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rocksdb/db/db_flush_test.cc

2570 lines
92 KiB

// 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 <atomic>
#include <limits>
#include "db/db_impl/db_impl.h"
#include "db/db_test_util.h"
#include "env/mock_env.h"
#include "file/filename.h"
#include "port/port.h"
#include "port/stack_trace.h"
#include "rocksdb/utilities/transaction_db.h"
#include "test_util/sync_point.h"
#include "test_util/testutil.h"
#include "util/cast_util.h"
#include "util/mutexlock.h"
#include "utilities/fault_injection_env.h"
#include "utilities/fault_injection_fs.h"
namespace ROCKSDB_NAMESPACE {
// This is a static filter used for filtering
// kvs during the compaction process.
static std::string NEW_VALUE = "NewValue";
class DBFlushTest : public DBTestBase {
public:
DBFlushTest() : DBTestBase("db_flush_test", /*env_do_fsync=*/true) {}
};
class DBFlushDirectIOTest : public DBFlushTest,
public ::testing::WithParamInterface<bool> {
public:
DBFlushDirectIOTest() : DBFlushTest() {}
};
class DBAtomicFlushTest : public DBFlushTest,
public ::testing::WithParamInterface<bool> {
public:
DBAtomicFlushTest() : DBFlushTest() {}
};
// We had issue when two background threads trying to flush at the same time,
// only one of them get committed. The test verifies the issue is fixed.
TEST_F(DBFlushTest, FlushWhileWritingManifest) {
Options options;
options.disable_auto_compactions = true;
options.max_background_flushes = 2;
options.env = env_;
Reopen(options);
FlushOptions no_wait;
no_wait.wait = false;
no_wait.allow_write_stall=true;
SyncPoint::GetInstance()->LoadDependency(
{{"VersionSet::LogAndApply:WriteManifest",
"DBFlushTest::FlushWhileWritingManifest:1"},
{"MemTableList::TryInstallMemtableFlushResults:InProgress",
"VersionSet::LogAndApply:WriteManifestDone"}});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put("foo", "v"));
ASSERT_OK(dbfull()->Flush(no_wait));
TEST_SYNC_POINT("DBFlushTest::FlushWhileWritingManifest:1");
ASSERT_OK(Put("bar", "v"));
ASSERT_OK(dbfull()->Flush(no_wait));
// If the issue is hit we will wait here forever.
ASSERT_OK(dbfull()->TEST_WaitForFlushMemTable());
#ifndef ROCKSDB_LITE
ASSERT_EQ(2, TotalTableFiles());
#endif // ROCKSDB_LITE
}
// Disable this test temporarily on Travis as it fails intermittently.
// Github issue: #4151
TEST_F(DBFlushTest, SyncFail) {
std::unique_ptr<FaultInjectionTestEnv> fault_injection_env(
new FaultInjectionTestEnv(env_));
Options options;
options.disable_auto_compactions = true;
options.env = fault_injection_env.get();
SyncPoint::GetInstance()->LoadDependency(
{{"DBFlushTest::SyncFail:1", "DBImpl::SyncClosedLogs:Start"},
{"DBImpl::SyncClosedLogs:Failed", "DBFlushTest::SyncFail:2"}});
SyncPoint::GetInstance()->EnableProcessing();
CreateAndReopenWithCF({"pikachu"}, options);
ASSERT_OK(Put("key", "value"));
FlushOptions flush_options;
flush_options.wait = false;
ASSERT_OK(dbfull()->Flush(flush_options));
// Flush installs a new super-version. Get the ref count after that.
fault_injection_env->SetFilesystemActive(false);
TEST_SYNC_POINT("DBFlushTest::SyncFail:1");
TEST_SYNC_POINT("DBFlushTest::SyncFail:2");
fault_injection_env->SetFilesystemActive(true);
// Now the background job will do the flush; wait for it.
// Returns the IO error happend during flush.
ASSERT_NOK(dbfull()->TEST_WaitForFlushMemTable());
#ifndef ROCKSDB_LITE
ASSERT_EQ("", FilesPerLevel()); // flush failed.
#endif // ROCKSDB_LITE
Destroy(options);
}
TEST_F(DBFlushTest, SyncSkip) {
Options options = CurrentOptions();
SyncPoint::GetInstance()->LoadDependency(
{{"DBFlushTest::SyncSkip:1", "DBImpl::SyncClosedLogs:Skip"},
{"DBImpl::SyncClosedLogs:Skip", "DBFlushTest::SyncSkip:2"}});
SyncPoint::GetInstance()->EnableProcessing();
Reopen(options);
ASSERT_OK(Put("key", "value"));
FlushOptions flush_options;
flush_options.wait = false;
ASSERT_OK(dbfull()->Flush(flush_options));
TEST_SYNC_POINT("DBFlushTest::SyncSkip:1");
TEST_SYNC_POINT("DBFlushTest::SyncSkip:2");
// Now the background job will do the flush; wait for it.
ASSERT_OK(dbfull()->TEST_WaitForFlushMemTable());
Destroy(options);
}
TEST_F(DBFlushTest, FlushInLowPriThreadPool) {
// Verify setting an empty high-pri (flush) thread pool causes flushes to be
// scheduled in the low-pri (compaction) thread pool.
Options options = CurrentOptions();
options.level0_file_num_compaction_trigger = 4;
options.memtable_factory.reset(test::NewSpecialSkipListFactory(1));
Reopen(options);
env_->SetBackgroundThreads(0, Env::HIGH);
std::thread::id tid;
int num_flushes = 0, num_compactions = 0;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::BGWorkFlush", [&](void* /*arg*/) {
if (tid == std::thread::id()) {
tid = std::this_thread::get_id();
} else {
ASSERT_EQ(tid, std::this_thread::get_id());
}
++num_flushes;
});
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::BGWorkCompaction", [&](void* /*arg*/) {
ASSERT_EQ(tid, std::this_thread::get_id());
++num_compactions;
});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put("key", "val"));
for (int i = 0; i < 4; ++i) {
ASSERT_OK(Put("key", "val"));
ASSERT_OK(dbfull()->TEST_WaitForFlushMemTable());
}
ASSERT_OK(dbfull()->TEST_WaitForCompact());
ASSERT_EQ(4, num_flushes);
ASSERT_EQ(1, num_compactions);
}
// Test when flush job is submitted to low priority thread pool and when DB is
// closed in the meanwhile, CloseHelper doesn't hang.
TEST_F(DBFlushTest, CloseDBWhenFlushInLowPri) {
Options options = CurrentOptions();
options.max_background_flushes = 1;
options.max_total_wal_size = 8192;
DestroyAndReopen(options);
CreateColumnFamilies({"cf1", "cf2"}, options);
env_->SetBackgroundThreads(0, Env::HIGH);
env_->SetBackgroundThreads(1, Env::LOW);
test::SleepingBackgroundTask sleeping_task_low;
int num_flushes = 0;
SyncPoint::GetInstance()->SetCallBack("DBImpl::BGWorkFlush",
[&](void* /*arg*/) { ++num_flushes; });
int num_low_flush_unscheduled = 0;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::UnscheduleLowFlushCallback", [&](void* /*arg*/) {
num_low_flush_unscheduled++;
// There should be one flush job in low pool that needs to be
// unscheduled
ASSERT_EQ(num_low_flush_unscheduled, 1);
});
int num_high_flush_unscheduled = 0;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::UnscheduleHighFlushCallback", [&](void* /*arg*/) {
num_high_flush_unscheduled++;
// There should be no flush job in high pool
ASSERT_EQ(num_high_flush_unscheduled, 0);
});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put(0, "key1", DummyString(8192)));
// Block thread so that flush cannot be run and can be removed from the queue
// when called Unschedule.
env_->Schedule(&test::SleepingBackgroundTask::DoSleepTask, &sleeping_task_low,
Env::Priority::LOW);
sleeping_task_low.WaitUntilSleeping();
// Trigger flush and flush job will be scheduled to LOW priority thread.
ASSERT_OK(Put(0, "key2", DummyString(8192)));
// Close DB and flush job in low priority queue will be removed without
// running.
Close();
sleeping_task_low.WakeUp();
sleeping_task_low.WaitUntilDone();
ASSERT_EQ(0, num_flushes);
TryReopenWithColumnFamilies({"default", "cf1", "cf2"}, options);
ASSERT_OK(Put(0, "key3", DummyString(8192)));
ASSERT_OK(Flush(0));
ASSERT_EQ(1, num_flushes);
}
TEST_F(DBFlushTest, ManualFlushWithMinWriteBufferNumberToMerge) {
Options options = CurrentOptions();
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
Reopen(options);
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::BGWorkFlush",
"DBFlushTest::ManualFlushWithMinWriteBufferNumberToMerge:1"},
{"DBFlushTest::ManualFlushWithMinWriteBufferNumberToMerge:2",
"FlushJob::WriteLevel0Table"}});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put("key1", "value1"));
port::Thread t([&]() {
// The call wait for flush to finish, i.e. with flush_options.wait = true.
ASSERT_OK(Flush());
});
// Wait for flush start.
TEST_SYNC_POINT("DBFlushTest::ManualFlushWithMinWriteBufferNumberToMerge:1");
// Insert a second memtable before the manual flush finish.
// At the end of the manual flush job, it will check if further flush
// is needed, but it will not trigger flush of the second memtable because
// min_write_buffer_number_to_merge is not reached.
ASSERT_OK(Put("key2", "value2"));
ASSERT_OK(dbfull()->TEST_SwitchMemtable());
TEST_SYNC_POINT("DBFlushTest::ManualFlushWithMinWriteBufferNumberToMerge:2");
// Manual flush should return, without waiting for flush indefinitely.
t.join();
}
TEST_F(DBFlushTest, ScheduleOnlyOneBgThread) {
Options options = CurrentOptions();
Reopen(options);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
int called = 0;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::MaybeScheduleFlushOrCompaction:AfterSchedule:0", [&](void* arg) {
ASSERT_NE(nullptr, arg);
auto unscheduled_flushes = *reinterpret_cast<int*>(arg);
ASSERT_EQ(0, unscheduled_flushes);
++called;
});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put("a", "foo"));
FlushOptions flush_opts;
ASSERT_OK(dbfull()->Flush(flush_opts));
ASSERT_EQ(1, called);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
}
// The following 3 tests are designed for testing garbage statistics at flush
// time.
//
// ======= General Information ======= (from GitHub Wiki).
// There are three scenarios where memtable flush can be triggered:
//
// 1 - Memtable size exceeds ColumnFamilyOptions::write_buffer_size
// after a write.
// 2 - Total memtable size across all column families exceeds
// DBOptions::db_write_buffer_size,
// or DBOptions::write_buffer_manager signals a flush. In this scenario
// the largest memtable will be flushed.
// 3 - Total WAL file size exceeds DBOptions::max_total_wal_size.
// In this scenario the memtable with the oldest data will be flushed,
// in order to allow the WAL file with data from this memtable to be
// purged.
//
// As a result, a memtable can be flushed before it is full. This is one
// reason the generated SST file can be smaller than the corresponding
// memtable. Compression is another factor to make SST file smaller than
// corresponding memtable, since data in memtable is uncompressed.
TEST_F(DBFlushTest, StatisticsGarbageBasic) {
Options options = CurrentOptions();
// The following options are used to enforce several values that
// may already exist as default values to make this test resilient
// to default value updates in the future.
options.statistics = CreateDBStatistics();
// Record all statistics.
options.statistics->set_stats_level(StatsLevel::kAll);
// create the DB if it's not already present
options.create_if_missing = true;
// Useful for now as we are trying to compare uncompressed data savings on
// flush().
options.compression = kNoCompression;
// Prevent memtable in place updates. Should already be disabled
// (from Wiki:
// In place updates can be enabled by toggling on the bool
// inplace_update_support flag. However, this flag is by default set to
// false
// because this thread-safe in-place update support is not compatible
// with concurrent memtable writes. Note that the bool
// allow_concurrent_memtable_write is set to true by default )
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
// Enforce size of a single MemTable to 64MB (64MB = 67108864 bytes).
options.write_buffer_size = 64 << 20;
ASSERT_OK(TryReopen(options));
// Put multiple times the same key-values.
