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//===- FuzzerMerge.cpp - merging corpora ----------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// Merging corpora.
//===----------------------------------------------------------------------===//
#include "FuzzerCommand.h"
#include "FuzzerMerge.h"
#include "FuzzerIO.h"
#include "FuzzerInternal.h"
#include "FuzzerTracePC.h"
#include "FuzzerUtil.h"
#include <fstream>
#include <iterator>
#include <set>
#include <sstream>
#include <unordered_set>
namespace fuzzer {
bool Merger::Parse(const std::string &Str, bool ParseCoverage) {
std::istringstream SS(Str);
return Parse(SS, ParseCoverage);
}
void Merger::ParseOrExit(std::istream &IS, bool ParseCoverage) {
if (!Parse(IS, ParseCoverage)) {
Printf("MERGE: failed to parse the control file (unexpected error)\n");
exit(1);
}
}
// The control file example:
//
// 3 # The number of inputs
// 1 # The number of inputs in the first corpus, <= the previous number
// file0
// file1
// file2 # One file name per line.
// STARTED 0 123 # FileID, file size
// FT 0 1 4 6 8 # FileID COV1 COV2 ...
// COV 0 7 8 9 # FileID COV1 COV1
// STARTED 1 456 # If FT is missing, the input crashed while processing.
// STARTED 2 567
// FT 2 8 9
// COV 2 11 12
bool Merger::Parse(std::istream &IS, bool ParseCoverage) {
LastFailure.clear();
std::string Line;
// Parse NumFiles.
if (!std::getline(IS, Line, '\n')) return false;
std::istringstream L1(Line);
size_t NumFiles = 0;
L1 >> NumFiles;
if (NumFiles == 0 || NumFiles > 10000000) return false;
// Parse NumFilesInFirstCorpus.
if (!std::getline(IS, Line, '\n')) return false;
std::istringstream L2(Line);
NumFilesInFirstCorpus = NumFiles + 1;
L2 >> NumFilesInFirstCorpus;
if (NumFilesInFirstCorpus > NumFiles) return false;
// Parse file names.
Files.resize(NumFiles);
for (size_t i = 0; i < NumFiles; i++)
if (!std::getline(IS, Files[i].Name, '\n'))
return false;
// Parse STARTED, FT, and COV lines.
size_t ExpectedStartMarker = 0;
const size_t kInvalidStartMarker = -1;
size_t LastSeenStartMarker = kInvalidStartMarker;
bool HaveFtMarker = true;
std::vector<uint32_t> TmpFeatures;
std::set<uint32_t> PCs;
while (std::getline(IS, Line, '\n')) {
std::istringstream ISS1(Line);
std::string Marker;
uint32_t N;
if (!(ISS1 >> Marker) || !(ISS1 >> N))
return false;
if (Marker == "STARTED") {
// STARTED FILE_ID FILE_SIZE
if (ExpectedStartMarker != N)
return false;
ISS1 >> Files[ExpectedStartMarker].Size;
LastSeenStartMarker = ExpectedStartMarker;
assert(ExpectedStartMarker < Files.size());
ExpectedStartMarker++;
HaveFtMarker = false;
} else if (Marker == "FT") {
// FT FILE_ID COV1 COV2 COV3 ...
size_t CurrentFileIdx = N;
if (CurrentFileIdx != LastSeenStartMarker)
return false;
HaveFtMarker = true;
if (ParseCoverage) {
TmpFeatures.clear(); // use a vector from outer scope to avoid resizes.
while (ISS1 >> N)
TmpFeatures.push_back(N);
std::sort(TmpFeatures.begin(), TmpFeatures.end());
Files[CurrentFileIdx].Features = TmpFeatures;
}
} else if (Marker == "COV") {
size_t CurrentFileIdx = N;
if (CurrentFileIdx != LastSeenStartMarker)
return false;
if (ParseCoverage)
while (ISS1 >> N)
if (PCs.insert(N).second)
Files[CurrentFileIdx].Cov.push_back(N);
} else {
return false;
}
}
if (!HaveFtMarker && LastSeenStartMarker != kInvalidStartMarker)
LastFailure = Files[LastSeenStartMarker].Name;
FirstNotProcessedFile = ExpectedStartMarker;
return true;
}
size_t Merger::ApproximateMemoryConsumption() const {
size_t Res = 0;
for (const auto &F: Files)
Res += sizeof(F) + F.Features.size() * sizeof(F.Features[0]);
return Res;
}
// Decides which files need to be merged (add those to NewFiles).
