// 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). #pragma once #include #include #include #include #include #include #include #include "db/db_iter.h" #include "db/pre_release_callback.h" #include "db/read_callback.h" #include "db/snapshot_checker.h" #include "logging/logging.h" #include "rocksdb/db.h" #include "rocksdb/options.h" #include "rocksdb/utilities/transaction_db.h" #include "util/cast_util.h" #include "util/set_comparator.h" #include "util/string_util.h" #include "utilities/transactions/pessimistic_transaction.h" #include "utilities/transactions/pessimistic_transaction_db.h" #include "utilities/transactions/write_prepared_txn.h" namespace ROCKSDB_NAMESPACE { enum SnapshotBackup : bool { kUnbackedByDBSnapshot, kBackedByDBSnapshot }; // A PessimisticTransactionDB that writes data to DB after prepare phase of 2PC. // In this way some data in the DB might not be committed. The DB provides // mechanisms to tell such data apart from committed data. class WritePreparedTxnDB : public PessimisticTransactionDB { public: explicit WritePreparedTxnDB(DB* db, const TransactionDBOptions& txn_db_options) : PessimisticTransactionDB(db, txn_db_options), SNAPSHOT_CACHE_BITS(txn_db_options.wp_snapshot_cache_bits), SNAPSHOT_CACHE_SIZE(static_cast(1ull << SNAPSHOT_CACHE_BITS)), COMMIT_CACHE_BITS(txn_db_options.wp_commit_cache_bits), COMMIT_CACHE_SIZE(static_cast(1ull << COMMIT_CACHE_BITS)), FORMAT(COMMIT_CACHE_BITS) { Init(txn_db_options); } explicit WritePreparedTxnDB(StackableDB* db, const TransactionDBOptions& txn_db_options) : PessimisticTransactionDB(db, txn_db_options), SNAPSHOT_CACHE_BITS(txn_db_options.wp_snapshot_cache_bits), SNAPSHOT_CACHE_SIZE(static_cast(1ull << SNAPSHOT_CACHE_BITS)), COMMIT_CACHE_BITS(txn_db_options.wp_commit_cache_bits), COMMIT_CACHE_SIZE(static_cast(1ull << COMMIT_CACHE_BITS)), FORMAT(COMMIT_CACHE_BITS) { Init(txn_db_options); } virtual ~WritePreparedTxnDB(); virtual Status Initialize( const std::vector& compaction_enabled_cf_indices, const std::vector& handles) override; Transaction* BeginTransaction(const WriteOptions& write_options, const TransactionOptions& txn_options, Transaction* old_txn) override; using TransactionDB::Write; Status Write(const WriteOptions& opts, WriteBatch* updates) override; // Optimized version of ::Write that receives more optimization request such // as skip_concurrency_control. using PessimisticTransactionDB::Write; Status Write(const WriteOptions& opts, const TransactionDBWriteOptimizations&, WriteBatch* updates) override; // Write the batch to the underlying DB and mark it as committed. Could be // used by both directly from TxnDB or through a transaction. Status WriteInternal(const WriteOptions& write_options, WriteBatch* batch, size_t batch_cnt, WritePreparedTxn* txn); using DB::Get; virtual Status Get(const ReadOptions& _read_options, ColumnFamilyHandle* column_family, const Slice& key, PinnableSlice* value) override; using DB::MultiGet; virtual std::vector MultiGet( const ReadOptions& _read_options, const std::vector& column_family, const std::vector& keys, std::vector* values) override; using DB::NewIterator; virtual Iterator* NewIterator(const ReadOptions& _read_options, ColumnFamilyHandle* column_family) override; using DB::NewIterators; virtual Status NewIterators( const ReadOptions& _read_options, const std::vector& column_families, std::vector* iterators) override; // Check whether the transaction that wrote the value with sequence number seq // is visible to the snapshot with sequence number snapshot_seq. // Returns true if commit_seq <= snapshot_seq // If the snapshot_seq is already released and snapshot_seq <= max, sets // *snap_released to true and returns true as well. inline bool IsInSnapshot(uint64_t prep_seq, uint64_t snapshot_seq, uint64_t min_uncommitted = kMinUnCommittedSeq, bool* snap_released = nullptr) const { ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " min_uncommitted %" PRIu64, prep_seq, snapshot_seq, min_uncommitted); assert(min_uncommitted >= kMinUnCommittedSeq); // Caller is responsible to initialize snap_released. assert(snap_released == nullptr || *snap_released == false); // Here we try to infer the return value without looking into prepare list. // This would help avoiding synchronization over a shared map. // TODO(myabandeh): optimize this. This sequence of checks must be correct // but not necessary efficient if (prep_seq == 0) { // Compaction will output keys to bottom-level with sequence number 0 if // it is visible to the earliest snapshot. ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 1); return true; } if (snapshot_seq < prep_seq) { // snapshot_seq < prep_seq <= commit_seq => snapshot_seq < commit_seq ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 0); return false; } if (prep_seq < min_uncommitted) { ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32 " because of min_uncommitted %" PRIu64, prep_seq, snapshot_seq, 1, min_uncommitted); return true; } // Commit of delayed prepared has two non-atomic steps: add to commit cache, // remove from delayed prepared. Our reads from these two is also // non-atomic. By looking into commit cache first thus we might not find the // prep_seq neither in commit cache not in delayed_prepared_. To fix that i) // we check if there was any delayed prepared BEFORE looking into commit // cache, ii) if there was, we complete the search steps to be these: i) // commit cache, ii) delayed prepared, commit cache again. In this way if // the first query to commit cache missed the commit, the 2nd will catch it. bool was_empty; SequenceNumber max_evicted_seq_lb, max_evicted_seq_ub; CommitEntry64b dont_care; auto indexed_seq = prep_seq % COMMIT_CACHE_SIZE; size_t repeats = 0; do { repeats++; assert(repeats < 100); if (UNLIKELY(repeats >= 100)) { throw std::runtime_error( "The read was intrupted 100 times by update to max_evicted_seq_. " "This is unexpected in all setups"); } max_evicted_seq_lb = max_evicted_seq_.load(std::memory_order_acquire); TEST_SYNC_POINT( "WritePreparedTxnDB::IsInSnapshot:max_evicted_seq_:pause"); TEST_SYNC_POINT( "WritePreparedTxnDB::IsInSnapshot:max_evicted_seq_:resume"); was_empty = delayed_prepared_empty_.load(std::memory_order_acquire); TEST_SYNC_POINT( "WritePreparedTxnDB::IsInSnapshot:delayed_prepared_empty_:pause"); TEST_SYNC_POINT( "WritePreparedTxnDB::IsInSnapshot:delayed_prepared_empty_:resume"); CommitEntry cached; bool exist = GetCommitEntry(indexed_seq, &dont_care, &cached); TEST_SYNC_POINT("WritePreparedTxnDB::IsInSnapshot:GetCommitEntry:pause"); TEST_SYNC_POINT("WritePreparedTxnDB::IsInSnapshot:GetCommitEntry:resume"); if (exist && prep_seq == cached.prep_seq) { // It is committed and also not evicted from commit cache ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, cached.commit_seq <= snapshot_seq); return cached.commit_seq <= snapshot_seq; } // else it could be committed but not inserted in the map which could // happen after recovery, or it could be committed and evicted by another // commit, or never committed. // At this point we don't know if it was committed or it is still prepared max_evicted_seq_ub = max_evicted_seq_.load(std::memory_order_acquire); if (UNLIKELY(max_evicted_seq_lb != max_evicted_seq_ub)) { continue; } // Note: max_evicted_seq_ when we did GetCommitEntry <= max_evicted_seq_ub if (max_evicted_seq_ub < prep_seq) { // Not evicted from cache and also not present, so must be still // prepared ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 0); return false; } TEST_SYNC_POINT("WritePreparedTxnDB::IsInSnapshot:prepared_mutex_:pause"); TEST_SYNC_POINT( "WritePreparedTxnDB::IsInSnapshot:prepared_mutex_:resume"); if (!was_empty) { // We should not normally reach here WPRecordTick(TXN_PREPARE_MUTEX_OVERHEAD); ReadLock rl(&prepared_mutex_); ROCKS_LOG_WARN( info_log_, "prepared_mutex_ overhead %" PRIu64 " for %" PRIu64, static_cast(delayed_prepared_.size()), prep_seq); if (delayed_prepared_.find(prep_seq) != delayed_prepared_.end()) { // This is the order: 1) delayed_prepared_commits_ update, 2) publish // 3) delayed_prepared_ clean up. So check if it is the case of a late // clenaup. auto it = delayed_prepared_commits_.find(prep_seq); if (it == delayed_prepared_commits_.end()) { // Then it is not committed yet ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 0); return false; } else { ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " commit: %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, it->second, snapshot_seq <= it->second); return it->second <= snapshot_seq; } } else { // 2nd query to commit cache. Refer to was_empty comment above. exist = GetCommitEntry(indexed_seq, &dont_care, &cached); if (exist && prep_seq == cached.prep_seq) { ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, cached.commit_seq <= snapshot_seq); return cached.commit_seq <= snapshot_seq; } max_evicted_seq_ub = max_evicted_seq_.load(std::memory_order_acquire); } } } while (UNLIKELY(max_evicted_seq_lb != max_evicted_seq_ub)); // When advancing max_evicted_seq_, we move older entires from prepared to // delayed_prepared_. Also we move evicted entries from commit cache to // old_commit_map_ if it overlaps with any snapshot. Since prep_seq <= // max_evicted_seq_, we have three cases: i) in delayed_prepared_, ii) in // old_commit_map_, iii) committed with no conflict with any snapshot. Case // (i) delayed_prepared_ is checked above if (max_evicted_seq_ub < snapshot_seq) { // then (ii) cannot be the case // only (iii) is the case: committed // commit_seq <= max_evicted_seq_ < snapshot_seq => commit_seq < // snapshot_seq ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 1); return true; } // else (ii) might be the case: check the commit data saved for this // snapshot. If there was no overlapping commit entry, then it is committed // with a commit_seq lower than any live snapshot, including snapshot_seq. if (old_commit_map_empty_.load(std::memory_order_acquire)) { ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32 " released=1", prep_seq, snapshot_seq, 0); assert(snap_released); // This snapshot is not valid anymore. We cannot tell if prep_seq is // committed before or after the snapshot. Return true but also set // snap_released to true. *snap_released = true; return true; } { // We should not normally reach here unless sapshot_seq is old. This is a // rare case and it is ok to pay the cost of mutex ReadLock for such old, // reading transactions. WPRecordTick(TXN_OLD_COMMIT_MAP_MUTEX_OVERHEAD); ReadLock rl(&old_commit_map_mutex_); auto prep_set_entry = old_commit_map_.find(snapshot_seq); bool found = prep_set_entry != old_commit_map_.end(); if (found) { auto& vec = prep_set_entry->second; found = std::binary_search(vec.begin(), vec.end(), prep_seq); } else { // coming from compaction ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32 " released=1", prep_seq, snapshot_seq, 0); // This snapshot is not valid anymore. We cannot tell if prep_seq is // committed before or after the snapshot. Return true but also set // snap_released to true. assert(snap_released); *snap_released = true; return true; } if (!found) { ROCKS_LOG_DETAILS(info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 1); return true; } } // (ii) it the case: it is committed but after the snapshot_seq ROCKS_LOG_DETAILS( info_log_, "IsInSnapshot %" PRIu64 " in %" PRIu64 " returns %" PRId32, prep_seq, snapshot_seq, 0); return false; } // Add the transaction with prepare sequence seq to the prepared list. // Note: must be called serially with increasing seq on each call. // locked is true if prepared_mutex_ is already locked. void AddPrepared(uint64_t seq, bool locked = false); // Check if any of the prepared txns are less than new max_evicted_seq_. Must // be called with prepared_mutex_ write locked. void CheckPreparedAgainstMax(SequenceNumber new_max, bool locked); // Remove the transaction with prepare sequence seq from the prepared list void RemovePrepared(const uint64_t seq, const size_t batch_cnt = 1); // Add the transaction with prepare sequence prepare_seq and commit sequence // commit_seq to the commit map. loop_cnt is to detect infinite loops. // Note: must be called serially. void AddCommitted(uint64_t prepare_seq, uint64_t commit_seq, uint8_t loop_cnt = 0); struct CommitEntry { uint64_t prep_seq; uint64_t commit_seq; CommitEntry() : prep_seq(0), commit_seq(0) {} CommitEntry(uint64_t ps, uint64_t cs) : prep_seq(ps), commit_seq(cs) {} bool operator==(const CommitEntry& rhs) const { return prep_seq == rhs.prep_seq && commit_seq == rhs.commit_seq; } }; struct CommitEntry64bFormat { explicit CommitEntry64bFormat(size_t index_bits) : INDEX_BITS(index_bits), PREP_BITS(static_cast(64 - PAD_BITS - INDEX_BITS)), COMMIT_BITS(static_cast(64 - PREP_BITS)), COMMIT_FILTER(static_cast((1ull << COMMIT_BITS) - 1)), DELTA_UPPERBOUND(static_cast((1ull << COMMIT_BITS))) {} // Number of higher bits of a sequence number that is not used. They are // used to encode the value type, ... const size_t PAD_BITS = static_cast(8); // Number of lower bits from prepare seq that can be skipped as they are // implied by the index of the entry in the array const size_t INDEX_BITS; // Number of bits we use to encode the prepare seq const size_t PREP_BITS; // Number of bits we use to encode the commit seq. const size_t COMMIT_BITS; // Filter to encode/decode commit seq const uint64_t COMMIT_FILTER; // The value of commit_seq - prepare_seq + 1 must be less than this bound const uint64_t DELTA_UPPERBOUND; }; // Prepare Seq (64 bits) = PAD ... PAD PREP PREP ... PREP INDEX INDEX ... // INDEX Delta Seq (64 bits) = 0 0 0 0 0 0 0 0 0 0 0 0 DELTA DELTA ... // DELTA DELTA Encoded Value = PREP PREP .... PREP PREP DELTA DELTA // ... DELTA DELTA PAD: first bits of a seq that is reserved for tagging and // hence ignored PREP/INDEX: the used bits in a prepare seq number INDEX: the // bits that do not have to be encoded (will be provided externally) DELTA: // prep seq - commit seq + 1 Number of DELTA bits should be equal to number of // index bits + PADs struct CommitEntry64b { constexpr CommitEntry64b() noexcept : rep_(0) {} CommitEntry64b(const CommitEntry& entry, const CommitEntry64bFormat& format) : CommitEntry64b(entry.prep_seq, entry.commit_seq, format) {} CommitEntry64b(const uint64_t ps, const uint64_t cs, const CommitEntry64bFormat& format) { assert(ps < static_cast( (1ull << (format.PREP_BITS + format.INDEX_BITS)))); assert(ps <= cs); uint64_t delta = cs - ps + 1; // make initialized delta always >= 1 // zero is reserved for uninitialized entries assert(0 < delta); assert(delta < format.DELTA_UPPERBOUND); if (delta >= format.DELTA_UPPERBOUND) { throw std::runtime_error( "commit_seq >> prepare_seq. The allowed distance is " + std::to_string(format.DELTA_UPPERBOUND) + " commit_seq is " + std::to_string(cs) + " prepare_seq is " + std::to_string(ps)); } rep_ = (ps << format.PAD_BITS) & ~format.COMMIT_FILTER; rep_ = rep_ | delta; } // Return false if the entry is empty bool Parse(const uint64_t indexed_seq, CommitEntry* entry, const CommitEntry64bFormat& format) { uint64_t delta = rep_ & format.COMMIT_FILTER; // zero is reserved for uninitialized entries assert(delta < static_cast((1ull << format.COMMIT_BITS))); if (delta == 0) { return false; // initialized entry would have non-zero delta } assert(indexed_seq < static_cast((1ull << format.INDEX_BITS))); uint64_t prep_up = rep_ & ~format.COMMIT_FILTER; prep_up >>= format.PAD_BITS; const uint64_t& prep_low = indexed_seq; entry->prep_seq = prep_up | prep_low; entry->commit_seq = entry->prep_seq + delta - 1; return true; } private: uint64_t rep_; }; // Struct to hold ownership of snapshot and read callback for cleanup. struct IteratorState; std::shared_ptr> GetCFComparatorMap() { return cf_map_; } std::shared_ptr> GetCFHandleMap() { return handle_map_; } void UpdateCFComparatorMap( const std::vector& handles) override; void UpdateCFComparatorMap(ColumnFamilyHandle* handle) override; virtual const Snapshot* GetSnapshot() override; SnapshotImpl* GetSnapshotInternal(bool for_ww_conflict_check); protected: virtual Status VerifyCFOptions( const ColumnFamilyOptions& cf_options) override; // Assign the min and max sequence numbers for reading from the