mlw_wp.ml 42.7 KB
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(**************************************************************************)
(*                                                                        *)
(*  Copyright (C) 2010-2012                                               *)
(*    François Bobot                                                      *)
(*    Jean-Christophe Filliâtre                                           *)
(*    Claude Marché                                                       *)
(*    Guillaume Melquiond                                                 *)
(*    Andrei Paskevich                                                    *)
(*                                                                        *)
(*  This software is free software; you can redistribute it and/or        *)
(*  modify it under the terms of the GNU Library General Public           *)
(*  License version 2.1, with the special exception on linking            *)
(*  described in file LICENSE.                                            *)
(*                                                                        *)
(*  This software is distributed in the hope that it will be useful,      *)
(*  but WITHOUT ANY WARRANTY; without even the implied warranty of        *)
(*  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.                  *)
(*                                                                        *)
(**************************************************************************)

open Why3
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open Util
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open Ident
open Ty
open Term
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open Decl
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open Theory
open Mlw_ty
open Mlw_ty.T
open Mlw_expr

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let debug = Debug.register_info_flag "whyml_wp"
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  ~desc:"Print@ details@ of@ verification@ conditions@ generation."
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let no_track = Debug.register_flag "wp_no_track"
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  ~desc:"Do@ not@ remove@ redundant@ type@ invariant@ conditions@ from@ VCs."

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let no_eval = Debug.register_flag "wp_no_eval"
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  ~desc:"Do@ not@ simplify@ pattern@ matching@ on@ record@ datatypes@ in@ VCs."
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(** Marks *)
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let ts_mark = create_tysymbol (id_fresh "'mark") [] None
let ty_mark = ty_app ts_mark []

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let vtv_mark = vty_value (ity_pur ts_mark [])

let fresh_mark () = create_vsymbol (id_fresh "'mark") ty_mark
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let fs_at =
  let ty = ty_var (create_tvsymbol (id_fresh "a")) in
  create_lsymbol (id_fresh "at") [ty; ty_mark] (Some ty)

let fs_old =
  let ty = ty_var (create_tvsymbol (id_fresh "a")) in
  create_lsymbol (id_fresh "old") [ty] (Some ty)

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let th_mark_at =
  let uc = create_theory (id_fresh "WP builtins: at") in
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  let uc = add_ty_decl uc ts_mark in
  let uc = add_param_decl uc fs_at in
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  close_theory uc

let th_mark_old =
  let uc = create_theory (id_fresh "WP builtins: old") in
  let uc = use_export uc th_mark_at in
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  let uc = add_param_decl uc fs_old in
  close_theory uc

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let fs_now = create_lsymbol (id_fresh "%now") [] (Some ty_mark)
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let t_now = fs_app fs_now [] ty_mark
let e_now = e_lapp fs_now [] (ity_pur ts_mark [])
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(* [vs_old] appears in the postconditions given to the core API,
   which expects every vsymbol to be a pure part of a pvsymbol *)
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let pv_old = create_pvsymbol (id_fresh "%old") vtv_mark
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let vs_old = pv_old.pv_vs
let t_old  = t_var vs_old
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let t_at_old t = t_app fs_at [t; t_old] t.t_ty

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let ls_absurd = create_lsymbol (id_fresh "absurd") [] None
let t_absurd  = ps_app ls_absurd []
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let mk_t_if f = t_if f t_bool_true t_bool_false
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let to_term t = if t.t_ty = None then mk_t_if t else t
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(* any vs in post/xpost is either a pvsymbol or a fresh mark *)
let vtv_of_vs vs =
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  try (restore_pv vs).pv_vtv with Not_found -> vtv_mark
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(* replace every occurrence of [old(t)] with [at(t,'old)] *)
let rec remove_old f = match f.t_node with
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  | Tapp (ls,[t]) when ls_equal ls fs_old -> t_at_old (remove_old t)
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  | _ -> t_map remove_old f

(* replace every occurrence of [at(t,'now)] with [t] *)
let rec remove_at f = match f.t_node with
  | Tapp (ls, [t; { t_node = Tapp (fs,[]) }])
    when ls_equal ls fs_at && ls_equal fs fs_now -> remove_at t
  | _ -> t_map remove_at f

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(* replace [at(t,'old)] with [at(t,lab)] everywhere in formula [f] *)
let old_mark lab t = t_subst_single vs_old (t_var lab) t

(* replace [at(t,lab)] with [at(t,'now)] everywhere in formula [f] *)
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let erase_mark lab t = t_subst_single lab t_now t

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(* retreat to the point of the current postcondition's ['old] *)
let backstep fn q xq =
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  let lab = fresh_mark () in
  let f = fn (old_mark lab q) (Mexn.map (old_mark lab) xq) in
  erase_mark lab f
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(** WP utilities *)
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let fs_void = fs_tuple 0
let t_void = fs_app fs_void [] ty_unit

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let default_exn_post xs _ =
  let vs = create_vsymbol (id_fresh "result") (ty_of_ity xs.xs_ity) in
  create_post vs t_true

let default_post vty ef =
  let vs = create_vsymbol (id_fresh "result") (ty_of_vty vty) in
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  create_post vs t_true, Mexn.mapi default_exn_post ef.eff_raises
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let wp_label e f =
  let loc = if f.t_loc = None then e.e_loc else f.t_loc in
  let lab = Ident.Slab.union e.e_label f.t_label in
  t_label ?loc lab f

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let expl_pre       = Ident.create_label "expl:precondition"
let expl_post      = Ident.create_label "expl:normal postcondition"
let expl_xpost     = Ident.create_label "expl:exceptional postcondition"
let expl_assert    = Ident.create_label "expl:assertion"
let expl_check     = Ident.create_label "expl:check"
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let expl_inv       = Ident.create_label "expl:type invariant"
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let expl_variant   = Ident.create_label "expl:variant decreases"
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let expl_loop_init = Ident.create_label "expl:loop invariant init"
let expl_loop_keep = Ident.create_label "expl:loop invariant preservation"
let expl_loop_var  = Ident.create_label "expl:loop variant decreases"
(* FIXME? couldn't we just reuse "loop invariant" explanations? *)
let expl_for_init  = Ident.create_label "expl:for loop initialization"
let expl_for_keep  = Ident.create_label "expl:for loop preservation"
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let wp_expl l f =
  let lab = Slab.add Split_goal.stop_split f.t_label in
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  t_label ?loc:f.t_loc (Slab.add l lab) f
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let wp_and ~sym f1 f2 =
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  if sym then t_and_simp f1 f2 else t_and_asym_simp f1 f2

