#include /// For calculations related to sampling coefficients. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace ProfileEvents { extern const Event SelectedParts; extern const Event SelectedRanges; extern const Event SelectedMarks; } namespace DB { namespace ErrorCodes { extern const int LOGICAL_ERROR; extern const int INDEX_NOT_USED; extern const int ILLEGAL_TYPE_OF_COLUMN_FOR_FILTER; extern const int ILLEGAL_COLUMN; extern const int ARGUMENT_OUT_OF_BOUND; extern const int TOO_MANY_ROWS; extern const int CANNOT_PARSE_TEXT; extern const int TOO_MANY_PARTITIONS; extern const int DUPLICATED_PART_UUIDS; extern const int NO_SUCH_COLUMN_IN_TABLE; extern const int PROJECTION_NOT_USED; } MergeTreeDataSelectExecutor::MergeTreeDataSelectExecutor(const MergeTreeData & data_) : data(data_), log(&Poco::Logger::get(data.getLogName() + " (SelectExecutor)")) { } size_t MergeTreeDataSelectExecutor::getApproximateTotalRowsToRead( const MergeTreeData::DataPartsVector & parts, const StorageMetadataPtr & metadata_snapshot, const KeyCondition & key_condition, const Settings & settings, Poco::Logger * log) { size_t rows_count = 0; /// We will find out how many rows we would have read without sampling. LOG_DEBUG(log, "Preliminary index scan with condition: {}", key_condition.toString()); for (const auto & part : parts) { MarkRanges ranges = markRangesFromPKRange(part, metadata_snapshot, key_condition, settings, log); /** In order to get a lower bound on the number of rows that match the condition on PK, * consider only guaranteed full marks. * That is, do not take into account the first and last marks, which may be incomplete. */ for (const auto & range : ranges) if (range.end - range.begin > 2) rows_count += part->index_granularity.getRowsCountInRange({range.begin + 1, range.end - 1}); } return rows_count; } using RelativeSize = boost::rational; static std::string toString(const RelativeSize & x) { return ASTSampleRatio::toString(x.numerator()) + "/" + ASTSampleRatio::toString(x.denominator()); } /// Converts sample size to an approximate number of rows (ex. `SAMPLE 1000000`) to relative value (ex. `SAMPLE 0.1`). static RelativeSize convertAbsoluteSampleSizeToRelative(const ASTPtr & node, size_t approx_total_rows) { if (approx_total_rows == 0) return 1; const auto & node_sample = node->as(); auto absolute_sample_size = node_sample.ratio.numerator / node_sample.ratio.denominator; return std::min(RelativeSize(1), RelativeSize(absolute_sample_size) / RelativeSize(approx_total_rows)); } QueryPlanPtr MergeTreeDataSelectExecutor::read( const Names & column_names_to_return, const StorageMetadataPtr & metadata_snapshot, const SelectQueryInfo & query_info, ContextPtr context, const UInt64 max_block_size, const unsigned num_streams, QueryProcessingStage::Enum processed_stage, std::shared_ptr max_block_numbers_to_read) const { const auto & settings = context->getSettingsRef(); auto parts = data.getDataPartsVector(); if (!query_info.projection) { if (settings.allow_experimental_projection_optimization && settings.force_optimize_projection && !metadata_snapshot->projections.empty()) throw Exception("No projection is used when allow_experimental_projection_optimization = 1", ErrorCodes::PROJECTION_NOT_USED); return readFromParts( parts, column_names_to_return, metadata_snapshot, metadata_snapshot, query_info, context, max_block_size, num_streams, max_block_numbers_to_read); } LOG_DEBUG( log, "Choose {} projection {}", ProjectionDescription::typeToString(query_info.projection->desc->type), query_info.projection->desc->name); // if (query_info.projection->merge_tree_data_select_base_cache->sum_marks // + query_info.projection->merge_tree_data_select_projection_cache->sum_marks // == 0) // return std::make_unique(); MergeTreeData::DataPartsVector projection_parts; MergeTreeData::DataPartsVector normal_parts; for (const auto & part : parts) { const auto & projections = part->getProjectionParts(); auto it = projections.find(query_info.projection->desc->name); if (it != projections.end()) projection_parts.push_back(it->second); else normal_parts.push_back(part); } Pipes pipes; Pipe projection_pipe; Pipe ordinary_pipe; const auto & given_select = query_info.query->as(); if (!projection_parts.empty()) { LOG_DEBUG(log, "projection required columns: {}", fmt::join(query_info.projection->required_columns, ", ")); auto plan = readFromParts( projection_parts, query_info.projection->required_columns, metadata_snapshot, query_info.projection->desc->metadata, query_info, context, max_block_size, num_streams, max_block_numbers_to_read); if (plan) { // If `before_where` is not empty, transform input blocks by adding needed columns // originated from key columns. We already project the block at the end, using // projection_block, so we can just add more columns here without worrying // NOTE: prewhere is executed inside readFromParts if (query_info.projection->before_where) { // std::cerr << fmt::format("projection before_where: {}", query_info.projection->before_where->dumpDAG()); auto where_step = std::make_unique( plan->getCurrentDataStream(), query_info.projection->before_where, query_info.projection->where_column_name, query_info.projection->remove_where_filter); where_step->setStepDescription("WHERE"); plan->addStep(std::move(where_step)); } if (query_info.projection->before_aggregation) { // std::cerr << fmt::format("projection before_aggregation: {}", query_info.projection->before_aggregation->dumpDAG()); auto expression_before_aggregation = std::make_unique(plan->getCurrentDataStream(), query_info.projection->before_aggregation); expression_before_aggregation->setStepDescription("Before GROUP BY"); plan->addStep(std::move(expression_before_aggregation)); } projection_pipe = plan->convertToPipe( QueryPlanOptimizationSettings::fromContext(context), BuildQueryPipelineSettings::fromContext(context)); } } if (!normal_parts.empty()) { auto storage_from_base_parts_of_projection = StorageFromMergeTreeDataPart::create(std::move(normal_parts)); auto ast = query_info.projection->desc->query_ast->clone(); auto & select = ast->as(); if (given_select.where()) select.setExpression(ASTSelectQuery::Expression::WHERE, given_select.where()->clone()); if (given_select.prewhere()) select.setExpression(ASTSelectQuery::Expression::WHERE, given_select.prewhere()->clone()); // TODO will row policy filter work? // After overriding the group by clause, we finish the possible aggregations directly if (processed_stage >= QueryProcessingStage::Enum::WithMergeableState && given_select.groupBy()) select.setExpression(ASTSelectQuery::Expression::GROUP_BY, given_select.groupBy()->clone()); auto interpreter = InterpreterSelectQuery( ast, context, storage_from_base_parts_of_projection, nullptr, SelectQueryOptions{processed_stage}.ignoreAggregation().ignoreProjections()); ordinary_pipe = QueryPipeline::getPipe(interpreter.execute().pipeline); } if (query_info.projection->desc->type == ProjectionDescription::Type::Aggregate) { /// Here we create shared ManyAggregatedData for both projection and ordinary data. /// For ordinary data, AggregatedData is filled in a usual way. /// For projection data, AggregatedData is filled by merging aggregation states. /// When all AggregatedData is filled, we merge aggregation states together in a usual way. /// Pipeline will look like: /// ReadFromProjection -> Aggregating (only merge states) -> /// ReadFromProjection -> Aggregating (only merge states) -> /// ... -> Resize -> ConvertingAggregatedToChunks /// ReadFromOrdinaryPart -> Aggregating (usual) -> (added by last Aggregating) /// ReadFromOrdinaryPart -> Aggregating (usual) -> /// ... auto many_data = std::make_shared(projection_pipe.numOutputPorts() + ordinary_pipe.numOutputPorts()); size_t counter = 0; // TODO apply in_order_optimization here auto build_aggregate_pipe = [&](Pipe & pipe, bool projection) { const auto & header_before_aggregation = pipe.getHeader(); // std::cerr << "============ header before aggregation" << std::endl; // std::cerr << header_before_aggregation.dumpStructure() << std::endl; ColumnNumbers keys; for (const auto & key : query_info.projection->aggregation_keys) keys.push_back(header_before_aggregation.getPositionByName(key.name)); AggregateDescriptions aggregates = query_info.projection->aggregate_descriptions; if (!projection) { for (auto & descr : aggregates) if (descr.arguments.empty()) for (const auto & name : descr.argument_names) descr.arguments.push_back(header_before_aggregation.getPositionByName(name)); } AggregatingTransformParamsPtr transform_params; if (projection) { Aggregator::Params params( header_before_aggregation, keys, aggregates, query_info.projection->aggregate_overflow_row, settings.max_rows_to_group_by, settings.group_by_overflow_mode, settings.group_by_two_level_threshold, settings.group_by_two_level_threshold_bytes, settings.max_bytes_before_external_group_by, settings.empty_result_for_aggregation_by_empty_set, context->getTemporaryVolume(), settings.max_threads, settings.min_free_disk_space_for_temporary_data, header_before_aggregation); // The source header is also an intermediate header transform_params = std::make_shared(std::move(params), query_info.projection->aggregate_final); /// This