shithub: martian9

ref: 2b66d7d69e8f6da6f2f211c7fd3636b586588053
dir: /macro.ml/

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module T = Types.Types

let gen_sym root =
  let gen () =
    match Random.int (26 + 26 + 10) with
    | n when n < 26 -> int_of_char 'a' + n
    | n when n < 26 + 26 -> int_of_char 'A' + n - 26
    | n -> int_of_char '0' + n - 26 - 26
  in
  let gen _ = String.make 1 (char_of_int (gen ())) in
  root ^ String.concat "" (Array.to_list (Array.init 5 gen))
;;

let rec is_matching_pattern sym pattern args matched =
  match pattern, args with
  (* literals and ellipses not handled, yet *)
  | ph :: pt, ah :: at ->
    (* print_endline "    LIST <-> LIST"; *)
    if ph = "_" || (ph = Printer.print sym true && sym = ah)
    then is_matching_pattern sym pt at matched && true
    else (* print_endline (" ------> " ^ ph ^ " vs " ^ Printer.print ah true); *)
      is_matching_pattern sym pt at matched
  | ph :: pt, [] ->
    (* print_endline "    LIST <-> []";
     * print_endline ("      ph: " ^ ph);
     * print_endline ("      pt: " ^ String.concat "|" pt); *)
    if ph = "_" || ph = Printer.print sym true
    then is_matching_pattern sym pt [] matched && true
    else ph = "..." || List.hd pt = "..."
  | [], ah :: at ->
    (* print_endline "    [] <-> LIST"; *)
    false
  | _, _ -> matched
;;

let rec ellipsis pattern template args =
  let has_ellipsis =
    try
      ignore (Str.search_forward (Str.regexp "...") (Printer.stringify pattern true) 0);
      true
    with
    | Not_found -> false
  in
  let ellipsis_substitutions = ref [] in
  let missing = List.length args - List.length pattern + if has_ellipsis then 1 else 0 in
  print_endline ("missing: " ^ string_of_int missing);
  (* print_endline (" NEED TO ADD " ^ string_of_int missing ^ " PLACEHOLDERS"); *)
  match missing with
  | _ when missing = 0 || missing > 0 ->
    (* add arguments *)
    print_endline ("ADD " ^ string_of_int missing ^ " arguments");
    for i = 1 to missing do
      ellipsis_substitutions := !ellipsis_substitutions @ [ gen_sym "x" ]
    done;
    let pattern_str =
      Str.global_replace
        (Str.regexp "\\.\\.\\.")
        (String.concat " " !ellipsis_substitutions)
        (Printer.stringify pattern true)
    in
    let template_str =
      Str.global_replace
        (Str.regexp "\\.\\.\\.")
        (String.concat " " !ellipsis_substitutions)
        (Printer.print template true)
    in
    (* let args_str = Printer.stringify args true in *)
    (* print_endline ("ellipsis: template: " ^ template_str ^ "  args: " ^ args_str); *)
    "(" ^ pattern_str ^ ") " ^ template_str ^ ")"
  | _ when missing < 0 ->
    (* remove ellipsis and arg *)
    print_endline "REMOVE arguments";
    (* let rgx = Str.regexp "[a-zA-Z0-9]+ \\.\\.\\." in *)
    let rgx = Str.regexp "[a-zA-Z0-9]+ \\.\\.\\." in
    let pattern_str = Str.global_replace rgx "" (Printer.stringify pattern true) in
    let template_str = Str.global_replace rgx "" (Printer.stringify pattern true) in
    print_endline ("  pattern:  " ^ Printer.dump pattern);
    print_endline ("    pattern_str:  " ^ pattern_str);
    print_endline ("  template: " ^ Printer.print template true);
    print_endline ("    template_str: " ^ template_str);
    print_endline ("(" ^ pattern_str ^ ") " ^ template_str ^ ")");
    "(" ^ pattern_str ^ ") " ^ template_str ^ ")"
  | _ -> "(" ^ Printer.dump pattern ^ ") " ^ Printer.print template true ^ ")"
;;

let lambdaize pattern template args =
  match pattern, args with
  | ph :: pt, ah :: at :: rest ->
    let expr = "((lambda " ^ ellipsis pt template args ^ Printer.stringify args false ^ ")" in
    print_endline ("  lambdaize list list: " ^ expr);
    Reader.read expr
  | ph :: pt, ah :: at ->
    let expr =
      "((lambda ("
      ^ Printer.stringify pt true
      ^ ")"
      ^ Printer.print template true
      ^ ")"
      ^ Printer.stringify args true
      ^ ")"
    in
    print_endline ("  lambdaize short list: " ^ expr);
    Reader.read expr
  | ph :: pt, [] ->
    let expr = "'(lambda (" ^ Printer.stringify pt false ^ ") " ^ Printer.print template false ^ ")" in
    print_endline ("  lambdaize empty list: " ^ expr);
    Reader.read expr
  | _ ->
    print_endline "lambdaize: empty";
    Reader.read ("((lambda () " ^ Printer.print template true ^ "))")
;;

let rec expand ast env args sym meta =
  print_endline ("\n\nTHIS IS A MACRO: " ^ Printer.print sym true);
  print_endline ("   META: " ^ Printer.print meta true);
  print_endline ("   ARGS: " ^ Printer.dump args);
  print_endline ("    AST: " ^ Printer.print ast true);
  match meta with
  | T.Map { T.value = m } ->
    ((* let literals = Types.M9map.find Types.macro_literals m in *)
    try
      let transformers = Types.M9map.find Types.macro_transformers m in
      print_endline
        ("  -- EVAL_MACRO: "
        (*  ^ " literals: "
         * ^ Printer.print literals true *)
        ^ "     transformers: "
        ^ Printer.print transformers true);
      let rec match_transform transforms =
        match transforms with
        | hd :: tl ->
          (* print_endline ("      transform: " ^ Printer.print hd true); *)
          (match hd with
          | T.List { T.value = [ T.List { T.value = pattern }; T.List { T.value = template } ] } ->
            (* print_endline "   MULTI";
             * print_endline ("     - template: " ^ Printer.dump template); *)
            print_endline
              ("      matched (m)?: "
              ^ (if is_matching_pattern sym (List.map (fun x -> Printer.print x true) pattern) (Core.seq ast) true
                then "yes"
                else "no")
              ^ " ::> "
              ^ Printer.dump pattern);
            if is_matching_pattern sym (List.map (fun x -> Printer.print x true) pattern) (Core.seq ast) true
            then lambdaize pattern (Types.list template) args
            else match_transform tl
          | T.List { T.value = [ T.List { T.value = pattern }; atom ] } ->
            (* print_endline "   SINGLE"; *)
            print_endline
              ("      matched (s)?: "
              ^ (if is_matching_pattern sym (List.map (fun x -> Printer.print x true) pattern) (Core.seq ast) true
                then "yes"
                else "no")
              ^ " ::> "
              ^ Printer.dump pattern);
            if is_matching_pattern sym (List.map (fun x -> Printer.print x true) pattern) (Core.seq ast) true
            then lambdaize pattern atom args
            else match_transform tl
          | _ -> raise (Reader.Syntax_error "Unknown"))
          (* errors? *)
        | [] -> raise (Reader.Syntax_error ("No matching transform for macro: '" ^ Printer.print sym true))
      in
      match_transform (Core.seq transformers)
    with
    | Not_found -> raise (Reader.Syntax_error ("'" ^ Printer.print sym true ^ "' is not a known macro")))
  | _ -> raise (Reader.Syntax_error "syntax error with defined macro")
;;