#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { namespace ErrorCodes { extern const int BAD_ARGUMENTS; extern const int NOT_IMPLEMENTED; extern const int INCORRECT_QUERY; extern const int QUERY_IS_NOT_SUPPORTED_IN_MATERIALIZED_VIEW; } static inline String generateInnerTableName(const StorageID & view_id) { if (view_id.hasUUID()) return ".inner_id." + toString(view_id.uuid); return ".inner." + view_id.getTableName(); } /// Remove columns from target_header that does not exists in src_header static void removeNonCommonColumns(const Block & src_header, Block & target_header) { std::set target_only_positions; for (const auto & column : target_header) { if (!src_header.has(column.name)) target_only_positions.insert(target_header.getPositionByName(column.name)); } target_header.erase(target_only_positions); } StorageMaterializedView::StorageMaterializedView( const StorageID & table_id_, ContextPtr local_context, const ASTCreateQuery & query, const ColumnsDescription & columns_, bool attach_, const String & comment) : IStorage(table_id_), WithMutableContext(local_context->getGlobalContext()) { StorageInMemoryMetadata storage_metadata; storage_metadata.setColumns(columns_); if (!query.select) throw Exception(ErrorCodes::INCORRECT_QUERY, "SELECT query is not specified for {}", getName()); /// If the destination table is not set, use inner table has_inner_table = query.to_table_id.empty(); if (has_inner_table && !query.storage) throw Exception(ErrorCodes::INCORRECT_QUERY, "You must specify where to save results of a MaterializedView query: " "either ENGINE or an existing table in a TO clause"); if (query.select->list_of_selects->children.size() != 1) throw Exception(ErrorCodes::QUERY_IS_NOT_SUPPORTED_IN_MATERIALIZED_VIEW, "UNION is not supported for MATERIALIZED VIEW"); auto select = SelectQueryDescription::getSelectQueryFromASTForMatView(query.select->clone(), local_context); storage_metadata.setSelectQuery(select); if (!comment.empty()) storage_metadata.setComment(comment); setInMemoryMetadata(storage_metadata); bool point_to_itself_by_uuid = has_inner_table && query.to_inner_uuid != UUIDHelpers::Nil && query.to_inner_uuid == table_id_.uuid; bool point_to_itself_by_name = !has_inner_table && query.to_table_id.database_name == table_id_.database_name && query.to_table_id.table_name == table_id_.table_name; if (point_to_itself_by_uuid || point_to_itself_by_name) throw Exception(ErrorCodes::BAD_ARGUMENTS, "Materialized view {} cannot point to itself", table_id_.getFullTableName()); if (!has_inner_table) { target_table_id = query.to_table_id; } else if (attach_) { /// If there is an ATTACH request, then the internal table must already be created. target_table_id = StorageID(getStorageID().database_name, generateInnerTableName(getStorageID()), query.to_inner_uuid); } else { /// We will create a query to create an internal table. auto create_context = Context::createCopy(local_context); auto manual_create_query = std::make_shared(); manual_create_query->setDatabase(getStorageID().database_name); manual_create_query->setTable(generateInnerTableName(getStorageID())); manual_create_query->uuid = query.to_inner_uuid; auto new_columns_list = std::make_shared(); new_columns_list->set(new_columns_list->columns, query.columns_list->columns->ptr()); manual_create_query->set(manual_create_query->columns_list, new_columns_list); manual_create_query->set(manual_create_query->storage, query.storage->ptr()); InterpreterCreateQuery create_interpreter(manual_create_query, create_context); create_interpreter.setInternal(true); create_interpreter.execute(); target_table_id = DatabaseCatalog::instance().getTable({manual_create_query->getDatabase(), manual_create_query->getTable()}, getContext())->getStorageID(); } } QueryProcessingStage::Enum StorageMaterializedView::getQueryProcessingStage( ContextPtr local_context, QueryProcessingStage::Enum to_stage, const StorageSnapshotPtr &, SelectQueryInfo & query_info) const { /// TODO: Find a way to support projections for StorageMaterializedView. Why do we use different /// metadata for materialized view and target table? If they are the same, we can get rid of all /// converting and use it just like a normal view. query_info.ignore_projections = true; const auto & target_metadata = getTargetTable()->getInMemoryMetadataPtr(); return