Table of Contents
This chapter describes the various replication features provided by MySQL. It introduces replication concepts, shows how to set up replication servers, and serves as a reference to the available replication options. It also provides a list of frequently asked questions (with answers), and troubleshooting advice for solving replication problems.
MySQL Enterprise The MySQL Network Monitoring and Advisory Service provides numerous advisors that provide immediate feedback about replication-related problems. For more information see http://www.mysql.com/products/enterprise/advisors.html.
For a description of the syntax of replication-related SQL statements, see Section 13.6, “Replication Statements”.
MySQL features support for one-way, asynchronous replication, in which one server acts as the master, while one or more other servers act as slaves. This is in contrast to the synchronous replication which is a characteristic of MySQL Cluster (see Chapter 15, MySQL Cluster).
In single-master replication, the master server writes updates to its binary log files and maintains an index of those files to keep track of log rotation. The binary log files serve as a record of updates to be sent to any slave servers. When a slave connects to its master, it informs the master of the position up to which the slave read the logs at its last successful update. The slave receives any updates that have taken place since that time, and then blocks and waits for the master to notify it of new updates.
A slave server can itself serve as a master if you want to set up chained replication servers.
Multiple-master replication is possible, but raises issues not present in single-master replication. See Section 6.13, “Auto-Increment in Multiple-Master Replication”.
When you are using replication, all updates to the tables that are replicated should be performed on the master server. Otherwise, you must always be careful to avoid conflicts between updates that users make to tables on the master and updates that they make to tables on the slave.
Replication offers benefits for robustness, speed, and system administration:
Robustness is increased with a master/slave setup. In the event of problems with the master, you can switch to the slave as a backup.
Better response time for clients can be achieved by splitting
the load for processing client queries between the master and
slave servers. SELECT queries may be sent
to the slave to reduce the query processing load of the
master. Statements that modify data should still be sent to
the master so that the master and slave do not get out of
synchrony. This load-balancing strategy is effective if
non-updating queries dominate, but that is the normal case.
Another benefit of using replication is that you can perform database backups using a slave server without disturbing the master. The master continues to process updates while the backup is being made. See Section 5.9.1, “Database Backups”.
MySQL replication is based on the master server keeping track of all changes to your databases (updates, deletes, and so on) in its binary logs. Therefore, to use replication, you must enable binary logging on the master server. See Section 5.11.3, “The Binary Log”.
Each slave server receives from the master the saved updates that the master has recorded in its binary log, so that the slave can execute the same updates on its copy of the data.
It is extremely important to realize that the binary log is simply a record starting from the fixed point in time at which you enable binary logging. Any slaves that you set up need copies of the databases on your master as they existed at the moment you enabled binary logging on the master. If you start your slaves with databases that are not in the same state as those on the master when the binary log was started, your slaves are quite likely to fail.
After the slave has been set up with a copy of the master's data,
it connects to the master and waits for updates to process. If the
master fails, or the slave loses connectivity with your master,
the slave keeps trying to connect periodically until it is able to
resume listening for updates. The
--master-connect-retry option controls the retry
interval. The default is 60 seconds.
Each slave keeps track of where it left off when it last read from its master server. The master has no knowledge of how many slaves it has or which ones are up to date at any given time.
MySQL replication capabilities are implemented using three threads
(one on the master server and two on the slave). When a
START SLAVE statement is issued on a slave
server, the slave creates an I/O thread, which connects to the
master and asks it to send the updates recorded in its binary
logs. The master creates a thread to send the binary log contents
to the slave. This thread can be identified as the Binlog
Dump thread in the output of SHOW
PROCESSLIST on the master. The slave I/O thread reads
the updates that the master Binlog Dump thread
sends and copies them to local files, known as relay
logs, in the slave's data directory. The third thread
is the SQL thread, which the slave creates to read the relay logs
and to execute the updates they contain.
In the preceding description, there are three threads per master/slave connection. A master that has multiple slaves creates one thread for each currently-connected slave, and each slave has its own I/O and SQL threads.
The slave uses two threads so that reading updates from the master and executing them can be separated into two independent tasks. Thus, the task of reading statements is not slowed down if statement execution is slow. For example, if the slave server has not been running for a while, its I/O thread can quickly fetch all the binary log contents from the master when the slave starts, even if the SQL thread lags far behind. If the slave stops before the SQL thread has executed all the fetched statements, the I/O thread has at least fetched everything so that a safe copy of the statements is stored locally in the slave's relay logs, ready for execution the next time that the slave starts. This enables the master server to purge its binary logs sooner because it no longer needs to wait for the slave to fetch their contents.
The SHOW PROCESSLIST statement provides
information that tells you what is happening on the master and on
the slave regarding replication. The following example illustrates
how the three threads show up in the output from SHOW
PROCESSLIST.
On the master server, the output from SHOW
PROCESSLIST looks like this:
mysql> SHOW PROCESSLIST\G
*************************** 1. row ***************************
Id: 2
User: root
Host: localhost:32931
db: NULL
Command: Binlog Dump
Time: 94
State: Has sent all binlog to slave; waiting for binlog to
be updated
Info: NULL
Here, thread 2 is a Binlog Dump replication
thread for a connected slave. The State
information indicates that all outstanding updates have been sent
to the slave and that the master is waiting for more updates to
occur. If you see no Binlog Dump threads on a
master server, this means that replication is not running —
that is, that no slaves are currently connected.
On the slave server, the output from SHOW
PROCESSLIST looks like this:
mysql> SHOW PROCESSLIST\G
*************************** 1. row ***************************
Id: 10
User: system user
Host:
db: NULL
Command: Connect
Time: 11
State: Waiting for master to send event
Info: NULL
*************************** 2. row ***************************
Id: 11
User: system user
Host:
db: NULL
Command: Connect
Time: 11
State: Has read all relay log; waiting for the slave I/O
thread to update it
Info: NULL
This information indicates that thread 10 is the I/O thread that
is communicating with the master server, and thread 11 is the SQL
thread that is processing the updates stored in the relay logs. At
the time that the SHOW PROCESSLIST was run,
both threads were idle, waiting for further updates.
The value in the Time column can show how late
the slave is compared to the master. See
Section 6.10, “Replication FAQ”.
The following list shows the most common states you may see in
the State column for the master's
Binlog Dump thread. If you see no
Binlog Dump threads on a master server, this
means that replication is not running — that is, that no
slaves are currently connected.
Sending binlog event to slave
Binary logs consist of events, where an event is usually an update plus some other information. The thread has read an event from the binary log and is now sending it to the slave.
Finished reading one binlog; switching to next
binlog
The thread has finished reading a binary log file and is opening the next one to send to the slave.
Has sent all binlog to slave; waiting for binlog to
be updated
The thread has read all outstanding updates from the binary logs and sent them to the slave. The thread is now idle, waiting for new events to appear in the binary log resulting from new updates occurring on the master.
Waiting to finalize termination
A very brief state that occurs as the thread is stopping.
The following list shows the most common states you see in the
State column for a slave server I/O thread.
This state also appears in the Slave_IO_State
column displayed by SHOW SLAVE STATUS, so you
can get a good view of what is happening by using that
statement.
Connecting to master
The thread is attempting to connect to the master.
Checking master version
A state that occurs very briefly, after the connection to the master is established.
Registering slave on master
A state that occurs very briefly after the connection to the master is established.
