(* * Copyright (c) 2017-present, Facebook, Inc. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. *) open! IStd open AbsLoc open! AbstractDomain.Types module L = Logging module Dom = BufferOverrunDomain module Relation = BufferOverrunDomainRelation module PO = BufferOverrunProofObligations module Sem = BufferOverrunSemantics module Trace = BufferOverrunTrace module TraceSet = Trace.Set module TypModels = BufferOverrunTypModels module ModelEnv = struct type model_env = { pname: Typ.Procname.t ; node_hash: int ; location: Location.t ; tenv: Tenv.t ; integer_type_widths: Typ.IntegerWidths.t } let mk_model_env pname ~node_hash location tenv integer_type_widths = {pname; node_hash; location; tenv; integer_type_widths} end module Exec = struct open ModelEnv let load_locs id locs mem = let v = Dom.Mem.find_set locs mem in let mem = Dom.Mem.add_stack (Loc.of_id id) v mem in if not v.represents_multiple_values then match PowLoc.is_singleton_or_more locs with | IContainer.Singleton loc -> Dom.Mem.load_simple_alias id loc mem | _ -> mem else mem let rec decl_local_loc ({tenv} as model_env) loc typ ~inst_num ~represents_multiple_values ~dimension mem = match typ.Typ.desc with | Typ.Tarray {elt= typ; length; stride} -> let stride = Option.map ~f:IntLit.to_int_exn stride in decl_local_array model_env loc typ ~length ?stride ~inst_num ~represents_multiple_values ~dimension mem | Typ.Tstruct typname -> ( match TypModels.dispatch tenv typname with | Some (CArray {element_typ; length}) -> decl_local_array model_env loc element_typ ~length:(Some length) ~inst_num ~represents_multiple_values ~dimension mem | Some JavaCollection | None -> (mem, inst_num) ) | _ -> (mem, inst_num) and decl_local_array ({pname; node_hash; location} as model_env) loc typ ~length ?stride ~inst_num ~represents_multiple_values ~dimension mem = let size = Option.value_map ~default:Itv.top ~f:Itv.of_int_lit length in let path = Loc.get_path loc in let allocsite = let represents_multiple_values = represents_multiple_values || not (Itv.is_one size) in Allocsite.make pname ~node_hash ~inst_num ~dimension ~path ~represents_multiple_values in let mem = let arr, offset_opt = let traces = Trace.(Set.singleton location ArrayDeclaration) in match Typ.Procname.get_language pname with | Language.Clang -> let offset = Itv.zero in (Dom.Val.of_c_array_alloc allocsite ~stride ~offset ~size ~traces, Some offset) | Language.Java -> (Dom.Val.of_java_array_alloc allocsite ~length:size ~traces, None) in let arr = Dom.Val.sets_represents_multiple_values arr ~represents_multiple_values in let mem = Dom.Mem.init_array_relation allocsite ~offset_opt ~size ~size_exp_opt:None mem in if Int.equal dimension 1 then Dom.Mem.add_stack loc arr mem else Dom.Mem.add_heap loc arr mem in let loc = Loc.of_allocsite allocsite in let mem, _ = decl_local_loc model_env loc typ ~inst_num ~represents_multiple_values:true ~dimension:(dimension + 1) mem in (mem, inst_num + 1) let decl_local model_env (mem, inst_num) (loc, typ) = decl_local_loc model_env loc typ ~inst_num ~represents_multiple_values:false ~dimension:1 mem let init_c_array_fields {pname; node_hash; tenv; integer_type_widths} path typ locs ?dyn_length mem = let rec init_field path locs dimension ?dyn_length (mem, inst_num) (field_name, field_typ, _) = let field_path = Option.map path ~f:(fun path -> Symb.SymbolPath.field path field_name) in let field_loc = PowLoc.append_field locs ~fn:field_name in let mem = match field_typ.Typ.desc with | Tarray {length= Some length; stride} -> let length = Itv.of_int_lit length in let length = Option.value_map dyn_length ~default:length ~f:(fun dyn_length -> let i = Dom.Val.get_itv (Sem.eval integer_type_widths dyn_length mem) in Itv.plus i length ) in let stride = Option.map