mirror of
https://github.com/CatalaLang/catala.git
synced 2024-11-09 22:16:10 +03:00
415 lines
16 KiB
OCaml
415 lines
16 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) 2022 Inria, contributor:
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Denis Merigoux <denis.merigoux@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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open Catala_utils
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open Shared_ast
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open Ast
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module D = Dcalc.Ast
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(** TODO: This version is not yet debugged and ought to be specialized when
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Lcalc has more structure. *)
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type 'm ctx = {
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decl_ctx : decl_ctx;
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name_context : string;
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globally_bound_vars : 'm expr Var.Set.t;
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}
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let tys_as_tanys tys = List.map (fun x -> Mark.map (fun _ -> TAny) x) tys
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type 'm hoisted_closure = { name : 'm expr Var.t; closure : 'm expr }
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let rec hoist_context_free_closures :
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type m. m ctx -> m expr -> m hoisted_closure list * m expr boxed =
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fun ctx e ->
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let m = Mark.get e in
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match Mark.remove e with
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| EMatch { e; cases; name } ->
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let collected_closures, new_e = (hoist_context_free_closures ctx) e in
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(* We do not close the closures inside the arms of the match expression,
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since they get a special treatment at compilation to Scalc. *)
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let collected_closures, new_cases =
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EnumConstructor.Map.fold
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(fun cons e1 (collected_closures, new_cases) ->
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match Mark.remove e1 with
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| EAbs { binder; tys } ->
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let vars, body = Bindlib.unmbind binder in
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let new_collected_closures, new_body =
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(hoist_context_free_closures ctx) body
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in
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let new_binder = Expr.bind vars new_body in
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( collected_closures @ new_collected_closures,
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EnumConstructor.Map.add cons
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(Expr.eabs new_binder tys (Mark.get e1))
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new_cases )
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| _ -> failwith "should not happen")
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cases
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(collected_closures, EnumConstructor.Map.empty)
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in
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collected_closures, Expr.ematch new_e name new_cases m
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| EApp { f = EAbs { binder; tys }, e1_pos; args } ->
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(* let-binding, we should not close these *)
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let vars, body = Bindlib.unmbind binder in
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let collected_closures, new_body = (hoist_context_free_closures ctx) body in
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let new_binder = Expr.bind vars new_body in
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let collected_closures, new_args =
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List.fold_right
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(fun arg (collected_closures, new_args) ->
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let new_collected_closures, new_arg =
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(hoist_context_free_closures ctx) arg
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in
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collected_closures @ new_collected_closures, new_arg :: new_args)
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args (collected_closures, [])
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in
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( collected_closures,
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Expr.eapp (Expr.eabs new_binder (tys_as_tanys tys) e1_pos) new_args m )
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| EAbs _ ->
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(* this is the closure we want to hoist*)
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let closure_var = Var.make ctx.name_context in
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[{ name = closure_var; closure = e }], Expr.make_var closure_var m
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| EApp _ | EStruct _ | EStructAccess _ | ETuple _ | ETupleAccess _ | EInj _
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| EArray _ | ELit _ | EAssert _ | EOp _ | EIfThenElse _ | ERaise _ | ECatch _
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| EVar _ ->
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Expr.map_gather ~acc:[] ~join:( @ ) ~f:(hoist_context_free_closures ctx) e
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| _ -> .