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let wp_ands ~sym fl =
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  if sym then t_and_simp_l fl else t_and_asym_simp_l fl

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let wp_implies f1 f2 = t_implies_simp f1 f2
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let wp_let v t f = t_let_close_simp v t f

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let wp_forall vl f = t_forall_close_simp vl [] f

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let wp_forall_post v p f =
  (* we optimize for the case when a postcondition
     is of the form (... /\ result = t /\ ...) *)
  let rec down p = match p.t_node with
    | Tbinop (Tand,l,r) ->
        begin match down l with
          | None, _ ->
              let t, r = down r in
              t, t_label_copy p (t_and_simp l r)
          | t, l ->
              t, t_label_copy p (t_and_simp l r)
        end
    | Tapp (ps,[{t_node = Tvar u};t])
      when ls_equal ps ps_equ && vs_equal u v && not (Mvs.mem v t.t_vars) ->
        Some t, t_true
    | _ ->
        None, p
  in
  if ty_equal v.vs_ty ty_unit then
    t_subst_single v t_void (wp_implies p f)
  else match down p with
    | Some t, p -> wp_let v t (wp_implies p f)
    | _ -> wp_forall [v] (wp_implies p f)
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(* regs_of_reads, and therefore regs_of_effect, only take into account
   reads in program expressions and ignore the variables in specification *)
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let regs_of_reads  eff = Sreg.union eff.eff_reads eff.eff_ghostr
let regs_of_writes eff = Sreg.union eff.eff_writes eff.eff_ghostw
let regs_of_effect eff = Sreg.union (regs_of_reads eff) (regs_of_writes eff)
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let exns_of_raises eff = Sexn.union eff.eff_raises eff.eff_ghostx
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let open_post q =
  let v, f = open_post q in
  v, t_label_copy q f

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let open_unit_post q =
  let v, q = open_post q in
  t_subst_single v t_void q

let create_unit_post =
  let v = create_vsymbol (id_fresh "void") ty_unit in
  fun q -> create_post v q

let vs_result e =
  create_vsymbol (id_fresh ?loc:e.e_loc "result") (ty_of_vty e.e_vty)

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(** WP state *)

type wp_env = {
  prog_known : Mlw_decl.known_map;
  pure_known : Decl.known_map;
  global_env : Env.env;
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  ps_int_le  : Term.lsymbol;
  ps_int_ge  : Term.lsymbol;
  ps_int_lt  : Term.lsymbol;
  ps_int_gt  : Term.lsymbol;
  fs_int_pl  : Term.lsymbol;
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  letrec_var : term list Mint.t;
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}
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let decrease_alg ?loc env old_t t =
  let oty = t_type old_t in
  let nty = t_type t in
  let quit () =
    Loc.errorm ?loc "no default order for %a" Pretty.print_term t in
  let ts = match oty with { ty_node = Tyapp (ts,_) } -> ts | _ -> quit () in
  let csl = Decl.find_constructors env.pure_known ts in
  if csl = [] then quit ();
  let sbs = ty_match Mtv.empty (ty_app ts (List.map ty_var ts.ts_args)) oty in
  let add_arg acc fty =
    let fty = ty_inst sbs fty in
    if ty_equal fty nty then
      let vs = create_vsymbol (id_fresh "f") nty in
      t_or_simp acc (t_equ (t_var vs) t), pat_var vs
    else acc, pat_wild fty in
  let add_cs (cs,_) =
    let f, pl = Util.map_fold_left add_arg t_false cs.ls_args in
    t_close_branch (pat_app cs pl oty) f in
  t_case old_t (List.map add_cs csl)

let decrease_rel ?loc env old_t t = function
  | Some ls -> ps_app ls [t; old_t]
  | None when ty_equal (t_type t) ty_int ->
      t_and
        (ps_app env.ps_int_le [t_int_const "0"; old_t])
        (ps_app env.ps_int_lt [t; old_t])
  | None -> decrease_alg ?loc env old_t t

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let decrease ?loc env olds varl =
  let rec decr pr olds varl = match olds, varl with
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    | [], [] -> (* empty variant *)
        t_true
    | [old_t], [t, rel] ->
        t_and_simp pr (decrease_rel ?loc env old_t t rel)
    | old_t::_, (t,_)::_ when not (oty_equal old_t.t_ty t.t_ty) ->
        Loc.errorm ?loc "cannot use lexicographic ordering"
    | old_t::olds, (t,rel)::varl ->
        let dt = t_and_simp pr (decrease_rel ?loc env old_t t rel) in
        let pr = t_and_simp pr (t_equ old_t t) in
        t_or_simp dt (decr pr olds varl)
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    | _ -> assert false
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  in
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  decr t_true olds varl
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(** Reconstruct pure values after writes *)

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let find_constructors lkm km sts ity = match ity.ity_node with
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  | Itypur (ts,_) ->
      let base = ity_pur ts (List.map ity_var ts.ts_args) in
      let sbs = ity_match ity_subst_empty base ity in
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      let csl = Decl.find_constructors lkm ts in
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      if csl = [] || Sts.mem ts sts then Loc.errorm
        "Cannot update values of type %a" Mlw_pretty.print_ity base;
      let subst ty = ity_full_inst sbs (ity_of_ty ty), None in
      let cnstr (cs,_) = cs, List.map subst cs.ls_args in
      Sts.add ts sts, List.map cnstr csl
  | Ityapp (its,_,_) ->
      let base = ity_app its (List.map ity_var its.its_args) its.its_regs in
      let sbs = ity_match ity_subst_empty base ity in
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      let csl = Mlw_decl.find_constructors km its in
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      if csl = [] || Sts.mem its.its_pure sts then Loc.errorm
        "Cannot update values of type %a" Mlw_pretty.print_ity base;
      let subst vtv =
        ity_full_inst sbs vtv.vtv_ity,
        Util.option_map (reg_full_inst sbs) vtv.vtv_mut in
      let cnstr (cs,_) = cs.pl_ls, List.map subst cs.pl_args in
      Sts.add its.its_pure sts, List.map cnstr csl
  | Ityvar _ -> assert false

