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49a10feb21
Summary: In FilePrefetchBuffer if reads are sequential, after prefetching call ReadAsync API to prefetch data asynchronously so that in next prefetching data will be available. Data prefetched asynchronously will be readahead_size/2. It uses two buffers, one for synchronous prefetching and one for asynchronous. In case, the data is overlapping, the data is copied from both buffers to third buffer to make it continuous. This feature is under ReadOptions::async_io and is under experimental. Pull Request resolved: https://github.com/facebook/rocksdb/pull/9674 Test Plan: 1. Add new unit tests 2. Run **db_stress** to make sure nothing crashes. - Normal prefetch without `async_io` ran successfully: ``` export CRASH_TEST_EXT_ARGS=" --async_io=0" make crash_test -j ``` 3. **Run Regressions**. i) Main branch without any change for normal prefetching with async_io disabled: ``` ./db_bench -db=/tmp/prefix_scan_prefetch_main -benchmarks="fillseq" -key_size=32 -value_size=512 -num=5000000 - use_direct_io_for_flush_and_compaction=true -target_file_size_base=16777216 ``` ``` ./db_bench -use_existing_db=true -db=/tmp/prefix_scan_prefetch_main -benchmarks="seekrandom" -key_size=32 -value_size=512 -num=5000000 -use_direct_reads=true -seek_nexts=327680 -duration=120 -ops_between_duration_checks=1 Initializing RocksDB Options from the specified file Initializing RocksDB Options from command-line flags RocksDB: version 7.0 Date: Thu Mar 17 13:11:34 2022 CPU: 24 * Intel Core Processor (Broadwell) CPUCache: 16384 KB Keys: 32 bytes each (+ 0 bytes user-defined timestamp) Values: 512 bytes each (256 bytes after compression) Entries: 5000000 Prefix: 0 bytes Keys per prefix: 0 RawSize: 2594.0 MB (estimated) FileSize: 1373.3 MB (estimated) Write rate: 0 bytes/second Read rate: 0 ops/second Compression: Snappy Compression sampling rate: 0 Memtablerep: SkipListFactory Perf Level: 1 ------------------------------------------------ DB path: [/tmp/prefix_scan_prefetch_main] seekrandom : 483618.390 micros/op 2 ops/sec; 338.9 MB/s (249 of 249 found) ``` ii) normal prefetching after changes with async_io disable: ``` ./db_bench -use_existing_db=true -db=/tmp/prefix_scan_prefetch_withchange -benchmarks="seekrandom" -key_size=32 -value_size=512 -num=5000000 -use_direct_reads=true -seek_nexts=327680 -duration=120 -ops_between_duration_checks=1 Initializing RocksDB Options from the specified file Initializing RocksDB Options from command-line flags RocksDB: version 7.0 Date: Thu Mar 17 14:11:31 2022 CPU: 24 * Intel Core Processor (Broadwell) CPUCache: 16384 KB Keys: 32 bytes each (+ 0 bytes user-defined timestamp) Values: 512 bytes each (256 bytes after compression) Entries: 5000000 Prefix: 0 bytes Keys per prefix: 0 RawSize: 2594.0 MB (estimated) FileSize: 1373.3 MB (estimated) Write rate: 0 bytes/second Read rate: 0 ops/second Compression: Snappy Compression sampling rate: 0 Memtablerep: SkipListFactory Perf Level: 1 ------------------------------------------------ DB path: [/tmp/prefix_scan_prefetch_withchange] seekrandom : 471347.227 micros/op 2 ops/sec; 348.1 MB/s (255 of 255 found) ``` Reviewed By: anand1976 Differential Revision: D34731543 Pulled By: akankshamahajan15 fbshipit-source-id: 8e23aa93453d5fe3c672b9231ad582f60207937f
383 lines
12 KiB
C++
383 lines
12 KiB
C++
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
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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 "table/block_based/block_based_table_iterator.h"
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namespace ROCKSDB_NAMESPACE {
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void BlockBasedTableIterator::Seek(const Slice& target) { SeekImpl(&target); }
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void BlockBasedTableIterator::SeekToFirst() { SeekImpl(nullptr); }
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void BlockBasedTableIterator::SeekImpl(const Slice* target) {
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is_out_of_bound_ = false;
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is_at_first_key_from_index_ = false;
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if (target && !CheckPrefixMayMatch(*target, IterDirection::kForward)) {
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ResetDataIter();
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return;
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}
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bool need_seek_index = true;
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if (block_iter_points_to_real_block_ && block_iter_.Valid()) {
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// Reseek.
