Extend Sizeof with final extensible array length

Summary:
This diff extends Sizeof expressions with an optional expression for the
length of the final extensible array, if any.  For example, sizeof a
simple array `sizeof(t[n])` is represented by (modulo subtyping info)
`Sizeof t (Some n)`, and sizeof a struct whose final member is an array
`sizeof(struct s {... t[n] f})` is represented by `Sizeof (struct s
{... t[n] f}) (Some n)`.

This is an intermediate step toward eliminating expressions from types,
the redundancy between the length in the types and in the sizeof
expressions will be eliminated later.

Reviewed By: cristianoc

Differential Revision: D3358763

fbshipit-source-id: 2239bca
master
Josh Berdine 9 years ago committed by Facebook Github Bot 6
parent 5ed970efa9
commit a85a88d145

@ -657,7 +657,7 @@ type dexp =
| Darray of dexp dexp
| Dbinop of binop dexp dexp
| Dconst of const
| Dsizeof of typ Subtype.t
| Dsizeof of typ (option exp) Subtype.t
| Dderef of dexp
| Dfcall of dexp (list dexp) Location.t call_flags
| Darrow of dexp Ident.fieldname
@ -769,8 +769,10 @@ and exp =
| Lfield of exp Ident.fieldname typ
/** An array index offset: [exp1\[exp2\]] */
| Lindex of exp exp
/** A sizeof expression */
| Sizeof of typ Subtype.t;
/** A sizeof expression. [Sizeof typ (Some len)] represents the size of a value of type [typ]
which ends in an extensible array of length [len]. The lengths in [Tarray] record the
statically determined lengths, while the lengths in [Sizeof] record the dynamic lengths. */
| Sizeof of typ (option exp) Subtype.t;
/** Kind of prune instruction */
@ -937,7 +939,7 @@ let is_objc_ref_counter_field (fld, _, a) =>
let has_objc_ref_counter hpred =>
switch hpred {
| Hpointsto _ _ (Sizeof (Tstruct struct_typ) _) =>
| Hpointsto _ _ (Sizeof (Tstruct struct_typ) _ _) =>
IList.exists is_objc_ref_counter_field struct_typ.instance_fields
| _ => false
};
@ -1642,13 +1644,18 @@ and exp_compare (e1: exp) (e2: exp) :int =>
}
| (Lindex _, _) => (-1)
| (_, Lindex _) => 1
| (Sizeof t1 s1, Sizeof t2 s2) =>
| (Sizeof t1 l1 s1, Sizeof t2 l2 s2) =>
let n = typ_compare t1 t2;
if (n != 0) {
n
} else {
let n = opt_compare exp_compare l1 l2;
if (n != 0) {
n
} else {
Subtype.compare s1 s2
}
}
};
let const_equal c1 c2 => const_compare c1 c2 == 0;
@ -2190,7 +2197,7 @@ let rec dexp_to_string =
ampersand ^ s
}
| Dunop op de => str_unop op ^ dexp_to_string de
| Dsizeof typ _ => pp_to_string (pp_typ_full pe_text) typ
| Dsizeof typ _ _ => pp_to_string (pp_typ_full pe_text) typ
| Dunknown => "unknown"
| Dretcall de _ _ _ => "returned by " ^ dexp_to_string de
/** Pretty print a dexp. */
@ -2397,7 +2404,9 @@ and _pp_exp pe0 pp_t f e0 => {
| Lvar pv => Pvar.pp pe f pv
| Lfield e fld _ => F.fprintf f "%a.%a" pp_exp e Ident.pp_fieldname fld
| Lindex e1 e2 => F.fprintf f "%a[%a]" pp_exp e1 pp_exp e2
| Sizeof t s => F.fprintf f "sizeof(%a%a)" pp_t t Subtype.pp s
| Sizeof t l s =>
let pp_len f l => Option.map_default (F.fprintf f "[%a]" pp_exp) () l;
F.fprintf f "sizeof(%a%a%a)" pp_t t pp_len l Subtype.pp s
}
};
color_post_wrapper changed pe0 f
@ -2434,14 +2443,20 @@ let d_exp_list (el: list exp) => L.add_print_action (L.PTexp_list, Obj.repr el);
let pp_texp pe f =>
fun
| Sizeof t s => F.fprintf f "%a%a" (pp_typ pe) t Subtype.pp s
| Sizeof t l s => {
let pp_len f l => Option.map_default (F.fprintf f "[%a]" (pp_exp pe)) () l;
F.fprintf f "%a%a%a" (pp_typ pe) t pp_len l Subtype.pp s
}
| e => (pp_exp pe) f e;
/** Pretty print a type with all the details. */
let pp_texp_full pe f =>
fun
| Sizeof t s => F.fprintf f "%a%a" (pp_typ_full pe) t Subtype.pp s
| Sizeof t l s => {
let pp_len f l => Option.map_default (F.fprintf f "[%a]" (pp_exp pe)) () l;
F.fprintf f "%a%a%a" (pp_typ_full pe) t pp_len l Subtype.pp s
}
| e => (_pp_exp pe) (pp_typ_full pe) f e;
@ -3290,7 +3305,7 @@ let unsome_typ s =>
If not a sizeof, return the default type if given, otherwise raise an exception */
let texp_to_typ default_opt =>
fun
| Sizeof t _ => t
| Sizeof t _ _ => t
| _ => unsome_typ "texp_to_typ" default_opt;
@ -3416,7 +3431,10 @@ let rec exp_fpv =
| Lvar name => [name]
| Lfield e _ _ => exp_fpv e
| Lindex e1 e2 => exp_fpv e1 @ exp_fpv e2
| Sizeof _ => []
/* TODO: Sizeof length expressions may contain variables, do not ignore them. */
/* | Sizeof _ None _ => [] */
/* | Sizeof _ (Some l) _ => exp_fpv l */
| Sizeof _ _ _ => []
and exp_list_fpv el => IList.flatten (IList.map exp_fpv el);
let atom_fpv =
@ -3611,7 +3629,10 @@ let rec exp_fav_add fav =>
exp_fav_add fav e1;
exp_fav_add fav e2
}
| Sizeof _ => ();
/* TODO: Sizeof length expressions may contain variables, do not ignore them. */
/* | Sizeof _ None _ => () */
/* | Sizeof _ (Some l) _ => exp_fav_add fav l; */
| Sizeof _ _ _ => ();
let exp_fav = fav_imperative_to_functional exp_fav_add;
@ -4051,7 +4072,7 @@ and exp_sub (subst: subst) e =>
let e1' = exp_sub subst e1;
let e2' = exp_sub subst e2;
Lindex e1' e2'
| Sizeof t s => Sizeof (typ_sub subst t) s
| Sizeof t l s => Sizeof (typ_sub subst t) (Option.map (exp_sub subst) l) s
};
let instr_sub (subst: subst) instr => {
@ -4599,8 +4620,11 @@ let exp_get_vars exp => {
(fun vars_acc (captured_exp, _, _) => exp_get_vars_ captured_exp vars_acc)
vars
captured_vars
| Const (Cint _ | Cfun _ | Cstr _ | Cfloat _ | Cattribute _ | Cclass _ | Cptr_to_fld _)
| Sizeof _ => vars
| Const (Cint _ | Cfun _ | Cstr _ | Cfloat _ | Cattribute _ | Cclass _ | Cptr_to_fld _) => vars
/* TODO: Sizeof length expressions may contain variables, do not ignore them. */
/* | Sizeof _ None _ => vars */
/* | Sizeof _ (Some l) _ => exp_get_vars_ l vars */
| Sizeof _ _ _ => vars
};
exp_get_vars_ exp ([], [])
};
@ -4615,7 +4639,8 @@ let exp_get_offsets exp => {
| UnOp _
| BinOp _
| Lvar _
| Sizeof _ => offlist_past
| Sizeof _ None _ => offlist_past
| Sizeof _ (Some l) _ => f offlist_past l
| Cast _ sub_exp => f offlist_past sub_exp
| Lfield sub_exp fldname typ => f [Off_fld fldname typ, ...offlist_past] sub_exp
| Lindex sub_exp e => f [Off_index e, ...offlist_past] sub_exp

@ -230,7 +230,7 @@ type dexp =
| Darray of dexp dexp
| Dbinop of binop dexp dexp
| Dconst of const
| Dsizeof of typ Subtype.t
| Dsizeof of typ (option exp) Subtype.t
| Dderef of dexp
| Dfcall of dexp (list dexp) Location.t call_flags
| Darrow of dexp Ident.fieldname
@ -343,7 +343,7 @@ and exp =
/** An array index offset: [exp1\[exp2\]] */
| Lindex of exp exp
/** A sizeof expression */
| Sizeof of typ Subtype.t;
| Sizeof of typ (option exp) Subtype.t;
let struct_typ_equal: struct_typ => struct_typ => bool;
@ -539,7 +539,7 @@ type strexp =
and hpred =
| Hpointsto of exp strexp exp
/** represents [exp|->strexp:typexp] where [typexp]
is an expression representing a type, e.h. [sizeof(t)]. */
is an expression representing a type, e.g. [sizeof(t)]. */
| Hlseg of lseg_kind hpara exp exp (list exp)
/** higher - order predicate for singly - linked lists.
Should ensure that exp1!= exp2 implies that exp1 is allocated.

