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https://github.com/CatalaLang/catala.git
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782 lines
27 KiB
OCaml
782 lines
27 KiB
OCaml
(* This file is part of the Catala compiler, a specification language for tax
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and social benefits computation rules. Copyright (C) 2020 Inria, contributor:
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Denis Merigoux <denis.merigoux@inria.fr>, Alain Delaët-Tixeuil
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<alain.delaet--tixeuil@inria.fr>
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Licensed under the Apache License, Version 2.0 (the "License"); you may not
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use this file except in compliance with the License. You may obtain a copy of
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the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
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WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
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License for the specific language governing permissions and limitations under
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the License. *)
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[@@@ocaml.warning "-7-34"]
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open Utils
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module ScopeName : Uid.Id with type info = Uid.MarkedString.info =
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Uid.Make (Uid.MarkedString) ()
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module StructName : Uid.Id with type info = Uid.MarkedString.info =
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Uid.Make (Uid.MarkedString) ()
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module StructFieldName : Uid.Id with type info = Uid.MarkedString.info =
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Uid.Make (Uid.MarkedString) ()
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module StructMap : Map.S with type key = StructName.t = Map.Make (StructName)
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module EnumName : Uid.Id with type info = Uid.MarkedString.info =
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Uid.Make (Uid.MarkedString) ()
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module EnumConstructor : Uid.Id with type info = Uid.MarkedString.info =
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Uid.Make (Uid.MarkedString) ()
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module EnumMap : Map.S with type key = EnumName.t = Map.Make (EnumName)
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type typ_lit = TBool | TUnit | TInt | TRat | TMoney | TDate | TDuration
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type struct_name = StructName.t
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type enum_name = EnumName.t
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type marked_typ = typ Marked.pos
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and typ =
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| TLit of typ_lit
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| TTuple of marked_typ list * StructName.t option
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| TEnum of marked_typ list * EnumName.t
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| TArrow of marked_typ * marked_typ
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| TArray of marked_typ
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| TAny
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type date = Runtime.date
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type duration = Runtime.duration
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type integer = Runtime.integer
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type decimal = Runtime.decimal
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type money = Runtime.money
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type lit =
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| LBool of bool
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| LEmptyError
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| LInt of integer
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| LRat of decimal
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| LMoney of money
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| LUnit
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| LDate of date
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| LDuration of duration
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type op_kind = KInt | KRat | KMoney | KDate | KDuration
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type ternop = Fold
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type binop =
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| And
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| Or
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| Xor
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| Add of op_kind
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| Sub of op_kind
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| Mult of op_kind
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| Div of op_kind
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| Lt of op_kind
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| Lte of op_kind
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| Gt of op_kind
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| Gte of op_kind
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| Eq
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| Neq
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| Map
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| Concat
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| Filter
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type log_entry = VarDef of typ | BeginCall | EndCall | PosRecordIfTrueBool
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type unop =
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| Not
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| Minus of op_kind
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| Log of log_entry * Utils.Uid.MarkedString.info list
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| Length
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| IntToRat
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| GetDay
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| GetMonth
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| GetYear
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| RoundMoney
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| RoundDecimal
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type operator = Ternop of ternop | Binop of binop | Unop of unop
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(** Some structures used for type inference *)
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module Infer = struct
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module Any =
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Utils.Uid.Make
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(struct
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type info = unit
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let format_info fmt () = Format.fprintf fmt "any"
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end)
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()
