rocksdb/table/block_based/block_based_table_iterator.cc
akankshamahajan 5cb2d09d47 Refactor FilePrefetchBuffer code (#12097)
Summary:
Summary - Refactor FilePrefetchBuffer code
- Implementation:
FilePrefetchBuffer maintains a deque of free buffers (free_bufs_) of size num_buffers_ and buffers (bufs_) which contains the prefetched data. Whenever a buffer is consumed or is outdated (w.r.t. to requested offset), that buffer is cleared and returned to free_bufs_.

 If a buffer is available in free_bufs_, it's moved to bufs_ and is sent for prefetching. num_buffers_ defines how many buffers are maintained that contains prefetched data.
If num_buffers_ == 1, it's a sequential read flow. Read API will be called on that one buffer whenever the data is requested and is not in the buffer.
If num_buffers_ > 1, then the data is prefetched asynchronosuly in the buffers whenever the data is consumed from the buffers and that buffer is freed.
If num_buffers > 1, then requested data can be overlapping between 2 buffers. To return the continuous buffer overlap_bufs_ is used. The requested data is copied from 2 buffers to the overlap_bufs_ and overlap_bufs_ is returned to
the caller.

- Merged Sync and Async code flow into one in FilePrefetchBuffer.

Test Plan -
- Crash test passed
- Unit tests
- Pending - Benchmarks

Pull Request resolved: https://github.com/facebook/rocksdb/pull/12097

Reviewed By: ajkr

Differential Revision: D51759552

Pulled By: akankshamahajan15

fbshipit-source-id: 69a352945affac2ed22be96048d55863e0168ad5
2024-01-05 09:29:01 -08:00

875 lines
31 KiB
C++

// 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/block_based_table_iterator.h"
namespace ROCKSDB_NAMESPACE {
void BlockBasedTableIterator::SeekToFirst() { SeekImpl(nullptr, false); }
void BlockBasedTableIterator::Seek(const Slice& target) {
SeekImpl(&target, true);
}
void BlockBasedTableIterator::SeekSecondPass(const Slice* target) {
AsyncInitDataBlock(/*is_first_pass=*/false);
if (target) {
block_iter_.Seek(*target);
} else {
block_iter_.SeekToFirst();
}
FindKeyForward();
CheckOutOfBound();
if (target) {
assert(!Valid() || icomp_.Compare(*target, key()) <= 0);
}
}
void BlockBasedTableIterator::SeekImpl(const Slice* target,
bool async_prefetch) {
bool is_first_pass = !async_read_in_progress_;
if (!is_first_pass) {
SeekSecondPass(target);
return;
}
ResetBlockCacheLookupVar();
bool autotune_readaheadsize = is_first_pass &&
read_options_.auto_readahead_size &&
read_options_.iterate_upper_bound;
if (autotune_readaheadsize &&
table_->get_rep()->table_options.block_cache.get() &&
direction_ == IterDirection::kForward) {
readahead_cache_lookup_ = true;
}
is_out_of_bound_ = false;
is_at_first_key_from_index_ = false;
seek_stat_state_ = kNone;
bool filter_checked = false;
if (target &&
!CheckPrefixMayMatch(*target, IterDirection::kForward, &filter_checked)) {
ResetDataIter();
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_FILTERED
: NON_LAST_LEVEL_SEEK_FILTERED);
return;
}
if (filter_checked) {
seek_stat_state_ = kFilterUsed;
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_FILTER_MATCH
: NON_LAST_LEVEL_SEEK_FILTER_MATCH);
}
bool need_seek_index = true;
// In case of readahead_cache_lookup_, index_iter_ could change to find the
// readahead size in BlockCacheLookupForReadAheadSize so it needs to
// reseek.
if (IsIndexAtCurr() && block_iter_points_to_real_block_ &&
block_iter_.Valid()) {
// Reseek.
prev_block_offset_ = index_iter_->value().handle.offset();
if (target) {
// We can avoid an index seek if:
// 1. The new seek key is larger than the current key
// 2. The new seek key is within the upper bound of the block
// Since we don't necessarily know the internal key for either
// the current key or the upper bound, we check user keys and
// exclude the equality case. Considering internal keys can
// improve for the boundary cases, but it would complicate the
// code.
