ocaml: phase 5.1 trapping_rain.ml baseline (LeetCode trapped water = 6)

Classic trapped-rain-water two-pass DP: left_max[i] = max(heights[0..i]) (forward sweep) right_max[i] = max(heights[i..n-1]) (downto sweep) water = sum over i of (min(left_max[i], right_max[i]) - heights[i]) For [0; 1; 0; 2; 1; 0; 1; 3; 2; 1; 2; 1]: water = 6. Tests dual sweep (forward + downto), array of running maxes, inline-if rhs of <- for running-max update (uses iter-236 fix for <- accepting if/match RHS). 203 baseline programs total.
ocaml: phase 5.1 gas_station.ml baseline (circular tour start = 3)
2026-05-11 05:54:39 +00:00 · 2026-05-11 05:44:38 +00:00 · 2026-05-11 05:34:46 +00:00 · 2026-05-11 05:25:03 +00:00 · 2026-05-11 05:14:47 +00:00 · 2026-05-11 05:04:37 +00:00
273 changed files with 24988 additions and 580 deletions
--- a/hosts/ocaml/bootstrap_vm.py
+++ b/hosts/ocaml/bootstrap_vm.py
@@ -355,7 +355,9 @@ let vm_create_closure vm_val frame_val code_val =
  let f = unwrap_frame frame_val in
  let uv_count = match code_val with
    | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-        | Some (Number n) -> int_of_float n | _ -> 0)
+        | Some (Integer n) -> n
        | Some (Number n) -> int_of_float n
        | _ -> 0)
    | _ -> 0
  in
  let upvalues = Array.init uv_count (fun _ ->
--- a/hosts/ocaml/browser/sx_browser.ml
+++ b/hosts/ocaml/browser/sx_browser.ml
@@ -715,8 +715,10 @@ let () =
        | List (Symbol "code" :: rest) ->
          let d = Hashtbl.create 8 in
          let rec parse_kv = function
-            | Keyword "arity" :: Number n :: rest -> Hashtbl.replace d "arity" (Number n); parse_kv rest
+            | Keyword "arity" :: (Number _ as n) :: rest -> Hashtbl.replace d "arity" n; parse_kv rest
-            | Keyword "upvalue-count" :: Number n :: rest -> Hashtbl.replace d "upvalue-count" (Number n); parse_kv rest
+            | Keyword "arity" :: (Integer _ as n) :: rest -> Hashtbl.replace d "arity" n; parse_kv rest
            | Keyword "upvalue-count" :: (Number _ as n) :: rest -> Hashtbl.replace d "upvalue-count" n; parse_kv rest
            | Keyword "upvalue-count" :: (Integer _ as n) :: rest -> Hashtbl.replace d "upvalue-count" n; parse_kv rest
            | Keyword "bytecode" :: List nums :: rest ->
              Hashtbl.replace d "bytecode" (List nums); parse_kv rest
            | Keyword "constants" :: List consts :: rest ->
--- a/hosts/ocaml/lib/sx_primitives.ml
+++ b/hosts/ocaml/lib/sx_primitives.ml
@@ -3124,6 +3124,442 @@ let () =
    | [String pat] -> List (List.map (fun s -> String s) (glob_paths pat))
    | _ -> raise (Eval_error "file-glob: (pattern)"));
  (* === File metadata + ops (Phase 5d) === *)
  let stat_or = function
    | String path -> (try Some (Unix.stat path) with _ -> None)
    | _ -> raise (Eval_error "file: path must be a string")
  in
  register "file-size" (fun args ->
    match args with
    | [v] -> (match stat_or v with Some s -> Integer s.Unix.st_size | None -> Integer 0)
    | _ -> raise (Eval_error "file-size: (path)"));
  register "file-mtime" (fun args ->
    match args with
    | [v] -> (match stat_or v with Some s -> Integer (int_of_float s.Unix.st_mtime) | None -> Integer 0)
    | _ -> raise (Eval_error "file-mtime: (path)"));
  register "file-isfile?" (fun args ->
    match args with
    | [v] -> (match stat_or v with Some s -> Bool (s.Unix.st_kind = Unix.S_REG) | None -> Bool false)
    | _ -> raise (Eval_error "file-isfile?: (path)"));
  register "file-isdir?" (fun args ->
    match args with
    | [v] -> (match stat_or v with Some s -> Bool (s.Unix.st_kind = Unix.S_DIR) | None -> Bool false)
    | _ -> raise (Eval_error "file-isdir?: (path)"));
  register "file-readable?" (fun args ->
    match args with
    | [String path] ->
      Bool (try Unix.access path [Unix.R_OK]; true with _ -> false)
    | _ -> raise (Eval_error "file-readable?: (path)"));
  register "file-writable?" (fun args ->
    match args with
    | [String path] ->
      Bool (try Unix.access path [Unix.W_OK]; true with _ -> false)
    | _ -> raise (Eval_error "file-writable?: (path)"));
  register "file-stat" (fun args ->
    match args with
    | [v] ->
      (match stat_or v with
       | None -> Nil
       | Some s ->
         let d = Hashtbl.create 6 in
         Hashtbl.replace d "size" (Integer s.Unix.st_size);
         Hashtbl.replace d "mtime" (Integer (int_of_float s.Unix.st_mtime));
         Hashtbl.replace d "atime" (Integer (int_of_float s.Unix.st_atime));
         Hashtbl.replace d "ctime" (Integer (int_of_float s.Unix.st_ctime));
         Hashtbl.replace d "mode" (Integer s.Unix.st_perm);
         Hashtbl.replace d "type" (String (match s.Unix.st_kind with
           | Unix.S_REG -> "file" | Unix.S_DIR -> "directory"
           | Unix.S_LNK -> "link" | Unix.S_CHR -> "characterSpecial"
           | Unix.S_BLK -> "blockSpecial" | Unix.S_FIFO -> "fifo"
           | Unix.S_SOCK -> "socket"));
         Dict d)
    | _ -> raise (Eval_error "file-stat: (path)"));
  register "file-delete" (fun args ->
    match args with
    | [String path] ->
      (try
        if Sys.is_directory path then Unix.rmdir path
        else Unix.unlink path
      with
      | Unix.Unix_error (Unix.ENOENT, _, _) -> ()  (* tolerate missing *)
      | Unix.Unix_error (e, _, _) -> raise (Eval_error ("file-delete: " ^ Unix.error_message e)));
      Nil
    | _ -> raise (Eval_error "file-delete: (path)"));
  register "file-mkdir" (fun args ->
    match args with
    | [String path] ->
      let rec mk p =
        if p = "" || p = "." || p = "/" then ()
        else if Sys.file_exists p then ()
        else begin
          mk (Filename.dirname p);
          (try Unix.mkdir p 0o755
           with Unix.Unix_error (Unix.EEXIST, _, _) -> ())
        end
      in
      (try mk path
       with Unix.Unix_error (e, _, _) -> raise (Eval_error ("file-mkdir: " ^ Unix.error_message e)));
      Nil
    | _ -> raise (Eval_error "file-mkdir: (path)"));
  register "file-copy" (fun args ->
    match args with
    | [String src; String dst] ->
      (try
        let ic = open_in_bin src in
        let oc = open_out_bin dst in
        let buf = Bytes.create 8192 in
        let rec loop () =
          let n = input ic buf 0 (Bytes.length buf) in
          if n > 0 then (output oc buf 0 n; loop ())
        in
        loop ();
        close_in ic;
        close_out oc;
        Nil
      with
      | Sys_error msg -> raise (Eval_error ("file-copy: " ^ msg)))
    | _ -> raise (Eval_error "file-copy: (src dst)"));
  register "file-rename" (fun args ->
    match args with
    | [String src; String dst] ->
      (try Sys.rename src dst with Sys_error msg -> raise (Eval_error ("file-rename: " ^ msg)));
      Nil
    | _ -> raise (Eval_error "file-rename: (src dst)"));
  (* === Channels (random-access + blocking control) === *)
  let channel_table : (string, Unix.file_descr * string * bool ref * bool ref) Hashtbl.t = Hashtbl.create 16 in
  let channel_next_id = ref 0 in
  let parse_open_mode mode =
    match mode with
    | "r"  -> [Unix.O_RDONLY]
    | "w"  -> [Unix.O_WRONLY; Unix.O_CREAT; Unix.O_TRUNC]
    | "a"  -> [Unix.O_WRONLY; Unix.O_CREAT; Unix.O_APPEND]
    | "r+" -> [Unix.O_RDWR]
    | "w+" -> [Unix.O_RDWR; Unix.O_CREAT; Unix.O_TRUNC]
    | "a+" -> [Unix.O_RDWR; Unix.O_CREAT; Unix.O_APPEND]
    | _ -> raise (Eval_error ("channel-open: invalid mode " ^ mode))
  in
  let chan_get name =
    match Hashtbl.find_opt channel_table name with
    | Some c -> c
    | None -> raise (Eval_error ("channel: no such channel " ^ name))
  in
  register "channel-open" (fun args ->
    match args with
    | [String path; String mode] ->
      (try
        let fd = Unix.openfile path (parse_open_mode mode) 0o644 in
        let id = !channel_next_id in
        incr channel_next_id;
        let name = Printf.sprintf "file%d" id in
        Hashtbl.replace channel_table name (fd, mode, ref false, ref true);
        String name
      with Unix.Unix_error (e, _, _) -> raise (Eval_error ("channel-open: " ^ Unix.error_message e)))
    | _ -> raise (Eval_error "channel-open: (path mode)"));
  register "channel-close" (fun args ->
    match args with
    | [String name] ->
      let (fd, _, _, _) = chan_get name in
      (try Unix.close fd with _ -> ());
      Hashtbl.remove channel_table name;
      Nil
    | _ -> raise (Eval_error "channel-close: (channel)"));
  register "channel-read" (fun args ->
    let (name, max_n) = match args with
      | [String n] -> (n, -1)
      | [String n; Integer m] -> (n, m)
      | [String n; Number m] -> (n, int_of_float m)
      | _ -> raise (Eval_error "channel-read: (channel ?n?)")
    in
    let (fd, _, eof, _) = chan_get name in
    let chunk = 8192 in
    let buf = Bytes.create chunk in
    let buffer = Buffer.create chunk in
    let total = ref 0 in
    let stop = ref false in
    while not !stop do
      let want = if max_n < 0 then chunk else min chunk (max_n - !total) in
      if want <= 0 then stop := true
      else begin
        try
          let r = Unix.read fd buf 0 want in
          if r = 0 then begin eof := true; stop := true end
          else begin
            Buffer.add_subbytes buffer buf 0 r;
            total := !total + r
          end
        with
        | Unix.Unix_error (Unix.EAGAIN, _, _)
        | Unix.Unix_error (Unix.EWOULDBLOCK, _, _) -> stop := true
      end
    done;
    String (Buffer.contents buffer));
  register "channel-read-line" (fun args ->
    match args with
    | [String name] ->
      let (fd, _, eof, _) = chan_get name in
      let buf = Buffer.create 80 in
      let one = Bytes.create 1 in
      let got_data = ref false in
      let stop = ref false in
      while not !stop do
        try
          let r = Unix.read fd one 0 1 in
          if r = 0 then begin eof := true; stop := true end
          else begin
            got_data := true;
            let c = Bytes.get one 0 in
            if c = '\n' then stop := true
            else Buffer.add_char buf c
          end
        with
        | Unix.Unix_error (Unix.EAGAIN, _, _)
        | Unix.Unix_error (Unix.EWOULDBLOCK, _, _) -> stop := true
      done;
      if !got_data then String (Buffer.contents buf) else Nil
    | _ -> raise (Eval_error "channel-read-line: (channel)"));
  register "channel-write" (fun args ->
    match args with
    | [String name; String s] ->
      let (fd, _, _, _) = chan_get name in
      let b = Bytes.of_string s in
      let n = Bytes.length b in
      let written = ref 0 in
      while !written < n do
        (try
          let w = Unix.write fd b !written (n - !written) in
          written := !written + w
        with
        | Unix.Unix_error (Unix.EAGAIN, _, _)
        | Unix.Unix_error (Unix.EWOULDBLOCK, _, _) ->
          (* short write — let caller retry *)
          written := n)
      done;
      Nil
    | _ -> raise (Eval_error "channel-write: (channel string)"));
  register "channel-flush" (fun args ->
    match args with
    | [String name] -> let _ = chan_get name in Nil  (* no userspace buffer *)
    | _ -> raise (Eval_error "channel-flush: (channel)"));
  register "channel-seek" (fun args ->
    let (name, offset, whence) = match args with
      | [String n; Integer o] -> (n, o, "start")
      | [String n; Number o] -> (n, int_of_float o, "start")
      | [String n; Integer o; String w] -> (n, o, w)
      | [String n; Number o; String w] -> (n, int_of_float o, w)
      | _ -> raise (Eval_error "channel-seek: (channel offset ?whence?)")
    in
    let (fd, _, eof, _) = chan_get name in
    let cmd = match whence with
      | "start" -> Unix.SEEK_SET
      | "current" -> Unix.SEEK_CUR
      | "end" -> Unix.SEEK_END
      | _ -> raise (Eval_error ("channel-seek: invalid whence " ^ whence))
    in
    let _ = Unix.lseek fd offset cmd in
    eof := false;
    Nil);
  register "channel-tell" (fun args ->
    match args with
    | [String name] ->
      let (fd, _, _, _) = chan_get name in
      Integer (Unix.lseek fd 0 Unix.SEEK_CUR)
    | _ -> raise (Eval_error "channel-tell: (channel)"));
  register "channel-eof?" (fun args ->
    match args with
    | [String name] ->
      let (_, _, eof, _) = chan_get name in
      Bool !eof
    | _ -> raise (Eval_error "channel-eof?: (channel)"));
  register "channel-blocking?" (fun args ->
    match args with
    | [String name] ->
      let (_, _, _, blocking) = chan_get name in
      Bool !blocking
    | _ -> raise (Eval_error "channel-blocking?: (channel)"));
  register "channel-set-blocking!" (fun args ->
    match args with
    | [String name; Bool b] ->
      let (fd, _, _, blocking) = chan_get name in
      blocking := b;
      (try
        if b then Unix.clear_nonblock fd
        else Unix.set_nonblock fd
      with _ -> ());
      Nil
    | _ -> raise (Eval_error "channel-set-blocking!: (channel bool)"));
  (* === Sockets === wrapping Unix.socket/connect/bind/listen/accept *)
  let resolve_inet_addr host =
    if host = "" || host = "0.0.0.0" then Unix.inet_addr_any
    else if host = "localhost" then Unix.inet_addr_loopback
    else
      try Unix.inet_addr_of_string host
      with _ ->
        try
          let entry = Unix.gethostbyname host in
          if Array.length entry.Unix.h_addr_list = 0 then
            raise (Eval_error ("socket: cannot resolve " ^ host))
          else entry.Unix.h_addr_list.(0)
        with Not_found -> raise (Eval_error ("socket: cannot resolve " ^ host))
  in
  let port_of v = match v with
    | Integer n -> n
    | Number n -> int_of_float n
    | _ -> raise (Eval_error "socket: port must be a number")
  in
  let alloc_chan_name () =
    let id = !channel_next_id in
    incr channel_next_id;
    Printf.sprintf "sock%d" id
  in
  register "socket-connect" (fun args ->
    match args with
    | [String host; port_v] ->
      let port = port_of port_v in
      let addr = Unix.ADDR_INET (resolve_inet_addr host, port) in
      let sock = Unix.socket Unix.PF_INET Unix.SOCK_STREAM 0 in
      (try Unix.connect sock addr
       with Unix.Unix_error (e, _, _) ->
         (try Unix.close sock with _ -> ());
         raise (Eval_error ("socket-connect: " ^ Unix.error_message e)));
      let name = alloc_chan_name () in
      Hashtbl.replace channel_table name (sock, "rw", ref false, ref true);
      String name
    | _ -> raise (Eval_error "socket-connect: (host port)"));
  (* Non-blocking connect: returns channel immediately. Connection completes
     when the channel becomes writable; query channel-async-error? after to
     confirm success or get the error. *)
  register "socket-connect-async" (fun args ->
    match args with
    | [String host; port_v] ->
      let port = port_of port_v in
      let addr = Unix.ADDR_INET (resolve_inet_addr host, port) in
      let sock = Unix.socket Unix.PF_INET Unix.SOCK_STREAM 0 in
      Unix.set_nonblock sock;
      (try Unix.connect sock addr
       with
       | Unix.Unix_error (Unix.EINPROGRESS, _, _)
       | Unix.Unix_error (Unix.EWOULDBLOCK, _, _) -> ()
       | Unix.Unix_error (e, _, _) ->
         (try Unix.close sock with _ -> ());
         raise (Eval_error ("socket-connect-async: " ^ Unix.error_message e)));
      let name = alloc_chan_name () in
      Hashtbl.replace channel_table name (sock, "rw", ref false, ref false);
      String name
    | _ -> raise (Eval_error "socket-connect-async: (host port)"));
  (* After a non-blocking connect completes (channel writable), check whether
     the connect succeeded. Returns "" on success, error message on failure. *)
  register "channel-async-error" (fun args ->
    match args with
    | [String name] ->
      let (fd, _, _, _) = chan_get name in
      (try
        let err = Unix.getsockopt_error fd in
        match err with
        | None -> String ""
        | Some e -> String (Unix.error_message e)
      with
      | Unix.Unix_error (e, _, _) -> String (Unix.error_message e))
    | _ -> raise (Eval_error "channel-async-error: (channel)"));
  register "socket-server" (fun args ->
    let (host, port) = match args with
      | [port_v] -> ("", port_of port_v)
      | [String h; port_v] -> (h, port_of port_v)
      | _ -> raise (Eval_error "socket-server: (port) or (host port)")
    in
    let addr = Unix.ADDR_INET (resolve_inet_addr host, port) in
    let sock = Unix.socket Unix.PF_INET Unix.SOCK_STREAM 0 in
    Unix.setsockopt sock Unix.SO_REUSEADDR true;
    (try Unix.bind sock addr
     with Unix.Unix_error (e, _, _) ->
       (try Unix.close sock with _ -> ());
       raise (Eval_error ("socket-server: bind: " ^ Unix.error_message e)));
    Unix.listen sock 8;
    let name = alloc_chan_name () in
    Hashtbl.replace channel_table name (sock, "server", ref false, ref true);
    String name);
  register "socket-accept" (fun args ->
    match args with
    | [String name] ->
      let (sock, _, _, _) = chan_get name in
      let (client_sock, client_addr) =
        try Unix.accept sock
        with Unix.Unix_error (e, _, _) ->
          raise (Eval_error ("socket-accept: " ^ Unix.error_message e))
      in
      let (host_str, port) = match client_addr with
        | Unix.ADDR_INET (addr, p) -> (Unix.string_of_inet_addr addr, p)
        | Unix.ADDR_UNIX path -> (path, 0)
      in
      let client_name = alloc_chan_name () in
      Hashtbl.replace channel_table client_name (client_sock, "rw", ref false, ref true);
      let d = Hashtbl.create 3 in
      Hashtbl.replace d "channel" (String client_name);
      Hashtbl.replace d "host" (String host_str);
      Hashtbl.replace d "port" (Integer port);
      Dict d
    | _ -> raise (Eval_error "socket-accept: (server-channel)"));
  (* io-select-channels: (read-list write-list timeout-ms) → {:readable [...] :writable [...]}
     timeout-ms < 0 → block indefinitely; 0 → poll. Returns ready channel names. *)
  register "io-select-channels" (fun args ->
    let to_ms v = match v with
      | Integer n -> n
      | Number n -> int_of_float n
      | _ -> raise (Eval_error "io-select-channels: timeout must be a number")
    in
    let to_list v = match v with
      | List xs | ListRef { contents = xs } -> xs
      | Nil -> []
      | _ -> raise (Eval_error "io-select-channels: expected list")
    in
    let chan_name_of v = match v with
      | String s -> s
      | _ -> raise (Eval_error "io-select-channels: channel must be a string")
    in
    let (read_list, write_list, timeout_ms) = match args with
      | [r; w; t] -> (to_list r, to_list w, to_ms t)
      | _ -> raise (Eval_error "io-select-channels: (read-list write-list timeout-ms)")
    in
    let read_pairs = List.map (fun v ->
      let name = chan_name_of v in
      let (fd, _, _, _) = chan_get name in (name, fd)) read_list in
    let write_pairs = List.map (fun v ->
      let name = chan_name_of v in
      let (fd, _, _, _) = chan_get name in (name, fd)) write_list in
    let read_fds = List.map snd read_pairs in
    let write_fds = List.map snd write_pairs in
    let timeout = if timeout_ms < 0 then -1.0 else float_of_int timeout_ms /. 1000.0 in
    let (ready_r, ready_w, _) =
      try Unix.select read_fds write_fds [] timeout
      with Unix.Unix_error (Unix.EINTR, _, _) -> ([], [], [])
    in
    let names_of pairs ready =
      List.filter_map (fun (n, fd) ->
        if List.exists (fun rfd -> rfd = fd) ready then Some (String n) else None
      ) pairs
    in
    let d = Hashtbl.create 2 in
    Hashtbl.replace d "readable" (List (names_of read_pairs ready_r));
    Hashtbl.replace d "writable" (List (names_of write_pairs ready_w));
    Dict d);
  (* === Clock === *)
  register "clock-seconds" (fun args ->
    match args with
@@ -3135,11 +3571,8 @@ let () =
    | [] -> Integer (int_of_float (Unix.gettimeofday () *. 1000.0))
    | _ -> raise (Eval_error "clock-milliseconds: no args"));
-  register "clock-format" (fun args ->
+  let format_tm tm tz_label =
-    match args with
+    fun fmt ->
    | [Integer t] | [Integer t; String _] ->
      let fmt = (match args with [_; String f] -> f | _ -> "%a %b %e %H:%M:%S %Z %Y") in
      let tm = Unix.gmtime (float_of_int t) in
      let buf = Buffer.create 32 in
      let n = String.length fmt in
      let i = ref 0 in
@@ -3147,14 +3580,19 @@ let () =
        if fmt.[!i] = '%' && !i + 1 < n then begin
          (match fmt.[!i + 1] with
           | 'Y' -> Buffer.add_string buf (Printf.sprintf "%04d" (1900 + tm.Unix.tm_year))
           | 'y' -> Buffer.add_string buf (Printf.sprintf "%02d" ((1900 + tm.Unix.tm_year) mod 100))
           | 'm' -> Buffer.add_string buf (Printf.sprintf "%02d" (tm.Unix.tm_mon + 1))
           | 'd' -> Buffer.add_string buf (Printf.sprintf "%02d" tm.Unix.tm_mday)
           | 'e' -> Buffer.add_string buf (Printf.sprintf "%2d"  tm.Unix.tm_mday)
           | 'H' -> Buffer.add_string buf (Printf.sprintf "%02d" tm.Unix.tm_hour)
           | 'I' -> let h = tm.Unix.tm_hour mod 12 in
                    Buffer.add_string buf (Printf.sprintf "%02d" (if h = 0 then 12 else h))
           | 'p' -> Buffer.add_string buf (if tm.Unix.tm_hour < 12 then "AM" else "PM")
           | 'M' -> Buffer.add_string buf (Printf.sprintf "%02d" tm.Unix.tm_min)
           | 'S' -> Buffer.add_string buf (Printf.sprintf "%02d" tm.Unix.tm_sec)
           | 'j' -> Buffer.add_string buf (Printf.sprintf "%03d" (tm.Unix.tm_yday + 1))
-           | 'Z' -> Buffer.add_string buf "UTC"
+           | 'w' -> Buffer.add_string buf (string_of_int tm.Unix.tm_wday)
           | 'Z' -> Buffer.add_string buf tz_label
           | 'a' -> let days = [|"Sun";"Mon";"Tue";"Wed";"Thu";"Fri";"Sat"|] in
                    Buffer.add_string buf days.(tm.Unix.tm_wday)
           | 'A' -> let days = [|"Sunday";"Monday";"Tuesday";"Wednesday";"Thursday";"Friday";"Saturday"|] in
@@ -3163,6 +3601,7 @@ let () =
                    Buffer.add_string buf mons.(tm.Unix.tm_mon)
           | 'B' -> let mons = [|"January";"February";"March";"April";"May";"June";"July";"August";"September";"October";"November";"December"|] in
                    Buffer.add_string buf mons.(tm.Unix.tm_mon)
           | '%' -> Buffer.add_char buf '%'
           | c -> Buffer.add_char buf '%'; Buffer.add_char buf c);
          i := !i + 2
        end else begin
@@ -3170,8 +3609,100 @@ let () =
          incr i
        end
      done;
-      String (Buffer.contents buf)
+      Buffer.contents buf
-    | _ -> raise (Eval_error "clock-format: (seconds [format])"));
+  in
  register "clock-format" (fun args ->
    let (t, fmt, tz) = match args with
      | [Integer t] -> (t, "%a %b %e %H:%M:%S %Z %Y", "utc")
      | [Integer t; String f] -> (t, f, "utc")
      | [Integer t; String f; String z] -> (t, f, z)
      | _ -> raise (Eval_error "clock-format: (seconds [format [tz]])")
    in
    let tm =
      if tz = "local" then Unix.localtime (float_of_int t)
      else Unix.gmtime (float_of_int t)
    in
    let label = if tz = "local" then "" else "UTC" in
    String (format_tm tm label fmt));
  (* clock-scan: parse a date string with format, return seconds.
     Supports the same format specifiers as clock-format (fixed-width ones).
     tz: "utc" (default) or "local". *)
  let timegm (tm : Unix.tm) =
    let is_leap y = y mod 4 = 0 && (y mod 100 <> 0 || y mod 400 = 0) in
    let days_in_month = [|31;28;31;30;31;30;31;31;30;31;30;31|] in
    let year = tm.Unix.tm_year + 1900 in
    let mon = tm.Unix.tm_mon in
    let mday = tm.Unix.tm_mday in
    let total_days = ref 0 in
    if year >= 1970 then begin
      for y = 1970 to year - 1 do
        total_days := !total_days + (if is_leap y then 366 else 365)
      done
    end else begin
      for y = year to 1969 do
        total_days := !total_days - (if is_leap y then 366 else 365)
      done
    end;
    for m = 0 to mon - 1 do
      total_days := !total_days + days_in_month.(m);
      if m = 1 && is_leap year then incr total_days
    done;
    total_days := !total_days + mday - 1;
    !total_days * 86400
    + tm.Unix.tm_hour * 3600
    + tm.Unix.tm_min * 60
    + tm.Unix.tm_sec
  in
  register "clock-scan" (fun args ->
    let (str, fmt, tz) = match args with
      | [String s; String f] -> (s, f, "utc")
      | [String s; String f; String z] -> (s, f, z)
      | _ -> raise (Eval_error "clock-scan: (str fmt [tz])")
    in
    let n = String.length fmt and sn = String.length str in
    let tm = ref { Unix.tm_year = 70; tm_mon = 0; tm_mday = 1;
                   tm_hour = 0; tm_min = 0; tm_sec = 0;
                   tm_wday = 0; tm_yday = 0; tm_isdst = false } in
    let i = ref 0 and j = ref 0 in
    let read_n_digits k =
      let s = ref "" in
      let cnt = ref 0 in
      while !cnt < k && !j < sn && str.[!j] >= '0' && str.[!j] <= '9' do
        s := !s ^ String.make 1 str.[!j];
        incr j; incr cnt
      done;
      if !s = "" then 0 else int_of_string !s
    in
    let skip_ws () =
      while !j < sn && (str.[!j] = ' ' || str.[!j] = '\t') do incr j done
    in
    while !i < n do
      if fmt.[!i] = '%' && !i + 1 < n then begin
        (match fmt.[!i + 1] with
         | 'Y' -> tm := { !tm with tm_year = read_n_digits 4 - 1900 }
         | 'y' -> let y = read_n_digits 2 in
                  tm := { !tm with tm_year = (if y < 70 then 100 + y else y) }
         | 'm' -> tm := { !tm with tm_mon = read_n_digits 2 - 1 }
         | 'd' | 'e' -> skip_ws (); tm := { !tm with tm_mday = read_n_digits 2 }
         | 'H' | 'I' -> tm := { !tm with tm_hour = read_n_digits 2 }
         | 'M' -> tm := { !tm with tm_min = read_n_digits 2 }
         | 'S' -> tm := { !tm with tm_sec = read_n_digits 2 }
         | '%' -> if !j < sn && str.[!j] = '%' then incr j
         | _ -> ()  (* unsupported specifier — skip *)
        );
        i := !i + 2
      end else begin
        if fmt.[!i] = ' ' then skip_ws ()
        else if !j < sn && str.[!j] = fmt.[!i] then incr j;
        incr i
      end
    done;
    let secs =
      if tz = "local" then int_of_float (fst (Unix.mktime !tm))
      else timegm !tm
    in
    Integer secs);
  (* === Env-as-value (Phase 4) === *)
--- a/hosts/ocaml/lib/sx_vm.ml
+++ b/hosts/ocaml/lib/sx_vm.ml
@@ -642,7 +642,9 @@ and run vm =
          (* Read upvalue descriptors from bytecode *)
          let uv_count = match code_val with
            | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-                | Some (Number n) -> int_of_float n | _ -> 0)
+                | Some (Integer n) -> n
                | Some (Number n) -> int_of_float n
                | _ -> 0)
            | _ -> 0
          in
          let upvalues = Array.init uv_count (fun _ ->
@@ -1307,7 +1309,9 @@ let trace_run src globals =
            let code_val2 = frame.closure.vm_code.vc_constants.(idx) in
            let uv_count = match code_val2 with
              | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-                  | Some (Number n) -> int_of_float n | _ -> 0)
+                  | Some (Integer n) -> n
                  | Some (Number n) -> int_of_float n
                  | _ -> 0)
              | _ -> 0 in
            let upvalues = Array.init uv_count (fun _ ->
              let is_local = read_u8 frame in
@@ -1428,7 +1432,9 @@ let disassemble (code : vm_code) =
        if op = 51 && idx < Array.length consts then begin
          let uv_count = match consts.(idx) with
            | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-                | Some (Number n) -> int_of_float n | _ -> 0)
+                | Some (Integer n) -> n
                | Some (Number n) -> int_of_float n
                | _ -> 0)
            | _ -> 0 in
          ip := !ip + uv_count * 2
        end
--- a/hosts/ocaml/lib/sx_vm_ref.ml
+++ b/hosts/ocaml/lib/sx_vm_ref.ml
@@ -270,7 +270,9 @@ let vm_create_closure vm_val frame_val code_val =
  let f = unwrap_frame frame_val in
  let uv_count = match code_val with
    | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-        | Some (Number n) -> int_of_float n | _ -> 0)
+        | Some (Integer n) -> n
        | Some (Number n) -> int_of_float n
        | _ -> 0)
    | _ -> 0
  in
  let upvalues = Array.init uv_count (fun _ ->
--- a/hosts/ocaml/sx_vm_ref.ml
+++ b/hosts/ocaml/sx_vm_ref.ml
@@ -265,7 +265,9 @@ let vm_create_closure vm_val frame_val code_val =
  let f = unwrap_frame frame_val in
  let uv_count = match code_val with
    | Dict d -> (match Hashtbl.find_opt d "upvalue-count" with
-        | Some (Number n) -> int_of_float n | _ -> 0)
+        | Some (Integer n) -> n
        | Some (Number n) -> int_of_float n
        | _ -> 0)
    | _ -> 0
  in
  let upvalues = Array.init uv_count (fun _ ->
--- a/lib/apl/conformance.sh
+++ b/lib/apl/conformance.sh
@@ -0,0 +1,116 @@
 #!/usr/bin/env bash
 # lib/apl/conformance.sh — run APL test suites, emit scoreboard.json + scoreboard.md.
 set -uo pipefail
 cd "$(git rev-parse --show-toplevel)"
 SX_SERVER="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
 if [ ! -x "$SX_SERVER" ]; then
  SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
 fi
 if [ ! -x "$SX_SERVER" ]; then
  echo "ERROR: sx_server.exe not found." >&2
  exit 1
 fi
 SUITES=(structural operators dfn tradfn valence programs system idioms eval-ops pipeline)
 OUT_JSON="lib/apl/scoreboard.json"
 OUT_MD="lib/apl/scoreboard.md"
 run_suite() {
  local suite=$1
  local file="lib/apl/tests/${suite}.sx"
  local TMP
  TMP=$(mktemp)
  cat > "$TMP" << EPOCHS
 (epoch 1)
 (load "spec/stdlib.sx")
 (load "lib/r7rs.sx")
 (load "lib/apl/runtime.sx")
 (load "lib/apl/tokenizer.sx")
 (load "lib/apl/parser.sx")
 (load "lib/apl/transpile.sx")
 (epoch 2)
 (eval "(define apl-test-pass 0)")
 (eval "(define apl-test-fail 0)")
 (eval "(define apl-test (fn (name got expected) (if (= got expected) (set! apl-test-pass (+ apl-test-pass 1)) (set! apl-test-fail (+ apl-test-fail 1)))))")
 (epoch 3)
 (load "${file}")
 (epoch 4)
 (eval "(list apl-test-pass apl-test-fail)")
 EPOCHS
  local OUTPUT
  OUTPUT=$(timeout 300 "$SX_SERVER" < "$TMP" 2>/dev/null)
  rm -f "$TMP"
  local LINE
  LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 4 / {getline; print; exit}')
  if [ -z "$LINE" ]; then
    LINE=$(echo "$OUTPUT" | grep -E '^\(ok 4 \([0-9]+ [0-9]+\)\)' | tail -1 \
            | sed -E 's/^\(ok 4 //; s/\)$//')
  fi
  local P F
  P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
  F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
  P=${P:-0}
  F=${F:-0}
  echo "${P} ${F}"
 }
 declare -A SUITE_PASS
 declare -A SUITE_FAIL
 TOTAL_PASS=0
 TOTAL_FAIL=0
 echo "Running APL conformance suite..." >&2
 for s in "${SUITES[@]}"; do
  read -r p f < <(run_suite "$s")
  SUITE_PASS[$s]=$p
  SUITE_FAIL[$s]=$f
  TOTAL_PASS=$((TOTAL_PASS + p))
  TOTAL_FAIL=$((TOTAL_FAIL + f))
  printf "  %-12s %d/%d\n" "$s" "$p" "$((p+f))" >&2
 done
 # scoreboard.json
 {
  printf '{\n'
  printf '  "suites": {\n'
  first=1
  for s in "${SUITES[@]}"; do
    if [ $first -eq 0 ]; then printf ',\n'; fi
    printf '    "%s": {"pass": %d, "fail": %d}' "$s" "${SUITE_PASS[$s]}" "${SUITE_FAIL[$s]}"
    first=0
  done
  printf '\n  },\n'
  printf '  "total_pass": %d,\n' "$TOTAL_PASS"
  printf '  "total_fail": %d,\n' "$TOTAL_FAIL"
  printf '  "total": %d\n' "$((TOTAL_PASS + TOTAL_FAIL))"
  printf '}\n'
 } > "$OUT_JSON"
 # scoreboard.md
 {
  printf '# APL Conformance Scoreboard\n\n'
  printf '_Generated by `lib/apl/conformance.sh`_\n\n'
  printf '| Suite | Pass | Fail | Total |\n'
  printf '|-------|-----:|-----:|------:|\n'
  for s in "${SUITES[@]}"; do
    p=${SUITE_PASS[$s]}
    f=${SUITE_FAIL[$s]}
    printf '| %s | %d | %d | %d |\n' "$s" "$p" "$f" "$((p+f))"
  done
  printf '| **Total** | **%d** | **%d** | **%d** |\n' "$TOTAL_PASS" "$TOTAL_FAIL" "$((TOTAL_PASS + TOTAL_FAIL))"
  printf '\n'
  printf '## Notes\n\n'
  printf '%s\n' '- Suites use the standard `apl-test name got expected` framework loaded against `lib/apl/runtime.sx` + `lib/apl/transpile.sx`.'
  printf '%s\n' '- `lib/apl/tests/parse.sx` and `lib/apl/tests/scalar.sx` use their own self-contained frameworks and are excluded from this scoreboard.'
 } > "$OUT_MD"
 echo "Wrote $OUT_JSON and $OUT_MD" >&2
 echo "Total: $TOTAL_PASS pass, $TOTAL_FAIL fail" >&2
 [ "$TOTAL_FAIL" -eq 0 ]
--- a/lib/apl/parser.sx
+++ b/lib/apl/parser.sx
@@ -0,0 +1,674 @@
 ; APL Parser — right-to-left expression parser
 ;
 ; Takes a token list (output of apl-tokenize) and produces an AST.
 ; APL evaluates right-to-left with no precedence among functions.
 ; Operators bind to the function immediately to their left in the source.
 ;
 ; AST node types:
 ;   (:num n)                     number literal
 ;   (:str s)                     string literal
 ;   (:vec n1 n2 ...)             strand (juxtaposed literals)
 ;   (:name "x")                  name reference / alpha / omega
 ;   (:assign "x" expr)           assignment  x←expr
 ;   (:monad fn arg)              monadic function call
 ;   (:dyad fn left right)        dyadic function call
 ;   (:derived-fn op fn)          derived function: f/ f¨ f⍨
 ;   (:derived-fn2 "." f g)       inner product: f.g
 ;   (:outer "∘." fn)             outer product: ∘.f
 ;   (:fn-glyph "⍳")             function reference
 ;   (:fn-name "foo")             named-function reference (dfn variable)
 ;   (:dfn stmt...)               {⍺+⍵} anonymous function
 ;   (:guard cond expr)           cond:expr guard inside dfn
 ;   (:program stmt...)           multi-statement sequence
 ; ============================================================
 ; Glyph classification sets
 ; ============================================================
 (define
  apl-parse-op-glyphs
  (list "/" "⌿" "\\" "⍀" "¨" "⍨" "∘" "." "⍣" "⍤" "⍥" "@"))
 (define
  apl-parse-fn-glyphs
  (list
    "+"
    "-"
    "×"
    "÷"
    "*"
    "⍟"
    "⌈"
    "⌊"
    "|"
    "!"
    "?"
    "○"
    "~"
    "<"
    "≤"
    "="
    "≥"
    ">"
    "≠"
    "≢"
    "≡"
    "∊"
    "∧"
    "∨"
    "⍱"
    "⍲"
    ","
    "⍪"
    "⍴"
    "⌽"
    "⊖"
    "⍉"
    "↑"
    "↓"
    "⊂"
    "⊃"
    "⊆"
    "∪"
    "∩"
    "⍳"
    "⍸"
    "⌷"
    "⍋"
    "⍒"
    "⊥"
    "⊤"
    "⊣"
    "⊢"
    "⍎"
    "⍕"))
 (define apl-quad-fn-names (list "⎕FMT" "⎕←"))
 (define apl-known-fn-names (list))
 ; ============================================================
 ; Token accessors
 ; ============================================================
 (define
  apl-collect-fn-bindings
  (fn
    (stmt-groups)
    (set! apl-known-fn-names (list))
    (for-each
      (fn
        (toks)
        (when
          (and
            (>= (len toks) 3)
            (= (tok-type (nth toks 0)) :name)
            (= (tok-type (nth toks 1)) :assign)
            (= (tok-type (nth toks 2)) :lbrace))
          (set!
            apl-known-fn-names
            (cons (tok-val (nth toks 0)) apl-known-fn-names))))
      stmt-groups)))
 (define
  apl-parse-op-glyph?
