/* Copyright (c) 2002, 2010, Oracle and/or its affiliates. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 of the License. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /** @file @brief subselect Item @todo - add function from mysql_select that use JOIN* as parameter to JOIN methods (sql_select.h/sql_select.cc) */ #ifdef USE_PRAGMA_IMPLEMENTATION #pragma implementation // gcc: Class implementation #endif #include "mysql_priv.h" #include "sql_select.h" double get_post_group_estimate(JOIN* join, double join_op_rows); Item_subselect::Item_subselect(): Item_result_field(), value_assigned(0), own_engine(0), thd(0), old_engine(0), used_tables_cache(0), have_to_be_excluded(0), const_item_cache(1), inside_first_fix_fields(0), done_first_fix_fields(FALSE), expr_cache(0), forced_const(FALSE), substitution(0), engine(0), eliminated(FALSE), engine_changed(0), changed(0), is_correlated(FALSE) { DBUG_ENTER("Item_subselect::Item_subselect"); DBUG_PRINT("enter", ("this: 0x%lx", (ulong) this)); #ifndef DBUG_OFF exec_counter= 0; #endif with_subselect= 1; reset(); /* Item value is NULL if select_result_interceptor didn't change this value (i.e. some rows will be found returned) */ null_value= TRUE; DBUG_VOID_RETURN; } void Item_subselect::init(st_select_lex *select_lex, select_result_interceptor *result) { /* Please see Item_singlerow_subselect::invalidate_and_restore_select_lex(), which depends on alterations to the parse tree implemented here. */ DBUG_ENTER("Item_subselect::init"); DBUG_PRINT("enter", ("select_lex: 0x%lx this: 0x%lx", (ulong) select_lex, (ulong) this)); unit= select_lex->master_unit(); thd= unit->thd; if (unit->item) { /* Item can be changed in JOIN::prepare while engine in JOIN::optimize => we do not copy old_engine here */ engine= unit->item->engine; own_engine= FALSE; parsing_place= unit->item->parsing_place; thd->change_item_tree((Item**)&unit->item, this); engine->change_result(this, result, TRUE); } else { SELECT_LEX *outer_select= unit->outer_select(); /* do not take into account expression inside aggregate functions because they can access original table fields */ parsing_place= (outer_select->in_sum_expr ? NO_MATTER : outer_select->parsing_place); if (unit->is_union()) engine= new subselect_union_engine(thd, unit, result, this); else engine= new subselect_single_select_engine(thd, select_lex, result, this); } { SELECT_LEX *upper= unit->outer_select(); if (upper->parsing_place == IN_HAVING) upper->subquery_in_having= 1; /* The subquery is an expression cache candidate */ upper->expr_cache_may_be_used[upper->parsing_place]= TRUE; } DBUG_PRINT("info", ("engine: 0x%lx", (ulong)engine)); DBUG_VOID_RETURN; } st_select_lex * Item_subselect::get_select_lex() { return unit->first_select(); } void Item_subselect::cleanup() { DBUG_ENTER("Item_subselect::cleanup"); Item_result_field::cleanup(); if (old_engine) { if (engine) engine->cleanup(); engine= old_engine; old_engine= 0; } if (engine) engine->cleanup(); reset(); value_assigned= 0; expr_cache= 0; forced_const= FALSE; DBUG_PRINT("info", ("exec_counter: %d", exec_counter)); #ifndef DBUG_OFF exec_counter= 0; #endif DBUG_VOID_RETURN; } void Item_singlerow_subselect::cleanup() { DBUG_ENTER("Item_singlerow_subselect::cleanup"); value= 0; row= 0; Item_subselect::cleanup(); DBUG_VOID_RETURN; } void Item_in_subselect::cleanup() { DBUG_ENTER("Item_in_subselect::cleanup"); if (left_expr_cache) { left_expr_cache->delete_elements(); delete left_expr_cache; left_expr_cache= NULL; } /* TODO: This breaks the commented assert in add_strategy(). in_strategy&= ~SUBS_STRATEGY_CHOSEN; */ first_execution= TRUE; pushed_cond_guards= NULL; Item_subselect::cleanup(); DBUG_VOID_RETURN; } void Item_allany_subselect::cleanup() { /* The MAX/MIN transformation through injection is reverted through the change_item_tree() mechanism. Revert the select_lex object of the query to its initial state. */ for (SELECT_LEX *sl= unit->first_select(); sl; sl= sl->next_select()) if (test_strategy(SUBS_MAXMIN_INJECTED)) sl->with_sum_func= false; Item_in_subselect::cleanup(); } Item_subselect::~Item_subselect() { DBUG_ENTER("Item_subselect::~Item_subselect"); DBUG_PRINT("enter", ("this: 0x%lx", (ulong) this)); if (own_engine) delete engine; else engine->cleanup(); engine= NULL; DBUG_VOID_RETURN; } bool Item_subselect::select_transformer(JOIN *join) { DBUG_ENTER("Item_subselect::select_transformer"); DBUG_RETURN(false); } bool Item_subselect::fix_fields(THD *thd_param, Item **ref) { char const *save_where= thd_param->where; uint8 uncacheable; bool res; DBUG_ASSERT(fixed == 0); /* There is no reason to get a different THD. */ DBUG_ASSERT(thd == thd_param); if (!done_first_fix_fields) { done_first_fix_fields= TRUE; inside_first_fix_fields= TRUE; upper_refs.empty(); /* psergey-todo: remove _first_fix_fields calls, we need changes on every execution */ } eliminated= FALSE; parent_select= thd_param->lex->current_select; if (check_stack_overrun(thd, STACK_MIN_SIZE, (uchar*)&res)) return TRUE; if (!(res= engine->prepare())) { // all transformation is done (used by prepared statements) changed= 1; inside_first_fix_fields= FALSE; /* Substitute the current item with an Item_in_optimizer that was created by Item_in_subselect::select_in_like_transformer and call fix_fields for the substituted item which in turn calls engine->prepare for the subquery predicate. */ if (substitution) { /* If the top item of the WHERE/HAVING condition changed, set correct WHERE/HAVING for PS. */ if (unit->outer_select()->where == (*ref)) unit->outer_select()->where= substitution; else if (unit->outer_select()->having == (*ref)) unit->outer_select()->having= substitution; (*ref)= substitution; substitution->name= name; if (have_to_be_excluded) engine->exclude(); substitution= 0; thd->where= "checking transformed subquery"; if (!(*ref)->fixed) res= (*ref)->fix_fields(thd, ref); goto end; } // Is it one field subselect? if (engine->cols() > max_columns) { my_error(ER_OPERAND_COLUMNS, MYF(0), 1); goto end; } fix_length_and_dec(); } else goto end; if ((uncacheable= engine->uncacheable())) { const_item_cache= 0; if (uncacheable & UNCACHEABLE_RAND) used_tables_cache|= RAND_TABLE_BIT; } fixed= 1; end: done_first_fix_fields= FALSE; inside_first_fix_fields= FALSE; thd->where= save_where; return res; } bool Item_subselect::enumerate_field_refs_processor(uchar *arg) { List_iterator it(upper_refs); Ref_to_outside *upper; while ((upper= it++)) { if (upper->item->walk(&Item::enumerate_field_refs_processor, FALSE, arg)) return TRUE; } return FALSE; } bool Item_subselect::mark_as_eliminated_processor(uchar *arg) { eliminated= TRUE; return FALSE; } /** Remove a subselect item from its unit so that the unit no longer represents a subquery. @param arg unused parameter @return FALSE to force the evaluation of the processor for the subsequent items. */ bool Item_subselect::eliminate_subselect_processor(uchar *arg) { unit->item= NULL; unit->exclude_from_tree(); eliminated= TRUE; return FALSE; } /** Adjust the master select of the subquery to be the fake_select which represents the whole UNION right above the subquery, instead of the last query of the UNION. @param arg pointer to the fake select @return FALSE to force the evaluation of the processor for the subsequent items. */ bool Item_subselect::set_fake_select_as_master_processor(uchar *arg) { SELECT_LEX *fake_select= (SELECT_LEX*) arg; /* Move the st_select_lex_unit of a subquery from a global ORDER BY clause to become a direct child of the fake_select of a UNION. In this way the ORDER BY that is applied to the temporary table that contains the result of the whole UNION, and all columns in the subquery are resolved against this table. The transformation is applied only for immediate child subqueries of a UNION query. */ if (unit->outer_select()->master_unit()->fake_select_lex == fake_select) { /* Set the master of the subquery to be the fake select (i.e. the whole UNION), instead of the last query in the UNION. */ fake_select->add_slave(unit); DBUG_ASSERT(unit->outer_select() == fake_select); /* Adjust the name resolution context hierarchy accordingly. */ for (SELECT_LEX *sl= unit->first_select(); sl; sl= sl->next_select()) sl->context.outer_context= &(fake_select->context); /* Undo Item_subselect::eliminate_subselect_processor because at that phase we don't know yet that the ORDER clause will be moved to the fake select. */ unit->item= this; eliminated= FALSE; } return FALSE; } bool Item_subselect::mark_as_dependent(THD *thd, st_select_lex *select, Item *item) { if (inside_first_fix_fields) { is_correlated= TRUE; Ref_to_outside *upper; if (!(upper= new (thd->stmt_arena->mem_root) Ref_to_outside())) return TRUE; upper->select= select; upper->item= item; if (upper_refs.push_back(upper, thd->stmt_arena->mem_root)) return TRUE; } return FALSE; } /* Adjust attributes after our parent select has been merged into grandparent DESCRIPTION Subquery is a composite object which may be correlated, that is, it may have 1. references to tables of the parent select (i.e. one that has the clause with the subquery predicate) 2. references to tables of the grandparent select 3. references to tables of further ancestors. Before the pullout, this item indicates: - #1 with table bits in used_tables() - #2 and #3 with OUTER_REF_TABLE_BIT. After parent has been merged with grandparent: - references to parent and grandparent tables should be indicated with table bits. - references to greatgrandparent and further ancestors - with OUTER_REF_TABLE_BIT. */ void Item_subselect::fix_after_pullout(st_select_lex *new_parent, Item **ref) { recalc_used_tables(new_parent, TRUE); parent_select= new_parent; } class Field_fixer: public Field_enumerator { public: table_map used_tables; /* Collect used_tables here */ st_select_lex *new_parent; /* Select we're in */ virtual void visit_field(Item_field *item) { //for (TABLE_LIST *tbl= new_parent->leaf_tables; tbl; tbl= tbl->next_local) //{ // if (tbl->table == field->table) // { used_tables|= item->field->table->map; // return; // } //} //used_tables |= OUTER_REF_TABLE_BIT; } }; /* Recalculate used_tables_cache */ void Item_subselect::recalc_used_tables(st_select_lex *new_parent, bool after_pullout) { List_iterator it(upper_refs); Ref_to_outside *upper; used_tables_cache= 0; while ((upper= it++)) { bool found= FALSE; /* Check if 1. the upper reference refers to the new immediate parent select, or 2. one of the further ancestors. We rely on the fact that the tree of selects is modified by some kind of 'flattening', i.e. a process where child selects are merged into their parents. The merged selects are removed from the select tree but keep pointers to their parents. */ for (st_select_lex *sel= upper->select; sel; sel= sel->outer_select()) { /* If we've reached the new parent select by walking upwards from reference's original select, this means that the reference is now referring to the direct parent: */ if (sel == new_parent) { found= TRUE; /* upper->item may be NULL when we've referred to a grouping function, in which case we don't care about what it's table_map really is, because item->with_sum_func==1 will ensure correct placement of the item. */ if (upper->item) { // Now, iterate over fields and collect used_tables() attribute: Field_fixer fixer; fixer.used_tables= 0; fixer.new_parent= new_parent; upper->item->walk(&Item::enumerate_field_refs_processor, FALSE, (uchar*)&fixer); used_tables_cache |= fixer.used_tables; upper->item->walk(&Item::update_table_bitmaps_processor, FALSE, NULL); /* if (after_pullout) upper->item->fix_after_pullout(new_parent, &(upper->item)); upper->item->update_used_tables(); */ } } } if (!found) used_tables_cache|= OUTER_REF_TABLE_BIT; } /* Don't update const_tables_cache yet as we don't yet know which of the parent's tables are constant. Parent will call update_used_tables() after he has done const table detection, and that will be our chance to update const_tables_cache. */ } bool Item_subselect::walk(Item_processor processor, bool walk_subquery, uchar *argument) { if (!(unit->uncacheable & ~UNCACHEABLE_DEPENDENT) && engine->is_executed() && !unit->describe) { /* The subquery has already been executed (for real, it wasn't EXPLAIN's fake execution) so it should not matter what it has inside. The actual reason for not walking inside is that parts of the subquery (e.g. JTBM join nests and their IN-equality conditions may have been invalidated by irreversible cleanups (those happen after an uncorrelated subquery has been executed). */ return (this->*processor)(argument); } if (walk_subquery) { for (SELECT_LEX *lex= unit->first_select(); lex; lex= lex->next_select()) { List_iterator li(lex->item_list); Item *item; ORDER *order; if (lex->where && (lex->where)->walk(processor, walk_subquery, argument)) return 1; if (lex->having && (lex->having)->walk(processor, walk_subquery, argument)) return 1; /* TODO: why does this walk WHERE/HAVING but not ON expressions of outer joins? */ while ((item=li++)) { if (item->walk(processor, walk_subquery, argument)) return 1; } for (order= lex->order_list.first ; order; order= order->next) { if ((*order->item)->walk(processor, walk_subquery, argument)) return 1; } for (order= lex->group_list.first ; order; order= order->next) { if ((*order->item)->walk(processor, walk_subquery, argument)) return 1; } } } return (this->*processor)(argument); } bool Item_subselect::exec() { int res; /* Do not execute subselect in case of a fatal error or if the query has been killed. */ if (thd->is_error() || thd->killed) return 1; DBUG_ASSERT(!thd->lex->context_analysis_only); /* Simulate a failure in sub-query execution. Used to test e.g. out of memory or query being killed conditions. */ DBUG_EXECUTE_IF("subselect_exec_fail", return 1;); res= engine->exec(); #ifndef DBUG_OFF ++exec_counter; #endif if (engine_changed) { engine_changed= 0; return exec(); } return (res); } void Item_subselect::get_cache_parameters(List ¶meters) { Collect_deps_prm prm= {¶meters, unit->first_select()->nest_level_base, unit->first_select()->nest_level}; walk(&Item::collect_outer_ref_processor, TRUE, (uchar*)&prm); } int Item_in_subselect::optimize(double *out_rows, double *cost) { int res; DBUG_ENTER("Item_in_subselect::optimize"); SELECT_LEX *save_select= thd->lex->current_select; JOIN *join= unit->first_select()->join; thd->lex->current_select= join->select_lex; if ((res= join->optimize())) DBUG_RETURN(res); /* Calculate #rows and cost of join execution */ join->get_partial_cost_and_fanout(join->table_count - join->const_tables, table_map(-1), cost, out_rows); /* Adjust join output cardinality. There can be these cases: - Have no GROUP BY and no aggregate funcs: we won't get into this function because such join will be processed as a merged semi-join (TODO: does it really mean we don't need to handle such cases here at all? put ASSERT) - Have no GROUP BY but have aggregate funcs: output is 1 record. - Have GROUP BY and have (or not) aggregate funcs: need to adjust output cardinality. */ thd->lex->current_select= save_select; if (!join->group_list && !join->group_optimized_away && join->tmp_table_param.sum_func_count) { DBUG_PRINT("info",("Materialized join will have only 1 row (it has " "aggregates but no GROUP BY")); *out_rows= 1; } /* Now with grouping */ if (join->group_list) { DBUG_PRINT("info",("Materialized join has grouping, trying to estimate it")); double output_rows= get_post_group_estimate(join, *out_rows); DBUG_PRINT("info",("Got value of %g", output_rows)); *out_rows= output_rows; } DBUG_RETURN(res); } /** Check if an expression cache is needed for this subquery @param thd Thread handle @details The function checks whether a cache is needed for a subquery and whether the result of the subquery can be put in cache. @retval TRUE cache is needed @retval FALSE otherwise */ bool Item_subselect::expr_cache_is_needed(THD *thd) { return ((engine->uncacheable() & UNCACHEABLE_DEPENDENT) && engine->cols() == 1 && optimizer_flag(thd, OPTIMIZER_SWITCH_SUBQUERY_CACHE) && !(engine->uncacheable() & (UNCACHEABLE_RAND | UNCACHEABLE_SIDEEFFECT))); } /** Check if an expression cache is needed for this subquery @param thd Thread handle @details The function checks whether a cache is needed for a subquery and whether the result of the subquery can be put in cache. @note This method allows many columns in the subquery because it is supported by Item_in optimizer and result of the IN subquery will be scalar in this case. @retval TRUE cache is needed @retval FALSE otherwise */ bool Item_in_subselect::expr_cache_is_needed(THD *thd) { return (optimizer_flag(thd, OPTIMIZER_SWITCH_SUBQUERY_CACHE) && !(engine->uncacheable() & (UNCACHEABLE_RAND | UNCACHEABLE_SIDEEFFECT))); } /* Compute the IN predicate if the left operand's cache changed. */ bool Item_in_subselect::exec() { DBUG_ENTER("Item_in_subselect::exec"); /* Initialize the cache of the left predicate operand. This has to be done as late as now, because Cached_item directly contains a resolved field (not an item, and in some cases (when temp tables are created), these fields end up pointing to the wrong field. One solution is to change Cached_item to not resolve its field upon creation, but to resolve it dynamically from a given Item_ref object. TODO: the cache should be applied conditionally based on: - rules - e.g. only if the left operand is known to be ordered, and/or - on a cost-based basis, that takes into account the cost of a cache lookup, the cache hit rate, and the savings per cache hit. */ if (!left_expr_cache && (test_strategy(SUBS_MATERIALIZATION))) init_left_expr_cache(); /* If the new left operand is already in the cache, reuse the old result. Use the cached result only if this is not the first execution of IN because the cache is not valid for the first execution. */ if (!first_execution && left_expr_cache && test_if_item_cache_changed(*left_expr_cache) < 0) DBUG_RETURN(FALSE); /* The exec() method below updates item::value, and item::null_value, thus if we don't call it, the next call to item::val_int() will return whatever result was computed by its previous call. */ DBUG_RETURN(Item_subselect::exec()); } Item::Type Item_subselect::type() const { return SUBSELECT_ITEM; } void Item_subselect::fix_length_and_dec() { engine->fix_length_and_dec(0); } table_map Item_subselect::used_tables() const { return (table_map) (engine->uncacheable() ? used_tables_cache : 0L); } bool Item_subselect::const_item() const { return thd->lex->context_analysis_only ? FALSE : const_item_cache; } Item *Item_subselect::get_tmp_table_item(THD *thd_arg) { if (!with_sum_func && !const_item()) return new Item_field(result_field); return copy_or_same(thd_arg); } void Item_subselect::update_used_tables() { if (!forced_const) { recalc_used_tables(parent_select, FALSE); if (!engine->uncacheable()) { // did all used tables become static? if (!