// 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. #include "rocksdb/options.h" #ifndef ROCKSDB_LITE #include #include #include #include #include "db/db_impl/db_impl.h" #include "db/db_test_util.h" #include "db/log_format.h" #include "db/version_set.h" #include "file/filename.h" #include "port/stack_trace.h" #include "rocksdb/cache.h" #include "rocksdb/convenience.h" #include "rocksdb/db.h" #include "rocksdb/env.h" #include "rocksdb/table.h" #include "rocksdb/utilities/transaction_db.h" #include "rocksdb/write_batch.h" #include "table/block_based/block_based_table_builder.h" #include "table/meta_blocks.h" #include "table/mock_table.h" #include "test_util/testharness.h" #include "test_util/testutil.h" #include "util/cast_util.h" #include "util/random.h" #include "util/string_util.h" namespace ROCKSDB_NAMESPACE { static constexpr int kValueSize = 1000; namespace { // A wrapper that allows injection of errors. class ErrorEnv : public EnvWrapper { public: bool writable_file_error_; int num_writable_file_errors_; explicit ErrorEnv(Env* _target) : EnvWrapper(_target), writable_file_error_(false), num_writable_file_errors_(0) {} const char* Name() const override { return "ErrorEnv"; } virtual Status NewWritableFile(const std::string& fname, std::unique_ptr* result, const EnvOptions& soptions) override { result->reset(); if (writable_file_error_) { ++num_writable_file_errors_; return Status::IOError(fname, "fake error"); } return target()->NewWritableFile(fname, result, soptions); } }; } // namespace class CorruptionTest : public testing::Test { public: std::shared_ptr env_guard_; ErrorEnv* env_; std::string dbname_; std::shared_ptr tiny_cache_; Options options_; DB* db_; CorruptionTest() { // If LRU cache shard bit is smaller than 2 (or -1 which will automatically // set it to 0), test SequenceNumberRecovery will fail, likely because of a // bug in recovery code. Keep it 4 for now to make the test passes. tiny_cache_ = NewLRUCache(100, 4); Env* base_env = Env::Default(); EXPECT_OK( test::CreateEnvFromSystem(ConfigOptions(), &base_env, &env_guard_)); EXPECT_NE(base_env, nullptr); env_ = new ErrorEnv(base_env); options_.wal_recovery_mode = WALRecoveryMode::kTolerateCorruptedTailRecords; options_.env = env_; dbname_ = test::PerThreadDBPath(env_, "corruption_test"); Status s = DestroyDB(dbname_, options_); EXPECT_OK(s); db_ = nullptr; options_.create_if_missing = true; BlockBasedTableOptions table_options; table_options.block_size_deviation = 0; // make unit test pass for now options_.table_factory.reset(NewBlockBasedTableFactory(table_options)); Reopen(); options_.create_if_missing = false; } ~CorruptionTest() override { SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->LoadDependency({}); SyncPoint::GetInstance()->ClearAllCallBacks(); delete db_; db_ = nullptr; if (getenv("KEEP_DB")) { fprintf(stdout, "db is still at %s\n", dbname_.c_str()); } else { Options opts; opts.env = env_->target(); EXPECT_OK(DestroyDB(dbname_, opts)); } delete env_; } void CloseDb() { delete db_; db_ = nullptr; } Status TryReopen(Options* options = nullptr) { delete db_; db_ = nullptr; Options opt = (options ? *options : options_); if (opt.env == Options().env) { // If env is not overridden, replace it with ErrorEnv. // Otherwise, the test already uses a non-default Env. opt.env = env_; } opt.arena_block_size = 4096; BlockBasedTableOptions table_options; table_options.block_cache = tiny_cache_; table_options.block_size_deviation = 0; opt.table_factory.reset(NewBlockBasedTableFactory(table_options)); return DB::Open(opt, dbname_, &db_); } void Reopen(Options* options = nullptr) { ASSERT_OK(TryReopen(options)); } void RepairDB() { delete db_; db_ = nullptr; ASSERT_OK(::ROCKSDB_NAMESPACE::RepairDB(dbname_, options_)); } void Build(int n, int start, int flush_every) { std::string key_space, value_space; WriteBatch batch; for (int i = 0; i < n; i++) { if (flush_every != 0 && i != 0 && i % flush_every == 0) { DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); } //if ((i % 100) == 0) fprintf(stderr, "@ %d of %d\n", i, n); Slice key = Key(i + start, &key_space); batch.Clear(); ASSERT_OK(batch.Put(key, Value(i + start, &value_space))); ASSERT_OK(db_->Write(WriteOptions(), &batch)); } } void Build(int n, int flush_every = 0) { Build(n, 0, flush_every); } void Check(int min_expected, int max_expected) { uint64_t next_expected = 0; uint64_t missed = 0; int bad_keys = 0; int bad_values = 0; int correct = 0; std::string value_space; // Do not verify checksums. If we verify checksums then the // db itself will raise errors because data is corrupted. // Instead, we want the reads to be successful and this test // will detect whether the appropriate corruptions have // occurred. Iterator* iter = db_->NewIterator(ReadOptions(false, true)); for (iter->SeekToFirst(); iter->Valid(); iter->Next()) { ASSERT_OK(iter->status()); uint64_t key; Slice in(iter->key()); if (!ConsumeDecimalNumber(&in, &key) || !in.empty() || key < next_expected) { bad_keys++; continue; } missed += (key - next_expected); next_expected = key + 1; if (iter->value() != Value(static_cast(key), &value_space)) { bad_values++; } else { correct++; } } iter->status().PermitUncheckedError(); delete iter; fprintf(stderr, "expected=%d..