@ -420,7 +420,7 @@ let typ_get_recursive_flds tenv typ_exp =
false
in
match typ_exp with
| Sil.Sizeof (typ, _) ->
| Sil.Sizeof (typ, _, _) ->
(match Tenv.expand_type tenv typ with
| Sil.Tint _ | Sil.Tvoid | Sil.Tfun _ | Sil.Tptr _ | Sil.Tfloat _ -> []
| Sil.Tstruct { Sil.instance_fields } ->
@ -903,14 +903,14 @@ let get_cycle root prop =
let visited' = (fst et_src):: visited in
let res = (match get_points_to e with
| None -> path, false
| Some (Sil.Hpointsto(_, Sil.Estruct(fl, _), Sil.Sizeof(te, _))) ->
| Some (Sil.Hpointsto(_, Sil.Estruct(fl, _), Sil.Sizeof(te, _, _))) ->
dfs e_root (e, te) ((et_src, f, e):: path) fl visited'
| _ -> path, false (* check for lists *)) in
if snd res then res
else dfs e_root et_src path el' visited') in
L.d_strln "Looking for cycle with root expression: "; Sil.d_hpred root; L.d_strln "";
match root with
| Sil.Hpointsto(e_root, Sil.Estruct(fl, _), Sil.Sizeof(te, _)) ->
| Sil.Hpointsto(e_root, Sil.Estruct(fl, _), Sil.Sizeof(te, _, _)) ->
let se_root = Sil.Eexp(e_root, Sil.Inone) in
(* start dfs with empty path and expr pointing to root *)
let (pot_cycle, res) = dfs se_root (se_root, te) [] fl [] in
@ -929,7 +929,7 @@ let get_cycle root prop =
let should_raise_objc_leak hpred =
match hpred with
| Sil.Hpointsto(_, Sil.Estruct((fn, Sil.Eexp( (Sil.Const (Sil.Cint i)), _)):: _, _),
Sil.Sizeof (typ, _))
Sil.Sizeof (typ, _, _))
when Ident.fieldname_is_hidden fn && Sil.Int.gt i Sil.Int.zero (* counter > 0 *) ->
Mleak_buckets.should_raise_objc_leak typ
| _ -> None
@ -949,7 +949,7 @@ let get_var_retain_cycle _prop =
| _ -> false in
let is_hpred_block v h =
match h, v with
| Sil.Hpointsto (e, _, Sil.Sizeof(typ, _)), Sil.Eexp (e', _)
| Sil.Hpointsto (e, _, Sil.Sizeof(typ, _, _)), Sil.Eexp (e', _)
when Sil.exp_equal e e' && Sil.is_block_type typ -> true
| _, _ -> false in
let find v =
@ -967,7 +967,7 @@ let get_var_retain_cycle _prop =
| Some pvar -> [((sexp pvar, t), f, e')]
| _ -> (match find_block e with
| Some blk -> [((sexp blk, t), f, e')]
| _ -> [((sexp (Sil.Sizeof(t, Sil.Subtype.exact)), t), f, e')]) in
| _ -> [((sexp (Sil.Sizeof (t, None, Sil.Subtype.exact)), t), f, e')]) in
(* returns the pvars of the first cycle we find in sigma. *)
(* This is an heuristic that works if there is one cycle. *)
(* In case there are more than one cycle we may return not necessarily*)

@ -332,7 +332,7 @@ let create_idmap sigma : idmap =
extend_idmap id { typ = t; alloc = true } idmap
| _ -> () in
let do_hpred = function
| Sil.Hpointsto (e, se, Sil.Sizeof (typ, _)) ->
| Sil.Hpointsto (e, se, Sil.Sizeof (typ, _, _)) ->
do_lhs_e e (Sil.Tptr (typ, Sil.Pk_pointer));
do_se se typ
| Sil.Hlseg (_, _, e, f, el) ->
@ -427,7 +427,7 @@ let pp_texp_for_malloc fmt =
| Sil.Tarray (t, e) ->
Sil.Tarray (handle_arr_size t, e) in
function
| Sil.Sizeof (typ, _) ->
| Sil.Sizeof (typ, _, _) ->
let typ' = handle_arr_size typ in
F.fprintf fmt "sizeof(%a)" (pp_typ_c pe) typ'
| e -> pp_exp_c pe fmt e

@ -821,8 +821,10 @@ let rec exp_construct_fresh side e =
let e1' = exp_construct_fresh side e1 in
let e2' = exp_construct_fresh side e2 in
Sil.Lindex(e1', e2')
| Sil.Sizeof _ ->
| Sil.Sizeof (_, None, _) ->
e
| Sil.Sizeof (typ, Some len, st) ->
Sil.Sizeof (typ, Some (exp_construct_fresh side len), st)
let strexp_construct_fresh side =
let f (e, inst_opt) = (exp_construct_fresh side e, inst_opt) in
@ -948,12 +950,18 @@ let rec exp_partial_join (e1: Sil.exp) (e2: Sil.exp) : Sil.exp =
let e1'' = exp_partial_join e1 e2 in
let e2'' = exp_partial_join e1' e2' in
Sil.Lindex(e1'', e2'')
| Sil.Sizeof (t1, st1), Sil.Sizeof (t2, st2) ->
Sil.Sizeof (typ_partial_join t1 t2, Sil.Subtype.join st1 st2)
| Sil.Sizeof (t1, len1, st1), Sil.Sizeof (t2, len2, st2) ->
Sil.Sizeof (typ_partial_join t1 t2, len_partial_join len1 len2, Sil.Subtype.join st1 st2)
| _ ->
L.d_str "exp_partial_join no match "; Sil.d_exp e1; L.d_str " "; Sil.d_exp e2; L.d_ln ();
raise IList.Fail
and len_partial_join len1 len2 =
match len1, len2 with
| None, _ -> len2
| _, None -> len1
| Some len1, Some len2 -> Some (size_partial_join len1 len2)
and size_partial_join size1 size2 = match size1, size2 with
| Sil.BinOp(Sil.PlusA, e1, Sil.Const c1), Sil.BinOp(Sil.PlusA, e2, Sil.Const c2) ->
let e' = exp_partial_join e1 e2 in

@ -294,7 +294,7 @@ let rec dotty_mk_node pe sigma =
let n = !dotty_state_count in
incr dotty_state_count;
let do_hpred_lambda exp_color = function
| (Sil.Hpointsto (e, Sil.Earray(e', l, _), Sil.Sizeof(Sil.Tarray(t, _), _)), lambda) ->
| (Sil.Hpointsto (e, Sil.Earray (e', l, _), Sil.Sizeof (Sil.Tarray(t, _), _, _)), lambda) ->
incr dotty_state_count; (* increment once more n+1 is the box for the array *)
let e_color_str = color_to_str (exp_color e) in
let e_color_str'= color_to_str (exp_color e') in
@ -673,7 +673,7 @@ let filter_useless_spec_dollar_box (nodes: dotty_node list) (links: link list) =
(* print a struct node *)
let rec print_struct f pe e te l coo c =
let print_type = match te with
| Sil.Sizeof (t, _) ->
| Sil.Sizeof (t, _, _) ->
let str_t = Sil.typ_to_string t in
(match Str.split_delim (Str.regexp_string Config.anonymous_block_prefix) str_t with
| [_; _] -> "BLOCK object"

@ -388,9 +388,9 @@ and _exp_rv_dexp (_seen : Sil.ExpSet.t) node e : Sil.dexp option =
| Sil.Cast (_, e1) ->
if verbose then (L.d_str "exp_rv_dexp: Cast "; Sil.d_exp e; L.d_ln ());
_exp_rv_dexp seen node e1
| Sil.Sizeof (typ, sub) ->
| Sil.Sizeof (typ, len, sub) ->
if verbose then (L.d_str "exp_rv_dexp: type "; Sil.d_exp e; L.d_ln ());
Some (Sil.Dsizeof (typ, sub))
Some (Sil.Dsizeof (typ, len, sub))
| _ ->
if verbose then (L.d_str "exp_rv_dexp: no match for "; Sil.d_exp e; L.d_ln ());
None
@ -497,12 +497,12 @@ let explain_leak tenv hpred prop alloc_att_opt bucket =
(Pvar.is_local pvar || Pvar.is_global pvar) &&
not (pvar_is_frontend_tmp pvar) &&
match hpred_typ_opt, find_typ_without_ptr prop pvar with
| Some (Sil.Sizeof (t1, _)), Some (Sil.Sizeof (Sil.Tptr (_t2, _), _)) ->
| Some (Sil.Sizeof (t1, _, _)), Some (Sil.Sizeof (Sil.Tptr (t2_, _), _, _)) ->
(try
let t2 = Tenv.expand_type tenv _t2 in
let t2 = Tenv.expand_type tenv t2_ in
Sil.typ_equal t1 t2
with exn when SymOp.exn_not_failure exn -> false)
| Some (Sil.Sizeof (Sil.Tint _, _)), Some (Sil.Sizeof (Sil.Tint _, _))
| Some (Sil.Sizeof (Sil.Tint _, _, _)), Some (Sil.Sizeof (Sil.Tint _, _, _))
when is_file -> (* must be a file opened with "open" *)
true
| _ -> false in
@ -570,7 +570,7 @@ let vpath_find prop _exp : Sil.dexp option * Sil.typ option =
(match lexp with
| Sil.Lvar pv ->
let typo = match texp with
| Sil.Sizeof (Sil.Tstruct struct_typ, _) ->
| Sil.Sizeof (Sil.Tstruct struct_typ, _, _) ->
(try
let _, t, _ =
IList.find (fun (f', _, _) ->
@ -596,7 +596,7 @@ let vpath_find prop _exp : Sil.dexp option * Sil.typ option =
(match lexp with
| Sil.Lvar pv when not (pvar_is_frontend_tmp pv) ->
let typo = match texp with
| Sil.Sizeof (typ, _) -> Some typ
| Sil.Sizeof (typ, _, _) -> Some typ
| _ -> None in
Some (Sil.Dpvar pv), typo
| Sil.Var id ->

@ -28,6 +28,11 @@ let sort = List.sort
let stable_sort = List.stable_sort
let tl = List.tl
let rec last = function
| [] -> invalid_arg "IList.last"
| [x] -> x
| _ :: xs -> last xs
(** tail-recursive variant of List.fold_right *)
let fold_right f l a =
let g x y = f y x in

@ -64,6 +64,9 @@ val split : ('a * 'b) list -> 'a list * 'b list
val stable_sort : ('a -> 'a -> int) -> 'a list -> 'a list
val tl : 'a list -> 'a list
(** last element, raises invalid_arg if empty *)
val last : 'a list -> 'a
(* Drops the first n elements from a list. *)
val drop_first : int -> 'a list -> 'a list

@ -640,7 +640,7 @@ let report_context_leaks pname sigma tenv =
let context_exps =
IList.fold_left
(fun exps hpred -> match hpred with
| Sil.Hpointsto (_, Eexp (exp, _), Sizeof (Tptr (Tstruct struct_typ, _), _))
| Sil.Hpointsto (_, Eexp (exp, _), Sizeof (Tptr (Tstruct struct_typ, _), _, _))
when AndroidFramework.is_context tenv struct_typ &&
not (AndroidFramework.is_application tenv struct_typ) ->
(exp, struct_typ) :: exps
@ -807,8 +807,8 @@ let prop_init_formals_seed tenv new_formals (prop : 'a Prop.t) : Prop.exposed Pr
let sigma_new_formals =
let do_formal (pv, typ) =
let texp = match !Config.curr_language with
| Config.Clang -> Sil.Sizeof (typ, Sil.Subtype.exact)
| Config.Java -> Sil.Sizeof (typ, Sil.Subtype.subtypes) in
| Config.Clang -> Sil.Sizeof (typ, None, Sil.Subtype.exact)
| Config.Java -> Sil.Sizeof (typ, None, Sil.Subtype.subtypes) in
Prop.mk_ptsto_lvar (Some tenv) Prop.Fld_init Sil.inst_formal (pv, texp, None) in
IList.map do_formal new_formals in
let sigma_seed =

