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293bcd3817
HandleExceptions only takes an array of exceptions, and returns Some if only one of them is Some, None if they are all None, or raises a conflict error otherwise. The compilation of default terms then wraps this in a match (for the result of HandleExceptions), and an if-then-else (for the justification-consequence in the None case). This avoids the complexity of having to handle thunked functions as arguments.
1455 lines
49 KiB
OCaml
1455 lines
49 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) 2023 Inria, contributor:
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Louis Gesbert <louis.gesbert@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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type flags = {
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with_conditions : bool;
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with_cleanup : bool;
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merge_level : int;
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format : [ `Dot | `Convert of string ];
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show : string option;
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output : Global.raw_file option;
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base_src_url : string;
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}
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(* -- Definition of the lazy interpreter -- *)
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let log fmt = Format.ifprintf Format.err_formatter (fmt ^^ "@\n")
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let error e = Message.error ~pos:(Expr.pos e)
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let noassert = true
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module Env = struct
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type t = Env of (expr, elt) Var.Map.t
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and elt = { base : expr * t; mutable reduced : expr * t }
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and expr = (dcalc, annot custom) gexpr
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and annot = { conditions : (expr * t) list }
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let find v (Env t) = Var.Map.find v t
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(* let get_bas v t = let v, env = find v t in v, !env *)
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let add v e e_env (Env t) =
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Env (Var.Map.add v { base = e, e_env; reduced = e, e_env } t)
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let empty = Env Var.Map.empty
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let join (Env t1) (Env t2) =
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Env
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(Var.Map.union
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(fun _ x1 x2 ->
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(* assert (x1 == x2); *)
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Some x2)
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t1 t2)
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let print ppf (Env t) =
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Format.pp_print_list ~pp_sep:Format.pp_print_space
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(fun ppf v -> Print.var_debug ppf v)
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ppf (Var.Map.keys t)
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end
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type expr = Env.expr
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type annot = Env.annot = { conditions : (expr * Env.t) list }
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type laziness_level = {
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eval_struct : bool;
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(* if true, evaluate members of structures, tuples, etc. *)
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eval_op : bool;
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(* if false, evaluate the operands but keep e.g. `3 + 4` as is *)
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eval_match : bool;
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eval_default : bool;
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(* if false, stop evaluating as soon as you can discriminate with
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`EEmptyError` *)
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eval_vars : expr Var.t -> bool;
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(* if false, variables are only resolved when they point to another
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unchanged variable *)
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}
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let value_level =
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{
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eval_struct = false;
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eval_op = true;
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eval_match = true;
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eval_default = true;
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eval_vars = (fun _ -> true);
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}
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let add_condition ~condition e =
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Mark.map_mark
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(fun (Custom { pos; custom = { conditions } }) ->
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Custom { pos; custom = { conditions = condition :: conditions } })
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e
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let add_conditions ~conditions e =
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Mark.map_mark
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(fun (Custom { pos; custom = { conditions = c } }) ->
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Custom { pos; custom = { conditions = conditions @ c } })
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e
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let neg_op = function
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| Op.Xor ->
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Some Op.Eq
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(* Alright, we are cheating here since the type is wider, but the
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transformation preserves the semantics *)
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| Op.Lt_int_int -> Some Op.Gte_int_int
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| Op.Lt_rat_rat -> Some Op.Gte_rat_rat
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| Op.Lt_mon_mon -> Some Op.Gte_mon_mon
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| Op.Lt_dat_dat -> Some Op.Gte_dat_dat
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| Op.Lt_dur_dur -> Some Op.Gte_dur_dur
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| Op.Lte_int_int -> Some Op.Gt_int_int
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| Op.Lte_rat_rat -> Some Op.Gt_rat_rat
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| Op.Lte_mon_mon -> Some Op.Gt_mon_mon
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| Op.Lte_dat_dat -> Some Op.Gt_dat_dat
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| Op.Lte_dur_dur -> Some Op.Gt_dur_dur
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| Op.Gt_int_int -> Some Op.Lte_int_int
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| Op.Gt_rat_rat -> Some Op.Lte_rat_rat
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| Op.Gt_mon_mon -> Some Op.Lte_mon_mon
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| Op.Gt_dat_dat -> Some Op.Lte_dat_dat
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| Op.Gt_dur_dur -> Some Op.Lte_dur_dur
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| Op.Gte_int_int -> Some Op.Lt_int_int
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| Op.Gte_rat_rat -> Some Op.Lt_rat_rat
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| Op.Gte_mon_mon -> Some Op.Lt_mon_mon
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| Op.Gte_dat_dat -> Some Op.Lt_dat_dat
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| Op.Gte_dur_dur -> Some Op.Lt_dur_dur
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| _ -> None
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let rec bool_negation pos e =
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match Expr.skip_wrappers e with
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| ELit (LBool true), m -> ELit (LBool false), m
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| ELit (LBool false), m -> ELit (LBool true), m
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| EAppOp { op = Op.Not, _; args = [(e, _)] }, m -> e, m
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| (EAppOp { op = op, opos; tys; args = [e1; e2] }, m) as e -> (
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match op with
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| Op.And ->
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( EAppOp
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{
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op = Op.Or, opos;
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tys;
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args = [bool_negation pos e1; bool_negation pos e2];
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},
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m )
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| Op.Or ->
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( EAppOp
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{
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op = Op.And, opos;
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tys;
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args = [bool_negation pos e1; bool_negation pos e2];
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},
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m )
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| op -> (
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match neg_op op with
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| Some op -> EAppOp { op = op, opos; tys; args = [e1; e2] }, m
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| None ->
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( EAppOp
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{
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op = Op.Not, opos;
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tys = [TLit TBool, Expr.mark_pos m];
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args = [e];
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},
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m )))
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| (_, m) as e ->
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( EAppOp
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{ op = Op.Not, pos; tys = [TLit TBool, Expr.mark_pos m]; args = [e] },
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m )
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let rec lazy_eval : decl_ctx -> Env.t -> laziness_level -> expr -> expr * Env.t
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=
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fun ctx env llevel e0 ->
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let eval_to_value ?(eval_default = true) env e =
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lazy_eval ctx env { value_level with eval_default } e
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in
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match e0 with
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| EVar v, _ ->
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if (not llevel.eval_default) || not (llevel.eval_vars v) then e0, env
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else
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(* Variables reducing to EEmpty should not propagate to parent EDefault
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(?) *)
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let env_elt =
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try Env.find v env
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with Var.Map.Not_found _ ->
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error e0 "Variable %a undefined [@[<hv>%a@]]" Print.var_debug v
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Env.print env
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in
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let e, env1 = env_elt.reduced in
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let r, env1 = lazy_eval ctx env1 llevel e in
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env_elt.reduced <- r, env1;
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r, Env.join env env1
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| EAppOp { op = op, opos; args; tys }, m -> (
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if
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(not llevel.eval_default)
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&& not (List.equal Expr.equal args [ELit LUnit, m])
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(* Applications to () encode thunked default terms *)
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then e0, env
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else
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match op with
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| (Op.Map | Op.Filter | Op.Reduce | Op.Fold | Op.Length) as op -> (
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(* when not llevel.eval_op *)
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(* Distribute collection operations to the terms rather than use their
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runtime implementations *)
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let arr = List.hd (List.rev args) in
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(* All these ops have the array as last arg *)
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let aty = List.hd (List.rev tys) in
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match eval_to_value env arr with
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| (EArray elts, _), env ->
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let eapp f e = EApp { f; args = [e]; tys = [] }, m in
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let empty_condition () =
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(* Is the expression [length(arr) = 0] *)
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let pos = Expr.mark_pos m in
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( EAppOp
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{
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op = Op.Eq_int_int, opos;
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tys = [TLit TInt, pos; TLit TInt, pos];
