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|
/*
Copyright (c) 2000, 2015, Oracle and/or its affiliates.
Copyright (c) 2008, 2017, MariaDB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*****************************************************************************
**
** This file implements classes defined in sql_class.h
** Especially the classes to handle a result from a select
**
*****************************************************************************/
#ifdef USE_PRAGMA_IMPLEMENTATION
#pragma implementation // gcc: Class implementation
#endif
#include <my_global.h> /* NO_EMBEDDED_ACCESS_CHECKS */
#include "sql_priv.h"
#include "sql_class.h"
#include "sql_cache.h" // query_cache_abort
#include "sql_base.h" // close_thread_tables
#include "sql_time.h" // date_time_format_copy
#include "tztime.h" // MYSQL_TIME <-> my_time_t
#include "sql_acl.h" // NO_ACCESS,
// acl_getroot_no_password
#include "sql_base.h" // close_temporary_tables
#include "sql_handler.h" // mysql_ha_cleanup
#include "rpl_rli.h"
#include "rpl_filter.h"
#include "rpl_record.h"
#include "slave.h"
#include <my_bitmap.h>
#include "log_event.h"
#include "sql_audit.h"
#include <m_ctype.h>
#include <sys/stat.h>
#include <thr_alarm.h>
#ifdef __WIN__
#include <io.h>
#endif
#include <mysys_err.h>
#include <limits.h>
#include "sp_rcontext.h"
#include "sp_cache.h"
#include "transaction.h"
#include "sql_select.h" /* declares create_tmp_table() */
#include "debug_sync.h"
#include "sql_parse.h" // is_update_query
#include "sql_callback.h"
#include "lock.h"
#include "wsrep_mysqld.h"
#include "wsrep_thd.h"
#include "sql_connect.h"
#include "my_atomic.h"
#ifdef HAVE_SYS_SYSCALL_H
#include <sys/syscall.h>
#endif
/*
The following is used to initialise Table_ident with a internal
table name
*/
char internal_table_name[2]= "*";
char empty_c_string[1]= {0}; /* used for not defined db */
const char * const THD::DEFAULT_WHERE= "field list";
/****************************************************************************
** User variables
****************************************************************************/
extern "C" uchar *get_var_key(user_var_entry *entry, size_t *length,
my_bool not_used __attribute__((unused)))
{
*length= entry->name.length;
return (uchar*) entry->name.str;
}
extern "C" void free_user_var(user_var_entry *entry)
{
char *pos= (char*) entry+ALIGN_SIZE(sizeof(*entry));
if (entry->value && entry->value != pos)
my_free(entry->value);
my_free(entry);
}
bool Key_part_spec::operator==(const Key_part_spec& other) const
{
return length == other.length &&
!my_strcasecmp(system_charset_info, field_name.str,
other.field_name.str);
}
/**
Construct an (almost) deep copy of this key. Only those
elements that are known to never change are not copied.
If out of memory, a partial copy is returned and an error is set
in THD.
*/
Key::Key(const Key &rhs, MEM_ROOT *mem_root)
:DDL_options(rhs),type(rhs.type),
key_create_info(rhs.key_create_info),
columns(rhs.columns, mem_root),
name(rhs.name),
option_list(rhs.option_list),
generated(rhs.generated)
{
list_copy_and_replace_each_value(columns, mem_root);
}
/**
Construct an (almost) deep copy of this foreign key. Only those
elements that are known to never change are not copied.
If out of memory, a partial copy is returned and an error is set
in THD.
*/
Foreign_key::Foreign_key(const Foreign_key &rhs, MEM_ROOT *mem_root)
:Key(rhs,mem_root),
ref_db(rhs.ref_db),
ref_table(rhs.ref_table),
ref_columns(rhs.ref_columns,mem_root),
delete_opt(rhs.delete_opt),
update_opt(rhs.update_opt),
match_opt(rhs.match_opt)
{
list_copy_and_replace_each_value(ref_columns, mem_root);
}
/*
Test if a foreign key (= generated key) is a prefix of the given key
(ignoring key name, key type and order of columns)
NOTES:
This is only used to test if an index for a FOREIGN KEY exists
IMPLEMENTATION
We only compare field names
RETURN
0 Generated key is a prefix of other key
1 Not equal
*/
bool foreign_key_prefix(Key *a, Key *b)
{
/* Ensure that 'a' is the generated key */
if (a->generated)
{
if (b->generated && a->columns.elements > b->columns.elements)
swap_variables(Key*, a, b); // Put shorter key in 'a'
}
else
{
if (!b->generated)
return TRUE; // No foreign key
swap_variables(Key*, a, b); // Put generated key in 'a'
}
/* Test if 'a' is a prefix of 'b' */
if (a->columns.elements > b->columns.elements)
return TRUE; // Can't be prefix
List_iterator<Key_part_spec> col_it1(a->columns);
List_iterator<Key_part_spec> col_it2(b->columns);
const Key_part_spec *col1, *col2;
#ifdef ENABLE_WHEN_INNODB_CAN_HANDLE_SWAPED_FOREIGN_KEY_COLUMNS
while ((col1= col_it1++))
{
bool found= 0;
col_it2.rewind();
while ((col2= col_it2++))
{
if (*col1 == *col2)
{
found= TRUE;
break;
}
}
if (!found)
return TRUE; // Error
}
return FALSE; // Is prefix
#else
while ((col1= col_it1++))
{
col2= col_it2++;
if (!(*col1 == *col2))
return TRUE;
}
return FALSE; // Is prefix
#endif
}
/*
@brief
Check if the foreign key options are compatible with the specification
of the columns on which the key is created
@retval
FALSE The foreign key options are compatible with key columns
@retval
TRUE Otherwise
*/
bool Foreign_key::validate(List<Create_field> &table_fields)
{
Create_field *sql_field;
Key_part_spec *column;
List_iterator<Key_part_spec> cols(columns);
List_iterator<Create_field> it(table_fields);
DBUG_ENTER("Foreign_key::validate");
while ((column= cols++))
{
it.rewind();
while ((sql_field= it++) &&
my_strcasecmp(system_charset_info,
column->field_name.str,
sql_field->field_name)) {}
if (!sql_field)
{
my_error(ER_KEY_COLUMN_DOES_NOT_EXITS, MYF(0), column->field_name.str);
DBUG_RETURN(TRUE);
}
if (type == Key::FOREIGN_KEY && sql_field->vcol_info)
{
if (delete_opt == FK_OPTION_SET_NULL)
{
my_error(ER_WRONG_FK_OPTION_FOR_VIRTUAL_COLUMN, MYF(0),
"ON DELETE SET NULL");
DBUG_RETURN(TRUE);
}
if (update_opt == FK_OPTION_SET_NULL)
{
my_error(ER_WRONG_FK_OPTION_FOR_VIRTUAL_COLUMN, MYF(0),
"ON UPDATE SET NULL");
DBUG_RETURN(TRUE);
}
if (update_opt == FK_OPTION_CASCADE)
{
my_error(ER_WRONG_FK_OPTION_FOR_VIRTUAL_COLUMN, MYF(0),
"ON UPDATE CASCADE");
DBUG_RETURN(TRUE);
}
}
}
DBUG_RETURN(FALSE);
}
/****************************************************************************
** Thread specific functions
****************************************************************************/
#ifdef ONLY_FOR_MYSQL_CLOSED_SOURCE_SCHEDULED
/**
Get reference to scheduler data object
@param thd THD object
@retval Scheduler data object on THD
*/
void *thd_get_scheduler_data(THD *thd)
{
return thd->scheduler.data;
}
/**
Set reference to Scheduler data object for THD object
@param thd THD object
@param psi Scheduler data object to set on THD
*/
void thd_set_scheduler_data(THD *thd, void *data)
{
thd->scheduler.data= data;
}
/**
Get reference to Performance Schema object for THD object
@param thd THD object
@retval Performance schema object for thread on THD
*/
PSI_thread *thd_get_psi(THD *thd)
{
return thd->scheduler.m_psi;
}
/**
Get net_wait_timeout for THD object
@param thd THD object
@retval net_wait_timeout value for thread on THD
*/
ulong thd_get_net_wait_timeout(THD* thd)
{
return thd->variables.net_wait_timeout;
}
/**
Set reference to Performance Schema object for THD object
@param thd THD object
@param psi Performance schema object for thread
*/
void thd_set_psi(THD *thd, PSI_thread *psi)
{
thd->scheduler.m_psi= psi;
}
/**
Set the state on connection to killed
@param thd THD object
*/
void thd_set_killed(THD *thd)
{
thd->set_killed(KILL_CONNECTION);
}
/**
Clear errors from the previous THD
@param thd THD object
*/
void thd_clear_errors(THD *thd)
{
my_errno= 0;
thd->mysys_var->abort= 0;
}
/**
Set thread stack in THD object
@param thd Thread object
@param stack_start Start of stack to set in THD object
*/
void thd_set_thread_stack(THD *thd, char *stack_start)
{
thd->thread_stack= stack_start;
}
/**
Close the socket used by this connection
@param thd THD object
*/
void thd_close_connection(THD *thd)
{
if (thd->net.vio)
vio_close(thd->net.vio);
}
/**
Lock data that needs protection in THD object
@param thd THD object
*/
void thd_lock_data(THD *thd)
{
mysql_mutex_lock(&thd->LOCK_thd_data);
}
/**
Unlock data that needs protection in THD object
@param thd THD object
*/
void thd_unlock_data(THD *thd)
{
mysql_mutex_unlock(&thd->LOCK_thd_data);
}
/**
Support method to check if connection has already started transcaction
@param client_cntx Low level client context
@retval TRUE if connection already started transaction
*/
bool thd_is_transaction_active(THD *thd)
{
return thd->transaction.is_active();
}
/**
Check if there is buffered data on the socket representing the connection
@param thd THD object
*/
int thd_connection_has_data(THD *thd)
{
Vio *vio= thd->net.vio;
return vio->has_data(vio);
}
/**
Set reading/writing on socket, used by SHOW PROCESSLIST
@param thd THD object
@param val Value to set it to (0 or 1)
*/
void thd_set_net_read_write(THD *thd, uint val)
{
thd->net.reading_or_writing= val;
}
/**
Get reading/writing on socket from THD object
@param thd THD object
@retval net.reading_or_writing value for thread on THD.
*/
uint thd_get_net_read_write(THD *thd)
{
return thd->net.reading_or_writing;
}
/**
Set reference to mysys variable in THD object
@param thd THD object
@param mysys_var Reference to set
*/
void thd_set_mysys_var(THD *thd, st_my_thread_var *mysys_var)
{
thd->set_mysys_var(mysys_var);
}
/**
Get socket file descriptor for this connection
@param thd THD object
@retval Socket of the connection
*/
my_socket thd_get_fd(THD *thd)
{
return mysql_socket_getfd(thd->net.vio->mysql_socket);
}
#endif
/**
Get thread attributes for connection threads
@retval Reference to thread attribute for connection threads
*/
pthread_attr_t *get_connection_attrib(void)
{
return &connection_attrib;
}
/**
Get max number of connections
@retval Max number of connections for MySQL Server
*/
ulong get_max_connections(void)
{
return max_connections;
}
/*
The following functions form part of the C plugin API
*/
extern "C" int mysql_tmpfile(const char *prefix)
{
char filename[FN_REFLEN];
File fd = create_temp_file(filename, mysql_tmpdir, prefix,
#ifdef __WIN__
O_BINARY | O_TRUNC | O_SEQUENTIAL |
O_SHORT_LIVED |
#endif /* __WIN__ */
O_CREAT | O_EXCL | O_RDWR | O_TEMPORARY,
MYF(MY_WME));
if (fd >= 0) {
#ifndef __WIN__
/*
This can be removed once the following bug is fixed:
Bug #28903 create_temp_file() doesn't honor O_TEMPORARY option
(file not removed) (Unix)
*/
unlink(filename);
#endif /* !__WIN__ */
}
return fd;
}
extern "C"
int thd_in_lock_tables(const THD *thd)
{
return MY_TEST(thd->in_lock_tables);
}
extern "C"
int thd_tablespace_op(const THD *thd)
{
return MY_TEST(thd->tablespace_op);
}
extern "C"
const char *set_thd_proc_info(THD *thd_arg, const char *info,
const char *calling_function,
const char *calling_file,
const unsigned int calling_line)
{
PSI_stage_info old_stage;
PSI_stage_info new_stage;
old_stage.m_key= 0;
old_stage.m_name= info;
set_thd_stage_info(thd_arg, & old_stage, & new_stage,
calling_function, calling_file, calling_line);
return new_stage.m_name;
}
extern "C"
void set_thd_stage_info(void *thd_arg,
const PSI_stage_info *new_stage,
PSI_stage_info *old_stage,
const char *calling_func,
const char *calling_file,
const unsigned int calling_line)
{
THD *thd= (THD*) thd_arg;
if (thd == NULL)
thd= current_thd;
if (old_stage)
thd->backup_stage(old_stage);
if (new_stage)
thd->enter_stage(new_stage, calling_func, calling_file, calling_line);
}
void thd_enter_cond(MYSQL_THD thd, mysql_cond_t *cond, mysql_mutex_t *mutex,
const PSI_stage_info *stage, PSI_stage_info *old_stage,
const char *src_function, const char *src_file,
int src_line)
{
if (!thd)
thd= current_thd;
return thd->enter_cond(cond, mutex, stage, old_stage, src_function, src_file,
src_line);
}
void thd_exit_cond(MYSQL_THD thd, const PSI_stage_info *stage,
const char *src_function, const char *src_file,
int src_line)
{
if (!thd)
thd= current_thd;
thd->exit_cond(stage, src_function, src_file, src_line);
return;
}
extern "C"
void **thd_ha_data(const THD *thd, const struct handlerton *hton)
{
return (void **) &thd->ha_data[hton->slot].ha_ptr;
}
extern "C"
void thd_storage_lock_wait(THD *thd, long long value)
{
thd->utime_after_lock+= value;
}
/**
Provide a handler data getter to simplify coding
*/
extern "C"
void *thd_get_ha_data(const THD *thd, const struct handlerton *hton)
{
return *thd_ha_data(thd, hton);
}
/**
Provide a handler data setter to simplify coding
@see thd_set_ha_data() definition in plugin.h
*/
extern "C"
void thd_set_ha_data(THD *thd, const struct handlerton *hton,
const void *ha_data)
{
plugin_ref *lock= &thd->ha_data[hton->slot].lock;
if (ha_data && !*lock)
*lock= ha_lock_engine(NULL, (handlerton*) hton);
else if (!ha_data && *lock)
{
plugin_unlock(NULL, *lock);
*lock= NULL;
}
*thd_ha_data(thd, hton)= (void*) ha_data;
}
/**
Allow storage engine to wakeup commits waiting in THD::wait_for_prior_commit.
@see thd_wakeup_subsequent_commits() definition in plugin.h
*/
extern "C"
void thd_wakeup_subsequent_commits(THD *thd, int wakeup_error)
{
thd->wakeup_subsequent_commits(wakeup_error);
}
extern "C"
long long thd_test_options(const THD *thd, long long test_options)
{
return thd->variables.option_bits & test_options;
}
extern "C"
int thd_sql_command(const THD *thd)
{
return (int) thd->lex->sql_command;
}
extern "C"
int thd_tx_isolation(const THD *thd)
{
return (int) thd->tx_isolation;
}
extern "C"
int thd_tx_is_read_only(const THD *thd)
{
return (int) thd->tx_read_only;
}
extern "C"
{ /* Functions for thd_error_context_service */
const char *thd_get_error_message(const THD *thd)
{
return thd->get_stmt_da()->message();
}
uint thd_get_error_number(const THD *thd)
{
return thd->get_stmt_da()->sql_errno();
}
ulong thd_get_error_row(const THD *thd)
{
return thd->get_stmt_da()->current_row_for_warning();
}
void thd_inc_error_row(THD *thd)
{
thd->get_stmt_da()->inc_current_row_for_warning();
}
}
/**
Dumps a text description of a thread, its security context
(user, host) and the current query.
@param thd thread context
@param buffer pointer to preferred result buffer
@param length length of buffer
@param max_query_len how many chars of query to copy (0 for all)
@return Pointer to string
*/
extern "C"
char *thd_get_error_context_description(THD *thd, char *buffer,
unsigned int length,
unsigned int max_query_len)
{
String str(buffer, length, &my_charset_latin1);
const Security_context *sctx= &thd->main_security_ctx;
char header[256];
int len;
mysql_mutex_lock(&LOCK_thread_count);
/*
The pointers thd->query and thd->proc_info might change since they are
being modified concurrently. This is acceptable for proc_info since its
values doesn't have to very accurate and the memory it points to is static,
but we need to attempt a snapshot on the pointer values to avoid using NULL
values. The pointer to thd->query however, doesn't point to static memory
and has to be protected by thd->LOCK_thd_data or risk pointing to
uninitialized memory.
*/
const char *proc_info= thd->proc_info;
len= my_snprintf(header, sizeof(header),
"MySQL thread id %lu, OS thread handle 0x%lx, query id %lu",
thd->thread_id, (ulong) thd->real_id, (ulong) thd->query_id);
str.length(0);
str.append(header, len);
if (sctx->host)
{
str.append(' ');
str.append(sctx->host);
}
if (sctx->ip)
{
str.append(' ');
str.append(sctx->ip);
}
if (sctx->user)
{
str.append(' ');
str.append(sctx->user);
}
if (proc_info)
{
str.append(' ');
str.append(proc_info);
}
/* Don't wait if LOCK_thd_data is used as this could cause a deadlock */
if (!mysql_mutex_trylock(&thd->LOCK_thd_data))
{
if (thd->query())
{
if (max_query_len < 1)
len= thd->query_length();
else
len= MY_MIN(thd->query_length(), max_query_len);
str.append('\n');
str.append(thd->query(), len);
}
mysql_mutex_unlock(&thd->LOCK_thd_data);
}
mysql_mutex_unlock(&LOCK_thread_count);
if (str.c_ptr_safe() == buffer)
return buffer;
/*
We have to copy the new string to the destination buffer because the string
was reallocated to a larger buffer to be able to fit.
*/
DBUG_ASSERT(buffer != NULL);
length= MY_MIN(str.length(), length-1);
memcpy(buffer, str.c_ptr_quick(), length);
/* Make sure that the new string is null terminated */
buffer[length]= '\0';
return buffer;
}
#if MARIA_PLUGIN_INTERFACE_VERSION < 0x0200
/**
TODO: This function is for API compatibility, remove it eventually.
All engines should switch to use thd_get_error_context_description()
plugin service function.
*/
extern "C"
char *thd_security_context(THD *thd,
char *buffer, unsigned int length,
unsigned int max_query_len)
{
return thd_get_error_context_description(thd, buffer, length, max_query_len);
}
#endif
/**
Implementation of Drop_table_error_handler::handle_condition().
The reason in having this implementation is to silence technical low-level
warnings during DROP TABLE operation. Currently we don't want to expose
the following warnings during DROP TABLE:
- Some of table files are missed or invalid (the table is going to be
deleted anyway, so why bother that something was missed);
- A trigger associated with the table does not have DEFINER (One of the
MySQL specifics now is that triggers are loaded for the table being
dropped. So, we may have a warning that trigger does not have DEFINER
attribute during DROP TABLE operation).
@return TRUE if the condition is handled.
*/
bool Drop_table_error_handler::handle_condition(THD *thd,
uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level level,
const char* msg,
Sql_condition ** cond_hdl)
{
*cond_hdl= NULL;
return ((sql_errno == EE_DELETE && my_errno == ENOENT) ||
sql_errno == ER_TRG_NO_DEFINER);
}
/**
Send timeout to thread.
Note that this is always safe as the thread will always remove it's
timeouts at end of query (and thus before THD is destroyed)
*/
extern "C" void thd_kill_timeout(THD* thd)
{
thd->status_var.max_statement_time_exceeded++;
mysql_mutex_lock(&thd->LOCK_thd_data);
/* Kill queries that can't cause data corruptions */
thd->awake(KILL_TIMEOUT);
mysql_mutex_unlock(&thd->LOCK_thd_data);
}
THD::THD(bool is_wsrep_applier)
:Statement(&main_lex, &main_mem_root, STMT_CONVENTIONAL_EXECUTION,
/* statement id */ 0),
rli_fake(0), rgi_fake(0), rgi_slave(NULL),
protocol_text(this), protocol_binary(this),
in_sub_stmt(0), log_all_errors(0),
binlog_unsafe_warning_flags(0),
binlog_table_maps(0),
table_map_for_update(0),
arg_of_last_insert_id_function(FALSE),
first_successful_insert_id_in_prev_stmt(0),
first_successful_insert_id_in_prev_stmt_for_binlog(0),
first_successful_insert_id_in_cur_stmt(0),
stmt_depends_on_first_successful_insert_id_in_prev_stmt(FALSE),
m_examined_row_count(0),
accessed_rows_and_keys(0),
m_digest(NULL),
m_statement_psi(NULL),
m_idle_psi(NULL),
thread_id(0),
os_thread_id(0),
global_disable_checkpoint(0),
failed_com_change_user(0),
is_fatal_error(0),
transaction_rollback_request(0),
is_fatal_sub_stmt_error(false),
rand_used(0),
time_zone_used(0),
in_lock_tables(0),
bootstrap(0),
derived_tables_processing(FALSE),
waiting_on_group_commit(FALSE), has_waiter(FALSE),
spcont(NULL),
m_parser_state(NULL),
#if defined(ENABLED_DEBUG_SYNC)
debug_sync_control(0),
#endif /* defined(ENABLED_DEBUG_SYNC) */
wait_for_commit_ptr(0),
m_internal_handler(0),
main_da(0, false, false),
m_stmt_da(&main_da),
tdc_hash_pins(0),
xid_hash_pins(0)
#ifdef WITH_WSREP
,
wsrep_applier(is_wsrep_applier),
wsrep_applier_closing(false),
wsrep_client_thread(false),
wsrep_apply_toi(false),
wsrep_po_handle(WSREP_PO_INITIALIZER),
wsrep_po_cnt(0),
wsrep_apply_format(0),
wsrep_ignore_table(false)
#endif
{
ulong tmp;
bzero(&variables, sizeof(variables));
/*
We set THR_THD to temporally point to this THD to register all the
variables that allocates memory for this THD
*/
THD *old_THR_THD= current_thd;
set_current_thd(this);
status_var.local_memory_used= sizeof(THD);
status_var.global_memory_used= 0;
variables.max_mem_used= global_system_variables.max_mem_used;
main_da.init();
mdl_context.init(this);
/*
Pass nominal parameters to init_alloc_root only to ensure that
the destructor works OK in case of an error. The main_mem_root
will be re-initialized in init_for_queries().
*/
init_sql_alloc(&main_mem_root, ALLOC_ROOT_MIN_BLOCK_SIZE, 0,
MYF(MY_THREAD_SPECIFIC));
stmt_arena= this;
thread_stack= 0;
scheduler= thread_scheduler; // Will be fixed later
event_scheduler.data= 0;
event_scheduler.m_psi= 0;
skip_wait_timeout= false;
extra_port= 0;
catalog= (char*)"std"; // the only catalog we have for now
main_security_ctx.init();
security_ctx= &main_security_ctx;
no_errors= 0;
password= 0;
query_start_used= query_start_sec_part_used= 0;
count_cuted_fields= CHECK_FIELD_IGNORE;
killed= NOT_KILLED;
killed_err= 0;
col_access=0;
is_slave_error= thread_specific_used= FALSE;
my_hash_clear(&handler_tables_hash);
my_hash_clear(&ull_hash);
tmp_table=0;
cuted_fields= 0L;
m_sent_row_count= 0L;
limit_found_rows= 0;
m_row_count_func= -1;
statement_id_counter= 0UL;
// Must be reset to handle error with THD's created for init of mysqld
lex->current_select= 0;
user_time.val= start_time= start_time_sec_part= 0;
start_utime= utime_after_query= prior_thr_create_utime= 0L;
utime_after_lock= 0L;
progress.arena= 0;
progress.report_to_client= 0;
progress.max_counter= 0;
current_linfo = 0;
slave_thread = 0;
connection_name.str= 0;
connection_name.length= 0;
file_id = 0;
query_id= 0;
query_name_consts= 0;
semisync_info= 0;
db_charset= global_system_variables.collation_database;
bzero(ha_data, sizeof(ha_data));
mysys_var=0;
binlog_evt_union.do_union= FALSE;
enable_slow_log= 0;
durability_property= HA_REGULAR_DURABILITY;
#ifndef DBUG_OFF
dbug_sentry=THD_SENTRY_MAGIC;
#endif
#ifndef EMBEDDED_LIBRARY
mysql_audit_init_thd(this);
#endif
net.vio=0;
net.buff= 0;
client_capabilities= 0; // minimalistic client
system_thread= NON_SYSTEM_THREAD;
cleanup_done= abort_on_warning= 0;
peer_port= 0; // For SHOW PROCESSLIST
transaction.m_pending_rows_event= 0;
transaction.on= 1;
wt_thd_lazy_init(&transaction.wt, &variables.wt_deadlock_search_depth_short,
&variables.wt_timeout_short,
&variables.wt_deadlock_search_depth_long,
&variables.wt_timeout_long);
#ifdef SIGNAL_WITH_VIO_CLOSE
active_vio = 0;
#endif
mysql_mutex_init(key_LOCK_thd_data, &LOCK_thd_data, MY_MUTEX_INIT_FAST);
mysql_mutex_init(key_LOCK_wakeup_ready, &LOCK_wakeup_ready, MY_MUTEX_INIT_FAST);
mysql_mutex_init(key_LOCK_thd_kill, &LOCK_thd_kill, MY_MUTEX_INIT_FAST);
mysql_cond_init(key_COND_wakeup_ready, &COND_wakeup_ready, 0);
/*
LOCK_thread_count goes before LOCK_thd_data - the former is called around
'delete thd', the latter - in THD::~THD
*/
mysql_mutex_record_order(&LOCK_thread_count, &LOCK_thd_data);
/* Variables with default values */
proc_info="login";
where= THD::DEFAULT_WHERE;
variables.server_id = global_system_variables.server_id;
slave_net = 0;
m_command=COM_CONNECT;
*scramble= '\0';
#ifdef WITH_WSREP
mysql_mutex_init(key_LOCK_wsrep_thd, &LOCK_wsrep_thd, MY_MUTEX_INIT_FAST);
wsrep_ws_handle.trx_id = WSREP_UNDEFINED_TRX_ID;
wsrep_ws_handle.opaque = NULL;
wsrep_retry_counter = 0;
wsrep_PA_safe = true;
wsrep_retry_query = NULL;
wsrep_retry_query_len = 0;
wsrep_retry_command = COM_CONNECT;
wsrep_consistency_check = NO_CONSISTENCY_CHECK;
wsrep_mysql_replicated = 0;
wsrep_TOI_pre_query = NULL;
wsrep_TOI_pre_query_len = 0;
wsrep_info[sizeof(wsrep_info) - 1] = '\0'; /* make sure it is 0-terminated */
wsrep_sync_wait_gtid = WSREP_GTID_UNDEFINED;
wsrep_affected_rows = 0;
wsrep_replicate_GTID = false;
wsrep_skip_wsrep_GTID = false;
#endif
/* Call to init() below requires fully initialized Open_tables_state. */
reset_open_tables_state(this);
init();
#if defined(ENABLED_PROFILING)
profiling.set_thd(this);
#endif
user_connect=(USER_CONN *)0;
my_hash_init(&user_vars, system_charset_info, USER_VARS_HASH_SIZE, 0, 0,
(my_hash_get_key) get_var_key,
(my_hash_free_key) free_user_var, HASH_THREAD_SPECIFIC);
sp_proc_cache= NULL;
sp_func_cache= NULL;
/* For user vars replication*/
if (opt_bin_log)
my_init_dynamic_array(&user_var_events,
sizeof(BINLOG_USER_VAR_EVENT *), 16, 16, MYF(0));
else
bzero((char*) &user_var_events, sizeof(user_var_events));
/* Protocol */
protocol= &protocol_text; // Default protocol
protocol_text.init(this);
protocol_binary.init(this);
thr_timer_init(&query_timer, (void (*)(void*)) thd_kill_timeout, this);
tablespace_op=FALSE;
/*
Initialize the random generator. We call my_rnd() without a lock as
it's not really critical if two threads modifies the structure at the
same time. We ensure that we have an unique number foreach thread
by adding the address of the stack.
