#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 #include #include #include #include #include namespace DB { using LogAST = DebugASTLog; /// set to true to enable logs namespace ErrorCodes { extern const int UNKNOWN_IDENTIFIER; extern const int ILLEGAL_AGGREGATION; extern const int EXPECTED_ALL_OR_ANY; } ExpressionAnalyzer::ExpressionAnalyzer( const ASTPtr & query_, const SyntaxAnalyzerResultPtr & syntax_analyzer_result_, const Context & context_, const NamesAndTypesList & additional_source_columns, const NameSet & required_result_columns_, size_t subquery_depth_, bool do_global_, const SubqueriesForSets & subqueries_for_sets_) : ExpressionAnalyzerData(syntax_analyzer_result_->source_columns, required_result_columns_, subqueries_for_sets_) , query(query_), context(context_), settings(context.getSettings()) , subquery_depth(subquery_depth_), do_global(do_global_) , syntax(syntax_analyzer_result_) { storage = syntax->storage; rewrite_subqueries = syntax->rewrite_subqueries; select_query = typeid_cast(query.get()); if (!additional_source_columns.empty()) { source_columns.insert(source_columns.end(), additional_source_columns.begin(), additional_source_columns.end()); removeDuplicateColumns(source_columns); } /// Delete the unnecessary from `source_columns` list. Form `columns_added_by_join`. collectUsedColumns(); /// external_tables, subqueries_for_sets for global subqueries. /// Replaces global subqueries with the generated names of temporary tables that will be sent to remote servers. initGlobalSubqueriesAndExternalTables(); /// has_aggregation, aggregation_keys, aggregate_descriptions, aggregated_columns. /// This analysis should be performed after processing global subqueries, because otherwise, /// if the aggregate function contains a global subquery, then `analyzeAggregation` method will save /// in `aggregate_descriptions` the information about the parameters of this aggregate function, among which /// global subquery. Then, when you call `initGlobalSubqueriesAndExternalTables` method, this /// the global subquery will be replaced with a temporary table, resulting in aggregate_descriptions /// will contain out-of-date information, which will lead to an error when the query is executed. analyzeAggregation(); } bool ExpressionAnalyzer::isRemoteStorage() const { return storage && storage->isRemote(); } void ExpressionAnalyzer::analyzeAggregation() { /** Find aggregation keys (aggregation_keys), information about aggregate functions (aggregate_descriptions), * as well as a set of columns obtained after the aggregation, if any, * or after all the actions that are usually performed before aggregation (aggregated_columns). * * Everything below (compiling temporary ExpressionActions) - only for the purpose of query analysis (type output). */ if (select_query && (select_query->group_expression_list || select_query->having_expression)) has_aggregation = true; ExpressionActionsPtr temp_actions = std::make_shared(source_columns, context); if (select_query) { bool is_array_join_left; ASTPtr array_join_expression_list = select_query->array_join_expression_list(is_array_join_left); if (array_join_expression_list) { getRootActions(array_join_expression_list, true, temp_actions); addMultipleArrayJoinAction(temp_actions, is_array_join_left); array_join_columns = temp_actions->getSampleBlock().getNamesAndTypesList(); } const ASTTablesInSelectQueryElement * join = select_query->join(); if (join) { const auto table_join = static_cast(*join->table_join); if (table_join.using_expression_list) getRootActions(table_join.using_expression_list, true, temp_actions); if (table_join.on_expression) for (const auto & key_ast : analyzedJoin().key_asts_left) getRootActions(key_ast, true, temp_actions); addJoinAction(temp_actions, true); } } getAggregates(query, temp_actions); if (has_aggregation) { assertSelect(); /// Find out aggregation keys. if (select_query->group_expression_list) { NameSet unique_keys; ASTs & group_asts = select_query->group_expression_list->children; for (ssize_t i = 0; i < ssize_t(group_asts.size()); ++i) { ssize_t size = group_asts.size(); getRootActions(group_asts[i], true, temp_actions); const auto & column_name = group_asts[i]->getColumnName(); const auto & block = temp_actions->getSampleBlock(); if (!block.has(column_name)) throw Exception("Unknown identifier (in GROUP BY): " + column_name, ErrorCodes::UNKNOWN_IDENTIFIER); const auto & col = block.getByName(column_name); /// Constant expressions have non-null column pointer at this