mirror of
https://github.com/c64scene-ar/llvm-6502.git
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63da212749
git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@238658 91177308-0d34-0410-b5e6-96231b3b80d8
344 lines
10 KiB
C++
344 lines
10 KiB
C++
//===- FuzzerLoop.cpp - Fuzzer's main loop --------------------------------===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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// Fuzzer's main loop.
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//===----------------------------------------------------------------------===//
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#include "FuzzerInternal.h"
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#include <sanitizer/coverage_interface.h>
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#include <algorithm>
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namespace fuzzer {
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// Only one Fuzzer per process.
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static Fuzzer *F;
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Fuzzer::Fuzzer(UserSuppliedFuzzer &USF, FuzzingOptions Options)
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: USF(USF), Options(Options) {
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SetDeathCallback();
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InitializeTraceState();
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assert(!F);
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F = this;
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}
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void Fuzzer::SetDeathCallback() {
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__sanitizer_set_death_callback(StaticDeathCallback);
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}
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void Fuzzer::PrintUnitInASCIIOrTokens(const Unit &U, const char *PrintAfter) {
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if (Options.Tokens.empty()) {
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PrintASCII(U, PrintAfter);
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} else {
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auto T = SubstituteTokens(U);
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T.push_back(0);
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Printf("%s%s", T.data(), PrintAfter);
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}
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}
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void Fuzzer::StaticDeathCallback() {
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assert(F);
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F->DeathCallback();
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}
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void Fuzzer::DeathCallback() {
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Printf("DEATH:\n");
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Print(CurrentUnit, "\n");
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PrintUnitInASCIIOrTokens(CurrentUnit, "\n");
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WriteToCrash(CurrentUnit, "crash-");
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}
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void Fuzzer::StaticAlarmCallback() {
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assert(F);
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F->AlarmCallback();
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}
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void Fuzzer::AlarmCallback() {
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assert(Options.UnitTimeoutSec > 0);
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size_t Seconds =
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duration_cast<seconds>(system_clock::now() - UnitStartTime).count();
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if (Seconds == 0) return;
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if (Options.Verbosity >= 2)
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Printf("AlarmCallback %zd\n", Seconds);
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if (Seconds >= (size_t)Options.UnitTimeoutSec) {
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Printf("ALARM: working on the last Unit for %zd seconds\n", Seconds);
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Printf(" and the timeout value is %d (use -timeout=N to change)\n",
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Options.UnitTimeoutSec);
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Print(CurrentUnit, "\n");
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PrintUnitInASCIIOrTokens(CurrentUnit, "\n");
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WriteToCrash(CurrentUnit, "timeout-");
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exit(1);
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}
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}
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void Fuzzer::PrintStats(const char *Where, size_t Cov, const char *End) {
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if (!Options.Verbosity) return;
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size_t Seconds = secondsSinceProcessStartUp();
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size_t ExecPerSec = (Seconds ? TotalNumberOfRuns / Seconds : 0);
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Printf("#%zd\t%s cov %zd bits %zd units %zd exec/s %zd %s", TotalNumberOfRuns,
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Where, Cov, TotalBits(), Corpus.size(), ExecPerSec, End);
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}
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void Fuzzer::RereadOutputCorpus() {
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if (Options.OutputCorpus.empty()) return;
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std::vector<Unit> AdditionalCorpus;
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ReadDirToVectorOfUnits(Options.OutputCorpus.c_str(), &AdditionalCorpus,
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&EpochOfLastReadOfOutputCorpus);
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if (Corpus.empty()) {
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Corpus = AdditionalCorpus;
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return;
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}
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if (!Options.Reload) return;
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if (Options.Verbosity >= 2)
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Printf("Reload: read %zd new units.\n", AdditionalCorpus.size());
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for (auto &X : AdditionalCorpus) {
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if (X.size() > (size_t)Options.MaxLen)
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X.resize(Options.MaxLen);
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if (UnitHashesAddedToCorpus.insert(Hash(X)).second) {
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CurrentUnit.clear();
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CurrentUnit.insert(CurrentUnit.begin(), X.begin(), X.end());
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size_t NewCoverage = RunOne(CurrentUnit);
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if (NewCoverage) {
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Corpus.push_back(X);
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if (Options.Verbosity >= 1)
