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|
/* Copyright (c) 2000, 2012, Oracle and/or its affiliates.
Copyright (c) 2009, 2012, Monty Program Ab.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */
/** @file handler.cc
@brief
Handler-calling-functions
*/
#include "sql_priv.h"
#include "unireg.h"
#include "rpl_handler.h"
#include "sql_cache.h" // query_cache, query_cache_*
#include "sql_connect.h" // global_table_stats
#include "key.h" // key_copy, key_unpack, key_cmp_if_same, key_cmp
#include "sql_table.h" // build_table_filename
#include "sql_parse.h" // check_stack_overrun
#include "sql_acl.h" // SUPER_ACL
#include "sql_base.h" // free_io_cache
#include "discover.h" // writefrm
#include "log_event.h" // *_rows_log_event
#include "create_options.h"
#include "rpl_filter.h"
#include <myisampack.h>
#include "transaction.h"
#include "myisam.h"
#include "probes_mysql.h"
#include <mysql/psi/mysql_table.h>
#include "debug_sync.h" // DEBUG_SYNC
#ifdef WITH_PARTITION_STORAGE_ENGINE
#include "ha_partition.h"
#endif
#ifdef WITH_ARIA_STORAGE_ENGINE
#include "../storage/maria/ha_maria.h"
#endif
/*
While we have legacy_db_type, we have this array to
check for dups and to find handlerton from legacy_db_type.
Remove when legacy_db_type is finally gone
*/
st_plugin_int *hton2plugin[MAX_HA];
static handlerton *installed_htons[128];
#define BITMAP_STACKBUF_SIZE (128/8)
KEY_CREATE_INFO default_key_create_info=
{ HA_KEY_ALG_UNDEF, 0, {NullS, 0}, {NullS, 0}, true };
/* number of entries in handlertons[] */
ulong total_ha= 0;
/* number of storage engines (from handlertons[]) that support 2pc */
ulong total_ha_2pc= 0;
/* size of savepoint storage area (see ha_init) */
ulong savepoint_alloc_size= 0;
static const LEX_STRING sys_table_aliases[]=
{
{ C_STRING_WITH_LEN("INNOBASE") }, { C_STRING_WITH_LEN("INNODB") },
{ C_STRING_WITH_LEN("NDB") }, { C_STRING_WITH_LEN("NDBCLUSTER") },
{ C_STRING_WITH_LEN("HEAP") }, { C_STRING_WITH_LEN("MEMORY") },
{ C_STRING_WITH_LEN("MERGE") }, { C_STRING_WITH_LEN("MRG_MYISAM") },
{ C_STRING_WITH_LEN("Maria") }, { C_STRING_WITH_LEN("Aria") },
{NullS, 0}
};
const char *ha_row_type[] = {
"", "FIXED", "DYNAMIC", "COMPRESSED", "REDUNDANT", "COMPACT",
"PAGE",
"?","?","?"
};
const char *tx_isolation_names[] =
{ "READ-UNCOMMITTED", "READ-COMMITTED", "REPEATABLE-READ", "SERIALIZABLE",
NullS};
TYPELIB tx_isolation_typelib= {array_elements(tx_isolation_names)-1,"",
tx_isolation_names, NULL};
static TYPELIB known_extensions= {0,"known_exts", NULL, NULL};
uint known_extensions_id= 0;
static int commit_one_phase_2(THD *thd, bool all, THD_TRANS *trans,
bool is_real_trans);
static plugin_ref ha_default_plugin(THD *thd)
{
if (thd->variables.table_plugin)
return thd->variables.table_plugin;
return my_plugin_lock(thd, global_system_variables.table_plugin);
}
/** @brief
Return the default storage engine handlerton for thread
SYNOPSIS
ha_default_handlerton(thd)
thd current thread
RETURN
pointer to handlerton
*/
handlerton *ha_default_handlerton(THD *thd)
{
plugin_ref plugin= ha_default_plugin(thd);
DBUG_ASSERT(plugin);
handlerton *hton= plugin_data(plugin, handlerton*);
DBUG_ASSERT(hton);
return hton;
}
/** @brief
Return the storage engine handlerton for the supplied name
SYNOPSIS
ha_resolve_by_name(thd, name)
thd current thread
name name of storage engine
RETURN
pointer to storage engine plugin handle
*/
plugin_ref ha_resolve_by_name(THD *thd, const LEX_STRING *name)
{
const LEX_STRING *table_alias;
plugin_ref plugin;
redo:
/* my_strnncoll is a macro and gcc doesn't do early expansion of macro */
if (thd && !my_charset_latin1.coll->strnncoll(&my_charset_latin1,
(const uchar *)name->str, name->length,
(const uchar *)STRING_WITH_LEN("DEFAULT"), 0))
return ha_default_plugin(thd);
if ((plugin= my_plugin_lock_by_name(thd, name, MYSQL_STORAGE_ENGINE_PLUGIN)))
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton && !(hton->flags & HTON_NOT_USER_SELECTABLE))
return plugin;
/*
unlocking plugin immediately after locking is relatively low cost.
*/
plugin_unlock(thd, plugin);
}
/*
We check for the historical aliases.
*/
for (table_alias= sys_table_aliases; table_alias->str; table_alias+= 2)
{
if (!my_strnncoll(&my_charset_latin1,
(const uchar *)name->str, name->length,
(const uchar *)table_alias->str, table_alias->length))
{
name= table_alias + 1;
goto redo;
}
}
return NULL;
}
plugin_ref ha_lock_engine(THD *thd, const handlerton *hton)
{
if (hton)
{
st_plugin_int *plugin= hton2plugin[hton->slot];
return my_plugin_lock(thd, plugin_int_to_ref(plugin));
}
return NULL;
}
handlerton *ha_resolve_by_legacy_type(THD *thd, enum legacy_db_type db_type)
{
plugin_ref plugin;
switch (db_type) {
case DB_TYPE_DEFAULT:
return ha_default_handlerton(thd);
default:
if (db_type > DB_TYPE_UNKNOWN && db_type < DB_TYPE_DEFAULT &&
(plugin= ha_lock_engine(thd, installed_htons[db_type])))
return plugin_data(plugin, handlerton*);
/* fall through */
case DB_TYPE_UNKNOWN:
return NULL;
}
}
/**
Use other database handler if databasehandler is not compiled in.
*/
handlerton *ha_checktype(THD *thd, enum legacy_db_type database_type,
bool no_substitute, bool report_error)
{
handlerton *hton= ha_resolve_by_legacy_type(thd, database_type);
if (ha_storage_engine_is_enabled(hton))
return hton;
if (no_substitute)
{
if (report_error)
{
const char *engine_name= ha_resolve_storage_engine_name(hton);
my_error(ER_FEATURE_DISABLED,MYF(0),engine_name,engine_name);
}
return NULL;
}
(void) RUN_HOOK(transaction, after_rollback, (thd, FALSE));
switch (database_type) {
case DB_TYPE_MRG_ISAM:
return ha_resolve_by_legacy_type(thd, DB_TYPE_MRG_MYISAM);
default:
break;
}
return ha_default_handlerton(thd);
} /* ha_checktype */
handler *get_new_handler(TABLE_SHARE *share, MEM_ROOT *alloc,
handlerton *db_type)
{
handler *file;
DBUG_ENTER("get_new_handler");
DBUG_PRINT("enter", ("alloc: 0x%lx", (long) alloc));
if (db_type && db_type->state == SHOW_OPTION_YES && db_type->create)
{
if ((file= db_type->create(db_type, share, alloc)))
file->init();
DBUG_RETURN(file);
}
/*
Try the default table type
Here the call to current_thd() is ok as we call this function a lot of
times but we enter this branch very seldom.
*/
DBUG_RETURN(get_new_handler(share, alloc, ha_default_handlerton(current_thd)));
}
#ifdef WITH_PARTITION_STORAGE_ENGINE
handler *get_ha_partition(partition_info *part_info)
{
ha_partition *partition;
DBUG_ENTER("get_ha_partition");
if ((partition= new ha_partition(partition_hton, part_info)))
{
if (partition->initialize_partition(current_thd->mem_root))
{
delete partition;
partition= 0;
}
else
partition->init();
}
else
{
my_error(ER_OUTOFMEMORY, MYF(0), static_cast<int>(sizeof(ha_partition)));
}
DBUG_RETURN(((handler*) partition));
}
#endif
static const char **handler_errmsgs;
C_MODE_START
static const char **get_handler_errmsgs()
{
return handler_errmsgs;
}
C_MODE_END
/**
Register handler error messages for use with my_error().
@retval
0 OK
@retval
!=0 Error
*/
int ha_init_errors(void)
{
#define SETMSG(nr, msg) handler_errmsgs[(nr) - HA_ERR_FIRST]= (msg)
/* Allocate a pointer array for the error message strings. */
/* Zerofill it to avoid uninitialized gaps. */
if (! (handler_errmsgs= (const char**) my_malloc(HA_ERR_ERRORS * sizeof(char*),
MYF(MY_WME | MY_ZEROFILL))))
return 1;
/* Set the dedicated error messages. */
SETMSG(HA_ERR_KEY_NOT_FOUND, ER_DEFAULT(ER_KEY_NOT_FOUND));
SETMSG(HA_ERR_FOUND_DUPP_KEY, ER_DEFAULT(ER_DUP_KEY));
SETMSG(HA_ERR_RECORD_CHANGED, "Update wich is recoverable");
SETMSG(HA_ERR_WRONG_INDEX, "Wrong index given to function");
SETMSG(HA_ERR_CRASHED, ER_DEFAULT(ER_NOT_KEYFILE));
SETMSG(HA_ERR_WRONG_IN_RECORD, ER_DEFAULT(ER_CRASHED_ON_USAGE));
SETMSG(HA_ERR_OUT_OF_MEM, "Table handler out of memory");
SETMSG(HA_ERR_NOT_A_TABLE, "Incorrect file format '%.64s'");
SETMSG(HA_ERR_WRONG_COMMAND, "Command not supported");
SETMSG(HA_ERR_OLD_FILE, ER_DEFAULT(ER_OLD_KEYFILE));
SETMSG(HA_ERR_NO_ACTIVE_RECORD, "No record read in update");
SETMSG(HA_ERR_RECORD_DELETED, "Intern record deleted");
SETMSG(HA_ERR_RECORD_FILE_FULL, ER_DEFAULT(ER_RECORD_FILE_FULL));
SETMSG(HA_ERR_INDEX_FILE_FULL, "No more room in index file '%.64s'");
SETMSG(HA_ERR_END_OF_FILE, "End in next/prev/first/last");
SETMSG(HA_ERR_UNSUPPORTED, ER_DEFAULT(ER_ILLEGAL_HA));
SETMSG(HA_ERR_TO_BIG_ROW, "Too big row");
SETMSG(HA_WRONG_CREATE_OPTION, "Wrong create option");
SETMSG(HA_ERR_FOUND_DUPP_UNIQUE, ER_DEFAULT(ER_DUP_UNIQUE));
SETMSG(HA_ERR_UNKNOWN_CHARSET, "Can't open charset");
SETMSG(HA_ERR_WRONG_MRG_TABLE_DEF, ER_DEFAULT(ER_WRONG_MRG_TABLE));
SETMSG(HA_ERR_CRASHED_ON_REPAIR, ER_DEFAULT(ER_CRASHED_ON_REPAIR));
SETMSG(HA_ERR_CRASHED_ON_USAGE, ER_DEFAULT(ER_CRASHED_ON_USAGE));
SETMSG(HA_ERR_LOCK_WAIT_TIMEOUT, ER_DEFAULT(ER_LOCK_WAIT_TIMEOUT));
SETMSG(HA_ERR_LOCK_TABLE_FULL, ER_DEFAULT(ER_LOCK_TABLE_FULL));
SETMSG(HA_ERR_READ_ONLY_TRANSACTION, ER_DEFAULT(ER_READ_ONLY_TRANSACTION));
SETMSG(HA_ERR_LOCK_DEADLOCK, ER_DEFAULT(ER_LOCK_DEADLOCK));
SETMSG(HA_ERR_CANNOT_ADD_FOREIGN, ER_DEFAULT(ER_CANNOT_ADD_FOREIGN));
SETMSG(HA_ERR_NO_REFERENCED_ROW, ER_DEFAULT(ER_NO_REFERENCED_ROW_2));
SETMSG(HA_ERR_ROW_IS_REFERENCED, ER_DEFAULT(ER_ROW_IS_REFERENCED_2));
SETMSG(HA_ERR_NO_SAVEPOINT, "No savepoint with that name");
SETMSG(HA_ERR_NON_UNIQUE_BLOCK_SIZE, "Non unique key block size");
SETMSG(HA_ERR_NO_SUCH_TABLE, "No such table: '%.64s'");
SETMSG(HA_ERR_TABLE_EXIST, ER_DEFAULT(ER_TABLE_EXISTS_ERROR));
SETMSG(HA_ERR_NO_CONNECTION, "Could not connect to storage engine");
SETMSG(HA_ERR_TABLE_DEF_CHANGED, ER_DEFAULT(ER_TABLE_DEF_CHANGED));
SETMSG(HA_ERR_FOREIGN_DUPLICATE_KEY, "FK constraint would lead to duplicate key");
SETMSG(HA_ERR_TABLE_NEEDS_UPGRADE, ER_DEFAULT(ER_TABLE_NEEDS_UPGRADE));
SETMSG(HA_ERR_TABLE_READONLY, ER_DEFAULT(ER_OPEN_AS_READONLY));
SETMSG(HA_ERR_AUTOINC_READ_FAILED, ER_DEFAULT(ER_AUTOINC_READ_FAILED));
SETMSG(HA_ERR_AUTOINC_ERANGE, ER_DEFAULT(ER_WARN_DATA_OUT_OF_RANGE));
SETMSG(HA_ERR_TOO_MANY_CONCURRENT_TRXS, ER_DEFAULT(ER_TOO_MANY_CONCURRENT_TRXS));
SETMSG(HA_ERR_INDEX_COL_TOO_LONG, ER_DEFAULT(ER_INDEX_COLUMN_TOO_LONG));
SETMSG(HA_ERR_INDEX_CORRUPT, ER_DEFAULT(ER_INDEX_CORRUPT));
SETMSG(HA_FTS_INVALID_DOCID, "Invalid InnoDB FTS Doc ID");
SETMSG(HA_ERR_TABLE_IN_FK_CHECK, ER_DEFAULT(ER_TABLE_IN_FK_CHECK));
SETMSG(HA_ERR_DISK_FULL, ER_DEFAULT(ER_DISK_FULL));
/* Register the error messages for use with my_error(). */
return my_error_register(get_handler_errmsgs, HA_ERR_FIRST, HA_ERR_LAST);
}
/**
Unregister handler error messages.
@retval
0 OK
@retval
!=0 Error
*/
static int ha_finish_errors(void)
{
const char **errmsgs;
/* Allocate a pointer array for the error message strings. */
if (! (errmsgs= my_error_unregister(HA_ERR_FIRST, HA_ERR_LAST)))
return 1;
my_free(errmsgs);
return 0;
}
int ha_finalize_handlerton(st_plugin_int *plugin)
{
handlerton *hton= (handlerton *)plugin->data;
DBUG_ENTER("ha_finalize_handlerton");
/* hton can be NULL here, if ha_initialize_handlerton() failed. */
if (!hton)
goto end;
switch (hton->state) {
case SHOW_OPTION_NO:
case SHOW_OPTION_DISABLED:
break;
case SHOW_OPTION_YES:
if (installed_htons[hton->db_type] == hton)
installed_htons[hton->db_type]= NULL;
break;
};
if (hton->panic)
hton->panic(hton, HA_PANIC_CLOSE);
if (plugin->plugin->deinit)
{
/*
Today we have no defined/special behavior for uninstalling
engine plugins.
*/
DBUG_PRINT("info", ("Deinitializing plugin: '%s'", plugin->name.str));
if (plugin->plugin->deinit(NULL))
{
DBUG_PRINT("warning", ("Plugin '%s' deinit function returned error.",
plugin->name.str));
}
}
/*
In case a plugin is uninstalled and re-installed later, it should
reuse an array slot. Otherwise the number of uninstall/install
cycles would be limited.
*/
if (hton->slot != HA_SLOT_UNDEF)
{
/* Make sure we are not unpluging another plugin */
DBUG_ASSERT(hton2plugin[hton->slot] == plugin);
DBUG_ASSERT(hton->slot < MAX_HA);
hton2plugin[hton->slot]= NULL;
}
my_free(hton);
end:
DBUG_RETURN(0);
}
int ha_initialize_handlerton(st_plugin_int *plugin)
{
handlerton *hton;
DBUG_ENTER("ha_initialize_handlerton");
DBUG_PRINT("plugin", ("initialize plugin: '%s'", plugin->name.str));
hton= (handlerton *)my_malloc(sizeof(handlerton),
MYF(MY_WME | MY_ZEROFILL));
if (hton == NULL)
{
sql_print_error("Unable to allocate memory for plugin '%s' handlerton.",
plugin->name.str);
goto err_no_hton_memory;
}
hton->slot= HA_SLOT_UNDEF;
/* Historical Requirement */
plugin->data= hton; // shortcut for the future
if (plugin->plugin->init && plugin->plugin->init(hton))
{
sql_print_error("Plugin '%s' init function returned error.",
plugin->name.str);
goto err;
}
/*
the switch below and hton->state should be removed when
command-line options for plugins will be implemented
*/
switch (hton->state) {
case SHOW_OPTION_NO:
break;
case SHOW_OPTION_YES:
{
uint tmp;
ulong fslot;
/* now check the db_type for conflict */
if (hton->db_type <= DB_TYPE_UNKNOWN ||
hton->db_type >= DB_TYPE_DEFAULT ||
installed_htons[hton->db_type])
{
int idx= (int) DB_TYPE_FIRST_DYNAMIC;
while (idx < (int) DB_TYPE_DEFAULT && installed_htons[idx])
idx++;
if (idx == (int) DB_TYPE_DEFAULT)
{
sql_print_warning("Too many storage engines!");
goto err_deinit;
}
if (hton->db_type != DB_TYPE_UNKNOWN)
sql_print_warning("Storage engine '%s' has conflicting typecode. "
"Assigning value %d.", plugin->plugin->name, idx);
hton->db_type= (enum legacy_db_type) idx;
}
/*
In case a plugin is uninstalled and re-installed later, it should
reuse an array slot. Otherwise the number of uninstall/install
cycles would be limited. So look for a free slot.
*/
DBUG_PRINT("plugin", ("total_ha: %lu", total_ha));
for (fslot= 0; fslot < total_ha; fslot++)
{
if (!hton2plugin[fslot])
break;
}
if (fslot < total_ha)
hton->slot= fslot;
else
{
if (total_ha >= MAX_HA)
{
sql_print_error("Too many plugins loaded. Limit is %lu. "
"Failed on '%s'", (ulong) MAX_HA, plugin->name.str);
goto err_deinit;
}
hton->slot= total_ha++;
}
installed_htons[hton->db_type]= hton;
tmp= hton->savepoint_offset;
hton->savepoint_offset= savepoint_alloc_size;
savepoint_alloc_size+= tmp;
hton2plugin[hton->slot]=plugin;
if (hton->prepare)
total_ha_2pc++;
break;
}
/* fall through */
default:
hton->state= SHOW_OPTION_DISABLED;
break;
}
/*
This is entirely for legacy. We will create a new "disk based" hton and a
"memory" hton which will be configurable longterm. We should be able to
remove partition and myisammrg.
*/
switch (hton->db_type) {
case DB_TYPE_HEAP:
heap_hton= hton;
break;
case DB_TYPE_MYISAM:
myisam_hton= hton;
break;
case DB_TYPE_PARTITION_DB:
partition_hton= hton;
break;
default:
break;
};
DBUG_RETURN(0);
err_deinit:
/*
Let plugin do its inner deinitialization as plugin->init()
was successfully called before.
*/
if (plugin->plugin->deinit)
(void) plugin->plugin->deinit(NULL);
err:
my_free(hton);
err_no_hton_memory:
plugin->data= NULL;
DBUG_RETURN(1);
}
int ha_init()
{
int error= 0;
DBUG_ENTER("ha_init");
DBUG_ASSERT(total_ha < MAX_HA);
/*
Check if there is a transaction-capable storage engine besides the
binary log (which is considered a transaction-capable storage engine in
counting total_ha)
*/
opt_using_transactions= total_ha>(ulong)opt_bin_log;
savepoint_alloc_size+= sizeof(SAVEPOINT);
DBUG_RETURN(error);
}
int ha_end()
{
int error= 0;
DBUG_ENTER("ha_end");
/*
This should be eventualy based on the graceful shutdown flag.
So if flag is equal to HA_PANIC_CLOSE, the deallocate
the errors.
*/
if (ha_finish_errors())
error= 1;
DBUG_RETURN(error);
}
static my_bool dropdb_handlerton(THD *unused1, plugin_ref plugin,
void *path)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->drop_database)
hton->drop_database(hton, (char *)path);
return FALSE;
}
void ha_drop_database(char* path)
{
plugin_foreach(NULL, dropdb_handlerton, MYSQL_STORAGE_ENGINE_PLUGIN, path);
}
static my_bool checkpoint_state_handlerton(THD *unused1, plugin_ref plugin,
void *disable)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->checkpoint_state)
hton->checkpoint_state(hton, (int) *(bool*) disable);
return FALSE;
}
void ha_checkpoint_state(bool disable)
{
plugin_foreach(NULL, checkpoint_state_handlerton, MYSQL_STORAGE_ENGINE_PLUGIN, &disable);
}
struct st_commit_checkpoint_request {
void *cookie;
void (*pre_hook)(void *);
};
static my_bool commit_checkpoint_request_handlerton(THD *unused1, plugin_ref plugin,
void *data)
{
st_commit_checkpoint_request *st= (st_commit_checkpoint_request *)data;
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->commit_checkpoint_request)
{
void *cookie= st->cookie;
if (st->pre_hook)
(*st->pre_hook)(cookie);
(*hton->commit_checkpoint_request)(hton, cookie);
}
return FALSE;
}
/*
Invoke commit_checkpoint_request() in all storage engines that implement it.
