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23fa5b7789
Summary: To make it consistent with the compaction picker which uses the `sstableKeyCompare()` to pick the overlap files. For example, without this change, it may cut L1 files like: ``` L1: [2-21] [22-30] L2: [1-10] [21-30] ``` Because "21" on L1 is smaller than "21" on L2. But for compaction, these 2 files are overlapped. `sstableKeyCompare()` also take range delete into consideration which may cut file for the same key. It also makes the `max_compaction_bytes` calculation more accurate for cases like above, the overlapped bytes was under estimated. Also make sure the 2 keys won't be splitted to 2 files because of reaching `max_compaction_bytes`. Pull Request resolved: https://github.com/facebook/rocksdb/pull/10763 Reviewed By: cbi42 Differential Revision: D39971904 Pulled By: cbi42 fbshipit-source-id: bcc309e9c3dc61a8f50667a6f633e6132c0154a8
647 lines
25 KiB
C++
647 lines
25 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(const Status& intput_status,
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const SeqnoToTimeMapping& seqno_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_time_mapping_str;
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seqno_time_mapping.Encode(seqno_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_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->marked_for_compaction = builder_->NeedCompact();
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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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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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assert(!internal_key.empty());
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InternalKey ikey;
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ikey.DecodeFrom(internal_key);
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assert(ikey.Valid());
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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, ikey,
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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, ikey, 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, ikey,
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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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// always update grandparent information like overlapped file number, size
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// etc.
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const Slice& internal_key = c_iter.key();
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const uint64_t previous_overlapped_bytes = grandparent_overlapped_bytes_;
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size_t num_grandparent_boundaries_crossed =
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UpdateGrandparentBoundaryInfo(internal_key);
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if (!HasBuilder()) {
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return false;
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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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const InternalKeyComparator* icmp =
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&compaction_->column_family_data()->internal_comparator();
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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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// check ttl file boundaries if there's any
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if (!files_to_cut_for_ttl_.empty()) {
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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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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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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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}
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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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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_) {
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s = blob_garbage_meter_->ProcessOutFlow(key, value);
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}
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if (!s.ok()) {
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return s;
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}
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const ParsedInternalKey& ikey = c_iter.ikey();
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s = current_output().meta.UpdateBoundaries(key, value, ikey.sequence,
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ikey.type);
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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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return s;
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}
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Status CompactionOutputs::AddRangeDels(
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const Slice* comp_start_user_key, const Slice* comp_end_user_key,
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CompactionIterationStats& range_del_out_stats, bool bottommost_level,
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const InternalKeyComparator& icmp, SequenceNumber earliest_snapshot,
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const Slice& next_table_min_key, const std::string& full_history_ts_low) {
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assert(HasRangeDel());
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FileMetaData& meta = current_output().meta;
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const Comparator* ucmp = icmp.user_comparator();
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Slice lower_bound_guard, upper_bound_guard;
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std::string smallest_user_key;
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const Slice *lower_bound, *upper_bound;
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bool lower_bound_from_sub_compact = false;
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size_t output_size = outputs_.size();
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if (output_size == 1) {
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// For the first output table, include range tombstones before the min
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// key but after the subcompaction boundary.
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lower_bound = comp_start_user_key;
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lower_bound_from_sub_compact = true;
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} else if (meta.smallest.size() > 0) {
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// For subsequent output tables, only include range tombstones from min
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// key onwards since the previous file was extended to contain range
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// tombstones falling before min key.
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smallest_user_key = meta.smallest.user_key().ToString(false /*hex*/);
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lower_bound_guard = Slice(smallest_user_key);
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lower_bound = &lower_bound_guard;
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} else {
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lower_bound = nullptr;
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}
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if (!next_table_min_key.empty()) {
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// This may be the last file in the subcompaction in some cases, so we
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// need to compare the end key of subcompaction with the next file start
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// key. When the end key is chosen by the subcompaction, we know that
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// it must be the biggest key in output file. Therefore, it is safe to
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// use the smaller key as the upper bound of the output file, to ensure
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// that there is no overlapping between different output files.