// The encoded length of a db entry in the memtable is
// defined in db/memtable.cc (MemTable::Add) as the variable:
// encoded_len= VarintLength(internal_key_size) --> =
// log_256(internal_key).
// Min # of bytes
// necessary to
// store
// internal_key_size.
// + internal_key_size --> = actual key string,
// (size key_size: w/o term null char)
// + 8 bytes for
// fixed uint64 "seq
// number
// +
// insertion type"
// + VarintLength(val_size) --> = min # of bytes to
// store val_size
// + val_size --> = actual value
// string
// For example, in our situation, "key1" : size 4, "value1" : size 6
// (the terminating null characters are not copied over to the memtable).
// And therefore encoded_len = 1 + (4+8) + 1 + 6 = 20 bytes per entry.
// However in terms of raw data contained in the memtable, and written
// over to the SSTable, we only count internal_key_size and val_size,
// because this is the only raw chunk of bytes that contains everything
// necessary to reconstruct a user entry: sequence number, insertion type,
// key, and value.
// To test the relevance of our Memtable garbage statistics,
// namely MEMTABLE_PAYLOAD_BYTES_AT_FLUSH and MEMTABLE_GARBAGE_BYTES_AT_FLUSH,
// we insert K-V pairs with 3 distinct keys (of length 4),
// and random values of arbitrary length RAND_VALUES_LENGTH,
// and we repeat this step NUM_REPEAT times total.
// At the end, we insert 3 final K-V pairs with the same 3 keys
// and known values (these will be the final values, of length 6).
// I chose NUM_REPEAT=2,000 such that no automatic flush is
// triggered (the number of bytes in the memtable is therefore
// well below any meaningful heuristic for a memtable of size 64MB).
// As a result, since each K-V pair is inserted as a payload
// of N meaningful bytes (sequence number, insertion type,
// key, and value = 8 + 4 + RAND_VALUE_LENGTH),
// MEMTABLE_GARBAGE_BYTES_AT_FLUSH should be equal to 2,000 * N bytes
// and MEMTABLE_PAYLAOD_BYTES_AT_FLUSH = MEMTABLE_GARBAGE_BYTES_AT_FLUSH +
// (3*(8 + 4 + 6)) bytes. For RAND_VALUE_LENGTH = 172 (arbitrary value), we
// expect:
// N = 8 + 4 + 172 = 184 bytes
// MEMTABLE_GARBAGE_BYTES_AT_FLUSH = 2,000 * 184 = 368,000 bytes.
// MEMTABLE_PAYLOAD_BYTES_AT_FLUSH = 368,000 + 3*18 = 368,054 bytes.
const size_t NUM_REPEAT = 2000;
const size_t RAND_VALUES_LENGTH = 172;
const std::string KEY1 = "key1";
const std::string KEY2 = "key2";
const std::string KEY3 = "key3";
const std::string VALUE1 = "value1";
const std::string VALUE2 = "value2";
const std::string VALUE3 = "value3";
uint64_t EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH = 0;
uint64_t EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH = 0;
Random rnd(301);
// Insertion of of K-V pairs, multiple times.
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
std::string p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY1.size() + p_v1.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY2.size() + p_v2.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY3.size() + p_v3.size() + sizeof(uint64_t);
}
// The memtable data bytes includes the "garbage"
// bytes along with the useful payload.
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH =
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH;
ASSERT_OK(Put(KEY1, VALUE1));
ASSERT_OK(Put(KEY2, VALUE2));
ASSERT_OK(Put(KEY3, VALUE3));
// Add useful payload to the memtable data bytes:
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH +=
KEY1.size() + VALUE1.size() + KEY2.size() + VALUE2.size() + KEY3.size() +
VALUE3.size() + 3 * sizeof(uint64_t);
// We assert that the last K-V pairs have been successfully inserted,
// and that the valid values are VALUE1, VALUE2, VALUE3.
PinnableSlice value;
ASSERT_OK(Get(KEY1, &value));
ASSERT_EQ(value.ToString(), VALUE1);
ASSERT_OK(Get(KEY2, &value));
ASSERT_EQ(value.ToString(), VALUE2);
ASSERT_OK(Get(KEY3, &value));
ASSERT_EQ(value.ToString(), VALUE3);
// Force flush to SST. Increments the statistics counter.
ASSERT_OK(Flush());
// Collect statistics.
uint64_t mem_data_bytes =
TestGetTickerCount(options, MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
uint64_t mem_garbage_bytes =
TestGetTickerCount(options, MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
EXPECT_EQ(mem_data_bytes, EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
EXPECT_EQ(mem_garbage_bytes, EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
Close();
}
TEST_F(DBFlushTest, StatisticsGarbageInsertAndDeletes) {
Options options = CurrentOptions();
options.statistics = CreateDBStatistics();
options.statistics->set_stats_level(StatsLevel::kAll);
options.create_if_missing = true;
options.compression = kNoCompression;
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
options.write_buffer_size = 67108864;
ASSERT_OK(TryReopen(options));
const size_t NUM_REPEAT = 2000;
const size_t RAND_VALUES_LENGTH = 37;
const std::string KEY1 = "key1";
const std::string KEY2 = "key2";
const std::string KEY3 = "key3";
const std::string KEY4 = "key4";
const std::string KEY5 = "key5";
const std::string KEY6 = "key6";
uint64_t EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH = 0;
uint64_t EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH = 0;
WriteBatch batch;
Random rnd(301);
// Insertion of of K-V pairs, multiple times.
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
std::string p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY1.size() + p_v1.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY2.size() + p_v2.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY3.size() + p_v3.size() + sizeof(uint64_t);
ASSERT_OK(Delete(KEY1));
ASSERT_OK(Delete(KEY2));
ASSERT_OK(Delete(KEY3));
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY1.size() + KEY2.size() + KEY3.size() + 3 * sizeof(uint64_t);
}
// The memtable data bytes includes the "garbage"
// bytes along with the useful payload.
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH =
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH;
// Note : one set of delete for KEY1, KEY2, KEY3 is written to
// SSTable to propagate the delete operations to K-V pairs
// that could have been inserted into the database during past Flush
// opeartions.
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH -=
KEY1.size() + KEY2.size() + KEY3.size() + 3 * sizeof(uint64_t);
// Additional useful paylaod.
ASSERT_OK(Delete(KEY4));
ASSERT_OK(Delete(KEY5));
ASSERT_OK(Delete(KEY6));
// // Add useful payload to the memtable data bytes:
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH +=
KEY4.size() + KEY5.size() + KEY6.size() + 3 * sizeof(uint64_t);
// We assert that the K-V pairs have been successfully deleted.
PinnableSlice value;
ASSERT_NOK(Get(KEY1, &value));
ASSERT_NOK(Get(KEY2, &value));
ASSERT_NOK(Get(KEY3, &value));
// Force flush to SST. Increments the statistics counter.
ASSERT_OK(Flush());
// Collect statistics.
uint64_t mem_data_bytes =
TestGetTickerCount(options, MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
uint64_t mem_garbage_bytes =
TestGetTickerCount(options, MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
EXPECT_EQ(mem_data_bytes, EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
EXPECT_EQ(mem_garbage_bytes, EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
Close();
}
TEST_F(DBFlushTest, StatisticsGarbageRangeDeletes) {
Options options = CurrentOptions();
options.statistics = CreateDBStatistics();
options.statistics->set_stats_level(StatsLevel::kAll);
options.create_if_missing = true;
options.compression = kNoCompression;
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
options.write_buffer_size = 67108864;
ASSERT_OK(TryReopen(options));
const size_t NUM_REPEAT = 1000;
const size_t RAND_VALUES_LENGTH = 42;
const std::string KEY1 = "key1";
const std::string KEY2 = "key2";
const std::string KEY3 = "key3";
const std::string KEY4 = "key4";
const std::string KEY5 = "key5";
const std::string KEY6 = "key6";
const std::string VALUE3 = "value3";
uint64_t EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH = 0;
uint64_t EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH = 0;
Random rnd(301);
// Insertion of of K-V pairs, multiple times.
// Also insert DeleteRange
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
std::string p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
std::string p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY1.size() + p_v1.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY2.size() + p_v2.size() + sizeof(uint64_t);
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
KEY3.size() + p_v3.size() + sizeof(uint64_t);
ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY1,
KEY2));
// Note: DeleteRange have an exclusive upper bound, e.g. here: [KEY2,KEY3)
// is deleted.
ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY2,
KEY3));
// Delete ranges are stored as a regular K-V pair, with key=STARTKEY,
// value=ENDKEY.
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH +=
(KEY1.size() + KEY2.size() + sizeof(uint64_t)) +
(KEY2.size() + KEY3.size() + sizeof(uint64_t));
}
// The memtable data bytes includes the "garbage"
// bytes along with the useful payload.
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH =
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH;
// Note : one set of deleteRange for (KEY1, KEY2) and (KEY2, KEY3) is written
// to SSTable to propagate the deleteRange operations to K-V pairs that could
// have been inserted into the database during past Flush opeartions.
EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH -=
(KEY1.size() + KEY2.size() + sizeof(uint64_t)) +
(KEY2.size() + KEY3.size() + sizeof(uint64_t));
// Overwrite KEY3 with known value (VALUE3)
// Note that during the whole time KEY3 has never been deleted
// by the RangeDeletes.
ASSERT_OK(Put(KEY3, VALUE3));
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH +=
KEY3.size() + VALUE3.size() + sizeof(uint64_t);
// Additional useful paylaod.
ASSERT_OK(
db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY4, KEY5));
ASSERT_OK(
db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY5, KEY6));
// Add useful payload to the memtable data bytes:
EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH +=
(KEY4.size() + KEY5.size() + sizeof(uint64_t)) +
(KEY5.size() + KEY6.size() + sizeof(uint64_t));
// We assert that the K-V pairs have been successfully deleted.
PinnableSlice value;
ASSERT_NOK(Get(KEY1, &value));
ASSERT_NOK(Get(KEY2, &value));
// And that KEY3's value is correct.
ASSERT_OK(Get(KEY3, &value));
ASSERT_EQ(value, VALUE3);
// Force flush to SST. Increments the statistics counter.
ASSERT_OK(Flush());
// Collect statistics.
uint64_t mem_data_bytes =
TestGetTickerCount(options, MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
uint64_t mem_garbage_bytes =
TestGetTickerCount(options, MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
EXPECT_EQ(mem_data_bytes, EXPECTED_MEMTABLE_PAYLOAD_BYTES_AT_FLUSH);
EXPECT_EQ(mem_garbage_bytes, EXPECTED_MEMTABLE_GARBAGE_BYTES_AT_FLUSH);
Close();
}
#ifndef ROCKSDB_LITE
// This simple Listener can only handle one flush at a time.
class TestFlushListener : public EventListener {
public:
TestFlushListener(Env* env, DBFlushTest* test)
: slowdown_count(0), stop_count(0), db_closed(), env_(env), test_(test) {
db_closed = false;
}
~TestFlushListener() override {
prev_fc_info_.status.PermitUncheckedError(); // Ignore the status
}
void OnTableFileCreated(const TableFileCreationInfo& info) override {
// remember the info for later checking the FlushJobInfo.
prev_fc_info_ = info;
ASSERT_GT(info.db_name.size(), 0U);
ASSERT_GT(info.cf_name.size(), 0U);
ASSERT_GT(info.file_path.size(), 0U);
ASSERT_GT(info.job_id, 0);
ASSERT_GT(info.table_properties.data_size, 0U);
ASSERT_GT(info.table_properties.raw_key_size, 0U);
ASSERT_GT(info.table_properties.raw_value_size, 0U);
ASSERT_GT(info.table_properties.num_data_blocks, 0U);
ASSERT_GT(info.table_properties.num_entries, 0U);
ASSERT_EQ(info.file_checksum, kUnknownFileChecksum);
ASSERT_EQ(info.file_checksum_func_name, kUnknownFileChecksumFuncName);
}
void OnFlushCompleted(DB* db, const FlushJobInfo& info) override {
flushed_dbs_.push_back(db);
flushed_column_family_names_.push_back(info.cf_name);
if (info.triggered_writes_slowdown) {
slowdown_count++;
}
if (info.triggered_writes_stop) {
stop_count++;
}
// verify whether the previously created file matches the flushed file.
