[tiger.ml.git] / compiler / src / lib / tiger / tiger_semant.ml

module List = ListLabels

module A         = Tiger_absyn
module Dag       = Tiger_dag
module Env       = Tiger_env
module E         = Tiger_error
module Escape    = Tiger_semant_escape
module Pos       = Tiger_position
module Sym       = Tiger_symbol
module Temp      = Tiger_temp
module Translate = Tiger_translate
module Type      = Tiger_env_type
module Value     = Tiger_env_value

(* The only reason for having this seemingly-superfluous inner module is to
 * have this nice signature as a summary of what each function does. *)
module Semant : sig
  type expty =
    { exp : Translate.exp
    ; ty  : Type.t
    }

  (* Violating normal naming convention just to make it easier to follow
   * Appel's
   *)
  val transExp : env:Env.t -> A.exp -> expty

  (* transVar does not seem to be needed, as trvar handles all our cases.
   * Am I wrong?
   *
   * val transVar : env:Env.t -> A.var -> expty
   *
   *)
end = struct
  type expty =
    { exp : Translate.exp
    ; ty  : Type.t
    }

  let rec actual_ty ty ~pos =
    match ty with
    | Type.Name (name, ty_opt_ref) ->
        (match !ty_opt_ref with
        | None ->
            E.raise (E.Unknown_type {ty_id=name; pos})
        | Some ty ->
            actual_ty ty ~pos
        )
    | Type.Unit
    | Type.Nil
    | Type.Int
    | Type.String
    | Type.Record _
    | Type.Array _ ->
        ty

  let return ty     = {exp = Translate.dummy__FIXME; ty}
  let return_unit   = return Type.Unit
  let return_nil    = return Type.Nil
  let return_int    = return Type.Int
  let return_string = return Type.String

  let env_get_typ ~sym ~env ~pos : Type.t =
    match Env.get_typ env sym with
    | Some ty -> ty
    | None    -> E.raise (E.Unknown_type {ty_id=sym; pos})

  let env_get_typ_actual ~sym ~env ~pos : Type.t =
    actual_ty (env_get_typ ~sym ~env ~pos) ~pos

  let env_get_val ~sym ~env ~pos : Value.t =
    match Env.get_val env sym with
    | Some ty -> ty
    | None    -> E.raise (E.Unknown_id {id=sym; pos})

  let check_same {exp=_; ty=ty_left} {exp=_; ty=ty_right} ~pos : unit =
    if Type.is_equal ty_left ty_right then
      ()
    else
      E.raise (E.Wrong_type {expected=ty_left; given=ty_right; pos})

  let check_int expty ~pos : unit =
    check_same return_int expty ~pos

  let paths_of_typedecs typedecs : (Sym.t * Sym.t * Pos.t) list list =
    let (path, paths) =
      List.fold_left typedecs ~init:([], []) ~f:(
        fun (path, paths) (A.TypeDec {name=child; ty; pos}) ->
          match ty with
          | A.NameTy {symbol=parent; _} ->
              (((parent, child, pos) :: path), paths)
          | A.RecordTy _
          | A.ArrayTy _ ->
              ([], path :: paths)
      )
    in
    List.map (path :: paths) ~f:List.rev

  let check_cycles (typedecs : A.typedec list) : unit =
    let non_empty_paths =
      List.filter
        (paths_of_typedecs typedecs)
        ~f:(function [] -> false | _ -> true)
    in
    List.iter non_empty_paths ~f:(
      fun path ->
        match Dag.of_list (List.map path ~f:(fun (p, c, _) -> (p, c))) with
        | Ok _ ->
            ()
        | Error `Cycle ->
            let (_, from_id, from_pos) = List.hd           path  in
            let (_,   to_id,   to_pos) = List.hd (List.rev path) in
            E.raise (E.Cycle_in_type_decs {from_id; from_pos; to_id; to_pos})
    )

