// 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. #pragma once #include #include #include "db/db_impl/db_impl.h" #include "db/range_del_aggregator.h" #include "memory/arena.h" #include "options/cf_options.h" #include "rocksdb/db.h" #include "rocksdb/iterator.h" #include "rocksdb/wide_columns.h" #include "table/iterator_wrapper.h" #include "util/autovector.h" namespace ROCKSDB_NAMESPACE { class Version; // This file declares the factory functions of DBIter, in its original form // or a wrapped form with class ArenaWrappedDBIter, which is defined here. // Class DBIter, which is declared and implemented inside db_iter.cc, is // an iterator that converts internal keys (yielded by an InternalIterator) // that were live at the specified sequence number into appropriate user // keys. // Each internal key consists of a user key, a sequence number, and a value // type. DBIter deals with multiple key versions, tombstones, merge operands, // etc, and exposes an Iterator. // For example, DBIter may wrap following InternalIterator: // user key: AAA value: v3 seqno: 100 type: Put // user key: AAA value: v2 seqno: 97 type: Put // user key: AAA value: v1 seqno: 95 type: Put // user key: BBB value: v1 seqno: 90 type: Put // user key: BBC value: N/A seqno: 98 type: Delete // user key: BBC value: v1 seqno: 95 type: Put // If the snapshot passed in is 102, then the DBIter is expected to // expose the following iterator: // key: AAA value: v3 // key: BBB value: v1 // If the snapshot passed in is 96, then it should expose: // key: AAA value: v1 // key: BBB value: v1 // key: BBC value: v1 // // Memtables and sstables that make the DB representation contain // (userkey,seq,type) => uservalue entries. DBIter // combines multiple entries for the same userkey found in the DB // representation into a single entry while accounting for sequence // numbers, deletion markers, overwrites, etc. class DBIter final : public Iterator { public: // The following is grossly complicated. TODO: clean it up // Which direction is the iterator currently moving? // (1) When moving forward: // (1a) if current_entry_is_merged_ = false, the internal iterator is // positioned at the exact entry that yields this->key(), this->value() // (1b) if current_entry_is_merged_ = true, the internal iterator is // positioned immediately after the last entry that contributed to the // current this->value(). That entry may or may not have key equal to // this->key(). // (2) When moving backwards, the internal iterator is positioned // just before all entries whose user key == this->key(). enum Direction : uint8_t { kForward, kReverse }; // LocalStatistics contain Statistics counters that will be aggregated per // each iterator instance and then will be sent to the global statistics when // the iterator is destroyed. // // The purpose of this approach is to avoid perf regression happening // when multiple threads bump the atomic counters from a DBIter::Next(). struct LocalStatistics { explicit LocalStatistics() { ResetCounters(); } void ResetCounters() { next_count_ = 0; next_found_count_ = 0; prev_count_ = 0; prev_found_count_ = 0; bytes_read_ = 0; skip_count_ = 0; } void BumpGlobalStatistics(Statistics* global_statistics) { RecordTick(global_statistics, NUMBER_DB_NEXT, next_count_); RecordTick(global_statistics, NUMBER_DB_NEXT_FOUND, next_found_count_); RecordTick(global_statistics, NUMBER_DB_PREV, prev_count_); RecordTick(global_statistics, NUMBER_DB_PREV_FOUND, prev_found_count_); RecordTick(global_statistics, ITER_BYTES_READ, bytes_read_); RecordTick(global_statistics, NUMBER_ITER_SKIP, skip_count_); PERF_COUNTER_ADD(iter_read_bytes, bytes_read_); ResetCounters(); } // Map to Tickers::NUMBER_DB_NEXT uint64_t next_count_; // Map to Tickers::NUMBER_DB_NEXT_FOUND uint64_t next_found_count_; // Map to Tickers::NUMBER_DB_PREV uint64_t prev_count_; // Map to Tickers::NUMBER_DB_PREV_FOUND uint64_t prev_found_count_; // Map to Tickers::ITER_BYTES_READ uint64_t bytes_read_; // Map to Tickers::NUMBER_ITER_SKIP uint64_t skip_count_; }; DBIter(Env* _env, const ReadOptions& read_options, const ImmutableOptions& ioptions, const MutableCFOptions& mutable_cf_options, const Comparator* cmp, InternalIterator* iter, const Version* version, SequenceNumber s, bool arena_mode, uint64_t max_sequential_skip_in_iterations, ReadCallback* read_callback, DBImpl* db_impl, ColumnFamilyData* cfd, bool expose_blob_index); // No copying allowed DBIter(const DBIter&) = delete; void operator=(const DBIter&) = delete; ~DBIter() override { // Release pinned data if any if (pinned_iters_mgr_.PinningEnabled()) { pinned_iters_mgr_.ReleasePinnedData(); } RecordTick(statistics_, NO_ITERATOR_DELETED); ResetInternalKeysSkippedCounter(); local_stats_.BumpGlobalStatistics(statistics_); iter_.DeleteIter(arena_mode_); } void SetIter(InternalIterator* iter) { assert(iter_.iter() == nullptr); iter_.Set(iter); iter_.iter()->SetPinnedItersMgr(&pinned_iters_mgr_); } bool Valid() const override { #ifdef ROCKSDB_ASSERT_STATUS_CHECKED if (valid_) { status_.PermitUncheckedError(); } #endif // ROCKSDB_ASSERT_STATUS_CHECKED return valid_; } Slice key() const override { assert(valid_); if (timestamp_lb_) { return saved_key_.GetInternalKey(); } else { const Slice ukey_and_ts = saved_key_.GetUserKey(); return Slice(ukey_and_ts.data(), ukey_and_ts.size() - timestamp_size_); } } Slice value() const override { assert(valid_); return value_; } const WideColumns& columns() const override { assert(valid_); return wide_columns_; } Status status() const override { if (status_.ok()) { return iter_.status(); } else { assert(!valid_); return status_; } } Slice timestamp() const override { assert(valid_); assert(timestamp_size_ > 0); if (direction_ == kReverse) { return saved_timestamp_; } const Slice ukey_and_ts = saved_key_.GetUserKey(); assert(timestamp_size_ < ukey_and_ts.size()); return ExtractTimestampFromUserKey(ukey_and_ts, timestamp_size_); } bool IsBlob() const { assert(valid_); return is_blob_; } Status GetProperty(std::string prop_name, std::string* prop) override; void Next() final override; void Prev() final override; // 'target' does not contain timestamp, even if user timestamp feature is // enabled. void Seek(const Slice& target) final override; void SeekForPrev(const Slice& target) final override; void SeekToFirst() final override; void SeekToLast() final override; Env* env() const { return env_; } void set_sequence(uint64_t s) { sequence_ = s; if (read_callback_) { read_callback_->Refresh(s); } iter_.SetRangeDelReadSeqno(s); } void set_valid(bool v) { valid_ = v; } private: // For all methods in this block: // PRE: iter_->Valid() && status_.ok() // Return false if there was an error, and status() is non-ok, valid_ = false; // in this case callers would usually stop what they were doing and return. bool ReverseToForward(); bool ReverseToBackward(); // Set saved_key_ to the seek key to target, with proper sequence number set. // It might get adjusted if the seek key is smaller than iterator lower bound. // target does not have timestamp. void SetSavedKeyToSeekTarget(const Slice& target); // Set saved_key_ to the seek key to target, with proper sequence number set. // It might get adjusted if the seek key is larger than iterator upper bound. // target does not have timestamp. void SetSavedKeyToSeekForPrevTarget(const Slice& target); bool FindValueForCurrentKey(); bool FindValueForCurrentKeyUsingSeek(); bool FindUserKeyBeforeSavedKey(); // If `skipping_saved_key` is true, the function will keep iterating until it // finds a user key that is larger than `saved_key_`. // If `prefix` is not null, the iterator needs to stop when all keys for the // prefix are exhausted and the iterator is set to invalid. bool FindNextUserEntry(bool skipping_saved_key, const Slice* prefix); // Internal implementation of FindNextUserEntry(). bool FindNextUserEntryInternal(bool skipping_saved_key, const Slice* prefix); bool ParseKey(ParsedInternalKey* key); bool MergeValuesNewToOld(); // If prefix is not null, we need to set the iterator to invalid if no more // entry can be found within the prefix. void PrevInternal(const Slice* prefix); bool TooManyInternalKeysSkipped(bool increment = true); bool IsVisible(SequenceNumber sequence, const Slice& ts, bool* more_recent = nullptr); // Temporarily pin the blocks that we encounter until ReleaseTempPinnedData() // is called void TempPinData() { if (!pin_thru_lifetime_) { pinned_iters_mgr_.StartPinning(); } } // Release blocks pinned by TempPinData() void ReleaseTempPinnedData() { if (!pin_thru_lifetime_ && pinned_iters_mgr_.PinningEnabled()) { pinned_iters_mgr_.ReleasePinnedData(); } } inline void ClearSavedValue() { if (saved_value_.capacity() > 1048576) { std::string empty; swap(empty, saved_value_); } else { saved_value_.clear(); } } inline void ResetInternalKeysSkippedCounter() { local_stats_.skip_count_ += num_internal_keys_skipped_; if (valid_) { local_stats_.skip_count_--; } num_internal_keys_skipped_ = 0; } bool expect_total_order_inner_iter() { assert(expect_total_order_inner_iter_ || prefix_extractor_ != nullptr); return expect_total_order_inner_iter_; } // If lower bound of timestamp is given by ReadOptions.iter_start_ts, we need // to return versions of the same key. We cannot just skip if the key value // is the