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let analyze_var fn_down fn_join lkm km sts vs ity =
  let sts, csl = find_constructors lkm km sts ity in
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  let branch (cs,ityl) =
    let mk_var (ity,_) = create_vsymbol (id_fresh "y") (ty_of_ity ity) in
    let vars = List.map mk_var ityl in
    let mk_arg vs (ity, mut) = fn_down sts vs ity mut in
    let t = fn_join cs (List.map2 mk_arg vars ityl) vs.vs_ty in
    let pat = pat_app cs (List.map pat_var vars) vs.vs_ty in
    t_close_branch pat t in
  t_case (t_var vs) (List.map branch csl)

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let update_var env mreg vs =
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  let rec update sts vs ity mut =
    (* are we a mutable variable? *)
    let get_vs r = Mreg.find_def vs r mreg in
    let vs = Util.option_apply vs get_vs mut in
    (* should we update our value further? *)
    let check_reg r _ = reg_occurs r ity.ity_vars in
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    if ity_pure ity || not (Mreg.exists check_reg mreg) then t_var vs
    else analyze_var update fs_app env.pure_known env.prog_known sts vs ity
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  in
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  let vtv = vtv_of_vs vs in
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  update Sts.empty vs vtv.vtv_ity vtv.vtv_mut

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(* substitute the updated values in the "contemporary" variables *)
let rec subst_at_now now m t = match t.t_node with
  | Tvar vs when now ->
      begin try t_var (Mvs.find vs m) with Not_found -> t end
  | Tapp (ls, _) when ls_equal ls fs_old -> assert false
  | Tapp (ls, [_; mark]) when ls_equal ls fs_at ->
      let now = match mark.t_node with
        | Tvar vs when vs_equal vs vs_old -> assert false
        | Tapp (ls,[]) when ls_equal ls fs_now -> true
        | _ -> false in
      t_map (subst_at_now now m) t
  | Tlet _ | Tcase _ | Teps _ | Tquant _ ->
      (* do not open unless necessary *)
      let m = Mvs.set_inter m t.t_vars in
      if Mvs.is_empty m then t else
      t_map (subst_at_now now m) t
  | _ ->
      t_map (subst_at_now now m) t

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(* quantify over all references in eff
   eff : effect
   f   : formula

   let eff = { rho1, ..., rhon }
   we collect in vars all variables involving these regions
   let vars = { v1, ..., vm }

     forall r1:ty(rho1). ... forall rn:ty(rhon).
     let v'1 = update v1 r1...rn in
     ...
     let v'm = update vm r1...rn in
     f[vi <- v'i]
*)

let model1_lab = Slab.singleton (create_label "model:1")
let model2_lab = Slab.singleton (create_label "model:quantify(2)")
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let model3_lab = Slab.singleton (create_label "model:cond")

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let mk_var id label ty = create_vsymbol (id_clone ~label id) ty

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let quantify env regs f =
  (* mreg : updated region -> vs *)
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  let get_var reg () =
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    let test vs _ id = match vtv_of_vs vs with
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      | { vtv_ity = { ity_node = Ityapp (_,_,[r]) }}
      | { vtv_mut = Some r } when reg_equal r reg -> vs.vs_name
      | _ -> id in
    let id = Mvs.fold test f.t_vars reg.reg_name in
    mk_var id model1_lab (ty_of_ity reg.reg_ity)
  in
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  let mreg = Mreg.mapi get_var regs in
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  (* update all program variables involving these regions *)
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  let update_var vs _ = match update_var env mreg vs with
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    | { t_node = Tvar nv } when vs_equal vs nv -> None
    | t -> Some t in
  let vars = Mvs.mapi_filter update_var f.t_vars in
  (* vv' : old vs -> new vs *)
  let new_var vs _ = mk_var vs.vs_name model2_lab vs.vs_ty in
  let vv' = Mvs.mapi new_var vars in
  (* quantify *)
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  let update v t f = wp_let (Mvs.find v vv') t f in
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  let f = Mvs.fold update vars (subst_at_now true vv' f) in
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  wp_forall (List.rev (Mreg.values mreg)) f
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(** Invariants *)

let get_invariant km t =
  let ty = t_type t in
  let ts = match ty.ty_node with
    | Tyapp (ts,_) -> ts
    | _ -> assert false in
  let rec find_td = function
    | (its,_,inv) :: _ when ts_equal ts its.its_pure -> inv
    | _ :: tdl -> find_td tdl
    | [] -> assert false in
  let pd = Mid.find ts.ts_name km in
  let inv = match pd.Mlw_decl.pd_node with
    | Mlw_decl.PDdata tdl -> find_td tdl
    | _ -> assert false in
  let sbs = Ty.ty_match Mtv.empty (t_type inv) ty in
  let u, p = open_post (t_ty_subst sbs Mvs.empty inv) in
  wp_expl expl_inv (t_subst_single u t p)

let ps_inv = Term.create_psymbol (id_fresh "inv")
  [ty_var (create_tvsymbol (id_fresh "a"))]

let full_invariant lkm km vs ity =
  let rec update sts vs ity _ =
    if not (ity_inv ity) then t_true else
    (* what is our current invariant? *)
    let f = match ity.ity_node with
      | Ityapp (its,_,_) when its.its_inv ->
          if Debug.test_flag no_track
          then get_invariant km (t_var vs)
          else ps_app ps_inv [t_var vs]
      | _ -> t_true in
    (* what are our sub-invariants? *)
    let join _ fl _ = wp_ands ~sym:true fl in
    let g = analyze_var update join lkm km sts vs ity in
    (* put everything together *)
    wp_and ~sym:true f g
  in
  update Sts.empty vs ity None