part is hacky. /// We want AggregatingTransform to work with aggregate states instead of normal columns. /// It is almost the same, just instead of adding new data to aggregation state we merge it with existing. /// /// It is needed because data in projection: /// * is not merged completely (we may have states with the same key in different parts) /// * is not split into buckets (so if we just use MergingAggregated, it will use single thread) transform_params->only_merge = true; } else { Aggregator::Params params( header_before_aggregation, keys, aggregates, query_info.projection->aggregate_overflow_row, settings.max_rows_to_group_by, settings.group_by_overflow_mode, settings.group_by_two_level_threshold, settings.group_by_two_level_threshold_bytes, settings.max_bytes_before_external_group_by, settings.empty_result_for_aggregation_by_empty_set, context->getTemporaryVolume(), settings.max_threads, settings.min_free_disk_space_for_temporary_data); transform_params = std::make_shared(std::move(params), query_info.projection->aggregate_final); } pipe.resize(pipe.numOutputPorts(), true, true); auto merge_threads = num_streams; auto temporary_data_merge_threads = settings.aggregation_memory_efficient_merge_threads ? static_cast(settings.aggregation_memory_efficient_merge_threads) : static_cast(settings.max_threads); pipe.addSimpleTransform([&](const Block & header) { return std::make_shared( header, transform_params, many_data, counter++, merge_threads, temporary_data_merge_threads); }); // std::cerr << "============ header after aggregation" << std::endl; // std::cerr << pipe.getHeader().dumpStructure() << std::endl; }; if (!projection_pipe.empty()) build_aggregate_pipe(projection_pipe, true); if (!ordinary_pipe.empty()) build_aggregate_pipe(ordinary_pipe, false); } pipes.emplace_back(std::move(projection_pipe)); pipes.emplace_back(std::move(ordinary_pipe)); auto pipe = Pipe::unitePipes(std::move(pipes)); // TODO what if pipe is empty? pipe.resize(1); auto step = std::make_unique(std::move(pipe), "MergeTree(with projection)"); auto plan = std::make_unique(); plan->addStep(std::move(step)); return plan; } MergeTreeDataSelectSamplingData MergeTreeDataSelectExecutor::getSampling( const ASTSelectQuery & select, MergeTreeData::DataPartsVector & parts, const StorageMetadataPtr & metadata_snapshot, KeyCondition & key_condition, const MergeTreeData & data, Poco::Logger * log, bool sample_factor_column_queried, NamesAndTypesList available_real_columns, ContextPtr context) { const Settings & settings = context->getSettingsRef(); /// Sampling. MergeTreeDataSelectSamplingData sampling; RelativeSize relative_sample_size = 0; RelativeSize relative_sample_offset = 0; auto select_sample_size = select.sampleSize(); auto select_sample_offset = select.sampleOffset(); if (select_sample_size) { relative_sample_size.assign( select_sample_size->as().ratio.numerator, select_sample_size->as().ratio.denominator); if (relative_sample_size < 0) throw Exception("Negative sample size", ErrorCodes::ARGUMENT_OUT_OF_BOUND); relative_sample_offset = 0; if (select_sample_offset) relative_sample_offset.assign( select_sample_offset->as().ratio.numerator, select_sample_offset->as().ratio.denominator); if (relative_sample_offset < 0) throw Exception("Negative sample offset", ErrorCodes::ARGUMENT_OUT_OF_BOUND); /// Convert absolute value of the sampling (in form `SAMPLE 1000000` - how many rows to /// read) into the relative `SAMPLE 0.1` (how much data to read). size_t approx_total_rows = 0; if (relative_sample_size > 1 || relative_sample_offset > 1) approx_total_rows = getApproximateTotalRowsToRead(parts, metadata_snapshot, key_condition, settings, log); if (relative_sample_size > 1) { relative_sample_size = convertAbsoluteSampleSizeToRelative(select_sample_size, approx_total_rows); LOG_DEBUG(log, "Selected relative sample size: {}", toString(relative_sample_size)); } /// SAMPLE 1 is the same as the absence of SAMPLE. if (relative_sample_size == RelativeSize(1)) relative_sample_size = 0; if (relative_sample_offset > 0 && RelativeSize(0) == relative_sample_size) throw Exception("Sampling offset is incorrect because no sampling", ErrorCodes::ARGUMENT_OUT_OF_BOUND); if (relative_sample_offset > 1) { relative_sample_offset = convertAbsoluteSampleSizeToRelative(select_sample_offset, approx_total_rows); LOG_DEBUG(log, "Selected relative sample offset: {}", toString(relative_sample_offset)); } } /** Which range of sampling key values do I need to read? * First, in the whole range ("universe") we select the interval * of relative `relative_sample_size` size, offset from the beginning by `relative_sample_offset`. * * Example: SAMPLE 0.4 OFFSET 0.3 * * [------********------] * ^ - offset * <------> - size * * If the interval passes through the end of the universe, then cut its right side. * * Example: SAMPLE 0.4 OFFSET 0.8 * * [----------------****] * ^ - offset * <------> - size * * Next, if the `parallel_replicas_count`, `parallel_replica_offset` settings are set, * then it is necessary to break the received interval into pieces of the number `parallel_replicas_count`, * and select a piece with the number `parallel_replica_offset` (from zero). * * Example: SAMPLE 0.4 OFFSET 0.3, parallel_replicas_count = 2, parallel_replica_offset = 1 * * [----------****------] * ^ - offset * <------> - size * <--><--> - pieces for different `parallel_replica_offset`, select the second one. * * It is very important that the intervals for different `parallel_replica_offset` cover the entire range without gaps and overlaps. * It is also important that the entire universe can be covered using SAMPLE 0.1 OFFSET 0, ... OFFSET 0.9 and similar decimals. */ /// Parallel replicas has been requested but there is no way to sample data. /// Select all data from first replica and no data from other replicas. if (settings.parallel_replicas_count > 1 && !data.supportsSampling() && settings.parallel_replica_offset > 0) { LOG_DEBUG(log, "Will use no data on this replica because parallel replicas processing has been requested" " (the setting 'max_parallel_replicas') but the table does not support sampling and this replica is not the first."); sampling.read_nothing = true; return sampling; } sampling.use_sampling = relative_sample_size > 0 || (settings.parallel_replicas_count > 1 && data.supportsSampling()); bool no_data = false; /// There is nothing left after sampling. if (sampling.use_sampling) { if (sample_factor_column_queried && relative_sample_size != RelativeSize(0)) sampling.used_sample_factor = 1.0 / boost::rational_cast(relative_sample_size); RelativeSize size_of_universum = 0; const auto & sampling_key = metadata_snapshot->getSamplingKey(); DataTypePtr sampling_column_type = sampling_key.data_types[0]; if (sampling_key.data_types.size() == 1) { if (typeid_cast(sampling_column_type.get())) size_of_universum = RelativeSize(std::numeric_limits::max()) + RelativeSize(1); else if (typeid_cast(sampling_column_type.get())) size_of_universum = RelativeSize(std::numeric_limits::max()) + RelativeSize(1); else if (typeid_cast(sampling_column_type.get())) size_of_universum = RelativeSize(std::numeric_limits::max()) + RelativeSize(1); else if (typeid_cast(sampling_column_type.get())) size_of_universum = RelativeSize(std::numeric_limits::max()) + RelativeSize(1); } if (size_of_universum == RelativeSize(0)) throw Exception( "Invalid sampling column type in storage parameters: " + sampling_column_type->getName() + ". Must be one unsigned integer type", ErrorCodes::ILLEGAL_TYPE_OF_COLUMN_FOR_FILTER); if (settings.parallel_replicas_count > 1) { if (relative_sample_size == RelativeSize(0)) relative_sample_size = 1; relative_sample_size /= settings.parallel_replicas_count.value; relative_sample_offset += relative_sample_size * RelativeSize(settings.parallel_replica_offset.value); } if (relative_sample_offset >= RelativeSize(1)) no_data = true; /// Calculate the half-interval of `[lower, upper)` column values. bool has_lower_limit = false; bool has_upper_limit = false; RelativeSize lower_limit_rational = relative_sample_offset * size_of_universum; RelativeSize upper_limit_rational = (relative_sample_offset + relative_sample_size) * size_of_universum; UInt64 lower = boost::rational_cast(lower_limit_rational); UInt64 upper = boost::rational_cast(upper_limit_rational); if (lower > 0) has_lower_limit = true; if (upper_limit_rational < size_of_universum) has_upper_limit = true; /*std::cerr << std::fixed << std::setprecision(100) << "relative_sample_size: " << relative_sample_size << "\n" << "relative_sample_offset: " << relative_sample_offset << "\n" << "lower_limit_float: " << lower_limit_rational << "\n" << "upper_limit_float: " << upper_limit_rational << "\n" << "lower: " << lower << "\n" << "upper: " << upper << "\n";*/ if ((has_upper_limit && upper == 0) || (has_lower_limit && has_upper_limit && lower == upper)) no_data = true; if (no_data || (!has_lower_limit && !has_upper_limit)) { sampling.use_sampling = false; } else { /// Let's add the conditions to cut off something else when the index is scanned again and when the request is processed. std::shared_ptr lower_function; std::shared_ptr upper_function; /// If