stage. if (col.column && col.column->isColumnConst()) { /// But don't remove last key column if no aggregate functions, otherwise aggregation will not work. if (!aggregate_descriptions.empty() || size > 1) { if (i + 1 < static_cast(size)) group_asts[i] = std::move(group_asts.back()); group_asts.pop_back(); --i; continue; } } NameAndTypePair key{column_name, col.type}; /// Aggregation keys are uniqued. if (!unique_keys.count(key.name)) { unique_keys.insert(key.name); aggregation_keys.push_back(key); /// Key is no longer needed, therefore we can save a little by moving it. aggregated_columns.push_back(std::move(key)); } } if (group_asts.empty()) { select_query->group_expression_list = nullptr; has_aggregation = select_query->having_expression || aggregate_descriptions.size(); } } for (size_t i = 0; i < aggregate_descriptions.size(); ++i) { AggregateDescription & desc = aggregate_descriptions[i]; aggregated_columns.emplace_back(desc.column_name, desc.function->getReturnType()); } } else { aggregated_columns = temp_actions->getSampleBlock().getNamesAndTypesList(); } } void ExpressionAnalyzer::initGlobalSubqueriesAndExternalTables() { /// Adds existing external tables (not subqueries) to the external_tables dictionary. ExternalTablesVisitor::Data tables_data{context, external_tables}; ExternalTablesVisitor(tables_data).visit(query); if (do_global) { GlobalSubqueriesVisitor::Data subqueries_data(context, subquery_depth, isRemoteStorage(), external_tables, subqueries_for_sets, has_global_subqueries); GlobalSubqueriesVisitor(subqueries_data).visit(query); } } void ExpressionAnalyzer::makeSetsForIndex() { if (storage && select_query && storage->supportsIndexForIn()) { if (select_query->where_expression) makeSetsForIndexImpl(select_query->where_expression); if (select_query->prewhere_expression) makeSetsForIndexImpl(select_query->prewhere_expression); } } void ExpressionAnalyzer::tryMakeSetForIndexFromSubquery(const ASTPtr & subquery_or_table_name) { auto set_key = PreparedSetKey::forSubquery(*subquery_or_table_name); if (prepared_sets.count(set_key)) return; /// Already prepared. auto interpreter_subquery = interpretSubquery(subquery_or_table_name, context, subquery_depth + 1, {}); BlockIO res = interpreter_subquery->execute(); SetPtr set = std::make_shared(settings.size_limits_for_set, true); set->setHeader(res.in->getHeader()); while (Block block = res.in->read()) { /// If the limits have been exceeded, give up and let the default subquery processing actions take place. if (!set->insertFromBlock(block)) return; } prepared_sets[set_key] = std::move(set); } void ExpressionAnalyzer::makeSetsForIndexImpl(const ASTPtr & node) { for (auto & child : node->children) { /// Don't descend into subqueries. if (typeid_cast(child.get())) continue; /// Don't descend into lambda functions const ASTFunction * func = typeid_cast(child.get()); if (func && func->name == "lambda") continue; makeSetsForIndexImpl(child); } const ASTFunction * func = typeid_cast(node.get()); if (func && functionIsInOperator(func->name)) { const IAST & args = *func->arguments; if (storage && storage->mayBenefitFromIndexForIn(args.children.at(0))) { const ASTPtr & arg = args.children.at(1); if (typeid_cast(arg.get()) || isIdentifier(arg)) { if (settings.use_index_for_in_with_subqueries) tryMakeSetForIndexFromSubquery(arg); } else { NamesAndTypesList temp_columns = source_columns; temp_columns.insert(temp_columns.end(), array_join_columns.begin(), array_join_columns.end()); for (const auto & joined_column : columns_added_by_join) temp_columns.push_back(joined_column.name_and_type); ExpressionActionsPtr temp_actions = std::make_shared(temp_columns, context); getRootActions(func->arguments->children.at(0), true, temp_actions); Block sample_block_with_calculated_columns = temp_actions->getSampleBlock(); if (sample_block_with_calculated_columns.has(args.children.at(0)->getColumnName())) makeExplicitSet(func, sample_block_with_calculated_columns, true, context, settings.size_limits_for_set, prepared_sets); } } } } void ExpressionAnalyzer::getRootActions(const ASTPtr & ast, bool no_subqueries, ExpressionActionsPtr & actions, bool only_consts) { LogAST log; ActionsVisitor actions_visitor(context, settings.size_limits_for_set, subquery_depth, source_columns, actions, prepared_sets, subqueries_for_sets, no_subqueries, only_consts, !isRemoteStorage(), log.stream()); actions_visitor.visit(ast); actions = actions_visitor.popActionsLevel(); } void ExpressionAnalyzer::getActionsFromJoinKeys(const ASTTableJoin & table_join, bool no_subqueries, ExpressionActionsPtr & actions) { bool only_consts = false; LogAST log; ActionsVisitor actions_visitor(context, settings.size_limits_for_set, subquery_depth, source_columns, actions, prepared_sets, subqueries_for_sets, no_subqueries, only_consts, !isRemoteStorage(), log.stream()); if (table_join.using_expression_list) actions_visitor.visit(table_join.using_expression_list); else if (table_join.on_expression) { for (const auto & ast : analyzedJoin().key_asts_left) actions_visitor.visit(ast); } actions = actions_visitor.popActionsLevel(); } void ExpressionAnalyzer::getAggregates(const ASTPtr & ast, ExpressionActionsPtr & actions) { /// There can not be aggregate functions inside the WHERE and PREWHERE. if (select_query && (ast.get() == select_query->where_expression.get() || ast.get() == select_query->prewhere_expression.get())) { assertNoAggregates(ast, "in WHERE or PREWHERE"); return; } /// If we are not analyzing a SELECT query, but a separate expression, then there can not be aggregate functions in it. if (!select_query) { assertNoAggregates(ast, "in wrong place"); return; } const ASTFunction * node = typeid_cast(ast.get()); if (node && AggregateFunctionFactory::instance().isAggregateFunctionName(node->name)) { has_aggregation = true; AggregateDescription aggregate; aggregate.column_name = node->getColumnName(); /// Make unique aggregate functions. for (size_t i = 0; i < aggregate_descriptions.size(); ++i) if (aggregate_descriptions[i].column_name == aggregate.column_name) return; const ASTs & arguments = node->arguments->children; aggregate.argument_names.resize(arguments.size()); DataTypes types(arguments.size()); for (size_t i = 0; i < arguments.size(); ++i) { /// There can not be other aggregate functions within the aggregate functions. assertNoAggregates(arguments[i], "inside another aggregate function"); getRootActions(arguments[i], true, actions); const std::string & name = arguments[i]->getColumnName(); types[i] = actions->getSampleBlock().getByName(name).type; aggregate.argument_names[i] = name; } aggregate.parameters = (node->parameters) ? getAggregateFunctionParametersArray(node->parameters) : Array(); aggregate.function = AggregateFunctionFactory::instance().get(node->name, types, aggregate.parameters); aggregate_descriptions.push_back(aggregate); } else { for (const auto & child : ast->children) if (!typeid_cast(child.get()) && !typeid_cast(child.get())) getAggregates(child, actions); } } void ExpressionAnalyzer::assertNoAggregates(const ASTPtr & ast, const char * description) { const ASTFunction * node = typeid_cast(ast.get()); if (node && AggregateFunctionFactory::instance().isAggregateFunctionName(node->name)) throw Exception("Aggregate function " + node->getColumnName() + " is found " + String(description) + " in query", ErrorCodes::ILLEGAL_AGGREGATION); for (const auto & child : ast->children) if (!typeid_cast(child.get()) && !typeid_cast(child.get())) assertNoAggregates(child, description); } void ExpressionAnalyzer::assertSelect() const { if (!select_query) throw Exception("Not a select query", ErrorCodes::LOGICAL_ERROR); } void ExpressionAnalyzer::assertAggregation() const { if (!has_aggregation) throw Exception("No aggregation", ErrorCodes::LOGICAL_ERROR); } void ExpressionAnalyzer::initChain(ExpressionActionsChain & chain, const NamesAndTypesList & columns) const { if (chain.steps.empty()) { chain.steps.emplace_back(std::make_shared(columns, context)); } } /// "Big" ARRAY JOIN. void ExpressionAnalyzer::addMultipleArrayJoinAction(ExpressionActionsPtr & actions, bool array_join_is_left) const { NameSet result_columns; for (const auto & result_source : syntax->array_join_result_to_source) { /// Assign new names to columns, if needed. if (result_source.first != result_source.second) actions->add(ExpressionAction::copyColumn(result_source.second, result_source.first)); /// Make ARRAY JOIN (replace arrays with their insides) for the columns in these new names. result_columns.insert(result_source.first); } actions->add(ExpressionAction::arrayJoin(result_columns, array_join_is_left, context)); } bool ExpressionAnalyzer::appendArrayJoin(ExpressionActionsChain & chain, bool only_types) { assertSelect(); bool is_array_join_left; ASTPtr array_join_expression_list = select_query->array_join_expression_list(is_array_join_left); if (!array_join_expression_list) return false; initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getRootActions(array_join_expression_list, only_types, step.actions); addMultipleArrayJoinAction(step.actions, is_array_join_left); return