// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). // // Copyright 2014 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. // This test uses a custom FileSystem to keep track of the state of a file // system the last "Sync". The data being written is cached in a "buffer". // Only when "Sync" is called, the data will be persistent. It can simulate // file data loss (or entire files) not protected by a "Sync". For any of the // FileSystem related operations, by specify the "IOStatus Error", a specific // error can be returned when file system is not activated. #include "utilities/fault_injection_fs.h" #include #include #include #include "env/composite_env_wrapper.h" #include "port/lang.h" #include "port/stack_trace.h" #include "test_util/sync_point.h" #include "util/coding.h" #include "util/crc32c.h" #include "util/mutexlock.h" #include "util/random.h" #include "util/string_util.h" #include "util/xxhash.h" namespace ROCKSDB_NAMESPACE { const std::string kNewFileNoOverwrite = ""; // Assume a filename, and not a directory name like "/foo/bar/" std::string TestFSGetDirName(const std::string filename) { size_t found = filename.find_last_of("/\\"); if (found == std::string::npos) { return ""; } else { return filename.substr(0, found); } } // Trim the tailing "/" in the end of `str` std::string TestFSTrimDirname(const std::string& str) { size_t found = str.find_last_not_of("/"); if (found == std::string::npos) { return str; } return str.substr(0, found + 1); } // Return pair of a full path. std::pair TestFSGetDirAndName( const std::string& name) { std::string dirname = TestFSGetDirName(name); std::string fname = name.substr(dirname.size() + 1); return std::make_pair(dirname, fname); } // Calculate the checksum of the data with corresponding checksum // type. If name does not match, no checksum is returned. void CalculateTypedChecksum(const ChecksumType& checksum_type, const char* data, size_t size, std::string* checksum) { if (checksum_type == ChecksumType::kCRC32c) { uint32_t v_crc32c = crc32c::Extend(0, data, size); PutFixed32(checksum, v_crc32c); return; } else if (checksum_type == ChecksumType::kxxHash) { uint32_t v = XXH32(data, size, 0); PutFixed32(checksum, v); } return; } IOStatus FSFileState::DropUnsyncedData() { buffer_.resize(0); return IOStatus::OK(); } IOStatus FSFileState::DropRandomUnsyncedData(Random* rand) { int range = static_cast(buffer_.size()); size_t truncated_size = static_cast(rand->Uniform(range)); buffer_.resize(truncated_size); return IOStatus::OK(); } IOStatus TestFSDirectory::Fsync(const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } fs_->SyncDir(dirname_); IOStatus s = dir_->Fsync(options, dbg); { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } return s; } IOStatus TestFSDirectory::Close(const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } IOStatus s = dir_->Close(options, dbg); return s; } IOStatus TestFSDirectory::FsyncWithDirOptions( const IOOptions& options, IODebugContext* dbg, const DirFsyncOptions& dir_fsync_options) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } fs_->SyncDir(dirname_); IOStatus s = dir_->FsyncWithDirOptions(options, dbg, dir_fsync_options); { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } return s; } TestFSWritableFile::TestFSWritableFile(const std::string& fname, const FileOptions& file_opts, std::unique_ptr&& f, FaultInjectionTestFS* fs) : state_(fname), file_opts_(file_opts), target_(std::move(f)), writable_file_opened_(true), fs_(fs) { assert(target_ != nullptr); state_.pos_ = 0; } TestFSWritableFile::~TestFSWritableFile() { if (writable_file_opened_) { Close(IOOptions(), nullptr).PermitUncheckedError(); } } IOStatus TestFSWritableFile::Append(const Slice& data, const IOOptions& options, IODebugContext* dbg) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } if (target_->use_direct_io()) { target_->Append(data, options, dbg).PermitUncheckedError(); } else { state_.buffer_.append(data.data(), data.size()); state_.pos_ += data.size(); fs_->WritableFileAppended(state_); } IOStatus io_s = fs_->InjectWriteError(state_.filename_); return io_s; } // By setting the IngestDataCorruptionBeforeWrite(), the data corruption is // simulated. IOStatus TestFSWritableFile::Append( const Slice& data, const IOOptions& options, const DataVerificationInfo& verification_info, IODebugContext* dbg) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } if (fs_->ShouldDataCorruptionBeforeWrite()) { return IOStatus::Corruption("Data is corrupted!"); } // Calculate the checksum std::string checksum; CalculateTypedChecksum(fs_->GetChecksumHandoffFuncType(), data.data(), data.size(), &checksum); if (fs_->GetChecksumHandoffFuncType() != ChecksumType::kNoChecksum && checksum != verification_info.checksum.ToString()) { std::string msg = "Data is corrupted! Origin data checksum: " + verification_info.checksum.ToString() + "current data checksum: " + checksum; return IOStatus::Corruption(msg); } if (target_->use_direct_io()) { target_->Append(data, options, dbg).PermitUncheckedError(); } else { state_.buffer_.append(data.data(), data.size()); state_.pos_ += data.size(); fs_->WritableFileAppended(state_); } IOStatus io_s = fs_->InjectWriteError(state_.filename_); return io_s; } IOStatus TestFSWritableFile::PositionedAppend( const Slice& data, uint64_t offset, const IOOptions& options, const DataVerificationInfo& verification_info, IODebugContext* dbg) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } if (fs_->ShouldDataCorruptionBeforeWrite()) { return IOStatus::Corruption("Data is corrupted!"); } // Calculate the checksum std::string checksum; CalculateTypedChecksum(fs_->GetChecksumHandoffFuncType(), data.data(), data.size(), &checksum); if (fs_->GetChecksumHandoffFuncType() != ChecksumType::kNoChecksum && checksum != verification_info.checksum.ToString()) { std::string msg = "Data is corrupted! Origin data checksum: " + verification_info.checksum.ToString() + "current data checksum: " + checksum; return IOStatus::Corruption(msg); } target_->PositionedAppend(data, offset, options, dbg); IOStatus io_s = fs_->InjectWriteError(state_.filename_); return io_s; } IOStatus TestFSWritableFile::Close(const IOOptions& options, IODebugContext* dbg) { MutexLock l(&mutex_); fs_->WritableFileClosed(state_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } writable_file_opened_ = false; IOStatus io_s; if (!target_->use_direct_io()) { io_s = target_->Append(state_.buffer_, options, dbg); } if (io_s.ok()) { state_.buffer_.resize(0); // Ignore sync errors target_->Sync(options, dbg).PermitUncheckedError(); io_s = target_->Close(options, dbg); } if (io_s.ok()) { IOStatus in_s = fs_->InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } return io_s; } IOStatus TestFSWritableFile::Flush(const IOOptions&, IODebugContext*) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } if (fs_->IsFilesystemActive()) { state_.pos_at_last_flush_ = state_.pos_; } return IOStatus::OK(); } IOStatus TestFSWritableFile::Sync(const IOOptions& options, IODebugContext* dbg) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } if (target_->use_direct_io()) { // For Direct IO mode, we don't buffer anything in TestFSWritableFile. // So just return return IOStatus::OK(); } IOStatus io_s = target_->Append(state_.buffer_, options, dbg); state_.buffer_.resize(0); // Ignore sync errors target_->Sync(options, dbg).PermitUncheckedError(); state_.pos_at_last_sync_ = state_.pos_; fs_->WritableFileSynced(state_); return io_s; } IOStatus TestFSWritableFile::RangeSync(uint64_t offset, uint64_t nbytes, const IOOptions& options, IODebugContext* dbg) { MutexLock l(&mutex_); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } // Assumes caller passes consecutive byte ranges. uint64_t sync_limit = offset + nbytes; uint64_t buf_begin = state_.pos_at_last_sync_ < 0 ? 