db. A seq > // max is not valid, and a seq < min is valid, and a min <= seq < max requires // further checking. Normally max is defined by the snapshot and min is by // minimum uncommitted seq. inline SnapshotBackup AssignMinMaxSeqs(const Snapshot* snapshot, SequenceNumber* min, SequenceNumber* max); // Validate is a snapshot sequence number is still valid based on the latest // db status. backed_by_snapshot specifies if the number is baked by an actual // snapshot object. order specified the memory order with which we load the // atomic variables: relax is enough for the default since we care about last // value seen by same thread. inline bool ValidateSnapshot( const SequenceNumber snap_seq, const SnapshotBackup backed_by_snapshot, std::memory_order order = std::memory_order_relaxed); // Get a dummy snapshot that refers to kMaxSequenceNumber Snapshot* GetMaxSnapshot() { return &dummy_max_snapshot_; } bool ShouldRollbackWithSingleDelete(ColumnFamilyHandle* column_family, const Slice& key) { return rollback_deletion_type_callback_ ? rollback_deletion_type_callback_(this, column_family, key) : false; } std::function rollback_deletion_type_callback_; private: friend class AddPreparedCallback; friend class PreparedHeap_BasicsTest_Test; friend class PreparedHeap_Concurrent_Test; friend class PreparedHeap_EmptyAtTheEnd_Test; friend class SnapshotConcurrentAccessTest_SnapshotConcurrentAccess_Test; friend class WritePreparedCommitEntryPreReleaseCallback; friend class WritePreparedTransactionTestBase; friend class WritePreparedTxn; friend class WritePreparedTxnDBMock; friend class WritePreparedTransactionTest_AddPreparedBeforeMax_Test; friend class WritePreparedTransactionTest_AdvanceMaxEvictedSeqBasic_Test; friend class WritePreparedTransactionTest_AdvanceMaxEvictedSeqWithDuplicates_Test; friend class WritePreparedTransactionTest_AdvanceSeqByOne_Test; friend class WritePreparedTransactionTest_BasicRecovery_Test; friend class WritePreparedTransactionTest_CheckAgainstSnapshots_Test; friend class WritePreparedTransactionTest_CleanupSnapshotEqualToMax_Test; friend class WritePreparedTransactionTest_ConflictDetectionAfterRecovery_Test; friend class WritePreparedTransactionTest_CommitMap_Test; friend class WritePreparedTransactionTest_DoubleSnapshot_Test; friend class WritePreparedTransactionTest_IsInSnapshotEmptyMap_Test; friend class WritePreparedTransactionTest_IsInSnapshotReleased_Test; friend class WritePreparedTransactionTest_IsInSnapshot_Test; friend class WritePreparedTransactionTest_NewSnapshotLargerThanMax_Test; friend class WritePreparedTransactionTest_MaxCatchupWithNewSnapshot_Test; friend class WritePreparedTransactionTest_MaxCatchupWithUnbackedSnapshot_Test; friend class WritePreparedTransactionTest_NonAtomicCommitOfDelayedPrepared_Test; friend class WritePreparedTransactionTest_NonAtomicUpdateOfDelayedPrepared_Test; friend class WritePreparedTransactionTest_NonAtomicUpdateOfMaxEvictedSeq_Test; friend class WritePreparedTransactionTest_OldCommitMapGC_Test; friend class WritePreparedTransactionTest_Rollback_Test; friend class WritePreparedTransactionTest_SmallestUnCommittedSeq_Test; friend class WriteUnpreparedTxn; friend class WriteUnpreparedTxnDB; friend class WriteUnpreparedTransactionTest_RecoveryTest_Test; friend class MultiOpsTxnsStressTest; void Init(const TransactionDBOptions& txn_db_opts); void WPRecordTick(uint32_t ticker_type) const { RecordTick(db_impl_->immutable_db_options_.statistics.get(), ticker_type); } Status GetImpl(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, std::string* value) { assert(value != nullptr); PinnableSlice pinnable_val(value); assert(!pinnable_val.IsPinned()); auto s = GetImpl(options, column_family, key, &pinnable_val); if (s.ok() && pinnable_val.IsPinned()) { value->assign(pinnable_val.data(), pinnable_val.size()); } // else value is already assigned return s; } Status GetImpl(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, PinnableSlice* value); // A heap with the amortized O(1) complexity for erase. It uses one extra heap // to keep track of erased entries that are not yet on top of the main heap. class PreparedHeap { // The mutex is required for push and pop from PreparedHeap. ::erase will // use external synchronization via prepared_mutex_. port::Mutex push_pop_mutex_; std::deque heap_; std::priority_queue, std::greater> erased_heap_; std::atomic heap_top_ = {kMaxSequenceNumber}; // True when testing crash recovery bool TEST_CRASH_ = false; friend class WritePreparedTxnDB; public: ~PreparedHeap() { if (!TEST_CRASH_) { assert(heap_.empty()); assert(erased_heap_.empty()); } } port::Mutex* push_pop_mutex() { return &push_pop_mutex_; } inline bool empty() { return top() == kMaxSequenceNumber; } // Returns kMaxSequenceNumber if empty() and the smallest otherwise. inline uint64_t top() { return heap_top_.load(std::memory_order_acquire); } inline void push(uint64_t v) { push_pop_mutex_.AssertHeld(); if (heap_.empty()) { heap_top_.store(v, std::memory_order_release); } else { assert(heap_top_.load() < v); } heap_.push_back(v); } void pop(bool locked = false) { if (!locked) { push_pop_mutex()->Lock(); } push_pop_mutex_.AssertHeld(); heap_.pop_front(); while (!heap_.empty() && !erased_heap_.empty() && // heap_.top() > erased_heap_.top() could happen if we have erased // a non-existent entry. Ideally the user should not do that but we // should be resilient against