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type unionfind_typ = typ Marked.pos UnionFind.elem
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(** We do not reuse {!type: Dcalc.Ast.typ} because we have to include a new
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[TAny] variant. Indeed, error terms can have any type and this has to be
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captured by the type sytem. *)
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and typ =
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| TLit of typ_lit
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| TArrow of unionfind_typ * unionfind_typ
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| TTuple of unionfind_typ list * StructName.t option
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| TEnum of unionfind_typ list * EnumName.t
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| TArray of unionfind_typ
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| TAny of Any.t
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let rec typ_to_ast (ty : unionfind_typ) : marked_typ =
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let ty, pos = UnionFind.get (UnionFind.find ty) in
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match ty with
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| TLit l -> TLit l, pos
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| TTuple (ts, s) -> TTuple (List.map typ_to_ast ts, s), pos
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| TEnum (ts, e) -> TEnum (List.map typ_to_ast ts, e), pos
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| TArrow (t1, t2) -> TArrow (typ_to_ast t1, typ_to_ast t2), pos
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| TAny _ -> TAny, pos
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| TArray t1 -> TArray (typ_to_ast t1), pos
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let rec ast_to_typ (ty : marked_typ) : unionfind_typ =
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let ty' =
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match Marked.unmark ty with
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| TLit l -> TLit l
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| TArrow (t1, t2) -> TArrow (ast_to_typ t1, ast_to_typ t2)
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| TTuple (ts, s) -> TTuple (List.map (fun t -> ast_to_typ t) ts, s)
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| TEnum (ts, e) -> TEnum (List.map (fun t -> ast_to_typ t) ts, e)
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| TArray t -> TArray (ast_to_typ t)
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| TAny -> TAny (Any.fresh ())
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in
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UnionFind.make (Marked.same_mark_as ty' ty)
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end
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type untyped = { pos : Pos.t } [@@ocaml.unboxed]
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type typed = { pos : Pos.t; ty : Infer.unionfind_typ }
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(** The generic type of AST markings. Using a GADT allows functions to be
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polymorphic in the marking, but still do transformations on types when
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appropriate *)
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type _ mark = Untyped : untyped -> untyped mark | Typed : typed -> typed mark
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type ('a, 'm) marked = ('a, 'm mark) Marked.t
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type 'm marked_expr = ('m expr, 'm) marked
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and 'm expr =
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| EVar of 'm expr Bindlib.var
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| ETuple of 'm marked_expr list * StructName.t option
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| ETupleAccess of
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'm marked_expr * int * StructName.t option * typ Marked.pos list
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| EInj of 'm marked_expr * int * EnumName.t * typ Marked.pos list
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| EMatch of 'm marked_expr * 'm marked_expr list * EnumName.t
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| EArray of 'm marked_expr list
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| ELit of lit
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| EAbs of
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(('m expr, 'm marked_expr) Bindlib.mbinder[@opaque]) * typ Marked.pos list
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| EApp of 'm marked_expr * 'm marked_expr list
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| EAssert of 'm marked_expr
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| EOp of operator
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| EDefault of 'm marked_expr list * 'm marked_expr * 'm marked_expr
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| EIfThenElse of 'm marked_expr * 'm marked_expr * 'm marked_expr
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| ErrorOnEmpty of 'm marked_expr
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type typed_expr = typed marked_expr
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type struct_ctx = (StructFieldName.t * typ Marked.pos) list StructMap.t
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type enum_ctx = (EnumConstructor.t * typ Marked.pos) list EnumMap.t
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type decl_ctx = { ctx_enums : enum_ctx; ctx_structs : struct_ctx }
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type 'm binder = ('m expr, 'm marked_expr) Bindlib.binder
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type scope_let_kind =
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| DestructuringInputStruct
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| ScopeVarDefinition
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| SubScopeVarDefinition
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| CallingSubScope
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| DestructuringSubScopeResults
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| Assertion
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type ('expr, 'm) scope_let = {
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scope_let_kind : scope_let_kind;
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scope_let_typ : typ Marked.pos;
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scope_let_expr : ('expr, 'm) marked;
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scope_let_next : ('expr, ('expr, 'm) scope_body_expr) Bindlib.binder;
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scope_let_pos : Pos.t;
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}
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and ('expr, 'm) scope_body_expr =
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| Result of ('expr, 'm) marked
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| ScopeLet of ('expr, 'm) scope_let
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type ('expr, 'm) scope_body = {
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scope_body_input_struct : StructName.t;
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scope_body_output_struct : StructName.t;
