rocksdb/utilities/transactions/write_unprepared_transaction_test.cc

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// 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).
#ifndef ROCKSDB_LITE
#include "utilities/transactions/transaction_test.h"
#include "utilities/transactions/write_unprepared_txn.h"
#include "utilities/transactions/write_unprepared_txn_db.h"
namespace ROCKSDB_NAMESPACE {
class WriteUnpreparedTransactionTestBase : public TransactionTestBase {
public:
WriteUnpreparedTransactionTestBase(bool use_stackable_db,
bool two_write_queue,
TxnDBWritePolicy write_policy)
Unordered Writes (#5218) Summary: Performing unordered writes in rocksdb when unordered_write option is set to true. When enabled the writes to memtable are done without joining any write thread. This offers much higher write throughput since the upcoming writes would not have to wait for the slowest memtable write to finish. The tradeoff is that the writes visible to a snapshot might change over time. If the application cannot tolerate that, it should implement its own mechanisms to work around that. Using TransactionDB with WRITE_PREPARED write policy is one way to achieve that. Doing so increases the max throughput by 2.2x without however compromising the snapshot guarantees. The patch is prepared based on an original by siying Existing unit tests are extended to include unordered_write option. Benchmark Results: ``` TEST_TMPDIR=/dev/shm/ ./db_bench_unordered --benchmarks=fillrandom --threads=32 --num=10000000 -max_write_buffer_number=16 --max_background_jobs=64 --batch_size=8 --writes=3000000 -level0_file_num_compaction_trigger=99999 --level0_slowdown_writes_trigger=99999 --level0_stop_writes_trigger=99999 -enable_pipelined_write=false -disable_auto_compactions --unordered_write=1 ``` With WAL - Vanilla RocksDB: 78.6 MB/s - WRITER_PREPARED with unordered_write: 177.8 MB/s (2.2x) - unordered_write: 368.9 MB/s (4.7x with relaxed snapshot guarantees) Without WAL - Vanilla RocksDB: 111.3 MB/s - WRITER_PREPARED with unordered_write: 259.3 MB/s MB/s (2.3x) - unordered_write: 645.6 MB/s (5.8x with relaxed snapshot guarantees) - WRITER_PREPARED with unordered_write disable concurrency control: 185.3 MB/s MB/s (2.35x) Limitations: - The feature is not yet extended to `max_successive_merges` > 0. The feature is also incompatible with `enable_pipelined_write` = true as well as with `allow_concurrent_memtable_write` = false. Pull Request resolved: https://github.com/facebook/rocksdb/pull/5218 Differential Revision: D15219029 Pulled By: maysamyabandeh fbshipit-source-id: 38f2abc4af8780148c6128acdba2b3227bc81759
2019-05-14 02:43:47 +02:00
: TransactionTestBase(use_stackable_db, two_write_queue, write_policy,
kOrderedWrite) {}
};
class WriteUnpreparedTransactionTest
: public WriteUnpreparedTransactionTestBase,
virtual public ::testing::WithParamInterface<
std::tuple<bool, bool, TxnDBWritePolicy>> {
public:
WriteUnpreparedTransactionTest()
: WriteUnpreparedTransactionTestBase(std::get<0>(GetParam()),
std::get<1>(GetParam()),
std::get<2>(GetParam())){}
};
INSTANTIATE_TEST_CASE_P(
WriteUnpreparedTransactionTest, WriteUnpreparedTransactionTest,
::testing::Values(std::make_tuple(false, false, WRITE_UNPREPARED),
std::make_tuple(false, true, WRITE_UNPREPARED)));
enum StressAction { NO_SNAPSHOT, RO_SNAPSHOT, REFRESH_SNAPSHOT };
class WriteUnpreparedStressTest : public WriteUnpreparedTransactionTestBase,
virtual public ::testing::WithParamInterface<
std::tuple<bool, StressAction>> {
public:
WriteUnpreparedStressTest()
: WriteUnpreparedTransactionTestBase(false, std::get<0>(GetParam()),
WRITE_UNPREPARED),
action_(std::get<1>(GetParam())) {}
StressAction action_;
};
INSTANTIATE_TEST_CASE_P(
WriteUnpreparedStressTest, WriteUnpreparedStressTest,
::testing::Values(std::make_tuple(false, NO_SNAPSHOT),
std::make_tuple(false, RO_SNAPSHOT),
std::make_tuple(false, REFRESH_SNAPSHOT),
std::make_tuple(true, NO_SNAPSHOT),
std::make_tuple(true, RO_SNAPSHOT),
std::make_tuple(true, REFRESH_SNAPSHOT)));
TEST_P(WriteUnpreparedTransactionTest, ReadYourOwnWrite) {
// The following tests checks whether reading your own write for
// a transaction works for write unprepared, when there are uncommitted
// values written into DB.