it. heap_.front() >= erased_heap_.top()) { if (heap_.front() == erased_heap_.top()) { heap_.pop_front(); } uint64_t erased __attribute__((__unused__)); erased = erased_heap_.top(); erased_heap_.pop(); // No duplicate prepare sequence numbers assert(erased_heap_.empty() || erased_heap_.top() != erased); } while (heap_.empty() && !erased_heap_.empty()) { erased_heap_.pop(); } heap_top_.store(!heap_.empty() ? heap_.front() : kMaxSequenceNumber, std::memory_order_release); if (!locked) { push_pop_mutex()->Unlock(); } } // Concurrrent calls needs external synchronization. It is safe to be called // concurrent to push and pop though. void erase(uint64_t seq) { if (!empty()) { auto top_seq = top(); if (seq < top_seq) { // Already popped, ignore it. } else if (top_seq == seq) { pop(); #ifndef NDEBUG MutexLock ml(push_pop_mutex()); assert(heap_.empty() || heap_.front() != seq); #endif } else { // top() > seq // Down the heap, remember to pop it later erased_heap_.push(seq); } } } }; void TEST_Crash() override { prepared_txns_.TEST_CRASH_ = true; } // Get the commit entry with index indexed_seq from the commit table. It // returns true if such entry exists. bool GetCommitEntry(const uint64_t indexed_seq, CommitEntry64b* entry_64b, CommitEntry* entry) const; // Rewrite the entry with the index indexed_seq in the commit table with the // commit entry . If the rewrite results into eviction, // sets the evicted_entry and returns true. bool AddCommitEntry(const uint64_t indexed_seq, const CommitEntry& new_entry, CommitEntry* evicted_entry); // Rewrite the entry with the index indexed_seq in the commit table with the // commit entry new_entry only if the existing entry matches the // expected_entry. Returns false otherwise. bool ExchangeCommitEntry(const uint64_t indexed_seq, CommitEntry64b& expected_entry, const CommitEntry& new_entry); // Increase max_evicted_seq_ from the previous value prev_max to the new // value. This also involves taking care of prepared txns that are not // committed before new_max, as well as updating the list of live snapshots at // the time of updating the max. Thread-safety: this function can be called // concurrently. The concurrent invocations of this function is equivalent to // a serial invocation in which the last invocation is the one with the // largest new_max value. void AdvanceMaxEvictedSeq(const SequenceNumber& prev_max, const SequenceNumber& new_max); inline SequenceNumber SmallestUnCommittedSeq() { // Note: We have two lists to look into, but for performance reasons they // are not read atomically. Since CheckPreparedAgainstMax copies the entry // to delayed_prepared_ before removing it from prepared_txns_, to ensure // that a prepared entry will not go unmissed, we look into them in opposite // order: first read prepared_txns_ and then delayed_prepared_. // This must be called before calling ::top. This is because the concurrent // thread would call ::RemovePrepared before updating // GetLatestSequenceNumber(). Reading then in opposite order here guarantees // that the ::top that we read would be lower the ::top if we had otherwise // update/read them atomically. auto next_prepare = db_impl_->GetLatestSequenceNumber() + 1; auto min_prepare = prepared_txns_.top(); // Since we update the prepare_heap always from the main write queue via // PreReleaseCallback, the prepared_txns_.top() indicates the smallest // prepared data in 2pc transactions. For non-2pc transactions that are // written in two steps, we also update prepared_txns_ at the first step // (via the same mechanism) so that their uncommitted data is reflected in // SmallestUnCommittedSeq. if (!delayed_prepared_empty_.load()) { ReadLock rl(&prepared_mutex_); if (!delayed_prepared_.empty()) { return *delayed_prepared_.begin(); } } bool empty = min_prepare == kMaxSequenceNumber; if (empty) { // Since GetLatestSequenceNumber is updated // after prepared_txns_ are, the value of GetLatestSequenceNumber would // reflect any uncommitted data that is not added to prepared_txns_ yet. // Otherwise, if there is no concurrent txn, this value simply reflects // that latest value in the memtable. return next_prepare; } else { return std::min(min_prepare, next_prepare); } } // Enhance the snapshot object by recording in it the smallest uncommitted seq inline void EnhanceSnapshot(SnapshotImpl* snapshot, SequenceNumber min_uncommitted) { assert(snapshot); assert(min_uncommitted <= snapshot->number_ + 1); snapshot->min_uncommitted_ = min_uncommitted; } virtual const std::vector GetSnapshotListFromDB( SequenceNumber max); // Will be called by the public ReleaseSnapshot method. Does the maintenance // internal to WritePreparedTxnDB void ReleaseSnapshotInternal(const SequenceNumber snap_seq); // Update the list of snapshots corresponding to the soon-to-be-updated // max_evicted_seq_. Thread-safety: this function can be called concurrently. // The concurrent invocations of this function is equivalent to a serial // invocation in which the last invocation is the one with the largest // version value. void UpdateSnapshots(const std::vector& snapshots, const SequenceNumber& version); // Check the new list of new snapshots against the old one to see if any of // the snapshots are released and to do the cleanup for the released snapshot. void CleanupReleasedSnapshots( const std::vector& new_snapshots, const std::vector& old_snapshots); // Check an evicted entry against