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[@@warning "-32"]
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(** Returns the expression with closed closures and the set of free variables
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inside this new expression. Implementation guided by
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http://gallium.inria.fr/~fpottier/mpri/cours04.pdf#page=10
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(environment-passing closure conversion). *)
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let rec transform_closures_expr :
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type m. m ctx -> m expr -> m expr Var.Set.t * m expr boxed =
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fun ctx e ->
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let m = Mark.get e in
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match Mark.remove e with
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| EStruct _ | EStructAccess _ | ETuple _ | ETupleAccess _ | EInj _ | EArray _
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| ELit _ | EAssert _ | EOp _ | EIfThenElse _ | ERaise _ | ECatch _ ->
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Expr.map_gather ~acc:Var.Set.empty ~join:Var.Set.union
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~f:(transform_closures_expr ctx)
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e
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| EVar v ->
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( (if Var.Set.mem v ctx.globally_bound_vars then Var.Set.empty
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else Var.Set.singleton v),
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(Bindlib.box_var v, m) )
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| EMatch { e; cases; name } ->
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let free_vars, new_e = (transform_closures_expr ctx) e in
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(* We do not close the clotures inside the arms of the match expression,
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since they get a special treatment at compilation to Scalc. *)
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let free_vars, new_cases =
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EnumConstructor.Map.fold
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(fun cons e1 (free_vars, new_cases) ->
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match Mark.remove e1 with
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| EAbs { binder; tys } ->
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let vars, body = Bindlib.unmbind binder in
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let new_free_vars, new_body = (transform_closures_expr ctx) body in
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let new_binder = Expr.bind vars new_body in
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( Var.Set.union free_vars
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(Var.Set.diff new_free_vars
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(Var.Set.of_list (Array.to_list vars))),
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EnumConstructor.Map.add cons
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(Expr.eabs new_binder tys (Mark.get e1))
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new_cases )
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| _ -> failwith "should not happen")
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cases
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(free_vars, EnumConstructor.Map.empty)
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in
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free_vars, Expr.ematch new_e name new_cases m
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| EApp { f = EAbs { binder; tys }, e1_pos; args } ->
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(* let-binding, we should not close these *)
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let vars, body = Bindlib.unmbind binder in
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let free_vars, new_body = (transform_closures_expr ctx) body in
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let new_binder = Expr.bind vars new_body in
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let free_vars, new_args =
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List.fold_right
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(fun arg (free_vars, new_args) ->
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let new_free_vars, new_arg = (transform_closures_expr ctx) arg in
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Var.Set.union free_vars new_free_vars, new_arg :: new_args)
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args (free_vars, [])
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in
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( free_vars,
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Expr.eapp (Expr.eabs new_binder (tys_as_tanys tys) e1_pos) new_args m )
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| EAbs { binder; tys } ->
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(* λ x.t *)
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let binder_mark = m in
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let binder_pos = Expr.mark_pos binder_mark in
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(* Converting the closure. *)
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let vars, body = Bindlib.unmbind binder in
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(* t *)
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let body_vars, new_body = (transform_closures_expr ctx) body in
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(* [[t]] *)
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let extra_vars =
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Var.Set.diff body_vars (Var.Set.of_list (Array.to_list vars))
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in
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let extra_vars_list = Var.Set.elements extra_vars in
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(* x1, ..., xn *)
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let code_var = Var.make ctx.name_context in
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(* code *)
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let closure_env_arg_var = Var.make "env" in
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let closure_env_var = Var.make "env" in
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let any_ty = TAny, binder_pos in
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(* let env = from_closure_env env in let arg0 = env.0 in ... *)
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let new_closure_body =
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Expr.make_let_in closure_env_var any_ty
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(Expr.eapp
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(Expr.eop Operator.FromClosureEnv
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[TClosureEnv, binder_pos]
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binder_mark)
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[Expr.evar closure_env_arg_var binder_mark]
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binder_mark)
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(Expr.make_multiple_let_in
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(Array.of_list extra_vars_list)
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(List.map (fun _ -> any_ty) extra_vars_list)
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(List.mapi
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(fun i _ ->
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Expr.etupleaccess
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(Expr.evar closure_env_var binder_mark)
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i
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(List.length extra_vars_list)
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binder_mark)
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extra_vars_list)
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new_body binder_pos)
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binder_pos
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in
