mirror of
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02443dd93f
Summary: This change is before a planned DBImpl change to ensure all sufficiently recent sequence numbers since Open are covered by SeqnoToTimeMapping (bug fix with existing test work-arounds). **Intended follow-up** However, I found enough issues with SeqnoToTimeMapping to warrant this PR first, including very small fixes in DB implementation related to API contract of SeqnoToTimeMapping. Functional fixes / changes: * This fixes some mishandling of boundary cases. For example, if the user decides to stop writing to DB, the last written sequence number would perpetually have its write time updated to "now" and would always be ineligible for migration to cold tier. Part of the problem is that the SeqnoToTimeMapping would return a seqno known to have been written before (immediately or otherwise) the requested time, but compaction_job.cc would include that seqno in the preserve/exclude set. That is fixed (in part) by adding one in compaction_job.cc * That problem was worse because a whole range of seqnos could be updated perpetually with new times in SeqnoToTimeMapping::Append (if no writes to DB). That logic was apparently optimized for GetOldestApproximateTime (now GetProximalTimeBeforeSeqno), which is not used in production, to the detriment of GetOldestSequenceNum (now GetProximalSeqnoBeforeTime), which is used in production. (Perhaps plans changed during development?) This is fixed in Append to optimize for accuracy of GetProximalSeqnoBeforeTime. (Unit tests added and updated.) * Related: SeqnoToTimeMapping did not have a clear contract about the relationships between seqnos and times, just the idea of a rough correspondence. Now the class description makes it clear that the write time of each recorded seqno comes before or at the associated time, to support getting best results for GetProximalSeqnoBeforeTime. And this makes it easier to make clear the contract of each API function. * Update `DBImpl::RecordSeqnoToTimeMapping()` to follow this ordering in gathering samples. Some part of these changes has required an expanded test work-around for the problem (see intended follow-up above) that the DB does not immediately ensure recent seqnos are covered by its mapping. These work-arounds will be removed with that planned work. An apparent compaction bug is revealed in PrecludeLastLevelTest::RangeDelsCauseFileEndpointsToOverlap, so that test is disabled. Filed GitHub issue #11909 Cosmetic / code safety things (not exhaustive): * Fix some confusing names. * `seqno_time_mapping` was used inconsistently in places. Now just `seqno_to_time_mapping` to correspond to class name. * Rename confusing `GetOldestSequenceNum` -> `GetProximalSeqnoBeforeTime` and `GetOldestApproximateTime` -> `GetProximalTimeBeforeSeqno`. Part of the motivation is that our times and seqnos here have the same underlying type, so we want to be clear about which is expected where to avoid mixing. * Rename `kUnknownSeqnoTime` to `kUnknownTimeBeforeAll` because the value is a bad choice for unknown if we ever add ProximalAfterBlah functions. * Arithmetic on SeqnoTimePair doesn't make sense except for delta encoding, so use better names / APIs with that in mind. * (OMG) Don't allow direct comparison between SeqnoTimePair and SequenceNumber. (There is no checking that it isn't compared against time by accident.) * A field name essentially matching the containing class name is a confusing pattern (`seqno_time_mapping_`). * Wrap calls to confusing (but useful) upper_bound and lower_bound functions to have clearer names and more code reuse. Pull Request resolved: https://github.com/facebook/rocksdb/pull/11905 Test Plan: GetOldestSequenceNum (now GetProximalSeqnoBeforeTime) and TruncateOldEntries were lacking unit tests, despite both being used in production (experimental feature). Added those and expanded others. Reviewed By: jowlyzhang Differential Revision: D49755592 Pulled By: pdillinger fbshipit-source-id: f72a3baac74d24b963c77e538bba89a7fc8dce51
795 lines
32 KiB
C++
795 lines
32 KiB
C++
// Copyright (c) Meta Platforms, Inc. and affiliates.
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//
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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//
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// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file. See the AUTHORS file for names of contributors.
