// 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). #include "db/compaction/compaction_iterator.h" #include #include #include "db/blob/blob_fetcher.h" #include "db/blob/blob_file_builder.h" #include "db/blob/blob_index.h" #include "db/blob/prefetch_buffer_collection.h" #include "db/snapshot_checker.h" #include "db/wide/wide_column_serialization.h" #include "logging/logging.h" #include "port/likely.h" #include "rocksdb/listener.h" #include "table/internal_iterator.h" #include "test_util/sync_point.h" namespace ROCKSDB_NAMESPACE { CompactionIterator::CompactionIterator( InternalIterator* input, const Comparator* cmp, MergeHelper* merge_helper, SequenceNumber last_sequence, std::vector* snapshots, SequenceNumber earliest_write_conflict_snapshot, SequenceNumber job_snapshot, const SnapshotChecker* snapshot_checker, Env* env, bool report_detailed_time, bool expect_valid_internal_key, CompactionRangeDelAggregator* range_del_agg, BlobFileBuilder* blob_file_builder, bool allow_data_in_errors, bool enforce_single_del_contracts, const std::atomic& manual_compaction_canceled, const Compaction* compaction, const CompactionFilter* compaction_filter, const std::atomic* shutting_down, const std::shared_ptr info_log, const std::string* full_history_ts_low, const SequenceNumber preserve_time_min_seqno, const SequenceNumber preclude_last_level_min_seqno) : CompactionIterator( input, cmp, merge_helper, last_sequence, snapshots, earliest_write_conflict_snapshot, job_snapshot, snapshot_checker, env, report_detailed_time, expect_valid_internal_key, range_del_agg, blob_file_builder, allow_data_in_errors, enforce_single_del_contracts, manual_compaction_canceled, std::unique_ptr( compaction ? new RealCompaction(compaction) : nullptr), compaction_filter, shutting_down, info_log, full_history_ts_low, preserve_time_min_seqno, preclude_last_level_min_seqno) {} CompactionIterator::CompactionIterator( InternalIterator* input, const Comparator* cmp, MergeHelper* merge_helper, SequenceNumber /*last_sequence*/, std::vector* snapshots, SequenceNumber earliest_write_conflict_snapshot, SequenceNumber job_snapshot, const SnapshotChecker* snapshot_checker, Env* env, bool report_detailed_time, bool expect_valid_internal_key, CompactionRangeDelAggregator* range_del_agg, BlobFileBuilder* blob_file_builder, bool allow_data_in_errors, bool enforce_single_del_contracts, const std::atomic& manual_compaction_canceled, std::unique_ptr compaction, const CompactionFilter* compaction_filter, const std::atomic* shutting_down, const std::shared_ptr info_log, const std::string* full_history_ts_low, const SequenceNumber preserve_time_min_seqno, const SequenceNumber preclude_last_level_min_seqno) : input_(input, cmp, !compaction || compaction->DoesInputReferenceBlobFiles()), cmp_(cmp), merge_helper_(merge_helper), snapshots_(snapshots), earliest_write_conflict_snapshot_(earliest_write_conflict_snapshot), job_snapshot_(job_snapshot), snapshot_checker_(snapshot_checker), env_(env), clock_(env_->GetSystemClock().get()), report_detailed_time_(report_detailed_time), expect_valid_internal_key_(expect_valid_internal_key), range_del_agg_(range_del_agg), blob_file_builder_(blob_file_builder), compaction_(std::move(compaction)), compaction_filter_(compaction_filter), shutting_down_(shutting_down), manual_compaction_canceled_(manual_compaction_canceled), bottommost_level_(!compaction_ ? false : compaction_->bottommost_level() && !compaction_->allow_ingest_behind()), // snapshots_ cannot be nullptr, but we will assert later in the body of // the constructor. visible_at_tip_(snapshots_ ? snapshots_->empty() : false), earliest_snapshot_(!snapshots_ || snapshots_->empty() ? kMaxSequenceNumber : snapshots_->at(0)), info_log_(info_log), allow_data_in_errors_(allow_data_in_errors), enforce_single_del_contracts_(enforce_single_del_contracts), timestamp_size_(cmp_ ? cmp_->timestamp_size() : 0), full_history_ts_low_(full_history_ts_low), current_user_key_sequence_(0), current_user_key_snapshot_(0), merge_out_iter_(merge_helper_), blob_garbage_collection_cutoff_file_number_( ComputeBlobGarbageCollectionCutoffFileNumber(compaction_.get())), blob_fetcher_(CreateBlobFetcherIfNeeded(compaction_.get())), prefetch_buffers_( CreatePrefetchBufferCollectionIfNeeded(compaction_.get())), current_key_committed_(false), cmp_with_history_ts_low_(0), level_(compaction_ == nullptr ? 0 : compaction_->level()), preserve_time_min_seqno_(preserve_time_min_seqno), preclude_last_level_min_seqno_(preclude_last_level_min_seqno) { assert(snapshots_ != nullptr); assert(preserve_time_min_seqno_ <= preclude_last_level_min_seqno_); if (compaction_ != nullptr) { level_ptrs_ = std::vector(compaction_->number_levels(), 0); } #ifndef NDEBUG // findEarliestVisibleSnapshot assumes this ordering. for (size_t i = 1; i < snapshots_->size(); ++i) { assert(snapshots_->at(i - 1) < snapshots_->at(i)); } assert(timestamp_size_ == 0 || !full_history_ts_low_ || timestamp_size_ == full_history_ts_low_->size()); #endif input_.SetPinnedItersMgr(&pinned_iters_mgr_); // The default `merge_until_status_` does not need to be checked since it is // overwritten as soon as `MergeUntil()` is called merge_until_status_.PermitUncheckedError(); TEST_SYNC_POINT_CALLBACK("CompactionIterator:AfterInit", compaction_.get()); } CompactionIterator::~CompactionIterator() { // input_ Iterator lifetime is longer than pinned_iters_mgr_ lifetime input_.SetPinnedItersMgr(nullptr); } void CompactionIterator::ResetRecordCounts() { iter_stats_.num_record_drop_user = 0; iter_stats_.num_record_drop_hidden = 0; iter_stats_.num_record_drop_obsolete = 0; iter_stats_.num_record_drop_range_del = 0; iter_stats_.num_range_del_drop_obsolete = 0; iter_stats_.num_optimized_del_drop_obsolete = 0; } void CompactionIterator::SeekToFirst() { NextFromInput(); PrepareOutput(); } void CompactionIterator::Next() { // If there is a merge output, return it before continuing to process the // input. if (merge_out_iter_.Valid()) { merge_out_iter_.Next(); // Check if we returned all records of the merge output. if (merge_out_iter_.Valid()) { key_ = merge_out_iter_.key(); value_ = merge_out_iter_.value(); Status s = ParseInternalKey(key_, &ikey_, allow_data_in_errors_); // MergeUntil stops when it encounters a corrupt key and does not // include them in the result, so we expect the keys here to be valid. if (!s.ok()) { ROCKS_LOG_FATAL( info_log_, "Invalid ikey %s in compaction. %s", allow_data_in_errors_ ? key_.ToString(true).c_str() : "hidden", s.getState()); assert(false); } // Keep current_key_ in sync. if (0 == timestamp_size_) { current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); } else { Slice ts = ikey_.GetTimestamp(timestamp_size_); current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type, &ts); } key_ = current_key_.GetInternalKey(); ikey_.user_key = current_key_.GetUserKey(); validity_info_.SetValid(ValidContext::kMerge1); } else { if (merge_until_status_.IsMergeInProgress()) { // `Status::MergeInProgress()` tells us that the previous `MergeUntil()` // produced only merge operands. Those merge operands were accessed and // written out using `merge_out_iter_`. Since `merge_out_iter_` is // exhausted at this point, all merge operands have been written out. // // Still, there may be a base value (PUT, DELETE, SINGLEDEL, etc.) that // needs to be written out. Normally, `CompactionIterator` would skip it // on the basis that it has already output something in the same // snapshot stripe. To prevent this, we reset `has_current_user_key_` to // trick the future iteration from finding out the snapshot stripe is // unchanged. has_current_user_key_ = false; } // We consumed all pinned merge operands, release pinned iterators pinned_iters_mgr_.ReleasePinnedData(); // MergeHelper moves the iterator to the first record after the merged // records, so even though we reached the end of the merge output, we do // not want to advance the iterator. NextFromInput(); } } else { // Only advance the input iterator if there is no merge output and the // iterator is not already at the next record. if (!at_next_) { AdvanceInputIter(); } NextFromInput(); } if (Valid()) { // Record that we've outputted a record for the current key. has_outputted_key_ = true; } PrepareOutput(); } bool CompactionIterator::InvokeFilterIfNeeded(bool* need_skip, Slice* skip_until) { if (!compaction_filter_) { return true; } if (ikey_.type != kTypeValue && ikey_.type != kTypeBlobIndex && ikey_.type != kTypeWideColumnEntity) { return true; } CompactionFilter::Decision decision = CompactionFilter::Decision::kUndetermined; CompactionFilter::ValueType value_type = ikey_.type == kTypeValue ? CompactionFilter::ValueType::kValue : ikey_.type == kTypeBlobIndex ? CompactionFilter::ValueType::kBlobIndex : CompactionFilter::ValueType::kWideColumnEntity; // Hack: pass internal key to BlobIndexCompactionFilter since it needs // to get sequence number. assert(compaction_filter_); const Slice& filter_key = (ikey_.type != kTypeBlobIndex || !compaction_filter_->IsStackedBlobDbInternalCompactionFilter()) ? ikey_.user_key : key_; compaction_filter_value_.clear(); compaction_filter_skip_until_.Clear(); std::vector> new_columns; { StopWatchNano timer(clock_, report_detailed_time_); if (ikey_.type == kTypeBlobIndex) { decision = compaction_filter_->FilterBlobByKey( level_, filter_key, &compaction_filter_value_, compaction_filter_skip_until_.rep()); if (decision == CompactionFilter::Decision::kUndetermined && !compaction_filter_->IsStackedBlobDbInternalCompactionFilter()) { if (!compaction_) { status_ = Status::Corruption("Unexpected blob index outside of compaction"); validity_info_.Invalidate(); return false; } TEST_SYNC_POINT_CALLBACK( "CompactionIterator::InvokeFilterIfNeeded::TamperWithBlobIndex", &value_); // For integrated BlobDB impl, CompactionIterator reads blob value. // For Stacked BlobDB impl, the corresponding CompactionFilter's // FilterV2 method should read the blob value. BlobIndex blob_index; Status s = blob_index.DecodeFrom(value_); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return false; } FilePrefetchBuffer* prefetch_buffer = prefetch_buffers_ ? prefetch_buffers_->GetOrCreatePrefetchBuffer( blob_index.file_number()) : nullptr; uint64_t bytes_read = 0; assert(blob_fetcher_); s = blob_fetcher_->FetchBlob(ikey_.user_key, blob_index, prefetch_buffer, &blob_value_, &bytes_read); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return false; } ++iter_stats_.num_blobs_read; iter_stats_.total_blob_bytes_read += bytes_read; value_type = CompactionFilter::ValueType::kValue; } } if (decision == CompactionFilter::Decision::kUndetermined) { const Slice* existing_val = nullptr; const WideColumns* existing_col = nullptr; WideColumns existing_columns; if (ikey_.type != kTypeWideColumnEntity) { if (!blob_value_.empty()) { existing_val = &blob_value_; } else { existing_val = &value_; } } else { Slice value_copy = value_; const Status s = WideColumnSerialization::Deserialize(value_copy, existing_columns); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return false; } existing_col = &existing_columns; } decision = compaction_filter_->FilterV3( level_, filter_key, value_type, existing_val, existing_col, &compaction_filter_value_, &new_columns, compaction_filter_skip_until_.rep()); } iter_stats_.total_filter_time += env_ != nullptr && report_detailed_time_ ? timer.ElapsedNanos() : 0; } if (decision == CompactionFilter::Decision::kUndetermined) { // Should not reach here, since FilterV2/FilterV3 should never return // kUndetermined. status_ = Status::NotSupported( "FilterV2/FilterV3 should never return kUndetermined"); validity_info_.Invalidate(); return false; } if (decision == CompactionFilter::Decision::kRemoveAndSkipUntil && cmp_->Compare(*compaction_filter_skip_until_.rep(), ikey_.user_key) <= 0) { // Can't skip to a key smaller than the current one. // Keep the key as per FilterV2/FilterV3 documentation. decision = CompactionFilter::Decision::kKeep; } if (decision == CompactionFilter::Decision::kRemove) { // convert the current key to a delete; key_ is pointing into // current_key_ at this point, so updating current_key_ updates key() ikey_.type = kTypeDeletion; current_key_.UpdateInternalKey(ikey_.sequence, kTypeDeletion); // no value associated with delete value_.clear(); iter_stats_.num_record_drop_user++; } else if (decision == CompactionFilter::Decision::kPurge) { // convert the current key to a single delete; key_ is pointing into // current_key_ at this point, so updating current_key_ updates key() ikey_.type = kTypeSingleDeletion; current_key_.UpdateInternalKey(ikey_.sequence, kTypeSingleDeletion); // no value associated with single delete value_.clear(); iter_stats_.num_record_drop_user++; } else if (decision == CompactionFilter::Decision::kChangeValue) { if (ikey_.type != kTypeValue) { ikey_.type = kTypeValue; current_key_.UpdateInternalKey(ikey_.sequence, kTypeValue); } value_ = compaction_filter_value_; } else if (decision == CompactionFilter::Decision::kRemoveAndSkipUntil) { *need_skip = true; compaction_filter_skip_until_.ConvertFromUserKey(kMaxSequenceNumber, kValueTypeForSeek); *skip_until = compaction_filter_skip_until_.Encode(); } else if (decision == CompactionFilter::Decision::kChangeBlobIndex) { // Only the StackableDB-based BlobDB impl's compaction filter should return // kChangeBlobIndex. Decision about rewriting blob and changing blob index // in the integrated BlobDB impl is made in subsequent call to // PrepareOutput() and its callees. if (!compaction_filter_->IsStackedBlobDbInternalCompactionFilter()) { status_ = Status::NotSupported( "Only stacked BlobDB's internal compaction filter can return " "kChangeBlobIndex."); validity_info_.Invalidate(); return false; } if (ikey_.type != kTypeBlobIndex) { ikey_.type = kTypeBlobIndex; current_key_.UpdateInternalKey(ikey_.sequence, kTypeBlobIndex); } value_ = compaction_filter_value_; } else if (decision == CompactionFilter::Decision::kIOError) { if (!compaction_filter_->IsStackedBlobDbInternalCompactionFilter()) { status_ = Status::NotSupported( "CompactionFilter for integrated BlobDB should not return kIOError"); validity_info_.Invalidate(); return false; } status_ = Status::IOError("Failed to access blob during compaction filter"); validity_info_.Invalidate(); return false; } else if (decision == CompactionFilter::Decision::kChangeWideColumnEntity) { WideColumns sorted_columns; sorted_columns.reserve(new_columns.size()); for (const auto& column : new_columns) { sorted_columns.emplace_back(column.first, column.second); } std::sort(sorted_columns.begin(), sorted_columns.end(), [](const WideColumn& lhs, const WideColumn& rhs) { return lhs.name().compare(rhs.name()) < 0; }); { const Status s = WideColumnSerialization::Serialize( sorted_columns, compaction_filter_value_); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return false; } } if (ikey_.type != kTypeWideColumnEntity) { ikey_.type = kTypeWideColumnEntity; current_key_.UpdateInternalKey(ikey_.sequence, kTypeWideColumnEntity); } value_ = compaction_filter_value_; } return true; } void CompactionIterator::NextFromInput() { at_next_ = false; validity_info_.Invalidate(); while (!Valid() && input_.Valid() && !IsPausingManualCompaction() && !IsShuttingDown()) { key_ = input_.key(); value_ = input_.value(); blob_value_.Reset(); iter_stats_.num_input_records++; is_range_del_ = input_.IsDeleteRangeSentinelKey(); Status pik_status = ParseInternalKey(key_, &ikey_, allow_data_in_errors_); if (!pik_status.ok()) { iter_stats_.num_input_corrupt_records++; // If `expect_valid_internal_key_` is false, return the corrupted key // and let the caller decide what to do with it. if (expect_valid_internal_key_) { status_ = pik_status; return; } key_ = current_key_.SetInternalKey(key_); has_current_user_key_ = false; current_user_key_sequence_ = kMaxSequenceNumber; current_user_key_snapshot_ = 0; validity_info_.SetValid(ValidContext::kParseKeyError); break; } TEST_SYNC_POINT_CALLBACK("CompactionIterator:ProcessKV", &ikey_); if (is_range_del_) { validity_info_.SetValid(kRangeDeletion); break; } // Update input statistics if (ikey_.type == kTypeDeletion || ikey_.type == kTypeSingleDeletion || ikey_.type == kTypeDeletionWithTimestamp) { iter_stats_.num_input_deletion_records++; } iter_stats_.total_input_raw_key_bytes += key_.size(); iter_stats_.total_input_raw_value_bytes += value_.size(); // If need_skip is true, we should seek the input iterator // to internal key skip_until and continue from there. bool need_skip = false; // Points either into compaction_filter_skip_until_ or into // merge_helper_->compaction_filter_skip_until_. Slice skip_until; bool user_key_equal_without_ts = false; int cmp_ts = 0; if (has_current_user_key_) { user_key_equal_without_ts = cmp_->EqualWithoutTimestamp(ikey_.user_key, current_user_key_); // if timestamp_size_ > 0, then curr_ts_ has been initialized by a // previous key. cmp_ts = timestamp_size_ ? cmp_->CompareTimestamp( ExtractTimestampFromUserKey( ikey_.user_key, timestamp_size_), curr_ts_) : 0; } // Check whether the user key changed. After this if statement current_key_ // is a copy of the current input key (maybe converted to a delete by the // compaction filter). ikey_.user_key is pointing to the copy. if (!has_current_user_key_ || !user_key_equal_without_ts || cmp_ts != 0) { // First occurrence of this user key // Copy key for output key_ = current_key_.SetInternalKey(key_, &ikey_); int prev_cmp_with_ts_low = !full_history_ts_low_ ? 0 : curr_ts_.empty() ? 