ASSERT_EQ(prev_fc_info_.db_name, db->GetName());
ASSERT_EQ(prev_fc_info_.cf_name, info.cf_name);
ASSERT_EQ(prev_fc_info_.job_id, info.job_id);
ASSERT_EQ(prev_fc_info_.file_path, info.file_path);
ASSERT_EQ(TableFileNameToNumber(info.file_path), info.file_number);
// Note: the following chunk relies on the notification pertaining to the
// database pointed to by DBTestBase::db_, and is thus bypassed when
// that assumption does not hold (see the test case MultiDBMultiListeners
// below).
ASSERT_TRUE(test_);
if (db == test_->db_) {
std::vector<std::vector<FileMetaData>> files_by_level;
test_->dbfull()->TEST_GetFilesMetaData(db->DefaultColumnFamily(),
&files_by_level);
ASSERT_FALSE(files_by_level.empty());
auto it = std::find_if(files_by_level[0].begin(), files_by_level[0].end(),
[&](const FileMetaData& meta) {
return meta.fd.GetNumber() == info.file_number;
});
ASSERT_NE(it, files_by_level[0].end());
ASSERT_EQ(info.oldest_blob_file_number, it->oldest_blob_file_number);
}
ASSERT_EQ(db->GetEnv()->GetThreadID(), info.thread_id);
ASSERT_GT(info.thread_id, 0U);
}
std::vector<std::string> flushed_column_family_names_;
std::vector<DB*> flushed_dbs_;
int slowdown_count;
int stop_count;
bool db_closing;
std::atomic_bool db_closed;
TableFileCreationInfo prev_fc_info_;
protected:
Env* env_;
DBFlushTest* test_;
};
#endif // !ROCKSDB_LITE
TEST_F(DBFlushTest, MemPurgeBasic) {
Options options = CurrentOptions();
// The following options are used to enforce several values that
// may already exist as default values to make this test resilient
// to default value updates in the future.
options.statistics = CreateDBStatistics();
// Record all statistics.
options.statistics->set_stats_level(StatsLevel::kAll);
// create the DB if it's not already present
options.create_if_missing = true;
// Useful for now as we are trying to compare uncompressed data savings on
// flush().
options.compression = kNoCompression;
// Prevent memtable in place updates. Should already be disabled
// (from Wiki:
// In place updates can be enabled by toggling on the bool
// inplace_update_support flag. However, this flag is by default set to
// false
// because this thread-safe in-place update support is not compatible
// with concurrent memtable writes. Note that the bool
// allow_concurrent_memtable_write is set to true by default )
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
// Enforce size of a single MemTable to 64MB (64MB = 67108864 bytes).
options.write_buffer_size = 1 << 20;
// Activate the MemPurge prototype.
options.experimental_mempurge_threshold = 1.0;
#ifndef ROCKSDB_LITE
TestFlushListener* listener = new TestFlushListener(options.env, this);
options.listeners.emplace_back(listener);
#endif // !ROCKSDB_LITE
ASSERT_OK(TryReopen(options));
uint32_t mempurge_count = 0;
uint32_t sst_count = 0;
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:MemPurgeSuccessful",
[&](void* /*arg*/) { mempurge_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:SSTFileCreated", [&](void* /*arg*/) { sst_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing();
std::string KEY1 = "IamKey1";
std::string KEY2 = "IamKey2";
std::string KEY3 = "IamKey3";
std::string KEY4 = "IamKey4";
std::string KEY5 = "IamKey5";
std::string KEY6 = "IamKey6";
std::string KEY7 = "IamKey7";
std::string KEY8 = "IamKey8";
std::string KEY9 = "IamKey9";
std::string RNDKEY1, RNDKEY2, RNDKEY3;
const std::string NOT_FOUND = "NOT_FOUND";
// Heavy overwrite workload,
// more than would fit in maximum allowed memtables.
Random rnd(719);
const size_t NUM_REPEAT = 100;
const size_t RAND_KEYS_LENGTH = 57;
const size_t RAND_VALUES_LENGTH = 10240;
std::string p_v1, p_v2, p_v3, p_v4, p_v5, p_v6, p_v7, p_v8, p_v9, p_rv1,
p_rv2, p_rv3;
// Insert a very first set of keys that will be
// mempurged at least once.
p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v4 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
ASSERT_OK(Put(KEY4, p_v4));
ASSERT_EQ(Get(KEY1), p_v1);
ASSERT_EQ(Get(KEY2), p_v2);
ASSERT_EQ(Get(KEY3), p_v3);
ASSERT_EQ(Get(KEY4), p_v4);
// Insertion of of K-V pairs, multiple times (overwrites).
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
p_v5 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v6 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v7 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v8 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v9 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY5, p_v5));
ASSERT_OK(Put(KEY6, p_v6));
ASSERT_OK(Put(KEY7, p_v7));
ASSERT_OK(Put(KEY8, p_v8));
ASSERT_OK(Put(KEY9, p_v9));
ASSERT_EQ(Get(KEY1), p_v1);
ASSERT_EQ(Get(KEY2), p_v2);
ASSERT_EQ(Get(KEY3), p_v3);
ASSERT_EQ(Get(KEY4), p_v4);
ASSERT_EQ(Get(KEY5), p_v5);
ASSERT_EQ(Get(KEY6), p_v6);
ASSERT_EQ(Get(KEY7), p_v7);
ASSERT_EQ(Get(KEY8), p_v8);
ASSERT_EQ(Get(KEY9), p_v9);
}
// Check that there was at least one mempurge
const uint32_t EXPECTED_MIN_MEMPURGE_COUNT = 1;
// Check that there was no SST files created during flush.
const uint32_t EXPECTED_SST_COUNT = 0;
EXPECT_GE(mempurge_count, EXPECTED_MIN_MEMPURGE_COUNT);
EXPECT_EQ(sst_count, EXPECTED_SST_COUNT);
const uint32_t mempurge_count_record = mempurge_count;
// Insertion of of K-V pairs, no overwrites.
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
RNDKEY1 = rnd.RandomString(RAND_KEYS_LENGTH);
RNDKEY2 = rnd.RandomString(RAND_KEYS_LENGTH);
RNDKEY3 = rnd.RandomString(RAND_KEYS_LENGTH);
p_rv1 = rnd.RandomString(RAND_VALUES_LENGTH);
p_rv2 = rnd.RandomString(RAND_VALUES_LENGTH);
p_rv3 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(RNDKEY1, p_rv1));
ASSERT_OK(Put(RNDKEY2, p_rv2));
ASSERT_OK(Put(RNDKEY3, p_rv3));
ASSERT_EQ(Get(KEY1), p_v1);
ASSERT_EQ(Get(KEY2), p_v2);
ASSERT_EQ(Get(KEY3), p_v3);
ASSERT_EQ(Get(KEY4), p_v4);
ASSERT_EQ(Get(KEY5), p_v5);
ASSERT_EQ(Get(KEY6), p_v6);
ASSERT_EQ(Get(KEY7), p_v7);
ASSERT_EQ(Get(KEY8), p_v8);
ASSERT_EQ(Get(KEY9), p_v9);
ASSERT_EQ(Get(RNDKEY1), p_rv1);
ASSERT_EQ(Get(RNDKEY2), p_rv2);
ASSERT_EQ(Get(RNDKEY3), p_rv3);
}
// Assert that at least one flush to storage has been performed
ASSERT_GT(sst_count, EXPECTED_SST_COUNT);
// (which will consequently increase the number of mempurges recorded too).
ASSERT_GE(mempurge_count, mempurge_count_record);
// Assert that there is no data corruption, even with
// a flush to storage.
ASSERT_EQ(Get(KEY1), p_v1);
ASSERT_EQ(Get(KEY2), p_v2);
ASSERT_EQ(Get(KEY3), p_v3);
ASSERT_EQ(Get(KEY4), p_v4);
ASSERT_EQ(Get(KEY5), p_v5);
ASSERT_EQ(Get(KEY6), p_v6);
ASSERT_EQ(Get(KEY7), p_v7);
ASSERT_EQ(Get(KEY8), p_v8);
ASSERT_EQ(Get(KEY9), p_v9);
ASSERT_EQ(Get(RNDKEY1), p_rv1);
ASSERT_EQ(Get(RNDKEY2), p_rv2);
ASSERT_EQ(Get(RNDKEY3), p_rv3);
Close();
}
TEST_F(DBFlushTest, MemPurgeDeleteAndDeleteRange) {
Options options = CurrentOptions();
options.statistics = CreateDBStatistics();
options.statistics->set_stats_level(StatsLevel::kAll);
options.create_if_missing = true;
options.compression = kNoCompression;
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
#ifndef ROCKSDB_LITE
TestFlushListener* listener = new TestFlushListener(options.env, this);
options.listeners.emplace_back(listener);
#endif // !ROCKSDB_LITE
// Enforce size of a single MemTable to 64MB (64MB = 67108864 bytes).
options.write_buffer_size = 1 << 20;
// Activate the MemPurge prototype.
options.experimental_mempurge_threshold = 1.0;
ASSERT_OK(TryReopen(options));
uint32_t mempurge_count = 0;
uint32_t sst_count = 0;
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:MemPurgeSuccessful",
[&](void* /*arg*/) { mempurge_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:SSTFileCreated", [&](void* /*arg*/) { sst_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing();
std::string KEY1 = "ThisIsKey1";
std::string KEY2 = "ThisIsKey2";
std::string KEY3 = "ThisIsKey3";
std::string KEY4 = "ThisIsKey4";
std::string KEY5 = "ThisIsKey5";
const std::string NOT_FOUND = "NOT_FOUND";
Random rnd(117);
const size_t NUM_REPEAT = 100;
const size_t RAND_VALUES_LENGTH = 10240;
std::string key, value, p_v1, p_v2, p_v3, p_v3b, p_v4, p_v5;
int count = 0;
const int EXPECTED_COUNT_FORLOOP = 3;
const int EXPECTED_COUNT_END = 4;
ReadOptions ropt;
ropt.pin_data = true;
ropt.total_order_seek = true;
Iterator* iter = nullptr;
// Insertion of of K-V pairs, multiple times.
// Also insert DeleteRange
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v3b = rnd.RandomString(RAND_VALUES_LENGTH);
p_v4 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v5 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
ASSERT_OK(Put(KEY4, p_v4));
ASSERT_OK(Put(KEY5, p_v5));
ASSERT_OK(Delete(KEY2));
ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY2,
KEY4));
ASSERT_OK(Put(KEY3, p_v3b));
ASSERT_OK(db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), KEY1,
KEY3));
ASSERT_OK(Delete(KEY1));
ASSERT_EQ(Get(KEY1), NOT_FOUND);
ASSERT_EQ(Get(KEY2), NOT_FOUND);
ASSERT_EQ(Get(KEY3), p_v3b);
ASSERT_EQ(Get(KEY4), p_v4);
ASSERT_EQ(Get(KEY5), p_v5);
iter = db_->NewIterator(ropt);
iter->SeekToFirst();
count = 0;
for (; iter->Valid(); iter->Next()) {
ASSERT_OK(iter->status());
key = (iter->key()).ToString(false);
value = (iter->value()).ToString(false);
if (key.compare(KEY3) == 0)
ASSERT_EQ(value, p_v3b);
else if (key.compare(KEY4) == 0)
ASSERT_EQ(value, p_v4);
else if (key.compare(KEY5) == 0)
ASSERT_EQ(value, p_v5);
else
ASSERT_EQ(value, NOT_FOUND);
count++;
}
// Expected count here is 3: KEY3, KEY4, KEY5.