If pre_hook is non-NULL, the hook will be called prior to each invocation.
*/
void
ha_commit_checkpoint_request(void *cookie, void (*pre_hook)(void *))
{
st_commit_checkpoint_request st;
st.cookie= cookie;
st.pre_hook= pre_hook;
plugin_foreach(NULL, commit_checkpoint_request_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &st);
}
static my_bool closecon_handlerton(THD *thd, plugin_ref plugin,
void *unused)
{
handlerton *hton= plugin_data(plugin, handlerton *);
/*
there's no need to rollback here as all transactions must
be rolled back already
*/
if (hton->state == SHOW_OPTION_YES && thd_get_ha_data(thd, hton))
{
if (hton->close_connection)
hton->close_connection(hton, thd);
/* make sure ha_data is reset and ha_data_lock is released */
thd_set_ha_data(thd, hton, NULL);
}
return FALSE;
}
/**
@note
don't bother to rollback here, it's done already
*/
void ha_close_connection(THD* thd)
{
plugin_foreach(thd, closecon_handlerton, MYSQL_STORAGE_ENGINE_PLUGIN, 0);
}
static my_bool kill_handlerton(THD *thd, plugin_ref plugin,
void *level)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->kill_query &&
thd_get_ha_data(thd, hton))
hton->kill_query(hton, thd, *(enum thd_kill_levels *) level);
return FALSE;
}
void ha_kill_query(THD* thd, enum thd_kill_levels level)
{
DBUG_ENTER("ha_kill_query");
plugin_foreach(thd, kill_handlerton, MYSQL_STORAGE_ENGINE_PLUGIN, &level);
DBUG_VOID_RETURN;
}
/* ========================================================================
======================= TRANSACTIONS ===================================*/
/**
Transaction handling in the server
==================================
In each client connection, MySQL maintains two transactional
states:
- a statement transaction,
- a standard, also called normal transaction.
Historical note
---------------
"Statement transaction" is a non-standard term that comes
from the times when MySQL supported BerkeleyDB storage engine.
First of all, it should be said that in BerkeleyDB auto-commit
mode auto-commits operations that are atomic to the storage
engine itself, such as a write of a record, and are too
high-granular to be atomic from the application perspective
(MySQL). One SQL statement could involve many BerkeleyDB
auto-committed operations and thus BerkeleyDB auto-commit was of
little use to MySQL.
Secondly, instead of SQL standard savepoints, BerkeleyDB
provided the concept of "nested transactions". In a nutshell,
transactions could be arbitrarily nested, but when the parent
transaction was committed or aborted, all its child (nested)
transactions were handled committed or aborted as well.
Commit of a nested transaction, in turn, made its changes
visible, but not durable: it destroyed the nested transaction,
all its changes would become available to the parent and
currently active nested transactions of this parent.
So the mechanism of nested transactions was employed to
provide "all or nothing" guarantee of SQL statements
required by the standard.
A nested transaction would be created at start of each SQL
statement, and destroyed (committed or aborted) at statement
end. Such nested transaction was internally referred to as
a "statement transaction" and gave birth to the term.
(Historical note ends)
Since then a statement transaction is started for each statement
that accesses transactional tables or uses the binary log. If
the statement succeeds, the statement transaction is committed.
If the statement fails, the transaction is rolled back. Commits
of statement transactions are not durable -- each such
transaction is nested in the normal transaction, and if the
normal transaction is rolled back, the effects of all enclosed
statement transactions are undone as well. Technically,
a statement transaction can be viewed as a savepoint which is
maintained automatically in order to make effects of one
statement atomic.
The normal transaction is started by the user and is ended
usually upon a user request as well. The normal transaction
encloses transactions of all statements issued between
its beginning and its end.
In autocommit mode, the normal transaction is equivalent
to the statement transaction.
Since MySQL supports PSEA (pluggable storage engine
architecture), more than one transactional engine can be
active at a time. Hence transactions, from the server
point of view, are always distributed. In particular,
transactional state is maintained independently for each
engine. In order to commit a transaction the two phase
commit protocol is employed.
Not all statements are executed in context of a transaction.
Administrative and status information statements do not modify
engine data, and thus do not start a statement transaction and
also have no effect on the normal transaction. Examples of such
statements are SHOW STATUS and RESET SLAVE.
Similarly DDL statements are not transactional,
and therefore a transaction is [almost] never started for a DDL
statement. The difference between a DDL statement and a purely
administrative statement though is that a DDL statement always
commits the current transaction before proceeding, if there is
any.
At last, SQL statements that work with non-transactional
engines also have no effect on the transaction state of the
connection. Even though they are written to the binary log,
and the binary log is, overall, transactional, the writes
are done in "write-through" mode, directly to the binlog
file, followed with a OS cache sync, in other words,
bypassing the binlog undo log (translog).
They do not commit the current normal transaction.
A failure of a statement that uses non-transactional tables
would cause a rollback of the statement transaction, but
in case there no non-transactional tables are used,
no statement transaction is started.
Data layout
-----------
The server stores its transaction-related data in
thd->transaction. This structure has two members of type
THD_TRANS. These members correspond to the statement and
normal transactions respectively:
- thd->transaction.stmt contains a list of engines
that are participating in the given statement
- thd->transaction.all contains a list of engines that
have participated in any of the statement transactions started
within the context of the normal transaction.
Each element of the list contains a pointer to the storage
engine, engine-specific transactional data, and engine-specific
transaction flags.
In autocommit mode thd->transaction.all is empty.
Instead, data of thd->transaction.stmt is
used to commit/rollback the normal transaction.
The list of registered engines has a few important properties:
- no engine is registered in the list twice
- engines are present in the list a reverse temporal order --
new participants are always added to the beginning of the list.
Transaction life cycle
----------------------
When a new connection is established, thd->transaction
members are initialized to an empty state.
If a statement uses any tables, all affected engines
are registered in the statement engine list. In
non-autocommit mode, the same engines are registered in
the normal transaction list.
At the end of the statement, the server issues a commit
or a roll back for all engines in the statement list.
At this point transaction flags of an engine, if any, are
propagated from the statement list to the list of the normal
transaction.
When commit/rollback is finished, the statement list is
cleared. It will be filled in again by the next statement,
and emptied again at the next statement's end.
The normal transaction is committed in a similar way
(by going over all engines in thd->transaction.all list)
but at different times:
- upon COMMIT SQL statement is issued by the user
- implicitly, by the server, at the beginning of a DDL statement
or SET AUTOCOMMIT={0|1} statement.
The normal transaction can be rolled back as well:
- if the user has requested so, by issuing ROLLBACK SQL
statement
- if one of the storage engines requested a rollback
by setting thd->transaction_rollback_request. This may
happen in case, e.g., when the transaction in the engine was
chosen a victim of the internal deadlock resolution algorithm
and rolled back internally. When such a situation happens, there
is little the server can do and the only option is to rollback
transactions in all other participating engines. In this case
the rollback is accompanied by an error sent to the user.
As follows from the use cases above, the normal transaction
is never committed when there is an outstanding statement
transaction. In most cases there is no conflict, since
commits of the normal transaction are issued by a stand-alone
administrative or DDL statement, thus no outstanding statement
transaction of the previous statement exists. Besides,
all statements that manipulate with the normal transaction
are prohibited in stored functions and triggers, therefore
no conflicting situation can occur in a sub-statement either.
The remaining rare cases when the server explicitly has
to commit the statement transaction prior to committing the normal
one cover error-handling scenarios (see for example
SQLCOM_LOCK_TABLES).
When committing a statement or a normal transaction, the server
either uses the two-phase commit protocol, or issues a commit
in each engine independently. The two-phase commit protocol
is used only if:
- all participating engines support two-phase commit (provide
handlerton::prepare PSEA API call) and
- transactions in at least two engines modify data (i.e. are
not read-only).
Note that the two phase commit is used for
statement transactions, even though they are not durable anyway.
This is done to ensure logical consistency of data in a multiple-
engine transaction.
For example, imagine that some day MySQL supports unique
constraint checks deferred till the end of statement. In such
case a commit in one of the engines may yield ER_DUP_KEY,
and MySQL should be able to gracefully abort statement
transactions of other participants.
After the normal transaction has been committed,
thd->transaction.all list is cleared.
When a connection is closed, the current normal transaction, if
any, is rolled back.
Roles and responsibilities
--------------------------
The server has no way to know that an engine participates in
the statement and a transaction has been started
in it unless the engine says so. Thus, in order to be
a part of a transaction, the engine must "register" itself.
This is done by invoking trans_register_ha() server call.
Normally the engine registers itself whenever handler::external_lock()
is called. trans_register_ha() can be invoked many times: if
an engine is already registered, the call does nothing.
In case autocommit is not set, the engine must register itself
twice -- both in the statement list and in the normal transaction
list.
In which list to register is a parameter of trans_register_ha().
Note, that although the registration interface in itself is
fairly clear, the current usage practice often leads to undesired
effects. E.g. since a call to trans_register_ha() in most engines
is embedded into implementation of handler::external_lock(), some
DDL statements start a transaction (at least from the server
point of view) even though they are not expected to. E.g.
CREATE TABLE does not start a transaction, since
handler::external_lock() is never called during CREATE TABLE. But
CREATE TABLE ... SELECT does, since handler::external_lock() is
called for the table that is being selected from. This has no
practical effects currently, but must be kept in mind
nevertheless.
Once an engine is registered, the server will do the rest
of the work.
During statement execution, whenever any of data-modifying
PSEA API methods is used, e.g. handler::write_row() or
handler::update_row(), the read-write flag is raised in the
statement transaction for the involved engine.
Currently All PSEA calls are "traced", and the data can not be
changed in a way other than issuing a PSEA call. Important:
unless this invariant is preserved the server will not know that
a transaction in a given engine is read-write and will not
involve the two-phase commit protocol!
At the end of a statement, server call trans_commit_stmt is
invoked. This call in turn invokes handlerton::prepare()
for every involved engine. Prepare is followed by a call
to handlerton::commit_one_phase() If a one-phase commit
will suffice, handlerton::prepare() is not invoked and
the server only calls handlerton::commit_one_phase().
At statement commit, the statement-related read-write
engine flag is propagated to the corresponding flag in the
normal transaction. When the commit is complete, the list
of registered engines is cleared.
Rollback is handled in a similar fashion.
Additional notes on DDL and the normal transaction.
---------------------------------------------------
DDLs and operations with non-transactional engines
do not "register" in thd->transaction lists, and thus do not
modify the transaction state. Besides, each DDL in
MySQL is prefixed with an implicit normal transaction commit
(a call to trans_commit_implicit()), and thus leaves nothing
to modify.
However, as it has been pointed out with CREATE TABLE .. SELECT,
some DDL statements can start a *new* transaction.
Behaviour of the server in this case is currently badly
defined.
DDL statements use a form of "semantic" logging
to maintain atomicity: if CREATE TABLE .. SELECT failed,
the newly created table is deleted.
In addition, some DDL statements issue interim transaction
commits: e.g. ALTER TABLE issues a commit after data is copied
from the original table to the internal temporary table. Other
statements, e.g. CREATE TABLE ... SELECT do not always commit
after itself.
And finally there is a group of DDL statements such as
RENAME/DROP TABLE that doesn't start a new transaction
and doesn't commit.
This diversity makes it hard to say what will happen if
by chance a stored function is invoked during a DDL --
whether any modifications it makes will be committed or not
is not clear. Fortunately, SQL grammar of few DDLs allows
invocation of a stored function.
A consistent behaviour is perhaps to always commit the normal
transaction after all DDLs, just like the statement transaction
is always committed at the end of all statements.
*/
/**
Register a storage engine for a transaction.
Every storage engine MUST call this function when it starts
a transaction or a statement (that is it must be called both for the
"beginning of transaction" and "beginning of statement").
Only storage engines registered for the transaction/statement
will know when to commit/rollback it.
@note
trans_register_ha is idempotent - storage engine may register many
times per transaction.
*/
void trans_register_ha(THD *thd, bool all, handlerton *ht_arg)
{
THD_TRANS *trans;
Ha_trx_info *ha_info;
DBUG_ENTER("trans_register_ha");
DBUG_PRINT("enter",("%s", all ? "all" : "stmt"));
if (all)
{
trans= &thd->transaction.all;
thd->server_status|= SERVER_STATUS_IN_TRANS;
if (thd->tx_read_only)
thd->server_status|= SERVER_STATUS_IN_TRANS_READONLY;
DBUG_PRINT("info", ("setting SERVER_STATUS_IN_TRANS"));
}
else
trans= &thd->transaction.stmt;
ha_info= thd->ha_data[ht_arg->slot].ha_info + (all ? 1 : 0);
if (ha_info->is_started())
DBUG_VOID_RETURN; /* already registered, return */
ha_info->register_ha(trans, ht_arg);
trans->no_2pc|=(ht_arg->prepare==0);
if (thd->transaction.xid_state.xid.is_null())
thd->transaction.xid_state.xid.set(thd->query_id);
DBUG_VOID_RETURN;
}
/**
@retval
0 ok
@retval
1 error, transaction was rolled back
*/
int ha_prepare(THD *thd)
{
int error=0, all=1;
THD_TRANS *trans=all ? &thd->transaction.all : &thd->transaction.stmt;
Ha_trx_info *ha_info= trans->ha_list;
DBUG_ENTER("ha_prepare");
if (ha_info)
{
for (; ha_info; ha_info= ha_info->next())
{
int err;
handlerton *ht= ha_info->ht();
status_var_increment(thd->status_var.ha_prepare_count);
if (ht->prepare)
{
if ((err= ht->prepare(ht, thd, all)))
{
my_error(ER_ERROR_DURING_COMMIT, MYF(0), err);
ha_rollback_trans(thd, all);
error=1;
break;
}
}
else
{
push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN,
ER_ILLEGAL_HA, ER(ER_ILLEGAL_HA),
ha_resolve_storage_engine_name(ht));
}
}
}
DBUG_RETURN(error);
}
/**
Check if we can skip the two-phase commit.
A helper function to evaluate if two-phase commit is mandatory.
As a side effect, propagates the read-only/read-write flags
of the statement transaction to its enclosing normal transaction.
If we have at least two engines with read-write changes we must
run a two-phase commit. Otherwise we can run several independent
commits as the only transactional engine has read-write changes
and others are read-only.
@retval 0 All engines are read-only.
@retval 1 We have the only engine with read-write changes.
@retval >1 More than one engine have read-write changes.
Note: return value might NOT be the exact number of
engines with read-write changes.
*/
static
uint
ha_check_and_coalesce_trx_read_only(THD *thd, Ha_trx_info *ha_list,
bool all)
{
/* The number of storage engines that have actual changes. */
unsigned rw_ha_count= 0;
Ha_trx_info *ha_info;
for (ha_info= ha_list; ha_info; ha_info= ha_info->next())
{
if (ha_info->is_trx_read_write())
++rw_ha_count;
if (! all)
{
Ha_trx_info *ha_info_all= &thd->ha_data[ha_info->ht()->slot].ha_info[1];
DBUG_ASSERT(ha_info != ha_info_all);
/*
Merge read-only/read-write information about statement
transaction to its enclosing normal transaction. Do this
only if in a real transaction -- that is, if we know
that ha_info_all is registered in thd->transaction.all.
Since otherwise we only clutter the normal transaction flags.
*/
if (ha_info_all->is_started()) /* FALSE if autocommit. */
ha_info_all->coalesce_trx_with(ha_info);
}
else if (rw_ha_count > 1)
{
/*
It is a normal transaction, so we don't need to merge read/write
information up, and the need for two-phase commit has been
already established. Break the loop prematurely.
*/
break;
}
}
return rw_ha_count;
}
/**
@retval
0 ok
@retval
1 transaction was rolled back
@retval
2 error during commit, data may be inconsistent
@todo
Since we don't support nested statement transactions in 5.0,
we can't commit or rollback stmt transactions while we are inside
stored functions or triggers. So we simply do nothing now.
TODO: This should be fixed in later ( >= 5.1) releases.
*/
int ha_commit_trans(THD *thd, bool all)
{
int error= 0, cookie;
/*
'all' means that this is either an explicit commit issued by
user, or an implicit commit issued by a DDL.
*/
THD_TRANS *trans= all ? &thd->transaction.all : &thd->transaction.stmt;
/*
"real" is a nick name for a transaction for which a commit will
make persistent changes. E.g. a 'stmt' transaction inside a 'all'
transation is not 'real': even though it's possible to commit it,
the changes are not durable as they might be rolled back if the
enclosing 'all' transaction is rolled back.
*/
bool is_real_trans= all || thd->transaction.all.ha_list == 0;
Ha_trx_info *ha_info= trans->ha_list;
bool need_prepare_ordered, need_commit_ordered;
my_xid xid;
DBUG_ENTER("ha_commit_trans");
/* Just a random warning to test warnings pushed during autocommit. */
DBUG_EXECUTE_IF("warn_during_ha_commit_trans",
push_warning(thd, Sql_condition::WARN_LEVEL_WARN,
ER_WARNING_NOT_COMPLETE_ROLLBACK,
ER(ER_WARNING_NOT_COMPLETE_ROLLBACK)););
DBUG_PRINT("info",
("all: %d thd->in_sub_stmt: %d ha_info: %p is_real_trans: %d",
all, thd->in_sub_stmt, ha_info, is_real_trans));
/*
We must not commit the normal transaction if a statement
transaction is pending. Otherwise statement transaction
flags will not get propagated to its normal transaction's
counterpart.
*/
DBUG_ASSERT(thd->transaction.stmt.ha_list == NULL ||
trans == &thd->transaction.stmt);
if (thd->in_sub_stmt)
{
DBUG_ASSERT(0);
/*
Since we don't support nested statement transactions in 5.0,
we can't commit or rollback stmt transactions while we are inside
stored functions or triggers. So we simply do nothing now.
TODO: This should be fixed in later ( >= 5.1) releases.
*/
if (!all)
DBUG_RETURN(0);
/*
We assume that all statements which commit or rollback main transaction
are prohibited inside of stored functions or triggers. So they should
bail out with error even before ha_commit_trans() call. To be 100% safe
let us throw error in non-debug builds.
*/
my_error(ER_COMMIT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0));
DBUG_RETURN(2);
}
#ifdef WITH_ARIA_STORAGE_ENGINE
ha_maria::implicit_commit(thd, TRUE);
#endif
if (!ha_info)
{
/*
Free resources and perform other cleanup even for 'empty' transactions.
*/
if (is_real_trans)
thd->transaction.cleanup();
DBUG_RETURN(0);
}
DBUG_EXECUTE_IF("crash_commit_before", DBUG_SUICIDE(););
/* Close all cursors that can not survive COMMIT */
if (is_real_trans) /* not a statement commit */
thd->stmt_map.close_transient_cursors();
uint rw_ha_count= ha_check_and_coalesce_trx_read_only(thd, ha_info, all);
/* rw_trans is TRUE when we in a transaction changing data */
bool rw_trans= is_real_trans && (rw_ha_count > 0);
MDL_request mdl_request;
if (rw_trans)
{
/*
Acquire a metadata lock which will ensure that COMMIT is blocked
by an active FLUSH TABLES WITH READ LOCK (and vice versa:
COMMIT in progress blocks FTWRL).
We allow the owner of FTWRL to COMMIT; we assume that it knows
what it does.
*/
mdl_request.init(MDL_key::COMMIT, "", "", MDL_INTENTION_EXCLUSIVE,
MDL_EXPLICIT);
if (thd->mdl_context.acquire_lock(&mdl_request,
thd->variables.lock_wait_timeout))
{
ha_rollback_trans(thd, all);
DBUG_RETURN(1);
}
DEBUG_SYNC(thd, "ha_commit_trans_after_acquire_commit_lock");
}
if (rw_trans &&
opt_readonly &&
!(thd->security_ctx->master_access & SUPER_ACL) &&
!thd->slave_thread)
{
my_error(ER_OPTION_PREVENTS_STATEMENT, MYF(0), "--read-only");
goto err;
}
if (trans->no_2pc || (rw_ha_count <= 1))
{
error= ha_commit_one_phase(thd, all);
goto done;
}
need_prepare_ordered= FALSE;
need_commit_ordered= FALSE;
xid= thd->transaction.xid_state.xid.get_my_xid();
for (Ha_trx_info *hi= ha_info; hi; hi= hi->next())
{
int err;
handlerton *ht= hi->ht();
/*
Do not call two-phase commit if this particular
transaction is read-only. This allows for simpler
implementation in engines that are always read-only.
*/
if (! hi->is_trx_read_write())
continue;
/*
Sic: we know that prepare() is not NULL since otherwise
trans->no_2pc would have been set.