0 : cmp_->CompareTimestamp(curr_ts_, *full_history_ts_low_); // If timestamp_size_ > 0, then copy from ikey_ to curr_ts_ for the use // in next iteration to compare with the timestamp of next key. UpdateTimestampAndCompareWithFullHistoryLow(); // If // (1) !has_current_user_key_, OR // (2) timestamp is disabled, OR // (3) all history will be preserved, OR // (4) user key (excluding timestamp) is different from previous key, OR // (5) timestamp is NO older than *full_history_ts_low_, OR // (6) timestamp is the largest one older than full_history_ts_low_, // then current_user_key_ must be treated as a different user key. // This means, if a user key (excluding ts) is the same as the previous // user key, and its ts is older than *full_history_ts_low_, then we // consider this key for GC, e.g. it may be dropped if certain conditions // match. if (!has_current_user_key_ || !timestamp_size_ || !full_history_ts_low_ || !user_key_equal_without_ts || cmp_with_history_ts_low_ >= 0 || prev_cmp_with_ts_low >= 0) { // Initialize for future comparison for rule (A) and etc. current_user_key_sequence_ = kMaxSequenceNumber; current_user_key_snapshot_ = 0; has_current_user_key_ = true; } current_user_key_ = ikey_.user_key; has_outputted_key_ = false; last_key_seq_zeroed_ = false; current_key_committed_ = KeyCommitted(ikey_.sequence); // Apply the compaction filter to the first committed version of the user // key. if (current_key_committed_ && !InvokeFilterIfNeeded(&need_skip, &skip_until)) { break; } } else { // Update the current key to reflect the new sequence number/type without // copying the user key. // TODO(rven): Compaction filter does not process keys in this path // Need to have the compaction filter process multiple versions // if we have versions on both sides of a snapshot current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); key_ = current_key_.GetInternalKey(); ikey_.user_key = current_key_.GetUserKey(); // Note that newer version of a key is ordered before older versions. If a // newer version of a key is committed, so as the older version. No need // to query snapshot_checker_ in that case. if (UNLIKELY(!current_key_committed_)) { assert(snapshot_checker_ != nullptr); current_key_committed_ = KeyCommitted(ikey_.sequence); // Apply the compaction filter to the first committed version of the // user key. if (current_key_committed_ && !InvokeFilterIfNeeded(&need_skip, &skip_until)) { break; } } } if (UNLIKELY(!current_key_committed_)) { assert(snapshot_checker_ != nullptr); validity_info_.SetValid(ValidContext::kCurrentKeyUncommitted); break; } // If there are no snapshots, then this kv affect visibility at tip. // Otherwise, search though all existing snapshots to find the earliest // snapshot that is affected by this kv. SequenceNumber last_sequence = current_user_key_sequence_; current_user_key_sequence_ = ikey_.sequence; SequenceNumber last_snapshot = current_user_key_snapshot_; SequenceNumber prev_snapshot = 0; // 0 means no previous snapshot current_user_key_snapshot_ = visible_at_tip_ ? earliest_snapshot_ : findEarliestVisibleSnapshot(ikey_.sequence, &prev_snapshot); if (need_skip) { // This case is handled below. } else if (clear_and_output_next_key_) { // In the previous iteration we encountered a single delete that we could // not compact out. We will keep this Put, but can drop it's data. // (See Optimization 3, below.) if (ikey_.type != kTypeValue && ikey_.type != kTypeBlobIndex && ikey_.type != kTypeWideColumnEntity) { ROCKS_LOG_FATAL(info_log_, "Unexpected key %s for compaction output", ikey_.DebugString(allow_data_in_errors_, true).c_str()); assert(false); } if (current_user_key_snapshot_ < last_snapshot) { ROCKS_LOG_FATAL(info_log_, "key %s, current_user_key_snapshot_ (%" PRIu64 ") < last_snapshot (%" PRIu64 ")", ikey_.DebugString(allow_data_in_errors_, true).c_str(), current_user_key_snapshot_, last_snapshot); assert(false); } if (ikey_.type == kTypeBlobIndex || ikey_.type == kTypeWideColumnEntity) { ikey_.type = kTypeValue; current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); } value_.clear(); validity_info_.SetValid(ValidContext::kKeepSDAndClearPut); clear_and_output_next_key_ = false; } else if (ikey_.type == kTypeSingleDeletion) { // We can compact out a SingleDelete if: // 1) We encounter the corresponding PUT -OR- we know that this key // doesn't appear past this output level // =AND= // 2) We've already returned a record in this snapshot -OR- // there are no earlier earliest_write_conflict_snapshot. // // A note about 2) above: // we try to determine whether there is any earlier write conflict // checking snapshot by calling DefinitelyInSnapshot() with seq and // earliest_write_conflict_snapshot as arguments. For write-prepared // and write-unprepared transactions, if earliest_write_conflict_snapshot // is evicted from WritePreparedTxnDB::commit_cache, then // DefinitelyInSnapshot(seq, earliest_write_conflict_snapshot) returns // false, even if the seq is actually visible within // earliest_write_conflict_snapshot. Consequently, CompactionIterator // may try to zero out its sequence number, thus hitting assertion error // in debug mode or cause incorrect DBIter return result. // We observe that earliest_write_conflict_snapshot >= earliest_snapshot, // and the seq zeroing logic depends on // DefinitelyInSnapshot(seq, earliest_snapshot). Therefore, if we cannot // determine whether seq is **definitely** in // earliest_write_conflict_snapshot, then we can additionally check if // seq is definitely in earliest_snapshot. If the latter holds, then the // former holds too. // // Rule 1 is needed for SingleDelete correctness. Rule 2 is needed to // allow Transactions to do write-conflict checking (if we compacted away // all keys, then we wouldn't know that a write happened in this // snapshot). If there is no earlier snapshot, then we know that there // are no active transactions that need to know about any writes. // // Optimization 3: // If we encounter a SingleDelete followed by a PUT and Rule 2 is NOT // true, then we must output a SingleDelete. In this case, we will decide // to also output the PUT. While we are compacting less by outputting the // PUT now, hopefully this will lead to better compaction in the future // when Rule 2 is later true (Ie, We are hoping we can later compact out // both the SingleDelete and the Put, while we couldn't if we only // outputted the SingleDelete now). // In this case, we can save space by removing the PUT's value as it will // never be read. // // Deletes and Merges are not supported on the same key that has a // SingleDelete as it is not possible to correctly do any partial // compaction of such a combination of operations. The result of mixing // those operations for a given key is documented as being undefined. So // we can