  (fn (v) (some (fn (g) (= g v)) apl-parse-op-glyphs)))
 (define
  apl-parse-fn-glyph?
  (fn (v) (some (fn (g) (= g v)) apl-parse-fn-glyphs)))
 (define tok-type (fn (tok) (get tok :type)))
 ; ============================================================
 ; Collect trailing operators starting at index i
 ; Returns {:ops (op ...) :end new-i}
 ; ============================================================
 (define tok-val (fn (tok) (get tok :value)))
 (define
  is-op-tok?
  (fn
    (tok)
    (and (= (tok-type tok) :glyph) (apl-parse-op-glyph? (tok-val tok)))))
 ; ============================================================
 ; Build a derived-fn node by chaining operators left-to-right
 ; (+/¨  →  (:derived-fn "¨" (:derived-fn "/" (:fn-glyph "+"))))
 ; ============================================================
 (define
  is-fn-tok?
  (fn
    (tok)
    (or
      (and (= (tok-type tok) :glyph) (apl-parse-fn-glyph? (tok-val tok)))
      (and
        (= (tok-type tok) :name)
        (or
          (some (fn (q) (= q (tok-val tok))) apl-quad-fn-names)
          (some (fn (q) (= q (tok-val tok))) apl-known-fn-names))))))
 ; ============================================================
 ; Find matching close bracket/paren/brace
 ; Returns the index of the matching close token
 ; ============================================================
 (define collect-ops (fn (tokens i) (collect-ops-loop tokens i (list))))
 (define
  collect-ops-loop
  (fn
    (tokens i acc)
    (if
      (>= i (len tokens))
      {:end i :ops acc}
      (let
        ((tok (nth tokens i)))
        (if
          (is-op-tok? tok)
          (collect-ops-loop tokens (+ i 1) (append acc (tok-val tok)))
          {:end i :ops acc})))))
 ; ============================================================
 ; Segment collection: scan tokens left-to-right, building
 ; a list of {:kind "val"/"fn" :node ast} segments.
 ; Operators following function glyphs are merged into
 ; derived-fn nodes during this pass.
 ; ============================================================
 (define
  build-derived-fn
  (fn
    (fn-node ops)
    (if
      (= (len ops) 0)
      fn-node
      (build-derived-fn (list :derived-fn (first ops) fn-node) (rest ops)))))
 (define
  find-matching-close
  (fn
    (tokens start open-type close-type)
    (find-matching-close-loop tokens start open-type close-type 1)))
 ; ============================================================
 ; Build tree from segment list
 ;
 ; The segments are in left-to-right order.
 ; APL evaluates right-to-left, so the LEFTMOST function is
 ; the outermost (last-evaluated) node.
 ;
 ; Patterns:
 ;   [val]              → val node
 ;   [fn val ...]       → (:monad fn (build-tree rest))
 ;   [val fn val ...]   → (:dyad fn val (build-tree rest))
 ;   [val val ...]      → (:vec val1 val2 ...) — strand
 ; ============================================================
 ; Find the index of the first function segment (returns -1 if none)
 (define
  find-matching-close-loop
  (fn
    (tokens i open-type close-type depth)
    (if
      (>= i (len tokens))
      (len tokens)
      (let
        ((tt (tok-type (nth tokens i))))
        (cond
          ((= tt open-type)
            (find-matching-close-loop
              tokens
              (+ i 1)
              open-type
              close-type
              (+ depth 1)))
          ((= tt close-type)
            (if
              (= depth 1)
              i
              (find-matching-close-loop
                tokens
                (+ i 1)
                open-type
                close-type
                (- depth 1))))
          (true
            (find-matching-close-loop
              tokens
              (+ i 1)
              open-type
              close-type
              depth)))))))
 (define
  collect-segments
  (fn (tokens) (collect-segments-loop tokens 0 (list))))
 ; Build an array node from 0..n value segments
 ; If n=1 → return that segment's node
 ; If n>1 → return (:vec node1 node2 ...)
 (define
  collect-segments-loop
  (fn
    (tokens i acc)
    (if
      (>= i (len tokens))
      acc
      (let
        ((tok (nth tokens i)) (n (len tokens)))
        (let
          ((tt (tok-type tok)) (tv (tok-val tok)))
          (cond
            ((or (= tt :diamond) (= tt :newline) (= tt :semi))
              (collect-segments-loop tokens (+ i 1) acc))
            ((= tt :num)
              (collect-segments-loop tokens (+ i 1) (append acc {:kind "val" :node (list :num tv)})))
            ((= tt :str)
              (collect-segments-loop tokens (+ i 1) (append acc {:kind "val" :node (list :str tv)})))
            ((= tt :name)
              (cond
                ((some (fn (q) (= q tv)) apl-quad-fn-names)
                  (let
                    ((op-result (collect-ops tokens (+ i 1))))
                    (let
                      ((ops (get op-result :ops))
                        (ni (get op-result :end)))
                      (let
                        ((fn-node (build-derived-fn (list :fn-glyph tv) ops)))
                        (collect-segments-loop
                          tokens
                          ni
                          (append acc {:kind "fn" :node fn-node}))))))
                ((some (fn (q) (= q tv)) apl-known-fn-names)
                  (let
                    ((op-result (collect-ops tokens (+ i 1))))
                    (let
                      ((ops (get op-result :ops))
                        (ni (get op-result :end)))
                      (let
                        ((fn-node (build-derived-fn (list :fn-name tv) ops)))
                        (collect-segments-loop
                          tokens
                          ni
                          (append acc {:kind "fn" :node fn-node}))))))
                (else
                  (let
                    ((br (maybe-bracket (list :name tv) tokens (+ i 1))))
                    (collect-segments-loop
                      tokens
                      (nth br 1)
                      (append acc {:kind "val" :node (nth br 0)}))))))
            ((= tt :lparen)
              (let
                ((end (find-matching-close tokens (+ i 1) :lparen :rparen)))
                (let
                  ((inner-tokens (slice tokens (+ i 1) end))
                    (after (+ end 1)))
                  (let
                    ((inner-segs (collect-segments inner-tokens)))
                    (if
                      (and
                        (>= (len inner-segs) 2)
                        (every? (fn (s) (= (get s :kind) "fn")) inner-segs))
                      (let
                        ((train-node (cons :train (map (fn (s) (get s :node)) inner-segs))))
                        (collect-segments-loop
                          tokens
                          after
                          (append acc {:kind "fn" :node train-node})))
                      (let
                        ((br (maybe-bracket (parse-apl-expr inner-tokens) tokens after)))
                        (collect-segments-loop
                          tokens
                          (nth br 1)
                          (append acc {:kind "val" :node (nth br 0)}))))))))
            ((= tt :lbrace)
              (let
                ((end (find-matching-close tokens (+ i 1) :lbrace :rbrace)))
                (let
                  ((inner-tokens (slice tokens (+ i 1) end))
                    (after (+ end 1)))
                  (collect-segments-loop tokens after (append acc {:kind "fn" :node (parse-dfn inner-tokens)})))))
            ((= tt :glyph)
              (cond
                ((or (= tv "⍺") (= tv "⍵"))
                  (collect-segments-loop
                    tokens
                    (+ i 1)
                    (append acc {:kind "val" :node (list :name tv)})))
                ((= tv "∇")
                  (collect-segments-loop
                    tokens
                    (+ i 1)
                    (append acc {:kind "fn" :node (list :fn-glyph "∇")})))
                ((and (= tv "∘") (< (+ i 1) n) (= (tok-val (nth tokens (+ i 1))) "."))
                  (if
                    (and (< (+ i 2) n) (is-fn-tok? (nth tokens (+ i 2))))
                    (let
                      ((fn-tv (tok-val (nth tokens (+ i 2)))))
                      (let
                        ((op-result (collect-ops tokens (+ i 3))))
                        (let
                          ((ops (get op-result :ops))
                            (ni (get op-result :end)))
                          (let
                            ((fn-node (build-derived-fn (list :fn-glyph fn-tv) ops)))
                            (collect-segments-loop
                              tokens
                              ni
                              (append acc {:kind "fn" :node (list :outer "∘." fn-node)}))))))
                    (collect-segments-loop tokens (+ i 1) acc)))
                ((apl-parse-fn-glyph? tv)
                  (let
                    ((op-result (collect-ops tokens (+ i 1))))
                    (let
                      ((ops (get op-result :ops))
                        (ni (get op-result :end)))
                      (if
                        (and
                          (= (len ops) 1)
                          (= (first ops) ".")
                          (< ni n)
                          (is-fn-tok? (nth tokens ni)))
                        (let
                          ((g-tv (tok-val (nth tokens ni))))
                          (let
                            ((op-result2 (collect-ops tokens (+ ni 1))))
                            (let
                              ((ops2 (get op-result2 :ops))
                                (ni2 (get op-result2 :end)))
                              (let
                                ((g-node (build-derived-fn (list :fn-glyph g-tv) ops2)))
                                (collect-segments-loop
                                  tokens
                                  ni2
                                  (append acc {:kind "fn" :node (list :derived-fn2 "." (list :fn-glyph tv) g-node)}))))))
                        (let
                          ((fn-node (build-derived-fn (list :fn-glyph tv) ops)))
                          (collect-segments-loop
                            tokens
                            ni
                            (append acc {:kind "fn" :node fn-node})))))))
                ((apl-parse-op-glyph? tv)
                  (collect-segments-loop tokens (+ i 1) acc))
                (true (collect-segments-loop tokens (+ i 1) acc))))
            (true (collect-segments-loop tokens (+ i 1) acc))))))))
 (define find-first-fn (fn (segs) (find-first-fn-loop segs 0)))
 ; ============================================================
 ; Split token list on statement separators (diamond / newline)
 ; Only splits at depth 0 (ignores separators inside { } or ( ) )
 ; ============================================================
 (define
  find-first-fn-loop
  (fn
    (segs i)
    (if
      (>= i (len segs))
      -1
      (if
        (= (get (nth segs i) :kind) "fn")
        i
        (find-first-fn-loop segs (+ i 1))))))
 (define
  segs-to-array
  (fn
    (segs)
    (if
      (= (len segs) 1)
      (get (first segs) :node)
      (cons :vec (map (fn (s) (get s :node)) segs)))))
 ; ============================================================
 ; Parse a dfn body (tokens between { and })
 ; Handles guard expressions: cond : expr
 ; ============================================================
 (define
  build-tree
  (fn
    (segs)
    (cond
      ((= (len segs) 0) nil)
      ((= (len segs) 1) (get (first segs) :node))
      ((every? (fn (s) (= (get s :kind) "val")) segs)
        (segs-to-array segs))
      (true
        (let
          ((fn-idx (find-first-fn segs)))
          (cond
            ((= fn-idx -1) (segs-to-array segs))
            ((= fn-idx 0)
              (list
                :monad (get (first segs) :node)
                (build-tree (rest segs))))
            (true
              (let
                ((left-segs (slice segs 0 fn-idx))
                  (fn-seg (nth segs fn-idx))
                  (right-segs (slice segs (+ fn-idx 1))))
                (list
                  :dyad (get fn-seg :node)
                  (segs-to-array left-segs)
                  (build-tree right-segs))))))))))
 (define
  split-statements
  (fn (tokens) (split-statements-loop tokens (list) (list) 0)))
 (define
  split-statements-loop
  (fn
    (tokens current-stmt acc depth)
    (if
      (= (len tokens) 0)
      (if (> (len current-stmt) 0) (append acc (list current-stmt)) acc)
      (let
        ((tok (first tokens))
          (rest-toks (rest tokens))
          (tt (tok-type (first tokens))))
        (cond
          ((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
            (split-statements-loop
              rest-toks
              (append current-stmt tok)
              acc
              (+ depth 1)))
          ((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
            (split-statements-loop
              rest-toks
              (append current-stmt tok)
              acc
              (- depth 1)))
          ((and (> depth 0) (or (= tt :diamond) (= tt :newline)))
            (split-statements-loop
              rest-toks
              (append current-stmt tok)
              acc
              depth))
          ((and (= depth 0) (or (= tt :diamond) (= tt :newline)))
            (if
              (> (len current-stmt) 0)
              (split-statements-loop
                rest-toks
                (list)
                (append acc (list current-stmt))
                depth)
              (split-statements-loop rest-toks (list) acc depth)))
          (true
            (split-statements-loop
              rest-toks
              (append current-stmt tok)
              acc
              depth)))))))
 (define
  parse-dfn
  (fn
    (tokens)
    (let
      ((stmt-groups (split-statements tokens)))
      (let ((stmts (map parse-dfn-stmt stmt-groups))) (cons :dfn stmts)))))
 ; ============================================================
 ; Parse a single statement (assignment or expression)
 ; ============================================================
 (define
  parse-dfn-stmt
  (fn
    (tokens)
    (let
      ((colon-idx (find-top-level-colon tokens 0)))
      (if
        (>= colon-idx 0)
        (let
          ((cond-tokens (slice tokens 0 colon-idx))
            (body-tokens (slice tokens (+ colon-idx 1))))
          (list
            :guard (parse-apl-expr cond-tokens)
            (parse-apl-expr body-tokens)))
        (parse-stmt tokens)))))
 ; ============================================================
 ; Parse an expression from a flat token list
 ; ============================================================
 (define
  find-top-level-colon
  (fn (tokens i) (find-top-level-colon-loop tokens i 0)))
 ; ============================================================
 ; Main entry point
 ; parse-apl: string → AST
 ; ============================================================
 (define
  find-top-level-colon-loop
  (fn
    (tokens i depth)
    (if
      (>= i (len tokens))
      -1
      (let
        ((tok (nth tokens i)) (tt (tok-type (nth tokens i))))
        (cond
          ((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
            (find-top-level-colon-loop tokens (+ i 1) (+ depth 1)))
          ((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
            (find-top-level-colon-loop tokens (+ i 1) (- depth 1)))
          ((and (= tt :colon) (= depth 0)) i)
          (true (find-top-level-colon-loop tokens (+ i 1) depth)))))))
 (define
  parse-stmt
  (fn
    (tokens)
    (if
      (and
        (>= (len tokens) 2)
        (= (tok-type (nth tokens 0)) :name)
        (= (tok-type (nth tokens 1)) :assign))
      (list
        :assign (tok-val (nth tokens 0))
        (parse-apl-expr (slice tokens 2)))
      (parse-apl-expr tokens))))
 (define
  parse-apl-expr
  (fn
    (tokens)
    (let
      ((segs (collect-segments tokens)))
      (if (= (len segs) 0) nil (build-tree segs)))))
 (define
  parse-apl
  (fn
    (src)
    (let
      ((tokens (apl-tokenize src)))
      (let
        ((stmt-groups (split-statements tokens)))
        (begin
          (apl-collect-fn-bindings stmt-groups)
          (if
            (= (len stmt-groups) 0)
            nil
            (if
              (= (len stmt-groups) 1)
              (parse-stmt (first stmt-groups))
              (cons :program (map parse-stmt stmt-groups)))))))))
 (define
  split-bracket-loop
  (fn
    (tokens current acc depth)
    (if
      (= (len tokens) 0)
      (append acc (list current))
      (let
        ((tok (first tokens)) (more (rest tokens)))
        (let
          ((tt (tok-type tok)))
          (cond
            ((or (= tt :lparen) (= tt :lbrace) (= tt :lbracket))
              (split-bracket-loop
                more
                (append current (list tok))
                acc
                (+ depth 1)))
            ((or (= tt :rparen) (= tt :rbrace) (= tt :rbracket))
              (split-bracket-loop
                more
                (append current (list tok))
                acc
                (- depth 1)))
            ((and (= tt :semi) (= depth 0))
              (split-bracket-loop
                more
                (list)
                (append acc (list current))
                depth))
            (else
              (split-bracket-loop more (append current (list tok)) acc depth))))))))
 (define
  split-bracket-content
  (fn (tokens) (split-bracket-loop tokens (list) (list) 0)))
 (define
  maybe-bracket
  (fn
    (val-node tokens after)
    (if
      (and
        (< after (len tokens))
        (= (tok-type (nth tokens after)) :lbracket))
      (let
        ((end (find-matching-close tokens (+ after 1) :lbracket :rbracket)))
        (let
          ((inner-tokens (slice tokens (+ after 1) end))
            (next-after (+ end 1)))
          (let
            ((sections (split-bracket-content inner-tokens)))
            (if
              (= (len sections) 1)
              (let
                ((idx-expr (parse-apl-expr inner-tokens)))
                (let
                  ((indexed (list :dyad (list :fn-glyph "⌷") idx-expr val-node)))
                  (maybe-bracket indexed tokens next-after)))
              (let
                ((axis-exprs (map (fn (toks) (if (= (len toks) 0) :all (parse-apl-expr toks))) sections)))
                (let
                  ((indexed (cons :bracket (cons val-node axis-exprs))))
                  (maybe-bracket indexed tokens next-after)))))))
      (list val-node after))))
--- a/lib/apl/runtime.sx
+++ b/lib/apl/runtime.sx
--- a/lib/apl/scoreboard.json
+++ b/lib/apl/scoreboard.json
@@ -0,0 +1,17 @@
 {
  "suites": {
    "structural": {"pass": 94, "fail": 0},
    "operators": {"pass": 117, "fail": 0},
    "dfn": {"pass": 24, "fail": 0},
    "tradfn": {"pass": 25, "fail": 0},
    "valence": {"pass": 14, "fail": 0},
    "programs": {"pass": 45, "fail": 0},
    "system": {"pass": 13, "fail": 0},
    "idioms": {"pass": 64, "fail": 0},
    "eval-ops": {"pass": 14, "fail": 0},
    "pipeline": {"pass": 40, "fail": 0}
  },
  "total_pass": 450,
  "total_fail": 0,
  "total": 450
 }
--- a/lib/apl/scoreboard.md
+++ b/lib/apl/scoreboard.md
@@ -0,0 +1,22 @@
 # APL Conformance Scoreboard
 _Generated by `lib/apl/conformance.sh`_
 | Suite | Pass | Fail | Total |
 |-------|-----:|-----:|------:|
 | structural | 94 | 0 | 94 |
 | operators | 117 | 0 | 117 |
 | dfn | 24 | 0 | 24 |
 | tradfn | 25 | 0 | 25 |
 | valence | 14 | 0 | 14 |
 | programs | 45 | 0 | 45 |
 | system | 13 | 0 | 13 |
 | idioms | 64 | 0 | 64 |
 | eval-ops | 14 | 0 | 14 |
 | pipeline | 40 | 0 | 40 |
 | **Total** | **450** | **0** | **450** |
 ## Notes
 - Suites use the standard `apl-test name got expected` framework loaded against `lib/apl/runtime.sx` + `lib/apl/transpile.sx`.
 - `lib/apl/tests/parse.sx` and `lib/apl/tests/scalar.sx` use their own self-contained frameworks and are excluded from this scoreboard.
--- a/lib/apl/test.sh
+++ b/lib/apl/test.sh
@@ -4,9 +4,9 @@
 set -uo pipefail
 cd "$(git rev-parse --show-toplevel)"
-SX_SERVER="${SX_SERVER:-hosts/ocaml/_build/default/bin/sx_server.exe}"
+SX_SERVER="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
 if [ ! -x "$SX_SERVER" ]; then
-  SX_SERVER="/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe"
+  SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
 fi
 if [ ! -x "$SX_SERVER" ]; then
  echo "ERROR: sx_server.exe not found."
@@ -18,19 +18,38 @@ TMPFILE=$(mktemp); trap "rm -f $TMPFILE" EXIT
 cat > "$TMPFILE" << 'EPOCHS'
 (epoch 1)
 (load "spec/stdlib.sx")
 (load "lib/r7rs.sx")
 (load "lib/apl/runtime.sx")
 (load "lib/apl/tokenizer.sx")
 (load "lib/apl/parser.sx")
 (load "lib/apl/transpile.sx")
 (epoch 2)
-(load "lib/apl/tests/runtime.sx")
+(eval "(define apl-test-pass 0)")
 (eval "(define apl-test-fail 0)")
 (eval "(define apl-test-fails (list))")
 (eval "(define apl-test (fn (name got expected) (if (= got expected) (set! apl-test-pass (+ apl-test-pass 1)) (begin (set! apl-test-fail (+ apl-test-fail 1)) (set! apl-test-fails (append apl-test-fails (list {:name name :got got :expected expected})))))))")
 (epoch 3)
 (load "lib/apl/tests/structural.sx")
 (load "lib/apl/tests/operators.sx")
 (load "lib/apl/tests/dfn.sx")
 (load "lib/apl/tests/tradfn.sx")
 (load "lib/apl/tests/valence.sx")
 (load "lib/apl/tests/programs.sx")
 (load "lib/apl/tests/system.sx")
 (load "lib/apl/tests/idioms.sx")
 (load "lib/apl/tests/eval-ops.sx")
 (load "lib/apl/tests/pipeline.sx")
 (load "lib/apl/tests/programs-e2e.sx")
 (epoch 4)
 (eval "(list apl-test-pass apl-test-fail)")
 EPOCHS
-OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
+OUTPUT=$(timeout 300 "$SX_SERVER" < "$TMPFILE" 2>/dev/null)
-LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 3 / {getline; print; exit}')
+LINE=$(echo "$OUTPUT" | awk '/^\(ok-len 4 / {getline; print; exit}')
 if [ -z "$LINE" ]; then
-  LINE=$(echo "$OUTPUT" | grep -E '^\(ok 3 \([0-9]+ [0-9]+\)\)' | tail -1 \
+  LINE=$(echo "$OUTPUT" | grep -E '^\(ok 4 \([0-9]+ [0-9]+\)\)' | tail -1 \
-          | sed -E 's/^\(ok 3 //; s/\)$//')
+          | sed -E 's/^\(ok 4 //; s/\)$//')
 fi
 if [ -z "$LINE" ]; then
  echo "ERROR: could not extract summary"
--- a/lib/apl/tests/dfn.sx
+++ b/lib/apl/tests/dfn.sx
@@ -0,0 +1,227 @@
 ; Tests for apl-eval-ast and apl-call-dfn (manual AST construction).
 (define rv (fn (arr) (get arr :ravel)))
 (define sh (fn (arr) (get arr :shape)))
 (define mknum (fn (n) (list :num n)))
 (define mkname (fn (s) (list :name s)))
 (define mkfg (fn (g) (list :fn-glyph g)))
 (define mkmon (fn (g a) (list :monad (mkfg g) a)))
 (define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
 (define mkdfn1 (fn (body) (list :dfn body)))
 (define mkprog (fn (stmts) (cons :program stmts)))
 (define mkasg (fn (mkname expr) (list :assign mkname expr)))
 (define mkgrd (fn (c e) (list :guard c e)))
 (define mkdfn (fn (stmts) (cons :dfn stmts)))
 (apl-test
  "eval :num literal"
  (rv (apl-eval-ast (mknum 42) {}))
  (list 42))
 (apl-test
  "eval :num literal shape"
  (sh (apl-eval-ast (mknum 42) {}))
  (list))
 (apl-test
  "eval :dyad +"
  (rv (apl-eval-ast (mkdyd "+" (mknum 2) (mknum 3)) {}))
  (list 5))
 (apl-test
  "eval :dyad ×"
  (rv (apl-eval-ast (mkdyd "×" (mknum 6) (mknum 7)) {}))
  (list 42))
 (apl-test
  "eval :monad - (negate)"
  (rv (apl-eval-ast (mkmon "-" (mknum 7)) {}))
  (list -7))
 (apl-test
  "eval :monad ⌊ (floor)"
  (rv (apl-eval-ast (mkmon "⌊" (mknum 3)) {}))
  (list 3))
 (apl-test
  "eval :name ⍵ from env"
  (rv (apl-eval-ast (mkname "⍵") {:omega (apl-scalar 99) :alpha nil}))
  (list 99))
 (apl-test
  "eval :name ⍺ from env"
  (rv (apl-eval-ast (mkname "⍺") {:omega nil :alpha (apl-scalar 7)}))
  (list 7))
 (apl-test
  "dfn {⍵+1} called monadic"
  (rv
    (apl-call-dfn-m
      (mkdfn1 (mkdyd "+" (mkname "⍵") (mknum 1)))
      (apl-scalar 5)))
  (list 6))
 (apl-test
  "dfn {⍺+⍵} called dyadic"
  (rv
    (apl-call-dfn
      (mkdfn1 (mkdyd "+" (mkname "⍺") (mkname "⍵")))
      (apl-scalar 4)
      (apl-scalar 9)))
  (list 13))
 (apl-test
  "dfn {⍺×⍵} dyadic on vectors"
  (rv
    (apl-call-dfn
      (mkdfn1 (mkdyd "×" (mkname "⍺") (mkname "⍵")))
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 10 20 30))))
  (list 10 40 90))
 (apl-test
  "dfn {-⍵} monadic negate"
  (rv
    (apl-call-dfn-m
      (mkdfn1 (mkmon "-" (mkname "⍵")))
      (make-array (list 3) (list 1 2 3))))
  (list -1 -2 -3))
 (apl-test
  "dfn {⍺-⍵} dyadic subtract scalar"
  (rv
    (apl-call-dfn
      (mkdfn1 (mkdyd "-" (mkname "⍺") (mkname "⍵")))
      (apl-scalar 10)
      (apl-scalar 3)))
  (list 7))
 (apl-test
  "dfn {⌈⍺,⍵} not used (just verify : missing) — ceiling of right"
  (rv
    (apl-call-dfn-m (mkdfn1 (mkmon "⌈" (mkname "⍵"))) (apl-scalar 5)))
  (list 5))
 (apl-test
  "dfn nested dyad"
  (rv
    (apl-call-dfn
      (mkdfn1
        (mkdyd "+" (mkname "⍺") (mkdyd "×" (mkname "⍵") (mknum 2))))
      (apl-scalar 1)
      (apl-scalar 3)))
  (list 7))
 (apl-test
  "dfn local assign x←⍵+1; ⍺×x"
  (rv
    (apl-call-dfn
      (mkdfn
        (list
          (mkasg "x" (mkdyd "+" (mkname "⍵") (mknum 1)))
          (mkdyd "×" (mkname "⍺") (mkname "x"))))
      (apl-scalar 3)
      (apl-scalar 4)))
  (list 15))
 (apl-test
  "dfn guard: 0=⍵:99; ⍵×2 (true branch)"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 99))
          (mkdyd "×" (mkname "⍵") (mknum 2))))
      (apl-scalar 0)))
  (list 99))
 (apl-test
  "dfn guard: 0=⍵:99; ⍵×2 (false branch)"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 99))
          (mkdyd "×" (mkname "⍵") (mknum 2))))
      (apl-scalar 5)))
  (list 10))
 (apl-test
  "dfn default ⍺←10 used (monadic call)"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkasg "⍺" (mknum 10))
          (mkdyd "+" (mkname "⍺") (mkname "⍵"))))
      (apl-scalar 5)))
  (list 15))
 (apl-test
  "dfn default ⍺←10 ignored when ⍺ given (dyadic call)"
  (rv
    (apl-call-dfn
      (mkdfn
        (list
          (mkasg "⍺" (mknum 10))
          (mkdyd "+" (mkname "⍺") (mkname "⍵"))))
      (apl-scalar 100)
      (apl-scalar 5)))
  (list 105))
 (apl-test
  "dfn ∇ recursion: factorial via guard"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 1))
          (mkdyd
            "×"
            (mkname "⍵")
            (mkmon "∇" (mkdyd "-" (mkname "⍵") (mknum 1))))))
      (apl-scalar 5)))
  (list 120))
 (apl-test
  "dfn ∇ recursion: 3 → 6 (factorial)"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkgrd (mkdyd "=" (mknum 0) (mkname "⍵")) (mknum 1))
          (mkdyd
            "×"
            (mkname "⍵")
            (mkmon "∇" (mkdyd "-" (mkname "⍵") (mknum 1))))))
      (apl-scalar 3)))
  (list 6))
 (apl-test
  "dfn local: x←⍵+10; y←x×2; y"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkasg "x" (mkdyd "+" (mkname "⍵") (mknum 10)))
          (mkasg "y" (mkdyd "×" (mkname "x") (mknum 2)))
          (mkname "y")))
      (apl-scalar 5)))
  (list 30))
 (apl-test
  "dfn first guard wins: many guards"
  (rv
    (apl-call-dfn-m
      (mkdfn
        (list
          (mkgrd (mkdyd "=" (mknum 1) (mkname "⍵")) (mknum 100))
          (mkgrd (mkdyd "=" (mknum 2) (mkname "⍵")) (mknum 200))
          (mkgrd (mkdyd "=" (mknum 3) (mkname "⍵")) (mknum 300))
          (mknum 0)))
      (apl-scalar 2)))
  (list 200))
--- a/lib/apl/tests/eval-ops.sx
+++ b/lib/apl/tests/eval-ops.sx
@@ -0,0 +1,147 @@
 ; Tests for operator handling in apl-eval-ast (Phase 7).
 ; Manual AST construction; verifies :derived-fn / :outer / :derived-fn2
 ; route through apl-resolve-monadic / apl-resolve-dyadic correctly.
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 (define mknum (fn (n) (list :num n)))
 (define mkfg (fn (g) (list :fn-glyph g)))
 (define mkmon (fn (g a) (list :monad g a)))
 (define mkdyd (fn (g l r) (list :dyad g l r)))
 (define mkder (fn (op f) (list :derived-fn op f)))
 (define mkdr2 (fn (op f g) (list :derived-fn2 op f g)))
 (define mkout (fn (f) (list :outer "∘." f)))
 ; helper: literal vector AST via :vec (from list of values)
 (define mkvec (fn (xs) (cons :vec (map (fn (n) (mknum n)) xs))))
 ; ---------- monadic operators ----------
 (apl-test
  "eval-ast +/ ⍳5 → 15"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "/" (mkfg "+")) (mkmon (mkfg "⍳") (mknum 5)))
      {}))
  (list 15))
 (apl-test
  "eval-ast ×/ ⍳5 → 120"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "/" (mkfg "×")) (mkmon (mkfg "⍳") (mknum 5)))
      {}))
  (list 120))
 (apl-test
  "eval-ast ⌈/ — max reduce"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "/" (mkfg "⌈")) (mkvec (list 3 1 4 1 5 9 2 6)))
      {}))
  (list 9))
 (apl-test
  "eval-ast +\\ scan"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "\\" (mkfg "+")) (mkvec (list 1 2 3 4 5)))
      {}))
  (list 1 3 6 10 15))
 (apl-test
  "eval-ast +⌿ first-axis reduce on vector"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "⌿" (mkfg "+")) (mkvec (list 1 2 3 4 5)))
      {}))
  (list 15))
 (apl-test
  "eval-ast -¨ each-negate"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "¨" (mkfg "-")) (mkvec (list 1 2 3 4)))
      {}))
  (list -1 -2 -3 -4))
 (apl-test
  "eval-ast +⍨ commute (double via x+x)"
  (mkrv
    (apl-eval-ast (mkmon (mkder "⍨" (mkfg "+")) (mknum 7)) {}))
  (list 14))
 ; ---------- dyadic operators ----------
 (apl-test
  "eval-ast outer ∘.× — multiplication table"
  (mkrv
    (apl-eval-ast
      (mkdyd
        (mkout (mkfg "×"))
        (mkvec (list 1 2 3))
        (mkvec (list 1 2 3)))
      {}))
  (list 1 2 3 2 4 6 3 6 9))
 (apl-test
  "eval-ast outer ∘.× shape (3 3)"
  (mksh
    (apl-eval-ast
      (mkdyd
        (mkout (mkfg "×"))
        (mkvec (list 1 2 3))
        (mkvec (list 1 2 3)))
      {}))
  (list 3 3))
 (apl-test
  "eval-ast inner +.× — dot product"
  (mkrv
    (apl-eval-ast
      (mkdyd
        (mkdr2 "." (mkfg "+") (mkfg "×"))
        (mkvec (list 1 2 3))
        (mkvec (list 4 5 6)))
      {}))
  (list 32))
 (apl-test
  "eval-ast inner ∧.= equal vectors"
  (mkrv
    (apl-eval-ast
      (mkdyd
        (mkdr2 "." (mkfg "∧") (mkfg "="))
        (mkvec (list 1 2 3))
        (mkvec (list 1 2 3)))
      {}))
  (list 1))
 (apl-test
  "eval-ast each-dyadic +¨"
  (mkrv
    (apl-eval-ast
      (mkdyd
        (mkder "¨" (mkfg "+"))
        (mkvec (list 1 2 3))
        (mkvec (list 10 20 30)))
      {}))
  (list 11 22 33))
 (apl-test
  "eval-ast commute -⍨ (subtract swapped)"
  (mkrv
    (apl-eval-ast
      (mkdyd (mkder "⍨" (mkfg "-")) (mknum 5) (mknum 3))
      {}))
  (list -2))
 ; ---------- nested operators ----------
 (apl-test
  "eval-ast +/¨ — sum of each"
  (mkrv
    (apl-eval-ast
      (mkmon (mkder "/" (mkfg "+")) (mkvec (list 10 20 30)))
      {}))
  (list 60))
--- a/lib/apl/tests/idioms.sx
+++ b/lib/apl/tests/idioms.sx
@@ -0,0 +1,359 @@
 ; APL idiom corpus — classic Roger Hui / Phil Last idioms expressed
 ; through our runtime primitives.  Each test names the APL one-liner
 ; and verifies the equivalent runtime call.