*/
err= ht->prepare(ht, thd, all);
status_var_increment(thd->status_var.ha_prepare_count);
if (err)
my_error(ER_ERROR_DURING_COMMIT, MYF(0), err);
if (err)
goto err;
need_prepare_ordered|= (ht->prepare_ordered != NULL);
need_commit_ordered|= (ht->commit_ordered != NULL);
}
DEBUG_SYNC(thd, "ha_commit_trans_after_prepare");
DBUG_EXECUTE_IF("crash_commit_after_prepare", DBUG_SUICIDE(););
if (!is_real_trans)
{
error= commit_one_phase_2(thd, all, trans, is_real_trans);
goto done;
}
DEBUG_SYNC(thd, "ha_commit_trans_before_log_and_order");
cookie= tc_log->log_and_order(thd, xid, all, need_prepare_ordered,
need_commit_ordered);
if (!cookie)
goto err;
DEBUG_SYNC(thd, "ha_commit_trans_after_log_and_order");
DBUG_EXECUTE_IF("crash_commit_after_log", DBUG_SUICIDE(););
error= commit_one_phase_2(thd, all, trans, is_real_trans) ? 2 : 0;
DBUG_EXECUTE_IF("crash_commit_before_unlog", DBUG_SUICIDE(););
if (tc_log->unlog(cookie, xid))
{
error= 2; /* Error during commit */
goto end;
}
done:
DBUG_EXECUTE_IF("crash_commit_after", DBUG_SUICIDE(););
RUN_HOOK(transaction, after_commit, (thd, FALSE));
goto end;
/* Come here if error and we need to rollback. */
err:
error= 1; /* Transaction was rolled back */
ha_rollback_trans(thd, all);
end:
if (rw_trans && mdl_request.ticket)
{
/*
We do not always immediately release transactional locks
after ha_commit_trans() (see uses of ha_enable_transaction()),
thus we release the commit blocker lock as soon as it's
not needed.
*/
thd->mdl_context.release_lock(mdl_request.ticket);
}
DBUG_RETURN(error);
}
/**
@note
This function does not care about global read lock. A caller should.
@param[in] all Is set in case of explicit commit
(COMMIT statement), or implicit commit
issued by DDL. Is not set when called
at the end of statement, even if
autocommit=1.
*/
int ha_commit_one_phase(THD *thd, bool all)
{
THD_TRANS *trans=all ? &thd->transaction.all : &thd->transaction.stmt;
/*
"real" is a nick name for a transaction for which a commit will
make persistent changes. E.g. a 'stmt' transaction inside a 'all'
transaction is not 'real': even though it's possible to commit it,
the changes are not durable as they might be rolled back if the
enclosing 'all' transaction is rolled back.
We establish the value of 'is_real_trans' by checking
if it's an explicit COMMIT/BEGIN statement, or implicit
commit issued by DDL (all == TRUE), or if we're running
in autocommit mode (it's only in the autocommit mode
ha_commit_one_phase() can be called with an empty
transaction.all.ha_list, see why in trans_register_ha()).
*/
bool is_real_trans=all || thd->transaction.all.ha_list == 0;
DBUG_ENTER("ha_commit_one_phase");
int res= commit_one_phase_2(thd, all, trans, is_real_trans);
DBUG_RETURN(res);
}
static int
commit_one_phase_2(THD *thd, bool all, THD_TRANS *trans, bool is_real_trans)
{
int error= 0;
Ha_trx_info *ha_info= trans->ha_list, *ha_info_next;
DBUG_ENTER("commit_one_phase_2");
if (ha_info)
{
for (; ha_info; ha_info= ha_info_next)
{
int err;
handlerton *ht= ha_info->ht();
if ((err= ht->commit(ht, thd, all)))
{
my_error(ER_ERROR_DURING_COMMIT, MYF(0), err);
error=1;
}
/* Should this be done only if is_real_trans is set ? */
status_var_increment(thd->status_var.ha_commit_count);
ha_info_next= ha_info->next();
ha_info->reset(); /* keep it conveniently zero-filled */
}
trans->ha_list= 0;
trans->no_2pc=0;
if (all)
{
#ifdef HAVE_QUERY_CACHE
if (thd->transaction.changed_tables)
query_cache.invalidate(thd, thd->transaction.changed_tables);
#endif
}
}
/* Free resources and perform other cleanup even for 'empty' transactions. */
if (is_real_trans)
thd->transaction.cleanup();
DBUG_RETURN(error);
}
int ha_rollback_trans(THD *thd, bool all)
{
int error=0;
THD_TRANS *trans=all ? &thd->transaction.all : &thd->transaction.stmt;
Ha_trx_info *ha_info= trans->ha_list, *ha_info_next;
/*
"real" is a nick name for a transaction for which a commit will
make persistent changes. E.g. a 'stmt' transaction inside a 'all'
transaction is not 'real': even though it's possible to commit it,
the changes are not durable as they might be rolled back if the
enclosing 'all' transaction is rolled back.
We establish the value of 'is_real_trans' by checking
if it's an explicit COMMIT or BEGIN statement, or implicit
commit issued by DDL (in these cases all == TRUE),
or if we're running in autocommit mode (it's only in the autocommit mode
ha_commit_one_phase() is called with an empty
transaction.all.ha_list, see why in trans_register_ha()).
*/
bool is_real_trans=all || thd->transaction.all.ha_list == 0;
DBUG_ENTER("ha_rollback_trans");
/*
We must not rollback the normal transaction if a statement
transaction is pending.
*/
DBUG_ASSERT(thd->transaction.stmt.ha_list == NULL ||
trans == &thd->transaction.stmt);
if (thd->in_sub_stmt)
{
DBUG_ASSERT(0);
/*
If we are inside stored function or trigger we should not commit or
rollback current statement transaction. See comment in ha_commit_trans()
call for more information.
*/
if (!all)
DBUG_RETURN(0);
my_error(ER_COMMIT_NOT_ALLOWED_IN_SF_OR_TRG, MYF(0));
DBUG_RETURN(1);
}
if (ha_info)
{
/* Close all cursors that can not survive ROLLBACK */
if (is_real_trans) /* not a statement commit */
thd->stmt_map.close_transient_cursors();
for (; ha_info; ha_info= ha_info_next)
{
int err;
handlerton *ht= ha_info->ht();
if ((err= ht->rollback(ht, thd, all)))
{ // cannot happen
my_error(ER_ERROR_DURING_ROLLBACK, MYF(0), err);
error=1;
}
status_var_increment(thd->status_var.ha_rollback_count);
ha_info_next= ha_info->next();
ha_info->reset(); /* keep it conveniently zero-filled */
}
trans->ha_list= 0;
trans->no_2pc=0;
if (is_real_trans && thd->transaction_rollback_request &&
thd->transaction.xid_state.xa_state != XA_NOTR)
thd->transaction.xid_state.rm_error= thd->get_stmt_da()->sql_errno();
}
/* Always cleanup. Even if nht==0. There may be savepoints. */
if (is_real_trans)
thd->transaction.cleanup();
if (all)
thd->transaction_rollback_request= FALSE;
/*
If a non-transactional table was updated, warn; don't warn if this is a
slave thread (because when a slave thread executes a ROLLBACK, it has
been read from the binary log, so it's 100% sure and normal to produce
error ER_WARNING_NOT_COMPLETE_ROLLBACK. If we sent the warning to the
slave SQL thread, it would not stop the thread but just be printed in
the error log; but we don't want users to wonder why they have this
message in the error log, so we don't send it.
We don't have to test for thd->killed == KILL_SYSTEM_THREAD as
it doesn't matter if a warning is pushed to a system thread or not:
No one will see it...
*/
if (is_real_trans && thd->transaction.all.modified_non_trans_table &&
!thd->slave_thread && thd->killed < KILL_CONNECTION)
push_warning(thd, Sql_condition::WARN_LEVEL_WARN,
ER_WARNING_NOT_COMPLETE_ROLLBACK,
ER(ER_WARNING_NOT_COMPLETE_ROLLBACK));
(void) RUN_HOOK(transaction, after_rollback, (thd, FALSE));
DBUG_RETURN(error);
}
struct xahton_st {
XID *xid;
int result;
};
static my_bool xacommit_handlerton(THD *unused1, plugin_ref plugin,
void *arg)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->recover)
{
hton->commit_by_xid(hton, ((struct xahton_st *)arg)->xid);
((struct xahton_st *)arg)->result= 0;
}
return FALSE;
}
static my_bool xarollback_handlerton(THD *unused1, plugin_ref plugin,
void *arg)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->recover)
{
hton->rollback_by_xid(hton, ((struct xahton_st *)arg)->xid);
((struct xahton_st *)arg)->result= 0;
}
return FALSE;
}
int ha_commit_or_rollback_by_xid(XID *xid, bool commit)
{
struct xahton_st xaop;
xaop.xid= xid;
xaop.result= 1;
plugin_foreach(NULL, commit ? xacommit_handlerton : xarollback_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &xaop);
return xaop.result;
}
#ifndef DBUG_OFF
/**
@note
This does not need to be multi-byte safe or anything
*/
static char* xid_to_str(char *buf, XID *xid)
{
int i;
char *s=buf;
*s++='\'';
for (i=0; i < xid->gtrid_length+xid->bqual_length; i++)
{
uchar c=(uchar)xid->data[i];
/* is_next_dig is set if next character is a number */
bool is_next_dig= FALSE;
if (i < XIDDATASIZE)
{
char ch= xid->data[i+1];
is_next_dig= (ch >= '0' && ch <='9');
}
if (i == xid->gtrid_length)
{
*s++='\'';
if (xid->bqual_length)
{
*s++='.';
*s++='\'';
}
}
if (c < 32 || c > 126)
{
*s++='\\';
/*
If next character is a number, write current character with
3 octal numbers to ensure that the next number is not seen
as part of the octal number
*/
if (c > 077 || is_next_dig)
*s++=_dig_vec_lower[c >> 6];
if (c > 007 || is_next_dig)
*s++=_dig_vec_lower[(c >> 3) & 7];
*s++=_dig_vec_lower[c & 7];
}
else
{
if (c == '\'' || c == '\\')
*s++='\\';
*s++=c;
}
}
*s++='\'';
*s=0;
return buf;
}
#endif
/**
recover() step of xa.
@note
there are three modes of operation:
- automatic recover after a crash
in this case commit_list != 0, tc_heuristic_recover==0
all xids from commit_list are committed, others are rolled back
- manual (heuristic) recover
in this case commit_list==0, tc_heuristic_recover != 0
DBA has explicitly specified that all prepared transactions should
be committed (or rolled back).
- no recovery (MySQL did not detect a crash)
in this case commit_list==0, tc_heuristic_recover == 0
there should be no prepared transactions in this case.
*/
struct xarecover_st
{
int len, found_foreign_xids, found_my_xids;
XID *list;
HASH *commit_list;
bool dry_run;
};
static my_bool xarecover_handlerton(THD *unused, plugin_ref plugin,
void *arg)
{
handlerton *hton= plugin_data(plugin, handlerton *);
struct xarecover_st *info= (struct xarecover_st *) arg;
int got;
if (hton->state == SHOW_OPTION_YES && hton->recover)
{
while ((got= hton->recover(hton, info->list, info->len)) > 0 )
{
sql_print_information("Found %d prepared transaction(s) in %s",
got, hton_name(hton)->str);
for (int i=0; i < got; i ++)
{
my_xid x=info->list[i].get_my_xid();
if (!x) // not "mine" - that is generated by external TM
{
#ifndef DBUG_OFF
char buf[XIDDATASIZE*4+6]; // see xid_to_str
sql_print_information("ignore xid %s", xid_to_str(buf, info->list+i));
#endif
xid_cache_insert(info->list+i, XA_PREPARED);
info->found_foreign_xids++;
continue;
}
if (info->dry_run)
{
info->found_my_xids++;
continue;
}
// recovery mode
if (info->commit_list ?
my_hash_search(info->commit_list, (uchar *)&x, sizeof(x)) != 0 :
tc_heuristic_recover == TC_HEURISTIC_RECOVER_COMMIT)
{
#ifndef DBUG_OFF
char buf[XIDDATASIZE*4+6]; // see xid_to_str
sql_print_information("commit xid %s", xid_to_str(buf, info->list+i));
#endif
hton->commit_by_xid(hton, info->list+i);
}
else
{
#ifndef DBUG_OFF
char buf[XIDDATASIZE*4+6]; // see xid_to_str
sql_print_information("rollback xid %s",
xid_to_str(buf, info->list+i));
#endif
hton->rollback_by_xid(hton, info->list+i);
}
}
if (got < info->len)
break;
}
}
return FALSE;
}
int ha_recover(HASH *commit_list)
{
struct xarecover_st info;
DBUG_ENTER("ha_recover");
info.found_foreign_xids= info.found_my_xids= 0;
info.commit_list= commit_list;
info.dry_run= (info.commit_list==0 && tc_heuristic_recover==0);
info.list= NULL;
/* commit_list and tc_heuristic_recover cannot be set both */
DBUG_ASSERT(info.commit_list==0 || tc_heuristic_recover==0);
/* if either is set, total_ha_2pc must be set too */
DBUG_ASSERT(info.dry_run || total_ha_2pc>(ulong)opt_bin_log);
if (total_ha_2pc <= (ulong)opt_bin_log)
DBUG_RETURN(0);
if (info.commit_list)
sql_print_information("Starting crash recovery...");
for (info.len= MAX_XID_LIST_SIZE ;
info.list==0 && info.len > MIN_XID_LIST_SIZE; info.len/=2)
{
info.list=(XID *)my_malloc(info.len*sizeof(XID), MYF(0));
}
if (!info.list)
{
sql_print_error(ER(ER_OUTOFMEMORY),
static_cast<int>(info.len*sizeof(XID)));
DBUG_RETURN(1);
}
plugin_foreach(NULL, xarecover_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &info);
my_free(info.list);
if (info.found_foreign_xids)
sql_print_warning("Found %d prepared XA transactions",
info.found_foreign_xids);
if (info.dry_run && info.found_my_xids)
{
sql_print_error("Found %d prepared transactions! It means that mysqld was "
"not shut down properly last time and critical recovery "
"information (last binlog or %s file) was manually deleted "
"after a crash. You have to start mysqld with "
"--tc-heuristic-recover switch to commit or rollback "
"pending transactions.",
info.found_my_xids, opt_tc_log_file);
DBUG_RETURN(1);
}
if (info.commit_list)
sql_print_information("Crash recovery finished.");
DBUG_RETURN(0);
}
/**
return the list of XID's to a client, the same way SHOW commands do.
@note
I didn't find in XA specs that an RM cannot return the same XID twice,
so mysql_xa_recover does not filter XID's to ensure uniqueness.
It can be easily fixed later, if necessary.
*/
bool mysql_xa_recover(THD *thd)
{
List<Item> field_list;
Protocol *protocol= thd->protocol;
int i=0;
XID_STATE *xs;
DBUG_ENTER("mysql_xa_recover");
field_list.push_back(new Item_int("formatID", 0, MY_INT32_NUM_DECIMAL_DIGITS));
field_list.push_back(new Item_int("gtrid_length", 0, MY_INT32_NUM_DECIMAL_DIGITS));
field_list.push_back(new Item_int("bqual_length", 0, MY_INT32_NUM_DECIMAL_DIGITS));
field_list.push_back(new Item_empty_string("data",XIDDATASIZE));
if (protocol->send_result_set_metadata(&field_list,
Protocol::SEND_NUM_ROWS | Protocol::SEND_EOF))
DBUG_RETURN(1);
mysql_mutex_lock(&LOCK_xid_cache);
while ((xs= (XID_STATE*) my_hash_element(&xid_cache, i++)))
{
if (xs->xa_state==XA_PREPARED)
{
protocol->prepare_for_resend();
protocol->store_longlong((longlong)xs->xid.formatID, FALSE);
protocol->store_longlong((longlong)xs->xid.gtrid_length, FALSE);
protocol->store_longlong((longlong)xs->xid.bqual_length, FALSE);
protocol->store(xs->xid.data, xs->xid.gtrid_length+xs->xid.bqual_length,
&my_charset_bin);
if (protocol->write())
{
mysql_mutex_unlock(&LOCK_xid_cache);
DBUG_RETURN(1);
}
}
}
mysql_mutex_unlock(&LOCK_xid_cache);
my_eof(thd);
DBUG_RETURN(0);
}
/*
Called by engine to notify TC that a new commit checkpoint has been reached.
See comments on handlerton method commit_checkpoint_request() for details.
*/
void
commit_checkpoint_notify_ha(handlerton *hton, void *cookie)
{
tc_log->commit_checkpoint_notify(cookie);
}
/**
@details
This function should be called when MySQL sends rows of a SELECT result set
or the EOF mark to the client. It releases a possible adaptive hash index
S-latch held by thd in InnoDB and also releases a possible InnoDB query
FIFO ticket to enter InnoDB. To save CPU time, InnoDB allows a thd to
keep them over several calls of the InnoDB handler interface when a join
is executed. But when we let the control to pass to the client they have
to be released because if the application program uses mysql_use_result(),
it may deadlock on the S-latch if the application on another connection
performs another SQL query. In MySQL-4.1 this is even more important because
there a connection can have several SELECT queries open at the same time.
@param thd the thread handle of the current connection
@return
always 0
*/
int ha_release_temporary_latches(THD *thd)
{
Ha_trx_info *info;
/*
Note that below we assume that only transactional storage engines
may need release_temporary_latches(). If this will ever become false,
we could iterate on thd->open_tables instead (and remove duplicates
as if (!seen[hton->slot]) { seen[hton->slot]=1; ... }).
*/
for (info= thd->transaction.stmt.ha_list; info; info= info->next())
{
handlerton *hton= info->ht();
if (hton && hton->release_temporary_latches)
hton->release_temporary_latches(hton, thd);
}
return 0;
}
int ha_rollback_to_savepoint(THD *thd, SAVEPOINT *sv)
{
int error=0;
THD_TRANS *trans= (thd->in_sub_stmt ? &thd->transaction.stmt :
&thd->transaction.all);
Ha_trx_info *ha_info, *ha_info_next;
DBUG_ENTER("ha_rollback_to_savepoint");
trans->no_2pc=0;
/*
rolling back to savepoint in all storage engines that were part of the
transaction when the savepoint was set
*/
for (ha_info= sv->ha_list; ha_info; ha_info= ha_info->next())
{
int err;
handlerton *ht= ha_info->ht();
DBUG_ASSERT(ht);
DBUG_ASSERT(ht->savepoint_set != 0);
if ((err= ht->savepoint_rollback(ht, thd,
(uchar *)(sv+1)+ht->savepoint_offset)))
{ // cannot happen
my_error(ER_ERROR_DURING_ROLLBACK, MYF(0), err);
error=1;
}
status_var_increment(thd->status_var.ha_savepoint_rollback_count);
trans->no_2pc|= ht->prepare == 0;
}
/*
rolling back the transaction in all storage engines that were not part of
the transaction when the savepoint was set
*/
for (ha_info= trans->ha_list; ha_info != sv->ha_list;
ha_info= ha_info_next)
{
int err;
handlerton *ht= ha_info->ht();
if ((err= ht->rollback(ht, thd, !thd->in_sub_stmt)))
{ // cannot happen
my_error(ER_ERROR_DURING_ROLLBACK, MYF(0), err);
error=1;
}
status_var_increment(thd->status_var.ha_rollback_count);
ha_info_next= ha_info->next();
ha_info->reset(); /* keep it conveniently zero-filled */
}
trans->ha_list= sv->ha_list;
DBUG_RETURN(error);
}
/**
@note
according to the sql standard (ISO/IEC 9075-2:2003)
section "4.33.4 SQL-statements and transaction states",
SAVEPOINT is *not* transaction-initiating SQL-statement
*/
int ha_savepoint(THD *thd, SAVEPOINT *sv)
{
int error=0;
THD_TRANS *trans= (thd->in_sub_stmt ? &thd->transaction.stmt :
&thd->transaction.all);
Ha_trx_info *ha_info= trans->ha_list;
DBUG_ENTER("ha_savepoint");
for (; ha_info; ha_info= ha_info->next())
{
int err;
handlerton *ht= ha_info->ht();
DBUG_ASSERT(ht);
if (! ht->savepoint_set)
{
my_error(ER_CHECK_NOT_IMPLEMENTED, MYF(0), "SAVEPOINT");
error=1;
break;
}
if ((err= ht->savepoint_set(ht, thd, (uchar *)(sv+1)+ht->savepoint_offset)))
{ // cannot happen
my_error(ER_GET_ERRNO, MYF(0), err);
error=1;
}
status_var_increment(thd->status_var.ha_savepoint_count);
}
/*
Remember the list of registered storage engines. All new
engines are prepended to the beginning of the list.
*/
sv->ha_list= trans->ha_list;
DBUG_RETURN(error);
}
int ha_release_savepoint(THD *thd, SAVEPOINT *sv)
{
int error=0;
Ha_trx_info *ha_info= sv->ha_list;
DBUG_ENTER("ha_release_savepoint");
for (; ha_info; ha_info= ha_info->next())
{
int err;
handlerton *ht= ha_info->ht();
/* Savepoint life time is enclosed into transaction life time. */
DBUG_ASSERT(ht);
if (!ht->savepoint_release)
continue;
if ((err= ht->savepoint_release(ht, thd,
(uchar *)(sv+1) + ht->savepoint_offset)))
{ // cannot happen
my_error(ER_GET_ERRNO, MYF(0), err);
error=1;
}
}
DBUG_RETURN(error);
}
static my_bool snapshot_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES &&
hton->start_consistent_snapshot)
{
hton->start_consistent_snapshot(hton, thd);
*((bool *)arg)= false;
}
return FALSE;
}
int ha_start_consistent_snapshot(THD *thd)
{
bool warn= true;
/*
Holding the LOCK_commit_ordered mutex ensures that we get the same
snapshot for all engines (including the binary log). This allows us
among other things to do backups with
START TRANSACTION WITH CONSISTENT SNAPSHOT and
have a consistent binlog position.