// Returns the number of new features added.
size_t Merger::Merge(const std::set<uint32_t> &InitialFeatures,
std::set<uint32_t> *NewFeatures,
const std::set<uint32_t> &InitialCov,
std::set<uint32_t> *NewCov,
std::vector<std::string> *NewFiles) {
NewFiles->clear();
NewFeatures->clear();
NewCov->clear();
assert(NumFilesInFirstCorpus <= Files.size());
std::set<uint32_t> AllFeatures = InitialFeatures;
// What features are in the initial corpus?
for (size_t i = 0; i < NumFilesInFirstCorpus; i++) {
auto &Cur = Files[i].Features;
AllFeatures.insert(Cur.begin(), Cur.end());
}
// Remove all features that we already know from all other inputs.
for (size_t i = NumFilesInFirstCorpus; i < Files.size(); i++) {
auto &Cur = Files[i].Features;
std::vector<uint32_t> Tmp;
std::set_difference(Cur.begin(), Cur.end(), AllFeatures.begin(),
AllFeatures.end(), std::inserter(Tmp, Tmp.begin()));
Cur.swap(Tmp);
}
// Sort. Give preference to
// * smaller files
// * files with more features.
std::sort(Files.begin() + NumFilesInFirstCorpus, Files.end(),
[&](const MergeFileInfo &a, const MergeFileInfo &b) -> bool {
if (a.Size != b.Size)
return a.Size < b.Size;
return a.Features.size() > b.Features.size();
});
// One greedy pass: add the file's features to AllFeatures.
// If new features were added, add this file to NewFiles.
for (size_t i = NumFilesInFirstCorpus; i < Files.size(); i++) {
auto &Cur = Files[i].Features;
// Printf("%s -> sz %zd ft %zd\n", Files[i].Name.c_str(),
// Files[i].Size, Cur.size());
bool FoundNewFeatures = false;
for (auto Fe: Cur) {
if (AllFeatures.insert(Fe).second) {
FoundNewFeatures = true;
NewFeatures->insert(Fe);
}
}
if (FoundNewFeatures)
NewFiles->push_back(Files[i].Name);
for (auto Cov : Files[i].Cov)
if (InitialCov.find(Cov) == InitialCov.end())
NewCov->insert(Cov);
}
return NewFeatures->size();
}
std::set<uint32_t> Merger::AllFeatures() const {
std::set<uint32_t> S;
for (auto &File : Files)
S.insert(File.Features.begin(), File.Features.end());
return S;
}
// Inner process. May crash if the target crashes.
void Fuzzer::CrashResistantMergeInternalStep(const std::string &CFPath,
bool IsSetCoverMerge) {
Printf("MERGE-INNER: using the control file '%s'\n", CFPath.c_str());
Merger M;
std::ifstream IF(CFPath);
M.ParseOrExit(IF, false);
IF.close();
if (!M.LastFailure.empty())
Printf("MERGE-INNER: '%s' caused a failure at the previous merge step\n",
M.LastFailure.c_str());
Printf("MERGE-INNER: %zd total files;"
" %zd processed earlier; will process %zd files now\n",
M.Files.size(), M.FirstNotProcessedFile,
M.Files.size() - M.FirstNotProcessedFile);
std::ofstream OF(CFPath, std::ofstream::out | std::ofstream::app);
std::set<size_t> AllFeatures;
auto PrintStatsWrapper = [this, &AllFeatures](const char* Where) {
this->PrintStats(Where, "\n", 0, AllFeatures.size());
};
std::set<const TracePC::PCTableEntry *> AllPCs;
for (size_t i = M.FirstNotProcessedFile; i < M.Files.size(); i++) {
Fuzzer::MaybeExitGracefully();
auto U = FileToVector(M.Files[i].Name);
if (U.size() > MaxInputLen) {
U.resize(MaxInputLen);
U.shrink_to_fit();
}
// Write the pre-run marker.