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args =
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[
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( EAppOp
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{ op = Op.Length, opos; tys = [aty]; args = [arr] },
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m );
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ELit (LInt (Runtime.integer_of_int 0)), m;
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];
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},
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m )
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in
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let e, env =
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match op, args, elts with
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| (Op.Map | Op.Filter), _, [] ->
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let e = EArray [], m in
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add_condition ~condition:(empty_condition (), env) e, env
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| (Op.Reduce | Op.Fold), [_; dft; _], [] ->
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add_condition ~condition:(empty_condition (), env) dft, env
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| Op.Map, [f; _], elts -> (EArray (List.map (eapp f) elts), m), env
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| Op.Filter, [f; _], elts ->
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let rev_elts, env =
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List.fold_left
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(fun (elts, env) e ->
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let cond = eapp f e in
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match lazy_eval ctx env value_level cond with
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| (ELit (LBool true), _), _ ->
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add_condition ~condition:(cond, env) e :: elts, env
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| (ELit (LBool false), _), _ -> elts, env
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| _ -> assert false)
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([], env) elts
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in
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(EArray (List.rev rev_elts), m), env
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(* Note: no annots for removed terms, even if the result is empty *)
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| Op.Reduce, [f; _; _], elt0 :: elts ->
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let e =
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List.fold_left
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(fun acc elt -> EApp { f; args = [acc; elt]; tys = [] }, m)
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elt0 elts
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in
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e, env
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| Op.Fold, [f; base; _], elts ->
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let e =
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List.fold_left
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(fun acc elt -> EApp { f; args = [acc; elt]; tys = [] }, m)
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base elts
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in
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e, env
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| Op.Length, [_], elts ->
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(ELit (LInt (Runtime.integer_of_int (List.length elts))), m), env
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| _ -> assert false
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in
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(* We did a transformation (removing the outer operator), but further
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evaluation may be needed to guarantee that [llevel] is reached *)
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lazy_eval ctx env { llevel with eval_match = true } e
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| _ -> (EAppOp { op = op, opos; args; tys }, m), env)
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| _ ->
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let env, args =
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List.fold_left_map
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(fun env e ->
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let e, env = lazy_eval ctx env llevel e in
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env, e)
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env args
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in
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if not llevel.eval_op then (EAppOp { op = op, opos; args; tys }, m), env
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else
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let renv = ref env in
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(* Dirty workaround returning env and conds from evaluate_operator *)
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let eval e =
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let e, env = lazy_eval ctx !renv llevel e in
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renv := env;
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e
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in
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let e =
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Interpreter.evaluate_operator eval (op, opos) m Global.En
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(* Default language to English but this should not raise any error
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messages so we don't care. *)
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args
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in
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e, !renv)
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(* fixme: this forwards eempty *)
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| EApp { f; args }, m -> (
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if
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(not llevel.eval_default)
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&& not (List.equal Expr.equal args [ELit LUnit, m])
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(* Applications to () encode thunked default terms *)
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then e0, env
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else
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match eval_to_value env f with
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| (EAbs { binder; _ }, _), env ->
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let vars, body = Bindlib.unmbind binder in
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log "@[<v 2>@[<hov 4>{";
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let env =
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Seq.fold_left2
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(fun env1 var e ->
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log "@[<hov 2>LET %a = %a@]@ " Print.var_debug var Expr.format e;
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Env.add var e env env1)
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env (Array.to_seq vars) (List.to_seq args)
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in
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log "@]@[<hov 4>IN [%a]@]" (Print.expr ~debug:true ()) body;
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let e, env = lazy_eval ctx env llevel body in
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log "@]}";
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e, env
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| e, _ -> error e "Invalid apply on %a" Expr.format e)
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| (EAbs _ | ELit _ | EEmpty), _ -> e0, env (* these are values *)
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| (EStruct _ | ETuple _ | EInj _ | EArray _), _ ->
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if not llevel.eval_struct then e0, env
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else
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let env, e =
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Expr.map_gather ~acc:env ~join:Env.join
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~f:(fun e ->
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let e, env = lazy_eval ctx env llevel e in
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env, Expr.box e)
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e0
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in
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Expr.unbox e, env
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| EStructAccess { e; name; field }, _ -> (
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if not llevel.eval_default then e0, env
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else
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match eval_to_value env e with
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| (EStruct { name = n; fields }, _), env when StructName.equal name n ->
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let e, env =
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lazy_eval ctx env llevel (StructField.Map.find field fields)
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in
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e, env
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| _ -> e0, env)
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| ETupleAccess { e; index; size }, _ -> (
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if not llevel.eval_default then e0, env
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||
else
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match eval_to_value env e with
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||
| (ETuple es, _), env when List.length es = size ->
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lazy_eval ctx env llevel (List.nth es index)
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| e, _ -> error e "Invalid tuple access on %a" Expr.format e)
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| EMatch { e; name; cases }, _ -> (
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if not llevel.eval_match then e0, env
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else
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match eval_to_value env e with
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| (EInj { name = n; cons; e = e1 }, m), env when EnumName.equal name n ->
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let condition = e, env in
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(* FIXME: condition should be "e TEST_MATCH n" but we don't have a
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concise expression to express that *)
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let e1, env =
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lazy_eval ctx env llevel
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( EApp
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{
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f = EnumConstructor.Map.find cons cases;
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args = [e1];
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tys = [];
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},
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m )
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in
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add_condition ~condition e1, env
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| e, _ -> error e "Invalid match argument %a" Expr.format e)
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| EDefault { excepts; just; cons }, m -> (
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let excs =
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List.filter_map
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||
(fun e ->
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match eval_to_value env e ~eval_default:false with
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| (EEmpty, _), _ -> None
|
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| e -> Some e)
|
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excepts
|
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in
|
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match excs with
|
||
| [] -> (
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match eval_to_value env just with
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||
| (ELit (LBool true), _), _ ->
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let condition = just, env in
|
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let e, env = lazy_eval ctx env llevel cons in
|
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add_condition ~condition e, env
|
||
| (ELit (LBool false), _), _ -> (EEmpty, m), env
|
||
(* Note: conditions for empty are skipped *)
|
||
| e, _ -> error e "Invalid exception justification %a" Expr.format e)
|
||
| [(e, env)] ->
|
||
log "@[<hov 5>EVAL %a@]" Expr.format e;
|
||
lazy_eval ctx env llevel e
|
||
| _ :: _ :: _ ->
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||
Message.error ~pos:(Expr.mark_pos m)
|
||
~extra_pos:(List.map (fun (e, _) -> "", Expr.pos e) excs)
|
||
"Conflicting exceptions")
|
||
| EPureDefault e, _ -> lazy_eval ctx env llevel e
|
||
| EIfThenElse { cond; etrue; efalse }, m -> (
|
||
match eval_to_value env cond with
|
||
| (ELit (LBool true), _), _ ->
|
||
let condition = cond, env in
|
||
let e, env = lazy_eval ctx env llevel etrue in
|
||
add_condition ~condition e, env
|
||
| (ELit (LBool false), m), _ -> (
|
||
let condition = bool_negation (Expr.mark_pos m) cond, env in
|
||
let e, env = lazy_eval ctx env llevel efalse in
|
||
match efalse with
|
||
(* The negated condition is not added for nested [else if] to reduce
|
||
verbosity *)
|
||
| EIfThenElse _, _ -> e, env
|
||
| _ -> add_condition ~condition e, env)
|
||
| e, _ -> error e "Invalid condition %a" Expr.format e)
|
||
| EErrorOnEmpty e, _ -> (
|
||
match eval_to_value env e ~eval_default:false with
|
||
| ((EEmpty, _) as e'), _ ->
|
||
(* This does _not_ match the eager semantics ! *)
|
||
error e' "This value is undefined %a" Expr.format e
|
||
| e, env -> lazy_eval ctx env llevel e)
|
||
| EAssert e, m -> (
|
||
if noassert then (ELit LUnit, m), env
|
||
else
|
||
match eval_to_value env e with
|
||
| (ELit (LBool true), m), env -> (ELit LUnit, m), env
|
||
| (ELit (LBool false), _), _ ->
|
||
error e "Assert failure (%a)" Expr.format e error e
|
||
"Assert failure (%a)" Expr.format e
|
||
| _ -> error e "Invalid assertion condition %a" Expr.format e)
|
||
| EFatalError err, _ ->
|
||
error e0 "%a" Format.pp_print_text (Runtime.error_message err)
|
||
| EExternal _, _ -> assert false (* todo *)
|
||
| _ -> .