choose how to handle such a combinations of operations. We will // try to compact out as much as we can in these cases. // We will report counts on these anomalous cases. // // Note: If timestamp is enabled, then record will be eligible for // deletion, only if, along with above conditions (Rule 1 and Rule 2) // full_history_ts_low_ is specified and timestamp for that key is less // than *full_history_ts_low_. If it's not eligible for deletion, then we // will output the SingleDelete. For Optimization 3 also, if // full_history_ts_low_ is specified and timestamp for the key is less // than *full_history_ts_low_ then only optimization will be applied. // The easiest way to process a SingleDelete during iteration is to peek // ahead at the next key. const bool is_timestamp_eligible_for_gc = (timestamp_size_ == 0 || (full_history_ts_low_ && cmp_with_history_ts_low_ < 0)); ParsedInternalKey next_ikey; AdvanceInputIter(); while (input_.Valid() && input_.IsDeleteRangeSentinelKey() && ParseInternalKey(input_.key(), &next_ikey, allow_data_in_errors_) .ok() && cmp_->EqualWithoutTimestamp(ikey_.user_key, next_ikey.user_key)) { // skip range tombstone start keys with the same user key // since they are not "real" point keys. AdvanceInputIter(); } // Check whether the next key exists, is not corrupt, and is the same key // as the single delete. if (input_.Valid() && ParseInternalKey(input_.key(), &next_ikey, allow_data_in_errors_) .ok() && cmp_->EqualWithoutTimestamp(ikey_.user_key, next_ikey.user_key)) { assert(!input_.IsDeleteRangeSentinelKey()); #ifndef NDEBUG const Compaction* c = compaction_ ? compaction_->real_compaction() : nullptr; #endif TEST_SYNC_POINT_CALLBACK( "CompactionIterator::NextFromInput:SingleDelete:1", const_cast(c)); if (last_key_seq_zeroed_) { ++iter_stats_.num_record_drop_hidden; ++iter_stats_.num_record_drop_obsolete; assert(bottommost_level_); AdvanceInputIter(); } else if (prev_snapshot == 0 || DefinitelyNotInSnapshot(next_ikey.sequence, prev_snapshot)) { // Check whether the next key belongs to the same snapshot as the // SingleDelete. TEST_SYNC_POINT_CALLBACK( "CompactionIterator::NextFromInput:SingleDelete:2", nullptr); if (next_ikey.type == kTypeSingleDeletion) { // We encountered two SingleDeletes for same key in a row. This // could be due to unexpected user input. If write-(un)prepared // transaction is used, this could also be due to releasing an old // snapshot between a Put and its matching SingleDelete. // Skip the first SingleDelete and let the next iteration decide // how to handle the second SingleDelete. // First SingleDelete has been skipped since we already called // input_.Next(). ++iter_stats_.num_record_drop_obsolete; ++iter_stats_.num_single_del_mismatch; } else if (next_ikey.type == kTypeDeletion) { std::ostringstream oss; oss << "Found SD and type: " << static_cast(next_ikey.type) << " on the same key, violating the contract " "of SingleDelete. Check your application to make sure the " "application does not mix SingleDelete and Delete for " "the same key. If you are using " "write-prepared/write-unprepared transactions, and use " "SingleDelete to delete certain keys, then make sure " "TransactionDBOptions::rollback_deletion_type_callback is " "configured properly. Mixing SD and DEL can lead to " "undefined behaviors"; ++iter_stats_.num_record_drop_obsolete; ++iter_stats_.num_single_del_mismatch; if (enforce_single_del_contracts_) { ROCKS_LOG_ERROR(info_log_, "%s", oss.str().c_str()); validity_info_.Invalidate(); status_ = Status::Corruption(oss.str()); return; } ROCKS_LOG_WARN(info_log_, "%s", oss.str().c_str()); } else if (!is_timestamp_eligible_for_gc) { // We cannot drop the SingleDelete as timestamp is enabled, and // timestamp of this key is greater than or equal to // *full_history_ts_low_. We will output the SingleDelete. validity_info_.SetValid(ValidContext::kKeepTsHistory); } else if (has_outputted_key_ || DefinitelyInSnapshot(ikey_.sequence, earliest_write_conflict_snapshot_) || (earliest_snapshot_ < earliest_write_conflict_snapshot_ && DefinitelyInSnapshot(ikey_.sequence, earliest_snapshot_))) { // Found a matching value, we can drop the single delete and the // value. It is safe to drop both records since we've already // outputted a key in this snapshot, or there is no earlier // snapshot (Rule 2 above). // Note: it doesn't matter whether the second key is a Put or if it // is an unexpected Merge or Delete. We will compact it out // either way. We will maintain counts of how many mismatches // happened if (next_ikey.type != kTypeValue && next_ikey.type != kTypeBlobIndex && next_ikey.type != kTypeWideColumnEntity) { ++iter_stats_.num_single_del_mismatch; } ++iter_stats_.num_record_drop_hidden; ++iter_stats_.num_record_drop_obsolete; // Already called input_.Next() once. Call it a second time to // skip past the second key. AdvanceInputIter(); } else { // Found a matching value, but we cannot drop both keys since // there is an earlier snapshot and we need to leave behind a record // to know that a write happened in this snapshot (Rule 2 above). // Clear the value and output the SingleDelete. (The value will be // outputted on the next iteration.) // Setting valid_ to true will output the current SingleDelete validity_info_.SetValid(ValidContext::kKeepSDForConflictCheck); // Set up the Put to be outputted in the next iteration. // (Optimization 3). clear_and_output_next_key_ = true; TEST_SYNC_POINT_CALLBACK( "CompactionIterator::NextFromInput:KeepSDForWW", /*arg=*/nullptr); } } else { // We hit the next snapshot without hitting a put, so the iterator // returns the single delete. validity_info_.SetValid(ValidContext::kKeepSDForSnapshot); TEST_SYNC_POINT_CALLBACK( "CompactionIterator::NextFromInput:SingleDelete:3", const_cast(c)); } } else { // We are at the end of the input, could not parse the next key, or hit // a different key. The iterator returns the single delete if the key // possibly exists beyond the current output level. We set // has_current_user_key to false so that if the iterator is at the next // key, we do not compare