(* * 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! IStd open! AbstractDomain.Types module F = Format module L = Logging module GlobalVar = SiofTrace.GlobalVar module GlobalVarSet = SiofTrace.GlobalVarSet let methods_whitelist = QualifiedCppName.Match.of_fuzzy_qual_names Config.siof_safe_methods let is_whitelisted (pname: Typ.Procname.t) = Typ.Procname.get_qualifiers pname |> QualifiedCppName.Match.match_qualifiers methods_whitelist type siof_model = { qual_name: string (** (fuzzy) name of the method, eg "std::ios_base::Init::Init" *) ; initialized_globals: string list (** names of variables that are guaranteed to be initialized once the method is executed, eg ["std::cerr"] *) } let parse_siof_model (qual_name, initialized_globals) = {qual_name; initialized_globals} let standard_streams = [ "std::cerr" ; "std::wcerr" ; "std::cin" ; "std::wcin" ; "std::clog" ; "std::wclog" ; "std::cout" ; "std::wcout" ] let always_initialized = (* We model "std::ios_base::Init::Init" as initializing [standard_streams], which works if either infer's cxx models are enabled ([Config.cxx_infer_headers]) or if the stdlib is a recent libstdc++ (which is kind enough to create an [std::ios_base::Init] object explicitely). In other cases, we assume they are always initialized so as not to be noisy. The issue to remove this assumption would be to detect when is included in a file without swapping the C++ includes for our own. *) if Config.siof_check_iostreams then [] else standard_streams let models = List.map ~f:parse_siof_model [("std::ios_base::Init::Init", standard_streams)] let is_modelled = let models_matcher = List.map models ~f:(fun {qual_name} -> qual_name) |> QualifiedCppName.Match.of_fuzzy_qual_names in fun pname -> Typ.Procname.get_qualifiers pname |> QualifiedCppName.Match.match_qualifiers models_matcher module Payload = SummaryPayload.Make (struct type t = SiofDomain.Summary.astate let update_payloads astate (payloads: Payloads.t) = {payloads with siof= Some astate} let of_payloads (payloads: Payloads.t) = payloads.siof end) module TransferFunctions (CFG : ProcCfg.S) = struct module CFG = CFG module Domain = SiofDomain type extras = ProcData.no_extras let is_compile_time_constructed pdesc pv = let init_pname = Pvar.get_initializer_pname pv in match Option.bind init_pname ~f:(Payload.read pdesc) with | Some (Bottom, _) -> (* we analyzed the initializer for this global and found that it doesn't require any runtime initialization so cannot participate in SIOF *) true | _ -> false let filter_global_accesses initialized = let initialized_matcher = Domain.VarNames.elements initialized |> QualifiedCppName.Match.of_fuzzy_qual_names in Staged.stage (fun (* gvar \notin initialized, up to some fuzzing *) gvar -> QualifiedCppName.of_qual_string (Pvar.to_string gvar) |> Fn.non (QualifiedCppName.Match.match_qualifiers initialized_matcher) ) let is_not_always_initialized = Staged.unstage (filter_global_accesses (Domain.VarNames.of_list always_initialized)) let get_globals pdesc e = let is_dangerous_global pv = Pvar.is_global pv && not (Pvar.is_static_local pv) && not (Pvar.is_pod pv) && not (Pvar.is_compile_constant pv) && not (is_compile_time_constructed pdesc pv) && is_not_always_initialized pv in Exp.program_vars e |> Sequence.fold ~init:GlobalVarSet.empty ~f:(fun gset g -> if is_dangerous_global g then GlobalVarSet.add g gset else gset ) let add_globals astate loc globals = if GlobalVarSet.is_empty globals then astate else let trace = match fst astate with Bottom -> SiofTrace.empty | NonBottom t -> t in let is_dangerous = (* filter out variables that are known to be already initialized *) let initialized = snd astate in filter_global_accesses initialized |> Staged.unstage in let trace_with_non_init_globals = GlobalVarSet.fold (fun global acc -> if is_dangerous global then SiofTrace.add_sink (SiofTrace.make_access global loc) acc else acc ) globals trace in (NonBottom trace_with_non_init_globals, snd astate) let add_actuals_globals astate0 pdesc call_loc actuals = List.fold_left actuals ~init:astate0 ~f:(fun astate (e, _) -> get_globals pdesc e |> add_globals astate call_loc ) let at_least_nonbottom = Domain.join (NonBottom SiofTrace.empty, Domain.VarNames.empty) let exec_instr astate {ProcData.pdesc} _ (instr: Sil.instr) = match instr with | Load (_, exp, _, loc) | Store (_, _, exp, loc) | Prune (exp, loc, _, _) -> get_globals pdesc exp |> add_globals astate loc | Call (_, Const (Cfun callee_pname), _, _, _) when is_whitelisted callee_pname -> at_least_nonbottom astate | Call (_, Const (Cfun callee_pname), _, _, _) when is_modelled callee_pname -> let init = List.find_map_exn models ~f:(fun {qual_name; initialized_globals} -> if QualifiedCppName.Match.of_fuzzy_qual_names [qual_name] |> Fn.flip QualifiedCppName.Match.match_qualifiers (Typ.Procname.get_qualifiers callee_pname) then Some initialized_globals else None ) in Domain.join astate (NonBottom SiofTrace.empty, Domain.VarNames.of_list