%d; got=%d; bad_keys=%d; bad_values=%d; missed=%llu\n", min_expected, max_expected, correct, bad_keys, bad_values, static_cast(missed)); ASSERT_LE(min_expected, correct); ASSERT_GE(max_expected, correct); } void Corrupt(FileType filetype, int offset, int bytes_to_corrupt) { // Pick file to corrupt std::vector filenames; ASSERT_OK(env_->GetChildren(dbname_, &filenames)); uint64_t number; FileType type; std::string fname; int picked_number = -1; for (size_t i = 0; i < filenames.size(); i++) { if (ParseFileName(filenames[i], &number, &type) && type == filetype && static_cast(number) > picked_number) { // Pick latest file fname = dbname_ + "/" + filenames[i]; picked_number = static_cast(number); } } ASSERT_TRUE(!fname.empty()) << filetype; ASSERT_OK(test::CorruptFile(env_, fname, offset, bytes_to_corrupt)); } // corrupts exactly one file at level `level`. if no file found at level, // asserts void CorruptTableFileAtLevel(int level, int offset, int bytes_to_corrupt) { std::vector metadata; db_->GetLiveFilesMetaData(&metadata); for (const auto& m : metadata) { if (m.level == level) { ASSERT_OK(test::CorruptFile(env_, dbname_ + "/" + m.name, offset, bytes_to_corrupt)); return; } } FAIL() << "no file found at level"; } int Property(const std::string& name) { std::string property; int result; if (db_->GetProperty(name, &property) && sscanf(property.c_str(), "%d", &result) == 1) { return result; } else { return -1; } } // Return the ith key Slice Key(int i, std::string* storage) { char buf[100]; snprintf(buf, sizeof(buf), "%016d", i); storage->assign(buf, strlen(buf)); return Slice(*storage); } // Return the value to associate with the specified key Slice Value(int k, std::string* storage) { if (k == 0) { // Ugh. Random seed of 0 used to produce no entropy. This code // preserves the implementation that was in place when all of the // magic values in this file were picked. *storage = std::string(kValueSize, ' '); } else { Random r(k); *storage = r.RandomString(kValueSize); } return Slice(*storage); } void GetSortedWalFiles(std::vector& file_nums) { std::vector tmp_files; ASSERT_OK(env_->GetChildren(dbname_, &tmp_files)); FileType type = kWalFile; for (const auto& file : tmp_files) { uint64_t number = 0; if (ParseFileName(file, &number, &type) && type == kWalFile) { file_nums.push_back(number); } } std::sort(file_nums.begin(), file_nums.end()); } void CorruptFileWithTruncation(FileType file, uint64_t number, uint64_t bytes_to_truncate = 0) { std::string path; switch (file) { case FileType::kWalFile: path = LogFileName(dbname_, number); break; // TODO: Add other file types as this method is being used for those file // types. default: return; } uint64_t old_size = 0; ASSERT_OK(env_->GetFileSize(path, &old_size)); assert(old_size > bytes_to_truncate); uint64_t new_size = old_size - bytes_to_truncate; // If bytes_to_truncate == 0, it will do full truncation. if (bytes_to_truncate == 0) { new_size = 0; } ASSERT_OK(test::TruncateFile(env_, path, new_size)); } }; TEST_F(CorruptionTest, Recovery) { Build(100); Check(100, 100); #ifdef OS_WIN // On Wndows OS Disk cache does not behave properly // We do not call FlushBuffers on every Flush. If we do not close // the log file prior to the corruption we end up with the first // block not corrupted but only the second. However, under the debugger // things work just fine but never pass when running normally // For that reason people may want to run with unbuffered I/O. That option // is not available for WAL though. CloseDb(); #endif Corrupt(kWalFile, 19, 1); // WriteBatch tag for first record Corrupt(kWalFile, log::kBlockSize + 1000, 1); // Somewhere in second block ASSERT_TRUE(!TryReopen().ok()); options_.paranoid_checks = false; Reopen(&options_); // The 64 records in the first two log blocks are completely lost. Check(36, 36); } TEST_F(CorruptionTest, PostPITRCorruptionWALsRetained) { // Repro for bug where WALs following the point-in-time recovery were not // retained leading to the next recovery failing. CloseDb(); options_.wal_recovery_mode = WALRecoveryMode::kPointInTimeRecovery; const std::string test_cf_name = "test_cf"; std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); cf_descs.emplace_back(test_cf_name, ColumnFamilyOptions()); uint64_t log_num; { options_.create_missing_column_families = true; std::vector cfhs; ASSERT_OK(DB::Open(options_, dbname_, cf_descs, &cfhs, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report ASSERT_OK(db_->Put(WriteOptions(), cfhs[0], "k", "v")); ASSERT_OK(db_->Put(WriteOptions(), cfhs[1], "k", "v")); ASSERT_OK(db_->Put(WriteOptions(), cfhs[0], "k2", "v2")); std::vector file_nums; GetSortedWalFiles(file_nums); log_num = file_nums.back(); for (auto* cfh : cfhs) { delete cfh; } CloseDb(); } CorruptFileWithTruncation(FileType::kWalFile, log_num, /*bytes_to_truncate=*/1); { // Recover "k" -> "v" for both CFs. "k2" -> "v2" is lost due to truncation. options_.avoid_flush_during_recovery = true; std::vector cfhs; ASSERT_OK(DB::Open(options_, dbname_, cf_descs, &cfhs, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report // Flush one but not both CFs and write some data so there's a seqno gap // between the PITR corruption and the next DB session's first WAL. ASSERT_OK(db_->Put(WriteOptions(), cfhs[1], "k2", "v2")); ASSERT_OK(db_->Flush(FlushOptions(), cfhs[1])); for (auto* cfh : cfhs) { delete cfh; } CloseDb(); } // With the bug, this DB open would remove the WALs following the PITR // corruption. Then, the next recovery would fail. for (int i = 0; i < 2; ++i) { std::vector cfhs; ASSERT_OK(DB::Open(options_, dbname_, cf_descs, &cfhs, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report for (auto* cfh : cfhs) { delete cfh; } CloseDb(); } } TEST_F(CorruptionTest, RecoverWriteError) { env_->writable_file_error_ = true; Status s = TryReopen(); ASSERT_TRUE(!s.ok()); } TEST_F(CorruptionTest, NewFileErrorDuringWrite) { // Do enough writing to force minor compaction env_->writable_file_error_ = true; const int num = static_cast(3 + (Options().write_buffer_size / kValueSize)); std::string value_storage; Status s; bool failed = false; for (int i = 0; i < num; i++) { WriteBatch batch; ASSERT_OK(batch.Put("a", Value(100, &value_storage))); s = db_->Write(WriteOptions(), &batch); if (!s.ok()) { failed = true; } ASSERT_TRUE(!failed || !s.ok()); } ASSERT_TRUE(!s.ok()); ASSERT_GE(env_->num_writable_file_errors_, 1); env_->writable_file_error_ = false; Reopen(); } TEST_F(CorruptionTest, TableFile) { Build(100); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(dbi->TEST_CompactRange(0, nullptr, nullptr)); ASSERT_OK(dbi->TEST_CompactRange(1, nullptr, nullptr)); Corrupt(kTableFile, 100, 1); Check(99, 99); ASSERT_NOK(dbi->VerifyChecksum()); } TEST_F(CorruptionTest, VerifyChecksumReadahead) { Options options; SpecialEnv senv(env_->target()); options.env = &senv; // Disable block cache as we are going to check checksum for // the same file twice and measure number of reads. BlockBasedTableOptions table_options_no_bc; table_options_no_bc.no_block_cache = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options_no_bc)); Reopen(&options); Build(10000); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(dbi->TEST_CompactRange(0, nullptr, nullptr)); ASSERT_OK(dbi->TEST_CompactRange(1, nullptr, nullptr)); senv.count_random_reads_ = true; senv.random_read_counter_.Reset(); ASSERT_OK(dbi->VerifyChecksum()); // Make sure the counter is enabled. ASSERT_GT(senv.random_read_counter_.Read(), 0); // The SST file is about 10MB. Default readahead size is 256KB. // Give a conservative 20 reads for metadata blocks, The number // of random reads should be within 10 MB / 256KB + 20 = 60. ASSERT_LT(senv.random_read_counter_.Read(), 60); senv.random_read_bytes_counter_ = 0; ReadOptions ro; ro.readahead_size = size_t{32 * 1024}; ASSERT_OK(dbi->VerifyChecksum(ro)); // The SST file is about 10MB. We set readahead size to 32KB. // Give 0 to 20 reads for metadata blocks, and allow real read // to range from 24KB to 48KB. The lower bound would be: // 10MB / 48KB + 0 = 213 // The higher bound is // 10MB / 24KB + 20 = 447. ASSERT_GE(senv.random_read_counter_.Read(), 213); ASSERT_LE(senv.random_read_counter_.Read(), 447); // Test readahead shouldn't break mmap mode (where it should be // disabled). options.allow_mmap_reads = true; Reopen(&options); dbi = static_cast(db_); ASSERT_OK(dbi->VerifyChecksum(ro)); CloseDb(); } TEST_F(CorruptionTest, TableFileIndexData) { Options options; // very big, we'll trigger flushes manually options.write_buffer_size = 100 * 1024 * 1024; Reopen(&options); // build 2 tables, flush at 5000 Build(10000, 5000); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); // corrupt an index block of an entire file Corrupt(kTableFile, -2000, 500); options.paranoid_checks = false; Reopen(&options); dbi = static_cast_with_check(db_); // one full file may be readable, since only one was corrupted // the other file should be fully non-readable, since index was corrupted Check(0, 5000); ASSERT_NOK(dbi->VerifyChecksum()); // In paranoid mode, the db cannot be opened due to the corrupted file. ASSERT_TRUE(TryReopen().IsCorruption()); } TEST_F(CorruptionTest, MissingDescriptor) { Build(1000); RepairDB(); Reopen(); Check(1000, 1000); } TEST_F(CorruptionTest, SequenceNumberRecovery) { ASSERT_OK(db_->Put(WriteOptions(), "foo", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo", "v2")); ASSERT_OK(db_->Put(WriteOptions(), "foo", "v3")); ASSERT_OK(db_->Put(WriteOptions(), "foo", "v4")); ASSERT_OK(db_->Put(WriteOptions(), "foo", "v5")); RepairDB(); Reopen(); std::string v; ASSERT_OK(db_->Get(ReadOptions(), "foo", &v)); ASSERT_EQ("v5", v); // Write something. If sequence number was not recovered properly, // it will be hidden by an earlier write. ASSERT_OK(db_->Put(WriteOptions(), "foo", "v6")); ASSERT_OK(db_->Get(ReadOptions(), "foo", &v)); ASSERT_EQ("v6", v); Reopen(); ASSERT_OK(db_->Get(ReadOptions(), "foo", &v)); ASSERT_EQ("v6", v); } TEST_F(CorruptionTest, CorruptedDescriptor) { ASSERT_OK(db_->Put(WriteOptions(), "foo", "hello")); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); Corrupt(kDescriptorFile, 0, 1000); Status s = TryReopen(); ASSERT_TRUE(!s.ok()); RepairDB(); Reopen(); std::string v; ASSERT_OK(db_->Get(ReadOptions(), "foo", &v)); ASSERT_EQ("hello", v); } TEST_F(CorruptionTest, CompactionInputError) { Options options; options.env = env_; Reopen(&options); Build(10); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(dbi->TEST_CompactRange(0, nullptr, nullptr)); ASSERT_OK(dbi->TEST_CompactRange(1, nullptr, nullptr)); ASSERT_EQ(1, Property("rocksdb.num-files-at-level2")); Corrupt(kTableFile, 100, 1); Check(9, 9); ASSERT_NOK(dbi->VerifyChecksum()); // Force compactions by writing lots of values Build(10000); Check(10000, 10000); ASSERT_NOK(dbi->VerifyChecksum()); } TEST_F(CorruptionTest, CompactionInputErrorParanoid) { Options options; options.env = env_; options.paranoid_checks = true; options.write_buffer_size = 131072; options.max_write_buffer_number = 2; Reopen(&options); DBImpl* dbi = static_cast_with_check(db_); // Fill levels >= 1 for (int level = 1; level < dbi->NumberLevels(); level++) { ASSERT_OK(dbi->Put(WriteOptions(), "", "begin")); ASSERT_OK(dbi->Put(WriteOptions(), "~", "end")); ASSERT_OK(dbi->TEST_FlushMemTable()); for (int comp_level = 0; comp_level < dbi->NumberLevels() - level; ++comp_level) { ASSERT_OK(dbi->TEST_CompactRange(comp_level, nullptr, nullptr)); } } Reopen(&options); dbi = static_cast_with_check(db_); Build(10); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(dbi->TEST_WaitForCompact()); ASSERT_EQ(1, Property("rocksdb.num-files-at-level0")); CorruptTableFileAtLevel(0, 100, 1); Check(9, 9); ASSERT_NOK(dbi->VerifyChecksum()); // Write must eventually fail because of corrupted table Status s; std::string tmp1, tmp2; bool failed = false; for (int i = 0; i < 10000; i++) { s = db_->Put(WriteOptions(), Key(i, &tmp1), Value(i, &tmp2)); if (!s.ok()) { failed = true; } // if one write failed, every subsequent write must fail, too ASSERT_TRUE(!failed || !s.ok()) << "write did not fail in a corrupted db"; } ASSERT_TRUE(!s.ok()) << "write did not fail in corrupted paranoid db"; } TEST_F(CorruptionTest, UnrelatedKeys) { Build(10); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); Corrupt(kTableFile, 100, 1); ASSERT_NOK(dbi->VerifyChecksum()); std::string