OF << "STARTED " << i << " " << U.size() << "\n";
OF.flush(); // Flush is important since Command::Execute may crash.
// Run.
TPC.ResetMaps();
ExecuteCallback(U.data(), U.size());
// Collect coverage. We are iterating over the files in this order:
// * First, files in the initial corpus ordered by size, smallest first.
// * Then, all other files, smallest first.
std::set<size_t> Features;
if (IsSetCoverMerge)
TPC.CollectFeatures([&](size_t Feature) { Features.insert(Feature); });
else
TPC.CollectFeatures([&](size_t Feature) {
if (AllFeatures.insert(Feature).second)
Features.insert(Feature);
});
TPC.UpdateObservedPCs();
// Show stats.
if (!(TotalNumberOfRuns & (TotalNumberOfRuns - 1)))
PrintStatsWrapper("pulse ");
if (TotalNumberOfRuns == M.NumFilesInFirstCorpus)
PrintStatsWrapper("LOADED");
// Write the post-run marker and the coverage.
OF << "FT " << i;
for (size_t F : Features)
OF << " " << F;
OF << "\n";
OF << "COV " << i;
TPC.ForEachObservedPC([&](const TracePC::PCTableEntry *TE) {
if (AllPCs.insert(TE).second)
OF << " " << TPC.PCTableEntryIdx(TE);
});
OF << "\n";
OF.flush();
}
PrintStatsWrapper("DONE ");
}
// Merges all corpora into the first corpus. A file is added into
// the first corpus only if it adds new features. Unlike `Merger::Merge`,
// this implementation calculates an approximation of the minimum set
// of corpora files, that cover all known features (set cover problem).
// Generally, this means that files with more features are preferred for
// merge into the first corpus. When two files have the same number of
// features, the smaller one is preferred.
size_t Merger::SetCoverMerge(const std::set<uint32_t> &InitialFeatures,
std::set<uint32_t> *NewFeatures,
const std::set<uint32_t> &InitialCov,
std::set<uint32_t> *NewCov,
std::vector<std::string> *NewFiles) {
assert(NumFilesInFirstCorpus <= Files.size());
NewFiles->clear();
NewFeatures->clear();
NewCov->clear();
std::set<uint32_t> AllFeatures;
// 1 << 21 - 1 is the maximum feature index.
// See 'kFeatureSetSize' in 'FuzzerCorpus.h'.
const uint32_t kFeatureSetSize = 1 << 21;
std::vector<bool> Covered(kFeatureSetSize, false);
size_t NumCovered = 0;
std::set<uint32_t> ExistingFeatures = InitialFeatures;
for (size_t i = 0; i < NumFilesInFirstCorpus; ++i)
ExistingFeatures.insert(Files[i].Features.begin(), Files[i].Features.end());
// Mark the existing features as covered.
for (const auto &F : ExistingFeatures) {
if (!Covered[F % kFeatureSetSize]) {
++NumCovered;
Covered[F % kFeatureSetSize] = true;
}
// Calculate an underestimation of the set of covered features
// since the `Covered` bitvector is smaller than the feature range.
AllFeatures.insert(F % kFeatureSetSize);
}
std::set<size_t> RemainingFiles;
for (size_t i = NumFilesInFirstCorpus; i < Files.size(); ++i) {
// Construct an incremental sequence which represent the
// indices to all files (excluding those in the initial corpus).
// RemainingFiles = range(NumFilesInFirstCorpus..Files.size()).
RemainingFiles.insert(i);
// Insert this file's unique features to all features.
for (const auto &F : Files[i].Features)
AllFeatures.insert(F % kFeatureSetSize);
}
// Integrate files into Covered until set is complete.
while (NumCovered != AllFeatures.size()) {
// Index to file with largest number of unique features.
size_t MaxFeaturesIndex = NumFilesInFirstCorpus;
// Indices to remove from RemainingFiles.
std::set<size_t> RemoveIndices;
// Running max unique feature count.