stride ~f:IntLit.to_int_exn in let allocsite = let represents_multiple_values = not (Itv.is_one length) in Allocsite.make pname ~node_hash ~inst_num ~dimension ~path:field_path ~represents_multiple_values in let offset, size = (Itv.zero, length) in let v = let traces = TraceSet.bottom (* TODO: location of field declaration *) in Dom.Val.of_c_array_alloc allocsite ~stride ~offset ~size ~traces in mem |> Dom.Mem.strong_update field_loc v |> Dom.Mem.init_array_relation allocsite ~offset_opt:(Some offset) ~size ~size_exp_opt:None | _ -> init_fields field_path field_typ field_loc dimension ?dyn_length mem in (mem, inst_num + 1) and init_fields path typ locs dimension ?dyn_length mem = match typ.Typ.desc with | Tstruct typename -> ( match Tenv.lookup tenv typename with | Some str -> let f = init_field path locs (dimension + 1) in IList.fold_last ~f ~f_last:(f ?dyn_length) ~init:(mem, 1) str.Typ.Struct.fields |> fst | None -> mem ) | _ -> mem in init_fields path typ locs 1 ?dyn_length mem let rec set_dyn_length ({location; tenv} as model_env) typ locs dyn_length mem = match typ.Typ.desc with | Tstruct typename -> ( match Tenv.lookup tenv typename with | Some {fields} when not (List.is_empty fields) -> ( let field_name, field_typ, _ = List.last_exn fields in let field_loc = PowLoc.append_field locs ~fn:field_name in match field_typ.Typ.desc with | Tarray {length= Some length} -> let length = Itv.plus (Itv.of_int_lit length) dyn_length |> Dom.Val.of_itv in let v = Dom.Mem.find_set field_loc mem |> Dom.Val.set_array_length location ~length in Dom.Mem.strong_update field_loc v mem | _ -> set_dyn_length model_env field_typ field_loc dyn_length mem ) | _ -> mem ) | _ -> mem let get_max_char s = String.fold s ~init:0 ~f:(fun acc c -> max acc (Char.to_int c)) let decl_string {pname; node_hash; location; integer_type_widths} ~do_alloc locs s mem = let stride = Some (Typ.width_of_ikind integer_type_widths IChar / 8) in let offset = Itv.zero in let size = Itv.of_int (String.length s + 1) in let traces = Trace.Set.singleton location Trace.ArrayDeclaration in let char_itv = Itv.join Itv.zero (Itv.of_int (get_max_char s)) in let decl loc mem = (* It doesn't allocate if the character pointer is in stack, because they are already allocated at the entry of the function. *) let deref_loc, mem = if do_alloc then let allocsite = let deref_kind = Symb.SymbolPath.Deref_ArrayIndex in let path = Loc.get_path loc in let deref_path = Option.map ~f:(fun path -> Symb.SymbolPath.deref ~deref_kind path) path in Allocsite.make pname ~node_hash ~inst_num:0 ~dimension:1 ~path:deref_path ~represents_multiple_values:true in let v = Dom.Val.of_c_array_alloc allocsite ~stride ~offset ~size ~traces in (Loc.of_allocsite allocsite, Dom.Mem.update_mem (PowLoc.singleton loc) v mem) else (loc, mem) in mem |> Dom.Mem.add_heap deref_loc (Dom.Val.of_itv char_itv) |> Dom.Mem.set_first_idx_of_null deref_loc (Dom.Val.of_itv ~traces (Itv.of_int (String.length s))) in PowLoc.fold decl locs mem let set_c_strlen ~tgt ~src mem = let traces = TraceSet.join (Dom.Val.get_traces tgt) (Dom.Val.get_traces src) in let src_itv = Dom.Val.get_itv src in let set_c_strlen1 allocsite arrinfo acc = let loc = Loc.of_allocsite allocsite in let idx = Dom.Val.of_itv ~traces (ArrayBlk.ArrInfo.offsetof arrinfo) in if Itv.( <= ) ~lhs:Itv.zero ~rhs:src_itv then Dom.Mem.set_first_idx_of_null loc idx acc else Dom.Mem.unset_first_idx_of_null loc idx acc in ArrayBlk.fold set_c_strlen1 (Dom.Val.get_array_blk tgt) mem end module Check = struct let check_access ~size ~idx ~offset ~size_sym_exp ~idx_sym_exp ~relation ~arr_traces ~idx_traces ~last_included ~latest_prune location cond_set = match (size, idx) with | NonBottom length, NonBottom idx -> PO.ConditionSet.add_array_access location ~size:length ~offset ~idx ~size_sym_exp ~idx_sym_exp ~relation ~last_included ~idx_traces ~arr_traces ~latest_prune cond_set | _ -> cond_set let log_array_access allocsite size offset idx = L.