  let rec transExp ~env exp =
    let rec trexp exp =
      (match exp with
      | A.NilExp ->
          return_nil
      | A.IntExp _ ->
          return_int
      | A.StringExp {string=_; _} ->
          return_string
      | A.CallExp {func; args; pos} ->
          (match env_get_val ~sym:func ~env ~pos with
          | Value.Fun {formals; result; level=_; label=_} ->
              let expected = List.length formals in
              let given    = List.length args in
              if given = expected then
                begin
                  List.iter2 formals args ~f:(fun ty_expected exp_given ->
                    check_same
                      (return (actual_ty ~pos ty_expected))
                      (trexp exp_given)
                      ~pos;
                  );
                  return (actual_ty ~pos result)
                end
              else
                E.raise (E.Wrong_number_of_args {func; expected; given; pos})
          | Value.Var _ ->
              E.raise (E.Id_not_a_function {id=func; pos})
          )
      | A.OpExp {oper; left; right; pos} ->
          trop oper ~left ~right ~pos
      | A.RecordExp {fields=field_exps; typ; pos} ->
          let ty = env_get_typ_actual ~sym:typ ~env ~pos in
          Type.if_record
            ty
            ~f:(fun field_tys ->
              List.iter field_exps ~f:(fun (field, exp, pos) ->
                (match List.assoc_opt field field_tys with
                | Some field_ty ->
                    check_same (return (actual_ty ~pos field_ty)) (trexp exp) ~pos
                | None ->
                    E.raise
                      (E.No_such_field_in_record {field; record=ty; pos})
                )
              )
            )
            ~otherwise:(fun () ->
              E.raise (E.Wrong_type_used_as_record {ty_id=typ; ty; pos})
            );
          return (actual_ty ~pos ty)
      | A.SeqExp [] ->
          return_unit
      | A.SeqExp exps ->
          let last xs =
            xs
            |> List.rev  (* Yes, redundant, but clean-looking ;-P *)
            |> List.hd   (* Empty is matched in above SeqExp match case *)
          in
          exps
          |> List.map ~f:(fun (exp, _) -> trexp exp)
          |> last
      | A.AssignExp {var; exp; pos} ->
          check_same (trvar var) (trexp exp) ~pos;
          (* TODO: Add var->exp to val env? *)
          return_unit
      | A.IfExp {test; then'; else'; pos} ->
          (* test : must be int, because we have no bool *)
          (* then : must equal else *)
          (* else : must equal then or be None *)
          check_int (trexp test) ~pos;
          (match (trexp then', else') with
          | expty_then, None ->
              expty_then
          | expty_then, Some else' ->
              let expty_else = trexp else' in
              check_same expty_then expty_else ~pos;
              expty_then
          )
      | A.WhileExp {test; body; pos} ->
          (* test : must be int, because we have no bool *)
          check_int (trexp test) ~pos;
          let (loop, env) = Env.loop_begin env in
          (* Only care if an error is raised *)
          ignore (transExp ~env body);
          ignore (Env.loop_end env loop);
          return_unit
      | A.ForExp {var; lo; hi; body; pos; escape=_} ->
          check_int (trexp lo) ~pos;
          check_int (trexp hi) ~pos;
          let (loop, env) = Env.loop_begin env in
          let level = Env.level_get env in
          (* Assuming all escape, for now *)
          let access = Translate.alloc_local ~level ~escapes:true in
          let env = Env.set_val env var (Value.Var {ty = Type.Int; access}) in
          (* Only care if an error is raised *)
          ignore (transExp ~env body);
