// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). // // Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "db/db_impl.h" #ifndef __STDC_FORMAT_MACROS #define __STDC_FORMAT_MACROS #endif #include #include "db/error_handler.h" #include "db/event_helpers.h" #include "monitoring/perf_context_imp.h" #include "options/options_helper.h" #include "util/sync_point.h" namespace rocksdb { // Convenience methods Status DBImpl::Put(const WriteOptions& o, ColumnFamilyHandle* column_family, const Slice& key, const Slice& val) { return DB::Put(o, column_family, key, val); } Status DBImpl::Merge(const WriteOptions& o, ColumnFamilyHandle* column_family, const Slice& key, const Slice& val) { auto cfh = reinterpret_cast(column_family); if (!cfh->cfd()->ioptions()->merge_operator) { return Status::NotSupported("Provide a merge_operator when opening DB"); } else { return DB::Merge(o, column_family, key, val); } } Status DBImpl::Delete(const WriteOptions& write_options, ColumnFamilyHandle* column_family, const Slice& key) { return DB::Delete(write_options, column_family, key); } Status DBImpl::SingleDelete(const WriteOptions& write_options, ColumnFamilyHandle* column_family, const Slice& key) { return DB::SingleDelete(write_options, column_family, key); } void DBImpl::SetRecoverableStatePreReleaseCallback( PreReleaseCallback* callback) { recoverable_state_pre_release_callback_.reset(callback); } Status DBImpl::Write(const WriteOptions& write_options, WriteBatch* my_batch) { return WriteImpl(write_options, my_batch, nullptr, nullptr); } #ifndef ROCKSDB_LITE Status DBImpl::WriteWithCallback(const WriteOptions& write_options, WriteBatch* my_batch, WriteCallback* callback) { return WriteImpl(write_options, my_batch, callback, nullptr); } #endif // ROCKSDB_LITE // The main write queue. This is the only write queue that updates LastSequence. // When using one write queue, the same sequence also indicates the last // published sequence. Status DBImpl::WriteImpl(const WriteOptions& write_options, WriteBatch* my_batch, WriteCallback* callback, uint64_t* log_used, uint64_t log_ref, bool disable_memtable, uint64_t* seq_used, size_t batch_cnt, PreReleaseCallback* pre_release_callback) { assert(!seq_per_batch_ || batch_cnt != 0); if (my_batch == nullptr) { return Status::Corruption("Batch is nullptr!"); } if (tracer_) { InstrumentedMutexLock lock(&trace_mutex_); if (tracer_) { tracer_->Write(my_batch); } } if (write_options.sync && write_options.disableWAL) { return Status::InvalidArgument("Sync writes has to enable WAL."); } if (two_write_queues_ && immutable_db_options_.enable_pipelined_write) { return Status::NotSupported( "pipelined_writes is not compatible with concurrent prepares"); } if (seq_per_batch_ && immutable_db_options_.enable_pipelined_write) { // TODO(yiwu): update pipeline write with seq_per_batch and batch_cnt return Status::NotSupported( "pipelined_writes is not compatible with seq_per_batch"); } // Otherwise IsLatestPersistentState optimization does not make sense assert(!WriteBatchInternal::IsLatestPersistentState(my_batch) || disable_memtable); Status status; if (write_options.low_pri) { status = ThrottleLowPriWritesIfNeeded(write_options, my_batch); if (!status.ok()) { return status; } } if (two_write_queues_ && disable_memtable) { return WriteImplWALOnly(write_options, my_batch, callback, log_used, log_ref, seq_used, batch_cnt, pre_release_callback); } if (immutable_db_options_.enable_pipelined_write) { return PipelinedWriteImpl(write_options, my_batch, callback, log_used, log_ref, disable_memtable, seq_used); } PERF_TIMER_GUARD(write_pre_and_post_process_time); WriteThread::Writer w(write_options, my_batch, callback, log_ref, disable_memtable, batch_cnt, pre_release_callback); if (!write_options.disableWAL) { RecordTick(stats_, WRITE_WITH_WAL); } StopWatch write_sw(env_, immutable_db_options_.statistics.get(), DB_WRITE); write_thread_.JoinBatchGroup(&w); if (w.state == WriteThread::STATE_PARALLEL_MEMTABLE_WRITER) { // we are a non-leader in a parallel group if (w.ShouldWriteToMemtable()) { PERF_TIMER_STOP(write_pre_and_post_process_time); PERF_TIMER_GUARD(write_memtable_time); ColumnFamilyMemTablesImpl column_family_memtables( versions_->GetColumnFamilySet()); w.status = WriteBatchInternal::InsertInto( &w, w.sequence, &column_family_memtables, &flush_scheduler_, write_options.ignore_missing_column_families, 0 /*log_number*/, this, true /*concurrent_memtable_writes*/, seq_per_batch_, w.batch_cnt); PERF_TIMER_START(write_pre_and_post_process_time); } if (write_thread_.CompleteParallelMemTableWriter(&w)) { // we're responsible for exit batch group for (auto* writer : *(w.write_group)) { if (!writer->CallbackFailed() && writer->pre_release_callback) { assert(writer->sequence != kMaxSequenceNumber); Status ws = writer->pre_release_callback->Callback(writer->sequence, disable_memtable); if (!ws.ok()) { status = ws; break; } } } // TODO(myabandeh): propagate status to write_group auto last_sequence = w.write_group->last_sequence; versions_->SetLastSequence(last_sequence); MemTableInsertStatusCheck(w.status); write_thread_.ExitAsBatchGroupFollower(&w); } assert(w.state == WriteThread::STATE_COMPLETED); // STATE_COMPLETED conditional below handles exit status = w.FinalStatus(); } if (w.state == WriteThread::STATE_COMPLETED) { if (log_used != nullptr) { *log_used = w.log_used; } if (seq_used != nullptr) { *seq_used = w.sequence; } // write is complete and leader has updated sequence return w.FinalStatus(); } // else we are the leader of the write batch group assert(w.state == WriteThread::STATE_GROUP_LEADER); // Once reaches this point, the current writer "w" will try to do its write // job. It may also pick up some of the remaining writers in the "writers_" // when it finds suitable, and finish them in the same write batch. // This is how a write job could be done by the other writer. WriteContext write_context; WriteThread::WriteGroup write_group; bool in_parallel_group = false; uint64_t last_sequence = kMaxSequenceNumber; if (!two_write_queues_) { last_sequence = versions_->LastSequence(); } mutex_.Lock(); bool need_log_sync = write_options.sync; bool need_log_dir_sync = need_log_sync && !log_dir_synced_; if (!two_write_queues_ || !disable_memtable) { // With concurrent writes we do preprocess only in the write thread that // also does write to memtable to avoid sync issue on shared data structure // with the other thread // PreprocessWrite does its own perf timing. PERF_TIMER_STOP(write_pre_and_post_process_time); status = PreprocessWrite(write_options, &need_log_sync, &write_context); PERF_TIMER_START(write_pre_and_post_process_time); } log::Writer* log_writer = logs_.back().writer; mutex_.Unlock(); // Add to log and apply to memtable. We can release the lock // during this phase since &w is currently responsible for logging // and protects against concurrent loggers and concurrent writes // into memtables TEST_SYNC_POINT("DBImpl::WriteImpl:BeforeLeaderEnters"); last_batch_group_size_ = write_thread_.EnterAsBatchGroupLeader(&w, &write_group); if (status.ok()) { // Rules for when we can update the memtable concurrently // 1. supported by memtable // 2. Puts are not okay if inplace_update_support // 3. Merges are not okay // // Rules 1..2 are enforced by checking the options // during startup (CheckConcurrentWritesSupported), so if // options.allow_concurrent_memtable_write is true then they can be // assumed to be true. Rule 3 is checked for each batch. We could // relax rules 2 if we could prevent write batches from referring // more than once to a particular key. bool parallel = immutable_db_options_.allow_concurrent_memtable_write && write_group.size > 1; size_t total_count = 0; size_t valid_batches = 0; size_t total_byte_size = 0; for (auto* writer : write_group) { if (writer->CheckCallback(this)) { valid_batches += writer->batch_cnt; if (writer->ShouldWriteToMemtable()) { total_count += WriteBatchInternal::Count(writer->batch); parallel = parallel && !writer->batch->HasMerge(); } total_byte_size = WriteBatchInternal::AppendedByteSize( total_byte_size, WriteBatchInternal::ByteSize(writer->batch)); } } // Note about seq_per_batch_: either disableWAL is set for the entire write // group or not. In either case we inc seq for each write batch with no // failed callback. This means that there could be a batch with // disalbe_memtable in between; although we do not write this batch to // memtable it still consumes a seq. Otherwise, if !seq_per_batch_, we inc // the seq per valid written key to mem. size_t seq_inc = seq_per_batch_ ? valid_batches : total_count; const bool concurrent_update = two_write_queues_; // Update stats while we are an exclusive group leader, so we know // that nobody else can be writing to these particular stats. // We're optimistic, updating the stats before we successfully // commit. That lets us release our leader status early. auto stats = default_cf_internal_stats_; stats->AddDBStats(InternalStats::NUMBER_KEYS_WRITTEN, total_count, concurrent_update); RecordTick(stats_, NUMBER_KEYS_WRITTEN, total_count); stats->AddDBStats(InternalStats::BYTES_WRITTEN, total_byte_size, concurrent_update); RecordTick(stats_, BYTES_WRITTEN, total_byte_size); stats->AddDBStats(InternalStats::WRITE_DONE_BY_SELF, 1, concurrent_update); RecordTick(stats_, WRITE_DONE_BY_SELF); auto write_done_by_other = write_group.size - 1; if (write_done_by_other > 0) { stats->AddDBStats(InternalStats::WRITE_DONE_BY_OTHER, write_done_by_other, concurrent_update); RecordTick(stats_, WRITE_DONE_BY_OTHER, write_done_by_other); } MeasureTime(stats_, BYTES_PER_WRITE, total_byte_size); if (write_options.disableWAL) { has_unpersisted_data_.store(true, std::memory_order_relaxed); } PERF_TIMER_STOP(write_pre_and_post_process_time); if (!two_write_queues_) { if (status.ok() && !write_options.disableWAL) { PERF_TIMER_GUARD(write_wal_time); status = WriteToWAL(write_group, log_writer, log_used, need_log_sync, need_log_dir_sync, last_sequence + 1); } } else { if (status.ok() && !write_options.disableWAL) { PERF_TIMER_GUARD(write_wal_time); // LastAllocatedSequence is increased inside WriteToWAL under // wal_write_mutex_ to ensure ordered events in WAL status = ConcurrentWriteToWAL(write_group, log_used, &last_sequence, seq_inc); } else { // Otherwise we inc seq number for memtable writes last_sequence = versions_->FetchAddLastAllocatedSequence(seq_inc); } } assert(last_sequence != kMaxSequenceNumber); const SequenceNumber current_sequence = last_sequence + 1; last_sequence += seq_inc; if (status.ok()) { PERF_TIMER_GUARD(write_memtable_time); if (!parallel) { // w.sequence will be set inside InsertInto w.status = WriteBatchInternal::InsertInto( write_group, current_sequence, column_family_memtables_.get(), &flush_scheduler_, write_options.ignore_missing_column_families, 0 /*recovery_log_number*/, this, parallel, seq_per_batch_, batch_per_txn_); } else { SequenceNumber next_sequence = current_sequence; // Note: the logic for advancing seq here must be consistent with the // logic in WriteBatchInternal::InsertInto(write_group...) as well as // with WriteBatchInternal::InsertInto(write_batch...) that is called on // the merged batch during recovery from the WAL. for (auto* writer : write_group) { if (writer->CallbackFailed()) { continue; } writer->sequence = next_sequence; if (seq_per_batch_) { assert(writer->batch_cnt); next_sequence += writer->batch_cnt; } else if (writer->ShouldWriteToMemtable()) { next_sequence += WriteBatchInternal::Count(writer->batch); } } write_group.last_sequence = last_sequence; write_thread_.LaunchParallelMemTableWriters(&write_group); in_parallel_group = true; // Each parallel follower is doing each own writes. The leader should // also do its own. if (w.ShouldWriteToMemtable()) { ColumnFamilyMemTablesImpl column_family_memtables( versions_->GetColumnFamilySet()); assert(w.sequence == current_sequence); w.status = WriteBatchInternal::InsertInto( &w, w.sequence, &column_family_memtables, &flush_scheduler_, write_options.ignore_missing_column_families, 0 /*log_number*/, this, true /*concurrent_memtable_writes*/, seq_per_batch_, w.batch_cnt, batch_per_txn_); } } if (seq_used != nullptr) { *seq_used = w.sequence; } } } PERF_TIMER_START(write_pre_and_post_process_time); if (!w.CallbackFailed()) { WriteStatusCheck(status); } if (need_log_sync) { mutex_.Lock(); MarkLogsSynced(logfile_number_, need_log_dir_sync, status); mutex_.Unlock(); // Requesting sync with two_write_queues_ is expected to be very rare. We // hence provide a simple implementation that is not necessarily efficient. if (two_write_queues_) { if (manual_wal_flush_) { status = FlushWAL(true); } else { status = SyncWAL(); } } } bool should_exit_batch_group = true; if (in_parallel_group) { // CompleteParallelWorker returns true if this thread should // handle exit, false means somebody else did should_exit_batch_group = write_thread_.CompleteParallelMemTableWriter(&w); } if (should_exit_batch_group) { if (status.ok()) { for (auto* writer : write_group) { if (!writer->CallbackFailed() && writer->pre_release_callback) { assert(writer->sequence != kMaxSequenceNumber); Status ws = writer->pre_release_callback->Callback(writer->sequence, disable_memtable); if (!ws.ok()) { status = ws; break; } } } versions_->SetLastSequence(last_sequence); } MemTableInsertStatusCheck(w.status); write_thread_.ExitAsBatchGroupLeader(write_group, status); } if (status.ok()) { status = w.FinalStatus(); } return status; } Status DBImpl::PipelinedWriteImpl(const WriteOptions& write_options, WriteBatch* my_batch, WriteCallback* callback, uint64_t* log_used, uint64_t log_ref, bool disable_memtable, uint64_t* seq_used) { PERF_TIMER_GUARD(write_pre_and_post_process_time); StopWatch write_sw(env_, immutable_db_options_.statistics.get(), DB_WRITE); WriteContext write_context; WriteThread::Writer w(write_options, my_batch, callback, log_ref, disable_memtable); write_thread_.JoinBatchGroup(&w); if (w.state == WriteThread::STATE_GROUP_LEADER) { WriteThread::WriteGroup wal_write_group; if (w.callback && !w.callback->AllowWriteBatching()) { write_thread_.WaitForMemTableWriters(); } mutex_.Lock(); bool need_log_sync = !write_options.disableWAL && write_options.sync; bool need_log_dir_sync = need_log_sync && !log_dir_synced_; // PreprocessWrite does its own perf timing. PERF_TIMER_STOP(write_pre_and_post_process_time); w.status = PreprocessWrite(write_options, &need_log_sync, &write_context); PERF_TIMER_START(write_pre_and_post_process_time); log::Writer* log_writer = logs_.back().writer; mutex_.Unlock(); // This can set non-OK status if callback fail. last_batch_group_size_ = write_thread_.EnterAsBatchGroupLeader(&w, &wal_write_group); const SequenceNumber current_sequence = write_thread_.UpdateLastSequence(versions_->LastSequence()) + 1; size_t total_count = 0; size_t total_byte_size = 0; if (w.status.ok()) { SequenceNumber next_sequence = current_sequence; for (auto writer : wal_write_group) { if (writer->CheckCallback(this)) { if (writer->ShouldWriteToMemtable()) { writer->sequence = next_sequence; size_t count = WriteBatchInternal::Count(writer->batch); next_sequence += count; total_count += count; } total_byte_size = WriteBatchInternal::AppendedByteSize( total_byte_size, WriteBatchInternal::ByteSize(writer->batch)); } } if (w.disable_wal) { has_unpersisted_data_.store(true, std::memory_order_relaxed); } write_thread_.UpdateLastSequence(current_sequence + total_count - 1); } auto stats = default_cf_internal_stats_; stats->AddDBStats(InternalStats::NUMBER_KEYS_WRITTEN, total_count); RecordTick(stats_, NUMBER_KEYS_WRITTEN, total_count); stats->AddDBStats(InternalStats::BYTES_WRITTEN, total_byte_size); RecordTick(stats_, BYTES_WRITTEN, total_byte_size); MeasureTime(stats_, BYTES_PER_WRITE, total_byte_size); PERF_TIMER_STOP(write_pre_and_post_process_time); if (w.ShouldWriteToWAL()) { PERF_TIMER_GUARD(write_wal_time); stats->AddDBStats(InternalStats::WRITE_DONE_BY_SELF, 1); RecordTick(stats_, WRITE_DONE_BY_SELF, 1); if (wal_write_group.size > 1) { stats->AddDBStats(InternalStats::WRITE_DONE_BY_OTHER, wal_write_group.size - 1); RecordTick(stats_, WRITE_DONE_BY_OTHER, wal_write_group.size - 1); } w.status = WriteToWAL(wal_write_group, log_writer, log_used, need_log_sync, need_log_dir_sync, current_sequence); } if (!w.CallbackFailed()) { WriteStatusCheck(w.status); } if (need_log_sync) { mutex_.Lock(); MarkLogsSynced(logfile_number_, need_log_dir_sync, w.status); mutex_.Unlock(); } write_thread_.ExitAsBatchGroupLeader(wal_write_group, w.status); } WriteThread::WriteGroup memtable_write_group; if (w.state == WriteThread::STATE_MEMTABLE_WRITER_LEADER) { PERF_TIMER_GUARD(write_memtable_time); assert(w.status.ok()); write_thread_.EnterAsMemTableWriter(&w, &memtable_write_group); if (memtable_write_group.size > 1 && immutable_db_options_.allow_concurrent_memtable_write) { write_thread_.LaunchParallelMemTableWriters(&memtable_write_group); } else { memtable_write_group.status = WriteBatchInternal::InsertInto( memtable_write_group, w.sequence, column_family_memtables_.get(), &flush_scheduler_, write_options.ignore_missing_column_families, 0 /*log_number*/, this, false /*concurrent_memtable_writes*/, seq_per_batch_, batch_per_txn_); versions_->SetLastSequence(memtable_write_group.last_sequence); write_thread_.ExitAsMemTableWriter(&w, memtable_write_group); } } if (w.state == WriteThread::STATE_PARALLEL_MEMTABLE_WRITER) { assert(w.ShouldWriteToMemtable()); ColumnFamilyMemTablesImpl column_family_memtables( versions_->GetColumnFamilySet()); w.status = WriteBatchInternal::InsertInto( &w, w.sequence, &column_family_memtables, &flush_scheduler_, write_options.ignore_missing_column_families, 0 /*log_number*/, this, true /*concurrent_memtable_writes*/); if (write_thread_.CompleteParallelMemTableWriter(&w)) { MemTableInsertStatusCheck(w.status); versions_->SetLastSequence(w.write_group->last_sequence); write_thread_.ExitAsMemTableWriter(&w, *w.write_group); } } if (seq_used != nullptr) { *seq_used = w.sequence; } assert(w.state == WriteThread::STATE_COMPLETED); return w.FinalStatus(); } // The 2nd write queue. If enabled it will be used only for WAL-only writes. // This is the only queue that updates LastPublishedSequence which is only // applicable in a two-queue setting. Status DBImpl::WriteImplWALOnly(const WriteOptions& write_options, WriteBatch* my_batch, WriteCallback* callback, uint64_t* log_used, uint64_t log_ref, uint64_t* seq_used, size_t batch_cnt, PreReleaseCallback* pre_release_callback) { Status status; PERF_TIMER_GUARD(write_pre_and_post_process_time); WriteThread::Writer w(write_options, my_batch, callback, log_ref, true /* disable_memtable */, batch_cnt, pre_release_callback); RecordTick(stats_, WRITE_WITH_WAL); StopWatch write_sw(env_, immutable_db_options_.statistics.get(), DB_WRITE); nonmem_write_thread_.JoinBatchGroup(&w); assert(w.state != WriteThread::STATE_PARALLEL_MEMTABLE_WRITER); if (w.state == WriteThread::STATE_COMPLETED) { if (log_used != nullptr) { *log_used = w.log_used; } if (seq_used != nullptr) { *seq_used = w.sequence; } return w.FinalStatus(); } // else we are the leader of the write batch group assert(w.state == WriteThread::STATE_GROUP_LEADER); WriteThread::WriteGroup write_group; uint64_t last_sequence; nonmem_write_thread_.EnterAsBatchGroupLeader(&w, &write_group); // Note: no need to update last_batch_group_size_ here since the batch writes // to WAL only size_t total_byte_size = 0; for (auto* writer : write_group) { if (writer->CheckCallback(this)) { total_byte_size = WriteBatchInternal::AppendedByteSize( total_byte_size, WriteBatchInternal::ByteSize(writer->batch)); } } const bool concurrent_update = true; // Update stats while we are an exclusive group leader, so we know // that nobody else can be writing to these particular stats. // We're optimistic, updating the stats before we successfully // commit. That lets us release our leader status early. auto stats = default_cf_internal_stats_; stats->AddDBStats(InternalStats::BYTES_WRITTEN, total_byte_size, concurrent_update); RecordTick(stats_, BYTES_WRITTEN, total_byte_size); stats->AddDBStats(InternalStats::WRITE_DONE_BY_SELF, 1, concurrent_update); RecordTick(stats_, WRITE_DONE_BY_SELF); auto write_done_by_other = write_group.size - 1; if (write_done_by_other > 0) { stats->AddDBStats(InternalStats::WRITE_DONE_BY_OTHER, write_done_by_other, concurrent_update); RecordTick(stats_, WRITE_DONE_BY_OTHER, write_done_by_other); } MeasureTime(stats_, BYTES_PER_WRITE, total_byte_size); PERF_TIMER_STOP(write_pre_and_post_process_time); PERF_TIMER_GUARD(write_wal_time); // LastAllocatedSequence is increased inside WriteToWAL under // wal_write_mutex_ to ensure ordered events in WAL size_t seq_inc = 0 /* total_count */; if (seq_per_batch_) { size_t total_batch_cnt = 0; for (auto* writer : write_group) { assert(writer->batch_cnt); total_batch_cnt += writer->batch_cnt; } seq_inc = total_batch_cnt; } if (!write_options.disableWAL) { status = ConcurrentWriteToWAL(write_group, log_used, &last_sequence, seq_inc); } else { // Otherwise we inc seq number to do solely the seq allocation last_sequence = versions_->FetchAddLastAllocatedSequence(seq_inc); } auto curr_seq = last_sequence + 1; for (auto* writer : write_group) { if (writer->CallbackFailed()) { continue; } writer->sequence = curr_seq; if (seq_per_batch_) { assert(writer->batch_cnt); curr_seq += writer->batch_cnt; } // else seq advances only by memtable writes } if (status.ok() && write_options.sync) { assert(!write_options.disableWAL); // Requesting sync with two_write_queues_ is expected to be very rare. We // hance provide a simple implementation that is not necessarily efficient. if (manual_wal_flush_) { status = FlushWAL(true); } else { status = SyncWAL(); } } PERF_TIMER_START(write_pre_and_post_process_time); if (!w.CallbackFailed()) { WriteStatusCheck(status); } if (status.ok()) { for (auto* writer : write_group) { if (!writer->CallbackFailed() && writer->pre_release_callback) { assert(writer->sequence != kMaxSequenceNumber); const bool DISABLE_MEMTABLE = true; Status ws = writer->pre_release_callback->Callback(writer->sequence, DISABLE_MEMTABLE); if (!ws.ok()) { status = ws; break; } } } } nonmem_write_thread_.ExitAsBatchGroupLeader(write_group, status); if (status.ok()) { status = w.FinalStatus(); } if (seq_used != nullptr) { *seq_used = w.sequence; } return status; } void DBImpl::WriteStatusCheck(const Status& status) { // Is setting bg_error_ enough here? This will at least stop // compaction and fail any further writes. if (immutable_db_options_.paranoid_checks && !status.ok() && !status.IsBusy() && !status.IsIncomplete()) { mutex_.Lock(); error_handler_.SetBGError(status, BackgroundErrorReason::kWriteCallback); mutex_.Unlock(); } } void DBImpl::MemTableInsertStatusCheck(const Status& status) { // A non-OK status here indicates that the state implied by the // WAL has diverged from the in-memory state. This could be // because of a corrupt write_batch (very bad), or because the // client specified an invalid column family and didn't specify // ignore_missing_column_families. if (!status.ok()) { mutex_.Lock(); assert(!error_handler_.IsBGWorkStopped()); error_handler_.SetBGError(status, BackgroundErrorReason::kMemTable); mutex_.Unlock(); } } Status DBImpl::PreprocessWrite(const WriteOptions& write_options, bool* need_log_sync, WriteContext* write_context) { mutex_.AssertHeld(); assert(write_context != nullptr && need_log_sync != nullptr); Status status; if (error_handler_.IsDBStopped()) { status = error_handler_.GetBGError(); } PERF_TIMER_GUARD(write_scheduling_flushes_compactions_time); assert(!single_column_family_mode_ || versions_->GetColumnFamilySet()->NumberOfColumnFamilies() == 1); if (UNLIKELY(status.ok() && !single_column_family_mode_ && total_log_size_ > GetMaxTotalWalSize())) { status = SwitchWAL(write_context); } if (UNLIKELY(status.ok() && write_buffer_manager_->ShouldFlush())) { // Before a new memtable is added in SwitchMemtable(), // write_buffer_manager_->ShouldFlush() will keep returning true. If another // thread is writing to another DB with the same write buffer, they may also // be flushed. We may end up with flushing much more DBs than needed. It's // suboptimal but still correct. status = HandleWriteBufferFull(write_context); } if (UNLIKELY(status.ok() && !flush_scheduler_.Empty())) { status = ScheduleFlushes(write_context); } PERF_TIMER_STOP(write_scheduling_flushes_compactions_time); PERF_TIMER_GUARD(write_pre_and_post_process_time); if (UNLIKELY(status.ok() && (write_controller_.IsStopped() || write_controller_.NeedsDelay()))) { PERF_TIMER_STOP(write_pre_and_post_process_time); PERF_TIMER_GUARD(write_delay_time); // We don't know size of curent batch so that we always use the size // for previous one. It might create a fairness issue that expiration // might happen for smaller writes but larger writes can go through. // Can optimize it if it is an issue. status = DelayWrite(last_batch_group_size_, write_options); PERF_TIMER_START(write_pre_and_post_process_time); } if (status.ok() && *need_log_sync) { // Wait until the parallel syncs are finished. Any sync process has to sync // the front log too so it is enough to check the status of front() // We do a while loop since log_sync_cv_ is signalled when any sync is // finished // Note: there does not seem to be a reason to wait for parallel sync at // this early step but it is not important since parallel sync (SyncWAL) and // need_log_sync are usually not used together. while (logs_.front().getting_synced) { log_sync_cv_.Wait(); } for (auto& log : logs_) { assert(!log.getting_synced); // This is just to prevent the logs to be synced by a parallel SyncWAL // call. We will do the actual syncing later after we will write to the // WAL. // Note: there does not seem to be a reason to set this early before we // actually write to the WAL log.getting_synced = true; } } else { *need_log_sync = false; } return status; } WriteBatch* DBImpl::MergeBatch(const WriteThread::WriteGroup& write_group, WriteBatch* tmp_batch, size_t* write_with_wal, WriteBatch** to_be_cached_state) { assert(write_with_wal != nullptr); assert(tmp_batch != nullptr); assert(*to_be_cached_state == nullptr); WriteBatch* merged_batch = nullptr; *write_with_wal = 0; auto* leader = write_group.leader; assert(!leader->disable_wal); // Same holds for all in the batch group if (write_group.size == 1 && !leader->CallbackFailed() && leader->batch->GetWalTerminationPoint().is_cleared()) { // we simply write the first WriteBatch to WAL if the group only // contains one batch, that batch should be written to the WAL, // and the batch is not wanting to be truncated merged_batch = leader->batch; if (WriteBatchInternal::IsLatestPersistentState(merged_batch)) { *to_be_cached_state = merged_batch; } *write_with_wal = 1; } else { // WAL needs all of the batches flattened into a single batch. // We could avoid copying here with an iov-like AddRecord // interface merged_batch = tmp_batch; for (auto writer : write_group) { if (!writer->CallbackFailed()) { WriteBatchInternal::Append(merged_batch, writer->batch, /*WAL_only*/ true); if (WriteBatchInternal::IsLatestPersistentState(writer->batch)) { // We only need to cache the last of such write batch *to_be_cached_state = writer->batch; } (*write_with_wal)++; } } } return merged_batch; } // When two_write_queues_ is disabled, this function is called from the only // write thread. Otherwise this must be called holding log_write_mutex_. Status DBImpl::WriteToWAL(const WriteBatch& merged_batch, log::Writer* log_writer, uint64_t* log_used, uint64_t* log_size) { assert(log_size != nullptr); Slice log_entry = WriteBatchInternal::Contents(&merged_batch); *log_size = log_entry.size(); // When two_write_queues_ WriteToWAL has to be protected from concurretn calls // from the two queues anyway and log_write_mutex_ is already held. Otherwise // if manual_wal_flush_ is enabled we need to protect log_writer->AddRecord // from possible concurrent calls via the FlushWAL by the application. const bool needs_locking = manual_wal_flush_ && !two_write_queues_; // Due to performance cocerns of missed branch prediction penalize the new // manual_wal_flush_ feature (by UNLIKELY) instead of the more common case // when we do not need any locking. if (UNLIKELY(needs_locking)) { log_write_mutex_.Lock(); } Status status = log_writer->AddRecord(log_entry); if (UNLIKELY(needs_locking)) { log_write_mutex_.Unlock(); } if (log_used != nullptr) { *log_used = logfile_number_; } total_log_size_ += log_entry.size(); // TODO(myabandeh): it might be unsafe to access alive_log_files_.back() here // since alive_log_files_ might be modified concurrently alive_log_files_.back().AddSize(log_entry.size()); log_empty_ = false; return status; } Status DBImpl::WriteToWAL(const WriteThread::WriteGroup& write_group, log::Writer* log_writer, uint64_t* log_used, bool need_log_sync, bool need_log_dir_sync, SequenceNumber sequence) { Status status; assert(!write_group.leader->disable_wal); // Same holds for all in the batch group size_t write_with_wal = 0; WriteBatch* to_be_cached_state = nullptr; WriteBatch* merged_batch = MergeBatch(write_group, &tmp_batch_, &write_with_wal, &to_be_cached_state); if (merged_batch == write_group.leader->batch) { write_group.leader->log_used = logfile_number_; } else if (write_with_wal > 1) { for (auto writer : write_group) { writer->log_used = logfile_number_; } } WriteBatchInternal::SetSequence(merged_batch, sequence); uint64_t log_size; status = WriteToWAL(*merged_batch, log_writer, log_used, &log_size); if (to_be_cached_state) { cached_recoverable_state_ = *to_be_cached_state; cached_recoverable_state_empty_ = false; } if (status.ok() && need_log_sync) { StopWatch sw(env_, stats_, WAL_FILE_SYNC_MICROS); // It's safe to access logs_ with unlocked mutex_ here because: // - we've set getting_synced=true for all logs, // so other threads won't pop from logs_ while we're here, // - only writer thread can push to logs_, and we're in // writer thread, so no one will push to logs_, // - as long as other threads don't modify it, it's safe to read // from std::deque from multiple threads concurrently. for (auto& log : logs_) { status = log.writer->file()->Sync(immutable_db_options_.use_fsync); if (!status.ok()) { break; } } if (status.ok() && need_log_dir_sync) { // We only sync WAL directory the first time WAL syncing is // requested, so that in case users never turn on WAL sync, // we can avoid the disk I/O in the write code path. status = directories_.GetWalDir()->Fsync(); } } if (merged_batch == &tmp_batch_) { tmp_batch_.Clear(); } if (status.ok()) { auto stats = default_cf_internal_stats_; if (need_log_sync) { stats->AddDBStats(InternalStats::WAL_FILE_SYNCED, 1); RecordTick(stats_, WAL_FILE_SYNCED); } stats->AddDBStats(InternalStats::WAL_FILE_BYTES, log_size); RecordTick(stats_, WAL_FILE_BYTES, log_size); stats->AddDBStats(InternalStats::WRITE_WITH_WAL, write_with_wal); RecordTick(stats_, WRITE_WITH_WAL, write_with_wal); } return status; } Status DBImpl::ConcurrentWriteToWAL(const WriteThread::WriteGroup& write_group, uint64_t* log_used, SequenceNumber* last_sequence, size_t seq_inc) { Status status; assert(!write_group.leader->disable_wal); // Same holds for all in the batch group WriteBatch tmp_batch; size_t write_with_wal = 0; WriteBatch* to_be_cached_state = nullptr; WriteBatch* merged_batch = MergeBatch(write_group, &tmp_batch, &write_with_wal, &to_be_cached_state); // We need to lock log_write_mutex_ since logs_ and alive_log_files might be // pushed back concurrently log_write_mutex_.Lock(); if (merged_batch == write_group.leader->batch) { write_group.leader->log_used = logfile_number_; } else if (write_with_wal > 1) { for (auto writer : write_group) { writer->log_used = logfile_number_; } } *last_sequence = versions_->FetchAddLastAllocatedSequence(seq_inc); auto sequence = *last_sequence + 1; WriteBatchInternal::SetSequence(merged_batch, sequence); log::Writer* log_writer = logs_.back().writer; uint64_t log_size; status = WriteToWAL(*merged_batch, log_writer, log_used, &log_size); if (to_be_cached_state) { cached_recoverable_state_ = *to_be_cached_state; cached_recoverable_state_empty_ = false; } log_write_mutex_.Unlock(); if (status.ok()) { const bool concurrent = true; auto stats = default_cf_internal_stats_; stats->AddDBStats(InternalStats::WAL_FILE_BYTES, log_size, concurrent); RecordTick(stats_, WAL_FILE_BYTES, log_size); stats->AddDBStats(InternalStats::WRITE_WITH_WAL, write_with_wal, concurrent); RecordTick(stats_, WRITE_WITH_WAL, write_with_wal); } return status; } Status