auto verify_state = [](Iterator* iter, const std::string& key,
const std::string& value) {
ASSERT_TRUE(iter->Valid());
ASSERT_OK(iter->status());
ASSERT_EQ(key, iter->key().ToString());
ASSERT_EQ(value, iter->value().ToString());
};
// Test always reseeking vs never reseeking.
for (uint64_t max_skip : {0, std::numeric_limits<int>::max()}) {
options.max_sequential_skip_in_iterations = max_skip;
options.disable_auto_compactions = true;
ASSERT_OK(ReOpen());
TransactionOptions txn_options;
WriteOptions woptions;
ReadOptions roptions;
ASSERT_OK(db->Put(woptions, "a", ""));
ASSERT_OK(db->Put(woptions, "b", ""));
Transaction* txn = db->BeginTransaction(woptions, txn_options);
WriteUnpreparedTxn* wup_txn = dynamic_cast<WriteUnpreparedTxn*>(txn);
txn->SetSnapshot();
for (int i = 0; i < 5; i++) {
std::string stored_value = "v" + ToString(i);
ASSERT_OK(txn->Put("a", stored_value));
ASSERT_OK(txn->Put("b", stored_value));
ASSERT_OK(wup_txn->FlushWriteBatchToDB(false));
// Test Get()
std::string value;
ASSERT_OK(txn->Get(roptions, "a", &value));
ASSERT_EQ(value, stored_value);
ASSERT_OK(txn->Get(roptions, "b", &value));
ASSERT_EQ(value, stored_value);
// Test Next()
auto iter = txn->GetIterator(roptions);
iter->Seek("a");
verify_state(iter, "a", stored_value);
iter->Next();
verify_state(iter, "b", stored_value);
iter->SeekToFirst();
verify_state(iter, "a", stored_value);
iter->Next();
verify_state(iter, "b", stored_value);
delete iter;
// Test Prev()
iter = txn->GetIterator(roptions);
iter->SeekForPrev("b");
verify_state(iter, "b", stored_value);
iter->Prev();
verify_state(iter, "a", stored_value);
iter->SeekToLast();
verify_state(iter, "b", stored_value);
iter->Prev();
verify_state(iter, "a", stored_value);
delete iter;
}
delete txn;
}
}
#if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN)
TEST_P(WriteUnpreparedStressTest, ReadYourOwnWriteStress) {
// This is a stress test where different threads are writing random keys, and
// then before committing or aborting the transaction, it validates to see
// that it can read the keys it wrote, and the keys it did not write respect
// the snapshot. To avoid row lock contention (and simply stressing the
// locking system), each thread is mostly only writing to its own set of keys.
const uint32_t kNumIter = 1000;
const uint32_t kNumThreads = 10;
const uint32_t kNumKeys = 5;
// Test with
// 1. no snapshots set
// 2. snapshot set on ReadOptions
// 3. snapshot set, and refreshing after every write.
StressAction a = action_;
WriteOptions write_options;
txn_db_options.transaction_lock_timeout = -1;
options.disable_auto_compactions = true;
ASSERT_OK(ReOpen());
std::vector<std::string> keys;
for (uint32_t k = 0; k < kNumKeys * kNumThreads; k++) {
keys.push_back("k" + ToString(k));
}
RandomShuffle(keys.begin(), keys.end());
// This counter will act as a "sequence number" to help us validate
// visibility logic with snapshots. If we had direct access to the seqno of
// snapshots and key/values, then we should directly compare those instead.
std::atomic<int64_t> counter(0);
std::function<void(uint32_t)> stress_thread = [&](int id) {
size_t tid = std::hash<std::thread::id>()(std::this_thread::get_id());
Random64 rnd(static_cast<uint32_t>(tid));
Transaction* txn;
TransactionOptions txn_options;
// batch_size of 1 causes writes to DB for every marker.