live snapshots to see if it should be kept // around or it can be safely discarded (and hence assume committed for all // snapshots). Thread-safety: this function can be called concurrently. If it // is called concurrently with multiple UpdateSnapshots, the result is the // same as checking the intersection of the snapshot list before updates with // the snapshot list of all the concurrent updates. void CheckAgainstSnapshots(const CommitEntry& evicted); // Add a new entry to old_commit_map_ if prep_seq <= snapshot_seq < // commit_seq. Return false if checking the next snapshot(s) is not needed. // This is the case if none of the next snapshots could satisfy the condition. // next_is_larger: the next snapshot will be a larger value bool MaybeUpdateOldCommitMap(const uint64_t& prep_seq, const uint64_t& commit_seq, const uint64_t& snapshot_seq, const bool next_is_larger); // A trick to increase the last visible sequence number by one and also wait // for the in-flight commits to be visible. void AdvanceSeqByOne(); // The list of live snapshots at the last time that max_evicted_seq_ advanced. // The list stored into two data structures: in snapshot_cache_ that is // efficient for concurrent reads, and in snapshots_ if the data does not fit // into snapshot_cache_. The total number of snapshots in the two lists std::atomic snapshots_total_ = {}; // The list sorted in ascending order. Thread-safety for writes is provided // with snapshots_mutex_ and concurrent reads are safe due to std::atomic for // each entry. In x86_64 architecture such reads are compiled to simple read // instructions. const size_t SNAPSHOT_CACHE_BITS; const size_t SNAPSHOT_CACHE_SIZE; std::unique_ptr[]> snapshot_cache_; // 2nd list for storing snapshots. The list sorted in ascending order. // Thread-safety is provided with snapshots_mutex_. std::vector snapshots_; // The list of all snapshots: snapshots_ + snapshot_cache_. This list although // redundant but simplifies CleanupOldSnapshots implementation. // Thread-safety is provided with snapshots_mutex_. std::vector snapshots_all_; // The version of the latest list of snapshots. This can be used to avoid // rewriting a list that is concurrently updated with a more recent version. SequenceNumber snapshots_version_ = 0; // A heap of prepared transactions. Thread-safety is provided with // prepared_mutex_. PreparedHeap prepared_txns_; const size_t COMMIT_CACHE_BITS; const size_t COMMIT_CACHE_SIZE; const CommitEntry64bFormat FORMAT; // commit_cache_ must be initialized to zero to tell apart an empty index from // a filled one. Thread-safety is provided with commit_cache_mutex_. std::unique_ptr[]> commit_cache_; // The largest evicted *commit* sequence number from the commit_cache_. If a // seq is smaller than max_evicted_seq_ is might or might not be present in // commit_cache_. So commit_cache_ must first be checked before consulting // with max_evicted_seq_. std::atomic max_evicted_seq_ = {}; // Order: 1) update future_max_evicted_seq_ = new_max, 2) // GetSnapshotListFromDB(new_max), max_evicted_seq_ = new_max. Since // GetSnapshotInternal guarantess that the snapshot seq is larger than // future_max_evicted_seq_, this guarantes that if a snapshot is not larger // than max has already being looked at via a GetSnapshotListFromDB(new_max). std::atomic future_max_evicted_seq_ = {}; // Advance max_evicted_seq_ by this value each time it needs an update. The // larger the value, the less frequent advances we would have. We do not want // it to be too large either as it would cause stalls by doing too much // maintenance work under the lock. size_t INC_STEP_FOR_MAX_EVICTED = 1; // A map from old snapshots (expected to be used by a few read-only txns) to // prepared sequence number of the evicted entries from commit_cache_ that // overlaps with such snapshot. These are the prepared sequence numbers that // the snapshot, to which they are mapped, cannot assume to be committed just // because it is no longer in the commit_cache_. The vector must be sorted // after each update. // Thread-safety is provided with old_commit_map_mutex_. std::map> old_commit_map_; // A set of long-running prepared transactions that are not finished by the // time max_evicted_seq_ advances their sequence number. This is expected to // be empty normally. Thread-safety is provided with prepared_mutex_. std::set delayed_prepared_; // Commit of a delayed prepared: 1) update commit cache, 2) update // delayed_prepared_commits_, 3) publish seq, 3) clean up delayed_prepared_. // delayed_prepared_commits_ will help us tell apart the unprepared txns from // the ones that are committed but not cleaned up yet. std::unordered_map delayed_prepared_commits_; // Update when delayed_prepared_.empty() changes. Expected to be true // normally. std::atomic delayed_prepared_empty_ = {true}; // Update when old_commit_map_.empty() changes. Expected to be true normally. std::atomic old_commit_map_empty_ = {true}; mutable port::RWMutex prepared_mutex_; mutable port::RWMutex old_commit_map_mutex_; mutable port::RWMutex commit_cache_mutex_; mutable port::RWMutex snapshots_mutex_; // A cache of the cf comparators // Thread safety: since it is a const it is safe to read it concurrently std::shared_ptr> cf_map_; // A cache of the cf handles // Thread safety: since the handle is read-only object it is a const it is // safe to read it concurrently