shithub: martian9

ref: a3761f1b564b3a2574fc038a352f332190a78344
dir: /m9.ml/

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(*
  Martian Scheme
  Copyright 2020, McKay Marston

  This is a project for me to
    1) Get more familiar with OCaml.
    2) Try to provide a natively supported r7rs-small scheme for Plan9.

  It is heavily inspired by s9fes (http://www.t3x.org/s9fes), and the
  make a lisp project (https://github.com/kanaka/mal - thanks
  https://github.com/chouser for the fantastic implementation!)
 *)

module T = Types.Types

let repl_env = Env.make (Some Core.base)

let rec quasiquote ast =
  match ast with
  | T.List { T.value = [ T.Symbol { T.value = "unquote" }; ast ] } -> ast
  | T.Vector { T.value = [ T.Symbol { T.value = "unquote" }; ast ] } -> ast
  | T.List
      { T.value =
          T.List { T.value = [ T.Symbol { T.value = "unquote-splicing" }; head ] } :: tail
      }
  | T.Vector
      { T.value =
          T.List { T.value = [ T.Symbol { T.value = "unquote-splicing" }; head ] } :: tail
      } -> Types.list [ Types.symbol "concat"; head; quasiquote (Types.list tail) ]
  | T.List { T.value = head :: tail } | T.Vector { T.value = head :: tail } ->
    Types.list [ Types.symbol "cons"; quasiquote head; quasiquote (Types.list tail) ]
  | ast -> Types.list [ Types.symbol "quote"; ast ]
;;

let eval_macro sym args env meta =
  match meta with
  | T.Map { T.value = m } ->
     (try
       let literals = Types.M9map.find Types.macro_literals m in
       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 ("__ hd: " ^ Printer.print hd true);
                        print_endline ("__ arg length: " ^ string_of_int (List.length args));
                        let foo = T.List hd in
                        print_endline ("__ transform length: " ^ string_of_int (List.length foo));
                        match_transform tl
          | [] -> ())
       in
       match_transform (Core.seq transformers)
     with Not_found -> ())
  | _ -> ()
;;

let rec preparse ast env =
    match ast with
    | T.List { T.value = s :: args } ->
      (match
         try Env.get env s with
         | _ -> T.Nil
       with
       | T.Macro { T.value = s; meta = m } ->
          print_endline (" THIS IS A MACRO: " ^ Printer.print s true);
          print_endline ("   META: " ^ Printer.print m true);
          print_endline ("   ARGS: " ^ Printer.dump args);
          eval_macro s args env m; ast
       | _ -> ast)
    | _ -> ast
;;

let rec eval_ast ast env =
  match ast with
  | T.Symbol s -> Env.get env ast
  | T.List { T.value = xs; T.meta } ->
    T.List { T.value = List.map (fun x -> eval x env) xs; T.meta }
  | T.Vector { T.value = xs; T.meta } ->
    T.Vector { T.value = List.map (fun x -> eval x env) xs; T.meta }
  | T.Macro { T.value = m } ->
    print_endline ("wait, what? " ^ Printer.print m true);
    T.Nil
  | _ -> ast

