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1402 lines
65 KiB
1402 lines
65 KiB
(*
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* Copyright (c) 2009 - 2013 Monoidics ltd.
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* Copyright (c) 2013 - present Facebook, Inc.
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* All rights reserved.
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*
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* This source code is licensed under the BSD style license found in the
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* LICENSE file in the root directory of this source tree. An additional grant
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* of patent rights can be found in the PATENTS file in the same directory.
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*)
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open! Utils
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(** Re-arrangement and extension of structures with fresh variables *)
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module L = Logging
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module F = Format
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let list_product l1 l2 =
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let l1' = IList.rev l1 in
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let l2' = IList.rev l2 in
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IList.fold_left
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(fun acc x -> IList.fold_left (fun acc' y -> (x, y):: acc') acc l2')
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[] l1'
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let rec list_rev_and_concat l1 l2 =
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match l1 with
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| [] -> l2
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| x1:: l1' -> list_rev_and_concat l1' (x1:: l2)
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(** Check whether the index is out of bounds.
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If the length is - 1, no check is performed.
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If the index is provably out of bound, a bound error is given.
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If the length is a constant and the index is not provably in bound, a warning is given.
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*)
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let check_bad_index pname p len index loc =
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let len_is_constant = match len with
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| Exp.Const _ -> true
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| _ -> false in
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let index_provably_out_of_bound () =
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let index_too_large = Prop.mk_inequality (Exp.BinOp (Binop.Le, len, index)) in
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let index_negative = Prop.mk_inequality (Exp.BinOp (Binop.Le, index, Exp.minus_one)) in
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(Prover.check_atom p index_too_large) || (Prover.check_atom p index_negative) in
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let index_provably_in_bound () =
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let len_minus_one = Exp.BinOp(Binop.PlusA, len, Exp.minus_one) in
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let index_not_too_large = Prop.mk_inequality (Exp.BinOp(Binop.Le, index, len_minus_one)) in
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let index_nonnegative = Prop.mk_inequality (Exp.BinOp(Binop.Le, Exp.zero, index)) in
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Prover.check_zero index || (* index 0 always in bound, even when we know nothing about len *)
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((Prover.check_atom p index_not_too_large) && (Prover.check_atom p index_nonnegative)) in
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let index_has_bounds () =
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match Prover.get_bounds p index with
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| Some _, Some _ -> true
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| _ -> false in
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let get_const_opt = function
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| Exp.Const (Const.Cint n) -> Some n
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| _ -> None in
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if not (index_provably_in_bound ()) then
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begin
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let len_const_opt = get_const_opt len in
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let index_const_opt = get_const_opt index in
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if index_provably_out_of_bound () then
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let deref_str = Localise.deref_str_array_bound len_const_opt index_const_opt in
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let exn =
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Exceptions.Array_out_of_bounds_l1
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(Errdesc.explain_array_access deref_str p loc, __POS__) in
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let pre_opt = State.get_normalized_pre (Abs.abstract_no_symop pname) in
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Reporting.log_warning pname ~pre: pre_opt exn
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else if len_is_constant then
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let deref_str = Localise.deref_str_array_bound len_const_opt index_const_opt in
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let desc = Errdesc.explain_array_access deref_str p loc in
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let exn = if index_has_bounds ()
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then Exceptions.Array_out_of_bounds_l2 (desc, __POS__)
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else Exceptions.Array_out_of_bounds_l3 (desc, __POS__) in
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let pre_opt = State.get_normalized_pre (Abs.abstract_no_symop pname) in
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Reporting.log_warning pname ~pre: pre_opt exn
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end
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(** Perform bounds checking *)
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let bounds_check pname prop len e =
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if Config.trace_rearrange then
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begin
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L.d_str "Bounds check index:"; Sil.d_exp e;
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L.d_str " len: "; Sil.d_exp len;
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L.d_ln()
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end;
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check_bad_index pname prop len e
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let rec create_struct_values pname tenv orig_prop footprint_part kind max_stamp t
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(off: Sil.offset list) inst : Sil.atom list * Sil.strexp * Typ.t =
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if Config.trace_rearrange then
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begin
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L.d_increase_indent 1;
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L.d_strln "entering create_struct_values";
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L.d_str "typ: "; Typ.d_full t; L.d_ln ();
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L.d_str "off: "; Sil.d_offset_list off; L.d_ln (); L.d_ln ()
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end;
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let new_id () =
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incr max_stamp;
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Ident.create kind !max_stamp in
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let res =
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match t, off with
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| Typ.Tstruct _, [] ->
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([], Sil.Estruct ([], inst), t)
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| Typ.Tstruct ({ Typ.instance_fields; static_fields } as struct_typ ),
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(Sil.Off_fld (f, _)):: off' ->
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let _, t', _ =
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try
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IList.find (fun (f', _, _) -> Ident.fieldname_equal f f')
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(instance_fields @ static_fields)
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with Not_found ->
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raise (Exceptions.Bad_footprint __POS__) in
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let atoms', se', res_t' =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp t' off' inst in
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let se = Sil.Estruct ([(f, se')], inst) in
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let replace_typ_of_f (f', t', a') =
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if Ident.fieldname_equal f f' then (f, res_t', a') else (f', t', a') in
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let instance_fields' =
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IList.sort Typ.fld_typ_ann_compare (IList.map replace_typ_of_f instance_fields) in
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(atoms', se, Typ.Tstruct { struct_typ with Typ.instance_fields = instance_fields'})
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| Typ.Tstruct _, (Sil.Off_index e):: off' ->
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let atoms', se', res_t' =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp t off' inst in
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let e' = Sil.array_clean_new_index footprint_part e in
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let len = Exp.Var (new_id ()) in
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let se = Sil.Earray (len, [(e', se')], inst) in
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let res_t = Typ.Tarray (res_t', None) in
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(Sil.Aeq(e, e') :: atoms', se, res_t)
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| Typ.Tarray (t', len_), off ->
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let len = match len_ with
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| None -> Exp.Var (new_id ())
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| Some len -> Exp.Const (Const.Cint len) in
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(match off with
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| [] ->
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([], Sil.Earray (len, [], inst), t)
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| (Sil.Off_index e) :: off' ->
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bounds_check pname orig_prop len e (State.get_loc ());
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let atoms', se', res_t' =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp t' off' inst in
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let e' = Sil.array_clean_new_index footprint_part e in
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let se = Sil.Earray (len, [(e', se')], inst) in
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let res_t = Typ.Tarray (res_t', len_) in
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(Sil.Aeq(e, e') :: atoms', se, res_t)
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| (Sil.Off_fld _) :: _ ->
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assert false
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)
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| Typ.Tint _, [] | Typ.Tfloat _, [] | Typ.Tvoid, [] | Typ.Tfun _, [] | Typ.Tptr _, [] ->
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let id = new_id () in
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([], Sil.Eexp (Exp.Var id, inst), t)
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| Typ.Tint _, [Sil.Off_index e] | Typ.Tfloat _, [Sil.Off_index e]
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| Typ.Tvoid, [Sil.Off_index e]
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| Typ.Tfun _, [Sil.Off_index e] | Typ.Tptr _, [Sil.Off_index e] ->
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(* In this case, we lift t to the t array. *)
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let t' = match t with
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| Typ.Tptr(t', _) -> t'
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| _ -> t in
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let len = Exp.Var (new_id ()) in
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let atoms', se', res_t' =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp t' [] inst in
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let e' = Sil.array_clean_new_index footprint_part e in
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let se = Sil.Earray (len, [(e', se')], inst) in
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let res_t = Typ.Tarray (res_t', None) in
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(Sil.Aeq(e, e'):: atoms', se, res_t)
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| Typ.Tint _, _ | Typ.Tfloat _, _ | Typ.Tvoid, _ | Typ.Tfun _, _ | Typ.Tptr _, _ ->
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L.d_str "create_struct_values type:"; Typ.d_full t;
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L.d_str " off: "; Sil.d_offset_list off; L.d_ln();
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raise (Exceptions.Bad_footprint __POS__)
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| Typ.Tvar _, _ ->
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L.d_str "create_struct_values type:"; Typ.d_full t;
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L.d_str " off: "; Sil.d_offset_list off; L.d_ln();
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assert false in
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if Config.trace_rearrange then
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begin
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let _, se, _ = res in
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L.d_strln "exiting create_struct_values, returning";
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Sil.d_sexp se;
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L.d_decrease_indent 1;
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L.d_ln (); L.d_ln ()
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end;
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res
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(** Extend the strexp by populating the path indicated by [off].
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This means that it will add missing flds and do the case - analysis
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for array accesses. This does not catch the array - bounds errors.
