(* * Copyright (c) 2016 - present Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD style license found in the * LICENSE file in the root directory of this source tree. An additional grant * of patent rights can be found in the PATENTS file in the same directory. *) open! Utils (** Models for the builtin functions supported *) open SymExec module L = Logging module F = Format let execute___no_op prop path: Builtin.ret_typ = [(prop, path)] (** model va_arg as always returning 0 *) let execute___builtin_va_arg { Builtin.pdesc; tenv; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = match args, ret_ids with | [_; _; (lexp3, typ3)], _ -> let instr' = Sil.Set (lexp3, typ3, Sil.exp_zero, loc) in SymExec.instrs ~mask_errors:true tenv pdesc [instr'] [(prop_, path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) let mk_empty_array size = Sil.Earray (size, [], Sil.inst_none) (* Make a rearranged array. As it is rearranged when it appears in a precondition it requires that the function is called with the array allocated. If not infer return a null pointer deref *) let mk_empty_array_rearranged size = Sil.Earray (size, [], Sil.inst_rearrange true (State.get_loc ()) (State.get_path_pos ())) let extract_array_type typ = if (!Config.curr_language = Config.Java) then match typ with | Sil.Tptr ( Sil.Tarray (typ', _), _) -> Some typ' | _ -> None else match typ with | Sil.Tptr (typ', _) | Sil.Tarray (typ', _) -> Some typ' | _ -> None (** Return a result from a procedure call. *) let return_result e prop ret_ids = match ret_ids with | [ret_id] -> Prop.conjoin_eq e (Sil.Var ret_id) prop | _ -> prop (* Add an array of typ pointed to by lexp to prop_ if it doesnt exist alread*) (* Return the new prop and the array size *) (* Return None if it fails to add the array *) let add_array_to_prop pdesc prop_ lexp typ = let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in begin try let hpred = IList.find (function | Sil.Hpointsto(e, _, _) -> Sil.exp_equal e n_lexp | _ -> false) (Prop.get_sigma prop) in match hpred with | Sil.Hpointsto(_, Sil.Earray(size, _, _), _) -> Some (size, prop) | _ -> None (* e points to something but not an array *) with Not_found -> (* e is not allocated, so we can add the array *) let otyp' = (extract_array_type typ) in match otyp' with | Some 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 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 let prop''= Prop.replace_sigma_footprint (hpred:: sigma_fp) prop' in let prop''= Prop.normalize prop'' in Some (size, prop'') | _ -> None end (* Add an array in prop if it is not allocated.*) let execute___require_allocated_array { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(lexp, typ)] when IList.length ret_ids <= 1 -> (match add_array_to_prop pdesc prop_ lexp typ with | None -> [] | Some (_, prop) -> [(prop, path)]) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___get_array_size { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(lexp, typ)] when IList.length ret_ids <= 1 -> (match add_array_to_prop pdesc prop_ lexp typ with | None -> [] | Some (size, prop) -> [(return_result size prop ret_ids, path)]) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___set_array_size { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, typ); (size, _)], []-> (match add_array_to_prop pdesc prop_ lexp typ with | None -> [] | Some (_, prop_a) -> (* Invariant: prop_a has an array pointed to by lexp *) let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop__ = check_arith_norm_exp pname lexp prop_a in let n_size, prop = check_arith_norm_exp pname size prop__ in let hpred, sigma' = IList.partition (function | Sil.Hpointsto(e, _, _) -> Sil.exp_equal e n_lexp | _ -> false) (Prop.get_sigma prop) in (match hpred with | [Sil.Hpointsto(e, Sil.Earray(_, esel, inst), t)] -> let hpred' = Sil.Hpointsto (e, Sil.Earray (n_size, esel, inst), t) in let prop' = Prop.replace_sigma (hpred':: sigma') prop in [(Prop.normalize prop', path)] | _ -> [])) (* by construction of prop_a this case is impossible *) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___print_value { Builtin.pdesc; prop_; path; args; } : Builtin.ret_typ = L.err "__print_value: "; let pname = Cfg.Procdesc.get_proc_name pdesc in let do_arg (lexp, _) = let n_lexp, _ = check_arith_norm_exp pname lexp prop_ in L.err "%a " (Sil.pp_exp pe_text) n_lexp in IList.iter do_arg args; L.err "@."; [(prop_, path)] let is_undefined_opt prop n_lexp = let is_undef = Option.is_some (Prop.get_undef_attribute prop n_lexp) in is_undef && (Config.angelic_execution || Config.optimistic_cast) (** Creates an object in the heap with a given type, when the object is not known to be null or when it doesn't appear already in the heap. *) let create_type tenv n_lexp typ prop = let prop_type = try let _ = IList.find (function | Sil.Hpointsto(e, _, _) -> Sil.exp_equal e n_lexp | _ -> false) (Prop.get_sigma prop) in prop with Not_found -> let mhpred = match typ with | 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 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 hpred = Prop.mk_ptsto n_lexp sexp texp in Some hpred | _ -> None in match mhpred with | Some hpred -> 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 let prop''= let has_normal_variables = Sil.fav_exists (Sil.exp_fav n_lexp) Ident.is_normal in if (is_undefined_opt prop n_lexp) || has_normal_variables then prop' else Prop.replace_sigma_footprint (hpred:: sigma_fp) prop' in let prop''= Prop.normalize prop'' in prop'' | None -> prop in let sil_is_null = Sil.BinOp (Sil.Eq, n_lexp, Sil.exp_zero) in let sil_is_nonnull = Sil.UnOp (Sil.LNot, sil_is_null, None) in let null_case = Propset.to_proplist (prune ~positive:true sil_is_null prop) in let non_null_case = Propset.to_proplist (prune ~positive:true sil_is_nonnull prop_type) in if ((IList.length non_null_case) > 0) && (!Config.footprint) then non_null_case else if ((IList.length non_null_case) > 0) && (is_undefined_opt prop n_lexp) then non_null_case else null_case @ non_null_case let execute___get_type_of { Builtin.pdesc; tenv; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(lexp, typ)] when IList.length ret_ids <= 1 -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in let props = create_type tenv n_lexp typ prop in let aux prop = begin try let hpred = IList.find (function | Sil.Hpointsto(e, _, _) -> Sil.exp_equal e n_lexp | _ -> false) (Prop.get_sigma prop) in match hpred with | Sil.Hpointsto(_, _, texp) -> (return_result texp prop ret_ids), path | _ -> assert false with Not_found -> (return_result Sil.exp_zero prop ret_ids), path end in (IList.map aux props) | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** replace the type of the ptsto rooted at [root_e] with [texp] in [prop] *) let replace_ptsto_texp prop root_e texp = let process_sigma sigma = let sigma1, sigma2 = IList.partition (function | Sil.Hpointsto(e, _, _) -> Sil.exp_equal e root_e | _ -> false) sigma in match sigma1 with | [Sil.Hpointsto(e, se, _)] -> (Sil.Hpointsto (e, se, texp)) :: sigma2 | _ -> sigma in let sigma = Prop.get_sigma prop in let sigma_fp = Prop.get_sigma_footprint prop in let prop'= Prop.replace_sigma (process_sigma sigma) prop in let prop''= Prop.replace_sigma_footprint (process_sigma sigma_fp) prop' in Prop.normalize prop'' let execute___instanceof_cast ~instof { Builtin.pdesc; tenv; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(val1_, typ1); (texp2_, _)] when IList.length ret_ids <= 1 -> let pname = Cfg.Procdesc.get_proc_name pdesc in let val1, prop__ = check_arith_norm_exp pname val1_ prop_ in let texp2, prop = check_arith_norm_exp pname texp2_ prop__ in let is_cast_to_reference = match typ1 with | Sil.Tptr (_, Sil.Pk_reference) -> true | _ -> false in (* In Java, we throw an exception, in C++ we return 0 in case of a cast to a pointer, *) (* and throw an exception in case of a cast to a reference. *) let should_throw_exception = !Config.curr_language = Config.Java || is_cast_to_reference in let deal_with_failed_cast val1 _ texp1 texp2 = Tabulation.raise_cast_exception __POS__ None texp1 texp2 val1 in let exe_one_prop prop = if Sil.exp_equal texp2 Sil.exp_zero then [(return_result Sil.exp_zero prop ret_ids, path)] else begin try let hpred = IList.find (function | Sil.Hpointsto (e1, _, _) -> Sil.exp_equal e1 val1 | _ -> false) (Prop.get_sigma prop) in match hpred with | Sil.Hpointsto (_, _, texp1) -> let pos_type_opt, neg_type_opt = Prover.Subtyping_check.subtype_case_analysis tenv texp1 texp2 in let mk_res type_opt res_e = match type_opt with | None -> [] | Some texp1' -> let prop' = if Sil.exp_equal texp1 texp1' then prop else replace_ptsto_texp prop val1 texp1' in [(return_result res_e prop' ret_ids, path)] in if instof then (* instanceof *) begin let pos_res = mk_res pos_type_opt Sil.exp_one in let neg_res = mk_res neg_type_opt Sil.exp_zero in pos_res @ neg_res end else (* cast *) if not should_throw_exception then (* C++ case when negative cast returns 0 *) let pos_res = mk_res pos_type_opt val1 in let neg_res = mk_res neg_type_opt Sil.exp_zero in pos_res @ neg_res else begin if (!Config.footprint = true) then begin match pos_type_opt with | None -> deal_with_failed_cast val1 typ1 texp1 texp2 | Some _ -> mk_res pos_type_opt val1 end else (* !Config.footprint = false *) begin match neg_type_opt with | Some _ -> if is_undefined_opt prop val1 then mk_res pos_type_opt val1 else deal_with_failed_cast val1 typ1 texp1 texp2 | None -> mk_res pos_type_opt val1 end end | _ -> [] with Not_found -> [(return_result val1 prop ret_ids, path)] end in let props = create_type tenv val1 typ1 prop in IList.flatten (IList.map exe_one_prop props) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___instanceof builtin_args : Builtin.ret_typ = execute___instanceof_cast ~instof:true builtin_args let execute___cast builtin_args : Builtin.ret_typ = execute___instanceof_cast ~instof:false builtin_args let set_resource_attribute prop path n_lexp loc ra_res = let prop' = match Prop.get_resource_attribute prop n_lexp with | Some (Sil.Aresource (_ as ra)) -> Prop.add_or_replace_exp_attribute prop n_lexp (Sil.Aresource { ra with Sil.ra_res = ra_res }) | _ -> ( let pname = Sil.mem_alloc_pname Sil.Mnew in let ra = { Sil.ra_kind = Sil.Racquire; Sil.ra_res = ra_res; Sil.ra_pname = pname; Sil.ra_loc = loc; Sil.ra_vpath = None } in Prop.add_or_replace_exp_attribute prop n_lexp (Sil.Aresource ra)) in [(prop', path)] (** Set the attibute of the value as file *) let execute___set_file_attribute { Builtin.pdesc; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, _)], _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in set_resource_attribute