// 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). #include "utilities/transactions/transaction_test.h" #include #include #include #include #include "db/db_impl/db_impl.h" #include "port/port.h" #include "rocksdb/db.h" #include "rocksdb/options.h" #include "rocksdb/perf_context.h" #include "rocksdb/utilities/transaction.h" #include "rocksdb/utilities/transaction_db.h" #include "table/mock_table.h" #include "test_util/sync_point.h" #include "test_util/testharness.h" #include "test_util/testutil.h" #include "test_util/transaction_test_util.h" #include "util/random.h" #include "util/string_util.h" #include "utilities/merge_operators.h" #include "utilities/merge_operators/string_append/stringappend.h" #include "utilities/transactions/pessimistic_transaction_db.h" namespace ROCKSDB_NAMESPACE { INSTANTIATE_TEST_CASE_P( DBAsBaseDB, TransactionTest, ::testing::Values( std::make_tuple(false, false, WRITE_COMMITTED, kOrderedWrite), std::make_tuple(false, true, WRITE_COMMITTED, kOrderedWrite), std::make_tuple(false, false, WRITE_PREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_PREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_PREPARED, kUnorderedWrite), std::make_tuple(false, false, WRITE_UNPREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_UNPREPARED, kOrderedWrite))); INSTANTIATE_TEST_CASE_P( DBAsBaseDB, TransactionStressTest, ::testing::Values( std::make_tuple(false, false, WRITE_COMMITTED, kOrderedWrite), std::make_tuple(false, true, WRITE_COMMITTED, kOrderedWrite), std::make_tuple(false, false, WRITE_PREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_PREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_PREPARED, kUnorderedWrite), std::make_tuple(false, false, WRITE_UNPREPARED, kOrderedWrite), std::make_tuple(false, true, WRITE_UNPREPARED, kOrderedWrite))); INSTANTIATE_TEST_CASE_P( StackableDBAsBaseDB, TransactionTest, ::testing::Values( std::make_tuple(true, true, WRITE_COMMITTED, kOrderedWrite), std::make_tuple(true, true, WRITE_PREPARED, kOrderedWrite), std::make_tuple(true, true, WRITE_UNPREPARED, kOrderedWrite))); // MySQLStyleTransactionTest takes far too long for valgrind to run. Only do it // in full mode (`ROCKSDB_FULL_VALGRIND_RUN` compiler flag is set). #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) INSTANTIATE_TEST_CASE_P( MySQLStyleTransactionTest, MySQLStyleTransactionTest, ::testing::Values( std::make_tuple(false, false, WRITE_COMMITTED, kOrderedWrite, false), std::make_tuple(false, true, WRITE_COMMITTED, kOrderedWrite, false), std::make_tuple(false, false, WRITE_PREPARED, kOrderedWrite, false), std::make_tuple(false, false, WRITE_PREPARED, kOrderedWrite, true), std::make_tuple(false, true, WRITE_PREPARED, kOrderedWrite, false), std::make_tuple(false, true, WRITE_PREPARED, kOrderedWrite, true), std::make_tuple(false, false, WRITE_UNPREPARED, kOrderedWrite, false), std::make_tuple(false, false, WRITE_UNPREPARED, kOrderedWrite, true), std::make_tuple(false, true, WRITE_UNPREPARED, kOrderedWrite, false), std::make_tuple(false, true, WRITE_UNPREPARED, kOrderedWrite, true), std::make_tuple(false, true, WRITE_PREPARED, kUnorderedWrite, false), std::make_tuple(false, true, WRITE_PREPARED, kUnorderedWrite, true))); #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionTest, TestUpperBoundUponDeletion) { // Reproduction from the original bug report, 11606 // This test does writes without snapshot validation, and then tries to create // iterator later, which is unsupported in write unprepared. if (txn_db_options.write_policy == WRITE_UNPREPARED) { return; } WriteOptions write_options; ReadOptions read_options; Status s; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); // Write some keys in a txn s = txn->Put("2", "2"); ASSERT_OK(s); s = txn->Put("1", "1"); ASSERT_OK(s); s = txn->Delete("2"); ASSERT_OK(s); read_options.iterate_upper_bound = new Slice("2", 1); Iterator* iter = txn->GetIterator(read_options); ASSERT_OK(iter->status()); iter->SeekToFirst(); while (iter->Valid()) { ASSERT_EQ("1", iter->key().ToString()); iter->Next(); } delete iter; delete txn; delete read_options.iterate_upper_bound; } TEST_P(TransactionTest, TestTxnRespectBoundsInReadOption) { if (txn_db_options.write_policy == WRITE_UNPREPARED) { return; } WriteOptions write_options; { std::unique_ptr txn(db->BeginTransaction(write_options)); // writes that should be observed by base_iterator_ in BaseDeltaIterator ASSERT_OK(txn->Put("a", "aa")); ASSERT_OK(txn->Put("c", "cc")); ASSERT_OK(txn->Put("e", "ee")); ASSERT_OK(txn->Put("f", "ff")); ASSERT_TRUE(txn->Commit().ok()); } std::unique_ptr txn2(db->BeginTransaction(write_options)); // writes that should be observed by delta_iterator_ in BaseDeltaIterator ASSERT_OK(txn2->Put("b", "bb")); ASSERT_OK(txn2->Put("c", "cc")); ASSERT_OK(txn2->Put("f", "ff")); // delta_iterator_: b c f // base_iterator_: a c e f // // given range [c, f) // assert only {c, e} can be seen ReadOptions ro; ro.iterate_lower_bound = new Slice("c"); ro.iterate_upper_bound = new Slice("f"); std::unique_ptr iter(txn2->GetIterator(ro)); iter->Seek(Slice("b")); ASSERT_EQ("c", iter->key()); // lower bound capping iter->Seek(Slice("f")); ASSERT_FALSE(iter->Valid()); // out of bound iter->SeekForPrev(Slice("f")); ASSERT_EQ("e", iter->key()); // upper bound capping iter->SeekForPrev(Slice("b")); ASSERT_FALSE(iter->Valid()); // out of bound // move to the lower bound iter->SeekToFirst(); ASSERT_EQ("c", iter->key()); iter->Prev(); ASSERT_FALSE(iter->Valid()); // move to the upper bound iter->SeekToLast(); ASSERT_EQ("e", iter->key()); iter->Next(); ASSERT_FALSE(iter->Valid()); // reversely walk to the beginning iter->SeekToLast(); ASSERT_EQ("e", iter->key()); iter->Prev(); ASSERT_EQ("c", iter->key()); iter->Prev(); ASSERT_FALSE(iter->Valid()); delete ro.iterate_lower_bound; delete ro.iterate_upper_bound; } TEST_P(TransactionTest, DoubleEmptyWrite) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; WriteBatch batch; ASSERT_OK(db->Write(write_options, &batch)); ASSERT_OK(db->Write(write_options, &batch)); // Also test committing empty transactions in 2PC TransactionOptions txn_options; Transaction* txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Prepare()); ASSERT_OK(txn0->Commit()); delete txn0; // Also test that it works during recovery txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid2")); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0a"))); ASSERT_OK(txn0->Prepare()); delete txn0; static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete()); assert(db != nullptr); txn0 = db->GetTransactionByName("xid2"); ASSERT_OK(txn0->Commit()); delete txn0; } TEST_P(TransactionTest, SuccessTest) { ASSERT_OK(db->ResetStats()); WriteOptions write_options; ReadOptions read_options; std::string value; ASSERT_OK(db->Put(write_options, Slice("foo"), Slice("bar"))); ASSERT_OK(db->Put(write_options, Slice("foo2"), Slice("bar"))); Transaction* txn = db->BeginTransaction(write_options, TransactionOptions()); ASSERT_TRUE(txn); ASSERT_EQ(0, txn->GetNumPuts()); ASSERT_LE(0, txn->GetID()); ASSERT_OK(txn->GetForUpdate(read_options, "foo", &value)); ASSERT_EQ(value, "bar"); ASSERT_OK(txn->Put(Slice("foo"), Slice("bar2"))); ASSERT_EQ(1, txn->GetNumPuts()); ASSERT_OK(txn->GetForUpdate(read_options, "foo", &value)); ASSERT_EQ(value, "bar2"); ASSERT_OK(txn->Commit()); ASSERT_OK(db->Get(read_options, "foo", &value)); ASSERT_EQ(value, "bar2"); delete txn; } // Test the basic API of the pinnable slice overload of GetForUpdate() TEST_P(TransactionTest, SuccessTestPinnable) { ASSERT_OK(db->ResetStats()); WriteOptions write_options; ReadOptions read_options; PinnableSlice pinnable_val; ASSERT_OK(db->Put(write_options, Slice("foo"), Slice("bar"))); ASSERT_OK(db->Put(write_options, Slice("foo2"), Slice("bar"))); Transaction* txn = db->BeginTransaction(write_options, TransactionOptions()); ASSERT_TRUE(txn); ASSERT_EQ(0, txn->GetNumPuts()); ASSERT_LE(0, txn->GetID()); ASSERT_OK(txn->GetForUpdate(read_options, "foo", &pinnable_val)); ASSERT_EQ(*pinnable_val.GetSelf(), std::string("bar")); ASSERT_OK(txn->Put(Slice("foo"), Slice("bar2"))); ASSERT_EQ(1, txn->GetNumPuts()); ASSERT_OK(txn->GetForUpdate(read_options, "foo", &pinnable_val)); ASSERT_EQ(*pinnable_val.GetSelf(), std::string("bar2")); ASSERT_OK(txn->Commit()); ASSERT_OK( db->Get(read_options, db->DefaultColumnFamily(), "foo", &pinnable_val)); ASSERT_EQ(*pinnable_val.GetSelf(), std::string("bar2")); delete txn; } TEST_P(TransactionTest, SwitchMemtableDuringPrepareAndCommit_WC) { const TxnDBWritePolicy write_policy = std::get<2>(GetParam()); if (write_policy != TxnDBWritePolicy::WRITE_COMMITTED) { ROCKSDB_GTEST_BYPASS("Test applies to write-committed only"); return; } ASSERT_OK(db->Put(WriteOptions(), "key0", "value")); TransactionOptions txn_opts; txn_opts.use_only_the_last_commit_time_batch_for_recovery = true; Transaction* txn = db->BeginTransaction(WriteOptions(), txn_opts); assert(txn); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); SyncPoint::GetInstance()->SetCallBack( "FlushJob::WriteLevel0Table", [&](void* arg) { // db mutex not held. auto* mems = static_cast*>(arg); assert(mems); ASSERT_EQ(1, mems->size()); auto* ctwb = txn->GetCommitTimeWriteBatch(); ASSERT_OK(ctwb->Put("gtid", "123")); ASSERT_OK(txn->Commit()); delete txn; }); SyncPoint::GetInstance()->EnableProcessing(); ASSERT_OK(txn->Put("key1", "value")); ASSERT_OK(txn->SetName("txn1")); ASSERT_OK(txn->Prepare()); auto dbimpl = static_cast_with_check(db->GetRootDB()); ASSERT_OK(dbimpl->TEST_SwitchMemtable(nullptr)); ASSERT_OK(dbimpl->TEST_FlushMemTable( /*wait=*/false, /*allow_write_stall=*/true, /*cfh=*/nullptr)); ASSERT_OK(dbimpl->TEST_WaitForFlushMemTable()); { std::string value; ASSERT_OK(db->Get(ReadOptions(), "key1", &value)); ASSERT_EQ("value", value); } ASSERT_OK(dbimpl->SyncWAL()); delete db; db = nullptr; Status s; if (use_stackable_db_ == false) { s = TransactionDB::Open(options, txn_db_options, dbname, &db); } else { s = OpenWithStackableDB(); } ASSERT_OK(s); assert(db); { std::string value; ASSERT_OK(db->Get(ReadOptions(), "gtid", &value)); ASSERT_EQ("123", value); ASSERT_OK(db->Get(ReadOptions(), "key1", &value)); ASSERT_EQ("value", value); } SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); } // The test clarifies the contract of do_validate and assume_tracked // in GetForUpdate and Put/Merge/Delete TEST_P(TransactionTest, AssumeExclusiveTracked) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; TransactionOptions txn_options; txn_options.lock_timeout = 1; const bool EXCLUSIVE = true; const bool DO_VALIDATE = true; const bool ASSUME_LOCKED = true; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); txn->SetSnapshot(); // commit a value after the snapshot is taken ASSERT_OK(db->Put(write_options, Slice("foo"), Slice("bar"))); // By default write should fail to the commit after our snapshot s = txn->GetForUpdate(read_options, "foo", &value, EXCLUSIVE); ASSERT_TRUE(s.IsBusy()); // But the user could direct the db to skip validating the snapshot. The read // value then should be the most recently committed ASSERT_OK( txn->GetForUpdate(read_options, "foo", &value, EXCLUSIVE, !DO_VALIDATE)); ASSERT_EQ(value, "bar"); // Although ValidateSnapshot is skipped the key must have still got locked s = db->Put(write_options, Slice("foo"), Slice("bar")); ASSERT_TRUE(s.IsTimedOut()); // By default the write operations should fail due to the commit after the // snapshot s = txn->Put(Slice("foo"), Slice("bar1")); ASSERT_TRUE(s.IsBusy()); s = txn->Put(db->DefaultColumnFamily(), Slice("foo"), Slice("bar1"), !ASSUME_LOCKED); ASSERT_TRUE(s.IsBusy()); // But the user could direct the db that it already assumes exclusive lock on // the key due to the previous GetForUpdate call. ASSERT_OK(txn->Put(db->DefaultColumnFamily(), Slice("foo"), Slice("bar1"), ASSUME_LOCKED)); ASSERT_OK(txn->Merge(db->DefaultColumnFamily(), Slice("foo"), Slice("bar2"), ASSUME_LOCKED)); ASSERT_OK( txn->Delete(db->DefaultColumnFamily(), Slice("foo"), ASSUME_LOCKED)); ASSERT_OK(txn->SingleDelete(db->DefaultColumnFamily(), Slice("foo"), ASSUME_LOCKED)); ASSERT_OK(txn->Rollback()); delete txn; } // This test clarifies the contract of ValidateSnapshot TEST_P(TransactionTest, ValidateSnapshotTest) { for (bool with_flush : {true}) { for (bool with_2pc : {true}) { ASSERT_OK(ReOpen()); WriteOptions write_options; ReadOptions read_options; std::string value; assert(db != nullptr); Transaction* txn1 = db->BeginTransaction(write_options, TransactionOptions()); ASSERT_TRUE(txn1); ASSERT_OK(txn1->Put(Slice("foo"), Slice("bar1"))); if (with_2pc) { ASSERT_OK(txn1->SetName("xid1")); ASSERT_OK(txn1->Prepare()); } if (with_flush) { auto db_impl = static_cast_with_check(db->GetRootDB()); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // Make sure the flushed memtable is not kept in memory int max_memtable_in_history = std::max( options.max_write_buffer_number, static_cast(options.max_write_buffer_size_to_maintain) / static_cast(options.write_buffer_size)) + 1; for (int i = 0; i < max_memtable_in_history; i++) { ASSERT_OK(db->Put(write_options, Slice("key"), Slice("value"))); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); } } Transaction* txn2 = db->BeginTransaction(write_options, TransactionOptions()); ASSERT_TRUE(txn2); txn2->SetSnapshot(); ASSERT_OK(txn1->Commit()); delete txn1; auto pes_txn2 = dynamic_cast(txn2); // Test the simple case where the key is not tracked yet auto trakced_seq = kMaxSequenceNumber; auto s = pes_txn2->ValidateSnapshot(db->DefaultColumnFamily(), "foo", &trakced_seq); ASSERT_TRUE(s.IsBusy()); delete txn2; } } } TEST_P(TransactionTest, WaitingTxn) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; txn_options.lock_timeout = 1; s = db->Put(write_options, Slice("foo"), Slice("bar")); ASSERT_OK(s); /* create second cf */ ColumnFamilyHandle* cfa; ColumnFamilyOptions cf_options; s = db->CreateColumnFamily(cf_options, "CFA", &cfa); ASSERT_OK(s); s = db->Put(write_options, cfa, Slice("foo"), Slice("bar")); ASSERT_OK(s); Transaction* txn1 = db->BeginTransaction(write_options, txn_options); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); TransactionID id1 = txn1->GetID(); ASSERT_TRUE(txn1); ASSERT_TRUE(txn2); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "PointLockManager::AcquireWithTimeout:WaitingTxn", [&](void* /*arg*/) { std::string key; uint32_t cf_id; std::vector wait = txn2->GetWaitingTxns(&cf_id, &key); ASSERT_EQ(key, "foo"); ASSERT_EQ(wait.size(), 1); ASSERT_EQ(wait[0], id1); ASSERT_EQ(cf_id, 0U); }); get_perf_context()->Reset(); // lock key in default cf s = txn1->GetForUpdate(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); ASSERT_EQ(get_perf_context()->key_lock_wait_count, 0); // lock key in cfa s = txn1->GetForUpdate(read_options, cfa, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); ASSERT_EQ(get_perf_context()->key_lock_wait_count, 0); auto lock_data = db->GetLockStatusData(); // Locked keys exist in both column family. ASSERT_EQ(lock_data.size(), 2); auto cf_iterator = lock_data.begin(); // The iterator points to an unordered_multimap // thus the test can not assume any particular order. // Column family is 1 or 0 (cfa). if (cf_iterator->first != 1 && cf_iterator->first != 0) { FAIL(); } // The locked key is "foo" and is locked by txn1 ASSERT_EQ(cf_iterator->second.key, "foo"); ASSERT_EQ(cf_iterator->second.ids.size(), 1); ASSERT_EQ(cf_iterator->second.ids[0], txn1->GetID()); cf_iterator++; // Column family is 0 (default) or 1. if (cf_iterator->first != 1 && cf_iterator->first != 0) { FAIL(); } // The locked key is "foo" and is locked by txn1 ASSERT_EQ(cf_iterator->second.key, "foo"); ASSERT_EQ(cf_iterator->second.ids.size(), 1); ASSERT_EQ(cf_iterator->second.ids[0], txn1->GetID()); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); s = txn2->GetForUpdate(read_options, "foo", &value); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); ASSERT_EQ(get_perf_context()->key_lock_wait_count, 1); ASSERT_GE(get_perf_context()->key_lock_wait_time, 0); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); delete cfa; delete txn1; delete txn2; } TEST_P(TransactionTest, SharedLocks) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; Status s; txn_options.lock_timeout = 1; s = db->Put(write_options, Slice("foo"), Slice("bar")); ASSERT_OK(s); Transaction* txn1 = db->BeginTransaction(write_options, txn_options); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); Transaction* txn3 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); ASSERT_TRUE(txn2); ASSERT_TRUE(txn3); // Test shared access between txns s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn3->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); auto lock_data = db->GetLockStatusData(); ASSERT_EQ(lock_data.size(), 1); auto cf_iterator = lock_data.begin(); ASSERT_EQ(cf_iterator->second.key, "foo"); // We compare whether the set of txns locking this key is the same. To do // this, we need to sort both vectors so that the comparison is done // correctly. std::vector expected_txns = {txn1->GetID(), txn2->GetID(), txn3->GetID()}; std::vector lock_txns = cf_iterator->second.ids; ASSERT_EQ(expected_txns, lock_txns); ASSERT_FALSE(cf_iterator->second.exclusive); ASSERT_OK(txn1->Rollback()); ASSERT_OK(txn2->Rollback()); ASSERT_OK(txn3->Rollback()); // Test txn1 and txn2 sharing a lock and txn3 trying to obtain it. s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn3->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); txn1->UndoGetForUpdate("foo"); s = txn3->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); txn2->UndoGetForUpdate("foo"); s = txn3->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_OK(s); ASSERT_OK(txn1->Rollback()); ASSERT_OK(txn2->Rollback()); ASSERT_OK(txn3->Rollback()); // Test txn1 and txn2 sharing a lock and txn2 trying to upgrade lock. s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); txn1->UndoGetForUpdate("foo"); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_OK(s); ASSERT_OK(txn1->Rollback()); ASSERT_OK(txn2->Rollback()); // Test txn1 trying to downgrade its lock. s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr, true /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); // Should still fail after "downgrading". s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); ASSERT_OK(txn1->Rollback()); ASSERT_OK(txn2->Rollback()); // Test txn1 holding an exclusive lock and txn2 trying to obtain shared // access. s = txn1->GetForUpdate(read_options, "foo", (std::string*)nullptr); ASSERT_OK(s); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); txn1->UndoGetForUpdate("foo"); s = txn2->GetForUpdate(read_options, "foo", (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); delete txn1; delete txn2; delete txn3; } TEST_P(TransactionTest, DeadlockCycleShared) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; txn_options.lock_timeout = 1000000; txn_options.deadlock_detect = true; // Set up a wait for chain like this: // // Tn -> T(n*2) // Tn -> T(n*2 + 1) // // So we have: // T1 -> T2 -> T4 ... // | |> T5 ... // |> T3 -> T6 ... // |> T7 ... // up to T31, then T[16 - 31] -> T1. // Note that Tn holds lock on floor(n / 2). std::vector txns(31); for (uint32_t i = 0; i < 31; i++) { txns[i] = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txns[i]); auto s = txns[i]->GetForUpdate(read_options, std::to_string((i + 1) / 2), (std::string*)nullptr, false /* exclusive */); ASSERT_OK(s); } std::atomic checkpoints(0); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "PointLockManager::AcquireWithTimeout:WaitingTxn", [&](void* /*arg*/) { checkpoints.fetch_add(1); }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); // We want the leaf transactions to block and hold everyone back. std::vector threads; for (uint32_t i = 0; i < 15; i++) { std::function blocking_thread = [&, i] { auto s = txns[i]->GetForUpdate(read_options, std::to_string(i + 1), (std::string*)nullptr, true /* exclusive */); ASSERT_OK(s); ASSERT_OK(txns[i]->Rollback()); delete txns[i]; }; threads.emplace_back(blocking_thread); } // Wait until all threads are waiting on each other. while (checkpoints.load() != 15) { /* sleep override */ std::this_thread::sleep_for(std::chrono::milliseconds(100)); } ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); // Complete the cycle T[16 - 31] -> T1 for (uint32_t i = 15; i < 31; i++) { auto s = txns[i]->GetForUpdate(read_options, "0", (std::string*)nullptr, true /* exclusive */); ASSERT_TRUE(s.IsDeadlock()); // Calculate next buffer len, plateau at 5 when 5 records are inserted. const uint32_t curr_dlock_buffer_len_ = (i - 14 > kInitialMaxDeadlocks) ? kInitialMaxDeadlocks : (i - 14); auto dlock_buffer = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer.size(), curr_dlock_buffer_len_); auto dlock_entry = dlock_buffer[0].path; ASSERT_EQ(dlock_entry.size(), kInitialMaxDeadlocks); int64_t pre_deadlock_time = dlock_buffer[0].deadlock_time; int64_t cur_deadlock_time = 0; for (auto const& dl_path_rec : dlock_buffer) { cur_deadlock_time = dl_path_rec.deadlock_time; ASSERT_NE(cur_deadlock_time, 0); ASSERT_TRUE(cur_deadlock_time <= pre_deadlock_time); pre_deadlock_time = cur_deadlock_time; } int64_t curr_waiting_key = 0; // Offset of each txn id from the root of the shared dlock tree's txn id. int64_t offset_root = dlock_entry[0].m_txn_id - 1; // Offset of the final entry in the dlock path from the root's txn id. TransactionID leaf_id = dlock_entry[dlock_entry.size() - 1].m_txn_id - offset_root; for (auto it = dlock_entry.rbegin(); it != dlock_entry.rend(); ++it) { auto dl_node = *it; ASSERT_EQ(dl_node.m_txn_id, offset_root + leaf_id); ASSERT_EQ(dl_node.m_cf_id, 0U); ASSERT_EQ(dl_node.m_waiting_key, std::to_string(curr_waiting_key)); ASSERT_EQ(dl_node.m_exclusive, true); if (curr_waiting_key == 0) { curr_waiting_key = leaf_id; } curr_waiting_key /= 2; leaf_id /= 2; } } // Rollback the leaf transaction. for (uint32_t i = 15; i < 31; i++) { ASSERT_OK(txns[i]->Rollback()); delete txns[i]; } for (auto& t : threads) { t.join(); } // Downsize the buffer and verify the 3 latest deadlocks are preserved. auto dlock_buffer_before_resize = db->GetDeadlockInfoBuffer(); db->SetDeadlockInfoBufferSize(3); auto dlock_buffer_after_resize = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer_after_resize.size(), 3); for (uint32_t i = 0; i < dlock_buffer_after_resize.size(); i++) { for (uint32_t j = 0; j < dlock_buffer_after_resize[i].path.size(); j++) { ASSERT_EQ(dlock_buffer_after_resize[i].path[j].m_txn_id, dlock_buffer_before_resize[i].path[j].m_txn_id); } } // Upsize the buffer and verify the 3 latest dealocks are preserved. dlock_buffer_before_resize = db->GetDeadlockInfoBuffer(); db->SetDeadlockInfoBufferSize(5); dlock_buffer_after_resize = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer_after_resize.size(), 3); for (uint32_t i = 0; i < dlock_buffer_before_resize.size(); i++) { for (uint32_t j = 0; j < dlock_buffer_before_resize[i].path.size(); j++) { ASSERT_EQ(dlock_buffer_after_resize[i].path[j].m_txn_id, dlock_buffer_before_resize[i].path[j].m_txn_id); } } // Downsize to 0 and verify the size is consistent. dlock_buffer_before_resize = db->GetDeadlockInfoBuffer(); db->SetDeadlockInfoBufferSize(0); dlock_buffer_after_resize = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer_after_resize.size(), 0); // Upsize from 0 to verify the size is persistent. dlock_buffer_before_resize = db->GetDeadlockInfoBuffer(); db->SetDeadlockInfoBufferSize(3); dlock_buffer_after_resize = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer_after_resize.size(), 0); // Contrived case of shared lock of cycle size 2 to verify that a shared // lock causing a deadlock is correctly reported as "shared" in the buffer. std::vector txns_shared(2); // Create a cycle of size 2. for (uint32_t i = 0; i < 2; i++) { txns_shared[i] = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txns_shared[i]); auto s = txns_shared[i]->GetForUpdate(read_options, std::to_string(i), (std::string*)nullptr); ASSERT_OK(s); } std::atomic checkpoints_shared(0); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "PointLockManager::AcquireWithTimeout:WaitingTxn", [&](void* /*arg*/) { checkpoints_shared.fetch_add(1); }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); std::vector threads_shared; for (uint32_t i = 0; i < 1; i++) { std::function blocking_thread = [&, i] { auto s = txns_shared[i]->GetForUpdate(read_options, std::to_string(i + 1), (std::string*)nullptr); ASSERT_OK(s); ASSERT_OK(txns_shared[i]->Rollback()); delete txns_shared[i]; }; threads_shared.emplace_back(blocking_thread); } // Wait until all threads are waiting on each other. while (checkpoints_shared.load() != 1) { /* sleep override */ std::this_thread::sleep_for(std::chrono::milliseconds(100)); } ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); // Complete the cycle T2 -> T1 with a shared lock. auto s = txns_shared[1]->GetForUpdate(read_options, "0", (std::string*)nullptr, false); ASSERT_TRUE(s.IsDeadlock()); auto dlock_buffer = db->GetDeadlockInfoBuffer(); // Verify the size of the buffer and the single path. ASSERT_EQ(dlock_buffer.size(), 1); ASSERT_EQ(dlock_buffer[0].path.size(), 2); // Verify the exclusivity field of the transactions in the deadlock path. ASSERT_TRUE(dlock_buffer[0].path[0].m_exclusive); ASSERT_FALSE(dlock_buffer[0].path[1].m_exclusive); ASSERT_OK(txns_shared[1]->Rollback()); delete txns_shared[1]; for (auto& t : threads_shared) { t.join(); } } #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionStressTest, DeadlockCycle) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; // offset by 2 from the max depth to test edge case const uint32_t kMaxCycleLength = 52; txn_options.lock_timeout = 1000000; txn_options.deadlock_detect = true; for (uint32_t len = 2; len < kMaxCycleLength; len++) { // Set up a long wait for chain like this: // // T1 -> T2 -> T3 -> ... -> Tlen std::vector txns(len); for (uint32_t i = 0; i < len; i++) { txns[i] = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txns[i]); auto s = txns[i]->GetForUpdate(read_options, std::to_string(i), (std::string*)nullptr); ASSERT_OK(s); } std::atomic checkpoints(0); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "PointLockManager::AcquireWithTimeout:WaitingTxn", [&](void* /*arg*/) { checkpoints.fetch_add(1); }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); // We want the last transaction in the chain to block and hold everyone // back. std::vector threads; for (uint32_t i = 0; i + 1 < len; i++) { std::function blocking_thread = [&, i] { auto s = txns[i]->GetForUpdate(read_options, std::to_string(i + 1), (std::string*)nullptr); ASSERT_OK(s); ASSERT_OK(txns[i]->Rollback()); delete txns[i]; }; threads.emplace_back(blocking_thread); } // Wait until all threads are waiting on each other. while (checkpoints.load() != len - 1) { /* sleep override */ std::this_thread::sleep_for(std::chrono::milliseconds(100)); } ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); // Complete the cycle Tlen -> T1 auto s = txns[len - 1]->GetForUpdate(read_options, "0", (std::string*)nullptr); ASSERT_TRUE(s.IsDeadlock()); const uint32_t dlock_buffer_size_ = (len - 1 > 5) ? 5 : (len - 1); uint32_t curr_waiting_key = 0; TransactionID curr_txn_id = txns[0]->GetID(); auto dlock_buffer = db->GetDeadlockInfoBuffer(); ASSERT_EQ(dlock_buffer.size(), dlock_buffer_size_); uint32_t check_len = len; bool check_limit_flag = false; // Special case for a deadlock path that exceeds the maximum depth. if (len > 50) { check_len = 0; check_limit_flag = true; } auto dlock_entry = dlock_buffer[0].path; ASSERT_EQ(dlock_entry.size(), check_len); ASSERT_EQ(dlock_buffer[0].limit_exceeded, check_limit_flag); int64_t pre_deadlock_time = dlock_buffer[0].deadlock_time; int64_t cur_deadlock_time = 0; for (auto const& dl_path_rec : dlock_buffer) { cur_deadlock_time = dl_path_rec.deadlock_time; ASSERT_NE(cur_deadlock_time, 0); ASSERT_TRUE(cur_deadlock_time <= pre_deadlock_time); pre_deadlock_time = cur_deadlock_time; } // Iterates backwards over path verifying decreasing txn_ids. for (auto it = dlock_entry.rbegin(); it != dlock_entry.rend(); ++it) { auto dl_node = *it; ASSERT_EQ(dl_node.m_txn_id, len + curr_txn_id - 1); ASSERT_EQ(dl_node.m_cf_id, 0u); ASSERT_EQ(dl_node.m_waiting_key, std::to_string(curr_waiting_key)); ASSERT_EQ(dl_node.m_exclusive, true); curr_txn_id--; if (curr_waiting_key == 0) { curr_waiting_key = len; } curr_waiting_key--; } // Rollback the last transaction. ASSERT_OK(txns[len - 1]->Rollback()); delete txns[len - 1]; for (auto& t : threads) { t.join(); } } } TEST_P(TransactionStressTest, DeadlockStress) { const uint32_t NUM_TXN_THREADS = 10; const uint32_t NUM_KEYS = 100; const uint32_t NUM_ITERS = 1000; WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; txn_options.lock_timeout = 1000000; txn_options.deadlock_detect = true; std::vector keys; for (uint32_t i = 0; i < NUM_KEYS; i++) { ASSERT_OK(db->Put(write_options, Slice(std::to_string(i)), Slice(""))); keys.push_back(std::to_string(i)); } size_t tid = std::hash()(std::this_thread::get_id()); Random rnd(static_cast(tid)); std::function stress_thread = [&](uint32_t seed) { std::default_random_engine g(seed); Transaction* txn; for (uint32_t i = 0; i < NUM_ITERS; i++) { txn = db->BeginTransaction(write_options, txn_options); auto random_keys = keys; std::shuffle(random_keys.begin(), random_keys.end(), g); // Lock keys in random order. for (const auto& k : random_keys) { // Lock mostly for shared access, but exclusive 1/4 of the time. auto s = txn->GetForUpdate(read_options, k, (std::string*)nullptr, txn->GetID() % 4 == 0); if (!s.ok()) { ASSERT_TRUE(s.IsDeadlock()); ASSERT_OK(txn->Rollback()); break; } } delete txn; } }; std::vector threads; for (uint32_t i = 0; i < NUM_TXN_THREADS; i++) { threads.emplace_back(stress_thread, rnd.Next()); } for (auto& t : threads) { t.join(); } } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionTest, CommitTimeBatchFailTest) { WriteOptions write_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); ASSERT_OK(txn1->GetCommitTimeWriteBatch()->Put("cat", "dog")); s = txn1->Put("foo", "bar"); ASSERT_OK(s); // fails due to non-empty commit-time batch s = txn1->Commit(); ASSERT_EQ(s, Status::InvalidArgument()); delete txn1; } TEST_P(TransactionTest, LogMarkLeakTest) { TransactionOptions txn_options; WriteOptions write_options; options.write_buffer_size = 1024; ASSERT_OK(ReOpenNoDelete()); assert(db != nullptr); Random rnd(47); std::vector txns; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); // At the beginning there should be no log containing prepare data ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); for (size_t i = 0; i < 100; i++) { Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn->SetName("xid" + std::to_string(i))); ASSERT_OK(txn->Put(Slice("foo" + std::to_string(i)), Slice("bar"))); ASSERT_OK(txn->Prepare()); ASSERT_GT(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); if (rnd.OneIn(5)) { txns.push_back(txn); } else { ASSERT_OK(txn->Commit()); delete txn; } ASSERT_OK(db_impl->TEST_FlushMemTable(true)); } for (auto txn : txns) { ASSERT_OK(txn->Commit()); delete txn; } // At the end there should be no log left containing prepare data ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); // Make sure that the underlying data structures are properly truncated and // cause not leak ASSERT_EQ(db_impl->TEST_PreparedSectionCompletedSize(), 0); ASSERT_EQ(db_impl->TEST_LogsWithPrepSize(), 0); } TEST_P(TransactionTest, SimpleTwoPhaseTransactionTest) { for (bool cwb4recovery : {true, false}) { ASSERT_OK(ReOpen()); WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; txn_options.use_only_the_last_commit_time_batch_for_recovery = cwb4recovery; std::string value; Status s; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("xid"); ASSERT_OK(s); ASSERT_EQ(db->GetTransactionByName("xid"), txn); // transaction put s = txn->Put(Slice("foo"), Slice("bar")); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); // regular db put s = db->Put(write_options, Slice("foo2"), Slice("bar2")); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); // regular db read ASSERT_OK(db->Get(read_options, "foo2", &value)); ASSERT_EQ(value, "bar2"); // commit time put if (cwb4recovery) { ASSERT_OK( txn->GetCommitTimeWriteBatch()->Put(Slice("gtid"), Slice("dogs"))); ASSERT_OK( txn->GetCommitTimeWriteBatch()->Put(Slice("gtid2"), Slice("cats"))); } // nothing has been prepped yet ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); s = txn->Prepare(); ASSERT_OK(s); // data not im mem yet s = db->Get(read_options, Slice("foo"), &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, Slice("gtid"), &value); ASSERT_TRUE(s.IsNotFound()); // find trans in list of prepared transactions std::vector prepared_trans; db->GetAllPreparedTransactions(&prepared_trans); ASSERT_EQ(prepared_trans.size(), 1); ASSERT_EQ(prepared_trans.front()->GetName(), "xid"); auto log_containing_prep = db_impl->TEST_FindMinLogContainingOutstandingPrep(); ASSERT_GT(log_containing_prep, 0); // make commit s = txn->Commit(); ASSERT_OK(s); // value is now available s = db->Get(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); // we already committed s = txn->Commit(); ASSERT_EQ(s, Status::InvalidArgument()); // no longer is prepared results db->GetAllPreparedTransactions(&prepared_trans); ASSERT_EQ(prepared_trans.size(), 0); ASSERT_EQ(db->GetTransactionByName("xid"), nullptr); // heap should not care about prepared section anymore ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // but now our memtable should be referencing the prep section ASSERT_GE(log_containing_prep, db_impl->MinLogNumberToKeep()); ASSERT_EQ(log_containing_prep, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; default: assert(false); } ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // After flush the recoverable state must be visible if (cwb4recovery) { s = db->Get(read_options, "gtid", &value); ASSERT_OK(s); ASSERT_EQ(value, "dogs"); s = db->Get(read_options, "gtid2", &value); ASSERT_OK(s); ASSERT_EQ(value, "cats"); } // after memtable flush we can now relese the log ASSERT_GT(db_impl->MinLogNumberToKeep(), log_containing_prep); ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); delete txn; if (cwb4recovery) { // kill and reopen to trigger recovery s = ReOpenNoDelete(); ASSERT_OK(s); assert(db != nullptr); s = db->Get(read_options, "gtid", &value); ASSERT_OK(s); ASSERT_EQ(value, "dogs"); s = db->Get(read_options, "gtid2", &value); ASSERT_OK(s); ASSERT_EQ(value, "cats"); } } } TEST_P(TransactionTest, TwoPhaseNameTest) { Status s; WriteOptions write_options; TransactionOptions txn_options; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); Transaction* txn3 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn3); delete txn3; // cant prepare txn without name s = txn1->Prepare(); ASSERT_EQ(s, Status::InvalidArgument()); // name too short s = txn1->SetName(""); ASSERT_EQ(s, Status::InvalidArgument()); // name too long s = txn1->SetName(std::string(513, 'x')); ASSERT_EQ(s, Status::InvalidArgument()); // valid set name s = txn1->SetName("name1"); ASSERT_OK(s); // cant have duplicate name s = txn2->SetName("name1"); ASSERT_EQ(s, Status::InvalidArgument()); // shouldn't be able to prepare s = txn2->Prepare(); ASSERT_EQ(s, Status::InvalidArgument()); // valid name set s = txn2->SetName("name2"); ASSERT_OK(s); // cant reset name s = txn2->SetName("name3"); ASSERT_EQ(s, Status::InvalidArgument()); ASSERT_EQ(txn1->GetName(), "name1"); ASSERT_EQ(txn2->GetName(), "name2"); s = txn1->Prepare(); ASSERT_OK(s); // can't rename after prepare s = txn1->SetName("name4"); ASSERT_EQ(s, Status::InvalidArgument()); ASSERT_OK(txn1->Rollback()); ASSERT_OK(txn2->Rollback()); delete txn1; delete txn2; } TEST_P(TransactionTest, TwoPhaseEmptyWriteTest) { for (bool cwb4recovery : {true, false}) { for (bool test_with_empty_wal : {true, false}) { if (!cwb4recovery && test_with_empty_wal) { continue; } ASSERT_OK(ReOpen()); Status s; std::string value; WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; txn_options.use_only_the_last_commit_time_batch_for_recovery = cwb4recovery; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); s = txn1->SetName("joe"); ASSERT_OK(s); s = txn2->SetName("bob"); ASSERT_OK(s); s = txn1->Prepare(); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); delete txn1; if (cwb4recovery) { ASSERT_OK( txn2->GetCommitTimeWriteBatch()->Put(Slice("foo"), Slice("bar"))); } s = txn2->Prepare(); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn2; if (cwb4recovery) { if (test_with_empty_wal) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // After flush the state must be visible s = db->Get(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); } ASSERT_OK(db->FlushWAL(true)); // kill and reopen to trigger recovery s = ReOpenNoDelete(); ASSERT_OK(s); assert(db != nullptr); s = db->Get(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); } } } } #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionStressTest, TwoPhaseExpirationTest) { Status s; WriteOptions write_options; TransactionOptions txn_options; txn_options.expiration = 500; // 500ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); ASSERT_TRUE(txn1); s = txn1->SetName("joe"); ASSERT_OK(s); s = txn2->SetName("bob"); ASSERT_OK(s); s = txn1->Prepare(); ASSERT_OK(s); /* sleep override */ std::this_thread::sleep_for(std::chrono::milliseconds(1000)); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Prepare(); ASSERT_EQ(s, Status::Expired()); delete txn1; delete txn2; } TEST_P(TransactionTest, TwoPhaseRollbackTest) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("xid"); ASSERT_OK(s); // transaction put s = txn->Put(Slice("tfoo"), Slice("tbar")); ASSERT_OK(s); // value is readable form txn s = txn->Get(read_options, Slice("tfoo"), &value); ASSERT_OK(s); ASSERT_EQ(value, "tbar"); // issue rollback s = txn->Rollback(); ASSERT_OK(s); // value is nolonger readable s = txn->Get(read_options, Slice("tfoo"), &value); ASSERT_TRUE(s.IsNotFound()); ASSERT_EQ(txn->GetNumPuts(), 0); // put new txn values s = txn->Put(Slice("tfoo2"), Slice("tbar2")); ASSERT_OK(s); // new value is readable from txn s = txn->Get(read_options, Slice("tfoo2"), &value); ASSERT_OK(s); ASSERT_EQ(value, "tbar2"); s = txn->Prepare(); ASSERT_OK(s); // flush to next wal s = db->Put(write_options, Slice("foo"), Slice("bar")); ASSERT_OK(s); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // issue rollback (marker written to WAL) s = txn->Rollback(); ASSERT_OK(s); // value is nolonger readable s = txn->Get(read_options, Slice("tfoo2"), &value); ASSERT_TRUE(s.IsNotFound()); ASSERT_EQ(txn->GetNumPuts(), 0); // make commit s = txn->Commit(); ASSERT_EQ(s, Status::InvalidArgument()); // try rollback again s = txn->Rollback(); ASSERT_EQ(s, Status::InvalidArgument()); delete txn; } TEST_P(TransactionTest, PersistentTwoPhaseTransactionTest) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("xid"); ASSERT_OK(s); ASSERT_EQ(db->GetTransactionByName("xid"), txn); // transaction put s = txn->Put(Slice("foo"), Slice("bar")); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); // txn read s = txn->Get(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); // regular db put s = db->Put(write_options, Slice("foo2"), Slice("bar2")); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // regular db read ASSERT_OK(db->Get(read_options, "foo2", &value)); ASSERT_EQ(value, "bar2"); // nothing has been prepped yet ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); // prepare s = txn->Prepare(); ASSERT_OK(s); // still not available to db s = db->Get(read_options, Slice("foo"), &value); ASSERT_TRUE(s.IsNotFound()); ASSERT_OK(db->FlushWAL(false)); delete txn; // kill and reopen static_cast(db)->TEST_Crash(); s = ReOpenNoDelete(); ASSERT_OK(s); assert(db != nullptr); db_impl = static_cast_with_check(db->GetRootDB()); // find trans in list of prepared transactions std::vector prepared_trans; db->GetAllPreparedTransactions(&prepared_trans); ASSERT_EQ(prepared_trans.size(), 1); txn = prepared_trans.front(); ASSERT_TRUE(txn); ASSERT_EQ(txn->GetName(), "xid"); ASSERT_EQ(db->GetTransactionByName("xid"), txn); // log has been marked auto log_containing_prep = db_impl->TEST_FindMinLogContainingOutstandingPrep(); ASSERT_GT(log_containing_prep, 0); // value is readable from txn s = txn->Get(read_options, "foo", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar"); // make commit s = txn->Commit(); ASSERT_OK(s); // value is now available ASSERT_OK(db->Get(read_options, "foo", &value)); ASSERT_EQ(value, "bar"); // we already committed s = txn->Commit(); ASSERT_EQ(s, Status::InvalidArgument()); // no longer is prepared results prepared_trans.clear(); db->GetAllPreparedTransactions(&prepared_trans); ASSERT_EQ(prepared_trans.size(), 0); // transaction should no longer be visible ASSERT_EQ(db->GetTransactionByName("xid"), nullptr); // heap should not care about prepared section anymore ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // but now our memtable should be referencing the prep section ASSERT_EQ(log_containing_prep, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); ASSERT_GE(log_containing_prep, db_impl->MinLogNumberToKeep()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; default: assert(false); } // Add a dummy record to memtable before a flush. Otherwise, the // memtable will be empty and flush will be skipped. s = db->Put(write_options, Slice("foo3"), Slice("bar3")); ASSERT_OK(s); ASSERT_OK(db_impl->TEST_FlushMemTable(true)); // after memtable flush we can now release the log ASSERT_GT(db_impl->MinLogNumberToKeep(), log_containing_prep); ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); delete txn; // deleting transaction should unregister transaction ASSERT_EQ(db->GetTransactionByName("xid"), nullptr); } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) // TODO this test needs to be updated with serial commits TEST_P(TransactionTest, DISABLED_TwoPhaseMultiThreadTest) { // mix transaction writes and regular writes const uint32_t NUM_TXN_THREADS = 50; std::atomic txn_thread_num(0); std::function txn_write_thread = [&]() { uint32_t id = txn_thread_num.fetch_add(1); WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; TransactionOptions