// Copyright (c) 2018-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). #pragma once #include #include #include #include #include #include "db/dbformat.h" #include "db/pinned_iterators_manager.h" #include "rocksdb/status.h" #include "table/internal_iterator.h" namespace ROCKSDB_NAMESPACE { struct FragmentedRangeTombstoneList; struct FragmentedRangeTombstoneListCache { // ensure only the first reader needs to initialize l std::mutex reader_mutex; std::unique_ptr tombstones = nullptr; // readers will first check this bool to avoid std::atomic initialized = false; }; struct FragmentedRangeTombstoneList { public: // A compact representation of a "stack" of range tombstone fragments, which // start and end at the same user keys but have different sequence numbers. // The members seq_start_idx and seq_end_idx are intended to be parameters to // seq_iter(). // If user-defined timestamp is enabled, `start` and `end` should be user keys // with timestamp, and the timestamps are set to max timestamp to be returned // by parsed_start_key()/parsed_end_key(). seq_start_idx and seq_end_idx will // also be used as parameters to ts_iter(). struct RangeTombstoneStack { RangeTombstoneStack(const Slice& start, const Slice& end, size_t start_idx, size_t end_idx) : start_key(start), end_key(end), seq_start_idx(start_idx), seq_end_idx(end_idx) {} Slice start_key; Slice end_key; size_t seq_start_idx; size_t seq_end_idx; }; // Assumes unfragmented_tombstones->key() and unfragmented_tombstones->value() // both contain timestamp if enabled. FragmentedRangeTombstoneList( std::unique_ptr unfragmented_tombstones, const InternalKeyComparator& icmp, bool for_compaction = false, const std::vector& snapshots = {}, const bool tombstone_end_include_ts = true); std::vector::const_iterator begin() const { return tombstones_.begin(); } std::vector::const_iterator end() const { return tombstones_.end(); } std::vector::const_iterator seq_iter(size_t idx) const { return std::next(tombstone_seqs_.begin(), idx); } std::vector::const_iterator ts_iter(size_t idx) const { return std::next(tombstone_timestamps_.begin(), idx); } std::vector::const_iterator seq_begin() const { return tombstone_seqs_.begin(); } std::vector::const_iterator seq_end() const { return tombstone_seqs_.end(); } bool empty() const { return tombstones_.empty(); } // Returns true if the stored tombstones contain with one with a sequence // number in [lower, upper]. // This method is not const as it internally lazy initialize a set of // sequence numbers (`seq_set_`). bool ContainsRange(SequenceNumber lower, SequenceNumber upper); uint64_t num_unfragmented_tombstones() const { return num_unfragmented_tombstones_; } uint64_t total_tombstone_payload_bytes() const { return total_tombstone_payload_bytes_; } private: // Given an ordered range tombstone iterator unfragmented_tombstones, // "fragment" the tombstones into non-overlapping pieces. Each // "non-overlapping piece" is a RangeTombstoneStack in tombstones_, which // contains start_key, end_key, and indices that points to sequence numbers // (in tombstone_seqs_) and timestamps (in tombstone_timestamps_). If // for_compaction is true, then `snapshots` should be provided. Range // tombstone fragments are dropped if they are not visible in any snapshot and // user-defined timestamp is not enabled. That is, for each snapshot stripe // [lower, upper], the range tombstone fragment with largest seqno in [lower, // upper] is preserved, and all the other range tombstones are dropped. void FragmentTombstones( std::unique_ptr unfragmented_tombstones, const InternalKeyComparator& icmp, bool for_compaction, const std::vector& snapshots); std::vector tombstones_; std::vector tombstone_seqs_; std::vector tombstone_timestamps_; std::once_flag seq_set_init_once_flag_; std::set seq_set_; std::list pinned_slices_; PinnedIteratorsManager pinned_iters_mgr_; uint64_t num_unfragmented_tombstones_; uint64_t total_tombstone_payload_bytes_; }; // FragmentedRangeTombstoneIterator converts an InternalIterator of a range-del // meta block into an iterator over non-overlapping tombstone fragments. The // tombstone fragmentation process should be more efficient than the range // tombstone collapsing algorithm in