@ -687,7 +687,7 @@ let desc_leak hpred_type_opt value_str_opt resource_opt resource_action_opt loc
| Some (Sil.Sizeof (Sil.Tstruct
{ Sil.csu = Csu.Class _;
Sil.struct_name = Some classname;
}, _)) ->
}, _, _)) ->
" of type " ^ Mangled.to_string classname ^ " "
| _ -> " " in
let desc_str =
@ -772,7 +772,7 @@ let desc_retain_cycle prop cycle loc cycle_dotty =
else e_str in
str_cycle:=!str_cycle^" ("^(string_of_int !ct)^") object "^e_str^" retaining "^e_str^"."^(Ident.fieldname_to_string f)^", ";
ct:=!ct +1
| Sil.Eexp(Sil.Sizeof(typ, _), _) ->
| Sil.Eexp (Sil.Sizeof (typ, _, _), _) ->
str_cycle:=!str_cycle^" ("^(string_of_int !ct)^") an object of "^(Sil.typ_to_string typ)^" retaining another object via instance variable "^(Ident.fieldname_to_string f)^", ";
ct:=!ct +1
| _ -> () in

@ -76,7 +76,8 @@ let add_array_to_prop pdesc prop_ lexp typ =
let size = Sil.Var(Ident.create_fresh Ident.kfootprint) in
let s = mk_empty_array_rearranged size in
let hpred =
Prop.mk_ptsto n_lexp s (Sil.Sizeof(Sil.Tarray(typ', size), Sil.Subtype.exact)) in
Prop.mk_ptsto n_lexp s
(Sil.Sizeof (Sil.Tarray (typ', size), None, Sil.Subtype.exact)) in
let sigma = Prop.get_sigma prop in
let sigma_fp = Prop.get_sigma_footprint prop in
let prop'= Prop.replace_sigma (hpred:: sigma) prop in
@ -157,13 +158,13 @@ let create_type tenv n_lexp typ prop =
| Sil.Tptr (typ', _) ->
let sexp = Sil.Estruct ([], Sil.inst_none) in
let typ'' = Tenv.expand_type tenv typ' in
let texp = Sil.Sizeof (typ'', Sil.Subtype.subtypes) in
let texp = Sil.Sizeof (typ'', None, Sil.Subtype.subtypes) in
let hpred = Prop.mk_ptsto n_lexp sexp texp in
Some hpred
| Sil.Tarray _ ->
let size = Sil.Var(Ident.create_fresh Ident.kfootprint) in
let sexp = mk_empty_array size in
let texp = Sil.Sizeof (typ, Sil.Subtype.subtypes) in
let texp = Sil.Sizeof (typ, None, Sil.Subtype.subtypes) in
let hpred = Prop.mk_ptsto n_lexp sexp texp in
Some hpred
| _ -> None in
@ -569,7 +570,7 @@ let execute___release_autorelease_pool
| Sil.Hpointsto(e1, _, _) -> Sil.exp_equal e1 exp
| _ -> false) (Prop.get_sigma prop_) in
match hpred with
| Sil.Hpointsto(_, _, Sil.Sizeof (typ, _)) ->
| Sil.Hpointsto (_, _, Sil.Sizeof (typ, _, _)) ->
let res1 =
execute___objc_release
{ builtin_args with
@ -668,7 +669,7 @@ let execute___objc_cast { Builtin.pdesc; prop_; path; ret_ids; args; }
| Sil.Hpointsto(e1, _, _) -> Sil.exp_equal e1 val1
| _ -> false) (Prop.get_sigma prop) in
match hpred, texp2 with
| Sil.Hpointsto(val1, _, _), Sil.Sizeof (_, _) ->
| Sil.Hpointsto (val1, _, _), Sil.Sizeof _ ->
let prop' = replace_ptsto_texp prop val1 texp2 in
[(return_result val1 prop' ret_ids, path)]
| _ -> [(return_result val1 prop ret_ids, path)]
@ -760,19 +761,22 @@ let execute_alloc mk can_return_null
| Sil.BinOp (bop, e1', e2') ->
Sil.BinOp (bop, evaluate_char_sizeof e1', evaluate_char_sizeof e2')
| Sil.Const _ | Sil.Cast _ | Sil.Lvar _ | Sil.Lfield _ | Sil.Lindex _ -> e
| Sil.Sizeof (Sil.Tarray(Sil.Tint ik, size), _) when Sil.ikind_is_char ik ->
evaluate_char_sizeof size
| Sil.Sizeof (Sil.Tarray (Sil.Tint ik, _), Some len, _) when Sil.ikind_is_char ik ->
evaluate_char_sizeof len
| Sil.Sizeof (Sil.Tarray (Sil.Tint ik, len), None, _) when Sil.ikind_is_char ik ->
evaluate_char_sizeof len
| Sil.Sizeof _ -> e in
let handle_sizeof_exp size_exp =
Sil.Sizeof (Sil.Tarray (Sil.Tint Sil.IChar, size_exp), Sil.Subtype.exact) in
let handle_sizeof_exp len =
Sil.Sizeof (Sil.Tarray (Sil.Tint Sil.IChar, len), Some len, Sil.Subtype.exact) in
let size_exp, procname = match args with
| [(Sil.Sizeof (Sil.Tstruct
{ Sil.csu = Csu.Class Csu.Objc; struct_name = Some c } as s, subt), _)] ->
| [(Sil.Sizeof
(Sil.Tstruct
{ Sil.csu = Csu.Class Csu.Objc; struct_name = Some c } as s, len, subt), _)] ->
let struct_type =
match AttributesTable.get_correct_type_from_objc_class_name c with
| Some struct_type -> struct_type
| None -> s in
Sil.Sizeof (struct_type, subt), pname
Sil.Sizeof (struct_type, len, subt), pname
| [(size_exp, _)] -> (* for malloc and __new *)
size_exp, Sil.mem_alloc_pname mk
| [(size_exp, _); (Sil.Const (Sil.Cfun pname), _)] ->
@ -822,7 +826,7 @@ let execute___cxx_typeid ({ Builtin.pdesc; tenv; prop_; args; loc} as r)
| Sil.Hpointsto (e, _, _) -> Sil.exp_equal e n_lexp
| _ -> false) (Prop.get_sigma prop) in
match hpred with
| Sil.Hpointsto (_, _, Sil.Sizeof (dynamic_type, _)) -> dynamic_type
| Sil.Hpointsto (_, _, Sil.Sizeof (dynamic_type, _, _)) -> dynamic_type
| _ -> typ
with Not_found -> typ in
let typ_string = Sil.typ_to_string typ in
@ -1157,7 +1161,7 @@ let execute_objc_alloc_no_fail
{ Builtin.pdesc; tenv; ret_ids; loc; } =
let alloc_fun = Sil.Const (Sil.Cfun __objc_alloc_no_fail) in
let ptr_typ = Sil.Tptr (typ, Sil.Pk_pointer) in
let sizeof_typ = Sil.Sizeof (typ, Sil.Subtype.exact) in
let sizeof_typ = Sil.Sizeof (typ, None, Sil.Subtype.exact) in
let alloc_fun_exp =
match alloc_fun_opt with
| Some pname -> [Sil.Const (Sil.Cfun pname), Sil.Tvoid]