txn_options.write_batch_flush_threshold = 1;
ReadOptions read_options;
for (uint32_t i = 0; i < kNumIter; i++) {
std::set<std::string> owned_keys(keys.begin() + id * kNumKeys,
keys.begin() + (id + 1) * kNumKeys);
// Add unowned keys to make the workload more interesting, but this
// increases row lock contention, so just do it sometimes.
if (rnd.OneIn(2)) {
owned_keys.insert(keys[rnd.Uniform(kNumKeys * kNumThreads)]);
}
txn = db->BeginTransaction(write_options, txn_options);
ASSERT_OK(txn->SetName(ToString(id)));
txn->SetSnapshot();
if (a >= RO_SNAPSHOT) {
read_options.snapshot = txn->GetSnapshot();
ASSERT_TRUE(read_options.snapshot != nullptr);
}
uint64_t buf[2];
buf[0] = id;
// When scanning through the database, make sure that all unprepared
// keys have value >= snapshot and all other keys have value < snapshot.
int64_t snapshot_num = counter.fetch_add(1);
Status s;
for (const auto& key : owned_keys) {
buf[1] = counter.fetch_add(1);
s = txn->Put(key, Slice((const char*)buf, sizeof(buf)));
if (!s.ok()) {
break;
}
if (a == REFRESH_SNAPSHOT) {
txn->SetSnapshot();
read_options.snapshot = txn->GetSnapshot();
snapshot_num = counter.fetch_add(1);
}
}
// Failure is possible due to snapshot validation. In this case,
// rollback and move onto next iteration.
if (!s.ok()) {
ASSERT_TRUE(s.IsBusy());
ASSERT_OK(txn->Rollback());
delete txn;
continue;
}
auto verify_key = [&owned_keys, &a, &id, &snapshot_num](
const std::string& key, const std::string& value) {
if (owned_keys.count(key) > 0) {
ASSERT_EQ(value.size(), 16);
// Since this key is part of owned_keys, then this key must be
// unprepared by this transaction identified by 'id'
ASSERT_EQ(((int64_t*)value.c_str())[0], id);
if (a == REFRESH_SNAPSHOT) {
// If refresh snapshot is true, then the snapshot is refreshed
// after every Put(), meaning that the current snapshot in
// snapshot_num must be greater than the "seqno" of any keys
// written by the current transaction.
ASSERT_LT(((int64_t*)value.c_str())[1], snapshot_num);
} else {
// If refresh snapshot is not on, then the snapshot was taken at
// the beginning of the transaction, meaning all writes must come
// after snapshot_num
ASSERT_GT(((int64_t*)value.c_str())[1], snapshot_num);
}
} else if (a >= RO_SNAPSHOT) {
// If this is not an unprepared key, just assert that the key
// "seqno" is smaller than the snapshot seqno.
ASSERT_EQ(value.size(), 16);
ASSERT_LT(((int64_t*)value.c_str())[1], snapshot_num);
}
};
// Validate Get()/Next()/Prev(). Do only one of them to save time, and
// reduce lock contention.
switch (rnd.Uniform(3)) {
case 0: // Validate Get()
{
for (const auto& key : keys) {
std::string value;
s = txn->Get(read_options, Slice(key), &value);
if (!s.ok()) {
ASSERT_TRUE(s.IsNotFound());
ASSERT_EQ(owned_keys.count(key), 0);
} else {
verify_key(key, value);
}
}
break;
}
case 1: // Validate Next()
{
Iterator* iter = txn->GetIterator(read_options);
ASSERT_OK(iter->status());
for (iter->SeekToFirst(); iter->Valid(); iter->Next()) {
verify_key(iter->key().ToString(), iter->value().ToString());
}
ASSERT_OK(iter->status());
delete iter;
break;
}
case 2: // Validate Prev()
{
Iterator* iter = txn->GetIterator(read_options);
ASSERT_OK(iter->status());
for (iter->SeekToLast(); iter->Valid(); iter->Prev()) {
verify_key(iter->key().ToString(), iter->value().ToString());
}
ASSERT_OK(iter->status());
delete iter;
break;
}
default:
FAIL();
}
if (rnd.OneIn(2)) {
ASSERT_OK(txn->Commit());
} else {
ASSERT_OK(txn->Rollback());
}
delete txn;
}
};
std::vector<port::Thread> threads;
for (uint32_t i = 0; i < kNumThreads; i++) {
threads.emplace_back(stress_thread, i);
}
for (auto& t : threads) {
t.join();
}
}
#endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN)
// This tests how write unprepared behaves during recovery when the DB crashes
// after a transaction has either been unprepared or prepared, and tests if
// the changes are correctly applied for prepared transactions if we decide to
// rollback/commit.