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scope_body_expr : ('expr, ('expr, 'm) scope_body_expr) Bindlib.binder;
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}
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type ('expr, 'm) scope_def = {
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scope_name : ScopeName.t;
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scope_body : ('expr, 'm) scope_body;
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scope_next : ('expr, ('expr, 'm) scopes) Bindlib.binder;
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}
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and ('expr, 'm) scopes = Nil | ScopeDef of ('expr, 'm) scope_def
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type 'm program = {
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decl_ctx : decl_ctx;
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scopes : ('m expr, 'm) scopes;
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}
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let no_mark (type m) : m mark -> m mark = function
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| Untyped _ -> Untyped { pos = Pos.no_pos }
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| Typed _ ->
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Typed
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{
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pos = Pos.no_pos;
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ty = UnionFind.make Infer.(TAny (Any.fresh ()), Pos.no_pos);
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}
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let mark_pos (type m) (m : m mark) : Pos.t =
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match m with Untyped { pos } | Typed { pos; _ } -> pos
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let pos (type m) (x : ('a, m) marked) : Pos.t = mark_pos (Marked.get_mark x)
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let ty (_, Typed { ty; _ }) : typ = Marked.unmark (Infer.typ_to_ast ty)
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let with_ty (type m) (ty : Infer.unionfind_typ) (x : ('a, m) marked) :
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('a, typed) marked =
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Marked.mark
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(match Marked.get_mark x with
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| Untyped { pos } -> Typed { pos; ty }
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| Typed m -> Typed { m with ty })
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(Marked.unmark x)
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let evar v mark = Bindlib.box_apply (fun v' -> v', mark) (Bindlib.box_var v)
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let etuple args s mark =
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Bindlib.box_apply (fun args -> ETuple (args, s), mark) (Bindlib.box_list args)
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let etupleaccess e1 i s typs mark =
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Bindlib.box_apply (fun e1 -> ETupleAccess (e1, i, s, typs), mark) e1
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let einj e1 i e_name typs mark =
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Bindlib.box_apply (fun e1 -> EInj (e1, i, e_name, typs), mark) e1
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let ematch arg arms e_name mark =
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Bindlib.box_apply2
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(fun arg arms -> EMatch (arg, arms, e_name), mark)
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arg (Bindlib.box_list arms)
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let earray args mark =
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Bindlib.box_apply (fun args -> EArray args, mark) (Bindlib.box_list args)
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let elit l mark = Bindlib.box (ELit l, mark)
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let eabs binder typs mark =
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Bindlib.box_apply (fun binder -> EAbs (binder, typs), mark) binder
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let eapp e1 args mark =
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Bindlib.box_apply2
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(fun e1 args -> EApp (e1, args), mark)
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e1 (Bindlib.box_list args)
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let eassert e1 mark = Bindlib.box_apply (fun e1 -> EAssert e1, mark) e1
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let eop op mark = Bindlib.box (EOp op, mark)
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let edefault excepts just cons mark =
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Bindlib.box_apply3
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(fun excepts just cons -> EDefault (excepts, just, cons), mark)
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(Bindlib.box_list excepts) just cons
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let eifthenelse e1 e2 e3 mark =
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Bindlib.box_apply3 (fun e1 e2 e3 -> EIfThenElse (e1, e2, e3), mark) e1 e2 e3
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let eerroronempty e1 mark =
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Bindlib.box_apply (fun e1 -> ErrorOnEmpty e1, mark) e1
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let map_expr ctx ~f e =
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match Marked.unmark e with
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| EVar v -> evar v (Marked.get_mark e)
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| EApp (e1, args) ->
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eapp (f ctx e1) (List.map (f ctx) args) (Marked.get_mark e)
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| EAbs (binder, typs) ->
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eabs (Bindlib.box_mbinder (f ctx) binder) typs (Marked.get_mark e)
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| ETuple (args, s) -> etuple (List.map (f ctx) args) s (Marked.get_mark e)
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| ETupleAccess (e1, n, s_name, typs) ->
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etupleaccess ((f ctx) e1) n s_name typs (Marked.get_mark e)
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| EInj (e1, i, e_name, typs) ->
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einj ((f ctx) e1) i e_name typs (Marked.get_mark e)
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| EMatch (arg, arms, e_name) ->
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ematch ((f ctx) arg) (List.map (f ctx) arms) e_name (Marked.get_mark e)
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| EArray args -> earray (List.map (f ctx) args) (Marked.get_mark e)
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| ELit l -> elit l (Marked.get_mark e)
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| EAssert e1 -> eassert ((f ctx) e1) (Marked.get_mark e)
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| EOp op -> Bindlib.box (EOp op, Marked.get_mark e)
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| EDefault (excepts, just, cons) ->
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edefault
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(List.map (f ctx) excepts)
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((f ctx) just)