(used_tables_cache & ~engine->upper_select_const_tables())) const_item_cache= 1; } } } void Item_subselect::print(String *str, enum_query_type query_type) { if (engine) { str->append('('); engine->print(str, query_type); str->append(')'); } else str->append("(...)"); } Item_singlerow_subselect::Item_singlerow_subselect(st_select_lex *select_lex) :Item_subselect(), value(0) { DBUG_ENTER("Item_singlerow_subselect::Item_singlerow_subselect"); init(select_lex, new select_singlerow_subselect(this)); maybe_null= 1; max_columns= UINT_MAX; DBUG_VOID_RETURN; } st_select_lex * Item_singlerow_subselect::invalidate_and_restore_select_lex() { DBUG_ENTER("Item_singlerow_subselect::invalidate_and_restore_select_lex"); st_select_lex *result= get_select_lex(); DBUG_ASSERT(result); /* This code restore the parse tree in it's state before the execution of Item_singlerow_subselect::Item_singlerow_subselect(), and in particular decouples this object from the SELECT_LEX, so that the SELECT_LEX can be used with a different flavor or Item_subselect instead, as part of query rewriting. */ unit->item= NULL; DBUG_RETURN(result); } Item_maxmin_subselect::Item_maxmin_subselect(THD *thd_param, Item_subselect *parent, st_select_lex *select_lex, bool max_arg) :Item_singlerow_subselect(), was_values(TRUE) { DBUG_ENTER("Item_maxmin_subselect::Item_maxmin_subselect"); max= max_arg; init(select_lex, new select_max_min_finder_subselect(this, max_arg, parent->substype() == Item_subselect::ALL_SUBS)); max_columns= 1; maybe_null= 1; max_columns= 1; /* Following information was collected during performing fix_fields() of Items belonged to subquery, which will be not repeated */ used_tables_cache= parent->get_used_tables_cache(); const_item_cache= parent->const_item(); /* this subquery always creates during preparation, so we can assign thd here */ thd= thd_param; DBUG_VOID_RETURN; } void Item_maxmin_subselect::cleanup() { DBUG_ENTER("Item_maxmin_subselect::cleanup"); Item_singlerow_subselect::cleanup(); /* By default it is TRUE to avoid TRUE reporting by Item_func_not_all/Item_func_nop_all if this item was never called. Engine exec() set it to FALSE by reset_value_registration() call. select_max_min_finder_subselect::send_data() set it back to TRUE if some value will be found. */ was_values= TRUE; DBUG_VOID_RETURN; } void Item_maxmin_subselect::print(String *str, enum_query_type query_type) { str->append(max?"":"", 5); Item_singlerow_subselect::print(str, query_type); } void Item_singlerow_subselect::reset() { Item_subselect::reset(); if (value) { for(uint i= 0; i < engine->cols(); i++) row[i]->set_null(); } } /** @todo - We cant change name of Item_field or Item_ref, because it will prevent it's correct resolving, but we should save name of removed item => we do not make optimization if top item of list is field or reference. - switch off this optimization for prepare statement, because we do not rollback this changes. Make rollback for it, or special name resolving mode in 5.0. @param join Join object of the subquery (i.e. 'child' join). @retval false The subquery was transformed */ bool Item_singlerow_subselect::select_transformer(JOIN *join) { DBUG_ENTER("Item_singlerow_subselect::select_transformer"); if (changed) DBUG_RETURN(false); SELECT_LEX *select_lex= join->select_lex; Query_arena *arena= thd->stmt_arena; if (!select_lex->master_unit()->is_union() && !select_lex->table_list.elements && select_lex->item_list.elements == 1 && !select_lex->item_list.head()->with_sum_func && /* We cant change name of Item_field or Item_ref, because it will prevent it's correct resolving, but we should save name of removed item => we do not make optimization if top item of list is field or reference. TODO: solve above problem */ !(select_lex->item_list.head()->type() == FIELD_ITEM || select_lex->item_list.head()->type() == REF_ITEM) && !join->conds && !join->having && /* switch off this optimization for prepare statement, because we do not rollback this changes TODO: make rollback for it, or special name resolving mode in 5.0. */ !arena->is_stmt_prepare_or_first_sp_execute() ) { have_to_be_excluded= 1; if (thd->lex->describe) { char warn_buff[MYSQL_ERRMSG_SIZE]; sprintf(warn_buff, ER(ER_SELECT_REDUCED), select_lex->select_number); push_warning(thd, MYSQL_ERROR::WARN_LEVEL_NOTE, ER_SELECT_REDUCED, warn_buff); } substitution= select_lex->item_list.head(); /* as far as we moved content to upper level, field which depend of 'upper' select is not really dependent => we remove this dependence */ substitution->walk(&Item::remove_dependence_processor, 0, (uchar *) select_lex->outer_select()); } DBUG_RETURN(false); } void Item_singlerow_subselect::store(uint i, Item *item) { row[i]->store(item); row[i]->cache_value(); } enum Item_result Item_singlerow_subselect::result_type() const { return engine->type(); } /* Don't rely on the result type to calculate field type. Ask the engine instead. */ enum_field_types Item_singlerow_subselect::field_type() const { return engine->field_type(); } void Item_singlerow_subselect::fix_length_and_dec() { if ((max_columns= engine->cols()) == 1) { engine->fix_length_and_dec(row= &value); } else { if (!(row= (Item_cache**) sql_alloc(sizeof(Item_cache*)*max_columns))) return; engine->fix_length_and_dec(row); value= *row; } unsigned_flag= value->unsigned_flag; /* If there are not tables in subquery then ability to have NULL value depends on SELECT list (if single row subquery have tables then it always can be NULL if there are not records fetched). */ if (engine->no_tables()) maybe_null= engine->may_be_null(); else { for (uint i= 0; i < max_columns; i++) row[i]->maybe_null= TRUE; } } /** Add an expression cache for this subquery if it is needed @param thd_arg Thread handle @details The function checks whether an expression cache is needed for this item and if if so wraps the item into an item of the class Item_exp_cache_wrapper with an appropriate expression cache set up there. @note used from Item::transform() @return new wrapper item if an expression cache is needed, this item - otherwise */ Item* Item_singlerow_subselect::expr_cache_insert_transformer(uchar *thd_arg) { THD *thd= (THD*) thd_arg; DBUG_ENTER("Item_singlerow_subselect::expr_cache_insert_transformer"); if (expr_cache) DBUG_RETURN(expr_cache); if (expr_cache_is_needed(thd) && (expr_cache= set_expr_cache(thd))) DBUG_RETURN(expr_cache); DBUG_RETURN(this); } uint Item_singlerow_subselect::cols() { return engine->cols(); } bool Item_singlerow_subselect::check_cols(uint c) { if (c != engine->cols()) { my_error(ER_OPERAND_COLUMNS, MYF(0), c); return 1; } return 0; } bool Item_singlerow_subselect::null_inside() { for (uint i= 0; i < max_columns ; i++) { if (row[i]->null_value) return 1; } return 0; } void Item_singlerow_subselect::bring_value() { if (!exec() && assigned()) null_value= 0; else reset(); } double Item_singlerow_subselect::val_real() { DBUG_ASSERT(fixed == 1); if (!exec() && !value->null_value) { null_value= FALSE; return value->val_real(); } else { reset(); return 0; } } longlong Item_singlerow_subselect::val_int() { DBUG_ASSERT(fixed == 1); if (!exec() && !value->null_value) { null_value= FALSE; return value->val_int(); } else { reset(); return 0; } } String *Item_singlerow_subselect::val_str(String *str) { if (!exec() && !value->null_value) { null_value= FALSE; return value->val_str(str); } else { reset(); return 0; } } my_decimal *Item_singlerow_subselect::val_decimal(my_decimal *decimal_value) { if (!exec() && !value->null_value) { null_value= FALSE; return value->val_decimal(decimal_value); } else { reset(); return 0; } } bool Item_singlerow_subselect::val_bool() { if (!exec() && !value->null_value) { null_value= FALSE; return value->val_bool(); } else { reset(); return 0; } } Item_exists_subselect::Item_exists_subselect(st_select_lex *select_lex): Item_subselect() { DBUG_ENTER("Item_exists_subselect::Item_exists_subselect"); bool val_bool(); init(select_lex, new select_exists_subselect(this)); max_columns= UINT_MAX; null_value= FALSE; //can't be NULL maybe_null= 0; //can't be NULL value= 0; DBUG_VOID_RETURN; } void Item_exists_subselect::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("exists")); Item_subselect::print(str, query_type); } bool Item_in_subselect::test_limit(st_select_lex_unit *unit_arg) { if (unit_arg->fake_select_lex && unit_arg->fake_select_lex->test_limit()) return(1); SELECT_LEX *sl= unit_arg->first_select(); for (; sl; sl= sl->next_select()) { if (sl->test_limit()) return(1); } return(0); } Item_in_subselect::Item_in_subselect(Item * left_exp, st_select_lex *select_lex): Item_exists_subselect(), left_expr_cache(0), first_execution(TRUE), in_strategy(SUBS_NOT_TRANSFORMED), optimizer(0), pushed_cond_guards(NULL), emb_on_expr_nest(NULL), is_jtbm_merged(FALSE), is_flattenable_semijoin(FALSE), is_registered_semijoin(FALSE), upper_item(0) { DBUG_ENTER("Item_in_subselect::Item_in_subselect"); left_expr= left_exp; func= &eq_creator; init(select_lex, new select_exists_subselect(this)); max_columns= UINT_MAX; maybe_null= 1; abort_on_null= 0; reset(); //if test_limit will fail then error will be reported to client test_limit(select_lex->master_unit()); DBUG_VOID_RETURN; } int Item_in_subselect::get_identifier() { return engine->get_identifier(); } Item_allany_subselect::Item_allany_subselect(Item * left_exp, chooser_compare_func_creator fc, st_select_lex *select_lex, bool all_arg) :Item_in_subselect(), func_creator(fc), all(all_arg) { DBUG_ENTER("Item_allany_subselect::Item_allany_subselect"); left_expr= left_exp; func= func_creator(all_arg); init(select_lex, new select_exists_subselect(this)); max_columns= 1; abort_on_null= 0; reset(); //if test_limit will fail then error will be reported to client test_limit(select_lex->master_unit()); DBUG_VOID_RETURN; } /** Initialize length and decimals for EXISTS and inherited (IN/ALL/ANY) subqueries */ void Item_exists_subselect::init_length_and_dec() { decimals= 0; max_length= 1; max_columns= engine->cols(); } void Item_exists_subselect::fix_length_and_dec() { DBUG_ENTER("Item_exists_subselect::fix_length_and_dec"); init_length_and_dec(); /* We need only 1 row to determine existence (i.e. any EXISTS that is not an IN always requires LIMIT 1) */ unit->global_parameters->select_limit= new Item_int((int32) 1); DBUG_PRINT("info", ("Set limit to 1")); DBUG_VOID_RETURN; } void Item_in_subselect::fix_length_and_dec() { DBUG_ENTER("Item_in_subselect::fix_length_and_dec"); init_length_and_dec(); /* Unlike Item_exists_subselect, LIMIT 1 is set later for Item_in_subselect, depending on the chosen strategy. */ DBUG_VOID_RETURN; } /** Add an expression cache for this subquery if it is needed @param thd_arg Thread handle @details The function checks whether an expression cache is needed for this item and if if so wraps the item into an item of the class Item_exp_cache_wrapper with an appropriate expression cache set up there. @note used from Item::transform() @return new wrapper item if an expression cache is needed, this item - otherwise */ Item* Item_exists_subselect::expr_cache_insert_transformer(uchar *thd_arg) { THD *thd= (THD*) thd_arg; DBUG_ENTER("Item_exists_subselect::expr_cache_insert_transformer"); if (expr_cache) DBUG_RETURN(expr_cache); if (substype() == EXISTS_SUBS && expr_cache_is_needed(thd) && (expr_cache= set_expr_cache(thd))) DBUG_RETURN(expr_cache); DBUG_RETURN(this); } double Item_exists_subselect::val_real() { DBUG_ASSERT(fixed == 1); if (exec()) { reset(); return 0; } return (double) value; } longlong Item_exists_subselect::val_int() { DBUG_ASSERT(fixed == 1); if (exec()) { reset(); return 0; } return value; } /** Return the result of EXISTS as a string value Converts the true/false result into a string value. Note that currently this cannot be NULL, so if the query exection fails it will return 0. @param decimal_value[out] buffer to hold the resulting string value @retval Pointer to the converted string. Can't be a NULL pointer, as currently EXISTS cannot return NULL. */ String *Item_exists_subselect::val_str(String *str) { DBUG_ASSERT(fixed == 1); if (exec()) reset(); str->set((ulonglong)value,&my_charset_bin); return str; } /** Return the result of EXISTS as a decimal value Converts the true/false result into a decimal value. Note that currently this cannot be NULL, so if the query exection fails it will return 0. @param decimal_value[out] Buffer to hold the resulting decimal value @retval Pointer to the converted decimal. Can't be a NULL pointer, as currently EXISTS cannot return NULL. */ my_decimal *Item_exists_subselect::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(fixed == 1); if (exec()) reset(); int2my_decimal(E_DEC_FATAL_ERROR, value, 0, decimal_value); return decimal_value; } bool Item_exists_subselect::val_bool() { DBUG_ASSERT(fixed == 1); if (exec()) { reset(); return 0; } return value != 0; } double Item_in_subselect::val_real() { /* As far as Item_in_subselect called only from Item_in_optimizer this method should not be used */ DBUG_ASSERT(0); DBUG_ASSERT(fixed == 1); null_value= was_null= FALSE; if (exec()) { reset(); return 0; } if (was_null && !value) null_value= TRUE; return (double) value; } longlong Item_in_subselect::val_int() { /* As far as Item_in_subselect called only from Item_in_optimizer this method should not be used */ DBUG_ASSERT(0); DBUG_ASSERT(fixed == 1); null_value= was_null= FALSE; if (exec()) { reset(); return 0; } if (was_null && !value) null_value= TRUE; return value; } String *Item_in_subselect::val_str(String *str) { /* As far as Item_in_subselect called only from Item_in_optimizer this method should not be used */ DBUG_ASSERT(0); DBUG_ASSERT(fixed == 1); null_value= was_null= FALSE; if (exec()) { reset(); return 0; } if (was_null && !value) { null_value= TRUE; return 0; } str->set((ulonglong)value, &my_charset_bin); return str; } bool Item_in_subselect::val_bool() { DBUG_ASSERT(fixed == 1); if (forced_const) return value; null_value= was_null= FALSE; if (exec()) { reset(); return 0; } if (was_null && !value) null_value= TRUE; return value; } my_decimal *Item_in_subselect::val_decimal(my_decimal *decimal_value) { /* As far as Item_in_subselect called only from Item_in_optimizer this method should not be used */ DBUG_ASSERT(0); null_value= was_null= FALSE; DBUG_ASSERT(fixed == 1); if (exec()) { reset(); return 0; } if (was_null && !value) null_value= TRUE; int2my_decimal(E_DEC_FATAL_ERROR, value, 0, decimal_value); return decimal_value; } /** Prepare a single-column IN/ALL/ANY subselect for rewriting. @param join Join object of the subquery (i.e. 'child' join). @details Prepare a single-column subquery to be rewritten. Given the subquery. If the subquery has no tables it will be turned to an expression between left part and SELECT list. In other cases the subquery will be wrapped with Item_in_optimizer which allow later to turn it to EXISTS or MAX/MIN. @retval false The subquery was transformed @retval true Error */ bool Item_in_subselect::single_value_transformer(JOIN *join) { SELECT_LEX *select_lex= join->select_lex; DBUG_ENTER("Item_in_subselect::single_value_transformer"); /* Check that the right part of the subselect contains no more than one column. E.g. in SELECT 1 IN (SELECT * ..) the right part is (SELECT * ...) */ // psergey: duplicated_subselect_card_check if (select_lex->item_list.elements > 1) { my_error(ER_OPERAND_COLUMNS, MYF(0), 1); DBUG_RETURN(true); } Item* join_having= join->having ? join->having : join->tmp_having; if (!(join_having || select_lex->with_sum_func || select_lex->group_list.elements) && select_lex->table_list.elements == 0 && !select_lex->master_unit()->is_union()) { Item *where_item= (Item*) select_lex->item_list.head(); /* it is single select without tables => possible optimization remove the dependence mark since the item is moved to upper select and is not outer anymore. */ where_item->walk(&Item::remove_dependence_processor, 0, (uchar *) select_lex->outer_select()); substitution= func->create(left_expr, where_item); have_to_be_excluded= 1; if (thd->lex->describe) { char warn_buff[MYSQL_ERRMSG_SIZE]; sprintf(warn_buff, ER(ER_SELECT_REDUCED), select_lex->select_number); push_warning(thd, MYSQL_ERROR::WARN_LEVEL_NOTE, ER_SELECT_REDUCED, warn_buff); } DBUG_RETURN(false); } /* Wrap the current IN predicate in an Item_in_optimizer. The actual substitution in the Item tree takes place in Item_subselect::fix_fields. */ if (!substitution) { /* We're invoked for the 1st (or the only) SELECT in the subquery UNION */ substitution= optimizer; SELECT_LEX *current= thd->lex->current_select; thd->lex->current_select= current->return_after_parsing(); //optimizer never use Item **ref => we can pass 0 as parameter if (!optimizer || optimizer->fix_left(thd, 0)) { thd->lex->current_select= current; DBUG_RETURN(true); } thd->lex->current_select= current; /* We will refer to upper level cache array => we have to save it for SP */ optimizer->keep_top_level_cache(); /* As far as Item_ref_in_optimizer do not substitute itself on fix_fields we can use same item for all selects. */ expr= new Item_direct_ref(&select_lex->context, (Item**)optimizer->get_cache(), (char *)"", (char *)in_left_expr_name); } DBUG_RETURN(false); } /** Apply transformation max/min transwormation to ALL/ANY subquery if it is possible. @param join Join object of the subquery (i.e. 