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#include "db/compaction/compaction_outputs.h"
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#include "db/builder.h"
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namespace ROCKSDB_NAMESPACE {
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void CompactionOutputs::NewBuilder(const TableBuilderOptions& tboptions) {
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builder_.reset(NewTableBuilder(tboptions, file_writer_.get()));
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}
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Status CompactionOutputs::Finish(
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const Status& intput_status,
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const SeqnoToTimeMapping& seqno_to_time_mapping) {
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FileMetaData* meta = GetMetaData();
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assert(meta != nullptr);
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Status s = intput_status;
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if (s.ok()) {
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std::string seqno_to_time_mapping_str;
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seqno_to_time_mapping.Encode(
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seqno_to_time_mapping_str, meta->fd.smallest_seqno,
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meta->fd.largest_seqno, meta->file_creation_time);
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builder_->SetSeqnoTimeTableProperties(seqno_to_time_mapping_str,
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meta->oldest_ancester_time);
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s = builder_->Finish();
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} else {
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builder_->Abandon();
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}
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Status io_s = builder_->io_status();
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if (s.ok()) {
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s = io_s;
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} else {
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io_s.PermitUncheckedError();
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}
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const uint64_t current_bytes = builder_->FileSize();
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if (s.ok()) {
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meta->fd.file_size = current_bytes;
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meta->tail_size = builder_->GetTailSize();
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meta->marked_for_compaction = builder_->NeedCompact();
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meta->user_defined_timestamps_persisted = static_cast<bool>(
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builder_->GetTableProperties().user_defined_timestamps_persisted);
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}
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current_output().finished = true;
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stats_.bytes_written += current_bytes;
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stats_.num_output_files = outputs_.size();
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return s;
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}
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IOStatus CompactionOutputs::WriterSyncClose(const Status& input_status,
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SystemClock* clock,
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Statistics* statistics,
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bool use_fsync) {
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IOStatus io_s;
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if (input_status.ok()) {
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StopWatch sw(clock, statistics, COMPACTION_OUTFILE_SYNC_MICROS);
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io_s = file_writer_->Sync(use_fsync);
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}
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if (input_status.ok() && io_s.ok()) {
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io_s = file_writer_->Close();
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}
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if (input_status.ok() && io_s.ok()) {
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FileMetaData* meta = GetMetaData();
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meta->file_checksum = file_writer_->GetFileChecksum();
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meta->file_checksum_func_name = file_writer_->GetFileChecksumFuncName();
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}
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file_writer_.reset();
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return io_s;
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}
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bool CompactionOutputs::UpdateFilesToCutForTTLStates(
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const Slice& internal_key) {
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if (!files_to_cut_for_ttl_.empty()) {
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const InternalKeyComparator* icmp =
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&compaction_->column_family_data()->internal_comparator();
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if (cur_files_to_cut_for_ttl_ != -1) {
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// Previous key is inside the range of a file
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if (icmp->Compare(internal_key,
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files_to_cut_for_ttl_[cur_files_to_cut_for_ttl_]
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->largest.Encode()) > 0) {
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next_files_to_cut_for_ttl_ = cur_files_to_cut_for_ttl_ + 1;
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cur_files_to_cut_for_ttl_ = -1;
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return true;
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}
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} else {
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// Look for the key position
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while (next_files_to_cut_for_ttl_ <
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static_cast<int>(files_to_cut_for_ttl_.size())) {
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if (icmp->Compare(internal_key,
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files_to_cut_for_ttl_[next_files_to_cut_for_ttl_]
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->smallest.Encode()) >= 0) {
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if (icmp->Compare(internal_key,
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files_to_cut_for_ttl_[next_files_to_cut_for_ttl_]
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->largest.Encode()) <= 0) {
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// With in the current file
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cur_files_to_cut_for_ttl_ = next_files_to_cut_for_ttl_;
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return true;
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}
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// Beyond the current file
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next_files_to_cut_for_ttl_++;
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} else {
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// Still fall into the gap
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break;
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}
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}
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}
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}
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return false;
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}
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size_t CompactionOutputs::UpdateGrandparentBoundaryInfo(
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const Slice& internal_key) {
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size_t curr_key_boundary_switched_num = 0;
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const std::vector<FileMetaData*>& grandparents = compaction_->grandparents();
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if (grandparents.empty()) {
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return curr_key_boundary_switched_num;
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}
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const Comparator* ucmp = compaction_->column_family_data()->user_comparator();
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// Move the grandparent_index_ to the file containing the current user_key.
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// If there are multiple files containing the same user_key, make sure the
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// index points to the last file containing the key.
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while (grandparent_index_ < grandparents.size()) {
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if (being_grandparent_gap_) {
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if (sstableKeyCompare(ucmp, internal_key,
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grandparents[grandparent_index_]->smallest) < 0) {
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break;
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}
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if (seen_key_) {
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curr_key_boundary_switched_num++;
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grandparent_overlapped_bytes_ +=
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grandparents[grandparent_index_]->fd.GetFileSize();
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grandparent_boundary_switched_num_++;
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}
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being_grandparent_gap_ = false;
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} else {
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int cmp_result = sstableKeyCompare(
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ucmp, internal_key, grandparents[grandparent_index_]->largest);
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// If it's same key, make sure grandparent_index_ is pointing to the last
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// one.
