Mini Shell
#ifndef MYSQL_SERVICE_DEBUG_SYNC_INCLUDED
/* Copyright (c) 2009, 2010, Oracle and/or its affiliates.
Copyright (c) 2012, Monty Program Ab
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */
/**
@file
== Debug Sync Facility ==
The Debug Sync Facility allows placement of synchronization points in
the server code by using the DEBUG_SYNC macro:
open_tables(...)
DEBUG_SYNC(thd, "after_open_tables");
lock_tables(...)
When activated, a sync point can
- Emit a signal and/or
- Wait for a signal
Nomenclature:
- signal: A value of a global variable that persists
until overwritten by a new signal. The global
variable can also be seen as a "signal post"
or "flag mast". Then the signal is what is
attached to the "signal post" or "flag mast".
- emit a signal: Assign the value (the signal) to the global
variable ("set a flag") and broadcast a
global condition to wake those waiting for
a signal.
- wait for a signal: Loop over waiting for the global condition until
the global value matches the wait-for signal.
By default, all sync points are inactive. They do nothing (except to
burn a couple of CPU cycles for checking if they are active).
A sync point becomes active when an action is requested for it.
To do so, put a line like this in the test case file:
SET DEBUG_SYNC= 'after_open_tables SIGNAL opened WAIT_FOR flushed';
This activates the sync point 'after_open_tables'. It requests it to
emit the signal 'opened' and wait for another thread to emit the signal
'flushed' when the thread's execution runs through the sync point.
For every sync point there can be one action per thread only. Every
thread can request multiple actions, but only one per sync point. In
other words, a thread can activate multiple sync points.
Here is an example how to activate and use the sync points:
--connection conn1
SET DEBUG_SYNC= 'after_open_tables SIGNAL opened WAIT_FOR flushed';
send INSERT INTO t1 VALUES(1);
--connection conn2
SET DEBUG_SYNC= 'now WAIT_FOR opened';
SET DEBUG_SYNC= 'after_abort_locks SIGNAL flushed';
FLUSH TABLE t1;
When conn1 runs through the INSERT statement, it hits the sync point
'after_open_tables'. It notices that it is active and executes its
action. It emits the signal 'opened' and waits for another thread to
emit the signal 'flushed'.
conn2 waits immediately at the special sync point 'now' for another
thread to emit the 'opened' signal.
A signal remains in effect until it is overwritten. If conn1 signals
'opened' before conn2 reaches 'now', conn2 will still find the 'opened'
signal. It does not wait in this case.
When conn2 reaches 'after_abort_locks', it signals 'flushed', which lets
conn1 awake.
Normally the activation of a sync point is cleared when it has been
executed. Sometimes it is necessary to keep the sync point active for
another execution. You can add an execute count to the action:
SET DEBUG_SYNC= 'name SIGNAL sig EXECUTE 3';
This sets the signal point's activation counter to 3. Each execution
decrements the counter. After the third execution the sync point
becomes inactive.
One of the primary goals of this facility is to eliminate sleeps from
the test suite. In most cases it should be possible to rewrite test
cases so that they do not need to sleep. (But this facility cannot
synchronize multiple processes.) However, to support test development,
and as a last resort, sync point waiting times out. There is a default
timeout, but it can be overridden:
SET DEBUG_SYNC= 'name WAIT_FOR sig TIMEOUT 10 EXECUTE 2';
TIMEOUT 0 is special: If the signal is not present, the wait times out
immediately.
When a wait timed out (even on TIMEOUT 0), a warning is generated so
that it shows up in the test result.
You can throw an error message and kill the query when a synchronization
point is hit a certain number of times:
SET DEBUG_SYNC= 'name HIT_LIMIT 3';
Or combine it with signal and/or wait:
SET DEBUG_SYNC= 'name SIGNAL sig EXECUTE 2 HIT_LIMIT 3';
Here the first two hits emit the signal, the third hit returns the error
message and kills the query.