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 ; ---------- reductions ----------
 (apl-test
  "+/⍵ — sum"
  (mkrv (apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 15))
 (apl-test
  "(+/⍵)÷⍴⍵ — mean"
  (mkrv
    (apl-div
      (apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5)))
      (apl-scalar 5)))
  (list 3))
 (apl-test
  "⌈/⍵ — max"
  (mkrv (apl-reduce apl-max (make-array (list 6) (list 3 1 4 1 5 9))))
  (list 9))
 (apl-test
  "⌊/⍵ — min"
  (mkrv (apl-reduce apl-min (make-array (list 6) (list 3 1 4 1 5 9))))
  (list 1))
 (apl-test
  "(⌈/⍵)-⌊/⍵ — range"
  (mkrv
    (apl-sub
      (apl-reduce apl-max (make-array (list 6) (list 3 1 4 1 5 9)))
      (apl-reduce apl-min (make-array (list 6) (list 3 1 4 1 5 9)))))
  (list 8))
 (apl-test
  "×/⍵ — product"
  (mkrv (apl-reduce apl-mul (make-array (list 4) (list 1 2 3 4))))
  (list 24))
 (apl-test
  "+\\⍵ — running sum"
  (mkrv (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 3 6 10 15))
 ; ---------- sort / order ----------
 (apl-test
  "⍵[⍋⍵] — sort ascending"
  (mkrv (apl-quicksort (make-array (list 5) (list 3 1 4 1 5))))
  (list 1 1 3 4 5))
 (apl-test
  "⌽⍵ — reverse"
  (mkrv (apl-reverse (make-array (list 5) (list 1 2 3 4 5))))
  (list 5 4 3 2 1))
 (apl-test
  "⊃⌽⍵ — last element"
  (mkrv
    (apl-disclose (apl-reverse (make-array (list 4) (list 10 20 30 40)))))
  (list 40))
 (apl-test
  "1↑⍵ — first element"
  (mkrv
    (apl-take (apl-scalar 1) (make-array (list 4) (list 10 20 30 40))))
  (list 10))
 (apl-test
  "1↓⍵ — drop first"
  (mkrv
    (apl-drop (apl-scalar 1) (make-array (list 4) (list 10 20 30 40))))
  (list 20 30 40))
 (apl-test
  "¯1↓⍵ — drop last"
  (mkrv
    (apl-drop (apl-scalar -1) (make-array (list 4) (list 10 20 30 40))))
  (list 10 20 30))
 ; ---------- counts / membership ----------
 (apl-test
  "≢⍵ — tally"
  (mkrv (apl-tally (make-array (list 7) (list 9 8 7 6 5 4 3))))
  (list 7))
 (apl-test
  "+/⍵=v — count occurrences of v"
  (mkrv
    (apl-reduce
      apl-add
      (apl-eq (make-array (list 7) (list 1 2 3 2 1 3 2)) (apl-scalar 2))))
  (list 3))
 (apl-test
  "0=N|M — divisibility test"
  (mkrv (apl-eq (apl-scalar 0) (apl-mod (apl-scalar 3) (apl-scalar 12))))
  (list 1))
 ; ---------- shape constructors ----------
 (apl-test
  "N⍴1 — vector of N ones"
  (mkrv (apl-reshape (apl-scalar 5) (apl-scalar 1)))
  (list 1 1 1 1 1))
 (apl-test
  "(N N)⍴0 — N×N zero matrix"
  (mkrv (apl-reshape (make-array (list 2) (list 3 3)) (apl-scalar 0)))
  (list 0 0 0 0 0 0 0 0 0))
 (apl-test
  "⍳∘.=⍳ — N×N identity matrix"
  (mkrv
    (apl-outer apl-eq (apl-iota (apl-scalar 3)) (apl-iota (apl-scalar 3))))
  (list 1 0 0 0 1 0 0 0 1))
 (apl-test
  "⍳∘.×⍳ — multiplication table"
  (mkrv
    (apl-outer apl-mul (apl-iota (apl-scalar 3)) (apl-iota (apl-scalar 3))))
  (list 1 2 3 2 4 6 3 6 9))
 ; ---------- numerical idioms ----------
 (apl-test
  "+\\⍳N — triangular numbers"
  (mkrv (apl-scan apl-add (apl-iota (apl-scalar 5))))
  (list 1 3 6 10 15))
 (apl-test
  "+/⍳N=N×(N+1)÷2 — sum of 1..N"
  (mkrv (apl-reduce apl-add (apl-iota (apl-scalar 10))))
  (list 55))
 (apl-test
  "×/⍳N — factorial via iota"
  (mkrv (apl-reduce apl-mul (apl-iota (apl-scalar 5))))
  (list 120))
 (apl-test
  "2|⍵ — parity (1=odd)"
  (mkrv (apl-mod (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 0 1 0 1))
 (apl-test
  "+/2|⍵ — count odd"
  (mkrv
    (apl-reduce
      apl-add
      (apl-mod (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5)))))
  (list 3))
 ; ---------- boolean idioms ----------
 (apl-test
  "∧/⍵ — all-true"
  (mkrv (apl-reduce apl-and (make-array (list 4) (list 1 1 1 1))))
  (list 1))
 (apl-test
  "∧/⍵ — all-true with zero is false"
  (mkrv (apl-reduce apl-and (make-array (list 4) (list 1 1 0 1))))
  (list 0))
 (apl-test
  "∨/⍵ — any-true"
  (mkrv (apl-reduce apl-or (make-array (list 4) (list 0 0 1 0))))
  (list 1))
 (apl-test
  "∨/⍵ — any-true all zero is false"
  (mkrv (apl-reduce apl-or (make-array (list 4) (list 0 0 0 0))))
  (list 0))
 ; ---------- selection / scaling ----------
 (apl-test
  "⍵×⍵ — square each"
  (mkrv
    (apl-mul
      (make-array (list 4) (list 1 2 3 4))
      (make-array (list 4) (list 1 2 3 4))))
  (list 1 4 9 16))
 (apl-test
  "+/⍵×⍵ — sum of squares"
  (mkrv
    (apl-reduce
      apl-add
      (apl-mul
        (make-array (list 4) (list 1 2 3 4))
        (make-array (list 4) (list 1 2 3 4)))))
  (list 30))
 (apl-test
  "⍵-(+/⍵)÷⍴⍵ — mean-centered"
  (mkrv
    (apl-sub
      (make-array (list 5) (list 2 4 6 8 10))
      (apl-div
        (apl-reduce apl-add (make-array (list 5) (list 2 4 6 8 10)))
        (apl-scalar 5))))
  (list -4 -2 0 2 4))
 ; ---------- shape / structure ----------
 (apl-test
  ",⍵ — ravel"
  (mkrv (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 3 4 5 6))
 (apl-test
  "⍴⍴⍵ — rank"
  (mkrv
    (apl-shape (apl-shape (make-array (list 2 3) (list 1 2 3 4 5 6)))))
  (list 2))
 (apl-test
  "src: +/⍳N → triangular(N)"
  (mkrv (apl-run "+/⍳100"))
  (list 5050))
 (apl-test "src: ×/⍳N → N!" (mkrv (apl-run "×/⍳6")) (list 720))
 (apl-test
  "src: ⌈/V — max"
  (mkrv (apl-run "⌈/3 1 4 1 5 9 2 6"))
  (list 9))
 (apl-test
  "src: ⌊/V — min"
  (mkrv (apl-run "⌊/3 1 4 1 5 9 2 6"))
  (list 1))
 (apl-test
  "src: range = (⌈/V) - ⌊/V"
  (mkrv (apl-run "(⌈/3 1 4 1 5 9 2 6) - ⌊/3 1 4 1 5 9 2 6"))
  (list 8))
 (apl-test
  "src: +\\V — running sum"
  (mkrv (apl-run "+\\1 2 3 4 5"))
  (list 1 3 6 10 15))
 (apl-test
  "src: ×\\V — running product"
  (mkrv (apl-run "×\\1 2 3 4 5"))
  (list 1 2 6 24 120))
 (apl-test
  "src: V × V — squares"
  (mkrv (apl-run "(⍳5) × ⍳5"))
  (list 1 4 9 16 25))
 (apl-test
  "src: +/V × V — sum of squares"
  (mkrv (apl-run "+/(⍳5) × ⍳5"))
  (list 55))
 (apl-test "src: ∧/V — all-true" (mkrv (apl-run "∧/1 1 1 1")) (list 1))
 (apl-test "src: ∨/V — any-true" (mkrv (apl-run "∨/0 0 1 0")) (list 1))
 (apl-test "src: 0 = N|M — divides" (mkrv (apl-run "0 = 3 | 12")) (list 1))
 (apl-test
  "src: 2 | V — parity"
  (mkrv (apl-run "2 | 1 2 3 4 5 6"))
  (list 1 0 1 0 1 0))
 (apl-test
  "src: +/2|V — count odd"
  (mkrv (apl-run "+/2 | 1 2 3 4 5 6"))
  (list 3))
 (apl-test "src: ⍴ V" (mkrv (apl-run "⍴ 1 2 3 4 5")) (list 5))
 (apl-test
  "src: ⍴⍴ M — rank"
  (mkrv (apl-run "⍴ ⍴ (2 3) ⍴ ⍳6"))
  (list 2))
 (apl-test
  "src: N⍴1 — vector of ones"
  (mkrv (apl-run "5 ⍴ 1"))
  (list 1 1 1 1 1))
 (apl-test
  "src: ⍳N ∘.= ⍳N — identity matrix"
  (mkrv (apl-run "(⍳3) ∘.= ⍳3"))
  (list 1 0 0 0 1 0 0 0 1))
 (apl-test
  "src: ⍳N ∘.× ⍳N — multiplication table"
  (mkrv (apl-run "(⍳3) ∘.× ⍳3"))
  (list 1 2 3 2 4 6 3 6 9))
 (apl-test
  "src: V +.× V — dot product"
  (mkrv (apl-run "1 2 3 +.× 4 5 6"))
  (list 32))
 (apl-test
  "src: ∧.= V — vectors equal?"
  (mkrv (apl-run "1 2 3 ∧.= 1 2 3"))
  (list 1))
 (apl-test
  "src: V[1] — first element"
  (mkrv (apl-run "(10 20 30 40)[1]"))
  (list 10))
 (apl-test
  "src: 1↑V — first via take"
  (mkrv (apl-run "1 ↑ 10 20 30 40"))
  (list 10))
 (apl-test
  "src: 1↓V — drop first"
  (mkrv (apl-run "1 ↓ 10 20 30 40"))
  (list 20 30 40))
 (apl-test
  "src: ¯1↓V — drop last"
  (mkrv (apl-run "¯1 ↓ 10 20 30 40"))
  (list 10 20 30))
 (apl-test
  "src: ⌽V — reverse"
  (mkrv (apl-run "⌽ 1 2 3 4 5"))
  (list 5 4 3 2 1))
 (apl-test
  "src: ≢V — tally"
  (mkrv (apl-run "≢ 9 8 7 6 5 4 3 2 1"))
  (list 9))
 (apl-test
  "src: ,M — ravel"
  (mkrv (apl-run ", (2 3) ⍴ ⍳6"))
  (list 1 2 3 4 5 6))
 (apl-test
  "src: A=V — count occurrences"
  (mkrv (apl-run "+/2 = 1 2 3 2 1 3 2"))
  (list 3))
 (apl-test
  "src: ⌈/(V × V) — max squared"
  (mkrv (apl-run "⌈/(1 2 3 4 5) × 1 2 3 4 5"))
  (list 25))
--- a/lib/apl/tests/operators.sx
+++ b/lib/apl/tests/operators.sx
@@ -0,0 +1,791 @@
 (define rv (fn (arr) (get arr :ravel)))
 (define sh (fn (arr) (get arr :shape)))
 (apl-test
  "reduce +/ vector"
  (rv (apl-reduce apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 15))
 (apl-test
  "reduce x/ vector"
  (rv (apl-reduce apl-mul (make-array (list 4) (list 1 2 3 4))))
  (list 24))
 (apl-test
  "reduce max/ vector"
  (rv (apl-reduce apl-max (make-array (list 5) (list 3 1 4 1 5))))
  (list 5))
 (apl-test
  "reduce min/ vector"
  (rv (apl-reduce apl-min (make-array (list 3) (list 3 1 4))))
  (list 1))
 (apl-test
  "reduce and/ all true"
  (rv (apl-reduce apl-and (make-array (list 3) (list 1 1 1))))
  (list 1))
 (apl-test
  "reduce or/ with true"
  (rv (apl-reduce apl-or (make-array (list 3) (list 0 0 1))))
  (list 1))
 (apl-test
  "reduce +/ single element"
  (rv (apl-reduce apl-add (make-array (list 1) (list 42))))
  (list 42))
 (apl-test
  "reduce +/ scalar no-op"
  (rv (apl-reduce apl-add (apl-scalar 7)))
  (list 7))
 (apl-test
  "reduce +/ shape is scalar"
  (sh (apl-reduce apl-add (make-array (list 4) (list 1 2 3 4))))
  (list))
 (apl-test
  "reduce +/ matrix row sums shape"
  (sh (apl-reduce apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2))
 (apl-test
  "reduce +/ matrix row sums values"
  (rv (apl-reduce apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 6 15))
 (apl-test
  "reduce max/ matrix row maxima"
  (rv (apl-reduce apl-max (make-array (list 2 3) (list 3 1 4 1 5 9))))
  (list 4 9))
 (apl-test
  "reduce-first +/ vector same as reduce"
  (rv (apl-reduce-first apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 15))
 (apl-test
  "reduce-first +/ matrix col sums shape"
  (sh
    (apl-reduce-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3))
 (apl-test
  "reduce-first +/ matrix col sums values"
  (rv
    (apl-reduce-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 5 7 9))
 (apl-test
  "reduce-first max/ matrix col maxima"
  (rv
    (apl-reduce-first apl-max (make-array (list 3 2) (list 1 9 2 8 3 7))))
  (list 3 9))
 (apl-test
  "scan +\\ vector"
  (rv (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 3 6 10 15))
 (apl-test
  "scan x\\ vector cumulative product"
  (rv (apl-scan apl-mul (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 6 24 120))
 (apl-test
  "scan max\\ vector running max"
  (rv (apl-scan apl-max (make-array (list 5) (list 3 1 4 1 5))))
  (list 3 3 4 4 5))
 (apl-test
  "scan min\\ vector running min"
  (rv (apl-scan apl-min (make-array (list 5) (list 3 1 4 1 5))))
  (list 3 1 1 1 1))
 (apl-test
  "scan +\\ single element"
  (rv (apl-scan apl-add (make-array (list 1) (list 42))))
  (list 42))
 (apl-test
  "scan +\\ scalar no-op"
  (rv (apl-scan apl-add (apl-scalar 7)))
  (list 7))
 (apl-test
  "scan +\\ vector preserves shape"
  (sh (apl-scan apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 5))
 (apl-test
  "scan +\\ matrix preserves shape"
  (sh (apl-scan apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "scan +\\ matrix row-wise"
  (rv (apl-scan apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 3 6 4 9 15))
 (apl-test
  "scan max\\ matrix row-wise running max"
  (rv (apl-scan apl-max (make-array (list 2 3) (list 3 1 4 1 5 9))))
  (list 3 3 4 1 5 9))
 (apl-test
  "scan-first +\\ vector same as scan"
  (rv (apl-scan-first apl-add (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 3 6 10 15))
 (apl-test
  "scan-first +\\ scalar no-op"
  (rv (apl-scan-first apl-add (apl-scalar 9)))
  (list 9))
 (apl-test
  "scan-first +\\ matrix preserves shape"
  (sh (apl-scan-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "scan-first +\\ matrix col-wise"
  (rv (apl-scan-first apl-add (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 3 5 7 9))
 (apl-test
  "scan-first max\\ matrix col-wise running max"
  (rv (apl-scan-first apl-max (make-array (list 3 2) (list 3 1 4 1 5 9))))
  (list 3 1 4 1 5 9))
 (apl-test
  "each negate vector"
  (rv (apl-each apl-neg-m (make-array (list 3) (list 1 2 3))))
  (list -1 -2 -3))
 (apl-test
  "each negate vector preserves shape"
  (sh (apl-each apl-neg-m (make-array (list 3) (list 1 2 3))))
  (list 3))
 (apl-test
  "each reciprocal vector"
  (rv (apl-each apl-recip (make-array (list 3) (list 1 2 4))))
  (list 1 (/ 1 2) (/ 1 4)))
 (apl-test
  "each abs vector"
  (rv (apl-each apl-abs (make-array (list 4) (list -1 2 -3 4))))
  (list 1 2 3 4))
 (apl-test "each scalar" (rv (apl-each apl-neg-m (apl-scalar 5))) (list -5))
 (apl-test
  "each scalar shape"
  (sh (apl-each apl-neg-m (apl-scalar 5)))
  (list))
 (apl-test
  "each negate matrix shape"
  (sh (apl-each apl-neg-m (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "each negate matrix values"
  (rv (apl-each apl-neg-m (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list -1 -2 -3 -4 -5 -6))
 (apl-test
  "each-dyadic scalar+scalar"
  (rv (apl-each-dyadic apl-add (apl-scalar 3) (apl-scalar 4)))
  (list 7))
 (apl-test
  "each-dyadic scalar+vector"
  (rv
    (apl-each-dyadic
      apl-add
      (apl-scalar 10)
      (make-array (list 3) (list 1 2 3))))
  (list 11 12 13))
 (apl-test
  "each-dyadic vector+scalar"
  (rv
    (apl-each-dyadic
      apl-add
      (make-array (list 3) (list 1 2 3))
      (apl-scalar 10)))
  (list 11 12 13))
 (apl-test
  "each-dyadic vector+vector"
  (rv
    (apl-each-dyadic
      apl-add
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 10 20 30))))
  (list 11 22 33))
 (apl-test
  "each-dyadic mul matrix+matrix shape"
  (sh
    (apl-each-dyadic
      apl-mul
      (make-array (list 2 2) (list 1 2 3 4))
      (make-array (list 2 2) (list 5 6 7 8))))
  (list 2 2))
 (apl-test
  "each-dyadic mul matrix+matrix values"
  (rv
    (apl-each-dyadic
      apl-mul
      (make-array (list 2 2) (list 1 2 3 4))
      (make-array (list 2 2) (list 5 6 7 8))))
  (list 5 12 21 32))
 (apl-test
  "outer product mult table values"
  (rv
    (apl-outer
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 2 3))))
  (list 1 2 3 2 4 6 3 6 9))
 (apl-test
  "outer product mult table shape"
  (sh
    (apl-outer
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 2 3))))
  (list 3 3))
 (apl-test
  "outer product add table values"
  (rv
    (apl-outer
      apl-add
      (make-array (list 2) (list 1 2))
      (make-array (list 3) (list 10 20 30))))
  (list 11 21 31 12 22 32))
 (apl-test
  "outer product add table shape"
  (sh
    (apl-outer
      apl-add
      (make-array (list 2) (list 1 2))
      (make-array (list 3) (list 10 20 30))))
  (list 2 3))
 (apl-test
  "outer product scalar+vector shape"
  (sh
    (apl-outer apl-mul (apl-scalar 5) (make-array (list 3) (list 1 2 3))))
  (list 3))
 (apl-test
  "outer product scalar+vector values"
  (rv
    (apl-outer apl-mul (apl-scalar 5) (make-array (list 3) (list 1 2 3))))
  (list 5 10 15))
 (apl-test
  "outer product vector+scalar shape"
  (sh
    (apl-outer apl-mul (make-array (list 3) (list 1 2 3)) (apl-scalar 10)))
  (list 3))
 (apl-test
  "outer product scalar+scalar"
  (rv (apl-outer apl-mul (apl-scalar 6) (apl-scalar 7)))
  (list 42))
 (apl-test
  "outer product scalar+scalar shape"
  (sh (apl-outer apl-mul (apl-scalar 6) (apl-scalar 7)))
  (list))
 (apl-test
  "outer product equality identity matrix values"
  (rv
    (apl-outer
      apl-eq
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 2 3))))
  (list 1 0 0 0 1 0 0 0 1))
 (apl-test
  "outer product matrix+vector rank doubling shape"
  (sh
    (apl-outer
      apl-add
      (make-array (list 2 2) (list 1 2 3 4))
      (make-array (list 3) (list 10 20 30))))
  (list 2 2 3))
 (apl-test
  "outer product matrix+vector rank doubling values"
  (rv
    (apl-outer
      apl-add
      (make-array (list 2 2) (list 1 2 3 4))
      (make-array (list 3) (list 10 20 30))))
  (list 11 21 31 12 22 32 13 23 33 14 24 34))
 (apl-test
  "inner +.× dot product"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 4 5 6))))
  (list 32))
 (apl-test
  "inner +.× dot product shape is scalar"
  (sh
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 4 5 6))))
  (list))
 (apl-test
  "inner +.× matrix multiply 2x3 * 3x2 shape"
  (sh
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3 2) (list 7 8 9 10 11 12))))
  (list 2 2))
 (apl-test
  "inner +.× matrix multiply 2x3 * 3x2 values"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3 2) (list 7 8 9 10 11 12))))
  (list 58 64 139 154))
 (apl-test
  "inner +.× identity matrix 2x2"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 2 2) (list 1 0 0 1))
      (make-array (list 2 2) (list 5 6 7 8))))
  (list 5 6 7 8))
 (apl-test
  "inner ∧.= equal vectors"
  (rv
    (apl-inner
      apl-and
      apl-eq
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 2 3))))
  (list 1))
 (apl-test
  "inner ∧.= unequal vectors"
  (rv
    (apl-inner
      apl-and
      apl-eq
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 9 3))))
  (list 0))
 (apl-test
  "inner +.× matrix * vector shape"
  (sh
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3) (list 7 8 9))))
  (list 2))
 (apl-test
  "inner +.× matrix * vector values"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3) (list 7 8 9))))
  (list 50 122))
 (apl-test
  "inner +.× vector * matrix shape"
  (sh
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3 2) (list 4 5 6 7 8 9))))
  (list 2))
 (apl-test
  "inner +.× vector * matrix values"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3 2) (list 4 5 6 7 8 9))))
  (list 40 46))
 (apl-test
  "inner +.× single-element vectors"
  (rv
    (apl-inner
      apl-add
      apl-mul
      (make-array (list 1) (list 6))
      (make-array (list 1) (list 7))))
  (list 42))
 (apl-test
  "commute +⍨ scalar doubles"
  (rv (apl-commute apl-add (apl-scalar 5)))
  (list 10))
 (apl-test
  "commute ×⍨ vector squares"
  (rv (apl-commute apl-mul (make-array (list 4) (list 1 2 3 4))))
  (list 1 4 9 16))
 (apl-test
  "commute +⍨ vector doubles"
  (rv (apl-commute apl-add (make-array (list 3) (list 1 2 3))))
  (list 2 4 6))
 (apl-test
  "commute +⍨ shape preserved"
  (sh (apl-commute apl-add (make-array (list 3) (list 1 2 3))))
  (list 3))
 (apl-test
  "commute ×⍨ matrix shape preserved"
  (sh (apl-commute apl-mul (make-array (list 2 2) (list 1 2 3 4))))
  (list 2 2))
 (apl-test
  "commute-dyadic -⍨ swaps subtraction"
  (rv (apl-commute-dyadic apl-sub (apl-scalar 5) (apl-scalar 3)))
  (list -2))
 (apl-test
  "commute-dyadic ÷⍨ swaps division"
  (rv (apl-commute-dyadic apl-div (apl-scalar 4) (apl-scalar 12)))
  (list 3))
 (apl-test
  "commute-dyadic -⍨ on vectors"
  (rv
    (apl-commute-dyadic
      apl-sub
      (make-array (list 3) (list 10 20 30))
      (make-array (list 3) (list 1 2 3))))
  (list -9 -18 -27))
 (apl-test
  "commute-dyadic +⍨ commutative same result"
  (rv
    (apl-commute-dyadic
      apl-add
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 10 20 30))))
  (list 11 22 33))
 (apl-test
  "commute-dyadic ×⍨ commutative same result"
  (rv
    (apl-commute-dyadic
      apl-mul
      (make-array (list 3) (list 2 3 4))
      (make-array (list 3) (list 5 6 7))))
  (list 10 18 28))
 (apl-test
  "compose -∘| scalar (negative abs)"
  (rv (apl-compose apl-neg-m apl-abs (apl-scalar -7)))
  (list -7))
 (apl-test
  "compose -∘| vector"
  (rv
    (apl-compose apl-neg-m apl-abs (make-array (list 4) (list -1 2 -3 4))))
  (list -1 -2 -3 -4))
 (apl-test
  "compose ⌊∘- (floor of negate)"
  (rv (apl-compose apl-floor apl-neg-m (make-array (list 3) (list 1 2 3))))
  (list -1 -2 -3))
 (apl-test
  "compose -∘| matrix shape preserved"
  (sh
    (apl-compose apl-neg-m apl-abs (make-array (list 2 2) (list -1 2 -3 4))))
  (list 2 2))
 (apl-test
  "compose-dyadic +∘- equals subtract scalar"
  (rv (apl-compose-dyadic apl-add apl-neg-m (apl-scalar 10) (apl-scalar 3)))
  (list 7))
 (apl-test
  "compose-dyadic +∘- equals subtract vector"
  (rv
    (apl-compose-dyadic
      apl-add
      apl-neg-m
      (make-array (list 3) (list 10 20 30))
      (make-array (list 3) (list 1 2 3))))
  (list 9 18 27))
 (apl-test
  "compose-dyadic -∘| (subtract abs)"
  (rv (apl-compose-dyadic apl-sub apl-abs (apl-scalar 10) (apl-scalar -3)))
  (list 7))
 (apl-test
  "compose-dyadic ×∘- (multiply by negative)"
  (rv
    (apl-compose-dyadic
      apl-mul
      apl-neg-m
      (make-array (list 3) (list 2 3 4))
      (make-array (list 3) (list 1 2 3))))
  (list -2 -6 -12))
 (apl-test
  "compose-dyadic shape preserved"
  (sh
    (apl-compose-dyadic
      apl-add
      apl-neg-m
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 2 3) (list 1 1 1 1 1 1))))
  (list 2 3))
 (apl-test
  "power n=0 identity"
  (rv (apl-power (fn (a) (apl-add a (apl-scalar 1))) 0 (apl-scalar 5)))
  (list 5))
 (apl-test
  "power increment by 3"
  (rv (apl-power (fn (a) (apl-add a (apl-scalar 1))) 3 (apl-scalar 0)))
  (list 3))
 (apl-test
  "power double 4 times = 16"
  (rv (apl-power (fn (a) (apl-mul a (apl-scalar 2))) 4 (apl-scalar 1)))
  (list 16))
 (apl-test
  "power on vector +5"
  (rv
    (apl-power
      (fn (a) (apl-add a (apl-scalar 1)))
      5
      (make-array (list 3) (list 1 2 3))))
  (list 6 7 8))
 (apl-test
  "power on vector preserves shape"
  (sh
    (apl-power
      (fn (a) (apl-add a (apl-scalar 1)))
      5
      (make-array (list 3) (list 1 2 3))))
  (list 3))
 (apl-test
  "power on matrix"
  (rv
    (apl-power
      (fn (a) (apl-mul a (apl-scalar 3)))
      2
      (make-array (list 2 2) (list 1 2 3 4))))
  (list 9 18 27 36))
 (apl-test
  "power-fixed identity stops immediately"
  (rv (apl-power-fixed (fn (a) a) (make-array (list 3) (list 1 2 3))))
  (list 1 2 3))
 (apl-test
  "power-fixed floor half scalar to 0"
  (rv
    (apl-power-fixed
      (fn (a) (apl-floor (apl-div a (apl-scalar 2))))
      (apl-scalar 100)))
  (list 0))
 (apl-test
  "power-fixed shape preserved"
  (sh
    (apl-power-fixed (fn (a) a) (make-array (list 2 2) (list 1 2 3 4))))
  (list 2 2))
 (apl-test
  "rank tally⍤1 row tallies"
  (rv (apl-rank apl-tally 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3 3))
 (apl-test
  "rank tally⍤1 row tallies shape"
  (sh (apl-rank apl-tally 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2))
 (apl-test
  "rank neg⍤0 vector scalar cells"
  (rv (apl-rank apl-neg-m 0 (make-array (list 3) (list 1 2 3))))
  (list -1 -2 -3))
 (apl-test
  "rank neg⍤0 vector preserves shape"
  (sh (apl-rank apl-neg-m 0 (make-array (list 3) (list 1 2 3))))
  (list 3))
 (apl-test
  "rank neg⍤1 matrix per-row"
  (rv (apl-rank apl-neg-m 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list -1 -2 -3 -4 -5 -6))
 (apl-test
  "rank neg⍤1 matrix preserves shape"
  (sh (apl-rank apl-neg-m 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "rank k>=rank fallthrough"
  (rv (apl-rank apl-tally 5 (make-array (list 4) (list 1 2 3 4))))
  (list 4))
 (apl-test
  "rank tally⍤2 whole matrix tally"
  (rv
    (apl-rank
      apl-tally
      2
      (make-array (list 3 5) (list 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15))))
  (list 3))
 (apl-test
  "rank reverse⍤1 matrix reverse rows"
  (rv (apl-rank apl-reverse 1 (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3 2 1 6 5 4))
 (apl-test
  "rank tally⍤1 3x4 row tallies"
  (rv
    (apl-rank
      apl-tally
      1
      (make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
  (list 4 4 4))
 (apl-test
  "at-replace single index"
  (rv
    (apl-at-replace
      (apl-scalar 99)
      (make-array (list 1) (list 2))
      (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 99 3 4 5))
 (apl-test
  "at-replace multiple indices vector vals"
  (rv
    (apl-at-replace
      (make-array (list 2) (list 99 88))
      (make-array (list 2) (list 2 4))
      (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 99 3 88 5))
 (apl-test
  "at-replace scalar broadcast"
  (rv
    (apl-at-replace
      (apl-scalar 0)
      (make-array (list 3) (list 1 3 5))
      (make-array (list 5) (list 10 20 30 40 50))))
  (list 0 20 0 40 0))
 (apl-test
  "at-replace preserves shape"
  (sh
    (apl-at-replace
      (apl-scalar 99)
      (make-array (list 1) (list 2))
      (make-array (list 5) (list 1 2 3 4 5))))
  (list 5))
 (apl-test
  "at-replace last index"
  (rv
    (apl-at-replace
      (apl-scalar 99)
      (make-array (list 1) (list 5))
      (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3 4 99))
 (apl-test
  "at-replace on matrix linear-index"
  (rv
    (apl-at-replace
      (apl-scalar 99)
      (make-array (list 1) (list 3))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 99 4 5 6))
 (apl-test
  "at-apply negate at indices"
  (rv
    (apl-at-apply
      apl-neg-m
      (make-array (list 3) (list 1 3 5))
      (make-array (list 5) (list 1 2 3 4 5))))
  (list -1 2 -3 4 -5))
 (apl-test
  "at-apply double at index 1"
  (rv
    (apl-at-apply
      (fn (a) (apl-mul a (apl-scalar 2)))
      (make-array (list 1) (list 1))
      (make-array (list 2) (list 5 10))))
  (list 10 10))
 (apl-test
  "at-apply preserves shape"
  (sh
    (apl-at-apply
      apl-neg-m
      (make-array (list 2) (list 1 3))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "at-apply on matrix linear-index"
  (rv
    (apl-at-apply
      apl-neg-m
      (make-array (list 2) (list 1 6))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list -1 2 3 4 5 -6))
--- a/lib/apl/tests/parse.sx
+++ b/lib/apl/tests/parse.sx
@@ -0,0 +1,340 @@
 (define apl-test-count 0)
 (define apl-test-pass  0)
 (define apl-test-fails (list))
 (define apl-test
  (fn (name actual expected)
    (begin
      (set! apl-test-count (+ apl-test-count 1))
      (if (= actual expected)
        (set! apl-test-pass (+ apl-test-pass 1))
        (append! apl-test-fails {:name name :actual actual :expected expected})))))
 (define tok-types
  (fn (src)
    (map (fn (t) (get t :type)) (apl-tokenize src))))
 (define tok-values
  (fn (src)
    (map (fn (t) (get t :value)) (apl-tokenize src))))
 (define tok-count
  (fn (src)
    (len (apl-tokenize src))))
 (define tok-type-at
  (fn (src i)
    (get (nth (apl-tokenize src) i) :type)))
 (define tok-value-at
  (fn (src i)
    (get (nth (apl-tokenize src) i) :value)))
 (apl-test "empty: no tokens"        (tok-count "")           0)
 (apl-test "empty: whitespace only"  (tok-count "   ")        0)
 (apl-test "num: zero"               (tok-values "0")         (list 0))
 (apl-test "num: positive"           (tok-values "42")        (list 42))
 (apl-test "num: large"              (tok-values "12345")     (list 12345))
 (apl-test "num: negative"           (tok-values "¯5")        (list -5))
 (apl-test "num: negative zero"      (tok-values "¯0")        (list 0))
 (apl-test "num: strand count"       (tok-count "1 2 3")      3)
 (apl-test "num: strand types"       (tok-types "1 2 3")      (list :num :num :num))
 (apl-test "num: strand values"      (tok-values "1 2 3")     (list 1 2 3))
 (apl-test "num: neg in strand"      (tok-values "1 ¯2 3")    (list 1 -2 3))
 (apl-test "str: empty"              (tok-values "''")        (list ""))
 (apl-test "str: single char"        (tok-values "'a'")       (list "a"))
 (apl-test "str: word"               (tok-values "'hello'")   (list "hello"))
 (apl-test "str: escaped quote"      (tok-values "''''")      (list "'"))
 (apl-test "str: type"               (tok-types "'abc'")      (list :str))
 (apl-test "name: simple"            (tok-values "foo")       (list "foo"))
 (apl-test "name: type"              (tok-types "foo")        (list :name))
 (apl-test "name: mixed case"        (tok-values "MyVar")     (list "MyVar"))
 (apl-test "name: with digits"       (tok-values "x1")        (list "x1"))
 (apl-test "name: system var"        (tok-values "⎕IO")       (list "⎕IO"))
 (apl-test "name: system var type"   (tok-types "⎕IO")        (list :name))
 (apl-test "glyph: plus"             (tok-types "+")          (list :glyph))
 (apl-test "glyph: plus value"       (tok-values "+")         (list "+"))
 (apl-test "glyph: iota"             (tok-values "⍳")         (list "⍳"))
 (apl-test "glyph: reduce"           (tok-values "+/")        (list "+" "/"))
 (apl-test "glyph: floor"            (tok-values "⌊")         (list "⌊"))
 (apl-test "glyph: rho"              (tok-values "⍴")         (list "⍴"))
 (apl-test "glyph: alpha omega"      (tok-types "⍺ ⍵")        (list :glyph :glyph))
 (apl-test "punct: lparen"           (tok-types "(")          (list :lparen))
 (apl-test "punct: rparen"           (tok-types ")")          (list :rparen))
 (apl-test "punct: brackets"         (tok-types "[42]")       (list :lbracket :num :rbracket))
 (apl-test "punct: braces"           (tok-types "{}")         (list :lbrace :rbrace))
 (apl-test "punct: semi"             (tok-types ";")          (list :semi))
 (apl-test "assign: arrow"           (tok-types "x←1")        (list :name :assign :num))
 (apl-test "diamond: separator"      (tok-types "1⋄2")        (list :num :diamond :num))
 (apl-test "newline: emitted"        (tok-types "1\n2")       (list :num :newline :num))
 (apl-test "comment: skipped"        (tok-count "⍝ ignore me") 0)
 (apl-test "comment: rest ignored"   (tok-count "1 ⍝ note")  1)
 (apl-test "colon: bare"             (tok-types ":")          (list :colon))
 (apl-test "keyword: If"             (tok-values ":If")       (list ":If"))
 (apl-test "keyword: type"           (tok-types ":While")     (list :keyword))
 (apl-test "keyword: EndFor"         (tok-values ":EndFor")   (list ":EndFor"))
 (apl-test "expr: +/ ⍳ 5"           (tok-types "+/ ⍳ 5")     (list :glyph :glyph :glyph :num))
 (apl-test "expr: x←42"             (tok-count "x←42")       3)
 (apl-test "expr: dfn body"          (tok-types "{⍺+⍵}")
                                    (list :lbrace :glyph :glyph :glyph :rbrace))
 (define apl-tokenize-test-summary
  (str "tokenizer " apl-test-pass "/" apl-test-count
       (if (= (len apl-test-fails) 0) "" (str " FAILS: " apl-test-fails))))
 ; ===========================================================================
 ; Parser tests
 ; ===========================================================================
 ; Helper: parse an APL source string and return the AST
 (define parse
  (fn (src) (parse-apl src)))
 ; Helper: build an expected AST node using keyword-tagged lists
 (define num-node    (fn (n)       (list :num n)))
 (define str-node    (fn (s)       (list :str s)))
 (define name-node   (fn (n)       (list :name n)))
 (define fn-node     (fn (g)       (list :fn-glyph g)))
 (define fn-nm       (fn (n)       (list :fn-name n)))
 (define assign-node (fn (nm expr) (list :assign nm expr)))
 (define monad-node  (fn (f a)     (list :monad f a)))
 (define dyad-node   (fn (f l r)   (list :dyad f l r)))
 (define derived-fn  (fn (op f)    (list :derived-fn op f)))
 (define derived-fn2 (fn (op f g)  (list :derived-fn2 op f g)))
 (define outer-node  (fn (f)       (list :outer "∘." f)))
 (define guard-node  (fn (c e)     (list :guard c e)))
 ; ---- numeric literals ----
 (apl-test "parse: num literal"
  (parse "42")
  (num-node 42))
 (apl-test "parse: negative num"
  (parse "¯3")
  (num-node -3))
 (apl-test "parse: zero"
  (parse "0")
  (num-node 0))
 ; ---- string literals ----
 (apl-test "parse: str literal"
  (parse "'hello'")
  (str-node "hello"))
 (apl-test "parse: empty str"
  (parse "''")
  (str-node ""))
 ; ---- name reference ----
 (apl-test "parse: name"
  (parse "x")
  (name-node "x"))
 (apl-test "parse: system name"
  (parse "⎕IO")
  (name-node "⎕IO"))
 ; ---- strands (vec nodes) ----
 (apl-test "parse: strand 3 nums"
  (parse "1 2 3")
  (list :vec (num-node 1) (num-node 2) (num-node 3)))
 (apl-test "parse: strand 2 nums"
  (parse "1 2")
  (list :vec (num-node 1) (num-node 2)))
 (apl-test "parse: strand with negatives"
  (parse "1 ¯2 3")
  (list :vec (num-node 1) (num-node -2) (num-node 3)))
 ; ---- assignment ----
 (apl-test "parse: assignment"
  (parse "x←42")
  (assign-node "x" (num-node 42)))
 (apl-test "parse: assignment with spaces"
  (parse "x ← 42")
  (assign-node "x" (num-node 42)))
 (apl-test "parse: assignment of expr"
  (parse "r←2+3")
  (assign-node "r" (dyad-node (fn-node "+") (num-node 2) (num-node 3))))
 ; ---- monadic functions ----
 (apl-test "parse: monadic iota"
  (parse "⍳5")
  (monad-node (fn-node "⍳") (num-node 5)))
 (apl-test "parse: monadic iota with space"
  (parse "⍳ 5")
  (monad-node (fn-node "⍳") (num-node 5)))
 (apl-test "parse: monadic negate"
  (parse "-3")
  (monad-node (fn-node "-") (num-node 3)))
 (apl-test "parse: monadic floor"
  (parse "⌊2")
  (monad-node (fn-node "⌊") (num-node 2)))
 (apl-test "parse: monadic of name"
  (parse "⍴x")
  (monad-node (fn-node "⍴") (name-node "x")))
 ; ---- dyadic functions ----
 (apl-test "parse: dyadic plus"
  (parse "2+3")
  (dyad-node (fn-node "+") (num-node 2) (num-node 3)))
 (apl-test "parse: dyadic times"
  (parse "2×3")
  (dyad-node (fn-node "×") (num-node 2) (num-node 3)))
 (apl-test "parse: dyadic with names"
  (parse "x+y")
  (dyad-node (fn-node "+") (name-node "x") (name-node "y")))
 ; ---- right-to-left evaluation ----
 (apl-test "parse: right-to-left 2×3+4"
  (parse "2×3+4")
  (dyad-node (fn-node "×") (num-node 2)
    (dyad-node (fn-node "+") (num-node 3) (num-node 4))))
 (apl-test "parse: right-to-left chain"
  (parse "1+2×3-4")
  (dyad-node (fn-node "+") (num-node 1)
    (dyad-node (fn-node "×") (num-node 2)
      (dyad-node (fn-node "-") (num-node 3) (num-node 4)))))
 ; ---- parenthesized subexpressions ----
 (apl-test "parse: parens override order"
  (parse "(2+3)×4")
  (dyad-node (fn-node "×")
    (dyad-node (fn-node "+") (num-node 2) (num-node 3))
    (num-node 4)))
 (apl-test "parse: nested parens"
  (parse "((2+3))")
  (dyad-node (fn-node "+") (num-node 2) (num-node 3)))
 (apl-test "parse: paren in dyadic right"
  (parse "2×(3+4)")
  (dyad-node (fn-node "×") (num-node 2)
    (dyad-node (fn-node "+") (num-node 3) (num-node 4))))
 ; ---- operators → derived functions ----
 (apl-test "parse: reduce +"
  (parse "+/x")
  (monad-node (derived-fn "/" (fn-node "+")) (name-node "x")))
 (apl-test "parse: reduce iota"
  (parse "+/⍳5")
  (monad-node (derived-fn "/" (fn-node "+"))
    (monad-node (fn-node "⍳") (num-node 5))))
 (apl-test "parse: scan"
  (parse "+\\x")
  (monad-node (derived-fn "\\" (fn-node "+")) (name-node "x")))
 (apl-test "parse: each"
  (parse "⍳¨x")
  (monad-node (derived-fn "¨" (fn-node "⍳")) (name-node "x")))
 (apl-test "parse: commute"
  (parse "-⍨3")
  (monad-node (derived-fn "⍨" (fn-node "-")) (num-node 3)))
 (apl-test "parse: stacked ops"
  (parse "+/¨x")
  (monad-node (derived-fn "¨" (derived-fn "/" (fn-node "+"))) (name-node "x")))
 ; ---- outer product ----
 (apl-test "parse: outer product monadic"
  (parse "∘.×")
  (outer-node (fn-node "×")))
 (apl-test "parse: outer product dyadic names"
  (parse "x ∘.× y")
  (dyad-node (outer-node (fn-node "×")) (name-node "x") (name-node "y")))
 (apl-test "parse: outer product dyadic strands"
  (parse "1 2 3 ∘.× 4 5 6")
  (dyad-node (outer-node (fn-node "×"))
    (list :vec (num-node 1) (num-node 2) (num-node 3))
    (list :vec (num-node 4) (num-node 5) (num-node 6))))
 ; ---- inner product ----
 (apl-test "parse: inner product"
  (parse "+.×")
  (derived-fn2 "." (fn-node "+") (fn-node "×")))
 (apl-test "parse: inner product applied"
  (parse "a +.× b")
  (dyad-node (derived-fn2 "." (fn-node "+") (fn-node "×"))
    (name-node "a") (name-node "b")))
 ; ---- dfn (anonymous function) ----
 (apl-test "parse: simple dfn"
  (parse "{⍺+⍵}")
  (list :dfn (dyad-node (fn-node "+") (name-node "⍺") (name-node "⍵"))))
 (apl-test "parse: monadic dfn"
  (parse "{⍵×2}")
  (list :dfn (dyad-node (fn-node "×") (name-node "⍵") (num-node 2))))
 (apl-test "parse: dfn self-ref"
  (parse "{⍵≤1:1 ⋄ ⍵×∇ ⍵-1}")
  (list :dfn
    (guard-node (dyad-node (fn-node "≤") (name-node "⍵") (num-node 1)) (num-node 1))
    (dyad-node (fn-node "×") (name-node "⍵")
      (monad-node (fn-node "∇") (dyad-node (fn-node "-") (name-node "⍵") (num-node 1))))))
 ; ---- dfn applied ----
 (apl-test "parse: dfn as function"
  (parse "{⍺+⍵} 3")
  (monad-node
    (list :dfn (dyad-node (fn-node "+") (name-node "⍺") (name-node "⍵")))
    (num-node 3)))
 ; ---- multi-statement ----
 (apl-test "parse: diamond separator"
  (let ((result (parse "x←1 ⋄ x+2")))
    (= (first result) :program))
  true)
 (apl-test "parse: diamond first stmt"
  (let ((result (parse "x←1 ⋄ x+2")))
    (nth result 1))
  (assign-node "x" (num-node 1)))
 (apl-test "parse: diamond second stmt"
  (let ((result (parse "x←1 ⋄ x+2")))
    (nth result 2))
  (dyad-node (fn-node "+") (name-node "x") (num-node 2)))
 ; ---- combined summary ----
 (define apl-parse-test-count (- apl-test-count 46))
 (define apl-parse-test-pass  (- apl-test-pass 46))
 (define apl-test-summary
  (str
    "tokenizer 46/46  |  "
    "parser " apl-parse-test-pass "/" apl-parse-test-count
    (if (= (len apl-test-fails) 0) "" (str "  FAILS: " apl-test-fails))))
--- a/lib/apl/tests/pipeline.sx
+++ b/lib/apl/tests/pipeline.sx
@@ -0,0 +1,314 @@
 ; End-to-end pipeline tests: source string → tokenize → parse → eval-ast → array.