'child' join). @details If this is an ALL/ANY single-value subselect, try to rewrite it with a MIN/MAX subselect. We can do that if a possible NULL result of the subselect can be ignored. E.g. SELECT * FROM t1 WHERE b > ANY (SELECT a FROM t2) can be rewritten with SELECT * FROM t1 WHERE b > (SELECT MAX(a) FROM t2). We can't check that this optimization is safe if it's not a top-level item of the WHERE clause (e.g. because the WHERE clause can contain IS NULL/IS NOT NULL functions). If so, we rewrite ALL/ANY with NOT EXISTS later in this method. @retval false The subquery was transformed @retval true Error */ bool Item_allany_subselect::transform_into_max_min(JOIN *join) { DBUG_ENTER("Item_allany_subselect::transform_into_max_min"); if (!test_strategy(SUBS_MAXMIN_INJECTED | SUBS_MAXMIN_ENGINE)) DBUG_RETURN(false); Item **place= optimizer->arguments() + 1; THD *thd= join->thd; SELECT_LEX *select_lex= join->select_lex; Item *subs; /* */ DBUG_ASSERT(!substitution); /* Check if optimization with aggregate min/max possible 1 There is no aggregate in the subquery 2 It is not UNION 3 There is tables 4 It is not ALL subquery with possible NULLs in the SELECT list */ if (!select_lex->group_list.elements && /*1*/ !select_lex->having && /*1*/ !select_lex->with_sum_func && /*1*/ !(select_lex->next_select()) && /*2*/ select_lex->table_list.elements && /*3*/ (!select_lex->ref_pointer_array[0]->maybe_null || /*4*/ substype() != Item_subselect::ALL_SUBS)) /*4*/ { Item_sum_hybrid *item; nesting_map save_allow_sum_func; if (func->l_op()) { /* (ALL && (> || =>)) || (ANY && (< || =<)) for ALL condition is inverted */ item= new Item_sum_max(*select_lex->ref_pointer_array); } else { /* (ALL && (< || =<)) || (ANY && (> || =>)) for ALL condition is inverted */ item= new Item_sum_min(*select_lex->ref_pointer_array); } if (upper_item) upper_item->set_sum_test(item); thd->change_item_tree(select_lex->ref_pointer_array, item); { List_iterator it(select_lex->item_list); it++; thd->change_item_tree(it.ref(), item); } DBUG_EXECUTE("where", print_where(item, "rewrite with MIN/MAX", QT_ORDINARY);); if (thd->variables.sql_mode & MODE_ONLY_FULL_GROUP_BY) { select_lex->set_non_agg_field_used(false); } save_allow_sum_func= thd->lex->allow_sum_func; thd->lex->allow_sum_func|= 1 << thd->lex->current_select->nest_level; /* Item_sum_(max|min) can't substitute other item => we can use 0 as reference, also Item_sum_(max|min) can't be fixed after creation, so we do not check item->fixed */ if (item->fix_fields(thd, 0)) DBUG_RETURN(true); thd->lex->allow_sum_func= save_allow_sum_func; /* we added aggregate function => we have to change statistic */ count_field_types(select_lex, &join->tmp_table_param, join->all_fields, 0); if (join->prepare_stage2()) DBUG_RETURN(true); subs= new Item_singlerow_subselect(select_lex); /* Remove other strategies if any (we already changed the query and can't apply other strategy). */ set_strategy(SUBS_MAXMIN_INJECTED); } else { Item_maxmin_subselect *item; subs= item= new Item_maxmin_subselect(thd, this, select_lex, func->l_op()); if (upper_item) upper_item->set_sub_test(item); /* Remove other strategies if any (we already changed the query and can't apply other strategy). */ set_strategy(SUBS_MAXMIN_ENGINE); } /* The swap is needed for expressions of type 'f1 < ALL ( SELECT ....)' where we want to evaluate the sub query even if f1 would be null. */ subs= func->create_swap(*(optimizer->get_cache()), subs); thd->change_item_tree(place, subs); if (subs->fix_fields(thd, &subs)) DBUG_RETURN(true); DBUG_ASSERT(subs == (*place)); // There was no substitutions select_lex->master_unit()->uncacheable&= ~UNCACHEABLE_DEPENDENT_INJECTED; select_lex->uncacheable&= ~UNCACHEABLE_DEPENDENT_INJECTED; DBUG_RETURN(false); } bool Item_in_subselect::fix_having(Item *having, SELECT_LEX *select_lex) { bool fix_res= 0; if (!having->fixed) { select_lex->having_fix_field= 1; fix_res= having->fix_fields(thd, 0); select_lex->having_fix_field= 0; } return fix_res; } bool Item_allany_subselect::is_maxmin_applicable(JOIN *join) { /* Check if max/min optimization applicable: It is top item of WHERE condition. */ return (abort_on_null || (upper_item && upper_item->is_top_level_item())) && !join->select_lex->master_unit()->uncacheable && !func->eqne_op(); } /** Create the predicates needed to transform a single-column IN/ALL/ANY subselect into a correlated EXISTS via predicate injection. @param join[in] Join object of the subquery (i.e. 'child' join). @param where_item[out] the in-to-exists addition to the where clause @param having_item[out] the in-to-exists addition to the having clause @details The correlated predicates are created as follows: - If the subquery has aggregates, GROUP BY, or HAVING, convert to SELECT ie FROM ... HAVING subq_having AND trigcond(oe $cmp$ ref_or_null_helper) the addition is wrapped into trigger only when we want to distinguish between NULL and FALSE results. - Otherwise (no aggregates/GROUP BY/HAVING) convert it to one of the following: = If we don't need to distinguish between NULL and FALSE subquery: SELECT ie FROM ... WHERE subq_where AND (oe $cmp$ ie) = If we need to distinguish between those: SELECT ie FROM ... WHERE subq_where AND trigcond((oe $cmp$ ie) OR (ie IS NULL)) HAVING trigcond((ie)) @retval false If the new conditions were created successfully @retval true Error */ bool Item_in_subselect::create_single_in_to_exists_cond(JOIN * join, Item **where_item, Item **having_item) { SELECT_LEX *select_lex= join->select_lex; /* The non-transformed HAVING clause of 'join' may be stored in two ways during JOIN::optimize: this->tmp_having= this->having; this->having= 0; */ Item* join_having= join->having ? join->having : join->tmp_having; DBUG_ENTER("Item_in_subselect::create_single_in_to_exists_cond"); *where_item= NULL; *having_item= NULL; if (join_having || select_lex->with_sum_func || select_lex->group_list.elements) { Item *item= func->create(expr, new Item_ref_null_helper(&select_lex->context, this, select_lex-> ref_pointer_array, (char *)"", this->full_name())); if (!abort_on_null && left_expr->maybe_null) { /* We can encounter "NULL IN (SELECT ...)". Wrap the added condition within a trig_cond. */ item= new Item_func_trig_cond(item, get_cond_guard(0)); } if (!join_having) item->name= (char*) in_having_cond; if (fix_having(item, select_lex)) DBUG_RETURN(true); *having_item= item; } else { Item *item= (Item*) select_lex->item_list.head(); if (select_lex->table_list.elements) { Item *having= item; Item *orig_item= item; item= func->create(expr, item); if (!abort_on_null && orig_item->maybe_null) { having= new Item_is_not_null_test(this, having); if (left_expr->maybe_null) { if (!(having= new Item_func_trig_cond(having, get_cond_guard(0)))) DBUG_RETURN(true); } having->name= (char*) in_having_cond; if (fix_having(having, select_lex)) DBUG_RETURN(true); *having_item= having; item= new Item_cond_or(item, new Item_func_isnull(orig_item)); } /* If we may encounter NULL IN (SELECT ...) and care whether subquery result is NULL or FALSE, wrap condition in a trig_cond. */ if (!abort_on_null && left_expr->maybe_null) { if (!(item= new Item_func_trig_cond(item, get_cond_guard(0)))) DBUG_RETURN(true); } /* TODO: figure out why the following is done here in single_value_transformer but there is no corresponding action in row_value_transformer? */ item->name= (char *) in_additional_cond; if (!item->fixed && item->fix_fields(thd, 0)) DBUG_RETURN(true); *where_item= item; } else { if (select_lex->master_unit()->is_union()) { Item *new_having= func->create(expr, new Item_ref_null_helper(&select_lex->context, this, select_lex->ref_pointer_array, (char *)"", (char *)"")); if (!abort_on_null && left_expr->maybe_null) { if (!(new_having= new Item_func_trig_cond(new_having, get_cond_guard(0)))) DBUG_RETURN(true); } new_having->name= (char*) in_having_cond; if (fix_having(new_having, select_lex)) DBUG_RETURN(true); *having_item= new_having; } else DBUG_ASSERT(false); } } DBUG_RETURN(false); } /** Wrap a multi-column IN/ALL/ANY subselect into an Item_in_optimizer. @param join Join object of the subquery (i.e. 'child' join). @details The subquery predicate is wrapped into an Item_in_optimizer. Later the query optimization phase chooses whether the subquery under the Item_in_optimizer will be further transformed into an equivalent correlated EXISTS by injecting additional predicates, or will be executed via subquery materialization in its unmodified form. @retval false The subquery was transformed @retval true Error */ bool Item_in_subselect::row_value_transformer(JOIN *join) { SELECT_LEX *select_lex= join->select_lex; uint cols_num= left_expr->cols(); DBUG_ENTER("Item_in_subselect::row_value_transformer"); // psergey: duplicated_subselect_card_check if (select_lex->item_list.elements != cols_num) { my_error(ER_OPERAND_COLUMNS, MYF(0), cols_num); DBUG_RETURN(true); } /* Wrap the current IN predicate in an Item_in_optimizer. The actual substitution in the Item tree takes place in Item_subselect::fix_fields. */ if (!substitution) { //first call for this unit SELECT_LEX_UNIT *master_unit= select_lex->master_unit(); substitution= optimizer; SELECT_LEX *current= thd->lex->current_select; thd->lex->current_select= current->return_after_parsing(); //optimizer never use Item **ref => we can pass 0 as parameter if (!optimizer || optimizer->fix_left(thd, 0)) { thd->lex->current_select= current; DBUG_RETURN(true); } // we will refer to upper level cache array => we have to save it in PS optimizer->keep_top_level_cache(); thd->lex->current_select= current; /* The uncacheable property controls a number of actions, e.g. whether to save/restore (via init_save_join_tab/restore_tmp) the original JOIN for plans with a temp table where the original JOIN was overriden by make_simple_join. The UNCACHEABLE_EXPLAIN is ignored by EXPLAIN, thus non-correlated subqueries will not appear as such to EXPLAIN. */ master_unit->uncacheable|= UNCACHEABLE_EXPLAIN; select_lex->uncacheable|= UNCACHEABLE_EXPLAIN; } DBUG_RETURN(false); } /** Create the predicates needed to transform a multi-column IN/ALL/ANY subselect into a correlated EXISTS via predicate injection. @details The correlated predicates are created as follows: - If the subquery has aggregates, GROUP BY, or HAVING, convert to (l1, l2, l3) IN (SELECT v1, v2, v3 ... HAVING having) => EXISTS (SELECT ... HAVING having and (l1 = v1 or is null v1) and (l2 = v2 or is null v2) and (l3 = v3 or is null v3) and is_not_null_test(v1) and is_not_null_test(v2) and is_not_null_test(v3)) where is_not_null_test used to register nulls in case if we have not found matching to return correct NULL value. - Otherwise (no aggregates/GROUP BY/HAVING) convert the subquery as follows: (l1, l2, l3) IN (SELECT v1, v2, v3 ... WHERE where) => EXISTS (SELECT ... WHERE where and (l1 = v1 or is null v1) and (l2 = v2 or is null v2) and (l3 = v3 or is null v3) HAVING is_not_null_test(v1) and is_not_null_test(v2) and is_not_null_test(v3)) where is_not_null_test registers NULLs values but reject rows. in case when we do not need correct NULL, we have simplier construction: EXISTS (SELECT ... WHERE where and (l1 = v1) and (l2 = v2) and (l3 = v3) @param join[in] Join object of the subquery (i.e. 'child' join). @param where_item[out] the in-to-exists addition to the where clause @param having_item[out] the in-to-exists addition to the having clause @retval false If the new conditions were created successfully @retval true Error */ bool Item_in_subselect::create_row_in_to_exists_cond(JOIN * join, Item **where_item, Item **having_item) { SELECT_LEX *select_lex= join->select_lex; uint cols_num= left_expr->cols(); /* The non-transformed HAVING clause of 'join' may be stored in two ways during JOIN::optimize: this->tmp_having= this->having; this->having= 0; */ Item* join_having= join->having ? join->having : join->tmp_having; bool is_having_used= (join_having || select_lex->with_sum_func || select_lex->group_list.first || !select_lex->table_list.elements); DBUG_ENTER("Item_in_subselect::create_row_in_to_exists_cond"); *where_item= NULL; *having_item= NULL; if (is_having_used) { /* TODO: say here explicitly if the order of AND parts matters or not. */ Item *item_having_part2= 0; for (uint i= 0; i < cols_num; i++) { DBUG_ASSERT((left_expr->fixed && select_lex->ref_pointer_array[i]->fixed) || (select_lex->ref_pointer_array[i]->type() == REF_ITEM && ((Item_ref*)(select_lex->ref_pointer_array[i]))->ref_type() == Item_ref::OUTER_REF)); if (select_lex->ref_pointer_array[i]-> check_cols(left_expr->element_index(i)->cols())) DBUG_RETURN(true); Item *item_eq= new Item_func_eq(new Item_ref(&select_lex->context, (*optimizer->get_cache())-> addr(i), (char *)"", (char *)in_left_expr_name), new Item_ref(&select_lex->context, select_lex->ref_pointer_array + i, (char *)"", (char *)"")); Item *item_isnull= new Item_func_isnull(new Item_ref(&select_lex->context, select_lex->ref_pointer_array+i, (char *)"", (char *)"")); Item *col_item= new Item_cond_or(item_eq, item_isnull); if (!abort_on_null && left_expr->element_index(i)->maybe_null) { if (!(col_item= new Item_func_trig_cond(col_item, get_cond_guard(i)))) DBUG_RETURN(true); } *having_item= and_items(*having_item, col_item); Item *item_nnull_test= new Item_is_not_null_test(this, new Item_ref(&select_lex->context, select_lex-> ref_pointer_array + i, (char *)"", (char *)"")); if (!abort_on_null && left_expr->element_index(i)->maybe_null) { if (!(item_nnull_test= new Item_func_trig_cond(item_nnull_test, get_cond_guard(i)))) DBUG_RETURN(true); } item_having_part2= and_items(item_having_part2, item_nnull_test); item_having_part2->top_level_item(); } *having_item= and_items(*having_item, item_having_part2); } else { for (uint i= 0; i < cols_num; i++) { Item *item, *item_isnull; DBUG_ASSERT((left_expr->fixed && select_lex->ref_pointer_array[i]->fixed) || (select_lex->ref_pointer_array[i]->type() == REF_ITEM && ((Item_ref*)(select_lex->ref_pointer_array[i]))->ref_type() == Item_ref::OUTER_REF)); if (select_lex->ref_pointer_array[i]-> check_cols(left_expr->element_index(i)->cols())) DBUG_RETURN(true); item= new Item_func_eq(new Item_direct_ref(&select_lex->context, (*optimizer->get_cache())-> addr(i), (char *)"", (char *)in_left_expr_name), new Item_direct_ref(&select_lex->context, select_lex-> ref_pointer_array+i, (char *)"", (char *)"")); if (!abort_on_null) { Item *having_col_item= new Item_is_not_null_test(this, new Item_ref(&select_lex->context, select_lex->ref_pointer_array + i, (char *)"", (char *)"")); item_isnull= new Item_func_isnull(new Item_direct_ref(&select_lex->context, select_lex-> ref_pointer_array+i, (char *)"", (char *)"")); item= new Item_cond_or(item, item_isnull); /* TODO: why we create the above for cases where the right part cant be NULL? */ if (left_expr->element_index(i)->maybe_null) { if (!(item= new Item_func_trig_cond(item, get_cond_guard(i)))) DBUG_RETURN(true); if (!(having_col_item= new Item_func_trig_cond(having_col_item, get_cond_guard(i)))) DBUG_RETURN(true); } *having_item= and_items(*having_item, having_col_item); } *where_item= and_items(*where_item, item); } } if (*where_item) { if (!(*where_item)->fixed && (*where_item)->fix_fields(thd, 0)) DBUG_RETURN(true); (*where_item)->top_level_item(); } if (*having_item) { if (!join_having) (*having_item)->name= (char*) in_having_cond; if (fix_having(*having_item, select_lex)) DBUG_RETURN(true); (*having_item)->top_level_item(); } DBUG_RETURN(false); } bool Item_in_subselect::select_transformer(JOIN *join) { return select_in_like_transformer(join); } /** Create the predicates needed to transform an IN/ALL/ANY subselect into a correlated EXISTS via predicate injection. @param join_arg Join object of the subquery. @retval FALSE ok @retval TRUE error */ bool Item_in_subselect::create_in_to_exists_cond(JOIN *join_arg) { bool res; DBUG_ASSERT(engine->engine_type() == subselect_engine::SINGLE_SELECT_ENGINE || engine->engine_type() == subselect_engine::UNION_ENGINE); /* TODO: the call to init_cond_guards allocates and initializes an array of booleans that may not be used later because we may choose materialization. The two calls below to create_XYZ_cond depend on this boolean array. If the dependency is removed, the call can be moved to a later phase. */ init_cond_guards(); if (left_expr->cols() == 1) res= create_single_in_to_exists_cond(join_arg, &(join_arg->in_to_exists_where), &(join_arg->in_to_exists_having)); else res= create_row_in_to_exists_cond(join_arg, &(join_arg->in_to_exists_where), &(join_arg->in_to_exists_having)); /* The IN=>EXISTS transformation makes non-correlated subqueries correlated. */ join_arg->select_lex->uncacheable|= UNCACHEABLE_DEPENDENT_INJECTED; /* The uncacheable property controls a number of actions, e.g. whether to save/restore (via init_save_join_tab/restore_tmp) the original JOIN for plans with a temp table where the original JOIN was overriden by make_simple_join. The UNCACHEABLE_EXPLAIN is ignored by EXPLAIN, thus non-correlated subqueries will not appear as such to EXPLAIN. */ join_arg->select_lex->master_unit()->uncacheable|= UNCACHEABLE_EXPLAIN; join_arg->select_lex->uncacheable|= UNCACHEABLE_EXPLAIN; return (res); } /** Transform an IN/ALL/ANY subselect into a correlated EXISTS via injecting correlated in-to-exists predicates. @param join_arg Join object of the subquery. @retval FALSE ok @retval TRUE error */ bool Item_in_subselect::inject_in_to_exists_cond(JOIN *join_arg) { SELECT_LEX *select_lex= join_arg->select_lex; Item *where_item= join_arg->in_to_exists_where; Item *having_item= join_arg->in_to_exists_having; DBUG_ENTER("Item_in_subselect::inject_in_to_exists_cond"); if (where_item) { List *and_args= NULL; /* If the top-level Item of the WHERE clause is an AND, detach the multiple equality list that was attached to the end of the AND argument list by build_equal_items_for_cond(). The multiple equalities must be detached because fix_fields merges lower level AND arguments into the upper AND. As a result, the arguments from lower-level ANDs are concatenated after the multiple equalities. When the multiple equality list is treated as such, it turns out that it contains non-Item_equal object which is wrong. */ if (join_arg->conds && join_arg->conds->type() == Item::COND_ITEM && ((Item_cond*) join_arg->conds)->functype() == Item_func::COND_AND_FUNC) { and_args= ((Item_cond*) join_arg->conds)->argument_list(); if (join_arg->cond_equal) and_args->disjoin((List *) &join_arg->cond_equal->current_level); } where_item= and_items(join_arg->conds, where_item); if (!where_item->fixed && where_item->fix_fields(thd, 0)) DBUG_RETURN(true); // TIMOUR TODO: call optimize_cond() for the new where clause thd->change_item_tree(&select_lex->where, where_item); select_lex->where->top_level_item(); join_arg->conds= select_lex->where; /* Attach back the list of multiple equalities to the new top-level AND. */ if (and_args && join_arg->cond_equal) { /* The argument list of the top-level AND may change after fix fields. */ and_args= ((Item_cond*) join_arg->conds)->argument_list(); List_iterator li(join_arg->cond_equal->current_level); Item_equal *elem; while ((elem= li++)) { and_args->push_back(elem); } } } if (having_item) { Item* join_having= join_arg->having ? join_arg->having:join_arg->tmp_having; having_item= and_items(join_having, having_item); if (fix_having(having_item, select_lex)) DBUG_RETURN(true); // TIMOUR TODO: call optimize_cond() for the new having clause thd->change_item_tree(&select_lex->having, having_item); select_lex->having->top_level_item(); join_arg->having= select_lex->having; } join_arg->thd->change_item_tree(&unit->global_parameters->select_limit, new Item_int((int32) 1)); unit->select_limit_cnt= 1; DBUG_RETURN(false); } /** Prepare IN/ALL/ANY/SOME subquery transformation and call the appropriate transformation function. @param join JOIN object of transforming subquery @notes To decide which transformation procedure (scalar or row) applicable here we have to call fix_fields() for the left expression to be able to call cols() method on it. Also this method makes arena management for underlying transformation methods. @retval false OK @retval true Error */ bool Item_in_subselect::select_in_like_transformer(JOIN *join) { Query_arena *arena, backup; SELECT_LEX *current= thd->lex->current_select; const char *save_where= thd->where; bool trans_res= true; bool result; DBUG_ENTER("Item_in_subselect::select_in_like_transformer"); /* IN/SOME/ALL/ANY subqueries aren't support LIMIT clause. Without it ORDER BY clause becomes meaningless thus we drop it here. */ for (SELECT_LEX *sl= current->master_unit()->first_select(); sl; sl= sl->next_select()) { if (sl->join) { sl->join->order= 0; sl->join->skip_sort_order= 1; } } if (changed) DBUG_RETURN(false); thd->where= "IN/ALL/ANY subquery"; /* In some optimisation cases we will not need this Item_in_optimizer object, but we can't know it here, but here we need address correct reference on left expresion. //psergey: he means degenerate cases like "... IN (SELECT 1)" */ if (!optimizer) { arena= thd->activate_stmt_arena_if_needed(&backup); result= (!