*/
mysql_mutex_lock(&LOCK_commit_ordered);
plugin_foreach(thd, snapshot_handlerton, MYSQL_STORAGE_ENGINE_PLUGIN, &warn);
mysql_mutex_unlock(&LOCK_commit_ordered);
/*
Same idea as when one wants to CREATE TABLE in one engine which does not
exist:
*/
if (warn)
push_warning(thd, Sql_condition::WARN_LEVEL_WARN, ER_UNKNOWN_ERROR,
"This MySQL server does not support any "
"consistent-read capable storage engine");
return 0;
}
static my_bool flush_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->flush_logs &&
hton->flush_logs(hton))
return TRUE;
return FALSE;
}
bool ha_flush_logs(handlerton *db_type)
{
if (db_type == NULL)
{
if (plugin_foreach(NULL, flush_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, 0))
return TRUE;
}
else
{
if (db_type->state != SHOW_OPTION_YES ||
(db_type->flush_logs && db_type->flush_logs(db_type)))
return TRUE;
}
return FALSE;
}
/**
@brief make canonical filename
@param[in] file table handler
@param[in] path original path
@param[out] tmp_path buffer for canonized path
@details Lower case db name and table name path parts for
non file based tables when lower_case_table_names
is 2 (store as is, compare in lower case).
Filesystem path prefix (mysql_data_home or tmpdir)
is left intact.
@note tmp_path may be left intact if no conversion was
performed.
@retval canonized path
@todo This may be done more efficiently when table path
gets built. Convert this function to something like
ASSERT_CANONICAL_FILENAME.
*/
const char *get_canonical_filename(handler *file, const char *path,
char *tmp_path)
{
uint i;
if (lower_case_table_names != 2 || (file->ha_table_flags() & HA_FILE_BASED))
return path;
for (i= 0; i <= mysql_tmpdir_list.max; i++)
{
if (is_prefix(path, mysql_tmpdir_list.list[i]))
return path;
}
/* Ensure that table handler get path in lower case */
if (tmp_path != path)
strmov(tmp_path, path);
/*
we only should turn into lowercase database/table part
so start the process after homedirectory
*/
my_casedn_str(files_charset_info, tmp_path + mysql_data_home_len);
return tmp_path;
}
/**
An interceptor to hijack the text of the error message without
setting an error in the thread. We need the text to present it
in the form of a warning to the user.
*/
struct Ha_delete_table_error_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);
char buff[MYSQL_ERRMSG_SIZE];
};
bool
Ha_delete_table_error_handler::
handle_condition(THD *,
uint,
const char*,
Sql_condition::enum_warning_level,
const char* msg,
Sql_condition ** cond_hdl)
{
*cond_hdl= NULL;
/* Grab the error message */
strmake(buff, msg, sizeof(buff)-1);
return TRUE;
}
/** @brief
This should return ENOENT if the file doesn't exists.
The .frm file will be deleted only if we return 0 or ENOENT
*/
int ha_delete_table(THD *thd, handlerton *table_type, const char *path,
const char *db, const char *alias, bool generate_warning)
{
handler *file;
char tmp_path[FN_REFLEN];
int error;
TABLE dummy_table;
TABLE_SHARE dummy_share;
DBUG_ENTER("ha_delete_table");
bzero((char*) &dummy_table, sizeof(dummy_table));
bzero((char*) &dummy_share, sizeof(dummy_share));
dummy_table.s= &dummy_share;
/* DB_TYPE_UNKNOWN is used in ALTER TABLE when renaming only .frm files */
if (table_type == NULL ||
! (file=get_new_handler((TABLE_SHARE*)0, thd->mem_root, table_type)))
DBUG_RETURN(ENOENT);
path= get_canonical_filename(file, path, tmp_path);
if ((error= file->ha_delete_table(path)) && generate_warning)
{
/*
Because file->print_error() use my_error() to generate the error message
we use an internal error handler to intercept it and store the text
in a temporary buffer. Later the message will be presented to user
as a warning.
*/
Ha_delete_table_error_handler ha_delete_table_error_handler;
/* Fill up strucutures that print_error may need */
dummy_share.path.str= (char*) path;
dummy_share.path.length= strlen(path);
dummy_share.db.str= (char*) db;
dummy_share.db.length= strlen(db);
dummy_share.table_name.str= (char*) alias;
dummy_share.table_name.length= strlen(alias);
dummy_table.alias.set(alias, dummy_share.table_name.length,
table_alias_charset);
file->change_table_ptr(&dummy_table, &dummy_share);
thd->push_internal_handler(&ha_delete_table_error_handler);
file->print_error(error, 0);
thd->pop_internal_handler();
/*
XXX: should we convert *all* errors to warnings here?
What if the error is fatal?
*/
push_warning(thd, Sql_condition::WARN_LEVEL_WARN, error,
ha_delete_table_error_handler.buff);
}
delete file;
#ifdef HAVE_PSI_TABLE_INTERFACE
if (likely(error == 0))
{
my_bool temp_table= (my_bool)is_prefix(alias, tmp_file_prefix);
PSI_TABLE_CALL(drop_table_share)(temp_table, db, strlen(db),
alias, strlen(alias));
}
#endif
DBUG_RETURN(error);
}
/****************************************************************************
** General handler functions
****************************************************************************/
handler *handler::clone(const char *name, MEM_ROOT *mem_root)
{
handler *new_handler= get_new_handler(table->s, mem_root, ht);
if (!new_handler)
return NULL;
if (new_handler->set_ha_share_ref(ha_share))
goto err;
/*
Allocate handler->ref here because otherwise ha_open will allocate it
on this->table->mem_root and we will not be able to reclaim that memory
when the clone handler object is destroyed.
*/
if (!(new_handler->ref= (uchar*) alloc_root(mem_root,
ALIGN_SIZE(ref_length)*2)))
goto err;
/*
TODO: Implement a more efficient way to have more than one index open for
the same table instance. The ha_open call is not cachable for clone.
This is not critical as the engines already have the table open
and should be able to use the original instance of the table.
*/
if (new_handler->ha_open(table, name, table->db_stat,
HA_OPEN_IGNORE_IF_LOCKED))
goto err;
return new_handler;
err:
delete new_handler;
return NULL;
}
double handler::keyread_time(uint index, uint ranges, ha_rows rows)
{
/*
It is assumed that we will read trough the whole key range and that all
key blocks are half full (normally things are much better). It is also
assumed that each time we read the next key from the index, the handler
performs a random seek, thus the cost is proportional to the number of
blocks read. This model does not take into account clustered indexes -
engines that support that (e.g. InnoDB) may want to overwrite this method.
The model counts in the time to read index entries from cache.
*/
ulong len= table->key_info[index].key_length + ref_length;
if (index == table->s->primary_key && table->file->primary_key_is_clustered())
len= table->s->stored_rec_length;
double keys_per_block= (stats.block_size/2.0/len+1);
return (rows + keys_per_block-1)/ keys_per_block +
len*rows/(stats.block_size+1)/TIME_FOR_COMPARE ;
}
void **handler::ha_data(THD *thd) const
{
return thd_ha_data(thd, ht);
}
THD *handler::ha_thd(void) const
{
DBUG_ASSERT(!table || !table->in_use || table->in_use == current_thd);
return (table && table->in_use) ? table->in_use : current_thd;
}
void handler::unbind_psi()
{
#ifdef HAVE_PSI_TABLE_INTERFACE
/*
Notify the instrumentation that this table is not owned
by this thread any more.
*/
PSI_TABLE_CALL(unbind_table)(m_psi);
#endif
}
void handler::rebind_psi()
{
#ifdef HAVE_PSI_TABLE_INTERFACE
/*
Notify the instrumentation that this table is now owned
by this thread.
*/
PSI_table_share *share_psi= ha_table_share_psi(table_share);
m_psi= PSI_TABLE_CALL(rebind_table)(share_psi, this, m_psi);
#endif
}
PSI_table_share *handler::ha_table_share_psi(const TABLE_SHARE *share) const
{
return share->m_psi;
}
/** @brief
Open database-handler.
IMPLEMENTATION
Try O_RDONLY if cannot open as O_RDWR
Don't wait for locks if not HA_OPEN_WAIT_IF_LOCKED is set
*/
int handler::ha_open(TABLE *table_arg, const char *name, int mode,
uint test_if_locked)
{
int error;
DBUG_ENTER("handler::ha_open");
DBUG_PRINT("enter",
("name: %s db_type: %d db_stat: %d mode: %d lock_test: %d",
name, ht->db_type, table_arg->db_stat, mode,
test_if_locked));
table= table_arg;
DBUG_ASSERT(table->s == table_share);
DBUG_ASSERT(m_lock_type == F_UNLCK);
DBUG_PRINT("info", ("old m_lock_type: %d F_UNLCK %d", m_lock_type, F_UNLCK));
DBUG_ASSERT(alloc_root_inited(&table->mem_root));
if ((error=open(name,mode,test_if_locked)))
{
if ((error == EACCES || error == EROFS) && mode == O_RDWR &&
(table->db_stat & HA_TRY_READ_ONLY))
{
table->db_stat|=HA_READ_ONLY;
error=open(name,O_RDONLY,test_if_locked);
}
}
if (error)
{
my_errno= error; /* Safeguard */
DBUG_PRINT("error",("error: %d errno: %d",error,errno));
}
else
{
DBUG_ASSERT(m_psi == NULL);
DBUG_ASSERT(table_share != NULL);
#ifdef HAVE_PSI_TABLE_INTERFACE
/*
Do not call this for partitions handlers, since it may take too much
resources.
So only use the m_psi on table level, not for individual partitions.
*/
if (!(test_if_locked & HA_OPEN_NO_PSI_CALL))
{
PSI_table_share *share_psi= ha_table_share_psi(table_share);
m_psi= PSI_TABLE_CALL(open_table)(share_psi, this);
}
#endif
if (table->s->db_options_in_use & HA_OPTION_READ_ONLY_DATA)
table->db_stat|=HA_READ_ONLY;
(void) extra(HA_EXTRA_NO_READCHECK); // Not needed in SQL
/* ref is already allocated for us if we're called from handler::clone() */
if (!ref && !(ref= (uchar*) alloc_root(&table->mem_root,
ALIGN_SIZE(ref_length)*2)))
{
ha_close();
error=HA_ERR_OUT_OF_MEM;
}
else
dup_ref=ref+ALIGN_SIZE(ref_length);
cached_table_flags= table_flags();
}
reset_statistics();
internal_tmp_table= test(test_if_locked & HA_OPEN_INTERNAL_TABLE);
DBUG_RETURN(error);
}
int handler::ha_close(void)
{
DBUG_ENTER("ha_close");
/*
Increment global statistics for temporary tables.
In_use is 0 for tables that was closed from the table cache.
*/
if (table->in_use)
status_var_add(table->in_use->status_var.rows_tmp_read, rows_tmp_read);
#ifdef HAVE_PSI_TABLE_INTERFACE
PSI_TABLE_CALL(close_table)(m_psi);
m_psi= NULL; /* instrumentation handle, invalid after close_table() */
#endif
// TODO: set table= NULL to mark the handler as closed?
DBUG_ASSERT(m_psi == NULL);
DBUG_ASSERT(m_lock_type == F_UNLCK);
DBUG_ASSERT(inited == NONE);
DBUG_RETURN(close());
}
int handler::ha_rnd_next(uchar *buf)
{
int result;
DBUG_ENTER("handler::ha_rnd_next");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited == RND);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, MAX_KEY, 0,
{ result= rnd_next(buf); })
if (!result)
{
update_rows_read();
increment_statistics(&SSV::ha_read_rnd_next_count);
}
else if (result == HA_ERR_RECORD_DELETED)
increment_statistics(&SSV::ha_read_rnd_deleted_count);
else
increment_statistics(&SSV::ha_read_rnd_next_count);
table->status=result ? STATUS_NOT_FOUND: 0;
DBUG_RETURN(result);
}
int handler::ha_rnd_pos(uchar *buf, uchar *pos)
{
int result;
DBUG_ENTER("handler::ha_rnd_pos");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
/* TODO: Find out how to solve ha_rnd_pos when finding duplicate update. */
/* DBUG_ASSERT(inited == RND); */
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, MAX_KEY, 0,
{ result= rnd_pos(buf, pos); })
increment_statistics(&SSV::ha_read_rnd_count);
if (!result)
update_rows_read();
table->status=result ? STATUS_NOT_FOUND: 0;
DBUG_RETURN(result);
}
int handler::ha_index_read_map(uchar *buf, const uchar *key,
key_part_map keypart_map,
enum ha_rkey_function find_flag)
{
int result;
DBUG_ENTER("handler::ha_index_read_map");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_read_map(buf, key, keypart_map, find_flag); })
increment_statistics(&SSV::ha_read_key_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
DBUG_RETURN(result);
}
/*
@note: Other index lookup/navigation functions require prior
handler->index_init() call. This function is different, it requires
that the scan is not initialized, and accepts "uint index" as an argument.
*/
int handler::ha_index_read_idx_map(uchar *buf, uint index, const uchar *key,
key_part_map keypart_map,
enum ha_rkey_function find_flag)
{
int result;
DBUG_ASSERT(inited==NONE);
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(end_range == NULL);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, index, 0,
{ result= index_read_idx_map(buf, index, key, keypart_map, find_flag); })
increment_statistics(&SSV::ha_read_key_count);
if (!result)
{
update_rows_read();
index_rows_read[index]++;
}
table->status=result ? STATUS_NOT_FOUND: 0;
return result;
}
int handler::ha_index_next(uchar * buf)
{
int result;
DBUG_ENTER("handler::ha_index_next");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_next(buf); })
increment_statistics(&SSV::ha_read_next_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
DBUG_RETURN(result);
}
int handler::ha_index_prev(uchar * buf)
{
int result;
DBUG_ENTER("handler::ha_index_prev");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_prev(buf); })
increment_statistics(&SSV::ha_read_prev_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
DBUG_RETURN(result);
}
int handler::ha_index_first(uchar * buf)
{
int result;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_first(buf); })
increment_statistics(&SSV::ha_read_first_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
return result;
}
int handler::ha_index_last(uchar * buf)
{
int result;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_last(buf); })
increment_statistics(&SSV::ha_read_last_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
return result;
}
int handler::ha_index_next_same(uchar *buf, const uchar *key, uint keylen)
{
int result;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ASSERT(inited==INDEX);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_FETCH_ROW, active_index, 0,
{ result= index_next_same(buf, key, keylen); })
increment_statistics(&SSV::ha_read_next_count);
if (!result)
update_index_statistics();
table->status=result ? STATUS_NOT_FOUND: 0;
return result;
}
/* Initialize handler for random reading, with error handling */
int handler::ha_rnd_init_with_error(bool scan)
{
int error;
if (!(error= ha_rnd_init(scan)))
return 0;
table->file->print_error(error, MYF(0));
return error;
}
/**
Read first row (only) from a table.
This is never called for InnoDB tables, as these table types
has the HA_STATS_RECORDS_IS_EXACT set.
*/
int handler::read_first_row(uchar * buf, uint primary_key)
{
register int error;
DBUG_ENTER("handler::read_first_row");
/*
If there is very few deleted rows in the table, find the first row by
scanning the table.
TODO remove the test for HA_READ_ORDER
*/
if (stats.deleted < 10 || primary_key >= MAX_KEY ||
!(index_flags(primary_key, 0, 0) & HA_READ_ORDER))
{
if (!(error= ha_rnd_init(1)))
{
while ((error= ha_rnd_next(buf)) == HA_ERR_RECORD_DELETED)
/* skip deleted row */;
const int end_error= ha_rnd_end();
if (!error)
error= end_error;
}
}
else
{
/* Find the first row through the primary key */
if (!(error= ha_index_init(primary_key, 0)))
{
error= ha_index_first(buf);
const int end_error= ha_index_end();
if (!error)
error= end_error;
}
}
DBUG_RETURN(error);
}
/**
Generate the next auto-increment number based on increment and offset.
computes the lowest number
- strictly greater than "nr"
- of the form: auto_increment_offset + N * auto_increment_increment
If overflow happened then return MAX_ULONGLONG value as an
indication of overflow.
In most cases increment= offset= 1, in which case we get:
@verbatim 1,2,3,4,5,... @endverbatim
If increment=10 and offset=5 and previous number is 1, we get:
@verbatim 1,5,15,25,35,... @endverbatim
*/
inline ulonglong
compute_next_insert_id(ulonglong nr,struct system_variables *variables)
{
const ulonglong save_nr= nr;
if (variables->auto_increment_increment == 1)
nr= nr + 1; // optimization of the formula below
else
{
nr= (((nr+ variables->auto_increment_increment -
variables->auto_increment_offset)) /
(ulonglong) variables->auto_increment_increment);
nr= (nr* (ulonglong) variables->auto_increment_increment +
variables->auto_increment_offset);
}
if (unlikely(nr <= save_nr))
return ULONGLONG_MAX;
return nr;
}
void handler::adjust_next_insert_id_after_explicit_value(ulonglong nr)
{
/*
If we have set THD::next_insert_id previously and plan to insert an
explicitely-specified value larger than this, we need to increase
THD::next_insert_id to be greater than the explicit value.
*/
if ((next_insert_id > 0) && (nr >= next_insert_id))
set_next_insert_id(compute_next_insert_id(nr, &table->in_use->variables));
}
/** @brief
Computes the largest number X:
- smaller than or equal to "nr"
- of the form: auto_increment_offset + N * auto_increment_increment
where N>=0.
SYNOPSIS
prev_insert_id
nr Number to "round down"
variables variables struct containing auto_increment_increment and
auto_increment_offset
RETURN
The number X if it exists, "nr" otherwise.
*/
inline ulonglong
prev_insert_id(ulonglong nr, struct system_variables *variables)
{
if (unlikely(nr < variables->auto_increment_offset))
{
/*
There's nothing good we can do here. That is a pathological case, where
the offset is larger than the column's max possible value, i.e. not even
the first sequence value may be inserted. User will receive warning.
*/
DBUG_PRINT("info",("auto_increment: nr: %lu cannot honour "
"auto_increment_offset: %lu",
(ulong) nr, variables->auto_increment_offset));
return nr;
}
if (variables->auto_increment_increment == 1)
return nr; // optimization of the formula below
nr= (((nr - variables->auto_increment_offset)) /
(ulonglong) variables->auto_increment_increment);
return (nr * (ulonglong) variables->auto_increment_increment +
variables->auto_increment_offset);
}
/**
Update the auto_increment field if necessary.
Updates columns with type NEXT_NUMBER if:
- If column value is set to NULL (in which case
auto_increment_field_not_null is 0)
- If column is set to 0 and (sql_mode & MODE_NO_AUTO_VALUE_ON_ZERO) is not
set. In the future we will only set NEXT_NUMBER fields if one sets them
to NULL (or they are not included in the insert list).
In those cases, we check if the currently reserved interval still has
values we have not used. If yes, we pick the smallest one and use it.
Otherwise:
- If a list of intervals has been provided to the statement via SET
INSERT_ID or via an Intvar_log_event (in a replication slave), we pick the
first unused interval from this list, consider it as reserved.
- Otherwise we set the column for the first row to the value
next_insert_id(get_auto_increment(column))) which is usually
max-used-column-value+1.
We call get_auto_increment() for the first row in a multi-row
statement. get_auto_increment() will tell us the interval of values it
reserved for us.
- In both cases, for the following rows we use those reserved values without
calling the handler again (we just progress in the interval, computing
each new value from the previous one). Until we have exhausted them, then
we either take the next provided interval or call get_auto_increment()
again to reserve a new interval.
- In both cases, the reserved intervals are remembered in
thd->auto_inc_intervals_in_cur_stmt_for_binlog if statement-based
binlogging; the last reserved interval is remembered in
auto_inc_interval_for_cur_row. The number of reserved intervals is
remembered in auto_inc_intervals_count. It differs from the number of
elements in thd->auto_inc_intervals_in_cur_stmt_for_binlog() because the
latter list is cumulative over all statements forming one binlog event
(when stored functions and triggers are used), and collapses two
contiguous intervals in one (see its append() method).
The idea is that generated auto_increment values are predictable and
independent of the column values in the table. This is needed to be
able to replicate into a table that already has rows with a higher
auto-increment value than the one that is inserted.
After we have already generated an auto-increment number and the user
inserts a column with a higher value than the last used one, we will
start counting from the inserted value.
This function's "outputs" are: the table's auto_increment field is filled
with a value, thd->next_insert_id is filled with the value to use for the
next row, if a value was autogenerated for the current row it is stored in
thd->insert_id_for_cur_row, if get_auto_increment() was called
thd->auto_inc_interval_for_cur_row is modified, if that interval is not
present in thd->auto_inc_intervals_in_cur_stmt_for_binlog it is added to
this list.
@todo
Replace all references to "next number" or NEXT_NUMBER to
"auto_increment", everywhere (see below: there is
table->auto_increment_field_not_null, and there also exists
table->next_number_field, it's not consistent).
@retval
0 ok
@retval
HA_ERR_AUTOINC_READ_FAILED get_auto_increment() was called and
returned ~(ulonglong) 0
@retval
HA_ERR_AUTOINC_ERANGE storing value in field caused strict mode
failure.
*/
#define AUTO_INC_DEFAULT_NB_ROWS 1 // Some prefer 1024 here
#define AUTO_INC_DEFAULT_NB_MAX_BITS 16
#define AUTO_INC_DEFAULT_NB_MAX ((1 << AUTO_INC_DEFAULT_NB_MAX_BITS) - 1)
int handler::update_auto_increment()
{
ulonglong nr, nb_reserved_values;
bool append= FALSE;
THD *thd= table->in_use;
struct system_variables *variables= &thd->variables;
int result=0, tmp;
enum enum_check_fields save_count_cuted_fields;
DBUG_ENTER("handler::update_auto_increment");
/*
next_insert_id is a "cursor" into the reserved interval, it may go greater
than the interval, but not smaller.
