// Copyright (c) Meta Platforms, Inc. and affiliates. // // 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). #include "db/db_test_util.h" #include "db/periodic_task_scheduler.h" #include "db/seqno_to_time_mapping.h" #include "port/stack_trace.h" #include "rocksdb/iostats_context.h" #include "rocksdb/utilities/debug.h" #include "test_util/mock_time_env.h" #ifndef ROCKSDB_LITE namespace ROCKSDB_NAMESPACE { class SeqnoTimeTest : public DBTestBase { public: SeqnoTimeTest() : DBTestBase("seqno_time_test", /*env_do_fsync=*/false) { mock_clock_ = std::make_shared(env_->GetSystemClock()); mock_env_ = std::make_unique(env_, mock_clock_); } protected: std::unique_ptr mock_env_; std::shared_ptr mock_clock_; void SetUp() override { mock_clock_->InstallTimedWaitFixCallback(); SyncPoint::GetInstance()->SetCallBack( "DBImpl::StartPeriodicTaskScheduler:Init", [&](void* arg) { auto periodic_task_scheduler_ptr = reinterpret_cast(arg); periodic_task_scheduler_ptr->TEST_OverrideTimer(mock_clock_.get()); }); } // make sure the file is not in cache, otherwise it won't have IO info void AssertKeyTemperature(int key_id, Temperature expected_temperature) { get_iostats_context()->Reset(); IOStatsContext* iostats = get_iostats_context(); std::string result = Get(Key(key_id)); ASSERT_FALSE(result.empty()); ASSERT_GT(iostats->bytes_read, 0); switch (expected_temperature) { case Temperature::kUnknown: ASSERT_EQ(iostats->file_io_stats_by_temperature.cold_file_read_count, 0); ASSERT_EQ(iostats->file_io_stats_by_temperature.cold_file_bytes_read, 0); break; case Temperature::kCold: ASSERT_GT(iostats->file_io_stats_by_temperature.cold_file_read_count, 0); ASSERT_GT(iostats->file_io_stats_by_temperature.cold_file_bytes_read, 0); break; default: // the test only support kCold now for the bottommost temperature FAIL(); } } }; TEST_F(SeqnoTimeTest, TemperatureBasicUniversal) { const int kNumTrigger = 4; const int kNumLevels = 7; const int kNumKeys = 100; const int kKeyPerSec = 10; Options options = CurrentOptions(); options.compaction_style = kCompactionStyleUniversal; options.preclude_last_level_data_seconds = 10000; options.env = mock_env_.get(); options.bottommost_temperature = Temperature::kCold; options.num_levels = kNumLevels; DestroyAndReopen(options); // pass some time first, otherwise the first a few keys write time are going // to be zero, and internally zero has special meaning: kUnknownSeqnoTime dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(kKeyPerSec)); }); int sst_num = 0; // Write files that are overlap and enough to trigger compaction for (; sst_num < kNumTrigger; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun([&] { mock_clock_->MockSleepForSeconds(static_cast(kKeyPerSec)); }); } ASSERT_OK(Flush()); } ASSERT_OK(dbfull()->WaitForCompact(true)); // All data is hot, only output to penultimate level ASSERT_EQ("0,0,0,0,0,1", FilesPerLevel()); ASSERT_GT(GetSstSizeHelper(Temperature::kUnknown), 0); ASSERT_EQ(GetSstSizeHelper(Temperature::kCold), 0); // read a random key, which should be hot (kUnknown) AssertKeyTemperature(20, Temperature::kUnknown); // Write more data, but still all hot until the 10th SST, as: // write a key every 10 seconds, 100 keys per SST, each SST takes 1000 seconds // The preclude_last_level_data_seconds is 10k for (; sst_num < kNumTrigger * 2; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun([&] { mock_clock_->MockSleepForSeconds(static_cast(kKeyPerSec)); }); } ASSERT_OK(Flush()); ASSERT_OK(dbfull()->WaitForCompact(true)); ASSERT_GT(GetSstSizeHelper(Temperature::kUnknown), 0); ASSERT_EQ(GetSstSizeHelper(Temperature::kCold), 0); } // Now we have both hot data and cold data for (; sst_num < kNumTrigger * 3; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun([&] { mock_clock_->MockSleepForSeconds(static_cast(kKeyPerSec)); }); } ASSERT_OK(Flush()); ASSERT_OK(dbfull()->WaitForCompact(true)); } CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); uint64_t hot_data_size = GetSstSizeHelper(Temperature::kUnknown); uint64_t cold_data_size = GetSstSizeHelper(Temperature::kCold); ASSERT_GT(hot_data_size, 0); ASSERT_GT(cold_data_size, 0); // the first a few key should be cold AssertKeyTemperature(20, Temperature::kCold); for (int i = 0; i < 30; i++) { dbfull()->TEST_WaitForPeridicTaskRun([&] { mock_clock_->MockSleepForSeconds(static_cast(20 * kKeyPerSec)); }); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); // the hot/cold data cut off range should be between i * 20 + 200 -> 250 AssertKeyTemperature(i * 20 + 250, Temperature::kUnknown); AssertKeyTemperature(i * 20 + 200, Temperature::kCold); } ASSERT_LT(GetSstSizeHelper(Temperature::kUnknown), hot_data_size); ASSERT_GT(GetSstSizeHelper(Temperature::kCold), cold_data_size); // Wait again, the most of the data should be cold after that // but it may not be all cold, because if there's no new data write to SST, // the compaction will not get the new seqno->time sampling to decide the last // a few data's time. for (int i = 0; i < 5; i++) { dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(1000)); }); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); } // any random data close to the end should be cold AssertKeyTemperature(1000, Temperature::kCold); // close explicitly, because the env is local variable which will be released // first. Close(); } TEST_F(SeqnoTimeTest, TemperatureBasicLevel) { const int kNumLevels = 7; const int kNumKeys = 100; Options options = CurrentOptions(); options.preclude_last_level_data_seconds = 10000; options.env = mock_env_.get(); options.bottommost_temperature = Temperature::kCold; options.num_levels = kNumLevels; options.level_compaction_dynamic_level_bytes = true; // TODO(zjay): for level compaction, auto-compaction may stuck in deadloop, if // the penultimate level score > 1, but the hot is not cold enough to compact // to last level, which will keep triggering compaction. options.disable_auto_compactions = true; DestroyAndReopen(options); // pass some time first, otherwise the first a few keys write time are going // to be zero, and internally zero has special meaning: kUnknownSeqnoTime dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); int sst_num = 0; // Write files that are overlap for (; sst_num < 4; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } ASSERT_OK(Flush()); } CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); // All data is hot, only output to penultimate level ASSERT_EQ("0,0,0,0,0,1", FilesPerLevel()); ASSERT_GT(GetSstSizeHelper(Temperature::kUnknown), 0); ASSERT_EQ(GetSstSizeHelper(Temperature::kCold), 0); // read a random key, which should be hot (kUnknown) AssertKeyTemperature(20, Temperature::kUnknown); // Adding more data to have mixed hot and cold data for (; sst_num < 14; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } ASSERT_OK(Flush()); } ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); ASSERT_GT(GetSstSizeHelper(Temperature::kUnknown), 0); ASSERT_EQ(GetSstSizeHelper(Temperature::kCold), 0); // Compact the files to the last level which should split the hot/cold data MoveFilesToLevel(6); uint64_t hot_data_size = GetSstSizeHelper(Temperature::kUnknown); uint64_t cold_data_size = GetSstSizeHelper(Temperature::kCold); ASSERT_GT(hot_data_size, 0); ASSERT_GT(cold_data_size, 0); // the first a few key should be cold AssertKeyTemperature(20, Temperature::kCold); // Wait some time, with each wait, the cold data is increasing and hot data is // decreasing for (int i = 0; i < 30; i++) { dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(200)); }); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); uint64_t pre_hot = hot_data_size; uint64_t pre_cold = cold_data_size; hot_data_size = GetSstSizeHelper(Temperature::kUnknown); cold_data_size = GetSstSizeHelper(Temperature::kCold); ASSERT_LT(hot_data_size, pre_hot); ASSERT_GT(cold_data_size, pre_cold); // the hot/cold cut_off key should be around i * 20 + 400 -> 450 AssertKeyTemperature(i * 20 + 450, Temperature::kUnknown); AssertKeyTemperature(i * 20 + 400, Temperature::kCold); } // Wait again, the most of the data should be cold