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((f ctx) cons)
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(Marked.get_mark e)
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| EIfThenElse (e1, e2, e3) ->
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eifthenelse ((f ctx) e1) ((f ctx) e2) ((f ctx) e3) (Marked.get_mark e)
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| ErrorOnEmpty e1 -> eerroronempty ((f ctx) e1) (Marked.get_mark e)
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type ('expr, 'm) box_expr_sig =
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('expr, 'm) marked -> ('expr, 'm) marked Bindlib.box
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(** See [Bindlib.box_term] documentation for why we are doing that. *)
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let box_expr : ('m expr, 'm) box_expr_sig =
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fun e ->
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let rec id_t () e = map_expr () ~f:id_t e in
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id_t () e
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let rec fold_left_scope_lets ~f ~init scope_body_expr =
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match scope_body_expr with
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| Result _ -> init
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| ScopeLet scope_let ->
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let var, next = Bindlib.unbind scope_let.scope_let_next in
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fold_left_scope_lets ~f ~init:(f init scope_let var) next
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let rec fold_right_scope_lets ~f ~init scope_body_expr =
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match scope_body_expr with
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| Result result -> init result
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| ScopeLet scope_let ->
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let var, next = Bindlib.unbind scope_let.scope_let_next in
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let next_result = fold_right_scope_lets ~f ~init next in
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f scope_let var next_result
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let map_exprs_in_scope_lets ~f ~varf scope_body_expr =
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fold_right_scope_lets
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~f:(fun scope_let var_next acc ->
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Bindlib.box_apply2
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(fun scope_let_next scope_let_expr ->
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ScopeLet { scope_let with scope_let_next; scope_let_expr })
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(Bindlib.bind_var (varf var_next) acc)
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(f scope_let.scope_let_expr))
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~init:(fun res -> Bindlib.box_apply (fun res -> Result res) (f res))
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scope_body_expr
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let rec fold_left_scope_defs ~f ~init scopes =
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match scopes with
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| Nil -> init
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| ScopeDef scope_def ->
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let var, next = Bindlib.unbind scope_def.scope_next in
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fold_left_scope_defs ~f ~init:(f init scope_def var) next
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let rec fold_right_scope_defs ~f ~init scopes =
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match scopes with
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| Nil -> init
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| ScopeDef scope_def ->
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let var_next, next = Bindlib.unbind scope_def.scope_next in
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let result_next = fold_right_scope_defs ~f ~init next in
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f scope_def var_next result_next
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let map_scope_defs ~f scopes =
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fold_right_scope_defs
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~f:(fun scope_def var_next acc ->
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let new_scope_def = f scope_def in
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let new_next = Bindlib.bind_var var_next acc in
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Bindlib.box_apply2
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(fun new_scope_def new_next ->
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ScopeDef { new_scope_def with scope_next = new_next })
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new_scope_def new_next)
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~init:(Bindlib.box Nil) scopes
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let map_exprs_in_scopes ~f ~varf scopes =
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fold_right_scope_defs
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~f:(fun scope_def var_next acc ->
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let scope_input_var, scope_lets =
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Bindlib.unbind scope_def.scope_body.scope_body_expr
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in
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let new_scope_body_expr = map_exprs_in_scope_lets ~f ~varf scope_lets in
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let new_scope_body_expr =
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Bindlib.bind_var (varf scope_input_var) new_scope_body_expr
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in
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let new_next = Bindlib.bind_var (varf var_next) acc in
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Bindlib.box_apply2
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(fun scope_body_expr scope_next ->
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ScopeDef {
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scope_def with
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scope_body = { scope_def.scope_body with scope_body_expr };
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scope_next;
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})
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new_scope_body_expr
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new_next)
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~init:(Bindlib.box Nil)
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scopes
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type 'm var = 'm expr Bindlib.var
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let new_var s = Bindlib.new_var (fun x -> EVar x) s
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module Var = struct
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type t = V : 'm var -> t
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(* We use this trivial GADT to make the 'm parameter disappear under an
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existential. It's fine for a use as keys only.
