// 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 (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. #if !defined(ROCKSDB_LITE) && !defined(OS_WIN) #include #include #include "db/db_impl.h" #include "env/env_chroot.h" #include "port/port.h" #include "port/stack_trace.h" #include "rocksdb/rate_limiter.h" #include "rocksdb/transaction_log.h" #include "rocksdb/types.h" #include "rocksdb/utilities/backupable_db.h" #include "rocksdb/utilities/options_util.h" #include "util/file_reader_writer.h" #include "util/filename.h" #include "util/mutexlock.h" #include "util/random.h" #include "util/stderr_logger.h" #include "util/string_util.h" #include "util/sync_point.h" #include "util/testharness.h" #include "util/testutil.h" namespace rocksdb { namespace { using std::unique_ptr; class DummyDB : public StackableDB { public: /* implicit */ DummyDB(const Options& options, const std::string& dbname) : StackableDB(nullptr), options_(options), dbname_(dbname), deletions_enabled_(true), sequence_number_(0) {} SequenceNumber GetLatestSequenceNumber() const override { return ++sequence_number_; } const std::string& GetName() const override { return dbname_; } Env* GetEnv() const override { return options_.env; } using DB::GetOptions; Options GetOptions(ColumnFamilyHandle* /*column_family*/) const override { return options_; } DBOptions GetDBOptions() const override { return DBOptions(options_); } Status EnableFileDeletions(bool /*force*/) override { EXPECT_TRUE(!deletions_enabled_); deletions_enabled_ = true; return Status::OK(); } Status DisableFileDeletions() override { EXPECT_TRUE(deletions_enabled_); deletions_enabled_ = false; return Status::OK(); } Status GetLiveFiles(std::vector& vec, uint64_t* mfs, bool /*flush_memtable*/ = true) override { EXPECT_TRUE(!deletions_enabled_); vec = live_files_; *mfs = 100; return Status::OK(); } ColumnFamilyHandle* DefaultColumnFamily() const override { return nullptr; } class DummyLogFile : public LogFile { public: /* implicit */ DummyLogFile(const std::string& path, bool alive = true) : path_(path), alive_(alive) {} std::string PathName() const override { return path_; } uint64_t LogNumber() const override { // what business do you have calling this method? ADD_FAILURE(); return 0; } WalFileType Type() const override { return alive_ ? kAliveLogFile : kArchivedLogFile; } SequenceNumber StartSequence() const override { // this seqnum guarantees the dummy file will be included in the backup // as long as it is alive. return kMaxSequenceNumber; } uint64_t SizeFileBytes() const override { return 0; } private: std::string path_; bool alive_; }; // DummyLogFile Status GetSortedWalFiles(VectorLogPtr& files) override { EXPECT_TRUE(!deletions_enabled_); files.resize(wal_files_.size()); for (size_t i = 0; i < files.size(); ++i) { files[i].reset( new DummyLogFile(wal_files_[i].first, wal_files_[i].second)); } return Status::OK(); } // To avoid FlushWAL called on stacked db which is nullptr Status FlushWAL(bool /*sync*/) override { return Status::OK(); } std::vector live_files_; // pair std::vector> wal_files_; private: Options options_; std::string dbname_; bool deletions_enabled_; mutable SequenceNumber sequence_number_; }; // DummyDB class TestEnv : public EnvWrapper { public: explicit TestEnv(Env* t) : EnvWrapper(t) {} class DummySequentialFile : public SequentialFile { public: explicit DummySequentialFile(bool fail_reads) : SequentialFile(), rnd_(5), fail_reads_(fail_reads) {} Status Read(size_t n, Slice* result, char* scratch) override { if (fail_reads_) { return Status::IOError(); } size_t read_size = (n > size_left) ? size_left : n; for (size_t i = 0; i < read_size; ++i) { scratch[i] = rnd_.Next() & 255; } *result = Slice(scratch, read_size); size_left -= read_size; return Status::OK(); } Status Skip(uint64_t n) override { size_left = (n > size_left) ? size_left - n : 0; return Status::OK(); } private: size_t size_left = 200; Random rnd_; bool fail_reads_; }; Status NewSequentialFile(const std::string& f, std::unique_ptr* r, const EnvOptions& options) override { MutexLock l(&mutex_); if (dummy_sequential_file_) { r->reset( new TestEnv::DummySequentialFile(dummy_sequential_file_fail_reads_)); return Status::OK(); } else { Status s = EnvWrapper::NewSequentialFile(f, r, options); if (s.ok()) { if ((*r)->use_direct_io()) { ++num_direct_seq_readers_; } ++num_seq_readers_; } return s; } } Status NewWritableFile(const std::string& f, std::unique_ptr* r, const EnvOptions& options) override { MutexLock l(&mutex_); written_files_.push_back(f); if (limit_written_files_ <= 0) { return Status::NotSupported("Sorry, can't do this"); } limit_written_files_--; Status s = EnvWrapper::NewWritableFile(f, r, options); if (s.ok()) { if ((*r)->use_direct_io()) { ++num_direct_writers_; } ++num_writers_; } return s; } Status NewRandomAccessFile(const std::string& fname, unique_ptr* result, const EnvOptions& options) override { MutexLock l(&mutex_); Status s = EnvWrapper::NewRandomAccessFile(fname, result, options); if (s.ok()) { if ((*result)->use_direct_io()) { ++num_direct_rand_readers_; } ++num_rand_readers_; } return s; } Status DeleteFile(const std::string& fname) override { MutexLock l(&mutex_); if (fail_delete_files_) { return Status::IOError(); } EXPECT_GT(limit_delete_files_, 0U); limit_delete_files_--; return EnvWrapper::DeleteFile(fname); } Status DeleteDir(const std::string& dirname) override { MutexLock l(&mutex_); if (fail_delete_files_) { return Status::IOError(); } return EnvWrapper::DeleteDir(dirname); } void AssertWrittenFiles(std::vector& should_have_written) { MutexLock l(&mutex_); std::sort(should_have_written.begin(), should_have_written.end()); std::sort(written_files_.begin(), written_files_.end()); ASSERT_EQ(should_have_written, written_files_); } void ClearWrittenFiles() { MutexLock l(&mutex_); written_files_.clear(); } void SetLimitWrittenFiles(uint64_t limit) { MutexLock l(&mutex_); limit_written_files_ = limit; } void SetLimitDeleteFiles(uint64_t limit) { MutexLock l(&mutex_); limit_delete_files_ = limit; } void SetDeleteFileFailure(bool fail) { MutexLock l(&mutex_); fail_delete_files_ = fail; } void SetDummySequentialFile(bool dummy_sequential_file) { MutexLock l(&mutex_); dummy_sequential_file_ = dummy_sequential_file; } void SetDummySequentialFileFailReads(bool dummy_sequential_file_fail_reads) { MutexLock l(&mutex_); dummy_sequential_file_fail_reads_ = dummy_sequential_file_fail_reads; } void SetGetChildrenFailure(bool fail) { get_children_failure_ = fail; } Status GetChildren(const std::string& dir, std::vector* r) override { if (get_children_failure_) { return