Requesting binlog dump
A state that occurs very briefly, after the connection to the master is established. The thread sends to the master a request for the contents of its binary logs, starting from the requested binary log filename and position.
Waiting to reconnect after a failed binlog dump
request
If the binary log dump request failed (due to
disconnection), the thread goes into this state while it
sleeps, then tries to reconnect periodically. The interval
between retries can be specified using the
--master-connect-retry option.
Reconnecting after a failed binlog dump
request
The thread is trying to reconnect to the master.
Waiting for master to send event
The thread has connected to the master and is waiting for
binary log events to arrive. This can last for a long time
if the master is idle. If the wait lasts for
slave_net_timeout seconds, a timeout
occurs. At that point, the thread considers the connection
to be broken and makes an attempt to reconnect.
Queueing master event to the relay log
The thread has read an event and is copying it to the relay log so that the SQL thread can process it.
Waiting to reconnect after a failed master event
read
An error occurred while reading (due to disconnection). The
thread is sleeping for
master-connect-retry seconds before
attempting to reconnect.
Reconnecting after a failed master event
read
The thread is trying to reconnect to the master. When
connection is established again, the state becomes
Waiting for master to send event.
Waiting for the slave SQL thread to free enough
relay log space
You are using a non-zero
relay_log_space_limit value, and the
relay logs have grown large enough that their combined size
exceeds this value. The I/O thread is waiting until the SQL
thread frees enough space by processing relay log contents
so that it can delete some relay log files.
Waiting for slave mutex on exit
A state that occurs briefly as the thread is stopping.
The following list shows the most common states you may see in
the State column for a slave server SQL
thread:
Reading event from the relay log
The thread has read an event from the relay log so that the event can be processed.
Has read all relay log; waiting for the slave I/O
thread to update it
The thread has processed all events in the relay log files, and is now waiting for the I/O thread to write new events to the relay log.
Waiting for slave mutex on exit
A very brief state that occurs as the thread is stopping.
The State column for the I/O thread may also
show the text of a statement. This indicates that the thread has
read an event from the relay log, extracted the statement from
it, and is executing it.
By default, relay logs filenames have the form
host_name-relay-bin.nnnnnnhost_name is the name of the
slave server host and nnnnnn is a
sequence number. Successive relay log files are created using
successive sequence numbers, beginning with
000001. The slave uses an index file to track
the relay log files currently in use. The default relay log
index filename is
host_name-relay-bin.index--relay-log and
--relay-log-index server options. See
Section 6.8, “Replication Startup Options”.
Relay logs have the same format as binary logs and can be read
using mysqlbinlog. The SQL thread
automatically deletes each relay log file as soon as it has
executed all events in the file and no longer needs it. There is
no explicit mechanism for deleting relay logs because the SQL
thread takes care of doing so. However, FLUSH
LOGS rotates relay logs, which influences when the SQL
thread deletes them.
A slave server creates a new relay log file under the following conditions:
Each time the I/O thread starts.
When the logs are flushed; for example, with FLUSH
LOGS or mysqladmin flush-logs.
When the size of the current relay log file becomes too large. The meaning of “too large” is determined as follows:
If the value of max_relay_log_size is
greater than 0, that is the maximum relay log file size.
If the value of max_relay_log_size is
0, max_binlog_size determines the
maximum relay log file size.
A slave replication server creates two additional small files in
the data directory. These status files are
named master.info and
relay-log.info by default. Their names can
be changed by using the --master-info-file and
--relay-log-info-file options. See
Section 6.8, “Replication Startup Options”.
The two status files contain information like that shown in the
output of the SHOW SLAVE STATUS statement,
which is discussed in Section 13.6.2, “SQL Statements for Controlling Slave Servers”.
Because the status files are stored on disk, they survive a
slave server's shutdown. The next time the slave starts up, it
reads the two files to determine how far it has proceeded in
reading binary logs from the master and in processing its own
relay logs.
The I/O thread updates the master.info
file. The following table shows the correspondence between the
lines in the file and the columns displayed by SHOW
SLAVE STATUS.
| Line | Description |
| 1 | Number of lines in the file |
| 2 | Master_Log_File |
| 3 | Read_Master_Log_Pos |
| 4 | Master_Host |
| 5 | Master_User |
| 6 | Password (not shown by SHOW SLAVE STATUS) |
| 7 | Master_Port |
| 8 | Connect_Retry |
| 9 | Master_SSL_Allowed |
| 10 | Master_SSL_CA_File |
| 11 | Master_SSL_CA_Path |
| 12 | Master_SSL_Cert |
| 13 | Master_SSL_Cipher |
| 14 | Master_SSL_Key |
The SQL thread updates the relay-log.info
file. The following table shows the correspondence between the
lines in the file and the columns displayed by SHOW
SLAVE STATUS.
| Line | Description |
| 1 | Relay_Log_File |
| 2 | Relay_Log_Pos |
| 3 | Relay_Master_Log_File |
| 4 | Exec_Master_Log_Pos |
The contents of the relay-log.info file and
the states shown by the SHOW SLAVE STATES
command may not match if the relay-log.info
file has not been flushed to disk. Ideally, you should only view
relay-log.info on a slave that is offline
(i.e. mysqld is not running). For a running
system, SHOW SLAVE STATUS should be used.
When you back up the slave's data, you should back up these two
status files as well, along with the relay log files. They are
needed to resume replication after you restore the slave's data.
If you lose the relay logs but still have the
relay-log.info file, you can check it to
determine how far the SQL thread has executed in the master
binary logs. Then you can use CHANGE MASTER
TO with the MASTER_LOG_FILE and
MASTER_LOG_POS options to tell the slave to
re-read the binary logs from that point. Of course, this
requires that the binary logs still exist on the master server.
If your slave is subject to replicating LOAD DATA
INFILE statements, you should also back up any
SQL_LOAD-* files that exist in the
directory that the slave uses for this purpose. The slave needs
these files to resume replication of any interrupted
LOAD DATA INFILE operations. The directory
location is specified using the
--slave-load-tmpdir option. If this option is
not specified, the directory location is the value of the
tmpdir system variable.
This section briefly describes how to set up complete replication of a MySQL server. It assumes that you want to replicate all databases on the master and have not previously configured replication. You must shut down your master server briefly to complete the steps outlined here.
This procedure is written in terms of setting up a single slave, but you can repeat it to set up multiple slaves.
Although this method is the most straightforward way to set up a slave, it is not the only one. For example, if you have a snapshot of the master's data, and the master already has its server ID set and binary logging enabled, you can set up a slave without shutting down the master or even blocking updates to it. For more details, please see Section 6.10, “Replication FAQ”.
If you want to administer a MySQL replication setup, we suggest that you read this entire chapter through and try all statements mentioned in Section 13.6.1, “SQL Statements for Controlling Master Servers”, and Section 13.6.2, “SQL Statements for Controlling Slave Servers”. You should also familiarize yourself with the replication startup options described in Section 6.8, “Replication Startup Options”.
Note: This procedure and some of
the replication SQL statements shown in later sections require the
SUPER privilege.
Make sure that the versions of MySQL installed on the master and slave are compatible according to the table shown in Section 6.5, “Replication Compatibility Between MySQL Versions”. Ideally, you should use the most recent version of MySQL on both master and slave.
If you encounter a problem, please do not report it as a bug until you have verified that the problem is present in the latest MySQL release.