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If we want to implement the checks for array bounds errors,
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we need to change this function. *)
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let rec _strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp
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se typ (off : Sil.offset list) inst =
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let new_id () =
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incr max_stamp;
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Ident.create kind !max_stamp in
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match off, se, typ with
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| [], Sil.Eexp _, _
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| [], Sil.Estruct _, _ ->
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[([], se, typ)]
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| [], Sil.Earray _, _ ->
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let off_new = Sil.Off_index(Exp.zero):: off in
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_strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp se typ off_new inst
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| (Sil.Off_fld _) :: _, Sil.Earray _, Typ.Tarray _ ->
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let off_new = Sil.Off_index(Exp.zero):: off in
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_strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp se typ off_new inst
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| (Sil.Off_fld (f, _)):: off', Sil.Estruct (fsel, inst'),
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Typ.Tstruct ({ Typ.instance_fields; static_fields } as struct_typ) ->
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let replace_fv new_v fv = if Ident.fieldname_equal (fst fv) f then (f, new_v) else fv in
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let _, typ', _ =
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try
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IList.find (fun (f', _, _) -> Ident.fieldname_equal f f')
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(instance_fields @ static_fields)
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with Not_found ->
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raise (Exceptions.Missing_fld (f, __POS__)) in
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begin
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try
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let _, se' = IList.find (fun (f', _) -> Ident.fieldname_equal f f') fsel in
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let atoms_se_typ_list' =
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_strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp se' typ' off' inst in
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let replace acc (res_atoms', res_se', res_typ') =
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let replace_fse = replace_fv res_se' in
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let res_fsel' = IList.sort Sil.fld_strexp_compare (IList.map replace_fse fsel) in
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let replace_fta (f, t, a) = let f', t' = replace_fv res_typ' (f, t) in (f', t', a) in
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let instance_fields' =
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IList.sort Typ.fld_typ_ann_compare (IList.map replace_fta instance_fields) in
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let struct_typ =
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Typ.Tstruct { struct_typ with Typ.instance_fields = instance_fields' } in
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(res_atoms', Sil.Estruct (res_fsel', inst'), struct_typ) :: acc in
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IList.fold_left replace [] atoms_se_typ_list'
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with Not_found ->
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let atoms', se', res_typ' =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp typ' off' inst in
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let res_fsel' = IList.sort Sil.fld_strexp_compare ((f, se'):: fsel) in
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let replace_fta (f', t', a') = if Ident.fieldname_equal f' f then (f, res_typ', a') else (f', t', a') in
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let instance_fields' =
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IList.sort Typ.fld_typ_ann_compare (IList.map replace_fta instance_fields) in
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let struct_typ = Typ.Tstruct { struct_typ with Typ.instance_fields = instance_fields' } in
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[(atoms', Sil.Estruct (res_fsel', inst'), struct_typ)]
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end
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| (Sil.Off_fld (_, _)):: _, _, _ ->
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raise (Exceptions.Bad_footprint __POS__)
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| (Sil.Off_index _):: _, Sil.Eexp _, Typ.Tint _
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| (Sil.Off_index _):: _, Sil.Eexp _, Typ.Tfloat _
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| (Sil.Off_index _):: _, Sil.Eexp _, Typ.Tvoid
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| (Sil.Off_index _):: _, Sil.Eexp _, Typ.Tfun _
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| (Sil.Off_index _):: _, Sil.Eexp _, Typ.Tptr _
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| (Sil.Off_index _):: _, Sil.Estruct _, Typ.Tstruct _ ->
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(* L.d_strln_color Orange "turn into an array"; *)
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let len = match se with
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| Sil.Eexp (_, Sil.Ialloc) -> Exp.one (* if allocated explicitly, we know len is 1 *)
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| _ ->
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if Config.type_size then Exp.one (* Exp.Sizeof (typ, Subtype.exact) *)
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else Exp.Var (new_id ()) in
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let se_new = Sil.Earray (len, [(Exp.zero, se)], inst) in
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let typ_new = Typ.Tarray (typ, None) in
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_strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp se_new typ_new off inst
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| (Sil.Off_index e) :: off', Sil.Earray (len, esel, inst_arr), Typ.Tarray (typ', len_for_typ') ->
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bounds_check pname orig_prop len e (State.get_loc ());
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begin
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try
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let _, se' = IList.find (fun (e', _) -> Exp.equal e e') esel in
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let atoms_se_typ_list' =
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_strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp se' typ' off' inst in
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let replace acc (res_atoms', res_se', res_typ') =
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let replace_ise ise = if Exp.equal e (fst ise) then (e, res_se') else ise in
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let res_esel' = IList.map replace_ise esel in
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if (Typ.equal res_typ' typ') || (IList.length res_esel' = 1) then
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( res_atoms'
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, Sil.Earray (len, res_esel', inst_arr)
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, Typ.Tarray (res_typ', len_for_typ') )
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:: acc
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else
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raise (Exceptions.Bad_footprint __POS__) in
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IList.fold_left replace [] atoms_se_typ_list'
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with Not_found ->
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array_case_analysis_index pname tenv orig_prop
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footprint_part kind max_stamp
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len esel
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len_for_typ' typ'
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e off' inst_arr inst
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end
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| _, _, _ ->
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raise (Exceptions.Bad_footprint __POS__)
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and array_case_analysis_index pname tenv orig_prop
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footprint_part kind max_stamp
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array_len array_cont
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typ_array_len typ_cont
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index off inst_arr inst
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=
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let check_sound t' =
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if not (Typ.equal typ_cont t' || array_cont == [])
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then raise (Exceptions.Bad_footprint __POS__) in
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let index_in_array =
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IList.exists (fun (i, _) -> Prover.check_equal Prop.prop_emp index i) array_cont in
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let array_is_full =
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match array_len with
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| Exp.Const (Const.Cint n') -> IntLit.geq (IntLit.of_int (IList.length array_cont)) n'
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| _ -> false in
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if index_in_array then
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let array_default = Sil.Earray (array_len, array_cont, inst_arr) in
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let typ_default = Typ.Tarray (typ_cont, typ_array_len) in
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[([], array_default, typ_default)]
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else if !Config.footprint then begin
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let atoms, elem_se, elem_typ =
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp typ_cont off inst in
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check_sound elem_typ;
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let cont_new = IList.sort Sil.exp_strexp_compare ((index, elem_se):: array_cont) in
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let array_new = Sil.Earray (array_len, cont_new, inst_arr) in
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let typ_new = Typ.Tarray (elem_typ, typ_array_len) in
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[(atoms, array_new, typ_new)]
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end
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else begin
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let res_new =
|
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if array_is_full then []
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else begin
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let atoms, elem_se, elem_typ =
|
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create_struct_values
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pname tenv orig_prop footprint_part kind max_stamp typ_cont off inst in
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check_sound elem_typ;
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let cont_new = IList.sort Sil.exp_strexp_compare ((index, elem_se):: array_cont) in
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let array_new = Sil.Earray (array_len, cont_new, inst_arr) in
|
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let typ_new = Typ.Tarray (elem_typ, typ_array_len) in
|
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[(atoms, array_new, typ_new)]
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end in
|
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let rec handle_case acc isel_seen_rev = function
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| [] -> IList.flatten (IList.rev (res_new:: acc))
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| (i, se) as ise :: isel_unseen ->
|
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let atoms_se_typ_list =
|
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_strexp_extend_values
|
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pname tenv orig_prop footprint_part kind max_stamp se typ_cont off inst in
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let atoms_se_typ_list' =
|
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IList.fold_left (fun acc' (atoms', se', typ') ->
|
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check_sound typ';
|
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let atoms_new = Sil.Aeq (index, i) :: atoms' in
|
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let isel_new = list_rev_and_concat isel_seen_rev ((i, se'):: isel_unseen) in
|
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let array_new = Sil.Earray (array_len, isel_new, inst_arr) in
|
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let typ_new = Typ.Tarray (typ', typ_array_len) in
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(atoms_new, array_new, typ_new):: acc'
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) [] atoms_se_typ_list in
|
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let acc_new = atoms_se_typ_list' :: acc in
|
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let isel_seen_rev_new = ise :: isel_seen_rev in
|
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handle_case acc_new isel_seen_rev_new isel_unseen in
|
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handle_case [] [] array_cont
|
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end
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|
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let exp_has_only_footprint_ids e =
|
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let fav = Sil.exp_fav e in
|
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Sil.fav_filter_ident fav (fun id -> not (Ident.is_footprint id));
|
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Sil.fav_is_empty fav
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|
|
|
let laundry_offset_for_footprint max_stamp offs_in =
|
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let rec laundry offs_seen eqs offs =
|
|
match offs with
|
|
| [] ->
|
|
(IList.rev offs_seen, IList.rev eqs)
|
|
| (Sil.Off_fld _ as off):: offs' ->
|
|
let offs_seen' = off:: offs_seen in
|
|
laundry offs_seen' eqs offs'
|
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| (Sil.Off_index(idx) as off):: offs' ->
|
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if exp_has_only_footprint_ids idx then
|
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let offs_seen' = off:: offs_seen in
|
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laundry offs_seen' eqs offs'
|
|
else
|
|
let () = incr max_stamp in
|
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let fid_new = Ident.create Ident.kfootprint !max_stamp in
|
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let exp_new = Exp.Var fid_new in
|
|
let off_new = Sil.Off_index exp_new in
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let offs_seen' = off_new:: offs_seen in
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let eqs' = (fid_new, idx):: eqs in
|
|
laundry offs_seen' eqs' offs' in
|
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laundry [] [] offs_in
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|
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let strexp_extend_values
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pname tenv orig_prop footprint_part kind max_stamp
|
|
se te (off : Sil.offset list) inst =
|
|
let typ = Exp.texp_to_typ None te in
|
|
let off', laundry_atoms =
|
|
let off', eqs = laundry_offset_for_footprint max_stamp off in
|
|
(* do laundry_offset whether footprint_part is true or not, so max_stamp is modified anyway *)
|
|
if footprint_part then
|
|
off', IList.map (fun (id, e) -> Prop.mk_eq (Exp.Var id) e) eqs
|
|
else off, [] in
|
|
if Config.trace_rearrange then
|
|
(L.d_str "entering strexp_extend_values se: "; Sil.d_sexp se; L.d_str " typ: ";
|
|
Typ.d_full typ; L.d_str " off': "; Sil.d_offset_list off';
|
|
L.d_strln (if footprint_part then " FP" else " RE"));
|
|
let atoms_se_typ_list =
|
|
_strexp_extend_values
|
|
pname tenv orig_prop footprint_part kind max_stamp se typ off' inst in
|
|
let atoms_se_typ_list_filtered =
|
|
let check_neg_atom atom = Prover.check_atom Prop.prop_emp (Prover.atom_negate atom) in
|
|
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 len, st = match te with
|
|
| Exp.Sizeof(_, len, st) -> (len, st)
|
|
| _ -> None, Subtype.exact in
|
|
IList.map (fun (atoms', se', typ') -> (laundry_atoms @ atoms', se', Exp.Sizeof (typ', len, st)))
|
|
atoms_se_typ_list_filtered
|
|
|
|
let collect_root_offset exp =
|
|
let root = Exp.root_of_lexp exp in
|
|
let offsets = Sil.exp_get_offsets exp in
|
|
(root, offsets)
|
|
|
|
(** Exp.Construct a points-to predicate for an expression, to add to a footprint. *)
|
|
let mk_ptsto_exp_footprint
|
|
pname tenv orig_prop (lexp, typ) max_stamp inst : Sil.hpred * Sil.hpred * Sil.atom list =
|
|
let root, off = collect_root_offset lexp in
|
|
if not (exp_has_only_footprint_ids root)
|
|
then begin
|
|
(* in angelic mode, purposely ignore dangling pointer warnings during the footprint phase -- we
|
|
* will fix them during the re - execution phase *)
|
|
if not (Config.angelic_execution && !Config.footprint) then
|
|
begin
|
|
if Config.developer_mode then
|
|
L.err "!!!! Footprint Error, Bad Root : %a !!!! @\n" (Sil.pp_exp pe_text) lexp;
|
|
let deref_str = Localise.deref_str_dangling None in
|
|
let err_desc =
|
|
Errdesc.explain_dereference deref_str orig_prop (State.get_loc ()) in
|
|
raise
|
|
(Exceptions.Dangling_pointer_dereference
|
|
(None, err_desc, __POS__))
|
|
end
|
|
end;
|
|
let off_foot, eqs = laundry_offset_for_footprint max_stamp off in
|
|
let st = match !Config.curr_language with
|
|
| Config.Clang -> Subtype.exact
|
|
| Config.Java -> Subtype.subtypes in
|
|
let create_ptsto footprint_part off0 = match root, off0, typ with
|
|
| Exp.Lvar pvar, [], Typ.Tfun _ ->
|
|
let fun_name = Procname.from_string_c_fun (Mangled.to_string (Pvar.get_name pvar)) in
|
|
let fun_exp = Exp.Const (Const.Cfun fun_name) in
|
|
([], Prop.mk_ptsto root (Sil.Eexp (fun_exp, inst)) (Exp.Sizeof (typ, None, st)))
|
|
| _, [], Typ.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 (Exp.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 (Exp.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
|
|
let atoms' = IList.map (fun (id, e) -> Prop.mk_eq (Exp.Var id) e) eqs in
|
|
(ptsto, ptsto_foot, atoms @ atoms')
|
|
|
|
(** Check if the path in exp exists already in the current ptsto predicate.
