/* Copyright (C) 2000 MySQL AB & MySQL Finland AB & TCX DataKonsult AB 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; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /* Basic functions needed by many modules */ #include "mysql_priv.h" #include "sql_select.h" #include "sp_head.h" #include "sp.h" #include "sql_trigger.h" #include <m_ctype.h> #include <my_dir.h> #include <hash.h> #ifdef __WIN__ #include <io.h> #endif TABLE *unused_tables; /* Used by mysql_test */ HASH open_cache; /* Used by mysql_test */ static int open_unireg_entry(THD *thd, TABLE *entry, const char *db, const char *name, const char *alias, TABLE_LIST *table_list, MEM_ROOT *mem_root); static void free_cache_entry(TABLE *entry); static void mysql_rm_tmp_tables(void); static bool open_new_frm(THD *thd, const char *path, const char *alias, const char *db, const char *table_name, uint db_stat, uint prgflag, uint ha_open_flags, TABLE *outparam, TABLE_LIST *table_desc, MEM_ROOT *mem_root); extern "C" byte *table_cache_key(const byte *record,uint *length, my_bool not_used __attribute__((unused))) { TABLE *entry=(TABLE*) record; *length= entry->s->key_length; return (byte*) entry->s->table_cache_key; } bool table_cache_init(void) { mysql_rm_tmp_tables(); return hash_init(&open_cache, &my_charset_bin, table_cache_size+16, 0, 0,table_cache_key, (hash_free_key) free_cache_entry, 0) != 0; } void table_cache_free(void) { DBUG_ENTER("table_cache_free"); close_cached_tables((THD*) 0,0,(TABLE_LIST*) 0); if (!open_cache.records) // Safety first hash_free(&open_cache); DBUG_VOID_RETURN; } uint cached_tables(void) { return open_cache.records; } #ifdef EXTRA_DEBUG static void check_unused(void) { uint count=0,idx=0; TABLE *cur_link,*start_link; if ((start_link=cur_link=unused_tables)) { do { if (cur_link != cur_link->next->prev || cur_link != cur_link->prev->next) { DBUG_PRINT("error",("Unused_links aren't linked properly")); /* purecov: inspected */ return; /* purecov: inspected */ } } while (count++ < open_cache.records && (cur_link=cur_link->next) != start_link); if (cur_link != start_link) { DBUG_PRINT("error",("Unused_links aren't connected")); /* purecov: inspected */ } } for (idx=0 ; idx < open_cache.records ; idx++) { TABLE *entry=(TABLE*) hash_element(&open_cache,idx); if (!entry->in_use) count--; } if (count != 0) { DBUG_PRINT("error",("Unused_links doesn't match open_cache: diff: %d", /* purecov: inspected */ count)); /* purecov: inspected */ } } #else #define check_unused() #endif /* Create a list for all open tables matching SQL expression SYNOPSIS list_open_tables() thd Thread THD wild SQL like expression NOTES One gets only a list of tables for which one has any kind of privilege. db and table names are allocated in result struct, so one doesn't need a lock on LOCK_open when traversing the return list. RETURN VALUES NULL Error (Probably OOM) # Pointer to list of names of open tables. */ OPEN_TABLE_LIST *list_open_tables(THD *thd, const char *db, const char *wild) { int result = 0; OPEN_TABLE_LIST **start_list, *open_list; TABLE_LIST table_list; DBUG_ENTER("list_open_tables"); VOID(pthread_mutex_lock(&LOCK_open)); bzero((char*) &table_list,sizeof(table_list)); start_list= &open_list; open_list=0; for (uint idx=0 ; result == 0 && idx < open_cache.records; idx++) { OPEN_TABLE_LIST *table; TABLE *entry=(TABLE*) hash_element(&open_cache,idx); TABLE_SHARE *share= entry->s; DBUG_ASSERT(share->table_name != 0); if ((!share->table_name)) // To be removed continue; // Shouldn't happen if (db && my_strcasecmp(system_charset_info, db, share->db)) continue; if (wild && wild_compare(share->table_name,wild,0)) continue; /* Check if user has SELECT privilege for any column in the table */ table_list.db= (char*) share->db; table_list.table_name= (char*) share->table_name; table_list.grant.privilege=0; if (check_table_access(thd,SELECT_ACL | EXTRA_ACL,&table_list,1)) continue; /* need to check if we haven't already listed it */ for (table= open_list ; table ; table=table->next) { if (!strcmp(table->table,share->table_name) && !strcmp(table->db,entry->s->db)) { if (entry->in_use) table->in_use++; if (entry->locked_by_name) table->locked++; break; } } if (table) continue; if (!(*start_list = (OPEN_TABLE_LIST *) sql_alloc(sizeof(**start_list)+share->key_length))) { open_list=0; // Out of memory break; } strmov((*start_list)->table= strmov(((*start_list)->db= (char*) ((*start_list)+1)), entry->s->db)+1, entry->s->table_name); (*start_list)->in_use= entry->in_use ? 1 : 0; (*start_list)->locked= entry->locked_by_name ? 1 : 0; start_list= &(*start_list)->next; *start_list=0; } VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(open_list); } /***************************************************************************** * Functions to free open table cache ****************************************************************************/ void intern_close_table(TABLE *table) { // Free all structures free_io_cache(table); delete table->triggers; if (table->file) VOID(closefrm(table)); // close file } /* Remove table from the open table cache SYNOPSIS free_cache_entry() table Table to remove NOTE We need to have a lock on LOCK_open when calling this */ static void free_cache_entry(TABLE *table) { DBUG_ENTER("free_cache_entry"); safe_mutex_assert_owner(&LOCK_open); intern_close_table(table); if (!table->in_use) { table->next->prev=table->prev; /* remove from used chain */ table->prev->next=table->next; if (table == unused_tables) { unused_tables=unused_tables->next; if (table == unused_tables) unused_tables=0; } check_unused(); // consisty check } my_free((gptr) table,MYF(0)); DBUG_VOID_RETURN; } /* Free resources allocated by filesort() and read_record() */ void free_io_cache(TABLE *table) { DBUG_ENTER("free_io_cache"); if (table->sort.io_cache) { close_cached_file(table->sort.io_cache); my_free((gptr) table->sort.io_cache,MYF(0)); table->sort.io_cache=0; } DBUG_VOID_RETURN; } /* Close all tables which aren't in use by any thread THD can be NULL, but then if_wait_for_refresh must be FALSE and tables must be NULL. */ bool close_cached_tables(THD *thd, bool if_wait_for_refresh, TABLE_LIST *tables) { bool result=0; DBUG_ENTER("close_cached_tables"); DBUG_ASSERT(thd || (!if_wait_for_refresh && !tables)); VOID(pthread_mutex_lock(&LOCK_open)); if (!tables) { while (unused_tables) { #ifdef EXTRA_DEBUG if (hash_delete(&open_cache,(byte*) unused_tables)) printf("Warning: Couldn't delete open table from hash\n"); #else VOID(hash_delete(&open_cache,(byte*) unused_tables)); #endif } refresh_version++; // Force close of open tables } else { bool found=0; for (TABLE_LIST *table= tables; table; table= table->next_local) { if (remove_table_from_cache(thd, table->db, table->table_name, RTFC_OWNED_BY_THD_FLAG)) found=1; } if (!found) if_wait_for_refresh=0; // Nothing to wait for } #ifndef EMBEDDED_LIBRARY if (!tables) kill_delayed_threads(); #endif if (if_wait_for_refresh) { /* If there is any table that has a lower refresh_version, wait until this is closed (or this thread is killed) before returning */ thd->mysys_var->current_mutex= &LOCK_open; thd->mysys_var->current_cond= &COND_refresh; thd->proc_info="Flushing tables"; close_old_data_files(thd,thd->open_tables,1,1); mysql_ha_flush(thd, tables, MYSQL_HA_REOPEN_ON_USAGE | MYSQL_HA_FLUSH_ALL, TRUE); bool found=1; /* Wait until all threads has closed all the tables we had locked */ DBUG_PRINT("info", ("Waiting for other threads to close their open tables")); while (found && ! thd->killed) { found=0; for (uint idx=0 ; idx < open_cache.records ; idx++) { TABLE *table=(TABLE*) hash_element(&open_cache,idx); if ((table->s->version) < refresh_version && table->db_stat) { found=1; DBUG_PRINT("signal", ("Waiting for COND_refresh")); pthread_cond_wait(&COND_refresh,&LOCK_open); break; } } } /* No other thread has the locked tables open; reopen them and get the old locks. This should always succeed (unless some external process has removed the tables) */ thd->in_lock_tables=1; result=reopen_tables(thd,1,1); thd->in_lock_tables=0; /* Set version for table */ for (TABLE *table=thd->open_tables; table ; table= table->next) table->s->version= refresh_version; } VOID(pthread_mutex_unlock(&LOCK_open)); if (if_wait_for_refresh) { pthread_mutex_lock(&thd->mysys_var->mutex); thd->mysys_var->current_mutex= 0; thd->mysys_var->current_cond= 0; thd->proc_info=0; pthread_mutex_unlock(&thd->mysys_var->mutex); } DBUG_RETURN(result); } /* Mark all tables in the list which were used by current substatement as free for reuse. SYNOPSIS mark_used_tables_as_free_for_reuse() thd - thread context table - head of the list of tables DESCRIPTION Marks all tables in the list which were used by current substatement (they are marked by its query_id) as free for reuse. NOTE The reason we reset query_id is that it's not enough to just test if table->query_id != thd->query_id to know if a table is in use. For example SELECT f1_that_uses_t1() FROM t1; In f1_that_uses_t1() we will see one instance of t1 where query_id is set to query_id of original query. */ static void mark_used_tables_as_free_for_reuse(THD *thd, TABLE *table) { for (; table ; table= table->next) if (table->query_id == thd->query_id) table->query_id= 0; } /* Close all tables used by the current substatement, or all tables used by this thread if we are on the upper level. SYNOPSIS close_thread_tables() thd Thread handler lock_in_use Set to 1 (0 = default) if caller has a lock on LOCK_open skip_derived Set to 1 (0 = default) if we should not free derived tables. stopper When closing tables from thd->open_tables(->next)*, don't close/remove tables starting from stopper. IMPLEMENTATION Unlocks tables and frees derived tables. Put all normal tables used by thread in free list. When in prelocked mode it will only close/mark as free for reuse tables opened by this substatement, it will also check if we are closing tables after execution of complete query (i.e. we are on upper level) and will leave prelocked mode if needed. */ void close_thread_tables(THD *thd, bool lock_in_use, bool skip_derived) { bool found_old_table; prelocked_mode_type prelocked_mode= thd->prelocked_mode; DBUG_ENTER("close_thread_tables"); /* We are assuming here that thd->derived_tables contains ONLY derived tables for this substatement. i.e. instead of approach which uses query_id matching for determining which of the derived tables belong to this substatement we rely on the ability of substatements to save/restore thd->derived_tables during their execution. TODO: Probably even better approach is to simply associate list of derived tables with (sub-)statement instead of thread and destroy them at the end of its execution. */ if (thd->derived_tables && !skip_derived) { TABLE *table, *next; /* Close all derived tables generated in queries like SELECT * FROM (SELECT * FROM t1) */ for (table= thd->derived_tables ; table ; table= next) { next= table->next; free_tmp_table(thd, table); } thd->derived_tables= 0; } if (prelocked_mode) { /* Mark all temporary tables used by this substatement as free for reuse. */ mark_used_tables_as_free_for_reuse(thd, thd->temporary_tables); } if (thd->locked_tables || prelocked_mode) { /* Let us commit transaction for statement. Since in 5.0 we only have one statement transaction and don't allow several nested statement transactions this call will do nothing if we are inside of stored function or trigger (i.e. statement transaction is already active and does not belong to statement for which we do close_thread_tables()). TODO: This should be fixed in later releases. */ ha_commit_stmt(thd); /* We are under simple LOCK TABLES so should not do anything else. */ if (!prelocked_mode) DBUG_VOID_RETURN; if (!thd->lex->requires_prelocking()) { /* If we are executing one of substatements we have to mark all tables which it used as free for reuse. */ mark_used_tables_as_free_for_reuse(thd, thd->open_tables); DBUG_VOID_RETURN; } DBUG_ASSERT(prelocked_mode); /* We are in prelocked mode, so we have to leave it now with doing implicit UNLOCK TABLES if need. */ DBUG_PRINT("info",("thd->prelocked_mode= NON_PRELOCKED")); thd->prelocked_mode= NON_PRELOCKED; if (prelocked_mode == PRELOCKED_UNDER_LOCK_TABLES) DBUG_VOID_RETURN; thd->lock= thd->locked_tables; thd->locked_tables= 0; /* Fallthrough */ } if (thd->lock) { mysql_unlock_tables(thd, thd->lock); thd->lock=0; } /* assume handlers auto-commit (if some doesn't - transaction handling in MySQL should be redesigned to support it; it's a big change, and it's not worth it - better to commit explicitly only writing transactions, read-only ones should better take care of themselves. saves some work in 2pc too) see also sql_parse.cc - dispatch_command() */ bzero(&thd->transaction.stmt, sizeof(thd->transaction.stmt)); if (!thd->active_transaction()) thd->transaction.xid_state.xid.null(); /* VOID(pthread_sigmask(SIG_SETMASK,&thd->block_signals,NULL)); */ if (!lock_in_use) VOID(pthread_mutex_lock(&LOCK_open)); safe_mutex_assert_owner(&LOCK_open); DBUG_PRINT("info", ("thd->open_tables: %p", thd->open_tables)); found_old_table= 0; while (thd->open_tables) found_old_table|=close_thread_table(thd, &thd->open_tables); thd->some_tables_deleted=0; /* Free tables to hold down open files */ while (open_cache.records > table_cache_size && unused_tables) VOID(hash_delete(&open_cache,(byte*) unused_tables)); /* purecov: tested */ check_unused(); if (found_old_table) { /* Tell threads waiting for refresh that something has happened */ broadcast_refresh(); } if (!lock_in_use) VOID(pthread_mutex_unlock(&LOCK_open)); /* VOID(pthread_sigmask(SIG_SETMASK,&thd->signals,NULL)); */ if (prelocked_mode == PRELOCKED) { /* If we are here then we are leaving normal prelocked mode, so it is good idea to turn off OPTION_TABLE_LOCK flag. */ DBUG_ASSERT(thd->lex->requires_prelocking()); thd->options&= ~(ulong) (OPTION_TABLE_LOCK); } DBUG_VOID_RETURN; } /* move one table to free list */ bool close_thread_table(THD *thd, TABLE **table_ptr) { bool found_old_table= 0; TABLE *table= *table_ptr; DBUG_ENTER("close_thread_table"); DBUG_ASSERT(table->key_read == 0); DBUG_ASSERT(table->file->inited == handler::NONE); *table_ptr=table->next; if (table->s->version != refresh_version || thd->version != refresh_version || !table->db_stat) { VOID(hash_delete(&open_cache,(byte*) table)); found_old_table=1; } else { if (table->s->flush_version != flush_version) { table->s->flush_version= flush_version; table->file->extra(HA_EXTRA_FLUSH); } else { // Free memory and reset for next loop table->file->reset(); } table->in_use=0; if (unused_tables) { table->next=unused_tables; /* Link in last */ table->prev=unused_tables->prev; unused_tables->prev=table; table->prev->next=table; } else unused_tables=table->next=table->prev=table; } DBUG_RETURN(found_old_table); } /* Close and delete temporary tables */ void close_temporary(TABLE *table,bool delete_table) { DBUG_ENTER("close_temporary"); char path[FN_REFLEN]; db_type table_type=table->s->db_type; strmov(path,table->s->path); free_io_cache(table); closefrm(table); my_free((char*) table,MYF(0)); if (delete_table) rm_temporary_table(table_type, path); DBUG_VOID_RETURN; } /* close_temporary_tables' internal, 4 is due to uint4korr definition */ static inline uint tmpkeyval(THD *thd, TABLE *table) { return uint4korr(table->s->table_cache_key + table->s->key_length - 4); } /* Creates one DROP TEMPORARY TABLE binlog event for each pseudo-thread */ void close_temporary_tables(THD *thd) { TABLE *table; if (!thd->temporary_tables) return; if (!mysql_bin_log.is_open()) { TABLE *next; for (table= thd->temporary_tables; table; table= next) { next= table->next; close_temporary(table, 1); } thd->temporary_tables= 0; return; } TABLE *next, *prev_table /* prev link is not maintained in TABLE's double-linked list */; bool was_quote_show= true; /* to assume thd->options has OPTION_QUOTE_SHOW_CREATE */ // Better add "if exists", in case a RESET MASTER has been done const char stub[]= "DROP /*!40005 TEMPORARY */ TABLE IF EXISTS "; uint stub_len= sizeof(stub) - 1; char buf[256]; memcpy(buf, stub, stub_len); String s_query= String(buf, sizeof(buf), system_charset_info); bool found_user_tables= false; LINT_INIT(next); /* insertion sort of temp tables by pseudo_thread_id to build ordered list of sublists of equal pseudo_thread_id */ for (prev_table= thd->temporary_tables, table= prev_table->next; table; prev_table= table, table= table->next) { TABLE *prev_sorted /* same as for prev_table */, *sorted; if (is_user_table(table)) { if (!found_user_tables) found_user_tables= true; for (prev_sorted= NULL, sorted= thd->temporary_tables; sorted != table; prev_sorted= sorted, sorted= sorted->next) { if (!is_user_table(sorted) || tmpkeyval(thd, sorted) > tmpkeyval(thd, table)) { /* move into the sorted part of the list from the unsorted */ prev_table->next= table->next; table->next= sorted; if (prev_sorted) { prev_sorted->next= table; } else { thd->temporary_tables= table; } table= prev_table; break; } } } } /* We always quote db,table names though it is slight overkill */ if (found_user_tables && !