txn_options; txn_options.lock_timeout = 1000000; if (id % 2 == 0) { txn_options.expiration = 1000000; } TransactionName name("xid_" + std::string(1, 'A' + static_cast(id))); Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn->SetName(name)); for (int i = 0; i < 10; i++) { std::string key(name + "_" + std::string(1, static_cast('A' + i))); ASSERT_OK(txn->Put(key, "val")); } ASSERT_OK(txn->Prepare()); ASSERT_OK(txn->Commit()); delete txn; }; // assure that all thread are in the same write group std::atomic t_wait_on_prepare(0); std::atomic t_wait_on_commit(0); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "WriteThread::JoinBatchGroup:Wait", [&](void* arg) { auto* writer = static_cast(arg); if (writer->ShouldWriteToWAL()) { t_wait_on_prepare.fetch_add(1); // wait for friends while (t_wait_on_prepare.load() < NUM_TXN_THREADS) { env->SleepForMicroseconds(10); } } else if (writer->ShouldWriteToMemtable()) { t_wait_on_commit.fetch_add(1); // wait for friends while (t_wait_on_commit.load() < NUM_TXN_THREADS) { env->SleepForMicroseconds(10); } } else { FAIL(); } }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); // do all the writes std::vector threads; for (uint32_t i = 0; i < NUM_TXN_THREADS; i++) { threads.emplace_back(txn_write_thread); } for (auto& t : threads) { t.join(); } ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->ClearAllCallBacks(); ReadOptions read_options; std::string value; Status s; for (uint32_t t = 0; t < NUM_TXN_THREADS; t++) { TransactionName name("xid_" + std::string(1, 'A' + static_cast(t))); for (int i = 0; i < 10; i++) { std::string key(name + "_" + std::string(1, static_cast('A' + i))); s = db->Get(read_options, key, &value); ASSERT_OK(s); ASSERT_EQ(value, "val"); } } } #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionStressTest, TwoPhaseLongPrepareTest) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("bob"); ASSERT_OK(s); // transaction put s = txn->Put(Slice("foo"), Slice("bar")); ASSERT_OK(s); // prepare s = txn->Prepare(); ASSERT_OK(s); delete txn; for (int i = 0; i < 1000; i++) { std::string key(i, 'k'); std::string val(1000, 'v'); assert(db != nullptr); s = db->Put(write_options, key, val); ASSERT_OK(s); if (i % 29 == 0) { // crash fault_fs->SetFilesystemActive(false); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete()); } else if (i % 37 == 0) { // close ASSERT_OK(ReOpenNoDelete()); } } // commit old txn txn = db->GetTransactionByName("bob"); ASSERT_TRUE(txn); s = txn->Commit(); ASSERT_OK(s); // verify data txn data s = db->Get(read_options, "foo", &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, "bar"); // verify non txn data for (int i = 0; i < 1000; i++) { std::string key(i, 'k'); std::string val(1000, 'v'); s = db->Get(read_options, key, &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, val); } delete txn; } TEST_P(TransactionTest, TwoPhaseSequenceTest) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("xid"); ASSERT_OK(s); // transaction put s = txn->Put(Slice("foo"), Slice("bar")); ASSERT_OK(s); s = txn->Put(Slice("foo2"), Slice("bar2")); ASSERT_OK(s); s = txn->Put(Slice("foo3"), Slice("bar3")); ASSERT_OK(s); s = txn->Put(Slice("foo4"), Slice("bar4")); ASSERT_OK(s); // prepare s = txn->Prepare(); ASSERT_OK(s); // make commit s = txn->Commit(); ASSERT_OK(s); delete txn; // kill and reopen fault_fs->SetFilesystemActive(false); ASSERT_OK(ReOpenNoDelete()); assert(db != nullptr); // value is now available s = db->Get(read_options, "foo4", &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, "bar4"); } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionTest, TwoPhaseDoubleRecoveryTest) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("a"); ASSERT_OK(s); // transaction put s = txn->Put(Slice("foo"), Slice("bar")); ASSERT_OK(s); // prepare s = txn->Prepare(); ASSERT_OK(s); delete txn; // kill and reopen fault_fs->SetFilesystemActive(false); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete()); // commit old txn assert(db != nullptr); // Make clang analyze happy. txn = db->GetTransactionByName("a"); assert(txn != nullptr); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "foo", &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, "bar"); delete txn; txn = db->BeginTransaction(write_options, txn_options); s = txn->SetName("b"); ASSERT_OK(s); s = txn->Put(Slice("foo2"), Slice("bar2")); ASSERT_OK(s); s = txn->Prepare(); ASSERT_OK(s); s = txn->Commit(); ASSERT_OK(s); delete txn; // kill and reopen fault_fs->SetFilesystemActive(false); ASSERT_OK(ReOpenNoDelete()); assert(db != nullptr); // value is now available s = db->Get(read_options, "foo", &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, "bar"); s = db->Get(read_options, "foo2", &value); ASSERT_EQ(s, Status::OK()); ASSERT_EQ(value, "bar2"); } TEST_P(TransactionTest, TwoPhaseLogRollingTest) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); Status s; std::string v; ColumnFamilyHandle *cfa, *cfb; // Create 2 new column families ColumnFamilyOptions cf_options; s = db->CreateColumnFamily(cf_options, "CFA", &cfa); ASSERT_OK(s); s = db->CreateColumnFamily(cf_options, "CFB", &cfb); ASSERT_OK(s); WriteOptions wopts; wopts.disableWAL = false; wopts.sync = true; TransactionOptions topts1; Transaction* txn1 = db->BeginTransaction(wopts, topts1); s = txn1->SetName("xid1"); ASSERT_OK(s); TransactionOptions topts2; Transaction* txn2 = db->BeginTransaction(wopts, topts2); s = txn2->SetName("xid2"); ASSERT_OK(s); // transaction put in two column families s = txn1->Put(cfa, "ka1", "va1"); ASSERT_OK(s); // transaction put in two column families s = txn2->Put(cfa, "ka2", "va2"); ASSERT_OK(s); s = txn2->Put(cfb, "kb2", "vb2"); ASSERT_OK(s); // write prep section to wal s = txn1->Prepare(); ASSERT_OK(s); // our log should be in the heap ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), txn1->GetLogNumber()); ASSERT_EQ(db_impl->TEST_LogfileNumber(), txn1->GetLastLogNumber()); // flush default cf to crate new log s = db->Put(wopts, "foo", "bar"); ASSERT_OK(s); s = db_impl->TEST_FlushMemTable(true); ASSERT_OK(s); // make sure we are on a new log ASSERT_GT(db_impl->TEST_LogfileNumber(), txn1->GetLastLogNumber()); // put txn2 prep section in this log s = txn2->Prepare(); ASSERT_OK(s); ASSERT_EQ(db_impl->TEST_LogfileNumber(), txn2->GetLastLogNumber()); // heap should still see first log ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), txn1->GetLogNumber()); // commit txn1 s = txn1->Commit(); ASSERT_OK(s); // heap should now show txn2s log ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), txn2->GetLogNumber()); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // we should see txn1s log refernced by the memtables ASSERT_EQ(txn1->GetLogNumber(), db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; default: assert(false); } // flush default cf to crate new log s = db->Put(wopts, "foo", "bar2"); ASSERT_OK(s); s = db_impl->TEST_FlushMemTable(true); ASSERT_OK(s); // make sure we are on a new log ASSERT_GT(db_impl->TEST_LogfileNumber(), txn2->GetLastLogNumber()); // commit txn2 s = txn2->Commit(); ASSERT_OK(s); // heap should not show any logs ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // should show the first txn log ASSERT_EQ(txn1->GetLogNumber(), db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; default: assert(false); } // flush only cfa memtable s = db_impl->TEST_FlushMemTable(true, false, cfa); ASSERT_OK(s); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // should show the first txn log ASSERT_EQ(txn2->GetLogNumber(), db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(0, db_impl->TEST_FindMinPrepLogReferencedByMemTable()); break; default: assert(false); } // flush only cfb memtable s = db_impl->TEST_FlushMemTable(true, false, cfb); ASSERT_OK(s); // should show not dependency on logs ASSERT_EQ(db_impl->TEST_FindMinPrepLogReferencedByMemTable(), 0); ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), 0); delete txn1; delete txn2; delete cfa; delete cfb; } TEST_P(TransactionTest, TwoPhaseLogRollingTest2) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); Status s; ColumnFamilyHandle *cfa, *cfb; ColumnFamilyOptions cf_options; s = db->CreateColumnFamily(cf_options, "CFA", &cfa); ASSERT_OK(s); s = db->CreateColumnFamily(cf_options, "CFB", &cfb); ASSERT_OK(s); WriteOptions wopts; wopts.disableWAL = false; wopts.sync = true; auto cfh_a = static_cast_with_check(cfa); auto cfh_b = static_cast_with_check(cfb); TransactionOptions topts1; Transaction* txn1 = db->BeginTransaction(wopts, topts1); s = txn1->SetName("xid1"); ASSERT_OK(s); s = txn1->Put(cfa, "boys", "girls1"); ASSERT_OK(s); Transaction* txn2 = db->BeginTransaction(wopts, topts1); s = txn2->SetName("xid2"); ASSERT_OK(s); s = txn2->Put(cfb, "up", "down1"); ASSERT_OK(s); // prepre transaction in LOG A s = txn1->Prepare(); ASSERT_OK(s); // prepre transaction in LOG A s = txn2->Prepare(); ASSERT_OK(s); // regular put so that mem table can actually be flushed for log rolling s = db->Put(wopts, "cats", "dogs1"); ASSERT_OK(s); auto prepare_log_no = txn1->GetLastLogNumber(); // roll to LOG B s = db_impl->TEST_FlushMemTable(true); ASSERT_OK(s); // now we pause background work so that // imm()s are not flushed before we can check their status s = db_impl->PauseBackgroundWork(); ASSERT_OK(s); ASSERT_GT(db_impl->TEST_LogfileNumber(), prepare_log_no); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // This cf is empty and should ref the latest log ASSERT_GT(cfh_a->cfd()->GetLogNumber(), prepare_log_no); ASSERT_EQ(cfh_a->cfd()->GetLogNumber(), db_impl->TEST_LogfileNumber()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // This cf is not flushed yet and should ref the log that has its data ASSERT_EQ(cfh_a->cfd()->GetLogNumber(), prepare_log_no); break; default: assert(false); } ASSERT_EQ(db_impl->TEST_FindMinLogContainingOutstandingPrep(), txn1->GetLogNumber()); ASSERT_EQ(db_impl->TEST_FindMinPrepLogReferencedByMemTable(), 0); // commit in LOG B s = txn1->Commit(); ASSERT_OK(s); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: ASSERT_EQ(db_impl->TEST_FindMinPrepLogReferencedByMemTable(), prepare_log_no); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // In these modes memtable do not ref the prep sections ASSERT_EQ(db_impl->TEST_FindMinPrepLogReferencedByMemTable(), 0); break; default: assert(false); } ASSERT_TRUE(!db_impl->TEST_UnableToReleaseOldestLog()); // request a flush for all column families such that the earliest // alive log file can be killed ASSERT_OK(db_impl->TEST_SwitchWAL()); // log cannot be flushed because txn2 has not been commited ASSERT_TRUE(!db_impl->TEST_IsLogGettingFlushed()); ASSERT_TRUE(db_impl->TEST_UnableToReleaseOldestLog()); // assert that cfa has a flush requested ASSERT_TRUE(cfh_a->cfd()->imm()->HasFlushRequested()); switch (txn_db_options.write_policy) { case WRITE_COMMITTED: // cfb should not be flushed becuse it has no data from LOG A ASSERT_TRUE(!cfh_b->cfd()->imm()->HasFlushRequested()); break; case WRITE_PREPARED: case WRITE_UNPREPARED: // cfb should be flushed becuse it has prepared data from LOG A ASSERT_TRUE(cfh_b->cfd()->imm()->HasFlushRequested()); break; default: assert(false); } // cfb now has data from LOG A s = txn2->Commit(); ASSERT_OK(s); ASSERT_OK(db_impl->TEST_SwitchWAL()); ASSERT_TRUE(!db_impl->TEST_UnableToReleaseOldestLog()); // we should see that cfb now has a flush requested ASSERT_TRUE(cfh_b->cfd()->imm()->HasFlushRequested()); // all data in LOG A resides in a memtable that has been // requested for a flush ASSERT_TRUE(db_impl->TEST_IsLogGettingFlushed()); delete txn1; delete txn2; delete cfa; delete cfb; } /* * 1) use prepare to keep first log around to determine starting sequence * during recovery. * 2) insert many values, skipping wal, to increase seqid. * 3) insert final value into wal * 4) recover and see that final value was properly recovered - not * hidden behind improperly summed sequence ids */ TEST_P(TransactionTest, TwoPhaseOutOfOrderDelete) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); WriteOptions wal_on, wal_off; wal_on.sync = true; wal_on.disableWAL = false; wal_off.disableWAL = true; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn1 = db->BeginTransaction(wal_on, txn_options); s = txn1->SetName("1"); ASSERT_OK(s); s = db->Put(wal_on, "first", "first"); ASSERT_OK(s); s = txn1->Put(Slice("dummy"), Slice("dummy")); ASSERT_OK(s); s = txn1->Prepare(); ASSERT_OK(s); s = db->Put(wal_off, "cats", "dogs1"); ASSERT_OK(s); s = db->Put(wal_off, "cats", "dogs2"); ASSERT_OK(s); s = db->Put(wal_off, "cats", "dogs3"); ASSERT_OK(s); s = db_impl->TEST_FlushMemTable(true); ASSERT_OK(s); s = db->Put(wal_on, "cats", "dogs4"); ASSERT_OK(s); ASSERT_OK(db->FlushWAL(false)); // kill and reopen fault_fs->SetFilesystemActive(false); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete()); assert(db != nullptr); s = db->Get(read_options, "first", &value); ASSERT_OK(s); ASSERT_EQ(value, "first"); s = db->Get(read_options, "cats", &value); ASSERT_OK(s); ASSERT_EQ(value, "dogs4"); } TEST_P(TransactionTest, FirstWriteTest) { WriteOptions write_options; // Test conflict checking against the very first write to a db. // The transaction's snapshot will have seq 1 and the following write // will have sequence 1. Status s = db->Put(write_options, "A", "a"); Transaction* txn = db->BeginTransaction(write_options); txn->SetSnapshot(); ASSERT_OK(s); s = txn->Put("A", "b"); ASSERT_OK(s); delete txn; } TEST_P(TransactionTest, FirstWriteTest2) { WriteOptions write_options; Transaction* txn = db->BeginTransaction(write_options); txn->SetSnapshot(); // Test conflict checking against the very first write to a db. // The transaction's snapshot is a seq 0 while the following write // will have sequence 1. Status s = db->Put(write_options, "A", "a"); ASSERT_OK(s); s = txn->Put("A", "b"); ASSERT_TRUE(s.IsBusy()); delete txn; } TEST_P(TransactionTest, WriteOptionsTest) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = true; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); ASSERT_TRUE(txn->GetWriteOptions()->sync); write_options.sync = false; txn->SetWriteOptions(write_options); ASSERT_FALSE(txn->GetWriteOptions()->sync); ASSERT_TRUE(txn->GetWriteOptions()->disableWAL); delete txn; } TEST_P(TransactionTest, WriteConflictTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, "foo", "A")); ASSERT_OK(db->Put(write_options, "foo2", "B")); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->Put("foo", "A2"); ASSERT_OK(s); s = txn->Put("foo2", "B2"); ASSERT_OK(s); // This Put outside of a transaction will conflict with the previous write s = db->Put(write_options, "foo", "xxx"); ASSERT_TRUE(s.IsTimedOut()); s = db->Get(read_options, "foo", &value); ASSERT_EQ(value, "A"); s = txn->Commit(); ASSERT_OK(s); ASSERT_OK(db->Get(read_options, "foo", &value)); ASSERT_EQ(value, "A2"); ASSERT_OK(db->Get(read_options, "foo2", &value)); ASSERT_EQ(value, "B2"); delete txn; } TEST_P(TransactionTest, WriteConflictTest2) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, "foo", "bar")); txn_options.set_snapshot = true; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); // This Put outside of a transaction will conflict with a later write s = db->Put(write_options, "foo", "barz"); ASSERT_OK(s); s = txn->Put("foo2", "X"); ASSERT_OK(s); s = txn->Put("foo", "bar2"); // Conflicts with write done after snapshot taken ASSERT_TRUE(s.IsBusy()); s = txn->Put("foo3", "Y"); ASSERT_OK(s); s = db->Get(read_options, "foo", &value); ASSERT_EQ(value, "barz"); ASSERT_EQ(2, txn->GetNumKeys()); s = txn->Commit(); ASSERT_OK(s); // Txn should commit, but only write foo2 and foo3 // Verify that transaction wrote foo2 and foo3 but not foo ASSERT_OK(db->Get(read_options, "foo", &value)); ASSERT_EQ(value, "barz"); ASSERT_OK(db->Get(read_options, "foo2", &value)); ASSERT_EQ(value, "X"); ASSERT_OK(db->Get(read_options, "foo3", &value)); ASSERT_EQ(value, "Y"); delete txn; } TEST_P(TransactionTest, ReadConflictTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; TransactionOptions txn_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, "foo", "bar")); ASSERT_OK(db->Put(write_options, "foo2", "bar")); txn_options.set_snapshot = true; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "foo", &value)); ASSERT_EQ(value, "bar"); // This Put outside of a transaction will conflict with the previous read s = db->Put(write_options, "foo", "barz"); ASSERT_TRUE(s.IsTimedOut()); s = db->Get(read_options, "foo", &value); ASSERT_EQ(value, "bar"); s = txn->Get(read_options, "foo", &value); ASSERT_EQ(value, "bar"); s = txn->Commit(); ASSERT_OK(s); delete txn; } TEST_P(TransactionTest, TxnOnlyTest) { // Test to make sure transactions work when there are no other writes in an // empty db. WriteOptions write_options; ReadOptions read_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->Put("x", "y"); ASSERT_OK(s); s = txn->Commit(); ASSERT_OK(s); delete txn; } TEST_P(TransactionTest, FlushTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, Slice("foo"), Slice("bar"))); ASSERT_OK(db->Put(write_options, Slice("foo2"), Slice("bar"))); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "foo", &value)); ASSERT_EQ(value, "bar"); s = txn->Put(Slice("foo"), Slice("bar2")); ASSERT_OK(s); ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "foo", &value)); ASSERT_EQ(value, "bar2"); // Put a random key so we have a memtable to flush s = db->Put(write_options, "dummy", "dummy"); ASSERT_OK(s); // force a memtable flush FlushOptions flush_ops; ASSERT_OK(db->Flush(flush_ops)); s = txn->Commit(); // txn should commit since the flushed table is still in MemtableList History ASSERT_OK(s); ASSERT_OK(db->Get(read_options, "foo", &value)); ASSERT_EQ(value, "bar2"); delete txn; } TEST_P(TransactionTest, FlushTest2) { const size_t num_tests = 3; for (size_t n = 0; n < num_tests; n++) { // Test different table factories switch (n) { case 0: break; case 1: options.table_factory.reset(new mock::MockTableFactory()); break; case 2: { PlainTableOptions pt_opts; pt_opts.hash_table_ratio = 0; options.table_factory.reset(NewPlainTableFactory(pt_opts)); break; } } Status s = ReOpen(); ASSERT_OK(s); assert(db != nullptr); WriteOptions write_options; ReadOptions read_options, snapshot_read_options; TransactionOptions txn_options; std::string value; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); ASSERT_OK(db->Put(write_options, Slice("foo"), Slice("bar"))); ASSERT_OK(db->Put(write_options, Slice("foo2"), Slice("bar2"))); ASSERT_OK(db->Put(write_options, Slice("foo3"), Slice("bar3"))); txn_options.set_snapshot = true; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "foo", &value)); ASSERT_EQ(value, "bar"); s = txn->Put(Slice("foo"), Slice("bar2")); ASSERT_OK(s); ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "foo", &value)); ASSERT_EQ(value, "bar2"); // verify foo is locked by txn s = db->Delete(write_options, "foo"); ASSERT_TRUE(s.IsTimedOut()); s = db->Put(write_options, "Z", "z"); ASSERT_OK(s); s = db->Put(write_options, "dummy", "dummy"); ASSERT_OK(s); s = db->Put(write_options, "S", "s"); ASSERT_OK(s); s = db->SingleDelete(write_options, "S"); ASSERT_OK(s); s = txn->Delete("S"); // Should fail after encountering a write to S in memtable ASSERT_TRUE(s.IsBusy()); // force a memtable flush s = db_impl->TEST_FlushMemTable(true); ASSERT_OK(s); // Put a random key so we have a MemTable to flush s = db->Put(write_options, "dummy", "dummy2"); ASSERT_OK(s); // force a memtable flush ASSERT_OK(db_impl->TEST_FlushMemTable(true)); s = db->Put(write_options, "dummy", "dummy3"); ASSERT_OK(s); // force a memtable flush // Since our test db has max_write_buffer_number=2, this flush will cause // the first memtable to get purged from the MemtableList history. ASSERT_OK(db_impl->TEST_FlushMemTable(true)); s = txn->Put("X", "Y"); // Should succeed after verifying there is no write to X in SST file ASSERT_OK(s); s = txn->Put("Z", "zz"); // Should fail after encountering a write to Z in SST file ASSERT_TRUE(s.IsBusy()); s = txn->GetForUpdate(read_options, "foo2", &value); // should succeed since key was written before txn started ASSERT_OK(s); // verify foo2 is locked by txn s = db->Delete(write_options, "foo2"); ASSERT_TRUE(s.IsTimedOut()); s = txn->Delete("S"); // Should fail after encountering a write to S in SST file ASSERT_TRUE(s.IsBusy()); // Write a bunch of keys to db to force a compaction Random rnd(47); for (int i = 0; i < 1000; i++) { s = db->Put(write_options, std::to_string(i), test::CompressibleString(&rnd, 0.8, 100, &value)); ASSERT_OK(s); } s = txn->Put("X", "yy"); // Should succeed after verifying there is no write to X in SST file ASSERT_OK(s); s = txn->Put("Z", "zzz"); // Should fail after encountering a write to Z in SST file ASSERT_TRUE(s.IsBusy()); s = txn->Delete("S"); // Should fail after encountering a write to S in SST file ASSERT_TRUE(s.IsBusy()); s = txn->GetForUpdate(read_options, "foo3", &value); // should succeed since key was written before txn started ASSERT_OK(s); // verify foo3 is locked by txn s = db->Delete(write_options, "foo3"); ASSERT_TRUE(s.IsTimedOut()); ASSERT_OK(db_impl->TEST_WaitForCompact()); s = txn->Commit(); ASSERT_OK(s); // Transaction should only write the keys that succeeded. s = db->Get(read_options, "foo", &value); ASSERT_EQ(value, "bar2"); s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("yy", value); s = db->Get(read_options, "Z", &value); ASSERT_OK(s); ASSERT_EQ("z", value); delete txn; } } TEST_P(TransactionTest, WaitForCompactAbortOnPause) { Status s = ReOpen(); ASSERT_OK(s); assert(db != nullptr); DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); // Pause the background jobs. ASSERT_OK(db_impl->PauseBackgroundWork()); WaitForCompactOptions waitForCompactOptions = WaitForCompactOptions(); waitForCompactOptions.abort_on_pause = true; s = db->WaitForCompact(waitForCompactOptions); ASSERT_NOK(s); ASSERT_FALSE(s.IsNotSupported()); ASSERT_TRUE(s.IsAborted()); } TEST_P(TransactionTest, NoSnapshotTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, "AAA", "bar")); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); // Modify key after transaction start ASSERT_OK(db->Put(write_options, "AAA", "bar1")); // Read and write without a snap ASSERT_OK(txn->GetForUpdate(read_options, "AAA", &value)); ASSERT_EQ(value, "bar1"); s = txn->Put("AAA", "bar2"); ASSERT_OK(s); // Should commit since read/write was done after data changed s = txn->Commit(); ASSERT_OK(s); ASSERT_OK(txn->GetForUpdate(read_options, "AAA", &value)); ASSERT_EQ(value, "bar2"); delete txn; } TEST_P(TransactionTest, MultipleSnapshotTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; ASSERT_OK(db->Put(write_options, "AAA", "bar")); ASSERT_OK(db->Put(write_options, "BBB", "bar")); ASSERT_OK(db->Put(write_options, "CCC", "bar")); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); ASSERT_OK(db->Put(write_options, "AAA", "bar1")); // Read and write without a snapshot ASSERT_OK(txn->GetForUpdate(read_options, "AAA", &value)); ASSERT_EQ(value, "bar1"); s = txn->Put("AAA", "bar2"); ASSERT_OK(s); // Modify BBB before snapshot is taken ASSERT_OK(db->Put(write_options, "BBB", "bar1")); txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); // Read and write with snapshot ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "BBB", &value)); ASSERT_EQ(value, "bar1"); s = txn->Put("BBB", "bar2"); ASSERT_OK(s); ASSERT_OK(db->Put(write_options, "CCC", "bar1")); // Set a new snapshot txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); // Read and write with snapshot ASSERT_OK(txn->GetForUpdate(snapshot_read_options, "CCC", &value)); ASSERT_EQ(value, "bar1"); s = txn->Put("CCC", "bar2"); ASSERT_OK(s); s = txn->GetForUpdate(read_options, "AAA", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); s = txn->GetForUpdate(read_options, "BBB", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); s = txn->GetForUpdate(read_options, "CCC", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); s = db->Get(read_options, "AAA", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar1"); s = db->Get(read_options, "BBB", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar1"); s = db->Get(read_options, "CCC", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar1"); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "AAA", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); s = db->Get(read_options, "BBB", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); s = db->Get(read_options, "CCC", &value); ASSERT_OK(s); ASSERT_EQ(value, "bar2"); // verify that we track multiple writes to the same key at different snapshots delete txn; txn = db->BeginTransaction(write_options); // Potentially conflicting writes ASSERT_OK(db->Put(write_options, "ZZZ", "zzz")); ASSERT_OK(db->Put(write_options, "XXX", "xxx")); txn->SetSnapshot(); TransactionOptions txn_options; txn_options.set_snapshot = true; Transaction* txn2 = db->BeginTransaction(write_options, txn_options); txn2->SetSnapshot(); // This should not conflict in txn since the snapshot is later than the // previous write (spoiler alert: it will later conflict with txn2). s = txn->Put("ZZZ", "zzzz"); ASSERT_OK(s); s = txn->Commit(); ASSERT_OK(s); delete txn; // This will conflict since the snapshot is earlier than another write to ZZZ s = txn2->Put("ZZZ", "xxxxx"); ASSERT_TRUE(s.IsBusy()); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "ZZZ", &value); ASSERT_OK(s); ASSERT_EQ(value, "zzzz"); delete txn2; } TEST_P(TransactionTest, ColumnFamiliesTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; TransactionOptions txn_options; std::string value; Status s; ColumnFamilyHandle *cfa, *cfb; ColumnFamilyOptions cf_options; // Create 2 new column families s = db->CreateColumnFamily(cf_options, "CFA", &cfa); ASSERT_OK(s); s = db->CreateColumnFamily(cf_options, "CFB", &cfb); ASSERT_OK(s); delete cfa; delete cfb; delete db; db = nullptr; // open DB with three column families std::vector column_families; // have to open default column family column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); // open the new column families column_families.emplace_back("CFA", ColumnFamilyOptions()); column_families.emplace_back("CFB", ColumnFamilyOptions()); std::vector handles; ASSERT_OK(ReOpenNoDelete(column_families, &handles)); assert(db != nullptr); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); txn_options.set_snapshot = true; Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); // Write some data to the db WriteBatch batch; ASSERT_OK(batch.Put("foo", "foo")); ASSERT_OK(batch.Put(handles[1], "AAA", "bar")); ASSERT_OK(batch.Put(handles[1], "AAAZZZ", "bar")); s = db->Write(write_options, &batch); ASSERT_OK(s); ASSERT_OK(db->Delete(write_options, handles[1], "AAAZZZ")); // These keys do not conflict with existing writes since they're in // different column families s = txn->Delete("AAA"); ASSERT_OK(s); s = txn->GetForUpdate(snapshot_read_options, handles[1], "foo", &value); ASSERT_TRUE(s.IsNotFound()); Slice key_slice("AAAZZZ"); Slice value_slices[2] = {Slice("bar"), Slice("bar")}; s = txn->Put(handles[2], SliceParts(&key_slice, 1), SliceParts(value_slices, 2)); ASSERT_OK(s); ASSERT_EQ(3, txn->GetNumKeys()); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "AAA", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, handles[2], "AAAZZZ", &value); ASSERT_EQ(value, "barbar"); Slice key_slices[3] = {Slice("AAA"), Slice("ZZ"), Slice("Z")}; Slice value_slice("barbarbar"); s = txn2->Delete(handles[2], "XXX"); ASSERT_OK(s); s = txn2->Delete(handles[1], "XXX"); ASSERT_OK(s); // This write will cause a conflict with the earlier batch write s = txn2->Put(handles[1], SliceParts(key_slices, 3), SliceParts(&value_slice, 1)); ASSERT_TRUE(s.IsBusy()); s = txn2->Commit(); ASSERT_OK(s); // In the above the latest change to AAAZZZ in handles[1] is delete. s = db->Get(read_options, handles[1], "AAAZZZ", &value); ASSERT_TRUE(s.IsNotFound()); delete txn; delete txn2; txn = db->BeginTransaction(write_options, txn_options); snapshot_read_options.snapshot = txn->GetSnapshot(); txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); std::vector multiget_cfh = {handles[1], handles[2], handles[0], handles[2]}; std::vector multiget_keys = {"AAA", "AAAZZZ", "foo", "foo"}; std::vector values(4); std::vector results = txn->MultiGetForUpdate( snapshot_read_options, multiget_cfh, multiget_keys, &values); ASSERT_OK(results[0]); ASSERT_OK(results[1]); ASSERT_OK(results[2]); ASSERT_TRUE(results[3].IsNotFound()); ASSERT_EQ(values[0], "bar"); ASSERT_EQ(values[1], "barbar"); ASSERT_EQ(values[2], "foo"); s = txn->SingleDelete(handles[2], "ZZZ"); ASSERT_OK(s); s = txn->Put(handles[2], "ZZZ", "YYY"); ASSERT_OK(s); s = txn->Put(handles[2], "ZZZ", "YYYY"); ASSERT_OK(s); s = txn->Delete(handles[2], "ZZZ"); ASSERT_OK(s); s = txn->Put(handles[2], "AAAZZZ", "barbarbar"); ASSERT_OK(s); ASSERT_EQ(5, txn->GetNumKeys()); // Txn should commit s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, handles[2], "ZZZ", &value); ASSERT_TRUE(s.IsNotFound()); // Put a key which will conflict with the next txn using the previous snapshot ASSERT_OK(db->Put(write_options, handles[2], "foo", "000")); results = txn2->MultiGetForUpdate(snapshot_read_options, multiget_cfh, multiget_keys, &values); // All results should fail since there was a conflict ASSERT_TRUE(results[0].IsBusy()); ASSERT_TRUE(results[1].IsBusy()); ASSERT_TRUE(results[2].IsBusy()); ASSERT_TRUE(results[3].IsBusy()); s = db->Get(read_options, handles[2], "foo", &value); ASSERT_EQ(value, "000"); s = txn2->Commit(); ASSERT_OK(s); s = db->DropColumnFamily(handles[1]); ASSERT_OK(s); s = db->DropColumnFamily(handles[2]); ASSERT_OK(s); delete txn; delete txn2; for (auto handle : handles) { delete handle; } } TEST_P(TransactionTest, WriteImportedColumnFamilyTest) { WriteOptions write_options; ReadOptions read_options; ColumnFamilyOptions cf_options; ImportColumnFamilyOptions import_options; ExportImportFilesMetaData* metadata_ptr = nullptr; ColumnFamilyHandle* import_cf = nullptr; ColumnFamilyHandle* export_cf = nullptr; std::string export_files_dir = test::PerThreadDBPath(env.get(), "cf_export"); std::string value; Status s; { // Create a column family to export s = db->CreateColumnFamily(cf_options, "CF_EXPORT", &export_cf); ASSERT_OK(s); // Write some data to the db WriteBatch batch; ASSERT_OK(batch.Put(export_cf, "K1", "V1")); ASSERT_OK(batch.Put(export_cf, "K2", "V2")); s = db->Write(write_options, &batch); ASSERT_OK(s); Checkpoint* checkpoint = nullptr; s = Checkpoint::Create(db, &checkpoint); ASSERT_OK(s); s = checkpoint->ExportColumnFamily(export_cf, export_files_dir, &metadata_ptr); ASSERT_OK(s); ASSERT_NE(metadata_ptr, nullptr); delete checkpoint; s = db->DropColumnFamily(export_cf); ASSERT_OK(s); delete export_cf; } { // Create a new column family with import s = db->CreateColumnFamilyWithImport( cf_options, "CF_IMPORT", import_options, *metadata_ptr, &import_cf); ASSERT_OK(s); s = db->Get(read_options, import_cf, "K1", &value); ASSERT_OK(s); ASSERT_EQ(value, "V1"); s = db->Get(read_options, import_cf, "K2", &value); ASSERT_OK(s); ASSERT_EQ(value, "V2"); // Wirte a new key-value pair Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->Put(import_cf, "K3", "V3"); ASSERT_OK(s); s = txn->Commit(); ASSERT_OK(s); delete txn; s = db->Get(read_options, import_cf, "K3", &value); ASSERT_OK(s); ASSERT_EQ(value, "V3"); s = db->DropColumnFamily(import_cf); ASSERT_OK(s); delete import_cf; } delete metadata_ptr; EXPECT_OK(DestroyDir(env.get(), export_files_dir)); } TEST_P(TransactionTest, MultiGetBatchedTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; TransactionOptions txn_options; std::string value; Status s; ColumnFamilyHandle* cf; ColumnFamilyOptions cf_options; // Create a new column families s = db->CreateColumnFamily(cf_options, "CF", &cf); ASSERT_OK(s); delete cf; delete db; db = nullptr; // open DB with three column families std::vector column_families; // have to open default column family column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); // open the new column families cf_options.merge_operator = MergeOperators::CreateStringAppendOperator(); column_families.emplace_back("CF", cf_options); std::vector handles; options.merge_operator = MergeOperators::CreateStringAppendOperator(); ASSERT_OK(ReOpenNoDelete(column_families, &handles)); assert(db != nullptr); // Write some data to the db WriteBatch batch; ASSERT_OK(batch.Put(handles[1], "aaa", "val1")); ASSERT_OK(batch.Put(handles[1], "bbb", "val2")); ASSERT_OK(batch.Put(handles[1], "ccc", "val3")); ASSERT_OK(batch.Put(handles[1], "ddd", "foo")); ASSERT_OK(batch.Put(handles[1], "eee", "val5")); ASSERT_OK(batch.Put(handles[1], "fff", "val6")); ASSERT_OK(batch.Merge(handles[1], "ggg", "foo")); s = db->Write(write_options, &batch); ASSERT_OK(s); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); txn_options.set_snapshot = true; // Write some data to the db s = txn->Delete(handles[1], "bbb"); ASSERT_OK(s); s = txn->Put(handles[1], "ccc", "val3_new"); ASSERT_OK(s); s = txn->Merge(handles[1], "ddd", "bar"); ASSERT_OK(s); std::vector keys = {"aaa", "bbb", "ccc", "ddd", "eee", "fff", "ggg"}; std::vector values(keys.size()); std::vector statuses(keys.size()); txn->MultiGet(snapshot_read_options, handles[1], keys.size(), keys.data(), values.data(), statuses.data()); ASSERT_TRUE(statuses[0].ok()); ASSERT_EQ(values[0], "val1"); ASSERT_TRUE(statuses[1].IsNotFound()); ASSERT_TRUE(statuses[2].ok()); ASSERT_EQ(values[2], "val3_new"); ASSERT_TRUE(statuses[3].ok()); ASSERT_EQ(values[3], "foo,bar"); ASSERT_TRUE(statuses[4].ok()); ASSERT_EQ(values[4], "val5"); ASSERT_TRUE(statuses[5].ok()); ASSERT_EQ(values[5], "val6"); ASSERT_TRUE(statuses[6].ok()); ASSERT_EQ(values[6], "foo"); delete txn; for (auto handle : handles) { delete handle; } } // This test calls WriteBatchWithIndex::MultiGetFromBatchAndDB with a large // number of keys, i.e greater than MultiGetContext::MAX_BATCH_SIZE, which is // is 32. This forces autovector allocations in the MultiGet code paths // to use std::vector in addition to stack allocations. The MultiGet keys // includes Merges, which are handled specially in MultiGetFromBatchAndDB by // allocating an autovector of MergeContexts TEST_P(TransactionTest, MultiGetLargeBatchedTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; ColumnFamilyHandle* cf; ColumnFamilyOptions cf_options; std::vector key_str; for (int i = 0; i < 100; ++i) { key_str.emplace_back(std::to_string(i)); } // Create a new column families s = db->CreateColumnFamily(cf_options, "CF", &cf); ASSERT_OK(s); delete cf; delete db; db = nullptr; // open DB with three column families std::vector column_families; // have to open default column family column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); // open the new column families cf_options.merge_operator = MergeOperators::CreateStringAppendOperator(); column_families.emplace_back("CF", cf_options); std::vector handles; options.merge_operator = MergeOperators::CreateStringAppendOperator(); ASSERT_OK(ReOpenNoDelete(column_families, &handles)); assert(db != nullptr); // Write some data to the db WriteBatch batch; for (int i = 0; i < 3 * MultiGetContext::MAX_BATCH_SIZE; ++i) { std::string val = "val" + std::to_string(i); ASSERT_OK(batch.Put(handles[1], key_str[i], val)); } s = db->Write(write_options, &batch); ASSERT_OK(s); WriteBatchWithIndex wb; // Write some data to the db s = wb.Delete(handles[1], std::to_string(1)); ASSERT_OK(s); s = wb.Put(handles[1], std::to_string(2), "new_val" + std::to_string(2)); ASSERT_OK(s); // Write a lot of merges so when we call MultiGetFromBatchAndDB later on, // it is forced to use std::vector in ROCKSDB_NAMESPACE::autovector to // allocate MergeContexts. The number of merges needs to be > // MultiGetContext::MAX_BATCH_SIZE for (int i = 8; i < MultiGetContext::MAX_BATCH_SIZE + 24; ++i) { s = wb.Merge(handles[1], std::to_string(i), "merge"); ASSERT_OK(s); } // MultiGet a lot of keys in order to force std::vector reallocations std::vector keys; for (int i = 0; i < MultiGetContext::MAX_BATCH_SIZE + 32; ++i) { keys.emplace_back(key_str[i]); } std::vector values(keys.size()); std::vector statuses(keys.size()); wb.MultiGetFromBatchAndDB(db, snapshot_read_options, handles[1], keys.size(), keys.data(), values.data(), statuses.data(), false); for (size_t i = 0; i < keys.size(); ++i) { if (i == 1) { ASSERT_TRUE(statuses[1].IsNotFound()); } else if (i == 2) { ASSERT_TRUE(statuses[2].ok()); ASSERT_EQ(values[2], "new_val" + std::to_string(2)); } else if (i >= 8 && i < 56) { ASSERT_TRUE(statuses[i].ok()); ASSERT_EQ(values[i], "val" + std::to_string(i) + ",merge"); } else { ASSERT_TRUE(statuses[i].ok()); if (values[i] != "val" + std::to_string(i)) { ASSERT_EQ(values[i], "val" + std::to_string(i)); } } } for (auto handle : handles) { delete handle; } } TEST_P(TransactionTest, MultiGetSnapshot) { WriteOptions write_options; TransactionOptions transaction_options; Transaction* txn1 = db->BeginTransaction(write_options, transaction_options); Slice key = "foo"; Status s = txn1->Put(key, "bar"); ASSERT_OK(s); s = txn1->SetName("test"); ASSERT_OK(s); s = txn1->Prepare(); ASSERT_OK(s); // Get snapshot between prepare and commit // Un-committed data should be invisible to other transactions const Snapshot* s1 = db->GetSnapshot(); s = txn1->Commit(); ASSERT_OK(s); delete txn1; Transaction* txn2 = db->BeginTransaction(write_options, transaction_options); ReadOptions read_options; read_options.snapshot = s1; std::vector keys; std::vector values(1); std::vector statuses(1); keys.push_back(key); auto cfd = db->DefaultColumnFamily(); txn2->MultiGet(read_options, cfd, 1, keys.data(), values.data(), statuses.data()); ASSERT_TRUE(statuses[0].IsNotFound()); delete txn2; db->ReleaseSnapshot(s1); } TEST_P(TransactionTest, ColumnFamiliesTest2) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; ColumnFamilyHandle *one, *two; ColumnFamilyOptions cf_options; // Create 2 new column families s = db->CreateColumnFamily(cf_options, "ONE", &one); ASSERT_OK(s); s = db->CreateColumnFamily(cf_options, "TWO", &two); ASSERT_OK(s); Transaction* txn1 = db->BeginTransaction(write_options); ASSERT_TRUE(txn1); Transaction* txn2 = db->BeginTransaction(write_options); ASSERT_TRUE(txn2); s = txn1->Put(one, "X", "1"); ASSERT_OK(s); s = txn1->Put(two, "X", "2"); ASSERT_OK(s); s = txn1->Put("X", "0"); ASSERT_OK(s); s = txn2->Put(one, "X", "11"); ASSERT_TRUE(s.IsTimedOut()); s = txn1->Commit(); ASSERT_OK(s); // Drop first column family s = db->DropColumnFamily(one); ASSERT_OK(s); // Should fail since column family was dropped. s = txn2->Commit(); ASSERT_OK(s); delete txn1; txn1 = db->BeginTransaction(write_options); ASSERT_TRUE(txn1); // Should fail since column family was dropped s = txn1->Put(one, "X", "111"); ASSERT_TRUE(s.IsInvalidArgument()); s = txn1->Put(two, "X", "222"); ASSERT_OK(s); s = txn1->Put("X", "000"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = db->Get(read_options, two, "X", &value); ASSERT_OK(s); ASSERT_EQ("222", value); s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("000", value); s = db->DropColumnFamily(two); ASSERT_OK(s); delete txn1; delete txn2; delete one; delete two; } TEST_P(TransactionTest, EmptyTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; s = db->Put(write_options, "aaa", "aaa"); ASSERT_OK(s); Transaction* txn = db->BeginTransaction(write_options); s = txn->Commit(); ASSERT_OK(s); delete txn; txn = db->BeginTransaction(write_options); ASSERT_OK(txn->Rollback()); delete txn; txn = db->BeginTransaction(write_options); s = txn->GetForUpdate(read_options, "aaa", &value); ASSERT_EQ(value, "aaa"); s = txn->Commit(); ASSERT_OK(s); delete txn; txn = db->BeginTransaction(write_options); txn->SetSnapshot(); s = txn->GetForUpdate(read_options, "aaa", &value); ASSERT_EQ(value, "aaa"); // Conflicts with previous GetForUpdate s = db->Put(write_options, "aaa", "xxx"); ASSERT_TRUE(s.IsTimedOut()); // transaction expired! s = txn->Commit(); ASSERT_OK(s); delete txn; } TEST_P(TransactionTest, PredicateManyPreceders) { WriteOptions write_options; ReadOptions read_options1, read_options2; TransactionOptions txn_options; std::string value; Status s; txn_options.set_snapshot = true; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); read_options1.snapshot = txn1->GetSnapshot(); Transaction* txn2 = db->BeginTransaction(write_options); txn2->SetSnapshot(); read_options2.snapshot = txn2->GetSnapshot(); std::vector multiget_keys = {"1", "2", "3"}; std::vector multiget_values; std::vector results = txn1->MultiGetForUpdate(read_options1, multiget_keys, &multiget_values); ASSERT_EQ(results.size(), 3); ASSERT_TRUE(results[0].IsNotFound()); ASSERT_TRUE(results[1].IsNotFound()); ASSERT_TRUE(results[2].IsNotFound()); s = txn2->Put("2", "x"); // Conflict's with txn1's MultiGetForUpdate ASSERT_TRUE(s.IsTimedOut()); ASSERT_OK(txn2->Rollback()); multiget_values.clear(); results = txn1->MultiGetForUpdate(read_options1, multiget_keys, &multiget_values); ASSERT_EQ(results.size(), 3); ASSERT_TRUE(results[0].IsNotFound()); ASSERT_TRUE(results[1].IsNotFound()); ASSERT_TRUE(results[2].IsNotFound()); s = txn1->Commit(); ASSERT_OK(s); delete txn1; delete txn2; txn1 = db->BeginTransaction(write_options, txn_options); read_options1.snapshot = txn1->GetSnapshot(); txn2 = db->BeginTransaction(write_options, txn_options); read_options2.snapshot = txn2->GetSnapshot(); s = txn1->Put("4", "x"); ASSERT_OK(s); s = txn2->Delete("4"); // conflict ASSERT_TRUE(s.IsTimedOut()); s = txn1->Commit(); ASSERT_OK(s); s = txn2->GetForUpdate(read_options2, "4", &value); ASSERT_TRUE(s.IsBusy()); ASSERT_OK(txn2->Rollback()); delete txn1; delete txn2; } TEST_P(TransactionTest, LostUpdate) { WriteOptions write_options; ReadOptions read_options, read_options1, read_options2; TransactionOptions txn_options; std::string value; Status s; // Test 2 transactions writing to the same key in multiple orders and // with/without snapshots Transaction* txn1 = db->BeginTransaction(write_options); Transaction* txn2 = db->BeginTransaction(write_options); s = txn1->Put("1", "1"); ASSERT_OK(s); s = txn2->Put("1", "2"); // conflict ASSERT_TRUE(s.IsTimedOut()); s = txn2->Commit(); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = db->Get(read_options, "1", &value); ASSERT_OK(s); ASSERT_EQ("1", value); delete