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if (cmp_result < 0 ||
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(cmp_result == 0 &&
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(grandparent_index_ == grandparents.size() - 1 ||
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sstableKeyCompare(ucmp, internal_key,
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grandparents[grandparent_index_ + 1]->smallest) <
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0))) {
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break;
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}
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if (seen_key_) {
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curr_key_boundary_switched_num++;
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grandparent_boundary_switched_num_++;
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}
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being_grandparent_gap_ = true;
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grandparent_index_++;
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}
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}
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// If the first key is in the middle of a grandparent file, adding it to the
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// overlap
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if (!seen_key_ && !being_grandparent_gap_) {
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assert(grandparent_overlapped_bytes_ == 0);
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grandparent_overlapped_bytes_ =
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GetCurrentKeyGrandparentOverlappedBytes(internal_key);
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}
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seen_key_ = true;
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return curr_key_boundary_switched_num;
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}
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uint64_t CompactionOutputs::GetCurrentKeyGrandparentOverlappedBytes(
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const Slice& internal_key) const {
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// no overlap with any grandparent file
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if (being_grandparent_gap_) {
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return 0;
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}
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uint64_t overlapped_bytes = 0;
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const std::vector<FileMetaData*>& grandparents = compaction_->grandparents();
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const Comparator* ucmp = compaction_->column_family_data()->user_comparator();
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InternalKey ikey;
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ikey.DecodeFrom(internal_key);
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#ifndef NDEBUG
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// make sure the grandparent_index_ is pointing to the last files containing
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// the current key.
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int cmp_result =
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sstableKeyCompare(ucmp, ikey, grandparents[grandparent_index_]->largest);
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assert(
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cmp_result < 0 ||
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(cmp_result == 0 &&
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(grandparent_index_ == grandparents.size() - 1 ||
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sstableKeyCompare(
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ucmp, ikey, grandparents[grandparent_index_ + 1]->smallest) < 0)));
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assert(sstableKeyCompare(ucmp, ikey,
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grandparents[grandparent_index_]->smallest) >= 0);
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#endif
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overlapped_bytes += grandparents[grandparent_index_]->fd.GetFileSize();
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// go backwards to find all overlapped files, one key can overlap multiple
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// files. In the following example, if the current output key is `c`, and one
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// compaction file was cut before `c`, current `c` can overlap with 3 files:
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// [a b] [c...
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// [b, b] [c, c] [c, c] [c, d]
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for (int64_t i = static_cast<int64_t>(grandparent_index_) - 1;
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i >= 0 && sstableKeyCompare(ucmp, ikey, grandparents[i]->largest) == 0;
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i--) {
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overlapped_bytes += grandparents[i]->fd.GetFileSize();
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}
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return overlapped_bytes;
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}
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bool CompactionOutputs::ShouldStopBefore(const CompactionIterator& c_iter) {
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assert(c_iter.Valid());
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const Slice& internal_key = c_iter.key();
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#ifndef NDEBUG
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bool should_stop = false;
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std::pair<bool*, const Slice> p{&should_stop, internal_key};
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TEST_SYNC_POINT_CALLBACK(
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"CompactionOutputs::ShouldStopBefore::manual_decision", (void*)&p);
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if (should_stop) {
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return true;
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}
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#endif // NDEBUG
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const uint64_t previous_overlapped_bytes = grandparent_overlapped_bytes_;
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const InternalKeyComparator* icmp =
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&compaction_->column_family_data()->internal_comparator();
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size_t num_grandparent_boundaries_crossed = 0;
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bool should_stop_for_ttl = false;
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// Always update grandparent information like overlapped file number, size
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// etc., and TTL states.
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// If compaction_->output_level() == 0, there is no need to update grandparent
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// info, and that `grandparent` should be empty.
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if (compaction_->output_level() > 0) {
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num_grandparent_boundaries_crossed =
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UpdateGrandparentBoundaryInfo(internal_key);
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should_stop_for_ttl = UpdateFilesToCutForTTLStates(internal_key);
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}
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if (!HasBuilder()) {
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return false;
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}
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if (should_stop_for_ttl) {
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return true;
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}
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// If there's user defined partitioner, check that first
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if (partitioner_ && partitioner_->ShouldPartition(PartitionerRequest(
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last_key_for_partitioner_, c_iter.user_key(),
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current_output_file_size_)) == kRequired) {
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return true;
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}
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// files output to Level 0 won't be split
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if (compaction_->output_level() == 0) {
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return false;
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}
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// reach the max file size
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if (current_output_file_size_ >= compaction_->max_output_file_size()) {
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return true;
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}
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// Check if it needs to split for RoundRobin
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// Invalid local_output_split_key indicates that we do not need to split
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if (local_output_split_key_ != nullptr && !is_split_) {
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// Split occurs when the next key is larger than/equal to the cursor
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if (icmp->Compare(internal_key, local_output_split_key_->Encode()) >= 0) {
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is_split_ = true;
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return true;
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}
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}
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// only check if the current key is going to cross the grandparents file
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// boundary (either the file beginning or ending).
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if (num_grandparent_boundaries_crossed > 0) {
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// Cut the file before the current key if the size of the current output
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// file + its overlapped grandparent files is bigger than
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// max_compaction_bytes. Which is to prevent future bigger than
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// max_compaction_bytes compaction from the current output level.
