/* Copyright (c) 2000, 2018, Oracle and/or its affiliates. Copyright (c) 2010, 2020, MariaDB Corporation. 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., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */ #ifdef USE_PRAGMA_IMPLEMENTATION #pragma implementation // gcc: Class implementation #endif #include /* NO_EMBEDDED_ACCESS_CHECKS */ #include "sql_priv.h" #include #include #include "my_dir.h" #include "sp_rcontext.h" #include "sp_head.h" #include "sql_trigger.h" #include "sql_select.h" #include "sql_show.h" // append_identifier #include "sql_view.h" // VIEW_ANY_SQL #include "sql_time.h" // str_to_datetime_with_warn, // make_truncated_value_warning #include "sql_acl.h" // get_column_grant, // SELECT_ACL, UPDATE_ACL, // INSERT_ACL, // check_grant_column #include "sql_base.h" // enum_resolution_type, // REPORT_EXCEPT_NOT_FOUND, // find_item_in_list, // RESOLVED_AGAINST_ALIAS, ... #include "sql_expression_cache.h" const String my_null_string("NULL", 4, default_charset_info); const String my_default_string("DEFAULT", 7, default_charset_info); static int save_field_in_field(Field *, bool *, Field *, bool); /** Compare two Items for List::add_unique() */ bool cmp_items(Item *a, Item *b) { return a->eq(b, FALSE); } /** Set max_sum_func_level if it is needed */ inline void set_max_sum_func_level(SELECT_LEX *select) { LEX *lex_s= select->parent_lex; if (lex_s->in_sum_func && lex_s->in_sum_func->nest_level >= select->nest_level) set_if_bigger(lex_s->in_sum_func->max_sum_func_level, select->nest_level - 1); } /***************************************************************************** ** Item functions *****************************************************************************/ /** Init all special items. */ void item_init(void) { item_func_sleep_init(); uuid_short_init(); } void Item::push_note_converted_to_negative_complement(THD *thd) { push_warning(thd, Sql_condition::WARN_LEVEL_NOTE, ER_UNKNOWN_ERROR, "Cast to signed converted positive out-of-range integer to " "it's negative complement"); } void Item::push_note_converted_to_positive_complement(THD *thd) { push_warning(thd, Sql_condition::WARN_LEVEL_NOTE, ER_UNKNOWN_ERROR, "Cast to unsigned converted negative integer to it's " "positive complement"); } /** @todo Make this functions class dependent */ bool Item::val_bool() { switch(result_type()) { case INT_RESULT: return val_int() != 0; case DECIMAL_RESULT: { my_decimal decimal_value; my_decimal *val= val_decimal(&decimal_value); if (val) return !my_decimal_is_zero(val); return 0; } case REAL_RESULT: case STRING_RESULT: return val_real() != 0.0; case ROW_RESULT: case TIME_RESULT: DBUG_ASSERT(0); return 0; // Wrong (but safe) } return 0; // Wrong (but safe) } /** Get date/time/datetime. Optionally extend TIME result to DATETIME. */ bool Item::get_date_with_conversion(MYSQL_TIME *ltime, ulonglong fuzzydate) { THD *thd= current_thd; /* Some TIME type items return error when trying to do get_date() without TIME_TIME_ONLY set (e.g. Item_field for Field_time). In the SQL standard time->datetime conversion mode we add TIME_TIME_ONLY. In the legacy time->datetime conversion mode we do not add TIME_TIME_ONLY and leave it to get_date() to check date. */ ulonglong time_flag= (field_type() == MYSQL_TYPE_TIME && !(thd->variables.old_behavior & OLD_MODE_ZERO_DATE_TIME_CAST)) ? TIME_TIME_ONLY : 0; if (get_date(ltime, fuzzydate | time_flag)) return true; if (ltime->time_type == MYSQL_TIMESTAMP_TIME && !(fuzzydate & TIME_TIME_ONLY) && convert_time_to_datetime(thd, ltime, fuzzydate)) return true; return false; } longlong Item::val_datetime_packed_result() { MYSQL_TIME ltime, tmp; if (get_date_result(<ime, TIME_FUZZY_DATES | TIME_INVALID_DATES)) return 0; if (ltime.time_type != MYSQL_TIMESTAMP_TIME) return pack_time(<ime); if ((null_value= time_to_datetime_with_warn(current_thd, <ime, &tmp, 0))) return 0; return pack_time(&tmp); } /** Get date/time/datetime. If DATETIME or DATE result is returned, it's converted to TIME. */ bool Item::get_time_with_conversion(THD *thd, MYSQL_TIME *ltime, ulonglong fuzzydate) { if (get_date(ltime, fuzzydate)) return true; if (ltime->time_type != MYSQL_TIMESTAMP_TIME) { MYSQL_TIME ltime2; if ((thd->variables.old_behavior & OLD_MODE_ZERO_DATE_TIME_CAST) && (ltime->year || ltime->day || ltime->month)) { /* Old mode conversion from DATETIME with non-zero YYYYMMDD part to TIME works very inconsistently. Possible variants: - truncate the YYYYMMDD part - add (MM*33+DD)*24 to hours - add (MM*31+DD)*24 to hours Let's return TRUE here, to disallow equal field propagation. Note, If we start to use this method in more pieces of the code other than equal field propagation, we should probably return TRUE only if some flag in fuzzydate is set. */ return true; } if (datetime_to_time_with_warn(thd, ltime, <ime2, TIME_SECOND_PART_DIGITS)) { /* If the time difference between CURRENT_DATE and ltime did not fit into the supported TIME range, then we set the difference to the maximum possible value in the supported TIME range */ DBUG_ASSERT(0); return (null_value= true); } *ltime= ltime2; } return false; } /* For the items which don't have its own fast val_str_ascii() implementation we provide a generic slower version, which converts from the Item character set to ASCII. For better performance conversion happens only in case of a "tricky" Item character set (e.g. UCS2). Normally conversion does not happen. */ String *Item::val_str_ascii(String *str) { DBUG_ASSERT(str != &str_value); uint errors; String *res= val_str(&str_value); if (!res) return 0; if (!(res->charset()->state & MY_CS_NONASCII)) str= res; else { if ((null_value= str->copy(res->ptr(), res->length(), collation.collation, &my_charset_latin1, &errors))) return 0; } return str; } String *Item::val_str(String *str, String *converter, CHARSET_INFO *cs) { String *res= val_str(str); if (null_value) return (String *) 0; if (!cs) return res; uint errors; if ((null_value= converter->copy(res->ptr(), res->length(), collation.collation, cs, &errors))) return (String *) 0; return converter; } String *Item::val_string_from_real(String *str) { double nr= val_real(); if (null_value) return 0; /* purecov: inspected */ str->set_real(nr,decimals, &my_charset_numeric); return str; } String *Item::val_string_from_int(String *str) { longlong nr= val_int(); if (null_value) return 0; str->set_int(nr, unsigned_flag, &my_charset_numeric); return str; } String *Item::val_string_from_decimal(String *str) { my_decimal dec_buf, *dec= val_decimal(&dec_buf); if (null_value) return 0; my_decimal_round(E_DEC_FATAL_ERROR, dec, decimals, FALSE, &dec_buf); my_decimal2string(E_DEC_FATAL_ERROR, &dec_buf, 0, 0, 0, str); return str; } /* All val_xxx_from_date() must call this method, to expose consistent behaviour regarding SQL_MODE when converting DATE/DATETIME to other data types. */ bool Item::get_temporal_with_sql_mode(MYSQL_TIME *ltime) { return get_date(ltime, field_type() == MYSQL_TYPE_TIME ? TIME_TIME_ONLY : sql_mode_for_dates(current_thd)); } bool Item::is_null_from_temporal() { MYSQL_TIME ltime; return get_temporal_with_sql_mode(<ime); } String *Item::val_string_from_date(String *str) { MYSQL_TIME ltime; if (get_temporal_with_sql_mode(<ime) || str->alloc(MAX_DATE_STRING_REP_LENGTH)) { null_value= 1; return (String *) 0; } str->length(my_TIME_to_str(<ime, const_cast(str->ptr()), decimals)); str->set_charset(&my_charset_numeric); return str; } my_decimal *Item::val_decimal_from_real(my_decimal *decimal_value) { double nr= val_real(); if (null_value) return 0; double2my_decimal(E_DEC_FATAL_ERROR, nr, decimal_value); return (decimal_value); } my_decimal *Item::val_decimal_from_int(my_decimal *decimal_value) { longlong nr= val_int(); if (null_value) return 0; int2my_decimal(E_DEC_FATAL_ERROR, nr, unsigned_flag, decimal_value); return decimal_value; } my_decimal *Item::val_decimal_from_string(my_decimal *decimal_value) { String *res; if (!(res= val_str(&str_value))) return 0; return decimal_from_string_with_check(decimal_value, res); } my_decimal *Item::val_decimal_from_date(my_decimal *decimal_value) { DBUG_ASSERT(fixed == 1); MYSQL_TIME ltime; if (get_temporal_with_sql_mode(<ime)) { my_decimal_set_zero(decimal_value); null_value= 1; // set NULL, stop processing return 0; } return date2my_decimal(<ime, decimal_value); } my_decimal *Item::val_decimal_from_time(my_decimal *decimal_value) { DBUG_ASSERT(fixed == 1); MYSQL_TIME ltime; if (get_time(<ime)) { my_decimal_set_zero(decimal_value); return 0; } return date2my_decimal(<ime, decimal_value); } longlong Item::val_int_from_date() { DBUG_ASSERT(fixed == 1); MYSQL_TIME ltime; if (get_temporal_with_sql_mode(<ime)) return 0; longlong v= TIME_to_ulonglong(<ime); return ltime.neg ? -v : v; } double Item::val_real_from_date() { DBUG_ASSERT(fixed == 1); MYSQL_TIME ltime; if (get_temporal_with_sql_mode(<ime)) return 0; return TIME_to_double(<ime); } double Item::val_real_from_decimal() { /* Note that fix_fields may not be called for Item_avg_field items */ double result; my_decimal value_buff, *dec_val= val_decimal(&value_buff); if (null_value) return 0.0; my_decimal2double(E_DEC_FATAL_ERROR, dec_val, &result); return result; } longlong Item::val_int_from_decimal() { /* Note that fix_fields may not be called for Item_avg_field items */ longlong result; my_decimal value, *dec_val= val_decimal(&value); if (null_value) return 0; my_decimal2int(E_DEC_FATAL_ERROR, dec_val, unsigned_flag, &result); return result; } int Item::save_time_in_field(Field *field) { MYSQL_TIME ltime; if (get_time(<ime)) return set_field_to_null_with_conversions(field, 0); field->set_notnull(); return field->store_time_dec(<ime, decimals); } int Item::save_date_in_field(Field *field) { MYSQL_TIME ltime; if (get_date(<ime, sql_mode_for_dates(field->table->in_use))) return set_field_to_null_with_conversions(field, 0); field->set_notnull(); return field->store_time_dec(<ime, decimals); } /* Store the string value in field directly SYNOPSIS Item::save_str_value_in_field() field a pointer to field where to store result the pointer to the string value to be stored DESCRIPTION The method is used by Item_*::save_in_field implementations when we don't need to calculate the value to store See Item_string::save_in_field() implementation for example IMPLEMENTATION Check if the Item is null and stores the NULL or the result value in the field accordingly. RETURN Nonzero value if error */ int Item::save_str_value_in_field(Field *field, String *result) { if (null_value) return set_field_to_null(field); field->set_notnull(); return field->store(result->ptr(), result->length(), collation.collation); } Item::Item(THD *thd): is_expensive_cache(-1), rsize(0), name(0), orig_name(0), name_length(0), fixed(0), is_autogenerated_name(TRUE) { DBUG_ASSERT(thd); marker= 0; maybe_null=null_value=with_sum_func=with_window_func=with_field=0; in_rollup= 0; with_subselect= 0; with_param= 0; /* Initially this item is not attached to any JOIN_TAB. */ join_tab_idx= MAX_TABLES; /* Put item in free list so that we can free all items at end */ next= thd->free_list; thd->free_list= this; /* Item constructor can be called during execution other then SQL_COM command => we should check thd->lex->current_select on zero (thd->lex can be uninitialised) */ if (thd->lex->current_select) { enum_parsing_place place= thd->lex->current_select->parsing_place; if (place == SELECT_LIST || place == IN_HAVING) thd->lex->current_select->select_n_having_items++; } } const TABLE_SHARE *Item::field_table_or_null() { if (real_item()->type() != Item::FIELD_ITEM) return NULL; return ((Item_field *) this)->field->table->s; } /** Constructor used by Item_field, Item_ref & aggregate (sum) functions. Used for duplicating lists in processing queries with temporary tables. */ Item::Item(THD *thd, Item *item): Type_std_attributes(item), join_tab_idx(item->join_tab_idx), is_expensive_cache(-1), rsize(0), str_value(item->str_value), name(item->name), orig_name(item->orig_name), name_length(item->name_length), marker(item->marker), maybe_null(item->maybe_null), in_rollup(item->in_rollup), null_value(item->null_value), with_sum_func(item->with_sum_func), with_param(item->with_param), with_window_func(item->with_window_func), with_field(item->with_field), fixed(item->fixed), is_autogenerated_name(item->is_autogenerated_name), with_subselect(item->has_subquery()) { next= thd->free_list; // Put in free list thd->free_list= this; } uint Item::decimal_precision() const { Item_result restype= result_type(); if ((restype == DECIMAL_RESULT) || (restype == INT_RESULT)) { uint prec= my_decimal_length_to_precision(max_char_length(), decimals, unsigned_flag); return MY_MIN(prec, DECIMAL_MAX_PRECISION); } uint res= max_char_length(); /* Return at least one decimal digit, even if Item::max_char_length() returned 0. This is important to avoid attempts to create fields of types INT(0) or DECIMAL(0,0) when converting NULL or empty strings to INT/DECIMAL: CREATE TABLE t1 AS SELECT CONVERT(NULL,SIGNED) AS a; */ return res ? MY_MIN(res, DECIMAL_MAX_PRECISION) : 1; } uint Item::temporal_precision(enum_field_types type_arg) { if (const_item() && result_type() == STRING_RESULT && !is_temporal_type(field_type())) { MYSQL_TIME ltime; String buf, *tmp; MYSQL_TIME_STATUS status; DBUG_ASSERT(fixed); if ((tmp= val_str(&buf)) && !(type_arg == MYSQL_TYPE_TIME ? str_to_time(tmp->charset(), tmp->ptr(), tmp->length(), <ime, TIME_TIME_ONLY, &status) : str_to_datetime(tmp->charset(), tmp->ptr(), tmp->length(), <ime, TIME_FUZZY_DATES, &status))) return MY_MIN(status.precision, TIME_SECOND_PART_DIGITS); } return MY_MIN(decimals, TIME_SECOND_PART_DIGITS); } void Item::print_parenthesised(String *str, enum_query_type query_type, enum precedence parent_prec) { bool need_parens= precedence() < parent_prec; if (need_parens) str->append('('); print(str, query_type); if (need_parens) str->append(')'); } void Item::print(String *str, enum_query_type query_type) { str->append(full_name()); } void Item::print_item_w_name(String *str, enum_query_type query_type) { print(str, query_type); if (name) { THD *thd= current_thd; str->append(STRING_WITH_LEN(" AS ")); append_identifier(thd, str, name, (uint) strlen(name)); } } void Item::print_value(String *str) { char buff[MAX_FIELD_WIDTH]; String *ptr, tmp(buff,sizeof(buff),str->charset()); ptr= val_str(&tmp); if (!ptr) str->append("NULL"); else { switch (cmp_type()) { case STRING_RESULT: case TIME_RESULT: append_unescaped(str, ptr->ptr(), ptr->length()); break; case DECIMAL_RESULT: case REAL_RESULT: case INT_RESULT: str->append(*ptr); break; case ROW_RESULT: DBUG_ASSERT(0); } } } void Item::cleanup() { DBUG_ENTER("Item::cleanup"); DBUG_PRINT("enter", ("this: %p", this)); fixed= 0; marker= 0; join_tab_idx= MAX_TABLES; if (orig_name) name= orig_name; DBUG_VOID_RETURN; } /** cleanup() item if it is 'fixed'. @param arg a dummy parameter, is not used here */ bool Item::cleanup_processor(void *arg) { if (fixed) cleanup(); return FALSE; } /** rename item (used for views, cleanup() return original name). @param new_name new name of item; */ void Item::rename(char *new_name) { /* we can compare pointers to names here, because if name was not changed, pointer will be same */ if (!orig_name && new_name != name) orig_name= name; name= new_name; } /** Traverse item tree possibly transforming it (replacing items). This function is designed to ease transformation of Item trees. Re-execution note: every such transformation is registered for rollback by THD::change_item_tree() and is rolled back at the end of execution by THD::rollback_item_tree_changes(). Therefore: - this function can not be used at prepared statement prepare (in particular, in fix_fields!), as only permanent transformation of Item trees are allowed at prepare. - the transformer function shall allocate new Items in execution memory root (thd->mem_root) and not anywhere else: allocated items will be gone in the end of execution. If you don't need to transform an item tree, but only traverse it, please use Item::walk() instead. @param transformer functor that performs transformation of a subtree @param arg opaque argument passed to the functor @return Returns pointer to the new subtree root. THD::change_item_tree() should be called for it if transformation took place, i.e. if a pointer to newly allocated item is returned. */ Item* Item::transform(THD *thd, Item_transformer transformer, uchar *arg) { DBUG_ASSERT(!thd->stmt_arena->is_stmt_prepare()); return (this->*transformer)(thd, arg); } /** Create and set up an expression cache for this item @param thd Thread handle @param depends_on List of the expression parameters @details The function creates an expression cache for an item and its parameters specified by the 'depends_on' list. Then the expression cache is placed into a cache wrapper that is returned as the result of the function. @returns A pointer to created wrapper item if successful, NULL - otherwise */ Item* Item::set_expr_cache(THD *thd) { DBUG_ENTER("Item::set_expr_cache"); Item_cache_wrapper *wrapper; if ((wrapper= new (thd->mem_root) Item_cache_wrapper(thd, this)) && !wrapper->fix_fields(thd, (Item**)&wrapper)) { if (wrapper->set_cache(thd)) DBUG_RETURN(NULL); DBUG_RETURN(wrapper); } DBUG_RETURN(NULL); } Item_ident::Item_ident(THD *thd, Name_resolution_context *context_arg, const char *db_name_arg,const char *table_name_arg, const char *field_name_arg) :Item_result_field(thd), orig_db_name(db_name_arg), orig_table_name(table_name_arg), orig_field_name(field_name_arg), context(context_arg), db_name(db_name_arg), table_name(table_name_arg), field_name(field_name_arg), alias_name_used(FALSE), cached_field_index(NO_CACHED_FIELD_INDEX), cached_table(0), depended_from(0), can_be_depended(TRUE) { name = (char*) field_name_arg; name_length= name ? strlen(name) : 0; DBUG_ASSERT(!context || context->select_lex); } Item_ident::Item_ident(THD *thd, TABLE_LIST *view_arg, const char *field_name_arg) :Item_result_field(thd), orig_db_name(NullS), orig_table_name(view_arg->table_name), orig_field_name(field_name_arg), context(&view_arg->view->select_lex.context), db_name(NullS), table_name(view_arg->alias), field_name(field_name_arg), alias_name_used(FALSE), cached_field_index(NO_CACHED_FIELD_INDEX), cached_table(NULL), depended_from(NULL), can_be_depended(TRUE) { name = (char*) field_name_arg; name_length= name ? strlen(name) : 0; DBUG_ASSERT(!context || context->select_lex); } /** Constructor used by Item_field & Item_*_ref (see Item comment) */ Item_ident::Item_ident(THD *thd, Item_ident *item) :Item_result_field(thd, item), orig_db_name(item->orig_db_name), orig_table_name(item->orig_table_name), orig_field_name(item->orig_field_name), context(item->context), db_name(item->db_name), table_name(item->table_name), field_name(item->field_name), alias_name_used(item->alias_name_used), cached_field_index(item->cached_field_index), cached_table(item->cached_table), depended_from(item->depended_from), can_be_depended(item->can_be_depended) { DBUG_ASSERT(!context || context->select_lex); } void Item_ident::cleanup() { DBUG_ENTER("Item_ident::cleanup"); bool was_fixed= fixed; Item_result_field::cleanup(); db_name= orig_db_name; table_name= orig_table_name; field_name= orig_field_name; /* Store if this Item was depended */ if (was_fixed) { /* We can trust that depended_from set correctly only if this item was fixed */ can_be_depended= MY_TEST(depended_from); } DBUG_VOID_RETURN; } bool Item_ident::remove_dependence_processor(void * arg) { DBUG_ENTER("Item_ident::remove_dependence_processor"); if (get_depended_from() == (st_select_lex *) arg) depended_from= 0; context= &((st_select_lex *) arg)->context; DBUG_RETURN(0); } bool Item_ident::collect_outer_ref_processor(void *param) { Collect_deps_prm *prm= (Collect_deps_prm *)param; if (depended_from && depended_from->nest_level_base == prm->nest_level_base && depended_from->nest_level < prm->nest_level) { if (prm->collect) prm->parameters->add_unique(this, &cmp_items); else prm->count++; } return FALSE; } /** Store the pointer to this item field into a list if not already there. The method is used by Item::walk to collect all unique Item_field objects from a tree of Items into a set of items represented as a list. Item_cond::walk() and Item_func::walk() stop the evaluation of the processor function for its arguments once the processor returns true.Therefore in order to force this method being called for all item arguments in a condition the method must return false. @param arg pointer to a List @return FALSE to force the evaluation of collect_item_field_processor for the subsequent items. */ bool Item_field::collect_item_field_processor(void *arg) { DBUG_ENTER("Item_field::collect_item_field_processor"); DBUG_PRINT("info", ("%s", field->field_name ? field->field_name : "noname")); List *item_list= (List*) arg; List_iterator item_list_it(*item_list); Item_field *curr_item; while ((curr_item= item_list_it++)) { if (curr_item->eq(this, 1)) DBUG_RETURN(FALSE); /* Already in the set. */ } item_list->push_back(this); DBUG_RETURN(FALSE); } bool Item_field::add_field_to_set_processor(void *arg) { DBUG_ENTER("Item_field::add_field_to_set_processor"); DBUG_PRINT("info", ("%s", field->field_name ? field->field_name : "noname")); TABLE *table= (TABLE *) arg; if (field->table == table) bitmap_set_bit(&table->tmp_set, field->field_index); DBUG_RETURN(FALSE); } /** Rename fields in an expression to new field name as speficied by ALTER TABLE */ bool Item_field::rename_fields_processor(void *arg) { Item::func_processor_rename *rename= (Item::func_processor_rename*) arg; List_iterator def_it(rename->fields); Create_field *def; while ((def=def_it++)) { if (def->change && (!db_name || !db_name[0] || !my_strcasecmp(table_alias_charset, db_name, rename->db_name.str)) && (!table_name || !table_name[0] || !my_strcasecmp(table_alias_charset, table_name, rename->table_name.str)) && !my_strcasecmp(system_charset_info, field_name, def->change)) { field_name= def->field_name; break; } } return 0; } /** Check if an Item_field references some field from a list of fields. Check whether the Item_field represented by 'this' references any of the fields in the keyparts passed via 'arg'. Used with the method Item::walk() to test whether any keypart in a sequence of keyparts is referenced in an expression. @param arg Field being compared, arg must be of type Field @retval TRUE if 'this' references the field 'arg' @retval FALSE otherwise */ bool Item_field::find_item_in_field_list_processor(void *arg) { KEY_PART_INFO *first_non_group_part= *((KEY_PART_INFO **) arg); KEY_PART_INFO *last_part= *(((KEY_PART_INFO **) arg) + 1); KEY_PART_INFO *cur_part; for (cur_part= first_non_group_part; cur_part != last_part; cur_part++) { if (field->eq(cur_part->field)) return TRUE; } return FALSE; } /* Mark field in read_map NOTES This is used by filesort to register used fields in a a temporary column read set or to register used fields in a view or check constraint */ bool Item_field::register_field_in_read_map(void *arg) { TABLE *table= (TABLE *) arg; int res= 0; if (field->vcol_info && !bitmap_fast_test_and_set(field->table->vcol_set, field->field_index)) { res= field->vcol_info->expr->walk(&Item::register_field_in_read_map,1,arg); } if (field->table == table || !table) bitmap_set_bit(field->table->read_set, field->field_index); return res; } /* @brief Mark field in bitmap supplied as *arg */ bool Item_field::register_field_in_bitmap(void *arg) { MY_BITMAP *bitmap= (MY_BITMAP *) arg; DBUG_ASSERT(bitmap); bitmap_set_bit(bitmap, field->field_index); return 0; } /* Mark field in write_map NOTES This is used by UPDATE to register underlying fields of used view fields. */ bool Item_field::register_field_in_write_map(void *arg) { TABLE *table= (TABLE *) arg; if (field->table == table || !table) bitmap_set_bit(field->table->write_set, field->field_index); return 0; } /** Check that we are not referring to any not yet initialized fields Fields are initialized in this order: - All fields that have default value as a constant are initialized first. - Then user-specified values from the INSERT list - Then all fields that has a default expression, in field_index order. - Then all virtual fields, in field_index order. - Then auto-increment values This means: - For default fields we can't access the same field or a field after itself that doesn't have a non-constant default value. - A virtual field can't access itself or a virtual field after itself. - user-specified values will not see virtual fields or default expressions, as in INSERT t1 (a) VALUES (b); - no virtual fields can access auto-increment values This is used by fix_vcol_expr() when a table is opened We don't have to check fields that are marked as NO_DEFAULT_VALUE as the upper level will ensure that all these will be given a value. */ bool Item_field::check_field_expression_processor(void *arg) { Field *org_field= (Field*) arg; if (field->flags & NO_DEFAULT_VALUE_FLAG) return 0; if ((field->default_value && field->default_value->flags) || field->vcol_info) { if (field == org_field || (!org_field->vcol_info && field->vcol_info) || (((field->vcol_info && org_field->vcol_info) || (!field->vcol_info && !org_field->vcol_info)) && field->field_index >= org_field->field_index)) { my_error(ER_EXPRESSION_REFERS_TO_UNINIT_FIELD, MYF(0), org_field->field_name, field->field_name); return 1; } } return 0; } bool Item_field::update_vcol_processor(void *arg) { MY_BITMAP *map= (MY_BITMAP *) arg; if (field->vcol_info && !bitmap_fast_test_and_set(map, field->field_index)) { field->vcol_info->expr->walk(&Item::update_vcol_processor, 0, arg); field->vcol_info->expr->save_in_field(field, 0); } return 0; } bool Item::check_cols(uint c) { if (c != 1) { my_error(ER_OPERAND_COLUMNS, MYF(0), c); return 1; } return 0; } void Item::set_name(THD *thd, const char *str, uint length, CHARSET_INFO *cs) { if (!length) { /* Empty string, used by AS or internal function like last_insert_id() */ name= (char*) str; name_length= 0; return; } const char *str_start= str; if (!cs->ctype || cs->mbminlen > 1) { str+= cs->cset->scan(cs, str, str + length, MY_SEQ_SPACES); length-= (uint)(str - str_start); } else { /* This will probably need a better implementation in the future: a function in CHARSET_INFO structure. */ while (length && !my_isgraph(cs,*str)) { // Fix problem with yacc length--; str++; } } if (str != str_start && !is_autogenerated_name) { char buff[SAFE_NAME_LEN]; strmake(buff, str_start, MY_MIN(sizeof(buff)-1, length + (int) (str-str_start))); if (length == 0) push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN, ER_NAME_BECOMES_EMPTY, ER_THD(thd, ER_NAME_BECOMES_EMPTY), buff); else push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN, ER_REMOVED_SPACES, ER_THD(thd, ER_REMOVED_SPACES), buff); } if (!my_charset_same(cs, system_charset_info)) { size_t res_length; name= sql_strmake_with_convert(thd, str, length, cs, MAX_ALIAS_NAME, system_charset_info, &res_length); name_length= res_length; } else name= thd->strmake(str, (name_length= MY_MIN(length,MAX_ALIAS_NAME))); } void Item::set_name_no_truncate(THD *thd, const char *str, uint length, CHARSET_INFO *cs) { if (!my_charset_same(cs, system_charset_info)) { size_t res_length; name= sql_strmake_with_convert(thd, str, length, cs, UINT_MAX, system_charset_info, &res_length); name_length= res_length; } else name= thd->strmake(str, (name_length= length)); } void Item::set_name_for_rollback(THD *thd, const char *str, uint length, CHARSET_INFO *cs) { char *old_name, *new_name; old_name= name; set_name(thd, str, length, cs); new_name= name; if (old_name != new_name) { name= old_name; thd->change_item_tree((Item **) &name, (Item *) new_name); } } /** @details This function is called when: - Comparing items in the WHERE clause (when doing where optimization) - When trying to find an ORDER BY/GROUP BY item in the SELECT part */ bool Item::eq(const Item *item, bool binary_cmp) const { /* Note, that this is never TRUE if item is a Item_param: for all basic constants we have special checks, and Item_param's type() can be only among basic constant types. */ return type() == item->type() && name && item->name && !my_strcasecmp(system_charset_info,name,item->name); } Item *Item::safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { if (!needs_charset_converter(tocs)) return this; Item_func_conv_charset *conv= new (thd->mem_root) Item_func_conv_charset(thd, this, tocs, 1); return conv->safe ? conv : NULL; } /** Some pieces of the code do not support changing of Item_cache to other Item types. Example: Item_singlerow_subselect has "Item_cache **row". Creating of Item_func_conv_charset followed by THD::change_item_tree() should not change row[i] from Item_cache directly to Item_func_conv_charset, because Item_singlerow_subselect later calls Item_cache-specific methods, e.g. row[i]->store() and row[i]->cache_value(). Let's wrap Item_func_conv_charset in a new Item_cache, so the Item_cache-specific methods can still be used for Item_singlerow_subselect::row[i] safely. As a bonus we cache the converted value, instead of converting every time TODO: we should eventually check all other use cases of change_item_tree(). Perhaps some more potentially dangerous substitution examples exist. */ Item *Item_cache::safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { if (!example) return Item::safe_charset_converter(thd, tocs); Item *conv= example->safe_charset_converter(thd, tocs); if (conv == example) return this; Item_cache *cache; if (!conv || conv->fix_fields(thd, (Item **) NULL) || !(cache= new (thd->mem_root) Item_cache_str(thd, conv))) return NULL; // Safe conversion is not possible, or OEM cache->setup(thd, conv); cache->fixed= false; // Make Item::fix_fields() happy return cache; } /** @details Created mostly for mysql_prepare_table(). Important when a string ENUM/SET column is described with a numeric default value: CREATE TABLE t1(a SET('a') DEFAULT 1); We cannot use generic Item::safe_charset_converter(), because the latter returns a non-fixed Item, so val_str() crashes afterwards. Override Item_num method, to return a fixed item. */ Item *Item_num::safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { /* Item_num returns pure ASCII result, so conversion is needed only in case of "tricky" character sets like UCS2. If tocs is not "tricky", return the item itself. */ if (!(tocs->state & MY_CS_NONASCII)) return this; Item *conv; if ((conv= const_charset_converter(thd, tocs, true))) conv->fix_char_length(max_char_length()); return conv; } /** Create character set converter for constant items using Item_null, Item_string or Item_static_string_func. @param tocs Character set to to convert the string to. @param lossless Whether data loss is acceptable. @param func_name Function name, or NULL. @return this, if conversion is not needed, NULL, if safe conversion is not possible, or a new item representing the converted constant. */ Item *Item::const_charset_converter(THD *thd, CHARSET_INFO *tocs, bool lossless, const char *func_name) { DBUG_ASSERT(const_item()); DBUG_ASSERT(fixed); StringBuffer<64>tmp; String *s= val_str(&tmp); MEM_ROOT *mem_root= thd->mem_root; if (!s) return new (mem_root) Item_null(thd, (char *) func_name, tocs); if (!needs_charset_converter(s->length(), tocs)) { if (collation.collation == &my_charset_bin && tocs != &my_charset_bin && !this->check_well_formed_result(s, true)) return NULL; return this; } uint conv_errors; Item_string *conv= (func_name ? new (mem_root) Item_static_string_func(thd, func_name, s, tocs, &conv_errors, collation.derivation, collation.repertoire) : new (mem_root) Item_string(thd, s, tocs, &conv_errors, collation.derivation, collation.repertoire)); if (!conv || (conv_errors && lossless)) { /* Safe conversion is not possible (or EOM). We could not convert a string into the requested character set without data loss. The target charset does not cover all the characters from the string. Operation cannot be done correctly. */ return NULL; } if (s->charset() == &my_charset_bin && tocs != &my_charset_bin && !conv->check_well_formed_result(true)) return NULL; return conv; } Item *Item_param::safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { /* Return "this" if in prepare. result_type may change at execition time, to it's possible that the converter will not be needed at all: PREPARE stmt FROM 'SELECT * FROM t1 WHERE field = ?'; SET @arg= 1; EXECUTE stmt USING @arg; In the above example result_type is STRING_RESULT at prepare time, and INT_RESULT at execution time. */ return !const_item() || state == NULL_VALUE ? this : const_charset_converter(thd, tocs, true); } /** Get the value of the function as a MYSQL_TIME structure. As a extra convenience the time structure is reset on error or NULL values! */ bool Item::get_date(MYSQL_TIME *ltime,ulonglong fuzzydate) { if (field_type() == MYSQL_TYPE_TIME) fuzzydate|= TIME_TIME_ONLY; switch (result_type()) { case INT_RESULT: { longlong value= val_int(); bool neg= !unsigned_flag && value < 0; if (field_type() == MYSQL_TYPE_YEAR) { if (max_length == 2) { if (value < 70) value+= 2000; else if (value <= 1900) value+= 1900; } value*= 10000; /* make it YYYYMMHH */ } if (null_value || int_to_datetime_with_warn(neg, neg ? -value : value, ltime, fuzzydate, field_table_or_null(), field_name_or_null())) goto err; return null_value= false; } case REAL_RESULT: { double value= val_real(); if (null_value || double_to_datetime_with_warn(value, ltime, fuzzydate, field_table_or_null(), field_name_or_null())) goto err; return null_value= false; } case DECIMAL_RESULT: { my_decimal value, *res; if (!