For cases where you are not sure that an action is taken and thus
cleared in any case, you can force to clear (deactivate) a sync point:
SET DEBUG_SYNC= 'name CLEAR';
If you want to clear all actions and clear the global signal, use:
SET DEBUG_SYNC= 'RESET';
This is the only way to reset the global signal to an empty string.
For testing of the facility itself you can execute a sync point just
as if it had been hit:
SET DEBUG_SYNC= 'name TEST';
=== Formal Syntax ===
The string to "assign" to the DEBUG_SYNC variable can contain:
{RESET |
<sync point name> TEST |
<sync point name> CLEAR |
<sync point name> {{SIGNAL <signal name> |
WAIT_FOR <signal name> [TIMEOUT <seconds>]}
[EXECUTE <count>] &| HIT_LIMIT <count>}
Here '&|' means 'and/or'. This means that one of the sections
separated by '&|' must be present or both of them.
=== Activation/Deactivation ===
The facility is an optional part of the MySQL server.
It is enabled in a debug server by default.
./configure --enable-debug-sync
The Debug Sync Facility, when compiled in, is disabled by default. It
can be enabled by a mysqld command line option:
--debug-sync-timeout[=default_wait_timeout_value_in_seconds]
'default_wait_timeout_value_in_seconds' is the default timeout for the
WAIT_FOR action. If set to zero, the facility stays disabled.
The facility is enabled by default in the test suite, but can be
disabled with:
mysql-test-run.pl ... --debug-sync-timeout=0 ...
Likewise the default wait timeout can be set:
mysql-test-run.pl ... --debug-sync-timeout=10 ...
The command line option influences the readable value of the system
variable 'debug_sync'.
* If the facility is not compiled in, the system variable does not exist.
* If --debug-sync-timeout=0 the value of the variable reads as "OFF".
* Otherwise the value reads as "ON - current signal: " followed by the
current signal string, which can be empty.
The readable variable value is the same, regardless if read as global
or session value.
Setting the 'debug-sync' system variable requires 'SUPER' privilege.
You can never read back the string that you assigned to the variable,
unless you assign the value that the variable does already have. But
that would give a parse error. A syntactically correct string is
parsed into a debug sync action and stored apart from the variable value.
=== Implementation ===
Pseudo code for a sync point:
#define DEBUG_SYNC(thd, sync_point_name)
if (unlikely(opt_debug_sync_timeout))
debug_sync(thd, STRING_WITH_LEN(sync_point_name))
The sync point performs a binary search in a sorted array of actions
for this thread.
The SET DEBUG_SYNC statement adds a requested action to the array or
overwrites an existing action for the same sync point. When it adds a
new action, the array is sorted again.
=== A typical synchronization pattern ===
There are quite a few places in MySQL, where we use a synchronization
pattern like this:
mysql_mutex_lock(&mutex);
thd->enter_cond(&condition_variable, &mutex, new_message);
#if defined(ENABLE_DEBUG_SYNC)
if (!thd->killed && !end_of_wait_condition)
DEBUG_SYNC(thd, "sync_point_name");
#endif
while (!thd->killed && !end_of_wait_condition)
mysql_cond_wait(&condition_variable, &mutex);
thd->exit_cond(old_message);
Here some explanations:
thd->enter_cond() is used to register the condition variable and the
mutex in thd->mysys_var. This is done to allow the thread to be
interrupted (killed) from its sleep. Another thread can find the
condition variable to signal and mutex to use for synchronization in
this thread's THD::mysys_var.
thd->enter_cond() requires the mutex to be acquired in advance.
thd->exit_cond() unregisters the condition variable and mutex and
releases the mutex.