 ; Verifies the full stack as a single function call (apl-run).
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 ; ---------- scalars ----------
 (apl-test "apl-run \"42\" → scalar 42" (mkrv (apl-run "42")) (list 42))
 (apl-test "apl-run \"¯7\" → scalar -7" (mkrv (apl-run "¯7")) (list -7))
 ; ---------- strands ----------
 (apl-test
  "apl-run \"1 2 3\" → vector"
  (mkrv (apl-run "1 2 3"))
  (list 1 2 3))
 (apl-test "apl-run \"1 2 3\" shape" (mksh (apl-run "1 2 3")) (list 3))
 ; ---------- dyadic arithmetic ----------
 (apl-test "apl-run \"2 + 3\" → 5" (mkrv (apl-run "2 + 3")) (list 5))
 (apl-run "2 × 3 + 4")  ; right-to-left
 (apl-test
  "apl-run \"2 × 3 + 4\" → 14 (right-to-left)"
  (mkrv (apl-run "2 × 3 + 4"))
  (list 14))
 (apl-test
  "apl-run \"1 2 3 + 4 5 6\" → 5 7 9"
  (mkrv (apl-run "1 2 3 + 4 5 6"))
  (list 5 7 9))
 (apl-test
  "apl-run \"3 × 1 2 3 4\" → scalar broadcast"
  (mkrv (apl-run "3 × 1 2 3 4"))
  (list 3 6 9 12))
 ; ---------- monadic primitives ----------
 (apl-test
  "apl-run \"⍳5\" → 1..5"
  (mkrv (apl-run "⍳5"))
  (list 1 2 3 4 5))
 (apl-test
  "apl-run \"-3\" → -3 (monadic negate)"
  (mkrv (apl-run "-3"))
  (list -3))
 (apl-test
  "apl-run \"⌈/ 1 3 9 5 7\" → 9 (max-reduce)"
  (mkrv (apl-run "⌈/ 1 3 9 5 7"))
  (list 9))
 (apl-test
  "apl-run \"⌊/ 4 7 2 9 1 3\" → 1 (min-reduce)"
  (mkrv (apl-run "⌊/ 4 7 2 9 1 3"))
  (list 1))
 ; ---------- operators ----------
 (apl-test "apl-run \"+/⍳5\" → 15" (mkrv (apl-run "+/⍳5")) (list 15))
 (apl-test "apl-run \"×/⍳5\" → 120" (mkrv (apl-run "×/⍳5")) (list 120))
 (apl-test
  "apl-run \"⌈/3 1 4 1 5 9 2\" → 9"
  (mkrv (apl-run "⌈/3 1 4 1 5 9 2"))
  (list 9))
 (apl-test
  "apl-run \"+\\\\⍳5\" → triangular numbers"
  (mkrv (apl-run "+\\⍳5"))
  (list 1 3 6 10 15))
 ; ---------- outer / inner products ----------
 (apl-test
  "apl-run \"1 2 3 ∘.× 1 2 3\" → mult table values"
  (mkrv (apl-run "1 2 3 ∘.× 1 2 3"))
  (list 1 2 3 2 4 6 3 6 9))
 (apl-test
  "apl-run \"1 2 3 +.× 4 5 6\" → dot product 32"
  (mkrv (apl-run "1 2 3 +.× 4 5 6"))
  (list 32))
 ; ---------- shape ----------
 (apl-test
  "apl-run \"⍴ 1 2 3 4 5\" → 5"
  (mkrv (apl-run "⍴ 1 2 3 4 5"))
  (list 5))
 (apl-test "apl-run \"⍴⍳10\" → 10" (mkrv (apl-run "⍴⍳10")) (list 10))
 ; ---------- comparison ----------
 (apl-test "apl-run \"3 < 5\" → 1" (mkrv (apl-run "3 < 5")) (list 1))
 (apl-test "apl-run \"5 = 5\" → 1" (mkrv (apl-run "5 = 5")) (list 1))
 (apl-test
  "apl-run \"1 2 3 = 1 0 3\" → 1 0 1"
  (mkrv (apl-run "1 2 3 = 1 0 3"))
  (list 1 0 1))
 ; ---------- famous one-liners ----------
 (apl-test
  "apl-run \"+/(⍳10)\" → sum 1..10 = 55"
  (mkrv (apl-run "+/(⍳10)"))
  (list 55))
 (apl-test
  "apl-run \"×/⍳10\" → 10! = 3628800"
  (mkrv (apl-run "×/⍳10"))
  (list 3628800))
 (apl-test "apl-run \"⎕IO\" → 1" (mkrv (apl-run "⎕IO")) (list 1))
 (apl-test "apl-run \"⎕ML\" → 1" (mkrv (apl-run "⎕ML")) (list 1))
 (apl-test "apl-run \"⎕FR\" → 1248" (mkrv (apl-run "⎕FR")) (list 1248))
 (apl-test "apl-run \"⎕TS\" shape (7)" (mksh (apl-run "⎕TS")) (list 7))
 (apl-test "apl-run \"⎕FMT 42\" → \"42\"" (apl-run "⎕FMT 42") "42")
 (apl-test
  "apl-run \"⎕FMT 1 2 3\" → \"1 2 3\""
  (apl-run "⎕FMT 1 2 3")
  "1 2 3")
 (apl-test
  "apl-run \"⎕FMT ⍳5\" → \"1 2 3 4 5\""
  (apl-run "⎕FMT ⍳5")
  "1 2 3 4 5")
 (apl-test "apl-run \"⎕IO + 4\" → 5" (mkrv (apl-run "⎕IO + 4")) (list 5))
 (apl-test
  "apl-run \"(10 20 30 40 50)[3]\" → 30"
  (mkrv (apl-run "(10 20 30 40 50)[3]"))
  (list 30))
 (apl-test
  "apl-run \"(⍳10)[5]\" → 5"
  (mkrv (apl-run "(⍳10)[5]"))
  (list 5))
 (apl-test
  "apl-run \"A ← 100 200 300 ⋄ A[2]\" → 200"
  (mkrv (apl-run "A ← 100 200 300 ⋄ A[2]"))
  (list 200))
 (apl-test
  "apl-run \"V ← ⍳10 ⋄ V[3]\" → 3"
  (mkrv (apl-run "V ← ⍳10 ⋄ V[3]"))
  (list 3))
 (apl-test
  "apl-run \"(10 20 30)[1]\" → 10 (1-indexed)"
  (mkrv (apl-run "(10 20 30)[1]"))
  (list 10))
 (apl-test
  "apl-run \"V ← 10 20 30 40 50 ⋄ V[3] + 1\" → 31"
  (mkrv (apl-run "V ← 10 20 30 40 50 ⋄ V[3] + 1"))
  (list 31))
 (apl-test
  "apl-run \"(⍳5)[3] × 7\" → 21"
  (mkrv (apl-run "(⍳5)[3] × 7"))
  (list 21))
 (apl-test "decimal: 3.7 → 3.7" (mkrv (apl-run "3.7")) (list 3.7))
 (apl-test "decimal: ¯2.5 → -2.5" (mkrv (apl-run "¯2.5")) (list -2.5))
 (apl-test "decimal: 1.5 + 2.5 → 4" (mkrv (apl-run "1.5 + 2.5")) (list 4))
 (apl-test "decimal: ⌊3.7 → 3" (mkrv (apl-run "⌊ 3.7")) (list 3))
 (apl-test "decimal: ⌈3.7 → 4" (mkrv (apl-run "⌈ 3.7")) (list 4))
 (apl-test
  "⎕← scalar passthrough"
  (mkrv (apl-run "⎕← 42"))
  (list 42))
 (apl-test
  "⎕← vector passthrough"
  (mkrv (apl-run "⎕← 1 2 3"))
  (list 1 2 3))
 (apl-test
  "string: 'abc' → 3-char vector"
  (mkrv (apl-run "'abc'"))
  (list "a" "b" "c"))
 (apl-test "string: 'a' is rank-0 scalar" (mksh (apl-run "'a'")) (list))
 (apl-test "string: 'hello' shape (5)" (mksh (apl-run "'hello'")) (list 5))
 (apl-test
  "named-fn: f ← {⍺+⍵} ⋄ 3 f 4 → 7"
  (mkrv (apl-run "f ← {⍺+⍵} ⋄ 3 f 4"))
  (list 7))
 (apl-test
  "named-fn monadic: sq ← {⍵×⍵} ⋄ sq 7 → 49"
  (mkrv (apl-run "sq ← {⍵×⍵} ⋄ sq 7"))
  (list 49))
 (apl-test
  "named-fn dyadic: hyp ← {((⍺×⍺)+⍵×⍵)} ⋄ 3 hyp 4 → 25"
  (mkrv (apl-run "hyp ← {((⍺×⍺)+⍵×⍵)} ⋄ 3 hyp 4"))
  (list 25))
 (apl-test
  "named-fn: dbl ← {⍵+⍵} ⋄ dbl ⍳5"
  (mkrv (apl-run "dbl ← {⍵+⍵} ⋄ dbl ⍳5"))
  (list 2 4 6 8 10))
 (apl-test
  "named-fn factorial via ∇ recursion"
  (mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 5"))
  (list 120))
 (apl-test
  "named-fn used twice in expr: dbl ← {⍵+⍵} ⋄ (dbl 3) + dbl 4"
  (mkrv (apl-run "dbl ← {⍵+⍵} ⋄ (dbl 3) + dbl 4"))
  (list 14))
 (apl-test
  "named-fn with vector arg: neg ← {-⍵} ⋄ neg 1 2 3"
  (mkrv (apl-run "neg ← {-⍵} ⋄ neg 1 2 3"))
  (list -1 -2 -3))
 (apl-test
  "multi-axis: M[2;2] → center"
  (mkrv (apl-run "M ← (3 3) ⍴ ⍳9 ⋄ M[2;2]"))
  (list 5))
 (apl-test
  "multi-axis: M[1;] → first row"
  (mkrv (apl-run "M ← (3 3) ⍴ ⍳9 ⋄ M[1;]"))
  (list 1 2 3))
 (apl-test
  "multi-axis: M[;2] → second column"
  (mkrv (apl-run "M ← (3 3) ⍴ ⍳9 ⋄ M[;2]"))
  (list 2 5 8))
 (apl-test
  "multi-axis: M[1 2;1 2] → 2x2 block"
  (mkrv (apl-run "M ← (2 3) ⍴ ⍳6 ⋄ M[1 2;1 2]"))
  (list 1 2 4 5))
 (apl-test
  "multi-axis: M[1 2;1 2] shape (2 2)"
  (mksh (apl-run "M ← (2 3) ⍴ ⍳6 ⋄ M[1 2;1 2]"))
  (list 2 2))
 (apl-test
  "multi-axis: M[;] full matrix"
  (mkrv (apl-run "M ← (2 2) ⍴ 10 20 30 40 ⋄ M[;]"))
  (list 10 20 30 40))
 (apl-test
  "multi-axis: M[1;] shape collapsed"
  (mksh (apl-run "M ← (3 3) ⍴ ⍳9 ⋄ M[1;]"))
  (list 3))
 (apl-test
  "multi-axis: select all rows of column 3"
  (mkrv (apl-run "M ← (4 3) ⍴ 1 2 3 4 5 6 7 8 9 10 11 12 ⋄ M[;3]"))
  (list 3 6 9 12))
 (apl-test
  "train: mean = (+/÷≢) on 1..5"
  (mkrv (apl-run "(+/÷≢) 1 2 3 4 5"))
  (list 3))
 (apl-test
  "train: mean of 2 4 6 8 10"
  (mkrv (apl-run "(+/÷≢) 2 4 6 8 10"))
  (list 6))
 (apl-test
  "train 2-atop: (- ⌊) 5 → -5"
  (mkrv (apl-run "(- ⌊) 5"))
  (list -5))
 (apl-test
  "train 3-fork dyadic: 2(+×-)5 → -21"
  (mkrv (apl-run "2 (+ × -) 5"))
  (list -21))
 (apl-test
  "train: range = (⌈/-⌊/) on vector"
  (mkrv (apl-run "(⌈/-⌊/) 3 1 4 1 5 9 2 6"))
  (list 8))
 (apl-test
  "train: mean of ⍳10 has shape ()"
  (mksh (apl-run "(+/÷≢) ⍳10"))
  (list))
--- a/lib/apl/tests/programs-e2e.sx
+++ b/lib/apl/tests/programs-e2e.sx
@@ -0,0 +1,96 @@
 ; End-to-end tests of the classic-program archetypes — running APL
 ; source through the full pipeline (tokenize → parse → eval-ast → runtime).
 ;
 ; These mirror the algorithms documented in lib/apl/tests/programs/*.apl
 ; but use forms our pipeline supports today (named functions instead of
 ; the inline ⍵← rebinding idiom; multi-stmt over single one-liners).
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 ; ---------- factorial via ∇ recursion (cf. n-queens style) ----------
 (apl-test
  "e2e: factorial 5! = 120"
  (mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 5"))
  (list 120))
 (apl-test
  "e2e: factorial 7! = 5040"
  (mkrv (apl-run "fact ← {0=⍵:1 ⋄ ⍵×∇⍵-1} ⋄ fact 7"))
  (list 5040))
 (apl-test
  "e2e: factorial via ×/⍳N (no recursion)"
  (mkrv (apl-run "fact ← {×/⍳⍵} ⋄ fact 6"))
  (list 720))
 ; ---------- sum / triangular numbers (sum-1..N) ----------
 (apl-test
  "e2e: triangular(10) = 55"
  (mkrv (apl-run "tri ← {+/⍳⍵} ⋄ tri 10"))
  (list 55))
 (apl-test
  "e2e: triangular(100) = 5050"
  (mkrv (apl-run "tri ← {+/⍳⍵} ⋄ tri 100"))
  (list 5050))
 ; ---------- sum of squares ----------
 (apl-test
  "e2e: sum-of-squares 1..5 = 55"
  (mkrv (apl-run "ss ← {+/⍵×⍵} ⋄ ss ⍳5"))
  (list 55))
 (apl-test
  "e2e: sum-of-squares 1..10 = 385"
  (mkrv (apl-run "ss ← {+/⍵×⍵} ⋄ ss ⍳10"))
  (list 385))
 ; ---------- divisor-counting (prime-sieve building blocks) ----------
 (apl-test
  "e2e: divisor counts 1..5 via outer mod"
  (mkrv (apl-run "P ← ⍳ 5 ⋄ +⌿ 0 = P ∘.| P"))
  (list 1 2 2 3 2))
 (apl-test
  "e2e: divisor counts 1..10"
  (mkrv (apl-run "P ← ⍳ 10 ⋄ +⌿ 0 = P ∘.| P"))
  (list 1 2 2 3 2 4 2 4 3 4))
 (apl-test
  "e2e: prime-mask 1..10 (count==2)"
  (mkrv (apl-run "P ← ⍳ 10 ⋄ 2 = +⌿ 0 = P ∘.| P"))
  (list 0 1 1 0 1 0 1 0 0 0))
 ; ---------- monadic primitives chained ----------
 (apl-test
  "e2e: sum of |abs| = 15"
  (mkrv (apl-run "+/|¯1 ¯2 ¯3 ¯4 ¯5"))
  (list 15))
 (apl-test
  "e2e: max of squares 1..6"
  (mkrv (apl-run "⌈/(⍳6)×⍳6"))
  (list 36))
 ; ---------- nested named functions ----------
 (apl-test
  "e2e: compose dbl and sq via two named fns"
  (mkrv (apl-run "dbl ← {⍵+⍵} ⋄ sq ← {⍵×⍵} ⋄ sq dbl 3"))
  (list 36))
 (apl-test
  "e2e: max-of-two as named dyadic fn"
  (mkrv (apl-run "mx ← {⍺⌈⍵} ⋄ 5 mx 3"))
  (list 5))
 (apl-test
  "e2e: sqrt-via-newton 1 step from 1 → 2.5"
  (mkrv (apl-run "step ← {(⍵+⍺÷⍵)÷2} ⋄ 4 step 1"))
  (list 2.5))
--- a/lib/apl/tests/programs.sx
+++ b/lib/apl/tests/programs.sx
@@ -0,0 +1,306 @@
 ; Tests for classic APL programs (lib/apl/tests/programs/*.apl).
 ; Programs are showcase APL source; runtime impl is in lib/apl/runtime.sx.
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 ; ===== primes (Sieve of Eratosthenes) =====
 (apl-test "primes 1 → empty" (mkrv (apl-primes 1)) (list))
 (apl-test "primes 2 → just 2" (mkrv (apl-primes 2)) (list 2))
 (apl-test "primes 10 → 2 3 5 7" (mkrv (apl-primes 10)) (list 2 3 5 7))
 (apl-test
  "primes 20 → 2 3 5 7 11 13 17 19"
  (mkrv (apl-primes 20))
  (list 2 3 5 7 11 13 17 19))
 (apl-test
  "primes 30"
  (mkrv (apl-primes 30))
  (list 2 3 5 7 11 13 17 19 23 29))
 (apl-test
  "primes 50"
  (mkrv (apl-primes 50))
  (list 2 3 5 7 11 13 17 19 23 29 31 37 41 43 47))
 (apl-test "primes 7 length" (first (mksh (apl-primes 7))) 4)
 (apl-test "primes 100 has 25 primes" (first (mksh (apl-primes 100))) 25)
 ; ===== compress helper sanity =====
 (apl-test
  "compress 1 0 1 0 1 / 10 20 30 40 50"
  (mkrv
    (apl-compress
      (make-array (list 5) (list 1 0 1 0 1))
      (make-array (list 5) (list 10 20 30 40 50))))
  (list 10 30 50))
 (apl-test
  "compress all-zero mask → empty"
  (mkrv
    (apl-compress
      (make-array (list 3) (list 0 0 0))
      (make-array (list 3) (list 1 2 3))))
  (list))
 (apl-test
  "compress all-one mask → full vector"
  (mkrv
    (apl-compress
      (make-array (list 3) (list 1 1 1))
      (make-array (list 3) (list 1 2 3))))
  (list 1 2 3))
 (apl-test
  "life: empty 5x5 stays empty"
  (mkrv
    (apl-life-step
      (make-array
        (list 5 5)
        (list 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0))))
  (list 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0))
 (apl-test
  "life: horizontal blinker → vertical blinker"
  (mkrv
    (apl-life-step
      (make-array
        (list 5 5)
        (list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))))
  (list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0))
 (apl-test
  "life: vertical blinker → horizontal blinker"
  (mkrv
    (apl-life-step
      (make-array
        (list 5 5)
        (list 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0))))
  (list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))
 (apl-test
  "life: blinker has period 2"
  (mkrv
    (apl-life-step
      (apl-life-step
        (make-array
          (list 5 5)
          (list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0)))))
  (list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))
 (apl-test
  "life: 2x2 block stable on 5x5"
  (mkrv
    (apl-life-step
      (make-array
        (list 5 5)
        (list 0 0 0 0 0 0 1 1 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0))))
  (list 0 0 0 0 0 0 1 1 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0))
 (apl-test
  "life: shape preserved"
  (mksh
    (apl-life-step
      (make-array
        (list 5 5)
        (list 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0))))
  (list 5 5))
 (apl-test
  "life: glider on 6x6 advances"
  (mkrv
    (apl-life-step
      (make-array
        (list 6 6)
        (list
          0
          0
          0
          0
          0
          0
          0
          0
          1
          0
          0
          0
          0
          0
          0
          1
          0
          0
          0
          1
          1
          1
          0
          0
          0
          0
          0
          0
          0
          0
          0
          0
          0
          0
          0
          0))))
  (list
    0
    0
    0
    0
    0
    0
    0
    0
    0
    0
    0
    0
    0
    1
    0
    1
    0
    0
    0
    0
    1
    1
    0
    0
    0
    0
    1
    0
    0
    0
    0
    0
    0
    0
    0
    0))
 (apl-test
  "mandelbrot c=0 stays bounded"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0)) 100))
  (list 100))
 (apl-test
  "mandelbrot c=-1 cycle bounded"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list -1)) 100))
  (list 100))
 (apl-test
  "mandelbrot c=-2 boundary stays bounded"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list -2)) 100))
  (list 100))
 (apl-test
  "mandelbrot c=0.25 boundary stays bounded"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0.25)) 100))
  (list 100))
 (apl-test
  "mandelbrot c=1 escapes at iter 3"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list 1)) 100))
  (list 3))
 (apl-test
  "mandelbrot c=0.5 escapes at iter 5"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list 0.5)) 100))
  (list 5))
 (apl-test
  "mandelbrot batched grid (rank-polymorphic)"
  (mkrv (apl-mandelbrot-1d (make-array (list 5) (list -2 -1 0 1 2)) 10))
  (list 10 10 10 3 2))
 (apl-test
  "mandelbrot batched preserves shape"
  (mksh (apl-mandelbrot-1d (make-array (list 5) (list -2 -1 0 1 2)) 10))
  (list 5))
 (apl-test
  "mandelbrot c=-1.5 stays bounded"
  (mkrv (apl-mandelbrot-1d (make-array (list 1) (list -1.5)) 100))
  (list 100))
 (apl-test "queens 1 → 1 solution" (mkrv (apl-queens 1)) (list 1))
 (apl-test "queens 2 → 0 solutions" (mkrv (apl-queens 2)) (list 0))
 (apl-test "queens 3 → 0 solutions" (mkrv (apl-queens 3)) (list 0))
 (apl-test "queens 4 → 2 solutions" (mkrv (apl-queens 4)) (list 2))
 (apl-test "queens 5 → 10 solutions" (mkrv (apl-queens 5)) (list 10))
 (apl-test "queens 6 → 4 solutions" (mkrv (apl-queens 6)) (list 4))
 (apl-test "queens 7 → 40 solutions" (mkrv (apl-queens 7)) (list 40))
 (apl-test "queens 8 → 92 solutions" (mkrv (apl-queens 8)) (list 92))
 (apl-test "permutations of 3 has 6" (len (apl-permutations 3)) 6)
 (apl-test "permutations of 4 has 24" (len (apl-permutations 4)) 24)
 (apl-test
  "quicksort empty"
  (mkrv (apl-quicksort (make-array (list 0) (list))))
  (list))
 (apl-test
  "quicksort single"
  (mkrv (apl-quicksort (make-array (list 1) (list 42))))
  (list 42))
 (apl-test
  "quicksort already sorted"
  (mkrv (apl-quicksort (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3 4 5))
 (apl-test
  "quicksort reverse sorted"
  (mkrv (apl-quicksort (make-array (list 5) (list 5 4 3 2 1))))
  (list 1 2 3 4 5))
 (apl-test
  "quicksort with duplicates"
  (mkrv (apl-quicksort (make-array (list 7) (list 3 1 4 1 5 9 2))))
  (list 1 1 2 3 4 5 9))
 (apl-test
  "quicksort all equal"
  (mkrv (apl-quicksort (make-array (list 5) (list 7 7 7 7 7))))
  (list 7 7 7 7 7))
 (apl-test
  "quicksort negatives"
  (mkrv (apl-quicksort (make-array (list 5) (list -3 1 -1 2 0))))
  (list -3 -1 0 1 2))
 (apl-test
  "quicksort 11-element pi"
  (mkrv
    (apl-quicksort (make-array (list 11) (list 3 1 4 1 5 9 2 6 5 3 5))))
  (list 1 1 2 3 3 4 5 5 5 6 9))
 (apl-test
  "quicksort preserves length"
  (first
    (mksh (apl-quicksort (make-array (list 7) (list 3 1 4 1 5 9 2)))))
  7)
--- a/lib/apl/tests/programs/life.apl
+++ b/lib/apl/tests/programs/life.apl
@@ -0,0 +1,22 @@
 ⍝ Conway's Game of Life — toroidal one-liner
 ⍝
 ⍝ The classic Roger Hui formulation:
 ⍝   life ← {⊃1 ⍵ ∨.∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵}
 ⍝
 ⍝ Read right-to-left:
 ⍝   ⊂⍵                : enclose the board (so it's a single scalar item)
 ⍝   ¯1 0 1 ⌽¨ ⊂⍵      : produce 3 horizontally-shifted copies
 ⍝   ¯1 0 1 ∘.⊖ …      : outer-product with vertical shifts → 3×3 = 9 shifts
 ⍝   +/ +/ …           : sum the 9 boards element-wise → neighbor-count + self
 ⍝   3 4 = …           : boolean — count is exactly 3 or exactly 4
 ⍝   1 ⍵ ∨.∧ …         : "alive next" iff (count=3) or (alive AND count=4)
 ⍝   ⊃ …               : disclose back to a 2D board
 ⍝
 ⍝ Rules in plain language:
 ⍝   - dead cell + 3 live neighbors → born
 ⍝   - live cell + 2 or 3 live neighbors → survives
 ⍝   - all else → dies
 ⍝
 ⍝ Toroidal: edges wrap (rotate is cyclic).
 life ← {⊃1 ⍵ ∨.∧ 3 4 = +/ +/ ¯1 0 1 ∘.⊖ ¯1 0 1 ⌽¨ ⊂⍵}
--- a/lib/apl/tests/programs/mandelbrot.apl
+++ b/lib/apl/tests/programs/mandelbrot.apl
@@ -0,0 +1,29 @@
 ⍝ Mandelbrot — real-axis subset
 ⍝
 ⍝ For complex c, the Mandelbrot set is { c : |z_n| stays bounded } where
 ⍝   z_0 = 0, z_{n+1} = z_n² + c.
 ⍝ Restricting c (and z) to ℝ gives the segment c ∈ [-2, 1/4]
 ⍝ where the iteration stays bounded.
 ⍝
 ⍝ Rank-polymorphic batched-iteration form:
 ⍝   mandelbrot ← {⍵ ⍵⍵ ⍺⍺ +,(⍺⍺ × ⍺⍺) }
 ⍝
 ⍝ Pseudocode (as we don't have ⎕ system fns yet):
 ⍝   z      ← 0×c                             ⍝ start at zero
 ⍝   alive  ← 1+0×c                           ⍝ all "still in"
 ⍝   for k iterations:
 ⍝     alive ← alive ∧ 4 ≥ z×z                ⍝ still bounded?
 ⍝     z     ← alive × c + z×z                ⍝ freeze escaped via mask
 ⍝     count ← count + alive                  ⍝ tally surviving iters
 ⍝
 ⍝ Examples (count after 100 iterations):
 ⍝   c=0      : 100  (z stays at 0)
 ⍝   c=-1     : 100  (cycles 0,-1,0,-1,...)
 ⍝   c=-2     : 100  (settles at 2 — boundary)
 ⍝   c=0.25   : 100  (boundary — converges to 0.5)
 ⍝   c=0.5    : 5    (escapes by iteration 6)
 ⍝   c=1      : 3    (escapes quickly)
 ⍝
 ⍝ Real-axis Mandelbrot set: bounded for c ∈ [-2, 0.25].
 mandelbrot ← {z←alive←count←0×⍵ ⋄ {alive←alive∧4≥z×z ⋄ z←alive×⍵+z×z ⋄ count+←alive}⍣⍺⊢⍵}
--- a/lib/apl/tests/programs/n-queens.apl
+++ b/lib/apl/tests/programs/n-queens.apl
@@ -0,0 +1,18 @@
 ⍝ N-Queens — count solutions to placing N non-attacking queens on N×N
 ⍝
 ⍝ A solution is encoded as a permutation P of 1..N where P[i] is the
 ⍝ column of the queen in row i.  Rows and columns are then automatically
 ⍝ unique (it's a permutation).  We must additionally rule out queens
 ⍝ sharing a diagonal: |i-j| = |P[i]-P[j]| for any pair.
 ⍝
 ⍝ Backtracking via reduce — the classic Roger Hui style:
 ⍝   queens ← {≢{⍵,¨⍨↓(0=∊(¨⍳⍴⍵)≠.+|⍵)/⍳⍴⍵}/(⍳⍵)⍴⊂⍳⍵}
 ⍝
 ⍝ Plain reading:
 ⍝   permute 1..N, keep those where no two queens share a diagonal.
 ⍝
 ⍝ Known solution counts (OEIS A000170):
 ⍝     N    1   2   3   4   5   6   7    8    9    10
 ⍝   q(N)   1   0   0   2  10   4  40   92  352   724
 queens ← {≢({(i j)←⍺⍵ ⋄ (|i-j)≠|(P[i])-(P[j])}⌿permutations ⍵)}
--- a/lib/apl/tests/programs/primes.apl
+++ b/lib/apl/tests/programs/primes.apl
@@ -0,0 +1,16 @@
 ⍝ Sieve of Eratosthenes — the classic APL one-liner
 ⍝   primes ← (2=+⌿0=A∘.|A)/A←⍳N
 ⍝
 ⍝ Read right-to-left:
 ⍝   A ← ⍳N        : A is 1..N
 ⍝   A∘.|A         : outer-product residue table — M[i,j] = A[j] mod A[i]
 ⍝   0=...         : boolean — true where A[i] divides A[j]
 ⍝   +⌿...         : column sums — count of divisors per A[j]
 ⍝   2=...         : true for numbers with exactly 2 divisors (1 and self) → primes
 ⍝   .../A         : compress — select A[j] where mask[j] is true
 ⍝
 ⍝ Examples:
 ⍝   primes 10  →  2 3 5 7
 ⍝   primes 30  →  2 3 5 7 11 13 17 19 23 29
 primes ← {(2=+⌿0=⍵∘.|⍵)/⍵←⍳⍵}
--- a/lib/apl/tests/programs/quicksort.apl
+++ b/lib/apl/tests/programs/quicksort.apl
@@ -0,0 +1,25 @@
 ⍝ Quicksort — the classic Roger Hui one-liner
 ⍝
 ⍝ Q ← {1≥≢⍵:⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p←⍵⌷⍨?≢⍵}
 ⍝
 ⍝ Read right-to-left:
 ⍝   ?≢⍵          : pick a random index in 1..length
 ⍝   ⍵⌷⍨…         : take that element as pivot p
 ⍝   ⍵>p          : boolean — elements greater than pivot
 ⍝   ∇⍵⌿⍨…        : recursively sort the > partition
 ⍝   (p=⍵)/⍵      : keep elements equal to pivot
 ⍝   ⍵<p          : boolean — elements less than pivot
 ⍝   ∇⍵⌿⍨…        : recursively sort the < partition
 ⍝   ,            : catenate ⟨less⟩ ⟨equal⟩ ⟨greater⟩
 ⍝   1≥≢⍵:⍵       : guard — base case for length ≤ 1
 ⍝
 ⍝ Stability: not stable on duplicates (but eq-class is preserved as a block).
 ⍝ Worst case O(N²) on already-sorted input with deterministic pivot;
 ⍝ randomized pivot selection gives expected O(N log N).
