#pragma once #include #include #include #include #include #include #include #include #include #include namespace DB { class Block; class Context; struct ExpressionActionsChain; class ExpressionActions; using ExpressionActionsPtr = std::shared_ptr; using ManyExpressionActions = std::vector; struct ASTTableJoin; class IJoin; using JoinPtr = std::shared_ptr; class ASTFunction; class ASTExpressionList; class ASTSelectQuery; struct ASTTablesInSelectQueryElement; /// Create columns in block or return false if not possible bool sanitizeBlock(Block & block); /// ExpressionAnalyzer sources, intermediates and results. It splits data and logic, allows to test them separately. struct ExpressionAnalyzerData { SubqueriesForSets subqueries_for_sets; PreparedSets prepared_sets; /// Columns after ARRAY JOIN, JOIN, and/or aggregation. NamesAndTypesList aggregated_columns; NamesAndTypesList array_join_columns; bool has_aggregation = false; NamesAndTypesList aggregation_keys; AggregateDescriptions aggregate_descriptions; bool has_global_subqueries = false; /// All new temporary tables obtained by performing the GLOBAL IN/JOIN subqueries. TemporaryTablesMapping external_tables; }; /** Transforms an expression from a syntax tree into a sequence of actions to execute it. * * NOTE: if `ast` is a SELECT query from a table, the structure of this table should not change during the lifetime of ExpressionAnalyzer. */ class ExpressionAnalyzer : protected ExpressionAnalyzerData, private boost::noncopyable { private: /// Extracts settings to enlight which are used (and avoid copy of others). struct ExtractedSettings { const bool use_index_for_in_with_subqueries; const SizeLimits size_limits_for_set; ExtractedSettings(const Settings & settings_) : use_index_for_in_with_subqueries(settings_.use_index_for_in_with_subqueries), size_limits_for_set(settings_.max_rows_in_set, settings_.max_bytes_in_set, settings_.set_overflow_mode) {} }; public: /// Ctor for non-select queries. Generally its usage is: /// auto actions = ExpressionAnalyzer(query, syntax, context).getActions(); ExpressionAnalyzer( const ASTPtr & query_, const SyntaxAnalyzerResultPtr & syntax_analyzer_result_, const Context & context_) : ExpressionAnalyzer(query_, syntax_analyzer_result_, context_, 0, false) {} void appendExpression(ExpressionActionsChain & chain, const ASTPtr & expr, bool only_types); /// If `ast` is not a SELECT query, just gets all the actions to evaluate the expression. /// If add_aliases, only the calculated values in the desired order and add aliases. /// If also project_result, than only aliases remain in the output block. /// Otherwise, only temporary columns will be deleted from the block. ExpressionActionsPtr getActions(bool add_aliases, bool project_result = true); /// Actions that can be performed on an empty block: adding constants and applying functions that depend only on constants. /// Does not execute subqueries. ExpressionActionsPtr getConstActions(); /** Sets that require a subquery to be create. * Only the sets needed to perform actions returned from already executed `append*` or `getActions`. * That is, you need to call getSetsWithSubqueries after all calls of `append*` or `getActions` * and create all the returned sets before performing the actions. */ const SubqueriesForSets & getSubqueriesForSets() const { return subqueries_for_sets; } /// Get intermediates for tests const ExpressionAnalyzerData & getAnalyzedData() const { return *this; } protected: ExpressionAnalyzer( const ASTPtr & query_, const SyntaxAnalyzerResultPtr & syntax_analyzer_result_, const Context & context_, size_t subquery_depth_, bool do_global_); ASTPtr query; const Context & context; const ExtractedSettings settings; size_t subquery_depth; SyntaxAnalyzerResultPtr syntax; const ConstStoragePtr & storage() const { return syntax->storage; } /// The main table in FROM clause, if exists. const AnalyzedJoin & analyzedJoin() const { return *syntax->analyzed_join; } const NamesAndTypesList & sourceColumns() const { return syntax->required_source_columns; } const