(res= val_decimal(&value)) || decimal_to_datetime_with_warn(res, ltime, fuzzydate, field_table_or_null(), field_name_or_null())) goto err; return null_value= false; } case STRING_RESULT: { char buff[40]; String tmp(buff,sizeof(buff), &my_charset_bin),*res; if (!(res=val_str(&tmp)) || str_to_datetime_with_warn(res->charset(), res->ptr(), res->length(), ltime, fuzzydate)) goto err; return null_value= false; } default: null_value= true; DBUG_ASSERT(0); } err: return null_value|= make_zero_date(ltime, fuzzydate); } bool Item::make_zero_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { /* if the item was not null and conversion failed, we return a zero date if allowed, otherwise - null. */ bzero((char*) ltime,sizeof(*ltime)); if (fuzzydate & TIME_TIME_ONLY) { /* In the following scenario: - The caller expected to get a TIME value - Item returned a not NULL string or numeric value - But then conversion from string or number to TIME failed we need to change the default time_type from MYSQL_TIMESTAMP_DATE (which was set in bzero) to MYSQL_TIMESTAMP_TIME and therefore return TIME'00:00:00' rather than DATE'0000-00-00'. If we don't do this, methods like Item::get_time_with_conversion() will erroneously subtract CURRENT_DATE from '0000-00-00 00:00:00' and return TIME'-838:59:59' instead of TIME'00:00:00' as a result. */ ltime->time_type= MYSQL_TIMESTAMP_TIME; } return !(fuzzydate & TIME_FUZZY_DATES); } bool Item::get_seconds(ulonglong *sec, ulong *sec_part) { if (decimals == 0) { // optimize for an important special case longlong val= val_int(); bool neg= val < 0 && !unsigned_flag; *sec= neg ? -val : val; *sec_part= 0; return neg; } my_decimal tmp, *dec= val_decimal(&tmp); if (!dec) return 0; return my_decimal2seconds(dec, sec, sec_part); } CHARSET_INFO *Item::default_charset() { return current_thd->variables.collation_connection; } /* Save value in field, but don't give any warnings NOTES This is used to temporary store and retrieve a value in a column, for example in opt_range to adjust the key value to fit the column. */ int Item::save_in_field_no_warnings(Field *field, bool no_conversions) { int res; TABLE *table= field->table; THD *thd= table->in_use; enum_check_fields tmp= thd->count_cuted_fields; MY_BITMAP *old_map= dbug_tmp_use_all_columns(table, &table->write_set); sql_mode_t sql_mode= thd->variables.sql_mode; thd->variables.sql_mode&= ~(MODE_NO_ZERO_IN_DATE | MODE_NO_ZERO_DATE); thd->variables.sql_mode|= MODE_INVALID_DATES; thd->count_cuted_fields= CHECK_FIELD_IGNORE; res= save_in_field(field, no_conversions); thd->count_cuted_fields= tmp; dbug_tmp_restore_column_map(&table->write_set, old_map); thd->variables.sql_mode= sql_mode; return res; } #ifndef DBUG_OFF static inline void mark_unsupported_func(const char *where, const char *processor_name) { char buff[64]; my_snprintf(buff, sizeof(buff), "%s::%s", where ? where: "", processor_name); DBUG_ENTER(buff); my_snprintf(buff, sizeof(buff), "%s returns TRUE: unsupported function", processor_name); DBUG_PRINT("info", ("%s", buff)); DBUG_VOID_RETURN; } #else #define mark_unsupported_func(X,Y) {} #endif bool mark_unsupported_function(const char *where, void *store, uint result) { Item::vcol_func_processor_result *res= (Item::vcol_func_processor_result*) store; uint old_errors= res->errors; mark_unsupported_func(where, "check_vcol_func_processor"); res->errors|= result; /* Store type of expression */ /* Store the name to the highest violation (normally VCOL_IMPOSSIBLE) */ if (result > old_errors) res->name= where ? where : ""; return false; } /* convenience helper for mark_unsupported_function() above */ bool mark_unsupported_function(const char *w1, const char *w2, void *store, uint result) { char *ptr= (char*)current_thd->alloc(strlen(w1) + strlen(w2) + 1); if (ptr) strxmov(ptr, w1, w2, NullS); return mark_unsupported_function(ptr, store, result); } /***************************************************************************** Item_sp_variable methods *****************************************************************************/ Item_sp_variable::Item_sp_variable(THD *thd, char *sp_var_name_str, uint sp_var_name_length): Item(thd), m_thd(0) #ifndef DBUG_OFF , m_sp(0) #endif { m_name.str= sp_var_name_str; m_name.length= sp_var_name_length; } bool Item_sp_variable::fix_fields(THD *thd, Item **) { Item *it; m_thd= thd; /* NOTE: this must be set before any this_xxx() */ it= this_item(); DBUG_ASSERT(it->fixed); max_length= it->max_length; decimals= it->decimals; unsigned_flag= it->unsigned_flag; with_param= 1; if (thd->lex->current_select && thd->lex->current_select->master_unit()->item) thd->lex->current_select->master_unit()->item->with_param= 1; fixed= 1; collation.set(it->collation.collation, it->collation.derivation); return FALSE; } double Item_sp_variable::val_real() { DBUG_ASSERT(fixed); Item *it= this_item(); double ret= it->val_real(); null_value= it->null_value; return ret; } longlong Item_sp_variable::val_int() { DBUG_ASSERT(fixed); Item *it= this_item(); longlong ret= it->val_int(); null_value= it->null_value; return ret; } String *Item_sp_variable::val_str(String *sp) { DBUG_ASSERT(fixed); Item *it= this_item(); String *res= it->val_str(sp); null_value= it->null_value; if (!res) return NULL; /* This way we mark returned value of val_str as const, so that various functions (e.g. CONCAT) won't try to modify the value of the Item. Analogous mechanism is implemented for Item_param. Without this trick Item_splocal could be changed as a side-effect of expression computation. Here is an example of what happens without it: suppose x is varchar local variable in a SP with initial value 'ab' Then select concat(x,'c'); would change x's value to 'abc', as Item_func_concat::val_str() would use x's internal buffer to compute the result. This is intended behaviour of Item_func_concat. Comments to Item_param class contain some more details on the topic. */ if (res != &str_value) str_value.set(res->ptr(), res->length(), res->charset()); else res->mark_as_const(); return &str_value; } my_decimal *Item_sp_variable::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(fixed); Item *it= this_item(); my_decimal *val= it->val_decimal(decimal_value); null_value= it->null_value; return val; } bool Item_sp_variable::is_null() { return this_item()->is_null(); } /***************************************************************************** Item_splocal methods *****************************************************************************/ Item_splocal::Item_splocal(THD *thd, const LEX_STRING &sp_var_name, uint sp_var_idx, enum_field_types sp_var_type, uint pos_in_q, uint len_in_q): Item_sp_variable(thd, sp_var_name.str, sp_var_name.length), Rewritable_query_parameter(pos_in_q, len_in_q), m_var_idx(sp_var_idx) { maybe_null= TRUE; sp_var_type= real_type_to_type(sp_var_type); m_type= sp_map_item_type(sp_var_type); set_handler_by_field_type(sp_var_type); } Item * Item_splocal::this_item() { DBUG_ASSERT(m_sp == m_thd->spcont->sp); return m_thd->spcont->get_item(m_var_idx); } const Item * Item_splocal::this_item() const { DBUG_ASSERT(m_sp == m_thd->spcont->sp); return m_thd->spcont->get_item(m_var_idx); } Item ** Item_splocal::this_item_addr(THD *thd, Item **) { DBUG_ASSERT(m_sp == thd->spcont->sp); return thd->spcont->get_item_addr(m_var_idx); } void Item_splocal::print(String *str, enum_query_type) { str->reserve(m_name.length+8); str->append(m_name.str, m_name.length); str->append('@'); str->qs_append(m_var_idx); } bool Item_splocal::set_value(THD *thd, sp_rcontext *ctx, Item **it) { return ctx->set_variable(thd, get_var_idx(), it); } /***************************************************************************** Item_case_expr methods *****************************************************************************/ Item_case_expr::Item_case_expr(THD *thd, uint case_expr_id): Item_sp_variable(thd, C_STRING_WITH_LEN("case_expr")), m_case_expr_id(case_expr_id) { } Item * Item_case_expr::this_item() { DBUG_ASSERT(m_sp == m_thd->spcont->sp); return m_thd->spcont->get_case_expr(m_case_expr_id); } const Item * Item_case_expr::this_item() const { DBUG_ASSERT(m_sp == m_thd->spcont->sp); return m_thd->spcont->get_case_expr(m_case_expr_id); } Item ** Item_case_expr::this_item_addr(THD *thd, Item **) { DBUG_ASSERT(m_sp == thd->spcont->sp); return thd->spcont->get_case_expr_addr(m_case_expr_id); } void Item_case_expr::print(String *str, enum_query_type) { if (str->reserve(MAX_INT_WIDTH + sizeof("case_expr@"))) return; /* purecov: inspected */ (void) str->append(STRING_WITH_LEN("case_expr@")); str->qs_append(m_case_expr_id); } /***************************************************************************** Item_name_const methods *****************************************************************************/ double Item_name_const::val_real() { DBUG_ASSERT(fixed); double ret= value_item->val_real(); null_value= value_item->null_value; return ret; } longlong Item_name_const::val_int() { DBUG_ASSERT(fixed); longlong ret= value_item->val_int(); null_value= value_item->null_value; return ret; } String *Item_name_const::val_str(String *sp) { DBUG_ASSERT(fixed); String *ret= value_item->val_str(sp); null_value= value_item->null_value; return ret; } my_decimal *Item_name_const::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(fixed); my_decimal *val= value_item->val_decimal(decimal_value); null_value= value_item->null_value; return val; } bool Item_name_const::is_null() { return value_item->is_null(); } Item_name_const::Item_name_const(THD *thd, Item *name_arg, Item *val): Item(thd), value_item(val), name_item(name_arg) { StringBuffer<128> name_buffer; String *name_str; Item::maybe_null= TRUE; valid_args= true; if (!name_item->basic_const_item() || !(name_str= name_item->val_str(&name_buffer))) // Can't have a NULL name goto err; set_name(thd, name_str->ptr(), name_str->length(), name_str->charset()); if (value_item->basic_const_item()) return; // ok if (value_item->type() == FUNC_ITEM) { Item_func *value_func= (Item_func *) value_item; if (value_func->functype() != Item_func::COLLATE_FUNC && value_func->functype() != Item_func::NEG_FUNC) goto err; if (value_func->key_item()->basic_const_item()) return; // ok } err: valid_args= false; my_error(ER_WRONG_ARGUMENTS, MYF(0), "NAME_CONST"); } Item::Type Item_name_const::type() const { /* As 1. one can try to create the Item_name_const passing non-constant arguments, although it's incorrect and 2. the type() method can be called before the fix_fields() to get type information for a further type cast, e.g. if (item->type() == FIELD_ITEM) ((Item_field *) item)->... we return NULL_ITEM in the case to avoid wrong casting. valid_args guarantees value_item->basic_const_item(); if type is FUNC_ITEM, then we have a fudged item_func_neg() on our hands and return the underlying type. For Item_func_set_collation() e.g. NAME_CONST('name', 'value' COLLATE collation) we return its 'value' argument type. */ if (!valid_args) return NULL_ITEM; Item::Type value_type= value_item->type(); if (value_type == FUNC_ITEM) { /* The second argument of NAME_CONST('name', 'value') must be a simple constant item or a NEG_FUNC/COLLATE_FUNC. */ DBUG_ASSERT(((Item_func *) value_item)->functype() == Item_func::NEG_FUNC || ((Item_func *) value_item)->functype() == Item_func::COLLATE_FUNC); return ((Item_func *) value_item)->key_item()->type(); } return value_type; } bool Item_name_const::fix_fields(THD *thd, Item **ref) { if ((!value_item->fixed && value_item->fix_fields(thd, &value_item)) || (!name_item->fixed && name_item->fix_fields(thd, &name_item)) || !value_item->const_item() || !name_item->const_item()) { my_error(ER_RESERVED_SYNTAX, MYF(0), "NAME_CONST"); return TRUE; } if (value_item->collation.derivation == DERIVATION_NUMERIC) collation.set_numeric(); else collation.set(value_item->collation.collation, DERIVATION_IMPLICIT); max_length= value_item->max_length; decimals= value_item->decimals; fixed= 1; return FALSE; } void Item_name_const::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("NAME_CONST(")); name_item->print(str, query_type); str->append(','); value_item->print(str, query_type); str->append(')'); } /* need a special class to adjust printing : references to aggregate functions must not be printed as refs because the aggregate functions that are added to the front of select list are not printed as well. */ class Item_aggregate_ref : public Item_ref { public: Item_aggregate_ref(THD *thd, Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg): Item_ref(thd, context_arg, item, table_name_arg, field_name_arg) {} virtual inline void print (String *str, enum_query_type query_type) { if (ref) (*ref)->print(str, query_type); else Item_ident::print(str, query_type); } virtual Ref_Type ref_type() { return AGGREGATE_REF; } }; /** Move SUM items out from item tree and replace with reference. @param thd Thread handler @param ref_pointer_array Pointer to array of reference fields @param fields All fields in select @param ref Pointer to item @param split_flags Zero or more of the following flags SPLIT_FUNC_SKIP_REGISTERED: Function be must skipped for registered SUM SUM items SPLIT_SUM_SELECT We are called on the select level and have to register items operated on sum function @note All found SUM items are added FIRST in the fields list and we replace the item with a reference. If this is an item in the SELECT list then we also have to split out all arguments to functions used together with the sum function. For example in case of SELECT A*sum(B) we have to split out both A and sum(B). This is not needed for ORDER BY, GROUP BY or HAVING as all references to items in the select list are already of type REF thd->fatal_error() may be called if we are out of memory */ void Item::split_sum_func2(THD *thd, Ref_ptr_array ref_pointer_array, List &fields, Item **ref, uint split_flags) { if (unlikely(type() == SUM_FUNC_ITEM)) { /* An item of type Item_sum is registered if ref_by != 0 */ if ((split_flags & SPLIT_SUM_SKIP_REGISTERED) && ((Item_sum *) this)->ref_by) return; } else if (type() == WINDOW_FUNC_ITEM || with_window_func) { /* Skip the else part, window functions are very special functions: they need to have their own fields in the temp. table, but they need to be proceessed differently than regular aggregate functions Call split_sum_func here so that each argument gets its fields to point to the temporary table. */ split_sum_func(thd, ref_pointer_array, fields, split_flags); if (type() == FUNC_ITEM) { return; } } else { /* Not a SUM() function */ if (unlikely((!with_sum_func && !(split_flags & SPLIT_SUM_SELECT)))) { /* This is not a SUM function and there are no SUM functions inside. Nothing more to do. */ return; } if (likely(with_sum_func || (type() == FUNC_ITEM && (((Item_func *) this)->functype() == Item_func::ISNOTNULLTEST_FUNC || ((Item_func *) this)->functype() == Item_func::TRIG_COND_FUNC)))) { /* Will call split_sum_func2() for all items */ split_sum_func(thd, ref_pointer_array, fields, split_flags); return; } if (unlikely((!(used_tables() & ~PARAM_TABLE_BIT) || (type() == REF_ITEM && ((Item_ref*)this)->ref_type() != Item_ref::VIEW_REF)))) return; } /* Replace item with a reference so that we can easily calculate it (in case of sum functions) or copy it (in case of fields) The test above is to ensure we don't do a reference for things that are constants (PARAM_TABLE_BIT is in effect a constant) or already referenced (for example an item in HAVING) Exception is Item_direct_view_ref which we need to convert to Item_ref to allow fields from view being stored in tmp table. */ Item_ref *item_ref; uint el= fields.elements; /* If this is an item_ref, get the original item This is a safety measure if this is called for things that is already a reference. */ Item *real_itm= real_item(); ref_pointer_array[el]= real_itm; if (type() == WINDOW_FUNC_ITEM) { if (!(item_ref= (new (thd->mem_root) Item_direct_ref(thd, &thd->lex->current_select->context, &ref_pointer_array[el], 0, name)))) return; // fatal_error is set } else { if (!(item_ref= (new (thd->mem_root) Item_aggregate_ref(thd, &thd->lex->current_select->context, &ref_pointer_array[el], 0, name)))) return; // fatal_error is set } if (type() == SUM_FUNC_ITEM) item_ref->depended_from= ((Item_sum *) this)->depended_from(); fields.push_front(real_itm); thd->change_item_tree(ref, item_ref); } static bool left_is_superset(const DTCollation *left, const DTCollation *right) { /* Allow convert to Unicode */ if (left->collation->state & MY_CS_UNICODE && (left->derivation < right->derivation || (left->derivation == right->derivation && (!(right->collation->state & MY_CS_UNICODE) || /* The code below makes 4-byte utf8 a superset over 3-byte utf8 */ (left->collation->state & MY_CS_UNICODE_SUPPLEMENT && !(right->collation->state & MY_CS_UNICODE_SUPPLEMENT) && left->collation->mbmaxlen > right->collation->mbmaxlen && left->collation->mbminlen == right->collation->mbminlen))))) return TRUE; /* Allow convert from ASCII */ if (right->repertoire == MY_REPERTOIRE_ASCII && (left->derivation < right->derivation || (left->derivation == right->derivation && !(left->repertoire == MY_REPERTOIRE_ASCII)))) return TRUE; /* Disallow conversion otherwise */ return FALSE; } /** Aggregate two collations together taking into account their coercibility (aka derivation):. 0 == DERIVATION_EXPLICIT - an explicitly written COLLATE clause @n 1 == DERIVATION_NONE - a mix of two different collations @n 2 == DERIVATION_IMPLICIT - a column @n 3 == DERIVATION_COERCIBLE - a string constant. The most important rules are: -# If collations are the same: chose this collation, and the strongest derivation. -# If collations are different: - Character sets may differ, but only if conversion without data loss is possible. The caller provides flags whether character set conversion attempts should be done. If no flags are substituted, then the character sets must be the same. Currently processed flags are: MY_COLL_ALLOW_SUPERSET_CONV - allow conversion to a superset MY_COLL_ALLOW_COERCIBLE_CONV - allow conversion of a coercible value - two EXPLICIT collations produce an error, e.g. this is wrong: CONCAT(expr1 collate latin1_swedish_ci, expr2 collate latin1_german_ci) - the side with smaller derivation value wins, i.e. a column is stronger than a string constant, an explicit COLLATE clause is stronger than a column. - if derivations are the same, we have DERIVATION_NONE, we'll wait for an explicit COLLATE clause which possibly can come from another argument later: for example, this is valid, but we don't know yet when collecting the first two arguments: @code CONCAT(latin1_swedish_ci_column, latin1_german1_ci_column, expr COLLATE latin1_german2_ci) @endcode */ bool DTCollation::aggregate(const DTCollation &dt, uint flags) { if (!my_charset_same(collation, dt.collation)) { /* We do allow to use binary strings (like BLOBS) together with character strings. Binaries have more precedence than a character string of the same derivation. */ if (collation == &my_charset_bin) { if (derivation <= dt.derivation) { /* Do nothing */ } else { set(dt); } } else if (dt.collation == &my_charset_bin) { if (dt.derivation <= derivation) { set(dt); } } else if ((flags & MY_COLL_ALLOW_SUPERSET_CONV) && left_is_superset(this, &dt)) { /* Do nothing */ } else if ((flags & MY_COLL_ALLOW_SUPERSET_CONV) && left_is_superset(&dt, this)) { set(dt); } else if ((flags & MY_COLL_ALLOW_COERCIBLE_CONV) && derivation < dt.derivation && dt.derivation >= DERIVATION_SYSCONST) { /* Do nothing */ } else if ((flags & MY_COLL_ALLOW_COERCIBLE_CONV) && dt.derivation < derivation && derivation >= DERIVATION_SYSCONST) { set(dt); } else { // Cannot apply conversion set(&my_charset_bin, DERIVATION_NONE, (dt.repertoire|repertoire)); return 1; } } else if (derivation < dt.derivation) { /* Do nothing */ } else if (dt.derivation < derivation) { set(dt); } else { if (collation == dt.collation) { /* Do nothing */ } else { if (derivation == DERIVATION_EXPLICIT) { set(0, DERIVATION_NONE, 0); return 1; } if (collation->state & MY_CS_BINSORT && dt.collation->state & MY_CS_BINSORT) return 1; if (collation->state & MY_CS_BINSORT) return 0; if (dt.collation->state & MY_CS_BINSORT) { set(dt); return 0; } CHARSET_INFO *bin= get_charset_by_csname(collation->csname, MY_CS_BINSORT,MYF(0)); set(bin, DERIVATION_NONE); } } repertoire|= dt.repertoire; return 0; } /******************************/ static void my_coll_agg_error(DTCollation &c1, DTCollation &c2, const char *fname) { my_error(ER_CANT_AGGREGATE_2COLLATIONS,MYF(0), c1.collation->name,c1.derivation_name(), c2.collation->name,c2.derivation_name(), fname); } static void my_coll_agg_error(DTCollation &c1, DTCollation &c2, DTCollation &c3, const char *fname) { my_error(ER_CANT_AGGREGATE_3COLLATIONS,MYF(0), c1.collation->name,c1.derivation_name(), c2.collation->name,c2.derivation_name(), c3.collation->name,c3.derivation_name(), fname); } static void my_coll_agg_error(Item** args, uint count, const char *fname, int item_sep) { if (count == 2) my_coll_agg_error(args[0]->collation, args[item_sep]->collation, fname); else if (count == 3) my_coll_agg_error(args[0]->collation, args[item_sep]->collation, args[2*item_sep]->collation, fname); else my_error(ER_CANT_AGGREGATE_NCOLLATIONS,MYF(0),fname); } bool Item_func_or_sum::agg_item_collations(DTCollation &c, const char *fname, Item **av, uint count, uint flags, int item_sep) { uint i; Item **arg; bool unknown_cs= 0; c.set(av[0]->collation); for (i= 1, arg= &av[item_sep]; i < count; i++, arg+= item_sep) { if (c.aggregate((*arg)->collation, flags)) { if (c.derivation == DERIVATION_NONE && c.collation == &my_charset_bin) { unknown_cs= 1; continue; } my_coll_agg_error(av, count, fname, item_sep); return TRUE; } } if (unknown_cs && c.derivation != DERIVATION_EXPLICIT) { my_coll_agg_error(av, count, fname, item_sep); return TRUE; } if ((flags & MY_COLL_DISALLOW_NONE) && c.derivation == DERIVATION_NONE) { my_coll_agg_error(av, count, fname, item_sep); return TRUE; } /* If all arguments where numbers, reset to @@collation_connection */ if (flags & MY_COLL_ALLOW_NUMERIC_CONV && c.derivation == DERIVATION_NUMERIC) c.set(Item::default_charset(), DERIVATION_COERCIBLE, MY_REPERTOIRE_NUMERIC); return FALSE; } bool Item_func_or_sum::agg_item_set_converter(const DTCollation &coll, const char *fname, Item **args, uint nargs, uint flags, int item_sep) { THD *thd= current_thd; if (thd->lex->is_ps_or_view_context_analysis()) return false; Item **arg, *safe_args[2]= {NULL, NULL}; /* For better error reporting: save the first and the second argument. We need this only if the the number of args is 3 or 2: - for a longer argument list, "Illegal mix of collations" doesn't display each argument's characteristics. - if nargs is 1, then this error cannot happen. */ if (nargs >=2 && nargs <= 3) { safe_args[0]= args[0]; safe_args[1]= args[item_sep]; } bool res= FALSE; uint i; DBUG_ASSERT(!thd->stmt_arena->is_stmt_prepare()); for (i= 0, arg= args; i < nargs; i++, arg+= item_sep) { Item* conv= (*arg)->safe_charset_converter(thd, coll.collation); if (conv == *arg) continue; if (!conv) { if (nargs >=2 && nargs <= 3) { /* restore the original arguments for better error message */ args[0]= safe_args[0]; args[item_sep]= safe_args[1]; } my_coll_agg_error(args, nargs, fname, item_sep); res= TRUE; break; // we cannot return here, we need to restore "arena". } thd->change_item_tree(arg, conv); if (conv->fix_fields(thd, arg)) { res= TRUE; break; // we cannot return here, we need to restore "arena". } } return res; } /** @brief Building clone for Item_func_or_sum @param thd thread handle @param mem_root part of the memory for the clone @details This method fisrt builds clones of the arguments. If it is successful with buiding the clones then it constructs a copy of this Item_func_or_sum object and attaches to it the built clones of the arguments. @retval clone of the item on success 0 on a failure */ Item* Item_func_or_sum::build_clone(THD *thd, MEM_ROOT *mem_root) { Item *copy_tmp_args[2]= {0,0}; Item **copy_args= copy_tmp_args; if (arg_count > 2) { if (!(copy_args= (Item**) alloc_root(mem_root, sizeof(Item*) * arg_count))) return 0; } for (uint i= 0; i < arg_count; i++) { Item *arg_clone= args[i]->build_clone(thd, mem_root); if (!arg_clone) return 0; copy_args[i]= arg_clone; } Item_func_or_sum *copy= (Item_func_or_sum *) get_copy(thd, mem_root); if (!copy) return 0; if (arg_count > 2) copy->args= copy_args; else if (arg_count > 0) { copy->args= copy->tmp_arg; memcpy(copy->args, copy_args, sizeof(Item *) * arg_count); } return copy; } /** @brief Building clone for Item_ref @param thd thread handle @param mem_root part of the memory for the clone @details This method gets copy of the current item and also builds clone for its reference. @retval clone of the item 0 if an error occured */ Item* Item_ref::build_clone(THD *thd, MEM_ROOT *mem_root) { Item_ref *copy= (Item_ref *) get_copy(thd, mem_root); if (!copy) return 0; copy->ref= (Item**) alloc_root(mem_root, sizeof(Item*)); if (!copy->ref) return 0; Item *item_clone= (* ref)->build_clone(thd, mem_root); if (!item_clone) return 0; *copy->ref= item_clone; return copy; } void Item_ident_for_show::make_field(THD *thd, Send_field *tmp_field) { tmp_field->table_name= tmp_field->org_table_name= table_name; tmp_field->db_name= db_name; tmp_field->col_name= tmp_field->org_col_name= field->field_name; tmp_field->charsetnr= field->charset()->number; tmp_field->length=field->field_length; tmp_field->type=field->type(); tmp_field->flags= field->table->maybe_null ? (field->flags & ~NOT_NULL_FLAG) : field->flags; tmp_field->decimals= field->decimals(); } /**********************************************/ Item_field::Item_field(THD *thd, Field *f) :Item_ident(thd, 0, NullS, *f->table_name, f->field_name), item_equal(0), have_privileges(0), any_privileges(0) { set_field(f); /* field_name and table_name should not point to garbage if this item is to be reused */ orig_table_name= orig_field_name= ""; with_field= 1; } /** Constructor used inside setup_wild(). Ensures that field, table, and database names will live as long as Item_field (this is important in prepared statements). */ Item_field::Item_field(THD *thd, Name_resolution_context *context_arg, Field *f) :Item_ident(thd, context_arg, f->table->s->db.str, *f->table_name, f->field_name), item_equal(0), have_privileges(0), any_privileges(0) { /* We always need to provide Item_field with a fully qualified field name to avoid ambiguity when executing prepared statements like SELECT * from d1.t1, d2.t1; (assuming d1.t1 and d2.t1 have columns with same names). This is because prepared statements never deal with wildcards in select list ('*') and always fix fields using fully specified path (i.e. db.table.column). No check for OOM: if db_name is NULL, we'll just get "Field not found" error. We need to copy db_name, table_name and field_name because they must be allocated in the statement memory, not in table memory (the table structure can go away and pop up again between subsequent executions of a prepared statement or after the close_tables_for_reopen() call in mysql_multi_update_prepare() or due to wildcard expansion in stored procedures). */ { if (db_name) orig_db_name= thd->strdup(db_name); if (table_name) orig_table_name= thd->strdup(table_name); if (field_name) orig_field_name= thd->strdup(field_name); /* We don't restore 'name' in cleanup because it's not changed during execution. Still we need it to point to persistent memory if this item is to be reused. */ name= (char*) orig_field_name; } set_field(f); with_field= 1; } Item_field::Item_field(THD *thd, Name_resolution_context *context_arg, const char *db_arg,const char *table_name_arg, const char *field_name_arg) :Item_ident(thd, context_arg, db_arg, table_name_arg, field_name_arg), field(0), item_equal(0), have_privileges(0), any_privileges(0) { SELECT_LEX *select= thd->lex->current_select; collation.set(DERIVATION_IMPLICIT); if (select && select->parsing_place != IN_HAVING) select->select_n_where_fields++; with_field= 1; } /** Constructor need to process subselect with temporary tables (see Item) */ Item_field::Item_field(THD *thd, Item_field *item) :Item_ident(thd, item), field(item->field), item_equal(item->item_equal), have_privileges(item->have_privileges), any_privileges(item->any_privileges) { collation.set(DERIVATION_IMPLICIT); with_field= 1; } /** Calculate the max column length not taking into account the limitations over integer types. When storing data into fields the server currently just ignores the limits specified on integer types, e.g. 1234 can safely be stored in an int(2) and will not cause an error. Thus when creating temporary tables and doing transformations we must adjust the maximum field length to reflect this fact. We take the un-restricted maximum length and adjust it similarly to how the declared length is adjusted wrt unsignedness etc. TODO: this all needs to go when we disable storing 1234 in int(2). @param field_par Original field the use to calculate the lengths @param max_length Item's calculated explicit max length @return The adjusted max length */ inline static uint32 adjust_max_effective_column_length(Field *field_par, uint32 max_length) { uint32 new_max_length= field_par->max_display_length(); uint32 sign_length= (field_par->flags & UNSIGNED_FLAG) ? 0 : 1; switch (field_par->type()) { case MYSQL_TYPE_INT24: /* Compensate for MAX_MEDIUMINT_WIDTH being 1 too long (8) compared to the actual number of digits that can fit into the column. */ new_max_length+= 1; /* fall through */ case MYSQL_TYPE_LONG: case MYSQL_TYPE_TINY: case MYSQL_TYPE_SHORT: /* Take out the sign and add a conditional sign */ new_max_length= new_max_length - 1 + sign_length; break; /* BINGINT is always 20 no matter the sign */ case MYSQL_TYPE_LONGLONG: /* make gcc happy */ default: break; } /* Adjust only if the actual precision based one is bigger than specified */ return new_max_length > max_length ? new_max_length : max_length; } void Item_field::set_field(Field *field_par) { field=result_field=field_par; // for easy coding with fields maybe_null=field->maybe_null(); decimals= field->decimals(); table_name= *field_par->table_name; field_name= field_par->field_name; db_name= field_par->table->s->db.str; alias_name_used= field_par->table->alias_name_used; unsigned_flag= MY_TEST(field_par->flags & UNSIGNED_FLAG); collation.set(field_par->charset(), field_par->derivation(), field_par->repertoire()); fix_char_length(field_par->char_length()); max_length= adjust_max_effective_column_length(field_par, max_length); fixed= 1; if (field->table->s->tmp_table == SYSTEM_TMP_TABLE) any_privileges= 0; } /** Reset this item to point to a field from the new temporary table. This is used when we create a new temporary table for each execution of prepared statement. */ void Item_field::reset_field(Field *f) { set_field(f); /* 'name' is pointing at field->field_name of old field */ name= (char*) f->field_name; } void Item_field::load_data_print_for_log_event(THD *thd, String *to) const { append_identifier(thd, to, name, (uint) strlen(name)); } bool Item_field::load_data_set_no_data(THD *thd, const Load_data_param *param) { if (field->load_data_set_no_data(thd, param->is_fixed_length())) return true; /* TODO: We probably should not throw warning for each field. But how about intention to always have the same number of warnings in THD::cuted_fields (and get rid of cuted_fields in the end ?) */ thd->cuted_fields++; push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN, ER_WARN_TOO_FEW_RECORDS, ER_THD(thd, ER_WARN_TOO_FEW_RECORDS), thd->get_stmt_da()->current_row_for_warning()); return false; } bool Item_field::enumerate_field_refs_processor(void *arg) { Field_enumerator *fe= (Field_enumerator*)arg; fe->visit_field(this); return FALSE; } bool Item_field::update_table_bitmaps_processor(void *arg) { update_table_bitmaps(); return FALSE; } static inline void set_field_to_new_field(Field **field, Field **new_field) { if (*field && (*field)->table == new_field[0]->table) { Field *newf= new_field[(*field)->field_index]; if ((*field)->ptr == newf->ptr) *field= newf; } } bool Item_field::switch_to_nullable_fields_processor(void *arg) { Field **new_fields= (Field **)arg; set_field_to_new_field(&field, new_fields); set_field_to_new_field(&result_field, new_fields); maybe_null= field && field->maybe_null(); return 0; } const char *Item_ident::full_name() const { char *tmp; if (!table_name || !field_name) return field_name ? field_name : name ? name : "tmp_field"; if (db_name && db_name[0]) { THD *thd= current_thd; tmp=(char*) thd->alloc((uint) strlen(db_name)+(uint) strlen(table_name)+ (uint) strlen(field_name)+3); strxmov(tmp,db_name,".",table_name,".",field_name,NullS); } else { if (table_name[0]) { THD *thd= current_thd; tmp= (char*) thd->alloc((uint) strlen(table_name) + (uint) strlen(field_name) + 2); strxmov(tmp, table_name, ".", field_name, NullS); } else tmp= (char*) field_name; } return tmp; } void Item_ident::print(String *str, enum_query_type query_type) { THD *thd= current_thd; char d_name_buff[MAX_ALIAS_NAME], t_name_buff[MAX_ALIAS_NAME]; const char *d_name= db_name, *t_name= table_name; bool use_table_name= table_name && table_name[0]; bool use_db_name= use_table_name && db_name && db_name[0] && !alias_name_used; if (use_db_name && (query_type & QT_ITEM_IDENT_SKIP_DB_NAMES)) use_db_name= !thd->db || strcmp(thd->db, db_name); if (use_db_name) use_db_name= !