[inferbo] Do not append field to the unknown location

Summary:
This diff revises how to handle the unknown location in inferbo in two ways:

* stop appending field to the `Unknown` location, e.g. `Unknown.x.a` is evaluated to `Unknown`
* redesign the abstract of multiple locations, like `Bottom` < `Unknown` < `Known` locations

I am doing them in one diff since applying only one of them showed bad results.

Background: `Unknown` was adopted for abstracting all unknown concrete locations, so we could avoid missing semantics of assignments to unknown locations. We tried to keep soundness. However, it brought some other problems related to precision and performance.

1. Sometimes especially when Inferbo failed to reason precise pointer values, `Unknown` may point to many other abstract locations.

2. At that time, value assignments to `*Unknown` makes the situation worse: many abstract locations are updated with imprecise values.

This problem harmed not only its precision, but also its performance since it introduced more location entries in the abstract memory.

Reviewed By: jvillard

Differential Revision: D21017789

fbshipit-source-id: 0bb6bd8b5
master
Sungkeun Cho 5 years ago committed by Facebook GitHub Bot
parent 6e4a729ab6
commit 30ca51366d

@ -143,10 +143,13 @@ module Loc = struct
let of_allocsite a = Allocsite a let of_allocsite a = Allocsite a
let append_star_field l0 ~fn = let append_star_field l0 ~fn =
let rec aux = function let rec aux l =
match l with
| Allocsite a when Allocsite.is_unknown a ->
l
| Var _ | Allocsite _ -> | Var _ | Allocsite _ ->
StarField {prefix= l0; last_field= fn} StarField {prefix= l0; last_field= fn}
| StarField {last_field} as l when Fieldname.equal fn last_field -> | StarField {last_field} when Fieldname.equal fn last_field ->
l l
| StarField {prefix} -> | StarField {prefix} ->
StarField {prefix; last_field= fn} StarField {prefix; last_field= fn}
@ -161,6 +164,8 @@ module Loc = struct
if Symb.SymbolPath.is_field_depth_beyond_limit depth then append_star_field l0 ~fn if Symb.SymbolPath.is_field_depth_beyond_limit depth then append_star_field l0 ~fn
else else
match l with match l with
| Allocsite a when Allocsite.is_unknown a ->
l
| Var _ | Allocsite _ -> | Var _ | Allocsite _ ->
Field {prefix= l0; fn; typ} Field {prefix= l0; fn; typ}
| StarField {last_field} as l when Fieldname.equal fn last_field -> | StarField {last_field} as l when Fieldname.equal fn last_field ->
@ -392,30 +397,174 @@ module Loc = struct
x x
end end
module LocSet = PrettyPrintable.MakePPSet (Loc)
module PowLoc = struct module PowLoc = struct
include AbstractDomain.FiniteSet (Loc) (* The known set of locations should not be empty and not include the unknown location. Every
constructors in this module should be defined carefully to keep that constraint. *)
type t = Bottom | Unknown | Known of LocSet.t [@@deriving compare]
let pp f = function
| Bottom ->
F.pp_print_string f SpecialChars.up_tack
| Unknown ->
Loc.pp f Loc.unknown
| Known locs ->
LocSet.pp f locs
let leq ~lhs ~rhs =
match (lhs, rhs) with
| Bottom, _ ->
true
| _, Bottom ->
false
| Unknown, _ ->
true
| _, Unknown ->
false
| Known lhs, Known rhs ->
LocSet.subset lhs rhs
let bot = empty
let is_bot = is_empty let join x y =
match (x, y) with
| Bottom, _ ->
y
| _, Bottom ->
x
| Unknown, _ ->
y
| _, Unknown ->
x
| Known x, Known y ->
Known (LocSet.union x y)
let widen ~prev ~next ~num_iters:_ = join prev next
let bot = Bottom
let is_bot = function Bottom -> true | Unknown | Known _ -> false