 ⍝
 ⍝ Examples:
 ⍝   Q 3 1 4 1 5 9 2 6 5 3 5    →  1 1 2 3 3 4 5 5 5 6 9
 ⍝   Q ⍳0                        →  ⍬   (empty)
 ⍝   Q ,42                       →  42
 quicksort ← {1≥≢⍵:⍵ ⋄ p←⍵⌷⍨?≢⍵ ⋄ (∇⍵⌿⍨⍵<p),(p=⍵)/⍵,∇⍵⌿⍨⍵>p}
--- a/lib/apl/tests/scalar.sx
+++ b/lib/apl/tests/scalar.sx
@@ -0,0 +1,369 @@
 ; APL scalar primitives test suite
 ; Requires: lib/apl/runtime.sx
 ; ============================================================
 ; Test framework
 ; ============================================================
 (define apl-rt-count 0)
 (define apl-rt-pass 0)
 (define apl-rt-fails (list))
 ; Element-wise list comparison (handles both List and ListRef)
 (define
  lists-eq
  (fn
    (a b)
    (if
      (and (= (len a) 0) (= (len b) 0))
      true
      (if
        (not (= (len a) (len b)))
        false
        (if
          (not (= (first a) (first b)))
          false
          (lists-eq (rest a) (rest b)))))))
 (define
  apl-rt-test
  (fn
    (name actual expected)
    (begin
      (set! apl-rt-count (+ apl-rt-count 1))
      (if
        (equal? actual expected)
        (set! apl-rt-pass (+ apl-rt-pass 1))
        (append! apl-rt-fails {:actual actual :expected expected :name name})))))
 ; Test that a ravel equals a plain list (handles ListRef vs List)
 (define
  ravel-test
  (fn
    (name arr expected-list)
    (begin
      (set! apl-rt-count (+ apl-rt-count 1))
      (let
        ((actual (get arr :ravel)))
        (if
          (lists-eq actual expected-list)
          (set! apl-rt-pass (+ apl-rt-pass 1))
          (append! apl-rt-fails {:actual actual :expected expected-list :name name}))))))
 ; Test a scalar ravel value (single-element list)
 (define
  scalar-test
  (fn (name arr expected-val) (ravel-test name arr (list expected-val))))
 ; ============================================================
 ; Array constructor tests
 ; ============================================================
 (apl-rt-test
  "scalar: shape is empty list"
  (get (apl-scalar 5) :shape)
  (list))
 (apl-rt-test
  "scalar: ravel has one element"
  (get (apl-scalar 5) :ravel)
  (list 5))
 (apl-rt-test "scalar: rank 0" (array-rank (apl-scalar 5)) 0)
 (apl-rt-test "scalar? returns true for scalar" (scalar? (apl-scalar 5)) true)
 (apl-rt-test "scalar: zero" (get (apl-scalar 0) :ravel) (list 0))
 (apl-rt-test
  "vector: shape is (3)"
  (get (apl-vector (list 1 2 3)) :shape)
  (list 3))
 (apl-rt-test
  "vector: ravel matches input"
  (get (apl-vector (list 1 2 3)) :ravel)
  (list 1 2 3))
 (apl-rt-test "vector: rank 1" (array-rank (apl-vector (list 1 2 3))) 1)
 (apl-rt-test
  "scalar? returns false for vector"
  (scalar? (apl-vector (list 1 2 3)))
  false)
 (apl-rt-test
  "make-array: rank 2"
  (array-rank (make-array (list 2 3) (list 1 2 3 4 5 6)))
  2)
 (apl-rt-test
  "make-array: shape"
  (get (make-array (list 2 3) (list 1 2 3 4 5 6)) :shape)
  (list 2 3))
 (apl-rt-test
  "array-ref: first element"
  (array-ref (apl-vector (list 10 20 30)) 0)
  10)
 (apl-rt-test
  "array-ref: last element"
  (array-ref (apl-vector (list 10 20 30)) 2)
  30)
 (apl-rt-test "enclose: wraps in rank-0" (scalar? (enclose 42)) true)
 (apl-rt-test
  "enclose: ravel contains value"
  (get (enclose 42) :ravel)
  (list 42))
 (apl-rt-test "disclose: unwraps rank-0" (disclose (enclose 42)) 42)
 ; ============================================================
 ; Shape primitive tests
 ; ============================================================
 (ravel-test "⍴ scalar: returns empty" (apl-shape (apl-scalar 5)) (list))
 (ravel-test
  "⍴ vector: returns (3)"
  (apl-shape (apl-vector (list 1 2 3)))
  (list 3))
 (ravel-test
  "⍴ matrix: returns (2 3)"
  (apl-shape (make-array (list 2 3) (list 1 2 3 4 5 6)))
  (list 2 3))
 (ravel-test
  ", ravel scalar: vector of 1"
  (apl-ravel (apl-scalar 5))
  (list 5))
 (apl-rt-test
  ", ravel vector: same elements"
  (get (apl-ravel (apl-vector (list 1 2 3))) :ravel)
  (list 1 2 3))
 (apl-rt-test
  ", ravel matrix: all elements"
  (get (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))) :ravel)
  (list 1 2 3 4 5 6))
 (scalar-test "≢ tally scalar: 1" (apl-tally (apl-scalar 5)) 1)
 (scalar-test
  "≢ tally vector: first dimension"
  (apl-tally (apl-vector (list 1 2 3)))
  3)
 (scalar-test
  "≢ tally matrix: first dimension"
  (apl-tally (make-array (list 2 3) (list 1 2 3 4 5 6)))
  2)
 (scalar-test
  "≡ depth flat vector: 0"
  (apl-depth (apl-vector (list 1 2 3)))
  0)
 (scalar-test "≡ depth scalar: 0" (apl-depth (apl-scalar 5)) 0)
 (scalar-test
  "≡ depth nested (enclose in vector): 1"
  (apl-depth (enclose (apl-vector (list 1 2 3))))
  1)
 ; ============================================================
 ; ⍳ iota tests
 ; ============================================================
 (apl-rt-test
  "⍳5 shape is (5)"
  (get (apl-iota (apl-scalar 5)) :shape)
  (list 5))
 (ravel-test "⍳5 ravel is 1..5" (apl-iota (apl-scalar 5)) (list 1 2 3 4 5))
 (ravel-test "⍳1 ravel is (1)" (apl-iota (apl-scalar 1)) (list 1))
 (ravel-test "⍳0 ravel is empty" (apl-iota (apl-scalar 0)) (list))
 (apl-rt-test "apl-io is 1" apl-io 1)
 ; ============================================================
 ; Arithmetic broadcast tests
 ; ============================================================
 (scalar-test
  "+ scalar scalar: 3+4=7"
  (apl-add (apl-scalar 3) (apl-scalar 4))
  7)
 (ravel-test
  "+ vector scalar: +10"
  (apl-add (apl-vector (list 1 2 3)) (apl-scalar 10))
  (list 11 12 13))
 (ravel-test
  "+ scalar vector: 10+"
  (apl-add (apl-scalar 10) (apl-vector (list 1 2 3)))
  (list 11 12 13))
 (ravel-test
  "+ vector vector"
  (apl-add (apl-vector (list 1 2 3)) (apl-vector (list 4 5 6)))
  (list 5 7 9))
 (scalar-test "- negate monadic" (apl-neg-m (apl-scalar 5)) -5)
 (scalar-test "- dyadic 10-3=7" (apl-sub (apl-scalar 10) (apl-scalar 3)) 7)
 (scalar-test "× signum positive" (apl-signum (apl-scalar 7)) 1)
 (scalar-test "× signum negative" (apl-signum (apl-scalar -3)) -1)
 (scalar-test "× signum zero" (apl-signum (apl-scalar 0)) 0)
 (scalar-test "× dyadic 3×4=12" (apl-mul (apl-scalar 3) (apl-scalar 4)) 12)
 (scalar-test "÷ reciprocal 1÷4=0.25" (apl-recip (apl-scalar 4)) 0.25)
 (scalar-test
  "÷ dyadic 10÷4=2.5"
  (apl-div (apl-scalar 10) (apl-scalar 4))
  2.5)
 (scalar-test "⌈ ceiling 2.3→3" (apl-ceil (apl-scalar 2.3)) 3)
 (scalar-test "⌈ max 3 5 → 5" (apl-max (apl-scalar 3) (apl-scalar 5)) 5)
 (scalar-test "⌊ floor 2.7→2" (apl-floor (apl-scalar 2.7)) 2)
 (scalar-test "⌊ min 3 5 → 3" (apl-min (apl-scalar 3) (apl-scalar 5)) 3)
 (scalar-test "* exp monadic e^0=1" (apl-exp (apl-scalar 0)) 1)
 (scalar-test
  "* pow dyadic 2^10=1024"
  (apl-pow (apl-scalar 2) (apl-scalar 10))
  1024)
 (scalar-test "⍟ ln 1=0" (apl-ln (apl-scalar 1)) 0)
 (scalar-test "| abs positive" (apl-abs (apl-scalar 5)) 5)
 (scalar-test "| abs negative" (apl-abs (apl-scalar -5)) 5)
 (scalar-test "| mod 3|7=1" (apl-mod (apl-scalar 3) (apl-scalar 7)) 1)
 (scalar-test "! factorial 5!=120" (apl-fact (apl-scalar 5)) 120)
 (scalar-test "! factorial 0!=1" (apl-fact (apl-scalar 0)) 1)
 (scalar-test
  "! binomial 4 choose 2 = 6"
  (apl-binomial (apl-scalar 4) (apl-scalar 2))
  6)
 (scalar-test "○ pi×0=0" (apl-pi-times (apl-scalar 0)) 0)
 (scalar-test "○ trig sin(0)=0" (apl-trig (apl-scalar 1) (apl-scalar 0)) 0)
 (scalar-test "○ trig cos(0)=1" (apl-trig (apl-scalar 2) (apl-scalar 0)) 1)
 ; ============================================================
 ; Comparison tests
 ; ============================================================
 (scalar-test "< less: 3<5 → 1" (apl-lt (apl-scalar 3) (apl-scalar 5)) 1)
 (scalar-test "< less: 5<3 → 0" (apl-lt (apl-scalar 5) (apl-scalar 3)) 0)
 (scalar-test
  "≤ le equal: 3≤3 → 1"
  (apl-le (apl-scalar 3) (apl-scalar 3))
  1)
 (scalar-test "= eq: 5=5 → 1" (apl-eq (apl-scalar 5) (apl-scalar 5)) 1)
 (scalar-test "= ne: 5=6 → 0" (apl-eq (apl-scalar 5) (apl-scalar 6)) 0)
 (scalar-test "≥ ge: 5≥3 → 1" (apl-ge (apl-scalar 5) (apl-scalar 3)) 1)
 (scalar-test "> gt: 5>3 → 1" (apl-gt (apl-scalar 5) (apl-scalar 3)) 1)
 (scalar-test "≠ ne: 5≠3 → 1" (apl-ne (apl-scalar 5) (apl-scalar 3)) 1)
 (ravel-test
  "comparison vector broadcast: 1 2 3 < 2 → 1 0 0"
  (apl-lt (apl-vector (list 1 2 3)) (apl-scalar 2))
  (list 1 0 0))
 ; ============================================================
 ; Logical tests
 ; ============================================================
 (scalar-test "~ not 0 → 1" (apl-not (apl-scalar 0)) 1)
 (scalar-test "~ not 1 → 0" (apl-not (apl-scalar 1)) 0)
 (ravel-test
  "~ not vector: 1 0 1 0 → 0 1 0 1"
  (apl-not (apl-vector (list 1 0 1 0)))
  (list 0 1 0 1))
 (scalar-test
  "∧ and 1∧1 → 1"
  (apl-and (apl-scalar 1) (apl-scalar 1))
  1)
 (scalar-test
  "∧ and 1∧0 → 0"
  (apl-and (apl-scalar 1) (apl-scalar 0))
  0)
 (scalar-test "∨ or 0∨1 → 1" (apl-or (apl-scalar 0) (apl-scalar 1)) 1)
 (scalar-test "∨ or 0∨0 → 0" (apl-or (apl-scalar 0) (apl-scalar 0)) 0)
 (scalar-test
  "⍱ nor 0⍱0 → 1"
  (apl-nor (apl-scalar 0) (apl-scalar 0))
  1)
 (scalar-test
  "⍱ nor 1⍱0 → 0"
  (apl-nor (apl-scalar 1) (apl-scalar 0))
  0)
 (scalar-test
  "⍲ nand 1⍲1 → 0"
  (apl-nand (apl-scalar 1) (apl-scalar 1))
  0)
 (scalar-test
  "⍲ nand 1⍲0 → 1"
  (apl-nand (apl-scalar 1) (apl-scalar 0))
  1)
 ; ============================================================
 ; plus-m identity test
 ; ============================================================
 (scalar-test "+ monadic identity: +5 → 5" (apl-plus-m (apl-scalar 5)) 5)
 ; ============================================================
 ; Summary
 ; ============================================================
 (define
  apl-scalar-summary
  (str
    "scalar "
    apl-rt-pass
    "/"
    apl-rt-count
    (if (= (len apl-rt-fails) 0) "" (str " FAILS: " apl-rt-fails))))
--- a/lib/apl/tests/structural.sx
+++ b/lib/apl/tests/structural.sx
@@ -0,0 +1,608 @@
 ;; lib/apl/tests/structural.sx — Phase 3: structural primitives
 ;; Tests for: apl-reshape, apl-ravel, apl-transpose, apl-transpose-dyadic
 ;; Loaded after runtime.sx; shares apl-test / apl-test-pass / apl-test-fail.
 (define rv (fn (arr) (get arr :ravel)))
 (define sh (fn (arr) (get arr :shape)))
 ;; ---------------------------------------------------------------------------
 ;; 1. Ravel (monadic ,)
 ;; ---------------------------------------------------------------------------
 (apl-test "ravel scalar" (rv (apl-ravel (apl-scalar 5))) (list 5))
 (apl-test
  "ravel vector"
  (rv (apl-ravel (make-array (list 3) (list 1 2 3))))
  (list 1 2 3))
 (apl-test
  "ravel matrix"
  (rv (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 3 4 5 6))
 (apl-test
  "ravel shape is rank-1"
  (sh (apl-ravel (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 6))
 ;; ---------------------------------------------------------------------------
 ;; 2. Reshape (dyadic ⍴)
 ;; ---------------------------------------------------------------------------
 (apl-test
  "reshape 2x3 ravel"
  (rv
    (apl-reshape
      (make-array (list 2) (list 2 3))
      (make-array (list 6) (list 1 2 3 4 5 6))))
  (list 1 2 3 4 5 6))
 (apl-test
  "reshape 2x3 shape"
  (sh
    (apl-reshape
      (make-array (list 2) (list 2 3))
      (make-array (list 6) (list 1 2 3 4 5 6))))
  (list 2 3))
 (apl-test
  "reshape cycle 6 from 1 2"
  (rv
    (apl-reshape
      (make-array (list 1) (list 6))
      (make-array (list 2) (list 1 2))))
  (list 1 2 1 2 1 2))
 (apl-test
  "reshape cycle 2x3 from 1 2"
  (rv
    (apl-reshape
      (make-array (list 2) (list 2 3))
      (make-array (list 2) (list 1 2))))
  (list 1 2 1 2 1 2))
 (apl-test
  "reshape scalar fill"
  (rv (apl-reshape (make-array (list 1) (list 4)) (apl-scalar 7)))
  (list 7 7 7 7))
 (apl-test
  "reshape truncate"
  (rv
    (apl-reshape
      (make-array (list 1) (list 3))
      (make-array (list 6) (list 10 20 30 40 50 60))))
  (list 10 20 30))
 (apl-test
  "reshape matrix to vector"
  (sh
    (apl-reshape
      (make-array (list 1) (list 6))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 6))
 (apl-test
  "reshape 2x2x3"
  (sh
    (apl-reshape
      (make-array (list 3) (list 2 2 3))
      (make-array (list 12) (range 1 13))))
  (list 2 2 3))
 (apl-test
  "reshape to empty"
  (rv
    (apl-reshape
      (make-array (list 1) (list 0))
      (make-array (list 3) (list 1 2 3))))
  (list))
 ;; ---------------------------------------------------------------------------
 ;; 3. Monadic transpose (⍉)
 ;; ---------------------------------------------------------------------------
 (apl-test
  "transpose scalar shape"
  (sh (apl-transpose (apl-scalar 99)))
  (list))
 (apl-test
  "transpose scalar ravel"
  (rv (apl-transpose (apl-scalar 99)))
  (list 99))
 (apl-test
  "transpose vector shape"
  (sh (apl-transpose (make-array (list 3) (list 3 1 4))))
  (list 3))
 (apl-test
  "transpose vector ravel"
  (rv (apl-transpose (make-array (list 3) (list 3 1 4))))
  (list 3 1 4))
 (apl-test
  "transpose 2x3 shape"
  (sh (apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3 2))
 (apl-test
  "transpose 2x3 ravel"
  (rv (apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 4 2 5 3 6))
 (apl-test
  "transpose 3x3"
  (rv (apl-transpose (make-array (list 3 3) (list 1 2 3 4 5 6 7 8 9))))
  (list 1 4 7 2 5 8 3 6 9))
 (apl-test
  "transpose 1x4 shape"
  (sh (apl-transpose (make-array (list 1 4) (list 1 2 3 4))))
  (list 4 1))
 (apl-test
  "transpose twice identity"
  (rv
    (apl-transpose
      (apl-transpose (make-array (list 2 3) (list 1 2 3 4 5 6)))))
  (list 1 2 3 4 5 6))
 (apl-test
  "transpose 3d shape"
  (sh (apl-transpose (make-array (list 2 3 4) (range 0 24))))
  (list 4 3 2))
 ;; ---------------------------------------------------------------------------
 ;; 4. Dyadic transpose (perm⍉arr)
 ;; ---------------------------------------------------------------------------
 (apl-test
  "dyadic-transpose identity"
  (rv
    (apl-transpose-dyadic
      (make-array (list 2) (list 1 2))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 3 4 5 6))
 (apl-test
  "dyadic-transpose swap 2x3"
  (rv
    (apl-transpose-dyadic
      (make-array (list 2) (list 2 1))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 4 2 5 3 6))
 (apl-test
  "dyadic-transpose swap shape"
  (sh
    (apl-transpose-dyadic
      (make-array (list 2) (list 2 1))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3 2))
 (apl-test
  "dyadic-transpose 3d shape"
  (sh
    (apl-transpose-dyadic
      (make-array (list 3) (list 2 1 3))
      (make-array (list 2 3 4) (range 0 24))))
  (list 3 2 4))
 (apl-test
  "take 3 from front"
  (rv (apl-take (apl-scalar 3) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3))
 (apl-test
  "take 0"
  (rv (apl-take (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
  (list))
 (apl-test
  "take -2 from back"
  (rv (apl-take (apl-scalar -2) (make-array (list 5) (list 1 2 3 4 5))))
  (list 4 5))
 (apl-test
  "take over-take pads with 0"
  (rv (apl-take (apl-scalar 7) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3 4 5 0 0))
 (apl-test
  "take matrix 1 row 2 cols shape"
  (sh
    (apl-take
      (make-array (list 2) (list 1 2))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2))
 (apl-test
  "take matrix 1 row 2 cols ravel"
  (rv
    (apl-take
      (make-array (list 2) (list 1 2))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2))
 (apl-test
  "take matrix negative row"
  (rv
    (apl-take
      (make-array (list 2) (list -1 3))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 4 5 6))
 (apl-test
  "drop 2 from front"
  (rv (apl-drop (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
  (list 3 4 5))
 (apl-test
  "drop -2 from back"
  (rv (apl-drop (apl-scalar -2) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3))
 (apl-test
  "drop all"
  (rv (apl-drop (apl-scalar 5) (make-array (list 5) (list 1 2 3 4 5))))
  (list))
 (apl-test
  "drop 0"
  (rv (apl-drop (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3 4 5))
 (apl-test
  "drop matrix 1 row shape"
  (sh
    (apl-drop
      (make-array (list 2) (list 1 0))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 3))
 (apl-test
  "drop matrix 1 row ravel"
  (rv
    (apl-drop
      (make-array (list 2) (list 1 0))
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 4 5 6))
 (apl-test
  "reverse vector"
  (rv (apl-reverse (make-array (list 5) (list 1 2 3 4 5))))
  (list 5 4 3 2 1))
 (apl-test
  "reverse scalar identity"
  (rv (apl-reverse (apl-scalar 42)))
  (list 42))
 (apl-test
  "reverse matrix last axis"
  (rv (apl-reverse (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 3 2 1 6 5 4))
 (apl-test
  "reverse-first matrix"
  (rv (apl-reverse-first (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 4 5 6 1 2 3))
 (apl-test
  "reverse-first vector identity"
  (rv (apl-reverse-first (make-array (list 4) (list 1 2 3 4))))
  (list 4 3 2 1))
 (apl-test
  "rotate vector left by 2"
  (rv (apl-rotate (apl-scalar 2) (make-array (list 5) (list 1 2 3 4 5))))
  (list 3 4 5 1 2))
 (apl-test
  "rotate vector right by 1 (negative)"
  (rv (apl-rotate (apl-scalar -1) (make-array (list 5) (list 1 2 3 4 5))))
  (list 5 1 2 3 4))
 (apl-test
  "rotate by 0 is identity"
  (rv (apl-rotate (apl-scalar 0) (make-array (list 5) (list 1 2 3 4 5))))
  (list 1 2 3 4 5))
 (apl-test
  "rotate matrix last axis"
  (rv
    (apl-rotate (apl-scalar 1) (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 2 3 1 5 6 4))
 (apl-test
  "rotate-first matrix"
  (rv
    (apl-rotate-first
      (apl-scalar 1)
      (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 4 5 6 1 2 3))
 (apl-test
  "cat v,v ravel"
  (rv
    (apl-catenate
      (make-array (list 3) (list 1 2 3))
      (make-array (list 2) (list 4 5))))
  (list 1 2 3 4 5))
 (apl-test
  "cat v,v shape"
  (sh
    (apl-catenate
      (make-array (list 3) (list 1 2 3))
      (make-array (list 2) (list 4 5))))
  (list 5))
 (apl-test
  "cat scalar,v"
  (rv (apl-catenate (apl-scalar 99) (make-array (list 3) (list 1 2 3))))
  (list 99 1 2 3))
 (apl-test
  "cat v,scalar"
  (rv (apl-catenate (make-array (list 3) (list 1 2 3)) (apl-scalar 99)))
  (list 1 2 3 99))
 (apl-test
  "cat matrix last-axis shape"
  (sh
    (apl-catenate
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 2 2) (list 7 8 9 10))))
  (list 2 5))
 (apl-test
  "cat matrix last-axis ravel"
  (rv
    (apl-catenate
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 2 2) (list 7 8 9 10))))
  (list 1 2 3 7 8 4 5 6 9 10))
 (apl-test
  "cat-first v,v shape"
  (sh
    (apl-catenate-first
      (make-array (list 3) (list 1 2 3))
      (make-array (list 2) (list 4 5))))
  (list 5))
 (apl-test
  "cat-first matrix shape"
  (sh
    (apl-catenate-first
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3 3) (list 11 12 13 14 15 16 17 18 19))))
  (list 5 3))
 (apl-test
  "cat-first matrix ravel"
  (rv
    (apl-catenate-first
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3 3) (list 11 12 13 14 15 16 17 18 19))))
  (list 1 2 3 4 5 6 11 12 13 14 15 16 17 18 19))
 (apl-test
  "squad scalar into vector"
  (rv
    (apl-squad (apl-scalar 2) (make-array (list 5) (list 10 20 30 40 50))))
  (list 20))
 (apl-test
  "squad first element"
  (rv (apl-squad (apl-scalar 1) (make-array (list 3) (list 10 20 30))))
  (list 10))
 (apl-test
  "squad last element"
  (rv
    (apl-squad (apl-scalar 5) (make-array (list 5) (list 10 20 30 40 50))))
  (list 50))
 (apl-test
  "squad fully specified matrix element"
  (rv
    (apl-squad
      (make-array (list 2) (list 2 3))
      (make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
  (list 7))
 (apl-test
  "squad partial row of matrix shape"
  (sh
    (apl-squad
      (apl-scalar 2)
      (make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
  (list 4))
 (apl-test
  "squad partial row of matrix ravel"
  (rv
    (apl-squad
      (apl-scalar 2)
      (make-array (list 3 4) (list 1 2 3 4 5 6 7 8 9 10 11 12))))
  (list 5 6 7 8))
 (apl-test
  "squad partial 3d slice shape"
  (sh (apl-squad (apl-scalar 1) (make-array (list 2 3 4) (range 1 25))))
  (list 3 4))
 (apl-test
  "grade-up basic"
  (rv (apl-grade-up (make-array (list 5) (list 3 1 4 1 5))))
  (list 2 4 1 3 5))
 (apl-test
  "grade-up shape"
  (sh (apl-grade-up (make-array (list 4) (list 4 1 3 2))))
  (list 4))
 (apl-test
  "grade-up no duplicates"
  (rv (apl-grade-up (make-array (list 4) (list 4 1 3 2))))
  (list 2 4 3 1))
 (apl-test
  "grade-up already sorted"
  (rv (apl-grade-up (make-array (list 3) (list 1 2 3))))
  (list 1 2 3))
 (apl-test
  "grade-up reverse sorted"
  (rv (apl-grade-up (make-array (list 3) (list 3 2 1))))
  (list 3 2 1))
 (apl-test
  "grade-down basic"
  (rv (apl-grade-down (make-array (list 5) (list 3 1 4 1 5))))
  (list 5 3 1 2 4))
 (apl-test
  "grade-down no duplicates"
  (rv (apl-grade-down (make-array (list 4) (list 4 1 3 2))))
  (list 1 3 4 2))
 (apl-test
  "grade-up single element"
  (rv (apl-grade-up (make-array (list 1) (list 42))))
  (list 1))
 (apl-test
  "enclose shape is scalar"
  (sh (apl-enclose (make-array (list 3) (list 1 2 3))))
  (list))
 (apl-test
  "enclose ravel length is 1"
  (len (rv (apl-enclose (make-array (list 3) (list 1 2 3)))))
  1)
 (apl-test
  "enclose inner ravel"
  (rv (first (rv (apl-enclose (make-array (list 3) (list 1 2 3))))))
  (list 1 2 3))
 (apl-test
  "disclose of enclose round-trips ravel"
  (rv (apl-disclose (apl-enclose (make-array (list 3) (list 10 20 30)))))
  (list 10 20 30))
 (apl-test
  "disclose of enclose round-trips shape"
  (sh (apl-disclose (apl-enclose (make-array (list 3) (list 10 20 30)))))
  (list 3))
 (apl-test
  "disclose scalar ravel"
  (rv (apl-disclose (apl-scalar 42)))
  (list 42))
 (apl-test
  "disclose vector ravel"
  (rv (apl-disclose (make-array (list 3) (list 5 6 7))))
  (list 5))
 (apl-test
  "disclose matrix returns first row"
  (rv (apl-disclose (make-array (list 2 3) (list 1 2 3 4 5 6))))
  (list 1 2 3))
 (apl-test
  "member basic"
  (rv
    (apl-member
      (make-array (list 3) (list 1 2 3))
      (make-array (list 2) (list 2 3))))
  (list 0 1 1))
 (apl-test
  "member all absent"
  (rv
    (apl-member
      (make-array (list 3) (list 4 5 6))
      (make-array (list 3) (list 1 2 3))))
  (list 0 0 0))
 (apl-test
  "member scalar"
  (rv (apl-member (apl-scalar 5) (make-array (list 3) (list 1 5 9))))
  (list 1))
 (apl-test
  "member shape preserved"
  (sh
    (apl-member
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3) (list 1 3 5))))
  (list 2 3))
 (apl-test
  "member matrix ravel"
  (rv
    (apl-member
      (make-array (list 2 3) (list 1 2 3 4 5 6))
      (make-array (list 3) (list 1 3 5))))
  (list 1 0 1 0 1 0))
 (apl-test
  "index-of basic"
  (rv
    (apl-index-of
      (make-array (list 4) (list 10 20 30 40))
      (make-array (list 3) (list 20 40 10))))
  (list 2 4 1))
 (apl-test
  "index-of not-found"
  (rv
    (apl-index-of
      (make-array (list 3) (list 1 2 3))
      (make-array (list 2) (list 5 2))))
  (list 4 2))
 (apl-test
  "index-of scalar right"
  (rv
    (apl-index-of (make-array (list 3) (list 10 20 30)) (apl-scalar 20)))
  (list 2))
 (apl-test
  "without basic"
  (rv
    (apl-without
      (make-array (list 5) (list 1 2 3 4 5))
      (make-array (list 2) (list 2 4))))
  (list 1 3 5))
 (apl-test
  "without shape"
  (sh
    (apl-without
      (make-array (list 5) (list 1 2 3 4 5))
      (make-array (list 2) (list 2 4))))
  (list 3))
 (apl-test
  "without nothing removed"
  (rv
    (apl-without
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 4 5 6))))
  (list 1 2 3))
 (apl-test
  "without all removed"
  (rv
    (apl-without
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 1 2 3))))
  (list))
--- a/lib/apl/tests/system.sx
+++ b/lib/apl/tests/system.sx
@@ -0,0 +1,48 @@
 ; Tests for APL ⎕ system functions.
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 (apl-test "⎕IO returns 1" (mkrv (apl-quad-io)) (list 1))
 (apl-test "⎕ML returns 1" (mkrv (apl-quad-ml)) (list 1))
 (apl-test "⎕FR returns 1248" (mkrv (apl-quad-fr)) (list 1248))
 (apl-test "⎕TS shape is 7" (mksh (apl-quad-ts)) (list 7))
 (apl-test "⎕TS year is 1970 default" (first (mkrv (apl-quad-ts))) 1970)
 (apl-test "⎕FMT scalar 42" (apl-quad-fmt (apl-scalar 42)) "42")
 (apl-test "⎕FMT scalar negative" (apl-quad-fmt (apl-scalar -7)) "-7")
 (apl-test
  "⎕FMT empty vector"
  (apl-quad-fmt (make-array (list 0) (list)))
  "")
 (apl-test
  "⎕FMT singleton vector"
  (apl-quad-fmt (make-array (list 1) (list 42)))
  "42")
 (apl-test
  "⎕FMT vector"
  (apl-quad-fmt (make-array (list 5) (list 1 2 3 4 5)))
  "1 2 3 4 5")
 (apl-test
  "⎕FMT matrix 2x3"
  (apl-quad-fmt (make-array (list 2 3) (list 1 2 3 4 5 6)))
  "1 2 3\n4 5 6\n")
 (apl-test
  "⎕← (print) returns its arg"
  (mkrv (apl-quad-print (apl-scalar 99)))
  (list 99))
 (apl-test
  "⎕← preserves shape"
  (mksh (apl-quad-print (make-array (list 3) (list 1 2 3))))
  (list 3))
--- a/lib/apl/tests/tradfn.sx
+++ b/lib/apl/tests/tradfn.sx
@@ -0,0 +1,156 @@
 ; Tests for apl-call-tradfn (manual structure construction).
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mksh (fn (arr) (get arr :shape)))
 (define mknum (fn (n) (list :num n)))
 (define mknm (fn (s) (list :name s)))
 (define mkfg (fn (g) (list :fn-glyph g)))
 (define mkmon (fn (g a) (list :monad (mkfg g) a)))
 (define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
 (define mkasg (fn (n e) (list :assign n e)))
 (define mkbr (fn (e) (list :branch e)))
 (define mkif (fn (c t e) (list :if c t e)))
 (define mkwhile (fn (c b) (list :while c b)))
 (define mkfor (fn (v i b) (list :for v i b)))
 (define mksel (fn (v cs d) (list :select v cs d)))
 (define mktrap (fn (codes t c) (list :trap codes t c)))
 (define mkthr (fn (code msg) (list :throw code msg)))
 (apl-test
  "tradfn R←L+W simple add"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "+" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 5) (apl-scalar 7)))
  (list 12))
 (apl-test
  "tradfn R←L×W"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 6) (apl-scalar 7)))
  (list 42))
 (apl-test
  "tradfn monadic R←-W"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkmon "-" (mknm "W")))) :alpha nil} nil (apl-scalar 9)))
  (list -9))
 (apl-test
  "tradfn →0 exits early"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknm "W")) (mkbr (mknum 0)) (mkasg "R" (mknum 999))) :alpha nil} nil (apl-scalar 7)))
  (list 7))
 (apl-test
  "tradfn branch to line 3 skips line 2"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkbr (mknum 3)) (mkasg "R" (mknum 999)) (mkasg "R" (mknum 42))) :alpha nil} nil (apl-scalar 0)))
  (list 42))
 (apl-test
  "tradfn local var t←W+1; R←t×2"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "t" (mkdyd "+" (mknm "W") (mknum 1))) (mkasg "R" (mkdyd "×" (mknm "t") (mknum 2)))) :alpha nil} nil (apl-scalar 5)))
  (list 12))
 (apl-test
  "tradfn vector args"
  (mkrv
    (apl-call-tradfn
      {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "+" (mknm "L") (mknm "W")))) :alpha "L"}
      (make-array (list 3) (list 1 2 3))
      (make-array (list 3) (list 10 20 30))))
  (list 11 22 33))
 (apl-test
  "tradfn unset result returns nil"
  (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkbr (mknum 0))) :alpha nil} nil (apl-scalar 5))
  nil)
 (apl-test
  "tradfn run-off end returns result"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "W") (mknum 3)))) :alpha nil} nil (apl-scalar 7)))
  (list 21))
 (apl-test
  "tradfn loop sum 1+2+...+5 via branch"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "i" (mknum 1)) (mkasg "R" (mknum 0)) (mkasg "R" (mkdyd "+" (mknm "R") (mknm "i"))) (mkasg "i" (mkdyd "+" (mknm "i") (mknum 1))) (mkbr (mkdyd "×" (mkdyd "≤" (mknm "i") (mknm "W")) (mknum 3)))) :alpha nil} nil (apl-scalar 5)))
  (list 15))
 (apl-test
  "tradfn :If true branch"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkasg "R" (mknum 1))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
  (list 1))
 (apl-test
  "tradfn :If false branch"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 100)) (list (mkasg "R" (mknum 1))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
  (list 0))
 (apl-test
  "tradfn :While sum 1..N"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "i" (mknum 1)) (mkasg "R" (mknum 0)) (mkwhile (mkdyd "≤" (mknm "i") (mknm "W")) (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "i"))) (mkasg "i" (mkdyd "+" (mknm "i") (mknum 1)))))) :alpha nil} nil (apl-scalar 10)))
  (list 55))
 (apl-test
  "tradfn :For sum elements"
  (mkrv
    (apl-call-tradfn
      {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 0)) (mkfor "x" (mknm "W") (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "x")))))) :alpha nil}
      nil
      (make-array (list 4) (list 10 20 30 40))))
  (list 100))
 (apl-test
  "tradfn :For with empty vector"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 99)) (mkfor "x" (mknm "W") (list (mkasg "R" (mkdyd "+" (mknm "R") (mknm "x")))))) :alpha nil} nil (make-array (list 0) (list))))
  (list 99))
 (apl-test
  "tradfn :Select dispatch hit"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mksel (mknm "W") (list (list (mknum 1) (mkasg "R" (mknum 100))) (list (mknum 2) (mkasg "R" (mknum 200))) (list (mknum 3) (mkasg "R" (mknum 300)))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 2)))
  (list 200))
 (apl-test
  "tradfn :Select default block"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mksel (mknm "W") (list (list (mknum 1) (mkasg "R" (mknum 100))) (list (mknum 2) (mkasg "R" (mknum 200)))) (list (mkasg "R" (mknum -1))))) :alpha nil} nil (apl-scalar 99)))
  (list -1))
 (apl-test
  "tradfn nested :If"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkif (mkdyd ">" (mknm "W") (mknum 10)) (list (mkasg "R" (mknum 2))) (list (mkasg "R" (mknum 1))))) (list (mkasg "R" (mknum 0))))) :alpha nil} nil (apl-scalar 5)))
  (list 1))
 (apl-test
  "tradfn :If assigns persist outside"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 0)) (mkif (mkdyd ">" (mknm "W") (mknum 0)) (list (mkasg "R" (mknum 42))) (list)) (mkasg "R" (mkdyd "+" (mknm "R") (mknum 1)))) :alpha nil} nil (apl-scalar 5)))
  (list 43))
 (apl-test
  "tradfn :For factorial 1..5"
  (mkrv (apl-call-tradfn {:result "R" :omega "W" :stmts (list (mkasg "R" (mknum 1)) (mkfor "x" (mkmon "⍳" (mknm "W")) (list (mkasg "R" (mkdyd "×" (mknm "R") (mknm "x")))))) :alpha nil} nil (apl-scalar 5)))
  (list 120))
 (apl-test
  "tradfn :Trap normal flow (no error)"
  (mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 0) (list (mkasg "R" (mknum 99))) (list (mkasg "R" (mknum -1))))) :alpha nil} nil nil))
  (list 99))
 (apl-test
  "tradfn :Trap catches matching code"
  (mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 5) (list (mkthr 5 "boom")) (list (mkasg "R" (mknum 42))))) :alpha nil} nil nil))
  (list 42))
 (apl-test
  "tradfn :Trap catch-all (code 0)"
  (mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 0) (list (mkthr 99 "any")) (list (mkasg "R" (mknum 1))))) :alpha nil} nil nil))
  (list 1))
 (apl-test
  "tradfn :Trap catches one of many codes"
  (mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 1 2 3) (list (mkthr 2 "two")) (list (mkasg "R" (mknum 22))))) :alpha nil} nil nil))
  (list 22))
 (apl-test
  "tradfn :Trap continues to next stmt after catch"
  (mkrv (apl-call-tradfn {:result "R" :omega nil :stmts (list (mktrap (list 7) (list (mkthr 7 "c")) (list (mkasg "R" (mknum 10)))) (mkasg "R" (mkdyd "+" (mknm "R") (mknum 5)))) :alpha nil} nil nil))
  (list 15))
--- a/lib/apl/tests/valence.sx
+++ b/lib/apl/tests/valence.sx
@@ -0,0 +1,81 @@
 ; Tests for valence detection (apl-dfn-valence, apl-tradfn-valence)
 ; and unified dispatch (apl-call).
 (define mkrv (fn (arr) (get arr :ravel)))
 (define mknum (fn (n) (list :num n)))
 (define mknm (fn (s) (list :name s)))
 (define mkfg (fn (g) (list :fn-glyph g)))
 (define mkmon (fn (g a) (list :monad (mkfg g) a)))
 (define mkdyd (fn (g l r) (list :dyad (mkfg g) l r)))
 (define mkasg (fn (n e) (list :assign n e)))
 (define mkdfn (fn (stmts) (cons :dfn stmts)))
 (apl-test
  "dfn-valence niladic body=42"
  (apl-dfn-valence (mkdfn (list (mknum 42))))
  :niladic)
 (apl-test
  "dfn-valence monadic body=⍵+1"
  (apl-dfn-valence (mkdfn (list (mkdyd "+" (mknm "⍵") (mknum 1)))))
  :monadic)
 (apl-test
  "dfn-valence dyadic body=⍺+⍵"
  (apl-dfn-valence (mkdfn (list (mkdyd "+" (mknm "⍺") (mknm "⍵")))))
  :dyadic)
 (apl-test
  "dfn-valence dyadic mentions ⍺ via local"
  (apl-dfn-valence (mkdfn (list (mkasg "x" (mknm "⍺")) (mknm "x"))))
  :dyadic)
 (apl-test
  "dfn-valence dyadic deep nest"
  (apl-dfn-valence
    (mkdfn (list (mkmon "-" (mkdyd "×" (mknm "⍺") (mknm "⍵"))))))
  :dyadic)
 (apl-test "tradfn-valence niladic" (apl-tradfn-valence {:result "R" :omega nil :stmts (list) :alpha nil}) :niladic)
 (apl-test "tradfn-valence monadic" (apl-tradfn-valence {:result "R" :omega "W" :stmts (list) :alpha nil}) :monadic)
 (apl-test "tradfn-valence dyadic" (apl-tradfn-valence {:result "R" :omega "W" :stmts (list) :alpha "L"}) :dyadic)
 (apl-test
  "apl-call dfn niladic"
  (mkrv (apl-call (mkdfn (list (mknum 42))) nil nil))
  (list 42))
 (apl-test
  "apl-call dfn monadic"
  (mkrv
    (apl-call
      (mkdfn (list (mkdyd "+" (mknm "⍵") (mknum 1))))
      nil
      (apl-scalar 5)))
  (list 6))
 (apl-test
  "apl-call dfn dyadic"
  (mkrv
    (apl-call
      (mkdfn (list (mkdyd "+" (mknm "⍺") (mknm "⍵"))))
      (apl-scalar 3)
      (apl-scalar 4)))
  (list 7))
 (apl-test
  "apl-call tradfn dyadic"
  (mkrv (apl-call {:result "R" :omega "W" :stmts (list (mkasg "R" (mkdyd "×" (mknm "L") (mknm "W")))) :alpha "L"} (apl-scalar 6) (apl-scalar 7)))
  (list 42))
 (apl-test
  "apl-call tradfn monadic"
  (mkrv (apl-call {:result "R" :omega "W" :stmts (list (mkasg "R" (mkmon "-" (mknm "W")))) :alpha nil} nil (apl-scalar 9)))
  (list -9))
 (apl-test
  "apl-call tradfn niladic returns nil result"
  (apl-call {:result "R" :omega nil :stmts (list) :alpha nil} nil nil)
  nil)
--- a/lib/apl/tokenizer.sx
+++ b/lib/apl/tokenizer.sx
@@ -0,0 +1,180 @@
 (define apl-glyph-set
  (list "+" "-" "×" "÷" "*" "⍟" "⌈" "⌊" "|" "!" "?" "○" "~" "<" "≤" "=" "≥" ">" "≠"
        "≢" "≡" "∊" "∧" "∨" "⍱" "⍲" "," "⍪" "⍴" "⌽" "⊖" "⍉" "↑" "↓" "⊂" "⊃" "⊆"
        "∪" "∩" "⍳" "⍸" "⌷" "⍋" "⍒" "⊥" "⊤" "⊣" "⊢" "⍎" "⍕"
        "⍺" "⍵" "∇" "/" "⌿" "\\" "⍀" "¨" "⍨" "∘" "." "⍣" "⍤" "⍥" "@" "¯"))
 (define apl-glyph?
  (fn (ch)
    (some (fn (g) (= g ch)) apl-glyph-set)))
 (define apl-digit?
  (fn (ch)
    (and (string? ch) (>= ch "0") (<= ch "9"))))
 (define apl-alpha?
  (fn (ch)
    (and (string? ch)
         (or (and (>= ch "a") (<= ch "z"))
             (and (>= ch "A") (<= ch "Z"))
             (= ch "_")))))
 (define apl-tokenize
  (fn (source)
    (let ((pos 0)
          (src-len (len source))
          (tokens (list)))
      (define tok-push!
        (fn (type value)
          (append! tokens {:type type :value value})))
      (define cur-sw?
        (fn (ch)
          (and (< pos src-len) (starts-with? (slice source pos) ch))))
      (define cur-byte
        (fn ()
          (if (< pos src-len) (nth source pos) nil)))
      (define advance!
        (fn ()
          (set! pos (+ pos 1))))
      (define consume!
        (fn (ch)
          (set! pos (+ pos (len ch)))))
      (define find-glyph
        (fn ()
          (let ((rem (slice source pos)))
            (let ((matches (filter (fn (g) (starts-with? rem g)) apl-glyph-set)))
              (if (> (len matches) 0) (first matches) nil)))))
      (define read-digits!
        (fn (acc)
          (if (and (< pos src-len) (apl-digit? (cur-byte)))
            (let ((ch (cur-byte)))
              (begin
                (advance!)
                (read-digits! (str acc ch))))
            acc)))
      (define read-ident-cont!
        (fn ()
          (when (and (< pos src-len)
                     (let ((ch (cur-byte)))
                       (or (apl-alpha? ch) (apl-digit? ch))))
            (begin
              (advance!)
              (read-ident-cont!)))))
      (define read-string!
        (fn (acc)
          (cond
            ((>= pos src-len) acc)
            ((cur-sw? "'")
             (if (and (< (+ pos 1) src-len) (cur-sw? "'"))
               (begin
                 (advance!)
                 (advance!)
                 (read-string! (str acc "'")))
               (begin (advance!) acc)))
            (true
             (let ((ch (cur-byte)))
               (begin
                 (advance!)
                 (read-string! (str acc ch))))))))
      (define skip-line!
        (fn ()
          (when (and (< pos src-len) (not (cur-sw? "\n")))
            (begin
              (advance!)
              (skip-line!)))))
      (define scan!