*/
DBUG_ASSERT(next_insert_id >= auto_inc_interval_for_cur_row.minimum());
if ((nr= table->next_number_field->val_int()) != 0 ||
(table->auto_increment_field_not_null &&
thd->variables.sql_mode & MODE_NO_AUTO_VALUE_ON_ZERO))
{
/*
Update next_insert_id if we had already generated a value in this
statement (case of INSERT VALUES(null),(3763),(null):
the last NULL needs to insert 3764, not the value of the first NULL plus
1).
Ignore negative values.
*/
if ((longlong) nr > 0 || (table->next_number_field->flags & UNSIGNED_FLAG))
adjust_next_insert_id_after_explicit_value(nr);
insert_id_for_cur_row= 0; // didn't generate anything
DBUG_RETURN(0);
}
if ((nr= next_insert_id) >= auto_inc_interval_for_cur_row.maximum())
{
/* next_insert_id is beyond what is reserved, so we reserve more. */
const Discrete_interval *forced=
thd->auto_inc_intervals_forced.get_next();
if (forced != NULL)
{
nr= forced->minimum();
nb_reserved_values= forced->values();
}
else
{
/*
handler::estimation_rows_to_insert was set by
handler::ha_start_bulk_insert(); if 0 it means "unknown".
*/
ulonglong nb_desired_values;
/*
If an estimation was given to the engine:
- use it.
- if we already reserved numbers, it means the estimation was
not accurate, then we'll reserve 2*AUTO_INC_DEFAULT_NB_ROWS the 2nd
time, twice that the 3rd time etc.
If no estimation was given, use those increasing defaults from the
start, starting from AUTO_INC_DEFAULT_NB_ROWS.
Don't go beyond a max to not reserve "way too much" (because
reservation means potentially losing unused values).
Note that in prelocked mode no estimation is given.
*/
if ((auto_inc_intervals_count == 0) && (estimation_rows_to_insert > 0))
nb_desired_values= estimation_rows_to_insert;
else if ((auto_inc_intervals_count == 0) &&
(thd->lex->many_values.elements > 0))
{
/*
For multi-row inserts, if the bulk inserts cannot be started, the
handler::estimation_rows_to_insert will not be set. But we still
want to reserve the autoinc values.
*/
nb_desired_values= thd->lex->many_values.elements;
}
else /* go with the increasing defaults */
{
/* avoid overflow in formula, with this if() */
if (auto_inc_intervals_count <= AUTO_INC_DEFAULT_NB_MAX_BITS)
{
nb_desired_values= AUTO_INC_DEFAULT_NB_ROWS *
(1 << auto_inc_intervals_count);
set_if_smaller(nb_desired_values, AUTO_INC_DEFAULT_NB_MAX);
}
else
nb_desired_values= AUTO_INC_DEFAULT_NB_MAX;
}
get_auto_increment(variables->auto_increment_offset,
variables->auto_increment_increment,
nb_desired_values, &nr,
&nb_reserved_values);
if (nr == ULONGLONG_MAX)
DBUG_RETURN(HA_ERR_AUTOINC_READ_FAILED); // Mark failure
/*
That rounding below should not be needed when all engines actually
respect offset and increment in get_auto_increment(). But they don't
so we still do it. Wonder if for the not-first-in-index we should do
it. Hope that this rounding didn't push us out of the interval; even
if it did we cannot do anything about it (calling the engine again
will not help as we inserted no row).
*/
nr= compute_next_insert_id(nr-1, variables);
}
if (table->s->next_number_keypart == 0)
{
/* We must defer the appending until "nr" has been possibly truncated */
append= TRUE;
}
else
{
/*
For such auto_increment there is no notion of interval, just a
singleton. The interval is not even stored in
thd->auto_inc_interval_for_cur_row, so we are sure to call the engine
for next row.
*/
DBUG_PRINT("info",("auto_increment: special not-first-in-index"));
}
}
if (unlikely(nr == ULONGLONG_MAX))
DBUG_RETURN(HA_ERR_AUTOINC_ERANGE);
DBUG_PRINT("info",("auto_increment: %llu nb_reserved_values: %llu",
nr, append ? nb_reserved_values : 0));
/* Store field without warning (Warning will be printed by insert) */
save_count_cuted_fields= thd->count_cuted_fields;
thd->count_cuted_fields= CHECK_FIELD_IGNORE;
tmp= table->next_number_field->store((longlong) nr, TRUE);
thd->count_cuted_fields= save_count_cuted_fields;
if (unlikely(tmp)) // Out of range value in store
{
/*
It's better to return an error here than getting a confusing
'duplicate key error' later.
*/
result= HA_ERR_AUTOINC_ERANGE;
}
if (append)
{
auto_inc_interval_for_cur_row.replace(nr, nb_reserved_values,
variables->auto_increment_increment);
auto_inc_intervals_count++;
/* Row-based replication does not need to store intervals in binlog */
if (mysql_bin_log.is_open() && !thd->is_current_stmt_binlog_format_row())
thd->auto_inc_intervals_in_cur_stmt_for_binlog.append(auto_inc_interval_for_cur_row.minimum(),
auto_inc_interval_for_cur_row.values(),
variables->auto_increment_increment);
}
/*
Record this autogenerated value. If the caller then
succeeds to insert this value, it will call
record_first_successful_insert_id_in_cur_stmt()
which will set first_successful_insert_id_in_cur_stmt if it's not
already set.
*/
insert_id_for_cur_row= nr;
if (result) // overflow
DBUG_RETURN(result);
/*
Set next insert id to point to next auto-increment value to be able to
handle multi-row statements.
*/
set_next_insert_id(compute_next_insert_id(nr, variables));
DBUG_RETURN(0);
}
/** @brief
MySQL signal that it changed the column bitmap
USAGE
This is for handlers that needs to setup their own column bitmaps.
Normally the handler should set up their own column bitmaps in
index_init() or rnd_init() and in any column_bitmaps_signal() call after
this.
The handler is allowd to do changes to the bitmap after a index_init or
rnd_init() call is made as after this, MySQL will not use the bitmap
for any program logic checking.
*/
void handler::column_bitmaps_signal()
{
DBUG_ENTER("column_bitmaps_signal");
if (table)
DBUG_PRINT("info", ("read_set: 0x%lx write_set: 0x%lx",
(long) table->read_set, (long) table->write_set));
DBUG_VOID_RETURN;
}
/** @brief
Reserves an interval of auto_increment values from the handler.
SYNOPSIS
get_auto_increment()
offset
increment
nb_desired_values how many values we want
first_value (OUT) the first value reserved by the handler
nb_reserved_values (OUT) how many values the handler reserved
offset and increment means that we want values to be of the form
offset + N * increment, where N>=0 is integer.
If the function sets *first_value to ~(ulonglong)0 it means an error.
If the function sets *nb_reserved_values to ULONGLONG_MAX it means it has
reserved to "positive infinite".
*/
void handler::get_auto_increment(ulonglong offset, ulonglong increment,
ulonglong nb_desired_values,
ulonglong *first_value,
ulonglong *nb_reserved_values)
{
ulonglong nr;
int error;
(void) extra(HA_EXTRA_KEYREAD);
table->mark_columns_used_by_index_no_reset(table->s->next_number_index,
table->read_set);
column_bitmaps_signal();
if (ha_index_init(table->s->next_number_index, 1))
{
/* This should never happen, assert in debug, and fail in release build */
DBUG_ASSERT(0);
*first_value= ULONGLONG_MAX;
return;
}
if (table->s->next_number_keypart == 0)
{ // Autoincrement at key-start
error= ha_index_last(table->record[1]);
/*
MySQL implicitely assumes such method does locking (as MySQL decides to
use nr+increment without checking again with the handler, in
handler::update_auto_increment()), so reserves to infinite.
*/
*nb_reserved_values= ULONGLONG_MAX;
}
else
{
uchar key[MAX_KEY_LENGTH];
key_copy(key, table->record[0],
table->key_info + table->s->next_number_index,
table->s->next_number_key_offset);
error= ha_index_read_map(table->record[1], key,
make_prev_keypart_map(table->s->
next_number_keypart),
HA_READ_PREFIX_LAST);
/*
MySQL needs to call us for next row: assume we are inserting ("a",null)
here, we return 3, and next this statement will want to insert
("b",null): there is no reason why ("b",3+1) would be the good row to
insert: maybe it already exists, maybe 3+1 is too large...
*/
*nb_reserved_values= 1;
}
if (error)
{
if (error == HA_ERR_END_OF_FILE || error == HA_ERR_KEY_NOT_FOUND)
{
/* No entry found, start with 1. */
nr= 1;
}
else
{
DBUG_ASSERT(0);
nr= ULONGLONG_MAX;
}
}
else
nr= ((ulonglong) table->next_number_field->
val_int_offset(table->s->rec_buff_length)+1);
ha_index_end();
(void) extra(HA_EXTRA_NO_KEYREAD);
*first_value= nr;
return;
}
void handler::ha_release_auto_increment()
{
DBUG_ENTER("ha_release_auto_increment");
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK ||
(!next_insert_id && !insert_id_for_cur_row));
release_auto_increment();
insert_id_for_cur_row= 0;
auto_inc_interval_for_cur_row.replace(0, 0, 0);
auto_inc_intervals_count= 0;
if (next_insert_id > 0)
{
next_insert_id= 0;
/*
this statement used forced auto_increment values if there were some,
wipe them away for other statements.
*/
table->in_use->auto_inc_intervals_forced.empty();
}
DBUG_VOID_RETURN;
}
/**
Construct and emit duplicate key error message using information
from table's record buffer.
@param table TABLE object which record buffer should be used as
source for column values.
@param key Key description.
@param msg Error message template to which key value should be
added.
@param errflag Flags for my_error() call.
*/
void print_keydup_error(TABLE *table, KEY *key, const char *msg, myf errflag)
{
/* Write the duplicated key in the error message */
char key_buff[MAX_KEY_LENGTH];
String str(key_buff,sizeof(key_buff),system_charset_info);
if (key == NULL)
{
/* Key is unknown */
str.copy("", 0, system_charset_info);
my_printf_error(ER_DUP_ENTRY, msg, errflag, str.c_ptr(), "*UNKNOWN*");
}
else
{
/* Table is opened and defined at this point */
key_unpack(&str,table, key);
uint max_length=MYSQL_ERRMSG_SIZE-(uint) strlen(msg);
if (str.length() >= max_length)
{
str.length(max_length-4);
str.append(STRING_WITH_LEN("..."));
}
my_printf_error(ER_DUP_ENTRY, msg, errflag, str.c_ptr_safe(), key->name);
}
}
/**
Construct and emit duplicate key error message using information
from table's record buffer.
@sa print_keydup_error(table, key, msg, errflag).
*/
void print_keydup_error(TABLE *table, KEY *key, myf errflag)
{
print_keydup_error(table, key, ER(ER_DUP_ENTRY_WITH_KEY_NAME), errflag);
}
/**
Print error that we got from handler function.
@note
In case of delete table it's only safe to use the following parts of
the 'table' structure:
- table->s->path
- table->alias
*/
#define SET_FATAL_ERROR fatal_error=1
void handler::print_error(int error, myf errflag)
{
bool fatal_error= 0;
DBUG_ENTER("handler::print_error");
DBUG_PRINT("enter",("error: %d",error));
int textno=ER_GET_ERRNO;
switch (error) {
case EACCES:
textno=ER_OPEN_AS_READONLY;
break;
case EAGAIN:
textno=ER_FILE_USED;
break;
case ENOENT:
textno=ER_FILE_NOT_FOUND;
break;
case ENOSPC:
case HA_ERR_DISK_FULL:
textno= ER_DISK_FULL;
SET_FATAL_ERROR; // Ensure error is logged
break;
case HA_ERR_KEY_NOT_FOUND:
case HA_ERR_NO_ACTIVE_RECORD:
case HA_ERR_RECORD_DELETED:
case HA_ERR_END_OF_FILE:
/*
This errors is not not normally fatal (for example for reads). However
if you get it during an update or delete, then its fatal.
As the user is calling print_error() (which is not done on read), we
assume something when wrong with the update or delete.
*/
SET_FATAL_ERROR;
textno=ER_KEY_NOT_FOUND;
break;
case HA_ERR_ABORTED_BY_USER:
{
DBUG_ASSERT(table->in_use->killed);
table->in_use->send_kill_message();
DBUG_VOID_RETURN;
}
case HA_ERR_WRONG_MRG_TABLE_DEF:
textno=ER_WRONG_MRG_TABLE;
break;
case HA_ERR_FOUND_DUPP_KEY:
{
if (table)
{
uint key_nr=get_dup_key(error);
if ((int) key_nr >= 0)
{
print_keydup_error(table,
key_nr == MAX_KEY ? NULL : &table->key_info[key_nr],
errflag);
DBUG_VOID_RETURN;
}
}
textno=ER_DUP_KEY;
break;
}
case HA_ERR_FOREIGN_DUPLICATE_KEY:
{
char rec_buf[MAX_KEY_LENGTH];
String rec(rec_buf, sizeof(rec_buf), system_charset_info);
/* Table is opened and defined at this point */
/*
Just print the subset of fields that are part of the first index,
printing the whole row from there is not easy.
*/
key_unpack(&rec, table, &table->key_info[0]);
char child_table_name[NAME_LEN + 1];
char child_key_name[NAME_LEN + 1];
if (get_foreign_dup_key(child_table_name, sizeof(child_table_name),
child_key_name, sizeof(child_key_name)))
{
my_error(ER_FOREIGN_DUPLICATE_KEY_WITH_CHILD_INFO, errflag,
table_share->table_name.str, rec.c_ptr_safe(),
child_table_name, child_key_name);
}
else
{
my_error(ER_FOREIGN_DUPLICATE_KEY_WITHOUT_CHILD_INFO, errflag,
table_share->table_name.str, rec.c_ptr_safe());
}
DBUG_VOID_RETURN;
}
case HA_ERR_NULL_IN_SPATIAL:
my_error(ER_CANT_CREATE_GEOMETRY_OBJECT, errflag);
DBUG_VOID_RETURN;
case HA_ERR_FOUND_DUPP_UNIQUE:
textno=ER_DUP_UNIQUE;
break;
case HA_ERR_RECORD_CHANGED:
/*
This is not fatal error when using HANDLER interface
SET_FATAL_ERROR;
*/
textno=ER_CHECKREAD;
break;
case HA_ERR_CRASHED:
SET_FATAL_ERROR;
textno=ER_NOT_KEYFILE;
break;
case HA_ERR_WRONG_IN_RECORD:
SET_FATAL_ERROR;
textno= ER_CRASHED_ON_USAGE;
break;
case HA_ERR_CRASHED_ON_USAGE:
SET_FATAL_ERROR;
textno=ER_CRASHED_ON_USAGE;
break;
case HA_ERR_NOT_A_TABLE:
textno= error;
break;
case HA_ERR_CRASHED_ON_REPAIR:
SET_FATAL_ERROR;
textno=ER_CRASHED_ON_REPAIR;
break;
case HA_ERR_OUT_OF_MEM:
textno=ER_OUT_OF_RESOURCES;
break;
case HA_ERR_WRONG_COMMAND:
textno=ER_ILLEGAL_HA;
break;
case HA_ERR_OLD_FILE:
textno=ER_OLD_KEYFILE;
break;
case HA_ERR_UNSUPPORTED:
textno=ER_UNSUPPORTED_EXTENSION;
break;
case HA_ERR_RECORD_FILE_FULL:
case HA_ERR_INDEX_FILE_FULL:
{
textno=ER_RECORD_FILE_FULL;
/* Write the error message to error log */
errflag|= ME_NOREFRESH;
break;
}
case HA_ERR_LOCK_WAIT_TIMEOUT:
textno=ER_LOCK_WAIT_TIMEOUT;
break;
case HA_ERR_LOCK_TABLE_FULL:
textno=ER_LOCK_TABLE_FULL;
break;
case HA_ERR_LOCK_DEADLOCK:
textno=ER_LOCK_DEADLOCK;
/* cannot continue. the statement was already aborted in the engine */
SET_FATAL_ERROR;
break;
case HA_ERR_READ_ONLY_TRANSACTION:
textno=ER_READ_ONLY_TRANSACTION;
break;
case HA_ERR_CANNOT_ADD_FOREIGN:
textno=ER_CANNOT_ADD_FOREIGN;
break;
case HA_ERR_ROW_IS_REFERENCED:
{
String str;
get_error_message(error, &str);
my_error(ER_ROW_IS_REFERENCED_2, errflag, str.c_ptr_safe());
DBUG_VOID_RETURN;
}
case HA_ERR_NO_REFERENCED_ROW:
{
String str;
get_error_message(error, &str);
my_error(ER_NO_REFERENCED_ROW_2, errflag, str.c_ptr_safe());
DBUG_VOID_RETURN;
}
case HA_ERR_TABLE_DEF_CHANGED:
textno=ER_TABLE_DEF_CHANGED;
break;
case HA_ERR_NO_SUCH_TABLE:
my_error(ER_NO_SUCH_TABLE_IN_ENGINE, errflag, table_share->db.str,
table_share->table_name.str);
DBUG_VOID_RETURN;
case HA_ERR_RBR_LOGGING_FAILED:
textno= ER_BINLOG_ROW_LOGGING_FAILED;
break;
case HA_ERR_DROP_INDEX_FK:
{
const char *ptr= "???";
uint key_nr= get_dup_key(error);
if ((int) key_nr >= 0)
ptr= table->key_info[key_nr].name;
my_error(ER_DROP_INDEX_FK, errflag, ptr);
DBUG_VOID_RETURN;
}
case HA_ERR_TABLE_NEEDS_UPGRADE:
textno=ER_TABLE_NEEDS_UPGRADE;
break;
case HA_ERR_NO_PARTITION_FOUND:
textno=ER_WRONG_PARTITION_NAME;
break;
case HA_ERR_TABLE_READONLY:
textno= ER_OPEN_AS_READONLY;
break;
case HA_ERR_AUTOINC_READ_FAILED:
textno= ER_AUTOINC_READ_FAILED;
break;
case HA_ERR_AUTOINC_ERANGE:
textno= error;
my_error(textno, errflag, table->next_number_field->field_name,
table->in_use->get_stmt_da()->current_row_for_warning());
DBUG_VOID_RETURN;
break;
case HA_ERR_TOO_MANY_CONCURRENT_TRXS:
textno= ER_TOO_MANY_CONCURRENT_TRXS;
break;
case HA_ERR_INDEX_COL_TOO_LONG:
textno= ER_INDEX_COLUMN_TOO_LONG;
break;
case HA_ERR_NOT_IN_LOCK_PARTITIONS:
textno=ER_ROW_DOES_NOT_MATCH_GIVEN_PARTITION_SET;
break;
case HA_ERR_INDEX_CORRUPT:
textno= ER_INDEX_CORRUPT;
break;
case HA_ERR_UNDO_REC_TOO_BIG:
textno= ER_UNDO_RECORD_TOO_BIG;
break;
case HA_ERR_TABLE_IN_FK_CHECK:
textno= ER_TABLE_IN_FK_CHECK;
break;
default:
{
/* The error was "unknown" to this function.
Ask handler if it has got a message for this error */
bool temporary= FALSE;
String str;
temporary= get_error_message(error, &str);
if (!str.is_empty())
{
const char* engine= table_type();
if (temporary)
my_error(ER_GET_TEMPORARY_ERRMSG, errflag, error, str.c_ptr(),
engine);
else
{
SET_FATAL_ERROR;
my_error(ER_GET_ERRMSG, errflag, error, str.c_ptr(), engine);
}
}
else
my_error(ER_GET_ERRNO,errflag,error);
DBUG_VOID_RETURN;
}
}
if (fatal_error)
{
/* Ensure this becomes a true error */
errflag&= ~(ME_JUST_WARNING | ME_JUST_INFO);
if ((debug_assert_if_crashed_table ||
global_system_variables.log_warnings > 1))
{
/*
Log error to log before we crash or if extended warnings are requested
*/
errflag|= ME_NOREFRESH;
}
}
my_error(textno, errflag, table_share->table_name.str, error);
DBUG_VOID_RETURN;
}
/**
Return an error message specific to this handler.
@param error error code previously returned by handler
@param buf pointer to String where to add error message
@return
Returns true if this is a temporary error
*/
bool handler::get_error_message(int error, String* buf)
{
return FALSE;
}
/**
Check for incompatible collation changes.
@retval
HA_ADMIN_NEEDS_UPGRADE Table may have data requiring upgrade.