|
||
|
||
let result_level base_vars =
|
||
{
|
||
value_level with
|
||
eval_struct = true;
|
||
eval_op = false;
|
||
eval_vars = (fun v -> not (Var.Set.mem v base_vars));
|
||
}
|
||
|
||
let interpret_program (prg : ('dcalc, 'm) gexpr program) (scope : ScopeName.t) :
|
||
('t, 'm) gexpr * Env.t =
|
||
let ctx = prg.decl_ctx in
|
||
let (all_env, scopes), () =
|
||
BoundList.fold_left prg.code_items ~init:(Env.empty, ScopeName.Map.empty)
|
||
~f:(fun (env, scopes) item v ->
|
||
match item with
|
||
| ScopeDef (name, body) ->
|
||
let e = Scope.to_expr ctx body in
|
||
let e = Expr.remove_logging_calls (Expr.unbox e) in
|
||
( Env.add v (Expr.unbox e) env env,
|
||
ScopeName.Map.add name (v, body.scope_body_input_struct) scopes )
|
||
| Topdef (_, _, e) -> Env.add v e env env, scopes)
|
||
in
|
||
let scope_v, _scope_arg_struct = ScopeName.Map.find scope scopes in
|
||
let e, env = (Env.find scope_v all_env).base in
|
||
log "=====================";
|
||
log "%a" (Print.expr ~debug:true ()) e;
|
||
log "=====================";
|
||
(* let m = Mark.get e in *)
|
||
(* let application_arg =
|
||
* Expr.estruct scope_arg_struct
|
||
* (StructField.Map.map
|
||
* (function
|
||
* | TArrow (ty_in, ty_out), _ ->
|
||
* Expr.make_abs
|
||
* [| Var.make "_" |]
|
||
* (Bindlib.box EEmptyError, Expr.with_ty m ty_out)
|
||
* ty_in (Expr.mark_pos m)
|
||
* | ty -> Expr.evar (Var.make "undefined_input") (Expr.with_ty m ty))
|
||
* (StructName.Map.find scope_arg_struct ctx.ctx_structs))
|
||
* m
|
||
* in *)
|
||
match e with
|
||
| EAbs { binder; _ }, _ ->
|
||
let _vars, e = Bindlib.unmbind binder in
|
||
let rec get_vars base_vars env = function
|
||
| EApp { f = EAbs { binder; _ }, _; args = [arg] }, _ ->
|
||
let vars, e = Bindlib.unmbind binder in
|
||
let var = vars.(0) in
|
||
let base_vars =
|
||
match Expr.skip_wrappers arg with
|
||
| ELit _, _ -> Var.Set.add var base_vars
|
||
| _ -> base_vars
|
||
in
|
||
let env = Env.add var arg env env in
|
||
get_vars base_vars env e
|
||
| e -> base_vars, env, e
|
||
in
|
||
let base_vars, env, e = get_vars Var.Set.empty env e in
|
||
lazy_eval ctx env (result_level base_vars) e
|
||
| _ -> assert false
|
||
|
||
let print_value_with_env ctx ppf env expr =
|
||
let already_printed = ref Var.Set.empty in
|
||
let rec aux env ppf expr =
|
||
Print.expr ~debug:true () ppf expr;
|
||
Format.pp_print_cut ppf ();
|
||
let vars = Var.Set.diff (Expr.free_vars expr) !already_printed in
|
||
Var.Set.iter
|
||
(fun v ->
|
||
let e, env = (Env.find v env).reduced in
|
||
let e, env = lazy_eval ctx env (result_level Var.Set.empty) e in
|
||
Format.fprintf ppf "@[<hov 2>%a %a =@ %a =@ %a@]@,@," Print.punctuation
|
||
"»" Print.var_debug v Expr.format
|
||
(fst (lazy_eval ctx env value_level e))
|
||
(aux env) e)
|
||
vars;
|
||
already_printed := Var.Set.union !already_printed vars;
|
||
Format.pp_print_cut ppf ()
|
||
in
|
||
Format.pp_open_vbox ppf 2;
|
||
aux env ppf expr;
|
||
Format.pp_close_box ppf ()
|
||
|
||
module V = struct
|
||
type t = expr
|
||
|
||
let compare a b = Expr.compare a b
|
||
|
||
let hash = function
|
||
| EVar v, _ -> Var.hash v
|
||
| EAbs { tys; _ }, _ -> Hashtbl.hash tys
|
||
| e, _ -> Hashtbl.hash e
|
||
|
||
let equal a b = Expr.equal a b
|
||
let format = Expr.format
|
||
end
|
||
|
||
module E = struct
|
||
type hand_side = Lhs of string | Rhs of string
|
||
type t = { side : hand_side option; condition : bool }
|
||
|
||
let compare x y =
|
||
match Bool.compare x.condition y.condition with
|
||
| 0 ->
|
||
Option.compare
|
||
(fun x y ->
|
||
match x, y with
|
||
| Lhs s, Lhs t | Rhs s, Rhs t -> String.compare s t
|
||
| Lhs _, Rhs _ -> -1
|
||
| Rhs _, Lhs _ -> 1)
|
||
x.side y.side
|
||
| n -> n
|
||
|
||
let default = { side = None; condition = false }
|
||
end
|
||
|
||
module G = Graph.Persistent.Digraph.AbstractLabeled (V) (E)
|
||
|
||
let op_kind = function
|
||
| Op.Add_int_int | Add_rat_rat | Add_mon_mon | Add_dat_dur _ | Add_dur_dur
|
||
| Sub_int_int | Sub_rat_rat | Sub_mon_mon | Sub_dat_dat | Sub_dat_dur
|
||
| Sub_dur_dur ->
|
||
`Sum
|
||
| Mult_int_int | Mult_rat_rat | Mult_mon_rat | Mult_dur_int | Div_int_int
|
||
| Div_rat_rat | Div_mon_rat | Div_mon_mon | Div_dur_dur ->
|
||
`Product
|
||
| Round_mon | Round_rat -> `Round
|
||
| Map | Filter | Reduce | Fold -> `Fct
|
||
| _ -> `Other
|
||
|
||
module GTopo = Graph.Topological.Make (G)
|
||
|
||
let to_graph ctx env expr =
|
||
let rec aux env g e =
|
||
(* lazy_eval ctx env (result_level base_vars) e *)
|
||
match Expr.skip_wrappers e with
|
||
| ( EAppOp { op = (ToRat_int | ToRat_mon | ToMoney_rat), _; args = [arg]; _ },
|
||
_ ) ->
|
||
aux env g arg
|
||
(* we skip conversions *)
|
||
| ELit l, _ ->
|
||
let v = G.V.create e in
|
||
G.add_vertex g v, v
|
||
| (EVar var, _) as e ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let child, env = (Env.find var env).base in
|
||
let g, child_v = aux env g child in
|
||
G.add_edge g v child_v, v
|
||
| EAppOp { op = _; args; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let g, children = List.fold_left_map (aux env) g args in
|
||
List.fold_left (fun g -> G.add_edge g v) g children, v
|
||
| EInj { e; _ }, _ -> aux env g e
|
||
| EStruct { fields; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let args = StructField.Map.values fields in
|
||
let g, children = List.fold_left_map (aux env) g args in
|
||
List.fold_left (fun g -> G.add_edge g v) g children, v
|
||
| _ ->
|
||
Format.eprintf "%a" Expr.format e;
|
||
assert false
|
||
in
|
||
let base_g, _ = aux env G.empty expr in
|
||
base_g
|
||
|
||
let rec is_const e =
|
||