*/
tmp= (ulong) (my_rnd(&sql_rand) * 0xffffffff);
my_rnd_init(&rand, tmp + (ulong) &rand, tmp + (ulong) ::global_query_id);
substitute_null_with_insert_id = FALSE;
thr_lock_info_init(&lock_info); /* safety: will be reset after start */
lock_info.mysql_thd= (void *)this;
m_token_array= NULL;
if (max_digest_length > 0)
{
m_token_array= (unsigned char*) my_malloc(max_digest_length,
MYF(MY_WME|MY_THREAD_SPECIFIC));
}
m_binlog_invoker= INVOKER_NONE;
memset(&invoker_user, 0, sizeof(invoker_user));
memset(&invoker_host, 0, sizeof(invoker_host));
prepare_derived_at_open= FALSE;
create_tmp_table_for_derived= FALSE;
save_prep_leaf_list= FALSE;
/* Restore THR_THD */
set_current_thd(old_THR_THD);
}
void THD::push_internal_handler(Internal_error_handler *handler)
{
DBUG_ENTER("THD::push_internal_handler");
if (m_internal_handler)
{
handler->m_prev_internal_handler= m_internal_handler;
m_internal_handler= handler;
}
else
{
m_internal_handler= handler;
}
DBUG_VOID_RETURN;
}
bool THD::handle_condition(uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level level,
const char* msg,
Sql_condition ** cond_hdl)
{
if (!m_internal_handler)
{
*cond_hdl= NULL;
return FALSE;
}
for (Internal_error_handler *error_handler= m_internal_handler;
error_handler;
error_handler= error_handler->m_prev_internal_handler)
{
if (error_handler->handle_condition(this, sql_errno, sqlstate, level, msg,
cond_hdl))
{
return TRUE;
}
}
return FALSE;
}
Internal_error_handler *THD::pop_internal_handler()
{
DBUG_ENTER("THD::pop_internal_handler");
DBUG_ASSERT(m_internal_handler != NULL);
Internal_error_handler *popped_handler= m_internal_handler;
m_internal_handler= m_internal_handler->m_prev_internal_handler;
DBUG_RETURN(popped_handler);
}
void THD::raise_error(uint sql_errno)
{
const char* msg= ER_THD(this, sql_errno);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_ERROR,
msg);
}
void THD::raise_error_printf(uint sql_errno, ...)
{
va_list args;
char ebuff[MYSQL_ERRMSG_SIZE];
DBUG_ENTER("THD::raise_error_printf");
DBUG_PRINT("my", ("nr: %d errno: %d", sql_errno, errno));
const char* format= ER_THD(this, sql_errno);
va_start(args, sql_errno);
my_vsnprintf(ebuff, sizeof(ebuff), format, args);
va_end(args);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_ERROR,
ebuff);
DBUG_VOID_RETURN;
}
void THD::raise_warning(uint sql_errno)
{
const char* msg= ER_THD(this, sql_errno);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_WARN,
msg);
}
void THD::raise_warning_printf(uint sql_errno, ...)
{
va_list args;
char ebuff[MYSQL_ERRMSG_SIZE];
DBUG_ENTER("THD::raise_warning_printf");
DBUG_PRINT("enter", ("warning: %u", sql_errno));
const char* format= ER_THD(this, sql_errno);
va_start(args, sql_errno);
my_vsnprintf(ebuff, sizeof(ebuff), format, args);
va_end(args);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_WARN,
ebuff);
DBUG_VOID_RETURN;
}
void THD::raise_note(uint sql_errno)
{
DBUG_ENTER("THD::raise_note");
DBUG_PRINT("enter", ("code: %d", sql_errno));
if (!(variables.option_bits & OPTION_SQL_NOTES))
DBUG_VOID_RETURN;
const char* msg= ER_THD(this, sql_errno);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_NOTE,
msg);
DBUG_VOID_RETURN;
}
void THD::raise_note_printf(uint sql_errno, ...)
{
va_list args;
char ebuff[MYSQL_ERRMSG_SIZE];
DBUG_ENTER("THD::raise_note_printf");
DBUG_PRINT("enter",("code: %u", sql_errno));
if (!(variables.option_bits & OPTION_SQL_NOTES))
DBUG_VOID_RETURN;
const char* format= ER_THD(this, sql_errno);
va_start(args, sql_errno);
my_vsnprintf(ebuff, sizeof(ebuff), format, args);
va_end(args);
(void) raise_condition(sql_errno,
NULL,
Sql_condition::WARN_LEVEL_NOTE,
ebuff);
DBUG_VOID_RETURN;
}
Sql_condition* THD::raise_condition(uint sql_errno,
const char* sqlstate,
Sql_condition::enum_warning_level level,
const char* msg)
{
Diagnostics_area *da= get_stmt_da();
Sql_condition *cond= NULL;
DBUG_ENTER("THD::raise_condition");
if (!(variables.option_bits & OPTION_SQL_NOTES) &&
(level == Sql_condition::WARN_LEVEL_NOTE))
DBUG_RETURN(NULL);
da->opt_clear_warning_info(query_id);
/*
TODO: replace by DBUG_ASSERT(sql_errno != 0) once all bugs similar to
Bug#36768 are fixed: a SQL condition must have a real (!=0) error number
so that it can be caught by handlers.
*/
if (sql_errno == 0)
sql_errno= ER_UNKNOWN_ERROR;
if (msg == NULL)
msg= ER_THD(this, sql_errno);
if (sqlstate == NULL)
sqlstate= mysql_errno_to_sqlstate(sql_errno);
if ((level == Sql_condition::WARN_LEVEL_WARN) &&
really_abort_on_warning())
{
/*
FIXME:
push_warning and strict SQL_MODE case.
*/
level= Sql_condition::WARN_LEVEL_ERROR;
set_killed(KILL_BAD_DATA);
}
switch (level)
{
case Sql_condition::WARN_LEVEL_NOTE:
case Sql_condition::WARN_LEVEL_WARN:
got_warning= 1;
break;
case Sql_condition::WARN_LEVEL_ERROR:
break;
default:
DBUG_ASSERT(FALSE);
}
if (handle_condition(sql_errno, sqlstate, level, msg, &cond))
DBUG_RETURN(cond);
if (level == Sql_condition::WARN_LEVEL_ERROR)
{
mysql_audit_general(this, MYSQL_AUDIT_GENERAL_ERROR, sql_errno, msg);
is_slave_error= 1; // needed to catch query errors during replication
if (!da->is_error())
{
set_row_count_func(-1);
da->set_error_status(sql_errno, msg, sqlstate, cond);
}
}
query_cache_abort(this, &query_cache_tls);
/*
Avoid pushing a condition for fatal out of memory errors as this will
require memory allocation and therefore might fail. Non fatal out of
memory errors can occur if raised by SIGNAL/RESIGNAL statement.
*/
if (!(is_fatal_error && (sql_errno == EE_OUTOFMEMORY ||
sql_errno == ER_OUTOFMEMORY)))
{
cond= da->push_warning(this, sql_errno, sqlstate, level, msg);
}
DBUG_RETURN(cond);
}
extern "C"
void *thd_alloc(MYSQL_THD thd, unsigned int size)
{
return thd->alloc(size);
}
extern "C"
void *thd_calloc(MYSQL_THD thd, unsigned int size)
{
return thd->calloc(size);
}
extern "C"
char *thd_strdup(MYSQL_THD thd, const char *str)
{
return thd->strdup(str);
}
extern "C"
char *thd_strmake(MYSQL_THD thd, const char *str, unsigned int size)
{
return thd->strmake(str, size);
}
extern "C"
LEX_STRING *thd_make_lex_string(THD *thd, LEX_STRING *lex_str,
const char *str, unsigned int size,
int allocate_lex_string)
{
return allocate_lex_string ? thd->make_lex_string(str, size)
: thd->make_lex_string(lex_str, str, size);
}
extern "C"
void *thd_memdup(MYSQL_THD thd, const void* str, unsigned int size)
{
return thd->memdup(str, size);
}
extern "C"
void thd_get_xid(const MYSQL_THD thd, MYSQL_XID *xid)
{
*xid = *(MYSQL_XID *) &thd->transaction.xid_state.xid;
}
extern "C"
my_time_t thd_TIME_to_gmt_sec(MYSQL_THD thd, const MYSQL_TIME *ltime,
unsigned int *errcode)
{
Time_zone *tz= thd ? thd->variables.time_zone :
global_system_variables.time_zone;
return tz->TIME_to_gmt_sec(ltime, errcode);
}
extern "C"
void thd_gmt_sec_to_TIME(MYSQL_THD thd, MYSQL_TIME *ltime, my_time_t t)
{
Time_zone *tz= thd ? thd->variables.time_zone :
global_system_variables.time_zone;
tz->gmt_sec_to_TIME(ltime, t);
}
#ifdef _WIN32
extern "C" THD *_current_thd_noinline(void)
{
return my_pthread_getspecific_ptr(THD*,THR_THD);
}
#endif
/*
Init common variables that has to be reset on start and on change_user
*/
void THD::init(void)
{
DBUG_ENTER("thd::init");
mysql_mutex_lock(&LOCK_global_system_variables);
plugin_thdvar_init(this);
/*
plugin_thd_var_init() sets variables= global_system_variables, which
has reset variables.pseudo_thread_id to 0. We need to correct it here to
avoid temporary tables replication failure.
*/
variables.pseudo_thread_id= thread_id;
variables.default_master_connection.str= default_master_connection_buff;
::strmake(variables.default_master_connection.str,
global_system_variables.default_master_connection.str,
variables.default_master_connection.length);
mysql_mutex_unlock(&LOCK_global_system_variables);
server_status= SERVER_STATUS_AUTOCOMMIT;
if (variables.sql_mode & MODE_NO_BACKSLASH_ESCAPES)
server_status|= SERVER_STATUS_NO_BACKSLASH_ESCAPES;
if (variables.sql_mode & MODE_ANSI_QUOTES)
server_status|= SERVER_STATUS_ANSI_QUOTES;
transaction.all.modified_non_trans_table=
transaction.stmt.modified_non_trans_table= FALSE;
transaction.all.m_unsafe_rollback_flags=
transaction.stmt.m_unsafe_rollback_flags= 0;
open_options=ha_open_options;
update_lock_default= (variables.low_priority_updates ?
TL_WRITE_LOW_PRIORITY :
TL_WRITE);
tx_isolation= (enum_tx_isolation) variables.tx_isolation;
tx_read_only= variables.tx_read_only;
update_charset();
reset_current_stmt_binlog_format_row();
reset_binlog_local_stmt_filter();
set_status_var_init();
bzero((char *) &org_status_var, sizeof(org_status_var));
start_bytes_received= 0;
last_commit_gtid.seq_no= 0;
status_in_global= 0;
#ifdef WITH_WSREP
wsrep_exec_mode= wsrep_applier ? REPL_RECV : LOCAL_STATE;
wsrep_conflict_state= NO_CONFLICT;
wsrep_query_state= QUERY_IDLE;
wsrep_last_query_id= 0;
wsrep_trx_meta.gtid= WSREP_GTID_UNDEFINED;
wsrep_trx_meta.depends_on= WSREP_SEQNO_UNDEFINED;
wsrep_converted_lock_session= false;
wsrep_retry_counter= 0;
wsrep_rgi= NULL;
wsrep_PA_safe= true;
wsrep_consistency_check = NO_CONSISTENCY_CHECK;
wsrep_mysql_replicated = 0;
wsrep_TOI_pre_query = NULL;
wsrep_TOI_pre_query_len = 0;
wsrep_sync_wait_gtid = WSREP_GTID_UNDEFINED;
wsrep_affected_rows = 0;
wsrep_replicate_GTID = false;
wsrep_skip_wsrep_GTID = false;
#endif /* WITH_WSREP */
if (variables.sql_log_bin)
variables.option_bits|= OPTION_BIN_LOG;
else
variables.option_bits&= ~OPTION_BIN_LOG;
variables.sql_log_bin_off= 0;
select_commands= update_commands= other_commands= 0;
/* Set to handle counting of aborted connections */
userstat_running= opt_userstat_running;
last_global_update_time= current_connect_time= time(NULL);
#if defined(ENABLED_DEBUG_SYNC)
/* Initialize the Debug Sync Facility. See debug_sync.cc. */
debug_sync_init_thread(this);
#endif /* defined(ENABLED_DEBUG_SYNC) */
apc_target.init(&LOCK_thd_data);
DBUG_VOID_RETURN;
}
/* Updates some status variables to be used by update_global_user_stats */
void THD::update_stats(void)
{
/* sql_command == SQLCOM_END in case of parse errors or quit */
if (lex->sql_command != SQLCOM_END)
{
/* A SQL query. */
if (lex->sql_command == SQLCOM_SELECT)
select_commands++;
else if (sql_command_flags[lex->sql_command] & CF_STATUS_COMMAND)
{
/* Ignore 'SHOW ' commands */
}
else if (is_update_query(lex->sql_command))
update_commands++;
else
other_commands++;
}
}
void THD::update_all_stats()
{
ulonglong end_cpu_time, end_utime;
double busy_time, cpu_time;
/* This is set at start of query if opt_userstat_running was set */
if (!userstat_running)
return;
end_cpu_time= my_getcputime();
end_utime= microsecond_interval_timer();
busy_time= (end_utime - start_utime) / 1000000.0;
cpu_time= (end_cpu_time - start_cpu_time) / 10000000.0;
/* In case there are bad values, 2629743 is the #seconds in a month. */
if (cpu_time > 2629743.0)
cpu_time= 0;
status_var_add(status_var.cpu_time, cpu_time);
status_var_add(status_var.busy_time, busy_time);
update_global_user_stats(this, TRUE, my_time(0));
// Has to be updated after update_global_user_stats()
userstat_running= 0;
}
/*
Init THD for query processing.
This has to be called once before we call mysql_parse.
See also comments in sql_class.h.
*/
void THD::init_for_queries()
{
set_time();
ha_enable_transaction(this,TRUE);
reset_root_defaults(mem_root, variables.query_alloc_block_size,
variables.query_prealloc_size);
reset_root_defaults(&transaction.mem_root,
variables.trans_alloc_block_size,
variables.trans_prealloc_size);
transaction.xid_state.xid.null();
}
/*
Do what's needed when one invokes change user
SYNOPSIS
change_user()
IMPLEMENTATION
Reset all resources that are connection specific
*/
void THD::change_user(void)
{
add_status_to_global();
cleanup();
reset_killed();
cleanup_done= 0;
status_in_global= 0;
init();
stmt_map.reset();
my_hash_init(&user_vars, system_charset_info, USER_VARS_HASH_SIZE, 0, 0,
(my_hash_get_key) get_var_key,
(my_hash_free_key) free_user_var, 0);
sp_cache_clear(&sp_proc_cache);
sp_cache_clear(&sp_func_cache);
}
/* Do operations that may take a long time */
void THD::cleanup(void)
{
DBUG_ENTER("THD::cleanup");
DBUG_ASSERT(cleanup_done == 0);
set_killed(KILL_CONNECTION);
#ifdef ENABLE_WHEN_BINLOG_WILL_BE_ABLE_TO_PREPARE
if (transaction.xid_state.xa_state == XA_PREPARED)
{
#error xid_state in the cache should be replaced by the allocated value
}
#endif
mysql_ha_cleanup(this);
locked_tables_list.unlock_locked_tables(this);
delete_dynamic(&user_var_events);
close_temporary_tables(this);
transaction.xid_state.xa_state= XA_NOTR;
trans_rollback(this);
xid_cache_delete(this, &transaction.xid_state);
DBUG_ASSERT(open_tables == NULL);
/*
If the thread was in the middle of an ongoing transaction (rolled
back a few lines above) or under LOCK TABLES (unlocked the tables
and left the mode a few lines above), there will be outstanding
metadata locks. Release them.
*/
mdl_context.release_transactional_locks();
/* Release the global read lock, if acquired. */
if (global_read_lock.is_acquired())
global_read_lock.unlock_global_read_lock(this);
if (user_connect)
{
decrease_user_connections(user_connect);
user_connect= 0; // Safety
}
wt_thd_destroy(&transaction.wt);
#if defined(ENABLED_DEBUG_SYNC)
/* End the Debug Sync Facility. See debug_sync.cc. */
debug_sync_end_thread(this);
#endif /* defined(ENABLED_DEBUG_SYNC) */
my_hash_free(&user_vars);
sp_cache_clear(&sp_proc_cache);
sp_cache_clear(&sp_func_cache);
mysql_ull_cleanup(this);
/* All metadata locks must have been released by now. */
DBUG_ASSERT(!mdl_context.has_locks());
apc_target.destroy();
cleanup_done=1;
DBUG_VOID_RETURN;
}
THD::~THD()
{
THD *orig_thd= current_thd;
THD_CHECK_SENTRY(this);
DBUG_ENTER("~THD()");
/*
In error cases, thd may not be current thd. We have to fix this so
that memory allocation counting is done correctly
*/
set_current_thd(this);
if (!status_in_global)
add_status_to_global();
/* Ensure that no one is using THD */
mysql_mutex_lock(&LOCK_thd_data);
mysql_mutex_unlock(&LOCK_thd_data);
#ifdef WITH_WSREP
mysql_mutex_lock(&LOCK_wsrep_thd);
mysql_mutex_unlock(&LOCK_wsrep_thd);
mysql_mutex_destroy(&LOCK_wsrep_thd);
if (wsrep_rgi) delete wsrep_rgi;
#endif
/* Close connection */
#ifndef EMBEDDED_LIBRARY
if (net.vio)
vio_delete(net.vio);
net_end(&net);
#endif
stmt_map.reset(); /* close all prepared statements */
if (!cleanup_done)
cleanup();
mdl_context.destroy();
ha_close_connection(this);
mysql_audit_release(this);
plugin_thdvar_cleanup(this);
main_security_ctx.destroy();
my_free(db);
db= NULL;
free_root(&transaction.mem_root,MYF(0));
mysql_cond_destroy(&COND_wakeup_ready);
mysql_mutex_destroy(&LOCK_wakeup_ready);
mysql_mutex_destroy(&LOCK_thd_data);
mysql_mutex_destroy(&LOCK_thd_kill);
#ifndef DBUG_OFF
dbug_sentry= THD_SENTRY_GONE;
#endif
#ifndef EMBEDDED_LIBRARY
if (rgi_fake)
{
delete rgi_fake;
rgi_fake= NULL;
}
if (rli_fake)
{
delete rli_fake;
rli_fake= NULL;
}
mysql_audit_free_thd(this);
if (rgi_slave)
rgi_slave->cleanup_after_session();
my_free(semisync_info);
#endif
main_lex.free_set_stmt_mem_root();
free_root(&main_mem_root, MYF(0));
my_free(m_token_array);
main_da.free_memory();
if (tdc_hash_pins)
lf_hash_put_pins(tdc_hash_pins);
if (xid_hash_pins)
lf_hash_put_pins(xid_hash_pins);
/* Ensure everything is freed */
status_var.local_memory_used-= sizeof(THD);
if (status_var.local_memory_used != 0)
{
DBUG_PRINT("error", ("memory_used: %lld", status_var.local_memory_used));
SAFEMALLOC_REPORT_MEMORY(my_thread_dbug_id());
DBUG_ASSERT(status_var.local_memory_used == 0);
}
update_global_memory_status(status_var.global_memory_used);
set_current_thd(orig_thd == this ? 0 : orig_thd);
DBUG_VOID_RETURN;
}
/*
Add all status variables to another status variable array
SYNOPSIS
add_to_status()
to_var add to this array
from_var from this array
NOTES
This function assumes that all variables at start are long/ulong and
other types are handled explicitely
*/
void add_to_status(STATUS_VAR *to_var, STATUS_VAR *from_var)
{
ulong *end= (ulong*) ((uchar*) to_var +
offsetof(STATUS_VAR, last_system_status_var) +
sizeof(ulong));
ulong *to= (ulong*) to_var, *from= (ulong*) from_var;
while (to != end)
*(to++)+= *(from++);
/* Handle the not ulong variables. See end of system_status_var */
to_var->bytes_received+= from_var->bytes_received;
to_var->bytes_sent+= from_var->bytes_sent;
to_var->rows_read+= from_var->rows_read;
to_var->rows_sent+= from_var->rows_sent;
to_var->rows_tmp_read+= from_var->rows_tmp_read;
to_var->binlog_bytes_written+= from_var->binlog_bytes_written;
to_var->cpu_time+= from_var->cpu_time;
to_var->busy_time+= from_var->busy_time;
/*
Update global_memory_used. We have to do this with atomic_add as the
global value can change outside of LOCK_status.
*/
if (to_var == &global_status_var)
{
DBUG_PRINT("info", ("global memory_used: %lld size: %lld",
(longlong) global_status_var.global_memory_used,
(longlong) from_var->global_memory_used));
}
// workaround for gcc 4.2.4-1ubuntu4 -fPIE (from DEB_BUILD_HARDENING=1)
int64 volatile * volatile ptr= &to_var->global_memory_used;
my_atomic_add64_explicit(ptr, from_var->global_memory_used,
MY_MEMORY_ORDER_RELAXED);
}
/*
Add the difference between two status variable arrays to another one.
SYNOPSIS
add_diff_to_status
to_var add to this array
from_var from this array
dec_var minus this array
NOTE
This function assumes that all variables at start are long/ulong and
other types are handled explicitely
*/
void add_diff_to_status(STATUS_VAR *to_var, STATUS_VAR *from_var,
STATUS_VAR *dec_var)
{
ulong *end= (ulong*) ((uchar*) to_var + offsetof(STATUS_VAR,
last_system_status_var) +
sizeof(ulong));
ulong *to= (ulong*) to_var, *from= (ulong*) from_var, *dec= (ulong*) dec_var;
while (to != end)
*(to++)+= *(from++) - *(dec++);
to_var->bytes_received+= from_var->bytes_received -
dec_var->bytes_received;
to_var->bytes_sent+= from_var->bytes_sent - dec_var->bytes_sent;
to_var->rows_read+= from_var->rows_read - dec_var->rows_read;
to_var->rows_sent+= from_var->rows_sent - dec_var->rows_sent;
to_var->rows_tmp_read+= from_var->rows_tmp_read - dec_var->rows_tmp_read;
to_var->binlog_bytes_written+= from_var->binlog_bytes_written -
dec_var->binlog_bytes_written;
to_var->cpu_time+= from_var->cpu_time - dec_var->cpu_time;
to_var->busy_time+= from_var->busy_time - dec_var->busy_time;
/*
We don't need to accumulate memory_used as these are not reset or used by
the calling functions. See execute_show_status().
*/
}
#define SECONDS_TO_WAIT_FOR_KILL 2
#if !defined(__WIN__) && defined(HAVE_SELECT)
/* my_sleep() can wait for sub second times */
#define WAIT_FOR_KILL_TRY_TIMES 20
#else
#define WAIT_FOR_KILL_TRY_TIMES 2
#endif
/**
Awake a thread.
@param[in] state_to_set value for THD::killed
This is normally called from another thread's THD object.
@note Do always call this while holding LOCK_thd_data.
NOT_KILLED is used to awake a thread for a slave
*/
void THD::awake(killed_state state_to_set)
{
DBUG_ENTER("THD::awake");
DBUG_PRINT("enter", ("this: %p current_thd: %p state: %d",
this, current_thd, (int) state_to_set));
THD_CHECK_SENTRY(this);
mysql_mutex_assert_owner(&LOCK_thd_data);
print_aborted_warning(3, "KILLED");
/*
Don't degrade killed state, for example from a KILL_CONNECTION to
STATEMENT TIMEOUT
*/
if (killed >= KILL_CONNECTION)
state_to_set= killed;
/* Set the 'killed' flag of 'this', which is the target THD object. */
mysql_mutex_lock(&LOCK_thd_kill);
set_killed_no_mutex(state_to_set);
if (state_to_set >= KILL_CONNECTION || state_to_set == NOT_KILLED)
{
#ifdef SIGNAL_WITH_VIO_CLOSE
if (this != current_thd)
{
if(active_vio)
vio_shutdown(active_vio, SHUT_RDWR);
}
#endif
/* Mark the target thread's alarm request expired, and signal alarm. */
thr_alarm_kill(thread_id);
/* Send an event to the scheduler that a thread should be killed. */
if (!slave_thread)
MYSQL_CALLBACK(scheduler, post_kill_notification, (this));
}
/* Interrupt target waiting inside a storage engine. */
if (state_to_set != NOT_KILLED)
ha_kill_query(this, thd_kill_level(this));
/* Broadcast a condition to kick the target if it is waiting on it. */
if (mysys_var)
{
mysql_mutex_lock(&mysys_var->mutex);
if (!system_thread) // Don't abort locks
mysys_var->abort=1;
/*
This broadcast could be up in the air if the victim thread
exits the cond in the time between read and broadcast, but that is
ok since all we want to do is to make the victim thread get out
of waiting on current_cond.
If we see a non-zero current_cond: it cannot be an old value (because
then exit_cond() should have run and it can't because we have mutex); so
it is the true value but maybe current_mutex is not yet non-zero (we're
in the middle of enter_cond() and there is a "memory order
inversion"). So we test the mutex too to not lock 0.
Note that there is a small chance we fail to kill. If victim has locked
current_mutex, but hasn't yet entered enter_cond() (which means that
current_cond and current_mutex are 0), then the victim will not get
a signal and it may wait "forever" on the cond (until
we issue a second KILL or the status it's waiting for happens).
It's true that we have set its thd->killed but it may not
see it immediately and so may have time to reach the cond_wait().
However, where possible, we test for killed once again after
enter_cond(). This should make the signaling as safe as possible.
However, there is still a small chance of failure on platforms with
instruction or memory write reordering.
We have to do the loop with trylock, because if we would use
pthread_mutex_lock(), we can cause a deadlock as we are here locking
the mysys_var->mutex and mysys_var->current_mutex in a different order
than in the thread we are trying to kill.
We only sleep for 2 seconds as we don't want to have LOCK_thd_data
locked too long time.
There is a small change we may not succeed in aborting a thread that
is not yet waiting for a mutex, but as this happens only for a
thread that was doing something else when the kill was issued and
which should detect the kill flag before it starts to wait, this
should be good enough.
*/
if (mysys_var->current_cond && mysys_var->current_mutex)
{
uint i;
for (i= 0; i < WAIT_FOR_KILL_TRY_TIMES * SECONDS_TO_WAIT_FOR_KILL; i++)
{
int ret= mysql_mutex_trylock(mysys_var->current_mutex);
mysql_cond_broadcast(mysys_var->current_cond);
if (!ret)
{
/* Signal is sure to get through */
mysql_mutex_unlock(mysys_var->current_mutex);
break;
}
my_sleep(1000000L / WAIT_FOR_KILL_TRY_TIMES);
}
}
mysql_mutex_unlock(&mysys_var->mutex);
}
mysql_mutex_unlock(&LOCK_thd_kill);
DBUG_VOID_RETURN;
}
/**
Close the Vio associated this session.
@remark LOCK_thd_data is taken due to the fact that
the Vio might be disassociated concurrently.
*/
void THD::disconnect()
{
Vio *vio= NULL;
mysql_mutex_lock(&LOCK_thd_data);
set_killed(KILL_CONNECTION);
#ifdef SIGNAL_WITH_VIO_CLOSE
/*
Since a active vio might might have not been set yet, in
any case save a reference to avoid closing a inexistent
one or closing the vio twice if there is a active one.
*/
vio= active_vio;
close_active_vio();
#endif
/* Disconnect even if a active vio is not associated. */
if (net.vio != vio)
vio_close(net.vio);
net.thd= 0; // Don't collect statistics
mysql_mutex_unlock(&LOCK_thd_data);
}
bool THD::notify_shared_lock(MDL_context_owner *ctx_in_use,
bool needs_thr_lock_abort)
{
THD *in_use= ctx_in_use->get_thd();
bool signalled= FALSE;
DBUG_ENTER("THD::notify_shared_lock");
DBUG_PRINT("enter",("needs_thr_lock_abort: %d", needs_thr_lock_abort));
if ((in_use->system_thread & SYSTEM_THREAD_DELAYED_INSERT) &&
!in_use->killed)
{
/* This code is similar to kill_delayed_threads() */
DBUG_PRINT("info", ("kill delayed thread"));
mysql_mutex_lock(&in_use->LOCK_thd_data);
if (in_use->killed < KILL_CONNECTION)
in_use->set_killed(KILL_CONNECTION);
if (in_use->mysys_var)
{
mysql_mutex_lock(&in_use->mysys_var->mutex);
if (in_use->mysys_var->current_cond)
mysql_cond_broadcast(in_use->mysys_var->current_cond);
/* Abort if about to wait in thr_upgrade_write_delay_lock */
in_use->mysys_var->abort= 1;
mysql_mutex_unlock(&in_use->mysys_var->mutex);
}
mysql_mutex_unlock(&in_use->LOCK_thd_data);
signalled= TRUE;
}
if (needs_thr_lock_abort)
{
mysql_mutex_lock(&in_use->LOCK_thd_data);
/* If not already dying */
if (in_use->killed != KILL_CONNECTION_HARD)
{
for (TABLE *thd_table= in_use->open_tables;
thd_table ;
thd_table= thd_table->next)
{
/*
Check for TABLE::needs_reopen() is needed since in some
places we call handler::close() for table instance (and set
TABLE::db_stat to 0) and do not remove such instances from
the THD::open_tables for some time, during which other
thread can see those instances (e.g. see partitioning code).
*/
if (!thd_table->needs_reopen())
{
signalled|= mysql_lock_abort_for_thread(this, thd_table);
if (WSREP(this) && wsrep_thd_is_BF(this, FALSE))
{
WSREP_DEBUG("remove_table_from_cache: %llu",
(unsigned long long) this->real_id);
wsrep_abort_thd((void *)this, (void *)in_use, FALSE);
}
}
}
}
mysql_mutex_unlock(&in_use->LOCK_thd_data);
}
DBUG_RETURN(signalled);
}
/*
Get error number for killed state
Note that the error message can't have any parameters.
If one needs parameters, one should use THD::killed_err_msg
See thd::kill_message()
*/
int THD::killed_errno()
{
DBUG_ENTER("killed_errno");
DBUG_PRINT("enter", ("killed: %d killed_errno: %d",
killed, killed_err ? killed_err->no: 0));
/* Ensure that killed_err is not set if we are not killed */
DBUG_ASSERT(!killed_err || killed != NOT_KILLED);
if (killed_err)
DBUG_RETURN(killed_err->no);
switch (killed) {
case NOT_KILLED:
case KILL_HARD_BIT:
DBUG_RETURN(0); // Probably wrong usage
case KILL_BAD_DATA:
case KILL_BAD_DATA_HARD:
case ABORT_QUERY_HARD:
case ABORT_QUERY:
DBUG_RETURN(0); // Not a real error
case KILL_CONNECTION:
case KILL_CONNECTION_HARD:
case KILL_SYSTEM_THREAD:
case KILL_SYSTEM_THREAD_HARD:
DBUG_RETURN(ER_CONNECTION_KILLED);
case KILL_QUERY:
case KILL_QUERY_HARD:
DBUG_RETURN(ER_QUERY_INTERRUPTED);
case KILL_TIMEOUT:
case KILL_TIMEOUT_HARD:
DBUG_RETURN(ER_STATEMENT_TIMEOUT);
case KILL_SERVER:
case KILL_SERVER_HARD:
DBUG_RETURN(ER_SERVER_SHUTDOWN);
}
DBUG_RETURN(0); // Keep compiler happy
}
/*
Remember the location of thread info, the structure needed for
sql_alloc() and the structure for the net buffer
*/
bool THD::store_globals()
{
/*
Assert that thread_stack is initialized: it's necessary to be able
to track stack overrun.
*/
DBUG_ASSERT(thread_stack);
if (set_current_thd(this) ||
my_pthread_setspecific_ptr(THR_MALLOC, &mem_root))
return 1;
/*
mysys_var is concurrently readable by a killer thread.
It is protected by LOCK_thd_data, it is not needed to lock while the
pointer is changing from NULL not non-NULL. If the kill thread reads
NULL it doesn't refer to anything, but if it is non-NULL we need to
ensure that the thread doesn't proceed to assign another thread to
have the mysys_var reference (which in fact refers to the worker
threads local storage with key THR_KEY_mysys.
*/
mysys_var=my_thread_var;
/*
Let mysqld define the thread id (not mysys)
This allows us to move THD to different threads if needed.
*/
mysys_var->id= thread_id;
#ifdef __NR_gettid
os_thread_id= (uint32)syscall(__NR_gettid);
#else
os_thread_id= 0;
#endif
real_id= pthread_self(); // For debugging
mysys_var->stack_ends_here= thread_stack + // for consistency, see libevent_thread_proc
STACK_DIRECTION * (long)my_thread_stack_size;
if (net.vio)
{
vio_set_thread_id(net.vio, real_id);
net.thd= this;
}
/*
We have to call thr_lock_info_init() again here as THD may have been
created in another thread
*/
thr_lock_info_init(&lock_info);
return 0;
}
/**
Untie THD from current thread
Used when using --thread-handling=pool-of-threads
*/
void THD::reset_globals()
{
mysql_mutex_lock(&LOCK_thd_data);
mysys_var= 0;
mysql_mutex_unlock(&LOCK_thd_data);
/* Undocking the thread specific data. */
set_current_thd(0);
my_pthread_setspecific_ptr(THR_MALLOC, NULL);
net.thd= 0;
}
/*
Cleanup after query.
SYNOPSIS
THD::cleanup_after_query()
DESCRIPTION
This function is used to reset thread data to its default state.
NOTE
This function is not suitable for setting thread data to some
non-default values, as there is only one replication thread, so
different master threads may overwrite data of each other on
slave.
*/
void THD::cleanup_after_query()
{
DBUG_ENTER("THD::cleanup_after_query");
thd_progress_end(this);
/*
Reset rand_used so that detection of calls to rand() will save random
seeds if needed by the slave.
Do not reset rand_used if inside a stored function or trigger because
only the call to these operations is logged. Thus only the calling
statement needs to detect rand() calls made by its substatements. These
substatements must not set rand_used to 0 because it would remove the
detection of rand() by the calling statement.
*/
if (!in_sub_stmt) /* stored functions and triggers are a special case */
{
/* Forget those values, for next binlogger: */
stmt_depends_on_first_successful_insert_id_in_prev_stmt= 0;
auto_inc_intervals_in_cur_stmt_for_binlog.empty();
rand_used= 0;
#ifndef EMBEDDED_LIBRARY
/*
Clean possible unused INSERT_ID events by current statement.
is_update_query() is needed to ignore SET statements:
Statements that don't update anything directly and don't
used stored functions. This is mostly necessary to ignore
statements in binlog between SET INSERT_ID and DML statement
which is intended to consume its event (there can be other
SET statements between them).
*/
if ((rgi_slave || rli_fake) && is_update_query(lex->sql_command))
auto_inc_intervals_forced.empty();
#endif
}
/*
Forget the binlog stmt filter for the next query.
There are some code paths that:
- do not call THD::decide_logging_format()
- do call THD::binlog_query(),
making this reset necessary.
*/
reset_binlog_local_stmt_filter();
if (first_successful_insert_id_in_cur_stmt > 0)
{
/* set what LAST_INSERT_ID() will return */
first_successful_insert_id_in_prev_stmt=
first_successful_insert_id_in_cur_stmt;
first_successful_insert_id_in_cur_stmt= 0;
substitute_null_with_insert_id= TRUE;
}
arg_of_last_insert_id_function= 0;
/* Free Items that were created during this execution */
free_items();
/* Reset where. */
where= THD::DEFAULT_WHERE;
/* reset table map for multi-table update */
table_map_for_update= 0;
m_binlog_invoker= INVOKER_NONE;
#ifdef WITH_WSREP
if (TOTAL_ORDER == wsrep_exec_mode)
{
wsrep_exec_mode = LOCAL_STATE;
}
#endif /* WITH_WSREP */
#ifndef EMBEDDED_LIBRARY
if (rgi_slave)
rgi_slave->cleanup_after_query();
#endif
#ifdef WITH_WSREP
wsrep_sync_wait_gtid= WSREP_GTID_UNDEFINED;
if (!in_active_multi_stmt_transaction())
wsrep_affected_rows= 0;
#endif /* WITH_WSREP */
DBUG_VOID_RETURN;
}
/*
Convert a string to another character set
SYNOPSIS
convert_string()
to Store new allocated string here
to_cs New character set for allocated string
from String to convert
from_length Length of string to convert
from_cs Original character set
NOTES
to will be 0-terminated to make it easy to pass to system funcs
RETURN
0 ok
1 End of memory.
In this case to->str will point to 0 and to->length will be 0.
*/
bool THD::convert_string(LEX_STRING *to, CHARSET_INFO *to_cs,
const char *from, uint from_length,
CHARSET_INFO *from_cs)
{
DBUG_ENTER("THD::convert_string");
size_t new_length= to_cs->mbmaxlen * from_length;
uint dummy_errors;
if (alloc_lex_string(to, new_length + 1))
DBUG_RETURN(true); // EOM
to->length= copy_and_convert((char*) to->str, new_length, to_cs,
from, from_length, from_cs, &dummy_errors);
to->str[to->length]= 0; // Safety
DBUG_RETURN(false);
}
/*
Convert a string between two character sets.
dstcs and srccs cannot be &my_charset_bin.
*/
bool THD::convert_fix(CHARSET_INFO *dstcs, LEX_STRING *dst,
CHARSET_INFO *srccs, const char *src, uint src_length,
String_copier *status)
{
DBUG_ENTER("THD::convert_fix");
size_t dst_length= dstcs->mbmaxlen * src_length;
if (alloc_lex_string(dst, dst_length + 1))
DBUG_RETURN(true); // EOM
dst->length= status->convert_fix(dstcs, (char*) dst->str, dst_length,
srccs, src, src_length, src_length);
dst->str[dst->length]= 0; // Safety
DBUG_RETURN(false);
}
/*
Copy or convert a string.
*/
bool THD::copy_fix(CHARSET_INFO *dstcs, LEX_STRING *dst,
CHARSET_INFO *srccs, const char *src, uint src_length,
String_copier *status)
{
DBUG_ENTER("THD::copy_fix");
size_t dst_length= dstcs->mbmaxlen * src_length;
if (alloc_lex_string(dst, dst_length + 1))
DBUG_RETURN(true); // EOM
dst->length= status->well_formed_copy(dstcs, dst->str, dst_length,
srccs, src, src_length, src_length);
dst->str[dst->length]= '\0';
DBUG_RETURN(false);
}
class String_copier_with_error: public String_copier
{
public:
bool check_errors(CHARSET_INFO *srccs, const char *src, uint src_length)
{
if (most_important_error_pos())
{
ErrConvString err(src, src_length, &my_charset_bin);
my_error(ER_INVALID_CHARACTER_STRING, MYF(0), srccs->csname, err.ptr());
return true;
}
return false;
}
};
bool THD::convert_with_error(CHARSET_INFO *dstcs, LEX_STRING *dst,
CHARSET_INFO *srccs,
const char *src, uint src_length)
{
String_copier_with_error status;
return convert_fix(dstcs, dst, srccs, src, src_length, &status) ||
status.check_errors(srccs, src, src_length);
}
bool THD::copy_with_error(CHARSET_INFO *dstcs, LEX_STRING *dst,
CHARSET_INFO *srccs,
const char *src, uint src_length)
{
String_copier_with_error status;
return copy_fix(dstcs, dst, srccs, src, src_length, &status) ||
status.check_errors(srccs, src, src_length);
}
/*
Convert string from source character set to target character set inplace.
SYNOPSIS
THD::convert_string
DESCRIPTION
Convert string using convert_buffer - buffer for character set
conversion shared between all protocols.
RETURN
0 ok
!0 out of memory
*/
bool THD::convert_string(String *s, CHARSET_INFO *from_cs, CHARSET_INFO *to_cs)
{
uint dummy_errors;
if (convert_buffer.copy(s->ptr(), s->length(), from_cs, to_cs, &dummy_errors))
return TRUE;
/* If convert_buffer >> s copying is more efficient long term */
if (convert_buffer.alloced_length() >= convert_buffer.length() * 2 ||
!s->is_alloced())
{
return s->copy(convert_buffer);
}
s->swap(convert_buffer);
return FALSE;
}
/*
Update some cache variables when character set changes
*/
void THD::update_charset()
{
uint32 not_used;
charset_is_system_charset=
!String::needs_conversion(0,
variables.character_set_client,
system_charset_info,
¬_used);
charset_is_collation_connection=
!String::needs_conversion(0,
variables.character_set_client,
variables.collation_connection,
¬_used);
charset_is_character_set_filesystem=
!String::needs_conversion(0,
variables.character_set_client,
variables.character_set_filesystem,
¬_used);
}
/* routings to adding tables to list of changed in transaction tables */
inline static void list_include(CHANGED_TABLE_LIST** prev,
CHANGED_TABLE_LIST* curr,
CHANGED_TABLE_LIST* new_table)
{
if (new_table)
{
*prev = new_table;
(*prev)->next = curr;
}
}
/* add table to list of changed in transaction tables */
void THD::add_changed_table(TABLE *table)
{
DBUG_ENTER("THD::add_changed_table(table)");
DBUG_ASSERT(in_multi_stmt_transaction_mode() && table->file->has_transactions());
add_changed_table(table->s->table_cache_key.str,
(long) table->s->table_cache_key.length);
DBUG_VOID_RETURN;
}
void THD::add_changed_table(const char *key, long key_length)
{
DBUG_ENTER("THD::add_changed_table(key)");
CHANGED_TABLE_LIST **prev_changed = &transaction.changed_tables;
CHANGED_TABLE_LIST *curr = transaction.changed_tables;
for (; curr; prev_changed = &(curr->next), curr = curr->next)
{
int cmp = (long)curr->key_length - (long)key_length;
if (cmp < 0)
{
list_include(prev_changed, curr, changed_table_dup(key, key_length));
DBUG_PRINT("info",
("key_length: %ld %u", key_length,
(*prev_changed)->key_length));
DBUG_VOID_RETURN;
}
else if (cmp == 0)
{
cmp = memcmp(curr->key, key, curr->key_length);
if (cmp < 0)
{
list_include(prev_changed, curr, changed_table_dup(key, key_length));
DBUG_PRINT("info",
("key_length: %ld %u", key_length,
(*prev_changed)->key_length));
DBUG_VOID_RETURN;
}
else if (cmp == 0)
{
DBUG_PRINT("info", ("already in list"));
DBUG_VOID_RETURN;
}
}
}
*prev_changed = changed_table_dup(key, key_length);
DBUG_PRINT("info", ("key_length: %ld %u", key_length,
(*prev_changed)->key_length));
DBUG_VOID_RETURN;
}
CHANGED_TABLE_LIST* THD::changed_table_dup(const char *key, long key_length)
{
CHANGED_TABLE_LIST* new_table =
(CHANGED_TABLE_LIST*) trans_alloc(ALIGN_SIZE(sizeof(CHANGED_TABLE_LIST))+
key_length + 1);
if (!new_table)
{
my_error(EE_OUTOFMEMORY, MYF(ME_BELL+ME_FATALERROR),
ALIGN_SIZE(sizeof(TABLE_LIST)) + key_length + 1);
set_killed(KILL_CONNECTION);
return 0;
}
new_table->key= ((char*)new_table)+ ALIGN_SIZE(sizeof(CHANGED_TABLE_LIST));
new_table->next = 0;
new_table->key_length = key_length;
::memcpy(new_table->key, key, key_length);
return new_table;
}
int THD::send_explain_fields(select_result *result, uint8 explain_flags, bool is_analyze)
{
List<Item> field_list;
if (lex->explain_json)
make_explain_json_field_list(field_list, is_analyze);
else
make_explain_field_list(field_list, explain_flags, is_analyze);
result->prepare(field_list, NULL);
return (result->send_result_set_metadata(field_list,
Protocol::SEND_NUM_ROWS |
Protocol::SEND_EOF));
}
void THD::make_explain_json_field_list(List<Item> &field_list, bool is_analyze)
{
Item *item= new (mem_root) Item_empty_string(this, (is_analyze ?
"ANALYZE" :
"EXPLAIN"),
78, system_charset_info);
field_list.push_back(item, mem_root);
}
/*
Populate the provided field_list with EXPLAIN output columns.
this->lex->describe has the EXPLAIN flags
The set/order of columns must be kept in sync with
Explain_query::print_explain and co.
*/
void THD::make_explain_field_list(List<Item> &field_list, uint8 explain_flags,
bool is_analyze)
{
Item *item;
CHARSET_INFO *cs= system_charset_info;
field_list.push_back(item= new (mem_root)
Item_return_int(this, "id", 3,
MYSQL_TYPE_LONGLONG), mem_root);
item->maybe_null= 1;
field_list.push_back(new (mem_root)
Item_empty_string(this, "select_type", 19, cs),
mem_root);
field_list.push_back(item= new (mem_root)
Item_empty_string(this, "table", NAME_CHAR_LEN, cs),
mem_root);
item->maybe_null= 1;
if (explain_flags & DESCRIBE_PARTITIONS)
{
/* Maximum length of string that make_used_partitions_str() can produce */
item= new (mem_root) Item_empty_string(this, "partitions",
MAX_PARTITIONS * (1 + FN_LEN), cs);
field_list.push_back(item, mem_root);
item->maybe_null= 1;
}
field_list.push_back(item= new (mem_root)
Item_empty_string(this, "type", 10, cs),
mem_root);
item->maybe_null= 1;
field_list.push_back(item= new (mem_root)
Item_empty_string(this, "possible_keys",
NAME_CHAR_LEN*MAX_KEY, cs),
mem_root);
item->maybe_null=1;
field_list.push_back(item=new (mem_root)
Item_empty_string(this, "key", NAME_CHAR_LEN, cs),
mem_root);
item->maybe_null=1;
field_list.push_back(item=new (mem_root)
Item_empty_string(this, "key_len",
NAME_CHAR_LEN*MAX_KEY),
mem_root);
item->maybe_null=1;
field_list.push_back(item=new (mem_root)
Item_empty_string(this, "ref",
NAME_CHAR_LEN*MAX_REF_PARTS, cs),
mem_root);
item->maybe_null=1;
field_list.push_back(item= new (mem_root)
Item_return_int(this, "rows", 10, MYSQL_TYPE_LONGLONG),
mem_root);
if (is_analyze)
{
field_list.push_back(item= new (mem_root)
Item_float(this, "r_rows", 0.1234, 10, 4),
mem_root);
item->maybe_null=1;
}
if (is_analyze || (explain_flags & DESCRIBE_EXTENDED))
{
field_list.push_back(item= new (mem_root)
Item_float(this, "filtered", 0.1234, 2, 4),
mem_root);
item->maybe_null=1;
}
if (is_analyze)
{
field_list.push_back(item= new (mem_root)
Item_float(this, "r_filtered", 0.1234, 2, 4),
mem_root);
item->maybe_null=1;
}
item->maybe_null= 1;
field_list.push_back(new (mem_root)
Item_empty_string(this, "Extra", 255, cs),
mem_root);
}
#ifdef SIGNAL_WITH_VIO_CLOSE
void THD::close_active_vio()
{
DBUG_ENTER("close_active_vio");
mysql_mutex_assert_owner(&LOCK_thd_data);
#ifndef EMBEDDED_LIBRARY
if (active_vio)
{
vio_close(active_vio);
active_vio = 0;
}
#endif
DBUG_VOID_RETURN;
}
#endif
struct Item_change_record: public ilink
{
Item **place;
Item *old_value;
/* Placement new was hidden by `new' in ilink (TODO: check): */
static void *operator new(size_t size, void *mem) { return mem; }
static void operator delete(void *ptr, size_t size) {}
static void operator delete(void *ptr, void *mem) { /* never called */ }
};
/*
Register an item tree tree transformation, performed by the query
optimizer. We need a pointer to runtime_memroot because it may be !=
thd->mem_root (due to possible set_n_backup_active_arena called for thd).
*/
void THD::nocheck_register_item_tree_change(Item **place, Item *old_value,
MEM_ROOT *runtime_memroot)
{
Item_change_record *change;
DBUG_ENTER("THD::nocheck_register_item_tree_change");
DBUG_PRINT("enter", ("Register %p <- %p", old_value, (*place)));
/*
Now we use one node per change, which adds some memory overhead,
but still is rather fast as we use alloc_root for allocations.
A list of item tree changes of an average query should be short.
*/
void *change_mem= alloc_root(runtime_memroot, sizeof(*change));
if (change_mem == 0)
{
/*
OOM, thd->fatal_error() is called by the error handler of the
memroot. Just return.
*/
DBUG_VOID_RETURN;
}
change= new (change_mem) Item_change_record;
change->place= place;
change->old_value= old_value;
change_list.append(change);
DBUG_VOID_RETURN;
}
/**
Check and register item change if needed
@param place place where we should assign new value
@param new_value place of the new value
@details
Let C be a reference to an item that changed the reference A
at the location (occurrence) L1 and this change has been registered.
If C is substituted for reference A another location (occurrence) L2
that is to be registered as well than this change has to be
consistent with the first change in order the procedure that rollback
changes to substitute the same reference at both locations L1 and L2.
*/
void THD::check_and_register_item_tree_change(Item **place, Item **new_value,
MEM_ROOT *runtime_memroot)
{
Item_change_record *change;
DBUG_ENTER("THD::check_and_register_item_tree_change");
DBUG_PRINT("enter", ("Register: %p (%p) <- %p (%p)",
*place, place, *new_value, new_value));
I_List_iterator<Item_change_record> it(change_list);
while ((change= it++))
{
if (change->place == new_value)
break; // we need only very first value
}
if (change)
nocheck_register_item_tree_change(place, change->old_value,
runtime_memroot);
DBUG_VOID_RETURN;
}
void THD::rollback_item_tree_changes()
{
I_List_iterator<Item_change_record> it(change_list);
Item_change_record *change;
while ((change= it++))
{
*change->place= change->old_value;
}
/* We can forget about changes memory: it's allocated in runtime memroot */
change_list.empty();
}
/*****************************************************************************
** Functions to provide a interface to select results
*****************************************************************************/
void select_result::cleanup()
{
/* do nothing */
}
bool select_result::check_simple_select() const
{
my_error(ER_SP_BAD_CURSOR_QUERY, MYF(0));
return TRUE;
}
static String default_line_term("\n",default_charset_info);
static String default_escaped("\\",default_charset_info);
static String default_field_term("\t",default_charset_info);
static String default_enclosed_and_line_start("", default_charset_info);
static String default_xml_row_term("<row>", default_charset_info);
sql_exchange::sql_exchange(char *name, bool flag,
enum enum_filetype filetype_arg)
:file_name(name), opt_enclosed(0), dumpfile(flag), skip_lines(0)
{
filetype= filetype_arg;
field_term= &default_field_term;
enclosed= line_start= &default_enclosed_and_line_start;
line_term= filetype == FILETYPE_CSV ?
&default_line_term : &default_xml_row_term;
escaped= &default_escaped;
cs= NULL;
}
bool sql_exchange::escaped_given(void)
{
return escaped != &default_escaped;
}
bool select_send::send_result_set_metadata(List<Item> &list, uint flags)
{
bool res;
#ifdef WITH_WSREP
if (WSREP(thd) && thd->wsrep_retry_query)
{
WSREP_DEBUG("skipping select metadata");
return FALSE;
}
#endif /* WITH_WSREP */
if (!(res= thd->protocol->send_result_set_metadata(&list, flags)))
is_result_set_started= 1;
return res;
}
void select_send::abort_result_set()
{
DBUG_ENTER("select_send::abort_result_set");
if (is_result_set_started && thd->spcont)
{
/*
We're executing a stored procedure, have an open result
set and an SQL exception condition. In this situation we
must abort the current statement, silence the error and
start executing the continue/exit handler if one is found.
Before aborting the statement, let's end the open result set, as
otherwise the client will hang due to the violation of the
client/server protocol.
*/
thd->spcont->end_partial_result_set= TRUE;
}
DBUG_VOID_RETURN;
}
/**
Cleanup an instance of this class for re-use
at next execution of a prepared statement/
stored procedure statement.