|
|
If it exists, return None. Otherwise, return [Some fld] with [fld] the missing field. *)
|
|
let prop_iter_check_fields_ptsto_shallow iter lexp =
|
|
let offset = Sil.exp_get_offsets lexp in
|
|
let (_, se, _) =
|
|
match Prop.prop_iter_current iter with
|
|
| Sil.Hpointsto (e, se, t), _ -> (e, se, t)
|
|
| _ -> assert false in
|
|
let rec check_offset se = function
|
|
| [] -> None
|
|
| (Sil.Off_fld (fld, _)):: off' ->
|
|
(match se with
|
|
| Sil.Estruct (fsel, _) ->
|
|
(try
|
|
let _, se' = IList.find (fun (fld', _) -> Ident.fieldname_equal fld fld') fsel in
|
|
check_offset se' off'
|
|
with Not_found -> Some fld)
|
|
| _ -> Some fld)
|
|
| (Sil.Off_index _):: _ -> None in
|
|
check_offset se offset
|
|
|
|
let fav_max_stamp fav =
|
|
let max_stamp = ref 0 in
|
|
let f id = max_stamp := max !max_stamp (Ident.get_stamp id) in
|
|
IList.iter f (Sil.fav_to_list fav);
|
|
max_stamp
|
|
|
|
(** [prop_iter_extend_ptsto iter lexp] extends the current psto
|
|
predicate in [iter] with enough fields to follow the path in
|
|
[lexp] -- field splitting model. It also materializes all
|
|
indices accessed in lexp. *)
|
|
let prop_iter_extend_ptsto pname tenv orig_prop iter lexp inst =
|
|
if Config.trace_rearrange then
|
|
(L.d_str "entering prop_iter_extend_ptsto lexp: "; Sil.d_exp lexp; L.d_ln ());
|
|
let offset = Sil.exp_get_offsets lexp in
|
|
let max_stamp = fav_max_stamp (Prop.prop_iter_fav iter) in
|
|
let max_stamp_val = !max_stamp in
|
|
let extend_footprint_pred = function
|
|
| Sil.Hpointsto(e, se, te) ->
|
|
let atoms_se_te_list =
|
|
strexp_extend_values
|
|
pname tenv orig_prop true Ident.kfootprint (ref max_stamp_val) se te offset inst in
|
|
IList.map (fun (atoms', se', te') -> (atoms', Sil.Hpointsto (e, se', te'))) atoms_se_te_list
|
|
| Sil.Hlseg (k, hpara, e1, e2, el) ->
|
|
begin
|
|
match hpara.Sil.body with
|
|
| Sil.Hpointsto(e', se', te'):: body_rest ->
|
|
let atoms_se_te_list =
|
|
strexp_extend_values
|
|
pname tenv orig_prop true Ident.kfootprint
|
|
(ref max_stamp_val) se' te' offset inst in
|
|
let atoms_body_list =
|
|
IList.map (fun (atoms0, se0, te0) -> (atoms0, Sil.Hpointsto(e', se0, te0):: body_rest)) atoms_se_te_list in
|
|
let atoms_hpara_list =
|
|
IList.map (fun (atoms, body') -> (atoms, { hpara with Sil.body = body'})) atoms_body_list in
|
|
IList.map (fun (atoms, hpara') -> (atoms, Sil.Hlseg(k, hpara', e1, e2, el))) atoms_hpara_list
|
|
| _ -> assert false
|
|
end
|
|
| _ -> assert false in
|
|
let atoms_se_te_to_iter e (atoms, se, te) =
|
|
let iter' = IList.fold_left (Prop.prop_iter_add_atom !Config.footprint) iter atoms in
|
|
Prop.prop_iter_update_current iter' (Sil.Hpointsto (e, se, te)) in
|
|
let do_extend e se te =
|
|
if Config.trace_rearrange then begin
|
|
L.d_strln "entering do_extend";
|
|
L.d_str "e: "; Sil.d_exp e; L.d_str " se : "; Sil.d_sexp se; L.d_str " te: "; Sil.d_texp_full te;
|
|
L.d_ln (); L.d_ln ()
|
|
end;
|
|
let extend_kind = match e with (* Determine whether to extend the footprint part or just the normal part *)
|
|
| Exp.Var id when not (Ident.is_footprint id) -> Ident.kprimed
|
|
| Exp.Lvar pvar when Pvar.is_local pvar -> Ident.kprimed
|
|
| _ -> Ident.kfootprint in
|
|
let iter_list =
|
|
let atoms_se_te_list =
|
|
strexp_extend_values
|
|
pname tenv orig_prop false extend_kind max_stamp se te offset inst in
|
|
IList.map (atoms_se_te_to_iter e) atoms_se_te_list in
|
|
let res_iter_list =
|
|
if Ident.kind_equal extend_kind Ident.kprimed
|
|
then iter_list (* normal part already extended: nothing to do *)
|
|
else (* extend footprint part *)
|
|
let atoms_fp_sigma_list =
|
|
let footprint_sigma = Prop.prop_iter_get_footprint_sigma iter in
|
|
let sigma_pto, sigma_rest =
|
|
IList.partition (function
|
|
| Sil.Hpointsto(e', _, _) -> Exp.equal e e'
|
|
| Sil.Hlseg (_, _, e1, _, _) -> Exp.equal e e1
|
|
| Sil.Hdllseg (_, _, e_iF, _, _, e_iB, _) ->
|
|
Exp.equal e e_iF || Exp.equal e e_iB
|
|
) footprint_sigma in
|
|
let atoms_sigma_list =
|
|
match sigma_pto with
|
|
| [hpred] ->
|
|
let atoms_hpred_list = extend_footprint_pred hpred in
|
|
IList.map (fun (atoms, hpred') -> (atoms, hpred' :: sigma_rest)) atoms_hpred_list
|
|
| _ ->
|
|
L.d_warning "Cannot extend "; Sil.d_exp lexp; L.d_strln " in"; Prop.d_prop (Prop.prop_iter_to_prop iter); L.d_ln();
|
|
[([], footprint_sigma)] in
|
|
IList.map (fun (atoms, sigma') -> (atoms, IList.stable_sort Sil.hpred_compare sigma')) atoms_sigma_list in
|
|
let iter_atoms_fp_sigma_list =
|
|
list_product iter_list atoms_fp_sigma_list in
|
|
IList.map (fun (iter, (atoms, fp_sigma)) ->
|
|
let iter' = IList.fold_left (Prop.prop_iter_add_atom !Config.footprint) iter atoms in
|
|
Prop.prop_iter_replace_footprint_sigma iter' fp_sigma
|
|
) iter_atoms_fp_sigma_list in
|
|
let res_prop_list =
|
|
IList.map Prop.prop_iter_to_prop res_iter_list in
|
|
begin
|
|
L.d_str "in prop_iter_extend_ptsto lexp: "; Sil.d_exp lexp; L.d_ln ();
|
|
L.d_strln "prop before:";
|
|
let prop_before = Prop.prop_iter_to_prop iter in
|
|
Prop.d_prop prop_before; L.d_ln ();
|
|
L.d_ln (); L.d_ln ();
|
|
L.d_strln "prop list after:";
|
|
Propgraph.d_proplist prop_before res_prop_list; L.d_ln ();
|
|
L.d_ln (); L.d_ln ();
|
|
res_iter_list
|
|
end in
|
|
begin
|
|
match Prop.prop_iter_current iter with
|
|
| Sil.Hpointsto (e, se, te), _ -> do_extend e se te
|
|
| _ -> assert false
|
|
end
|
|
|
|
(** Add a pointsto for [root(lexp): typ] to the sigma and footprint of a
|
|
prop, if it's compatible with the allowed footprint
|
|
variables. Then, change it into a iterator. This function ensures
|
|
that [root(lexp): typ] is the current hpred of the iterator. typ
|
|
is the type of the root of lexp. *)
|
|
let prop_iter_add_hpred_footprint_to_prop pname tenv prop (lexp, typ) inst =
|
|
let max_stamp = fav_max_stamp (Prop.prop_footprint_fav prop) in
|
|
let ptsto, ptsto_foot, atoms =
|
|
mk_ptsto_exp_footprint pname tenv prop (lexp, typ) max_stamp inst in
|
|
L.d_strln "++++ Adding footprint frame";
|
|
Prop.d_prop (Prop.prop_hpred_star Prop.prop_emp ptsto);
|
|
L.d_ln (); L.d_ln ();
|
|
let eprop = Prop.expose prop in
|
|
let sigma_fp = ptsto_foot :: eprop.Prop.sigma_fp in
|
|
let nsigma_fp = Prop.sigma_normalize_prop Prop.prop_emp sigma_fp in
|
|
let prop' = Prop.normalize (Prop.set eprop ~sigma_fp:nsigma_fp) in
|
|
let prop_new = IList.fold_left (Prop.prop_atom_and ~footprint:!Config.footprint) prop' atoms in
|
|
let iter = match (Prop.prop_iter_create prop_new) with
|
|
| None ->
|
|
let prop_new' = Prop.normalize (Prop.prop_hpred_star prop_new ptsto) in
|
|
begin
|
|
match (Prop.prop_iter_create prop_new') with
|
|
| None -> assert false
|
|
| Some iter -> iter
|
|
end
|
|
| Some iter -> Prop.prop_iter_prev_then_insert iter ptsto in
|
|
let offsets_default = Sil.exp_get_offsets lexp in