@ -456,9 +456,10 @@ let sym_eval abs e =
Sil.Const (Sil.Cclosure { c with captured_vars; })
| Sil.Const _ ->
e
| Sil.Sizeof (Sil.Tarray (Sil.Tint ik, e), _)
| Sil.Sizeof (Sil.Tarray (Sil.Tint ik, l), None, _)
| Sil.Sizeof (Sil.Tarray (Sil.Tint ik, _), Some l, _)
when Sil.ikind_is_char ik && !Config.curr_language <> Config.Java ->
eval e
eval l
| Sil.Sizeof _ ->
e
| Sil.Cast (_, e1) ->
@ -593,7 +594,7 @@ let sym_eval abs e =
eval (Sil.BinOp (Sil.PlusPI, e11, e2'))
| Sil.BinOp
(Sil.PlusA,
(Sil.Sizeof (Sil.Tstruct struct_typ, _) as e1),
(Sil.Sizeof (Sil.Tstruct struct_typ, None, _) as e1),
e2) ->
(* pattern for extensible structs given a struct declatead as struct s { ... t arr[n] ... },
allocation pattern malloc(sizeof(struct s) + k * siezof(t)) turn it into
@ -603,13 +604,13 @@ let sym_eval abs e =
let instance_fields = struct_typ.Sil.instance_fields in
(match IList.rev instance_fields, e2' with
(fname, Sil.Tarray (typ, size), _) :: ltfa,
Sil.BinOp(Sil.Mult, num_elem, Sil.Sizeof (texp, st))
Sil.BinOp(Sil.Mult, num_elem, Sil.Sizeof (texp, None, st))
when instance_fields != [] && Sil.typ_equal typ texp ->
let size' = Sil.BinOp(Sil.PlusA, size, num_elem) in
let ltfa' = (fname, Sil.Tarray(typ, size'), Sil.item_annotation_empty) :: ltfa in
let struct_typ' =
{ struct_typ with Sil.instance_fields = IList.rev ltfa' } in
Sil.Sizeof (Sil.Tstruct struct_typ', st)
Sil.Sizeof (Sil.Tstruct struct_typ', None, st)
| _ -> Sil.BinOp(Sil.PlusA, e1', e2'))
| Sil.BinOp (Sil.PlusA as oplus, e1, e2)
| Sil.BinOp (Sil.PlusPI as oplus, e1, e2) ->
@ -625,6 +626,19 @@ let sym_eval abs e =
| _ -> Sil.BinOp (ominus, x, y) in
begin
match e1', e2' with
| Sil.Sizeof (typ, Some len1, st),
Sil.BinOp (Sil.Mult, len2, Sil.Sizeof (elt, None, _))
when isPlusA
&& (match typ with
| Sil.Tarray (elt2, _) ->
Sil.typ_equal elt elt2
| Sil.Tstruct {instance_fields= _::_ as flds} ->
Sil.typ_equal elt (snd3 (IList.last flds))
| _ ->
false) ->
(* pattern for extensible structs:
sizeof(struct s {... t[l]}) + k * sizeof(elt)) = sizeof(struct s {... t[l + k]}) *)
Sil.Sizeof (typ, Some (len1 +++ len2), st)
| Sil.Const c, _ when iszero_int_float c ->
e2'
| _, Sil.Const c when iszero_int_float c ->
@ -691,13 +705,6 @@ let sym_eval abs e =
| Sil.BinOp (Sil.MinusPP, e1, e2) ->
if abs then Sil.exp_get_undefined false
else Sil.BinOp (Sil.MinusPP, eval e1, eval e2)
| Sil.BinOp (Sil.Mult, esize, Sil.Sizeof (t, st))
| Sil.BinOp(Sil.Mult, Sil.Sizeof (t, st), esize) ->
begin
match eval esize, eval (Sil.Sizeof (t, st)) with
| Sil.Const (Sil.Cint i), e' when Sil.Int.isone i -> e'
| esize', e' -> Sil.BinOp(Sil.Mult, esize', e')
end
| Sil.BinOp (Sil.Mult, e1, e2) ->
let e1' = eval e1 in
let e2' = eval e2 in
@ -721,6 +728,9 @@ let sym_eval abs e =
Sil.exp_float (v *. w)
| Sil.Var _, Sil.Var _ ->
Sil.BinOp(Sil.Mult, e1', e2')
| _, Sil.Sizeof _
| Sil.Sizeof _, _ ->
Sil.BinOp(Sil.Mult, e1', e2')
| _, _ ->
if abs then Sil.exp_get_undefined false else Sil.BinOp(Sil.Mult, e1', e2')
end
@ -739,10 +749,11 @@ let sym_eval abs e =
Sil.exp_int (Sil.Int.div n m)
| Sil.Const (Sil.Cfloat v), Sil.Const (Sil.Cfloat w) ->
Sil.exp_float (v /.w)
| Sil.Sizeof(Sil.Tarray(typ, size), _), Sil.Sizeof(_typ, _)
(* pattern: sizeof(arr) / sizeof(arr[0]) = size of arr *)
when Sil.typ_equal _typ typ ->
size
| Sil.Sizeof (Sil.Tarray (elt, _), Some len, _), Sil.Sizeof (elt2, None, _)
| Sil.Sizeof (Sil.Tarray (elt, len), None, _), Sil.Sizeof (elt2, None, _)
(* pattern: sizeof(elt[len]) / sizeof(elt) = len *)
when Sil.typ_equal elt elt2 ->
len
| _ ->
if abs then Sil.exp_get_undefined false else Sil.BinOp (Sil.Div, e1', e2')
end
@ -842,7 +853,8 @@ let exp_normalize sub exp =
else sym_eval false exp'
let rec texp_normalize sub exp = match exp with
| Sil.Sizeof (typ, st) -> Sil.Sizeof (typ_normalize sub typ, st)
| Sil.Sizeof (typ, len, st) ->
Sil.Sizeof (typ_normalize sub typ, Option.map (exp_normalize sub) len, st)
| _ -> exp_normalize sub exp
(* NOTE: usage of == operator in flds_norm and typ_normalize is intended*)
@ -1141,7 +1153,7 @@ let rec strexp_normalize sub se =
end
(** create a strexp of the given type, populating the structures if [expand_structs] is true *)
let rec create_strexp_of_type tenvo struct_init_mode typ inst =
let rec create_strexp_of_type tenvo struct_init_mode typ len inst =
let init_value () =
let create_fresh_var () =
let fresh_id =
@ -1154,24 +1166,30 @@ let rec create_strexp_of_type tenvo struct_init_mode typ inst =
| _ -> Sil.exp_zero
else
create_fresh_var () in
match typ with
| Sil.Tint _ | Sil.Tfloat _ | Sil.Tvoid | Sil.Tfun _ | Sil.Tptr _ ->
match typ, len with
| (Sil.Tint _ | Sil.Tfloat _ | Sil.Tvoid | Sil.Tfun _ | Sil.Tptr _), None ->
Sil.Eexp (init_value (), inst)
| Sil.Tstruct { Sil.instance_fields } ->
begin
| Sil.Tstruct { Sil.instance_fields }, _ -> (
match struct_init_mode with
| No_init -> Sil.Estruct ([], inst)
| No_init ->
Sil.Estruct ([], inst)
| Fld_init ->
let f (fld, t, a) =
(* pass len as an accumulator, so that it is passed to create_strexp_of_type for the last
field, but always return None so that only the last field receives len *)
let f (fld, t, a) (flds, len) =
if Sil.is_objc_ref_counter_field (fld, t, a) then
(fld, Sil.Eexp (Sil.exp_one, inst))
((fld, Sil.Eexp (Sil.exp_one, inst)) :: flds, None)
else
(fld, create_strexp_of_type tenvo struct_init_mode t inst) in
Sil.Estruct (IList.map f instance_fields, inst)
end
| Sil.Tarray (_, size) ->
((fld, create_strexp_of_type tenvo struct_init_mode t len inst) :: flds, None) in
let flds, _ = IList.fold_right f instance_fields ([], len) in
Sil.Estruct (flds, inst)
)
| Sil.Tarray (_, size), None ->
Sil.Earray (size, [], inst)
| Sil.Tvar _ ->
| Sil.Tarray _, Some len ->
Sil.Earray (len, [], inst)
| Sil.Tvar _, _
| (Sil.Tint _ | Sil.Tfloat _ | Sil.Tvoid | Sil.Tfun _ | Sil.Tptr _), Some _ ->
assert false
(** Sil.Construct a pointsto. *)
@ -1185,8 +1203,8 @@ let mk_ptsto lexp sexp te =
initialize the fields of structs with fresh variables. *)
let mk_ptsto_exp tenvo struct_init_mode (exp, te, expo) inst : Sil.hpred =
let default_strexp () = match te with
| Sil.Sizeof (typ, _) ->
create_strexp_of_type tenvo struct_init_mode typ inst
| Sil.Sizeof (typ, len, _) ->
create_strexp_of_type tenvo struct_init_mode typ len inst
| Sil.Var _ ->
Sil.Estruct ([], inst)
| te ->
@ -1214,19 +1232,24 @@ let rec hpred_normalize sub hpred =
let normalized_cnt = strexp_normalize sub cnt in
let normalized_te = texp_normalize sub te in
begin match normalized_cnt, normalized_te with
| Sil.Earray (Sil.Sizeof (t, st1), [], inst), Sil.Sizeof (Sil.Tarray _, _) ->
| Sil.Earray (Sil.Sizeof _ as size, [], inst), Sil.Sizeof (Sil.Tarray _, _, _) ->
(* check for an empty array whose size expression is (Sizeof type), and turn the array
into a strexp of the given type *)
let hpred' = mk_ptsto_exp None Fld_init (root, Sil.Sizeof (t, st1), None) inst in
let hpred' = mk_ptsto_exp None Fld_init (root, size, None) inst in
replace_hpred hpred'
| Sil.Earray (Sil.BinOp(Sil.Mult, Sil.Sizeof (t, st1), x), esel, inst),
Sil.Sizeof (Sil.Tarray _, _)
| Sil.Earray (Sil.BinOp(Sil.Mult, x, Sil.Sizeof (t, st1)), esel, inst),
Sil.Sizeof (Sil.Tarray _, _) ->
(* check for an array whose size expression is n * (Sizeof type), and turn the array
into a strexp of the given type *)
let hpred' =
mk_ptsto_exp None Fld_init (root, Sil.Sizeof (Sil.Tarray(t, x), st1), None) inst in
| ( Sil.Earray (Sil.BinOp (Sil.Mult, Sil.Sizeof (t, None, st1), x), esel, inst)
| Sil.Earray (Sil.BinOp (Sil.Mult, x, Sil.Sizeof (t, None, st1)), esel, inst)),
Sil.Sizeof (Sil.Tarray (elt, _) as arr, _, _)
when Sil.typ_equal t elt ->
let len = Some x in
let hpred' = mk_ptsto_exp None Fld_init (root, Sil.Sizeof (arr, len, st1), None) inst in
replace_hpred (replace_array_contents hpred' esel)
| ( Sil.Earray (Sil.BinOp (Sil.Mult, Sil.Sizeof (t, Some len, st1), x), esel, inst)
| Sil.Earray (Sil.BinOp (Sil.Mult, x, Sil.Sizeof (t, Some len, st1)), esel, inst)),
Sil.Sizeof (Sil.Tarray (elt, _) as arr, _, _)
when Sil.typ_equal t elt ->
let len = Some (Sil.BinOp(Sil.Mult, x, len)) in
let hpred' = mk_ptsto_exp None Fld_init (root, Sil.Sizeof (arr, len, st1), None) inst in
replace_hpred (replace_array_contents hpred' esel)
| _ -> Sil.Hpointsto (normalized_root, normalized_cnt, normalized_te)
end
@ -1337,7 +1360,8 @@ let rec pi_sorted_remove_redundant = function
let sigma_get_unsigned_exps sigma =
let uexps = ref [] in
let do_hpred = function
| Sil.Hpointsto(_, Sil.Eexp(e, _), Sil.Sizeof (Sil.Tint ik, _)) when Sil.ikind_is_unsigned ik ->
| Sil.Hpointsto (_, Sil.Eexp (e, _), Sil.Sizeof (Sil.Tint ik, _, _))
when Sil.ikind_is_unsigned ik ->
uexps := e :: !uexps
| _ -> () in
IList.iter do_hpred sigma;
@ -1622,13 +1646,13 @@ let get_fld_typ_path_opt src_exps snk_exp_ reachable_hpreds_ =
| (_, Sil.Eexp (e, _)) -> Sil.exp_equal target_exp e
| _ -> false in
let extend_path hpred (snk_exp, path, reachable_hpreds) = match hpred with
| Sil.Hpointsto (lhs, Sil.Estruct (flds, _), Sil.Sizeof (typ, _)) ->
| Sil.Hpointsto (lhs, Sil.Estruct (flds, _), Sil.Sizeof (typ, _, _)) ->
(try
let fld, _ = IList.find (fun fld -> strexp_matches snk_exp fld) flds in
let reachable_hpreds' = Sil.HpredSet.remove hpred reachable_hpreds in
(lhs, (Some fld, typ) :: path, reachable_hpreds')
with Not_found -> (snk_exp, path, reachable_hpreds))
| Sil.Hpointsto (lhs, Sil.Earray (_, elems, _), Sil.Sizeof (typ, _)) ->
| Sil.Hpointsto (lhs, Sil.Earray (_, elems, _), Sil.Sizeof (typ, _, _)) ->
if IList.exists (fun pair -> strexp_matches snk_exp pair) elems
then
let reachable_hpreds' = Sil.HpredSet.remove hpred reachable_hpreds in
@ -2039,7 +2063,8 @@ let find_arithmetic_problem proc_node_session prop exp =
| Sil.Lvar _ -> ()
| Sil.Lfield (e, _, _) -> walk e
| Sil.Lindex (e1, e2) -> walk e1; walk e2
| Sil.Sizeof _ -> () in
| Sil.Sizeof (_, None, _) -> ()
| Sil.Sizeof (_, Some len, _) -> walk len in
walk exp;
try Some (Div0 (IList.find check_zero !exps_divided)), !res
with Not_found ->
@ -2320,7 +2345,8 @@ let rec exp_captured_ren ren = function
| Sil.Var id -> Sil.Var (ident_captured_ren ren id)
| Sil.Const (Sil.Cexn e) -> Sil.Const (Sil.Cexn (exp_captured_ren ren e))
| Sil.Const _ as e -> e
| Sil.Sizeof (t, st) -> Sil.Sizeof (typ_captured_ren ren t, st)
| Sil.Sizeof (t, len, st) ->
Sil.Sizeof (typ_captured_ren ren t, Option.map (exp_captured_ren ren) len, st)
| Sil.Cast (t, e) -> Sil.Cast (t, exp_captured_ren ren e)
| Sil.UnOp (op, e, topt) ->
let topt' = match topt with