DBImpl::WriteRecoverableState() { mutex_.AssertHeld(); if (!cached_recoverable_state_empty_) { bool dont_care_bool; SequenceNumber next_seq; if (two_write_queues_) { log_write_mutex_.Lock(); } SequenceNumber seq; if (two_write_queues_) { seq = versions_->FetchAddLastAllocatedSequence(0); } else { seq = versions_->LastSequence(); } WriteBatchInternal::SetSequence(&cached_recoverable_state_, seq + 1); auto status = WriteBatchInternal::InsertInto( &cached_recoverable_state_, column_family_memtables_.get(), &flush_scheduler_, true, 0 /*recovery_log_number*/, this, false /* concurrent_memtable_writes */, &next_seq, &dont_care_bool, seq_per_batch_); auto last_seq = next_seq - 1; if (two_write_queues_) { versions_->FetchAddLastAllocatedSequence(last_seq - seq); versions_->SetLastPublishedSequence(last_seq); } versions_->SetLastSequence(last_seq); if (two_write_queues_) { log_write_mutex_.Unlock(); } if (status.ok() && recoverable_state_pre_release_callback_) { const bool DISABLE_MEMTABLE = true; for (uint64_t sub_batch_seq = seq + 1; sub_batch_seq < next_seq && status.ok(); sub_batch_seq++) { status = recoverable_state_pre_release_callback_->Callback( sub_batch_seq, !DISABLE_MEMTABLE); } } if (status.ok()) { cached_recoverable_state_.Clear(); cached_recoverable_state_empty_ = true; } return status; } return Status::OK(); } void DBImpl::SelectColumnFamiliesForAtomicFlush( autovector* cfds) { for (ColumnFamilyData* cfd : *versions_->GetColumnFamilySet()) { if (cfd->IsDropped()) { continue; } if (cfd->imm()->NumNotFlushed() != 0 || !cfd->mem()->IsEmpty() || !cached_recoverable_state_empty_.load()) { cfds->push_back(cfd); } } } // Assign sequence number for atomic flush. void DBImpl::AssignAtomicFlushSeq(const autovector& cfds) { assert(atomic_flush_); auto seq = versions_->LastSequence(); for (auto cfd : cfds) { cfd->imm()->AssignAtomicFlushSeq(seq); } } Status DBImpl::SwitchWAL(WriteContext* write_context) { mutex_.AssertHeld(); assert(write_context != nullptr); Status status; if (alive_log_files_.begin()->getting_flushed) { return status; } auto oldest_alive_log = alive_log_files_.begin()->number; bool flush_wont_release_oldest_log = false; if (allow_2pc()) { auto oldest_log_with_uncommited_prep = logs_with_prep_tracker_.FindMinLogContainingOutstandingPrep(); assert(oldest_log_with_uncommited_prep == 0 || oldest_log_with_uncommited_prep >= oldest_alive_log); if (oldest_log_with_uncommited_prep > 0 && oldest_log_with_uncommited_prep == oldest_alive_log) { if (unable_to_release_oldest_log_) { // we already attempted to flush all column families dependent on // the oldest alive log but the log still contained uncommited // transactions so there is still nothing that we can do. return status; } else { ROCKS_LOG_WARN( immutable_db_options_.info_log, "Unable to release oldest log due to uncommited transaction"); unable_to_release_oldest_log_ = true; flush_wont_release_oldest_log = true; } } } if (!flush_wont_release_oldest_log) { // we only mark this log as getting flushed if we have successfully // flushed all data in this log. If this log contains outstanding prepared // transactions then we cannot flush this log until those transactions are commited. unable_to_release_oldest_log_ = false; alive_log_files_.begin()->getting_flushed = true; } ROCKS_LOG_INFO(immutable_db_options_.info_log, "Flushing all column families with data in WAL number %" PRIu64 ". Total log size is %" PRIu64 " while max_total_wal_size is %" PRIu64, oldest_alive_log, total_log_size_.load(), GetMaxTotalWalSize()); // no need to refcount because drop is happening in write thread, so can't // happen while we're in the write thread autovector cfds; if (atomic_flush_) { SelectColumnFamiliesForAtomicFlush(&cfds); } else { for (auto cfd : *versions_->GetColumnFamilySet()) { if (cfd->IsDropped()) { continue; } if (cfd->OldestLogToKeep() <= oldest_alive_log) { cfds.push_back(cfd); } } } for (const auto cfd : cfds) { cfd->Ref(); status = SwitchMemtable(cfd, write_context); cfd->Unref(); if (!status.ok()) { break; } } if (status.ok()) { if (atomic_flush_) { AssignAtomicFlushSeq(cfds); } for (auto cfd : cfds) { cfd->imm()->FlushRequested(); } FlushRequest flush_req; GenerateFlushRequest(cfds, &flush_req); SchedulePendingFlush(flush_req, FlushReason::kWriteBufferManager); MaybeScheduleFlushOrCompaction(); } return status; } Status DBImpl::HandleWriteBufferFull(WriteContext* write_context) { mutex_.AssertHeld(); assert(write_context != nullptr); Status status; // Before a new memtable is added in SwitchMemtable(), // write_buffer_manager_->ShouldFlush() will keep returning true. If another // thread is writing to another DB with the same write buffer, they may also // be flushed. We may end up with flushing much more DBs than needed. It's // suboptimal but still correct. ROCKS_LOG_INFO( immutable_db_options_.info_log, "Flushing column family with largest mem table size. Write buffer is " "using %" PRIu64 " bytes out of a total of %" PRIu64 ".", write_buffer_manager_->memory_usage(), write_buffer_manager_->buffer_size()); // no need to refcount because drop is happening in write thread, so can't // happen while we're in the write thread autovector cfds; if (atomic_flush_) { SelectColumnFamiliesForAtomicFlush(&cfds); } else { ColumnFamilyData* cfd_picked = nullptr; SequenceNumber seq_num_for_cf_picked = kMaxSequenceNumber; for (auto cfd : *versions_->GetColumnFamilySet()) { if (cfd->IsDropped()) { continue; } if (!cfd->mem()->IsEmpty()) { // We only consider active mem table, hoping immutable memtable is // already in the process of flushing. uint64_t seq = cfd->mem()->GetCreationSeq(); if (cfd_picked == nullptr || seq < seq_num_for_cf_picked) { cfd_picked = cfd; seq_num_for_cf_picked = seq; } } } if (cfd_picked != nullptr) { cfds.push_back(cfd_picked); } } for (const auto cfd : cfds) { if (cfd->mem()->IsEmpty()) { continue; } cfd->Ref(); status = SwitchMemtable(cfd, write_context); cfd->Unref(); if (!status.ok()) { break; } } if (status.ok()) { if (atomic_flush_) { AssignAtomicFlushSeq(cfds); } for (const auto cfd : cfds) { cfd->imm()->FlushRequested(); } FlushRequest flush_req; GenerateFlushRequest(cfds, &flush_req); SchedulePendingFlush(flush_req, FlushReason::kWriteBufferFull); MaybeScheduleFlushOrCompaction(); } return status; } uint64_t DBImpl::GetMaxTotalWalSize() const { mutex_.AssertHeld(); return mutable_db_options_.max_total_wal_size == 0 ? 