(** Value tracking *)
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type point = int
type value = point list Mls.t (* constructor -> field list *)
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type state = {
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  st_km   : Mlw_decl.known_map;
  st_lkm  : Decl.known_map;
  st_mem  : (point, value) Hashtbl.t;
  st_next : point ref;
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}

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type names = point Mvs.t  (* variable -> point *)
type condition = lsymbol Mint.t (* point -> constructor *)
type lesson = condition list Mint.t (* point -> conditions for invariant *)

let empty_state lkm km = {
  st_km   = km;
  st_lkm  = lkm;
  st_mem  = Hashtbl.create 5;
  st_next = ref 0;
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}

let next_point state =
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  let res = !(state.st_next) in incr state.st_next; res
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let make_value state ty =
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  let get_p _ = next_point state in
  let new_cs cs = List.map get_p cs.ls_args in
  let add_cs m (cs,_) = Mls.add cs (new_cs cs) m in
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  let csl = match ty.ty_node with
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    | Tyapp (ts,_) -> Decl.find_constructors state.st_lkm ts
    | _ -> [] in
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  List.fold_left add_cs Mls.empty csl

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let match_point state ty p =
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  try Hashtbl.find state.st_mem p with Not_found ->
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  let value = make_value state ty in
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  if not (Mls.is_empty value) then
    Hashtbl.replace state.st_mem p value;
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  value

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let rec open_pattern state names value p pat = match pat.pat_node with
  | Pwild -> names
  | Pvar vs -> Mvs.add vs p names
  | Papp (cs,patl) ->
      let add_pat names p pat =
        let value = match_point state pat.pat_ty p in
        open_pattern state names value p pat in
      List.fold_left2 add_pat names (Mls.find cs value) patl
  | Por _ ->
      let add_vs vs s = Mvs.add vs (next_point state) s in
      Svs.fold add_vs pat.pat_vars names
  | Pas (pat,vs) ->
      open_pattern state (Mvs.add vs p names) value p pat

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let rec point_of_term state names t = match t.t_node with
  | Tvar vs ->
      Mvs.find vs names
  | Tapp (ls, tl) ->
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      begin match Mid.find ls.ls_name state.st_lkm with
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        | { Decl.d_node = Decl.Ddata tdl } ->
            let is_cs (cs,_) = ls_equal ls cs in
            let is_cs (_,csl) = List.exists is_cs csl in
            if List.exists is_cs tdl
            then point_of_constructor state names ls tl
            else point_of_projection state names ls (List.hd tl)
        | _ -> next_point state
      end
  | Tlet (t1, bt) ->
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      let p1 = point_of_term state names t1 in
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      let v, t2 = t_open_bound bt in
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      let names = Mvs.add v p1 names in
      point_of_term state names t2
  | Tcase (t1,[br]) ->
      let pat, t2 = t_open_branch br in
      let p1 = point_of_term state names t1 in
      let value = match_point state pat.pat_ty p1 in
      let names = open_pattern state names value p1 pat in
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      point_of_term state names t2
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  | Tcase (t1,bl) ->
      (* we treat here the case of a value update: the value
         of each branch must be a distinct constructor *)
      let p = next_point state in
      let ty = of_option t.t_ty in
      let p1 = point_of_term state names t1 in
      let value = match_point state (of_option t1.t_ty) p1 in
      let branch acc br =
        let pat, t2 = t_open_branch br in
        let ls = match t2.t_node with
          | Tapp (ls,_) -> ls | _ -> raise Exit in
        let names = open_pattern state names value p1 pat in
        let p2 = point_of_term state names t2 in
        let v2 = match_point state ty p2 in
        Mls.add_new Exit ls (Mls.find_exn Exit ls v2) acc
      in
      begin try
        let value = List.fold_left branch Mls.empty bl in
        let value = Mls.set_union value (make_value state ty) in
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        Hashtbl.replace state.st_mem p value
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      with Exit -> () end;
      p
  | Tconst _ | Tif _ | Teps _ -> next_point state
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  | Tquant _ | Tbinop _ | Tnot _ | Ttrue | Tfalse -> assert false

and point_of_constructor state names ls tl =
  let p = next_point state in
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  let pl = List.map (point_of_term state names) tl in
  let value = make_value state (of_option ls.ls_value) in
  let value = Mls.add ls pl value in
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  Hashtbl.replace state.st_mem p value;
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  p

and point_of_projection state names ls t1 =
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  let ty = of_option t1.t_ty in
  let csl = match ty.ty_node with
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    | Tyapp (ts,_) -> Decl.find_constructors state.st_lkm ts
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    | _ -> assert false in
  match csl with
    | [cs,pjl] ->
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        let p1 = point_of_term state names t1 in
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        let value = match_point state ty p1 in
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        let rec find_p pjl pl = match pjl, pl with
          | Some pj::_, p::_ when ls_equal ls pj -> p
          | _::pjl, _::pl -> find_p pjl pl
          | _ -> assert false in
        find_p pjl (Mls.find cs value)
    | _ -> next_point state (* more than one, can't choose *)

