208 lines
7.6 KiB
OCaml
208 lines
7.6 KiB
OCaml
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(*
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Cours "Sémantique et Application à la Vérification de programmes"
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Antoine Miné 2015
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Marc Chevalier 2018
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Josselin Giet 2021
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Ecole normale supérieure, Paris, France / CNRS / INRIA
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*)
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(*
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Signature of abstract domains representing sets of integers
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(for instance: constants or intervals).
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*)
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open Abstract_syntax_tree
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module type VALUE_DOMAIN =
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sig
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(* type of abstract elements *)
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(* an element of type t abstracts a set of integers *)
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type t
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(* unrestricted value: [-oo,+oo] *)
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val top: t
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(* bottom value: empty set *)
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val bottom: t
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(* constant: {c} *)
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val const: Z.t -> t
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(* interval: [a,b] *)
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val rand: Z.t -> Z.t -> t
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(* unary operation *)
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val unary: t -> int_unary_op -> t
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(* binary operation *)
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val binary: t -> t -> int_binary_op -> t
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(* comparison *)
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(* [compare x y op] returns (x',y') where
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- x' abstracts the set of v in x such that v op v' is true for some v' in y
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- y' abstracts the set of v' in y such that v op v' is true for some v in x
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i.e., we filter the abstract values x and y knowing that the test is true
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a safe, but not precise implementation, would be:
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compare x y op = (x,y)
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*)
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val compare: t -> t -> compare_op -> (t * t)
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(* backards unary operation *)
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(* [bwd_unary x op r] return x':
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- x' abstracts the set of v in x such as op v is in r
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i.e., we fiter the abstract values x knowing the result r of applying
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the operation on x
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*)
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val bwd_unary: t -> int_unary_op -> t -> t
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(* backward binary operation *)
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(* [bwd_binary x y op r] returns (x',y') where
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- x' abstracts the set of v in x such that v op v' is in r for some v' in y
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- y' abstracts the set of v' in y such that v op v' is in r for some v in x
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i.e., we filter the abstract values x and y knowing that, after
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applying the operation op, the result is in r
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*)
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val bwd_binary: t -> t -> int_binary_op -> t -> (t * t)
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(* set-theoretic operations *)
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val join: t -> t -> t
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val meet: t -> t -> t
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(* widening *)
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val widen: t -> t -> t
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(* narrowing *)
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val narrow: t -> t -> t
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(* subset inclusion of concretizations *)
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val subset: t -> t -> bool
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(* check the emptiness of the concretization *)
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val is_bottom: t -> bool
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(* print abstract element *)
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val print: Format.formatter -> t -> unit
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end
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open Cfg
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open Domain
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module NonRelational (V : VALUE_DOMAIN) : DOMAIN = struct
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module VMap = VarMap
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type t = Bot | E of V.t VMap.t
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let init = E VMap.empty (* Nonpresent variables are 0 *)
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let bottom = Bot
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let print out env = match env with
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| Bot -> Format.fprintf out "@[<h 0>Bot@]"
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| E map -> begin Format.fprintf out "@[<h 0>{";
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VMap.iter (fun varid val1 -> Format.fprintf out "%a : %a @ " Cfg_printer.print_var varid V.print val1) map;
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Format.fprintf out "}@]"; end
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let rec compute e expr = match expr with
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| CFG_int_unary (uop, aux) -> V.unary (compute e aux) uop
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| CFG_int_binary (bop, aux1, aux2) -> V.binary (compute e aux1) (compute e aux2) bop
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| CFG_int_var v -> (try ( VMap.find v e )with Not_found -> V.const Z.zero)
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| CFG_int_const c -> V.const c
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| CFG_int_rand (c1, c2) -> V.rand c1 c2
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let assign env v expr = match env with
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| Bot -> Bot
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| E envmap -> E (VMap.add v (compute envmap expr) envmap)
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let join env1 env2 = match (env1, env2) with
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| Bot, x | x, Bot -> x
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| E map1, E map2 ->