|
|
Prop.prop_iter_set_state iter offsets_default
|
|
|
|
(** If [lexp] is an access to a field that is annotated with @GuardedBy, add constraints to [prop]
|
|
expressing the safety conditions for the access. Complain if these conditions cannot be met. *)
|
|
let add_guarded_by_constraints prop lexp pdesc =
|
|
let pname = Cfg.Procdesc.get_proc_name pdesc in
|
|
let excluded_guardedby_string str =
|
|
(* nothing with a space in it can be a valid Java expression, shouldn't warn *)
|
|
let is_invalid_exp_str str =
|
|
String.contains str ' ' in
|
|
(* don't warn on @GuardedBy("ui_thread") in any form *)
|
|
let is_ui_thread str =
|
|
let lowercase_str = String.lowercase str in
|
|
lowercase_str = "ui_thread" || lowercase_str = "ui-thread" || lowercase_str = "uithread" in
|
|
is_invalid_exp_str str || is_ui_thread str in
|
|
let guarded_by_str_is_this guarded_by_str =
|
|
string_is_suffix "this" guarded_by_str in
|
|
let guarded_by_str_is_class guarded_by_str class_str =
|
|
string_is_suffix guarded_by_str (class_str ^ ".class") in
|
|
let guarded_by_str_is_current_class guarded_by_str = function
|
|
| Procname.Java java_pname ->
|
|
(* programmers write @GuardedBy("MyClass.class") when the field is guarded by the class *)
|
|
guarded_by_str_is_class guarded_by_str (Procname.java_get_class_name java_pname)
|
|
| _ -> false in
|
|
(* return true if [guarded_by_str] is as suffix of "<name_of_current_proc>.this" *)
|
|
let guarded_by_str_is_current_class_this guarded_by_str = function
|
|
| Procname.Java java_pname ->
|
|
let fully_qualified_this =
|
|
Printf.sprintf "%s.this" (Procname.java_get_class_name java_pname) in
|
|
string_is_suffix guarded_by_str fully_qualified_this
|
|
| _ -> false in
|
|
let extract_guarded_by_str item_annot =
|
|
let annot_extract_guarded_by_str (annot, _) =
|
|
if Annotations.annot_ends_with annot Annotations.guarded_by
|
|
then
|
|
match annot.Typ.parameters with
|
|
| [guarded_by_str] when not (excluded_guardedby_string guarded_by_str) ->
|
|
Some guarded_by_str
|
|
| _ ->
|
|
None
|
|
else
|
|
None in
|
|
IList.find_map_opt annot_extract_guarded_by_str item_annot in
|
|
(* if [fld] is annotated with @GuardedBy("mLock"), return mLock *)
|
|
let get_guarded_by_fld_str fld typ =
|
|
match Typ.get_field_type_and_annotation fld typ with
|
|
| Some (_, item_annot) ->
|
|
begin
|
|
match extract_guarded_by_str item_annot with
|
|
| Some "this" ->
|
|
(* expand "this" into <classname>.this *)
|
|
Some (Printf.sprintf "%s.this" (Ident.java_fieldname_get_class fld))
|
|
| guarded_by_str_opt ->
|
|
guarded_by_str_opt
|
|
end
|
|
| _ -> None in
|
|
(* find A.guarded_by_fld_str |-> B and return Some B, or None if there is no such hpred *)
|
|
let find_guarded_by_exp guarded_by_str sigma =
|
|
let is_guarded_by_strexp (fld, _) =
|
|
(* this comparison needs to be somewhat fuzzy, since programmers are free to write
|
|
@GuardedBy("mLock"), @GuardedBy("MyClass.mLock"), or use other conventions *)
|
|
Ident.fieldname_to_flat_string fld = guarded_by_str ||
|
|
Ident.fieldname_to_string fld = guarded_by_str in
|
|
IList.find_map_opt
|
|
(function
|
|
| Sil.Hpointsto ((Const (Cclass clazz) as lhs_exp), _, Exp.Sizeof (typ, _, _))
|
|
when guarded_by_str_is_class guarded_by_str (Ident.name_to_string clazz) ->
|
|
Some (Sil.Eexp (lhs_exp, Sil.inst_none), typ)
|
|
| Sil.Hpointsto (_, Estruct (flds, _), Exp.Sizeof (typ, _, _)) ->
|
|
let get_fld_strexp_and_typ f flds =
|
|
try
|
|
let fld, strexp = IList.find f flds in
|
|
begin
|
|
match Typ.get_field_type_and_annotation fld typ with
|
|
| Some (fld_typ, _) -> Some (strexp, fld_typ)
|
|
| None -> None
|
|
end
|
|
with Not_found -> None in
|
|
begin
|
|
(* first, try to find a field that exactly matches the guarded-by string *)
|
|
match get_fld_strexp_and_typ is_guarded_by_strexp flds with
|
|
| None when guarded_by_str_is_this guarded_by_str ->
|
|
(* if the guarded-by string is "OuterClass.this", look for "this$n" for some n.
|
|
note that this is a bit sketchy when there are mutliple this$n's, but there's
|
|
nothing we can do to disambiguate them. *)
|
|
get_fld_strexp_and_typ
|
|
(fun (f, _) -> Ident.java_fieldname_is_outer_instance f)
|
|
flds
|
|
| res ->
|
|
res
|
|
end
|
|
| Sil.Hpointsto (Lvar pvar, rhs_exp, Exp.Sizeof (typ, _, _))
|
|
when guarded_by_str_is_current_class_this guarded_by_str pname && Pvar.is_this pvar ->
|
|
Some (rhs_exp, typ)
|
|
| _ ->
|
|
None)
|
|
sigma in
|
|
(* warn if the access to [lexp] is not protected by the [guarded_by_fld_str] lock *)
|
|
let enforce_guarded_access_ accessed_fld guarded_by_str prop =
|
|
(* return true if [pdesc] has an annotation that matches [guarded_by_str] *)
|
|
let proc_has_matching_annot pdesc guarded_by_str =
|
|
let proc_signature =
|
|
Annotations.get_annotated_signature (Cfg.Procdesc.get_attributes pdesc) in
|
|
let proc_annot, _ = proc_signature.Annotations.ret in
|
|
match extract_guarded_by_str proc_annot with
|
|
| Some proc_guarded_by_str ->
|
|
(* the lock is not held, but the procedure is annotated with @GuardedBy *)
|
|
proc_guarded_by_str = guarded_by_str
|
|
| None -> false in
|
|
let is_synchronized_on_class guarded_by_str =
|
|
guarded_by_str_is_current_class guarded_by_str pname &&
|
|
Cfg.Procdesc.is_java_synchronized pdesc && Procname.java_is_static pname in
|
|
let warn accessed_fld guarded_by_str =
|
|
let loc = State.get_loc () in
|
|
let err_desc =
|
|
Localise.desc_unsafe_guarded_by_access pname accessed_fld guarded_by_str loc in
|
|
let exn = Exceptions.Unsafe_guarded_by_access (err_desc, __POS__) in
|
|
Reporting.log_error pname exn in
|
|
let rec is_read_write_lock typ =
|
|
let str_is_read_write_lock str = string_is_suffix "ReadWriteUpdateLock" str in
|
|
match typ with
|
|
| Typ.Tstruct { struct_name=Some name} -> str_is_read_write_lock (Mangled.to_string name)
|
|
| Typ.Tvar name -> str_is_read_write_lock (Typename.to_string name)
|
|
| Typ.Tptr (typ, _) -> is_read_write_lock typ
|
|
| _ -> false in
|
|
let has_lock guarded_by_exp =
|
|
(* procedure is synchronized and guarded by this *)
|
|
(guarded_by_str_is_current_class_this guarded_by_str pname &&
|
|
Cfg.Procdesc.is_java_synchronized pdesc) ||
|
|
(guarded_by_str_is_current_class guarded_by_str pname &&
|
|
Cfg.Procdesc.is_java_synchronized pdesc && Procname.java_is_static pname) ||
|
|
(* or the prop says we already have the lock *)
|
|
IList.exists
|
|
(function
|
|
| Sil.Apred (Alocked, _) -> true
|
|
| _ -> false)
|
|
(Attribute.get_for_exp prop guarded_by_exp) in
|
|
let should_warn pdesc =
|
|
(* adding this check implements "by reference" semantics for guarded-by rather than "by value"
|
|
semantics. if this access is through a local L or field V.f
|
|
(where f is not the @GuardedBy field!), we will not warn.