sample and final are used together no need to calculate sampling expression twice. /// The first time it was calculated for final, because sample key is a part of the PK. /// So, assume that we already have calculated column. ASTPtr sampling_key_ast = metadata_snapshot->getSamplingKeyAST(); if (select.final()) { sampling_key_ast = std::make_shared(sampling_key.column_names[0]); /// We do spoil available_real_columns here, but it is not used later. available_real_columns.emplace_back(sampling_key.column_names[0], std::move(sampling_column_type)); } if (has_lower_limit) { if (!key_condition.addCondition(sampling_key.column_names[0], Range::createLeftBounded(lower, true))) throw Exception("Sampling column not in primary key", ErrorCodes::ILLEGAL_COLUMN); ASTPtr args = std::make_shared(); args->children.push_back(sampling_key_ast); args->children.push_back(std::make_shared(lower)); lower_function = std::make_shared(); lower_function->name = "greaterOrEquals"; lower_function->arguments = args; lower_function->children.push_back(lower_function->arguments); sampling.filter_function = lower_function; } if (has_upper_limit) { if (!key_condition.addCondition(sampling_key.column_names[0], Range::createRightBounded(upper, false))) throw Exception("Sampling column not in primary key", ErrorCodes::ILLEGAL_COLUMN); ASTPtr args = std::make_shared(); args->children.push_back(sampling_key_ast); args->children.push_back(std::make_shared(upper)); upper_function = std::make_shared(); upper_function->name = "less"; upper_function->arguments = args; upper_function->children.push_back(upper_function->arguments); sampling.filter_function = upper_function; } if (has_lower_limit && has_upper_limit) { ASTPtr args = std::make_shared(); args->children.push_back(lower_function); args->children.push_back(upper_function); sampling.filter_function = std::make_shared(); sampling.filter_function->name = "and"; sampling.filter_function->arguments = args; sampling.filter_function->children.push_back(sampling.filter_function->arguments); } ASTPtr query = sampling.filter_function; auto syntax_result = TreeRewriter(context).analyze(query, available_real_columns); sampling.filter_expression = ExpressionAnalyzer(sampling.filter_function, syntax_result, context).getActionsDAG(false); } } if (no_data) { LOG_DEBUG(log, "Sampling yields no data."); sampling.read_nothing = true; } return sampling; } std::optional> MergeTreeDataSelectExecutor::filterPartsByVirtualColumns( const MergeTreeData & data, MergeTreeData::DataPartsVector & parts, const ASTPtr & query, ContextPtr context) { std::unordered_set part_values; ASTPtr expression_ast; auto virtual_columns_block = data.getBlockWithVirtualPartColumns(parts, true /* one_part */); // Generate valid expressions for filtering VirtualColumnUtils::prepareFilterBlockWithQuery(query, context, virtual_columns_block, expression_ast); // If there is still something left, fill the virtual block and do the filtering. if (expression_ast) { virtual_columns_block = data.getBlockWithVirtualPartColumns(parts, false /* one_part */); VirtualColumnUtils::filterBlockWithQuery(query, virtual_columns_block, context, expression_ast); return VirtualColumnUtils::extractSingleValueFromBlock(virtual_columns_block, "_part"); } return {}; } void MergeTreeDataSelectExecutor::filterPartsByPartition( const StorageMetadataPtr & metadata_snapshot, const MergeTreeData & data, const SelectQueryInfo & query_info, const ContextPtr & context, const ContextPtr & query_context, MergeTreeData::DataPartsVector & parts, const std::optional> & part_values, const PartitionIdToMaxBlock * max_block_numbers_to_read, Poco::Logger * log, ReadFromMergeTree::IndexStats & index_stats) { const Settings & settings = context->getSettingsRef(); std::optional partition_pruner; std::optional minmax_idx_condition; DataTypes minmax_columns_types; if (metadata_snapshot->hasPartitionKey()) { const auto & partition_key = metadata_snapshot->getPartitionKey(); auto minmax_columns_names = data.getMinMaxColumnsNames(partition_key); minmax_columns_types = data.getMinMaxColumnsTypes(partition_key); minmax_idx_condition.emplace( query_info, context, minmax_columns_names, data.getMinMaxExpr(partition_key, ExpressionActionsSettings::fromContext(context))); partition_pruner.emplace(metadata_snapshot, query_info, context, false /* strict */); if (settings.force_index_by_date && (minmax_idx_condition->alwaysUnknownOrTrue() && partition_pruner->isUseless())) { String msg = "Neither MinMax index by columns ("; bool first = true; for (const String & col : minmax_columns_names) { if (first) first = false; else msg += ", "; msg += col; } msg += ") nor partition expr is used and setting 'force_index_by_date' is set"; throw Exception(msg, ErrorCodes::INDEX_NOT_USED); } } PartFilterCounters part_filter_counters; if (query_context->getSettingsRef().allow_experimental_query_deduplication) selectPartsToReadWithUUIDFilter( parts, part_values, data.getPinnedPartUUIDs(), minmax_idx_condition, minmax_columns_types, partition_pruner, max_block_numbers_to_read, query_context, part_filter_counters, log); else selectPartsToRead( parts, part_values, minmax_idx_condition, minmax_columns_types, partition_pruner, max_block_numbers_to_read, part_filter_counters); index_stats.emplace_back(ReadFromMergeTree::IndexStat{ .type = ReadFromMergeTree::IndexType::None, .num_parts_after = part_filter_counters.num_initial_selected_parts, .num_granules_after = part_filter_counters.num_initial_selected_granules}); if (minmax_idx_condition) { auto description = minmax_idx_condition->getDescription(); index_stats.emplace_back(ReadFromMergeTree::IndexStat{ .type = ReadFromMergeTree::IndexType::MinMax, .condition = std::move(description.condition), .used_keys = std::move(description.used_keys), .num_parts_after = part_filter_counters.num_parts_after_minmax, .num_granules_after = part_filter_counters.num_granules_after_minmax}); LOG_DEBUG(log, "MinMax index condition: {}", minmax_idx_condition->toString()); } if (partition_pruner) { auto description = partition_pruner->getKeyCondition().getDescription(); index_stats.emplace_back(ReadFromMergeTree::IndexStat{ .type = ReadFromMergeTree::IndexType::Partition, .condition = std::move(description.condition), .used_keys = std::move(description.used_keys), .num_parts_after = part_filter_counters.num_parts_after_partition_pruner, .num_granules_after = part_filter_counters.num_granules_after_partition_pruner}); } } RangesInDataParts MergeTreeDataSelectExecutor::filterPartsByPrimaryKeyAndSkipIndexes( MergeTreeData::DataPartsVector && parts, StorageMetadataPtr metadata_snapshot, const SelectQueryInfo & query_info, const ContextPtr & context, KeyCondition & key_condition, const MergeTreeReaderSettings & reader_settings, Poco::Logger * log, size_t num_streams, ReadFromMergeTree::IndexStats & index_stats, bool use_skip_indexes) { RangesInDataParts parts_with_ranges(parts.size()); const Settings & settings = context->getSettingsRef(); /// Let's start analyzing all useful indices struct DataSkippingIndexAndCondition { MergeTreeIndexPtr index; MergeTreeIndexConditionPtr condition; std::atomic total_granules{0}; std::atomic granules_dropped{0}; std::atomic total_parts{0}; std::atomic parts_dropped{0}; DataSkippingIndexAndCondition(MergeTreeIndexPtr index_, MergeTreeIndexConditionPtr condition_) : index(index_), condition(condition_) { } }; std::list useful_indices; if (use_skip_indexes) { for (const auto & index : metadata_snapshot->getSecondaryIndices()) { auto index_helper = MergeTreeIndexFactory::instance().get(index); auto condition = index_helper->createIndexCondition(query_info, context); if (!condition->alwaysUnknownOrTrue()) useful_indices.emplace_back(index_helper, condition); } } if (use_skip_indexes && settings.force_data_skipping_indices.changed) { const auto & indices = settings.force_data_skipping_indices.toString(); Strings forced_indices; { Tokens tokens(&indices[0], &indices[indices.size()], settings.max_query_size); IParser::Pos pos(tokens, settings.max_parser_depth); Expected expected; if (!parseIdentifiersOrStringLiterals(pos, expected, forced_indices)) throw Exception(ErrorCodes::CANNOT_PARSE_TEXT, "Cannot parse force_data_skipping_indices ('{}')", indices); } if (forced_indices.empty()) throw Exception(ErrorCodes::CANNOT_PARSE_TEXT, "No indices parsed from force_data_skipping_indices ('{}')", indices); std::unordered_set useful_indices_names; for (const auto & useful_index : useful_indices) useful_indices_names.insert(useful_index.index->index.name); for (const auto & index_name : forced_indices) { if (!useful_indices_names.count(index_name)) { throw Exception( ErrorCodes::INDEX_NOT_USED, "Index {} is not used and setting 'force_data_skipping_indices' contains it", backQuote(index_name)); } } } std::atomic sum_marks_pk = 0; std::atomic sum_parts_pk = 0; /// Let's find what range to read from each part. { std::atomic total_rows{0}; SizeLimits limits; if (settings.read_overflow_mode == OverflowMode::THROW && settings.max_rows_to_read) limits = SizeLimits(settings.max_rows_to_read, 0, settings.read_overflow_mode); SizeLimits leaf_limits; if (settings.read_overflow_mode_leaf == OverflowMode::THROW && settings.max_rows_to_read_leaf) leaf_limits = SizeLimits(settings.max_rows_to_read_leaf, 0, settings.read_overflow_mode_leaf); auto process_part = [&](size_t part_index) { auto & part = parts[part_index]; RangesInDataPart ranges(part, part_index); size_t total_marks_count = part->index_granularity.getMarksCountWithoutFinal(); if (metadata_snapshot->hasPrimaryKey()) ranges.ranges = markRangesFromPKRange(part, metadata_snapshot, key_condition, settings, log); else if (total_marks_count) ranges.ranges = MarkRanges{MarkRange{0, total_marks_count}}; sum_marks_pk.fetch_add(ranges.getMarksCount(), std::memory_order_relaxed); if (!ranges.ranges.empty()) sum_parts_pk.fetch_add(1, std::memory_order_relaxed); for (auto & index_and_condition : useful_indices) { if (ranges.ranges.empty()) break; index_and_condition.total_parts.fetch_add(1, std::memory_order_relaxed); size_t total_granules = 0; size_t granules_dropped = 0; ranges.ranges = filterMarksUsingIndex( index_and_condition.index, index_and_condition.condition, part, ranges.ranges, settings, reader_settings, total_granules, granules_dropped, log); index_and_condition.total_granules.fetch_add(total_granules, std::memory_order_relaxed); index_and_condition.granules_dropped.fetch_add(granules_dropped, std::memory_order_relaxed); if (ranges.ranges.empty()) index_and_condition.parts_dropped.fetch_add(1, std::memory_order_relaxed); } if (!ranges.ranges.empty()) { if (limits.max_rows || leaf_limits.max_rows) { /// Fail fast if estimated number of rows to read exceeds the limit auto current_rows_estimate = ranges.getRowsCount(); size_t prev_total_rows_estimate = total_rows.fetch_add(current_rows_estimate); size_t total_rows_estimate = current_rows_estimate + prev_total_rows_estimate; limits.check(total_rows_estimate, 0, "rows (controlled by 'max_rows_to_read' setting)", ErrorCodes::TOO_MANY_ROWS); leaf_limits.check( total_rows_estimate, 0, "rows (controlled by 'max_rows_to_read_leaf' setting)", ErrorCodes::TOO_MANY_ROWS); } parts_with_ranges[part_index] = std::move(ranges); } }; size_t num_threads = std::min(size_t(num_streams), parts.size()); if (num_threads <= 1) { for (size_t part_index = 0; part_index < parts.size(); ++part_index) process_part(part_index); } else { /// Parallel loading of data parts. ThreadPool pool(num_threads); for (size_t part_index = 0; part_index < parts.size(); ++part_index) pool.scheduleOrThrowOnError([&, part_index, thread_group = CurrentThread::getGroup()] { SCOPE_EXIT_SAFE(if (thread_group) CurrentThread::detachQueryIfNotDetached();); if (thread_group) CurrentThread::attachTo(thread_group); process_part(part_index); }); pool.wait(); } /// Skip empty ranges. size_t next_part = 0; for (size_t part_index = 0; part_index < parts.size(); ++part_index) { auto & part = parts_with_ranges[part_index]; if (!part.data_part) continue; if (next_part != part_index) std::swap(parts_with_ranges[next_part], part); ++next_part; } parts_with_ranges.resize(next_part); } if (metadata_snapshot->hasPrimaryKey()) { auto description = key_condition.getDescription(); index_stats.emplace_back(ReadFromMergeTree::IndexStat{ .type = ReadFromMergeTree::IndexType::PrimaryKey, .condition = std::move(description.condition), .used_keys = std::move(description.used_keys), .num_parts_after = sum_parts_pk.load(std::memory_order_relaxed), .num_granules_after = sum_marks_pk.load(std::memory_order_relaxed)}); } for (const auto & index_and_condition : useful_indices) { const auto & index_name = index_and_condition.index->index.name; LOG_DEBUG( log, "Index {} has dropped {}/{} granules.", backQuote(index_name), index_and_condition.granules_dropped, index_and_condition.total_granules); std::string description = index_and_condition.index->index.type + " GRANULARITY " + std::to_string(index_and_condition.index->index.granularity); index_stats.emplace_back(ReadFromMergeTree::IndexStat{ .type = ReadFromMergeTree::IndexType::Skip, .name = index_name, .description = std::move(description), .num_parts_after = index_and_condition.total_parts - index_and_condition.parts_dropped, .num_granules_after = index_and_condition.total_granules - index_and_condition.granules_dropped}); } return parts_with_ranges; } String MergeTreeDataSelectExecutor::checkLimits( const MergeTreeData & data, const RangesInDataParts & parts_with_ranges, const ContextPtr & context) { const auto & settings = context->getSettingsRef(); // Check limitations. query_id is used as the quota RAII's resource key. String query_id; { const auto data_settings = data.getSettings(); auto max_partitions_to_read = settings.max_partitions_to_read.changed ? settings.max_partitions_to_read : data_settings->max_partitions_to_read; if (max_partitions_to_read > 0) { std::set partitions; for (const auto & part_with_ranges : parts_with_ranges) partitions.insert(part_with_ranges.data_part->info.partition_id); if (partitions.size() > size_t(max_partitions_to_read)) throw Exception( ErrorCodes::TOO_MANY_PARTITIONS, "Too many partitions to read. Current {}, max {}", partitions.size(), max_partitions_to_read); } if (data_settings->max_concurrent_queries > 0 && data_settings->min_marks_to_honor_max_concurrent_queries > 0) { size_t sum_marks = 0; for (const auto & part : parts_with_ranges) sum_marks += part.getMarksCount(); if (sum_marks >= data_settings->min_marks_to_honor_max_concurrent_queries) { query_id = context->getCurrentQueryId(); if (!query_id.empty()) data.insertQueryIdOrThrow(query_id, data_settings->max_concurrent_queries); } } } return query_id; } static void selectColumnNames( const Names & column_names_to_return, const MergeTreeData & data, Names & real_column_names, Names & virt_column_names, bool & sample_factor_column_queried) { sample_factor_column_queried = false; for (const String & name : column_names_to_return) { if (name == "_part") { virt_column_names.push_back(name); } else if (name == "_part_index") { virt_column_names.push_back(name); } else if (name == "_partition_id") { virt_column_names.push_back(name); } else if (name == "_part_uuid") { virt_column_names.push_back(name); } else if (name == "_partition_value") { if (!typeid_cast(data.getPartitionValueType().get())) { throw Exception( ErrorCodes::NO_SUCH_COLUMN_IN_TABLE, "Missing column `_partition_value` because there is no partition column in table {}", data.getStorageID().getTableName()); } virt_column_names.push_back(name); } else if (name == "_sample_factor") { sample_factor_column_queried = true; virt_column_names.push_back(name); } else { real_column_names.push_back(name); } } } size_t MergeTreeDataSelectExecutor::estimateNumMarksToRead( MergeTreeData::DataPartsVector parts, const Names & column_names_to_return, const StorageMetadataPtr & metadata_snapshot_base, const StorageMetadataPtr & metadata_snapshot, const SelectQueryInfo & query_info, ContextPtr context, unsigned num_streams, std::shared_ptr max_block_numbers_to_read) const { size_t total_parts = parts.size(); if (total_parts == 0) return 0; Names real_column_names; Names virt_column_names; /// If query contains restrictions on the virtual column `_part` or `_part_index`, select only parts suitable for it. /// The virtual column `_sample_factor` (which is equal to 1 / used sample rate) can be requested in the query. bool sample_factor_column_queried = false; selectColumnNames(column_names_to_return, data, real_column_names, virt_column_names, sample_factor_column_queried); auto part_values = filterPartsByVirtualColumns(data, parts, query_info.query, context); if (part_values && part_values->empty()) return 0; /// If there are only virtual columns in the query, you must request at least one non-virtual one. if (real_column_names.empty()) { NamesAndTypesList available_real_columns = metadata_snapshot->getColumns().getAllPhysical(); real_column_names.push_back(ExpressionActions::getSmallestColumn(available_real_columns)); } metadata_snapshot->check(real_column_names, data.getVirtuals(), data.getStorageID()); const auto & primary_key = metadata_snapshot->getPrimaryKey(); Names primary_key_columns = primary_key.column_names; KeyCondition key_condition(query_info, context, primary_key_columns, primary_key.expression); if (key_condition.alwaysUnknownOrTrue()) { size_t total_marks = 0; for (const auto & part : parts) total_marks += part->index_granularity.getMarksCountWithoutFinal(); return total_marks; } const auto & select = query_info.query->as(); auto query_context = context->hasQueryContext() ? context->getQueryContext() : context; ReadFromMergeTree::IndexStats index_stats; filterPartsByPartition( metadata_snapshot_base, data, query_info, context, query_context, parts, part_values, max_block_numbers_to_read.get(), log, index_stats); auto sampling = MergeTreeDataSelectExecutor::getSampling( select, parts, metadata_snapshot, key_condition, data, log, sample_factor_column_queried, metadata_snapshot->getColumns().getAllPhysical(), context); if (sampling.read_nothing) return 0; /// Do not init. Ther are not used (cause skip index is ignored) MergeTreeReaderSettings reader_settings; auto parts_with_ranges = filterPartsByPrimaryKeyAndSkipIndexes( std::move(parts), metadata_snapshot, query_info, context, key_condition, reader_settings, log, num_streams, index_stats, false); return