same but timestamps are different but fall in timestamp range. inline int CompareKeyForSkip(const Slice& a, const Slice& b) { return timestamp_lb_ != nullptr ? user_comparator_.Compare(a, b) : user_comparator_.CompareWithoutTimestamp(a, b); } // Retrieves the blob value for the specified user key using the given blob // index when using the integrated BlobDB implementation. bool SetBlobValueIfNeeded(const Slice& user_key, const Slice& blob_index); void ResetBlobValue() { is_blob_ = false; blob_value_.Reset(); } void SetValueAndColumnsFromPlain(const Slice& slice) { assert(value_.empty()); assert(wide_columns_.empty()); value_ = slice; wide_columns_.emplace_back(kDefaultWideColumnName, slice); } bool SetValueAndColumnsFromEntity(Slice slice); bool SetValueAndColumnsFromMergeResult(const Status& merge_status, ValueType result_type); void ResetValueAndColumns() { value_.clear(); wide_columns_.clear(); } // The following methods perform the actual merge operation for the // no base value/plain base value/wide-column base value cases. // If user-defined timestamp is enabled, `user_key` includes timestamp. bool MergeWithNoBaseValue(const Slice& user_key); bool MergeWithPlainBaseValue(const Slice& value, const Slice& user_key); bool MergeWithWideColumnBaseValue(const Slice& entity, const Slice& user_key); const SliceTransform* prefix_extractor_; Env* const env_; SystemClock* clock_; Logger* logger_; UserComparatorWrapper user_comparator_; const MergeOperator* const merge_operator_; IteratorWrapper iter_; const Version* version_; ReadCallback* read_callback_; // Max visible sequence number. It is normally the snapshot seq unless we have // uncommitted data in db as in WriteUnCommitted. SequenceNumber sequence_; IterKey saved_key_; // Reusable internal key data structure. This is only used inside one function // and should not be used across functions. Reusing this object can reduce // overhead of calling construction of the function if creating it each time. ParsedInternalKey ikey_; std::string saved_value_; Slice pinned_value_; // for prefix seek mode to support prev() PinnableSlice blob_value_; // Value of the default column Slice value_; // All columns (i.e. name-value pairs) WideColumns wide_columns_; Statistics* statistics_; uint64_t max_skip_; uint64_t max_skippable_internal_keys_; uint64_t num_internal_keys_skipped_; const Slice* iterate_lower_bound_; const Slice* iterate_upper_bound_; // The prefix of the seek key. It is only used when prefix_same_as_start_ // is true and prefix extractor is not null. In Next() or Prev(), current keys // will be checked against this prefix, so that the iterator can be // invalidated if the keys in this prefix has been exhausted. Set it using // SetUserKey() and use it using GetUserKey(). IterKey prefix_; Status status_; Direction direction_; bool valid_; bool current_entry_is_merged_; // True if we know that the current entry's seqnum is 0. // This information is used as that the next entry will be for another // user key. bool is_key_seqnum_zero_; const bool prefix_same_as_start_; // Means that we will pin all data blocks we read as long the Iterator // is not deleted, will be true if ReadOptions::pin_data is true const bool pin_thru_lifetime_; // Expect the inner iterator to maintain a total order. // prefix_extractor_ must be non-NULL if the value is false. const bool expect_total_order_inner_iter_; ReadTier read_tier_; bool fill_cache_; bool verify_checksums_; // Whether the iterator is allowed to expose blob references. Set to true when // the stacked BlobDB implementation is used, false otherwise. bool expose_blob_index_; bool is_blob_; bool arena_mode_; const Env::IOActivity io_activity_; // List of operands for merge operator. MergeContext merge_context_; LocalStatistics local_stats_; PinnedIteratorsManager pinned_iters_mgr_; DBImpl* db_impl_; ColumnFamilyData* cfd_; const Slice* const timestamp_ub_; const Slice* const timestamp_lb_; const size_t timestamp_size_; std::string saved_timestamp_; }; // Return a new iterator that converts internal keys (yielded by // "*internal_iter") that were live at the specified `sequence` number // into appropriate user keys. extern Iterator* NewDBIterator( Env* env, const ReadOptions& read_options, const ImmutableOptions& ioptions, const MutableCFOptions& mutable_cf_options, const Comparator* user_key_comparator, InternalIterator* internal_iter, const Version* version, const SequenceNumber& sequence, uint64_t max_sequential_skip_in_iterations, ReadCallback* read_callback, DBImpl* db_impl = nullptr, ColumnFamilyData* cfd = nullptr, bool expose_blob_index = false); } // namespace ROCKSDB_NAMESPACE