          ignore (Env.loop_end env loop);
          return_unit
      | A.BreakExp pos ->
          (match Env.loop_current env with
          | Some _ -> ()
          | None   -> E.raise (E.Break_outside_loop pos)
          );
          return_unit
      | A.LetExp {decs; body; pos=_} ->
          (* (1) decs augment env *)
          (* (2) body checked against the new env *)
          let env =
            List.fold_left decs ~init:env ~f:(fun env dec -> transDec dec ~env)
          in
          transExp body ~env
      | A.ArrayExp {typ; size; init; pos} ->
          check_int (trexp size) ~pos;
          let ty = env_get_typ_actual ~sym:typ ~env ~pos in
          Type.if_array
            ty
            ~f:(fun ty_elements ->
              check_same (return (actual_ty ~pos ty_elements)) (trexp init) ~pos
            )
            ~otherwise:(fun () ->
              E.raise (E.Wrong_type_used_as_array {ty_id=typ; ty; pos})
            );
          return (actual_ty ~pos ty)
      | A.VarExp var ->
          trvar var
      )
    and trvar =
      (function
      | A.SimpleVar {symbol=sym; pos} ->
          (match env_get_val ~sym ~env ~pos with
          | Value.Fun _ ->
              E.raise (E.Id_is_a_function {id=sym; pos})
          | Value.Var {ty; access=_} ->
              return (actual_ty ~pos ty)
          )
      | A.FieldVar {var; symbol; pos} ->
          let {exp=_; ty} = trvar var in
          Type.if_record
            ty
            ~f:(fun fields ->
              (match List.assoc_opt symbol fields with
              | None ->
                  E.raise
                    (E.No_such_field_in_record {field=symbol; record=ty; pos})
              | Some ty ->
                  return (actual_ty ~pos ty)
              )
            )
            ~otherwise:(fun () -> E.raise (E.Exp_not_a_record {ty; pos}))
      | A.SubscriptVar {var; exp; pos} ->
          let {exp=_; ty} = trvar var in
          check_int (trexp exp) ~pos;
          Type.if_array
            ty
            ~f:(fun ty_elements -> return (actual_ty ~pos ty_elements))
            ~otherwise:(fun () -> E.raise (E.Exp_not_an_array {ty; pos}))
      )
    and trop oper ~left ~right ~pos =
      (* TODO: Refactor trop - all opers return bool/int *)
      let expty_left  = trexp left in
      let expty_right = trexp right in
      check_same expty_left expty_right ~pos;
      let {exp=_; ty} = expty_left in
      let module T = Type in
      (match oper with
      (* Arithmetic: int *)
      | A.PlusOp
      | A.MinusOp
      | A.TimesOp
      | A.DivideOp ->
          check_int expty_left ~pos;
          return_int
      (* Equality: int, string, array, record *)
      | A.EqOp
      | A.NeqOp ->
          if (T.is_int    ty)
          || (T.is_string ty)
          || (T.is_array  ty)
          || (T.is_record ty)
          then
            return_int  (* Because we have no bool type *)
          else
            E.raise (E.Invalid_operand_type
              { oper
              ; valid = ["int"; "string"; "array"; "record"]
              ; given = ty
              ; pos
              })
      (* Order: int, string *)
      | A.LtOp
      | A.LeOp
      | A.GtOp
      | A.GeOp ->
          if (T.is_int    ty)
          || (T.is_string ty)
          then
            return_int  (* Because we have no bool type *)
          else
            E.raise (E.Invalid_operand_type
              { oper
              ; valid = ["int"; "string"]
              ; given = ty
              ; pos
              })
      )
    in
    trexp exp
  and transDec ~(env : Env.t) (dec : A.dec) : Env.t =
    (match dec with
    | A.VarDec {name; typ=typ_opt; init; pos=pos_outter; escape=_} ->
        let ty =
          (match (typ_opt, transExp ~env init) with