index_stats.back().num_granules_after; } QueryPlanPtr MergeTreeDataSelectExecutor::readFromParts( MergeTreeData::DataPartsVector parts, const Names & column_names_to_return, const StorageMetadataPtr & metadata_snapshot_base, const StorageMetadataPtr & metadata_snapshot, const SelectQueryInfo & query_info, ContextPtr context, const UInt64 max_block_size, const unsigned num_streams, std::shared_ptr max_block_numbers_to_read) const { size_t total_parts = parts.size(); if (total_parts == 0) return std::make_unique(); Names real_column_names; Names virt_column_names; /// If query contains restrictions on the virtual column `_part` or `_part_index`, select only parts suitable for it. /// The virtual column `_sample_factor` (which is equal to 1 / used sample rate) can be requested in the query. bool sample_factor_column_queried = false; selectColumnNames(column_names_to_return, data, real_column_names, virt_column_names, sample_factor_column_queried); const auto & settings = context->getSettingsRef(); MergeTreeReaderSettings reader_settings = { .min_bytes_to_use_direct_io = settings.min_bytes_to_use_direct_io, .min_bytes_to_use_mmap_io = settings.min_bytes_to_use_mmap_io, .mmap_cache = context->getMMappedFileCache(), .max_read_buffer_size = settings.max_read_buffer_size, .save_marks_in_cache = true, .checksum_on_read = settings.checksum_on_read, }; ReadFromMergeTree::Settings step_settings { .max_block_size = max_block_size, .num_streams = num_streams, .preferred_block_size_bytes = settings.preferred_block_size_bytes, .preferred_max_column_in_block_size_bytes = settings.preferred_max_column_in_block_size_bytes, .use_uncompressed_cache = settings.use_uncompressed_cache, .force_primary_key = settings.force_primary_key, .sample_factor_column_queried = sample_factor_column_queried, .reader_settings = reader_settings, .backoff_settings = MergeTreeReadPool::BackoffSettings(settings), }; auto read_from_merge_tree = std::make_unique( query_info, max_block_numbers_to_read, context, data, metadata_snapshot, metadata_snapshot_base, real_column_names, parts, query_info.projection ? query_info.projection->prewhere_info : query_info.prewhere_info, virt_column_names, step_settings, log ); QueryPlanPtr plan = std::make_unique(); plan->addStep(std::move(read_from_merge_tree)); return plan; } namespace { /// Marks are placed whenever threshold on rows or bytes is met. /// So we have to return the number of marks on whatever estimate is higher - by rows or by bytes. size_t roundRowsOrBytesToMarks( size_t rows_setting, size_t bytes_setting, size_t rows_granularity, size_t bytes_granularity) { size_t res = (rows_setting + rows_granularity - 1) / rows_granularity; if (bytes_granularity == 0) return res; else return std::max(res, (bytes_setting + bytes_granularity - 1) / bytes_granularity); } } // QueryPlanPtr MergeTreeDataSelectExecutor::spreadMarkRangesAmongStreams( // RangesInDataParts && parts, // // ReadFromMergeTree::IndexStatPtr index_stats, // size_t num_streams, // const Names & column_names, // const StorageMetadataPtr & metadata_snapshot, // UInt64 max_block_size, // bool use_uncompressed_cache, // const SelectQueryInfo & query_info, // const Names & virt_columns, // const Settings & settings, // const MergeTreeReaderSettings & reader_settings, // const String & query_id) const // { // /// Count marks for each part. // std::vector sum_marks_in_parts(parts.size()); // size_t sum_marks = 0; // size_t total_rows = 0; // const auto data_settings = data.getSettings(); // size_t adaptive_parts = 0; // for (size_t i = 0; i < parts.size(); ++i) // { // total_rows += parts[i].getRowsCount(); // sum_marks_in_parts[i] = parts[i].getMarksCount(); // sum_marks += sum_marks_in_parts[i]; // if (parts[i].data_part->index_granularity_info.is_adaptive) // ++adaptive_parts; // } // size_t index_granularity_bytes = 0; // if (adaptive_parts > parts.size() / 2) // index_granularity_bytes = data_settings->index_granularity_bytes; // const size_t max_marks_to_use_cache = roundRowsOrBytesToMarks( // settings.merge_tree_max_rows_to_use_cache, // settings.merge_tree_max_bytes_to_use_cache, // data_settings->index_granularity, // index_granularity_bytes); // const size_t min_marks_for_concurrent_read = minMarksForConcurrentRead( // settings.merge_tree_min_rows_for_concurrent_read, // settings.merge_tree_min_bytes_for_concurrent_read, // data_settings->index_granularity, // index_granularity_bytes, // sum_marks); // if (sum_marks > max_marks_to_use_cache) // use_uncompressed_cache = false; // if (0 == sum_marks) // return {}; // ReadFromMergeTree::Settings step_settings // { // .max_block_size = max_block_size, // .preferred_block_size_bytes = settings.preferred_block_size_bytes, // .preferred_max_column_in_block_size_bytes = settings.preferred_max_column_in_block_size_bytes, // .min_marks_for_concurrent_read = min_marks_for_concurrent_read, // .use_uncompressed_cache = use_uncompressed_cache, // .reader_settings = reader_settings, // .backoff_settings = MergeTreeReadPool::BackoffSettings(settings), // }; // if (num_streams > 1) // { // /// Reduce the number of num_streams if the data is small. // if (sum_marks < num_streams * min_marks_for_concurrent_read && parts.size() < num_streams) // num_streams = std::max((sum_marks + min_marks_for_concurrent_read - 1) / min_marks_for_concurrent_read, parts.size()); // } // auto plan = std::make_unique(); // auto step = std::make_unique( // data, // metadata_snapshot, // query_id, // column_names, // std::move(parts), // // std::move(index_stats), // query_info.projection ? query_info.projection->prewhere_info : query_info.prewhere_info, // virt_columns, // step_settings, // num_streams, // ReadFromMergeTree::ReadType::Default); // plan->addStep(std::move(step)); // return plan; // } // static ActionsDAGPtr createProjection(const Block & header) // { // auto projection = std::make_shared(header.getNamesAndTypesList()); // projection->removeUnusedActions(header.getNames()); // projection->projectInput(); // return projection; // } // QueryPlanPtr MergeTreeDataSelectExecutor::spreadMarkRangesAmongStreamsWithOrder( // RangesInDataParts && parts, // // ReadFromMergeTree::IndexStatPtr index_stats, // size_t num_streams, // const Names & column_names, // const StorageMetadataPtr & metadata_snapshot, // UInt64 max_block_size, // bool use_uncompressed_cache, // const SelectQueryInfo & query_info, // const ActionsDAGPtr & sorting_key_prefix_expr, // const Names & virt_columns, // const Settings & settings, // const MergeTreeReaderSettings & reader_settings, // ActionsDAGPtr & out_projection, // const String & query_id, // const InputOrderInfoPtr & input_order_info) const // { // size_t sum_marks = 0; // size_t adaptive_parts = 0; // std::vector sum_marks_in_parts(parts.size()); // const auto data_settings = data.getSettings(); // for (size_t i = 0; i < parts.size(); ++i) // { // sum_marks_in_parts[i] = parts[i].getMarksCount(); // sum_marks += sum_marks_in_parts[i]; // if (parts[i].data_part->index_granularity_info.is_adaptive) // ++adaptive_parts; // } // size_t index_granularity_bytes = 0; // if (adaptive_parts > parts.size() / 2) // index_granularity_bytes = data_settings->index_granularity_bytes; // const size_t max_marks_to_use_cache = roundRowsOrBytesToMarks( // settings.merge_tree_max_rows_to_use_cache, // settings.merge_tree_max_bytes_to_use_cache, // data_settings->index_granularity, // index_granularity_bytes); // const size_t min_marks_for_concurrent_read = minMarksForConcurrentRead( // settings.merge_tree_min_rows_for_concurrent_read, // settings.merge_tree_min_bytes_for_concurrent_read, // data_settings->index_granularity, // index_granularity_bytes, // sum_marks); // if (sum_marks > max_marks_to_use_cache) // use_uncompressed_cache = false; // Pipes res; // if (sum_marks == 0) // return {}; // /// Let's split ranges to avoid reading much data. // auto split_ranges = [rows_granularity = data_settings->index_granularity, max_block_size](const auto & ranges, int direction) // { // MarkRanges new_ranges; // const size_t max_marks_in_range = (max_block_size + rows_granularity - 1) / rows_granularity; // size_t marks_in_range = 1; // if (direction == 1) // { // /// Split first few ranges to avoid reading much data. // bool split = false; // for (auto range : ranges) // { // while (!split && range.begin + marks_in_range < range.end) // { // new_ranges.emplace_back(range.begin, range.begin + marks_in_range); // range.begin += marks_in_range; // marks_in_range *= 2; // if (marks_in_range > max_marks_in_range) // split = true; // } // new_ranges.emplace_back(range.begin, range.end); // } // } // else // { // /// Split all ranges to avoid reading much data, because we have to // /// store whole range in memory to reverse it. // for (auto it = ranges.rbegin(); it != ranges.rend(); ++it) // { // auto range = *it; // while (range.begin + marks_in_range < range.end) // { // new_ranges.emplace_front(range.end - marks_in_range, range.end); // range.end -= marks_in_range; // marks_in_range = std::min(marks_in_range * 2, max_marks_in_range); // } // new_ranges.emplace_front(range.begin, range.end); // } // } // return