TEST_P(WriteUnpreparedTransactionTest, RecoveryTest) {
WriteOptions write_options;
write_options.disableWAL = false;
TransactionOptions txn_options;
std::vector<Transaction*> prepared_trans;
WriteUnpreparedTxnDB* wup_db;
options.disable_auto_compactions = true;
enum Action { UNPREPARED, ROLLBACK, COMMIT };
// batch_size of 1 causes writes to DB for every marker.
for (size_t batch_size : {1, 1000000}) {
txn_options.write_batch_flush_threshold = batch_size;
for (bool empty : {true, false}) {
for (Action a : {UNPREPARED, ROLLBACK, COMMIT}) {
for (int num_batches = 1; num_batches < 10; num_batches++) {
// Reset database.
prepared_trans.clear();
ASSERT_OK(ReOpen());
wup_db = dynamic_cast<WriteUnpreparedTxnDB*>(db);
if (!empty) {
for (int i = 0; i < num_batches; i++) {
ASSERT_OK(db->Put(WriteOptions(), "k" + ToString(i),
"before value" + ToString(i)));
}
}
// Write num_batches unprepared batches.
Transaction* txn = db->BeginTransaction(write_options, txn_options);
WriteUnpreparedTxn* wup_txn = dynamic_cast<WriteUnpreparedTxn*>(txn);
ASSERT_OK(txn->SetName("xid"));
for (int i = 0; i < num_batches; i++) {
ASSERT_OK(txn->Put("k" + ToString(i), "value" + ToString(i)));
if (txn_options.write_batch_flush_threshold == 1) {
// WriteUnprepared will check write_batch_flush_threshold and
// possibly flush before appending to the write batch. No flush
// will happen at the first write because the batch is still
// empty, so after k puts, there should be k-1 flushed batches.
ASSERT_EQ(wup_txn->GetUnpreparedSequenceNumbers().size(), i);
} else {
ASSERT_EQ(wup_txn->GetUnpreparedSequenceNumbers().size(), 0);
}
}
if (a == UNPREPARED) {
// This is done to prevent the destructor from rolling back the
// transaction for us, since we want to pretend we crashed and
// test that recovery does the rollback.
wup_txn->unprep_seqs_.clear();
} else {
ASSERT_OK(txn->Prepare());
}
delete txn;
// Crash and run recovery code paths.
ASSERT_OK(wup_db->db_impl_->FlushWAL(true));
wup_db->TEST_Crash();
ASSERT_OK(ReOpenNoDelete());
assert(db != nullptr);
db->GetAllPreparedTransactions(&prepared_trans);
ASSERT_EQ(prepared_trans.size(), a == UNPREPARED ? 0 : 1);
if (a == ROLLBACK) {
ASSERT_OK(prepared_trans[0]->Rollback());
delete prepared_trans[0];
} else if (a == COMMIT) {
ASSERT_OK(prepared_trans[0]->Commit());
delete prepared_trans[0];
}
Iterator* iter = db->NewIterator(ReadOptions());
ASSERT_OK(iter->status());
iter->SeekToFirst();
// Check that DB has before values.
if (!empty || a == COMMIT) {
for (int i = 0; i < num_batches; i++) {
ASSERT_TRUE(iter->Valid());
ASSERT_EQ(iter->key().ToString(), "k" + ToString(i));
if (a == COMMIT) {
ASSERT_EQ(iter->value().ToString(), "value" + ToString(i));
} else {
ASSERT_EQ(iter->value().ToString(),
"before value" + ToString(i));
}
iter->Next();
}
}
ASSERT_FALSE(iter->Valid());
ASSERT_OK(iter->status());
delete iter;
}
}
}
}
}
// Basic test to see that unprepared batch gets written to DB when batch size
// is exceeded. It also does some basic checks to see if commit/rollback works
// as expected for write unprepared.