match Expr.skip_wrappers e with
|
||
| ELit _, _ -> true
|
||
| EInj { e; _ }, _ -> is_const e
|
||
| EStruct { fields; _ }, _ ->
|
||
StructField.Map.for_all (fun _ e -> is_const e) fields
|
||
| EArray el, _ -> List.for_all is_const el
|
||
| _ -> false
|
||
|
||
let program_to_graph
|
||
options
|
||
(prg : (dcalc, 'm) gexpr program)
|
||
(scope : ScopeName.t) : G.t * expr Var.Set.t * Env.t =
|
||
let ctx = prg.decl_ctx in
|
||
let customize =
|
||
Expr.map_marks ~f:(fun m ->
|
||
Custom { pos = Expr.mark_pos m; custom = { conditions = [] } })
|
||
in
|
||
let (all_env, scopes), () =
|
||
BoundList.fold_left prg.code_items ~init:(Env.empty, ScopeName.Map.empty)
|
||
~f:(fun (env, scopes) item v ->
|
||
match item with
|
||
| ScopeDef (name, body) ->
|
||
let e = Scope.to_expr ctx body in
|
||
let e = customize (Expr.unbox e) in
|
||
let e = Expr.remove_logging_calls (Expr.unbox e) in
|
||
let e = Expr.rename_vars (Expr.unbox e) in
|
||
( Env.add (Var.translate v) (Expr.unbox e) env env,
|
||
ScopeName.Map.add name (v, body.scope_body_input_struct) scopes )
|
||
| Topdef (_, _, e) ->
|
||
Env.add (Var.translate v) (Expr.unbox (customize e)) env env, scopes)
|
||
in
|
||
let scope_v, _scope_arg_struct = ScopeName.Map.find scope scopes in
|
||
let e, env = (Env.find (Var.translate scope_v) all_env).base in
|
||
let e =
|
||
match e with
|
||
| EAbs { binder; _ }, _ ->
|
||
let _vars, e = Bindlib.unmbind binder in
|
||
e
|
||
| _ -> assert false
|
||
in
|
||
let rec get_vars base_vars env = function
|
||
| EApp { f = EAbs { binder; _ }, _; args = [arg] }, _ ->
|
||
let vars, e = Bindlib.unmbind binder in
|
||
let var = vars.(0) in
|
||
let base_vars =
|
||
if is_const arg then Var.Set.add var base_vars else base_vars
|
||
in
|
||
let env = Env.add var arg env env in
|
||
get_vars base_vars env e
|
||
| e -> base_vars, env, e
|
||
in
|
||
let base_vars, env, e = get_vars Var.Set.empty env e in
|
||
let e1, env = lazy_eval ctx env (result_level base_vars) e in
|
||
let level =
|
||
{
|
||
value_level with
|
||
eval_struct = false;
|
||
eval_op = false;
|
||
eval_match = false;
|
||
eval_vars = (fun v -> false);
|
||
}
|
||
in
|
||
let rec aux parent (g, var_vertices, env0) e =
|
||
let e, env0 = lazy_eval ctx env0 level e in
|
||
let m = Mark.get e in
|
||
let (Custom { custom = { conditions; _ }; _ }) = m in
|
||
let g, var_vertices, env0 =
|
||
(* add conditions *)
|
||
if not options.with_conditions then g, var_vertices, env0
|
||
else
|
||
match parent with
|
||
| None -> g, var_vertices, env0
|
||
| Some parent ->
|
||
List.fold_left
|
||
(fun (g, var_vertices, env0) (econd, env) ->
|
||
let (g, var_vertices, env), vcond =
|
||
aux (Some parent) (g, var_vertices, env) econd
|
||
in
|
||
( G.add_edge_e g
|
||
(G.E.create parent { side = None; condition = true } vcond),
|
||
var_vertices,
|
||
Env.join env0 env ))
|
||
(g, var_vertices, env0) conditions
|
||
in
|
||
let e = Mark.set m (Expr.skip_wrappers e) in
|
||
match e with
|
||
| ( EAppOp
|
||
{ op = (ToRat_int | ToRat_mon | ToMoney_rat), _; args = [arg]; tys },
|
||
_ ) ->
|
||
aux parent (g, var_vertices, env0) (Mark.set m arg)
|
||
(* we skip conversions *)
|
||
| ELit l, _ ->
|
||
let v = G.V.create e in
|
||
(G.add_vertex g v, var_vertices, env0), v
|
||
| EVar var, _ -> (
|
||
try (g, var_vertices, env0), Var.Map.find var var_vertices
|
||
with Var.Map.Not_found _ -> (
|
||
try
|
||
let child, env = (Env.find var env0).base in
|
||
let m = Mark.get child in
|
||
let v = G.V.create (Mark.set m e) in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), child_v =
|
||
aux (Some v) (g, var_vertices, Env.join env0 env) child
|
||
in
|
||
let var_vertices =
|
||
(* Duplicates non-base constant var nodes *)
|
||
if Var.Set.mem var base_vars then var_vertices
|
||
else
|
||
let rec is_lit v =
|
||
match G.V.label v with
|
||
| ELit _, _ -> true
|
||
| EVar var, _ when not (Var.Set.mem var base_vars) -> (
|
||
match G.succ g v with [v] -> is_lit v | _ -> false)
|
||
| _ -> false
|
||
in
|
||
if is_lit child_v then var_vertices
|
||
(* This duplicates constant var nodes *)
|
||
else Var.Map.add var v var_vertices
|
||
in
|
||
(G.add_edge g v child_v, var_vertices, env), v
|
||
with Var.Map.Not_found _ ->
|
||
Message.warning "VAR NOT FOUND: %a" Print.var var;
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
(g, var_vertices, env), v))
|
||
| EAppOp { op = (Map | Filter | Reduce | Fold), _; args = _ :: args; _ }, _
|
||
->
|
||
(* First argument (which is a function) is ignored *)
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), children =
|
||
List.fold_left_map (aux (Some v)) (g, var_vertices, env0) args
|
||
in
|
||
( (List.fold_left (fun g -> G.add_edge g v) g children, var_vertices, env),
|
||
v )
|
||
| EAppOp { op = op, _; args = [lhs; rhs]; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), lhs =
|
||
aux (Some v) (g, var_vertices, env0) lhs
|
||
in
|
||
let (g, var_vertices, env), rhs =
|
||
aux (Some v) (g, var_vertices, env) rhs
|
||
in
|
||
let lhs_label, rhs_label =
|
||
match op with
|
||
| Add_int_int | Add_rat_rat | Add_mon_mon | Add_dat_dur _ | Add_dur_dur
|
||
->
|
||
Some (E.Lhs "⊕"), Some (E.Rhs "⊕")
|
||
| Sub_int_int | Sub_rat_rat | Sub_mon_mon | Sub_dat_dat | Sub_dat_dur
|
||
| Sub_dur_dur ->
|
||
Some (E.Lhs "⊕"), Some (E.Rhs "⊖")
|
||
| Mult_int_int | Mult_rat_rat | Mult_mon_rat | Mult_dur_int ->
|
||
Some (E.Lhs "⊗"), Some (E.Rhs "⊗")
|
||
| Div_int_int | Div_rat_rat | Div_mon_rat | Div_mon_mon | Div_dur_dur ->
|
||
Some (E.Lhs "⊗"), Some (E.Rhs "⊘")
|
||
| _ -> None, None
|
||
in
|
||
let g =
|
||
G.add_edge_e g
|
||
(G.E.create v { side = lhs_label; condition = false } lhs)