(debug BufferOverrun Verbose) "@[Add condition :@,array: %a@, size: %a@, idx: %a + %a@,@]@." Allocsite.pp allocsite Itv.pp size Itv.ItvPure.pp offset Itv.pp idx let offsetof arr_info = match ArrayBlk.ArrInfo.offsetof arr_info with | Bottom -> (* Java's collection has no offset. *) Itv.ItvPure.zero | NonBottom offset -> offset let array_access ~arr ~idx ~idx_sym_exp ~relation ~is_plus ~last_included ~latest_prune location cond_set = let idx_traces = Dom.Val.get_traces idx in let idx = let idx_itv = Dom.Val.get_itv idx in if is_plus then idx_itv else Itv.neg idx_itv in let arr_traces = Dom.Val.get_traces arr in let size_sym_exp = Relation.SymExp.of_sym (Dom.Val.get_size_sym arr) in let idx_sym_exp = let offset_sym_exp = Relation.SymExp.of_sym (Dom.Val.get_offset_sym arr) in Option.map2 offset_sym_exp idx_sym_exp ~f:(fun offset_sym_exp idx_sym_exp -> let op = if is_plus then Relation.SymExp.plus else Relation.SymExp.minus in op idx_sym_exp offset_sym_exp ) in let array_access1 allocsite arr_info acc = let size = ArrayBlk.ArrInfo.sizeof arr_info in let offset = offsetof arr_info in log_array_access allocsite size offset idx ; check_access ~size ~idx ~offset ~size_sym_exp ~idx_sym_exp ~relation ~arr_traces ~idx_traces ~last_included ~latest_prune location acc in ArrayBlk.fold array_access1 (Dom.Val.get_array_blk arr) cond_set let lindex integer_type_widths ~array_exp ~index_exp ~last_included mem location cond_set = let idx = Sem.eval integer_type_widths index_exp mem in let arr = Sem.eval_arr integer_type_widths array_exp mem in let idx_sym_exp = Relation.SymExp.of_exp ~get_sym_f:(Sem.get_sym_f integer_type_widths mem) index_exp in let relation = Dom.Mem.get_relation mem in let latest_prune = Dom.Mem.get_latest_prune mem in array_access ~arr ~idx ~idx_sym_exp ~relation ~is_plus:true ~last_included ~latest_prune location cond_set let array_access_byte ~arr ~idx ~relation ~is_plus ~last_included ~latest_prune location cond_set = let idx_traces = Dom.Val.get_traces idx in let idx = let idx_itv = Dom.Val.get_itv idx in if is_plus then idx_itv else Itv.neg idx_itv in let arr_traces = Dom.Val.get_traces arr in let array_access_byte1 allocsite arr_info acc = let size = ArrayBlk.ArrInfo.byte_size arr_info in let offset = offsetof arr_info in log_array_access allocsite size offset idx ; check_access ~size ~idx ~offset ~size_sym_exp:None ~idx_sym_exp:None ~relation ~arr_traces ~idx_traces ~last_included ~latest_prune location acc in ArrayBlk.fold array_access_byte1 (Dom.Val.get_array_blk arr) cond_set let lindex_byte integer_type_widths ~array_exp ~byte_index_exp ~last_included mem location cond_set = let idx = Sem.eval integer_type_widths byte_index_exp mem in let arr = Sem.eval_arr integer_type_widths array_exp mem in let relation = Dom.Mem.get_relation mem in let latest_prune = Dom.Mem.get_latest_prune mem in array_access_byte ~arr ~idx ~relation ~is_plus:true ~last_included ~latest_prune location cond_set let binary_operation integer_type_widths bop ~lhs ~rhs ~latest_prune location cond_set = let lhs_itv = Dom.Val.get_itv lhs in let rhs_itv = Dom.Val.get_itv rhs in match (lhs_itv, rhs_itv) with | NonBottom lhs_itv, NonBottom rhs_itv -> L.(debug BufferOverrun Verbose) "@[Add condition :@,bop:%s@, lhs: %a@, rhs: %a@,@]@." (Binop.str Pp.text bop) Itv.ItvPure.pp lhs_itv Itv.ItvPure.pp rhs_itv ; PO.ConditionSet.add_binary_operation integer_type_widths location bop ~lhs:lhs_itv ~rhs:rhs_itv ~lhs_traces:(Dom.Val.get_traces lhs) ~rhs_traces:(Dom.Val.get_traces rhs) ~latest_prune cond_set | _, _ -> cond_set end