std::shared_ptr> handle_map_; // A dummy snapshot object that refers to kMaxSequenceNumber SnapshotImpl dummy_max_snapshot_; }; class WritePreparedTxnReadCallback : public ReadCallback { public: WritePreparedTxnReadCallback(WritePreparedTxnDB* db, SequenceNumber snapshot) : ReadCallback(snapshot), db_(db), backed_by_snapshot_(kBackedByDBSnapshot) {} WritePreparedTxnReadCallback(WritePreparedTxnDB* db, SequenceNumber snapshot, SequenceNumber min_uncommitted, SnapshotBackup backed_by_snapshot) : ReadCallback(snapshot, min_uncommitted), db_(db), backed_by_snapshot_(backed_by_snapshot) { (void)backed_by_snapshot_; // to silence unused private field warning } virtual ~WritePreparedTxnReadCallback() { // If it is not backed by snapshot, the caller must check validity assert(valid_checked_ || backed_by_snapshot_ == kBackedByDBSnapshot); } // Will be called to see if the seq number visible; if not it moves on to // the next seq number. inline virtual bool IsVisibleFullCheck(SequenceNumber seq) override { auto snapshot = max_visible_seq_; bool snap_released = false; auto ret = db_->IsInSnapshot(seq, snapshot, min_uncommitted_, &snap_released); assert(!snap_released || backed_by_snapshot_ == kUnbackedByDBSnapshot); snap_released_ |= snap_released; return ret; } inline bool valid() { valid_checked_ = true; return snap_released_ == false; } // TODO(myabandeh): override Refresh when Iterator::Refresh is supported private: WritePreparedTxnDB* db_; // Whether max_visible_seq_ is backed by a snapshot const SnapshotBackup backed_by_snapshot_; bool snap_released_ = false; // Safety check to ensure that the caller has checked invalid statuses bool valid_checked_ = false; }; class AddPreparedCallback : public PreReleaseCallback { public: AddPreparedCallback(WritePreparedTxnDB* db, DBImpl* db_impl, size_t sub_batch_cnt, bool two_write_queues, bool first_prepare_batch) : db_(db), db_impl_(db_impl), sub_batch_cnt_(sub_batch_cnt), two_write_queues_(two_write_queues), first_prepare_batch_(first_prepare_batch) { (void)two_write_queues_; // to silence unused private field warning } virtual Status Callback(SequenceNumber prepare_seq, bool is_mem_disabled __attribute__((__unused__)), uint64_t log_number, size_t index, size_t total) override { assert(index < total); // To reduce the cost of lock acquisition competing with the concurrent // prepare requests, lock on the first callback and unlock on the last. const bool do_lock = !two_write_queues_ || index == 0; const bool do_unlock = !two_write_queues_ || index + 1 == total; // Always Prepare from the main queue assert(!two_write_queues_ || !is_mem_disabled); // implies the 1st queue TEST_SYNC_POINT("AddPreparedCallback::AddPrepared::begin:pause"); TEST_SYNC_POINT("AddPreparedCallback::AddPrepared::begin:resume"); if (do_lock) { db_->prepared_txns_.push_pop_mutex()->Lock(); } const bool kLocked = true; for (size_t i = 0; i < sub_batch_cnt_; i++) { db_->AddPrepared(prepare_seq + i, kLocked); } if (do_unlock) { db_->prepared_txns_.push_pop_mutex()->Unlock(); } TEST_SYNC_POINT("AddPreparedCallback::AddPrepared::end"); if (first_prepare_batch_) { assert(log_number != 0); db_impl_->logs_with_prep_tracker()->MarkLogAsContainingPrepSection( log_number); } return Status::OK(); } private: WritePreparedTxnDB* db_; DBImpl* db_impl_; size_t sub_batch_cnt_; bool two_write_queues_; // It is 2PC and this is the first prepare batch. Always the case in 2PC // unless it is WriteUnPrepared. bool first_prepare_batch_; }; class WritePreparedCommitEntryPreReleaseCallback : public PreReleaseCallback { public: // includes_data indicates that the commit also writes non-empty // CommitTimeWriteBatch to memtable, which needs to be committed separately. WritePreparedCommitEntryPreReleaseCallback( WritePreparedTxnDB* db, DBImpl* db_impl, SequenceNumber prep_seq, size_t prep_batch_cnt, size_t data_batch_cnt = 0, SequenceNumber aux_seq = kMaxSequenceNumber, size_t aux_batch_cnt = 0) : db_(db), db_impl_(db_impl), prep_seq_(prep_seq), prep_batch_cnt_(prep_batch_cnt), data_batch_cnt_(data_batch_cnt), includes_data_(data_batch_cnt_ > 0), aux_seq_(aux_seq), aux_batch_cnt_(aux_batch_cnt), includes_aux_batch_(aux_batch_cnt > 0) { assert((prep_batch_cnt_ > 0) != (prep_seq == kMaxSequenceNumber)); // xor assert(prep_batch_cnt_ > 0 || data_batch_cnt_ > 0); assert((aux_batch_cnt_ > 0) != (aux_seq == kMaxSequenceNumber)); // xor } virtual Status Callback(SequenceNumber commit_seq, bool is_mem_disabled __attribute__((__unused__)), uint64_t, size_t /*index*/, size_t /*total*/) override { // Always commit from the 2nd queue assert(!db_impl_->immutable_db_options().two_write_queues || is_mem_disabled); assert(includes_data_ || prep_seq_ != kMaxSequenceNumber); // Data batch is what accompanied with the commit marker and affects the // last seq in the commit batch. const uint64_t last_commit_seq = LIKELY(data_batch_cnt_ <= 1) ? commit_seq : commit_seq + data_batch_cnt_ - 1; if (prep_seq_ != kMaxSequenceNumber) { for (size_t i = 0; i < prep_batch_cnt_; i++) { db_->AddCommitted(prep_seq_ + i, last_commit_seq); } } // else there was no prepare phase if (includes_aux_batch_) { for (size_t i = 0; i < aux_batch_cnt_; i++) { db_->AddCommitted(aux_seq_ + i, last_commit_seq); } } if (includes_data_) { assert(data_batch_cnt_); // Commit the data that is accompanied with the commit request for (size_t i = 0; i < data_batch_cnt_; i++) { // For commit seq of each batch