|
|
*)
|
|
let is_accessible_through_local_ref exp =
|
|
IList.exists
|
|
(function
|
|
| Sil.Hpointsto (Lvar _, Eexp (rhs_exp, _), _) ->
|
|
Exp.equal exp rhs_exp
|
|
| Sil.Hpointsto (_, Estruct (flds, _), _) ->
|
|
IList.exists
|
|
(fun (fld, strexp) -> match strexp with
|
|
| Sil.Eexp (rhs_exp, _) ->
|
|
Exp.equal exp rhs_exp && not (Ident.fieldname_equal fld accessed_fld)
|
|
| _ ->
|
|
false)
|
|
flds
|
|
| _ -> false)
|
|
prop.Prop.sigma in
|
|
Cfg.Procdesc.get_access pdesc <> PredSymb.Private &&
|
|
not (Annotations.pdesc_has_annot pdesc Annotations.visibleForTesting) &&
|
|
not (Procname.java_is_access_method (Cfg.Procdesc.get_proc_name pdesc)) &&
|
|
not (is_accessible_through_local_ref lexp) in
|
|
match find_guarded_by_exp guarded_by_str prop.Prop.sigma with
|
|
| Some (Sil.Eexp (guarded_by_exp, _), typ) ->
|
|
if is_read_write_lock typ
|
|
then
|
|
(* TODO: model/understand read-write locks rather than ignoring them *)
|
|
prop
|
|
else if has_lock guarded_by_exp
|
|
then
|
|
(* we have the lock; no need to add a proof obligation *)
|
|
(* TODO: materialize [fld], but don't add [fld] to the footprint. *)
|
|
prop
|
|
else
|
|
(* we don't know if we have the lock or not. *)
|
|
if should_warn pdesc
|
|
then
|
|
begin
|
|
(* non-private method; can't ensure that the lock is held. warn. *)
|
|
warn accessed_fld guarded_by_str;
|
|
prop
|
|
end
|
|
else
|
|
(* private method. add locked proof obligation to [pdesc] *)
|
|
Attribute.add ~footprint:true prop Alocked [guarded_by_exp]
|
|
| _ ->
|
|
if not (proc_has_matching_annot pdesc guarded_by_str
|
|
|| is_synchronized_on_class guarded_by_str) && should_warn pdesc
|
|
then
|
|
(* can't find the object the annotation refers to, and procedure is not annotated. warn *)
|
|
warn accessed_fld guarded_by_str
|
|
else
|
|
(* procedure has same GuardedBy annotation as the field. we would like to add a proof
|
|
obligation, but we can't (because we can't find an expression corresponding to the
|
|
lock in the current prop). so just be silent. *)
|
|
();
|
|
prop in
|
|
let enforce_guarded_access fld typ prop =
|
|
match get_guarded_by_fld_str fld typ with
|
|
| Some guarded_by_fld_str -> enforce_guarded_access_ fld guarded_by_fld_str prop
|
|
| None -> prop in
|
|
let check_fld_locks typ prop_acc (fld, strexp) = match strexp with
|
|
| Sil.Eexp (exp, _) when Exp.equal exp lexp -> enforce_guarded_access fld typ prop_acc
|
|
| _ -> prop_acc in
|
|
let hpred_check_flds prop_acc = function
|
|
| Sil.Hpointsto (_, Estruct (flds, _), Sizeof (typ, _, _)) ->
|
|
IList.fold_left (check_fld_locks typ) prop_acc flds
|
|
| _ ->
|
|
prop_acc in
|
|
match lexp with
|
|
| Exp.Lfield (_, fld, typ) ->
|
|
(* check for direct access to field annotated with @GuardedBy *)
|
|
enforce_guarded_access fld typ prop
|
|
| _ ->
|
|
(* check for access via alias *)
|
|
IList.fold_left hpred_check_flds prop prop.Prop.sigma
|
|
|
|
(** Add a pointsto for [root(lexp): typ] to the iterator and to the
|
|
footprint, if it's compatible with the allowed footprint
|
|
variables. This function ensures that [root(lexp): typ] is the
|
|
current hpred of the iterator. typ is the type of the root of lexp. *)
|
|
let prop_iter_add_hpred_footprint pname tenv orig_prop iter (lexp, typ) inst =
|
|
let max_stamp = fav_max_stamp (Prop.prop_iter_footprint_fav iter) in
|
|
let ptsto, ptsto_foot, atoms =
|
|
mk_ptsto_exp_footprint pname tenv orig_prop (lexp, typ) max_stamp inst in
|
|
L.d_strln "++++ Adding footprint frame";
|
|
Prop.d_prop (Prop.prop_hpred_star Prop.prop_emp ptsto);
|
|
L.d_ln (); L.d_ln ();
|
|
let sigma_fp = ptsto_foot :: (Prop.prop_iter_get_footprint_sigma iter) in
|
|
let iter_foot = Prop.prop_iter_prev_then_insert iter ptsto in
|
|
let iter_foot_atoms = IList.fold_left (Prop.prop_iter_add_atom (!Config.footprint)) iter_foot atoms in
|
|
let iter' = Prop.prop_iter_replace_footprint_sigma iter_foot_atoms sigma_fp in
|
|
let offsets_default = Sil.exp_get_offsets lexp in
|
|
Prop.prop_iter_set_state iter' offsets_default
|
|
|
|
exception ARRAY_ACCESS
|
|
|
|
let rearrange_arith lexp prop =
|
|
if Config.trace_rearrange then begin
|
|
L.d_strln "entering rearrange_arith";
|
|
L.d_str "lexp: "; Sil.d_exp lexp; L.d_ln ();
|
|
L.d_str "prop: "; L.d_ln (); Prop.d_prop prop; L.d_ln (); L.d_ln ()
|
|
end;
|
|
if (Config.array_level >= 2) then raise ARRAY_ACCESS
|
|
else
|
|
let root = Exp.root_of_lexp lexp in
|
|
if Prover.check_allocatedness prop root then
|
|
raise ARRAY_ACCESS
|
|
else
|
|
raise (Exceptions.Symexec_memory_error __POS__)
|
|
|
|
let pp_rearrangement_error message prop lexp =
|
|
L.d_strln (".... Rearrangement Error .... " ^ message);
|
|
L.d_str "Exp:"; Sil.d_exp lexp; L.d_ln ();
|
|
L.d_str "Prop:"; L.d_ln (); Prop.d_prop prop; L.d_ln (); L.d_ln ()
|
|
|
|
(** do re-arrangment for an iter whose current element is a pointsto *)
|
|
let iter_rearrange_ptsto pname tenv orig_prop iter lexp inst =
|
|
if Config.trace_rearrange then begin
|
|
L.d_increase_indent 1;
|
|
L.d_strln "entering iter_rearrange_ptsto";
|
|
L.d_str "lexp: "; Sil.d_exp lexp; L.d_ln ();
|
|
L.d_strln "prop:"; Prop.d_prop orig_prop; L.d_ln ();
|
|
L.d_strln "iter:"; Prop.d_prop (Prop.prop_iter_to_prop iter);
|
|
L.d_ln (); L.d_ln ()
|
|
end;
|
|
let check_field_splitting () =
|
|
match prop_iter_check_fields_ptsto_shallow iter lexp with
|
|
| None -> ()
|
|
| Some fld ->
|
|
begin
|
|
pp_rearrangement_error "field splitting check failed" orig_prop lexp;
|
|
raise (Exceptions.Missing_fld (fld, __POS__))
|
|
end in
|
|
let res =
|
|
if !Config.footprint
|
|
then
|
|
prop_iter_extend_ptsto pname tenv orig_prop iter lexp inst
|
|
else
|
|
begin
|
|
check_field_splitting ();
|
|
match Prop.prop_iter_current iter with
|
|
| Sil.Hpointsto (e, se, te), offset ->
|
|
let max_stamp = fav_max_stamp (Prop.prop_iter_fav iter) in
|
|
let atoms_se_te_list =
|
|
strexp_extend_values
|
|
pname tenv orig_prop false Ident.kprimed max_stamp se te offset inst in
|
|
let handle_case (atoms', se', te') =
|
|
let iter' = IList.fold_left (Prop.prop_iter_add_atom !Config.footprint) iter atoms' in
|
|
Prop.prop_iter_update_current iter' (Sil.Hpointsto (e, se', te')) in
|
|
let filter it =
|
|
let p = Prop.prop_iter_to_prop it in
|
|
not (Prover.check_inconsistency p) in
|
|
IList.filter filter (IList.map handle_case atoms_se_te_list)
|
|
| _ -> [iter]
|
|
end in
|
|
begin
|
|
if Config.trace_rearrange then begin
|
|
L.d_strln "exiting iter_rearrange_ptsto, returning results";
|
|
Prop.d_proplist_with_typ (IList.map Prop.prop_iter_to_prop res);
|
|
L.d_decrease_indent 1;
|
|
L.d_ln (); L.d_ln ()
|
|
end;
|
|
res
|
|
end
|
|
|
|
(** do re-arrangment for an iter whose current element is a nonempty listseg *)
|
|
let iter_rearrange_ne_lseg recurse_on_iters iter para e1 e2 elist =
|
|
if Config.nelseg then
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_inst1) = Sil.hpara_instantiate para e1 n' elist in
|
|
let hpred_list1 = para_inst1@[Prop.mk_lseg Sil.Lseg_NE para n' e2 elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_base_case =
|
|
let (_, para_inst) = Sil.hpara_instantiate para e1 e2 elist in
|
|
Prop.prop_iter_update_current_by_list iter para_inst in
|
|
recurse_on_iters [iter_inductive_case; iter_base_case]
|
|
else
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_inst1) = Sil.hpara_instantiate para e1 n' elist in
