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rocksdb/table/block_based/partitioned_index_iterator.cc
akankshamahajan 5b5b011cdd Avoid double block cache lookup during Seek with async_io option (#11616) 
Summary:
With the async_io option, the Seek happens in 2 phases. Phase 1 starts an asynchronous read on a block cache miss, and phase 2 waits for it to complete and finishes the seek. In both phases, BlockBasedTable::NewDataBlockIterator is called, which tries to lookup the block cache for the data block first before looking in the prefetch buffer. It's optimized by doing the block cache lookup only in the first phase and save some CPU.

Pull Request resolved: https://github.com/facebook/rocksdb/pull/11616

Test Plan: Added unit test

Reviewed By: jaykorean

Differential Revision: D47477887

Pulled By: akankshamahajan15

fbshipit-source-id: 0355e0a68fc0ea2eb92340ae42735afcdbcbfd79
2023-09-18 11:32:30 -07:00

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// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
//
// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file. See the AUTHORS file for names of contributors.
#include "table/block_based/partitioned_index_iterator.h"
namespace ROCKSDB_NAMESPACE {
void PartitionedIndexIterator::Seek(const Slice& target) { SeekImpl(&target); }
void PartitionedIndexIterator::SeekToFirst() { SeekImpl(nullptr); }
void PartitionedIndexIterator::SeekImpl(const Slice* target) {
SavePrevIndexValue();
if (target) {
index_iter_->Seek(*target);
} else {
index_iter_->SeekToFirst();
}
if (!index_iter_->Valid()) {
ResetPartitionedIndexIter();
return;
}
InitPartitionedIndexBlock();
if (target) {
block_iter_.Seek(*target);
} else {
block_iter_.SeekToFirst();
}
FindKeyForward();
// We could check upper bound here, but that would be too complicated
// and checking index upper bound is less useful than for data blocks.
if (target) {
assert(!Valid() || (table_->get_rep()->index_key_includes_seq
? (icomp_.Compare(*target, key()) <= 0)
: (user_comparator_.Compare(ExtractUserKey(*target),
key()) <= 0)));
}
}
void PartitionedIndexIterator::SeekToLast() {
SavePrevIndexValue();
index_iter_->SeekToLast();
if (!index_iter_->Valid()) {
ResetPartitionedIndexIter();
return;
}
InitPartitionedIndexBlock();
block_iter_.SeekToLast();
FindKeyBackward();
}
void PartitionedIndexIterator::Next() {
assert(block_iter_points_to_real_block_);
block_iter_.Next();
FindKeyForward();
}
void PartitionedIndexIterator::Prev() {
assert(block_iter_points_to_real_block_);
block_iter_.Prev();
FindKeyBackward();
}
void PartitionedIndexIterator::InitPartitionedIndexBlock() {
BlockHandle partitioned_index_handle = index_iter_->value().handle;
if (!block_iter_points_to_real_block_ ||
partitioned_index_handle.offset() != prev_block_offset_ ||
// if previous attempt of reading the block missed cache, try again
block_iter_.status().IsIncomplete()) {
if (block_iter_points_to_real_block_) {
ResetPartitionedIndexIter();
}
auto* rep = table_->get_rep();
bool is_for_compaction =
lookup_context_.caller == TableReaderCaller::kCompaction;
// Prefetch additional data for range scans (iterators).
// Implicit auto readahead:
// Enabled after 2 sequential IOs when ReadOptions.readahead_size == 0.
// Explicit user requested readahead:
// Enabled from the very first IO when ReadOptions.readahead_size is set.
block_prefetcher_.PrefetchIfNeeded(
rep, partitioned_index_handle, read_options_.readahead_size,
is_for_compaction, /*no_sequential_checking=*/false, read_options_);
Status s;
table_->NewDataBlockIterator<IndexBlockIter>(
read_options_, partitioned_index_handle, &block_iter_,
BlockType::kIndex,
/*get_context=*/nullptr, &lookup_context_,
block_prefetcher_.prefetch_buffer(),
/*for_compaction=*/is_for_compaction, /*async_read=*/false, s,
/*use_block_cache_for_lookup=*/true);
block_iter_points_to_real_block_ = true;
// We could check upper bound here but it is complicated to reason about
// upper bound in index iterator. On the other than, in large scans, index
// iterators are moved much less frequently compared to data blocks. So
// the upper bound check is skipped for simplicity.
}
}
void PartitionedIndexIterator::FindKeyForward() {
// This method's code is kept short to make it likely to be inlined.
assert(block_iter_points_to_real_block_);
if (!block_iter_.Valid()) {
// This is the only call site of FindBlockForward(), but it's extracted into
// a separate method to keep FindKeyForward() short and likely to be
// inlined. When transitioning to a different block, we call
// FindBlockForward(), which is much longer and is probably not inlined.
FindBlockForward();
} else {
// This is the fast path that avoids a function call.
}
}
void PartitionedIndexIterator::FindBlockForward() {
// TODO the while loop inherits from two-level-iterator. We don't know
// whether a block can be empty so it can be replaced by an "if".
do {
if (!block_iter_.status().ok()) {
return;
}
ResetPartitionedIndexIter();
index_iter_->Next();
if (!index_iter_->Valid()) {
return;
}
InitPartitionedIndexBlock();
block_iter_.SeekToFirst();
} while (!block_iter_.Valid());
}
void PartitionedIndexIterator::FindKeyBackward() {
while (!block_iter_.Valid()) {
if (!block_iter_.status().ok()) {
return;
}
ResetPartitionedIndexIter();
index_iter_->Prev();
if (index_iter_->Valid()) {
InitPartitionedIndexBlock();
block_iter_.SeekToLast();
} else {
return;
}
}
}
} // namespace ROCKSDB_NAMESPACE
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