true; } void ExpressionAnalyzer::addJoinAction(ExpressionActionsPtr & actions, bool only_types) const { NamesAndTypesList columns_added_by_join_list; for (const auto & joined_column : columns_added_by_join) columns_added_by_join_list.push_back(joined_column.name_and_type); if (only_types) actions->add(ExpressionAction::ordinaryJoin(nullptr, analyzedJoin().key_names_left, columns_added_by_join_list)); else for (auto & subquery_for_set : subqueries_for_sets) if (subquery_for_set.second.join) actions->add(ExpressionAction::ordinaryJoin(subquery_for_set.second.join, analyzedJoin().key_names_left, columns_added_by_join_list)); } static void appendRequiredColumns(NameSet & required_columns, const Block & sample, const AnalyzedJoin & analyzed_join) { for (auto & column : analyzed_join.key_names_right) if (!sample.has(column)) required_columns.insert(column); for (auto & column : analyzed_join.columns_from_joined_table) if (!sample.has(column.name_and_type.name)) required_columns.insert(column.name_and_type.name); } bool ExpressionAnalyzer::appendJoin(ExpressionActionsChain & chain, bool only_types) { assertSelect(); if (!select_query->join()) return false; initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); const auto & join_element = static_cast(*select_query->join()); auto & join_params = static_cast(*join_element.table_join); if (join_params.strictness == ASTTableJoin::Strictness::Unspecified && join_params.kind != ASTTableJoin::Kind::Cross) { if (settings.join_default_strictness == "ANY") join_params.strictness = ASTTableJoin::Strictness::Any; else if (settings.join_default_strictness == "ALL") join_params.strictness = ASTTableJoin::Strictness::All; else throw Exception("Expected ANY or ALL in JOIN section, because setting (join_default_strictness) is empty", DB::ErrorCodes::EXPECTED_ALL_OR_ANY); } const auto & table_to_join = static_cast(*join_element.table_expression); getActionsFromJoinKeys(join_params, only_types, step.actions); /// Two JOINs are not supported with the same subquery, but different USINGs. auto join_hash = join_element.getTreeHash(); SubqueryForSet & subquery_for_set = subqueries_for_sets[toString(join_hash.first) + "_" + toString(join_hash.second)]; /// Special case - if table name is specified on the right of JOIN, then the table has the type Join (the previously prepared mapping). /// TODO This syntax does not support specifying a database name. if (table_to_join.database_and_table_name) { DatabaseAndTableWithAlias database_table(table_to_join.database_and_table_name); StoragePtr table = context.tryGetTable(database_table.database, database_table.table); if (table) { StorageJoin * storage_join = dynamic_cast(table.get()); if (storage_join) { storage_join->assertCompatible(join_params.kind, join_params.strictness); /// TODO Check the set of keys. JoinPtr & join = storage_join->getJoin(); subquery_for_set.join = join; } } } if (!subquery_for_set.join) { auto & analyzed_join = analyzedJoin(); /// Actions which need to be calculated on joined block. ExpressionActionsPtr joined_block_actions = analyzed_join.createJoinedBlockActions(columns_added_by_join, select_query, context); /** For GLOBAL JOINs (in the case, for example, of the push method for executing GLOBAL subqueries), the following occurs * - in the addExternalStorage function, the JOIN (SELECT ...) subquery is replaced with JOIN _data1, * in the subquery_for_set object this subquery is exposed as source and the temporary table _data1 as the `table`. * - this function shows the expression JOIN _data1. */ if (!subquery_for_set.source) { ASTPtr table; if (table_to_join.subquery) table = table_to_join.subquery; else if (table_to_join.table_function) table = table_to_join.table_function; else if (table_to_join.database_and_table_name) table = table_to_join.database_and_table_name; Names action_columns = joined_block_actions->getRequiredColumns(); NameSet required_columns(action_columns.begin(), action_columns.end()); appendRequiredColumns(required_columns, joined_block_actions->getSampleBlock(), analyzed_join); Names original_columns = analyzed_join.getOriginalColumnNames(required_columns); auto interpreter = interpretSubquery(table, context, subquery_depth, original_columns); subquery_for_set.makeSource(interpreter, analyzed_join.columns_from_joined_table, required_columns); } Block sample_block = subquery_for_set.renamedSampleBlock(); joined_block_actions->execute(sample_block); /// TODO You