#pragma once #include #include #include namespace DB { class Context; class ExpressionActions; struct ExpressionActionsChain; class Join; using JoinPtr = std::shared_ptr; class IAST; using ASTPtr = std::shared_ptr; class Set; using SetPtr = std::shared_ptr; using PreparedSets = std::unordered_map; class IBlockInputStream; using BlockInputStreamPtr = std::shared_ptr; class IStorage; using StoragePtr = std::shared_ptr; using Tables = std::map; class ASTFunction; class ASTExpressionList; class ASTSelectQuery; /** Information on what to do when executing a subquery in the [GLOBAL] IN/JOIN section. */ struct SubqueryForSet { /// The source is obtained using the InterpreterSelectQuery subquery. BlockInputStreamPtr source; Block source_sample; /// If set, build it from result. SetPtr set; JoinPtr join; /// If set, put the result into the table. /// This is a temporary table for transferring to remote servers for distributed query processing. StoragePtr table; }; /// ID of subquery -> what to do with it. using SubqueriesForSets = std::unordered_map; /** 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 : private boost::noncopyable { private: using ExpressionActionsPtr = std::shared_ptr; public: ExpressionAnalyzer( const ASTPtr & ast_, const Context & context_, const StoragePtr & storage_, const NamesAndTypesList & columns_, size_t subquery_depth_ = 0, bool do_global_ = false); /// Does the expression have aggregate functions or a GROUP BY or HAVING section. bool hasAggregation() const { return has_aggregation; } /// Get a list of aggregation keys and descriptions of aggregate functions if the query contains GROUP BY. void getAggregateInfo(Names & key_names, AggregateDescriptions & aggregates) const; /** Get a set of columns that are enough to read from the table to evaluate the expression. * Columns added from another table by JOIN are not counted. */ Names getRequiredColumns() 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); 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); void appendSelect(ExpressionActionsChain & chain, bool only_types); bool appendOrderBy(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; /// If `ast` is not a SELECT query, just gets all the actions to evaluate the expression. /// If project_result, only the calculated values in the desired order, renamed to aliases, remain in the output block. /// Otherwise, only temporary columns will be deleted from the block. ExpressionActionsPtr getActions(bool project_result); /// 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. */ SubqueriesForSets getSubqueriesForSets() const { return subqueries_for_sets; } PreparedSets getPreparedSets() { return prepared_sets; } /** Tables that will need to be sent to remote servers for distributed query processing. */ const Tables & getExternalTables() const { return external_tables; } /// If ast is a SELECT query, it gets the aliases and column types from the SELECT section. Block getSelectSampleBlock(); /// Create Set-s that we can from IN section to use the index on them. void makeSetsForIndex(); private: ASTPtr ast; ASTSelectQuery * select_query; const Context & context; Settings settings; size_t subquery_depth; /// Columns that are mentioned in the expression, but were not specified in the constructor. NameSet unknown_required_columns; /** Original columns. * First, all available columns of the table are placed here. Then (when parsing the query), unused columns are deleted. */ NamesAndTypesList columns; /// Columns after ARRAY JOIN, JOIN, and/or aggregation. NamesAndTypesList aggregated_columns; /// The table from which the query is made. const StoragePtr storage; bool has_aggregation = false; NamesAndTypesList aggregation_keys; AggregateDescriptions aggregate_descriptions; SubqueriesForSets subqueries_for_sets; PreparedSets prepared_sets; /// NOTE: So far, only one JOIN per query is supported. /** Query of the form `SELECT expr(x) AS FROM t1 ANY LEFT JOIN (SELECT expr(x) AS k FROM t2) USING k` * The join is made by column k. * During the JOIN, * - in the "right" table, it will be available by alias `k`, since `Project` action for the subquery was executed. * - in the "left" table, it will be accessible by the name `expr(x)`, since `Project` action has not been executed yet. * You must remember both of these options. */ Names join_key_names_left; Names join_key_names_right; NamesAndTypesList columns_added_by_join; using Aliases = std::unordered_map; Aliases aliases; using SetOfASTs = std::set; using MapOfASTs = std::map; /// Which column is needed to be ARRAY-JOIN'ed to get the specified. /// For example, for `SELECT s.v ... ARRAY JOIN a AS s` will get "s.v" -> "a.v". NameToNameMap array_join_result_to_source; /// For the ARRAY JOIN section, mapping from the alias to the full column name. /// For example, for `ARRAY JOIN [1,2] AS b` "b" -> "array(1,2)" will enter here. NameToNameMap array_join_alias_to_name; /// The backward mapping for array_join_alias_to_name. NameToNameMap