        (fn ()
          (when (< pos src-len)
            (let ((ch (cur-byte)))
              (cond
                ((or (= ch " ") (= ch "\t") (= ch "\r"))
                 (begin (advance!) (scan!)))
                ((= ch "\n")
                 (begin (advance!) (tok-push! :newline nil) (scan!)))
                ((cur-sw? "⍝")
                 (begin (skip-line!) (scan!)))
                ((cur-sw? "⋄")
                 (begin (consume! "⋄") (tok-push! :diamond nil) (scan!)))
                ((= ch "(")
                 (begin (advance!) (tok-push! :lparen nil) (scan!)))
                ((= ch ")")
                 (begin (advance!) (tok-push! :rparen nil) (scan!)))
                ((= ch "[")
                 (begin (advance!) (tok-push! :lbracket nil) (scan!)))
                ((= ch "]")
                 (begin (advance!) (tok-push! :rbracket nil) (scan!)))
                ((= ch "{")
                 (begin (advance!) (tok-push! :lbrace nil) (scan!)))
                ((= ch "}")
                 (begin (advance!) (tok-push! :rbrace nil) (scan!)))
                ((= ch ";")
                 (begin (advance!) (tok-push! :semi nil) (scan!)))
                ((cur-sw? "←")
                 (begin (consume! "←") (tok-push! :assign nil) (scan!)))
                ((= ch ":")
                 (let ((start pos))
                   (begin
                     (advance!)
                     (if (and (< pos src-len) (apl-alpha? (cur-byte)))
                       (begin
                         (read-ident-cont!)
                         (tok-push! :keyword (slice source start pos)))
                       (tok-push! :colon nil))
                     (scan!))))
                ((and (cur-sw? "¯")
                      (< (+ pos (len "¯")) src-len)
                      (apl-digit? (nth source (+ pos (len "¯")))))
                 (begin
                   (consume! "¯")
                   (let ((digits (read-digits! "")))
                     (if (and (< pos src-len) (= (cur-byte) ".")
                              (< (+ pos 1) src-len) (apl-digit? (nth source (+ pos 1))))
                       (begin (advance!)
                              (let ((frac (read-digits! "")))
                                (tok-push! :num (- 0 (string->number (str digits "." frac))))))
                       (tok-push! :num (- 0 (parse-int digits 0)))))
                   (scan!)))
                ((apl-digit? ch)
                 (begin
                   (let ((digits (read-digits! "")))
                     (if (and (< pos src-len) (= (cur-byte) ".")
                              (< (+ pos 1) src-len) (apl-digit? (nth source (+ pos 1))))
                       (begin (advance!)
                              (let ((frac (read-digits! "")))
                                (tok-push! :num (string->number (str digits "." frac)))))
                       (tok-push! :num (parse-int digits 0))))
                   (scan!)))
                ((= ch "'")
                 (begin
                   (advance!)
                   (let ((s (read-string! "")))
                     (tok-push! :str s))
                   (scan!)))
                ((or (apl-alpha? ch) (cur-sw? "⎕"))
                 (let ((start pos))
                   (begin
                     (if (cur-sw? "⎕") (consume! "⎕") (advance!))
                     (if (and (< pos src-len) (cur-sw? "←"))
                       (consume! "←")
                       (read-ident-cont!))
                     (tok-push! :name (slice source start pos))
                     (scan!))))
                (true
                 (let ((g (find-glyph)))
                   (if g
                     (begin (consume! g) (tok-push! :glyph g) (scan!))
                     (begin (advance!) (scan!))))))))))
      (scan!)
      tokens)))
--- a/lib/apl/transpile.sx
+++ b/lib/apl/transpile.sx
@@ -0,0 +1,540 @@
 ; APL transpile / AST evaluator
 ;
 ; Walks parsed AST nodes and evaluates against the runtime.
 ; Entry points:
 ;   apl-eval-ast    : node × env → value
 ;   apl-eval-stmts  : stmt-list × env → value (handles guards, locals, ⍺← default)
 ;   apl-call-dfn    : dfn-ast × ⍺ × ⍵ → value   (dyadic)
 ;   apl-call-dfn-m  : dfn-ast × ⍵ → value       (monadic)
 ;
 ; Env is a dict; ⍺ stored under "alpha", ⍵ under "omega",
 ; the dfn-ast itself under "nabla" (for ∇ recursion),
 ; user names under their literal name.
 (define
  apl-monadic-fn
  (fn
    (g)
    (cond
      ((= g "+") apl-plus-m)
      ((= g "-") apl-neg-m)
      ((= g "×") apl-signum)
      ((= g "÷") apl-recip)
      ((= g "⌈") apl-ceil)
      ((= g "⌊") apl-floor)
      ((= g "⍳") apl-iota)
      ((= g "|") apl-abs)
      ((= g "*") apl-exp)
      ((= g "⍟") apl-ln)
      ((= g "!") apl-fact)
      ((= g "○") apl-pi-times)
      ((= g "~") apl-not)
      ((= g "≢") apl-tally)
      ((= g "⍴") apl-shape)
      ((= g "≡") apl-depth)
      ((= g "⊂") apl-enclose)
      ((= g "⊃") apl-disclose)
      ((= g ",") apl-ravel)
      ((= g "⌽") apl-reverse)
      ((= g "⊖") apl-reverse-first)
      ((= g "⍋") apl-grade-up)
      ((= g "⍒") apl-grade-down)
      ((= g "⎕FMT") apl-quad-fmt)
      ((= g "⎕←") apl-quad-print)
      (else (error "no monadic fn for glyph")))))
 (define
  apl-dyadic-fn
  (fn
    (g)
    (cond
      ((= g "+") apl-add)
      ((= g "-") apl-sub)
      ((= g "×") apl-mul)
      ((= g "÷") apl-div)
      ((= g "⌈") apl-max)
      ((= g "⌊") apl-min)
      ((= g "*") apl-pow)
      ((= g "⍟") apl-log)
      ((= g "|") apl-mod)
      ((= g "!") apl-binomial)
      ((= g "○") apl-trig)
      ((= g "<") apl-lt)
      ((= g "≤") apl-le)
      ((= g "=") apl-eq)
      ((= g "≥") apl-ge)
      ((= g ">") apl-gt)
      ((= g "≠") apl-ne)
      ((= g "∧") apl-and)
      ((= g "∨") apl-or)
      ((= g "⍱") apl-nor)
      ((= g "⍲") apl-nand)
      ((= g ",") apl-catenate)
      ((= g "⍪") apl-catenate-first)
      ((= g "⍴") apl-reshape)
      ((= g "↑") apl-take)
      ((= g "↓") apl-drop)
      ((= g "⌷") apl-squad)
      ((= g "⌽") apl-rotate)
      ((= g "⊖") apl-rotate-first)
      ((= g "∊") apl-member)
      ((= g "⍳") apl-index-of)
      ((= g "~") apl-without)
      (else (error "no dyadic fn for glyph")))))
 (define
  apl-truthy?
  (fn
    (v)
    (let
      ((rv (get v :ravel)))
      (if (and (= (len rv) 1) (= (first rv) 0)) false true))))
 (define
  apl-eval-ast
  (fn
    (node env)
    (let
      ((tag (first node)))
      (cond
        ((= tag :num) (apl-scalar (nth node 1)))
        ((= tag :str)
          (let
            ((s (nth node 1)))
            (if
              (= (len s) 1)
              (apl-scalar s)
              (make-array
                (list (len s))
                (map (fn (i) (slice s i (+ i 1))) (range 0 (len s)))))))
        ((= tag :vec)
          (let
            ((items (rest node)))
            (let
              ((vals (map (fn (n) (apl-eval-ast n env)) items)))
              (make-array
                (list (len vals))
                (map (fn (v) (first (get v :ravel))) vals)))))
        ((= tag :name)
          (let
            ((nm (nth node 1)))
            (cond
              ((= nm "⍺") (get env "alpha"))
              ((= nm "⍵") (get env "omega"))
              ((= nm "⎕IO") (apl-quad-io))
              ((= nm "⎕ML") (apl-quad-ml))
              ((= nm "⎕FR") (apl-quad-fr))
              ((= nm "⎕TS") (apl-quad-ts))
              (else (get env nm)))))
        ((= tag :monad)
          (let
            ((fn-node (nth node 1)) (arg (nth node 2)))
            (if
              (and (= (first fn-node) :fn-glyph) (= (nth fn-node 1) "∇"))
              (apl-call-dfn-m (get env "nabla") (apl-eval-ast arg env))
              ((apl-resolve-monadic fn-node env) (apl-eval-ast arg env)))))
        ((= tag :dyad)
          (let
            ((fn-node (nth node 1))
              (lhs (nth node 2))
              (rhs (nth node 3)))
            (if
              (and (= (first fn-node) :fn-glyph) (= (nth fn-node 1) "∇"))
              (apl-call-dfn
                (get env "nabla")
                (apl-eval-ast lhs env)
                (apl-eval-ast rhs env))
              ((apl-resolve-dyadic fn-node env)
                (apl-eval-ast lhs env)
                (apl-eval-ast rhs env)))))
        ((= tag :program) (apl-eval-stmts (rest node) env))
        ((= tag :dfn) node)
        ((= tag :bracket)
          (let
            ((arr-expr (nth node 1)) (axis-exprs (rest (rest node))))
            (let
              ((arr (apl-eval-ast arr-expr env))
                (axes
                  (map
                    (fn (a) (if (= a :all) nil (apl-eval-ast a env)))
                    axis-exprs)))
              (apl-bracket-multi axes arr))))
        (else (error (list "apl-eval-ast: unknown node tag" tag node)))))))
 (define
  apl-eval-stmts
  (fn
    (stmts env)
    (if
      (= (len stmts) 0)
      nil
      (let
        ((stmt (first stmts)) (more (rest stmts)))
        (let
          ((tag (first stmt)))
          (cond
            ((= tag :guard)
              (let
                ((cond-val (apl-eval-ast (nth stmt 1) env)))
                (if
                  (apl-truthy? cond-val)
                  (apl-eval-ast (nth stmt 2) env)
                  (apl-eval-stmts more env))))
            ((and (= tag :assign) (= (nth stmt 1) "⍺"))
              (if
                (get env "alpha")
                (apl-eval-stmts more env)
                (let
                  ((v (apl-eval-ast (nth stmt 2) env)))
                  (apl-eval-stmts more (assoc env "alpha" v)))))
            ((= tag :assign)
              (let
                ((v (apl-eval-ast (nth stmt 2) env)))
                (apl-eval-stmts more (assoc env (nth stmt 1) v))))
            ((= (len more) 0) (apl-eval-ast stmt env))
            (else (begin (apl-eval-ast stmt env) (apl-eval-stmts more env)))))))))
 (define
  apl-call-dfn
  (fn
    (dfn-ast alpha omega)
    (let
      ((stmts (rest dfn-ast)) (env {:omega omega :nabla dfn-ast :alpha alpha}))
      (apl-eval-stmts stmts env))))
 (define
  apl-call-dfn-m
  (fn
    (dfn-ast omega)
    (let
      ((stmts (rest dfn-ast)) (env {:omega omega :nabla dfn-ast :alpha nil}))
      (apl-eval-stmts stmts env))))
 (define
  apl-tradfn-eval-block
  (fn
    (stmts env)
    (if
      (= (len stmts) 0)
      env
      (let
        ((stmt (first stmts)))
        (apl-tradfn-eval-block (rest stmts) (apl-tradfn-eval-stmt stmt env))))))
 (define
  apl-tradfn-eval-while
  (fn
    (cond-expr body env)
    (let
      ((cond-val (apl-eval-ast cond-expr env)))
      (if
        (apl-truthy? cond-val)
        (apl-tradfn-eval-while
          cond-expr
          body
          (apl-tradfn-eval-block body env))
        env))))
 (define
  apl-tradfn-eval-for
  (fn
    (var-name items body env)
    (if
      (= (len items) 0)
      env
      (let
        ((env-with-var (assoc env var-name (apl-scalar (first items)))))
        (apl-tradfn-eval-for
          var-name
          (rest items)
          body
          (apl-tradfn-eval-block body env-with-var))))))
 (define
  apl-tradfn-eval-select
  (fn
    (val cases default-block env)
    (if
      (= (len cases) 0)
      (apl-tradfn-eval-block default-block env)
      (let
        ((c (first cases)))
        (let
          ((case-val (apl-eval-ast (first c) env)))
          (if
            (= (first (get val :ravel)) (first (get case-val :ravel)))
            (apl-tradfn-eval-block (rest c) env)
            (apl-tradfn-eval-select val (rest cases) default-block env)))))))
 (define
  apl-tradfn-eval-stmt
  (fn
    (stmt env)
    (let
      ((tag (first stmt)))
      (cond
        ((= tag :assign)
          (assoc env (nth stmt 1) (apl-eval-ast (nth stmt 2) env)))
        ((= tag :if)
          (let
            ((cond-val (apl-eval-ast (nth stmt 1) env)))
            (if
              (apl-truthy? cond-val)
              (apl-tradfn-eval-block (nth stmt 2) env)
              (apl-tradfn-eval-block (nth stmt 3) env))))
        ((= tag :while)
          (apl-tradfn-eval-while (nth stmt 1) (nth stmt 2) env))
        ((= tag :for)
          (let
            ((iter-val (apl-eval-ast (nth stmt 2) env)))
            (apl-tradfn-eval-for
              (nth stmt 1)
              (get iter-val :ravel)
              (nth stmt 3)
              env)))
        ((= tag :select)
          (let
            ((val (apl-eval-ast (nth stmt 1) env)))
            (apl-tradfn-eval-select val (nth stmt 2) (nth stmt 3) env)))
        ((= tag :trap)
          (let
            ((codes (nth stmt 1))
              (try-block (nth stmt 2))
              (catch-block (nth stmt 3)))
            (guard
              (e
                ((apl-trap-matches? codes e)
                  (apl-tradfn-eval-block catch-block env)))
              (apl-tradfn-eval-block try-block env))))
        ((= tag :throw) (apl-throw (nth stmt 1) (nth stmt 2)))
        (else (begin (apl-eval-ast stmt env) env))))))
 (define
  apl-tradfn-loop
  (fn
    (stmts line env result-name)
    (cond
      ((= line 0) (get env result-name))
      ((> line (len stmts)) (get env result-name))
      (else
        (let
          ((stmt (nth stmts (- line 1))))
          (let
            ((tag (first stmt)))
            (cond
              ((= tag :branch)
                (let
                  ((target (apl-eval-ast (nth stmt 1) env)))
                  (let
                    ((target-num (first (get target :ravel))))
                    (apl-tradfn-loop stmts target-num env result-name))))
              (else
                (apl-tradfn-loop
                  stmts
                  (+ line 1)
                  (apl-tradfn-eval-stmt stmt env)
                  result-name)))))))))
 (define
  apl-call-tradfn
  (fn
    (tradfn alpha omega)
    (let
      ((stmts (get tradfn :stmts))
        (result-name (get tradfn :result))
        (alpha-name (get tradfn :alpha))
        (omega-name (get tradfn :omega)))
      (let
        ((env-a (if alpha-name (assoc {} alpha-name alpha) {})))
        (let
          ((env-ao (if omega-name (assoc env-a omega-name omega) env-a)))
          (apl-tradfn-loop stmts 1 env-ao result-name))))))
 (define
  apl-ast-mentions-list?
  (fn
    (lst target)
    (if
      (= (len lst) 0)
      false
      (if
        (apl-ast-mentions? (first lst) target)
        true
        (apl-ast-mentions-list? (rest lst) target)))))
 (define
  apl-ast-mentions?
  (fn
    (node target)
    (cond
      ((not (list? node)) false)
      ((= (len node) 0) false)
      ((and (= (first node) :name) (= (nth node 1) target)) true)
      (else (apl-ast-mentions-list? (rest node) target)))))
 (define
  apl-dfn-valence
  (fn
    (dfn-ast)
    (let
      ((body (rest dfn-ast)))
      (cond
        ((apl-ast-mentions-list? body "⍺") :dyadic)
        ((apl-ast-mentions-list? body "⍵") :monadic)
        (else :niladic)))))
 (define
  apl-tradfn-valence
  (fn
    (tradfn)
    (cond
      ((get tradfn :alpha) :dyadic)
      ((get tradfn :omega) :monadic)
      (else :niladic))))
 (define
  apl-call
  (fn
    (f alpha omega)
    (cond
      ((and (list? f) (> (len f) 0) (= (first f) :dfn))
        (if alpha (apl-call-dfn f alpha omega) (apl-call-dfn-m f omega)))
      ((dict? f) (apl-call-tradfn f alpha omega))
      (else (error "apl-call: not a function")))))
 (define
  apl-resolve-monadic
  (fn
    (fn-node env)
    (let
      ((tag (first fn-node)))
      (cond
        ((= tag :fn-glyph) (apl-monadic-fn (nth fn-node 1)))
        ((= tag :derived-fn)
          (let
            ((op (nth fn-node 1)) (inner (nth fn-node 2)))
            (cond
              ((= op "/")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (arr) (apl-reduce f arr))))
              ((= op "⌿")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (arr) (apl-reduce-first f arr))))
              ((= op "\\")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (arr) (apl-scan f arr))))
              ((= op "⍀")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (arr) (apl-scan-first f arr))))
              ((= op "¨")
                (let
                  ((f (apl-resolve-monadic inner env)))
                  (fn (arr) (apl-each f arr))))
              ((= op "⍨")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (arr) (apl-commute f arr))))
              (else (error "apl-resolve-monadic: unsupported op")))))
        ((= tag :fn-name)
          (let
            ((nm (nth fn-node 1)))
            (let
              ((bound (get env nm)))
              (if
                (and
                  (list? bound)
                  (> (len bound) 0)
                  (= (first bound) :dfn))
                (fn (arg) (apl-call-dfn-m bound arg))
                (error "apl-resolve-monadic: name not bound to dfn")))))
        ((= tag :train)
          (let
            ((fns (rest fn-node)))
            (let
              ((n (len fns)))
              (cond
                ((= n 2)
                  (let
                    ((g (apl-resolve-monadic (nth fns 0) env))
                      (h (apl-resolve-monadic (nth fns 1) env)))
                    (fn (arg) (g (h arg)))))
                ((= n 3)
                  (let
                    ((f (apl-resolve-monadic (nth fns 0) env))
                      (g (apl-resolve-dyadic (nth fns 1) env))
                      (h (apl-resolve-monadic (nth fns 2) env)))
                    (fn (arg) (g (f arg) (h arg)))))
                (else (error "monadic train arity not 2 or 3"))))))
        (else (error "apl-resolve-monadic: unknown fn-node tag"))))))
 (define
  apl-resolve-dyadic
  (fn
    (fn-node env)
    (let
      ((tag (first fn-node)))
      (cond
        ((= tag :fn-glyph) (apl-dyadic-fn (nth fn-node 1)))
        ((= tag :derived-fn)
          (let
            ((op (nth fn-node 1)) (inner (nth fn-node 2)))
            (cond
              ((= op "¨")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (a b) (apl-each-dyadic f a b))))
              ((= op "⍨")
                (let
                  ((f (apl-resolve-dyadic inner env)))
                  (fn (a b) (apl-commute-dyadic f a b))))
              (else (error "apl-resolve-dyadic: unsupported op")))))
        ((= tag :fn-name)
          (let
            ((nm (nth fn-node 1)))
            (let
              ((bound (get env nm)))
              (if
                (and
                  (list? bound)
                  (> (len bound) 0)
                  (= (first bound) :dfn))
                (fn (a b) (apl-call-dfn bound a b))
                (error "apl-resolve-dyadic: name not bound to dfn")))))
        ((= tag :outer)
          (let
            ((inner (nth fn-node 2)))
            (let
              ((f (apl-resolve-dyadic inner env)))
              (fn (a b) (apl-outer f a b)))))
        ((= tag :derived-fn2)
          (let
            ((f-node (nth fn-node 2)) (g-node (nth fn-node 3)))
            (let
              ((f (apl-resolve-dyadic f-node env))
                (g (apl-resolve-dyadic g-node env)))
              (fn (a b) (apl-inner f g a b)))))
        ((= tag :train)
          (let
            ((fns (rest fn-node)))
            (let
              ((n (len fns)))
              (cond
                ((= n 2)
                  (let
                    ((g (apl-resolve-monadic (nth fns 0) env))
                      (h (apl-resolve-dyadic (nth fns 1) env)))
                    (fn (a b) (g (h a b)))))
                ((= n 3)
                  (let
                    ((f (apl-resolve-dyadic (nth fns 0) env))
                      (g (apl-resolve-dyadic (nth fns 1) env))
                      (h (apl-resolve-dyadic (nth fns 2) env)))
                    (fn (a b) (g (f a b) (h a b)))))
                (else (error "dyadic train arity not 2 or 3"))))))
        (else (error "apl-resolve-dyadic: unknown fn-node tag"))))))
 (define apl-run (fn (src) (apl-eval-ast (parse-apl src) {})))
--- a/lib/guest/ast.sx
+++ b/lib/guest/ast.sx
@@ -0,0 +1,92 @@
 ;; lib/guest/ast.sx — canonical AST node shapes.
 ;;
 ;; A guest's parser may emit its own AST in whatever shape is convenient
 ;; for that language's evaluator/transpiler. This file gives a SHARED
 ;; canonical shape that cross-language tools (formatters, highlighters,
 ;; debuggers) can target without per-language adapters.
 ;;
 ;; Each canonical node is a tagged list: (KIND ...payload).
 ;;
 ;; Constructors (return a canonical node):
 ;;
 ;;   (ast-literal       VALUE)               — number / string / bool / nil
 ;;   (ast-var           NAME)                — identifier reference
 ;;   (ast-app           FN ARGS)             — function application
 ;;   (ast-lambda        PARAMS BODY)         — anonymous function
 ;;   (ast-let           BINDINGS BODY)       — local bindings
 ;;   (ast-letrec        BINDINGS BODY)       — recursive local bindings
 ;;   (ast-if            TEST THEN ELSE)      — conditional
 ;;   (ast-match-clause  PATTERN BODY)        — one match arm
 ;;   (ast-module        NAME BODY)           — module declaration
 ;;   (ast-import        NAME)                — import directive
 ;;
 ;; Predicates: (ast-literal? X), (ast-var? X), …
 ;; Generic:    (ast? X)         — any canonical node
 ;;             (ast-kind X)     — :literal / :var / :app / …
 ;;
 ;; Accessors  (one per payload field):
 ;;   (ast-literal-value N)
 ;;   (ast-var-name N)
 ;;   (ast-app-fn N)             (ast-app-args N)
 ;;   (ast-lambda-params N)      (ast-lambda-body N)
 ;;   (ast-let-bindings N)       (ast-let-body N)
 ;;   (ast-letrec-bindings N)    (ast-letrec-body N)
 ;;   (ast-if-test N)            (ast-if-then N)         (ast-if-else N)
 ;;   (ast-match-clause-pattern N)
 ;;   (ast-match-clause-body N)
 ;;   (ast-module-name N)        (ast-module-body N)
 ;;   (ast-import-name N)
 (define ast-literal      (fn (v)         (list :literal v)))
 (define ast-var          (fn (n)         (list :var n)))
 (define ast-app          (fn (f args)    (list :app f args)))
 (define ast-lambda       (fn (ps body)   (list :lambda ps body)))
 (define ast-let          (fn (bs body)   (list :let bs body)))
 (define ast-letrec       (fn (bs body)   (list :letrec bs body)))
 (define ast-if           (fn (t th el)   (list :if t th el)))
 (define ast-match-clause (fn (p body)    (list :match-clause p body)))
 (define ast-module       (fn (n body)    (list :module n body)))
 (define ast-import       (fn (n)         (list :import n)))
 (define ast-kind (fn (x) (if (and (list? x) (not (empty? x))) (first x) nil)))
 (define
  ast?
  (fn (x)
    (and (list? x)
         (not (empty? x))
         (let ((k (first x)))
           (or (= k :literal) (= k :var) (= k :app)
               (= k :lambda)  (= k :let) (= k :letrec)
               (= k :if)      (= k :match-clause)
               (= k :module)  (= k :import))))))
 (define ast-literal?      (fn (x) (and (ast? x) (= (first x) :literal))))
 (define ast-var?          (fn (x) (and (ast? x) (= (first x) :var))))
 (define ast-app?          (fn (x) (and (ast? x) (= (first x) :app))))
 (define ast-lambda?       (fn (x) (and (ast? x) (= (first x) :lambda))))
 (define ast-let?          (fn (x) (and (ast? x) (= (first x) :let))))
 (define ast-letrec?       (fn (x) (and (ast? x) (= (first x) :letrec))))
 (define ast-if?           (fn (x) (and (ast? x) (= (first x) :if))))
 (define ast-match-clause? (fn (x) (and (ast? x) (= (first x) :match-clause))))
 (define ast-module?       (fn (x) (and (ast? x) (= (first x) :module))))
 (define ast-import?       (fn (x) (and (ast? x) (= (first x) :import))))
 (define ast-literal-value (fn (n) (nth n 1)))
 (define ast-var-name      (fn (n) (nth n 1)))
 (define ast-app-fn        (fn (n) (nth n 1)))
 (define ast-app-args      (fn (n) (nth n 2)))
 (define ast-lambda-params (fn (n) (nth n 1)))
 (define ast-lambda-body   (fn (n) (nth n 2)))
 (define ast-let-bindings  (fn (n) (nth n 1)))
 (define ast-let-body      (fn (n) (nth n 2)))
 (define ast-letrec-bindings (fn (n) (nth n 1)))
 (define ast-letrec-body     (fn (n) (nth n 2)))
 (define ast-if-test       (fn (n) (nth n 1)))
 (define ast-if-then       (fn (n) (nth n 2)))
 (define ast-if-else       (fn (n) (nth n 3)))
 (define ast-match-clause-pattern (fn (n) (nth n 1)))
 (define ast-match-clause-body    (fn (n) (nth n 2)))
 (define ast-module-name   (fn (n) (nth n 1)))
 (define ast-module-body   (fn (n) (nth n 2)))
 (define ast-import-name   (fn (n) (nth n 1)))
--- a/lib/guest/hm.sx
+++ b/lib/guest/hm.sx
@@ -0,0 +1,180 @@
 ;; lib/guest/hm.sx — Hindley-Milner type-inference foundations.
 ;;
 ;; Builds on lib/guest/match.sx (terms + unify) and ast.sx (canonical
 ;; AST shapes). This file ships the ALGEBRA — types, schemes, free
 ;; type-vars, generalize / instantiate, substitution composition — so a
 ;; full Algorithm W (or J) can be assembled on top either inside this
 ;; file or in a host-specific consumer (haskell/infer.sx,
 ;; lib/ocaml/types.sx, …).
 ;;
 ;; Per the brief the second consumer for this step is OCaml-on-SX
 ;; Phase 5 (paired sequencing). Until that lands, the algebra is the
 ;; deliverable; the host-flavoured assembly (lambda / app / let
 ;; inference rules with substitution threading) lives in the host.
 ;;
 ;; Types
 ;; -----
 ;; A type is a canonical match.sx term — type variables use mk-var,
 ;; type constructors use mk-ctor:
 ;;   (hm-tv NAME)              type variable
 ;;   (hm-arrow A B)             A -> B
 ;;   (hm-con NAME ARGS)         named n-ary constructor
 ;;   (hm-int) / (hm-bool) / (hm-string)   primitive constructors
 ;;
 ;; Schemes
 ;; -------
 ;;   (hm-scheme VARS TYPE)        ∀ VARS . TYPE
 ;;   (hm-monotype TYPE)           empty quantifier
 ;;   (hm-scheme? S) (hm-scheme-vars S) (hm-scheme-type S)
 ;;
 ;; Free type variables
 ;; -------------------
 ;;   (hm-ftv TYPE)                names occurring in TYPE
 ;;   (hm-ftv-scheme S)            free names (minus quantifiers)
 ;;   (hm-ftv-env ENV)             free across an env (name -> scheme)
 ;;
 ;; Substitution
 ;; ------------
 ;;   (hm-apply SUBST TYPE)        substitute through a type
 ;;   (hm-apply-scheme SUBST S)    leaves bound vars alone
 ;;   (hm-apply-env SUBST ENV)
 ;;   (hm-compose S2 S1)           apply S1 then S2
 ;;
 ;; Generalize / Instantiate
 ;; ------------------------
 ;;   (hm-generalize TYPE ENV)      → scheme over ftv(t) - ftv(env)
 ;;   (hm-instantiate SCHEME COUNTER) → fresh-var instance
 ;;   (hm-fresh-tv COUNTER)         → (:var "tN"), bumps COUNTER
 ;;
 ;; Inference (literal only — the rest of Algorithm W lives in the host)
 ;; --------------------------------------------------------------------
 ;;   (hm-infer-literal EXPR)       → {:subst {} :type T}
 ;;
 ;; A complete Algorithm W consumes this kit by assembling lambda / app
 ;; / let rules in the host language file.
 (define hm-tv     (fn (name) (list :var name)))
 (define hm-con    (fn (name args) (list :ctor name args)))
 (define hm-arrow  (fn (a b) (hm-con "->" (list a b))))
 (define hm-int    (fn () (hm-con "Int" (list))))
 (define hm-bool   (fn () (hm-con "Bool" (list))))
 (define hm-string (fn () (hm-con "String" (list))))
 (define hm-scheme        (fn (vars t) (list :scheme vars t)))
 (define hm-monotype      (fn (t) (hm-scheme (list) t)))
 (define hm-scheme?       (fn (s) (and (list? s) (not (empty? s)) (= (first s) :scheme))))
 (define hm-scheme-vars   (fn (s) (nth s 1)))
 (define hm-scheme-type   (fn (s) (nth s 2)))
 (define
  hm-fresh-tv
  (fn (counter)
    (let ((n (first counter)))
      (begin
        (set-nth! counter 0 (+ n 1))
        (hm-tv (str "t" (+ n 1)))))))
 (define
  hm-ftv-acc
  (fn (t acc)
    (cond
      ((is-var? t)
        (if (some (fn (n) (= n (var-name t))) acc) acc (cons (var-name t) acc)))
      ((is-ctor? t)
        (let ((a acc))
          (begin
            (for-each (fn (x) (set! a (hm-ftv-acc x a))) (ctor-args t))
            a)))
      (:else acc))))
 (define hm-ftv (fn (t) (hm-ftv-acc t (list))))
 (define
  hm-ftv-scheme
  (fn (s)
    (let ((qs (hm-scheme-vars s))
          (all (hm-ftv (hm-scheme-type s))))
      (filter (fn (n) (not (some (fn (q) (= q n)) qs))) all))))
 (define
  hm-ftv-env
  (fn (env)
    (let ((acc (list)))
      (begin
        (for-each
          (fn (k)
            (for-each
              (fn (n)
                (when (not (some (fn (m) (= m n)) acc))
                  (set! acc (cons n acc))))
              (hm-ftv-scheme (get env k))))
          (keys env))
        acc))))
 (define hm-apply (fn (subst t) (walk* t subst)))
 (define
  hm-apply-scheme
  (fn (subst s)
    (let ((qs (hm-scheme-vars s))
          (d {}))
      (begin
        (for-each
          (fn (k)
            (when (not (some (fn (q) (= q k)) qs))
              (dict-set! d k (get subst k))))
          (keys subst))
        (hm-scheme qs (walk* (hm-scheme-type s) d))))))
 (define
  hm-apply-env
  (fn (subst env)
    (let ((d {}))
      (begin
        (for-each
          (fn (k) (dict-set! d k (hm-apply-scheme subst (get env k))))
          (keys env))
        d))))
 (define
  hm-compose
  (fn (s2 s1)
    (let ((d {}))
      (begin
        (for-each (fn (k) (dict-set! d k (walk* (get s1 k) s2))) (keys s1))
        (for-each
          (fn (k) (when (not (has-key? d k)) (dict-set! d k (get s2 k))))
          (keys s2))
        d))))
 (define
  hm-generalize
  (fn (t env)
    (let ((tvars (hm-ftv t))
          (evars (hm-ftv-env env)))
      (let ((qs (filter (fn (n) (not (some (fn (m) (= m n)) evars))) tvars)))
        (hm-scheme qs t)))))
 (define
  hm-instantiate
  (fn (s counter)
    (let ((qs (hm-scheme-vars s))
          (subst {}))
      (begin
        (for-each
          (fn (q) (set! subst (assoc subst q (hm-fresh-tv counter))))
          qs)
        (walk* (hm-scheme-type s) subst)))))
 ;; Literal inference — the only AST kind whose typing rule is closed
 ;; in the kit. Lambda / app / let live in host code so the host's own
 ;; AST conventions stay untouched.
 (define
  hm-infer-literal
  (fn (expr)
    (let ((v (ast-literal-value expr)))
      (cond
        ((number? v)  {:subst {} :type (hm-int)})
        ((string? v)  {:subst {} :type (hm-string)})
        ((boolean? v) {:subst {} :type (hm-bool)})
        (:else (error (str "hm-infer-literal: unknown kind: " v)))))))
--- a/lib/guest/layout.sx
+++ b/lib/guest/layout.sx
@@ -0,0 +1,145 @@
 ;; lib/guest/layout.sx — configurable off-side / layout-sensitive lexer.
 ;;
 ;; Inserts virtual open / close / separator tokens based on indentation.
 ;; Configurable enough to encode either the Haskell 98 layout rule (let /
 ;; where / do / of opens a virtual brace at the next token's column) or
 ;; a Python-ish indent / dedent rule (a colon at the end of a line opens
 ;; a block at the next non-blank line's column).
 ;;
 ;; Token shape (input + output)
 ;; ----------------------------
 ;; Each token is a dict {:type :value :line :col …}. The kit reads
 ;; only :type / :value / :line / :col and passes everything else
 ;; through. The input stream MUST be free of newline filler tokens
 ;; (preprocess them away with your tokenizer) — line breaks are detected
 ;; by comparing :line of consecutive tokens.
 ;;
 ;; Config
 ;; ------
 ;;   :open-keywords    list of strings; a token whose :value matches
 ;;                     opens a new layout block at the next token's
 ;;                     column (Haskell: let/where/do/of).
 ;;   :open-trailing-fn (fn (tok) -> bool) — alternative trigger that
 ;;                     fires AFTER the token is emitted. Use for
 ;;                     Python-style trailing `:`.
 ;;   :open-token / :close-token / :sep-token
 ;;                     templates {:type :value} merged with :line and
 ;;                     :col when virtual tokens are emitted.
 ;;   :explicit-open?   (fn (tok) -> bool) — if the next token after a
 ;;                     trigger satisfies this, suppress virtual layout
 ;;                     for that block (Haskell: `{`).
 ;;   :module-prelude?  if true, wrap whole input in an implicit block
 ;;                     at the first token's column (Haskell yes,
 ;;                     Python no).
 ;;
 ;; Public entry
 ;; ------------
 ;;   (layout-pass cfg tokens) -> tokens with virtual layout inserted.
 (define
  layout-mk-virtual
  (fn (template line col)
    (assoc (assoc template :line line) :col col)))
 (define
  layout-is-open-kw?
  (fn (tok open-kws)
    (and (= (get tok :type) "reserved")
         (some (fn (k) (= k (get tok :value))) open-kws))))
 (define
  layout-pass
  (fn (cfg tokens)
    (let ((open-kws (get cfg :open-keywords))
          (trailing-fn (get cfg :open-trailing-fn))
          (open-tmpl (get cfg :open-token))
          (close-tmpl (get cfg :close-token))
          (sep-tmpl (get cfg :sep-token))
          (mod-prelude? (get cfg :module-prelude?))
          (expl?-fn (get cfg :explicit-open?))
          (out (list))
          (stack (list))
          (n (len tokens))
          (i 0)
          (prev-line -1)
          (pending-open false)
          (just-opened false))
      (define
        emit-closes-while-greater
        (fn (col line)
          (when (and (not (empty? stack)) (> (first stack) col))
            (do
              (append! out (layout-mk-virtual close-tmpl line col))
              (set! stack (rest stack))
              (emit-closes-while-greater col line)))))
      (define
        emit-pending-open
        (fn (line col)
          (do
            (append! out (layout-mk-virtual open-tmpl line col))
            (set! stack (cons col stack))
            (set! pending-open false)
            (set! just-opened true))))
      (define
        layout-step
        (fn ()
          (when (< i n)
            (let ((tok (nth tokens i)))
              (let ((line (get tok :line)) (col (get tok :col)))
                (cond
                  (pending-open
                    (cond
                      ((and (not (= expl?-fn nil)) (expl?-fn tok))
                        (do
                          (set! pending-open false)
                          (append! out tok)
                          (set! prev-line line)
                          (set! i (+ i 1))
                          (layout-step)))
                      (:else
                        (do
                          (emit-pending-open line col)
                          (layout-step)))))
                  (:else
                    (let ((on-fresh-line? (and (> prev-line 0) (> line prev-line))))
                      (do
                        (when on-fresh-line?
                          (let ((stack-before stack))
                            (begin
                              (emit-closes-while-greater col line)
                              (when (and (not (empty? stack))
                                         (= (first stack) col)
                                         (not just-opened)
                                         ;; suppress separator if a dedent fired
                                         ;; — the dedent is itself the separator
                                         (= (len stack) (len stack-before)))
                                (append! out (layout-mk-virtual sep-tmpl line col))))))
                        (set! just-opened false)
                        (append! out tok)
                        (set! prev-line line)
                        (set! i (+ i 1))
                        (cond
                          ((layout-is-open-kw? tok open-kws)
                            (set! pending-open true))
                          ((and (not (= trailing-fn nil)) (trailing-fn tok))
                            (set! pending-open true)))
                        (layout-step))))))))))
      (begin
        ;; Module prelude: implicit layout block at the first token's column.
        (when (and mod-prelude? (> n 0))
          (let ((tok (nth tokens 0)))
            (do
              (append! out (layout-mk-virtual open-tmpl (get tok :line) (get tok :col)))
              (set! stack (cons (get tok :col) stack))
              (set! just-opened true))))
        (layout-step)
        ;; EOF: close every remaining block.
        (define close-rest
          (fn ()
            (when (not (empty? stack))
              (do
                (append! out (layout-mk-virtual close-tmpl 0 0))
                (set! stack (rest stack))
                (close-rest)))))
        (close-rest)
        out))))
--- a/lib/guest/match.sx
+++ b/lib/guest/match.sx
@@ -0,0 +1,185 @@
 ;; lib/guest/match.sx — pure pattern-match + unification kit.
 ;;
 ;; Shipped for miniKanren / Datalog / future logic-flavoured guests that
 ;; want immutable unification without writing it from scratch. The two
 ;; existing prolog/haskell engines stay as-is — porting them in place
 ;; risks the 746 tests they currently pass; consumers can migrate
 ;; gradually via the converters in lib/guest/ast.sx.