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if (grandparent_overlapped_bytes_ + current_output_file_size_ >
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compaction_->max_compaction_bytes()) {
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return true;
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}
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// Cut the file if including the key is going to add a skippable file on
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// the grandparent level AND its size is reasonably big (1/8 of target file
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// size). For example, if it's compacting the files L0 + L1:
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// L0: [1, 21]
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// L1: [3, 23]
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// L2: [2, 4] [11, 15] [22, 24]
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// Without this break, it will output as:
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// L1: [1,3, 21,23]
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// With this break, it will output as (assuming [11, 15] at L2 is bigger
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// than 1/8 of target size):
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// L1: [1,3] [21,23]
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// Then for the future compactions, [11,15] won't be included.
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// For random datasets (either evenly distributed or skewed), it rarely
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// triggers this condition, but if the user is adding 2 different datasets
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// without any overlap, it may likely happen.
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// More details, check PR #1963
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const size_t num_skippable_boundaries_crossed =
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being_grandparent_gap_ ? 2 : 3;
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if (compaction_->immutable_options()->compaction_style ==
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kCompactionStyleLevel &&
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compaction_->immutable_options()->level_compaction_dynamic_file_size &&
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num_grandparent_boundaries_crossed >=
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num_skippable_boundaries_crossed &&
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grandparent_overlapped_bytes_ - previous_overlapped_bytes >
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compaction_->target_output_file_size() / 8) {
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return true;
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}
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// Pre-cut the output file if it's reaching a certain size AND it's at the
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// boundary of a grandparent file. It can reduce the future compaction size,
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// the cost is having smaller files.
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// The pre-cut size threshold is based on how many grandparent boundaries
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// it has seen before. Basically, if it has seen no boundary at all, then it
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// will pre-cut at 50% target file size. Every boundary it has seen
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// increases the threshold by 5%, max at 90%, which it will always cut.
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// The idea is based on if it has seen more boundaries before, it will more
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// likely to see another boundary (file cutting opportunity) before the
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// target file size. The test shows it can generate larger files than a
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// static threshold like 75% and has a similar write amplification
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// improvement.
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if (compaction_->immutable_options()->compaction_style ==
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kCompactionStyleLevel &&
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compaction_->immutable_options()->level_compaction_dynamic_file_size &&
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current_output_file_size_ >=
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((compaction_->target_output_file_size() + 99) / 100) *
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(50 + std::min(grandparent_boundary_switched_num_ * 5,
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size_t{40}))) {
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return true;
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}
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}
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return false;
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}
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Status CompactionOutputs::AddToOutput(
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const CompactionIterator& c_iter,
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const CompactionFileOpenFunc& open_file_func,
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const CompactionFileCloseFunc& close_file_func) {
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Status s;
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bool is_range_del = c_iter.IsDeleteRangeSentinelKey();
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if (is_range_del && compaction_->bottommost_level()) {
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// We don't consider range tombstone for bottommost level since:
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// 1. there is no grandparent and hence no overlap to consider
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// 2. range tombstone may be dropped at bottommost level.
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return s;
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}
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const Slice& key = c_iter.key();
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if (ShouldStopBefore(c_iter) && HasBuilder()) {
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s = close_file_func(*this, c_iter.InputStatus(), key);
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if (!s.ok()) {
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return s;
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}
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// reset grandparent information
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grandparent_boundary_switched_num_ = 0;
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grandparent_overlapped_bytes_ =
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GetCurrentKeyGrandparentOverlappedBytes(key);