prop path n_lexp loc Sil.Rfile | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Set the attibute of the value as lock *) let execute___set_lock_attribute { Builtin.pdesc; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, _)], _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in set_resource_attribute prop path n_lexp loc Sil.Rlock | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Set the resource attribute of the first real argument of method as ignore, the first argument is assumed to be "this" *) let execute___method_set_ignore_attribute { Builtin.pdesc; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = match args, ret_ids with | [_ ; (lexp, _)], _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in set_resource_attribute prop path n_lexp loc Sil.Rignore | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Set the attibute of the value as memory *) let execute___set_mem_attribute { Builtin.pdesc; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, _)], _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in set_resource_attribute prop path n_lexp loc (Sil.Rmemory Sil.Mnew) | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** report an error if [lexp] is tainted; otherwise, add untained([lexp]) as a precondition *) let execute___check_untainted { Builtin.pdesc; prop_; path; ret_ids; args; proc_name = callee_pname; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, _)], _ -> let caller_pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp caller_pname lexp prop_ in [(check_untainted n_lexp Sil.Tk_unknown caller_pname callee_pname prop, path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** take a pointer to a struct, and return the value of a hidden field in the struct *) let execute___get_hidden_field { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(lexp, _)] -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in let ret_val = ref None in let return_val p = match !ret_val with | Some e -> return_result e p ret_ids | None -> p in let foot_var = lazy (Sil.Var (Ident.create_fresh Ident.kfootprint)) in let filter_fld_hidden (f, _ ) = Ident.fieldname_is_hidden f in let has_fld_hidden fsel = IList.exists filter_fld_hidden fsel in let do_hpred in_foot hpred = match hpred with | Sil.Hpointsto(e, Sil.Estruct (fsel, inst), texp) when Sil.exp_equal e n_lexp && (not (has_fld_hidden fsel)) -> let foot_e = Lazy.force foot_var in ret_val := Some foot_e; let se = Sil.Eexp(foot_e, Sil.inst_none) in let fsel' = (Ident.fieldname_hidden, se) :: fsel in Sil.Hpointsto(e, Sil.Estruct (fsel', inst), texp) | Sil.Hpointsto(e, Sil.Estruct (fsel, _), _) when Sil.exp_equal e n_lexp && not in_foot && has_fld_hidden fsel -> let set_ret_val () = match IList.find filter_fld_hidden fsel with | _, Sil.Eexp(e, _) -> ret_val := Some e | _ -> () in set_ret_val(); hpred | _ -> hpred in let sigma' = IList.map (do_hpred false) (Prop.get_sigma prop) in let sigma_fp' = IList.map (do_hpred true) (Prop.get_sigma_footprint prop) in let prop' = Prop.replace_sigma_footprint sigma_fp' (Prop.replace_sigma sigma' prop) in let prop'' = return_val (Prop.normalize prop') in [(prop'', path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** take a pointer to a struct and a value, and set a hidden field in the struct to the given value *) let execute___set_hidden_field { Builtin.pdesc; prop_; path; args; } : Builtin.ret_typ = match args with | [(lexp1, _); (lexp2, _)] -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp1, prop__ = check_arith_norm_exp pname lexp1 prop_ in let n_lexp2, prop = check_arith_norm_exp pname lexp2 prop__ in let foot_var = lazy (Sil.Var (Ident.create_fresh Ident.kfootprint)) in let filter_fld_hidden (f, _ ) = Ident.fieldname_is_hidden f in let has_fld_hidden fsel = IList.exists filter_fld_hidden fsel in let do_hpred in_foot hpred = match hpred with | Sil.Hpointsto(e, Sil.Estruct (fsel, inst), texp) when Sil.exp_equal e n_lexp1 && not in_foot -> let se = Sil.Eexp(n_lexp2, Sil.inst_none) in let fsel' = (Ident.fieldname_hidden, se) :: (IList.filter (fun x -> not (filter_fld_hidden x)) fsel) in Sil.Hpointsto(e, Sil.Estruct (fsel', inst), texp) | Sil.Hpointsto(e, Sil.Estruct (fsel, inst), texp) when Sil.exp_equal e n_lexp1 && in_foot && not (has_fld_hidden fsel) -> let foot_e = Lazy.force foot_var in let se = Sil.Eexp(foot_e, Sil.inst_none) in let fsel' = (Ident.fieldname_hidden, se) :: fsel in Sil.Hpointsto(e, Sil.Estruct (fsel', inst), texp) | _ -> hpred in let sigma' = IList.map (do_hpred false) (Prop.get_sigma prop) in let sigma_fp' = IList.map (do_hpred true) (Prop.get_sigma_footprint prop) in let prop' = Prop.replace_sigma_footprint sigma_fp' (Prop.replace_sigma sigma' prop) in let prop'' = Prop.normalize prop' in [(prop'', path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) (* Update the objective-c hidden counter by applying the operation op and the operand delta.