Set up an account on the master server that the slave server
can use to connect. This account must be given the
REPLICATION SLAVE privilege. If the account
is used only for replication (which is recommended), you don't
need to grant any additional privileges.
MySQL Enterprise
Subscribers to the MySQL Network Monitoring and Advisory
Service are quickly notified if there is a replication
master and no account with the REPLICATION
SLAVE privilege. For more information see
http://www.mysql.com/products/enterprise/advisors.html.
Suppose that your domain is mydomain.com
and that you want to create an account with a username of
repl such that slave servers can use the
account to access the master server from any host in your
domain using a password of slavepass. To
create the account, use this GRANT
statement:
mysql>GRANT REPLICATION SLAVE ON *.*->TO 'repl'@'%.mydomain.com' IDENTIFIED BY 'slavepass';
For additional information about setting up user accounts and privileges, see Section 5.8, “MySQL User Account Management”.
Flush all the tables and block write statements by executing a
FLUSH TABLES WITH READ LOCK statement:
mysql> FLUSH TABLES WITH READ LOCK;
For InnoDB tables, note that FLUSH
TABLES WITH READ LOCK also blocks
COMMIT operations. When you have acquired a
global read lock, you can start a filesystem snapshot of your
InnoDB tables. Internally (inside the
InnoDB storage engine) the snapshot won't
be consistent (because the InnoDB caches
are not flushed), but this is not a cause for concern, because
InnoDB resolves this at startup and
delivers a consistent result. This means that
InnoDB can perform crash recovery when
started on this snapshot, without corruption. However, there
is no way to stop the MySQL server while insuring a consistent
snapshot of your InnoDB tables.
Leave running the client from which you issue the
FLUSH TABLES statement so that the read
lock remains in effect. (If you exit the client, the lock is
released.) Then take a snapshot of the data on your master
server.
The easiest way to create a snapshot is to use an archiving program to make a binary backup of the databases in your master's data directory. For example, use tar on Unix, or PowerArchiver, WinRAR, WinZip, or any similar software on Windows. To use tar to create an archive that includes all databases, change location into the master server's data directory, then execute this command:
shell> tar -cvf /tmp/mysql-snapshot.tar .
If you want the archive to include only a database called
this_db, use this command instead:
shell> tar -cvf /tmp/mysql-snapshot.tar ./this_db
Then copy the archive file to the /tmp
directory on the slave server host. On that machine, change
location into the slave's data directory, and unpack the
archive file using this command:
shell> tar -xvf /tmp/mysql-snapshot.tar
You may not want to replicate the mysql
database if the slave server has a different set of user
accounts from those that exist on the master. In this case,
you should exclude it from the archive. You also need not
include any log files in the archive, or the
master.info or
relay-log.info files.
While the read lock placed by FLUSH TABLES WITH READ
LOCK is in effect, read the value of the current
binary log name and offset on the master:
mysql > SHOW MASTER STATUS;
+---------------+----------+--------------+------------------+
| File | Position | Binlog_Do_DB | Binlog_Ignore_DB |
+---------------+----------+--------------+------------------+
| mysql-bin.003 | 73 | test | manual,mysql |
+---------------+----------+--------------+------------------+
The File column shows the name of the log
and Position shows the offset within the
file. In this example, the binary log file is
mysql-bin.003 and the offset is 73. Record
these values. You need them later when you are setting up the
slave. They represent the replication coordinates at which the
slave should begin processing new updates from the master.
If the master has been running previously without binary
logging enabled, the log name and position values displayed by
SHOW MASTER STATUS or mysqldump
--master-data will be empty. In that case, the
values that you need to use later when specifying the slave's
log file and position are the empty string
('') and 4.
After you have taken the snapshot and recorded the log name and offset, you can re-enable write activity on the master:
mysql> UNLOCK TABLES;
If you are using InnoDB tables, ideally you
should use the InnoDB Hot
Backup tool, which takes a consistent snapshot
without acquiring any locks on the master server, and records
the log name and offset corresponding to the snapshot to be
later used on the slave. Hot Backup is an
additional non-free (commercial) tool that is not included in
the standard MySQL distribution. See the
InnoDB Hot Backup home
page at http://www.innodb.com/manual.php for
detailed information.
Without the Hot Backup tool, the quickest
way to take a binary snapshot of InnoDB
tables is to shut down the master server and copy the
InnoDB data files, log files, and table
format files (.frm files). To record the
current log file name and offset, you should issue the
following statements before you shut down the server:
mysql>FLUSH TABLES WITH READ LOCK;mysql>SHOW MASTER STATUS;
Then record the log name and the offset from the output of
SHOW MASTER STATUS as was shown earlier.
After recording the log name and the offset, shut down the
server without unlocking the tables to
make sure that the server goes down with the snapshot
corresponding to the current log file and offset:
shell> mysqladmin -u root shutdown
An alternative that works for both MyISAM
and InnoDB tables is to take an SQL dump of
the master instead of a binary copy as described in the
preceding discussion. For this, you can use mysqldump
--master-data on your master and later load the SQL
dump file into your slave. However, this is slower than doing
a binary copy.
Make sure that the [mysqld] section of the
my.cnf file on the master host includes a
log-bin option. The section should also
have a
server-id=
option, where master_idmaster_id must be a
positive integer value from 1 to
232 – 1. For example:
[mysqld] log-bin=mysql-bin server-id=1
If those options are not present, add them and restart the server. The server cannot act as a replication master unless binary logging is enabled.
Note: For the greatest
possible durability and consistency in a replication setup
using InnoDB with transactions, you should
use innodb_flush_log_at_trx_commit=1,
sync_binlog=1, and, before MySQL 5.0.3,
innodb_safe_binlog, in the master
my.cnf file.
(innodb_safe_binlog is not needed from
5.0.3 on.)
Stop the server that is to be used as a slave and add the
following lines to its my.cnf file:
[mysqld]
server-id=slave_id
The slave_id value, like the
master_id value, must be a positive
integer value from 1 to 232 –
1. In addition, it is necessary that the ID of the slave be
different from the ID of the master. For example:
[mysqld] server-id=2
If you are setting up multiple slaves, each one must have a
unique server-id value that differs from
that of the master and from each of the other slaves. Think of
server-id values as something similar to IP
addresses: These IDs uniquely identify each server instance in
the community of replication partners.
If you do not specify a server-id value, it
is set to 1 if you have not defined
master-host; otherwise it is set to 2. Note
that in the case of server-id omission, a
master refuses connections from all slaves, and a slave
refuses to connect to a master. Thus, omitting
server-id is good only for backup with a
binary log.
If you made a binary backup of the master server's data, copy it to the slave server's data directory before starting the slave. Make sure that the privileges on the files and directories are correct. The system account that you use to run the slave server must be able to read and write the files, just as on the master.
If you made a backup using mysqldump, start the slave first. The dump file is loaded in a later step.
Start the slave server. If it has been replicating previously,
start the slave server with the
--skip-slave-start option so that it doesn't
immediately try to connect to its master. You also may want to
start the slave server with the
--log-warnings option to get more messages in
the error log about problems (for example, network or
connection problems). The option is enabled by default, but
aborted connections are not logged to the error log unless the
option value is greater than 1.