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if (UNLIKELY(is_range_del)) {
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// lower bound for this new output file, this is needed as the lower bound
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// does not come from the smallest point key in this case.
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range_tombstone_lower_bound_.DecodeFrom(key);
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} else {
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range_tombstone_lower_bound_.Clear();
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}
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}
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// Open output file if necessary
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if (!HasBuilder()) {
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s = open_file_func(*this);
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if (!s.ok()) {
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return s;
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}
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}
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// c_iter may emit range deletion keys, so update `last_key_for_partitioner_`
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// here before returning below when `is_range_del` is true
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if (partitioner_) {
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last_key_for_partitioner_.assign(c_iter.user_key().data_,
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c_iter.user_key().size_);
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}
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if (UNLIKELY(is_range_del)) {
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return s;
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}
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assert(builder_ != nullptr);
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const Slice& value = c_iter.value();
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s = current_output().validator.Add(key, value);
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if (!s.ok()) {
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return s;
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}
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builder_->Add(key, value);
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stats_.num_output_records++;
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current_output_file_size_ = builder_->EstimatedFileSize();
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if (blob_garbage_meter_) {
|
|
s = blob_garbage_meter_->ProcessOutFlow(key, value);
|
|
}
|
|
|
|
if (!s.ok()) {
|
|
return s;
|
|
}
|
|
|
|
const ParsedInternalKey& ikey = c_iter.ikey();
|
|
s = current_output().meta.UpdateBoundaries(key, value, ikey.sequence,
|
|
ikey.type);
|
|
|
|
return s;
|
|
}
|
|
|
|
namespace {
|
|
void SetMaxSeqAndTs(InternalKey& internal_key, const Slice& user_key,
|
|
const size_t ts_sz) {
|
|
if (ts_sz) {
|
|
static constexpr char kTsMax[] = "\xff\xff\xff\xff\xff\xff\xff\xff\xff";
|
|
if (ts_sz <= strlen(kTsMax)) {
|
|
internal_key = InternalKey(user_key, kMaxSequenceNumber,
|
|
kTypeRangeDeletion, Slice(kTsMax, ts_sz));
|
|
} else {
|
|
internal_key =
|
|
InternalKey(user_key, kMaxSequenceNumber, kTypeRangeDeletion,
|
|
std::string(ts_sz, '\xff'));
|
|
}
|
|
} else {
|
|
internal_key.Set(user_key, kMaxSequenceNumber, kTypeRangeDeletion);
|
|
}
|
|
}
|
|
} // namespace
|
|
|
|
Status CompactionOutputs::AddRangeDels(
|
|
const Slice* comp_start_user_key, const Slice* comp_end_user_key,
|
|
CompactionIterationStats& range_del_out_stats, bool bottommost_level,
|
|
const InternalKeyComparator& icmp, SequenceNumber earliest_snapshot,
|
|
const Slice& next_table_min_key, const std::string& full_history_ts_low) {
|
|
// The following example does not happen since
|
|
// CompactionOutput::ShouldStopBefore() always return false for the first
|
|
// point key. But we should consider removing this dependency. Suppose for the
|
|
// first compaction output file,
|
|
// - next_table_min_key.user_key == comp_start_user_key
|
|
// - no point key is in the output file
|
|
// - there is a range tombstone @seqno to be added that covers
|
|
// comp_start_user_key
|
|
// Then meta.smallest will be set to comp_start_user_key@seqno
|
|
// and meta.largest will be set to comp_start_user_key@kMaxSequenceNumber
|
|
// which violates the assumption that meta.smallest should be <= meta.largest.
|
|
assert(HasRangeDel());
|
|
FileMetaData& meta = current_output().meta;
|
|
const Comparator* ucmp = icmp.user_comparator();
|
|
InternalKey lower_bound_buf, upper_bound_buf;
|
|
Slice lower_bound_guard, upper_bound_guard;
|
|
std::string smallest_user_key;
|
|
const Slice *lower_bound, *upper_bound;
|
|
|
|
// We first determine the internal key lower_bound and upper_bound for
|
|
// this output file. All and only range tombstones that overlap with
|
|
// [lower_bound, upper_bound] should be added to this file. File
|
|
// boundaries (meta.smallest/largest) should be updated accordingly when
|
|
// extended by range tombstones.
|
|
size_t output_size = outputs_.size();
|
|
if (output_size == 1) {
|
|
// This is the first file in the subcompaction.
|
|
//
|
|
// When outputting a range tombstone that spans a subcompaction boundary,
|
|
// the files on either side of that boundary need to include that
|
|
// boundary's user key. Otherwise, the spanning range tombstone would lose
|
|
// coverage.
|
|
//
|
|
// To achieve this while preventing files from overlapping in internal key
|
|
// (an LSM invariant violation), we allow the earlier file to include the
|
|
// boundary user key up to `kMaxSequenceNumber,kTypeRangeDeletion`. The
|
|
// later file can begin at the boundary user key at the newest key version
|
|
// it contains. At this point that version number is unknown since we have
|
|
// not processed the range tombstones yet, so permit any version. Same story
|
|
// applies to timestamp, and a non-nullptr `comp_start_user_key` should have
|
|
// `kMaxTs` here, which similarly permits any timestamp.
|
|
if (comp_start_user_key) {
|
|
lower_bound_buf.Set(*comp_start_user_key, kMaxSequenceNumber,
|
|
kTypeRangeDeletion);
|
|
lower_bound_guard = lower_bound_buf.Encode();
|
|
lower_bound = &lower_bound_guard;
|
|
} else {
|
|
lower_bound = nullptr;
|
|
}
|
|
} else {
|
|
// For subsequent output tables, only include range tombstones from min
|
|
// key onwards since the previous file was extended to contain range
|
|
// tombstones falling before min key.
|
|
if (range_tombstone_lower_bound_.size() > 0) {
|
|
assert(meta.smallest.size() == 0 ||
|
|
icmp.Compare(range_tombstone_lower_bound_, meta.smallest) < 0);
|
|
lower_bound_guard = range_tombstone_lower_bound_.Encode();
|
|
} else {
|
|
assert(meta.smallest.size() > 0);
|
|
lower_bound_guard = meta.smallest.Encode();
|
|
}
|
|
lower_bound = &lower_bound_guard;
|
|
}
|
|
|
|
const size_t ts_sz = ucmp->timestamp_size();
|
|
if (next_table_min_key.empty()) {
|
|
// Last file of the subcompaction.