and eval ast env =
  match preparse ast env with
  | T.List { T.value = [] } -> ast
  (* Can this be replaced with a define-syntax thing? *)
  | T.List
      { T.value = [ T.Symbol { T.value = "define" }; T.List { T.value = arg_list }; body ]
      } ->
    let sym = List.hd arg_list in
    let rest = List.tl arg_list in
    let func =
      eval
        (Reader.read
           ("(lambda ("
           ^ String.concat " " (List.map (fun x -> Printer.print x false) rest)
           ^ ") "
           ^ Printer.print body true
           ^ ")"))
        env
    in
    Env.set env sym func;
    func
  | T.List { T.value = [ T.Symbol { T.value = "define" }; key; expr ] } ->
    let value = eval expr env in
    Env.set env key value;
    value
  | T.List
      { T.value =
          [ T.Symbol { T.value = "define-syntax" }; keyword; T.List { T.value = macro } ]
      } ->
    print_endline ("define-syntax: " ^ Printer.print keyword true);
    (match macro with
    | _ :: literals :: groups ->
      let macro_entry =
        Types.macro (Printer.print keyword true) literals (Types.list groups)
      in
      print_endline ("  macro_entry: " ^ Printer.print macro_entry true);
      print_endline ("   literals: " ^ Printer.print literals true);
      print_endline ("   groups: " ^ Printer.dump groups);
      Env.set env keyword macro_entry;
      macro_entry
    | _ -> T.Nil)
  | T.List
      { T.value =
          [ T.Symbol { T.value = "lambda" }; T.Vector { T.value = arg_names }; expr ]
      }
  | T.List
      { T.value =
          [ T.Symbol { T.value = "lambda" }; T.List { T.value = arg_names }; expr ]
      } ->
    Types.proc (function args ->
        let sub_env = Env.make (Some env) in
        let rec bind_args a b =
          match a, b with
          | [ T.Symbol { T.value = "." }; name ], args ->
            Env.set sub_env name (Types.list args)
          | name :: names, arg :: args ->
            Env.set sub_env name arg;
            bind_args names args
          | [], [] -> ()
          | _ -> raise (Reader.Syntax_error "wrong parameter count for lambda")
        in
        bind_args arg_names args;
        eval expr sub_env)
  (* Can these be replace with define-syntax stuff? *)
  | T.List
      { T.value = [ T.Symbol { T.value = "let" }; T.Vector { T.value = bindings }; body ]
      }
  | T.List
      { T.value = [ T.Symbol { T.value = "let" }; T.List { T.value = bindings }; body ] }
    ->
    let sub_env = Env.make (Some env) in
    let rec bind_pairs = function
      | T.List { T.value = [ T.Symbol { T.value = sym }; expr ] } :: more ->
        let value = eval expr env in
        Env.set env (Types.symbol sym) value;
        bind_pairs more
      | _ -> ()
    in
    bind_pairs bindings;
    eval body sub_env
  | T.List { T.value = T.Symbol { T.value = "begin" } :: body } ->
    List.fold_left (fun x expr -> eval expr env) T.Nil body
  | T.List { T.value = [ T.Symbol { T.value = "if" }; cond; then_expr; else_expr ] } ->
    if Types.to_bool (eval cond env) then eval then_expr env else eval else_expr env
  | T.List { T.value = [ T.Symbol { T.value = "if" }; cond; then_expr ] } ->
    if Types.to_bool (eval cond env) then eval then_expr env else T.Nil
  | T.List { T.value = [ T.Symbol { T.value = "quote" }; ast ] } -> ast
  | T.List { T.value = [ T.Symbol { T.value = "quasiquote" }; ast ] } ->
    eval (quasiquote ast) env
  | T.List _ ->
    (match eval_ast ast env with
    | T.List { T.value = T.Proc { T.value = f } :: args } -> f args
    | _ as x ->
      raise (Reader.Syntax_error ("'" ^ Printer.print x true ^ "' not a function")))
  | _ -> eval_ast ast env
;;

let nameplate = "Martian9 Scheme v0.1"
let read str = Reader.read str
let print exp = Printer.print exp true
let rep str env = print (eval (read str) env)

let rec main =
  try
    Core.init Core.base;
    Env.set
      repl_env
      (Types.symbol "eval")
      (Types.proc (function
          | [ ast ] -> eval ast repl_env
          | _ -> T.Nil));
    ignore
      (rep
         "(define load-file (lambda (f) (eval (read-string (string \"(begin \" (slurp f) \
          \")\")))))"
         repl_env);
    if Array.length Sys.argv > 1
    then print_endline (rep ("(load-file \"" ^ Sys.argv.(1) ^ "\")") repl_env)
    else (
      print_endline nameplate;
      while true do
        print_string "m9> ";
        let line = read_line () in
        try print_endline (rep line repl_env) with
        | End_of_file -> ()
        | Invalid_argument x ->
          output_string stderr ("Invalid argument: " ^ x ^ "\n");
          flush stderr
      done)
  with
  | End_of_file -> ()
;;