|
||
in
|
||
let g =
|
||
G.add_edge_e g
|
||
(G.E.create v { side = rhs_label; condition = false } rhs)
|
||
in
|
||
(g, var_vertices, env), v
|
||
| EAppOp { op = _; args; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), children =
|
||
List.fold_left_map (aux (Some v)) (g, var_vertices, env0) args
|
||
in
|
||
( (List.fold_left (fun g -> G.add_edge g v) g children, var_vertices, env),
|
||
v )
|
||
| EInj { e; _ }, _ -> aux parent (g, var_vertices, env0) e
|
||
| EStruct { fields; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let args = StructField.Map.values fields in
|
||
let (g, var_vertices, env), children =
|
||
List.fold_left_map (aux (Some v)) (g, var_vertices, env0) args
|
||
in
|
||
( (List.fold_left (fun g -> G.add_edge g v) g children, var_vertices, env),
|
||
v )
|
||
| EArray elts, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), children =
|
||
List.fold_left_map (aux (Some v)) (g, var_vertices, env0) elts
|
||
in
|
||
( (List.fold_left (fun g -> G.add_edge g v) g children, var_vertices, env),
|
||
v )
|
||
| EAbs _, _ ->
|
||
(g, var_vertices, env), G.V.create e (* (testing -> ignored) *)
|
||
| EMatch { name; e; cases }, _ -> aux parent (g, var_vertices, env0) e
|
||
| EStructAccess { e; field; _ }, _ ->
|
||
let v = G.V.create e in
|
||
let g = G.add_vertex g v in
|
||
let (g, var_vertices, env), child =
|
||
aux (Some v) (g, var_vertices, env0) e
|
||
in
|
||
(G.add_edge g v child, var_vertices, env), v
|
||
| _ ->
|
||
Format.eprintf "%a" Expr.format e;
|
||
assert false
|
||
in
|
||
let (g, vmap, env), _ = aux None (G.empty, Var.Map.empty, env) e in
|
||
log "BASE: @[<v>%a@]"
|
||
(Format.pp_print_list Print.var)
|
||
(Var.Set.elements base_vars);
|
||
g, base_vars, env
|
||
|
||
let reverse_graph g =
|
||
G.fold_edges_e
|
||
(fun e g ->
|
||
G.add_edge_e (G.remove_edge_e g e)
|
||
(G.E.create (G.E.dst e) (G.E.label e) (G.E.src e)))
|
||
g g
|
||
|
||
let subst_by v1 e2 e =
|
||
let rec f = function
|
||
| EVar v, m when Var.equal v v1 -> Expr.box e2
|
||
| e -> Expr.map ~f ~op:Fun.id e
|
||
in
|
||
Expr.unbox (f e)
|
||
|
||
let map_vertices f g =
|
||
G.fold_vertex
|
||
(fun v g ->
|
||
let v' = G.V.create (f v) in
|
||
let g =
|
||
G.fold_pred_e
|
||
(fun e g -> G.add_edge_e g (G.E.create (G.E.src e) (G.E.label e) v'))
|
||
g v g
|
||
in
|
||
let g =
|
||
G.fold_succ_e
|
||
(fun e g -> G.add_edge_e g (G.E.create v' (G.E.label e) (G.E.dst e)))
|
||
g v g
|
||
in
|
||
G.remove_vertex g v)
|
||
g g
|
||
|
||
let rec graph_cleanup options g base_vars =
|
||
(* let _g =
|
||
* let module GCtr = Graph.Contraction.Make (G) in
|
||
* GCtr.contract
|
||
* (fun e ->
|
||
* G.E.label e = None
|
||
* &&
|
||
* match G.V.label (G.E.src e), G.V.label (G.E.dst e) with
|
||
* | (EVar _, _), (EVar _, _) -> true
|
||
* | ( (EApp { f = EOp { op = op1; _ }, _; args = [_; _] }, _),
|
||
* (EApp { f = EOp { op = op2; _ }, _; args = [_; _] }, _) ) -> (
|
||
* match op_kind op1, op_kind op2 with
|
||
* | `Sum, `Sum -> true
|
||
* | `Prod, `Prod -> true
|
||
* | _ -> false)
|
||
* | _ -> false)
|
||
* g
|
||
* in *)
|
||
let module GTop = Graph.Topological.Make (G) in
|
||
let module VMap = Map.Make (struct
|
||
include G.V
|
||
|
||
let format ppf v = V.format ppf (G.V.label v)
|
||
end) in
|
||
let g, vmap =
|
||
(* Remove separate nodes for variable literal values *)
|
||
G.fold_vertex
|
||
(fun v (g, vmap) ->
|
||
match G.V.label v with
|
||
(* | (ELit _, _), [EVar _, _] -> G.remove_vertex g v *)
|
||
| ELit _, m ->
|
||
( G.remove_vertex g v,
|
||
(* Forward position of the deleted literal to its parent *)
|
||
List.fold_left
|
||
(fun vmap v ->
|
||
let out =
|
||
G.succ_e g v
|
||
|> List.filter (fun e -> not (G.E.label e).condition)
|
||
in
|
||
match out with [_] -> VMap.add v m vmap | _ -> vmap)
|
||
vmap (G.pred g v) )
|
||
| _, _ -> g, vmap)
|
||
g (g, VMap.empty)
|
||
in
|
||
let g =
|
||
map_vertices
|
||
(fun v ->
|
||
match VMap.find_opt v vmap with
|
||
| Some m -> Mark.set m (G.V.label v)
|
||
| None -> G.V.label v)
|
||
g
|
||
in
|
||
let g =
|
||
(* Merge intermediate operations *)
|
||
let g = reverse_graph g in
|
||
GTop.fold (* Variables -> result order *)
|
||
(fun v g ->
|
||
let succ = G.succ g v in
|
||
match G.V.label v, succ, List.map G.V.label succ with
|
||
| (EAppOp _, _), [v2], [(EAppOp _, _)] ->
|
||
let g =
|
||
List.fold_left
|
||
(fun g e ->
|
||
G.add_edge_e g (G.E.create (G.E.src e) (G.E.label e) v2))
|
||
g (G.pred_e g v)
|
||
in
|
||
G.remove_vertex g v
|
||
| _ -> g)
|
||
g g
|
||
|> reverse_graph
|
||
in
|
||
let g, substs =
|
||
(* Remove intermediate variables *)
|
||
GTop.fold (* Result -> variables order *)
|
||
(fun v (g, substs) ->
|
||
let succ_e = G.succ_e g v in
|
||
if List.exists (fun ed -> (G.E.label ed).condition) succ_e then
|
||
g, substs
|
||
else
|
||
let succ = List.map G.E.dst succ_e in
|
||
match G.V.label v, succ, List.map G.V.label succ with
|
||
| (EVar var1, m1), [v2], [(EVar var2, m2)]
|
||
when not (Var.Set.mem var1 base_vars) ->
|
||
let g =
|
||
List.fold_left
|
||
(fun g e ->
|
||
G.add_edge_e g (G.E.create (G.E.src e) (G.E.label e) v2))
|
||
g (G.pred_e g v)
|
||
in
|
||
( G.remove_vertex g v,
|
||
fun e -> subst_by var1 (EVar var2, m2) (substs e) )
|
||
| (EVar var1, m1), [v2], [((EApp _, _) as e2)]
|
||
when not (Var.Set.mem var1 base_vars) -> (
|
||
let pred_e = G.pred_e g v in
|
||
match pred_e, List.map (fun e -> G.V.label (G.E.src e)) pred_e with
|
||
| [pred_e], [(EApp _, _)]
|
||
when G.E.src pred_e |> G.out_degree g <= options.merge_level ->
|
||
(* Arbitrary heuristics: don't merge if the child node already has