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prev_block_offset_ = index_iter_->value().handle.offset();
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if (target) {
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// We can avoid an index seek if:
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// 1. The new seek key is larger than the current key
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// 2. The new seek key is within the upper bound of the block
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// Since we don't necessarily know the internal key for either
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// the current key or the upper bound, we check user keys and
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// exclude the equality case. Considering internal keys can
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// improve for the boundary cases, but it would complicate the
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// code.
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if (user_comparator_.Compare(ExtractUserKey(*target),
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block_iter_.user_key()) > 0 &&
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user_comparator_.Compare(ExtractUserKey(*target),
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index_iter_->user_key()) < 0) {
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need_seek_index = false;
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}
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}
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}
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if (need_seek_index) {
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if (target) {
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index_iter_->Seek(*target);
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} else {
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index_iter_->SeekToFirst();
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}
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if (!index_iter_->Valid()) {
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ResetDataIter();
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return;
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}
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}
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IndexValue v = index_iter_->value();
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const bool same_block = block_iter_points_to_real_block_ &&
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v.handle.offset() == prev_block_offset_;
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if (!v.first_internal_key.empty() && !same_block &&
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(!target || icomp_.Compare(*target, v.first_internal_key) <= 0) &&
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allow_unprepared_value_) {
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// Index contains the first key of the block, and it's >= target.
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// We can defer reading the block.
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is_at_first_key_from_index_ = true;
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// ResetDataIter() will invalidate block_iter_. Thus, there is no need to
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// call CheckDataBlockWithinUpperBound() to check for iterate_upper_bound
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// as that will be done later when the data block is actually read.
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ResetDataIter();
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} else {
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// Need to use the data block.
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if (!same_block) {
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InitDataBlock();
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} else {
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// When the user does a reseek, the iterate_upper_bound might have
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// changed. CheckDataBlockWithinUpperBound() needs to be called
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// explicitly if the reseek ends up in the same data block.
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// If the reseek ends up in a different block, InitDataBlock() will do
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// the iterator upper bound check.
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CheckDataBlockWithinUpperBound();
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}
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if (target) {
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block_iter_.Seek(*target);
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} else {
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block_iter_.SeekToFirst();
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}
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FindKeyForward();
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}
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CheckOutOfBound();
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if (target) {
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assert(!Valid() || icomp_.Compare(*target, key()) <= 0);
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}
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}
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void BlockBasedTableIterator::SeekForPrev(const Slice& target) {
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is_out_of_bound_ = false;
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is_at_first_key_from_index_ = false;
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// For now totally disable prefix seek in auto prefix mode because we don't
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// have logic
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if (!CheckPrefixMayMatch(target, IterDirection::kBackward)) {
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ResetDataIter();
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return;
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}
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SavePrevIndexValue();
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// Call Seek() rather than SeekForPrev() in the index block, because the
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// target data block will likely to contain the position for `target`, the
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// same as Seek(), rather than than before.
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// For example, if we have three data blocks, each containing two keys:
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// [2, 4] [6, 8] [10, 12]
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// (the keys in the index block would be [4, 8, 12])
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// and the user calls SeekForPrev(7), we need to go to the second block,
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// just like if they call Seek(7).
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// The only case where the block is difference is when they seek to a position
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// in the boundary. For example, if they SeekForPrev(5), we should go to the
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// first block, rather than the second. However, we don't have the information
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// to distinguish the two unless we read the second block. In this case, we'll
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// end up with reading two blocks.
