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mariadb/sql/event_scheduler.cc
unknown 66cd6d0c8f Patch for BUG#31111: --read-only crashes MySQL (events fail to load). 
There actually were several problems here:
  - WRITE-lock is required to load events from the mysql.event table,
    but in the read-only mode an ordinary user can not acquire it;
  - Security_context::master_access attribute was not properly
    initialized in Security_context::init(), which led to differences
    in behavior with and without debug configure options.
  - if the server failed to load events from mysql.event, it forgot to
    close the mysql.event table, that led to the coredump, described
    in the bug report.

The patch is to fix all these problems:
  - Use the super-user to acquire WRITE-lock on the mysql.even table;
  - The WRITE-lock is acquired by the event scheduler in two cases:
    - on initial loading of events from the database;
    - when an event has been executed, so its attributes should
      be updated.
    Other cases when WRITE-lock is needed for the mysql.event table
    happen under the user account. So, nothing should be changed there
    for the read-only mode. The user is able to create/update/drop
    an event only if he is a super-user.
  - Initialize Security_context::master_access;
  - Close the mysql.event table in case something went wrong.


mysql-test/r/events_bugs.result:
  Update result file.
mysql-test/t/events_bugs.test:
  A test case for BUG#31111: --read-only crashes MySQL (events fail
  to load).
sql/event_data_objects.cc:
  When the worker thread is going to drop event after the execution
  we should do it under the super-user privileges in order to be able
  to lock the mysql.event table for writing in the read-only mode.
  
  This is a system operation, where user SQL can not be executed.
  So, there is no risk in compromising security by dropping an event
  under the super-user privileges.
sql/event_db_repository.cc:
  1. Close tables if something went wrong in simple_open_n_lock_tables();
  2. As soon as the system event scheduler thread is running under
     the super-user privileges, we should always be able to acquire
     WRITE-lock on the mysql.event table. However, let's have an assert
     to check this.
sql/event_scheduler.cc:
  Run the system event scheduler thread under the super-user privileges.
  In particular, this is needed to be able to lock the mysql.event table
  for writing when the server is running in the read-only mode.
  
  The event scheduler executes only system operations and does not
  execute user SQL (this is what the worker threads for). So, there
  is no risk in compromising security by running the event scheduler
  under the super-user privileges.
sql/events.cc:
  Open the mysql.event table as the super user to be able to acquire
  WRITE-lock in the read-only mode.
sql/sql_class.cc:
  Initialize Security_context::master_acces.
2007-10-19 19:57:08 +04:00

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/* Copyright (C) 2004-2006 MySQL AB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
#include "mysql_priv.h"
#include "events.h"
#include "event_data_objects.h"
#include "event_scheduler.h"
#include "event_queue.h"
#include "event_db_repository.h"
/**
@addtogroup Event_Scheduler
@{
*/
#ifdef __GNUC__
#if __GNUC__ >= 2
#define SCHED_FUNC __FUNCTION__
#endif
#else
#define SCHED_FUNC "<unknown>"
#endif
#define LOCK_DATA() lock_data(SCHED_FUNC, __LINE__)
#define UNLOCK_DATA() unlock_data(SCHED_FUNC, __LINE__)
#define COND_STATE_WAIT(mythd, abstime, msg) \
cond_wait(mythd, abstime, msg, SCHED_FUNC, __LINE__)
extern pthread_attr_t connection_attrib;
Event_db_repository *Event_worker_thread::db_repository;
static
const LEX_STRING scheduler_states_names[] =
{
{ C_STRING_WITH_LEN("INITIALIZED") },
{ C_STRING_WITH_LEN("RUNNING") },
{ C_STRING_WITH_LEN("STOPPING") }
};
struct scheduler_param {
THD *thd;
Event_scheduler *scheduler;
};
/*
Prints the stack of infos, warnings, errors from thd to
the console so it can be fetched by the logs-into-tables and
checked later.