*/
void select_send::cleanup()
{
is_result_set_started= FALSE;
}
/* Send data to client. Returns 0 if ok */
int select_send::send_data(List<Item> &items)
{
Protocol *protocol= thd->protocol;
DBUG_ENTER("select_send::send_data");
/* unit is not set when using 'delete ... returning' */
if (unit && unit->offset_limit_cnt)
{ // using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(FALSE);
}
if (thd->killed == ABORT_QUERY)
DBUG_RETURN(FALSE);
/*
We may be passing the control from mysqld to the client: release the
InnoDB adaptive hash S-latch to avoid thread deadlocks if it was reserved
by thd
*/
ha_release_temporary_latches(thd);
protocol->prepare_for_resend();
if (protocol->send_result_set_row(&items))
{
protocol->remove_last_row();
DBUG_RETURN(TRUE);
}
thd->inc_sent_row_count(1);
if (thd->vio_ok())
DBUG_RETURN(protocol->write());
DBUG_RETURN(0);
}
bool select_send::send_eof()
{
/*
We may be passing the control from mysqld to the client: release the
InnoDB adaptive hash S-latch to avoid thread deadlocks if it was reserved
by thd
*/
ha_release_temporary_latches(thd);
/*
Don't send EOF if we're in error condition (which implies we've already
sent or are sending an error)
*/
if (thd->is_error())
return TRUE;
::my_eof(thd);
is_result_set_started= 0;
return FALSE;
}
/************************************************************************
Handling writing to file
************************************************************************/
bool select_to_file::send_eof()
{
int error= MY_TEST(end_io_cache(&cache));
if (mysql_file_close(file, MYF(MY_WME)) || thd->is_error())
error= true;
if (!error && !suppress_my_ok)
{
::my_ok(thd,row_count);
}
file= -1;
return error;
}
void select_to_file::cleanup()
{
/* In case of error send_eof() may be not called: close the file here. */
if (file >= 0)
{
(void) end_io_cache(&cache);
mysql_file_close(file, MYF(0));
file= -1;
}
path[0]= '\0';
row_count= 0;
}
select_to_file::~select_to_file()
{
if (file >= 0)
{ // This only happens in case of error
(void) end_io_cache(&cache);
mysql_file_close(file, MYF(0));
file= -1;
}
}
/***************************************************************************
** Export of select to textfile
***************************************************************************/
select_export::~select_export()
{
thd->set_sent_row_count(row_count);
}
/*
Create file with IO cache
SYNOPSIS
create_file()
thd Thread handle
path File name
exchange Excange class
cache IO cache
RETURN
>= 0 File handle
-1 Error
*/
static File create_file(THD *thd, char *path, sql_exchange *exchange,
IO_CACHE *cache)
{
File file;
uint option= MY_UNPACK_FILENAME | MY_RELATIVE_PATH;
#ifdef DONT_ALLOW_FULL_LOAD_DATA_PATHS
option|= MY_REPLACE_DIR; // Force use of db directory
#endif
if (!dirname_length(exchange->file_name))
{
strxnmov(path, FN_REFLEN-1, mysql_real_data_home, thd->db ? thd->db : "",
NullS);
(void) fn_format(path, exchange->file_name, path, "", option);
}
else
(void) fn_format(path, exchange->file_name, mysql_real_data_home, "", option);
if (!is_secure_file_path(path))
{
/* Write only allowed to dir or subdir specified by secure_file_priv */
my_error(ER_OPTION_PREVENTS_STATEMENT, MYF(0), "--secure-file-priv");
return -1;
}
if (!access(path, F_OK))
{
my_error(ER_FILE_EXISTS_ERROR, MYF(0), exchange->file_name);
return -1;
}
/* Create the file world readable */
if ((file= mysql_file_create(key_select_to_file,
path, 0666, O_WRONLY|O_EXCL, MYF(MY_WME))) < 0)
return file;
#ifdef HAVE_FCHMOD
(void) fchmod(file, 0666); // Because of umask()
#else
(void) chmod(path, 0666);
#endif
if (init_io_cache(cache, file, 0L, WRITE_CACHE, 0L, 1, MYF(MY_WME)))
{
mysql_file_close(file, MYF(0));
/* Delete file on error, it was just created */
mysql_file_delete(key_select_to_file, path, MYF(0));
return -1;
}
return file;
}
int
select_export::prepare(List<Item> &list, SELECT_LEX_UNIT *u)
{
bool blob_flag=0;
bool string_results= FALSE, non_string_results= FALSE;
unit= u;
if ((uint) strlen(exchange->file_name) + NAME_LEN >= FN_REFLEN)
strmake_buf(path,exchange->file_name);
write_cs= exchange->cs ? exchange->cs : &my_charset_bin;
if ((file= create_file(thd, path, exchange, &cache)) < 0)
return 1;
/* Check if there is any blobs in data */
{
List_iterator_fast<Item> li(list);
Item *item;
while ((item=li++))
{
if (item->max_length >= MAX_BLOB_WIDTH)
{
blob_flag=1;
break;
}
if (item->result_type() == STRING_RESULT)
string_results= TRUE;
else
non_string_results= TRUE;
}
}
if (exchange->escaped->numchars() > 1 || exchange->enclosed->numchars() > 1)
{
my_error(ER_WRONG_FIELD_TERMINATORS, MYF(0));
return TRUE;
}
if (exchange->escaped->length() > 1 || exchange->enclosed->length() > 1 ||
!my_isascii(exchange->escaped->ptr()[0]) ||
!my_isascii(exchange->enclosed->ptr()[0]) ||
!exchange->field_term->is_ascii() || !exchange->line_term->is_ascii() ||
!exchange->line_start->is_ascii())
{
/*
Current LOAD DATA INFILE recognizes field/line separators "as is" without
converting from client charset to data file charset. So, it is supposed,
that input file of LOAD DATA INFILE consists of data in one charset and
separators in other charset. For the compatibility with that [buggy]
behaviour SELECT INTO OUTFILE implementation has been saved "as is" too,
but the new warning message has been added:
Non-ASCII separator arguments are not fully supported
*/
push_warning(thd, Sql_condition::WARN_LEVEL_WARN,
WARN_NON_ASCII_SEPARATOR_NOT_IMPLEMENTED,
ER_THD(thd, WARN_NON_ASCII_SEPARATOR_NOT_IMPLEMENTED));
}
field_term_length=exchange->field_term->length();
field_term_char= field_term_length ?
(int) (uchar) (*exchange->field_term)[0] : INT_MAX;
if (!exchange->line_term->length())
exchange->line_term=exchange->field_term; // Use this if it exists
field_sep_char= (exchange->enclosed->length() ?
(int) (uchar) (*exchange->enclosed)[0] : field_term_char);
if (exchange->escaped->length() && (exchange->escaped_given() ||
!(thd->variables.sql_mode & MODE_NO_BACKSLASH_ESCAPES)))
escape_char= (int) (uchar) (*exchange->escaped)[0];
else
escape_char= -1;
is_ambiguous_field_sep= MY_TEST(strchr(ESCAPE_CHARS, field_sep_char));
is_unsafe_field_sep= MY_TEST(strchr(NUMERIC_CHARS, field_sep_char));
line_sep_char= (exchange->line_term->length() ?
(int) (uchar) (*exchange->line_term)[0] : INT_MAX);
if (!field_term_length)
exchange->opt_enclosed=0;
if (!exchange->enclosed->length())
exchange->opt_enclosed=1; // A little quicker loop
fixed_row_size= (!field_term_length && !exchange->enclosed->length() &&
!blob_flag);
if ((is_ambiguous_field_sep && exchange->enclosed->is_empty() &&
(string_results || is_unsafe_field_sep)) ||
(exchange->opt_enclosed && non_string_results &&
field_term_length && strchr(NUMERIC_CHARS, field_term_char)))
{
push_warning(thd, Sql_condition::WARN_LEVEL_WARN,
ER_AMBIGUOUS_FIELD_TERM,
ER_THD(thd, ER_AMBIGUOUS_FIELD_TERM));
is_ambiguous_field_term= TRUE;
}
else
is_ambiguous_field_term= FALSE;
return 0;
}
#define NEED_ESCAPING(x) ((int) (uchar) (x) == escape_char || \
(enclosed ? (int) (uchar) (x) == field_sep_char \
: (int) (uchar) (x) == field_term_char) || \
(int) (uchar) (x) == line_sep_char || \
!(x))
int select_export::send_data(List<Item> &items)
{
DBUG_ENTER("select_export::send_data");
char buff[MAX_FIELD_WIDTH],null_buff[2],space[MAX_FIELD_WIDTH];
char cvt_buff[MAX_FIELD_WIDTH];
String cvt_str(cvt_buff, sizeof(cvt_buff), write_cs);
bool space_inited=0;
String tmp(buff,sizeof(buff),&my_charset_bin),*res;
tmp.length(0);
if (unit->offset_limit_cnt)
{ // using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(0);
}
if (thd->killed == ABORT_QUERY)
DBUG_RETURN(0);
row_count++;
Item *item;
uint used_length=0,items_left=items.elements;
List_iterator_fast<Item> li(items);
if (my_b_write(&cache,(uchar*) exchange->line_start->ptr(),
exchange->line_start->length()))
goto err;
while ((item=li++))
{
Item_result result_type=item->result_type();
bool enclosed = (exchange->enclosed->length() &&
(!exchange->opt_enclosed || result_type == STRING_RESULT));
res=item->str_result(&tmp);
if (res && !my_charset_same(write_cs, res->charset()) &&
!my_charset_same(write_cs, &my_charset_bin))
{
String_copier copier;
const char *error_pos;
uint32 bytes;
uint64 estimated_bytes=
((uint64) res->length() / res->charset()->mbminlen + 1) *
write_cs->mbmaxlen + 1;
set_if_smaller(estimated_bytes, UINT_MAX32);
if (cvt_str.realloc((uint32) estimated_bytes))
{
my_error(ER_OUTOFMEMORY, MYF(ME_FATALERROR), (uint32) estimated_bytes);
goto err;
}
bytes= copier.well_formed_copy(write_cs, (char *) cvt_str.ptr(),
cvt_str.alloced_length(),
res->charset(),
res->ptr(), res->length());
error_pos= copier.most_important_error_pos();
if (error_pos)
{
char printable_buff[32];
convert_to_printable(printable_buff, sizeof(printable_buff),
error_pos, res->ptr() + res->length() - error_pos,
res->charset(), 6);
push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN,
ER_TRUNCATED_WRONG_VALUE_FOR_FIELD,
ER_THD(thd, ER_TRUNCATED_WRONG_VALUE_FOR_FIELD),
"string", printable_buff,
item->name, static_cast<long>(row_count));
}
else if (copier.source_end_pos() < res->ptr() + res->length())
{
/*
result is longer than UINT_MAX32 and doesn't fit into String
*/
push_warning_printf(thd, Sql_condition::WARN_LEVEL_WARN,
WARN_DATA_TRUNCATED,
ER_THD(thd, WARN_DATA_TRUNCATED),
item->full_name(), static_cast<long>(row_count));
}
cvt_str.length(bytes);
res= &cvt_str;
}
if (res && enclosed)
{
if (my_b_write(&cache,(uchar*) exchange->enclosed->ptr(),
exchange->enclosed->length()))
goto err;
}
if (!res)
{ // NULL
if (!fixed_row_size)
{
if (escape_char != -1) // Use \N syntax
{
null_buff[0]=escape_char;
null_buff[1]='N';
if (my_b_write(&cache,(uchar*) null_buff,2))
goto err;
}
else if (my_b_write(&cache,(uchar*) "NULL",4))
goto err;
}
else
{
used_length=0; // Fill with space
}
}
else
{
if (fixed_row_size)
used_length=MY_MIN(res->length(),item->max_length);
else
used_length=res->length();
if ((result_type == STRING_RESULT || is_unsafe_field_sep) &&
escape_char != -1)
{
char *pos, *start, *end;
CHARSET_INFO *res_charset= res->charset();
CHARSET_INFO *character_set_client= thd->variables.
character_set_client;
bool check_second_byte= (res_charset == &my_charset_bin) &&
character_set_client->
escape_with_backslash_is_dangerous;
DBUG_ASSERT(character_set_client->mbmaxlen == 2 ||
!character_set_client->escape_with_backslash_is_dangerous);
for (start=pos=(char*) res->ptr(),end=pos+used_length ;
pos != end ;
pos++)
{
#ifdef USE_MB
if (use_mb(res_charset))
{
int l;
if ((l=my_ismbchar(res_charset, pos, end)))
{
pos += l-1;
continue;
}
}
#endif
/*
Special case when dumping BINARY/VARBINARY/BLOB values
for the clients with character sets big5, cp932, gbk and sjis,
which can have the escape character (0x5C "\" by default)
as the second byte of a multi-byte sequence.
If
- pos[0] is a valid multi-byte head (e.g 0xEE) and
- pos[1] is 0x00, which will be escaped as "\0",
then we'll get "0xEE + 0x5C + 0x30" in the output file.
If this file is later loaded using this sequence of commands:
mysql> create table t1 (a varchar(128)) character set big5;
mysql> LOAD DATA INFILE 'dump.txt' INTO TABLE t1;
then 0x5C will be misinterpreted as the second byte
of a multi-byte character "0xEE + 0x5C", instead of
escape character for 0x00.
To avoid this confusion, we'll escape the multi-byte
head character too, so the sequence "0xEE + 0x00" will be
dumped as "0x5C + 0xEE + 0x5C + 0x30".
Note, in the condition below we only check if
mbcharlen is equal to 2, because there are no
character sets with mbmaxlen longer than 2
and with escape_with_backslash_is_dangerous set.
DBUG_ASSERT before the loop makes that sure.
*/
if ((NEED_ESCAPING(*pos) ||
(check_second_byte &&
my_mbcharlen(character_set_client, (uchar) *pos) == 2 &&
pos + 1 < end &&
NEED_ESCAPING(pos[1]))) &&
/*
Don't escape field_term_char by doubling - doubling is only
valid for ENCLOSED BY characters:
*/
(enclosed || !is_ambiguous_field_term ||
(int) (uchar) *pos != field_term_char))
{
char tmp_buff[2];
tmp_buff[0]= ((int) (uchar) *pos == field_sep_char &&
is_ambiguous_field_sep) ?
field_sep_char : escape_char;
tmp_buff[1]= *pos ? *pos : '0';
if (my_b_write(&cache,(uchar*) start,(uint) (pos-start)) ||
my_b_write(&cache,(uchar*) tmp_buff,2))
goto err;
start=pos+1;
}
}
if (my_b_write(&cache,(uchar*) start,(uint) (pos-start)))
goto err;
}
else if (my_b_write(&cache,(uchar*) res->ptr(),used_length))
goto err;
}
if (fixed_row_size)
{ // Fill with space
if (item->max_length > used_length)
{
if (!space_inited)
{
space_inited=1;
bfill(space,sizeof(space),' ');
}
uint length=item->max_length-used_length;
for (; length > sizeof(space) ; length-=sizeof(space))
{
if (my_b_write(&cache,(uchar*) space,sizeof(space)))
goto err;
}
if (my_b_write(&cache,(uchar*) space,length))
goto err;
}
}
if (res && enclosed)
{
if (my_b_write(&cache, (uchar*) exchange->enclosed->ptr(),
exchange->enclosed->length()))
goto err;
}
if (--items_left)
{
if (my_b_write(&cache, (uchar*) exchange->field_term->ptr(),
field_term_length))
goto err;
}
}
if (my_b_write(&cache,(uchar*) exchange->line_term->ptr(),
exchange->line_term->length()))
goto err;
DBUG_RETURN(0);
err:
DBUG_RETURN(1);
}
/***************************************************************************
** Dump of select to a binary file
***************************************************************************/
int
select_dump::prepare(List<Item> &list __attribute__((unused)),
SELECT_LEX_UNIT *u)
{
unit= u;
return (int) ((file= create_file(thd, path, exchange, &cache)) < 0);
}
int select_dump::send_data(List<Item> &items)
{
List_iterator_fast<Item> li(items);
char buff[MAX_FIELD_WIDTH];
String tmp(buff,sizeof(buff),&my_charset_bin),*res;
tmp.length(0);
Item *item;
DBUG_ENTER("select_dump::send_data");
if (unit->offset_limit_cnt)
{ // using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(0);
}
if (thd->killed == ABORT_QUERY)
DBUG_RETURN(0);
if (row_count++ > 1)
{
my_message(ER_TOO_MANY_ROWS, ER_THD(thd, ER_TOO_MANY_ROWS), MYF(0));
goto err;
}
while ((item=li++))
{
res=item->str_result(&tmp);
if (!res) // If NULL
{
if (my_b_write(&cache,(uchar*) "",1))
goto err;
}
else if (my_b_write(&cache,(uchar*) res->ptr(),res->length()))
{
my_error(ER_ERROR_ON_WRITE, MYF(0), path, my_errno);
goto err;
}
}
DBUG_RETURN(0);
err:
DBUG_RETURN(1);
}
int select_singlerow_subselect::send_data(List<Item> &items)
{
DBUG_ENTER("select_singlerow_subselect::send_data");
Item_singlerow_subselect *it= (Item_singlerow_subselect *)item;
if (it->assigned())
{
my_message(ER_SUBQUERY_NO_1_ROW, ER_THD(thd, ER_SUBQUERY_NO_1_ROW),
MYF(current_thd->lex->ignore ? ME_JUST_WARNING : 0));
DBUG_RETURN(1);
}
if (unit->offset_limit_cnt)
{ // Using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(0);
}
if (thd->killed == ABORT_QUERY)
DBUG_RETURN(0);
List_iterator_fast<Item> li(items);
Item *val_item;
for (uint i= 0; (val_item= li++); i++)
it->store(i, val_item);
it->assigned(1);
DBUG_RETURN(0);
}
void select_max_min_finder_subselect::cleanup()
{
DBUG_ENTER("select_max_min_finder_subselect::cleanup");
cache= 0;
DBUG_VOID_RETURN;
}
int select_max_min_finder_subselect::send_data(List<Item> &items)
{
DBUG_ENTER("select_max_min_finder_subselect::send_data");
Item_maxmin_subselect *it= (Item_maxmin_subselect *)item;
List_iterator_fast<Item> li(items);
Item *val_item= li++;
it->register_value();
if (it->assigned())
{
cache->store(val_item);
if ((this->*op)())
it->store(0, cache);
}
else
{
if (!cache)
{
cache= Item_cache::get_cache(thd, val_item);
switch (val_item->result_type()) {
case REAL_RESULT:
op= &select_max_min_finder_subselect::cmp_real;
break;
case INT_RESULT:
op= &select_max_min_finder_subselect::cmp_int;
break;
case STRING_RESULT:
op= &select_max_min_finder_subselect::cmp_str;
break;
case DECIMAL_RESULT:
op= &select_max_min_finder_subselect::cmp_decimal;
break;
case ROW_RESULT:
case TIME_RESULT:
// This case should never be choosen
DBUG_ASSERT(0);
op= 0;
}
}
cache->store(val_item);
it->store(0, cache);
}
it->assigned(1);
DBUG_RETURN(0);
}
bool select_max_min_finder_subselect::cmp_real()
{
Item *maxmin= ((Item_singlerow_subselect *)item)->element_index(0);
double val1= cache->val_real(), val2= maxmin->val_real();
/* Ignore NULLs for ANY and keep them for ALL subqueries */
if (cache->null_value)
return (is_all && !maxmin->null_value) || (!is_all && maxmin->null_value);
if (maxmin->null_value)
return !is_all;
if (fmax)
return(val1 > val2);
return (val1 < val2);
}
bool select_max_min_finder_subselect::cmp_int()
{
Item *maxmin= ((Item_singlerow_subselect *)item)->element_index(0);
longlong val1= cache->val_int(), val2= maxmin->val_int();
/* Ignore NULLs for ANY and keep them for ALL subqueries */
if (cache->null_value)
return (is_all && !maxmin->null_value) || (!is_all && maxmin->null_value);
if (maxmin->null_value)
return !is_all;
if (fmax)
return(val1 > val2);
return (val1 < val2);
}
bool select_max_min_finder_subselect::cmp_decimal()
{
Item *maxmin= ((Item_singlerow_subselect *)item)->element_index(0);
my_decimal cval, *cvalue= cache->val_decimal(&cval);
my_decimal mval, *mvalue= maxmin->val_decimal(&mval);
/* Ignore NULLs for ANY and keep them for ALL subqueries */
if (cache->null_value)
return (is_all && !maxmin->null_value) || (!is_all && maxmin->null_value);
if (maxmin->null_value)
return !is_all;
if (fmax)
return (my_decimal_cmp(cvalue, mvalue) > 0) ;
return (my_decimal_cmp(cvalue,mvalue) < 0);
}
bool select_max_min_finder_subselect::cmp_str()
{
String *val1, *val2, buf1, buf2;
Item *maxmin= ((Item_singlerow_subselect *)item)->element_index(0);
/*
as far as both operand is Item_cache buf1 & buf2 will not be used,
but added for safety
*/
val1= cache->val_str(&buf1);
val2= maxmin->val_str(&buf1);
/* Ignore NULLs for ANY and keep them for ALL subqueries */
if (cache->null_value)
return (is_all && !maxmin->null_value) || (!is_all && maxmin->null_value);
if (maxmin->null_value)
return !is_all;
if (fmax)
return (sortcmp(val1, val2, cache->collation.collation) > 0) ;
return (sortcmp(val1, val2, cache->collation.collation) < 0);
}
int select_exists_subselect::send_data(List<Item> &items)
{
DBUG_ENTER("select_exists_subselect::send_data");
Item_exists_subselect *it= (Item_exists_subselect *)item;
if (unit->offset_limit_cnt)
{ // Using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(0);
}
if (thd->killed == ABORT_QUERY)
DBUG_RETURN(0);
it->value= 1;
it->assigned(1);
DBUG_RETURN(0);
}
/***************************************************************************
Dump of select to variables
***************************************************************************/
int select_dumpvar::prepare(List<Item> &list, SELECT_LEX_UNIT *u)
{
unit= u;
if (var_list.elements != list.elements)
{
my_message(ER_WRONG_NUMBER_OF_COLUMNS_IN_SELECT,
ER_THD(thd, ER_WRONG_NUMBER_OF_COLUMNS_IN_SELECT), MYF(0));
return 1;
}
return 0;
}
bool select_dumpvar::check_simple_select() const
{
my_error(ER_SP_BAD_CURSOR_SELECT, MYF(0));
return TRUE;
}
void select_dumpvar::cleanup()
{
row_count= 0;
}
Query_arena::Type Query_arena::type() const
{
DBUG_ASSERT(0); /* Should never be called */
return STATEMENT;
}
void Query_arena::free_items()
{
Item *next;
DBUG_ENTER("Query_arena::free_items");
/* This works because items are allocated with sql_alloc() */
for (; free_list; free_list= next)
{
next= free_list->next;
DBUG_ASSERT(free_list != next);
DBUG_PRINT("info", ("free item: 0x%lx", (ulong) free_list));
free_list->delete_self();
}
/* Postcondition: free_list is 0 */
DBUG_VOID_RETURN;
}
void Query_arena::set_query_arena(Query_arena *set)
{
mem_root= set->mem_root;
free_list= set->free_list;
state= set->state;
}
void Query_arena::cleanup_stmt()
{
DBUG_ASSERT(! "Query_arena::cleanup_stmt() not implemented");
}
/*
Statement functions
*/
Statement::Statement(LEX *lex_arg, MEM_ROOT *mem_root_arg,
enum enum_state state_arg, ulong id_arg)
:Query_arena(mem_root_arg, state_arg),
id(id_arg),
mark_used_columns(MARK_COLUMNS_READ),
lex(lex_arg),
db(NULL),
db_length(0)
{
name.str= NULL;
}
Query_arena::Type Statement::type() const
{
return STATEMENT;
}
void Statement::set_statement(Statement *stmt)
{
id= stmt->id;
mark_used_columns= stmt->mark_used_columns;
stmt_lex= lex= stmt->lex;
query_string= stmt->query_string;
}
void
Statement::set_n_backup_statement(Statement *stmt, Statement *backup)
{
DBUG_ENTER("Statement::set_n_backup_statement");
backup->set_statement(this);
set_statement(stmt);
DBUG_VOID_RETURN;
}
void Statement::restore_backup_statement(Statement *stmt, Statement *backup)
{
DBUG_ENTER("Statement::restore_backup_statement");
stmt->set_statement(this);
set_statement(backup);
DBUG_VOID_RETURN;
}
void THD::end_statement()
{
DBUG_ENTER("THD::end_statement");
/* Cleanup SQL processing state to reuse this statement in next query. */
lex_end(lex);
delete lex->result;
lex->result= 0;
/* Note that free_list is freed in cleanup_after_query() */
/*
Don't free mem_root, as mem_root is freed in the end of dispatch_command
(once for any command).
*/
DBUG_VOID_RETURN;
}
/*
Start using arena specified by @set. Current arena data will be saved to
*backup.
*/
void THD::set_n_backup_active_arena(Query_arena *set, Query_arena *backup)
{
DBUG_ENTER("THD::set_n_backup_active_arena");
DBUG_ASSERT(backup->is_backup_arena == FALSE);
backup->set_query_arena(this);
set_query_arena(set);
#ifndef DBUG_OFF
backup->is_backup_arena= TRUE;
#endif
DBUG_VOID_RETURN;
}
/*
Stop using the temporary arena, and start again using the arena that is
specified in *backup.
The temporary arena is returned back into *set.
*/
void THD::restore_active_arena(Query_arena *set, Query_arena *backup)
{
DBUG_ENTER("THD::restore_active_arena");
DBUG_ASSERT(backup->is_backup_arena);
set->set_query_arena(this);
set_query_arena(backup);
#ifndef DBUG_OFF
backup->is_backup_arena= FALSE;
#endif
DBUG_VOID_RETURN;
}
Statement::~Statement()
{
}
C_MODE_START
static uchar *
get_statement_id_as_hash_key(const uchar *record, size_t *key_length,
my_bool not_used __attribute__((unused)))
{
const Statement *statement= (const Statement *) record;
*key_length= sizeof(statement->id);
return (uchar *) &((const Statement *) statement)->id;
}
static void delete_statement_as_hash_key(void *key)
{
delete (Statement *) key;
}
static uchar *get_stmt_name_hash_key(Statement *entry, size_t *length,
my_bool not_used __attribute__((unused)))
{
*length= entry->name.length;
return (uchar*) entry->name.str;
}
C_MODE_END
Statement_map::Statement_map() :
last_found_statement(0)
{
enum
{
START_STMT_HASH_SIZE = 16,
START_NAME_HASH_SIZE = 16
};
my_hash_init(&st_hash, &my_charset_bin, START_STMT_HASH_SIZE, 0, 0,
get_statement_id_as_hash_key,
delete_statement_as_hash_key, MYF(0));
my_hash_init(&names_hash, system_charset_info, START_NAME_HASH_SIZE, 0, 0,
(my_hash_get_key) get_stmt_name_hash_key,
NULL,MYF(0));
}
/*
Insert a new statement to the thread-local statement map.
DESCRIPTION
If there was an old statement with the same name, replace it with the
new one. Otherwise, check if max_prepared_stmt_count is not reached yet,
increase prepared_stmt_count, and insert the new statement. It's okay
to delete an old statement and fail to insert the new one.
POSTCONDITIONS
All named prepared statements are also present in names_hash.
Statement names in names_hash are unique.
The statement is added only if prepared_stmt_count < max_prepard_stmt_count
last_found_statement always points to a valid statement or is 0
RETURN VALUE
0 success
1 error: out of resources or max_prepared_stmt_count limit has been
reached. An error is sent to the client, the statement is deleted.
*/
int Statement_map::insert(THD *thd, Statement *statement)
{
if (my_hash_insert(&st_hash, (uchar*) statement))
{
/*
Delete is needed only in case of an insert failure. In all other
cases hash_delete will also delete the statement.
*/
delete statement;
my_error(ER_OUT_OF_RESOURCES, MYF(0));
goto err_st_hash;
}
if (statement->name.str && my_hash_insert(&names_hash, (uchar*) statement))
{
my_error(ER_OUT_OF_RESOURCES, MYF(0));
goto err_names_hash;
}
mysql_mutex_lock(&LOCK_prepared_stmt_count);
/*
We don't check that prepared_stmt_count is <= max_prepared_stmt_count
because we would like to allow to lower the total limit
of prepared statements below the current count. In that case
no new statements can be added until prepared_stmt_count drops below
the limit.