if (user_comparator_.Compare(ExtractUserKey(*target),
block_iter_.user_key()) > 0 &&
user_comparator_.Compare(ExtractUserKey(*target),
index_iter_->user_key()) < 0) {
need_seek_index = false;
}
}
}
if (need_seek_index) {
if (target) {
index_iter_->Seek(*target);
} else {
index_iter_->SeekToFirst();
}
is_index_at_curr_block_ = true;
if (!index_iter_->Valid()) {
ResetDataIter();
return;
}
}
// After reseek, index_iter_ point to the right key i.e. target in
// case of readahead_cache_lookup_. So index_iter_ can be used directly.
IndexValue v = index_iter_->value();
const bool same_block = block_iter_points_to_real_block_ &&
v.handle.offset() == prev_block_offset_;
if (!v.first_internal_key.empty() && !same_block &&
(!target || icomp_.Compare(*target, v.first_internal_key) <= 0) &&
allow_unprepared_value_) {
// Index contains the first key of the block, and it's >= target.
// We can defer reading the block.
is_at_first_key_from_index_ = true;
// ResetDataIter() will invalidate block_iter_. Thus, there is no need to
// call CheckDataBlockWithinUpperBound() to check for iterate_upper_bound
// as that will be done later when the data block is actually read.
ResetDataIter();
} else {
// Need to use the data block.
if (!same_block) {
if (read_options_.async_io && async_prefetch) {
AsyncInitDataBlock(/*is_first_pass=*/true);
if (async_read_in_progress_) {
// Status::TryAgain indicates asynchronous request for retrieval of
// data blocks has been submitted. So it should return at this point
// and Seek should be called again to retrieve the requested block
// and execute the remaining code.
return;
}
} else {
InitDataBlock();
}
} else {
// When the user does a reseek, the iterate_upper_bound might have
// changed. CheckDataBlockWithinUpperBound() needs to be called
// explicitly if the reseek ends up in the same data block.
// If the reseek ends up in a different block, InitDataBlock() will do
// the iterator upper bound check.
CheckDataBlockWithinUpperBound();
}
if (target) {
block_iter_.Seek(*target);
} else {
block_iter_.SeekToFirst();
}
FindKeyForward();
}
CheckOutOfBound();
if (target) {
assert(!Valid() || icomp_.Compare(*target, key()) <= 0);
}
}
void BlockBasedTableIterator::SeekForPrev(const Slice& target) {
direction_ = IterDirection::kBackward;
ResetBlockCacheLookupVar();
is_out_of_bound_ = false;
is_at_first_key_from_index_ = false;
seek_stat_state_ = kNone;
bool filter_checked = false;
// For now totally disable prefix seek in auto prefix mode because we don't
// have logic
if (!CheckPrefixMayMatch(target, IterDirection::kBackward, &filter_checked)) {
ResetDataIter();
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_FILTERED
: NON_LAST_LEVEL_SEEK_FILTERED);
return;
}
if (filter_checked) {
seek_stat_state_ = kFilterUsed;
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_FILTER_MATCH
: NON_LAST_LEVEL_SEEK_FILTER_MATCH);
}
SavePrevIndexValue();
// Call Seek() rather than SeekForPrev() in the index block, because the
// target data block will likely to contain the position for `target`, the
// same as Seek(), rather than than before.
// For example, if we have three data blocks, each containing two keys:
// [2, 4] [6, 8] [10, 12]
// (the keys in the index block would be [4, 8, 12])
// and the user calls SeekForPrev(7), we need to go to the second block,
// just like if they call Seek(7).