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let rec track_values state names lesson cond f = match f.t_node with
  | Tapp (ls, [t1]) when ls_equal ls ps_inv ->
      let p1 = point_of_term state names t1 in
      let condl = Mint.find_def [] p1 lesson in
      let contains c1 c2 = Mint.submap (fun _ -> ls_equal) c2 c1 in
      if List.exists (contains cond) condl then
        lesson, t_true
      else
        let good c = not (contains c cond) in
        let condl = List.filter good condl in
        let l = Mint.add p1 (cond::condl) lesson in
        l, get_invariant state.st_km t1
  | Tbinop (Timplies, f1, f2) ->
      let l, f1 = track_values state names lesson cond f1 in
      let _, f2 = track_values state names l cond f2 in
      lesson, t_label_copy f (t_implies_simp f1 f2)
  | Tbinop (Tand, f1, f2) ->
      let l, f1 = track_values state names lesson cond f1 in
      let l, f2 = track_values state names l cond f2 in
      l, t_label_copy f (t_and_simp f1 f2)
  | Tif (fc, f1, f2) ->
      let _, f1 = track_values state names lesson cond f1 in
      let _, f2 = track_values state names lesson cond f2 in
      lesson, t_label_copy f (t_if_simp fc f1 f2)
  | Tcase (t1, bl) ->
      let p1 = point_of_term state names t1 in
      let value = match_point state (of_option t1.t_ty) p1 in
      let is_pat_var = function
        | { pat_node = Pvar _ } -> true | _ -> false in
      let branch l br =
        let pat, f1, cb = t_open_branch_cb br in
        let learn, cond = match bl, pat.pat_node with
          | [_], _ -> true, cond (* one branch, can learn *)
          | _, Papp (cs, pl) when List.for_all is_pat_var pl ->
              (try true, Mint.add_new Exit p1 cs cond (* can learn *)
              with Exit -> false, cond) (* contradiction, cannot learn *)
          | _, _ -> false, cond (* complex pattern, will not learn *)
        in
        let names = open_pattern state names value p1 pat in
        let m, f1 = track_values state names lesson cond f1 in
        let l = if learn then m else l in
        l, cb pat f1
      in
      let l, bl = Util.map_fold_left branch lesson bl in
      l, t_label_copy f (t_case t1 bl)
  | Tlet (t1, bf) ->
      let p1 = point_of_term state names t1 in
      let v, f1, cb = t_open_bound_cb bf in
      let names = Mvs.add v p1 names in
      let l, f1 = track_values state names lesson cond f1 in
      l, t_label_copy f (t_let_simp t1 (cb v f1))
  | Tquant (Tforall, qf) ->
      let vl, trl, f1, cb = t_open_quant_cb qf in
      let add_vs s vs = Mvs.add vs (next_point state) s in
      let names = List.fold_left add_vs names vl in
      let l, f1 = track_values state names lesson cond f1 in
      l, t_label_copy f (t_forall_simp (cb vl trl f1))
  | Tbinop ((Tor|Tiff),_,_) | Tquant (Texists,_)
  | Tapp _ | Tnot _ | Ttrue | Tfalse -> lesson, f
  | Tvar _ | Tconst _ | Teps _ -> assert false

let track_values lkm km f =
  let state = empty_state lkm km in
  let _, f = track_values state Mvs.empty Mint.empty Mint.empty f in
  f
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(** Weakest preconditions *)