          | None, {ty; exp=_} ->
              ty
          | Some (sym, pos_inner), expty_init ->
              let ty = env_get_typ_actual ~sym ~env ~pos:pos_inner in
              check_same (return ty) expty_init ~pos:pos_outter;
              ty
          )
        in
        let access =
          Translate.alloc_local
            ~level:(Env.level_get env)
            ~escapes:true  (* Assuming all escape, for now... *)
        in
        Env.set_val env name (Value.Var {ty; access})
    | A.TypeDecs typedecs ->
        check_cycles typedecs;
        let env =
          List.fold_left typedecs ~init:env ~f:(
            fun env (A.TypeDec {name; ty=_; pos=_}) ->
              Env.set_typ env name (Type.Name (name, ref None))
          )
        in
        List.iter typedecs ~f:(fun (A.TypeDec {name=ty_name; ty=ty_exp; pos}) ->
          let ty = transTy ~env ~ty_name ~ty_exp in
          (match env_get_typ ~sym:ty_name ~env ~pos with
          | Type.Name (_, ty_opt_ref) ->
              ty_opt_ref := Some ty
          | Type.Unit
          | Type.Nil
          | Type.Int
          | Type.String
          | Type.Record _
          | Type.Array _ ->
              ()
          )
        );
        env
    | A.FunDecs fundecs ->
        let env_with_fun_heads_only =
          List.fold_left fundecs ~init:env ~f:(
            fun env (A.FunDec {name; params; result; body=_; pos=_}) ->
              let formals =
                List.map params ~f:(
                  fun (A.Field {name=_; typ; pos; escape=_}) ->
                    env_get_typ_actual ~env ~sym:typ ~pos
                )
              in
              let result =
                match result with
                | Some (s, p) -> env_get_typ_actual ~sym:s ~env ~pos:p
                | None        -> Type.Unit
              in
              let label = Temp.Label.gen () in
              let level =
                Translate.Level.next
                  (Env.level_get env)
                  ~name:label
                  (* Assuming all escape (for now) *)
                  ~formals:(List.map formals ~f:(fun _ -> true))
              in
              let env = Env.level_set env level in
              Env.set_val env name (Value.Fun {formals; result; level; label})
          )
        in
        List.iter fundecs ~f:(
          fun (A.FunDec {name=_; params; result=_; body; pos=_}) ->
            let env_with_fun_heads_and_local_vars =
              List.fold_left params ~init:env_with_fun_heads_only ~f:(
                fun env (A.Field {name=var_name; escape=_; typ; pos}) ->
                  let var_ty = env_get_typ_actual ~env ~sym:typ ~pos in
                  let level = Env.level_get env in
                  (* Assuming all escape, for now *)
                  let access = Translate.alloc_local ~level ~escapes:true in
                  Env.set_val
                    env
                    var_name
                    (Value.Var {ty = var_ty; access})
              )
            in
            (* we only care if an exception is raised *)
            ignore (transExp ~env:env_with_fun_heads_and_local_vars body);
        );
        env_with_fun_heads_only
    )
  and transTy ~(env : Env.t) ~ty_name ~(ty_exp : A.ty) : Type.t =
    (match ty_exp with
    | A.NameTy {symbol=sym; pos} ->
        env_get_typ ~sym ~env ~pos
    | A.RecordTy fields ->
        let fields =
          List.map fields ~f:(fun (A.Field {name; escape=_; typ; pos}) ->
            let ty = env_get_typ ~sym:typ ~env ~pos in
            (name, ty)
          )
        in
        Type.new_record ~name:ty_name ~fields
    | A.ArrayTy {symbol=sym; pos} ->
        let element_ty = env_get_typ ~sym ~env ~pos in
        Type.new_array ~name:ty_name ~ty:element_ty
    )
end