// The only case where the block is difference is when they seek to a position
// in the boundary. For example, if they SeekForPrev(5), we should go to the
// first block, rather than the second. However, we don't have the information
// to distinguish the two unless we read the second block. In this case, we'll
// end up with reading two blocks.
index_iter_->Seek(target);
is_index_at_curr_block_ = true;
if (!index_iter_->Valid()) {
auto seek_status = index_iter_->status();
// Check for IO error
if (!seek_status.IsNotFound() && !seek_status.ok()) {
ResetDataIter();
return;
}
// With prefix index, Seek() returns NotFound if the prefix doesn't exist
if (seek_status.IsNotFound()) {
// Any key less than the target is fine for prefix seek
ResetDataIter();
return;
} else {
index_iter_->SeekToLast();
}
// Check for IO error
if (!index_iter_->Valid()) {
ResetDataIter();
return;
}
}
InitDataBlock();
block_iter_.SeekForPrev(target);
FindKeyBackward();
CheckDataBlockWithinUpperBound();
assert(!block_iter_.Valid() ||
icomp_.Compare(target, block_iter_.key()) >= 0);
}
void BlockBasedTableIterator::SeekToLast() {
direction_ = IterDirection::kBackward;
ResetBlockCacheLookupVar();
is_out_of_bound_ = false;
is_at_first_key_from_index_ = false;
seek_stat_state_ = kNone;
SavePrevIndexValue();
index_iter_->SeekToLast();
is_index_at_curr_block_ = true;
if (!index_iter_->Valid()) {
ResetDataIter();
return;
}
InitDataBlock();
block_iter_.SeekToLast();
FindKeyBackward();
CheckDataBlockWithinUpperBound();
}
void BlockBasedTableIterator::Next() {
if (is_at_first_key_from_index_ && !MaterializeCurrentBlock()) {
return;
}
assert(block_iter_points_to_real_block_);
block_iter_.Next();
FindKeyForward();
CheckOutOfBound();
}
bool BlockBasedTableIterator::NextAndGetResult(IterateResult* result) {
Next();
bool is_valid = Valid();
if (is_valid) {
result->key = key();
result->bound_check_result = UpperBoundCheckResult();
result->value_prepared = !is_at_first_key_from_index_;
}
return is_valid;
}
void BlockBasedTableIterator::Prev() {
if (readahead_cache_lookup_ && !IsIndexAtCurr()) {
// In case of readahead_cache_lookup_, index_iter_ has moved forward. So we
// need to reseek the index_iter_ to point to current block by using
// block_iter_'s key.
if (Valid()) {
ResetBlockCacheLookupVar();
direction_ = IterDirection::kBackward;
Slice last_key = key();
index_iter_->Seek(last_key);
is_index_at_curr_block_ = true;
// Check for IO error.
if (!index_iter_->Valid()) {
ResetDataIter();
return;
}
}
if (!Valid()) {
ResetDataIter();
return;
}
}
ResetBlockCacheLookupVar();
if (is_at_first_key_from_index_) {
is_at_first_key_from_index_ = false;
index_iter_->Prev();
if (!index_iter_->Valid()) {
return;
}
InitDataBlock();
block_iter_.SeekToLast();
} else {
assert(block_iter_points_to_real_block_);
block_iter_.Prev();
}
FindKeyBackward();
}
void BlockBasedTableIterator::InitDataBlock() {
BlockHandle data_block_handle;
bool is_in_cache = false;
bool use_block_cache_for_lookup = true;
if (DoesContainBlockHandles()) {
data_block_handle = block_handles_.front().handle_;
is_in_cache = block_handles_.front().is_cache_hit_;
use_block_cache_for_lookup = false;
} else {
data_block_handle = index_iter_->value().handle;
}
if (!block_iter_points_to_real_block_ ||
data_block_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_) {
ResetDataIter();
}
bool is_for_compaction =
lookup_context_.caller == TableReaderCaller::kCompaction;
// Initialize Data Block From CacheableEntry.