let unknown = Unknown
let singleton l = if Loc.is_unknown l then Unknown else Known (LocSet.singleton l)
let fold f ploc init =
match ploc with
| Bottom ->
init
| Unknown ->
f Loc.unknown init
| Known ploc ->
LocSet.fold f ploc init
let exists f ploc =
match ploc with
| Bottom ->
false
| Unknown ->
f Loc.unknown
| Known ploc ->
LocSet.exists f ploc
let normalize ploc =
match ploc with
| Bottom | Unknown ->
ploc
| Known ploc' -> (
match LocSet.is_singleton_or_more ploc' with
| Empty ->
Bottom
| Singleton loc when Loc.is_unknown loc ->
Unknown
| More when LocSet.mem Loc.unknown ploc' ->
Known (LocSet.remove Loc.unknown ploc')
| _ ->
ploc )
let map f ploc =
match ploc with
| Bottom ->
Bottom
| Unknown ->
singleton (f Loc.unknown)
| Known ploc ->
Known (LocSet.map f ploc) |> normalize
let is_singleton_or_more = function
| Bottom ->
IContainer.Empty
| Unknown ->
IContainer.Singleton Loc.unknown
| Known ploc ->
LocSet.is_singleton_or_more ploc
let min_elt_opt = function
| Bottom ->
None
| Unknown ->
Some Loc.unknown
| Known ploc ->
LocSet.min_elt_opt ploc
let add l ploc =
match ploc with
| Bottom | Unknown ->
singleton l
| Known _ when Loc.is_unknown l ->
ploc
| Known ploc ->
Known (LocSet.add l ploc)
let mem l = function
| Bottom ->
false
| Unknown ->
Loc.is_unknown l
| Known ploc ->
LocSet.mem l ploc
let unknown = singleton Loc.unknown
let append_field ploc ~fn = let append_field ploc ~fn =
if is_bot ploc then singleton Loc.unknown match normalize ploc with
else fold (fun l -> add (Loc.append_field l ~fn)) ploc empty | Bottom ->
(* Return the unknown location to avoid unintended unreachable nodes *)
Unknown
| Unknown ->
ploc
| Known ploc ->
Known (LocSet.fold (fun l -> LocSet.add (Loc.append_field l ~fn)) ploc LocSet.empty)
let append_star_field ploc ~fn = let append_star_field ploc ~fn =
if is_bot ploc then singleton Loc.unknown match normalize ploc with
else fold (fun l -> add (Loc.append_star_field l ~fn)) ploc empty | Bottom ->
(* Return the unknown location to avoid unintended unreachable nodes *)
Unknown
| Unknown ->
ploc
| Known ploc ->
Known (LocSet.fold (fun l -> LocSet.add (Loc.append_star_field l ~fn)) ploc LocSet.empty)
let lift_cmp cmp_loc ploc1 ploc2 = let lift_cmp cmp_loc ploc1 ploc2 =
match (is_singleton_or_more ploc1, is_singleton_or_more ploc2) with match (ploc1, ploc2) with
| Known ploc1, Known ploc2 -> (
match (LocSet.is_singleton_or_more ploc1, LocSet.is_singleton_or_more ploc2) with
| IContainer.Singleton loc1, IContainer.Singleton loc2 -> | IContainer.Singleton loc1, IContainer.Singleton loc2 ->
Boolean.EqualOrder.of_equal cmp_loc (Loc.eq loc1 loc2) Boolean.EqualOrder.of_equal cmp_loc (Loc.eq loc1 loc2)
| _ -> | _ ->
Boolean.Top )
| _, _ ->
Boolean.Top Boolean.Top
@ -432,7 +581,7 @@ module PowLoc = struct
let subst x (eval_locpath : eval_locpath) = let subst x (eval_locpath : eval_locpath) =
fold (fun l acc -> join acc (subst_loc l eval_locpath)) x empty fold (fun l acc -> join acc (subst_loc l eval_locpath)) x bot
let exists_str ~f x = exists (fun l -> Loc.exists_str ~f l) x let exists_str ~f x = exists (fun l -> Loc.exists_str ~f l) x
@ -440,6 +589,14 @@ module PowLoc = struct
let of_c_strlen x = map Loc.of_c_strlen x let of_c_strlen x = map Loc.of_c_strlen x
let cast typ x = map (Loc.cast typ) x let cast typ x = map (Loc.cast typ) x
let to_set = function
| Bottom ->
LocSet.empty
| Unknown ->
LocSet.singleton Loc.unknown
| Known ploc ->
ploc
end end
let always_strong_update = false let always_strong_update = false