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(bindlib defines [any_var] similarly but it's not exported)
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todo: add [@@ocaml.unboxed] once it's possible through abstract types *)
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let t v = V v
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let make (s : string) : t = V (new_var s)
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let compare (V x) (V y) = Bindlib.compare_vars x y
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end
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module VarSet = Set.Make (Var)
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module VarMap = Map.Make (Var)
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(* let rec free_vars_expr (e : untyped marked_expr) : VarSet.t = match
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Marked.unmark e with | EVar v -> VarSet.singleton v | ETuple (es, _) | EArray
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es -> es |> List.map free_vars_expr |> List.fold_left VarSet.union
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VarSet.empty | ETupleAccess (e1, _, _, _) | EAssert e1 | ErrorOnEmpty e1 |
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EInj (e1, _, _, _) -> free_vars_expr e1 | EApp (e1, es) | EMatch (e1, es, _)
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-> e1 :: es |> List.map free_vars_expr |> List.fold_left VarSet.union
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VarSet.empty | EDefault (es, ejust, econs) -> ejust :: econs :: es |>
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List.map free_vars_expr |> List.fold_left VarSet.union VarSet.empty | EOp _ |
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ELit _ -> VarSet.empty | EIfThenElse (e1, e2, e3) -> [e1; e2; e3] |> List.map
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free_vars_expr |> List.fold_left VarSet.union VarSet.empty | EAbs (binder, _)
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-> let vs, body = Bindlib.unmbind binder in Array.fold_right VarSet.remove vs
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(free_vars_expr body)
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module VarMap = Map.Make (Var(struct type t = untyped end)) module VarSet =
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Set.Make (Var(struct type t = untyped end))
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let rec free_vars_expr (e : expr) : VarSet.t = match Marked.unmark e with |
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EVar (v, _) -> VarSet.singleton v | ETuple (es, _) | EArray es -> es |>
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List.map free_vars_expr |> List.fold_left VarSet.union VarSet.empty |
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ETupleAccess (e1, _, _, _) | EAssert e1 | ErrorOnEmpty e1 | EInj (e1, _, _,
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_) -> free_vars_expr e1 | EApp (e1, es) | EMatch (e1, es, _) -> e1 :: es |>
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List.map free_vars_expr |> List.fold_left VarSet.union VarSet.empty |
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EDefault (es, ejust, econs) -> ejust :: econs :: es |> List.map
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free_vars_expr |> List.fold_left VarSet.union VarSet.empty | EOp _ | ELit _
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-> VarSet.empty | EIfThenElse (e1, e2, e3) -> [e1; e2; e3] |> List.map
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free_vars_expr |> List.fold_left VarSet.union VarSet.empty | EAbs ((binder,
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_), _) -> let vs, body = Bindlib.unmbind binder in Array.fold_right
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VarSet.remove vs (free_vars_expr body)
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let rec free_vars_scope_body_expr (scope_lets : expr scope_body_expr) :
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VarSet.t = match scope_lets with | Result e -> free_vars_expr e | ScopeLet {
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scope_let_expr = e; scope_let_next = next; _ } -> let v, body =
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Bindlib.unbind next in VarSet.union (free_vars_expr e) (VarSet.remove v
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(free_vars_scope_body_expr body))
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let free_vars_scope_body (scope_body : expr scope_body) : VarSet.t = let {
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scope_body_expr = binder; _ } = scope_body in let v, body = Bindlib.unbind
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binder in VarSet.remove v (free_vars_scope_body_expr body)
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let rec free_vars_scopes (scopes : expr scopes) : VarSet.t = match scopes
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with | Nil -> VarSet.empty | ScopeDef { scope_body = body; scope_next = next;
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_ } -> let v, next = Bindlib.unbind next in VarSet.union (VarSet.remove v
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(free_vars_scopes next)) (free_vars_scope_body body) (* type vars = expr
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Bindlib.mvar *) *)
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let make_var ((x, mark) : ('m expr Bindlib.var, 'm) marked) :
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'm marked_expr Bindlib.box =
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Bindlib.box_apply (fun x -> x, mark) (Bindlib.box_var x)
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(* 'm expr → 'e 'm marked_expr = ('m expr, 'm) marked → ('e, 'm) marked
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('e, 'x) marked = ('e, 'x mark) Marked.t = ('e * 'x mark)
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'e Bindlib.mvar -> ('e, 'm) Marked.t Bindlib.box -> typ Marked.pos list -> 'm
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-> ('e, 'm) Marked.t Bindlib.box *)
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(* 'e = 'm expr ('e, 'm) marked = ('e, 'm mark) Marked.t = ('m expr, 'm mark)
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Marked.t *)
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type ('e, 'm) make_abs_sig =
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'e Bindlib.mvar ->
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('e, 'm) marked Bindlib.box ->
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typ Marked.pos list ->
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'm mark ->
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('e, 'm) marked Bindlib.box
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let (make_abs : ('m expr, 'm) make_abs_sig) =
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fun xs e taus mark ->
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Bindlib.box_apply (fun b -> EAbs (b, taus), mark) (Bindlib.bind_mvar xs e)
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let make_app :
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'm marked_expr Bindlib.box ->
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'm marked_expr Bindlib.box list ->
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'm mark ->
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'm marked_expr Bindlib.box =
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fun e u mark ->