If you made a backup of the master server's data using mysqldump, load the dump file into the slave server:
shell> mysql -u root -p < dump_file.sql
Execute the following statement on the slave, replacing the option values with the actual values relevant to your system:
mysql>CHANGE MASTER TO->MASTER_HOST='->master_host_name',MASTER_USER='->replication_user_name',MASTER_PASSWORD='->replication_password',MASTER_LOG_FILE='->recorded_log_file_name',MASTER_LOG_POS=recorded_log_position;
The following table shows the maximum allowable length for the string-valued options:
MASTER_HOST | 60 |
MASTER_USER | 16 |
MASTER_PASSWORD | 32 |
MASTER_LOG_FILE | 255 |
Start the slave threads:
mysql> START SLAVE;
After you have performed this procedure, the slave should connect to the master and catch up on any updates that have occurred since the snapshot was taken.
If you have forgotten to set the server-id
option for the master, slaves cannot connect to it.
If you have forgotten to set the server-id
option for the slave, you get the following error in the slave's
error log:
Warning: You should set server-id to a non-0 value if master_host is set; we will force server id to 2, but this MySQL server will not act as a slave.
You also find error messages in the slave's error log if it is not able to replicate for any other reason.
Once a slave is replicating, you can find in its data directory
one file named master.info and another named
relay-log.info. The slave uses these two
files to keep track of how much of the master's binary log it has
processed. Do not remove or edit these files
unless you know exactly what you are doing and fully understand
the implications. Even in that case, it is preferred that you use
the CHANGE MASTER TO statement to change
replication parameters. The slave will use the values specified in
the statement to update the status files automatically.
Note: The content of
master.info overrides some of the server
options specified on the command line or in
my.cnf. See
Section 6.8, “Replication Startup Options”, for more details.
Once you have a snapshot of the master, you can use it to set up other slaves by following the slave portion of the procedure just described. You do not need to take another snapshot of the master; you can use the same one for each slave.
The binary log format as implemented in MySQL 5.0 is
considerably different from that used in previous versions. Major
changes were made in MySQL 5.0.3 (for improvements to handling of
character sets and LOAD DATA INFILE) and 5.0.4
(for improvements to handling of time zones).
We recommend using the most recent MySQL version available because replication capabilities are continually being improved. We also recommend using the same version for both the master and the slave. We recommend upgrading masters and slaves running alpha or beta versions to new (production) versions. Replication from a 5.0.3 master to a 5.0.2 slave will fail; from a 5.0.4 master to a 5.0.3 slave will also fail. In general, slaves running MySQL 5.0.x may be used with older masters (even those running MySQL 3.23, 4.0, or 4.1), but not the reverse. For more information on potential issues, see Section 6.7, “Replication Features and Known Problems”.
Note: You cannot replicate from a master that uses a newer binary log format to a slave that uses an older format (for example, from MySQL 5.0 to MySQL 4.1.) This has significant implications for upgrading replication servers, as described in Section 6.6, “Upgrading a Replication Setup”.
The preceding information pertains to replication compatibility at the protocol level. However, there can be other constraints, such as SQL-level compatibility issues. For example, a 5.0 master cannot replicate to a 4.1 slave if the replicated statements use SQL features available in 5.0 but not in 4.1. These and other issues are discussed in Section 6.7, “Replication Features and Known Problems”.
When you upgrade servers that participate in a replication setup, the procedure for upgrading depends on the current server versions and the version to which you are upgrading.
This section applies to upgrading replication from MySQL 3.23, 4.0, or 4.1 to MySQL 5.0. A 4.0 server should be 4.0.3 or newer.
When you upgrade a master to 5.0 from an earlier MySQL release series, you should first ensure that all the slaves of this master are using the same 5.0.x release. If this is not the case, you should first upgrade the slaves. To upgrade each slave, shut it down, upgrade it to the appropriate 5.0.x version, restart it, and restart replication. The 5.0 slave is able to read the old relay logs written prior to the upgrade and to execute the statements they contain. Relay logs created by the slave after the upgrade are in 5.0 format.
After the slaves have been upgraded, shut down the master, upgrade it to the same 5.0.x release as the slaves, and restart it. The 5.0 master is able to read the old binary logs written prior to the upgrade and to send them to the 5.0 slaves. The slaves recognize the old format and handle it properly. Binary logs created by the master following the upgrade are in 5.0 format. These too are recognized by the 5.0 slaves.
In other words, there are no measures to take when upgrading to MySQL 5.0, except that the slaves must be MySQL 5.0 before you can upgrade the master to 5.0. Note that downgrading from 5.0 to older versions does not work so simply: You must ensure that any 5.0 binary logs or relay logs have been fully processed, so that you can remove them before proceeding with the downgrade.
In general, replication compatibility at the SQL level requires
that any features used be supported by both the master and the
slave servers. If you use a feature on a master server that is
available only as of a given version of MySQL, you cannot
replicate to a slave that is older than that version. Such
incompatibilities are likely to occur between series, so that, for
example, you cannot replicate from MySQL 5.0 to
4.1. However, these incompatibilities also can occur
for within-series replication. For example, the
SLEEP() function is available in MySQL 5.0.12
and up. If you use this function on the master server, you cannot
replicate to a slave server that is older than MySQL 5.0.12.
If you are planning to use replication between 5.0 and a previous version of MySQL you should consult the edition of the MySQL Reference Manual corresponding to the earlier release series for information regarding the replication characteristics of that series.
The following list provides details about what is supported and
what is not. Additional InnoDB-specific
information about replication is given in
Section 14.2.6.5, “InnoDB and MySQL Replication”.
Replication issues with regard to stored routines and triggers is described in Section 17.4, “Binary Logging of Stored Routines and Triggers”.
Known issue: In MySQL 5.0.17,
the syntax for CREATE TRIGGER changed to
include a DEFINER clause for specifying
which access privileges to check at trigger invocation time.
(See Section 18.1, “CREATE TRIGGER Syntax”, for more information.)
However, if you attempt to replicate from a master server
older than MySQL 5.0.17 to a slave running MySQL 5.0.17
through 5.0.19, replication of CREATE
TRIGGER statements fails on the slave with a
Definer not fully qualified error. A
workaround is to create triggers on the master using a
version-specific comment embedded in each CREATE
TRIGGER statement:
CREATE /*!50017 DEFINER = 'root'@'localhost' */ TRIGGER ... ;
CREATE TRIGGER statements written this way
will replicate to newer slaves, which pick up the
DEFINER clause from the comment and execute
successfully.
This slave problem is fixed as of MySQL 5.0.20.
Replication of AUTO_INCREMENT,
LAST_INSERT_ID(), and
TIMESTAMP values is done correctly, subject
to the following exceptions.
INSERT DELAYED ... VALUES(LAST_INSERT_ID())
inserts a different value on the master and the slave. (Bug#20819) This is fixed in MySQL 5.1 when using
row-based or mixed-format binary logging.
Before MySQL 5.0.26, a stored procedure that uses
LAST_INSERT_ID() does not replicate
properly.
When a statement uses a stored function that inserts into an
AUTO_INCREMENT column, the generated
AUTO_INCREMENT value is not written into
the binary log, so a different value can in some cases be
inserted on the slave.
Adding an AUTO_INCREMENT column to a table
with ALTER TABLE might not produce the same
ordering of the rows on the slave and the master. This occurs
because the order in which the rows are numbered depends on
the specific storage engine used for the table and the order
in which the rows were inserted. If it is important to have
the same order on the master and slave, the rows must be
ordered before assigning an AUTO_INCREMENT
number. Assuming that you want to add an
AUTO_INCREMENT column to the table
t1, the following statements produce a new
table t2 identical to t1
but with an AUTO_INCREMENT column:
CREATE TABLE t2 LIKE t1; ALTER TABLE t2 ADD id INT AUTO_INCREMENT PRIMARY KEY; INSERT INTO t2 SELECT * FROM t1 ORDER BY col1, col2;
This assumes that the table t1 has columns
col1 and col2.