SYNOPSIS
evex_print_warnings
thd Thread used during the execution of the event
et The event itself
*/
void
Event_worker_thread::print_warnings(THD *thd, Event_job_data *et)
{
MYSQL_ERROR *err;
DBUG_ENTER("evex_print_warnings");
if (!thd->warn_list.elements)
DBUG_VOID_RETURN;
char msg_buf[10 * STRING_BUFFER_USUAL_SIZE];
char prefix_buf[5 * STRING_BUFFER_USUAL_SIZE];
String prefix(prefix_buf, sizeof(prefix_buf), system_charset_info);
prefix.length(0);
prefix.append("Event Scheduler: [");
prefix.append(et->definer.str, et->definer.length, system_charset_info);
prefix.append("][", 2);
prefix.append(et->dbname.str, et->dbname.length, system_charset_info);
prefix.append('.');
prefix.append(et->name.str, et->name.length, system_charset_info);
prefix.append("] ", 2);
List_iterator_fast<MYSQL_ERROR> it(thd->warn_list);
while ((err= it++))
{
String err_msg(msg_buf, sizeof(msg_buf), system_charset_info);
/* set it to 0 or we start adding at the end. That's the trick ;) */
err_msg.length(0);
err_msg.append(prefix);
err_msg.append(err->msg, strlen(err->msg), system_charset_info);
DBUG_ASSERT(err->level < 3);
(sql_print_message_handlers[err->level])("%*s", err_msg.length(),
err_msg.c_ptr());
}
DBUG_VOID_RETURN;
}
/*
Performs post initialization of structures in a new thread.
SYNOPSIS
post_init_event_thread()
thd Thread
NOTES
Before this is called, one should not do any DBUG_XXX() calls.
*/
bool
post_init_event_thread(THD *thd)
{
(void) init_new_connection_handler_thread();
if (init_thr_lock() || thd->store_globals())
{
thd->cleanup();
return TRUE;
}
pthread_mutex_lock(&LOCK_thread_count);
threads.append(thd);
thread_count++;
thread_running++;
pthread_mutex_unlock(&LOCK_thread_count);
return FALSE;
}
/*
Cleans up the THD and the threaded environment of the thread.
SYNOPSIS
deinit_event_thread()
thd Thread
*/
void
deinit_event_thread(THD *thd)
{
thd->proc_info= "Clearing";
DBUG_ASSERT(thd->net.buff != 0);
net_end(&thd->net);
DBUG_PRINT("exit", ("Event thread finishing"));
pthread_mutex_lock(&LOCK_thread_count);
thread_count--;
thread_running--;
delete thd;
pthread_mutex_unlock(&LOCK_thread_count);
}
/*
Performs pre- pthread_create() initialisation of THD. Do this
in the thread that will pass THD to the child thread. In the
child thread call post_init_event_thread().
SYNOPSIS
pre_init_event_thread()
thd The THD of the thread. Has to be allocated by the caller.
NOTES
1. The host of the thead is my_localhost
2. thd->net is initted with NULL - no communication.
*/
void
pre_init_event_thread(THD* thd)
{
DBUG_ENTER("pre_init_event_thread");
thd->client_capabilities= 0;
thd->security_ctx->master_access= 0;
thd->security_ctx->db_access= 0;
thd->security_ctx->host_or_ip= (char*)my_localhost;
my_net_init(&thd->net, NULL);
thd->security_ctx->set_user((char*)"event_scheduler");
thd->net.read_timeout= slave_net_timeout;
thd->slave_thread= 0;
thd->options|= OPTION_AUTO_IS_NULL;
thd->client_capabilities|= CLIENT_MULTI_RESULTS;
pthread_mutex_lock(&LOCK_thread_count);
thd->thread_id= thd->variables.pseudo_thread_id= thread_id++;
pthread_mutex_unlock(&LOCK_thread_count);
/*
Guarantees that we will see the thread in SHOW PROCESSLIST though its
vio is NULL.
*/
thd->proc_info= "Initialized";
thd->version= refresh_version;
thd->set_time();
DBUG_VOID_RETURN;
}
/*
Function that executes the scheduler,
SYNOPSIS
event_scheduler_thread()
arg Pointer to `struct scheduler_param`
RETURN VALUE
0 OK
*/
pthread_handler_t
event_scheduler_thread(void *arg)
{
/* needs to be first for thread_stack */
THD *thd= (THD *) ((struct scheduler_param *) arg)->thd;
Event_scheduler *scheduler= ((struct scheduler_param *) arg)->scheduler;
bool res;
thd->thread_stack= (char *)&thd; // remember where our stack is
res= post_init_event_thread(thd);
DBUG_ENTER("event_scheduler_thread");
my_free((char*)arg, MYF(0));
if (!res)
scheduler->run(thd);
my_thread_end();
DBUG_RETURN(0); // Against gcc warnings
}
/**
Function that executes an event in a child thread. Setups the
environment for the event execution and cleans after that.
