#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { static std::string * GetAlias(ASTPtr & ast) { if (ASTFunction * node = dynamic_cast(&*ast)) { return &node->alias; } else if (ASTIdentifier * node = dynamic_cast(&*ast)) { return &node->alias; } else if (ASTLiteral * node = dynamic_cast(&*ast)) { return &node->alias; } else { return NULL; } } void ExpressionAnalyzer::init() { select_query = dynamic_cast(&*ast); has_aggregation = false; createAliasesDict(ast); /// Если есть агрегатные функции, присвоит has_aggregation=true. normalizeTree(); /// Найдем агрегатные функции. if (select_query && (select_query->group_expression_list || select_query->having_expression)) has_aggregation = true; ExpressionActions temp_actions(columns, settings); getAggregatesImpl(ast, temp_actions); if (has_aggregation) { assertSelect(); /// Найдем ключи агрегации. if (select_query->group_expression_list) { const ASTs & group_asts = select_query->group_expression_list->children; for (size_t i = 0; i < group_asts.size(); ++i) { getActionsImpl(group_asts[i], true, false, temp_actions); NameAndTypePair key; key.first = group_asts[i]->getColumnName(); key.second = temp_actions.getSampleBlock().getByName(key.first).type; aggregation_keys.push_back(key); } } aggregated_columns = aggregation_keys; for (size_t i = 0; i < aggregate_descriptions.size(); ++i) { AggregateDescription & desc = aggregate_descriptions[i]; aggregated_columns.push_back(NameAndTypePair(desc.column_name, desc.function->getReturnType())); } } else { aggregated_columns = columns; } } NamesAndTypesList::iterator ExpressionAnalyzer::findColumn(const String & name, NamesAndTypesList & cols) { NamesAndTypesList::iterator it; for (it = cols.begin(); it != cols.end(); ++it) if (it->first == name) break; return it; } void ExpressionAnalyzer::createAliasesDict(ASTPtr & ast) { /// Обход снизу-вверх. Не опускаемся в подзапросы. for (ASTs::iterator it = ast->children.begin(); it != ast->children.end(); ++it) if (!dynamic_cast(&**it)) createAliasesDict(*it); std::string * alias = GetAlias(ast); if (alias && !alias->empty()) { if (aliases.count(*alias) && ast->getTreeID() != aliases[*alias]->getTreeID()) { throw Exception("Different expressions with the same alias " + *alias, ErrorCodes::MULTIPLE_EXPRESSIONS_FOR_ALIAS); } else { aliases[*alias] = ast; } } } StoragePtr ExpressionAnalyzer::getTable() { if (const ASTSelectQuery * select = dynamic_cast(&*ast)) { if (select->table && !dynamic_cast(&*select->table)) { String database = select->database ? dynamic_cast(*select->database).name : ""; const String & table = dynamic_cast(*select->table).name; return context.tryGetTable(database, table); } } return StoragePtr(); } bool ExpressionAnalyzer::needSignRewrite() { if (settings.sign_rewrite && storage) { if (const StorageMergeTree * merge_tree = dynamic_cast(&*storage)) return merge_tree->getName() == "CollapsingMergeTree"; if (const StorageDistributed * distributed = dynamic_cast(&*storage)) return !distributed->getSignColumnName().empty(); } return false; } String ExpressionAnalyzer::getSignColumnName() { if (const StorageMergeTree * merge_tree = dynamic_cast(&*storage)) return merge_tree->getSignColumnName(); if (const StorageDistributed * distributed = dynamic_cast(&*storage)) return distributed->getSignColumnName(); return ""; } ASTPtr ExpressionAnalyzer::createSignColumn() { ASTIdentifier * p_sign_column = new ASTIdentifier(ast->range, sign_column_name); ASTIdentifier & sign_column = *p_sign_column; ASTPtr sign_column_node = p_sign_column; sign_column.name = sign_column_name; return sign_column_node; } ASTPtr ExpressionAnalyzer::rewriteCount(const ASTFunction * node) { /// 'Sign' ASTExpressionList * p_exp_list = new ASTExpressionList; ASTExpressionList & exp_list = *p_exp_list; ASTPtr exp_list_node = p_exp_list; exp_list.children.push_back(createSignColumn()); /// sum(Sign) ASTFunction * p_sum = new ASTFunction; ASTFunction & sum = *p_sum; ASTPtr sum_node = p_sum; sum.name = "sum"; sum.alias = node->alias; sum.arguments = exp_list_node; sum.children.push_back(exp_list_node); return sum_node; } ASTPtr ExpressionAnalyzer::rewriteSum(const ASTFunction * node) { /// 'x', 'Sign' ASTExpressionList * p_mult_exp_list = new ASTExpressionList; ASTExpressionList & mult_exp_list = *p_mult_exp_list; ASTPtr mult_exp_list_node = p_mult_exp_list; mult_exp_list.children.push_back(createSignColumn()); mult_exp_list.children.push_back(node->arguments->children[0]); /// x * Sign ASTFunction * p_mult = new ASTFunction; ASTFunction & mult = *p_mult; ASTPtr mult_node = p_mult; mult.name = "multiply"; mult.arguments = mult_exp_list_node; mult.children.push_back(mult_exp_list_node); /// 'x * Sign' ASTExpressionList * p_exp_list = new ASTExpressionList; ASTExpressionList & exp_list = *p_exp_list; ASTPtr exp_list_node = p_exp_list; exp_list.children.push_back(mult_node); /// sum(x * Sign) ASTFunction * p_sum = new ASTFunction; ASTFunction & sum = *p_sum; ASTPtr sum_node = p_sum; sum.name = "sum"; sum.alias = node->alias; sum.arguments = exp_list_node; sum.children.push_back(exp_list_node); return sum_node; } ASTPtr ExpressionAnalyzer::rewriteAvg(const ASTFunction * node) { /// node без alias для переписывания числителя и знаменателя ASTPtr node_clone = node->clone(); ASTFunction * node_clone_func = dynamic_cast(&*node_clone); node_clone_func->alias = ""; /// 'sum(Sign * x)', 'sum(Sign)' ASTExpressionList * p_div_exp_list = new ASTExpressionList; ASTExpressionList & div_exp_list = *p_div_exp_list; ASTPtr div_exp_list_node = p_div_exp_list; div_exp_list.children.push_back(rewriteSum(node_clone_func)); div_exp_list.children.push_back(rewriteCount(node_clone_func)); /// sum(Sign * x) / sum(Sign) ASTFunction * p_div = new ASTFunction; ASTFunction & div = *p_div; ASTPtr div_node = p_div; div.name = "divide"; div.alias = node->alias; div.arguments = div_exp_list_node; div.children.push_back(div_exp_list_node); return div_node; } void ExpressionAnalyzer::considerSignRewrite(ASTPtr & ast) { ASTFunction * node = dynamic_cast(&*ast); if (!node) return; const String & name = node->name; if (name == "count") ast = rewriteCount(node); if (name == "sum") ast = rewriteSum(node); if (name == "avg") ast = rewriteAvg(node); } void ExpressionAnalyzer::normalizeTree() { SetOfASTs tmp_set; MapOfASTs tmp_map; if (needSignRewrite()) sign_column_name = getSignColumnName(); normalizeTreeImpl(ast, tmp_map, tmp_set); } /// finished_asts - уже обработанные вершины (и на что они заменены) /// current_asts - вершины в текущем стеке вызовов этого метода void ExpressionAnalyzer::normalizeTreeImpl(ASTPtr & ast, MapOfASTs & finished_asts, SetOfASTs & current_asts) { if (current_asts.count(ast)) { throw Exception("Cyclic aliases", ErrorCodes::CYCLIC_ALIASES); } if (finished_asts.count(ast)) { ast = finished_asts[ast]; return; } ASTPtr initial_ast = ast; current_asts.insert(initial_ast); /// Действия, выполняемые сверху вниз. if (!sign_column_name.empty()) considerSignRewrite(ast); if (ASTIdentifier * node = dynamic_cast(&*ast)) { if (node->kind == ASTIdentifier::Column) { /// Если это алиас Aliases::const_iterator jt = aliases.find(node->name); if (jt != aliases.end()) { /// Заменим его на соответствующий узел дерева ast = jt->second; normalizeTreeImpl(ast, finished_asts, current_asts); } else { /// Проверим имеет ли смысл sign-rewrite if (node->name == sign_column_name) throw Exception("Requested Sign column while sign-rewrite is on.", ErrorCodes::QUERY_SECTION_DOESNT_MAKE_SENSE); if (findColumn(node->name) == columns.end()) throw Exception("Unknown identifier: " + node->name, ErrorCodes::UNKNOWN_IDENTIFIER); } } } else if (ASTExpressionList * node = dynamic_cast(&*ast)) { /// Заменим * на список столбцов. ASTs & asts = node->children; for (int i = static_cast(asts.size()) - 1; i >= 0; --i) { if (ASTAsterisk * asterisk = dynamic_cast(&*asts[i])) { ASTs all_columns; for (NamesAndTypesList::const_iterator it = columns.begin(); it != columns.end(); ++it) all_columns.push_back(new ASTIdentifier(asterisk->range, it->first)); asts.erase(asts.begin() + i); asts.insert(asts.begin() + i, all_columns.begin(), all_columns.end()); } } } /// Рекурсивные вызовы. Не опускаемся в подзапросы. for (ASTs::iterator it = ast->children.begin(); it != ast->children.end(); ++it) if (!dynamic_cast(&**it)) normalizeTreeImpl(*it, finished_asts, current_asts); /// Действия, выполняемые снизу вверх. /// Если секция WHERE или HAVING состоит из одного алиаса, ссылку нужно заменить не только в children, но и в where_expression и having_expression. if (ASTSelectQuery * select = dynamic_cast(&*ast)) { if (select->where_expression) normalizeTreeImpl(select->where_expression, finished_asts, current_asts); if (select->having_expression) normalizeTreeImpl(select->having_expression, finished_asts, current_asts); } if (ASTFunction * node = dynamic_cast(&*ast)) { if (node->name == "lambda") { node->kind = ASTFunction::LAMBDA_EXPRESSION; } else if (context.getAggregateFunctionFactory().isAggregateFunctionName(node->name)) { node->kind = ASTFunction::AGGREGATE_FUNCTION; } else if (node->name == "arrayJoin") { node->kind = ASTFunction::ARRAY_JOIN; } else { node->kind = ASTFunction::FUNCTION; } } current_asts.erase(initial_ast); current_asts.erase(ast); finished_asts[initial_ast] = ast; } void ExpressionAnalyzer::makeSet(ASTFunction * node, ExpressionActions & actions) { /** Нужно преобразовать правый аргумент в множество. * Это может быть перечисление значений или подзапрос. * Перечисление значений парсится как функция tuple. */ IAST & args = *node->arguments; ASTPtr & arg = args.children[1]; if (dynamic_cast(&*arg)) { /// Исполняем подзапрос, превращаем результат в множество, и кладём это множество на место подзапроса. InterpreterSelectQuery interpreter(arg->children[0], context, QueryProcessingStage::Complete, subquery_depth + 1); ASTSet * ast_set = new ASTSet(arg->getColumnName()); ast_set->set = new Set; ast_set->set->create(interpreter.execute()); arg = ast_set; } else if (ASTFunction * set_func = dynamic_cast(&*arg)) { /// Случай явного перечисления значений. if (set_func->name != "tuple") throw Exception("Incorrect type of 2nd argument for function " + node->name + ". Must be subquery or set of values.", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT); DataTypes set_element_types; ASTPtr & left_arg = args.children[0]; ASTFunction * left_arg_tuple = dynamic_cast(&*left_arg); if (left_arg_tuple && left_arg_tuple->name == "tuple") { for (ASTs::const_iterator it = left_arg_tuple->arguments->children.begin(); it != left_arg_tuple->arguments->children.end(); ++it) set_element_types.push_back(actions.getSampleBlock().getByName((*it)->getColumnName()).type); } else { DataTypePtr left_type = actions.getSampleBlock().getByName(left_arg->getColumnName()).type; if (DataTypeArray * array_type = dynamic_cast(&*left_type)) set_element_types.push_back(array_type->getNestedType()); else set_element_types.push_back(left_type); } ASTSet * ast_set = new ASTSet(arg->getColumnName()); ast_set->set = new Set; ast_set->set->create(set_element_types, set_func->arguments); arg = ast_set; } else if (!dynamic_cast(&*arg)) throw Exception("Incorrect type of 2nd argument for function " + node->name + ". Must be subquery or set of values.", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT); } static std::string getUniqueName(const Block & block, const std::string & prefix) { int i = 1; while (block.has(prefix + Poco::NumberFormatter::format(i))) ++i; return prefix + Poco::NumberFormatter::format(i); } void