@ -108,8 +108,12 @@ module Loc : sig
(** It appends field. [typ] is the type of [fn]. *) (** It appends field. [typ] is the type of [fn]. *)
end end
module LocSet : PrettyPrintable.PPSet with type elt = Loc.t
module PowLoc : sig module PowLoc : sig
include AbstractDomain.FiniteSetS with type elt = Loc.t include AbstractDomain.S
val compare : t -> t -> int
val append_field : t -> fn:Fieldname.t -> t val append_field : t -> fn:Fieldname.t -> t
@ -117,6 +121,20 @@ module PowLoc : sig
val bot : t val bot : t
val add : Loc.t -> t -> t
val exists : (Loc.t -> bool) -> t -> bool
val mem : Loc.t -> t -> bool
val is_singleton_or_more : t -> Loc.t IContainer.singleton_or_more
val min_elt_opt : t -> Loc.t option
val singleton : Loc.t -> t
val fold : (Loc.t -> 'a -> 'a) -> t -> 'a -> 'a
val cast : Typ.typ -> t -> t val cast : Typ.typ -> t -> t
val of_c_strlen : t -> t val of_c_strlen : t -> t
@ -141,6 +159,8 @@ module PowLoc : sig
val lift_cmp : Boolean.EqualOrder.t -> t -> t -> Boolean.t val lift_cmp : Boolean.EqualOrder.t -> t -> t -> Boolean.t
(** It lifts a comparison of [Loc.t] to [t]. The comparison can be [Boolean.EqualOrder.eq], (** It lifts a comparison of [Loc.t] to [t]. The comparison can be [Boolean.EqualOrder.eq],
[Boolean.EqualOrder.ne], etc. *) [Boolean.EqualOrder.ne], etc. *)
val to_set : t -> LocSet.t
end end
val can_strong_update : PowLoc.t -> bool val can_strong_update : PowLoc.t -> bool

@ -357,7 +357,7 @@ let subst : t -> Bound.eval_sym -> PowLoc.eval_locpath -> PowLoc.t * t =
in in
PowLoc.fold add_allocsite locs (powloc_acc, acc) PowLoc.fold add_allocsite locs (powloc_acc, acc)
in in
fold subst1 a (PowLoc.empty, empty) fold subst1 a (PowLoc.bot, empty)
let is_symbolic : t -> bool = fun a -> exists (fun _ ai -> ArrInfo.is_symbolic ai) a let is_symbolic : t -> bool = fun a -> exists (fun _ ai -> ArrInfo.is_symbolic ai) a

@ -92,8 +92,8 @@ module TransferFunctions = struct
let instantiate_mem_reachable (ret_id, ret_typ) callee_formals callee_pname params let instantiate_mem_reachable (ret_id, ret_typ) callee_formals callee_pname params
~callee_exit_mem ({Dom.eval_locpath} as eval_sym_trace) mem location = ~callee_exit_mem ({Dom.eval_locpath} as eval_sym_trace) mem location =
let formal_locs = let formal_locs =
List.fold callee_formals ~init:PowLoc.bot ~f:(fun acc (formal, _) -> List.fold callee_formals ~init:LocSet.empty ~f:(fun acc (formal, _) ->
PowLoc.add (Loc.of_pvar formal) acc ) LocSet.add (Loc.of_pvar formal) acc )
in in
let copy_reachable_locs_from locs mem = let copy_reachable_locs_from locs mem =
let copy loc acc = let copy loc acc =
@ -103,7 +103,7 @@ module TransferFunctions = struct
PowLoc.fold (fun loc acc -> Dom.Mem.add_heap loc v acc) locs acc ) PowLoc.fold (fun loc acc -> Dom.Mem.add_heap loc v acc) locs acc )
in in
let reachable_locs = Dom.Mem.get_reachable_locs_from callee_formals locs callee_exit_mem in let reachable_locs = Dom.Mem.get_reachable_locs_from callee_formals locs callee_exit_mem in
PowLoc.fold copy (PowLoc.diff reachable_locs formal_locs) mem LocSet.fold copy (LocSet.diff reachable_locs formal_locs) mem
in in
let instantiate_ret_alias mem = let instantiate_ret_alias mem =
let subst_loc l = let subst_loc l =
@ -136,7 +136,8 @@ module TransferFunctions = struct
in in
Dom.Mem.add_stack ret_var (Dom.Val.subst ret_val eval_sym_trace location) mem Dom.Mem.add_stack ret_var (Dom.Val.subst ret_val eval_sym_trace location) mem
|> instantiate_ret_alias |> instantiate_ret_alias
|> copy_reachable_locs_from (PowLoc.join formal_locs (Dom.Val.get_all_locs ret_val)) |> copy_reachable_locs_from
(LocSet.union formal_locs (Dom.Val.get_all_locs ret_val |> PowLoc.to_set))
|> instantiate_latest_prune ~ret_id ~callee_exit_mem eval_sym_trace location |> instantiate_latest_prune ~ret_id ~callee_exit_mem eval_sym_trace location
@ -228,8 +229,8 @@ module TransferFunctions = struct
Option.value_map (Dom.Mem.find_opt loc from_mem) ~default:acc ~f:(fun v -> Option.value_map (Dom.Mem.find_opt loc from_mem) ~default:acc ~f:(fun v ->
Dom.Mem.add_heap loc v acc ) Dom.Mem.add_heap loc v acc )
in in
let reachable_locs = Dom.Mem.get_reachable_locs_from [] (PowLoc.singleton loc) from_mem in let reachable_locs = Dom.Mem.get_reachable_locs_from [] (LocSet.singleton loc) from_mem in
PowLoc.fold copy reachable_locs to_mem LocSet.fold copy reachable_locs to_mem
in in
fun tenv get_summary exp mem -> fun tenv get_summary exp mem ->
Option.value_map (Exp.get_java_class_initializer tenv exp) ~default:mem Option.value_map (Exp.get_java_class_initializer tenv exp) ~default:mem

