// Copyright (c) 2013, 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. // // Copyright (c) 2011 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. #ifndef ROCKSDB_LITE #include "rocksdb/utilities/backupable_db.h" #include "db/filename.h" #include "util/channel.h" #include "util/coding.h" #include "util/crc32c.h" #include "util/file_reader_writer.h" #include "util/logging.h" #include "util/string_util.h" #include "rocksdb/transaction_log.h" #ifndef __STDC_FORMAT_MACROS #define __STDC_FORMAT_MACROS #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include "port/port.h" namespace rocksdb { class BackupRateLimiter { public: BackupRateLimiter(Env* env, uint64_t max_bytes_per_second, uint64_t bytes_per_check) : env_(env), max_bytes_per_second_(max_bytes_per_second), bytes_per_check_(bytes_per_check), micros_start_time_(env->NowMicros()), bytes_since_start_(0) {} void ReportAndWait(uint64_t bytes_since_last_call) { bytes_since_start_ += bytes_since_last_call; if (bytes_since_start_ < bytes_per_check_) { // not enough bytes to be rate-limited return; } uint64_t now = env_->NowMicros(); uint64_t interval = now - micros_start_time_; uint64_t should_take_micros = (bytes_since_start_ * kMicrosInSecond) / max_bytes_per_second_; if (should_take_micros > interval) { env_->SleepForMicroseconds( static_cast(should_take_micros - interval)); now = env_->NowMicros(); } // reset interval micros_start_time_ = now; bytes_since_start_ = 0; } private: Env* env_; uint64_t max_bytes_per_second_; uint64_t bytes_per_check_; uint64_t micros_start_time_; uint64_t bytes_since_start_; static const uint64_t kMicrosInSecond = 1000 * 1000LL; }; void BackupStatistics::IncrementNumberSuccessBackup() { number_success_backup++; } void BackupStatistics::IncrementNumberFailBackup() { number_fail_backup++; } uint32_t BackupStatistics::GetNumberSuccessBackup() const { return number_success_backup; } uint32_t BackupStatistics::GetNumberFailBackup() const { return number_fail_backup; } std::string BackupStatistics::ToString() const { char result[50]; snprintf(result, sizeof(result), "# success backup: %u, # fail backup: %u", GetNumberSuccessBackup(), GetNumberFailBackup()); return result; } void BackupableDBOptions::Dump(Logger* logger) const { Log(logger, " Options.backup_dir: %s", backup_dir.c_str()); Log(logger, " Options.backup_env: %p", backup_env); Log(logger, " Options.share_table_files: %d", static_cast(share_table_files)); Log(logger, " Options.info_log: %p", info_log); Log(logger, " Options.sync: %d", static_cast(sync)); Log(logger, " Options.destroy_old_data: %d", static_cast(destroy_old_data)); Log(logger, " Options.backup_log_files: %d", static_cast(backup_log_files)); Log(logger, " Options.backup_rate_limit: %" PRIu64, backup_rate_limit); Log(logger, " Options.restore_rate_limit: %" PRIu64, restore_rate_limit); Log(logger, "Options.max_background_operations: %d", max_background_operations); } // -------- BackupEngineImpl class --------- class BackupEngineImpl : public BackupEngine { public: BackupEngineImpl(Env* db_env, const BackupableDBOptions& options, bool read_only = false); ~BackupEngineImpl(); Status CreateNewBackup(DB* db, bool flush_before_backup = false) override; Status PurgeOldBackups(uint32_t num_backups_to_keep) override; Status DeleteBackup(BackupID backup_id) override; void StopBackup() override { stop_backup_.store(true, std::memory_order_release); } Status GarbageCollect() override; void GetBackupInfo(std::vector* backup_info) override; void GetCorruptedBackups(std::vector* corrupt_backup_ids) override; Status RestoreDBFromBackup( BackupID backup_id, const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options = RestoreOptions()) override; Status RestoreDBFromLatestBackup( const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options = RestoreOptions()) override { return RestoreDBFromBackup(latest_backup_id_, db_dir, wal_dir, restore_options); } Status Initialize(); private: void DeleteChildren(const std::string& dir, uint32_t file_type_filter = 0); struct FileInfo { FileInfo(const std::string& fname, uint64_t sz, uint32_t checksum) : refs(0), filename(fname), size(sz), checksum_value(checksum) {} FileInfo(const FileInfo&) = delete; FileInfo& operator=(const FileInfo&) = delete; int refs; const std::string filename; const uint64_t size; const uint32_t checksum_value; }; class BackupMeta { public: BackupMeta(const std::string& meta_filename, std::unordered_map>* file_infos, Env* env) : timestamp_(0), size_(0), meta_filename_(meta_filename), file_infos_(file_infos), env_(env) {} BackupMeta(const BackupMeta&) = delete; BackupMeta& operator=(const BackupMeta&) = delete; ~BackupMeta() {} void RecordTimestamp() { env_->GetCurrentTime(×tamp_); } int64_t GetTimestamp() const { return timestamp_; } uint64_t GetSize() const { return size_; } uint32_t GetNumberFiles() { return static_cast(files_.size()); } void SetSequenceNumber(uint64_t sequence_number) { sequence_number_ = sequence_number; } uint64_t GetSequenceNumber() { return sequence_number_; } Status AddFile(std::shared_ptr file_info); Status Delete(bool delete_meta = true); bool Empty() { return files_.empty(); } std::shared_ptr GetFile(const std::string& filename) const { auto it = file_infos_->find(filename); if (it == file_infos_->end()) return nullptr; return it->second; } const std::vector>& GetFiles() { return files_; } Status LoadFromFile(const std::string& backup_dir); Status StoreToFile(bool sync); std::string GetInfoString() { std::ostringstream ss; ss << "Timestamp: " << timestamp_ << std::endl; char human_size[16]; AppendHumanBytes(size_, human_size, sizeof(human_size)); ss << "Size: " << human_size << std::endl; ss << "Files:" << std::endl; for (const auto& file : files_) { AppendHumanBytes(file->size, human_size, sizeof(human_size)); ss << file->filename << ", size " << human_size << ", refs " << file->refs << std::endl; } return ss.str(); } private: int64_t timestamp_; // sequence number is only approximate, should not be used // by clients uint64_t sequence_number_; uint64_t size_; std::string const meta_filename_; // files with relative paths (without "/" prefix!!) std::vector> files_; std::unordered_map>* file_infos_; Env* env_; static const