tmp1, tmp2; ASSERT_OK(db_->Put(WriteOptions(), Key(1000, &tmp1), Value(1000, &tmp2))); std::string v; ASSERT_OK(db_->Get(ReadOptions(), Key(1000, &tmp1), &v)); ASSERT_EQ(Value(1000, &tmp2).ToString(), v); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(db_->Get(ReadOptions(), Key(1000, &tmp1), &v)); ASSERT_EQ(Value(1000, &tmp2).ToString(), v); } TEST_F(CorruptionTest, RangeDeletionCorrupted) { ASSERT_OK( db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), "a", "b")); ASSERT_OK(db_->Flush(FlushOptions())); std::vector metadata; db_->GetLiveFilesMetaData(&metadata); ASSERT_EQ(static_cast(1), metadata.size()); std::string filename = dbname_ + metadata[0].name; FileOptions file_opts; const auto& fs = options_.env->GetFileSystem(); std::unique_ptr file_reader; ASSERT_OK(RandomAccessFileReader::Create(fs, filename, file_opts, &file_reader, nullptr)); uint64_t file_size; ASSERT_OK( fs->GetFileSize(filename, file_opts.io_options, &file_size, nullptr)); BlockHandle range_del_handle; ASSERT_OK(FindMetaBlockInFile( file_reader.get(), file_size, kBlockBasedTableMagicNumber, ImmutableOptions(options_), kRangeDelBlockName, &range_del_handle)); ASSERT_OK(TryReopen()); ASSERT_OK(test::CorruptFile(env_, filename, static_cast(range_del_handle.offset()), 1)); ASSERT_TRUE(TryReopen().IsCorruption()); } TEST_F(CorruptionTest, FileSystemStateCorrupted) { for (int iter = 0; iter < 2; ++iter) { Options options; options.env = env_; options.paranoid_checks = true; options.create_if_missing = true; Reopen(&options); Build(10); ASSERT_OK(db_->Flush(FlushOptions())); DBImpl* dbi = static_cast_with_check(db_); std::vector metadata; dbi->GetLiveFilesMetaData(&metadata); ASSERT_GT(metadata.size(), 0); std::string filename = dbname_ + metadata[0].name; delete db_; db_ = nullptr; if (iter == 0) { // corrupt file size std::unique_ptr file; ASSERT_OK(env_->NewWritableFile(filename, &file, EnvOptions())); ASSERT_OK(file->Append(Slice("corrupted sst"))); file.reset(); Status x = TryReopen(&options); ASSERT_TRUE(x.IsCorruption()); } else { // delete the file ASSERT_OK(env_->DeleteFile(filename)); Status x = TryReopen(&options); ASSERT_TRUE(x.IsCorruption()); } ASSERT_OK(DestroyDB(dbname_, options_)); } } static const auto& corruption_modes = { mock::MockTableFactory::kCorruptNone, mock::MockTableFactory::kCorruptKey, mock::MockTableFactory::kCorruptValue, mock::MockTableFactory::kCorruptReorderKey}; TEST_F(CorruptionTest, ParanoidFileChecksOnFlush) { Options options; options.env = env_; options.check_flush_compaction_key_order = false; options.paranoid_file_checks = true; options.create_if_missing = true; Status s; for (const auto& mode : corruption_modes) { delete db_; db_ = nullptr; s = DestroyDB(dbname_, options); ASSERT_OK(s); std::shared_ptr mock = std::make_shared(); options.table_factory = mock; mock->SetCorruptionMode(mode); ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report Build(10); s = db_->Flush(FlushOptions()); if (mode == mock::MockTableFactory::kCorruptNone) { ASSERT_OK(s); } else { ASSERT_NOK(s); } } } TEST_F(CorruptionTest, ParanoidFileChecksOnCompact) { Options options; options.env = env_; options.paranoid_file_checks = true; options.create_if_missing = true; options.check_flush_compaction_key_order = false; Status s; for (const auto& mode : corruption_modes) { delete db_; db_ = nullptr; s = DestroyDB(dbname_, options); ASSERT_OK(s); std::shared_ptr mock = std::make_shared(); options.table_factory = mock; ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report Build(100, 2); // ASSERT_OK(db_->Flush(FlushOptions())); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); mock->SetCorruptionMode(mode); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; s = dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr); if (mode == mock::MockTableFactory::kCorruptNone) { ASSERT_OK(s); } else { ASSERT_NOK(s); } } } TEST_F(CorruptionTest, ParanoidFileChecksWithDeleteRangeFirst) { Options options; options.env = env_; options.check_flush_compaction_key_order = false; options.paranoid_file_checks = true; options.create_if_missing = true; for (bool do_flush : {true, false}) { delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, options)); ASSERT_OK(DB::Open(options, dbname_, &db_)); std::string start, end; assert(db_ != nullptr); // suppress false clang-analyze report ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(3, &start), Key(7, &end))); auto snap = db_->GetSnapshot(); ASSERT_NE(snap, nullptr); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(8, &start), Key(9, &end))); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(2, &start), Key(5, &end))); Build(10); if (do_flush) { ASSERT_OK(db_->Flush(FlushOptions())); } else { DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); } db_->ReleaseSnapshot(snap); } } TEST_F(CorruptionTest, ParanoidFileChecksWithDeleteRange) { Options options; options.env = env_; options.check_flush_compaction_key_order = false; options.paranoid_file_checks = true; options.create_if_missing = true; for (bool do_flush : {true, false}) { delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, options)); ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report Build(10, 0, 0); std::string start, end; ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(5, &start), Key(15, &end))); auto snap = db_->GetSnapshot(); ASSERT_NE(snap, nullptr); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(8, &start), Key(9, &end))); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(12, &start), Key(17, &end))); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(2, &start), Key(4, &end))); Build(10, 10, 0); if (do_flush) { ASSERT_OK(db_->Flush(FlushOptions())); } else { DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); } db_->ReleaseSnapshot(snap); } } TEST_F(CorruptionTest, ParanoidFileChecksWithDeleteRangeLast) { Options options; options.env = env_; options.check_flush_compaction_key_order = false; options.paranoid_file_checks = true; options.create_if_missing = true; for (bool do_flush : {true, false}) { delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, options)); ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report std::string start, end; Build(10); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(3, &start), Key(7, &end))); auto snap = db_->GetSnapshot(); ASSERT_NE(snap, nullptr); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(6, &start), Key(8, &end))); ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), Key(2, &start), Key(5, &end))); if (do_flush) { ASSERT_OK(db_->Flush(FlushOptions())); } else { DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); } db_->ReleaseSnapshot(snap); } } TEST_F(CorruptionTest, LogCorruptionErrorsInCompactionIterator) { Options options; options.env = env_; options.create_if_missing = true; options.allow_data_in_errors = true; auto mode = mock::MockTableFactory::kCorruptKey; delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, options)); std::shared_ptr mock = std::make_shared(); mock->SetCorruptionMode(mode); options.table_factory = mock; ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report Build(100, 2); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; Status s = dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr); ASSERT_NOK(s); ASSERT_TRUE(s.IsCorruption()); } TEST_F(CorruptionTest, CompactionKeyOrderCheck) { Options options; options.env = env_; options.paranoid_file_checks = false; options.create_if_missing = true; options.check_flush_compaction_key_order = false; delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, options)); std::shared_ptr mock = std::make_shared(); options.table_factory = mock; ASSERT_OK(DB::Open(options, dbname_, &db_)); assert(db_ != nullptr); // suppress false clang-analyze report mock->SetCorruptionMode(mock::MockTableFactory::kCorruptReorderKey); Build(100, 2); DBImpl* dbi = static_cast_with_check(db_); ASSERT_OK(dbi->TEST_FlushMemTable()); mock->SetCorruptionMode(mock::MockTableFactory::kCorruptNone); ASSERT_OK(db_->SetOptions({{"check_flush_compaction_key_order", "true"}})); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_NOK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); } TEST_F(CorruptionTest, FlushKeyOrderCheck) { Options options; options.env = env_; options.paranoid_file_checks = false; options.create_if_missing = true; ASSERT_OK(db_->SetOptions({{"check_flush_compaction_key_order", "true"}})); ASSERT_OK(db_->Put(WriteOptions(), "foo1", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo2", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo3", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo4", "v1")); int cnt = 0; // Generate some out of order keys from the memtable SyncPoint::GetInstance()->SetCallBack( "MemTableIterator::Next:0", [&](void* arg) { MemTableRep::Iterator* mem_iter = static_cast(arg); if (++cnt == 3) { mem_iter->Prev(); mem_iter->Prev(); } }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); Status s = static_cast_with_check(db_)->TEST_FlushMemTable(); ASSERT_NOK(s); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); } TEST_F(CorruptionTest, DisableKeyOrderCheck) { ASSERT_OK(db_->SetOptions({{"check_flush_compaction_key_order", "false"}})); DBImpl* dbi = static_cast_with_check(db_); SyncPoint::GetInstance()->SetCallBack( "OutputValidator::Add:order_check", [&](void* /*arg*/) { ASSERT_TRUE(false); }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); ASSERT_OK(db_->Put(WriteOptions(), "foo1", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo3", "v1")); ASSERT_OK(dbi->TEST_FlushMemTable()); ASSERT_OK(db_->Put(WriteOptions(), "foo2", "v1")); ASSERT_OK(db_->Put(WriteOptions(), "foo4", "v1")); ASSERT_OK(dbi->TEST_FlushMemTable()); CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK( dbi->CompactRange(cro, dbi->DefaultColumnFamily(), nullptr, nullptr)); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); } TEST_F(CorruptionTest, VerifyWholeTableChecksum) { CloseDb(); Options options; options.env = env_; ASSERT_OK(DestroyDB(dbname_, options)); options.create_if_missing = true; options.file_checksum_gen_factory = ROCKSDB_NAMESPACE::GetFileChecksumGenCrc32cFactory(); Reopen(&options); Build(10, 5); ASSERT_OK(db_->VerifyFileChecksums(ReadOptions())); CloseDb(); // Corrupt the first byte of each table file, this must be data block. Corrupt(kTableFile, 0, 1); ASSERT_OK(TryReopen(&options)); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); int count{0}; SyncPoint::GetInstance()->SetCallBack( "DBImpl::VerifyFullFileChecksum:mismatch", [&](void* arg) { auto* s = reinterpret_cast(arg); ASSERT_NE(s, nullptr); ++count; ASSERT_NOK(*s); }); SyncPoint::GetInstance()->EnableProcessing(); ASSERT_TRUE(db_->VerifyFileChecksums(ReadOptions()).IsCorruption()); ASSERT_EQ(1, count); } class CrashDuringRecoveryWithCorruptionTest : public CorruptionTest, public testing::WithParamInterface> { public: explicit CrashDuringRecoveryWithCorruptionTest() : CorruptionTest(), avoid_flush_during_recovery_(std::get<0>(GetParam())), track_and_verify_wals_in_manifest_(std::get<1>(GetParam())) {} protected: const bool avoid_flush_during_recovery_; const bool track_and_verify_wals_in_manifest_; }; INSTANTIATE_TEST_CASE_P(CorruptionTest, CrashDuringRecoveryWithCorruptionTest, ::testing::Values(std::make_tuple(true, false), std::make_tuple(false, false), std::make_tuple(true, true), std::make_tuple(false, true))); // In case of non-TransactionDB with avoid_flush_during_recovery = true, RocksDB // won't flush the data from WAL to L0 for all column families if possible. As a // result, not all column families can increase their log_numbers, and // min_log_number_to_keep won't change. // It may prematurely persist a new MANIFEST even before we can declare the DB // is in consistent state after recovery (this is when the new WAL is synced) // and advances log_numbers for some column families. // // If there is power failure before we sync the new WAL, we will end up in // a situation in which after persisting the MANIFEST, RocksDB will see some // column families' log_numbers larger than the corrupted wal, and // "Column family inconsistency: SST file contains data beyond the point of // corruption" error will be hit, causing recovery to fail. // // After adding the fix, only after new WAL is synced, RocksDB persist a new // MANIFEST with column families to ensure RocksDB is in consistent state. // RocksDB writes an empty WriteBatch as a sentinel to the new WAL which is // synced immediately afterwards. The sequence number of the sentinel // WriteBatch will be the next sequence number immediately after the largest // sequence number recovered from previous WALs and MANIFEST because of which DB // will be in consistent state. // If a future recovery starts from the new MANIFEST, then it means the new WAL // is successfully synced. Due to the sentinel empty write batch at the // beginning, kPointInTimeRecovery of WAL is guaranteed to go after this point. // If future recovery starts from the old MANIFEST, it means the writing the new // MANIFEST failed. It won't have the "SST ahead of WAL" error. // // The combination of corrupting a WAL and injecting an error during subsequent // re-open exposes the bug of prematurely persisting a new MANIFEST with // advanced ColumnFamilyData::log_number. TEST_P(CrashDuringRecoveryWithCorruptionTest, CrashDuringRecovery) { CloseDb(); Options options; options.track_and_verify_wals_in_manifest = track_and_verify_wals_in_manifest_; options.wal_recovery_mode = WALRecoveryMode::kPointInTimeRecovery; options.avoid_flush_during_recovery = false; options.env = env_; ASSERT_OK(DestroyDB(dbname_, options)); options.create_if_missing = true; options.max_write_buffer_number = 8; Reopen(&options); Status s; const std::string test_cf_name = "test_cf"; ColumnFamilyHandle* cfh = nullptr; s = db_->CreateColumnFamily(options, test_cf_name, &cfh); ASSERT_OK(s); delete cfh; CloseDb(); std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, options); cf_descs.emplace_back(test_cf_name, options); std::vector handles; // 1. Open and populate the DB. Write and flush default_cf several times to // advance wal number so that some column families have advanced log_number // while other don't. { ASSERT_OK(DB::Open(options, dbname_, cf_descs, &handles, &db_)); auto* dbimpl = static_cast_with_check(db_); assert(dbimpl); // Write one key to test_cf. ASSERT_OK(db_->Put(WriteOptions(), handles[1], "old_key", "dontcare")); ASSERT_OK(db_->Flush(FlushOptions(), handles[1])); // Write to default_cf and flush this cf several times to advance wal // number. TEST_SwitchMemtable makes sure WALs are not synced and test can // corrupt un-sync WAL. for (int i = 0; i < 2; ++i) { ASSERT_OK(db_->Put(WriteOptions(), "key" + std::to_string(i), "value" + std::to_string(i))); ASSERT_OK(dbimpl->TEST_SwitchMemtable()); } for (auto* h : handles) { delete h; } handles.clear(); CloseDb(); } // 2. Corrupt second last un-syned wal file to emulate power reset which // caused the DB to lose the un-synced WAL. { std::vector file_nums; GetSortedWalFiles(file_nums); size_t size = file_nums.size(); assert(size >= 2); uint64_t log_num = file_nums[size - 2]; CorruptFileWithTruncation(FileType::kWalFile, log_num, /*bytes_to_truncate=*/8); } // 3. After first crash reopen the DB which contains corrupted WAL. Default // family has higher log number than corrupted wal number. // // Case1: If avoid_flush_during_recovery = true, RocksDB won't flush the data // from WAL to L0 for all column families (test_cf_name in this case). As a // result, not all column families can increase their log_numbers, and // min_log_number_to_keep won't change. // // Case2: If avoid_flush_during_recovery = false, all column families have // flushed their data from WAL to L0 during recovery, and none of them will // ever need to read the WALs again. // 4. Fault is injected to fail the recovery. { SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); SyncPoint::GetInstance()->SetCallBack( "DBImpl::GetLogSizeAndMaybeTruncate:0", [&](void* arg) { auto* tmp_s = reinterpret_cast(arg); assert(tmp_s); *tmp_s = Status::IOError("Injected"); }); SyncPoint::GetInstance()->EnableProcessing(); handles.clear(); options.avoid_flush_during_recovery = true; s = DB::Open(options, dbname_, cf_descs, &handles, &db_); ASSERT_TRUE(s.IsIOError()); ASSERT_EQ("IO error: Injected", s.ToString()); for (auto* h : handles) { delete h; } CloseDb(); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); } // 5. After second crash reopen the db with second corruption. Default family // has higher log number than corrupted wal number. // // Case1: If avoid_flush_during_recovery = true, we persist a new // MANIFEST with advanced log_numbers for some column families only after // syncing the WAL. So during second crash, RocksDB will skip the corrupted // WAL files as they have been moved to different folder. Since newly synced // WAL file's sequence number (sentinel WriteBatch) will be the next // sequence number immediately after the largest sequence number recovered // from previous WALs and MANIFEST, db will be in consistent state and opens // successfully. // // Case2: If avoid_flush_during_recovery = false, the corrupted WAL is below // this number. So during a second crash after persisting the new MANIFEST, // RocksDB will skip the corrupted WAL(s) because they are all below this // bound. Therefore, we won't hit the "column family inconsistency" error // message. { options.avoid_flush_during_recovery = avoid_flush_during_recovery_; ASSERT_OK(DB::Open(options, dbname_, cf_descs, &handles, &db_)); // Verify that data is not lost. { std::string