open Semant

let transProg absyn =
  Escape.find ~prog:absyn;
  let {exp = _; ty = _} = transExp absyn ~env:Env.base in
  ()
Commit	Line	Data
523e2b06 SK	1	module List = ListLabels
523e2b06 SK	2
155ee327	3	module A = Tiger_absyn
e6e82c08	4	module Dag = Tiger_dag
155ee327 SK	5	module Env = Tiger_env
155ee327 SK	6	module E = Tiger_error
21d0f050	7	module Escape = Tiger_semant_escape
e6e82c08 SK	8	module Pos = Tiger_position
e6e82c08 SK	9	module Sym = Tiger_symbol
cc540a7e	10	module Temp = Tiger_temp
155ee327 SK	11	module Translate = Tiger_translate
	12	module Type = Tiger_env_type
	13	module Value = Tiger_env_value
	14
	15	(* The only reason for having this seemingly-superfluous inner module is to
	16	* have this nice signature as a summary of what each function does. *)
	17	module Semant : sig
	18	type expty =
	19	{ exp : Translate.exp
	20	; ty : Type.t
	21	}
	22
	23	(* Violating normal naming convention just to make it easier to follow
	24	* Appel's
	25	*)
	26	val transExp : env:Env.t -> A.exp -> expty
862e5c05 SK	27
	28	(* transVar does not seem to be needed, as trvar handles all our cases.
	29	* Am I wrong?
	30	*
	31	* val transVar : env:Env.t -> A.var -> expty
	32	*
	33	*)
155ee327 SK	34	end = struct
	35	type expty =
	36	{ exp : Translate.exp
	37	; ty : Type.t
	38	}
	39
cbb4ffb6 SK	40	let rec actual_ty ty ~pos =
	41	match ty with
	42	\| Type.Name (name, ty_opt_ref) ->
	43	(match !ty_opt_ref with
	44	\| None ->
	45	E.raise (E.Unknown_type {ty_id=name; pos})
	46	\| Some ty ->
	47	actual_ty ty ~pos
	48	)
	49	\| Type.Unit
	50	\| Type.Nil
	51	\| Type.Int
	52	\| Type.String
	53	\| Type.Record _
	54	\| Type.Array _ ->
	55	ty
	56
6ca1afb7	57	let return ty = {exp = Translate.dummy__FIXME; ty}
523e2b06 SK	58	let return_unit = return Type.Unit
	59	let return_nil = return Type.Nil
	60	let return_int = return Type.Int
	61	let return_string = return Type.String
155ee327	62
523e2b06 SK	63	let env_get_typ ~sym ~env ~pos : Type.t =
	64	match Env.get_typ env sym with
	65	\| Some ty -> ty
	66	\| None -> E.raise (E.Unknown_type {ty_id=sym; pos})
	67
cbb4ffb6 SK	68	let env_get_typ_actual ~sym ~env ~pos : Type.t =
	69	actual_ty (env_get_typ ~sym ~env ~pos) ~pos
	70
523e2b06 SK	71	let env_get_val ~sym ~env ~pos : Value.t =
	72	match Env.get_val env sym with
	73	\| Some ty -> ty
	74	\| None -> E.raise (E.Unknown_id {id=sym; pos})
	75
	76	let check_same {exp=_; ty=ty_left} {exp=_; ty=ty_right} ~pos : unit =
	77	if Type.is_equal ty_left ty_right then
	78	()
	79	else
	80	E.raise (E.Wrong_type {expected=ty_left; given=ty_right; pos})
	81
	82	let check_int expty ~pos : unit =
cbb4ffb6	83	check_same return_int expty ~pos
978cb41c	84
e6e82c08 SK	85	let paths_of_typedecs typedecs : (Sym.t * Sym.t * Pos.t) list list =
	86	let (path, paths) =
	87	List.fold_left typedecs ~init:([], []) ~f:(
	88	fun (path, paths) (A.TypeDec {name=child; ty; pos}) ->
	89	match ty with
	90	\| A.NameTy {symbol=parent; _} ->
	91	(((parent, child, pos) :: path), paths)
	92	\| A.RecordTy _
	93	\| A.ArrayTy _ ->
	94	([], path :: paths)
	95	)
	96	in
	97	List.map (path :: paths) ~f:List.rev
	98
	99	let check_cycles (typedecs : A.typedec list) : unit =
	100	let non_empty_paths =
	101	List.filter
	102	(paths_of_typedecs typedecs)
	103	~f:(function [] -> false \| _ -> true)
	104	in
	105	List.iter non_empty_paths ~f:(
	106	fun path ->
	107	match Dag.of_list (List.map path ~f:(fun (p, c, _) -> (p, c))) with
	108	\| Ok _ ->
	109	()
	110	\| Error `Cycle ->
	111	let (_, from_id, from_pos) = List.hd path in
	112	let (_, to_id, to_pos) = List.hd (List.rev path) in