it again against the previous key at the next // iteration. If the next key is corrupt, we return before the // comparison, so the value of has_current_user_key does not matter. has_current_user_key_ = false; if (compaction_ != nullptr && DefinitelyInSnapshot(ikey_.sequence, earliest_snapshot_) && compaction_->KeyNotExistsBeyondOutputLevel(ikey_.user_key, &level_ptrs_) && is_timestamp_eligible_for_gc) { // Key doesn't exist outside of this range. // Can compact out this SingleDelete. ++iter_stats_.num_record_drop_obsolete; ++iter_stats_.num_single_del_fallthru; if (!bottommost_level_) { ++iter_stats_.num_optimized_del_drop_obsolete; } } else if (last_key_seq_zeroed_) { // Skip. ++iter_stats_.num_record_drop_hidden; ++iter_stats_.num_record_drop_obsolete; assert(bottommost_level_); } else { // Output SingleDelete validity_info_.SetValid(ValidContext::kKeepSD); } } if (Valid()) { at_next_ = true; } } else if (last_snapshot == current_user_key_snapshot_ || (last_snapshot > 0 && last_snapshot < current_user_key_snapshot_)) { // If the earliest snapshot is which this key is visible in // is the same as the visibility of a previous instance of the // same key, then this kv is not visible in any snapshot. // Hidden by an newer entry for same user key // // Note: Dropping this key will not affect TransactionDB write-conflict // checking since there has already been a record returned for this key // in this snapshot. if (last_sequence < current_user_key_sequence_) { ROCKS_LOG_FATAL(info_log_, "key %s, last_sequence (%" PRIu64 ") < current_user_key_sequence_ (%" PRIu64 ")", ikey_.DebugString(allow_data_in_errors_, true).c_str(), last_sequence, current_user_key_sequence_); assert(false); } ++iter_stats_.num_record_drop_hidden; // rule (A) AdvanceInputIter(); } else if (compaction_ != nullptr && (ikey_.type == kTypeDeletion || (ikey_.type == kTypeDeletionWithTimestamp && cmp_with_history_ts_low_ < 0)) && DefinitelyInSnapshot(ikey_.sequence, earliest_snapshot_) && compaction_->KeyNotExistsBeyondOutputLevel(ikey_.user_key, &level_ptrs_)) { // TODO(noetzli): This is the only place where we use compaction_ // (besides the constructor). We should probably get rid of this // dependency and find a way to do similar filtering during flushes. // // For this user key: // (1) there is no data in higher levels // (2) data in lower levels will have larger sequence numbers // (3) data in layers that are being compacted here and have // smaller sequence numbers will be dropped in the next // few iterations of this loop (by rule (A) above). // Therefore this deletion marker is obsolete and can be dropped. // // Note: Dropping this Delete will not affect TransactionDB // write-conflict checking since it is earlier than any snapshot. // // It seems that we can also drop deletion later than earliest snapshot // given that: // (1) The deletion is earlier than earliest_write_conflict_snapshot, and // (2) No value exist earlier than the deletion. // // Note also that a deletion marker of type kTypeDeletionWithTimestamp // will be treated as a different user key unless the timestamp is older // than *full_history_ts_low_. ++iter_stats_.num_record_drop_obsolete; if (!bottommost_level_) { ++iter_stats_.num_optimized_del_drop_obsolete; } AdvanceInputIter(); } else if ((ikey_.type == kTypeDeletion || (ikey_.type == kTypeDeletionWithTimestamp && cmp_with_history_ts_low_ < 0)) && bottommost_level_) { // Handle the case where we have a delete key at the bottom most level // We can skip outputting the key iff there are no subsequent puts for // this key assert(!compaction_ || compaction_->KeyNotExistsBeyondOutputLevel( ikey_.user_key, &level_ptrs_)); ParsedInternalKey next_ikey; AdvanceInputIter(); #ifndef NDEBUG const Compaction* c = compaction_ ? compaction_->real_compaction() : nullptr; #endif TEST_SYNC_POINT_CALLBACK( "CompactionIterator::NextFromInput:BottommostDelete:1", const_cast(c)); // Skip over all versions of this key that happen to occur in the same // snapshot range as the delete. // // Note that a deletion marker of type kTypeDeletionWithTimestamp will be // considered to have a different user key unless the timestamp is older // than *full_history_ts_low_. // // Range tombstone start keys are skipped as they are not "real" keys. while (!IsPausingManualCompaction() && !IsShuttingDown() && input_.Valid() && (ParseInternalKey(input_.key(), &next_ikey, allow_data_in_errors_) .ok()) && cmp_->EqualWithoutTimestamp(ikey_.user_key, next_ikey.user_key) && (prev_snapshot == 0 || input_.IsDeleteRangeSentinelKey() || DefinitelyNotInSnapshot(next_ikey.sequence, prev_snapshot))) { AdvanceInputIter(); } // If you find you still need to output a row with this key, we need to // output the delete too if (input_.Valid() && (ParseInternalKey(input_.key(), &next_ikey, allow_data_in_errors_) .ok()) && cmp_->EqualWithoutTimestamp(ikey_.user_key, next_ikey.user_key)) { validity_info_.SetValid(ValidContext::kKeepDel); at_next_ = true; } } else if (ikey_.type == kTypeMerge) { if (!merge_helper_->HasOperator()) { status_ = Status::InvalidArgument( "merge_operator is not properly initialized."); return; } pinned_iters_mgr_.StartPinning(); // We know the merge type entry is not hidden, otherwise we would // have hit (A) // We encapsulate the merge related state machine in a different // object to minimize change to the existing flow. merge_until_status_ = merge_helper_->MergeUntil( &input_, range_del_agg_, prev_snapshot, bottommost_level_, allow_data_in_errors_, blob_fetcher_.get(), full_history_ts_low_, prefetch_buffers_.get(), &iter_stats_); merge_out_iter_.SeekToFirst(); if (!merge_until_status_.ok() && !merge_until_status_.IsMergeInProgress()) { status_ = merge_until_status_; return; } else if (merge_out_iter_.Valid()) { // NOTE: key, value, and ikey_ refer to old entries. // These will be correctly set below. key_ = merge_out_iter_.key(); value_ = merge_out_iter_.value(); pik_status = ParseInternalKey(key_, &ikey_, allow_data_in_errors_); // MergeUntil stops when it encounters a corrupt key and does not // include them in the