@retval
0 No upgrade required.
*/
int handler::check_collation_compatibility()
{
ulong mysql_version= table->s->mysql_version;
if (mysql_version < 50124)
{
KEY *key= table->key_info;
KEY *key_end= key + table->s->keys;
for (; key < key_end; key++)
{
KEY_PART_INFO *key_part= key->key_part;
KEY_PART_INFO *key_part_end= key_part + key->user_defined_key_parts;
for (; key_part < key_part_end; key_part++)
{
if (!key_part->fieldnr)
continue;
Field *field= table->field[key_part->fieldnr - 1];
uint cs_number= field->charset()->number;
if ((mysql_version < 50048 &&
(cs_number == 11 || /* ascii_general_ci - bug #29499, bug #27562 */
cs_number == 41 || /* latin7_general_ci - bug #29461 */
cs_number == 42 || /* latin7_general_cs - bug #29461 */
cs_number == 20 || /* latin7_estonian_cs - bug #29461 */
cs_number == 21 || /* latin2_hungarian_ci - bug #29461 */
cs_number == 22 || /* koi8u_general_ci - bug #29461 */
cs_number == 23 || /* cp1251_ukrainian_ci - bug #29461 */
cs_number == 26)) || /* cp1250_general_ci - bug #29461 */
(mysql_version < 50124 &&
(cs_number == 33 || /* utf8_general_ci - bug #27877 */
cs_number == 35))) /* ucs2_general_ci - bug #27877 */
return HA_ADMIN_NEEDS_UPGRADE;
}
}
}
return 0;
}
int handler::ha_check_for_upgrade(HA_CHECK_OPT *check_opt)
{
int error;
KEY *keyinfo, *keyend;
KEY_PART_INFO *keypart, *keypartend;
if (!table->s->mysql_version)
{
/* check for blob-in-key error */
keyinfo= table->key_info;
keyend= table->key_info + table->s->keys;
for (; keyinfo < keyend; keyinfo++)
{
keypart= keyinfo->key_part;
keypartend= keypart + keyinfo->user_defined_key_parts;
for (; keypart < keypartend; keypart++)
{
if (!keypart->fieldnr)
continue;
Field *field= table->field[keypart->fieldnr-1];
if (field->type() == MYSQL_TYPE_BLOB)
{
if (check_opt->sql_flags & TT_FOR_UPGRADE)
check_opt->flags= T_MEDIUM;
return HA_ADMIN_NEEDS_CHECK;
}
}
}
}
if (table->s->frm_version != FRM_VER_TRUE_VARCHAR)
return HA_ADMIN_NEEDS_ALTER;
if ((error= check_collation_compatibility()))
return error;
return check_for_upgrade(check_opt);
}
int handler::check_old_types()
{
Field** field;
if (!table->s->mysql_version)
{
/* check for bad DECIMAL field */
for (field= table->field; (*field); field++)
{
if ((*field)->type() == MYSQL_TYPE_NEWDECIMAL)
{
return HA_ADMIN_NEEDS_ALTER;
}
if ((*field)->type() == MYSQL_TYPE_VAR_STRING)
{
return HA_ADMIN_NEEDS_ALTER;
}
}
}
return 0;
}
static bool update_frm_version(TABLE *table)
{
char path[FN_REFLEN];
File file;
int result= 1;
DBUG_ENTER("update_frm_version");
/*
No need to update frm version in case table was created or checked
by server with the same version. This also ensures that we do not
update frm version for temporary tables as this code doesn't support
temporary tables.
*/
if (table->s->mysql_version == MYSQL_VERSION_ID)
DBUG_RETURN(0);
strxmov(path, table->s->normalized_path.str, reg_ext, NullS);
if ((file= mysql_file_open(key_file_frm,
path, O_RDWR|O_BINARY, MYF(MY_WME))) >= 0)
{
uchar version[4];
int4store(version, MYSQL_VERSION_ID);
if ((result= mysql_file_pwrite(file, (uchar*) version, 4, 51L, MYF_RW)))
goto err;
table->s->mysql_version= MYSQL_VERSION_ID;
}
err:
if (file >= 0)
(void) mysql_file_close(file, MYF(MY_WME));
DBUG_RETURN(result);
}
/**
@return
key if error because of duplicated keys
*/
uint handler::get_dup_key(int error)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
DBUG_ENTER("handler::get_dup_key");
table->file->errkey = (uint) -1;
if (error == HA_ERR_FOUND_DUPP_KEY || error == HA_ERR_FOREIGN_DUPLICATE_KEY ||
error == HA_ERR_FOUND_DUPP_UNIQUE || error == HA_ERR_NULL_IN_SPATIAL ||
error == HA_ERR_DROP_INDEX_FK)
table->file->info(HA_STATUS_ERRKEY | HA_STATUS_NO_LOCK);
DBUG_RETURN(table->file->errkey);
}
/**
Delete all files with extension from bas_ext().
@param name Base name of table
@note
We assume that the handler may return more extensions than
was actually used for the file.
@retval
0 If we successfully deleted at least one file from base_ext and
didn't get any other errors than ENOENT
@retval
!0 Error
*/
int handler::delete_table(const char *name)
{
int saved_error= 0;
int error= 0;
int enoent_or_zero= ENOENT; // Error if no file was deleted
char buff[FN_REFLEN];
for (const char **ext=bas_ext(); *ext ; ext++)
{
fn_format(buff, name, "", *ext, MY_UNPACK_FILENAME|MY_APPEND_EXT);
if (mysql_file_delete_with_symlink(key_file_misc, buff, MYF(0)))
{
if (my_errno != ENOENT)
{
/*
If error on the first existing file, return the error.
Otherwise delete as much as possible.
*/
if (enoent_or_zero)
return my_errno;
saved_error= my_errno;
}
}
else
enoent_or_zero= 0; // No error for ENOENT
error= enoent_or_zero;
}
return saved_error ? saved_error : error;
}
int handler::rename_table(const char * from, const char * to)
{
int error= 0;
const char **ext, **start_ext;
start_ext= bas_ext();
for (ext= start_ext; *ext ; ext++)
{
if (rename_file_ext(from, to, *ext))
{
if ((error=my_errno) != ENOENT)
break;
error= 0;
}
}
if (error)
{
/* Try to revert the rename. Ignore errors. */
for (; ext >= start_ext; ext--)
rename_file_ext(to, from, *ext);
}
return error;
}
void handler::drop_table(const char *name)
{
ha_close();
delete_table(name);
}
/**
Performs checks upon the table.
@param thd thread doing CHECK TABLE operation
@param check_opt options from the parser
@retval
HA_ADMIN_OK Successful upgrade
@retval
HA_ADMIN_NEEDS_UPGRADE Table has structures requiring upgrade
@retval
HA_ADMIN_NEEDS_ALTER Table has structures requiring ALTER TABLE
@retval
HA_ADMIN_NOT_IMPLEMENTED
*/
int handler::ha_check(THD *thd, HA_CHECK_OPT *check_opt)
{
int error;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
if ((table->s->mysql_version >= MYSQL_VERSION_ID) &&
(check_opt->sql_flags & TT_FOR_UPGRADE))
return 0;
if (table->s->mysql_version < MYSQL_VERSION_ID)
{
if ((error= check_old_types()))
return error;
error= ha_check_for_upgrade(check_opt);
if (error && (error != HA_ADMIN_NEEDS_CHECK))
return error;
if (!error && (check_opt->sql_flags & TT_FOR_UPGRADE))
return 0;
}
if ((error= check(thd, check_opt)))
return error;
return update_frm_version(table);
}
/**
A helper function to mark a transaction read-write,
if it is started.
*/
void
handler::mark_trx_read_write_part2()
{
Ha_trx_info *ha_info= &ha_thd()->ha_data[ht->slot].ha_info[0];
/* Don't call this function again for this statement */
mark_trx_done= TRUE;
/*
When a storage engine method is called, the transaction must
have been started, unless it's a DDL call, for which the
storage engine starts the transaction internally, and commits
it internally, without registering in the ha_list.
Unfortunately here we can't know know for sure if the engine
has registered the transaction or not, so we must check.
*/
if (ha_info->is_started())
{
DBUG_ASSERT(has_transactions());
/*
table_share can be NULL in ha_delete_table(). See implementation
of standalone function ha_delete_table() in sql_base.cc.
*/
if (table_share == NULL || table_share->tmp_table == NO_TMP_TABLE)
ha_info->set_trx_read_write();
}
}
/**
Repair table: public interface.
@sa handler::repair()
*/
int handler::ha_repair(THD* thd, HA_CHECK_OPT* check_opt)
{
int result;
mark_trx_read_write();
result= repair(thd, check_opt);
DBUG_ASSERT(result == HA_ADMIN_NOT_IMPLEMENTED ||
ha_table_flags() & HA_CAN_REPAIR);
if (result == HA_ADMIN_OK)
result= update_frm_version(table);
return result;
}
/**
Bulk update row: public interface.
@sa handler::bulk_update_row()
*/
int
handler::ha_bulk_update_row(const uchar *old_data, uchar *new_data,
uint *dup_key_found)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return bulk_update_row(old_data, new_data, dup_key_found);
}
/**
Delete all rows: public interface.
@sa handler::delete_all_rows()
*/
int
handler::ha_delete_all_rows()
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return delete_all_rows();
}
/**
Truncate table: public interface.
@sa handler::truncate()
*/
int
handler::ha_truncate()
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return truncate();
}
/**
Reset auto increment: public interface.
@sa handler::reset_auto_increment()
*/
int
handler::ha_reset_auto_increment(ulonglong value)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return reset_auto_increment(value);
}
/**
Optimize table: public interface.
@sa handler::optimize()
*/
int
handler::ha_optimize(THD* thd, HA_CHECK_OPT* check_opt)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return optimize(thd, check_opt);
}
/**
Analyze table: public interface.
@sa handler::analyze()
*/
int
handler::ha_analyze(THD* thd, HA_CHECK_OPT* check_opt)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
mark_trx_read_write();
return analyze(thd, check_opt);
}
/**
Check and repair table: public interface.
@sa handler::check_and_repair()
*/
bool
handler::ha_check_and_repair(THD *thd)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_UNLCK);
mark_trx_read_write();
return check_and_repair(thd);
}
/**
Disable indexes: public interface.
@sa handler::disable_indexes()
*/
int
handler::ha_disable_indexes(uint mode)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
mark_trx_read_write();
return disable_indexes(mode);
}
/**
Enable indexes: public interface.
@sa handler::enable_indexes()
*/
int
handler::ha_enable_indexes(uint mode)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
mark_trx_read_write();
return enable_indexes(mode);
}
/**
Discard or import tablespace: public interface.
@sa handler::discard_or_import_tablespace()
*/
int
handler::ha_discard_or_import_tablespace(my_bool discard)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
mark_trx_read_write();
return discard_or_import_tablespace(discard);
}
bool handler::ha_prepare_inplace_alter_table(TABLE *altered_table,
Alter_inplace_info *ha_alter_info)
{
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
mark_trx_read_write();
return prepare_inplace_alter_table(altered_table, ha_alter_info);
}
bool handler::ha_commit_inplace_alter_table(TABLE *altered_table,
Alter_inplace_info *ha_alter_info,
bool commit)
{
/*
At this point we should have an exclusive metadata lock on the table.
The exception is if we're about to roll back changes (commit= false).
In this case, we might be rolling back after a failed lock upgrade,
so we could be holding the same lock level as for inplace_alter_table().
*/
DBUG_ASSERT(ha_thd()->mdl_context.is_lock_owner(MDL_key::TABLE,
table->s->db.str,
table->s->table_name.str,
MDL_EXCLUSIVE) ||
!commit);
return commit_inplace_alter_table(altered_table, ha_alter_info, commit);
}
/*
Default implementation to support in-place alter table
and old online add/drop index API
*/
enum_alter_inplace_result
handler::check_if_supported_inplace_alter(TABLE *altered_table,
Alter_inplace_info *ha_alter_info)
{
DBUG_ENTER("check_if_supported_alter");
HA_CREATE_INFO *create_info= ha_alter_info->create_info;
Alter_inplace_info::HA_ALTER_FLAGS inplace_offline_operations=
Alter_inplace_info::ALTER_COLUMN_EQUAL_PACK_LENGTH |
Alter_inplace_info::ALTER_COLUMN_NAME |
Alter_inplace_info::ALTER_COLUMN_DEFAULT |
Alter_inplace_info::CHANGE_CREATE_OPTION |
Alter_inplace_info::ALTER_RENAME;
/* Is there at least one operation that requires copy algorithm? */
if (ha_alter_info->handler_flags & ~inplace_offline_operations)
DBUG_RETURN(HA_ALTER_INPLACE_NOT_SUPPORTED);
/*
ALTER TABLE tbl_name CONVERT TO CHARACTER SET .. and
ALTER TABLE table_name DEFAULT CHARSET = .. most likely
change column charsets and so not supported in-place through
old API.
Changing of PACK_KEYS, MAX_ROWS and ROW_FORMAT options were
not supported as in-place operations in old API either.
*/
if (create_info->used_fields & (HA_CREATE_USED_CHARSET |
HA_CREATE_USED_DEFAULT_CHARSET |
HA_CREATE_USED_PACK_KEYS |
HA_CREATE_USED_MAX_ROWS) ||
(table->s->row_type != create_info->row_type))
DBUG_RETURN(HA_ALTER_INPLACE_NOT_SUPPORTED);
uint table_changes= (ha_alter_info->handler_flags &
Alter_inplace_info::ALTER_COLUMN_EQUAL_PACK_LENGTH) ?
IS_EQUAL_PACK_LENGTH : IS_EQUAL_YES;
if (table->file->check_if_incompatible_data(create_info, table_changes)
== COMPATIBLE_DATA_YES)
DBUG_RETURN(HA_ALTER_INPLACE_EXCLUSIVE_LOCK);
DBUG_RETURN(HA_ALTER_INPLACE_NOT_SUPPORTED);
}
/*
Default implementation to support in-place alter table
and old online add/drop index API
*/
void handler::notify_table_changed()
{
ha_create_handler_files(table->s->path.str, NULL, CHF_INDEX_FLAG, NULL);
}
void Alter_inplace_info::report_unsupported_error(const char *not_supported,
const char *try_instead)
{
if (unsupported_reason == NULL)
my_error(ER_ALTER_OPERATION_NOT_SUPPORTED, MYF(0),
not_supported, try_instead);
else
my_error(ER_ALTER_OPERATION_NOT_SUPPORTED_REASON, MYF(0),
not_supported, unsupported_reason, try_instead);
}
/**
Rename table: public interface.
@sa handler::rename_table()
*/
int
handler::ha_rename_table(const char *from, const char *to)
{
DBUG_ASSERT(m_lock_type == F_UNLCK);
mark_trx_read_write();
return rename_table(from, to);
}
/**
Delete table: public interface.
@sa handler::delete_table()
*/
int
handler::ha_delete_table(const char *name)
{
mark_trx_read_write();
return delete_table(name);
}
/**
Drop table in the engine: public interface.
@sa handler::drop_table()
The difference between this and delete_table() is that the table is open in
drop_table().
*/
void
handler::ha_drop_table(const char *name)
{
DBUG_ASSERT(m_lock_type == F_UNLCK);
mark_trx_read_write();
return drop_table(name);
}
/**
Create a table in the engine: public interface.
@sa handler::create()
*/
int
handler::ha_create(const char *name, TABLE *form, HA_CREATE_INFO *info)
{
DBUG_ASSERT(m_lock_type == F_UNLCK);
mark_trx_read_write();
return create(name, form, info);
}
/**
Create handler files for CREATE TABLE: public interface.
@sa handler::create_handler_files()
*/
int
handler::ha_create_handler_files(const char *name, const char *old_name,
int action_flag, HA_CREATE_INFO *info)
{
/*
Normally this is done when unlocked, but in fast_alter_partition_table,
it is done on an already locked handler when preparing to alter/rename
partitions.
*/
DBUG_ASSERT(m_lock_type == F_UNLCK ||
(!old_name && strcmp(name, table_share->path.str)));
mark_trx_read_write();
return create_handler_files(name, old_name, action_flag, info);
}
/**
Change partitions: public interface.
@sa handler::change_partitions()
*/
int
handler::ha_change_partitions(HA_CREATE_INFO *create_info,
const char *path,
ulonglong * const copied,
ulonglong * const deleted,
const uchar *pack_frm_data,
size_t pack_frm_len)
{ /*
Must have at least RDLCK or be a TMP table. Read lock is needed to read
from current partitions and write lock will be taken on new partitions.
*/
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type != F_UNLCK);
mark_trx_read_write();
return change_partitions(create_info, path, copied, deleted,
pack_frm_data, pack_frm_len);
}
/**
Drop partitions: public interface.
@sa handler::drop_partitions()
*/
int
handler::ha_drop_partitions(const char *path)
{
DBUG_ASSERT(!table->db_stat);
mark_trx_read_write();
return drop_partitions(path);
}
/**
Rename partitions: public interface.
@sa handler::rename_partitions()
*/
int
handler::ha_rename_partitions(const char *path)
{
DBUG_ASSERT(!table->db_stat);
mark_trx_read_write();
return rename_partitions(path);
}
/**
Tell the storage engine that it is allowed to "disable transaction" in the
handler. It is a hint that ACID is not required - it is used in NDB for
ALTER TABLE, for example, when data are copied to temporary table.
A storage engine may treat this hint any way it likes. NDB for example
starts to commit every now and then automatically.
This hint can be safely ignored.
*/
int ha_enable_transaction(THD *thd, bool on)
{
int error=0;
DBUG_ENTER("ha_enable_transaction");
DBUG_PRINT("enter", ("on: %d", (int) on));
if ((thd->transaction.on= on))
{
/*
Now all storage engines should have transaction handling enabled.
But some may have it enabled all the time - "disabling" transactions
is an optimization hint that storage engine is free to ignore.
So, let's commit an open transaction (if any) now.
*/
if (!(error= ha_commit_trans(thd, 0)))
error= trans_commit_implicit(thd);
}
DBUG_RETURN(error);
}
int handler::index_next_same(uchar *buf, const uchar *key, uint keylen)
{
int error;
DBUG_ENTER("handler::index_next_same");
if (!(error=index_next(buf)))
{
my_ptrdiff_t ptrdiff= buf - table->record[0];
uchar *UNINIT_VAR(save_record_0);
KEY *UNINIT_VAR(key_info);
KEY_PART_INFO *UNINIT_VAR(key_part);
KEY_PART_INFO *UNINIT_VAR(key_part_end);
/*
key_cmp_if_same() compares table->record[0] against 'key'.
In parts it uses table->record[0] directly, in parts it uses
field objects with their local pointers into table->record[0].
If 'buf' is distinct from table->record[0], we need to move
all record references. This is table->record[0] itself and
the field pointers of the fields used in this key.
*/
if (ptrdiff)
{
save_record_0= table->record[0];
table->record[0]= buf;
key_info= table->key_info + active_index;
key_part= key_info->key_part;
key_part_end= key_part + key_info->user_defined_key_parts;
for (; key_part < key_part_end; key_part++)
{
DBUG_ASSERT(key_part->field);
key_part->field->move_field_offset(ptrdiff);
}
}
if (key_cmp_if_same(table, key, active_index, keylen))
{
table->status=STATUS_NOT_FOUND;
error=HA_ERR_END_OF_FILE;
}
/* Move back if necessary. */
if (ptrdiff)
{
table->record[0]= save_record_0;
for (key_part= key_info->key_part; key_part < key_part_end; key_part++)
key_part->field->move_field_offset(-ptrdiff);
}
}
DBUG_PRINT("return",("%i", error));
DBUG_RETURN(error);
}
void handler::get_dynamic_partition_info(PARTITION_STATS *stat_info,
uint part_id)
{
info(HA_STATUS_CONST | HA_STATUS_TIME | HA_STATUS_VARIABLE |
HA_STATUS_NO_LOCK);
stat_info->records= stats.records;
stat_info->mean_rec_length= stats.mean_rec_length;
stat_info->data_file_length= stats.data_file_length;
stat_info->max_data_file_length= stats.max_data_file_length;
stat_info->index_file_length= stats.index_file_length;
stat_info->delete_length= stats.delete_length;
stat_info->create_time= stats.create_time;
stat_info->update_time= stats.update_time;
stat_info->check_time= stats.check_time;
stat_info->check_sum= 0;
if (table_flags() & (HA_HAS_OLD_CHECKSUM | HA_HAS_OLD_CHECKSUM))
stat_info->check_sum= checksum();
return;
}
/*
Updates the global table stats with the TABLE this handler represents
*/
void handler::update_global_table_stats()
{
TABLE_STATS * table_stats;
status_var_add(table->in_use->status_var.rows_read, rows_read);
DBUG_ASSERT(rows_tmp_read == 0);
if (!table->in_use->userstat_running)
{
rows_read= rows_changed= 0;
return;
}
if (rows_read + rows_changed == 0)
return; // Nothing to update.
DBUG_ASSERT(table->s && table->s->table_cache_key.str);
mysql_mutex_lock(&LOCK_global_table_stats);
/* Gets the global table stats, creating one if necessary. */
if (!(table_stats= (TABLE_STATS*)
my_hash_search(&global_table_stats,
(uchar*) table->s->table_cache_key.str,
table->s->table_cache_key.length)))
{
if (!(table_stats = ((TABLE_STATS*)
my_malloc(sizeof(TABLE_STATS),
MYF(MY_WME | MY_ZEROFILL)))))
{
/* Out of memory error already given */
goto end;
}
memcpy(table_stats->table, table->s->table_cache_key.str,
table->s->table_cache_key.length);
table_stats->table_name_length= table->s->table_cache_key.length;
table_stats->engine_type= ht->db_type;
/* No need to set variables to 0, as we use MY_ZEROFILL above */
if (my_hash_insert(&global_table_stats, (uchar*) table_stats))
{
/* Out of memory error is already given */
my_free(table_stats);
goto end;
}
}
// Updates the global table stats.
table_stats->rows_read+= rows_read;
table_stats->rows_changed+= rows_changed;
table_stats->rows_changed_x_indexes+= (rows_changed *
(table->s->keys ? table->s->keys :
1));
rows_read= rows_changed= 0;
end:
mysql_mutex_unlock(&LOCK_global_table_stats);
}
/*
Updates the global index stats with this handler's accumulated index reads.