ASSERT_EQ(count, EXPECTED_COUNT_FORLOOP);
if (iter) {
delete iter;
}
}
// Check that there was at least one mempurge
const uint32_t EXPECTED_MIN_MEMPURGE_COUNT = 1;
// Check that there was no SST files created during flush.
const uint32_t EXPECTED_SST_COUNT = 0;
EXPECT_GE(mempurge_count, EXPECTED_MIN_MEMPURGE_COUNT);
EXPECT_EQ(sst_count, EXPECTED_SST_COUNT);
// Additional test for the iterator+memPurge.
ASSERT_OK(Put(KEY2, p_v2));
iter = db_->NewIterator(ropt);
iter->SeekToFirst();
ASSERT_OK(Put(KEY4, p_v4));
count = 0;
for (; iter->Valid(); iter->Next()) {
ASSERT_OK(iter->status());
key = (iter->key()).ToString(false);
value = (iter->value()).ToString(false);
if (key.compare(KEY2) == 0)
ASSERT_EQ(value, p_v2);
else if (key.compare(KEY3) == 0)
ASSERT_EQ(value, p_v3b);
else if (key.compare(KEY4) == 0)
ASSERT_EQ(value, p_v4);
else if (key.compare(KEY5) == 0)
ASSERT_EQ(value, p_v5);
else
ASSERT_EQ(value, NOT_FOUND);
count++;
}
// Expected count here is 4: KEY2, KEY3, KEY4, KEY5.
ASSERT_EQ(count, EXPECTED_COUNT_END);
if (iter) delete iter;
Close();
}
// Create a Compaction Fitler that will be invoked
// at flush time and will update the value of a KV pair
// if the key string is "lower" than the filter_key_ string.
class ConditionalUpdateFilter : public CompactionFilter {
public:
explicit ConditionalUpdateFilter(const std::string* filtered_key)
: filtered_key_(filtered_key) {}
bool Filter(int /*level*/, const Slice& key, const Slice& /*value*/,
std::string* new_value, bool* value_changed) const override {
// If key<filtered_key_, update the value of the KV-pair.
if (key.compare(*filtered_key_) < 0) {
assert(new_value != nullptr);
*new_value = NEW_VALUE;
*value_changed = true;
}
return false /*do not remove this KV-pair*/;
}
const char* Name() const override { return "ConditionalUpdateFilter"; }
private:
const std::string* filtered_key_;
};
class ConditionalUpdateFilterFactory : public CompactionFilterFactory {
public:
explicit ConditionalUpdateFilterFactory(const Slice& filtered_key)
: filtered_key_(filtered_key.ToString()) {}
std::unique_ptr<CompactionFilter> CreateCompactionFilter(
const CompactionFilter::Context& /*context*/) override {
return std::unique_ptr<CompactionFilter>(
new ConditionalUpdateFilter(&filtered_key_));
}
const char* Name() const override { return "ConditionalUpdateFilterFactory"; }
bool ShouldFilterTableFileCreation(
TableFileCreationReason reason) const override {
// This compaction filter will be invoked
// at flush time (and therefore at MemPurge time).
return (reason == TableFileCreationReason::kFlush);
}
private:
std::string filtered_key_;
};
TEST_F(DBFlushTest, MemPurgeAndCompactionFilter) {
Options options = CurrentOptions();
std::string KEY1 = "ThisIsKey1";
std::string KEY2 = "ThisIsKey2";
std::string KEY3 = "ThisIsKey3";
std::string KEY4 = "ThisIsKey4";
std::string KEY5 = "ThisIsKey5";
std::string KEY6 = "ThisIsKey6";
std::string KEY7 = "ThisIsKey7";
std::string KEY8 = "ThisIsKey8";
std::string KEY9 = "ThisIsKey9";
const std::string NOT_FOUND = "NOT_FOUND";
options.statistics = CreateDBStatistics();
options.statistics->set_stats_level(StatsLevel::kAll);
options.create_if_missing = true;
options.compression = kNoCompression;
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
#ifndef ROCKSDB_LITE
TestFlushListener* listener = new TestFlushListener(options.env, this);
options.listeners.emplace_back(listener);
#endif // !ROCKSDB_LITE
// Create a ConditionalUpdate compaction filter
// that will update all the values of the KV pairs
// where the keys are "lower" than KEY4.
options.compaction_filter_factory =
std::make_shared<ConditionalUpdateFilterFactory>(KEY4);
// Enforce size of a single MemTable to 64MB (64MB = 67108864 bytes).
options.write_buffer_size = 1 << 20;
// Activate the MemPurge prototype.
options.experimental_mempurge_threshold = 1.0;
ASSERT_OK(TryReopen(options));
uint32_t mempurge_count = 0;
uint32_t sst_count = 0;
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:MemPurgeSuccessful",
[&](void* /*arg*/) { mempurge_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:SSTFileCreated", [&](void* /*arg*/) { sst_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing();
Random rnd(53);
const size_t NUM_REPEAT = 1000;
const size_t RAND_VALUES_LENGTH = 10240;
std::string p_v1, p_v2, p_v3, p_v4, p_v5, p_v6, p_v7, p_v8, p_v9;
p_v1 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v2 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v3 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v4 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v5 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY1, p_v1));
ASSERT_OK(Put(KEY2, p_v2));
ASSERT_OK(Put(KEY3, p_v3));
ASSERT_OK(Put(KEY4, p_v4));
ASSERT_OK(Put(KEY5, p_v5));
ASSERT_OK(Delete(KEY1));
// Insertion of of K-V pairs, multiple times.
for (size_t i = 0; i < NUM_REPEAT; i++) {
// Create value strings of arbitrary
// length RAND_VALUES_LENGTH bytes.
p_v6 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v7 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v8 = rnd.RandomString(RAND_VALUES_LENGTH);
p_v9 = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(KEY6, p_v6));
ASSERT_OK(Put(KEY7, p_v7));
ASSERT_OK(Put(KEY8, p_v8));
ASSERT_OK(Put(KEY9, p_v9));
ASSERT_OK(Delete(KEY7));
}
// Check that there was at least one mempurge
const uint32_t EXPECTED_MIN_MEMPURGE_COUNT = 1;
// Check that there was no SST files created during flush.
const uint32_t EXPECTED_SST_COUNT = 0;
EXPECT_GE(mempurge_count, EXPECTED_MIN_MEMPURGE_COUNT);
EXPECT_EQ(sst_count, EXPECTED_SST_COUNT);
// Verify that the ConditionalUpdateCompactionFilter
// updated the values of KEY2 and KEY3, and not KEY4 and KEY5.
ASSERT_EQ(Get(KEY1), NOT_FOUND);
ASSERT_EQ(Get(KEY2), NEW_VALUE);
ASSERT_EQ(Get(KEY3), NEW_VALUE);
ASSERT_EQ(Get(KEY4), p_v4);
ASSERT_EQ(Get(KEY5), p_v5);
}
TEST_F(DBFlushTest, MemPurgeWALSupport) {
Options options = CurrentOptions();
options.statistics = CreateDBStatistics();
options.statistics->set_stats_level(StatsLevel::kAll);
options.create_if_missing = true;
options.compression = kNoCompression;
options.inplace_update_support = false;
options.allow_concurrent_memtable_write = true;
// Enforce size of a single MemTable to 128KB.
options.write_buffer_size = 128 << 10;
// Activate the MemPurge prototype.
options.experimental_mempurge_threshold = 1.0;
ASSERT_OK(TryReopen(options));
const size_t KVSIZE = 10;
do {
CreateAndReopenWithCF({"pikachu"}, options);
ASSERT_OK(Put(1, "foo", "v1"));
ASSERT_OK(Put(1, "baz", "v5"));
ReopenWithColumnFamilies({"default", "pikachu"}, options);
ASSERT_EQ("v1", Get(1, "foo"));
ASSERT_EQ("v1", Get(1, "foo"));
ASSERT_EQ("v5", Get(1, "baz"));
ASSERT_OK(Put(0, "bar", "v2"));
ASSERT_OK(Put(1, "bar", "v2"));
ASSERT_OK(Put(1, "foo", "v3"));
uint32_t mempurge_count = 0;
uint32_t sst_count = 0;
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:MemPurgeSuccessful",
[&](void* /*arg*/) { mempurge_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"DBImpl::FlushJob:SSTFileCreated", [&](void* /*arg*/) { sst_count++; });
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing();
std::vector<std::string> keys;
for (size_t k = 0; k < KVSIZE; k++) {
keys.push_back("IamKey" + std::to_string(k));
}
std::string RNDKEY, RNDVALUE;
const std::string NOT_FOUND = "NOT_FOUND";
// Heavy overwrite workload,
// more than would fit in maximum allowed memtables.
Random rnd(719);
const size_t NUM_REPEAT = 100;
const size_t RAND_KEY_LENGTH = 4096;
const size_t RAND_VALUES_LENGTH = 1024;
std::vector<std::string> values_default(KVSIZE), values_pikachu(KVSIZE);
// Insert a very first set of keys that will be
// mempurged at least once.
for (size_t k = 0; k < KVSIZE / 2; k++) {
values_default[k] = rnd.RandomString(RAND_VALUES_LENGTH);
values_pikachu[k] = rnd.RandomString(RAND_VALUES_LENGTH);
}
// Insert keys[0:KVSIZE/2] to
// both 'default' and 'pikachu' CFs.
for (size_t k = 0; k < KVSIZE / 2; k++) {
ASSERT_OK(Put(0, keys[k], values_default[k]));
ASSERT_OK(Put(1, keys[k], values_pikachu[k]));
}
// Check that the insertion was seamless.
for (size_t k = 0; k < KVSIZE / 2; k++) {
ASSERT_EQ(Get(0, keys[k]), values_default[k]);
ASSERT_EQ(Get(1, keys[k]), values_pikachu[k]);
}
// Insertion of of K-V pairs, multiple times (overwrites)
// into 'default' CF. Will trigger mempurge.
for (size_t j = 0; j < NUM_REPEAT; j++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
for (size_t k = KVSIZE / 2; k < KVSIZE; k++) {
values_default[k] = rnd.RandomString(RAND_VALUES_LENGTH);
}
// Insert K-V into default CF.
for (size_t k = KVSIZE / 2; k < KVSIZE; k++) {
ASSERT_OK(Put(0, keys[k], values_default[k]));
}
// Check key validity, for all keys, both in
// default and pikachu CFs.
for (size_t k = 0; k < KVSIZE; k++) {
ASSERT_EQ(Get(0, keys[k]), values_default[k]);
}
// Note that at this point, only keys[0:KVSIZE/2]
// have been inserted into Pikachu.
for (size_t k = 0; k < KVSIZE / 2; k++) {
ASSERT_EQ(Get(1, keys[k]), values_pikachu[k]);
}
}
// Insertion of of K-V pairs, multiple times (overwrites)
// into 'pikachu' CF. Will trigger mempurge.