|
||
> level parents *)
|
||
let g =
|
||
G.add_edge_e g
|
||
(G.E.create (G.E.src pred_e) (G.E.label pred_e) v2)
|
||
in
|
||
G.remove_vertex g v, fun e -> subst_by var1 e2 (substs e)
|
||
| _ -> g, substs)
|
||
| _ -> g, substs)
|
||
g (g, G.V.label)
|
||
in
|
||
let g = map_vertices substs g in
|
||
let g =
|
||
(* Merge intermediate operations (again) *)
|
||
let g = reverse_graph g in
|
||
GTop.fold (* Variables -> result order *)
|
||
(fun v g ->
|
||
let succ = G.succ g v in
|
||
match G.V.label v, succ, List.map G.V.label succ with
|
||
| (EAppOp _, _), [v2], [(EAppOp _, _)] ->
|
||
let g =
|
||
List.fold_left
|
||
(fun g e ->
|
||
G.add_edge_e g (G.E.create (G.E.src e) (G.E.label e) v2))
|
||
g (G.pred_e g v)
|
||
in
|
||
G.remove_vertex g v
|
||
| _ -> g)
|
||
g g
|
||
|> reverse_graph
|
||
in
|
||
let g =
|
||
let module EMap = Map.Make (struct
|
||
type t = expr
|
||
|
||
let compare = Expr.compare
|
||
let format = Expr.format
|
||
end) in
|
||
(* Merge duplicate nodes *)
|
||
let emap =
|
||
G.fold_vertex
|
||
(fun v expr_map ->
|
||
let e = G.V.label v in
|
||
EMap.update e
|
||
(function None -> Some [v] | Some l -> Some (v :: l))
|
||
expr_map)
|
||
g EMap.empty
|
||
in
|
||
EMap.fold
|
||
(fun expr vs g ->
|
||
match vs with
|
||
| [] | [_] -> g
|
||
| v0 :: vn ->
|
||
let e_in =
|
||
List.map (G.pred_e g) vs
|
||
|> List.flatten
|
||
|> List.map (fun e -> G.E.create (G.E.src e) (G.E.label e) v0)
|
||
|> List.sort_uniq G.E.compare
|
||
in
|
||
let e_out =
|
||
List.map (G.succ_e g) vs
|
||
|> List.flatten
|
||
|> List.map (fun e -> G.E.create v0 (G.E.label e) (G.E.dst e))
|
||
|> List.sort_uniq G.E.compare
|
||
in
|
||
let g = List.fold_left G.remove_vertex g vn in
|
||
let g = List.fold_left G.remove_edge_e g (G.succ_e g v0) in
|
||
let g = List.fold_left G.remove_edge_e g (G.pred_e g v0) in
|
||
let g = List.fold_left G.add_edge_e g e_in in
|
||
let g = List.fold_left G.add_edge_e g e_out in
|
||
g)
|
||
emap g
|
||
in
|
||
g
|
||
|
||
let expr_to_dot_label0 :
|
||
type a.
|
||
Global.backend_lang ->
|
||
decl_ctx ->
|
||
Env.t ->
|
||
Format.formatter ->
|
||
(a, 't) gexpr ->
|
||
unit =
|
||
fun lang ctx env ->
|
||
let xlang ~en ?(pl = en) ~fr () =
|
||
match lang with Global.Fr -> fr | Global.En -> en | Global.Pl -> pl
|
||
in
|
||
let rec aux_value : type a t. Format.formatter -> (a, t) gexpr -> unit =
|
||
fun ppf e -> Print.UserFacing.value ~fallback lang ppf e
|
||
and fallback : type a t. Format.formatter -> (a, t) gexpr -> unit =
|
||
fun ppf e ->
|
||
let module E = Print.ExprGen (struct
|
||
let var ppf v = String.format ppf (Bindlib.name_of v)
|
||
let lit = Print.UserFacing.lit lang
|
||
|
||
let operator : type x. Format.formatter -> x operator -> unit =
|
||
fun ppf o ->
|
||
let open Op in
|
||
let str =
|
||
match o with
|
||
| Eq_int_int | Eq_rat_rat | Eq_mon_mon | Eq_dur_dur | Eq_dat_dat | Eq
|
||
->
|
||
"="
|
||
| Minus_int | Minus_rat | Minus_mon | Minus_dur | Minus -> "-"
|
||
| ToRat_int | ToRat_mon | ToRat -> ""
|
||
| ToMoney_rat | ToMoney -> ""
|
||
| Add_int_int | Add_rat_rat | Add_mon_mon | Add_dat_dur _
|
||
| Add_dur_dur | Add ->
|
||
"+"
|
||
| Sub_int_int | Sub_rat_rat | Sub_mon_mon | Sub_dat_dat | Sub_dat_dur
|
||
| Sub_dur_dur | Sub ->
|
||
"-"
|
||
| Mult_int_int | Mult_rat_rat | Mult_mon_rat | Mult_dur_int | Mult ->
|
||
"×"
|
||
| Div_int_int | Div_rat_rat | Div_mon_mon | Div_mon_rat | Div_dur_dur
|
||
| Div ->
|
||
"/"
|
||
| Lt_int_int | Lt_rat_rat | Lt_mon_mon | Lt_dur_dur | Lt_dat_dat | Lt
|
||
->
|
||
"<"
|
||
| Lte_int_int | Lte_rat_rat | Lte_mon_mon | Lte_dur_dur | Lte_dat_dat
|
||
| Lte ->
|
||
"<="
|
||
| Gt_int_int | Gt_rat_rat | Gt_mon_mon | Gt_dur_dur | Gt_dat_dat | Gt
|
||
->
|
||
">"
|
||
| Gte_int_int | Gte_rat_rat | Gte_mon_mon | Gte_dur_dur | Gte_dat_dat
|
||
| Gte ->
|
||
">="
|
||
| Concat -> "++"
|
||
| Not -> xlang () ~en:"not" ~fr:"non"
|
||
| Length -> xlang () ~en:"length" ~fr:"nombre"
|
||
| GetDay -> xlang () ~en:"day_of_month" ~fr:"jour_du_mois"
|
||
| GetMonth -> xlang () ~en:"month" ~fr:"mois"
|
||
| GetYear -> xlang () ~en:"year" ~fr:"année"
|
||
| FirstDayOfMonth ->
|
||
xlang () ~en:"first_day_of_month" ~fr:"premier_jour_du_mois"
|
||
| LastDayOfMonth ->
|
||
xlang () ~en:"last_day_of_month" ~fr:"dernier_jour_du_mois"
|
||
| Round_rat | Round_mon | Round -> xlang () ~en:"round" ~fr:"arrondi"
|
||
| Log _ -> xlang () ~en:"Log" ~fr:"Journal"
|
||
| And -> xlang () ~en:"and" ~fr:"et"
|
||
| Or -> xlang () ~en:"or" ~fr:"ou"
|
||
| Xor -> xlang () ~en:"xor" ~fr:"ou bien"
|
||
| Map -> xlang () ~en:"on_every" ~fr:"pour_chaque"
|
||
| Map2 -> xlang () ~en:"on_every_2" ~fr:"pour_chaque_2"
|
||
| Reduce -> xlang () ~en:"reduce" ~fr:"réunion"
|
||
| Filter -> xlang () ~en:"filter" ~fr:"filtre"
|
||
| Fold -> xlang () ~en:"fold" ~fr:"pliage"
|
||
| HandleExceptions -> ""
|
||
| ToClosureEnv -> ""
|
||
| FromClosureEnv -> ""
|
||
in
|
||
Format.pp_print_string ppf str
|
||
|
||
let pre_map = Expr.skip_wrappers
|
||
|
||
let bypass : type a t. Format.formatter -> (a, t) gexpr -> bool =
|
||
fun ppf e ->
|
||
match Mark.remove e with
|
||
| ELit _ | EArray _ | ETuple _ | EStruct _ | EInj _ | EEmpty | EAbs _
|
||
| EExternal _ ->
|
||
aux_value ppf e;
|
||
true
|
||
| EMatch { e; cases; _ } ->
|
||
let cases =
|
||
List.map
|
||
(function
|
||
| cons, (EAbs { binder; _ }, _) ->
|
||
cons, snd (Bindlib.unmbind binder)
|
||
| cons, e -> cons, e)
|
||
(EnumConstructor.Map.bindings cases)
|
||
in
|
||
if
|
||
List.for_all
|
||
(function _, (ELit (LBool _), _) -> true | _ -> false)
|
||
cases
|
||
then (
|
||
let cases =
|
||
List.filter_map
|
||