0 : state_.pos_at_last_sync_; IOStatus io_s; if (sync_limit < buf_begin) { return io_s; } uint64_t num_to_sync = std::min(static_cast(state_.buffer_.size()), sync_limit - buf_begin); Slice buf_to_sync(state_.buffer_.data(), num_to_sync); io_s = target_->Append(buf_to_sync, options, dbg); state_.buffer_ = state_.buffer_.substr(num_to_sync); // Ignore sync errors target_->RangeSync(offset, nbytes, options, dbg).PermitUncheckedError(); state_.pos_at_last_sync_ = offset + num_to_sync; fs_->WritableFileSynced(state_); return io_s; } TestFSRandomRWFile::TestFSRandomRWFile(const std::string& /*fname*/, std::unique_ptr&& f, FaultInjectionTestFS* fs) : target_(std::move(f)), file_opened_(true), fs_(fs) { assert(target_ != nullptr); } TestFSRandomRWFile::~TestFSRandomRWFile() { if (file_opened_) { Close(IOOptions(), nullptr).PermitUncheckedError(); } } IOStatus TestFSRandomRWFile::Write(uint64_t offset, const Slice& data, const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } return target_->Write(offset, data, options, dbg); } IOStatus TestFSRandomRWFile::Read(uint64_t offset, size_t n, const IOOptions& options, Slice* result, char* scratch, IODebugContext* dbg) const { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } return target_->Read(offset, n, options, result, scratch, dbg); } IOStatus TestFSRandomRWFile::Close(const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } file_opened_ = false; return target_->Close(options, dbg); } IOStatus TestFSRandomRWFile::Flush(const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } return target_->Flush(options, dbg); } IOStatus TestFSRandomRWFile::Sync(const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } return target_->Sync(options, dbg); } TestFSRandomAccessFile::TestFSRandomAccessFile( const std::string& /*fname*/, std::unique_ptr&& f, FaultInjectionTestFS* fs) : target_(std::move(f)), fs_(fs) { assert(target_ != nullptr); } IOStatus TestFSRandomAccessFile::Read(uint64_t offset, size_t n, const IOOptions& options, Slice* result, char* scratch, IODebugContext* dbg) const { TEST_SYNC_POINT("FaultInjectionTestFS::RandomRead"); if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } IOStatus s = target_->Read(offset, n, options, result, scratch, dbg); if (s.ok()) { s = fs_->InjectThreadSpecificReadError( FaultInjectionTestFS::ErrorOperation::kRead, result, use_direct_io(), scratch, /*need_count_increase=*/true, /*fault_injected=*/nullptr); } if (s.ok() && fs_->ShouldInjectRandomReadError()) { return IOStatus::IOError("injected read error"); } return s; } IOStatus TestFSRandomAccessFile::ReadAsync( FSReadRequest& req, const IOOptions& opts, std::function cb, void* cb_arg, void** io_handle, IOHandleDeleter* del_fn, IODebugContext* /*dbg*/) { IOStatus ret; IOStatus s; FSReadRequest res; if (!fs_->IsFilesystemActive()) { ret = fs_->GetError(); } else { ret = fs_->InjectThreadSpecificReadError( FaultInjectionTestFS::ErrorOperation::kRead, &res.result, use_direct_io(), req.scratch, /*need_count_increase=*/true, /*fault_injected=*/nullptr); } if (ret.ok()) { if (fs_->ShouldInjectRandomReadError()) { ret = IOStatus::IOError("injected read error"); } else { s = target_->ReadAsync(req, opts, cb, cb_arg, io_handle, del_fn, nullptr); } } if (!ret.ok()) { res.status = ret; cb(res, cb_arg); } return s; } IOStatus TestFSRandomAccessFile::MultiRead(FSReadRequest* reqs, size_t num_reqs, const IOOptions& options, IODebugContext* dbg) { if (!fs_->IsFilesystemActive()) { return fs_->GetError(); } IOStatus s = target_->MultiRead(reqs, num_reqs, options, dbg); bool injected_error = false; for (size_t i = 0; i < num_reqs; i++) { if (!reqs[i].status.ok()) { // Already seeing an error. break; } bool this_injected_error; reqs[i].status = fs_->InjectThreadSpecificReadError( FaultInjectionTestFS::ErrorOperation::kRead, &(reqs[i].result), use_direct_io(), reqs[i].scratch, /*need_count_increase=*/true, /*fault_injected=*/&this_injected_error); injected_error |= this_injected_error; } if (s.ok()) { s = fs_->InjectThreadSpecificReadError( FaultInjectionTestFS::ErrorOperation::kMultiRead, nullptr, use_direct_io(), nullptr, /*need_count_increase=*/!injected_error, /*fault_injected=*/nullptr); } if (s.ok() && fs_->ShouldInjectRandomReadError()) { return IOStatus::IOError("injected read error"); } return s; } size_t TestFSRandomAccessFile::GetUniqueId(char* id, size_t max_size) const { if (fs_->ShouldFailGetUniqueId()) { return 0; } else { return target_->GetUniqueId(id, max_size); } } IOStatus TestFSSequentialFile::Read(size_t n, const IOOptions& options, Slice* result, char* scratch, IODebugContext* dbg) { IOStatus s = target()->Read(n, options, result, scratch, dbg); if (s.ok() && fs_->ShouldInjectRandomReadError()) { return IOStatus::IOError("injected seq read error"); } return s; } IOStatus TestFSSequentialFile::PositionedRead(uint64_t offset, size_t n, const IOOptions& options, Slice* result, char* scratch, IODebugContext* dbg) { IOStatus s = target()->PositionedRead(offset, n, options, result, scratch, dbg); if (s.ok() && fs_->ShouldInjectRandomReadError()) { return IOStatus::IOError("injected seq positioned read error"); } return s; } IOStatus FaultInjectionTestFS::NewDirectory( const std::string& name, const IOOptions& options, std::unique_ptr* result, IODebugContext* dbg) { std::unique_ptr r; IOStatus io_s = target()->NewDirectory(name, options, &r, dbg); if (!io_s.ok()) { return io_s; } result->reset( new TestFSDirectory(this, TestFSTrimDirname(name), r.release())); return IOStatus::OK(); } IOStatus FaultInjectionTestFS::NewWritableFile( const std::string& fname, const FileOptions& file_opts, std::unique_ptr* result, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } if (ShouldUseDiretWritable(fname)) { return target()->NewWritableFile(fname, file_opts, result, dbg); } IOStatus io_s = target()->NewWritableFile(fname, file_opts, result, dbg); if (io_s.ok()) { result->reset( new TestFSWritableFile(fname, file_opts, std::move(*result), this)); // WritableFileWriter* file is opened // again then it will be truncated - so forget our saved state. UntrackFile(fname); { MutexLock l(&mutex_); open_managed_files_.insert(fname); auto dir_and_name = TestFSGetDirAndName(fname); auto& list = dir_to_new_files_since_last_sync_[dir_and_name.first]; // The new file could overwrite an old one. Here we simplify // the implementation by assuming no file of this name after // dropping unsynced files. list[dir_and_name.second] = kNewFileNoOverwrite; } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } } return io_s; } IOStatus FaultInjectionTestFS::ReopenWritableFile( const std::string& fname, const FileOptions& file_opts, std::unique_ptr* result, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } if (ShouldUseDiretWritable(fname)) { return target()->ReopenWritableFile(fname, file_opts, result, dbg); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } bool exists; IOStatus io_s, exists_s = target()->FileExists(fname, IOOptions(), nullptr /* dbg */); if (exists_s.IsNotFound()) { exists = false; } else if (exists_s.ok()) { exists = true; } else { io_s = exists_s; exists = false; } if (io_s.ok()) { io_s = target()->ReopenWritableFile(fname, file_opts, result, dbg); } // Only track files we created. Files created outside of this // `FaultInjectionTestFS` are not eligible for tracking/data dropping // (for example, they may contain data a previous db_stress run expects to // be recovered). This could be extended to track/drop data appended once // the file is under `FaultInjectionTestFS`'s control. if (io_s.ok()) { bool should_track; { MutexLock l(&mutex_); if (db_file_state_.find(fname) != db_file_state_.end()) { // It was written by this `FileSystem` earlier. assert(exists); should_track = true; } else if (!exists) { // It was created by this `FileSystem` just now. should_track = true; open_managed_files_.insert(fname); auto dir_and_name = TestFSGetDirAndName(fname); auto& list = dir_to_new_files_since_last_sync_[dir_and_name.first]; list[dir_and_name.second] = kNewFileNoOverwrite; } else { should_track = false; } } if (should_track) { result->reset( new TestFSWritableFile(fname, file_opts, std::move(*result), this)); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } } return io_s; } IOStatus FaultInjectionTestFS::NewRandomRWFile( const std::string& fname, const FileOptions& file_opts, std::unique_ptr* result, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } if (ShouldUseDiretWritable(fname)) { return target()->NewRandomRWFile(fname, file_opts, result, dbg); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } IOStatus io_s = target()->NewRandomRWFile(fname, file_opts, result, dbg); if (io_s.ok()) { result->reset(new TestFSRandomRWFile(fname, std::move(*result), this)); // WritableFileWriter* file is opened // again then it will be truncated - so forget our saved state. UntrackFile(fname); { MutexLock l(&mutex_); open_managed_files_.insert(fname); auto dir_and_name = TestFSGetDirAndName(fname); auto& list = dir_to_new_files_since_last_sync_[dir_and_name.first]; // It could be overwriting an old file, but we simplify the // implementation by ignoring it. list[dir_and_name.second] = kNewFileNoOverwrite; } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } } return io_s; } IOStatus FaultInjectionTestFS::NewRandomAccessFile( const std::string& fname, const FileOptions& file_opts, std::unique_ptr* result, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } if (ShouldInjectRandomReadError()) { return IOStatus::IOError("injected error when open random access file"); } IOStatus io_s = InjectThreadSpecificReadError(ErrorOperation::kOpen, nullptr, false, nullptr, /*need_count_increase=*/true, /*fault_injected=*/nullptr); if (io_s.ok()) { io_s = target()->NewRandomAccessFile(fname, file_opts, result, dbg); } if (io_s.ok()) { result->reset(new TestFSRandomAccessFile(fname, std::move(*result), this)); } return io_s; } IOStatus FaultInjectionTestFS::NewSequentialFile( const std::string& fname, const FileOptions& file_opts, std::unique_ptr* result, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } if (ShouldInjectRandomReadError()) { return IOStatus::IOError("injected read error when creating seq file"); } IOStatus io_s = target()->NewSequentialFile(fname, file_opts, result, dbg); if (io_s.ok()) { result->reset(new TestFSSequentialFile(std::move(*result), this)); } return io_s; } IOStatus FaultInjectionTestFS::DeleteFile(const std::string& f, const IOOptions& options, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } IOStatus io_s = FileSystemWrapper::DeleteFile(f, options, dbg); if (io_s.ok()) { UntrackFile(f); { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } } return io_s; } IOStatus FaultInjectionTestFS::RenameFile(const std::string& s, const std::string& t, const IOOptions& options, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } // We preserve contents of overwritten files up to a size threshold. // We could keep previous file in another name, but we need to worry about // garbage collect the those files. We do it if it is needed later. // We ignore I/O errors here for simplicity. std::string previous_contents = kNewFileNoOverwrite; if (target()->FileExists(t, IOOptions(), nullptr).ok()) { uint64_t file_size; if (target()->GetFileSize(t, IOOptions(), &file_size, nullptr).ok() && file_size < 1024) { ReadFileToString(target(), t, &previous_contents).PermitUncheckedError(); } } IOStatus io_s = FileSystemWrapper::RenameFile(s, t, options, dbg); if (io_s.ok()) { { MutexLock l(&mutex_); if (db_file_state_.find(s) != db_file_state_.end()) { db_file_state_[t] = db_file_state_[s]; db_file_state_.erase(s); } auto sdn = TestFSGetDirAndName(s); auto tdn = TestFSGetDirAndName(t); if (dir_to_new_files_since_last_sync_[sdn.first].erase(sdn.second) != 0) { auto& tlist = dir_to_new_files_since_last_sync_[tdn.first]; assert(tlist.find(tdn.second) == tlist.end()); tlist[tdn.second] = previous_contents; } } IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } return io_s; } IOStatus FaultInjectionTestFS::LinkFile(const std::string& s, const