(optimizer= new Item_in_optimizer(left_expr, this))); if (arena) thd->restore_active_arena(arena, &backup); if (result) goto err; } thd->lex->current_select= current->return_after_parsing(); result= (!left_expr->fixed && left_expr->fix_fields(thd, optimizer->arguments())); /* fix_fields can change reference to left_expr, we need reassign it */ left_expr= optimizer->arguments()[0]; thd->lex->current_select= current; if (result) goto err; /* Both transformers call fix_fields() only for Items created inside them, and all that items do not make permanent changes in current item arena which allow to us call them with changed arena (if we do not know nature of Item, we have to call fix_fields() for it only with original arena to avoid memory leack) */ arena= thd->activate_stmt_arena_if_needed(&backup); if (left_expr->cols() == 1) trans_res= single_value_transformer(join); else { /* we do not support row operation for ALL/ANY/SOME */ if (func != &eq_creator) { if (arena) thd->restore_active_arena(arena, &backup); my_error(ER_OPERAND_COLUMNS, MYF(0), 1); DBUG_RETURN(true); } trans_res= row_value_transformer(join); } if (arena) thd->restore_active_arena(arena, &backup); err: thd->where= save_where; DBUG_RETURN(trans_res); } void Item_in_subselect::print(String *str, enum_query_type query_type) { if (test_strategy(SUBS_IN_TO_EXISTS)) str->append(STRING_WITH_LEN("")); else { left_expr->print(str, query_type); str->append(STRING_WITH_LEN(" in ")); } Item_subselect::print(str, query_type); } bool Item_in_subselect::fix_fields(THD *thd_arg, Item **ref) { uint outer_cols_num; List *inner_cols; if (test_strategy(SUBS_SEMI_JOIN)) return !( (*ref)= new Item_int(1)); /* Check if the outer and inner IN operands match in those cases when we will not perform IN=>EXISTS transformation. Currently this is when we use subquery materialization. The condition below is true when this method was called recursively from inside JOIN::prepare for the JOIN object created by the call chain Item_subselect::fix_fields -> subselect_single_select_engine::prepare, which creates a JOIN object for the subquery and calls JOIN::prepare for the JOIN of the subquery. Notice that in some cases, this doesn't happen, and the check_cols() test for each Item happens later in Item_in_subselect::row_value_in_to_exists_transformer. The reason for this mess is that our JOIN::prepare phase works top-down instead of bottom-up, so we first do name resoluton and semantic checks for the outer selects, then for the inner. */ if (engine && engine->engine_type() == subselect_engine::SINGLE_SELECT_ENGINE && ((subselect_single_select_engine*)engine)->join) { outer_cols_num= left_expr->cols(); if (unit->is_union()) inner_cols= &(unit->types); else inner_cols= &(unit->first_select()->item_list); if (outer_cols_num != inner_cols->elements) { my_error(ER_OPERAND_COLUMNS, MYF(0), outer_cols_num); return TRUE; } if (outer_cols_num > 1) { List_iterator inner_col_it(*inner_cols); Item *inner_col; for (uint i= 0; i < outer_cols_num; i++) { inner_col= inner_col_it++; if (inner_col->check_cols(left_expr->element_index(i)->cols())) return TRUE; } } } if ((thd_arg->lex->context_analysis_only & CONTEXT_ANALYSIS_ONLY_VIEW) && left_expr && !left_expr->fixed && left_expr->fix_fields(thd_arg, &left_expr)) return TRUE; if (Item_subselect::fix_fields(thd_arg, ref)) return TRUE; fixed= TRUE; return FALSE; } void Item_in_subselect::fix_after_pullout(st_select_lex *new_parent, Item **ref) { left_expr->fix_after_pullout(new_parent, &left_expr); Item_subselect::fix_after_pullout(new_parent, ref); used_tables_cache |= left_expr->used_tables(); } void Item_in_subselect::update_used_tables() { Item_subselect::update_used_tables(); left_expr->update_used_tables(); used_tables_cache |= left_expr->used_tables(); } /** Try to create and initialize an engine to compute a subselect via materialization. @details The method creates a new engine for materialized execution, and initializes the engine. The initialization may fail - either because it wasn't possible to create the needed temporary table and its index, - or because of a memory allocation error, @returns @retval TRUE memory allocation error occurred @retval FALSE an execution method was chosen successfully */ bool Item_in_subselect::setup_mat_engine() { subselect_hash_sj_engine *mat_engine= NULL; subselect_single_select_engine *select_engine; DBUG_ENTER("Item_in_subselect::setup_mat_engine"); /* The select_engine (that executes transformed IN=>EXISTS subselects) is pre-created at parse time, and is stored in statment memory (preserved across PS executions). */ DBUG_ASSERT(engine->engine_type() == subselect_engine::SINGLE_SELECT_ENGINE); select_engine= (subselect_single_select_engine*) engine; /* Create/initialize execution objects. */ if (!(mat_engine= new subselect_hash_sj_engine(thd, this, select_engine))) DBUG_RETURN(TRUE); if (mat_engine->init(&select_engine->join->fields_list, engine->get_identifier())) DBUG_RETURN(TRUE); engine= mat_engine; DBUG_RETURN(FALSE); } /** Initialize the cache of the left operand of the IN predicate. @note This method has the same purpose as alloc_group_fields(), but it takes a different kind of collection of items, and the list we push to is dynamically allocated. @retval TRUE if a memory allocation error occurred or the cache is not applicable to the current query @retval FALSE if success */ bool Item_in_subselect::init_left_expr_cache() { JOIN *outer_join; outer_join= unit->outer_select()->join; /* An IN predicate might be evaluated in a query for which all tables have been optimzied away. */ if (!outer_join || !outer_join->table_count || !outer_join->tables_list) return TRUE; if (!(left_expr_cache= new List)) return TRUE; for (uint i= 0; i < left_expr->cols(); i++) { Cached_item *cur_item_cache= new_Cached_item(thd, left_expr->element_index(i), FALSE); if (!cur_item_cache || left_expr_cache->push_front(cur_item_cache)) return TRUE; } return FALSE; } bool Item_in_subselect::init_cond_guards() { uint cols_num= left_expr->cols(); if (!abort_on_null && left_expr->maybe_null && !pushed_cond_guards) { if (!(pushed_cond_guards= (bool*)thd->alloc(sizeof(bool) * cols_num))) return TRUE; for (uint i= 0; i < cols_num; i++) pushed_cond_guards[i]= TRUE; } return FALSE; } bool Item_allany_subselect::select_transformer(JOIN *join) { DBUG_ENTER("Item_allany_subselect::select_transformer"); DBUG_ASSERT((in_strategy & ~(SUBS_MAXMIN_INJECTED | SUBS_MAXMIN_ENGINE | SUBS_IN_TO_EXISTS | SUBS_STRATEGY_CHOSEN)) == 0); if (upper_item) upper_item->show= 1; DBUG_RETURN(select_in_like_transformer(join)); } void Item_allany_subselect::print(String *str, enum_query_type query_type) { if (test_strategy(SUBS_IN_TO_EXISTS)) str->append(STRING_WITH_LEN("")); else { left_expr->print(str, query_type); str->append(' '); str->append(func->symbol(all)); str->append(all ? " all " : " any ", 5); } Item_subselect::print(str, query_type); } void subselect_engine::set_thd(THD *thd_arg) { thd= thd_arg; if (result) result->set_thd(thd_arg); } subselect_single_select_engine:: subselect_single_select_engine(THD *thd_arg, st_select_lex *select, select_result_interceptor *result_arg, Item_subselect *item_arg) :subselect_engine(thd_arg, item_arg, result_arg), prepared(0), executed(0), optimize_error(0), select_lex(select), join(0) { select_lex->master_unit()->item= item_arg; } int subselect_single_select_engine::get_identifier() { return select_lex->select_number; } void subselect_single_select_engine::cleanup() { DBUG_ENTER("subselect_single_select_engine::cleanup"); prepared= executed= optimize_error= 0; join= 0; result->cleanup(); select_lex->uncacheable&= ~UNCACHEABLE_DEPENDENT_INJECTED; DBUG_VOID_RETURN; } void subselect_union_engine::cleanup() { DBUG_ENTER("subselect_union_engine::cleanup"); unit->reinit_exec_mechanism(); result->cleanup(); unit->uncacheable&= ~UNCACHEABLE_DEPENDENT_INJECTED; for (SELECT_LEX *sl= unit->first_select(); sl; sl= sl->next_select()) sl->uncacheable&= ~UNCACHEABLE_DEPENDENT_INJECTED; DBUG_VOID_RETURN; } bool subselect_union_engine::is_executed() const { return unit->executed; } /* Check if last execution of the subquery engine produced any rows SYNOPSIS subselect_union_engine::no_rows() DESCRIPTION Check if last execution of the subquery engine produced any rows. The return value is undefined if last execution ended in an error. RETURN TRUE - Last subselect execution has produced no rows FALSE - Otherwise */ bool subselect_union_engine::no_rows() { /* Check if we got any rows when reading UNION result from temp. table: */ return test(!unit->fake_select_lex->join->send_records); } void subselect_uniquesubquery_engine::cleanup() { DBUG_ENTER("subselect_uniquesubquery_engine::cleanup"); /* Tell handler we don't need the index anymore */ if (tab->table->file->inited) tab->table->file->ha_index_end(); DBUG_VOID_RETURN; } subselect_union_engine::subselect_union_engine(THD *thd_arg, st_select_lex_unit *u, select_result_interceptor *result_arg, Item_subselect *item_arg) :subselect_engine(thd_arg, item_arg, result_arg) { unit= u; if (!result_arg) //out of memory current_thd->fatal_error(); unit->item= item_arg; } /** Create and prepare the JOIN object that represents the query execution plan for the subquery. @details This method is called from Item_subselect::fix_fields. For prepared statements it is called both during the PREPARE and EXECUTE phases in the following ways: - During PREPARE the optimizer needs some properties (join->fields_list.elements) of the JOIN to proceed with preparation of the remaining query (namely to complete ::fix_fields for the subselect related classes. In the end of PREPARE the JOIN is deleted. - When we EXECUTE the query, Item_subselect::fix_fields is called again, and the JOIN object is re-created again, prepared and executed. In the end of execution it is deleted. In all cases the JOIN is created in runtime memory (not in the permanent memory root). @todo Re-check what properties of 'join' are needed during prepare, and see if we can avoid creating a JOIN during JOIN::prepare of the outer join. @retval 0 if success @retval 1 if error */ int subselect_single_select_engine::prepare() { if (prepared) return 0; if (select_lex->join) { select_lex->cleanup(); } join= new JOIN(thd, select_lex->item_list, select_lex->options | SELECT_NO_UNLOCK, result); if (!join || !result) { thd->fatal_error(); //out of memory return 1; } prepared= 1; SELECT_LEX *save_select= thd->lex->current_select; thd->lex->current_select= select_lex; if (join->prepare(&select_lex->ref_pointer_array, select_lex->table_list.first, select_lex->with_wild, select_lex->where, select_lex->order_list.elements + select_lex->group_list.elements, select_lex->order_list.first, select_lex->group_list.first, select_lex->having, NULL, select_lex, select_lex->master_unit())) return 1; thd->lex->current_select= save_select; return 0; } int subselect_union_engine::prepare() { return unit->prepare(thd, result, SELECT_NO_UNLOCK); } int subselect_uniquesubquery_engine::prepare() { /* Should never be called. */ DBUG_ASSERT(FALSE); return 1; } /* Check if last execution of the subquery engine produced any rows SYNOPSIS subselect_single_select_engine::no_rows() DESCRIPTION Check if last execution of the subquery engine produced any rows. The return value is undefined if last execution ended in an error. RETURN TRUE - Last subselect execution has produced no rows FALSE - Otherwise */ bool subselect_single_select_engine::no_rows() { return !item->assigned(); } /* makes storage for the output values for the subquery and calcuates their data and column types and their nullability. */ void subselect_engine::set_row(List &item_list, Item_cache **row) { Item *sel_item; List_iterator_fast li(item_list); res_type= STRING_RESULT; res_field_type= MYSQL_TYPE_VAR_STRING; for (uint i= 0; (sel_item= li++); i++) { item->max_length= sel_item->max_length; res_type= sel_item->result_type(); res_field_type= sel_item->field_type(); item->decimals= sel_item->decimals; item->unsigned_flag= sel_item->unsigned_flag; maybe_null= sel_item->maybe_null; if (!(row[i]= Item_cache::get_cache(sel_item))) return; row[i]->setup(sel_item); //psergey-backport-timours: row[i]->store(sel_item); } if (item_list.elements > 1) res_type= ROW_RESULT; } void subselect_single_select_engine::fix_length_and_dec(Item_cache **row) { DBUG_ASSERT(row || select_lex->item_list.elements==1); set_row(select_lex->item_list, row); item->collation.set(row[0]->collation); if (cols() != 1) maybe_null= 0; } void subselect_union_engine::fix_length_and_dec(Item_cache **row) { DBUG_ASSERT(row || unit->first_select()->item_list.elements==1); if (unit->first_select()->item_list.elements == 1) { set_row(unit->types, row); item->collation.set(row[0]->collation); } else { bool maybe_null_saved= maybe_null; set_row(unit->types, row); maybe_null= maybe_null_saved; } } void subselect_uniquesubquery_engine::fix_length_and_dec(Item_cache **row) { //this never should be called DBUG_ASSERT(0); } int init_read_record_seq(JOIN_TAB *tab); int join_read_always_key_or_null(JOIN_TAB *tab); int join_read_next_same_or_null(READ_RECORD *info); int subselect_single_select_engine::exec() { DBUG_ENTER("subselect_single_select_engine::exec"); if (optimize_error) DBUG_RETURN(1); char const *save_where= thd->where; SELECT_LEX *save_select= thd->lex->current_select; thd->lex->current_select= select_lex; if (!join->optimized) { SELECT_LEX_UNIT *unit= select_lex->master_unit(); unit->set_limit(unit->global_parameters); if (join->optimize()) { thd->where= save_where; executed= optimize_error= 1; thd->lex->current_select= save_select; DBUG_RETURN(join->error ? join->error : 1); } if (!select_lex->uncacheable && thd->lex->describe && !(join->select_options & SELECT_DESCRIBE)) { item->update_used_tables(); if (item->const_item()) { /* It's necessary to keep original JOIN table because create_sort_index() function may overwrite original JOIN_TAB::type and wrong optimization method can be selected on re-execution. */ select_lex->uncacheable|= UNCACHEABLE_EXPLAIN; select_lex->master_unit()->uncacheable|= UNCACHEABLE_EXPLAIN; /* Force join->join_tmp creation, because this subquery will be replaced by a simple select from the materialization temp table by optimize() called by EXPLAIN and we need to preserve the initial query structure so we can display it. */ if (join->need_tmp && join->init_save_join_tab()) DBUG_RETURN(1); /* purecov: inspected */ } } if (item->engine_changed) { DBUG_RETURN(1); } } if (select_lex->uncacheable && select_lex->uncacheable != UNCACHEABLE_EXPLAIN && executed) { if (join->reinit()) { thd->where= save_where; thd->lex->current_select= save_select; DBUG_RETURN(1); } item->reset(); item->assigned((executed= 0)); } if (!executed) { item->reset_value_registration(); JOIN_TAB *changed_tabs[MAX_TABLES]; JOIN_TAB **last_changed_tab= changed_tabs; if (item->have_guarded_conds()) { /* For at least one of the pushed predicates the following is true: We should not apply optimizations based on the condition that was pushed down into the subquery. Those optimizations are ref[_or_null] acceses. Change them to be full table scans. */ for (JOIN_TAB *tab= first_linear_tab(join, WITHOUT_CONST_TABLES); tab; tab= next_linear_tab(join, tab, WITH_BUSH_ROOTS)) { if (tab && tab->keyuse) { for (uint i= 0; i < tab->ref.key_parts; i++) { bool *cond_guard= tab->ref.cond_guards[i]; if (cond_guard && !