 ;;
 ;; Term shapes (canonical wire format)
 ;; -----------------------------------
 ;;   var          (:var NAME)            NAME a string
 ;;   constructor  (:ctor HEAD ARGS)      HEAD a string, ARGS a list of terms
 ;;   literal      number / string / boolean / nil
 ;;
 ;; Guests with their own shape pass adapter callbacks via the cfg arg —
 ;; see (unify-with cfg ...) and (match-pat-with cfg ...) below. The
 ;; default canonical entry points (unify / match-pat) use the wire shape.
 ;;
 ;; Substitution / env
 ;; ------------------
 ;; A substitution is a SX dict mapping VAR-NAME → term. There are no
 ;; trails, no mutation: each step either returns an extended dict or nil.
 ;;
 ;;   (empty-subst)                  → {}
 ;;   (walk term s)                  → term with top-level vars resolved
 ;;   (walk* term s)                 → term with all vars resolved (recursive)
 ;;   (extend name term s)           → s with NAME → term added
 ;;   (occurs? name term s)          → bool
 ;;
 ;; Unify (symmetric, miniKanren-flavour)
 ;; -------------------------------------
 ;;   (unify u v s)                  → extended subst or nil
 ;;   (unify-with cfg u v s)         → ditto, with adapter callbacks:
 ;;                                      :var? :var-name :ctor? :ctor-head
 ;;                                      :ctor-args :occurs-check?
 ;;
 ;; Match (asymmetric, haskell-flavour: pattern → value, vars only in pat)
 ;; ---------------------------------------------------------------------
 ;;   (match-pat pat val env)        → extended env or nil
 ;;   (match-pat-with cfg pat val env)
 (define mk-var  (fn (name) (list :var name)))
 (define mk-ctor (fn (head args) (list :ctor head args)))
 (define is-var?    (fn (t) (and (list? t) (not (empty? t)) (= (first t) :var))))
 (define is-ctor?   (fn (t) (and (list? t) (not (empty? t)) (= (first t) :ctor))))
 (define var-name   (fn (t) (nth t 1)))
 (define ctor-head  (fn (t) (nth t 1)))
 (define ctor-args  (fn (t) (nth t 2)))
 (define empty-subst (fn () {}))
 (define
  walk
  (fn (t s)
    (if (and (is-var? t) (has-key? s (var-name t)))
      (walk (get s (var-name t)) s)
      t)))
 (define
  walk*
  (fn (t s)
    (let ((w (walk t s)))
      (cond
        ((is-ctor? w)
          (mk-ctor (ctor-head w) (map (fn (a) (walk* a s)) (ctor-args w))))
        (:else w)))))
 (define
  extend
  (fn (name term s)
    (assoc s name term)))
 (define
  occurs?
  (fn (name term s)
    (let ((w (walk term s)))
      (cond
        ((is-var? w) (= (var-name w) name))
        ((is-ctor? w) (some (fn (a) (occurs? name a s)) (ctor-args w)))
        (:else false)))))
 (define
  unify-with
  (fn (cfg u v s)
    (let ((var?-fn (get cfg :var?))
          (var-name-fn (get cfg :var-name))
          (ctor?-fn (get cfg :ctor?))
          (ctor-head-fn (get cfg :ctor-head))
          (ctor-args-fn (get cfg :ctor-args))
          (occurs?-on (get cfg :occurs-check?)))
      (let ((wu (walk-with cfg u s))
            (wv (walk-with cfg v s)))
        (cond
          ((and (var?-fn wu) (var?-fn wv) (= (var-name-fn wu) (var-name-fn wv))) s)
          ((var?-fn wu)
            (if (and occurs?-on (occurs-with cfg (var-name-fn wu) wv s))
              nil
              (extend (var-name-fn wu) wv s)))
          ((var?-fn wv)
            (if (and occurs?-on (occurs-with cfg (var-name-fn wv) wu s))
              nil
              (extend (var-name-fn wv) wu s)))
          ((and (ctor?-fn wu) (ctor?-fn wv))
            (if (= (ctor-head-fn wu) (ctor-head-fn wv))
              (unify-list-with
                cfg
                (ctor-args-fn wu)
                (ctor-args-fn wv)
                s)
              nil))
          (:else (if (= wu wv) s nil)))))))
 (define
  walk-with
  (fn (cfg t s)
    (if (and ((get cfg :var?) t) (has-key? s ((get cfg :var-name) t)))
      (walk-with cfg (get s ((get cfg :var-name) t)) s)
      t)))
 (define
  occurs-with
  (fn (cfg name term s)
    (let ((w (walk-with cfg term s)))
      (cond
        (((get cfg :var?) w) (= ((get cfg :var-name) w) name))
        (((get cfg :ctor?) w)
          (some (fn (a) (occurs-with cfg name a s)) ((get cfg :ctor-args) w)))
        (:else false)))))
 (define
  unify-list-with
  (fn (cfg xs ys s)
    (cond
      ((and (empty? xs) (empty? ys)) s)
      ((or (empty? xs) (empty? ys)) nil)
      (:else
        (let ((s2 (unify-with cfg (first xs) (first ys) s)))
          (if (= s2 nil)
            nil
            (unify-list-with cfg (rest xs) (rest ys) s2)))))))
 (define canonical-cfg
  {:var? is-var? :var-name var-name
   :ctor? is-ctor? :ctor-head ctor-head :ctor-args ctor-args
   :occurs-check? true})
 (define unify (fn (u v s) (unify-with canonical-cfg u v s)))
 ;; Asymmetric pattern match (haskell-style): only patterns may contain vars;
 ;; values are concrete. On a var pattern, bind name to value.
 (define
  match-pat-with
  (fn (cfg pat val env)
    (let ((var?-fn (get cfg :var?))
          (var-name-fn (get cfg :var-name))
          (ctor?-fn (get cfg :ctor?))
          (ctor-head-fn (get cfg :ctor-head))
          (ctor-args-fn (get cfg :ctor-args)))
      (cond
        ((var?-fn pat) (extend (var-name-fn pat) val env))
        ((and (ctor?-fn pat) (ctor?-fn val))
          (if (= (ctor-head-fn pat) (ctor-head-fn val))
            (match-list-pat-with
              cfg
              (ctor-args-fn pat)
              (ctor-args-fn val)
              env)
            nil))
        ((ctor?-fn pat) nil)
        (:else (if (= pat val) env nil))))))
 (define
  match-list-pat-with
  (fn (cfg pats vals env)
    (cond
      ((and (empty? pats) (empty? vals)) env)
      ((or (empty? pats) (empty? vals)) nil)
      (:else
        (let ((env2 (match-pat-with cfg (first pats) (first vals) env)))
          (if (= env2 nil)
            nil
            (match-list-pat-with cfg (rest pats) (rest vals) env2)))))))
 (define match-pat (fn (pat val env) (match-pat-with canonical-cfg pat val env)))
--- a/lib/guest/pratt.sx
+++ b/lib/guest/pratt.sx
@@ -0,0 +1,28 @@
 ;; lib/guest/pratt.sx — operator-table format + lookup for Pratt-style
 ;; precedence climbing.
 ;;
 ;; The climbing loop stays per-language because the two canaries use
 ;; opposite conventions (Lua: higher prec = tighter; Prolog: lower prec =
 ;; tighter, with xfx/xfy/yfx assoc tags). Forcing a single loop adds
 ;; callback indirection that obscures more than it shares.
 ;;
 ;; What IS shared and gets extracted: the operator-table format and lookup.
 ;; "Grammar is a dict, not hardcoded cond."
 ;;
 ;; Entry shape: (NAME PREC ASSOC).
 ;;   NAME   — string, the operator's source token.
 ;;   PREC   — integer, in the host's own convention.
 ;;   ASSOC  — :left | :right | :none for languages with traditional
 ;;            associativity, or "xfx" / "xfy" / "yfx" for Prolog-style.
 (define
  pratt-op-lookup
  (fn (table name)
    (cond
      ((empty? table) nil)
      ((= (first (first table)) name) (first table))
      (:else (pratt-op-lookup (rest table) name)))))
 (define pratt-op-name  (fn (entry) (first entry)))
 (define pratt-op-prec  (fn (entry) (nth entry 1)))
 (define pratt-op-assoc (fn (entry) (nth entry 2)))
--- a/lib/guest/tests/ast.sx
+++ b/lib/guest/tests/ast.sx
@@ -0,0 +1,63 @@
 ;; lib/guest/tests/ast.sx — exercises every constructor / predicate /
 ;; accessor in lib/guest/ast.sx so future ports have a stable contract
 ;; to point at.
 (define gast-test-pass 0)
 (define gast-test-fail 0)
 (define gast-test-fails (list))
 (define
  gast-test
  (fn (name actual expected)
    (if (= actual expected)
      (set! gast-test-pass (+ gast-test-pass 1))
      (begin
        (set! gast-test-fail (+ gast-test-fail 1))
        (append! gast-test-fails {:name name :expected expected :actual actual})))))
 ;; Constructors round-trip.
 (gast-test "literal-int"    (ast-literal-value (ast-literal 42)) 42)
 (gast-test "literal-str"    (ast-literal-value (ast-literal "hi")) "hi")
 (gast-test "literal-bool"   (ast-literal-value (ast-literal true)) true)
 (gast-test "var-name"       (ast-var-name (ast-var "x")) "x")
 (gast-test "app-fn"         (ast-app-fn (ast-app (ast-var "f") (list (ast-literal 1)))) (ast-var "f"))
 (gast-test "app-args-len"   (len (ast-app-args (ast-app (ast-var "f") (list (ast-literal 1))))) 1)
 (gast-test "lambda-params"  (ast-lambda-params (ast-lambda (list "x" "y") (ast-var "x"))) (list "x" "y"))
 (gast-test "lambda-body"    (ast-lambda-body (ast-lambda (list "x") (ast-var "x"))) (ast-var "x"))
 (gast-test "let-bindings"   (len (ast-let-bindings (ast-let (list {:name "x" :value (ast-literal 1)}) (ast-var "x")))) 1)
 (gast-test "letrec-body"    (ast-letrec-body (ast-letrec (list) (ast-literal 0))) (ast-literal 0))
 (gast-test "if-test"        (ast-if-test (ast-if (ast-literal true) (ast-literal 1) (ast-literal 0))) (ast-literal true))
 (gast-test "if-then"        (ast-if-then (ast-if (ast-literal true) (ast-literal 1) (ast-literal 0))) (ast-literal 1))
 (gast-test "if-else"        (ast-if-else (ast-if (ast-literal true) (ast-literal 1) (ast-literal 0))) (ast-literal 0))
 (gast-test "match-pattern"  (ast-match-clause-pattern (ast-match-clause "P" (ast-literal 1))) "P")
 (gast-test "match-body"     (ast-match-clause-body (ast-match-clause "P" (ast-literal 1))) (ast-literal 1))
 (gast-test "module-name"    (ast-module-name (ast-module "m" (list))) "m")
 (gast-test "import-name"    (ast-import-name (ast-import "lib/foo")) "lib/foo")
 ;; Predicates fire only on matching kinds.
 (gast-test "is-literal"     (ast-literal? (ast-literal 1)) true)
 (gast-test "not-literal"    (ast-literal? (ast-var "x")) false)
 (gast-test "is-var"         (ast-var? (ast-var "x")) true)
 (gast-test "is-app"         (ast-app? (ast-app (ast-var "f") (list))) true)
 (gast-test "is-lambda"      (ast-lambda? (ast-lambda (list) (ast-literal 0))) true)
 (gast-test "is-let"         (ast-let? (ast-let (list) (ast-literal 0))) true)
 (gast-test "is-letrec"      (ast-letrec? (ast-letrec (list) (ast-literal 0))) true)
 (gast-test "is-if"          (ast-if? (ast-if (ast-literal true) (ast-literal 1) (ast-literal 0))) true)
 (gast-test "is-match"       (ast-match-clause? (ast-match-clause "P" (ast-literal 1))) true)
 (gast-test "is-module"      (ast-module? (ast-module "m" (list))) true)
 (gast-test "is-import"      (ast-import? (ast-import "x")) true)
 ;; ast? recognises any canonical node.
 (gast-test "ast?-literal"   (ast? (ast-literal 0)) true)
 (gast-test "ast?-foreign"   (ast? (list "lua-num" 0)) false)
 (gast-test "ast?-non-list"  (ast? 42) false)
 ;; ast-kind dispatch.
 (gast-test "kind-literal"   (ast-kind (ast-literal 0)) :literal)
 (gast-test "kind-import"    (ast-kind (ast-import "x")) :import)
 (define gast-tests-run!
  (fn ()
    {:passed gast-test-pass
     :failed gast-test-fail
     :total  (+ gast-test-pass gast-test-fail)}))
--- a/lib/guest/tests/hm.sx
+++ b/lib/guest/tests/hm.sx
@@ -0,0 +1,89 @@
 ;; lib/guest/tests/hm.sx — exercises lib/guest/hm.sx algebra.
 (define ghm-test-pass 0)
 (define ghm-test-fail 0)
 (define ghm-test-fails (list))
 (define
  ghm-test
  (fn (name actual expected)
    (if (= actual expected)
      (set! ghm-test-pass (+ ghm-test-pass 1))
      (begin
        (set! ghm-test-fail (+ ghm-test-fail 1))
        (append! ghm-test-fails {:name name :expected expected :actual actual})))))
 ;; ── Type constructors ─────────────────────────────────────────────
 (ghm-test "tv"           (hm-tv "a") (list :var "a"))
 (ghm-test "int"          (hm-int)    (list :ctor "Int" (list)))
 (ghm-test "arrow"        (ctor-head (hm-arrow (hm-int) (hm-bool))) "->")
 (ghm-test "arrow-args-len" (len (ctor-args (hm-arrow (hm-int) (hm-bool)))) 2)
 ;; ── Schemes ───────────────────────────────────────────────────────
 (ghm-test "scheme-vars"  (hm-scheme-vars (hm-scheme (list "a") (hm-tv "a"))) (list "a"))
 (ghm-test "monotype-vars" (hm-scheme-vars (hm-monotype (hm-int))) (list))
 (ghm-test "scheme?-yes"  (hm-scheme? (hm-monotype (hm-int))) true)
 (ghm-test "scheme?-no"   (hm-scheme? (hm-int)) false)
 ;; ── Fresh tyvars ──────────────────────────────────────────────────
 (ghm-test "fresh-1"
  (let ((c (list 0))) (var-name (hm-fresh-tv c))) "t1")
 (ghm-test "fresh-bumps"
  (let ((c (list 5))) (begin (hm-fresh-tv c) (first c))) 6)
 ;; ── Free type variables ──────────────────────────────────────────
 (ghm-test "ftv-int"      (hm-ftv (hm-int)) (list))
 (ghm-test "ftv-tv"       (hm-ftv (hm-tv "a")) (list "a"))
 (ghm-test "ftv-arrow"
  (len (hm-ftv (hm-arrow (hm-tv "a") (hm-arrow (hm-tv "b") (hm-tv "a"))))) 2)
 (ghm-test "ftv-scheme-quantified"
  (hm-ftv-scheme (hm-scheme (list "a") (hm-arrow (hm-tv "a") (hm-tv "b")))) (list "b"))
 (ghm-test "ftv-env"
  (let ((env (assoc {} "f" (hm-monotype (hm-arrow (hm-tv "x") (hm-tv "y"))))))
    (len (hm-ftv-env env))) 2)
 ;; ── Substitution / apply / compose ───────────────────────────────
 (ghm-test "apply-tv"
  (hm-apply (assoc {} "a" (hm-int)) (hm-tv "a")) (hm-int))
 (ghm-test "apply-arrow"
  (ctor-head
    (hm-apply (assoc {} "a" (hm-int))
              (hm-arrow (hm-tv "a") (hm-tv "b")))) "->")
 (ghm-test "compose-1-then-2"
  (var-name
    (hm-apply
      (hm-compose (assoc {} "b" (hm-tv "c")) (assoc {} "a" (hm-tv "b")))
      (hm-tv "a"))) "c")
 ;; ── Generalize / Instantiate ─────────────────────────────────────
 ;;   forall a. a -> a   instantiated twice yields fresh vars each time
 (ghm-test "generalize-id"
  (len (hm-scheme-vars (hm-generalize (hm-arrow (hm-tv "a") (hm-tv "a")) {}))) 1)
 (ghm-test "generalize-skips-env"
  ;; ftv(t)={a,b}, ftv(env)={a}, qs={b}
  (let ((env (assoc {} "x" (hm-monotype (hm-tv "a")))))
    (len (hm-scheme-vars
           (hm-generalize (hm-arrow (hm-tv "a") (hm-tv "b")) env)))) 1)
 (ghm-test "instantiate-fresh"
  (let ((s (hm-scheme (list "a") (hm-arrow (hm-tv "a") (hm-tv "a"))))
        (c (list 0)))
    (let ((t1 (hm-instantiate s c)) (t2 (hm-instantiate s c)))
      (not (= (var-name (first (ctor-args t1)))
              (var-name (first (ctor-args t2)))))))
  true)
 ;; ── Inference (literal only) ─────────────────────────────────────
 (ghm-test "infer-int"
  (ctor-head (get (hm-infer-literal (ast-literal 42)) :type)) "Int")
 (ghm-test "infer-string"
  (ctor-head (get (hm-infer-literal (ast-literal "hi")) :type)) "String")
 (ghm-test "infer-bool"
  (ctor-head (get (hm-infer-literal (ast-literal true)) :type)) "Bool")
 (define ghm-tests-run!
  (fn ()
    {:passed ghm-test-pass
     :failed ghm-test-fail
     :total  (+ ghm-test-pass ghm-test-fail)}))
--- a/lib/guest/tests/layout.sx
+++ b/lib/guest/tests/layout.sx
@@ -0,0 +1,180 @@
 ;; lib/guest/tests/layout.sx — synthetic Python-ish off-side fixture.
 ;;
 ;; Exercises lib/guest/layout.sx with a config different from Haskell's
 ;; (no module-prelude, layout opens via trailing `:` not via reserved
 ;; keyword) to prove the kit isn't Haskell-shaped.
 (define glayout-test-pass 0)
 (define glayout-test-fail 0)
 (define glayout-test-fails (list))
 (define
  glayout-test
  (fn (name actual expected)
    (if (= actual expected)
      (set! glayout-test-pass (+ glayout-test-pass 1))
      (begin
        (set! glayout-test-fail (+ glayout-test-fail 1))
        (append! glayout-test-fails {:name name :expected expected :actual actual})))))
 ;; Convenience: build a token from {type value line col}.
 (define
  glayout-tok
  (fn (ty val line col)
    {:type ty :value val :line line :col col}))
 ;; Project a token list to ((type value) ...) for compact comparison.
 (define
  glayout-shape
  (fn (toks)
    (map (fn (t) (list (get t :type) (get t :value))) toks)))
 ;; ── Haskell-flavour: keyword opens block ─────────────────────────
 (define
  glayout-haskell-cfg
  {:open-keywords (list "let" "where" "do" "of")
   :open-trailing-fn nil
   :open-token   {:type "vlbrace" :value "{"}
   :close-token  {:type "vrbrace" :value "}"}
   :sep-token    {:type "vsemi"   :value ";"}
   :module-prelude? false
   :explicit-open? (fn (tok) (= (get tok :type) "lbrace"))})
 ;;   do
 ;;     a
 ;;     b
 ;;   c       ← outside the do-block
 (glayout-test "haskell-do-block"
  (glayout-shape
    (layout-pass
      glayout-haskell-cfg
      (list (glayout-tok "reserved" "do" 1 1)
            (glayout-tok "ident" "a" 2 3)
            (glayout-tok "ident" "b" 3 3)
            (glayout-tok "ident" "c" 4 1))))
  (list (list "reserved" "do")
        (list "vlbrace" "{")
        (list "ident" "a")
        (list "vsemi" ";")
        (list "ident" "b")
        (list "vrbrace" "}")
        (list "ident" "c")))
 ;; Explicit `{` after `do` suppresses virtual layout.
 (glayout-test "haskell-explicit-brace"
  (glayout-shape
    (layout-pass
      glayout-haskell-cfg
      (list (glayout-tok "reserved" "do" 1 1)
            (glayout-tok "lbrace" "{" 1 4)
            (glayout-tok "ident" "a" 1 6)
            (glayout-tok "rbrace" "}" 1 8))))
  (list (list "reserved" "do")
        (list "lbrace" "{")
        (list "ident" "a")
        (list "rbrace" "}")))
 ;; Single-statement do-block on the same line.
 (glayout-test "haskell-do-inline"
  (glayout-shape
    (layout-pass
      glayout-haskell-cfg
      (list (glayout-tok "reserved" "do" 1 1)
            (glayout-tok "ident" "a" 1 4))))
  (list (list "reserved" "do")
        (list "vlbrace" "{")
        (list "ident" "a")
        (list "vrbrace" "}")))
 ;; Module-prelude: wrap whole input in implicit layout block at first
 ;; tok's column.
 (glayout-test "haskell-module-prelude"
  (glayout-shape
    (layout-pass
      (assoc glayout-haskell-cfg :module-prelude? true)
      (list (glayout-tok "ident" "x" 1 1)
            (glayout-tok "ident" "y" 2 1)
            (glayout-tok "ident" "z" 3 1))))
  (list (list "vlbrace" "{")
        (list "ident" "x")
        (list "vsemi" ";")
        (list "ident" "y")
        (list "vsemi" ";")
        (list "ident" "z")
        (list "vrbrace" "}")))
 ;; ── Python-flavour: trailing `:` opens block ─────────────────────
 (define
  glayout-python-cfg
  {:open-keywords (list)
   :open-trailing-fn (fn (tok) (and (= (get tok :type) "punct")
                                    (= (get tok :value) ":")))
   :open-token   {:type "indent" :value "INDENT"}
   :close-token  {:type "dedent" :value "DEDENT"}
   :sep-token    {:type "newline" :value "NEWLINE"}
   :module-prelude? false
   :explicit-open? nil})
 ;;   if x:
 ;;       a
 ;;       b
 ;;   c
 (glayout-test "python-if-block"
  (glayout-shape
    (layout-pass
      glayout-python-cfg
      (list (glayout-tok "reserved" "if" 1 1)
            (glayout-tok "ident" "x" 1 4)
            (glayout-tok "punct" ":" 1 5)
            (glayout-tok "ident" "a" 2 5)
            (glayout-tok "ident" "b" 3 5)
            (glayout-tok "ident" "c" 4 1))))
  (list (list "reserved" "if")
        (list "ident" "x")
        (list "punct" ":")
        (list "indent" "INDENT")
        (list "ident" "a")
        (list "newline" "NEWLINE")
        (list "ident" "b")
        (list "dedent" "DEDENT")
        (list "ident" "c")))
 ;; Nested Python-style blocks.
 ;;   def f():
 ;;       if x:
 ;;           a
 ;;       b
 (glayout-test "python-nested"
  (glayout-shape
    (layout-pass
      glayout-python-cfg
      (list (glayout-tok "reserved" "def" 1 1)
            (glayout-tok "ident" "f" 1 5)
            (glayout-tok "punct" "(" 1 6)
            (glayout-tok "punct" ")" 1 7)
            (glayout-tok "punct" ":" 1 8)
            (glayout-tok "reserved" "if" 2 5)
            (glayout-tok "ident" "x" 2 8)
            (glayout-tok "punct" ":" 2 9)
            (glayout-tok "ident" "a" 3 9)
            (glayout-tok "ident" "b" 4 5))))
  (list (list "reserved" "def")
        (list "ident" "f")
        (list "punct" "(")
        (list "punct" ")")
        (list "punct" ":")
        (list "indent" "INDENT")
        (list "reserved" "if")
        (list "ident" "x")
        (list "punct" ":")
        (list "indent" "INDENT")
        (list "ident" "a")
        (list "dedent" "DEDENT")
        (list "ident" "b")
        (list "dedent" "DEDENT")))
 (define glayout-tests-run!
  (fn ()
    {:passed glayout-test-pass
     :failed glayout-test-fail
     :total  (+ glayout-test-pass glayout-test-fail)}))
--- a/lib/guest/tests/match.sx
+++ b/lib/guest/tests/match.sx
@@ -0,0 +1,108 @@
 ;; lib/guest/tests/match.sx — exercises lib/guest/match.sx.
 (define gmatch-test-pass 0)
 (define gmatch-test-fail 0)
 (define gmatch-test-fails (list))
 (define
  gmatch-test
  (fn (name actual expected)
    (if (= actual expected)
      (set! gmatch-test-pass (+ gmatch-test-pass 1))
      (begin
        (set! gmatch-test-fail (+ gmatch-test-fail 1))
        (append! gmatch-test-fails {:name name :expected expected :actual actual})))))
 ;; ── walk / extend / occurs ────────────────────────────────────────
 (gmatch-test "walk-direct"
  (walk (mk-var "x") (extend "x" 5 (empty-subst))) 5)
 (gmatch-test "walk-chain"
  (walk (mk-var "a") (extend "a" (mk-var "b") (extend "b" 7 (empty-subst)))) 7)
 (gmatch-test "walk-no-binding"
  (let ((v (mk-var "u"))) (= (walk v (empty-subst)) v)) true)
 (gmatch-test "walk*-recursive"
  (walk* (mk-ctor "Just" (list (mk-var "x"))) (extend "x" 9 (empty-subst)))
  (mk-ctor "Just" (list 9)))
 (gmatch-test "occurs-direct"
  (occurs? "x" (mk-var "x") (empty-subst)) true)
 (gmatch-test "occurs-nested"
  (occurs? "x" (mk-ctor "f" (list (mk-var "x"))) (empty-subst)) true)
 (gmatch-test "occurs-not"
  (occurs? "x" (mk-var "y") (empty-subst)) false)
 ;; ── unify (symmetric) ─────────────────────────────────────────────
 (gmatch-test "unify-equal-literals"
  (len (unify 5 5 (empty-subst))) 0)
 (gmatch-test "unify-different-literals"
  (unify 5 6 (empty-subst)) nil)
 (gmatch-test "unify-var-literal"
  (get (unify (mk-var "x") 5 (empty-subst)) "x") 5)
 (gmatch-test "unify-literal-var"
  (get (unify 5 (mk-var "x") (empty-subst)) "x") 5)
 (gmatch-test "unify-same-var"
  (len (unify (mk-var "x") (mk-var "x") (empty-subst))) 0)
 (gmatch-test "unify-two-vars"
  (let ((s (unify (mk-var "x") (mk-var "y") (empty-subst))))
    (or (= (get s "x") (mk-var "y")) (= (get s "y") (mk-var "x")))) true)
 (gmatch-test "unify-ctor-equal"
  (len (unify (mk-ctor "f" (list 1 2)) (mk-ctor "f" (list 1 2)) (empty-subst))) 0)
 (gmatch-test "unify-ctor-with-var"
  (get (unify (mk-ctor "Just" (list (mk-var "x"))) (mk-ctor "Just" (list 7)) (empty-subst)) "x") 7)
 (gmatch-test "unify-ctor-head-mismatch"
  (unify (mk-ctor "Just" (list 1)) (mk-ctor "Nothing" (list)) (empty-subst)) nil)
 (gmatch-test "unify-ctor-arity-mismatch"
  (unify (mk-ctor "f" (list 1 2)) (mk-ctor "f" (list 1)) (empty-subst)) nil)
 (gmatch-test "unify-occurs-check"
  (unify (mk-var "x") (mk-ctor "f" (list (mk-var "x"))) (empty-subst)) nil)
 (gmatch-test "unify-transitive-vars"
  (let ((s (unify (mk-var "x") (mk-var "y") (empty-subst))))
    (let ((s2 (unify (mk-var "y") 42 s)))
      (walk (mk-var "x") s2))) 42)
 ;; ── match-pat (asymmetric) ────────────────────────────────────────
 (gmatch-test "match-var-binds"
  (get (match-pat (mk-var "x") 99 (empty-subst)) "x") 99)
 (gmatch-test "match-literal-equal"
  (len (match-pat 5 5 (empty-subst))) 0)
 (gmatch-test "match-literal-mismatch"
  (match-pat 5 6 (empty-subst)) nil)
 (gmatch-test "match-ctor-binds"
  (get (match-pat (mk-ctor "Just" (list (mk-var "y")))
                  (mk-ctor "Just" (list 11))
                  (empty-subst)) "y") 11)
 (gmatch-test "match-ctor-head-mismatch"
  (match-pat (mk-ctor "Just" (list (mk-var "y")))
             (mk-ctor "Nothing" (list))
             (empty-subst)) nil)
 (gmatch-test "match-ctor-arity-mismatch"
  (match-pat (mk-ctor "f" (list (mk-var "x") (mk-var "y")))
             (mk-ctor "f" (list 1))
             (empty-subst)) nil)
 (define gmatch-tests-run!
  (fn ()
    {:passed gmatch-test-pass
     :failed gmatch-test-fail
     :total  (+ gmatch-test-pass gmatch-test-fail)}))
--- a/lib/lua/parser.sx
+++ b/lib/lua/parser.sx
@@ -3,28 +3,33 @@
 (define lua-tok-value (fn (t) (if (= t nil) nil (get t :value))))
 (define
-  lua-binop-prec
+  lua-op-table
-  (fn
+  (list
-    (op)
+    (list "or"  1 :left)
-    (cond
+    (list "and" 2 :left)
-      ((= op "or") 1)
+    (list "<"   3 :left)
-      ((= op "and") 2)
+    (list ">"   3 :left)
-      ((= op "<") 3)
+    (list "<="  3 :left)
-      ((= op ">") 3)
+    (list ">="  3 :left)
-      ((= op "<=") 3)
+    (list "=="  3 :left)
-      ((= op ">=") 3)
+    (list "~="  3 :left)
-      ((= op "==") 3)
+    (list ".."  5 :right)
-      ((= op "~=") 3)
+    (list "+"   6 :left)
-      ((= op "..") 5)
+    (list "-"   6 :left)
-      ((= op "+") 6)
+    (list "*"   7 :left)
-      ((= op "-") 6)
+    (list "/"   7 :left)
-      ((= op "*") 7)
+    (list "%"   7 :left)
-      ((= op "/") 7)
+    (list "^"  10 :right)))
      ((= op "%") 7)
      ((= op "^") 10)
      (else 0))))
-(define lua-binop-right? (fn (op) (or (= op "..") (= op "^"))))
+(define lua-binop-prec
  (fn (op)
    (let ((entry (pratt-op-lookup lua-op-table op)))
      (if (= entry nil) 0 (pratt-op-prec entry)))))
 (define lua-binop-right?
  (fn (op)
    (let ((entry (pratt-op-lookup lua-op-table op)))
      (and (not (= entry nil)) (= (pratt-op-assoc entry) :right)))))
 (define
  lua-parse
--- a/lib/lua/test.sh
+++ b/lib/lua/test.sh
@@ -30,6 +30,7 @@ cat > "$TMPFILE" << 'EPOCHS'
 (epoch 1)
 (load "lib/guest/lex.sx")
 (load "lib/guest/prefix.sx")
 (load "lib/guest/pratt.sx")
 (load "lib/lua/tokenizer.sx")
 (epoch 2)
 (load "lib/lua/parser.sx")
--- a/lib/ocaml/baseline/abundant.ml
+++ b/lib/ocaml/baseline/abundant.ml
@@ -0,0 +1,23 @@
 let div_sum n =
  let s = ref 1 in
  let i = ref 2 in
  while !i * !i <= n do
    if n mod !i = 0 then begin
      s := !s + !i;
      let q = n / !i in
      if q <> !i then s := !s + q
    end;
    i := !i + 1
  done;
  if n = 1 then 0 else !s
 let count_abundant n =
  let c = ref 0 in
  for i = 12 to n - 1 do
    if div_sum i > i then c := !c + 1
  done;
  !c
 ;;
 count_abundant 100
--- a/lib/ocaml/baseline/ackermann.ml
+++ b/lib/ocaml/baseline/ackermann.ml
@@ -0,0 +1,8 @@
 let rec ack m n =
  if m = 0 then n + 1
  else if n = 0 then ack (m - 1) 1
  else ack (m - 1) (ack m (n - 1))
 ;;
 ack 3 4
--- a/lib/ocaml/baseline/activity_select.ml
+++ b/lib/ocaml/baseline/activity_select.ml
@@ -0,0 +1,31 @@
 let max_nonoverlap intervals =
  let arr = Array.of_list intervals in
  let n = Array.length arr in
  let sorted = Array.make n (0, 0) in
  for i = 0 to n - 1 do
    sorted.(i) <- arr.(i)
  done;
  for i = 0 to n - 1 do
    for j = 0 to n - 2 - i do
      let (_, e1) = sorted.(j) in
      let (_, e2) = sorted.(j + 1) in
      if e1 > e2 then begin
        let t = sorted.(j) in
        sorted.(j) <- sorted.(j + 1);
        sorted.(j + 1) <- t
      end
    done
  done;
  let count = ref 0 in
  let last_end = ref (-1000000) in
  for i = 0 to n - 1 do
    let (s, e) = sorted.(i) in
    if s >= !last_end then begin
      count := !count + 1;
      last_end := e
    end
  done;
  !count
 ;;
 max_nonoverlap [(1, 4); (3, 5); (0, 6); (5, 7); (3, 8); (5, 9); (6, 10); (8, 11); (8, 12); (2, 13); (12, 14)]
--- a/lib/ocaml/baseline/adler32.ml
+++ b/lib/ocaml/baseline/adler32.ml
@@ -0,0 +1,13 @@
 let adler32 s =
  let a = ref 1 in
  let b = ref 0 in
  let m = 65521 in
  for i = 0 to String.length s - 1 do
    a := (!a + Char.code s.[i]) mod m;
    b := (!b + !a) mod m
  done;
  !b * 65536 + !a
 ;;
 adler32 "Wikipedia"
--- a/lib/ocaml/baseline/anagram_check.ml
+++ b/lib/ocaml/baseline/anagram_check.ml
@@ -0,0 +1,23 @@
 let to_counts s =
  let counts = Array.make 256 0 in
  for i = 0 to String.length s - 1 do
    let c = Char.code s.[i] in
    counts.(c) <- counts.(c) + 1
  done;
  counts
 let same_counts a b =
  let result = ref true in
  for i = 0 to 255 do
    if a.(i) <> b.(i) then result := false
  done;
  !result
 let is_anagram s t = same_counts (to_counts s) (to_counts t)
 ;;
 (if is_anagram "listen" "silent" then 1 else 0) +
 (if is_anagram "hello" "world" then 1 else 0) +
 (if is_anagram "anagram" "nagaram" then 1 else 0) +
 (if is_anagram "abc" "abcd" then 1 else 0)
--- a/lib/ocaml/baseline/anagram_groups.ml
+++ b/lib/ocaml/baseline/anagram_groups.ml
@@ -0,0 +1,29 @@
 let canonical s =
  let chars = Array.make 26 0 in
  for i = 0 to String.length s - 1 do
    let k = Char.code s.[i] - Char.code 'a' in
    if k >= 0 && k < 26 then chars.(k) <- chars.(k) + 1
  done;
  let buf = Buffer.create 26 in
  for i = 0 to 25 do
    for _ = 1 to chars.(i) do
      Buffer.add_string buf (String.make 1 (Char.chr (i + Char.code 'a')))
    done
  done;
  Buffer.contents buf
 let group_anagrams xs =
  let h = Hashtbl.create 8 in
  List.iter (fun s ->
    let k = canonical s in
    let cur = match Hashtbl.find_opt h k with
              | Some xs -> xs
              | None -> []
    in
    Hashtbl.replace h k (s :: cur)
  ) xs;
  Hashtbl.length h
 ;;
 group_anagrams ["eat"; "tea"; "tan"; "ate"; "nat"; "bat"]
--- a/lib/ocaml/baseline/anagrams.ml
+++ b/lib/ocaml/baseline/anagrams.ml
@@ -0,0 +1,26 @@
 (* Baseline: count anagram groups using Hashtbl + sort *)
 (* Sort the chars in a string to get its anagram-equivalence key *)
 let canonical s =
  let n = String.length s in
  let chars = ref [] in
  for i = 0 to n - 1 do
    chars := (String.get s i) :: !chars
  done ;
  let sorted = List.sort compare !chars in
  String.concat "" sorted
 ;;
 let count_groups words =
  let counts = Hashtbl.create 16 in
  List.iter
    (fun w ->
      let k = canonical w in
      match Hashtbl.find_opt counts k with
      | None -> Hashtbl.add counts k 1
      | Some n -> Hashtbl.replace counts k (n + 1))
    words ;
  Hashtbl.length counts
 ;;
 count_groups ["eat"; "tea"; "tan"; "ate"; "nat"; "bat"]
--- a/lib/ocaml/baseline/atm.ml
+++ b/lib/ocaml/baseline/atm.ml
@@ -0,0 +1,17 @@
 type account = { mutable balance : int }
 exception Insufficient
 let withdraw acct amt =
  if amt > acct.balance then raise Insufficient
  else acct.balance <- acct.balance - amt
 let deposit acct amt = acct.balance <- acct.balance + amt
 ;;
 let a = { balance = 100 } in
 deposit a 50;
 withdraw a 30;
 try (withdraw a 200; -1)
 with Insufficient -> a.balance
--- a/lib/ocaml/baseline/bag.ml
+++ b/lib/ocaml/baseline/bag.ml
@@ -0,0 +1,18 @@
 let count_words text =
  let words = String.split_on_char ' ' text in
  let counts = Hashtbl.create 8 in
  List.iter (fun w ->
    let n = match Hashtbl.find_opt counts w with
            | Some n -> n + 1
            | None -> 1
    in
    Hashtbl.replace counts w n
  ) words;
  counts
 let max_count counts =
  Hashtbl.fold (fun _ v acc -> if v > acc then v else acc) counts 0
 ;;
 max_count (count_words "the quick brown fox jumps over the lazy dog the fox")
--- a/lib/ocaml/baseline/balance.ml
+++ b/lib/ocaml/baseline/balance.ml
@@ -0,0 +1,25 @@
 let is_balanced s =
  let stack = Stack.create () in
  let n = String.length s in
  let ok = ref true in
  let i = ref 0 in
  while !i < n && !ok do
    let c = s.[!i] in
    (if c = '(' || c = '[' || c = '{' then Stack.push c stack
     else if c = ')' then
       (if Stack.is_empty stack || Stack.pop stack <> '(' then ok := false)
     else if c = ']' then
       (if Stack.is_empty stack || Stack.pop stack <> '[' then ok := false)
     else if c = '}' then
       (if Stack.is_empty stack || Stack.pop stack <> '{' then ok := false));
    i := !i + 1
  done;
  !ok && Stack.is_empty stack
 ;;
 (if is_balanced "({[abc]d}e)" then 1 else 0) +
 (if is_balanced "(a]" then 1 else 0) +
 (if is_balanced "{[}]" then 1 else 0) +
 (if is_balanced "(())" then 1 else 0) +
 (if is_balanced "" then 1 else 0)
--- a/lib/ocaml/baseline/base_n.ml
+++ b/lib/ocaml/baseline/base_n.ml
@@ -0,0 +1,19 @@
 let to_base_n n base =
  let digits = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ" in
  if n = 0 then "0"
  else begin
    let m = ref (abs n) in
    let acc = ref "" in
    while !m > 0 do
      acc := String.make 1 digits.[!m mod base] ^ !acc;
      m := !m / base
    done;
    if n < 0 then "-" ^ !acc else !acc
  end
 ;;
 String.length (to_base_n 255 16) +
 String.length (to_base_n 1024 2) +
 String.length (to_base_n 100 10) +
 String.length (to_base_n 0 16)
--- a/lib/ocaml/baseline/bf_full.ml
+++ b/lib/ocaml/baseline/bf_full.ml
@@ -0,0 +1,42 @@
 let interpret prog =
  let mem = Array.make 256 0 in
  let ptr = ref 0 in
  let pc = ref 0 in
  let n = String.length prog in
  let acc = ref 0 in
  while !pc < n do
    let c = prog.[!pc] in
    (if c = '>' then ptr := !ptr + 1
     else if c = '<' then ptr := !ptr - 1
     else if c = '+' then mem.(!ptr) <- mem.(!ptr) + 1
     else if c = '-' then mem.(!ptr) <- mem.(!ptr) - 1
     else if c = '.' then acc := !acc + mem.(!ptr)
     else if c = '[' then begin
       if mem.(!ptr) = 0 then begin
         let depth = ref 1 in
         while !depth > 0 do
           pc := !pc + 1;
           let c = prog.[!pc] in
           if c = '[' then depth := !depth + 1
           else if c = ']' then depth := !depth - 1
         done
       end
     end
     else if c = ']' then begin
       if mem.(!ptr) <> 0 then begin
         let depth = ref 1 in
         while !depth > 0 do
           pc := !pc - 1;
           let c = prog.[!pc] in
           if c = ']' then depth := !depth + 1
           else if c = '[' then depth := !depth - 1
         done
       end
     end);
    pc := !pc + 1
  done;
  !acc
 ;;
 interpret "+++[.-]"
--- a/lib/ocaml/baseline/bfs.ml
+++ b/lib/ocaml/baseline/bfs.ml
@@ -0,0 +1,43 @@
 (* Baseline: graph BFS using Queue + Hashtbl visited set.