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(* fun env arg0 ... -> new_closure_body *)
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let new_closure =
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Expr.make_abs
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(Array.concat [Array.make 1 closure_env_arg_var; vars])
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new_closure_body
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((TClosureEnv, binder_pos) :: tys)
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(Expr.pos e)
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in
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( extra_vars,
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Expr.make_let_in code_var
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(TAny, Expr.pos e)
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new_closure
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(Expr.etuple
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((Bindlib.box_var code_var, binder_mark)
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:: [
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Expr.eapp
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(Expr.eop Operator.ToClosureEnv
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[TAny, Expr.pos e]
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(Mark.get e))
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[
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(if extra_vars_list = [] then Expr.elit LUnit binder_mark
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else
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Expr.etuple
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(List.map
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(fun extra_var ->
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Bindlib.box_var extra_var, binder_mark)
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extra_vars_list)
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m);
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]
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(Mark.get e);
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])
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m)
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(Expr.pos e) )
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| EApp
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{
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f =
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(EOp { op = HandleDefaultOpt | Fold | Map | Filter | Reduce; _ }, _)
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as f;
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args;
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} ->
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(* Special case for some operators: its arguments closures thunks because if
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you want to extract it as a function you need these closures to preserve
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evaluation order, but backends that don't support closures will simply
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extract these operators in a inlined way and skip the thunks. *)
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let free_vars, new_args =
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List.fold_right
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(fun (arg : (lcalc, m) gexpr) (free_vars, new_args) ->
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let m_arg = Mark.get arg in
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match Mark.remove arg with
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| EAbs { binder; tys } ->
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let vars, arg = Bindlib.unmbind binder in
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let new_free_vars, new_arg = (transform_closures_expr ctx) arg in
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let new_arg =
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Expr.make_abs vars new_arg tys (Expr.mark_pos m_arg)
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in
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Var.Set.union free_vars new_free_vars, new_arg :: new_args
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| _ ->
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let new_free_vars, new_arg = transform_closures_expr ctx arg in
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Var.Set.union free_vars new_free_vars, new_arg :: new_args)
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args (Var.Set.empty, [])
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in
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free_vars, Expr.eapp (Expr.box f) new_args (Mark.get e)
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| EApp { f = EOp _, _; _ } ->
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(* This corresponds to an operator call, which we don't want to transform*)
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Expr.map_gather ~acc:Var.Set.empty ~join:Var.Set.union
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~f:(transform_closures_expr ctx)
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e
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| EApp { f = EVar v, _; _ } when Var.Set.mem v ctx.globally_bound_vars ->
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(* This corresponds to a scope call, which we don't want to transform*)
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Expr.map_gather ~acc:Var.Set.empty ~join:Var.Set.union
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~f:(transform_closures_expr ctx)
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e
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| EApp { f = e1; args } ->
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let free_vars, new_e1 = (transform_closures_expr ctx) e1 in
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let code_env_var = Var.make "code_and_env" in
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let env_var = Var.make "env" in
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let code_var = Var.make "code" in
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let free_vars, new_args =
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List.fold_right
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(fun arg (free_vars, new_args) ->
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let new_free_vars, new_arg = (transform_closures_expr ctx) arg in
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Var.Set.union free_vars new_free_vars, new_arg :: new_args)
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args (free_vars, [])
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in
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let call_expr =
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let m1 = Mark.get e1 in
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Expr.make_let_in code_var
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(TAny, Expr.pos e)
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(Expr.etupleaccess (Bindlib.box_var code_env_var, m1) 0 2 m)
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(Expr.make_let_in env_var
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(TAny, Expr.pos e)
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(Expr.etupleaccess (Bindlib.box_var code_env_var, m1) 1 2 m)
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(Expr.eapp
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(Bindlib.box_var code_var, m1)
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((Bindlib.box_var env_var, m1) :: new_args)
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m)
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(Expr.pos e))
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(Expr.pos e)
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in
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( free_vars,
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Expr.make_let_in code_env_var
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(TAny, Expr.pos e)
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new_e1 call_expr (Expr.pos e) )
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| _ -> .