*/
if (prepared_stmt_count >= max_prepared_stmt_count)
{
mysql_mutex_unlock(&LOCK_prepared_stmt_count);
my_error(ER_MAX_PREPARED_STMT_COUNT_REACHED, MYF(0),
max_prepared_stmt_count);
goto err_max;
}
prepared_stmt_count++;
mysql_mutex_unlock(&LOCK_prepared_stmt_count);
last_found_statement= statement;
return 0;
err_max:
if (statement->name.str)
my_hash_delete(&names_hash, (uchar*) statement);
err_names_hash:
my_hash_delete(&st_hash, (uchar*) statement);
err_st_hash:
return 1;
}
void Statement_map::close_transient_cursors()
{
#ifdef TO_BE_IMPLEMENTED
Statement *stmt;
while ((stmt= transient_cursor_list.head()))
stmt->close_cursor(); /* deletes itself from the list */
#endif
}
void Statement_map::erase(Statement *statement)
{
if (statement == last_found_statement)
last_found_statement= 0;
if (statement->name.str)
my_hash_delete(&names_hash, (uchar *) statement);
my_hash_delete(&st_hash, (uchar *) statement);
mysql_mutex_lock(&LOCK_prepared_stmt_count);
DBUG_ASSERT(prepared_stmt_count > 0);
prepared_stmt_count--;
mysql_mutex_unlock(&LOCK_prepared_stmt_count);
}
void Statement_map::reset()
{
/* Must be first, hash_free will reset st_hash.records */
mysql_mutex_lock(&LOCK_prepared_stmt_count);
DBUG_ASSERT(prepared_stmt_count >= st_hash.records);
prepared_stmt_count-= st_hash.records;
mysql_mutex_unlock(&LOCK_prepared_stmt_count);
my_hash_reset(&names_hash);
my_hash_reset(&st_hash);
last_found_statement= 0;
}
Statement_map::~Statement_map()
{
/* Must go first, hash_free will reset st_hash.records */
mysql_mutex_lock(&LOCK_prepared_stmt_count);
DBUG_ASSERT(prepared_stmt_count >= st_hash.records);
prepared_stmt_count-= st_hash.records;
mysql_mutex_unlock(&LOCK_prepared_stmt_count);
my_hash_free(&names_hash);
my_hash_free(&st_hash);
}
bool my_var_user::set(THD *thd, Item *item)
{
Item_func_set_user_var *suv= new (thd->mem_root) Item_func_set_user_var(thd, name, item);
suv->save_item_result(item);
return suv->fix_fields(thd, 0) || suv->update();
}
bool my_var_sp::set(THD *thd, Item *item)
{
return thd->spcont->set_variable(thd, offset, &item);
}
int select_dumpvar::send_data(List<Item> &items)
{
List_iterator_fast<my_var> var_li(var_list);
List_iterator<Item> it(items);
Item *item;
my_var *mv;
DBUG_ENTER("select_dumpvar::send_data");
if (unit->offset_limit_cnt)
{ // using limit offset,count
unit->offset_limit_cnt--;
DBUG_RETURN(0);
}
if (row_count++)
{
my_message(ER_TOO_MANY_ROWS, ER_THD(thd, ER_TOO_MANY_ROWS), MYF(0));
DBUG_RETURN(1);
}
while ((mv= var_li++) && (item= it++))
{
if (mv->set(thd, item))
DBUG_RETURN(1);
}
DBUG_RETURN(thd->is_error());
}
bool select_dumpvar::send_eof()
{
if (! row_count)
push_warning(thd, Sql_condition::WARN_LEVEL_WARN,
ER_SP_FETCH_NO_DATA, ER_THD(thd, ER_SP_FETCH_NO_DATA));
/*
Don't send EOF if we're in error condition (which implies we've already
sent or are sending an error)
*/
if (thd->is_error())
return true;
if (!suppress_my_ok)
::my_ok(thd,row_count);
return 0;
}
bool
select_materialize_with_stats::
create_result_table(THD *thd_arg, List<Item> *column_types,
bool is_union_distinct, ulonglong options,
const char *table_alias, bool bit_fields_as_long,
bool create_table,
bool keep_row_order)
{
DBUG_ASSERT(table == 0);
tmp_table_param.field_count= column_types->elements;
tmp_table_param.bit_fields_as_long= bit_fields_as_long;
if (! (table= create_tmp_table(thd_arg, &tmp_table_param, *column_types,
(ORDER*) 0, is_union_distinct, 1,
options, HA_POS_ERROR, (char*) table_alias,
!create_table, keep_row_order)))
return TRUE;
col_stat= (Column_statistics*) table->in_use->alloc(table->s->fields *
sizeof(Column_statistics));
if (!col_stat)
return TRUE;
reset();
table->file->extra(HA_EXTRA_WRITE_CACHE);
table->file->extra(HA_EXTRA_IGNORE_DUP_KEY);
return FALSE;
}
void select_materialize_with_stats::reset()
{
memset(col_stat, 0, table->s->fields * sizeof(Column_statistics));
max_nulls_in_row= 0;
count_rows= 0;
}
void select_materialize_with_stats::cleanup()
{
reset();
select_union::cleanup();
}
/**
Override select_union::send_data to analyze each row for NULLs and to
update null_statistics before sending data to the client.
@return TRUE if fatal error when sending data to the client
@return FALSE on success
*/
int select_materialize_with_stats::send_data(List<Item> &items)
{
List_iterator_fast<Item> item_it(items);
Item *cur_item;
Column_statistics *cur_col_stat= col_stat;
uint nulls_in_row= 0;
int res;
if ((res= select_union::send_data(items)))
return res;
if (table->null_catch_flags & REJECT_ROW_DUE_TO_NULL_FIELDS)
{
table->null_catch_flags&= ~REJECT_ROW_DUE_TO_NULL_FIELDS;
return 0;
}
/* Skip duplicate rows. */
if (write_err == HA_ERR_FOUND_DUPP_KEY ||
write_err == HA_ERR_FOUND_DUPP_UNIQUE)
return 0;
++count_rows;
while ((cur_item= item_it++))
{
if (cur_item->is_null_result())
{
++cur_col_stat->null_count;
cur_col_stat->max_null_row= count_rows;
if (!cur_col_stat->min_null_row)
cur_col_stat->min_null_row= count_rows;
++nulls_in_row;
}
++cur_col_stat;
}
if (nulls_in_row > max_nulls_in_row)
max_nulls_in_row= nulls_in_row;
return 0;
}
/****************************************************************************
TMP_TABLE_PARAM
****************************************************************************/
void TMP_TABLE_PARAM::init()
{
DBUG_ENTER("TMP_TABLE_PARAM::init");
DBUG_PRINT("enter", ("this: 0x%lx", (ulong)this));
field_count= sum_func_count= func_count= hidden_field_count= 0;
group_parts= group_length= group_null_parts= 0;
quick_group= 1;
table_charset= 0;
precomputed_group_by= 0;
bit_fields_as_long= 0;
materialized_subquery= 0;
force_not_null_cols= 0;
skip_create_table= 0;
DBUG_VOID_RETURN;
}
void thd_increment_bytes_sent(void *thd, ulong length)
{
/* thd == 0 when close_connection() calls net_send_error() */
if (likely(thd != 0))
{
((THD*) thd)->status_var.bytes_sent+= length;
}
}
my_bool thd_net_is_killed()
{
THD *thd= current_thd;
return thd && thd->killed ? 1 : 0;
}
void thd_increment_bytes_received(void *thd, ulong length)
{
((THD*) thd)->status_var.bytes_received+= length;
}
void thd_increment_net_big_packet_count(void *thd, ulong length)
{
((THD*) thd)->status_var.net_big_packet_count+= length;
}
void THD::set_status_var_init()
{
bzero((char*) &status_var, offsetof(STATUS_VAR,
last_cleared_system_status_var));
}
void Security_context::init()
{
host= user= ip= external_user= 0;
host_or_ip= "connecting host";
priv_user[0]= priv_host[0]= proxy_user[0]= priv_role[0]= '\0';
master_access= 0;
#ifndef NO_EMBEDDED_ACCESS_CHECKS
db_access= NO_ACCESS;
#endif
}
void Security_context::destroy()
{
DBUG_PRINT("info", ("freeing security context"));
// If not pointer to constant
if (host != my_localhost)
{
my_free(host);
host= NULL;
}
if (user != delayed_user)
{
my_free(user);
user= NULL;
}
if (external_user)
{
my_free(external_user);
external_user= NULL;
}
my_free(ip);
ip= NULL;
}
void Security_context::skip_grants()
{
/* privileges for the user are unknown everything is allowed */
host_or_ip= (char *)"";
master_access= ~NO_ACCESS;
*priv_user= *priv_host= '\0';
}
bool Security_context::set_user(char *user_arg)
{
my_free(user);
user= my_strdup(user_arg, MYF(0));
return user == 0;
}
#ifndef NO_EMBEDDED_ACCESS_CHECKS
/**
Initialize this security context from the passed in credentials
and activate it in the current thread.
@param thd
@param definer_user
@param definer_host
@param db
@param[out] backup Save a pointer to the current security context
in the thread. In case of success it points to the
saved old context, otherwise it points to NULL.
During execution of a statement, multiple security contexts may
be needed:
- the security context of the authenticated user, used as the
default security context for all top-level statements
- in case of a view or a stored program, possibly the security
context of the definer of the routine, if the object is
defined with SQL SECURITY DEFINER option.
The currently "active" security context is parameterized in THD
member security_ctx. By default, after a connection is
established, this member points at the "main" security context
- the credentials of the authenticated user.
Later, if we would like to execute some sub-statement or a part
of a statement under credentials of a different user, e.g.
definer of a procedure, we authenticate this user in a local
instance of Security_context by means of this method (and
ultimately by means of acl_getroot), and make the
local instance active in the thread by re-setting
thd->security_ctx pointer.
Note, that the life cycle and memory management of the "main" and
temporary security contexts are different.
For the main security context, the memory for user/host/ip is
allocated on system heap, and the THD class frees this memory in
its destructor. The only case when contents of the main security
context may change during its life time is when someone issued
CHANGE USER command.
Memory management of a "temporary" security context is
responsibility of the module that creates it.
@retval TRUE there is no user with the given credentials. The erro
is reported in the thread.
@retval FALSE success
*/
bool
Security_context::
change_security_context(THD *thd,
LEX_STRING *definer_user,
LEX_STRING *definer_host,
LEX_STRING *db,
Security_context **backup)
{
bool needs_change;
DBUG_ENTER("Security_context::change_security_context");
DBUG_ASSERT(definer_user->str && definer_host->str);
*backup= NULL;
needs_change= (strcmp(definer_user->str, thd->security_ctx->priv_user) ||
my_strcasecmp(system_charset_info, definer_host->str,
thd->security_ctx->priv_host));
if (needs_change)
{
if (acl_getroot(this, definer_user->str, definer_host->str,
definer_host->str, db->str))
{
my_error(ER_NO_SUCH_USER, MYF(0), definer_user->str,
definer_host->str);
DBUG_RETURN(TRUE);
}
*backup= thd->security_ctx;
thd->security_ctx= this;
}
DBUG_RETURN(FALSE);
}
void
Security_context::restore_security_context(THD *thd,
Security_context *backup)
{
if (backup)
thd->security_ctx= backup;
}
#endif
bool Security_context::user_matches(Security_context *them)
{
return ((user != NULL) && (them->user != NULL) &&
!strcmp(user, them->user));
}
/****************************************************************************
Handling of open and locked tables states.
This is used when we want to open/lock (and then close) some tables when
we already have a set of tables open and locked. We use these methods for
access to mysql.proc table to find definitions of stored routines.
****************************************************************************/
void THD::reset_n_backup_open_tables_state(Open_tables_backup *backup)
{
DBUG_ENTER("reset_n_backup_open_tables_state");
backup->set_open_tables_state(this);
backup->mdl_system_tables_svp= mdl_context.mdl_savepoint();
reset_open_tables_state(this);
state_flags|= Open_tables_state::BACKUPS_AVAIL;
DBUG_VOID_RETURN;
}
void THD::restore_backup_open_tables_state(Open_tables_backup *backup)
{
DBUG_ENTER("restore_backup_open_tables_state");
mdl_context.rollback_to_savepoint(backup->mdl_system_tables_svp);
/*
Before we will throw away current open tables state we want
to be sure that it was properly cleaned up.
*/
DBUG_ASSERT(open_tables == 0 && temporary_tables == 0 &&
derived_tables == 0 &&
lock == 0 &&
locked_tables_mode == LTM_NONE &&
m_reprepare_observer == NULL);
set_open_tables_state(backup);
DBUG_VOID_RETURN;
}
#if MARIA_PLUGIN_INTERFACE_VERSION < 0x0200
/**
This is a backward compatibility method, made obsolete
by the thd_kill_statement service. Keep it here to avoid breaking the
ABI in case some binary plugins still use it.
*/
#undef thd_killed
extern "C" int thd_killed(const MYSQL_THD thd)
{
return thd_kill_level(thd) > THD_ABORT_SOFTLY;
}
#else
#error now thd_killed() function can go away
#endif
/*
return thd->killed status to the client,
mapped to the API enum thd_kill_levels values.
@note Since this function is called quite frequently thd_kill_level(NULL) is
forbidden for performance reasons (saves one conditional branch). If your ever
need to call thd_kill_level() when THD is not available, you options are (most
to least preferred):
- try to pass THD through to thd_kill_level()
- add current_thd to some service and use thd_killed(current_thd)
- add thd_killed_current() function to kill statement service
- add if (!thd) thd= current_thd here
*/
extern "C" enum thd_kill_levels thd_kill_level(const MYSQL_THD thd)
{
DBUG_ASSERT(thd);
if (likely(thd->killed == NOT_KILLED))
{
Apc_target *apc_target= (Apc_target*) &thd->apc_target;
if (unlikely(apc_target->have_apc_requests()))
{
if (thd == current_thd)
apc_target->process_apc_requests();
}
return THD_IS_NOT_KILLED;
}
return thd->killed & KILL_HARD_BIT ? THD_ABORT_ASAP : THD_ABORT_SOFTLY;
}
/**
Send an out-of-band progress report to the client
The report is sent every 'thd->...progress_report_time' second,
however not more often than global.progress_report_time.
If global.progress_report_time is 0, then don't send progress reports, but
check every second if the value has changed
We clear any errors that we get from sending the progress packet to
the client as we don't want to set an error without the caller knowing
about it.
*/
static void thd_send_progress(THD *thd)
{
/* Check if we should send the client a progress report */
ulonglong report_time= my_interval_timer();
if (report_time > thd->progress.next_report_time)
{
uint seconds_to_next= MY_MAX(thd->variables.progress_report_time,
global_system_variables.progress_report_time);
if (seconds_to_next == 0) // Turned off
seconds_to_next= 1; // Check again after 1 second
thd->progress.next_report_time= (report_time +
seconds_to_next * 1000000000ULL);
if (global_system_variables.progress_report_time &&
thd->variables.progress_report_time && !thd->is_error())
{
net_send_progress_packet(thd);
if (thd->is_error())
thd->clear_error();
}
}
}
/** Initialize progress report handling **/
extern "C" void thd_progress_init(MYSQL_THD thd, uint max_stage)
{
DBUG_ASSERT(thd->stmt_arena != thd->progress.arena);
if (thd->progress.arena)
return; // already initialized
/*
Send progress reports to clients that supports it, if the command
is a high level command (like ALTER TABLE) and we are not in a
stored procedure
*/
thd->progress.report= ((thd->client_capabilities & CLIENT_PROGRESS) &&
thd->progress.report_to_client &&
!thd->in_sub_stmt);
thd->progress.next_report_time= 0;
thd->progress.stage= 0;
thd->progress.counter= thd->progress.max_counter= 0;
thd->progress.max_stage= max_stage;
thd->progress.arena= thd->stmt_arena;
}
/* Inform processlist and the client that some progress has been made */
extern "C" void thd_progress_report(MYSQL_THD thd,
ulonglong progress, ulonglong max_progress)
{
if (thd->stmt_arena != thd->progress.arena)
return;
if (thd->progress.max_counter != max_progress) // Simple optimization
{
mysql_mutex_lock(&thd->LOCK_thd_data);
thd->progress.counter= progress;
thd->progress.max_counter= max_progress;
mysql_mutex_unlock(&thd->LOCK_thd_data);
}
else
thd->progress.counter= progress;
if (thd->progress.report)
thd_send_progress(thd);
}
/**
Move to next stage in process list handling
This will reset the timer to ensure the progress is sent to the client
if client progress reports are activated.
*/
extern "C" void thd_progress_next_stage(MYSQL_THD thd)
{
if (thd->stmt_arena != thd->progress.arena)
return;
mysql_mutex_lock(&thd->LOCK_thd_data);
thd->progress.stage++;
thd->progress.counter= 0;
DBUG_ASSERT(thd->progress.stage < thd->progress.max_stage);
mysql_mutex_unlock(&thd->LOCK_thd_data);
if (thd->progress.report)
{
thd->progress.next_report_time= 0; // Send new stage info
thd_send_progress(thd);
}
}
/**
Disable reporting of progress in process list.
@note
This function is safe to call even if one has not called thd_progress_init.
This function should be called by all parts that does progress
reporting to ensure that progress list doesn't contain 100 % done
forever.
*/
extern "C" void thd_progress_end(MYSQL_THD thd)
{
if (thd->stmt_arena != thd->progress.arena)
return;
/*
It's enough to reset max_counter to set disable progress indicator
in processlist.
*/
thd->progress.max_counter= 0;
thd->progress.arena= 0;
}
/**
Return the thread id of a user thread
@param thd user thread
@return thread id
*/
extern "C" unsigned long thd_get_thread_id(const MYSQL_THD thd)
{
return((unsigned long)thd->thread_id);
}
/**
Check if THD socket is still connected.
*/
extern "C" int thd_is_connected(MYSQL_THD thd)
{
return thd->is_connected();
}
extern "C" double thd_rnd(MYSQL_THD thd)
{
return my_rnd(&thd->rand);
}
/**
Generate string of printable random characters of requested length.
@param to[out] Buffer for generation; must be at least length+1 bytes
long; result string is always null-terminated
@param length[in] How many random characters to put in buffer
*/
extern "C" void thd_create_random_password(MYSQL_THD thd,
char *to, size_t length)
{
for (char *end= to + length; to < end; to++)
*to= (char) (my_rnd(&thd->rand)*94 + 33);
*to= '\0';
}
#ifdef INNODB_COMPATIBILITY_HOOKS
extern "C" const struct charset_info_st *thd_charset(MYSQL_THD thd)
{
return(thd->charset());
}
/**
OBSOLETE : there's no way to ensure the string is null terminated.
Use thd_query_string instead()
*/
extern "C" char **thd_query(MYSQL_THD thd)
{
return (&thd->query_string.string.str);
}
/**
Get the current query string for the thread.
@param The MySQL internal thread pointer
@return query string and length. May be non-null-terminated.
*/
extern "C" LEX_STRING * thd_query_string (MYSQL_THD thd)
{
return(&thd->query_string.string);
}
extern "C" int thd_slave_thread(const MYSQL_THD thd)
{
return(thd->slave_thread);
}
/* Returns true for a worker thread in parallel replication. */
extern "C" int thd_rpl_is_parallel(const MYSQL_THD thd)
{
return thd->rgi_slave && thd->rgi_slave->is_parallel_exec;
}
/* Returns high resolution timestamp for the start
of the current query. */
extern "C" unsigned long long thd_start_utime(const MYSQL_THD thd)
{
return thd->start_utime;
}
/*
This function can optionally be called to check if thd_report_wait_for()
needs to be called for waits done by a given transaction.
If this function returns false for a given thd, there is no need to do any
calls to thd_report_wait_for() on that thd.
This call is optional; it is safe to call thd_report_wait_for() in any case.
This call can be used to save some redundant calls to thd_report_wait_for()
if desired. (This is unlikely to matter much unless there are _lots_ of
waits to report, as the overhead of thd_report_wait_for() is small).
*/
extern "C" int
thd_need_wait_for(const MYSQL_THD thd)
{
rpl_group_info *rgi;
if (mysql_bin_log.is_open())
return true;
if (!thd)
return false;
rgi= thd->rgi_slave;
if (!rgi)
return false;
return rgi->is_parallel_exec;
}
/*
Used by InnoDB/XtraDB to report that one transaction THD is about to go to
wait for a transactional lock held by another transactions OTHER_THD.
This is used for parallel replication, where transactions are required to
commit in the same order on the slave as they did on the master. If the
transactions on the slave encounters lock conflicts on the slave that did
not exist on the master, this can cause deadlocks.
Normally, such conflicts will not occur, because the same conflict would
have prevented the two transactions from committing in parallel on the
master, thus preventing them from running in parallel on the slave in the
first place. However, it is possible in case when the optimizer chooses a
different plan on the slave than on the master (eg. table scan instead of
index scan).
InnoDB/XtraDB reports lock waits using this call. If a lock wait causes a
deadlock with the pre-determined commit order, we kill the later transaction,
and later re-try it, to resolve the deadlock.
This call need only receive reports about waits for locks that will remain
until the holding transaction commits. InnoDB/XtraDB auto-increment locks
are released earlier, and so need not be reported. (Such false positives are
not harmful, but could lead to unnecessary kill and retry, so best avoided).
*/
extern "C" void
thd_report_wait_for(MYSQL_THD thd, MYSQL_THD other_thd)
{
rpl_group_info *rgi;
rpl_group_info *other_rgi;
if (!thd)
return;
DEBUG_SYNC(thd, "thd_report_wait_for");
thd->transaction.stmt.mark_trans_did_wait();
if (!other_thd)
return;
binlog_report_wait_for(thd, other_thd);
rgi= thd->rgi_slave;
other_rgi= other_thd->rgi_slave;
if (!rgi || !other_rgi)
return;
if (!rgi->is_parallel_exec)
return;
if (rgi->rli != other_rgi->rli)
return;
if (!rgi->gtid_sub_id || !other_rgi->gtid_sub_id)
return;
if (rgi->current_gtid.domain_id != other_rgi->current_gtid.domain_id)
return;
if (rgi->gtid_sub_id > other_rgi->gtid_sub_id)
return;
/*
This transaction is about to wait for another transaction that is required
by replication binlog order to commit after. This would cause a deadlock.
So send a kill to the other transaction, with a temporary error; this will
cause replication to rollback (and later re-try) the other transaction,
releasing the lock for this transaction so replication can proceed.
*/
other_rgi->killed_for_retry= rpl_group_info::RETRY_KILL_KILLED;
mysql_mutex_lock(&other_thd->LOCK_thd_data);
other_thd->awake(KILL_CONNECTION);
mysql_mutex_unlock(&other_thd->LOCK_thd_data);
}
/*
Used by storage engines (currently TokuDB) to report that one transaction
THD is about to go to wait for a transactional lock held by another
transactions OTHER_THD.
This is used for parallel replication, where transactions are required to
commit in the same order on the slave as they did on the master. If the
transactions on the slave encounter lock conflicts on the slave that did not
exist on the master, this can cause deadlocks. This is primarily used in
optimistic (and aggressive) modes.
Normally, such conflicts will not occur in conservative mode, because the
same conflict would have prevented the two transactions from committing in
parallel on the master, thus preventing them from running in parallel on the
slave in the first place. However, it is possible in case when the optimizer
chooses a different plan on the slave than on the master (eg. table scan
instead of index scan).
InnoDB/XtraDB reports lock waits using this call. If a lock wait causes a
deadlock with the pre-determined commit order, we kill the later transaction,
and later re-try it, to resolve the deadlock.
This call need only receive reports about waits for locks that will remain
until the holding transaction commits. InnoDB/XtraDB auto-increment locks,
for example, are released earlier, and so need not be reported. (Such false
positives are not harmful, but could lead to unnecessary kill and retry, so
best avoided).
Returns 1 if the OTHER_THD will be killed to resolve deadlock, 0 if not. The
actual kill will happen later, asynchronously from another thread. The
caller does not need to take any actions on the return value if the
handlerton kill_query method is implemented to abort the to-be-killed
transaction.
*/
extern "C" int
thd_rpl_deadlock_check(MYSQL_THD thd, MYSQL_THD other_thd)
{
rpl_group_info *rgi;
rpl_group_info *other_rgi;
if (!thd)
return 0;
DEBUG_SYNC(thd, "thd_report_wait_for");
thd->transaction.stmt.mark_trans_did_wait();
if (!other_thd)
return 0;
binlog_report_wait_for(thd, other_thd);
rgi= thd->rgi_slave;
other_rgi= other_thd->rgi_slave;
if (!rgi || !other_rgi)
return 0;
if (!rgi->is_parallel_exec)
return 0;
if (rgi->rli != other_rgi->rli)
return 0;
if (!rgi->gtid_sub_id || !other_rgi->gtid_sub_id)
return 0;
if (rgi->current_gtid.domain_id != other_rgi->current_gtid.domain_id)
return 0;
if (rgi->gtid_sub_id > other_rgi->gtid_sub_id)
return 0;
/*
This transaction is about to wait for another transaction that is required
by replication binlog order to commit after. This would cause a deadlock.
So send a kill to the other transaction, with a temporary error; this will
cause replication to rollback (and later re-try) the other transaction,
releasing the lock for this transaction so replication can proceed.
*/
#ifdef HAVE_REPLICATION
slave_background_kill_request(other_thd);
#endif
return 1;
}
/*
This function is called from InnoDB/XtraDB to check if the commit order of
two transactions has already been decided by the upper layer. This happens
in parallel replication, where the commit order is forced to be the same on
the slave as it was originally on the master.
If this function returns false, it means that such commit order will be
enforced. This allows the storage engine to optionally omit gap lock waits
or similar measures that would otherwise be needed to ensure that
transactions would be serialised in a way that would cause a commit order
that is correct for binlogging for statement-based replication.
Since transactions are only run in parallel on the slave if they ran without
lock conflicts on the master, normally no lock conflicts on the slave happen
during parallel replication. However, there are a couple of corner cases
where it can happen, like these secondary-index operations:
T1: INSERT INTO t1 VALUES (7, NULL);
T2: DELETE FROM t1 WHERE b <= 3;
T1: UPDATE t1 SET secondary=NULL WHERE primary=1
T2: DELETE t1 WHERE secondary <= 3
The DELETE takes a gap lock that can block the INSERT/UPDATE, but the row
locks set by INSERT/UPDATE do not block the DELETE. Thus, the execution
order of the transactions determine whether a lock conflict occurs or
not. Thus a lock conflict can occur on the slave where it did not on the
master.
If this function returns true, normal locking should be done as required by
the binlogging and transaction isolation level in effect. But if it returns
false, the correct order will be enforced anyway, and InnoDB/XtraDB can
avoid taking the gap lock, preventing the lock conflict.
Calling this function is just an optimisation to avoid unnecessary
deadlocks. If it was not used, a gap lock would be set that could eventually
cause a deadlock; the deadlock would be caught by thd_report_wait_for() and
the transaction T2 killed and rolled back (and later re-tried).
*/
extern "C" int
thd_need_ordering_with(const MYSQL_THD thd, const MYSQL_THD other_thd)
{
rpl_group_info *rgi, *other_rgi;
DBUG_EXECUTE_IF("disable_thd_need_ordering_with", return 1;);
if (!thd || !other_thd)
return 1;
rgi= thd->rgi_slave;
other_rgi= other_thd->rgi_slave;
if (!rgi || !other_rgi)
return 1;
if (!rgi->is_parallel_exec)
return 1;
if (rgi->rli != other_rgi->rli)
return 1;
if (rgi->current_gtid.domain_id != other_rgi->current_gtid.domain_id)
return 1;
if (!rgi->commit_id || rgi->commit_id != other_rgi->commit_id)
return 1;
DBUG_EXECUTE_IF("thd_need_ordering_with_force", return 1;);
/*
Otherwise, these two threads are doing parallel replication within the same
replication domain. Their commit order is already fixed, so we do not need
gap locks or similar to otherwise enforce ordering (and in fact such locks
could lead to unnecessary deadlocks and transaction retry).