@ -260,7 +260,7 @@ module Val = struct
; itv_updated_by= ItvUpdatedBy.Top ; itv_updated_by= ItvUpdatedBy.Top
; modeled_range= ModeledRange.bottom ; modeled_range= ModeledRange.bottom
; taint= Taint.bottom ; taint= Taint.bottom
; powloc= (if is_int then PowLoc.bottom else PowLoc.unknown) ; powloc= (if is_int then PowLoc.bot else PowLoc.unknown)
; arrayblk= (if is_int then ArrayBlk.bottom else ArrayBlk.unknown) ; arrayblk= (if is_int then ArrayBlk.bottom else ArrayBlk.unknown)
; traces } ; traces }
@ -484,7 +484,7 @@ module Val = struct
Itv.is_bottom pruned_itv Itv.is_bottom pruned_itv
&& (not (Itv.is_bottom x.itv)) && (not (Itv.is_bottom x.itv))
&& Itv.is_bottom y.itv && Itv.is_bottom y.itv
&& not (PowLoc.is_bottom (get_all_locs y)) && not (PowLoc.is_bot (get_all_locs y))
then x.itv then x.itv
else pruned_itv else pruned_itv
in in
@ -929,12 +929,22 @@ module MemPure = struct
(** Collect the location that was increased by one, i.e., [x -> x+1] *) (** Collect the location that was increased by one, i.e., [x -> x+1] *)
let get_incr_locs m = let get_incr_locs m =
fold (fun l v acc -> if MVal.is_incr_of l v then PowLoc.add l acc else acc) m PowLoc.empty fold (fun l v acc -> if MVal.is_incr_of l v then PowLoc.add l acc else acc) m PowLoc.bot
let find_opt l m = Option.map (find_opt l m) ~f:MVal.get_val let find_opt l m = Option.map (find_opt l m) ~f:MVal.get_val
let add ?(represents_multiple_values = false) l v m = let add ?(represents_multiple_values = false) l ({Val.powloc; arrayblk} as v) m =
let v =
if Loc.is_unknown l then
(* We do not add the other locations except the unknown itself in its value. This spoiled
other values raising out of memory sometimes, rather than being helpful for analysis
precision. *)
{ v with
Val.powloc= (if PowLoc.is_bot powloc then powloc else PowLoc.unknown)
; arrayblk= (if ArrayBlk.is_bottom arrayblk then arrayblk else ArrayBlk.unknown) }
else v
in
let f = function let f = function
| None -> | None ->
Some (represents_multiple_values || Loc.represents_multiple_values l, v) Some (represents_multiple_values || Loc.represents_multiple_values l, v)
@ -1030,7 +1040,7 @@ module AliasTarget = struct
| IteratorOffset {java_tmp= None} | IteratorOffset {java_tmp= None}
| IteratorHasNext {java_tmp= None} | IteratorHasNext {java_tmp= None}
| Top -> | Top ->
PowLoc.empty PowLoc.bot
let use_loc l x = PowLoc.mem l (get_locs x) let use_loc l x = PowLoc.mem l (get_locs x)
@ -2093,7 +2103,7 @@ module MemReach = struct
let add_iterator_alias_common ~cond ~alias_add id m = let add_iterator_alias_common ~cond ~alias_add id m =
let locs = let locs =
let accum_loc l v acc = if cond v then PowLoc.add l acc else acc in let accum_loc l v acc = if cond v then PowLoc.add l acc else acc in
MemPure.fold accum_loc m.mem_pure PowLoc.empty MemPure.fold accum_loc m.mem_pure PowLoc.bot
in in
{m with alias= alias_add id locs m.alias} {m with alias= alias_add id locs m.alias}
@ -2260,29 +2270,29 @@ module MemReach = struct
let set_latest_prune : LatestPrune.t -> t -> t = fun latest_prune x -> {x with latest_prune} let set_latest_prune : LatestPrune.t -> t -> t = fun latest_prune x -> {x with latest_prune}
let get_reachable_locs_from_aux : f:(Pvar.t -> bool) -> PowLoc.t -> _ t0 -> PowLoc.t = let get_reachable_locs_from_aux : f:(Pvar.t -> bool) -> LocSet.t -> _ t0 -> LocSet.t =
let add_reachable1 ~root loc v acc = let add_reachable1 ~root loc v acc =