Important: To guarantee the
same ordering on both master and slave,
all columns of t1 must
be referenced in the ORDER BY clause.
The instructions just given are subject to the limitations of
CREATE TABLE ... LIKE: Foreign key
definitions are ignored, as are the DATA
DIRECTORY and INDEX DIRECTORY
table options. If a table definition includes any of those
characteristics, create t2 using a
CREATE TABLE statement that is identical to
the one used to create t1, but with the
addition of the AUTO_INCREMENT column.
Regardless of the method used to create and populate the copy
having the AUTO_INCREMENT column, the final
step is to drop the original table and then rename the copy:
DROP t1; ALTER TABLE t2 RENAME t1;
Certain functions do not replicate well under some conditions:
The USER(),
CURRENT_USER(),
UUID(), VERSION(),
and LOAD_FILE() functions are
replicated without change and thus do not work reliably on
the slave.
As of MySQL 5.0.13, the SYSDATE()
function is no longer equivalent to
NOW(). Implications are that
SYSDATE() is not replication-safe
because it is not affected by SET
TIMESTAMP statements in the binary log and is
non-deterministic. To avoid this, you can start the server
with the --sysdate-is-now option to cause
SYSDATE() to be an alias for
NOW().
The GET_LOCK(),
RELEASE_LOCK(),
IS_FREE_LOCK(), and
IS_USED_LOCK() functions that handle
user-level locks are replicated without the slave knowing
the concurrency context on master. Therefore, these
functions should not be used to insert into a master's
table because the content on the slave would differ. (For
example, do not issue a statement such as INSERT
INTO mytable VALUES(GET_LOCK(...)).)
As a workaround for the preceding limitations, you can use the
strategy of saving the problematic function result in a user
variable and referring to the variable in a later statement.
For example, the following single-row
INSERT is problematic due to the reference
to the UUID() function:
INSERT INTO t VALUES(UUID());
To work around the problem, do this instead:
SET @my_uuid = UUID(); INSERT INTO t VALUES(@my_uuid);
That sequence of statements replicates because the value of
@my_uuid is stored in the binary log as a
user-variable event prior to the INSERT
statement and is available for use in the
INSERT.
The same idea applies to multiple-row inserts, but is more cumbersome to use. For a two-row insert, you can do this:
SET @my_uuid1 = UUID(); @my_uuid2 = UUID(); INSERT INTO t VALUES(@my_uuid1),(@my_uuid2);
However, if the number of rows is large or unknown, the workaround is difficult or impracticable. For example, you cannot convert the following statement to one in which a given individual user variable is associated with each row:
INSERT INTO t2 SELECT UUID(), * FROM t1;
User privileges are replicated only if the
mysql database is replicated. That is, the
GRANT, REVOKE,
SET PASSWORD, CREATE
USER, and DROP USER statements
take effect on the slave only if the replication setup
includes the mysql database.
If you're replicating all databases, but don't want statements
that affect user privileges to be replicated, set up the slave
to not replicate the mysql database, using
the --replicate-wild-ignore-table=mysql.%
option. The slave will recognize that issuing
privilege-related SQL statements won't have an effect, and
thus not execute those statements.
The FOREIGN_KEY_CHECKS,
SQL_MODE, UNIQUE_CHECKS,
and SQL_AUTO_IS_NULL variables are all
replicated in MySQL 5.0. The
storage_engine system variable (also known
as table_type) is not yet replicated, which
is a good thing for replication between different storage
engines.
Starting from MySQL 5.0.3 (master and slave), replication works even if the master and slave have different global character set variables. Starting from MySQL 5.0.4 (master and slave), replication works even if the master and slave have different global time zone variables.
The following applies to replication between MySQL servers that use different character sets:
If the master uses MySQL 4.1, you must
always use the same
global character set and collation on
the master and the slave, regardless of the MySQL version
running on the slave. (These are controlled by the
--character-set-server and
--collation-server options.) Otherwise,
you may get duplicate-key errors on the slave, because a
key that is unique in the master character set might not
be unique in the slave character set. Note that this is
not a cause for concern when master and slave are both
MySQL 5.0 or later.
If the master is older than MySQL 4.1.3, the character set
of any client should never be made different from its
global value because this character set change is not
known to the slave. In other words, clients should not use
SET NAMES, SET CHARACTER
SET, and so forth. If both the master and the
slave are 4.1.3 or newer, clients can freely set session
values for character set variables because these settings
are written to the binary log and so are known to the
slave. That is, clients can use SET
NAMES or SET CHARACTER SET or
can set variables such as
collation_client or
collation_server. However, clients are
prevented from changing the global
value of these variables; as stated previously, the master
and slave must always have identical global character set
values.
If you have databases on the master with character sets
that differ from the global
character_set_server value, you should
design your CREATE TABLE statements so
that tables in those databases do not implicitly rely on
the database default character set (see Bug#2326). A good
workaround is to state the character set and collation
explicitly in CREATE TABLE statements.
If the master uses MySQL 4.1, the same system time zone should
be set for both master and slave. Otherwise some statements
will not be replicated properly, such as statements that use
the NOW() or
FROM_UNIXTIME() functions. You can set the
time zone in which MySQL server runs by using the
--timezone=
option of the timezone_namemysqld_safe script or by
setting the TZ environment variable. Both
master and slave should also have the same default connection
time zone setting; that is, the
--default-time-zone parameter should have the
same value for both master and slave. Note that this is not
necessary when the master is MySQL 5.0 or later.
CONVERT_TZ(...,...,@@global.time_zone) is
not properly replicated.
CONVERT_TZ(...,...,@@session.time_zone) is
properly replicated only if the master and slave are from
MySQL 5.0.4 or newer.
Session variables are not replicated properly when used in
statements that update tables. For example, SET
MAX_JOIN_SIZE=1000 followed by INSERT INTO
mytable VALUES(@@MAX_JOIN_SIZE) will not insert the
same data on the master and the slave. This does not apply to
the common sequence of SET TIME_ZONE=...
followed by INSERT INTO mytable
VALUES(CONVERT_TZ(...,...,@@time_zone)), which
replicates correctly as of MySQL 5.0.4.
It is possible to replicate transactional tables on the master
using non-transactional tables on the slave. For example, you
can replicate an InnoDB master table as a
MyISAM slave table. However, if you do
this, there are problems if the slave is stopped in the middle
of a BEGIN/COMMIT block
because the slave restarts at the beginning of the
BEGIN block.
Update statements that refer to user-defined variables (that
is, variables of the form
@) are
replicated correctly in MySQL 5.0. However, this
is not true for versions prior to 4.1. Note that user variable
names are case insensitive starting in MySQL 5.0. You should
take this into account when setting up replication between
MySQL 5.0 and older versions.
var_name
Non-delayed INSERT statements that refer to
RAND() or user-defined variables replicate
correctly. However, changing the statements to use
INSERT DELAYED can result in different
results on master and slave.
Slaves can connect to masters using SSL.