	113	E.raise (E.Cycle_in_type_decs {from_id; from_pos; to_id; to_pos})
	114	)
	115
523e2b06 SK	116	let rec transExp ~env exp =
	117	let rec trexp exp =
	118	(match exp with
	119	\| A.NilExp ->
	120	return_nil
	121	\| A.IntExp _ ->
	122	return_int
	123	\| A.StringExp {string=_; _} ->
	124	return_string
978cb41c SK	125	\| A.CallExp {func; args; pos} ->
978cb41c SK	126	(match env_get_val ~sym:func ~env ~pos with
cc540a7e	127	\| Value.Fun {formals; result; level=_; label=_} ->
54e838f4 SK	128	let expected = List.length formals in
	129	let given = List.length args in
	130	if given = expected then
	131	begin
	132	List.iter2 formals args ~f:(fun ty_expected exp_given ->
	133	check_same
	134	(return (actual_ty ~pos ty_expected))
	135	(trexp exp_given)
	136	~pos;
	137	);
	138	return (actual_ty ~pos result)
	139	end
	140	else
	141	E.raise (E.Wrong_number_of_args {func; expected; given; pos})
978cb41c SK	142	\| Value.Var _ ->
	143	E.raise (E.Id_not_a_function {id=func; pos})
	144	)
523e2b06 SK	145	\| A.OpExp {oper; left; right; pos} ->
523e2b06 SK	146	trop oper ~left ~right ~pos
0ed7a07c	147	\| A.RecordExp {fields=field_exps; typ; pos} ->
cbb4ffb6	148	let ty = env_get_typ_actual ~sym:typ ~env ~pos in
0ed7a07c SK	149	Type.if_record
	150	ty
	151	~f:(fun field_tys ->
	152	List.iter field_exps ~f:(fun (field, exp, pos) ->
	153	(match List.assoc_opt field field_tys with
	154	\| Some field_ty ->
cbb4ffb6	155	check_same (return (actual_ty ~pos field_ty)) (trexp exp) ~pos
0ed7a07c SK	156	\| None ->
	157	E.raise
	158	(E.No_such_field_in_record {field; record=ty; pos})
	159	)
	160	)
	161	)
	162	~otherwise:(fun () ->
	163	E.raise (E.Wrong_type_used_as_record {ty_id=typ; ty; pos})
	164	);
cbb4ffb6	165	return (actual_ty ~pos ty)
9d8471b2	166	\| A.SeqExp [] ->
523e2b06	167	return_unit
9d8471b2 SK	168	\| A.SeqExp exps ->
	169	let last xs =
	170	xs
	171	\|> List.rev (* Yes, redundant, but clean-looking ;-P *)
	172	\|> List.hd (* Empty is matched in above SeqExp match case *)
	173	in
	174	exps
cbb4ffb6	175	\|> List.map ~f:(fun (exp, _) -> trexp exp)
9d8471b2	176	\|> last
523e2b06 SK	177	\| A.AssignExp {var; exp; pos} ->
	178	check_same (trvar var) (trexp exp) ~pos;
	179	(* TODO: Add var->exp to val env? *)
	180	return_unit
	181	\| A.IfExp {test; then'; else'; pos} ->
	182	(* test : must be int, because we have no bool *)
	183	(* then : must equal else *)
	184	(* else : must equal then or be None *)
	185	check_int (trexp test) ~pos;
	186	(match (trexp then', else') with
	187	\| expty_then, None ->
	188	expty_then
	189	\| expty_then, Some else' ->
	190	let expty_else = trexp else' in
	191	check_same expty_then expty_else ~pos;
	192	expty_then
	193	)
	194	\| A.WhileExp {test; body; pos} ->
	195	(* test : must be int, because we have no bool *)
	196	check_int (trexp test) ~pos;
35dccbd3 SK	197	let (loop, env) = Env.loop_begin env in
	198	(* Only care if an error is raised *)
	199	ignore (transExp ~env body);
	200	ignore (Env.loop_end env loop);
523e2b06 SK	201	return_unit
	202	\| A.ForExp {var; lo; hi; body; pos; escape=_} ->
	203	check_int (trexp lo) ~pos;
	204	check_int (trexp hi) ~pos;
35dccbd3	205	let (loop, env) = Env.loop_begin env in
cc540a7e SK	206	let level = Env.level_get env in
	207	(* Assuming all escape, for now *)
	208	let access = Translate.alloc_local ~level ~escapes:true in
	209	let env = Env.set_val env var (Value.Var {ty = Type.Int; access}) in
35dccbd3	210	(* Only care if an error is raised *)
85e08b69	211	ignore (transExp ~env body);
35dccbd3	212	ignore (Env.loop_end env loop);
523e2b06	213	return_unit