*) (* Eg. op=+/- delta is an integer *) let execute___objc_counter_update ~mask_errors op delta { Builtin.pdesc; tenv; prop_; path; args; loc; } : Builtin.ret_typ = match args with | [(lexp, typ)] -> let typ' = (match Tenv.expand_type tenv typ with | Sil.Tstruct _ as s -> s | Sil.Tptr(t, _) -> Tenv.expand_type tenv t | s' -> L.d_str ("Trying to update hidden field of not a struc. Type: " ^ (Sil.typ_to_string s')); assert false) in (* Assumes that lexp is a temp n$1 that has the value of the object. *) (* This is the case as a call f(o) it's translates as n$1=*&o; f(n$1) *) (* n$2 = *n$1.hidden *) let tmp = Ident.create_fresh Ident.knormal in let hidden_field = Sil.Lfield(lexp, Ident.fieldname_hidden, typ') in let counter_to_tmp = Sil.Letderef(tmp, hidden_field, typ', loc) in (* *n$1.hidden = (n$2 +/- delta) *) let update_counter = Sil.Set (hidden_field, typ', Sil.BinOp(op, Sil.Var tmp, Sil.Const (Sil.Cint delta)), loc) in let update_counter_instrs = [ counter_to_tmp; update_counter; Sil.Remove_temps([tmp], loc) ] in SymExec.instrs ~mask_errors tenv pdesc update_counter_instrs [(prop_, path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) (* Given a list of args checks if the first is the flag indicating whether is a call to retain/release for which we have to suppress NPE report or not. If the flag is present it is removed from the list of args. *) let get_suppress_npe_flag args = match args with | (Sil.Const (Sil.Cint i), Sil.Tint Sil.IBool):: args' when Sil.Int.isone i -> false, args' (* this is a CFRelease/CFRetain *) | _ -> true, args let execute___objc_retain_impl ({ Builtin.prop_; args; ret_ids; } as builtin_args) : Builtin.ret_typ = let mask_errors, args' = get_suppress_npe_flag args in match args' with | [(lexp, _)] -> let prop = return_result lexp prop_ ret_ids in execute___objc_counter_update ~mask_errors (Sil.PlusA) (Sil.Int.one) { builtin_args with Builtin.prop_ = prop; args = args'; } | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___objc_retain builtin_args : Builtin.ret_typ = if Config.objc_memory_model_on then execute___objc_retain_impl builtin_args else execute___no_op builtin_args.Builtin.prop_ builtin_args.Builtin.path let execute___objc_retain_cf builtin_args : Builtin.ret_typ = execute___objc_retain_impl builtin_args let execute___objc_release_impl ({ Builtin.args; } as builtin_args) : Builtin.ret_typ = let mask_errors, args' = get_suppress_npe_flag args in execute___objc_counter_update ~mask_errors Sil.MinusA Sil.Int.one { builtin_args with Builtin.args = args'; } let execute___objc_release builtin_args : Builtin.ret_typ = if Config.objc_memory_model_on then execute___objc_release_impl builtin_args else execute___no_op builtin_args.Builtin.prop_ builtin_args.Builtin.path let execute___objc_release_cf builtin_args : Builtin.ret_typ = execute___objc_release_impl builtin_args (** Set the attibute of the value as objc autoreleased *) let execute___set_autorelease_attribute { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args, ret_ids with | [(lexp, _)], _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let prop = return_result lexp prop_ ret_ids in if Config.objc_memory_model_on then let n_lexp, prop = check_arith_norm_exp pname lexp prop in let prop' = Prop.add_or_replace_exp_attribute prop n_lexp Sil.Aautorelease in [(prop', path)] else execute___no_op prop path | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Release all the objects in the pool *) let execute___release_autorelease_pool ({ Builtin.prop_; path; } as builtin_args) : Builtin.ret_typ = if Config.objc_memory_model_on then let autoreleased_objects = Prop.get_atoms_with_attribute Sil.Aautorelease prop_ in let prop_without_attribute = Prop.remove_attribute Sil.Aautorelease prop_ in let call_release res exp = match res with | (prop', path'):: _ -> (try let hpred = IList.find (function | Sil.Hpointsto(e1, _, _) -> Sil.exp_equal e1 exp | _ -> false) (Prop.get_sigma prop_) in match hpred with | Sil.Hpointsto(_, _, Sil.Sizeof (typ, _)) -> let res1 = execute___objc_release { builtin_args with Builtin.args = [(exp, typ)]; prop_ = prop'; path = path'; } in res1 | _ -> res with Not_found -> res) | [] -> res in IList.fold_left call_release [(prop_without_attribute, path)] autoreleased_objects else execute___no_op prop_ path let set_attr pdesc prop path exp attr = let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname exp prop in [(Prop.add_or_replace_exp_attribute prop n_lexp attr, path)] let delete_attr pdesc prop path exp attr = let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname exp prop in [(Prop.remove_attribute_from_exp attr prop n_lexp, path)] (** Set attibute att *) let execute___set_attr attr { Builtin.pdesc; prop_; path; args; } : Builtin.ret_typ = match args with | [(lexp, _)] -> set_attr pdesc prop_ path lexp attr | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Delete the locked attibute of the value*) let execute___delete_locked_attribute { Builtin.prop_; pdesc; path; args; } : Builtin.ret_typ = match args with | [(lexp, _)] -> delete_attr pdesc prop_ path lexp Sil.Alocked | _ -> raise (Exceptions.Wrong_argument_number __POS__) (** Set the attibute of the value as locked*) let execute___set_locked_attribute builtin_args : Builtin.ret_typ = execute___set_attr (Sil.Alocked) builtin_args (** Set the attibute of the value as resource/unlocked*) let execute___set_unlocked_attribute ({ Builtin.pdesc; loc; } as builtin_args) : Builtin.ret_typ = let pname = Cfg.Procdesc.get_proc_name pdesc in (* ra_kind = Rrelease in following indicates unlocked *) let ra = { Sil.ra_kind = Sil.Rrelease; ra_res = Sil.Rlock; ra_pname = pname; ra_loc = loc; ra_vpath = None; } in execute___set_attr (Sil.Aresource ra) builtin_args (** Set the attibute of the value as tainted *) let execute___set_taint_attribute ({ Builtin.pdesc; args; prop_; path; }) : Builtin.ret_typ = match args with | (exp, _) :: [(Sil.Const (Sil.Cstr taint_kind_str), _)] -> let taint_source = Cfg.Procdesc.get_proc_name pdesc in let taint_kind = match taint_kind_str with | "UnverifiedSSLSocket" -> Sil.Tk_unverified_SSL_socket | "SharedPreferenceData" -> Sil.Tk_shared_preferences_data | other_str -> failwith ("Unrecognized taint kind " ^ other_str) in set_attr pdesc prop_ path exp (Sil.Ataint { Sil.taint_source; taint_kind}) | _ -> (* note: we can also get this if [taint_kind] is not a string literal *) raise (Exceptions.Wrong_argument_number __POS__) (** Set the attibute of the value as tainted *) let execute___set_untaint_attribute ({ Builtin.pdesc; args; prop_; path; }) : Builtin.ret_typ = match args with | (exp, _) :: [] -> let taint_source = Cfg.Procdesc.get_proc_name pdesc in let taint_kind = Sil.Tk_unknown in (* TODO: change builtin to specify taint kind *) set_attr pdesc prop_ path exp (Sil.Auntaint { Sil.taint_source; taint_kind}) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___objc_cast { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(val1_, _); (texp2_, _)] when IList.length ret_ids <= 1 -> let pname = Cfg.Procdesc.get_proc_name pdesc in let val1, prop__ = check_arith_norm_exp pname val1_ prop_ in let texp2, prop = check_arith_norm_exp pname texp2_ prop__ in (try let hpred = IList.find (function | Sil.Hpointsto(e1, _, _) -> Sil.exp_equal e1 val1 | _ -> false) (Prop.get_sigma prop) in match hpred, texp2 with | 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)] with Not_found -> [(return_result val1 prop ret_ids, path)]) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute_abort { Builtin.proc_name; } : Builtin.ret_typ = raise (Exceptions.Precondition_not_found (Localise.verbatim_desc (Procname.to_string proc_name), __POS__)) let execute_exit { Builtin.prop_; path; } : Builtin.ret_typ = SymExec.diverge prop_ path let _execute_free mk loc acc iter = match Prop.prop_iter_current iter with | (Sil.Hpointsto(lexp, _, _), []) -> let prop = Prop.prop_iter_remove_curr_then_to_prop iter in let pname = Sil.mem_dealloc_pname mk in let ra = { Sil.ra_kind = Sil.Rrelease; Sil.ra_res = Sil.Rmemory mk; Sil.ra_pname = pname; Sil.ra_loc = loc; Sil.ra_vpath = None } in (* mark value as freed *) let p_res = Prop.add_or_replace_exp_attribute_check_changed Tabulation.check_attr_dealloc_mismatch prop lexp (Sil.Aresource ra) in p_res :: acc | (Sil.Hpointsto _, _ :: _) -> assert false (* alignment error *) | _ -> assert false (* should not happen *) let _execute_free_nonzero mk pdesc tenv instr prop lexp typ loc = try begin match Prover.is_root prop lexp lexp with | None -> L.d_strln ".... Alignment Error: Freed a non root ...."; assert false | Some _ -> let prop_list = IList.fold_left (_execute_free mk loc) [] (Rearrange.rearrange pdesc tenv lexp typ prop loc) in IList.rev prop_list end with Rearrange.ARRAY_ACCESS -> if (Config.array_level = 0) then assert false else begin L.d_strln ".... Array containing allocated heap cells ...."; L.d_str " Instr: "; Sil.d_instr instr; L.d_ln (); L.d_str " PROP: "; Prop.d_prop prop; L.d_ln (); raise (Exceptions.Array_of_pointsto __POS__) end let execute_free mk { Builtin.pdesc; instr; tenv; prop_; path; args; loc; } : Builtin.ret_typ = match args with | [(lexp, typ)] -> begin let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in let prop_nonzero = (* case n_lexp!=0 *) Propset.to_proplist (prune ~positive:true n_lexp prop) in let prop_zero = (* case n_lexp==0 *) Propset.to_proplist (prune ~positive:false n_lexp prop) in let plist = prop_zero @ (* model: if 0 then skip else _execute_free_nonzero *) IList.flatten (IList.map (fun p -> _execute_free_nonzero mk pdesc tenv instr p (Prop.exp_normalize_prop p lexp) typ loc) prop_nonzero) in IList.map (fun p -> (p, path)) plist end | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute_alloc mk can_return_null { Builtin.pdesc; tenv; prop_; path; ret_ids; args; loc; } : Builtin.ret_typ = let pname = Cfg.Procdesc.get_proc_name pdesc in let rec evaluate_char_sizeof e = match e with | Sil.Var _ -> e | Sil.UnOp (uop, e', typ) -> Sil.UnOp (uop, evaluate_char_sizeof e', typ) | 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 _ -> e in let handle_sizeof_exp size_exp = Sil.Sizeof (Sil.Tarray (Sil.Tint Sil.IChar, size_exp), 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), _)] -> 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 | [(size_exp, _)] -> (* for malloc and __new *) size_exp, Sil.mem_alloc_pname mk | [(size_exp, _); (Sil.Const (Sil.Cfun pname), _)] -> size_exp, pname | _ -> raise (Exceptions.Wrong_argument_number __POS__) in let ret_id = match ret_ids with | [ret_id] -> ret_id | _ -> Ident.create_fresh Ident.kprimed in let size_exp', prop = let n_size_exp, prop = check_arith_norm_exp pname size_exp prop_ in let n_size_exp' = evaluate_char_sizeof n_size_exp in Prop.exp_normalize_prop prop n_size_exp', prop in let cnt_te = handle_sizeof_exp size_exp' in let id_new = Ident.create_fresh Ident.kprimed in let exp_new = Sil.Var id_new in let ptsto_new = Prop.mk_ptsto_exp (Some tenv) Prop.Fld_init (exp_new, cnt_te, None) Sil.Ialloc in let prop_plus_ptsto = let prop' = Prop.normalize (Prop.prop_sigma_star prop [ptsto_new]) in let ra = { Sil.ra_kind = Sil.Racquire; Sil.ra_res = Sil.Rmemory mk; Sil.ra_pname = procname; Sil.ra_loc = loc; Sil.ra_vpath = None } in (* mark value as allocated *) Prop.add_or_replace_exp_attribute prop' exp_new (Sil.Aresource ra) in let prop_alloc = Prop.conjoin_eq (Sil.Var ret_id) exp_new prop_plus_ptsto in if can_return_null then let prop_null = Prop.conjoin_eq (Sil.Var ret_id) Sil.exp_zero prop in [(prop_alloc, path); (prop_null, path)] else [(prop_alloc, path)] let execute___cxx_typeid ({ Builtin.pdesc; tenv; prop_; args; loc} as r) : Builtin.ret_typ = match args with | type_info_exp :: rest -> (let res = execute_alloc Sil.Mnew false { r with args = [type_info_exp] } in match rest with | [(field_exp, _); (lexp, typ)] -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp, prop = check_arith_norm_exp pname lexp prop_ in let typ = try let hpred = IList.find (function | 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 | _ -> typ with Not_found -> typ in let typ_string = Sil.typ_to_string typ in let set_instr = Sil.Set (field_exp, Sil.Tvoid, Sil.Const (Sil.Cstr typ_string), loc) in SymExec.instrs ~mask_errors:true tenv pdesc [set_instr] res | _ -> res) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute_pthread_create ({ Builtin.prop_; path; args; } as builtin_args) : Builtin.ret_typ = match args with | [_; _; start_routine; arg] -> let routine_name = Prop.exp_normalize_prop prop_ (fst start_routine) in let routine_arg = Prop.exp_normalize_prop prop_ (fst arg) in (match routine_name, (snd start_routine) with | Sil.Lvar pvar, _ -> let fun_name = Pvar.get_name pvar in let fun_string = Mangled.to_string fun_name in L.d_strln ("pthread_create: calling function " ^ fun_string); begin match Specs.get_summary (Procname.from_string_c_fun fun_string) with | None -> assert false | Some callee_summary -> SymExec.proc_call callee_summary { builtin_args with args = [(routine_arg, snd arg)] } end | _ -> L.d_str "pthread_create: unknown function "; Sil.d_exp routine_name; L.d_strln ", skipping call."; [(prop_, path)]) | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute_skip { Builtin.prop_; path; } : Builtin.ret_typ = [(prop_, path)] let execute_scan_function skip_n_arguments ({ Builtin.args } as call_args) : Builtin.ret_typ = match args with | _ when IList.length args >= skip_n_arguments -> let varargs = ref args in for _ = 1 to skip_n_arguments do varargs := IList.tl !varargs done; SymExec.unknown_or_scan_call ~is_scan:true None Sil.item_annotation_empty { call_args with args = !varargs } | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute__unwrap_exception { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(ret_exn, _)] -> begin let pname = Cfg.Procdesc.get_proc_name pdesc in let n_ret_exn, prop = check_arith_norm_exp pname ret_exn prop_ in match n_ret_exn with | Sil.Const (Sil.Cexn exp) -> let prop_with_exn = return_result exp prop ret_ids in [(prop_with_exn, path)] | _ -> assert false end | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute_return_first_argument { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | (arg1_, _):: _ -> let pname = Cfg.Procdesc.get_proc_name pdesc in let arg1, prop = check_arith_norm_exp pname arg1_ prop_ in let prop' = return_result arg1 prop ret_ids in [(prop', path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) let execute___split_get_nth { Builtin.pdesc; prop_; path; ret_ids; args; } : Builtin.ret_typ = match args with | [(lexp1, _); (lexp2, _); (lexp3, _)] -> let pname = Cfg.Procdesc.get_proc_name pdesc in let n_lexp1, prop__ = check_arith_norm_exp pname lexp1 prop_ in let n_lexp2, prop___ = check_arith_norm_exp pname lexp2 prop__ in let n_lexp3, prop = check_arith_norm_exp pname lexp3 prop___ in (match n_lexp1, n_lexp2, n_lexp3 with | Sil.Const (Sil.Cstr str1), Sil.Const (Sil.Cstr str2), Sil.Const (Sil.Cint n_sil) -> (let n = Sil.Int.to_int n_sil in try let parts = Str.split (Str.regexp_string str2) str1 in let n_part = IList.nth parts n in let res = Sil.Const (Sil.Cstr n_part) in [(return_result res prop ret_ids, path)] with Not_found -> assert false) | _ -> [(prop, path)]) | _ -> raise (Exceptions.Wrong_argument_number __POS__) (* forces the expression passed as parameter to be assumed true at the point where this builtin is called, diverges if this causes an inconsistency *) let execute___infer_assume { Builtin.prop_; path; args; } : Builtin.ret_typ = match args with | [(lexp, _)] -> let prop_assume = Prop.conjoin_eq lexp (Sil.exp_bool true) prop_ in if Prover.check_inconsistency prop_assume then SymExec.diverge prop_assume path else [(prop_assume, path)] | _ -> raise (Exceptions.Wrong_argument_number __POS__) (* creates a named error state *) let execute___infer_fail { Builtin.pdesc; tenv; prop_; path; args; loc; } : Builtin.ret_typ = let error_str = match args with | [(lexp_msg, _)] -> begin match Prop.exp_normalize_prop prop_ lexp_msg with | Sil.Const (Sil.Cstr str) -> str | _ -> assert false end | _ -> raise (Exceptions.Wrong_argument_number __POS__) in let set_instr = Sil.Set (Sil.Lvar Sil.custom_error, Sil.Tvoid, Sil.Const (Sil.Cstr error_str), loc) in SymExec.instrs ~mask_errors:true tenv pdesc [set_instr] [(prop_, path)] (* translate builtin assertion failure *) let execute___assert_fail { Builtin.pdesc; tenv; prop_; path; args; loc; } : Builtin.ret_typ = let error_str = match args with | l when IList.length l = 4 -> Config.default_failure_name | _ -> raise (Exceptions.Wrong_argument_number __POS__) in let set_instr = Sil.Set (Sil.Lvar Sil.custom_error, Sil.Tvoid, Sil.Const (Sil.Cstr error_str), loc) in SymExec.instrs ~mask_errors:true tenv pdesc [set_instr] [(prop_, path)] let __assert_fail = Builtin.register "__assert_fail" execute___assert_fail let _ = Builtin.register (* model for va_arg *) "__builtin_va_arg" execute___builtin_va_arg let _ = Builtin.register "__builtin_va_copy" execute_skip let _ = Builtin.register (* model va_end as skip *) "__builtin_va_end" execute_skip let _ = Builtin.register "__builtin_va_start" execute_skip let __cast = Builtin.register (* [__cast(val,typ)] implements java's [typ(val)] *) "__cast" execute___cast let _ = Builtin.register (* report a taint error if the parameter is tainted, and assume it is untainted afterward *) "__check_untainted" execute___check_untainted let __delete = Builtin.register (* like free *) "__delete" (execute_free Sil.Mnew) let __delete_array = Builtin.register (* like free *) "__delete_array" (execute_free Sil.Mnew_array) let __exit = Builtin.register (* _exit from C library *) "_exit" execute_exit let __get_array_size = Builtin.register (* return the size of the array passed as a parameter *) "__get_array_size" execute___get_array_size let __require_allocated_array = Builtin.register (* require the parameter to point to an allocated array *) "__require_allocated_array" execute___require_allocated_array let _ = Builtin.register (* return the value of a hidden field in the struct *) "__get_hidden_field" execute___get_hidden_field let __get_type_of = Builtin.register (* return the get the type of the allocated object passed as a parameter *) "__get_type_of" execute___get_type_of let __infer_assume = Builtin.register (* infer assume, diverging on inconsistencies *) "__infer_assume" execute___infer_assume let __infer_fail = Builtin.register (* externally create new errors *) "__infer_fail" execute___infer_fail let __instanceof = Builtin.register (* [__instanceof(val,typ)] implements java's [val instanceof typ] *) "__instanceof" execute___instanceof let _ = Builtin.register "__method_set_ignore_attribute" execute___method_set_ignore_attribute let __new = Builtin.register (* like malloc, but always succeeds *) "__new" (execute_alloc Sil.Mnew false) let __new_array = Builtin.register (* like malloc, but always succeeds *) "__new_array" (execute_alloc Sil.Mnew_array false) let __objc_alloc = Builtin.register (* Objective C alloc *) "__objc_alloc" (execute_alloc Sil.Mobjc true) let __objc_alloc_no_fail = Builtin.register (* like __objc_alloc, but does not return nil *) "__objc_alloc_no_fail" (execute_alloc Sil.Mobjc false) let __objc_cast = Builtin.register (* objective-c "cast" *) "__objc_cast" execute___objc_cast let __objc_release = Builtin.register (* objective-c "release" *) "__objc_release" execute___objc_release let __objc_release_autorelease_pool = Builtin.register (* set the attribute of the parameter as autorelease *) "__objc_release_autorelease_pool" execute___release_autorelease_pool let __objc_release_cf = Builtin.register (* objective-c "release" *) "__objc_release_cf" execute___objc_release_cf let __objc_retain = Builtin.register (* objective-c "retain" *) "__objc_retain" execute___objc_retain let __objc_retain_cf = Builtin.register "__objc_retain_cf" execute___objc_retain_cf let __cxx_typeid = Builtin.register (* C++ "typeid" *) "__cxx_typeid" execute___cxx_typeid let __placement_delete = Builtin.register (* placement delete is skip *) "__placement_delete" execute_skip let __placement_new = Builtin.register (* placement new returns the first argument *) "__placement_new" execute_return_first_argument let _ = Builtin.register (* print a value as seen by the engine *) "__print_value" execute___print_value let __set_array_size = Builtin.register (* set the size of the array passed as a parameter *) "__set_array_size" execute___set_array_size let __set_autorelease_attribute = Builtin.register (* set the attribute of the parameter as autorelease *) "__set_autorelease_attribute" execute___set_autorelease_attribute let __set_file_attribute = Builtin.register (* set the attribute of the parameter as file *) "__set_file_attribute" execute___set_file_attribute let __set_lock_attribute = Builtin.register (* set the attribute of the parameter as file *) "__set_lock_attribute" execute___set_lock_attribute let __set_mem_attribute = Builtin.register (* set the attribute of the parameter as memory *) "__set_mem_attribute" execute___set_mem_attribute let __set_observer_attribute = Builtin.register (* set the observer attribute of the parameter *) "__set_observer_attribute" (execute___set_attr Sil.Aobserver) let __set_unsubscribed_observer_attribute = Builtin.register (* set the unregistered observer attribute of the parameter *) "__set_unsubscribed_observer_attribute" (execute___set_attr Sil.Aunsubscribed_observer) let __split_get_nth = Builtin.register (* splits a string given a separator and returns the nth string *) "__split_get_nth" execute___split_get_nth let _ = Builtin.register (* set a hidden field in the struct to the given value *) "__set_hidden_field" execute___set_hidden_field let _ = Builtin.register (* set the attribute of the parameter as tainted *) "__set_taint_attribute" execute___set_taint_attribute let _ = Builtin.register (* set the attribute of the parameter as untainted *) "__set_untaint_attribute" execute___set_untaint_attribute let __set_locked_attribute = Builtin.register (* set the attribute of the parameter as locked *) "__set_locked_attribute" execute___set_locked_attribute let __set_unlocked_attribute = Builtin.register (* set the attribute of the parameter as unlocked *) "__set_unlocked_attribute" execute___set_unlocked_attribute let __delete_locked_attribute = Builtin.register (* delete the locked attribute, when it exists *) "__delete_locked_attribute" execute___delete_locked_attribute let _ = Builtin.register "__throw" execute_skip let __unwrap_exception = Builtin.register (* unwrap an exception *) "__unwrap_exception" execute__unwrap_exception let _ = Builtin.register (* abort from C library *) "abort" execute_abort let _ = Builtin.register (* exit from C library *) "exit" execute_exit let _ = Builtin.register (* free from C library, requires allocated memory *) "free" (execute_free Sil.Mmalloc) let _ = Builtin.register (* fscanf from C library *) "fscanf" (execute_scan_function 2) let _ = Builtin.register (* vsscanf from C library *) "fwscanf" (execute_scan_function 2) let _ = Builtin.register (* malloc from C library *) "malloc" (execute_alloc Sil.Mmalloc true) let malloc_no_fail = Builtin.register (* malloc from ObjC library *) "malloc_no_fail" (execute_alloc Sil.Mmalloc false) let _ = Builtin.register (* register execution handler for pthread_create *) "pthread_create" execute_pthread_create let _ = Builtin.register (* scanf from C library *) "scanf" (execute_scan_function 1) let _ = Builtin.register (* sscanf from C library *) "sscanf" (execute_scan_function 2) let _ = Builtin.register (* vsscanf from C library *) "swscanf" (execute_scan_function 2) let _ = Builtin.register (* vfwscanf from C library *) "vfscanf" (execute_scan_function 2) let _ = Builtin.register (* vsscanf from C library *) "vfwscanf" (execute_scan_function 2) let _ = Builtin.register (* vscanf from C library *) "vscanf" (execute_scan_function 1) let _ = Builtin.register (* vsscanf from C library *) "vsscanf" (execute_scan_function 2) let _ = Builtin.register (* vsscanf from C library *) "vswscanf" (execute_scan_function 2) let _ = Builtin.register (* vsscanf from C library *) "vwscanf" (execute_scan_function 1) let _ = Builtin.register (* vsscanf from C library *) "wscanf" (execute_scan_function 1) let execute_objc_alloc_no_fail symb_state typ alloc_fun_opt { 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 alloc_fun_exp = match alloc_fun_opt with | Some pname -> [Sil.Const (Sil.Cfun pname), Sil.Tvoid] | None -> [] in let alloc_instr = Sil.Call (ret_ids, alloc_fun, [(sizeof_typ, ptr_typ)] @ alloc_fun_exp, loc, Sil.cf_default) in SymExec.instrs tenv pdesc [alloc_instr] symb_state let mk_objc_class_method class_name method_name = let method_kind = Procname.mangled_of_objc_method_kind Procname.Class_objc_method in (Procname.ObjC_Cpp (Procname.objc_cpp class_name method_name method_kind)) (* NSArray models *) let arrayWithObjects_pname = mk_objc_class_method "NSArray" "arrayWithObjects:" let arrayWithObjectsCount_pname = mk_objc_class_method "NSArray" "arrayWithObjects:count:" let execute_objc_NSArray_alloc_no_fail ({ Builtin.tenv; } as builtin_args) symb_state pname = let nsarray_typ_ = Sil.Tvar (Typename.TN_csu (Csu.Class Csu.Objc, Mangled.from_string "NSArray")) in let nsarray_typ = Tenv.expand_type tenv nsarray_typ_ in execute_objc_alloc_no_fail symb_state nsarray_typ (Some pname) builtin_args let execute_NSArray_arrayWithObjects_count builtin_args = let n_formals = 1 in let res = SymExec.check_variadic_sentinel ~fails_on_nil: true n_formals (0,1) builtin_args in execute_objc_NSArray_alloc_no_fail builtin_args res arrayWithObjectsCount_pname let execute_NSArray_arrayWithObjects builtin_args = let n_formals = 1 in let res = SymExec.check_variadic_sentinel n_formals (0,1) builtin_args in execute_objc_NSArray_alloc_no_fail builtin_args res arrayWithObjects_pname let _ = Builtin.register_procname arrayWithObjectsCount_pname execute_NSArray_arrayWithObjects_count; Builtin.register_procname arrayWithObjects_pname execute_NSArray_arrayWithObjects (* NSDictionary models *) let execute_objc_NSDictionary_alloc_no_fail symb_state pname ({ Builtin.tenv; } as builtin_args) = let nsdictionary_typ_ = Sil.Tvar (Typename.TN_csu (Csu.Class Csu.Objc, Mangled.from_string "NSDictionary")) in let nsdictionary_typ = Tenv.expand_type tenv nsdictionary_typ_ in execute_objc_alloc_no_fail symb_state nsdictionary_typ (Some pname) builtin_args let __objc_dictionary_literal_pname = mk_objc_class_method "NSDictionary" "dictionaryWithObjects:forKeys:count:" let execute___objc_dictionary_literal builtin_args = let n_formals = 1 in let res' = SymExec.check_variadic_sentinel ~fails_on_nil: true n_formals (0,1) builtin_args in let pname = __objc_dictionary_literal_pname in execute_objc_NSDictionary_alloc_no_fail res' pname builtin_args let __objc_dictionary_literal = let pname = __objc_dictionary_literal_pname in Builtin.register_procname pname execute___objc_dictionary_literal; pname