*/
return 0;
}
/*
If the storage engine detects a deadlock, and needs to choose a victim
transaction to roll back, it can call this function to ask the upper
server layer for which of two possible transactions is prefered to be
aborted and rolled back.
In parallel replication, if two transactions are running in parallel and
one is fixed to commit before the other, then the one that commits later
will be prefered as the victim - chosing the early transaction as a victim
will not resolve the deadlock anyway, as the later transaction still needs
to wait for the earlier to commit.
Otherwise, a transaction that uses only transactional tables, and can thus
be safely rolled back, will be prefered as a deadlock victim over a
transaction that also modified non-transactional (eg. MyISAM) tables.
The return value is -1 if the first transaction is prefered as a deadlock
victim, 1 if the second transaction is prefered, or 0 for no preference (in
which case the storage engine can make the choice as it prefers).
*/
extern "C" int
thd_deadlock_victim_preference(const MYSQL_THD thd1, const MYSQL_THD thd2)
{
rpl_group_info *rgi1, *rgi2;
bool nontrans1, nontrans2;
if (!thd1 || !thd2)
return 0;
/*
If the transactions are participating in the same replication domain in
parallel replication, then request to select the one that will commit
later (in the fixed commit order from the master) as the deadlock victim.
*/
rgi1= thd1->rgi_slave;
rgi2= thd2->rgi_slave;
if (rgi1 && rgi2 &&
rgi1->is_parallel_exec &&
rgi1->rli == rgi2->rli &&
rgi1->current_gtid.domain_id == rgi2->current_gtid.domain_id)
return rgi1->gtid_sub_id < rgi2->gtid_sub_id ? 1 : -1;
/*
If one transaction has modified non-transactional tables (so that it
cannot be safely rolled back), and the other has not, then prefer to
select the purely transactional one as the victim.
*/
nontrans1= thd1->transaction.all.modified_non_trans_table;
nontrans2= thd2->transaction.all.modified_non_trans_table;
if (nontrans1 && !nontrans2)
return 1;
else if (!nontrans1 && nontrans2)
return -1;
/* No preferences, let the storage engine decide. */
return 0;
}
extern "C" int thd_non_transactional_update(const MYSQL_THD thd)
{
return(thd->transaction.all.modified_non_trans_table);
}
extern "C" int thd_binlog_format(const MYSQL_THD thd)
{
if (WSREP(thd))
{
/* for wsrep binlog format is meaningful also when binlogging is off */
return (int) thd->wsrep_binlog_format();
}
if (mysql_bin_log.is_open() && (thd->variables.option_bits & OPTION_BIN_LOG))
return (int) thd->variables.binlog_format;
return BINLOG_FORMAT_UNSPEC;
}
extern "C" void thd_mark_transaction_to_rollback(MYSQL_THD thd, bool all)
{
DBUG_ASSERT(thd);
thd->mark_transaction_to_rollback(all);
}
extern "C" bool thd_binlog_filter_ok(const MYSQL_THD thd)
{
return binlog_filter->db_ok(thd->db);
}
/*
This is similar to sqlcom_can_generate_row_events, with the expection
that we only return 1 if we are going to generate row events in a
transaction.
CREATE OR REPLACE is always safe to do as this will run in it's own
transaction.
*/
extern "C" bool thd_sqlcom_can_generate_row_events(const MYSQL_THD thd)
{
return (sqlcom_can_generate_row_events(thd) && thd->lex->sql_command !=
SQLCOM_CREATE_TABLE);
}
extern "C" enum durability_properties thd_get_durability_property(const MYSQL_THD thd)
{
enum durability_properties ret= HA_REGULAR_DURABILITY;
if (thd != NULL)
ret= thd->durability_property;
return ret;
}
/** Get the auto_increment_offset auto_increment_increment.
Exposed by thd_autoinc_service.
Needed by InnoDB.
@param thd Thread object
@param off auto_increment_offset
@param inc auto_increment_increment */
extern "C" void thd_get_autoinc(const MYSQL_THD thd, ulong* off, ulong* inc)
{
*off = thd->variables.auto_increment_offset;
*inc = thd->variables.auto_increment_increment;
}
/**
Is strict sql_mode set.
Needed by InnoDB.
@param thd Thread object
@return True if sql_mode has strict mode (all or trans).
@retval true sql_mode has strict mode (all or trans).
@retval false sql_mode has not strict mode (all or trans).
*/
extern "C" bool thd_is_strict_mode(const MYSQL_THD thd)
{
return thd->is_strict_mode();
}
/*
Interface for MySQL Server, plugins and storage engines to report
when they are going to sleep/stall.
SYNOPSIS
thd_wait_begin()
thd Thread object
Can be NULL, in this case current THD is used.
wait_type Type of wait
1 -- short wait (e.g. for mutex)
2 -- medium wait (e.g. for disk io)
3 -- large wait (e.g. for locked row/table)
NOTES
This is used by the threadpool to have better knowledge of which
threads that currently are actively running on CPUs. When a thread
reports that it's going to sleep/stall, the threadpool scheduler is
free to start another thread in the pool most likely. The expected wait
time is simply an indication of how long the wait is expected to
become, the real wait time could be very different.
thd_wait_end MUST be called immediately after waking up again.
*/
extern "C" void thd_wait_begin(MYSQL_THD thd, int wait_type)
{
if (!thd)
{
thd= current_thd;
if (unlikely(!thd))
return;
}
MYSQL_CALLBACK(thd->scheduler, thd_wait_begin, (thd, wait_type));
}
/**
Interface for MySQL Server, plugins and storage engines to report
when they waking up from a sleep/stall.
@param thd Thread handle
Can be NULL, in this case current THD is used.
*/
extern "C" void thd_wait_end(MYSQL_THD thd)
{
if (!thd)
{
thd= current_thd;
if (unlikely(!thd))
return;
}
MYSQL_CALLBACK(thd->scheduler, thd_wait_end, (thd));
}
#endif // INNODB_COMPATIBILITY_HOOKS */
/****************************************************************************
Handling of statement states in functions and triggers.
This is used to ensure that the function/trigger gets a clean state
to work with and does not cause any side effects of the calling statement.
It also allows most stored functions and triggers to replicate even
if they are used items that would normally be stored in the binary
replication (like last_insert_id() etc...)
The following things is done
- Disable binary logging for the duration of the statement
- Disable multi-result-sets for the duration of the statement
- Value of last_insert_id() is saved and restored
- Value set by 'SET INSERT_ID=#' is reset and restored
- Value for found_rows() is reset and restored
- examined_row_count is added to the total
- cuted_fields is added to the total
- new savepoint level is created and destroyed
NOTES:
Seed for random() is saved for the first! usage of RAND()
We reset examined_row_count and cuted_fields and add these to the
result to ensure that if we have a bug that would reset these within
a function, we are not loosing any rows from the main statement.
We do not reset value of last_insert_id().
****************************************************************************/
void THD::reset_sub_statement_state(Sub_statement_state *backup,
uint new_state)
{
#ifndef EMBEDDED_LIBRARY
/* BUG#33029, if we are replicating from a buggy master, reset
auto_inc_intervals_forced to prevent substatement
(triggers/functions) from using erroneous INSERT_ID value
*/
if (rpl_master_erroneous_autoinc(this))
{
DBUG_ASSERT(backup->auto_inc_intervals_forced.nb_elements() == 0);
auto_inc_intervals_forced.swap(&backup->auto_inc_intervals_forced);
}
#endif
backup->option_bits= variables.option_bits;
backup->count_cuted_fields= count_cuted_fields;
backup->in_sub_stmt= in_sub_stmt;
backup->enable_slow_log= enable_slow_log;
backup->query_plan_flags= query_plan_flags;
backup->limit_found_rows= limit_found_rows;
backup->examined_row_count= m_examined_row_count;
backup->sent_row_count= m_sent_row_count;
backup->cuted_fields= cuted_fields;
backup->client_capabilities= client_capabilities;
backup->savepoints= transaction.savepoints;
backup->first_successful_insert_id_in_prev_stmt=
first_successful_insert_id_in_prev_stmt;
backup->first_successful_insert_id_in_cur_stmt=
first_successful_insert_id_in_cur_stmt;
if ((!lex->requires_prelocking() || is_update_query(lex->sql_command)) &&
!is_current_stmt_binlog_format_row())
{
variables.option_bits&= ~OPTION_BIN_LOG;
}
if ((backup->option_bits & OPTION_BIN_LOG) &&
is_update_query(lex->sql_command) &&
!is_current_stmt_binlog_format_row())
mysql_bin_log.start_union_events(this, this->query_id);
/* Disable result sets */
client_capabilities &= ~CLIENT_MULTI_RESULTS;
in_sub_stmt|= new_state;
m_examined_row_count= 0;
m_sent_row_count= 0;
cuted_fields= 0;
transaction.savepoints= 0;
first_successful_insert_id_in_cur_stmt= 0;
}
void THD::restore_sub_statement_state(Sub_statement_state *backup)
{
DBUG_ENTER("THD::restore_sub_statement_state");
#ifndef EMBEDDED_LIBRARY
/* BUG#33029, if we are replicating from a buggy master, restore
auto_inc_intervals_forced so that the top statement can use the
INSERT_ID value set before this statement.
*/
if (rpl_master_erroneous_autoinc(this))
{
backup->auto_inc_intervals_forced.swap(&auto_inc_intervals_forced);
DBUG_ASSERT(backup->auto_inc_intervals_forced.nb_elements() == 0);
}
#endif
/*
To save resources we want to release savepoints which were created
during execution of function or trigger before leaving their savepoint
level. It is enough to release first savepoint set on this level since
all later savepoints will be released automatically.
*/
if (transaction.savepoints)
{
SAVEPOINT *sv;
for (sv= transaction.savepoints; sv->prev; sv= sv->prev)
{}
/* ha_release_savepoint() never returns error. */
(void)ha_release_savepoint(this, sv);
}
count_cuted_fields= backup->count_cuted_fields;
transaction.savepoints= backup->savepoints;
variables.option_bits= backup->option_bits;
in_sub_stmt= backup->in_sub_stmt;
enable_slow_log= backup->enable_slow_log;
query_plan_flags= backup->query_plan_flags;
first_successful_insert_id_in_prev_stmt=
backup->first_successful_insert_id_in_prev_stmt;
first_successful_insert_id_in_cur_stmt=
backup->first_successful_insert_id_in_cur_stmt;
limit_found_rows= backup->limit_found_rows;
set_sent_row_count(backup->sent_row_count);
client_capabilities= backup->client_capabilities;
/*
If we've left sub-statement mode, reset the fatal error flag.
Otherwise keep the current value, to propagate it up the sub-statement
stack.
NOTE: is_fatal_sub_stmt_error can be set only if we've been in the
sub-statement mode.
*/
if (!in_sub_stmt)
is_fatal_sub_stmt_error= false;
if ((variables.option_bits & OPTION_BIN_LOG) && is_update_query(lex->sql_command) &&
!is_current_stmt_binlog_format_row())
mysql_bin_log.stop_union_events(this);
/*
The following is added to the old values as we are interested in the
total complexity of the query
*/
inc_examined_row_count(backup->examined_row_count);
cuted_fields+= backup->cuted_fields;
DBUG_VOID_RETURN;
}
void THD::set_statement(Statement *stmt)
{
mysql_mutex_lock(&LOCK_thd_data);
Statement::set_statement(stmt);
mysql_mutex_unlock(&LOCK_thd_data);
}
void THD::set_sent_row_count(ha_rows count)
{
m_sent_row_count= count;
MYSQL_SET_STATEMENT_ROWS_SENT(m_statement_psi, m_sent_row_count);
}
void THD::set_examined_row_count(ha_rows count)
{
m_examined_row_count= count;
MYSQL_SET_STATEMENT_ROWS_EXAMINED(m_statement_psi, m_examined_row_count);
}
void THD::inc_sent_row_count(ha_rows count)
{
m_sent_row_count+= count;
MYSQL_SET_STATEMENT_ROWS_SENT(m_statement_psi, m_sent_row_count);
}
void THD::inc_examined_row_count(ha_rows count)
{
m_examined_row_count+= count;
MYSQL_SET_STATEMENT_ROWS_EXAMINED(m_statement_psi, m_examined_row_count);
}
void THD::inc_status_created_tmp_disk_tables()
{
status_var_increment(status_var.created_tmp_disk_tables_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_created_tmp_disk_tables)(m_statement_psi, 1);
#endif
}
void THD::inc_status_created_tmp_tables()
{
status_var_increment(status_var.created_tmp_tables_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_created_tmp_tables)(m_statement_psi, 1);
#endif
}
void THD::inc_status_select_full_join()
{
status_var_increment(status_var.select_full_join_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_select_full_join)(m_statement_psi, 1);
#endif
}
void THD::inc_status_select_full_range_join()
{
status_var_increment(status_var.select_full_range_join_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_select_full_range_join)(m_statement_psi, 1);
#endif
}
void THD::inc_status_select_range()
{
status_var_increment(status_var.select_range_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_select_range)(m_statement_psi, 1);
#endif
}
void THD::inc_status_select_range_check()
{
status_var_increment(status_var.select_range_check_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_select_range_check)(m_statement_psi, 1);
#endif
}
void THD::inc_status_select_scan()
{
status_var_increment(status_var.select_scan_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_select_scan)(m_statement_psi, 1);
#endif
}
void THD::inc_status_sort_merge_passes()
{
status_var_increment(status_var.filesort_merge_passes_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_sort_merge_passes)(m_statement_psi, 1);
#endif
}
void THD::inc_status_sort_range()
{
status_var_increment(status_var.filesort_range_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_sort_range)(m_statement_psi, 1);
#endif
}
void THD::inc_status_sort_rows(ha_rows count)
{
statistic_add(status_var.filesort_rows_, count, &LOCK_status);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_sort_rows)(m_statement_psi, count);
#endif
}
void THD::inc_status_sort_scan()
{
status_var_increment(status_var.filesort_scan_count_);
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(inc_statement_sort_scan)(m_statement_psi, 1);
#endif
}
void THD::set_status_no_index_used()
{
server_status|= SERVER_QUERY_NO_INDEX_USED;
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(set_statement_no_index_used)(m_statement_psi);
#endif
}
void THD::set_status_no_good_index_used()
{
server_status|= SERVER_QUERY_NO_GOOD_INDEX_USED;
#ifdef HAVE_PSI_STATEMENT_INTERFACE
PSI_STATEMENT_CALL(set_statement_no_good_index_used)(m_statement_psi);
#endif
}
/** Assign a new value to thd->query and thd->query_id. */
void THD::set_query_and_id(char *query_arg, uint32 query_length_arg,
CHARSET_INFO *cs,
query_id_t new_query_id)
{
mysql_mutex_lock(&LOCK_thd_data);
set_query_inner(query_arg, query_length_arg, cs);
mysql_mutex_unlock(&LOCK_thd_data);
query_id= new_query_id;
}
/** Assign a new value to thd->mysys_var. */
void THD::set_mysys_var(struct st_my_thread_var *new_mysys_var)
{
mysql_mutex_lock(&LOCK_thd_data);
mysys_var= new_mysys_var;
mysql_mutex_unlock(&LOCK_thd_data);
}
/**
Leave explicit LOCK TABLES or prelocked mode and restore value of
transaction sentinel in MDL subsystem.
*/
void THD::leave_locked_tables_mode()
{
if (locked_tables_mode == LTM_LOCK_TABLES)
{
/*
When leaving LOCK TABLES mode we have to change the duration of most
of the metadata locks being held, except for HANDLER and GRL locks,
to transactional for them to be properly released at UNLOCK TABLES.
*/
mdl_context.set_transaction_duration_for_all_locks();
/*
Make sure we don't release the global read lock and commit blocker
when leaving LTM.
*/
global_read_lock.set_explicit_lock_duration(this);
/* Also ensure that we don't release metadata locks for open HANDLERs. */
if (handler_tables_hash.records)
mysql_ha_set_explicit_lock_duration(this);
if (ull_hash.records)
mysql_ull_set_explicit_lock_duration(this);
}
locked_tables_mode= LTM_NONE;
}
void THD::get_definer(LEX_USER *definer, bool role)
{
binlog_invoker(role);
#if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION)
#ifdef WITH_WSREP
if ((wsrep_applier || slave_thread) && has_invoker())
#else
if (slave_thread && has_invoker())
#endif
{
definer->user = invoker_user;
definer->host= invoker_host;
definer->reset_auth();
}
else
#endif
get_default_definer(this, definer, role);
}
/**
Mark transaction to rollback and mark error as fatal to a sub-statement.
@param all TRUE <=> rollback main transaction.
*/
void THD::mark_transaction_to_rollback(bool all)
{
/*
There is no point in setting is_fatal_sub_stmt_error unless
we are actually in_sub_stmt.
*/
if (in_sub_stmt)
is_fatal_sub_stmt_error= true;
transaction_rollback_request= all;
}
/***************************************************************************
Handling of XA id cacheing
***************************************************************************/
class XID_cache_element
{
/*
m_state is used to prevent elements from being deleted while XA RECOVER
iterates xid cache and to prevent recovered elments from being acquired by
multiple threads.
bits 1..29 are reference counter
bit 30 is RECOVERED flag
bit 31 is ACQUIRED flag (thread owns this xid)
bit 32 is unused
Newly allocated and deleted elements have m_state set to 0.
On lock() m_state is atomically incremented. It also creates load-ACQUIRE
memory barrier to make sure m_state is actually updated before furhter
memory accesses. Attempting to lock an element that has neither ACQUIRED
nor RECOVERED flag set returns failure and further accesses to element
memory are forbidden.
On unlock() m_state is decremented. It also creates store-RELEASE memory
barrier to make sure m_state is actually updated after preceding memory
accesses.
ACQUIRED flag is set when thread registers it's xid or when thread acquires
recovered xid.
RECOVERED flag is set for elements found during crash recovery.
ACQUIRED and RECOVERED flags are cleared before element is deleted from
hash in a spin loop, after last reference is released.
*/
int32 m_state;
public:
static const int32 ACQUIRED= 1 << 30;
static const int32 RECOVERED= 1 << 29;
XID_STATE *m_xid_state;
bool is_set(int32 flag)
{ return my_atomic_load32_explicit(&m_state, MY_MEMORY_ORDER_RELAXED) & flag; }
void set(int32 flag)
{
DBUG_ASSERT(!is_set(ACQUIRED | RECOVERED));
my_atomic_add32_explicit(&m_state, flag, MY_MEMORY_ORDER_RELAXED);
}
bool lock()
{
int32 old= my_atomic_add32_explicit(&m_state, 1, MY_MEMORY_ORDER_ACQUIRE);
if (old & (ACQUIRED | RECOVERED))
return true;
unlock();
return false;
}
void unlock()
{ my_atomic_add32_explicit(&m_state, -1, MY_MEMORY_ORDER_RELEASE); }
void mark_uninitialized()
{
int32 old= ACQUIRED;
while (!my_atomic_cas32_weak_explicit(&m_state, &old, 0,
MY_MEMORY_ORDER_RELAXED,
MY_MEMORY_ORDER_RELAXED))
{
old&= ACQUIRED | RECOVERED;
(void) LF_BACKOFF;
}
}
bool acquire_recovered()
{
int32 old= RECOVERED;
while (!my_atomic_cas32_weak_explicit(&m_state, &old, ACQUIRED | RECOVERED,
MY_MEMORY_ORDER_RELAXED,
MY_MEMORY_ORDER_RELAXED))
{
if (!(old & RECOVERED) || (old & ACQUIRED))
return false;
old= RECOVERED;
(void) LF_BACKOFF;
}
return true;
}
static void lf_hash_initializer(LF_HASH *hash __attribute__((unused)),
XID_cache_element *element,
XID_STATE *xid_state)
{
DBUG_ASSERT(!element->is_set(ACQUIRED | RECOVERED));
element->m_xid_state= xid_state;
xid_state->xid_cache_element= element;
}
static void lf_alloc_constructor(uchar *ptr)
{
XID_cache_element *element= (XID_cache_element*) (ptr + LF_HASH_OVERHEAD);
element->m_state= 0;
}
static void lf_alloc_destructor(uchar *ptr)
{
XID_cache_element *element= (XID_cache_element*) (ptr + LF_HASH_OVERHEAD);
DBUG_ASSERT(!element->is_set(ACQUIRED));
if (element->is_set(RECOVERED))
my_free(element->m_xid_state);
}
static uchar *key(const XID_cache_element *element, size_t *length,
my_bool not_used __attribute__((unused)))
{
*length= element->m_xid_state->xid.key_length();
return element->m_xid_state->xid.key();
}
};
static LF_HASH xid_cache;
static bool xid_cache_inited;
bool THD::fix_xid_hash_pins()
{
if (!xid_hash_pins)
xid_hash_pins= lf_hash_get_pins(&xid_cache);
return !xid_hash_pins;
}
void xid_cache_init()
{
xid_cache_inited= true;
lf_hash_init(&xid_cache, sizeof(XID_cache_element), LF_HASH_UNIQUE, 0, 0,
(my_hash_get_key) XID_cache_element::key, &my_charset_bin);
xid_cache.alloc.constructor= XID_cache_element::lf_alloc_constructor;
xid_cache.alloc.destructor= XID_cache_element::lf_alloc_destructor;
xid_cache.initializer=
(lf_hash_initializer) XID_cache_element::lf_hash_initializer;
}
void xid_cache_free()
{
if (xid_cache_inited)
{
lf_hash_destroy(&xid_cache);
xid_cache_inited= false;
}
}
/**
Find recovered XA transaction by XID.
*/
XID_STATE *xid_cache_search(THD *thd, XID *xid)
{
XID_STATE *xs= 0;
DBUG_ASSERT(thd->xid_hash_pins);
XID_cache_element *element=
(XID_cache_element*) lf_hash_search(&xid_cache, thd->xid_hash_pins,
xid->key(), xid->key_length());
if (element)
{
if (element->acquire_recovered())
xs= element->m_xid_state;
lf_hash_search_unpin(thd->xid_hash_pins);
DEBUG_SYNC(thd, "xa_after_search");
}
return xs;
}
bool xid_cache_insert(XID *xid, enum xa_states xa_state)
{
XID_STATE *xs;
LF_PINS *pins;
int res= 1;
if (!(pins= lf_hash_get_pins(&xid_cache)))
return true;
if ((xs= (XID_STATE*) my_malloc(sizeof(*xs), MYF(MY_WME))))
{
xs->xa_state=xa_state;
xs->xid.set(xid);
xs->rm_error=0;
if ((res= lf_hash_insert(&xid_cache, pins, xs)))
my_free(xs);
else
xs->xid_cache_element->set(XID_cache_element::RECOVERED);
if (res == 1)
res= 0;
}
lf_hash_put_pins(pins);
return res;
}
bool xid_cache_insert(THD *thd, XID_STATE *xid_state)
{
if (thd->fix_xid_hash_pins())
return true;
int res= lf_hash_insert(&xid_cache, thd->xid_hash_pins, xid_state);
switch (res)
{
case 0:
xid_state->xid_cache_element->set(XID_cache_element::ACQUIRED);
break;
case 1:
my_error(ER_XAER_DUPID, MYF(0));
/* fall through */
default:
xid_state->xid_cache_element= 0;
}
return res;
}
void xid_cache_delete(THD *thd, XID_STATE *xid_state)
{
if (xid_state->xid_cache_element)
{
bool recovered= xid_state->xid_cache_element->is_set(XID_cache_element::RECOVERED);
DBUG_ASSERT(thd->xid_hash_pins);
xid_state->xid_cache_element->mark_uninitialized();
lf_hash_delete(&xid_cache, thd->xid_hash_pins,
xid_state->xid.key(), xid_state->xid.key_length());
xid_state->xid_cache_element= 0;
if (recovered)
my_free(xid_state);
}
}
struct xid_cache_iterate_arg
{
my_hash_walk_action action;
void *argument;
};
static my_bool xid_cache_iterate_callback(XID_cache_element *element,
xid_cache_iterate_arg *arg)
{
my_bool res= FALSE;
if (element->lock())
{
res= arg->action(element->m_xid_state, arg->argument);
element->unlock();
}
return res;
}
int xid_cache_iterate(THD *thd, my_hash_walk_action action, void *arg)
{
xid_cache_iterate_arg argument= { action, arg };
return thd->fix_xid_hash_pins() ? -1 :
lf_hash_iterate(&xid_cache, thd->xid_hash_pins,
(my_hash_walk_action) xid_cache_iterate_callback,
&argument);
}
/*
Tells if two (or more) tables have auto_increment columns and we want to
lock those tables with a write lock.
SYNOPSIS
has_two_write_locked_tables_with_auto_increment
tables Table list
NOTES:
Call this function only when you have established the list of all tables
which you'll want to update (including stored functions, triggers, views
inside your statement).
*/
static bool
has_write_table_with_auto_increment(TABLE_LIST *tables)
{
for (TABLE_LIST *table= tables; table; table= table->next_global)
{
/* we must do preliminary checks as table->table may be NULL */
if (!table->placeholder() &&
table->table->found_next_number_field &&
(table->lock_type >= TL_WRITE_ALLOW_WRITE))
return 1;
}
return 0;
}
/*
checks if we have select tables in the table list and write tables
with auto-increment column.
SYNOPSIS
has_two_write_locked_tables_with_auto_increment_and_select
tables Table list
RETURN VALUES
-true if the table list has atleast one table with auto-increment column
and atleast one table to select from.
-false otherwise
*/
static bool
has_write_table_with_auto_increment_and_select(TABLE_LIST *tables)
{
bool has_select= false;
bool has_auto_increment_tables = has_write_table_with_auto_increment(tables);
for(TABLE_LIST *table= tables; table; table= table->next_global)
{
if (!table->placeholder() &&
(table->lock_type <= TL_READ_NO_INSERT))
{
has_select= true;
break;
}
}
return(has_select && has_auto_increment_tables);
}
/*
Tells if there is a table whose auto_increment column is a part
of a compound primary key while is not the first column in
the table definition.
@param tables Table list
@return true if the table exists, fais if does not.
*/
static bool
has_write_table_auto_increment_not_first_in_pk(TABLE_LIST *tables)
{
for (TABLE_LIST *table= tables; table; table= table->next_global)
{
/* we must do preliminary checks as table->table may be NULL */
if (!table->placeholder() &&
table->table->found_next_number_field &&
(table->lock_type >= TL_WRITE_ALLOW_WRITE)
&& table->table->s->next_number_keypart != 0)
return 1;
}
return 0;
}
/**
Decide on logging format to use for the statement and issue errors
or warnings as needed. The decision depends on the following
parameters:
- The logging mode, i.e., the value of binlog_format. Can be
statement, mixed, or row.
- The type of statement. There are three types of statements:
"normal" safe statements; unsafe statements; and row injections.
An unsafe statement is one that, if logged in statement format,
might produce different results when replayed on the slave (e.g.,
INSERT DELAYED). A row injection is either a BINLOG statement, or
a row event executed by the slave's SQL thread.
- The capabilities of tables modified by the statement. The
*capabilities vector* for a table is a set of flags associated
with the table. Currently, it only includes two flags: *row
capability flag* and *statement capability flag*.