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upper_bound_guard = ExtractUserKey(next_table_min_key);
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if (comp_end_user_key != nullptr &&
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ucmp->CompareWithoutTimestamp(upper_bound_guard, *comp_end_user_key) >=
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0) {
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upper_bound = comp_end_user_key;
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} else {
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upper_bound = &upper_bound_guard;
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}
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} else {
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// This is the last file in the subcompaction, so extend until the
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// subcompaction ends.
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upper_bound = comp_end_user_key;
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}
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bool has_overlapping_endpoints;
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if (upper_bound != nullptr && meta.largest.size() > 0) {
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has_overlapping_endpoints = ucmp->CompareWithoutTimestamp(
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meta.largest.user_key(), *upper_bound) == 0;
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} else {
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has_overlapping_endpoints = false;
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}
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// The end key of the subcompaction must be bigger or equal to the upper
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// bound. If the end of subcompaction is null or the upper bound is null,
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// it means that this file is the last file in the compaction. So there
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// will be no overlapping between this file and others.
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assert(comp_end_user_key == nullptr || upper_bound == nullptr ||
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ucmp->CompareWithoutTimestamp(*upper_bound, *comp_end_user_key) <= 0);
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auto it = range_del_agg_->NewIterator(lower_bound, upper_bound,
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has_overlapping_endpoints);
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// Position the range tombstone output iterator. There may be tombstone
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// fragments that are entirely out of range, so make sure that we do not
|
|
// include those.
|
|
if (lower_bound != nullptr) {
|
|
it->Seek(*lower_bound);
|
|
} else {
|
|
it->SeekToFirst();
|
|
}
|
|
for (; it->Valid(); it->Next()) {
|
|
auto tombstone = it->Tombstone();
|
|
if (upper_bound != nullptr) {
|
|
int cmp =
|
|
ucmp->CompareWithoutTimestamp(*upper_bound, tombstone.start_key_);
|
|
if ((has_overlapping_endpoints && cmp < 0) ||
|
|
(!has_overlapping_endpoints && cmp <= 0)) {
|
|
// Tombstones starting after upper_bound only need to be included in
|
|
// the next table. If the current SST ends before upper_bound, i.e.,
|
|
// `has_overlapping_endpoints == false`, we can also skip over range
|
|
// tombstones that start exactly at upper_bound. Such range
|
|
// tombstones will be included in the next file and are not relevant
|
|
// to the point keys or endpoints of the current file.
|
|
break;
|
|
}
|
|
}
|
|
|
|
const size_t ts_sz = ucmp->timestamp_size();
|
|
// 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_.
|
|
if (bottommost_level && tombstone.seq_ <= earliest_snapshot &&
|
|
(ts_sz == 0 ||
|
|
(!full_history_ts_low.empty() &&
|
|
ucmp->CompareTimestamp(tombstone.ts_, full_history_ts_low) < 0))) {
|
|
// 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;
|
|
}
|
|
|
|
auto kv = tombstone.Serialize();
|
|
assert(lower_bound == nullptr ||
|
|
ucmp->CompareWithoutTimestamp(*lower_bound, kv.second) < 0);
|
|
// Range tombstone is not supported by output validator yet.
|
|
builder_->Add(kv.first.Encode(), kv.second);
|
|
InternalKey smallest_candidate = std::move(kv.first);
|
|
if (lower_bound != nullptr &&
|
|
ucmp->CompareWithoutTimestamp(smallest_candidate.user_key(),
|
|
*lower_bound) <= 0) {
|
|
// Pretend the smallest key has the same user key as lower_bound
|
|
// (the max key in the previous table or subcompaction) in order for
|
|
// files to appear key-space partitioned.
|
|
//
|
|
// When lower_bound is chosen by a subcompaction, we know that
|
|
// subcompactions over smaller keys cannot contain any keys at
|
|
// lower_bound. We also know that smaller subcompactions exist,
|
|
// because otherwise the subcompaction woud be unbounded on the left.
