(* This file is part of the Catala compiler, a specification language for tax and social benefits computation rules. Copyright (C) 2020 Inria, contributor: Alain Delaƫt-Tixeuil Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. *) open Catala_utils open Shared_ast module D = Dcalc.Ast module A = Ast (** We make use of the strong invriants on the structure of programs: Defaultable values can only appear in certin positions. This information is given by the type structure of expressions. In particular this mean we don't need to use the monadic bind while computing arithmetic opertions or function calls. The resulting function is not more difficult than what we had when translating without exceptions. The typing translation is to simply trnsform default type into option types. *) let rec translate_typ (tau : typ) : typ = Mark.copy tau begin match Mark.remove tau with | TDefault t -> TOption (translate_typ t) | TLit l -> TLit l | TTuple ts -> TTuple (List.map translate_typ ts) | TStruct s -> TStruct s | TEnum en -> TEnum en | TOption _ -> Message.error ~internal:true "The types option should not appear before the dcalc -> lcalc \ translation step." | TClosureEnv -> Message.error ~internal:true "The types closure_env should not appear before the dcalc -> lcalc \ translation step." | TAny -> TAny | TArray ts -> TArray (translate_typ ts) | TArrow (t1, t2) -> TArrow (List.map translate_typ t1, translate_typ t2) end let translate_mark m = Expr.map_ty translate_typ m let rec translate_default (exceptions : 'm D.expr list) (just : 'm D.expr) (cons : 'm D.expr) (mark_default : 'm mark) : 'm A.expr boxed = (* Since the program is well typed, all exceptions have as type [option 't] *) let pos = Expr.mark_pos mark_default in let ty_option = Expr.maybe_ty mark_default in let ty_array = TArray ty_option, pos in let ty_alpha = match ty_option with | TOption ty, _ -> ty | (TAny, _) as ty -> ty | _ -> assert false in let mark_alpha = Expr.with_ty mark_default ty_alpha in let if_just_then_cons = let none = Expr.einj ~cons:Expr.none_constr ~name:Expr.option_enum ~e:(Expr.elit LUnit (Expr.with_ty mark_default (TLit TUnit, pos))) mark_default in match just with | ELit (LBool b), _ -> if b then translate_expr cons else none | just -> Expr.eifthenelse (translate_expr just) (translate_expr cons) (Expr.einj ~e:(Expr.elit LUnit (Expr.with_ty mark_default (TLit TUnit, pos))) ~cons:Expr.none_constr ~name:Expr.option_enum mark_default) mark_default in let match_some e = match just with | ELit (LBool false), _ -> (* in this case we can just forward the option in the argument *) e | _ -> Expr.ematch ~name:Expr.option_enum ~e ~cases: (EnumConstructor.Map.of_list [ (* Some x -> Some x *) ( Expr.some_constr, let x = Var.make "x" in Expr.make_ghost_abs [x] (Expr.einj ~name:Expr.option_enum ~cons:Expr.some_constr ~e:(Expr.evar x mark_alpha) mark_default) [ty_alpha] pos ); (* None -> if just then cons else None *) Expr.none_constr, Expr.thunk_term if_just_then_cons; ]) mark_default in match exceptions with | [] -> if_just_then_cons | [((EInj { cons; _ }, _) as e)] -> if EnumConstructor.equal cons Expr.none_constr then Expr.thunk_term if_just_then_cons else if EnumConstructor.equal cons Expr.some_constr then translate_expr e else assert false | [single_exception] -> match_some (translate_expr single_exception) | exceptions -> let exceptions = List.map translate_expr exceptions in match_some (Expr.eappop ~op:(Op.HandleExceptions, Expr.pos cons) ~tys:[ty_array] ~args:[Expr.earray exceptions (Expr.with_ty mark_default ty_array)] mark_default) and translate_expr (e : 'm D.expr) : 'm A.expr boxed = match e with | EEmpty, m -> let m = translate_mark m in let pos = Expr.mark_pos m in Expr.einj ~e:(Expr.elit LUnit (Expr.with_ty m (TLit TUnit, pos))) ~cons:Expr.none_constr ~name:Expr.option_enum m | EErrorOnEmpty arg, m -> let m = translate_mark m in let pos = Expr.mark_pos m in let cases = EnumConstructor.Map.of_list [ ( Expr.none_constr, let x = Var.make "_" in Expr.make_ghost_abs [x] (Expr.efatalerror NoValue m) [TAny, pos] pos ); (* | None x -> raise NoValueProvided *) Expr.some_constr, Expr.fun_id ~var_name:"arg" m (* | Some x -> x *); ] in Expr.ematch ~e:(translate_expr arg) ~name:Expr.option_enum ~cases m | EDefault { excepts; just; cons }, m -> translate_default excepts just cons (translate_mark m) | EPureDefault e, m -> Expr.einj ~e:(translate_expr e) ~cons:Expr.some_constr ~name:Expr.option_enum (translate_mark m) | EAppOp { op; tys; args }, m -> Expr.eappop ~op:(Operator.translate op) ~tys:(List.map translate_typ tys) ~args:(List.map translate_expr args) (translate_mark m) | ( ( ELit _ | EArray _ | EVar _ | EApp _ | EAbs _ | EExternal _ | EIfThenElse _ | ETuple _ | ETupleAccess _ | EInj _ | EAssert _ | EFatalError _ | EStruct _ | EStructAccess _ | EMatch _ ), _ ) as e -> Expr.map ~f:translate_expr ~typ:translate_typ e | _ -> . let add_option_type ctx = { ctx with ctx_enums = EnumName.Map.add Expr.option_enum Expr.option_enum_config ctx.ctx_enums; } let add_option_type_program prg = { prg with decl_ctx = add_option_type prg.decl_ctx } let translate_program (prg : 'm D.program) : 'm A.program = Program.map_exprs (add_option_type_program prg) ~typ:translate_typ ~varf:Var.translate ~f:translate_expr