*cond_guard) { /* Change the access method to full table scan */ tab->save_read_first_record= tab->read_first_record; tab->save_read_record= tab->read_record.read_record; tab->read_first_record= init_read_record_seq; tab->read_record.record= tab->table->record[0]; tab->read_record.thd= join->thd; tab->read_record.ref_length= tab->table->file->ref_length; tab->read_record.unlock_row= rr_unlock_row; *(last_changed_tab++)= tab; break; } } } } } join->exec(); /* Enable the optimizations back */ for (JOIN_TAB **ptab= changed_tabs; ptab != last_changed_tab; ptab++) { JOIN_TAB *tab= *ptab; tab->read_record.record= 0; tab->read_record.ref_length= 0; tab->read_first_record= tab->save_read_first_record; tab->read_record.read_record= tab->save_read_record; } executed= 1; thd->where= save_where; thd->lex->current_select= save_select; DBUG_RETURN(join->error || thd->is_fatal_error || thd->is_error()); } thd->where= save_where; thd->lex->current_select= save_select; DBUG_RETURN(0); } int subselect_union_engine::exec() { char const *save_where= thd->where; int res= unit->exec(); thd->where= save_where; return res; } /* Search for at least one row satisfying select condition SYNOPSIS subselect_uniquesubquery_engine::scan_table() DESCRIPTION Scan the table using sequential access until we find at least one row satisfying select condition. The caller must set this->empty_result_set=FALSE before calling this function. This function will set it to TRUE if it finds a matching row. RETURN FALSE - OK TRUE - Error */ int subselect_uniquesubquery_engine::scan_table() { int error; TABLE *table= tab->table; DBUG_ENTER("subselect_uniquesubquery_engine::scan_table"); if (table->file->inited) table->file->ha_index_end(); if (table->file->ha_rnd_init_with_error(1)) DBUG_RETURN(1); table->file->extra_opt(HA_EXTRA_CACHE, current_thd->variables.read_buff_size); table->null_row= 0; for (;;) { error=table->file->ha_rnd_next(table->record[0]); if (error) { if (error == HA_ERR_RECORD_DELETED) { error= 0; continue; } if (error == HA_ERR_END_OF_FILE) { error= 0; break; } else { error= report_error(table, error); break; } } if (!cond || cond->val_int()) { empty_result_set= FALSE; break; } } table->file->ha_rnd_end(); DBUG_RETURN(error != 0); } /* Copy ref key and check for null parts in it SYNOPSIS subselect_uniquesubquery_engine::copy_ref_key() DESCRIPTION Copy ref key and check for null parts in it. Depending on the nullability and conversion problems this function recognizes and processes the following states : 1. Partial match on top level. This means IN has a value of FALSE regardless of the data in the subquery table. Detected by finding a NULL in the left IN operand of a top level expression. We may actually skip reading the subquery, so return TRUE to skip the table scan in subselect_uniquesubquery_engine::exec and make the value of the IN predicate a NULL (that is equal to FALSE on top level). 2. No exact match when IN is nested inside another predicate. Detected by finding a NULL in the left IN operand when IN is not a top level predicate. We cannot have an exact match. But we must proceed further with a table scan to find out if it's a partial match (and IN has a value of NULL) or no match (and IN has a value of FALSE). So we return FALSE to continue with the scan and see if there are any record that would constitute a partial match (as we cannot determine that from the index). 3. Error converting the left IN operand to the column type of the right IN operand. This counts as no match (and IN has the value of FALSE). We mark the subquery table cursor as having no more rows (to ensure that the processing that follows will not find a match) and return FALSE, so IN is not treated as returning NULL. RETURN FALSE - The value of the IN predicate is not known. Proceed to find the value of the IN predicate using the determined values of null_keypart and table->status. TRUE - IN predicate has a value of NULL. Stop the processing right there and return NULL to the outer predicates. */ bool subselect_uniquesubquery_engine::copy_ref_key() { DBUG_ENTER("subselect_uniquesubquery_engine::copy_ref_key"); for (store_key **copy= tab->ref.key_copy ; *copy ; copy++) { tab->ref.key_err= (*copy)->copy(); /* When there is a NULL part in the key we don't need to make index lookup for such key thus we don't need to copy whole key. If we later should do a sequential scan return OK. Fail otherwise. See also the comment for the subselect_uniquesubquery_engine::exec() function. */ null_keypart= (*copy)->null_key; if (null_keypart) { bool top_level= ((Item_in_subselect *) item)->is_top_level_item(); if (top_level) { /* Partial match on top level */ DBUG_RETURN(1); } else { /* No exact match when IN is nested inside another predicate */ break; } } /* Check if the error is equal to STORE_KEY_FATAL. This is not expressed using the store_key::store_key_result enum because ref.key_err is a boolean and we want to detect both TRUE and STORE_KEY_FATAL from the space of the union of the values of [TRUE, FALSE] and store_key::store_key_result. TODO: fix the variable an return types. */ if (tab->ref.key_err & 1) { /* Error converting the left IN operand to the column type of the right IN operand. */ tab->table->status= STATUS_NOT_FOUND; break; } } DBUG_RETURN(0); } /* @retval 1 A NULL was found in the outer reference, index lookup is not applicable, the outer ref is unsusable as a lookup key, use some other method to find a match. @retval 0 The outer ref was copied into an index lookup key. @retval -1 The outer ref cannot possibly match any row, IN is FALSE. */ /* TIMOUR: this method is a variant of copy_ref_key(), needs refactoring. */ int subselect_uniquesubquery_engine::copy_ref_key_simple() { for (store_key **copy= tab->ref.key_copy ; *copy ; copy++) { enum store_key::store_key_result store_res; store_res= (*copy)->copy(); tab->ref.key_err= store_res; /* When there is a NULL part in the key we don't need to make index lookup for such key thus we don't need to copy whole key. If we later should do a sequential scan return OK. Fail otherwise. See also the comment for the subselect_uniquesubquery_engine::exec() function. */ null_keypart= (*copy)->null_key; if (null_keypart) return 1; /* Check if the error is equal to STORE_KEY_FATAL. This is not expressed using the store_key::store_key_result enum because ref.key_err is a boolean and we want to detect both TRUE and STORE_KEY_FATAL from the space of the union of the values of [TRUE, FALSE] and store_key::store_key_result. TODO: fix the variable an return types. */ if (store_res == store_key::STORE_KEY_FATAL) { /* Error converting the left IN operand to the column type of the right IN operand. */ return -1; } } return 0; } /* Execute subselect SYNOPSIS subselect_uniquesubquery_engine::exec() DESCRIPTION Find rows corresponding to the ref key using index access. If some part of the lookup key is NULL, then we're evaluating NULL IN (SELECT ... ) This is a special case, we don't need to search for NULL in the table, instead, the result value is - NULL if select produces empty row set - FALSE otherwise. In some cases (IN subselect is a top level item, i.e. abort_on_null==TRUE) the caller doesn't distinguish between NULL and FALSE result and we just return FALSE. Otherwise we make a full table scan to see if there is at least one matching row. The result of this function (info about whether a row was found) is stored in this->empty_result_set. NOTE RETURN FALSE - ok TRUE - an error occured while scanning */ int subselect_uniquesubquery_engine::exec() { DBUG_ENTER("subselect_uniquesubquery_engine::exec"); int error; TABLE *table= tab->table; empty_result_set= TRUE; table->status= 0; /* TODO: change to use of 'full_scan' here? */ if (copy_ref_key()) { /* TIMOUR: copy_ref_key() == 1 means NULL result, not error, why return 1? Check who reiles on this result. */ DBUG_RETURN(1); } if (table->status) { /* We know that there will be no rows even if we scan. Can be set in copy_ref_key. */ ((Item_in_subselect *) item)->value= 0; DBUG_RETURN(0); } if (!tab->preread_init_done && tab->preread_init()) DBUG_RETURN(1); if (null_keypart) DBUG_RETURN(scan_table()); if (!table->file->inited) table->file->ha_index_init(tab->ref.key, 0); error= table->file->ha_index_read_map(table->record[0], tab->ref.key_buff, make_prev_keypart_map(tab-> ref.key_parts), HA_READ_KEY_EXACT); if (error && error != HA_ERR_KEY_NOT_FOUND && error != HA_ERR_END_OF_FILE) error= report_error(table, error); else { error= 0; table->null_row= 0; if (!table->status && (!cond || cond->val_int())) { ((Item_in_subselect *) item)->value= 1; empty_result_set= FALSE; } else ((Item_in_subselect *) item)->value= 0; } DBUG_RETURN(error != 0); } /* TIMOUR: write comment */ int subselect_uniquesubquery_engine::index_lookup() { DBUG_ENTER("subselect_uniquesubquery_engine::index_lookup"); int error; TABLE *table= tab->table; if (!table->file->inited) table->file->ha_index_init(tab->ref.key, 0); error= table->file->ha_index_read_map(table->record[0], tab->ref.key_buff, make_prev_keypart_map(tab-> ref.key_parts), HA_READ_KEY_EXACT); DBUG_PRINT("info", ("lookup result: %i", error)); if (error && error != HA_ERR_KEY_NOT_FOUND && error != HA_ERR_END_OF_FILE) { /* TIMOUR: I don't understand at all when do we need to call report_error. In most places where we access an index, we don't do this. Why here? */ error= report_error(table, error); DBUG_RETURN(error); } table->null_row= 0; if (!error && (!cond || cond->val_int())) ((Item_in_subselect *) item)->value= 1; else ((Item_in_subselect *) item)->value= 0; DBUG_RETURN(0); } subselect_uniquesubquery_engine::~subselect_uniquesubquery_engine() { /* Tell handler we don't need the index anymore */ //psergey-merge-todo: the following was gone in 6.0: //psergey-merge: don't need this after all: tab->table->file->ha_index_end(); } /* Index-lookup subselect 'engine' - run the subquery SYNOPSIS subselect_indexsubquery_engine:exec() full_scan DESCRIPTION The engine is used to resolve subqueries in form oe IN (SELECT key FROM tbl WHERE subq_where) The value of the predicate is calculated as follows: 1. If oe IS NULL, this is a special case, do a full table scan on table tbl and search for row that satisfies subq_where. If such row is found, return NULL, otherwise return FALSE. 2. Make an index lookup via key=oe, search for a row that satisfies subq_where. If found, return TRUE. 3. If check_null==TRUE, make another lookup via key=NULL, search for a row that satisfies subq_where. If found, return NULL, otherwise return FALSE. TODO The step #1 can be optimized further when the index has several key parts. Consider a subquery: (oe1, oe2) IN (SELECT keypart1, keypart2 FROM tbl WHERE subq_where) and suppose we need to evaluate it for {oe1, oe2}=={const1, NULL}. Current code will do a full table scan and obtain correct result. There is a better option: instead of evaluating SELECT keypart1, keypart2 FROM tbl WHERE subq_where (1) and checking if it has produced any matching rows, evaluate SELECT keypart2 FROM tbl WHERE subq_where AND keypart1=const1 (2) If this query produces a row, the result is NULL (as we're evaluating "(const1, NULL) IN { (const1, X), ... }", which has a value of UNKNOWN, i.e. NULL). If the query produces no rows, the result is FALSE. We currently evaluate (1) by doing a full table scan. (2) can be evaluated by doing a "ref" scan on "keypart1=const1", which can be much cheaper. We can use index statistics to quickly check whether "ref" scan will be cheaper than full table scan. RETURN 0 1 */ int subselect_indexsubquery_engine::exec() { DBUG_ENTER("subselect_indexsubquery_engine"); int error; bool null_finding= 0; TABLE *table= tab->table; ((Item_in_subselect *) item)->value= 0; empty_result_set= TRUE; null_keypart= 0; table->status= 0; if (check_null) { /* We need to check for NULL if there wasn't a matching value */ *tab->ref.null_ref_key= 0; // Search first for not null ((Item_in_subselect *) item)->was_null= 0; } /* Copy the ref key and check for nulls... */ if (copy_ref_key()) DBUG_RETURN(1); if (table->status) { /* We know that there will be no rows even if we scan. Can be set in copy_ref_key. */ ((Item_in_subselect *) item)->value= 0; DBUG_RETURN(0); } if (!tab->preread_init_done && tab->preread_init()) DBUG_RETURN(1); if (null_keypart) DBUG_RETURN(scan_table()); if (!table->file->inited) table->file->ha_index_init(tab->ref.key, 1); error= table->file->ha_index_read_map(table->record[0], tab->ref.key_buff, make_prev_keypart_map(tab-> ref.key_parts), HA_READ_KEY_EXACT); if (error && error != HA_ERR_KEY_NOT_FOUND && error != HA_ERR_END_OF_FILE) error= report_error(table, error); else { for (;;) { error= 0; table->null_row= 0; if (!table->status) { if ((!cond || cond->val_int()) && (!having || having->val_int())) { empty_result_set= FALSE; if (null_finding) ((Item_in_subselect *) item)->was_null= 1; else ((Item_in_subselect *) item)->value= 1; break; } error= table->file->ha_index_next_same(table->record[0], tab->ref.key_buff, tab->ref.key_length); if (error && error != HA_ERR_END_OF_FILE) { error= report_error(table, error); break; } } else { if (!check_null || null_finding) break; /* We don't need to check nulls */ *tab->ref.null_ref_key= 1; null_finding= 1; /* Check if there exists a row with a null value in the index */ if ((error= (safe_index_read(tab) == 1))) break; } } } DBUG_RETURN(error != 0); } uint subselect_single_select_engine::cols() { //psergey-sj-backport: the following assert was gone in 6.0: //DBUG_ASSERT(select_lex->join != 0); // should be called after fix_fields() //return select_lex->join->fields_list.elements; return select_lex->item_list.elements; } uint subselect_union_engine::cols() { DBUG_ASSERT(unit->is_prepared()); // should be called after fix_fields() return unit->types.elements; } uint8 subselect_single_select_engine::uncacheable() { return select_lex->uncacheable; } uint8 subselect_union_engine::uncacheable() { return unit->uncacheable; } void subselect_single_select_engine::exclude() { select_lex->master_unit()->exclude_level(); } void subselect_union_engine::exclude() { unit->exclude_level(); } void subselect_uniquesubquery_engine::exclude() { //this never should be called DBUG_ASSERT(0); } table_map subselect_engine::calc_const_tables(List &list) { table_map map= 0; List_iterator ti(list); TABLE_LIST *table; //for (; table; table= table->next_leaf) while ((table= ti++)) { TABLE *tbl= table->table; if (tbl && tbl->const_table) map|= tbl->map; } return map; } table_map subselect_single_select_engine::upper_select_const_tables() { return calc_const_tables(select_lex->outer_select()->leaf_tables); } table_map subselect_union_engine::upper_select_const_tables() { return calc_const_tables(unit->outer_select()->leaf_tables); } void subselect_single_select_engine::print(String *str, enum_query_type query_type) { select_lex->print(thd, str, query_type); } void subselect_union_engine::print(String *str, enum_query_type query_type) { unit->print(str, query_type); } void subselect_uniquesubquery_engine::print(String *str, enum_query_type query_type) { char *table_name= tab->table->s->table_name.str; str->append(STRING_WITH_LEN("(")); tab->ref.items[0]->print(str, query_type); str->append(STRING_WITH_LEN(" in ")); if (tab->table->s->table_category == TABLE_CATEGORY_TEMPORARY) { /* Temporary tables' names change across runs, so they can't be used for EXPLAIN EXTENDED. */ str->append(STRING_WITH_LEN("")); } else str->append(table_name, tab->table->s->table_name.length); KEY *key_info= tab->table->key_info+ tab->ref.key; str->append(STRING_WITH_LEN(" on ")); str->append(key_info->name); if (cond) { str->append(STRING_WITH_LEN(" where ")); cond->print(str, query_type); } str->append(')'); } /* TODO: The above ::print method should be changed as below. Do it after all other tests pass. void subselect_uniquesubquery_engine::print(String *str) { KEY *key_info= tab->table->key_info + tab->ref.key; str->append(STRING_WITH_LEN("(")); for (uint i= 0; i < key_info->key_parts; i++) tab->ref.items[i]->print(str); str->append(STRING_WITH_LEN(" in ")); str->append(tab->table->s->table_name.str, tab->table->s->table_name.length); str->append(STRING_WITH_LEN(" on ")); str->append(key_info->name); if (cond) { str->append(STRING_WITH_LEN(" where ")); cond->print(str); } str->append(')'); } */ void subselect_indexsubquery_engine::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("(")); tab->ref.items[0]->print(str, query_type); str->append(STRING_WITH_LEN(" in ")); str->append(tab->table->s->table_name.str, tab->table->s->table_name.length); KEY *key_info= tab->table->key_info+ tab->ref.key; str->append(STRING_WITH_LEN(" on ")); str->append(key_info->name); if (check_null) str->append(STRING_WITH_LEN(" checking NULL")); if (cond) { str->append(STRING_WITH_LEN(" where ")); cond->print(str, query_type); } if (having) { str->append(STRING_WITH_LEN(" having ")); having->print(str, query_type); } str->append(')'); } /** change select_result object of engine. @param si new subselect Item @param res new select_result object @param temp temporary assignment @retval FALSE OK @retval TRUE error */ bool subselect_single_select_engine::change_result(Item_subselect *si, select_result_interceptor *res, bool temp) { item= si; if (temp) { /* Here we reuse change_item_tree to roll back assignment. It has nothing special about Item* pointer so it is safe conversion. We do not change the interface to be compatible with MySQL. */ thd->change_item_tree((Item**) &result, (Item*)res); } else result= res; /* We can't use 'result' below as gcc 4.2.4's alias optimization assumes that result was not changed by thd->change_item_tree(). I tried to find a solution to make gcc happy, but could not find anything that would not require a lot of extra code that would be harder to manage than the current code. */ return select_lex->join->change_result(res); } /** change select_result object of engine. @param si new subselect Item @param res new select_result object @retval FALSE OK @retval TRUE error */ bool subselect_union_engine::change_result(Item_subselect *si, select_result_interceptor *res, bool temp) { item= si; int rc= unit->change_result(res, result); if (temp) thd->change_item_tree((Item**) &result, (Item*)res); else result= res; return rc; } /** change select_result emulation, never should be called. @param si new subselect Item @param res new select_result object @retval FALSE OK @retval TRUE error */ bool subselect_uniquesubquery_engine::change_result(Item_subselect *si, select_result_interceptor *res, bool temp __attribute__((unused))) { DBUG_ASSERT(0); return TRUE; } /** Report about presence of tables in subquery. @retval TRUE there are not tables used in subquery @retval FALSE there are some tables in subquery */ bool subselect_single_select_engine::no_tables() { return(select_lex->table_list.elements == 0); } /* Check statically whether the subquery can return NULL SINOPSYS subselect_single_select_engine::may_be_null() RETURN FALSE can guarantee that the subquery never return NULL TRUE otherwise */ bool subselect_single_select_engine::may_be_null() { return ((no_tables() && !join->conds && !join->having) ? maybe_null : 1); } /** Report about presence of tables in subquery. @retval TRUE there are not tables used in subquery @retval FALSE there are some tables in subquery */ bool subselect_union_engine::no_tables() { for (SELECT_LEX *sl= unit->first_select(); sl; sl= sl->next_select()) { if (sl->table_list.elements) return FALSE; } return TRUE; } /** Report about presence of tables in subquery. @retval TRUE there are not tables used in subquery @retval FALSE there are some tables in subquery */ bool subselect_uniquesubquery_engine::no_tables() { /* returning value is correct, but this method should never be called */ DBUG_ASSERT(FALSE); return 0; } /****************************************************************************** WL#1110 - Implementation of class subselect_hash_sj_engine ******************************************************************************/ /** Check if an IN predicate should be executed via partial matching using only schema information. @details This test essentially has three results: - partial matching is applicable, but cannot be executed due to a limitation in the total number of indexes, as a result we can't use subquery materialization at all. - partial matching is either applicable or not, and this can be determined by looking at 'this->max_keys'. If max_keys > 1, then we need partial matching because there are more indexes than just the one we use during materialization to remove duplicates. @note TIMOUR: The schema-based analysis for partial matching can be done once for prepared statement and remembered. It is done here to remove the need to save/restore all related variables between each re-execution, thus making the code simpler. @retval PARTIAL_MATCH if a partial match should be used @retval COMPLETE_MATCH if a complete match (index lookup) should be used */ subselect_hash_sj_engine::exec_strategy subselect_hash_sj_engine::get_strategy_using_schema() { Item_in_subselect *item_in= (Item_in_subselect *) item; if (item_in->is_top_level_item()) return COMPLETE_MATCH; else { List_iterator inner_col_it(*item_in->unit->get_unit_column_types()); Item *outer_col, *inner_col; for (uint i= 0; i < item_in->left_expr->cols(); i++) { outer_col= item_in->left_expr->element_index(i); inner_col= inner_col_it++; if (!inner_col->maybe_null && !outer_col->maybe_null) bitmap_set_bit(&non_null_key_parts, i); else { bitmap_set_bit(&partial_match_key_parts, i); ++count_partial_match_columns; } } } /* If no column contains NULLs use regular hash index lookups. */ if (count_partial_match_columns) return PARTIAL_MATCH; return COMPLETE_MATCH; } /** Test whether an IN predicate must be computed via partial matching based on the NULL statistics for each column of a materialized subquery. @details The procedure analyzes column NULL statistics, updates the matching type of columns that cannot be NULL or that contain only NULLs. Based on this, the procedure determines the final execution strategy for the [NOT] IN predicate. @retval PARTIAL_MATCH if a partial match should be used @retval COMPLETE_MATCH if a complete match (index lookup) should be used */ subselect_hash_sj_engine::exec_strategy subselect_hash_sj_engine::get_strategy_using_data() { Item_in_subselect *item_in= (Item_in_subselect *) item; select_materialize_with_stats *result_sink= (select_materialize_with_stats *) result; Item *outer_col; /* If we already determined that a complete match is enough based on schema information, nothing can be better. */ if (strategy == COMPLETE_MATCH) return COMPLETE_MATCH; for (uint i= 0; i < item_in->left_expr->cols(); i++) { if (!bitmap_is_set(&partial_match_key_parts, i)) continue; outer_col= item_in->left_expr->element_index(i); /* If column 'i' doesn't contain NULLs, and the corresponding outer reference cannot have a NULL value, then 'i' is a non-nullable column. */ if (result_sink->get_null_count_of_col(i) == 0 && !outer_col->maybe_null) { bitmap_clear_bit(&partial_match_key_parts, i); bitmap_set_bit(&non_null_key_parts, i); --count_partial_match_columns; } if (result_sink->get_null_count_of_col(i) == tmp_table->file->stats.records) ++count_null_only_columns; if (result_sink->get_null_count_of_col(i)) ++count_columns_with_nulls; } /* If no column contains NULLs use regular hash index lookups. */ if (!count_partial_match_columns) return COMPLETE_MATCH; return PARTIAL_MATCH; } void subselect_hash_sj_engine::choose_partial_match_strategy( bool has_non_null_key, bool has_covering_null_row, MY_BITMAP *partial_match_key_parts) { ulonglong pm_buff_size; DBUG_ASSERT(strategy == PARTIAL_MATCH); /* Choose according to global optimizer switch. If only one of the switches is 'ON', then the remaining strategy is the only possible one. The only cases when this will be overriden is when the total size of all buffers for the merge strategy is bigger than the 'rowid_merge_buff_size' system variable, or if there isn't enough physical memory to allocate the buffers. */ if (!optimizer_flag(thd, OPTIMIZER_SWITCH_PARTIAL_MATCH_ROWID_MERGE) && optimizer_flag(thd, OPTIMIZER_SWITCH_PARTIAL_MATCH_TABLE_SCAN)) strategy= PARTIAL_MATCH_SCAN; else if ( optimizer_flag(thd, OPTIMIZER_SWITCH_PARTIAL_MATCH_ROWID_MERGE) && !optimizer_flag(thd, OPTIMIZER_SWITCH_PARTIAL_MATCH_TABLE_SCAN)) strategy= PARTIAL_MATCH_MERGE; /* If both switches are ON, or both are OFF, we interpret that as "let the optimizer decide". Perform a cost based choice between the two partial matching strategies. */ /* TIMOUR: the above interpretation of the switch values could be changed to: - if both are ON - let the optimizer decide, - if both are OFF - do not use partial matching, therefore do not use materialization in non-top-level predicates. The problem with this is that we know for sure if we need partial matching only after the subquery is materialized, and this is too late to revert to the IN=>EXISTS strategy. */ if (strategy == PARTIAL_MATCH) { /* TIMOUR: Currently we use a super simplistic measure. This will be addressed in a separate task. */ if (tmp_table->file->stats.records < 100) strategy= PARTIAL_MATCH_SCAN; else strategy= PARTIAL_MATCH_MERGE; } /* Check if there is enough memory for the rowid merge strategy. */ if (strategy == PARTIAL_MATCH_MERGE) { pm_buff_size= rowid_merge_buff_size(has_non_null_key, has_covering_null_row, partial_match_key_parts); if (pm_buff_size > thd->variables.rowid_merge_buff_size) strategy= PARTIAL_MATCH_SCAN; } } /* Compute the memory size of all buffers proportional to the number of rows in tmp_table. @details If the result is bigger than thd->variables.rowid_merge_buff_size, partial matching via merging is not applicable. */ ulonglong subselect_hash_sj_engine::rowid_merge_buff_size( bool has_non_null_key, bool has_covering_null_row, MY_BITMAP *partial_match_key_parts) { /* Total size of all buffers used by partial matching. */ ulonglong buff_size; ha_rows row_count= tmp_table->file->stats.records; uint rowid_length= tmp_table->file->ref_length; select_materialize_with_stats *result_sink= (select_materialize_with_stats *) result; ha_rows max_null_row; /* Size of the subselect_rowid_merge_engine::row_num_to_rowid buffer. */ buff_size= row_count * rowid_length * sizeof(uchar); if (has_non_null_key) { /* Add the size of Ordered_key::key_buff of the only non-NULL key. */ buff_size+= row_count * sizeof(rownum_t); } if (!has_covering_null_row) { for (uint i= 0; i < partial_match_key_parts->n_bits; i++) { if (!bitmap_is_set(partial_match_key_parts, i) || result_sink->get_null_count_of_col(i) == row_count) continue; /* In these cases we wouldn't construct Ordered keys. */ /* Add the size of Ordered_key::key_buff */ buff_size+= (row_count - result_sink->get_null_count_of_col(i)) * sizeof(rownum_t); /* Add the size of Ordered_key::null_key */ max_null_row= result_sink->get_max_null_of_col(i); if (max_null_row >= UINT_MAX) { /* There can be at most UINT_MAX bits in a MY_BITMAP that is used to store NULLs in an Ordered_key. Return a number of bytes bigger than the maximum allowed memory buffer for partial matching to disable the rowid merge strategy. */ return ULONGLONG_MAX; } buff_size+= bitmap_buffer_size(max_null_row); } } return buff_size; } /* Initialize a MY_BITMAP with a buffer allocated on the current memory root. TIMOUR: move to bitmap C file? */ static my_bool bitmap_init_memroot(MY_BITMAP *map, uint n_bits, MEM_ROOT *mem_root) { my_bitmap_map *bitmap_buf; if (!(bitmap_buf= (my_bitmap_map*) alloc_root(mem_root, bitmap_buffer_size(n_bits))) || bitmap_init(map, bitmap_buf, n_bits, FALSE)) return TRUE; bitmap_clear_all(map); return FALSE; } /** Create all structures needed for IN execution that can live between PS reexecution. @param tmp_columns the items that produce the data for the temp table @param subquery_id subquery's identifier (to make "" name for EXPLAIN) @details - Create a temporary table to store the result of the IN subquery. The temporary table has one hash index on all its columns. - Create a new result sink that sends the result stream of the subquery to the temporary table, @notice: Currently Item_subselect::init() already chooses and creates at parse time an engine with a corresponding JOIN to execute the subquery. @retval TRUE if error @retval FALSE otherwise */ bool subselect_hash_sj_engine::init(List *tmp_columns, uint subquery_id) { select_union *result_sink; /* Options to create_tmp_table. */ ulonglong tmp_create_options= thd->options | TMP_TABLE_ALL_COLUMNS; /* | TMP_TABLE_FORCE_MYISAM; TIMOUR: force MYISAM */ DBUG_ENTER("subselect_hash_sj_engine::init"); if (bitmap_init_memroot(&non_null_key_parts, tmp_columns->elements, thd->mem_root) || bitmap_init_memroot(&partial_match_key_parts, tmp_columns->elements, thd->mem_root)) DBUG_RETURN(TRUE); /* Create and initialize a select result interceptor that stores the result stream in a temporary table. The temporary table itself is managed (created/filled/etc) internally by the interceptor. */ /* TIMOUR: Select a more efficient result sink when we know there is no need to collect data statistics. if (strategy == COMPLETE_MATCH) { if (!(result= new select_union)) DBUG_RETURN(TRUE); } else if (strategy == PARTIAL_MATCH) { if (!(result= new select_materialize_with_stats)) DBUG_RETURN(TRUE); } */ if (!(result_sink= new select_materialize_with_stats)) DBUG_RETURN(TRUE); char buf[32]; uint len= my_snprintf(buf, sizeof(buf), "", subquery_id); char *name; if (!(name= (char*)thd->alloc(len + 1))) DBUG_RETURN(TRUE); memcpy(name, buf, len+1); result_sink->get_tmp_table_param()->materialized_subquery= true; if (result_sink->create_result_table(thd, tmp_columns, TRUE, tmp_create_options, name, TRUE, TRUE)) DBUG_RETURN(TRUE); tmp_table= result_sink->table; result= result_sink; /* If the subquery has blobs, or the total key lenght is bigger than some length, or the total number of key parts is more than the allowed maximum (currently MAX_REF_PARTS == 16), then the created index cannot be used for lookups and we can't use hash semi join. If this is the case, delete the temporary table since it will not be used, and tell the caller we failed to initialize the engine. */ if (tmp_table->s->keys == 0) { DBUG_ASSERT( tmp_table->s->uniques || tmp_table->key_info->key_length >= tmp_table->file->max_key_length() || tmp_table->key_info->key_parts > tmp_table->file->max_key_parts()); free_tmp_table(thd, tmp_table); tmp_table= NULL; delete result; result= NULL; DBUG_RETURN(TRUE); } /* Make sure there is only one index on the temp table, and it doesn't have the extra key part created when s->uniques > 0. */ DBUG_ASSERT(tmp_table->s->keys == 1 && ((Item_in_subselect *) item)->left_expr->cols() == tmp_table->key_info->key_parts); if (make_semi_join_conds() || /* A unique_engine is used both for complete and partial matching. */ !(lookup_engine= make_unique_engine())) DBUG_RETURN(TRUE); /* Repeat name resolution for 'cond' since cond is not part of any clause of the query, and it is not 'fixed' during JOIN::prepare. */ if (semi_join_conds && !semi_join_conds->fixed && semi_join_conds->fix_fields(thd, (Item**)&semi_join_conds)) DBUG_RETURN(TRUE); /* Let our engine reuse this query plan for materialization. */ materialize_join= materialize_engine->join; materialize_join->change_result(result); DBUG_RETURN(FALSE); } /* Create an artificial condition to post-filter those rows matched by index lookups that cannot be distinguished by the index lookup procedure. @notes The need for post-filtering may occur e.g. because of truncation. Prepared statements execution requires that fix_fields is called for every execution. In order to call fix_fields we need to create a Name_resolution_context and a corresponding TABLE_LIST for the temporary table for the subquery, so that all column references to the materialized subquery table can be resolved correctly. @returns @retval TRUE memory allocation error occurred @retval FALSE the conditions were created and resolved (fixed) */ bool subselect_hash_sj_engine::make_semi_join_conds() { /* Table reference for tmp_table that is used to resolve column references (Item_fields) to columns in tmp_table. */ TABLE_LIST *tmp_table_ref; /* Name resolution context for all tmp_table columns created below. */ Name_resolution_context *context; Item_in_subselect *item_in= (Item_in_subselect *) item; DBUG_ENTER("subselect_hash_sj_engine::make_semi_join_conds"); DBUG_ASSERT(semi_join_conds == NULL); if (!(semi_join_conds= new Item_cond_and)) DBUG_RETURN(TRUE); if (!(tmp_table_ref= (TABLE_LIST*) thd->alloc(sizeof(TABLE_LIST)))) DBUG_RETURN(TRUE); tmp_table_ref->init_one_table("", tmp_table->alias.c_ptr(), TL_READ); tmp_table_ref->table= tmp_table; context= new Name_resolution_context; context->init(); context->first_name_resolution_table= context->last_name_resolution_table= tmp_table_ref; semi_join_conds_context= context; for (uint i= 0; i < item_in->left_expr->cols(); i++) { Item_func_eq *eq_cond; /* New equi-join condition for the current column. */ /* Item for the corresponding field from the materialized temp table. */ Item_field *right_col_item; if (!(right_col_item= new Item_field(thd, context, tmp_table->field[i])) || !(eq_cond= new Item_func_eq(item_in->left_expr->element_index(i), right_col_item)) || (((Item_cond_and*)semi_join_conds)->add(eq_cond))) { delete semi_join_conds; semi_join_conds= NULL; DBUG_RETURN(TRUE); } } if (semi_join_conds->fix_fields(thd, (Item**)&semi_join_conds)) DBUG_RETURN(TRUE); DBUG_RETURN(FALSE); } /** Create a new uniquesubquery engine for the execution of an IN predicate. @details Create and initialize a new JOIN_TAB, and Table_ref objects to perform lookups into the indexed temporary table. @retval A new subselect_hash_sj_engine object @retval NULL if a memory allocation error occurs */ subselect_uniquesubquery_engine* subselect_hash_sj_engine::make_unique_engine() { Item_in_subselect *item_in= (Item_in_subselect *) item; Item_iterator_row it(item_in->left_expr); /* The only index on the temporary table. */ KEY *tmp_key= tmp_table->key_info; JOIN_TAB *tab; DBUG_ENTER("subselect_hash_sj_engine::make_unique_engine"); /* Create and initialize the JOIN_TAB that represents an index lookup plan operator into the materialized subquery result. Notice that: - this JOIN_TAB has no corresponding JOIN (and doesn't need one), and - here we initialize only those members that are used by subselect_uniquesubquery_engine, so these objects are incomplete. */ if (!(tab= (JOIN_TAB*) thd->alloc(sizeof(JOIN_TAB)))) DBUG_RETURN(NULL); tab->table= tmp_table; tab->preread_init_done= FALSE; tab->ref.tmp_table_index_lookup_init(thd, tmp_key, it, FALSE); DBUG_RETURN(new subselect_uniquesubquery_engine(thd, tab, item, semi_join_conds)); } subselect_hash_sj_engine::~subselect_hash_sj_engine() { delete lookup_engine; delete result; if (tmp_table) free_tmp_table(thd, tmp_table); } int subselect_hash_sj_engine::prepare() { /* Create and optimize the JOIN that will be used to materialize the subquery if not yet created. */ return materialize_engine->prepare(); } /** Cleanup performed after each PS execution. @details Called in the end of JOIN::prepare for PS from Item_subselect::cleanup. */ void subselect_hash_sj_engine::cleanup() { enum_engine_type lookup_engine_type= lookup_engine->engine_type(); is_materialized= FALSE; bitmap_clear_all(&non_null_key_parts); bitmap_clear_all(&partial_match_key_parts); count_partial_match_columns= 0; count_null_only_columns= 0; strategy= UNDEFINED; materialize_engine->cleanup(); /* Restore the original Item_in_subselect engine. This engine is created once at parse time and stored across executions, while all other materialization related engines are created and chosen for each execution. */ ((Item_in_subselect *) item)->engine= materialize_engine; if (lookup_engine_type == TABLE_SCAN_ENGINE || lookup_engine_type == ROWID_MERGE_ENGINE) { subselect_engine *inner_lookup_engine; inner_lookup_engine= ((subselect_partial_match_engine*) lookup_engine)->lookup_engine; /* Partial match engines are recreated for each PS execution inside subselect_hash_sj_engine::exec(). */ delete lookup_engine; lookup_engine= inner_lookup_engine; } DBUG_ASSERT(lookup_engine->engine_type() == UNIQUESUBQUERY_ENGINE); lookup_engine->cleanup(); result->cleanup(); /* Resets the temp table as well. */ DBUG_ASSERT(tmp_table); free_tmp_table(thd, tmp_table); tmp_table= NULL; } /* Get fanout produced by tables specified in the table_map */ double get_fanout_with_deps(JOIN *join, table_map tset) { /* Handle the case of "Impossible WHERE" */ if (join->table_count == 0) return 0.0; /* First, recursively get all tables we depend on */ table_map deps_to_check= tset; table_map checked_deps= 0; table_map further_deps; do { further_deps= 0; Table_map_iterator tm_it(deps_to_check); int tableno; while ((tableno = tm_it.next_bit()) != Table_map_iterator::BITMAP_END) { /* get tableno's dependency tables that are not in needed_set */ further_deps |= join->map2table[tableno]->ref.depend_map & ~checked_deps; } checked_deps |= deps_to_check; deps_to_check= further_deps; } while (further_deps != 0); /* Now, walk the join order and calculate the fanout */ double fanout= 1; for (JOIN_TAB *tab= first_top_level_tab(join, WITHOUT_CONST_TABLES); tab; tab= next_top_level_tab(join, tab)) { /* Ignore SJM nests. They have tab->table==NULL. There is no point to walk inside them, because GROUP BY clause cannot refer to tables from within subquery. */ if (!tab->is_sjm_nest() && (tab->table->map & checked_deps) && !tab->emb_sj_nest && tab->records_read != 0) { fanout *= rows2double(tab->records_read); } } return fanout; } #if 0 void check_out_index_stats(JOIN *join) { ORDER *order; uint n_order_items; /* First, collect the keys that we can use in each table. We can use a key if - all tables refer to it. */ key_map key_start_use[MAX_TABLES]; key_map key_infix_use[MAX_TABLES]; table_map key_used=0; table_map non_key_used= 0; bzero(&key_start_use, sizeof(key_start_use)); //psergey-todo: safe initialization! bzero(&key_infix_use, sizeof(key_infix_use)); for (order= join->group_list; order; order= order->next) { Item *item= order->item[0]; if (item->real_type() == Item::FIELD_ITEM) { if (item->used_tables() & OUTER_REF_TABLE_BIT) continue; /* outside references are like constants for us */ Field *field= ((Item_field*)item->real_item())->field; uint table_no= field->table->tablenr; if (!(non_key_used && table_map(1) << table_no) && !field->part_of_key.is_clear_all()) { key_map infix_map= field->part_of_key; infix_map.subtract(field->key_start); key_start_use[table_no].merge(field->key_start); key_infix_use[table_no].merge(infix_map); key_used |= table_no; } continue; } /* Note: the below will cause clauses like GROUP BY YEAR(date) not to be handled. */ non_key_used |= item->used_tables(); } Table_map_iterator tm_it(key_used & ~non_key_used); int tableno; while ((tableno = tm_it.next_bit()) != Table_map_iterator::BITMAP_END) { key_map::iterator key_it(key_start_use); int keyno; while ((keyno = tm_it.next_bit()) != key_map::iterator::BITMAP_END) { for (order= join->group_list; order; order= order->next) { Item *item= order->item[0]; if (item->used_tables() & (table_map(1) << tableno)) { DBUG_ASSERT(item->real_type() == Item::FIELD_ITEM); } } /* if (continuation) { walk through list and find which key parts are occupied; // note that the above can't be made any faster. } else use rec_per_key[0]; find out the cardinality. check if cardinality decreases if we use it; */ } } } #endif /* Get an estimate of how many records will be produced after the GROUP BY operation. @param join Join we're operating on @param join_op_rows How many records will be produced by the join operations (this is what join optimizer produces) @seealso See also optimize_semijoin_nests(), grep for "Adjust output cardinality estimates". Very similar code there that is not joined with this one because we operate on different data structs and too much effort is needed to abstract them out. @return Number of records we expect to get after the GROUP BY operation */ double get_post_group_estimate(JOIN* join, double join_op_rows) { table_map tables_in_group_list= table_map(0); /* Find out which tables are used in GROUP BY list */ for (ORDER *order= join->group_list; order; order= order->next) { Item *item= order->item[0]; if (item->used_tables() & RAND_TABLE_BIT) { /* Each join output record will be in its own group */ return join_op_rows; } tables_in_group_list|= item->used_tables(); } tables_in_group_list &= ~PSEUDO_TABLE_BITS; /* Use join fanouts to calculate the max. number of records in the group-list */ double fanout_rows[MAX_KEY]; bzero(&fanout_rows, sizeof(fanout_rows)); double out_rows; out_rows= get_fanout_with_deps(join, tables_in_group_list); #if 0 /* The following will be needed when making use of index stats: */ /* Also generate max. number of records for each of the tables mentioned in the group-list. We'll use that a baseline number that we'll try to reduce by using - #table-records - index statistics. */ Table_map_iterator tm_it(tables_in_group_list); int tableno; while ((tableno = tm_it.next_bit()) != Table_map_iterator::BITMAP_END) { fanout_rows[tableno]= get_fanout_with_deps(join, table_map(1) << tableno); } /* Try to bring down estimates using index statistics. */ //check_out_index_stats(join); #endif return out_rows; } /** Execute a subquery IN predicate via materialization. @details If needed materialize the subquery into a temporary table, then copmpute the predicate via a lookup into this table. @retval TRUE if error @retval FALSE otherwise */ int subselect_hash_sj_engine::exec() { Item_in_subselect *item_in= (Item_in_subselect *) item; SELECT_LEX *save_select= thd->lex->current_select; subselect_partial_match_engine *pm_engine= NULL; int res= 0; DBUG_ENTER("subselect_hash_sj_engine::exec"); /* Optimize and materialize the subquery during the first execution of the subquery predicate. */ thd->lex->current_select= materialize_engine->select_lex; /* The subquery should be optimized, and materialized only once. */ DBUG_ASSERT(materialize_join->optimized && !is_materialized); materialize_join->exec(); if ((res= test(materialize_join->error || thd->is_fatal_error || thd->is_error()))) goto err; /* TODO: - Unlock all subquery tables as we don't need them. To implement this we need to add new functionality to JOIN::join_free that can unlock all tables in a subquery (and all its subqueries). - The temp table used for grouping in the subquery can be freed immediately after materialization (yet it's done together with unlocking). */ is_materialized= TRUE; /* If the subquery returned no rows, the temporary table is empty, so we know directly that the result of IN is FALSE. We first update the table statistics, then we test if the temporary table for the query result is empty. */ tmp_table->file->info(HA_STATUS_VARIABLE); if (!tmp_table->file->stats.records) { /* The value of IN will not change during this execution. */ item_in->reset(); item_in->make_const(); item_in->set_first_execution(); DBUG_RETURN(FALSE); } /* TIMOUR: The schema-based analysis for partial matching can be done once for prepared statement and remembered. It is done here to remove the need to save/restore all related variables between each re-execution, thus making the code simpler. */ strategy= get_strategy_using_schema(); /* This call may discover that we don't need partial matching at all. */ strategy= get_strategy_using_data(); if (strategy == PARTIAL_MATCH) { uint count_pm_keys; /* Total number of keys needed for partial matching. */ MY_BITMAP *nn_key_parts= NULL; /* Key parts of the only non-NULL index. */ uint count_non_null_columns= 0; /* Number of columns in nn_key_parts. */ bool has_covering_null_row; bool has_covering_null_columns; select_materialize_with_stats *result_sink= (select_materialize_with_stats *) result; uint field_count= tmp_table->s->fields; if (count_partial_match_columns < field_count) { nn_key_parts= &non_null_key_parts; count_non_null_columns= bitmap_bits_set(nn_key_parts); } has_covering_null_row= (result_sink->get_max_nulls_in_row() == field_count); has_covering_null_columns= (count_non_null_columns + count_null_only_columns == field_count); if (has_covering_null_row && has_covering_null_columns) { /* The whole table consist of only NULL values. The result of IN is a constant UNKNOWN. */ DBUG_ASSERT(tmp_table->file->stats.records == 1); item_in->value= 0; item_in->null_value= 1; item_in->make_const(); item_in->set_first_execution(); DBUG_RETURN(FALSE); } if (has_covering_null_row) { DBUG_ASSERT(count_partial_match_columns = field_count); count_pm_keys= 0; } else if (has_covering_null_columns) count_pm_keys= 1; else count_pm_keys= count_partial_match_columns - count_null_only_columns + (nn_key_parts ? 1 : 0); choose_partial_match_strategy(test(nn_key_parts), has_covering_null_row, &partial_match_key_parts); DBUG_ASSERT(strategy == PARTIAL_MATCH_MERGE || strategy == PARTIAL_MATCH_SCAN); if (strategy == PARTIAL_MATCH_MERGE) { pm_engine= new subselect_rowid_merge_engine(thd, (subselect_uniquesubquery_engine*) lookup_engine, tmp_table, count_pm_keys, has_covering_null_row, has_covering_null_columns, count_columns_with_nulls, item, result, semi_join_conds->argument_list()); if (!pm_engine || ((subselect_rowid_merge_engine*) pm_engine)-> init(nn_key_parts, &partial_match_key_parts)) { /* The call to init() would fail if there was not enough memory to allocate all buffers for the rowid merge strategy. In this case revert to table scanning which doesn't need any big buffers. */ delete pm_engine; pm_engine= NULL; strategy= PARTIAL_MATCH_SCAN; } } if (strategy == PARTIAL_MATCH_SCAN) { if (!(pm_engine= new subselect_table_scan_engine(thd, (subselect_uniquesubquery_engine*) lookup_engine, tmp_table, item, result, semi_join_conds->argument_list(), has_covering_null_row, has_covering_null_columns, count_columns_with_nulls))) { /* This is an irrecoverable error. */ res= 1; goto err; } } } if (pm_engine) lookup_engine= pm_engine; item_in->change_engine(lookup_engine); err: thd->lex->current_select= save_select; DBUG_RETURN(res); } /** Print the state of this engine into a string for debugging and views. */ void subselect_hash_sj_engine::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN(" (")); materialize_engine->print(str, query_type); str->append(STRING_WITH_LEN(" ), ")); if (lookup_engine) lookup_engine->print(str, query_type); else str->append(STRING_WITH_LEN( "" )); } void subselect_hash_sj_engine::fix_length_and_dec(Item_cache** row) { DBUG_ASSERT(FALSE); } void subselect_hash_sj_engine::exclude() { DBUG_ASSERT(FALSE); } bool subselect_hash_sj_engine::no_tables() { DBUG_ASSERT(FALSE); return FALSE; } bool subselect_hash_sj_engine::change_result(Item_subselect *si, select_result_interceptor *res, bool temp __attribute__((unused))) { DBUG_ASSERT(FALSE); return TRUE; } Ordered_key::Ordered_key(uint keyid_arg, TABLE *tbl_arg, Item *search_key_arg, ha_rows null_count_arg, ha_rows min_null_row_arg, ha_rows max_null_row_arg, uchar *row_num_to_rowid_arg) : keyid(keyid_arg), tbl(tbl_arg), search_key(search_key_arg), row_num_to_rowid(row_num_to_rowid_arg), null_count(null_count_arg) { DBUG_ASSERT(tbl->file->stats.records > null_count); key_buff_elements= tbl->file->stats.records - null_count; cur_key_idx= HA_POS_ERROR; DBUG_ASSERT((null_count && min_null_row_arg && max_null_row_arg) || (!null_count && !min_null_row_arg && !max_null_row_arg)); if (null_count) { /* The counters are 1-based, for key access we need 0-based indexes. */ min_null_row= min_null_row_arg - 1; max_null_row= max_null_row_arg - 1; } else min_null_row= max_null_row= 0; } Ordered_key::~Ordered_key() { my_free((char*) key_buff, MYF(0)); bitmap_free(&null_key); } /* Cleanup that needs to be done for each PS (re)execution. */ void Ordered_key::cleanup() { /* Currently these keys are recreated for each PS re-execution, thus there is nothing to cleanup, the whole object goes away after execution is over. All handler related initialization/deinitialization is done by the parent subselect_rowid_merge_engine object. */ } /* Initialize a multi-column index. */ bool Ordered_key::init(MY_BITMAP *columns_to_index) { THD *thd= tbl->in_use; uint cur_key_col= 0; Item_field *cur_tmp_field; Item_func_lt *fn_less_than; key_column_count= bitmap_bits_set(columns_to_index); key_columns= (Item_field**) thd->alloc(key_column_count * sizeof(Item_field*)); compare_pred= (Item_func_lt**) thd->alloc(key_column_count * sizeof(Item_func_lt*)); if (!key_columns || !compare_pred) return TRUE; /* Revert to table scan partial match. */ for (uint i= 0; i < columns_to_index->n_bits; i++) { if (!bitmap_is_set(columns_to_index, i)) continue; cur_tmp_field= new Item_field(tbl->field[i]); /* Create the predicate (tmp_column[i] < outer_ref[i]). */ fn_less_than= new Item_func_lt(cur_tmp_field, search_key->element_index(i)); fn_less_than->fix_fields(thd, (Item**) &fn_less_than); key_columns[cur_key_col]= cur_tmp_field; compare_pred[cur_key_col]= fn_less_than; ++cur_key_col; } if (alloc_keys_buffers()) { /* TIMOUR revert to partial match via table scan. */ return TRUE; } return FALSE; } /* Initialize a single-column index. */ bool Ordered_key::init(int col_idx) { THD *thd= tbl->in_use; key_column_count= 1; // TIMOUR: check for mem allocation err, revert to scan key_columns= (Item_field**) thd->alloc(sizeof(Item_field*)); compare_pred= (Item_func_lt**) thd->alloc(sizeof(Item_func_lt*)); key_columns[0]= new Item_field(tbl->field[col_idx]); /* Create the predicate (tmp_column[i] < outer_ref[i]). */ compare_pred[0]= new Item_func_lt(key_columns[0], search_key->element_index(col_idx)); compare_pred[0]->fix_fields(thd, (Item**)&compare_pred[0]); if (alloc_keys_buffers()) { /* TIMOUR revert to partial match via table scan. */ return TRUE; } return FALSE; } /* Allocate the buffers for both the row number, and the NULL-bitmap indexes. */ bool Ordered_key::alloc_keys_buffers() { DBUG_ASSERT(key_buff_elements > 0); if (!(key_buff= (rownum_t*) my_malloc((size_t)(key_buff_elements * sizeof(rownum_t)), MYF(MY_WME)))) return TRUE; /* TIMOUR: it is enough to create bitmaps with size (max_null_row - min_null_row), and then use min_null_row as lookup offset. */ /* Notice that max_null_row is max array index, we need count, so +1. */ if (bitmap_init(&null_key, NULL, (uint)(max_null_row + 1), FALSE)) return TRUE; cur_key_idx= HA_POS_ERROR; return FALSE; } /* Quick sort comparison function that compares two rows of the same table indentfied with their row numbers. @retval -1 @retval 0 @retval +1 */ int Ordered_key::cmp_keys_by_row_data(ha_rows a, ha_rows b) { uchar *rowid_a, *rowid_b; int error, cmp_res; /* The length in bytes of the rowids (positions) of tmp_table. */ uint rowid_length= tbl->file->ref_length; if (a == b) return 0; /* Get the corresponding rowids. */ rowid_a= row_num_to_rowid + a * rowid_length; rowid_b= row_num_to_rowid + b * rowid_length; /* Fetch the rows for comparison. */ error= tbl->file->ha_rnd_pos(tbl->record[0], rowid_a); DBUG_ASSERT(!error); error= tbl->file->ha_rnd_pos(tbl->record[1], rowid_b); DBUG_ASSERT(!error); /* Compare the two rows by the corresponding values of the indexed columns. */ for (uint i= 0; i < key_column_count; i++) { Field *cur_field= key_columns[i]->field; if ((cmp_res= cur_field->cmp_offset(tbl->s->rec_buff_length))) return (cmp_res > 0 ? 1 : -1); } return 0; } int Ordered_key::cmp_keys_by_row_data_and_rownum(Ordered_key *key, rownum_t* a, rownum_t* b) { /* The result of comparing the two keys according to their row data. */ int cmp_row_res= key->cmp_keys_by_row_data(*a, *b); if (cmp_row_res) return cmp_row_res; return (*a < *b) ? -1 : (*a > *b) ? 1 : 0; } void Ordered_key::sort_keys() { my_qsort2(key_buff, (size_t) key_buff_elements, sizeof(rownum_t), (qsort2_cmp) &cmp_keys_by_row_data_and_rownum, (void*) this); /* Invalidate the current row position. */ cur_key_idx= HA_POS_ERROR; } /* The fraction of rows that do not contain NULL in the columns indexed by this key. @retval 1 if there are no NULLs @retval 0 if only NULLs */ double Ordered_key::null_selectivity() { /* We should not be processing empty tables. */ DBUG_ASSERT(tbl->file->stats.records); return (1 - (double) null_count / (double) tbl->file->stats.records); } /* Compare the value(s) of the current key in 'search_key' with the data of the current table record. @notes The comparison result follows from the way compare_pred is created in Ordered_key::init. Currently compare_pred compares a field in of the current row with the corresponding Item that contains the search key. @param row_num Number of the row (not index in the key_buff array) @retval -1 if (current row < search_key) @retval 0 if (current row == search_key) @retval +1 if (current row > search_key) */ int Ordered_key::cmp_key_with_search_key(rownum_t row_num) { /* The length in bytes of the rowids (positions) of tmp_table. */ uint rowid_length= tbl->file->ref_length; uchar *cur_rowid= row_num_to_rowid + row_num * rowid_length; int error, cmp_res; error= tbl->file->ha_rnd_pos(tbl->record[0], cur_rowid); DBUG_ASSERT(!error); for (uint i= 0; i < key_column_count; i++) { cmp_res= compare_pred[i]->get_comparator()->compare(); /* Unlike Arg_comparator::compare_row() here there should be no NULLs. */ DBUG_ASSERT(!compare_pred[i]->null_value); if (cmp_res) return (cmp_res > 0 ? 1 : -1); } return 0; } /* Find a key in a sorted array of keys via binary search. see create_subq_in_equalities() */ bool Ordered_key::lookup() { DBUG_ASSERT(key_buff_elements); ha_rows lo= 0; ha_rows hi= key_buff_elements - 1; ha_rows mid; int cmp_res; while (lo <= hi) { mid= lo + (hi - lo) / 2; cmp_res= cmp_key_with_search_key(key_buff[mid]); /* In order to find the minimum match, check if the pevious element is equal or smaller than the found one. If equal, we need to search further to the left. */ if (!cmp_res && mid > 0) cmp_res= !cmp_key_with_search_key(key_buff[mid - 1]) ? 