|
|
// As a result, we know that no other files on the output level will
|
|
// contain actual keys at lower_bound (an output file may have a
|
|
// largest key of lower_bound@kMaxSequenceNumber, but this only
|
|
// indicates a large range tombstone was truncated). Therefore, it is
|
|
// safe to use the tombstone's sequence number, to ensure that keys at
|
|
// lower_bound at lower levels are covered by truncated tombstones.
|
|
//
|
|
// If lower_bound was chosen by the smallest data key in the file,
|
|
// choose lowest seqnum so this file's smallest internal key comes
|
|
// after the previous file's largest. The fake seqnum is OK because
|
|
// the read path's file-picking code only considers user key.
|
|
if (lower_bound_from_sub_compact) {
|
|
if (ts_sz) {
|
|
assert(tombstone.ts_.size() == ts_sz);
|
|
smallest_candidate = InternalKey(*lower_bound, tombstone.seq_,
|
|
kTypeRangeDeletion, tombstone.ts_);
|
|
} else {
|
|
smallest_candidate =
|
|
InternalKey(*lower_bound, tombstone.seq_, kTypeRangeDeletion);
|
|
}
|
|
} else {
|
|
smallest_candidate = InternalKey(*lower_bound, 0, kTypeRangeDeletion);
|
|
}
|
|
}
|
|
InternalKey largest_candidate = tombstone.SerializeEndKey();
|
|
if (upper_bound != nullptr &&
|
|
ucmp->CompareWithoutTimestamp(*upper_bound,
|
|
largest_candidate.user_key()) <= 0) {
|
|
// Pretend the largest key has the same user key as upper_bound (the
|
|
// min key in the following table or subcompaction) in order for files
|
|
// to appear key-space partitioned.
|
|
//
|
|
// Choose highest seqnum so this file's largest internal key comes
|
|
// before the next file's/subcompaction's smallest. The fake seqnum is
|
|
// OK because the read path's file-picking code only considers the
|
|
// user key portion.
|
|
//
|
|
// Note Seek() also creates InternalKey with (user_key,
|
|
// kMaxSequenceNumber), but with kTypeDeletion (0x7) instead of
|
|
// kTypeRangeDeletion (0xF), so the range tombstone comes before the
|
|
// Seek() key in InternalKey's ordering. So Seek() will look in the
|
|
// next file for the user key
|
|
if (ts_sz) {
|
|
static constexpr char kTsMax[] = "\xff\xff\xff\xff\xff\xff\xff\xff\xff";
|
|
if (ts_sz <= strlen(kTsMax)) {
|
|
largest_candidate =
|
|
InternalKey(*upper_bound, kMaxSequenceNumber, kTypeRangeDeletion,
|
|
Slice(kTsMax, ts_sz));
|
|
} else {
|
|
largest_candidate =
|
|
InternalKey(*upper_bound, kMaxSequenceNumber, kTypeRangeDeletion,
|
|
std::string(ts_sz, '\xff'));
|
|
}
|
|
} else {
|
|
largest_candidate =
|
|
InternalKey(*upper_bound, kMaxSequenceNumber, kTypeRangeDeletion);
|
|
}
|
|
}
|
|
#ifndef NDEBUG
|
|
SequenceNumber smallest_ikey_seqnum = kMaxSequenceNumber;
|
|
if (meta.smallest.size() > 0) {
|
|
smallest_ikey_seqnum = GetInternalKeySeqno(meta.smallest.Encode());
|
|
}
|
|
#endif
|
|
meta.UpdateBoundariesForRange(smallest_candidate, largest_candidate,
|
|
tombstone.seq_, icmp);
|
|
// The smallest key in a file is used for range tombstone truncation, so
|
|
// it cannot have a seqnum of 0 (unless the smallest data key in a file
|
|
// has a seqnum of 0). Otherwise, the truncated tombstone may expose
|
|
// deleted keys at lower levels.
|
|
assert(smallest_ikey_seqnum == 0 ||
|
|
ExtractInternalKeyFooter(meta.smallest.Encode()) !=
|
|
PackSequenceAndType(0, kTypeRangeDeletion));
|
|
}
|
|
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();
|
|
}
|
|
}
|
|
|
|
} // namespace ROCKSDB_NAMESPACE
|