SYNOPSIS
event_worker_thread()
arg The Event_job_data object to be processed
RETURN VALUE
0 OK
*/
pthread_handler_t
event_worker_thread(void *arg)
{
THD *thd;
Event_queue_element_for_exec *event= (Event_queue_element_for_exec *)arg;
thd= event->thd;
Event_worker_thread worker_thread;
worker_thread.run(thd, event);
my_thread_end();
return 0; // Can't return anything here
}
/**
Function that executes an event in a child thread. Setups the
environment for the event execution and cleans after that.
SYNOPSIS
Event_worker_thread::run()
thd Thread context
event The Event_queue_element_for_exec object to be processed
*/
void
Event_worker_thread::run(THD *thd, Event_queue_element_for_exec *event)
{
/* needs to be first for thread_stack */
char my_stack;
Event_job_data job_data;
bool res;
thd->thread_stack= &my_stack; // remember where our stack is
res= post_init_event_thread(thd);
DBUG_ENTER("Event_worker_thread::run");
DBUG_PRINT("info", ("Time is %ld, THD: 0x%lx", (long) my_time(0), (long) thd));
if (res)
goto end;
if ((res= db_repository->load_named_event(thd, event->dbname, event->name,
&job_data)))
{
DBUG_PRINT("error", ("Got error from load_named_event"));
goto end;
}
sql_print_information("Event Scheduler: "
"[%s].[%s.%s] started in thread %lu.",
job_data.definer.str,
job_data.dbname.str, job_data.name.str,
thd->thread_id);
thd->enable_slow_log= TRUE;
res= job_data.execute(thd, event->dropped);
print_warnings(thd, &job_data);
if (res)
sql_print_information("Event Scheduler: "
"[%s].[%s.%s] event execution failed.",
job_data.definer.str,
job_data.dbname.str, job_data.name.str);
else
sql_print_information("Event Scheduler: "
"[%s].[%s.%s] executed successfully in thread %lu.",
job_data.definer.str,
job_data.dbname.str, job_data.name.str,
thd->thread_id);
end:
DBUG_PRINT("info", ("Done with Event %s.%s", event->dbname.str,
event->name.str));
delete event;
deinit_event_thread(thd);
DBUG_VOID_RETURN;
}
Event_scheduler::Event_scheduler(Event_queue *queue_arg)
:state(INITIALIZED),
scheduler_thd(NULL),
queue(queue_arg),
mutex_last_locked_at_line(0),
mutex_last_unlocked_at_line(0),
mutex_last_locked_in_func("n/a"),
mutex_last_unlocked_in_func("n/a"),
mutex_scheduler_data_locked(FALSE),
waiting_on_cond(FALSE),
started_events(0)
{
pthread_mutex_init(&LOCK_scheduler_state, MY_MUTEX_INIT_FAST);
pthread_cond_init(&COND_state, NULL);
}
Event_scheduler::~Event_scheduler()
{
stop(); /* does nothing if not running */
pthread_mutex_destroy(&LOCK_scheduler_state);
pthread_cond_destroy(&COND_state);
}
/*
Starts the scheduler (again). Creates a new THD and passes it to
a forked thread. Does not wait for acknowledgement from the new
thread that it has started. Asynchronous starting. Most of the
needed initializations are done in the current thread to minimize
the chance of failure in the spawned thread.