(was_quote_show= (thd->options & OPTION_QUOTE_SHOW_CREATE))) { thd->options |= OPTION_QUOTE_SHOW_CREATE; } /* scan sorted tmps to generate sequence of DROP */ for (table= thd->temporary_tables; table; table= next) { if (is_user_table(table)) { /* Set pseudo_thread_id to be that of the processed table */ thd->variables.pseudo_thread_id= tmpkeyval(thd, table); /* Loop forward through all tables within the sublist of common pseudo_thread_id to create single DROP query */ for (s_query.length(stub_len); table && is_user_table(table) && tmpkeyval(thd, table) == thd->variables.pseudo_thread_id; table= next) { /* We are going to add 4 ` around the db/table names and possible more due to special characters in the names */ append_identifier(thd, &s_query, table->s->db, strlen(table->s->db)); s_query.q_append('.'); append_identifier(thd, &s_query, table->s->table_name, strlen(table->s->table_name)); s_query.q_append(','); next= table->next; close_temporary(table, 1); } thd->clear_error(); CHARSET_INFO *cs_save= thd->variables.character_set_client; thd->variables.character_set_client= system_charset_info; Query_log_event qinfo(thd, s_query.ptr(), s_query.length() - 1 /* to remove trailing ',' */, 0, FALSE); thd->variables.character_set_client= cs_save; /* Imagine the thread had created a temp table, then was doing a SELECT, and the SELECT was killed. Then it's not clever to mark the statement above as "killed", because it's not really a statement updating data, and there are 99.99% chances it will succeed on slave. If a real update (one updating a persistent table) was killed on the master, then this real update will be logged with error_code=killed, rightfully causing the slave to stop. */ qinfo.error_code= 0; mysql_bin_log.write(&qinfo); } else { next= table->next; close_temporary(table, 1); } } if (!was_quote_show) thd->options &= ~OPTION_QUOTE_SHOW_CREATE; /* restore option */ thd->temporary_tables=0; } /* Find table in list. SYNOPSIS find_table_in_list() table Pointer to table list offset Offset to which list in table structure to use db_name Data base name table_name Table name NOTES: This is called by find_table_in_local_list() and find_table_in_global_list(). RETURN VALUES NULL Table not found # Pointer to found table. */ TABLE_LIST *find_table_in_list(TABLE_LIST *table, st_table_list *TABLE_LIST::*link, const char *db_name, const char *table_name) { for (; table; table= table->*link ) { if ((table->table == 0 || table->table->s->tmp_table == NO_TMP_TABLE) && strcmp(table->db, db_name) == 0 && strcmp(table->table_name, table_name) == 0) break; } return table; } /* Test that table is unique (It's only exists once in the table list) SYNOPSIS unique_table() thd thread handle table table which should be checked table_list list of tables NOTE: to exclude derived tables from check we use following mechanism: a) during derived table processing set THD::derived_tables_processing b) JOIN::prepare set SELECT::exclude_from_table_unique_test if THD::derived_tables_processing set. (we can't use JOIN::execute because for PS we perform only JOIN::prepare, but we can't set this flag in JOIN::prepare if we are not sure that we are in derived table processing loop, because multi-update call fix_fields() for some its items (which mean JOIN::prepare for subqueries) before unique_table call to detect which tables should be locked for write). c) unique_table skip all tables which belong to SELECT with SELECT::exclude_from_table_unique_test set. Also SELECT::exclude_from_table_unique_test used to exclude from check tables of main SELECT of multi-delete and multi-update We also skip tables with TABLE_LIST::prelocking_placeholder set, because we want to allow SELECTs from them, and their modification will rise the error anyway. TODO: when we will have table/view change detection we can do this check only once for PS/SP RETURN found duplicate 0 if table is unique */ TABLE_LIST* unique_table(THD *thd, TABLE_LIST *table, TABLE_LIST *table_list) { TABLE_LIST *res; const char *d_name, *t_name; DBUG_ENTER("unique_table"); DBUG_PRINT("enter", ("table alias: %s", table->alias)); /* If this function called for query which update table (INSERT/UPDATE/...) then we have in table->table pointer to TABLE object which we are updating even if it is VIEW so we need TABLE_LIST of this TABLE object to get right names (even if lower_case_table_names used). If this function called for CREATE command that we have not opened table (table->table equal to 0) and right names is in current TABLE_LIST object. */ if (table->table) { /* temporary table is always unique */ if (table->table && table->table->s->tmp_table != NO_TMP_TABLE) DBUG_RETURN(0); table= table->find_underlying_table(table->table); /* as far as we have table->table we have to find real TABLE_LIST of it in underlying tables */ DBUG_ASSERT(table); } d_name= table->db; t_name= table->table_name; DBUG_PRINT("info", ("real table: %s.%s", d_name, t_name)); for (;;) { if (((! (res= find_table_in_global_list(table_list, d_name, t_name))) && (! (res= mysql_lock_have_duplicate(thd, table, table_list)))) || ((!res->table || res->table != table->table) && res->select_lex && !res->select_lex->exclude_from_table_unique_test && !res->prelocking_placeholder)) break; /* If we found entry of this table or table of SELECT which already processed in derived table or top select of multi-update/multi-delete (exclude_from_table_unique_test) or prelocking placeholder. */ table_list= res->next_global; DBUG_PRINT("info", ("found same copy of table or table which we should skip")); } DBUG_RETURN(res); } /* Issue correct error message in case we found 2 duplicate tables which prevent some update operation SYNOPSIS update_non_unique_table_error() update table which we try to update operation name of update operation duplicate duplicate table which we found NOTE: here we hide view underlying tables if we have them */ void update_non_unique_table_error(TABLE_LIST *update, const char *operation, TABLE_LIST *duplicate) { update= update->top_table(); duplicate= duplicate->top_table(); if (!update->view || !duplicate->view || update->view == duplicate->view || update->view_name.length != duplicate->view_name.length || update->view_db.length != duplicate->view_db.length || my_strcasecmp(table_alias_charset, update->view_name.str, duplicate->view_name.str) != 0 || my_strcasecmp(table_alias_charset, update->view_db.str, duplicate->view_db.str) != 0) { /* it is not the same view repeated (but it can be parts of the same copy of view), so we have to hide underlying tables. */ if (update->view) { if (update->view == duplicate->view) my_error(ER_NON_UPDATABLE_TABLE, MYF(0), update->alias, operation); else my_error(ER_VIEW_PREVENT_UPDATE, MYF(0), (duplicate->view ? duplicate->alias : update->alias), operation, update->alias); return; } if (duplicate->view) { my_error(ER_VIEW_PREVENT_UPDATE, MYF(0), duplicate->alias, operation, update->alias); return; } } my_error(ER_UPDATE_TABLE_USED, MYF(0), update->alias); } TABLE **find_temporary_table(THD *thd, const char *db, const char *table_name) { char key[MAX_DBKEY_LENGTH]; uint key_length= (uint) (strmov(strmov(key,db)+1,table_name)-key)+1; TABLE *table,**prev; int4store(key+key_length,thd->server_id); key_length += 4; int4store(key+key_length,thd->variables.pseudo_thread_id); key_length += 4; prev= &thd->temporary_tables; for (table=thd->temporary_tables ; table ; table=table->next) { if (table->s->key_length == key_length && !memcmp(table->s->table_cache_key,key,key_length)) return prev; prev= &table->next; } return 0; // Not a temporary table } bool close_temporary_table(THD *thd, const char *db, const char *table_name) { TABLE *table,**prev; if (!(prev=find_temporary_table(thd,db,table_name))) return 1; table= *prev; *prev= table->next; close_temporary(table, 1); if (thd->slave_thread) --slave_open_temp_tables; return 0; } /* Used by ALTER TABLE when the table is a temporary one. It changes something only if the ALTER contained a RENAME clause (otherwise, table_name is the old name). Prepares a table cache key, which is the concatenation of db, table_name and thd->slave_proxy_id, separated by '\0'. */ bool rename_temporary_table(THD* thd, TABLE *table, const char *db, const char *table_name) { char *key; TABLE_SHARE *share= table->s; if (!(key=(char*) alloc_root(&table->mem_root, (uint) strlen(db)+ (uint) strlen(table_name)+6+4))) return 1; /* purecov: inspected */ share->key_length= (uint) (strmov((char*) (share->table_name= strmov(share->table_cache_key= key, db)+1), table_name) - share->table_cache_key)+1; share->db= share->table_cache_key; int4store(key+share->key_length, thd->server_id); share->key_length+= 4; int4store(key+share->key_length, thd->variables.pseudo_thread_id); share->key_length+= 4; return 0; } /* move table first in unused links */ static void relink_unused(TABLE *table) { if (table != unused_tables) { table->prev->next=table->next; /* Remove from unused list */ table->next->prev=table->prev; table->next=unused_tables; /* Link in unused tables */ table->prev=unused_tables->prev; unused_tables->prev->next=table; unused_tables->prev=table; unused_tables=table; check_unused(); } } /* Remove all instances of table from the current open list Free all locks on tables that are done with LOCK TABLES */ TABLE *unlink_open_table(THD *thd, TABLE *list, TABLE *find) { char key[MAX_DBKEY_LENGTH]; uint key_length= find->s->key_length; TABLE *start=list,**prev,*next; prev= &start; memcpy(key, find->s->table_cache_key, key_length); for (; list ; list=next) { next=list->next; if (list->s->key_length == key_length && !memcmp(list->s->table_cache_key, key, key_length)) { if (thd->locked_tables) mysql_lock_remove(thd, thd->locked_tables,list); VOID(hash_delete(&open_cache,(byte*) list)); // Close table } else { *prev=list; // put in use list prev= &list->next; } } *prev=0; // Notify any 'refresh' threads broadcast_refresh(); return start; } /* When we call the following function we must have a lock on LOCK_open ; This lock will be unlocked on return. */ void wait_for_refresh(THD *thd) { DBUG_ENTER("wait_for_refresh"); safe_mutex_assert_owner(&LOCK_open); /* Wait until the current table is up to date */ const char *proc_info; thd->mysys_var->current_mutex= &LOCK_open; thd->mysys_var->current_cond= &COND_refresh; proc_info=thd->proc_info; thd->proc_info="Waiting for table"; if (!thd->killed) (void) pthread_cond_wait(&COND_refresh,&LOCK_open); pthread_mutex_unlock(&LOCK_open); // Must be unlocked first pthread_mutex_lock(&thd->mysys_var->mutex); thd->mysys_var->current_mutex= 0; thd->mysys_var->current_cond= 0; thd->proc_info= proc_info; pthread_mutex_unlock(&thd->mysys_var->mutex); DBUG_VOID_RETURN; } /* Open table which is already name-locked by this thread. SYNOPSIS reopen_name_locked_table() thd Thread handle table_list TABLE_LIST object for table to be open, TABLE_LIST::table member should point to TABLE object which was used for name-locking. NOTE This function assumes that its caller already acquired LOCK_open mutex. RETURN VALUE FALSE - Success TRUE - Error */ bool reopen_name_locked_table(THD* thd, TABLE_LIST* table_list) { TABLE *table= table_list->table; TABLE_SHARE *share; char *db= table_list->db; char *table_name= table_list->table_name; char key[MAX_DBKEY_LENGTH]; uint key_length; TABLE orig_table; DBUG_ENTER("reopen_name_locked_table"); safe_mutex_assert_owner(&LOCK_open); if (thd->killed || !table) DBUG_RETURN(TRUE); orig_table= *table; key_length=(uint) (strmov(strmov(key,db)+1,table_name)-key)+1; if (open_unireg_entry(thd, table, db, table_name, table_name, 0, thd->mem_root) || !(table->s->table_cache_key= memdup_root(&table->mem_root, (char*) key, key_length))) { intern_close_table(table); /* If there was an error during opening of table (for example if it does not exist) '*table' object can be wiped out. To be able properly release name-lock in this case we should restore this object to its original state. */ *table= orig_table; DBUG_RETURN(TRUE); } share= table->s; share->db= share->table_cache_key; share->key_length=key_length; share->version=0; share->flush_version=0; table->in_use = thd; check_unused(); table->next = thd->open_tables; thd->open_tables = table; table->tablenr=thd->current_tablenr++; table->used_fields=0; table->const_table=0; table->null_row= table->maybe_null= table->force_index= 0; table->status=STATUS_NO_RECORD; table->keys_in_use_for_query= share->keys_in_use; table->used_keys= share->keys_for_keyread; DBUG_RETURN(FALSE); } /* Open a table. SYNOPSIS open_table() thd Thread context. table_list Open first table in list. refresh INOUT Pointer to memory that will be set to 1 if we need to close all tables and reopen them. If this is a NULL pointer, then the table is not put in the thread-open-list. flags Bitmap of flags to modify how open works: MYSQL_LOCK_IGNORE_FLUSH - Open table even if someone has done a flush or namelock on it. No version number checking is done. MYSQL_OPEN_IGNORE_LOCKED_TABLES - Open table ignoring set of locked tables and prelocked mode. IMPLEMENTATION Uses a cache of open tables to find a table not in use. RETURN NULL Open failed. If refresh is set then one should close all other tables and retry the open. # Success. Pointer to TABLE object for open table. */ TABLE *open_table(THD *thd, TABLE_LIST *table_list, MEM_ROOT *mem_root, bool *refresh, uint flags) { reg1 TABLE *table; char key[MAX_DBKEY_LENGTH]; uint key_length; char *alias= table_list->alias; HASH_SEARCH_STATE state; DBUG_ENTER("open_table"); /* find a unused table in the open table cache */ if (refresh) *refresh=0; /* an open table operation needs a lot of the stack space */ if (check_stack_overrun(thd, STACK_MIN_SIZE_FOR_OPEN, (char *)&alias)) DBUG_RETURN(0); if (thd->killed) DBUG_RETURN(0); key_length= (uint) (strmov(strmov(key, table_list->db)+1, table_list->table_name)-key)+1; int4store(key + key_length, thd->server_id); int4store(key + key_length + 4, thd->variables.pseudo_thread_id); if (!table_list->skip_temporary) { for (table= thd->temporary_tables; table ; table=table->next) { if (table->s->key_length == key_length + TMP_TABLE_KEY_EXTRA && !memcmp(table->s->table_cache_key, key, key_length + TMP_TABLE_KEY_EXTRA)) { if (table->query_id == thd->query_id || thd->prelocked_mode && table->query_id) { my_error(ER_CANT_REOPEN_TABLE, MYF(0), table->alias); DBUG_RETURN(0); } table->query_id= thd->query_id; table->clear_query_id= 1; thd->tmp_table_used= 1; DBUG_PRINT("info",("Using temporary table")); goto reset; } } } if (!(flags & MYSQL_OPEN_IGNORE_LOCKED_TABLES) && (thd->locked_tables || thd->prelocked_mode)) { // Using table locks TABLE *best_table= 0; int best_distance= INT_MIN; bool check_if_used= thd->prelocked_mode && ((int) table_list->lock_type >= (int) TL_WRITE_ALLOW_WRITE); for (table=thd->open_tables; table ; table=table->next) { if (table->s->key_length == key_length && !memcmp(table->s->table_cache_key, key, key_length)) { if (check_if_used && table->query_id && table->query_id != thd->query_id) { /* If we are in stored function or trigger we should ensure that we won't change table that is already used by calling statement. So if we are opening table for writing, we should check that it is not already open by some calling stamement. */ my_error(ER_CANT_UPDATE_USED_TABLE_IN_SF_OR_TRG, MYF(0), table->s->table_name); DBUG_RETURN(0); } if (!my_strcasecmp(system_charset_info, table->alias, alias) && table->query_id != thd->query_id && /* skip tables already used */ !(thd->prelocked_mode && table->query_id)) { int distance= ((int) table->reginfo.lock_type - (int) table_list->lock_type); /* Find a table that either has the exact lock type requested, or has the best suitable lock. In case there is no locked table that has an equal or higher lock than requested, we us the closest matching lock to be able to produce an error message about wrong lock mode on the table. The best_table is changed if bd < 0 <= d or bd < d < 0 or 0 <= d < bd. distance < 0 - No suitable lock found distance > 0 - we have lock mode higher then we require distance == 0 - we have lock mode exactly which we need */ if (best_distance < 0 && distance > best_distance || distance >= 0 && distance < best_distance) { best_distance= distance; best_table= table; if (best_distance == 0 && !check_if_used) { /* If we have found perfect match and we don't need to check that table is not used by one of calling statements (assuming that we are inside of function or trigger) we can finish iterating through open tables list. */ break; } } } } } if (best_table) { table= best_table; table->query_id= thd->query_id; DBUG_PRINT("info",("Using locked table")); goto reset; } /* is it view? (it is work around to allow to open view with locked tables, real fix will be made after definition cache will be made) */ { char path[FN_REFLEN]; db_type not_used; strxnmov(path, FN_REFLEN, mysql_data_home, "/", table_list->db, "/", table_list->table_name, reg_ext, NullS); (void) unpack_filename(path, path); if (mysql_frm_type(thd, path, ¬_used) == FRMTYPE_VIEW) { /* Will not be used (because it's VIEW) but has to be passed. Also we will not free it (because it is a stack variable). */ TABLE tab; table= &tab; VOID(pthread_mutex_lock(&LOCK_open)); if (!open_unireg_entry(thd, table, table_list->db, table_list->table_name, alias, table_list, mem_root)) { DBUG_ASSERT(table_list->view != 0); VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(0); // VIEW } VOID(pthread_mutex_unlock(&LOCK_open)); } } my_error(ER_TABLE_NOT_LOCKED, MYF(0), alias); DBUG_RETURN(0); } VOID(pthread_mutex_lock(&LOCK_open)); if (!thd->open_tables) thd->version=refresh_version; else if ((thd->version != refresh_version) && ! (flags & MYSQL_LOCK_IGNORE_FLUSH)) { /* Someone did a refresh while thread was opening tables */ if (refresh) *refresh=1; VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(0); } /* close handler tables which are marked for flush */ if (thd->handler_tables) mysql_ha_flush(thd, (TABLE_LIST*) NULL, MYSQL_HA_REOPEN_ON_USAGE, TRUE); for (table= (TABLE*) hash_first(&open_cache, (byte*) key, key_length, &state); table && table->in_use ; table= (TABLE*) hash_next(&open_cache, (byte*) key, key_length, &state)) { if (table->s->version != refresh_version) { DBUG_PRINT("note", ("Found table '%s.