txn1; delete txn2; txn_options.set_snapshot = true; txn1 = db->BeginTransaction(write_options, txn_options); read_options1.snapshot = txn1->GetSnapshot(); txn2 = db->BeginTransaction(write_options, txn_options); read_options2.snapshot = txn2->GetSnapshot(); s = txn1->Put("1", "3"); ASSERT_OK(s); s = txn2->Put("1", "4"); // conflict ASSERT_TRUE(s.IsTimedOut()); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "1", &value); ASSERT_OK(s); ASSERT_EQ("3", value); delete txn1; delete txn2; txn1 = db->BeginTransaction(write_options, txn_options); read_options1.snapshot = txn1->GetSnapshot(); txn2 = db->BeginTransaction(write_options, txn_options); read_options2.snapshot = txn2->GetSnapshot(); s = txn1->Put("1", "5"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Put("1", "6"); ASSERT_TRUE(s.IsBusy()); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "1", &value); ASSERT_OK(s); ASSERT_EQ("5", value); delete txn1; delete txn2; txn1 = db->BeginTransaction(write_options, txn_options); read_options1.snapshot = txn1->GetSnapshot(); txn2 = db->BeginTransaction(write_options, txn_options); read_options2.snapshot = txn2->GetSnapshot(); s = txn1->Put("1", "7"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); txn2->SetSnapshot(); s = txn2->Put("1", "8"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "1", &value); ASSERT_OK(s); ASSERT_EQ("8", value); delete txn1; delete txn2; txn1 = db->BeginTransaction(write_options); txn2 = db->BeginTransaction(write_options); s = txn1->Put("1", "9"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Put("1", "10"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn1; delete txn2; s = db->Get(read_options, "1", &value); ASSERT_OK(s); ASSERT_EQ(value, "10"); } TEST_P(TransactionTest, UntrackedWrites) { if (txn_db_options.write_policy == WRITE_UNPREPARED) { // TODO(lth): For WriteUnprepared, validate that untracked writes are // not supported. return; } WriteOptions write_options; ReadOptions read_options; std::string value; Status s; // Verify transaction rollback works for untracked keys. Transaction* txn = db->BeginTransaction(write_options); txn->SetSnapshot(); s = txn->PutUntracked("untracked", "0"); ASSERT_OK(s); ASSERT_OK(txn->Rollback()); s = db->Get(read_options, "untracked", &value); ASSERT_TRUE(s.IsNotFound()); delete txn; txn = db->BeginTransaction(write_options); txn->SetSnapshot(); s = db->Put(write_options, "untracked", "x"); ASSERT_OK(s); // Untracked writes should succeed even though key was written after snapshot s = txn->PutUntracked("untracked", "1"); ASSERT_OK(s); s = txn->MergeUntracked("untracked", "2"); ASSERT_OK(s); s = txn->DeleteUntracked("untracked"); ASSERT_OK(s); // Conflict s = txn->Put("untracked", "3"); ASSERT_TRUE(s.IsBusy()); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "untracked", &value); ASSERT_TRUE(s.IsNotFound()); delete txn; } TEST_P(TransactionTest, ExpiredTransaction) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; // Set txn expiration timeout to 0 microseconds (expires instantly) txn_options.expiration = 0; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); s = txn1->Put("X", "1"); ASSERT_OK(s); s = txn1->Put("Y", "1"); ASSERT_OK(s); Transaction* txn2 = db->BeginTransaction(write_options); // txn2 should be able to write to X since txn1 has expired s = txn2->Put("X", "2"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("2", value); s = txn1->Put("Z", "1"); ASSERT_OK(s); // txn1 should fail to commit since it is expired s = txn1->Commit(); ASSERT_TRUE(s.IsExpired()); s = db->Get(read_options, "Y", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, "Z", &value); ASSERT_TRUE(s.IsNotFound()); delete txn1; delete txn2; } TEST_P(TransactionTest, ReinitializeTest) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; // Set txn expiration timeout to 0 microseconds (expires instantly) txn_options.expiration = 0; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); // Reinitialize transaction to no long expire txn_options.expiration = -1; txn1 = db->BeginTransaction(write_options, txn_options, txn1); s = txn1->Put("Z", "z"); ASSERT_OK(s); // Should commit since not expired s = txn1->Commit(); ASSERT_OK(s); txn1 = db->BeginTransaction(write_options, txn_options, txn1); s = txn1->Put("Z", "zz"); ASSERT_OK(s); // Reinitilize txn1 and verify that Z gets unlocked txn1 = db->BeginTransaction(write_options, txn_options, txn1); Transaction* txn2 = db->BeginTransaction(write_options, txn_options, nullptr); s = txn2->Put("Z", "zzz"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = db->Get(read_options, "Z", &value); ASSERT_OK(s); ASSERT_EQ(value, "zzz"); // Verify snapshots get reinitialized correctly txn1->SetSnapshot(); s = txn1->Put("Z", "zzzz"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = db->Get(read_options, "Z", &value); ASSERT_OK(s); ASSERT_EQ(value, "zzzz"); txn1 = db->BeginTransaction(write_options, txn_options, txn1); const Snapshot* snapshot = txn1->GetSnapshot(); ASSERT_FALSE(snapshot); txn_options.set_snapshot = true; txn1 = db->BeginTransaction(write_options, txn_options, txn1); snapshot = txn1->GetSnapshot(); ASSERT_TRUE(snapshot); s = txn1->Put("Z", "a"); ASSERT_OK(s); ASSERT_OK(txn1->Rollback()); s = txn1->Put("Y", "y"); ASSERT_OK(s); txn_options.set_snapshot = false; txn1 = db->BeginTransaction(write_options, txn_options, txn1); snapshot = txn1->GetSnapshot(); ASSERT_FALSE(snapshot); s = txn1->Put("X", "x"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = db->Get(read_options, "Z", &value); ASSERT_OK(s); ASSERT_EQ(value, "zzzz"); s = db->Get(read_options, "Y", &value); ASSERT_TRUE(s.IsNotFound()); txn1 = db->BeginTransaction(write_options, txn_options, txn1); s = txn1->SetName("name"); ASSERT_OK(s); s = txn1->Prepare(); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); txn1 = db->BeginTransaction(write_options, txn_options, txn1); s = txn1->SetName("name"); ASSERT_OK(s); delete txn1; } TEST_P(TransactionTest, Rollback) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(s); s = txn1->Put("X", "1"); ASSERT_OK(s); Transaction* txn2 = db->BeginTransaction(write_options); // txn2 should not be able to write to X since txn1 has it locked s = txn2->Put("X", "2"); ASSERT_TRUE(s.IsTimedOut()); ASSERT_OK(txn1->Rollback()); delete txn1; // txn2 should now be able to write to X s = txn2->Put("X", "3"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("3", value); delete txn2; } TEST_P(TransactionTest, LockLimitTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; TransactionOptions txn_options; std::string value; Status s; delete db; db = nullptr; // Open DB with a lock limit of 3 txn_db_options.max_num_locks = 3; ASSERT_OK(ReOpen()); assert(db != nullptr); ASSERT_OK(s); // Create a txn and verify we can only lock up to 3 keys Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn); s = txn->Put("X", "x"); ASSERT_OK(s); s = txn->Put("Y", "y"); ASSERT_OK(s); s = txn->Put("Z", "z"); ASSERT_OK(s); // lock limit reached s = txn->Put("W", "w"); ASSERT_TRUE(s.IsBusy()); // re-locking same key shouldn't put us over the limit s = txn->Put("X", "xx"); ASSERT_OK(s); s = txn->GetForUpdate(read_options, "W", &value); ASSERT_TRUE(s.IsBusy()); s = txn->GetForUpdate(read_options, "V", &value); ASSERT_TRUE(s.IsBusy()); // re-locking same key shouldn't put us over the limit s = txn->GetForUpdate(read_options, "Y", &value); ASSERT_OK(s); ASSERT_EQ("y", value); s = txn->Get(read_options, "W", &value); ASSERT_TRUE(s.IsNotFound()); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); // "X" currently locked s = txn2->Put("X", "x"); ASSERT_TRUE(s.IsTimedOut()); // lock limit reached s = txn2->Put("M", "m"); ASSERT_TRUE(s.IsBusy()); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("xx", value); s = db->Get(read_options, "W", &value); ASSERT_TRUE(s.IsNotFound()); // Committing txn should release its locks and allow txn2 to proceed s = txn2->Put("X", "x2"); ASSERT_OK(s); s = txn2->Delete("X"); ASSERT_OK(s); s = txn2->Put("M", "m"); ASSERT_OK(s); s = txn2->Put("Z", "z2"); ASSERT_OK(s); // lock limit reached s = txn2->Delete("Y"); ASSERT_TRUE(s.IsBusy()); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "Z", &value); ASSERT_OK(s); ASSERT_EQ("z2", value); s = db->Get(read_options, "Y", &value); ASSERT_OK(s); ASSERT_EQ("y", value); s = db->Get(read_options, "X", &value); ASSERT_TRUE(s.IsNotFound()); delete txn; delete txn2; } TEST_P(TransactionTest, IteratorTest) { // This test does writes without snapshot validation, and then tries to create // iterator later, which is unsupported in write unprepared. if (txn_db_options.write_policy == WRITE_UNPREPARED) { return; } WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; // Write some keys to the db s = db->Put(write_options, "A", "a"); ASSERT_OK(s); s = db->Put(write_options, "G", "g"); ASSERT_OK(s); s = db->Put(write_options, "F", "f"); ASSERT_OK(s); s = db->Put(write_options, "C", "c"); ASSERT_OK(s); s = db->Put(write_options, "D", "d"); ASSERT_OK(s); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); // Write some keys in a txn s = txn->Put("B", "b"); ASSERT_OK(s); s = txn->Put("H", "h"); ASSERT_OK(s); s = txn->Delete("D"); ASSERT_OK(s); s = txn->Put("E", "e"); ASSERT_OK(s); txn->SetSnapshot(); const Snapshot* snapshot = txn->GetSnapshot(); // Write some keys to the db after the snapshot s = db->Put(write_options, "BB", "xx"); ASSERT_OK(s); s = db->Put(write_options, "C", "xx"); ASSERT_OK(s); read_options.snapshot = snapshot; Iterator* iter = txn->GetIterator(read_options); ASSERT_OK(iter->status()); iter->SeekToFirst(); // Read all keys via iter and lock them all std::string results[] = {"a", "b", "c", "e", "f", "g", "h"}; for (int i = 0; i < 7; i++) { ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ(results[i], iter->value().ToString()); s = txn->GetForUpdate(read_options, iter->key(), (std::string*)nullptr); if (i == 2) { // "C" was modified after txn's snapshot ASSERT_TRUE(s.IsBusy()); } else { ASSERT_OK(s); } iter->Next(); } ASSERT_FALSE(iter->Valid()); iter->Seek("G"); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("g", iter->value().ToString()); iter->Prev(); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("f", iter->value().ToString()); iter->Seek("D"); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("e", iter->value().ToString()); iter->Seek("C"); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("c", iter->value().ToString()); iter->Next(); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("e", iter->value().ToString()); iter->Seek(""); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("a", iter->value().ToString()); iter->Seek("X"); ASSERT_OK(iter->status()); ASSERT_FALSE(iter->Valid()); iter->SeekToLast(); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("h", iter->value().ToString()); s = txn->Commit(); ASSERT_OK(s); delete iter; delete txn; } TEST_P(TransactionTest, DisableIndexingTest) { // Skip this test for write unprepared. It does not solely rely on WBWI for // read your own writes, so depending on whether batches are flushed or not, // only some writes will be visible. // // Also, write unprepared does not support creating iterators if there has // been txn->Put() without snapshot validation. if (txn_db_options.write_policy == WRITE_UNPREPARED) { return; } WriteOptions write_options; ReadOptions read_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); txn->DisableIndexing(); s = txn->Put("B", "b"); ASSERT_OK(s); s = txn->Get(read_options, "B", &value); ASSERT_TRUE(s.IsNotFound()); Iterator* iter = txn->GetIterator(read_options); ASSERT_OK(iter->status()); iter->Seek("B"); ASSERT_OK(iter->status()); ASSERT_FALSE(iter->Valid()); s = txn->Delete("A"); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); txn->EnableIndexing(); s = txn->Put("B", "bb"); ASSERT_OK(s); iter->Seek("B"); ASSERT_OK(iter->status()); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("bb", iter->value().ToString()); s = txn->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("bb", value); s = txn->Put("A", "aa"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("aa", value); delete iter; delete txn; } TEST_P(TransactionTest, SavepointTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); ASSERT_EQ(0, txn->GetNumPuts()); s = txn->RollbackToSavePoint(); ASSERT_TRUE(s.IsNotFound()); txn->SetSavePoint(); // 1 ASSERT_OK(txn->RollbackToSavePoint()); // Rollback to beginning of txn s = txn->RollbackToSavePoint(); ASSERT_TRUE(s.IsNotFound()); s = txn->Put("B", "b"); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("b", value); delete txn; txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Put("B", "bb"); ASSERT_OK(s); s = txn->Put("C", "c"); ASSERT_OK(s); txn->SetSavePoint(); // 2 s = txn->Delete("B"); ASSERT_OK(s); s = txn->Put("C", "cc"); ASSERT_OK(s); s = txn->Put("D", "d"); ASSERT_OK(s); ASSERT_EQ(5, txn->GetNumPuts()); ASSERT_EQ(1, txn->GetNumDeletes()); ASSERT_OK(txn->RollbackToSavePoint()); // Rollback to 2 ASSERT_EQ(3, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); s = txn->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("bb", value); s = txn->Get(read_options, "C", &value); ASSERT_OK(s); ASSERT_EQ("c", value); s = txn->Get(read_options, "D", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Put("E", "e"); ASSERT_OK(s); ASSERT_EQ(5, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); // Rollback to beginning of txn s = txn->RollbackToSavePoint(); ASSERT_TRUE(s.IsNotFound()); ASSERT_OK(txn->Rollback()); ASSERT_EQ(0, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); s = txn->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("b", value); s = txn->Get(read_options, "D", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Get(read_options, "D", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Get(read_options, "E", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Put("A", "aa"); ASSERT_OK(s); s = txn->Put("F", "f"); ASSERT_OK(s); ASSERT_EQ(2, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); txn->SetSavePoint(); // 3 txn->SetSavePoint(); // 4 s = txn->Put("G", "g"); ASSERT_OK(s); s = txn->SingleDelete("F"); ASSERT_OK(s); s = txn->Delete("B"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("aa", value); s = txn->Get(read_options, "F", &value); // According to db.h, doing a SingleDelete on a key that has been // overwritten will have undefinied behavior. So it is unclear what the // result of fetching "F" should be. The current implementation will // return NotFound in this case. ASSERT_TRUE(s.IsNotFound()); s = txn->Get(read_options, "B", &value); ASSERT_TRUE(s.IsNotFound()); ASSERT_EQ(3, txn->GetNumPuts()); ASSERT_EQ(2, txn->GetNumDeletes()); ASSERT_OK(txn->RollbackToSavePoint()); // Rollback to 3 ASSERT_EQ(2, txn->GetNumPuts()); ASSERT_EQ(0, txn->GetNumDeletes()); s = txn->Get(read_options, "F", &value); ASSERT_OK(s); ASSERT_EQ("f", value); s = txn->Get(read_options, "G", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Commit(); ASSERT_OK(s); s = db->Get(read_options, "F", &value); ASSERT_OK(s); ASSERT_EQ("f", value); s = db->Get(read_options, "G", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("aa", value); s = db->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("b", value); s = db->Get(read_options, "C", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, "D", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, "E", &value); ASSERT_TRUE(s.IsNotFound()); delete txn; } TEST_P(TransactionTest, SavepointTest2) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; Status s; txn_options.lock_timeout = 1; // 1 ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); s = txn1->Put("A", ""); ASSERT_OK(s); txn1->SetSavePoint(); // 1 s = txn1->Put("A", "a"); ASSERT_OK(s); s = txn1->Put("C", "c"); ASSERT_OK(s); txn1->SetSavePoint(); // 2 s = txn1->Put("A", "a"); ASSERT_OK(s); s = txn1->Put("B", "b"); ASSERT_OK(s); ASSERT_OK(txn1->RollbackToSavePoint()); // Rollback to 2 // Verify that "A" and "C" is still locked while "B" is not Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); s = txn2->Put("A", "a2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b2"); ASSERT_OK(s); s = txn1->Put("A", "aa"); ASSERT_OK(s); s = txn1->Put("B", "bb"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = txn1->Put("A", "aaa"); ASSERT_OK(s); s = txn1->Put("B", "bbb"); ASSERT_OK(s); s = txn1->Put("C", "ccc"); ASSERT_OK(s); txn1->SetSavePoint(); // 3 ASSERT_OK(txn1->RollbackToSavePoint()); // Rollback to 3 // Verify that "A", "B", "C" are still locked txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); s = txn2->Put("A", "a2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c2"); ASSERT_TRUE(s.IsTimedOut()); ASSERT_OK(txn1->RollbackToSavePoint()); // Rollback to 1 // Verify that only "A" is locked s = txn2->Put("A", "a3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b3"); ASSERT_OK(s); s = txn2->Put("C", "c3po"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); delete txn1; // Verify "A" "C" "B" are no longer locked s = txn2->Put("A", "a4"); ASSERT_OK(s); s = txn2->Put("B", "b4"); ASSERT_OK(s); s = txn2->Put("C", "c4"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn2; } TEST_P(TransactionTest, SavepointTest3) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; Status s; txn_options.lock_timeout = 1; // 1 ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); s = txn1->PopSavePoint(); // No SavePoint present ASSERT_TRUE(s.IsNotFound()); s = txn1->Put("A", ""); ASSERT_OK(s); s = txn1->PopSavePoint(); // Still no SavePoint present ASSERT_TRUE(s.IsNotFound()); txn1->SetSavePoint(); // 1 s = txn1->Put("A", "a"); ASSERT_OK(s); s = txn1->PopSavePoint(); // Remove 1 ASSERT_TRUE(txn1->RollbackToSavePoint().IsNotFound()); // Verify that "A" is still locked Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); s = txn2->Put("A", "a2"); ASSERT_TRUE(s.IsTimedOut()); delete txn2; txn1->SetSavePoint(); // 2 s = txn1->Put("B", "b"); ASSERT_OK(s); txn1->SetSavePoint(); // 3 s = txn1->Put("B", "b2"); ASSERT_OK(s); ASSERT_OK(txn1->RollbackToSavePoint()); // Roll back to 2 s = txn1->PopSavePoint(); ASSERT_OK(s); s = txn1->PopSavePoint(); ASSERT_TRUE(s.IsNotFound()); s = txn1->Commit(); ASSERT_OK(s); delete txn1; std::string value; // tnx1 should have modified "A" to "a" s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); // tnx1 should have set "B" to just "b" s = db->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("b", value); s = db->Get(read_options, "C", &value); ASSERT_TRUE(s.IsNotFound()); } TEST_P(TransactionTest, SavepointTest4) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; Status s; txn_options.lock_timeout = 1; // 1 ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); txn1->SetSavePoint(); // 1 s = txn1->Put("A", "a"); ASSERT_OK(s); txn1->SetSavePoint(); // 2 s = txn1->Put("B", "b"); ASSERT_OK(s); s = txn1->PopSavePoint(); // Remove 2 ASSERT_OK(s); // Verify that A/B still exists. std::string value; ASSERT_OK(txn1->Get(read_options, "A", &value)); ASSERT_EQ("a", value); ASSERT_OK(txn1->Get(read_options, "B", &value)); ASSERT_EQ("b", value); ASSERT_OK(txn1->RollbackToSavePoint()); // Rollback to 1 // Verify that everything was rolled back. s = txn1->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->Get(read_options, "B", &value); ASSERT_TRUE(s.IsNotFound()); // Nothing should be locked Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); s = txn2->Put("A", ""); ASSERT_OK(s); s = txn2->Put("B", ""); ASSERT_OK(s); delete txn2; delete txn1; } TEST_P(TransactionTest, UndoGetForUpdateTest) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; txn_options.lock_timeout = 1; // 1 ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); txn1->UndoGetForUpdate("A"); s = txn1->Commit(); ASSERT_OK(s); delete txn1; txn1 = db->BeginTransaction(write_options, txn_options); txn1->UndoGetForUpdate("A"); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); // Verify that A is locked Transaction* txn2 = db->BeginTransaction(write_options, txn_options); s = txn2->Put("A", "a"); ASSERT_TRUE(s.IsTimedOut()); txn1->UndoGetForUpdate("A"); // Verify that A is now unlocked s = txn2->Put("A", "a2"); ASSERT_OK(s); ASSERT_OK(txn2->Commit()); delete txn2; s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a2", value); s = txn1->Delete("A"); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->Put("B", "b3"); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "B", &value); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); // Verify that A and B are still locked txn2 = db->BeginTransaction(write_options, txn_options); s = txn2->Put("A", "a4"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b4"); ASSERT_TRUE(s.IsTimedOut()); ASSERT_OK(txn1->Rollback()); delete txn1; // Verify that A and B are no longer locked s = txn2->Put("A", "a5"); ASSERT_OK(s); s = txn2->Put("B", "b5"); ASSERT_OK(s); s = txn2->Commit(); delete txn2; ASSERT_OK(s); txn1 = db->BeginTransaction(write_options, txn_options); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "C", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "C", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->GetForUpdate(read_options, "B", &value); ASSERT_OK(s); s = txn1->Put("B", "b5"); s = txn1->GetForUpdate(read_options, "B", &value); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("X"); // Verify A,B,C are locked txn2 = db->BeginTransaction(write_options, txn_options); s = txn2->Put("A", "a6"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Delete("B"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c6"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("X", "x6"); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("X"); // Verify A,B are locked and C is not s = txn2->Put("A", "a6"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Delete("B"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c6"); ASSERT_OK(s); s = txn2->Put("X", "x6"); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("X"); // Verify B is locked and A and C are not s = txn2->Put("A", "a7"); ASSERT_OK(s); s = txn2->Delete("B"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c7"); ASSERT_OK(s); s = txn2->Put("X", "x7"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = txn1->Commit(); ASSERT_OK(s); delete txn1; } TEST_P(TransactionTest, UndoGetForUpdateTest2) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; std::string value; Status s; s = db->Put(write_options, "A", ""); ASSERT_OK(s); txn_options.lock_timeout = 1; // 1 ms Transaction* txn1 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn1); s = txn1->GetForUpdate(read_options, "A", &value); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "B", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->Put("F", "f"); ASSERT_OK(s); txn1->SetSavePoint(); // 1 txn1->UndoGetForUpdate("A"); s = txn1->GetForUpdate(read_options, "C", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->GetForUpdate(read_options, "D", &value); ASSERT_TRUE(s.IsNotFound()); s = txn1->Put("E", "e"); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "E", &value); ASSERT_OK(s); s = txn1->GetForUpdate(read_options, "F", &value); ASSERT_OK(s); // Verify A,B,C,D,E,F are still locked Transaction* txn2 = db->BeginTransaction(write_options, txn_options); s = txn2->Put("A", "a1"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b1"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c1"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("D", "d1"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("E", "e1"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f1"); ASSERT_TRUE(s.IsTimedOut()); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("E"); // Verify A,B,D,E,F are still locked and C is not. s = txn2->Put("A", "a2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("D", "d2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("E", "e2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c2"); ASSERT_OK(s); txn1->SetSavePoint(); // 2 s = txn1->Put("H", "h"); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("D"); txn1->UndoGetForUpdate("E"); txn1->UndoGetForUpdate("F"); txn1->UndoGetForUpdate("G"); txn1->UndoGetForUpdate("H"); // Verify A,B,D,E,F,H are still locked and C,G are not. s = txn2->Put("A", "a3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("D", "d3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("E", "e3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("H", "h3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c3"); ASSERT_OK(s); s = txn2->Put("G", "g3"); ASSERT_OK(s); ASSERT_OK(txn1->RollbackToSavePoint()); // rollback to 2 // Verify A,B,D,E,F are still locked and C,G,H are not. s = txn2->Put("A", "a3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("D", "d3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("E", "e3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c3"); ASSERT_OK(s); s = txn2->Put("G", "g3"); ASSERT_OK(s); s = txn2->Put("H", "h3"); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("D"); txn1->UndoGetForUpdate("E"); txn1->UndoGetForUpdate("F"); txn1->UndoGetForUpdate("G"); txn1->UndoGetForUpdate("H"); // Verify A,B,E,F are still locked and C,D,G,H are not. s = txn2->Put("A", "a3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("E", "e3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c3"); ASSERT_OK(s); s = txn2->Put("D", "d3"); ASSERT_OK(s); s = txn2->Put("G", "g3"); ASSERT_OK(s); s = txn2->Put("H", "h3"); ASSERT_OK(s); ASSERT_OK(txn1->RollbackToSavePoint()); // rollback to 1 // Verify A,B,F are still locked and C,D,E,G,H are not. s = txn2->Put("A", "a3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("B", "b3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("F", "f3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("C", "c3"); ASSERT_OK(s); s = txn2->Put("D", "d3"); ASSERT_OK(s); s = txn2->Put("E", "e3"); ASSERT_OK(s); s = txn2->Put("G", "g3"); ASSERT_OK(s); s = txn2->Put("H", "h3"); ASSERT_OK(s); txn1->UndoGetForUpdate("A"); txn1->UndoGetForUpdate("B"); txn1->UndoGetForUpdate("C"); txn1->UndoGetForUpdate("D"); txn1->UndoGetForUpdate("E"); txn1->UndoGetForUpdate("F"); txn1->UndoGetForUpdate("G"); txn1->UndoGetForUpdate("H"); // Verify F is still locked and A,B,C,D,E,G,H are not. s = txn2->Put("F", "f3"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Put("A", "a3"); ASSERT_OK(s); s = txn2->Put("B", "b3"); ASSERT_OK(s); s = txn2->Put("C", "c3"); ASSERT_OK(s); s = txn2->Put("D", "d3"); ASSERT_OK(s); s = txn2->Put("E", "e3"); ASSERT_OK(s); s = txn2->Put("G", "g3"); ASSERT_OK(s); s = txn2->Put("H", "h3"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn1; delete txn2; } TEST_P(TransactionTest, TimeoutTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; delete db; db = nullptr; // transaction writes have an infinite timeout, // but we will override this when we start a txn // db writes have infinite timeout txn_db_options.transaction_lock_timeout = -1; txn_db_options.default_lock_timeout = -1; s = TransactionDB::Open(options, txn_db_options, dbname, &db); assert(db != nullptr); ASSERT_OK(s); s = db->Put(write_options, "aaa", "aaa"); ASSERT_OK(s); TransactionOptions txn_options0; txn_options0.expiration = 100; // 100ms txn_options0.lock_timeout = 50; // txn timeout no longer infinite Transaction* txn1 = db->BeginTransaction(write_options, txn_options0); s = txn1->GetForUpdate(read_options, "aaa", (std::string*)nullptr); ASSERT_OK(s); // Conflicts with previous GetForUpdate. // Since db writes do not have a timeout, this should eventually succeed when // the transaction expires. s = db->Put(write_options, "aaa", "xxx"); ASSERT_OK(s); ASSERT_GE(txn1->GetElapsedTime(), static_cast(txn_options0.expiration)); s = txn1->Commit(); ASSERT_TRUE(s.IsExpired()); // expired! s = db->Get(read_options, "aaa", &value); ASSERT_OK(s); ASSERT_EQ("xxx", value); delete txn1; delete db; // transaction writes have 10ms timeout, // db writes have infinite timeout txn_db_options.transaction_lock_timeout = 50; txn_db_options.default_lock_timeout = -1; s = TransactionDB::Open(options, txn_db_options, dbname, &db); ASSERT_OK(s); s = db->Put(write_options, "aaa", "aaa"); ASSERT_OK(s); TransactionOptions txn_options; txn_options.expiration = 100; // 100ms txn1 = db->BeginTransaction(write_options, txn_options); s = txn1->GetForUpdate(read_options, "aaa", (std::string*)nullptr); ASSERT_OK(s); // Conflicts with previous GetForUpdate. // Since db writes do not have a timeout, this should eventually succeed when // the transaction expires. s = db->Put(write_options, "aaa", "xxx"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_NOK(s); // expired! s = db->Get(read_options, "aaa", &value); ASSERT_OK(s); ASSERT_EQ("xxx", value); delete txn1; txn_options.expiration = 6000000; // 100 minutes txn_options.lock_timeout = 1; // 1ms txn1 = db->BeginTransaction(write_options, txn_options); txn1->SetLockTimeout(100); TransactionOptions txn_options2; txn_options2.expiration = 10; // 10ms Transaction* txn2 = db->BeginTransaction(write_options, txn_options2); ASSERT_OK(s); s = txn2->Put("a", "2"); ASSERT_OK(s); // txn1 has a lock timeout longer than txn2's expiration, so it will win s = txn1->Delete("a"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); // txn2 should be expired out since txn1 waiting until its timeout expired. s = txn2->Commit(); ASSERT_TRUE(s.IsExpired()); delete txn1; delete txn2; txn_options.expiration = 6000000; // 100 minutes txn1 = db->BeginTransaction(write_options, txn_options); txn_options2.expiration = 100000000; txn2 = db->BeginTransaction(write_options, txn_options2); s = txn1->Delete("asdf"); ASSERT_OK(s); // txn2 has a smaller lock timeout than txn1's expiration, so it will time out s = txn2->Delete("asdf"); ASSERT_TRUE(s.IsTimedOut()); ASSERT_EQ(s.ToString(), "Operation timed out: Timeout waiting to lock key"); s = txn1->Commit(); ASSERT_OK(s); s = txn2->Put("asdf", "asdf"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); s = db->Get(read_options, "asdf", &value); ASSERT_OK(s); ASSERT_EQ("asdf", value); delete txn1; delete txn2; } TEST_P(TransactionTest, SingleDeleteTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = txn->SingleDelete("A"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Commit(); ASSERT_OK(s); delete txn; txn = db->BeginTransaction(write_options); s = txn->SingleDelete("A"); ASSERT_OK(s); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); s = txn->Commit(); ASSERT_OK(s); delete txn; s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); txn = db->BeginTransaction(write_options); s = txn->SingleDelete("A"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn->Commit(); ASSERT_OK(s); delete txn; s = db->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); txn = db->BeginTransaction(write_options); Transaction* txn2 = db->BeginTransaction(write_options); txn2->SetSnapshot(); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Put("A", "a2"); ASSERT_OK(s); s = txn->SingleDelete("A"); ASSERT_OK(s); s = txn->SingleDelete("B"); ASSERT_OK(s); // According to db.h, doing a SingleDelete on a key that has been // overwritten will have undefinied behavior. So it is unclear what the // result of fetching "A" should be. The current implementation will // return NotFound in this case. s = txn->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = txn2->Put("B", "b"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = txn->Commit(); ASSERT_OK(s); delete txn; // According to db.h, doing a SingleDelete on a key that has been // overwritten will have undefinied behavior. So it is unclear what the // result of fetching "A" should be. The current implementation will // return NotFound in this case. s = db->Get(read_options, "A", &value); ASSERT_TRUE(s.IsNotFound()); s = db->Get(read_options, "B", &value); ASSERT_TRUE(s.IsNotFound()); } TEST_P(TransactionTest, MergeTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; Transaction* txn = db->BeginTransaction(write_options, TransactionOptions()); ASSERT_TRUE(txn); s = db->Put(write_options, "A", "a0"); ASSERT_OK(s); s = txn->Merge("A", "1"); ASSERT_OK(s); s = txn->Merge("A", "2"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a0,1,2", value); s = txn->Put("A", "a"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a", value); s = txn->Merge("A", "3"); ASSERT_OK(s); s = txn->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a,3", value); TransactionOptions txn_options; txn_options.lock_timeout = 1; // 1 ms Transaction* txn2 = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn2); // verify that txn has "A" locked s = txn2->Merge("A", "4"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = txn->Commit(); ASSERT_OK(s); delete txn; s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a,3", value); } TEST_P(TransactionTest, DeleteRangeSupportTest) { // The `DeleteRange()` API is banned everywhere. ASSERT_TRUE( db->DeleteRange(WriteOptions(), db->DefaultColumnFamily(), "a", "b") .IsNotSupported()); // But range deletions can be added via the `Write()` API by specifying the // proper flags to promise there are no conflicts according to the DB type // (see `TransactionDB::DeleteRange()` API doc for details). for (bool skip_concurrency_control : {false, true}) { for (bool skip_duplicate_key_check : {false, true}) { ASSERT_OK(db->Put(WriteOptions(), "a", "val")); WriteBatch wb; ASSERT_OK(wb.DeleteRange("a", "b")); TransactionDBWriteOptimizations flags; flags.skip_concurrency_control = skip_concurrency_control; flags.skip_duplicate_key_check = skip_duplicate_key_check; Status s = db->Write(WriteOptions(), flags, &wb); std::string value; switch (txn_db_options.write_policy) { case WRITE_COMMITTED: if (skip_concurrency_control) { ASSERT_OK(s); ASSERT_TRUE(db->Get(ReadOptions(), "a", &value).IsNotFound()); } else { ASSERT_NOK(s); ASSERT_OK(db->Get(ReadOptions(), "a", &value)); } break; case WRITE_PREPARED: FALLTHROUGH_INTENDED; case WRITE_UNPREPARED: if (skip_concurrency_control && skip_duplicate_key_check) { ASSERT_OK(s); ASSERT_TRUE(db->Get(ReadOptions(), "a", &value).IsNotFound()); } else { ASSERT_NOK(s); ASSERT_OK(db->Get(ReadOptions(), "a", &value)); } break; } // Without any promises from the user, range deletion via other `Write()` // APIs are still banned. ASSERT_OK(db->Put(WriteOptions(), "a", "val")); ASSERT_NOK(db->Write(WriteOptions(), &wb)); ASSERT_OK(db->Get(ReadOptions(), "a", &value)); } } } TEST_P(TransactionTest, DeferSnapshotTest) { WriteOptions write_options; ReadOptions read_options; std::string value; Status s; s = db->Put(write_options, "A", "a0"); ASSERT_OK(s); Transaction* txn1 = db->BeginTransaction(write_options); Transaction* txn2 = db->BeginTransaction(write_options); txn1->SetSnapshotOnNextOperation(); auto snapshot = txn1->GetSnapshot(); ASSERT_FALSE(snapshot); s = txn2->Put("A", "a2"); ASSERT_OK(s); s = txn2->Commit(); ASSERT_OK(s); delete txn2; s = txn1->GetForUpdate(read_options, "A", &value); // Should not conflict with txn2 since snapshot wasn't set until // GetForUpdate was called. ASSERT_OK(s); ASSERT_EQ("a2", value); s = txn1->Put("A", "a1"); ASSERT_OK(s); s = db->Put(write_options, "B", "b0"); ASSERT_OK(s); // Cannot lock B since it was written after the snapshot was set s = txn1->Put("B", "b1"); ASSERT_TRUE(s.IsBusy()); s = txn1->Commit(); ASSERT_OK(s); delete txn1; s = db->Get(read_options, "A", &value); ASSERT_OK(s); ASSERT_EQ("a1", value); s = db->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_EQ("b0", value); } TEST_P(TransactionTest, DeferSnapshotTest2) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; Transaction* txn1 = db->BeginTransaction(write_options); txn1->SetSnapshot(); s = txn1->Put("A", "a1"); ASSERT_OK(s); s = db->Put(write_options, "C", "c0"); ASSERT_OK(s); s = db->Put(write_options, "D", "d0"); ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); txn1->SetSnapshotOnNextOperation(); s = txn1->Get(snapshot_read_options, "C", &value); // Snapshot was set before C was written ASSERT_TRUE(s.IsNotFound()); s = txn1->Get(snapshot_read_options, "D", &value); // Snapshot was set before D was written ASSERT_TRUE(s.IsNotFound()); // Snapshot should not have changed yet. snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "C", &value); // Snapshot was set before C was written ASSERT_TRUE(s.IsNotFound()); s = txn1->Get(snapshot_read_options, "D", &value); // Snapshot was set before D was written ASSERT_TRUE(s.IsNotFound()); s = txn1->GetForUpdate(read_options, "C", &value); ASSERT_OK(s); ASSERT_EQ("c0", value); s = db->Put(write_options, "D", "d00"); ASSERT_OK(s); // Snapshot is now set snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "D", &value); ASSERT_OK(s); ASSERT_EQ("d0", value); s = txn1->Commit(); ASSERT_OK(s); delete txn1; } TEST_P(TransactionTest, DeferSnapshotSavePointTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; Transaction* txn1 = db->BeginTransaction(write_options); txn1->SetSavePoint(); // 1 s = db->Put(write_options, "T", "1"); ASSERT_OK(s); txn1->SetSnapshotOnNextOperation(); s = db->Put(write_options, "T", "2"); ASSERT_OK(s); txn1->SetSavePoint(); // 2 s = db->Put(write_options, "T", "3"); ASSERT_OK(s); s = txn1->Put("A", "a"); ASSERT_OK(s); txn1->SetSavePoint(); // 3 s = db->Put(write_options, "T", "4"); ASSERT_OK(s); txn1->SetSnapshot(); txn1->SetSnapshotOnNextOperation(); txn1->SetSavePoint(); // 4 s = db->Put(write_options, "T", "5"); ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("4", value); s = txn1->Put("A", "a1"); ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("5", value); s = txn1->RollbackToSavePoint(); // Rollback to 4 ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("4", value); s = txn1->RollbackToSavePoint(); // Rollback to 3 ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("3", value); s = txn1->Get(read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("5", value); s = txn1->RollbackToSavePoint(); // Rollback to 2 ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); ASSERT_FALSE(snapshot_read_options.snapshot); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("5", value); s = txn1->Delete("A"); ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); ASSERT_TRUE(snapshot_read_options.snapshot); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("5", value); s = txn1->RollbackToSavePoint(); // Rollback to 1 ASSERT_OK(s); s = txn1->Delete("A"); ASSERT_OK(s); snapshot_read_options.snapshot = txn1->GetSnapshot(); ASSERT_FALSE(snapshot_read_options.snapshot); s = txn1->Get(snapshot_read_options, "T", &value); ASSERT_OK(s); ASSERT_EQ("5", value); s = txn1->Commit(); ASSERT_OK(s); delete txn1; } TEST_P(TransactionTest, SetSnapshotOnNextOperationWithNotification) { WriteOptions write_options; ReadOptions read_options; std::string value; class Notifier : public TransactionNotifier { private: const Snapshot** snapshot_ptr_; public: explicit Notifier(const Snapshot** snapshot_ptr) : snapshot_ptr_(snapshot_ptr) {} void SnapshotCreated(const Snapshot* newSnapshot) override { *snapshot_ptr_ = newSnapshot; } }; std::shared_ptr notifier = std::make_shared(&read_options.snapshot); Status s; s = db->Put(write_options, "B", "0"); ASSERT_OK(s); Transaction* txn1 = db->BeginTransaction(write_options); txn1->SetSnapshotOnNextOperation(notifier); ASSERT_FALSE(read_options.snapshot); s = db->Put(write_options, "B", "1"); ASSERT_OK(s); // A Get does not generate the snapshot s = txn1->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_FALSE(read_options.snapshot); ASSERT_EQ(value, "1"); // Any other operation does s = txn1->Put("A", "0"); ASSERT_OK(s); // Now change "B". s = db->Put(write_options, "B", "2"); ASSERT_OK(s); // The original value should still be read s = txn1->Get(read_options, "B", &value); ASSERT_OK(s); ASSERT_TRUE(read_options.snapshot); ASSERT_EQ(value, "1"); s = txn1->Commit(); ASSERT_OK(s); delete txn1; } TEST_P(TransactionTest, ClearSnapshotTest) { WriteOptions write_options; ReadOptions read_options, snapshot_read_options; std::string value; Status s; s = db->Put(write_options, "foo", "0"); ASSERT_OK(s); Transaction* txn = db->BeginTransaction(write_options); ASSERT_TRUE(txn); s = db->Put(write_options, "foo", "1"); ASSERT_OK(s); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_FALSE(snapshot_read_options.snapshot); // No snapshot created yet s = txn->Get(snapshot_read_options, "foo", &value); ASSERT_EQ(value, "1"); txn->SetSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_TRUE(snapshot_read_options.snapshot); s = db->Put(write_options, "foo", "2"); ASSERT_OK(s); // Snapshot was created before change to '2' s = txn->Get(snapshot_read_options, "foo", &value); ASSERT_EQ(value, "1"); txn->ClearSnapshot(); snapshot_read_options.snapshot = txn->GetSnapshot(); ASSERT_FALSE(snapshot_read_options.snapshot); // Snapshot has now been cleared s = txn->Get(snapshot_read_options, "foo", &value); ASSERT_EQ(value, "2"); s = txn->Commit(); ASSERT_OK(s); delete txn; } TEST_P(TransactionTest, ToggleAutoCompactionTest) { Status s; ColumnFamilyHandle *cfa, *cfb; ColumnFamilyOptions cf_options; // Create 2 new column families s = db->CreateColumnFamily(cf_options, "CFA", &cfa); ASSERT_OK(s); s = db->CreateColumnFamily(cf_options, "CFB", &cfb); ASSERT_OK(s); delete cfa; delete cfb; delete db; // open DB with three column families std::vector column_families; // have to open default column family column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); // open the new column families column_families.emplace_back("CFA", ColumnFamilyOptions()); column_families.emplace_back("CFB", ColumnFamilyOptions()); ColumnFamilyOptions* cf_opt_default = &column_families[0].options; ColumnFamilyOptions* cf_opt_cfa = &column_families[1].options; ColumnFamilyOptions* cf_opt_cfb = &column_families[2].options; cf_opt_default->disable_auto_compactions = false; cf_opt_cfa->disable_auto_compactions = true; cf_opt_cfb->disable_auto_compactions = false; std::vector handles; s = TransactionDB::Open(options, txn_db_options, dbname, column_families, &handles, &db); ASSERT_OK(s); auto cfh_default = static_cast_with_check(handles[0]); auto opt_default = *cfh_default->cfd()->GetLatestMutableCFOptions(); auto cfh_a = static_cast_with_check(handles[1]); auto opt_a = *cfh_a->cfd()->GetLatestMutableCFOptions(); auto cfh_b = static_cast_with_check(handles[2]); auto opt_b = *cfh_b->cfd()->GetLatestMutableCFOptions(); ASSERT_EQ(opt_default.disable_auto_compactions, false); ASSERT_EQ(opt_a.disable_auto_compactions, true); ASSERT_EQ(opt_b.disable_auto_compactions, false); for (auto handle : handles) { delete handle; } } TEST_P(TransactionStressTest, ExpiredTransactionDataRace1) { // In this test, txn1 should succeed committing, // as the callback is called after txn1 starts committing. ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->LoadDependency( {{"TransactionTest::ExpirableTransactionDataRace:1"}}); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "TransactionTest::ExpirableTransactionDataRace:1", [&](void* /*arg*/) { WriteOptions write_options; TransactionOptions txn_options; // Force txn1 to expire /* sleep override */ std::this_thread::sleep_for(std::chrono::milliseconds(1500)); Transaction* txn2 = db->BeginTransaction(write_options, txn_options); Status s; s = txn2->Put("X", "2"); ASSERT_TRUE(s.IsTimedOut()); s = txn2->Commit(); ASSERT_OK(s); delete txn2; }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); WriteOptions write_options; TransactionOptions txn_options; txn_options.expiration = 1000; // 1 second Transaction* txn1 = db->BeginTransaction(write_options, txn_options); Status s; s = txn1->Put("X", "1"); ASSERT_OK(s); s = txn1->Commit(); ASSERT_OK(s); ReadOptions read_options; std::string value; s = db->Get(read_options, "X", &value); ASSERT_OK(s); ASSERT_EQ("1", value); delete txn1; ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); } #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) namespace { // cmt_delay_ms is the delay between prepare and commit // first_id is the id of the first transaction Status TransactionStressTestInserter( TransactionDB* db, const size_t num_transactions, const size_t num_sets, const size_t num_keys_per_set, Random64* rand, const uint64_t cmt_delay_ms = 0, const uint64_t first_id = 0) { WriteOptions write_options; ReadOptions read_options; TransactionOptions txn_options; txn_options.use_only_the_last_commit_time_batch_for_recovery = true; // Inside the inserter we might also retake the snapshot. We do both since two // separte functions are engaged for each. txn_options.set_snapshot = rand->OneIn(2); RandomTransactionInserter inserter( rand, write_options, read_options, num_keys_per_set, static_cast(num_sets), cmt_delay_ms, first_id); for (size_t t = 0; t < num_transactions; t++) { bool success = inserter.TransactionDBInsert(db, txn_options); if (!success) { // unexpected failure return inserter.GetLastStatus(); } } inserter.GetLastStatus().PermitUncheckedError(); // Make sure at least some of the transactions succeeded. It's ok if // some failed due to write-conflicts. if (num_transactions != 1 && inserter.GetFailureCount() > num_transactions / 2) { return Status::TryAgain("Too many transactions failed! " + std::to_string(inserter.GetFailureCount()) + " / " + std::to_string(num_transactions)); } return Status::OK(); } } // namespace // Worker threads add a number to a key from each set of keys. The checker // threads verify that the sum of all keys in each set are equal. TEST_P(MySQLStyleTransactionTest, TransactionStressTest) { // Small write buffer to trigger more compactions options.write_buffer_size = 1024; txn_db_options.rollback_deletion_type_callback = [](TransactionDB*, ColumnFamilyHandle*, const Slice& key) { return RandomTransactionInserter::RollbackDeletionTypeCallback(key); }; ASSERT_OK(ReOpenNoDelete()); constexpr size_t num_workers = 4; // worker threads count constexpr size_t num_checkers = 2; // checker threads count constexpr size_t num_slow_checkers = 2; // checker threads emulating backups constexpr size_t num_slow_workers = 1; // slow worker threads count constexpr size_t num_transactions_per_thread = 1000; constexpr uint16_t num_sets = 3; constexpr size_t num_keys_per_set = 100; // Setting the key-space to be 100 keys should cause enough write-conflicts // to make this test interesting. std::vector threads; std::atomic finished = {0}; constexpr bool TAKE_SNAPSHOT = true; uint64_t time_seed = env->NowMicros(); printf("time_seed is %" PRIu64 "\n", time_seed); // would help to reproduce std::function call_inserter = [&] { size_t thd_seed = std::hash()(std::this_thread::get_id()); Random64 rand(time_seed * thd_seed); ASSERT_OK(TransactionStressTestInserter(db, num_transactions_per_thread, num_sets, num_keys_per_set, &rand)); finished++; }; std::function call_checker = [&] { size_t thd_seed = std::hash()(std::this_thread::get_id()); Random64 rand(time_seed * thd_seed); // Verify that data is consistent while (finished < num_workers) { ASSERT_OK(RandomTransactionInserter::Verify( db, num_sets, num_keys_per_set, TAKE_SNAPSHOT, &rand)); } }; std::function call_slow_checker = [&] { size_t thd_seed = std::hash()(std::this_thread::get_id()); Random64 rand(time_seed * thd_seed); // Verify that data is consistent while (finished < num_workers) { uint64_t delay_ms = rand.Uniform(100) + 1; Status s = RandomTransactionInserter::Verify( db, num_sets, num_keys_per_set, TAKE_SNAPSHOT, &rand, delay_ms); ASSERT_OK(s); } }; std::function call_slow_inserter = [&] { size_t thd_seed = std::hash()(std::this_thread::get_id()); Random64 rand(time_seed * thd_seed); uint64_t id = 0; // Verify that data is consistent while (finished < num_workers) { uint64_t delay_ms = rand.Uniform(500) + 1; ASSERT_OK(TransactionStressTestInserter(db, 1, num_sets, num_keys_per_set, &rand, delay_ms, id++)); } }; for (uint32_t i = 0; i < num_workers; i++) { threads.emplace_back(call_inserter); } for (uint32_t i = 0; i < num_checkers; i++) { threads.emplace_back(call_checker); } if (with_slow_threads_) { for (uint32_t i = 0; i < num_slow_checkers; i++) { threads.emplace_back(call_slow_checker); } for (uint32_t i = 0; i < num_slow_workers; i++) { threads.emplace_back(call_slow_inserter); } } // Wait for all threads to finish for (auto& t : threads) { t.join(); } // Verify that data is consistent Status s = RandomTransactionInserter::Verify(db, num_sets, num_keys_per_set, !TAKE_SNAPSHOT); ASSERT_OK(s); } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionTest, MemoryLimitTest) { TransactionOptions txn_options; // Header (12 bytes) + NOOP (1 byte) + 2 * 8 bytes for data. txn_options.max_write_batch_size = 29; // Set threshold to unlimited so that the write batch does not get flushed, // and can hit the memory limit. txn_options.write_batch_flush_threshold = 0; std::string value; Status s; Transaction* txn = db->BeginTransaction(WriteOptions(), txn_options); ASSERT_TRUE(txn); ASSERT_EQ(0, txn->GetNumPuts()); ASSERT_LE(0, txn->GetID()); s = txn->Put(Slice("a"), Slice("....")); ASSERT_OK(s); ASSERT_EQ(1, txn->GetNumPuts()); s = txn->Put(Slice("b"), Slice("....")); ASSERT_OK(s); ASSERT_EQ(2, txn->GetNumPuts()); s = txn->Put(Slice("b"), Slice("....")); ASSERT_TRUE(s.IsMemoryLimit()); ASSERT_EQ(2, txn->GetNumPuts()); ASSERT_OK(txn->Rollback()); delete txn; } #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) // This test clarifies the existing expectation from the sequence number // algorithm. It could detect mistakes in updating the code but it is not // necessarily the one acceptable way. If the algorithm is legitimately changed, // this unit test should be updated as well. TEST_P(TransactionStressTest, SeqAdvanceTest) { // TODO(myabandeh): must be test with false before new releases const bool short_test = true; WriteOptions wopts; FlushOptions fopt; options.disable_auto_compactions = true; ASSERT_OK(ReOpen()); // Do the test with NUM_BRANCHES branches in it. Each run of a test takes some // of the branches. This is the same as counting a binary number where i-th // bit represents whether we take branch i in the represented by the number. const size_t NUM_BRANCHES = short_test ? 6 : 10; // Helper function that shows if the branch is to be taken in the run // represented by the number n. auto branch_do = [&](size_t n, size_t* branch) { assert(*branch < NUM_BRANCHES); const size_t filter = static_cast(1) << *branch; return n & filter; }; const size_t max_n = static_cast(1) << NUM_BRANCHES; for (size_t n = 0; n < max_n; n++) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); size_t branch = 0; auto seq = db_impl->GetLatestSequenceNumber(); exp_seq = seq; TestTxn0(0); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); if (branch_do(n, &branch)) { ASSERT_OK(db_impl->Flush(fopt)); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); } if (!short_test && branch_do(n, &branch)) { ASSERT_OK(db_impl->FlushWAL(true)); ASSERT_OK(ReOpenNoDelete()); db_impl = static_cast_with_check(db->GetRootDB()); seq = db_impl->GetLatestSequenceNumber(); ASSERT_EQ(exp_seq, seq); } // Doing it twice might detect some bugs TestTxn0(1); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); TestTxn1(0); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); if (branch_do(n, &branch)) { ASSERT_OK(db_impl->Flush(fopt)); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); } if (!short_test && branch_do(n, &branch)) { ASSERT_OK(db_impl->FlushWAL(true)); ASSERT_OK(ReOpenNoDelete()); db_impl = static_cast_with_check(db->GetRootDB()); seq = db_impl->GetLatestSequenceNumber(); ASSERT_EQ(exp_seq, seq); } TestTxn3(0); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); if (branch_do(n, &branch)) { ASSERT_OK(db_impl->Flush(fopt)); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); } if (!short_test && branch_do(n, &branch)) { ASSERT_OK(db_impl->FlushWAL(true)); ASSERT_OK(ReOpenNoDelete()); db_impl = static_cast_with_check(db->GetRootDB()); seq = db_impl->GetLatestSequenceNumber(); ASSERT_EQ(exp_seq, seq); } TestTxn4(0); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); if (branch_do(n, &branch)) { ASSERT_OK(db_impl->Flush(fopt)); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); } if (!short_test && branch_do(n, &branch)) { ASSERT_OK(db_impl->FlushWAL(true)); ASSERT_OK(ReOpenNoDelete()); db_impl = static_cast_with_check(db->GetRootDB()); seq = db_impl->GetLatestSequenceNumber(); ASSERT_EQ(exp_seq, seq); } TestTxn2(0); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); if (branch_do(n, &branch)) { ASSERT_OK(db_impl->Flush(fopt)); seq = db_impl->TEST_GetLastVisibleSequence(); ASSERT_EQ(exp_seq, seq); } if (!short_test && branch_do(n, &branch)) { ASSERT_OK(db_impl->FlushWAL(true)); ASSERT_OK(ReOpenNoDelete()); db_impl = static_cast_with_check(db->GetRootDB()); seq = db_impl->GetLatestSequenceNumber(); ASSERT_EQ(exp_seq, seq); } ASSERT_OK(ReOpen()); } } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) // Verify that the optimization would not compromize the correctness TEST_P(TransactionTest, Optimizations) { size_t comb_cnt = size_t(1) << 2; // 2 is number of optimization vars for (size_t new_comb = 0; new_comb < comb_cnt; new_comb++) { TransactionDBWriteOptimizations optimizations; optimizations.skip_concurrency_control = IsInCombination(0, new_comb); optimizations.skip_duplicate_key_check = IsInCombination(1, new_comb); ASSERT_OK(ReOpen()); WriteOptions write_options; WriteBatch batch; ASSERT_OK(batch.Put(Slice("k"), Slice("v1"))); ASSERT_OK(db->Write(write_options, &batch)); ReadOptions ropt; PinnableSlice pinnable_val; ASSERT_OK(db->Get(ropt, db->DefaultColumnFamily(), "k", &pinnable_val)); ASSERT_TRUE(pinnable_val == ("v1")); } } // A comparator that uses only the first three bytes class ThreeBytewiseComparator : public Comparator { public: ThreeBytewiseComparator() = default; const char* Name() const override { return "test.ThreeBytewiseComparator"; } int Compare(const Slice& a, const Slice& b) const override { Slice na = Slice(a.data(), a.size() < 3 ? a.size() : 3); Slice nb = Slice(b.data(), b.size() < 3 ? b.size() : 3); return na.compare(nb); } bool Equal(const Slice& a, const Slice& b) const override { Slice na = Slice(a.data(), a.size() < 3 ? a.size() : 3); Slice nb = Slice(b.data(), b.size() < 3 ? b.size() : 3); return na == nb; } // These methods below don't seem relevant to this test. Implement them if // proven othersize. void FindShortestSeparator(std::string* start, const Slice& limit) const override { const Comparator* bytewise_comp = BytewiseComparator(); bytewise_comp->FindShortestSeparator(start, limit); } void FindShortSuccessor(std::string* key) const override { const Comparator* bytewise_comp = BytewiseComparator(); bytewise_comp->FindShortSuccessor(key); } }; #if !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) TEST_P(TransactionTest, GetWithoutSnapshot) { WriteOptions write_options; std::atomic finish = {false}; ASSERT_OK(db->Put(write_options, "key", "value")); ROCKSDB_NAMESPACE::port::Thread commit_thread([&]() { for (int i = 0; i < 100; i++) { TransactionOptions txn_options; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn->SetName("xid")); ASSERT_OK(txn->Put("key", "overridedvalue")); ASSERT_OK(txn->Put("key", "value")); ASSERT_OK(txn->Prepare()); ASSERT_OK(txn->Commit()); delete txn; } finish = true; }); ROCKSDB_NAMESPACE::port::Thread read_thread([&]() { while (!finish) { ReadOptions ropt; PinnableSlice pinnable_val; ASSERT_OK(db->Get(ropt, db->DefaultColumnFamily(), "key", &pinnable_val)); ASSERT_TRUE(pinnable_val == ("value")); } }); commit_thread.join(); read_thread.join(); } #endif // !defined(ROCKSDB_VALGRIND_RUN) || defined(ROCKSDB_FULL_VALGRIND_RUN) // Test that the transactional db can handle duplicate keys in the write batch TEST_P(TransactionTest, DuplicateKeys) { ColumnFamilyOptions cf_options; std::string cf_name = "two"; ColumnFamilyHandle* cf_handle = nullptr; { ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); WriteOptions write_options; WriteBatch batch; ASSERT_OK(batch.Put(Slice("key"), Slice("value"))); ASSERT_OK(batch.Put(Slice("key2"), Slice("value2"))); // duplicate the keys ASSERT_OK(batch.Put(Slice("key"), Slice("value3"))); // duplicate the 2nd key. It should not be counted duplicate since a // sub-patch is cut after the last duplicate. ASSERT_OK(batch.Put(Slice("key2"), Slice("value4"))); // duplicate the keys but in a different cf. It should not be counted as // duplicate keys ASSERT_OK(batch.Put(cf_handle, Slice("key"), Slice("value5"))); ASSERT_OK(db->Write(write_options, &batch)); ReadOptions ropt; PinnableSlice pinnable_val; auto s = db->Get(ropt, db->DefaultColumnFamily(), "key", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("value3")); s = db->Get(ropt, db->DefaultColumnFamily(), "key2", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("value4")); s = db->Get(ropt, cf_handle, "key", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("value5")); delete cf_handle; } // Test with non-bytewise comparator { ASSERT_OK(ReOpen()); std::unique_ptr comp_gc(new ThreeBytewiseComparator()); cf_options.comparator = comp_gc.get(); ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); WriteOptions write_options; WriteBatch batch; ASSERT_OK(batch.Put(cf_handle, Slice("key"), Slice("value"))); // The first three bytes are the same, do it must be counted as duplicate ASSERT_OK(batch.Put(cf_handle, Slice("key2"), Slice("value2"))); // check for 2nd duplicate key in cf with non-default comparator ASSERT_OK(batch.Put(cf_handle, Slice("key2b"), Slice("value2b"))); ASSERT_OK(db->Write(write_options, &batch)); // The value must be the most recent value for all the keys equal to "key", // including "key2" ReadOptions ropt; PinnableSlice pinnable_val; ASSERT_OK(db->Get(ropt, cf_handle, "key", &pinnable_val)); ASSERT_TRUE(pinnable_val == ("value2b")); // Test duplicate keys with rollback TransactionOptions txn_options; Transaction* txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(cf_handle, Slice("key3"), Slice("value3"))); ASSERT_OK(txn0->Merge(cf_handle, Slice("key4"), Slice("value4"))); ASSERT_OK(txn0->Rollback()); ASSERT_OK(db->Get(ropt, cf_handle, "key5", &pinnable_val)); ASSERT_TRUE(pinnable_val == ("value2b")); delete txn0; delete cf_handle; cf_options.comparator = BytewiseComparator(); } for (bool do_prepare : {true, false}) { for (bool do_rollback : {true, false}) { for (bool with_commit_batch : {true, false}) { if (with_commit_batch && !do_prepare) { continue; } if (with_commit_batch && do_rollback) { continue; } ASSERT_OK(ReOpen()); ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); TransactionOptions txn_options; txn_options.use_only_the_last_commit_time_batch_for_recovery = true; WriteOptions write_options; Transaction* txn0 = db->BeginTransaction(write_options, txn_options); auto s = txn0->SetName("xid"); ASSERT_OK(s); s = txn0->Put(Slice("foo0"), Slice("bar0a")); ASSERT_OK(s); s = txn0->Put(Slice("foo0"), Slice("bar0b")); ASSERT_OK(s); s = txn0->Put(Slice("foo1"), Slice("bar1")); ASSERT_OK(s); s = txn0->Merge(Slice("foo2"), Slice("bar2a")); ASSERT_OK(s); // Repeat a key after the start of a sub-patch. This should not cause a // duplicate in the most recent sub-patch and hence not creating a new // sub-patch. s = txn0->Put(Slice("foo0"), Slice("bar0c")); ASSERT_OK(s); s = txn0->Merge(Slice("foo2"), Slice("bar2b")); ASSERT_OK(s); // duplicate the keys but in a different cf. It should not be counted as // duplicate. s = txn0->Put(cf_handle, Slice("foo0"), Slice("bar0-cf1")); ASSERT_OK(s); s = txn0->Put(Slice("foo3"), Slice("bar3")); ASSERT_OK(s); s = txn0->Merge(Slice("foo3"), Slice("bar3")); ASSERT_OK(s); s = txn0->Put(Slice("foo4"), Slice("bar4")); ASSERT_OK(s); s = txn0->Delete(Slice("foo4")); ASSERT_OK(s); s = txn0->SingleDelete(Slice("foo4")); ASSERT_OK(s); if (do_prepare) { s = txn0->Prepare(); ASSERT_OK(s); } if (do_rollback) { // Test rolling back the batch with duplicates s = txn0->Rollback(); ASSERT_OK(s); } else { if (with_commit_batch) { assert(do_prepare); auto cb = txn0->GetCommitTimeWriteBatch(); // duplicate a key in the original batch // TODO(myabandeh): the behavior of GetCommitTimeWriteBatch // conflicting with the prepared batch is currently undefined and // gives different results in different implementations. // s = cb->Put(Slice("foo0"), Slice("bar0d")); // ASSERT_OK(s); // add a new duplicate key s = cb->Put(Slice("foo6"), Slice("bar6a")); ASSERT_OK(s); s = cb->Put(Slice("foo6"), Slice("bar6b")); ASSERT_OK(s); // add a duplicate key that is removed in the same batch s = cb->Put(Slice("foo7"), Slice("bar7a")); ASSERT_OK(s); s = cb->Delete(Slice("foo7")); ASSERT_OK(s); } s = txn0->Commit(); ASSERT_OK(s); } delete txn0; ReadOptions ropt; PinnableSlice pinnable_val; if (do_rollback) { s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); s = db->Get(ropt, cf_handle, "foo0", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); s = db->Get(ropt, db->DefaultColumnFamily(), "foo1", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); s = db->Get(ropt, db->DefaultColumnFamily(), "foo2", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); s = db->Get(ropt, db->DefaultColumnFamily(), "foo3", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); s = db->Get(ropt, db->DefaultColumnFamily(), "foo4", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); } else { s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0c")); s = db->Get(ropt, cf_handle, "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0-cf1")); s = db->Get(ropt, db->DefaultColumnFamily(), "foo1", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1")); s = db->Get(ropt, db->DefaultColumnFamily(), "foo2", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar2a,bar2b")); s = db->Get(ropt, db->DefaultColumnFamily(), "foo3", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar3,bar3")); s = db->Get(ropt, db->DefaultColumnFamily(), "foo4", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); if (with_commit_batch) { s = db->Get(ropt, db->DefaultColumnFamily(), "foo6", &pinnable_val); if (txn_db_options.write_policy == TxnDBWritePolicy::WRITE_COMMITTED) { ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar6b")); } else { ASSERT_TRUE(s.IsNotFound()); } s = db->Get(ropt, db->DefaultColumnFamily(), "foo7", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); } } delete cf_handle; } // with_commit_batch } // do_rollback } // do_prepare if (!options.unordered_write) { // Also test with max_successive_merges > 0. max_successive_merges will not // affect our algorithm for duplicate key insertion but we add the test to // verify that. cf_options.max_successive_merges = 2; cf_options.merge_operator = MergeOperators::CreateStringAppendOperator(); ASSERT_OK(ReOpen()); ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); WriteOptions write_options; // Ensure one value for the key ASSERT_OK(db->Put(write_options, cf_handle, Slice("key"), Slice("value"))); WriteBatch batch; // Merge more than max_successive_merges times ASSERT_OK(batch.Merge(cf_handle, Slice("key"), Slice("1"))); ASSERT_OK(batch.Merge(cf_handle, Slice("key"), Slice("2"))); ASSERT_OK(batch.Merge(cf_handle, Slice("key"), Slice("3"))); ASSERT_OK(batch.Merge(cf_handle, Slice("key"), Slice("4"))); ASSERT_OK(db->Write(write_options, &batch)); ReadOptions read_options; std::string value; ASSERT_OK(db->Get(read_options, cf_handle, "key", &value)); ASSERT_EQ(value, "value,1,2,3,4"); delete cf_handle; } { // Test