SYNOPSIS
Event_scheduler::start()
RETURN VALUE
FALSE OK
TRUE Error (not reported)
*/
bool
Event_scheduler::start()
{
THD *new_thd= NULL;
bool ret= FALSE;
pthread_t th;
struct scheduler_param *scheduler_param_value;
DBUG_ENTER("Event_scheduler::start");
LOCK_DATA();
DBUG_PRINT("info", ("state before action %s", scheduler_states_names[state].str));
if (state > INITIALIZED)
goto end;
if (!(new_thd= new THD))
{
sql_print_error("Event Scheduler: Cannot initialize the scheduler thread");
ret= TRUE;
goto end;
}
pre_init_event_thread(new_thd);
new_thd->system_thread= SYSTEM_THREAD_EVENT_SCHEDULER;
new_thd->command= COM_DAEMON;
/*
We should run the event scheduler thread under the super-user privileges.
In particular, this is needed to be able to lock the mysql.event table
for writing when the server is running in the read-only mode.
*/
new_thd->security_ctx->master_access |= SUPER_ACL;
scheduler_param_value=
(struct scheduler_param *)my_malloc(sizeof(struct scheduler_param), MYF(0));
scheduler_param_value->thd= new_thd;
scheduler_param_value->scheduler= this;
scheduler_thd= new_thd;
DBUG_PRINT("info", ("Setting state go RUNNING"));
state= RUNNING;
DBUG_PRINT("info", ("Forking new thread for scheduler. THD: 0x%lx", (long) new_thd));
if (pthread_create(&th, &connection_attrib, event_scheduler_thread,
(void*)scheduler_param_value))
{
DBUG_PRINT("error", ("cannot create a new thread"));
state= INITIALIZED;
scheduler_thd= NULL;
ret= TRUE;
new_thd->proc_info= "Clearing";
DBUG_ASSERT(new_thd->net.buff != 0);
net_end(&new_thd->net);
pthread_mutex_lock(&LOCK_thread_count);
thread_count--;
thread_running--;
delete new_thd;
pthread_mutex_unlock(&LOCK_thread_count);
}
end:
UNLOCK_DATA();
DBUG_RETURN(ret);
}
/*
The main loop of the scheduler.
SYNOPSIS
Event_scheduler::run()
thd Thread
RETURN VALUE
FALSE OK
TRUE Error (Serious error)
*/
bool
Event_scheduler::run(THD *thd)
{
int res= FALSE;
DBUG_ENTER("Event_scheduler::run");
sql_print_information("Event Scheduler: scheduler thread started with id %lu",
thd->thread_id);
/*
Recalculate the values in the queue because there could have been stops
in executions of the scheduler and some times could have passed by.
*/
queue->recalculate_activation_times(thd);
while (is_running())
{
Event_queue_element_for_exec *event_name;
/* Gets a minimized version */
if (queue->get_top_for_execution_if_time(thd, &event_name))
{
sql_print_information("Event Scheduler: "
"Serious error during getting next "
"event to execute. Stopping");
break;
}
DBUG_PRINT("info", ("get_top_for_execution_if_time returned "
"event_name=0x%lx", (long) event_name));
if (event_name)
{
if ((res= execute_top(event_name)))
break;
}
else
{
DBUG_ASSERT(thd->killed);
DBUG_PRINT("info", ("job_data is NULL, the thread was killed"));
}
DBUG_PRINT("info", ("state=%s", scheduler_states_names[state].str));
}
LOCK_DATA();
deinit_event_thread(thd);
scheduler_thd= NULL;
state= INITIALIZED;
DBUG_PRINT("info", ("Signalling back to the stopper COND_state"));
pthread_cond_signal(&COND_state);
UNLOCK_DATA();
DBUG_RETURN(res);
}
/*
Creates a new THD instance and then forks a new thread, while passing
the THD pointer and job_data to it.
SYNOPSIS
Event_scheduler::execute_top()
RETURN VALUE
FALSE OK
TRUE Error (Serious error)
*/
bool
Event_scheduler::execute_top(Event_queue_element_for_exec *event_name)
{
THD *new_thd;
pthread_t th;
int res= 0;
DBUG_ENTER("Event_scheduler::execute_top");
if (!(new_thd= new THD()))
goto error;
pre_init_event_thread(new_thd);
new_thd->system_thread= SYSTEM_THREAD_EVENT_WORKER;
event_name->thd= new_thd;
DBUG_PRINT("info", ("Event %s@%s ready for start",
event_name->dbname.str, event_name->name.str));
/*
TODO: should use thread pool here, preferably with an upper limit
on number of threads: if too many events are scheduled for the
same time, starting all of them at once won't help them run truly
in parallel (because of the great amount of synchronization), so
we may as well execute them in sequence, keeping concurrency at a
reasonable level.