35dccbd3 SK	214	\| A.BreakExp pos ->
	215	(match Env.loop_current env with
	216	\| Some _ -> ()
	217	\| None -> E.raise (E.Break_outside_loop pos)
	218	);
523e2b06	219	return_unit
8744eb3a SK	220	\| A.LetExp {decs; body; pos=_} ->
	221	(* (1) decs augment env *)
	222	(* (2) body checked against the new env *)
	223	let env =
	224	List.fold_left decs ~init:env ~f:(fun env dec -> transDec dec ~env)
	225	in
	226	transExp body ~env
4c550cd5 SK	227	\| A.ArrayExp {typ; size; init; pos} ->
4c550cd5 SK	228	check_int (trexp size) ~pos;
cbb4ffb6	229	let ty = env_get_typ_actual ~sym:typ ~env ~pos in
4c550cd5 SK	230	Type.if_array
	231	ty
	232	~f:(fun ty_elements ->
cbb4ffb6	233	check_same (return (actual_ty ~pos ty_elements)) (trexp init) ~pos
4c550cd5 SK	234	)
	235	~otherwise:(fun () ->
	236	E.raise (E.Wrong_type_used_as_array {ty_id=typ; ty; pos})
	237	);
cbb4ffb6	238	return (actual_ty ~pos ty)
523e2b06 SK	239	\| A.VarExp var ->
	240	trvar var
	241	)
	242	and trvar =
	243	(function
	244	\| A.SimpleVar {symbol=sym; pos} ->
	245	(match env_get_val ~sym ~env ~pos with
cc540a7e SK	246	\| Value.Fun _ ->
	247	E.raise (E.Id_is_a_function {id=sym; pos})
	248	\| Value.Var {ty; access=_} ->
	249	return (actual_ty ~pos ty)
523e2b06 SK	250	)
	251	\| A.FieldVar {var; symbol; pos} ->
	252	let {exp=_; ty} = trvar var in
	253	Type.if_record
	254	ty
	255	~f:(fun fields ->
	256	(match List.assoc_opt symbol fields with
	257	\| None ->
	258	E.raise
	259	(E.No_such_field_in_record {field=symbol; record=ty; pos})
	260	\| Some ty ->
cbb4ffb6	261	return (actual_ty ~pos ty)
523e2b06 SK	262	)
	263	)
	264	~otherwise:(fun () -> E.raise (E.Exp_not_a_record {ty; pos}))
161a300d SK	265	\| A.SubscriptVar {var; exp; pos} ->
	266	let {exp=_; ty} = trvar var in
	267	check_int (trexp exp) ~pos;
	268	Type.if_array
	269	ty
cbb4ffb6	270	~f:(fun ty_elements -> return (actual_ty ~pos ty_elements))
161a300d	271	~otherwise:(fun () -> E.raise (E.Exp_not_an_array {ty; pos}))
523e2b06 SK	272	)
523e2b06 SK	273	and trop oper ~left ~right ~pos =
cbb4ffb6	274	(* TODO: Refactor trop - all opers return bool/int *)
523e2b06 SK	275	let expty_left = trexp left in
	276	let expty_right = trexp right in
	277	check_same expty_left expty_right ~pos;
	278	let {exp=_; ty} = expty_left in
	279	let module T = Type in
	280	(match oper with
	281	(* Arithmetic: int *)
	282	\| A.PlusOp
	283	\| A.MinusOp
	284	\| A.TimesOp
	285	\| A.DivideOp ->
	286	check_int expty_left ~pos;
	287	return_int
	288	(* Equality: int, string, array, record *)
	289	\| A.EqOp
	290	\| A.NeqOp ->
	291	if (T.is_int ty)
	292	\|\| (T.is_string ty)
	293	\|\| (T.is_array ty)
	294	\|\| (T.is_record ty)
	295	then
cbb4ffb6	296	return_int (* Because we have no bool type *)
523e2b06 SK	297	else
	298	E.raise (E.Invalid_operand_type
	299	{ oper
	300	; valid = ["int"; "string"; "array"; "record"]
	301	; given = ty
	302	; pos
	303	})
	304	(* Order: int, string *)
	305	\| A.LtOp
	306	\| A.LeOp
	307	\| A.GtOp
	308	\| A.GeOp ->
	309	if (T.is_int ty)
	310	\|\| (T.is_string ty)
	311	then
cbb4ffb6	312	return_int (* Because we have no bool type *)
523e2b06 SK	313	else
	314	E.raise (E.Invalid_operand_type
	315	{ oper
	316	; valid = ["int"; "string"]
	317	; given = ty
	318	; pos
	319	})
	320	)
	321	in
	322	trexp exp
862e5c05	323	and transDec ~(env : Env.t) (dec : A.dec) : Env.t =
8744eb3a SK	324	(match dec with
	325	\| A.VarDec {name; typ=typ_opt; init; pos=pos_outter; escape=_} ->
	326	let ty =
	327	(match (typ_opt, transExp ~env init) with
6ca1afb7	328	\| None, {ty; exp=_} ->
8744eb3a SK	329	ty
8744eb3a SK	330	\| Some (sym, pos_inner), expty_init ->
cbb4ffb6 SK	331	let ty = env_get_typ_actual ~sym ~env ~pos:pos_inner in
cbb4ffb6 SK	332	check_same (return ty) expty_init ~pos:pos_outter;
8744eb3a SK	333	ty
	334	)
	335	in
cc540a7e SK	336	let access =
	337	Translate.alloc_local
	338	~level:(Env.level_get env)
	339	~escapes:true (* Assuming all escape, for now... *)
	340	in
	341	Env.set_val env name (Value.Var {ty; access})
0324a942	342	\| A.TypeDecs typedecs ->
e6e82c08	343	check_cycles typedecs;
cbb4ffb6 SK	344	let env =
	345	List.fold_left typedecs ~init:env ~f:(
	346	fun env (A.TypeDec {name; ty=_; pos=_}) ->
	347	Env.set_typ env name (Type.Name (name, ref None))
	348	)
	349	in
a131e30c SK	350	List.iter typedecs ~f:(fun (A.TypeDec {name=ty_name; ty=ty_exp; pos}) ->
	351	let ty = transTy ~env ~ty_name ~ty_exp in
	352	(match env_get_typ ~sym:ty_name ~env ~pos with
9340b0e3	353	\| Type.Name (_, ty_opt_ref) ->
cbb4ffb6 SK	354	ty_opt_ref := Some ty
	355	\| Type.Unit
	356	\| Type.Nil
	357	\| Type.Int
	358	\| Type.String
	359	\| Type.Record _
	360	\| Type.Array _ ->
	361	()
	362	)
	363	);
	364	env
76c771a7	365	\| A.FunDecs fundecs ->
a284f5c2 SK	366	let env_with_fun_heads_only =
	367	List.fold_left fundecs ~init:env ~f:(
	368	fun env (A.FunDec {name; params; result; body=_; pos=_}) ->
	369	let formals =
	370	List.map params ~f:(
	371	fun (A.Field {name=_; typ; pos; escape=_}) ->
	372	env_get_typ_actual ~env ~sym:typ ~pos
	373	)
	374	in
	375	let result =
	376	match result with
	377	\| Some (s, p) -> env_get_typ_actual ~sym:s ~env ~pos:p
	378	\| None -> Type.Unit
	379	in
cc540a7e SK	380	let label = Temp.Label.gen () in
	381	let level =
	382	Translate.Level.next
	383	(Env.level_get env)
	384	~name:label
	385	(* Assuming all escape (for now) *)
	386	~formals:(List.map formals ~f:(fun _ -> true))
	387	in
	388	let env = Env.level_set env level in
	389	Env.set_val env name (Value.Fun {formals; result; level; label})
a284f5c2 SK	390	)
	391	in
	392	List.iter fundecs ~f:(
	393	fun (A.FunDec {name=_; params; result=_; body; pos=_}) ->
	394	let env_with_fun_heads_and_local_vars =
	395	List.fold_left params ~init:env_with_fun_heads_only ~f:(
	396	fun env (A.Field {name=var_name; escape=_; typ; pos}) ->
	397	let var_ty = env_get_typ_actual ~env ~sym:typ ~pos in
cc540a7e SK	398	let level = Env.level_get env in
	399	(* Assuming all escape, for now *)
	400	let access = Translate.alloc_local ~level ~escapes:true in
	401	Env.set_val
	402	env
	403	var_name
	404	(Value.Var {ty = var_ty; access})
76c771a7 SK	405	)
76c771a7 SK	406	in
a284f5c2 SK	407	(* we only care if an exception is raised *)
	408	ignore (transExp ~env:env_with_fun_heads_and_local_vars body);
	409	);
	410	env_with_fun_heads_only
8744eb3a	411	)
a131e30c	412	and transTy ~(env : Env.t) ~ty_name ~(ty_exp : A.ty) : Type.t =
cbb4ffb6	413	(match ty_exp with
0324a942 SK	414	\| A.NameTy {symbol=sym; pos} ->
	415	env_get_typ ~sym ~env ~pos
	416	\| A.RecordTy fields ->
	417	let fields =
	418	List.map fields ~f:(fun (A.Field {name; escape=_; typ; pos}) ->
	419	let ty = env_get_typ ~sym:typ ~env ~pos in
	420	(name, ty)
	421	)
	422	in
a131e30c	423	Type.new_record ~name:ty_name ~fields
0324a942 SK	424	\| A.ArrayTy {symbol=sym; pos} ->
0324a942 SK	425	let element_ty = env_get_typ ~sym ~env ~pos in
a131e30c	426	Type.new_array ~name:ty_name ~ty:element_ty
0324a942	427	)
155ee327 SK	428	end
155ee327 SK	429
8744eb3a SK	430	open Semant
8744eb3a SK	431
155ee327	432	let transProg absyn =
cc540a7e	433	Escape.find ~prog:absyn;
155ee327 SK	434	let {exp = _; ty = _} = transExp absyn ~env:Env.base in
155ee327 SK	435	()