getTargetTable()->getQueryProcessingStage(local_context, to_stage, getTargetTable()->getStorageSnapshot(target_metadata, local_context), query_info); } void StorageMaterializedView::read( QueryPlan & query_plan, const Names & column_names, const StorageSnapshotPtr & storage_snapshot, SelectQueryInfo & query_info, ContextPtr local_context, QueryProcessingStage::Enum processed_stage, const size_t max_block_size, const size_t num_streams) { auto storage = getTargetTable(); auto lock = storage->lockForShare(local_context->getCurrentQueryId(), local_context->getSettingsRef().lock_acquire_timeout); auto target_metadata_snapshot = storage->getInMemoryMetadataPtr(); auto target_storage_snapshot = storage->getStorageSnapshot(target_metadata_snapshot, local_context); if (query_info.order_optimizer) query_info.input_order_info = query_info.order_optimizer->getInputOrder(target_metadata_snapshot, local_context); storage->read(query_plan, column_names, target_storage_snapshot, query_info, local_context, processed_stage, max_block_size, num_streams); if (query_plan.isInitialized()) { auto mv_header = getHeaderForProcessingStage(column_names, storage_snapshot, query_info, local_context, processed_stage); auto target_header = query_plan.getCurrentDataStream().header; /// No need to convert columns that does not exists in MV removeNonCommonColumns(mv_header, target_header); /// No need to convert columns that does not exists in the result header. /// /// Distributed storage may process query up to the specific stage, and /// so the result header may not include all the columns from the /// materialized view. removeNonCommonColumns(target_header, mv_header); if (!blocksHaveEqualStructure(mv_header, target_header)) { auto converting_actions = ActionsDAG::makeConvertingActions(target_header.getColumnsWithTypeAndName(), mv_header.getColumnsWithTypeAndName(), ActionsDAG::MatchColumnsMode::Name); /* Leave columns outside from materialized view structure as is. * They may be added in case of distributed query with JOIN. * In that case underlying table returns joined columns as well. */ converting_actions->projectInput(false); auto converting_step = std::make_unique(query_plan.getCurrentDataStream(), converting_actions); converting_step->setStepDescription("Convert target table structure to MaterializedView structure"); query_plan.addStep(std::move(converting_step)); } query_plan.addStorageHolder(storage); query_plan.addTableLock(std::move(lock)); } } SinkToStoragePtr StorageMaterializedView::write(const ASTPtr & query, const StorageMetadataPtr & /*metadata_snapshot*/, ContextPtr local_context, bool async_insert) { auto storage = getTargetTable(); auto lock = storage->lockForShare(local_context->getCurrentQueryId(), local_context->getSettingsRef().lock_acquire_timeout); auto metadata_snapshot = storage->getInMemoryMetadataPtr(); auto sink = storage->write(query, metadata_snapshot, local_context, async_insert); sink->addTableLock(lock); return sink; } void StorageMaterializedView::drop() { auto table_id = getStorageID(); const auto & select_query = getInMemoryMetadataPtr()->getSelectQuery(); if (!select_query.select_table_id.empty()) DatabaseCatalog::instance().removeViewDependency(select_query.select_table_id, table_id); /// Sync flag and the setting make sense for Atomic databases only. /// However, with Atomic databases, IStorage::drop() can be called only from a background task in DatabaseCatalog. /// Running synchronous DROP from that task leads to deadlock. /// Usually dropInnerTableIfAny is no-op, because the inner table is dropped before enqueueing a drop task for the MV itself. /// But there's a race condition with SYSTEM RESTART REPLICA: the inner table might be detached due to RESTART. /// In this case, dropInnerTableIfAny will not find the inner table and will not drop it during executions of DROP query for the MV itself. /// DDLGuard does not protect from that, because RESTART REPLICA acquires DDLGuard for the inner table name, /// but DROP acquires DDLGuard for the name of MV. And we cannot acquire second DDLGuard for the inner name in DROP, /// because it may lead to lock-order-inversion (DDLGuards must be acquired in lexicographical order). dropInnerTableIfAny(/* sync */ false, getContext()); } void StorageMaterializedView::dropInnerTableIfAny(bool sync, ContextPtr local_context) { /// We will use `sync` argument wneh this function is called