The row capability flag is set if and only if the engine can
handle row-based logging. The statement capability flag is set if
and only if the table can handle statement-based logging.
Decision table for logging format
---------------------------------
The following table summarizes how the format and generated
warning/error depends on the tables' capabilities, the statement
type, and the current binlog_format.
Row capable N NNNNNNNNN YYYYYYYYY YYYYYYYYY
Statement capable N YYYYYYYYY NNNNNNNNN YYYYYYYYY
Statement type * SSSUUUIII SSSUUUIII SSSUUUIII
binlog_format * SMRSMRSMR SMRSMRSMR SMRSMRSMR
Logged format - SS-S----- -RR-RR-RR SRRSRR-RR
Warning/Error 1 --2732444 5--5--6-- ---7--6--
Legend
------
Row capable: N - Some table not row-capable, Y - All tables row-capable
Stmt capable: N - Some table not stmt-capable, Y - All tables stmt-capable
Statement type: (S)afe, (U)nsafe, or Row (I)njection
binlog_format: (S)TATEMENT, (M)IXED, or (R)OW
Logged format: (S)tatement or (R)ow
Warning/Error: Warnings and error messages are as follows:
1. Error: Cannot execute statement: binlogging impossible since both
row-incapable engines and statement-incapable engines are
involved.
2. Error: Cannot execute statement: binlogging impossible since
BINLOG_FORMAT = ROW and at least one table uses a storage engine
limited to statement-logging.
3. Error: Cannot execute statement: binlogging of unsafe statement
is impossible when storage engine is limited to statement-logging
and BINLOG_FORMAT = MIXED.
4. Error: Cannot execute row injection: binlogging impossible since
at least one table uses a storage engine limited to
statement-logging.
5. Error: Cannot execute statement: binlogging impossible since
BINLOG_FORMAT = STATEMENT and at least one table uses a storage
engine limited to row-logging.
6. Warning: Unsafe statement binlogged in statement format since
BINLOG_FORMAT = STATEMENT.
In addition, we can produce the following error (not depending on
the variables of the decision diagram):
7. Error: Cannot execute statement: binlogging impossible since more
than one engine is involved and at least one engine is
self-logging.
For each error case above, the statement is prevented from being
logged, we report an error, and roll back the statement. For
warnings, we set the thd->binlog_flags variable: the warning will be
printed only if the statement is successfully logged.
@see THD::binlog_query
@param[in] thd Client thread
@param[in] tables Tables involved in the query
@retval 0 No error; statement can be logged.
@retval -1 One of the error conditions above applies (1, 2, 4, 5, or 6).
*/
int THD::decide_logging_format(TABLE_LIST *tables)
{
DBUG_ENTER("THD::decide_logging_format");
DBUG_PRINT("info", ("Query: %s", query()));
DBUG_PRINT("info", ("variables.binlog_format: %lu",
variables.binlog_format));
DBUG_PRINT("info", ("lex->get_stmt_unsafe_flags(): 0x%x",
lex->get_stmt_unsafe_flags()));
reset_binlog_local_stmt_filter();
/*
We should not decide logging format if the binlog is closed or
binlogging is off, or if the statement is filtered out from the
binlog by filtering rules.
*/
if (mysql_bin_log.is_open() && (variables.option_bits & OPTION_BIN_LOG) &&
!(wsrep_binlog_format() == BINLOG_FORMAT_STMT &&
!binlog_filter->db_ok(db)))
{
/*
Compute one bit field with the union of all the engine
capabilities, and one with the intersection of all the engine
capabilities.
*/
handler::Table_flags flags_write_some_set= 0;
handler::Table_flags flags_access_some_set= 0;
handler::Table_flags flags_write_all_set=
HA_BINLOG_ROW_CAPABLE | HA_BINLOG_STMT_CAPABLE;
/*
If different types of engines are about to be updated.
For example: Innodb and Falcon; Innodb and MyIsam.
*/
my_bool multi_write_engine= FALSE;
/*
If different types of engines are about to be accessed
and any of them is about to be updated. For example:
Innodb and Falcon; Innodb and MyIsam.
*/
my_bool multi_access_engine= FALSE;
/*
Identifies if a table is changed.
*/
my_bool is_write= FALSE;
/*
A pointer to a previous table that was changed.
*/
TABLE* prev_write_table= NULL;
/*
A pointer to a previous table that was accessed.
*/
TABLE* prev_access_table= NULL;
/**
The number of tables used in the current statement,
that should be replicated.
*/
uint replicated_tables_count= 0;
/**
The number of tables written to in the current statement,
that should not be replicated.
A table should not be replicated when it is considered
'local' to a MySQL instance.
Currently, these tables are:
- mysql.slow_log
- mysql.general_log
- mysql.slave_relay_log_info
- mysql.slave_master_info
- mysql.slave_worker_info
- performance_schema.*
- TODO: information_schema.*
In practice, from this list, only performance_schema.* tables
are written to by user queries.
*/
uint non_replicated_tables_count= 0;
#ifndef DBUG_OFF
{
static const char *prelocked_mode_name[] = {
"NON_PRELOCKED",
"LOCK_TABLES",
"PRELOCKED",
"PRELOCKED_UNDER_LOCK_TABLES",
};
compile_time_assert(array_elements(prelocked_mode_name) == LTM_always_last);
DBUG_PRINT("debug", ("prelocked_mode: %s",
prelocked_mode_name[locked_tables_mode]));
}
#endif
if (wsrep_binlog_format() != BINLOG_FORMAT_ROW && tables)
{
/*
DML statements that modify a table with an auto_increment column based on
rows selected from a table are unsafe as the order in which the rows are
fetched fron the select tables cannot be determined and may differ on
master and slave.
*/
if (has_write_table_with_auto_increment_and_select(tables))
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_WRITE_AUTOINC_SELECT);
if (has_write_table_auto_increment_not_first_in_pk(tables))
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_AUTOINC_NOT_FIRST);
/*
A query that modifies autoinc column in sub-statement can make the
master and slave inconsistent.
We can solve these problems in mixed mode by switching to binlogging
if at least one updated table is used by sub-statement
*/
if (lex->requires_prelocking() &&
has_write_table_with_auto_increment(lex->first_not_own_table()))
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_AUTOINC_COLUMNS);
}
/*
Get the capabilities vector for all involved storage engines and
mask out the flags for the binary log.
*/
for (TABLE_LIST *table= tables; table; table= table->next_global)
{
if (table->placeholder())
continue;
handler::Table_flags const flags= table->table->file->ha_table_flags();
DBUG_PRINT("info", ("table: %s; ha_table_flags: 0x%llx",
table->table_name, flags));
if (table->table->no_replicate)
{
/*
The statement uses a table that is not replicated.
The following properties about the table:
- persistent / transient
- transactional / non transactional
- temporary / permanent
- read or write
- multiple engines involved because of this table
are not relevant, as this table is completely ignored.
Because the statement uses a non replicated table,
using STATEMENT format in the binlog is impossible.
Either this statement will be discarded entirely,
or it will be logged (possibly partially) in ROW format.
*/
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_SYSTEM_TABLE);
if (table->lock_type >= TL_WRITE_ALLOW_WRITE)
{
non_replicated_tables_count++;
continue;
}
}
replicated_tables_count++;
if (table->lock_type >= TL_WRITE_ALLOW_WRITE)
{
if (prev_write_table && prev_write_table->file->ht !=
table->table->file->ht)
multi_write_engine= TRUE;
my_bool trans= table->table->file->has_transactions();
if (table->table->s->tmp_table)
lex->set_stmt_accessed_table(trans ? LEX::STMT_WRITES_TEMP_TRANS_TABLE :
LEX::STMT_WRITES_TEMP_NON_TRANS_TABLE);
else
lex->set_stmt_accessed_table(trans ? LEX::STMT_WRITES_TRANS_TABLE :
LEX::STMT_WRITES_NON_TRANS_TABLE);
flags_write_all_set &= flags;
flags_write_some_set |= flags;
is_write= TRUE;
prev_write_table= table->table;
}
flags_access_some_set |= flags;
if (lex->sql_command != SQLCOM_CREATE_TABLE ||
(lex->sql_command == SQLCOM_CREATE_TABLE && lex->tmp_table()))
{
my_bool trans= table->table->file->has_transactions();
if (table->table->s->tmp_table)
lex->set_stmt_accessed_table(trans ? LEX::STMT_READS_TEMP_TRANS_TABLE :
LEX::STMT_READS_TEMP_NON_TRANS_TABLE);
else
lex->set_stmt_accessed_table(trans ? LEX::STMT_READS_TRANS_TABLE :
LEX::STMT_READS_NON_TRANS_TABLE);
}
if (prev_access_table && prev_access_table->file->ht !=
table->table->file->ht)
multi_access_engine= TRUE;
prev_access_table= table->table;
}
DBUG_PRINT("info", ("flags_write_all_set: 0x%llx", flags_write_all_set));
DBUG_PRINT("info", ("flags_write_some_set: 0x%llx", flags_write_some_set));
DBUG_PRINT("info", ("flags_access_some_set: 0x%llx", flags_access_some_set));
DBUG_PRINT("info", ("multi_write_engine: %d", multi_write_engine));
DBUG_PRINT("info", ("multi_access_engine: %d", multi_access_engine));
int error= 0;
int unsafe_flags;
bool multi_stmt_trans= in_multi_stmt_transaction_mode();
bool trans_table= trans_has_updated_trans_table(this);
bool binlog_direct= variables.binlog_direct_non_trans_update;
if (lex->is_mixed_stmt_unsafe(multi_stmt_trans, binlog_direct,
trans_table, tx_isolation))
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_MIXED_STATEMENT);
else if (multi_stmt_trans && trans_table && !binlog_direct &&
lex->stmt_accessed_table(LEX::STMT_WRITES_NON_TRANS_TABLE))
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_NONTRANS_AFTER_TRANS);
/*
If more than one engine is involved in the statement and at
least one is doing it's own logging (is *self-logging*), the
statement cannot be logged atomically, so we generate an error
rather than allowing the binlog to become corrupt.
*/
if (multi_write_engine &&
(flags_write_some_set & HA_HAS_OWN_BINLOGGING))
my_error((error= ER_BINLOG_MULTIPLE_ENGINES_AND_SELF_LOGGING_ENGINE),
MYF(0));
else if (multi_access_engine && flags_access_some_set & HA_HAS_OWN_BINLOGGING)
lex->set_stmt_unsafe(LEX::BINLOG_STMT_UNSAFE_MULTIPLE_ENGINES_AND_SELF_LOGGING_ENGINE);
/* both statement-only and row-only engines involved */
if ((flags_write_all_set & (HA_BINLOG_STMT_CAPABLE | HA_BINLOG_ROW_CAPABLE)) == 0)
{
/*
1. Error: Binary logging impossible since both row-incapable
engines and statement-incapable engines are involved
*/
my_error((error= ER_BINLOG_ROW_ENGINE_AND_STMT_ENGINE), MYF(0));
}
/* statement-only engines involved */
else if ((flags_write_all_set & HA_BINLOG_ROW_CAPABLE) == 0)
{
if (lex->is_stmt_row_injection())
{
/*
4. Error: Cannot execute row injection since table uses
storage engine limited to statement-logging
*/
my_error((error= ER_BINLOG_ROW_INJECTION_AND_STMT_ENGINE), MYF(0));
}
else if (wsrep_binlog_format() == BINLOG_FORMAT_ROW &&
sqlcom_can_generate_row_events(this))
{
/*
2. Error: Cannot modify table that uses a storage engine
limited to statement-logging when BINLOG_FORMAT = ROW
*/
my_error((error= ER_BINLOG_ROW_MODE_AND_STMT_ENGINE), MYF(0));
}
else if ((unsafe_flags= lex->get_stmt_unsafe_flags()) != 0)
{
/*
3. Error: Cannot execute statement: binlogging of unsafe
statement is impossible when storage engine is limited to
statement-logging and BINLOG_FORMAT = MIXED.
*/
for (int unsafe_type= 0;
unsafe_type < LEX::BINLOG_STMT_UNSAFE_COUNT;
unsafe_type++)
if (unsafe_flags & (1 << unsafe_type))
my_error((error= ER_BINLOG_UNSAFE_AND_STMT_ENGINE), MYF(0),
ER_THD(this,
LEX::binlog_stmt_unsafe_errcode[unsafe_type]));
}
/* log in statement format! */
}
/* no statement-only engines */
else
{
/* binlog_format = STATEMENT */
if (wsrep_binlog_format() == BINLOG_FORMAT_STMT)
{
if (lex->is_stmt_row_injection())
{
/*
We have to log the statement as row or give an error.
Better to accept what master gives us than stopping replication.
*/
set_current_stmt_binlog_format_row();
}
else if ((flags_write_all_set & HA_BINLOG_STMT_CAPABLE) == 0 &&
sqlcom_can_generate_row_events(this))
{
/*
5. Error: Cannot modify table that uses a storage engine
limited to row-logging when binlog_format = STATEMENT
*/
if (IF_WSREP((!WSREP(this) || wsrep_exec_mode == LOCAL_STATE),1))
{
my_error((error= ER_BINLOG_STMT_MODE_AND_ROW_ENGINE), MYF(0), "");
}
}
else if (is_write && (unsafe_flags= lex->get_stmt_unsafe_flags()) != 0)
{
/*
7. Warning: Unsafe statement logged as statement due to
binlog_format = STATEMENT
*/
binlog_unsafe_warning_flags|= unsafe_flags;
DBUG_PRINT("info", ("Scheduling warning to be issued by "
"binlog_query: '%s'",
ER_THD(this, ER_BINLOG_UNSAFE_STATEMENT)));
DBUG_PRINT("info", ("binlog_unsafe_warning_flags: 0x%x",
binlog_unsafe_warning_flags));
}
/* log in statement format (or row if row event)! */
}
/* No statement-only engines and binlog_format != STATEMENT.
I.e., nothing prevents us from row logging if needed. */
else
{
if (lex->is_stmt_unsafe() || lex->is_stmt_row_injection()
|| (flags_write_all_set & HA_BINLOG_STMT_CAPABLE) == 0)
{
/* log in row format! */
set_current_stmt_binlog_format_row_if_mixed();
}
}
}
if (non_replicated_tables_count > 0)
{
if ((replicated_tables_count == 0) || ! is_write)
{
DBUG_PRINT("info", ("decision: no logging, no replicated table affected"));
set_binlog_local_stmt_filter();
}
else
{
if (! is_current_stmt_binlog_format_row())
{
my_error((error= ER_BINLOG_STMT_MODE_AND_NO_REPL_TABLES), MYF(0));
}
else
{
clear_binlog_local_stmt_filter();
}
}
}
else
{
clear_binlog_local_stmt_filter();
}
if (error) {
DBUG_PRINT("info", ("decision: no logging since an error was generated"));
DBUG_RETURN(-1);
}
DBUG_PRINT("info", ("decision: logging in %s format",
is_current_stmt_binlog_format_row() ?
"ROW" : "STATEMENT"));
if (variables.binlog_format == BINLOG_FORMAT_ROW &&
(lex->sql_command == SQLCOM_UPDATE ||
lex->sql_command == SQLCOM_UPDATE_MULTI ||
lex->sql_command == SQLCOM_DELETE ||
lex->sql_command == SQLCOM_DELETE_MULTI))
{
String table_names;
/*
Generate a warning for UPDATE/DELETE statements that modify a
BLACKHOLE table, as row events are not logged in row format.
*/
for (TABLE_LIST *table= tables; table; table= table->next_global)
{
if (table->placeholder())
continue;
if (table->table->file->ht->db_type == DB_TYPE_BLACKHOLE_DB &&
table->lock_type >= TL_WRITE_ALLOW_WRITE)
{
table_names.append(table->table_name);
table_names.append(",");
}
}
if (!table_names.is_empty())
{
bool is_update= (lex->sql_command == SQLCOM_UPDATE ||
lex->sql_command == SQLCOM_UPDATE_MULTI);
/*
Replace the last ',' with '.' for table_names
*/
table_names.replace(table_names.length()-1, 1, ".", 1);
push_warning_printf(this, Sql_condition::WARN_LEVEL_WARN,
ER_UNKNOWN_ERROR,
"Row events are not logged for %s statements "
"that modify BLACKHOLE tables in row format. "
"Table(s): '%-.192s'",
is_update ? "UPDATE" : "DELETE",
table_names.c_ptr());
}
}
}
#ifndef DBUG_OFF
else
DBUG_PRINT("info", ("decision: no logging since "
"mysql_bin_log.is_open() = %d "
"and (options & OPTION_BIN_LOG) = 0x%llx "
"and binlog_format = %u "
"and binlog_filter->db_ok(db) = %d",
mysql_bin_log.is_open(),
(variables.option_bits & OPTION_BIN_LOG),
(uint) wsrep_binlog_format(),
binlog_filter->db_ok(db)));
#endif
DBUG_RETURN(0);
}
/*
Implementation of interface to write rows to the binary log through the
thread. The thread is responsible for writing the rows it has
inserted/updated/deleted.
*/
#ifndef MYSQL_CLIENT
/*
Template member function for ensuring that there is an rows log
event of the apropriate type before proceeding.
PRE CONDITION:
- Events of type 'RowEventT' have the type code 'type_code'.
POST CONDITION:
If a non-NULL pointer is returned, the pending event for thread 'thd' will
be an event of type 'RowEventT' (which have the type code 'type_code')
will either empty or have enough space to hold 'needed' bytes. In
addition, the columns bitmap will be correct for the row, meaning that
the pending event will be flushed if the columns in the event differ from
the columns suppled to the function.
RETURNS
If no error, a non-NULL pending event (either one which already existed or
the newly created one).
If error, NULL.
*/
template <class RowsEventT> Rows_log_event*
THD::binlog_prepare_pending_rows_event(TABLE* table, uint32 serv_id,
size_t needed,
bool is_transactional,
RowsEventT *hint __attribute__((unused)))
{
DBUG_ENTER("binlog_prepare_pending_rows_event");
/* Pre-conditions */
DBUG_ASSERT(table->s->table_map_id != ~0UL);
/* Fetch the type code for the RowsEventT template parameter */
int const general_type_code= RowsEventT::TYPE_CODE;
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_transactional= 1;
/*
There is no good place to set up the transactional data, so we
have to do it here.
*/
if (binlog_setup_trx_data() == NULL)
DBUG_RETURN(NULL);
Rows_log_event* pending= binlog_get_pending_rows_event(is_transactional);
if (unlikely(pending && !pending->is_valid()))
DBUG_RETURN(NULL);
/*
Check if the current event is non-NULL and a write-rows
event. Also check if the table provided is mapped: if it is not,
then we have switched to writing to a new table.
If there is no pending event, we need to create one. If there is a pending
event, but it's not about the same table id, or not of the same type
(between Write, Update and Delete), or not the same affected columns, or
going to be too big, flush this event to disk and create a new pending
event.
*/
if (!pending ||
pending->server_id != serv_id ||
pending->get_table_id() != table->s->table_map_id ||
pending->get_general_type_code() != general_type_code ||
pending->get_data_size() + needed > opt_binlog_rows_event_max_size ||
pending->read_write_bitmaps_cmp(table) == FALSE)
{
/* Create a new RowsEventT... */
Rows_log_event* const
ev= new RowsEventT(this, table, table->s->table_map_id,
is_transactional);
if (unlikely(!ev))
DBUG_RETURN(NULL);
ev->server_id= serv_id; // I don't like this, it's too easy to forget.
/*
flush the pending event and replace it with the newly created
event...
*/
if (unlikely(
mysql_bin_log.flush_and_set_pending_rows_event(this, ev,
is_transactional)))
{
delete ev;
DBUG_RETURN(NULL);
}
DBUG_RETURN(ev); /* This is the new pending event */
}
DBUG_RETURN(pending); /* This is the current pending event */
}
/* Declare in unnamed namespace. */
CPP_UNNAMED_NS_START
/**
Class to handle temporary allocation of memory for row data.
The responsibilities of the class is to provide memory for
packing one or two rows of packed data (depending on what
constructor is called).
In order to make the allocation more efficient for "simple" rows,
i.e., rows that do not contain any blobs, a pointer to the
allocated memory is of memory is stored in the table structure
for simple rows. If memory for a table containing a blob field
is requested, only memory for that is allocated, and subsequently
released when the object is destroyed.
*/
class Row_data_memory {
public:
/**
Build an object to keep track of a block-local piece of memory
for storing a row of data.
@param table
Table where the pre-allocated memory is stored.
@param length
Length of data that is needed, if the record contain blobs.
*/
Row_data_memory(TABLE *table, size_t const len1)
: m_memory(0)
{
#ifndef DBUG_OFF
m_alloc_checked= FALSE;
#endif
allocate_memory(table, len1);
m_ptr[0]= has_memory() ? m_memory : 0;
m_ptr[1]= 0;
}
Row_data_memory(TABLE *table, size_t const len1, size_t const len2)
: m_memory(0)
{
#ifndef DBUG_OFF
m_alloc_checked= FALSE;
#endif
allocate_memory(table, len1 + len2);
m_ptr[0]= has_memory() ? m_memory : 0;
m_ptr[1]= has_memory() ? m_memory + len1 : 0;
}
~Row_data_memory()
{
if (m_memory != 0 && m_release_memory_on_destruction)
my_free(m_memory);
}
/**
Is there memory allocated?
@retval true There is memory allocated
@retval false Memory allocation failed
*/
bool has_memory() const {
#ifndef DBUG_OFF
m_alloc_checked= TRUE;
#endif
return m_memory != 0;
}
uchar *slot(uint s)
{
DBUG_ASSERT(s < sizeof(m_ptr)/sizeof(*m_ptr));
DBUG_ASSERT(m_ptr[s] != 0);
DBUG_ASSERT(m_alloc_checked == TRUE);
return m_ptr[s];
}
private:
void allocate_memory(TABLE *const table, size_t const total_length)
{
if (table->s->blob_fields == 0)
{
/*
The maximum length of a packed record is less than this
length. We use this value instead of the supplied length
when allocating memory for records, since we don't know how
the memory will be used in future allocations.
Since table->s->reclength is for unpacked records, we have
to add two bytes for each field, which can potentially be
added to hold the length of a packed field.
*/
size_t const maxlen= table->s->reclength + 2 * table->s->fields;
/*
Allocate memory for two records if memory hasn't been
allocated. We allocate memory for two records so that it can
be used when processing update rows as well.
*/
if (table->write_row_record == 0)
table->write_row_record=
(uchar *) alloc_root(&table->mem_root, 2 * maxlen);
m_memory= table->write_row_record;
m_release_memory_on_destruction= FALSE;
}
else
{
m_memory= (uchar *) my_malloc(total_length, MYF(MY_WME));
m_release_memory_on_destruction= TRUE;
}
}
#ifndef DBUG_OFF
mutable bool m_alloc_checked;
#endif
bool m_release_memory_on_destruction;
uchar *m_memory;
uchar *m_ptr[2];
};
CPP_UNNAMED_NS_END
int THD::binlog_write_row(TABLE* table, bool is_trans,
uchar const *record)
{
DBUG_ASSERT(is_current_stmt_binlog_format_row() &&
((WSREP(this) && wsrep_emulate_bin_log) || mysql_bin_log.is_open()));
/*
Pack records into format for transfer. We are allocating more
memory than needed, but that doesn't matter.
*/
Row_data_memory memory(table, max_row_length(table, record));
if (!memory.has_memory())
return HA_ERR_OUT_OF_MEM;
uchar *row_data= memory.slot(0);
size_t const len= pack_row(table, table->rpl_write_set, row_data, record);
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_trans= 1;
Rows_log_event* const ev=
binlog_prepare_pending_rows_event(table, variables.server_id,
len, is_trans,
static_cast<Write_rows_log_event*>(0));
if (unlikely(ev == 0))
return HA_ERR_OUT_OF_MEM;
return ev->add_row_data(row_data, len);
}
int THD::binlog_update_row(TABLE* table, bool is_trans,
const uchar *before_record,
const uchar *after_record)
{
DBUG_ASSERT(is_current_stmt_binlog_format_row() &&
((WSREP(this) && wsrep_emulate_bin_log) || mysql_bin_log.is_open()));
size_t const before_maxlen = max_row_length(table, before_record);
size_t const after_maxlen = max_row_length(table, after_record);
Row_data_memory row_data(table, before_maxlen, after_maxlen);
if (!row_data.has_memory())
return HA_ERR_OUT_OF_MEM;
uchar *before_row= row_data.slot(0);
uchar *after_row= row_data.slot(1);
size_t const before_size= pack_row(table, table->read_set, before_row,
before_record);
size_t const after_size= pack_row(table, table->rpl_write_set, after_row,
after_record);
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_trans= 1;
/*
Don't print debug messages when running valgrind since they can
trigger false warnings.
*/
#ifndef HAVE_valgrind
DBUG_DUMP("before_record", before_record, table->s->reclength);
DBUG_DUMP("after_record", after_record, table->s->reclength);
DBUG_DUMP("before_row", before_row, before_size);
DBUG_DUMP("after_row", after_row, after_size);
#endif
Rows_log_event* const ev=
binlog_prepare_pending_rows_event(table, variables.server_id,
before_size + after_size, is_trans,
static_cast<Update_rows_log_event*>(0));
if (unlikely(ev == 0))
return HA_ERR_OUT_OF_MEM;
int error= ev->add_row_data(before_row, before_size) ||
ev->add_row_data(after_row, after_size);
return error;
}
int THD::binlog_delete_row(TABLE* table, bool is_trans,
uchar const *record)
{
DBUG_ASSERT(is_current_stmt_binlog_format_row() &&
((WSREP(this) && wsrep_emulate_bin_log) || mysql_bin_log.is_open()));
/**
Save a reference to the original read bitmaps
We will need this to restore the bitmaps at the end as
binlog_prepare_row_images() may change table->read_set.
table->read_set is used by pack_row and deep in
binlog_prepare_pending_events().
*/
MY_BITMAP *old_read_set= table->read_set;
/**
This will remove spurious fields required during execution but
not needed for binlogging. This is done according to the:
binlog-row-image option.
*/
binlog_prepare_row_images(table);
/*
Pack records into format for transfer. We are allocating more
memory than needed, but that doesn't matter.
*/
Row_data_memory memory(table, max_row_length(table, record));
if (unlikely(!memory.has_memory()))
return HA_ERR_OUT_OF_MEM;
uchar *row_data= memory.slot(0);
DBUG_DUMP("table->read_set", (uchar*) table->read_set->bitmap, (table->s->fields + 7) / 8);
size_t const len= pack_row(table, table->read_set, row_data, record);
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_trans= 1;
Rows_log_event* const ev=
binlog_prepare_pending_rows_event(table, variables.server_id,
len, is_trans,
static_cast<Delete_rows_log_event*>(0));
if (unlikely(ev == 0))
return HA_ERR_OUT_OF_MEM;
int error= ev->add_row_data(row_data, len);
/* restore read set for the rest of execution */
table->column_bitmaps_set_no_signal(old_read_set,
table->write_set);
return error;
}
void THD::binlog_prepare_row_images(TABLE *table)
{
DBUG_ENTER("THD::binlog_prepare_row_images");
/**
Remove from read_set spurious columns. The write_set has been
handled before in table->mark_columns_needed_for_update.