TEST_P(WriteUnpreparedTransactionTest, UnpreparedBatch) {
WriteOptions write_options;
TransactionOptions txn_options;
const int kNumKeys = 10;
// batch_size of 1 causes writes to DB for every marker.
for (size_t batch_size : {1, 1000000}) {
txn_options.write_batch_flush_threshold = batch_size;
for (bool prepare : {false, true}) {
for (bool commit : {false, true}) {
ASSERT_OK(ReOpen());
Transaction* txn = db->BeginTransaction(write_options, txn_options);
WriteUnpreparedTxn* wup_txn = dynamic_cast<WriteUnpreparedTxn*>(txn);
ASSERT_OK(txn->SetName("xid"));
for (int i = 0; i < kNumKeys; i++) {
ASSERT_OK(txn->Put("k" + ToString(i), "v" + ToString(i)));
if (txn_options.write_batch_flush_threshold == 1) {
// WriteUnprepared will check write_batch_flush_threshold and
// possibly flush before appending to the write batch. No flush will
// happen at the first write because the batch is still empty, so
// after k puts, there should be k-1 flushed batches.
ASSERT_EQ(wup_txn->GetUnpreparedSequenceNumbers().size(), i);
} else {
ASSERT_EQ(wup_txn->GetUnpreparedSequenceNumbers().size(), 0);
}
}
if (prepare) {
ASSERT_OK(txn->Prepare());
}
Iterator* iter = db->NewIterator(ReadOptions());
ASSERT_OK(iter->status());
iter->SeekToFirst();
assert(!iter->Valid());
ASSERT_FALSE(iter->Valid());
ASSERT_OK(iter->status());
delete iter;
if (commit) {
ASSERT_OK(txn->Commit());
} else {
ASSERT_OK(txn->Rollback());
}
delete txn;
iter = db->NewIterator(ReadOptions());
ASSERT_OK(iter->status());
iter->SeekToFirst();
for (int i = 0; i < (commit ? kNumKeys : 0); i++) {
ASSERT_TRUE(iter->Valid());
ASSERT_EQ(iter->key().ToString(), "k" + ToString(i));
ASSERT_EQ(iter->value().ToString(), "v" + ToString(i));
iter->Next();
}
ASSERT_FALSE(iter->Valid());
ASSERT_OK(iter->status());
delete iter;
}
}
}
}
// Test whether logs containing unprepared/prepared batches are kept even
// after memtable finishes flushing, and whether they are removed when
// transaction commits/aborts.
//
// TODO(lth): Merge with TransactionTest/TwoPhaseLogRollingTest tests.
TEST_P(WriteUnpreparedTransactionTest, MarkLogWithPrepSection) {
WriteOptions write_options;
TransactionOptions txn_options;
// batch_size of 1 causes writes to DB for every marker.
txn_options.write_batch_flush_threshold = 1;
const int kNumKeys = 10;
WriteOptions wopts;
wopts.sync = true;
for (bool prepare : {false, true}) {
for (bool commit : {false, true}) {
ASSERT_OK(ReOpen());
auto wup_db = dynamic_cast<WriteUnpreparedTxnDB*>(db);
auto db_impl = wup_db->db_impl_;
Transaction* txn1 = db->BeginTransaction(write_options, txn_options);
ASSERT_OK(txn1->SetName("xid1"));
Transaction* txn2 = db->BeginTransaction(write_options, txn_options);
ASSERT_OK(txn2->SetName("xid2"));
// Spread this transaction across multiple log files.