if (is_in_cache) {
Status s;
block_iter_.Invalidate(Status::OK());
table_->NewDataBlockIterator<DataBlockIter>(
read_options_, (block_handles_.front().cachable_entry_).As<Block>(),
&block_iter_, s);
} else {
auto* rep = table_->get_rep();
std::function<void(bool, uint64_t&, uint64_t&)> readaheadsize_cb =
nullptr;
if (readahead_cache_lookup_) {
readaheadsize_cb = std::bind(
&BlockBasedTableIterator::BlockCacheLookupForReadAheadSize, this,
std::placeholders::_1, std::placeholders::_2,
std::placeholders::_3);
}
// 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, data_block_handle, read_options_.readahead_size,
is_for_compaction,
/*no_sequential_checking=*/false, read_options_, readaheadsize_cb,
read_options_.async_io);
Status s;
table_->NewDataBlockIterator<DataBlockIter>(
read_options_, data_block_handle, &block_iter_, BlockType::kData,
/*get_context=*/nullptr, &lookup_context_,
block_prefetcher_.prefetch_buffer(),
/*for_compaction=*/is_for_compaction, /*async_read=*/false, s,
use_block_cache_for_lookup);
}
block_iter_points_to_real_block_ = true;
CheckDataBlockWithinUpperBound();
if (!is_for_compaction &&
(seek_stat_state_ & kDataBlockReadSinceLastSeek) == 0) {
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_DATA
: NON_LAST_LEVEL_SEEK_DATA);
seek_stat_state_ = static_cast<SeekStatState>(
seek_stat_state_ | kDataBlockReadSinceLastSeek | kReportOnUseful);
}
}
}
void BlockBasedTableIterator::AsyncInitDataBlock(bool is_first_pass) {
BlockHandle data_block_handle;
bool is_for_compaction =
lookup_context_.caller == TableReaderCaller::kCompaction;
if (is_first_pass) {
data_block_handle = index_iter_->value().handle;
if (!block_iter_points_to_real_block_ ||
data_block_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_) {
ResetDataIter();
}
auto* rep = table_->get_rep();
std::function<void(bool, uint64_t&, uint64_t&)> readaheadsize_cb =
nullptr;
if (readahead_cache_lookup_) {
readaheadsize_cb = std::bind(
&BlockBasedTableIterator::BlockCacheLookupForReadAheadSize, this,
std::placeholders::_1, std::placeholders::_2,
std::placeholders::_3);
}
// 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.
// In case of async_io with Implicit readahead, block_prefetcher_ will
// always the create the prefetch buffer by setting no_sequential_checking
// = true.
block_prefetcher_.PrefetchIfNeeded(
rep, data_block_handle, read_options_.readahead_size,
is_for_compaction, /*no_sequential_checking=*/read_options_.async_io,
read_options_, readaheadsize_cb, read_options_.async_io);
Status s;
table_->NewDataBlockIterator<DataBlockIter>(
read_options_, data_block_handle, &block_iter_, BlockType::kData,
/*get_context=*/nullptr, &lookup_context_,
block_prefetcher_.prefetch_buffer(),
/*for_compaction=*/is_for_compaction, /*async_read=*/true, s,
/*use_block_cache_for_lookup=*/true);
if (s.IsTryAgain()) {
async_read_in_progress_ = true;
return;
}
}
} else {
// Second pass will call the Poll to get the data block which has been
// requested asynchronously.
bool is_in_cache = false;
if (DoesContainBlockHandles()) {
data_block_handle = block_handles_.front().handle_;
is_in_cache = block_handles_.front().is_cache_hit_;
} else {
data_block_handle = index_iter_->value().handle;
}
Status s;
// Initialize Data Block From CacheableEntry.
if (is_in_cache) {
block_iter_.Invalidate(Status::OK());
table_->NewDataBlockIterator<DataBlockIter>(
read_options_, (block_handles_.front().cachable_entry_).As<Block>(),
&block_iter_, s);
} else {
table_->NewDataBlockIterator<DataBlockIter>(
read_options_, data_block_handle, &block_iter_, BlockType::kData,
/*get_context=*/nullptr, &lookup_context_,
block_prefetcher_.prefetch_buffer(),
/*for_compaction=*/is_for_compaction, /*async_read=*/false, s,
/*use_block_cache_for_lookup=*/false);
}
}
block_iter_points_to_real_block_ = true;
CheckDataBlockWithinUpperBound();
if (!is_for_compaction &&
(seek_stat_state_ & kDataBlockReadSinceLastSeek) == 0) {
RecordTick(table_->GetStatistics(), is_last_level_
? LAST_LEVEL_SEEK_DATA
: NON_LAST_LEVEL_SEEK_DATA);
seek_stat_state_ = static_cast<SeekStatState>(
seek_stat_state_ | kDataBlockReadSinceLastSeek | kReportOnUseful);
}
async_read_in_progress_ = false;
}
bool BlockBasedTableIterator::MaterializeCurrentBlock() {
assert(is_at_first_key_from_index_);
assert(!block_iter_points_to_real_block_);
assert(index_iter_->Valid());
is_at_first_key_from_index_ = false;
InitDataBlock();
assert(block_iter_points_to_real_block_);
if (!block_iter_.status().ok()) {
return false;
}
block_iter_.SeekToFirst();
// MaterializeCurrentBlock is called when block is actually read by
// calling InitDataBlock. is_at_first_key_from_index_ will be false for block
// handles placed in blockhandle. So index_ will be pointing to current block.
// After InitDataBlock, index_iter_ can point to different block if
// BlockCacheLookupForReadAheadSize is called.
Slice first_internal_key;
if (DoesContainBlockHandles()) {
first_internal_key = block_handles_.front().first_internal_key_;
} else {
first_internal_key = index_iter_->value().first_internal_key;
}
if (!block_iter_.Valid() ||
icomp_.Compare(block_iter_.key(), first_internal_key) != 0) {
block_iter_.Invalidate(Status::Corruption(
"first key in index doesn't match first key in block"));
return false;
}
return true;
}
void BlockBasedTableIterator::FindKeyForward() {
// This method's code is kept short to make it likely to be inlined.
assert(!is_out_of_bound_);
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 BlockBasedTableIterator::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;
}
// Whether next data block is out of upper bound, if there is one.
// index_iter_ can point to different block in case of
// readahead_cache_lookup_. readahead_cache_lookup_ will be handle the
// upper_bound check.
bool next_block_is_out_of_bound =
IsIndexAtCurr() && read_options_.iterate_upper_bound != nullptr &&
block_iter_points_to_real_block_ &&
block_upper_bound_check_ == BlockUpperBound::kUpperBoundInCurBlock;
assert(!next_block_is_out_of_bound ||
user_comparator_.CompareWithoutTimestamp(
*read_options_.iterate_upper_bound, /*a_has_ts=*/false,
index_iter_->user_key(), /*b_has_ts=*/true) <= 0);
ResetDataIter();
if (DoesContainBlockHandles()) {
// Advance and point to that next Block handle to make that block handle
// current.
block_handles_.pop_front();
}
if (!DoesContainBlockHandles()) {
// For readahead_cache_lookup_ enabled scenario -
// 1. In case of Seek, block_handle will be empty and it should be follow
// as usual doing index_iter_->Next().
// 2. If block_handles is empty and index is not at current because of
// lookup (during Next), it should skip doing index_iter_->Next(), as
// it's already pointing to next block;
// 3. Last block could be out of bound and it won't iterate over that
// during BlockCacheLookup. We need to set for that block here.
if (IsIndexAtCurr() || is_index_out_of_bound_) {
index_iter_->Next();
if (is_index_out_of_bound_) {
next_block_is_out_of_bound = is_index_out_of_bound_;
is_index_out_of_bound_ = false;
}
} else {
// Skip Next as index_iter_ already points to correct index when it
// iterates in BlockCacheLookupForReadAheadSize.
is_index_at_curr_block_ = true;
}
if (next_block_is_out_of_bound) {
// The next block is out of bound. No need to read it.
TEST_SYNC_POINT_CALLBACK("BlockBasedTableIterator:out_of_bound",
nullptr);
// We need to make sure this is not the last data block before setting
// is_out_of_bound_, since the index key for the last data block can be
// larger than smallest key of the next file on the same level.
if (index_iter_->Valid()) {
is_out_of_bound_ = true;
}
return;
}
if (!index_iter_->Valid()) {
return;
}
IndexValue v = index_iter_->value();
if (!v.first_internal_key.empty() && allow_unprepared_value_) {
// Index contains the first key of the block. Defer reading the block.
is_at_first_key_from_index_ = true;
return;
}
}
InitDataBlock();
block_iter_.SeekToFirst();
} while (!block_iter_.Valid());
}
void BlockBasedTableIterator::FindKeyBackward() {
while (!block_iter_.Valid()) {
if (!block_iter_.status().ok()) {
return;
}
ResetDataIter();
index_iter_->Prev();
if (index_iter_->Valid()) {
InitDataBlock();
block_iter_.SeekToLast();
} else {
return;
}
}
// We could have check lower bound here too, but we opt not to do it for
// code simplicity.
}
void BlockBasedTableIterator::CheckOutOfBound() {
if (read_options_.iterate_upper_bound != nullptr &&
block_upper_bound_check_ != BlockUpperBound::kUpperBoundBeyondCurBlock &&
Valid()) {
is_out_of_bound_ =
user_comparator_.CompareWithoutTimestamp(
*read_options_.iterate_upper_bound, /*a_has_ts=*/false, user_key(),
/*b_has_ts=*/true) <= 0;
}
}
void BlockBasedTableIterator::CheckDataBlockWithinUpperBound() {
if (IsIndexAtCurr() && read_options_.iterate_upper_bound != nullptr &&
block_iter_points_to_real_block_) {
block_upper_bound_check_ = (user_comparator_.CompareWithoutTimestamp(
*read_options_.iterate_upper_bound,
/*a_has_ts=*/false, index_iter_->user_key(),
/*b_has_ts=*/true) > 0)
? BlockUpperBound::kUpperBoundBeyondCurBlock
: BlockUpperBound::kUpperBoundInCurBlock;
}
}
void BlockBasedTableIterator::InitializeStartAndEndOffsets(
bool read_curr_block, bool& found_first_miss_block,
uint64_t& start_updated_offset, uint64_t& end_updated_offset,
size_t& prev_handles_size) {
prev_handles_size = block_handles_.size();
size_t footer = table_->get_rep()->footer.GetBlockTrailerSize();
// It initialize start and end offset to begin which is covered by following
// scenarios
if (read_curr_block) {
if (!DoesContainBlockHandles()) {
// Scenario 1 : read_curr_block (callback made on miss block which caller
// was reading) and it has no existing handles in queue. i.e.
// index_iter_ is pointing to block that is being read by
// caller.
//
// Add current block here as it doesn't need any lookup.
BlockHandleInfo block_handle_info;
block_handle_info.handle_ = index_iter_->value().handle;
block_handle_info.SetFirstInternalKey(
index_iter_->value().first_internal_key);
end_updated_offset = block_handle_info.handle_.offset() + footer +
block_handle_info.handle_.size();
block_handles_.emplace_back(std::move(block_handle_info));
index_iter_->Next();
is_index_at_curr_block_ = false;
found_first_miss_block = true;
} else {
// Scenario 2 : read_curr_block (callback made on miss block which caller
// was reading) but the queue already has some handles.
//
// It can be due to reading error in second buffer in FilePrefetchBuffer.
// BlockHandles already added to the queue but there was error in fetching
// those data blocks. So in this call they need to be read again.
found_first_miss_block = true;
// Initialize prev_handles_size to 0 as all those handles need to be read
// again.
prev_handles_size = 0;
start_updated_offset = block_handles_.front().handle_.offset();
end_updated_offset = block_handles_.back().handle_.offset() + footer +
block_handles_.back().handle_.size();
}
} else {
// Scenario 3 : read_curr_block is false (callback made to do additional
// prefetching in buffers) and the queue already has some
// handles from first buffer.
if (DoesContainBlockHandles()) {
start_updated_offset = block_handles_.back().handle_.offset() + footer +
block_handles_.back().handle_.size();
end_updated_offset = start_updated_offset;
} else {
// Scenario 4 : read_curr_block is false (callback made to do additional
// prefetching in buffers) but the queue has no handle
// from first buffer.
//
// It can be when Reseek is from block cache (which doesn't clear the
// buffers in FilePrefetchBuffer but clears block handles from queue) and
// reseek also lies within the buffer. So Next will get data from
// exisiting buffers untill this callback is made to prefetch additional
// data. All handles need to be added to the queue starting from
// index_iter_.
assert(index_iter_->Valid());
start_updated_offset = index_iter_->value().handle.offset();
end_updated_offset = start_updated_offset;
}
}
}
// BlockCacheLookupForReadAheadSize API lookups in the block cache and tries to
// reduce the start and end offset passed.
//
// Implementation -
// This function looks into the block cache for the blocks between start_offset
// and end_offset and add all the handles in the queue.
// It then iterates from the end to find first miss block and update the end
// offset to that block.
// It also iterates from the start and find first miss block and update the
// start offset to that block.
//
// Arguments -
// start_offset : Offset from which the caller wants to read.
// end_offset : End offset till which the caller wants to read.
// read_curr_block : True if this call was due to miss in the cache and
// caller wants to read that block.
// False if current call is to prefetch additional data in
// extra buffers.
void BlockBasedTableIterator::BlockCacheLookupForReadAheadSize(
bool read_curr_block, uint64_t& start_offset, uint64_t& end_offset) {
uint64_t start_updated_offset = start_offset;
// readahead_cache_lookup_ can be set false, if after Seek and Next
// there is SeekForPrev or any other backward operation.
if (!readahead_cache_lookup_) {
return;
}
size_t footer = table_->get_rep()->footer.GetBlockTrailerSize();
if (read_curr_block && !DoesContainBlockHandles() &&
IsNextBlockOutOfBound()) {
end_offset = index_iter_->value().handle.offset() + footer +
index_iter_->value().handle.size();
return;
}
uint64_t end_updated_offset = start_updated_offset;
bool found_first_miss_block = false;
size_t prev_handles_size;
// Initialize start and end offsets based on exisiting handles in the queue
// and read_curr_block argument passed.
InitializeStartAndEndOffsets(read_curr_block, found_first_miss_block,
start_updated_offset, end_updated_offset,
prev_handles_size);
while (index_iter_->Valid() && !is_index_out_of_bound_) {
BlockHandle block_handle = index_iter_->value().handle;
// Adding this data block exceeds end offset. So this data
// block won't be added.
// There can be a case where passed end offset is smaller than
// block_handle.size() + footer because of readahead_size truncated to
// upper_bound. So we prefer to read the block rather than skip it to avoid
// sync read calls in case of async_io.
if (start_updated_offset != end_updated_offset &&
(end_updated_offset + block_handle.size() + footer > end_offset)) {
break;
}
// For current data block, do the lookup in the cache. Lookup should pin the
// data block in cache.
BlockHandleInfo block_handle_info;
block_handle_info.handle_ = index_iter_->value().handle;
block_handle_info.SetFirstInternalKey(
index_iter_->value().first_internal_key);
end_updated_offset += footer + block_handle_info.handle_.size();
Status s = table_->LookupAndPinBlocksInCache<Block_kData>(
read_options_, block_handle,
&(block_handle_info.cachable_entry_).As<Block_kData>());
if (!s.ok()) {
break;
}
block_handle_info.is_cache_hit_ =
(block_handle_info.cachable_entry_.GetValue() ||
block_handle_info.cachable_entry_.GetCacheHandle());
// If this is the first miss block, update start offset to this block.
if (!found_first_miss_block && !block_handle_info.is_cache_hit_) {
found_first_miss_block = true;
start_updated_offset = block_handle_info.handle_.offset();
}
// Add the handle to the queue.
block_handles_.emplace_back(std::move(block_handle_info));
// Can't figure out for current block if current block
// is out of bound. But for next block we can find that.
// If curr block's index key >= iterate_upper_bound, it
// means all the keys in next block or above are out of
// bound.
if (IsNextBlockOutOfBound()) {
is_index_out_of_bound_ = true;
break;
}
index_iter_->Next();
is_index_at_curr_block_ = false;
};
if (found_first_miss_block) {
// Iterate cache hit block handles from the end till a Miss is there, to
// truncate and update the end offset till that Miss.
auto it = block_handles_.rbegin();
auto it_end =
block_handles_.rbegin() + (block_handles_.size() - prev_handles_size);
while (it != it_end && (*it).is_cache_hit_ &&
start_updated_offset != (*it).handle_.offset()) {
it++;
}
end_updated_offset = (*it).handle_.offset() + footer + (*it).handle_.size();
} else {
// Nothing to read. Can be because of IOError in index_iter_->Next() or
// reached upper_bound.
end_updated_offset = start_updated_offset;
}
end_offset = end_updated_offset;
start_offset = start_updated_offset;
ResetPreviousBlockOffset();
}
} // namespace ROCKSDB_NAMESPACE