if Loc.equal root loc then PowLoc.union acc (Val.get_all_locs v) if Loc.equal root loc then LocSet.union acc (Val.get_all_locs v |> PowLoc.to_set)
else if Loc.is_field_of ~loc:root ~field_loc:loc then PowLoc.add loc acc else if Loc.is_field_of ~loc:root ~field_loc:loc then LocSet.add loc acc
else acc else acc
in in
let rec add_from_locs heap locs acc = PowLoc.fold (add_from_loc heap) locs acc let rec add_from_locs heap locs acc = LocSet.fold (add_from_loc heap) locs acc
and add_from_loc heap loc acc = and add_from_loc heap loc acc =
if PowLoc.mem loc acc then acc if LocSet.mem loc acc then acc
else else
let reachable_locs = MemPure.fold (add_reachable1 ~root:loc) heap PowLoc.empty in let reachable_locs = MemPure.fold (add_reachable1 ~root:loc) heap LocSet.empty in
add_from_locs heap reachable_locs (PowLoc.add loc acc) add_from_locs heap reachable_locs (LocSet.add loc acc)
in in
let add_param_locs ~f mem acc = let add_param_locs ~f mem acc =
let add_loc loc _ acc = if Loc.exists_pvar ~f loc then PowLoc.add loc acc else acc in let add_loc loc _ acc = if Loc.exists_pvar ~f loc then LocSet.add loc acc else acc in
MemPure.fold add_loc mem acc MemPure.fold add_loc mem acc
in in
fun ~f locs m -> fun ~f locs m ->
let locs = add_param_locs ~f m.mem_pure locs in let locs = add_param_locs ~f m.mem_pure locs in
add_from_locs m.mem_pure locs PowLoc.empty add_from_locs m.mem_pure locs LocSet.empty
let get_reachable_locs_from : (Pvar.t * Typ.t) list -> PowLoc.t -> _ t0 -> PowLoc.t = let get_reachable_locs_from : (Pvar.t * Typ.t) list -> LocSet.t -> _ t0 -> LocSet.t =
fun formals locs m -> fun formals locs m ->
let is_formal pvar = List.exists formals ~f:(fun (formal, _) -> Pvar.equal pvar formal) in let is_formal pvar = List.exists formals ~f:(fun (formal, _) -> Pvar.equal pvar formal) in
get_reachable_locs_from_aux ~f:is_formal locs m get_reachable_locs_from_aux ~f:is_formal locs m
@ -2304,9 +2314,9 @@ module MemReach = struct
Pvar.is_return pvar || Pvar.is_global pvar Pvar.is_return pvar || Pvar.is_global pvar
|| List.exists formals ~f:(fun (formal, _) -> Pvar.equal formal pvar) || List.exists formals ~f:(fun (formal, _) -> Pvar.equal formal pvar)
in in
get_reachable_locs_from_aux ~f PowLoc.empty m get_reachable_locs_from_aux ~f LocSet.empty m
in in
fun l -> PowLoc.mem l reachable_locs fun l -> LocSet.mem l reachable_locs
in in
let stack_locs = StackLocs.filter is_reachable m.stack_locs in let stack_locs = StackLocs.filter is_reachable m.stack_locs in
let mem_pure = MemPure.filter (fun l _ -> is_reachable l) m.mem_pure in let mem_pure = MemPure.filter (fun l _ -> is_reachable l) m.mem_pure in
@ -2536,9 +2546,9 @@ module Mem = struct
let strong_update : PowLoc.t -> Val.t -> t -> t = fun p v -> map ~f:(MemReach.strong_update p v) let strong_update : PowLoc.t -> Val.t -> t -> t = fun p v -> map ~f:(MemReach.strong_update p v)
let get_reachable_locs_from : (Pvar.t * Typ.t) list -> PowLoc.t -> _ t0 -> PowLoc.t = let get_reachable_locs_from : (Pvar.t * Typ.t) list -> LocSet.t -> _ t0 -> LocSet.t =
fun formals locs -> fun formals locs ->
f_lift_default ~default:PowLoc.empty (MemReach.get_reachable_locs_from formals locs) f_lift_default ~default:LocSet.empty (MemReach.get_reachable_locs_from formals locs)
let update_mem : PowLoc.t -> Val.t -> t -> t = fun ploc v -> map ~f:(MemReach.update_mem ploc v) let update_mem : PowLoc.t -> Val.t -> t -> t = fun ploc v -> map ~f:(MemReach.update_mem ploc v)