// Updated upon finding a file with more features.
size_t MaxNumFeatures = 0;
// Iterate over all files not yet integrated into Covered,
// to find the file which has the largest number of
// features that are not already in Covered.
for (const auto &i : RemainingFiles) {
const auto &File = Files[i];
size_t CurrentUnique = 0;
// Count number of features in this file
// which are not yet in Covered.
for (const auto &F : File.Features)
if (!Covered[F % kFeatureSetSize])
++CurrentUnique;
if (CurrentUnique == 0) {
// All features in this file are already in Covered: skip next time.
RemoveIndices.insert(i);
} else if (CurrentUnique > MaxNumFeatures ||
(CurrentUnique == MaxNumFeatures &&
File.Size < Files[MaxFeaturesIndex].Size)) {
// Update the max features file based on unique features
// Break ties by selecting smaller files.
MaxNumFeatures = CurrentUnique;
MaxFeaturesIndex = i;
}
}
// Must be a valid index/
assert(MaxFeaturesIndex < Files.size());
// Remove any feature-less files found.
for (const auto &i : RemoveIndices)
RemainingFiles.erase(i);
if (MaxNumFeatures == 0) {
// Did not find a file that adds unique features.
// This means that we should have no remaining files.
assert(RemainingFiles.size() == 0);
assert(NumCovered == AllFeatures.size());
break;
}
// MaxFeaturesIndex must be an element of Remaining.
assert(RemainingFiles.find(MaxFeaturesIndex) != RemainingFiles.end());
// Remove the file with the most features from Remaining.
RemainingFiles.erase(MaxFeaturesIndex);
const auto &MaxFeatureFile = Files[MaxFeaturesIndex];
// Add the features of the max feature file to Covered.
for (const auto &F : MaxFeatureFile.Features) {
if (!Covered[F % kFeatureSetSize]) {
++NumCovered;
Covered[F % kFeatureSetSize] = true;
NewFeatures->insert(F);
}
}
// Add the index to this file to the result.
NewFiles->push_back(MaxFeatureFile.Name);
// Update NewCov with the additional coverage
// that MaxFeatureFile provides.
for (const auto &C : MaxFeatureFile.Cov)
if (InitialCov.find(C) == InitialCov.end())
NewCov->insert(C);
}
return NewFeatures->size();
}
static size_t
WriteNewControlFile(const std::string &CFPath,
const std::vector<SizedFile> &OldCorpus,
const std::vector<SizedFile> &NewCorpus,
const std::vector<MergeFileInfo> &KnownFiles) {
std::unordered_set<std::string> FilesToSkip;
for (auto &SF: KnownFiles)
FilesToSkip.insert(SF.Name);
std::vector<std::string> FilesToUse;
auto MaybeUseFile = [=, &FilesToUse](std::string Name) {
if (FilesToSkip.find(Name) == FilesToSkip.end())
FilesToUse.push_back(Name);
};
for (auto &SF: OldCorpus)
MaybeUseFile(SF.File);
auto FilesToUseFromOldCorpus = FilesToUse.size();
for (auto &SF: NewCorpus)
MaybeUseFile(SF.File);
RemoveFile(CFPath);
std::ofstream ControlFile(CFPath);
ControlFile << FilesToUse.size() << "\n";
ControlFile << FilesToUseFromOldCorpus << "\n";
for (auto &FN: FilesToUse)
ControlFile << FN << "\n";
if (!ControlFile) {
Printf("MERGE-OUTER: failed to write to the control file: %s\n",
CFPath.c_str());
exit(1);
}
return FilesToUse.size();
}
// Outer process. Does not call the target code and thus should not fail.
void CrashResistantMerge(const std::vector<std::string> &Args,
const std::vector<SizedFile> &OldCorpus,
const std::vector<SizedFile> &NewCorpus,
std::vector<std::string> *NewFiles,
const std::set<uint32_t> &InitialFeatures,
std::set<uint32_t> *NewFeatures,
const std::set<uint32_t> &InitialCov,
std::set<uint32_t> *NewCov, const std::string &CFPath,
bool V, /*Verbose*/
bool IsSetCoverMerge) {
if (NewCorpus.empty() && OldCorpus.empty()) return; // Nothing to merge.