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PrintStats("RELOAD", NewCoverage);
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}
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}
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}
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}
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void Fuzzer::ShuffleAndMinimize() {
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size_t MaxCov = 0;
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bool PreferSmall =
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(Options.PreferSmallDuringInitialShuffle == 1 ||
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(Options.PreferSmallDuringInitialShuffle == -1 && rand() % 2));
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if (Options.Verbosity)
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Printf("PreferSmall: %d\n", PreferSmall);
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PrintStats("READ ", 0);
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std::vector<Unit> NewCorpus;
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std::random_shuffle(Corpus.begin(), Corpus.end());
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if (PreferSmall)
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std::stable_sort(
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Corpus.begin(), Corpus.end(),
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[](const Unit &A, const Unit &B) { return A.size() < B.size(); });
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Unit &U = CurrentUnit;
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for (const auto &C : Corpus) {
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for (size_t First = 0; First < 1; First++) {
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U.clear();
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size_t Last = std::min(First + Options.MaxLen, C.size());
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U.insert(U.begin(), C.begin() + First, C.begin() + Last);
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size_t NewCoverage = RunOne(U);
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if (NewCoverage) {
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MaxCov = NewCoverage;
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NewCorpus.push_back(U);
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if (Options.Verbosity >= 2)
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Printf("NEW0: %zd L %zd\n", NewCoverage, U.size());
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}
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}
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}
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Corpus = NewCorpus;
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for (auto &X : Corpus)
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UnitHashesAddedToCorpus.insert(Hash(X));
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PrintStats("INITED", MaxCov);
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}
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size_t Fuzzer::RunOne(const Unit &U) {
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UnitStartTime = system_clock::now();
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TotalNumberOfRuns++;
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size_t Res = 0;
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if (Options.UseFullCoverageSet)
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Res = RunOneMaximizeFullCoverageSet(U);
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else
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Res = RunOneMaximizeTotalCoverage(U);
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auto UnitStopTime = system_clock::now();
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auto TimeOfUnit =
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duration_cast<seconds>(UnitStopTime - UnitStartTime).count();
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if (TimeOfUnit > TimeOfLongestUnitInSeconds) {
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TimeOfLongestUnitInSeconds = TimeOfUnit;
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Printf("Longest unit: %zd s:\n", TimeOfLongestUnitInSeconds);
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Print(U, "\n");
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}
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return Res;
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}
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void Fuzzer::RunOneAndUpdateCorpus(const Unit &U) {
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if (TotalNumberOfRuns >= Options.MaxNumberOfRuns)
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return;
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ReportNewCoverage(RunOne(U), U);
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}
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static uintptr_t HashOfArrayOfPCs(uintptr_t *PCs, uintptr_t NumPCs) {
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uintptr_t Res = 0;
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for (uintptr_t i = 0; i < NumPCs; i++) {
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Res = (Res + PCs[i]) * 7;
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}
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return Res;
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}
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Unit Fuzzer::SubstituteTokens(const Unit &U) const {
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Unit Res;
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for (auto Idx : U) {
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if (Idx < Options.Tokens.size()) {
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std::string Token = Options.Tokens[Idx];
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Res.insert(Res.end(), Token.begin(), Token.end());
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} else {
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Res.push_back(' ');
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}
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}
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// FIXME: Apply DFSan labels.
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return Res;
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}
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void Fuzzer::ExecuteCallback(const Unit &U) {
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if (Options.Tokens.empty()) {
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USF.TargetFunction(U.data(), U.size());
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} else {
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auto T = SubstituteTokens(U);
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USF.TargetFunction(T.data(), T.size());
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}
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}
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// Experimental.
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// Fuly reset the current coverage state, run a single unit,
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// compute a hash function from the full coverage set,
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// return non-zero if the hash value is new.
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// This produces tons of new units and as is it's only suitable for small tests,
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// e.g. test/FullCoverageSetTest.cpp. FIXME: make it scale.