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let rec wp_expr env e q xq =
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  let f = wp_desc env e q xq in
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  if Debug.test_flag debug then begin
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    Format.eprintf "@[--------@\n@[<hov 2>e = %a@]@\n" Mlw_pretty.print_expr e;
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    Format.eprintf "@[<hov 2>q = %a@]@\n" Pretty.print_term q;
    Format.eprintf "@[<hov 2>f = %a@]@\n----@]@." Pretty.print_term f;
  end;
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  f
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and wp_desc env e q xq = match e.e_node with
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  | Elogic t ->
      let v, q = open_post q in
      let t = wp_label e t in
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      (* NOTE: if you replace this t_subst by t_let or anything else,
         you must handle separately the case "let mark = 'now in ...",
         which requires 'now to be substituted for mark in q *)
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      t_subst_single v (to_term t) q
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  | Evalue pv ->
      let v, q = open_post q in
      let t = wp_label e (t_var pv.pv_vs) in
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      t_subst_single v t q
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  | Earrow _ ->
      let q = open_unit_post q in
      (* wp_label e *) q (* FIXME? *)
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  | Elet ({ let_sym = LetV v; let_expr = e1 }, e2)
    when Util.option_eq Loc.equal v.pv_vs.vs_name.id_loc e1.e_loc ->
    (* we push the label down, past the implicitly inserted "let" *)
      let w = wp_expr env (e_label_copy e e2) q xq in
      let q = create_post v.pv_vs w in
      wp_expr env e1 q xq
  | Elet ({ let_sym = LetV v; let_expr = e1 }, e2) ->
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      let w = wp_expr env e2 q xq in
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      let q = create_post v.pv_vs w in
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      wp_label e (wp_expr env e1 q xq)
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  | Elet ({ let_sym = LetA _; let_expr = e1 }, e2) ->
      let w = wp_expr env e2 q xq in
      let q = create_unit_post w in
      wp_label e (wp_expr env e1 q xq)
  | Erec (rdl, e1) ->
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      let fr = wp_rec_defn env rdl in
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      let fe = wp_expr env e1 q xq in
      let fr = wp_ands ~sym:true fr in
      wp_label e (wp_and ~sym:true fr fe)
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  | Eif (e1, e2, e3) ->
      let res = vs_result e1 in
      let test = t_equ (t_var res) t_bool_true in
      let test = t_label ?loc:e1.e_loc model3_lab test in
      (* if both branches are pure, do not split *)
      let w =
        let get_term e = match e.e_node with
          | Elogic t -> to_term t
          | Evalue v -> t_var v.pv_vs
          | _ -> raise Exit in
        try
          let r2 = get_term e2 in
          let r3 = get_term e3 in
          let v, q = open_post q in
          t_subst_single v (t_if_simp test r2 r3) q
        with Exit ->
          let w2 = wp_expr env e2 q xq in
          let w3 = wp_expr env e3 q xq in
          t_if_simp test w2 w3
      in
      let q = create_post res w in
      wp_label e (wp_expr env e1 q xq)
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  (* optimization for the particular case let _ = e1 in e2 *)
  | Ecase (e1, [{ ppat_pattern = { pat_node = Term.Pwild }}, e2]) ->
      let w = wp_expr env e2 q xq in
      let q = create_post (vs_result e1) w in
      wp_label e (wp_expr env e1 q xq)
  (* optimization for the particular case let () = e1 in e2 *)
  | Ecase (e1, [{ ppat_pattern = { pat_node = Term.Papp (cs,[]) }}, e2])
    when ls_equal cs fs_void ->
      let w = wp_expr env e2 q xq in
      let q = create_unit_post w in
      wp_label e (wp_expr env e1 q xq)
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  | Ecase (e1, bl) ->
      let res = vs_result e1 in
      let branch ({ ppat_pattern = pat }, e) =
        t_close_branch pat (wp_expr env e q xq) in
      let w = t_case (t_var res) (List.map branch bl) in
      let q = create_post res w in
      wp_label e (wp_expr env e1 q xq)
  | Eghost e1 ->
      wp_label e (wp_expr env e1 q xq)
  | Eraise (xs, e1) ->
      let q = try Mexn.find xs xq with
        Not_found -> assert false in
      wp_label e (wp_expr env e1 q xq)
  | Etry (e1, bl) ->
      let branch (xs,v,e) acc =
        let w = wp_expr env e q xq in
        let q = create_post v.pv_vs w in
        Mexn.add xs q acc in
      let xq = List.fold_right branch bl xq in
      wp_label e (wp_expr env e1 q xq)
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  | Eassert (Aassert, f) ->
      let q = open_unit_post q in
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      let f = wp_expl expl_assert f in
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      wp_and ~sym:false (wp_label e f) q
  | Eassert (Acheck, f) ->
      let q = open_unit_post q in
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      let f = wp_expl expl_check f in
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      wp_and ~sym:true (wp_label e f) q
  | Eassert (Aassume, f) ->
      let q = open_unit_post q in
      wp_implies (wp_label e f) q
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  | Eabsurd ->
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      wp_label e t_absurd
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  | Eany spec ->
      let p = wp_label e (wp_expl expl_pre spec.c_pre) in
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      let p = t_label ?loc:e.e_loc p.t_label p in
      (* TODO: propagate call labels into tyc.c_post *)
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      let w = wp_abstract env spec.c_effect spec.c_post spec.c_xpost q xq in
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      wp_and ~sym:false p w (* FIXME? do we need pre? *)
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  | Eapp (e1,_,spec) ->
      let p = wp_label e (wp_expl expl_pre spec.c_pre) in
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      let p = t_label ?loc:e.e_loc p.t_label p in
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      let d = if spec.c_letrec = 0 then t_true else
        let olds = Mint.find_def [] spec.c_letrec env.letrec_var in
        if olds = [] then t_true (* we are out of letrec *) else
        let d = decrease ?loc:e.e_loc env olds spec.c_variant in
        wp_expl expl_variant (t_label ?loc:e.e_loc d.t_label d) in
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      (* TODO: propagate call labels into tyc.c_post *)
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      let w = wp_abstract env spec.c_effect spec.c_post spec.c_xpost q xq in
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      let w = wp_and ~sym:false (wp_and ~sym:true d p) w in (* FIXME? ~sym? *)
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      let q = create_unit_post w in
      wp_expr env e1 q xq (* FIXME? should (wp_label e) rather be here? *)
  | Eabstr (e1, c_q, c_xq) ->
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      let w1 = backstep (wp_expr env e1) c_q c_xq in
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      let w2 = wp_abstract env e1.e_effect c_q c_xq q xq in
      wp_and ~sym:true (wp_label e w1) w2
  | Eassign (e1, reg, pv) ->
      let rec get_term d = match d.e_node with
        | Elogic t -> t
        | Evalue v -> t_var v.pv_vs
        | Eghost e | Elet (_,e) | Erec (_,e) -> get_term e
        | _ -> Loc.errorm ?loc:e.e_loc