*/
DBUG_PRINT_BITSET("debug", "table->read_set (before preparing): %s", table->read_set);
THD *thd= table->in_use;
/**
if there is a primary key in the table (ie, user declared PK or a
non-null unique index) and we dont want to ship the entire image,
and the handler involved supports this.
*/
if (table->s->primary_key < MAX_KEY &&
(thd->variables.binlog_row_image < BINLOG_ROW_IMAGE_FULL) &&
!ha_check_storage_engine_flag(table->s->db_type(), HTON_NO_BINLOG_ROW_OPT))
{
/**
Just to be sure that tmp_set is currently not in use as
the read_set already.
*/
DBUG_ASSERT(table->read_set != &table->tmp_set);
bitmap_clear_all(&table->tmp_set);
switch(thd->variables.binlog_row_image)
{
case BINLOG_ROW_IMAGE_MINIMAL:
/* MINIMAL: Mark only PK */
table->mark_columns_used_by_index_no_reset(table->s->primary_key,
&table->tmp_set);
break;
case BINLOG_ROW_IMAGE_NOBLOB:
/**
NOBLOB: Remove unnecessary BLOB fields from read_set
(the ones that are not part of PK).
*/
bitmap_union(&table->tmp_set, table->read_set);
for (Field **ptr=table->field ; *ptr ; ptr++)
{
Field *field= (*ptr);
if ((field->type() == MYSQL_TYPE_BLOB) &&
!(field->flags & PRI_KEY_FLAG))
bitmap_clear_bit(&table->tmp_set, field->field_index);
}
break;
default:
DBUG_ASSERT(0); // impossible.
}
/* set the temporary read_set */
table->column_bitmaps_set_no_signal(&table->tmp_set,
table->write_set);
}
DBUG_PRINT_BITSET("debug", "table->read_set (after preparing): %s", table->read_set);
DBUG_VOID_RETURN;
}
int THD::binlog_remove_pending_rows_event(bool clear_maps,
bool is_transactional)
{
DBUG_ENTER("THD::binlog_remove_pending_rows_event");
if(!WSREP_EMULATE_BINLOG(this) && !mysql_bin_log.is_open())
DBUG_RETURN(0);
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_transactional= 1;
mysql_bin_log.remove_pending_rows_event(this, is_transactional);
if (clear_maps)
binlog_table_maps= 0;
DBUG_RETURN(0);
}
int THD::binlog_flush_pending_rows_event(bool stmt_end, bool is_transactional)
{
DBUG_ENTER("THD::binlog_flush_pending_rows_event");
/*
We shall flush the pending event even if we are not in row-based
mode: it might be the case that we left row-based mode before
flushing anything (e.g., if we have explicitly locked tables).
*/
if(!WSREP_EMULATE_BINLOG(this) && !mysql_bin_log.is_open())
DBUG_RETURN(0);
/* Ensure that all events in a GTID group are in the same cache */
if (variables.option_bits & OPTION_GTID_BEGIN)
is_transactional= 1;
/*
Mark the event as the last event of a statement if the stmt_end
flag is set.
*/
int error= 0;
if (Rows_log_event *pending= binlog_get_pending_rows_event(is_transactional))
{
if (stmt_end)
{
pending->set_flags(Rows_log_event::STMT_END_F);
binlog_table_maps= 0;
}
error= mysql_bin_log.flush_and_set_pending_rows_event(this, 0,
is_transactional);
}
DBUG_RETURN(error);
}
#if !defined(DBUG_OFF) && !defined(_lint)
static const char *
show_query_type(THD::enum_binlog_query_type qtype)
{
switch (qtype) {
case THD::ROW_QUERY_TYPE:
return "ROW";
case THD::STMT_QUERY_TYPE:
return "STMT";
case THD::QUERY_TYPE_COUNT:
default:
DBUG_ASSERT(0 <= qtype && qtype < THD::QUERY_TYPE_COUNT);
}
static char buf[64];
sprintf(buf, "UNKNOWN#%d", qtype);
return buf;
}
#endif
/*
Constants required for the limit unsafe warnings suppression
*/
//seconds after which the limit unsafe warnings suppression will be activated
#define LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT 5*60
//number of limit unsafe warnings after which the suppression will be activated
#define LIMIT_UNSAFE_WARNING_ACTIVATION_THRESHOLD_COUNT 10
static ulonglong unsafe_suppression_start_time= 0;
static bool unsafe_warning_suppression_active[LEX::BINLOG_STMT_UNSAFE_COUNT];
static ulong unsafe_warnings_count[LEX::BINLOG_STMT_UNSAFE_COUNT];
static ulong total_unsafe_warnings_count;
/**
Auxiliary function to reset the limit unsafety warning suppression.
This is done without mutex protection, but this should be good
enough as it doesn't matter if we loose a couple of suppressed
messages or if this is called multiple times.
*/
static void reset_binlog_unsafe_suppression(ulonglong now)
{
uint i;
DBUG_ENTER("reset_binlog_unsafe_suppression");
unsafe_suppression_start_time= now;
total_unsafe_warnings_count= 0;
for (i= 0 ; i < LEX::BINLOG_STMT_UNSAFE_COUNT ; i++)
{
unsafe_warnings_count[i]= 0;
unsafe_warning_suppression_active[i]= 0;
}
DBUG_VOID_RETURN;
}
/**
Auxiliary function to print warning in the error log.
*/
static void print_unsafe_warning_to_log(THD *thd, int unsafe_type, char* buf,
char* query)
{
DBUG_ENTER("print_unsafe_warning_in_log");
sprintf(buf, ER_THD(thd, ER_BINLOG_UNSAFE_STATEMENT),
ER_THD(thd, LEX::binlog_stmt_unsafe_errcode[unsafe_type]));
sql_print_warning(ER_THD(thd, ER_MESSAGE_AND_STATEMENT), buf, query);
DBUG_VOID_RETURN;
}
/**
Auxiliary function to check if the warning for unsafe repliction statements
should be thrown or suppressed.
Logic is:
- If we get more than LIMIT_UNSAFE_WARNING_ACTIVATION_THRESHOLD_COUNT errors
of one type, that type of errors will be suppressed for
LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT.
- When the time limit has been reached, all suppression is reset.
This means that if one gets many different types of errors, some of them
may be reset less than LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT. However at
least one error is disable for this time.
SYNOPSIS:
@params
unsafe_type - The type of unsafety.
RETURN:
0 0k to log
1 Message suppressed
*/
static bool protect_against_unsafe_warning_flood(int unsafe_type)
{
ulong count;
ulonglong now= my_interval_timer()/1000000000ULL;
DBUG_ENTER("protect_against_unsafe_warning_flood");
count= ++unsafe_warnings_count[unsafe_type];
total_unsafe_warnings_count++;
/*
INITIALIZING:
If this is the first time this function is called with log warning
enabled, the monitoring the unsafe warnings should start.
*/
if (unsafe_suppression_start_time == 0)
{
reset_binlog_unsafe_suppression(now);
DBUG_RETURN(0);
}
/*
The following is true if we got too many errors or if the error was
already suppressed
*/
if (count >= LIMIT_UNSAFE_WARNING_ACTIVATION_THRESHOLD_COUNT)
{
ulonglong diff_time= (now - unsafe_suppression_start_time);
if (!unsafe_warning_suppression_active[unsafe_type])
{
/*
ACTIVATION:
We got LIMIT_UNSAFE_WARNING_ACTIVATION_THRESHOLD_COUNT warnings in
less than LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT we activate the
suppression.
*/
if (diff_time <= LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT)
{
unsafe_warning_suppression_active[unsafe_type]= 1;
sql_print_information("Suppressing warnings of type '%s' for up to %d seconds because of flooding",
ER(LEX::binlog_stmt_unsafe_errcode[unsafe_type]),
LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT);
}
else
{
/*
There is no flooding till now, therefore we restart the monitoring
*/
reset_binlog_unsafe_suppression(now);
}
}
else
{
/* This type of warnings was suppressed */
if (diff_time > LIMIT_UNSAFE_WARNING_ACTIVATION_TIMEOUT)
{
ulong save_count= total_unsafe_warnings_count;
/* Print a suppression note and remove the suppression */
reset_binlog_unsafe_suppression(now);
sql_print_information("Suppressed %lu unsafe warnings during "
"the last %d seconds",
save_count, (int) diff_time);
}
}
}
DBUG_RETURN(unsafe_warning_suppression_active[unsafe_type]);
}
/**
Auxiliary method used by @c binlog_query() to raise warnings.
The type of warning and the type of unsafeness is stored in
THD::binlog_unsafe_warning_flags.
*/
void THD::issue_unsafe_warnings()
{
char buf[MYSQL_ERRMSG_SIZE * 2];
uint32 unsafe_type_flags;
DBUG_ENTER("issue_unsafe_warnings");
/*
Ensure that binlog_unsafe_warning_flags is big enough to hold all
bits. This is actually a constant expression.
*/
DBUG_ASSERT(LEX::BINLOG_STMT_UNSAFE_COUNT <=
sizeof(binlog_unsafe_warning_flags) * CHAR_BIT);
if (!(unsafe_type_flags= binlog_unsafe_warning_flags))
DBUG_VOID_RETURN; // Nothing to do
/*
For each unsafe_type, check if the statement is unsafe in this way
and issue a warning.
*/
for (int unsafe_type=0;
unsafe_type < LEX::BINLOG_STMT_UNSAFE_COUNT;
unsafe_type++)
{
if ((unsafe_type_flags & (1 << unsafe_type)) != 0)
{
push_warning_printf(this, Sql_condition::WARN_LEVEL_NOTE,
ER_BINLOG_UNSAFE_STATEMENT,
ER_THD(this, ER_BINLOG_UNSAFE_STATEMENT),
ER_THD(this, LEX::binlog_stmt_unsafe_errcode[unsafe_type]));
if (global_system_variables.log_warnings > 0 &&
!protect_against_unsafe_warning_flood(unsafe_type))
print_unsafe_warning_to_log(this, unsafe_type, buf, query());
}
}
DBUG_VOID_RETURN;
}
/**
Log the current query.
The query will be logged in either row format or statement format
depending on the value of @c current_stmt_binlog_format_row field and
the value of the @c qtype parameter.
This function must be called:
- After the all calls to ha_*_row() functions have been issued.
- After any writes to system tables. Rationale: if system tables
were written after a call to this function, and the master crashes
after the call to this function and before writing the system
tables, then the master and slave get out of sync.
- Before tables are unlocked and closed.
@see decide_logging_format
@retval 0 Success
@retval nonzero If there is a failure when writing the query (e.g.,
write failure), then the error code is returned.
*/
int THD::binlog_query(THD::enum_binlog_query_type qtype, char const *query_arg,
ulong query_len, bool is_trans, bool direct,
bool suppress_use, int errcode)
{
DBUG_ENTER("THD::binlog_query");
DBUG_PRINT("enter", ("qtype: %s query: '%-.*s'",
show_query_type(qtype), (int) query_len, query_arg));
DBUG_ASSERT(query_arg);
DBUG_ASSERT(WSREP_EMULATE_BINLOG(this) || mysql_bin_log.is_open());
/* If this is withing a BEGIN ... COMMIT group, don't log it */
if (variables.option_bits & OPTION_GTID_BEGIN)
{
direct= 0;
is_trans= 1;
}
DBUG_PRINT("info", ("is_trans: %d direct: %d", is_trans, direct));
if (get_binlog_local_stmt_filter() == BINLOG_FILTER_SET)
{
/*
The current statement is to be ignored, and not written to
the binlog. Do not call issue_unsafe_warnings().
*/
DBUG_RETURN(0);
}
/*
If we are not in prelocked mode, mysql_unlock_tables() will be
called after this binlog_query(), so we have to flush the pending
rows event with the STMT_END_F set to unlock all tables at the
slave side as well.
If we are in prelocked mode, the flushing will be done inside the
top-most close_thread_tables().
*/
if (this->locked_tables_mode <= LTM_LOCK_TABLES)
if (int error= binlog_flush_pending_rows_event(TRUE, is_trans))
DBUG_RETURN(error);
/*
Warnings for unsafe statements logged in statement format are
printed in three places instead of in decide_logging_format().
This is because the warnings should be printed only if the statement
is actually logged. When executing decide_logging_format(), we cannot
know for sure if the statement will be logged:
1 - sp_head::execute_procedure which prints out warnings for calls to
stored procedures.
2 - sp_head::execute_function which prints out warnings for calls
involving functions.
3 - THD::binlog_query (here) which prints warning for top level
statements not covered by the two cases above: i.e., if not insided a
procedure and a function.
Besides, we should not try to print these warnings if it is not
possible to write statements to the binary log as it happens when
the execution is inside a function, or generaly speaking, when
the variables.option_bits & OPTION_BIN_LOG is false.
*/
if ((variables.option_bits & OPTION_BIN_LOG) &&
spcont == NULL && !binlog_evt_union.do_union)
issue_unsafe_warnings();
switch (qtype) {
/*
ROW_QUERY_TYPE means that the statement may be logged either in
row format or in statement format. If
current_stmt_binlog_format is row, it means that the
statement has already been logged in row format and hence shall
not be logged again.
*/
case THD::ROW_QUERY_TYPE:
DBUG_PRINT("debug",
("is_current_stmt_binlog_format_row: %d",
is_current_stmt_binlog_format_row()));
if (is_current_stmt_binlog_format_row())
DBUG_RETURN(0);
/* Fall through */
/*
STMT_QUERY_TYPE means that the query must be logged in statement
format; it cannot be logged in row format. This is typically
used by DDL statements. It is an error to use this query type
if current_stmt_binlog_format_row is row.
@todo Currently there are places that call this method with
STMT_QUERY_TYPE and current_stmt_binlog_format is row. Fix those
places and add assert to ensure correct behavior. /Sven
*/
case THD::STMT_QUERY_TYPE:
/*
The MYSQL_LOG::write() function will set the STMT_END_F flag and
flush the pending rows event if necessary.
*/
{
Query_log_event qinfo(this, query_arg, query_len, is_trans, direct,
suppress_use, errcode);
/*
Binlog table maps will be irrelevant after a Query_log_event
(they are just removed on the slave side) so after the query
log event is written to the binary log, we pretend that no
table maps were written.
*/
int error= mysql_bin_log.write(&qinfo);
binlog_table_maps= 0;
DBUG_RETURN(error);
}
case THD::QUERY_TYPE_COUNT:
default:
DBUG_ASSERT(qtype < QUERY_TYPE_COUNT);
}
DBUG_RETURN(0);
}
void
THD::wait_for_wakeup_ready()
{
mysql_mutex_lock(&LOCK_wakeup_ready);
while (!wakeup_ready)
mysql_cond_wait(&COND_wakeup_ready, &LOCK_wakeup_ready);
mysql_mutex_unlock(&LOCK_wakeup_ready);
}
void
THD::signal_wakeup_ready()
{
mysql_mutex_lock(&LOCK_wakeup_ready);
wakeup_ready= true;
mysql_mutex_unlock(&LOCK_wakeup_ready);
mysql_cond_signal(&COND_wakeup_ready);
}
void THD::rgi_lock_temporary_tables()
{
mysql_mutex_lock(&rgi_slave->rli->data_lock);
temporary_tables= rgi_slave->rli->save_temporary_tables;
}
void THD::rgi_unlock_temporary_tables(bool clear)
{
rgi_slave->rli->save_temporary_tables= temporary_tables;
mysql_mutex_unlock(&rgi_slave->rli->data_lock);
if (clear)
{
/*
Temporary tables are shared with other by sql execution threads.
As a safety messure, clear the pointer to the common area.
*/
temporary_tables= 0;
}
}
bool THD::rgi_have_temporary_tables()
{
return rgi_slave->rli->save_temporary_tables != 0;
}
void
wait_for_commit::reinit()
{
subsequent_commits_list= NULL;
next_subsequent_commit= NULL;
waitee= NULL;
opaque_pointer= NULL;
wakeup_error= 0;
wakeup_subsequent_commits_running= false;
commit_started= false;
#ifdef SAFE_MUTEX
/*
When using SAFE_MUTEX, the ordering between taking the LOCK_wait_commit
mutexes is checked. This causes a problem when we re-use a mutex, as then
the expected locking order may change.
So in this case, do a re-init of the mutex. In release builds, we want to
avoid the overhead of a re-init though.
To ensure that no one is locking the mutex, we take a lock of it first.
For full explanation, see wait_for_commit::~wait_for_commit()
*/
mysql_mutex_lock(&LOCK_wait_commit);
mysql_mutex_unlock(&LOCK_wait_commit);
mysql_mutex_destroy(&LOCK_wait_commit);
mysql_mutex_init(key_LOCK_wait_commit, &LOCK_wait_commit, MY_MUTEX_INIT_FAST);
#endif
}
wait_for_commit::wait_for_commit()
{
mysql_mutex_init(key_LOCK_wait_commit, &LOCK_wait_commit, MY_MUTEX_INIT_FAST);
mysql_cond_init(key_COND_wait_commit, &COND_wait_commit, 0);
reinit();
}
wait_for_commit::~wait_for_commit()
{
/*
Since we do a dirty read of the waiting_for_commit flag in
wait_for_prior_commit() and in unregister_wait_for_prior_commit(), we need
to take extra care before freeing the wait_for_commit object.
It is possible for the waitee to be pre-empted inside wakeup(), just after
it has cleared the waiting_for_commit flag and before it has released the
LOCK_wait_commit mutex. And then it is possible for the waiter to find the
flag cleared in wait_for_prior_commit() and go finish up things and
de-allocate the LOCK_wait_commit and COND_wait_commit objects before the
waitee has time to be re-scheduled and finish unlocking the mutex and
signalling the condition. This would lead to the waitee accessing no
longer valid memory.
To prevent this, we do an extra lock/unlock of the mutex here before
deallocation; this makes certain that any waitee has completed wakeup()
first.
*/
mysql_mutex_lock(&LOCK_wait_commit);
mysql_mutex_unlock(&LOCK_wait_commit);
mysql_mutex_destroy(&LOCK_wait_commit);
mysql_cond_destroy(&COND_wait_commit);
}
void
wait_for_commit::wakeup(int wakeup_error)
{
/*
We signal each waiter on their own condition and mutex (rather than using
pthread_cond_broadcast() or something like that).
Otherwise we would need to somehow ensure that they were done
waking up before we could allow this THD to be destroyed, which would
be annoying and unnecessary.
Note that wakeup_subsequent_commits2() depends on this function being a
full memory barrier (it is, because it takes a mutex lock).
*/
mysql_mutex_lock(&LOCK_wait_commit);
waitee= NULL;
this->wakeup_error= wakeup_error;
/*
Note that it is critical that the mysql_cond_signal() here is done while
still holding the mutex. As soon as we release the mutex, the waiter might
deallocate the condition object.
*/
mysql_cond_signal(&COND_wait_commit);
mysql_mutex_unlock(&LOCK_wait_commit);
}
/*
Register that the next commit of this THD should wait to complete until
commit in another THD (the waitee) has completed.
The wait may occur explicitly, with the waiter sitting in
wait_for_prior_commit() until the waitee calls wakeup_subsequent_commits().
Alternatively, the TC (eg. binlog) may do the commits of both waitee and
waiter at once during group commit, resolving both of them in the right
order.
Only one waitee can be registered for a waiter; it must be removed by
wait_for_prior_commit() or unregister_wait_for_prior_commit() before a new
one is registered. But it is ok for several waiters to register a wait for
the same waitee. It is also permissible for one THD to be both a waiter and
a waitee at the same time.
*/
void
wait_for_commit::register_wait_for_prior_commit(wait_for_commit *waitee)
{
DBUG_ASSERT(!this->waitee /* No prior registration allowed */);
wakeup_error= 0;
this->waitee= waitee;
mysql_mutex_lock(&waitee->LOCK_wait_commit);
/*
If waitee is in the middle of wakeup, then there is nothing to wait for,
so we need not register. This is necessary to avoid a race in unregister,
see comments on wakeup_subsequent_commits2() for details.
*/
if (waitee->wakeup_subsequent_commits_running)
this->waitee= NULL;
else
{
/*
Put ourself at the head of the waitee's list of transactions that must
wait for it to commit first.
*/
this->next_subsequent_commit= waitee->subsequent_commits_list;
waitee->subsequent_commits_list= this;
}
mysql_mutex_unlock(&waitee->LOCK_wait_commit);
}
/*
Wait for commit of another transaction to complete, as already registered
with register_wait_for_prior_commit(). If the commit already completed,
returns immediately.
*/
int
wait_for_commit::wait_for_prior_commit2(THD *thd)
{
PSI_stage_info old_stage;
wait_for_commit *loc_waitee;
mysql_mutex_lock(&LOCK_wait_commit);
DEBUG_SYNC(thd, "wait_for_prior_commit_waiting");
thd->ENTER_COND(&COND_wait_commit, &LOCK_wait_commit,
&stage_waiting_for_prior_transaction_to_commit,
&old_stage);
while ((loc_waitee= this->waitee) && !thd->check_killed())
mysql_cond_wait(&COND_wait_commit, &LOCK_wait_commit);
if (!loc_waitee)
{
if (wakeup_error)
my_error(ER_PRIOR_COMMIT_FAILED, MYF(0));
goto end;
}
/*
Wait was interrupted by kill. We need to unregister our wait and give the
error. But if a wakeup is already in progress, then we must ignore the
kill and not give error, otherwise we get inconsistency between waitee and
waiter as to whether we succeed or fail (eg. we may roll back but waitee
might attempt to commit both us and any subsequent commits waiting for us).
*/
mysql_mutex_lock(&loc_waitee->LOCK_wait_commit);
if (loc_waitee->wakeup_subsequent_commits_running)
{
/* We are being woken up; ignore the kill and just wait. */
mysql_mutex_unlock(&loc_waitee->LOCK_wait_commit);
do
{
mysql_cond_wait(&COND_wait_commit, &LOCK_wait_commit);
} while (this->waitee);
if (wakeup_error)
my_error(ER_PRIOR_COMMIT_FAILED, MYF(0));
goto end;
}
remove_from_list(&loc_waitee->subsequent_commits_list);
mysql_mutex_unlock(&loc_waitee->LOCK_wait_commit);
this->waitee= NULL;
wakeup_error= thd->killed_errno();
if (!wakeup_error)
wakeup_error= ER_QUERY_INTERRUPTED;
my_message(wakeup_error, ER_THD(thd, wakeup_error), MYF(0));
thd->EXIT_COND(&old_stage);
/*
Must do the DEBUG_SYNC() _after_ exit_cond(), as DEBUG_SYNC is not safe to
use within enter_cond/exit_cond.
*/
DEBUG_SYNC(thd, "wait_for_prior_commit_killed");
return wakeup_error;
end:
thd->EXIT_COND(&old_stage);
return wakeup_error;
}
/*
Wakeup anyone waiting for us to have committed.
Note about locking:
We have a potential race or deadlock between wakeup_subsequent_commits() in
the waitee and unregister_wait_for_prior_commit() in the waiter.
Both waiter and waitee needs to take their own lock before it is safe to take
a lock on the other party - else the other party might disappear and invalid
memory data could be accessed. But if we take the two locks in different
order, we may end up in a deadlock.
The waiter needs to lock the waitee to delete itself from the list in
unregister_wait_for_prior_commit(). Thus wakeup_subsequent_commits() can not
hold its own lock while locking waiters, as this could lead to deadlock.
So we need to prevent unregister_wait_for_prior_commit() running while wakeup
is in progress - otherwise the unregister could complete before the wakeup,
leading to incorrect spurious wakeup or accessing invalid memory.
However, if we are in the middle of running wakeup_subsequent_commits(), then
there is no need for unregister_wait_for_prior_commit() in the first place -
the waiter can just do a normal wait_for_prior_commit(), as it will be
immediately woken up.
So the solution to the potential race/deadlock is to set a flag in the waitee
that wakeup_subsequent_commits() is in progress. When this flag is set,
unregister_wait_for_prior_commit() becomes just wait_for_prior_commit().
Then also register_wait_for_prior_commit() needs to check if
wakeup_subsequent_commits() is running, and skip the registration if
so. This is needed in case a new waiter manages to register itself and
immediately try to unregister while wakeup_subsequent_commits() is
running. Else the new waiter would also wait rather than unregister, but it
would not be woken up until next wakeup, which could be potentially much
later than necessary.
*/
void
wait_for_commit::wakeup_subsequent_commits2(int wakeup_error)
{
wait_for_commit *waiter;
mysql_mutex_lock(&LOCK_wait_commit);
wakeup_subsequent_commits_running= true;
waiter= subsequent_commits_list;
subsequent_commits_list= NULL;
mysql_mutex_unlock(&LOCK_wait_commit);
while (waiter)
{
/*
Important: we must grab the next pointer before waking up the waiter;
once the wakeup is done, the field could be invalidated at any time.
*/
wait_for_commit *next= waiter->next_subsequent_commit;
waiter->wakeup(wakeup_error);
waiter= next;
}
/*
We need a full memory barrier between walking the list above, and clearing
the flag wakeup_subsequent_commits_running below. This barrier is needed
to ensure that no other thread will start to modify the list pointers
before we are done traversing the list.
But wait_for_commit::wakeup() does a full memory barrier already (it locks
a mutex), so no extra explicit barrier is needed here.
*/
wakeup_subsequent_commits_running= false;
DBUG_EXECUTE_IF("inject_wakeup_subsequent_commits_sleep", my_sleep(21000););
}
/* Cancel a previously registered wait for another THD to commit before us. */
void
wait_for_commit::unregister_wait_for_prior_commit2()
{
wait_for_commit *loc_waitee;
mysql_mutex_lock(&LOCK_wait_commit);
if ((loc_waitee= this->waitee))
{
mysql_mutex_lock(&loc_waitee->LOCK_wait_commit);
if (loc_waitee->wakeup_subsequent_commits_running)
{
/*
When a wakeup is running, we cannot safely remove ourselves from the
list without corrupting it. Instead we can just wait, as wakeup is
already in progress and will thus be immediate.
See comments on wakeup_subsequent_commits2() for more details.
*/
mysql_mutex_unlock(&loc_waitee->LOCK_wait_commit);
while (this->waitee)
mysql_cond_wait(&COND_wait_commit, &LOCK_wait_commit);
}
else
{
/* Remove ourselves from the list in the waitee. */
remove_from_list(&loc_waitee->subsequent_commits_list);
mysql_mutex_unlock(&loc_waitee->LOCK_wait_commit);
this->waitee= NULL;
}
}
wakeup_error= 0;
mysql_mutex_unlock(&LOCK_wait_commit);
}
bool Discrete_intervals_list::append(ulonglong start, ulonglong val,
ulonglong incr)
{
DBUG_ENTER("Discrete_intervals_list::append");
/* first, see if this can be merged with previous */
if ((head == NULL) || tail->merge_if_contiguous(start, val, incr))
{
/* it cannot, so need to add a new interval */
Discrete_interval *new_interval= new Discrete_interval(start, val, incr);
DBUG_RETURN(append(new_interval));
}
DBUG_RETURN(0);
}
bool Discrete_intervals_list::append(Discrete_interval *new_interval)
{
DBUG_ENTER("Discrete_intervals_list::append");
if (unlikely(new_interval == NULL))
DBUG_RETURN(1);
DBUG_PRINT("info",("adding new auto_increment interval"));
if (head == NULL)
head= current= new_interval;
else
tail->next= new_interval;
tail= new_interval;
elements++;
DBUG_RETURN(0);
}
#endif /* !defined(MYSQL_CLIENT) */
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