(cached_table && cached_table->belong_to_view && cached_table->belong_to_view->compact_view_format); if (use_table_name && (query_type & QT_ITEM_IDENT_SKIP_TABLE_NAMES)) { /* Don't print the table name if it's the only table in the context XXX technically, that's a sufficient, but too strong condition */ if (!context) use_db_name= use_table_name= false; else if (context->outer_context) use_table_name= true; else if (context->last_name_resolution_table == context->first_name_resolution_table) use_db_name= use_table_name= false; else if (!context->last_name_resolution_table && !context->first_name_resolution_table->next_name_resolution_table) use_db_name= use_table_name= false; } if (!field_name || !field_name[0]) { append_identifier(thd, str, STRING_WITH_LEN("tmp_field")); return; } if (lower_case_table_names== 1 || (lower_case_table_names == 2 && !alias_name_used)) { if (use_table_name) { strmov(t_name_buff, table_name); my_casedn_str(files_charset_info, t_name_buff); t_name= t_name_buff; } if (use_db_name) { strmov(d_name_buff, db_name); my_casedn_str(files_charset_info, d_name_buff); d_name= d_name_buff; } } if (use_db_name) { append_identifier(thd, str, d_name, (uint)strlen(d_name)); str->append('.'); DBUG_ASSERT(use_table_name); } if (use_table_name) { append_identifier(thd, str, t_name, (uint) strlen(t_name)); str->append('.'); } append_identifier(thd, str, field_name, (uint) strlen(field_name)); } /* ARGSUSED */ String *Item_field::val_str(String *str) { DBUG_ASSERT(fixed == 1); if ((null_value=field->is_null())) return 0; str->set_charset(str_value.charset()); return field->val_str(str,&str_value); } double Item_field::val_real() { DBUG_ASSERT(fixed == 1); if ((null_value=field->is_null())) return 0.0; return field->val_real(); } longlong Item_field::val_int() { DBUG_ASSERT(fixed == 1); if ((null_value=field->is_null())) return 0; return field->val_int(); } my_decimal *Item_field::val_decimal(my_decimal *decimal_value) { if ((null_value= field->is_null())) return 0; return field->val_decimal(decimal_value); } String *Item_field::str_result(String *str) { if ((null_value=result_field->is_null())) return 0; str->set_charset(str_value.charset()); return result_field->val_str(str,&str_value); } bool Item_field::get_date(MYSQL_TIME *ltime,ulonglong fuzzydate) { if ((null_value=field->is_null()) || field->get_date(ltime,fuzzydate)) { bzero((char*) ltime,sizeof(*ltime)); return 1; } return 0; } bool Item_field::get_date_result(MYSQL_TIME *ltime, ulonglong fuzzydate) { if ((null_value= result_field->is_null()) || result_field->get_date(ltime, fuzzydate)) { bzero((char*) ltime,sizeof(*ltime)); return true; } return false; } void Item_field::save_result(Field *to) { save_field_in_field(result_field, &null_value, to, TRUE); } double Item_field::val_result() { if ((null_value=result_field->is_null())) return 0.0; return result_field->val_real(); } longlong Item_field::val_int_result() { if ((null_value=result_field->is_null())) return 0; return result_field->val_int(); } my_decimal *Item_field::val_decimal_result(my_decimal *decimal_value) { if ((null_value= result_field->is_null())) return 0; return result_field->val_decimal(decimal_value); } bool Item_field::val_bool_result() { if ((null_value= result_field->is_null())) return false; return result_field->val_bool(); } bool Item_field::is_null_result() { return (null_value=result_field->is_null()); } bool Item_field::eq(const Item *item, bool binary_cmp) const { Item *real_item2= ((Item *) item)->real_item(); if (real_item2->type() != FIELD_ITEM) return 0; Item_field *item_field= (Item_field*) real_item2; if (item_field->field && field) return item_field->field == field; /* We may come here when we are trying to find a function in a GROUP BY clause from the select list. In this case the '100 % correct' way to do this would be to first run fix_fields() on the GROUP BY item and then retry this function, but I think it's better to relax the checking a bit as we will in most cases do the correct thing by just checking the field name. (In cases where we would choose wrong we would have to generate a ER_NON_UNIQ_ERROR). */ return (!my_strcasecmp(system_charset_info, item_field->name, field_name) && (!item_field->table_name || !table_name || (!my_strcasecmp(table_alias_charset, item_field->table_name, table_name) && (!item_field->db_name || !db_name || (item_field->db_name && !strcmp(item_field->db_name, db_name)))))); } table_map Item_field::used_tables() const { if (field->table->const_table) return 0; // const item return (get_depended_from() ? OUTER_REF_TABLE_BIT : field->table->map); } table_map Item_field::all_used_tables() const { return (get_depended_from() ? OUTER_REF_TABLE_BIT : field->table->map); } void Item_field::fix_after_pullout(st_select_lex *new_parent, Item **ref, bool merge) { if (new_parent == get_depended_from()) depended_from= NULL; if (context) { bool need_change= false; /* Suppose there are nested selects: select_id=1 select_id=2 select_id=3 <----+ select_id=4 -+ select_id=5 --+ Suppose, pullout operation has moved anything that had select_id=4 or 5 in to select_id=3. If this Item_field had a name resolution context pointing into select_lex with id=4 or id=5, it needs a new name resolution context. However, it could also be that this object is a part of outer reference: Item_ref(Item_field(field in select with select_id=1))). - The Item_ref object has a context with select_id=5, and so needs a new name resolution context. - The Item_field object has a context with select_id=1, and doesn't need a new name resolution context. So, the following loop walks from Item_field's current context upwards. If we find that the select we've been pulled out to is up there, we create the new name resolution context. Otherwise, we don't. */ for (Name_resolution_context *ct= context; ct; ct= ct->outer_context) { if (new_parent == ct->select_lex) { need_change= true; break; } } if (!need_change) return; if (!merge) { /* It is transformation without merge. This field was "outer" for the inner SELECT where it was taken and moved up. "Outer" fields uses normal SELECT_LEX context of upper SELECTs for name resolution, so we can switch everything to it safely. */ this->context= &new_parent->context; return; } Name_resolution_context *ctx= new Name_resolution_context(); if (context->select_lex == new_parent) { /* This field was pushed in then pulled out (for example left part of IN) */ ctx->outer_context= context->outer_context; } else if (context->outer_context) { /* just pull to the upper context */ ctx->outer_context= context->outer_context->outer_context; } else { /* No upper context (merging Derived/VIEW where context chain ends) */ ctx->outer_context= NULL; } ctx->table_list= context->first_name_resolution_table; ctx->select_lex= new_parent; if (context->select_lex == NULL) ctx->select_lex= NULL; ctx->first_name_resolution_table= context->first_name_resolution_table; ctx->last_name_resolution_table= context->last_name_resolution_table; ctx->error_processor= context->error_processor; ctx->error_processor_data= context->error_processor_data; ctx->resolve_in_select_list= context->resolve_in_select_list; ctx->security_ctx= context->security_ctx; this->context=ctx; } } Item *Item_field::get_tmp_table_item(THD *thd) { Item_field *new_item= new (thd->mem_root) Item_temptable_field(thd, this); if (new_item) new_item->field= new_item->result_field; return new_item; } longlong Item_field::val_int_endpoint(bool left_endp, bool *incl_endp) { longlong res= val_int(); return null_value? LONGLONG_MIN : res; } /** Create an item from a string we KNOW points to a valid longlong end \\0 terminated number string. This is always 'signed'. Unsigned values are created with Item_uint() */ Item_int::Item_int(THD *thd, const char *str_arg, uint length): Item_num(thd) { char *end_ptr= (char*) str_arg + length; int error; value= my_strtoll10(str_arg, &end_ptr, &error); max_length= (uint) (end_ptr - str_arg); name= (char*) str_arg; fixed= 1; } my_decimal *Item_int::val_decimal(my_decimal *decimal_value) { int2my_decimal(E_DEC_FATAL_ERROR, value, unsigned_flag, decimal_value); return decimal_value; } String *Item_int::val_str(String *str) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); str->set_int(value, unsigned_flag, collation.collation); return str; } void Item_int::print(String *str, enum_query_type query_type) { // my_charset_bin is good enough for numbers str_value.set_int(value, unsigned_flag, &my_charset_bin); str->append(str_value); } Item *Item_bool::neg_transformer(THD *thd) { value= !value; name= 0; return this; } Item_uint::Item_uint(THD *thd, const char *str_arg, uint length): Item_int(thd, str_arg, length) { unsigned_flag= 1; } Item_uint::Item_uint(THD *thd, const char *str_arg, longlong i, uint length): Item_int(thd, str_arg, i, length) { unsigned_flag= 1; } String *Item_uint::val_str(String *str) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); str->set((ulonglong) value, collation.collation); return str; } void Item_uint::print(String *str, enum_query_type query_type) { // latin1 is good enough for numbers str_value.set((ulonglong) value, default_charset()); str->append(str_value); } Item_decimal::Item_decimal(THD *thd, const char *str_arg, uint length, CHARSET_INFO *charset): Item_num(thd) { str2my_decimal(E_DEC_FATAL_ERROR, str_arg, length, charset, &decimal_value); name= (char*) str_arg; decimals= (uint8) decimal_value.frac; fixed= 1; max_length= my_decimal_precision_to_length_no_truncation(decimal_value.intg + decimals, decimals, unsigned_flag); } Item_decimal::Item_decimal(THD *thd, longlong val, bool unsig): Item_num(thd) { int2my_decimal(E_DEC_FATAL_ERROR, val, unsig, &decimal_value); decimals= (uint8) decimal_value.frac; fixed= 1; max_length= my_decimal_precision_to_length_no_truncation(decimal_value.intg + decimals, decimals, unsigned_flag); } Item_decimal::Item_decimal(THD *thd, double val, int precision, int scale): Item_num(thd) { double2my_decimal(E_DEC_FATAL_ERROR, val, &decimal_value); decimals= (uint8) decimal_value.frac; fixed= 1; max_length= my_decimal_precision_to_length_no_truncation(decimal_value.intg + decimals, decimals, unsigned_flag); } Item_decimal::Item_decimal(THD *thd, const char *str, const my_decimal *val_arg, uint decimal_par, uint length): Item_num(thd) { my_decimal2decimal(val_arg, &decimal_value); name= (char*) str; decimals= (uint8) decimal_par; max_length= length; fixed= 1; } Item_decimal::Item_decimal(THD *thd, my_decimal *value_par): Item_num(thd) { my_decimal2decimal(value_par, &decimal_value); decimals= (uint8) decimal_value.frac; fixed= 1; max_length= my_decimal_precision_to_length_no_truncation(decimal_value.intg + decimals, decimals, unsigned_flag); } Item_decimal::Item_decimal(THD *thd, const uchar *bin, int precision, int scale): Item_num(thd) { binary2my_decimal(E_DEC_FATAL_ERROR, bin, &decimal_value, precision, scale); decimals= (uint8) decimal_value.frac; fixed= 1; max_length= my_decimal_precision_to_length_no_truncation(precision, decimals, unsigned_flag); } longlong Item_decimal::val_int() { longlong result; my_decimal2int(E_DEC_FATAL_ERROR, &decimal_value, unsigned_flag, &result); return result; } double Item_decimal::val_real() { double result; my_decimal2double(E_DEC_FATAL_ERROR, &decimal_value, &result); return result; } String *Item_decimal::val_str(String *result) { result->set_charset(&my_charset_numeric); my_decimal2string(E_DEC_FATAL_ERROR, &decimal_value, 0, 0, 0, result); return result; } void Item_decimal::print(String *str, enum_query_type query_type) { my_decimal2string(E_DEC_FATAL_ERROR, &decimal_value, 0, 0, 0, &str_value); str->append(str_value); } bool Item_decimal::eq(const Item *item, bool binary_cmp) const { if (type() == item->type() && item->basic_const_item()) { /* We need to cast off const to call val_decimal(). This should be OK for a basic constant. Additionally, we can pass 0 as a true decimal constant will return its internal decimal storage and ignore the argument. */ Item *arg= (Item*) item; my_decimal *value= arg->val_decimal(0); return !my_decimal_cmp(&decimal_value, value); } return 0; } void Item_decimal::set_decimal_value(my_decimal *value_par) { my_decimal2decimal(value_par, &decimal_value); decimals= (uint8) decimal_value.frac; unsigned_flag= !decimal_value.sign(); max_length= my_decimal_precision_to_length_no_truncation(decimal_value.intg + decimals, decimals, unsigned_flag); } Item *Item_decimal::clone_item(THD *thd) { return new (thd->mem_root) Item_decimal(thd, name, &decimal_value, decimals, max_length); } String *Item_float::val_str(String *str) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); str->set_real(value, decimals, &my_charset_numeric); return str; } my_decimal *Item_float::val_decimal(my_decimal *decimal_value) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); double2my_decimal(E_DEC_FATAL_ERROR, value, decimal_value); return (decimal_value); } Item *Item_float::clone_item(THD *thd) { return new (thd->mem_root) Item_float(thd, name, value, decimals, max_length); } void Item_string::print(String *str, enum_query_type query_type) { const bool print_introducer= !(query_type & QT_WITHOUT_INTRODUCERS) && is_cs_specified(); if (print_introducer) { str->append('_'); str->append(collation.collation->csname); } str->append('\''); if (query_type & QT_TO_SYSTEM_CHARSET) { if (print_introducer) { /* Because we wrote an introducer, we must print str_value in its charset, and the resulting bytes must not be changed until they reach the end client. But the caller is asking for system_charset_info, and may later convert into character_set_results. That means two conversions: we must ensure that they don't change our printed bytes. So we print str_value in the least common denominator of the three charsets involved: ASCII. Non-ASCII characters are printed as \xFF sequences (which is ASCII too). This way, our bytes will not be changed. */ ErrConvString tmp(str_value.ptr(), str_value.length(), &my_charset_bin); str->append(tmp.ptr()); } else { str_value.print(str, system_charset_info); } } else { /* We're restoring a parse-able statement from an Item tree. Make sure to revert character set conversions that previously happened in the parser when Item_string was created. */ if (print_introducer) { /* Print the string as is, without conversion: Strings with introducers are not converted in the parser. */ str_value.print(str); } else { /* Print the string with conversion. Strings without introducers are converted in the parser, from character_set_client to character_set_connection. When restoring a CREATE VIEW statement, - str_value.charsets() contains parse time character_set_connection - str->charset() contains parse time character_set_client So we convert the string back from parse-time character_set_connection to parse time character_set_client. In some cases, e.g. SHOW PROCEDURE CODE, it's also possible that str->charset() is "utf8mb3" instead of parse time character_set_client. In these cases we convert here from the parse-time character_set_connection to utf8mb3. QQ: perhaps the code behind SHOW PROCEDURE CODE should also request the result in the parse-time character_set_client (like the code restoring CREATE VIEW statements does), rather than in utf8mb3: - utf8mb3 does not work well with non-BMP characters (e.g. emoji). - Simply changing utf8mb3 to utf8mb4 will not fully help: some character sets have unassigned characters, they get lost during during cs->utf8mb4->cs round trip. */ str_value.print_with_conversion(str, str->charset()); } } str->append('\''); } double Item_string::val_real() { DBUG_ASSERT(fixed == 1); return double_from_string_with_check(&str_value); } /** @todo Give error if we wanted a signed integer and we got an unsigned one */ longlong Item_string::val_int() { DBUG_ASSERT(fixed == 1); return longlong_from_string_with_check(&str_value); } my_decimal *Item_string::val_decimal(my_decimal *decimal_value) { return val_decimal_from_string(decimal_value); } double Item_null::val_real() { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); null_value=1; return 0.0; } longlong Item_null::val_int() { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); null_value=1; return 0; } /* ARGSUSED */ String *Item_null::val_str(String *str) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); null_value=1; return 0; } my_decimal *Item_null::val_decimal(my_decimal *decimal_value) { return 0; } longlong Item_null::val_datetime_packed() { null_value= true; return 0; } longlong Item_null::val_time_packed() { null_value= true; return 0; } bool Item_null::get_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { // following assert is redundant, because fixed=1 assigned in constructor DBUG_ASSERT(fixed == 1); make_zero_date(ltime, fuzzydate); return (null_value= true); } Item *Item_null::safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { return this; } Item *Item_null::clone_item(THD *thd) { return new (thd->mem_root) Item_null(thd, name); } /*********************** Item_param related ******************************/ /** Default function of Item_param::set_param_func, so in case of malformed packet the server won't SIGSEGV. */ static void default_set_param_func(Item_param *param, uchar **pos __attribute__((unused)), ulong len __attribute__((unused))) { param->set_null(); } Item_param::Item_param(THD *thd, uint pos_in_query_arg): Item_basic_value(thd), Rewritable_query_parameter(pos_in_query_arg, 1), Type_handler_hybrid_field_type(MYSQL_TYPE_VARCHAR), state(NO_VALUE), /* Don't pretend to be a literal unless value for this item is set. */ item_type(PARAM_ITEM), indicator(STMT_INDICATOR_NONE), set_param_func(default_set_param_func), m_out_param_info(NULL), /* Set m_is_settable_routine_parameter to "true" by default. This is needed for client-server protocol, whose parameters are always settable. For dynamic SQL, settability depends on the type of Item passed as an actual parameter. See Item_param::set_from_item(). */ m_is_settable_routine_parameter(true), m_clones(thd->mem_root) { name= (char*) "?"; /* Since we can't say whenever this item can be NULL or cannot be NULL before mysql_stmt_execute(), so we assuming that it can be NULL until value is set. */ maybe_null= 1; } /* Add reference to Item_param used in a copy of CTE to its master as a clone */ bool Item_param::add_as_clone(THD *thd) { LEX *lex= thd->lex; uint master_pos= pos_in_query + lex->clone_spec_offset; List_iterator_fast it(lex->param_list); Item_param *master_param; while ((master_param = it++)) { if (master_pos == master_param->pos_in_query) return master_param->register_clone(this); } DBUG_ASSERT(false); return false; } /* Update all clones of Item_param to sync their values with the item's value */ void Item_param::sync_clones() { Item_param **c_ptr= m_clones.begin(); Item_param **end= m_clones.end(); for ( ; c_ptr < end; c_ptr++) { Item_param *c= *c_ptr; /* Scalar-type members: */ c->maybe_null= maybe_null; c->null_value= null_value; c->max_length= max_length; c->decimals= decimals; c->state= state; c->item_type= item_type; c->set_param_func= set_param_func; c->value= value; c->unsigned_flag= unsigned_flag; /* Class-type members: */ c->decimal_value= decimal_value; /* Note that String's assignment op properly sets m_is_alloced to 'false', which is correct here: c->str_value doesn't own anything. */ c->str_value= str_value; c->str_value_ptr= str_value_ptr; c->collation= collation; } } void Item_param::set_null() { DBUG_ENTER("Item_param::set_null"); /* These are cleared after each execution by reset() method or by setting other value. */ null_value= 1; /* Because of NULL and string values we need to set max_length for each new placeholder value: user can submit NULL for any placeholder type, and string length can be different in each execution. */ max_length= 0; decimals= 0; state= NULL_VALUE; fix_type(Item::NULL_ITEM); DBUG_VOID_RETURN; } void Item_param::set_int(longlong i, uint32 max_length_arg) { DBUG_ENTER("Item_param::set_int"); value.integer= (longlong) i; state= INT_VALUE; collation.set_numeric(); max_length= max_length_arg; decimals= 0; maybe_null= 0; null_value= 0; fix_type(Item::INT_ITEM); DBUG_VOID_RETURN; } void Item_param::set_double(double d) { DBUG_ENTER("Item_param::set_double"); value.real= d; state= REAL_VALUE; collation.set_numeric(); max_length= DBL_DIG + 8; decimals= NOT_FIXED_DEC; maybe_null= 0; null_value= 0; fix_type(Item::REAL_ITEM); DBUG_VOID_RETURN; } /** Set decimal parameter value from string. @param str character string @param length string length @note As we use character strings to send decimal values in binary protocol, we use str2my_decimal to convert it to internal decimal value. */ void Item_param::set_decimal(const char *str, ulong length) { char *end; DBUG_ENTER("Item_param::set_decimal"); end= (char*) str+length; str2my_decimal(E_DEC_FATAL_ERROR, str, &decimal_value, &end); state= DECIMAL_VALUE; decimals= decimal_value.frac; collation.set_numeric(); max_length= my_decimal_precision_to_length_no_truncation(decimal_value.precision(), decimals, unsigned_flag); maybe_null= 0; null_value= 0; fix_type(Item::DECIMAL_ITEM); DBUG_VOID_RETURN; } void Item_param::set_decimal(const my_decimal *dv, bool unsigned_arg) { state= DECIMAL_VALUE; my_decimal2decimal(dv, &decimal_value); decimals= (uint8) decimal_value.frac; collation.set_numeric(); unsigned_flag= unsigned_arg; max_length= my_decimal_precision_to_length(decimal_value.intg + decimals, decimals, unsigned_flag); maybe_null= 0; null_value= 0; fix_type(Item::DECIMAL_ITEM); } void Item_param::fix_temporal(uint32 max_length_arg, uint decimals_arg) { state= TIME_VALUE; collation.set_numeric(); max_length= max_length_arg; decimals= decimals_arg; maybe_null= 0; null_value= 0; fix_type(Item::DATE_ITEM); } void Item_param::set_time(const MYSQL_TIME *tm, uint32 max_length_arg, uint decimals_arg) { value.time= *tm; maybe_null= 0; null_value= 0; fix_temporal(max_length_arg, decimals_arg); } /** Set parameter value from MYSQL_TIME value. @param tm datetime value to set (time_type is ignored) @param type type of datetime value @param max_length_arg max length of datetime value as string @note If we value to be stored is not normalized, zero value will be stored instead and proper warning will be produced. This function relies on the fact that even wrong value sent over binary protocol fits into MAX_DATE_STRING_REP_LENGTH buffer. */ void Item_param::set_time(MYSQL_TIME *tm, timestamp_type time_type, uint32 max_length_arg) { DBUG_ENTER("Item_param::set_time"); value.time= *tm; value.time.time_type= time_type; if (check_datetime_range(&value.time)) { ErrConvTime str(&value.time); make_truncated_value_warning(current_thd, Sql_condition::WARN_LEVEL_WARN, &str, time_type, NULL, NULL, NULL); set_zero_time(&value.time, time_type); } maybe_null= 0; null_value= 0; fix_temporal(max_length_arg, tm->second_part > 0 ? TIME_SECOND_PART_DIGITS : 0); DBUG_VOID_RETURN; } bool Item_param::set_str(const char *str, ulong length) { DBUG_ENTER("Item_param::set_str"); /* Assign string with no conversion: data is converted only after it's been written to the binary log. */ uint dummy_errors; if (str_value.copy(str, length, &my_charset_bin, &my_charset_bin, &dummy_errors)) DBUG_RETURN(TRUE); state= STRING_VALUE; max_length= length; maybe_null= 0; null_value= 0; /* max_length and decimals are set after charset conversion */ /* sic: str may be not null-terminated, don't add DBUG_PRINT here */ fix_type(Item::STRING_ITEM); DBUG_RETURN(FALSE); } bool Item_param::set_longdata(const char *str, ulong length) { DBUG_ENTER("Item_param::set_longdata"); /* If client character set is multibyte, end of long data packet may hit at the middle of a multibyte character. Additionally, if binary log is open we must write long data value to the binary log in character set of client. This is why we can't convert long data to connection character set as it comes (here), and first have to concatenate all pieces together, write query to the binary log and only then perform conversion. */ if (str_value.length() + length > max_long_data_size) { my_message(ER_UNKNOWN_ERROR, "Parameter of prepared statement which is set through " "mysql_send_long_data() is longer than " "'max_long_data_size' bytes", MYF(0)); DBUG_RETURN(true); } if (str_value.append(str, length, &my_charset_bin)) DBUG_RETURN(TRUE); state= LONG_DATA_VALUE; maybe_null= 0; null_value= 0; fix_type(Item::STRING_ITEM); DBUG_RETURN(FALSE); } void Item_param::CONVERSION_INFO::set(THD *thd, CHARSET_INFO *fromcs) { CHARSET_INFO *tocs= thd->variables.collation_connection; character_set_of_placeholder= fromcs; character_set_client= thd->variables.character_set_client; /* Setup source and destination character sets so that they are different only if conversion is necessary: this will make later checks easier. */ uint32 dummy_offset; final_character_set_of_str_value= String::needs_conversion(0, fromcs, tocs, &dummy_offset) ? tocs : fromcs; } bool Item_param::CONVERSION_INFO::convert(THD *thd, String *str) { return thd->convert_string(str, character_set_of_placeholder, final_character_set_of_str_value); } /** Set parameter value from Item. @param thd Current thread @param item Item @retval 0 OK @retval 1 Out of memory */ bool Item_param::set_from_item(THD *thd, Item *item) { DBUG_ENTER("Item_param::set_from_item"); m_is_settable_routine_parameter= item->get_settable_routine_parameter(); if (limit_clause_param) { longlong val= item->val_int(); if (item->null_value) { set_null(); DBUG_RETURN(false); } else { unsigned_flag= item->unsigned_flag; set_int(val, MY_INT64_NUM_DECIMAL_DIGITS); set_handler_by_result_type(item->result_type()); DBUG_RETURN(!unsigned_flag && value.integer < 0 ? 1 : 0); } } struct st_value tmp; if (!item->store(&tmp, 0)) { unsigned_flag= item->unsigned_flag; switch (item->cmp_type()) { case REAL_RESULT: set_double(tmp.value.m_double); set_handler_by_field_type(MYSQL_TYPE_DOUBLE); break; case INT_RESULT: set_int(tmp.value.m_longlong, MY_INT64_NUM_DECIMAL_DIGITS); set_handler_by_field_type(MYSQL_TYPE_LONGLONG); break; case STRING_RESULT: { value.cs_info.set(thd, item->collation.collation); /* Exact value of max_length is not known unless data is converted to charset of connection, so we have to set it later. */ set_handler_by_field_type(MYSQL_TYPE_VARCHAR); if (set_str(tmp.m_string.ptr(), tmp.m_string.length())) DBUG_RETURN(1); break; } case DECIMAL_RESULT: { set_decimal(&tmp.m_decimal, unsigned_flag); set_handler_by_field_type(MYSQL_TYPE_NEWDECIMAL); break; } case TIME_RESULT: { set_time(&tmp.value.m_time, item->max_length, item->decimals); set_handler(item->type_handler()); break; } case ROW_RESULT: DBUG_ASSERT(0); set_null(); } } else set_null(); DBUG_RETURN(0); } /** Resets parameter after execution. @note We clear null_value here instead of setting it in set_* methods, because we want more easily handle case for long data. */ void Item_param::reset() { DBUG_ENTER("Item_param::reset"); /* Shrink string buffer if it's bigger than max possible CHAR column */ if (str_value.alloced_length() > MAX_CHAR_WIDTH) str_value.free(); else str_value.length(0); str_value_ptr.length(0); /* We must prevent all charset conversions until data has been written to the binary log. */ str_value.set_charset(&my_charset_bin); collation.set(&my_charset_bin, DERIVATION_COERCIBLE); state= NO_VALUE; maybe_null= 1; null_value= 0; fixed= false; /* Don't reset item_type to PARAM_ITEM: it's only needed to guard us from item optimizations at prepare stage, when item doesn't yet contain a literal of some kind. In all other cases when this object is accessed its value is set (this assumption is guarded by 'state' and DBUG_ASSERTS(state != NO_VALUE) in all Item_param::get_* methods). */ DBUG_VOID_RETURN; } int Item_param::save_in_field(Field *field, bool no_conversions) { field->set_notnull(); /* There's no "default" intentionally, to make compiler complain when adding a new XXX_VALUE value. Garbage (e.g. in case of a memory overrun) is handled after the switch. */ switch (state) { case INT_VALUE: return field->store(value.integer, unsigned_flag); case REAL_VALUE: return field->store(value.real); case DECIMAL_VALUE: return field->store_decimal(&decimal_value); case TIME_VALUE: field->store_time_dec(&value.time, decimals); return 0; case STRING_VALUE: case LONG_DATA_VALUE: return field->store(str_value.ptr(), str_value.length(), str_value.charset()); case NULL_VALUE: return set_field_to_null_with_conversions(field, no_conversions); case DEFAULT_VALUE: return field->save_in_field_default_value(field->table->pos_in_table_list-> top_table() != field->table->pos_in_table_list); case IGNORE_VALUE: return field->save_in_field_ignore_value(field->table->pos_in_table_list-> top_table() != field->table->pos_in_table_list); case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return true; } DBUG_ASSERT(0); // Garbage return 1; } void Item_param::invalid_default_param() const { my_message(ER_INVALID_DEFAULT_PARAM, ER_THD(current_thd, ER_INVALID_DEFAULT_PARAM), MYF(0)); } bool Item_param::get_date(MYSQL_TIME *res, ulonglong fuzzydate) { if (state == TIME_VALUE) { *res= value.time; return 0; } return Item::get_date(res, fuzzydate); } double Item_param::val_real() { // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case REAL_VALUE: return value.real; case INT_VALUE: return (double) value.integer; case DECIMAL_VALUE: { double result; my_decimal2double(E_DEC_FATAL_ERROR, &decimal_value, &result); return result; } case STRING_VALUE: case LONG_DATA_VALUE: { return double_from_string_with_check(&str_value); } case TIME_VALUE: /* This works for example when user says SELECT ?+0.0 and supplies time value for the placeholder. */ return TIME_to_double(&value.time); case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); // fall through case NULL_VALUE: return 0.0; case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return 0.0; } DBUG_ASSERT(0); // Garbage return 0.0; } longlong Item_param::val_int() { // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case REAL_VALUE: return Converter_double_to_longlong(value.real, unsigned_flag).result(); case INT_VALUE: return value.integer; case DECIMAL_VALUE: { longlong i; my_decimal2int(E_DEC_FATAL_ERROR, &decimal_value, unsigned_flag, &i); return i; } case STRING_VALUE: case LONG_DATA_VALUE: { return longlong_from_string_with_check(&str_value); } case TIME_VALUE: return (longlong) TIME_to_ulonglong(&value.time); case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); // fall through case NULL_VALUE: return 0; case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return 0; } DBUG_ASSERT(0); // Garbage return 0; } my_decimal *Item_param::val_decimal(my_decimal *dec) { // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case DECIMAL_VALUE: return &decimal_value; case REAL_VALUE: double2my_decimal(E_DEC_FATAL_ERROR, value.real, dec); return dec; case INT_VALUE: int2my_decimal(E_DEC_FATAL_ERROR, value.integer, unsigned_flag, dec); return dec; case STRING_VALUE: case LONG_DATA_VALUE: return decimal_from_string_with_check(dec, &str_value); case TIME_VALUE: { return TIME_to_my_decimal(&value.time, dec); } case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); // fall through case NULL_VALUE: return 0; case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return 0; } DBUG_ASSERT(0); // Gabrage return 0; } String *Item_param::val_str(String* str) { // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case STRING_VALUE: case LONG_DATA_VALUE: return &str_value_ptr; case REAL_VALUE: str->set_real(value.real, NOT_FIXED_DEC, &my_charset_bin); return str; case INT_VALUE: str->set(value.integer, &my_charset_bin); return str; case DECIMAL_VALUE: if (my_decimal2string(E_DEC_FATAL_ERROR, &decimal_value, 0, 0, 0, str) <= 1) return str; return NULL; case TIME_VALUE: { if (str->reserve(MAX_DATE_STRING_REP_LENGTH)) break; str->length((uint) my_TIME_to_str(&value.time, (char*) str->ptr(), decimals)); str->set_charset(&my_charset_bin); return str; } case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); // fall through case NULL_VALUE: return NULL; case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return NULL; } DBUG_ASSERT(0); // Garbage return NULL; } /** Return Param item values in string format, for generating the dynamic query used in update/binary logs. @todo - Change interface and implementation to fill log data in place and avoid one more memcpy/alloc between str and log string. - In case of error we need to notify replication that binary log contains wrong statement */ const String *Item_param::query_val_str(THD *thd, String* str) const { // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case INT_VALUE: str->set_int(value.integer, unsigned_flag, &my_charset_bin); return str; case REAL_VALUE: str->set_real(value.real, NOT_FIXED_DEC, &my_charset_bin); return str; case DECIMAL_VALUE: if (my_decimal2string(E_DEC_FATAL_ERROR, &decimal_value, 0, 0, 0, str) > 1) return &my_null_string; return str; case TIME_VALUE: { static const uint32 typelen= 9; // "TIMESTAMP" is the longest type name char *buf, *ptr; str->length(0); /* TODO: in case of error we need to notify replication that binary log contains wrong statement */ if (str->reserve(MAX_DATE_STRING_REP_LENGTH + 3 + typelen)) break; /* Create date string inplace */ switch (value.time.time_type) { case MYSQL_TIMESTAMP_DATE: str->append(C_STRING_WITH_LEN("DATE")); break; case MYSQL_TIMESTAMP_TIME: str->append(C_STRING_WITH_LEN("TIME")); break; case MYSQL_TIMESTAMP_DATETIME: str->append(C_STRING_WITH_LEN("TIMESTAMP")); break; case MYSQL_TIMESTAMP_ERROR: case MYSQL_TIMESTAMP_NONE: break; } DBUG_ASSERT(str->length() <= typelen); buf= str->c_ptr_quick(); ptr= buf + str->length(); *ptr++= '\''; ptr+= (uint) my_TIME_to_str(&value.time, ptr, decimals); *ptr++= '\''; str->length((uint32) (ptr - buf)); return str; } case STRING_VALUE: case LONG_DATA_VALUE: { str->length(0); append_query_string(value.cs_info.character_set_client, str, str_value.ptr(), str_value.length(), thd->variables.sql_mode & MODE_NO_BACKSLASH_ESCAPES); return str; } case IGNORE_VALUE: case DEFAULT_VALUE: return &my_default_string; case NULL_VALUE: return &my_null_string; case NO_VALUE: DBUG_ASSERT(0); // Should not be possible return NULL; } DBUG_ASSERT(0); // Garbage return NULL; } /** Convert string from client character set to the character set of connection. */ bool Item_param::convert_str_value(THD *thd) { bool rc= FALSE; if (state == STRING_VALUE || state == LONG_DATA_VALUE) { rc= value.cs_info.convert_if_needed(thd, &str_value); /* Here str_value is guaranteed to be in final_character_set_of_str_value */ /* str_value_ptr is returned from val_str(). It must be not alloced to prevent it's modification by val_str() invoker. */ str_value_ptr.set(str_value.ptr(), str_value.length(), str_value.charset()); /* Synchronize item charset and length with value charset */ fix_charset_and_length_from_str_value(DERIVATION_COERCIBLE); } return rc; } bool Item_param::basic_const_item() const { DBUG_ASSERT(fixed || state == NO_VALUE); if (state == NO_VALUE || state == TIME_VALUE) return FALSE; return TRUE; } /* see comments in the header file */ Item * Item_param::clone_item(THD *thd) { MEM_ROOT *mem_root= thd->mem_root; // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); // fall through case NULL_VALUE: return new (mem_root) Item_null(thd, name); case INT_VALUE: return (unsigned_flag ? new (mem_root) Item_uint(thd, name, value.integer, max_length) : new (mem_root) Item_int(thd, name, value.integer, max_length)); case REAL_VALUE: return new (mem_root) Item_float(thd, name, value.real, decimals, max_length); case DECIMAL_VALUE: return 0; // Should create Item_decimal. See MDEV-11361. case STRING_VALUE: case LONG_DATA_VALUE: return new (mem_root) Item_string(thd, name, str_value.c_ptr_quick(), str_value.length(), str_value.charset(), collation.derivation, collation.repertoire); case TIME_VALUE: return 0; case NO_VALUE: return 0; } DBUG_ASSERT(0); // Garbage return 0; } bool Item_param::eq(const Item *item, bool binary_cmp) const { if (!basic_const_item()) return FALSE; // There's no "default". See comments in Item_param::save_in_field(). switch (state) { case IGNORE_VALUE: case DEFAULT_VALUE: invalid_default_param(); return false; case NULL_VALUE: return null_eq(item); case INT_VALUE: return int_eq(value.integer, item); case REAL_VALUE: return real_eq(value.real, item); case STRING_VALUE: case LONG_DATA_VALUE: return str_eq(&str_value, item, binary_cmp); case DECIMAL_VALUE: case TIME_VALUE: case NO_VALUE: return false; } DBUG_ASSERT(0); // Garbage return FALSE; } /* End of Item_param related */ void Item_param::print(String *str, enum_query_type query_type) { if (state == NO_VALUE) { str->append('?'); } else if (state == DEFAULT_VALUE) { str->append("default"); } else if (state == IGNORE_VALUE) { str->append("ignore"); } else { char buffer[STRING_BUFFER_USUAL_SIZE]; String tmp(buffer, sizeof(buffer), &my_charset_bin); const String *res; res= query_val_str(current_thd, &tmp); str->append(*res); } } /** Preserve the original parameter types and values when re-preparing a prepared statement. @details Copy parameter type information and conversion function pointers from a parameter of the old statement to the corresponding parameter of the new one. Move parameter values from the old parameters to the new one. We simply "exchange" the values, which allows to save on allocation and character set conversion in case a parameter is a string or a blob/clob. The old parameter gets the value of this one, which ensures that all memory of this parameter is freed correctly. @param[in] src parameter item of the original prepared statement */ void Item_param::set_param_type_and_swap_value(Item_param *src) { Type_std_attributes::set(src); set_handler(src->type_handler()); set_param_func= src->set_param_func; item_type= src->item_type; maybe_null= src->maybe_null; null_value= src->null_value; state= src->state; fixed= src->fixed; value= src->value; decimal_value.swap(src->decimal_value); str_value.swap(src->str_value); str_value_ptr.swap(src->str_value_ptr); } void Item_param::set_default() { m_is_settable_routine_parameter= false; state= DEFAULT_VALUE; fixed= true; /* When Item_param is set to DEFAULT_VALUE: - its val_str() and val_decimal() return NULL - get_date() returns true It's important also to have null_value==true for DEFAULT_VALUE. Otherwise the callers of val_xxx() and get_date(), e.g. Item::send(), can misbehave (e.g. crash on asserts). */ null_value= true; } void Item_param::set_ignore() { m_is_settable_routine_parameter= false; state= IGNORE_VALUE; fixed= true; null_value= true; } /** This operation is intended to store some item value in Item_param to be used later. @param thd thread context @param ctx stored procedure runtime context @param it a pointer to an item in the tree @return Error status @retval TRUE on error @retval FALSE on success */ bool Item_param::set_value(THD *thd, sp_rcontext *ctx, Item **it) { Item *arg= *it; if (arg->is_null()) { set_null(); return FALSE; } null_value= FALSE; unsigned_flag= arg->unsigned_flag; switch (arg->result_type()) { case STRING_RESULT: { char str_buffer[STRING_BUFFER_USUAL_SIZE]; String sv_buffer(str_buffer, sizeof(str_buffer), &my_charset_bin); String *sv= arg->val_str(&sv_buffer); if (!sv) return TRUE; set_str(sv->c_ptr_safe(), sv->length()); str_value_ptr.set(str_value.ptr(), str_value.length(), str_value.charset()); collation.set(str_value.charset(), DERIVATION_COERCIBLE); decimals= 0; break; } case REAL_RESULT: set_double(arg->val_real()); break; case INT_RESULT: set_int(arg->val_int(), arg->max_length); break; case DECIMAL_RESULT: { my_decimal dv_buf; my_decimal *dv= arg->val_decimal(&dv_buf); if (!dv) return TRUE; set_decimal(dv, !dv->sign()); break; } default: /* That can not happen. */ DBUG_ASSERT(TRUE); // Abort in debug mode. set_null(); // Set to NULL in release mode. return FALSE; } set_handler_by_result_type(arg->result_type()); return FALSE; } /** Setter of Item_param::m_out_param_info. m_out_param_info is used to store information about store routine OUT-parameters, such as stored routine name, database, stored routine variable name. It is supposed to be set in sp_head::execute() after Item_param::set_value() is called. */ void Item_param::set_out_param_info(Send_field *info) { m_out_param_info= info; set_handler_by_field_type(m_out_param_info->type); } /** Getter of Item_param::m_out_param_info. m_out_param_info is used to store information about store routine OUT-parameters, such as stored routine name, database, stored routine variable name. It is supposed to be retrieved in Protocol_binary::send_out_parameters() during creation of OUT-parameter result set. */ const Send_field * Item_param::get_out_param_info() const { return m_out_param_info; } /** Fill meta-data information for the corresponding column in a result set. If this is an OUT-parameter of a stored procedure, preserve meta-data of stored-routine variable. @param field container for meta-data to be filled */ void Item_param::make_field(THD *thd, Send_field *field) { Item::make_field(thd, field); if (!m_out_param_info) return; /* This is an OUT-parameter of stored procedure. We should use OUT-parameter info to fill out the names. */ field->db_name= m_out_param_info->db_name; field->table_name= m_out_param_info->table_name; field->org_table_name= m_out_param_info->org_table_name; field->col_name= m_out_param_info->col_name; field->org_col_name= m_out_param_info->org_col_name; field->length= m_out_param_info->length; field->charsetnr= m_out_param_info->charsetnr; field->flags= m_out_param_info->flags; field->decimals= m_out_param_info->decimals; field->type= m_out_param_info->type; } bool Item_param::append_for_log(THD *thd, String *str) { StringBuffer buf; const String *val= query_val_str(thd, &buf); return str->append(*val); } /**************************************************************************** Item_copy_string ****************************************************************************/ double Item_copy_string::val_real() { int err_not_used; char *end_not_used; return (null_value ? 0.0 : my_strntod(str_value.charset(), (char*) str_value.ptr(), str_value.length(), &end_not_used, &err_not_used)); } longlong Item_copy_string::val_int() { int err; return null_value ? 0 : my_strntoll(str_value.charset(),str_value.ptr(), str_value.length(), 10, (char**) 0, &err); } int Item_copy_string::save_in_field(Field *field, bool no_conversions) { return save_str_value_in_field(field, &str_value); } void Item_copy_string::copy() { String *res=item->val_str(&str_value); if (res && res != &str_value) str_value.copy(*res); null_value=item->null_value; } /* ARGSUSED */ String *Item_copy_string::val_str(String *str) { // Item_copy_string is used without fix_fields call if (null_value) return (String*) 0; return &str_value; } my_decimal *Item_copy_string::val_decimal(my_decimal *decimal_value) { // Item_copy_string is used without fix_fields call if (null_value) return (my_decimal *) 0; string2my_decimal(E_DEC_FATAL_ERROR, &str_value, decimal_value); return (decimal_value); } /* Functions to convert item to field (for send_result_set_metadata) */ /* ARGSUSED */ bool Item::fix_fields(THD *thd, Item **ref) { // We do not check fields which are fixed during construction DBUG_ASSERT(fixed == 0 || basic_const_item()); fixed= 1; return FALSE; } void Item_ref_null_helper::save_val(Field *to) { DBUG_ASSERT(fixed == 1); (*ref)->save_val(to); owner->was_null|= null_value= (*ref)->null_value; } double Item_ref_null_helper::val_real() { DBUG_ASSERT(fixed == 1); double tmp= (*ref)->val_result(); owner->was_null|= null_value= (*ref)->null_value; return tmp; } longlong Item_ref_null_helper::val_int() { DBUG_ASSERT(fixed == 1); longlong tmp= (*ref)->val_int_result(); owner->was_null|= null_value= (*ref)->null_value; return tmp; } my_decimal *Item_ref_null_helper::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(fixed == 1); my_decimal *val= (*ref)->val_decimal_result(decimal_value); owner->was_null|= null_value= (*ref)->null_value; return val; } bool Item_ref_null_helper::val_bool() { DBUG_ASSERT(fixed == 1); bool val= (*ref)->val_bool_result(); owner->was_null|= null_value= (*ref)->null_value; return val; } String* Item_ref_null_helper::val_str(String* s) { DBUG_ASSERT(fixed == 1); String* tmp= (*ref)->str_result(s); owner->was_null|= null_value= (*ref)->null_value; return tmp; } bool Item_ref_null_helper::get_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { return (owner->was_null|= null_value= (*ref)->get_date_result(ltime, fuzzydate)); } /** Mark item and SELECT_LEXs as dependent if item was resolved in outer SELECT. @param thd thread handler @param last select from which current item depend @param current current select @param resolved_item item which was resolved in outer SELECT(for warning) @param mark_item item which should be marked (can be differ in case of substitution) @param suppress_warning_output flag specifying whether to suppress output of a warning message */ static bool mark_as_dependent(THD *thd, SELECT_LEX *last, SELECT_LEX *current, Item_ident *resolved_item, Item_ident *mark_item, bool suppress_warning_output) { DBUG_ENTER("mark_as_dependent"); DBUG_PRINT("info", ("current select: %d (%p) last: %d (%p)", current->select_number, current, (last ? last->select_number : 0), last)); /* store pointer on SELECT_LEX from which item is dependent */ if (mark_item && mark_item->can_be_depended) { DBUG_PRINT("info", ("mark_item: %p lex: %p", mark_item, last)); mark_item->depended_from= last; } if (current->mark_as_dependent(thd, last, /** resolved_item psergey-thu **/ mark_item)) DBUG_RETURN(TRUE); if ((thd->lex->describe & DESCRIBE_EXTENDED) && !suppress_warning_output) { const char *db_name= (resolved_item->db_name ? resolved_item->db_name : ""); const char *table_name= (resolved_item->table_name ? resolved_item->table_name : ""); push_warning_printf(thd, Sql_condition::WARN_LEVEL_NOTE, ER_WARN_FIELD_RESOLVED, ER_THD(thd,ER_WARN_FIELD_RESOLVED), db_name, (db_name[0] ? "." : ""), table_name, (table_name [0] ? "." : ""), resolved_item->field_name, current->select_number, last->select_number); } DBUG_RETURN(FALSE); } /** Mark range of selects and resolved identifier (field/reference) item as dependent. @param thd thread handler @param last_select select where resolved_item was resolved @param current_sel current select (select where resolved_item was placed) @param found_field field which was found during resolving @param found_item Item which was found during resolving (if resolved identifier belongs to VIEW) @param resolved_item Identifier which was resolved @param suppress_warning_output flag specifying whether to suppress output of a warning message @note We have to mark all items between current_sel (including) and last_select (excluding) as dependent (select before last_select should be marked with actual table mask used by resolved item, all other with OUTER_REF_TABLE_BIT) and also write dependence information to Item of resolved identifier. */ void mark_select_range_as_dependent(THD *thd, SELECT_LEX *last_select, SELECT_LEX *current_sel, Field *found_field, Item *found_item, Item_ident *resolved_item, bool suppress_warning_output) { /* Go from current SELECT to SELECT where field was resolved (it have to be reachable from current SELECT, because it was already done once when we resolved this field and cached result of resolving) */ SELECT_LEX *previous_select= current_sel; for (; previous_select->outer_select() != last_select; previous_select= previous_select->outer_select()) { Item_subselect *prev_subselect_item= previous_select->master_unit()->item; prev_subselect_item->used_tables_cache|= OUTER_REF_TABLE_BIT; prev_subselect_item->const_item_cache= 0; } { Item_subselect *prev_subselect_item= previous_select->master_unit()->item; Item_ident *dependent= resolved_item; if (found_field == view_ref_found) { Item::Type type= found_item->type(); prev_subselect_item->used_tables_cache|= found_item->used_tables(); dependent= ((type == Item::REF_ITEM || type == Item::FIELD_ITEM) ? (Item_ident*) found_item : 0); } else prev_subselect_item->used_tables_cache|= found_field->table->map; prev_subselect_item->const_item_cache= 0; mark_as_dependent(thd, last_select, current_sel, resolved_item, dependent, suppress_warning_output); } } /** Search a GROUP BY clause for a field with a certain name. Search the GROUP BY list for a column named as find_item. When searching preference is given to columns that are qualified with the same table (and database) name as the one being searched for. @param find_item the item being searched for @param group_list GROUP BY clause @return - the found item on success - NULL if find_item is not in group_list */ static Item** find_field_in_group_list(Item *find_item, ORDER *group_list) { const char *db_name; const char *table_name; const char *field_name; ORDER *found_group= NULL; int found_match_degree= 0; char name_buff[SAFE_NAME_LEN+1]; if (find_item->type() == Item::FIELD_ITEM || find_item->type() == Item::REF_ITEM) { db_name= ((Item_ident*) find_item)->db_name; table_name= ((Item_ident*) find_item)->table_name; field_name= ((Item_ident*) find_item)->field_name; } else return NULL; if (db_name && lower_case_table_names) { /* Convert database to lower case for comparison */ strmake_buf(name_buff, db_name); my_casedn_str(files_charset_info, name_buff); db_name= name_buff; } DBUG_ASSERT(field_name != 0); for (ORDER *cur_group= group_list ; cur_group ; cur_group= cur_group->next) { int cur_match_degree= 0; /* SELECT list element with explicit alias */ if ((*(cur_group->item))->name && !table_name && !(*(cur_group->item))->is_autogenerated_name && !my_strcasecmp(system_charset_info, (*(cur_group->item))->name, field_name)) { ++cur_match_degree; } /* Reference on the field or view/derived field. */ else if ((*(cur_group->item))->type() == Item::FIELD_ITEM || (*(cur_group->item))->type() == Item::REF_ITEM ) { Item_ident *cur_field= (Item_ident*) *cur_group->item; const char *l_db_name= cur_field->db_name; const char *l_table_name= cur_field->table_name; const char *l_field_name= cur_field->field_name; DBUG_ASSERT(l_field_name != 0); if (!my_strcasecmp(system_charset_info, l_field_name, field_name)) ++cur_match_degree; else continue; if (l_table_name && table_name) { /* If field_name is qualified by a table name. */ if (my_strcasecmp(table_alias_charset, l_table_name, table_name)) /* Same field names, different tables. */ return NULL; ++cur_match_degree; if (l_db_name && db_name) { /* If field_name is also qualified by a database name. */ if (strcmp(l_db_name, db_name)) /* Same field names, different databases. */ return NULL; ++cur_match_degree; } } } else continue; if (cur_match_degree > found_match_degree) { found_match_degree= cur_match_degree; found_group= cur_group; } else if (found_group && (cur_match_degree == found_match_degree) && !(*(found_group->item))->eq((*(cur_group->item)), 0)) { /* If the current resolve candidate matches equally well as the current best match, they must reference the same column, otherwise the field is ambiguous. */ my_error(ER_NON_UNIQ_ERROR, MYF(0), find_item->full_name(), current_thd->where); return NULL; } } if (found_group) return found_group->item; else return NULL; } /** Resolve a column reference in a sub-select. Resolve a column reference (usually inside a HAVING clause) against the SELECT and GROUP BY clauses of the query described by 'select'. The name resolution algorithm searches both the SELECT and GROUP BY clauses, and in case of a name conflict prefers GROUP BY column names over SELECT names. If both clauses contain different fields with the same names, a warning is issued that name of 'ref' is ambiguous. We extend ANSI SQL in that when no GROUP BY column is found, then a HAVING name is resolved as a possibly derived SELECT column. This extension is allowed only if the MODE_ONLY_FULL_GROUP_BY sql mode isn't enabled. @param thd current thread @param ref column reference being resolved @param select the select that ref is resolved against @note The resolution procedure is: - Search for a column or derived column named col_ref_i [in table T_j] in the SELECT clause of Q. - Search for a column named col_ref_i [in table T_j] in the GROUP BY clause of Q. - If found different columns with the same name in GROUP BY and SELECT: - if the condition that uses this column name is pushed down into the HAVING clause return the SELECT column - else issue a warning and return the GROUP BY column. - Otherwise - if the MODE_ONLY_FULL_GROUP_BY mode is enabled return error - else return the found SELECT column. @return - NULL - there was an error, and the error was already reported - not_found_item - the item was not resolved, no error was reported - resolved item - if the item was resolved */ static Item** resolve_ref_in_select_and_group(THD *thd, Item_ident *ref, SELECT_LEX *select) { Item **group_by_ref= NULL; Item **select_ref= NULL; ORDER *group_list= select->group_list.first; bool ambiguous_fields= FALSE; uint counter; enum_resolution_type resolution; /* Search for a column or derived column named as 'ref' in the SELECT clause of the current select. */ if (!(select_ref= find_item_in_list(ref, *(select->get_item_list()), &counter, REPORT_EXCEPT_NOT_FOUND, &resolution))) return NULL; /* Some error occurred. */ if (resolution == RESOLVED_AGAINST_ALIAS) ref->alias_name_used= TRUE; /* If this is a non-aggregated field inside HAVING, search in GROUP BY. */ if (select->having_fix_field && !ref->with_sum_func && group_list) { group_by_ref= find_field_in_group_list(ref, group_list); /* Check if the fields found in SELECT and GROUP BY are the same field. */ if (group_by_ref && (select_ref != not_found_item) && !((*group_by_ref)->eq(*select_ref, 0)) && (!select->having_fix_field_for_pushed_cond)) { ambiguous_fields= TRUE; push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN, ER_NON_UNIQ_ERROR, ER_THD(thd,ER_NON_UNIQ_ERROR), ref->full_name(), thd->where); } } if (thd->variables.sql_mode & MODE_ONLY_FULL_GROUP_BY && select->having_fix_field && select_ref != not_found_item && !group_by_ref && !ref->alias_name_used) { /* Report the error if fields was found only in the SELECT item list and the strict mode is enabled. */ my_error(ER_NON_GROUPING_FIELD_USED, MYF(0), ref->name, "HAVING"); return NULL; } if (select_ref != not_found_item || group_by_ref) { if (select_ref != not_found_item && !ambiguous_fields) { DBUG_ASSERT(*select_ref != 0); if (!select->ref_pointer_array[counter]) { my_error(ER_ILLEGAL_REFERENCE, MYF(0), ref->name, "forward reference in item list"); return NULL; } DBUG_ASSERT((*select_ref)->fixed); return &select->ref_pointer_array[counter]; } if (group_by_ref) return group_by_ref; DBUG_ASSERT(FALSE); return NULL; /* So there is no compiler warning. */ } return (Item**) not_found_item; } /* @brief Whether a table belongs to an outer select. @param table table to check @param select current select @details Try to find select the table belongs to by ascending the derived tables chain. */ static bool is_outer_table(TABLE_LIST *table, SELECT_LEX *select) { DBUG_ASSERT(table->select_lex != select); TABLE_LIST *tl; if (table->belong_to_view && table->belong_to_view->select_lex == select) return FALSE; for (tl= select->master_unit()->derived; tl && tl->is_merged_derived(); select= tl->select_lex, tl= select->master_unit()->derived) { if (tl->select_lex == table->select_lex) return FALSE; } return TRUE; } /** Resolve the name of an outer select column reference. @param[in] thd current thread @param[in,out] from_field found field reference or (Field*)not_found_field @param[in,out] reference view column if this item was resolved to a view column @description The method resolves the column reference represented by 'this' as a column present in outer selects that contain current select. In prepared statements, because of cache, find_field_in_tables() can resolve fields even if they don't belong to current context. In this case this method only finds appropriate context and marks current select as dependent. The found reference of field should be provided in 'from_field'. The cache is critical for prepared statements of type: SELECT a FROM (SELECT a FROM test.t1) AS s1 NATURAL JOIN t2 AS s2; This is internally converted to a join similar to SELECT a FROM t1 AS s1,t2 AS s2 WHERE t2.a=t1.a; Without the cache, we would on re-prepare not know if 'a' did match s1.a or s2.a. @note This is the inner loop of Item_field::fix_fields: @code for each outer query Q_k beginning from the inner-most one { search for a column or derived column named col_ref_i [in table T_j] in the FROM clause of Q_k; if such a column is not found Search for a column or derived column named col_ref_i [in table T_j] in the SELECT and GROUP clauses of Q_k. } @endcode @retval 1 column succefully resolved and fix_fields() should continue. @retval 0 column fully fixed and fix_fields() should return FALSE @retval -1 error occurred */ int Item_field::fix_outer_field(THD *thd, Field **from_field, Item **reference) { enum_parsing_place place= NO_MATTER; bool field_found= (*from_field != not_found_field); bool upward_lookup= FALSE; TABLE_LIST *table_list; /* Calculate the TABLE_LIST for the table */ table_list= (cached_table ? cached_table : field_found && (*from_field) != view_ref_found ? (*from_field)->table->pos_in_table_list : 0); /* If there are outer contexts (outer selects, but current select is not derived table or view) try to resolve this reference in the outer contexts. We treat each subselect as a separate namespace, so that different subselects may contain columns with the same names. The subselects are searched starting from the innermost. */ Name_resolution_context *last_checked_context= context; Item **ref= (Item **) not_found_item; /* There are cases when name resolution context is absent (when we are not doing name resolution), but here the name resolution context should be present because we are doing name resolution */ DBUG_ASSERT(context); SELECT_LEX *current_sel= context->select_lex; LEX *lex_s= context->select_lex->parent_lex; Name_resolution_context *outer_context= 0; SELECT_LEX *select= 0; /* Currently derived tables cannot be correlated */ if (current_sel->master_unit()->first_select()->linkage != DERIVED_TABLE_TYPE) outer_context= context->outer_context; /* This assert is to ensure we have an outer contex when *from_field is set. If this would not be the case, we would assert in mark_as_dependent as last_checked_countex == context */ DBUG_ASSERT(outer_context || !*from_field || *from_field == not_found_field); for (; outer_context; outer_context= outer_context->outer_context) { select= outer_context->select_lex; Item_subselect *prev_subselect_item= last_checked_context->select_lex->master_unit()->item; last_checked_context= outer_context; upward_lookup= TRUE; place= prev_subselect_item->parsing_place; /* If outer_field is set, field was already found by first call to find_field_in_tables(). Only need to find appropriate context. */ if (field_found && outer_context->select_lex != table_list->select_lex) continue; /* In case of a view, find_field_in_tables() writes the pointer to the found view field into '*reference', in other words, it substitutes this Item_field with the found expression. */ if (field_found || (*from_field= find_field_in_tables(thd, this, outer_context-> first_name_resolution_table, outer_context-> last_name_resolution_table, reference, IGNORE_EXCEPT_NON_UNIQUE, TRUE, TRUE)) != not_found_field) { if (*from_field) { if (thd->variables.sql_mode & MODE_ONLY_FULL_GROUP_BY && select->cur_pos_in_select_list != UNDEF_POS) { /* As this is an outer field it should be added to the list of non aggregated fields of the outer select. */ if (select->join) { marker= select->cur_pos_in_select_list; select->join->non_agg_fields.push_back(this, thd->mem_root); } else { /* join is absent if it is upper SELECT_LEX of non-select command */ DBUG_ASSERT(select->master_unit()->outer_select() == NULL && (thd->lex->sql_command != SQLCOM_SELECT && thd->lex->sql_command != SQLCOM_UPDATE_MULTI && thd->lex->sql_command != SQLCOM_DELETE_MULTI && thd->lex->sql_command != SQLCOM_INSERT_SELECT && thd->lex->sql_command != SQLCOM_REPLACE_SELECT)); } } if (*from_field != view_ref_found) { prev_subselect_item->used_tables_cache|= (*from_field)->table->map; prev_subselect_item->const_item_cache= 0; set_field(*from_field); if (!last_checked_context->select_lex->having_fix_field && select->group_list.elements && (place == SELECT_LIST || place == IN_HAVING)) { Item_outer_ref *rf; /* If an outer field is resolved in a grouping select then it is replaced for an Item_outer_ref object. Otherwise an Item_field object is used. The new Item_outer_ref object is saved in the inner_refs_list of the outer select. Here it is only created. It can be fixed only after the original field has been fixed and this is done in the fix_inner_refs() function. */ ; if (!(rf= new (thd->mem_root) Item_outer_ref(thd, context, this))) return -1; thd->change_item_tree(reference, rf); select->inner_refs_list.push_back(rf, thd->mem_root); rf->in_sum_func= lex_s->in_sum_func; } /* A reference is resolved to a nest level that's outer or the same as the nest level of the enclosing set function : adjust the value of max_arg_level for the function if it's needed. */ if (lex_s->in_sum_func && lex_s->in_sum_func->nest_level >= select->nest_level) { Item::Type ref_type= (*reference)->type(); set_if_bigger(lex_s->in_sum_func->max_arg_level, select->nest_level); set_field(*from_field); fixed= 1; mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, this, ((ref_type == REF_ITEM || ref_type == FIELD_ITEM) ? (Item_ident*) (*reference) : 0), false); return 0; } } else { Item::Type ref_type= (*reference)->type(); prev_subselect_item->used_tables_and_const_cache_join(*reference); mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, this, ((ref_type == REF_ITEM || ref_type == FIELD_ITEM) ? (Item_ident*) (*reference) : 0), false); if (lex_s->in_sum_func && lex_s->in_sum_func->nest_level >= select->nest_level) { set_if_bigger(lex_s->in_sum_func->max_arg_level, select->nest_level); } /* A reference to a view field had been found and we substituted it instead of this Item (find_field_in_tables does it by assigning the new value to *reference), so now we can return from this function. */ return 0; } } break; } /* Search in SELECT and GROUP lists of the outer select. */ if (place != IN_WHERE && place != IN_ON) { if (!(ref= resolve_ref_in_select_and_group(thd, this, select))) return -1; /* Some error occurred (e.g. ambiguous names). */ if (ref != not_found_item) { DBUG_ASSERT(*ref && (*ref)->fixed); prev_subselect_item->used_tables_and_const_cache_join(*ref); break; } } /* Reference is not found in this select => this subquery depend on outer select (or we just trying to find wrong identifier, in this case it does not matter which used tables bits we set) */ prev_subselect_item->used_tables_cache|= OUTER_REF_TABLE_BIT; prev_subselect_item->const_item_cache= 0; } DBUG_ASSERT(ref != 0); if (!*from_field) return -1; if (ref == not_found_item && *from_field == not_found_field) { if (upward_lookup) { // We can't say exactly what absent table or field my_error(ER_BAD_FIELD_ERROR, MYF(0), full_name(), thd->where); } else { /* Call find_field_in_tables only to report the error */ find_field_in_tables(thd, this, context->first_name_resolution_table, context->last_name_resolution_table, reference, REPORT_ALL_ERRORS, !any_privileges, TRUE); } return -1; } else if (ref != not_found_item) { Item *save; Item_ref *rf; /* Should have been checked in resolve_ref_in_select_and_group(). */ DBUG_ASSERT(*ref && (*ref)->fixed); /* Here, a subset of actions performed by Item_ref::set_properties is not enough. So we pass ptr to NULL into Item_[direct]_ref constructor, so no initialization is performed, and call fix_fields() below. */ save= *ref; *ref= NULL; // Don't call set_properties() rf= (place == IN_HAVING ? new (thd->mem_root) Item_ref(thd, context, ref, (char*) table_name, (char*) field_name, alias_name_used) : (!select->group_list.elements ? new (thd->mem_root) Item_direct_ref(thd, context, ref, (char*) table_name, (char*) field_name, alias_name_used) : new (thd->mem_root) Item_outer_ref(thd, context, ref, (char*) table_name, (char*) field_name, alias_name_used))); *ref= save; if (!rf) return -1; if (place != IN_HAVING && select->group_list.elements) { outer_context->select_lex->inner_refs_list.push_back((Item_outer_ref*)rf, thd->mem_root); ((Item_outer_ref*)rf)->in_sum_func= lex_s->in_sum_func; } thd->change_item_tree(reference, rf); /* rf is Item_ref => never substitute other items (in this case) during fix_fields() => we can use rf after fix_fields() */ DBUG_ASSERT(!rf->fixed); // Assured by Item_ref() if (rf->fix_fields(thd, reference) || rf->check_cols(1)) return -1; /* We can not "move" aggregate function in the place where its arguments are not defined. */ set_max_sum_func_level(select); mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, rf, rf, false); return 0; } else { /* We can not "move" aggregate function in the place where its arguments are not defined. */ set_max_sum_func_level(select); mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, this, (Item_ident*)*reference, false); if (last_checked_context->select_lex->having_fix_field) { Item_ref *rf; rf= new (thd->mem_root) Item_ref(thd, context, (*from_field)->table->s->db.str, (*from_field)->table->alias.c_ptr(), (char*) field_name); if (!rf) return -1; thd->change_item_tree(reference, rf); /* rf is Item_ref => never substitute other items (in this case) during fix_fields() => we can use rf after fix_fields() */ DBUG_ASSERT(!rf->fixed); // Assured by Item_ref() if (rf->fix_fields(thd, reference) || rf->check_cols(1)) return -1; return 0; } } return 1; } /** Resolve the name of a column reference. The method resolves the column reference represented by 'this' as a column present in one of: FROM clause, SELECT clause, GROUP BY clause of a query Q, or in outer queries that contain Q. The name resolution algorithm used is (where [T_j] is an optional table name that qualifies the column name): @code resolve_column_reference([T_j].col_ref_i) { search for a column or derived column named col_ref_i [in table T_j] in the FROM clause of Q; if such a column is NOT found AND // Lookup in outer queries. there are outer queries { for each outer query Q_k beginning from the inner-most one { search for a column or derived column named col_ref_i [in table T_j] in the FROM clause of Q_k; if such a column is not found Search for a column or derived column named col_ref_i [in table T_j] in the SELECT and GROUP clauses of Q_k. } } } @endcode Notice that compared to Item_ref::fix_fields, here we first search the FROM clause, and then we search the SELECT and GROUP BY clauses. @param[in] thd current thread @param[in,out] reference view column if this item was resolved to a view column @retval TRUE if error @retval FALSE on success */ bool Item_field::fix_fields(THD *thd, Item **reference) { DBUG_ASSERT(fixed == 0); Field *from_field= (Field *)not_found_field; bool outer_fixed= false; SELECT_LEX *select; LEX *lex_s; if (context) { select= context->select_lex; lex_s= context->select_lex->parent_lex; } else { // No real name resolution, used somewhere in SP DBUG_ASSERT(field); select= NULL; lex_s= NULL; } if (!field) // If field is not checked { TABLE_LIST *table_list; /* In case of view, find_field_in_tables() write pointer to view field expression to 'reference', i.e. it substitute that expression instead of this Item_field */ if ((from_field= find_field_in_tables(thd, this, context->first_name_resolution_table, context->last_name_resolution_table, reference, thd->lex->use_only_table_context ? REPORT_ALL_ERRORS : IGNORE_EXCEPT_NON_UNIQUE, !any_privileges, TRUE)) == not_found_field) { int ret; /* Look up in current select's item_list to find aliased fields */ if (select && select->is_item_list_lookup) { uint counter; enum_resolution_type resolution; Item** res= find_item_in_list(this, select->item_list, &counter, REPORT_EXCEPT_NOT_FOUND, &resolution); if (!res) return 1; if (resolution == RESOLVED_AGAINST_ALIAS) alias_name_used= TRUE; if (res != (Item **)not_found_item) { if ((*res)->type() == Item::FIELD_ITEM) { /* It's an Item_field referencing another Item_field in the select list. Use the field from the Item_field in the select list and leave the Item_field instance in place. */ Field *new_field= (*((Item_field**)res))->field; if (new_field == NULL) { /* The column to which we link isn't valid. */ my_error(ER_BAD_FIELD_ERROR, MYF(0), (*res)->name, thd->where); return(1); } /* We can not "move" aggregate function in the place where its arguments are not defined. */ set_max_sum_func_level(select); set_field(new_field); depended_from= (*((Item_field**)res))->depended_from; return 0; } else { /* It's not an Item_field in the select list so we must make a new Item_ref to point to the Item in the select list and replace the Item_field created by the parser with the new Item_ref. */ Item_ref *rf= new (thd->mem_root) Item_ref(thd, context, db_name, table_name, field_name); if (!rf) return 1; bool err= rf->fix_fields(thd, (Item **) &rf) || rf->check_cols(1); if (err) return TRUE; thd->change_item_tree(reference, select->context_analysis_place == IN_GROUP_BY && alias_name_used ? *rf->ref : rf); /* We can not "move" aggregate function in the place where its arguments are not defined. */ set_max_sum_func_level(select); return FALSE; } } } if (!select) { my_error(ER_BAD_FIELD_ERROR, MYF(0), full_name(), thd->where); goto error; } if ((ret= fix_outer_field(thd, &from_field, reference)) < 0) goto error; outer_fixed= TRUE; if (!ret) goto mark_non_agg_field; } else if (!from_field) goto error; table_list= (cached_table ? cached_table : from_field != view_ref_found ? from_field->table->pos_in_table_list : 0); if (!outer_fixed && table_list && table_list->select_lex && context->select_lex && table_list->select_lex != context->select_lex && !context->select_lex->is_merged_child_of(table_list->select_lex) && is_outer_table(table_list, context->select_lex)) { int ret; if ((ret= fix_outer_field(thd, &from_field, reference)) < 0) goto error; outer_fixed= 1; if (!ret) goto mark_non_agg_field; } if (lex_s && lex_s->in_sum_func && lex_s->in_sum_func->nest_level == select->nest_level) set_if_bigger(lex_s->in_sum_func->max_arg_level, select->nest_level); /* if it is not expression from merged VIEW we will set this field. We can leave expression substituted from view for next PS/SP rexecution (i.e. do not register this substitution for reverting on cleanup() (register_item_tree_changing())), because this subtree will be fix_field'ed during setup_tables()->setup_underlying() (i.e. before all other expressions of query, and references on tables which do not present in query will not make problems. Also we suppose that view can't be changed during PS/SP life. */ if (from_field == view_ref_found) return FALSE; set_field(from_field); } else if (thd->mark_used_columns != MARK_COLUMNS_NONE) { TABLE *table= field->table; MY_BITMAP *current_bitmap, *other_bitmap; if (thd->mark_used_columns == MARK_COLUMNS_READ) { current_bitmap= table->read_set; other_bitmap= table->write_set; } else { current_bitmap= table->write_set; other_bitmap= table->read_set; } if (!bitmap_fast_test_and_set(current_bitmap, field->field_index)) { if (!bitmap_is_set(other_bitmap, field->field_index)) { /* First usage of column */ table->used_fields++; // Used to optimize loops /* purecov: begin inspected */ table->covering_keys.intersect(field->part_of_key); /* purecov: end */ } } } #ifndef NO_EMBEDDED_ACCESS_CHECKS if (any_privileges) { char *db, *tab; db= field->table->s->db.str; tab= field->table->s->table_name.str; if (!(have_privileges= (get_column_grant(thd, &field->table->grant, db, tab, field_name) & VIEW_ANY_ACL))) { my_error(ER_COLUMNACCESS_DENIED_ERROR, MYF(0), "ANY", thd->security_ctx->priv_user, thd->security_ctx->host_or_ip, field_name, tab); goto error; } } #endif fixed= 1; if (field->vcol_info) fix_session_vcol_expr_for_read(thd, field, field->vcol_info); if (thd->variables.sql_mode & MODE_ONLY_FULL_GROUP_BY && !outer_fixed && select && !lex_s->in_sum_func && select->cur_pos_in_select_list != UNDEF_POS && select->join) { select->join->non_agg_fields.push_back(this, thd->mem_root); marker= select->cur_pos_in_select_list; } mark_non_agg_field: /* table->pos_in_table_list can be 0 when fixing partition functions or virtual fields. */ if (fixed && (thd->variables.sql_mode & MODE_ONLY_FULL_GROUP_BY) && field->table->pos_in_table_list) { /* Mark selects according to presence of non aggregated fields. Fields from outer selects added to the aggregate function outer_fields list as it's unknown at the moment whether it's aggregated or not. We're using the select lex of the cached table (if present). */ SELECT_LEX *select_lex; if (cached_table) select_lex= cached_table->select_lex; else if (!(select_lex= field->table->pos_in_table_list->select_lex)) { /* This can only happen when there is no real table in the query. We are using the field's resolution context. context->select_lex is eee safe for use because it's either the SELECT we want to use (the current level) or a stub added by non-SELECT queries. */ select_lex= context->select_lex; } if (!lex_s || !lex_s->in_sum_func) select_lex->set_non_agg_field_used(true); else { if (outer_fixed) lex_s->in_sum_func->outer_fields.push_back(this, thd->mem_root); else if (lex_s->in_sum_func->nest_level != select->nest_level) select_lex->set_non_agg_field_used(true); } } return FALSE; error: context->process_error(thd); return TRUE; } bool Item_field::post_fix_fields_part_expr_processor(void *int_arg) { DBUG_ASSERT(fixed); if (field->vcol_info) field->vcol_info->mark_as_in_partitioning_expr(); /* Update table_name to be real table name, not the alias. Because alias is reallocated for every statement, and this item has a long life time */ table_name= field->table->s->table_name.str; return FALSE; } bool Item_field::check_valid_arguments_processor(void *bool_arg) { Virtual_column_info *vcol= field->vcol_info; if (!vcol) return FALSE; return vcol->expr->walk(&Item::check_partition_func_processor, 0, NULL) || vcol->expr->walk(&Item::check_valid_arguments_processor, 0, NULL); } void Item_field::cleanup() { DBUG_ENTER("Item_field::cleanup"); Item_ident::cleanup(); depended_from= NULL; /* Even if this object was created by direct link to field in setup_wild() it will be linked correctly next time by name of field and table alias. I.e. we can drop 'field'. */ field= 0; item_equal= NULL; null_value= FALSE; DBUG_VOID_RETURN; } /** Find a field among specified multiple equalities. The function first searches the field among multiple equalities of the current level (in the cond_equal->current_level list). If it fails, it continues searching in upper levels accessed through a pointer cond_equal->upper_levels. The search terminates as soon as a multiple equality containing the field is found. @param cond_equal reference to list of multiple equalities where the field (this object) is to be looked for @return - First Item_equal containing the field, if success - 0, otherwise */ Item_equal *Item_field::find_item_equal(COND_EQUAL *cond_equal) { Item_equal *item= 0; while (cond_equal) { List_iterator_fast li(cond_equal->current_level); while ((item= li++)) { if (item->contains(field)) return item; } /* The field is not found in any of the multiple equalities of the current level. Look for it in upper levels */ cond_equal= cond_equal->upper_levels; } return 0; } /** Set a pointer to the multiple equality the field reference belongs to (if any). The function looks for a multiple equality containing the field item among those referenced by arg. In the case such equality exists the function does the following. If the found multiple equality contains a constant, then the field reference is substituted for this constant, otherwise it sets a pointer to the multiple equality in the field item. @param arg reference to list of multiple equalities where the field (this object) is to be looked for @note This function is supposed to be called as a callback parameter in calls of the compile method. @return - pointer to the replacing constant item, if the field item was substituted - pointer to the field item, otherwise. */ Item *Item_field::propagate_equal_fields(THD *thd, const Context &ctx, COND_EQUAL *arg) { if (!(item_equal= find_item_equal(arg))) return this; if (!field->can_be_substituted_to_equal_item(ctx, item_equal)) { item_equal= NULL; return this; } Item *item= item_equal->get_const(); if (!item) { /* The found Item_equal is Okey, but it does not have a constant item yet. Keep this->item_equal point to the found Item_equal. */ return this; } if (!(item= field->get_equal_const_item(thd, ctx, item))) { /* Could not do safe conversion from the original constant item to a field-compatible constant item. For example, we tried to optimize: WHERE date_column=' garbage ' AND LENGTH(date_column)=8; to WHERE date_column=' garbage ' AND LENGTH(DATE'XXXX-YY-ZZ'); but failed to create a valid DATE literal from the given string literal. Do not do constant propagation in such cases and unlink "this" from the found Item_equal (as this equality not useful). */ item_equal= NULL; return this; } return item; } /** Replace an Item_field for an equal Item_field that evaluated earlier (if any). If this->item_equal points to some item and coincides with arg then the function returns a pointer to an item that is taken from the very beginning of the item_equal list which the Item_field object refers to (belongs to) unless item_equal contains a constant item. In this case the function returns this constant item, (if the substitution does not require conversion). If the Item_field object does not refer any Item_equal object 'this' is returned . @param arg NULL or points to so some item of the Item_equal type @note This function is supposed to be called as a callback parameter in calls of the transformer method. @return - pointer to a replacement Item_field if there is a better equal item or a pointer to a constant equal item; - this - otherwise. */ Item *Item_field::replace_equal_field(THD *thd, uchar *arg) { REPLACE_EQUAL_FIELD_ARG* param= (REPLACE_EQUAL_FIELD_ARG*)arg; if (item_equal && item_equal == param->item_equal) { Item *const_item2= item_equal->get_const(); if (const_item2) { /* Currently we don't allow to create Item_equal with compare_type() different from its Item_field's cmp_type(). Field_xxx::test_if_equality_guarantees_uniqueness() prevent this. Also, Item_field::propagate_equal_fields() does not allow to assign this->item_equal to any instances of Item_equal if "this" is used in a non-native comparison context, or with an incompatible collation. So the fact that we have (item_equal != NULL) means that the currently processed function (the owner of "this") uses the field in its native comparison context, and it's safe to replace it to the constant from item_equal. */ DBUG_ASSERT(cmp_type() == item_equal->compare_type()); return const_item2; } Item_field *subst= (Item_field *)(item_equal->get_first(param->context_tab, this)); if (subst) subst= (Item_field *) (subst->real_item()); if (subst && !field->eq(subst->field)) return subst; } return this; } void Item::init_make_field(Send_field *tmp_field, enum enum_field_types field_type_arg) { char *empty_name= (char*) ""; tmp_field->db_name= empty_name; tmp_field->org_table_name= empty_name; tmp_field->org_col_name= empty_name; tmp_field->table_name= empty_name; tmp_field->col_name= name; tmp_field->charsetnr= collation.collation->number; tmp_field->flags= (maybe_null ? 0 : NOT_NULL_FLAG) | (my_binary_compare(charset_for_protocol()) ? BINARY_FLAG : 0); tmp_field->type= field_type_arg; tmp_field->length=max_length; tmp_field->decimals=decimals; if (unsigned_flag) tmp_field->flags |= UNSIGNED_FLAG; } void Item::make_field(THD *thd, Send_field *tmp_field) { init_make_field(tmp_field, field_type()); } void Item_empty_string::make_field(THD *thd, Send_field *tmp_field) { init_make_field(tmp_field, string_field_type()); } /** Verifies that the input string is well-formed according to its character set. @param send_error If true, call my_error if string is not well-formed. Will truncate input string if it is not well-formed. @return If well-formed: input string. If not well-formed: if strict mode: NULL pointer and we set this Item's value to NULL if not strict mode: input string truncated up to last good character */ String *Item::check_well_formed_result(String *str, bool send_error) { /* Check whether we got a well-formed string */ CHARSET_INFO *cs= str->charset(); uint wlen= str->well_formed_length(); null_value= false; if (wlen < str->length()) { THD *thd= current_thd; char hexbuf[7]; uint diff= str->length() - wlen; set_if_smaller(diff, 3); octet2hex(hexbuf, str->ptr() + wlen, diff); if (send_error) { my_error(ER_INVALID_CHARACTER_STRING, MYF(0), cs->csname, hexbuf); return 0; } if (thd->is_strict_mode()) { null_value= 1; str= 0; } else { str->length(wlen); } push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN, ER_INVALID_CHARACTER_STRING, ER_THD(thd, ER_INVALID_CHARACTER_STRING), cs->csname, hexbuf); } return str; } /** Copy a string with optional character set conversion. */ bool String_copier_for_item::copy_with_warn(CHARSET_INFO *dstcs, String *dst, CHARSET_INFO *srccs, const char *src, uint32 src_length, uint32 nchars) { if ((dst->copy(dstcs, srccs, src, src_length, nchars, this))) return true; // EOM if (const char *pos= well_formed_error_pos()) { ErrConvString err(pos, src_length - (pos - src), &my_charset_bin); push_warning_printf(m_thd, Sql_condition::WARN_LEVEL_WARN, ER_INVALID_CHARACTER_STRING, ER_THD(m_thd, ER_INVALID_CHARACTER_STRING), srccs == &my_charset_bin ? dstcs->csname : srccs->csname, err.ptr()); return false; } if (const char *pos= cannot_convert_error_pos()) { char buf[16]; int mblen= my_charlen(srccs, pos, src + src_length); DBUG_ASSERT(mblen > 0 && mblen * 2 + 1 <= (int) sizeof(buf)); octet2hex(buf, pos, mblen); push_warning_printf(m_thd, Sql_condition::WARN_LEVEL_WARN, ER_CANNOT_CONVERT_CHARACTER, ER_THD(m_thd, ER_CANNOT_CONVERT_CHARACTER), srccs->csname, buf, dstcs->csname); return false; } return false; } /* Compare two items using a given collation SYNOPSIS eq_by_collation() item item to compare with binary_cmp TRUE <-> compare as binaries cs collation to use when comparing strings DESCRIPTION This method works exactly as Item::eq if the collation cs coincides with the collation of the compared objects. Otherwise, first the collations that differ from cs are replaced for cs and then the items are compared by Item::eq. After the comparison the original collations of items are restored. RETURN 1 compared items has been detected as equal 0 otherwise */ bool Item::eq_by_collation(Item *item, bool binary_cmp, CHARSET_INFO *cs) { CHARSET_INFO *save_cs= 0; CHARSET_INFO *save_item_cs= 0; if (collation.collation != cs) { save_cs= collation.collation; collation.collation= cs; } if (item->collation.collation != cs) { save_item_cs= item->collation.collation; item->collation.collation= cs; } bool res= eq(item, binary_cmp); if (save_cs) collation.collation= save_cs; if (save_item_cs) item->collation.collation= save_item_cs; return res; } /** Create a field to hold a string value from an item. If too_big_for_varchar() create a blob @n If max_length > 0 create a varchar @n If max_length == 0 create a CHAR(0) @param table Table for which the field is created */ Field *Item::make_string_field(TABLE *table) { Field *field; MEM_ROOT *mem_root= table->in_use->mem_root; DBUG_ASSERT(collation.collation); /* Note: the following check is repeated in subquery_types_allow_materialization(): */ if (too_big_for_varchar()) field= new (mem_root) Field_blob(max_length, maybe_null, name, collation.collation, TRUE); /* Item_type_holder holds the exact type, do not change it */ else if (max_length > 0 && (type() != Item::TYPE_HOLDER || field_type() != MYSQL_TYPE_STRING)) field= new (mem_root) Field_varstring(max_length, maybe_null, name, table->s, collation.collation); else field= new (mem_root) Field_string(max_length, maybe_null, name, collation.collation); if (field) field->init(table); return field; } /** Create a field based on field_type of argument. For now, this is only used to create a field for IFNULL(x,something) and time functions @retval NULL error @retval \# Created field */ Field *Item::tmp_table_field_from_field_type(TABLE *table, bool fixed_length, bool set_blob_packlength) { /* The field functions defines a field to be not null if null_ptr is not 0 */ uchar *null_ptr= maybe_null ? (uchar*) "" : 0; Field *field; MEM_ROOT *mem_root= table->in_use->mem_root; switch (field_type()) { case MYSQL_TYPE_DECIMAL: case MYSQL_TYPE_NEWDECIMAL: field= Field_new_decimal::create_from_item(mem_root, this); break; case MYSQL_TYPE_TINY: field= new (mem_root) Field_tiny((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, 0, unsigned_flag); break; case MYSQL_TYPE_SHORT: field= new (mem_root) Field_short((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, 0, unsigned_flag); break; case MYSQL_TYPE_LONG: field= new (mem_root) Field_long((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, 0, unsigned_flag); break; #ifdef HAVE_LONG_LONG case MYSQL_TYPE_LONGLONG: field= new (mem_root) Field_longlong((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, 0, unsigned_flag); break; #endif case MYSQL_TYPE_FLOAT: field= new (mem_root) Field_float((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, decimals, 0, unsigned_flag); break; case MYSQL_TYPE_DOUBLE: field= new (mem_root) Field_double((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, decimals, 0, unsigned_flag); break; case MYSQL_TYPE_INT24: field= new (mem_root) Field_medium((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name, 0, unsigned_flag); break; case MYSQL_TYPE_NEWDATE: case MYSQL_TYPE_DATE: field= new (mem_root) Field_newdate(0, null_ptr, 0, Field::NONE, name); break; case MYSQL_TYPE_TIME: field= new_Field_time(mem_root, 0, null_ptr, 0, Field::NONE, name, decimals); break; case MYSQL_TYPE_TIMESTAMP: field= new_Field_timestamp(mem_root, 0, null_ptr, 0, Field::NONE, name, 0, decimals); break; case MYSQL_TYPE_DATETIME: field= new_Field_datetime(mem_root, 0, null_ptr, 0, Field::NONE, name, decimals); break; case MYSQL_TYPE_YEAR: field= new (mem_root) Field_year((uchar*) 0, max_length, null_ptr, 0, Field::NONE, name); break; case MYSQL_TYPE_BIT: field= new (mem_root) Field_bit_as_char(NULL, max_length, null_ptr, 0, Field::NONE, name); break; default: /* This case should never be chosen */ DBUG_ASSERT(0); /* If something goes awfully wrong, it's better to get a string than die */ case MYSQL_TYPE_NULL: case MYSQL_TYPE_STRING: if (fixed_length && !too_big_for_varchar()) { field= new (mem_root) Field_string(max_length, maybe_null, name, collation.collation); break; } /* fall through */ case MYSQL_TYPE_ENUM: case MYSQL_TYPE_SET: case MYSQL_TYPE_VAR_STRING: case MYSQL_TYPE_VARCHAR: return make_string_field(table); case MYSQL_TYPE_TINY_BLOB: case MYSQL_TYPE_MEDIUM_BLOB: case MYSQL_TYPE_LONG_BLOB: case MYSQL_TYPE_BLOB: field= new (mem_root) Field_blob(max_length, maybe_null, name, collation.collation, set_blob_packlength); break; // Blob handled outside of case #ifdef HAVE_SPATIAL case MYSQL_TYPE_GEOMETRY: field= new (mem_root) Field_geom(max_length, maybe_null, name, table->s, get_geometry_type()); #endif /* HAVE_SPATIAL */ } if (field) field->init(table); return field; } /* ARGSUSED */ void Item_field::make_field(THD *thd, Send_field *tmp_field) { field->make_field(tmp_field); DBUG_ASSERT(tmp_field->table_name != 0); if (name) tmp_field->col_name=name; // Use user supplied name if (table_name) tmp_field->table_name= table_name; if (db_name) tmp_field->db_name= db_name; } /** Save a field value in another field @param from Field to take the value from @param [out] null_value Pointer to the null_value flag to set @param to Field to save the value in @param no_conversions How to deal with NULL value @details The function takes the value of the field 'from' and, if this value is not null, it saves in the field 'to' setting off the flag referenced by 'null_value'. Otherwise this flag is set on and field 'to' is also set to null possibly with conversion. @note This function is used by the functions Item_field::save_in_field, Item_field::save_org_in_field and Item_ref::save_in_field @retval FALSE OK @retval TRUE Error */ static int save_field_in_field(Field *from, bool *null_value, Field *to, bool no_conversions) { int res; DBUG_ENTER("save_field_in_field"); if (from->is_null()) { (*null_value)= 1; DBUG_RETURN(set_field_to_null_with_conversions(to, no_conversions)); } to->set_notnull(); /* If we're setting the same field as the one we're reading from there's nothing to do. This can happen in 'SET x = x' type of scenarios. */ if (to == from) { (*null_value)= 0; DBUG_RETURN(0); } res= field_conv(to, from); (*null_value)= 0; DBUG_RETURN(res); } fast_field_copier Item_field::setup_fast_field_copier(Field *to) { return to->get_fast_field_copier(field); } /** Set a field's value from a item. */ void Item_field::save_org_in_field(Field *to, fast_field_copier fast_field_copier_func) { DBUG_ENTER("Item_field::save_org_in_field"); DBUG_PRINT("enter", ("setup: %p data: %p", to, fast_field_copier_func)); if (fast_field_copier_func) { if (field->is_null()) { null_value= TRUE; set_field_to_null_with_conversions(to, TRUE); DBUG_VOID_RETURN; } to->set_notnull(); if (to == field) { null_value= 0; DBUG_VOID_RETURN; } (*fast_field_copier_func)(to, field); } else save_field_in_field(field, &null_value, to, TRUE); DBUG_VOID_RETURN; } int Item_field::save_in_field(Field *to, bool no_conversions) { return save_field_in_field(result_field, &null_value, to, no_conversions); } /** Store null in field. This is used on INSERT. Allow NULL to be inserted in timestamp and auto_increment values. @param field Field where we want to store NULL @retval 0 ok @retval 1 Field doesn't support NULL values and can't handle 'field = NULL' */ int Item_null::save_in_field(Field *field, bool no_conversions) { return set_field_to_null_with_conversions(field, no_conversions); } /** Store null in field. @param field Field where we want to store NULL @retval 0 OK @retval 1 Field doesn't support NULL values */ int Item_null::save_safe_in_field(Field *field) { return set_field_to_null(field); } /* This implementation can lose str_value content, so if the Item uses str_value to store something, it should reimplement it's ::save_in_field() as Item_string, for example, does. Note: all Item_XXX::val_str(str) methods must NOT assume that str != str_value. For example, see fix for bug #44743. */ int Item::save_in_field(Field *field, bool no_conversions) { int error; if (result_type() == STRING_RESULT) { String *result; CHARSET_INFO *cs= collation.collation; char buff[MAX_FIELD_WIDTH]; // Alloc buffer for small columns str_value.set_quick(buff, sizeof(buff), cs); result=val_str(&str_value); if (null_value) { str_value.set_quick(0, 0, cs); return set_field_to_null_with_conversions(field, no_conversions); } /* NOTE: If null_value == FALSE, "result" must be not NULL. */ field->set_notnull(); error=field->store(result->ptr(),result->length(),cs); str_value.set_quick(0, 0, cs); } else if (result_type() == REAL_RESULT) { double nr= val_real(); if (null_value) return set_field_to_null_with_conversions(field, no_conversions); field->set_notnull(); error=field->store(nr); } else if (result_type() == DECIMAL_RESULT) { my_decimal decimal_value; my_decimal *value= val_decimal(&decimal_value); if (null_value) return set_field_to_null_with_conversions(field, no_conversions); field->set_notnull(); error=field->store_decimal(value); } else { longlong nr=val_int(); if (null_value) return set_field_to_null_with_conversions(field, no_conversions); field->set_notnull(); error=field->store(nr, unsigned_flag); } return error ? error : (field->table->in_use->is_error() ? 1 : 0); } bool Item::save_in_param(THD *thd, Item_param *param) { return param->set_from_item(thd, this); } int Item_string::save_in_field(Field *field, bool no_conversions) { String *result; result=val_str(&str_value); return save_str_value_in_field(field, result); } Item *Item_string::clone_item(THD *thd) { return new (thd->mem_root) Item_string(thd, name, str_value.ptr(), str_value.length(), collation.collation); } static int save_int_value_in_field (Field *field, longlong nr, bool null_value, bool unsigned_flag) { if (null_value) return set_field_to_null(field); field->set_notnull(); return field->store(nr, unsigned_flag); } int Item_int::save_in_field(Field *field, bool no_conversions) { return save_int_value_in_field (field, val_int(), null_value, unsigned_flag); } Item *Item_int::clone_item(THD *thd) { return new (thd->mem_root) Item_int(thd, name, value, max_length); } void Item_datetime::set(longlong packed) { unpack_time(packed, <ime); } int Item_datetime::save_in_field(Field *field, bool no_conversions) { field->set_notnull(); return field->store_time_dec(<ime, decimals); } longlong Item_datetime::val_int() { return TIME_to_ulonglong(<ime); } int Item_decimal::save_in_field(Field *field, bool no_conversions) { field->set_notnull(); return field->store_decimal(&decimal_value); } Item *Item_int_with_ref::clone_item(THD *thd) { DBUG_ASSERT(ref->const_item()); /* We need to evaluate the constant to make sure it works with parameter markers. */ return (ref->unsigned_flag ? new (thd->mem_root) Item_uint(thd, ref->name, ref->val_int(), ref->max_length) : new (thd->mem_root) Item_int(thd, ref->name, ref->val_int(), ref->max_length)); } Item *Item::neg(THD *thd) { return new (thd->mem_root) Item_func_neg(thd, this); } Item *Item_int::neg(THD *thd) { /* The following if should never be true with code generated by our parser as LONGLONG_MIN values will be stored as decimal. The code is here in case someone generates an int from inside MariaDB */ if (unlikely(value == LONGLONG_MIN)) { /* Precision for int not big enough; Convert constant to decimal */ Item_decimal *item= new (thd->mem_root) Item_decimal(thd, value, 0); return item ? item->neg(thd) : item; } if (value > 0) max_length++; else if (value < 0 && max_length) max_length--; value= -value; name= 0; return this; } Item *Item_decimal::neg(THD *thd) { my_decimal_neg(&decimal_value); unsigned_flag= 0; name= 0; max_length= my_decimal_precision_to_length_no_truncation( decimal_value.intg + decimals, decimals, unsigned_flag); return this; } Item *Item_float::neg(THD *thd) { if (value > 0) max_length++; else if (value < 0 && max_length) max_length--; value= -value; name= presentation= 0 ; return this; } Item *Item_uint::neg(THD *thd) { Item_decimal *item; if (((ulonglong)value) <= LONGLONG_MAX) return new (thd->mem_root) Item_int(thd, -value, max_length+1); if (value == LONGLONG_MIN) return new (thd->mem_root) Item_int(thd, value, max_length+1); if (!(item= new (thd->mem_root) Item_decimal(thd, value, 1))) return 0; return item->neg(thd); } Item *Item_uint::clone_item(THD *thd) { return new (thd->mem_root) Item_uint(thd, name, value, max_length); } static uint nr_of_decimals(const char *str, const char *end) { const char *decimal_point; /* Find position for '.' */ for (;;) { if (str == end) return 0; if (*str == 'e' || *str == 'E') return NOT_FIXED_DEC; if (*str++ == '.') break; } decimal_point= str; for ( ; str < end && my_isdigit(system_charset_info, *str) ; str++) ; if (str < end && (*str == 'e' || *str == 'E')) return NOT_FIXED_DEC; /* QQ: The number of decimal digist in fact should be (str - decimal_point - 1). But it seems the result of nr_of_decimals() is never used! In case of 'e' and 'E' nr_of_decimals returns NOT_FIXED_DEC. In case if there is no 'e' or 'E' parser code in sql_yacc.yy never calls Item_float::Item_float() - it creates Item_decimal instead. The only piece of code where we call Item_float::Item_float(str, len) without having 'e' or 'E' is item_xmlfunc.cc, but this Item_float never appears in metadata itself. Changing the code to return (str - decimal_point - 1) does not make any changes in the test results. This should be addressed somehow. Looks like a reminder from before real DECIMAL times. */ return (uint) (str - decimal_point); } /** This function is only called during parsing: - when parsing SQL query from sql_yacc.yy - when parsing XPath query from item_xmlfunc.cc We will signal an error if value is not a true double value (overflow): eng: Illegal %s '%-.192s' value found during parsing Note: the string is NOT null terminated when called from item_xmlfunc.cc, so this->name will contain some SQL query tail behind the "length" bytes. This is Ok for now, as this Item is never seen in SHOW, or EXPLAIN, or anywhere else in metadata. Item->name should be fixed to use LEX_STRING eventually. */ Item_float::Item_float(THD *thd, const char *str_arg, uint length): Item_num(thd) { int error; char *end_not_used; value= my_strntod(&my_charset_bin, (char*) str_arg, length, &end_not_used, &error); if (error) { char tmp[NAME_LEN + 2]; my_snprintf(tmp, sizeof(tmp), "%.