|
|
let hpred_list1 = para_inst1@[Prop.mk_lseg Sil.Lseg_PE para n' e2 elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
recurse_on_iters [iter_inductive_case]
|
|
|
|
(** do re-arrangment for an iter whose current element is a nonempty dllseg to be unrolled from lhs *)
|
|
let iter_rearrange_ne_dllseg_first recurse_on_iters iter para_dll e1 e2 e3 e4 elist =
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_dll_inst1) = Sil.hpara_dll_instantiate para_dll e1 e2 n' elist in
|
|
let hpred_list1 = para_dll_inst1@[Prop.mk_dllseg Sil.Lseg_NE para_dll n' e1 e3 e4 elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_base_case =
|
|
let (_, para_dll_inst) = Sil.hpara_dll_instantiate para_dll e1 e2 e3 elist in
|
|
let iter' = Prop.prop_iter_update_current_by_list iter para_dll_inst in
|
|
let prop' = Prop.prop_iter_to_prop iter' in
|
|
let prop'' = Prop.conjoin_eq ~footprint: (!Config.footprint) e1 e4 prop' in
|
|
match (Prop.prop_iter_create prop'') with
|
|
| None -> assert false
|
|
| Some iter' -> iter' in
|
|
recurse_on_iters [iter_inductive_case; iter_base_case]
|
|
|
|
(** do re-arrangment for an iter whose current element is a nonempty dllseg to be unrolled from rhs *)
|
|
let iter_rearrange_ne_dllseg_last recurse_on_iters iter para_dll e1 e2 e3 e4 elist =
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_dll_inst1) = Sil.hpara_dll_instantiate para_dll e4 n' e3 elist in
|
|
let hpred_list1 = para_dll_inst1@[Prop.mk_dllseg Sil.Lseg_NE para_dll e1 e2 e4 n' elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_base_case =
|
|
let (_, para_dll_inst) = Sil.hpara_dll_instantiate para_dll e4 e2 e3 elist in
|
|
let iter' = Prop.prop_iter_update_current_by_list iter para_dll_inst in
|
|
let prop' = Prop.prop_iter_to_prop iter' in
|
|
let prop'' = Prop.conjoin_eq ~footprint: (!Config.footprint) e1 e4 prop' in
|
|
match (Prop.prop_iter_create prop'') with
|
|
| None -> assert false
|
|
| Some iter' -> iter' in
|
|
recurse_on_iters [iter_inductive_case; iter_base_case]
|
|
|
|
(** do re-arrangment for an iter whose current element is a possibly empty listseg *)
|
|
let iter_rearrange_pe_lseg recurse_on_iters default_case_iter iter para e1 e2 elist =
|
|
let iter_nonemp_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_inst1) = Sil.hpara_instantiate para e1 n' elist in
|
|
let hpred_list1 = para_inst1@[Prop.mk_lseg Sil.Lseg_PE para n' e2 elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_subcases =
|
|
let removed_prop = Prop.prop_iter_remove_curr_then_to_prop iter in
|
|
let prop' = Prop.conjoin_eq ~footprint: (!Config.footprint) e1 e2 removed_prop in
|
|
match (Prop.prop_iter_create prop') with
|
|
| None ->
|
|
let iter' = default_case_iter (Prop.prop_iter_set_state iter ()) in
|
|
[Prop.prop_iter_set_state iter' ()]
|
|
| Some iter' -> [iter_nonemp_case; iter'] in
|
|
recurse_on_iters iter_subcases
|
|
|
|
(** do re-arrangment for an iter whose current element is a possibly empty dllseg to be unrolled from lhs *)
|
|
let iter_rearrange_pe_dllseg_first recurse_on_iters default_case_iter iter para_dll e1 e2 e3 e4 elist =
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_dll_inst1) = Sil.hpara_dll_instantiate para_dll e1 e2 n' elist in
|
|
let hpred_list1 = para_dll_inst1@[Prop.mk_dllseg Sil.Lseg_PE para_dll n' e1 e3 e4 elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_subcases =
|
|
let removed_prop = Prop.prop_iter_remove_curr_then_to_prop iter in
|
|
let prop' = Prop.conjoin_eq ~footprint: (!Config.footprint) e1 e3 removed_prop in
|
|
let prop'' = Prop.conjoin_eq ~footprint: (!Config.footprint) e2 e4 prop' in
|
|
match (Prop.prop_iter_create prop'') with
|
|
| None ->
|
|
let iter' = default_case_iter (Prop.prop_iter_set_state iter ()) in
|
|
[Prop.prop_iter_set_state iter' ()]
|
|
| Some iter' -> [iter_inductive_case; iter'] in
|
|
recurse_on_iters iter_subcases
|
|
|
|
(** do re-arrangment for an iter whose current element is a possibly empty dllseg to be unrolled from rhs *)
|
|
let iter_rearrange_pe_dllseg_last recurse_on_iters default_case_iter iter para_dll e1 e2 e3 e4 elist =
|
|
let iter_inductive_case =
|
|
let n' = Exp.Var (Ident.create_fresh Ident.kprimed) in
|
|
let (_, para_dll_inst1) = Sil.hpara_dll_instantiate para_dll e4 n' e3 elist in
|
|
let hpred_list1 = para_dll_inst1@[Prop.mk_dllseg Sil.Lseg_PE para_dll e1 e2 e4 n' elist] in
|
|
Prop.prop_iter_update_current_by_list iter hpred_list1 in
|
|
let iter_subcases =
|
|
let removed_prop = Prop.prop_iter_remove_curr_then_to_prop iter in
|
|
let prop' = Prop.conjoin_eq ~footprint: (!Config.footprint) e1 e3 removed_prop in
|
|
let prop'' = Prop.conjoin_eq ~footprint: (!Config.footprint) e2 e4 prop' in
|
|
match (Prop.prop_iter_create prop'') with
|
|
| None ->
|
|
let iter' = default_case_iter (Prop.prop_iter_set_state iter ()) in
|
|
[Prop.prop_iter_set_state iter' ()]
|
|
| Some iter' -> [iter_inductive_case; iter'] in
|
|
recurse_on_iters iter_subcases
|
|
|
|
(** find the type at the offset from the given type expression, if any *)
|
|
let type_at_offset texp off =
|
|
let rec strip_offset off typ = match off, typ with
|
|
| [], _ -> Some typ
|
|
| (Sil.Off_fld (f, _)):: off', Typ.Tstruct { Typ.instance_fields } ->
|
|
(try
|
|
let typ' =
|
|
(fun (_, y, _) -> y)
|
|
(IList.find (fun (f', _, _) -> Ident.fieldname_equal f f') instance_fields) in
|
|
strip_offset off' typ'
|
|
with Not_found -> None)
|
|
| (Sil.Off_index _) :: off', Typ.Tarray (typ', _) ->
|
|
strip_offset off' typ'
|
|
| _ -> None in
|
|
match texp with
|
|
| Exp.Sizeof(typ, _, _) ->
|
|
strip_offset off typ
|
|
| _ -> None
|
|
|
|
(** Check that the size of a type coming from an instruction does not exceed the size of the type from the pointsto predicate
|
|
For example, that a pointer to int is not used to assign to a char *)
|
|
let check_type_size pname prop texp off typ_from_instr =
|
|
L.d_strln_color Orange "check_type_size";
|
|
L.d_str "off: "; Sil.d_offset_list off; L.d_ln ();
|
|
L.d_str "typ_from_instr: "; Typ.d_full typ_from_instr; L.d_ln ();
|
|
match type_at_offset texp off with
|
|
| Some typ_of_object ->
|
|
L.d_str "typ_o: "; Typ.d_full typ_of_object; L.d_ln ();
|
|
if Prover.type_size_comparable typ_from_instr typ_of_object && Prover.check_type_size_leq typ_from_instr typ_of_object = false
|
|
then begin
|
|
let deref_str = Localise.deref_str_pointer_size_mismatch typ_from_instr typ_of_object in
|
|
let loc = State.get_loc () in
|
|
let exn =
|
|
Exceptions.Pointer_size_mismatch (
|
|
Errdesc.explain_dereference deref_str prop loc, __POS__) in
|
|
let pre_opt = State.get_normalized_pre (Abs.abstract_no_symop pname) in
|
|
Reporting.log_warning pname ~pre: pre_opt exn
|
|
end
|
|
| None ->
|
|
L.d_str "texp: "; Sil.d_texp_full texp; L.d_ln ()
|
|
|
|
(** Exposes lexp |->- from iter. In case that it is not possible to
|
|
* expose lexp |->-, this function prints an error message and
|
|
* faults. There are four things to note. First, typ is the type of the
|
|
* root of lexp. Second, prop should mean the same as iter. Third, the
|
|
* result [] means that the given input iter is inconsistent. This
|
|
* happens when the theorem prover can prove the inconsistency of prop,
|
|
* only after unrolling some predicates in prop. This function ensures
|
|