*/
void handler::update_global_index_stats()
{
DBUG_ASSERT(table->s);
if (!table->in_use->userstat_running)
{
/* Reset all index read values */
bzero(index_rows_read, sizeof(index_rows_read[0]) * table->s->keys);
return;
}
for (uint index = 0; index < table->s->keys; index++)
{
if (index_rows_read[index])
{
INDEX_STATS* index_stats;
uint key_length;
KEY *key_info = &table->key_info[index]; // Rows were read using this
DBUG_ASSERT(key_info->cache_name);
if (!key_info->cache_name)
continue;
key_length= table->s->table_cache_key.length + key_info->name_length + 1;
mysql_mutex_lock(&LOCK_global_index_stats);
// Gets the global index stats, creating one if necessary.
if (!(index_stats= (INDEX_STATS*) my_hash_search(&global_index_stats,
key_info->cache_name,
key_length)))
{
if (!(index_stats = ((INDEX_STATS*)
my_malloc(sizeof(INDEX_STATS),
MYF(MY_WME | MY_ZEROFILL)))))
goto end; // Error is already given
memcpy(index_stats->index, key_info->cache_name, key_length);
index_stats->index_name_length= key_length;
if (my_hash_insert(&global_index_stats, (uchar*) index_stats))
{
my_free(index_stats);
goto end;
}
}
/* Updates the global index stats. */
index_stats->rows_read+= index_rows_read[index];
index_rows_read[index]= 0;
end:
mysql_mutex_unlock(&LOCK_global_index_stats);
}
}
}
/****************************************************************************
** Some general functions that isn't in the handler class
****************************************************************************/
/**
Initiates table-file and calls appropriate database-creator.
@retval
0 ok
@retval
1 error
*/
int ha_create_table(THD *thd, const char *path,
const char *db, const char *table_name,
HA_CREATE_INFO *create_info,
bool update_create_info)
{
int error= 1;
TABLE table;
char name_buff[FN_REFLEN];
const char *name;
TABLE_SHARE share;
DBUG_ENTER("ha_create_table");
#ifdef HAVE_PSI_TABLE_INTERFACE
my_bool temp_table= (my_bool)is_prefix(table_name, tmp_file_prefix) ||
(create_info->options & HA_LEX_CREATE_TMP_TABLE ? TRUE : FALSE);
#endif
init_tmp_table_share(thd, &share, db, 0, table_name, path);
if (open_table_def(thd, &share, 0))
goto err;
#ifdef HAVE_PSI_TABLE_INTERFACE
share.m_psi= PSI_TABLE_CALL(get_table_share)(temp_table, &share);
#endif
if (open_table_from_share(thd, &share, "", 0, (uint) READ_ALL, 0, &table,
TRUE))
goto err;
if (update_create_info)
update_create_info_from_table(create_info, &table);
name= get_canonical_filename(table.file, share.path.str, name_buff);
error= table.file->ha_create(name, &table, create_info);
(void) closefrm(&table, 0);
if (error)
{
strxmov(name_buff, db, ".", table_name, NullS);
my_error(ER_CANT_CREATE_TABLE, MYF(ME_BELL+ME_WAITTANG), name_buff, error);
#ifdef HAVE_PSI_TABLE_INTERFACE
PSI_TABLE_CALL(drop_table_share)(temp_table, db, strlen(db), table_name,
strlen(table_name));
#endif
}
err:
free_table_share(&share);
DBUG_RETURN(error != 0);
}
/**
Try to discover table from engine.
@note
If found, write the frm file to disk.
@retval
-1 Table did not exists
@retval
0 Table created ok
@retval
> 0 Error, table existed but could not be created
*/
int ha_create_table_from_engine(THD* thd, const char *db, const char *name)
{
int error;
uchar *frmblob;
size_t frmlen;
char path[FN_REFLEN + 1];
HA_CREATE_INFO create_info;
TABLE table;
TABLE_SHARE share;
DBUG_ENTER("ha_create_table_from_engine");
DBUG_PRINT("enter", ("name '%s'.'%s'", db, name));
bzero((uchar*) &create_info,sizeof(create_info));
if ((error= ha_discover(thd, db, name, &frmblob, &frmlen)))
{
/* Table could not be discovered and thus not created */
DBUG_RETURN(error);
}
/*
Table exists in handler and could be discovered
frmblob and frmlen are set, write the frm to disk
*/
build_table_filename(path, sizeof(path) - 1, db, name, "", 0);
// Save the frm file
error= writefrm(path, frmblob, frmlen);
my_free(frmblob);
if (error)
DBUG_RETURN(2);
init_tmp_table_share(thd, &share, db, 0, name, path);
if (open_table_def(thd, &share, 0))
{
DBUG_RETURN(3);
}
#ifdef HAVE_PSI_TABLE_INTERFACE
/*
Table discovery is not instrumented.
Once discovered, the table will be opened normally,
and instrumented normally.
*/
#endif
if (open_table_from_share(thd, &share, "" ,0, 0, 0, &table, FALSE))
{
free_table_share(&share);
DBUG_RETURN(3);
}
update_create_info_from_table(&create_info, &table);
create_info.table_options|= HA_OPTION_CREATE_FROM_ENGINE;
get_canonical_filename(table.file, path, path);
error=table.file->ha_create(path, &table, &create_info);
(void) closefrm(&table, 1);
DBUG_RETURN(error != 0);
}
/**
Try to find a table in a storage engine.
@param db Normalized table schema name
@param name Normalized table name.
@param[out] exists Only valid if the function succeeded.
@retval TRUE An error is found
@retval FALSE Success, check *exists
*/
bool
ha_check_if_table_exists(THD* thd, const char *db, const char *name,
bool *exists)
{
uchar *frmblob= NULL;
size_t frmlen;
DBUG_ENTER("ha_check_if_table_exists");
*exists= ! ha_discover(thd, db, name, &frmblob, &frmlen);
if (*exists)
my_free(frmblob);
DBUG_RETURN(FALSE);
}
void st_ha_check_opt::init()
{
flags= sql_flags= 0;
start_time= my_time(0);
}
/*****************************************************************************
Key cache handling.
This code is only relevant for ISAM/MyISAM tables
key_cache->cache may be 0 only in the case where a key cache is not
initialized or when we where not able to init the key cache in a previous
call to ha_init_key_cache() (probably out of memory)
*****************************************************************************/
/**
Init a key cache if it has not been initied before.
*/
int ha_init_key_cache(const char *name, KEY_CACHE *key_cache, void *unused
__attribute__((unused)))
{
DBUG_ENTER("ha_init_key_cache");
if (!key_cache->key_cache_inited)
{
mysql_mutex_lock(&LOCK_global_system_variables);
size_t tmp_buff_size= (size_t) key_cache->param_buff_size;
uint tmp_block_size= (uint) key_cache->param_block_size;
uint division_limit= (uint)key_cache->param_division_limit;
uint age_threshold= (uint)key_cache->param_age_threshold;
uint partitions= (uint)key_cache->param_partitions;
mysql_mutex_unlock(&LOCK_global_system_variables);
DBUG_RETURN(!init_key_cache(key_cache,
tmp_block_size,
tmp_buff_size,
division_limit, age_threshold,
partitions));
}
DBUG_RETURN(0);
}
/**
Resize key cache.
*/
int ha_resize_key_cache(KEY_CACHE *key_cache)
{
DBUG_ENTER("ha_resize_key_cache");
if (key_cache->key_cache_inited)
{
mysql_mutex_lock(&LOCK_global_system_variables);
size_t tmp_buff_size= (size_t) key_cache->param_buff_size;
long tmp_block_size= (long) key_cache->param_block_size;
uint division_limit= (uint)key_cache->param_division_limit;
uint age_threshold= (uint)key_cache->param_age_threshold;
mysql_mutex_unlock(&LOCK_global_system_variables);
DBUG_RETURN(!resize_key_cache(key_cache, tmp_block_size,
tmp_buff_size,
division_limit, age_threshold));
}
DBUG_RETURN(0);
}
/**
Change parameters for key cache (like division_limit)
*/
int ha_change_key_cache_param(KEY_CACHE *key_cache)
{
DBUG_ENTER("ha_change_key_cache_param");
if (key_cache->key_cache_inited)
{
mysql_mutex_lock(&LOCK_global_system_variables);
uint division_limit= (uint)key_cache->param_division_limit;
uint age_threshold= (uint)key_cache->param_age_threshold;
mysql_mutex_unlock(&LOCK_global_system_variables);
change_key_cache_param(key_cache, division_limit, age_threshold);
}
DBUG_RETURN(0);
}
/**
Repartition key cache
*/
int ha_repartition_key_cache(KEY_CACHE *key_cache)
{
DBUG_ENTER("ha_repartition_key_cache");
if (key_cache->key_cache_inited)
{
mysql_mutex_lock(&LOCK_global_system_variables);
size_t tmp_buff_size= (size_t) key_cache->param_buff_size;
long tmp_block_size= (long) key_cache->param_block_size;
uint division_limit= (uint)key_cache->param_division_limit;
uint age_threshold= (uint)key_cache->param_age_threshold;
uint partitions= (uint)key_cache->param_partitions;
mysql_mutex_unlock(&LOCK_global_system_variables);
DBUG_RETURN(!repartition_key_cache(key_cache, tmp_block_size,
tmp_buff_size,
division_limit, age_threshold,
partitions));
}
DBUG_RETURN(0);
}
/**
Move all tables from one key cache to another one.
*/
int ha_change_key_cache(KEY_CACHE *old_key_cache,
KEY_CACHE *new_key_cache)
{
mi_change_key_cache(old_key_cache, new_key_cache);
return 0;
}
/**
Try to discover one table from handler(s).
@retval
-1 Table did not exists
@retval
0 OK. In this case *frmblob and *frmlen are set
@retval
>0 error. frmblob and frmlen may not be set
*/
struct st_discover_args
{
const char *db;
const char *name;
uchar **frmblob;
size_t *frmlen;
};
static my_bool discover_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
st_discover_args *vargs= (st_discover_args *)arg;
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->discover &&
(!(hton->discover(hton, thd, vargs->db, vargs->name,
vargs->frmblob,
vargs->frmlen))))
return TRUE;
return FALSE;
}
int ha_discover(THD *thd, const char *db, const char *name,
uchar **frmblob, size_t *frmlen)
{
int error= -1; // Table does not exist in any handler
DBUG_ENTER("ha_discover");
DBUG_PRINT("enter", ("db: %s, name: %s", db, name));
st_discover_args args= {db, name, frmblob, frmlen};
if (is_prefix(name,tmp_file_prefix)) /* skip temporary tables */
DBUG_RETURN(error);
if (plugin_foreach(thd, discover_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &args))
error= 0;
if (!error)
status_var_increment(thd->status_var.ha_discover_count);
DBUG_RETURN(error);
}
/**
Call this function in order to give the handler the possiblity
to ask engine if there are any new tables that should be written to disk
or any dropped tables that need to be removed from disk
*/
struct st_find_files_args
{
const char *db;
const char *path;
const char *wild;
bool dir;
List<LEX_STRING> *files;
};
static my_bool find_files_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
st_find_files_args *vargs= (st_find_files_args *)arg;
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->find_files)
if (hton->find_files(hton, thd, vargs->db, vargs->path, vargs->wild,
vargs->dir, vargs->files))
return TRUE;
return FALSE;
}
int
ha_find_files(THD *thd,const char *db,const char *path,
const char *wild, bool dir, List<LEX_STRING> *files)
{
int error= 0;
DBUG_ENTER("ha_find_files");
DBUG_PRINT("enter", ("db: '%s' path: '%s' wild: '%s' dir: %d",
db, path, wild, dir));
st_find_files_args args= {db, path, wild, dir, files};
plugin_foreach(thd, find_files_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &args);
/* The return value is not currently used */
DBUG_RETURN(error);
}
/**
Ask handler if the table exists in engine.
@retval
HA_ERR_NO_SUCH_TABLE Table does not exist
@retval
HA_ERR_TABLE_EXIST Table exists
@retval
\# Error code
*/
struct st_table_exists_in_engine_args
{
const char *db;
const char *name;
int err;
};
static my_bool table_exists_in_engine_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
st_table_exists_in_engine_args *vargs= (st_table_exists_in_engine_args *)arg;
handlerton *hton= plugin_data(plugin, handlerton *);
int err= HA_ERR_NO_SUCH_TABLE;
if (hton->state == SHOW_OPTION_YES && hton->table_exists_in_engine)
err = hton->table_exists_in_engine(hton, thd, vargs->db, vargs->name);
vargs->err = err;
if (vargs->err == HA_ERR_TABLE_EXIST)
return TRUE;
return FALSE;
}
int ha_table_exists_in_engine(THD* thd, const char* db, const char* name)
{
DBUG_ENTER("ha_table_exists_in_engine");
DBUG_PRINT("enter", ("db: %s, name: %s", db, name));
st_table_exists_in_engine_args args= {db, name, HA_ERR_NO_SUCH_TABLE};
plugin_foreach(thd, table_exists_in_engine_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &args);
DBUG_PRINT("exit", ("error: %d", args.err));
DBUG_RETURN(args.err);
}
#ifdef HAVE_NDB_BINLOG
/*
TODO: change this into a dynamic struct
List<handlerton> does not work as
1. binlog_end is called when MEM_ROOT is gone
2. cannot work with thd MEM_ROOT as memory should be freed
*/
#define MAX_HTON_LIST_ST 63
struct hton_list_st
{
handlerton *hton[MAX_HTON_LIST_ST];
uint sz;
};
struct binlog_func_st
{
enum_binlog_func fn;
void *arg;
};
/** @brief
Listing handlertons first to avoid recursive calls and deadlock
*/
static my_bool binlog_func_list(THD *thd, plugin_ref plugin, void *arg)
{
hton_list_st *hton_list= (hton_list_st *)arg;
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->binlog_func)
{
uint sz= hton_list->sz;
if (sz == MAX_HTON_LIST_ST-1)
{
/* list full */
return FALSE;
}
hton_list->hton[sz]= hton;
hton_list->sz= sz+1;
}
return FALSE;
}
static my_bool binlog_func_foreach(THD *thd, binlog_func_st *bfn)
{
hton_list_st hton_list;
uint i, sz;
hton_list.sz= 0;
plugin_foreach(thd, binlog_func_list,
MYSQL_STORAGE_ENGINE_PLUGIN, &hton_list);
for (i= 0, sz= hton_list.sz; i < sz ; i++)
hton_list.hton[i]->binlog_func(hton_list.hton[i], thd, bfn->fn, bfn->arg);
return FALSE;
}
int ha_reset_logs(THD *thd)
{
binlog_func_st bfn= {BFN_RESET_LOGS, 0};
binlog_func_foreach(thd, &bfn);
return 0;
}
void ha_reset_slave(THD* thd)
{
binlog_func_st bfn= {BFN_RESET_SLAVE, 0};
binlog_func_foreach(thd, &bfn);
}
void ha_binlog_wait(THD* thd)
{
binlog_func_st bfn= {BFN_BINLOG_WAIT, 0};
binlog_func_foreach(thd, &bfn);
}
int ha_binlog_end(THD* thd)
{
binlog_func_st bfn= {BFN_BINLOG_END, 0};
binlog_func_foreach(thd, &bfn);
return 0;
}
int ha_binlog_index_purge_file(THD *thd, const char *file)
{
binlog_func_st bfn= {BFN_BINLOG_PURGE_FILE, (void *)file};
binlog_func_foreach(thd, &bfn);
return 0;
}
struct binlog_log_query_st
{
enum_binlog_command binlog_command;
const char *query;
uint query_length;
const char *db;
const char *table_name;
};
static my_bool binlog_log_query_handlerton2(THD *thd,
handlerton *hton,
void *args)
{
struct binlog_log_query_st *b= (struct binlog_log_query_st*)args;
if (hton->state == SHOW_OPTION_YES && hton->binlog_log_query)
hton->binlog_log_query(hton, thd,
b->binlog_command,
b->query,
b->query_length,
b->db,
b->table_name);
return FALSE;
}
static my_bool binlog_log_query_handlerton(THD *thd,
plugin_ref plugin,
void *args)
{
return binlog_log_query_handlerton2(thd, plugin_data(plugin, handlerton *), args);
}
void ha_binlog_log_query(THD *thd, handlerton *hton,
enum_binlog_command binlog_command,
const char *query, uint query_length,
const char *db, const char *table_name)
{
struct binlog_log_query_st b;
b.binlog_command= binlog_command;
b.query= query;
b.query_length= query_length;
b.db= db;
b.table_name= table_name;
if (hton == 0)
plugin_foreach(thd, binlog_log_query_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &b);
else
binlog_log_query_handlerton2(thd, hton, &b);
}
#endif
/**
Read first row between two ranges.
Store ranges for future calls to read_range_next.
@param start_key Start key. Is 0 if no min range
@param end_key End key. Is 0 if no max range
@param eq_range_arg Set to 1 if start_key == end_key
@param sorted Set to 1 if result should be sorted per key
@note
Record is read into table->record[0]
@retval
0 Found row
@retval
HA_ERR_END_OF_FILE No rows in range
@retval
\# Error code
*/
int handler::read_range_first(const key_range *start_key,
const key_range *end_key,
bool eq_range_arg, bool sorted)
{
int result;
DBUG_ENTER("handler::read_range_first");
eq_range= eq_range_arg;
end_range= 0;
if (end_key)
{
end_range= &save_end_range;
save_end_range= *end_key;
key_compare_result_on_equal= ((end_key->flag == HA_READ_BEFORE_KEY) ? 1 :
(end_key->flag == HA_READ_AFTER_KEY) ? -1 : 0);
}
range_key_part= table->key_info[active_index].key_part;
if (!start_key) // Read first record
result= ha_index_first(table->record[0]);
else
result= ha_index_read_map(table->record[0],
start_key->key,
start_key->keypart_map,
start_key->flag);
if (result)
DBUG_RETURN((result == HA_ERR_KEY_NOT_FOUND)
? HA_ERR_END_OF_FILE
: result);
if (compare_key(end_range) <= 0)
{
DBUG_RETURN(0);
}
else
{
/*
The last read row does not fall in the range. So request
storage engine to release row lock if possible.
*/
unlock_row();
DBUG_RETURN(HA_ERR_END_OF_FILE);
}
}
/**
Read next row between two ranges.
@note
Record is read into table->record[0]
@retval
0 Found row
@retval
HA_ERR_END_OF_FILE No rows in range
@retval
\# Error code
*/
int handler::read_range_next()
{
int result;
DBUG_ENTER("handler::read_range_next");
if (eq_range)
{
/* We trust that index_next_same always gives a row in range */
DBUG_RETURN(ha_index_next_same(table->record[0],
end_range->key,
end_range->length));
}
result= ha_index_next(table->record[0]);
if (result)
DBUG_RETURN(result);
if (compare_key(end_range) <= 0)
{
DBUG_RETURN(0);
}
else
{
/*
The last read row does not fall in the range. So request
storage engine to release row lock if possible.
*/
unlock_row();
DBUG_RETURN(HA_ERR_END_OF_FILE);
}
}
/**
Compare if found key (in row) is over max-value.
@param range range to compare to row. May be 0 for no range
@seealso
key.cc::key_cmp()
@return
The return value is SIGN(key_in_row - range_key):
- 0 : Key is equal to range or 'range' == 0 (no range)
- -1 : Key is less than range
- 1 : Key is larger than range
*/
int handler::compare_key(key_range *range)
{
int cmp;
if (!range || in_range_check_pushed_down)
return 0; // No max range
cmp= key_cmp(range_key_part, range->key, range->length);
if (!cmp)
cmp= key_compare_result_on_equal;
return cmp;
}
/*
Same as compare_key() but doesn't check have in_range_check_pushed_down.
This is used by index condition pushdown implementation.
*/
int handler::compare_key2(key_range *range)
{
int cmp;
if (!range)
return 0; // no max range
cmp= key_cmp(range_key_part, range->key, range->length);
if (!cmp)
cmp= key_compare_result_on_equal;
return cmp;
}
/**
ICP callback - to be called by an engine to check the pushed condition
*/
extern "C" enum icp_result handler_index_cond_check(void* h_arg)
{
handler *h= (handler*)h_arg;
THD *thd= h->table->in_use;
enum icp_result res;
enum thd_kill_levels abort_at= h->has_transactions() ?
THD_ABORT_SOFTLY : THD_ABORT_ASAP;
if (thd_kill_level(thd) > abort_at)
return ICP_ABORTED_BY_USER;
if (h->end_range && h->compare_key2(h->end_range) > 0)
return ICP_OUT_OF_RANGE;
h->increment_statistics(&SSV::ha_icp_attempts);
if ((res= h->pushed_idx_cond->val_int()? ICP_MATCH : ICP_NO_MATCH) ==
ICP_MATCH)
h->increment_statistics(&SSV::ha_icp_match);
return res;
}
int handler::index_read_idx_map(uchar * buf, uint index, const uchar * key,
key_part_map keypart_map,
enum ha_rkey_function find_flag)
{
int error, error1;
LINT_INIT(error1);
error= ha_index_init(index, 0);
if (!error)
{
error= index_read_map(buf, key, keypart_map, find_flag);
error1= ha_index_end();
}
return error ? error : error1;
}
/**
Returns a list of all known extensions.