*/
/* Major failure */
if ((res= pthread_create(&th, &connection_attrib, event_worker_thread,
event_name)))
goto error;
++started_events;
DBUG_PRINT("info", ("Event is in THD: 0x%lx", (long) new_thd));
DBUG_RETURN(FALSE);
error:
DBUG_PRINT("error", ("Event_scheduler::execute_top() res: %d", res));
if (new_thd)
{
new_thd->proc_info= "Clearing";
DBUG_ASSERT(new_thd->net.buff != 0);
net_end(&new_thd->net);
pthread_mutex_lock(&LOCK_thread_count);
thread_count--;
thread_running--;
delete new_thd;
pthread_mutex_unlock(&LOCK_thread_count);
}
delete event_name;
DBUG_RETURN(TRUE);
}
/*
Checks whether the state of the scheduler is RUNNING
SYNOPSIS
Event_scheduler::is_running()
RETURN VALUE
TRUE RUNNING
FALSE Not RUNNING
*/
bool
Event_scheduler::is_running()
{
LOCK_DATA();
bool ret= (state == RUNNING);
UNLOCK_DATA();
return ret;
}
/**
Stops the scheduler (again). Waits for acknowledgement from the
scheduler that it has stopped - synchronous stopping.
Already running events will not be stopped. If the user needs
them stopped manual intervention is needed.
SYNOPSIS
Event_scheduler::stop()
RETURN VALUE
FALSE OK
TRUE Error (not reported)
*/
bool
Event_scheduler::stop()
{
THD *thd= current_thd;
DBUG_ENTER("Event_scheduler::stop");
DBUG_PRINT("enter", ("thd: 0x%lx", (long) thd));
LOCK_DATA();
DBUG_PRINT("info", ("state before action %s", scheduler_states_names[state].str));
if (state != RUNNING)
goto end;
/* Guarantee we don't catch spurious signals */
do {
DBUG_PRINT("info", ("Waiting for COND_started_or_stopped from "
"the scheduler thread. Current value of state is %s . "
"workers count=%d", scheduler_states_names[state].str,
workers_count()));
/*
NOTE: We don't use kill_one_thread() because it can't kill COM_DEAMON
threads. In addition, kill_one_thread() requires THD but during shutdown
current_thd is NULL. Hence, if kill_one_thread should be used it has to
be modified to kill also daemons, by adding a flag, and also we have to
create artificial THD here. To save all this work, we just do what
kill_one_thread() does to kill a thread. See also sql_repl.cc for similar
usage.
*/
state= STOPPING;
DBUG_PRINT("info", ("Scheduler thread has id %lu",
scheduler_thd->thread_id));
/* Lock from delete */
pthread_mutex_lock(&scheduler_thd->LOCK_delete);
/* This will wake up the thread if it waits on Queue's conditional */
sql_print_information("Event Scheduler: Killing the scheduler thread, "
"thread id %lu",
scheduler_thd->thread_id);
scheduler_thd->awake(THD::KILL_CONNECTION);
pthread_mutex_unlock(&scheduler_thd->LOCK_delete);
/* thd could be 0x0, when shutting down */
sql_print_information("Event Scheduler: "
"Waiting for the scheduler thread to reply");
COND_STATE_WAIT(thd, NULL, "Waiting scheduler to stop");
} while (state == STOPPING);
DBUG_PRINT("info", ("Scheduler thread has cleaned up. Set state to INIT"));
sql_print_information("Event Scheduler: Stopped");
end:
UNLOCK_DATA();
DBUG_RETURN(FALSE);
}
/*
Returns the number of living event worker threads.