@ -515,7 +515,7 @@ module Mem : sig
val get_latest_prune : _ t0 -> LatestPrune.t val get_latest_prune : _ t0 -> LatestPrune.t
val get_reachable_locs_from : (Pvar.t * Typ.t) list -> AbsLoc.PowLoc.t -> _ t0 -> AbsLoc.PowLoc.t val get_reachable_locs_from : (Pvar.t * Typ.t) list -> AbsLoc.LocSet.t -> _ t0 -> AbsLoc.LocSet.t
(** Get reachable locations from [formals] and [locs] when called (** Get reachable locations from [formals] and [locs] when called
[get_reachable_locs_from formals locs mem] *) [get_reachable_locs_from formals locs mem] *)

@ -778,7 +778,7 @@ module JavaInteger = struct
let intValue exp = let intValue exp =
let exec _ ~ret:(id, _) mem = let exec _ ~ret:(id, _) mem =
let powloc = Sem.eval_locs exp mem in let powloc = Sem.eval_locs exp mem in
let v = if PowLoc.is_empty powloc then Dom.Val.Itv.top else Dom.Mem.find_set powloc mem in let v = if PowLoc.is_bot powloc then Dom.Val.Itv.top else Dom.Mem.find_set powloc mem in
model_by_value v id mem model_by_value v id mem
in in
{exec; check= no_check} {exec; check= no_check}

@ -285,7 +285,7 @@ let rec eval_locs : Exp.t -> Mem.t -> PowLoc.t =
| BinOp ((Binop.MinusPI | Binop.PlusPI), e, _) | Cast (_, e) -> | BinOp ((Binop.MinusPI | Binop.PlusPI), e, _) | Cast (_, e) ->
eval_locs e mem eval_locs e mem
| BinOp _ | Closure _ | Const _ | Exn _ | Sizeof _ | UnOp _ -> | BinOp _ | Closure _ | Const _ | Exn _ | Sizeof _ | UnOp _ ->
PowLoc.empty PowLoc.bot
| Lfield (e, fn, _) -> | Lfield (e, fn, _) ->
eval_locs e mem |> PowLoc.append_field ~fn eval_locs e mem |> PowLoc.append_field ~fn
| Lindex (((Lfield _ | Lindex _) as e), _) -> | Lindex (((Lfield _ | Lindex _) as e), _) ->
@ -425,7 +425,7 @@ and eval_locpath ~mode params p mem =
let locs = eval_locpath ~mode params prefix mem in let locs = eval_locpath ~mode params prefix mem in
PowLoc.append_star_field ~fn locs PowLoc.append_star_field ~fn locs
in in
if PowLoc.is_empty res then ( if PowLoc.is_bot res then (
match mode with match mode with
| EvalPOReachability -> | EvalPOReachability ->
res res
@ -510,7 +510,7 @@ let conservative_array_length ?traces arr_locs mem =
let eval_array_locs_length arr_locs mem = let eval_array_locs_length arr_locs mem =
if PowLoc.is_empty arr_locs then Val.Itv.top if PowLoc.is_bot arr_locs then Val.Itv.top
else else
let arr = Mem.find_set arr_locs mem in let arr = Mem.find_set arr_locs mem in
let traces = Val.get_traces arr in let traces = Val.get_traces arr in

@ -285,7 +285,7 @@ module Check = struct
let arr = let arr =
if Language.curr_language_is Java then if Language.curr_language_is Java then
let arr_locs = Sem.eval_locs array_exp mem in let arr_locs = Sem.eval_locs array_exp mem in
if PowLoc.is_empty arr_locs then Dom.Val.Itv.top else Dom.Mem.find_set arr_locs mem if PowLoc.is_bot arr_locs then Dom.Val.Itv.top else Dom.Mem.find_set arr_locs mem
else Sem.eval_arr integer_type_widths array_exp mem else Sem.eval_arr integer_type_widths array_exp mem
in in
let latest_prune = Dom.Mem.get_latest_prune mem in let latest_prune = Dom.Mem.get_latest_prune mem in