do not need to set this up when JOIN is only needed on remote servers. subquery_for_set.join = std::make_shared(analyzedJoin().key_names_right, settings.join_use_nulls, settings.size_limits_for_join, join_params.kind, join_params.strictness); subquery_for_set.join->setSampleBlock(sample_block); subquery_for_set.joined_block_actions = joined_block_actions; } addJoinAction(step.actions, false); return true; } bool ExpressionAnalyzer::appendPrewhere( ExpressionActionsChain & chain, bool only_types, const Names & additional_required_columns) { assertSelect(); if (!select_query->prewhere_expression) return false; initChain(chain, source_columns); auto & step = chain.getLastStep(); getRootActions(select_query->prewhere_expression, only_types, step.actions); String prewhere_column_name = select_query->prewhere_expression->getColumnName(); step.required_output.push_back(prewhere_column_name); step.can_remove_required_output.push_back(true); { /// Remove unused source_columns from prewhere actions. auto tmp_actions = std::make_shared(source_columns, context); getRootActions(select_query->prewhere_expression, only_types, tmp_actions); tmp_actions->finalize({prewhere_column_name}); auto required_columns = tmp_actions->getRequiredColumns(); NameSet required_source_columns(required_columns.begin(), required_columns.end()); /// Add required columns to required output in order not to remove them after prewhere execution. /// TODO: add sampling and final execution to common chain. for (const auto & column : additional_required_columns) { if (required_source_columns.count(column)) { step.required_output.push_back(column); step.can_remove_required_output.push_back(true); } } auto names = step.actions->getSampleBlock().getNames(); NameSet name_set(names.begin(), names.end()); for (const auto & column : source_columns) if (required_source_columns.count(column.name) == 0) name_set.erase(column.name); Names required_output(name_set.begin(), name_set.end()); step.actions->finalize(required_output); } { /// Add empty action with input = {prewhere actions output} + {unused source columns} /// Reasons: /// 1. Remove remove source columns which are used only in prewhere actions during prewhere actions execution. /// Example: select A prewhere B > 0. B can be removed at prewhere step. /// 2. Store side columns which were calculated during prewhere actions execution if they are used. /// Example: select F(A) prewhere F(A) > 0. F(A) can be saved from prewhere step. /// 3. Check if we can remove filter column at prewhere step. If we can, action will store single REMOVE_COLUMN. ColumnsWithTypeAndName columns = step.actions->getSampleBlock().getColumnsWithTypeAndName(); auto required_columns = step.actions->getRequiredColumns(); NameSet prewhere_input_names(required_columns.begin(), required_columns.end()); NameSet unused_source_columns; for (const auto & column : source_columns) { if (prewhere_input_names.count(column.name) == 0) { columns.emplace_back(column.type, column.name); unused_source_columns.emplace(column.name); } } chain.steps.emplace_back(std::make_shared(std::move(columns), context)); chain.steps.back().additional_input = std::move(unused_source_columns); } return true; } bool ExpressionAnalyzer::appendWhere(ExpressionActionsChain & chain, bool only_types) { assertSelect(); if (!select_query->where_expression) return false; initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); step.required_output.push_back(select_query->where_expression->getColumnName()); step.can_remove_required_output = {true}; getRootActions(select_query->where_expression, only_types, step.actions); return true; } bool ExpressionAnalyzer::appendGroupBy(ExpressionActionsChain & chain, bool only_types) { assertAggregation(); if (!select_query->group_expression_list) return false; initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); ASTs asts = select_query->group_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { step.required_output.push_back(asts[i]->getColumnName()); getRootActions(asts[i], only_types, step.actions); } return true; } void ExpressionAnalyzer::appendAggregateFunctionsArguments(ExpressionActionsChain & chain, bool only_types) { assertAggregation(); initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); for (size_t i = 0; i < aggregate_descriptions.size(); ++i) { for (size_t j = 0; j < aggregate_descriptions[i].argument_names.size(); ++j) { step.required_output.push_back(aggregate_descriptions[i].argument_names[j]); } } getActionsBeforeAggregation(select_query->select_expression_list, step.actions, only_types); if (select_query->having_expression) getActionsBeforeAggregation(select_query->having_expression, step.actions, only_types); if (select_query->order_expression_list) getActionsBeforeAggregation(select_query->order_expression_list, step.actions, only_types); } bool ExpressionAnalyzer::appendHaving(ExpressionActionsChain & chain, bool only_types) { assertAggregation(); if (!select_query->having_expression) return false; initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); step.required_output.push_back(select_query->having_expression->getColumnName()); getRootActions(select_query->having_expression, only_types, step.actions); return true; } void ExpressionAnalyzer::appendSelect(ExpressionActionsChain & chain, bool only_types) { assertSelect(); initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getRootActions(select_query->select_expression_list, only_types, step.actions); for (const auto & child : select_query->select_expression_list->children) step.required_output.push_back(child->getColumnName()); } bool ExpressionAnalyzer::appendOrderBy(ExpressionActionsChain & chain, bool only_types) { assertSelect(); if (!select_query->order_expression_list) return false; initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getRootActions(select_query->order_expression_list, only_types, step.actions); ASTs asts = select_query->order_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { ASTOrderByElement * ast = typeid_cast(asts[i].get()); if (!ast || ast->children.size() < 1) throw Exception("Bad order expression AST", ErrorCodes::UNKNOWN_TYPE_OF_AST_NODE); ASTPtr order_expression = ast->children.at(0); step.required_output.push_back(order_expression->getColumnName()); } return true; } bool ExpressionAnalyzer::appendLimitBy(ExpressionActionsChain & chain, bool only_types) { assertSelect(); if (!select_query->limit_by_expression_list) return false; initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getRootActions(select_query->limit_by_expression_list, only_types, step.actions); for (const auto & child : select_query->limit_by_expression_list->children) step.required_output.push_back(child->getColumnName()); return true; } void ExpressionAnalyzer::appendProjectResult(ExpressionActionsChain & chain) const { assertSelect(); initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); NamesWithAliases result_columns; ASTs asts = select_query->select_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { String result_name = asts[i]->getAliasOrColumnName(); if (required_result_columns.empty() || required_result_columns.count(result_name)) { result_columns.emplace_back(asts[i]->getColumnName(), result_name); step.required_output.push_back(result_columns.back().second); } } step.actions->add(ExpressionAction::project(result_columns)); } void ExpressionAnalyzer::appendExpression(ExpressionActionsChain & chain, const ASTPtr & expr, bool only_types) { initChain(chain, source_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getRootActions(expr, only_types, step.actions); step.required_output.push_back(expr->getColumnName()); } void ExpressionAnalyzer::getActionsBeforeAggregation(const ASTPtr & ast, ExpressionActionsPtr & actions, bool no_subqueries) { ASTFunction * node = typeid_cast(ast.get()); if (node && AggregateFunctionFactory::instance().isAggregateFunctionName(node->name)) for (auto & argument : node->arguments->children) getRootActions(argument, no_subqueries, actions); else for (auto & child : ast->children) getActionsBeforeAggregation(child, actions, no_subqueries); } ExpressionActionsPtr ExpressionAnalyzer::getActions(bool add_aliases, bool project_result) { ExpressionActionsPtr actions = std::make_shared(source_columns, context); NamesWithAliases result_columns; Names result_names; ASTs asts; if (auto node = typeid_cast(query.get())) asts = node->children; else asts = ASTs(1, query); for (size_t i = 0; i < asts.size(); ++i) { std::string name = asts[i]->getColumnName(); std::string alias; if (add_aliases) alias = asts[i]->getAliasOrColumnName(); else alias = name; result_columns.emplace_back(name, alias); result_names.push_back(alias); getRootActions(asts[i], false, actions); } if (add_aliases) { if (project_result) actions->add(ExpressionAction::project(result_columns)); else actions->add(ExpressionAction::addAliases(result_columns)); } if (!