new_ranges; // }; // const size_t min_marks_per_stream = (sum_marks - 1) / num_streams + 1; // bool need_preliminary_merge = (parts.size() > settings.read_in_order_two_level_merge_threshold); // std::vector plans; // for (size_t i = 0; i < num_streams && !parts.empty(); ++i) // { // size_t need_marks = min_marks_per_stream; // RangesInDataParts new_parts; // /// Loop over parts. // /// We will iteratively take part or some subrange of a part from the back // /// and assign a stream to read from it. // while (need_marks > 0 && !parts.empty()) // { // RangesInDataPart part = parts.back(); // parts.pop_back(); // size_t & marks_in_part = sum_marks_in_parts.back(); // /// We will not take too few rows from a part. // if (marks_in_part >= min_marks_for_concurrent_read && // need_marks < min_marks_for_concurrent_read) // need_marks = min_marks_for_concurrent_read; // /// Do not leave too few rows in the part. // if (marks_in_part > need_marks && // marks_in_part - need_marks < min_marks_for_concurrent_read) // need_marks = marks_in_part; // MarkRanges ranges_to_get_from_part; // /// We take the whole part if it is small enough. // if (marks_in_part <= need_marks) // { // ranges_to_get_from_part = part.ranges; // need_marks -= marks_in_part; // sum_marks_in_parts.pop_back(); // } // else // { // /// Loop through ranges in part. Take enough ranges to cover "need_marks". // while (need_marks > 0) // { // if (part.ranges.empty()) // throw Exception("Unexpected end of ranges while spreading marks among streams", ErrorCodes::LOGICAL_ERROR); // MarkRange & range = part.ranges.front(); // const size_t marks_in_range = range.end - range.begin; // const size_t marks_to_get_from_range = std::min(marks_in_range, need_marks); // ranges_to_get_from_part.emplace_back(range.begin, range.begin + marks_to_get_from_range); // range.begin += marks_to_get_from_range; // marks_in_part -= marks_to_get_from_range; // need_marks -= marks_to_get_from_range; // if (range.begin == range.end) // part.ranges.pop_front(); // } // parts.emplace_back(part); // } // ranges_to_get_from_part = split_ranges(ranges_to_get_from_part, input_order_info->direction); // new_parts.emplace_back(part.data_part, part.part_index_in_query, std::move(ranges_to_get_from_part)); // } // ReadFromMergeTree::Settings step_settings // { // .max_block_size = max_block_size, // .preferred_block_size_bytes = settings.preferred_block_size_bytes, // .preferred_max_column_in_block_size_bytes = settings.preferred_max_column_in_block_size_bytes, // .min_marks_for_concurrent_read = min_marks_for_concurrent_read, // .use_uncompressed_cache = use_uncompressed_cache, // .reader_settings = reader_settings, // .backoff_settings = MergeTreeReadPool::BackoffSettings(settings), // }; // auto read_type = input_order_info->direction == 1 // ? ReadFromMergeTree::ReadType::InOrder // : ReadFromMergeTree::ReadType::InReverseOrder; // auto plan = std::make_unique(); // auto step = std::make_unique( // data, // metadata_snapshot, // query_id, // column_names, // std::move(new_parts), // // std::move(index_stats), // query_info.projection ? query_info.projection->prewhere_info : query_info.prewhere_info, // virt_columns, // step_settings, // num_streams, // read_type); // plan->addStep(std::move(step)); // plans.emplace_back(std::move(plan)); // } // if (need_preliminary_merge) // { // SortDescription sort_description; // for (size_t j = 0; j < input_order_info->order_key_prefix_descr.size(); ++j) // sort_description.emplace_back(metadata_snapshot->getSortingKey().column_names[j], // input_order_info->direction, 1); // for (auto & plan : plans) // { // /// Drop temporary columns, added by 'sorting_key_prefix_expr' // out_projection = createProjection(plan->getCurrentDataStream().header); // auto expression_step = std::make_unique( // plan->getCurrentDataStream(), // sorting_key_prefix_expr); // expression_step->setStepDescription("Calculate sorting key prefix"); // plan->addStep(std::move(expression_step)); // auto merging_sorted = std::make_unique( // plan->getCurrentDataStream(), // sort_description, // max_block_size); // merging_sorted->setStepDescription("Merge sorting mark ranges"); // plan->addStep(std::move(merging_sorted)); // } // } // if (plans.size() == 1) // return std::move(plans.front()); // DataStreams input_streams; // for (const auto & plan : plans) // input_streams.emplace_back(plan->getCurrentDataStream()); // auto union_step = std::make_unique(std::move(input_streams)); // auto plan = std::make_unique(); // plan->unitePlans(std::move(union_step), std::move(plans)); // return plan; // } // QueryPlanPtr MergeTreeDataSelectExecutor::spreadMarkRangesAmongStreamsFinal( // RangesInDataParts && parts, // size_t num_streams, // const Names & column_names, // const StorageMetadataPtr & metadata_snapshot, // UInt64 max_block_size, // bool use_uncompressed_cache, // const SelectQueryInfo & query_info, // const Names & virt_columns, // const Settings & settings, // const MergeTreeReaderSettings & reader_settings, // ActionsDAGPtr & out_projection, // const String & query_id) const // { // const auto data_settings = data.getSettings(); // size_t sum_marks = 0; // size_t adaptive_parts = 0; // for (const auto & part : parts) // { // for (const auto & range : part.ranges) // sum_marks += range.end - range.begin; // if (part.data_part->index_granularity_info.is_adaptive) // ++adaptive_parts; // } // size_t index_granularity_bytes = 0; // if (adaptive_parts >= parts.size() / 2) // index_granularity_bytes = data_settings->index_granularity_bytes; // const size_t max_marks_to_use_cache = roundRowsOrBytesToMarks( // settings.merge_tree_max_rows_to_use_cache, // settings.merge_tree_max_bytes_to_use_cache, // data_settings->index_granularity, // index_granularity_bytes); // if (sum_marks > max_marks_to_use_cache) // use_uncompressed_cache = false; // if (num_streams > settings.max_final_threads) // num_streams = settings.max_final_threads; // /// If setting do_not_merge_across_partitions_select_final is true than we won't merge parts from different partitions. // /// We have all parts in parts vector, where parts with same partition are nearby. // /// So we will store iterators pointed to the beginning of each partition range (and parts.end()), // /// then we will create a pipe for each partition that will run selecting processor and merging processor // /// for the parts with this partition. In the end we will unite all the pipes. // std::vector parts_to_merge_ranges; // auto it = parts.begin(); // parts_to_merge_ranges.push_back(it); // if (settings.do_not_merge_across_partitions_select_final) // { // while (it != parts.end()) // { // it = std::find_if( // it, parts.end(), [&it](auto & part) { return it->data_part->info.partition_id != part.data_part->info.partition_id; }); // parts_to_merge_ranges.push_back(it); // } // /// We divide threads for each partition equally. But we will create at least the number of partitions threads. // /// (So, the total number of threads could be more than initial num_streams. // num_streams /= (parts_to_merge_ranges.size() - 1); // } // else // { // /// If do_not_merge_across_partitions_select_final is false we just merge all the parts. // parts_to_merge_ranges.push_back(parts.end()); // } // std::vector partition_plans; // /// If do_not_merge_across_partitions_select_final is true and num_streams > 1 // /// we will store lonely parts with level > 0 to use parallel select on them. // std::vector lonely_parts; // size_t total_rows_in_lonely_parts = 0; // size_t sum_marks_in_lonely_parts = 0; // for (size_t range_index = 0; range_index < parts_to_merge_ranges.size() - 1; ++range_index) // { // QueryPlanPtr plan; // { // RangesInDataParts new_parts; // /// If do_not_merge_across_partitions_select_final is true and there is only one part in partition // /// with level > 0 then we won't postprocess this part and if num_streams > 1 we // /// can use parallel select on such parts. We save such parts in one vector and then use // /// MergeTreeReadPool and MergeTreeThreadSelectBlockInputProcessor for parallel select. // if (num_streams > 1 && settings.do_not_merge_across_partitions_select_final && // std::distance(parts_to_merge_ranges[range_index], parts_to_merge_ranges[range_index + 1]) == 1 && // parts_to_merge_ranges[range_index]->data_part->info.level > 0) // { // total_rows_in_lonely_parts += parts_to_merge_ranges[range_index]->getRowsCount(); // sum_marks_in_lonely_parts += parts_to_merge_ranges[range_index]->getMarksCount(); // lonely_parts.push_back(std::move(*parts_to_merge_ranges[range_index])); // continue; // } // else // { // for (auto part_it = parts_to_merge_ranges[range_index]; part_it != parts_to_merge_ranges[range_index + 1]; ++part_it) // { // new_parts.emplace_back(part_it->data_part, part_it->part_index_in_query, part_it->ranges); // } // } // if (new_parts.empty()) // continue; // ReadFromMergeTree::Settings step_settings // { // .max_block_size = max_block_size, // .preferred_block_size_bytes = settings.preferred_block_size_bytes, // .preferred_max_column_in_block_size_bytes = settings.preferred_max_column_in_block_size_bytes, // .min_marks_for_concurrent_read = 0, /// this setting