use the commit seq of the last batch. // This would make debugging easier by having all the batches having // the same sequence number. db_->AddCommitted(commit_seq + i, last_commit_seq); } } if (db_impl_->immutable_db_options().two_write_queues) { assert(is_mem_disabled); // implies the 2nd queue // Publish the sequence number. We can do that here assuming the callback // is invoked only from one write queue, which would guarantee that the // publish sequence numbers will be in order, i.e., once a seq is // published all the seq prior to that are also publishable. db_impl_->SetLastPublishedSequence(last_commit_seq); // Note RemovePrepared should be called after publishing the seq. // Otherwise SmallestUnCommittedSeq optimization breaks. if (prep_seq_ != kMaxSequenceNumber) { db_->RemovePrepared(prep_seq_, prep_batch_cnt_); } // else there was no prepare phase if (includes_aux_batch_) { db_->RemovePrepared(aux_seq_, aux_batch_cnt_); } } // else SequenceNumber that is updated as part of the write already does the // publishing return Status::OK(); } private: WritePreparedTxnDB* db_; DBImpl* db_impl_; // kMaxSequenceNumber if there was no prepare phase SequenceNumber prep_seq_; size_t prep_batch_cnt_; size_t data_batch_cnt_; // Data here is the batch that is written with the commit marker, either // because it is commit without prepare or commit has a CommitTimeWriteBatch. bool includes_data_; // Auxiliary batch (if there is any) is a batch that is written before, but // gets the same commit seq as prepare batch or data batch. This is used in // two write queues where the CommitTimeWriteBatch becomes the aux batch and // we do a separate write to actually commit everything. SequenceNumber aux_seq_; size_t aux_batch_cnt_; bool includes_aux_batch_; }; // For two_write_queues commit both the aborted batch and the cleanup batch and // then published the seq class WritePreparedRollbackPreReleaseCallback : public PreReleaseCallback { public: WritePreparedRollbackPreReleaseCallback(WritePreparedTxnDB* db, DBImpl* db_impl, SequenceNumber prep_seq, SequenceNumber rollback_seq, size_t prep_batch_cnt) : db_(db), db_impl_(db_impl), prep_seq_(prep_seq), rollback_seq_(rollback_seq), prep_batch_cnt_(prep_batch_cnt) { assert(prep_seq != kMaxSequenceNumber); assert(rollback_seq != kMaxSequenceNumber); assert(prep_batch_cnt_ > 0); } Status Callback(SequenceNumber commit_seq, bool is_mem_disabled, uint64_t, size_t /*index*/, size_t /*total*/) override { // Always commit from the 2nd queue assert(is_mem_disabled); // implies the 2nd queue assert(db_impl_->immutable_db_options().two_write_queues); #ifdef NDEBUG (void)is_mem_disabled; #endif const uint64_t last_commit_seq = commit_seq; db_->AddCommitted(rollback_seq_, last_commit_seq); for (size_t i = 0; i < prep_batch_cnt_; i++) { db_->AddCommitted(prep_seq_ + i, last_commit_seq); } db_impl_->SetLastPublishedSequence(last_commit_seq); return Status::OK(); } private: WritePreparedTxnDB* db_; DBImpl* db_impl_; SequenceNumber prep_seq_; SequenceNumber rollback_seq_; size_t prep_batch_cnt_; }; // Count the number of sub-batches inside a batch. A sub-batch does not have // duplicate keys. struct SubBatchCounter : public WriteBatch::Handler { explicit SubBatchCounter(std::map& comparators) : comparators_(comparators), batches_(1) {} std::map& comparators_; using CFKeys = std::set; std::map keys_; size_t batches_; size_t BatchCount() { return batches_; } void AddKey(const uint32_t cf, const Slice& key); void InitWithComp(const uint32_t cf); Status MarkNoop(bool) override { return Status::OK(); } Status MarkEndPrepare(const Slice&) override { return Status::OK(); } Status MarkCommit(const Slice&) override { return Status::OK(); } Status PutCF(uint32_t cf, const Slice& key, const Slice&) override { AddKey(cf, key); return Status::OK(); } Status DeleteCF(uint32_t cf, const Slice& key) override { AddKey(cf, key); return Status::OK(); } Status SingleDeleteCF(uint32_t cf, const Slice& key) override { AddKey(cf, key); return Status::OK(); } Status MergeCF(uint32_t cf, const Slice& key, const Slice&) override { AddKey(cf, key); return Status::OK(); } Status MarkBeginPrepare(bool) override { return Status::OK(); } Status MarkRollback(const Slice&) override { return Status::OK(); } Handler::OptionState WriteAfterCommit() const override { return Handler::OptionState::kDisabled; } }; SnapshotBackup WritePreparedTxnDB::AssignMinMaxSeqs(const Snapshot* snapshot, SequenceNumber* min, SequenceNumber* max) { if (snapshot != nullptr) { *min = static_cast_with_check(snapshot)->min_uncommitted_; *max = static_cast_with_check(snapshot)->number_; // A duplicate of the check in EnhanceSnapshot(). assert(*min <= *max + 1); return kBackedByDBSnapshot; } else { *min = SmallestUnCommittedSeq(); *max = 0; // to be assigned later after sv is referenced. return kUnbackedByDBSnapshot; } } bool WritePreparedTxnDB::ValidateSnapshot( const SequenceNumber snap_seq, const SnapshotBackup backed_by_snapshot, std::memory_order order) { if (backed_by_snapshot == kBackedByDBSnapshot) { return true; } else { SequenceNumber max = max_evicted_seq_.load(order); // Validate that max has not advanced the snapshot seq that is not backed // by a real snapshot. This is a very rare case that should not happen in // real workloads. if (UNLIKELY(snap_seq <= max && snap_seq != 0)) { return false; } } return true; } } // namespace ROCKSDB_NAMESPACE