%s' with different refresh version", table_list->db, table_list->table_name)); if (flags & MYSQL_LOCK_IGNORE_FLUSH) { /* Force close at once after usage */ thd->version= table->s->version; continue; } /* There is a refresh in progress for this table Wait until the table is freed or the thread is killed. */ close_old_data_files(thd,thd->open_tables,0,0); if (table->in_use != thd) wait_for_refresh(thd); else { VOID(pthread_mutex_unlock(&LOCK_open)); } if (refresh) *refresh=1; DBUG_RETURN(0); } } if (table) { if (table == unused_tables) { // First unused unused_tables=unused_tables->next; // Remove from link if (table == unused_tables) unused_tables=0; } table->prev->next=table->next; /* Remove from unused list */ table->next->prev=table->prev; table->in_use= thd; } else { TABLE_SHARE *share; /* Free cache if too big */ while (open_cache.records > table_cache_size && unused_tables) VOID(hash_delete(&open_cache,(byte*) unused_tables)); /* purecov: tested */ /* make a new table */ if (!(table=(TABLE*) my_malloc(sizeof(*table),MYF(MY_WME)))) { VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(NULL); } if (open_unireg_entry(thd, table, table_list->db, table_list->table_name, alias, table_list, mem_root) || (!table_list->view && !(table->s->table_cache_key= memdup_root(&table->mem_root, (char*) key, key_length)))) { table->next=table->prev=table; free_cache_entry(table); VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(NULL); } if (table_list->view) { my_free((gptr)table, MYF(0)); VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(0); // VIEW } share= table->s; share->db= share->table_cache_key; share->key_length= key_length; share->version= refresh_version; share->flush_version= flush_version; DBUG_PRINT("info", ("inserting table %p into the cache", table)); VOID(my_hash_insert(&open_cache,(byte*) table)); } check_unused(); // Debugging call VOID(pthread_mutex_unlock(&LOCK_open)); if (refresh) { table->next=thd->open_tables; /* Link into simple list */ thd->open_tables=table; } table->reginfo.lock_type=TL_READ; /* Assume read */ reset: if (thd->lex->need_correct_ident()) table->alias_name_used= my_strcasecmp(table_alias_charset, table->s->table_name, alias); /* Fix alias if table name changes */ if (strcmp(table->alias, alias)) { uint length=(uint) strlen(alias)+1; table->alias= (char*) my_realloc((char*) table->alias, length, MYF(MY_WME)); memcpy((char*) table->alias, alias, length); } /* These variables are also set in reopen_table() */ table->tablenr=thd->current_tablenr++; table->used_fields=0; table->const_table=0; table->null_row= table->maybe_null= table->force_index= 0; table->status=STATUS_NO_RECORD; table->keys_in_use_for_query= table->s->keys_in_use; table->insert_values= 0; table->used_keys= table->s->keys_for_keyread; table->fulltext_searched= 0; table->file->ft_handler= 0; if (table->timestamp_field) table->timestamp_field_type= table->timestamp_field->get_auto_set_type(); table_list->updatable= 1; // It is not derived table nor non-updatable VIEW DBUG_ASSERT(table->key_read == 0); DBUG_RETURN(table); } TABLE *find_locked_table(THD *thd, const char *db,const char *table_name) { char key[MAX_DBKEY_LENGTH]; uint key_length=(uint) (strmov(strmov(key,db)+1,table_name)-key)+1; for (TABLE *table=thd->open_tables; table ; table=table->next) { if (table->s->key_length == key_length && !memcmp(table->s->table_cache_key,key,key_length)) return table; } return(0); } /**************************************************************************** Reopen an table because the definition has changed. The date file for the table is already closed. SYNOPSIS reopen_table() table Table to be opened locked 1 if we have already a lock on LOCK_open NOTES table->query_id will be 0 if table was reopened RETURN 0 ok 1 error ('table' is unchanged if table couldn't be reopened) ****************************************************************************/ bool reopen_table(TABLE *table,bool locked) { TABLE tmp; char *db= table->s->table_cache_key; const char *table_name= table->s->table_name; bool error= 1; Field **field; uint key,part; DBUG_ENTER("reopen_table"); #ifdef EXTRA_DEBUG if (table->db_stat) sql_print_error("Table %s had a open data handler in reopen_table", table->alias); #endif if (!locked) VOID(pthread_mutex_lock(&LOCK_open)); safe_mutex_assert_owner(&LOCK_open); if (open_unireg_entry(table->in_use, &tmp, db, table_name, table->alias, 0, table->in_use->mem_root)) goto end; free_io_cache(table); if (!(tmp.s->table_cache_key= memdup_root(&tmp.mem_root,db, table->s->key_length))) { delete tmp.triggers; closefrm(&tmp); // End of memory goto end; } tmp.s->db= tmp.s->table_cache_key; /* This list copies variables set by open_table */ tmp.tablenr= table->tablenr; tmp.used_fields= table->used_fields; tmp.const_table= table->const_table; tmp.null_row= table->null_row; tmp.maybe_null= table->maybe_null; tmp.status= table->status; tmp.keys_in_use_for_query= tmp.s->keys_in_use; tmp.used_keys= tmp.s->keys_for_keyread; /* Get state */ tmp.s->key_length= table->s->key_length; tmp.in_use= table->in_use; tmp.reginfo.lock_type=table->reginfo.lock_type; tmp.s->version= refresh_version; tmp.s->tmp_table= table->s->tmp_table; tmp.grant= table->grant; /* Replace table in open list */ tmp.next= table->next; tmp.prev= table->prev; delete table->triggers; if (table->file) VOID(closefrm(table)); // close file, free everything *table= tmp; table->s= &table->share_not_to_be_used; table->file->change_table_ptr(table); DBUG_ASSERT(table->alias != 0); for (field=table->field ; *field ; field++) { (*field)->table= (*field)->orig_table= table; (*field)->table_name= &table->alias; } for (key=0 ; key < table->s->keys ; key++) { for (part=0 ; part < table->key_info[key].usable_key_parts ; part++) table->key_info[key].key_part[part].field->table= table; } if (table->triggers) table->triggers->set_table(table); broadcast_refresh(); error=0; end: if (!locked) VOID(pthread_mutex_unlock(&LOCK_open)); DBUG_RETURN(error); } /* Used with ALTER TABLE: Close all instanses of table when LOCK TABLES is in used; Close first all instances of table and then reopen them */ bool close_data_tables(THD *thd,const char *db, const char *table_name) { TABLE *table; for (table=thd->open_tables; table ; table=table->next) { if (!strcmp(table->s->table_name, table_name) && !strcmp(table->s->db, db)) { mysql_lock_remove(thd, thd->locked_tables,table); table->file->close(); table->db_stat=0; } } return 0; // For the future } /* Reopen all tables with closed data files One should have lock on LOCK_open when calling this */ bool reopen_tables(THD *thd,bool get_locks,bool in_refresh) { DBUG_ENTER("reopen_tables"); safe_mutex_assert_owner(&LOCK_open); if (!thd->open_tables) DBUG_RETURN(0); TABLE *table,*next,**prev; TABLE **tables,**tables_ptr; // For locks bool error=0, not_used; if (get_locks) { /* The ptr is checked later */ uint opens=0; for (table=thd->open_tables; table ; table=table->next) opens++; tables= (TABLE**) my_alloca(sizeof(TABLE*)*opens); } else tables= &thd->open_tables; tables_ptr =tables; prev= &thd->open_tables; for (table=thd->open_tables; table ; table=next) { uint db_stat=table->db_stat; next=table->next; if (!tables || (!db_stat && reopen_table(table,1))) { my_error(ER_CANT_REOPEN_TABLE, MYF(0), table->alias); VOID(hash_delete(&open_cache,(byte*) table)); error=1; } else { *prev= table; prev= &table->next; if (get_locks && !db_stat) *tables_ptr++= table; // need new lock on this if (in_refresh) { table->s->version=0; table->locked_by_flush=0; } } } if (tables != tables_ptr) // Should we get back old locks { MYSQL_LOCK *lock; /* We should always get these locks */ thd->some_tables_deleted=0; if ((lock= mysql_lock_tables(thd, tables, (uint) (tables_ptr - tables), 0, ¬_used))) { thd->locked_tables=mysql_lock_merge(thd->locked_tables,lock); } else error=1; } if (get_locks && tables) { my_afree((gptr) tables); } broadcast_refresh(); *prev=0; DBUG_RETURN(error); } /* Close handlers for tables in list, but leave the TABLE structure intact so that we can re-open these quickly abort_locks is set if called from flush_tables. */ void close_old_data_files(THD *thd, TABLE *table, bool abort_locks, bool send_refresh) { DBUG_ENTER("close_old_data_files"); bool found=send_refresh; for (; table ; table=table->next) { if (table->s->version != refresh_version) { found=1; if (!abort_locks) // If not from flush tables table->s->version= refresh_version; // Let other threads use table if (table->db_stat) { if (abort_locks) { mysql_lock_abort(thd,table); // Close waiting threads mysql_lock_remove(thd, thd->locked_tables,table); table->locked_by_flush=1; // Will be reopened with locks } table->file->close(); table->db_stat=0; } } } if (found) broadcast_refresh(); DBUG_VOID_RETURN; } /* Wait until all threads has closed the tables in the list We have also to wait if there is thread that has a lock on this table even if the table is closed */ bool table_is_used(TABLE *table, bool wait_for_name_lock) { do { char *key= table->s->table_cache_key; uint key_length= table->s->key_length; HASH_SEARCH_STATE state; for (TABLE *search= (TABLE*) hash_first(&open_cache, (byte*) key, key_length, &state); search ; search= (TABLE*) hash_next(&open_cache, (byte*) key, key_length, &state)) { if (search->locked_by_flush || search->locked_by_name && wait_for_name_lock || search->db_stat && search->s->version < refresh_version) return 1; // Table is used } } while ((table=table->next)); return 0; } /* Wait until all used tables are refreshed */ bool wait_for_tables(THD *thd) { bool result; DBUG_ENTER("wait_for_tables"); thd->proc_info="Waiting for tables"; pthread_mutex_lock(&LOCK_open); while (!thd->killed) { thd->some_tables_deleted=0; close_old_data_files(thd,thd->open_tables,0,dropping_tables != 0); mysql_ha_flush(thd, (TABLE_LIST*) NULL, MYSQL_HA_REOPEN_ON_USAGE, TRUE); if (!table_is_used(thd->open_tables,1)) break; (void) pthread_cond_wait(&COND_refresh,&LOCK_open); } if (thd->killed) result= 1; // aborted else { /* Now we can open all tables without any interference */ thd->proc_info="Reopen tables"; thd->version= refresh_version; result=reopen_tables(thd,0,0); } pthread_mutex_unlock(&LOCK_open); thd->proc_info=0; DBUG_RETURN(result); } /* drop tables from locked list */ bool drop_locked_tables(THD *thd,const char *db, const char *table_name) { TABLE *table,*next,**prev; bool found=0; prev= &thd->open_tables; for (table= thd->open_tables; table ; table=next) { next=table->next; if (!strcmp(table->s->table_name, table_name) && !strcmp(table->s->db, db)) { mysql_lock_remove(thd, thd->locked_tables,table); VOID(hash_delete(&open_cache,(byte*) table)); found=1; } else { *prev=table; prev= &table->next; } } *prev=0; if (found) broadcast_refresh(); if (thd->locked_tables && thd->locked_tables->table_count == 0) { my_free((gptr) thd->locked_tables,MYF(0)); thd->locked_tables=0; } return found; } /* If we have the table open, which only happens when a LOCK TABLE has been done on the table, change the lock type to a lock that will abort all other threads trying to get the lock. */ void abort_locked_tables(THD *thd,const char *db, const char *table_name) { TABLE *table; for (table= thd->open_tables; table ; table= table->next) { if (!strcmp(table->s->table_name,table_name) && !strcmp(table->s->db, db)) { mysql_lock_abort(thd,table); break; } } } /* Load a table definition from file and open unireg table SYNOPSIS open_unireg_entry() thd Thread handle entry Store open table definition here db Database name name Table name alias Alias name table_desc TABLE_LIST descriptor (used with views) mem_root temporary mem_root for parsing NOTES Extra argument for open is taken from thd->open_options RETURN 0 ok # Error */ static int open_unireg_entry(THD *thd, TABLE *entry, const char *db, const char *name, const char *alias, TABLE_LIST *table_desc, MEM_ROOT *mem_root) { char path[FN_REFLEN]; int error; uint discover_retry_count= 0; DBUG_ENTER("open_unireg_entry"); strxmov(path, mysql_data_home, "/", db, "/", name, NullS); while ((error= openfrm(thd, path, alias, (uint) (HA_OPEN_KEYFILE | HA_OPEN_RNDFILE | HA_GET_INDEX | HA_TRY_READ_ONLY | NO_ERR_ON_NEW_FRM), READ_KEYINFO | COMPUTE_TYPES | EXTRA_RECORD, thd->open_options, entry)) && (error != 5 || (fn_format(path, path, 0, reg_ext, MY_UNPACK_FILENAME), open_new_frm(thd, path, alias, db, name, (uint) (HA_OPEN_KEYFILE | HA_OPEN_RNDFILE | HA_GET_INDEX | HA_TRY_READ_ONLY), READ_KEYINFO | COMPUTE_TYPES | EXTRA_RECORD, thd->open_options, entry, table_desc, mem_root)))) { if (!entry->s || !entry->s->crashed) { /* Frm file could not be found on disk Since it does not exist, no one can be using it LOCK_open has been locked to protect from someone else trying to discover the table at the same time. */ if (discover_retry_count++ != 0) goto err; if (ha_create_table_from_engine(thd, db, name) > 0) { /* Give right error message */ thd->clear_error(); DBUG_PRINT("error", ("Discovery of %s/%s failed", db, name)); my_printf_error(ER_UNKNOWN_ERROR, "Failed to open '%-.64s', error while " "unpacking from engine", MYF(0), name); goto err; } mysql_reset_errors(thd, 1); // Clear warnings thd->clear_error(); // Clear error message continue; } // Code below is for repairing a crashed file TABLE_LIST table_list; bzero((char*) &table_list, sizeof(table_list)); // just for safe table_list.db=(char*) db; table_list.table_name=(char*) name; safe_mutex_assert_owner(&LOCK_open); if ((error=lock_table_name(thd,&table_list))) { if (error < 0) { goto err; } if (wait_for_locked_table_names(thd,&table_list)) { unlock_table_name(thd,&table_list); goto err; } } pthread_mutex_unlock(&LOCK_open); thd->clear_error(); // Clear error message error= 0; if (openfrm(thd, path, alias, (uint) (HA_OPEN_KEYFILE | HA_OPEN_RNDFILE | HA_GET_INDEX | HA_TRY_READ_ONLY), READ_KEYINFO | COMPUTE_TYPES | EXTRA_RECORD, ha_open_options | HA_OPEN_FOR_REPAIR, entry) || ! entry->file || (entry->file->is_crashed() && entry->file->check_and_repair(thd))) { /* Give right error message */ thd->clear_error(); my_error(ER_NOT_KEYFILE, MYF(0), name, my_errno); sql_print_error("Couldn't repair table: %s.%s",db,name); if (entry->file) closefrm(entry); error=1; } else thd->clear_error(); // Clear error message pthread_mutex_lock(&LOCK_open); unlock_table_name(thd,&table_list); if (error) goto err; break; } if (error == 5) DBUG_RETURN(0); // we have just opened VIEW /* We can't mark all tables in 'mysql' database as system since we don't allow to lock such tables for writing with any other tables (even with other system tables) and some privilege tables need this. */ if (!my_strcasecmp(system_charset_info, db, "mysql") && !my_strcasecmp(system_charset_info, name, "proc")) entry->s->system_table= 1; if (Table_triggers_list::check_n_load(thd, db, name, entry, 0)) goto err; /* If we are here, there was no fatal error (but error may be still unitialized). */ if (unlikely(entry->file->implicit_emptied)) { entry->file->implicit_emptied= 0; if (mysql_bin_log.is_open()) { char *query, *end; uint query_buf_size= 20 + 2*NAME_LEN + 1; if ((query= (char*)my_malloc(query_buf_size,MYF(MY_WME)))) { end = strxmov(strmov(query, "DELETE FROM `"), db,"`.`",name,"`", NullS); Query_log_event qinfo(thd, query, (ulong)(end-query), 0, FALSE); mysql_bin_log.write(&qinfo); my_free(query, MYF(0)); } else { /* As replication is maybe going to be corrupted, we need to warn the DBA on top of warning the client (which will automatically be done because of MYF(MY_WME) in my_malloc() above). */ sql_print_error("When opening HEAP table, could not allocate \ memory to write 'DELETE FROM `%s`.