after that // hot data might not be empty, because if we don't write new data, there's // no seqno->time sampling available to the compaction for (int i = 0; i < 5; i++) { dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(1000)); }); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); } // any random data close to the end should be cold AssertKeyTemperature(1000, Temperature::kCold); Close(); } enum class SeqnoTimeTestType : char { kTrackInternalTimeSeconds = 0, kPrecludeLastLevel = 1, kBothSetTrackSmaller = 2, }; class SeqnoTimeTablePropTest : public SeqnoTimeTest, public ::testing::WithParamInterface { public: SeqnoTimeTablePropTest() : SeqnoTimeTest() {} void SetTrackTimeDurationOptions(uint64_t track_time_duration, Options& options) const { // either option set will enable the time tracking feature switch (GetParam()) { case SeqnoTimeTestType::kTrackInternalTimeSeconds: options.preclude_last_level_data_seconds = 0; options.preserve_internal_time_seconds = track_time_duration; break; case SeqnoTimeTestType::kPrecludeLastLevel: options.preclude_last_level_data_seconds = track_time_duration; options.preserve_internal_time_seconds = 0; break; case SeqnoTimeTestType::kBothSetTrackSmaller: options.preclude_last_level_data_seconds = track_time_duration; options.preserve_internal_time_seconds = track_time_duration / 10; break; } } }; INSTANTIATE_TEST_CASE_P( SeqnoTimeTablePropTest, SeqnoTimeTablePropTest, ::testing::Values(SeqnoTimeTestType::kTrackInternalTimeSeconds, SeqnoTimeTestType::kPrecludeLastLevel, SeqnoTimeTestType::kBothSetTrackSmaller)); TEST_P(SeqnoTimeTablePropTest, BasicSeqnoToTimeMapping) { Options options = CurrentOptions(); SetTrackTimeDurationOptions(10000, options); options.env = mock_env_.get(); options.disable_auto_compactions = true; DestroyAndReopen(options); std::set checked_file_nums; SequenceNumber start_seq = dbfull()->GetLatestSequenceNumber(); // Write a key every 10 seconds for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } ASSERT_OK(Flush()); TablePropertiesCollection tables_props; ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 1); auto it = tables_props.begin(); SeqnoToTimeMapping tp_mapping; ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); ASSERT_FALSE(tp_mapping.Empty()); auto seqs = tp_mapping.TEST_GetInternalMapping(); // about ~20 seqs->time entries, because the sample rate is 10000/100, and it // passes 2k time. ASSERT_GE(seqs.size(), 19); ASSERT_LE(seqs.size(), 21); SequenceNumber seq_end = dbfull()->GetLatestSequenceNumber(); for (auto i = start_seq; i < start_seq + 10; i++) { ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i + 1) * 10); } start_seq += 10; for (auto i = start_seq; i < seq_end; i++) { // The result is within the range ASSERT_GE(tp_mapping.GetOldestApproximateTime(i), (i - 10) * 10); ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i + 10) * 10); } checked_file_nums.insert(it->second->orig_file_number); start_seq = seq_end; // Write a key every 1 seconds for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i + 190), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(1)); }); } seq_end = dbfull()->GetLatestSequenceNumber(); ASSERT_OK(Flush()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 2); it = tables_props.begin(); while (it != tables_props.end()) { if (!checked_file_nums.count(it->second->orig_file_number)) { break; } it++; } ASSERT_TRUE(it != tables_props.end()); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); // There only a few time sample ASSERT_GE(seqs.size(), 1); ASSERT_LE(seqs.size(), 3); for (auto i = start_seq; i < seq_end; i++) { // The result is not very accurate, as there is more data write within small // range of time ASSERT_GE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) + 1000); ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) + 3000); } checked_file_nums.insert(it->second->orig_file_number); start_seq = seq_end; // Write a key every 200 seconds for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i + 380), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(200)); }); } seq_end = dbfull()->GetLatestSequenceNumber(); ASSERT_OK(Flush()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 3); it = tables_props.begin(); while (it != tables_props.end()) { if (!checked_file_nums.count(it->second->orig_file_number)) { break; } it++; } ASSERT_TRUE(it != tables_props.end()); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); // The sequence number -> time entries should be maxed ASSERT_GE(seqs.size(), 99); ASSERT_LE(seqs.size(), 101); for (auto i = start_seq; i < seq_end - 99; i++) { // likely the first 100 entries reports 0 ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) + 3000); } start_seq += 101; for (auto i = start_seq; i < seq_end; i++) { ASSERT_GE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) * 200 + 22200); ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) * 200 + 22600); } checked_file_nums.insert(it->second->orig_file_number); start_seq = seq_end; // Write a key every 100 seconds for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i + 570), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } seq_end = dbfull()->GetLatestSequenceNumber(); ASSERT_OK(Flush()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 4); it = tables_props.begin(); while (it != tables_props.end()) { if (!checked_file_nums.count(it->second->orig_file_number)) { break; } it++; } ASSERT_TRUE(it != tables_props.end()); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 99); ASSERT_LE(seqs.size(), 101); checked_file_nums.insert(it->second->orig_file_number); // re-enable compaction ASSERT_OK(dbfull()->SetOptions({ {"disable_auto_compactions", "false"}, })); ASSERT_OK(dbfull()->TEST_WaitForCompact()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_GE(tables_props.size(), 1); it = tables_props.begin(); while (it != tables_props.end()) { if (!checked_file_nums.count(it->second->orig_file_number)) { break; } it++; } ASSERT_TRUE(it != tables_props.end()); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 99); ASSERT_LE(seqs.size(), 101); for (auto i = start_seq; i < seq_end - 99; i++) { // likely the first 100 entries reports 0 ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) * 100 + 50000); } start_seq += 101; for (auto i = start_seq; i < seq_end; i++) { ASSERT_GE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) * 100 + 52200); ASSERT_LE(tp_mapping.GetOldestApproximateTime(i), (i - start_seq) * 100 + 52400); } ASSERT_OK(db_->Close()); } TEST_P(SeqnoTimeTablePropTest, MultiCFs) { Options options = CurrentOptions(); options.preclude_last_level_data_seconds = 0; options.preserve_internal_time_seconds = 0; options.env = mock_env_.get(); options.stats_dump_period_sec = 0; options.stats_persist_period_sec = 0; ReopenWithColumnFamilies({"default"}, options); const PeriodicTaskScheduler& scheduler = dbfull()->TEST_GetPeriodicTaskScheduler(); ASSERT_FALSE(scheduler.TEST_HasTask(PeriodicTaskType::kRecordSeqnoTime)); // Write some data and increase the current time for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } ASSERT_OK(Flush()); TablePropertiesCollection tables_props; ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 1); auto it = tables_props.begin(); ASSERT_TRUE(it->second->seqno_to_time_mapping.empty()); ASSERT_TRUE(dbfull()->TEST_GetSeqnoToTimeMapping().Empty()); Options options_1 = options; SetTrackTimeDurationOptions(10000, options_1); CreateColumnFamilies({"one"}, options_1); ASSERT_TRUE(scheduler.TEST_HasTask(PeriodicTaskType::kRecordSeqnoTime)); // Write some data to the default CF (without preclude_last_level feature) for (int i = 0; i < 200; i++) { ASSERT_OK(Put(Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } ASSERT_OK(Flush()); // Write some data to the CF one for (int i = 0; i < 20; i++) { ASSERT_OK(Put(1, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } ASSERT_OK(Flush(1)); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(handles_[1], &tables_props)); ASSERT_EQ(tables_props.size(), 1); it = tables_props.begin(); SeqnoToTimeMapping tp_mapping; ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); ASSERT_FALSE(tp_mapping.Empty()); auto seqs = tp_mapping.TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 1); ASSERT_LE(seqs.size(), 4); // Create one more CF with larger preclude_last_level time Options options_2 = options; SetTrackTimeDurationOptions(1000000, options_2); // 1m CreateColumnFamilies({"two"}, options_2); // Add more data to CF "two" to fill the in memory mapping for (int i = 0; i < 2000; i++) { ASSERT_OK(Put(2, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } seqs = dbfull()->TEST_GetSeqnoToTimeMapping().TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 1000 - 1); ASSERT_LE(seqs.size(), 1000 + 1); ASSERT_OK(Flush(2)); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(handles_[2], &tables_props)); ASSERT_EQ(tables_props.size(), 1); it = tables_props.begin(); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); // the max encoded entries is 100 ASSERT_GE(seqs.size(), 100 - 1); ASSERT_LE(seqs.size(), 100 + 1); // Write some data to default CF, as all memtable with preclude_last_level // enabled have flushed, the in-memory seqno->time mapping should be cleared for (int i = 0; i < 10; i++) { ASSERT_OK(Put(0, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } seqs = dbfull()->TEST_GetSeqnoToTimeMapping().TEST_GetInternalMapping(); ASSERT_OK(Flush(0)); // trigger compaction for CF "two" and make sure the compaction output has // seqno_to_time_mapping for (int j = 0; j < 3; j++) { for (int i = 0; i < 200; i++) { ASSERT_OK(Put(2, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } ASSERT_OK(Flush(2)); } ASSERT_OK(dbfull()->TEST_WaitForCompact()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(handles_[2], &tables_props)); ASSERT_EQ(tables_props.size(), 1); it = tables_props.begin(); tp_mapping.Clear(); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); seqs = tp_mapping.TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 99); ASSERT_LE(seqs.size(), 101); for (int j = 0; j < 2; j++) { for (int i = 0; i < 200; i++) { ASSERT_OK(Put(0, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } ASSERT_OK(Flush(0)); } ASSERT_OK(dbfull()->TEST_WaitForCompact()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(handles_[0], &tables_props)); ASSERT_EQ(tables_props.size(), 1); it = tables_props.begin(); ASSERT_TRUE(it->second->seqno_to_time_mapping.empty()); // Write some data to CF "two", but don't flush to accumulate for (int i = 0; i < 1000; i++) { ASSERT_OK(Put(2, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } ASSERT_GE( dbfull()->TEST_GetSeqnoToTimeMapping().TEST_GetInternalMapping().size(), 500); // After dropping CF "one", the in-memory mapping will be change to only // follow CF "two" options. ASSERT_OK(db_->DropColumnFamily(handles_[1])); ASSERT_LE( dbfull()->TEST_GetSeqnoToTimeMapping().TEST_GetInternalMapping().size(), 100 + 5); // After dropping CF "two", the in-memory mapping is also clear. ASSERT_OK(db_->DropColumnFamily(handles_[2])); ASSERT_EQ( dbfull()->TEST_GetSeqnoToTimeMapping().TEST_GetInternalMapping().size(), 0); // And the timer worker is stopped ASSERT_FALSE(scheduler.TEST_HasTask(PeriodicTaskType::kRecordSeqnoTime)); Close(); } TEST_P(SeqnoTimeTablePropTest, MultiInstancesBasic) { const int kInstanceNum = 2; Options options = CurrentOptions(); SetTrackTimeDurationOptions(10000, options); options.env = mock_env_.get(); options.stats_dump_period_sec = 0; options.stats_persist_period_sec = 0; auto dbs = std::vector(kInstanceNum); for (int i = 0; i < kInstanceNum; i++) { ASSERT_OK( DB::Open(options, test::PerThreadDBPath(std::to_string(i)), &(dbs[i]))); } // Make sure the second instance has the worker enabled auto dbi = static_cast_with_check(dbs[1]); WriteOptions wo; for (int i = 0; i < 200; i++) { ASSERT_OK(dbi->Put(wo, Key(i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(100)); }); } SeqnoToTimeMapping seqno_to_time_mapping = dbi->TEST_GetSeqnoToTimeMapping(); ASSERT_GT(seqno_to_time_mapping.Size(), 10); for (int i = 0; i < kInstanceNum; i++) { ASSERT_OK(dbs[i]->Close()); delete