std::string& t, const IOOptions& options, IODebugContext* dbg) { if (!IsFilesystemActive()) { return GetError(); } { IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } // Using the value in `dir_to_new_files_since_last_sync_` for the source file // may be a more reasonable choice. std::string previous_contents = kNewFileNoOverwrite; IOStatus io_s = FileSystemWrapper::LinkFile(s, t, options, dbg); if (io_s.ok()) { { MutexLock l(&mutex_); if (db_file_state_.find(s) != db_file_state_.end()) { db_file_state_[t] = db_file_state_[s]; } auto sdn = TestFSGetDirAndName(s); auto tdn = TestFSGetDirAndName(t); if (dir_to_new_files_since_last_sync_[sdn.first].find(sdn.second) != dir_to_new_files_since_last_sync_[sdn.first].end()) { auto& tlist = dir_to_new_files_since_last_sync_[tdn.first]; assert(tlist.find(tdn.second) == tlist.end()); tlist[tdn.second] = previous_contents; } } IOStatus in_s = InjectMetadataWriteError(); if (!in_s.ok()) { return in_s; } } return io_s; } IOStatus FaultInjectionTestFS::Poll(std::vector& io_handles, size_t min_completions) { return target()->Poll(io_handles, min_completions); } IOStatus FaultInjectionTestFS::AbortIO(std::vector& io_handles) { return target()->AbortIO(io_handles); } void FaultInjectionTestFS::WritableFileClosed(const FSFileState& state) { MutexLock l(&mutex_); if (open_managed_files_.find(state.filename_) != open_managed_files_.end()) { db_file_state_[state.filename_] = state; open_managed_files_.erase(state.filename_); } } void FaultInjectionTestFS::WritableFileSynced(const FSFileState& state) { MutexLock l(&mutex_); if (open_managed_files_.find(state.filename_) != open_managed_files_.end()) { if (db_file_state_.find(state.filename_) == db_file_state_.end()) { db_file_state_.insert(std::make_pair(state.filename_, state)); } else { db_file_state_[state.filename_] = state; } } } void FaultInjectionTestFS::WritableFileAppended(const FSFileState& state) { MutexLock l(&mutex_); if (open_managed_files_.find(state.filename_) != open_managed_files_.end()) { if (db_file_state_.find(state.filename_) == db_file_state_.end()) { db_file_state_.insert(std::make_pair(state.filename_, state)); } else { db_file_state_[state.filename_] = state; } } } IOStatus FaultInjectionTestFS::DropUnsyncedFileData() { IOStatus io_s; MutexLock l(&mutex_); for (std::map::iterator it = db_file_state_.begin(); io_s.ok() && it != db_file_state_.end(); ++it) { FSFileState& fs_state = it->second; if (!fs_state.IsFullySynced()) { io_s = fs_state.DropUnsyncedData(); } } return io_s; } IOStatus FaultInjectionTestFS::DropRandomUnsyncedFileData(Random* rnd) { IOStatus io_s; MutexLock l(&mutex_); for (std::map::iterator it = db_file_state_.begin(); io_s.ok() && it != db_file_state_.end(); ++it) { FSFileState& fs_state = it->second; if (!fs_state.IsFullySynced()) { io_s = fs_state.DropRandomUnsyncedData(rnd); } } return io_s; } IOStatus FaultInjectionTestFS::DeleteFilesCreatedAfterLastDirSync( const IOOptions& options, IODebugContext* dbg) { // Because DeleteFile access this container make a copy to avoid deadlock std::map> map_copy; { MutexLock l(&mutex_); map_copy.insert(dir_to_new_files_since_last_sync_.begin(), dir_to_new_files_since_last_sync_.end()); } for (auto& pair : map_copy) { for (auto& file_pair : pair.second) { if (file_pair.second == kNewFileNoOverwrite) { IOStatus io_s = DeleteFile(pair.first + "/" + file_pair.first, options, dbg); if (!io_s.ok()) { return io_s; } } else { IOOptions opts; IOStatus io_s = WriteStringToFile(target(), file_pair.second, pair.first + "/" + file_pair.first, true, opts); if (!io_s.ok()) { return io_s; } } } } return IOStatus::OK(); } void FaultInjectionTestFS::ResetState() { MutexLock l(&mutex_); db_file_state_.clear(); dir_to_new_files_since_last_sync_.clear(); SetFilesystemActiveNoLock(true); } void FaultInjectionTestFS::UntrackFile(const std::string& f) { MutexLock l(&mutex_); auto dir_and_name = TestFSGetDirAndName(f); dir_to_new_files_since_last_sync_[dir_and_name.first].erase( dir_and_name.second); db_file_state_.erase(f); open_managed_files_.erase(f); } IOStatus FaultInjectionTestFS::InjectThreadSpecificReadError( ErrorOperation op, Slice* result, bool direct_io, char* scratch, bool need_count_increase, bool* fault_injected) { bool dummy_bool; bool& ret_fault_injected = fault_injected ? *fault_injected : dummy_bool; ret_fault_injected = false; ErrorContext* ctx = static_cast(thread_local_error_->Get()); if (ctx == nullptr || !ctx->enable_error_injection || !ctx->one_in) { return IOStatus::OK(); } IOStatus ret; if (ctx->rand.OneIn(ctx->one_in)) { if (ctx->count == 0) { ctx->message = ""; } if (need_count_increase) { ctx->count++; } if (ctx->callstack) { free(ctx->callstack); } ctx->callstack = port::SaveStack(&ctx->frames); if (op != ErrorOperation::kMultiReadSingleReq) { // Likely non-per read status code for MultiRead ctx->message += "injected read error; "; ret_fault_injected = true; ret = IOStatus::IOError(ctx->message); } else if (Random::GetTLSInstance()->OneIn(8)) { assert(result); // For a small chance, set the failure to status but turn the // result to be empty, which is supposed to be caught for a check. *result = Slice(); ctx->message += "injected empty result; "; ret_fault_injected = true; } else if (!direct_io && Random::GetTLSInstance()->OneIn(7) && scratch != nullptr && result->data() == scratch) { assert(result); // With direct I/O, many extra bytes might be read so corrupting // one byte might not cause checksum mismatch. Skip checksum // corruption injection. // We only corrupt data if the result is filled to `scratch`. For other // cases, the data might not be able to be modified (e.g mmaped files) // or has unintended side effects. // For a small chance, set the failure to status but corrupt the // result in a way that checksum checking is supposed to fail. // Corrupt the last byte, which is supposed to be a checksum byte // It would work for CRC. Not 100% sure for xxhash and will adjust // if it is not the case. const_cast(result->data())[result->size() - 1]++; ctx->message += "injected corrupt last byte; "; ret_fault_injected = true; } else { ctx->message += "injected error result multiget single; "; ret_fault_injected = true; ret = IOStatus::IOError(ctx->message); } } if (ctx->retryable) { ret.SetRetryable(true); } return ret; } bool FaultInjectionTestFS::TryParseFileName(const std::string& file_name, uint64_t* number, FileType* type) { std::size_t found = file_name.find_last_of("/"); std::string file = file_name.substr(found); return ParseFileName(file, number, type); } IOStatus FaultInjectionTestFS::InjectWriteError(const std::string& file_name) { MutexLock l(&mutex_); if (!enable_write_error_injection_ || !write_error_one_in_) { return IOStatus::OK(); } bool allowed_type = false; if (inject_for_all_file_types_) { allowed_type = true; } else { uint64_t number; FileType cur_type = kTempFile; if (TryParseFileName(file_name, &number, &cur_type)) { for (const auto& type : write_error_allowed_types_) { if (cur_type == type) { allowed_type = true; } } } } if (allowed_type) { if (write_error_rand_.OneIn(write_error_one_in_)) { return GetError(); } } return IOStatus::OK(); } IOStatus FaultInjectionTestFS::InjectMetadataWriteError() { { MutexLock l(&mutex_); if (!enable_metadata_write_error_injection_ || !metadata_write_error_one_in_ || !write_error_rand_.OneIn(metadata_write_error_one_in_)) { return IOStatus::OK(); } } TEST_SYNC_POINT("FaultInjectionTestFS::InjectMetadataWriteError:Injected"); return IOStatus::IOError("injected metadata write error"); } void FaultInjectionTestFS::PrintFaultBacktrace() { #if defined(OS_LINUX) ErrorContext* ctx = static_cast(thread_local_error_->Get()); if (ctx == nullptr) { return; } fprintf(stderr, "Injected error type = %d\n", ctx->type); fprintf(stderr, "Message: %s\n", ctx->message.c_str()); port::PrintAndFreeStack(ctx->callstack, ctx->frames); ctx->callstack = nullptr; #endif } } // namespace ROCKSDB_NAMESPACE