`%s`' to the binary log",db,name); delete entry->triggers; if (entry->file) closefrm(entry); goto err; } } } DBUG_RETURN(0); err: /* Hide "Table doesn't exist" errors if table belong to view */ if (thd->net.last_errno == ER_NO_SUCH_TABLE && table_desc && table_desc->belong_to_view) { TABLE_LIST *view= table_desc->belong_to_view; thd->clear_error(); my_error(ER_VIEW_INVALID, MYF(0), view->view_db.str, view->view_name.str); } DBUG_RETURN(1); } /* Open all tables in list SYNOPSIS open_tables() thd - thread handler start - list of tables in/out counter - number of opened tables will be return using this parameter flags - bitmap of flags to modify how the tables will be open: MYSQL_LOCK_IGNORE_FLUSH - open table even if someone has done a flush or namelock on it. NOTE Unless we are already in prelocked mode, this function will also precache all SP/SFs explicitly or implicitly (via views and triggers) used by the query and add tables needed for their execution to table list. If resulting tables list will be non empty it will mark query as requiring precaching. Prelocked mode will be enabled for such query during lock_tables() call. If query for which we are opening tables is already marked as requiring prelocking it won't do such precaching and will simply reuse table list which is already built. RETURN 0 - OK -1 - error */ int open_tables(THD *thd, TABLE_LIST **start, uint *counter, uint flags) { TABLE_LIST *tables; bool refresh; int result=0; MEM_ROOT new_frm_mem; /* Also used for indicating that prelocking is need */ TABLE_LIST **query_tables_last_own; DBUG_ENTER("open_tables"); /* temporary mem_root for new .frm parsing. TODO: variables for size */ init_alloc_root(&new_frm_mem, 8024, 8024); thd->current_tablenr= 0; restart: *counter= 0; query_tables_last_own= 0; thd->proc_info="Opening tables"; /* If we are not already executing prelocked statement and don't have statement for which table list for prelocking is already built, let us cache routines and try to build such table list. NOTE: We will mark statement as requiring prelocking only if we will have non empty table list. But this does not guarantee that in prelocked mode we will have some locked tables, because queries which use only derived/information schema tables and views possible. Thus "counter" may be still zero for prelocked statement... */ if (!thd->prelocked_mode && !thd->lex->requires_prelocking() && thd->lex->sroutines_list.elements) { bool first_no_prelocking, need_prelocking, tabs_changed; TABLE_LIST **save_query_tables_last= thd->lex->query_tables_last; DBUG_ASSERT(thd->lex->query_tables == *start); sp_get_prelocking_info(thd, &need_prelocking, &first_no_prelocking); if (sp_cache_routines_and_add_tables(thd, thd->lex, first_no_prelocking, &tabs_changed)) { /* Serious error during reading stored routines from mysql.proc table. Something's wrong with the table or its contents, and an error has been emitted; we must abort. */ result= -1; goto err; } else if ((tabs_changed || *start) && need_prelocking) { query_tables_last_own= save_query_tables_last; *start= thd->lex->query_tables; } } for (tables= *start; tables ;tables= tables->next_global) { /* Ignore placeholders for derived tables. After derived tables processing, link to created temporary table will be put here. If this is derived table for view then we still want to process routines used by this view. */ if (tables->derived) { if (tables->view) goto process_view_routines; continue; } if (tables->schema_table) { if (!mysql_schema_table(thd, thd->lex, tables)) continue; DBUG_RETURN(-1); } (*counter)++; if (!tables->table && !(tables->table= open_table(thd, tables, &new_frm_mem, &refresh, flags))) { free_root(&new_frm_mem, MYF(MY_KEEP_PREALLOC)); if (tables->view) { /* VIEW placeholder */ (*counter)--; /* tables->next_global list consists of two parts: 1) Query tables and underlying tables of views. 2) Tables used by all stored routines that this statement invokes on execution. We need to know where the bound between these two parts is. If we've just opened a view, which was the last table in part #1, and it has added its base tables after itself, adjust the boundary pointer accordingly. */ if (query_tables_last_own == &(tables->next_global) && tables->view->query_tables) query_tables_last_own= tables->view->query_tables_last; /* Let us free memory used by 'sroutines' hash here since we never call destructor for this LEX. */ hash_free(&tables->view->sroutines); goto process_view_routines; } if (refresh) // Refresh in progress { /* We have met name-locked or old version of table. Now we have to close all tables which are not up to date. We also have to throw away set of prelocked tables (and thus close tables from this set that were open by now) since it possible that one of tables which determined its content was changed. Instead of implementing complex/non-robust logic mentioned above we simply close and then reopen all tables. In order to prepare for recalculation of set of prelocked tables we pretend that we have finished calculation which we were doing currently. */ if (query_tables_last_own) thd->lex->mark_as_requiring_prelocking(query_tables_last_own); close_tables_for_reopen(thd, start); goto restart; } result= -1; // Fatal error break; } else { /* If we are not already in prelocked mode and extended table list is not yet built and we have trigger for table being opened then we should cache all routines used by its triggers and add their tables to prelocking list. If we lock table for reading we won't update it so there is no need to process its triggers since they never will be activated. */ if (!thd->prelocked_mode && !thd->lex->requires_prelocking() && tables->table->triggers && tables->lock_type >= TL_WRITE_ALLOW_WRITE) { if (!query_tables_last_own) query_tables_last_own= thd->lex->query_tables_last; if (sp_cache_routines_and_add_tables_for_triggers(thd, thd->lex, tables)) { /* Serious error during reading stored routines from mysql.proc table. Something's wrong with the table or its contents, and an error has been emitted; we must abort. */ result= -1; goto err; } } free_root(&new_frm_mem, MYF(MY_KEEP_PREALLOC)); } if (tables->lock_type != TL_UNLOCK && ! thd->locked_tables) tables->table->reginfo.lock_type=tables->lock_type; tables->table->grant= tables->grant; process_view_routines: /* Again we may need cache all routines used by this view and add tables used by them to table list. */ if (tables->view && !thd->prelocked_mode && !thd->lex->requires_prelocking() && tables->view->sroutines_list.elements) { /* We have at least one table in TL here. */ if (!query_tables_last_own) query_tables_last_own= thd->lex->query_tables_last; if (sp_cache_routines_and_add_tables_for_view(thd, thd->lex, tables)) { /* Serious error during reading stored routines from mysql.proc table. Something's wrong with the table or its contents, and an error has been emitted; we must abort. */ result= -1; goto err; } } } err: thd->proc_info=0; free_root(&new_frm_mem, MYF(0)); // Free pre-alloced block if (query_tables_last_own) thd->lex->mark_as_requiring_prelocking(query_tables_last_own); DBUG_RETURN(result); } /* Check that lock is ok for tables; Call start stmt if ok SYNOPSIS check_lock_and_start_stmt() thd Thread handle table_list Table to check lock_type Lock used for table RETURN VALUES 0 ok 1 error */ static bool check_lock_and_start_stmt(THD *thd, TABLE *table, thr_lock_type lock_type) { int error; DBUG_ENTER("check_lock_and_start_stmt"); if ((int) lock_type >= (int) TL_WRITE_ALLOW_READ && (int) table->reginfo.lock_type < (int) TL_WRITE_ALLOW_READ) { my_error(ER_TABLE_NOT_LOCKED_FOR_WRITE, MYF(0),table->alias); DBUG_RETURN(1); } if ((error=table->file->start_stmt(thd, lock_type))) { table->file->print_error(error,MYF(0)); DBUG_RETURN(1); } DBUG_RETURN(0); } /* Open and lock one table SYNOPSIS open_ltable() thd Thread handler table_list Table to open is first table in this list lock_type Lock to use for open NOTE This function don't do anything like SP/SF/views/triggers analysis done in open_tables(). It is intended for opening of only one concrete table. And used only in special contexts. RETURN VALUES table Opened table 0 Error If ok, the following are also set: table_list->lock_type lock_type table_list->table table */ TABLE *open_ltable(THD *thd, TABLE_LIST *table_list, thr_lock_type lock_type) { TABLE *table; bool refresh; DBUG_ENTER("open_ltable"); thd->proc_info="Opening table"; thd->current_tablenr= 0; /* open_ltable can be used only for BASIC TABLEs */ table_list->required_type= FRMTYPE_TABLE; while (!(table= open_table(thd, table_list, thd->mem_root, &refresh, 0)) && refresh) ; if (table) { #if defined( __WIN__) || defined(OS2) /* Win32 can't drop a file that is open */ if (lock_type == TL_WRITE_ALLOW_READ) { lock_type= TL_WRITE; } #endif /* __WIN__ || OS2 */ table_list->lock_type= lock_type; table_list->table= table; table->grant= table_list->grant; if (thd->locked_tables) { if (check_lock_and_start_stmt(thd, table, lock_type)) table= 0; } else { DBUG_ASSERT(thd->lock == 0); // You must lock everything at once if ((table->reginfo.lock_type= lock_type) != TL_UNLOCK) if (! (thd->lock= mysql_lock_tables(thd, &table_list->table, 1, 0, &refresh))) table= 0; } } thd->proc_info=0; DBUG_RETURN(table); } /* Open all tables in list and locks them for read without derived tables processing. SYNOPSIS simple_open_n_lock_tables() thd - thread handler tables - list of tables for open&locking RETURN 0 - ok -1 - error NOTE The lock will automaticaly be freed by close_thread_tables() */ int simple_open_n_lock_tables(THD *thd, TABLE_LIST *tables) { uint counter; bool need_reopen; DBUG_ENTER("simple_open_n_lock_tables"); for ( ; ; ) { if (open_tables(thd, &tables, &counter, 0)) DBUG_RETURN(-1); if (!lock_tables(thd, tables, counter, &need_reopen)) break; if (!need_reopen) DBUG_RETURN(-1); close_tables_for_reopen(thd, &tables); } DBUG_RETURN(0); } /* Open all tables in list, locks them and process derived tables tables processing. SYNOPSIS open_and_lock_tables() thd - thread handler tables - list of tables for open&locking RETURN FALSE - ok TRUE - error NOTE The lock will automaticaly be freed by close_thread_tables() */ bool open_and_lock_tables(THD *thd, TABLE_LIST *tables) { uint counter; bool need_reopen; DBUG_ENTER("open_and_lock_tables"); for ( ; ; ) { if (open_tables(thd, &tables, &counter, 0)) DBUG_RETURN(-1); if (!lock_tables(thd, tables, counter, &need_reopen)) break; if (!need_reopen) DBUG_RETURN(-1); close_tables_for_reopen(thd, &tables); } if (mysql_handle_derived(thd->lex, &mysql_derived_prepare) || (thd->fill_derived_tables() && mysql_handle_derived(thd->lex, &mysql_derived_filling))) DBUG_RETURN(TRUE); /* purecov: inspected */ DBUG_RETURN(0); } /* Open all tables in list and process derived tables SYNOPSIS open_normal_and_derived_tables thd - thread handler tables - list of tables for open flags - bitmap of flags to modify how the tables will be open: MYSQL_LOCK_IGNORE_FLUSH - open table even if someone has done a flush or namelock on it. RETURN FALSE - ok TRUE - error NOTE This is to be used on prepare stage when you don't read any data from the tables. */ bool open_normal_and_derived_tables(THD *thd, TABLE_LIST *tables, uint flags) { uint counter; DBUG_ENTER("open_normal_and_derived_tables"); DBUG_ASSERT(!thd->fill_derived_tables()); if (open_tables(thd, &tables, &counter, flags) || mysql_handle_derived(thd->lex, &mysql_derived_prepare)) DBUG_RETURN(TRUE); /* purecov: inspected */ DBUG_RETURN(0); } /* Mark all real tables in the list as free for reuse. SYNOPSIS mark_real_tables_as_free_for_reuse() thd - thread context table - head of the list of tables DESCRIPTION Marks all real tables in the list (i.e. not views, derived or schema tables) as free for reuse. */ static void mark_real_tables_as_free_for_reuse(TABLE_LIST *table) { for (; table; table= table->next_global) if (!table->placeholder() && !table->schema_table) table->table->query_id= 0; } /* Lock all tables in list SYNOPSIS lock_tables() thd Thread handler tables Tables to lock count Number of opened tables need_reopen Out parameter which if TRUE indicates that some tables were dropped or altered during this call and therefore invoker should reopen tables and try to lock them once again (in this case lock_tables() will also return error). NOTES You can't call lock_tables twice, as this would break the dead-lock-free handling thr_lock gives us. You most always get all needed locks at once. If query for which we are calling this function marked as requring prelocking, this function will do implicit LOCK TABLES and change thd::prelocked_mode accordingly. RETURN VALUES 0 ok -1 Error */ int lock_tables(THD *thd, TABLE_LIST *tables, uint count, bool *need_reopen) { TABLE_LIST *table; DBUG_ENTER("lock_tables"); /* We can't meet statement requiring prelocking if we already in prelocked mode. */ DBUG_ASSERT(!thd->prelocked_mode || !thd->lex->requires_prelocking()); /* If statement requires prelocking then it has non-empty table list. So it is safe to shortcut. */ DBUG_ASSERT(!thd->lex->requires_prelocking() || tables); *need_reopen= FALSE; if (!tables) DBUG_RETURN(0); /* We need this extra check for thd->prelocked_mode because we want to avoid attempts to lock tables in substatements. Checking for thd->locked_tables is not enough in some situations. For example for SP containing "drop table t3; create temporary t3 ..; insert into t3 ...;" thd->locked_tables may be 0 after drop tables, and without this extra check insert will try to lock temporary table t3, that will lead to memory leak... */ if (!thd->locked_tables && !thd->prelocked_mode) { DBUG_ASSERT(thd->lock == 0); // You must lock everything at once TABLE **start,**ptr; if (!(ptr=start=(TABLE**) thd->alloc(sizeof(TABLE*)*count))) DBUG_RETURN(-1); for (table= tables; table; table= table->next_global) { if (!table->placeholder() && !table->schema_table) *(ptr++)= table->table; } /* We have to emulate LOCK TABLES if we are statement needs prelocking. */ if (thd->lex->requires_prelocking()) { thd->in_lock_tables=1; thd->options|= OPTION_TABLE_LOCK; } if (! (thd->lock= mysql_lock_tables(thd, start, (uint) (ptr - start), MYSQL_LOCK_NOTIFY_IF_NEED_REOPEN, need_reopen))) { if (thd->lex->requires_prelocking()) { thd->options&= ~(ulong) (OPTION_TABLE_LOCK); thd->in_lock_tables=0; } DBUG_RETURN(-1); } if (thd->lex->requires_prelocking() && thd->lex->sql_command != SQLCOM_LOCK_TABLES) { TABLE_LIST *first_not_own= thd->lex->first_not_own_table(); /* We just have done implicit LOCK TABLES, and now we have to emulate first open_and_lock_tables() after it. Note that "LOCK TABLES" can also be marked as requiring prelocking (e.g. if one locks view which uses functions). We should not emulate such open_and_lock_tables() in this case. We also should not set THD::prelocked_mode or first close_thread_tables() call will do "UNLOCK TABLES". */ thd->locked_tables= thd->lock; thd->lock= 0; thd->in_lock_tables=0; for (table= tables; table != first_not_own; table= table->next_global) { if (!table->placeholder() && !table->schema_table) { table->table->query_id= thd->query_id; if (check_lock_and_start_stmt(thd, table->table, table->lock_type)) { ha_rollback_stmt(thd); mysql_unlock_tables(thd, thd->locked_tables); thd->locked_tables= 0; thd->options&= ~(ulong) (OPTION_TABLE_LOCK); DBUG_RETURN(-1); } } } /* Let us mark all tables which don't belong to the statement itself, and was marked as occupied during open_tables() as free for reuse. */ mark_real_tables_as_free_for_reuse(first_not_own); DBUG_PRINT("info",("prelocked_mode= PRELOCKED")); thd->prelocked_mode= PRELOCKED; } } else { TABLE_LIST *first_not_own= thd->lex->first_not_own_table(); for (table= tables; table != first_not_own; table= table->next_global) { if (!table->placeholder() && !table->schema_table && check_lock_and_start_stmt(thd, table->table, table->lock_type)) { ha_rollback_stmt(thd); DBUG_RETURN(-1); } } /* If we are under explicit LOCK TABLES and our statement requires prelocking, we should mark all "additional" tables as free for use and enter prelocked mode. */ if (thd->lex->requires_prelocking()) { mark_real_tables_as_free_for_reuse(first_not_own); DBUG_PRINT("info", ("thd->prelocked_mode= PRELOCKED_UNDER_LOCK_TABLES")); thd->prelocked_mode= PRELOCKED_UNDER_LOCK_TABLES; } } DBUG_RETURN(0); } /* Prepare statement for reopening of tables and recalculation of set of prelocked tables. SYNOPSIS close_tables_for_reopen() thd in Thread context tables in/out List of tables which we were trying to open and lock */ void close_tables_for_reopen(THD *thd, TABLE_LIST **tables) { /* If table list consists only from tables from prelocking set, table list for new attempt should be empty, so we have to update list's root pointer. */ if (thd->lex->first_not_own_table() == *tables) *tables= 0; thd->lex->chop_off_not_own_tables(); sp_remove_not_own_routines(thd->lex); for (TABLE_LIST *tmp= *tables; tmp; tmp= tmp->next_global) tmp->table= 0; mark_used_tables_as_free_for_reuse(thd, thd->temporary_tables); close_thread_tables(thd); } /* Open a single table without table caching and don't set it in open_list Used by alter_table to open a temporary table and when creating a temporary table with CREATE TEMPORARY ... */ TABLE *open_temporary_table(THD *thd, const char *path, const char *db, const char *table_name, bool link_in_list) { TABLE *tmp_table; TABLE_SHARE *share; DBUG_ENTER("open_temporary_table"); /* The extra size in my_malloc() is for table_cache_key 4 bytes for master thread id if we are in the slave 1 byte to terminate db 1 byte to terminate table_name total of 6 extra bytes in my_malloc in addition to table/db stuff */ if (!