dbs[i]; } } TEST_P(SeqnoTimeTablePropTest, SeqnoToTimeMappingUniversal) { const int kNumTrigger = 4; const int kNumLevels = 7; const int kNumKeys = 100; Options options = CurrentOptions(); SetTrackTimeDurationOptions(10000, options); options.compaction_style = kCompactionStyleUniversal; options.num_levels = kNumLevels; options.env = mock_env_.get(); DestroyAndReopen(options); std::atomic_uint64_t num_seqno_zeroing{0}; SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); SyncPoint::GetInstance()->SetCallBack( "CompactionIterator::PrepareOutput:ZeroingSeq", [&](void* /*arg*/) { num_seqno_zeroing++; }); SyncPoint::GetInstance()->EnableProcessing(); int sst_num = 0; for (; sst_num < kNumTrigger - 1; sst_num++) { for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } ASSERT_OK(Flush()); } TablePropertiesCollection tables_props; ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 3); for (const auto& props : tables_props) { ASSERT_FALSE(props.second->seqno_to_time_mapping.empty()); SeqnoToTimeMapping tp_mapping; ASSERT_OK(tp_mapping.Add(props.second->seqno_to_time_mapping)); ASSERT_OK(tp_mapping.Sort()); ASSERT_FALSE(tp_mapping.Empty()); auto seqs = tp_mapping.TEST_GetInternalMapping(); ASSERT_GE(seqs.size(), 10 - 1); ASSERT_LE(seqs.size(), 10 + 1); } // Trigger a compaction for (int i = 0; i < kNumKeys; i++) { ASSERT_OK(Put(Key(sst_num * (kNumKeys - 1) + i), "value")); dbfull()->TEST_WaitForPeridicTaskRun( [&] { mock_clock_->MockSleepForSeconds(static_cast(10)); }); } sst_num++; ASSERT_OK(Flush()); ASSERT_OK(dbfull()->TEST_WaitForCompact()); tables_props.clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 1); auto it = tables_props.begin(); SeqnoToTimeMapping tp_mapping; ASSERT_FALSE(it->second->seqno_to_time_mapping.empty()); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); // compact to the last level CompactRangeOptions cro; cro.bottommost_level_compaction = BottommostLevelCompaction::kForce; ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); // make sure the data is all compacted to penultimate level if the feature is // on, otherwise, compacted to the last level. if (options.preclude_last_level_data_seconds > 0) { ASSERT_GT(NumTableFilesAtLevel(5), 0); ASSERT_EQ(NumTableFilesAtLevel(6), 0); } else { ASSERT_EQ(NumTableFilesAtLevel(5), 0); ASSERT_GT(NumTableFilesAtLevel(6), 0); } // regardless the file is on the last level or not, it should keep the time // information and sequence number are not set tables_props.clear(); tp_mapping.Clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); ASSERT_EQ(tables_props.size(), 1); ASSERT_EQ(num_seqno_zeroing, 0); it = tables_props.begin(); ASSERT_FALSE(it->second->seqno_to_time_mapping.empty()); ASSERT_OK(tp_mapping.Add(it->second->seqno_to_time_mapping)); // make half of the data expired mock_clock_->MockSleepForSeconds(static_cast(8000)); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); tables_props.clear(); tp_mapping.Clear(); ASSERT_OK(dbfull()->GetPropertiesOfAllTables(&tables_props)); if (options.preclude_last_level_data_seconds > 0) { ASSERT_EQ(tables_props.size(), 2); } else { ASSERT_EQ(tables_props.size(), 1); } ASSERT_GT(num_seqno_zeroing, 0); std::vector key_versions; ASSERT_OK(GetAllKeyVersions(db_, Slice(), Slice(), std::numeric_limits::max(), &key_versions)); // make sure there're more than 300 keys and first 100 keys are having seqno // zeroed out, the last 100 key seqno not zeroed out ASSERT_GT(key_versions.size(), 300); for (int i = 0; i < 100; i++) { ASSERT_EQ(key_versions[i].sequence, 0); } auto rit = key_versions.rbegin(); for (int i = 0; i < 100; i++) { ASSERT_GT(rit->sequence, 0); rit++; } // make all data expired and compact again to push it to the last level // regardless if the tiering feature is enabled or not mock_clock_->MockSleepForSeconds(static_cast(20000)); ASSERT_OK(db_->CompactRange(cro, nullptr, nullptr)); ASSERT_GT(num_seqno_zeroing, 0); ASSERT_GT(NumTableFilesAtLevel(6), 0); Close(); } TEST_F(SeqnoTimeTest, MappingAppend) { SeqnoToTimeMapping