result, so we expect the keys here to valid. if (!pik_status.ok()) { ROCKS_LOG_FATAL( info_log_, "Invalid key %s in compaction. %s", allow_data_in_errors_ ? key_.ToString(true).c_str() : "hidden", pik_status.getState()); assert(false); } // Keep current_key_ in sync. current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); key_ = current_key_.GetInternalKey(); ikey_.user_key = current_key_.GetUserKey(); validity_info_.SetValid(ValidContext::kMerge2); } else { // all merge operands were filtered out. reset the user key, since the // batch consumed by the merge operator should not shadow any keys // coming after the merges has_current_user_key_ = false; pinned_iters_mgr_.ReleasePinnedData(); if (merge_helper_->FilteredUntil(&skip_until)) { need_skip = true; } } } else { // 1. new user key -OR- // 2. different snapshot stripe // If user-defined timestamp is enabled, we consider keys for GC if they // are below history_ts_low_. CompactionRangeDelAggregator::ShouldDelete() // only considers range deletions that are at or below history_ts_low_ and // trim_ts_. We drop keys here that are below history_ts_low_ and are // covered by a range tombstone that is at or below history_ts_low_ and // trim_ts. bool should_delete = false; if (!timestamp_size_ || cmp_with_history_ts_low_ < 0) { should_delete = range_del_agg_->ShouldDelete( key_, RangeDelPositioningMode::kForwardTraversal); } if (should_delete) { ++iter_stats_.num_record_drop_hidden; ++iter_stats_.num_record_drop_range_del; AdvanceInputIter(); } else { validity_info_.SetValid(ValidContext::kNewUserKey); } } if (need_skip) { SkipUntil(skip_until); } } if (!Valid() && IsShuttingDown()) { status_ = Status::ShutdownInProgress(); } if (IsPausingManualCompaction()) { status_ = Status::Incomplete(Status::SubCode::kManualCompactionPaused); } // Propagate corruption status from memtable itereator if (!input_.Valid() && input_.status().IsCorruption()) { status_ = input_.status(); } } bool CompactionIterator::ExtractLargeValueIfNeededImpl() { if (!blob_file_builder_) { return false; } blob_index_.clear(); const Status s = blob_file_builder_->Add(user_key(), value_, &blob_index_); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return false; } if (blob_index_.empty()) { return false; } value_ = blob_index_; return true; } void CompactionIterator::ExtractLargeValueIfNeeded() { assert(ikey_.type == kTypeValue); if (!ExtractLargeValueIfNeededImpl()) { return; } ikey_.type = kTypeBlobIndex; current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); } void CompactionIterator::GarbageCollectBlobIfNeeded() { assert(ikey_.type == kTypeBlobIndex); if (!compaction_) { return; } // GC for integrated BlobDB if (compaction_->enable_blob_garbage_collection()) { TEST_SYNC_POINT_CALLBACK( "CompactionIterator::GarbageCollectBlobIfNeeded::TamperWithBlobIndex", &value_); BlobIndex blob_index; { const Status s = blob_index.DecodeFrom(value_); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return; } } if (blob_index.file_number() >= blob_garbage_collection_cutoff_file_number_) { return; } FilePrefetchBuffer* prefetch_buffer = prefetch_buffers_ ? prefetch_buffers_->GetOrCreatePrefetchBuffer( blob_index.file_number()) : nullptr; uint64_t bytes_read = 0; { assert(blob_fetcher_); const Status s = blob_fetcher_->FetchBlob( user_key(), blob_index, prefetch_buffer, &blob_value_, &bytes_read); if (!s.ok()) { status_ = s; validity_info_.Invalidate(); return; } } ++iter_stats_.num_blobs_read; iter_stats_.total_blob_bytes_read += bytes_read; ++iter_stats_.num_blobs_relocated; iter_stats_.total_blob_bytes_relocated += blob_index.size(); value_ = blob_value_; if (ExtractLargeValueIfNeededImpl()) { return; } ikey_.type = kTypeValue; current_key_.UpdateInternalKey(ikey_.sequence, ikey_.type); return; } // GC for stacked BlobDB if (compaction_filter_ && compaction_filter_->IsStackedBlobDbInternalCompactionFilter()) { const auto blob_decision = compaction_filter_->PrepareBlobOutput( user_key(), value_, &compaction_filter_value_); if (blob_decision == CompactionFilter::BlobDecision::kCorruption) { status_ = Status::Corruption("Corrupted blob reference encountered during GC"); validity_info_.Invalidate(); return; } if (blob_decision == CompactionFilter::BlobDecision::kIOError) { status_ = Status::IOError("Could not relocate blob during GC"); validity_info_.Invalidate(); return; } if (blob_decision == CompactionFilter::BlobDecision::kChangeValue) { value_ = compaction_filter_value_; return; } } } void CompactionIterator::DecideOutputLevel() { assert(compaction_->SupportsPerKeyPlacement()); output_to_penultimate_level_ = false; // if the key is newer than the cutoff sequence or within the earliest // snapshot, it should output to the penultimate level. if (ikey_.sequence > preclude_last_level_min_seqno_ || ikey_.sequence > earliest_snapshot_) { output_to_penultimate_level_ = true; } #ifndef NDEBUG // Could be overridden by unittest PerKeyPlacementContext context(level_, ikey_.user_key, value_, ikey_.sequence, output_to_penultimate_level_); TEST_SYNC_POINT_CALLBACK("CompactionIterator::PrepareOutput.context", &context); if (ikey_.sequence > earliest_snapshot_) { output_to_penultimate_level_ = true; } #endif // NDEBUG if (output_to_penultimate_level_) { // If it's decided to output to the penultimate level, but unsafe to do so, // still output to the last level. For example, moving the data from a lower // level to a higher level outside of the higher-level input key range is // considered unsafe, because the key may conflict with higher-level SSTs // not from this compaction. // TODO: add statistic for declined output_to_penultimate_level bool safe_to_penultimate_level = compaction_->WithinPenultimateLevelOutputRange(ikey_.user_key); if (!safe_to_penultimate_level) { output_to_penultimate_level_ = false; // It could happen when disable/enable `last_level_temperature` while // holding a snapshot. When `last_level_temperature` is not set // (==kUnknown), the data newer than any snapshot is pushed to the last // level, but when the per_key_placement feature is enabled on the fly, // the data later than the snapshot has to be moved to the penultimate // level, which may or may not be safe. So the user needs to make sure all // snapshot is released before enabling `last_level_temperature` feature // We will migrate the feature to `last_level_temperature` and maybe make // it not dynamically changeable. if (ikey_.sequence > earliest_snapshot_) { status_ = Status::Corruption( "Unsafe to store Seq later than snapshot in the last level if " "per_key_placement is enabled"); } } } } void CompactionIterator::PrepareOutput() { if (Valid()) { if (LIKELY(!is_range_del_)) { if (ikey_.type == kTypeValue) { ExtractLargeValueIfNeeded(); } else if (ikey_.type == kTypeBlobIndex) { GarbageCollectBlobIfNeeded(); } } if (compaction_ != nullptr && compaction_->SupportsPerKeyPlacement()) { DecideOutputLevel(); } // Zeroing out the sequence number leads to better compression. // If this is the bottommost level (no files in lower levels) // and the earliest snapshot is larger than this seqno // and the userkey differs from the last userkey in compaction // then we can squash the seqno to zero. // // This is safe for TransactionDB write-conflict checking since transactions // only care about sequence number larger than any active snapshots. // // Can we do the same for levels above bottom level as long as // KeyNotExistsBeyondOutputLevel() return true? if (Valid() && compaction_ != nullptr && !compaction_->allow_ingest_behind() && bottommost_level_ && DefinitelyInSnapshot(ikey_.sequence, earliest_snapshot_) && ikey_.type != kTypeMerge && current_key_committed_ && !output_to_penultimate_level_ && ikey_.sequence < preserve_time_min_seqno_ && !is_range_del_) { if (ikey_.type == kTypeDeletion || (ikey_.type == kTypeSingleDeletion && timestamp_size_ == 0)) { ROCKS_LOG_FATAL( info_log_, "Unexpected key %s for seq-zero optimization. " "earliest_snapshot %" PRIu64 ", earliest_write_conflict_snapshot %" PRIu64 " job_snapshot %" PRIu64 ". timestamp_size: %d full_history_ts_low_ %s. validity %x", ikey_.DebugString(allow_data_in_errors_, true).c_str(), earliest_snapshot_, earliest_write_conflict_snapshot_, job_snapshot_, static_cast(timestamp_size_), full_history_ts_low_ != nullptr ? Slice(*full_history_ts_low_).ToString(true).c_str() : "null", validity_info_.rep); assert(false); } ikey_.sequence = 0; last_key_seq_zeroed_ = true; TEST_SYNC_POINT_CALLBACK("CompactionIterator::PrepareOutput:ZeroingSeq", &ikey_); if (!timestamp_size_) { current_key_.UpdateInternalKey(0, ikey_.type); } else if (full_history_ts_low_ && cmp_with_history_ts_low_ < 0) { // We can also zero out timestamp for better compression. // For the same user key (excluding timestamp), the timestamp-based // history can be collapsed to save some space if the timestamp is // older than *full_history_ts_low_. const std::string kTsMin(timestamp_size_, static_cast(0)); const Slice ts_slice = kTsMin; ikey_.SetTimestamp(ts_slice); current_key_.UpdateInternalKey(0, ikey_.type, &ts_slice); } } } } inline SequenceNumber CompactionIterator::findEarliestVisibleSnapshot( SequenceNumber in, SequenceNumber* prev_snapshot) { assert(snapshots_->size()); if (snapshots_->size() == 0) { ROCKS_LOG_FATAL(info_log_, "No snapshot left in findEarliestVisibleSnapshot"); } auto snapshots_iter = std::lower_bound(snapshots_->begin(), snapshots_->end(), in); assert(prev_snapshot != nullptr); if (snapshots_iter == snapshots_->begin()) { *prev_snapshot = 0; } else { *prev_snapshot = *std::prev(snapshots_iter); if (*prev_snapshot >= in) { ROCKS_LOG_FATAL(info_log_, "*prev_snapshot (%" PRIu64 ") >= in (%" PRIu64 ") in findEarliestVisibleSnapshot", *prev_snapshot, in); assert(false); } } if (snapshot_checker_ == nullptr) { return snapshots_iter != snapshots_->end() ? *snapshots_iter : kMaxSequenceNumber; } bool has_released_snapshot = !released_snapshots_.empty(); for (; snapshots_iter != snapshots_->end(); ++snapshots_iter) { auto cur = *snapshots_iter; if (in > cur) { ROCKS_LOG_FATAL(info_log_, "in (%" PRIu64 ") > cur (%" PRIu64 ") in findEarliestVisibleSnapshot", in, cur); assert(false); } // Skip if cur is in released_snapshots. if (has_released_snapshot && released_snapshots_.count(cur) > 0) { continue; } auto res = snapshot_checker_->CheckInSnapshot(in, cur); if (res == SnapshotCheckerResult::kInSnapshot) { return cur; } else if (res == SnapshotCheckerResult::kSnapshotReleased) { released_snapshots_.insert(cur); } *prev_snapshot = cur; } return kMaxSequenceNumber; } uint64_t CompactionIterator::ComputeBlobGarbageCollectionCutoffFileNumber( const CompactionProxy* compaction) { if (!compaction) { return 0; } if (!compaction->enable_blob_garbage_collection()) { return 0; } const Version* const version = compaction->input_version(); assert(version); const VersionStorageInfo* const storage_info = version->storage_info(); assert(storage_info); const auto& blob_files = storage_info->GetBlobFiles(); const size_t cutoff_index = static_cast( compaction->blob_garbage_collection_age_cutoff() * blob_files.size()); if (cutoff_index >= blob_files.size()) { return std::numeric_limits::max(); } const auto& meta = blob_files[cutoff_index]; assert(meta); return meta->GetBlobFileNumber(); } std::unique_ptr CompactionIterator::CreateBlobFetcherIfNeeded( const CompactionProxy* compaction) { if (!compaction) { return nullptr; } const Version* const version = compaction->input_version(); if (!version) { return nullptr; } ReadOptions read_options; read_options.io_activity = Env::IOActivity::kCompaction; read_options.fill_cache = false; return std::unique_ptr(new BlobFetcher(version, read_options)); } std::unique_ptr CompactionIterator::CreatePrefetchBufferCollectionIfNeeded( const CompactionProxy* compaction) { if (!compaction) { return nullptr; } if (!compaction->input_version()) { return nullptr; } if (compaction->allow_mmap_reads()) { return nullptr; } const uint64_t readahead_size = compaction->blob_compaction_readahead_size(); if (!readahead_size) { return nullptr; } return std::unique_ptr( new PrefetchBufferCollection(readahead_size)); } } // namespace ROCKSDB_NAMESPACE