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(* Here I have to reimplement Scope.map_exprs_in_lets because I'm changing the
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type *)
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let closure_conversion_scope_let ctx scope_body_expr =
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Scope.fold_right_lets
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~f:(fun scope_let var_next acc ->
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let _free_vars, new_scope_let_expr =
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(transform_closures_expr
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{ ctx with name_context = Bindlib.name_of var_next })
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scope_let.scope_let_expr
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in
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Bindlib.box_apply2
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(fun scope_let_next scope_let_expr ->
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ScopeLet
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{
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scope_let with
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scope_let_next;
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scope_let_expr;
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scope_let_typ = Mark.copy scope_let.scope_let_typ TAny;
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})
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(Bindlib.bind_var var_next acc)
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(Expr.Box.lift new_scope_let_expr))
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~init:(fun res ->
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let _free_vars, new_scope_let_expr = (transform_closures_expr ctx) res in
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(* INVARIANT here: the result expr of a scope is simply a struct
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containing all output variables so nothing should be converted here, so
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no need to take into account free variables. *)
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Bindlib.box_apply
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(fun res -> Result res)
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(Expr.Box.lift new_scope_let_expr))
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scope_body_expr
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let closure_conversion (p : 'm program) : 'm program Bindlib.box =
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let _, new_code_items =
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Scope.fold_map
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~f:(fun toplevel_vars var code_item ->
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match code_item with
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| ScopeDef (name, body) ->
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let scope_input_var, scope_body_expr =
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Bindlib.unbind body.scope_body_expr
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in
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let ctx =
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{
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decl_ctx = p.decl_ctx;
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name_context = Mark.remove (ScopeName.get_info name);
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globally_bound_vars = toplevel_vars;
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}
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in
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let new_scope_lets =
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closure_conversion_scope_let ctx scope_body_expr
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in
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let new_scope_body_expr =
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Bindlib.bind_var scope_input_var new_scope_lets
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in
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( Var.Set.add var toplevel_vars,
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Bindlib.box_apply
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(fun scope_body_expr ->
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ScopeDef (name, { body with scope_body_expr }))
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new_scope_body_expr )
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| Topdef (name, ty, expr) ->
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let ctx =
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{
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decl_ctx = p.decl_ctx;
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name_context = Mark.remove (TopdefName.get_info name);
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globally_bound_vars = toplevel_vars;
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}
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in
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let _free_vars, new_expr = transform_closures_expr ctx expr in
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( Var.Set.add var toplevel_vars,
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Bindlib.box_apply
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(fun e -> Topdef (name, ty, e))
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(Expr.Box.lift new_expr) ))
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~varf:(fun v -> v)
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Var.Set.empty p.code_items
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in
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(* Now we need to further tweak [decl_ctx] because some of the user-defined
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types can have closures in them and these closured might have changed type.
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So we reset them to [TAny] in the hopes that the transformation applied
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will not yield to type unification conflicts. Indeed, consider the
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following closure: [let f = if ... then fun v -> x + v else fun v -> v]. To
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be typed correctly once converted, this closure needs an existential type
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but the Catala typechecker doesn't have them. However, this kind of type
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conflict is difficult to produce using the Catala surface language: it can
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only happen if you store a closure which is the output of a scope inside a
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user-defined data structure, and if you do it in two different places in
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the code with two closures that don't have the same capture footprint. *)
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let new_decl_ctx =
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let rec type_contains_arrow t =
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match Mark.remove t with
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| TArrow _ -> true
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| TAny -> true
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| TOption t' -> type_contains_arrow t'
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| TClosureEnv | TLit _ -> false
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| TArray ts -> type_contains_arrow ts
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| TTuple ts -> List.exists type_contains_arrow ts
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| TEnum e ->
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EnumConstructor.Map.exists
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(fun _ t' -> type_contains_arrow t')
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(EnumName.Map.find e p.decl_ctx.ctx_enums)
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| TStruct s ->
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StructField.Map.exists
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(fun _ t' -> type_contains_arrow t')
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(StructName.Map.find s p.decl_ctx.ctx_structs)
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in
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let replace_fun_typs t =
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if type_contains_arrow t then Mark.copy t TAny else t
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in
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{
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p.decl_ctx with
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ctx_structs =
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StructName.Map.map
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(StructField.Map.map replace_fun_typs)
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p.decl_ctx.ctx_structs;
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ctx_enums =
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EnumName.Map.map
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(EnumConstructor.Map.map replace_fun_typs)
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p.decl_ctx.ctx_enums;
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}
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in
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Bindlib.box_apply
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(fun new_code_items ->
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{ code_items = new_code_items; decl_ctx = new_decl_ctx })
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new_code_items
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