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Bindlib.box_apply2 (fun e u -> EApp (e, u), mark) e (Bindlib.box_list u)
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type ('expr, 'm) make_let_in_sig =
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'expr Bindlib.var ->
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typ Marked.pos ->
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('expr, 'm) marked Bindlib.box ->
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('expr, 'm) marked Bindlib.box ->
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Pos.t ->
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('expr, 'm) marked Bindlib.box
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let map_mark
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(type m)
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(pos_f : Pos.t -> Pos.t)
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(ty_f : Infer.unionfind_typ -> Infer.unionfind_typ)
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(m : m mark) : m mark =
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match m with
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| Untyped { pos } -> Untyped { pos = pos_f pos }
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| Typed { pos; ty } -> Typed { pos = pos_f pos; ty = ty_f ty }
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let map_mark2
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(type m)
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(pos_f : Pos.t -> Pos.t -> Pos.t)
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(ty_f : typed -> typed -> Infer.unionfind_typ)
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(m1 : m mark)
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(m2 : m mark) : m mark =
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match m1, m2 with
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| Untyped m1, Untyped m2 -> Untyped { pos = pos_f m1.pos m2.pos }
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| Typed m1, Typed m2 -> Typed { pos = pos_f m1.pos m2.pos; ty = ty_f m1 m2 }
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let fold_marks
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(type m)
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(pos_f : Pos.t list -> Pos.t)
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(ty_f : typed list -> Infer.unionfind_typ)
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(ms : m mark list) : m mark =
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match ms with
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| [] -> invalid_arg "Dcalc.Ast.fold_mark"
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| Untyped _ :: _ as ms ->
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Untyped { pos = pos_f (List.map (function Untyped { pos } -> pos) ms) }
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| Typed _ :: _ ->
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Typed
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{
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pos = pos_f (List.map (function Typed { pos; _ } -> pos) ms);
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ty = ty_f (List.map (function Typed m -> m) ms);
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}
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let empty_thunked_term mark : 'm marked_expr =
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let silent = new_var "_" in
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let pos = mark_pos mark in
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Bindlib.unbox
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(make_abs [| silent |]
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(Bindlib.box (ELit LEmptyError, mark))
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[TLit TUnit, mark_pos mark]
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(map_mark
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(fun pos -> pos)
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(fun ty ->
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UnionFind.make
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Infer.(
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TArrow (UnionFind.make (TLit TUnit, pos), ty), mark_pos mark))
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mark))
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let (make_let_in : ('m expr, 'm) make_let_in_sig) =
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fun x tau e1 e2 pos ->
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let m_e1 = Marked.get_mark (Bindlib.unbox e1) in
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let m_e2 = Marked.get_mark (Bindlib.unbox e2) in
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let m_abs =
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map_mark2
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(fun _ _ -> pos)
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(fun m1 m2 -> UnionFind.make (Infer.TArrow (m1.ty, m2.ty), m1.pos))
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m_e1 m_e2
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in
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make_app (make_abs [| x |] e2 [tau] m_abs) [e1] m_e2
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let is_value (e : 'e marked_expr) : bool =
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match Marked.unmark e with ELit _ | EAbs _ | EOp _ -> true | _ -> false
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let rec equal_typs (ty1 : typ Marked.pos) (ty2 : typ Marked.pos) : bool =
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match Marked.unmark ty1, Marked.unmark ty2 with
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| TLit l1, TLit l2 -> l1 = l2
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| TTuple (tys1, n1), TTuple (tys2, n2) -> n1 = n2 && equal_typs_list tys1 tys2
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| TEnum (tys1, n1), TEnum (tys2, n2) -> n1 = n2 && equal_typs_list tys1 tys2
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| TArrow (t1, t1'), TArrow (t2, t2') -> equal_typs t1 t2 && equal_typs t1' t2'
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| TArray t1, TArray t2 -> equal_typs t1 t2
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| TAny, TAny -> true
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| _, _ -> false
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and equal_typs_list (tys1 : typ Marked.pos list) (tys2 : typ Marked.pos list) :
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bool =
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List.length tys1 = List.length tys2
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&& (* OCaml && operator short-circuits when a clause is false, we can safely
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assume here that both lists have equal length *)
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List.for_all (fun (x, y) -> equal_typs x y) (List.combine tys1 tys2)
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let equal_log_entries (l1 : log_entry) (l2 : log_entry) : bool =
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match l1, l2 with
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| VarDef t1, VarDef t2 -> equal_typs (t1, Pos.no_pos) (t2, Pos.no_pos)
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| x, y -> x = y
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let equal_unops (op1 : unop) (op2 : unop) : bool =