@ -70,6 +70,7 @@ codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::fB_FP, 0, INTEGER_OVERFLOW_
codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::lI_FP, 2, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: std::unique_ptr<LMB<TFM>,std::default_delete<LMB<TFM>>>::operator->,Array access: Offset: [-oo, +oo] Size: [0, +oo]] codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::lI_FP, 2, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: std::unique_ptr<LMB<TFM>,std::default_delete<LMB<TFM>>>::operator->,Array access: Offset: [-oo, +oo] Size: [0, +oo]]
codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::lI_FP, 2, INTEGER_OVERFLOW_L5, no_bucket, ERROR, [<LHS trace>,Call,Parameter `*o`,Call,Parameter `*k`,Call,Parameter `*k`,Assignment,Assignment,Assignment,Assignment,Binary operation: ([-oo, +oo] - 1):signed32] codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::lI_FP, 2, INTEGER_OVERFLOW_L5, no_bucket, ERROR, [<LHS trace>,Call,Parameter `*o`,Call,Parameter `*k`,Call,Parameter `*k`,Assignment,Assignment,Assignment,Assignment,Binary operation: ([-oo, +oo] - 1):signed32]
codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::uI, 0, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: std::unique_ptr<LMB<TFM>,std::default_delete<LMB<TFM>>>::operator->,Array access: Offset: [-oo, +oo] Size: [0, +oo]] codetoanalyze/cpp/bufferoverrun/repro1.cpp, LM<TFM>::uI, 0, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: std::unique_ptr<LMB<TFM>,std::default_delete<LMB<TFM>>>::operator->,Array access: Offset: [-oo, +oo] Size: [0, +oo]]
codetoanalyze/cpp/bufferoverrun/repro1.cpp, am_Good_FP, 5, BUFFER_OVERRUN_U5, no_bucket, ERROR, [Call,Call,Call,Assignment,Assignment,Call,Unknown value from: lo::~lo,Call,Assignment,Call,<Offset trace>,Parameter `bi`,<Length trace>,Parameter `*this->b->cpp.vector_elem`,Array access: Offset: [-oo, +oo] Size: [0, +oo] by call to `ral_good` ]
codetoanalyze/cpp/bufferoverrun/repro1.cpp, am_Good_FP, 5, INTEGER_OVERFLOW_L5, no_bucket, ERROR, [Call,Call,Call,Assignment,Assignment,Call,Parameter `t->bI`,Call,Assignment,Call,<LHS trace>,Parameter `bi`,Binary operation: ([-oo, +oo] - 1):signed32 by call to `ral_good` ] codetoanalyze/cpp/bufferoverrun/repro1.cpp, am_Good_FP, 5, INTEGER_OVERFLOW_L5, no_bucket, ERROR, [Call,Call,Call,Assignment,Assignment,Call,Parameter `t->bI`,Call,Assignment,Call,<LHS trace>,Parameter `bi`,Binary operation: ([-oo, +oo] - 1):signed32 by call to `ral_good` ]
codetoanalyze/cpp/bufferoverrun/simple_vector.cpp, my_vector_oob_Bad, 2, BUFFER_OVERRUN_L2, no_bucket, ERROR, [Parameter `v->_size`,Call,<Offset trace>,Parameter `i`,<Length trace>,Parameter `this->_size`,Array declaration,Assignment,Array access: Offset: v->_size Size: v->_size by call to `int_vector::access_at` ] codetoanalyze/cpp/bufferoverrun/simple_vector.cpp, my_vector_oob_Bad, 2, BUFFER_OVERRUN_L2, no_bucket, ERROR, [Parameter `v->_size`,Call,<Offset trace>,Parameter `i`,<Length trace>,Parameter `this->_size`,Array declaration,Assignment,Array access: Offset: v->_size Size: v->_size by call to `int_vector::access_at` ]
codetoanalyze/cpp/bufferoverrun/smart_ptr.cpp, smart_ptr::call_method_Bad, 3, BUFFER_OVERRUN_L1, no_bucket, ERROR, [Call,Parameter `n`,Assignment,Call,<Offset trace>,Parameter `this->i`,<Length trace>,Array declaration,Array access: Offset: 8 Size: 5 by call to `smart_ptr::my_class::array_access` ] codetoanalyze/cpp/bufferoverrun/smart_ptr.cpp, smart_ptr::call_method_Bad, 3, BUFFER_OVERRUN_L1, no_bucket, ERROR, [Call,Parameter `n`,Assignment,Call,<Offset trace>,Parameter `this->i`,<Length trace>,Array declaration,Array access: Offset: 8 Size: 5 by call to `smart_ptr::my_class::array_access` ]

