's currently host-only.")
(h3 :class "text-lg font-semibold mt-8 mb-3" "3.5a Byte Buffers")
(p "Fixed-size mutable byte arrays. A small primitive surface that unlocks "
"binary protocol parsing, image headers, wire formats, and efficient CID computation:")
(~docs/code :code
(str ";; Create and write\n"
"(let ((buf (make-buffer 256)))\n"
" (buffer-write-u8! buf 0 #xFF)\n"
" (buffer-write-u32! buf 1 magic-number)\n"
" (buffer-slice buf 0 5))\n"
"\n"
";; Read from network/file\n"
"(let ((header (buffer-slice packet 0 12)))\n"
" (case (buffer-read-u8 header 0)\n"
" (1 (parse-handshake header))\n"
" (2 (parse-data header))\n"
" (else (error \"unknown packet type\"))))"))
(p "Primitives:")
(ul :class "list-disc pl-6 mb-4 space-y-1"
(li (code "make-buffer") " — allocate N zero-filled bytes")
(li (code "buffer-read-u8/u16/u32") ", " (code "buffer-read-i8/i16/i32") " — typed reads at offset")
(li (code "buffer-write-u8!/u16!/u32!") " — typed writes at offset (big-endian default)")
(li (code "buffer-slice") " — zero-copy view of a region")
(li (code "buffer-length") " — byte count")
(li (code "buffer->list") ", " (code "list->buffer") " — conversion to/from byte lists")
(li (code "buffer->string") ", " (code "string->buffer") " — UTF-8 encode/decode"))
(p "Host mapping:")
(div :class "overflow-x-auto mb-6"
(table :class "min-w-full text-sm"
(thead (tr
(th :class "text-left pr-4 pb-2 font-semibold" "Primitive")
(th :class "text-left pr-4 pb-2 font-semibold" "JavaScript")
(th :class "text-left pr-4 pb-2 font-semibold" "Python")
(th :class "text-left pb-2 font-semibold" "OCaml")))
(tbody
(tr (td :class "pr-4 py-1 font-mono" "make-buffer")
(td :class "pr-4" "new ArrayBuffer(n)")
(td :class "pr-4" "bytearray(n)")
(td "Bytes.create n"))
(tr (td :class "pr-4 py-1 font-mono" "buffer-read-u32")
(td :class "pr-4" "DataView.getUint32")
(td :class "pr-4" "struct.unpack_from")
(td "Bytes.get_int32_be"))
(tr (td :class "pr-4 py-1 font-mono" "buffer-slice")
(td :class "pr-4" "new Uint8Array(buf, off, len)")
(td :class "pr-4" "memoryview(buf)[off:off+len]")
(td "Bytes.sub buf off len")))))
(p "Byte buffers connect directly to content addressing (Step 3). "
"Computing a CID currently requires host-side hashing of opaque SX text. "
"With buffers, the hash input can be a canonical binary representation — "
"deterministic, compact, and consistent across hosts.")
(h3 :class "text-lg font-semibold mt-8 mb-3" "3.5b Typed Structs")
(p "Named product types with fixed fields. On interpreted hosts, structs are syntactic sugar over dicts. "
"On compiled hosts (OCaml, Rust), they compile to unboxed records — no dict overhead, "
"no hash lookups, no string key comparisons:")
(~docs/code :code
(str ";; Define a struct\n"
"(defstruct point (x : number) (y : number))\n"
"\n"
";; Construct\n"
"(let ((p (make-point 3 4)))\n"
" ;; Access — compiles to field offset on native hosts\n"
" (+ (point-x p) (point-y p))) ;; => 7\n"
"\n"
";; Pattern match\n"
"(case p\n"
" ((point x y) (sqrt (+ (* x x) (* y y))))) ;; => 5"))
(p "What " (code "defstruct") " generates:")
(ul :class "list-disc pl-6 mb-4 space-y-1"
(li (code "make-point") " — constructor (arity-checked)")
(li (code "point?") " — type predicate")
(li (code "point-x") ", " (code "point-y") " — field accessors")
(li (code "point") " — case pattern for destructuring"))
(p "The performance difference matters for compiled hosts:")
(div :class "overflow-x-auto mb-6"
(table :class "min-w-full text-sm"
(thead (tr
(th :class "text-left pr-4 pb-2 font-semibold" "Operation")
(th :class "text-left pr-4 pb-2 font-semibold" "Dict (current)")
(th :class "text-left pb-2 font-semibold" "Struct (compiled)")))
(tbody
(tr (td :class "pr-4 py-1" "Field access")
(td :class "pr-4" "Hash lookup — O(1) amortized, cache-unfriendly")
(td "Offset load — O(1) actual, single instruction"))
(tr (td :class "pr-4 py-1" "Construction")
(td :class "pr-4" "Allocate hash table + insert N entries")
(td "Allocate N words, write sequentially"))
(tr (td :class "pr-4 py-1" "Pattern match")
(td :class "pr-4" "N string comparisons")
(td "Tag check + field projection")))))
(p "Typed structs connect to the gradual type system in " (code "types.sx") ". "
"A " (code "defstruct") " declaration is a type definition that the type checker can verify "
"and the compiler can exploit. On interpreted hosts, the same code runs — just slower.")