*s", length, str_arg); my_error(ER_ILLEGAL_VALUE_FOR_TYPE, MYF(0), "double", tmp); } presentation= name=(char*) str_arg; decimals=(uint8) nr_of_decimals(str_arg, str_arg+length); max_length=length; fixed= 1; } int Item_float::save_in_field(Field *field, bool no_conversions) { double nr= val_real(); if (null_value) return set_field_to_null(field); field->set_notnull(); return field->store(nr); } void Item_float::print(String *str, enum_query_type query_type) { if (presentation) { str->append(presentation); return; } char buffer[20]; String num(buffer, sizeof(buffer), &my_charset_bin); num.set_real(value, decimals, &my_charset_bin); str->append(num); } inline uint char_val(char X) { return (uint) (X >= '0' && X <= '9' ? X-'0' : X >= 'A' && X <= 'Z' ? X-'A'+10 : X-'a'+10); } void Item_hex_constant::hex_string_init(THD *thd, const char *str, uint str_length) { max_length=(str_length+1)/2; char *ptr=(char*) thd->alloc(max_length+1); if (!ptr) { str_value.set("", 0, &my_charset_bin); return; } str_value.set(ptr,max_length,&my_charset_bin); char *end=ptr+max_length; if (max_length*2 != str_length) *ptr++=char_val(*str++); // Not even, assume 0 prefix while (ptr != end) { *ptr++= (char) (char_val(str[0])*16+char_val(str[1])); str+=2; } *ptr=0; // Keep purify happy collation.set(&my_charset_bin, DERIVATION_COERCIBLE); fixed= 1; unsigned_flag= 1; } void Item_hex_hybrid::print(String *str, enum_query_type query_type) { uint32 len= MY_MIN(str_value.length(), sizeof(longlong)); const char *ptr= str_value.ptr() + str_value.length() - len; str->append("0x"); str->append_hex(ptr, len); } void Item_hex_string::print(String *str, enum_query_type query_type) { str->append("X'"); str->append_hex(str_value.ptr(), str_value.length()); str->append("'"); } /* bin item. In string context this is a binary string. In number context this is a longlong value. */ Item_bin_string::Item_bin_string(THD *thd, const char *str, uint str_length): Item_hex_hybrid(thd) { const char *end= str + str_length - 1; char *ptr; uchar bits= 0; uint power= 1; max_length= (str_length + 7) >> 3; if (!(ptr= (char*) thd->alloc(max_length + 1))) return; str_value.set(ptr, max_length, &my_charset_bin); if (max_length > 0) { ptr+= max_length - 1; ptr[1]= 0; // Set end null for string for (; end >= str; end--) { if (power == 256) { power= 1; *ptr--= bits; bits= 0; } if (*end == '1') bits|= power; power<<= 1; } *ptr= (char) bits; } else ptr[0]= 0; collation.set(&my_charset_bin, DERIVATION_COERCIBLE); fixed= 1; } bool Item_temporal_literal::eq(const Item *item, bool binary_cmp) const { return item->basic_const_item() && type() == item->type() && field_type() == ((Item_temporal_literal *) item)->field_type() && !my_time_compare(&cached_time, &((Item_temporal_literal *) item)->cached_time); } void Item_date_literal::print(String *str, enum_query_type query_type) { str->append("DATE'"); char buf[MAX_DATE_STRING_REP_LENGTH]; my_date_to_str(&cached_time, buf); str->append(buf); str->append('\''); } Item *Item_date_literal::clone_item(THD *thd) { return new (thd->mem_root) Item_date_literal(thd, &cached_time); } bool Item_date_literal::get_date(MYSQL_TIME *ltime, ulonglong fuzzy_date) { DBUG_ASSERT(fixed); fuzzy_date |= sql_mode_for_dates(current_thd); *ltime= cached_time; return (null_value= check_date_with_warn(ltime, fuzzy_date, MYSQL_TIMESTAMP_ERROR)); } void Item_datetime_literal::print(String *str, enum_query_type query_type) { str->append("TIMESTAMP'"); char buf[MAX_DATE_STRING_REP_LENGTH]; my_datetime_to_str(&cached_time, buf, decimals); str->append(buf); str->append('\''); } Item *Item_datetime_literal::clone_item(THD *thd) { return new (thd->mem_root) Item_datetime_literal(thd, &cached_time, decimals); } bool Item_datetime_literal::get_date(MYSQL_TIME *ltime, ulonglong fuzzy_date) { DBUG_ASSERT(fixed); fuzzy_date |= sql_mode_for_dates(current_thd); *ltime= cached_time; return (null_value= check_date_with_warn(ltime, fuzzy_date, MYSQL_TIMESTAMP_ERROR)); } void Item_time_literal::print(String *str, enum_query_type query_type) { str->append("TIME'"); char buf[MAX_DATE_STRING_REP_LENGTH]; my_time_to_str(&cached_time, buf, decimals); str->append(buf); str->append('\''); } Item *Item_time_literal::clone_item(THD *thd) { return new (thd->mem_root) Item_time_literal(thd, &cached_time, decimals); } bool Item_time_literal::get_date(MYSQL_TIME *ltime, ulonglong fuzzy_date) { DBUG_ASSERT(fixed); *ltime= cached_time; if (fuzzy_date & TIME_TIME_ONLY) return (null_value= false); return (null_value= check_date_with_warn(ltime, fuzzy_date, MYSQL_TIMESTAMP_ERROR)); } /** Pack data in buffer for sending. */ bool Item_null::send(Protocol *protocol, String *packet) { return protocol->store_null(); } /** This is only called from items that is not of type item_field. */ bool Item::send(Protocol *protocol, String *buffer) { bool UNINIT_VAR(result); // Will be set if null_value == 0 enum_field_types f_type; switch ((f_type=field_type())) { default: case MYSQL_TYPE_NULL: case MYSQL_TYPE_DECIMAL: case MYSQL_TYPE_ENUM: case MYSQL_TYPE_SET: case MYSQL_TYPE_TINY_BLOB: case MYSQL_TYPE_MEDIUM_BLOB: case MYSQL_TYPE_LONG_BLOB: case MYSQL_TYPE_BLOB: case MYSQL_TYPE_GEOMETRY: case MYSQL_TYPE_STRING: case MYSQL_TYPE_VAR_STRING: case MYSQL_TYPE_VARCHAR: case MYSQL_TYPE_BIT: case MYSQL_TYPE_NEWDECIMAL: { String *res; if ((res=val_str(buffer))) { DBUG_ASSERT(!null_value); result= protocol->store(res->ptr(),res->length(),res->charset()); } else { DBUG_ASSERT(null_value); } break; } case MYSQL_TYPE_TINY: { longlong nr; nr= val_int(); if (!null_value) result= protocol->store_tiny(nr); break; } case MYSQL_TYPE_SHORT: case MYSQL_TYPE_YEAR: { longlong nr; nr= val_int(); if (!null_value) result= protocol->store_short(nr); break; } case MYSQL_TYPE_INT24: case MYSQL_TYPE_LONG: { longlong nr; nr= val_int(); if (!null_value) result= protocol->store_long(nr); break; } case MYSQL_TYPE_LONGLONG: { longlong nr; nr= val_int(); if (!null_value) result= protocol->store_longlong(nr, unsigned_flag); break; } case MYSQL_TYPE_FLOAT: { float nr; nr= (float) val_real(); if (!null_value) result= protocol->store(nr, decimals, buffer); break; } case MYSQL_TYPE_DOUBLE: { double nr= val_real(); if (!null_value) result= protocol->store(nr, decimals, buffer); break; } case MYSQL_TYPE_DATETIME: case MYSQL_TYPE_DATE: case MYSQL_TYPE_TIMESTAMP: { MYSQL_TIME tm; get_date(&tm, sql_mode_for_dates(current_thd)); if (!null_value) { if (f_type == MYSQL_TYPE_DATE) return protocol->store_date(&tm); else result= protocol->store(&tm, decimals); } break; } case MYSQL_TYPE_TIME: { MYSQL_TIME tm; get_time(&tm); if (!null_value) result= protocol->store_time(&tm, decimals); break; } } if (null_value) result= protocol->store_null(); return result; } /** Check if an item is a constant one and can be cached. @param arg [out] TRUE <=> Cache this item. @return TRUE Go deeper in item tree. @return FALSE Don't go deeper in item tree. */ bool Item::cache_const_expr_analyzer(uchar **arg) { bool *cache_flag= (bool*)*arg; if (!*cache_flag) { Item *item= real_item(); /* Cache constant items unless it's a basic constant, constant field or a subselect (they use their own cache). */ if (const_item() && !(basic_const_item() || item->basic_const_item() || item->type() == Item::NULL_ITEM || /* Item_name_const hack */ item->type() == Item::FIELD_ITEM || item->type() == SUBSELECT_ITEM || item->type() == CACHE_ITEM || /* Do not cache GET_USER_VAR() function as its const_item() may return TRUE for the current thread but it still may change during the execution. */ (item->type() == Item::FUNC_ITEM && ((Item_func*)item)->functype() == Item_func::GUSERVAR_FUNC))) *cache_flag= TRUE; return TRUE; } return FALSE; } /** Cache item if needed. @param arg TRUE <=> Cache this item. @return cache if cache needed. @return this otherwise. */ Item* Item::cache_const_expr_transformer(THD *thd, uchar *arg) { if (*(bool*)arg) { *((bool*)arg)= FALSE; Item_cache *cache= Item_cache::get_cache(thd, this); if (!cache) return NULL; cache->setup(thd, this); cache->store(this); return cache; } return this; } /** Find Item by reference in the expression */ bool Item::find_item_processor(void *arg) { return (this == ((Item *) arg)); } bool Item_field::send(Protocol *protocol, String *buffer) { return protocol->store(result_field); } Item* Item::propagate_equal_fields_and_change_item_tree(THD *thd, const Context &ctx, COND_EQUAL *cond, Item **place) { Item *item= propagate_equal_fields(thd, ctx, cond); if (item && item != this) thd->change_item_tree(place, item); return item; } void Item_field::update_null_value() { /* need to set no_errors to prevent warnings about type conversion popping up. */ THD *thd= field->table->in_use; int no_errors; no_errors= thd->no_errors; thd->no_errors= 1; Item::update_null_value(); thd->no_errors= no_errors; } /* Add the field to the select list and substitute it for the reference to the field. SYNOPSIS Item_field::update_value_transformer() select_arg current select DESCRIPTION If the field doesn't belong to the table being inserted into then it is added to the select list, pointer to it is stored in the ref_pointer_array of the select and the field itself is substituted for the Item_ref object. This is done in order to get correct values from update fields that belongs to the SELECT part in the INSERT .. SELECT .. ON DUPLICATE KEY UPDATE statement. RETURN 0 if error occurred ref if all conditions are met this field otherwise */ Item *Item_field::update_value_transformer(THD *thd, uchar *select_arg) { SELECT_LEX *select= (SELECT_LEX*)select_arg; DBUG_ASSERT(fixed); if (field->table != select->context.table_list->table && type() != Item::TRIGGER_FIELD_ITEM) { List *all_fields= &select->join->all_fields; Ref_ptr_array &ref_pointer_array= select->ref_pointer_array; int el= all_fields->elements; Item_ref *ref; ref_pointer_array[el]= (Item*)this; all_fields->push_front((Item*)this, thd->mem_root); ref= new (thd->mem_root) Item_ref(thd, &select->context, &ref_pointer_array[el], table_name, field_name); return ref; } return this; } static Item *get_field_item_for_having(THD *thd, Item *item, st_select_lex *sel) { DBUG_ASSERT(item->type() == Item::FIELD_ITEM || (item->type() == Item::REF_ITEM && ((Item_ref *) item)->ref_type() == Item_ref::VIEW_REF)); Item_field *field_item= NULL; table_map map= sel->master_unit()->derived->table->map; Item_equal *item_equal= item->get_item_equal(); if (!item_equal) field_item= (Item_field *)(item->real_item()); else { Item_equal_fields_iterator li(*item_equal); Item *equal_item; while ((equal_item= li++)) { if (equal_item->used_tables() == map) { field_item= (Item_field *)(equal_item->real_item()); break; } } } if (field_item) { Item_ref *ref= new (thd->mem_root) Item_ref(thd, &sel->context, NullS, NullS, field_item->field_name); return ref; } DBUG_ASSERT(0); return NULL; } Item *Item_ident::derived_field_transformer_for_having(THD *thd, uchar *arg) { st_select_lex *sel= (st_select_lex *)arg; context= &sel->context; return this; } Item *Item_field::derived_field_transformer_for_having(THD *thd, uchar *arg) { st_select_lex *sel= (st_select_lex *)arg; table_map tab_map= sel->master_unit()->derived->table->map; if (item_equal && !(item_equal->used_tables() & tab_map)) return this; if (!item_equal && used_tables() != tab_map) return this; Item *item= get_field_item_for_having(thd, this, sel); if (item) item->marker|= SUBSTITUTION_FL; return item; } Item *Item_direct_view_ref::derived_field_transformer_for_having(THD *thd, uchar *arg) { st_select_lex *sel= (st_select_lex *)arg; context= &sel->context; if ((*ref)->marker & SUBSTITUTION_FL) { this->marker|= SUBSTITUTION_FL; return this; } table_map tab_map= sel->master_unit()->derived->table->map; if ((item_equal && !(item_equal->used_tables() & tab_map)) || !item_equal) return this; return get_field_item_for_having(thd, this, sel); } static Item *find_producing_item(Item *item, st_select_lex *sel) { DBUG_ASSERT(item->type() == Item::FIELD_ITEM || (item->type() == Item::REF_ITEM && ((Item_ref *) item)->ref_type() == Item_ref::VIEW_REF)); Item_field *field_item= NULL; Item_equal *item_equal= item->get_item_equal(); table_map tab_map= sel->master_unit()->derived->table->map; if (item->used_tables() == tab_map) field_item= (Item_field *) (item->real_item()); if (!field_item && item_equal) { Item_equal_fields_iterator it(*item_equal); Item *equal_item; while ((equal_item= it++)) { if (equal_item->used_tables() == tab_map) { field_item= (Item_field *) (equal_item->real_item()); break; } } } List_iterator_fast li(sel->item_list); if (field_item) { Item *producing_item= NULL; uint field_no= field_item->field->field_index; for (uint i= 0; i <= field_no; i++) producing_item= li++; return producing_item; } return NULL; } Item *Item_field::derived_field_transformer_for_where(THD *thd, uchar *arg) { st_select_lex *sel= (st_select_lex *)arg; Item *producing_item= find_producing_item(this, sel); if (producing_item) { Item *producing_clone= producing_item->build_clone(thd, thd->mem_root); if (producing_clone) producing_clone->marker|= SUBSTITUTION_FL; return producing_clone; } return this; } Item *Item_direct_view_ref::derived_field_transformer_for_where(THD *thd, uchar *arg) { if ((*ref)->marker & SUBSTITUTION_FL) return (*ref); if (item_equal) { st_select_lex *sel= (st_select_lex *)arg; Item *producing_item= find_producing_item(this, sel); DBUG_ASSERT (producing_item != NULL); return producing_item->build_clone(thd, thd->mem_root); } return (*ref); } static Grouping_tmp_field *find_matching_grouping_field(Item *item, st_select_lex *sel) { DBUG_ASSERT(item->type() == Item::FIELD_ITEM || (item->type() == Item::REF_ITEM && ((Item_ref *) item)->ref_type() == Item_ref::VIEW_REF)); List_iterator li(sel->grouping_tmp_fields); Grouping_tmp_field *gr_field; Item_field *field_item= (Item_field *) (item->real_item()); while ((gr_field= li++)) { if (field_item->field == gr_field->tmp_field) return gr_field; } Item_equal *item_equal= item->get_item_equal(); if (item_equal) { Item_equal_fields_iterator it(*item_equal); Item *equal_item; while ((equal_item= it++)) { field_item= (Item_field *) (equal_item->real_item()); li.rewind(); while ((gr_field= li++)) { if (field_item->field == gr_field->tmp_field) return gr_field; } } } return NULL; } Item *Item_field::derived_grouping_field_transformer_for_where(THD *thd, uchar *arg) { st_select_lex *sel= (st_select_lex *)arg; Grouping_tmp_field *gr_field= find_matching_grouping_field(this, sel); if (gr_field) { Item *producing_clone= gr_field->producing_item->build_clone(thd, thd->mem_root); if (producing_clone) producing_clone->marker|= SUBSTITUTION_FL; return producing_clone; } return this; } Item * Item_direct_view_ref::derived_grouping_field_transformer_for_where(THD *thd, uchar *arg) { if ((*ref)->marker & SUBSTITUTION_FL) { this->marker|= SUBSTITUTION_FL; return this; } if (!item_equal) return this; st_select_lex *sel= (st_select_lex *)arg; Grouping_tmp_field *gr_field= find_matching_grouping_field(this, sel); return gr_field->producing_item->build_clone(thd, thd->mem_root); } void Item_field::print(String *str, enum_query_type query_type) { if (field && field->table->const_table && !(query_type & (QT_NO_DATA_EXPANSION | QT_VIEW_INTERNAL))) { print_value(str); return; } Item_ident::print(str, query_type); } void Item_temptable_field::print(String *str, enum_query_type query_type) { /* Item_ident doesn't have references to the underlying Field/TABLE objects, so it's ok to use the following: */ Item_ident::print(str, query_type); } Item_ref::Item_ref(THD *thd, Name_resolution_context *context_arg, Item **item, const char *table_name_arg, const char *field_name_arg, bool alias_name_used_arg): Item_ident(thd, context_arg, NullS, table_name_arg, field_name_arg), ref(item), reference_trough_name(0) { alias_name_used= alias_name_used_arg; /* This constructor used to create some internals references over fixed items */ if ((set_properties_only= (ref && *ref && (*ref)->fixed))) set_properties(); } /* A Field_enumerator-compatible class that invokes mark_as_dependent() for each field that is a reference to some ancestor of current_select. */ class Dependency_marker: public Field_enumerator { public: THD *thd; st_select_lex *current_select; virtual void visit_field(Item_field *item) { // Find which select the field is in. This is achieved by walking up // the select tree and looking for the table of interest. st_select_lex *sel; for (sel= current_select; sel ; sel= (sel->context.outer_context ? sel->context.outer_context->select_lex: NULL)) { List_iterator li(sel->leaf_tables); TABLE_LIST *tbl; while ((tbl= li++)) { if (tbl->table == item->field->table) { if (sel != current_select) mark_as_dependent(thd, sel, current_select, item, item, false); return; } } } } }; Item_ref::Item_ref(THD *thd, TABLE_LIST *view_arg, Item **item, const char *field_name_arg, bool alias_name_used_arg): Item_ident(thd, view_arg, field_name_arg), ref(item), reference_trough_name(0) { alias_name_used= alias_name_used_arg; /* This constructor is used to create some internal references over fixed items */ if ((set_properties_only= (ref && *ref && (*ref)->fixed))) set_properties(); } /** Resolve the name of a reference to a column reference. The method resolves the column reference represented by 'this' as a column present in one of: GROUP BY clause, SELECT clause, outer queries. It is used typically for columns in the HAVING clause which are not under aggregate functions. POSTCONDITION @n Item_ref::ref is 0 or points to a valid item. @note The name resolution algorithm used is (where [T_j] is an optional table name that qualifies the column name): @code resolve_extended([T_j].col_ref_i) { Search for a column or derived column named col_ref_i [in table T_j] in the SELECT and GROUP clauses of Q. if such a column is NOT found AND // Lookup in outer queries. there are outer queries { for each outer query Q_k beginning from the inner-most one { Search for a column or derived column named col_ref_i [in table T_j] in the SELECT and GROUP clauses of Q_k. if such a column is not found AND - Q_k is not a group query AND - Q_k is not inside an aggregate function OR - Q_(k-1) is not in a HAVING or SELECT clause of Q_k { search for a column or derived column named col_ref_i [in table T_j] in the FROM clause of Q_k; } } } } @endcode @n This procedure treats GROUP BY and SELECT clauses as one namespace for column references in HAVING. Notice that compared to Item_field::fix_fields, here we first search the SELECT and GROUP BY clauses, and then we search the FROM clause. @param[in] thd current thread @param[in,out] reference view column if this item was resolved to a view column @todo Here we could first find the field anyway, and then test this condition, so that we can give a better error message - ER_WRONG_FIELD_WITH_GROUP, instead of the less informative ER_BAD_FIELD_ERROR which we produce now. @retval TRUE if error @retval FALSE on success */ bool Item_ref::fix_fields(THD *thd, Item **reference) { enum_parsing_place place= NO_MATTER; DBUG_ASSERT(fixed == 0); SELECT_LEX *current_sel= context->select_lex; LEX *lex_s= context->select_lex->parent_lex; if (set_properties_only) { /* do nothing */ } else if (!ref || ref == not_found_item) { DBUG_ASSERT(reference_trough_name != 0); if (!(ref= resolve_ref_in_select_and_group(thd, this, context->select_lex))) goto error; /* Some error occurred (e.g. ambiguous names). */ if (ref == not_found_item) /* This reference was not resolved. */ { Name_resolution_context *last_checked_context= context; Name_resolution_context *outer_context= context->outer_context; Field *from_field; ref= 0; if (!outer_context) { /* The current reference cannot be resolved in this query. */ my_error(ER_BAD_FIELD_ERROR,MYF(0), this->full_name(), thd->where); goto error; } /* If there is an outer context (select), and it is not a derived table (which do not support the use of outer fields for now), try to resolve this reference in the outer select(s). We treat each subselect as a separate namespace, so that different subselects may contain columns with the same names. The subselects are searched starting from the innermost. */ from_field= (Field*) not_found_field; do { SELECT_LEX *select= outer_context->select_lex; Item_subselect *prev_subselect_item= last_checked_context->select_lex->master_unit()->item; last_checked_context= outer_context; /* Search in the SELECT and GROUP lists of the outer select. */ if (outer_context->resolve_in_select_list) { if (!(ref= resolve_ref_in_select_and_group(thd, this, select))) goto error; /* Some error occurred (e.g. ambiguous names). */ if (ref != not_found_item) { DBUG_ASSERT(*ref && (*ref)->fixed); prev_subselect_item->used_tables_and_const_cache_join(*ref); break; } /* Set ref to 0 to ensure that we get an error in case we replaced this item with another item and still use this item in some other place of the parse tree. */ ref= 0; } place= prev_subselect_item->parsing_place; /* Check table fields only if the subquery is used somewhere out of HAVING or the outer SELECT does not use grouping (i.e. tables are accessible). TODO: Here we could first find the field anyway, and then test this condition, so that we can give a better error message - ER_WRONG_FIELD_WITH_GROUP, instead of the less informative ER_BAD_FIELD_ERROR which we produce now. */ if ((place != IN_HAVING || (!select->with_sum_func && select->group_list.elements == 0))) { /* In case of view, find_field_in_tables() write pointer to view field expression to 'reference', i.e. it substitute that expression instead of this Item_ref */ from_field= find_field_in_tables(thd, this, outer_context-> first_name_resolution_table, outer_context-> last_name_resolution_table, reference, IGNORE_EXCEPT_NON_UNIQUE, TRUE, TRUE); if (! from_field) goto error; if (from_field == view_ref_found) { Item::Type refer_type= (*reference)->type(); prev_subselect_item->used_tables_and_const_cache_join(*reference); DBUG_ASSERT((*reference)->type() == REF_ITEM); mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, this, ((refer_type == REF_ITEM || refer_type == FIELD_ITEM) ? (Item_ident*) (*reference) : 0), false); /* view reference found, we substituted it instead of this Item, so can quit */ return FALSE; } if (from_field != not_found_field) { if (cached_table && cached_table->select_lex && outer_context->select_lex && cached_table->select_lex != outer_context->select_lex) { /* Due to cache, find_field_in_tables() can return field which doesn't belong to provided outer_context. In this case we have to find proper field context in order to fix field correctly. */ do { outer_context= outer_context->outer_context; select= outer_context->select_lex; prev_subselect_item= last_checked_context->select_lex->master_unit()->item; last_checked_context= outer_context; } while (outer_context && outer_context->select_lex && cached_table->select_lex != outer_context->select_lex); } prev_subselect_item->used_tables_cache|= from_field->table->map; prev_subselect_item->const_item_cache= 0; break; } } DBUG_ASSERT(from_field == not_found_field); /* Reference is not found => depend on outer (or just error). */ prev_subselect_item->used_tables_cache|= OUTER_REF_TABLE_BIT; prev_subselect_item->const_item_cache= 0; outer_context= outer_context->outer_context; } while (outer_context); DBUG_ASSERT(from_field != 0 && from_field != view_ref_found); if (from_field != not_found_field) { Item_field* fld; if (!(fld= new (thd->mem_root) Item_field(thd, from_field))) goto error; thd->change_item_tree(reference, fld); mark_as_dependent(thd, last_checked_context->select_lex, current_sel, fld, fld, false); /* A reference is resolved to a nest level that's outer or the same as the nest level of the enclosing set function : adjust the value of max_arg_level for the function if it's needed. */ if (lex_s->in_sum_func && lex_s->in_sum_func->nest_level >= last_checked_context->select_lex->nest_level) set_if_bigger(lex_s->in_sum_func->max_arg_level, last_checked_context->select_lex->nest_level); return FALSE; } if (ref == 0) { /* The item was not a table field and not a reference */ my_error(ER_BAD_FIELD_ERROR, MYF(0), this->full_name(), thd->where); goto error; } /* Should be checked in resolve_ref_in_select_and_group(). */ DBUG_ASSERT(*ref && (*ref)->fixed); mark_as_dependent(thd, last_checked_context->select_lex, context->select_lex, this, this, false); /* A reference is resolved to a nest level that's outer or the same as the nest level of the enclosing set function : adjust the value of max_arg_level for the function if it's needed. */ if (lex_s->in_sum_func && lex_s->in_sum_func->nest_level >= last_checked_context->select_lex->nest_level) set_if_bigger(lex_s->in_sum_func->max_arg_level, last_checked_context->select_lex->nest_level); } } DBUG_ASSERT(*ref); /* Check if this is an incorrect reference in a group function or forward reference. Do not issue an error if this is: 1. outer reference (will be fixed later by the fix_inner_refs function); 2. an unnamed reference inside an aggregate function. */ if (!((*ref)->type() == REF_ITEM && ((Item_ref *)(*ref))->ref_type() == OUTER_REF) && (((*ref)->with_sum_func && name && !(current_sel->linkage != GLOBAL_OPTIONS_TYPE && current_sel->having_fix_field)) || !(*ref)->fixed)) { my_error(ER_ILLEGAL_REFERENCE, MYF(0), name, ((*ref)->with_sum_func? "reference to group function": "forward reference in item list")); goto error; } set_properties(); if ((*ref)->check_cols(1)) goto error; return FALSE; error: context->process_error(thd); return TRUE; } void Item_ref::set_properties() { Type_std_attributes::set(*ref); maybe_null= (*ref)->maybe_null; /* We have to remember if we refer to a sum function, to ensure that split_sum_func() doesn't try to change the reference. */ with_sum_func= (*ref)->with_sum_func; with_param= (*ref)->with_param; with_window_func= (*ref)->with_window_func; with_field= (*ref)->with_field; fixed= 1; if (alias_name_used) return; if ((*ref)->type() == FIELD_ITEM) alias_name_used= ((Item_ident *) (*ref))->alias_name_used; else alias_name_used= TRUE; // it is not field, so it is was resolved by alias } void Item_ref::cleanup() { DBUG_ENTER("Item_ref::cleanup"); Item_ident::cleanup(); if (reference_trough_name) { /* We have to reset the reference as it may been freed */ ref= 0; } DBUG_VOID_RETURN; } /** Transform an Item_ref object with a transformer callback function. The function first applies the transform method to the item referenced by this Item_ref object. If this returns a new item the old item is substituted for a new one. After this the transformer is applied to the Item_ref object. @param transformer the transformer callback function to be applied to the nodes of the tree of the object @param argument parameter to be passed to the transformer @return Item returned as the result of transformation of the Item_ref object @retval !NULL The transformation was successful @retval NULL Out of memory error */ Item* Item_ref::transform(THD *thd, Item_transformer transformer, uchar *arg) { DBUG_ASSERT(!thd->stmt_arena->is_stmt_prepare()); DBUG_ASSERT((*ref) != NULL); /* Transform the object we are referencing. */ Item *new_item= (*ref)->transform(thd, transformer, arg); if (!new_item) return NULL; /* THD::change_item_tree() should be called only if the tree was really transformed, i.e. when a new item has been created. Otherwise we'll be allocating a lot of unnecessary memory for change records at each execution. */ if (*ref != new_item) thd->change_item_tree(ref, new_item); /* Transform the item ref object. */ return (this->*transformer)(thd, arg); } /** Compile an Item_ref object with a processor and a transformer callback functions. First the function applies the analyzer to the Item_ref object. Then if the analyzer succeeds we first apply the compile method to the object the Item_ref object is referencing. If this returns a new item the old item is substituted for a new one. After this the transformer is applied to the Item_ref object itself. The compile function is not called if the analyzer returns NULL in the parameter arg_p. @param analyzer the analyzer callback function to be applied to the nodes of the tree of the object @param[in,out] arg_p parameter to be passed to the processor @param transformer the transformer callback function to be applied to the nodes of the tree of the object @param arg_t parameter to be passed to the transformer @return Item returned as the result of transformation of the Item_ref object */ Item* Item_ref::compile(THD *thd, Item_analyzer analyzer, uchar **arg_p, Item_transformer transformer, uchar *arg_t) { /* Analyze this Item object. */ if (!