4 * max_total_in_memory_state_ : mutable_db_options_.max_total_wal_size; } // REQUIRES: mutex_ is held // REQUIRES: this thread is currently at the front of the writer queue Status DBImpl::DelayWrite(uint64_t num_bytes, const WriteOptions& write_options) { uint64_t time_delayed = 0; bool delayed = false; { StopWatch sw(env_, stats_, WRITE_STALL, &time_delayed); uint64_t delay = write_controller_.GetDelay(env_, num_bytes); if (delay > 0) { if (write_options.no_slowdown) { return Status::Incomplete("Write stall"); } TEST_SYNC_POINT("DBImpl::DelayWrite:Sleep"); // Notify write_thread_ about the stall so it can setup a barrier and // fail any pending writers with no_slowdown write_thread_.BeginWriteStall(); TEST_SYNC_POINT("DBImpl::DelayWrite:BeginWriteStallDone"); mutex_.Unlock(); // We will delay the write until we have slept for delay ms or // we don't need a delay anymore const uint64_t kDelayInterval = 1000; uint64_t stall_end = sw.start_time() + delay; while (write_controller_.NeedsDelay()) { if (env_->NowMicros() >= stall_end) { // We already delayed this write `delay` microseconds break; } delayed = true; // Sleep for 0.001 seconds env_->SleepForMicroseconds(kDelayInterval); } mutex_.Lock(); write_thread_.EndWriteStall(); } // Don't wait if there's a background error, even if its a soft error. We // might wait here indefinitely as the background compaction may never // finish successfully, resulting in the stall condition lasting // indefinitely while (error_handler_.GetBGError().ok() && write_controller_.IsStopped()) { if (write_options.no_slowdown) { return Status::Incomplete("Write stall"); } delayed = true; // Notify write_thread_ about the stall so it can setup a barrier and // fail any pending writers with no_slowdown write_thread_.BeginWriteStall(); TEST_SYNC_POINT("DBImpl::DelayWrite:Wait"); bg_cv_.Wait(); write_thread_.EndWriteStall(); } } assert(!delayed || !write_options.no_slowdown); if (delayed) { default_cf_internal_stats_->AddDBStats(InternalStats::WRITE_STALL_MICROS, time_delayed); RecordTick(stats_, STALL_MICROS, time_delayed); } // If DB is not in read-only mode and write_controller is not stopping // writes, we can ignore any background errors and allow the write to // proceed Status s; if (write_controller_.IsStopped()) { // If writes are still stopped, it means we bailed due to a background // error s = Status::Incomplete(error_handler_.GetBGError().ToString()); } if (error_handler_.IsDBStopped()) { s = error_handler_.GetBGError(); } return s; } Status DBImpl::ThrottleLowPriWritesIfNeeded(const WriteOptions& write_options, WriteBatch* my_batch) { assert(write_options.low_pri); // This is called outside the DB mutex. Although it is safe to make the call, // the consistency condition is not guaranteed to hold. It's OK to live with // it in this case. // If we need to speed compaction, it means the compaction is left behind // and we start to limit low pri writes to a limit. if (write_controller_.NeedSpeedupCompaction()) { if (allow_2pc() && (my_batch->HasCommit() || my_batch->HasRollback())) { // For 2PC, we only rate limit prepare, not commit. return Status::OK(); } if (write_options.no_slowdown) { return Status::Incomplete(); } else { assert(my_batch != nullptr); // Rate limit those writes. The reason that we don't completely wait // is that in case the write is heavy, low pri writes may never have // a chance to run. Now we guarantee we are still slowly making // progress. PERF_TIMER_GUARD(write_delay_time); write_controller_.low_pri_rate_limiter()->Request( my_batch->GetDataSize(), Env::IO_HIGH, nullptr /* stats */, RateLimiter::OpType::kWrite); } } return Status::OK(); } Status DBImpl::ScheduleFlushes(WriteContext* context) { autovector cfds; if (atomic_flush_) { SelectColumnFamiliesForAtomicFlush(&cfds); for (auto cfd : cfds) { cfd->Ref(); } flush_scheduler_.Clear(); } else { ColumnFamilyData* tmp_cfd; while ((tmp_cfd = flush_scheduler_.TakeNextColumnFamily()) != nullptr) { cfds.push_back(tmp_cfd); } } Status status; for (auto& cfd : cfds) { if (!cfd->mem()->IsEmpty()) { status = SwitchMemtable(cfd, context); } if (cfd->Unref()) { delete cfd; cfd = nullptr; } if (!status.ok()) { break; } } if (status.ok()) { if (atomic_flush_) { AssignAtomicFlushSeq(cfds); } FlushRequest flush_req; GenerateFlushRequest(cfds, &flush_req); SchedulePendingFlush(flush_req, FlushReason::kWriteBufferFull); MaybeScheduleFlushOrCompaction(); } return status; } #ifndef ROCKSDB_LITE void DBImpl::NotifyOnMemTableSealed(ColumnFamilyData* /*cfd*/, const MemTableInfo& mem_table_info) { if (immutable_db_options_.listeners.size() == 0U) { return; } if (shutting_down_.load(std::memory_order_acquire)) { return; } for (auto listener : immutable_db_options_.listeners) { listener->OnMemTableSealed(mem_table_info); } } #endif // ROCKSDB_LITE // REQUIRES: mutex_ is held // REQUIRES: this thread is currently at the front of the writer queue Status DBImpl::SwitchMemtable(ColumnFamilyData* cfd, WriteContext* context) { mutex_.AssertHeld(); WriteThread::Writer nonmem_w; if (two_write_queues_) { // SwitchMemtable is a rare event. To simply the reasoning, we make sure // that there is no concurrent thread writing to WAL. nonmem_write_thread_.EnterUnbatched(&nonmem_w, &mutex_); } std::unique_ptr lfile; log::Writer* new_log = nullptr; MemTable* new_mem = nullptr; // Recoverable state is persisted in WAL. After memtable switch, WAL might // be deleted, so we write the state to memtable to be persisted as well. Status s = WriteRecoverableState(); if (!s.ok()) { return s; } // In case of pipelined write is enabled, wait for all pending memtable // writers. if (immutable_db_options_.enable_pipelined_write) { // Memtable writers may call DB::Get in case max_successive_merges > 0, // which may lock mutex. Unlocking mutex here to avoid deadlock. mutex_.Unlock(); write_thread_.WaitForMemTableWriters(); mutex_.Lock(); } // Attempt to switch to a new memtable and trigger flush of old. // Do this without holding the dbmutex lock. assert(versions_->prev_log_number() == 0); if (two_write_queues_) { log_write_mutex_.Lock(); } bool creating_new_log = !log_empty_; if (two_write_queues_) { log_write_mutex_.Unlock(); } uint64_t recycle_log_number = 0; if (creating_new_log && immutable_db_options_.recycle_log_file_num && !log_recycle_files_.empty()) { recycle_log_number = log_recycle_files_.front(); log_recycle_files_.pop_front(); } uint64_t new_log_number = creating_new_log ? versions_->NewFileNumber() : logfile_number_; const MutableCFOptions mutable_cf_options = *cfd->GetLatestMutableCFOptions(); // Set memtable_info for memtable sealed callback #ifndef ROCKSDB_LITE