            "Cannot compute the WP for this assignment"
      in
      let f = t_equ (get_term e1) (t_var pv.pv_vs) in
      let c_q = create_unit_post f in
      let eff = eff_write eff_empty reg in
      let w = wp_abstract env eff c_q Mexn.empty q xq in
      let q = create_post (vs_result e1) w in
      wp_label e (wp_expr env e1 q xq)
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  | Eloop (inv, varl, e1) ->
      (* TODO: what do we do about well-foundness? *)
      let i = wp_expl expl_loop_keep inv in
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      let olds = List.map (fun (t,_) -> t_at_old t) varl in
      let d = decrease ?loc:e.e_loc env olds varl in
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      let d = wp_expl expl_loop_var d in
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      let q = create_unit_post (wp_and ~sym:true i d) in
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      let w = backstep (wp_expr env e1) q xq in
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      let regs = regs_of_writes e1.e_effect in
      let w = quantify env regs (wp_implies inv w) in
      let i = wp_expl expl_loop_init inv in
      wp_label e (wp_and ~sym:true i w)
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  | Efor ({pv_vs = x}, ({pv_vs = v1}, d, {pv_vs = v2}), inv, e1) ->
      (* wp(for x = v1 to v2 do inv { I(x) } e1, Q, R) =
             v1 > v2  -> Q
         and v1 <= v2 ->     I(v1)
                         and forall S. forall i. v1 <= i <= v2 ->
                                                 I(i) -> wp(e1, I(i+1), R)
                                       and I(v2+1) -> Q *)
      let gt, le, incr = match d with
        | Mlw_expr.To     -> env.ps_int_gt, env.ps_int_le, t_int_const "1"
        | Mlw_expr.DownTo -> env.ps_int_lt, env.ps_int_ge, t_int_const "-1" in
      let v1_gt_v2 = ps_app gt [t_var v1; t_var v2] in
      let v1_le_v2 = ps_app le [t_var v1; t_var v2] in
      let q = open_unit_post q in
      let wp_init =
        wp_expl expl_for_init (t_subst_single x (t_var v1) inv) in
      let wp_step =
        let nextx = fs_app env.fs_int_pl [t_var x; incr] ty_int in
        let post = create_unit_post (t_subst_single x nextx inv) in
        wp_expr env e1 post xq in
      let wp_last =
        let v2pl1 = fs_app env.fs_int_pl [t_var v2; incr] ty_int in
        wp_implies (t_subst_single x v2pl1 inv) q in
      let wp_good = wp_and ~sym:true
        wp_init
        (quantify env (regs_of_writes e1.e_effect)
           (wp_and ~sym:true
              (wp_expl expl_for_keep (wp_forall [x] (wp_implies
                (wp_and ~sym:true (ps_app le [t_var v1; t_var x])
                                  (ps_app le [t_var x;  t_var v2]))
                (wp_implies inv wp_step))))
              wp_last))
      in
      let wp_full = wp_and ~sym:true
        (wp_implies v1_gt_v2 q)
        (wp_implies v1_le_v2 wp_good)
      in
      wp_label e wp_full
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and wp_abstract env c_eff c_q c_xq q xq =
  let regs = regs_of_writes c_eff in
  let exns = exns_of_raises c_eff in
  let quantify_post c_q q =
    let v, f = open_post q in
    let c_v, c_f = open_post c_q in
    let c_f = t_subst_single c_v (t_var v) c_f in
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    let f = wp_forall_post v c_f f in
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    quantify env regs f
  in
  let quantify_xpost _ c_xq xq =
    Some (quantify_post c_xq xq) in
  let proceed c_q c_xq =
    let f = quantify_post c_q q in
    (* every xs in exns is guaranteed to be in c_xq and xq *)
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    assert (Mexn.set_submap exns xq);
    assert (Mexn.set_submap exns c_xq);
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    let xq = Mexn.set_inter xq exns in
    let c_xq = Mexn.set_inter c_xq exns in
    let mexn = Mexn.inter quantify_xpost c_xq xq in
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    (* FIXME? This wp_ands is asymmetric in Pgm_wp *)
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    wp_ands ~sym:true (f :: Mexn.values mexn)
  in
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  backstep proceed c_q c_xq
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and wp_fun_defn env lr { fun_ps = ps ; fun_lambda = l } =
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  let lab = fresh_mark () in
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  let add_arg sbs pv = ity_match sbs pv.pv_vtv.vtv_ity pv.pv_vtv.vtv_ity in
  let subst = List.fold_left add_arg ps.ps_subst l.l_args in
  let regs = Mreg.map (fun _ -> ()) subst.ity_subst_reg in
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  let args = List.map (fun pv -> pv.pv_vs) l.l_args in
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  let env = if lr = 0 || l.l_variant = [] then env else
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    let lab = t_var lab in
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    let t_at_lab (t,_) = t_app fs_at [t; lab] t.t_ty in
    let tl = List.map t_at_lab l.l_variant in
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    { env with letrec_var = Mint.add lr tl env.letrec_var }
  in
  let q = old_mark lab (wp_expl expl_post l.l_post) in
  let conv p = old_mark lab (wp_expl expl_xpost p) in
  let f = wp_expr env l.l_expr q (Mexn.map conv l.l_xpost) in
  let f = wp_implies l.l_pre (erase_mark lab f) in
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  wp_forall args (quantify env regs f)
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and wp_rec_defn env { rec_defn = rdl; rec_letrec = lr } =
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  List.map (wp_fun_defn env lr) rdl
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(***
let bool_to_prop env f =
  let ts_bool  = find_ts ~pure:true env "bool" in
  let ls_andb  = find_ls ~pure:true env "andb" in
  let ls_orb   = find_ls ~pure:true env "orb" in
  let ls_notb  = find_ls ~pure:true env "notb" in
  let ls_True  = find_ls ~pure:true env "True" in
  let ls_False = find_ls ~pure:true env "False" in
  let t_True   = fs_app ls_True [] (ty_app ts_bool []) in
  let is_bool ls = ls_equal ls ls_True || ls_equal ls ls_False in
  let rec t_iff_bool f1 f2 = match f1.t_node, f2.t_node with
    | Tnot f1, _ -> t_not_simp (t_iff_bool f1 f2)
    | _, Tnot f2 -> t_not_simp (t_iff_bool f1 f2)
    | Tapp (ps1, [t1; { t_node = Tapp (ls1, []) }]),
      Tapp (ps2, [t2; { t_node = Tapp (ls2, []) }])
      when ls_equal ps1 ps_equ && ls_equal ps2 ps_equ &&
           is_bool ls1 && is_bool ls2 ->
        if ls_equal ls1 ls2 then t_equ t1 t2 else t_neq t1 t2
    | _ ->
        t_iff_simp f1 f2
  in
  let rec t_btop t = t_label ?loc:t.t_loc t.t_label (* t_label_copy? *)
    (match t.t_node with
    | Tif (f,t1,t2) ->
        t_if_simp (f_btop f) (t_btop t1) (t_btop t2)
    | Tapp (ls, [t1;t2]) when ls_equal ls ls_andb ->
        t_and_simp (t_btop t1) (t_btop t2)
    | Tapp (ls, [t1;t2]) when ls_equal ls ls_orb ->
        t_or_simp (t_btop t1) (t_btop t2)
    | Tapp (ls, [t1]) when ls_equal ls ls_notb ->
        t_not_simp (t_btop t1)
    | Tapp (ls, []) when ls_equal ls ls_True ->
        t_true
    | Tapp (ls, []) when ls_equal ls ls_False ->
        t_false
    | _ ->
        t_equ_simp (f_btop t) t_True)
  and f_btop f = match f.t_node with
    | Tapp (ls, [{t_ty = Some {ty_node = Tyapp (ts, [])}} as l; r])
      when ls_equal ls ps_equ && ts_equal ts ts_bool ->
        t_label ?loc:f.t_loc f.t_label (t_iff_bool (t_btop l) (t_btop r))
    | _ ->
        t_map_simp f_btop f
  in
  f_btop f
***)
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(* replace t_absurd with t_false *)
let rec unabsurd f = match f.t_node with
  | Tapp (ls, []) when ls_equal ls ls_absurd ->
      t_label_copy f t_false
  | _ ->
      t_map unabsurd f