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index_iter_->Seek(target);
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if (!index_iter_->Valid()) {
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auto seek_status = index_iter_->status();
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// Check for IO error
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if (!seek_status.IsNotFound() && !seek_status.ok()) {
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ResetDataIter();
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return;
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}
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// With prefix index, Seek() returns NotFound if the prefix doesn't exist
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if (seek_status.IsNotFound()) {
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// Any key less than the target is fine for prefix seek
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ResetDataIter();
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return;
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} else {
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index_iter_->SeekToLast();
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}
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// Check for IO error
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if (!index_iter_->Valid()) {
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ResetDataIter();
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return;
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}
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}
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InitDataBlock();
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block_iter_.SeekForPrev(target);
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FindKeyBackward();
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CheckDataBlockWithinUpperBound();
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assert(!block_iter_.Valid() ||
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icomp_.Compare(target, block_iter_.key()) >= 0);
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}
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void BlockBasedTableIterator::SeekToLast() {
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is_out_of_bound_ = false;
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is_at_first_key_from_index_ = false;
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SavePrevIndexValue();
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index_iter_->SeekToLast();
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if (!index_iter_->Valid()) {
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ResetDataIter();
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return;
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}
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InitDataBlock();
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block_iter_.SeekToLast();
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FindKeyBackward();
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CheckDataBlockWithinUpperBound();
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}
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void BlockBasedTableIterator::Next() {
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if (is_at_first_key_from_index_ && !MaterializeCurrentBlock()) {
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return;
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}
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assert(block_iter_points_to_real_block_);
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block_iter_.Next();
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FindKeyForward();
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CheckOutOfBound();
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}
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bool BlockBasedTableIterator::NextAndGetResult(IterateResult* result) {
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Next();
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bool is_valid = Valid();
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if (is_valid) {
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result->key = key();
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result->bound_check_result = UpperBoundCheckResult();
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result->value_prepared = !is_at_first_key_from_index_;
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}
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return is_valid;
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}
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void BlockBasedTableIterator::Prev() {
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if (is_at_first_key_from_index_) {
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is_at_first_key_from_index_ = false;
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index_iter_->Prev();
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if (!index_iter_->Valid()) {
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return;
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}
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InitDataBlock();
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block_iter_.SeekToLast();
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} else {
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assert(block_iter_points_to_real_block_);
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block_iter_.Prev();
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}
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FindKeyBackward();
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}
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void BlockBasedTableIterator::InitDataBlock() {
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BlockHandle data_block_handle = index_iter_->value().handle;
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if (!block_iter_points_to_real_block_ ||
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data_block_handle.offset() != prev_block_offset_ ||
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// if previous attempt of reading the block missed cache, try again
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block_iter_.status().IsIncomplete()) {
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if (block_iter_points_to_real_block_) {
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ResetDataIter();
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}
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auto* rep = table_->get_rep();
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bool is_for_compaction =
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lookup_context_.caller == TableReaderCaller::kCompaction;
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// Prefetch additional data for range scans (iterators).
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// Implicit auto readahead:
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// Enabled after 2 sequential IOs when ReadOptions.readahead_size == 0.
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// Explicit user requested readahead:
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// Enabled from the very first IO when ReadOptions.readahead_size is set.
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block_prefetcher_.PrefetchIfNeeded(
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rep, data_block_handle, read_options_.readahead_size, is_for_compaction,
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read_options_.async_io);
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Status s;
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table_->NewDataBlockIterator<DataBlockIter>(
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read_options_, data_block_handle, &block_iter_, BlockType::kData,
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/*get_context=*/nullptr, &lookup_context_, s,
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block_prefetcher_.prefetch_buffer(),
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/*for_compaction=*/is_for_compaction);
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block_iter_points_to_real_block_ = true;
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CheckDataBlockWithinUpperBound();
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}
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}
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bool BlockBasedTableIterator::MaterializeCurrentBlock() {
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assert(is_at_first_key_from_index_);
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assert(!block_iter_points_to_real_block_);
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assert(index_iter_->Valid());
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is_at_first_key_from_index_ = false;
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InitDataBlock();
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assert(block_iter_points_to_real_block_);
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if (!block_iter_.status().ok()) {
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return false;
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}
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block_iter_.SeekToFirst();
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if (!block_iter_.Valid() ||
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icomp_.Compare(block_iter_.key(),
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index_iter_->value().first_internal_key) != 0) {
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block_iter_.Invalidate(Status::Corruption(
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"first key in index doesn't match first key in block"));
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return false;
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}
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return true;
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}
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void BlockBasedTableIterator::FindKeyForward() {
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// This method's code is kept short to make it likely to be inlined.