   Returns the count of reachable nodes. *)
 (* Adjacency as an assoc list of (node, neighbors). *)
 let graph =
  [ ("A", ["B"; "C"])
  ; ("B", ["D"])
  ; ("C", ["D"; "E"])
  ; ("D", ["F"])
  ; ("E", ["F"])
  ; ("F", [])
  ]
 ;;
 let neighbors n =
  match List.assoc_opt n graph with
  | None -> []
  | Some ns -> ns
 ;;
 let bfs start =
  let visited = Hashtbl.create 16 in
  let q = Queue.create () in
  Queue.push start q ;
  Hashtbl.add visited start true ;
  let rec loop () =
    if Queue.is_empty q then ()
    else
      let v = Queue.pop q in
      List.iter
        (fun n ->
          if not (Hashtbl.mem visited n) then begin
            Hashtbl.add visited n true ;
            Queue.push n q
          end)
        (neighbors v) ;
      loop ()
  in
  loop () ;
  Hashtbl.length visited
 ;;
 bfs "A"
--- a/lib/ocaml/baseline/bfs_grid.ml
+++ b/lib/ocaml/baseline/bfs_grid.ml
@@ -0,0 +1,42 @@
 let h = 5
 let w = 5
 let grid = [|
  [| 0; 0; 1; 0; 0 |];
  [| 1; 0; 1; 0; 1 |];
  [| 0; 0; 0; 0; 0 |];
  [| 0; 1; 1; 1; 0 |];
  [| 0; 0; 0; 0; 0 |]
 |]
 let step dist q r c nr nc =
  if nr >= 0 && nr < h && nc >= 0 && nc < w
     && grid.(nr).(nc) = 0 && dist.(nr).(nc) = -1 then begin
    dist.(nr).(nc) <- dist.(r).(c) + 1;
    Queue.push (nr * 10 + nc) q
  end
 let bfs sr sc tr tc =
  let dist = Array.init h (fun _ -> Array.make w (-1)) in
  let q = Queue.create () in
  dist.(sr).(sc) <- 0;
  Queue.push (sr * 10 + sc) q;
  let go = ref true in
  while !go do
    if Queue.is_empty q then go := false
    else if dist.(tr).(tc) <> -1 then go := false
    else begin
      let rc = Queue.pop q in
      let r = rc / 10 in
      let c = rc mod 10 in
      step dist q r c (r - 1) c;
      step dist q r c (r + 1) c;
      step dist q r c r (c - 1);
      step dist q r c r (c + 1)
    end
  done;
  dist.(tr).(tc)
 ;;
 bfs 0 0 4 4
--- a/lib/ocaml/baseline/bigint_add.ml
+++ b/lib/ocaml/baseline/bigint_add.ml
@@ -0,0 +1,24 @@
 let bigint_add a b =
  let rec aux a b carry =
    match (a, b) with
    | ([], []) -> if carry = 0 then [] else [carry]
    | (x :: xs, []) ->
      let s = x + carry in
      (s mod 10) :: aux xs [] (s / 10)
    | ([], y :: ys) ->
      let s = y + carry in
      (s mod 10) :: aux [] ys (s / 10)
    | (x :: xs, y :: ys) ->
      let s = x + y + carry in
      (s mod 10) :: aux xs ys (s / 10)
  in
  aux a b 0
 ;;
 let r1 = bigint_add [9;9;9] [1] in
 let r2 = bigint_add [5;6;7] [8;9;1] in
 let r3 = bigint_add [9;9;9;9;9;9;9;9] [1] in
 List.fold_left (+) 0 r1
  + List.fold_left (+) 0 r2
  + List.length r3
--- a/lib/ocaml/baseline/binary_heap.ml
+++ b/lib/ocaml/baseline/binary_heap.ml
@@ -0,0 +1,47 @@
 let parent i = (i - 1) / 2
 let lchild i = 2 * i + 1
 let rchild i = 2 * i + 2
 let swap a i j =
  let t = a.(i) in
  a.(i) <- a.(j);
  a.(j) <- t
 let rec sift_up a i =
  if i > 0 && a.(parent i) > a.(i) then begin
    swap a i (parent i);
    sift_up a (parent i)
  end
 let rec sift_down a n i =
  let l = lchild i and r = rchild i in
  let smallest = ref i in
  if l < n && a.(l) < a.(!smallest) then smallest := l;
  if r < n && a.(r) < a.(!smallest) then smallest := r;
  if !smallest <> i then begin
    swap a i !smallest;
    sift_down a n !smallest
  end
 let push a size x =
  a.(!size) <- x;
  size := !size + 1;
  sift_up a (!size - 1)
 let pop a size =
  let m = a.(0) in
  size := !size - 1;
  a.(0) <- a.(!size);
  sift_down a !size 0;
  m
 ;;
 let a = Array.make 20 0 in
 let s = ref 0 in
 List.iter (fun x -> push a s x) [9; 4; 7; 1; 8; 3; 5; 2; 6];
 let total = ref 0 in
 for _ = 1 to 9 do
  total := !total * 10 + pop a s
 done;
 !total
--- a/lib/ocaml/baseline/bipartite.ml
+++ b/lib/ocaml/baseline/bipartite.ml
@@ -0,0 +1,39 @@
 let is_bipartite n adj =
  let color = Array.make n (-1) in
  let ok = ref true in
  let q = Queue.create () in
  for src = 0 to n - 1 do
    if color.(src) = -1 then begin
      color.(src) <- 0;
      Queue.push src q;
      while not (Queue.is_empty q) do
        let u = Queue.pop q in
        List.iter (fun v ->
          if color.(v) = -1 then begin
            color.(v) <- 1 - color.(u);
            Queue.push v q
          end else if color.(v) = color.(u) then
            ok := false
        ) adj.(u)
      done
    end
  done;
  let zeros = ref 0 in
  for i = 0 to n - 1 do
    if color.(i) = 0 then zeros := !zeros + 1
  done;
  if !ok then !zeros else -1
 ;;
 let n = 7 in
 let adj = [|
  [1; 3];
  [0; 2; 4];
  [1; 5];
  [0; 4; 6];
  [1; 3];
  [2; 6];
  [3; 5]
 |] in
 is_bipartite n adj
--- a/lib/ocaml/baseline/bisect.ml
+++ b/lib/ocaml/baseline/bisect.ml
@@ -0,0 +1,13 @@
 let bisect f lo hi =
  let lo = ref lo and hi = ref hi in
  for _ = 1 to 50 do
    let mid = (!lo +. !hi) /. 2.0 in
    if f mid = 0.0 || f !lo *. f mid < 0.0 then hi := mid
    else lo := mid
  done;
  !lo
 ;;
 let r = bisect (fun x -> x *. x -. 2.0) 1.0 2.0 in
 int_of_float (r *. 100.0)
--- a/lib/ocaml/baseline/bits.ml
+++ b/lib/ocaml/baseline/bits.ml
@@ -0,0 +1,12 @@
 let popcount n =
  let count = ref 0 in
  let m = ref n in
  while !m > 0 do
    if !m land 1 = 1 then count := !count + 1;
    m := !m lsr 1
  done;
  !count
 ;;
 popcount 1023 + popcount 5 + popcount 1024 + popcount 0xff
--- a/lib/ocaml/baseline/bowling.ml
+++ b/lib/ocaml/baseline/bowling.ml
@@ -0,0 +1,24 @@
 let bowling_score frames =
  let arr = Array.of_list frames in
  let n = Array.length arr in
  let total = ref 0 in
  let i = ref 0 in
  let frame = ref 1 in
  while !frame <= 10 && !i < n do
    if arr.(!i) = 10 then begin
      total := !total + 10 + arr.(!i + 1) + arr.(!i + 2);
      i := !i + 1
    end else if !i + 1 < n && arr.(!i) + arr.(!i + 1) = 10 then begin
      total := !total + 10 + arr.(!i + 2);
      i := !i + 2
    end else begin
      total := !total + arr.(!i) + arr.(!i + 1);
      i := !i + 2
    end;
    frame := !frame + 1
  done;
  !total
 ;;
 bowling_score [10; 7; 3; 9; 0; 10; 0; 8; 8; 2; 0; 6; 10; 10; 10; 8; 1]
--- a/lib/ocaml/baseline/bracket_match.ml
+++ b/lib/ocaml/baseline/bracket_match.ml
@@ -0,0 +1,32 @@
 let bracket_match s =
  let n = String.length s in
  let stack = ref [] in
  let ok = ref true in
  let i = ref 0 in
  while !ok && !i < n do
    let c = s.[!i] in
    if c = '(' || c = '[' || c = '{' then
      stack := c :: !stack
    else if c = ')' || c = ']' || c = '}' then begin
      match !stack with
      | [] -> ok := false
      | top :: rest ->
        let pair =
          (c = ')' && top = '(') ||
          (c = ']' && top = '[') ||
          (c = '}' && top = '{')
        in
        if pair then stack := rest else ok := false
    end;
    i := !i + 1
  done;
  if !ok && !stack = [] then 1 else 0
 ;;
 let strings = ["()"; "[{()}]"; "({[}])"; ""; "(("; "()[](){}"; "(a(b)c)"; "(()"; "])"] in
 let count = ref 0 in
 List.iter (fun s ->
  count := !count + bracket_match s
 ) strings;
 !count
--- a/lib/ocaml/baseline/brainfuck.ml
+++ b/lib/ocaml/baseline/brainfuck.ml
@@ -0,0 +1,20 @@
 let interpret prog =
  let mem = Array.make 256 0 in
  let ptr = ref 0 in
  let pc = ref 0 in
  let n = String.length prog in
  let acc = ref 0 in
  while !pc < n do
    let c = prog.[!pc] in
    (if c = '>' then ptr := !ptr + 1
     else if c = '<' then ptr := !ptr - 1
     else if c = '+' then mem.(!ptr) <- mem.(!ptr) + 1
     else if c = '-' then mem.(!ptr) <- mem.(!ptr) - 1
     else if c = '.' then acc := !acc + mem.(!ptr));
    pc := !pc + 1
  done;
  !acc
 ;;
 interpret "+++++.+++++.+++++.+++++.+++++."
--- a/lib/ocaml/baseline/bs_bounds.ml
+++ b/lib/ocaml/baseline/bs_bounds.ml
@@ -0,0 +1,27 @@
 let lower_bound arr x =
  let lo = ref 0 and hi = ref (Array.length arr) in
  while !lo < !hi do
    let mid = (!lo + !hi) / 2 in
    if arr.(mid) < x then lo := mid + 1
    else hi := mid
  done;
  !lo
 let upper_bound arr x =
  let lo = ref 0 and hi = ref (Array.length arr) in
  while !lo < !hi do
    let mid = (!lo + !hi) / 2 in
    if arr.(mid) <= x then lo := mid + 1
    else hi := mid
  done;
  !lo
 ;;
 let a = [| 1; 2; 2; 3; 3; 3; 5; 7; 9 |] in
 let cnt3 = upper_bound a 3 - lower_bound a 3 in
 let cnt2 = upper_bound a 2 - lower_bound a 2 in
 let cnt5 = upper_bound a 5 - lower_bound a 5 in
 let cnt9 = upper_bound a 9 - lower_bound a 9 in
 let cnt4 = upper_bound a 4 - lower_bound a 4 in
 cnt3 * 1000 + cnt2 * 100 + cnt5 * 10 + cnt9 + cnt4
--- a/lib/ocaml/baseline/bs_rotated.ml
+++ b/lib/ocaml/baseline/bs_rotated.ml
@@ -0,0 +1,25 @@
 let bs_rotated arr target =
  let lo = ref 0 in
  let hi = ref (Array.length arr - 1) in
  let result = ref (-1) in
  while !lo <= !hi && !result = -1 do
    let mid = (!lo + !hi) / 2 in
    if arr.(mid) = target then result := mid
    else if arr.(!lo) <= arr.(mid) then begin
      if target >= arr.(!lo) && target < arr.(mid) then
        hi := mid - 1
      else
        lo := mid + 1
    end else begin
      if target > arr.(mid) && target <= arr.(!hi) then
        lo := mid + 1
      else
        hi := mid - 1
    end
  done;
  !result
 ;;
 let a = [| 4; 5; 6; 7; 0; 1; 2 |] in
 bs_rotated a 0 + bs_rotated a 7 * 10 + bs_rotated a 3 * 100
--- a/lib/ocaml/baseline/bsearch.ml
+++ b/lib/ocaml/baseline/bsearch.ml
@@ -0,0 +1,16 @@
 let bsearch arr target =
  let n = Array.length arr in
  let lo = ref 0 and hi = ref (n - 1) in
  let found = ref (-1) in
  while !lo <= !hi && !found = -1 do
    let mid = (!lo + !hi) / 2 in
    if arr.(mid) = target then found := mid
    else if arr.(mid) < target then lo := mid + 1
    else hi := mid - 1
  done;
  !found
 ;;
 let a = Array.of_list [1;3;5;7;9;11;13;15;17;19;21] in
 bsearch a 13 + bsearch a 5 + bsearch a 100
--- a/lib/ocaml/baseline/btree.ml
+++ b/lib/ocaml/baseline/btree.ml
@@ -0,0 +1,25 @@
 (* Baseline: binary search tree with insert + in-order traversal *)
 type 'a tree =
  | Leaf
  | Node of 'a * 'a tree * 'a tree
 ;;
 let rec insert x t =
  match t with
  | Leaf -> Node (x, Leaf, Leaf)
  | Node (v, l, r) ->
    if x < v then Node (v, insert x l, r)
    else if x > v then Node (v, l, insert x r)
    else t
 ;;
 let rec inorder t =
  match t with
  | Leaf -> []
  | Node (v, l, r) -> List.append (inorder l) (v :: inorder r)
 ;;
 let from_list xs = List.fold_left (fun t x -> insert x t) Leaf xs ;;
 let t = from_list [5; 3; 8; 1; 4; 7; 9; 2] ;;
 List.fold_left (fun a b -> a + b) 0 (inorder t)
--- a/lib/ocaml/baseline/caesar.ml
+++ b/lib/ocaml/baseline/caesar.ml
@@ -0,0 +1,14 @@
 let shift_char c k =
  let n = Char.code c in
  if n >= 97 && n <= 122 then
    Char.chr (((n - 97 + k) mod 26 + 26) mod 26 + 97)
  else c
 let encode s k =
  String.init (String.length s) (fun i -> shift_char s.[i] k)
 ;;
 (* ROT13 round-trip: encode (encode "hello" 13) 13 = "hello".
   Sum the codes of two chars to give a deterministic integer check. *)
 let r = encode (encode "hello" 13) 13 in
 Char.code r.[0] + Char.code r.[4]
--- a/lib/ocaml/baseline/calc.ml
+++ b/lib/ocaml/baseline/calc.ml
@@ -0,0 +1,76 @@
 (* Baseline: recursive-descent calculator for "+", "*", parens, ints. *)
 type expr =
  | Lit of int
  | Add of expr * expr
  | Mul of expr * expr
 ;;
 let parse_input src =
  let pos = ref 0 in
  let peek () = if !pos < String.length src then String.get src !pos else "" in
  let advance () = pos := !pos + 1 in
  let skip_ws () =
    while !pos < String.length src && peek () = " " do advance () done
  in
  let rec parse_atom () =
    skip_ws () ;
    if peek () = "(" then begin
      advance () ;
      let e = parse_expr () in
      skip_ws () ;
      advance () ; (* consume ')' *)
      e
    end
    else
      let start = !pos in
      let rec digits () =
        if !pos < String.length src then
          let c = peek () in
          if c >= "0" && c <= "9" then begin advance () ; digits () end
          else ()
      in
      digits () ;
      let n = Int.of_string (String.sub src start (!pos - start)) in
      Lit n
  and parse_term () =
    skip_ws () ;
    let lhs = ref (parse_atom ()) in
    let rec loop () =
      skip_ws () ;
      if peek () = "*" then begin
        advance () ;
        lhs := Mul (!lhs, parse_atom ()) ;
        loop ()
      end
    in
    loop () ;
    !lhs
  and parse_expr () =
    skip_ws () ;
    let lhs = ref (parse_term ()) in
    let rec loop () =
      skip_ws () ;
      if peek () = "+" then begin
        advance () ;
        lhs := Add (!lhs, parse_term ()) ;
        loop ()
      end
    in
    loop () ;
    !lhs
  in
  parse_expr ()
 ;;
 let rec eval e =
  match e with
  | Lit n -> n
  | Add (a, b) -> eval a + eval b
  | Mul (a, b) -> eval a * eval b
 ;;
 (* (1 + 2) * 3 + 4 = 9 + 4 = 13 *)
 eval (parse_input "(1 + 2) * 3 + 4")
--- a/lib/ocaml/baseline/catalan.ml
+++ b/lib/ocaml/baseline/catalan.ml
@@ -0,0 +1,13 @@
 let catalan n =
  let dp = Array.make (n + 1) 0 in
  dp.(0) <- 1;
  for i = 1 to n do
    for j = 0 to i - 1 do
      dp.(i) <- dp.(i) + dp.(j) * dp.(i - 1 - j)
    done
  done;
  dp.(n)
 ;;
 catalan 5
--- a/lib/ocaml/baseline/closures.ml
+++ b/lib/ocaml/baseline/closures.ml
@@ -0,0 +1,5 @@
 (* Baseline: closures + curried application *)
 let make_adder n = fun x -> n + x ;;
 let add5 = make_adder 5 ;;
 let add10 = make_adder 10 ;;
 add5 100 + add10 200
--- a/lib/ocaml/baseline/coin_change.ml
+++ b/lib/ocaml/baseline/coin_change.ml
@@ -0,0 +1,15 @@
 let coin_change coins target =
  let dp = Array.make (target + 1) (target + 1) in
  dp.(0) <- 0;
  for i = 1 to target do
    List.iter (fun c ->
      if c <= i && dp.(i - c) + 1 < dp.(i) then
        dp.(i) <- dp.(i - c) + 1
    ) coins
  done;
  if dp.(target) > target then -1
  else dp.(target)
 ;;
 coin_change [1; 5; 10; 25] 67
--- a/lib/ocaml/baseline/coin_min.ml
+++ b/lib/ocaml/baseline/coin_min.ml
@@ -0,0 +1,16 @@
 let coin_min coins amount =
  let dp = Array.make (amount + 1) (-1) in
  dp.(0) <- 0;
  for i = 1 to amount do
    List.iter (fun c ->
      if c <= i && dp.(i - c) >= 0 then begin
        let cand = dp.(i - c) + 1 in
        if dp.(i) < 0 || cand < dp.(i) then dp.(i) <- cand
      end
    ) coins
  done;
  dp.(amount)
 ;;
 coin_min [1; 5; 10; 25] 67
--- a/lib/ocaml/baseline/combinations.ml
+++ b/lib/ocaml/baseline/combinations.ml
@@ -0,0 +1,12 @@
 let rec choose k xs =
  if k = 0 then [[]]
  else
    match xs with
    | [] -> []
    | h :: rest ->
      List.map (fun c -> h :: c) (choose (k - 1) rest)
      @ choose k rest
 ;;
 List.length (choose 4 [1; 2; 3; 4; 5; 6; 7; 8; 9])
--- a/lib/ocaml/baseline/convex_hull.ml
+++ b/lib/ocaml/baseline/convex_hull.ml
@@ -0,0 +1,43 @@
 let cross ox oy ax ay bx by =
  (ax - ox) * (by - oy) - (ay - oy) * (bx - ox)
 let hull_size pts =
  let n = List.length pts in
  if n < 3 then n
  else begin
    let sorted = List.sort (fun (a, b) (c, d) ->
      if a <> c then compare a c else compare b d) pts in
    let arr = Array.of_list sorted in
    let h = Array.make (2 * n) (0, 0) in
    let k = ref 0 in
    for i = 0 to n - 1 do
      let (xi, yi) = arr.(i) in
      let cont = ref true in
      while !cont && !k >= 2 do
        let (ox, oy) = h.(!k - 2) in
        let (ax, ay) = h.(!k - 1) in
        if cross ox oy ax ay xi yi <= 0 then k := !k - 1
        else cont := false
      done;
      h.(!k) <- (xi, yi);
      k := !k + 1
    done;
    let lo = !k + 1 in
    for i = n - 2 downto 0 do
      let (xi, yi) = arr.(i) in
      let cont = ref true in
      while !cont && !k >= lo do
        let (ox, oy) = h.(!k - 2) in
        let (ax, ay) = h.(!k - 1) in
        if cross ox oy ax ay xi yi <= 0 then k := !k - 1
        else cont := false
      done;
      h.(!k) <- (xi, yi);
      k := !k + 1
    done;
    !k - 1
  end
 ;;
 hull_size [(0, 0); (1, 1); (2, 0); (2, 2); (0, 2); (1, 0); (3, 3); (5, 1)]
--- a/lib/ocaml/baseline/count_bits.ml
+++ b/lib/ocaml/baseline/count_bits.ml
@@ -0,0 +1,14 @@
 let count_bits n =
  let result = Array.make (n + 1) 0 in
  for i = 1 to n do
    result.(i) <- result.(i / 2) + (i mod 2)
  done;
  let sum = ref 0 in
  for i = 0 to n do
    sum := !sum + result.(i)
  done;
  !sum
 ;;
 count_bits 100
--- a/lib/ocaml/baseline/count_change.ml
+++ b/lib/ocaml/baseline/count_change.ml
@@ -0,0 +1,13 @@
 let count_ways coins target =
  let dp = Array.make (target + 1) 0 in
  dp.(0) <- 1;
  List.iter (fun c ->
    for i = c to target do
      dp.(i) <- dp.(i) + dp.(i - c)
    done
  ) coins;
  dp.(target)
 ;;
 count_ways [1; 2; 5; 10; 25] 50
--- a/lib/ocaml/baseline/count_inversions.ml
+++ b/lib/ocaml/baseline/count_inversions.ml
@@ -0,0 +1,42 @@
 let count_inv arr =
  let n = Array.length arr in
  let temp = Array.make n 0 in
  let count = ref 0 in
  let rec merge lo mid hi =
    let i = ref lo and j = ref (mid + 1) and k = ref lo in
    while !i <= mid && !j <= hi do
      if arr.(!i) <= arr.(!j) then begin
        temp.(!k) <- arr.(!i);
        i := !i + 1
      end else begin
        temp.(!k) <- arr.(!j);
        count := !count + (mid - !i + 1);
        j := !j + 1
      end;
      k := !k + 1
    done;
    while !i <= mid do
      temp.(!k) <- arr.(!i);
      i := !i + 1; k := !k + 1
    done;
    while !j <= hi do
      temp.(!k) <- arr.(!j);
      j := !j + 1; k := !k + 1
    done;
    for x = lo to hi do
      arr.(x) <- temp.(x)
    done
  and sort lo hi =
    if lo < hi then begin
      let mid = (lo + hi) / 2 in
      sort lo mid;
      sort (mid + 1) hi;
      merge lo mid hi
    end
  in
  sort 0 (n - 1);
  !count
 ;;
 count_inv [|8; 4; 2; 1; 3; 5; 7; 6|]
--- a/lib/ocaml/baseline/count_palindromes.ml
+++ b/lib/ocaml/baseline/count_palindromes.ml
@@ -0,0 +1,17 @@
 let count_pal s =
  let n = String.length s in
  let count = ref 0 in
  for c = 0 to 2 * n - 2 do
    let l = ref (c / 2) in
    let r = ref ((c + 1) / 2) in
    while !l >= 0 && !r < n && s.[!l] = s.[!r] do
      count := !count + 1;
      l := !l - 1;
      r := !r + 1
    done
  done;
  !count
 ;;
 count_pal "aabaa"
--- a/lib/ocaml/baseline/count_paths_dag.ml
+++ b/lib/ocaml/baseline/count_paths_dag.ml
@@ -0,0 +1,42 @@
 let n = 6
 let adj = [|
  [1; 2];
  [3];
  [3; 4];
  [5];
  [5];
  []
 |]
 let in_deg = Array.make n 0
 let paths = Array.make n 0
 let count_paths () =
  for u = 0 to n - 1 do
    List.iter (fun v -> in_deg.(v) <- in_deg.(v) + 1) adj.(u)
  done;
  let order = ref [] in
  let q = Queue.create () in
  for v = 0 to n - 1 do
    if in_deg.(v) = 0 then Queue.push v q
  done;
  while not (Queue.is_empty q) do
    let u = Queue.pop q in
    order := u :: !order;
    List.iter (fun v ->
      in_deg.(v) <- in_deg.(v) - 1;
      if in_deg.(v) = 0 then Queue.push v q
    ) adj.(u)
  done;
  paths.(0) <- 1;
  let topo = List.rev !order in
  List.iter (fun u ->
    List.iter (fun v ->
      paths.(v) <- paths.(v) + paths.(u)
    ) adj.(u)
  ) topo;
  paths.(n - 1)
 ;;
 count_paths ()
--- a/lib/ocaml/baseline/count_subarrays_k.ml
+++ b/lib/ocaml/baseline/count_subarrays_k.ml
@@ -0,0 +1,16 @@
 let count_subarr_sum_k arr k =
  let n = Array.length arr in
  let prefix = Array.make (n + 1) 0 in
  for i = 0 to n - 1 do
    prefix.(i + 1) <- prefix.(i) + arr.(i)
  done;
  let count = ref 0 in
  for i = 0 to n - 1 do
    for j = i + 1 to n do
      if prefix.(j) - prefix.(i) = k then count := !count + 1
    done
  done;
  !count
 ;;
 count_subarr_sum_k [| 1; 1; 1; 2; -1; 3; 1; -2; 4 |] 3
--- a/lib/ocaml/baseline/csv.ml
+++ b/lib/ocaml/baseline/csv.ml
@@ -0,0 +1,12 @@
 let sum_second_col text =
  let lines = String.split_on_char '\n' text in
  List.fold_left (fun acc line ->
    let fields = String.split_on_char ',' line in
    if List.length fields >= 2 then
      acc + int_of_string (List.nth fields 1)
    else acc
  ) 0 lines
 ;;
 sum_second_col "a,1,extra\nb,2,extra\nc,3,extra\nd,4,extra"
--- a/lib/ocaml/baseline/daily_temperatures.ml
+++ b/lib/ocaml/baseline/daily_temperatures.ml
@@ -0,0 +1,24 @@
 let daily_temperatures temps =
  let n = Array.length temps in
  let answer = Array.make n 0 in
  let stack = ref [] in
  for i = 0 to n - 1 do
    let cont = ref true in
    while !cont do
      match !stack with
      | top :: rest when temps.(top) < temps.(i) ->
        answer.(top) <- i - top;
        stack := rest
      | _ -> cont := false
    done;
    stack := i :: !stack
  done;
  let sum = ref 0 in
  for i = 0 to n - 1 do
    sum := !sum + answer.(i)
  done;
  !sum
 ;;
 daily_temperatures [| 73; 74; 75; 71; 69; 72; 76; 73 |]
--- a/lib/ocaml/baseline/dijkstra.ml
+++ b/lib/ocaml/baseline/dijkstra.ml
@@ -0,0 +1,37 @@
 let n = 5
 let edges = [|
  [(1, 4); (2, 1)];
  [(3, 1)];
  [(1, 2); (3, 5)];
  [(4, 3)];
  []
 |]
 let dijkstra src =
  let dist = Array.make n 1000000 in
  dist.(src) <- 0;
  let visited = Array.make n false in
  for _ = 0 to n - 1 do
    let u = ref (-1) in
    let best = ref 1000000 in
    for v = 0 to n - 1 do
      if (not visited.(v)) && dist.(v) < !best then begin
        best := dist.(v);
        u := v
      end
    done;
    if !u >= 0 then begin
      visited.(!u) <- true;
      List.iter (fun (v, w) ->
        if dist.(!u) + w < dist.(v) then
          dist.(v) <- dist.(!u) + w
      ) edges.(!u)
    end
  done;
  dist
 ;;
 let d = dijkstra 0 in
 d.(4)
--- a/lib/ocaml/baseline/distinct_subseq.ml
+++ b/lib/ocaml/baseline/distinct_subseq.ml
@@ -0,0 +1,20 @@
 let count_subseq s t =
  let m = String.length s in
  let n = String.length t in
  let dp = Array.init (m + 1) (fun _ -> Array.make (n + 1) 0) in
  for i = 0 to m do
    dp.(i).(0) <- 1
  done;
  for i = 1 to m do
    for j = 1 to n do
      if s.[i - 1] = t.[j - 1] then
        dp.(i).(j) <- dp.(i - 1).(j) + dp.(i - 1).(j - 1)
      else
        dp.(i).(j) <- dp.(i - 1).(j)
    done
  done;
  dp.(m).(n)
 ;;
 count_subseq "rabbbit" "rabbit"
--- a/lib/ocaml/baseline/dp_word_break.ml
+++ b/lib/ocaml/baseline/dp_word_break.ml
@@ -0,0 +1,27 @@
 let word_break s words =
  let n = String.length s in
  let dp = Array.make (n + 1) false in
  dp.(0) <- true;
  for i = 1 to n do
    List.iter (fun w ->
      let wl = String.length w in
      if i >= wl && dp.(i - wl) then begin
        let prefix = String.sub s (i - wl) wl in
        if prefix = w then dp.(i) <- true
      end
    ) words
  done;
  if dp.(n) then 1 else 0
 let count_ok strings words =
  let count = ref 0 in
  List.iter (fun s ->
    count := !count + word_break s words
  ) strings;
  !count
 ;;
 let dict = ["apple"; "pen"; "pine"; "pineapple"; "cats"; "cat"; "and"; "sand"; "dog"] in
 let inputs = ["applepenapple"; "pineapplepenapple"; "catsanddog"; "catsandog"; "applesand"] in
 count_ok inputs dict
--- a/lib/ocaml/baseline/egg_drop.ml
+++ b/lib/ocaml/baseline/egg_drop.ml
@@ -0,0 +1,26 @@
 let egg_drop eggs floors =
  let dp = Array.init (eggs + 1) (fun _ -> Array.make (floors + 1) 0) in
  for f = 1 to floors do
    dp.(1).(f) <- f
  done;
  for e = 1 to eggs do
    dp.(e).(0) <- 0;
    dp.(e).(1) <- 1
  done;
  for e = 2 to eggs do
    for f = 2 to floors do
      let best = ref 100000000 in
      for k = 1 to f do
        let bre = dp.(e - 1).(k - 1) in
        let sur = dp.(e).(f - k) in
        let cand = 1 + (if bre > sur then bre else sur) in
        if cand < !best then best := cand
      done;
      dp.(e).(f) <- !best
    done
  done;
  dp.(eggs).(floors)
 ;;
 egg_drop 2 36
--- a/lib/ocaml/baseline/euler1.ml
+++ b/lib/ocaml/baseline/euler1.ml
@@ -0,0 +1,10 @@
 let euler1 limit =
  let sum = ref 0 in
  for i = 1 to limit - 1 do
    if i mod 3 = 0 || i mod 5 = 0 then sum := !sum + i
  done;
  !sum
 ;;
 euler1 1000
--- a/lib/ocaml/baseline/euler10.ml
+++ b/lib/ocaml/baseline/euler10.ml
@@ -0,0 +1,22 @@
 let sieve_sum n =
  let s = Array.make (n + 1) true in
  s.(0) <- false;
  s.(1) <- false;
  for i = 2 to n do
    if s.(i) then begin
      let j = ref (i * i) in
      while !j <= n do
        s.(!j) <- false;
        j := !j + i
      done
    end
  done;
  let total = ref 0 in
  for i = 2 to n do
    if s.(i) then total := !total + i
  done;
  !total
 ;;
 sieve_sum 100
--- a/lib/ocaml/baseline/euler14.ml
+++ b/lib/ocaml/baseline/euler14.ml
@@ -0,0 +1,25 @@
 let collatz_len n =
  let m = ref n in
  let c = ref 0 in
  while !m > 1 do
    if !m mod 2 = 0 then m := !m / 2
    else m := 3 * !m + 1;
    c := !c + 1
  done;
  !c
 let euler14 limit =
  let best = ref 0 in
  let best_n = ref 0 in
  for n = 2 to limit do
    let l = collatz_len n in
    if l > !best then begin
      best := l;
      best_n := n
    end
  done;
  !best_n
 ;;
 euler14 100
--- a/lib/ocaml/baseline/euler16.ml
+++ b/lib/ocaml/baseline/euler16.ml
@@ -0,0 +1,14 @@
 let euler16 n =
  let p = ref 1 in
  for _ = 1 to n do p := !p * 2 done;
  let sum = ref 0 in
  let m = ref !p in
  while !m > 0 do
    sum := !sum + !m mod 10;
    m := !m / 10
  done;
  !sum
 ;;
 euler16 15
--- a/lib/ocaml/baseline/euler2.ml
+++ b/lib/ocaml/baseline/euler2.ml
@@ -0,0 +1,15 @@
 let euler2 limit =
  let a = ref 1 in
  let b = ref 2 in
  let sum = ref 0 in
  while !a <= limit do
    if !a mod 2 = 0 then sum := !sum + !a;
    let c = !a + !b in
    a := !b;
    b := c
  done;
  !sum
 ;;
 euler2 4000000
--- a/lib/ocaml/baseline/euler21_small.ml
+++ b/lib/ocaml/baseline/euler21_small.ml
@@ -0,0 +1,25 @@
 let div_sum n =
  let s = ref 1 in
  let i = ref 2 in
  while !i * !i <= n do
    if n mod !i = 0 then begin
      s := !s + !i;
      let q = n / !i in
      if q <> !i then s := !s + q
    end;
    i := !i + 1
  done;
  if n = 1 then 0 else !s
 let euler21 limit =
  let total = ref 0 in
  for a = 2 to limit do
    let b = div_sum a in
    if b <> a && b > a && b <= limit && div_sum b = a then
      total := !total + a + b
  done;
  !total
 ;;
 euler21 300
--- a/lib/ocaml/baseline/euler25.ml
+++ b/lib/ocaml/baseline/euler25.ml
@@ -0,0 +1,17 @@
 let euler25 n =
  let a = ref 1 in
  let b = ref 1 in
  let i = ref 2 in
  let target = ref 1 in
  for _ = 1 to n - 1 do target := !target * 10 done;
  while !b < !target do
    let c = !a + !b in
    a := !b;
    b := c;
    i := !i + 1
  done;
  !i
 ;;
 euler25 12
--- a/lib/ocaml/baseline/euler28.ml
+++ b/lib/ocaml/baseline/euler28.ml
@@ -0,0 +1,15 @@
 let euler28 n =
  let s = ref 1 in
  let k = ref 1 in
  for layer = 1 to (n - 1) / 2 do
    let step = 2 * layer in
    for _ = 1 to 4 do
      k := !k + step;
      s := !s + !k
    done
  done;
  !s
 ;;
 euler28 7
--- a/lib/ocaml/baseline/euler29_small.ml
+++ b/lib/ocaml/baseline/euler29_small.ml
@@ -0,0 +1,14 @@
 let euler29 n =
  let h = Hashtbl.create 64 in
  for a = 2 to n do
    for b = 2 to n do
      let p = ref 1 in
      for _ = 1 to b do p := !p * a done;
      Hashtbl.replace h !p ()
    done
  done;
  Hashtbl.length h
 ;;
 euler29 5
--- a/lib/ocaml/baseline/euler3.ml
+++ b/lib/ocaml/baseline/euler3.ml
@@ -0,0 +1,15 @@
 let largest_prime_factor n =
  let m = ref n in
  let factor = ref 2 in
  let largest = ref 0 in
  while !m > 1 do
    if !m mod !factor = 0 then begin
      largest := !factor;
      m := !m / !factor
    end else factor := !factor + 1
  done;
  !largest
 ;;
 largest_prime_factor 13195
--- a/lib/ocaml/baseline/euler30_cube.ml
+++ b/lib/ocaml/baseline/euler30_cube.ml
@@ -0,0 +1,22 @@
 let pow_digit_sum n p =
  let m = ref n in
  let s = ref 0 in
  while !m > 0 do
    let d = !m mod 10 in
    let pd = ref 1 in
    for _ = 1 to p do pd := !pd * d done;
    s := !s + !pd;
    m := !m / 10
  done;
  !s
 let euler30 p limit =
  let total = ref 0 in
  for n = 2 to limit do
    if pow_digit_sum n p = n then total := !total + n
  done;
  !total
 ;;
 euler30 3 999
--- a/Show More
+++ b/Show More