size_t NumAttempts = 0;
std::vector<MergeFileInfo> KnownFiles;
if (FileSize(CFPath)) {
VPrintf(V, "MERGE-OUTER: non-empty control file provided: '%s'\n",
CFPath.c_str());
Merger M;
std::ifstream IF(CFPath);
if (M.Parse(IF, /*ParseCoverage=*/true)) {
VPrintf(V, "MERGE-OUTER: control file ok, %zd files total,"
" first not processed file %zd\n",
M.Files.size(), M.FirstNotProcessedFile);
if (!M.LastFailure.empty())
VPrintf(V, "MERGE-OUTER: '%s' will be skipped as unlucky "
"(merge has stumbled on it the last time)\n",
M.LastFailure.c_str());
if (M.FirstNotProcessedFile >= M.Files.size()) {
// Merge has already been completed with the given merge control file.
if (M.Files.size() == OldCorpus.size() + NewCorpus.size()) {
VPrintf(
V,
"MERGE-OUTER: nothing to do, merge has been completed before\n");
exit(0);
}
// Number of input files likely changed, start merge from scratch, but
// reuse coverage information from the given merge control file.
VPrintf(
V,
"MERGE-OUTER: starting merge from scratch, but reusing coverage "
"information from the given control file\n");
KnownFiles = M.Files;
} else {
// There is a merge in progress, continue.
NumAttempts = M.Files.size() - M.FirstNotProcessedFile;
}
} else {
VPrintf(V, "MERGE-OUTER: bad control file, will overwrite it\n");
}
}
if (!NumAttempts) {
// The supplied control file is empty or bad, create a fresh one.
VPrintf(V, "MERGE-OUTER: "
"%zd files, %zd in the initial corpus, %zd processed earlier\n",
OldCorpus.size() + NewCorpus.size(), OldCorpus.size(),
KnownFiles.size());
NumAttempts = WriteNewControlFile(CFPath, OldCorpus, NewCorpus, KnownFiles);
}
// Execute the inner process until it passes.
// Every inner process should execute at least one input.
Command BaseCmd(Args);
BaseCmd.removeFlag("merge");
BaseCmd.removeFlag("set_cover_merge");
BaseCmd.removeFlag("fork");
BaseCmd.removeFlag("collect_data_flow");
for (size_t Attempt = 1; Attempt <= NumAttempts; Attempt++) {
Fuzzer::MaybeExitGracefully();
VPrintf(V, "MERGE-OUTER: attempt %zd\n", Attempt);
Command Cmd(BaseCmd);
Cmd.addFlag("merge_control_file", CFPath);
// If we are going to use the set cover implementation for
// minimization add the merge_inner=2 internal flag.
Cmd.addFlag("merge_inner", IsSetCoverMerge ? "2" : "1");
if (!V) {
Cmd.setOutputFile(getDevNull());
Cmd.combineOutAndErr();
}
auto ExitCode = ExecuteCommand(Cmd);
if (!ExitCode) {
VPrintf(V, "MERGE-OUTER: successful in %zd attempt(s)\n", Attempt);
break;
}
}
// Read the control file and do the merge.
Merger M;
std::ifstream IF(CFPath);
IF.seekg(0, IF.end);
VPrintf(V, "MERGE-OUTER: the control file has %zd bytes\n",
(size_t)IF.tellg());
IF.seekg(0, IF.beg);
M.ParseOrExit(IF, true);
IF.close();
VPrintf(V,
"MERGE-OUTER: consumed %zdMb (%zdMb rss) to parse the control file\n",
M.ApproximateMemoryConsumption() >> 20, GetPeakRSSMb());
M.Files.insert(M.Files.end(), KnownFiles.begin(), KnownFiles.end());
if (IsSetCoverMerge)
M.SetCoverMerge(InitialFeatures, NewFeatures, InitialCov, NewCov, NewFiles);
else
M.Merge(InitialFeatures, NewFeatures, InitialCov, NewCov, NewFiles);
VPrintf(V, "MERGE-OUTER: %zd new files with %zd new features added; "
"%zd new coverage edges\n",
NewFiles->size(), NewFeatures->size(), NewCov->size());
}
} // namespace fuzzer