Views are always replicated to slaves. Views are filtered by
their own name, not by the tables they refer to. This means
that a view can be replicated to the slave even if the view
contains a table that would normally be filtered out by
replication-ignore-table rules. Care should
therefore be taken to ensure that views do not replicate table
data that would normally be filtered for security reasons.
In MySQL 5.0 (starting from 5.0.3), there is a
global system variable
slave_transaction_retries: If the
replication slave SQL thread fails to execute a transaction
because of an InnoDB deadlock or because it
exceeded the InnoDB
innodb_lock_wait_timeout or the NDBCluster
TransactionDeadlockDetectionTimeout or
TransactionInactiveTimeout value, the
transaction automatically retries
slave_transaction_retries times before
stopping with an error. The default value is 10. Starting from
MySQL 5.0.4, the total retry count can be seen in the output
of SHOW STATUS; see
Section 5.2.5, “Status Variables”.
If a DATA DIRECTORY or INDEX
DIRECTORY table option is used in a CREATE
TABLE statement on the master server, the table
option is also used on the slave. This can cause problems if
no corresponding directory exists in the slave host filesystem
or if it exists but is not accessible to the slave server.
MySQL supports an sql_mode option called
NO_DIR_IN_CREATE. If the slave server is
run with this SQL mode enabled, it ignores the DATA
DIRECTORY and INDEX DIRECTORY
table options when replicating CREATE TABLE
statements. The result is that MyISAM data
and index files are created in the table's database directory.
It is possible for the data on the master and slave to become different if a statement is designed in such a way that the data modification is non-deterministic; that is, left to the will of the query optimizer. (This is in general not a good practice, even outside of replication.) For a detailed explanation of this issue, see Section B.1.8.1, “Open Issues in MySQL”.
Using LOAD TABLE FROM MASTER where the
master is running MySQL 4.1 and the slave is running MySQL 5.0
may corrupt the table data, and is not supported. (Bug#16261)
The following applies only if either the master or
the slave is running MySQL version 5.0.3 or older:
If on the master a LOAD DATA INFILE is
interrupted (integrity constraint violation, killed
connection, and so on), the slave skips the LOAD DATA
INFILE entirely. This means that if this command
permanently inserted or updated table records before being
interrupted, these modifications are not replicated to the
slave.
Some forms of the FLUSH statement are not
logged because they could cause problems if replicated to a
slave: FLUSH LOGS, FLUSH
MASTER, FLUSH SLAVE, and
FLUSH TABLES WITH READ LOCK. For a syntax
example, see Section 13.5.5.2, “FLUSH Syntax”. The FLUSH
TABLES, ANALYZE TABLE,
OPTIMIZE TABLE, and REPAIR
TABLE statements are written to the binary log and
thus replicated to slaves. This is not normally a problem
because these statements do not modify table data. However,
this can cause difficulties under certain circumstances. If
you replicate the privilege tables in the
mysql database and update those tables
directly without using GRANT, you must
issue a FLUSH PRIVILEGES on the slaves to
put the new privileges into effect. In addition, if you use
FLUSH TABLES when renaming a
MyISAM table that is part of a
MERGE table, you must issue FLUSH
TABLES manually on the slaves. These statements are
written to the binary log unless you specify
NO_WRITE_TO_BINLOG or its alias
LOCAL.
When a server shuts down and restarts, its
MEMORY (HEAP) tables
become empty. The master replicates this effect to slaves as
follows: The first time that the master uses each
MEMORY table after startup, it logs an
event that notifies the slaves that the table needs to be
emptied by writing a DELETE statement for
that table to the binary log. See
Section 14.4, “The MEMORY (HEAP) Storage Engine”, for more information
about MEMORY tables.
Temporary tables are replicated except in the case where you shut down the slave server (not just the slave threads) and you have replicated temporary tables that are used in updates that have not yet been executed on the slave. If you shut down the slave server, the temporary tables needed by those updates are no longer available when the slave is restarted. To avoid this problem, do not shut down the slave while it has temporary tables open. Instead, use the following procedure:
Issue a STOP SLAVE statement.
Use SHOW STATUS to check the value of
the Slave_open_temp_tables variable.
If the value is 0, issue a mysqladmin shutdown command to stop the slave.
If the value is not 0, restart the slave threads with
START SLAVE.
Repeat the procedure later until the
Slave_open_temp_tables variable is 0
and you can stop the slave.
The syntax for multiple-table DELETE
statements that use table aliases changed between MySQL 4.0
and 4.1. In MySQL 4.0, you should use the true table name to
refer to any table from which rows should be deleted:
DELETE test FROM test AS t1, test2 WHERE ...
In MySQL 4.1, you must use the alias:
DELETE t1 FROM test AS t1, test2 WHERE ...
If you use such DELETE statements, the
change in syntax means that a 4.0 master cannot replicate to
4.1 (or higher) slaves.
It is safe to connect servers in a circular master/slave
relationship if you use the
--log-slave-updates option. That means that
you can create a setup such as this:
A -> B -> C -> A
However, many statements do not work correctly in this kind of setup unless your client code is written to take care of the potential problems that can occur from updates that occur in different sequence on different servers.
Server IDs are encoded in binary log events, so server A knows
when an event that it reads was originally created by itself
and does not execute the event (unless server A was started
with the --replicate-same-server-id option,
which is meaningful only in rare cases). Thus, there are no
infinite loops. This type of circular setup works only if you
perform no conflicting updates between the tables. In other
words, if you insert data in both A and C, you should never
insert a row in A that may have a key that conflicts with a
row inserted in C. You should also not update the same rows on
two servers if the order in which the updates are applied is
significant.
If a statement on a slave produces an error, the slave SQL
thread terminates, and the slave writes a message to its error
log. You should then connect to the slave manually and
determine the cause of the problem. (SHOW SLAVE
STATUS is useful for this.) Then fix the problem
(for example, you might need to create a non-existent table)
and run START SLAVE.
It is safe to shut down a master server and restart it later.
When a slave loses its connection to the master, the slave
tries to reconnect immediately and retries periodically if
that fails. The default is to retry every 60 seconds. This may
be changed with the --master-connect-retry
option. A slave also is able to deal with network connectivity
outages. However, the slave notices the network outage only
after receiving no data from the master for
slave_net_timeout seconds. If your outages
are short, you may want to decrease
slave_net_timeout. See
Section 5.2.3, “System Variables”.
Shutting down the slave (cleanly) is also safe because it
keeps track of where it left off. Unclean shutdowns might
produce problems, especially if the disk cache was not flushed
to disk before the system went down. Your system fault
tolerance is greatly increased if you have a good
uninterruptible power supply. Unclean shutdowns of the master
may cause inconsistencies between the content of tables and
the binary log in master; this can be avoided by using
InnoDB tables and the
--innodb-safe-binlog option on the master.
See Section 5.11.3, “The Binary Log”.
Note:
--innodb-safe-binlog is unneeded as of MySQL
5.0.3, having been made obsolete by the introduction of XA
transaction support.
A crash on the master side can result in the master's binary
log having a final position less than the most recent position
read by the slave, due to the master's binary log file not
being flushed. This can cause the slave not to be able to
replicate when the master comes back up. Setting
sync_binlog=1 in the master
my.cnf file helps to minimize this
problem because it causes the master to flush its binary log
more frequently.