;; -----------------------------------------------------------------------
;; Step 4: Concurrent CEK — deep spec
;; ----------------------------------------------------------------------- ;; -----------------------------------------------------------------------
(h2 :class "text-xl font-bold mt-12 mb-4" "Step 4: Concurrent CEK") (h2 :class "text-xl font-bold mt-12 mb-4" "Step 4: Concurrent CEK")
@@ -449,33 +569,33 @@
(th :class "text-left pr-4 pb-2 font-semibold" "Primitive") (th :class "text-left pr-4 pb-2 font-semibold" "Primitive")
(th :class "text-left pr-4 pb-2 font-semibold" "JavaScript") (th :class "text-left pr-4 pb-2 font-semibold" "JavaScript")
(th :class "text-left pr-4 pb-2 font-semibold" "Python") (th :class "text-left pr-4 pb-2 font-semibold" "Python")
(th :class "text-left pr-4 pb-2 font-semibold" "Haskell") (th :class "text-left pr-4 pb-2 font-semibold" "OCaml")
(th :class "text-left pb-2 font-semibold" "Rust/WASM"))) (th :class "text-left pb-2 font-semibold" "Rust/WASM")))
(tbody (tbody
(tr (td :class "pr-4 py-1 font-mono" "spawn") (tr (td :class "pr-4 py-1 font-mono" "spawn")
(td :class "pr-4" "Web Worker") (td :class "pr-4" "Web Worker")
(td :class "pr-4" "asyncio.create_task") (td :class "pr-4" "asyncio.create_task")
(td :class "pr-4" "forkIO") (td :class "pr-4" "Eio.Fiber.fork")
(td "tokio::spawn")) (td "tokio::spawn"))
(tr (td :class "pr-4 py-1 font-mono" "channel") (tr (td :class "pr-4 py-1 font-mono" "channel")
(td :class "pr-4" "MessageChannel") (td :class "pr-4" "MessageChannel")
(td :class "pr-4" "asyncio.Queue") (td :class "pr-4" "asyncio.Queue")
(td :class "pr-4" "TChan (STM)") (td :class "pr-4" "Eio.Stream.t")
(td "mpsc::channel")) (td "mpsc::channel"))
(tr (td :class "pr-4 py-1 font-mono" "yield!") (tr (td :class "pr-4 py-1 font-mono" "yield!")
(td :class "pr-4" "setTimeout(0)") (td :class "pr-4" "setTimeout(0)")
(td :class "pr-4" "await asyncio.sleep(0)") (td :class "pr-4" "await asyncio.sleep(0)")
(td :class "pr-4" "threadDelay 0") (td :class "pr-4" "Eio.Fiber.yield")
(td "tokio::task::yield_now")) (td "tokio::task::yield_now"))
(tr (td :class "pr-4 py-1 font-mono" "freeze/thaw") (tr (td :class "pr-4 py-1 font-mono" "freeze/thaw")
(td :class "pr-4" "postMessage + JSON") (td :class "pr-4" "postMessage + JSON")
(td :class "pr-4" "pickle / SX text") (td :class "pr-4" "pickle / SX text")
(td :class "pr-4" "Serialise + SX text") (td :class "pr-4" "Marshal + SX text")
(td "serde + SX text")) (td "serde + SX text"))
(tr (td :class "pr-4 py-1 font-mono" "select") (tr (td :class "pr-4 py-1 font-mono" "select")
(td :class "pr-4" "Promise.race") (td :class "pr-4" "Promise.race")
(td :class "pr-4" "asyncio.wait FIRST_COMPLETED") (td :class "pr-4" "asyncio.wait FIRST_COMPLETED")
(td :class "pr-4" "STM orElse") (td :class "pr-4" "Eio.Fiber.any")
(td "tokio::select!"))))) (td "tokio::select!")))))
(h3 :class "text-lg font-semibold mt-8 mb-3" "4.7 Roadmap") (h3 :class "text-lg font-semibold mt-8 mb-3" "4.7 Roadmap")
@@ -501,9 +621,9 @@
(td :class "pr-4" "JavaScript") (td :class "pr-4" "JavaScript")
(td "Art DAG integration path")) (td "Art DAG integration path"))
(tr (td :class "pr-4 py-1" "4d") (tr (td :class "pr-4 py-1" "4d")
(td :class "pr-4" "Haskell bootstrapper") (td :class "pr-4" "OCaml bootstrapper → native compilation")
(td :class "pr-4" "Haskell") (td :class "pr-4" "OCaml")
(td "Spec portability, native concurrency")) (td "Native performance, direct CEK-to-ML mapping"))
(tr (td :class "pr-4 py-1" "4e") (tr (td :class "pr-4 py-1" "4e")
(td :class "pr-4" "Rust/WASM bootstrapper") (td :class "pr-4" "Rust/WASM bootstrapper")
(td :class "pr-4" "Rust") (td :class "pr-4" "Rust")
@@ -526,8 +646,8 @@
(td "Resource safety, exactly-once delivery"))))) (td "Resource safety, exactly-once delivery")))))
(p "Each phase is independently valuable. Phase 4a (Web Worker spawn) is the immediate next build. " (p "Each phase is independently valuable. Phase 4a (Web Worker spawn) is the immediate next build. "
"Phase 4d (Haskell) proves the spec is truly host-independent. " "Phase 4d (OCaml) proves the spec compiles to native code — the CEK machine maps directly to ML's runtime model. "
"Phase 4e (Rust/WASM) proves it can be fast. " "Phase 4e (Rust/WASM) proves it can run in the browser at near-native speed. "
"Phase 4g (IPFS) makes it distributed.") "Phase 4g (IPFS) makes it distributed.")
;; ----------------------------------------------------------------------- ;; -----------------------------------------------------------------------