* that the theorem prover cannot prove the inconsistency of any of the
|
|
* new iters in the result. *)
|
|
let rec iter_rearrange
|
|
pname tenv lexp typ_from_instr prop iter
|
|
inst: (Sil.offset list) Prop.prop_iter list =
|
|
let typ = match Sil.exp_get_offsets lexp with
|
|
| Sil.Off_fld (f, ((Typ.Tstruct _) as struct_typ)) :: _ ->
|
|
(* access through field: get the struct type from the field *)
|
|
if Config.trace_rearrange then begin
|
|
L.d_increase_indent 1;
|
|
L.d_str "iter_rearrange: root of lexp accesses field "; L.d_strln (Ident.fieldname_to_string f);
|
|
L.d_str " type from instruction: "; Typ.d_full typ_from_instr; L.d_ln();
|
|
L.d_str " struct type from field: "; Typ.d_full struct_typ; L.d_ln();
|
|
L.d_decrease_indent 1;
|
|
L.d_ln();
|
|
end;
|
|
struct_typ
|
|
| _ ->
|
|
typ_from_instr in
|
|
if Config.trace_rearrange then begin
|
|
L.d_increase_indent 1;
|
|
L.d_strln "entering iter_rearrange";
|
|
L.d_str "lexp: "; Sil.d_exp lexp; L.d_ln ();
|
|
L.d_str "typ: "; Typ.d_full typ; L.d_ln ();
|
|
L.d_strln "prop:"; Prop.d_prop prop; L.d_ln ();
|
|
L.d_strln "iter:"; Prop.d_prop (Prop.prop_iter_to_prop iter);
|
|
L.d_ln (); L.d_ln ()
|
|
end;
|
|
let default_case_iter (iter': unit Prop.prop_iter) =
|
|
if Config.trace_rearrange then L.d_strln "entering default_case_iter";
|
|
if !Config.footprint then
|
|
prop_iter_add_hpred_footprint pname tenv prop iter' (lexp, typ) inst
|
|
else
|
|
if (Config.array_level >= 1 && not !Config.footprint && Exp.pointer_arith lexp)
|
|
then rearrange_arith lexp prop
|
|
else begin
|
|
pp_rearrangement_error "cannot find predicate with root" prop lexp;
|
|
if not !Config.footprint then Printer.force_delayed_prints ();
|
|
raise (Exceptions.Symexec_memory_error __POS__)
|
|
end in
|
|
let recurse_on_iters iters =
|
|
let f_one_iter iter' =
|
|
let prop' = Prop.prop_iter_to_prop iter' in
|
|
if Prover.check_inconsistency prop' then []
|
|
else iter_rearrange pname tenv (Prop.lexp_normalize_prop prop' lexp) typ prop' iter' inst in
|
|
let rec f_many_iters iters_lst = function
|
|
| [] -> IList.flatten (IList.rev iters_lst)
|
|
| iter':: iters' ->
|
|
let iters_res' = f_one_iter iter' in
|
|
f_many_iters (iters_res':: iters_lst) iters' in
|
|
f_many_iters [] iters in
|
|
let filter = function
|
|
| Sil.Hpointsto (base, _, _) | Sil.Hlseg (_, _, base, _, _) ->
|
|
Prover.is_root prop base lexp
|
|
| Sil.Hdllseg (_, _, first, _, _, last, _) ->
|
|
let result_first = Prover.is_root prop first lexp in
|
|
match result_first with
|
|
| None -> Prover.is_root prop last lexp
|
|
| Some _ -> result_first in
|
|
let res =
|
|
match Prop.prop_iter_find iter filter with
|
|
| None ->
|
|
[default_case_iter iter]
|
|
| Some iter ->
|
|
match Prop.prop_iter_current iter with
|
|
| (Sil.Hpointsto (_, _, texp), off) ->
|
|
if Config.type_size then check_type_size pname prop texp off typ_from_instr;
|
|
iter_rearrange_ptsto pname tenv prop iter lexp inst
|
|
| (Sil.Hlseg (Sil.Lseg_NE, para, e1, e2, elist), _) ->
|
|
iter_rearrange_ne_lseg recurse_on_iters iter para e1 e2 elist
|
|
| (Sil.Hlseg (Sil.Lseg_PE, para, e1, e2, elist), _) ->
|
|
iter_rearrange_pe_lseg recurse_on_iters default_case_iter iter para e1 e2 elist
|
|
| (Sil.Hdllseg (Sil.Lseg_NE, para_dll, e1, e2, e3, e4, elist), _) ->
|
|
begin
|
|
match Prover.is_root prop e1 lexp, Prover.is_root prop e4 lexp with
|
|
| None, None -> assert false
|
|
| Some _, _ -> iter_rearrange_ne_dllseg_first recurse_on_iters iter para_dll e1 e2 e3 e4 elist
|
|
| _, Some _ -> iter_rearrange_ne_dllseg_last recurse_on_iters iter para_dll e1 e2 e3 e4 elist
|
|
end
|
|
| (Sil.Hdllseg (Sil.Lseg_PE, para_dll, e1, e2, e3, e4, elist), _) ->
|
|
begin
|
|
match Prover.is_root prop e1 lexp, Prover.is_root prop e4 lexp with
|
|
| None, None -> assert false
|
|
| Some _, _ -> iter_rearrange_pe_dllseg_first recurse_on_iters default_case_iter iter para_dll e1 e2 e3 e4 elist
|
|
| _, Some _ -> iter_rearrange_pe_dllseg_last recurse_on_iters default_case_iter iter para_dll e1 e2 e3 e4 elist
|
|
end in
|
|
if Config.trace_rearrange then begin
|
|
L.d_strln "exiting iter_rearrange, returning results";
|
|
Prop.d_proplist_with_typ (IList.map Prop.prop_iter_to_prop res);
|
|
L.d_decrease_indent 1;
|
|
L.d_ln (); L.d_ln ()
|
|
end;
|
|
res
|
|
|
|
let is_weak_captured_var pdesc pvar =
|
|
let pname = Cfg.Procdesc.get_proc_name pdesc in
|
|
match pname with
|
|
| Block _ ->
|
|
let is_weak_captured (var, typ) =
|
|
match typ with
|
|
| Typ.Tptr (_, Pk_objc_weak) ->
|
|
Mangled.equal (Pvar.get_name pvar) var
|
|
| _ -> false in
|
|
IList.exists is_weak_captured (Cfg.Procdesc.get_captured pdesc)
|
|
| _ -> false
|
|
|
|
|
|
(** Check for dereference errors: dereferencing 0, a freed value, or an undefined value *)
|
|
let check_dereference_error pdesc (prop : Prop.normal Prop.t) lexp loc =
|
|
let nullable_obj_str = ref None in
|
|
let nullable_str_is_weak_captured_var = ref false in
|
|
(* return true if deref_exp is only pointed to by fields/params with @Nullable annotations *)
|
|
let is_only_pt_by_nullable_fld_or_param deref_exp =
|
|
let ann_sig = Models.get_modelled_annotated_signature (Specs.pdesc_resolve_attributes pdesc) in
|
|
IList.for_all
|
|
(fun hpred ->
|
|
match hpred with
|
|
| Sil.Hpointsto (Exp.Lvar pvar, Sil.Eexp (Exp.Var _ as exp, _), _)
|
|
when Exp.equal exp deref_exp ->
|
|
let is_weak_captured_var = is_weak_captured_var pdesc pvar in
|
|
let is_nullable =
|
|
if Annotations.param_is_nullable pvar ann_sig || is_weak_captured_var
|
|
then
|
|
begin
|
|
nullable_obj_str := Some (Pvar.to_string pvar);
|
|
nullable_str_is_weak_captured_var := is_weak_captured_var;
|
|
true
|
|
end
|
|
else
|
|
let is_nullable_attr = function
|
|
| Sil.Apred ((Aretval (pname, ret_attr) | Aundef (pname, ret_attr, _, _)), _)
|
|
when Annotations.ia_is_nullable ret_attr ->
|
|
nullable_obj_str := Some (Procname.to_string pname);
|
|
true
|
|
| _ -> false in
|
|
IList.exists is_nullable_attr (Attribute.get_for_exp 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, _), Exp.Sizeof (typ, _, _)) ->
|
|
let fld_is_nullable fld =
|
|
match Typ.get_field_type_and_annotation fld typ with
|
|
| Some (_, annot) -> Annotations.ia_is_nullable annot
|
|
| _ -> false in
|
|
let is_strexp_pt_by_nullable_fld (fld, strexp) =
|
|
match strexp with
|
|
| Sil.Eexp (Exp.Var _ as exp, _) when Exp.equal exp deref_exp ->
|
|
let is_nullable = fld_is_nullable fld in
|
|
if is_nullable then
|
|
nullable_obj_str := Some (Ident.fieldname_to_simplified_string fld);
|
|
is_nullable
|
|
| _ -> true in
|
|
IList.for_all is_strexp_pt_by_nullable_fld flds
|
|
| _ -> true)
|
|
prop.Prop.sigma &&
|
|
!nullable_obj_str <> None in
|
|
let root = Exp.root_of_lexp lexp in
|
|
let is_deref_of_nullable =
|
|
let is_definitely_non_null exp prop =
|
|
Prover.check_disequal prop exp Exp.zero in
|
|
Config.report_nullable_inconsistency && not (is_definitely_non_null root prop)
|
|
&& is_only_pt_by_nullable_fld_or_param root in
|
|
let relevant_attributes_getters = [
|
|
Attribute.get_resource;
|
|
Attribute.get_undef;
|
|
] in
|
|
let get_relevant_attributes exp =
|
|
let rec fold_getters = function
|
|
| [] -> None
|
|
| getter:: tl -> match getter prop exp with
|
|
| Some _ as some_attr -> some_attr
|
|
| None -> fold_getters tl in
|
|
fold_getters relevant_attributes_getters in
|
|