Due to the non-transactional nature of
MyISAM tables, it is possible to have a
statement that only partially updates a table and returns an
error code. This can happen, for example, on a multiple-row
insert that has one row violating a key constraint, or if a
long update statement is killed after updating some of the
rows. If that happens on the master, the slave thread exits
and waits for the database administrator to decide what to do
about it unless the error code is legitimate and execution of
the statement results in the same error code on the slave. If
this error code validation behavior is not desirable, some or
all errors can be masked out (ignored) with the
--slave-skip-errors option.
If you update transactional tables from non-transactional
tables inside a
BEGIN/COMMIT sequence,
updates to the binary log may be out of synchrony with table
states if the non-transactional table is updated before the
transaction commits. This occurs because the transaction is
written to the binary log only when it is committed.
In situations where transactions mix updates to transactional
and non-transactional tables, the order of statements in the
binary log is correct, and all needed statements are written
to the binary log even in case of a
ROLLBACK. However, when a second connection
updates the non-transactional table before the first
connection's transaction is complete, statements can be logged
out of order, because the second connection's update is
written immediately after it is performed, regardless of the
state of the transaction being performed by the first
connection.
You should not use transactions in a replication environment that update both transactional and non-transactional tables.
Floating-point values are approximate, so comparisons involving them are inexact. This is true for operations that use floating-point values explicitly, or values that are converted to floating-point implicitly. Comparisons of floating-point values might yield different results on master and slave servers due to differences in computer architecture, the compiler used to build MySQL, and so forth. See Section 12.2.2, “Type Conversion in Expression Evaluation”, and Section B.1.5.8, “Problems with Floating-Point Comparisons”.
This section describes the options that you can use on slave replication servers. You can specify these options either on the command line or in an option file.
On the master and each slave, you must use the
server-id option to establish a unique
replication ID. For each server, you should pick a unique positive
integer in the range from 1 to 232
– 1, and each ID must be different from every other ID.
Example: server-id=3
Options that you can use on the master server for controlling binary logging are described in Section 5.11.3, “The Binary Log”.
Some slave server replication options are handled in a special
way, in the sense that each is ignored if a
master.info file exists when the slave starts
and contains a value for the option. The following options are
handled this way:
--master-host
--master-user
--master-password
--master-port
--master-connect-retry
--master-ssl
--master-ssl-ca
--master-ssl-capath
--master-ssl-cert
--master-ssl-cipher
--master-ssl-key
The master.info file format in MySQL
5.0 includes values corresponding to the SSL options.
In addition, the file format includes as its first line the number
of lines in the file. (See Section 6.3.4, “Replication Relay and Status Files”.) If you
upgrade an older server (before MySQL 4.1.1) to a newer version,
the new server upgrades the master.info file
to the new format automatically when it starts. However, if you
downgrade a newer server to an older version, you should remove
the first line manually before starting the older server for the
first time.
If no master.info file exists when the slave
server starts, it uses the values for those options that are
specified in option files or on the command line. This occurs when
you start the server as a replication slave for the very first
time, or when you have run RESET SLAVE and then
have shut down and restarted the slave.
If the master.info file exists when the slave
server starts, the server uses its contents and ignores any
options that correspond to the values listed in the file. Thus, if
you start the slave server with different values of the startup
options that correspond to values in the
master.info file, the different values have
no effect, because the server continues to use the
master.info file. To use different values,
you must either restart after removing the
master.info file or (preferably) use the
CHANGE MASTER TO statement to reset the values
while the slave is running.
Suppose that you specify this option in your
my.cnf file:
[mysqld]
master-host=some_host
The first time you start the server as a replication slave, it
reads and uses that option from the my.cnf
file. The server then records the value in the
master.info file. The next time you start the
server, it reads the master host value from the
master.info file only and ignores the value
in the option file. If you modify the my.cnf
file to specify a different master host of
some_other_host, the change still has
no effect. You should use CHANGE MASTER TO
instead.
Because the server gives an existing
master.info file precedence over the startup
options just described, you might prefer not to use startup
options for these values at all, and instead specify them by using
the CHANGE MASTER TO statement. See
Section 13.6.2.1, “CHANGE MASTER TO Syntax”.
This example shows a more extensive use of startup options to configure a slave server:
[mysqld] server-id=2 master-host=db-master.mycompany.com master-port=3306 master-user=pertinax master-password=freitag master-connect-retry=60 report-host=db-slave.mycompany.com
The following list describes startup options for controlling
replication. Many of these options can be reset while the server
is running by using the CHANGE MASTER TO
statement. Others, such as the --replicate-*
options, can be set only when the slave server starts.
Normally, a slave does not log to its own binary log any
updates that are received from a master server. This option
tells the slave to log the updates performed by its SQL thread
to its own binary log. For this option to have any effect, the
slave must also be started with the --log-bin
option to enable binary logging.
--log-slave-updates is used when you want to
chain replication servers. For example, you might want to set
up replication servers using this arrangement:
A -> B -> C
Here, A serves as the master for the slave B, and B serves as
the master for the slave C. For this to work, B must be both a
master and a slave. You must start both A
and B with --log-bin to enable binary
logging, and B with the --log-slave-updates
option so that updates received from A are logged by B to its
binary log.
This option causes a server to print more messages to the
error log about what it is doing. With respect to replication,
the server generates warnings that it succeeded in
reconnecting after a network/connection failure, and informs
you as to how each slave thread started. This option is
enabled by default; to disable it, use
--skip-log-warnings. Aborted connections are
not logged to the error log unless the value is greater than
1.
--master-connect-retry=
seconds
The number of seconds that the slave thread sleeps before
trying to reconnect to the master in case the master goes down
or the connection is lost. The value in the
master.info file takes precedence if it
can be read. If not set, the default is 60. Connection retries
are not invoked until the slave times out reading data from
the master according to the value of
--slave-net-timeout. The number of
reconnection attempts is limited by the
--master-retry-count option.
The hostname or IP number of the master replication server.
The value in master.info takes precedence
if it can be read. If no master host is specified, the slave
thread does not start.
The name to use for the file in which the slave records
information about the master. The default name is
master.info in the data directory.
The password of the account that the slave thread uses for
authentication when it connects to the master. The value in
the master.info file takes precedence if
it can be read. If not set, an empty password is assumed.
The TCP/IP port number that the master is listening on. The
value in the master.info file takes
precedence if it can be read. If not set, the compiled-in
setting is assumed (normally 3306).
The number of times that the slave tries to connect to the
master before giving up. Reconnects are attempted at intervals
set by --master-connect-retry and reconnects
are triggered when data reads by the slave time out according
to the --slave-net-timeout option. The
default value is 86400.
--master-ssl,
--master-ssl-ca=,
file_name--master-ssl-capath=,
directory_name--master-ssl-cert=,
file_name--master-ssl-cipher=,
cipher_list--master-ssl-key=
file_name
These options are used for setting up a secure replication
connection to the master server using SSL. Their meanings are
the same as the corresponding --ssl,
--ssl-ca, --ssl-capath,
--ssl-cert, --ssl-cipher,
--ssl-key options that are described in
Section 5.8.7.3, “SSL Command Options”. The values in the
master.info file take precedence if they
can be read.
The username of the account that the slave thread uses for
authentication when it connects to the master. This account
must have the REPLICATION SLAVE privilege.
The value in the master.info file takes
precedence if it can be read. If the master username is not
set, the name test is assumed.
The size at which the server rotates relay log files automatically. For more information, see Section 6.3.4, “Replication Relay and Status Files”. The default size is 1GB.