size_t max_backup_meta_file_size_ = 10 * 1024 * 1024; // 10MB }; // BackupMeta inline std::string GetAbsolutePath( const std::string &relative_path = "") const { assert(relative_path.size() == 0 || relative_path[0] != '/'); return options_.backup_dir + "/" + relative_path; } inline std::string GetPrivateDirRel() const { return "private"; } inline std::string GetSharedChecksumDirRel() const { return "shared_checksum"; } inline std::string GetPrivateFileRel(BackupID backup_id, bool tmp = false, const std::string& file = "") const { assert(file.size() == 0 || file[0] != '/'); return GetPrivateDirRel() + "/" + rocksdb::ToString(backup_id) + (tmp ? ".tmp" : "") + "/" + file; } inline std::string GetSharedFileRel(const std::string& file = "", bool tmp = false) const { assert(file.size() == 0 || file[0] != '/'); return "shared/" + file + (tmp ? ".tmp" : ""); } inline std::string GetSharedFileWithChecksumRel(const std::string& file = "", bool tmp = false) const { assert(file.size() == 0 || file[0] != '/'); return GetSharedChecksumDirRel() + "/" + file + (tmp ? ".tmp" : ""); } inline std::string GetSharedFileWithChecksum(const std::string& file, const uint32_t checksum_value, const uint64_t file_size) const { assert(file.size() == 0 || file[0] != '/'); std::string file_copy = file; return file_copy.insert(file_copy.find_last_of('.'), "_" + rocksdb::ToString(checksum_value) + "_" + rocksdb::ToString(file_size)); } inline std::string GetFileFromChecksumFile(const std::string& file) const { assert(file.size() == 0 || file[0] != '/'); std::string file_copy = file; size_t first_underscore = file_copy.find_first_of('_'); return file_copy.erase(first_underscore, file_copy.find_last_of('.') - first_underscore); } inline std::string GetLatestBackupFile(bool tmp = false) const { return GetAbsolutePath(std::string("LATEST_BACKUP") + (tmp ? ".tmp" : "")); } inline std::string GetBackupMetaDir() const { return GetAbsolutePath("meta"); } inline std::string GetBackupMetaFile(BackupID backup_id) const { return GetBackupMetaDir() + "/" + rocksdb::ToString(backup_id); } Status GetLatestBackupFileContents(uint32_t* latest_backup); Status PutLatestBackupFileContents(uint32_t latest_backup); // if size_limit == 0, there is no size limit, copy everything Status CopyFile(const std::string& src, const std::string& dst, Env* src_env, Env* dst_env, bool sync, BackupRateLimiter* rate_limiter, uint64_t* size = nullptr, uint32_t* checksum_value = nullptr, uint64_t size_limit = 0); Status CalculateChecksum(const std::string& src, Env* src_env, uint64_t size_limit, uint32_t* checksum_value); struct CopyResult { uint64_t size; uint32_t checksum_value; Status status; }; struct CopyWorkItem { std::string src_path; std::string dst_path; Env* src_env; Env* dst_env; bool sync; BackupRateLimiter* rate_limiter; uint64_t size_limit; std::promise result; CopyWorkItem() {} CopyWorkItem(const CopyWorkItem&) = delete; CopyWorkItem& operator=(const CopyWorkItem&) = delete; CopyWorkItem(CopyWorkItem&& o) { *this = std::move(o); } CopyWorkItem& operator=(CopyWorkItem&& o) { src_path = std::move(o.src_path); dst_path = std::move(o.dst_path); src_env = o.src_env; dst_env = o.dst_env; sync = o.sync; rate_limiter = o.rate_limiter; size_limit = o.size_limit; result = std::move(o.result); return *this; } CopyWorkItem(std::string _src_path, std::string _dst_path, Env* _src_env, Env* _dst_env, bool _sync, BackupRateLimiter* _rate_limiter, uint64_t _size_limit) : src_path(std::move(_src_path)), dst_path(std::move(_dst_path)), src_env(_src_env), dst_env(_dst_env), sync(_sync), rate_limiter(_rate_limiter), size_limit(_size_limit) {} }; struct BackupAfterCopyWorkItem { std::future result; bool shared; bool needed_to_copy; Env* backup_env; std::string dst_path_tmp; std::string dst_path; std::string dst_relative; BackupAfterCopyWorkItem() {} BackupAfterCopyWorkItem(BackupAfterCopyWorkItem&& o) { *this = std::move(o); } BackupAfterCopyWorkItem& operator=(BackupAfterCopyWorkItem&& o) { result = std::move(o.result); shared = o.shared; needed_to_copy = o.needed_to_copy; backup_env = o.backup_env; dst_path_tmp = std::move(o.dst_path_tmp); dst_path = std::move(o.dst_path); dst_relative = std::move(o.dst_relative); return *this; } BackupAfterCopyWorkItem(std::future&& _result, bool _shared, bool _needed_to_copy, Env* _backup_env, std::string _dst_path_tmp, std::string _dst_path, std::string _dst_relative) : result(std::move(_result)), shared(_shared), needed_to_copy(_needed_to_copy), backup_env(_backup_env), dst_path_tmp(std::move(_dst_path_tmp)), dst_path(std::move(_dst_path)), dst_relative(std::move(_dst_relative)) {} }; struct RestoreAfterCopyWorkItem { std::future result; uint32_t checksum_value; RestoreAfterCopyWorkItem() {} RestoreAfterCopyWorkItem(std::future&& _result, uint32_t _checksum_value) : result(std::move(_result)), checksum_value(_checksum_value) {} RestoreAfterCopyWorkItem(RestoreAfterCopyWorkItem&& o) { *this = std::move(o); } RestoreAfterCopyWorkItem& operator=(RestoreAfterCopyWorkItem&& o) { result = std::move(o.result); checksum_value = o.checksum_value; return *this; } }; bool initialized_; channel files_to_copy_; std::vector threads_; Status AddBackupFileWorkItem( std::unordered_set& live_dst_paths, std::vector& backup_items_to_finish, BackupID backup_id, bool shared, const std::string& src_dir, const std::string& src_fname, // starts with "/" BackupRateLimiter* rate_limiter, uint64_t size_limit = 0, bool shared_checksum = false); // backup state data BackupID latest_backup_id_; std::map> backups_; std::map>> corrupt_backups_; std::unordered_map> backuped_file_infos_; std::atomic stop_backup_; // options data BackupableDBOptions options_; Env* db_env_; Env* backup_env_; // directories unique_ptr backup_directory_; unique_ptr shared_directory_; unique_ptr meta_directory_; unique_ptr private_directory_; static const size_t kDefaultCopyFileBufferSize = 5 * 1024 * 1024LL; // 5MB size_t copy_file_buffer_size_; bool read_only_; BackupStatistics backup_statistics_; }; Status BackupEngine::Open(Env* env, const BackupableDBOptions& options, BackupEngine** backup_engine_ptr) { std::unique_ptr backup_engine( new BackupEngineImpl(env, options)); auto s = backup_engine->Initialize(); if (!s.ok()) { *backup_engine_ptr = nullptr; return s; } *backup_engine_ptr = backup_engine.release(); return Status::OK(); } BackupEngineImpl::BackupEngineImpl(Env* db_env, const BackupableDBOptions& options, bool read_only) : initialized_(false), stop_backup_(false), options_(options), db_env_(db_env), backup_env_(options.backup_env != nullptr ? options.backup_env : db_env_), copy_file_buffer_size_(kDefaultCopyFileBufferSize), read_only_(read_only) {} BackupEngineImpl::~BackupEngineImpl() { files_to_copy_.sendEof(); for (auto& t : threads_) { t.join(); } LogFlush(options_.info_log); } Status BackupEngineImpl::Initialize() { assert(!initialized_); initialized_ = true; if (read_only_) { Log(options_.info_log, "Starting read_only backup engine"); } options_.Dump(options_.info_log); if (!read_only_) { // gather the list of directories that we need to create std::vector*>> directories; directories.emplace_back(GetAbsolutePath(), &backup_directory_); if (options_.share_table_files) { if (options_.share_files_with_checksum) { directories.emplace_back( GetAbsolutePath(GetSharedFileWithChecksumRel()), &shared_directory_); } else { directories.emplace_back(GetAbsolutePath(GetSharedFileRel()), &shared_directory_); } } directories.emplace_back(GetAbsolutePath(GetPrivateDirRel()), &private_directory_); directories.emplace_back(GetBackupMetaDir(), &meta_directory_); // create all the dirs we need for (const auto& d : directories) { auto s = backup_env_->CreateDirIfMissing(d.first); if (s.ok()) { s = backup_env_->NewDirectory(d.first, d.second); } if (!s.ok()) { return s; } } } std::vector backup_meta_files; { auto s = backup_env_->GetChildren(GetBackupMetaDir(), &backup_meta_files); if (!s.ok()) { return s; } } // create backups_ structure for (auto& file : backup_meta_files) { if (file == "." || file == "..") { continue; } Log(options_.info_log, "Detected backup %s", file.c_str()); BackupID backup_id = 0; sscanf(file.c_str(), "%u", &backup_id); if (backup_id == 0 || file != rocksdb::ToString(backup_id)) { if (!read_only_) { // invalid file name, delete that auto s = backup_env_->DeleteFile(GetBackupMetaDir() + "/" + file); Log(options_.info_log, "Unrecognized meta file %s, deleting -- %s", file.c_str(), s.ToString().c_str()); } continue; } assert(backups_.find(backup_id) == backups_.end()); backups_.insert(std::move( std::make_pair(backup_id, unique_ptr(new BackupMeta( GetBackupMetaFile(backup_id), &backuped_file_infos_, backup_env_))))); } if (options_.destroy_old_data) { // Destroy old data assert(!read_only_); Log(options_.info_log, "Backup Engine started with destroy_old_data == true, deleting all " "backups"); auto s = PurgeOldBackups(0); if (s.ok()) { s = GarbageCollect(); } if (!s.ok()) { return s; } // start from beginning latest_backup_id_ = 0; } else { // Load data from storage // load the backups if any for (auto& backup : backups_) { Status s = backup.second->LoadFromFile(options_.backup_dir); if (!s.ok()) { Log(options_.info_log, "Backup %u corrupted -- %s", backup.first, s.ToString().c_str()); corrupt_backups_.insert(std::make_pair( backup.first, std::make_pair(s, std::move(backup.second)))); } else { Log(options_.info_log, "Loading backup %" PRIu32 " OK:\n%s", backup.first, backup.second->GetInfoString().c_str()); } } for (const auto& corrupt : corrupt_backups_) { backups_.erase(backups_.find(corrupt.first)); } Status s = GetLatestBackupFileContents(&latest_backup_id_); // If latest backup file is corrupted or non-existent // set latest backup as the biggest backup we have // or 0 if we have no backups if (!s.ok() || backups_.find(latest_backup_id_) == backups_.end()) { auto itr = backups_.end(); latest_backup_id_ = (itr == backups_.begin()) ? 0 : (--itr)->first; } } Log(options_.info_log, "Latest backup is %u", latest_backup_id_); // delete any backups that claim to be later than latest std::vector later_ids; for (auto itr = backups_.lower_bound(latest_backup_id_ + 1); itr != backups_.end(); itr++) { Log(options_.info_log, "Found backup claiming to be later than latest: %" PRIu32, itr->first); later_ids.push_back(itr->first); } for (auto id : later_ids) { Status s; if (!read_only_) { s = DeleteBackup(id); } else { auto backup = backups_.find(id); // We just found it couple of lines earlier! assert(backup != backups_.end()); s = backup->second->Delete(false); backups_.erase(backup); } if (!s.ok()) { Log(options_.info_log, "Failed deleting backup %" PRIu32 " -- %s", id, s.ToString().c_str()); } } if (!read_only_) { auto s = PutLatestBackupFileContents(latest_backup_id_); if (!s.ok()) { return s; } } // set up threads perform copies from files_to_copy_ in the background for (int t = 0; t < options_.max_background_operations; t++) { threads_.emplace_back([&]() { CopyWorkItem work_item; while (files_to_copy_.read(work_item)) { CopyResult result; result.status = CopyFile(work_item.src_path, work_item.dst_path, work_item.src_env, work_item.dst_env, work_item.sync, work_item.rate_limiter, &result.size, &result.checksum_value, work_item.size_limit); work_item.result.set_value(std::move(result)); } }); } Log(options_.info_log, "Initialized BackupEngine"); return Status::OK(); } Status BackupEngineImpl::CreateNewBackup(DB* db, bool flush_before_backup) { assert(initialized_); if (options_.max_background_operations > 1 && options_.backup_rate_limit != 0) { return Status::InvalidArgument( "Multi-threaded backups cannot use a backup_rate_limit"); } assert(!read_only_); Status s; std::vector live_files; VectorLogPtr live_wal_files; uint64_t manifest_file_size = 0; uint64_t sequence_number = db->GetLatestSequenceNumber(); s = db->DisableFileDeletions(); if (s.ok()) { // this will return live_files prefixed with "/" s = db->GetLiveFiles(live_files, &manifest_file_size, flush_before_backup); } // if we didn't flush before backup, we need to also get WAL files if (s.ok() && !flush_before_backup && options_.backup_log_files) { // returns file names prefixed with "/" s = db->GetSortedWalFiles(live_wal_files); } if (!s.ok()) { db->EnableFileDeletions(false); return s; } BackupID new_backup_id = latest_backup_id_ + 1; assert(backups_.find(new_backup_id) == backups_.end()); auto ret = backups_.insert(std::move( std::make_pair(new_backup_id, unique_ptr(new BackupMeta( GetBackupMetaFile(new_backup_id), &backuped_file_infos_, backup_env_))))); assert(ret.second == true); auto& new_backup = ret.first->second; new_backup->RecordTimestamp(); new_backup->SetSequenceNumber(sequence_number); auto start_backup = backup_env_-> NowMicros(); Log(options_.info_log, "Started the backup process -- creating backup %u", new_backup_id); // create temporary private dir s = backup_env_->CreateDir( GetAbsolutePath(GetPrivateFileRel(new_backup_id, true))); unique_ptr rate_limiter; if (options_.backup_rate_limit > 0) { copy_file_buffer_size_ = options_.backup_rate_limit / 10; rate_limiter.reset(new BackupRateLimiter(db_env_, options_.backup_rate_limit, copy_file_buffer_size_)); } // A set into which we will insert the dst_paths that are calculated for live // files and live WAL files. // This is used to check whether a live files shares a dst_path with another // live file. std::unordered_set live_dst_paths; live_dst_paths.reserve(live_files.size() + live_wal_files.size()); std::vector backup_items_to_finish; // Add a CopyWorkItem to the channel for each live file for (size_t i = 0; s.ok() && i < live_files.size(); ++i) { uint64_t number; FileType type; bool ok = ParseFileName(live_files[i], &number, &type); if (!ok) { assert(false); return Status::Corruption("Can't parse file name. This is very bad"); } // we should only get sst, manifest and current files here assert(type == kTableFile || type == kDescriptorFile || type == kCurrentFile); // rules: // * if it's kTableFile, then it's shared // * if it's kDescriptorFile, limit the size to manifest_file_size s = AddBackupFileWorkItem( live_dst_paths, backup_items_to_finish, new_backup_id, options_.share_table_files && type == kTableFile, db->GetName(), live_files[i], rate_limiter.get(), (type == kDescriptorFile) ? manifest_file_size : 0, options_.share_files_with_checksum && type == kTableFile); } // Add a CopyWorkItem to the channel for each WAL file for (size_t i = 0; s.ok() && i < live_wal_files.size(); ++i) { if (live_wal_files[i]->Type() == kAliveLogFile) { // we only care about live log files // copy the file into backup_dir/files// s = AddBackupFileWorkItem(live_dst_paths, backup_items_to_finish, new_backup_id, false, /* not shared */ db->GetOptions().wal_dir, live_wal_files[i]->PathName(), rate_limiter.get()); } } Status item_status; for (auto& item : backup_items_to_finish) { item.result.wait(); auto result = item.result.get(); item_status = result.status; if (item_status.ok() && item.shared && item.needed_to_copy) { item_status = item.backup_env->RenameFile(item.dst_path_tmp, item.dst_path); } if (item_status.ok()) { item_status = new_backup.get()->AddFile( std::make_shared(item.dst_relative, result.size, result.checksum_value)); } if (!item_status.ok()) { s = item_status; } } // we copied all the files, enable file deletions db->EnableFileDeletions(false); if (s.ok()) { // move tmp private backup to real backup folder Log(options_.info_log, "Moving tmp backup directory to the real one: %s -> %s\n", GetAbsolutePath(GetPrivateFileRel(new_backup_id, true)).c_str(), GetAbsolutePath(GetPrivateFileRel(new_backup_id, false)).c_str()); s = backup_env_->RenameFile( GetAbsolutePath(GetPrivateFileRel(new_backup_id, true)), // tmp GetAbsolutePath(GetPrivateFileRel(new_backup_id, false))); } auto backup_time = backup_env_->NowMicros() - start_backup; if (s.ok()) { // persist the backup metadata on the disk s = new_backup->StoreToFile(options_.sync); } if (s.ok()) { // install the newly created backup meta! (atomic) s = PutLatestBackupFileContents(new_backup_id); } if (s.ok() && options_.sync) { unique_ptr backup_private_directory; backup_env_->NewDirectory( GetAbsolutePath(GetPrivateFileRel(new_backup_id, false)), &backup_private_directory); if (backup_private_directory != nullptr) { backup_private_directory->Fsync(); } if (private_directory_ != nullptr) { private_directory_->Fsync(); } if (meta_directory_ != nullptr) { meta_directory_->Fsync(); } if (shared_directory_ != nullptr) { shared_directory_->Fsync(); } if (backup_directory_ != nullptr) { backup_directory_->Fsync(); } } if (s.ok()) { backup_statistics_.IncrementNumberSuccessBackup(); } if (!s.ok()) { backup_statistics_.IncrementNumberFailBackup(); // clean all the files we might have created Log(options_.info_log, "Backup failed -- %s", s.ToString().c_str()); Log(options_.info_log, "Backup Statistics %s\n", backup_statistics_.ToString().c_str()); // delete files that we might have already written DeleteBackup(new_backup_id); GarbageCollect(); return s; } // here we know that we succeeded and installed the new backup // in the LATEST_BACKUP file latest_backup_id_ = new_backup_id; Log(options_.info_log, "Backup DONE. All is good"); // backup_speed is in byte/second double backup_speed = new_backup->GetSize() / (1.048576 * backup_time); Log(options_.info_log, "Backup number of files: %u", new_backup->GetNumberFiles()); char human_size[16]; AppendHumanBytes(new_backup->GetSize(), human_size, sizeof(human_size)); Log(options_.info_log, "Backup size: %s", human_size); Log(options_.info_log, "Backup time: %" PRIu64 " microseconds", backup_time); Log(options_.info_log, "Backup speed: %.3f MB/s", backup_speed); Log(options_.info_log, "Backup Statistics %s", backup_statistics_.ToString().c_str()); return s; } Status BackupEngineImpl::PurgeOldBackups(uint32_t num_backups_to_keep) { assert(initialized_); assert(!read_only_); Log(options_.info_log, "Purging old backups, keeping %u", num_backups_to_keep); std::vector to_delete; auto itr = backups_.begin(); while ((backups_.size() - to_delete.size()) > num_backups_to_keep) { to_delete.push_back(itr->first); itr++; } for (auto backup_id : to_delete) { auto s = DeleteBackup(backup_id); if (!s.ok()) { return s; } } return Status::OK(); } Status BackupEngineImpl::DeleteBackup(BackupID backup_id) { assert(initialized_); assert(!read_only_); Log(options_.info_log, "Deleting backup %u", backup_id); auto backup = backups_.find(backup_id); if (backup != backups_.end()) { auto s = backup->second->Delete(); if (!s.ok()) { return s; } backups_.erase(backup); } else { auto corrupt = corrupt_backups_.find(backup_id); if (corrupt == corrupt_backups_.end()) { return Status::NotFound("Backup not found"); } auto s = corrupt->second.second->Delete(); if (!s.ok()) { return s; } corrupt_backups_.erase(corrupt); } std::vector to_delete; for (auto& itr : backuped_file_infos_) { if (itr.second->refs == 0) { Status s = backup_env_->DeleteFile(GetAbsolutePath(itr.first)); Log(options_.info_log, "Deleting %s -- %s", itr.first.c_str(), s.ToString().c_str()); to_delete.push_back(itr.first); } } for (auto& td : to_delete) { backuped_file_infos_.erase(td); } // take care of private dirs -- GarbageCollect() will take care of them // if they are not empty std::string private_dir = GetPrivateFileRel(backup_id); Status s = backup_env_->DeleteDir(GetAbsolutePath(private_dir)); Log(options_.info_log, "Deleting private dir %s -- %s", private_dir.c_str(), s.ToString().c_str()); return Status::OK(); } void BackupEngineImpl::GetBackupInfo(std::vector* backup_info) { assert(initialized_); backup_info->reserve(backups_.size()); for (auto& backup : backups_) { if (!backup.second->Empty()) { backup_info->push_back(BackupInfo( backup.first, backup.second->GetTimestamp(), backup.second->GetSize(), backup.second->GetNumberFiles())); } } } void BackupEngineImpl::GetCorruptedBackups( std::vector* corrupt_backup_ids) { assert(initialized_); corrupt_backup_ids->reserve(corrupt_backups_.size()); for (auto& backup : corrupt_backups_) { corrupt_backup_ids->push_back(backup.first); } } Status BackupEngineImpl::RestoreDBFromBackup( BackupID backup_id, const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options) { assert(initialized_); if (options_.max_background_operations > 1 && options_.restore_rate_limit != 0) { return Status::InvalidArgument( "Multi-threaded restores cannot use a restore_rate_limit"); } auto corrupt_itr = corrupt_backups_.find(backup_id); if (corrupt_itr != corrupt_backups_.end()) { return corrupt_itr->second.first; } auto backup_itr = backups_.find(backup_id); if (backup_itr == backups_.end()) { return Status::NotFound("Backup not found"); } auto& backup = backup_itr->second; if (backup->Empty()) { return Status::NotFound("Backup not found"); } Log(options_.info_log, "Restoring backup id %u\n", backup_id); Log(options_.info_log, "keep_log_files: %d\n", static_cast(restore_options.keep_log_files)); // just in case. Ignore errors db_env_->CreateDirIfMissing(db_dir); db_env_->CreateDirIfMissing(wal_dir); if (restore_options.keep_log_files) { // delete files in db_dir, but keep all the log files DeleteChildren(db_dir, 1 << kLogFile); // move all the files from archive dir to wal_dir std::string archive_dir = ArchivalDirectory(wal_dir); std::vector archive_files; db_env_->GetChildren(archive_dir, &archive_files); // ignore errors for (const auto& f : archive_files) { uint64_t number; FileType type; bool ok = ParseFileName(f, &number, &type); if (ok && type == kLogFile) { Log(options_.info_log, "Moving log file from archive/ to wal_dir: %s", f.c_str()); Status s = db_env_->RenameFile(archive_dir + "/" + f, wal_dir + "/" + f); if (!s.ok()) { // if we can't move log file from archive_dir to wal_dir, // we should fail, since it might mean data loss return s; } } } } else { DeleteChildren(wal_dir); DeleteChildren(ArchivalDirectory(wal_dir)); DeleteChildren(db_dir); } unique_ptr rate_limiter; if (options_.restore_rate_limit > 0) { copy_file_buffer_size_ = options_.restore_rate_limit / 10; rate_limiter.reset(new BackupRateLimiter(db_env_, options_.restore_rate_limit, copy_file_buffer_size_)); } Status s; std::vector restore_items_to_finish; for (const auto& file_info : backup->GetFiles()) { const std::string &file = file_info->filename; std::string dst; // 1. extract the filename size_t slash = file.find_last_of('/'); // file will either be shared/, shared_checksum/ // or private// assert(slash != std::string::npos); dst = file.substr(slash + 1); // if the file was in shared_checksum, extract the real file name // in this case the file is __. if (file.substr(0, slash) == GetSharedChecksumDirRel()) { dst = GetFileFromChecksumFile(dst); } // 2. find the filetype uint64_t number; FileType type; bool ok = ParseFileName(dst, &number, &type); if (!ok) { return Status::Corruption("Backup corrupted"); } // 3. Construct the final path // kLogFile lives in wal_dir and all the rest live in db_dir dst = ((type == kLogFile) ? wal_dir : db_dir) + "/" + dst; Log(options_.info_log, "Restoring %s to %s\n", file.c_str(), dst.c_str()); CopyWorkItem copy_work_item(GetAbsolutePath(file), dst, backup_env_, db_env_, false, rate_limiter.get(), 0 /* size_limit */); RestoreAfterCopyWorkItem after_copy_work_item( copy_work_item.result.get_future(), file_info->checksum_value); files_to_copy_.write(std::move(copy_work_item)); restore_items_to_finish.push_back(std::move(after_copy_work_item)); } Status item_status; for (auto& item : restore_items_to_finish) { item.result.wait(); auto result = item.result.get(); item_status = result.status; // Note: It is possible that both of the following bad-status cases occur // during copying. But, we only return one status. if (!item_status.ok()) { s = item_status; break; } else if (item.checksum_value != result.checksum_value) { s = Status::Corruption("Checksum check failed"); break; } } Log(options_.info_log, "Restoring done -- %s\n", s.ToString().c_str()); return s; } // latest backup id is an ASCII representation of latest backup id Status BackupEngineImpl::GetLatestBackupFileContents(uint32_t* latest_backup) { Status s; unique_ptr file; s = backup_env_->NewSequentialFile(GetLatestBackupFile(), &file, EnvOptions()); if (!s.ok()) { return s; } char buf[11]; Slice data; unique_ptr file_reader( new SequentialFileReader(std::move(file))); s = file_reader->Read(10, &data, buf); if (!s.ok() || data.size() == 0) { return s.ok() ? Status::Corruption("Latest backup file corrupted") : s; } buf[data.size()] = 0; *latest_backup = 0; sscanf(data.data(), "%u", latest_backup); if (backup_env_->FileExists(GetBackupMetaFile(*latest_backup)) == false) { s = Status::Corruption("Latest backup file corrupted"); } return Status::OK(); } // this operation HAS to be atomic // writing 4 bytes to the file is atomic alright, but we should *never* // do something like 1. delete file, 2. write new file // We write to a tmp file and then atomically rename Status BackupEngineImpl::PutLatestBackupFileContents(uint32_t latest_backup) { assert(!read_only_); Status s; unique_ptr file; EnvOptions env_options; env_options.use_mmap_writes = false; s = backup_env_->NewWritableFile(GetLatestBackupFile(true), &file, env_options); if (!s.ok()) { backup_env_->DeleteFile(GetLatestBackupFile(true)); return s; } unique_ptr file_writer( new WritableFileWriter(std::move(file), env_options)); char file_contents[10]; int len = sprintf(file_contents, "%u\n", latest_backup); s = file_writer->Append(Slice(file_contents, len)); if (s.ok() && options_.sync) { file_writer->Sync(false); } if (s.ok()) { s = file_writer->Close(); } if (s.ok()) { // atomically replace real file with new tmp s = backup_env_->RenameFile(GetLatestBackupFile(true), GetLatestBackupFile(false)); } return s; } Status BackupEngineImpl::CopyFile( const std::string& src, const std::string& dst, Env* src_env, Env* dst_env, bool sync, BackupRateLimiter* rate_limiter, uint64_t* size, uint32_t* checksum_value, uint64_t size_limit) { Status s; unique_ptr dst_file; unique_ptr src_file; EnvOptions env_options; env_options.use_mmap_writes = false; env_options.use_os_buffer = false; if (size != nullptr) { *size = 0; } if (checksum_value != nullptr) { *checksum_value = 0; } // Check if size limit is set. if not, set it to very big number if (size_limit == 0) { size_limit = std::numeric_limits::max(); } s = src_env->NewSequentialFile(src, &src_file, env_options); if (s.ok()) { s = dst_env->NewWritableFile(dst, &dst_file, env_options); } if (!s.ok()) { return s; } unique_ptr dest_writer( new WritableFileWriter(std::move(dst_file), env_options)); unique_ptr src_reader( new SequentialFileReader(std::move(src_file))); unique_ptr buf(new char[copy_file_buffer_size_]); Slice data; do { if (stop_backup_.load(std::memory_order_acquire)) { return Status::Incomplete("Backup stopped"); } size_t buffer_to_read = (copy_file_buffer_size_ < size_limit) ? copy_file_buffer_size_ : size_limit; s = src_reader->Read(buffer_to_read, &data, buf.get()); size_limit -= data.size(); if (!s.ok()) { return s; } if (size != nullptr) { *size += data.size(); } if (checksum_value != nullptr) { *checksum_value = crc32c::Extend(*checksum_value, data.data(), data.size()); } s = dest_writer->Append(data); if (rate_limiter != nullptr) { rate_limiter->ReportAndWait(data.size()); } } while (s.ok() && data.size() > 0 && size_limit > 0); if (s.ok() && sync) { s = dest_writer->Sync(false); } return s; } // src_fname will always start with "/" Status BackupEngineImpl::AddBackupFileWorkItem( std::unordered_set& live_dst_paths, std::vector& backup_items_to_finish, BackupID backup_id, bool shared, const std::string& src_dir, const std::string& src_fname, BackupRateLimiter* rate_limiter, uint64_t size_limit, bool shared_checksum) { assert(src_fname.size() > 0 && src_fname[0] == '/'); std::string dst_relative = src_fname.substr(1); std::string dst_relative_tmp; Status s; uint64_t size; uint32_t checksum_value = 0; if (shared && shared_checksum) { // add checksum and file length to the file name s = CalculateChecksum(src_dir + src_fname, db_env_, size_limit, &checksum_value); if (s.ok()) { s = db_env_->GetFileSize(src_dir + src_fname, &size); } if (!s.ok()) { return s; } dst_relative = GetSharedFileWithChecksum(dst_relative, checksum_value, size); dst_relative_tmp = GetSharedFileWithChecksumRel(dst_relative, true); dst_relative = GetSharedFileWithChecksumRel(dst_relative, false); } else if (shared) { dst_relative_tmp = GetSharedFileRel(dst_relative, true); dst_relative = GetSharedFileRel(dst_relative, false); } else { dst_relative_tmp = GetPrivateFileRel(backup_id, true, dst_relative); dst_relative = GetPrivateFileRel(backup_id, false, dst_relative); } std::string dst_path = GetAbsolutePath(dst_relative); std::string dst_path_tmp = GetAbsolutePath(dst_relative_tmp); // if it's shared, we also need to check if it exists -- if it does, no need // to copy it again. bool need_to_copy = true; // true if dst_path is the same path as another live file const bool same_path = live_dst_paths.find(dst_path) != live_dst_paths.end(); if (shared && (backup_env_->FileExists(dst_path) || same_path)) { need_to_copy = false; if (shared_checksum) { Log(options_.info_log, "%s already present, with checksum %u and size %" PRIu64, src_fname.c_str(), checksum_value, size); } else if (backuped_file_infos_.find(dst_relative) == backuped_file_infos_.end() && !same_path) { // file already exists, but it's not referenced by any backup. overwrite // the file Log(options_.info_log, "%s already present, but not referenced by any backup. We will " "overwrite the file.", src_fname.c_str()); need_to_copy = true; backup_env_->DeleteFile(dst_path); } else { // the file is present and referenced by a backup db_env_->GetFileSize(src_dir + src_fname, &size); // Ignore error Log(options_.info_log, "%s already present, calculate checksum", src_fname.c_str()); s = CalculateChecksum(src_dir + src_fname, db_env_, size_limit, &checksum_value); } } live_dst_paths.insert(dst_path); if (need_to_copy) { Log(options_.info_log, "Copying %s to %s", src_fname.c_str(), dst_path_tmp.c_str()); CopyWorkItem copy_work_item(src_dir + src_fname, dst_path_tmp, db_env_, backup_env_, options_.sync, rate_limiter, size_limit); BackupAfterCopyWorkItem after_copy_work_item( copy_work_item.result.get_future(), shared, need_to_copy, backup_env_, dst_path_tmp, dst_path, dst_relative); files_to_copy_.write(std::move(copy_work_item)); backup_items_to_finish.push_back(std::move(after_copy_work_item)); } else { std::promise promise_result; BackupAfterCopyWorkItem after_copy_work_item( promise_result.get_future(), shared, need_to_copy, backup_env_, dst_path_tmp, dst_path, dst_relative); backup_items_to_finish.push_back(std::move(after_copy_work_item)); CopyResult result; result.status = s; result.size = size; result.checksum_value = checksum_value; promise_result.set_value(std::move(result)); } return s; } Status BackupEngineImpl::CalculateChecksum(const std::string& src, Env* src_env, uint64_t size_limit, uint32_t* checksum_value) { *checksum_value = 0; if (size_limit == 0) { size_limit = std::numeric_limits::max(); } EnvOptions env_options; env_options.use_mmap_writes = false; env_options.use_os_buffer = false; std::unique_ptr src_file; Status s = src_env->NewSequentialFile(src, &src_file, env_options); if (!s.ok()) { return s; } unique_ptr src_reader( new SequentialFileReader(std::move(src_file))); std::unique_ptr buf(new char[copy_file_buffer_size_]); Slice data; do { if (stop_backup_.load(std::memory_order_acquire)) { return Status::Incomplete("Backup stopped"); } size_t buffer_to_read = (copy_file_buffer_size_ < size_limit) ? copy_file_buffer_size_ : size_limit; s = src_reader->Read(buffer_to_read, &data, buf.get()); if (!s.ok()) { return s; } size_limit -= data.size(); *checksum_value = crc32c::Extend(*checksum_value, data.data(), data.size()); } while (data.size() > 0 && size_limit > 0); return s; } void BackupEngineImpl::DeleteChildren(const std::string& dir, uint32_t file_type_filter) { std::vector children; db_env_->GetChildren(dir, &children); // ignore errors for (const auto& f : children) { uint64_t number; FileType type; bool ok = ParseFileName(f, &number, &type); if (ok && (file_type_filter & (1 << type))) { // don't delete this file continue; } db_env_->DeleteFile(dir + "/" + f); // ignore errors } } Status BackupEngineImpl::GarbageCollect() { assert(!read_only_); Log(options_.info_log, "Starting garbage collection"); // delete obsolete shared files std::vector shared_children; { auto s = backup_env_->GetChildren(GetAbsolutePath(GetSharedFileRel()), &shared_children); if (!s.ok()) { return s; } } for (auto& child : shared_children) { std::string rel_fname = GetSharedFileRel(child); auto child_itr = backuped_file_infos_.find(rel_fname); // if it's not refcounted, delete it if (child_itr == backuped_file_infos_.end() || child_itr->second->refs == 0) { // this might be a directory, but DeleteFile will just fail in that // case, so we're good Status s = backup_env_->DeleteFile(GetAbsolutePath(rel_fname)); Log(options_.info_log, "Deleting %s -- %s", rel_fname.c_str(), s.ToString().c_str()); backuped_file_infos_.erase(rel_fname); } } // delete obsolete private files std::vector private_children; { auto s = backup_env_->GetChildren(GetAbsolutePath(GetPrivateDirRel()), &private_children); if (!s.ok()) { return s; } } for (auto& child : private_children) { BackupID backup_id = 0; bool tmp_dir = child.find(".tmp") != std::string::npos; sscanf(child.c_str(), "%u", &backup_id); if (!tmp_dir && // if it's tmp_dir, delete it (backup_id == 0 || backups_.find(backup_id) != backups_.end())) { // it's either not a number or it's still alive. continue continue; } // here we have to delete the dir and all its children std::string full_private_path = GetAbsolutePath(GetPrivateFileRel(backup_id, tmp_dir)); std::vector subchildren; backup_env_->GetChildren(full_private_path, &subchildren); for (auto& subchild : subchildren) { Status s = backup_env_->DeleteFile(full_private_path + subchild); Log(options_.info_log, "Deleting %s -- %s", (full_private_path + subchild).c_str(), s.ToString().c_str()); } // finally delete the private dir Status s = backup_env_->DeleteDir(full_private_path); Log(options_.info_log, "Deleting dir %s -- %s", full_private_path.c_str(), s.ToString().c_str()); } return Status::OK(); } // ------- BackupMeta class -------- Status BackupEngineImpl::BackupMeta::AddFile( std::shared_ptr file_info) { auto itr = file_infos_->find(file_info->filename); if (itr == file_infos_->end()) { auto ret = file_infos_->insert({file_info->filename, file_info}); if (ret.second) { itr = ret.first; itr->second->refs = 1; } else { // if this happens, something is seriously wrong return Status::Corruption("In memory metadata insertion error"); } } else { if (itr->second->checksum_value != file_info->checksum_value) { return Status::Corruption( "Checksum mismatch for existing backup file. Delete old backups and " "try again."); } ++itr->second->refs; // increase refcount if already present } size_ += file_info->size; files_.push_back(itr->second); return Status::OK(); } Status BackupEngineImpl::BackupMeta::Delete(bool delete_meta) { Status s; for (const auto& file : files_) { --file->refs; // decrease refcount } files_.clear(); // delete meta file if (delete_meta && env_->FileExists(meta_filename_)) { s = env_->DeleteFile(meta_filename_); } timestamp_ = 0; return s; } // each backup meta file is of the format: // // // // // // ... Status BackupEngineImpl::BackupMeta::LoadFromFile( const std::string& backup_dir) { assert(Empty()); Status s; unique_ptr backup_meta_file; s = env_->NewSequentialFile(meta_filename_, &backup_meta_file, EnvOptions()); if (!s.ok()) { return s; } unique_ptr backup_meta_reader( new SequentialFileReader(std::move(backup_meta_file))); unique_ptr buf(new char[max_backup_meta_file_size_ + 1]); Slice data; s = backup_meta_reader->Read(max_backup_meta_file_size_, &data, buf.get()); if (!s.ok() || data.size() == max_backup_meta_file_size_) { return s.ok() ? Status::Corruption("File size too big") : s; } buf[data.size()] = 0; uint32_t num_files = 0; char *next; timestamp_ = strtoull(data.data(), &next, 10); data.remove_prefix(next - data.data() + 1); // +1 for '\n' sequence_number_ = strtoull(data.data(), &next, 10); data.remove_prefix(next - data.data() + 1); // +1 for '\n' num_files = static_cast(strtoul(data.data(), &next, 10)); data.remove_prefix(next - data.data() + 1); // +1 for '\n' std::vector> files; Slice checksum_prefix("crc32 "); for (uint32_t i = 0; s.ok() && i < num_files; ++i) { auto line = GetSliceUntil(&data, '\n'); std::string filename = GetSliceUntil(&line, ' ').ToString(); uint64_t size; const std::shared_ptr file_info = GetFile(filename); if (file_info) { size = file_info->size; } else { s = env_->GetFileSize(backup_dir + "/" + filename, &size); if (!s.ok()) { return s; } } if (line.empty()) { return Status::Corruption("File checksum is missing for " + filename + " in " + meta_filename_); } uint32_t checksum_value = 0; if (line.starts_with(checksum_prefix)) { line.remove_prefix(checksum_prefix.size()); checksum_value = static_cast( strtoul(line.data(), nullptr, 10)); if (line != rocksdb::ToString(checksum_value)) { return Status::Corruption("Invalid checksum value for " + filename + " in " + meta_filename_); } } else { return Status::Corruption("Unknown checksum type for " + filename + " in " + meta_filename_); } files.emplace_back(new FileInfo(filename, size, checksum_value)); } if (s.ok() && data.size() > 0) { // file has to be read completely. if not, we count it as corruption s = Status::Corruption("Tailing data in backup meta file in " + meta_filename_); } if (s.ok()) { files_.reserve(files.size()); for (const auto& file_info : files) { s = AddFile(file_info); if (!s.ok()) { break; } } } return s; } Status BackupEngineImpl::BackupMeta::StoreToFile(bool sync) { Status s; unique_ptr backup_meta_file; EnvOptions env_options; env_options.use_mmap_writes = false; s = env_->NewWritableFile(meta_filename_ + ".tmp", &backup_meta_file, env_options); if (!s.ok()) { return s; } unique_ptr buf(new char[max_backup_meta_file_size_]); int len = 0, buf_size = max_backup_meta_file_size_; len += snprintf(buf.get(), buf_size, "%" PRId64 "\n", timestamp_); len += snprintf(buf.get() + len, buf_size - len, "%" PRIu64 "\n", sequence_number_); len += snprintf(buf.get() + len, buf_size - len, "%" ROCKSDB_PRIszt "\n", files_.size()); for (const auto& file : files_) { // use crc32 for now, switch to something else if needed len += snprintf(buf.get() + len, buf_size - len, "%s crc32 %u\n", file->filename.c_str(), file->checksum_value); } s = backup_meta_file->Append(Slice(buf.get(), (size_t)len)); if (s.ok() && sync) { s = backup_meta_file->Sync(); } if (s.ok()) { s = backup_meta_file->Close(); } if (s.ok()) { s = env_->RenameFile(meta_filename_ + ".tmp", meta_filename_); } return s; } // -------- BackupEngineReadOnlyImpl --------- class BackupEngineReadOnlyImpl : public BackupEngineReadOnly { public: BackupEngineReadOnlyImpl(Env* db_env, const BackupableDBOptions& options) : backup_engine_(new BackupEngineImpl(db_env, options, true)) {} virtual ~BackupEngineReadOnlyImpl() {} virtual void GetBackupInfo(std::vector* backup_info) override { backup_engine_->GetBackupInfo(backup_info); } virtual void GetCorruptedBackups( std::vector* corrupt_backup_ids) override { backup_engine_->GetCorruptedBackups(corrupt_backup_ids); } virtual Status RestoreDBFromBackup( BackupID backup_id, const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options = RestoreOptions()) override { return backup_engine_->RestoreDBFromBackup(backup_id, db_dir, wal_dir, restore_options); } virtual Status RestoreDBFromLatestBackup( const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options = RestoreOptions()) override { return backup_engine_->RestoreDBFromLatestBackup(db_dir, wal_dir, restore_options); } Status Initialize() { return backup_engine_->Initialize(); } private: std::unique_ptr backup_engine_; }; Status BackupEngineReadOnly::Open(Env* env, const BackupableDBOptions& options, BackupEngineReadOnly** backup_engine_ptr) { if (options.destroy_old_data) { return Status::InvalidArgument( "Can't destroy old data with ReadOnly BackupEngine"); } std::unique_ptr backup_engine( new BackupEngineReadOnlyImpl(env, options)); auto s = backup_engine->Initialize(); if (!s.ok()) { *backup_engine_ptr = nullptr; return s; } *backup_engine_ptr = backup_engine.release(); return Status::OK(); } // --- BackupableDB methods -------- BackupableDB::BackupableDB(DB* db, const BackupableDBOptions& options) : StackableDB(db) { auto backup_engine_impl = new BackupEngineImpl(db->GetEnv(), options); status_ = backup_engine_impl->Initialize(); backup_engine_ = backup_engine_impl; } BackupableDB::~BackupableDB() { delete backup_engine_; } Status BackupableDB::CreateNewBackup(bool flush_before_backup) { if (!status_.ok()) { return status_; } return backup_engine_->CreateNewBackup(this, flush_before_backup); } void BackupableDB::GetBackupInfo(std::vector* backup_info) { if (!status_.ok()) { return; } backup_engine_->GetBackupInfo(backup_info); } void BackupableDB::GetCorruptedBackups(std::vector* corrupt_backup_ids) { if (!status_.ok()) { return; } backup_engine_->GetCorruptedBackups(corrupt_backup_ids); } Status BackupableDB::PurgeOldBackups(uint32_t num_backups_to_keep) { if (!status_.ok()) { return status_; } return backup_engine_->PurgeOldBackups(num_backups_to_keep); } Status BackupableDB::DeleteBackup(BackupID backup_id) { if (!status_.ok()) { return status_; } return backup_engine_->DeleteBackup(backup_id); } void BackupableDB::StopBackup() { backup_engine_->StopBackup(); } Status BackupableDB::GarbageCollect() { if (!status_.ok()) { return status_; } return backup_engine_->GarbageCollect(); } // --- RestoreBackupableDB methods ------ RestoreBackupableDB::RestoreBackupableDB(Env* db_env, const BackupableDBOptions& options) { auto backup_engine_impl = new BackupEngineImpl(db_env, options); status_ = backup_engine_impl->Initialize(); backup_engine_ = backup_engine_impl; } RestoreBackupableDB::~RestoreBackupableDB() { delete backup_engine_; } void RestoreBackupableDB::GetBackupInfo(std::vector* backup_info) { if (!status_.ok()) { return; } backup_engine_->GetBackupInfo(backup_info); } void RestoreBackupableDB::GetCorruptedBackups( std::vector* corrupt_backup_ids) { if (!status_.ok()) { return; } backup_engine_->GetCorruptedBackups(corrupt_backup_ids); } Status RestoreBackupableDB::RestoreDBFromBackup( BackupID backup_id, const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options) { if (!status_.ok()) { return status_; } return backup_engine_->RestoreDBFromBackup(backup_id, db_dir, wal_dir, restore_options); } Status RestoreBackupableDB::RestoreDBFromLatestBackup( const std::string& db_dir, const std::string& wal_dir, const RestoreOptions& restore_options) { if (!status_.ok()) { return status_; } return backup_engine_->RestoreDBFromLatestBackup(db_dir, wal_dir, restore_options); } Status RestoreBackupableDB::PurgeOldBackups(uint32_t num_backups_to_keep) { if (!status_.ok()) { return status_; } return backup_engine_->PurgeOldBackups(num_backups_to_keep); } Status RestoreBackupableDB::DeleteBackup(BackupID backup_id) { if (!status_.ok()) { return status_; } return backup_engine_->DeleteBackup(backup_id); } Status RestoreBackupableDB::GarbageCollect() { if (!status_.ok()) { return status_; } return backup_engine_->GarbageCollect(); } } // namespace rocksdb #endif // ROCKSDB_LITE