std::vector & aggregates() const { return syntax->aggregates; } NamesAndTypesList sourceWithJoinedColumns() const; /// Find global subqueries in the GLOBAL IN/JOIN sections. Fills in external_tables. void initGlobalSubqueriesAndExternalTables(bool do_global); void addMultipleArrayJoinAction(ExpressionActionsPtr & actions, bool is_left) const; void addJoinAction(ExpressionActionsPtr & actions, JoinPtr = {}) const; void getRootActions(const ASTPtr & ast, bool no_subqueries, ExpressionActionsPtr & actions, bool only_consts = false); /** Similar to getRootActions but do not make sets when analyzing IN functions. It's used in * analyzeAggregation which happens earlier than analyzing PREWHERE and WHERE. If we did, the * prepared sets would not be applicable for MergeTree index optimization. */ void getRootActionsNoMakeSet(const ASTPtr & ast, bool no_subqueries, ExpressionActionsPtr & actions, bool only_consts = false); /** Add aggregation keys to aggregation_keys, aggregate functions to aggregate_descriptions, * Create a set of columns aggregated_columns resulting after the aggregation, if any, * or after all the actions that are normally performed before aggregation. * Set has_aggregation = true if there is GROUP BY or at least one aggregate function. */ void analyzeAggregation(); bool makeAggregateDescriptions(ExpressionActionsPtr & actions); /// columns - the columns that are present before the transformations begin. void initChain(ExpressionActionsChain & chain, const NamesAndTypesList & columns) const; const ASTSelectQuery * getSelectQuery() const; bool isRemoteStorage() const; }; class SelectQueryExpressionAnalyzer; /// Result of SelectQueryExpressionAnalyzer: expressions for InterpreterSelectQuery struct ExpressionAnalysisResult { /// Do I need to perform the first part of the pipeline - running on remote servers during distributed processing. bool first_stage = false; /// Do I need to execute the second part of the pipeline - running on the initiating server during distributed processing. bool second_stage = false; bool need_aggregate = false; bool has_order_by = false; bool remove_where_filter = false; bool optimize_read_in_order = false; ExpressionActionsPtr before_join; /// including JOIN ExpressionActionsPtr before_where; ExpressionActionsPtr before_aggregation; ExpressionActionsPtr before_having; ExpressionActionsPtr before_order_and_select; ExpressionActionsPtr before_limit_by; ExpressionActionsPtr final_projection; /// Columns from the SELECT list, before renaming them to aliases. Names selected_columns; /// Columns will be removed after prewhere actions execution. Names columns_to_remove_after_prewhere; PrewhereInfoPtr prewhere_info; FilterInfoPtr filter_info; ConstantFilterDescription prewhere_constant_filter_description; ConstantFilterDescription where_constant_filter_description; /// Actions by every element of ORDER BY ManyExpressionActions order_by_elements_actions; ExpressionAnalysisResult() = default; ExpressionAnalysisResult( SelectQueryExpressionAnalyzer & query_analyzer, bool first_stage, bool second_stage, bool only_types, const FilterInfoPtr & filter_info, const Block & source_header); bool hasFilter() const { return filter_info.get(); } bool hasJoin() const { return before_join.get(); } bool hasPrewhere() const { return prewhere_info.get(); } bool hasWhere() const { return before_where.get(); } bool hasHaving() const { return before_having.get(); } bool hasLimitBy() const { return before_limit_by.get(); } void removeExtraColumns(); void checkActions(); void finalize(const ExpressionActionsChain & chain, const Context & context, size_t where_step_num); }; /// SelectQuery specific ExpressionAnalyzer part. class SelectQueryExpressionAnalyzer : public ExpressionAnalyzer { public: friend struct ExpressionAnalysisResult; SelectQueryExpressionAnalyzer( const ASTPtr & query_, const SyntaxAnalyzerResultPtr & syntax_analyzer_result_, const Context & context_, const NameSet & required_result_columns_ = {}, bool do_global_ = false, const