// 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). #ifndef ROCKSDB_LITE #include "utilities/transactions/write_unprepared_txn_db.h" #include "db/arena_wrapped_db_iter.h" #include "rocksdb/utilities/transaction_db.h" #include "util/cast_util.h" namespace ROCKSDB_NAMESPACE { // Instead of reconstructing a Transaction object, and calling rollback on it, // we can be more efficient with RollbackRecoveredTransaction by skipping // unnecessary steps (eg. updating CommitMap, reconstructing keyset) Status WriteUnpreparedTxnDB::RollbackRecoveredTransaction( const DBImpl::RecoveredTransaction* rtxn) { // TODO(lth): Reduce duplicate code with WritePrepared rollback logic. assert(rtxn->unprepared_); auto cf_map_shared_ptr = WritePreparedTxnDB::GetCFHandleMap(); auto cf_comp_map_shared_ptr = WritePreparedTxnDB::GetCFComparatorMap(); // In theory we could write with disableWAL = true during recovery, and // assume that if we crash again during recovery, we can just replay from // the very beginning. Unfortunately, the XIDs from the application may not // necessarily be unique across restarts, potentially leading to situations // like this: // // BEGIN_PREPARE(unprepared) Put(a) END_PREPARE(xid = 1) // -- crash and recover with Put(a) rolled back as it was not prepared // BEGIN_PREPARE(prepared) Put(b) END_PREPARE(xid = 1) // COMMIT(xid = 1) // -- crash and recover with both a, b // // We could just write the rollback marker, but then we would have to extend // MemTableInserter during recovery to actually do writes into the DB // instead of just dropping the in-memory write batch. // WriteOptions w_options; class InvalidSnapshotReadCallback : public ReadCallback { public: InvalidSnapshotReadCallback(SequenceNumber snapshot) : ReadCallback(snapshot) {} inline bool IsVisibleFullCheck(SequenceNumber) override { // The seq provided as snapshot is the seq right before we have locked and // wrote to it, so whatever is there, it is committed. return true; } // Ignore the refresh request since we are confident that our snapshot seq // is not going to be affected by concurrent compactions (not enabled yet.) void Refresh(SequenceNumber) override {} }; // Iterate starting with largest sequence number. for (auto it = rtxn->batches_.rbegin(); it != rtxn->batches_.rend(); ++it) { auto last_visible_txn = it->first - 1; const auto& batch = it->second.batch_; WriteBatch rollback_batch; struct RollbackWriteBatchBuilder : public WriteBatch::Handler { DBImpl* db_; ReadOptions roptions; InvalidSnapshotReadCallback callback; WriteBatch* rollback_batch_; std::map& comparators_; std::map& handles_; using CFKeys = std::set; std::map keys_; bool rollback_merge_operands_; RollbackWriteBatchBuilder( DBImpl* db, SequenceNumber snap_seq, WriteBatch* dst_batch, std::map& comparators, std::map& handles, bool rollback_merge_operands) : db_(db), callback(snap_seq), // disable min_uncommitted optimization rollback_batch_(dst_batch), comparators_(comparators), handles_(handles), rollback_merge_operands_(rollback_merge_operands) {} Status Rollback(uint32_t cf, const Slice& key) { Status s; CFKeys& cf_keys = keys_[cf]; if (cf_keys.size() == 0) { // just inserted auto cmp = comparators_[cf]; keys_[cf] = CFKeys(SetComparator(cmp)); } auto res = cf_keys.insert(key); if (res.second == false) { // second is false if a element already existed. return s; } PinnableSlice pinnable_val; bool not_used; auto cf_handle = handles_[cf]; DBImpl::GetImplOptions get_impl_options; get_impl_options.column_family = cf_handle; get_impl_options.value = &pinnable_val; get_impl_options.value_found = ¬_used; get_impl_options.callback = &callback; s = db_->GetImpl(roptions, key, get_impl_options); assert(s.ok() || s.IsNotFound()); if (s.ok()) { s = rollback_batch_->Put(cf_handle, key, pinnable_val); assert(s.ok()); } else if (s.IsNotFound()) { // There has been no readable value before txn. By adding a delete we // make sure that there will be none afterwards either. s = rollback_batch_->Delete(cf_handle, key); assert(s.ok()); } else { // Unexpected status. Return it to the user. } return s; } Status PutCF(uint32_t cf, const Slice& key, const Slice& /*val*/) override { return Rollback(cf, key); } Status DeleteCF(uint32_t cf, const Slice& key) override { return Rollback(cf, key); } Status SingleDeleteCF(uint32_t cf, const Slice& key) override { return Rollback(cf, key); } Status MergeCF(uint32_t cf, const Slice& key, const Slice& /*val*/) override { if (rollback_merge_operands_) { return Rollback(cf, key); } else { return Status::OK(); } } // Recovered batches do not contain 2PC markers. Status MarkNoop(bool) override { return Status::InvalidArgument(); } Status MarkBeginPrepare(bool) override { return Status::InvalidArgument(); } Status MarkEndPrepare(const Slice&) override { return Status::InvalidArgument(); } Status MarkCommit(const Slice&) override { return Status::InvalidArgument(); } Status MarkRollback(const Slice&) override { return Status::InvalidArgument(); } } rollback_handler(db_impl_, last_visible_txn, &rollback_batch, *cf_comp_map_shared_ptr.get(), *cf_map_shared_ptr.get(), txn_db_options_.rollback_merge_operands); auto s = batch->Iterate(&rollback_handler); if (!s.ok()) { return s; } // The Rollback marker will be used as a batch separator WriteBatchInternal::MarkRollback(&rollback_batch, rtxn->name_); const uint64_t kNoLogRef = 0; const bool kDisableMemtable = true; const size_t kOneBatch = 1; uint64_t seq_used = kMaxSequenceNumber; s = db_impl_->WriteImpl(w_options, &rollback_batch, nullptr, nullptr, kNoLogRef, !kDisableMemtable, &seq_used, kOneBatch); if (!s.ok()) { return s; } // If two_write_queues, we must manually release the sequence number to // readers. if (db_impl_->immutable_db_options().two_write_queues) { db_impl_->SetLastPublishedSequence(seq_used); } } return Status::OK(); } Status WriteUnpreparedTxnDB::Initialize( const std::vector& compaction_enabled_cf_indices, const std::vector& handles) { // TODO(lth): Reduce code duplication in this function. auto dbimpl = static_cast_with_check(GetRootDB()); assert(dbimpl != nullptr); db_impl_->SetSnapshotChecker(new WritePreparedSnapshotChecker(this)); // A callback to commit a single sub-batch class CommitSubBatchPreReleaseCallback : public PreReleaseCallback { public: explicit CommitSubBatchPreReleaseCallback(WritePreparedTxnDB* db) : db_(db) {} Status Callback(SequenceNumber commit_seq, bool is_mem_disabled __attribute__((__unused__)), uint64_t, size_t /*index*/, size_t /*total*/) override { assert(!is_mem_disabled); db_->AddCommitted(commit_seq, commit_seq); return Status::OK(); } private: WritePreparedTxnDB* db_; }; db_impl_->SetRecoverableStatePreReleaseCallback( new CommitSubBatchPreReleaseCallback(this)); // PessimisticTransactionDB::Initialize for (auto cf_ptr : handles) { AddColumnFamily(cf_ptr); } // Verify cf options for (auto handle : handles) { ColumnFamilyDescriptor cfd; Status s = handle->GetDescriptor(&cfd); if (!s.ok()) { return s; } s = VerifyCFOptions(cfd.options); if (!s.ok()) { return s; } } // Re-enable compaction for the column families that initially had // compaction enabled. std::vector compaction_enabled_cf_handles; compaction_enabled_cf_handles.reserve(compaction_enabled_cf_indices.size()); for (auto index : compaction_enabled_cf_indices) { compaction_enabled_cf_handles.push_back(handles[index]); } // create 'real' transactions from recovered shell transactions auto rtxns = dbimpl->recovered_transactions(); std::map ordered_seq_cnt; for (auto rtxn : rtxns) { auto recovered_trx = rtxn.second; assert(recovered_trx); assert(recovered_trx->batches_.size() >= 1); assert(recovered_trx->name_.length()); // We can only rollback transactions after AdvanceMaxEvictedSeq is called, // but AddPrepared must occur before AdvanceMaxEvictedSeq, which is why // two iterations is required. if (recovered_trx->unprepared_) { continue; } WriteOptions w_options; w_options.sync = true; TransactionOptions t_options; auto first_log_number = recovered_trx->batches_.begin()->second.log_number_; auto first_seq = recovered_trx->batches_.begin()->first; auto last_prepare_batch_cnt = recovered_trx->batches_.begin()->second.batch_cnt_; Transaction* real_trx = BeginTransaction(w_options, t_options, nullptr); assert(real_trx); auto wupt = static_cast_with_check(real_trx); wupt->recovered_txn_ = true; real_trx->SetLogNumber(first_log_number); real_trx->SetId(first_seq); Status s = real_trx->SetName(recovered_trx->name_); if (!s.ok()) { return s; } wupt->prepare_batch_cnt_ = last_prepare_batch_cnt; for (auto batch : recovered_trx->batches_) { const auto& seq = batch.first; const auto& batch_info = batch.second; auto cnt = batch_info.batch_cnt_ ? batch_info.batch_cnt_ : 1; assert(batch_info.log_number_); ordered_seq_cnt[seq] = cnt; assert(wupt->unprep_seqs_.count(seq) == 0); wupt->unprep_seqs_[seq] = cnt; s = wupt->RebuildFromWriteBatch(batch_info.batch_); assert(s.ok()); if (!s.ok()) { return s; } } const bool kClear = true; wupt->InitWriteBatch(kClear); real_trx->SetState(Transaction::PREPARED); if (!s.ok()) { return s; } } // AddPrepared must be called in order for (auto seq_cnt : ordered_seq_cnt) { auto seq = seq_cnt.first; auto cnt = seq_cnt.second; for (size_t i = 0; i < cnt; i++) { AddPrepared(seq + i); } } SequenceNumber prev_max = max_evicted_seq_; SequenceNumber last_seq = db_impl_->GetLatestSequenceNumber(); AdvanceMaxEvictedSeq(prev_max, last_seq); // Create a gap between max and the next snapshot. This simplifies the logic // in IsInSnapshot by not having to consider the special case of max == // snapshot after recovery. This is tested in IsInSnapshotEmptyMapTest. if (last_seq) { db_impl_->versions_->SetLastAllocatedSequence(last_seq + 1); db_impl_->versions_->SetLastSequence(last_seq + 1); db_impl_->versions_->SetLastPublishedSequence(last_seq + 1); } Status s; // Rollback unprepared transactions. for (auto rtxn : rtxns) { auto recovered_trx = rtxn.second; if (recovered_trx->unprepared_) { s = RollbackRecoveredTransaction(recovered_trx); if (!s.ok()) { return s; } continue; } } if (s.ok()) { dbimpl->DeleteAllRecoveredTransactions(); // Compaction should start only after max_evicted_seq_ is set AND recovered // transactions are either added to PrepareHeap or rolled back. s = EnableAutoCompaction(compaction_enabled_cf_handles); } return s; } Transaction* WriteUnpreparedTxnDB::BeginTransaction( const WriteOptions& write_options, const TransactionOptions& txn_options, Transaction* old_txn) { if (old_txn != nullptr) { ReinitializeTransaction(old_txn, write_options, txn_options); return old_txn; } else { return new WriteUnpreparedTxn(this, write_options, txn_options); } } // Struct to hold ownership of snapshot and read callback for iterator cleanup. struct WriteUnpreparedTxnDB::IteratorState { IteratorState(WritePreparedTxnDB* txn_db, SequenceNumber sequence, std::shared_ptr s, SequenceNumber min_uncommitted, WriteUnpreparedTxn* txn) : callback(txn_db, sequence, min_uncommitted, txn->unprep_seqs_, kBackedByDBSnapshot), snapshot(s) {} SequenceNumber MaxVisibleSeq() { return callback.max_visible_seq(); } WriteUnpreparedTxnReadCallback callback; std::shared_ptr