@ -221,7 +221,8 @@ val mk_neq : exp -> exp -> atom
val mk_eq : exp -> exp -> atom
(** create a strexp of the given type, populating the structures if [expand_structs] is true *)
val create_strexp_of_type: Tenv.t option -> struct_init_mode -> Sil.typ -> Sil.inst -> Sil.strexp
val create_strexp_of_type :
Tenv.t option -> struct_init_mode -> Sil.typ -> Sil.exp option -> Sil.inst -> Sil.strexp
(** Construct a pointsto. *)
val mk_ptsto : exp -> strexp -> exp -> hpred

@ -371,7 +371,7 @@ end = struct
let add_lt_minus1_e e =
lts := (Sil.exp_minus_one, e)::!lts in
let texp_is_unsigned = function
| Sil.Sizeof (Sil.Tint ik, _) -> Sil.ikind_is_unsigned ik
| Sil.Sizeof (Sil.Tint ik, _, _) -> Sil.ikind_is_unsigned ik
| _ -> false in
let strexp_lt_minus1 = function
| Sil.Eexp (e, _) -> add_lt_minus1_e e
@ -415,7 +415,8 @@ end = struct
(* L.d_str "check_le "; Sil.d_exp e1; L.d_str " "; Sil.d_exp e2; L.d_ln (); *)
match e1, e2 with
| Sil.Const (Sil.Cint n1), Sil.Const (Sil.Cint n2) -> Sil.Int.leq n1 n2
| Sil.BinOp (Sil.MinusA, Sil.Sizeof (t1, _), Sil.Sizeof (t2, _)), Sil.Const(Sil.Cint n2)
| Sil.BinOp (Sil.MinusA, Sil.Sizeof (t1, None, _), Sil.Sizeof (t2, None, _)),
Sil.Const(Sil.Cint n2)
when Sil.Int.isminusone n2 && type_size_comparable t1 t2 -> (* [ sizeof(t1) - sizeof(t2) <= -1 ] *)
check_type_size_lt t1 t2
| e, Sil.Const (Sil.Cint n) -> (* [e <= n' <= n |- e <= n] *)
@ -1423,8 +1424,9 @@ let expand_hpred_pointer calc_index_frame hpred : bool * bool * Sil.hpred =
| Sil.Hpointsto (Sil.Lfield (e, fld, typ_fld), se, t) ->
let t' = match t, typ_fld with
| _, Sil.Tstruct _ -> (* the struct type of fld is known *)
Sil.Sizeof (typ_fld, Sil.Subtype.exact)
| Sil.Sizeof (t1, st), _ -> (* the struct type of fld is not known -- typically Tvoid *)
Sil.Sizeof (typ_fld, None, Sil.Subtype.exact)
| Sil.Sizeof (t1, len, st), _ ->
(* the struct type of fld is not known -- typically Tvoid *)
Sil.Sizeof
(Sil.Tstruct
{ Sil.instance_fields = [(fld, t1, Sil.item_annotation_empty)];
@ -1434,18 +1436,18 @@ let expand_hpred_pointer calc_index_frame hpred : bool * bool * Sil.hpred =
Sil.superclasses = [];
Sil.def_methods = [];
Sil.struct_annotations = Sil.item_annotation_empty;
}, st)
}, len, st)
(* None as we don't know the stuct name *)
| _ -> raise (Failure "expand_hpred_pointer: Unexpected non-sizeof type in Lfield") in
let hpred' = Sil.Hpointsto (e, Sil.Estruct ([(fld, se)], Sil.inst_none), t') in
expand true true hpred'
| Sil.Hpointsto (Sil.Lindex (e, ind), se, t) ->
let size = Sil.exp_get_undefined false in
let clen = Sil.exp_get_undefined false in
let t' = match t with
| Sil.Sizeof (_t, st) ->
Sil.Sizeof (Sil.Tarray (_t, size), st)
| Sil.Sizeof (t_, vlen, st) ->
Sil.Sizeof (Sil.Tarray (t_, clen), vlen, st)
| _ -> raise (Failure "expand_hpred_pointer: Unexpected non-sizeof type in Lindex") in
let hpred' = Sil.Hpointsto (e, Sil.Earray (size, [(ind, se)], Sil.inst_none), t') in
let hpred' = Sil.Hpointsto (e, Sil.Earray (clen, [(ind, se)], Sil.inst_none), t') in
expand true true hpred'
| Sil.Hpointsto (Sil.BinOp (Sil.PlusPI, e1, e2), Sil.Earray (size, esel, inst), t) ->
let shift_exp e = Sil.BinOp (Sil.PlusA, e, e2) in
@ -1587,17 +1589,17 @@ struct
case, if they are possible *)
let subtype_case_analysis tenv texp1 texp2 =
match texp1, texp2 with
| Sil.Sizeof (t1, st1), Sil.Sizeof (t2, st2) ->
| Sil.Sizeof (t1, len1, st1), Sil.Sizeof (t2, len2, st2) ->
begin
let pos_opt, neg_opt = case_analysis_type tenv (t1, st1) (t2, st2) in
let pos_type_opt = match pos_opt with
| None -> None
| Some st1' ->
let t1' = if check_subtype tenv t1 t2 then t1 else t2 in
Some (Sil.Sizeof (t1', st1')) in
let t1', len1' = if check_subtype tenv t1 t2 then t1, len1 else t2, len2 in
Some (Sil.Sizeof (t1', len1', st1')) in
let neg_type_opt = match neg_opt with
| None -> None
| Some st1' -> Some (Sil.Sizeof (t1, st1')) in
| Some st1' -> Some (Sil.Sizeof (t1, len1, st1')) in
pos_type_opt, neg_type_opt
end
| _ -> (* don't know, consider both possibilities *)
@ -1606,7 +1608,7 @@ end
let cast_exception tenv texp1 texp2 e1 subs =
let _ = match texp1, texp2 with
| Sil.Sizeof (t1, _), Sil.Sizeof (t2, st2) ->
| Sil.Sizeof (t1, _, _), Sil.Sizeof (t2, _, st2) ->
if Config.developer_mode ||
(Sil.Subtype.is_cast st2 &&
not (Subtyping_check.check_subtype tenv t1 t2)) then
@ -1636,8 +1638,10 @@ let get_overrides_of tenv supertype pname =
(** Check the equality of two types ignoring flags in the subtyping components *)
let texp_equal_modulo_subtype_flag texp1 texp2 = match texp1, texp2 with
| Sil.Sizeof(t1, st1), Sil.Sizeof (t2, st2) ->
Sil.typ_equal t1 t2 && Sil.Subtype.equal_modulo_flag st1 st2
| Sil.Sizeof (t1, len1, st1), Sil.Sizeof (t2, len2, st2) ->
Sil.typ_equal t1 t2
&& (opt_equal Sil.exp_equal len1 len2)
&& Sil.Subtype.equal_modulo_flag st1 st2
| _ -> Sil.exp_equal texp1 texp2
(** check implication between type expressions *)
@ -1646,13 +1650,13 @@ let texp_imply tenv subs texp1 texp2 e1 calc_missing =
(* classes and arrays in Java, and just classes in C++ and ObjC *)
let types_subject_to_dynamic_cast =
match texp1, texp2 with
| Sil.Sizeof ((Sil.Tstruct _) as typ1, _), Sil.Sizeof (Sil.Tstruct _, _)
| Sil.Sizeof ((Sil.Tarray _) as typ1, _), Sil.Sizeof (Sil.Tarray _, _)
| Sil.Sizeof ((Sil.Tarray _) as typ1, _), Sil.Sizeof (Sil.Tstruct _, _)
| Sil.Sizeof ((Sil.Tstruct _) as typ1, _), Sil.Sizeof (Sil.Tarray _, _)
| Sil.Sizeof ((Sil.Tstruct _) as typ1, _, _), Sil.Sizeof (Sil.Tstruct _, _, _)
| Sil.Sizeof ((Sil.Tarray _) as typ1, _, _), Sil.Sizeof (Sil.Tarray _, _, _)
| Sil.Sizeof ((Sil.Tarray _) as typ1, _, _), Sil.Sizeof (Sil.Tstruct _, _, _)
| Sil.Sizeof ((Sil.Tstruct _) as typ1, _, _), Sil.Sizeof (Sil.Tarray _, _, _)
when is_java_class typ1 -> true
| Sil.Sizeof (typ1, _), Sil.Sizeof (typ2, _) ->
| Sil.Sizeof (typ1, _, _), Sil.Sizeof (typ2, _, _) ->
(Sil.is_cpp_class typ1 && Sil.is_cpp_class typ2) ||
(Sil.is_objc_class typ1 && Sil.is_objc_class typ2)
| _ -> false in
@ -1706,24 +1710,25 @@ let handle_parameter_subtype tenv prop1 sigma2 subs (e1, se1, texp1) (se2, texp2
let type_rhs e =
let sub_opt = ref None in
let filter = function
| Sil.Hpointsto(e', _, Sil.Sizeof(t, sub)) when Sil.exp_equal e' e ->
sub_opt := Some (t, sub);
| Sil.Hpointsto(e', _, Sil.Sizeof(t, len, sub)) when Sil.exp_equal e' e ->
sub_opt := Some (t, len, sub);
true
| _ -> false in
if IList.exists filter sigma2 then !sub_opt else None in
let add_subtype () = match texp1, texp2, se1, se2 with
| Sil.Sizeof(Sil.Tptr (_t1, _), _), Sil.Sizeof(Sil.Tptr (_t2, _), _),
Sil.Eexp(e1', _), Sil.Eexp(e2', _)
| Sil.Sizeof (Sil.Tptr (t1_, _), None, _), Sil.Sizeof (Sil.Tptr (t2_, _), None, _),
Sil.Eexp (e1', _), Sil.Eexp (e2', _)
when not (is_allocated_lhs e1') ->
begin
let t1, t2 = Tenv.expand_type tenv _t1, Tenv.expand_type tenv _t2 in
let t1, t2 = Tenv.expand_type tenv t1_, Tenv.expand_type tenv t2_ in
match type_rhs e2' with
| Some (t2_ptsto , sub2) ->
| Some (t2_ptsto, len2, sub2) ->
if not (Sil.typ_equal t1 t2) && Subtyping_check.check_subtype tenv t1 t2
then begin
let pos_type_opt, _ =
Subtyping_check.subtype_case_analysis tenv
(Sil.Sizeof (t1, Sil.Subtype.subtypes)) (Sil.Sizeof (t2_ptsto, sub2)) in
(Sil.Sizeof (t1, None, Sil.Subtype.subtypes))
(Sil.Sizeof (t2_ptsto, len2, sub2)) in
match pos_type_opt with
| Some t1_noptr ->
ProverState.add_frame_typ (e1', t1_noptr);
@ -1936,13 +1941,13 @@ and sigma_imply tenv calc_index_frame calc_missing subs prop1 sigma2 : (subst2 *
| _ -> None)
| _ -> None in
let mk_constant_string_hpred s = (* create an hpred from a constant string *)
let size = Sil.exp_int (Sil.Int.of_int (1 + String.length s)) in
let len = Sil.exp_int (Sil.Int.of_int (1 + String.length s)) in
let root = Sil.Const (Sil.Cstr s) in
let sexp =
let index = Sil.exp_int (Sil.Int.of_int (String.length s)) in
match !Config.curr_language with
| Config.Clang ->
Sil.Earray (size, [(index, Sil.Eexp (Sil.exp_zero, Sil.inst_none))], Sil.inst_none)
Sil.Earray (len, [(index, Sil.Eexp (Sil.exp_zero, Sil.inst_none))], Sil.inst_none)
| Config.Java ->
let mk_fld_sexp s =
let fld = Ident.create_fieldname (Mangled.from_string s) 0 in
@ -1952,14 +1957,15 @@ and sigma_imply tenv calc_index_frame calc_missing subs prop1 sigma2 : (subst2 *
Sil.Estruct (IList.map mk_fld_sexp fields, Sil.inst_none) in
let const_string_texp =
match !Config.curr_language with
| Config.Clang -> Sil.Sizeof (Sil.Tarray (Sil.Tint Sil.IChar, size), Sil.Subtype.exact)
| Config.Clang ->
Sil.Sizeof (Sil.Tarray (Sil.Tint Sil.IChar, len), Some len, Sil.Subtype.exact)
| Config.Java ->
let object_type =
Typename.TN_csu (Csu.Class Csu.Java, Mangled.from_string "java.lang.String") in
let typ = match Tenv.lookup tenv object_type with
| Some typ -> typ
| None -> assert false in
Sil.Sizeof (Sil.Tstruct typ, Sil.Subtype.exact) in
Sil.Sizeof (Sil.Tstruct typ, None, Sil.Subtype.exact) in
Sil.Hpointsto (root, sexp, const_string_texp) in
let mk_constant_class_hpred s = (* creat an hpred from a constant class *)
let root = Sil.Const (Sil.Cclass (Ident.string_to_name s)) in
@ -1971,7 +1977,7 @@ and sigma_imply tenv calc_index_frame calc_missing subs prop1 sigma2 : (subst2 *
let typ = match Tenv.lookup tenv class_type with
| Some typ -> typ
| None -> assert false in
Sil.Sizeof (Sil.Tstruct typ, Sil.Subtype.exact) in
Sil.Sizeof (Sil.Tstruct typ, None, Sil.Subtype.exact) in
Sil.Hpointsto (root, sexp, class_texp) in
try
(match move_primed_lhs_from_front subs sigma2 with