@ -251,7 +251,7 @@ class ArrayListTest {
ArrayList<Integer> unknown_array_list1; ArrayList<Integer> unknown_array_list1;
ArrayList<Integer> unknown_array_list2; ArrayList<Integer> unknown_array_list2;
void loop_on_unknown_iterator(MyI x, int j) { void loop_on_unknown_iterator_FN(MyI x, int j) {
ArrayList<Integer> a = new ArrayList<>(); ArrayList<Integer> a = new ArrayList<>();
ArrayList<Integer> b; ArrayList<Integer> b;
if (unknown_bool) { if (unknown_bool) {
@ -264,8 +264,7 @@ class ArrayListTest {
// precision with introducing a lot of FPs. To avoie that, we ignore the size of `Unknown` // precision with introducing a lot of FPs. To avoie that, we ignore the size of `Unknown`
// array list here, instead we get some FNs. // array list here, instead we get some FNs.
for (Integer i : b) { for (Integer i : b) {
// `a.size()` is evaluated to bottom, rather than [0,+oo] here, but which does not make // Since size of `b` is evaluted to [0,0], here is unreachable.
// branches unreachable.
if (a.size() <= -1) { if (a.size() <= -1) {
int[] c = new int[5]; int[] c = new int[5];
c[5] = 0; c[5] = 0;

@ -20,9 +20,8 @@ codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.add_in_loop_i
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alias_join_bad():void, 12, CONDITION_ALWAYS_TRUE, no_bucket, WARNING, [Here] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alias_join_bad():void, 12, CONDITION_ALWAYS_TRUE, no_bucket, WARNING, [Here]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alias_join_bad():void, 13, BUFFER_OVERRUN_L3, no_bucket, ERROR, [<Length trace>,Array declaration,Array access: Offset: 0 Size: [0, 2]] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alias_join_bad():void, 13, BUFFER_OVERRUN_L3, no_bucket, ERROR, [<Length trace>,Array declaration,Array access: Offset: 0 Size: [0, 2]]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alloc_is_negative_bad():void, 2, INFERBO_ALLOC_IS_NEGATIVE, no_bucket, ERROR, [Allocation: Length: -1] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.alloc_is_negative_bad():void, 2, INFERBO_ALLOC_IS_NEGATIVE, no_bucket, ERROR, [Allocation: Length: -1]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.loop_on_unknown_iterator(ArrayListTest$MyI,int):void, 12, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: ArrayList ArrayListTest$MyI.mk_unknown(),Assignment,Array access: Offset: [-oo, +oo] Size: [0, +oo]] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.loop_on_unknown_iterator_FN(ArrayListTest$MyI,int):void, 12, BUFFER_OVERRUN_U5, no_bucket, ERROR, [<Length trace>,Unknown value from: ArrayList ArrayListTest$MyI.mk_unknown(),Assignment,Array access: Offset: [-oo, +oo] Size: [0, +oo]]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.loop_on_unknown_iterator(ArrayListTest$MyI,int):void, 17, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Length trace>,Array declaration,Array access: Offset: 5 Size: 5] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.loop_on_unknown_iterator_FN(ArrayListTest$MyI,int):void, 12, CONDITION_ALWAYS_FALSE, no_bucket, WARNING, [Here]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.loop_on_unknown_iterator(ArrayListTest$MyI,int):void, 20, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Length trace>,Array declaration,Array access: Offset: 10 Size: 10]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.multi_adds_in_loop_iterator_bad(java.util.ArrayList):void, 8, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `b.elements[*]`,Assignment,<Length trace>,Array declaration,Array access: Offset: b.length + 1 Size: b.length] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.multi_adds_in_loop_iterator_bad(java.util.ArrayList):void, 8, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `b.elements[*]`,Assignment,<Length trace>,Array declaration,Array access: Offset: b.length + 1 Size: b.length]
codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.remove_in_loop_iterator_good_FP(java.util.ArrayList):void, 14, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `b.elements[*]`,Assignment,<Length trace>,Parameter `b.elements[*]`,Array access: Offset: b.length Size: b.length] codetoanalyze/java/bufferoverrun/ArrayListTest.java, ArrayListTest.remove_in_loop_iterator_good_FP(java.util.ArrayList):void, 14, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `b.elements[*]`,Assignment,<Length trace>,Parameter `b.elements[*]`,Array access: Offset: b.length Size: b.length]
codetoanalyze/java/bufferoverrun/ArrayMember.java, codetoanalyze.java.bufferoverrun.ArrayMember.load_array_member_Bad():void, 4, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `this.buf[*]`,Assignment,<Length trace>,Array declaration,Array access: Offset: [max(10, this.buf[*].lb), min(10, this.buf[*].ub)] Size: 10] codetoanalyze/java/bufferoverrun/ArrayMember.java, codetoanalyze.java.bufferoverrun.ArrayMember.load_array_member_Bad():void, 4, BUFFER_OVERRUN_L1, no_bucket, ERROR, [<Offset trace>,Parameter `this.buf[*]`,Assignment,<Length trace>,Array declaration,Array access: Offset: [max(10, this.buf[*].lb), min(10, this.buf[*].ub)] Size: 10]

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