|
|
if (comp_end_user_key) {
|
|
upper_bound_buf.Set(*comp_end_user_key, kMaxSequenceNumber,
|
|
kTypeRangeDeletion);
|
|
upper_bound_guard = upper_bound_buf.Encode();
|
|
upper_bound = &upper_bound_guard;
|
|
} else {
|
|
upper_bound = nullptr;
|
|
}
|
|
} else {
|
|
// There is another file coming whose coverage will begin at
|
|
// `next_table_min_key`. The current file needs to extend range tombstone
|
|
// coverage through its own keys (through `meta.largest`) and through user
|
|
// keys preceding `next_table_min_key`'s user key.
|
|
ParsedInternalKey next_table_min_key_parsed;
|
|
ParseInternalKey(next_table_min_key, &next_table_min_key_parsed,
|
|
false /* log_err_key */)
|
|
.PermitUncheckedError();
|
|
assert(next_table_min_key_parsed.sequence < kMaxSequenceNumber);
|
|
assert(meta.largest.size() == 0 ||
|
|
icmp.Compare(meta.largest.Encode(), next_table_min_key) < 0);
|
|
assert(!lower_bound || icmp.Compare(*lower_bound, next_table_min_key) <= 0);
|
|
if (meta.largest.size() > 0 &&
|
|
ucmp->EqualWithoutTimestamp(meta.largest.user_key(),
|
|
next_table_min_key_parsed.user_key)) {
|
|
// Caution: this assumes meta.largest.Encode() lives longer than
|
|
// upper_bound, which is only true if meta.largest is never updated.
|
|
// This just happens to be the case here since meta.largest serves
|
|
// as the upper_bound.
|
|
upper_bound_guard = meta.largest.Encode();
|
|
} else {
|
|
SetMaxSeqAndTs(upper_bound_buf, next_table_min_key_parsed.user_key,
|
|
ts_sz);
|
|
upper_bound_guard = upper_bound_buf.Encode();
|
|
}
|
|
upper_bound = &upper_bound_guard;
|
|
}
|
|
if (lower_bound && upper_bound &&
|
|
icmp.Compare(*lower_bound, *upper_bound) > 0) {
|
|
assert(meta.smallest.size() == 0 &&
|
|
ucmp->EqualWithoutTimestamp(ExtractUserKey(*lower_bound),
|
|
ExtractUserKey(*upper_bound)));
|
|
// This can only happen when lower_bound have the same user key as
|
|
// next_table_min_key and that there is no point key in the current
|
|
// compaction output file.
|
|
return Status::OK();
|
|
}
|
|
// The end key of the subcompaction must be bigger or equal to the upper
|
|
// bound. If the end of subcompaction is null or the upper bound is null,
|
|
// it means that this file is the last file in the compaction. So there
|
|
// will be no overlapping between this file and others.
|
|
assert(comp_end_user_key == nullptr || upper_bound == nullptr ||
|
|
ucmp->CompareWithoutTimestamp(ExtractUserKey(*upper_bound),
|
|
*comp_end_user_key) <= 0);
|
|
auto it = range_del_agg_->NewIterator(lower_bound, upper_bound);
|
|
Slice last_tombstone_start_user_key{};
|
|
bool reached_lower_bound = false;
|
|
const ReadOptions read_options(Env::IOActivity::kCompaction);
|
|
for (it->SeekToFirst(); it->Valid(); it->Next()) {
|
|
auto tombstone = it->Tombstone();
|
|
auto kv = tombstone.Serialize();
|
|
InternalKey tombstone_end = tombstone.SerializeEndKey();
|
|
// TODO: the underlying iterator should support clamping the bounds.
|
|
// tombstone_end.Encode is of form user_key@kMaxSeqno
|
|
// if it is equal to lower_bound, there is no need to include
|
|
// such range tombstone.
|
|
if (!reached_lower_bound && lower_bound &&
|
|
icmp.Compare(tombstone_end.Encode(), *lower_bound) <= 0) {
|
|
continue;
|
|
}
|
|
assert(!lower_bound ||
|
|
icmp.Compare(*lower_bound, tombstone_end.Encode()) <= 0);
|
|
reached_lower_bound = true;
|
|
|
|
// Garbage collection for range tombstones.
|
|
// If user-defined timestamp is enabled, range tombstones are dropped if
|
|
// they are at bottommost_level, below full_history_ts_low and not visible
|
|
// in any snapshot. trim_ts_ is passed to the constructor for
|
|
// range_del_agg_, and range_del_agg_ internally drops tombstones above
|
|
// trim_ts_.
|
|
bool consider_drop =
|
|
tombstone.seq_ <= earliest_snapshot &&
|
|
(ts_sz == 0 ||
|
|
(!full_history_ts_low.empty() &&
|
|
ucmp->CompareTimestamp(tombstone.ts_, full_history_ts_low) < 0));
|
|
if (consider_drop && bottommost_level) {
|
|
// TODO(andrewkr): tombstones that span multiple output files are
|
|
// counted for each compaction output file, so lots of double
|
|
// counting.