let attribute_opt = match get_relevant_attributes root with
|
|
| Some att -> Some att
|
|
| None -> (* try to remove an offset if any, and find the attribute there *)
|
|
let root_no_offset = match root with
|
|
| Exp.BinOp((Binop.PlusPI | Binop.PlusA | Binop.MinusPI | Binop.MinusA), base, _) -> base
|
|
| _ -> root in
|
|
get_relevant_attributes root_no_offset in
|
|
if Prover.check_zero (Exp.root_of_lexp root) || is_deref_of_nullable then
|
|
begin
|
|
let deref_str =
|
|
if is_deref_of_nullable then
|
|
match !nullable_obj_str with
|
|
| Some str ->
|
|
if !nullable_str_is_weak_captured_var then
|
|
Localise.deref_str_weak_variable_in_block None str
|
|
else Localise.deref_str_nullable None str
|
|
| None -> Localise.deref_str_nullable None ""
|
|
else Localise.deref_str_null None in
|
|
let err_desc =
|
|
Errdesc.explain_dereference ~use_buckets: true ~is_nullable: is_deref_of_nullable
|
|
deref_str prop loc in
|
|
if Localise.is_parameter_not_null_checked_desc err_desc then
|
|
raise (Exceptions.Parameter_not_null_checked (err_desc, __POS__))
|
|
else if Localise.is_field_not_null_checked_desc err_desc then
|
|
raise (Exceptions.Field_not_null_checked (err_desc, __POS__))
|
|
else if (Localise.is_empty_vector_access_desc err_desc) then
|
|
raise (Exceptions.Empty_vector_access (err_desc, __POS__))
|
|
else raise (Exceptions.Null_dereference (err_desc, __POS__))
|
|
end;
|
|
match attribute_opt with
|
|
| Some (Apred (Adangling dk, _)) ->
|
|
let deref_str = Localise.deref_str_dangling (Some dk) in
|
|
let err_desc = Errdesc.explain_dereference deref_str prop (State.get_loc ()) in
|
|
raise (Exceptions.Dangling_pointer_dereference (Some dk, err_desc, __POS__))
|
|
| Some (Apred (Aundef (s, _, undef_loc, _), _)) ->
|
|
if Config.angelic_execution then ()
|
|
else
|
|
let deref_str = Localise.deref_str_undef (s, undef_loc) in
|
|
let err_desc = Errdesc.explain_dereference deref_str prop loc in
|
|
raise (Exceptions.Skip_pointer_dereference (err_desc, __POS__))
|
|
| Some (Apred (Aresource ({ ra_kind = Rrelease } as ra), _)) ->
|
|
let deref_str = Localise.deref_str_freed ra in
|
|
let err_desc = Errdesc.explain_dereference ~use_buckets: true deref_str prop loc in
|
|
raise (Exceptions.Use_after_free (err_desc, __POS__))
|
|
| _ ->
|
|
if Prover.check_equal Prop.prop_emp (Exp.root_of_lexp root) Exp.minus_one then
|
|
let deref_str = Localise.deref_str_dangling None in
|
|
let err_desc = Errdesc.explain_dereference deref_str prop loc in
|
|
raise (Exceptions.Dangling_pointer_dereference (None, err_desc, __POS__))
|
|
|
|
(* Check that an expression representin an objc block can be null and raise a [B1] null exception.*)
|
|
(* It's used to check that we don't call possibly null blocks *)
|
|
let check_call_to_objc_block_error pdesc prop fun_exp loc =
|
|
let fun_exp_may_be_null () = (* may be null if we don't know if it is definitely not null *)
|
|
not (Prover.check_disequal prop (Exp.root_of_lexp fun_exp) Exp.zero) in
|
|
let try_explaining_exp e = (* when e is a temp var, try to find the pvar defining e*)
|
|
match e with
|
|
| Exp.Var id ->
|
|
(match (Errdesc.find_ident_assignment (State.get_node ()) id) with
|
|
| Some (_, e') -> e'
|
|
| None -> e)
|
|
| _ -> e in
|
|
let get_exp_called () = (* Exp called in the block's function call*)
|
|
match State.get_instr () with
|
|
| Some Sil.Call(_, Exp.Var id, _, _, _) ->
|
|
Errdesc.find_ident_assignment (State.get_node ()) id
|
|
| _ -> None in
|
|
let is_fun_exp_captured_var () = (* Called expression is a captured variable of the block *)
|
|
match get_exp_called () with
|
|
| Some (_, Exp.Lvar pvar) -> (* pvar is the block *)
|
|
let name = Pvar.get_name pvar in
|
|
IList.exists (fun (cn, _) -> (Mangled.equal name cn)) (Cfg.Procdesc.get_captured pdesc)
|
|
| _ -> false in
|
|
let is_field_deref () = (*Called expression is a field *)
|
|
match get_exp_called () with
|
|
| Some (_, (Exp.Lfield(e', fn, t))) ->
|
|
let e'' = try_explaining_exp e' in
|
|
Some (Exp.Lfield(e'', fn, t)), true (* the block dereferences is a field of an object*)
|
|
| Some (_, e) -> Some e, false
|
|
| _ -> None, false in
|
|
if (!Config.curr_language = Config.Clang) &&
|
|
fun_exp_may_be_null () &&
|
|
not (is_fun_exp_captured_var ()) then
|
|
begin
|
|
let deref_str = Localise.deref_str_null None in
|
|
let err_desc_nobuckets = Errdesc.explain_dereference ~is_nullable: true deref_str prop loc in
|
|
match fun_exp with
|
|
| Exp.Var id when Ident.is_footprint id ->
|
|
let e_opt, is_field_deref = is_field_deref () in
|
|
let err_desc_nobuckets' = (match e_opt with
|
|
| Some e -> Localise.parameter_field_not_null_checked_desc err_desc_nobuckets e
|
|
| _ -> err_desc_nobuckets) in
|
|
let err_desc =
|
|
Localise.error_desc_set_bucket
|
|
err_desc_nobuckets' Localise.BucketLevel.b1 Config.show_buckets in
|
|
if is_field_deref then
|
|
raise
|
|
(Exceptions.Field_not_null_checked
|
|
(err_desc, __POS__))
|
|
else
|
|
raise
|
|
(Exceptions.Parameter_not_null_checked
|
|
(err_desc, __POS__))
|
|
| _ ->
|
|
(* HP: fun_exp is not a footprint therefore,
|
|
either is a local or it's a modified param *)
|
|
let err_desc =
|
|
Localise.error_desc_set_bucket
|
|
err_desc_nobuckets Localise.BucketLevel.b1 Config.show_buckets in
|
|
raise (Exceptions.Null_dereference
|
|
(err_desc, __POS__))
|
|
end
|
|
|
|
(** [rearrange lexp prop] rearranges [prop] into the form [prop' * lexp|->strexp:typ].
|
|
It returns an iterator with [lexp |-> strexp: typ] as current predicate
|
|
and the path (an [offsetlist]) which leads to [lexp] as the iterator state. *)
|
|
let rearrange ?(report_deref_errors=true) pdesc tenv lexp typ prop loc
|
|
: (Sil.offset list) Prop.prop_iter list =
|
|
|
|
let nlexp = match Prop.exp_normalize_prop prop lexp with
|
|
| Exp.BinOp(Binop.PlusPI, ep, e) -> (* array access with pointer arithmetic *)
|
|
Exp.Lindex(ep, e)
|
|
| e -> e in
|
|
let ptr_tested_for_zero =
|
|
Prover.check_disequal prop (Exp.root_of_lexp nlexp) Exp.zero in
|
|
let inst = Sil.inst_rearrange (not ptr_tested_for_zero) loc (State.get_path_pos ()) in
|
|
L.d_strln ".... Rearrangement Start ....";
|
|
L.d_str "Exp: "; Sil.d_exp nlexp; L.d_ln ();
|
|
L.d_str "Prop: "; L.d_ln(); Prop.d_prop prop; L.d_ln (); L.d_ln ();
|
|
if report_deref_errors then check_dereference_error pdesc prop nlexp (State.get_loc ());
|
|
let pname = Cfg.Procdesc.get_proc_name pdesc in
|
|
let prop' =
|
|
if Config.csl_analysis && !Config.footprint && Procname.is_java pname &&
|
|
not (Procname.is_constructor pname || Procname.is_class_initializer pname)
|
|
then add_guarded_by_constraints prop lexp pdesc
|
|
else prop in
|
|
match Prop.prop_iter_create prop' with
|
|
| None ->
|
|
if !Config.footprint then
|
|
[prop_iter_add_hpred_footprint_to_prop pname tenv prop' (nlexp, typ) inst]
|
|
else
|
|
begin
|
|
pp_rearrangement_error "sigma is empty" prop nlexp;
|
|
raise (Exceptions.Symexec_memory_error __POS__)
|
|
end
|
|
| Some iter -> iter_rearrange pname tenv nlexp typ prop' iter inst
|
|
|
|
(*
|
|
let pp_off fmt off =
|
|
IList.iter (fun n -> match n with
|
|
| Sil.Off_fld (f, t) -> F.fprintf fmt "%a " Ident.pp_fieldname f
|
|
| Sil.Off_index e -> F.fprintf fmt "%a " (Sil.pp_exp pe_text) e) off
|
|
|
|
let sort_ftl ftl =
|
|
let compare (f1, _) (f2, _) = Ident.fieldname_compare f1 f2 in
|
|
IList.sort compare ftl
|
|
*)
|