for (int i = 0; i < kNumKeys; i++) {
ASSERT_OK(txn1->Put("k1" + ToString(i), "v" + ToString(i)));
if (i >= kNumKeys / 2) {
ASSERT_OK(txn2->Put("k2" + ToString(i), "v" + ToString(i)));
}
if (i > 0) {
ASSERT_OK(db_impl->TEST_SwitchWAL());
}
}
ASSERT_GT(txn1->GetLogNumber(), 0);
ASSERT_GT(txn2->GetLogNumber(), 0);
ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(),
txn1->GetLogNumber());
ASSERT_GT(db_impl->TEST_LogfileNumber(), txn1->GetLogNumber());
if (prepare) {
ASSERT_OK(txn1->Prepare());
ASSERT_OK(txn2->Prepare());
}
ASSERT_GE(db_impl->TEST_LogfileNumber(), txn1->GetLogNumber());
ASSERT_GE(db_impl->TEST_LogfileNumber(), txn2->GetLogNumber());
ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(),
txn1->GetLogNumber());
if (commit) {
ASSERT_OK(txn1->Commit());
} else {
ASSERT_OK(txn1->Rollback());
}
ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(),
txn2->GetLogNumber());
if (commit) {
ASSERT_OK(txn2->Commit());
} else {
ASSERT_OK(txn2->Rollback());
}
ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0);
delete txn1;
delete txn2;
}
}
}
TEST_P(WriteUnpreparedTransactionTest, NoSnapshotWrite) {
WriteOptions woptions;
TransactionOptions txn_options;
txn_options.write_batch_flush_threshold = 1;
Transaction* txn = db->BeginTransaction(woptions, txn_options);
// Do some writes with no snapshot
ASSERT_OK(txn->Put("a", "a"));
ASSERT_OK(txn->Put("b", "b"));
ASSERT_OK(txn->Put("c", "c"));
// Test that it is still possible to create iterators after writes with no
// snapshot, if iterator snapshot is fresh enough.
ReadOptions roptions;
auto iter = txn->GetIterator(roptions);
ASSERT_OK(iter->status());
int keys = 0;
for (iter->SeekToLast(); iter->Valid(); iter->Prev(), keys++) {
ASSERT_OK(iter->status());
ASSERT_EQ(iter->key().ToString(), iter->value().ToString());
}
ASSERT_EQ(keys, 3);
ASSERT_OK(iter->status());
delete iter;
delete txn;
}
// Test whether write to a transaction while iterating is supported.
TEST_P(WriteUnpreparedTransactionTest, IterateAndWrite) {
WriteOptions woptions;
TransactionOptions txn_options;
txn_options.write_batch_flush_threshold = 1;
enum Action { DO_DELETE, DO_UPDATE };
for (Action a : {DO_DELETE, DO_UPDATE}) {
for (int i = 0; i < 100; i++) {
ASSERT_OK(db->Put(woptions, ToString(i), ToString(i)));
}
Transaction* txn = db->BeginTransaction(woptions, txn_options);
// write_batch_ now contains 1 key.
ASSERT_OK(txn->Put("9", "a"));
ReadOptions roptions;
auto iter = txn->GetIterator(roptions);
ASSERT_OK(iter->status());
for (iter->SeekToFirst(); iter->Valid(); iter->Next()) {
ASSERT_OK(iter->status());
if (iter->key() == "9") {
ASSERT_EQ(iter->value().ToString(), "a");
} else {
ASSERT_EQ(iter->key().ToString(), iter->value().ToString());
}
if (a == DO_DELETE) {
ASSERT_OK(txn->Delete(iter->key()));
} else {
ASSERT_OK(txn->Put(iter->key(), "b"));
}
}
ASSERT_OK(iter->status());
delete iter;
ASSERT_OK(txn->Commit());
iter = db->NewIterator(roptions);
ASSERT_OK(iter->status());
if (a == DO_DELETE) {
// Check that db is empty.
iter->SeekToFirst();
ASSERT_FALSE(iter->Valid());
} else {
int keys = 0;
// Check that all values are updated to b.
for (iter->SeekToFirst(); iter->Valid(); iter->Next(), keys++) {
ASSERT_OK(iter->status());
ASSERT_EQ(iter->value().ToString(), "b");
}
ASSERT_EQ(keys, 100);
}
ASSERT_OK(iter->status());
delete iter;
delete txn;
}
}
// Test that using an iterator after transaction clear is not supported
TEST_P(WriteUnpreparedTransactionTest, IterateAfterClear) {
WriteOptions woptions;
TransactionOptions txn_options;
txn_options.write_batch_flush_threshold = 1;
enum Action { kCommit, kRollback };
for (Action a : {kCommit, kRollback}) {
for (int i = 0; i < 100; i++) {
ASSERT_OK(db->Put(woptions, ToString(i), ToString(i)));
}
Transaction* txn = db->BeginTransaction(woptions, txn_options);
ASSERT_OK(txn->Put("9", "a"));
ReadOptions roptions;
auto iter1 = txn->GetIterator(roptions);
auto iter2 = txn->GetIterator(roptions);
iter1->SeekToFirst();
iter2->Seek("9");
// Check that iterators are valid before transaction finishes.