@ -392,10 +392,11 @@ let strexp_extend_values
let check_not_inconsistent (atoms, _, _) = not (IList.exists check_neg_atom atoms) in
IList.filter check_not_inconsistent atoms_se_typ_list in
if Config.trace_rearrange then L.d_strln "exiting strexp_extend_values";
let st = match te with
| Sil.Sizeof(_, st) -> st
| _ -> Sil.Subtype.exact in
IList.map (fun (atoms', se', typ') -> (laundry_atoms @ atoms', se', Sil.Sizeof (typ', st))) atoms_se_typ_list_filtered
let len, st = match te with
| Sil.Sizeof(_, len, st) -> (len, st)
| _ -> None, Sil.Subtype.exact in
IList.map (fun (atoms', se', typ') -> (laundry_atoms @ atoms', se', Sil.Sizeof (typ', len, st)))
atoms_se_typ_list_filtered
let collect_root_offset exp =
let root = Sil.root_of_lexp exp in
@ -430,17 +431,17 @@ let mk_ptsto_exp_footprint
| Sil.Lvar pvar, [], Sil.Tfun _ ->
let fun_name = Procname.from_string_c_fun (Mangled.to_string (Pvar.get_name pvar)) in
let fun_exp = Sil.Const (Sil.Cfun fun_name) in
([], Prop.mk_ptsto root (Sil.Eexp (fun_exp, inst)) (Sil.Sizeof (typ, st)))
([], Prop.mk_ptsto root (Sil.Eexp (fun_exp, inst)) (Sil.Sizeof (typ, None, st)))
| _, [], Sil.Tfun _ ->
let atoms, se, t =
create_struct_values
pname tenv orig_prop footprint_part Ident.kfootprint max_stamp typ off0 inst in
(atoms, Prop.mk_ptsto root se (Sil.Sizeof (t, st)))
(atoms, Prop.mk_ptsto root se (Sil.Sizeof (t, None, st)))
| _ ->
let atoms, se, t =
create_struct_values
pname tenv orig_prop footprint_part Ident.kfootprint max_stamp typ off0 inst in
(atoms, Prop.mk_ptsto root se (Sil.Sizeof (t, st))) in
(atoms, Prop.mk_ptsto root se (Sil.Sizeof (t, None, st))) in
let atoms, ptsto_foot = create_ptsto true off_foot in
let sub = Sil.sub_of_list eqs in
let ptsto = Sil.hpred_sub sub ptsto_foot in
@ -709,7 +710,7 @@ let add_guarded_by_constraints prop lexp pdesc =
| _ ->
prop_acc in
let hpred_check_flds prop_acc = function
| Sil.Hpointsto (_, Estruct (flds, _), Sizeof (typ, _)) ->
| Sil.Hpointsto (_, Estruct (flds, _), Sizeof (typ, _, _)) ->
IList.fold_left (check_fld_locks typ) prop_acc flds
| _ ->
prop_acc in
@ -926,7 +927,7 @@ let type_at_offset texp off =
strip_offset off' typ'
| _ -> None in
match texp with
| Sil.Sizeof(typ, _) ->
| Sil.Sizeof(typ, _, _) ->
strip_offset off typ
| _ -> None
@ -1080,7 +1081,7 @@ let check_dereference_error pdesc (prop : Prop.normal Prop.t) lexp loc =
IList.exists is_nullable_attr (Prop.get_exp_attributes prop exp) in
(* it's ok for a non-nullable local to point to deref_exp *)
is_nullable || Pvar.is_local pvar
| Sil.Hpointsto (_, Sil.Estruct (flds, _), Sil.Sizeof (typ, _)) ->
| Sil.Hpointsto (_, Sil.Estruct (flds, _), Sil.Sizeof (typ, _, _)) ->
let fld_is_nullable fld =
match Annotations.get_field_type_and_annotation fld typ with
| Some (_, annot) -> Annotations.ia_is_nullable annot

@ -128,7 +128,7 @@ let rec apply_offlist
else
begin
L.d_strln "WARNING: struct assignment treated as nondeterministic assignment";
(f None, Prop.create_strexp_of_type (Some tenv) Prop.Fld_init typ inst, typ, None)
(f None, Prop.create_strexp_of_type (Some tenv) Prop.Fld_init typ None inst, typ, None)
end
| [], Sil.Earray _ ->
let offlist' = (Sil.Off_index Sil.exp_zero):: offlist in
@ -213,7 +213,7 @@ let rec apply_offlist
Finally, before running this function, the tool should run strexp_extend_value
in rearrange.ml for the same se and offlist, so that all the necessary
extensions of se are done before this function. *)
let ptsto_lookup pdesc tenv p (lexp, se, typ, st) offlist id =
let ptsto_lookup pdesc tenv p (lexp, se, typ, len, st) offlist id =
let f =
function Some exp -> exp | None -> Sil.Var id in
let fp_root =
@ -226,7 +226,7 @@ let ptsto_lookup pdesc tenv p (lexp, se, typ, st) offlist id =
match !lookup_inst with
| Some (Sil.Iinitial | Sil.Ialloc | Sil.Ilookup) -> true
| _ -> false in
let ptsto' = Prop.mk_ptsto lexp se' (Sil.Sizeof (typ', st)) in
let ptsto' = Prop.mk_ptsto lexp se' (Sil.Sizeof (typ', len, st)) in
(e', ptsto', pred_insts_op', lookup_uninitialized)
(** [ptsto_update p (lexp,se,typ) offlist exp] takes
@ -240,7 +240,7 @@ let ptsto_lookup pdesc tenv p (lexp, se, typ, st) offlist id =
the tool should run strexp_extend_value in rearrange.ml for the same
se and offlist, so that all the necessary extensions of se are done
before this function. *)
let ptsto_update pdesc tenv p (lexp, se, typ, st) offlist exp =
let ptsto_update pdesc tenv p (lexp, se, typ, len, st) offlist exp =
let f _ = exp in
let fp_root =
match lexp with Sil.Var id -> Ident.is_footprint id | _ -> false in
@ -249,7 +249,7 @@ let ptsto_update pdesc tenv p (lexp, se, typ, st) offlist exp =
let pos = State.get_path_pos () in
apply_offlist
pdesc tenv p fp_root true (lexp, se, typ) offlist f (State.get_inst_update pos) lookup_inst in
let ptsto' = Prop.mk_ptsto lexp se' (Sil.Sizeof (typ', st)) in
let ptsto' = Prop.mk_ptsto lexp se' (Sil.Sizeof (typ', len, st)) in
(ptsto', pred_insts_op')
let update_iter iter pi sigma =
@ -526,8 +526,8 @@ let resolve_typename prop receiver_exp =
| _ :: hpreds -> loop hpreds in
loop (Prop.get_sigma prop) in
match typexp_opt with
| Some (Sil.Sizeof (Sil.Tstruct { Sil.struct_name = None }, _)) -> None
| Some (Sil.Sizeof (Sil.Tstruct { Sil.csu = Csu.Class ck; struct_name = Some name }, _)) ->
| Some (Sil.Sizeof (Sil.Tstruct { Sil.struct_name = None }, _, _)) -> None
| Some (Sil.Sizeof (Sil.Tstruct { Sil.csu = Csu.Class ck; struct_name = Some name }, _, _)) ->
Some (Typename.TN_csu (Csu.Class ck, name))
| _ -> None
@ -777,7 +777,7 @@ let do_error_checks node_opt instr pname pdesc = match node_opt with
let add_strexp_to_footprint strexp abducted_pv typ prop =
let abducted_lvar = Sil.Lvar abducted_pv in
let lvar_pt_fpvar =
let sizeof_exp = Sil.Sizeof (typ, Sil.Subtype.subtypes) in
let sizeof_exp = Sil.Sizeof (typ, None, Sil.Subtype.subtypes) in
Prop.mk_ptsto abducted_lvar strexp sizeof_exp in
let sigma_fp = Prop.get_sigma_footprint prop in
Prop.normalize (Prop.replace_sigma_footprint (lvar_pt_fpvar :: sigma_fp) prop)
@ -793,7 +793,7 @@ let add_to_footprint abducted_pv typ prop =
footprint. we can get rid of this special case if we fix the abduction on struct values *)
let add_struct_value_to_footprint tenv abducted_pv typ prop =
let struct_strexp =
Prop.create_strexp_of_type (Some tenv) Prop.Fld_init typ Sil.inst_none in
Prop.create_strexp_of_type (Some tenv) Prop.Fld_init typ None Sil.inst_none in
let prop' = add_strexp_to_footprint struct_strexp abducted_pv typ prop in
prop', struct_strexp
@ -876,9 +876,9 @@ let execute_letderef ?(report_deref_errors=true) pname pdesc tenv id rhs_exp typ
let iter_ren = Prop.prop_iter_make_id_primed id iter in
let prop_ren = Prop.prop_iter_to_prop iter_ren in
match Prop.prop_iter_current iter_ren with
| (Sil.Hpointsto(lexp, strexp, Sil.Sizeof (typ, st)), offlist) ->
| (Sil.Hpointsto(lexp, strexp, Sil.Sizeof (typ, len, st)), offlist) ->
let contents, new_ptsto, pred_insts_op, lookup_uninitialized =
ptsto_lookup pdesc tenv prop_ren (lexp, strexp, typ, st) offlist id in
ptsto_lookup pdesc tenv prop_ren (lexp, strexp, typ, len, st) offlist id in
let update acc (pi, sigma) =
let pi' = Sil.Aeq (Sil.Var(id), contents):: pi in
let sigma' = new_ptsto:: sigma in
@ -948,14 +948,14 @@ let load_ret_annots pname =
let execute_set ?(report_deref_errors=true) pname pdesc tenv lhs_exp typ rhs_exp loc prop_ =
let execute_set_ pdesc tenv rhs_exp acc_in iter =
let (lexp, strexp, typ, st, offlist) =
let (lexp, strexp, typ, len, st, offlist) =
match Prop.prop_iter_current iter with
| (Sil.Hpointsto(lexp, strexp, Sil.Sizeof (typ, st)), offlist) ->
(lexp, strexp, typ, st, offlist)
| (Sil.Hpointsto(lexp, strexp, Sil.Sizeof (typ, len, st)), offlist) ->
(lexp, strexp, typ, len, st, offlist)
| _ -> assert false in
let p = Prop.prop_iter_to_prop iter in
let new_ptsto, pred_insts_op =
ptsto_update pdesc tenv p (lexp, strexp, typ, st) offlist rhs_exp in
ptsto_update pdesc tenv p (lexp, strexp, typ, len, st) offlist rhs_exp in
let update acc (pi, sigma) =
let sigma' = new_ptsto:: sigma in
let iter' = update_iter iter pi sigma' in
@ -1058,7 +1058,7 @@ let rec sym_exec tenv current_pdesc _instr (prop_: Prop.normal Prop.t) path
let lhs_is_ns_ptr () =
IList.exists
(function
| Sil.Hpointsto (_, Sil.Eexp (exp, _), Sil.Sizeof (Sil.Tptr (typ, _), _)) ->
| Sil.Hpointsto (_, Sil.Eexp (exp, _), Sil.Sizeof (Sil.Tptr (typ, _), _, _)) ->
Sil.exp_equal exp lhs_normal && is_nsnumber typ
| _ -> false)
(Prop.get_sigma prop__) in
@ -1242,7 +1242,7 @@ let rec sym_exec tenv current_pdesc _instr (prop_: Prop.normal Prop.t) path
ret_old_path [Prop.exist_quantify (Sil.fav_from_list temps) prop_]
| Sil.Declare_locals (ptl, _) ->
let sigma_locals =
let add_None (x, y) = (x, Sil.Sizeof (y, Sil.Subtype.exact), None) in
let add_None (x, y) = (x, Sil.Sizeof (y, None, Sil.Subtype.exact), None) in
let sigma_locals () =
IList.map
(Prop.mk_ptsto_lvar (Some tenv) Prop.Fld_init Sil.inst_initial)
@ -1353,7 +1353,7 @@ and add_constraints_on_actuals_by_ref tenv prop actuals_by_ref callee_pname call
let havoc_actual_by_ref (actual, actual_typ) prop =
let actual_pt_havocd_var =
let havocd_var = Sil.Var (Ident.create_fresh Ident.kprimed) in
let sizeof_exp = Sil.Sizeof (Sil.typ_strip_ptr actual_typ, Sil.Subtype.subtypes) in
let sizeof_exp = Sil.Sizeof (Sil.typ_strip_ptr actual_typ, None, Sil.Subtype.subtypes) in
Prop.mk_ptsto actual (Sil.Eexp (havocd_var, Sil.Inone)) sizeof_exp in
replace_actual_hpred actual actual_pt_havocd_var prop in
IList.fold_left (fun p var -> havoc_actual_by_ref var p) prop actuals_by_ref

@ -473,8 +473,8 @@ let texp_star texp1 texp2 =
if ftal_sub instance_fields1 instance_fields2 then t2 else t1
| _ -> t1 in
match texp1, texp2 with
| Sil.Sizeof (t1, st1), Sil.Sizeof (t2, st2) ->
Sil.Sizeof (typ_star t1 t2, Sil.Subtype.join st1 st2)
| Sil.Sizeof (t1, len1, st1), Sil.Sizeof (t2, _, st2) ->
Sil.Sizeof (typ_star t1 t2, len1, Sil.Subtype.join st1 st2)
| _ ->
texp1
@ -629,7 +629,7 @@ let prop_get_exn_name pname prop =
let ret_pvar = Sil.Lvar (Pvar.get_ret_pvar pname) in
let rec search_exn e = function
| [] -> None
| Sil.Hpointsto (e1, _, Sil.Sizeof (Sil.Tstruct { Sil.struct_name = Some name }, _)) :: _
| Sil.Hpointsto (e1, _, Sil.Sizeof (Sil.Tstruct { Sil.struct_name = Some name }, _, _)) :: _
when Sil.exp_equal e1 e ->
Some (Typename.TN_csu (Csu.Class Csu.Java, name))
| _ :: tl -> search_exn e tl in
@ -868,7 +868,7 @@ let mk_actual_precondition prop actual_params formal_params =
Prop.mk_ptsto
(Sil.Lvar formal_var)
(Sil.Eexp (actual_e, Sil.inst_actual_precondition))
(Sil.Sizeof (actual_t, Sil.Subtype.exact)) in
(Sil.Sizeof (actual_t, None, Sil.Subtype.exact)) in
let instantiated_formals = IList.map mk_instantiation formals_actuals in
let actual_pre = Prop.prop_sigma_star prop instantiated_formals in
Prop.normalize actual_pre

@ -48,6 +48,13 @@ let opt_equal cmp x1 x2 = match x1, x2 with
| None, Some _ -> false
| Some y1, Some y2 -> cmp y1 y2
let opt_compare cmp x1 x2 =
match x1, x2 with
| Some y1, Some y2 -> cmp y1 y2
| None, None -> 0
| None, _ -> -1
| _, None -> 1
(** Efficient comparison for integers *)
let int_compare (i: int) (j: int) = i - j
@ -64,6 +71,10 @@ let triple_compare compare compare' compare'' (x1, y1, z1) (x2, y2, z2) =
if n <> 0 then n else let n = compare' y1 y2 in
if n <> 0 then n else compare'' z1 z2
let fst3 (x,_,_) = x
let snd3 (_,x,_) = x
let trd3 (_,_,x) = x
(** {2 Useful Modules} *)
(** Set of integers *)

@ -44,6 +44,9 @@ val int_equal : int -> int -> bool
(** Extend and equality function to an option type. *)
val opt_equal : ('a -> 'a -> bool) -> 'a option -> 'a option -> bool
(** Comparison of option type. *)
val opt_compare : ('a -> 'a -> int) -> 'a option -> 'a option -> int
(** Generic comparison of pairs given a compare function for each element of the pair. *)
val pair_compare : ('a -> 'b -> int) -> ('c -> 'd -> int) -> ('a * 'c) -> ('b * 'd) -> int
@ -59,6 +62,15 @@ val string_equal : string -> string -> bool
(** Comparison for floats *)
val float_compare : float -> float -> int
(** Return the first component of a triple. *)
val fst3 : 'a * 'b * 'c -> 'a
(** Return the second component of a triple. *)
val snd3 : 'a * 'b * 'c -> 'b
(** Return the third component of a triple. *)
val trd3 : 'a * 'b * 'c -> 'c
(** {2 Useful Modules} *)
(** Set of integers *)

@ -216,7 +216,7 @@ struct
CTypes_decl.objc_class_name_to_sil_type trans_state.context.CContext.tenv class_name in
let expanded_type = CTypes.expand_structured_type trans_state.context.CContext.tenv typ in
{ empty_res_trans with
exps = [(Sil.Sizeof(expanded_type, Sil.Subtype.exact), Sil.Tint Sil.IULong)] }
exps = [(Sil.Sizeof(expanded_type, None, Sil.Subtype.exact), Sil.Tint Sil.IULong)] }
let add_reference_if_glvalue typ expr_info =
(* glvalue definition per C++11:*)
@ -426,7 +426,8 @@ struct
match tp with
| Some tp -> CTypes_decl.type_ptr_to_sil_type tenv tp
| None -> typ in (* Some default type since the type is missing *)
{ empty_res_trans with exps = [(Sil.Sizeof(sizeof_typ, Sil.Subtype.exact), sizeof_typ)]}
{ empty_res_trans with
exps = [(Sil.Sizeof (sizeof_typ, None, Sil.Subtype.exact), sizeof_typ)] }
| k -> Printing.log_stats
"\nWARNING: Missing translation of Uniry_Expression_Or_Trait of kind: \
%s . Expression ignored, returned -1... \n"
@ -2189,7 +2190,7 @@ struct
let sil_loc = CLocation.get_sil_location stmt_info context in
let cast_type = CTypes_decl.type_ptr_to_sil_type tenv cast_type_ptr in
let sizeof_expr = match cast_type with
| Sil.Tptr (typ, _) -> Sil.Sizeof (typ, subtypes)
| Sil.Tptr (typ, _) -> Sil.Sizeof (typ, None, subtypes)
| _ -> assert false in
let builtin = Sil.Const (Sil.Cfun ModelBuiltins.__cast) in
let stmt = match stmts with [stmt] -> stmt | _ -> assert false in
@ -2247,7 +2248,7 @@ struct
let fun_name = ModelBuiltins.__cxx_typeid in
let sil_fun = Sil.Const (Sil.Cfun fun_name) in
let ret_id = Ident.create_fresh Ident.knormal in
let type_info_objc = (Sil.Sizeof (typ, Sil.Subtype.exact), Sil.Tvoid) in
let type_info_objc = (Sil.Sizeof (typ, None, Sil.Subtype.exact), Sil.Tvoid) in
let field_name_decl = Ast_utils.make_qual_name_decl ["type_info"; "std"] "__type_name" in
let field_name = General_utils.mk_class_field_name field_name_decl in
let ret_exp = Sil.Var ret_id in

@ -296,7 +296,7 @@ let create_alloc_instrs context sil_loc function_type fname size_exp_opt procnam
function_type, styp
| _ -> Sil.Tptr (function_type, Sil.Pk_pointer), function_type in
let function_type_np = CTypes.expand_structured_type context.CContext.tenv function_type_np in
let sizeof_exp_ = Sil.Sizeof (function_type_np, Sil.Subtype.exact) in
let sizeof_exp_ = Sil.Sizeof (function_type_np, None, Sil.Subtype.exact) in
let sizeof_exp = match size_exp_opt with
| Some exp -> Sil.BinOp (Sil.Mult, sizeof_exp_, exp)
| None -> sizeof_exp_ in
@ -366,7 +366,7 @@ let create_cast_instrs context exp cast_from_typ cast_to_typ sil_loc =
let ret_id = Ident.create_fresh Ident.knormal in
let typ = CTypes.remove_pointer_to_typ cast_to_typ in
let cast_typ_no_pointer = CTypes.expand_structured_type context.CContext.tenv typ in
let sizeof_exp = Sil.Sizeof (cast_typ_no_pointer, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (cast_typ_no_pointer, None, Sil.Subtype.exact) in
let pname = ModelBuiltins.__objc_cast in
let args = [(exp, cast_from_typ); (sizeof_exp, Sil.Tint Sil.IULong)] in
let stmt_call = Sil.Call([ret_id], (Sil.Const (Sil.Cfun pname)), args, sil_loc, Sil.cf_default) in

@ -140,7 +140,7 @@ let check_condition case_zero find_canonical_duplicate curr_pname
Mangled.equal c throwable_class
| _ -> false in
let do_instr = function
| Sil.Call (_, Sil.Const (Sil.Cfun pn), [_; (Sil.Sizeof(t, _), _)], _, _) when
| Sil.Call (_, Sil.Const (Sil.Cfun pn), [_; (Sil.Sizeof(t, _, _), _)], _, _) when
Procname.equal pn ModelBuiltins.__instanceof && typ_is_throwable t ->
throwable_found := true
| _ -> () in

@ -68,12 +68,12 @@ let get_non_receiver_formals formals = tl_or_empty formals
(** create Sil corresponding to x = new typ() or x = new typ[]. For ordinary allocation, sizeof_typ
* and ret_typ should be the same, but arrays are slightly odd in that sizeof_typ will have a size
* component but the size component of ret_typ is always -1. *)
let inhabit_alloc sizeof_typ ret_typ alloc_kind env =
let inhabit_alloc sizeof_typ sizeof_len ret_typ alloc_kind env =
let retval = Ident.create_fresh Ident.knormal in
let inhabited_exp = Sil.Var retval in
let call_instr =
let fun_new = fun_exp_from_name alloc_kind in
let sizeof_exp = Sil.Sizeof (sizeof_typ, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (sizeof_typ, sizeof_len, Sil.Subtype.exact) in
let args = [(sizeof_exp, Sil.Tptr (ret_typ, Sil.Pk_pointer))] in
Sil.Call ([retval], fun_new, args, env.pc, cf_alloc) in
(inhabited_exp, env_add_instr call_instr env)
@ -87,11 +87,11 @@ let rec inhabit_typ typ cfg env =
| Sil.Tptr (Sil.Tarray (inner_typ, Sil.Const (Sil.Cint _)), Sil.Pk_pointer) ->
let arr_size = Sil.Const (Sil.Cint (Sil.Int.one)) in
let arr_typ = Sil.Tarray (inner_typ, arr_size) in
inhabit_alloc arr_typ typ ModelBuiltins.__new_array env
inhabit_alloc arr_typ (Some arr_size) typ ModelBuiltins.__new_array env
| Sil.Tptr (typ, Sil.Pk_pointer) as ptr_to_typ ->
(* TODO (t4575417): this case does not work correctly for enums, but they are currently
* broken in Infer anyway (see t4592290) *)
let (allocated_obj_exp, env) = inhabit_alloc typ typ ModelBuiltins.__new env in
let (allocated_obj_exp, env) = inhabit_alloc typ None typ ModelBuiltins.__new env in
(* select methods that are constructors and won't force us into infinite recursion because
* we are already inhabiting one of their argument types *)
let get_all_suitable_constructors typ = match typ with

@ -645,10 +645,11 @@ let get_array_size context pc expr_list content_type =
| (other_instrs, other_exprs) ->
(instrs@other_instrs, sil_size_expr:: other_exprs) in
let (instrs, sil_size_exprs) = (IList.fold_right get_expr_instr expr_list ([],[])) in
let get_array_type sil_size_expr content_type =
Sil.Tarray (content_type, sil_size_expr) in
let array_type = (IList.fold_right get_array_type sil_size_exprs content_type) in
let array_size = Sil.Sizeof (array_type, Sil.Subtype.exact) in
let get_array_type_len sil_size_expr (content_type, _) =
(Sil.Tarray (content_type, sil_size_expr), Some sil_size_expr) in
let array_type, array_len =
IList.fold_right get_array_type_len sil_size_exprs (content_type, None) in
let array_size = Sil.Sizeof (array_type, array_len, Sil.Subtype.exact) in
(instrs, array_size)
module Int =
@ -902,7 +903,7 @@ let rec instruction context pc instr : translation =
let builtin_new = Sil.Const (Sil.Cfun ModelBuiltins.__new) in
let class_type = JTransType.get_class_type program tenv cn in
let class_type_np = JTransType.get_class_type_no_pointer program tenv cn in
let sizeof_exp = Sil.Sizeof (class_type_np, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (class_type_np, None, Sil.Subtype.exact) in
let args = [(sizeof_exp, class_type)] in
let ret_id = Ident.create_fresh Ident.knormal in
let new_instr = Sil.Call([ret_id], builtin_new, args, loc, Sil.cf_default) in
@ -1016,7 +1017,7 @@ let rec instruction context pc instr : translation =
and npe_cn = JBasics.make_cn JConfig.npe_cl in
let class_type = JTransType.get_class_type program tenv npe_cn
and class_type_np = JTransType.get_class_type_no_pointer program tenv npe_cn in
let sizeof_exp = Sil.Sizeof (class_type_np, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (class_type_np, None, Sil.Subtype.exact) in
let args = [(sizeof_exp, class_type)] in
let ret_id = Ident.create_fresh Ident.knormal in
let new_instr = Sil.Call([ret_id], builtin_new, args, loc, Sil.cf_default) in
@ -1069,7 +1070,7 @@ let rec instruction context pc instr : translation =
let out_of_bound_cn = JBasics.make_cn JConfig.out_of_bound_cl in
let class_type = JTransType.get_class_type program tenv out_of_bound_cn
and class_type_np = JTransType.get_class_type_no_pointer program tenv out_of_bound_cn in
let sizeof_exp = Sil.Sizeof (class_type_np, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (class_type_np, None, Sil.Subtype.exact) in
let args = [(sizeof_exp, class_type)] in
let ret_id = Ident.create_fresh Ident.knormal in
let new_instr = Sil.Call([ret_id], builtin_new, args, loc, Sil.cf_default) in
@ -1108,7 +1109,7 @@ let rec instruction context pc instr : translation =
and cce_cn = JBasics.make_cn JConfig.cce_cl in
let class_type = JTransType.get_class_type program tenv cce_cn
and class_type_np = JTransType.get_class_type_no_pointer program tenv cce_cn in
let sizeof_exp = Sil.Sizeof (class_type_np, Sil.Subtype.exact) in
let sizeof_exp = Sil.Sizeof (class_type_np, None, Sil.Subtype.exact) in
let args = [(sizeof_exp, class_type)] in
let ret_id = Ident.create_fresh Ident.knormal in
let new_instr = Sil.Call([ret_id], builtin_new, args, loc, Sil.cf_default) in

@ -67,7 +67,9 @@ let translate_exceptions context exit_nodes get_body_nodes handler_table =
let id_instanceof = Ident.create_fresh Ident.knormal in
let instr_call_instanceof =
let instanceof_builtin = Sil.Const (Sil.Cfun ModelBuiltins.__instanceof) in
let args = [(Sil.Var id_exn_val, Sil.Tptr(exn_type, Sil.Pk_pointer)); (Sil.Sizeof (exn_type, Sil.Subtype.exact), Sil.Tvoid)] in
let args = [
(Sil.Var id_exn_val, Sil.Tptr(exn_type, Sil.Pk_pointer));
(Sil.Sizeof (exn_type, None, Sil.Subtype.exact), Sil.Tvoid)] in
Sil.Call ([id_instanceof], instanceof_builtin, args, loc, Sil.cf_default) in
let if_kind = Sil.Ik_switch in
let instr_prune_true = Sil.Prune (Sil.Var id_instanceof, loc, true, if_kind) in

@ -397,11 +397,11 @@ and value_type program tenv vt =
(** Translate object types into Sil.Sizeof expressions *)
let sizeof_of_object_type program tenv ot subtypes =
match object_type program tenv ot with
| Sil.Tptr (Sil.Tarray (vtyp, s), Sil.Pk_pointer) ->
let typ = (Sil.Tarray (vtyp, s)) in
Sil.Sizeof (typ, subtypes)
| Sil.Tptr (Sil.Tarray (vtyp, len), Sil.Pk_pointer) ->
let typ = (Sil.Tarray (vtyp, len)) in
Sil.Sizeof (typ, Some len, subtypes)
| Sil.Tptr (typ, _) ->
Sil.Sizeof (typ, subtypes)
Sil.Sizeof (typ, None, subtypes)
| _ ->
raise (Type_tranlsation_error "Pointer or array type expected in tenv")

Loading…
Cancel
Save