// Check that we keep the older logs for 'default' imm().
for (size_t j = 0; j < NUM_REPEAT; j++) {
// Create value strings of arbitrary length RAND_VALUES_LENGTH bytes.
for (size_t k = KVSIZE / 2; k < KVSIZE; k++) {
values_pikachu[k] = rnd.RandomString(RAND_VALUES_LENGTH);
}
// Insert K-V into pikachu CF.
for (size_t k = KVSIZE / 2; k < KVSIZE; k++) {
ASSERT_OK(Put(1, keys[k], values_pikachu[k]));
}
// Check key validity, for all keys,
// both in default and pikachu.
for (size_t k = 0; k < KVSIZE; k++) {
ASSERT_EQ(Get(0, keys[k]), values_default[k]);
ASSERT_EQ(Get(1, keys[k]), values_pikachu[k]);
}
}
// Check that there was at least one mempurge
const uint32_t EXPECTED_MIN_MEMPURGE_COUNT = 1;
// Check that there was no SST files created during flush.
const uint32_t EXPECTED_SST_COUNT = 0;
EXPECT_GE(mempurge_count, EXPECTED_MIN_MEMPURGE_COUNT);
if (options.experimental_mempurge_threshold ==
std::numeric_limits<double>::max()) {
EXPECT_EQ(sst_count, EXPECTED_SST_COUNT);
}
ReopenWithColumnFamilies({"default", "pikachu"}, options);
// Check that there was no data corruption anywhere,
// not in 'default' nor in 'Pikachu' CFs.
ASSERT_EQ("v3", Get(1, "foo"));
ASSERT_OK(Put(1, "foo", "v4"));
ASSERT_EQ("v4", Get(1, "foo"));
ASSERT_EQ("v2", Get(1, "bar"));
ASSERT_EQ("v5", Get(1, "baz"));
// Check keys in 'Default' and 'Pikachu'.
// keys[0:KVSIZE/2] were for sure contained
// in the imm() at Reopen/recovery time.
for (size_t k = 0; k < KVSIZE; k++) {
ASSERT_EQ(Get(0, keys[k]), values_default[k]);
ASSERT_EQ(Get(1, keys[k]), values_pikachu[k]);
}
// Insertion of random K-V pairs to trigger
// a flush in the Pikachu CF.
for (size_t j = 0; j < NUM_REPEAT; j++) {
RNDKEY = rnd.RandomString(RAND_KEY_LENGTH);
RNDVALUE = rnd.RandomString(RAND_VALUES_LENGTH);
ASSERT_OK(Put(1, RNDKEY, RNDVALUE));
}
// ASsert than there was at least one flush to storage.
EXPECT_GT(sst_count, EXPECTED_SST_COUNT);
ReopenWithColumnFamilies({"default", "pikachu"}, options);
ASSERT_EQ("v4", Get(1, "foo"));
ASSERT_EQ("v2", Get(1, "bar"));
ASSERT_EQ("v5", Get(1, "baz"));
// Since values in default are held in mutable mem()
// and imm(), check if the flush in pikachu didn't
// affect these values.
for (size_t k = 0; k < KVSIZE; k++) {
ASSERT_EQ(Get(0, keys[k]), values_default[k]);
ASSERT_EQ(Get(1, keys[k]), values_pikachu[k]);
}
ASSERT_EQ(Get(1, RNDKEY), RNDVALUE);
} while (ChangeWalOptions());
}
TEST_P(DBFlushDirectIOTest, DirectIO) {
Options options;
options.create_if_missing = true;
options.disable_auto_compactions = true;
options.max_background_flushes = 2;
options.use_direct_io_for_flush_and_compaction = GetParam();
options.env = MockEnv::Create(Env::Default());
SyncPoint::GetInstance()->SetCallBack(
"BuildTable:create_file", [&](void* arg) {
bool* use_direct_writes = static_cast<bool*>(arg);
ASSERT_EQ(*use_direct_writes,
options.use_direct_io_for_flush_and_compaction);
});
SyncPoint::GetInstance()->EnableProcessing();
Reopen(options);
ASSERT_OK(Put("foo", "v"));
FlushOptions flush_options;
flush_options.wait = true;
ASSERT_OK(dbfull()->Flush(flush_options));
Destroy(options);
delete options.env;
}
TEST_F(DBFlushTest, FlushError) {
Options options;
std::unique_ptr<FaultInjectionTestEnv> fault_injection_env(
new FaultInjectionTestEnv(env_));
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
options.disable_auto_compactions = true;
options.env = fault_injection_env.get();
Reopen(options);
ASSERT_OK(Put("key1", "value1"));
ASSERT_OK(Put("key2", "value2"));
fault_injection_env->SetFilesystemActive(false);
Status s = dbfull()->TEST_SwitchMemtable();
fault_injection_env->SetFilesystemActive(true);
Destroy(options);
ASSERT_NE(s, Status::OK());
}
TEST_F(DBFlushTest, ManualFlushFailsInReadOnlyMode) {
// Regression test for bug where manual flush hangs forever when the DB
// is in read-only mode. Verify it now at least returns, despite failing.
Options options;
std::unique_ptr<FaultInjectionTestEnv> fault_injection_env(
new FaultInjectionTestEnv(env_));
options.env = fault_injection_env.get();
options.max_write_buffer_number = 2;
Reopen(options);
// Trigger a first flush but don't let it run
ASSERT_OK(db_->PauseBackgroundWork());
ASSERT_OK(Put("key1", "value1"));
FlushOptions flush_opts;
flush_opts.wait = false;
ASSERT_OK(db_->Flush(flush_opts));
// Write a key to the second memtable so we have something to flush later
// after the DB is in read-only mode.
ASSERT_OK(Put("key2", "value2"));
// Let the first flush continue, hit an error, and put the DB in read-only
// mode.
fault_injection_env->SetFilesystemActive(false);
ASSERT_OK(db_->ContinueBackgroundWork());
// We ingested the error to env, so the returned status is not OK.
ASSERT_NOK(dbfull()->TEST_WaitForFlushMemTable());
#ifndef ROCKSDB_LITE
uint64_t num_bg_errors;
ASSERT_TRUE(db_->GetIntProperty(DB::Properties::kBackgroundErrors,
&num_bg_errors));
ASSERT_GT(num_bg_errors, 0);
#endif // ROCKSDB_LITE
// In the bug scenario, triggering another flush would cause the second flush
// to hang forever. After the fix we expect it to return an error.
ASSERT_NOK(db_->Flush(FlushOptions()));
Close();
}
TEST_F(DBFlushTest, CFDropRaceWithWaitForFlushMemTables) {
Options options = CurrentOptions();
options.create_if_missing = true;
CreateAndReopenWithCF({"pikachu"}, options);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::FlushMemTable:AfterScheduleFlush",
"DBFlushTest::CFDropRaceWithWaitForFlushMemTables:BeforeDrop"},
{"DBFlushTest::CFDropRaceWithWaitForFlushMemTables:AfterFree",
"DBImpl::BackgroundCallFlush:start"},
{"DBImpl::BackgroundCallFlush:start",
"DBImpl::FlushMemTable:BeforeWaitForBgFlush"}});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_EQ(2, handles_.size());
ASSERT_OK(Put(1, "key", "value"));
auto* cfd = static_cast<ColumnFamilyHandleImpl*>(handles_[1])->cfd();
port::Thread drop_cf_thr([&]() {
TEST_SYNC_POINT(
"DBFlushTest::CFDropRaceWithWaitForFlushMemTables:BeforeDrop");
ASSERT_OK(dbfull()->DropColumnFamily(handles_[1]));
ASSERT_OK(dbfull()->DestroyColumnFamilyHandle(handles_[1]));
handles_.resize(1);
TEST_SYNC_POINT(
"DBFlushTest::CFDropRaceWithWaitForFlushMemTables:AfterFree");
});
FlushOptions flush_opts;
flush_opts.allow_write_stall = true;
ASSERT_NOK(dbfull()->TEST_FlushMemTable(cfd, flush_opts));
drop_cf_thr.join();
Close();
SyncPoint::GetInstance()->DisableProcessing();
}
#ifndef ROCKSDB_LITE
TEST_F(DBFlushTest, FireOnFlushCompletedAfterCommittedResult) {
class TestListener : public EventListener {
public:
void OnFlushCompleted(DB* db, const FlushJobInfo& info) override {
// There's only one key in each flush.
ASSERT_EQ(info.smallest_seqno, info.largest_seqno);
ASSERT_NE(0, info.smallest_seqno);
if (info.smallest_seqno == seq1) {
// First flush completed
ASSERT_FALSE(completed1);
completed1 = true;
CheckFlushResultCommitted(db, seq1);
} else {
// Second flush completed
ASSERT_FALSE(completed2);
completed2 = true;
ASSERT_EQ(info.smallest_seqno, seq2);
CheckFlushResultCommitted(db, seq2);
}
}
void CheckFlushResultCommitted(DB* db, SequenceNumber seq) {
DBImpl* db_impl = static_cast_with_check<DBImpl>(db);
InstrumentedMutex* mutex = db_impl->mutex();
mutex->Lock();
auto* cfd = static_cast_with_check<ColumnFamilyHandleImpl>(
db->DefaultColumnFamily())
->cfd();
ASSERT_LT(seq, cfd->imm()->current()->GetEarliestSequenceNumber());
mutex->Unlock();
}
std::atomic<SequenceNumber> seq1{0};
std::atomic<SequenceNumber> seq2{0};
std::atomic<bool> completed1{false};
std::atomic<bool> completed2{false};
};
std::shared_ptr<TestListener> listener = std::make_shared<TestListener>();
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::FlushMemTableToOutputFile:AfterPickMemtables",
"DBFlushTest::FireOnFlushCompletedAfterCommittedResult:WaitFirst"},
{"DBImpl::FlushMemTableToOutputFile:Finish",
"DBFlushTest::FireOnFlushCompletedAfterCommittedResult:WaitSecond"}});
SyncPoint::GetInstance()->SetCallBack(
"FlushJob::WriteLevel0Table", [&listener](void* arg) {
// Wait for the second flush finished, out of mutex.
auto* mems = reinterpret_cast<autovector<MemTable*>*>(arg);
if (mems->front()->GetEarliestSequenceNumber() == listener->seq1 - 1) {
TEST_SYNC_POINT(
"DBFlushTest::FireOnFlushCompletedAfterCommittedResult:"
"WaitSecond");
}
});
Options options = CurrentOptions();
options.create_if_missing = true;
options.listeners.push_back(listener);
// Setting max_flush_jobs = max_background_jobs / 4 = 2.
options.max_background_jobs = 8;
// Allow 2 immutable memtables.
options.max_write_buffer_number = 3;
Reopen(options);
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put("foo", "v"));
listener->seq1 = db_->GetLatestSequenceNumber();
// t1 will wait for the second flush complete before committing flush result.
auto t1 = port::Thread([&]() {
// flush_opts.wait = true
ASSERT_OK(db_->Flush(FlushOptions()));
});
// Wait for first flush started.
TEST_SYNC_POINT(
"DBFlushTest::FireOnFlushCompletedAfterCommittedResult:WaitFirst");
// The second flush will exit early without commit its result. The work
// is delegated to the first flush.