ExpressionAnalyzer::getActionsImpl(ASTPtr ast, bool no_subqueries, bool only_consts, ExpressionActions & actions) { /// Если результат вычисления уже есть в блоке. if ((dynamic_cast(&*ast) || dynamic_cast(&*ast) || dynamic_cast(&*ast)) && actions.getSampleBlock().has(ast->getColumnName())) return; if (ASTFunction * node = dynamic_cast(&*ast)) { if (node->kind == ASTFunction::LAMBDA_EXPRESSION) throw Exception("Unexpected expression", ErrorCodes::UNEXPECTED_EXPRESSION); if (node->kind == ASTFunction::ARRAY_JOIN) { if (node->arguments->children.size() != 1) throw Exception("arrayJoin requires exactly 1 argument", ErrorCodes::TYPE_MISMATCH); ASTPtr arg = node->arguments->children[0]; getActionsImpl(arg, no_subqueries, only_consts, actions); if (!only_consts) actions.add(ExpressionActions::Action::arrayJoin(arg->getColumnName(), node->getColumnName())); return; } if (node->kind == ASTFunction::FUNCTION) { if (node->name == "in" || node->name == "notIn") { if (!no_subqueries) { /// Найдем тип первого аргумента (потом getActionsImpl вызовется для него снова и ни на что не повлияет). getActionsImpl(node->arguments->children[0], no_subqueries, only_consts, actions); /// Превратим tuple или подзапрос в множество. makeSet(node, actions); } else { /// Мы в той части дерева, которую не собираемся вычислять. Нужно только определить типы. /// Не будем выполнять подзапросы и составлять множества. Вставим произвольный столбец правильного типа. ColumnWithNameAndType fake_column; fake_column.name = node->getColumnName(); fake_column.type = new DataTypeUInt8; fake_column.column = new ColumnConstUInt8(1, 0); actions.add(ExpressionActions::Action::addColumn(fake_column)); getActionsImpl(node->arguments, no_subqueries, only_consts, actions); return; } } FunctionPtr function = context.getFunctionFactory().get(node->name, context); Names argument_names; DataTypes argument_types; /// Если у функции есть аргумент-лямбда-выражение, нужно определить его тип до рекурсивного вызова. bool has_lambda_arguments = false; for (size_t i = 0; i < node->arguments->children.size(); ++i) { ASTPtr child = node->arguments->children[i]; ASTFunction * lambda = dynamic_cast(&*child); if (lambda && lambda->name == "lambda") { /// Если аргумент лямбда-функция, только запомним ее примерный тип. if (lambda->arguments->children.size() != 2) throw Exception("lambda requires two arguments", ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH); ASTFunction * lambda_args_tuple = dynamic_cast(&*lambda->arguments->children[0]); if (!lambda_args_tuple || lambda_args_tuple->name != "tuple") throw Exception("First argument of lambda must be a tuple", ErrorCodes::TYPE_MISMATCH); has_lambda_arguments = true; argument_types.push_back(new DataTypeExpression(DataTypes(lambda_args_tuple->arguments->children.size()))); /// Не можем дать название child->getColumnName(), /// потому что оно не однозначно определяет выражение (типы аргументов могут быть разными). argument_names.push_back(getUniqueName(actions.getSampleBlock(), "__lambda")); } else { /// Если аргумент не лямбда-функция, вызовемся рекурсивно и узнаем его тип. getActionsImpl(child, no_subqueries, only_consts, actions); std::string name = child->getColumnName(); argument_types.push_back(actions.getSampleBlock().getByName(name).type); argument_names.push_back(name); } } if (has_lambda_arguments && !only_consts) { function->getLambdaArgumentTypes(argument_types); /// Вызовемся рекурсивно для лямбда-выражений. for (size_t i = 0; i < node->arguments->children.size(); ++i) { ASTPtr child = node->arguments->children[i]; ASTFunction * lambda = dynamic_cast(&*child); if (lambda && lambda->name == "lambda") { DataTypeExpression * lambda_type = dynamic_cast(&*argument_types[i]); ASTFunction * lambda_args_tuple = dynamic_cast(&*lambda->arguments->children[0]); ASTs lambda_arg_asts = lambda_args_tuple->arguments->children; NamesAndTypes lambda_args; NamesAndTypesList lambda_columns = actions.getRequiredColumnsWithTypes(); for (size_t j = 0; j < lambda_arg_asts.size(); ++j) { ASTIdentifier * identifier = dynamic_cast(&*lambda_arg_asts[j]); if (!identifier) throw Exception("lambda argument declarations must be identifiers", ErrorCodes::TYPE_MISMATCH); String arg_name = identifier->name; NameAndTypePair arg(arg_name, lambda_type->getArgumentTypes()[j]); NamesAndTypesList::iterator it = findColumn(arg_name, lambda_columns); if (it != lambda_columns.end()) it->second = arg.second; else lambda_columns.push_back(arg); lambda_args.push_back(arg); } ExpressionActionsPtr lambda_actions = new ExpressionActions(lambda_columns, settings); getActionsImpl(lambda->arguments->children[1], no_subqueries, only_consts, *lambda_actions); String result_name = lambda->arguments->children[1]->getColumnName(); lambda_actions->finalize(Names(1, result_name)); DataTypePtr result_type = lambda_actions->getSampleBlock().getByName(result_name).type; ColumnWithNameAndType lambda_column; lambda_column.column = new ColumnExpression(1, lambda_actions, lambda_args, result_type, result_name); lambda_column.type = argument_types[i]; lambda_column.name = argument_names[i]; actions.add(ExpressionActions::Action::addColumn(lambda_column)); } } } bool should_add = true; if (only_consts) { for (size_t i = 0; i < argument_names.size(); ++i) { if (!actions.getSampleBlock().has(argument_names[i])) { should_add = false; break; } } } if (should_add) actions.add(ExpressionActions::Action::applyFunction(function, argument_names, node->getColumnName())); } } else if (ASTLiteral * node = dynamic_cast(&*ast)) { DataTypePtr type = apply_visitor(FieldToDataType(), node->value); ColumnWithNameAndType column; column.column = type->createConstColumn(1, node->value); column.type = type; column.name = node->getColumnName(); actions.add(ExpressionActions::Action::addColumn(column)); } else if (ASTSet * node = dynamic_cast(&*ast)) { /// Множество в секции IN. ColumnWithNameAndType column; column.column = new ColumnSet(1, node->set); column.type = new DataTypeSet; column.name = node->getColumnName(); actions.add(ExpressionActions::Action::addColumn(column)); } else { for (ASTs::iterator it = ast->children.begin(); it != ast->children.end(); ++it) getActionsImpl(*it, no_subqueries, only_consts, actions); } } void ExpressionAnalyzer::getAggregatesImpl(ASTPtr ast, ExpressionActions & actions) { ASTFunction * node = dynamic_cast(&*ast); if (node && node->kind == ASTFunction::AGGREGATE_FUNCTION) { has_aggregation = true; AggregateDescription aggregate; aggregate.column_name = node->getColumnName(); for (size_t i = 0; i < aggregate_descriptions.size(); ++i) if (aggregate_descriptions[i].column_name == aggregate.column_name) return; ASTs & arguments = node->arguments->children; aggregate.argument_names.resize(arguments.size()); DataTypes types(arguments.size()); for (size_t i = 0; i < arguments.size(); ++i) { getActionsImpl(arguments[i], true, false, actions); const std::string & name = arguments[i]->getColumnName(); types[i] = actions.getSampleBlock().getByName(name).type; aggregate.argument_names[i] = name; } aggregate.function = context.getAggregateFunctionFactory().get(node->name, types); if (node->parameters) { ASTs & parameters = dynamic_cast(*node->parameters).children; Row params_row(parameters.size()); for (size_t i = 0; i < parameters.size(); ++i) { ASTLiteral * lit = dynamic_cast(&*parameters[i]); if (!lit) throw Exception("Parameters to aggregate functions must be literals", ErrorCodes::PARAMETERS_TO_AGGREGATE_FUNCTIONS_MUST_BE_LITERALS); params_row[i] = lit->value; } aggregate.function->setParameters(params_row); } aggregate.function->setArguments(types); if (!sign_column_name.empty()) considerSignRewrite(ast); aggregate_descriptions.push_back(aggregate); } else { for (size_t i = 0; i < ast->children.size(); ++i) { getAggregatesImpl(ast->children[i], actions); } } } void ExpressionAnalyzer::assertSelect() { if (!select_query) throw Exception("Not a select query", ErrorCodes::LOGICAL_ERROR); } void ExpressionAnalyzer::assertAggregation() { if (!has_aggregation) throw Exception("No aggregation", ErrorCodes::LOGICAL_ERROR); } void ExpressionAnalyzer::initChain(ExpressionActionsChain & chain, NamesAndTypesList & columns) { if (chain.steps.empty()) { chain.settings = settings; chain.steps.push_back(ExpressionActionsChain::Step(new ExpressionActions(columns, settings))); } } bool ExpressionAnalyzer::appendWhere(ExpressionActionsChain & chain) { assertSelect(); if (!select_query->where_expression) return false; initChain(chain, columns); ExpressionActionsChain::Step & step = chain.steps.back(); step.required_output.push_back(select_query->where_expression->getColumnName()); getActionsImpl(select_query->where_expression, false, false, *step.actions); return true; } bool ExpressionAnalyzer::appendGroupBy(ExpressionActionsChain & chain) { assertAggregation(); if (!select_query->group_expression_list) return false; initChain(chain, 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()); getActionsImpl(asts[i], false, false, *step.actions); } return true; } void ExpressionAnalyzer::appendAggregateFunctionsArguments(ExpressionActionsChain & chain) { assertAggregation(); initChain(chain, 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]); } } getActionsBeforeAggregationImpl(select_query->select_expression_list, *step.actions); if (select_query->having_expression) getActionsBeforeAggregationImpl(select_query->having_expression, *step.actions); if (select_query->order_expression_list) getActionsBeforeAggregationImpl(select_query->order_expression_list, *step.actions); } bool ExpressionAnalyzer::appendHaving(ExpressionActionsChain & chain) { 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()); getActionsImpl(select_query->having_expression, false, false, *step.actions); return true; } void ExpressionAnalyzer::appendSelect(ExpressionActionsChain & chain) { assertSelect(); initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getActionsImpl(select_query->select_expression_list, false, false, *step.actions); ASTs asts = select_query->select_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { step.required_output.push_back(asts[i]->getColumnName()); } } bool ExpressionAnalyzer::appendOrderBy(ExpressionActionsChain & chain) { assertSelect(); if (!select_query->order_expression_list) return false; initChain(chain, aggregated_columns); ExpressionActionsChain::Step & step = chain.steps.back(); getActionsImpl(select_query->order_expression_list, false, false, *step.actions); ASTs asts = select_query->order_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { ASTOrderByElement * ast = dynamic_cast(&*asts[i]); if (!ast || ast->children.size() != 1) throw Exception("Bad order expression AST", ErrorCodes::UNKNOWN_TYPE_OF_AST_NODE); ASTPtr order_expression = ast->children[0]; step.required_output.push_back(order_expression->getColumnName()); } return true; } void ExpressionAnalyzer::appendProjectResult(DB::ExpressionActionsChain & chain) { 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) { result_columns.push_back(NameWithAlias(asts[i]->getColumnName(), asts[i]->getAlias())); step.required_output.push_back(result_columns.back().second); } step.actions->add(ExpressionActions::Action::project(result_columns)); } Block ExpressionAnalyzer::getSelectSampleBlock() { assertSelect(); ExpressionActions temp_actions(aggregated_columns, settings); NamesWithAliases result_columns; ASTs asts = select_query->select_expression_list->children; for (size_t i = 0; i < asts.size(); ++i) { result_columns.push_back(NameWithAlias(asts[i]->getColumnName(), asts[i]->getAlias())); getActionsImpl(asts[i], true, false, temp_actions); } temp_actions.add(ExpressionActions::Action::project(result_columns)); return temp_actions.getSampleBlock(); } void ExpressionAnalyzer::getActionsBeforeAggregationImpl(ASTPtr ast, ExpressionActions & actions) { ASTFunction * node = dynamic_cast(&*ast); if (node && node->kind == ASTFunction::AGGREGATE_FUNCTION) { ASTs & arguments = node->arguments->children; for (size_t i = 0; i < arguments.size(); ++i) { getActionsImpl(arguments[i], false, false, actions); } } else { for (size_t i = 0; i < ast->children.size(); ++i) { getActionsBeforeAggregationImpl(ast->children[i], actions); } } } ExpressionActionsPtr ExpressionAnalyzer::getActions() { ExpressionActionsPtr actions = new ExpressionActions(columns, settings); NamesWithAliases result_columns; Names result_names; if (ASTExpressionList * node = dynamic_cast(&*ast)) { ASTs asts = node->children; for (size_t i = 0; i < asts.size(); ++i) { result_columns.push_back(NameWithAlias(asts[i]->getColumnName(), asts[i]->getAlias())); result_names.push_back(result_columns.back().first); getActionsImpl(asts[i], false, false, *actions); } } else { result_columns.push_back(NameWithAlias(ast->getColumnName(), ast->getAlias())); result_names.push_back(result_columns.back().first); getActionsImpl(ast, false, false, *actions); } actions->add(ExpressionActions::Action::project(result_columns)); actions->finalize(result_names); return actions; } ExpressionActionsPtr ExpressionAnalyzer::getConstActions() { if (has_aggregation) throw Exception("Expression has aggregation", ErrorCodes::LOGICAL_ERROR); ExpressionActionsPtr actions = new ExpressionActions(NamesAndTypesList(), settings); getActionsImpl(ast, true, true, *actions); return actions; } void ExpressionAnalyzer::getAggregateInfo(Names & key_names, AggregateDescriptions & aggregates) { for (NamesAndTypesList::iterator it = aggregation_keys.begin(); it != aggregation_keys.end(); ++it) key_names.push_back(it->first); aggregates = aggregate_descriptions; } Names ExpressionAnalyzer::getRequiredColumns() { NamesSet required; NamesSet ignored; getRequiredColumnsImpl(ast, required, ignored); Names res(required.begin(), required.end()); return res; } void ExpressionAnalyzer::getRequiredColumnsImpl(ASTPtr ast, NamesSet & required_columns, NamesSet & ignored_names) { if (ASTIdentifier * node = dynamic_cast(&*ast)) { if (node->kind == ASTIdentifier::Column && !ignored_names.count(node->name)) required_columns.insert(node->name); return; } if (ASTFunction * node = dynamic_cast(&*ast)) { if (node->kind == ASTFunction::LAMBDA_EXPRESSION) { if (node->arguments->children.size() != 2) throw Exception("lambda requires two arguments", ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH); ASTFunction * lambda_args_tuple = dynamic_cast(&*node->arguments->children[0]); if (!lambda_args_tuple || lambda_args_tuple->name != "tuple") throw Exception("First argument of lambda must be a tuple", ErrorCodes::TYPE_MISMATCH); /// Не нужно добавлять параметры лямбда-выражения в required_columns. Names added_ignored; for (size_t i = 0 ; i < lambda_args_tuple->children.size(); ++i) { ASTIdentifier * identifier = dynamic_cast(&*lambda_args_tuple->children[i]); if (!identifier) throw Exception("lambda argument declarations must be identifiers", ErrorCodes::TYPE_MISMATCH); std::string name = identifier->name; if (!ignored_names.count(name)) { ignored_names.insert(name); added_ignored.push_back(name); } } getRequiredColumnsImpl(node->arguments->children[1], required_columns, ignored_names); for (size_t i = 0; i < added_ignored.size(); ++i) ignored_names.erase(added_ignored[i]); return; } } for (size_t i = 0; i < ast->children.size(); ++i) getRequiredColumnsImpl(ast->children[i], required_columns, ignored_names); } }