|
|
range_del_out_stats.num_range_del_drop_obsolete++;
|
|
range_del_out_stats.num_record_drop_obsolete++;
|
|
continue;
|
|
}
|
|
|
|
assert(lower_bound == nullptr ||
|
|
ucmp->CompareWithoutTimestamp(ExtractUserKey(*lower_bound),
|
|
kv.second) < 0);
|
|
InternalKey tombstone_start = kv.first;
|
|
if (lower_bound &&
|
|
ucmp->CompareWithoutTimestamp(tombstone_start.user_key(),
|
|
ExtractUserKey(*lower_bound)) < 0) {
|
|
// This just updates the non-timestamp portion of `tombstone_start`'s user
|
|
// key. Ideally there would be a simpler API usage
|
|
ParsedInternalKey tombstone_start_parsed;
|
|
ParseInternalKey(tombstone_start.Encode(), &tombstone_start_parsed,
|
|
false /* log_err_key */)
|
|
.PermitUncheckedError();
|
|
// timestamp should be from where sequence number is from, which is from
|
|
// tombstone in this case
|
|
std::string ts =
|
|
tombstone_start_parsed.GetTimestamp(ucmp->timestamp_size())
|
|
.ToString();
|
|
tombstone_start_parsed.user_key = ExtractUserKey(*lower_bound);
|
|
tombstone_start.SetFrom(tombstone_start_parsed, ts);
|
|
}
|
|
if (upper_bound != nullptr &&
|
|
icmp.Compare(*upper_bound, tombstone_start.Encode()) < 0) {
|
|
break;
|
|
}
|
|
if (lower_bound &&
|
|
icmp.Compare(tombstone_start.Encode(), *lower_bound) < 0) {
|
|
tombstone_start.DecodeFrom(*lower_bound);
|
|
}
|
|
if (upper_bound && icmp.Compare(*upper_bound, tombstone_end.Encode()) < 0) {
|
|
tombstone_end.DecodeFrom(*upper_bound);
|
|
}
|
|
if (consider_drop && compaction_->KeyRangeNotExistsBeyondOutputLevel(
|
|
tombstone_start.user_key(),
|
|
tombstone_end.user_key(), &level_ptrs_)) {
|
|
range_del_out_stats.num_range_del_drop_obsolete++;
|
|
range_del_out_stats.num_record_drop_obsolete++;
|
|
continue;
|
|
}
|
|
// Here we show that *only* range tombstones that overlap with
|
|
// [lower_bound, upper_bound] are added to the current file, and
|
|
// sanity checking invariants that should hold:
|
|
// - [tombstone_start, tombstone_end] overlaps with [lower_bound,
|
|
// upper_bound]
|
|
// - meta.smallest <= meta.largest
|
|
// Corresponding assertions are made, the proof is broken is any of them
|
|
// fails.
|
|
// TODO: show that *all* range tombstones that overlap with
|
|
// [lower_bound, upper_bound] are added.
|
|
// TODO: some invariant about boundaries are correctly updated.
|
|
//
|
|
// Note that `tombstone_start` is updated in the if condition above, we use
|
|
// tombstone_start to refer to its initial value, i.e.,
|
|
// it->Tombstone().first, and use tombstone_start* to refer to its value
|
|
// after the update.
|
|
//
|
|
// To show [lower_bound, upper_bound] overlaps with [tombstone_start,
|
|
// tombstone_end]:
|
|
// lower_bound <= upper_bound from the if condition right after all
|
|
// bounds are initialized. We assume each tombstone fragment has
|
|
// start_key.user_key < end_key.user_key, so
|
|
// tombstone_start < tombstone_end by
|
|
// FragmentedTombstoneIterator::Tombstone(). So these two ranges are both
|
|
// non-emtpy. The flag `reached_lower_bound` and the if logic before it
|
|
// ensures lower_bound <= tombstone_end. tombstone_start is only updated
|
|
// if it has a smaller user_key than lower_bound user_key, so
|
|
// tombstone_start <= tombstone_start*. The above if condition implies
|
|
// tombstone_start* <= upper_bound. So we have
|
|
// tombstone_start <= upper_bound and lower_bound <= tombstone_end
|
|
// and the two ranges overlap.
|
|
//
|
|
// To show meta.smallest <= meta.largest:
|
|
// From the implementation of UpdateBoundariesForRange(), it suffices to
|
|
// prove that when it is first called in this function, its parameters
|
|
// satisfy `start <= end`, where start = max(tombstone_start*, lower_bound)
|
|
// and end = min(tombstone_end, upper_bound). From the above proof we have
|
|
// lower_bound <= tombstone_end and lower_bound <= upper_bound. We only need
|
|
// to show that tombstone_start* <= min(tombstone_end, upper_bound).
|
|
// Note that tombstone_start*.user_key = max(tombstone_start.user_key,
|
|
// lower_bound.user_key). Assuming tombstone_end always has
|
|
// kMaxSequenceNumber and lower_bound.seqno < kMaxSequenceNumber.