RangeDelAggregator because this leverages // the internal key ordering already provided by the input iterator, if // applicable (when the iterator is unsorted, a new sorted iterator is created // before proceeding). If there are few overlaps, creating a // FragmentedRangeTombstoneIterator should be O(n), while the RangeDelAggregator // tombstone collapsing is always O(n log n). class FragmentedRangeTombstoneIterator : public InternalIterator { public: FragmentedRangeTombstoneIterator(FragmentedRangeTombstoneList* tombstones, const InternalKeyComparator& icmp, SequenceNumber upper_bound, const Slice* ts_upper_bound = nullptr, SequenceNumber lower_bound = 0); FragmentedRangeTombstoneIterator( const std::shared_ptr& tombstones, const InternalKeyComparator& icmp, SequenceNumber upper_bound, const Slice* ts_upper_bound = nullptr, SequenceNumber lower_bound = 0); FragmentedRangeTombstoneIterator( const std::shared_ptr& tombstones, const InternalKeyComparator& icmp, SequenceNumber upper_bound, const Slice* ts_upper_bound = nullptr, SequenceNumber lower_bound = 0); void SetRangeDelReadSeqno(SequenceNumber read_seqno) override { upper_bound_ = read_seqno; } void SeekToFirst() override; void SeekToLast() override; void SeekToTopFirst(); void SeekToTopLast(); // NOTE: Seek and SeekForPrev do not behave in the way InternalIterator // seeking should behave. This is OK because they are not currently used, but // eventually FragmentedRangeTombstoneIterator should no longer implement // InternalIterator. // // Seeks to the range tombstone that covers target at a seqnum in the // snapshot. If no such tombstone exists, seek to the earliest tombstone in // the snapshot that ends after target. void Seek(const Slice& target) override; // Seeks to the range tombstone that covers target at a seqnum in the // snapshot. If no such tombstone exists, seek to the latest tombstone in the // snapshot that starts before target. void SeekForPrev(const Slice& target) override; void Next() override; void Prev() override; void TopNext(); void TopPrev(); bool Valid() const override; // Note that key() and value() do not return correct timestamp. // Caller should call timestamp() to get the current timestamp. Slice key() const override { MaybePinKey(); return current_start_key_.Encode(); } Slice value() const override { return pos_->end_key; } bool IsKeyPinned() const override { return false; } bool IsValuePinned() const override { return true; } Status status() const override { return Status::OK(); } bool empty() const { return tombstones_->empty(); } void Invalidate() { pos_ = tombstones_->end(); seq_pos_ = tombstones_->seq_end(); pinned_pos_ = tombstones_->end(); pinned_seq_pos_ = tombstones_->seq_end(); } RangeTombstone Tombstone(bool logical_strip_timestamp = false) const { assert(Valid()); if (icmp_->user_comparator()->timestamp_size()) { return RangeTombstone(start_key(), end_key(), seq(), timestamp(), logical_strip_timestamp); } return RangeTombstone(start_key(), end_key(), seq()); } // Note that start_key() and end_key() are not guaranteed to have the // correct timestamp. User can call timestamp() to get the correct // timestamp(). Slice start_key() const { return pos_->start_key; } Slice end_key() const { return pos_->end_key; } SequenceNumber seq() const { return *seq_pos_; } Slice timestamp() const { // seqno and timestamp are stored in the same order. return *tombstones_->ts_iter(seq_pos_ - tombstones_->seq_begin()); } // Current use case is by CompactionRangeDelAggregator to set // full_history_ts_low_. void SetTimestampUpperBound(const Slice* ts_upper_bound) { ts_upper_bound_ = ts_upper_bound; } ParsedInternalKey parsed_start_key() const { return ParsedInternalKey(pos_->start_key, seq(), kTypeRangeDeletion); } ParsedInternalKey parsed_end_key() const { return ParsedInternalKey(pos_->end_key, kMaxSequenceNumber, kTypeRangeDeletion); } // Return the max sequence number of a range tombstone that covers // the given user key. // If there is no covering tombstone, then 0 is returned. SequenceNumber MaxCoveringTombstoneSeqnum(const Slice& user_key); // Splits the iterator into n+1 iterators (where n is the number of // snapshots), each providing a view over a "stripe" of sequence numbers. The // iterators