Status::IOError("SimulatedFailure"); } return EnvWrapper::GetChildren(dir, r); } // Some test cases do not actually create the test files (e.g., see // DummyDB::live_files_) - for those cases, we mock those files' attributes // so CreateNewBackup() can get their attributes. void SetFilenamesForMockedAttrs(const std::vector& filenames) { filenames_for_mocked_attrs_ = filenames; } Status GetChildrenFileAttributes( const std::string& dir, std::vector* r) override { if (filenames_for_mocked_attrs_.size() > 0) { for (const auto& filename : filenames_for_mocked_attrs_) { r->push_back({dir + filename, 10 /* size_bytes */}); } return Status::OK(); } return EnvWrapper::GetChildrenFileAttributes(dir, r); } Status GetFileSize(const std::string& path, uint64_t* size_bytes) override { if (filenames_for_mocked_attrs_.size() > 0) { auto fname = path.substr(path.find_last_of('/')); auto filename_iter = std::find(filenames_for_mocked_attrs_.begin(), filenames_for_mocked_attrs_.end(), fname); if (filename_iter != filenames_for_mocked_attrs_.end()) { *size_bytes = 10; return Status::OK(); } return Status::NotFound(fname); } return EnvWrapper::GetFileSize(path, size_bytes); } void SetCreateDirIfMissingFailure(bool fail) { create_dir_if_missing_failure_ = fail; } Status CreateDirIfMissing(const std::string& d) override { if (create_dir_if_missing_failure_) { return Status::IOError("SimulatedFailure"); } return EnvWrapper::CreateDirIfMissing(d); } void SetNewDirectoryFailure(bool fail) { new_directory_failure_ = fail; } Status NewDirectory(const std::string& name, std::unique_ptr* result) override { if (new_directory_failure_) { return Status::IOError("SimulatedFailure"); } return EnvWrapper::NewDirectory(name, result); } void ClearFileOpenCounters() { MutexLock l(&mutex_); num_rand_readers_ = 0; num_direct_rand_readers_ = 0; num_seq_readers_ = 0; num_direct_seq_readers_ = 0; num_writers_ = 0; num_direct_writers_ = 0; } int num_rand_readers() { return num_rand_readers_; } int num_direct_rand_readers() { return num_direct_rand_readers_; } int num_seq_readers() { return num_seq_readers_; } int num_direct_seq_readers() { return num_direct_seq_readers_; } int num_writers() { return num_writers_; } int num_direct_writers() { return num_direct_writers_; } private: port::Mutex mutex_; bool dummy_sequential_file_ = false; bool dummy_sequential_file_fail_reads_ = false; std::vector written_files_; std::vector filenames_for_mocked_attrs_; uint64_t limit_written_files_ = 1000000; uint64_t limit_delete_files_ = 1000000; bool fail_delete_files_ = false; bool get_children_failure_ = false; bool create_dir_if_missing_failure_ = false; bool new_directory_failure_ = false; // Keeps track of how many files of each type were successfully opened, and // out of those, how many were opened with direct I/O. std::atomic num_rand_readers_; std::atomic num_direct_rand_readers_; std::atomic num_seq_readers_; std::atomic num_direct_seq_readers_; std::atomic num_writers_; std::atomic num_direct_writers_; }; // TestEnv class FileManager : public EnvWrapper { public: explicit FileManager(Env* t) : EnvWrapper(t), rnd_(5) {} Status DeleteRandomFileInDir(const std::string& dir) { std::vector children; GetChildren(dir, &children); if (children.size() <= 2) { // . and .. return Status::NotFound(""); } while (true) { int i = rnd_.Next() % children.size(); if (children[i] != "." && children[i] != "..") { return DeleteFile(dir + "/" + children[i]); } } // should never get here assert(false); return Status::NotFound(""); } Status AppendToRandomFileInDir(const std::string& dir, const std::string& data) { std::vector children; GetChildren(dir, &children); if (children.size() <= 2) { return Status::NotFound(""); } while (true) { int i = rnd_.Next() % children.size(); if (children[i] != "." && children[i] != "..") { return WriteToFile(dir + "/" + children[i], data); } } // should never get here assert(false); return Status::NotFound(""); } Status CorruptFile(const std::string& fname, uint64_t bytes_to_corrupt) { std::string file_contents; Status s = ReadFileToString(this, fname, &file_contents); if (!s.ok()) { return s; } s = DeleteFile(fname); if (!s.ok()) { return s; } for (uint64_t i = 0; i < bytes_to_corrupt; ++i) { std::string tmp; test::RandomString(&rnd_, 1, &tmp); file_contents[rnd_.Next() % file_contents.size()] = tmp[0]; } return WriteToFile(fname, file_contents); } Status CorruptChecksum(const std::string& fname, bool appear_valid) { std::string metadata; Status s = ReadFileToString(this, fname, &metadata); if (!s.ok()) { return s; } s = DeleteFile(fname); if (!s.ok()) { return s; } auto pos = metadata.find("private"); if (pos == std::string::npos) { return Status::Corruption("private file is expected"); } pos = metadata.find(" crc32 ", pos + 6); if (pos == std::string::npos) { return Status::Corruption("checksum not found"); } if (metadata.size() < pos + 7) { return Status::Corruption("bad CRC32 checksum value"); } if (appear_valid) { if (metadata[pos + 8] == '\n') { // single digit value, safe to insert one more digit metadata.insert(pos + 8, 1, '0'); } else { metadata.erase(pos + 8, 1); } } else { metadata[pos + 7] = 'a'; } return WriteToFile(fname, metadata); } Status WriteToFile(const std::string& fname, const std::string& data) { std::unique_ptr file; EnvOptions env_options; env_options.use_mmap_writes = false; Status s = EnvWrapper::NewWritableFile(fname, &file, env_options); if (!s.ok()) { return s; } return file->Append(Slice(data)); } private: Random rnd_; }; // FileManager // utility functions static size_t FillDB(DB* db, int from, int to) { size_t bytes_written = 0; for (int i = from; i < to; ++i) { std::string key = "testkey" + ToString(i); std::string value = "testvalue" + ToString(i); bytes_written += key.size() + value.size(); EXPECT_OK(db->Put(WriteOptions(), Slice(key), Slice(value))); } return bytes_written; } static void AssertExists(DB* db, int from, int to) { for (int i = from; i < to; ++i) { std::string key = "testkey" + ToString(i); std::string value; Status s = db->Get(ReadOptions(), Slice(key), &value); ASSERT_EQ(value, "testvalue" + ToString(i)); } } static void AssertEmpty(DB* db, int from, int to) { for (int i = from; i < to; ++i) { std::string key = "testkey" + ToString(i); std::string value = "testvalue" + ToString(i); Status s = db->Get(ReadOptions(), Slice(key), &value); ASSERT_TRUE(s.IsNotFound()); } } class BackupableDBTest : public testing::Test { public: BackupableDBTest() { // set up files std::string db_chroot = test::PerThreadDBPath("backupable_db"); std::string backup_chroot = test::PerThreadDBPath("backupable_db_backup"); Env::Default()->CreateDir(db_chroot); Env::Default()->CreateDir(backup_chroot); dbname_ = "/tempdb"; backupdir_ = "/tempbk"; // set up envs db_chroot_env_.reset(NewChrootEnv(Env::Default(), db_chroot)); backup_chroot_env_.reset(NewChrootEnv(Env::Default(), backup_chroot)); test_db_env_.reset(new TestEnv(db_chroot_env_.get())); test_backup_env_.reset(new TestEnv(backup_chroot_env_.get())); file_manager_.reset(new FileManager(backup_chroot_env_.get())); // set up db options options_.create_if_missing = true; options_.paranoid_checks = true; options_.write_buffer_size = 1 << 17; // 128KB options_.env = test_db_env_.get(); options_.wal_dir = dbname_; // Create logger DBOptions logger_options; logger_options.env = db_chroot_env_.get(); CreateLoggerFromOptions(dbname_, logger_options, &logger_); // set up backup db options backupable_options_.reset(new BackupableDBOptions( backupdir_, test_backup_env_.get(), true, logger_.get(), true)); // most tests will use multi-threaded backups backupable_options_->max_background_operations = 7; // delete old files in db DestroyDB(dbname_, options_); } DB* OpenDB() { DB* db; EXPECT_OK(DB::Open(options_, dbname_, &db)); return db; } void OpenDBAndBackupEngineShareWithChecksum( bool destroy_old_data = false, bool dummy = false, bool /*share_table_files*/ = true, bool share_with_checksums = false) { backupable_options_->share_files_with_checksum = share_with_checksums; OpenDBAndBackupEngine(destroy_old_data, dummy, share_with_checksums); } void OpenDBAndBackupEngine(bool destroy_old_data = false, bool dummy = false, bool share_table_files = true) { // reset all the defaults test_backup_env_->SetLimitWrittenFiles(1000000); test_db_env_->SetLimitWrittenFiles(1000000); test_db_env_->SetDummySequentialFile(dummy); DB* db; if (dummy) { dummy_db_ = new DummyDB(options_, dbname_); db = dummy_db_; } else { ASSERT_OK(DB::Open(options_, dbname_, &db)); } db_.reset(db); backupable_options_->destroy_old_data = destroy_old_data; backupable_options_->share_table_files = share_table_files; BackupEngine* backup_engine; ASSERT_OK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); backup_engine_.reset(backup_engine); } void CloseDBAndBackupEngine() { db_.reset(); backup_engine_.reset(); } void OpenBackupEngine() { backupable_options_->destroy_old_data = false; BackupEngine* backup_engine; ASSERT_OK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); backup_engine_.reset(backup_engine); } void CloseBackupEngine() { backup_engine_.reset(nullptr); } // restores backup backup_id and asserts the existence of // [start_exist, end_exist> and not-existence of // [end_exist, end> // // if backup_id == 0, it means restore from latest // if end == 0, don't check AssertEmpty void AssertBackupConsistency(BackupID backup_id, uint32_t start_exist, uint32_t end_exist, uint32_t end = 0, bool keep_log_files = false) { RestoreOptions restore_options(keep_log_files); bool opened_backup_engine = false; if (backup_engine_.get() == nullptr) { opened_backup_engine = true; OpenBackupEngine(); } if (backup_id > 0) { ASSERT_OK(backup_engine_->RestoreDBFromBackup(backup_id, dbname_, dbname_, restore_options)); } else { ASSERT_OK(backup_engine_->RestoreDBFromLatestBackup(dbname_, dbname_, restore_options)); } DB* db = OpenDB(); AssertExists(db, start_exist, end_exist); if (end != 0) { AssertEmpty(db, end_exist, end); } delete db; if (opened_backup_engine) { CloseBackupEngine(); } } void DeleteLogFiles() { std::vector delete_logs; db_chroot_env_->GetChildren(dbname_, &delete_logs); for (auto f : delete_logs) { uint64_t number; FileType type; bool ok = ParseFileName(f, &number, &type); if (ok && type == kLogFile) { db_chroot_env_->DeleteFile(dbname_ + "/" + f); } } } // files std::string dbname_; std::string backupdir_; // logger_ must be above backup_engine_ such that the engine's destructor, // which uses a raw pointer to the logger, executes first. std::shared_ptr logger_; // envs std::unique_ptr db_chroot_env_; std::unique_ptr backup_chroot_env_; std::unique_ptr test_db_env_; std::unique_ptr test_backup_env_; std::unique_ptr file_manager_; // all the dbs! DummyDB* dummy_db_; // BackupableDB owns dummy_db_ std::unique_ptr db_; std::unique_ptr backup_engine_; // options Options options_; protected: std::unique_ptr backupable_options_; }; // BackupableDBTest void AppendPath(const std::string& path, std::vector& v) { for (auto& f : v) { f = path + f; } } class BackupableDBTestWithParam : public BackupableDBTest, public testing::WithParamInterface { public: BackupableDBTestWithParam() { backupable_options_->share_files_with_checksum = GetParam(); } }; // This test verifies that the verifyBackup method correctly identifies // invalid backups TEST_P(BackupableDBTestWithParam, VerifyBackup) { const int keys_iteration = 5000; Random rnd(6); Status s; OpenDBAndBackupEngine(true); // create five backups for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); } CloseDBAndBackupEngine(); OpenDBAndBackupEngine(); // ---------- case 1. - valid backup ----------- ASSERT_TRUE(backup_engine_->VerifyBackup(1).ok()); // ---------- case 2. - delete a file -----------i file_manager_->DeleteRandomFileInDir(backupdir_ + "/private/1"); ASSERT_TRUE(backup_engine_->VerifyBackup(1).IsNotFound()); // ---------- case 3. - corrupt a file ----------- std::string append_data = "Corrupting a random file"; file_manager_->AppendToRandomFileInDir(backupdir_ + "/private/2", append_data); ASSERT_TRUE(backup_engine_->VerifyBackup(2).IsCorruption()); // ---------- case 4. - invalid backup ----------- ASSERT_TRUE(backup_engine_->VerifyBackup(6).IsNotFound()); CloseDBAndBackupEngine(); } // open DB, write, close DB, backup, restore, repeat TEST_P(BackupableDBTestWithParam, OfflineIntegrationTest) { // has to be a big number, so that it triggers the memtable flush const int keys_iteration = 5000; const int max_key = keys_iteration * 4 + 10; // first iter -- flush before backup // second iter -- don't flush before backup for (int iter = 0; iter < 2; ++iter) { // delete old data DestroyDB(dbname_, options_); bool destroy_data = true; // every iteration -- // 1. insert new data in the DB // 2. backup the DB // 3. destroy the db // 4. restore the db, check everything is still there for (int i = 0; i < 5; ++i) { // in last iteration, put smaller amount of data, int fill_up_to = std::min(keys_iteration * (i + 1), max_key); // ---- insert new data and back up ---- OpenDBAndBackupEngine(destroy_data); destroy_data = false; FillDB(db_.get(), keys_iteration * i, fill_up_to); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), iter == 0)); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); // ---- make sure it's empty ---- DB* db = OpenDB(); AssertEmpty(db, 0, fill_up_to); delete db; // ---- restore the DB ---- OpenBackupEngine(); if (i >= 3) { // test purge old backups // when i == 4, purge to only 1 backup // when i == 3, purge to 2 backups ASSERT_OK(backup_engine_->PurgeOldBackups(5 - i)); } // ---- make sure the data is there --- AssertBackupConsistency(0, 0, fill_up_to, max_key); CloseBackupEngine(); } } } // open DB, write, backup, write, backup, close, restore TEST_P(BackupableDBTestWithParam, OnlineIntegrationTest) { // has to be a big number, so that it triggers the memtable flush const int keys_iteration = 5000; const int max_key = keys_iteration * 4 + 10; Random rnd(7); // delete old data DestroyDB(dbname_, options_); OpenDBAndBackupEngine(true); // write some data, backup, repeat for (int i = 0; i < 5; ++i) { if (i == 4) { // delete backup number 2, online delete! ASSERT_OK(backup_engine_->DeleteBackup(2)); } // in last iteration, put smaller amount of data, // so that backups can share sst files int fill_up_to = std::min(keys_iteration * (i + 1), max_key); FillDB(db_.get(), keys_iteration * i, fill_up_to); // we should get consistent results with flush_before_backup // set to both true and false ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2))); } // close and destroy CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); // ---- make sure it's empty ---- DB* db = OpenDB(); AssertEmpty(db, 0, max_key); delete db; // ---- restore every backup and verify all the data is there ---- OpenBackupEngine(); for (int i = 1; i <= 5; ++i) { if (i == 2) { // we deleted backup 2 Status s = backup_engine_->RestoreDBFromBackup(2, dbname_, dbname_); ASSERT_TRUE(!s.ok()); } else { int fill_up_to = std::min(keys_iteration * i, max_key); AssertBackupConsistency(i, 0, fill_up_to, max_key); } } // delete some backups -- this should leave only backups 3 and 5 alive ASSERT_OK(backup_engine_->DeleteBackup(4)); ASSERT_OK(backup_engine_->PurgeOldBackups(2)); std::vector backup_info; backup_engine_->GetBackupInfo(&backup_info); ASSERT_EQ(2UL, backup_info.size()); // check backup 3 AssertBackupConsistency(3, 0, 3 * keys_iteration, max_key); // check backup 5 AssertBackupConsistency(5, 0, max_key); CloseBackupEngine(); } INSTANTIATE_TEST_CASE_P(BackupableDBTestWithParam, BackupableDBTestWithParam, ::testing::Bool()); // this will make sure that backup does not copy the same file twice TEST_F(BackupableDBTest, NoDoubleCopy) { OpenDBAndBackupEngine(true, true); // should write 5 DB files + one meta file test_backup_env_->SetLimitWrittenFiles(7); test_backup_env_->ClearWrittenFiles(); test_db_env_->SetLimitWrittenFiles(0); dummy_db_->live_files_ = {"/00010.sst", "/00011.sst", "/CURRENT", "/MANIFEST-01"}; dummy_db_->wal_files_ = {{"/00011.log", true}, {"/00012.log", false}}; test_db_env_->SetFilenamesForMockedAttrs(dummy_db_->live_files_); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false)); std::vector should_have_written = { "/shared/.00010.sst.tmp", "/shared/.00011.sst.tmp", "/private/1/CURRENT", "/private/1/MANIFEST-01", "/private/1/00011.log", "/meta/.1.tmp"}; AppendPath(backupdir_, should_have_written); test_backup_env_->AssertWrittenFiles(should_have_written); // should write 4 new DB files + one meta file // should not write/copy 00010.sst, since it's already there! test_backup_env_->SetLimitWrittenFiles(6); test_backup_env_->ClearWrittenFiles(); dummy_db_->live_files_ = {"/00010.sst", "/00015.sst", "/CURRENT", "/MANIFEST-01"}; dummy_db_->wal_files_ = {{"/00011.log", true}, {"/00012.log", false}}; test_db_env_->SetFilenamesForMockedAttrs(dummy_db_->live_files_); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false)); // should not open 00010.sst - it's already there should_have_written = {"/shared/.00015.sst.tmp", "/private/2/CURRENT", "/private/2/MANIFEST-01", "/private/2/00011.log", "/meta/.2.tmp"}; AppendPath(backupdir_, should_have_written); test_backup_env_->AssertWrittenFiles(should_have_written); ASSERT_OK(backup_engine_->DeleteBackup(1)); ASSERT_OK(test_backup_env_->FileExists(backupdir_ + "/shared/00010.sst")); // 00011.sst was only in backup 1, should be deleted ASSERT_EQ(Status::NotFound(), test_backup_env_->FileExists(backupdir_ + "/shared/00011.sst")); ASSERT_OK(test_backup_env_->FileExists(backupdir_ + "/shared/00015.sst")); // MANIFEST file size should be only 100 uint64_t size = 0; test_backup_env_->GetFileSize(backupdir_ + "/private/2/MANIFEST-01", &size); ASSERT_EQ(100UL, size); test_backup_env_->GetFileSize(backupdir_ + "/shared/00015.sst", &size); ASSERT_EQ(200UL, size); CloseDBAndBackupEngine(); } // test various kind of corruptions that may happen: // 1. Not able to write a file for backup - that backup should fail, // everything else should work // 2. Corrupted backup meta file or missing backuped file - we should // not be able to open that backup, but all other backups should be // fine // 3. Corrupted checksum value - if the checksum is not a valid uint32_t, // db open should fail, otherwise, it aborts during the restore process. TEST_F(BackupableDBTest, CorruptionsTest) { const int keys_iteration = 5000; Random rnd(6); Status s; OpenDBAndBackupEngine(true); // create five backups for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2))); } // ---------- case 1. - fail a write ----------- // try creating backup 6, but fail a write FillDB(db_.get(), keys_iteration * 5, keys_iteration * 6); test_backup_env_->SetLimitWrittenFiles(2); // should fail s = backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2)); ASSERT_TRUE(!s.ok()); test_backup_env_->SetLimitWrittenFiles(1000000); // latest backup should have all the keys CloseDBAndBackupEngine(); AssertBackupConsistency(0, 0, keys_iteration * 5, keys_iteration * 6); // --------- case 2. corrupted backup meta or missing backuped file ---- ASSERT_OK(file_manager_->CorruptFile(backupdir_ + "/meta/5", 3)); // since 5 meta is now corrupted, latest backup should be 4 AssertBackupConsistency(0, 0, keys_iteration * 4, keys_iteration * 5); OpenBackupEngine(); s = backup_engine_->RestoreDBFromBackup(5, dbname_, dbname_); ASSERT_TRUE(!s.ok()); CloseBackupEngine(); ASSERT_OK(file_manager_->DeleteRandomFileInDir(backupdir_ + "/private/4")); // 4 is corrupted, 3 is the latest backup now AssertBackupConsistency(0, 0, keys_iteration * 3, keys_iteration * 5); OpenBackupEngine(); s = backup_engine_->RestoreDBFromBackup(4, dbname_, dbname_); CloseBackupEngine(); ASSERT_TRUE(!s.ok()); // --------- case 3. corrupted checksum value ---- ASSERT_OK(file_manager_->CorruptChecksum(backupdir_ + "/meta/3", false)); // checksum of backup 3 is an invalid value, this can be detected at // db open time, and it reverts to the previous backup automatically AssertBackupConsistency(0, 0, keys_iteration * 2, keys_iteration * 5); // checksum of the backup 2 appears to be valid, this can cause checksum // mismatch and abort restore process ASSERT_OK(file_manager_->CorruptChecksum(backupdir_ + "/meta/2", true)); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/2")); OpenBackupEngine(); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/2")); s = backup_engine_->RestoreDBFromBackup(2, dbname_, dbname_); ASSERT_TRUE(!s.ok()); // make sure that no corrupt backups have actually been deleted! ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/1")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/2")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/3")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/4")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/5")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/1")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/2")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/3")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/4")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/5")); // delete the corrupt backups and then make sure they're actually deleted ASSERT_OK(backup_engine_->DeleteBackup(5)); ASSERT_OK(backup_engine_->DeleteBackup(4)); ASSERT_OK(backup_engine_->DeleteBackup(3)); ASSERT_OK(backup_engine_->DeleteBackup(2)); (void)backup_engine_->GarbageCollect(); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/meta/5")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/private/5")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/meta/4")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/private/4")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/meta/3")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/private/3")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/meta/2")); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(backupdir_ + "/private/2")); CloseBackupEngine(); AssertBackupConsistency(0, 0, keys_iteration * 1, keys_iteration * 5); // new backup should be 2! OpenDBAndBackupEngine(); FillDB(db_.get(), keys_iteration * 1, keys_iteration * 2); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2))); CloseDBAndBackupEngine(); AssertBackupConsistency(2, 0, keys_iteration * 2, keys_iteration * 5); } TEST_F(BackupableDBTest, InterruptCreationTest) { // Interrupt backup creation by failing new writes and failing cleanup of the // partial state. Then verify a subsequent backup can still succeed. const int keys_iteration = 5000; Random rnd(6); OpenDBAndBackupEngine(true /* destroy_old_data */); FillDB(db_.get(), 0, keys_iteration); test_backup_env_->SetLimitWrittenFiles(2); test_backup_env_->SetDeleteFileFailure(true); // should fail creation ASSERT_FALSE( backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2)).ok()); CloseDBAndBackupEngine(); // should also fail cleanup so the tmp directory stays behind ASSERT_OK(backup_chroot_env_->FileExists(backupdir_ + "/private/1/")); OpenDBAndBackupEngine(false /* destroy_old_data */); test_backup_env_->SetLimitWrittenFiles(1000000); test_backup_env_->SetDeleteFileFailure(false); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2))); // latest backup should have all the keys CloseDBAndBackupEngine(); AssertBackupConsistency(0, 0, keys_iteration); } inline std::string OptionsPath(std::string ret, int backupID) { ret += "/private/"; ret += std::to_string(backupID); ret += "/"; return ret; } // Backup the LATEST options file to // "/private//OPTIONS" TEST_F(BackupableDBTest, BackupOptions) { OpenDBAndBackupEngine(true); for (int i = 1; i < 5; i++) { std::string name; std::vector filenames; // Must reset() before reset(OpenDB()) again. // Calling OpenDB() while *db_ is existing will cause LOCK issue db_.reset(); db_.reset(OpenDB()); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); rocksdb::GetLatestOptionsFileName(db_->GetName(), options_.env, &name); ASSERT_OK(file_manager_->FileExists(OptionsPath(backupdir_, i) + name)); backup_chroot_env_->GetChildren(OptionsPath(backupdir_, i), &filenames); for (auto fn : filenames) { if (fn.compare(0, 7, "OPTIONS") == 0) { ASSERT_EQ(name, fn); } } } CloseDBAndBackupEngine(); } TEST_F(BackupableDBTest, SetOptionsBackupRaceCondition) { OpenDBAndBackupEngine(true); SyncPoint::GetInstance()->LoadDependency( {{"CheckpointImpl::CreateCheckpoint:SavedLiveFiles1", "BackupableDBTest::SetOptionsBackupRaceCondition:BeforeSetOptions"}, {"BackupableDBTest::SetOptionsBackupRaceCondition:AfterSetOptions", "CheckpointImpl::CreateCheckpoint:SavedLiveFiles2"}}); SyncPoint::GetInstance()->EnableProcessing(); rocksdb::port::Thread setoptions_thread{[this]() { TEST_SYNC_POINT( "BackupableDBTest::SetOptionsBackupRaceCondition:BeforeSetOptions"); DBImpl* dbi = static_cast(db_.get()); // Change arbitrary option to trigger OPTIONS file deletion ASSERT_OK(dbi->SetOptions(dbi->DefaultColumnFamily(), {{"paranoid_file_checks", "false"}})); ASSERT_OK(dbi->SetOptions(dbi->DefaultColumnFamily(), {{"paranoid_file_checks", "true"}})); ASSERT_OK(dbi->SetOptions(dbi->DefaultColumnFamily(), {{"paranoid_file_checks", "false"}})); TEST_SYNC_POINT( "BackupableDBTest::SetOptionsBackupRaceCondition:AfterSetOptions"); }}; ASSERT_OK(backup_engine_->CreateNewBackup(db_.get())); setoptions_thread.join(); CloseDBAndBackupEngine(); } // This test verifies we don't delete the latest backup when read-only option is // set TEST_F(BackupableDBTest, NoDeleteWithReadOnly) { const int keys_iteration = 5000; Random rnd(6); Status s; OpenDBAndBackupEngine(true); // create five backups for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(rnd.Next() % 2))); } CloseDBAndBackupEngine(); ASSERT_OK(file_manager_->WriteToFile(backupdir_ + "/LATEST_BACKUP", "4")); backupable_options_->destroy_old_data = false; BackupEngineReadOnly* read_only_backup_engine; ASSERT_OK(BackupEngineReadOnly::Open(backup_chroot_env_.get(), *backupable_options_, &read_only_backup_engine)); // assert that data from backup 5 is still here (even though LATEST_BACKUP // says 4 is latest) ASSERT_OK(file_manager_->FileExists(backupdir_ + "/meta/5")); ASSERT_OK(file_manager_->FileExists(backupdir_ + "/private/5")); // Behavior change: We now ignore LATEST_BACKUP contents. This means that // we should have 5 backups, even if LATEST_BACKUP says 4. std::vector