(this->*analyzer)(arg_p)) return NULL; /* Compile the Item we are referencing. */ DBUG_ASSERT((*ref) != NULL); if (*arg_p) { uchar *arg_v= *arg_p; Item *new_item= (*ref)->compile(thd, analyzer, &arg_v, transformer, arg_t); if (new_item && *ref != new_item) thd->change_item_tree(ref, new_item); } /* Transform this Item object. */ return (this->*transformer)(thd, arg_t); } void Item_ref::print(String *str, enum_query_type query_type) { if (ref) { if ((*ref)->type() != Item::CACHE_ITEM && (*ref)->type() != Item::WINDOW_FUNC_ITEM && ref_type() != VIEW_REF && !table_name && name && alias_name_used) { THD *thd= current_thd; append_identifier(thd, str, (*ref)->real_item()->name, strlen((*ref)->real_item()->name)); } else (*ref)->print(str, query_type); } else Item_ident::print(str, query_type); } bool Item_ref::send(Protocol *prot, String *tmp) { if (result_field) return prot->store(result_field); return (*ref)->send(prot, tmp); } double Item_ref::val_result() { if (result_field) { if ((null_value= result_field->is_null())) return 0.0; return result_field->val_real(); } return val_real(); } bool Item_ref::is_null_result() { if (result_field) return (null_value=result_field->is_null()); return is_null(); } longlong Item_ref::val_int_result() { if (result_field) { if ((null_value= result_field->is_null())) return 0; return result_field->val_int(); } return val_int(); } String *Item_ref::str_result(String* str) { if (result_field) { if ((null_value= result_field->is_null())) return 0; str->set_charset(str_value.charset()); return result_field->val_str(str, &str_value); } return val_str(str); } my_decimal *Item_ref::val_decimal_result(my_decimal *decimal_value) { if (result_field) { if ((null_value= result_field->is_null())) return 0; return result_field->val_decimal(decimal_value); } return val_decimal(decimal_value); } bool Item_ref::val_bool_result() { if (result_field) { if ((null_value= result_field->is_null())) return false; return result_field->val_bool(); } return val_bool(); } void Item_ref::save_result(Field *to) { if (result_field) { save_field_in_field(result_field, &null_value, to, TRUE); return; } (*ref)->save_result(to); null_value= (*ref)->null_value; } void Item_ref::save_val(Field *to) { (*ref)->save_result(to); null_value= (*ref)->null_value; } double Item_ref::val_real() { DBUG_ASSERT(fixed); double tmp=(*ref)->val_result(); null_value=(*ref)->null_value; return tmp; } longlong Item_ref::val_int() { DBUG_ASSERT(fixed); longlong tmp=(*ref)->val_int_result(); null_value=(*ref)->null_value; return tmp; } bool Item_ref::val_bool() { DBUG_ASSERT(fixed); bool tmp= (*ref)->val_bool_result(); null_value= (*ref)->null_value; return tmp; } String *Item_ref::val_str(String* tmp) { DBUG_ASSERT(fixed); tmp=(*ref)->str_result(tmp); null_value=(*ref)->null_value; return tmp; } bool Item_ref::is_null() { DBUG_ASSERT(fixed); bool tmp=(*ref)->is_null_result(); null_value=(*ref)->null_value; return tmp; } bool Item_ref::get_date(MYSQL_TIME *ltime,ulonglong fuzzydate) { return (null_value=(*ref)->get_date_result(ltime,fuzzydate)); } longlong Item_ref::val_datetime_packed() { DBUG_ASSERT(fixed); longlong tmp= (*ref)->val_datetime_packed_result(); null_value= (*ref)->null_value; return tmp; } longlong Item_ref::val_time_packed() { DBUG_ASSERT(fixed); longlong tmp= (*ref)->val_time_packed_result(); null_value= (*ref)->null_value; return tmp; } my_decimal *Item_ref::val_decimal(my_decimal *decimal_value) { my_decimal *val= (*ref)->val_decimal_result(decimal_value); null_value= (*ref)->null_value; return val; } int Item_ref::save_in_field(Field *to, bool no_conversions) { int res; if (result_field) { if (result_field->is_null()) { null_value= 1; res= set_field_to_null_with_conversions(to, no_conversions); return res; } to->set_notnull(); res= field_conv(to, result_field); null_value= 0; return res; } res= (*ref)->save_in_field(to, no_conversions); null_value= (*ref)->null_value; return res; } void Item_ref::save_org_in_field(Field *field, fast_field_copier optimizer_data) { (*ref)->save_org_in_field(field, optimizer_data); } void Item_ref::make_field(THD *thd, Send_field *field) { (*ref)->make_field(thd, field); /* Non-zero in case of a view */ if (name) field->col_name= name; if (table_name) field->table_name= table_name; if (db_name) field->db_name= db_name; if (orig_field_name) field->org_col_name= orig_field_name; if (orig_table_name) field->org_table_name= orig_table_name; } Item *Item_ref::get_tmp_table_item(THD *thd) { if (!result_field) return (*ref)->get_tmp_table_item(thd); Item_field *item= new (thd->mem_root) Item_field(thd, result_field); if (item) { item->table_name= table_name; item->db_name= db_name; } return item; } void Item_ref_null_helper::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("(")); if (ref) (*ref)->print(str, query_type); else str->append('?'); str->append(')'); } void Item_direct_ref::save_val(Field *to) { (*ref)->save_val(to); null_value=(*ref)->null_value; } double Item_direct_ref::val_real() { double tmp=(*ref)->val_real(); null_value=(*ref)->null_value; return tmp; } longlong Item_direct_ref::val_int() { longlong tmp=(*ref)->val_int(); null_value=(*ref)->null_value; return tmp; } String *Item_direct_ref::val_str(String* tmp) { tmp=(*ref)->val_str(tmp); null_value=(*ref)->null_value; return tmp; } my_decimal *Item_direct_ref::val_decimal(my_decimal *decimal_value) { my_decimal *tmp= (*ref)->val_decimal(decimal_value); null_value=(*ref)->null_value; return tmp; } bool Item_direct_ref::val_bool() { bool tmp= (*ref)->val_bool(); null_value=(*ref)->null_value; return tmp; } bool Item_direct_ref::is_null() { return (*ref)->is_null(); } bool Item_direct_ref::get_date(MYSQL_TIME *ltime,ulonglong fuzzydate) { return (null_value=(*ref)->get_date(ltime,fuzzydate)); } longlong Item_direct_ref::val_time_packed() { longlong tmp = (*ref)->val_time_packed(); null_value= (*ref)->null_value; return tmp; } longlong Item_direct_ref::val_datetime_packed() { longlong tmp = (*ref)->val_datetime_packed(); null_value= (*ref)->null_value; return tmp; } Item_cache_wrapper::~Item_cache_wrapper() { DBUG_ASSERT(expr_cache == 0); } Item_cache_wrapper::Item_cache_wrapper(THD *thd, Item *item_arg): Item_result_field(thd), orig_item(item_arg), expr_cache(NULL), expr_value(NULL) { DBUG_ASSERT(orig_item->fixed); Type_std_attributes::set(orig_item); maybe_null= orig_item->maybe_null; with_sum_func= orig_item->with_sum_func; with_param= orig_item->with_param; with_field= orig_item->with_field; name= item_arg->name; name_length= item_arg->name_length; with_subselect= orig_item->with_subselect; with_window_func= orig_item->with_window_func; if ((expr_value= Item_cache::get_cache(thd, orig_item))) expr_value->setup(thd, orig_item); fixed= 1; } /** Initialize the cache if it is needed */ void Item_cache_wrapper::init_on_demand() { if (!expr_cache->is_inited()) { orig_item->get_cache_parameters(parameters); expr_cache->init(); } } void Item_cache_wrapper::print(String *str, enum_query_type query_type) { if (query_type & QT_ITEM_CACHE_WRAPPER_SKIP_DETAILS) { /* Don't print the cache in EXPLAIN EXTENDED */ orig_item->print(str, query_type); return; } str->append(""); if (expr_cache) { init_on_demand(); expr_cache->print(str, query_type); } else str->append(STRING_WITH_LEN("<>")); str->append('('); orig_item->print(str, query_type); str->append(')'); } /** Prepare the expression cache wrapper (do nothing) @retval FALSE OK */ bool Item_cache_wrapper::fix_fields(THD *thd __attribute__((unused)), Item **it __attribute__((unused))) { DBUG_ASSERT(orig_item->fixed); DBUG_ASSERT(fixed); return FALSE; } bool Item_cache_wrapper::send(Protocol *protocol, String *buffer) { if (result_field) return protocol->store(result_field); return Item::send(protocol, buffer); } /** Clean the expression cache wrapper up before reusing it. */ void Item_cache_wrapper::cleanup() { DBUG_ENTER("Item_cache_wrapper::cleanup"); Item_result_field::cleanup(); delete expr_cache; expr_cache= 0; /* expr_value is Item so it will be destroyed from list of Items */ expr_value= 0; parameters.empty(); DBUG_VOID_RETURN; } /** Create an expression cache that uses a temporary table @param thd Thread handle @param depends_on Parameters of the expression to create cache for @details The function takes 'depends_on' as the list of all parameters for the expression wrapped into this object and creates an expression cache in a temporary table containing the field for the parameters and the result of the expression. @retval FALSE OK @retval TRUE Error */ bool Item_cache_wrapper::set_cache(THD *thd) { DBUG_ENTER("Item_cache_wrapper::set_cache"); DBUG_ASSERT(expr_cache == 0); expr_cache= new Expression_cache_tmptable(thd, parameters, expr_value); DBUG_RETURN(expr_cache == NULL); } Expression_cache_tracker* Item_cache_wrapper::init_tracker(MEM_ROOT *mem_root) { if (expr_cache) { Expression_cache_tracker* tracker= new(mem_root) Expression_cache_tracker(expr_cache); if (tracker) ((Expression_cache_tmptable *)expr_cache)->set_tracker(tracker); return tracker; } return NULL; } /** Check if the current values of the parameters are in the expression cache @details The function checks whether the current set of the parameters of the referenced item can be found in the expression cache. If so the function returns the item by which the result of the expression can be easily extracted from the cache with the corresponding val_* method. @retval NULL - parameters are not in the cache @retval - item providing the result of the expression found in cache */ Item *Item_cache_wrapper::check_cache() { DBUG_ENTER("Item_cache_wrapper::check_cache"); if (expr_cache) { Expression_cache_tmptable::result res; Item *cached_value; init_on_demand(); res= expr_cache->check_value(&cached_value); if (res == Expression_cache_tmptable::HIT) DBUG_RETURN(cached_value); } DBUG_RETURN(NULL); } /** Get the value of the cached expression and put it in the cache */ inline void Item_cache_wrapper::cache() { expr_value->store(orig_item); expr_value->cache_value(); expr_cache->put_value(expr_value); // put in expr_cache } /** Get the value of the possibly cached item into the field. */ void Item_cache_wrapper::save_val(Field *to) { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_int"); if (!expr_cache) { orig_item->save_val(to); null_value= orig_item->null_value; DBUG_VOID_RETURN; } if ((cached_value= check_cache())) { cached_value->save_val(to); null_value= cached_value->null_value; DBUG_VOID_RETURN; } cache(); null_value= expr_value->null_value; expr_value->save_val(to); DBUG_VOID_RETURN; } /** Get the integer value of the possibly cached item. */ longlong Item_cache_wrapper::val_int() { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_int"); if (!expr_cache) { longlong tmp= orig_item->val_int(); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { longlong tmp= cached_value->val_int(); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); null_value= expr_value->null_value; DBUG_RETURN(expr_value->val_int()); } /** Get the real value of the possibly cached item */ double Item_cache_wrapper::val_real() { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_real"); if (!expr_cache) { double tmp= orig_item->val_real(); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { double tmp= cached_value->val_real(); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); null_value= expr_value->null_value; DBUG_RETURN(expr_value->val_real()); } /** Get the string value of the possibly cached item */ String *Item_cache_wrapper::val_str(String* str) { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_str"); if (!expr_cache) { String *tmp= orig_item->val_str(str); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { String *tmp= cached_value->val_str(str); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); if ((null_value= expr_value->null_value)) DBUG_RETURN(NULL); DBUG_RETURN(expr_value->val_str(str)); } /** Get the decimal value of the possibly cached item */ my_decimal *Item_cache_wrapper::val_decimal(my_decimal* decimal_value) { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_decimal"); if (!expr_cache) { my_decimal *tmp= orig_item->val_decimal(decimal_value); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { my_decimal *tmp= cached_value->val_decimal(decimal_value); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); if ((null_value= expr_value->null_value)) DBUG_RETURN(NULL); DBUG_RETURN(expr_value->val_decimal(decimal_value)); } /** Get the boolean value of the possibly cached item */ bool Item_cache_wrapper::val_bool() { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::val_bool"); if (!expr_cache) { bool tmp= orig_item->val_bool(); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { bool tmp= cached_value->val_bool(); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); null_value= expr_value->null_value; DBUG_RETURN(expr_value->val_bool()); } /** Check for NULL the value of the possibly cached item */ bool Item_cache_wrapper::is_null() { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::is_null"); if (!expr_cache) { bool tmp= orig_item->is_null(); null_value= orig_item->null_value; DBUG_RETURN(tmp); } if ((cached_value= check_cache())) { bool tmp= cached_value->is_null(); null_value= cached_value->null_value; DBUG_RETURN(tmp); } cache(); DBUG_RETURN((null_value= expr_value->null_value)); } /** Get the date value of the possibly cached item */ bool Item_cache_wrapper::get_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { Item *cached_value; DBUG_ENTER("Item_cache_wrapper::get_date"); if (!expr_cache) DBUG_RETURN((null_value= orig_item->get_date(ltime, fuzzydate))); if ((cached_value= check_cache())) DBUG_RETURN((null_value= cached_value->get_date(ltime, fuzzydate))); cache(); DBUG_RETURN((null_value= expr_value->get_date(ltime, fuzzydate))); } int Item_cache_wrapper::save_in_field(Field *to, bool no_conversions) { int res; DBUG_ASSERT(!result_field); res= orig_item->save_in_field(to, no_conversions); null_value= orig_item->null_value; return res; } Item* Item_cache_wrapper::get_tmp_table_item(THD *thd) { if (!orig_item->with_sum_func && !orig_item->const_item()) return new (thd->mem_root) Item_temptable_field(thd, result_field); return copy_or_same(thd); } bool Item_direct_view_ref::send(Protocol *protocol, String *buffer) { if (check_null_ref()) return protocol->store_null(); return Item_direct_ref::send(protocol, buffer); } /** Prepare referenced field then call usual Item_direct_ref::fix_fields . @param thd thread handler @param reference reference on reference where this item stored @retval FALSE OK @retval TRUE Error */ bool Item_direct_view_ref::fix_fields(THD *thd, Item **reference) { /* view fild reference must be defined */ DBUG_ASSERT(*ref); /* (*ref)->check_cols() will be made in Item_direct_ref::fix_fields */ if ((*ref)->fixed) { Item *ref_item= (*ref)->real_item(); if (ref_item->type() == Item::FIELD_ITEM) { /* In some cases we need to update table read set(see bug#47150). If ref item is FIELD_ITEM and fixed then field and table have proper values. So we can use them for update. */ Field *fld= ((Item_field*) ref_item)->field; DBUG_ASSERT(fld && fld->table); if (thd->mark_used_columns == MARK_COLUMNS_READ) bitmap_set_bit(fld->table->read_set, fld->field_index); } } else if (!(*ref)->fixed && ((*ref)->fix_fields(thd, ref))) return TRUE; if (Item_direct_ref::fix_fields(thd, reference)) return TRUE; if (view->table && view->table->maybe_null) maybe_null= TRUE; set_null_ref_table(); return FALSE; } /* Prepare referenced outer field then call usual Item_direct_ref::fix_fields SYNOPSIS Item_outer_ref::fix_fields() thd thread handler reference reference on reference where this item stored RETURN FALSE OK TRUE Error */ bool Item_outer_ref::fix_fields(THD *thd, Item **reference) { bool err; /* outer_ref->check_cols() will be made in Item_direct_ref::fix_fields */ if ((*ref) && !(*ref)->fixed && ((*ref)->fix_fields(thd, reference))) return TRUE; err= Item_direct_ref::fix_fields(thd, reference); if (!outer_ref) outer_ref= *ref; if ((*ref)->type() == Item::FIELD_ITEM) table_name= ((Item_field*)outer_ref)->table_name; return err; } void Item_outer_ref::fix_after_pullout(st_select_lex *new_parent, Item **ref_arg, bool merge) { if (get_depended_from() == new_parent) { *ref_arg= outer_ref; (*ref_arg)->fix_after_pullout(new_parent, ref_arg, merge); } } void Item_ref::fix_after_pullout(st_select_lex *new_parent, Item **refptr, bool merge) { (*ref)->fix_after_pullout(new_parent, ref, merge); if (get_depended_from() == new_parent) depended_from= NULL; } /** Mark references from inner selects used in group by clause The method is used by the walk method when called for the expressions from the group by clause. The callsare occurred in the function fix_inner_refs invoked by JOIN::prepare. The parameter passed to Item_outer_ref::check_inner_refs_processor is the iterator over the list of inner references from the subselects of the select to be prepared. The function marks those references from this list whose occurrences are encountered in the group by expressions passed to the walk method. @param arg pointer to the iterator over a list of inner references @return FALSE always */ bool Item_outer_ref::check_inner_refs_processor(void *arg) { List_iterator_fast *it= ((List_iterator_fast *) arg); Item_outer_ref *tmp_ref; while ((tmp_ref= (*it)++)) { if (tmp_ref == this) { tmp_ref->found_in_group_by= 1; break; } } (*it).rewind(); return FALSE; } /** Compare two view column references for equality. A view column reference is considered equal to another column reference if the second one is a view column and if both column references resolve to the same item. It is assumed that both items are of the same type. @param item item to compare with @param binary_cmp make binary comparison @retval TRUE Referenced item is equal to given item @retval FALSE otherwise */ bool Item_direct_view_ref::eq(const Item *item, bool binary_cmp) const { if (item->type() == REF_ITEM) { Item_ref *item_ref= (Item_ref*) item; if (item_ref->ref_type() == VIEW_REF) { Item *item_ref_ref= *(item_ref->ref); return ((*ref)->real_item() == item_ref_ref->real_item()); } } return FALSE; } Item_equal *Item_direct_view_ref::find_item_equal(COND_EQUAL *cond_equal) { Item* field_item= real_item(); if (field_item->type() != FIELD_ITEM) return NULL; return ((Item_field *) field_item)->find_item_equal(cond_equal); } /** Set a pointer to the multiple equality the view field reference belongs to (if any). @details The function looks for a multiple equality containing this item of the type Item_direct_view_ref among those referenced by arg. In the case such equality exists the function does the following. If the found multiple equality contains a constant, then the item is substituted for this constant, otherwise the function sets a pointer to the multiple equality in the item. @param arg reference to list of multiple equalities where the item (this object) is to be looked for @note This function is supposed to be called as a callback parameter in calls of the compile method. @note The function calls Item_field::propagate_equal_fields() for the field item this->real_item() to do the job. Then it takes the pointer to equal_item from this field item and assigns it to this->item_equal. @return - pointer to the replacing constant item, if the field item was substituted - pointer to the field item, otherwise. */ Item *Item_direct_view_ref::propagate_equal_fields(THD *thd, const Context &ctx, COND_EQUAL *cond) { Item *field_item= real_item(); if (field_item->type() != FIELD_ITEM) return this; Item *item= field_item->propagate_equal_fields(thd, ctx, cond); set_item_equal(field_item->get_item_equal()); field_item->set_item_equal(NULL); if (item != field_item) return item; return this; } /** Replace an Item_direct_view_ref for an equal Item_field evaluated earlier (if any). @details If this->item_equal points to some item and coincides with arg then the function returns a pointer to a field item that is referred to by the first element of the item_equal list which the Item_direct_view_ref object belongs to unless item_equal contains a constant item. In this case the function returns this constant item (if the substitution does not require conversion). If the Item_direct_view_ref object does not refer any Item_equal object 'this' is returned . @param arg NULL or points to so some item of the Item_equal type @note This function is supposed to be called as a callback parameter in calls of the transformer method. @note The function calls Item_field::replace_equal_field for the field item this->real_item() to do the job. @return - pointer to a replacement Item_field if there is a better equal item or a pointer to a constant equal item; - this - otherwise. */ Item *Item_direct_view_ref::replace_equal_field(THD *thd, uchar *arg) { Item *field_item= real_item(); if (field_item->type() != FIELD_ITEM) return this; field_item->set_item_equal(item_equal); Item *item= field_item->replace_equal_field(thd, arg); field_item->set_item_equal(0); return item != field_item ? item : this; } bool Item_direct_view_ref::excl_dep_on_table(table_map tab_map) { table_map used= used_tables(); if (used & OUTER_REF_TABLE_BIT) return false; if (!(used & ~tab_map)) return true; if (item_equal) { DBUG_ASSERT(real_item()->type() == Item::FIELD_ITEM); return item_equal->used_tables() & tab_map; } return (*ref)->excl_dep_on_table(tab_map); } bool Item_direct_view_ref::excl_dep_on_grouping_fields(st_select_lex *sel) { if (item_equal) { DBUG_ASSERT(real_item()->type() == Item::FIELD_ITEM); return find_matching_grouping_field(this, sel) != NULL; } return (*ref)->excl_dep_on_grouping_fields(sel); } double Item_direct_view_ref::val_result() { double tmp=(*ref)->val_result(); null_value=(*ref)->null_value; return tmp; } longlong Item_direct_view_ref::val_int_result() { longlong tmp=(*ref)->val_int_result(); null_value=(*ref)->null_value; return tmp; } String *Item_direct_view_ref::str_result(String* tmp) { tmp=(*ref)->str_result(tmp); null_value=(*ref)->null_value; return tmp; } my_decimal *Item_direct_view_ref::val_decimal_result(my_decimal *val) { my_decimal *tmp= (*ref)->val_decimal_result(val); null_value=(*ref)->null_value; return tmp; } bool Item_direct_view_ref::val_bool_result() { bool tmp= (*ref)->val_bool_result(); null_value=(*ref)->null_value; return tmp; } bool Item_default_value::eq(const Item *item, bool binary_cmp) const { return item->type() == DEFAULT_VALUE_ITEM && ((Item_default_value *)item)->arg->eq(arg, binary_cmp); } bool Item_default_value::fix_fields(THD *thd, Item **items) { Item *real_arg; Item_field *field_arg; Field *def_field; DBUG_ASSERT(fixed == 0); if (!arg) { fixed= 1; return FALSE; } /* DEFAULT() do not need table field so should not ask handler to bring field value (mark column for read) */ enum_mark_columns save_mark_used_columns= thd->mark_used_columns; thd->mark_used_columns= MARK_COLUMNS_NONE; if (!arg->fixed && arg->fix_fields(thd, &arg)) { thd->mark_used_columns= save_mark_used_columns; goto error; } thd->mark_used_columns= save_mark_used_columns; real_arg= arg->real_item(); if (real_arg->type() != FIELD_ITEM) { my_error(ER_NO_DEFAULT_FOR_FIELD, MYF(0), arg->name); goto error; } field_arg= (Item_field *)real_arg; if ((field_arg->field->flags & NO_DEFAULT_VALUE_FLAG)) { my_error(ER_NO_DEFAULT_FOR_FIELD, MYF(0), field_arg->field->field_name); goto error; } if (!(def_field= (Field*) thd->alloc(field_arg->field->size_of()))) goto error; cached_field= def_field; memcpy((void *)def_field, (void *)field_arg->field, field_arg->field->size_of()); def_field->reset_fields(); // If non-constant default value expression if (def_field->default_value && def_field->default_value->flags) { uchar *newptr= (uchar*) thd->alloc(1+def_field->pack_length()); if (!newptr) goto error; /* Even if DEFAULT() do not read tables fields, the default value expression can do it. */ fix_session_vcol_expr_for_read(thd, def_field, def_field->default_value); if (thd->mark_used_columns != MARK_COLUMNS_NONE) def_field->default_value->expr->update_used_tables(); def_field->move_field(newptr+1, def_field->maybe_null() ? newptr : 0, 1); } else def_field->move_field_offset((my_ptrdiff_t) (def_field->table->s->default_values - def_field->table->record[0])); set_field(def_field); return FALSE; error: context->process_error(thd); return TRUE; } bool Item_default_value::enchant_default_with_arg_processor(void *proc_arg) { if (!arg) arg= (Item *)proc_arg; return 0; } void Item_default_value::cleanup() { delete cached_field; // Free cached blob data cached_field= 0; Item_field::cleanup(); } void Item_default_value::print(String *str, enum_query_type query_type) { if (!arg) { str->append(STRING_WITH_LEN("default")); return; } str->append(STRING_WITH_LEN("default(")); /* We take DEFAULT from a field so do not need it value in case of const tables but its name so we set QT_NO_DATA_EXPANSION (as we print for table definition, also we do not need table and database name) */ query_type= (enum_query_type) (query_type | QT_NO_DATA_EXPANSION); arg->print(str, query_type); str->append(')'); } void Item_default_value::calculate() { if (field->default_value) field->set_default(); DEBUG_SYNC(field->table->in_use, "after_Item_default_value_calculate"); } String *Item_default_value::val_str(String *str) { calculate(); return Item_field::val_str(str); } double Item_default_value::val_real() { calculate(); return Item_field::val_real(); } longlong Item_default_value::val_int() { calculate(); return Item_field::val_int(); } my_decimal *Item_default_value::val_decimal(my_decimal *decimal_value) { calculate(); return Item_field::val_decimal(decimal_value); } bool Item_default_value::get_date(MYSQL_TIME *ltime,ulonglong fuzzydate) { calculate(); return Item_field::get_date(ltime, fuzzydate); } bool Item_default_value::send(Protocol *protocol, String *buffer) { calculate(); return Item_field::send(protocol, buffer); } int Item_default_value::save_in_field(Field *field_arg, bool no_conversions) { if (arg) { calculate(); return Item_field::save_in_field(field_arg, no_conversions); } return field_arg->save_in_field_default_value(context->error_processor == &view_error_processor); } table_map Item_default_value::used_tables() const { if (!field || !field->default_value) return static_cast(0); if (!field->default_value->expr) // not fully parsed field return static_cast(RAND_TABLE_BIT); return field->default_value->expr->used_tables(); } /** This method like the walk method traverses the item tree, but at the same time it can replace some nodes in the tree. */ Item *Item_default_value::transform(THD *thd, Item_transformer transformer, uchar *args) { DBUG_ASSERT(!thd->stmt_arena->is_stmt_prepare()); /* If the value of arg is NULL, then this object represents a constant, so further transformation is unnecessary (and impossible). */ if (!arg) return 0; Item *new_item= arg->transform(thd, transformer, args); if (!new_item) return 0; /* THD::change_item_tree() should be called only if the tree was really transformed, i.e. when a new item has been created. Otherwise we'll be allocating a lot of unnecessary memory for change records at each execution. */ if (arg != new_item) thd->change_item_tree(&arg, new_item); return (this->*transformer)(thd, args); } void Item_ignore_value::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("ignore")); } int Item_ignore_value::save_in_field(Field *field_arg, bool no_conversions) { return field_arg->save_in_field_ignore_value(context->error_processor == &view_error_processor); } String *Item_ignore_value::val_str(String *str) { DBUG_ASSERT(0); // never should be called null_value= 1; return 0; } double Item_ignore_value::val_real() { DBUG_ASSERT(0); // never should be called null_value= 1; return 0.0; } longlong Item_ignore_value::val_int() { DBUG_ASSERT(0); // never should be called null_value= 1; return 0; } my_decimal *Item_ignore_value::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(0); // never should be called null_value= 1; return 0; } bool Item_ignore_value::get_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { DBUG_ASSERT(0); // never should be called null_value= 1; return TRUE; } bool Item_ignore_value::send(Protocol *protocol, String *buffer) { DBUG_ASSERT(0); // never should be called return TRUE; } bool Item_insert_value::eq(const Item *item, bool binary_cmp) const { return item->type() == INSERT_VALUE_ITEM && ((Item_insert_value *)item)->arg->eq(arg, binary_cmp); } bool Item_insert_value::fix_fields(THD *thd, Item **items) { DBUG_ASSERT(fixed == 0); /* We should only check that arg is in first table */ if (!arg->fixed) { bool res; TABLE_LIST *orig_next_table= context->last_name_resolution_table; context->last_name_resolution_table= context->first_name_resolution_table; res= arg->fix_fields(thd, &arg); context->last_name_resolution_table= orig_next_table; if (res) return TRUE; } if (arg->type() == REF_ITEM) arg= static_cast(arg)->ref[0]; if (arg->type() != FIELD_ITEM) { my_error(ER_BAD_FIELD_ERROR, MYF(0), "", "VALUES() function"); return TRUE; } Item_field *field_arg= (Item_field *)arg; if (field_arg->field->table->insert_values) { Field *def_field= (Field*) thd->alloc(field_arg->field->size_of()); if (!def_field) return TRUE; memcpy((void *)def_field, (void *)field_arg->field, field_arg->field->size_of()); def_field->move_field_offset((my_ptrdiff_t) (def_field->table->insert_values - def_field->table->record[0])); set_field(def_field); } else { static uchar null_bit=1; /* charset doesn't matter here */ Field *tmp_field= new Field_string(0, 0, &null_bit, 1, Field::NONE, field_arg->field->field_name, &my_charset_bin); if (tmp_field) { tmp_field->init(field_arg->field->table); set_field(tmp_field); // the index is important when read bits set tmp_field->field_index= field_arg->field->field_index; } } return FALSE; } void Item_insert_value::print(String *str, enum_query_type query_type) { str->append(STRING_WITH_LEN("values(")); arg->print(str, query_type); str->append(')'); } /** Find index of Field object which will be appropriate for item representing field of row being changed in trigger. @param thd current thread context @param table table of trigger (and where we looking for fields) @param table_grant_info GRANT_INFO of the subject table @note This function does almost the same as fix_fields() for Item_field but is invoked right after trigger definition parsing. Since at this stage we can't say exactly what Field object (corresponding to TABLE::record[0] or TABLE::record[1]) should be bound to this Item, we only find out index of the Field and then select concrete Field object in fix_fields() (by that time Table_triggers_list::old_field/ new_field should point to proper array of Fields). It also binds Item_trigger_field to Table_triggers_list object for table of trigger which uses this item. */ void Item_trigger_field::setup_field(THD *thd, TABLE *table, GRANT_INFO *table_grant_info) { /* It is too early to mark fields used here, because before execution of statement that will invoke trigger other statements may use same TABLE object, so all such mark-up will be wiped out. So instead we do it in Table_triggers_list::mark_fields_used() method which is called during execution of these statements. */ enum_mark_columns save_mark_used_columns= thd->mark_used_columns; thd->mark_used_columns= MARK_COLUMNS_NONE; /* Try to find field by its name and if it will be found set field_idx properly. */ (void)find_field_in_table(thd, table, field_name, (uint) strlen(field_name), 0, &field_idx); thd->mark_used_columns= save_mark_used_columns; triggers= table->triggers; table_grants= table_grant_info; } bool Item_trigger_field::eq(const Item *item, bool binary_cmp) const { return item->type() == TRIGGER_FIELD_ITEM && row_version == ((Item_trigger_field *)item)->row_version && !my_strcasecmp(system_charset_info, field_name, ((Item_trigger_field *)item)->field_name); } void Item_trigger_field::set_required_privilege(bool rw) { /* Require SELECT and UPDATE privilege if this field will be read and set, and only UPDATE privilege for setting the field. */ want_privilege= (rw ? SELECT_ACL | UPDATE_ACL : UPDATE_ACL); } bool Item_trigger_field::set_value(THD *thd, sp_rcontext * /*ctx*/, Item **it) { Item *item= sp_prepare_func_item(thd, it); if (!item) return true; if (!fixed) { if (fix_fields(thd, NULL)) return true; } // NOTE: field->table->copy_blobs should be false here, but let's // remember the value at runtime to avoid subtle bugs. bool copy_blobs_saved= field->table->copy_blobs; field->table->copy_blobs= true; int err_code= item->save_in_field(field, 0); field->table->copy_blobs= copy_blobs_saved; field->set_has_explicit_value(); return err_code < 0; } bool Item_trigger_field::fix_fields(THD *thd, Item **items) { /* Since trigger is object tightly associated with TABLE object most of its set up can be performed during trigger loading i.e. trigger parsing! So we have little to do in fix_fields. :) */ DBUG_ASSERT(fixed == 0); /* Set field. */ if (field_idx != (uint)-1) { #ifndef NO_EMBEDDED_ACCESS_CHECKS /* Check access privileges for the subject table. We check privileges only in runtime. */ if (table_grants) { table_grants->want_privilege= want_privilege; if (check_grant_column(thd, table_grants, triggers->trigger_table->s->db.str, triggers->trigger_table->s->table_name.str, field_name, strlen(field_name), thd->security_ctx)) return TRUE; } #endif // NO_EMBEDDED_ACCESS_CHECKS field= (row_version == OLD_ROW) ? triggers->old_field[field_idx] : triggers->new_field[field_idx]; set_field(field); fixed= 1; return FALSE; } my_error(ER_BAD_FIELD_ERROR, MYF(0), field_name, (row_version == NEW_ROW) ? "NEW" : "OLD"); return TRUE; } void Item_trigger_field::print(String *str, enum_query_type query_type) { str->append((row_version == NEW_ROW) ? "NEW" : "OLD", 3); str->append('.'); str->append(field_name); } bool Item_trigger_field::check_vcol_func_processor(void *arg) { const char *ver= row_version == NEW_ROW ? "NEW." : "OLD."; return mark_unsupported_function(ver, field_name, arg, VCOL_IMPOSSIBLE); } void Item_trigger_field::cleanup() { want_privilege= original_privilege; /* Since special nature of Item_trigger_field we should not do most of things from Item_field::cleanup() or Item_ident::cleanup() here. */ Item::cleanup(); } Item_result item_cmp_type(Item_result a,Item_result b) { if (a == b) return a; if (a == ROW_RESULT || b == ROW_RESULT) return ROW_RESULT; if (a == TIME_RESULT || b == TIME_RESULT) return TIME_RESULT; if ((a == INT_RESULT || a == DECIMAL_RESULT) && (b == INT_RESULT || b == DECIMAL_RESULT)) return DECIMAL_RESULT; return REAL_RESULT; } void resolve_const_item(THD *thd, Item **ref, Item *comp_item) { Item *item= *ref; if (item->basic_const_item()) return; // Can't be better Item *new_item= NULL; Item_result res_type= item_cmp_type(comp_item, item); char *name= item->name; // Alloced on THD::mem_root MEM_ROOT *mem_root= thd->mem_root; switch (res_type) { case TIME_RESULT: { enum_field_types type= item->field_type_for_temporal_comparison(comp_item); longlong value= item->val_temporal_packed(type); if (item->null_value) new_item= new (mem_root) Item_null(thd, name); else { Item_cache_temporal *cache= new (mem_root) Item_cache_temporal(thd, type); cache->store_packed(value, item); new_item= cache; } break; } case STRING_RESULT: { char buff[MAX_FIELD_WIDTH]; String tmp(buff,sizeof(buff),&my_charset_bin),*result; result=item->val_str(&tmp); if (item->null_value) new_item= new (mem_root) Item_null(thd, name); else { uint length= result->length(); char *tmp_str= thd->strmake(result->ptr(), length); new_item= new (mem_root) Item_string(thd, name, tmp_str, length, result->charset()); } break; } case INT_RESULT: { longlong result=item->val_int(); uint length=item->max_length; bool null_value=item->null_value; new_item= (null_value ? (Item*) new (mem_root) Item_null(thd, name) : (Item*) new (mem_root) Item_int(thd, name, result, length)); break; } case ROW_RESULT: if (item->type() == Item::ROW_ITEM && comp_item->type() == Item::ROW_ITEM) { /* Substitute constants only in Item_row's. Don't affect other Items with ROW_RESULT (eg Item_singlerow_subselect). For such Items more optimal is to detect if it is constant and replace it with Item_row. This would optimize queries like this: SELECT * FROM t1 WHERE (a,b) = (SELECT a,b FROM t2 LIMIT 1); */ Item_row *item_row= (Item_row*) item; Item_row *comp_item_row= (Item_row*) comp_item; uint col; new_item= 0; /* If item and comp_item are both Item_row's and have same number of cols then process items in Item_row one by one. We can't ignore NULL values here as this item may be used with <=>, in which case NULL's are significant. */ DBUG_ASSERT(item->result_type() == comp_item->result_type()); DBUG_ASSERT(item_row->cols() == comp_item_row->cols()); col= item_row->cols(); while (col-- > 0) resolve_const_item(thd, item_row->addr(col), comp_item_row->element_index(col)); break; } /* Fallthrough */ case REAL_RESULT: { // It must REAL_RESULT double result= item->val_real(); uint length=item->max_length,decimals=item->decimals; bool null_value=item->null_value; new_item= (null_value ? (Item*) new (mem_root) Item_null(thd, name) : (Item*) new (mem_root) Item_float(thd, name, result, decimals, length)); break; } case DECIMAL_RESULT: { my_decimal decimal_value; my_decimal *result= item->val_decimal(&decimal_value); uint length= item->max_length, decimals= item->decimals; bool null_value= item->null_value; new_item= (null_value ? (Item*) new (mem_root) Item_null(thd, name) : (Item*) new (mem_root) Item_decimal(thd, name, result, length, decimals)); break; } } if (new_item) thd->change_item_tree(ref, new_item); } /** Compare the value stored in field with the expression from the query. @param field Field which the Item is stored in after conversion @param item Original expression from query @return Returns an integer greater than, equal to, or less than 0 if the value stored in the field is greater than, equal to, or less than the original Item. A 0 may also be returned if out of memory. @note We use this in the range optimizer/partition pruning, because in some cases we can't store the value in the field without some precision/character loss. We similarly use it to verify that expressions like BIGINT_FIELD is done correctly (as int/decimal/float according to literal type). @todo rewrite it to use Arg_comparator (currently it's a simplified and incomplete version of it) */ int stored_field_cmp_to_item(THD *thd, Field *field, Item *item) { Item_result res_type=item_cmp_type(field->result_type(), item->result_type()); /* We have to check field->cmp_type() instead of res_type, as result_type() - and thus res_type - can never be TIME_RESULT (yet). */ if (field->cmp_type() == TIME_RESULT) { MYSQL_TIME field_time, item_time, item_time2, *item_time_cmp= &item_time; if (field->type() == MYSQL_TYPE_TIME) { field->get_time(&field_time); item->get_time(&item_time); } else { field->get_date(&field_time, TIME_INVALID_DATES); item->get_date(&item_time, TIME_INVALID_DATES); if (item_time.time_type == MYSQL_TIMESTAMP_TIME) if (time_to_datetime(thd, &item_time, item_time_cmp= &item_time2)) return 1; } return my_time_compare(&field_time, item_time_cmp); } if (res_type == STRING_RESULT) { char item_buff[MAX_FIELD_WIDTH]; char field_buff[MAX_FIELD_WIDTH]; String item_tmp(item_buff,sizeof(item_buff),&my_charset_bin); String field_tmp(field_buff,sizeof(field_buff),&my_charset_bin); String *item_result= item->val_str(&item_tmp); /* Some implementations of Item::val_str(String*) actually modify the field Item::null_value, hence we can't check it earlier. */ if (item->null_value) return 0; String *field_result= field->val_str(&field_tmp); return sortcmp(field_result, item_result, field->charset()); } if (res_type == INT_RESULT) return 0; // Both are of type int if (res_type == DECIMAL_RESULT) { my_decimal item_buf, *item_val, field_buf, *field_val; item_val= item->val_decimal(&item_buf); if (item->null_value) return 0; field_val= field->val_decimal(&field_buf); return my_decimal_cmp(field_val, item_val); } /* The patch for Bug#13463415 started using this function for comparing BIGINTs. That uncovered a bug in Visual Studio 32bit optimized mode. Prefixing the auto variables with volatile fixes the problem.... */ volatile double result= item->val_real(); if (item->null_value) return 0; volatile double field_result= field->val_real(); if (field_result < result) return -1; else if (field_result > result) return 1; return 0; } /** Get a cache item of given type. @param item value to be cached @param type required type of cache @return cache item */ Item_cache* Item_cache::get_cache(THD *thd, const Item *item, const Item_result type, const enum_field_types f_type) { MEM_ROOT *mem_root= thd->mem_root; switch (type) { case INT_RESULT: return new (mem_root) Item_cache_int(thd, f_type); case REAL_RESULT: return new (mem_root) Item_cache_real(thd); case DECIMAL_RESULT: return new (mem_root) Item_cache_decimal(thd); case STRING_RESULT: return new (mem_root) Item_cache_str(thd, item); case ROW_RESULT: return new (mem_root) Item_cache_row(thd); case TIME_RESULT: return new (mem_root) Item_cache_temporal(thd, f_type); } return 0; // Impossible } void Item_cache::store(Item *item) { example= item; if (!item) null_value= TRUE; value_cached= FALSE; } void Item_cache::print(String *str, enum_query_type query_type) { if (example && // There is a cached item (query_type & QT_NO_DATA_EXPANSION)) // Caller is show-create-table { // Instead of "cache" or the cached value, print the cached item name example->print(str, query_type); return; } if (value_cached) { print_value(str); return; } str->append(STRING_WITH_LEN("(")); if (example) example->print(str, query_type); else Item::print(str, query_type); str->append(')'); } /** Assign to this cache NULL value if it is possible */ void Item_cache::set_null() { if (maybe_null) { null_value= TRUE; value_cached= TRUE; } } bool Item_cache_int::cache_value() { if (!example) return FALSE; value_cached= TRUE; value= example->val_int_result(); null_value_inside= null_value= example->null_value; unsigned_flag= example->unsigned_flag; return TRUE; } String *Item_cache_int::val_str(String *str) { DBUG_ASSERT(fixed == 1); if (!has_value()) return NULL; str->set_int(value, unsigned_flag, default_charset()); return str; } my_decimal *Item_cache_int::val_decimal(my_decimal *decimal_val) { DBUG_ASSERT(fixed == 1); if (!has_value()) return NULL; int2my_decimal(E_DEC_FATAL_ERROR, value, unsigned_flag, decimal_val); return decimal_val; } double Item_cache_int::val_real() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0.0; return (double) value; } longlong Item_cache_int::val_int() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0; return value; } int Item_cache_int::save_in_field(Field *field, bool no_conversions) { int error; if (!has_value()) return set_field_to_null_with_conversions(field, no_conversions); field->set_notnull(); error= field->store(value, unsigned_flag); return error ? error : field->table->in_use->is_error() ? 1 : 0; } Item *Item_cache_int::convert_to_basic_const_item(THD *thd) { Item *new_item; DBUG_ASSERT(value_cached || example != 0); if (!value_cached) cache_value(); new_item= null_value ? (Item*) new (thd->mem_root) Item_null(thd) : (Item*) new (thd->mem_root) Item_int(thd, val_int(), max_length); return new_item; } Item_cache_temporal::Item_cache_temporal(THD *thd, enum_field_types field_type_arg): Item_cache_int(thd, field_type_arg) { if (mysql_type_to_time_type(Item_cache_temporal::field_type()) == MYSQL_TIMESTAMP_ERROR) set_handler_by_field_type(MYSQL_TYPE_DATETIME); } longlong Item_cache_temporal::val_datetime_packed() { DBUG_ASSERT(fixed == 1); if ((!value_cached && !cache_value()) || null_value) { null_value= TRUE; return 0; } return value; } longlong Item_cache_temporal::val_time_packed() { DBUG_ASSERT(fixed == 1); DBUG_ASSERT(Item_cache_temporal::field_type() == MYSQL_TYPE_TIME); if ((!value_cached && !cache_value()) || null_value) { null_value= TRUE; return 0; } return value; } String *Item_cache_temporal::val_str(String *str) { DBUG_ASSERT(fixed == 1); if (!has_value()) { null_value= true; return NULL; } return val_string_from_date(str); } my_decimal *Item_cache_temporal::val_decimal(my_decimal *decimal_value) { DBUG_ASSERT(fixed == 1); if ((!value_cached && !cache_value()) || null_value) { null_value= true; return NULL; } return val_decimal_from_date(decimal_value); } longlong Item_cache_temporal::val_int() { DBUG_ASSERT(fixed == 1); if ((!value_cached && !cache_value()) || null_value) { null_value= true; return 0; } return val_int_from_date(); } double Item_cache_temporal::val_real() { DBUG_ASSERT(fixed == 1); if ((!value_cached && !cache_value()) || null_value) { null_value= true; return 0; } return val_real_from_date(); } bool Item_cache_temporal::cache_value() { if (!example) return false; value_cached= true; MYSQL_TIME ltime; uint fuzzydate= TIME_FUZZY_DATES | TIME_INVALID_DATES; if (Item_cache_temporal::field_type() == MYSQL_TYPE_TIME) fuzzydate|= TIME_TIME_ONLY; value= 0; if (!example->get_date_result(<ime, fuzzydate)) { if (ltime.time_type == MYSQL_TIMESTAMP_TIME && !(fuzzydate & TIME_TIME_ONLY) && convert_time_to_datetime(current_thd, <ime, fuzzydate)) return true; value= pack_time(<ime); } null_value_inside= null_value= example->null_value; return true; } bool Item_cache_temporal::get_date(MYSQL_TIME *ltime, ulonglong fuzzydate) { ErrConvInteger str(value); if (!has_value()) { bzero((char*) ltime,sizeof(*ltime)); return null_value= true; } unpack_time(value, ltime); ltime->time_type= mysql_type_to_time_type(field_type()); if (ltime->time_type == MYSQL_TIMESTAMP_TIME) { if (fuzzydate & TIME_TIME_ONLY) { ltime->hour+= (ltime->month*32+ltime->day)*24; ltime->month= ltime->day= 0; } else if (convert_time_to_datetime(current_thd, ltime, fuzzydate)) return true; } return 0; } int Item_cache_temporal::save_in_field(Field *field, bool no_conversions) { MYSQL_TIME ltime; if (get_date(<ime, 0)) return set_field_to_null_with_conversions(field, no_conversions); field->set_notnull(); int error= field->store_time_dec(<ime, decimals); return error ? error : field->table->in_use->is_error() ? 1 : 0; } void Item_cache_temporal::store_packed(longlong val_arg, Item *example_arg) { /* An explicit value is given, save it. */ store(example_arg); value_cached= true; value= val_arg; null_value= false; } Item *Item_cache_temporal::clone_item(THD *thd) { Item_cache_temporal *item= new (thd->mem_root) Item_cache_temporal(thd, Item_cache_temporal::field_type()); item->store_packed(value, example); return item; } Item *Item_cache_temporal::convert_to_basic_const_item(THD *thd) { Item *new_item; DBUG_ASSERT(value_cached || example != 0); if (!value_cached) cache_value(); if (null_value) new_item= (Item*) new (thd->mem_root) Item_null(thd); else { MYSQL_TIME ltime; if (Item_cache_temporal::field_type() == MYSQL_TYPE_TIME) { unpack_time(val_time_packed(), <ime); new_item= (Item*) new (thd->mem_root) Item_time_literal(thd, <ime, decimals); } else { unpack_time(val_datetime_packed(), <ime); new_item= (Item*) new (thd->mem_root) Item_datetime_literal(thd, <ime, decimals); } } return new_item; } bool Item_cache_real::cache_value() { if (!example) return FALSE; value_cached= TRUE; value= example->val_result(); null_value_inside= null_value= example->null_value; return TRUE; } double Item_cache_real::val_real() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0.0; return value; } longlong Item_cache_real::val_int() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0; return Converter_double_to_longlong(value, unsigned_flag).result(); } String* Item_cache_real::val_str(String *str) { DBUG_ASSERT(fixed == 1); if (!has_value()) return NULL; str->set_real(value, decimals, default_charset()); return str; } my_decimal *Item_cache_real::val_decimal(my_decimal *decimal_val) { DBUG_ASSERT(fixed == 1); if (!has_value()) return NULL; double2my_decimal(E_DEC_FATAL_ERROR, value, decimal_val); return decimal_val; } Item *Item_cache_real::convert_to_basic_const_item(THD *thd) { Item *new_item; DBUG_ASSERT(value_cached || example != 0); if (!value_cached) cache_value(); new_item= null_value ? (Item*) new (thd->mem_root) Item_null(thd) : (Item*) new (thd->mem_root) Item_float(thd, val_real(), decimals); return new_item; } bool Item_cache_decimal::cache_value() { if (!example) return FALSE; value_cached= TRUE; my_decimal *val= example->val_decimal_result(&decimal_value); if (!(null_value_inside= null_value= example->null_value) && val != &decimal_value) my_decimal2decimal(val, &decimal_value); return TRUE; } double Item_cache_decimal::val_real() { DBUG_ASSERT(fixed); double res; if (!has_value()) return 0.0; my_decimal2double(E_DEC_FATAL_ERROR, &decimal_value, &res); return res; } longlong Item_cache_decimal::val_int() { DBUG_ASSERT(fixed); longlong res; if (!has_value()) return 0; my_decimal2int(E_DEC_FATAL_ERROR, &decimal_value, unsigned_flag, &res); return res; } String* Item_cache_decimal::val_str(String *str) { DBUG_ASSERT(fixed); if (!has_value()) return NULL; my_decimal_round(E_DEC_FATAL_ERROR, &decimal_value, decimals, FALSE, &decimal_value); my_decimal2string(E_DEC_FATAL_ERROR, &decimal_value, 0, 0, 0, str); return str; } my_decimal *Item_cache_decimal::val_decimal(my_decimal *val) { DBUG_ASSERT(fixed); if (!has_value()) return NULL; return &decimal_value; } Item *Item_cache_decimal::convert_to_basic_const_item(THD *thd) { Item *new_item; DBUG_ASSERT(value_cached || example != 0); if (!value_cached) cache_value(); if (null_value) new_item= (Item*) new (thd->mem_root) Item_null(thd); else { my_decimal decimal_value; my_decimal *result= val_decimal(&decimal_value); new_item= (Item*) new (thd->mem_root) Item_decimal(thd, result); } return new_item; } bool Item_cache_str::cache_value() { if (!example) { DBUG_ASSERT(value_cached == FALSE); return FALSE; } value_cached= TRUE; value_buff.set(buffer, sizeof(buffer), example->collation.collation); value= example->str_result(&value_buff); if ((null_value= null_value_inside= example->null_value)) value= 0; else if (value != &value_buff) { /* We copy string value to avoid changing value if 'item' is table field in queries like following (where t1.c is varchar): select a, (select a,b,c from t1 where t1.a=t2.a) = ROW(a,2,'a'), (select c from t1 where a=t2.a) from t2; */ value_buff.copy(*value); value= &value_buff; } else value_buff.copy(); return TRUE; } double Item_cache_str::val_real() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0.0; return value ? double_from_string_with_check(value) : 0.0; } longlong Item_cache_str::val_int() { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0; return value ? longlong_from_string_with_check(value) : 0; } String* Item_cache_str::val_str(String *str) { DBUG_ASSERT(fixed == 1); if (!has_value()) return 0; return value; } my_decimal *Item_cache_str::val_decimal(my_decimal *decimal_val) { DBUG_ASSERT(fixed == 1); if (!has_value()) return NULL; return value ? decimal_from_string_with_check(decimal_val, value) : 0; } int Item_cache_str::save_in_field(Field *field, bool no_conversions) { if (!has_value()) return set_field_to_null_with_conversions(field, no_conversions); int res= Item_cache::save_in_field(field, no_conversions); return (is_varbinary && field->type() == MYSQL_TYPE_STRING && value->length() < field->field_length) ? 1 : res; } bool Item_cache_row::allocate(THD *thd, uint num) { item_count= num; return (!(values= (Item_cache **) thd->calloc(sizeof(Item_cache *)*item_count))); } Item *Item_cache_str::convert_to_basic_const_item(THD *thd) { Item *new_item; DBUG_ASSERT(value_cached || example != 0); if (!value_cached) cache_value(); if (null_value) new_item= (Item*) new (thd->mem_root) Item_null(thd); else { char buff[MAX_FIELD_WIDTH]; String tmp(buff, sizeof(buff), value->charset()); String *result= val_str(&tmp); uint length= result->length(); char *tmp_str= thd->strmake(result->ptr(), length); new_item= new (thd->mem_root) Item_string(thd, tmp_str, length, result->charset()); } return new_item; } bool Item_cache_row::setup(THD *thd, Item *item) { example= item; null_value= true; if (!values && allocate(thd, item->cols())) return 1; for (uint i= 0; i < item_count; i++) { Item *el= item->element_index(i); Item_cache *tmp; if (!(tmp= values[i]= Item_cache::get_cache(thd, el))) return 1; tmp->setup(thd, el); } return 0; } void Item_cache_row::store(Item * item) { example= item; if (!item) { null_value= TRUE; return; } for (uint i= 0; i < item_count; i++) values[i]->store(item->element_index(i)); } bool Item_cache_row::cache_value() { if (!example) return FALSE; value_cached= TRUE; null_value= TRUE; null_value_inside= false; example->bring_value(); /* For Item_cache_row null_value is set to TRUE only when ALL the values inside the cache are NULL */ for (uint i= 0; i < item_count; i++) { values[i]->cache_value(); null_value&= values[i]->null_value; null_value_inside|= values[i]->null_value; } return TRUE; } void Item_cache_row::illegal_method_call(const char *method) { DBUG_ENTER("Item_cache_row::illegal_method_call"); DBUG_PRINT("error", ("!!! %s method was called for row item", method)); DBUG_ASSERT(0); my_error(ER_OPERAND_COLUMNS, MYF(0), 1); DBUG_VOID_RETURN; } bool Item_cache_row::check_cols(uint c) { if (c != item_count) { my_error(ER_OPERAND_COLUMNS, MYF(0), c); return 1; } return 0; } bool Item_cache_row::null_inside() { for (uint i= 0; i < item_count; i++) { if (values[i]->cols() > 1) { if (values[i]->null_inside()) return 1; } else { values[i]->update_null_value(); if (values[i]->null_value) return 1; } } return 0; } void Item_cache_row::bring_value() { if (!example) return; example->bring_value(); null_value= example->null_value; for (uint i= 0; i < item_count; i++) values[i]->bring_value(); } /** Assign to this cache NULL value if it is possible */ void Item_cache_row::set_null() { Item_cache::set_null(); if (!values) return; for (uint i= 0; i < item_count; i++) values[i]->set_null(); }; Item_type_holder::Item_type_holder(THD *thd, Item *item) :Item(thd, item), Type_handler_hybrid_real_field_type(get_real_type(item)), enum_set_typelib(0), geometry_type(Field::GEOM_GEOMETRY) { DBUG_ASSERT(item->fixed); maybe_null= item->maybe_null; collation.set(item->collation); get_full_info(item); /** Field::result_merge_type(real_field_type()) should be equal to result_type(), with one exception when "this" is a Item_field for a BIT field: - Field_bit::result_type() returns INT_RESULT, so does its Item_field. - Field::result_merge_type(MYSQL_TYPE_BIT) returns STRING_RESULT. Perhaps we need a new method in Type_handler to cover these type merging rules for UNION. */ DBUG_ASSERT(real_field_type() == MYSQL_TYPE_BIT || Item_type_holder::result_type() == Field::result_merge_type(Item_type_holder::real_field_type())); /* fix variable decimals which always is NOT_FIXED_DEC */ if (Field::result_merge_type(real_field_type()) == INT_RESULT) decimals= 0; prev_decimal_int_part= item->decimal_int_part(); #ifdef HAVE_SPATIAL if (item->field_type() == MYSQL_TYPE_GEOMETRY) geometry_type= item->get_geometry_type(); #endif /* HAVE_SPATIAL */ } /** Find real field type of item. @return type of field which should be created to store item value */ enum_field_types Item_type_holder::get_real_type(Item *item) { if (item->type() == REF_ITEM) item= item->real_item(); switch(item->type()) { case FIELD_ITEM: { /* Item_field::field_type ask Field_type() but sometimes field return a different type, like for enum/set, so we need to ask real type. */ Field *field= ((Item_field *) item)->field; enum_field_types type= field->real_type(); if (field->is_created_from_null_item) return MYSQL_TYPE_NULL; /* work around about varchar type field detection */ if (type == MYSQL_TYPE_STRING && field->type() == MYSQL_TYPE_VAR_STRING) return MYSQL_TYPE_VAR_STRING; return type; } case SUM_FUNC_ITEM: { /* Argument of aggregate function sometimes should be asked about field type */ Item_sum *item_sum= (Item_sum *) item; if (item_sum->keep_field_type()) return get_real_type(item_sum->get_arg(0)); break; } case FUNC_ITEM: if (((Item_func *) item)->functype() == Item_func::GUSERVAR_FUNC) { /* There are work around of problem with changing variable type on the fly and variable always report "string" as field type to get acceptable information for client in send_field, so we make field type from expression type. */ switch (item->result_type()) { case STRING_RESULT: return MYSQL_TYPE_VARCHAR; case INT_RESULT: return MYSQL_TYPE_LONGLONG; case REAL_RESULT: return MYSQL_TYPE_DOUBLE; case DECIMAL_RESULT: return MYSQL_TYPE_NEWDECIMAL; case ROW_RESULT: case TIME_RESULT: DBUG_ASSERT(0); return MYSQL_TYPE_VARCHAR; } } break; case TYPE_HOLDER: /* Item_type_holder and Item_blob should not appear in this context. In case they for some reasons do, returning field_type() is wrong anyway. They must return Item_type_holder::real_field_type() instead, to make the code in sql_type.cc and sql_type.h happy, as it expectes Field::real_type()-compatible rather than Field::field_type()-compatible valies in some places, and may in the future add some asserts preventing use of field_type() instead of real_type() and the other way around. */ DBUG_ASSERT(0); default: break; } return item->field_type(); } /** Find field type which can carry current Item_type_holder type and type of given Item. @param thd thread handler @param item given item to join its parameters with this item ones @retval TRUE error - types are incompatible @retval FALSE OK */ bool Item_type_holder::join_types(THD *thd, Item *item) { uint max_length_orig= max_length; uint decimals_orig= decimals; DBUG_ENTER("Item_type_holder::join_types"); DBUG_PRINT("info:", ("was type %d len %d, dec %d name %s", real_field_type(), max_length, decimals, (name ? name : ""))); DBUG_PRINT("info:", ("in type %d len %d, dec %d", get_real_type(item), item->max_length, item->decimals)); set_handler_by_real_type(Field::field_type_merge(real_field_type(), get_real_type(item))); { uint item_decimals= item->decimals; /* fix variable decimals which always is NOT_FIXED_DEC */ if (Field::result_merge_type(real_field_type()) == INT_RESULT) item_decimals= 0; decimals= MY_MAX(decimals, item_decimals); } if (Item_type_holder::field_type() == FIELD_TYPE_GEOMETRY) geometry_type= Field_geom::geometry_type_merge(geometry_type, item->get_geometry_type()); if (Field::result_merge_type(real_field_type()) == DECIMAL_RESULT) { collation.set_numeric(); decimals= MY_MIN(MY_MAX(decimals, item->decimals), DECIMAL_MAX_SCALE); int item_int_part= item->decimal_int_part(); int item_prec = MY_MAX(prev_decimal_int_part, item_int_part) + decimals; int precision= MY_MIN(item_prec, DECIMAL_MAX_PRECISION); unsigned_flag&= item->unsigned_flag; max_length= my_decimal_precision_to_length_no_truncation(precision, decimals, unsigned_flag); } switch (Field::result_merge_type(real_field_type())) { case STRING_RESULT: { const char *old_cs, *old_derivation; uint32 old_max_chars= max_length / collation.collation->mbmaxlen; old_cs= collation.collation->name; old_derivation= collation.derivation_name(); if (collation.aggregate(item->collation, MY_COLL_ALLOW_CONV)) { my_error(ER_CANT_AGGREGATE_2COLLATIONS, MYF(0), old_cs, old_derivation, item->collation.collation->name, item->collation.derivation_name(), "UNION"); DBUG_RETURN(TRUE); } /* To figure out max_length, we have to take into account possible expansion of the size of the values because of character set conversions. */ if (collation.collation != &my_charset_bin) { max_length= MY_MAX(old_max_chars * collation.collation->mbmaxlen, display_length(item) / item->collation.collation->mbmaxlen * collation.collation->mbmaxlen); } else set_if_bigger(max_length, display_length(item)); break; } case REAL_RESULT: { if (decimals != NOT_FIXED_DEC) { /* For FLOAT(M,D)/DOUBLE(M,D) do not change precision if both fields have the same M and D */ if (item->max_length != max_length_orig || item->decimals != decimals_orig) { int delta1= max_length_orig - decimals_orig; int delta2= item->max_length - item->decimals; max_length= MY_MAX(delta1, delta2) + decimals; if (Item_type_holder::real_field_type() == MYSQL_TYPE_FLOAT && max_length > FLT_DIG + 2) { max_length= MAX_FLOAT_STR_LENGTH; decimals= NOT_FIXED_DEC; } else if (Item_type_holder::real_field_type() == MYSQL_TYPE_DOUBLE && max_length > DBL_DIG + 2) { max_length= MAX_DOUBLE_STR_LENGTH; decimals= NOT_FIXED_DEC; } } } else max_length= (Item_type_holder::field_type() == MYSQL_TYPE_FLOAT) ? FLT_DIG+6 : DBL_DIG+7; break; } default: if (real_field_type() == MYSQL_TYPE_YEAR) max_length= MY_MAX(max_length, item->max_length); else max_length= MY_MAX(max_length, display_length(item)); }; maybe_null|= item->maybe_null; get_full_info(item); /* Remember decimal integer part to be used in DECIMAL_RESULT handleng */ prev_decimal_int_part= decimal_int_part(); DBUG_PRINT("info", ("become type: %d len: %u dec: %u", (int) real_field_type(), max_length, (uint) decimals)); DBUG_RETURN(FALSE); } /** Calculate length for merging result for given Item type. @param item Item for length detection @return length */ uint32 Item_type_holder::display_length(Item *item) { if (item->type() == Item::FIELD_ITEM) return ((Item_field *)item)->max_disp_length(); switch (item->field_type()) { case MYSQL_TYPE_DECIMAL: case MYSQL_TYPE_TIMESTAMP: case MYSQL_TYPE_DATE: case MYSQL_TYPE_TIME: case MYSQL_TYPE_DATETIME: case MYSQL_TYPE_YEAR: case MYSQL_TYPE_NEWDATE: case MYSQL_TYPE_VARCHAR: case MYSQL_TYPE_BIT: case MYSQL_TYPE_NEWDECIMAL: case MYSQL_TYPE_ENUM: case MYSQL_TYPE_SET: case MYSQL_TYPE_TINY_BLOB: case MYSQL_TYPE_MEDIUM_BLOB: case MYSQL_TYPE_LONG_BLOB: case MYSQL_TYPE_BLOB: case MYSQL_TYPE_VAR_STRING: case MYSQL_TYPE_STRING: case MYSQL_TYPE_GEOMETRY: return item->max_length; case MYSQL_TYPE_TINY: return 4; case MYSQL_TYPE_SHORT: return 6; case MYSQL_TYPE_LONG: return MY_INT32_NUM_DECIMAL_DIGITS; case MYSQL_TYPE_FLOAT: return 25; case MYSQL_TYPE_DOUBLE: return 53; case MYSQL_TYPE_NULL: return 0; case MYSQL_TYPE_LONGLONG: return 20; case MYSQL_TYPE_INT24: return 8; default: DBUG_ASSERT(0); // we should never go there return 0; } } /** Make temporary table field according collected information about type of UNION result. @param table temporary table for which we create fields @return created field */ Field *Item_type_holder::make_field_by_type(TABLE *table) { /* The field functions defines a field to be not null if null_ptr is not 0 */ uchar *null_ptr= maybe_null ? (uchar*) "" : 0; Field *field; switch (Item_type_holder::real_field_type()) { case MYSQL_TYPE_ENUM: DBUG_ASSERT(enum_set_typelib); field= new Field_enum((uchar *) 0, max_length, null_ptr, 0, Field::NONE, name, get_enum_pack_length(enum_set_typelib->count), enum_set_typelib, collation.collation); if (field) field->init(table); return field; case MYSQL_TYPE_SET: DBUG_ASSERT(enum_set_typelib); field= new Field_set((uchar *) 0, max_length, null_ptr, 0, Field::NONE, name, get_set_pack_length(enum_set_typelib->count), enum_set_typelib, collation.collation); if (field) field->init(table); return field; case MYSQL_TYPE_NULL: return make_string_field(table); default: break; } return tmp_table_field_from_field_type(table, false, true); } /** Get full information from Item about enum/set fields to be able to create them later. @param item Item for information collection */ void Item_type_holder::get_full_info(Item *item) { if (Item_type_holder::real_field_type() == MYSQL_TYPE_ENUM || Item_type_holder::real_field_type() == MYSQL_TYPE_SET) { if (item->type() == Item::SUM_FUNC_ITEM && (((Item_sum*)item)->sum_func() == Item_sum::MAX_FUNC || ((Item_sum*)item)->sum_func() == Item_sum::MIN_FUNC)) item = ((Item_sum*)item)->get_arg(0); /* We can have enum/set type after merging only if we have one enum|set field (or MIN|MAX(enum|set field)) and number of NULL fields */ DBUG_ASSERT((enum_set_typelib && get_real_type(item) == MYSQL_TYPE_NULL) || (!enum_set_typelib && item->real_item()->type() == Item::FIELD_ITEM && (get_real_type(item->real_item()) == MYSQL_TYPE_ENUM || get_real_type(item->real_item()) == MYSQL_TYPE_SET) && ((Field_enum*)((Item_field *) item->real_item())->field)->typelib)); if (!enum_set_typelib) { enum_set_typelib= ((Field_enum*)((Item_field *) item->real_item())->field)->typelib; } } } double Item_type_holder::val_real() { DBUG_ASSERT(0); // should never be called return 0.0; } longlong Item_type_holder::val_int() { DBUG_ASSERT(0); // should never be called return 0; } my_decimal *Item_type_holder::val_decimal(my_decimal *) { DBUG_ASSERT(0); // should never be called return 0; } String *Item_type_holder::val_str(String*) { DBUG_ASSERT(0); // should never be called return 0; } void Item_result_field::cleanup() { DBUG_ENTER("Item_result_field::cleanup()"); Item::cleanup(); result_field= 0; DBUG_VOID_RETURN; } /** Dummy error processor used by default by Name_resolution_context. @note do nothing */ void dummy_error_processor(THD *thd, void *data) {} /** Wrapper of hide_view_error call for Name_resolution_context error processor. @note hide view underlying tables details in error messages */ void view_error_processor(THD *thd, void *data) { ((TABLE_LIST *)data)->hide_view_error(thd); } st_select_lex *Item_ident::get_depended_from() const { st_select_lex *dep; if ((dep= depended_from)) for ( ; dep->merged_into; dep= dep->merged_into) ; return dep; } table_map Item_ref::used_tables() const { return get_depended_from() ? OUTER_REF_TABLE_BIT : (*ref)->used_tables(); } void Item_ref::update_used_tables() { if (!get_depended_from()) (*ref)->update_used_tables(); } void Item_direct_view_ref::update_used_tables() { set_null_ref_table(); Item_direct_ref::update_used_tables(); } table_map Item_direct_view_ref::used_tables() const { DBUG_ASSERT(fixed); if (get_depended_from()) return OUTER_REF_TABLE_BIT; if (view->is_merged_derived() || view->merged || !view->table) { table_map used= (*ref)->used_tables(); return (used ? used : ((null_ref_table != NO_NULL_TABLE) ? null_ref_table->map : (table_map)0 )); } return view->table->map; } table_map Item_direct_view_ref::not_null_tables() const { if (get_depended_from()) return 0; if (!( view->merged || !view->table)) return view->table->map; TABLE *tab= get_null_ref_table(); if (tab == NO_NULL_TABLE || (*ref)->used_tables()) return (*ref)->not_null_tables(); return get_null_ref_table()->map; } /* we add RAND_TABLE_BIT to prevent moving this item from HAVING to WHERE */ table_map Item_ref_null_helper::used_tables() const { return (get_depended_from() ? OUTER_REF_TABLE_BIT : (*ref)->used_tables() | RAND_TABLE_BIT); } #ifndef DBUG_OFF /* Debugger help function */ static char dbug_item_print_buf[2048]; const char *dbug_print_item(Item *item) { char *buf= dbug_item_print_buf; String str(buf, sizeof(dbug_item_print_buf), &my_charset_bin); str.length(0); if (!item) return "(Item*)NULL"; THD *thd= current_thd; ulonglong save_option_bits= thd->variables.option_bits; thd->variables.option_bits &= ~OPTION_QUOTE_SHOW_CREATE; item->print(&str, QT_EXPLAIN); thd->variables.option_bits= save_option_bits; if (str.c_ptr_safe() == buf) return buf; else return "Couldn't fit into buffer"; } const char *dbug_print_select(SELECT_LEX *sl) { char *buf= dbug_item_print_buf; String str(buf, sizeof(dbug_item_print_buf), &my_charset_bin); str.length(0); if (!sl) return "(SELECT_LEX*)NULL"; THD *thd= current_thd; ulonglong save_option_bits= thd->variables.option_bits; thd->variables.option_bits &= ~OPTION_QUOTE_SHOW_CREATE; sl->print(thd, &str, QT_EXPLAIN); thd->variables.option_bits= save_option_bits; if (str.c_ptr() == buf) return buf; else return "Couldn't fit into buffer"; } const char *dbug_print_unit(SELECT_LEX_UNIT *un) { char *buf= dbug_item_print_buf; String str(buf, sizeof(dbug_item_print_buf), &my_charset_bin); str.length(0); if (!un) return "(SELECT_LEX_UNIT*)NULL"; THD *thd= current_thd; ulonglong save_option_bits= thd->variables.option_bits; thd->variables.option_bits &= ~OPTION_QUOTE_SHOW_CREATE; un->print(&str, QT_EXPLAIN); thd->variables.option_bits= save_option_bits; if (str.c_ptr() == buf) return buf; else return "Couldn't fit into buffer"; } const char *dbug_print(Item *x) { return dbug_print_item(x); } const char *dbug_print(SELECT_LEX *x) { return dbug_print_select(x); } const char *dbug_print(SELECT_LEX_UNIT *x) { return dbug_print_unit(x); } #endif /*DBUG_OFF*/ bool Item_field::excl_dep_on_table(table_map tab_map) { return used_tables() == tab_map || (item_equal && (item_equal->used_tables() & tab_map)); } bool Item_field::excl_dep_on_grouping_fields(st_select_lex *sel) { return find_matching_grouping_field(this, sel) != NULL; } void Item::register_in(THD *thd) { next= thd->free_list; thd->free_list= this; }