array_join_name_to_alias; /// Do I need to prepare for execution global subqueries when analyzing the query. bool do_global; /// All new temporary tables obtained by performing the GLOBAL IN/JOIN subqueries. Tables external_tables; size_t external_table_id = 1; void init(); static NamesAndTypesList::iterator findColumn(const String & name, NamesAndTypesList & cols); NamesAndTypesList::iterator findColumn(const String & name) { return findColumn(name, columns); } /** Remove all unnecessary columns from the list of all available columns of the table (`columns`). * At the same time, form a set of unknown columns (`unknown_required_columns`), * as well as the columns added by JOIN (`columns_added_by_join`). */ void collectUsedColumns(); /** Find the columns that are obtained by JOIN. */ void collectJoinedColumns(NameSet & joined_columns, NamesAndTypesList & joined_columns_name_type); /** Create a dictionary of aliases. */ void addASTAliases(ASTPtr & ast, int ignore_levels = 0); /** For star nodes(`*`), expand them to a list of all columns. * For literal nodes, substitute aliases. */ void normalizeTree(); void normalizeTreeImpl(ASTPtr & ast, MapOfASTs & finished_asts, SetOfASTs & current_asts, std::string current_alias, size_t level); /// Eliminates injective function calls and constant expressions from group by statement void optimizeGroupBy(); /// Remove duplicate items from ORDER BY. void optimizeOrderBy(); void optimizeLimitBy(); /// remove Function_if AST if condition is constant void optimizeIfWithConstantCondition(); void optimizeIfWithConstantConditionImpl(ASTPtr & current_ast, Aliases & aliases) const; bool tryExtractConstValueFromCondition(const ASTPtr & condition, bool & value) const; void makeSet(const ASTFunction * node, const Block & sample_block); /// Adds a list of ALIAS columns from the table void addAliasColumns(); /// Replacing scalar subqueries with constant values. void executeScalarSubqueries(); void executeScalarSubqueriesImpl(ASTPtr & ast); /// Find global subqueries in the GLOBAL IN/JOIN sections. Fills in external_tables. void initGlobalSubqueriesAndExternalTables(); void initGlobalSubqueries(ASTPtr & ast); /// Finds in the query the usage of external tables (as table identifiers). Fills in external_tables. void findExternalTables(ASTPtr & ast); /** Initialize InterpreterSelectQuery for a subquery in the GLOBAL IN/JOIN section, * create a temporary table of type Memory and store it in the external_tables dictionary. */ void addExternalStorage(ASTPtr & subquery_or_table_name); void getArrayJoinedColumns(); void getArrayJoinedColumnsImpl(const ASTPtr & ast); void addMultipleArrayJoinAction(ExpressionActionsPtr & actions) const; void addJoinAction(ExpressionActionsPtr & actions, bool only_types) const; struct ScopeStack; void getActionsImpl(const ASTPtr & ast, bool no_subqueries, bool only_consts, ScopeStack & actions_stack); void getRootActions(const ASTPtr & ast, bool no_subqueries, bool only_consts, ExpressionActionsPtr & actions); void getActionsBeforeAggregation(const ASTPtr & ast, ExpressionActionsPtr & actions, bool no_subqueries); /** 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(); void getAggregates(const ASTPtr & ast, ExpressionActionsPtr & actions); void assertNoAggregates(const ASTPtr & ast, const char * description); /** Get a set of necessary columns to read from the table. * In this case, the columns specified in ignored_names are considered unnecessary. And the ignored_names parameter can be modified. * The set of columns available_joined_columns are the columns available from JOIN, they are not needed for reading from the main table. * Put in required_joined_columns the set of columns available from JOIN and needed. */ void getRequiredColumnsImpl(const ASTPtr & ast, const NameSet & available_columns, NameSet & required_columns, NameSet & ignored_names, const NameSet & available_joined_columns, NameSet & required_joined_columns); /// Get the table from which the query is made StoragePtr getTable(); /// columns - the columns that are present before the transformations begin. void initChain(ExpressionActionsChain & chain, const NamesAndTypesList & columns) const; void assertSelect() const; void assertAggregation() const; /** Create Set from an explicit enumeration of values in the query. * If create_ordered_set = true - create a data structure suitable for using the index. */ void makeExplicitSet(const ASTFunction * node, const Block & sample_block, bool create_ordered_set); void makeSetsForIndexImpl(const ASTPtr & node, const Block & sample_block); /** Translate qualified names such as db.table.column, table.column, table_alias.column * to unqualified names. This is done in a poor transitional way: * only one ("main") table is supported. Ambiguity is not detected or resolved. */ void translateQualifiedNames(); void translateQualifiedNamesImpl(ASTPtr & node, const String & database_name, const String & table_name, const String & alias); }; }