are keyed by the upper bound of their ranges (the provided // snapshots + kMaxSequenceNumber). // // NOTE: the iterators in the returned map are no longer valid if their // parent iterator is deleted, since they do not modify the refcount of the // underlying tombstone list. Therefore, this map should be deleted before // the parent iterator. std::map> SplitBySnapshot(const std::vector& snapshots); SequenceNumber upper_bound() const { return upper_bound_; } SequenceNumber lower_bound() const { return lower_bound_; } uint64_t num_unfragmented_tombstones() const { return tombstones_->num_unfragmented_tombstones(); } uint64_t total_tombstone_payload_bytes() const { return tombstones_->total_tombstone_payload_bytes(); } private: using RangeTombstoneStack = FragmentedRangeTombstoneList::RangeTombstoneStack; struct RangeTombstoneStackStartComparator { explicit RangeTombstoneStackStartComparator(const Comparator* c) : cmp(c) {} bool operator()(const RangeTombstoneStack& a, const RangeTombstoneStack& b) const { return cmp->CompareWithoutTimestamp(a.start_key, b.start_key) < 0; } bool operator()(const RangeTombstoneStack& a, const Slice& b) const { return cmp->CompareWithoutTimestamp(a.start_key, b) < 0; } bool operator()(const Slice& a, const RangeTombstoneStack& b) const { return cmp->CompareWithoutTimestamp(a, b.start_key) < 0; } const Comparator* cmp; }; struct RangeTombstoneStackEndComparator { explicit RangeTombstoneStackEndComparator(const Comparator* c) : cmp(c) {} bool operator()(const RangeTombstoneStack& a, const RangeTombstoneStack& b) const { return cmp->CompareWithoutTimestamp(a.end_key, b.end_key) < 0; } bool operator()(const RangeTombstoneStack& a, const Slice& b) const { return cmp->CompareWithoutTimestamp(a.end_key, b) < 0; } bool operator()(const Slice& a, const RangeTombstoneStack& b) const { return cmp->CompareWithoutTimestamp(a, b.end_key) < 0; } const Comparator* cmp; }; void MaybePinKey() const { if (pos_ != tombstones_->end() && seq_pos_ != tombstones_->seq_end() && (pinned_pos_ != pos_ || pinned_seq_pos_ != seq_pos_)) { current_start_key_.Set(pos_->start_key, *seq_pos_, kTypeRangeDeletion); pinned_pos_ = pos_; pinned_seq_pos_ = seq_pos_; } } void SeekToCoveringTombstone(const Slice& key); void SeekForPrevToCoveringTombstone(const Slice& key); void ScanForwardToVisibleTombstone(); void ScanBackwardToVisibleTombstone(); bool ValidPos() const { return Valid() && seq_pos_ != tombstones_->seq_iter(pos_->seq_end_idx); } const RangeTombstoneStackStartComparator tombstone_start_cmp_; const RangeTombstoneStackEndComparator tombstone_end_cmp_; const InternalKeyComparator* icmp_; const Comparator* ucmp_; std::shared_ptr tombstones_ref_; std::shared_ptr tombstones_cache_ref_; FragmentedRangeTombstoneList* tombstones_; SequenceNumber upper_bound_; SequenceNumber lower_bound_; // Only consider timestamps <= ts_upper_bound_. const Slice* ts_upper_bound_; std::vector::const_iterator pos_; std::vector::const_iterator seq_pos_; mutable std::vector::const_iterator pinned_pos_; mutable std::vector::const_iterator pinned_seq_pos_; mutable InternalKey current_start_key_; // Check the current RangeTombstoneStack `pos_` against timestamp // upper bound `ts_upper_bound_` and sequence number upper bound // `upper_bound_`. Update the sequence number (and timestamp) pointer // `seq_pos_` to the first valid position satisfying both bounds. void SetMaxVisibleSeqAndTimestamp() { seq_pos_ = std::lower_bound(tombstones_->seq_iter(pos_->seq_start_idx), tombstones_->seq_iter(pos_->seq_end_idx), upper_bound_, std::greater()); if (ts_upper_bound_ && !ts_upper_bound_->empty()) { auto ts_pos = std::lower_bound( tombstones_->ts_iter(pos_->seq_start_idx), tombstones_->ts_iter(pos_->seq_end_idx), *ts_upper_bound_, [this](const Slice& s1, const Slice& s2) { return ucmp_->CompareTimestamp(s1, s2) > 0; }); auto ts_idx = ts_pos - tombstones_->ts_iter(pos_->seq_start_idx); auto seq_idx = seq_pos_ - tombstones_->seq_iter(pos_->seq_start_idx); if (seq_idx < ts_idx) { // seq and ts are ordered in non-increasing order. Only updates seq_pos_ // to a larger index for smaller sequence number and timestamp. seq_pos_ = tombstones_->seq_iter(pos_->seq_start_idx + ts_idx); } } } }; } // namespace ROCKSDB_NAMESPACE