When this option is given, the server allows no updates except
from users that have the SUPER privilege or
(on a slave server) from updates performed by slave threads.
On a slave server, this can be useful to ensure that the slave
accepts updates only from its master server and not from
clients. As of MySQL 5.0.16, this option does not apply to
TEMPORARY tables.
The name for the relay log. The default name is
host_name-relay-bin.nnnnnnhost_name is the name of the
slave server host and nnnnnn
indicates that relay logs are created in numbered sequence.
You can specify the option to create hostname-independent
relay log names, or if your relay logs tend to be big (and you
don't want to decrease max_relay_log_size)
and you need to put them in some area different from the data
directory, or if you want to increase speed by balancing load
between disks.
The name to use for the relay log index file. The default name
is
host_name-relay-bin.indexhost_name is the name of the slave
server.
--relay-log-info-file=
file_name
The name to use for the file in which the slave records
information about the relay logs. The default name is
relay-log.info in the data directory.
Disable or enable automatic purging of relay logs as soon as
they are not needed any more. The default value is 1
(enabled). This is a global variable that can be changed
dynamically with SET GLOBAL relay_log_purge =
.
N
This option places an upper limit on the total size in bytes
of all relay logs on the slave. A value of 0 means “no
limit.” This is useful for a slave server host that has
limited disk space. When the limit is reached, the I/O thread
stops reading binary log events from the master server until
the SQL thread has caught up and deleted some unused relay
logs. Note that this limit is not absolute: There are cases
where the SQL thread needs more events before it can delete
relay logs. In that case, the I/O thread exceeds the limit
until it becomes possible for the SQL thread to delete some
relay logs, because not doing so would cause a deadlock. You
should not set --relay-log-space-limit to
less than twice the value of
--max-relay-log-size (or
--max-binlog-size if
--max-relay-log-size is 0). In that case,
there is a chance that the I/O thread waits for free space
because --relay-log-space-limit is exceeded,
but the SQL thread has no relay log to purge and is unable to
satisfy the I/O thread. This forces the I/O thread to
temporarily ignore --relay-log-space-limit.
Tell the slave to restrict replication to statements where the
default database (that is, the one selected by
USE) is db_name.
To specify more than one database, use this option multiple
times, once for each database. Note that this does not
replicate cross-database statements such as UPDATE
while having selected a different database
or no database.
some_db.some_table SET
foo='bar'
To specify multiple databases you must use multiple instances of this option. Because database names can contain commas, if you supply a comma separated list then the list will be treated as the name of a single database.
An example of what does not work as you might expect: If the
slave is started with --replicate-do-db=sales
and you issue the following statements on the master, the
UPDATE statement is
not replicated:
USE prices; UPDATE sales.january SET amount=amount+1000;
The main reason for this “just check the default
database” behavior is that it is difficult from the
statement alone to know whether it should be replicated (for
example, if you are using multiple-table
DELETE statements or multiple-table
UPDATE statements that act across multiple
databases). It is also faster to check only the default
database rather than all databases if there is no need.
If you need cross-database updates to work, use
--replicate-wild-do-table=
instead. See Section 6.9, “How Servers Evaluate Replication Rules”.
db_name.%
--replicate-do-table=
db_name.tbl_name
Tell the slave thread to restrict replication to the specified
table. To specify more than one table, use this option
multiple times, once for each table. This works for
cross-database updates, in contrast to
--replicate-do-db. See
Section 6.9, “How Servers Evaluate Replication Rules”.
Tells the slave to not replicate any statement where the
default database (that is, the one selected by
USE) is db_name.
To specify more than one database to ignore, use this option
multiple times, once for each database. You should not use
this option if you are using cross-database updates and you do
not want these updates to be replicated. See
Section 6.9, “How Servers Evaluate Replication Rules”.
An example of what does not work as you might expect: If the
slave is started with
--replicate-ignore-db=sales and you issue the
following statements on the master, the
UPDATE statement is
replicated:
USE prices; UPDATE sales.january SET amount=amount+1000;
In the preceding example the statement is replicated because
--replicate-ignore-db only applies to the
default database (set through the USE
statement). Because the sales database
was specified explicitly in the statement, the statement has
not been filtered.
If you need cross-database updates to work, use
--replicate-wild-ignore-table=
instead. See Section 6.9, “How Servers Evaluate Replication Rules”.
db_name.%
--replicate-ignore-table=
db_name.tbl_name
Tells the slave thread to not replicate any statement that
updates the specified table, even if any other tables might be
updated by the same statement. To specify more than one table
to ignore, use this option multiple times, once for each
table. This works for cross-database updates, in contrast to
--replicate-ignore-db. See
Section 6.9, “How Servers Evaluate Replication Rules”.
--replicate-rewrite-db=
from_name->to_name
Tells the slave to translate the default database (that is,
the one selected by USE) to
to_name if it was
from_name on the master. Only
statements involving tables are affected (not statements such
as CREATE DATABASE, DROP
DATABASE, and ALTER DATABASE),
and only if from_name is the
default database on the master. This does not work for
cross-database updates. The database name translation is done
before the --replicate-*
rules are tested.
If you use this option on the command line and the
‘>’ character is special to
your command interpreter, quote the option value. For example:
shell> mysqld --replicate-rewrite-db="olddb->newdb"
To be used on slave servers. Usually you should use the
default setting of 0, to prevent infinite loops caused by
circular replication. If set to 1, the slave does not skip
events having its own server ID. Normally, this is useful only
in rare configurations. Cannot be set to 1 if
--log-slave-updates is used. Note that by
default the slave I/O thread does not even write binary log
events to the relay log if they have the slave's server id
(this optimization helps save disk usage). So if you want to
use --replicate-same-server-id, be sure to
start the slave with this option before you make the slave
read its own events that you want the slave SQL thread to
execute.
--replicate-wild-do-table=
db_name.tbl_name
Tells the slave thread to restrict replication to statements
where any of the updated tables match the specified database
and table name patterns. Patterns can contain the
‘%’ and
‘_’ wildcard characters, which
have the same meaning as for the LIKE
pattern-matching operator. To specify more than one table, use
this option multiple times, once for each table. This works
for cross-database updates. See
Section 6.9, “How Servers Evaluate Replication Rules”.
Example: --replicate-wild-do-table=foo%.bar%
replicates only updates that use a table where the database
name starts with foo and the table name
starts with bar.
If the table name pattern is %, it matches
any table name and the option also applies to database-level
statements (CREATE DATABASE, DROP
DATABASE, and ALTER DATABASE).
For example, if you use
--replicate-wild-do-table=foo%.%,
database-level statements are replicated if the database name
matches the pattern foo%.
To include literal wildcard characters in the database or
table name patterns, escape them with a backslash. For
example, to replicate all tables of a database that is named
my_own%db, but not replicate tables from
the my1ownAABCdb database, you should
escape the ‘_’ and
‘%’ characters like this:
--replicate-wild-do-table=my\_own\%db. If
you're using the option on the command line, you might need to
double the backslashes or quote the option value, depending on
your command interpreter. For example, with the
bash shell, you would need to type
--replicate-wild-do-table=my\\_own\\%db.
--replicate-wild-ignore-table=
db_name.tbl_name
Tells the slave thread not to replicate a statement where any table matches the given wildcard pattern. To specify more than one table to ignore, use this option multiple times, once for each table. This works for cross-database updates. See