(function c, (ELit (LBool true), _) -> Some c | _ -> None)
|
||
cases
|
||
in
|
||
Format.fprintf ppf "%a @<1>%s @[<hov>%a@]" aux_value e "≅"
|
||
(Format.pp_print_list
|
||
~pp_sep:(fun ppf () ->
|
||
Format.fprintf ppf " %t@ " (fun ppf -> operator ppf Or))
|
||
EnumConstructor.format)
|
||
cases;
|
||
true)
|
||
else false
|
||
| _ -> false
|
||
end) in
|
||
E.expr ppf e
|
||
in
|
||
aux_value
|
||
|
||
let rec expr_to_dot_label lang ctx env ppf e =
|
||
let print_expr = expr_to_dot_label lang ctx env in
|
||
let e = Expr.skip_wrappers e in
|
||
match e with
|
||
| EVar v, _ ->
|
||
let e, _ = lazy_eval ctx env value_level e in
|
||
Format.fprintf ppf "%a = %a" String.format (Bindlib.name_of v)
|
||
(expr_to_dot_label0 lang ctx env)
|
||
e
|
||
| EStruct { name; fields }, _ ->
|
||
let pr ppf =
|
||
Format.fprintf ppf "{ %a | { { %a } | { %a }}}" StructName.format name
|
||
(Format.pp_print_list
|
||
~pp_sep:(fun ppf () -> Format.pp_print_string ppf " | ")
|
||
(fun ppf fld ->
|
||
StructField.format ppf fld;
|
||
Format.pp_print_string ppf "\\l"))
|
||
(StructField.Map.keys fields)
|
||
(Format.pp_print_list
|
||
~pp_sep:(fun ppf () -> Format.pp_print_string ppf " | ")
|
||
(fun ppf -> function
|
||
| ((EVar _ | ELit _ | EInj { e = (EVar _ | ELit _), _; _ }), _) as
|
||
e ->
|
||
print_expr ppf e;
|
||
Format.pp_print_string ppf "\\l"
|
||
| _ -> Format.pp_print_string ppf "…\\l"))
|
||
(StructField.Map.values fields)
|
||
in
|
||
Format.pp_print_string ppf (Message.unformat pr)
|
||
| EArray elts, _ ->
|
||
let pr ppf =
|
||
Format.fprintf ppf "{ %a }"
|
||
(Format.pp_print_list
|
||
~pp_sep:(fun ppf () -> Format.pp_print_string ppf " | ")
|
||
(fun ppf -> function
|
||
| ((EVar _ | ELit _), _) as e -> print_expr ppf e
|
||
| _ -> Format.pp_print_string ppf "…"))
|
||
elts
|
||
in
|
||
Format.pp_print_string ppf (Message.unformat pr)
|
||
| e -> Format.fprintf ppf "%a@," (expr_to_dot_label0 lang ctx env) e
|
||
|
||
let to_dot lang ppf ctx env base_vars g ~base_src_url =
|
||
let module GPr = Graph.Graphviz.Dot (struct
|
||
include G
|
||
|
||
let print_expr env ctx lang ppf e =
|
||
let out_funs = Format.pp_get_formatter_out_functions ppf () in
|
||
Format.pp_set_formatter_out_functions ppf
|
||
{
|
||
out_funs with
|
||
Format.out_newline = (fun () -> out_funs.out_string "\\l" 0 2);
|
||
};
|
||
expr_to_dot_label env ctx lang ppf e;
|
||
Format.pp_print_flush ppf ();
|
||
Format.pp_set_formatter_out_functions ppf out_funs
|
||
|
||
let graph_attributes _ = [ (* `Rankdir `LeftToRight *) ]
|
||
let default_vertex_attributes _ = []
|
||
|
||
let vertex_label v =
|
||
let print_expr = print_expr lang ctx env in
|
||
match G.V.label v with
|
||
| (EVar v, _) as e ->
|
||
Format.asprintf "%a = %a" String.format (Bindlib.name_of v) print_expr
|
||
(fst (lazy_eval ctx env value_level e))
|
||
| e -> Format.asprintf "%a" print_expr e
|
||
|
||
let vertex_name v = Printf.sprintf "x%03d" (G.V.hash v)
|
||
|
||
let vertex_attributes v =
|
||
let e = V.label v in
|
||
let pos = Expr.pos e in
|
||
let loc_text =
|
||
Re.replace_string
|
||
Re.(compile (char '\n'))
|
||
~by:" "
|
||
(String.concat "\n» " (List.rev (Pos.get_law_info pos)) ^ "\n")
|
||
in
|
||
`Label (vertex_label v (* ^ "\n" ^ loc_text *))
|
||
:: `Comment loc_text
|
||
(* :: `Url
|
||
* ("http://localhost:8080/fr/examples/housing-benefits#"
|
||
* ^ Re.(
|
||
* replace_string
|
||
* (compile
|
||
* (seq [char '/'; rep1 (diff any (char '/')); str "/../"]))
|
||
* ~by:"/" (Pos.get_file pos))
|
||
* ^ "-"
|
||
* ^ string_of_int (Pos.get_start_line pos)) *)
|
||
:: `Url
|
||
(base_src_url
|
||
^ "/"
|
||
^ Pos.get_file pos
|
||
^ "#L"
|
||
^ string_of_int (Pos.get_start_line pos))
|
||
:: `Fontname "DejaVu Sans Mono"
|
||
::
|
||
(match G.V.label v with
|
||
| EVar var, _ ->
|
||
if Var.Set.mem var base_vars then
|
||
[`Style `Filled; `Fillcolor 0xffaa55; `Shape `Box]
|
||
else if
|
||
List.exists (fun e -> not (G.E.label e).condition) (G.succ_e g v)
|
||
then
|
||
(* non-constants *)
|
||
[`Style `Filled; `Fillcolor 0xffee99; `Shape `Box]
|
||
else (* Constants *)
|
||
[`Style `Filled; `Fillcolor 0x77aaff; `Shape `Note]
|
||
| EStruct _, _ | EArray _, _ -> [`Shape `Record]
|
||
| EAppOp { op = op, _; _ }, _ -> (
|
||
match op_kind op with
|
||
| `Sum | `Product | _ -> [`Shape `Box] (* | _ -> [] *))
|
||
| _ -> [])
|
||
|
||
let get_subgraph v =
|
||
match G.V.label v with
|
||
| EVar var, _ -> (
|
||
if Var.Set.mem var base_vars then
|
||
Some
|
||
{
|
||
Graph.Graphviz.DotAttributes.sg_name = "inputs";
|
||
sg_attributes = [];
|
||
sg_parent = None;
|
||
}
|
||
else
|
||
match List.map G.V.label (G.succ g v) with
|
||
(* | [] | [ELit _, _] ->
|
||
* Some
|
||
* {
|
||
* Graph.Graphviz.DotAttributes.sg_name = "constants";
|
||
* sg_attributes = [`Shape `Box];
|
||
* sg_parent = None;
|
||
* } *)
|
||
| _ -> None)
|
||
| _ -> None
|
||
|
||
let default_edge_attributes _ = []
|
||
|
||
let edge_attributes e =
|
||
match E.label e with
|
||
| { condition = true; _ } ->
|
||
[`Style `Dashed; `Penwidth 5.; `Color 0xff7700; `Arrowhead `Odot]
|
||
| { side = Some (Lhs s | Rhs s); _ } ->
|
||
[ (* `Label s; `Color 0xbb7700 *) ]
|
||
| _ -> []
|
||
end) in
|
||
GPr.fprint_graph ppf (reverse_graph g)
|
||
|
||
(* -- Plugin registration -- *)
|
||
|
||
let options =
|
||
let open Cmdliner in
|
||
let conditions =
|
||
Arg.(
|
||
value
|
||
& flag
|
||
& info ["conditions"]
|
||
~doc:
|
||
"Include boolean conditions used to choose the specific formula \
|
||
nodes (with dashed lines) in the resulting graph. Without this, \
|
||
only the nodes contributing to the actual calculation are shown.")