No mutexes, worst case race is a minor surplus memory allocation
We have to recreate the extension map if mysqld is restarted (for example
within libmysqld)
@retval
pointer pointer to TYPELIB structure
*/
static my_bool exts_handlerton(THD *unused, plugin_ref plugin,
void *arg)
{
List<char> *found_exts= (List<char> *) arg;
handlerton *hton= plugin_data(plugin, handlerton *);
handler *file;
if (hton->state == SHOW_OPTION_YES && hton->create &&
(file= hton->create(hton, (TABLE_SHARE*) 0, current_thd->mem_root)))
{
List_iterator_fast<char> it(*found_exts);
const char **ext, *old_ext;
for (ext= file->bas_ext(); *ext; ext++)
{
while ((old_ext= it++))
{
if (!strcmp(old_ext, *ext))
break;
}
if (!old_ext)
found_exts->push_back((char *) *ext);
it.rewind();
}
delete file;
}
return FALSE;
}
TYPELIB *ha_known_exts(void)
{
if (!known_extensions.type_names || mysys_usage_id != known_extensions_id)
{
List<char> found_exts;
const char **ext, *old_ext;
known_extensions_id= mysys_usage_id;
found_exts.push_back((char*) TRG_EXT);
found_exts.push_back((char*) TRN_EXT);
plugin_foreach(NULL, exts_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &found_exts);
ext= (const char **) my_once_alloc(sizeof(char *)*
(found_exts.elements+1),
MYF(MY_WME | MY_FAE));
DBUG_ASSERT(ext != 0);
known_extensions.count= found_exts.elements;
known_extensions.type_names= ext;
List_iterator_fast<char> it(found_exts);
while ((old_ext= it++))
*ext++= old_ext;
*ext= 0;
}
return &known_extensions;
}
static bool stat_print(THD *thd, const char *type, uint type_len,
const char *file, uint file_len,
const char *status, uint status_len)
{
Protocol *protocol= thd->protocol;
protocol->prepare_for_resend();
protocol->store(type, type_len, system_charset_info);
protocol->store(file, file_len, system_charset_info);
protocol->store(status, status_len, system_charset_info);
if (protocol->write())
return TRUE;
return FALSE;
}
static my_bool showstat_handlerton(THD *thd, plugin_ref plugin,
void *arg)
{
enum ha_stat_type stat= *(enum ha_stat_type *) arg;
handlerton *hton= plugin_data(plugin, handlerton *);
if (hton->state == SHOW_OPTION_YES && hton->show_status &&
hton->show_status(hton, thd, stat_print, stat))
return TRUE;
return FALSE;
}
bool ha_show_status(THD *thd, handlerton *db_type, enum ha_stat_type stat)
{
List<Item> field_list;
Protocol *protocol= thd->protocol;
bool result;
field_list.push_back(new Item_empty_string("Type",10));
field_list.push_back(new Item_empty_string("Name",FN_REFLEN));
field_list.push_back(new Item_empty_string("Status",10));
if (protocol->send_result_set_metadata(&field_list,
Protocol::SEND_NUM_ROWS | Protocol::SEND_EOF))
return TRUE;
if (db_type == NULL)
{
result= plugin_foreach(thd, showstat_handlerton,
MYSQL_STORAGE_ENGINE_PLUGIN, &stat);
}
else
{
if (db_type->state != SHOW_OPTION_YES)
{
const LEX_STRING *name= hton_name(db_type);
result= stat_print(thd, name->str, name->length,
"", 0, "DISABLED", 8) ? 1 : 0;
}
else
result= db_type->show_status &&
db_type->show_status(db_type, thd, stat_print, stat) ? 1 : 0;
}
/*
We also check thd->is_error() as Innodb may return 0 even if
there was an error.
*/
if (!result && !thd->is_error())
my_eof(thd);
else if (!thd->is_error())
my_error(ER_GET_ERRNO, MYF(0), errno);
return result;
}
/*
Function to check if the conditions for row-based binlogging is
correct for the table.
A row in the given table should be replicated if:
- Row-based replication is enabled in the current thread
- The binlog is enabled
- It is not a temporary table
- The binary log is open
- The database the table resides in shall be binlogged (binlog_*_db rules)
- table is not mysql.event
*/
static bool check_table_binlog_row_based(THD *thd, TABLE *table)
{
if (table->s->cached_row_logging_check == -1)
{
int const check(table->s->tmp_table == NO_TMP_TABLE &&
binlog_filter->db_ok(table->s->db.str));
table->s->cached_row_logging_check= check;
}
DBUG_ASSERT(table->s->cached_row_logging_check == 0 ||
table->s->cached_row_logging_check == 1);
return (thd->is_current_stmt_binlog_format_row() &&
table->s->cached_row_logging_check &&
(thd->variables.option_bits & OPTION_BIN_LOG) &&
mysql_bin_log.is_open());
}
/** @brief
Write table maps for all (manually or automatically) locked tables
to the binary log. Also, if binlog_annotate_row_events is ON,
write Annotate_rows event before the first table map.
SYNOPSIS
write_locked_table_maps()
thd Pointer to THD structure
DESCRIPTION
This function will generate and write table maps for all tables
that are locked by the thread 'thd'.
RETURN VALUE
0 All OK
1 Failed to write all table maps
SEE ALSO
THD::lock
*/
static int write_locked_table_maps(THD *thd)
{
DBUG_ENTER("write_locked_table_maps");
DBUG_PRINT("enter", ("thd: 0x%lx thd->lock: 0x%lx "
"thd->extra_lock: 0x%lx",
(long) thd, (long) thd->lock, (long) thd->extra_lock));
DBUG_PRINT("debug", ("get_binlog_table_maps(): %d", thd->get_binlog_table_maps()));
if (thd->get_binlog_table_maps() == 0)
{
MYSQL_LOCK *locks[2];
locks[0]= thd->extra_lock;
locks[1]= thd->lock;
my_bool with_annotate= thd->variables.binlog_annotate_row_events &&
thd->query() && thd->query_length();
for (uint i= 0 ; i < sizeof(locks)/sizeof(*locks) ; ++i )
{
MYSQL_LOCK const *const lock= locks[i];
if (lock == NULL)
continue;
TABLE **const end_ptr= lock->table + lock->table_count;
for (TABLE **table_ptr= lock->table ;
table_ptr != end_ptr ;
++table_ptr)
{
TABLE *const table= *table_ptr;
DBUG_PRINT("info", ("Checking table %s", table->s->table_name.str));
if (table->current_lock == F_WRLCK &&
check_table_binlog_row_based(thd, table))
{
/*
We need to have a transactional behavior for SQLCOM_CREATE_TABLE
(e.g. CREATE TABLE... SELECT * FROM TABLE) in order to keep a
compatible behavior with the STMT based replication even when
the table is not transactional. In other words, if the operation
fails while executing the insert phase nothing is written to the
binlog.
Note that at this point, we check the type of a set of tables to
create the table map events. In the function binlog_log_row(),
which calls the current function, we check the type of the table
of the current row.
*/
bool const has_trans= thd->lex->sql_command == SQLCOM_CREATE_TABLE ||
table->file->has_transactions();
int const error= thd->binlog_write_table_map(table, has_trans,
&with_annotate);
/*
If an error occurs, it is the responsibility of the caller to
roll back the transaction.
*/
if (unlikely(error))
DBUG_RETURN(1);
}
}
}
}
DBUG_RETURN(0);
}
typedef bool Log_func(THD*, TABLE*, bool, MY_BITMAP*,
uint, const uchar*, const uchar*);
static int binlog_log_row(TABLE* table,
const uchar *before_record,
const uchar *after_record,
Log_func *log_func)
{
if (table->no_replicate)
return 0;
bool error= 0;
THD *const thd= table->in_use;
if (check_table_binlog_row_based(thd, table))
{
MY_BITMAP cols;
/* Potential buffer on the stack for the bitmap */
uint32 bitbuf[BITMAP_STACKBUF_SIZE/sizeof(uint32)];
uint n_fields= table->s->fields;
my_bool use_bitbuf= n_fields <= sizeof(bitbuf)*8;
/*
If there are no table maps written to the binary log, this is
the first row handled in this statement. In that case, we need
to write table maps for all locked tables to the binary log.
*/
if (likely(!(error= bitmap_init(&cols,
use_bitbuf ? bitbuf : NULL,
(n_fields + 7) & ~7UL,
FALSE))))
{
bitmap_set_all(&cols);
if (likely(!(error= write_locked_table_maps(thd))))
{
/*
We need to have a transactional behavior for SQLCOM_CREATE_TABLE
(i.e. CREATE TABLE... SELECT * FROM TABLE) in order to keep a
compatible behavior with the STMT based replication even when
the table is not transactional. In other words, if the operation
fails while executing the insert phase nothing is written to the
binlog.
*/
bool const has_trans= thd->lex->sql_command == SQLCOM_CREATE_TABLE ||
table->file->has_transactions();
error= (*log_func)(thd, table, has_trans, &cols, table->s->fields,
before_record, after_record);
}
if (!use_bitbuf)
bitmap_free(&cols);
}
}
return error ? HA_ERR_RBR_LOGGING_FAILED : 0;
}
int handler::ha_external_lock(THD *thd, int lock_type)
{
int error;
DBUG_ENTER("handler::ha_external_lock");
/*
Whether this is lock or unlock, this should be true, and is to verify that
if get_auto_increment() was called (thus may have reserved intervals or
taken a table lock), ha_release_auto_increment() was too.
*/
DBUG_ASSERT(next_insert_id == 0);
/* Consecutive calls for lock without unlocking in between is not allowed */
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
((lock_type != F_UNLCK && m_lock_type == F_UNLCK) ||
lock_type == F_UNLCK));
/* SQL HANDLER call locks/unlock while scanning (RND/INDEX). */
DBUG_ASSERT(inited == NONE || table->open_by_handler);
if (MYSQL_HANDLER_RDLOCK_START_ENABLED() ||
MYSQL_HANDLER_WRLOCK_START_ENABLED() ||
MYSQL_HANDLER_UNLOCK_START_ENABLED())
{
if (lock_type == F_RDLCK)
{
MYSQL_HANDLER_RDLOCK_START(table_share->db.str,
table_share->table_name.str);
}
else if (lock_type == F_WRLCK)
{
MYSQL_HANDLER_WRLOCK_START(table_share->db.str,
table_share->table_name.str);
}
else if (lock_type == F_UNLCK)
{
MYSQL_HANDLER_UNLOCK_START(table_share->db.str,
table_share->table_name.str);
}
}
ha_statistic_increment(&SSV::ha_external_lock_count);
/*
We cache the table flags if the locking succeeded. Otherwise, we
keep them as they were when they were fetched in ha_open().
*/
MYSQL_TABLE_LOCK_WAIT(m_psi, PSI_TABLE_EXTERNAL_LOCK, lock_type,
{ error= external_lock(thd, lock_type); })
if (error == 0)
{
/*
The lock type is needed by MRR when creating a clone of this handler
object and for assert checking.
*/
m_lock_type= lock_type;
cached_table_flags= table_flags();
}
if (MYSQL_HANDLER_RDLOCK_DONE_ENABLED() ||
MYSQL_HANDLER_WRLOCK_DONE_ENABLED() ||
MYSQL_HANDLER_UNLOCK_DONE_ENABLED())
{
if (lock_type == F_RDLCK)
{
MYSQL_HANDLER_RDLOCK_DONE(error);
}
else if (lock_type == F_WRLCK)
{
MYSQL_HANDLER_WRLOCK_DONE(error);
}
else if (lock_type == F_UNLCK)
{
MYSQL_HANDLER_UNLOCK_DONE(error);
}
}
DBUG_RETURN(error);
}
/** @brief
Check handler usage and reset state of file to after 'open'
*/
int handler::ha_reset()
{
DBUG_ENTER("ha_reset");
/* Check that we have called all proper deallocation functions */
DBUG_ASSERT((uchar*) table->def_read_set.bitmap +
table->s->column_bitmap_size ==
(uchar*) table->def_write_set.bitmap);
DBUG_ASSERT(bitmap_is_set_all(&table->s->all_set));
DBUG_ASSERT(table->key_read == 0);
/* ensure that ha_index_end / ha_rnd_end has been called */
DBUG_ASSERT(inited == NONE);
/* Free cache used by filesort */
free_io_cache(table);
/* reset the bitmaps to point to defaults */
table->default_column_bitmaps();
pushed_cond= NULL;
/* Reset information about pushed engine conditions */
cancel_pushed_idx_cond();
/* Reset information about pushed index conditions */
DBUG_RETURN(reset());
}
int handler::ha_write_row(uchar *buf)
{
int error;
Log_func *log_func= Write_rows_log_event::binlog_row_logging_function;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
DBUG_ENTER("handler::ha_write_row");
DEBUG_SYNC_C("ha_write_row_start");
MYSQL_INSERT_ROW_START(table_share->db.str, table_share->table_name.str);
mark_trx_read_write();
increment_statistics(&SSV::ha_write_count);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_WRITE_ROW, MAX_KEY, 0,
{ error= write_row(buf); })
MYSQL_INSERT_ROW_DONE(error);
if (unlikely(error))
DBUG_RETURN(error);
rows_changed++;
if (unlikely(error= binlog_log_row(table, 0, buf, log_func)))
DBUG_RETURN(error); /* purecov: inspected */
DEBUG_SYNC_C("ha_write_row_end");
DBUG_RETURN(0);
}
int handler::ha_update_row(const uchar *old_data, uchar *new_data)
{
int error;
Log_func *log_func= Update_rows_log_event::binlog_row_logging_function;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
/*
Some storage engines require that the new record is in record[0]
(and the old record is in record[1]).
*/
DBUG_ASSERT(new_data == table->record[0]);
MYSQL_UPDATE_ROW_START(table_share->db.str, table_share->table_name.str);
mark_trx_read_write();
increment_statistics(&SSV::ha_update_count);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_UPDATE_ROW, active_index, 0,
{ error= update_row(old_data, new_data);})
MYSQL_UPDATE_ROW_DONE(error);
if (unlikely(error))
return error;
rows_changed++;
if (unlikely(error= binlog_log_row(table, old_data, new_data, log_func)))
return error;
return 0;
}
int handler::ha_delete_row(const uchar *buf)
{
int error;
Log_func *log_func= Delete_rows_log_event::binlog_row_logging_function;
DBUG_ASSERT(table_share->tmp_table != NO_TMP_TABLE ||
m_lock_type == F_WRLCK);
MYSQL_DELETE_ROW_START(table_share->db.str, table_share->table_name.str);
mark_trx_read_write();
increment_statistics(&SSV::ha_delete_count);
MYSQL_TABLE_IO_WAIT(m_psi, PSI_TABLE_DELETE_ROW, active_index, 0,
{ error= delete_row(buf);})
MYSQL_DELETE_ROW_DONE(error);
if (unlikely(error))
return error;
rows_changed++;
if (unlikely(error= binlog_log_row(table, buf, 0, log_func)))
return error;
return 0;
}
/** @brief
use_hidden_primary_key() is called in case of an update/delete when
(table_flags() and HA_PRIMARY_KEY_REQUIRED_FOR_DELETE) is defined
but we don't have a primary key
*/
void handler::use_hidden_primary_key()
{
/* fallback to use all columns in the table to identify row */
table->column_bitmaps_set(&table->s->all_set, table->write_set);
}
/**
Get an initialized ha_share.
@return Initialized ha_share
@retval NULL ha_share is not yet initialized.
@retval != NULL previous initialized ha_share.
@note
If not a temp table, then LOCK_ha_data must be held.
*/
Handler_share *handler::get_ha_share_ptr()
{
DBUG_ENTER("handler::get_ha_share_ptr");
DBUG_ASSERT(ha_share && table_share);
#ifndef DBUG_OFF
if (table_share->tmp_table == NO_TMP_TABLE)
mysql_mutex_assert_owner(&table_share->LOCK_ha_data);
#endif
DBUG_RETURN(*ha_share);
}
/**
Set ha_share to be used by all instances of the same table/partition.
@param ha_share Handler_share to be shared.
@note
If not a temp table, then LOCK_ha_data must be held.
*/
void handler::set_ha_share_ptr(Handler_share *arg_ha_share)
{
DBUG_ENTER("handler::set_ha_share_ptr");
DBUG_ASSERT(ha_share);
#ifndef DBUG_OFF
if (table_share->tmp_table == NO_TMP_TABLE)
mysql_mutex_assert_owner(&table_share->LOCK_ha_data);
#endif
*ha_share= arg_ha_share;
DBUG_VOID_RETURN;
}
/**
Take a lock for protecting shared handler data.
*/
void handler::lock_shared_ha_data()
{
DBUG_ASSERT(table_share);
if (table_share->tmp_table == NO_TMP_TABLE)
mysql_mutex_lock(&table_share->LOCK_ha_data);
}
/**
Release lock for protecting ha_share.
*/
void handler::unlock_shared_ha_data()
{
DBUG_ASSERT(table_share);
if (table_share->tmp_table == NO_TMP_TABLE)
mysql_mutex_unlock(&table_share->LOCK_ha_data);
}
/** @brief
Dummy function which accept information about log files which is not need
by handlers
*/
void signal_log_not_needed(struct handlerton, char *log_file)
{
DBUG_ENTER("signal_log_not_needed");
DBUG_PRINT("enter", ("logfile '%s'", log_file));
DBUG_VOID_RETURN;
}
#ifdef TRANS_LOG_MGM_EXAMPLE_CODE
/*
Example of transaction log management functions based on assumption that logs
placed into a directory
*/
#include <my_dir.h>
#include <my_sys.h>
int example_of_iterator_using_for_logs_cleanup(handlerton *hton)
{
void *buffer;
int res= 1;
struct handler_iterator iterator;
struct handler_log_file_data data;
if (!hton->create_iterator)
return 1; /* iterator creator is not supported */
if ((*hton->create_iterator)(hton, HA_TRANSACTLOG_ITERATOR, &iterator) !=
HA_ITERATOR_OK)
{
/* error during creation of log iterator or iterator is not supported */
return 1;
}
while((*iterator.next)(&iterator, (void*)&data) == 0)
{
printf("%s\n", data.filename.str);
if (data.status == HA_LOG_STATUS_FREE &&
mysql_file_delete(INSTRUMENT_ME,
data.filename.str, MYF(MY_WME)))
goto err;
}
res= 0;
err:
(*iterator.destroy)(&iterator);
return res;
}
/*
Here we should get info from handler where it save logs but here is
just example, so we use constant.
IMHO FN_ROOTDIR ("/") is safe enough for example, because nobody has
rights on it except root and it consist of directories only at lest for
*nix (sorry, can't find windows-safe solution here, but it is only example).
*/
#define fl_dir FN_ROOTDIR
/** @brief
Dummy function to return log status should be replaced by function which
really detect the log status and check that the file is a log of this
handler.
*/
enum log_status fl_get_log_status(char *log)
{
MY_STAT stat_buff;
if (mysql_file_stat(INSTRUMENT_ME, log, &stat_buff, MYF(0)))
return HA_LOG_STATUS_INUSE;
return HA_LOG_STATUS_NOSUCHLOG;
}
struct fl_buff
{
LEX_STRING *names;
enum log_status *statuses;
uint32 entries;
uint32 current;
};
int fl_log_iterator_next(struct handler_iterator *iterator,
void *iterator_object)
{
struct fl_buff *buff= (struct fl_buff *)iterator->buffer;
struct handler_log_file_data *data=
(struct handler_log_file_data *) iterator_object;
if (buff->current >= buff->entries)
return 1;
data->filename= buff->names[buff->current];
data->status= buff->statuses[buff->current];
buff->current++;
return 0;
}
void fl_log_iterator_destroy(struct handler_iterator *iterator)
{
my_free(iterator->buffer);
}
/** @brief
returns buffer, to be assigned in handler_iterator struct
*/
enum handler_create_iterator_result
fl_log_iterator_buffer_init(struct handler_iterator *iterator)
{
MY_DIR *dirp;
struct fl_buff *buff;
char *name_ptr;
uchar *ptr;
FILEINFO *file;
uint32 i;
/* to be able to make my_free without crash in case of error */
iterator->buffer= 0;
if (!(dirp = my_dir(fl_dir, MYF(MY_THREAD_SPECIFIC))))
{
return HA_ITERATOR_ERROR;
}
if ((ptr= (uchar*)my_malloc(ALIGN_SIZE(sizeof(fl_buff)) +
((ALIGN_SIZE(sizeof(LEX_STRING)) +
sizeof(enum log_status) +
+ FN_REFLEN + 1) *
(uint) dirp->number_off_files),
MYF(MY_THREAD_SPECIFIC))) == 0)
{
return HA_ITERATOR_ERROR;
}
buff= (struct fl_buff *)ptr;
buff->entries= buff->current= 0;
ptr= ptr + (ALIGN_SIZE(sizeof(fl_buff)));
buff->names= (LEX_STRING*) (ptr);
ptr= ptr + ((ALIGN_SIZE(sizeof(LEX_STRING)) *
(uint) dirp->number_off_files));
buff->statuses= (enum log_status *)(ptr);
name_ptr= (char *)(ptr + (sizeof(enum log_status) *
(uint) dirp->number_off_files));
for (i=0 ; i < (uint) dirp->number_off_files ; i++)
{
enum log_status st;
file= dirp->dir_entry + i;
if ((file->name[0] == '.' &&
((file->name[1] == '.' && file->name[2] == '\0') ||
file->name[1] == '\0')))
continue;
if ((st= fl_get_log_status(file->name)) == HA_LOG_STATUS_NOSUCHLOG)
continue;
name_ptr= strxnmov(buff->names[buff->entries].str= name_ptr,
FN_REFLEN, fl_dir, file->name, NullS);
buff->names[buff->entries].length= (name_ptr -
buff->names[buff->entries].str);
buff->statuses[buff->entries]= st;
buff->entries++;
}
iterator->buffer= buff;
iterator->next= &fl_log_iterator_next;
iterator->destroy= &fl_log_iterator_destroy;
my_dirend(dirp);
return HA_ITERATOR_OK;
}
/* An example of a iterator creator */
enum handler_create_iterator_result
fl_create_iterator(enum handler_iterator_type type,
struct handler_iterator *iterator)
{
switch(type) {
case HA_TRANSACTLOG_ITERATOR:
return fl_log_iterator_buffer_init(iterator);
default:
return HA_ITERATOR_UNSUPPORTED;
}
}
#endif /*TRANS_LOG_MGM_EXAMPLE_CODE*/
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