SelectQueryOptions & options_ = {}) : ExpressionAnalyzer(query_, syntax_analyzer_result_, context_, options_.subquery_depth, do_global_) , required_result_columns(required_result_columns_), query_options(options_) { } /// Does the expression have aggregate functions or a GROUP BY or HAVING section. bool hasAggregation() const { return has_aggregation; } bool hasGlobalSubqueries() { return has_global_subqueries; } const NamesAndTypesList & aggregationKeys() const { return aggregation_keys; } const AggregateDescriptions & aggregates() const { return aggregate_descriptions; } /// Create Set-s that we make from IN section to use index on them. void makeSetsForIndex(const ASTPtr & node); const PreparedSets & getPreparedSets() const { return prepared_sets; } /// Tables that will need to be sent to remote servers for distributed query processing. const TemporaryTablesMapping & getExternalTables() const { return external_tables; } ExpressionActionsPtr simpleSelectActions(); /// These appends are public only for tests void appendSelect(ExpressionActionsChain & chain, bool only_types); /// Deletes all columns except mentioned by SELECT, arranges the remaining columns and renames them to aliases. void appendProjectResult(ExpressionActionsChain & chain) const; private: /// If non-empty, ignore all expressions not from this list. NameSet required_result_columns; SelectQueryOptions query_options; /** * Create Set from a subquery or a table expression in the query. The created set is suitable for using the index. * The set will not be created if its size hits the limit. */ void tryMakeSetForIndexFromSubquery(const ASTPtr & subquery_or_table_name); /** * Checks if subquery is not a plain StorageSet. * Because while making set we will read data from StorageSet which is not allowed. * Returns valid SetPtr from StorageSet if the latter is used after IN or nullptr otherwise. */ SetPtr isPlainStorageSetInSubquery(const ASTPtr & subquery_or_table_name); JoinPtr makeTableJoin(const ASTTablesInSelectQueryElement & join_element); void makeSubqueryForJoin(const ASTTablesInSelectQueryElement & join_element, NamesWithAliases && required_columns_with_aliases, SubqueryForSet & subquery_for_set) const; const ASTSelectQuery * getAggregatingQuery() const; /** These methods allow you to build a chain of transformations over a block, that receives values in the desired sections of the query. * * Example usage: * ExpressionActionsChain chain; * analyzer.appendWhere(chain); * chain.addStep(); * analyzer.appendSelect(chain); * analyzer.appendOrderBy(chain); * chain.finalize(); * * If only_types = true set, does not execute subqueries in the relevant parts of the query. The actions got this way * shouldn't be executed, they are only needed to get a list of columns with their types. */ /// Before aggregation: bool appendArrayJoin(ExpressionActionsChain & chain, bool only_types); bool appendJoin(ExpressionActionsChain & chain, bool only_types); /// Add preliminary rows filtration. Actions are created in other expression analyzer to prevent any possible alias injection. void appendPreliminaryFilter(ExpressionActionsChain & chain, ExpressionActionsPtr actions, String column_name); /// remove_filter is set in ExpressionActionsChain::finalize(); /// Columns in `additional_required_columns` will not be removed (they can be used for e.g. sampling or FINAL modifier). bool appendPrewhere(ExpressionActionsChain & chain, bool only_types, const Names & additional_required_columns); bool appendWhere(ExpressionActionsChain & chain, bool only_types); bool appendGroupBy(ExpressionActionsChain & chain, bool only_types); void appendAggregateFunctionsArguments(ExpressionActionsChain & chain, bool only_types); /// After aggregation: bool appendHaving(ExpressionActionsChain & chain, bool only_types); /// appendSelect bool appendOrderBy(ExpressionActionsChain & chain, bool only_types, bool optimize_read_in_order, ManyExpressionActions &); bool appendLimitBy(ExpressionActionsChain & chain, bool only_types); /// appendProjectResult }; }