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assert(!is_out_of_bound_);
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assert(block_iter_points_to_real_block_);
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if (!block_iter_.Valid()) {
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// This is the only call site of FindBlockForward(), but it's extracted into
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// a separate method to keep FindKeyForward() short and likely to be
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// inlined. When transitioning to a different block, we call
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// FindBlockForward(), which is much longer and is probably not inlined.
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FindBlockForward();
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} else {
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// This is the fast path that avoids a function call.
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}
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}
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void BlockBasedTableIterator::FindBlockForward() {
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// TODO the while loop inherits from two-level-iterator. We don't know
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// whether a block can be empty so it can be replaced by an "if".
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do {
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if (!block_iter_.status().ok()) {
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return;
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}
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// Whether next data block is out of upper bound, if there is one.
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const bool next_block_is_out_of_bound =
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read_options_.iterate_upper_bound != nullptr &&
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block_iter_points_to_real_block_ &&
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block_upper_bound_check_ == BlockUpperBound::kUpperBoundInCurBlock;
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assert(!next_block_is_out_of_bound ||
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user_comparator_.CompareWithoutTimestamp(
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*read_options_.iterate_upper_bound, /*a_has_ts=*/false,
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index_iter_->user_key(), /*b_has_ts=*/true) <= 0);
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ResetDataIter();
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index_iter_->Next();
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if (next_block_is_out_of_bound) {
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// The next block is out of bound. No need to read it.
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TEST_SYNC_POINT_CALLBACK("BlockBasedTableIterator:out_of_bound", nullptr);
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// We need to make sure this is not the last data block before setting
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// is_out_of_bound_, since the index key for the last data block can be
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// larger than smallest key of the next file on the same level.
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if (index_iter_->Valid()) {
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is_out_of_bound_ = true;
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}
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return;
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}
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if (!index_iter_->Valid()) {
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return;
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}
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IndexValue v = index_iter_->value();
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if (!v.first_internal_key.empty() && allow_unprepared_value_) {
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// Index contains the first key of the block. Defer reading the block.
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is_at_first_key_from_index_ = true;
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return;
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}
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InitDataBlock();
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block_iter_.SeekToFirst();
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} while (!block_iter_.Valid());
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}
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void BlockBasedTableIterator::FindKeyBackward() {
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while (!block_iter_.Valid()) {
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if (!block_iter_.status().ok()) {
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return;
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}
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ResetDataIter();
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index_iter_->Prev();
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if (index_iter_->Valid()) {
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InitDataBlock();
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block_iter_.SeekToLast();
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} else {
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return;
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}
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}
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// We could have check lower bound here too, but we opt not to do it for
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// code simplicity.
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}
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void BlockBasedTableIterator::CheckOutOfBound() {
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if (read_options_.iterate_upper_bound != nullptr &&
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block_upper_bound_check_ != BlockUpperBound::kUpperBoundBeyondCurBlock &&
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Valid()) {
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is_out_of_bound_ =
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user_comparator_.CompareWithoutTimestamp(
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*read_options_.iterate_upper_bound, /*a_has_ts=*/false, user_key(),
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/*b_has_ts=*/true) <= 0;
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}
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}
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void BlockBasedTableIterator::CheckDataBlockWithinUpperBound() {
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if (read_options_.iterate_upper_bound != nullptr &&
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block_iter_points_to_real_block_) {
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block_upper_bound_check_ = (user_comparator_.CompareWithoutTimestamp(
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*read_options_.iterate_upper_bound,
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/*a_has_ts=*/false, index_iter_->user_key(),
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/*b_has_ts=*/true) > 0)
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? BlockUpperBound::kUpperBoundBeyondCurBlock
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: BlockUpperBound::kUpperBoundInCurBlock;
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}
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}
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} // namespace ROCKSDB_NAMESPACE
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