v; ASSERT_OK(db_->Get(ReadOptions(), handles[1], "old_key", &v)); ASSERT_EQ("dontcare", v); v.clear(); ASSERT_OK(db_->Get(ReadOptions(), "key" + std::to_string(0), &v)); ASSERT_EQ("value" + std::to_string(0), v); // Since it's corrupting second last wal, below key is not found. v.clear(); ASSERT_EQ(db_->Get(ReadOptions(), "key" + std::to_string(1), &v), Status::NotFound()); } for (auto* h : handles) { delete h; } handles.clear(); CloseDb(); } } // In case of TransactionDB, it enables two-phase-commit. The prepare section of // an uncommitted transaction always need to be kept. Even if we perform flush // during recovery, we may still need to hold an old WAL. The // min_log_number_to_keep won't change, and "Column family inconsistency: SST // file contains data beyond the point of corruption" error will be hit, causing // recovery to fail. // // After adding the fix, only after new WAL is synced, RocksDB persist a new // MANIFEST with column families to ensure RocksDB is in consistent state. // RocksDB writes an empty WriteBatch as a sentinel to the new WAL which is // synced immediately afterwards. The sequence number of the sentinel // WriteBatch will be the next sequence number immediately after the largest // sequence number recovered from previous WALs and MANIFEST because of which DB // will be in consistent state. // If a future recovery starts from the new MANIFEST, then it means the new WAL // is successfully synced. Due to the sentinel empty write batch at the // beginning, kPointInTimeRecovery of WAL is guaranteed to go after this point. // If future recovery starts from the old MANIFEST, it means the writing the new // MANIFEST failed. It won't have the "SST ahead of WAL" error. // // The combination of corrupting a WAL and injecting an error during subsequent // re-open exposes the bug of prematurely persisting a new MANIFEST with // advanced ColumnFamilyData::log_number. TEST_P(CrashDuringRecoveryWithCorruptionTest, TxnDbCrashDuringRecovery) { CloseDb(); Options options; options.wal_recovery_mode = WALRecoveryMode::kPointInTimeRecovery; options.track_and_verify_wals_in_manifest = track_and_verify_wals_in_manifest_; options.avoid_flush_during_recovery = false; options.env = env_; ASSERT_OK(DestroyDB(dbname_, options)); options.create_if_missing = true; options.max_write_buffer_number = 3; Reopen(&options); // Create cf test_cf_name. ColumnFamilyHandle* cfh = nullptr; const std::string test_cf_name = "test_cf"; Status s = db_->CreateColumnFamily(options, test_cf_name, &cfh); ASSERT_OK(s); delete cfh; CloseDb(); std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, options); cf_descs.emplace_back(test_cf_name, options); std::vector handles; TransactionDB* txn_db = nullptr; TransactionDBOptions txn_db_opts; // 1. Open and populate the DB. Write and flush default_cf several times to // advance wal number so that some column families have advanced log_number // while other don't. { ASSERT_OK(TransactionDB::Open(options, txn_db_opts, dbname_, cf_descs, &handles, &txn_db)); auto* txn = txn_db->BeginTransaction(WriteOptions(), TransactionOptions()); // Put cf1 ASSERT_OK(txn->Put(handles[1], "foo", "value")); ASSERT_OK(txn->SetName("txn0")); ASSERT_OK(txn->Prepare()); ASSERT_OK(txn_db->Flush(FlushOptions())); delete txn; txn = nullptr; auto* dbimpl = static_cast_with_check(txn_db->GetRootDB()); assert(dbimpl); // Put and flush cf0 for (int i = 0; i < 2; ++i) { ASSERT_OK(txn_db->Put(WriteOptions(), "key" + std::to_string(i), "value" + std::to_string(i))); ASSERT_OK(dbimpl->TEST_SwitchMemtable()); } // Put cf1 txn = txn_db->BeginTransaction(WriteOptions(), TransactionOptions()); ASSERT_OK(txn->Put(handles[1], "foo1", "value1")); ASSERT_OK(txn->Commit()); delete txn; txn = nullptr; for (auto* h : handles) { delete h; } handles.clear(); delete txn_db; } // 2. Corrupt second last wal to emulate power reset which caused the DB to // lose the un-synced WAL. { std::vector file_nums; GetSortedWalFiles(file_nums); size_t size = file_nums.size(); assert(size >= 2); uint64_t log_num = file_nums[size - 2]; CorruptFileWithTruncation(FileType::kWalFile, log_num, /*bytes_to_truncate=*/8); } // 3. After first crash reopen the DB which contains corrupted WAL. Default // family has higher log number than corrupted wal number. There may be old // WAL files that it must not delete because they can contain data of // uncommitted transactions. As a result, min_log_number_to_keep won't change. { SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); SyncPoint::GetInstance()->SetCallBack( "DBImpl::Open::BeforeSyncWAL", [&](void* arg) { auto* tmp_s = reinterpret_cast(arg); assert(tmp_s); *tmp_s = Status::IOError("Injected"); }); SyncPoint::GetInstance()->EnableProcessing(); handles.clear(); s = TransactionDB::Open(options, txn_db_opts, dbname_, cf_descs, &handles, &txn_db); ASSERT_TRUE(s.IsIOError()); ASSERT_EQ("IO error: Injected", s.ToString()); for (auto* h : handles) { delete h; } CloseDb(); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); } // 4. Corrupt max_wal_num. { std::vector file_nums; GetSortedWalFiles(file_nums); size_t size = file_nums.size(); uint64_t log_num = file_nums[size - 1]; CorruptFileWithTruncation(FileType::kWalFile, log_num); } // 5. After second crash reopen the db with second corruption. Default family // has higher log number than corrupted wal number. // We persist a new MANIFEST with advanced log_numbers for some column // families only after syncing the WAL. So during second crash, RocksDB will // skip the corrupted WAL files as they have been moved to different folder. // Since newly synced WAL file's sequence number (sentinel WriteBatch) will be // the next sequence number immediately after the largest sequence number // recovered from previous WALs and MANIFEST, db will be in consistent state // and opens successfully. { ASSERT_OK(TransactionDB::Open(options, txn_db_opts, dbname_, cf_descs, &handles, &txn_db)); // Verify