(tmp_table=(TABLE*) my_malloc(sizeof(*tmp_table)+(uint) strlen(db)+ (uint) strlen(table_name)+6+4, MYF(MY_WME)))) DBUG_RETURN(0); /* purecov: inspected */ if (openfrm(thd, path, table_name, (uint) (HA_OPEN_KEYFILE | HA_OPEN_RNDFILE | HA_GET_INDEX), READ_KEYINFO | COMPUTE_TYPES | EXTRA_RECORD, ha_open_options, tmp_table)) { my_free((char*) tmp_table,MYF(0)); DBUG_RETURN(0); } share= tmp_table->s; tmp_table->reginfo.lock_type=TL_WRITE; // Simulate locked share->tmp_table= (tmp_table->file->has_transactions() ? TRANSACTIONAL_TMP_TABLE : TMP_TABLE); share->table_cache_key= (char*) (tmp_table+1); share->db= share->table_cache_key; share->key_length= (uint) (strmov(((char*) (share->table_name= strmov(share->table_cache_key, db)+1)), table_name) - share->table_cache_key) +1; int4store(share->table_cache_key + share->key_length, thd->server_id); share->key_length+= 4; int4store(share->table_cache_key + share->key_length, thd->variables.pseudo_thread_id); share->key_length+= 4; if (link_in_list) { tmp_table->next=thd->temporary_tables; thd->temporary_tables=tmp_table; if (thd->slave_thread) slave_open_temp_tables++; } DBUG_RETURN(tmp_table); } bool rm_temporary_table(enum db_type base, char *path) { bool error=0; DBUG_ENTER("rm_temporary_table"); fn_format(path, path,"",reg_ext,4); unpack_filename(path,path); if (my_delete(path,MYF(0))) error=1; /* purecov: inspected */ *fn_ext(path)='\0'; // remove extension handler *file= get_new_handler((TABLE*) 0, current_thd->mem_root, base); if (file && file->delete_table(path)) { error=1; sql_print_warning("Could not remove tmp table: '%s', error: %d", path, my_errno); } delete file; DBUG_RETURN(error); } /***************************************************************************** * The following find_field_in_XXX procedures implement the core of the * name resolution functionality. The entry point to resolve a column name in a * list of tables is 'find_field_in_tables'. It calls 'find_field_in_table_ref' * for each table reference. In turn, depending on the type of table reference, * 'find_field_in_table_ref' calls one of the 'find_field_in_XXX' procedures * below specific for the type of table reference. ******************************************************************************/ /* Special Field pointers as return values of find_field_in_XXX functions. */ Field *not_found_field= (Field*) 0x1; Field *view_ref_found= (Field*) 0x2; #define WRONG_GRANT (Field*) -1 static void update_field_dependencies(THD *thd, Field *field, TABLE *table) { if (thd->set_query_id) { if (field->query_id != thd->query_id) { field->query_id= thd->query_id; table->used_fields++; table->used_keys.intersect(field->part_of_key); } else thd->dupp_field= field; } } /* Find a field by name in a view that uses merge algorithm. SYNOPSIS find_field_in_view() thd thread handler table_list view to search for 'name' name name of field length length of name item_name name of item if it will be created (VIEW) ref expression substituted in VIEW should be passed using this reference (return view_ref_found) register_tree_change TRUE if ref is not stack variable and we need register changes in item tree RETURN 0 field is not found view_ref_found found value in VIEW (real result is in *ref) # pointer to field - only for schema table fields */ static Field * find_field_in_view(THD *thd, TABLE_LIST *table_list, const char *name, uint length, const char *item_name, Item **ref, bool register_tree_change) { DBUG_ENTER("find_field_in_view"); DBUG_PRINT("enter", ("view: '%s', field name: '%s', item name: '%s', ref 0x%lx", table_list->alias, name, item_name, (ulong) ref)); Field_iterator_view field_it; field_it.set(table_list); Query_arena *arena, backup; DBUG_ASSERT(table_list->schema_table_reformed || (ref != 0 && table_list->view != 0)); for (; !field_it.end_of_fields(); field_it.next()) { if (!my_strcasecmp(system_charset_info, field_it.name(), name)) { // in PS use own arena or data will be freed after prepare if (register_tree_change) arena= thd->activate_stmt_arena_if_needed(&backup); /* create_item() may, or may not create a new Item, depending on the column reference. See create_view_field() for details. */ Item *item= field_it.create_item(thd); if (register_tree_change && arena) thd->restore_active_arena(arena, &backup); if (!item) DBUG_RETURN(0); /* *ref != NULL means that *ref contains the item that we need to replace. If the item was aliased by the user, set the alias to the replacing item. We need to set alias on both ref itself and on ref real item. */ if (*ref && !(*ref)->is_autogenerated_name) { item->set_name((*ref)->name, (*ref)->name_length, system_charset_info); item->real_item()->set_name((*ref)->name, (*ref)->name_length, system_charset_info); } if (register_tree_change) thd->change_item_tree(ref, item); else *ref= item; DBUG_RETURN((Field*) view_ref_found); } } DBUG_RETURN(0); } /* Find field by name in a NATURAL/USING join table reference. SYNOPSIS find_field_in_natural_join() thd [in] thread handler table_ref [in] table reference to search name [in] name of field length [in] length of name ref [in/out] if 'name' is resolved to a view field, ref is set to point to the found view field register_tree_change [in] TRUE if ref is not stack variable and we need register changes in item tree actual_table [out] the original table reference where the field belongs - differs from 'table_list' only for NATURAL/USING joins DESCRIPTION Search for a field among the result fields of a NATURAL/USING join. Notice that this procedure is called only for non-qualified field names. In the case of qualified fields, we search directly the base tables of a natural join. RETURN NULL if the field was not found WRONG_GRANT if no access rights to the found field # Pointer to the found Field */ static Field * find_field_in_natural_join(THD *thd, TABLE_LIST *table_ref, const char *name, uint length, Item **ref, bool register_tree_change, TABLE_LIST **actual_table) { List_iterator_fast<Natural_join_column> field_it(*(table_ref->join_columns)); Natural_join_column *nj_col; Field *found_field; Query_arena *arena, backup; DBUG_ENTER("find_field_in_natural_join"); DBUG_PRINT("enter", ("field name: '%s', ref 0x%lx", name, (ulong) ref)); DBUG_ASSERT(table_ref->is_natural_join && table_ref->join_columns); DBUG_ASSERT(*actual_table == NULL); LINT_INIT(found_field); for (;;) { if (!(nj_col= field_it++)) DBUG_RETURN(NULL); if (!my_strcasecmp(system_charset_info, nj_col->name(), name)) break; } if (nj_col->view_field) { Item *item; if (register_tree_change) arena= thd->activate_stmt_arena_if_needed(&backup); /* create_item() may, or may not create a new Item, depending on the column reference. See create_view_field() for details. */ item= nj_col->create_item(thd); if (register_tree_change && arena) thd->restore_active_arena(arena, &backup); if (!item) DBUG_RETURN(NULL); DBUG_ASSERT(nj_col->table_field == NULL); if (nj_col->table_ref->schema_table_reformed) { /* Translation table items are always Item_fields and fixed already('mysql_schema_table' function). So we can return ->field. It is used only for 'show & where' commands. */ DBUG_RETURN(((Item_field*) (nj_col->view_field->item))->field); } if (register_tree_change) thd->change_item_tree(ref, item); else *ref= item; found_field= (Field*) view_ref_found; } else { /* This is a base table. */ DBUG_ASSERT(nj_col->view_field == NULL); DBUG_ASSERT(nj_col->table_ref->table == nj_col->table_field->table); found_field= nj_col->table_field; update_field_dependencies(thd, found_field, nj_col->table_ref->table); } *actual_table= nj_col->table_ref; DBUG_RETURN(found_field); } /* Find field by name in a base table or a view with temp table algorithm. SYNOPSIS find_field_in_table() thd thread handler table table where to search for the field name name of field length length of name allow_rowid do allow finding of "_rowid" field? cached_field_index_ptr cached position in field list (used to speedup lookup for fields in prepared tables) RETURN 0 field is not found # pointer to field */ Field * find_field_in_table(THD *thd, TABLE *table, const char *name, uint length, bool allow_rowid, uint *cached_field_index_ptr) { Field **field_ptr, *field; uint cached_field_index= *cached_field_index_ptr; DBUG_ENTER("find_field_in_table"); DBUG_PRINT("enter", ("table: '%s', field name: '%s'", table->alias, name)); /* We assume here that table->field < NO_CACHED_FIELD_INDEX = UINT_MAX */ if (cached_field_index < table->s->fields && !my_strcasecmp(system_charset_info, table->field[cached_field_index]->field_name, name)) field_ptr= table->field + cached_field_index; else if (table->s->name_hash.records) field_ptr= (Field**) hash_search(&table->s->name_hash, (byte*) name, length); else { if (!(field_ptr= table->field)) DBUG_RETURN((Field *)0); for (; *field_ptr; ++field_ptr) if (!my_strcasecmp(system_charset_info, (*field_ptr)->field_name, name)) break; } if (field_ptr && *field_ptr) { *cached_field_index_ptr= field_ptr - table->field; field= *field_ptr; } else { if (!allow_rowid || my_strcasecmp(system_charset_info, name, "_rowid") || !(field=table->rowid_field)) DBUG_RETURN((Field*) 0); } update_field_dependencies(thd, field, table); DBUG_RETURN(field); } /* Find field in a table reference. SYNOPSIS find_field_in_table_ref() thd [in] thread handler table_list [in] table reference to search name [in] name of field length [in] field length of name item_name [in] name of item if it will be created (VIEW) db_name [in] optional database name that qualifies the table_name [in] optional table name that qualifies the field ref [in/out] if 'name' is resolved to a view field, ref is set to point to the found view field check_privileges [in] check privileges allow_rowid [in] do allow finding of "_rowid" field? cached_field_index_ptr [in] cached position in field list (used to speedup lookup for fields in prepared tables) register_tree_change [in] TRUE if ref is not stack variable and we need register changes in item tree actual_table [out] the original table reference where the field belongs - differs from 'table_list' only for NATURAL_USING joins. DESCRIPTION Find a field in a table reference depending on the type of table reference. There are three types of table references with respect to the representation of their result columns: - an array of Field_translator objects for MERGE views and some information_schema tables, - an array of Field objects (and possibly a name hash) for stored tables, - a list of Natural_join_column objects for NATURAL/USING joins. This procedure detects the type of the table reference 'table_list' and calls the corresponding search routine. RETURN 0 field is not found view_ref_found found value in VIEW (real result is in *ref) # pointer to field */ Field * find_field_in_table_ref(THD *thd, TABLE_LIST *table_list, const char *name, uint length, const char *item_name, const char *db_name, const char *table_name, Item **ref, bool check_privileges, bool allow_rowid, uint *cached_field_index_ptr, bool register_tree_change, TABLE_LIST **actual_table) { Field *fld; DBUG_ENTER("find_field_in_table_ref"); DBUG_PRINT("enter", ("table: '%s' field name: '%s' item name: '%s' ref 0x%lx", table_list->alias, name, item_name, (ulong) ref)); /* Check that the table and database that qualify the current field name are the same as the table reference we are going to search for the field. Exclude from the test below nested joins because the columns in a nested join generally originate from different tables. Nested joins also have no table name, except when a nested join is a merge view or an information schema table. We include explicitly table references with a 'field_translation' table, because if there are views over natural joins we don't want to search inside the view, but we want to search directly in the view columns which are represented as a 'field_translation'. TODO: Ensure that table_name, db_name and tables->db always points to something ! */ if (/* Exclude nested joins. */ (!table_list->nested_join || /* Include merge views and information schema tables. */ table_list->field_translation) && /* Test if the field qualifiers match the table reference we plan to search. */ table_name && table_name[0] && (my_strcasecmp(table_alias_charset, table_list->alias, table_name) || (db_name && db_name[0] && table_list->db && table_list->db[0] && strcmp(db_name, table_list->db)))) DBUG_RETURN(0); *actual_table= NULL; if (table_list->field_translation) { /* 'table_list' is a view or an information schema table. */ if ((fld= find_field_in_view(thd, table_list, name, length, item_name, ref, register_tree_change))) *actual_table= table_list; } else if (!table_list->nested_join) { /* 'table_list' is a stored table. */ DBUG_ASSERT(table_list->table); if ((fld= find_field_in_table(thd, table_list->table, name, length, allow_rowid, cached_field_index_ptr))) *actual_table= table_list; } else { /* 'table_list' is a NATURAL/USING join, or an operand of such join that is a nested join itself. If the field name we search for is qualified, then search for the field in the table references used by NATURAL/USING the join. */ if (table_name && table_name[0]) { List_iterator<TABLE_LIST> it(table_list->nested_join->join_list); TABLE_LIST *table; while ((table= it++)) { if ((fld= find_field_in_table_ref(thd, table, name, length, item_name, db_name, table_name, ref, check_privileges, allow_rowid, cached_field_index_ptr, register_tree_change, actual_table))) DBUG_RETURN(fld); } DBUG_RETURN(0); } /* Non-qualified field, search directly in the result columns of the natural join. The condition of the outer IF is true for the top-most natural join, thus if the field is not qualified, we will search directly the top-most NATURAL/USING join. */ fld= find_field_in_natural_join(thd, table_list, name, length, ref, register_tree_change, actual_table); } #ifndef NO_EMBEDDED_ACCESS_CHECKS /* Check if there are sufficient access rights to the found field. */ if (fld && check_privileges && check_column_grant_in_table_ref(thd, *actual_table, name, length)) fld= WRONG_GRANT; #endif DBUG_RETURN(fld); } /* Find field in table list. SYNOPSIS find_field_in_tables() thd pointer to current thread structure item field item that should be found first_table list of tables to be searched for item last_table end of the list of tables to search for item. If NULL then search to the end of the list 'first_table'. ref if 'item' is resolved to a view field, ref is set to point to the found view field report_error Degree of error reporting: - IGNORE_ERRORS then do not report any error - IGNORE_EXCEPT_NON_UNIQUE report only non-unique fields, suppress all other errors - REPORT_EXCEPT_NON_UNIQUE report all other errors except when non-unique fields were found - REPORT_ALL_ERRORS check_privileges need to check privileges register_tree_change TRUE if ref is not a stack variable and we to need register changes in item tree RETURN VALUES 0 If error: the found field is not unique, or there are no sufficient access priviliges for the found field, or the field is qualified with non-existing table. not_found_field The function was called with report_error == (IGNORE_ERRORS || IGNORE_EXCEPT_NON_UNIQUE) and a field was not found. view_ref_found View field is found, item passed through ref parameter found field If a item was resolved to some field */ Field * find_field_in_tables(THD *thd, Item_ident *item, TABLE_LIST *first_table, TABLE_LIST *last_table, Item **ref, find_item_error_report_type report_error, bool check_privileges, bool register_tree_change) { Field *found=0; const char *db= item->db_name; const char *table_name= item->table_name; const char *name= item->field_name; uint length=(uint) strlen(name); char name_buff[NAME_LEN+1]; TABLE_LIST *cur_table= first_table; TABLE_LIST *actual_table; bool allow_rowid; if (!table_name || !table_name[0]) { table_name= 0; // For easier test db= 0; } allow_rowid= table_name || (cur_table && !cur_table->next_local); if (item->cached_table) { /* This shortcut is used by prepared statements. We assume that TABLE_LIST *first_table is not changed during query execution (which is true for all queries except RENAME but luckily RENAME doesn't use fields...) so we can rely on reusing pointer to its member. With this optimization we also miss case when addition of one more field makes some prepared query ambiguous and so erroneous, but we accept this trade off. */ TABLE_LIST *table_ref= item->cached_table; /* The condition (table_ref->view == NULL) ensures that we will call find_field_in_table even in the case of information schema tables when table_ref->field_translation != NULL. */ if (table_ref->table && !table_ref->view) found= find_field_in_table(thd, table_ref->table, name, length, TRUE, &(item->cached_field_index)); else found= find_field_in_table_ref(thd, table_ref, name, length, item->name, NULL, NULL, ref, check_privileges, TRUE, &(item->cached_field_index), register_tree_change, &actual_table); if (found) { if (found == WRONG_GRANT) return (Field*) 0; { SELECT_LEX *current_sel= thd->lex->current_select; SELECT_LEX *last_select= table_ref->select_lex; /* If the field was an outer referencee, mark all selects using this sub query as dependent on the outer query */ if (current_sel != last_select) mark_select_range_as_dependent(thd, last_select, current_sel, found, *ref, item); } return found; } } if (db && lower_case_table_names) { /* convert database to lower case for comparison. We can't do this in Item_field as this would change the 'name' of the item which may be used in the select list */ strmake(name_buff, db, sizeof(name_buff)-1); my_casedn_str(files_charset_info, name_buff); db= name_buff; } if (last_table) last_table= last_table->next_name_resolution_table; for (; cur_table != last_table ; cur_table= cur_table->next_name_resolution_table) { Field *cur_field= find_field_in_table_ref(thd, cur_table, name, length, item->name, db, table_name, ref, check_privileges, allow_rowid, &(item->cached_field_index), register_tree_change, &actual_table); if (cur_field) { if (cur_field == WRONG_GRANT) return (Field*) 0; /* Store the original table of the field, which may be different from cur_table in the case of NATURAL/USING join. */ item->cached_table= (!actual_table->cacheable_table || found) ? 