SYNOPSIS
Event_scheduler::workers_count()
*/
uint
Event_scheduler::workers_count()
{
THD *tmp;
uint count= 0;
DBUG_ENTER("Event_scheduler::workers_count");
pthread_mutex_lock(&LOCK_thread_count); // For unlink from list
I_List_iterator<THD> it(threads);
while ((tmp=it++))
if (tmp->system_thread == SYSTEM_THREAD_EVENT_WORKER)
++count;
pthread_mutex_unlock(&LOCK_thread_count);
DBUG_PRINT("exit", ("%d", count));
DBUG_RETURN(count);
}
/*
Auxiliary function for locking LOCK_scheduler_state. Used
by the LOCK_DATA macro.
SYNOPSIS
Event_scheduler::lock_data()
func Which function is requesting mutex lock
line On which line mutex lock is requested
*/
void
Event_scheduler::lock_data(const char *func, uint line)
{
DBUG_ENTER("Event_scheduler::lock_data");
DBUG_PRINT("enter", ("func=%s line=%u", func, line));
pthread_mutex_lock(&LOCK_scheduler_state);
mutex_last_locked_in_func= func;
mutex_last_locked_at_line= line;
mutex_scheduler_data_locked= TRUE;
DBUG_VOID_RETURN;
}
/*
Auxiliary function for unlocking LOCK_scheduler_state. Used
by the UNLOCK_DATA macro.
SYNOPSIS
Event_scheduler::unlock_data()
func Which function is requesting mutex unlock
line On which line mutex unlock is requested
*/
void
Event_scheduler::unlock_data(const char *func, uint line)
{
DBUG_ENTER("Event_scheduler::unlock_data");
DBUG_PRINT("enter", ("func=%s line=%u", func, line));
mutex_last_unlocked_at_line= line;
mutex_scheduler_data_locked= FALSE;
mutex_last_unlocked_in_func= func;
pthread_mutex_unlock(&LOCK_scheduler_state);
DBUG_VOID_RETURN;
}
/*
Wrapper for pthread_cond_wait/timedwait
SYNOPSIS
Event_scheduler::cond_wait()
thd Thread (Could be NULL during shutdown procedure)
abstime If not null then call pthread_cond_timedwait()
msg Message for thd->proc_info
func Which function is requesting cond_wait
line On which line cond_wait is requested
*/
void
Event_scheduler::cond_wait(THD *thd, struct timespec *abstime, const char* msg,
const char *func, uint line)
{
DBUG_ENTER("Event_scheduler::cond_wait");
waiting_on_cond= TRUE;
mutex_last_unlocked_at_line= line;
mutex_scheduler_data_locked= FALSE;
mutex_last_unlocked_in_func= func;
if (thd)
thd->enter_cond(&COND_state, &LOCK_scheduler_state, msg);
DBUG_PRINT("info", ("pthread_cond_%swait", abstime? "timed":""));
if (!abstime)
pthread_cond_wait(&COND_state, &LOCK_scheduler_state);
else
pthread_cond_timedwait(&COND_state, &LOCK_scheduler_state, abstime);
if (thd)
{
/*
This will free the lock so we need to relock. Not the best thing to
do but we need to obey cond_wait()
*/
thd->exit_cond("");
LOCK_DATA();
}
mutex_last_locked_in_func= func;
mutex_last_locked_at_line= line;
mutex_scheduler_data_locked= TRUE;
waiting_on_cond= FALSE;
DBUG_VOID_RETURN;
}
/*
Dumps the internal status of the scheduler
SYNOPSIS
Event_scheduler::dump_internal_status()
*/
void
Event_scheduler::dump_internal_status()
{
DBUG_ENTER("Event_scheduler::dump_internal_status");
puts("");
puts("Event scheduler status:");
printf("State : %s\n", scheduler_states_names[state].str);
printf("Thread id : %lu\n", scheduler_thd? scheduler_thd->thread_id : 0);
printf("LLA : %s:%u\n", mutex_last_locked_in_func,
mutex_last_locked_at_line);
printf("LUA : %s:%u\n", mutex_last_unlocked_in_func,
mutex_last_unlocked_at_line);
printf("WOC : %s\n", waiting_on_cond? "YES":"NO");
printf("Workers : %u\n", workers_count());
printf("Executed : %lu\n", (ulong) started_events);
printf("Data locked: %s\n", mutex_scheduler_data_locked ? "YES":"NO");
DBUG_VOID_RETURN;
}
/**
@} (End of group Event_Scheduler)
*/
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