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match op1, op2 with
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(* Log entries contain a typ which contain position information, we thus need
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to descend into them *)
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| Log (l1, info1), Log (l2, info2) -> equal_log_entries l1 l2 && info1 = info2
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(* All the other cases can be discharged through equality *)
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| _ -> op1 = op2
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let equal_ops (op1 : operator) (op2 : operator) : bool =
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match op1, op2 with
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| Ternop op1, Ternop op2 -> op1 = op2
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| Binop op1, Binop op2 -> op1 = op2
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| Unop op1, Unop op2 -> equal_unops op1 op2
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| _, _ -> false
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let rec equal_exprs (e1 : 'm marked_expr) (e2 : 'm marked_expr) : bool =
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match Marked.unmark e1, Marked.unmark e2 with
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| EVar v1, EVar v2 -> Bindlib.eq_vars v1 v2
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| ETuple (es1, n1), ETuple (es2, n2) -> n1 = n2 && equal_exprs_list es1 es2
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| ETupleAccess (e1, id1, n1, tys1), ETupleAccess (e2, id2, n2, tys2) ->
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equal_exprs e1 e2 && id1 = id2 && n1 = n2 && equal_typs_list tys1 tys2
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| EInj (e1, id1, n1, tys1), EInj (e2, id2, n2, tys2) ->
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equal_exprs e1 e2 && id1 = id2 && n1 = n2 && equal_typs_list tys1 tys2
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| EMatch (e1, cases1, n1), EMatch (e2, cases2, n2) ->
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n1 = n2 && equal_exprs e1 e2 && equal_exprs_list cases1 cases2
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| EArray es1, EArray es2 -> equal_exprs_list es1 es2
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| ELit l1, ELit l2 -> l1 = l2
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| EAbs (b1, tys1), EAbs (b2, tys2) ->
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equal_typs_list tys1 tys2
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&&
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let vars1, body1 = Bindlib.unmbind b1 in
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let body2 = Bindlib.msubst b2 (Array.map (fun x -> EVar x) vars1) in
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equal_exprs body1 body2
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| EAssert e1, EAssert e2 -> equal_exprs e1 e2
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| EOp op1, EOp op2 -> equal_ops op1 op2
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| EDefault (exc1, def1, cons1), EDefault (exc2, def2, cons2) ->
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equal_exprs def1 def2 && equal_exprs cons1 cons2
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&& equal_exprs_list exc1 exc2
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| EIfThenElse (if1, then1, else1), EIfThenElse (if2, then2, else2) ->
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equal_exprs if1 if2 && equal_exprs then1 then2 && equal_exprs else1 else2
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| ErrorOnEmpty e1, ErrorOnEmpty e2 -> equal_exprs e1 e2
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| _, _ -> false
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and equal_exprs_list (es1 : 'e marked_expr list) (es2 : 'm marked_expr list) :
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bool =
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List.length es1 = List.length es2
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&& (* OCaml && operator short-circuits when a clause is false, we can safely
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assume here that both lists have equal length *)
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List.for_all (fun (x, y) -> equal_exprs x y) (List.combine es1 es2)
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let rec unfold_scope_body_expr
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~(box_expr : ('expr, 'm) box_expr_sig)
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~(make_let_in : ('expr, 'm) make_let_in_sig)
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(ctx : decl_ctx)
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(scope_let : ('expr, 'm) scope_body_expr) : ('expr, 'm) marked Bindlib.box =
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match scope_let with
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| Result e -> box_expr e
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| ScopeLet
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{
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scope_let_kind = _;
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scope_let_typ;
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scope_let_expr;
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scope_let_next;
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scope_let_pos;
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} ->
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let var, next = Bindlib.unbind scope_let_next in
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make_let_in var scope_let_typ (box_expr scope_let_expr)
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(unfold_scope_body_expr ~box_expr ~make_let_in ctx next)
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scope_let_pos
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let build_whole_scope_expr
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~(box_expr : ('expr, 'm) box_expr_sig)
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~(make_abs : ('expr, 'm) make_abs_sig)
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~(make_let_in : ('expr, 'm) make_let_in_sig)
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(ctx : decl_ctx)
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(body : ('expr, 'm) scope_body)
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(mark_scope : 'm mark) : ('expr, 'm) marked Bindlib.box =
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let var, body_expr = Bindlib.unbind body.scope_body_expr in
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let body_expr = unfold_scope_body_expr ~box_expr ~make_let_in ctx body_expr in
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make_abs (Array.of_list [var]) body_expr
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[
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( TTuple
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( List.map snd
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(StructMap.find body.scope_body_input_struct ctx.ctx_structs),
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Some body.scope_body_input_struct ),
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mark_pos mark_scope );
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]
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mark_scope