init) | Call (_, Const (Cfun (ObjC_Cpp cpp_pname as callee_pname)), _ :: actuals_without_self, loc, _) when Typ.Procname.is_constructor callee_pname && Typ.Procname.ObjC_Cpp.is_constexpr cpp_pname -> add_actuals_globals astate pdesc loc actuals_without_self | Call (_, Const (Cfun callee_pname), actuals, loc, _) -> let callee_astate = match Payload.read pdesc callee_pname with | Some (NonBottom trace, initialized_by_callee) -> let already_initialized = snd astate in let dangerous_accesses = SiofTrace.sinks trace |> SiofTrace.Sinks.filter (fun sink -> SiofTrace.Sink.kind sink |> Staged.unstage (filter_global_accesses already_initialized) ) in let callsite = CallSite.make callee_pname loc in let sinks = SiofTrace.Sinks.map (fun access -> SiofTrace.Sink.with_callsite access callsite) dangerous_accesses in (NonBottom (SiofTrace.update_sinks trace sinks), initialized_by_callee) | Some ((Bottom, _) as callee_astate) -> callee_astate | None -> (Bottom, Domain.VarNames.empty) in add_actuals_globals astate pdesc loc actuals |> Domain.join callee_astate |> (* make sure it's not Bottom: we made a function call so this needs initialization *) at_least_nonbottom | Call (_, _, actuals, loc, _) -> add_actuals_globals astate pdesc loc actuals |> (* make sure it's not Bottom: we made a function call so this needs initialization *) at_least_nonbottom | Declare_locals _ | Remove_temps _ | Abstract _ | Nullify _ -> astate let pp_session_name _node fmt = F.pp_print_string fmt "siof" end module Analyzer = AbstractInterpreter.Make (ProcCfg.Normal) (TransferFunctions) let is_foreign tu_opt v = match (Pvar.get_translation_unit v, tu_opt) with | Some v_tu, Some current_tu -> not (SourceFile.equal current_tu v_tu) | None, Some _ -> true | _, None -> L.(die InternalError) "cannot be called with translation unit set to None" let report_siof summary trace pdesc gname loc = let trace_of_pname pname = match Payload.read pdesc pname with | Some (NonBottom summary, _) -> summary | _ -> SiofTrace.empty in let report_one_path ((_, path) as trace) = let description = match path with | [] -> assert false | (final_sink, _) :: _ -> F.asprintf "Initializer of %s accesses global variable from a different translation unit: %a" gname GlobalVar.pp (SiofTrace.Sink.kind final_sink) in let ltr = SiofTrace.trace_of_error loc gname trace in let exn = Exceptions.Checkers (IssueType.static_initialization_order_fiasco, Localise.verbatim_desc description) in Reporting.log_error summary ~loc ~ltr exn in let reportable_paths = SiofTrace.get_reportable_sink_paths trace ~trace_of_pname in if Config.filtering then List.hd reportable_paths |> Option.iter ~f:report_one_path else List.iter ~f:report_one_path reportable_paths let siof_check pdesc gname (summary: Summary.t) = match summary.payloads.siof with | Some (NonBottom post, _) -> let attrs = Procdesc.get_attributes pdesc in let tu_opt = let attrs = Procdesc.get_attributes pdesc in attrs.ProcAttributes.translation_unit in let foreign_sinks = SiofTrace.Sinks.filter (fun sink -> SiofTrace.Sink.kind sink |> is_foreign tu_opt) (SiofTrace.sinks post) in if not (SiofTrace.Sinks.is_empty foreign_sinks) then report_siof summary (SiofTrace.update_sinks post foreign_sinks) pdesc gname attrs.ProcAttributes.loc | Some (Bottom, _) | None -> () let checker {Callbacks.proc_desc; tenv; summary; get_procs_in_file} : Summary.t = let pname = Procdesc.get_proc_name proc_desc in let standard_streams_initialized_in_tu = let includes_iostream tu = let magic_iostream_marker = (* always [Some _] because we create a global variable with [mk_global] *) Option.value_exn ( Pvar.mk_global ~translation_unit:tu (Mangled.from_string (* infer's C++ headers define this global variable in *) "__infer_translation_unit_init_streams") |> Pvar.get_initializer_pname ) in get_procs_in_file pname |> List.exists ~f:(Typ.Procname.equal magic_iostream_marker) in Option.value_map ~default:false ~f:includes_iostream (Procdesc.get_attributes proc_desc).ProcAttributes.translation_unit in let proc_data = ProcData.make_default proc_desc tenv in let initial = ( Bottom , if standard_streams_initialized_in_tu then SiofDomain.VarNames.of_list standard_streams else SiofDomain.VarNames.empty ) in let updated_summary = (* If the function is constexpr then it doesn't participate in SIOF. The checker should be able to figure this out when analyzing the function, but we might as well use the user's specification if it's given to us. This also serves as an optimization as this skips the analysis of the function. *) if match pname with | ObjC_Cpp cpp_pname -> Typ.Procname.ObjC_Cpp.is_constexpr cpp_pname | _ -> false then Payload.update_summary initial summary else match Analyzer.compute_post proc_data ~initial with | Some post -> Payload.update_summary post summary | None -> summary in ( match Typ.Procname.get_global_name_of_initializer pname with | Some gname -> siof_check proc_desc gname updated_summary | None -> () ) ; updated_summary