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E (VMap.merge (fun v val1 val2 -> match val1, val2 with
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| None, None -> None
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| None, Some x | Some x, None -> Some (V.join x (V.const Z.zero))
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| Some x, Some y -> Some (V.join x y)) map1 map2)
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let meet env1 env2 = match(env1, env2) with
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| Bot, x | x, Bot -> Bot
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| E map1, E map2 ->
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E (VMap.merge (fun v val1 val2 -> match val1, val2 with
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| None, None -> None
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| None, Some x | Some x, None -> Some (V.meet x (V.const Z.zero))
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| Some x, Some y -> Some (V.meet x y)) map1 map2)
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type hc4_tree = HC4_int_unary of int_unary_op * hc4_tree * V.t
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| HC4_int_binary of int_binary_op * hc4_tree * hc4_tree * V.t
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| HC4_int_var of var * V.t
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| HC4_int_const of Z.t * V.t
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| HC4_int_rand of Z.t*Z.t * V.t
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let get_abst hc4 = (match hc4 with
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| HC4_int_unary (_,_,v) -> v
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| HC4_int_binary (_,_,_,v) -> v
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| HC4_int_var (_,v) -> v
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| HC4_int_const (_,v) -> v
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| HC4_int_rand (_,_,v) -> v)
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let rec build_HC4 iexp mapenv = match iexp with
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| CFG_int_unary (uop, iexp') -> let sub = build_HC4 iexp' mapenv in HC4_int_unary (uop, sub, (V.unary (get_abst sub) uop))
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| CFG_int_binary (bop, iexp1, iexp2) -> let sub1, sub2 = build_HC4 iexp1 mapenv, build_HC4 iexp2 mapenv in
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HC4_int_binary (bop,sub1,sub2,(V.binary (get_abst sub1) (get_abst sub2) bop))
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| CFG_int_var v -> let abst = (try( VMap.find v mapenv )with Not_found -> V.const Z.zero) in HC4_int_var (v, abst)
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| CFG_int_const z -> let abst = V.const z in HC4_int_const (z, abst)
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| CFG_int_rand (a, b) -> let abst = V.rand a b in HC4_int_rand (a,b,abst)
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let rec revise_HC4 tree mapenv newval = match tree with
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| HC4_int_unary (uop, sub, abst) -> revise_HC4 sub mapenv (V.bwd_unary (get_abst sub) uop (V.meet abst newval))
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| HC4_int_binary (bop, sub1, sub2, abst) -> let refined1, refined2 = V.bwd_binary (get_abst sub1) (get_abst sub2) bop (V.meet abst newval) in
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meet (revise_HC4 sub1 mapenv refined1) (revise_HC4 sub2 mapenv refined2)
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| HC4_int_var (v, abst) -> E (VMap.add v (V.meet abst newval) mapenv)
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| HC4_int_const (z,abst) -> if( V.is_bottom (V.meet abst newval) ) then Bot else E mapenv
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| HC4_int_rand (a,b,abst) -> if( V.is_bottom (V.meet abst newval) ) then Bot else E mapenv
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let rec guard_noneg env boolexp = match boolexp with
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| CFG_bool_unary (_, _) -> failwith "We were supposed to remove negations !!"
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| CFG_bool_binary (AST_AND, exp1, exp2) -> meet (guard_noneg env exp1) (guard_noneg env exp2)
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| CFG_bool_binary (AST_OR, exp1, exp2) -> join (guard_noneg env exp1) (guard_noneg env exp2)
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| CFG_bool_const (b) -> if b then env else Bot
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| CFG_bool_rand -> env
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| CFG_compare (cop, iexp1, iexp2) -> match env with
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| Bot -> Bot
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| E mapenv -> let hc4_1, hc4_2 = build_HC4 iexp1 mapenv, build_HC4 iexp2 mapenv in
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let newval1, newval2 = V.compare (get_abst hc4_1) (get_abst hc4_2) cop in (
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meet (revise_HC4 hc4_1 mapenv newval1) (revise_HC4 hc4_2 mapenv newval2) )
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let guard env boolexp = guard_noneg env (rm_negations boolexp)
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let widen env1 env2 = match (env1, env2) with
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| Bot, x | x, Bot -> x
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| E map1, E map2 ->
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E (VMap.merge (fun v val1 val2 -> match val1, val2 with
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| None, None -> None
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| None, Some x | Some x, None -> Some (V.widen x (V.const Z.zero))
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| Some x, Some y -> Some (V.widen x y)) map1 map2)
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let narrow env1 env2 = match(env1, env2) with
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| Bot, x | x, Bot -> Bot
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| E map1, E map2 ->
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E (VMap.merge (fun v val1 val2 -> match val1, val2 with
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| None, None -> None
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| None, Some x | Some x, None -> Some (V.narrow x (V.const Z.zero))
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| Some x, Some y -> Some (V.narrow x y)) map1 map2)
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let subset env1 env2 = match env1, env2 with
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| Bot, _ -> true
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| _, Bot -> false
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| E map1, E map2 -> let b1 = VMap.for_all (fun varid val1 -> match VMap.find_opt varid map2 with
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| None -> V.subset val1 (V.const Z.zero)
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| Some val2 -> V.subset val1 val2) map1 in
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let b2 = VMap.for_all (fun varid val2 -> match VMap.find_opt varid map1 with
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| None -> V.subset (V.const Z.zero) val2
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| Some val1 -> V.subset val1 val2) map2 in
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b1 && b2
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let is_bottom env = match env with
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| Bot -> true
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| E map -> VMap.exists (fun varid val1 -> V.is_bottom val1) map
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end
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