ASSERT_OK(Put("bar", "v"));
listener->seq2 = db_->GetLatestSequenceNumber();
FlushOptions flush_opts;
flush_opts.wait = false;
ASSERT_OK(db_->Flush(flush_opts));
t1.join();
ASSERT_TRUE(listener->completed1);
ASSERT_TRUE(listener->completed2);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
}
#endif // !ROCKSDB_LITE
TEST_F(DBFlushTest, FlushWithBlob) {
constexpr uint64_t min_blob_size = 10;
Options options;
options.enable_blob_files = true;
options.min_blob_size = min_blob_size;
options.disable_auto_compactions = true;
options.env = env_;
Reopen(options);
constexpr char short_value[] = "short";
static_assert(sizeof(short_value) - 1 < min_blob_size,
"short_value too long");
constexpr char long_value[] = "long_value";
static_assert(sizeof(long_value) - 1 >= min_blob_size,
"long_value too short");
ASSERT_OK(Put("key1", short_value));
ASSERT_OK(Put("key2", long_value));
ASSERT_OK(Flush());
ASSERT_EQ(Get("key1"), short_value);
ASSERT_EQ(Get("key2"), long_value);
VersionSet* const versions = dbfull()->TEST_GetVersionSet();
assert(versions);
ColumnFamilyData* const cfd = versions->GetColumnFamilySet()->GetDefault();
assert(cfd);
Version* const current = cfd->current();
assert(current);
const VersionStorageInfo* const storage_info = current->storage_info();
assert(storage_info);
const auto& l0_files = storage_info->LevelFiles(0);
ASSERT_EQ(l0_files.size(), 1);
const FileMetaData* const table_file = l0_files[0];
assert(table_file);
const auto& blob_files = storage_info->GetBlobFiles();
ASSERT_EQ(blob_files.size(), 1);
const auto& blob_file = blob_files.begin()->second;
assert(blob_file);
ASSERT_EQ(table_file->smallest.user_key(), "key1");
ASSERT_EQ(table_file->largest.user_key(), "key2");
ASSERT_EQ(table_file->fd.smallest_seqno, 1);
ASSERT_EQ(table_file->fd.largest_seqno, 2);
ASSERT_EQ(table_file->oldest_blob_file_number,
blob_file->GetBlobFileNumber());
ASSERT_EQ(blob_file->GetTotalBlobCount(), 1);
#ifndef ROCKSDB_LITE
const InternalStats* const internal_stats = cfd->internal_stats();
assert(internal_stats);
const auto& compaction_stats = internal_stats->TEST_GetCompactionStats();
ASSERT_FALSE(compaction_stats.empty());
ASSERT_EQ(compaction_stats[0].bytes_written, table_file->fd.GetFileSize());
ASSERT_EQ(compaction_stats[0].bytes_written_blob,
blob_file->GetTotalBlobBytes());
ASSERT_EQ(compaction_stats[0].num_output_files, 1);
ASSERT_EQ(compaction_stats[0].num_output_files_blob, 1);
const uint64_t* const cf_stats_value = internal_stats->TEST_GetCFStatsValue();
ASSERT_EQ(cf_stats_value[InternalStats::BYTES_FLUSHED],
compaction_stats[0].bytes_written +
compaction_stats[0].bytes_written_blob);
#endif // ROCKSDB_LITE
}
TEST_F(DBFlushTest, FlushWithChecksumHandoff1) {
if (mem_env_ || encrypted_env_) {
ROCKSDB_GTEST_SKIP("Test requires non-mem or non-encrypted environment");
return;
}
std::shared_ptr<FaultInjectionTestFS> fault_fs(
new FaultInjectionTestFS(FileSystem::Default()));
std::unique_ptr<Env> fault_fs_env(NewCompositeEnv(fault_fs));
Options options = CurrentOptions();
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
options.disable_auto_compactions = true;
options.env = fault_fs_env.get();
options.checksum_handoff_file_types.Add(FileType::kTableFile);
Reopen(options);
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
ASSERT_OK(Put("key1", "value1"));
ASSERT_OK(Put("key2", "value2"));
ASSERT_OK(dbfull()->TEST_SwitchMemtable());
// The hash does not match, write fails
// fault_fs->SetChecksumHandoffFuncType(ChecksumType::kxxHash);
// Since the file system returns IOStatus::Corruption, it is an
// unrecoverable error.
SyncPoint::GetInstance()->SetCallBack("FlushJob::Start", [&](void*) {
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kxxHash);
});
ASSERT_OK(Put("key3", "value3"));
ASSERT_OK(Put("key4", "value4"));
SyncPoint::GetInstance()->EnableProcessing();
Status s = Flush();
ASSERT_EQ(s.severity(),
ROCKSDB_NAMESPACE::Status::Severity::kUnrecoverableError);
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
Reopen(options);
// The file system does not support checksum handoff. The check
// will be ignored.
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kNoChecksum);
ASSERT_OK(Put("key5", "value5"));
ASSERT_OK(Put("key6", "value6"));
ASSERT_OK(dbfull()->TEST_SwitchMemtable());
// Each write will be similated as corrupted.
// Since the file system returns IOStatus::Corruption, it is an
// unrecoverable error.
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
SyncPoint::GetInstance()->SetCallBack("FlushJob::Start", [&](void*) {
fault_fs->IngestDataCorruptionBeforeWrite();
});
ASSERT_OK(Put("key7", "value7"));
ASSERT_OK(Put("key8", "value8"));
SyncPoint::GetInstance()->EnableProcessing();
s = Flush();
ASSERT_EQ(s.severity(),
ROCKSDB_NAMESPACE::Status::Severity::kUnrecoverableError);
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
}
TEST_F(DBFlushTest, FlushWithChecksumHandoff2) {
if (mem_env_ || encrypted_env_) {
ROCKSDB_GTEST_SKIP("Test requires non-mem or non-encrypted environment");
return;
}
std::shared_ptr<FaultInjectionTestFS> fault_fs(
new FaultInjectionTestFS(FileSystem::Default()));
std::unique_ptr<Env> fault_fs_env(NewCompositeEnv(fault_fs));
Options options = CurrentOptions();
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
options.disable_auto_compactions = true;
options.env = fault_fs_env.get();
Reopen(options);
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
ASSERT_OK(Put("key1", "value1"));
ASSERT_OK(Put("key2", "value2"));
ASSERT_OK(Flush());
// options is not set, the checksum handoff will not be triggered
SyncPoint::GetInstance()->SetCallBack("FlushJob::Start", [&](void*) {
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kxxHash);
});
ASSERT_OK(Put("key3", "value3"));
ASSERT_OK(Put("key4", "value4"));
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Flush());
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
Reopen(options);
// The file system does not support checksum handoff. The check
// will be ignored.
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kNoChecksum);
ASSERT_OK(Put("key5", "value5"));
ASSERT_OK(Put("key6", "value6"));
ASSERT_OK(Flush());
// options is not set, the checksum handoff will not be triggered
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
SyncPoint::GetInstance()->SetCallBack("FlushJob::Start", [&](void*) {
fault_fs->IngestDataCorruptionBeforeWrite();
});
ASSERT_OK(Put("key7", "value7"));
ASSERT_OK(Put("key8", "value8"));
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Flush());
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
}
TEST_F(DBFlushTest, FlushWithChecksumHandoffManifest1) {
if (mem_env_ || encrypted_env_) {
ROCKSDB_GTEST_SKIP("Test requires non-mem or non-encrypted environment");
return;
}
std::shared_ptr<FaultInjectionTestFS> fault_fs(
new FaultInjectionTestFS(FileSystem::Default()));
std::unique_ptr<Env> fault_fs_env(NewCompositeEnv(fault_fs));
Options options = CurrentOptions();
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
options.disable_auto_compactions = true;
options.env = fault_fs_env.get();
options.checksum_handoff_file_types.Add(FileType::kDescriptorFile);
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
Reopen(options);
ASSERT_OK(Put("key1", "value1"));
ASSERT_OK(Put("key2", "value2"));
ASSERT_OK(Flush());
// The hash does not match, write fails
// fault_fs->SetChecksumHandoffFuncType(ChecksumType::kxxHash);
// Since the file system returns IOStatus::Corruption, it is mapped to
// kFatalError error.
ASSERT_OK(Put("key3", "value3"));
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::LogAndApply:WriteManifest", [&](void*) {
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kxxHash);
});
ASSERT_OK(Put("key3", "value3"));
ASSERT_OK(Put("key4", "value4"));
SyncPoint::GetInstance()->EnableProcessing();
Status s = Flush();
ASSERT_EQ(s.severity(), ROCKSDB_NAMESPACE::Status::Severity::kFatalError);
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
}
TEST_F(DBFlushTest, FlushWithChecksumHandoffManifest2) {
if (mem_env_ || encrypted_env_) {
ROCKSDB_GTEST_SKIP("Test requires non-mem or non-encrypted environment");
return;
}
std::shared_ptr<FaultInjectionTestFS> fault_fs(
new FaultInjectionTestFS(FileSystem::Default()));
std::unique_ptr<Env> fault_fs_env(NewCompositeEnv(fault_fs));
Options options = CurrentOptions();
options.write_buffer_size = 100;
options.max_write_buffer_number = 4;
options.min_write_buffer_number_to_merge = 3;
options.disable_auto_compactions = true;
options.env = fault_fs_env.get();
options.checksum_handoff_file_types.Add(FileType::kDescriptorFile);
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kNoChecksum);
Reopen(options);
// The file system does not support checksum handoff. The check
// will be ignored.
ASSERT_OK(Put("key5", "value5"));
ASSERT_OK(Put("key6", "value6"));
ASSERT_OK(Flush());
// Each write will be similated as corrupted.
// Since the file system returns IOStatus::Corruption, it is mapped to
// kFatalError error.
fault_fs->SetChecksumHandoffFuncType(ChecksumType::kCRC32c);
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::LogAndApply:WriteManifest",
[&](void*) { fault_fs->IngestDataCorruptionBeforeWrite(); });
ASSERT_OK(Put("key7", "value7"));
ASSERT_OK(Put("key8", "value8"));
SyncPoint::GetInstance()->EnableProcessing();
Status s = Flush();
ASSERT_EQ(s.severity(), ROCKSDB_NAMESPACE::Status::Severity::kFatalError);
SyncPoint::GetInstance()->DisableProcessing();
Destroy(options);
}
class DBFlushTestBlobError : public DBFlushTest,
public testing::WithParamInterface<std::string> {
public:
DBFlushTestBlobError() : sync_point_(GetParam()) {}
std::string sync_point_;
};
INSTANTIATE_TEST_CASE_P(DBFlushTestBlobError, DBFlushTestBlobError,
::testing::ValuesIn(std::vector<std::string>{
"BlobFileBuilder::WriteBlobToFile:AddRecord",
"BlobFileBuilder::WriteBlobToFile:AppendFooter"}));
TEST_P(DBFlushTestBlobError, FlushError) {
Options options;
options.enable_blob_files = true;
options.disable_auto_compactions = true;
options.env = env_;
Reopen(options);
ASSERT_OK(Put("key", "blob"));
SyncPoint::GetInstance()->SetCallBack(sync_point_, [this](void* arg) {
Status* const s = static_cast<Status*>(arg);
assert(s);
(*s) = Status::IOError(sync_point_);
});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_NOK(Flush());
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
VersionSet* const versions = dbfull()->TEST_GetVersionSet();
assert(versions);
ColumnFamilyData* const cfd = versions->GetColumnFamilySet()->GetDefault();
assert(cfd);
Version* const current = cfd->current();
assert(current);
const VersionStorageInfo* const storage_info = current->storage_info();
assert(storage_info);
const auto& l0_files = storage_info->LevelFiles(0);
ASSERT_TRUE(l0_files.empty());
const auto& blob_files = storage_info->GetBlobFiles();
ASSERT_TRUE(blob_files.empty());
// Make sure the files generated by the failed job have been deleted
std::vector<std::string> files;
ASSERT_OK(env_->GetChildren(dbname_, &files));
for (const auto& file : files) {
uint64_t number = 0;
FileType type = kTableFile;
if (!ParseFileName(file, &number, &type)) {
continue;
}
ASSERT_NE(type, kTableFile);
ASSERT_NE(type, kBlobFile);
}
#ifndef ROCKSDB_LITE
const InternalStats* const internal_stats = cfd->internal_stats();
assert(internal_stats);
const auto& compaction_stats = internal_stats->TEST_GetCompactionStats();
ASSERT_FALSE(compaction_stats.empty());
if (sync_point_ == "BlobFileBuilder::WriteBlobToFile:AddRecord") {
ASSERT_EQ(compaction_stats[0].bytes_written, 0);
ASSERT_EQ(compaction_stats[0].bytes_written_blob, 0);
ASSERT_EQ(compaction_stats[0].num_output_files, 0);
ASSERT_EQ(compaction_stats[0].num_output_files_blob, 0);
} else {
// SST file writing succeeded; blob file writing failed (during Finish)
ASSERT_GT(compaction_stats[0].bytes_written, 0);
ASSERT_EQ(compaction_stats[0].bytes_written_blob, 0);
ASSERT_EQ(compaction_stats[0].num_output_files, 1);
ASSERT_EQ(compaction_stats[0].num_output_files_blob, 0);
}
const uint64_t* const cf_stats_value = internal_stats->TEST_GetCFStatsValue();
ASSERT_EQ(cf_stats_value[InternalStats::BYTES_FLUSHED],
compaction_stats[0].bytes_written +
compaction_stats[0].bytes_written_blob);
#endif // ROCKSDB_LITE
}
#ifndef ROCKSDB_LITE
TEST_P(DBAtomicFlushTest, ManualFlushUnder2PC) {
Options options = CurrentOptions();
options.create_if_missing = true;
options.allow_2pc = true;
options.atomic_flush = GetParam();
// 64MB so that memtable flush won't be trigger by the small writes.
options.write_buffer_size = (static_cast<size_t>(64) << 20);
// Destroy the DB to recreate as a TransactionDB.