0 : actual_table; DBUG_ASSERT(thd->where); /* If we found a fully qualified field we return it directly as it can't have duplicates. */ if (db) return cur_field; if (found) { if (report_error == REPORT_ALL_ERRORS || report_error == IGNORE_EXCEPT_NON_UNIQUE) my_error(ER_NON_UNIQ_ERROR, MYF(0), table_name ? item->full_name() : name, thd->where); return (Field*) 0; } found= cur_field; } } if (found) return found; /* If the field was qualified and there were no tables to search, issue an error that an unknown table was given. The situation is detected as follows: if there were no tables we wouldn't go through the loop and cur_table wouldn't be updated by the loop increment part, so it will be equal to the first table. */ if (table_name && (cur_table == first_table) && (report_error == REPORT_ALL_ERRORS || report_error == REPORT_EXCEPT_NON_UNIQUE)) { char buff[NAME_LEN*2+1]; if (db && db[0]) { strxnmov(buff,sizeof(buff)-1,db,".",table_name,NullS); table_name=buff; } my_error(ER_UNKNOWN_TABLE, MYF(0), table_name, thd->where); } else { if (report_error == REPORT_ALL_ERRORS || report_error == REPORT_EXCEPT_NON_UNIQUE) my_error(ER_BAD_FIELD_ERROR, MYF(0), item->full_name(), thd->where); else found= not_found_field; } return found; } /* Find Item in list of items (find_field_in_tables analog) TODO is it better return only counter? SYNOPSIS find_item_in_list() find Item to find items List of items counter To return number of found item report_error REPORT_ALL_ERRORS report errors, return 0 if error REPORT_EXCEPT_NOT_FOUND Do not report 'not found' error and return not_found_item, report other errors, return 0 IGNORE_ERRORS Do not report errors, return 0 if error unaliased Set to true if item is field which was found by original field name and not by its alias in item list. Set to false otherwise. RETURN VALUES 0 Item is not found or item is not unique, error message is reported not_found_item Function was called with report_error == REPORT_EXCEPT_NOT_FOUND and item was not found. No error message was reported found field */ /* Special Item pointer to serve as a return value from find_item_in_list(). */ Item **not_found_item= (Item**) 0x1; Item ** find_item_in_list(Item *find, List<Item> &items, uint *counter, find_item_error_report_type report_error, bool *unaliased) { List_iterator<Item> li(items); Item **found=0, **found_unaliased= 0, *item; const char *db_name=0; const char *field_name=0; const char *table_name=0; bool found_unaliased_non_uniq= 0; uint unaliased_counter; LINT_INIT(unaliased_counter); // Dependent on found_unaliased *unaliased= FALSE; if (find->type() == Item::FIELD_ITEM || find->type() == Item::REF_ITEM) { field_name= ((Item_ident*) find)->field_name; table_name= ((Item_ident*) find)->table_name; db_name= ((Item_ident*) find)->db_name; } for (uint i= 0; (item=li++); i++) { if (field_name && item->real_item()->type() == Item::FIELD_ITEM) { Item_ident *item_field= (Item_ident*) item; /* In case of group_concat() with ORDER BY condition in the QUERY item_field can be field of temporary table without item name (if this field created from expression argument of group_concat()), => we have to check presence of name before compare */ if (!item_field->name) continue; if (table_name) { /* If table name is specified we should find field 'field_name' in table 'table_name'. According to SQL-standard we should ignore aliases in this case. Since we should NOT prefer fields from the select list over other fields from the tables participating in this select in case of ambiguity we have to do extra check outside this function. We use strcmp for table names and database names as these may be case sensitive. In cases where they are not case sensitive, they are always in lower case. item_field->field_name and item_field->table_name can be 0x0 if item is not fix_field()'ed yet. */ if (item_field->field_name && item_field->table_name && !my_strcasecmp(system_charset_info, item_field->field_name, field_name) && !strcmp(item_field->table_name, table_name) && (!db_name || (item_field->db_name && !strcmp(item_field->db_name, db_name)))) { if (found_unaliased) { if ((*found_unaliased)->eq(item, 0)) continue; /* Two matching fields in select list. We already can bail out because we are searching through unaliased names only and will have duplicate error anyway. */ if (report_error != IGNORE_ERRORS) my_error(ER_NON_UNIQ_ERROR, MYF(0), find->full_name(), current_thd->where); return (Item**) 0; } found_unaliased= li.ref(); unaliased_counter= i; if (db_name) break; // Perfect match } } else if (!my_strcasecmp(system_charset_info, item_field->name, field_name)) { /* If table name was not given we should scan through aliases (or non-aliased fields) first. We are also checking unaliased name of the field in then next else-if, to be able to find instantly field (hidden by alias) if no suitable alias (or non-aliased field) was found. */ if (found) { if ((*found)->eq(item, 0)) continue; // Same field twice if (report_error != IGNORE_ERRORS) my_error(ER_NON_UNIQ_ERROR, MYF(0), find->full_name(), current_thd->where); return (Item**) 0; } found= li.ref(); *counter= i; } else if (!my_strcasecmp(system_charset_info, item_field->field_name, field_name)) { /* We will use un-aliased field or react on such ambiguities only if we won't be able to find aliased field. Again if we have ambiguity with field outside of select list we should prefer fields from select list. */ if (found_unaliased) { if ((*found_unaliased)->eq(item, 0)) continue; // Same field twice found_unaliased_non_uniq= 1; } else { found_unaliased= li.ref(); unaliased_counter= i; } } } else if (!table_name && (find->eq(item,0) || find->name && item->name && !my_strcasecmp(system_charset_info, item->name,find->name))) { found= li.ref(); *counter= i; break; } } if (!found) { if (found_unaliased_non_uniq) { if (report_error != IGNORE_ERRORS) my_error(ER_NON_UNIQ_ERROR, MYF(0), find->full_name(), current_thd->where); return (Item **) 0; } if (found_unaliased) { found= found_unaliased; *counter= unaliased_counter; *unaliased= TRUE; } } if (found) return found; if (report_error != REPORT_EXCEPT_NOT_FOUND) { if (report_error == REPORT_ALL_ERRORS) my_error(ER_BAD_FIELD_ERROR, MYF(0), find->full_name(), current_thd->where); return (Item **) 0; } else return (Item **) not_found_item; } /* Test if a string is a member of a list of strings. SYNOPSIS test_if_string_in_list() find the string to look for str_list a list of strings to be searched DESCRIPTION Sequentially search a list of strings for a string, and test whether the list contains the same string. RETURN TRUE if find is in str_list FALSE otherwise */ static bool test_if_string_in_list(const char *find, List<String> *str_list) { List_iterator<String> str_list_it(*str_list); String *curr_str; size_t find_length= strlen(find); while ((curr_str= str_list_it++)) { if (find_length != curr_str->length()) continue; if (!my_strcasecmp(system_charset_info, find, curr_str->ptr())) return TRUE; } return FALSE; } /* Create a new name resolution context for an item so that it is being resolved in a specific table reference. SYNOPSIS set_new_item_local_context() thd pointer to current thread item item for which new context is created and set table_ref table ref where an item showld be resolved DESCRIPTION Create a new name resolution context for an item, so that the item is resolved only the supplied 'table_ref'. RETURN FALSE if all OK TRUE otherwise */ static bool set_new_item_local_context(THD *thd, Item_ident *item, TABLE_LIST *table_ref) { Name_resolution_context *context; if (!(context= new (thd->mem_root) Name_resolution_context)) return TRUE; context->init(); context->first_name_resolution_table= context->last_name_resolution_table= table_ref; item->context= context; return FALSE; } /* Find and mark the common columns of two table references. SYNOPSIS mark_common_columns() thd [in] current thread table_ref_1 [in] the first (left) join operand table_ref_2 [in] the second (right) join operand using_fields [in] if the join is JOIN...USING - the join columns, if NATURAL join, then NULL found_using_fields [out] number of fields from the USING clause that were found among the common fields DESCRIPTION The procedure finds the common columns of two relations (either tables or intermediate join results), and adds an equi-join condition to the ON clause of 'table_ref_2' for each pair of matching columns. If some of table_ref_XXX represents a base table or view, then we create new 'Natural_join_column' instances for each column reference and store them in the 'join_columns' of the table reference. IMPLEMENTATION The procedure assumes that store_natural_using_join_columns() was called for the previous level of NATURAL/USING joins. RETURN TRUE error when some common column is non-unique, or out of memory FALSE OK */ static bool mark_common_columns(THD *thd, TABLE_LIST *table_ref_1, TABLE_LIST *table_ref_2, List<String> *using_fields, uint *found_using_fields) { Field_iterator_table_ref it_1, it_2; Natural_join_column *nj_col_1, *nj_col_2; Query_arena *arena, backup; bool result= TRUE; bool first_outer_loop= TRUE; /* Leaf table references to which new natural join columns are added if the leaves are != NULL. */ TABLE_LIST *leaf_1= (table_ref_1->nested_join && !table_ref_1->is_natural_join) ? NULL : table_ref_1; TABLE_LIST *leaf_2= (table_ref_2->nested_join && !table_ref_2->is_natural_join) ? NULL : table_ref_2; DBUG_ENTER("mark_common_columns"); DBUG_PRINT("info", ("operand_1: %s operand_2: %s", table_ref_1->alias, table_ref_2->alias)); *found_using_fields= 0; arena= thd->activate_stmt_arena_if_needed(&backup); for (it_1.set(table_ref_1); !it_1.end_of_fields(); it_1.next()) { bool found= FALSE; const char *field_name_1; if (!(nj_col_1= it_1.get_or_create_column_ref(leaf_1))) goto err; field_name_1= nj_col_1->name(); /* Find a field with the same name in table_ref_2. Note that for the second loop, it_2.set() will iterate over table_ref_2->join_columns and not generate any new elements or lists. */ nj_col_2= NULL; for (it_2.set(table_ref_2); !it_2.end_of_fields(); it_2.next()) { Natural_join_column *cur_nj_col_2; const char *cur_field_name_2; if (!(cur_nj_col_2= it_2.get_or_create_column_ref(leaf_2))) goto err; cur_field_name_2= cur_nj_col_2->name(); /* Compare the two columns and check for duplicate common fields. A common field is duplicate either if it was already found in table_ref_2 (then found == TRUE), or if a field in table_ref_2 was already matched by some previous field in table_ref_1 (then cur_nj_col_2->is_common == TRUE). */ if (!my_strcasecmp(system_charset_info, field_name_1, cur_field_name_2)) { if (found || cur_nj_col_2->is_common) { my_error(ER_NON_UNIQ_ERROR, MYF(0), field_name_1, thd->where); goto err; } nj_col_2= cur_nj_col_2; found= TRUE; } } if (first_outer_loop && leaf_2) { /* Make sure that the next inner loop "knows" that all columns are materialized already. */ leaf_2->is_join_columns_complete= TRUE; first_outer_loop= FALSE; } if (!found) continue; // No matching field /* field_1 and field_2 have the same names. Check if they are in the USING clause (if present), mark them as common fields, and add a new equi-join condition to the ON clause. */ if (nj_col_2 && (!using_fields || test_if_string_in_list(field_name_1, using_fields))) { Item *item_1= nj_col_1->create_item(thd); Item *item_2= nj_col_2->create_item(thd); Field *field_1= nj_col_1->field(); Field *field_2= nj_col_2->field(); Item_ident *item_ident_1, *item_ident_2; Item_func_eq *eq_cond; if (!item_1 || !item_2) goto err; // out of memory /* The following assert checks that the two created items are of type Item_ident. */ DBUG_ASSERT(!thd->lex->current_select->no_wrap_view_item); /* In the case of no_wrap_view_item == 0, the created items must be of sub-classes of Item_ident. */ DBUG_ASSERT(item_1->type() == Item::FIELD_ITEM || item_1->type() == Item::REF_ITEM); DBUG_ASSERT(item_2->type() == Item::FIELD_ITEM || item_2->type() == Item::REF_ITEM); /* We need to cast item_1,2 to Item_ident, because we need to hook name resolution contexts specific to each item. */ item_ident_1= (Item_ident*) item_1; item_ident_2= (Item_ident*) item_2; /* Create and hook special name resolution contexts to each item in the new join condition . We need this to both speed-up subsequent name resolution of these items, and to enable proper name resolution of the items during the execute phase of PS. */ if (set_new_item_local_context(thd, item_ident_1, nj_col_1->table_ref) || set_new_item_local_context(thd, item_ident_2, nj_col_2->table_ref)) goto err; if (!(eq_cond= new Item_func_eq(item_ident_1, item_ident_2))) goto err; /* Out of memory. */ /* Add the new equi-join condition to the ON clause. Notice that fix_fields() is applied to all ON conditions in setup_conds() so we don't do it here. */ add_join_on((table_ref_1->outer_join & JOIN_TYPE_RIGHT ? table_ref_1 : table_ref_2), eq_cond); nj_col_1->is_common= nj_col_2->is_common= TRUE; if (field_1) { /* Mark field_1 used for table cache. */ field_1->query_id= thd->query_id; nj_col_1->table_ref->table->used_keys.intersect(field_1->part_of_key); } if (field_2) { /* Mark field_2 used for table cache. */ field_2->query_id= thd->query_id; nj_col_2->table_ref->table->used_keys.intersect(field_2->part_of_key); } if (using_fields != NULL) ++(*found_using_fields); } } if (leaf_1) leaf_1->is_join_columns_complete= TRUE; /* Everything is OK. Notice that at this point there may be some column names in the USING clause that are not among the common columns. This is an SQL error and we check for this error in store_natural_using_join_columns() when (found_using_fields < length(join_using_fields)). */ result= FALSE; err: if (arena) thd->restore_active_arena(arena, &backup); DBUG_RETURN(result); } /* Materialize and store the row type of NATURAL/USING join. SYNOPSIS store_natural_using_join_columns() thd current thread natural_using_join the table reference of the NATURAL/USING join table_ref_1 the first (left) operand (of a NATURAL/USING join). table_ref_2 the second (right) operand (of a NATURAL/USING join). using_fields if the join is JOIN...USING - the join columns, if NATURAL join, then NULL found_using_fields number of fields from the USING clause that were found among the common fields DESCRIPTION Iterate over the columns of both join operands and sort and store all columns into the 'join_columns' list of natural_using_join where the list is formed by three parts: part1: The coalesced columns of table_ref_1 and table_ref_2, sorted according to the column order of the first table. part2: The other columns of the first table, in the order in which they were defined in CREATE TABLE. part3: The other columns of the second table, in the order in which they were defined in CREATE TABLE. Time complexity - O(N1+N2), where Ni = length(table_ref_i). IMPLEMENTATION The procedure assumes that mark_common_columns() has been called for the join that is being processed. RETURN TRUE error: Some common column is ambiguous FALSE OK */ static bool store_natural_using_join_columns(THD *thd, TABLE_LIST *natural_using_join, TABLE_LIST *table_ref_1, TABLE_LIST *table_ref_2, List<String> *using_fields, uint found_using_fields) { Field_iterator_table_ref it_1, it_2; Natural_join_column *nj_col_1, *nj_col_2; Query_arena *arena, backup; bool result= TRUE; List<Natural_join_column> *non_join_columns; DBUG_ENTER("store_natural_using_join_columns"); DBUG_ASSERT(!natural_using_join->join_columns); arena= thd->activate_stmt_arena_if_needed(&backup); if (!(non_join_columns= new List<Natural_join_column>) || !(natural_using_join->join_columns= new List<Natural_join_column>)) goto err; /* Append the columns of the first join operand. */ for (it_1.set(table_ref_1); !it_1.end_of_fields(); it_1.next()) { nj_col_1= it_1.get_natural_column_ref(); if (nj_col_1->is_common) { natural_using_join->join_columns->push_back(nj_col_1); /* Reset the common columns for the next call to mark_common_columns. */ nj_col_1->is_common= FALSE; } else non_join_columns->push_back(nj_col_1); } /* Check that all columns in the USING clause are among the common columns. If this is not the case, report the first one that was not found in an error. */ if (using_fields && found_using_fields < using_fields->elements) { String *using_field_name; List_iterator_fast<String> using_fields_it(*using_fields); while ((using_field_name= using_fields_it++)) { const char *using_field_name_ptr= using_field_name->c_ptr(); List_iterator_fast<Natural_join_column> it(*(natural_using_join->join_columns)); Natural_join_column *common_field; for (;;) { /* If reached the end of fields, and none was found, report error. */ if (!(common_field= it++)) { my_error(ER_BAD_FIELD_ERROR, MYF(0), using_field_name_ptr, current_thd->where); goto err; } if (!my_strcasecmp(system_charset_info, common_field->name(), using_field_name_ptr)) break; // Found match } } } /* Append the non-equi-join columns of the second join operand. */ for (it_2.set(table_ref_2); !it_2.end_of_fields(); it_2.next()) { nj_col_2= it_2.get_natural_column_ref(); if (!nj_col_2->is_common) non_join_columns->push_back(nj_col_2); else { /* Reset the common columns for the next call to mark_common_columns. */ nj_col_2->is_common= FALSE; } } if (non_join_columns->elements > 0) natural_using_join->join_columns->concat(non_join_columns); natural_using_join->is_join_columns_complete= TRUE; result= FALSE; err: if (arena) thd->restore_active_arena(arena, &backup); DBUG_RETURN(result); } /* Precompute and store the row types of the top-most NATURAL/USING joins. SYNOPSIS store_top_level_join_columns() thd current thread table_ref nested join or table in a FROM clause left_neighbor neighbor table reference to the left of table_ref at the same level in the join tree right_neighbor neighbor table reference to the right of table_ref at the same level in the join tree DESCRIPTION The procedure performs a post-order traversal of a nested join tree and materializes the row types of NATURAL/USING joins in a bottom-up manner until it reaches the TABLE_LIST elements that represent the top-most NATURAL/USING joins. The procedure should be applied to each element of SELECT_LEX::top_join_list (i.e. to each top-level element of the FROM clause). IMPLEMENTATION Notice that the table references in the list nested_join->join_list are in reverse order, thus when we iterate over it, we are moving from the right to the left in the FROM clause. RETURN TRUE Error FALSE OK */ static bool store_top_level_join_columns(THD *thd, TABLE_LIST *table_ref, TABLE_LIST *left_neighbor, TABLE_LIST *right_neighbor) { Query_arena *arena, backup; bool result= TRUE; DBUG_ENTER("store_top_level_join_columns"); arena= thd->activate_stmt_arena_if_needed(&backup); /* Call the procedure recursively for each nested table reference. */ if (table_ref->nested_join) { List_iterator_fast<TABLE_LIST> nested_it(table_ref->nested_join->join_list); TABLE_LIST *cur_left_neighbor= nested_it++; TABLE_LIST *cur_right_neighbor= NULL; while (cur_left_neighbor) { TABLE_LIST *cur_table_ref= cur_left_neighbor; cur_left_neighbor= nested_it++; /* The order of RIGHT JOIN operands is reversed in 'join list' to transform it into a LEFT JOIN. However, in this procedure we need the join operands in their lexical order, so below we reverse the join operands. Notice that this happens only in the first loop, and not in the second one, as in the second loop cur_left_neighbor == NULL. This is the correct behavior, because the second loop sets cur_table_ref reference correctly after the join operands are swapped in the first loop. */ if (cur_left_neighbor && cur_table_ref->outer_join & JOIN_TYPE_RIGHT) { /* This can happen only for JOIN ... ON. */ DBUG_ASSERT(table_ref->nested_join->join_list.elements == 2); swap_variables(TABLE_LIST*, cur_left_neighbor, cur_table_ref); } if (cur_table_ref->nested_join && store_top_level_join_columns(thd, cur_table_ref, cur_left_neighbor, cur_right_neighbor)) goto err; cur_right_neighbor= cur_table_ref; } } /* If this is a NATURAL/USING join, materialize its result columns and convert to a JOIN ... ON. */ if (table_ref->is_natural_join) { DBUG_ASSERT(table_ref->nested_join && table_ref->nested_join->join_list.elements == 2); List_iterator_fast<TABLE_LIST> operand_it(table_ref->nested_join->join_list); /* Notice that the order of join operands depends on whether table_ref represents a LEFT or a RIGHT join. In a RIGHT join, the operands are in inverted order. */ TABLE_LIST *table_ref_2= operand_it++; /* Second NATURAL join operand.*/ TABLE_LIST *table_ref_1= operand_it++; /* First NATURAL join operand. */ List<String> *using_fields= table_ref->join_using_fields; uint found_using_fields; /* The two join operands were interchanged in the parser, change the order back for 'mark_common_columns'. */ if (table_ref_2->outer_join & JOIN_TYPE_RIGHT) swap_variables(TABLE_LIST*, table_ref_1, table_ref_2); if (mark_common_columns(thd, table_ref_1, table_ref_2, using_fields, &found_using_fields)) goto err; /* Swap the join operands back, so that we pick the columns of the second one as the coalesced columns. In this way the coalesced columns are the same as of an equivalent LEFT JOIN. */ if (table_ref_1->outer_join & JOIN_TYPE_RIGHT) swap_variables(TABLE_LIST*, table_ref_1, table_ref_2); if (store_natural_using_join_columns(thd, table_ref, table_ref_1, table_ref_2, using_fields, found_using_fields)) goto err; /* Change NATURAL JOIN to JOIN ... ON. We do this for both operands because either one of them or the other is the one with the natural join flag because RIGHT joins are transformed into LEFT, and the two tables may be reordered. */ table_ref_1->natural_join= table_ref_2->natural_join= NULL; /* Add a TRUE condition to outer joins that have no common columns. */ if (table_ref_2->outer_join && !table_ref_1->on_expr && !table_ref_2->on_expr) table_ref_2->on_expr= new Item_int((longlong) 1,1); /* Always true. */ /* Change this table reference to become a leaf for name resolution. */ if (left_neighbor) { TABLE_LIST *last_leaf_on_the_left; last_leaf_on_the_left= left_neighbor->last_leaf_for_name_resolution(); last_leaf_on_the_left->next_name_resolution_table= table_ref; } if (right_neighbor) { TABLE_LIST *first_leaf_on_the_right; first_leaf_on_the_right= right_neighbor->first_leaf_for_name_resolution(); table_ref->next_name_resolution_table= first_leaf_on_the_right; } else table_ref->next_name_resolution_table= NULL; } result= FALSE; /* All is OK. */ err: if (arena) thd->restore_active_arena(arena, &backup); DBUG_RETURN(result); } /* Compute and store the row types of the top-most NATURAL/USING joins in a FROM clause. SYNOPSIS setup_natural_join_row_types() thd current thread from_clause list of top-level table references in a FROM clause DESCRIPTION Apply the procedure 'store_top_level_join_columns' to each of the top-level table referencs of the FROM clause. Adjust the list of tables for name resolution - context->first_name_resolution_table to the top-most, lef-most NATURAL/USING join. IMPLEMENTATION Notice that the table references in 'from_clause' are in reverse order, thus when we iterate over it, we are moving from the right to the left in the FROM clause. RETURN TRUE Error FALSE OK */ static bool setup_natural_join_row_types(THD *thd, List<TABLE_LIST> *from_clause, Name_resolution_context *context) { thd->where= "from clause"; if (from_clause->elements == 0) return FALSE; /* We come here in the case of UNIONs. */ List_iterator_fast<TABLE_LIST> table_ref_it(*from_clause); TABLE_LIST *table_ref; /* Current table reference. */ /* Table reference to the left of the current. */ TABLE_LIST *left_neighbor; /* Table reference to the right of the current. */ TABLE_LIST *right_neighbor= NULL; /* Note that tables in the list are in reversed order */ for (left_neighbor= table_ref_it++; left_neighbor ; ) { table_ref= left_neighbor; left_neighbor= table_ref_it++; /* For stored procedures do not redo work if already done. */ if (context->select_lex->first_execution) { if (store_top_level_join_columns(thd, table_ref, left_neighbor, right_neighbor)) return TRUE; if (left_neighbor) { TABLE_LIST *first_leaf_on_the_right; first_leaf_on_the_right= table_ref->first_leaf_for_name_resolution(); left_neighbor->next_name_resolution_table= first_leaf_on_the_right; } } right_neighbor= table_ref; } /* Store the top-most, left-most NATURAL/USING join, so that we start the search from that one instead of context->table_list. At this point right_neighbor points to the left-most top-level table reference in the FROM clause. */ DBUG_ASSERT(right_neighbor); context->first_name_resolution_table= right_neighbor->first_leaf_for_name_resolution(); return FALSE; } /**************************************************************************** ** Expand all '*' in given fields ****************************************************************************/ int setup_wild(THD *thd, TABLE_LIST *tables, List<Item> &fields, List<Item> *sum_func_list, uint wild_num) { if (!wild_num) return(0); Item *item; List_iterator<Item> it(fields); Query_arena *arena, backup; DBUG_ENTER("setup_wild"); /* Don't use arena if we are not in prepared statements or stored procedures For PS/SP we have to use arena to remember the changes */ arena= thd->activate_stmt_arena_if_needed(&backup); while (wild_num && (item= it++)) { if (item->type() == Item::FIELD_ITEM && ((Item_field*) item)->field_name && ((Item_field*) item)->field_name[0] == '*' && !((Item_field*) item)->field) { uint elem= fields.elements; bool any_privileges= ((Item_field *) item)->any_privileges; Item_subselect *subsel= thd->lex->current_select->master_unit()->item; if (subsel && subsel->substype() == Item_subselect::EXISTS_SUBS) { /* It is EXISTS(SELECT * ...) and we can replace * by any constant. Item_int do not need fix_fields() because it is basic constant. */ it.replace(new Item_int("Not_used", (longlong) 1, 21)); } else if (insert_fields(thd, ((Item_field*) item)->context, ((Item_field*) item)->db_name, ((Item_field*) item)->table_name, &it, any_privileges)) { if (arena) thd->restore_active_arena(arena, &backup); DBUG_RETURN(-1); } if (sum_func_list) { /* sum_func_list is a list that has the fields list as a tail. Because of this we have to update the element count also for this list after expanding the '*' entry. */ sum_func_list->elements+= fields.elements - elem; } wild_num--; } } if (arena) { /* make * substituting permanent */ SELECT_LEX *select_lex= thd->lex->current_select; select_lex->with_wild= 0; select_lex->item_list= fields; thd->restore_active_arena(arena, &backup); } DBUG_RETURN(0); } /**************************************************************************** ** Check that all given fields exists and fill struct with current data ****************************************************************************/ bool setup_fields(THD *thd, Item **ref_pointer_array, List<Item> &fields, bool set_query_id, List<Item> *sum_func_list, bool allow_sum_func) { reg2 Item *item; bool save_set_query_id= thd->set_query_id; nesting_map save_allow_sum_func= thd->lex->allow_sum_func; List_iterator<Item> it(fields); DBUG_ENTER("setup_fields"); thd->set_query_id=set_query_id; if (allow_sum_func) thd->lex->allow_sum_func|= 1 << thd->lex->current_select->nest_level; thd->where= THD::DEFAULT_WHERE; /* To prevent fail on forward lookup we fill it with zerows, then if we got pointer on zero after find_item_in_list we will know that it is forward lookup. There is other way to solve problem: fill array with pointers to list, but it will be slower. TODO: remove it when (if) we made one list for allfields and ref_pointer_array */ if (ref_pointer_array) bzero(ref_pointer_array, sizeof(Item *) * fields.elements); Item **ref= ref_pointer_array; while ((item= it++)) { if (!item->fixed && item->fix_fields(thd, it.ref()) || (item= *(it.ref()))->check_cols(1)) { thd->lex->allow_sum_func= save_allow_sum_func; thd->set_query_id= save_set_query_id; DBUG_RETURN(TRUE); /* purecov: inspected */ } if (ref) *(ref++)= item; if (item->with_sum_func && item->type() != Item::SUM_FUNC_ITEM && sum_func_list) item->split_sum_func(thd, ref_pointer_array, *sum_func_list); thd->used_tables|= item->used_tables(); } thd->lex->allow_sum_func= save_allow_sum_func; thd->set_query_id= save_set_query_id; DBUG_RETURN(test(thd->net.report_error)); } /* make list of leaves of join table tree SYNOPSIS make_leaves_list() list pointer to pointer on list first element tables table list RETURN pointer on pointer to next_leaf of last element */ TABLE_LIST **make_leaves_list(TABLE_LIST **list, TABLE_LIST *tables) { for (TABLE_LIST *table= tables; table; table= table->next_local) { if (table->merge_underlying_list) { DBUG_ASSERT(table->view && table->effective_algorithm == VIEW_ALGORITHM_MERGE); list= make_leaves_list(list, table->merge_underlying_list); } else { *list= table; list= &table->next_leaf; } } return list; } /* prepare tables SYNOPSIS setup_tables() thd Thread handler context name resolution contest to setup table list there from_clause Top-level list of table references in the FROM clause tables Table list (select_lex->table_list) conds Condition of current SELECT (can be changed by VIEW) leaves List of join table leaves list (select_lex->leaf_tables) refresh It is onle refresh for subquery select_insert It is SELECT ... INSERT command NOTE Check also that the 'used keys' and 'ignored keys' exists and set up the table structure accordingly. Create a list of leaf tables. For queries with NATURAL/USING JOINs, compute the row types of the top most natural/using join table references and link these into a list of table references for name resolution. This has to be called for all tables that are used by items, as otherwise table->map is not set and all Item_field will be regarded as const items. RETURN FALSE ok; In this case *map will includes the chosen index TRUE error */ bool setup_tables(THD *thd, Name_resolution_context *context, List<TABLE_LIST> *from_clause, TABLE_LIST *tables, Item **conds, TABLE_LIST **leaves, bool select_insert) { uint tablenr= 0; DBUG_ENTER("setup_tables"); context->table_list= context->first_name_resolution_table= tables; /* this is used for INSERT ... SELECT. For select we setup tables except first (and its underlying tables) */ TABLE_LIST *first_select_table= (select_insert ? tables->next_local: 0); if (!(*leaves)) make_leaves_list(leaves, tables); TABLE_LIST *table_list; for (table_list= *leaves; table_list; table_list= table_list->next_leaf, tablenr++) { TABLE *table= table_list->table; table->pos_in_table_list= table_list; if (first_select_table && table_list->top_table() == first_select_table) { /* new counting for SELECT of INSERT ... SELECT command */ first_select_table= 0; tablenr= 0; } setup_table_map(table, table_list, tablenr); table->used_keys= table->s->keys_for_keyread; if (table_list->use_index) { key_map map; get_key_map_from_key_list(&map, table, table_list->use_index); if (map.is_set_all()) DBUG_RETURN(1); table->keys_in_use_for_query=map; } if (table_list->ignore_index) { key_map map; get_key_map_from_key_list(&map, table, table_list->ignore_index); if (map.is_set_all()) DBUG_RETURN(1); table->keys_in_use_for_query.subtract(map); } table->used_keys.intersect(table->keys_in_use_for_query); } if (tablenr > MAX_TABLES) { my_error(ER_TOO_MANY_TABLES,MYF(0),MAX_TABLES); DBUG_RETURN(1); } for (table_list= tables; table_list; table_list= table_list->next_local) { if (table_list->merge_underlying_list) { DBUG_ASSERT(table_list->view && table_list->effective_algorithm == VIEW_ALGORITHM_MERGE); Query_arena *arena= thd->stmt_arena, backup; bool res; if (arena->is_conventional()) arena= 0; // For easier test else thd->set_n_backup_active_arena(arena, &backup); res= table_list->setup_underlying(thd); if (arena) thd->restore_active_arena(arena, &backup); if (res) DBUG_RETURN(1); } } /* Precompute and store the row types of NATURAL/USING joins. */ if (setup_natural_join_row_types(thd, from_clause, context)) DBUG_RETURN(1); DBUG_RETURN(0); } /* prepare tables and check access for the view tables SYNOPSIS setup_tables_and_check_view_access() thd Thread handler context name resolution contest to setup table list there from_clause Top-level list of table references in the FROM clause tables Table list (select_lex->table_list) conds Condition of current SELECT (can be changed by VIEW) leaves List of join table leaves list (select_lex->leaf_tables) refresh It is onle refresh for subquery select_insert It is SELECT ... INSERT command want_access what access is needed NOTE a wrapper for check_tables that will also check the resulting table leaves list for access to all the tables that belong to a view RETURN FALSE ok; In this case *map will include the chosen index TRUE error */ bool setup_tables_and_check_access(THD *thd, Name_resolution_context *context, List<TABLE_LIST> *from_clause, TABLE_LIST *tables, Item **conds, TABLE_LIST **leaves, bool select_insert, ulong want_access) { TABLE_LIST *leaves_tmp = NULL; if (setup_tables (thd, context, from_clause, tables, conds, &leaves_tmp, select_insert)) return TRUE; if (leaves) *leaves = leaves_tmp; for (; leaves_tmp; leaves_tmp= leaves_tmp->next_leaf) if (leaves_tmp->belong_to_view && check_single_table_access(thd, want_access, leaves_tmp)) { tables->hide_view_error(thd); return TRUE; } return FALSE; } /* Create a key_map from a list of index names SYNOPSIS get_key_map_from_key_list() map key_map to fill in table Table index_list List of index names RETURN 0 ok; In this case *map will includes the choosed index 1 error */ bool get_key_map_from_key_list(key_map *map, TABLE *table, List<String> *index_list) { List_iterator_fast<String> it(*index_list); String *name; uint pos; map->clear_all(); while ((name=it++)) { if (table->s->keynames.type_names == 0 || (pos= find_type(&table->s->keynames, name->ptr(), name->length(), 1)) <= 0) { my_error(ER_KEY_DOES_NOT_EXITS, MYF(0), name->c_ptr(), table->pos_in_table_list->alias); map->set_all(); return 1; } map->set_bit(pos-1); } return 0; } /* Drops in all fields instead of current '*' field SYNOPSIS insert_fields() thd Thread handler context Context for name resolution db_name Database name in case of 'database_name.table_name.*' table_name Table name in case of 'table_name.*' it Pointer to '*' any_privileges 0 If we should ensure that we have SELECT privileges for all columns 1 If any privilege is ok RETURN 0 ok 'it' is updated to point at last inserted 1 error. Error message is generated but not sent to client */ bool insert_fields(THD *thd, Name_resolution_context *context, const char *db_name, const char *table_name, List_iterator<Item> *it, bool any_privileges) { Field_iterator_table_ref field_iterator; bool found; char name_buff[NAME_LEN+1]; DBUG_ENTER("insert_fields"); DBUG_PRINT("arena", ("stmt arena: 0x%lx", (ulong)thd->stmt_arena)); if (db_name && lower_case_table_names) { /* convert database to lower case for comparison We can't do this in Item_field as this would change the 'name' of the item which may be used in the select list */ strmake(name_buff, db_name, sizeof(name_buff)-1); my_casedn_str(files_charset_info, name_buff); db_name= name_buff; } found= FALSE; /* If table names are qualified, then loop over all tables used in the query, else treat natural joins as leaves and do not iterate over their underlying tables. */ for (TABLE_LIST *tables= (table_name ? context->table_list : context->first_name_resolution_table); tables; tables= (table_name ? tables->next_local : tables->next_name_resolution_table) ) { Field *field; TABLE *table= tables->table; DBUG_ASSERT(tables->is_leaf_for_name_resolution()); if (table_name && my_strcasecmp(table_alias_charset, table_name, tables->alias) || (db_name && strcmp(tables->db,db_name))) continue; #ifndef NO_EMBEDDED_ACCESS_CHECKS /* Ensure that we have access rights to all fields to be inserted. */ if (!