from a DROP query /// and will ignore database_atomic_wait_for_drop_and_detach_synchronously when it's called from drop task. /// See the comment in StorageMaterializedView::drop. /// DDL queries with StorageMaterializedView are fundamentally broken. /// Best-effort to make them work: the inner table name is almost always less than the MV name (so it's safe to lock DDLGuard) bool may_lock_ddl_guard = getStorageID().getQualifiedName() < target_table_id.getQualifiedName(); if (has_inner_table && tryGetTargetTable()) InterpreterDropQuery::executeDropQuery(ASTDropQuery::Kind::Drop, getContext(), local_context, target_table_id, sync, /* ignore_sync_setting */ true, may_lock_ddl_guard); } void StorageMaterializedView::truncate(const ASTPtr &, const StorageMetadataPtr &, ContextPtr local_context, TableExclusiveLockHolder &) { if (has_inner_table) InterpreterDropQuery::executeDropQuery(ASTDropQuery::Kind::Truncate, getContext(), local_context, target_table_id, true); } void StorageMaterializedView::checkStatementCanBeForwarded() const { if (!has_inner_table) throw Exception(ErrorCodes::INCORRECT_QUERY, "MATERIALIZED VIEW targets existing table {}. " "Execute the statement directly on it.", target_table_id.getNameForLogs()); } bool StorageMaterializedView::optimize( const ASTPtr & query, const StorageMetadataPtr & /*metadata_snapshot*/, const ASTPtr & partition, bool final, bool deduplicate, const Names & deduplicate_by_columns, bool cleanup, ContextPtr local_context) { checkStatementCanBeForwarded(); auto storage_ptr = getTargetTable(); auto metadata_snapshot = storage_ptr->getInMemoryMetadataPtr(); return getTargetTable()->optimize(query, metadata_snapshot, partition, final, deduplicate, deduplicate_by_columns, cleanup, local_context); } void StorageMaterializedView::alter( const AlterCommands & params, ContextPtr local_context, AlterLockHolder &) { auto table_id = getStorageID(); StorageInMemoryMetadata new_metadata = getInMemoryMetadata(); StorageInMemoryMetadata old_metadata = getInMemoryMetadata(); params.apply(new_metadata, local_context); /// start modify query const auto & new_select = new_metadata.select; const auto & old_select = old_metadata.getSelectQuery(); DatabaseCatalog::instance().updateViewDependency(old_select.select_table_id, table_id, new_select.select_table_id, table_id); /// end modify query DatabaseCatalog::instance().getDatabase(table_id.database_name)->alterTable(local_context, table_id, new_metadata); setInMemoryMetadata(new_metadata); } void StorageMaterializedView::checkAlterIsPossible(const AlterCommands & commands, ContextPtr /*local_context*/) const { for (const auto & command : commands) { if (!command.isCommentAlter() && command.type != AlterCommand::MODIFY_QUERY) throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Alter of type '{}' is not supported by storage {}", command.type, getName()); } } void StorageMaterializedView::checkMutationIsPossible(const MutationCommands & commands, const Settings & settings) const { checkStatementCanBeForwarded(); getTargetTable()->checkMutationIsPossible(commands, settings); } Pipe StorageMaterializedView::alterPartition( const StorageMetadataPtr & metadata_snapshot, const PartitionCommands & commands, ContextPtr local_context) { checkStatementCanBeForwarded(); return getTargetTable()->alterPartition(metadata_snapshot, commands, local_context); } void StorageMaterializedView::checkAlterPartitionIsPossible( const PartitionCommands & commands, const StorageMetadataPtr & metadata_snapshot, const Settings & settings, ContextPtr local_context) const { checkStatementCanBeForwarded(); getTargetTable()->checkAlterPartitionIsPossible(commands, metadata_snapshot, settings, local_context); } void StorageMaterializedView::mutate(const MutationCommands & commands, ContextPtr local_context) { checkStatementCanBeForwarded(); getTargetTable()->mutate(commands, local_context); } void StorageMaterializedView::renameInMemory(const StorageID & new_table_id) { auto old_table_id = getStorageID(); auto metadata_snapshot = getInMemoryMetadataPtr(); bool from_atomic_to_atomic_database = old_table_id.hasUUID() && new_table_id.hasUUID(); if (!from_atomic_to_atomic_database && has_inner_table && tryGetTargetTable()) { auto new_target_table_name = generateInnerTableName(new_table_id); auto rename = std::make_shared(); assert(target_table_id.database_name == old_table_id.database_name); ASTRenameQuery::Element elem { ASTRenameQuery::Table { target_table_id.database_name.empty() ? nullptr : std::make_shared(target_table_id.database_name), std::make_shared(target_table_id.table_name) }, ASTRenameQuery::Table { new_table_id.database_name.empty() ? nullptr : std::make_shared(new_table_id.database_name), std::make_shared(new_target_table_name) } }; rename->elements.emplace_back(std::move(elem)); InterpreterRenameQuery(rename, getContext()).execute(); target_table_id.database_name = new_table_id.database_name; target_table_id.table_name = new_target_table_name; } IStorage::renameInMemory(new_table_id); if (from_atomic_to_atomic_database && has_inner_table) { assert(target_table_id.database_name == old_table_id.database_name); target_table_id.database_name = new_table_id.database_name; } const auto & select_query = metadata_snapshot->getSelectQuery(); // TODO Actually we don't need to update dependency if MV has UUID, but then db and table name will be outdated DatabaseCatalog::instance().updateViewDependency(select_query.select_table_id, old_table_id, select_query.select_table_id, getStorageID()); } void StorageMaterializedView::startup() { auto metadata_snapshot = getInMemoryMetadataPtr(); const auto & select_query = metadata_snapshot->getSelectQuery(); if (!select_query.select_table_id.empty()) DatabaseCatalog::instance().addViewDependency(select_query.select_table_id, getStorageID()); } void StorageMaterializedView::shutdown(bool) { auto metadata_snapshot = getInMemoryMetadataPtr(); const auto & select_query = metadata_snapshot->getSelectQuery(); /// Make sure the dependency is removed after DETACH TABLE if (!select_query.select_table_id.empty()) DatabaseCatalog::instance().removeViewDependency(select_query.select_table_id, getStorageID()); } StoragePtr StorageMaterializedView::getTargetTable() const { checkStackSize(); return DatabaseCatalog::instance().getTable(target_table_id, getContext()); } StoragePtr StorageMaterializedView::tryGetTargetTable() const { checkStackSize(); return DatabaseCatalog::instance().tryGetTable(target_table_id, getContext()); } NamesAndTypesList StorageMaterializedView::getVirtuals() const { return getTargetTable()->getVirtuals(); } Strings StorageMaterializedView::getDataPaths() const { if (auto table = tryGetTargetTable()) return table->getDataPaths(); return {}; } void StorageMaterializedView::backupData(BackupEntriesCollector & backup_entries_collector, const String & data_path_in_backup, const std::optional & partitions) { /// We backup the target table's data only if it's inner. if (hasInnerTable()) { if (auto table = tryGetTargetTable()) table->backupData(backup_entries_collector, data_path_in_backup, partitions); else LOG_WARNING(&Poco::Logger::get("StorageMaterializedView"), "Inner table does not exist, will not backup any data"); } } void StorageMaterializedView::restoreDataFromBackup(RestorerFromBackup & restorer, const String & data_path_in_backup, const std::optional & partitions) { if (hasInnerTable()) return getTargetTable()->restoreDataFromBackup(restorer, data_path_in_backup, partitions); } bool StorageMaterializedView::supportsBackupPartition() const { if (hasInnerTable()) return getTargetTable()->supportsBackupPartition(); return false; } std::optional StorageMaterializedView::totalRows(const Settings & settings) const { if (hasInnerTable()) { if (auto table = tryGetTargetTable()) return table->totalRows(settings); } return {}; } std::optional StorageMaterializedView::totalBytes(const Settings & settings) const { if (hasInnerTable()) { if (auto table = tryGetTargetTable()) return table->totalBytes(settings); } return {}; } ActionLock StorageMaterializedView::getActionLock(StorageActionBlockType type) { if (has_inner_table) { if (auto target_table = tryGetTargetTable()) return target_table->getActionLock(type); } return ActionLock{}; } bool StorageMaterializedView::isRemote() const { if (auto table = tryGetTargetTable()) return table->isRemote(); return false; } void registerStorageMaterializedView(StorageFactory & factory) { factory.registerStorage("MaterializedView", [](const StorageFactory::Arguments & args) { /// Pass local_context here to convey setting for inner table return std::make_shared( args.table_id, args.getLocalContext(), args.query, args.columns, args.attach, args.comment); }); } }