MemTableInfo memtable_info; memtable_info.cf_name = cfd->GetName(); memtable_info.first_seqno = cfd->mem()->GetFirstSequenceNumber(); memtable_info.earliest_seqno = cfd->mem()->GetEarliestSequenceNumber(); memtable_info.num_entries = cfd->mem()->num_entries(); memtable_info.num_deletes = cfd->mem()->num_deletes(); #endif // ROCKSDB_LITE // Log this later after lock release. It may be outdated, e.g., if background // flush happens before logging, but that should be ok. int num_imm_unflushed = cfd->imm()->NumNotFlushed(); DBOptions db_options = BuildDBOptions(immutable_db_options_, mutable_db_options_); const auto preallocate_block_size = GetWalPreallocateBlockSize(mutable_cf_options.write_buffer_size); auto write_hint = CalculateWALWriteHint(); mutex_.Unlock(); { std::string log_fname = LogFileName(immutable_db_options_.wal_dir, new_log_number); if (creating_new_log) { EnvOptions opt_env_opt = env_->OptimizeForLogWrite(env_options_, db_options); if (recycle_log_number) { ROCKS_LOG_INFO(immutable_db_options_.info_log, "reusing log %" PRIu64 " from recycle list\n", recycle_log_number); std::string old_log_fname = LogFileName(immutable_db_options_.wal_dir, recycle_log_number); s = env_->ReuseWritableFile(log_fname, old_log_fname, &lfile, opt_env_opt); } else { s = NewWritableFile(env_, log_fname, &lfile, opt_env_opt); } if (s.ok()) { // Our final size should be less than write_buffer_size // (compression, etc) but err on the side of caution. // use preallocate_block_size instead // of calling GetWalPreallocateBlockSize() lfile->SetPreallocationBlockSize(preallocate_block_size); lfile->SetWriteLifeTimeHint(write_hint); std::unique_ptr file_writer(new WritableFileWriter( std::move(lfile), log_fname, opt_env_opt, nullptr /* stats */, immutable_db_options_.listeners)); new_log = new log::Writer( std::move(file_writer), new_log_number, immutable_db_options_.recycle_log_file_num > 0, manual_wal_flush_); } } if (s.ok()) { SequenceNumber seq = versions_->LastSequence(); new_mem = cfd->ConstructNewMemtable(mutable_cf_options, seq); context->superversion_context.NewSuperVersion(); } #ifndef ROCKSDB_LITE // PLEASE NOTE: We assume that there are no failable operations // after lock is acquired below since we are already notifying // client about mem table becoming immutable. NotifyOnMemTableSealed(cfd, memtable_info); #endif //ROCKSDB_LITE } ROCKS_LOG_INFO(immutable_db_options_.info_log, "[%s] New memtable created with log file: #%" PRIu64 ". Immutable memtables: %d.\n", cfd->GetName().c_str(), new_log_number, num_imm_unflushed); mutex_.Lock(); if (s.ok() && creating_new_log) { log_write_mutex_.Lock(); logfile_number_ = new_log_number; assert(new_log != nullptr); log_empty_ = true; log_dir_synced_ = false; if (!logs_.empty()) { // Alway flush the buffer of the last log before switching to a new one log::Writer* cur_log_writer = logs_.back().writer; s = cur_log_writer->WriteBuffer(); if (!s.ok()) { ROCKS_LOG_WARN(immutable_db_options_.info_log, "[%s] Failed to switch from #%" PRIu64 " to #%" PRIu64 " WAL file -- %s\n", cfd->GetName().c_str(), cur_log_writer->get_log_number(), new_log_number); } } logs_.emplace_back(logfile_number_, new_log); alive_log_files_.push_back(LogFileNumberSize(logfile_number_)); log_write_mutex_.Unlock(); } if (!s.ok()) { // how do we fail if we're not creating new log? assert(creating_new_log); assert(!new_mem); assert(!new_log); if (two_write_queues_) { nonmem_write_thread_.ExitUnbatched(&nonmem_w); } return s; } for (auto loop_cfd : *versions_->GetColumnFamilySet()) { // all this is just optimization to delete logs that // are no longer needed -- if CF is empty, that means it // doesn't need that particular log to stay alive, so we just // advance the log number. no need to persist this in the manifest if (loop_cfd->mem()->GetFirstSequenceNumber() == 0 && loop_cfd->imm()->NumNotFlushed() == 0) { if (creating_new_log) { loop_cfd->SetLogNumber(logfile_number_); } loop_cfd->mem()->SetCreationSeq(versions_->LastSequence()); } } cfd->mem()->SetNextLogNumber(logfile_number_); cfd->imm()->Add(cfd->mem(), &context->memtables_to_free_); new_mem->Ref(); cfd->SetMemtable(new_mem); InstallSuperVersionAndScheduleWork(cfd, &context->superversion_context, mutable_cf_options); if (two_write_queues_) { nonmem_write_thread_.ExitUnbatched(&nonmem_w); } return s; } size_t DBImpl::GetWalPreallocateBlockSize(uint64_t write_buffer_size) const { mutex_.AssertHeld(); size_t bsize = static_cast( write_buffer_size / 10 + write_buffer_size); // Some users might set very high write_buffer_size and rely on // max_total_wal_size or other parameters to control the WAL size. if (mutable_db_options_.max_total_wal_size > 0) { bsize = std::min(bsize, static_cast( mutable_db_options_.max_total_wal_size)); } if (immutable_db_options_.db_write_buffer_size > 0) { bsize = std::min(bsize, immutable_db_options_.db_write_buffer_size); } if (immutable_db_options_.write_buffer_manager && immutable_db_options_.write_buffer_manager->enabled()) { bsize = std::min( bsize, immutable_db_options_.write_buffer_manager->buffer_size()); } return bsize; } // Default implementations of convenience methods that subclasses of DB // can call if they wish Status DB::Put(const WriteOptions& opt, ColumnFamilyHandle* column_family, const Slice& key, const Slice& value) { // Pre-allocate size of write batch conservatively. // 8 bytes are taken by header, 4 bytes for count, 1 byte for type, // and we allocate 11 extra bytes for key length, as well as value length. WriteBatch batch(key.size() + value.size() + 24); Status s = batch.Put(column_family, key, value); if (!s.ok()) { return s; } return Write(opt, &batch); } Status DB::Delete(const WriteOptions& opt, ColumnFamilyHandle* column_family, const Slice& key) { WriteBatch batch; batch.Delete(column_family, key); return Write(opt, &batch); } Status DB::SingleDelete(const WriteOptions& opt, ColumnFamilyHandle* column_family, const Slice& key) { WriteBatch batch; batch.SingleDelete(column_family, key); return Write(opt, &batch); } Status DB::DeleteRange(const WriteOptions& opt, ColumnFamilyHandle* column_family, const Slice& begin_key, const Slice& end_key) { WriteBatch batch; batch.DeleteRange(column_family, begin_key, end_key); return Write(opt, &batch); } Status DB::Merge(const WriteOptions& opt, ColumnFamilyHandle* column_family, const Slice& key, const Slice& value) { WriteBatch batch; Status s = batch.Merge(column_family, key, value); if (!s.ok()) { return s; } return Write(opt, &batch); } } // namespace rocksdb