backup_info; read_only_backup_engine->GetBackupInfo(&backup_info); ASSERT_EQ(5UL, backup_info.size()); delete read_only_backup_engine; } TEST_F(BackupableDBTest, FailOverwritingBackups) { options_.write_buffer_size = 1024 * 1024 * 1024; // 1GB options_.disable_auto_compactions = true; // create backups 1, 2, 3, 4, 5 OpenDBAndBackupEngine(true); for (int i = 0; i < 5; ++i) { CloseDBAndBackupEngine(); DeleteLogFiles(); OpenDBAndBackupEngine(false); FillDB(db_.get(), 100 * i, 100 * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); } CloseDBAndBackupEngine(); // restore 3 OpenBackupEngine(); ASSERT_OK(backup_engine_->RestoreDBFromBackup(3, dbname_, dbname_)); CloseBackupEngine(); OpenDBAndBackupEngine(false); FillDB(db_.get(), 0, 300); Status s = backup_engine_->CreateNewBackup(db_.get(), true); // the new backup fails because new table files // clash with old table files from backups 4 and 5 // (since write_buffer_size is huge, we can be sure that // each backup will generate only one sst file and that // a file generated by a new backup is the same as // sst file generated by backup 4) ASSERT_TRUE(s.IsCorruption()); ASSERT_OK(backup_engine_->DeleteBackup(4)); ASSERT_OK(backup_engine_->DeleteBackup(5)); // now, the backup can succeed ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); CloseDBAndBackupEngine(); } TEST_F(BackupableDBTest, NoShareTableFiles) { const int keys_iteration = 5000; OpenDBAndBackupEngine(true, false, false); for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(i % 2))); } CloseDBAndBackupEngine(); for (int i = 0; i < 5; ++i) { AssertBackupConsistency(i + 1, 0, keys_iteration * (i + 1), keys_iteration * 6); } } // Verify that you can backup and restore with share_files_with_checksum on TEST_F(BackupableDBTest, ShareTableFilesWithChecksums) { const int keys_iteration = 5000; OpenDBAndBackupEngineShareWithChecksum(true, false, true, true); for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), !!(i % 2))); } CloseDBAndBackupEngine(); for (int i = 0; i < 5; ++i) { AssertBackupConsistency(i + 1, 0, keys_iteration * (i + 1), keys_iteration * 6); } } // Verify that you can backup and restore using share_files_with_checksum set to // false and then transition this option to true TEST_F(BackupableDBTest, ShareTableFilesWithChecksumsTransition) { const int keys_iteration = 5000; // set share_files_with_checksum to false OpenDBAndBackupEngineShareWithChecksum(true, false, true, false); for (int i = 0; i < 5; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); } CloseDBAndBackupEngine(); for (int i = 0; i < 5; ++i) { AssertBackupConsistency(i + 1, 0, keys_iteration * (i + 1), keys_iteration * 6); } // set share_files_with_checksum to true and do some more backups OpenDBAndBackupEngineShareWithChecksum(true, false, true, true); for (int i = 5; i < 10; ++i) { FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); } CloseDBAndBackupEngine(); for (int i = 0; i < 5; ++i) { AssertBackupConsistency(i + 1, 0, keys_iteration * (i + 5 + 1), keys_iteration * 11); } } TEST_F(BackupableDBTest, DeleteTmpFiles) { for (bool shared_checksum : {false, true}) { if (shared_checksum) { OpenDBAndBackupEngineShareWithChecksum( false /* destroy_old_data */, false /* dummy */, true /* share_table_files */, true /* share_with_checksums */); } else { OpenDBAndBackupEngine(); } CloseDBAndBackupEngine(); std::string shared_tmp = backupdir_; if (shared_checksum) { shared_tmp += "/shared_checksum"; } else { shared_tmp += "/shared"; } shared_tmp += "/.00006.sst.tmp"; std::string private_tmp_dir = backupdir_ + "/private/10"; std::string private_tmp_file = private_tmp_dir + "/00003.sst"; file_manager_->WriteToFile(shared_tmp, "tmp"); file_manager_->CreateDir(private_tmp_dir); file_manager_->WriteToFile(private_tmp_file, "tmp"); ASSERT_OK(file_manager_->FileExists(private_tmp_dir)); if (shared_checksum) { OpenDBAndBackupEngineShareWithChecksum( false /* destroy_old_data */, false /* dummy */, true /* share_table_files */, true /* share_with_checksums */); } else { OpenDBAndBackupEngine(); } // Need to call this explicitly to delete tmp files (void)backup_engine_->GarbageCollect(); CloseDBAndBackupEngine(); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(shared_tmp)); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(private_tmp_file)); ASSERT_EQ(Status::NotFound(), file_manager_->FileExists(private_tmp_dir)); } } TEST_F(BackupableDBTest, KeepLogFiles) { backupable_options_->backup_log_files = false; // basically infinite options_.WAL_ttl_seconds = 24 * 60 * 60; OpenDBAndBackupEngine(true); FillDB(db_.get(), 0, 100); ASSERT_OK(db_->Flush(FlushOptions())); FillDB(db_.get(), 100, 200); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false)); FillDB(db_.get(), 200, 300); ASSERT_OK(db_->Flush(FlushOptions())); FillDB(db_.get(), 300, 400); ASSERT_OK(db_->Flush(FlushOptions())); FillDB(db_.get(), 400, 500); ASSERT_OK(db_->Flush(FlushOptions())); CloseDBAndBackupEngine(); // all data should be there if we call with keep_log_files = true AssertBackupConsistency(0, 0, 500, 600, true); } TEST_F(BackupableDBTest, RateLimiting) { size_t const kMicrosPerSec = 1000 * 1000LL; uint64_t const MB = 1024 * 1024; const std::vector> limits( {{1 * MB, 5 * MB}, {2 * MB, 3 * MB}}); std::shared_ptr backupThrottler(NewGenericRateLimiter(1)); std::shared_ptr restoreThrottler(NewGenericRateLimiter(1)); for (bool makeThrottler : {false, true}) { if (makeThrottler) { backupable_options_->backup_rate_limiter = backupThrottler; backupable_options_->restore_rate_limiter = restoreThrottler; } // iter 0 -- single threaded // iter 1 -- multi threaded for (int iter = 0; iter < 2; ++iter) { for (const auto& limit : limits) { // destroy old data DestroyDB(dbname_, Options()); if (makeThrottler) { backupThrottler->SetBytesPerSecond(limit.first); restoreThrottler->SetBytesPerSecond(limit.second); } else { backupable_options_->backup_rate_limit = limit.first; backupable_options_->restore_rate_limit = limit.second; } backupable_options_->max_background_operations = (iter == 0) ? 1 : 10; options_.compression = kNoCompression; OpenDBAndBackupEngine(true); size_t bytes_written = FillDB(db_.get(), 0, 100000); auto start_backup = db_chroot_env_->NowMicros(); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false)); auto backup_time = db_chroot_env_->NowMicros() - start_backup; auto rate_limited_backup_time = (bytes_written * kMicrosPerSec) / limit.first; ASSERT_GT(backup_time, 0.8 * rate_limited_backup_time); CloseDBAndBackupEngine(); OpenBackupEngine(); auto start_restore = db_chroot_env_->NowMicros(); ASSERT_OK(backup_engine_->RestoreDBFromLatestBackup(dbname_, dbname_)); auto restore_time = db_chroot_env_->NowMicros() - start_restore; CloseBackupEngine(); auto rate_limited_restore_time = (bytes_written * kMicrosPerSec) / limit.second; ASSERT_GT(restore_time, 0.8 * rate_limited_restore_time); AssertBackupConsistency(0, 0, 100000, 100010); } } } } TEST_F(BackupableDBTest, ReadOnlyBackupEngine) { DestroyDB(dbname_, options_); OpenDBAndBackupEngine(true); FillDB(db_.get(), 0, 100); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); FillDB(db_.get(), 100, 200); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); backupable_options_->destroy_old_data = false; test_backup_env_->ClearWrittenFiles(); test_backup_env_->SetLimitDeleteFiles(0); BackupEngineReadOnly* read_only_backup_engine; ASSERT_OK(BackupEngineReadOnly::Open( db_chroot_env_.get(), *backupable_options_, &read_only_backup_engine)); std::vector backup_info; read_only_backup_engine->GetBackupInfo(&backup_info); ASSERT_EQ(backup_info.size(), 2U); RestoreOptions restore_options(false); ASSERT_OK(read_only_backup_engine->RestoreDBFromLatestBackup( dbname_, dbname_, restore_options)); delete read_only_backup_engine; std::vector should_have_written; test_backup_env_->AssertWrittenFiles(should_have_written); DB* db = OpenDB(); AssertExists(db, 0, 200); delete db; } TEST_F(BackupableDBTest, ProgressCallbackDuringBackup) { DestroyDB(dbname_, options_); OpenDBAndBackupEngine(true); FillDB(db_.get(), 0, 100); bool is_callback_invoked = false; ASSERT_OK(backup_engine_->CreateNewBackup( db_.get(), true, [&is_callback_invoked]() { is_callback_invoked = true; })); ASSERT_TRUE(is_callback_invoked); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); } TEST_F(BackupableDBTest, GarbageCollectionBeforeBackup) { DestroyDB(dbname_, options_); OpenDBAndBackupEngine(true); backup_chroot_env_->CreateDirIfMissing(backupdir_ + "/shared"); std::string file_five = backupdir_ + "/shared/000007.sst"; std::string file_five_contents = "I'm not really a sst file"; // this depends on the fact that 00007.sst is the first file created by the DB ASSERT_OK(file_manager_->WriteToFile(file_five, file_five_contents)); FillDB(db_.get(), 0, 100); // backup overwrites file 000007.sst ASSERT_TRUE(backup_engine_->CreateNewBackup(db_.get(), true).ok()); std::string new_file_five_contents; ASSERT_OK(ReadFileToString(backup_chroot_env_.get(), file_five, &new_file_five_contents)); // file 000007.sst was overwritten ASSERT_TRUE(new_file_five_contents != file_five_contents); CloseDBAndBackupEngine(); AssertBackupConsistency(0, 0, 100); } // Test that we properly propagate Env failures TEST_F(BackupableDBTest, EnvFailures) { BackupEngine* backup_engine; // get children failure { test_backup_env_->SetGetChildrenFailure(true); ASSERT_NOK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); test_backup_env_->SetGetChildrenFailure(false); } // created dir failure { test_backup_env_->SetCreateDirIfMissingFailure(true); ASSERT_NOK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); test_backup_env_->SetCreateDirIfMissingFailure(false); } // new directory failure { test_backup_env_->SetNewDirectoryFailure(true); ASSERT_NOK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); test_backup_env_->SetNewDirectoryFailure(false); } // Read from meta-file failure { DestroyDB(dbname_, options_); OpenDBAndBackupEngine(true); FillDB(db_.get(), 0, 100); ASSERT_TRUE(backup_engine_->CreateNewBackup(db_.get(), true).ok()); CloseDBAndBackupEngine(); test_backup_env_->SetDummySequentialFile(true); test_backup_env_->SetDummySequentialFileFailReads(true); backupable_options_->destroy_old_data = false; ASSERT_NOK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); test_backup_env_->SetDummySequentialFile(false); test_backup_env_->SetDummySequentialFileFailReads(false); } // no failure { ASSERT_OK(BackupEngine::Open(test_db_env_.get(), *backupable_options_, &backup_engine)); delete backup_engine; } } // Verify manifest can roll while a backup is being created with the old // manifest. TEST_F(BackupableDBTest, ChangeManifestDuringBackupCreation) { DestroyDB(dbname_, options_); options_.max_manifest_file_size = 0; // always rollover manifest for file add OpenDBAndBackupEngine(true); FillDB(db_.get(), 0, 100); rocksdb::SyncPoint::GetInstance()->LoadDependency({ {"CheckpointImpl::CreateCheckpoint:SavedLiveFiles1", "VersionSet::LogAndApply:WriteManifest"}, {"VersionSet::LogAndApply:WriteManifestDone", "CheckpointImpl::CreateCheckpoint:SavedLiveFiles2"}, }); rocksdb::SyncPoint::GetInstance()->EnableProcessing(); rocksdb::port::Thread flush_thread{[this]() { ASSERT_OK(db_->Flush(FlushOptions())); }}; ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false)); flush_thread.join(); rocksdb::SyncPoint::GetInstance()->DisableProcessing(); // The last manifest roll would've already been cleaned up by the full scan // that happens when CreateNewBackup invokes EnableFileDeletions. We need to // trigger another roll to verify non-full scan purges stale manifests. DBImpl* db_impl = reinterpret_cast(db_.get()); std::string prev_manifest_path = DescriptorFileName(dbname_, db_impl->TEST_Current_Manifest_FileNo()); FillDB(db_.get(), 0, 100); ASSERT_OK(db_chroot_env_->FileExists(prev_manifest_path)); ASSERT_OK(db_->Flush(FlushOptions())); ASSERT_TRUE(db_chroot_env_->FileExists(prev_manifest_path).IsNotFound()); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); AssertBackupConsistency(0, 0, 100); } // see https://github.com/facebook/rocksdb/issues/921 TEST_F(BackupableDBTest, Issue921Test) { BackupEngine* backup_engine; backupable_options_->share_table_files = false; backup_chroot_env_->CreateDirIfMissing(backupable_options_->backup_dir); backupable_options_->backup_dir += "/new_dir"; ASSERT_OK(BackupEngine::Open(backup_chroot_env_.get(), *backupable_options_, &backup_engine)); delete backup_engine; } TEST_F(BackupableDBTest, BackupWithMetadata) { const int keys_iteration = 5000; OpenDBAndBackupEngine(true); // create five backups for (int i = 0; i < 5; ++i) { const std::string metadata = std::to_string(i); FillDB(db_.get(), keys_iteration * i, keys_iteration * (i + 1)); ASSERT_OK( backup_engine_->CreateNewBackupWithMetadata(db_.get(), metadata, true)); } CloseDBAndBackupEngine(); OpenDBAndBackupEngine(); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(5, backup_infos.size()); for (int i = 0; i < 5; i++) { ASSERT_EQ(std::to_string(i), backup_infos[i].app_metadata); } CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); } TEST_F(BackupableDBTest, BinaryMetadata) { OpenDBAndBackupEngine(true); std::string binaryMetadata = "abc\ndef"; binaryMetadata.push_back('\0'); binaryMetadata.append("ghi"); ASSERT_OK( backup_engine_->CreateNewBackupWithMetadata(db_.get(), binaryMetadata)); CloseDBAndBackupEngine(); OpenDBAndBackupEngine(); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(1, backup_infos.size()); ASSERT_EQ(binaryMetadata, backup_infos[0].app_metadata); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); } TEST_F(BackupableDBTest, MetadataTooLarge) { OpenDBAndBackupEngine(true); std::string largeMetadata(1024 * 1024 + 1, 0); ASSERT_NOK( backup_engine_->CreateNewBackupWithMetadata(db_.get(), largeMetadata)); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); } TEST_F(BackupableDBTest, LimitBackupsOpened) { // Verify the specified max backups are opened, including skipping over // corrupted backups. // // Setup: // - backups 1, 2, and 4 are valid // - backup 3 is corrupt // - max_valid_backups_to_open == 2 // // Expectation: the engine opens backups 4 and 2 since those are latest two // non-corrupt backups. const int kNumKeys = 5000; OpenDBAndBackupEngine(true); for (int i = 1; i <= 4; ++i) { FillDB(db_.get(), kNumKeys * i, kNumKeys * (i + 1)); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); if (i == 3) { ASSERT_OK(file_manager_->CorruptFile(backupdir_ + "/meta/3", 3)); } } CloseDBAndBackupEngine(); backupable_options_->max_valid_backups_to_open = 2; OpenDBAndBackupEngine(); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(2, backup_infos.size()); ASSERT_EQ(2, backup_infos[0].backup_id); ASSERT_EQ(4, backup_infos[1].backup_id); CloseDBAndBackupEngine(); DestroyDB(dbname_, options_); } TEST_F(BackupableDBTest, CreateWhenLatestBackupCorrupted) { // we should pick an ID greater than corrupted backups' IDs so creation can // succeed even when latest backup is corrupted. const int kNumKeys = 5000; OpenDBAndBackupEngine(true /* destroy_old_data */); FillDB(db_.get(), 0 /* from */, kNumKeys); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true /* flush_before_backup */)); ASSERT_OK(file_manager_->CorruptFile(backupdir_ + "/meta/1", 3 /* bytes_to_corrupt */)); CloseDBAndBackupEngine(); OpenDBAndBackupEngine(); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true /* flush_before_backup */)); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(1, backup_infos.size()); ASSERT_EQ(2, backup_infos[0].backup_id); } TEST_F(BackupableDBTest, WriteOnlyEngine) { // Verify we can open a backup engine and create new ones even if reading old // backups would fail with IOError. IOError is a more serious condition than // corruption and would cause the engine to fail opening. So the only way to // avoid is by not reading old backups at all, i.e., respecting // `max_valid_backups_to_open == 0`. const int kNumKeys = 5000; OpenDBAndBackupEngine(true /* destroy_old_data */); FillDB(db_.get(), 0 /* from */, kNumKeys); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); CloseDBAndBackupEngine(); backupable_options_->max_valid_backups_to_open = 0; // cause any meta-file reads to fail with IOError during Open test_backup_env_->SetDummySequentialFile(true); test_backup_env_->SetDummySequentialFileFailReads(true); OpenDBAndBackupEngine(); test_backup_env_->SetDummySequentialFileFailReads(false); test_backup_env_->SetDummySequentialFile(false); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(1, backup_infos.size()); ASSERT_EQ(2, backup_infos[0].backup_id); } TEST_F(BackupableDBTest, WriteOnlyEngineNoSharedFileDeletion) { // Verifies a write-only BackupEngine does not delete files belonging to valid // backups when GarbageCollect, PurgeOldBackups, or DeleteBackup are called. const int kNumKeys = 5000; for (int i = 0; i < 3; ++i) { OpenDBAndBackupEngine(i == 0 /* destroy_old_data */); FillDB(db_.get(), i * kNumKeys, (i + 1) * kNumKeys); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), true)); CloseDBAndBackupEngine(); backupable_options_->max_valid_backups_to_open = 0; OpenDBAndBackupEngine(); switch (i) { case 0: ASSERT_OK(backup_engine_->GarbageCollect()); break; case 1: ASSERT_OK(backup_engine_->PurgeOldBackups(1 /* num_backups_to_keep */)); break; case 2: ASSERT_OK(backup_engine_->DeleteBackup(2 /* backup_id */)); break; default: assert(false); } CloseDBAndBackupEngine(); backupable_options_->max_valid_backups_to_open = port::kMaxInt32; AssertBackupConsistency(i + 1, 0, (i + 1) * kNumKeys); } } TEST_P(BackupableDBTestWithParam, BackupUsingDirectIO) { // Tests direct I/O on the backup engine's reads and writes on the DB env and // backup env // We use ChrootEnv underneath so the below line checks for direct I/O support // in the chroot directory, not the true filesystem root. if (!test::IsDirectIOSupported(test_db_env_.get(), "/")) { return; } const int kNumKeysPerBackup = 100; const int kNumBackups = 3; options_.use_direct_reads = true; OpenDBAndBackupEngine(true /* destroy_old_data */); for (int i = 0; i < kNumBackups; ++i) { FillDB(db_.get(), i * kNumKeysPerBackup /* from */, (i + 1) * kNumKeysPerBackup /* to */); ASSERT_OK(db_->Flush(FlushOptions())); // Clear the file open counters and then do a bunch of backup engine ops. // For all ops, files should be opened in direct mode. test_backup_env_->ClearFileOpenCounters(); test_db_env_->ClearFileOpenCounters(); CloseBackupEngine(); OpenBackupEngine(); ASSERT_OK(backup_engine_->CreateNewBackup(db_.get(), false /* flush_before_backup */)); ASSERT_OK(backup_engine_->VerifyBackup(i + 1)); CloseBackupEngine(); OpenBackupEngine(); std::vector backup_infos; backup_engine_->GetBackupInfo(&backup_infos); ASSERT_EQ(static_cast(i + 1), backup_infos.size()); // Verify backup engine always opened files with direct I/O ASSERT_EQ(0, test_db_env_->num_writers()); ASSERT_EQ(0, test_db_env_->num_rand_readers()); ASSERT_GT(test_db_env_->num_direct_seq_readers(), 0); // Currently the DB doesn't support reading WALs or manifest with direct // I/O, so subtract two. ASSERT_EQ(test_db_env_->num_seq_readers() - 2, test_db_env_->num_direct_seq_readers()); ASSERT_EQ(0, test_db_env_->num_rand_readers()); } CloseDBAndBackupEngine(); for (int i = 0; i < kNumBackups; ++i) { AssertBackupConsistency(i + 1 /* backup_id */, i * kNumKeysPerBackup /* start_exist */, (i + 1) * kNumKeysPerBackup /* end_exist */, (i + 2) * kNumKeysPerBackup /* end */); } } } // anon namespace } // namespace rocksdb int main(int argc, char** argv) { rocksdb::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); } #else #include int main(int /*argc*/, char** /*argv*/) { fprintf(stderr, "SKIPPED as BackupableDB is not supported in ROCKSDB_LITE\n"); return 0; } #endif // !defined(ROCKSDB_LITE) && !defined(OS_WIN)