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let add_wp_decl km name f uc =
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  (* prepare a proposition symbol *)
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  let s = "WP_parameter " ^ name.id_string in
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  let lab = Ident.create_label ("expl:parameter " ^ name.id_string) in
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  let label = Slab.add lab name.id_label in
  let id = id_fresh ~label ?loc:name.id_loc s in
  let pr = create_prsymbol id in
  (* prepare the VC formula *)
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  let f = remove_at f in
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  (* let f = bool_to_prop uc f in *)
  let f = unabsurd f in
  (* get a known map with tuples added *)
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  let lkm = Theory.get_known uc in
  (* remove redundant invariants *)
  let f = if Debug.test_flag no_track then f else track_values lkm km f in
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  (* simplify f *)
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  let f = if Debug.test_flag no_eval then f else
    Eval_match.eval_match ~inline:Eval_match.inline_nonrec_linear lkm f in
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  (* printf "wp: f=%a@." print_term f; *)
  let d = create_prop_decl Pgoal pr f in
  Theory.add_decl uc d

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let mk_env env km th =
  let th_int = Env.find_theory env ["int"] "Int" in
  { prog_known = km;
    pure_known = Theory.get_known th;
    global_env = env;
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    ps_int_le  = Theory.ns_find_ls th_int.th_export ["infix <="];
    ps_int_ge  = Theory.ns_find_ls th_int.th_export ["infix >="];
    ps_int_lt  = Theory.ns_find_ls th_int.th_export ["infix <"];
    ps_int_gt  = Theory.ns_find_ls th_int.th_export ["infix >"];
    fs_int_pl  = Theory.ns_find_ls th_int.th_export ["infix +"];
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    letrec_var = Mint.empty;
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  }
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let wp_let env km th { let_sym = lv; let_expr = e } =
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  let env = mk_env env km th in
  let q, xq = default_post e.e_vty e.e_effect in
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  let f = wp_expr env e q xq in
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  let f = wp_forall (Mvs.keys f.t_vars) f in
  let id = match lv with
    | LetV pv -> pv.pv_vs.vs_name
    | LetA ps -> ps.ps_name in
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  add_wp_decl km id f th
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let wp_rec env km th rdl =
  let env = mk_env env km th in
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  let fl = wp_rec_defn env rdl in
  let add_one th d f =
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    Debug.dprintf debug "wp %s = %a@\n----------------@."
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      d.fun_ps.ps_name.id_string Pretty.print_term f;
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    let f = wp_forall (Mvs.keys f.t_vars) f in
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    add_wp_decl km d.fun_ps.ps_name f th
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  in
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  List.fold_left2 add_one th rdl.rec_defn fl
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let wp_val _env _km th _lv = th
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(*****************************************************************************)

(* Efficient Weakest Preconditions

  Following Leino, see
  http://research.microsoft.com/apps/pubs/default.aspx?id=70052

  Roughly, the idea is the following. From a program expression e, we compute
  two formulas OK and N. Formula OK means ``the execution of e does not go
  wrong'' and formula N is an input-output relation between initial and
  final state of e's execution.

  Thus the weakest precondition of e is simply OK.
  N is involved in recursive computations, e.g.
  OK(fun x -> {p} e {q}) = forall x. p => OK(e) /\ (forall result. N(e) => q)
  And so on.

  In practice, this is a bit more involved, since execution of e may raise
  exceptions. So formula N comes with other formulas E(x), once for each
  exception x that is possibly raised by e. E(x) is the input-output relation
  that holds when exception x is raised.
*)

let fast_wp = Debug.register_flag "fast_wp"
  ~desc:"Efficient Weakest Preconditions."

module Subst = struct

  type t = unit

  let empty = ()

  let term _s t = t

  let frame _ef s = s

end

let xs_result xs = create_vsymbol (id_fresh "result") (ty_of_ity xs.xs_ity)
let result e =
  vs_result e, Mexn.mapi (fun xs _ -> xs_result xs) e.e_effect.eff_raises

let is_vty_unit = function
  | VTvalue vtv -> ity_equal vtv.vtv_ity ity_unit
  | VTarrow _   -> false

let map_exns e f = Mexn.mapi (fun xs _ -> f xs) e.e_effect.eff_raises

let wp_nimplies ((n, _), xn) ((result, q), xq) =
  let f = wp_forall [result] (wp_implies n q) in
  assert (Mexn.cardinal xn = Mexn.cardinal xq);
  let x_implies _xs (n, _) (xresult, q) f =
    wp_forall [xresult] (wp_and ~sym:true f (wp_implies n q)) in
  Mexn.fold2_inter x_implies xn xq f

(* Input
   - a state s: Subst.t
   - names r = (result: vsymbol, xresult: vsymbol Mexn.t)
   - an expression e
   with: dom(xresult) = XS, the set of exceptions possibly raised
                            by a, that is e.e_effect.eff_raises

   Output is a triple (OK, ((NE, s), EX)) where
   - formula OK means ``e evaluates without any fault''
     (whatever the execution flow is)
   - formula NE means
     ``e terminates normally with final state s and output result''
   - for each exception x, EX(x) = (fx,sx), where formula fx means
     ``e raises exception x, with final state sw and value xresult(x) in x''
*)

let rec fast_wp_expr env s r e =
  let ok, _ as res = fast_wp_desc env s r e in
  if Debug.test_flag debug then begin
    Format.eprintf "@[--------@\n@[<hov 2>e = %a@]@\n" Mlw_pretty.print_expr e;
    Format.eprintf "@[<hov 2>OK = %a@]@\n" Pretty.print_term ok;
  end;
  res

and fast_wp_desc env s r e =
  let result, xresult = r in
  match e.e_node with
  | Elogic t ->
      (* OK: true
	 NE: result=t *)
      let t = wp_label e t in
      let t = Subst.term s (to_term t) in
      let ne = if is_vty_unit e.e_vty then t_true else t_equ (t_var result) t in
      t_true, ((ne, s), Mexn.empty)
  | Eassert (kind, f) ->
      (* assert: OK = f    / NE = f    *)
      (* check : OK = f    / NE = true *)
      (* assume: OK = true / NE = f    *)
      let ok = if kind = Aassume then t_true else f in
      let ne = if kind = Acheck then t_true else f in
      ok, ((ne, s), Mexn.empty)
  | Eabstr (_, _, _) -> assert false (*TODO*)
  | Etry (_, _) -> assert false (*TODO*)
  | Eraise (_, _) -> assert false (*TODO*)
  | Efor (_, _, _, _) -> assert false (*TODO*)
  | Eloop (_, _, _) -> assert false (*TODO*)
  | Eany _ -> assert false (*TODO*)
  | Eghost _ -> assert false (*TODO*)
  | Eassign (_, _, _) -> assert false (*TODO*)
  | Ecase (_, _) -> assert false (*TODO*)
  | Eif (_, _, _) -> assert false (*TODO*)
  | Erec (_, _) -> assert false (*TODO*)