that data is not lost. { std::string v; // Key not visible since it's not committed. ASSERT_EQ(txn_db->Get(ReadOptions(), handles[1], "foo", &v), Status::NotFound()); v.clear(); ASSERT_OK(txn_db->Get(ReadOptions(), "key" + std::to_string(0), &v)); ASSERT_EQ("value" + std::to_string(0), v); // Last WAL is corrupted which contains two keys below. v.clear(); ASSERT_EQ(txn_db->Get(ReadOptions(), "key" + std::to_string(1), &v), Status::NotFound()); v.clear(); ASSERT_EQ(txn_db->Get(ReadOptions(), handles[1], "foo1", &v), Status::NotFound()); } for (auto* h : handles) { delete h; } delete txn_db; } } // This test is similar to // CrashDuringRecoveryWithCorruptionTest.CrashDuringRecovery except it calls // flush and corrupts Last WAL. It calls flush to sync some of the WALs and // remaining are unsyned one of which is then corrupted to simulate crash. // // In case of non-TransactionDB with avoid_flush_during_recovery = true, RocksDB // won't flush the data from WAL to L0 for all column families if possible. As a // result, not all column families can increase their log_numbers, and // min_log_number_to_keep won't change. // It may prematurely persist a new MANIFEST even before we can declare the DB // is in consistent state after recovery (this is when the new WAL is synced) // and advances log_numbers for some column families. // // If there is power failure before we sync the new WAL, we will end up in // a situation in which after persisting the MANIFEST, RocksDB will see some // column families' log_numbers larger than the corrupted wal, and // "Column family inconsistency: SST file contains data beyond the point of // corruption" error will be hit, causing recovery to fail. // // After adding the fix, only after new WAL is synced, RocksDB persist a new // MANIFEST with column families to ensure RocksDB is in consistent state. // RocksDB writes an empty WriteBatch as a sentinel to the new WAL which is // synced immediately afterwards. The sequence number of the sentinel // WriteBatch will be the next sequence number immediately after the largest // sequence number recovered from previous WALs and MANIFEST because of which DB // will be in consistent state. // If a future recovery starts from the new MANIFEST, then it means the new WAL // is successfully synced. Due to the sentinel empty write batch at the // beginning, kPointInTimeRecovery of WAL is guaranteed to go after this point. // If future recovery starts from the old MANIFEST, it means the writing the new // MANIFEST failed. It won't have the "SST ahead of WAL" error. // The combination of corrupting a WAL and injecting an error during subsequent // re-open exposes the bug of prematurely persisting a new MANIFEST with // advanced ColumnFamilyData::log_number. TEST_P(CrashDuringRecoveryWithCorruptionTest, CrashDuringRecoveryWithFlush) { CloseDb(); Options options; options.wal_recovery_mode = WALRecoveryMode::kPointInTimeRecovery; options.avoid_flush_during_recovery = false; options.env = env_; options.create_if_missing = true; ASSERT_OK(DestroyDB(dbname_, options)); Reopen(&options); ColumnFamilyHandle* cfh = nullptr; const std::string test_cf_name = "test_cf"; Status s = db_->CreateColumnFamily(options, test_cf_name, &cfh); ASSERT_OK(s); delete cfh; CloseDb(); std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, options); cf_descs.emplace_back(test_cf_name, options); std::vector handles; { ASSERT_OK(DB::Open(options, dbname_, cf_descs, &handles, &db_)); // Write one key to test_cf. ASSERT_OK(db_->Put(WriteOptions(), handles[1], "old_key", "dontcare")); // Write to default_cf and flush this cf several times to advance wal // number. for (int i = 0; i < 2; ++i) { ASSERT_OK(db_->Put(WriteOptions(), "key" + std::to_string(i), "value" + std::to_string(i))); ASSERT_OK(db_->Flush(FlushOptions())); } ASSERT_OK(db_->Put(WriteOptions(), handles[1], "dontcare", "dontcare")); for (auto* h : handles) { delete h; } handles.clear(); CloseDb(); } // Corrupt second last un-syned wal file to emulate power reset which // caused the DB to lose the un-synced WAL. { std::vector file_nums; GetSortedWalFiles(file_nums); size_t size = file_nums.size(); uint64_t log_num = file_nums[size - 1]; CorruptFileWithTruncation(FileType::kWalFile, log_num, /*bytes_to_truncate=*/8); } // Fault is injected to fail the recovery. { SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); SyncPoint::GetInstance()->SetCallBack( "DBImpl::GetLogSizeAndMaybeTruncate:0", [&](void* arg) { auto* tmp_s = reinterpret_cast(arg); assert(tmp_s); *tmp_s = Status::IOError("Injected"); }); SyncPoint::GetInstance()->EnableProcessing(); handles.clear(); options.avoid_flush_during_recovery = true; s = DB::Open(options, dbname_, cf_descs, &handles, &db_); ASSERT_TRUE(s.IsIOError()); ASSERT_EQ("IO error: Injected", s.ToString()); for (auto* h : handles) { delete h; } CloseDb(); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); } // Reopen db again { options.avoid_flush_during_recovery = avoid_flush_during_recovery_; ASSERT_OK(DB::Open(options, dbname_, cf_descs, &handles, &db_)); // Verify that data is not lost. { std::string v; ASSERT_OK(db_->Get(ReadOptions(), handles[1], "old_key", &v)); ASSERT_EQ("dontcare", v); for (int i = 0; i < 2; ++i) { v.clear(); ASSERT_OK(db_->Get(ReadOptions(), "key" + std::to_string(i), &v)); ASSERT_EQ("value" + std::to_string(i), v); } // Since it's corrupting last wal after Flush, below key is not found. v.clear(); ASSERT_EQ(db_->Get(ReadOptions(), handles[1], "dontcare", &v), Status::NotFound()); } for (auto* h : handles) { delete h; } } } } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); RegisterCustomObjects(argc, argv); return RUN_ALL_TESTS(); } #else #include int main(int /*argc*/, char** /*argv*/) { fprintf(stderr, "SKIPPED as RepairDB() is not supported in ROCKSDB_LITE\n"); return 0; } #endif // !ROCKSDB_LITE