that the duplicate detection is not compromised after rolling back // to a save point TransactionOptions txn_options; WriteOptions write_options; Transaction* txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0a"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0b"))); txn0->SetSavePoint(); ASSERT_OK(txn0->RollbackToSavePoint()); ASSERT_OK(txn0->Commit()); delete txn0; } // Test sucessfull recovery after a crash { ASSERT_OK(ReOpen()); TransactionOptions txn_options; WriteOptions write_options; ReadOptions ropt; Transaction* txn0; PinnableSlice pinnable_val; Status s; std::unique_ptr comp_gc(new ThreeBytewiseComparator()); cf_options.comparator = comp_gc.get(); cf_options.merge_operator = MergeOperators::CreateStringAppendOperator(); ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); delete cf_handle; std::vector cfds{ ColumnFamilyDescriptor(kDefaultColumnFamilyName, ColumnFamilyOptions(options)), ColumnFamilyDescriptor(cf_name, cf_options), }; std::vector handles; ASSERT_OK(ReOpenNoDelete(cfds, &handles)); assert(db != nullptr); ASSERT_OK(db->Put(write_options, "foo0", "init")); ASSERT_OK(db->Put(write_options, "foo1", "init")); ASSERT_OK(db->Put(write_options, handles[1], "foo0", "init")); ASSERT_OK(db->Put(write_options, handles[1], "foo1", "init")); // one entry txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0a"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0a")); // two entries, no duplicate txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(handles[1], Slice("foo0"), Slice("bar0b"))); ASSERT_OK(txn0->Put(handles[1], Slice("fol1"), Slice("bar1b"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0b"))); ASSERT_OK(txn0->Put(Slice("foo1"), Slice("bar1b"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); // Flush only cf 1 ASSERT_OK(static_cast_with_check(db->GetRootDB()) ->TEST_FlushMemTable(true, false, handles[1])); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0b")); pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo1", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1b")); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0b")); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "fol1", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1b")); // one duplicate with ::Put txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(handles[1], Slice("key-nonkey0"), Slice("bar0c"))); ASSERT_OK(txn0->Put(handles[1], Slice("key-nonkey1"), Slice("bar1d"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0c"))); ASSERT_OK(txn0->Put(Slice("foo1"), Slice("bar1c"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0d"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); // Flush only cf 1 ASSERT_OK(static_cast_with_check(db->GetRootDB()) ->TEST_FlushMemTable(true, false, handles[1])); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0d")); pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo1", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1c")); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "key-nonkey2", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1d")); // Duplicate with ::Put, ::Delete txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(handles[1], Slice("key-nonkey0"), Slice("bar0e"))); ASSERT_OK(txn0->Delete(handles[1], Slice("key-nonkey1"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0e"))); ASSERT_OK(txn0->Delete(Slice("foo0"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); // Flush only cf 1 ASSERT_OK(static_cast_with_check(db->GetRootDB()) ->TEST_FlushMemTable(true, false, handles[1])); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "key-nonkey2", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); // Duplicate with ::Put, ::SingleDelete txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(handles[1], Slice("key-nonkey0"), Slice("bar0g"))); ASSERT_OK(txn0->SingleDelete(handles[1], Slice("key-nonkey1"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0e"))); ASSERT_OK(txn0->SingleDelete(Slice("foo0"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); // Flush only cf 1 ASSERT_OK(static_cast_with_check(db->GetRootDB()) ->TEST_FlushMemTable(true, false, handles[1])); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "key-nonkey2", &pinnable_val); ASSERT_TRUE(s.IsNotFound()); // Duplicate with ::Put, ::Merge txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Put(handles[1], Slice("key-nonkey0"), Slice("bar1i"))); ASSERT_OK(txn0->Merge(handles[1], Slice("key-nonkey1"), Slice("bar1j"))); ASSERT_OK(txn0->Put(Slice("foo0"), Slice("bar0f"))); ASSERT_OK(txn0->Merge(Slice("foo0"), Slice("bar0g"))); ASSERT_OK(txn0->Prepare()); delete txn0; // This will check the asserts inside recovery code ASSERT_OK(db->FlushWAL(true)); // Flush only cf 1 ASSERT_OK(static_cast_with_check(db->GetRootDB()) ->TEST_FlushMemTable(true, false, handles[1])); static_cast(db)->TEST_Crash(); ASSERT_OK(ReOpenNoDelete(cfds, &handles)); txn0 = db->GetTransactionByName("xid"); ASSERT_TRUE(txn0 != nullptr); ASSERT_OK(txn0->Commit()); delete txn0; pinnable_val.Reset(); s = db->Get(ropt, db->DefaultColumnFamily(), "foo0", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar0f,bar0g")); pinnable_val.Reset(); s = db->Get(ropt, handles[1], "key-nonkey2", &pinnable_val); ASSERT_OK(s); ASSERT_TRUE(pinnable_val == ("bar1i,bar1j")); for (auto h : handles) { delete h; } delete db; db = nullptr; } } // Test that the reseek optimization in iterators will not result in an infinite // loop if there are too many uncommitted entries before the snapshot. TEST_P(TransactionTest, ReseekOptimization) { WriteOptions write_options; write_options.sync = true; write_options.disableWAL = false; ColumnFamilyDescriptor cfd; ASSERT_OK(db->DefaultColumnFamily()->GetDescriptor(&cfd)); auto max_skip = cfd.options.max_sequential_skip_in_iterations; ASSERT_OK(db->Put(write_options, Slice("foo0"), Slice("initv"))); TransactionOptions txn_options; Transaction* txn0 = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn0->SetName("xid")); // Duplicate keys will result into separate sequence numbers in WritePrepared // and WriteUnPrepared for (size_t i = 0; i < 2 * max_skip; i++) { ASSERT_OK(txn0->Put(Slice("foo1"), Slice("bar"))); } ASSERT_OK(txn0->Prepare()); ASSERT_OK(db->Put(write_options, Slice("foo2"), Slice("initv"))); ReadOptions read_options; // To avoid loops read_options.max_skippable_internal_keys = 10 * max_skip; Iterator* iter = db->NewIterator(read_options); ASSERT_OK(iter->status()); size_t cnt = 0; iter->SeekToFirst(); while (iter->Valid()) { iter->Next(); ASSERT_OK(iter->status()); cnt++; } ASSERT_EQ(cnt, 2); cnt = 0; iter->SeekToLast(); while (iter->Valid()) { iter->Prev(); ASSERT_OK(iter->status()); cnt++; } ASSERT_EQ(cnt, 2); delete iter; ASSERT_OK(txn0->Rollback()); delete txn0; } // After recovery in kPointInTimeRecovery mode, the corrupted log file remains // there. The new log files should be still read succesfully during recovery of // the 2nd crash. TEST_P(TransactionTest, DoubleCrashInRecovery) { for (const bool manual_wal_flush : {false, true}) { for (const bool write_after_recovery : {false, true}) { options.wal_recovery_mode = WALRecoveryMode::kPointInTimeRecovery; options.manual_wal_flush = manual_wal_flush; ASSERT_OK(ReOpen()); std::string cf_name = "two"; ColumnFamilyOptions cf_options; ColumnFamilyHandle* cf_handle = nullptr; ASSERT_OK(db->CreateColumnFamily(cf_options, cf_name, &cf_handle)); // Add a prepare entry to prevent the older logs from being deleted. WriteOptions write_options; TransactionOptions txn_options; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn->SetName("xid")); ASSERT_OK(txn->Put(Slice("foo-prepare"), Slice("bar-prepare"))); ASSERT_OK(txn->Prepare()); FlushOptions flush_ops; ASSERT_OK(db->Flush(flush_ops)); // Now we have a log that cannot be deleted ASSERT_OK(db->Put(write_options, cf_handle, "foo1", "bar1")); // Flush only the 2nd cf ASSERT_OK(db->Flush(flush_ops, cf_handle)); // The value is large enough to be touched by the corruption we ingest // below. std::string large_value(400, ' '); // key/value not touched by corruption ASSERT_OK(db->Put(write_options, "foo2", "bar2")); // key/value touched by corruption ASSERT_OK(db->Put(write_options, "foo3", large_value)); // key/value not touched by corruption ASSERT_OK(db->Put(write_options, "foo4", "bar4")); ASSERT_OK(db->FlushWAL(true)); DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); uint64_t wal_file_id = db_impl->TEST_LogfileNumber(); std::string fname = LogFileName(dbname, wal_file_id); static_cast(db)->TEST_Crash(); delete txn; delete cf_handle; delete db; db = nullptr; // Corrupt the last log file in the middle, so that it is not corrupted // in the tail. std::string file_content; ASSERT_OK(ReadFileToString(env.get(), fname, &file_content)); file_content[400] = 'h'; file_content[401] = 'a'; ASSERT_OK(env->DeleteFile(fname)); ASSERT_OK(WriteStringToFile(env.get(), file_content, fname, true)); // Recover from corruption std::vector handles; std::vector column_families; column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions()); column_families.emplace_back("two", ColumnFamilyOptions()); ASSERT_OK(ReOpenNoDelete(column_families, &handles)); assert(db != nullptr); if (write_after_recovery) { // Write data to the log right after the corrupted log ASSERT_OK(db->Put(write_options, "foo5", large_value)); } // Persist data written to WAL during recovery or by the last Put ASSERT_OK(db->FlushWAL(true)); // 2nd crash to recover while having a valid log after the corrupted one. ASSERT_OK(ReOpenNoDelete(column_families, &handles)); assert(db != nullptr); txn = db->GetTransactionByName("xid"); ASSERT_TRUE(txn != nullptr); ASSERT_OK(txn->Commit()); delete txn; for (auto handle : handles) { delete handle; } } } } TEST_P(TransactionTest, CommitWithoutPrepare) { { // skip_prepare = false. WriteOptions write_options; TransactionOptions txn_options; txn_options.skip_prepare = false; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_TRUE(txn->Commit().IsTxnNotPrepared()); delete txn; } { // skip_prepare = true. WriteOptions write_options; TransactionOptions txn_options; txn_options.skip_prepare = true; Transaction* txn = db->BeginTransaction(write_options, txn_options); ASSERT_OK(txn->Commit()); delete txn; } } TEST_P(TransactionTest, OpenAndEnableU64Timestamp) { ASSERT_OK(ReOpenNoDelete()); assert(db); const std::string test_cf_name = "test_cf"; ColumnFamilyOptions cf_opts; cf_opts.comparator = test::BytewiseComparatorWithU64TsWrapper(); { ColumnFamilyHandle* cfh = nullptr; const Status s = db->CreateColumnFamily(cf_opts, test_cf_name, &cfh); if (txn_db_options.write_policy == WRITE_COMMITTED) { ASSERT_OK(s); delete cfh; } else { ASSERT_TRUE(s.IsNotSupported()); assert(!cfh); } } // Bypass transaction db layer. if (txn_db_options.write_policy != WRITE_COMMITTED) { DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); assert(db_impl); ColumnFamilyHandle* cfh = nullptr; ASSERT_OK(db_impl->CreateColumnFamily(cf_opts, test_cf_name, &cfh)); delete cfh; } { std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, options); cf_descs.emplace_back(test_cf_name, cf_opts); std::vector handles; const Status s = ReOpenNoDelete(cf_descs, &handles); if (txn_db_options.write_policy == WRITE_COMMITTED) { ASSERT_OK(s); for (auto* h : handles) { delete h; } } else { ASSERT_TRUE(s.IsNotSupported()); } } } TEST_P(TransactionTest, OpenAndEnableU32Timestamp) { class DummyComparatorWithU32Ts : public Comparator { public: DummyComparatorWithU32Ts() : Comparator(sizeof(uint32_t)) {} const char* Name() const override { return "DummyComparatorWithU32Ts"; } void FindShortSuccessor(std::string*) const override {} void FindShortestSeparator(std::string*, const Slice&) const override {} int Compare(const Slice&, const Slice&) const override { return 0; } }; std::unique_ptr dummy_ucmp(new DummyComparatorWithU32Ts()); ASSERT_OK(ReOpenNoDelete()); assert(db); const std::string test_cf_name = "test_cf"; ColumnFamilyOptions cf_opts; cf_opts.comparator = dummy_ucmp.get(); { ColumnFamilyHandle* cfh = nullptr; ASSERT_TRUE(db->CreateColumnFamily(cf_opts, test_cf_name, &cfh) .IsInvalidArgument()); } // Bypass transaction db layer. { ColumnFamilyHandle* cfh = nullptr; DBImpl* db_impl = static_cast_with_check(db->GetRootDB()); assert(db_impl); ASSERT_OK(db_impl->CreateColumnFamily(cf_opts, test_cf_name, &cfh)); delete cfh; } { std::vector cf_descs; cf_descs.emplace_back(kDefaultColumnFamilyName, options); cf_descs.emplace_back(test_cf_name, cf_opts); std::vector handles; ASSERT_TRUE(ReOpenNoDelete(cf_descs, &handles).IsInvalidArgument()); } } TEST_P(TransactionTest, WriteWithBulkCreatedColumnFamilies) { ColumnFamilyOptions cf_options; WriteOptions write_options; std::vector cf_names; std::vector cf_handles; cf_names.emplace_back("test_cf"); ASSERT_OK(db->CreateColumnFamilies(cf_options, cf_names, &cf_handles)); ASSERT_OK(db->Put(write_options, cf_handles[0], "foo", "bar")); ASSERT_OK(db->DropColumnFamilies(cf_handles)); for (auto* h : cf_handles) { delete h; } cf_handles.clear(); std::vector cf_descriptors; cf_descriptors.emplace_back("test_cf", ColumnFamilyOptions()); ASSERT_OK(db->CreateColumnFamilies(cf_options, cf_names, &cf_handles)); ASSERT_OK(db->Put(write_options, cf_handles[0], "foo", "bar")); ASSERT_OK(db->DropColumnFamilies(cf_handles)); for (auto* h : cf_handles) { delete h; } cf_handles.clear(); } TEST_P(TransactionTest, LockWal) { const TxnDBWritePolicy write_policy = std::get<2>(GetParam()); if (TxnDBWritePolicy::WRITE_COMMITTED != write_policy) { ROCKSDB_GTEST_BYPASS("Test only write-committed for now"); return; } ASSERT_OK(ReOpen()); SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->LoadDependency( {{"TransactionTest::LockWal:AfterLockWal", "TransactionTest::LockWal:BeforePrepareTxn2"}}); SyncPoint::GetInstance()->EnableProcessing(); std::unique_ptr txn0; WriteOptions wopts; wopts.no_slowdown = true; txn0.reset(db->BeginTransaction(wopts, TransactionOptions())); ASSERT_OK(txn0->SetName("txn0")); ASSERT_OK(txn0->Put("foo", "v0")); std::unique_ptr txn1; txn1.reset(db->BeginTransaction(wopts, TransactionOptions())); ASSERT_OK(txn1->SetName("txn1")); ASSERT_OK(txn1->Put("dummy", "v0")); ASSERT_OK(txn1->Prepare()); std::unique_ptr txn2; port::Thread worker([&]() { txn2.reset(db->BeginTransaction(WriteOptions(), TransactionOptions())); ASSERT_OK(txn2->SetName("txn2")); ASSERT_OK(txn2->Put("bar", "v0")); TEST_SYNC_POINT("TransactionTest::LockWal:BeforePrepareTxn2"); ASSERT_OK(txn2->Prepare()); ASSERT_OK(txn2->Commit()); }); ASSERT_OK(db->LockWAL()); // txn0 cannot prepare Status s = txn0->Prepare(); ASSERT_TRUE(s.IsIncomplete()); // txn1 cannot commit s = txn1->Commit(); ASSERT_TRUE(s.IsIncomplete()); TEST_SYNC_POINT("TransactionTest::LockWal:AfterLockWal"); ASSERT_OK(db->UnlockWAL()); txn0.reset(); txn0.reset(db->BeginTransaction(wopts, TransactionOptions())); ASSERT_OK(txn0->SetName("txn0_1")); ASSERT_OK(txn0->Put("foo", "v1")); ASSERT_OK(txn0->Prepare()); ASSERT_OK(txn0->Commit()); worker.join(); SyncPoint::GetInstance()->DisableProcessing(); } TEST_P(TransactionTest, StallTwoWriteQueues) { // There was a two_write_queues bug in which both write thread leaders (for // each queue) would attempt to own the stopping of writes in the primary // write queue. This nearly worked but could lead to some broken assertions // and a kind of deadlock in the test below. (Would resume if someone // eventually signalled bg_cv_ again.) if (!options.two_write_queues) { ROCKSDB_GTEST_BYPASS("Test only needed with two_write_queues"); return; } // Stop writes ASSERT_OK(db->LockWAL()); WriteOptions wopts; wopts.sync = true; wopts.disableWAL = false; // Create one write thread that blocks in the primary write queue and one // that blocks in the nonmem queue. bool t1_completed = false; bool t2_completed = false; port::Thread t1{[&]() { ASSERT_OK(db->Put(wopts, "x", "y")); t1_completed = true; }}; port::Thread t2{[&]() { std::unique_ptr txn0{db->BeginTransaction(wopts, {})}; ASSERT_OK(txn0->SetName("xid")); ASSERT_OK(txn0->Prepare()); // nonmem ASSERT_OK(txn0->Commit()); t2_completed = true; }}; // Sleep long enough to that above threads can usually reach a waiting point, // to usually reveal deadlock if the bug is present. std::this_thread::sleep_for(std::chrono::milliseconds(100)); // Ensure proper test setup ASSERT_FALSE(t1_completed); ASSERT_FALSE(t2_completed); // Resume writes ASSERT_OK(db->UnlockWAL()); // Wait for writes to finish t1.join(); t2.join(); // Ensure proper test setup ASSERT_TRUE(t1_completed); ASSERT_TRUE(t2_completed); } // Make sure UnlockWAL does not return until the stall it controls is cleared. TEST_P(TransactionTest, UnlockWALStallCleared) { auto dbimpl = static_cast_with_check(db->GetRootDB()); for (bool external_stall : {false, true}) { WriteOptions wopts; wopts.sync = true; wopts.disableWAL = false; ASSERT_OK(db->Put(wopts, "k1", "val1")); // Stall writes ASSERT_OK(db->LockWAL()); std::unique_ptr token; if (external_stall) { // Also make sure UnlockWAL can return despite another stall being in // effect. token = dbimpl->TEST_write_controler().GetStopToken(); } SyncPoint::GetInstance()->DisableProcessing(); std::vector sync_deps; sync_deps.push_back( {"DBImpl::DelayWrite:Wait", "TransactionTest::UnlockWALStallCleared:BeforeUnlockWAL1"}); if (options.two_write_queues && txn_db_options.write_policy == WRITE_COMMITTED) { sync_deps.push_back( {"DBImpl::DelayWrite:NonmemWait", "TransactionTest::UnlockWALStallCleared:BeforeUnlockWAL2"}); } SyncPoint::GetInstance()->LoadDependency(sync_deps); SyncPoint::GetInstance()->SetCallBack( "DBImpl::DelayWrite:AfterWait", [](void* arg) { auto& mu = *static_cast(arg); mu.AssertHeld(); // Pretend we are slow waking up from bg_cv_, to give a chance for the // bug to occur if it can. Randomly prefer one queue over the other. mu.Unlock(); if (Random::GetTLSInstance()->OneIn(2)) { std::this_thread::sleep_for(std::chrono::milliseconds(10)); } else { std::this_thread::yield(); } mu.Lock(); }); SyncPoint::GetInstance()->EnableProcessing(); // Create blocking writes (for both queues) in background and use // sync point dependency to get the stall into the write queue(s) std::atomic t1_completed{false}; port::Thread t1{[&]() { ASSERT_OK(db->Put(wopts, "k2", "val2")); t1_completed = true; }}; std::atomic t2_completed{false}; port::Thread t2{[&]() { std::unique_ptr txn0{db->BeginTransaction(wopts, {})}; ASSERT_OK(txn0->SetName("x1")); ASSERT_OK(txn0->Put("k3", "val3")); ASSERT_OK(txn0->Prepare()); // nonmem ASSERT_OK(txn0->Commit()); }}; // Be sure the test is set up appropriately TEST_SYNC_POINT("TransactionTest::UnlockWALStallCleared:BeforeUnlockWAL1"); TEST_SYNC_POINT("TransactionTest::UnlockWALStallCleared:BeforeUnlockWAL2"); ASSERT_FALSE(t1_completed.load()); ASSERT_FALSE(t2_completed.load()); // Clear the stall ASSERT_OK(db->UnlockWAL()); WriteOptions wopts2 = wopts; if (external_stall) { // We did not deadlock in UnlockWAL, so now async clear the external // stall and then do a blocking write. // DB mutex acquire+release is needed to ensure we don't reset token and // signal while DelayWrite() is between IsStopped() and // BeginWriteStall(). token.reset(); dbimpl->TEST_LockMutex(); dbimpl->TEST_UnlockMutex(); dbimpl->TEST_SignalAllBgCv(); } else { // To verify the LockWAL stall is guaranteed cleared, do a non-blocking // write that is attempting to catch a bug by attempting to come before // the thread that did BeginWriteStall() can do EndWriteStall() wopts2.no_slowdown = true; } std::unique_ptr txn0{db->BeginTransaction(wopts2, {})}; ASSERT_OK(txn0->SetName("x2")); ASSERT_OK(txn0->Put("k1", "val4")); ASSERT_OK(txn0->Prepare()); // nonmem ASSERT_OK(txn0->Commit()); t1.join(); t2.join(); } } TEST_F(TransactionDBTest, CollapseKey) { ASSERT_OK(ReOpen()); ASSERT_OK(db->Put({}, "hello", "world")); ASSERT_OK(db->Flush({})); ASSERT_OK(db->Merge({}, "hello", "world")); ASSERT_OK(db->Flush({})); ASSERT_OK(db->Merge({}, "hello", "world")); ASSERT_OK(db->Flush({})); std::string value; ASSERT_OK(db->Get({}, "hello", &value)); ASSERT_EQ("world,world,world", value); // get merge op info std::vector operands(3); GetMergeOperandsOptions mergeOperandOptions; mergeOperandOptions.expected_max_number_of_operands = 3; int numOperands; ASSERT_OK(db->GetMergeOperands({}, db->DefaultColumnFamily(), "hello", operands.data(), &mergeOperandOptions, &numOperands)); ASSERT_EQ(3, numOperands); // collapse key { std::unique_ptr txn0{ db->BeginTransaction(WriteOptions{}, TransactionOptions{})}; ASSERT_OK(txn0->CollapseKey(ReadOptions{}, "hello")); ASSERT_OK(txn0->Commit()); } // merge operands should be 1 ASSERT_OK(db->GetMergeOperands({}, db->DefaultColumnFamily(), "hello", operands.data(), &mergeOperandOptions, &numOperands)); ASSERT_EQ(1, numOperands); // get again after collapse ASSERT_OK(db->Get({}, "hello", &value)); ASSERT_EQ("world,world,world", value); // collapse of non-existent key { std::unique_ptr txn1{ db->BeginTransaction(WriteOptions{}, TransactionOptions{})}; ASSERT_TRUE(txn1->CollapseKey(ReadOptions{}, "dummy").IsNotFound()); } } } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }