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mariadb/sql/sql_base.cc
Oleksandr Byelkin ef7cb0a0b5 Merge branch '10.1' into 10.2
2020-08-02 11:05:29 +02:00

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/* Copyright (c) 2000, 2016, Oracle and/or its affiliates.
Copyright (c) 2010, 2020, MariaDB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA */
/* Basic functions needed by many modules */
#include <my_global.h>
#include "sql_base.h" // setup_table_map
#include "sql_priv.h"
#include "unireg.h"
#include "debug_sync.h"
#include "lock.h" // mysql_lock_remove,
// mysql_unlock_tables,
// mysql_lock_have_duplicate
#include "sql_show.h" // append_identifier
#include "strfunc.h" // find_type
#include "sql_view.h" // mysql_make_view, VIEW_ANY_ACL
#include "sql_parse.h" // check_table_access
#include "sql_insert.h" // kill_delayed_threads
#include "sql_acl.h" // *_ACL, check_grant_all_columns,
// check_column_grant_in_table_ref,
// get_column_grant
#include "sql_partition.h" // ALTER_PARTITION_PARAM_TYPE
#include "sql_derived.h" // mysql_derived_prepare,
// mysql_handle_derived,
// mysql_derived_filling
#include "sql_handler.h" // mysql_ha_flush
#include "sql_test.h"
#include "sql_partition.h" // ALTER_PARTITION_PARAM_TYPE
#include "log_event.h" // Query_log_event
#include "sql_select.h"
#include "sp_head.h"
#include "sp.h"
#include "sp_cache.h"
#include "sql_trigger.h"
#include "transaction.h"
#include "sql_prepare.h"
#include "sql_statistics.h"
#include "sql_cte.h"
#include <m_ctype.h>
#include <my_dir.h>
#include <hash.h>
#include "rpl_filter.h"
#include "sql_table.h" // build_table_filename
#include "datadict.h" // dd_frm_is_view()
#include "sql_hset.h" // Hash_set
#include "rpl_rli.h" // rpl_group_info
#ifdef __WIN__
#include <io.h>
#endif
#include "wsrep_mysqld.h"
#include "wsrep_thd.h"
bool
No_such_table_error_handler::handle_condition(THD *,
uint sql_errno,
const char*,
Sql_condition::enum_warning_level *level,
const char*,
Sql_condition ** cond_hdl)
{
*cond_hdl= NULL;
if (sql_errno == ER_NO_SUCH_TABLE || sql_errno == ER_NO_SUCH_TABLE_IN_ENGINE)
{
m_handled_errors++;
return TRUE;
}
if (*level == Sql_condition::WARN_LEVEL_ERROR)
m_unhandled_errors++;
return FALSE;
}
bool No_such_table_error_handler::safely_trapped_errors()
{
/*
If m_unhandled_errors != 0, something else, unanticipated, happened,
so the error is not trapped but returned to the caller.
Multiple ER_NO_SUCH_TABLE can be raised in case of views.
*/
return ((m_handled_errors > 0) && (m_unhandled_errors == 0));
}
/**
This internal handler is used to trap ER_NO_SUCH_TABLE and
ER_WRONG_MRG_TABLE errors during CHECK/REPAIR TABLE for MERGE
tables.
*/
class Repair_mrg_table_error_handler : public Internal_error_handler
{
public:
Repair_mrg_table_error_handler()
: m_handled_errors(false), m_unhandled_errors(false)
{}
bool handle_condition(THD *thd,
uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level *level,
const char* msg,
Sql_condition ** cond_hdl);
/**
Returns TRUE if there were ER_NO_SUCH_/WRONG_MRG_TABLE and there
were no unhandled errors. FALSE otherwise.
*/
bool safely_trapped_errors()
{
/*
Check for m_handled_errors is here for extra safety.
It can be useful in situation when call to open_table()
fails because some error which was suppressed by another
error handler (e.g. in case of MDL deadlock which we
decided to solve by back-off and retry).
*/
return (m_handled_errors && (! m_unhandled_errors));
}
private:
bool m_handled_errors;
bool m_unhandled_errors;
};
bool
Repair_mrg_table_error_handler::handle_condition(THD *,
uint sql_errno,
const char*,
Sql_condition::enum_warning_level *level,
const char*,
Sql_condition ** cond_hdl)
{
*cond_hdl= NULL;
if (sql_errno == ER_NO_SUCH_TABLE ||
sql_errno == ER_NO_SUCH_TABLE_IN_ENGINE ||
sql_errno == ER_WRONG_MRG_TABLE)
{
m_handled_errors= true;
return TRUE;
}
m_unhandled_errors= true;
return FALSE;
}
/**
@defgroup Data_Dictionary Data Dictionary
@{
*/
static bool check_and_update_table_version(THD *thd, TABLE_LIST *tables,
TABLE_SHARE *table_share);
static bool open_table_entry_fini(THD *thd, TABLE_SHARE *share, TABLE *entry);
static bool auto_repair_table(THD *thd, TABLE_LIST *table_list);
/**
Get table cache key for a table list element.
@param table_list[in] Table list element.
@param key[out] On return points to table cache key for the table.
@note Unlike create_table_def_key() call this function doesn't construct
key in a buffer provided by caller. Instead it relies on the fact
that table list element for which key is requested has properly
initialized MDL_request object and the fact that table definition
cache key is suffix of key used in MDL subsystem. So to get table
definition key it simply needs to return pointer to appropriate
part of MDL_key object nested in this table list element.
Indeed, this means that lifetime of key produced by this call is
limited by the lifetime of table list element which it got as
parameter.
@return Length of key.
*/
uint get_table_def_key(const TABLE_LIST *table_list, const char **key)
{
/*
This call relies on the fact that TABLE_LIST::mdl_request::key object
is properly initialized, so table definition cache can be produced
from key used by MDL subsystem.
*/
DBUG_ASSERT(!strcmp(table_list->get_db_name(),
table_list->mdl_request.key.db_name()) &&
!strcmp(table_list->get_table_name(),
table_list->mdl_request.key.name()));
*key= (const char*)table_list->mdl_request.key.ptr() + 1;
return table_list->mdl_request.key.length() - 1;
}
/*****************************************************************************
Functions to handle table definition cache (TABLE_SHARE)
*****************************************************************************/
/*
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 when traversing the return list.
RETURN VALUES
NULL Error (Probably OOM)
# Pointer to list of names of open tables.
*/
struct list_open_tables_arg
{
THD *thd;
const char *db;
const char *wild;
TABLE_LIST table_list;
OPEN_TABLE_LIST **start_list, *open_list;
};
static my_bool list_open_tables_callback(TDC_element *element,
list_open_tables_arg *arg)
{
char *db= (char*) element->m_key;
char *table_name= (char*) element->m_key + strlen((char*) element->m_key) + 1;
if (arg->db && my_strcasecmp(system_charset_info, arg->db, db))
return FALSE;
if (arg->wild && wild_compare(table_name, arg->wild, 0))
return FALSE;
/* Check if user has SELECT privilege for any column in the table */
arg->table_list.db= db;
arg->table_list.table_name= table_name;
arg->table_list.grant.privilege= 0;
if (check_table_access(arg->thd, SELECT_ACL, &arg->table_list, TRUE, 1, TRUE))
return FALSE;
if (!(*arg->start_list= (OPEN_TABLE_LIST *) arg->thd->alloc(
sizeof(**arg->start_list) + element->m_key_length)))
return TRUE;
strmov((*arg->start_list)->table=
strmov(((*arg->start_list)->db= (char*) ((*arg->start_list) + 1)),
db) + 1, table_name);
(*arg->start_list)->in_use= 0;
mysql_mutex_lock(&element->LOCK_table_share);
All_share_tables_list::Iterator it(element->all_tables);
TABLE *table;
while ((table= it++))
if (table->in_use)
++(*arg->start_list)->in_use;
mysql_mutex_unlock(&element->LOCK_table_share);
(*arg->start_list)->locked= 0; /* Obsolete. */
arg->start_list= &(*arg->start_list)->next;
*arg->start_list= 0;
return FALSE;
}
OPEN_TABLE_LIST *list_open_tables(THD *thd, const char *db, const char *wild)
{
list_open_tables_arg argument;
DBUG_ENTER("list_open_tables");
argument.thd= thd;
argument.db= db;
argument.wild= wild;
bzero((char*) &argument.table_list, sizeof(argument.table_list));
argument.start_list= &argument.open_list;
argument.open_list= 0;
if (tdc_iterate(thd, (my_hash_walk_action) list_open_tables_callback,
&argument, true))
DBUG_RETURN(0);
DBUG_RETURN(argument.open_list);
}
/*
Close all tables which aren't in use by any thread
@param thd Thread context
@param tables List of tables to remove from the cache
@param wait_for_refresh Wait for a impending flush
@param timeout Timeout for waiting for flush to be completed.
@note THD can be NULL, but then wait_for_refresh must be FALSE
and tables must be NULL.
@note When called as part of FLUSH TABLES WITH READ LOCK this function
ignores metadata locks held by other threads. In order to avoid
situation when FLUSH TABLES WITH READ LOCK sneaks in at the moment
when some write-locked table is being reopened (by FLUSH TABLES or
ALTER TABLE) we have to rely on additional global shared metadata
lock taken by thread trying to obtain global read lock.
*/
struct close_cached_tables_arg
{
tdc_version_t refresh_version;
TDC_element *element;
};
static my_bool close_cached_tables_callback(TDC_element *element,
close_cached_tables_arg *arg)
{
mysql_mutex_lock(&element->LOCK_table_share);
if (element->share && element->flushed &&
element->version < arg->refresh_version)
{
/* wait_for_old_version() will unlock mutex and free share */
arg->element= element;
return TRUE;
}
mysql_mutex_unlock(&element->LOCK_table_share);
return FALSE;
}
bool close_cached_tables(THD *thd, TABLE_LIST *tables,
bool wait_for_refresh, ulong timeout)
{
bool result= FALSE;
struct timespec abstime;
tdc_version_t refresh_version;
DBUG_ENTER("close_cached_tables");
DBUG_ASSERT(thd || (!wait_for_refresh && !tables));
refresh_version= tdc_increment_refresh_version();
if (!tables)
{
/*
Force close of all open tables.
Note that code in TABLE_SHARE::wait_for_old_version() assumes that
incrementing of refresh_version is followed by purge of unused table
shares.
*/
kill_delayed_threads();
/*
Get rid of all unused TABLE and TABLE_SHARE instances. By doing
this we automatically close all tables which were marked as "old".
*/
tc_purge(true);
/* Free table shares which were not freed implicitly by loop above. */
tdc_purge(true);
}
else
{
bool found=0;
for (TABLE_LIST *table= tables; table; table= table->next_local)
{
/* tdc_remove_table() also sets TABLE_SHARE::version to 0. */
found|= tdc_remove_table(thd, TDC_RT_REMOVE_UNUSED, table->db,
table->table_name, TRUE);
}
if (!found)
wait_for_refresh=0; // Nothing to wait for
}
DBUG_PRINT("info", ("open table definitions: %d",
(int) tdc_records()));
if (!wait_for_refresh)
DBUG_RETURN(result);
if (thd->locked_tables_mode)
{
/*
If we are under LOCK TABLES, we need to reopen the tables without
opening a door for any concurrent threads to sneak in and get
lock on our tables. To achieve this we use exclusive metadata
locks.
*/
TABLE_LIST *tables_to_reopen= (tables ? tables :
thd->locked_tables_list.locked_tables());
/* Close open HANDLER instances to avoid self-deadlock. */
mysql_ha_flush_tables(thd, tables_to_reopen);
for (TABLE_LIST *table_list= tables_to_reopen; table_list;
table_list= table_list->next_global)
{
int err;
/* A check that the table was locked for write is done by the caller. */
TABLE *table= find_table_for_mdl_upgrade(thd, table_list->db,
table_list->table_name, &err);
/* May return NULL if this table has already been closed via an alias. */
if (! table)
continue;
if (wait_while_table_is_used(thd, table,
HA_EXTRA_PREPARE_FOR_FORCED_CLOSE))
{
result= TRUE;
goto err_with_reopen;
}
close_all_tables_for_name(thd, table->s, HA_EXTRA_NOT_USED, NULL);
}
}
/* Wait until all threads have closed all the tables we are flushing. */
DBUG_PRINT("info", ("Waiting for other threads to close their open tables"));
/*
To a self-deadlock or deadlocks with other FLUSH threads
waiting on our open HANDLERs, we have to flush them.
*/
mysql_ha_flush(thd);
DEBUG_SYNC(thd, "after_flush_unlock");
if (!tables)
{
int r= 0;
close_cached_tables_arg argument;
argument.refresh_version= refresh_version;
set_timespec(abstime, timeout);
while (!thd->killed &&
(r= tdc_iterate(thd,
(my_hash_walk_action) close_cached_tables_callback,
&argument)) == 1 &&
!argument.element->share->wait_for_old_version(thd, &abstime,
MDL_wait_for_subgraph::DEADLOCK_WEIGHT_DDL))
/* no-op */;
if (r)
result= TRUE;
}
else
{
for (TABLE_LIST *table= tables; table; table= table->next_local)
{
if (thd->killed)
break;
if (tdc_wait_for_old_version(thd, table->db, table->table_name, timeout,
MDL_wait_for_subgraph::DEADLOCK_WEIGHT_DDL,
refresh_version))
{
result= TRUE;
break;
}
}
}
err_with_reopen:
if (thd->locked_tables_mode)
{
/*
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)
*/
if (thd->locked_tables_list.reopen_tables(thd, false))
result= true;
/*
Since downgrade_lock() won't do anything with shared
metadata lock it is much simpler to go through all open tables rather
than picking only those tables that were flushed.
*/
for (TABLE *tab= thd->open_tables; tab; tab= tab->next)
tab->mdl_ticket->downgrade_lock(MDL_SHARED_NO_READ_WRITE);
}
DBUG_RETURN(result);
}
/**
Close all tables which match specified connection string or
if specified string is NULL, then any table with a connection string.
*/
struct close_cached_connection_tables_arg
{
THD *thd;
LEX_STRING *connection;
TABLE_LIST *tables;
};
static my_bool close_cached_connection_tables_callback(
TDC_element *element, close_cached_connection_tables_arg *arg)
{
TABLE_LIST *tmp;
mysql_mutex_lock(&element->LOCK_table_share);
/* Ignore if table is not open or does not have a connect_string */
if (!element->share || !element->share->connect_string.length ||
!element->ref_count)
goto end;
/* Compare the connection string */
if (arg->connection &&
(arg->connection->length > element->share->connect_string.length ||
(arg->connection->length < element->share->connect_string.length &&
(element->share->connect_string.str[arg->connection->length] != '/' &&
element->share->connect_string.str[arg->connection->length] != '\\')) ||
strncasecmp(arg->connection->str, element->share->connect_string.str,
arg->connection->length)))
goto end;
/* close_cached_tables() only uses these elements */
if (!(tmp= (TABLE_LIST*) alloc_root(arg->thd->mem_root, sizeof(TABLE_LIST))) ||
!(tmp->db= strdup_root(arg->thd->mem_root, element->share->db.str)) ||
!(tmp->table_name= strdup_root(arg->thd->mem_root,
element->share->table_name.str)))
{
mysql_mutex_unlock(&element->LOCK_table_share);
return TRUE;
}
tmp->next_local= arg->tables;
arg->tables= tmp;
end:
mysql_mutex_unlock(&element->LOCK_table_share);
return FALSE;
}
bool close_cached_connection_tables(THD *thd, LEX_STRING *connection)
{
close_cached_connection_tables_arg argument;
DBUG_ENTER("close_cached_connections");
DBUG_ASSERT(thd);
argument.thd= thd;
argument.connection= connection;
argument.tables= NULL;
if (tdc_iterate(thd,
(my_hash_walk_action) close_cached_connection_tables_callback,
&argument))
DBUG_RETURN(true);
DBUG_RETURN(argument.tables ?
close_cached_tables(thd, argument.tables, FALSE, LONG_TIMEOUT) :
false);
}
/*
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.
Clear 'check_table_binlog_row_based_done' flag. For tables which were used
by current substatement the flag is cleared as part of 'ha_reset()' call.
For the rest of the open tables not used by current substament if this
flag is enabled as part of current substatement execution, clear the flag
explicitly.
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)
{
DBUG_ASSERT(table->pos_in_locked_tables == NULL ||
table->pos_in_locked_tables->table == table);
if (table->query_id == thd->query_id)
{
table->query_id= 0;
table->file->ha_reset();
}
else if (table->file->check_table_binlog_row_based_done)
table->file->clear_cached_table_binlog_row_based_flag();
}
}
/**
Close all open instances of the table but keep the MDL lock.
Works both under LOCK TABLES and in the normal mode.
Removes all closed instances of the table from the table cache.
@param thd thread handle
@param[in] share table share, but is just a handy way to
access the table cache key
@param[in] extra
HA_EXTRA_PREPARE_FOR_DROP
- The table is dropped
HA_EXTRA_PREPARE_FOR_RENAME
- The table is renamed
HA_EXTRA_NOT_USED
- The table is marked as closed in the
locked_table_list but kept there so one can call
locked_table_list->reopen_tables() to put it back.
In case of drop/rename the documented behavior is to
implicitly remove the table from LOCK TABLES
list.
@pre Must be called with an X MDL lock on the table.
*/
void
close_all_tables_for_name(THD *thd, TABLE_SHARE *share,
ha_extra_function extra,
TABLE *skip_table)
{
DBUG_ASSERT(!share->tmp_table);
char key[MAX_DBKEY_LENGTH];
uint key_length= share->table_cache_key.length;
const char *db= key;
const char *table_name= db + share->db.length + 1;
bool remove_from_locked_tables= extra != HA_EXTRA_NOT_USED;
memcpy(key, share->table_cache_key.str, key_length);
for (TABLE **prev= &thd->open_tables; *prev; )
{
TABLE *table= *prev;
if (table->s->table_cache_key.length == key_length &&
!memcmp(table->s->table_cache_key.str, key, key_length) &&
table != skip_table)
{
thd->locked_tables_list.unlink_from_list(thd,
table->pos_in_locked_tables,
remove_from_locked_tables);
/* Inform handler that there is a drop table or a rename going on */
if (extra != HA_EXTRA_NOT_USED && table->db_stat)
{
table->file->extra(extra);
extra= HA_EXTRA_NOT_USED; // Call extra once!
}
/*
Does nothing if the table is not locked.
This allows one to use this function after a table
has been unlocked, e.g. in partition management.
*/
mysql_lock_remove(thd, thd->lock, table);
close_thread_table(thd, prev);
}
else
{
/* Step to next entry in open_tables list. */
prev= &table->next;
}
}
if (skip_table == NULL)
{
/* Remove the table share from the cache. */
tdc_remove_table(thd, TDC_RT_REMOVE_ALL, db, table_name,
FALSE);
}
}
/*
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
IMPLEMENTATION
Unlocks tables and frees derived tables.
Put all normal tables used by thread in free list.
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)
{
TABLE *table;
DBUG_ENTER("close_thread_tables");
THD_STAGE_INFO(thd, stage_closing_tables);
#ifdef EXTRA_DEBUG
DBUG_PRINT("tcache", ("open tables:"));
for (table= thd->open_tables; table; table= table->next)
DBUG_PRINT("tcache", ("table: '%s'.'%s' %p", table->s->db.str,
table->s->table_name.str, table));
#endif
#if defined(ENABLED_DEBUG_SYNC)
/* debug_sync may not be initialized for some slave threads */
if (thd->debug_sync_control)
DEBUG_SYNC(thd, "before_close_thread_tables");
#endif
DBUG_ASSERT(thd->transaction.stmt.is_empty() || thd->in_sub_stmt ||
(thd->state_flags & Open_tables_state::BACKUPS_AVAIL));
/* Detach MERGE children after every statement. Even under LOCK TABLES. */
for (table= thd->open_tables; table; table= table->next)
{
/* Table might be in use by some outer statement. */
DBUG_PRINT("tcache", ("table: '%s' query_id: %lu",
table->s->table_name.str, (ulong) table->query_id));
if (thd->locked_tables_mode <= LTM_LOCK_TABLES ||
table->query_id == thd->query_id)
{
DBUG_ASSERT(table->file);
table->file->extra(HA_EXTRA_DETACH_CHILDREN);
}
}
/*
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)
{
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 (thd->rec_tables)
{
TABLE *next;
/*
Close all temporary tables created for recursive table references.
This action was postponed because the table could be used in the
statements like ANALYZE WITH r AS (...) SELECT * from r
where r is defined through recursion.
*/
for (table= thd->rec_tables ; table ; table= next)
{
next= table->next;
free_tmp_table(thd, table);
}
thd->rec_tables= 0;
}
/*
Mark all temporary tables used by this statement as free for reuse.
*/
thd->mark_tmp_tables_as_free_for_reuse();
if (thd->locked_tables_mode)
{
/* Ensure we are calling ha_reset() for all used tables */
mark_used_tables_as_free_for_reuse(thd, thd->open_tables);
/*
We are under simple LOCK TABLES or we're inside a sub-statement
of a prelocked statement, so should not do anything else.
Note that even if we are in LTM_LOCK_TABLES mode and statement
requires prelocking (e.g. when we are closing tables after
failing ot "open" all tables required for statement execution)
we will exit this function a few lines below.
*/
if (! thd->lex->requires_prelocking())
DBUG_VOID_RETURN;
/*
We are in the top-level statement of a prelocked statement,
so we have to leave the prelocked mode now with doing implicit
UNLOCK TABLES if needed.
*/
if (thd->locked_tables_mode == LTM_PRELOCKED_UNDER_LOCK_TABLES)
thd->locked_tables_mode= LTM_LOCK_TABLES;
if (thd->locked_tables_mode == LTM_LOCK_TABLES)
DBUG_VOID_RETURN;
thd->leave_locked_tables_mode();
/* Fallthrough */
}
if (thd->lock)
{
/*
For RBR we flush the pending event just before we unlock all the
tables. This means that we are at the end of a topmost
statement, so we ensure that the STMT_END_F flag is set on the
pending event. For statements that are *inside* stored
functions, the pending event will not be flushed: that will be
handled either before writing a query log event (inside
binlog_query()) or when preparing a pending event.
*/
(void)thd->binlog_flush_pending_rows_event(TRUE);
mysql_unlock_tables(thd, thd->lock);
thd->lock=0;
}
/*
Closing a MERGE child before the parent would be fatal if the
other thread tries to abort the MERGE lock in between.
*/
while (thd->open_tables)
(void) close_thread_table(thd, &thd->open_tables);
DBUG_VOID_RETURN;
}
/* move one table to free list */
void close_thread_table(THD *thd, TABLE **table_ptr)
{
TABLE *table= *table_ptr;
DBUG_ENTER("close_thread_table");
DBUG_PRINT("tcache", ("table: '%s'.'%s' %p", table->s->db.str,
table->s->table_name.str, table));
DBUG_ASSERT(!table->file->keyread_enabled());
DBUG_ASSERT(!table->file || table->file->inited == handler::NONE);
/*
The metadata lock must be released after giving back
the table to the table cache.
*/
DBUG_ASSERT(thd->mdl_context.is_lock_owner(MDL_key::TABLE,
table->s->db.str,
table->s->table_name.str,
MDL_SHARED));
table->mdl_ticket= NULL;
if (table->file)
{
table->file->update_global_table_stats();
table->file->update_global_index_stats();
}
mysql_mutex_lock(&thd->LOCK_thd_data);
*table_ptr=table->next;
mysql_mutex_unlock(&thd->LOCK_thd_data);
if (! table->needs_reopen())
{
/* Avoid having MERGE tables with attached children in table cache. */
table->file->extra(HA_EXTRA_DETACH_CHILDREN);
/* Free memory and reset for next loop. */
free_field_buffers_larger_than(table, MAX_TDC_BLOB_SIZE);
table->file->ha_reset();
}
/*
Do this *before* entering the TABLE_SHARE::tdc.LOCK_table_share
critical section.
*/
MYSQL_UNBIND_TABLE(table->file);
tc_release_table(table);
DBUG_VOID_RETURN;
}
/*
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,
TABLE_LIST *TABLE_LIST::*link,
const char *db_name,
const char *table_name)
{
for (; table; table= table->*link )
{
if (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)
@param thd thread handle
@param table table which should be checked
@param table_list list of tables
@param check_flag whether to check tables' aliases
Currently this is only used by INSERT
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) find_dup_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
@retval !=0 found duplicate
@retval 0 if table is unique
*/
static
TABLE_LIST* find_dup_table(THD *thd, TABLE_LIST *table, TABLE_LIST *table_list,
uint check_flag)
{
TABLE_LIST *res= 0;
const char *d_name, *t_name, *t_alias;
DBUG_ENTER("find_dup_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)
{
/* All MyISAMMRG children are plain MyISAM tables. */
DBUG_ASSERT(table->table->file->ht->db_type != DB_TYPE_MRG_MYISAM);
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;
t_alias= table->alias;
retry:
DBUG_PRINT("info", ("real table: %s.%s", d_name, t_name));
for (TABLE_LIST *tl= table_list; tl ; tl= tl->next_global, res= 0)
{
if (tl->select_lex && tl->select_lex->master_unit() &&
tl->select_lex->master_unit()->executed)
{
/*
There is no sense to check tables of already executed parts
of the query
*/
continue;
}
/*
Table is unique if it is present only once in the global list
of tables and once in the list of table locks.
*/
if (! (res= find_table_in_global_list(tl, d_name, t_name)))
break;
tl= res; // We can continue search after this table
/* Skip if same underlying table. */
if (res->table && (res->table == table->table))
continue;
/* Skip if table is tmp table */
if (check_flag & CHECK_DUP_SKIP_TEMP_TABLE &&
res->table && res->table->s->tmp_table != NO_TMP_TABLE)
{
continue;
}
if (check_flag & CHECK_DUP_FOR_CREATE)
DBUG_RETURN(res);
/* Skip if table alias does not match. */
if (check_flag & CHECK_DUP_ALLOW_DIFFERENT_ALIAS)
{
if (my_strcasecmp(table_alias_charset, t_alias, res->alias))
continue;
}
/*
If table is not excluded (could be a derived table) and table is not
a prelocking placeholder then we found either a duplicate entry
or a table that is part of a derived table (handled below).
Examples are:
INSERT INTO t1 SELECT * FROM t1;
INSERT INTO t1 SELECT * FROM view_containing_t1;
*/
if (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.
*/
DBUG_PRINT("info",
("found same copy of table or table which we should skip"));
}
if (res && res->belong_to_derived)
{
/*
We come here for queries of type:
INSERT INTO t1 (SELECT tmp.a FROM (select * FROM t1) as tmp);
Try to fix by materializing the derived table
*/
TABLE_LIST *derived= res->belong_to_derived;
if (derived->is_merged_derived() && !derived->derived->is_excluded())
{
DBUG_PRINT("info",
("convert merged to materialization to resolve the conflict"));
derived->change_refs_to_fields();
derived->set_materialized_derived();
goto retry;
}
}
DBUG_RETURN(res);
}
/**
Test that the subject table of INSERT/UPDATE/DELETE/CREATE
or (in case of MyISAMMRG) one of its children are not used later
in the query.
For MyISAMMRG tables, it is assumed that all the underlying
tables of @c table (if any) are listed right after it and that
their @c parent_l field points at the main table.
@retval non-NULL The table list element for the table that
represents the duplicate.
@retval NULL No duplicates found.
*/
TABLE_LIST*
unique_table(THD *thd, TABLE_LIST *table, TABLE_LIST *table_list,
uint check_flag)
{
TABLE_LIST *dup;
table= table->find_table_for_update();
if (table->table && table->table->file->ht->db_type == DB_TYPE_MRG_MYISAM)
{
TABLE_LIST *child;
dup= NULL;
/* Check duplicates of all merge children. */
for (child= table->next_global; child && child->parent_l == table;
child= child->next_global)
{
if ((dup= find_dup_table(thd, child, child->next_global, check_flag)))
break;
}
}
else
dup= find_dup_table(thd, table, table_list, check_flag);
return dup;
}
/*
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)
{
/* Issue the ER_NON_INSERTABLE_TABLE error for an INSERT */
if (update->view == duplicate->view)
my_error(!strncmp(operation, "INSERT", 6) ?
ER_NON_INSERTABLE_TABLE : 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, operation);
}
/**
Force all other threads to stop using the table by upgrading
metadata lock on it and remove unused TABLE instances from cache.
@param thd Thread handler
@param table Table to remove from cache
@param function HA_EXTRA_PREPARE_FOR_DROP if table is to be deleted
HA_EXTRA_FORCE_REOPEN if table is not be used
HA_EXTRA_PREPARE_FOR_RENAME if table is to be renamed
HA_EXTRA_NOT_USED Don't call extra()
@note When returning, the table will be unusable for other threads
until metadata lock is downgraded.
@retval FALSE Success.
@retval TRUE Failure (e.g. because thread was killed).
*/
bool wait_while_table_is_used(THD *thd, TABLE *table,
enum ha_extra_function function)
{
DBUG_ENTER("wait_while_table_is_used");
DBUG_ASSERT(!table->s->tmp_table);
DBUG_PRINT("enter", ("table: '%s' share: %p db_stat: %u version: %lld",
table->s->table_name.str, table->s,
table->db_stat, table->s->tdc->version));
if (thd->mdl_context.upgrade_shared_lock(
table->mdl_ticket, MDL_EXCLUSIVE,
thd->variables.lock_wait_timeout))
DBUG_RETURN(TRUE);
tdc_remove_table(thd, TDC_RT_REMOVE_NOT_OWN,
table->s->db.str, table->s->table_name.str,
FALSE);
/* extra() call must come only after all instances above are closed */
if (function != HA_EXTRA_NOT_USED)
DBUG_RETURN(table->file->extra(function));
DBUG_RETURN(FALSE);
}
/**
Close a and drop a just created table in CREATE TABLE ... SELECT.
@param thd Thread handle
@param table TABLE object for the table to be dropped
@param db_name Name of database for this table
@param table_name Name of this table
This routine assumes that the table to be closed is open only
by the calling thread, so we needn't wait until other threads
close the table. It also assumes that the table is first
in thd->open_ables and a data lock on it, if any, has been
released. To sum up, it's tuned to work with
CREATE TABLE ... SELECT and CREATE TABLE .. SELECT only.
Note, that currently CREATE TABLE ... SELECT is not supported
under LOCK TABLES. This function, still, can be called in
prelocked mode, e.g. if we do CREATE TABLE .. SELECT f1();
*/
void drop_open_table(THD *thd, TABLE *table, const char *db_name,
const char *table_name)
{
DBUG_ENTER("drop_open_table");
if (table->s->tmp_table)
thd->drop_temporary_table(table, NULL, true);
else
{
DBUG_ASSERT(table == thd->open_tables);
handlerton *table_type= table->s->db_type();
table->file->extra(HA_EXTRA_PREPARE_FOR_DROP);
close_thread_table(thd, &thd->open_tables);
/* Remove the table share from the table cache. */
tdc_remove_table(thd, TDC_RT_REMOVE_ALL, db_name, table_name,
FALSE);
/* Remove the table from the storage engine and rm the .frm. */
quick_rm_table(thd, table_type, db_name, table_name, 0);
}
DBUG_VOID_RETURN;
}
/**
An error handler which converts, if possible, ER_LOCK_DEADLOCK error
that can occur when we are trying to acquire a metadata lock to
a request for back-off and re-start of open_tables() process.
*/
class MDL_deadlock_handler : public Internal_error_handler
{
public:
MDL_deadlock_handler(Open_table_context *ot_ctx_arg)
: m_ot_ctx(ot_ctx_arg), m_is_active(FALSE)
{}
virtual ~MDL_deadlock_handler() {}
virtual bool handle_condition(THD *thd,
uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level *level,
const char* msg,
Sql_condition ** cond_hdl);
private:
/** Open table context to be used for back-off request. */
Open_table_context *m_ot_ctx;
/**
Indicates that we are already in the process of handling
ER_LOCK_DEADLOCK error. Allows to re-emit the error from
the error handler without falling into infinite recursion.
*/
bool m_is_active;
};
bool MDL_deadlock_handler::handle_condition(THD *,
uint sql_errno,
const char*,
Sql_condition::enum_warning_level*,
const char*,
Sql_condition ** cond_hdl)
{
*cond_hdl= NULL;
if (! m_is_active && sql_errno == ER_LOCK_DEADLOCK)
{
/* Disable the handler to avoid infinite recursion. */
m_is_active= TRUE;
(void) m_ot_ctx->request_backoff_action(
Open_table_context::OT_BACKOFF_AND_RETRY,
NULL);
m_is_active= FALSE;
/*
If the above back-off request failed, a new instance of
ER_LOCK_DEADLOCK error was emitted. Thus the current
instance of error condition can be treated as handled.
*/
return TRUE;
}
return FALSE;
}
/**
Try to acquire an MDL lock for a table being opened.
@param[in,out] thd Session context, to report errors.
@param[out] ot_ctx Open table context, to hold the back off
state. If we failed to acquire a lock
due to a lock conflict, we add the
failed request to the open table context.
@param[in,out] mdl_request A request for an MDL lock.
If we managed to acquire a ticket
(no errors or lock conflicts occurred),
contains a reference to it on
return. However, is not modified if MDL
lock type- modifying flags were provided.
@param[in] flags flags MYSQL_OPEN_FORCE_SHARED_MDL,
MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL or
MYSQL_OPEN_FAIL_ON_MDL_CONFLICT
@sa open_table().
@param[out] mdl_ticket Only modified if there was no error.
If we managed to acquire an MDL
lock, contains a reference to the
ticket, otherwise is set to NULL.
@retval TRUE An error occurred.
@retval FALSE No error, but perhaps a lock conflict, check mdl_ticket.
*/
static bool
open_table_get_mdl_lock(THD *thd, Open_table_context *ot_ctx,
MDL_request *mdl_request,
uint flags,
MDL_ticket **mdl_ticket)
{
MDL_request mdl_request_shared;
if (flags & (MYSQL_OPEN_FORCE_SHARED_MDL |
MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL))
{
/*
MYSQL_OPEN_FORCE_SHARED_MDL flag means that we are executing
PREPARE for a prepared statement and want to override
the type-of-operation aware metadata lock which was set
in the parser/during view opening with a simple shared
metadata lock.
This is necessary to allow concurrent execution of PREPARE
and LOCK TABLES WRITE statement against the same table.
MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL flag means that we open
the table in order to get information about it for one of I_S
queries and also want to override the type-of-operation aware
shared metadata lock which was set earlier (e.g. during view
opening) with a high-priority shared metadata lock.
This is necessary to avoid unnecessary waiting and extra
ER_WARN_I_S_SKIPPED_TABLE warnings when accessing I_S tables.
These two flags are mutually exclusive.
*/
DBUG_ASSERT(!(flags & MYSQL_OPEN_FORCE_SHARED_MDL) ||
!(flags & MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL));
mdl_request_shared.init(&mdl_request->key,
(flags & MYSQL_OPEN_FORCE_SHARED_MDL) ?
MDL_SHARED : MDL_SHARED_HIGH_PRIO,
MDL_TRANSACTION);
mdl_request= &mdl_request_shared;
}
if (flags & MYSQL_OPEN_FAIL_ON_MDL_CONFLICT)
{
/*
When table is being open in order to get data for I_S table,
we might have some tables not only open but also locked (e.g. when
this happens under LOCK TABLES or in a stored function).
As a result by waiting on a conflicting metadata lock to go away
we may create a deadlock which won't entirely belong to the
MDL subsystem and thus won't be detectable by this subsystem's
deadlock detector.
To avoid such situation we skip the trouble-making table if
there is a conflicting lock.
*/
if (thd->mdl_context.try_acquire_lock(mdl_request))
return TRUE;
if (mdl_request->ticket == NULL)
{
my_error(ER_WARN_I_S_SKIPPED_TABLE, MYF(0),
mdl_request->key.db_name(), mdl_request->key.name());
return TRUE;
}
}
else
{
/*
We are doing a normal table open. Let us try to acquire a metadata
lock on the table. If there is a conflicting lock, acquire_lock()
will wait for it to go away. Sometimes this waiting may lead to a
deadlock, with the following results:
1) If a deadlock is entirely within MDL subsystem, it is
detected by the deadlock detector of this subsystem.
ER_LOCK_DEADLOCK error is produced. Then, the error handler
that is installed prior to the call to acquire_lock() attempts
to request a back-off and retry. Upon success, ER_LOCK_DEADLOCK
error is suppressed, otherwise propagated up the calling stack.
2) Otherwise, a deadlock may occur when the wait-for graph
includes edges not visible to the MDL deadlock detector.
One such example is a wait on an InnoDB row lock, e.g. when:
conn C1 gets SR MDL lock on t1 with SELECT * FROM t1
conn C2 gets a row lock on t2 with SELECT * FROM t2 FOR UPDATE
conn C3 gets in and waits on C1 with DROP TABLE t0, t1
conn C2 continues and blocks on C3 with SELECT * FROM t0
conn C1 deadlocks by waiting on C2 by issuing SELECT * FROM
t2 LOCK IN SHARE MODE.
Such circular waits are currently only resolved by timeouts,
e.g. @@innodb_lock_wait_timeout or @@lock_wait_timeout.
*/
MDL_deadlock_handler mdl_deadlock_handler(ot_ctx);
thd->push_internal_handler(&mdl_deadlock_handler);
bool result= thd->mdl_context.acquire_lock(mdl_request,
ot_ctx->get_timeout());
thd->pop_internal_handler();
if (result && !ot_ctx->can_recover_from_failed_open())
return TRUE;
}
*mdl_ticket= mdl_request->ticket;
return FALSE;
}
/**
Check if the given table is actually a VIEW that was LOCK-ed
@param thd Thread context.
@param t Table to check.
@retval TRUE The 't'-table is a locked view
needed to remedy problem before retrying again.
@retval FALSE 't' was not locked, not a VIEW or an error happened.
*/
bool is_locked_view(THD *thd, TABLE_LIST *t)
{
DBUG_ENTER("check_locked_view");
/*
Is this table a view and not a base table?
(it is work around to allow to open view with locked tables,
real fix will be made after definition cache will be made)
Since opening of view which was not explicitly locked by LOCK
TABLES breaks metadata locking protocol (potentially can lead
to deadlocks) it should be disallowed.
*/
if (thd->mdl_context.is_lock_owner(MDL_key::TABLE,
t->db, t->table_name,
MDL_SHARED))
{
char path[FN_REFLEN + 1];
build_table_filename(path, sizeof(path) - 1,
t->db, t->table_name, reg_ext, 0);
/*
Note that we can't be 100% sure that it is a view since it's
possible that we either simply have not found unused TABLE
instance in THD::open_tables list or were unable to open table
during prelocking process (in this case in theory we still
should hold shared metadata lock on it).
*/
if (dd_frm_is_view(thd, path))
{
/*
If parent_l of the table_list is non null then a merge table
has this view as child table, which is not supported.
*/
if (t->parent_l)
{
my_error(ER_WRONG_MRG_TABLE, MYF(0));
DBUG_RETURN(FALSE);
}
if (!tdc_open_view(thd, t, CHECK_METADATA_VERSION))
{
DBUG_ASSERT(t->view != 0);
DBUG_RETURN(TRUE); // VIEW
}
}
}
DBUG_RETURN(FALSE);
}
/**
Open a base table.
@param thd Thread context.
@param table_list Open first table in list.
@param ot_ctx Context with flags which modify how open works
and which is used to recover from a failed
open_table() attempt.
Some examples of flags:
MYSQL_OPEN_IGNORE_FLUSH - Open table even if
someone has done a flush. No version number
checking is done.
MYSQL_OPEN_HAS_MDL_LOCK - instead of acquiring
metadata locks rely on that caller already has
appropriate ones.
Uses a cache of open tables to find a TABLE instance not in use.
If TABLE_LIST::open_strategy is set to OPEN_IF_EXISTS, the table is
opened only if it exists. If the open strategy is OPEN_STUB, the
underlying table is never opened. In both cases, metadata locks are
always taken according to the lock strategy.
The function used to open temporary tables, but now it opens base tables
only.
@retval TRUE Open failed. "action" parameter may contain type of action
needed to remedy problem before retrying again.
@retval FALSE Success. Members of TABLE_LIST structure are filled properly
(e.g. TABLE_LIST::table is set for real tables and
TABLE_LIST::view is set for views).
*/
bool open_table(THD *thd, TABLE_LIST *table_list, Open_table_context *ot_ctx)
{
TABLE *table;
const char *key;
uint key_length;
char *alias= table_list->alias;
uint flags= ot_ctx->get_flags();
MDL_ticket *mdl_ticket;
TABLE_SHARE *share;
uint gts_flags;
DBUG_ENTER("open_table");
/*
The table must not be opened already. The table can be pre-opened for
some statements if it is a temporary table.
open_temporary_table() must be used to open temporary tables.
*/
DBUG_ASSERT(!table_list->table);
/* an open table operation needs a lot of the stack space */
if (check_stack_overrun(thd, STACK_MIN_SIZE_FOR_OPEN, (uchar *)&alias))
DBUG_RETURN(TRUE);
if (!(flags & MYSQL_OPEN_IGNORE_KILLED) && thd->killed)
{
thd->send_kill_message();
DBUG_RETURN(TRUE);
}
/*
Check if we're trying to take a write lock in a read only transaction.
Note that we allow write locks on log tables as otherwise logging
to general/slow log would be disabled in read only transactions.
*/
if (table_list->mdl_request.is_write_lock_request() &&
thd->tx_read_only &&
!(flags & (MYSQL_LOCK_LOG_TABLE | MYSQL_OPEN_HAS_MDL_LOCK)))
{
my_error(ER_CANT_EXECUTE_IN_READ_ONLY_TRANSACTION, MYF(0));
DBUG_RETURN(true);
}
if (!table_list->db)
{
my_error(ER_NO_DB_ERROR, MYF(0));
DBUG_RETURN(true);
}
key_length= get_table_def_key(table_list, &key);
/*
If we're in pre-locked or LOCK TABLES mode, let's try to find the
requested table in the list of pre-opened and locked tables. If the
table is not there, return an error - we can't open not pre-opened
tables in pre-locked/LOCK TABLES mode.
TODO: move this block into a separate function.
*/
if (thd->locked_tables_mode &&
! (flags & MYSQL_OPEN_GET_NEW_TABLE))
{ // Using table locks
TABLE *best_table= 0;
int best_distance= INT_MIN;
for (table=thd->open_tables; table ; table=table->next)
{
if (table->s->table_cache_key.length == key_length &&
!memcmp(table->s->table_cache_key.str, key, key_length))
{
if (!my_strcasecmp(system_charset_info, table->alias.c_ptr(), alias) &&
table->query_id != thd->query_id && /* skip tables already used */
(thd->locked_tables_mode == LTM_LOCK_TABLES ||
table->query_id == 0))
{
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)
{
/*
We have found a perfect match and can finish iterating
through open tables list. Check for table use conflict
between calling statement and SP/trigger is done in
lock_tables().
*/
break;
}
}
}
}
}
if (best_table)
{
table= best_table;
table->query_id= thd->query_id;
table->init(thd, table_list);
DBUG_PRINT("info",("Using locked table"));
goto reset;
}
if (is_locked_view(thd, table_list))
DBUG_RETURN(FALSE); // VIEW
/*
No table in the locked tables list. In case of explicit LOCK TABLES
this can happen if a user did not include the table into the list.
In case of pre-locked mode locked tables list is generated automatically,
so we may only end up here if the table did not exist when
locked tables list was created.
*/
if (thd->locked_tables_mode == LTM_PRELOCKED)
my_error(ER_NO_SUCH_TABLE, MYF(0), table_list->db, table_list->alias);
else
my_error(ER_TABLE_NOT_LOCKED, MYF(0), alias);
DBUG_RETURN(TRUE);
}
/*
Non pre-locked/LOCK TABLES mode, and the table is not temporary.
This is the normal use case.
*/
if (! (flags & MYSQL_OPEN_HAS_MDL_LOCK))
{
/*
We are not under LOCK TABLES and going to acquire write-lock/
modify the base table. We need to acquire protection against
global read lock until end of this statement in order to have
this statement blocked by active FLUSH TABLES WITH READ LOCK.
We don't need to acquire this protection under LOCK TABLES as
such protection already acquired at LOCK TABLES time and
not released until UNLOCK TABLES.
We don't block statements which modify only temporary tables
as these tables are not preserved by any form of
backup which uses FLUSH TABLES WITH READ LOCK.
TODO: The fact that we sometimes acquire protection against
GRL only when we encounter table to be write-locked
slightly increases probability of deadlock.
This problem will be solved once Alik pushes his
temporary table refactoring patch and we can start
pre-acquiring metadata locks at the beggining of
open_tables() call.
*/
if (table_list->mdl_request.is_write_lock_request() &&
! (flags & (MYSQL_OPEN_IGNORE_GLOBAL_READ_LOCK |
MYSQL_OPEN_FORCE_SHARED_MDL |
MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL |
MYSQL_OPEN_SKIP_SCOPED_MDL_LOCK)) &&
! ot_ctx->has_protection_against_grl())
{
MDL_request protection_request;
MDL_deadlock_handler mdl_deadlock_handler(ot_ctx);
if (thd->global_read_lock.can_acquire_protection())
DBUG_RETURN(TRUE);
protection_request.init(MDL_key::GLOBAL, "", "", MDL_INTENTION_EXCLUSIVE,
MDL_STATEMENT);
/*
Install error handler which if possible will convert deadlock error
into request to back-off and restart process of opening tables.
*/
thd->push_internal_handler(&mdl_deadlock_handler);
bool result= thd->mdl_context.acquire_lock(&protection_request,
ot_ctx->get_timeout());
thd->pop_internal_handler();
if (result)
DBUG_RETURN(TRUE);
ot_ctx->set_has_protection_against_grl();
}
if (open_table_get_mdl_lock(thd, ot_ctx, &table_list->mdl_request,
flags, &mdl_ticket) ||
mdl_ticket == NULL)
{
DEBUG_SYNC(thd, "before_open_table_wait_refresh");
DBUG_RETURN(TRUE);
}
DEBUG_SYNC(thd, "after_open_table_mdl_shared");
}
else
{
/*
Grab reference to the MDL lock ticket that was acquired
by the caller.
*/
mdl_ticket= table_list->mdl_request.ticket;
}
if (table_list->open_strategy == TABLE_LIST::OPEN_IF_EXISTS)
{
if (!ha_table_exists(thd, table_list->db, table_list->table_name))
DBUG_RETURN(FALSE);
}
else if (table_list->open_strategy == TABLE_LIST::OPEN_STUB)
DBUG_RETURN(FALSE);
/* Table exists. Let us try to open it. */
if (table_list->i_s_requested_object & OPEN_TABLE_ONLY)
gts_flags= GTS_TABLE;
else if (table_list->i_s_requested_object & OPEN_VIEW_ONLY)
gts_flags= GTS_VIEW;
else
gts_flags= GTS_TABLE | GTS_VIEW;
retry_share:
share= tdc_acquire_share(thd, table_list, gts_flags, &table);
if (!share)
{
/*
Hide "Table doesn't exist" errors if the table belongs to a view.
The check for thd->is_error() is necessary to not push an
unwanted error in case the error was already silenced.
@todo Rework the alternative ways to deal with ER_NO_SUCH TABLE.
*/
if (thd->is_error())
{
if (table_list->parent_l)
{
thd->clear_error();
my_error(ER_WRONG_MRG_TABLE, MYF(0));
}
else if (table_list->belong_to_view)
{
TABLE_LIST *view= table_list->belong_to_view;
thd->clear_error();
my_error(ER_VIEW_INVALID, MYF(0),
view->view_db.str, view->view_name.str);
}
}
DBUG_RETURN(TRUE);
}
/*
Check if this TABLE_SHARE-object corresponds to a view. Note, that there is
no need to check TABLE_SHARE::tdc.flushed as we do for regular tables,
because view shares are always up to date.
*/
if (share->is_view)
{
/*
If parent_l of the table_list is non null then a merge table
has this view as child table, which is not supported.
*/
if (table_list->parent_l)
{
my_error(ER_WRONG_MRG_TABLE, MYF(0));
goto err_lock;
}
/*
This table is a view. Validate its metadata version: in particular,
that it was a view when the statement was prepared.
*/
if (check_and_update_table_version(thd, table_list, share))
goto err_lock;
/* Open view */
if (mysql_make_view(thd, share, table_list, false))
goto err_lock;
/* TODO: Don't free this */
tdc_release_share(share);
DBUG_ASSERT(table_list->view);
DBUG_RETURN(FALSE);
}
if (!(flags & MYSQL_OPEN_IGNORE_FLUSH))
{
if (share->tdc->flushed)
{
DBUG_PRINT("info", ("Found old share version: %lld current: %lld",
share->tdc->version, tdc_refresh_version()));
/*
We already have an MDL lock. But we have encountered an old
version of table in the table definition cache which is possible
when someone changes the table version directly in the cache
without acquiring a metadata lock (e.g. this can happen during
"rolling" FLUSH TABLE(S)).
Release our reference to share, wait until old version of
share goes away and then try to get new version of table share.
*/
if (table)
tc_release_table(table);
else
tdc_release_share(share);
MDL_deadlock_handler mdl_deadlock_handler(ot_ctx);
bool wait_result;
thd->push_internal_handler(&mdl_deadlock_handler);
wait_result= tdc_wait_for_old_version(thd, table_list->db,
table_list->table_name,
ot_ctx->get_timeout(),
mdl_ticket->get_deadlock_weight());
thd->pop_internal_handler();
if (wait_result)
DBUG_RETURN(TRUE);
goto retry_share;
}
if (thd->open_tables && thd->open_tables->s->tdc->flushed)
{
/*
If the version changes while we're opening the tables,
we have to back off, close all the tables opened-so-far,
and try to reopen them. Note: refresh_version is currently
changed only during FLUSH TABLES.
*/
if (table)
tc_release_table(table);
else
tdc_release_share(share);
(void)ot_ctx->request_backoff_action(Open_table_context::OT_REOPEN_TABLES,
NULL);
DBUG_RETURN(TRUE);
}
}
if (table)
{
DBUG_ASSERT(table->file != NULL);
MYSQL_REBIND_TABLE(table->file);
}
else
{
enum open_frm_error error;
/* make a new table */
if (!(table=(TABLE*) my_malloc(sizeof(*table),MYF(MY_WME))))
goto err_lock;
error= open_table_from_share(thd, share, alias,
HA_OPEN_KEYFILE | HA_TRY_READ_ONLY,
EXTRA_RECORD,
thd->open_options, table, FALSE);
if (error)
{
my_free(table);
if (error == OPEN_FRM_DISCOVER)
(void) ot_ctx->request_backoff_action(Open_table_context::OT_DISCOVER,
table_list);
else if (share->crashed)
{
if (!(flags & MYSQL_OPEN_IGNORE_REPAIR))
(void) ot_ctx->request_backoff_action(Open_table_context::OT_REPAIR,
table_list);
else
table_list->crashed= 1; /* Mark that table was crashed */
}
goto err_lock;
}
if (open_table_entry_fini(thd, share, table))
{
closefrm(table);
my_free(table);
goto err_lock;
}
/* Add table to the share's used tables list. */
tc_add_table(thd, table);
}
table->mdl_ticket= mdl_ticket;
table->reginfo.lock_type=TL_READ; /* Assume read */
table->init(thd, table_list);
table->next= thd->open_tables; /* Link into simple list */
thd->set_open_tables(table);
reset:
/*
Check that there is no reference to a condition from an earlier query
(cf. Bug#58553).
*/
DBUG_ASSERT(table->file->pushed_cond == NULL);
table_list->updatable= 1; // It is not derived table nor non-updatable VIEW
table_list->table= table;
#ifdef WITH_PARTITION_STORAGE_ENGINE
if (table->part_info)
{
/* Set all [named] partitions as used. */
if (table->part_info->set_partition_bitmaps(table_list))
DBUG_RETURN(true);
}
else if (table_list->partition_names)
{
/* Don't allow PARTITION () clause on a nonpartitioned table */
my_error(ER_PARTITION_CLAUSE_ON_NONPARTITIONED, MYF(0));
DBUG_RETURN(true);
}
#endif
DBUG_RETURN(FALSE);
err_lock:
tdc_release_share(share);
DBUG_PRINT("exit", ("failed"));
DBUG_RETURN(TRUE);
}
/**
Find table in the list of open tables.
@param list List of TABLE objects to be inspected.
@param db Database name
@param table_name Table name
@return Pointer to the TABLE object found, 0 if no table found.
*/
TABLE *find_locked_table(TABLE *list, const char *db, const char *table_name)
{
char key[MAX_DBKEY_LENGTH];
uint key_length= tdc_create_key(key, db, table_name);
for (TABLE *table= list; table ; table=table->next)
{
if (table->s->table_cache_key.length == key_length &&
!memcmp(table->s->table_cache_key.str, key, key_length))
return table;
}
return(0);
}
/**
Find instance of TABLE with upgradable or exclusive metadata
lock from the list of open tables, emit error if no such table
found.
@param thd Thread context
@param db Database name.
@param table_name Name of table.
@param p_error In the case of an error (when the function returns NULL)
the error number is stored there.
If the p_error is NULL, function launches the error itself.
@note This function checks if the connection holds a global IX
metadata lock. If no such lock is found, it is not safe to
upgrade the lock and ER_TABLE_NOT_LOCKED_FOR_WRITE will be
reported.
@return Pointer to TABLE instance with MDL_SHARED_UPGRADABLE
MDL_SHARED_NO_WRITE, MDL_SHARED_NO_READ_WRITE, or
MDL_EXCLUSIVE metadata lock, NULL otherwise.
*/
TABLE *find_table_for_mdl_upgrade(THD *thd, const char *db,
const char *table_name, int *p_error)
{
TABLE *tab= find_locked_table(thd->open_tables, db, table_name);
int error;
if (!tab)
{
error= ER_TABLE_NOT_LOCKED;
goto err_exit;
}
/*
It is not safe to upgrade the metadata lock without a global IX lock.
This can happen with FLUSH TABLES <list> WITH READ LOCK as we in these
cases don't take a global IX lock in order to be compatible with
global read lock.
*/
if (!thd->mdl_context.is_lock_owner(MDL_key::GLOBAL, "", "",
MDL_INTENTION_EXCLUSIVE))
{
error= ER_TABLE_NOT_LOCKED_FOR_WRITE;
goto err_exit;
}
while (tab->mdl_ticket != NULL &&
!tab->mdl_ticket->is_upgradable_or_exclusive() &&
(tab= find_locked_table(tab->next, db, table_name)))
continue;
if (unlikely(!tab))
{
error= ER_TABLE_NOT_LOCKED_FOR_WRITE;
goto err_exit;
}
return tab;
err_exit:
if (p_error)
*p_error= error;
else
my_error(error, MYF(0), table_name);
return NULL;
}
/***********************************************************************
class Locked_tables_list implementation. Declared in sql_class.h
************************************************************************/
/**
Enter LTM_LOCK_TABLES mode.
Enter the LOCK TABLES mode using all the tables that are
currently open and locked in this connection.
Initializes a TABLE_LIST instance for every locked table.
@param thd thread handle
@return TRUE if out of memory.
*/
bool
Locked_tables_list::init_locked_tables(THD *thd)
{
DBUG_ASSERT(thd->locked_tables_mode == LTM_NONE);
DBUG_ASSERT(m_locked_tables == NULL);
DBUG_ASSERT(m_reopen_array == NULL);
DBUG_ASSERT(m_locked_tables_count == 0);
for (TABLE *table= thd->open_tables; table;
table= table->next, m_locked_tables_count++)
{
TABLE_LIST *src_table_list= table->pos_in_table_list;
char *db, *table_name, *alias;
size_t db_len= table->s->db.length;
size_t table_name_len= table->s->table_name.length;
size_t alias_len= table->alias.length();
TABLE_LIST *dst_table_list;
if (! multi_alloc_root(&m_locked_tables_root,
&dst_table_list, sizeof(*dst_table_list),
&db, db_len + 1,
&table_name, table_name_len + 1,
&alias, alias_len + 1,
NullS))
{
reset();
return TRUE;
}
memcpy(db, table->s->db.str, db_len + 1);
memcpy(table_name, table->s->table_name.str, table_name_len + 1);
strmake(alias, table->alias.ptr(), alias_len);
dst_table_list->init_one_table(db, db_len, table_name, table_name_len,
alias, table->reginfo.lock_type);
dst_table_list->table= table;
dst_table_list->mdl_request.ticket= src_table_list->mdl_request.ticket;
/* Link last into the list of tables */
*(dst_table_list->prev_global= m_locked_tables_last)= dst_table_list;
m_locked_tables_last= &dst_table_list->next_global;
table->pos_in_locked_tables= dst_table_list;
}
if (m_locked_tables_count)
{
/**
Allocate an auxiliary array to pass to mysql_lock_tables()
in reopen_tables(). reopen_tables() is a critical
path and we don't want to complicate it with extra allocations.
*/
m_reopen_array= (TABLE_LIST**)alloc_root(&m_locked_tables_root,
sizeof(TABLE_LIST*) *
(m_locked_tables_count+1));
if (m_reopen_array == NULL)
{
reset();
return TRUE;
}
}
TRANSACT_TRACKER(add_trx_state(thd, TX_LOCKED_TABLES));
thd->enter_locked_tables_mode(LTM_LOCK_TABLES);
return FALSE;
}
/**
Leave LTM_LOCK_TABLES mode if it's been entered.
Close all locked tables, free memory, and leave the mode.
@note This function is a no-op if we're not in LOCK TABLES.
*/
void
Locked_tables_list::unlock_locked_tables(THD *thd)
{
DBUG_ASSERT(!thd->in_sub_stmt &&
!(thd->state_flags & Open_tables_state::BACKUPS_AVAIL));
/*
Sic: we must be careful to not close open tables if
we're not in LOCK TABLES mode: unlock_locked_tables() is
sometimes called implicitly, expecting no effect on
open tables, e.g. from begin_trans().
*/
if (thd->locked_tables_mode != LTM_LOCK_TABLES)
return;
for (TABLE_LIST *table_list= m_locked_tables;
table_list; table_list= table_list->next_global)
{
/*
Clear the position in the list, the TABLE object will be
returned to the table cache.
*/
if (table_list->table) // If not closed
table_list->table->pos_in_locked_tables= NULL;
}
thd->leave_locked_tables_mode();
TRANSACT_TRACKER(clear_trx_state(thd, TX_LOCKED_TABLES));
DBUG_ASSERT(thd->transaction.stmt.is_empty());
close_thread_tables(thd);
/*
We rely on the caller to implicitly commit the
transaction and release transactional locks.
*/
/*
After closing tables we can free memory used for storing lock
request for metadata locks and TABLE_LIST elements.
*/
reset();
}
/**
Remove all meta data locks associated with table and release locked
table mode if there is no locked tables anymore
*/
void
Locked_tables_list::unlock_locked_table(THD *thd, MDL_ticket *mdl_ticket)
{
/*
Ensure we are in locked table mode.
As this function is only called on error condition it's better
to check this condition here than in the caller.
*/
if (thd->locked_tables_mode != LTM_LOCK_TABLES)
return;
if (mdl_ticket)
{
/*
Under LOCK TABLES we may have several instances of table open
and locked and therefore have to remove several metadata lock
requests associated with them.
*/
thd->mdl_context.release_all_locks_for_name(mdl_ticket);
}
if (thd->lock->table_count == 0)
unlock_locked_tables(thd);
}
/*
Free memory allocated for storing locks
*/
void Locked_tables_list::reset()
{
free_root(&m_locked_tables_root, MYF(0));
m_locked_tables= NULL;
m_locked_tables_last= &m_locked_tables;
m_reopen_array= NULL;
m_locked_tables_count= 0;
some_table_marked_for_reopen= 0;
}
/**
Unlink a locked table from the locked tables list, either
temporarily or permanently.
@param thd thread handle
@param table_list the element of locked tables list.
The implementation assumes that this argument
points to a TABLE_LIST element linked into
the locked tables list. Passing a TABLE_LIST
instance that is not part of locked tables
list will lead to a crash.
@param remove_from_locked_tables
TRUE if the table is removed from the list
permanently.
This function is a no-op if we're not under LOCK TABLES.
@sa Locked_tables_list::reopen_tables()
*/
void Locked_tables_list::unlink_from_list(THD *thd,
TABLE_LIST *table_list,
bool remove_from_locked_tables)
{
/*
If mode is not LTM_LOCK_TABLES, we needn't do anything. Moreover,
outside this mode pos_in_locked_tables value is not trustworthy.
*/
if (thd->locked_tables_mode != LTM_LOCK_TABLES &&
thd->locked_tables_mode != LTM_PRELOCKED_UNDER_LOCK_TABLES)
return;
/*
table_list must be set and point to pos_in_locked_tables of some
table.
*/
DBUG_ASSERT(table_list->table->pos_in_locked_tables == table_list);
/* Clear the pointer, the table will be returned to the table cache. */
table_list->table->pos_in_locked_tables= NULL;
/* Mark the table as closed in the locked tables list. */
table_list->table= NULL;
/*
If the table is being dropped or renamed, remove it from
the locked tables list (implicitly drop the LOCK TABLES lock
on it).
*/
if (remove_from_locked_tables)
{
*table_list->prev_global= table_list->next_global;
if (table_list->next_global == NULL)
m_locked_tables_last= table_list->prev_global;
else
table_list->next_global->prev_global= table_list->prev_global;
m_locked_tables_count--;
}
}
/**
This is an attempt to recover (somewhat) in case of an error.
If we failed to reopen a closed table, let's unlink it from the
list and forget about it. From a user perspective that would look
as if the server "lost" the lock on one of the locked tables.
@note This function is a no-op if we're not under LOCK TABLES.
*/
void Locked_tables_list::
unlink_all_closed_tables(THD *thd, MYSQL_LOCK *lock, size_t reopen_count)
{
/* If we managed to take a lock, unlock tables and free the lock. */
if (lock)
mysql_unlock_tables(thd, lock);
/*
If a failure happened in reopen_tables(), we may have succeeded
reopening some tables, but not all.
This works when the connection was killed in mysql_lock_tables().
*/
if (reopen_count)
{
while (reopen_count--)
{
/*
When closing the table, we must remove it
from thd->open_tables list.
We rely on the fact that open_table() that was used
in reopen_tables() always links the opened table
to the beginning of the open_tables list.
*/
DBUG_ASSERT(thd->open_tables == m_reopen_array[reopen_count]->table);
thd->open_tables->pos_in_locked_tables->table= NULL;
thd->open_tables->pos_in_locked_tables= 0;
close_thread_table(thd, &thd->open_tables);
}
}
/* Exclude all closed tables from the LOCK TABLES list. */
for (TABLE_LIST *table_list= m_locked_tables; table_list; table_list=
table_list->next_global)
{
if (table_list->table == NULL)
{
/* Unlink from list. */
*table_list->prev_global= table_list->next_global;
if (table_list->next_global == NULL)
m_locked_tables_last= table_list->prev_global;
else
table_list->next_global->prev_global= table_list->prev_global;
m_locked_tables_count--;
}
}
/* If no tables left, do an automatic UNLOCK TABLES */
if (thd->lock && thd->lock->table_count == 0)
unlock_locked_tables(thd);
}
/*
Mark all instances of the table to be reopened
This is only needed when LOCK TABLES is active
*/
void Locked_tables_list::mark_table_for_reopen(THD *thd, TABLE *table)
{
TABLE_SHARE *share= table->s;
for (TABLE_LIST *table_list= m_locked_tables;
table_list; table_list= table_list->next_global)
{
if (table_list->table->s == share)
table_list->table->internal_set_needs_reopen(true);
}
/* This is needed in the case where lock tables where not used */
table->internal_set_needs_reopen(true);
some_table_marked_for_reopen= 1;
}
/**
Reopen the tables locked with LOCK TABLES and temporarily closed
by a DDL statement or FLUSH TABLES.
@param need_reopen If set, reopen open tables that are marked with
for reopen.
If not set, reopen tables that where closed.
@note This function is a no-op if we're not under LOCK TABLES.
@return TRUE if an error reopening the tables. May happen in
case of some fatal system error only, e.g. a disk
corruption, out of memory or a serious bug in the
locking.
*/
bool
Locked_tables_list::reopen_tables(THD *thd, bool need_reopen)
{
Open_table_context ot_ctx(thd, MYSQL_OPEN_REOPEN);
size_t reopen_count= 0;
MYSQL_LOCK *lock;
MYSQL_LOCK *merged_lock;
DBUG_ENTER("Locked_tables_list::reopen_tables");
DBUG_ASSERT(some_table_marked_for_reopen || !need_reopen);
/* Reset flag that some table was marked for reopen */
some_table_marked_for_reopen= 0;
for (TABLE_LIST *table_list= m_locked_tables;
table_list; table_list= table_list->next_global)
{
if (need_reopen)
{
if (!table_list->table || !table_list->table->needs_reopen())
continue;
for (TABLE **prev= &thd->open_tables; *prev; prev= &(*prev)->next)
{
if (*prev == table_list->table)
{
thd->locked_tables_list.unlink_from_list(thd, table_list, false);
mysql_lock_remove(thd, thd->lock, *prev);
(*prev)->file->extra(HA_EXTRA_PREPARE_FOR_FORCED_CLOSE);
close_thread_table(thd, prev);
break;
}
}
DBUG_ASSERT(table_list->table == NULL);
}
else
{
if (table_list->table) /* The table was not closed */
continue;
}
DBUG_ASSERT(reopen_count < m_locked_tables_count);
m_reopen_array[reopen_count++]= table_list;
}
if (reopen_count)
{
TABLE **tables= (TABLE**) my_alloca(reopen_count * sizeof(TABLE*));
for (uint i= 0 ; i < reopen_count ; i++)
{
TABLE_LIST *table_list= m_reopen_array[i];
/* Links into thd->open_tables upon success */
if (open_table(thd, table_list, &ot_ctx))
{
unlink_all_closed_tables(thd, 0, i);
my_afree((void*) tables);
DBUG_RETURN(TRUE);
}
tables[i]= table_list->table;
table_list->table->pos_in_locked_tables= table_list;
/* See also the comment on lock type in init_locked_tables(). */
table_list->table->reginfo.lock_type= table_list->lock_type;
}
thd->in_lock_tables= 1;
/*
We re-lock all tables with mysql_lock_tables() at once rather
than locking one table at a time because of the case
reported in Bug#45035: when the same table is present
in the list many times, thr_lock.c fails to grant READ lock
on a table that is already locked by WRITE lock, even if
WRITE lock is taken by the same thread. If READ and WRITE
lock are passed to thr_lock.c in the same list, everything
works fine. Patching legacy code of thr_lock.c is risking to
break something else.
*/
lock= mysql_lock_tables(thd, tables, reopen_count,
MYSQL_OPEN_REOPEN);
thd->in_lock_tables= 0;
if (lock == NULL || (merged_lock=
mysql_lock_merge(thd->lock, lock)) == NULL)
{
unlink_all_closed_tables(thd, lock, reopen_count);
if (! thd->killed)
my_error(ER_LOCK_DEADLOCK, MYF(0));
my_afree((void*) tables);
DBUG_RETURN(TRUE);
}
thd->lock= merged_lock;
my_afree((void*) tables);
}
DBUG_RETURN(FALSE);
}
/**
Add back a locked table to the locked list that we just removed from it.
This is needed in CREATE OR REPLACE TABLE where we are dropping, creating
and re-opening a locked table.
@return 0 0k
@return 1 error
*/
bool Locked_tables_list::restore_lock(THD *thd, TABLE_LIST *dst_table_list,
TABLE *table, MYSQL_LOCK *lock)
{
MYSQL_LOCK *merged_lock;
DBUG_ENTER("restore_lock");
DBUG_ASSERT(!strcmp(dst_table_list->table_name, table->s->table_name.str));
/* Ensure we have the memory to add the table back */
if (!(merged_lock= mysql_lock_merge(thd->lock, lock)))
DBUG_RETURN(1);
thd->lock= merged_lock;
/* Link to the new table */
dst_table_list->table= table;
/*
The lock type may have changed (normally it should not as create
table will lock the table in write mode
*/
dst_table_list->lock_type= table->reginfo.lock_type;
table->pos_in_locked_tables= dst_table_list;
add_back_last_deleted_lock(dst_table_list);
table->mdl_ticket->downgrade_lock(table->reginfo.lock_type >=
TL_WRITE_ALLOW_WRITE ?
MDL_SHARED_NO_READ_WRITE :
MDL_SHARED_READ);
DBUG_RETURN(0);
}
/*
Add back the last deleted lock structure.
This should be followed by a call to reopen_tables() to
open the table.
*/
void Locked_tables_list::add_back_last_deleted_lock(TABLE_LIST *dst_table_list)
{
/* Link the lock back in the locked tables list */
dst_table_list->prev_global= m_locked_tables_last;
*m_locked_tables_last= dst_table_list;
m_locked_tables_last= &dst_table_list->next_global;
dst_table_list->next_global= 0;
m_locked_tables_count++;
}
#ifndef DBUG_OFF
/* Cause a spurious statement reprepare for debug purposes. */
static bool inject_reprepare(THD *thd)
{
if (thd->m_reprepare_observer && thd->stmt_arena->is_reprepared == FALSE)
{
thd->m_reprepare_observer->report_error(thd);
return TRUE;
}
return FALSE;
}
#endif
/**
Compare metadata versions of an element obtained from the table
definition cache and its corresponding node in the parse tree.
@details If the new and the old values mismatch, invoke
Metadata_version_observer.
At prepared statement prepare, all TABLE_LIST version values are
NULL and we always have a mismatch. But there is no observer set
in THD, and therefore no error is reported. Instead, we update
the value in the parse tree, effectively recording the original
version.
At prepared statement execute, an observer may be installed. If
there is a version mismatch, we push an error and return TRUE.
For conventional execution (no prepared statements), the
observer is never installed.
@sa Execute_observer
@sa check_prepared_statement() to see cases when an observer is installed
@sa TABLE_LIST::is_table_ref_id_equal()
@sa TABLE_SHARE::get_table_ref_id()
@param[in] thd used to report errors
@param[in,out] tables TABLE_LIST instance created by the parser
Metadata version information in this object
is updated upon success.
@param[in] table_share an element from the table definition cache
@retval TRUE an error, which has been reported
@retval FALSE success, version in TABLE_LIST has been updated
*/
static bool
check_and_update_table_version(THD *thd,
TABLE_LIST *tables, TABLE_SHARE *table_share)
{
if (! tables->is_table_ref_id_equal(table_share))
{
if (thd->m_reprepare_observer &&
thd->m_reprepare_observer->report_error(thd))
{
/*
Version of the table share is different from the
previous execution of the prepared statement, and it is
unacceptable for this SQLCOM. Error has been reported.
*/
DBUG_ASSERT(thd->is_error());
return TRUE;
}
/* Always maintain the latest version and type */
tables->set_table_ref_id(table_share);
}
DBUG_EXECUTE_IF("reprepare_each_statement", return inject_reprepare(thd););
return FALSE;
}
/**
Compares versions of a stored routine obtained from the sp cache
and the version used at prepare.
@details If the new and the old values mismatch, invoke
Metadata_version_observer.
At prepared statement prepare, all Sroutine_hash_entry version values
are NULL and we always have a mismatch. But there is no observer set
in THD, and therefore no error is reported. Instead, we update
the value in Sroutine_hash_entry, effectively recording the original
version.
At prepared statement execute, an observer may be installed. If
there is a version mismatch, we push an error and return TRUE.
For conventional execution (no prepared statements), the
observer is never installed.
@param[in] thd used to report errors
@param[in/out] rt pointer to stored routine entry in the
parse tree
@param[in] sp pointer to stored routine cache entry.
Can be NULL if there is no such routine.
@retval TRUE an error, which has been reported
@retval FALSE success, version in Sroutine_hash_entry has been updated
*/
static bool
check_and_update_routine_version(THD *thd, Sroutine_hash_entry *rt,
sp_head *sp)
{
ulong spc_version= sp_cache_version();
/* sp is NULL if there is no such routine. */
ulong version= sp ? sp->sp_cache_version() : spc_version;
/*
If the version in the parse tree is stale,
or the version in the cache is stale and sp is not used,
we need to reprepare.
Sic: version != spc_version <--> sp is not NULL.
*/
if (rt->m_sp_cache_version != version ||
(version != spc_version && !sp->is_invoked()))
{
if (thd->m_reprepare_observer &&
thd->m_reprepare_observer->report_error(thd))
{
/*
Version of the sp cache is different from the
previous execution of the prepared statement, and it is
unacceptable for this SQLCOM. Error has been reported.
*/
DBUG_ASSERT(thd->is_error());
return TRUE;
}
/* Always maintain the latest cache version. */
rt->m_sp_cache_version= version;
}
return FALSE;
}
/**
Open view by getting its definition from disk (and table cache in future).
@param thd Thread handle
@param table_list TABLE_LIST with db, table_name & belong_to_view
@param flags Flags which modify how we open the view
@todo This function is needed for special handling of views under
LOCK TABLES. We probably should get rid of it in long term.
@return FALSE if success, TRUE - otherwise.
*/
bool tdc_open_view(THD *thd, TABLE_LIST *table_list, uint flags)
{
TABLE not_used;
TABLE_SHARE *share;
bool err= TRUE;
if (!(share= tdc_acquire_share(thd, table_list, GTS_VIEW)))
return TRUE;
DBUG_ASSERT(share->is_view);
if (flags & CHECK_METADATA_VERSION)
{
/*
Check TABLE_SHARE-version of view only if we have been instructed to do
so. We do not need to check the version if we're executing CREATE VIEW or
ALTER VIEW statements.
In the future, this functionality should be moved out from
tdc_open_view(), and tdc_open_view() should became a part of a clean
table-definition-cache interface.
*/
if (check_and_update_table_version(thd, table_list, share))
goto ret;
}
err= mysql_make_view(thd, share, table_list, (flags & OPEN_VIEW_NO_PARSE));
ret:
tdc_release_share(share);
return err;
}
/**
Finalize the process of TABLE creation by loading table triggers
and taking action if a HEAP table content was emptied implicitly.
*/
static bool open_table_entry_fini(THD *thd, TABLE_SHARE *share, TABLE *entry)
{
if (Table_triggers_list::check_n_load(thd, share->db.str,
share->table_name.str, entry, 0))
return TRUE;
/*
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_buf[2*FN_REFLEN + 21];
String query(query_buf, sizeof(query_buf), system_charset_info);
query.length(0);
query.append("DELETE FROM ");
append_identifier(thd, &query, share->db.str, share->db.length);
query.append(".");
append_identifier(thd, &query, share->table_name.str,
share->table_name.length);
/*
we bypass thd->binlog_query() here,
as it does a lot of extra work, that is simply wrong in this case
*/
Query_log_event qinfo(thd, query.ptr(), query.length(),
FALSE, TRUE, TRUE, 0);
if (mysql_bin_log.write(&qinfo))
return TRUE;
}
}
return FALSE;
}
/**
Auxiliary routine which is used for performing automatical table repair.
*/
static bool auto_repair_table(THD *thd, TABLE_LIST *table_list)
{
TABLE_SHARE *share;
TABLE *entry;
bool result= TRUE;
thd->clear_error();
if (!(entry= (TABLE*)my_malloc(sizeof(TABLE), MYF(MY_WME))))
return result;
if (!(share= tdc_acquire_share(thd, table_list, GTS_TABLE)))
goto end_free;
DBUG_ASSERT(! share->is_view);
if (open_table_from_share(thd, share, table_list->alias,
HA_OPEN_KEYFILE | HA_TRY_READ_ONLY,
EXTRA_RECORD,
ha_open_options | HA_OPEN_FOR_REPAIR,
entry, FALSE) || ! entry->file ||
(entry->file->is_crashed() && entry->file->ha_check_and_repair(thd)))
{
/* Give right error message */
thd->clear_error();
my_error(ER_NOT_KEYFILE, MYF(0), share->table_name.str);
sql_print_error("Couldn't repair table: %s.%s", share->db.str,
share->table_name.str);
if (entry->file)
closefrm(entry);
}
else
{
thd->clear_error(); // Clear error message
closefrm(entry);
result= FALSE;
}
tdc_release_share(share);
/* Remove the repaired share from the table cache. */
tdc_remove_table(thd, TDC_RT_REMOVE_ALL,
table_list->db, table_list->table_name,
FALSE);
end_free:
my_free(entry);
return result;
}
/** Open_table_context */
Open_table_context::Open_table_context(THD *thd, uint flags)
:m_thd(thd),
m_failed_table(NULL),
m_start_of_statement_svp(thd->mdl_context.mdl_savepoint()),
m_timeout(flags & MYSQL_LOCK_IGNORE_TIMEOUT ?
LONG_TIMEOUT : thd->variables.lock_wait_timeout),
m_flags(flags),
m_action(OT_NO_ACTION),
m_has_locks(thd->mdl_context.has_locks()),
m_has_protection_against_grl(FALSE)
{}
/**
Check if we can back-off and set back off action if we can.
Otherwise report and return error.
@retval TRUE if back-off is impossible.
@retval FALSE if we can back off. Back off action has been set.
*/
bool
Open_table_context::
request_backoff_action(enum_open_table_action action_arg,
TABLE_LIST *table)
{
/*
A back off action may be one of three kinds:
* We met a broken table that needs repair, or a table that
is not present on this MySQL server and needs re-discovery.
To perform the action, we need an exclusive metadata lock on
the table. Acquiring X lock while holding other shared
locks can easily lead to deadlocks. We rely on MDL deadlock
detector to discover them. If this is a multi-statement
transaction that holds metadata locks for completed statements,
we should keep these locks after discovery/repair.
The action type in this case is OT_DISCOVER or OT_REPAIR.
* Our attempt to acquire an MDL lock lead to a deadlock,
detected by the MDL deadlock detector. The current
session was chosen a victim. If this is a multi-statement
transaction that holds metadata locks taken by completed
statements, restarting locking for the current statement
may lead to a livelock. Releasing locks of completed
statements can not be done as will lead to violation
of ACID. Thus, again, if m_has_locks is set,
we report an error. Otherwise, when there are no metadata
locks other than which belong to this statement, we can
try to recover from error by releasing all locks and
restarting the pre-locking.
Similarly, a deadlock error can occur when the
pre-locking process met a TABLE_SHARE that is being
flushed, and unsuccessfully waited for the flush to
complete. A deadlock in this case can happen, e.g.,
when our session is holding a metadata lock that
is being waited on by a session which is using
the table which is being flushed. The only way
to recover from this error is, again, to close all
open tables, release all locks, and retry pre-locking.
Action type name is OT_REOPEN_TABLES. Re-trying
while holding some locks may lead to a livelock,
and thus we don't do it.
* Finally, this session has open TABLEs from different
"generations" of the table cache. This can happen, e.g.,
when, after this session has successfully opened one
table used for a statement, FLUSH TABLES interfered and
expelled another table used in it. FLUSH TABLES then
blocks and waits on the table already opened by this
statement.
We detect this situation by ensuring that table cache
version of all tables used in a statement is the same.
If it isn't, all tables needs to be reopened.
Note, that we can always perform a reopen in this case,
even if we already have metadata locks, since we don't
keep tables open between statements and a livelock
is not possible.
*/
if (action_arg == OT_BACKOFF_AND_RETRY && m_has_locks)
{
my_error(ER_LOCK_DEADLOCK, MYF(0));
m_thd->mark_transaction_to_rollback(true);
return TRUE;
}
/*
If auto-repair or discovery are requested, a pointer to table
list element must be provided.
*/
if (table)
{
DBUG_ASSERT(action_arg == OT_DISCOVER || action_arg == OT_REPAIR);
m_failed_table= (TABLE_LIST*) m_thd->alloc(sizeof(TABLE_LIST));
if (m_failed_table == NULL)
return TRUE;
m_failed_table->init_one_table(table->db, table->db_length,
table->table_name,
table->table_name_length,
table->alias, TL_WRITE);
m_failed_table->open_strategy= table->open_strategy;
m_failed_table->mdl_request.set_type(MDL_EXCLUSIVE);
}
m_action= action_arg;
return FALSE;
}
/**
An error handler to mark transaction to rollback on DEADLOCK error
during DISCOVER / REPAIR.
*/
class MDL_deadlock_discovery_repair_handler : public Internal_error_handler
{
public:
virtual bool handle_condition(THD *thd,
uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level *level,
const char* msg,
Sql_condition ** cond_hdl)
{
if (sql_errno == ER_LOCK_DEADLOCK)
{
thd->mark_transaction_to_rollback(true);
}
/*
We have marked this transaction to rollback. Return false to allow
error to be reported or handled by other handlers.
*/
return false;
}
};
/**
Recover from failed attempt of open table by performing requested action.
@pre This function should be called only with "action" != OT_NO_ACTION
and after having called @sa close_tables_for_reopen().
@retval FALSE - Success. One should try to open tables once again.
@retval TRUE - Error
*/
bool
Open_table_context::recover_from_failed_open()
{
bool result= FALSE;
MDL_deadlock_discovery_repair_handler handler;
/*
Install error handler to mark transaction to rollback on DEADLOCK error.
*/
m_thd->push_internal_handler(&handler);
/* Execute the action. */
switch (m_action)
{
case OT_BACKOFF_AND_RETRY:
break;
case OT_REOPEN_TABLES:
break;
case OT_DISCOVER:
{
if ((result= lock_table_names(m_thd, m_thd->lex->create_info,
m_failed_table, NULL,
get_timeout(), 0)))
break;
tdc_remove_table(m_thd, TDC_RT_REMOVE_ALL, m_failed_table->db,
m_failed_table->table_name, FALSE);
m_thd->get_stmt_da()->clear_warning_info(m_thd->query_id);
m_thd->clear_error(); // Clear error message
No_such_table_error_handler no_such_table_handler;
bool open_if_exists= m_failed_table->open_strategy == TABLE_LIST::OPEN_IF_EXISTS;
if (open_if_exists)
m_thd->push_internal_handler(&no_such_table_handler);
result= !tdc_acquire_share(m_thd, m_failed_table,
GTS_TABLE | GTS_FORCE_DISCOVERY | GTS_NOLOCK);
if (open_if_exists)
{
m_thd->pop_internal_handler();
if (result && no_such_table_handler.safely_trapped_errors())
result= FALSE;
}
/*
Rollback to start of the current statement to release exclusive lock
on table which was discovered but preserve locks from previous statements
in current transaction.
*/
m_thd->mdl_context.rollback_to_savepoint(start_of_statement_svp());
break;
}
case OT_REPAIR:
{
if ((result= lock_table_names(m_thd, m_thd->lex->create_info,
m_failed_table, NULL,
get_timeout(), 0)))
break;
tdc_remove_table(m_thd, TDC_RT_REMOVE_ALL, m_failed_table->db,
m_failed_table->table_name, FALSE);
result= auto_repair_table(m_thd, m_failed_table);
/*
Rollback to start of the current statement to release exclusive lock
on table which was discovered but preserve locks from previous statements
in current transaction.
*/
m_thd->mdl_context.rollback_to_savepoint(start_of_statement_svp());
break;
}
default:
DBUG_ASSERT(0);
}
m_thd->pop_internal_handler();
/*
Reset the pointers to conflicting MDL request and the
TABLE_LIST element, set when we need auto-discovery or repair,
for safety.
*/
m_failed_table= NULL;
/*
Reset flag indicating that we have already acquired protection
against GRL. It is no longer valid as the corresponding lock was
released by close_tables_for_reopen().
*/
m_has_protection_against_grl= FALSE;
/* Prepare for possible another back-off. */
m_action= OT_NO_ACTION;
return result;
}
/*
Return a appropriate read lock type given a table object.
@param thd Thread context
@param prelocking_ctx Prelocking context.
@param table_list Table list element for table to be locked.
@param routine_modifies_data
Some routine that is invoked by statement
modifies data.
@remark Due to a statement-based replication limitation, statements such as
INSERT INTO .. SELECT FROM .. and CREATE TABLE .. SELECT FROM need
to grab a TL_READ_NO_INSERT lock on the source table in order to
prevent the replication of a concurrent statement that modifies the
source table. If such a statement gets applied on the slave before
the INSERT .. SELECT statement finishes, data on the master could
differ from data on the slave and end-up with a discrepancy between
the binary log and table state.
This also applies to SELECT/SET/DO statements which use stored
functions. Calls to such functions are going to be logged as a
whole and thus should be serialized against concurrent changes
to tables used by those functions. This is avoided when functions
do not modify data but only read it, since in this case nothing is
written to the binary log. Argument routine_modifies_data
denotes the same. So effectively, if the statement is not a
update query and routine_modifies_data is false, then
prelocking_placeholder does not take importance.
Furthermore, this does not apply to I_S and log tables as it's
always unsafe to replicate such tables under statement-based
replication as the table on the slave might contain other data
(ie: general_log is enabled on the slave). The statement will
be marked as unsafe for SBR in decide_logging_format().
@remark Note that even in prelocked mode it is important to correctly
determine lock type value. In this mode lock type is passed to
handler::start_stmt() method and can be used by storage engine,
for example, to determine what kind of row locks it should acquire
when reading data from the table.
*/
thr_lock_type read_lock_type_for_table(THD *thd,
Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list,
bool routine_modifies_data)
{
/*
In cases when this function is called for a sub-statement executed in
prelocked mode we can't rely on OPTION_BIN_LOG flag in THD::options
bitmap to determine that binary logging is turned on as this bit can
be cleared before executing sub-statement. So instead we have to look
at THD::variables::sql_log_bin member.
*/
bool log_on= mysql_bin_log.is_open() && thd->variables.sql_log_bin;
if ((log_on == FALSE) || (thd->wsrep_binlog_format() == BINLOG_FORMAT_ROW) ||
(table_list->table->s->table_category == TABLE_CATEGORY_LOG) ||
(table_list->table->s->table_category == TABLE_CATEGORY_PERFORMANCE) ||
!(is_update_query(prelocking_ctx->sql_command) ||
(routine_modifies_data && table_list->prelocking_placeholder) ||
(thd->locked_tables_mode > LTM_LOCK_TABLES)))
return TL_READ;
else
return TL_READ_NO_INSERT;
}
/*
Handle element of prelocking set other than table. E.g. cache routine
and, if prelocking strategy prescribes so, extend the prelocking set
with tables and routines used by it.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context.
@param[in] rt Element of prelocking set to be processed.
@param[in] prelocking_strategy Strategy which specifies how the
prelocking set should be extended when
one of its elements is processed.
@param[in] has_prelocking_list Indicates that prelocking set/list for
this statement has already been built.
@param[in] ot_ctx Context of open_table used to recover from
locking failures.
@param[out] need_prelocking Set to TRUE if it was detected that this
statement will require prelocked mode for
its execution, not touched otherwise.
@param[out] routine_modifies_data Set to TRUE if it was detected that this
routine does modify table data.
@retval FALSE Success.
@retval TRUE Failure (Conflicting metadata lock, OOM, other errors).
*/
static bool
open_and_process_routine(THD *thd, Query_tables_list *prelocking_ctx,
Sroutine_hash_entry *rt,
Prelocking_strategy *prelocking_strategy,
bool has_prelocking_list,
Open_table_context *ot_ctx,
bool *need_prelocking, bool *routine_modifies_data)
{
MDL_key::enum_mdl_namespace mdl_type= rt->mdl_request.key.mdl_namespace();
DBUG_ENTER("open_and_process_routine");
*routine_modifies_data= false;
switch (mdl_type)
{
case MDL_key::FUNCTION:
case MDL_key::PROCEDURE:
{
sp_head *sp;
/*
Try to get MDL lock on the routine.
Note that we do not take locks on top-level CALLs as this can
lead to a deadlock. Not locking top-level CALLs does not break
the binlog as only the statements in the called procedure show
up there, not the CALL itself.
*/
if (rt != (Sroutine_hash_entry*)prelocking_ctx->sroutines_list.first ||
mdl_type != MDL_key::PROCEDURE)
{
/*
Since we acquire only shared lock on routines we don't
need to care about global intention exclusive locks.
*/
DBUG_ASSERT(rt->mdl_request.type == MDL_SHARED);
/*
Waiting for a conflicting metadata lock to go away may
lead to a deadlock, detected by MDL subsystem.
If possible, we try to resolve such deadlocks by releasing all
metadata locks and restarting the pre-locking process.
To prevent the error from polluting the diagnostics area
in case of successful resolution, install a special error
handler for ER_LOCK_DEADLOCK error.
*/
MDL_deadlock_handler mdl_deadlock_handler(ot_ctx);
thd->push_internal_handler(&mdl_deadlock_handler);
bool result= thd->mdl_context.acquire_lock(&rt->mdl_request,
ot_ctx->get_timeout());
thd->pop_internal_handler();
if (result)
DBUG_RETURN(TRUE);
DEBUG_SYNC(thd, "after_shared_lock_pname");
/* Ensures the routine is up-to-date and cached, if exists. */
if (sp_cache_routine(thd, rt, has_prelocking_list, &sp))
DBUG_RETURN(TRUE);
/* Remember the version of the routine in the parse tree. */
if (check_and_update_routine_version(thd, rt, sp))
DBUG_RETURN(TRUE);
/* 'sp' is NULL when there is no such routine. */
if (sp)
{
*routine_modifies_data= sp->modifies_data();
if (!has_prelocking_list)
prelocking_strategy->handle_routine(thd, prelocking_ctx, rt, sp,
need_prelocking);
}
}
else
{
/*
If it's a top level call, just make sure we have a recent
version of the routine, if it exists.
Validating routine version is unnecessary, since CALL
does not affect the prepared statement prelocked list.
*/
if (sp_cache_routine(thd, rt, FALSE, &sp))
DBUG_RETURN(TRUE);
}
}
break;
case MDL_key::TRIGGER:
/**
We add trigger entries to lex->sroutines_list, but we don't
load them here. The trigger entry is only used when building
a transitive closure of objects used in a statement, to avoid
adding to this closure objects that are used in the trigger more
than once.
E.g. if a trigger trg refers to table t2, and the trigger table t1
is used multiple times in the statement (say, because it's used in
function f1() twice), we will only add t2 once to the list of
tables to prelock.
We don't take metadata locks on triggers either: they are protected
by a respective lock on the table, on which the trigger is defined.
The only two cases which give "trouble" are SHOW CREATE TRIGGER
and DROP TRIGGER statements. For these, statement syntax doesn't
specify the table on which this trigger is defined, so we have
to make a "dirty" read in the data dictionary to find out the
table name. Once we discover the table name, we take a metadata
lock on it, and this protects all trigger operations.
Of course the table, in theory, may disappear between the dirty
read and metadata lock acquisition, but in that case we just return
a run-time error.
Grammar of other trigger DDL statements (CREATE, DROP) requires
the table to be specified explicitly, so we use the table metadata
lock to protect trigger metadata in these statements. Similarly, in
DML we always use triggers together with their tables, and thus don't
need to take separate metadata locks on them.
*/
break;
default:
/* Impossible type value. */
DBUG_ASSERT(0);
}
DBUG_RETURN(FALSE);
}
/*
If we are not already in prelocked mode and extended table list is not
yet built we might have to build the prelocking set for this statement.
Since currently no prelocking strategy prescribes doing anything for
tables which are only read, we do below checks only if table is going
to be changed.
*/
bool extend_table_list(THD *thd, TABLE_LIST *tables,
Prelocking_strategy *prelocking_strategy,
bool has_prelocking_list)
{
bool error= false;
LEX *lex= thd->lex;
if (thd->locked_tables_mode <= LTM_LOCK_TABLES &&
! has_prelocking_list && tables->updating &&
tables->lock_type >= TL_WRITE_ALLOW_WRITE)
{
bool need_prelocking= FALSE;
TABLE_LIST **save_query_tables_last= lex->query_tables_last;
/*
Extend statement's table list and the prelocking set with
tables and routines according to the current prelocking
strategy.
For example, for DML statements we need to add tables and routines
used by triggers which are going to be invoked for this element of
table list and also add tables required for handling of foreign keys.
*/
error= prelocking_strategy->handle_table(thd, lex, tables,
&need_prelocking);
if (need_prelocking && ! lex->requires_prelocking())
lex->mark_as_requiring_prelocking(save_query_tables_last);
}
return error;
}
/**
Handle table list element by obtaining metadata lock, opening table or view
and, if prelocking strategy prescribes so, extending the prelocking set with
tables and routines used by it.
@param[in] thd Thread context.
@param[in] lex LEX structure for statement.
@param[in] tables Table list element to be processed.
@param[in,out] counter Number of tables which are open.
@param[in] flags Bitmap of flags to modify how the tables
will be open, see open_table() description
for details.
@param[in] prelocking_strategy Strategy which specifies how the
prelocking set should be extended
when table or view is processed.
@param[in] has_prelocking_list Indicates that prelocking set/list for
this statement has already been built.
@param[in] ot_ctx Context used to recover from a failed
open_table() attempt.
@retval FALSE Success.
@retval TRUE Error, reported unless there is a chance to recover from it.
*/
static bool
open_and_process_table(THD *thd, TABLE_LIST *tables, uint *counter, uint flags,
Prelocking_strategy *prelocking_strategy,
bool has_prelocking_list, Open_table_context *ot_ctx)
{
bool error= FALSE;
bool safe_to_ignore_table= FALSE;
LEX *lex= thd->lex;
DBUG_ENTER("open_and_process_table");
DEBUG_SYNC(thd, "open_and_process_table");
/*
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 end;
/*
We restore view's name and database wiped out by derived tables
processing and fall back to standard open process in order to
obtain proper metadata locks and do other necessary steps like
stored routine processing.
*/
tables->db= tables->view_db.str;
tables->db_length= tables->view_db.length;
tables->table_name= tables->view_name.str;
tables->table_name_length= tables->view_name.length;
}
else if (tables->select_lex)
{
/*
Check whether 'tables' refers to a table defined in a with clause.
If so set the reference to the definition in tables->with.
*/
if (!tables->with)
tables->with= tables->select_lex->find_table_def_in_with_clauses(tables);
/*
If 'tables' is defined in a with clause set the pointer to the
specification from its definition in tables->derived.
*/
if (tables->with)
{
if (tables->is_recursive_with_table() &&
!tables->is_with_table_recursive_reference())
{
tables->with->rec_outer_references++;
With_element *with_elem= tables->with;
while ((with_elem= with_elem->get_next_mutually_recursive()) !=
tables->with)
with_elem->rec_outer_references++;
}
if (tables->set_as_with_table(thd, tables->with))
DBUG_RETURN(1);
else
goto end;
}
}
if (!tables->derived &&
is_infoschema_db(tables->db, tables->db_length))
{
/*
Check whether the information schema contains a table
whose name is tables->schema_table_name
*/
ST_SCHEMA_TABLE *schema_table= tables->schema_table;
if (!schema_table ||
(schema_table->hidden &&
((sql_command_flags[lex->sql_command] & CF_STATUS_COMMAND) == 0 ||
/*
this check is used for show columns|keys from I_S hidden table
*/
lex->sql_command == SQLCOM_SHOW_FIELDS ||
lex->sql_command == SQLCOM_SHOW_KEYS)))
{
my_error(ER_UNKNOWN_TABLE, MYF(0),
tables->table_name, INFORMATION_SCHEMA_NAME.str);
DBUG_RETURN(1);
}
}
/*
If this TABLE_LIST object is a placeholder for an information_schema
table, create a temporary table to represent the information_schema
table in the query. Do not fill it yet - will be filled during
execution.
*/
if (tables->schema_table)
{
/*
If this information_schema table is merged into a mergeable
view, ignore it for now -- it will be filled when its respective
TABLE_LIST is processed. This code works only during re-execution.
*/
if (tables->view)
{
MDL_ticket *mdl_ticket;
/*
We still need to take a MDL lock on the merged view to protect
it from concurrent changes.
*/
if (!open_table_get_mdl_lock(thd, ot_ctx, &tables->mdl_request,
flags, &mdl_ticket) &&
mdl_ticket != NULL)
goto process_view_routines;
/* Fall-through to return error. */
}
else if (!mysql_schema_table(thd, lex, tables) &&
!check_and_update_table_version(thd, tables, tables->table->s))
{
goto end;
}
error= TRUE;
goto end;
}
DBUG_PRINT("tcache", ("opening table: '%s'.'%s' item: %p",
tables->db, tables->table_name, tables)); //psergey: invalid read of size 1 here
(*counter)++;
/*
Not a placeholder: must be a base/temporary table or a view. Let us open it.
*/
if (tables->table)
{
/*
If this TABLE_LIST object has an associated open TABLE object
(TABLE_LIST::table is not NULL), that TABLE object must be a pre-opened
temporary table.
*/
DBUG_ASSERT(is_temporary_table(tables));
}
else if (tables->open_type == OT_TEMPORARY_ONLY)
{
/*
OT_TEMPORARY_ONLY means that we are in CREATE TEMPORARY TABLE statement.
Also such table list element can't correspond to prelocking placeholder
or to underlying table of merge table.
So existing temporary table should have been preopened by this moment
and we can simply continue without trying to open temporary or base
table.
*/
DBUG_ASSERT(tables->open_strategy);
DBUG_ASSERT(!tables->prelocking_placeholder);
DBUG_ASSERT(!tables->parent_l);
DBUG_RETURN(0);
}
/* Not a placeholder: must be a base table or a view. Let us open it. */
if (tables->prelocking_placeholder)
{
/*
For the tables added by the pre-locking code, attempt to open
the table but fail silently if the table does not exist.
The real failure will occur when/if a statement attempts to use
that table.
*/
No_such_table_error_handler no_such_table_handler;
thd->push_internal_handler(&no_such_table_handler);
/*
We're opening a table from the prelocking list.
Since this table list element might have been added after pre-opening
of temporary tables we have to try to open temporary table for it.
We can't simply skip this table list element and postpone opening of
temporary table till the execution of substatement for several reasons:
- Temporary table can be a MERGE table with base underlying tables,
so its underlying tables has to be properly open and locked at
prelocking stage.
- Temporary table can be a MERGE table and we might be in PREPARE
phase for a prepared statement. In this case it is important to call
HA_ATTACH_CHILDREN for all merge children.
This is necessary because merge children remember "TABLE_SHARE ref type"
and "TABLE_SHARE def version" in the HA_ATTACH_CHILDREN operation.
If HA_ATTACH_CHILDREN is not called, these attributes are not set.
Then, during the first EXECUTE, those attributes need to be updated.
That would cause statement re-preparing (because changing those
attributes during EXECUTE is caught by THD::m_reprepare_observers).
The problem is that since those attributes are not set in merge
children, another round of PREPARE will not help.
*/
error= thd->open_temporary_table(tables);
if (!error && !tables->table)
error= open_table(thd, tables, ot_ctx);
thd->pop_internal_handler();
safe_to_ignore_table= no_such_table_handler.safely_trapped_errors();
}
else if (tables->parent_l && (thd->open_options & HA_OPEN_FOR_REPAIR))
{
/*
Also fail silently for underlying tables of a MERGE table if this
table is opened for CHECK/REPAIR TABLE statement. This is needed
to provide complete list of problematic underlying tables in
CHECK/REPAIR TABLE output.
*/
Repair_mrg_table_error_handler repair_mrg_table_handler;
thd->push_internal_handler(&repair_mrg_table_handler);
error= thd->open_temporary_table(tables);
if (!error && !tables->table)
error= open_table(thd, tables, ot_ctx);
thd->pop_internal_handler();
safe_to_ignore_table= repair_mrg_table_handler.safely_trapped_errors();
}
else
{
if (tables->parent_l)
{
/*
Even if we are opening table not from the prelocking list we
still might need to look for a temporary table if this table
list element corresponds to underlying table of a merge table.
*/
error= thd->open_temporary_table(tables);
}
if (!error && !tables->table)
error= open_table(thd, tables, ot_ctx);
}
if (error)
{
if (! ot_ctx->can_recover_from_failed_open() && safe_to_ignore_table)
{
DBUG_PRINT("info", ("open_table: ignoring table '%s'.'%s'",
tables->db, tables->alias));
error= FALSE;
}
goto end;
}
/*
We can't rely on simple check for TABLE_LIST::view to determine
that this is a view since during re-execution we might reopen
ordinary table in place of view and thus have TABLE_LIST::view
set from repvious execution and TABLE_LIST::table set from
current.
*/
if (!tables->table && 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 (lex->query_tables_own_last == &(tables->next_global) &&
tables->view->query_tables)
lex->query_tables_own_last= tables->view->query_tables_last;
/*
Let us free memory used by 'sroutines' hash here since we never
call destructor for this LEX.
*/
my_hash_free(&tables->view->sroutines);
goto process_view_routines;
}
/*
Special types of open can succeed but still don't set
TABLE_LIST::table to anything.
*/
if (tables->open_strategy && !tables->table)
goto end;
error= extend_table_list(thd, tables, prelocking_strategy, has_prelocking_list);
if (error)
goto end;
/* Copy grant information from TABLE_LIST instance to TABLE one. */
tables->table->grant= tables->grant;
/* Check and update metadata version of a base table. */
error= check_and_update_table_version(thd, tables, tables->table->s);
if (error)
goto end;
/*
After opening a MERGE table add the children to the query list of
tables, so that they are opened too.
Note that placeholders don't have the handler open.
*/
/* MERGE tables need to access parent and child TABLE_LISTs. */
DBUG_ASSERT(tables->table->pos_in_table_list == tables);
/* Non-MERGE tables ignore this call. */
if (tables->table->file->extra(HA_EXTRA_ADD_CHILDREN_LIST))
{
error= TRUE;
goto end;
}
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->locked_tables_mode <= LTM_LOCK_TABLES &&
! has_prelocking_list)
{
bool need_prelocking= FALSE;
TABLE_LIST **save_query_tables_last= lex->query_tables_last;
error= prelocking_strategy->handle_view(thd, lex, tables,
&need_prelocking);
if (need_prelocking && ! lex->requires_prelocking())
lex->mark_as_requiring_prelocking(save_query_tables_last);
if (error)
goto end;
}
end:
DBUG_RETURN(error);
}
/**
Acquire upgradable (SNW, SNRW) metadata locks on tables used by
LOCK TABLES or by a DDL statement. Under LOCK TABLES, we can't take
new locks, so use open_tables_check_upgradable_mdl() instead.
@param thd Thread context.
@param options DDL options.
@param tables_start Start of list of tables on which upgradable locks
should be acquired.
@param tables_end End of list of tables.
@param lock_wait_timeout Seconds to wait before timeout.
@param flags Bitmap of flags to modify how the tables will be
open, see open_table() description for details.
@retval FALSE Success.
@retval TRUE Failure (e.g. connection was killed) or table existed
for a CREATE TABLE.
@notes
In case of CREATE TABLE we avoid a wait for tables that are in use
by first trying to do a meta data lock with timeout == 0. If we get a
timeout we will check if table exists (it should) and retry with
normal timeout if it didn't exists.
Note that for CREATE TABLE IF EXISTS we only generate a warning
but still return TRUE (to abort the calling open_table() function).
On must check THD->is_error() if one wants to distinguish between warning
and error.
*/
bool
lock_table_names(THD *thd, const DDL_options_st &options,
TABLE_LIST *tables_start, TABLE_LIST *tables_end,
ulong lock_wait_timeout, uint flags)
{
MDL_request_list mdl_requests;
TABLE_LIST *table;
MDL_request global_request;
ulong org_lock_wait_timeout= lock_wait_timeout;
/* Check if we are using CREATE TABLE ... IF NOT EXISTS */
bool create_table;
Dummy_error_handler error_handler;
DBUG_ENTER("lock_table_names");
DBUG_ASSERT(!thd->locked_tables_mode);
for (table= tables_start; table && table != tables_end;
table= table->next_global)
{
if (table->mdl_request.type < MDL_SHARED_UPGRADABLE ||
table->mdl_request.type == MDL_SHARED_READ_ONLY ||
table->open_type == OT_TEMPORARY_ONLY ||
(table->open_type == OT_TEMPORARY_OR_BASE && is_temporary_table(table)))
{
continue;
}
/* Write lock on normal tables is not allowed in a read only transaction. */
if (thd->tx_read_only)
{
my_error(ER_CANT_EXECUTE_IN_READ_ONLY_TRANSACTION, MYF(0));
DBUG_RETURN(true);
}
/* Scoped locks: Take intention exclusive locks on all involved schemas. */
if (!(flags & MYSQL_OPEN_SKIP_SCOPED_MDL_LOCK))
{
MDL_request *schema_request= new (thd->mem_root) MDL_request;
if (schema_request == NULL)
DBUG_RETURN(TRUE);
schema_request->init(MDL_key::SCHEMA, table->db, "",
MDL_INTENTION_EXCLUSIVE,
MDL_TRANSACTION);
mdl_requests.push_front(schema_request);
}
mdl_requests.push_front(&table->mdl_request);
}
if (mdl_requests.is_empty())
DBUG_RETURN(FALSE);
/* Check if CREATE TABLE without REPLACE was used */
create_table= thd->lex->sql_command == SQLCOM_CREATE_TABLE &&
!options.or_replace();
if (!(flags & MYSQL_OPEN_SKIP_SCOPED_MDL_LOCK))
{
/*
Protect this statement against concurrent global read lock
by acquiring global intention exclusive lock with statement
duration.
*/
if (thd->global_read_lock.can_acquire_protection())
DBUG_RETURN(TRUE);
global_request.init(MDL_key::GLOBAL, "", "", MDL_INTENTION_EXCLUSIVE,
MDL_STATEMENT);
mdl_requests.push_front(&global_request);
if (create_table)
#ifdef WITH_WSREP
if (!(thd->lex->sql_command == SQLCOM_CREATE_TABLE &&
thd->wsrep_exec_mode == REPL_RECV))
#endif
lock_wait_timeout= 0; // Don't wait for timeout
}
for (;;)
{
if (create_table)
thd->push_internal_handler(&error_handler); // Avoid warnings & errors
bool res= thd->mdl_context.acquire_locks(&mdl_requests, lock_wait_timeout);
if (create_table)
thd->pop_internal_handler();
if (!res)
DBUG_RETURN(FALSE); // Got locks
if (!create_table)
DBUG_RETURN(TRUE); // Return original error
/*
We come here in the case of lock timeout when executing CREATE TABLE.
Verify that table does exist (it usually does, as we got a lock conflict)
*/
if (ha_table_exists(thd, tables_start->db, tables_start->table_name))
{
if (options.if_not_exists())
{
push_warning_printf(thd, Sql_condition::WARN_LEVEL_NOTE,
ER_TABLE_EXISTS_ERROR,
ER_THD(thd, ER_TABLE_EXISTS_ERROR),
tables_start->table_name);
}
else
my_error(ER_TABLE_EXISTS_ERROR, MYF(0), tables_start->table_name);
DBUG_RETURN(TRUE);
}
/*
We got error from acquire_locks, but the table didn't exists.
This could happen if another connection runs a statement
involving this non-existent table, and this statement took the mdl,
but didn't error out with ER_NO_SUCH_TABLE yet (yes, a race condition).
We play safe and restart the original acquire_locks with the
original timeout.
*/
create_table= 0;
lock_wait_timeout= org_lock_wait_timeout;
}
}
/**
Check for upgradable (SNW, SNRW) metadata locks on tables to be opened
for a DDL statement. Under LOCK TABLES, we can't take new locks, so we
must check if appropriate locks were pre-acquired.
@param thd Thread context.
@param tables_start Start of list of tables on which upgradable locks
should be searched for.
@param tables_end End of list of tables.
@param flags Bitmap of flags to modify how the tables will be
open, see open_table() description for details.
@retval FALSE Success.
@retval TRUE Failure (e.g. connection was killed)
*/
static bool
open_tables_check_upgradable_mdl(THD *thd, TABLE_LIST *tables_start,
TABLE_LIST *tables_end, uint flags)
{
TABLE_LIST *table;
DBUG_ASSERT(thd->locked_tables_mode);
for (table= tables_start; table && table != tables_end;
table= table->next_global)
{
/*
Check below needs to be updated if this function starts
called for SRO locks.
*/
DBUG_ASSERT(table->mdl_request.type != MDL_SHARED_READ_ONLY);
if (table->mdl_request.type < MDL_SHARED_UPGRADABLE ||
table->open_type == OT_TEMPORARY_ONLY ||
(table->open_type == OT_TEMPORARY_OR_BASE && is_temporary_table(table)))
{
continue;
}
/*
We don't need to do anything about the found TABLE instance as it
will be handled later in open_tables(), we only need to check that
an upgradable lock is already acquired. When we enter LOCK TABLES
mode, SNRW locks are acquired before all other locks. So if under
LOCK TABLES we find that there is TABLE instance with upgradeable
lock, all other instances of TABLE for the same table will have the
same ticket.
Note that this works OK even for CREATE TABLE statements which
request X type of metadata lock. This is because under LOCK TABLES
such statements don't create the table but only check if it exists
or, in most complex case, only insert into it.
Thus SNRW lock should be enough.
Note that find_table_for_mdl_upgrade() will report an error if
no suitable ticket is found.
*/
if (!find_table_for_mdl_upgrade(thd, table->db, table->table_name, NULL))
return TRUE;
}
return FALSE;
}
/**
Open all tables in list
@param[in] thd Thread context.
@param[in] options DDL options.
@param[in,out] start List of tables to be open (it can be adjusted for
statement that uses tables only implicitly, e.g.
for "SELECT f1()").
@param[out] counter Number of tables which were open.
@param[in] flags Bitmap of flags to modify how the tables will be
open, see open_table() description for details.
@param[in] prelocking_strategy Strategy which specifies how prelocking
algorithm should work for this statement.
@note
Unless we are already in prelocked mode and prelocking strategy prescribes
so 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. Statement that uses SFs, invokes triggers or
requires foreign key checks will be marked as requiring prelocking.
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.
@retval FALSE Success.
@retval TRUE Error, reported.
*/
bool open_tables(THD *thd, const DDL_options_st &options,
TABLE_LIST **start, uint *counter, uint flags,
Prelocking_strategy *prelocking_strategy)
{
/*
We use pointers to "next_global" member in the last processed
TABLE_LIST element and to the "next" member in the last processed
Sroutine_hash_entry element as iterators over, correspondingly,
the table list and stored routines list which stay valid and allow
to continue iteration when new elements are added to the tail of
the lists.
*/
TABLE_LIST **table_to_open;
Sroutine_hash_entry **sroutine_to_open;
TABLE_LIST *tables;
Open_table_context ot_ctx(thd, flags);
bool error= FALSE;
bool some_routine_modifies_data= FALSE;
bool has_prelocking_list;
DBUG_ENTER("open_tables");
/* Accessing data in XA_IDLE or XA_PREPARED is not allowed. */
enum xa_states xa_state= thd->transaction.xid_state.xa_state;
if (*start && (xa_state == XA_IDLE || xa_state == XA_PREPARED))
{
my_error(ER_XAER_RMFAIL, MYF(0), xa_state_names[xa_state]);
DBUG_RETURN(true);
}
thd->current_tablenr= 0;
restart:
/*
Close HANDLER tables which are marked for flush or against which there
are pending exclusive metadata locks. This is needed both in order to
avoid deadlocks and to have a point during statement execution at
which such HANDLERs are closed even if they don't create problems for
the current session (i.e. to avoid having a DDL blocked by HANDLERs
opened for a long time).
*/
if (thd->handler_tables_hash.records)
mysql_ha_flush(thd);
has_prelocking_list= thd->lex->requires_prelocking();
table_to_open= start;
sroutine_to_open= &thd->lex->sroutines_list.first;
*counter= 0;
THD_STAGE_INFO(thd, stage_opening_tables);
prelocking_strategy->reset(thd);
/*
If we are executing LOCK TABLES statement or a DDL statement
(in non-LOCK TABLES mode) we might have to acquire upgradable
semi-exclusive metadata locks (SNW or SNRW) on some of the
tables to be opened.
When executing CREATE TABLE .. If NOT EXISTS .. SELECT, the
table may not yet exist, in which case we acquire an exclusive
lock.
We acquire all such locks at once here as doing this in one
by one fashion may lead to deadlocks or starvation. Later when
we will be opening corresponding table pre-acquired metadata
lock will be reused (thanks to the fact that in recursive case
metadata locks are acquired without waiting).
*/
if (! (flags & (MYSQL_OPEN_HAS_MDL_LOCK |
MYSQL_OPEN_FORCE_SHARED_MDL |
MYSQL_OPEN_FORCE_SHARED_HIGH_PRIO_MDL)))
{
if (thd->locked_tables_mode)
{
/*
Under LOCK TABLES, we can't acquire new locks, so we instead
need to check if appropriate locks were pre-acquired.
*/
if (open_tables_check_upgradable_mdl(thd, *start,
thd->lex->first_not_own_table(),
flags))
{
error= TRUE;
goto error;
}
}
else
{
TABLE_LIST *table;
if (lock_table_names(thd, options, *start,
thd->lex->first_not_own_table(),
ot_ctx.get_timeout(), flags))
{
error= TRUE;
goto error;
}
for (table= *start; table && table != thd->lex->first_not_own_table();
table= table->next_global)
{
if (table->mdl_request.type >= MDL_SHARED_UPGRADABLE)
table->mdl_request.ticket= NULL;
}
}
}
/*
Perform steps of prelocking algorithm until there are unprocessed
elements in prelocking list/set.
*/
while (*table_to_open ||
(thd->locked_tables_mode <= LTM_LOCK_TABLES && *sroutine_to_open))
{
/*
For every table in the list of tables to open, try to find or open
a table.
*/
for (tables= *table_to_open; tables;
table_to_open= &tables->next_global, tables= tables->next_global)
{
error= open_and_process_table(thd, tables, counter, flags,
prelocking_strategy, has_prelocking_list,
&ot_ctx);
if (error)
{
if (ot_ctx.can_recover_from_failed_open())
{
/*
We have met exclusive metadata lock or old version of table.
Now we have to close all tables and release metadata locks.
We also have to throw away set of prelocked tables (and thus
close tables from this set that were open by now) since it
is 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.
We have to save pointer to table list element for table which we
have failed to open since closing tables can trigger removal of
elements from the table list (if MERGE tables are involved),
*/
close_tables_for_reopen(thd, start, ot_ctx.start_of_statement_svp());
/*
Here we rely on the fact that 'tables' still points to the valid
TABLE_LIST element. Altough currently this assumption is valid
it may change in future.
*/
if (ot_ctx.recover_from_failed_open())
goto error;
/* Re-open temporary tables after close_tables_for_reopen(). */
if (thd->open_temporary_tables(*start))
goto error;
error= FALSE;
goto restart;
}
goto error;
}
DEBUG_SYNC(thd, "open_tables_after_open_and_process_table");
}
/*
If we are not already in prelocked mode and extended table list is
not yet built for our statement we need to cache routines it uses
and build the prelocking list for it.
If we are not in prelocked mode but have built the extended table
list, we still need to call open_and_process_routine() to take
MDL locks on the routines.
*/
if (thd->locked_tables_mode <= LTM_LOCK_TABLES)
{
/*
Process elements of the prelocking set which are present there
since parsing stage or were added to it by invocations of
Prelocking_strategy methods in the above loop over tables.
For example, if element is a routine, cache it and then,
if prelocking strategy prescribes so, add tables it uses to the
table list and routines it might invoke to the prelocking set.
*/
for (Sroutine_hash_entry *rt= *sroutine_to_open; rt;
sroutine_to_open= &rt->next, rt= rt->next)
{
bool need_prelocking= false;
bool routine_modifies_data;
TABLE_LIST **save_query_tables_last= thd->lex->query_tables_last;
error= open_and_process_routine(thd, thd->lex, rt, prelocking_strategy,
has_prelocking_list, &ot_ctx,
&need_prelocking,
&routine_modifies_data);
// Remember if any of SF modifies data.
some_routine_modifies_data|= routine_modifies_data;
if (need_prelocking && ! thd->lex->requires_prelocking())
thd->lex->mark_as_requiring_prelocking(save_query_tables_last);
if (need_prelocking && ! *start)
*start= thd->lex->query_tables;
if (error)
{
if (ot_ctx.can_recover_from_failed_open())
{
close_tables_for_reopen(thd, start,
ot_ctx.start_of_statement_svp());
if (ot_ctx.recover_from_failed_open())
goto error;
/* Re-open temporary tables after close_tables_for_reopen(). */
if (thd->open_temporary_tables(*start))
goto error;
error= FALSE;
goto restart;
}
/*
Serious error during reading stored routines from mysql.proc table.
Something is wrong with the table or its contents, and an error has
been emitted; we must abort.
*/
goto error;
}
}
}
if ((error= prelocking_strategy->handle_end(thd)))
goto error;
}
/*
After successful open of all tables, including MERGE parents and
children, attach the children to their parents. At end of statement,
the children are detached. Attaching and detaching are always done,
even under LOCK TABLES.
We also convert all TL_WRITE_DEFAULT and TL_READ_DEFAULT locks to
appropriate "real" lock types to be used for locking and to be passed
to storage engine.
And start wsrep TOI if needed.
*/
for (tables= *start; tables; tables= tables->next_global)
{
TABLE *tbl= tables->table;
if (!tbl)
continue;
/* Schema tables may not have a TABLE object here. */
if (tbl->file->ht->db_type == DB_TYPE_MRG_MYISAM)
{
/* MERGE tables need to access parent and child TABLE_LISTs. */
DBUG_ASSERT(tbl->pos_in_table_list == tables);
if (tbl->file->extra(HA_EXTRA_ATTACH_CHILDREN))
{
error= TRUE;
goto error;
}
}
/* Set appropriate TABLE::lock_type. */
if (tbl && tables->lock_type != TL_UNLOCK && !thd->locked_tables_mode)
{
if (tables->lock_type == TL_WRITE_DEFAULT)
tbl->reginfo.lock_type= thd->update_lock_default;
else if (tables->lock_type == TL_READ_DEFAULT)
tbl->reginfo.lock_type=
read_lock_type_for_table(thd, thd->lex, tables,
some_routine_modifies_data);
else
tbl->reginfo.lock_type= tables->lock_type;
}
}
if (WSREP(thd) &&
wsrep_replicate_myisam &&
(*start) &&
(*start)->table &&
(*start)->table->file->ht == myisam_hton &&
wsrep_thd_exec_mode(thd) == LOCAL_STATE &&
!is_stat_table((*start)->db, (*start)->alias) &&
thd->get_command() != COM_STMT_PREPARE &&
((thd->lex->sql_command == SQLCOM_INSERT ||
thd->lex->sql_command == SQLCOM_INSERT_SELECT ||
thd->lex->sql_command == SQLCOM_REPLACE ||
thd->lex->sql_command == SQLCOM_REPLACE_SELECT ||
thd->lex->sql_command == SQLCOM_UPDATE ||
thd->lex->sql_command == SQLCOM_UPDATE_MULTI ||
thd->lex->sql_command == SQLCOM_LOAD ||
thd->lex->sql_command == SQLCOM_DELETE)))
{
WSREP_TO_ISOLATION_BEGIN(NULL, NULL, (*start));
}
error:
WSREP_ERROR_LABEL:
THD_STAGE_INFO(thd, stage_after_opening_tables);
thd_proc_info(thd, 0);
if (error && *table_to_open)
{
(*table_to_open)->table= NULL;
}
DBUG_PRINT("open_tables", ("returning: %d", (int) error));
DBUG_RETURN(error);
}
/**
Defines how prelocking algorithm for DML statements should handle routines:
- For CALL statements we do unrolling (i.e. open and lock tables for each
sub-statement individually). So for such statements prelocking is enabled
only if stored functions are used in parameter list and only for period
during which we calculate values of parameters. Thus in this strategy we
ignore procedure which is directly called by such statement and extend
the prelocking set only with tables/functions used by SF called from the
parameter list.
- For any other statement any routine which is directly or indirectly called
by statement is going to be executed in prelocked mode. So in this case we
simply add all tables and routines used by it to the prelocking set.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context of the statement.
@param[in] rt Prelocking set element describing routine.
@param[in] sp Routine body.
@param[out] need_prelocking Set to TRUE if method detects that prelocking
required, not changed otherwise.
@retval FALSE Success.
@retval TRUE Failure (OOM).
*/
bool DML_prelocking_strategy::
handle_routine(THD *thd, Query_tables_list *prelocking_ctx,
Sroutine_hash_entry *rt, sp_head *sp, bool *need_prelocking)
{
/*
We assume that for any "CALL proc(...)" statement sroutines_list will
have 'proc' as first element (it may have several, consider e.g.
"proc(sp_func(...)))". This property is currently guaranted by the
parser.
*/
if (rt != (Sroutine_hash_entry*)prelocking_ctx->sroutines_list.first ||
rt->mdl_request.key.mdl_namespace() != MDL_key::PROCEDURE)
{
*need_prelocking= TRUE;
sp_update_stmt_used_routines(thd, prelocking_ctx, &sp->m_sroutines,
rt->belong_to_view);
(void)sp->add_used_tables_to_table_list(thd,
&prelocking_ctx->query_tables_last,
rt->belong_to_view);
}
sp->propagate_attributes(prelocking_ctx);
return FALSE;
}
/*
@note this can be changed to use a hash, instead of scanning the linked
list, if the performance of this function will ever become an issue
*/
bool table_already_fk_prelocked(TABLE_LIST *tl, LEX_STRING *db,
LEX_STRING *table, thr_lock_type lock_type)
{
for (; tl; tl= tl->next_global )
{
if (tl->lock_type >= lock_type &&
tl->prelocking_placeholder == TABLE_LIST::FK &&
strcmp(tl->db, db->str) == 0 &&
strcmp(tl->table_name, table->str) == 0)
return true;
}
return false;
}
/**
Defines how prelocking algorithm for DML statements should handle table list
elements:
- If table has triggers we should add all tables and routines
used by them to the prelocking set.
We do not need to acquire metadata locks on trigger names
in DML statements, since all DDL statements
that change trigger metadata always lock their
subject tables.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context of the statement.
@param[in] table_list Table list element for table.
@param[in] sp Routine body.
@param[out] need_prelocking Set to TRUE if method detects that prelocking
required, not changed otherwise.
@retval FALSE Success.
@retval TRUE Failure (OOM).
*/
bool DML_prelocking_strategy::
handle_table(THD *thd, Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list, bool *need_prelocking)
{
/* We rely on a caller to check that table is going to be changed. */
DBUG_ASSERT(table_list->lock_type >= TL_WRITE_ALLOW_WRITE);
if (table_list->trg_event_map)
{
if (table_list->table->triggers)
{
*need_prelocking= TRUE;
if (table_list->table->triggers->
add_tables_and_routines_for_triggers(thd, prelocking_ctx, table_list))
return TRUE;
}
if (table_list->table->file->referenced_by_foreign_key())
{
List <FOREIGN_KEY_INFO> fk_list;
List_iterator<FOREIGN_KEY_INFO> fk_list_it(fk_list);
FOREIGN_KEY_INFO *fk;
Query_arena *arena, backup;
arena= thd->activate_stmt_arena_if_needed(&backup);
table_list->table->file->get_parent_foreign_key_list(thd, &fk_list);
if (thd->is_error())
{
if (arena)
thd->restore_active_arena(arena, &backup);
return TRUE;
}
*need_prelocking= TRUE;
while ((fk= fk_list_it++))
{
// FK_OPTION_RESTRICT and FK_OPTION_NO_ACTION only need read access
static bool can_write[]= { true, false, true, true, false, true };
uint8 op= table_list->trg_event_map;
thr_lock_type lock_type;
if ((op & (1 << TRG_EVENT_DELETE) && can_write[fk->delete_method])
|| (op & (1 << TRG_EVENT_UPDATE) && can_write[fk->update_method]))
lock_type= TL_WRITE_ALLOW_WRITE;
else
lock_type= TL_READ;
if (table_already_fk_prelocked(prelocking_ctx->query_tables,
fk->foreign_db, fk->foreign_table,
lock_type))
continue;
TABLE_LIST *tl= (TABLE_LIST *) thd->alloc(sizeof(TABLE_LIST));
tl->init_one_table_for_prelocking(fk->foreign_db->str, fk->foreign_db->length,
fk->foreign_table->str, fk->foreign_table->length,
NULL, lock_type, false, table_list->belong_to_view,
op, &prelocking_ctx->query_tables_last);
}
if (arena)
thd->restore_active_arena(arena, &backup);
}
}
return FALSE;
}
/**
Defines how prelocking algorithm for DML statements should handle view -
all view routines should be added to the prelocking set.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context of the statement.
@param[in] table_list Table list element for view.
@param[in] sp Routine body.
@param[out] need_prelocking Set to TRUE if method detects that prelocking
required, not changed otherwise.
@retval FALSE Success.
@retval TRUE Failure (OOM).
*/
bool DML_prelocking_strategy::
handle_view(THD *thd, Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list, bool *need_prelocking)
{
if (table_list->view->uses_stored_routines())
{
*need_prelocking= TRUE;
sp_update_stmt_used_routines(thd, prelocking_ctx,
&table_list->view->sroutines_list,
table_list->top_table());
}
/*
If a trigger was defined on one of the associated tables then assign the
'trg_event_map' value of the view to the next table in table_list. When a
Stored function is invoked, all the associated tables including the tables
associated with the trigger are prelocked.
*/
if (table_list->trg_event_map && table_list->next_global)
table_list->next_global->trg_event_map= table_list->trg_event_map;
return FALSE;
}
/**
Defines how prelocking algorithm for LOCK TABLES statement should handle
table list elements.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context of the statement.
@param[in] table_list Table list element for table.
@param[in] sp Routine body.
@param[out] need_prelocking Set to TRUE if method detects that prelocking
required, not changed otherwise.
@retval FALSE Success.
@retval TRUE Failure (OOM).
*/
bool Lock_tables_prelocking_strategy::
handle_table(THD *thd, Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list, bool *need_prelocking)
{
TABLE_LIST **last= prelocking_ctx->query_tables_last;
if (DML_prelocking_strategy::handle_table(thd, prelocking_ctx, table_list,
need_prelocking))
return TRUE;
/*
normally we don't need to open FK-prelocked tables for RESTRICT,
MDL is enough. But under LOCK TABLES we have to open everything
*/
for (TABLE_LIST *tl= *last; tl; tl= tl->next_global)
tl->open_strategy= TABLE_LIST::OPEN_NORMAL;
/* We rely on a caller to check that table is going to be changed. */
DBUG_ASSERT(table_list->lock_type >= TL_WRITE_ALLOW_WRITE);
return FALSE;
}
/**
Defines how prelocking algorithm for ALTER TABLE statement should handle
routines - do nothing as this statement is not supposed to call routines.
We still can end up in this method when someone tries
to define a foreign key referencing a view, and not just
a simple view, but one that uses stored routines.
*/
bool Alter_table_prelocking_strategy::
handle_routine(THD *thd, Query_tables_list *prelocking_ctx,
Sroutine_hash_entry *rt, sp_head *sp, bool *need_prelocking)
{
return FALSE;
}
/**
Defines how prelocking algorithm for ALTER TABLE statement should handle
table list elements.
Unlike in DML, we do not process triggers here.
@param[in] thd Thread context.
@param[in] prelocking_ctx Prelocking context of the statement.
@param[in] table_list Table list element for table.
@param[in] sp Routine body.
@param[out] need_prelocking Set to TRUE if method detects that prelocking
required, not changed otherwise.
@retval FALSE Success.
@retval TRUE Failure (OOM).
*/
bool Alter_table_prelocking_strategy::
handle_table(THD *thd, Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list, bool *need_prelocking)
{
return FALSE;
}
/**
Defines how prelocking algorithm for ALTER TABLE statement
should handle view - do nothing. We don't need to add view
routines to the prelocking set in this case as view is not going
to be materialized.
*/
bool Alter_table_prelocking_strategy::
handle_view(THD *thd, Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list, bool *need_prelocking)
{
return FALSE;
}
/**
Check that lock is ok for tables; Call start stmt if ok
@param thd Thread handle.
@param prelocking_ctx Prelocking context.
@param table_list Table list element for table to be checked.
@retval FALSE - Ok.
@retval TRUE - Error.
*/
static bool check_lock_and_start_stmt(THD *thd,
Query_tables_list *prelocking_ctx,
TABLE_LIST *table_list)
{
int error;
thr_lock_type lock_type;
DBUG_ENTER("check_lock_and_start_stmt");
/*
Prelocking placeholder is not set for TABLE_LIST that
are directly used by TOP level statement.
*/
DBUG_ASSERT(table_list->prelocking_placeholder == false);
/*
TL_WRITE_DEFAULT and TL_READ_DEFAULT are supposed to be parser only
types of locks so they should be converted to appropriate other types
to be passed to storage engine. The exact lock type passed to the
engine is important as, for example, InnoDB uses it to determine
what kind of row locks should be acquired when executing statement
in prelocked mode or under LOCK TABLES with @@innodb_table_locks = 0.
Last argument routine_modifies_data for read_lock_type_for_table()
is ignored, as prelocking placeholder will never be set here.
*/
DBUG_ASSERT(table_list->prelocking_placeholder == false);
if (table_list->lock_type == TL_WRITE_DEFAULT)
lock_type= thd->update_lock_default;
else if (table_list->lock_type == TL_READ_DEFAULT)
lock_type= read_lock_type_for_table(thd, prelocking_ctx, table_list, true);
else
lock_type= table_list->lock_type;
if ((int) lock_type > (int) TL_WRITE_ALLOW_WRITE &&
(int) table_list->table->reginfo.lock_type <= (int) TL_WRITE_ALLOW_WRITE)
{
my_error(ER_TABLE_NOT_LOCKED_FOR_WRITE, MYF(0),
table_list->table->alias.c_ptr());
DBUG_RETURN(1);
}
if ((error= table_list->table->file->start_stmt(thd, lock_type)))
{
table_list->table->file->print_error(error, MYF(0));
DBUG_RETURN(1);
}
/*
Record in transaction state tracking
*/
TRANSACT_TRACKER(add_trx_state(thd, lock_type,
table_list->table->file->has_transactions()));
DBUG_RETURN(0);
}
/**
@brief Open and lock one table
@param[in] thd thread handle
@param[in] table_l table to open is first table in this list
@param[in] lock_type lock to use for table
@param[in] flags options to be used while opening and locking
table (see open_table(), mysql_lock_tables())
@param[in] prelocking_strategy Strategy which specifies how prelocking
algorithm should work for this statement.
@return table
@retval != NULL OK, opened table returned
@retval NULL Error
@note
If ok, the following are also set:
table_list->lock_type lock_type
table_list->table table
@note
If table_l is a list, not a single table, the list is temporarily
broken.
@detail
This function is meant as a replacement for open_ltable() when
MERGE tables can be opened. open_ltable() cannot open MERGE tables.
There may be more differences between open_n_lock_single_table() and
open_ltable(). One known difference is that open_ltable() does
neither call thd->decide_logging_format() nor handle some other logging
and locking issues because it does not call lock_tables().
*/
TABLE *open_n_lock_single_table(THD *thd, TABLE_LIST *table_l,
thr_lock_type lock_type, uint flags,
Prelocking_strategy *prelocking_strategy)
{
TABLE_LIST *save_next_global;
DBUG_ENTER("open_n_lock_single_table");
/* Remember old 'next' pointer. */
save_next_global= table_l->next_global;
/* Break list. */
table_l->next_global= NULL;
/* Set requested lock type. */
table_l->lock_type= lock_type;
/* Allow to open real tables only. */
table_l->required_type= FRMTYPE_TABLE;
/* Open the table. */
if (open_and_lock_tables(thd, table_l, FALSE, flags,
prelocking_strategy))
table_l->table= NULL; /* Just to be sure. */
/* Restore list. */
table_l->next_global= save_next_global;
DBUG_RETURN(table_l->table);
}
/*
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
lock_flags Flags passed to mysql_lock_table
NOTE
This function doesn't do anything like SP/SF/views/triggers analysis done
in open_table()/lock_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,
uint lock_flags)
{
TABLE *table;
Open_table_context ot_ctx(thd, lock_flags);
bool error;
DBUG_ENTER("open_ltable");
/* Ignore temporary tables as they have already been opened. */
if (table_list->table)
DBUG_RETURN(table_list->table);
/* should not be used in a prelocked_mode context, see NOTE above */
DBUG_ASSERT(thd->locked_tables_mode < LTM_PRELOCKED);
THD_STAGE_INFO(thd, stage_opening_tables);
thd->current_tablenr= 0;
/* open_ltable can be used only for BASIC TABLEs */
table_list->required_type= FRMTYPE_TABLE;
/* This function can't properly handle requests for such metadata locks. */
DBUG_ASSERT(table_list->mdl_request.type < MDL_SHARED_UPGRADABLE);
while ((error= open_table(thd, table_list, &ot_ctx)) &&
ot_ctx.can_recover_from_failed_open())
{
/*
Even though we have failed to open table we still need to
call release_transactional_locks() to release metadata locks which
might have been acquired successfully.
*/
thd->mdl_context.rollback_to_savepoint(ot_ctx.start_of_statement_svp());
table_list->mdl_request.ticket= 0;
if (ot_ctx.recover_from_failed_open())
break;
}
if (!error)
{
/*
We can't have a view or some special "open_strategy" in this function
so there should be a TABLE instance.
*/
DBUG_ASSERT(table_list->table);
table= table_list->table;
if (table->file->ht->db_type == DB_TYPE_MRG_MYISAM)
{
/* A MERGE table must not come here. */
/* purecov: begin tested */
my_error(ER_WRONG_OBJECT, MYF(0), table->s->db.str,
table->s->table_name.str, "BASE TABLE");
table= 0;
goto end;
/* purecov: end */
}
table_list->lock_type= lock_type;
table->grant= table_list->grant;
if (thd->locked_tables_mode)
{
if (check_lock_and_start_stmt(thd, thd->lex, table_list))
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,
lock_flags)))
{
table= 0;
}
}
}
else
table= 0;
end:
if (table == NULL)
{
if (!thd->in_sub_stmt)
trans_rollback_stmt(thd);
close_thread_tables(thd);
}
THD_STAGE_INFO(thd, stage_after_opening_tables);
thd_proc_info(thd, 0);
DBUG_RETURN(table);
}
/**
Open all tables in list, locks them and optionally process derived tables.
@param thd Thread context.
@param options DDL options.
@param tables List of tables for open and locking.
@param derived Whether to handle derived tables.
@param flags Bitmap of options to be used to open and lock
tables (see open_tables() and mysql_lock_tables()
for details).
@param prelocking_strategy Strategy which specifies how prelocking algorithm
should work for this statement.
@note
The thr_lock locks will automatically be freed by
close_thread_tables().
@retval FALSE OK.
@retval TRUE Error
*/
bool open_and_lock_tables(THD *thd, const DDL_options_st &options,
TABLE_LIST *tables,
bool derived, uint flags,
Prelocking_strategy *prelocking_strategy)
{
uint counter;
MDL_savepoint mdl_savepoint= thd->mdl_context.mdl_savepoint();
DBUG_ENTER("open_and_lock_tables");
DBUG_PRINT("enter", ("derived handling: %d", derived));
if (open_tables(thd, options, &tables, &counter, flags, prelocking_strategy))
goto err;
DBUG_EXECUTE_IF("sleep_open_and_lock_after_open", {
const char *old_proc_info= thd->proc_info;
thd->proc_info= "DBUG sleep";
my_sleep(6000000);
thd->proc_info= old_proc_info;});
if (lock_tables(thd, tables, counter, flags))
goto err;
(void) read_statistics_for_tables_if_needed(thd, tables);
if (derived)
{
if (mysql_handle_derived(thd->lex, DT_INIT))
goto err;
if (thd->prepare_derived_at_open &&
(mysql_handle_derived(thd->lex, DT_PREPARE)))
goto err;
}
DBUG_RETURN(FALSE);
err:
if (! thd->in_sub_stmt)
trans_rollback_stmt(thd); /* Necessary if derived handling failed. */
close_thread_tables(thd);
/* Don't keep locks for a failed statement. */
thd->mdl_context.rollback_to_savepoint(mdl_savepoint);
DBUG_RETURN(TRUE);
}
/*
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 on it.
dt_phases - set of flags to pass to the mysql_handle_derived
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 dt_phases)
{
DML_prelocking_strategy prelocking_strategy;
uint counter;
MDL_savepoint mdl_savepoint= thd->mdl_context.mdl_savepoint();
DBUG_ENTER("open_normal_and_derived_tables");
DBUG_ASSERT(!thd->fill_derived_tables());
if (open_tables(thd, &tables, &counter, flags, &prelocking_strategy) ||
mysql_handle_derived(thd->lex, dt_phases))
goto end;
DBUG_RETURN(0);
end:
/*
No need to commit/rollback the statement transaction: it's
either not started or we're filling in an INFORMATION_SCHEMA
table on the fly, and thus mustn't manipulate with the
transaction of the enclosing statement.
*/
DBUG_ASSERT(thd->transaction.stmt.is_empty() ||
(thd->state_flags & Open_tables_state::BACKUPS_AVAIL));
close_thread_tables(thd);
/* Don't keep locks for a failed statement. */
thd->mdl_context.rollback_to_savepoint(mdl_savepoint);
DBUG_RETURN(TRUE); /* purecov: inspected */
}
/*
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_list)
{
TABLE_LIST *table;
for (table= table_list; table; table= table->next_global)
if (!table->placeholder())
{
table->table->query_id= 0;
}
for (table= table_list; table; table= table->next_global)
if (!table->placeholder())
{
/*
Detach children of MyISAMMRG tables used in
sub-statements, they will be reattached at open.
This has to be done in a separate loop to make sure
that children have had their query_id cleared.
*/
table->table->file->extra(HA_EXTRA_DETACH_CHILDREN);
}
}
int TABLE::fix_vcol_exprs(THD *thd)
{
for (Field **vf= vfield; vf && *vf; vf++)
if (fix_session_vcol_expr(thd, (*vf)->vcol_info))
return 1;
for (Field **df= default_field; df && *df; df++)
if ((*df)->default_value &&
fix_session_vcol_expr(thd, (*df)->default_value))
return 1;
for (Virtual_column_info **cc= check_constraints; cc && *cc; cc++)
if (fix_session_vcol_expr(thd, (*cc)))
return 1;
return 0;
}
static bool fix_all_session_vcol_exprs(THD *thd, TABLE_LIST *tables)
{
Security_context *save_security_ctx= thd->security_ctx;
TABLE_LIST *first_not_own= thd->lex->first_not_own_table();
DBUG_ENTER("fix_session_vcol_expr");
int error= 0;
for (TABLE_LIST *table= tables; table && table != first_not_own && !error;
table= table->next_global)
{
TABLE *t= table->table;
if (!table->placeholder() && t->s->vcols_need_refixing &&
table->lock_type >= TL_WRITE_ALLOW_WRITE)
{
Query_arena *stmt_backup= thd->stmt_arena;
if (thd->stmt_arena->is_conventional())
thd->stmt_arena= t->expr_arena;
if (table->security_ctx)
thd->security_ctx= table->security_ctx;
error= t->fix_vcol_exprs(thd);
thd->security_ctx= save_security_ctx;
thd->stmt_arena= stmt_backup;
}
}
DBUG_RETURN(error);
}
/**
Lock all tables in a list.
@param thd Thread handler
@param tables Tables to lock
@param count Number of opened tables
@param flags Options (see mysql_lock_tables() for details)
You can't call lock_tables() while holding thr_lock locks, as
this would break the dead-lock-free handling thr_lock gives us.
You must always get all needed locks at once.
If the query for which we are calling this function is marked as
requiring prelocking, this function will change
locked_tables_mode to LTM_PRELOCKED.
@retval FALSE Success.
@retval TRUE A lock wait timeout, deadlock or out of memory.
*/
bool lock_tables(THD *thd, TABLE_LIST *tables, uint count,
uint flags)
{
TABLE_LIST *table;
DBUG_ENTER("lock_tables");
/*
We can't meet statement requiring prelocking if we already
in prelocked mode.
*/
DBUG_ASSERT(thd->locked_tables_mode <= LTM_LOCK_TABLES ||
!thd->lex->requires_prelocking());
if (!tables && !thd->lex->requires_prelocking())
DBUG_RETURN(thd->decide_logging_format(tables));
/*
Check for thd->locked_tables_mode to avoid a redundant
and harmful attempt to lock the already locked tables again.
Checking for thd->lock is not enough in some situations. For example,
if a stored function contains
"drop table t3; create temporary t3 ..; insert into t3 ...;"
thd->lock may be 0 after drop tables, whereas locked_tables_mode
is still on. In this situation an attempt to lock temporary
table t3 will lead to a memory leak.
*/
if (! thd->locked_tables_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(TRUE);
for (table= tables; table; table= table->next_global)
{
if (!table->placeholder())
*(ptr++)= table->table;
}
DEBUG_SYNC(thd, "before_lock_tables_takes_lock");
if (! (thd->lock= mysql_lock_tables(thd, start, (uint) (ptr - start),
flags)))
DBUG_RETURN(TRUE);
DEBUG_SYNC(thd, "after_lock_tables_takes_lock");
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.
When open_and_lock_tables() is called for a single table out of
a table list, the 'next_global' chain is temporarily broken. We
may not find 'first_not_own' before the end of the "list".
Look for example at those places where open_n_lock_single_table()
is called. That function implements the temporary breaking of
a table list for opening a single table.
*/
for (table= tables;
table && table != first_not_own;
table= table->next_global)
{
if (!table->placeholder())
{
table->table->query_id= thd->query_id;
if (check_lock_and_start_stmt(thd, thd->lex, table))
{
mysql_unlock_tables(thd, thd->lock);
thd->lock= 0;
DBUG_RETURN(TRUE);
}
}
}
/*
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",("locked_tables_mode= LTM_PRELOCKED"));
thd->enter_locked_tables_mode(LTM_PRELOCKED);
}
}
else
{
TABLE_LIST *first_not_own= thd->lex->first_not_own_table();
/*
When open_and_lock_tables() is called for a single table out of
a table list, the 'next_global' chain is temporarily broken. We
may not find 'first_not_own' before the end of the "list".
Look for example at those places where open_n_lock_single_table()
is called. That function implements the temporary breaking of
a table list for opening a single table.
*/
for (table= tables;
table && table != first_not_own;
table= table->next_global)
{
if (table->placeholder())
continue;
/*
In a stored function or trigger we should ensure that we won't change
a table that is already used by the calling statement.
*/
if (thd->locked_tables_mode >= LTM_PRELOCKED &&
table->lock_type >= TL_WRITE_ALLOW_WRITE)
{
for (TABLE* opentab= thd->open_tables; opentab; opentab= opentab->next)
{
if (table->table->s == opentab->s && opentab->query_id &&
table->table->query_id != opentab->query_id)
{
my_error(ER_CANT_UPDATE_USED_TABLE_IN_SF_OR_TRG, MYF(0),
table->table->s->table_name.str);
DBUG_RETURN(TRUE);
}
}
}
if (check_lock_and_start_stmt(thd, thd->lex, table))
{
DBUG_RETURN(TRUE);
}
}
/*
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->locked_tables_mode= LTM_PRELOCKED_UNDER_LOCK_TABLES"));
thd->locked_tables_mode= LTM_PRELOCKED_UNDER_LOCK_TABLES;
}
}
bool res= fix_all_session_vcol_exprs(thd, tables);
if (!res)
res= thd->decide_logging_format(tables);
DBUG_RETURN(res);
}
/*
Restart transaction for tables
This is used when we had to do an implicit commit after tables are opened
and want to restart transactions on tables.
This is used in case of:
LOCK TABLES xx
CREATE OR REPLACE TABLE xx;
*/
bool restart_trans_for_tables(THD *thd, TABLE_LIST *table)
{
DBUG_ENTER("restart_trans_for_tables");
for (; table; table= table->next_global)
{
if (table->placeholder())
continue;
if (check_lock_and_start_stmt(thd, thd->lex, table))
{
DBUG_ASSERT(0); // Should never happen
DBUG_RETURN(TRUE);
}
}
DBUG_RETURN(FALSE);
}
/**
Prepare statement for reopening of tables and recalculation of set of
prelocked tables.
@param[in] thd Thread context.
@param[in,out] tables List of tables which we were trying to open
and lock.
@param[in] start_of_statement_svp MDL savepoint which represents the set
of metadata locks which the current transaction
managed to acquire before execution of the current
statement and to which we should revert before
trying to reopen tables. NULL if no metadata locks
were held and thus all metadata locks should be
released.
*/
void close_tables_for_reopen(THD *thd, TABLE_LIST **tables,
const MDL_savepoint &start_of_statement_svp)
{
TABLE_LIST *first_not_own_table= thd->lex->first_not_own_table();
TABLE_LIST *tmp;
/*
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 (first_not_own_table == *tables)
*tables= 0;
thd->lex->chop_off_not_own_tables();
/* Reset MDL tickets for procedures/functions */
for (Sroutine_hash_entry *rt=
(Sroutine_hash_entry*)thd->lex->sroutines_list.first;
rt; rt= rt->next)
rt->mdl_request.ticket= NULL;
sp_remove_not_own_routines(thd->lex);
for (tmp= *tables; tmp; tmp= tmp->next_global)
{
tmp->table= 0;
tmp->mdl_request.ticket= NULL;
/* We have to cleanup translation tables of views. */
tmp->cleanup_items();
}
/*
No need to commit/rollback the statement transaction: it's
either not started or we're filling in an INFORMATION_SCHEMA
table on the fly, and thus mustn't manipulate with the
transaction of the enclosing statement.
*/
DBUG_ASSERT(thd->transaction.stmt.is_empty() ||
(thd->state_flags & Open_tables_state::BACKUPS_AVAIL));
close_thread_tables(thd);
thd->mdl_context.rollback_to_savepoint(start_of_statement_svp);
}
/*****************************************************************************
* 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)
{
DBUG_ENTER("update_field_dependencies");
if (thd->mark_used_columns != MARK_COLUMNS_NONE)
{
MY_BITMAP *bitmap;
/*
We always want to register the used keys, as the column bitmap may have
been set for all fields (for example for view).
*/
table->covering_keys.intersect(field->part_of_key);
if (field->vcol_info)
table->mark_virtual_col(field);
if (thd->mark_used_columns == MARK_COLUMNS_READ)
bitmap= table->read_set;
else
bitmap= table->write_set;
/*
The test-and-set mechanism in the bitmap is not reliable during
multi-UPDATE statements under MARK_COLUMNS_READ mode
(thd->mark_used_columns == MARK_COLUMNS_READ), as this bitmap contains
only those columns that are used in the SET clause. I.e they are being
set here. See multi_update::prepare()
*/
if (bitmap_fast_test_and_set(bitmap, field->field_index))
{
if (thd->mark_used_columns == MARK_COLUMNS_WRITE)
{
DBUG_PRINT("warning", ("Found duplicated field"));
thd->dup_field= field;
}
else
{
DBUG_PRINT("note", ("Field found before"));
}
DBUG_VOID_RETURN;
}
if (table->get_fields_in_item_tree)
field->flags|= GET_FIXED_FIELDS_FLAG;
table->used_fields++;
}
else if (table->get_fields_in_item_tree)
field->flags|= GET_FIXED_FIELDS_FLAG;
DBUG_VOID_RETURN;
}
/*
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 %p",
table_list->alias, name, item_name, ref));
Field_iterator_view field_it;
field_it.set(table_list);
Query_arena *arena= 0, backup;
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 &&
thd->stmt_arena->is_stmt_prepare_or_first_stmt_execute())
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 (arena)
thd->restore_active_arena(arena, &backup);
if (!item)
DBUG_RETURN(0);
if (!ref)
DBUG_RETURN((Field*) view_ref_found);
/*
*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)
{
if (register_tree_change)
{
item->set_name_for_rollback(thd, (*ref)->name,
(*ref)->name_length,
system_charset_info);
item->real_item()->set_name_for_rollback(thd, (*ref)->name,
(*ref)->name_length,
system_charset_info);
}
else
{
item->set_name(thd, (*ref)->name, (*ref)->name_length,
system_charset_info);
item->real_item()->set_name(thd, (*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, *curr_nj_col;
Field *UNINIT_VAR(found_field);
Query_arena *UNINIT_VAR(arena), backup;
DBUG_ENTER("find_field_in_natural_join");
DBUG_PRINT("enter", ("field name: '%s', ref %p",
name, ref));
DBUG_ASSERT(table_ref->is_natural_join && table_ref->join_columns);
DBUG_ASSERT(*actual_table == NULL);
for (nj_col= NULL, curr_nj_col= field_it++; curr_nj_col;
curr_nj_col= field_it++)
{
if (!my_strcasecmp(system_charset_info, curr_nj_col->name(), name))
{
if (nj_col)
{
my_error(ER_NON_UNIQ_ERROR, MYF(0), name, thd->where);
DBUG_RETURN(NULL);
}
nj_col= curr_nj_col;
}
}
if (!nj_col)
DBUG_RETURN(NULL);
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 (!item)
DBUG_RETURN(NULL);
/*
*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(thd, (*ref)->name, (*ref)->name_length,
system_charset_info);
item->real_item()->set_name(thd, (*ref)->name, (*ref)->name_length,
system_charset_info);
}
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);
Item *ref= 0;
/*
This fix_fields is not necessary (initially this item is fixed by
the Item_field constructor; after reopen_tables the Item_func_eq
calls fix_fields on that item), it's just a check during table
reopening for columns that was dropped by the concurrent connection.
*/
if (!nj_col->table_field->fixed &&
nj_col->table_field->fix_fields(thd, &ref))
{
DBUG_PRINT("info", ("column '%s' was dropped by the concurrent connection",
nj_col->table_field->name));
DBUG_RETURN(NULL);
}
DBUG_ASSERT(ref == 0); // Should not have changed
DBUG_ASSERT(nj_col->table_ref->table == nj_col->table_field->field->table);
found_field= nj_col->table_field->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.
The caller is expected to check column-level privileges.
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.c_ptr(),
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**) my_hash_search(&table->s->name_hash, (uchar*) name,
length);
if (field_ptr)
{
/*
field_ptr points to field in TABLE_SHARE. Convert it to the matching
field in table
*/
field_ptr= (table->field + (field_ptr - table->s->field));
}
}
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= (uint)(field_ptr - table->field);
field= *field_ptr;
}
else
{
if (!allow_rowid ||
my_strcasecmp(system_charset_info, name, "_rowid") ||
table->s->rowid_field_offset == 0)
DBUG_RETURN((Field*) 0);
field= table->field[table->s->rowid_field_offset-1];
}
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.
The routine checks column-level privieleges for the found field.
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_ASSERT(table_list->alias);
DBUG_ASSERT(name);
DBUG_ASSERT(item_name);
DBUG_PRINT("enter",
("table: '%s' field name: '%s' item name: '%s' ref %p",
table_list->alias, name, item_name, 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])) ||
(db_name && db_name[0] && table_list->db && table_list->db[0] &&
(table_list->schema_table ?
my_strcasecmp(system_charset_info, db_name, table_list->db) :
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);
}
if (fld)
{
#ifndef NO_EMBEDDED_ACCESS_CHECKS
/* Check if there are sufficient access rights to the found field. */
if (check_privileges &&
check_column_grant_in_table_ref(thd, *actual_table, name, length))
fld= WRONG_GRANT;
else
#endif
if (thd->mark_used_columns != MARK_COLUMNS_NONE)
{
/*
Get rw_set correct for this field so that the handler
knows that this field is involved in the query and gets
retrieved/updated
*/
Field *field_to_set= NULL;
if (fld == view_ref_found)
{
if (!ref)
DBUG_RETURN(fld);
Item *it= (*ref)->real_item();
if (it->type() == Item::FIELD_ITEM)
field_to_set= ((Item_field*)it)->field;
else
{
if (thd->mark_used_columns == MARK_COLUMNS_READ)
it->walk(&Item::register_field_in_read_map, 0, 0);
else
it->walk(&Item::register_field_in_write_map, 0, 0);
}
}
else
field_to_set= fld;
if (field_to_set)
{
TABLE *table= field_to_set->table;
if (thd->mark_used_columns == MARK_COLUMNS_READ)
bitmap_set_bit(table->read_set, field_to_set->field_index);
else
bitmap_set_bit(table->write_set, field_to_set->field_index);
}
}
}
DBUG_RETURN(fld);
}
/*
Find field in table, no side effects, only purpose is to check for field
in table object and get reference to the field if found.
SYNOPSIS
find_field_in_table_sef()
table table where to find
name Name of field searched for
RETURN
0 field is not found
# pointer to field
*/
Field *find_field_in_table_sef(TABLE *table, const char *name)
{
Field **field_ptr;
if (table->s->name_hash.records)
{
field_ptr= (Field**)my_hash_search(&table->s->name_hash,(uchar*) name,
strlen(name));
if (field_ptr)
{
/*
field_ptr points to field in TABLE_SHARE. Convert it to the matching
field in table
*/
field_ptr= (table->field + (field_ptr - table->s->field));
}
}
else
{
if (!(field_ptr= table->field))
return (Field *)0;
for (; *field_ptr; ++field_ptr)
if (!my_strcasecmp(system_charset_info, (*field_ptr)->field_name, name))
break;
}
if (field_ptr)
return *field_ptr;
else
return (Field *)0;
}
/*
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[SAFE_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)
{
DBUG_PRINT("info", ("using 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 &&
(!table_ref->is_merged_derived() ||
(!table_ref->is_multitable() && table_ref->merged_for_insert)))
{
found= find_field_in_table(thd, table_ref->table, name, length,
TRUE, &(item->cached_field_index));
#ifndef NO_EMBEDDED_ACCESS_CHECKS
/* Check if there are sufficient access rights to the found field. */
if (found && check_privileges &&
check_column_grant_in_table_ref(thd, table_ref, name, length))
found= WRONG_GRANT;
#endif
}
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;
/*
Only views fields should be marked as dependent, not an underlying
fields.
*/
if (!table_ref->belong_to_view &&
!table_ref->belong_to_derived)
{
SELECT_LEX *current_sel= item->context->select_lex;
SELECT_LEX *last_select= table_ref->select_lex;
bool all_merged= TRUE;
for (SELECT_LEX *sl= current_sel; sl && sl!=last_select;
sl=sl->outer_select())
{
Item *subs= sl->master_unit()->item;
if (subs->type() == Item::SUBSELECT_ITEM &&
((Item_subselect*)subs)->substype() == Item_subselect::IN_SUBS &&
((Item_in_subselect*)subs)->test_strategy(SUBS_SEMI_JOIN))
{
continue;
}
all_merged= FALSE;
break;
}
/*
If the field was an outer referencee, mark all selects using this
sub query as dependent on the outer query
*/
if (!all_merged && current_sel != last_select)
{
mark_select_range_as_dependent(thd, last_select, current_sel,
found, *ref, item);
}
}
return found;
}
}
else
item->can_be_depended= TRUE;
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_buf(name_buff, db);
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,
(thd->lex->sql_command ==
SQLCOM_SHOW_FIELDS)
? false : check_privileges,
allow_rowid,
&(item->cached_field_index),
register_tree_change,
&actual_table);
if (cur_field)
{
if (cur_field == WRONG_GRANT)
{
if (thd->lex->sql_command != SQLCOM_SHOW_FIELDS)
return (Field*) 0;
thd->clear_error();
cur_field= find_field_in_table_ref(thd, cur_table, name, length,
item->name, db, table_name, ref,
false,
allow_rowid,
&(item->cached_field_index),
register_tree_change,
&actual_table);
if (cur_field)
{
Field *nf=new Field_null(NULL,0,Field::NONE,
cur_field->field_name,
&my_charset_bin);
nf->init(cur_table->table);
cur_field= nf;
}
}
/*
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[SAFE_NAME_LEN*2 + 2];
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
resolution Set to the resolution type if the item is found
(it says whether the item is resolved
against an alias name,
or as a field name without alias,
or as a field hidden by alias,
or ignoring alias)
limit How many items in the list to check
(if limit==0 then all items are to be checked)
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,
enum_resolution_type *resolution, uint limit)
{
List_iterator<Item> li(items);
uint n_items= limit == 0 ? items.elements : limit;
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;
/*
true if the item that we search for is a valid name reference
(and not an item that happens to have a name).
*/
bool is_ref_by_name= 0;
uint unaliased_counter= 0;
*resolution= NOT_RESOLVED;
is_ref_by_name= (find->type() == Item::FIELD_ITEM ||
find->type() == Item::REF_ITEM);
if (is_ref_by_name)
{
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; i < n_items; i++)
{
item= li++;
if (field_name &&
(item->real_item()->type() == Item::FIELD_ITEM ||
((item->type() == Item::REF_ITEM) &&
(((Item_ref *)item)->ref_type() == Item_ref::VIEW_REF))))
{
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) &&
!my_strcasecmp(table_alias_charset, 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;
*resolution= RESOLVED_IGNORING_ALIAS;
if (db_name)
break; // Perfect match
}
}
else
{
int fname_cmp= my_strcasecmp(system_charset_info,
item_field->field_name,
field_name);
if (!my_strcasecmp(system_charset_info,
item_field->name,field_name))
{
/*
If table name was not given we should scan through aliases
and 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;
*resolution= fname_cmp ? RESOLVED_AGAINST_ALIAS:
RESOLVED_WITH_NO_ALIAS;
}
else if (!fname_cmp)
{
/*
We will use non-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;
}
found_unaliased= li.ref();
unaliased_counter= i;
}
}
}
else if (!table_name)
{
if (is_ref_by_name && find->name && item->name &&
!my_strcasecmp(system_charset_info,item->name,find->name))
{
found= li.ref();
*counter= i;
*resolution= RESOLVED_AGAINST_ALIAS;
break;
}
else if (find->eq(item,0))
{
found= li.ref();
*counter= i;
*resolution= RESOLVED_IGNORING_ALIAS;
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;
*resolution= RESOLVED_BEHIND_ALIAS;
}
}
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;
/* true if field_name_1 is a member of using_fields */
bool is_using_column_1;
if (!(nj_col_1= it_1.get_or_create_column_ref(thd, leaf_1)))
goto err;
field_name_1= nj_col_1->name();
is_using_column_1= using_fields &&
test_if_string_in_list(field_name_1, using_fields);
DBUG_PRINT ("info", ("field_name_1=%s.%s",
nj_col_1->table_name() ? nj_col_1->table_name() : "",
field_name_1));
/*
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(thd, leaf_2)))
goto err;
cur_field_name_2= cur_nj_col_2->name();
DBUG_PRINT ("info", ("cur_field_name_2=%s.%s",
cur_nj_col_2->table_name() ?
cur_nj_col_2->table_name() : "",
cur_field_name_2));
/*
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).
Note that it is too early to check the columns outside of the
USING list for ambiguity because they are not actually "referenced"
here. These columns must be checked only on unqualified reference
by name (e.g. in SELECT list).
*/
if (!my_strcasecmp(system_charset_info, field_name_1, cur_field_name_2))
{
DBUG_PRINT ("info", ("match c1.is_common=%d", nj_col_1->is_common));
if (cur_nj_col_2->is_common ||
(found && (!using_fields || is_using_column_1)))
{
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 ||is_using_column_1))
{
/*
Create non-fixed fully qualified field and let fix_fields to
resolve it.
*/
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 (thd->mem_root) Item_func_eq(thd, item_ident_1, item_ident_2)))
goto err; /* Out of memory. */
if (field_1 && field_1->vcol_info)
field_1->table->mark_virtual_col(field_1);
if (field_2 && field_2->vcol_info)
field_2->table->mark_virtual_col(field_2);
/*
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(thd, (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;
DBUG_PRINT ("info", ("%s.%s and %s.%s are common",
nj_col_1->table_name() ?
nj_col_1->table_name() : "",
nj_col_1->name(),
nj_col_2->table_name() ?
nj_col_2->table_name() : "",
nj_col_2->name()));
if (field_1)
{
TABLE *table_1= nj_col_1->table_ref->table;
/* Mark field_1 used for table cache. */
bitmap_set_bit(table_1->read_set, field_1->field_index);
table_1->covering_keys.intersect(field_1->part_of_key);
}
if (field_2)
{
TABLE *table_2= nj_col_2->table_ref->table;
/* Mark field_2 used for table cache. */
bitmap_set_bit(table_2->read_set, field_2->field_index);
table_2->covering_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;
List<Natural_join_column> *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>) ||
!(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)
{
join_columns->push_back(nj_col_1, thd->mem_root);
/* 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, thd->mem_root);
}
/*
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(*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, thd->mem_root);
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)
join_columns->append(non_join_columns);
natural_using_join->join_columns= join_columns;
natural_using_join->is_join_columns_complete= TRUE;
result= FALSE;
if (arena)
thd->restore_active_arena(arena, &backup);
DBUG_RETURN(result);
err:
/*
Actually we failed to build join columns list, so we have to
clear it to avoid problems with half-build join on next run.
The list was created in mark_common_columns().
*/
table_ref_1->remove_join_columns();
table_ref_2->remove_join_columns();
if (arena)
thd->restore_active_arena(arena, &backup);
DBUG_RETURN(TRUE);
}
/*
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 *same_level_left_neighbor= nested_it++;
TABLE_LIST *same_level_right_neighbor= NULL;
/* Left/right-most neighbors, possibly at higher levels in the join tree. */
TABLE_LIST *real_left_neighbor, *real_right_neighbor;
while (same_level_left_neighbor)
{
TABLE_LIST *cur_table_ref= same_level_left_neighbor;
same_level_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
same_level_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 (same_level_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*, same_level_left_neighbor, cur_table_ref);
}
/*
Pick the parent's left and right neighbors if there are no immediate
neighbors at the same level.
*/
real_left_neighbor= (same_level_left_neighbor) ?
same_level_left_neighbor : left_neighbor;
real_right_neighbor= (same_level_right_neighbor) ?
same_level_right_neighbor : right_neighbor;
if (cur_table_ref->nested_join &&
store_top_level_join_columns(thd, cur_table_ref,
real_left_neighbor, real_right_neighbor))
goto err;
same_level_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 (thd->mem_root) Item_int(thd, (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.
NOTES
We can't run this many times as the first_name_resolution_table would
be different for subsequent runs when sub queries has been optimized
away.
RETURN
TRUE Error
FALSE OK
*/
static bool setup_natural_join_row_types(THD *thd,
List<TABLE_LIST> *from_clause,
Name_resolution_context *context)
{
DBUG_ENTER("setup_natural_join_row_types");
thd->where= "from clause";
if (from_clause->elements == 0)
DBUG_RETURN(false); /* We come here in the case of UNIONs. */
/*
Do not redo work if already done:
1) for stored procedures,
2) for multitable update after lock failure and table reopening.
*/
if (!context->select_lex->first_natural_join_processing)
{
context->first_name_resolution_table= context->natural_join_first_table;
DBUG_PRINT("info", ("using cached setup_natural_join_row_types"));
DBUG_RETURN(false);
}
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;
do
{
left_neighbor= table_ref_it++;
}
while (left_neighbor && left_neighbor->sj_subq_pred);
if (store_top_level_join_columns(thd, table_ref,
left_neighbor, right_neighbor))
DBUG_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();
/*
This is only to ensure that first_name_resolution_table doesn't
change on re-execution
*/
context->natural_join_first_table= context->first_name_resolution_table;
context->select_lex->first_natural_join_processing= false;
DBUG_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, uint *hidden_bit_fields)
{
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);
thd->lex->current_select->cur_pos_in_select_list= 0;
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 (thd->mem_root) Item_int(thd, "Not_used", (longlong) 1,
MY_INT64_NUM_DECIMAL_DIGITS));
}
else if (insert_fields(thd, ((Item_field*) item)->context,
((Item_field*) item)->db_name,
((Item_field*) item)->table_name, &it,
any_privileges, hidden_bit_fields))
{
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--;
}
else
thd->lex->current_select->cur_pos_in_select_list++;
}
thd->lex->current_select->cur_pos_in_select_list= UNDEF_POS;
if (arena)
{
/* make * substituting permanent */
SELECT_LEX *select_lex= thd->lex->current_select;
select_lex->with_wild= 0;
#ifdef HAVE_valgrind
if (&select_lex->item_list != &fields) // Avoid warning
#endif
/*
The assignment below is translated to memcpy() call (at least on some
platforms). memcpy() expects that source and destination areas do not
overlap. That problem was detected by valgrind.
*/
if (&select_lex->item_list != &fields)
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, Ref_ptr_array ref_pointer_array,
List<Item> &fields, enum_mark_columns mark_used_columns,
List<Item> *sum_func_list, List<Item> *pre_fix,
bool allow_sum_func)
{
Item *item;
enum_mark_columns save_mark_used_columns= thd->mark_used_columns;
nesting_map save_allow_sum_func= thd->lex->allow_sum_func;
List_iterator<Item> it(fields);
bool save_is_item_list_lookup;
bool make_pre_fix= (pre_fix && (pre_fix->elements == 0));
DBUG_ENTER("setup_fields");
DBUG_PRINT("enter", ("ref_pointer_array: %p", ref_pointer_array.array()));
thd->mark_used_columns= mark_used_columns;
DBUG_PRINT("info", ("thd->mark_used_columns: %d", thd->mark_used_columns));
if (allow_sum_func)
thd->lex->allow_sum_func|=
(nesting_map)1 << thd->lex->current_select->nest_level;
thd->where= THD::DEFAULT_WHERE;
save_is_item_list_lookup= thd->lex->current_select->is_item_list_lookup;
thd->lex->current_select->is_item_list_lookup= 0;
/*
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.is_null())
{
DBUG_ASSERT(ref_pointer_array.size() >= fields.elements);
memset(ref_pointer_array.array(), 0, sizeof(Item *) * fields.elements);
}
/*
We call set_entry() there (before fix_fields() of the whole list of field
items) because:
1) the list of field items has same order as in the query, and the
Item_func_get_user_var item may go before the Item_func_set_user_var:
SELECT @a, @a := 10 FROM t;
2) The entry->update_query_id value controls constantness of
Item_func_get_user_var items, so in presence of Item_func_set_user_var
items we have to refresh their entries before fixing of
Item_func_get_user_var items.
*/
List_iterator<Item_func_set_user_var> li(thd->lex->set_var_list);
Item_func_set_user_var *var;
while ((var= li++))
var->set_entry(thd, FALSE);
Ref_ptr_array ref= ref_pointer_array;
thd->lex->current_select->cur_pos_in_select_list= 0;
while ((item= it++))
{
if (make_pre_fix)
pre_fix->push_back(item, thd->stmt_arena->mem_root);
if ((!item->fixed && item->fix_fields(thd, it.ref())) ||
(item= *(it.ref()))->check_cols(1))
{
thd->lex->current_select->is_item_list_lookup= save_is_item_list_lookup;
thd->lex->allow_sum_func= save_allow_sum_func;
thd->mark_used_columns= save_mark_used_columns;
DBUG_PRINT("info", ("thd->mark_used_columns: %d", thd->mark_used_columns));
DBUG_RETURN(TRUE); /* purecov: inspected */
}
if (!ref.is_null())
{
ref[0]= item;
ref.pop_front();
}
/*
split_sum_func() must be called for Window Function items, see
Item_window_func::split_sum_func.
*/
if (sum_func_list &&
((item->with_sum_func && item->type() != Item::SUM_FUNC_ITEM) ||
item->with_window_func))
{
item->split_sum_func(thd, ref_pointer_array, *sum_func_list,
SPLIT_SUM_SELECT);
}
thd->lex->current_select->select_list_tables|= item->used_tables();
thd->lex->used_tables|= item->used_tables();
thd->lex->current_select->cur_pos_in_select_list++;
}
thd->lex->current_select->is_item_list_lookup= save_is_item_list_lookup;
thd->lex->current_select->cur_pos_in_select_list= UNDEF_POS;
thd->lex->allow_sum_func= save_allow_sum_func;
thd->mark_used_columns= save_mark_used_columns;
DBUG_PRINT("info", ("thd->mark_used_columns: %d", thd->mark_used_columns));
DBUG_RETURN(MY_TEST(thd->is_error()));
}
/*
make list of leaves of join table tree
SYNOPSIS
make_leaves_list()
list pointer to pointer on list first element
tables table list
full_table_list whether to include tables from mergeable derived table/view.
we need them for checks for INSERT/UPDATE statements only.
RETURN pointer on pointer to next_leaf of last element
*/
void make_leaves_list(THD *thd, List<TABLE_LIST> &list, TABLE_LIST *tables,
bool full_table_list, TABLE_LIST *boundary)
{
for (TABLE_LIST *table= tables; table; table= table->next_local)
{
if (table == boundary)
full_table_list= !full_table_list;
if (full_table_list && table->is_merged_derived())
{
SELECT_LEX *select_lex= table->get_single_select();
/*
It's safe to use select_lex->leaf_tables because all derived
tables/views were already prepared and has their leaf_tables
set properly.
*/
make_leaves_list(thd, list, select_lex->get_table_list(),
full_table_list, boundary);
}
else
{
list.push_back(table, thd->mem_root);
}
}
}
/*
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)
leaves List of join table leaves list (select_lex->leaf_tables)
refresh It is only refresh for subquery
select_insert It is SELECT ... INSERT command
full_table_list a parameter to pass to the make_leaves_list function
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,
List<TABLE_LIST> &leaves, bool select_insert,
bool full_table_list)
{
uint tablenr= 0;
List_iterator<TABLE_LIST> ti(leaves);
TABLE_LIST *table_list;
DBUG_ENTER("setup_tables");
DBUG_ASSERT ((select_insert && !tables->next_name_resolution_table) || !tables ||
(context->table_list && context->first_name_resolution_table));
/*
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);
SELECT_LEX *select_lex= select_insert ? &thd->lex->select_lex :
thd->lex->current_select;
if (select_lex->first_cond_optimization)
{
leaves.empty();
if (select_lex->prep_leaf_list_state != SELECT_LEX::SAVED)
{
make_leaves_list(thd, leaves, tables, full_table_list, first_select_table);
select_lex->prep_leaf_list_state= SELECT_LEX::READY;
select_lex->leaf_tables_exec.empty();
}
else
{
List_iterator_fast <TABLE_LIST> ti(select_lex->leaf_tables_prep);
while ((table_list= ti++))
leaves.push_back(table_list, thd->mem_root);
}
while ((table_list= ti++))
{
TABLE *table= table_list->table;
if (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;
thd->lex->select_lex.insert_tables= tablenr;
tablenr= 0;
}
if(table_list->jtbm_subselect)
{
table_list->jtbm_table_no= tablenr;
}
else if (table)
{
table->pos_in_table_list= table_list;
setup_table_map(table, table_list, tablenr);
if (table_list->process_index_hints(table))
DBUG_RETURN(1);
}
tablenr++;
}
if (tablenr > MAX_TABLES)
{
my_error(ER_TOO_MANY_TABLES,MYF(0), static_cast<int>(MAX_TABLES));
DBUG_RETURN(1);
}
}
else
{
List_iterator_fast <TABLE_LIST> ti(select_lex->leaf_tables_exec);
select_lex->leaf_tables.empty();
while ((table_list= ti++))
{
if(table_list->jtbm_subselect)
{
table_list->jtbm_table_no= table_list->tablenr_exec;
}
else
{
table_list->table->tablenr= table_list->tablenr_exec;
table_list->table->map= table_list->map_exec;
table_list->table->maybe_null= table_list->maybe_null_exec;
table_list->table->pos_in_table_list= table_list;
if (table_list->process_index_hints(table_list->table))
DBUG_RETURN(1);
}
select_lex->leaf_tables.push_back(table_list);
}
}
for (table_list= tables;
table_list;
table_list= table_list->next_local)
{
if (table_list->merge_underlying_list)
{
DBUG_ASSERT(table_list->is_merged_derived());
Query_arena *arena, backup;
arena= thd->activate_stmt_arena_if_needed(&backup);
bool res;
res= table_list->setup_underlying(thd);
if (arena)
thd->restore_active_arena(arena, &backup);
if (res)
DBUG_RETURN(1);
}
if (table_list->jtbm_subselect)
{
Item *item= table_list->jtbm_subselect->optimizer;
if (table_list->jtbm_subselect->optimizer->fix_fields(thd, &item))
{
my_error(ER_TOO_MANY_TABLES,MYF(0), static_cast<int>(MAX_TABLES)); /* psergey-todo: WHY ER_TOO_MANY_TABLES ???*/
DBUG_RETURN(1);
}
DBUG_ASSERT(item == table_list->jtbm_subselect->optimizer);
}
}
/* 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_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
full_table_list a parameter to pass to the make_leaves_list function
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, List<TABLE_LIST> &leaves,
bool select_insert, ulong want_access_first,
ulong want_access, bool full_table_list)
{
DBUG_ENTER("setup_tables_and_check_access");
if (setup_tables(thd, context, from_clause, tables,
leaves, select_insert, full_table_list))
DBUG_RETURN(TRUE);
List_iterator<TABLE_LIST> ti(leaves);
TABLE_LIST *table_list;
ulong access= want_access_first;
while ((table_list= ti++))
{
if (table_list->belong_to_view && !table_list->view &&
check_single_table_access(thd, access, table_list, FALSE))
{
tables->hide_view_error(thd);
DBUG_RETURN(TRUE);
}
access= want_access;
}
DBUG_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, uint *hidden_bit_fields)
{
Field_iterator_table_ref field_iterator;
bool found;
char name_buff[SAFE_NAME_LEN+1];
DBUG_ENTER("insert_fields");
DBUG_PRINT("arena", ("stmt arena: %p",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_buf(name_buff, db_name);
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. Under
some circumstances, this check may be skipped.
- If any_privileges is true, skip the check.
- If the SELECT privilege has been found as fulfilled already for both
the TABLE and TABLE_LIST objects (and both of these exist, of
course), the check is skipped.
- If the SELECT privilege has been found fulfilled for the TABLE object
and the TABLE_LIST represents a derived table other than a view (see
below), the check is skipped.
- If the TABLE_LIST object represents a view, we may skip checking if
the SELECT privilege has been found fulfilled for it, regardless of
the TABLE object.
- If there is no TABLE object, the test is skipped if either
* the TABLE_LIST does not represent a view, or
* the SELECT privilege has been found fulfilled.
A TABLE_LIST that is not a view may be a subquery, an
information_schema table, or a nested table reference. See the comment
for TABLE_LIST.
*/
if (!((table && tables->is_non_derived() &&
(table->grant.privilege & SELECT_ACL)) ||
((!tables->is_non_derived() &&
(tables->grant.privilege & SELECT_ACL)))) &&
!any_privileges)
{
field_iterator.set(tables);
if (check_grant_all_columns(thd, SELECT_ACL, &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->lex->used_tables|= table->map;
thd->lex->current_select->select_list_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);
/* cache the table for the Item_fields inserted by expanding stars */
if (item->type() == Item::FIELD_ITEM && tables->cacheable_table)
((Item_field *)item)->cached_table= tables;
if (!found)
{
found= TRUE;
it->replace(item); /* Replace '*' with the first found item. */
}
else
it->after(item); /* Add 'item' to the SELECT list. */
if (item->type() == Item::FIELD_ITEM && item->field_type() == MYSQL_TYPE_BIT)
(*hidden_bit_fields)++;
#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 && !tables->is_with_table() && !tables->is_derived())
{
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.get_table_name();
if (!tables->schema_table &&
!(fld->have_privileges=
(get_column_grant(thd, field_iterator.grant(),
field_iterator.get_db_name(),
field_table_name, fld->field_name) &
VIEW_ANY_ACL)))
{
my_error(ER_TABLEACCESS_DENIED_ERROR, MYF(0), "ANY",
thd->security_ctx->priv_user,
thd->security_ctx->host_or_ip,
field_table_name);
DBUG_RETURN(TRUE);
}
}
#endif
if ((field= field_iterator.field()))
{
/* Mark fields as used to allow storage engine to optimze access */
bitmap_set_bit(field->table->read_set, field->field_index);
/*
Mark virtual fields for write and others that the virtual fields
depend on for read.
*/
if (field->vcol_info)
field->table->mark_virtual_col(field);
if (table)
{
table->covering_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->lex->used_tables|= field_table->map;
thd->lex->current_select->select_list_tables|=
field_table->map;
field_table->covering_keys.intersect(field->part_of_key);
field_table->used_fields++;
}
}
}
else
thd->lex->used_tables|= item->used_tables();
thd->lex->current_select->cur_pos_in_select_list++;
}
/*
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_error(ER_NO_TABLES_USED, MYF(0));
else if (!db_name && !thd->db)
my_error(ER_NO_DB_ERROR, MYF(0));
else
{
char name[FN_REFLEN];
my_snprintf(name, sizeof(name), "%s.%s",
db_name ? db_name : thd->db, table_name);
my_error(ER_BAD_TABLE_ERROR, MYF(0), name);
}
DBUG_RETURN(TRUE);
}
/**
Wrap Item_ident
@param thd thread handle
@param conds pointer to the condition which should be wrapped
*/
void wrap_ident(THD *thd, Item **conds)
{
Item_direct_ref_to_ident *wrapper;
DBUG_ASSERT((*conds)->type() == Item::FIELD_ITEM || (*conds)->type() == Item::REF_ITEM);
Query_arena *arena, backup;
arena= thd->activate_stmt_arena_if_needed(&backup);
if ((wrapper= new (thd->mem_root) Item_direct_ref_to_ident(thd, (Item_ident *) (*conds))))
(*conds)= (Item*) wrapper;
if (arena)
thd->restore_active_arena(arena, &backup);
}
/**
Prepare ON expression
@param thd Thread handle
@param table Pointer to table list
@param is_update Update flag
@retval TRUE error.
@retval FALSE OK.
*/
bool setup_on_expr(THD *thd, TABLE_LIST *table, bool is_update)
{
uchar buff[STACK_BUFF_ALLOC]; // Max argument in function
if (check_stack_overrun(thd, STACK_MIN_SIZE, buff))
return TRUE; // Fatal error flag is set!
for(; table; table= table->next_local)
{
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)
{
thd->where="on clause";
embedded->on_expr->mark_as_condition_AND_part(embedded);
if ((!embedded->on_expr->fixed &&
embedded->on_expr->fix_fields(thd, &embedded->on_expr)) ||
embedded->on_expr->check_cols(1))
return TRUE;
}
/*
If it's a semi-join nest, fix its "left expression", as it is used by
the SJ-Materialization
*/
if (embedded->sj_subq_pred)
{
Item **left_expr= &embedded->sj_subq_pred->left_expr;
if (!(*left_expr)->fixed && (*left_expr)->fix_fields(thd, left_expr))
return TRUE;
}
embedding= embedded->embedding;
}
while (embedding &&
embedding->nested_join->join_list.head() == embedded);
if (table->is_merged_derived())
{
SELECT_LEX *select_lex= table->get_single_select();
setup_on_expr(thd, select_lex->get_table_list(), is_update);
}
/* process CHECK OPTION */
if (is_update)
{
TABLE_LIST *view= table->top_table();
if (view->effective_with_check)
{
if (view->prepare_check_option(thd))
return TRUE;
thd->change_item_tree(&table->check_option, view->check_option);
}
}
}
return FALSE;
}
/*
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 occurred (e.g. out of memory)
FALSE if all is OK
*/
int setup_conds(THD *thd, TABLE_LIST *tables, List<TABLE_LIST> &leaves,
COND **conds)
{
SELECT_LEX *select_lex= thd->lex->current_select;
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();
bool save_is_item_list_lookup= select_lex->is_item_list_lookup;
TABLE_LIST *derived= select_lex->master_unit()->derived;
DBUG_ENTER("setup_conds");
/* Do not fix conditions for the derived tables that have been merged */
if (derived && derived->merged)
DBUG_RETURN(0);
select_lex->is_item_list_lookup= 0;
thd->mark_used_columns= MARK_COLUMNS_READ;
DBUG_PRINT("info", ("thd->mark_used_columns: %d", thd->mark_used_columns));
select_lex->cond_count= 0;
select_lex->between_count= 0;
select_lex->max_equal_elems= 0;
for (table= tables; table; table= table->next_local)
{
if (select_lex == &thd->lex->select_lex &&
select_lex->first_cond_optimization &&
table->merged_for_insert &&
table->prepare_where(thd, conds, FALSE))
goto err_no_arena;
}
if (*conds)
{
thd->where="where clause";
DBUG_EXECUTE("where",
print_where(*conds,
"WHERE in setup_conds",
QT_ORDINARY););
/*
Wrap alone field in WHERE clause in case it will be outer field of subquery
which need persistent pointer on it, but conds could be changed by optimizer
*/
if ((*conds)->type() == Item::FIELD_ITEM && !derived)
wrap_ident(thd, conds);
(*conds)->mark_as_condition_AND_part(NO_JOIN_NEST);
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.
*/
if (setup_on_expr(thd, tables, it_is_update))
goto err_no_arena;
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;
}
thd->lex->current_select->is_item_list_lookup= save_is_item_list_lookup;
DBUG_RETURN(MY_TEST(thd->is_error()));
err_no_arena:
select_lex->is_item_list_lookup= save_is_item_list_lookup;
DBUG_RETURN(1);
}
/******************************************************************************
** Fill a record with data (for INSERT or UPDATE)
** Returns : 1 if some field has wrong type
******************************************************************************/
/**
Fill the fields of a table with the values of an Item list
@param thd thread handler
@param table_arg the table that is being modified
@param fields Item_fields list to be filled
@param values values to fill with
@param ignore_errors TRUE if we should ignore errors
@param update TRUE if update query
@details
fill_record() may set table->auto_increment_field_not_null and a
caller should make sure that it is reset after their last call to this
function.
default functions are executed for inserts.
virtual fields are always updated
@return Status
@retval true An error occurred.
@retval false OK.
*/
bool
fill_record(THD *thd, TABLE *table_arg, List<Item> &fields, List<Item> &values,
bool ignore_errors, bool update)
{
List_iterator_fast<Item> f(fields),v(values);
Item *value, *fld;
Item_field *field;
bool save_abort_on_warning= thd->abort_on_warning;
bool save_no_errors= thd->no_errors;
DBUG_ENTER("fill_record");
thd->no_errors= ignore_errors;
/*
Reset the table->auto_increment_field_not_null as it is valid for
only one row.
*/
if (fields.elements)
{
/*
On INSERT or UPDATE fields are checked to be from the same table,
thus we safely can take table from the first field.
*/
fld= (Item_field*)f++;
if (!(field= fld->field_for_view_update()))
{
my_error(ER_NONUPDATEABLE_COLUMN, MYF(0), fld->name);
goto err;
}
DBUG_ASSERT(field->field->table == table_arg);
table_arg->auto_increment_field_not_null= FALSE;
f.rewind();
}
while ((fld= f++))
{
if (!(field= fld->field_for_view_update()))
{
my_error(ER_NONUPDATEABLE_COLUMN, MYF(0), fld->name);
goto err;
}
value=v++;
Field *rfield= field->field;
TABLE* table= rfield->table;
if (table->next_number_field &&
rfield->field_index == table->next_number_field->field_index)
table->auto_increment_field_not_null= TRUE;
if (rfield->vcol_info &&
!value->vcol_assignment_allowed_value() &&
table->s->table_category != TABLE_CATEGORY_TEMPORARY)
{
push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN,
ER_WARNING_NON_DEFAULT_VALUE_FOR_VIRTUAL_COLUMN,
ER_THD(thd, ER_WARNING_NON_DEFAULT_VALUE_FOR_VIRTUAL_COLUMN),
rfield->field_name, table->s->table_name.str);
}
if (rfield->stored_in_db() &&
(value->save_in_field(rfield, 0)) < 0 && !ignore_errors)
{
my_message(ER_UNKNOWN_ERROR, ER_THD(thd, ER_UNKNOWN_ERROR), MYF(0));
goto err;
}
rfield->set_has_explicit_value();
}
if (update)
table_arg->evaluate_update_default_function();
else
if (table_arg->default_field &&
table_arg->update_default_fields(ignore_errors))
goto err;
/* Update virtual fields */
if (table_arg->vfield &&
table_arg->update_virtual_fields(table_arg->file, VCOL_UPDATE_FOR_WRITE))
goto err;
thd->abort_on_warning= save_abort_on_warning;
thd->no_errors= save_no_errors;
DBUG_RETURN(thd->is_error());
err:
DBUG_PRINT("error",("got error"));
thd->abort_on_warning= save_abort_on_warning;
thd->no_errors= save_no_errors;
if (fields.elements)
table_arg->auto_increment_field_not_null= FALSE;
DBUG_RETURN(TRUE);
}
/**
Prepare Item_field's for fill_record_n_invoke_before_triggers()
This means redirecting from table->field to
table->field_to_fill(), if needed.
*/
void switch_to_nullable_trigger_fields(List<Item> &items, TABLE *table)
{
Field** field= table->field_to_fill();
/* True if we have NOT NULL fields and BEFORE triggers */
if (field != table->field)
{
List_iterator_fast<Item> it(items);
Item *item;
while ((item= it++))
item->walk(&Item::switch_to_nullable_fields_processor, 1, field);
table->triggers->reset_extra_null_bitmap();
}
}
/**
Prepare Virtual fields and field with default expressions to use
trigger fields
This means redirecting from table->field to
table->field_to_fill(), if needed.
*/
void switch_defaults_to_nullable_trigger_fields(TABLE *table)
{
if (!table->default_field)
return; // no defaults
Field **trigger_field= table->field_to_fill();
/* True if we have NOT NULL fields and BEFORE triggers */
if (trigger_field != table->field)
{
for (Field **field_ptr= table->default_field; *field_ptr ; field_ptr++)
{
Field *field= (*field_ptr);
field->default_value->expr->walk(&Item::switch_to_nullable_fields_processor, 1, trigger_field);
*field_ptr= (trigger_field[field->field_index]);
}
}
}
/**
Test NOT NULL constraint after BEFORE triggers
*/
static bool not_null_fields_have_null_values(TABLE *table)
{
Field **orig_field= table->field;
Field **filled_field= table->field_to_fill();
if (filled_field != orig_field)
{
THD *thd=table->in_use;
for (uint i=0; i < table->s->fields; i++)
{
Field *of= orig_field[i];
Field *ff= filled_field[i];
if (ff != of)
{
// copy after-update flags to of, copy before-update flags to ff
swap_variables(uint32, of->flags, ff->flags);
if (ff->is_real_null())
{
ff->set_notnull(); // for next row WHERE condition in UPDATE
if (convert_null_to_field_value_or_error(of) || thd->is_error())
return true;
}
}
}
}
return false;
}
/**
Fill fields in list with values from the list of items and invoke
before triggers.
@param thd thread context
@param table the table that is being modified
@param fields Item_fields list to be filled
@param values values to fill with
@param ignore_errors TRUE if we should ignore errors
@param event event type for triggers to be invoked
@detail
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 Status
@retval true An error occurred.
@retval false OK.
*/
bool
fill_record_n_invoke_before_triggers(THD *thd, TABLE *table,
List<Item> &fields,
List<Item> &values, bool ignore_errors,
enum trg_event_type event)
{
bool result;
Table_triggers_list *triggers= table->triggers;
result= fill_record(thd, table, fields, values, ignore_errors,
event == TRG_EVENT_UPDATE);
if (!result && triggers)
{
if (triggers->process_triggers(thd, event, TRG_ACTION_BEFORE,
TRUE) ||
not_null_fields_have_null_values(table))
return TRUE;
/*
Re-calculate virtual fields to cater for cases when base columns are
updated by the triggers.
*/
if (table->vfield && fields.elements)
{
Item *fld= (Item_field*) fields.head();
Item_field *item_field= fld->field_for_view_update();
if (item_field)
{
DBUG_ASSERT(table == item_field->field->table);
result|= table->update_virtual_fields(table->file,
VCOL_UPDATE_FOR_WRITE);
}
}
}
return result;
}
/**
Fill the field buffer of a table with the values of an Item list
All fields are given a value
@param thd thread handler
@param table_arg the table that is being modified
@param ptr pointer on pointer to record of fields
@param values values to fill with
@param ignore_errors TRUE if we should ignore errors
@param use_value forces usage of value of the items instead of result
@details
fill_record() may set table->auto_increment_field_not_null and a
caller should make sure that it is reset after their last call to this
function.
@return Status
@retval true An error occurred.
@retval false OK.
*/
bool
fill_record(THD *thd, TABLE *table, Field **ptr, List<Item> &values,
bool ignore_errors, bool use_value)
{
List_iterator_fast<Item> v(values);
List<TABLE> tbl_list;
Item *value;
Field *field;
bool abort_on_warning_saved= thd->abort_on_warning;
uint autoinc_index= table->next_number_field
? table->next_number_field->field_index
: ~0U;
DBUG_ENTER("fill_record");
if (!*ptr)
{
/* No fields to update, quite strange!*/
DBUG_RETURN(0);
}
/*
On INSERT or UPDATE fields are checked to be from the same table,
thus we safely can take table from the first field.
*/
DBUG_ASSERT((*ptr)->table == table);
/*
Reset the table->auto_increment_field_not_null as it is valid for
only one row.
*/
table->auto_increment_field_not_null= FALSE;
while ((field = *ptr++) && ! thd->is_error())
{
/* Ensure that all fields are from the same table */
DBUG_ASSERT(field->table == table);
value=v++;
if (field->field_index == autoinc_index)
table->auto_increment_field_not_null= TRUE;
if (field->vcol_info &&
!value->vcol_assignment_allowed_value() &&
table->s->table_category != TABLE_CATEGORY_TEMPORARY)
{
push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN,
ER_WARNING_NON_DEFAULT_VALUE_FOR_VIRTUAL_COLUMN,
ER_THD(thd, ER_WARNING_NON_DEFAULT_VALUE_FOR_VIRTUAL_COLUMN),
field->field_name, table->s->table_name.str);
}
if (use_value)
value->save_val(field);
else
if (value->save_in_field(field, 0) < 0)
goto err;
field->set_has_explicit_value();
}
/* Update virtual fields */
thd->abort_on_warning= FALSE;
if (table->vfield &&
table->update_virtual_fields(table->file, VCOL_UPDATE_FOR_WRITE))
goto err;
thd->abort_on_warning= abort_on_warning_saved;
DBUG_RETURN(thd->is_error());
err:
thd->abort_on_warning= abort_on_warning_saved;
table->auto_increment_field_not_null= FALSE;
DBUG_RETURN(TRUE);
}
/*
Fill fields in an array with values from the list of items and invoke
before triggers.
@param thd thread context
@param table the table that is being modified
@param ptr the fields to be filled
@param values values to fill with
@param ignore_errors TRUE if we should ignore errors
@param event event type for triggers to be invoked
@detail
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 Status
@retval true An error occurred.
@retval false OK.
*/
bool
fill_record_n_invoke_before_triggers(THD *thd, TABLE *table, Field **ptr,
List<Item> &values, bool ignore_errors,
enum trg_event_type event)
{
bool result;
Table_triggers_list *triggers= table->triggers;
result= fill_record(thd, table, ptr, values, ignore_errors, FALSE);
if (!result && triggers && *ptr)
result= triggers->process_triggers(thd, event, TRG_ACTION_BEFORE, TRUE) ||
not_null_fields_have_null_values(table);
/*
Re-calculate virtual fields to cater for cases when base columns are
updated by the triggers.
*/
if (!result && triggers && *ptr)
{
DBUG_ASSERT(table == (*ptr)->table);
if (table->vfield)
result= table->update_virtual_fields(table->file, VCOL_UPDATE_FOR_WRITE);
}
return result;
}
my_bool mysql_rm_tmp_tables(void)
{
uint i, idx;
char filePath[FN_REFLEN], *tmpdir, filePathCopy[FN_REFLEN];
MY_DIR *dirp;
FILEINFO *file;
TABLE_SHARE share;
THD *thd;
DBUG_ENTER("mysql_rm_tmp_tables");
if (!(thd= new THD(0)))
DBUG_RETURN(1);
thd->thread_stack= (char*) &thd;
thd->store_globals();
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_of_files ; idx++)
{
file=dirp->dir_entry+idx;
if (!strncmp(file->name, tmp_file_prefix, tmp_file_prefix_length))
{
char *ext= fn_ext(file->name);
uint ext_len= strlen(ext);
uint filePath_len= my_snprintf(filePath, sizeof(filePath),
"%s%c%s", tmpdir, FN_LIBCHAR,
file->name);
if (!strcmp(reg_ext, ext))
{
handler *handler_file= 0;
/* We should cut file extention before deleting of table */
memcpy(filePathCopy, filePath, filePath_len - ext_len);
filePathCopy[filePath_len - ext_len]= 0;
init_tmp_table_share(thd, &share, "", 0, "", filePathCopy);
if (!open_table_def(thd, &share) &&
((handler_file= get_new_handler(&share, thd->mem_root,
share.db_type()))))
{
handler_file->ha_delete_table(filePathCopy);
delete handler_file;
}
free_table_share(&share);
}
/*
File can be already deleted by tmp_table.file->delete_table().
So we hide error messages which happnes during deleting of these
files(MYF(0)).
*/
(void) mysql_file_delete(key_file_misc, filePath, MYF(0));
}
}
my_dirend(dirp);
}
delete thd;
DBUG_RETURN(0);
}
/*****************************************************************************
unireg support functions
*****************************************************************************/
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"));
while ((ifm=li++))
if (unlikely(!ifm->fixed))
/*
it mean that clause where was FT function was removed, so we have
to remove the function from the list.
*/
li.remove();
else
ifm->init_search(thd, no_order);
}
return 0;
}
bool is_equal(const LEX_STRING *a, const LEX_STRING *b)
{
return a->length == b->length && !strncmp(a->str, b->str, a->length);
}
/*
Open and lock system tables for read.
SYNOPSIS
open_system_tables_for_read()
thd Thread context.
table_list List of tables to open.
backup Pointer to Open_tables_state instance where
information about currently open tables will be
saved, and from which will be restored when we will
end work with system tables.
NOTES
Thanks to restrictions which we put on opening and locking of
system tables for writing, we can open and lock them for reading
even when we already have some other tables open and locked. One
must call close_system_tables() to close systems tables opened
with this call.
NOTES
In some situations we use this function to open system tables for
writing. It happens, for examples, with statistical tables when
they are updated by an ANALYZE command. In these cases we should
guarantee that system tables will not be deadlocked.
RETURN
FALSE Success
TRUE Error
*/
bool
open_system_tables_for_read(THD *thd, TABLE_LIST *table_list,
Open_tables_backup *backup)
{
Query_tables_list query_tables_list_backup;
LEX *lex= thd->lex;
DBUG_ENTER("open_system_tables_for_read");
/*
Besides using new Open_tables_state for opening system tables,
we also have to backup and reset/and then restore part of LEX
which is accessed by open_tables() in order to determine if
prelocking is needed and what tables should be added for it.
close_system_tables() doesn't require such treatment.
*/
lex->reset_n_backup_query_tables_list(&query_tables_list_backup);
thd->reset_n_backup_open_tables_state(backup);
thd->lex->sql_command= SQLCOM_SELECT;
if (open_and_lock_tables(thd, table_list, FALSE,
MYSQL_OPEN_IGNORE_FLUSH |
MYSQL_LOCK_IGNORE_TIMEOUT))
{
lex->restore_backup_query_tables_list(&query_tables_list_backup);
thd->restore_backup_open_tables_state(backup);
DBUG_RETURN(TRUE);
}
for (TABLE_LIST *tables= table_list; tables; tables= tables->next_global)
{
DBUG_ASSERT(tables->table->s->table_category == TABLE_CATEGORY_SYSTEM);
tables->table->use_all_columns();
}
lex->restore_backup_query_tables_list(&query_tables_list_backup);
DBUG_RETURN(FALSE);
}
/*
Close system tables, opened with open_system_tables_for_read().
SYNOPSIS
close_system_tables()
thd Thread context
backup Pointer to Open_tables_backup instance which holds
information about tables which were open before we
decided to access system tables.
*/
void
close_system_tables(THD *thd, Open_tables_backup *backup)
{
close_thread_tables(thd);
thd->restore_backup_open_tables_state(backup);
}
/**
A helper function to close a mysql.* table opened
in an auxiliary THD during bootstrap or in the main
connection, when we know that there are no locks
held by the connection due to a preceding implicit
commit.
We need this function since we'd like to not
just close the system table, but also release
the metadata lock on it.
Note, that in LOCK TABLES mode this function
does not release the metadata lock. But in this
mode the table can be opened only if it is locked
explicitly with LOCK TABLES.
*/
void
close_mysql_tables(THD *thd)
{
if (! thd->in_sub_stmt)
trans_commit_stmt(thd);
close_thread_tables(thd);
thd->mdl_context.release_transactional_locks();
}
/*
Open and lock one system table for update.
SYNOPSIS
open_system_table_for_update()
thd Thread context.
one_table Table to open.
NOTES
Table opened with this call should closed using close_thread_tables().
RETURN
0 Error
# Pointer to TABLE object of system table
*/
TABLE *
open_system_table_for_update(THD *thd, TABLE_LIST *one_table)
{
DBUG_ENTER("open_system_table_for_update");
TABLE *table= open_ltable(thd, one_table, one_table->lock_type,
MYSQL_LOCK_IGNORE_TIMEOUT);
if (table)
{
DBUG_ASSERT(table->s->table_category == TABLE_CATEGORY_SYSTEM);
table->use_all_columns();
}
DBUG_RETURN(table);
}
/**
Open a log table.
Opening such tables is performed internally in the server
implementation, and is a 'nested' open, since some tables
might be already opened by the current thread.
The thread context before this call is saved, and is restored
when calling close_log_table().
@param thd The current thread
@param one_table Log table to open
@param backup [out] Temporary storage used to save the thread context
*/
TABLE *
open_log_table(THD *thd, TABLE_LIST *one_table, Open_tables_backup *backup)
{
uint flags= ( MYSQL_OPEN_IGNORE_GLOBAL_READ_LOCK |
MYSQL_LOCK_IGNORE_GLOBAL_READ_ONLY |
MYSQL_OPEN_IGNORE_FLUSH |
MYSQL_LOCK_IGNORE_TIMEOUT |
MYSQL_LOCK_LOG_TABLE);
TABLE *table;
/* Save value that is changed in mysql_lock_tables() */
ulonglong save_utime_after_lock= thd->utime_after_lock;
DBUG_ENTER("open_log_table");
thd->reset_n_backup_open_tables_state(backup);
if ((table= open_ltable(thd, one_table, one_table->lock_type, flags)))
{
DBUG_ASSERT(table->s->table_category == TABLE_CATEGORY_LOG);
/* Make sure all columns get assigned to a default value */
table->use_all_columns();
DBUG_ASSERT(table->no_replicate);
}
else
thd->restore_backup_open_tables_state(backup);
thd->utime_after_lock= save_utime_after_lock;
DBUG_RETURN(table);
}
/**
Close a log table.
The last table opened by open_log_table()
is closed, then the thread context is restored.
@param thd The current thread
@param backup [in] the context to restore.
*/
void close_log_table(THD *thd, Open_tables_backup *backup)
{
close_system_tables(thd, backup);
}
/**
@brief
Remove 'fixed' flag from items in a list
@param items list of items to un-fix
@details
This function sets to 0 the 'fixed' flag for items in the 'items' list.
It's needed to force correct marking of views' fields for INSERT/UPDATE
statements.
*/
void unfix_fields(List<Item> &fields)
{
List_iterator<Item> li(fields);
Item *item;
while ((item= li++))
item->fixed= 0;
}
/**
Check result of dynamic column function and issue error if it is needed
@param rc The result code of dynamic column function
@return the result code which was get as an argument\
*/
int dynamic_column_error_message(enum_dyncol_func_result rc)
{
switch (rc) {
case ER_DYNCOL_YES:
case ER_DYNCOL_OK:
case ER_DYNCOL_TRUNCATED:
break; // it is not an error
case ER_DYNCOL_FORMAT:
my_error(ER_DYN_COL_WRONG_FORMAT, MYF(0));
break;
case ER_DYNCOL_LIMIT:
my_error(ER_DYN_COL_IMPLEMENTATION_LIMIT, MYF(0));
break;
case ER_DYNCOL_RESOURCE:
my_error(ER_OUT_OF_RESOURCES, MYF(0));
break;
case ER_DYNCOL_DATA:
my_error(ER_DYN_COL_DATA, MYF(0));
break;
case ER_DYNCOL_UNKNOWN_CHARSET:
my_error(ER_DYN_COL_WRONG_CHARSET, MYF(0));
break;
}
return rc;
}
/**
@} (end of group Data_Dictionary)
*/
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