snapshot; }; namespace { static void CleanupWriteUnpreparedTxnDBIterator(void* arg1, void* /*arg2*/) { delete reinterpret_cast(arg1); } } // anonymous namespace Iterator* WriteUnpreparedTxnDB::NewIterator(const ReadOptions& options, ColumnFamilyHandle* column_family, WriteUnpreparedTxn* txn) { // TODO(lth): Refactor so that this logic is shared with WritePrepared. constexpr bool ALLOW_BLOB = true; constexpr bool ALLOW_REFRESH = true; std::shared_ptr own_snapshot = nullptr; SequenceNumber snapshot_seq = kMaxSequenceNumber; SequenceNumber min_uncommitted = 0; // Currently, the Prev() iterator logic does not work well without snapshot // validation. The logic simply iterates through values of a key in // ascending seqno order, stopping at the first non-visible value and // returning the last visible value. // // For example, if snapshot sequence is 3, and we have the following keys: // foo: v1 1 // foo: v2 2 // foo: v3 3 // foo: v4 4 // foo: v5 5 // // Then 1, 2, 3 will be visible, but 4 will be non-visible, so we return v3, // which is the last visible value. // // For unprepared transactions, if we have snap_seq = 3, but the current // transaction has unprep_seq 5, then returning the first non-visible value // would be incorrect, as we should return v5, and not v3. The problem is that // there are committed values at snapshot_seq < commit_seq < unprep_seq. // // Snapshot validation can prevent this problem by ensuring that no committed // values exist at snapshot_seq < commit_seq, and thus any value with a // sequence number greater than snapshot_seq must be unprepared values. For // example, if the transaction had a snapshot at 3, then snapshot validation // would be performed during the Put(v5) call. It would find v4, and the Put // would fail with snapshot validation failure. // // TODO(lth): Improve Prev() logic to continue iterating until // max_visible_seq, and then return the last visible value, so that this // restriction can be lifted. const Snapshot* snapshot = nullptr; if (options.snapshot == nullptr) { snapshot = GetSnapshot(); own_snapshot = std::make_shared(db_impl_, snapshot); } else { snapshot = options.snapshot; } snapshot_seq = snapshot->GetSequenceNumber(); assert(snapshot_seq != kMaxSequenceNumber); // Iteration is safe as long as largest_validated_seq <= snapshot_seq. We are // guaranteed that for keys that were modified by this transaction (and thus // might have unprepared values), no committed values exist at // largest_validated_seq < commit_seq (or the contrapositive: any committed // value must exist at commit_seq <= largest_validated_seq). This implies // that commit_seq <= largest_validated_seq <= snapshot_seq or commit_seq <= // snapshot_seq. As explained above, the problem with Prev() only happens when // snapshot_seq < commit_seq. // // For keys that were not modified by this transaction, largest_validated_seq_ // is meaningless, and Prev() should just work with the existing visibility // logic. if (txn->largest_validated_seq_ > snapshot->GetSequenceNumber() && !txn->unprep_seqs_.empty()) { ROCKS_LOG_ERROR(info_log_, "WriteUnprepared iterator creation failed since the " "transaction has performed unvalidated writes"); return nullptr; } min_uncommitted = static_cast_with_check(snapshot)->min_uncommitted_; auto* cfd = static_cast_with_check(column_family)->cfd(); auto* state = new IteratorState(this, snapshot_seq, own_snapshot, min_uncommitted, txn); auto* db_iter = db_impl_->NewIteratorImpl(options, cfd, state->MaxVisibleSeq(), &state->callback, !ALLOW_BLOB, !ALLOW_REFRESH); db_iter->RegisterCleanup(CleanupWriteUnpreparedTxnDBIterator, state, nullptr); return db_iter; } } // namespace ROCKSDB_NAMESPACE #endif // ROCKSDB_LITE