//===- FuzzerDriver.cpp - FuzzerDriver function and flags -----------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // FuzzerDriver and flag parsing. //===----------------------------------------------------------------------===// #include "FuzzerInterface.h" #include "FuzzerInternal.h" #include #include #include #include #include #include namespace fuzzer { // Program arguments. struct FlagDescription { const char *Name; const char *Description; int Default; int *Flag; }; struct { #define FUZZER_FLAG(Type, Name, Default, Description) Type Name; #include "FuzzerFlags.def" #undef FUZZER_FLAG } Flags; static FlagDescription FlagDescriptions [] { #define FUZZER_FLAG(Type, Name, Default, Description) {#Name, Description, Default, &Flags.Name}, #include "FuzzerFlags.def" #undef FUZZER_FLAG }; static const size_t kNumFlags = sizeof(FlagDescriptions) / sizeof(FlagDescriptions[0]); static std::vector inputs; static const char *ProgName; static void PrintHelp() { std::cerr << "Usage: " << ProgName << " [-flag1=val1 [-flag2=val2 ...] ] [dir1 [dir2 ...] ]\n"; std::cerr << "\nFlags: (strictly in form -flag=value)\n"; size_t MaxFlagLen = 0; for (size_t F = 0; F < kNumFlags; F++) MaxFlagLen = std::max(strlen(FlagDescriptions[F].Name), MaxFlagLen); for (size_t F = 0; F < kNumFlags; F++) { const auto &D = FlagDescriptions[F]; std::cerr << " " << D.Name; for (size_t i = 0, n = MaxFlagLen - strlen(D.Name); i < n; i++) std::cerr << " "; std::cerr << "\t"; std::cerr << D.Default << "\t" << D.Description << "\n"; } } static const char *FlagValue(const char *Param, const char *Name) { size_t Len = strlen(Name); if (Param[0] == '-' && strstr(Param + 1, Name) == Param + 1 && Param[Len + 1] == '=') return &Param[Len + 2]; return nullptr; } static bool ParseOneFlag(const char *Param) { if (Param[0] != '-') return false; for (size_t F = 0; F < kNumFlags; F++) { const char *Name = FlagDescriptions[F].Name; const char *Str = FlagValue(Param, Name); if (Str) { int Val = std::stol(Str); *FlagDescriptions[F].Flag = Val; if (Flags.verbosity >= 2) std::cerr << "Flag: " << Name << " " << Val << "\n"; return true; } } PrintHelp(); exit(1); } // We don't use any library to minimize dependencies. static void ParseFlags(int argc, char **argv) { for (size_t F = 0; F < kNumFlags; F++) *FlagDescriptions[F].Flag = FlagDescriptions[F].Default; for (int A = 1; A < argc; A++) { if (ParseOneFlag(argv[A])) continue; inputs.push_back(argv[A]); } } static void WorkerThread(const std::string &Cmd, std::atomic *Counter, int NumJobs, std::atomic *HasErrors) { static std::mutex CerrMutex; while (true) { int C = (*Counter)++; if (C >= NumJobs) break; std::string Log = "fuzz-" + std::to_string(C) + ".log"; std::string ToRun = Cmd + " > " + Log + " 2>&1\n"; if (Flags.verbosity) std::cerr << ToRun; int ExitCode = system(ToRun.c_str()); if (ExitCode != 0) *HasErrors = true; std::lock_guard Lock(CerrMutex); std::cerr << "================== Job " << C << " exited with exit code " << ExitCode << " =================\n"; fuzzer::CopyFileToErr(Log); } } static int RunInMultipleProcesses(int argc, char **argv, int NumWorkers, int NumJobs) { std::atomic Counter(0); std::atomic HasErrors(false); std::string Cmd; for (int i = 0; i < argc; i++) { if (FlagValue(argv[i], "jobs") || FlagValue(argv[i], "workers")) continue; Cmd += argv[i]; Cmd += " "; } std::vector V; for (int i = 0; i < NumWorkers; i++) V.push_back(std::thread(WorkerThread, Cmd, &Counter, NumJobs, &HasErrors)); for (auto &T : V) T.join(); return HasErrors ? 1 : 0; } int FuzzerDriver(int argc, char **argv, UserCallback Callback) { using namespace fuzzer; ProgName = argv[0]; ParseFlags(argc, argv); if (Flags.help) { PrintHelp(); return 0; } if (Flags.workers > 0 && Flags.jobs > 0) return RunInMultipleProcesses(argc, argv, Flags.workers, Flags.jobs); Fuzzer::FuzzingOptions Options; Options.Verbosity = Flags.verbosity; Options.MaxLen = Flags.max_len; Options.DoCrossOver = Flags.cross_over; Options.MutateDepth = Flags.mutate_depth; Options.ExitOnFirst = Flags.exit_on_first; Options.UseCounters = Flags.use_counters; Options.UseFullCoverageSet = Flags.use_full_coverage_set; Options.UseCoveragePairs = Flags.use_coverage_pairs; Options.PreferSmallDuringInitialShuffle = Flags.prefer_small_during_initial_shuffle; if (Flags.runs >= 0) Options.MaxNumberOfRuns = Flags.runs; if (!inputs.empty()) Options.OutputCorpus = inputs[0]; Fuzzer F(Callback, Options); unsigned seed = Flags.seed; // Initialize seed. if (seed == 0) seed = time(0) * 10000 + getpid(); if (Flags.verbosity) std::cerr << "Seed: " << seed << "\n"; srand(seed); // Timer if (Flags.timeout > 0) SetTimer(Flags.timeout); for (auto &inp : inputs) F.ReadDir(inp); if (F.CorpusSize() == 0) F.AddToCorpus(Unit()); // Can't fuzz empty corpus, so add an empty input. F.ShuffleAndMinimize(); if (Flags.save_minimized_corpus) F.SaveCorpus(); F.Loop(Flags.iterations < 0 ? INT_MAX : Flags.iterations); if (Flags.verbosity) std::cerr << "Done " << F.getTotalNumberOfRuns() << " runs in " << F.secondsSinceProcessStartUp() << " seconds\n"; return 0; } } // namespace fuzzer