(add_aliases && project_result)) { /// We will not delete the original columns. for (const auto & column_name_type : source_columns) result_names.push_back(column_name_type.name); } actions->finalize(result_names); return actions; } ExpressionActionsPtr ExpressionAnalyzer::getConstActions() { ExpressionActionsPtr actions = std::make_shared(NamesAndTypesList(), context); getRootActions(query, true, actions, true); return actions; } void ExpressionAnalyzer::getAggregateInfo(Names & key_names, AggregateDescriptions & aggregates) const { for (const auto & name_and_type : aggregation_keys) key_names.emplace_back(name_and_type.name); aggregates = aggregate_descriptions; } void ExpressionAnalyzer::collectUsedColumns() { /** Calculate which columns are required to execute the expression. * Then, delete all other columns from the list of available columns. * After execution, columns will only contain the list of columns needed to read from the table. */ RequiredSourceColumnsVisitor::Data columns_context; RequiredSourceColumnsVisitor(columns_context).visit(query); NameSet required = columns_context.requiredColumns(); #if 0 std::cerr << "Query: " << query << std::endl; std::cerr << "CTX: " << columns_context << std::endl; std::cerr << "source_columns: "; for (const auto & name : source_columns) std::cerr << "'" << name.name << "' "; std::cerr << "required: "; for (const auto & name : required) std::cerr << "'" << name << "' "; std::cerr << std::endl; #endif if (columns_context.has_table_join) { const AnalyzedJoin & analyzed_join = analyzedJoin(); #if 0 std::cerr << "key_names_left: "; for (const auto & name : analyzed_join.key_names_left) std::cerr << "'" << name << "' "; std::cerr << "key_names_right: "; for (const auto & name : analyzed_join.key_names_right) std::cerr << "'" << name << "' "; std::cerr << "columns_from_joined_table: "; for (const auto & column : analyzed_join.columns_from_joined_table) std::cerr << "'" << column.name_and_type.name << '/' << column.original_name << "' "; std::cerr << "available_joined_columns: "; for (const auto & column : analyzed_join.available_joined_columns) std::cerr << "'" << column.name_and_type.name << '/' << column.original_name << "' "; std::cerr << std::endl; #endif NameSet avaliable_columns; for (const auto & name : source_columns) avaliable_columns.insert(name.name); /** You also need to ignore the identifiers of the columns that are obtained by JOIN. * (Do not assume that they are required for reading from the "left" table). */ columns_added_by_join.clear(); for (const auto & joined_column : analyzed_join.available_joined_columns) { auto & name = joined_column.name_and_type.name; if (required.count(name) && !avaliable_columns.count(name)) { columns_added_by_join.push_back(joined_column); required.erase(name); } } } if (columns_context.has_array_join) { /// Insert the columns required for the ARRAY JOIN calculation into the required columns list. NameSet array_join_sources; for (const auto & result_source : syntax->array_join_result_to_source) array_join_sources.insert(result_source.second); for (const auto & column_name_type : source_columns) if (array_join_sources.count(column_name_type.name)) required.insert(column_name_type.name); } /// You need to read at least one column to find the number of rows. if (select_query && required.empty()) required.insert(ExpressionActions::getSmallestColumn(source_columns)); NameSet unknown_required_source_columns = required; for (NamesAndTypesList::iterator it = source_columns.begin(); it != source_columns.end();) { const String & column_name = it->name; unknown_required_source_columns.erase(column_name); if (!required.count(column_name)) source_columns.erase(it++); else ++it; } /// If there are virtual columns among the unknown columns. Remove them from the list of unknown and add /// in columns list, so that when further processing they are also considered. if (storage) { for (auto it = unknown_required_source_columns.begin(); it != unknown_required_source_columns.end();) { if (storage->hasColumn(*it)) { source_columns.push_back(storage->getColumn(*it)); unknown_required_source_columns.erase(it++); } else ++it; } } if (!unknown_required_source_columns.empty()) { std::stringstream ss; ss << "query: '" << query << "' "; ss << columns_context; ss << "source_columns: "; for (const auto & name : source_columns) ss << "'" << name.name << "' "; throw Exception("Unknown identifier: " + *unknown_required_source_columns.begin() + (select_query && !select_query->tables ? ". Note that there are no tables (FROM clause) in your query" : "") + ", context: " + ss.str(), ErrorCodes::UNKNOWN_IDENTIFIER); } } }