If you want to have a Debug Sync point with the wait, please place it
behind enter_cond(). Only then you can safely decide, if the wait will
be taken. Also you will have THD::proc_info correct when the sync
point emits a signal. DEBUG_SYNC sets its own proc_info, but restores
the previous one before releasing its internal mutex. As soon as
another thread sees the signal, it does also see the proc_info from
before entering the sync point. In this case it will be "new_message",
which is associated with the wait that is to be synchronized.
In the example above, the wait condition is repeated before the sync
point. This is done to skip the sync point, if no wait takes place.
The sync point is before the loop (not inside the loop) to have it hit
once only. It is possible that the condition variable is signaled
multiple times without the wait condition to be true.
A bit off-topic: At some places, the loop is taken around the whole
synchronization pattern:
while (!thd->killed && !end_of_wait_condition)
{
mysql_mutex_lock(&mutex);
thd->enter_cond(&condition_variable, &mutex, new_message);
if (!thd->killed [&& !end_of_wait_condition])
{
[DEBUG_SYNC(thd, "sync_point_name");]
mysql_cond_wait(&condition_variable, &mutex);
}
thd->exit_cond(old_message);
}
Note that it is important to repeat the test for thd->killed after
enter_cond(). Otherwise the killing thread may kill this thread after
it tested thd->killed in the loop condition and before it registered
the condition variable and mutex in enter_cond(). In this case, the
killing thread does not know that this thread is going to wait on a
condition variable. It would just set THD::killed. But if we would not
test it again, we would go asleep though we are killed. If the killing
thread would kill us when we are after the second test, but still
before sleeping, we hold the mutex, which is registered in mysys_var.
The killing thread would try to acquire the mutex before signaling
the condition variable. Since the mutex is only released implicitly in
mysql_cond_wait(), the signaling happens at the right place. We
have a safe synchronization.
=== Co-work with the DBUG facility ===
When running the MySQL test suite with the --debug-dbug command line
option, the Debug Sync Facility writes trace messages to the DBUG
trace. The following shell commands proved very useful in extracting
relevant information:
egrep 'query:|debug_sync_exec:' mysql-test/var/log/mysqld.1.trace
It shows all executed SQL statements and all actions executed by
synchronization points.
Sometimes it is also useful to see, which synchronization points have
been run through (hit) with or without executing actions. Then add
"|debug_sync_point:" to the egrep pattern.
=== Further reading ===
For a discussion of other methods to synchronize threads see
http://forge.mysql.com/wiki/MySQL_Internals_Test_Synchronization
For complete syntax tests, functional tests, and examples see the test
case debug_sync.test.
See also http://forge.mysql.com/worklog/task.php?id=4259
*/
#ifndef MYSQL_ABI_CHECK
#include <stdlib.h>
#endif
#ifdef __cplusplus
extern "C" {
#endif
#ifdef MYSQL_DYNAMIC_PLUGIN
extern void (*debug_sync_service)(MYSQL_THD, const char *, size_t);
#else
#define debug_sync_service debug_sync_C_callback_ptr
extern void (*debug_sync_C_callback_ptr)(MYSQL_THD, const char *, size_t);
#endif
#ifdef ENABLED_DEBUG_SYNC
#define DEBUG_SYNC(thd, name) \
do { \
if (debug_sync_service) \
debug_sync_service(thd, STRING_WITH_LEN(name)); \
} while(0)
#define DEBUG_SYNC_C_IF_THD(thd, name) \
do { \
if (debug_sync_service && thd) \
debug_sync_service((MYSQL_THD) thd, STRING_WITH_LEN(name)); \
} while(0)
#else
#define DEBUG_SYNC(thd,name) do { } while(0)
#define DEBUG_SYNC_C_IF_THD(thd, _sync_point_name_) do { } while(0)
#endif /* defined(ENABLED_DEBUG_SYNC) */
/* compatibility macro */
#define DEBUG_SYNC_C(name) DEBUG_SYNC(NULL, name)
#ifdef __cplusplus
}
#endif
#define MYSQL_SERVICE_DEBUG_SYNC_INCLUDED
#endif
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