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size_t Fuzzer::RunOneMaximizeFullCoverageSet(const Unit &U) {
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__sanitizer_reset_coverage();
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ExecuteCallback(U);
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uintptr_t *PCs;
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uintptr_t NumPCs =__sanitizer_get_coverage_guards(&PCs);
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if (FullCoverageSets.insert(HashOfArrayOfPCs(PCs, NumPCs)).second)
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return FullCoverageSets.size();
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return 0;
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}
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size_t Fuzzer::RunOneMaximizeTotalCoverage(const Unit &U) {
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size_t NumCounters = __sanitizer_get_number_of_counters();
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if (Options.UseCounters) {
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CounterBitmap.resize(NumCounters);
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__sanitizer_update_counter_bitset_and_clear_counters(0);
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}
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size_t OldCoverage = __sanitizer_get_total_unique_coverage();
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ExecuteCallback(U);
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size_t NewCoverage = __sanitizer_get_total_unique_coverage();
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size_t NumNewBits = 0;
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if (Options.UseCounters)
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NumNewBits = __sanitizer_update_counter_bitset_and_clear_counters(
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CounterBitmap.data());
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if (!(TotalNumberOfRuns & (TotalNumberOfRuns - 1)) && Options.Verbosity)
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PrintStats("pulse ", NewCoverage);
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if (NewCoverage > OldCoverage || NumNewBits)
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return NewCoverage;
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return 0;
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}
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void Fuzzer::WriteToOutputCorpus(const Unit &U) {
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if (Options.OutputCorpus.empty()) return;
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std::string Path = DirPlusFile(Options.OutputCorpus, Hash(U));
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WriteToFile(U, Path);
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if (Options.Verbosity >= 2)
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Printf("Written to %s\n", Path.c_str());
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}
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void Fuzzer::WriteToCrash(const Unit &U, const char *Prefix) {
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std::string Path = Prefix + Hash(U);
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WriteToFile(U, Path);
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Printf("CRASHED; file written to %s\nBase64: ", Path.c_str());
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PrintFileAsBase64(Path);
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}
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void Fuzzer::SaveCorpus() {
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if (Options.OutputCorpus.empty()) return;
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for (const auto &U : Corpus)
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WriteToFile(U, DirPlusFile(Options.OutputCorpus, Hash(U)));
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if (Options.Verbosity)
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Printf("Written corpus of %zd files to %s\n", Corpus.size(),
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Options.OutputCorpus.c_str());
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}
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void Fuzzer::ReportNewCoverage(size_t NewCoverage, const Unit &U) {
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if (!NewCoverage) return;
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Corpus.push_back(U);
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UnitHashesAddedToCorpus.insert(Hash(U));
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PrintStats("NEW ", NewCoverage, "");
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if (Options.Verbosity) {
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Printf(" L: %zd", U.size());
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if (U.size() < 30) {
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Printf(" ");
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PrintUnitInASCIIOrTokens(U, "\t");
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Print(U);
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}
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Printf("\n");
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}
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WriteToOutputCorpus(U);
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if (Options.ExitOnFirst)
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exit(0);
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}
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void Fuzzer::MutateAndTestOne(Unit *U) {
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for (int i = 0; i < Options.MutateDepth; i++) {
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StartTraceRecording();
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size_t Size = U->size();
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U->resize(Options.MaxLen);
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size_t NewSize = USF.Mutate(U->data(), Size, U->size());
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assert(NewSize > 0 && "Mutator returned empty unit");
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assert(NewSize <= (size_t)Options.MaxLen &&
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"Mutator return overisized unit");
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U->resize(NewSize);
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RunOneAndUpdateCorpus(*U);
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size_t NumTraceBasedMutations = StopTraceRecording();
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for (size_t j = 0; j < NumTraceBasedMutations; j++) {
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ApplyTraceBasedMutation(j, U);
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RunOneAndUpdateCorpus(*U);
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}
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}
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}
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void Fuzzer::Loop(size_t NumIterations) {
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for (size_t i = 1; i <= NumIterations; i++) {
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for (size_t J1 = 0; J1 < Corpus.size(); J1++) {
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SyncCorpus();
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RereadOutputCorpus();
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if (TotalNumberOfRuns >= Options.MaxNumberOfRuns)
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return;
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// First, simply mutate the unit w/o doing crosses.
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CurrentUnit = Corpus[J1];
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MutateAndTestOne(&CurrentUnit);
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// Now, cross with others.
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if (Options.DoCrossOver && !Corpus[J1].empty()) {
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for (size_t J2 = 0; J2 < Corpus.size(); J2++) {
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CurrentUnit.resize(Options.MaxLen);
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size_t NewSize = USF.CrossOver(
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Corpus[J1].data(), Corpus[J1].size(), Corpus[J2].data(),
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Corpus[J2].size(), CurrentUnit.data(), CurrentUnit.size());
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assert(NewSize > 0 && "CrossOver returned empty unit");
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assert(NewSize <= (size_t)Options.MaxLen &&
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"CrossOver return overisized unit");
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CurrentUnit.resize(NewSize);
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MutateAndTestOne(&CurrentUnit);
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}
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}
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}
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}
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}
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void Fuzzer::SyncCorpus() {
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if (Options.SyncCommand.empty() || Options.OutputCorpus.empty()) return;
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auto Now = system_clock::now();
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if (duration_cast<seconds>(Now - LastExternalSync).count() <
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Options.SyncTimeout)
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return;
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LastExternalSync = Now;
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ExecuteCommand(Options.SyncCommand + " " + Options.OutputCorpus);
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}
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} // namespace fuzzer
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