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let build_scope_typ_from_sig
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(ctx : decl_ctx)
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(scope_input_struct_name : StructName.t)
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(scope_return_struct_name : StructName.t)
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(pos : Pos.t) : typ Marked.pos =
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let scope_sig = StructMap.find scope_input_struct_name ctx.ctx_structs in
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let scope_return_typ =
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StructMap.find scope_return_struct_name ctx.ctx_structs
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in
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let result_typ =
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TTuple (List.map snd scope_return_typ, Some scope_return_struct_name), pos
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in
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let input_typ =
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TTuple (List.map snd scope_sig, Some scope_input_struct_name), pos
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in
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TArrow (input_typ, result_typ), pos
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type 'expr scope_name_or_var =
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| ScopeName of ScopeName.t
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| ScopeVar of 'expr Bindlib.var
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let get_scope_body_mark scope_body =
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match snd (Bindlib.unbind scope_body.scope_body_expr) with
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| Result e | ScopeLet { scope_let_expr = e; _ } -> Marked.get_mark e
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let rec unfold_scopes
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~(box_expr : ('expr, 'm) box_expr_sig)
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~(make_abs : ('expr, 'm) make_abs_sig)
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~(make_let_in : ('expr, 'm) make_let_in_sig)
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(ctx : decl_ctx)
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(s : ('expr, 'm) scopes)
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(mark_witness : 'm mark)
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(main_scope : 'expr scope_name_or_var) : ('expr, 'm) marked Bindlib.box =
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match s with
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| Nil -> (
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match main_scope with
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| ScopeVar v ->
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Bindlib.box_apply (fun v -> v, no_mark mark_witness) (Bindlib.box_var v)
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| ScopeName _ -> failwith "should not happen")
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| ScopeDef { scope_name; scope_body; scope_next } ->
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let scope_var, scope_next = Bindlib.unbind scope_next in
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let scope_pos = Marked.get_mark (ScopeName.get_info scope_name) in
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let scope_body_mark = get_scope_body_mark scope_body in
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let main_scope =
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match main_scope with
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| ScopeVar v -> ScopeVar v
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| ScopeName n ->
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if ScopeName.compare n scope_name = 0 then ScopeVar scope_var
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else ScopeName n
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in
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make_let_in scope_var
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(build_scope_typ_from_sig ctx scope_body.scope_body_input_struct
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scope_body.scope_body_output_struct scope_pos)
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(build_whole_scope_expr ~box_expr ~make_abs ~make_let_in ctx scope_body
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scope_body_mark)
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(unfold_scopes ~box_expr ~make_abs ~make_let_in ctx scope_next
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mark_witness main_scope)
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scope_pos
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let build_whole_program_expr (p : 'm program) (main_scope : ScopeName.t) =
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unfold_scopes ~box_expr ~make_abs ~make_let_in p.decl_ctx p.scopes
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p.mark_witness (ScopeName main_scope)
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let rec expr_size (e : 'm marked_expr) : int =
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match Marked.unmark e with
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| EVar _ | ELit _ | EOp _ -> 1
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| ETuple (args, _) | EArray args ->
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List.fold_left (fun acc arg -> acc + expr_size arg) 1 args
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| ETupleAccess (e1, _, _, _)
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| EInj (e1, _, _, _)
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| EAssert e1
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| ErrorOnEmpty e1 ->
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expr_size e1 + 1
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| EMatch (arg, args, _) | EApp (arg, args) ->
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List.fold_left (fun acc arg -> acc + expr_size arg) (1 + expr_size arg) args
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| EAbs (binder, _) ->
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let _, body = Bindlib.unmbind binder in
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1 + expr_size body
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| EIfThenElse (e1, e2, e3) -> 1 + expr_size e1 + expr_size e2 + expr_size e3
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| EDefault (exceptions, just, cons) ->
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|
List.fold_left
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(fun acc except -> acc + expr_size except)
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(1 + expr_size just + expr_size cons)
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exceptions
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|
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let remove_logging_calls (e : 'm marked_expr) : 'm marked_expr Bindlib.box =
|
|
let rec f () e =
|
|
match Marked.unmark e with
|
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| EApp ((EOp (Unop (Log _)), _), [arg]) -> map_expr () ~f arg
|
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| _ -> map_expr () ~f e
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in
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|
f () e
|