Close();
Destroy(options, true);
// Create a TransactionDB.
TransactionDB* txn_db = nullptr;
TransactionDBOptions txn_db_opts;
txn_db_opts.write_policy = TxnDBWritePolicy::WRITE_COMMITTED;
ASSERT_OK(TransactionDB::Open(options, txn_db_opts, dbname_, &txn_db));
ASSERT_NE(txn_db, nullptr);
db_ = txn_db;
// Create two more columns other than default CF.
std::vector<std::string> cfs = {"puppy", "kitty"};
CreateColumnFamilies(cfs, options);
ASSERT_EQ(handles_.size(), 2);
ASSERT_EQ(handles_[0]->GetName(), cfs[0]);
ASSERT_EQ(handles_[1]->GetName(), cfs[1]);
const size_t kNumCfToFlush = options.atomic_flush ? 2 : 1;
WriteOptions wopts;
TransactionOptions txn_opts;
// txn1 only prepare, but does not commit.
// The WAL containing the prepared but uncommitted data must be kept.
Transaction* txn1 = txn_db->BeginTransaction(wopts, txn_opts, nullptr);
// txn2 not only prepare, but also commit.
Transaction* txn2 = txn_db->BeginTransaction(wopts, txn_opts, nullptr);
ASSERT_NE(txn1, nullptr);
ASSERT_NE(txn2, nullptr);
for (size_t i = 0; i < kNumCfToFlush; i++) {
ASSERT_OK(txn1->Put(handles_[i], "k1", "v1"));
ASSERT_OK(txn2->Put(handles_[i], "k2", "v2"));
}
// A txn must be named before prepare.
ASSERT_OK(txn1->SetName("txn1"));
ASSERT_OK(txn2->SetName("txn2"));
// Prepare writes to WAL, but not to memtable. (WriteCommitted)
ASSERT_OK(txn1->Prepare());
ASSERT_OK(txn2->Prepare());
// Commit writes to memtable.
ASSERT_OK(txn2->Commit());
delete txn1;
delete txn2;
// There are still data in memtable not flushed.
// But since data is small enough to reside in the active memtable,
// there are no immutable memtable.
for (size_t i = 0; i < kNumCfToFlush; i++) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_FALSE(cfh->cfd()->mem()->IsEmpty());
}
// Atomic flush memtables,
// the min log with prepared data should be written to MANIFEST.
std::vector<ColumnFamilyHandle*> cfs_to_flush(kNumCfToFlush);
for (size_t i = 0; i < kNumCfToFlush; i++) {
cfs_to_flush[i] = handles_[i];
}
ASSERT_OK(txn_db->Flush(FlushOptions(), cfs_to_flush));
// There are no remaining data in memtable after flush.
for (size_t i = 0; i < kNumCfToFlush; i++) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_TRUE(cfh->cfd()->mem()->IsEmpty());
ASSERT_EQ(cfh->cfd()->GetFlushReason(), FlushReason::kManualFlush);
}
// The recovered min log number with prepared data should be non-zero.
// In 2pc mode, MinLogNumberToKeep returns the
// VersionSet::min_log_number_to_keep_2pc recovered from MANIFEST, if it's 0,
// it means atomic flush didn't write the min_log_number_to_keep to MANIFEST.
cfs.push_back(kDefaultColumnFamilyName);
ASSERT_OK(TryReopenWithColumnFamilies(cfs, options));
DBImpl* db_impl = reinterpret_cast<DBImpl*>(db_);
ASSERT_TRUE(db_impl->allow_2pc());
ASSERT_NE(db_impl->MinLogNumberToKeep(), 0);
}
#endif // ROCKSDB_LITE
TEST_P(DBAtomicFlushTest, ManualAtomicFlush) {
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = GetParam();
options.write_buffer_size = (static_cast<size_t>(64) << 20);
CreateAndReopenWithCF({"pikachu", "eevee"}, options);
size_t num_cfs = handles_.size();
ASSERT_EQ(3, num_cfs);
WriteOptions wopts;
wopts.disableWAL = true;
for (size_t i = 0; i != num_cfs; ++i) {
ASSERT_OK(Put(static_cast<int>(i) /*cf*/, "key", "value", wopts));
}
for (size_t i = 0; i != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_FALSE(cfh->cfd()->mem()->IsEmpty());
}
std::vector<int> cf_ids;
for (size_t i = 0; i != num_cfs; ++i) {
cf_ids.emplace_back(static_cast<int>(i));
}
ASSERT_OK(Flush(cf_ids));
for (size_t i = 0; i != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(cfh->cfd()->GetFlushReason(), FlushReason::kManualFlush);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_TRUE(cfh->cfd()->mem()->IsEmpty());
}
}
TEST_P(DBAtomicFlushTest, PrecomputeMinLogNumberToKeepNon2PC) {
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = GetParam();
options.write_buffer_size = (static_cast<size_t>(64) << 20);
CreateAndReopenWithCF({"pikachu"}, options);
const size_t num_cfs = handles_.size();
ASSERT_EQ(num_cfs, 2);
WriteOptions wopts;
for (size_t i = 0; i != num_cfs; ++i) {
ASSERT_OK(Put(static_cast<int>(i) /*cf*/, "key", "value", wopts));
}
{
// Flush the default CF only.
std::vector<int> cf_ids{0};
ASSERT_OK(Flush(cf_ids));
autovector<ColumnFamilyData*> flushed_cfds;
autovector<autovector<VersionEdit*>> flush_edits;
auto flushed_cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[0]);
flushed_cfds.push_back(flushed_cfh->cfd());
flush_edits.push_back({});
auto unflushed_cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[1]);
ASSERT_EQ(PrecomputeMinLogNumberToKeepNon2PC(dbfull()->TEST_GetVersionSet(),
flushed_cfds, flush_edits),
unflushed_cfh->cfd()->GetLogNumber());
}
{
// Flush all CFs.
std::vector<int> cf_ids;
for (size_t i = 0; i != num_cfs; ++i) {
cf_ids.emplace_back(static_cast<int>(i));
}
ASSERT_OK(Flush(cf_ids));
uint64_t log_num_after_flush = dbfull()->TEST_GetCurrentLogNumber();
uint64_t min_log_number_to_keep = port::kMaxUint64;
autovector<ColumnFamilyData*> flushed_cfds;
autovector<autovector<VersionEdit*>> flush_edits;
for (size_t i = 0; i != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
flushed_cfds.push_back(cfh->cfd());
flush_edits.push_back({});
min_log_number_to_keep =
std::min(min_log_number_to_keep, cfh->cfd()->GetLogNumber());
}
ASSERT_EQ(min_log_number_to_keep, log_num_after_flush);
ASSERT_EQ(PrecomputeMinLogNumberToKeepNon2PC(dbfull()->TEST_GetVersionSet(),
flushed_cfds, flush_edits),
min_log_number_to_keep);
}
}
TEST_P(DBAtomicFlushTest, AtomicFlushTriggeredByMemTableFull) {
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = GetParam();
// 4KB so that we can easily trigger auto flush.
options.write_buffer_size = 4096;
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::BackgroundCallFlush:FlushFinish:0",
"DBAtomicFlushTest::AtomicFlushTriggeredByMemTableFull:BeforeCheck"}});
SyncPoint::GetInstance()->EnableProcessing();
CreateAndReopenWithCF({"pikachu", "eevee"}, options);
size_t num_cfs = handles_.size();
ASSERT_EQ(3, num_cfs);
WriteOptions wopts;
wopts.disableWAL = true;
for (size_t i = 0; i != num_cfs; ++i) {
ASSERT_OK(Put(static_cast<int>(i) /*cf*/, "key", "value", wopts));
}
// Keep writing to one of them column families to trigger auto flush.
for (int i = 0; i != 4000; ++i) {
ASSERT_OK(Put(static_cast<int>(num_cfs) - 1 /*cf*/,
"key" + std::to_string(i), "value" + std::to_string(i),
wopts));
}
TEST_SYNC_POINT(
"DBAtomicFlushTest::AtomicFlushTriggeredByMemTableFull:BeforeCheck");
if (options.atomic_flush) {
for (size_t i = 0; i + 1 != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_TRUE(cfh->cfd()->mem()->IsEmpty());
}
} else {
for (size_t i = 0; i + 1 != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(0, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_FALSE(cfh->cfd()->mem()->IsEmpty());
}
}
SyncPoint::GetInstance()->DisableProcessing();
}
TEST_P(DBAtomicFlushTest, AtomicFlushRollbackSomeJobs) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
std::unique_ptr<FaultInjectionTestEnv> fault_injection_env(
new FaultInjectionTestEnv(env_));
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
options.env = fault_injection_env.get();
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::AtomicFlushMemTablesToOutputFiles:SomeFlushJobsComplete:1",
"DBAtomicFlushTest::AtomicFlushRollbackSomeJobs:1"},
{"DBAtomicFlushTest::AtomicFlushRollbackSomeJobs:2",
"DBImpl::AtomicFlushMemTablesToOutputFiles:SomeFlushJobsComplete:2"}});
SyncPoint::GetInstance()->EnableProcessing();
CreateAndReopenWithCF({"pikachu", "eevee"}, options);
size_t num_cfs = handles_.size();
ASSERT_EQ(3, num_cfs);
WriteOptions wopts;
wopts.disableWAL = true;
for (size_t i = 0; i != num_cfs; ++i) {
int cf_id = static_cast<int>(i);
ASSERT_OK(Put(cf_id, "key", "value", wopts));
}
FlushOptions flush_opts;
flush_opts.wait = false;
ASSERT_OK(dbfull()->Flush(flush_opts, handles_));
TEST_SYNC_POINT("DBAtomicFlushTest::AtomicFlushRollbackSomeJobs:1");
fault_injection_env->SetFilesystemActive(false);
TEST_SYNC_POINT("DBAtomicFlushTest::AtomicFlushRollbackSomeJobs:2");
for (auto* cfh : handles_) {
// Returns the IO error happend during flush.