1 : 0; if (cmp_res == -1) { /* row[mid] < search_key */ lo= mid + 1; } else if (cmp_res == 1) { /* row[mid] > search_key */ if (!mid) goto not_found; hi= mid - 1; } else { /* row[mid] == search_key */ cur_key_idx= mid; return TRUE; } } not_found: cur_key_idx= HA_POS_ERROR; return FALSE; } /* Move the current index pointer to the next key with the same column values as the current key. Since the index is sorted, all such keys are contiguous. */ bool Ordered_key::next_same() { DBUG_ASSERT(key_buff_elements); if (cur_key_idx < key_buff_elements - 1) { /* TIMOUR: The below is quite inefficient, since as a result we will fetch every row (except the last one) twice. There must be a more efficient way, e.g. swapping record[0] and record[1], and reading only the new record. */ if (!cmp_keys_by_row_data(key_buff[cur_key_idx], key_buff[cur_key_idx + 1])) { ++cur_key_idx; return TRUE; } } return FALSE; } void Ordered_key::print(String *str) { uint i; str->append("{idx="); str->qs_append(keyid); str->append(", ("); for (i= 0; i < key_column_count - 1; i++) { str->append(key_columns[i]->field->field_name); str->append(", "); } str->append(key_columns[i]->field->field_name); str->append("), "); str->append("null_bitmap: (bits="); str->qs_append(null_key.n_bits); str->append(", nulls= "); str->qs_append((double)null_count); str->append(", min_null= "); str->qs_append((double)min_null_row); str->append(", max_null= "); str->qs_append((double)max_null_row); str->append("), "); str->append('}'); } subselect_partial_match_engine::subselect_partial_match_engine( THD *thd_arg, subselect_uniquesubquery_engine *engine_arg, TABLE *tmp_table_arg, Item_subselect *item_arg, select_result_interceptor *result_arg, List *equi_join_conds_arg, bool has_covering_null_row_arg, bool has_covering_null_columns_arg, uint count_columns_with_nulls_arg) :subselect_engine(thd_arg, item_arg, result_arg), tmp_table(tmp_table_arg), lookup_engine(engine_arg), equi_join_conds(equi_join_conds_arg), has_covering_null_row(has_covering_null_row_arg), has_covering_null_columns(has_covering_null_columns_arg), count_columns_with_nulls(count_columns_with_nulls_arg) {} int subselect_partial_match_engine::exec() { Item_in_subselect *item_in= (Item_in_subselect *) item; int copy_res, lookup_res; /* Try to find a matching row by index lookup. */ copy_res= lookup_engine->copy_ref_key_simple(); if (copy_res == -1) { /* The result is FALSE based on the outer reference. */ item_in->value= 0; item_in->null_value= 0; return 0; } else if (copy_res == 0) { /* Search for a complete match. */ if ((lookup_res= lookup_engine->index_lookup())) { /* An error occured during lookup(). */ item_in->value= 0; item_in->null_value= 0; return lookup_res; } else if (item_in->value || !count_columns_with_nulls) { /* A complete match was found, the result of IN is TRUE. If no match was found, and there are no NULLs in the materialized subquery, then the result is guaranteed to be false because this branch is executed when the outer reference has no NULLs as well. Notice: (this->item == lookup_engine->item) */ return 0; } } if (has_covering_null_row) { /* If there is a NULL-only row that coveres all columns the result of IN is UNKNOWN. */ item_in->value= 0; /* TIMOUR: which one is the right way to propagate an UNKNOWN result? Should we also set empty_result_set= FALSE; ??? */ //item_in->was_null= 1; item_in->null_value= 1; return 0; } /* There is no complete match. Look for a partial match (UNKNOWN result), or no match (FALSE). */ if (tmp_table->file->inited) tmp_table->file->ha_index_end(); if (partial_match()) { /* The result of IN is UNKNOWN. */ item_in->value= 0; /* TIMOUR: which one is the right way to propagate an UNKNOWN result? Should we also set empty_result_set= FALSE; ??? */ //item_in->was_null= 1; item_in->null_value= 1; } else { /* The result of IN is FALSE. */ item_in->value= 0; /* TIMOUR: which one is the right way to propagate an UNKNOWN result? Should we also set empty_result_set= FALSE; ??? */ //item_in->was_null= 0; item_in->null_value= 0; } return 0; } void subselect_partial_match_engine::print(String *str, enum_query_type query_type) { /* Should never be called as the actual engine cannot be known at query optimization time. DBUG_ASSERT(FALSE); */ } /* @param non_null_key_parts @param partial_match_key_parts A union of all single-column NULL key parts. @retval FALSE the engine was initialized successfully @retval TRUE there was some (memory allocation) error during initialization, such errors should be interpreted as revert to other strategy */ bool subselect_rowid_merge_engine::init(MY_BITMAP *non_null_key_parts, MY_BITMAP *partial_match_key_parts) { /* The length in bytes of the rowids (positions) of tmp_table. */ uint rowid_length= tmp_table->file->ref_length; ha_rows row_count= tmp_table->file->stats.records; rownum_t cur_rownum= 0; select_materialize_with_stats *result_sink= (select_materialize_with_stats *) result; uint cur_keyid= 0; Item_in_subselect *item_in= (Item_in_subselect*) item; int error; if (merge_keys_count == 0) { DBUG_ASSERT(bitmap_bits_set(partial_match_key_parts) == 0 || has_covering_null_row); /* There is nothing to initialize, we will only do regular lookups. */ return FALSE; } /* If all nullable columns contain only NULLs, there must be one index over all non-null columns. */ DBUG_ASSERT(!has_covering_null_columns || (has_covering_null_columns && merge_keys_count == 1 && non_null_key_parts)); /* Allocate buffers to hold the merged keys and the mapping between rowids and row numbers. All small buffers are allocated in the runtime memroot. Big buffers are allocated from the OS via malloc. */ if (!(merge_keys= (Ordered_key**) thd->alloc(merge_keys_count * sizeof(Ordered_key*))) || !(null_bitmaps= (MY_BITMAP**) thd->alloc(merge_keys_count * sizeof(MY_BITMAP*))) || !(row_num_to_rowid= (uchar*) my_malloc((size_t)(row_count * rowid_length), MYF(MY_WME)))) return TRUE; /* Create the only non-NULL key if there is any. */ if (non_null_key_parts) { non_null_key= new Ordered_key(cur_keyid, tmp_table, item_in->left_expr, 0, 0, 0, row_num_to_rowid); if (non_null_key->init(non_null_key_parts)) return TRUE; merge_keys[cur_keyid]= non_null_key; merge_keys[cur_keyid]->first(); ++cur_keyid; } /* If all nullable columns contain NULLs, the only key that is needed is the only non-NULL key that is already created above. */ if (!has_covering_null_columns) { if (bitmap_init_memroot(&matching_keys, merge_keys_count, thd->mem_root) || bitmap_init_memroot(&matching_outer_cols, merge_keys_count, thd->mem_root)) return TRUE; /* Create one single-column NULL-key for each column in partial_match_key_parts. */ for (uint i= 0; i < partial_match_key_parts->n_bits; i++) { /* Skip columns that have no NULLs, or contain only NULLs. */ if (!bitmap_is_set(partial_match_key_parts, i) || result_sink->get_null_count_of_col(i) == row_count) continue; merge_keys[cur_keyid]= new Ordered_key( cur_keyid, tmp_table, item_in->left_expr->element_index(i), result_sink->get_null_count_of_col(i), result_sink->get_min_null_of_col(i), result_sink->get_max_null_of_col(i), row_num_to_rowid); if (merge_keys[cur_keyid]->init(i)) return TRUE; merge_keys[cur_keyid]->first(); ++cur_keyid; } } DBUG_ASSERT(cur_keyid == merge_keys_count); /* Populate the indexes with data from the temporary table. */ if (tmp_table->file->ha_rnd_init_with_error(1)) return TRUE; tmp_table->file->extra_opt(HA_EXTRA_CACHE, current_thd->variables.read_buff_size); tmp_table->null_row= 0; while (TRUE) { error= tmp_table->file->ha_rnd_next(tmp_table->record[0]); if (error == HA_ERR_RECORD_DELETED) { /* We get this for duplicate records that should not be in tmp_table. */ continue; } /* This is a temp table that we fully own, there should be no other cause to stop the iteration than EOF. */ DBUG_ASSERT(!error || error == HA_ERR_END_OF_FILE); if (error == HA_ERR_END_OF_FILE) { DBUG_ASSERT(cur_rownum == tmp_table->file->stats.records); break; } /* Save the position of this record in the row_num -> rowid mapping. */ tmp_table->file->position(tmp_table->record[0]); memcpy(row_num_to_rowid + cur_rownum * rowid_length, tmp_table->file->ref, rowid_length); /* Add the current row number to the corresponding keys. */ if (non_null_key) { /* By definition there are no NULLs in the non-NULL key. */ non_null_key->add_key(cur_rownum); } for (uint i= (non_null_key ? 1 : 0); i < merge_keys_count; i++) { /* Check if the first and only indexed column contains NULL in the curent row, and add the row number to the corresponding key. */ if (tmp_table->field[merge_keys[i]->get_field_idx(0)]->is_null()) merge_keys[i]->set_null(cur_rownum); else merge_keys[i]->add_key(cur_rownum); } ++cur_rownum; } tmp_table->file->ha_rnd_end(); /* Sort all the keys by their NULL selectivity. */ my_qsort(merge_keys, merge_keys_count, sizeof(Ordered_key*), (qsort_cmp) cmp_keys_by_null_selectivity); /* Sort the keys in each of the indexes. */ for (uint i= 0; i < merge_keys_count; i++) merge_keys[i]->sort_keys(); if (init_queue(&pq, merge_keys_count, 0, FALSE, subselect_rowid_merge_engine::cmp_keys_by_cur_rownum, NULL, 0, 0)) return TRUE; return FALSE; } subselect_rowid_merge_engine::~subselect_rowid_merge_engine() { /* None of the resources below is allocated if there are no ordered keys. */ if (merge_keys_count) { my_free((char*) row_num_to_rowid, MYF(0)); for (uint i= 0; i < merge_keys_count; i++) delete merge_keys[i]; delete_queue(&pq); if (tmp_table->file->inited == handler::RND) tmp_table->file->ha_rnd_end(); } } void subselect_rowid_merge_engine::cleanup() { } /* Quick sort comparison function to compare keys in order of decreasing bitmap selectivity, so that the most selective keys come first. @param k1 first key to compare @param k2 second key to compare @retval 1 if k1 is less selective than k2 @retval 0 if k1 is equally selective as k2 @retval -1 if k1 is more selective than k2 */ int subselect_rowid_merge_engine::cmp_keys_by_null_selectivity(Ordered_key **k1, Ordered_key **k2) { double k1_sel= (*k1)->null_selectivity(); double k2_sel= (*k2)->null_selectivity(); if (k1_sel < k2_sel) return 1; if (k1_sel > k2_sel) return -1; return 0; } /* */ int subselect_rowid_merge_engine::cmp_keys_by_cur_rownum(void *arg, uchar *k1, uchar *k2) { rownum_t r1= ((Ordered_key*) k1)->current(); rownum_t r2= ((Ordered_key*) k2)->current(); return (r1 < r2) ? -1 : (r1 > r2) ? 1 : 0; } /* Check if certain table row contains a NULL in all columns for which there is no match in the corresponding value index. @note There is no need to check the columns that contain only NULLs, because those are guaranteed to match. @retval TRUE if a NULL row exists @retval FALSE otherwise */ bool subselect_rowid_merge_engine::test_null_row(rownum_t row_num) { Ordered_key *cur_key; for (uint i = 0; i < merge_keys_count; i++) { cur_key= merge_keys[i]; if (bitmap_is_set(&matching_keys, cur_key->get_keyid())) { /* The key 'i' (with id 'cur_keyid') already matches a value in row 'row_num', thus we skip it as it can't possibly match a NULL. */ continue; } if (!cur_key->is_null(row_num)) return FALSE; } return TRUE; } /** Test if a subset of NULL-able columns contains a row of NULLs. @retval TRUE if such a row exists @retval FALSE no complementing null row */ bool subselect_rowid_merge_engine:: exists_complementing_null_row(MY_BITMAP *keys_to_complement) { rownum_t highest_min_row= 0; rownum_t lowest_max_row= UINT_MAX; uint count_null_keys, i; Ordered_key *cur_key; if (!count_columns_with_nulls) { /* If there are both NULLs and non-NUll values in the outer reference, and the subquery contains no NULLs, a complementing NULL row cannot exist. */ return FALSE; } for (i= (non_null_key ? 1 : 0), count_null_keys= 0; i < merge_keys_count; i++) { cur_key= merge_keys[i]; if (bitmap_is_set(keys_to_complement, cur_key->get_keyid())) continue; if (!cur_key->get_null_count()) { /* If there is column without NULLs, there cannot be a partial match. */ return FALSE; } if (cur_key->get_min_null_row() > highest_min_row) highest_min_row= cur_key->get_min_null_row(); if (cur_key->get_max_null_row() < lowest_max_row) lowest_max_row= cur_key->get_max_null_row(); null_bitmaps[count_null_keys++]= cur_key->get_null_key(); } if (lowest_max_row < highest_min_row) { /* The intersection of NULL rows is empty. */ return FALSE; } return bitmap_exists_intersection((const MY_BITMAP**) null_bitmaps, count_null_keys, (uint)highest_min_row, (uint)lowest_max_row); } /* @retval TRUE there is a partial match (UNKNOWN) @retval FALSE there is no match at all (FALSE) */ bool subselect_rowid_merge_engine::partial_match() { Ordered_key *min_key; /* Key that contains the current minimum position. */ rownum_t min_row_num; /* Current row number of min_key. */ Ordered_key *cur_key; rownum_t cur_row_num; uint count_nulls_in_search_key= 0; uint max_null_in_any_row= ((select_materialize_with_stats *) result)->get_max_nulls_in_row(); bool res= FALSE; /* If there is a non-NULL key, it must be the first key in the keys array. */ DBUG_ASSERT(!non_null_key || (non_null_key && merge_keys[0] == non_null_key)); /* The prioryty queue for keys must be empty. */ DBUG_ASSERT(!pq.elements); /* All data accesses during execution are via handler::ha_rnd_pos() */ if (tmp_table->file->ha_rnd_init_with_error(0)) { res= FALSE; goto end; } /* Check if there is a match for the columns of the only non-NULL key. */ if (non_null_key && !non_null_key->lookup()) { res= FALSE; goto end; } /* If all nullable columns contain only NULLs, then there is a guranteed partial match, and we don't need to search for a matching row. */ if (has_covering_null_columns) { res= TRUE; goto end; } if (non_null_key) queue_insert(&pq, (uchar *) non_null_key); /* Do not add the non_null_key, since it was already processed above. */ bitmap_clear_all(&matching_outer_cols); for (uint i= test(non_null_key); i < merge_keys_count; i++) { DBUG_ASSERT(merge_keys[i]->get_column_count() == 1); if (merge_keys[i]->get_search_key(0)->null_value) { ++count_nulls_in_search_key; bitmap_set_bit(&matching_outer_cols, merge_keys[i]->get_keyid()); } else if (merge_keys[i]->lookup()) queue_insert(&pq, (uchar *) merge_keys[i]); } /* If the outer reference consists of only NULLs, or if it has NULLs in all nullable columns (above we guarantee there is a match for the non-null coumns), the result is UNKNOWN. */ if (count_nulls_in_search_key == merge_keys_count - test(non_null_key)) { res= TRUE; goto end; } /* If the outer row has NULLs in some columns, and there is no match for any of the remaining columns, and there is a subquery row with NULLs in all unmatched columns, then there is a partial match, otherwise the result is FALSE. */ if (count_nulls_in_search_key && !pq.elements) { DBUG_ASSERT(!non_null_key); /* Check if the intersection of all NULL bitmaps of all keys that are not in matching_outer_cols is non-empty. */ res= exists_complementing_null_row(&matching_outer_cols); goto end; } /* If there is no NULL (sub)row that covers all NULL columns, and there is no match for any of the NULL columns, the result is FALSE. Notice that if there is a non-null key, and there is only one matching key, the non-null key is the matching key. This is so, because this method returns FALSE if the non-null key doesn't have a match. */ if (!count_nulls_in_search_key && (!pq.elements || (pq.elements == 1 && non_null_key && max_null_in_any_row < merge_keys_count-1))) { if (!pq.elements) { DBUG_ASSERT(!non_null_key); /* The case of a covering null row is handled by subselect_partial_match_engine::exec() */ DBUG_ASSERT(max_null_in_any_row != tmp_table->s->fields); } res= FALSE; goto end; } DBUG_ASSERT(pq.elements); min_key= (Ordered_key*) queue_remove_top(&pq); min_row_num= min_key->current(); bitmap_set_bit(&matching_keys, min_key->get_keyid()); bitmap_union(&matching_keys, &matching_outer_cols); if (min_key->next_same()) queue_insert(&pq, (uchar *) min_key); if (pq.elements == 0) { /* Check the only matching row of the only key min_key for NULL matches in the other columns. */ res= test_null_row(min_row_num); goto end; } while (TRUE) { cur_key= (Ordered_key*) queue_remove_top(&pq); cur_row_num= cur_key->current(); if (cur_row_num == min_row_num) bitmap_set_bit(&matching_keys, cur_key->get_keyid()); else { /* Follows from the correct use of priority queue. */ DBUG_ASSERT(cur_row_num > min_row_num); if (test_null_row(min_row_num)) { res= TRUE; goto end; } else { min_key= cur_key; min_row_num= cur_row_num; bitmap_clear_all(&matching_keys); bitmap_set_bit(&matching_keys, min_key->get_keyid()); bitmap_union(&matching_keys, &matching_outer_cols); } } if (cur_key->next_same()) queue_insert(&pq, (uchar *) cur_key); if (pq.elements == 0) { /* Check the last row of the last column in PQ for NULL matches. */ res= test_null_row(min_row_num); goto end; } } /* We should never get here - all branches must be handled explicitly above. */ DBUG_ASSERT(FALSE); end: if (!has_covering_null_columns) bitmap_clear_all(&matching_keys); queue_remove_all(&pq); tmp_table->file->ha_rnd_end(); return res; } subselect_table_scan_engine::subselect_table_scan_engine( THD *thd_arg, subselect_uniquesubquery_engine *engine_arg, TABLE *tmp_table_arg, Item_subselect *item_arg, select_result_interceptor *result_arg, List *equi_join_conds_arg, bool has_covering_null_row_arg, bool has_covering_null_columns_arg, uint count_columns_with_nulls_arg) :subselect_partial_match_engine(thd_arg, engine_arg, tmp_table_arg, item_arg, result_arg, equi_join_conds_arg, has_covering_null_row_arg, has_covering_null_columns_arg, count_columns_with_nulls_arg) {} /* TIMOUR: This method is based on subselect_uniquesubquery_engine::scan_table(). Consider refactoring somehow, 80% of the code is the same. for each row_i in tmp_table { count_matches= 0; for each row element row_i[j] { if (outer_ref[j] is NULL || row_i[j] is NULL || outer_ref[j] == row_i[j]) ++count_matches; } if (count_matches == outer_ref.elements) return TRUE } return FALSE */ bool subselect_table_scan_engine::partial_match() { List_iterator_fast equality_it(*equi_join_conds); Item *cur_eq; uint count_matches; int error; bool res; if (tmp_table->file->ha_rnd_init_with_error(1)) { res= FALSE; goto end; } tmp_table->file->extra_opt(HA_EXTRA_CACHE, current_thd->variables.read_buff_size); for (;;) { error= tmp_table->file->ha_rnd_next(tmp_table->record[0]); if (error) { if (error == HA_ERR_RECORD_DELETED) { error= 0; continue; } if (error == HA_ERR_END_OF_FILE) { error= 0; break; } else { error= report_error(tmp_table, error); break; } } equality_it.rewind(); count_matches= 0; while ((cur_eq= equality_it++)) { DBUG_ASSERT(cur_eq->type() == Item::FUNC_ITEM && ((Item_func*)cur_eq)->functype() == Item_func::EQ_FUNC); if (!cur_eq->val_int() && !cur_eq->null_value) break; ++count_matches; } if (count_matches == tmp_table->s->fields) { res= TRUE; /* Found a matching row. */ goto end; } } res= FALSE; end: tmp_table->file->ha_rnd_end(); return res; } void subselect_table_scan_engine::cleanup() { }