is not used for reading in order // .use_uncompressed_cache = use_uncompressed_cache, // .reader_settings = reader_settings, // .backoff_settings = MergeTreeReadPool::BackoffSettings(settings), // }; // plan = std::make_unique(); // auto step = std::make_unique( // data, // metadata_snapshot, // query_id, // column_names, // std::move(new_parts), // // std::move(index_stats), // query_info.projection ? query_info.projection->prewhere_info : query_info.prewhere_info, // virt_columns, // step_settings, // num_streams, // ReadFromMergeTree::ReadType::InOrder); // plan->addStep(std::move(step)); // /// Drop temporary columns, added by 'sorting_key_expr' // if (!out_projection) // out_projection = createProjection(plan->getCurrentDataStream().header); // } // auto expression_step = std::make_unique( // plan->getCurrentDataStream(), // metadata_snapshot->getSortingKey().expression->getActionsDAG().clone()); // expression_step->setStepDescription("Calculate sorting key expression"); // plan->addStep(std::move(expression_step)); // /// If do_not_merge_across_partitions_select_final is true and there is only one part in partition // /// with level > 0 then we won't postprocess this part // if (settings.do_not_merge_across_partitions_select_final && // std::distance(parts_to_merge_ranges[range_index], parts_to_merge_ranges[range_index + 1]) == 1 && // parts_to_merge_ranges[range_index]->data_part->info.level > 0) // { // partition_plans.emplace_back(std::move(plan)); // continue; // } // Names sort_columns = metadata_snapshot->getSortingKeyColumns(); // SortDescription sort_description; // size_t sort_columns_size = sort_columns.size(); // sort_description.reserve(sort_columns_size); // Names partition_key_columns = metadata_snapshot->getPartitionKey().column_names; // const auto & header = plan->getCurrentDataStream().header; // for (size_t i = 0; i < sort_columns_size; ++i) // sort_description.emplace_back(header.getPositionByName(sort_columns[i]), 1, 1); // auto final_step = std::make_unique( // plan->getCurrentDataStream(), // std::min(num_streams, settings.max_final_threads), // sort_description, // data.merging_params, // partition_key_columns, // max_block_size); // final_step->setStepDescription("Merge rows for FINAL"); // plan->addStep(std::move(final_step)); // partition_plans.emplace_back(std::move(plan)); // } // if (!lonely_parts.empty()) // { // RangesInDataParts new_parts; // size_t num_streams_for_lonely_parts = num_streams * lonely_parts.size(); // const size_t min_marks_for_concurrent_read = minMarksForConcurrentRead( // settings.merge_tree_min_rows_for_concurrent_read, // settings.merge_tree_min_bytes_for_concurrent_read, // data_settings->index_granularity, // index_granularity_bytes, // sum_marks_in_lonely_parts); // /// Reduce the number of num_streams_for_lonely_parts if the data is small. // if (sum_marks_in_lonely_parts < num_streams_for_lonely_parts * min_marks_for_concurrent_read && lonely_parts.size() < num_streams_for_lonely_parts) // num_streams_for_lonely_parts = std::max((sum_marks_in_lonely_parts + min_marks_for_concurrent_read - 1) / min_marks_for_concurrent_read, lonely_parts.size()); // ReadFromMergeTree::Settings step_settings // { // .max_block_size = max_block_size, // .preferred_block_size_bytes = settings.preferred_block_size_bytes, // .preferred_max_column_in_block_size_bytes = settings.preferred_max_column_in_block_size_bytes, // .min_marks_for_concurrent_read = min_marks_for_concurrent_read, // .use_uncompressed_cache = use_uncompressed_cache, // .reader_settings = reader_settings, // .backoff_settings = MergeTreeReadPool::BackoffSettings(settings), // }; // auto plan = std::make_unique(); // auto step = std::make_unique( // data, // metadata_snapshot, // query_id, // column_names, // std::move(lonely_parts), // // std::move(index_stats), // query_info.projection ? query_info.projection->prewhere_info : query_info.prewhere_info, // virt_columns, // step_settings, // num_streams_for_lonely_parts, // ReadFromMergeTree::ReadType::Default); // plan->addStep(std::move(step)); // /// Drop temporary columns, added by 'sorting_key_expr' // if (!out_projection) // out_projection = createProjection(plan->getCurrentDataStream().header); // auto expression_step = std::make_unique( // plan->getCurrentDataStream(), // metadata_snapshot->getSortingKey().expression->getActionsDAG().clone()); // expression_step->setStepDescription("Calculate sorting key expression"); // plan->addStep(std::move(expression_step)); // partition_plans.emplace_back(std::move(plan)); // } // if (partition_plans.empty()) // return {}; // if (partition_plans.size() == 1) // return std::move(partition_plans.front()); // auto result_header = partition_plans.front()->getCurrentDataStream().header; // DataStreams input_streams; // for (const auto & partition_plan : partition_plans) // input_streams.push_back(partition_plan->getCurrentDataStream()); // auto union_step = std::make_unique(std::move(input_streams), result_header); // union_step->setStepDescription("Unite sources after FINAL"); // QueryPlanPtr plan = std::make_unique(); // plan->unitePlans(std::move(union_step), std::move(partition_plans)); // return plan; // } /// Calculates a set of mark ranges, that could possibly contain keys, required by condition. /// In other words, it removes subranges from whole range, that definitely could not contain required keys. MarkRanges MergeTreeDataSelectExecutor::markRangesFromPKRange( const MergeTreeData::DataPartPtr & part, const StorageMetadataPtr & metadata_snapshot, const KeyCondition & key_condition, const Settings & settings, Poco::Logger * log) { MarkRanges res; size_t marks_count = part->index_granularity.getMarksCount(); const auto & index = part->index; if (marks_count == 0) return res; bool has_final_mark = part->index_granularity.hasFinalMark(); /// If index is not used. if (key_condition.alwaysUnknownOrTrue()) { if (has_final_mark) res.push_back(MarkRange(0, marks_count - 1)); else res.push_back(MarkRange(0, marks_count)); return res; } size_t used_key_size = key_condition.getMaxKeyColumn() + 1; std::function create_field_ref; /// If there are no monotonic functions, there is no need to save block reference. /// Passing explicit field to FieldRef allows to optimize ranges and shows better performance. const auto & primary_key = metadata_snapshot->getPrimaryKey(); if (key_condition.hasMonotonicFunctionsChain()) { auto index_columns = std::make_shared(); for (size_t i = 0; i < used_key_size; ++i) index_columns->emplace_back(ColumnWithTypeAndName{index[i], primary_key.data_types[i], primary_key.column_names[i]}); create_field_ref = [index_columns](size_t row, size_t column, FieldRef & field) { field = {index_columns.get(), row, column}; }; } else { create_field_ref = [&index](size_t row, size_t column, FieldRef & field) { index[column]->get(row, field); }; } /// NOTE Creating temporary Field objects to pass to KeyCondition. std::vector index_left(used_key_size); std::vector index_right(used_key_size); auto may_be_true_in_range = [&](MarkRange & range) { if (range.end == marks_count && !has_final_mark) { for (size_t i = 0; i < used_key_size; ++i) create_field_ref(range.begin, i, index_left[i]); return key_condition.mayBeTrueAfter( used_key_size, index_left.data(), primary_key.data_types); } if (has_final_mark && range.end == marks_count) range.end -= 1; /// Remove final empty mark. It's useful only for primary key condition. for (size_t i = 0; i < used_key_size; ++i) { create_field_ref(range.begin, i, index_left[i]); create_field_ref(range.end, i, index_right[i]); } return key_condition.mayBeTrueInRange( used_key_size, index_left.data(), index_right.data(), primary_key.data_types); }; if (!key_condition.matchesExactContinuousRange()) { // Do exclusion search, where we drop ranges that do not match size_t min_marks_for_seek = roundRowsOrBytesToMarks( settings.merge_tree_min_rows_for_seek, settings.merge_tree_min_bytes_for_seek, part->index_granularity_info.fixed_index_granularity, part->index_granularity_info.index_granularity_bytes); /** There will always be disjoint suspicious segments on the stack, the leftmost one at the top (back). * At each step, take the left segment and check if it fits. * If fits, split it into smaller ones and put them on the stack. If not, discard it. * If the segment is already of one mark length, add it to response and discard it. */ std::vector ranges_stack = { {0, marks_count} }; size_t steps = 0; while (!ranges_stack.empty()) { MarkRange range = ranges_stack.back(); ranges_stack.pop_back(); steps++; if (!may_be_true_in_range(range)) continue; if (range.end == range.begin + 1) { /// We saw a useful gap between neighboring marks. Either add it to the last range, or start a new range. if (res.empty() || range.begin - res.back().end > min_marks_for_seek) res.push_back(range); else res.back().end = range.end; } else { /// Break the segment and put the result on the stack from right to left. size_t step = (range.end - range.begin - 1) / settings.merge_tree_coarse_index_granularity + 1; size_t end; for (end = range.end; end > range.begin + step; end -= step) ranges_stack.emplace_back(end - step, end); ranges_stack.emplace_back(range.begin, end); } } LOG_TRACE(log, "Used generic exclusion search over index for part {} with {} steps", part->name, steps); } else { /// In case when SELECT's predicate defines a single continuous interval of keys, /// we can use binary search algorithm to find the left and right endpoint key marks of such interval. /// The returned value is the minimum range of marks, containing all keys for which KeyCondition holds LOG_TRACE(log, "Running binary search on index range for part {} ({} marks)", part->name, marks_count); size_t steps = 0; MarkRange result_range; size_t searched_left = 0; size_t searched_right = marks_count; while (searched_left + 1 < searched_right) { const size_t middle = (searched_left + searched_right) / 2; MarkRange range(0, middle); if (may_be_true_in_range(range)) searched_right = middle; else searched_left = middle; ++steps; } result_range.begin = searched_left; LOG_TRACE(log, "Found (LEFT) boundary mark: {}", searched_left); searched_right = marks_count; while (searched_left + 1 < searched_right) { const size_t middle = (searched_left + searched_right) / 2; MarkRange range(middle, marks_count); if (may_be_true_in_range(range)) searched_left = middle; else searched_right = middle; ++steps; } result_range.end = searched_right; LOG_TRACE(log, "Found (RIGHT) boundary mark: {}", searched_right); if (result_range.begin < result_range.end && may_be_true_in_range(result_range)) res.emplace_back(std::move(result_range)); LOG_TRACE(log, "Found {} range in {} steps", res.empty() ? "empty" : "continuous", steps); } return res; } MarkRanges MergeTreeDataSelectExecutor::filterMarksUsingIndex( MergeTreeIndexPtr index_helper, MergeTreeIndexConditionPtr condition, MergeTreeData::DataPartPtr part, const MarkRanges & ranges, const Settings & settings, const MergeTreeReaderSettings & reader_settings, size_t & total_granules, size_t & granules_dropped, Poco::Logger * log) { if (!part->volume->getDisk()->exists(part->getFullRelativePath() + index_helper->getFileName() + ".idx")) { LOG_DEBUG(log, "File for index {} does not exist. Skipping it.", backQuote(index_helper->index.name)); return ranges; } auto index_granularity = index_helper->index.granularity; const size_t min_marks_for_seek = roundRowsOrBytesToMarks( settings.merge_tree_min_rows_for_seek, settings.merge_tree_min_bytes_for_seek, part->index_granularity_info.fixed_index_granularity, part->index_granularity_info.index_granularity_bytes); size_t marks_count = part->getMarksCount(); size_t final_mark = part->index_granularity.hasFinalMark(); size_t index_marks_count = (marks_count - final_mark + index_granularity - 1) / index_granularity; MergeTreeIndexReader reader( index_helper, part, index_marks_count, ranges, reader_settings); MarkRanges res; /// Some granules can cover two or more ranges, /// this variable is stored to avoid reading the same granule twice. MergeTreeIndexGranulePtr granule = nullptr; size_t last_index_mark = 0; for (const auto & range : ranges) { MarkRange index_range( range.begin / index_granularity, (range.end + index_granularity - 1) / index_granularity); if (last_index_mark != index_range.begin || !granule) reader.seek(index_range.begin); total_granules += index_range.end - index_range.begin; for (size_t index_mark = index_range.begin; index_mark < index_range.end; ++index_mark) { if (index_mark != index_range.begin || !granule || last_index_mark != index_range.begin) granule = reader.read(); MarkRange data_range( std::max(range.begin, index_mark * index_granularity), std::min(range.end, (index_mark + 1) * index_granularity)); if (!condition->mayBeTrueOnGranule(granule)) { ++granules_dropped; continue; } if (res.empty() || res.back().end - data_range.begin > min_marks_for_seek) res.push_back(data_range); else res.back().end = data_range.end; } last_index_mark = index_range.end - 1; } return res; } void MergeTreeDataSelectExecutor::selectPartsToRead( MergeTreeData::DataPartsVector & parts, const std::optional> & part_values, const std::optional & minmax_idx_condition, const DataTypes & minmax_columns_types, std::optional & partition_pruner, const PartitionIdToMaxBlock * max_block_numbers_to_read, PartFilterCounters & counters) { MergeTreeData::DataPartsVector prev_parts; std::swap(prev_parts, parts); for (const auto & part_or_projection : prev_parts) { const auto * part = part_or_projection->isProjectionPart() ? part_or_projection->getParentPart() : part_or_projection.get(); if (part_values && part_values->find(part->name) == part_values->end()) continue; if (part->isEmpty()) continue; if (max_block_numbers_to_read) { auto blocks_iterator = max_block_numbers_to_read->find(part->info.partition_id); if (blocks_iterator == max_block_numbers_to_read->end() || part->info.max_block > blocks_iterator->second) continue; } size_t num_granules = part->getMarksCount(); if (num_granules && part->index_granularity.hasFinalMark()) --num_granules; counters.num_initial_selected_parts += 1; counters.num_initial_selected_granules += num_granules; if (minmax_idx_condition && !minmax_idx_condition->checkInHyperrectangle( part->minmax_idx.hyperrectangle, minmax_columns_types).can_be_true) continue; counters.num_parts_after_minmax += 1; counters.num_granules_after_minmax += num_granules; if (partition_pruner) { if (partition_pruner->canBePruned(*part)) continue; } counters.num_parts_after_partition_pruner += 1; counters.num_granules_after_partition_pruner += num_granules; parts.push_back(part_or_projection); } } void MergeTreeDataSelectExecutor::selectPartsToReadWithUUIDFilter( MergeTreeData::DataPartsVector & parts, const std::optional> & part_values, MergeTreeData::PinnedPartUUIDsPtr pinned_part_uuids, const std::optional & minmax_idx_condition, const DataTypes & minmax_columns_types, std::optional & partition_pruner, const PartitionIdToMaxBlock * max_block_numbers_to_read, ContextPtr query_context, PartFilterCounters & counters, Poco::Logger * log) { const Settings & settings = query_context->getSettings(); /// process_parts prepare parts that have to be read for the query, /// returns false if duplicated parts' UUID have been met auto select_parts = [&] (MergeTreeData::DataPartsVector & selected_parts) -> bool { auto ignored_part_uuids = query_context->getIgnoredPartUUIDs(); std::unordered_set temp_part_uuids; MergeTreeData::DataPartsVector prev_parts; std::swap(prev_parts, selected_parts); for (const auto & part_or_projection : prev_parts) { const auto * part = part_or_projection->isProjectionPart() ? part_or_projection->getParentPart() : part_or_projection.get(); if (part_values && part_values->find(part->name) == part_values->end()) continue; if (part->isEmpty()) continue; if (max_block_numbers_to_read) { auto blocks_iterator = max_block_numbers_to_read->find(part->info.partition_id); if (blocks_iterator == max_block_numbers_to_read->end() || part->info.max_block > blocks_iterator->second) continue; } /// Skip the part if its uuid is meant to be excluded if (part->uuid != UUIDHelpers::Nil && ignored_part_uuids->has(part->uuid)) continue; size_t num_granules = part->getMarksCount(); if (num_granules && part->index_granularity.hasFinalMark()) --num_granules; counters.num_initial_selected_parts += 1; counters.num_initial_selected_granules += num_granules; if (minmax_idx_condition && !minmax_idx_condition->checkInHyperrectangle(part->minmax_idx.hyperrectangle, minmax_columns_types) .can_be_true) continue; counters.num_parts_after_minmax += 1; counters.num_granules_after_minmax += num_granules; if (partition_pruner) { if (partition_pruner->canBePruned(*part)) continue; } counters.num_parts_after_partition_pruner += 1; counters.num_granules_after_partition_pruner += num_granules; /// populate UUIDs and exclude ignored parts if enabled if (part->uuid != UUIDHelpers::Nil) { if (settings.experimental_query_deduplication_send_all_part_uuids || pinned_part_uuids->contains(part->uuid)) { auto result = temp_part_uuids.insert(part->uuid); if (!result.second) throw Exception("Found a part with the same UUID on the same replica.", ErrorCodes::LOGICAL_ERROR); } } selected_parts.push_back(part_or_projection); } if (!temp_part_uuids.empty()) { auto duplicates = query_context->getPartUUIDs()->add(std::vector{temp_part_uuids.begin(), temp_part_uuids.end()}); if (!duplicates.empty()) { /// on a local replica with prefer_localhost_replica=1 if any duplicates appeared during the first pass, /// adding them to the exclusion, so they will be skipped on second pass query_context->getIgnoredPartUUIDs()->add(duplicates); return false; } } return true; }; /// Process parts that have to be read for a query. auto needs_retry = !select_parts(parts); /// If any duplicated part UUIDs met during the first step, try to ignore them in second pass. /// This may happen when `prefer_localhost_replica` is set and "distributed" stage runs in the same process with "remote" stage. if (needs_retry) { LOG_DEBUG(log, "Found duplicate uuids locally, will retry part selection without them"); counters = PartFilterCounters(); /// Second attempt didn't help, throw an exception if (!select_parts(parts)) throw Exception("Found duplicate UUIDs while processing query.", ErrorCodes::DUPLICATED_PART_UUIDS); } } }