ASSERT_NOK(dbfull()->TEST_WaitForFlushMemTable(cfh));
}
for (size_t i = 0; i != num_cfs; ++i) {
auto cfh = static_cast<ColumnFamilyHandleImpl*>(handles_[i]);
ASSERT_EQ(1, cfh->cfd()->imm()->NumNotFlushed());
ASSERT_TRUE(cfh->cfd()->mem()->IsEmpty());
}
fault_injection_env->SetFilesystemActive(true);
Destroy(options);
}
TEST_P(DBAtomicFlushTest, FlushMultipleCFs_DropSomeBeforeRequestFlush) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
SyncPoint::GetInstance()->EnableProcessing();
CreateAndReopenWithCF({"pikachu", "eevee"}, options);
size_t num_cfs = handles_.size();
ASSERT_EQ(3, num_cfs);
WriteOptions wopts;
wopts.disableWAL = true;
std::vector<int> cf_ids;
for (size_t i = 0; i != num_cfs; ++i) {
int cf_id = static_cast<int>(i);
ASSERT_OK(Put(cf_id, "key", "value", wopts));
cf_ids.push_back(cf_id);
}
ASSERT_OK(dbfull()->DropColumnFamily(handles_[1]));
ASSERT_TRUE(Flush(cf_ids).IsColumnFamilyDropped());
Destroy(options);
}
TEST_P(DBAtomicFlushTest,
FlushMultipleCFs_DropSomeAfterScheduleFlushBeforeFlushJobRun) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
CreateAndReopenWithCF({"pikachu", "eevee"}, options);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::AtomicFlushMemTables:AfterScheduleFlush",
"DBAtomicFlushTest::BeforeDropCF"},
{"DBAtomicFlushTest::AfterDropCF",
"DBImpl::BackgroundCallFlush:start"}});
SyncPoint::GetInstance()->EnableProcessing();
size_t num_cfs = handles_.size();
ASSERT_EQ(3, num_cfs);
WriteOptions wopts;
wopts.disableWAL = true;
for (size_t i = 0; i != num_cfs; ++i) {
int cf_id = static_cast<int>(i);
ASSERT_OK(Put(cf_id, "key", "value", wopts));
}
port::Thread user_thread([&]() {
TEST_SYNC_POINT("DBAtomicFlushTest::BeforeDropCF");
ASSERT_OK(dbfull()->DropColumnFamily(handles_[1]));
TEST_SYNC_POINT("DBAtomicFlushTest::AfterDropCF");
});
FlushOptions flush_opts;
flush_opts.wait = true;
ASSERT_OK(dbfull()->Flush(flush_opts, handles_));
user_thread.join();
for (size_t i = 0; i != num_cfs; ++i) {
int cf_id = static_cast<int>(i);
ASSERT_EQ("value", Get(cf_id, "key"));
}
ReopenWithColumnFamilies({kDefaultColumnFamilyName, "eevee"}, options);
num_cfs = handles_.size();
ASSERT_EQ(2, num_cfs);
for (size_t i = 0; i != num_cfs; ++i) {
int cf_id = static_cast<int>(i);
ASSERT_EQ("value", Get(cf_id, "key"));
}
Destroy(options);
}
TEST_P(DBAtomicFlushTest, TriggerFlushAndClose) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
const int kNumKeysTriggerFlush = 4;
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
options.memtable_factory.reset(
test::NewSpecialSkipListFactory(kNumKeysTriggerFlush));
CreateAndReopenWithCF({"pikachu"}, options);
for (int i = 0; i != kNumKeysTriggerFlush; ++i) {
ASSERT_OK(Put(0, "key" + std::to_string(i), "value" + std::to_string(i)));
}
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_OK(Put(0, "key", "value"));
Close();
ReopenWithColumnFamilies({kDefaultColumnFamilyName, "pikachu"}, options);
ASSERT_EQ("value", Get(0, "key"));
}
TEST_P(DBAtomicFlushTest, PickMemtablesRaceWithBackgroundFlush) {
bool atomic_flush = GetParam();
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
options.max_write_buffer_number = 4;
// Set min_write_buffer_number_to_merge to be greater than 1, so that
// a column family with one memtable in the imm will not cause IsFlushPending
// to return true when flush_requested_ is false.
options.min_write_buffer_number_to_merge = 2;
CreateAndReopenWithCF({"pikachu"}, options);
ASSERT_EQ(2, handles_.size());
ASSERT_OK(dbfull()->PauseBackgroundWork());
ASSERT_OK(Put(0, "key00", "value00"));
ASSERT_OK(Put(1, "key10", "value10"));
FlushOptions flush_opts;
flush_opts.wait = false;
ASSERT_OK(dbfull()->Flush(flush_opts, handles_));
ASSERT_OK(Put(0, "key01", "value01"));
// Since max_write_buffer_number is 4, the following flush won't cause write
// stall.
ASSERT_OK(dbfull()->Flush(flush_opts));
ASSERT_OK(dbfull()->DropColumnFamily(handles_[1]));
ASSERT_OK(dbfull()->DestroyColumnFamilyHandle(handles_[1]));
handles_[1] = nullptr;
ASSERT_OK(dbfull()->ContinueBackgroundWork());
ASSERT_OK(dbfull()->TEST_WaitForFlushMemTable(handles_[0]));
delete handles_[0];
handles_.clear();
}
TEST_P(DBAtomicFlushTest, CFDropRaceWithWaitForFlushMemTables) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
Options options = CurrentOptions();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
CreateAndReopenWithCF({"pikachu"}, options);
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->LoadDependency(
{{"DBImpl::AtomicFlushMemTables:AfterScheduleFlush",
"DBAtomicFlushTest::CFDropRaceWithWaitForFlushMemTables:BeforeDrop"},
{"DBAtomicFlushTest::CFDropRaceWithWaitForFlushMemTables:AfterFree",
"DBImpl::BackgroundCallFlush:start"},
{"DBImpl::BackgroundCallFlush:start",
"DBImpl::AtomicFlushMemTables:BeforeWaitForBgFlush"}});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_EQ(2, handles_.size());
ASSERT_OK(Put(0, "key", "value"));
ASSERT_OK(Put(1, "key", "value"));
auto* cfd_default =
static_cast<ColumnFamilyHandleImpl*>(dbfull()->DefaultColumnFamily())
->cfd();
auto* cfd_pikachu = static_cast<ColumnFamilyHandleImpl*>(handles_[1])->cfd();
port::Thread drop_cf_thr([&]() {
TEST_SYNC_POINT(
"DBAtomicFlushTest::CFDropRaceWithWaitForFlushMemTables:BeforeDrop");
ASSERT_OK(dbfull()->DropColumnFamily(handles_[1]));
delete handles_[1];
handles_.resize(1);
TEST_SYNC_POINT(
"DBAtomicFlushTest::CFDropRaceWithWaitForFlushMemTables:AfterFree");
});
FlushOptions flush_opts;
flush_opts.allow_write_stall = true;
ASSERT_OK(dbfull()->TEST_AtomicFlushMemTables({cfd_default, cfd_pikachu},
flush_opts));
drop_cf_thr.join();
Close();
SyncPoint::GetInstance()->DisableProcessing();
}
TEST_P(DBAtomicFlushTest, RollbackAfterFailToInstallResults) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
auto fault_injection_env = std::make_shared<FaultInjectionTestEnv>(env_);
Options options = CurrentOptions();
options.env = fault_injection_env.get();
options.create_if_missing = true;
options.atomic_flush = atomic_flush;
CreateAndReopenWithCF({"pikachu"}, options);
ASSERT_EQ(2, handles_.size());
for (size_t cf = 0; cf < handles_.size(); ++cf) {
ASSERT_OK(Put(static_cast<int>(cf), "a", "value"));
}
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::ProcessManifestWrites:BeforeWriteLastVersionEdit:0",
[&](void* /*arg*/) { fault_injection_env->SetFilesystemActive(false); });
SyncPoint::GetInstance()->EnableProcessing();
FlushOptions flush_opts;
Status s = db_->Flush(flush_opts, handles_);
ASSERT_NOK(s);
fault_injection_env->SetFilesystemActive(true);
Close();
SyncPoint::GetInstance()->ClearAllCallBacks();
}
// In atomic flush, concurrent bg flush threads commit to the MANIFEST in
// serial, in the order of their picked memtables for each column family.
// Only when a bg flush thread finds out that its memtables are the earliest
// unflushed ones for all the included column families will this bg flush
// thread continue to commit to MANIFEST.
// This unit test uses sync point to coordinate the execution of two bg threads
// executing the same sequence of functions. The interleaving are as follows.
// time bg1 bg2
// | pick memtables to flush
// | flush memtables cf1_m1, cf2_m1
// | join MANIFEST write queue
// | pick memtabls to flush
// | flush memtables cf1_(m1+1)
// | join MANIFEST write queue
// | wait to write MANIFEST
// | write MANIFEST
// | IO error
// | detect IO error and stop waiting
// V
TEST_P(DBAtomicFlushTest, BgThreadNoWaitAfterManifestError) {
bool atomic_flush = GetParam();
if (!atomic_flush) {
return;
}
auto fault_injection_env = std::make_shared<FaultInjectionTestEnv>(env_);
Options options = GetDefaultOptions();
options.create_if_missing = true;
options.atomic_flush = true;
options.env = fault_injection_env.get();
// Set a larger value than default so that RocksDB can schedule concurrent
// background flush threads.
options.max_background_jobs = 8;
options.max_write_buffer_number = 8;
CreateAndReopenWithCF({"pikachu"}, options);
assert(2 == handles_.size());
WriteOptions write_opts;
write_opts.disableWAL = true;
ASSERT_OK(Put(0, "a", "v_0_a", write_opts));
ASSERT_OK(Put(1, "a", "v_1_a", write_opts));
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
SyncPoint::GetInstance()->LoadDependency({
{"BgFlushThr2:WaitToCommit", "BgFlushThr1:BeforeWriteManifest"},
});
std::thread::id bg_flush_thr1, bg_flush_thr2;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::BackgroundCallFlush:start", [&](void*) {
if (bg_flush_thr1 == std::thread::id()) {
bg_flush_thr1 = std::this_thread::get_id();
} else if (bg_flush_thr2 == std::thread::id()) {
bg_flush_thr2 = std::this_thread::get_id();
}
});
int called = 0;
SyncPoint::GetInstance()->SetCallBack(
"DBImpl::AtomicFlushMemTablesToOutputFiles:WaitToCommit", [&](void* arg) {
if (std::this_thread::get_id() == bg_flush_thr2) {
const auto* ptr = reinterpret_cast<std::pair<Status, bool>*>(arg);
assert(ptr);
if (0 == called) {
// When bg flush thread 2 reaches here for the first time.
ASSERT_OK(ptr->first);
ASSERT_TRUE(ptr->second);
} else if (1 == called) {
// When bg flush thread 2 reaches here for the second time.
ASSERT_TRUE(ptr->first.IsIOError());
ASSERT_FALSE(ptr->second);
}
++called;
TEST_SYNC_POINT("BgFlushThr2:WaitToCommit");
}
});
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::ProcessManifestWrites:BeforeWriteLastVersionEdit:0",
[&](void*) {
if (std::this_thread::get_id() == bg_flush_thr1) {
TEST_SYNC_POINT("BgFlushThr1:BeforeWriteManifest");
}
});
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::LogAndApply:WriteManifest", [&](void*) {
if (std::this_thread::get_id() != bg_flush_thr1) {
return;
}
ASSERT_OK(db_->Put(write_opts, "b", "v_1_b"));
FlushOptions flush_opts;
flush_opts.wait = false;
std::vector<ColumnFamilyHandle*> cfhs(1, db_->DefaultColumnFamily());
ASSERT_OK(dbfull()->Flush(flush_opts, cfhs));
});
SyncPoint::GetInstance()->SetCallBack(
"VersionSet::ProcessManifestWrites:AfterSyncManifest", [&](void* arg) {
auto* ptr = reinterpret_cast<IOStatus*>(arg);
assert(ptr);
*ptr = IOStatus::IOError("Injected failure");
});
SyncPoint::GetInstance()->EnableProcessing();
ASSERT_TRUE(dbfull()->Flush(FlushOptions(), handles_).IsIOError());
Close();
SyncPoint::GetInstance()->DisableProcessing();
SyncPoint::GetInstance()->ClearAllCallBacks();
}
INSTANTIATE_TEST_CASE_P(DBFlushDirectIOTest, DBFlushDirectIOTest,
testing::Bool());
INSTANTIATE_TEST_CASE_P(DBAtomicFlushTest, DBAtomicFlushTest, testing::Bool());
} // namespace ROCKSDB_NAMESPACE
int main(int argc, char** argv) {
ROCKSDB_NAMESPACE::port::InstallStackTraceHandler();
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}