|
|
// Since lower_bound <= tombstone_end and lower_bound.seqno <
|
|
// tombstone_end.seqno (in absolute number order, not internal key order),
|
|
// lower_bound.user_key < tombstone_end.user_key.
|
|
// Since lower_bound.user_key < tombstone_end.user_key and
|
|
// tombstone_start.user_key < tombstone_end.user_key, tombstone_start* <
|
|
// tombstone_end. Since tombstone_start* <= upper_bound from the above proof
|
|
// and tombstone_start* < tombstone_end, tombstone_start* <=
|
|
// min(tombstone_end, upper_bound), so the two ranges overlap.
|
|
|
|
// Range tombstone is not supported by output validator yet.
|
|
builder_->Add(kv.first.Encode(), kv.second);
|
|
assert(icmp.Compare(tombstone_start, tombstone_end) <= 0);
|
|
meta.UpdateBoundariesForRange(tombstone_start, tombstone_end,
|
|
tombstone.seq_, icmp);
|
|
if (!bottommost_level) {
|
|
bool start_user_key_changed =
|
|
last_tombstone_start_user_key.empty() ||
|
|
ucmp->CompareWithoutTimestamp(last_tombstone_start_user_key,
|
|
it->start_key()) < 0;
|
|
last_tombstone_start_user_key = it->start_key();
|
|
if (start_user_key_changed) {
|
|
// If tombstone_start >= tombstone_end, then either no key range is
|
|
// covered, or that they have the same user key. If they have the same
|
|
// user key, then the internal key range should only be within this
|
|
// level, and no keys from older levels is covered.
|
|
if (ucmp->CompareWithoutTimestamp(tombstone_start.user_key(),
|
|
tombstone_end.user_key()) < 0) {
|
|
SizeApproximationOptions approx_opts;
|
|
approx_opts.files_size_error_margin = 0.1;
|
|
auto approximate_covered_size =
|
|
compaction_->input_version()->version_set()->ApproximateSize(
|
|
approx_opts, read_options, compaction_->input_version(),
|
|
tombstone_start.Encode(), tombstone_end.Encode(),
|
|
compaction_->output_level() + 1 /* start_level */,
|
|
-1 /* end_level */, kCompaction);
|
|
meta.compensated_range_deletion_size += approximate_covered_size;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
return Status::OK();
|
|
}
|
|
|
|
void CompactionOutputs::FillFilesToCutForTtl() {
|
|
if (compaction_->immutable_options()->compaction_style !=
|
|
kCompactionStyleLevel ||
|
|
compaction_->immutable_options()->compaction_pri !=
|
|
kMinOverlappingRatio ||
|
|
compaction_->mutable_cf_options()->ttl == 0 ||
|
|
compaction_->num_input_levels() < 2 || compaction_->bottommost_level()) {
|
|
return;
|
|
}
|
|
|
|
// We define new file with the oldest ancestor time to be younger than 1/4
|
|
// TTL, and an old one to be older than 1/2 TTL time.
|
|
int64_t temp_current_time;
|
|
auto get_time_status =
|
|
compaction_->immutable_options()->clock->GetCurrentTime(
|
|
&temp_current_time);
|
|
if (!get_time_status.ok()) {
|
|
return;
|
|
}
|
|
|
|
auto current_time = static_cast<uint64_t>(temp_current_time);
|
|
if (current_time < compaction_->mutable_cf_options()->ttl) {
|
|
return;
|
|
}
|
|
|
|
uint64_t old_age_thres =
|
|
current_time - compaction_->mutable_cf_options()->ttl / 2;
|
|
const std::vector<FileMetaData*>& olevel =
|
|
*(compaction_->inputs(compaction_->num_input_levels() - 1));
|
|
for (FileMetaData* file : olevel) {
|
|
// Worth filtering out by start and end?
|
|
uint64_t oldest_ancester_time = file->TryGetOldestAncesterTime();
|
|
// We put old files if they are not too small to prevent a flood
|
|
// of small files.
|
|
if (oldest_ancester_time < old_age_thres &&
|
|
file->fd.GetFileSize() >
|
|
compaction_->mutable_cf_options()->target_file_size_base / 2) {
|
|
files_to_cut_for_ttl_.push_back(file);
|
|
}
|
|
}
|
|
}
|
|
|
|
CompactionOutputs::CompactionOutputs(const Compaction* compaction,
|
|
const bool is_penultimate_level)
|
|
: compaction_(compaction), is_penultimate_level_(is_penultimate_level) {
|
|
partitioner_ = compaction->output_level() == 0
|
|
? nullptr
|
|
: compaction->CreateSstPartitioner();
|
|
|
|
if (compaction->output_level() != 0) {
|
|
FillFilesToCutForTtl();
|
|
}
|
|
|
|
level_ptrs_ = std::vector<size_t>(compaction_->number_levels(), 0);
|
|
}
|
|
|
|
} // namespace ROCKSDB_NAMESPACE
|