|
||
in
|
||
let no_cleanup =
|
||
Arg.(
|
||
value
|
||
& flag
|
||
& info ["no-cleanup"]
|
||
~doc:
|
||
"Disable automatic cleanup of intermediate computation nodes. Very \
|
||
verbose but sometimes useful for debugging.")
|
||
in
|
||
let merge_level =
|
||
Arg.(
|
||
value
|
||
& opt int 2
|
||
& info ["merge-level"]
|
||
~doc:
|
||
"Determines an internal threshold to the heuristics for merging \
|
||
intermediate nodes with as many parents. Higher means more \
|
||
aggressive merges.")
|
||
in
|
||
let format =
|
||
let mkinfo s =
|
||
( `Convert s,
|
||
Arg.info [s]
|
||
~doc:
|
||
(Printf.sprintf
|
||
"Outputs a compiled $(b,.%s) file instead of a $(b,.dot) file \
|
||
(requires $(i,graphviz) to be installed)."
|
||
s) )
|
||
in
|
||
Arg.(
|
||
value
|
||
& vflag `Dot
|
||
[
|
||
( `Dot,
|
||
info ["dot"]
|
||
~doc:"Output the graph in dot format (this is the default)" );
|
||
mkinfo "svg";
|
||
mkinfo "png";
|
||
mkinfo "pdf";
|
||
])
|
||
in
|
||
let show =
|
||
Arg.(
|
||
value
|
||
& opt ~vopt:(Some "xdot") (some string) None
|
||
& info ["show"]
|
||
~doc:"Opens the resulting graph in the given command immediately.")
|
||
in
|
||
let base_src_url =
|
||
Arg.(
|
||
value
|
||
& opt string "https://github.com/CatalaLang/catala/blob/master"
|
||
& info ["url-base"] ~docv:"URL"
|
||
~doc:
|
||
"Base URL that can be used to browse the Catala code. Nodes will \
|
||
link to $(i,URL)/relative/filename.catala_xx#LNN where NN is the \
|
||
line number in the file")
|
||
in
|
||
let f with_conditions no_cleanup merge_level format show output base_src_url =
|
||
{
|
||
with_conditions;
|
||
with_cleanup = not no_cleanup;
|
||
merge_level;
|
||
format;
|
||
show;
|
||
output;
|
||
base_src_url;
|
||
}
|
||
in
|
||
Term.(
|
||
const f
|
||
$ conditions
|
||
$ no_cleanup
|
||
$ merge_level
|
||
$ format
|
||
$ show
|
||
$ Cli.Flags.output
|
||
$ base_src_url)
|
||
|
||
let run includes optimize ex_scope explain_options global_options =
|
||
let prg, _ =
|
||
Driver.Passes.dcalc global_options ~includes ~optimize
|
||
~check_invariants:false ~typed:Expr.typed
|
||
in
|
||
Interpreter.load_runtime_modules prg
|
||
~hashf:(Hash.finalise ~closure_conversion:false ~monomorphize_types:false);
|
||
let scope = Driver.Commands.get_scope_uid prg.decl_ctx ex_scope in
|
||
(* let result_expr, env = interpret_program prg scope in *)
|
||
let g, base_vars, env = program_to_graph explain_options prg scope in
|
||
log "Base variables detected: @[<hov>%a@]"
|
||
(Format.pp_print_list Print.var)
|
||
(Var.Set.elements base_vars);
|
||
let g =
|
||
if explain_options.with_cleanup then
|
||
graph_cleanup explain_options g base_vars
|
||
else g
|
||
in
|
||
let lang =
|
||
Cli.file_lang (Global.input_src_file global_options.Global.input_src)
|
||
in
|
||
let dot_content =
|
||
to_dot lang Format.str_formatter prg.decl_ctx env base_vars g
|
||
~base_src_url:explain_options.base_src_url;
|
||
Format.flush_str_formatter ()
|
||
|> Re.(replace_string (compile (seq [bow; str "comment="])) ~by:"tooltip=")
|
||
in
|
||
let with_dot_file =
|
||
match explain_options with
|
||
| { format = `Convert _; _ } | { show = Some _; output = None; _ } ->
|
||
File.with_temp_file "catala-explain" "dot" ~contents:dot_content
|
||
| { output; _ } ->
|
||
let _, with_out = Driver.Commands.get_output global_options output in
|
||
with_out (fun oc -> output_string oc dot_content);
|
||
fun f ->
|
||
f
|
||
(Option.value ~default:"-"
|
||
(Option.map Global.options.path_rewrite output))
|
||
in
|
||
with_dot_file
|
||
@@ fun dotfile ->
|
||
(match explain_options.format with
|
||
| `Convert fmt ->
|
||
let _, with_out =
|
||
Driver.Commands.get_output global_options explain_options.output
|
||
in
|
||
with_out (fun oc ->
|
||
output_string oc (File.process_out "dot" ["-T" ^ fmt; dotfile]))
|
||
| `Dot -> ());
|
||
match explain_options.show with
|
||
| None -> ()
|
||
| Some cmd ->
|
||
raise (Cli.Exit_with (Sys.command (cmd ^ " " ^ Filename.quote dotfile)))
|
||
|
||
let term =
|
||
let open Cmdliner.Term in
|
||
const run
|
||
$ Cli.Flags.include_dirs
|
||
$ Cli.Flags.optimize
|
||
$ Cli.Flags.ex_scope
|
||
$ options
|
||
|
||
let () =
|
||
Driver.Plugin.register "explain" term
|
||
~doc:
|
||
"Generates a graph of the formulas that are used for a given execution \
|
||
of a scope"
|
||
~man:
|
||
[
|
||
`P
|
||
"This command requires a given scope with no inputs (i.e. a test \
|
||
scope). A partial/lazy evaluation will recursively take place to \
|
||
explain intermediate formulas that take place in the computation, \
|
||
from the inputs (specified in the test scope) to the final outputs. \
|
||
The output is a graph, in .dot format (graphviz) by default (see \
|
||
$(b,--svg) and $(b,--show) for other options)";
|
||
]
|