ASSERT_TRUE(iter1->Valid());
ASSERT_TRUE(iter2->Valid());
ASSERT_OK(iter1->status());
ASSERT_OK(iter2->status());
if (a == kCommit) {
ASSERT_OK(txn->Commit());
} else {
ASSERT_OK(txn->Rollback());
}
// Check that iterators are invalidated after transaction finishes.
ASSERT_FALSE(iter1->Valid());
ASSERT_FALSE(iter2->Valid());
ASSERT_TRUE(iter1->status().IsInvalidArgument());
ASSERT_TRUE(iter2->status().IsInvalidArgument());
delete iter1;
delete iter2;
delete txn;
}
}
TEST_P(WriteUnpreparedTransactionTest, SavePoint) {
WriteOptions woptions;
TransactionOptions txn_options;
txn_options.write_batch_flush_threshold = 1;
Transaction* txn = db->BeginTransaction(woptions, txn_options);
txn->SetSavePoint();
ASSERT_OK(txn->Put("a", "a"));
ASSERT_OK(txn->Put("b", "b"));
ASSERT_OK(txn->Commit());
ReadOptions roptions;
std::string value;
ASSERT_OK(txn->Get(roptions, "a", &value));
ASSERT_EQ(value, "a");
ASSERT_OK(txn->Get(roptions, "b", &value));
ASSERT_EQ(value, "b");
delete txn;
}
TEST_P(WriteUnpreparedTransactionTest, UntrackedKeys) {
WriteOptions woptions;
TransactionOptions txn_options;
txn_options.write_batch_flush_threshold = 1;
Transaction* txn = db->BeginTransaction(woptions, txn_options);
auto wb = txn->GetWriteBatch()->GetWriteBatch();
ASSERT_OK(txn->Put("a", "a"));
ASSERT_OK(wb->Put("a_untrack", "a_untrack"));
txn->SetSavePoint();
ASSERT_OK(txn->Put("b", "b"));
ASSERT_OK(txn->Put("b_untrack", "b_untrack"));
ReadOptions roptions;
std::string value;
ASSERT_OK(txn->Get(roptions, "a", &value));
ASSERT_EQ(value, "a");
ASSERT_OK(txn->Get(roptions, "a_untrack", &value));
ASSERT_EQ(value, "a_untrack");
ASSERT_OK(txn->Get(roptions, "b", &value));
ASSERT_EQ(value, "b");
ASSERT_OK(txn->Get(roptions, "b_untrack", &value));
ASSERT_EQ(value, "b_untrack");
// b and b_untrack should be rolled back.
ASSERT_OK(txn->RollbackToSavePoint());
ASSERT_OK(txn->Get(roptions, "a", &value));
ASSERT_EQ(value, "a");
ASSERT_OK(txn->Get(roptions, "a_untrack", &value));
ASSERT_EQ(value, "a_untrack");
auto s = txn->Get(roptions, "b", &value);
ASSERT_TRUE(s.IsNotFound());
s = txn->Get(roptions, "b_untrack", &value);
ASSERT_TRUE(s.IsNotFound());
// Everything should be rolled back.
ASSERT_OK(txn->Rollback());
s = txn->Get(roptions, "a", &value);
ASSERT_TRUE(s.IsNotFound());
s = txn->Get(roptions, "a_untrack", &value);
ASSERT_TRUE(s.IsNotFound());
s = txn->Get(roptions, "b", &value);
ASSERT_TRUE(s.IsNotFound());
s = txn->Get(roptions, "b_untrack", &value);
ASSERT_TRUE(s.IsNotFound());
delete txn;
}
} // namespace ROCKSDB_NAMESPACE
int main(int argc, char** argv) {
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}
#else
#include <stdio.h>
int main(int /*argc*/, char** /*argv*/) {
fprintf(stderr,
"SKIPPED as Transactions are not supported in ROCKSDB_LITE\n");
return 0;
}
#endif // ROCKSDB_LITE