((table && (table->grant.privilege & SELECT_ACL) || tables->view && (tables->grant.privilege & SELECT_ACL))) && !any_privileges) { field_iterator.set(tables); if (check_grant_all_columns(thd, SELECT_ACL, field_iterator.grant(), field_iterator.db_name(), field_iterator.table_name(), &field_iterator)) DBUG_RETURN(TRUE); } #endif /* Update the tables used in the query based on the referenced fields. For views and natural joins this update is performed inside the loop below. */ if (table) thd->used_tables|= table->map; /* Initialize a generic field iterator for the current table reference. Notice that it is guaranteed that this iterator will iterate over the fields of a single table reference, because 'tables' is a leaf (for name resolution purposes). */ field_iterator.set(tables); for (; !field_iterator.end_of_fields(); field_iterator.next()) { Item *item; if (!(item= field_iterator.create_item(thd))) DBUG_RETURN(TRUE); if (!found) { found= TRUE; it->replace(item); /* Replace '*' with the first found item. */ } else it->after(item); /* Add 'item' to the SELECT list. */ #ifndef NO_EMBEDDED_ACCESS_CHECKS /* Set privilege information for the fields of newly created views. We have that (any_priviliges == TRUE) if and only if we are creating a view. In the time of view creation we can't use the MERGE algorithm, therefore if 'tables' is itself a view, it is represented by a temporary table. Thus in this case we can be sure that 'item' is an Item_field. */ if (any_privileges) { DBUG_ASSERT(tables->field_translation == NULL && table || tables->is_natural_join); DBUG_ASSERT(item->type() == Item::FIELD_ITEM); Item_field *fld= (Item_field*) item; const char *field_table_name= field_iterator.table_name(); if (!tables->schema_table && !(fld->have_privileges= (get_column_grant(thd, field_iterator.grant(), field_iterator.db_name(), field_table_name, fld->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, fld->field_name, field_table_name); DBUG_RETURN(TRUE); } } #endif if ((field= field_iterator.field())) { /* Mark if field used before in this select. Used by 'insert' to verify if a field name is used twice. */ if (field->query_id == thd->query_id) thd->dupp_field= field; field->query_id= thd->query_id; if (table) table->used_keys.intersect(field->part_of_key); if (tables->is_natural_join) { TABLE *field_table; /* In this case we are sure that the column ref will not be created because it was already created and stored with the natural join. */ Natural_join_column *nj_col; if (!(nj_col= field_iterator.get_natural_column_ref())) DBUG_RETURN(TRUE); DBUG_ASSERT(nj_col->table_field); field_table= nj_col->table_ref->table; if (field_table) { thd->used_tables|= field_table->map; field_table->used_keys.intersect(field->part_of_key); field_table->used_fields++; } } } else { thd->used_tables|= item->used_tables(); item->walk(&Item::reset_query_id_processor, (byte *)(&thd->query_id)); } } /* In case of stored tables, all fields are considered as used, while in the case of views, the fields considered as used are the ones marked in setup_tables during fix_fields of view columns. For NATURAL joins, used_tables is updated in the IF above. */ if (table) table->used_fields= table->s->fields; } if (found) DBUG_RETURN(FALSE); /* TODO: in the case when we skipped all columns because there was a qualified '*', and all columns were coalesced, we have to give a more meaningful message than ER_BAD_TABLE_ERROR. */ if (!table_name) my_message(ER_NO_TABLES_USED, ER(ER_NO_TABLES_USED), MYF(0)); else my_error(ER_BAD_TABLE_ERROR, MYF(0), table_name); DBUG_RETURN(TRUE); } /* Fix all conditions and outer join expressions. SYNOPSIS setup_conds() thd thread handler tables list of tables for name resolving (select_lex->table_list) leaves list of leaves of join table tree (select_lex->leaf_tables) conds WHERE clause DESCRIPTION TODO RETURN TRUE if some error occured (e.g. out of memory) FALSE if all is OK */ int setup_conds(THD *thd, TABLE_LIST *tables, TABLE_LIST *leaves, COND **conds) { SELECT_LEX *select_lex= thd->lex->current_select; Query_arena *arena= thd->stmt_arena, backup; TABLE_LIST *table= NULL; // For HP compilers /* it_is_update set to TRUE when tables of primary SELECT_LEX (SELECT_LEX which belong to LEX, i.e. most up SELECT) will be updated by INSERT/UPDATE/LOAD NOTE: using this condition helps to prevent call of prepare_check_option() from subquery of VIEW, because tables of subquery belongs to VIEW (see condition before prepare_check_option() call) */ bool it_is_update= (select_lex == &thd->lex->select_lex) && thd->lex->which_check_option_applicable(); DBUG_ENTER("setup_conds"); if (select_lex->conds_processed_with_permanent_arena || arena->is_conventional()) arena= 0; // For easier test thd->set_query_id=1; select_lex->cond_count= 0; for (table= tables; table; table= table->next_local) { if (table->prepare_where(thd, conds, FALSE)) goto err_no_arena; } if (*conds) { thd->where="where clause"; if (!(*conds)->fixed && (*conds)->fix_fields(thd, conds) || (*conds)->check_cols(1)) goto err_no_arena; } /* Apply fix_fields() to all ON clauses at all levels of nesting, including the ones inside view definitions. */ for (table= leaves; table; table= table->next_leaf) { TABLE_LIST *embedded; /* The table at the current level of nesting. */ TABLE_LIST *embedding= table; /* The parent nested table reference. */ do { embedded= embedding; if (embedded->on_expr) { /* Make a join an a expression */ thd->where="on clause"; if (!embedded->on_expr->fixed && embedded->on_expr->fix_fields(thd, &embedded->on_expr) || embedded->on_expr->check_cols(1)) goto err_no_arena; select_lex->cond_count++; } embedding= embedded->embedding; } while (embedding && embedding->nested_join->join_list.head() == embedded); /* process CHECK OPTION */ if (it_is_update) { TABLE_LIST *view= table->top_table(); if (view->effective_with_check) { if (view->prepare_check_option(thd)) goto err_no_arena; thd->change_item_tree(&table->check_option, view->check_option); } } } if (!thd->stmt_arena->is_conventional()) { /* We are in prepared statement preparation code => we should store WHERE clause changing for next executions. We do this ON -> WHERE transformation only once per PS/SP statement. */ select_lex->where= *conds; select_lex->conds_processed_with_permanent_arena= 1; } DBUG_RETURN(test(thd->net.report_error)); err_no_arena: DBUG_RETURN(1); } /****************************************************************************** ** Fill a record with data (for INSERT or UPDATE) ** Returns : 1 if some field has wrong type ******************************************************************************/ /* Fill fields with given items. SYNOPSIS fill_record() thd thread handler fields Item_fields list to be filled values values to fill with ignore_errors TRUE if we should ignore errors RETURN FALSE OK TRUE error occured */ static bool fill_record(THD * thd, List<Item> &fields, List<Item> &values, bool ignore_errors) { List_iterator_fast<Item> f(fields),v(values); Item *value; Item_field *field; DBUG_ENTER("fill_record"); while ((field=(Item_field*) f++)) { value=v++; Field *rfield= field->field; TABLE *table= rfield->table; if (rfield == table->next_number_field) table->auto_increment_field_not_null= TRUE; if ((value->save_in_field(rfield, 0) < 0) && !ignore_errors) { my_message(ER_UNKNOWN_ERROR, ER(ER_UNKNOWN_ERROR), MYF(0)); DBUG_RETURN(TRUE); } } DBUG_RETURN(thd->net.report_error); } /* Fill fields in list with values from the list of items and invoke before triggers. SYNOPSIS fill_record_n_invoke_before_triggers() thd thread context fields Item_fields list to be filled values values to fill with ignore_errors TRUE if we should ignore errors triggers object holding list of triggers to be invoked event event type for triggers to be invoked NOTE This function assumes that fields which values will be set and triggers to be invoked belong to the same table, and that TABLE::record[0] and record[1] buffers correspond to new and old versions of row respectively. RETURN FALSE OK TRUE error occured */ bool fill_record_n_invoke_before_triggers(THD *thd, List<Item> &fields, List<Item> &values, bool ignore_errors, Table_triggers_list *triggers, enum trg_event_type event) { return (fill_record(thd, fields, values, ignore_errors) || triggers && triggers->process_triggers(thd, event, TRG_ACTION_BEFORE, TRUE)); } /* Fill field buffer with values from Field list SYNOPSIS fill_record() thd thread handler ptr pointer on pointer to record values list of fields ignore_errors TRUE if we should ignore errors RETURN FALSE OK TRUE error occured */ bool fill_record(THD *thd, Field **ptr, List<Item> &values, bool ignore_errors) { List_iterator_fast<Item> v(values); Item *value; DBUG_ENTER("fill_record"); Field *field; while ((field = *ptr++)) { value=v++; TABLE *table= field->table; if (field == table->next_number_field) table->auto_increment_field_not_null= TRUE; if (value->save_in_field(field, 0) == -1) DBUG_RETURN(TRUE); } DBUG_RETURN(thd->net.report_error); } /* Fill fields in array with values from the list of items and invoke before triggers. SYNOPSIS fill_record_n_invoke_before_triggers() thd thread context ptr NULL-ended array of fields to be filled values values to fill with ignore_errors TRUE if we should ignore errors triggers object holding list of triggers to be invoked event event type for triggers to be invoked NOTE This function assumes that fields which values will be set and triggers to be invoked belong to the same table, and that TABLE::record[0] and record[1] buffers correspond to new and old versions of row respectively. RETURN FALSE OK TRUE error occured */ bool fill_record_n_invoke_before_triggers(THD *thd, Field **ptr, List<Item> &values, bool ignore_errors, Table_triggers_list *triggers, enum trg_event_type event) { return (fill_record(thd, ptr, values, ignore_errors) || triggers && triggers->process_triggers(thd, event, TRG_ACTION_BEFORE, TRUE)); } static void mysql_rm_tmp_tables(void) { uint i, idx; char filePath[FN_REFLEN], *tmpdir; MY_DIR *dirp; FILEINFO *file; DBUG_ENTER("mysql_rm_tmp_tables"); for (i=0; i<=mysql_tmpdir_list.max; i++) { tmpdir=mysql_tmpdir_list.list[i]; /* See if the directory exists */ if (!(dirp = my_dir(tmpdir,MYF(MY_WME | MY_DONT_SORT)))) continue; /* Remove all SQLxxx tables from directory */ for (idx=0 ; idx < (uint) dirp->number_off_files ; idx++) { file=dirp->dir_entry+idx; /* skiping . and .. */ if (file->name[0] == '.' && (!file->name[1] || (file->name[1] == '.' && !file->name[2]))) continue; if (!bcmp(file->name,tmp_file_prefix,tmp_file_prefix_length)) { sprintf(filePath,"%s%s",tmpdir,file->name); VOID(my_delete(filePath,MYF(MY_WME))); } } my_dirend(dirp); } DBUG_VOID_RETURN; } /***************************************************************************** unireg support functions *****************************************************************************/ /* Invalidate any cache entries that are for some DB SYNOPSIS remove_db_from_cache() db Database name. This will be in lower case if lower_case_table_name is set NOTE: We can't use hash_delete when looping hash_elements. We mark them first and afterwards delete those marked unused. */ void remove_db_from_cache(const char *db) { for (uint idx=0 ; idx < open_cache.records ; idx++) { TABLE *table=(TABLE*) hash_element(&open_cache,idx); if (!strcmp(table->s->db, db)) { table->s->version= 0L; /* Free when thread is ready */ if (!table->in_use) relink_unused(table); } } while (unused_tables && !unused_tables->s->version) VOID(hash_delete(&open_cache,(byte*) unused_tables)); } /* ** free all unused tables */ void flush_tables() { (void) pthread_mutex_lock(&LOCK_open); while (unused_tables) hash_delete(&open_cache,(byte*) unused_tables); (void) pthread_mutex_unlock(&LOCK_open); } /* Mark all entries with the table as deleted to force an reopen of the table The table will be closed (not stored in cache) by the current thread when close_thread_tables() is called. PREREQUISITES Lock on LOCK_open() RETURN 0 This thread now have exclusive access to this table and no other thread can access the table until close_thread_tables() is called. 1 Table is in use by another thread */ bool remove_table_from_cache(THD *thd, const char *db, const char *table_name, uint flags) { char key[MAX_DBKEY_LENGTH]; uint key_length; TABLE *table; bool result=0, signalled= 0; DBUG_ENTER("remove_table_from_cache"); DBUG_PRINT("enter", ("Table: '%s.%s' flags: %u", db, table_name, flags)); key_length=(uint) (strmov(strmov(key,db)+1,table_name)-key)+1; for (;;) { HASH_SEARCH_STATE state; result= signalled= 0; for (table= (TABLE*) hash_first(&open_cache, (byte*) key, key_length, &state); table; table= (TABLE*) hash_next(&open_cache, (byte*) key, key_length, &state)) { THD *in_use; table->s->version=0L; /* Free when thread is ready */ if (!(in_use=table->in_use)) { DBUG_PRINT("info",("Table was not in use")); relink_unused(table); } else if (in_use != thd) { in_use->some_tables_deleted=1; if (table->db_stat) { DBUG_PRINT("info", ("Found another active instance of the table")); result=1; } /* Kill delayed insert threads */ if ((in_use->system_thread & SYSTEM_THREAD_DELAYED_INSERT) && ! in_use->killed) { in_use->killed= THD::KILL_CONNECTION; pthread_mutex_lock(&in_use->mysys_var->mutex); if (in_use->mysys_var->current_cond) { pthread_mutex_lock(in_use->mysys_var->current_mutex); signalled= 1; pthread_cond_broadcast(in_use->mysys_var->current_cond); pthread_mutex_unlock(in_use->mysys_var->current_mutex); } pthread_mutex_unlock(&in_use->mysys_var->mutex); } /* Now we must abort all tables locks used by this thread as the thread may be waiting to get a lock for another table */ for (TABLE *thd_table= in_use->open_tables; thd_table ; thd_table= thd_table->next) { if (thd_table->db_stat) // If table is open signalled|= mysql_lock_abort_for_thread(thd, thd_table); } } else result= result || (flags & RTFC_OWNED_BY_THD_FLAG); } while (unused_tables && !unused_tables->s->version) VOID(hash_delete(&open_cache,(byte*) unused_tables)); if (result && (flags & RTFC_WAIT_OTHER_THREAD_FLAG)) { /* Signal any thread waiting for tables to be freed to reopen their tables */ broadcast_refresh(); DBUG_PRINT("info", ("Waiting for refresh signal")); if (!(flags & RTFC_CHECK_KILLED_FLAG) || !thd->killed) { dropping_tables++; if (likely(signalled)) (void) pthread_cond_wait(&COND_refresh, &LOCK_open); else { struct timespec abstime; /* It can happen that another thread has opened the table but has not yet locked any table at all. Since it can be locked waiting for a table that our thread has done LOCK TABLE x WRITE on previously, we need to ensure that the thread actually hears our signal before we go to sleep. Thus we wait for a short time and then we retry another loop in the remove_table_from_cache routine. */ set_timespec(abstime, 10); pthread_cond_timedwait(&COND_refresh, &LOCK_open, &abstime); } dropping_tables--; continue; } } break; } DBUG_RETURN(result); } int setup_ftfuncs(SELECT_LEX *select_lex) { List_iterator<Item_func_match> li(*(select_lex->ftfunc_list)), lj(*(select_lex->ftfunc_list)); Item_func_match *ftf, *ftf2; while ((ftf=li++)) { if (ftf->fix_index()) return 1; lj.rewind(); while ((ftf2=lj++) != ftf) { if (ftf->eq(ftf2,1) && !ftf2->master) ftf2->master=ftf; } } return 0; } int init_ftfuncs(THD *thd, SELECT_LEX *select_lex, bool no_order) { if (select_lex->ftfunc_list->elements) { List_iterator<Item_func_match> li(*(select_lex->ftfunc_list)); Item_func_match *ifm; DBUG_PRINT("info",("Performing FULLTEXT search")); thd->proc_info="FULLTEXT initialization"; while ((ifm=li++)) ifm->init_search(no_order); } return 0; } /* open new .frm format table SYNOPSIS open_new_frm() THD thread handler path path to .frm alias alias for table db database table_name name of table db_stat open flags (for example HA_OPEN_KEYFILE|HA_OPEN_RNDFILE..) can be 0 (example in ha_example_table) prgflag READ_ALL etc.. ha_open_flags HA_OPEN_ABORT_IF_LOCKED etc.. outparam result table table_desc TABLE_LIST descriptor mem_root temporary MEM_ROOT for parsing */ static bool open_new_frm(THD *thd, const char *path, const char *alias, const char *db, const char *table_name, uint db_stat, uint prgflag, uint ha_open_flags, TABLE *outparam, TABLE_LIST *table_desc, MEM_ROOT *mem_root) { LEX_STRING pathstr; File_parser *parser; DBUG_ENTER("open_new_frm"); pathstr.str= (char*) path; pathstr.length= strlen(path); if ((parser= sql_parse_prepare(&pathstr, mem_root, 1))) { if (is_equal(&view_type, parser->type())) { if (table_desc == 0 || table_desc->required_type == FRMTYPE_TABLE) { my_error(ER_WRONG_OBJECT, MYF(0), db, table_name, "BASE TABLE"); goto err; } if (mysql_make_view(thd, parser, table_desc)) goto err; } else { /* only VIEWs are supported now */ my_error(ER_FRM_UNKNOWN_TYPE, MYF(0), path, parser->type()->str); goto err; } DBUG_RETURN(0); } err: bzero(outparam, sizeof(TABLE)); // do not run repair DBUG_RETURN(1); } bool is_equal(const LEX_STRING *a, const LEX_STRING *b) { return a->length == b->length && !strncmp(a->str, b->str, a->length); }