test(/*max_time_duration=*/100, /*max_capacity=*/10); // ignore seqno == 0, as it may mean the seqno is zeroed out ASSERT_FALSE(test.Append(0, 9)); ASSERT_TRUE(test.Append(3, 10)); auto size = test.Size(); // normal add ASSERT_TRUE(test.Append(10, 11)); size++; ASSERT_EQ(size, test.Size()); // Append unsorted ASSERT_FALSE(test.Append(8, 12)); ASSERT_EQ(size, test.Size()); // Append with the same seqno, newer time will be accepted ASSERT_TRUE(test.Append(10, 12)); ASSERT_EQ(size, test.Size()); // older time will be ignored ASSERT_FALSE(test.Append(10, 9)); ASSERT_EQ(size, test.Size()); // new seqno with old time will be ignored ASSERT_FALSE(test.Append(12, 8)); ASSERT_EQ(size, test.Size()); } TEST_F(SeqnoTimeTest, GetOldestApproximateTime) { SeqnoToTimeMapping test(/*max_time_duration=*/100, /*max_capacity=*/10); ASSERT_EQ(test.GetOldestApproximateTime(10), kUnknownSeqnoTime); test.Append(3, 10); ASSERT_EQ(test.GetOldestApproximateTime(2), kUnknownSeqnoTime); ASSERT_EQ(test.GetOldestApproximateTime(3), 10); ASSERT_EQ(test.GetOldestApproximateTime(10), 10); test.Append(10, 100); test.Append(100, 1000); ASSERT_EQ(test.GetOldestApproximateTime(10), 100); ASSERT_EQ(test.GetOldestApproximateTime(40), 100); ASSERT_EQ(test.GetOldestApproximateTime(111), 1000); } TEST_F(SeqnoTimeTest, Sort) { SeqnoToTimeMapping test; // single entry test.Add(10, 11); ASSERT_OK(test.Sort()); ASSERT_EQ(test.Size(), 1); // duplicate, should be removed by sort test.Add(10, 11); // same seqno, but older time, should be removed test.Add(10, 9); // unuseful ones, should be removed by sort test.Add(11, 9); test.Add(9, 8); // Good ones test.Add(1, 10); test.Add(100, 100); ASSERT_OK(test.Sort()); auto seqs = test.TEST_GetInternalMapping(); std::deque expected; expected.emplace_back(1, 10); expected.emplace_back(10, 11); expected.emplace_back(100, 100); ASSERT_EQ(expected, seqs); } TEST_F(SeqnoTimeTest, EncodeDecodeBasic) { SeqnoToTimeMapping test(0, 1000); std::string output; test.Encode(output, 0, 1000, 100); ASSERT_TRUE(output.empty()); for (int i = 1; i <= 1000; i++) { ASSERT_TRUE(test.Append(i, i * 10)); } test.Encode(output, 0, 1000, 100); ASSERT_FALSE(output.empty()); SeqnoToTimeMapping decoded; ASSERT_OK(decoded.Add(output)); ASSERT_OK(decoded.Sort()); ASSERT_EQ(decoded.Size(), SeqnoToTimeMapping::kMaxSeqnoTimePairsPerSST); ASSERT_EQ(test.Size(), 1000); for (SequenceNumber seq = 0; seq <= 1000; seq++) { // test has the more accurate time mapping, encode only pick // kMaxSeqnoTimePairsPerSST number of entries, which is less accurate uint64_t target_time = test.GetOldestApproximateTime(seq); ASSERT_GE(decoded.GetOldestApproximateTime(seq), target_time < 200 ? 0 : target_time - 200); ASSERT_LE(decoded.GetOldestApproximateTime(seq), target_time); } } TEST_F(SeqnoTimeTest, EncodeDecodePerferNewTime) { SeqnoToTimeMapping test(0, 10); test.Append(1, 10); test.Append(5, 17); test.Append(6, 25); test.Append(8, 30); std::string output; test.Encode(output, 1, 10, 0, 3); SeqnoToTimeMapping decoded; ASSERT_OK(decoded.Add(output)); ASSERT_OK(decoded.Sort()); ASSERT_EQ(decoded.Size(), 3); auto seqs = decoded.TEST_GetInternalMapping(); std::deque expected; expected.emplace_back(1, 10); expected.emplace_back(6, 25); expected.emplace_back(8, 30); ASSERT_EQ(expected, seqs); // Add a few large time number test.Append(10, 100); test.Append(13, 200); test.Append(16, 300); output.clear(); test.Encode(output, 1, 20, 0, 4); decoded.Clear(); ASSERT_OK(decoded.Add(output)); ASSERT_OK(decoded.Sort()); ASSERT_EQ(decoded.Size(), 4); expected.clear(); expected.emplace_back(1, 10); // entry #6, #8 are skipped as they are too close to #1. // entry #100 is also within skip range, but if it's skipped, there not enough // number to fill 4 entries, so select it. expected.emplace_back(10, 100); expected.emplace_back(13, 200); expected.emplace_back(16, 300); seqs = decoded.TEST_GetInternalMapping(); ASSERT_EQ(expected, seqs); } } // namespace ROCKSDB_NAMESPACE #endif // ROCKSDB_LITE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }