Table of Contents
Replication enables data from one MySQL database server (the master) to be copied to one or more MySQL database servers (the slaves). Replication is asynchronous by default; slaves do not need to be connected permanently to receive updates from the master. Depending on the configuration, you can replicate all databases, selected databases, or even selected tables within a database.
Advantages of replication in MySQL include:
Scale-out solutions - spreading the load among multiple slaves to improve performance. In this environment, all writes and updates must take place on the master server. Reads, however, may take place on one or more slaves. This model can improve the performance of writes (since the master is dedicated to updates), while dramatically increasing read speed across an increasing number of slaves.
Data security - because data is replicated to the slave, and the slave can pause the replication process, it is possible to run backup services on the slave without corrupting the corresponding master data.
Analytics - live data can be created on the master, while the analysis of the information can take place on the slave without affecting the performance of the master.
Long-distance data distribution - you can use replication to create a local copy of data for a remote site to use, without permanent access to the master.
For information on how to use replication in such scenarios, see Section 18.3, “Replication Solutions”.
MySQL 5.7 supports different methods of replication. The traditional method is based on replicating events from the master's binary log, and requires the log files and positions in them to be synchronized between master and slave. The newer method based on global transaction identifiers (GTIDs) is transactional and therefore does not require working with log files or positions within these files, which greatly simplifies many common replication tasks. Replication using GTIDs guarantees consistency between master and slave as long as all transactions committed on the master have also been applied on the slave. For more information about GTIDs and GTID-based replication in MySQL, see Section 18.1.3, “Replication with Global Transaction Identifiers”. For information on using binary log file position based replication, see Section 18.1, “Configuring Replication”.
Replication in MySQL supports different types of synchronization. The original type of synchronization is 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 21, MySQL NDB Cluster 7.5). In MySQL 5.7, semisynchronous replication is supported in addition to the built-in asynchronous replication. With semisynchronous replication, a commit performed on the master blocks before returning to the session that performed the transaction until at least one slave acknowledges that it has received and logged the events for the transaction; see Section 18.3.9, “Semisynchronous Replication”. MySQL 5.7 also supports delayed replication such that a slave server deliberately lags behind the master by at least a specified amount of time; see Section 18.3.10, “Delayed Replication”. For scenarios where synchronous replication is required, use MySQL Cluster (see Chapter 21, MySQL NDB Cluster 7.5).
There are a number of solutions available for setting up replication between servers, and the best method to use depends on the presence of data and the engine types you are using. For more information on the available options, see Section 18.1.2, “Setting Up Binary Log File Position Based Replication”.
There are two core types of replication format, Statement Based Replication (SBR), which replicates entire SQL statements, and Row Based Replication (RBR), which replicates only the changed rows. You can also use a third variety, Mixed Based Replication (MBR). For more information on the different replication formats, see Section 18.2.1, “Replication Formats”.
Replication is controlled through a number of different options and variables. For more information, see Section 18.1.6, “Replication and Binary Logging Options and Variables”.
You can use replication to solve a number of different problems, including performance, supporting the backup of different databases, and as part of a larger solution to alleviate system failures. For information on how to address these issues, see Section 18.3, “Replication Solutions”.
For notes and tips on how different data types and statements are treated during replication, including details of replication features, version compatibility, upgrades, and potential problems and their resolution, see Section 18.4, “Replication Notes and Tips”. For answers to some questions often asked by those who are new to MySQL Replication, see Section A.13, “MySQL 5.7 FAQ: Replication”.
For detailed information on the implementation of replication, how replication works, the process and contents of the binary log, background threads and the rules used to decide how statements are recorded and replicated, see Section 18.2, “Replication Implementation”.
This section describes how to configure the different types of replication available in MySQL and includes the setup and configuration required for a replication environment, including step-by-step instructions for creating a new replication environment. The major components of this section are:
For a guide to setting up two or more servers for replication using binary log file positions, Section 18.1.2, “Setting Up Binary Log File Position Based Replication”, deals with the configuration of the servers and provides methods for copying data between the master and slaves.
For a guide to setting up two or more servers for replication using GTID transactions, Section 18.1.3, “Replication with Global Transaction Identifiers”, deals with the configuration of the servers.
Events in the binary log are recorded using a number of formats. These are referred to as statement-based replication (SBR) or row-based replication (RBR). A third type, mixed-format replication (MIXED), uses SBR or RBR replication automatically to take advantage of the benefits of both SBR and RBR formats when appropriate. The different formats are discussed in Section 18.2.1, “Replication Formats”.
Detailed information on the different configuration options and variables that apply to replication is provided in Section 18.1.6, “Replication and Binary Logging Options and Variables”.
Once started, the replication process should require little administration or monitoring. However, for advice on common tasks that you may want to execute, see Section 18.1.7, “Common Replication Administration Tasks”.
This section describes replication between MySQL servers based on the binary log file position method, where the MySQL instance operating as the master (the source of the database changes) writes updates and changes as “events” to the binary log. The information in the binary log is stored in different logging formats according to the database changes being recorded. Slaves are configured to read the binary log from the master and to execute the events in the binary log on the slave's local database.
Each slave receives a copy of the entire contents of the binary log. It is the responsibility of the slave to decide which statements in the binary log should be executed. Unless you specify otherwise, all events in the master binary log are executed on the slave. If required, you can configure the slave to process only events that apply to particular databases or tables.
You cannot configure the master to log only certain events.
Each slave keeps a record of the binary log coordinates: the file name and position within the file that it has read and processed from the master. This means that multiple slaves can be connected to the master and executing different parts of the same binary log. Because the slaves control this process, individual slaves can be connected and disconnected from the server without affecting the master's operation. Also, because each slave records the current position within the binary log, it is possible for slaves to be disconnected, reconnect and then resume processing.
The master and each slave must be configured with a unique ID
(using the server-id
option). In
addition, each slave must be configured with information about the
master host name, log file name, and position within that file.
These details can be controlled from within a MySQL session using
the CHANGE MASTER TO
statement on
the slave. The details are stored within the slave's master
info repository, which can be either a file or a table (see
Section 18.2.4, “Replication Relay and Status Logs”).
This section describes how to set up a MySQL server to use binary log file position based replication. There are a number of different methods for setting up replication, and the exact method to use depends on how you are setting up replication, and whether you already have data within your master database.
There are some generic tasks that are common to all setups:
On the master, you must enable binary logging and configure a unique server ID. This might require a server restart. See Section 18.1.2.1, “Setting the Replication Master Configuration”.
On each slave that you want to connect to the master, you must configure a unique server ID. This might require a server restart. See Section 18.1.2.5.1, “Setting the Replication Slave Configuration”.
Optionally, create a separate user for your slaves to use during authentication with the master when reading the binary log for replication. See Section 18.1.2.2, “Creating a User for Replication”.
Before creating a data snapshot or starting the replication process, on the master you should record the current position in the binary log. You need this information when configuring the slave so that the slave knows where within the binary log to start executing events. See Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”.
If you already have data on the master and want to use it to
synchronize the slave, you need to create a data snapshot to
copy the data to the slave. The storage engine you are using
has an impact on how you create the snapshot. When you are
using MyISAM
, you must stop
processing statements on the master to obtain a read-lock,
then obtain its current binary log coordinates and dump its
data, before permitting the master to continue executing
statements. If you do not stop the execution of statements,
the data dump and the master status information will not
match, resulting in inconsistent or corrupted databases on the
slaves. For more information on replicating a
MyISAM
master, see
Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”. If you are
using InnoDB
, you do not need a
read-lock and a transaction that is long enough to transfer
the data snapshot is sufficient. For more information, see
Section 15.19, “InnoDB and MySQL Replication”.
Configure the slave with settings for connecting to the master, such as the host name, login credentials, and binary log file name and position. See Section 18.1.2.5.2, “Setting the Master Configuration on the Slave”.
Certain steps within the setup process require the
SUPER
privilege. If you do not
have this privilege, it might not be possible to enable
replication.
After configuring the basic options, select your scenario:
To set up replication for a fresh installation of a master and slaves that contain no data, see Section 18.1.2.5.3, “Setting Up Replication between a New Master and Slaves”.
To set up replication of a new master using the data from an existing MySQL server, see Section 18.1.2.5.4, “Setting Up Replication with Existing Data”.
To add replication slaves to an existing replication environment, see Section 18.1.2.6, “Adding Slaves to a Replication Environment”.
Before administering MySQL replication servers, read this entire chapter and try all statements mentioned in Section 14.4.1, “SQL Statements for Controlling Master Servers”, and Section 14.4.2, “SQL Statements for Controlling Slave Servers”. Also familiarize yourself with the replication startup options described in Section 18.1.6, “Replication and Binary Logging Options and Variables”.
To configure a master to use binary log file position based replication, you must enable binary logging and establish a unique server ID. If this has not already been done, a server restart is required.
Binary logging must be enabled on the
master because the binary log is the basis for replicating
changes from the master to its slaves. If binary logging is not
enabled on the master using the log-bin
option, replication is not possible.
Each server within a replication group must be configured with a unique server ID. This ID is used to identify individual servers within the group, and must be a positive integer between 1 and (232)−1. How you organize and select the numbers is your choice.
To configure the binary log and server ID options, shut down the
MySQL server and edit the my.cnf
or
my.ini
file. Within the
[mysqld]
section of the configuration file,
add the log-bin
and
server-id
options. If these options already
exist, but are commented out, uncomment the options and alter
them according to your needs. For example, to enable binary
logging using a log file name prefix of
mysql-bin
, and configure a server ID of 1,
use these lines:
[mysqld] log-bin=mysql-bin server-id=1
After making the changes, restart the server.
The following options have an impact on this procedure:
if you omit server-id
(or
set it explicitly to its default value of 0), the master
refuses any connections from slaves.
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
and
sync_binlog=1
in the master
my.cnf
file.
Ensure that the
skip-networking
option is
not enabled on your replication master. If networking has
been disabled, the slave cannot communicate with the
master and replication fails.
Each slave connects to the master using a MySQL user name and
password, so there must be a user account on the master that the
slave can use to connect. Any account can be used for this
operation, providing it has been granted the
REPLICATION SLAVE
privilege. You
can choose to create a different account for each slave, or
connect to the master using the same account for each slave.
Although you do not have to create an account specifically for replication, you should be aware that the replication user name and password are stored in plain text in the master info repository file or table (see Section 18.2.4.2, “Slave Status Logs”). Therefore, you may want to create a separate account that has privileges only for the replication process, to minimize the possibility of compromise to other accounts.
To create a new account, use CREATE
USER
. To grant this account the privileges required
for replication, use the GRANT
statement. If you create an account solely for the purposes of
replication, that account needs only the
REPLICATION SLAVE
privilege. For
example, to set up a new user, repl
, that can
connect for replication from any host within the
mydomain.com
domain, issue these statements
on the master:
mysql>CREATE USER 'repl'@'%.mydomain.com' IDENTIFIED BY 'slavepass';
mysql>GRANT REPLICATION SLAVE ON *.* TO 'repl'@'%.mydomain.com';
See Section 14.7.1, “Account Management Statements”, for more information on statements for manipulation of user accounts.
To configure the slave to start the replication process at the correct point, you need the master's current coordinates within its binary log.
If the master has been running previously without binary logging
enabled, the log file name and position values displayed by
SHOW MASTER STATUS
or
mysqldump --master-data are 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
.
If the master has been binary logging previously, use this procedure to obtain the master binary log coordinates:
This procedure uses
FLUSH TABLES WITH READ
LOCK
, which blocks
COMMIT
operations for
InnoDB
tables.
Start a session on the master by connecting to it with the
command-line client, and flush all tables and block write
statements by executing the
FLUSH TABLES WITH
READ LOCK
statement:
mysql> FLUSH TABLES WITH READ LOCK;
Leave the client from which you issued the
FLUSH
TABLES
statement running so that the read lock
remains in effect. If you exit the client, the lock is
released.
In a different session on the master, use the
SHOW MASTER STATUS
statement
to determine the current binary log file name and position:
mysql > SHOW MASTER STATUS;
+------------------+----------+--------------+------------------+
| File | Position | Binlog_Do_DB | Binlog_Ignore_DB |
+------------------+----------+--------------+------------------+
| mysql-bin.000003 | 73 | test | manual,mysql |
+------------------+----------+--------------+------------------+
The File
column shows the name of the log
file and the Position
column shows the
position within the file. In this example, the binary log
file is mysql-bin.000003
and the position
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.
You now have the information you need to enable the slave to start reading from the binary log in the correct place to start replication.
The next step depends on whether you have existing data on the master. Choose one of the following options:
If you have existing data that needs be to synchronized with the slave before you start replication, leave the client running so that the lock remains in place. This prevents any further changes being made, so that the data copied to the slave is in synchrony with the master. Proceed to Section 18.1.2.4, “Choosing a Method for Data Snapshots”.
If you are setting up a new master and slave replication group, you can exit the first session to release the read lock. See Section 18.1.2.5.3, “Setting Up Replication between a New Master and Slaves” for how to proceed.
If the master database contains existing data it is necessary to copy this data to each slave. There are different ways to dump the data from the master database. The following sections describe possible options.
To select the appropriate method of dumping the database, choose between these options:
Use the mysqldump tool to create a dump
of all the databases you want to replicate. This is the
recommended method, especially when using
InnoDB
.
If your database is stored in binary portable files, you can
copy the raw data files to a slave. This can be more
efficient than using mysqldump and
importing the file on each slave, because it skips the
overhead of updating indexes as the
INSERT
statements are replayed. With
storage engines such as InnoDB
this is not recommended.
To create a snapshot of the data in an existing master database, use the mysqldump tool. Once the data dump has been completed, import this data into the slave before starting the replication process.
The following example dumps all databases to a file named
dbdump.db
, and includes the
--master-data
option which
automatically appends the CHANGE MASTER
TO
statement required on the slave to start the
replication process:
shell> mysqldump --all-databases --master-data > dbdump.db
If you do not use
--master-data
, then it is
necessary to lock all tables in a separate session manually.
See Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”.
It is possible to exclude certain databases from the dump
using the mysqldump tool. If you want to
choose which databases to include in the dump, do not use
--all-databases
. Choose one
of these options:
Exclude all the tables in the database using
--ignore-table
option.
Name only those databases which you want dumped using the
--databases
option.
For more information, see Section 5.5.4, “mysqldump — A Database Backup Program”.
To import the data, either copy the dump file to the slave, or access the file from the master when connecting remotely to the slave.
This section describes how to create a data snapshot using the raw files which make up the database. Employing this method with a table using a storage engine that has complex caching or logging algorithms requires extra steps to produce a perfect “point in time” snapshot: the initial copy command could leave out cache information and logging updates, even if you have acquired a global read lock. How the storage engine responds to this depends on its crash recovery abilities.
If you use InnoDB
tables, you can
use the mysqlbackup command from the MySQL
Enterprise Backup component to produce a consistent snapshot.
This command records the log name and offset corresponding to
the snapshot to be used on the slave. MySQL Enterprise Backup
is a commercial product that is included as part of a MySQL
Enterprise subscription. See
Section 29.2, “MySQL Enterprise Backup Overview” for detailed
information.
This method also does not work reliably if the master and
slave have different values for
ft_stopword_file
,
ft_min_word_len
, or
ft_max_word_len
and you are
copying tables having full-text indexes.
Assuming the above exceptions do not apply to your database,
use the cold
backup technique to obtain a reliable binary snapshot
of InnoDB
tables: do a
slow shutdown of the
MySQL Server, then copy the data files manually.
To create a raw data snapshot of
MyISAM
tables when your MySQL
data files exist on a single file system, you can use standard
file copy tools such as cp or
copy, a remote copy tool such as
scp or rsync, an
archiving tool such as zip or
tar, or a file system snapshot tool such as
dump. If you are replicating only certain
databases, copy only those files that relate to those tables.
For InnoDB
, all tables in all databases are
stored in the system
tablespace files, unless you have the
innodb_file_per_table
option
enabled.
The following files are not required for replication:
Files relating to the mysql
database.
The master info repository file, if used (see Section 18.2.4, “Replication Relay and Status Logs”).
The master's binary log files.
Any relay log files.
Depending on whether you are using InnoDB
tables or not, choose one of the following:
If you are using InnoDB
tables,
and also to get the most consistent results with a raw data
snapshot, shut down the master server during the process, as
follows:
Acquire a read lock and get the master's status. See Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”.
In a separate session, shut down the master server:
shell> mysqladmin shutdown
Make a copy of the MySQL data files. The following examples show common ways to do this. You need to choose only one of them:
shell>tar cf
shell>/tmp/db.tar
./data
zip -r
shell>/tmp/db.zip
./data
rsync --recursive
./data
/tmp/dbdata
Restart the master server.
If you are not using InnoDB
tables, you can get a snapshot of the system from a master
without shutting down the server as described in the following
steps:
Acquire a read lock and get the master's status. See Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”.
Make a copy of the MySQL data files. The following examples show common ways to do this. You need to choose only one of them:
shell>tar cf
shell>/tmp/db.tar
./data
zip -r
shell>/tmp/db.zip
./data
rsync --recursive
./data
/tmp/dbdata
In the client where you acquired the read lock, release the lock:
mysql> UNLOCK TABLES;
Once you have created the archive or copy of the database, copy the files to each slave before starting the slave replication process.
The following sections describe how to set up slaves. Before you proceed, ensure that you have:
Configured the MySQL master with the necessary configuration properties. See Section 18.1.2.1, “Setting the Replication Master Configuration”.
Obtained the master status information. See Section 18.1.2.3, “Obtaining the Replication Master Binary Log Coordinates”.
On the master, released the read lock:
mysql> UNLOCK TABLES;
Each replication slave must have a unique server ID. If this has not already been done, this part of slave setup requires a server restart.
If the slave server ID is not already set, or the current
value conflicts with the value that you have chosen for the
master server, shut down the slave server and edit the
[mysqld]
section of the configuration file
to specify a unique server ID. For example:
[mysqld] server-id=2
After making the changes, restart the server.
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 any of the other
slaves.
If you omit server-id
(or set
it explicitly to its default value of 0), the slave refuses
to connect to a master.
You do not have to enable binary logging on the slave for replication to be set up. However, if you enable binary logging on the slave, you can use the slave's binary log for data backups and crash recovery, and also use the slave as part of a more complex replication topology. For example, where this slave then acts as a master to other slaves.
To set up the slave to communicate with the master for replication, configure the slave with the necessary connection information. To do this, 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
;
Replication cannot use Unix socket files. You must be able to connect to the master MySQL server using TCP/IP.
The CHANGE MASTER TO
statement
has other options as well. For example, it is possible to set
up secure replication using SSL. For a full list of options,
and information about the maximum permissible length for the
string-valued options, see Section 14.4.2.1, “CHANGE MASTER TO Syntax”.
The next steps depend on whether you have existing data to import to the slave or not. See Section 18.1.2.4, “Choosing a Method for Data Snapshots” for more information. Choose one of the following:
If you do not have a snapshot of a database to import, see Section 18.1.2.5.3, “Setting Up Replication between a New Master and Slaves”.
If you have a snapshot of a database to import, see Section 18.1.2.5.4, “Setting Up Replication with Existing Data”.
When there is no snapshot of a previous database to import, configure the slave to start the replication from the new master.
To set up replication between a master and a new slave:
Start up the MySQL slave and connect to it.
Execute a CHANGE MASTER TO
statement to set the master replication server
configuration. See
Section 18.1.2.5.2, “Setting the Master Configuration on the Slave”.
Perform these slave setup steps on each slave.
This method can also be used if you are setting up new servers but have an existing dump of the databases from a different server that you want to load into your replication configuration. By loading the data into a new master, the data is automatically replicated to the slaves.
If you are setting up a new replication environment using the data from a different existing database server to create a new master, run the dump file generated from that server on the new master. The database updates are automatically propagated to the slaves:
shell> mysql -h master < fulldb.dump
When setting up replication with existing data, transfer the snapshot from the master to the slave before starting replication. The process for importing data to the slave depends on how you created the snapshot of data on the master.
Choose one of the following:
If you used mysqldump:
Start the slave, using the
--skip-slave-start
option
so that replication does not start.
Import the dump file:
shell> mysql < fulldb.dump
If you created a snapshot using the raw data files:
Extract the data files into your slave data directory. For example:
shell> tar xvf dbdump.tar
You may need to set permissions and ownership on the files so that the slave server can access and modify them.
Start the slave, using the
--skip-slave-start
option
so that replication does not start.
Configure the slave with the replication coordinates from
the master. This tells the slave the binary log file and
position within the file where replication needs to start.
Also, configure the slave with the login credentials and
host name of the master. For more information on the
CHANGE MASTER TO
statement
required, see
Section 18.1.2.5.2, “Setting the Master Configuration on the Slave”.
Start the slave threads:
mysql> START SLAVE;
After you have performed this procedure, the slave connects to the master and replicates any updates that have occurred on the master since the snapshot was taken.
If the server-id
option for the
master is not correctly set, slaves cannot connect to it.
Similarly, if you have not set the
server-id
option correctly 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.
The slave stores information about the master you have
configured in its master info repository. The master info
repository can be in the form of files or a table, as
determined by the value set for
--master-info-repository
. When
a slave uses --master-info-repository=FILE
,
two files are stored in the data directory, named
master.info
and
relay-log.info
. If
--master-info-repository=TABLE
instead, this
information is saved in the
master_slave_info
table in the
mysql
database. In either case, do
not remove or edit the files or table.
Always use the CHANGE MASTER TO
statement to change replication parameters. The slave can use
the values specified in the statement to update the status
files automatically. See Section 18.2.4, “Replication Relay and Status Logs”, for
more information.
The contents of the master info repository override some of
the server options specified on the command line or in
my.cnf
. See
Section 18.1.6, “Replication and Binary Logging Options and Variables”, for more details.
A single snapshot of the master suffices for multiple slaves. To set up additional slaves, use the same master snapshot and follow the slave portion of the procedure just described.
You can add another slave to an existing replication
configuration without stopping the master. Instead, set up the
new slave by making a copy of an existing slave, except that you
configure the new slave with a different
server-id
value.
To duplicate an existing slave:
Shut down the existing slave:
shell> mysqladmin shutdown
Copy the data directory from the existing slave to the new
slave. You can do this by creating an archive using
tar or WinZip
, or by
performing a direct copy using a tool such as
cp or rsync. Ensure
that you also copy the log files and relay log files.
A common problem that is encountered when adding new replication slaves is that the new slave fails with a series of warning and error messages like these:
071118 16:44:10 [Warning] Neither --relay-log nor --relay-log-index were used; so replication may break when this MySQL server acts as a slave and has his hostname changed!! Please use '--relay-log=new_slave_hostname
-relay-bin' to avoid this problem. 071118 16:44:10 [ERROR] Failed to open the relay log './old_slave_hostname
-relay-bin.003525' (relay_log_pos 22940879) 071118 16:44:10 [ERROR] Could not find target log during relay log initialization 071118 16:44:10 [ERROR] Failed to initialize the master info structure
This situation can occur if the
--relay-log
option is not
specified, as the relay log files contain the host name as
part of their file names. This is also true of the relay log
index file if the
--relay-log-index
option is
not used. See Section 18.1.6, “Replication and Binary Logging Options and Variables”, for
more information about these options.
To avoid this problem, use the same value for
--relay-log
on the new slave
that was used on the existing slave. If this option was not
set explicitly on the existing slave, use
.
If this is not possible, copy the existing slave's relay log
index file to the new slave and set the
existing_slave_hostname
-relay-bin--relay-log-index
option on
the new slave to match what was used on the existing slave.
If this option was not set explicitly on the existing slave,
use
.
Alternatively, if you have already tried to start the new
slave after following the remaining steps in this section
and have encountered errors like those described previously,
then perform the following steps:
existing_slave_hostname
-relay-bin.index
If you have not already done so, issue a
STOP SLAVE
on the new
slave.
If you have already started the existing slave again,
issue a STOP SLAVE
on the
existing slave as well.
Copy the contents of the existing slave's relay log index file into the new slave's relay log index file, making sure to overwrite any content already in the file.
Proceed with the remaining steps in this section.
Copy the master info and relay log info repositories (see Section 18.2.4, “Replication Relay and Status Logs”) from the existing slave to the new slave. These hold the current log coordinates for the master's binary log and the slave's relay log.
Start the existing slave.
On the new slave, edit the configuration and give the new
slave a unique server-id
not
used by the master or any of the existing slaves.
Start the new slave. The slave uses the information in its master info repository to start the replication process.
This section explains transaction-based replication using global transaction identifiers (GTIDs). When using GTIDs, each transaction can be identified and tracked as it is committed on the originating server and applied by any slaves; this means that it is not necessary when using GTIDs to refer to log files or positions within those files when starting a new slave or failing over to a new master, which greatly simplifies these tasks. Because GTID-based replication is completely transaction-based, it is simple to determine whether masters and slaves are consistent; as long as all transactions committed on a master are also committed on a slave, consistency between the two is guaranteed. You can use either statement-based or row-based replication with GTIDs (see Section 18.2.1, “Replication Formats”); however, for best results, we recommend that you use the row-based format.
This section discusses the following topics:
How GTIDs are defined and created, and how they are represented in the MySQL Server (see Section 18.1.3.1, “GTID Concepts”).
A general procedure for setting up and starting GTID-based replication (see Section 18.1.3.2, “Setting Up Replication Using GTIDs”).
Suggested methods for provisioning new replication servers when using GTIDs (see Section 18.1.3.3, “Using GTIDs for Failover and Scaleout”).
Restrictions and limitations that you should be aware of when using GTID-based replication (see Section 18.1.3.4, “Restrictions on Replication with GTIDs”).
For information about MySQL Server options and variables relating to GTID-based replication, see Section 18.1.6.5, “Global Transaction ID Options and Variables”. See also Section 13.17, “Functions Used with Global Transaction IDs”, which describes SQL functions supported by MySQL 5.7 for use with GTIDs.
A global transaction identifier (GTID) is a unique identifier created and associated with each transaction committed on the server of origin (master). This identifier is unique not only to the server on which it originated, but is unique across all servers in a given replication setup. There is a 1-to-1 mapping between all transactions and all GTIDs.
The following paragraphs provide a basic description of GTIDs. More advanced concepts are covered later in the following sections:
A GTID is represented as a pair of coordinates, separated by a
colon character (:
), as shown here:
GTID =source_id
:transaction_id
The source_id
identifies the
originating server. Normally, the server's
server_uuid
is used for this
purpose. The transaction_id
is a
sequence number determined by the order in which the transaction
was committed on this server; for example, the first transaction
to be committed has 1
as its
transaction_id
, and the tenth
transaction to be committed on the same originating server is
assigned a transaction_id
of
10
. It is not possible for a transaction to
have 0
as a sequence number in a GTID. For
example, the twenty-third transaction to be committed originally
on the server with the UUID
3E11FA47-71CA-11E1-9E33-C80AA9429562
has this
GTID:
3E11FA47-71CA-11E1-9E33-C80AA9429562:23
This format is used to represent GTIDs in the output of statements
such as SHOW SLAVE STATUS
as well
as in the binary log. They can also be seen when viewing the log
file with mysqlbinlog
--base64-output=DECODE-ROWS
or
in the output from SHOW BINLOG
EVENTS
.
As written in the output of statements such as
SHOW MASTER STATUS
or SHOW
SLAVE STATUS
, a sequence of GTIDs originating from the
same server may be collapsed into a single expression, as shown
here.
3E11FA47-71CA-11E1-9E33-C80AA9429562:1-5
The example just shown represents the first through fifth
transactions originating on the MySQL Server whose
server_uuid
is
3E11FA47-71CA-11E1-9E33-C80AA9429562
.
This format is also used to supply the argument required by the
START SLAVE
options
SQL_BEFORE_GTIDS
and
SQL_AFTER_GTIDS
.
A GTID set is a set of global transaction identifiers which is represented as shown here:
gtid_set
:uuid_set
[,uuid_set
] ... | ''uuid_set
:uuid
:interval
[:interval
]...uuid
:hhhhhhhh
-hhhh
-hhhh
-hhhh
-hhhhhhhhhhhh
h
: [0-9|A-F]interval
:n
[-n
] (n
>= 1)
GTID sets are used in the MySQL Server in several ways. For
example, the values stored by the
gtid_executed
and
gtid_purged
system variables
are represented as GTID sets. In addition, the functions
GTID_SUBSET()
and
GTID_SUBTRACT()
require GTID sets
as input. When GTID sets are returned from server variables,
UUIDs are in alphabetical order and numeric intervals are merged
and in ascending order.
GTIDs are always preserved between master and slave. This means that you can always determine the source for any transaction applied on any slave by examining its binary log. In addition, once a transaction with a given GTID is committed on a given server, any subsequent transaction having the same GTID is ignored by that server. Thus, a transaction committed on the master can be applied no more than once on the slave, which helps to guarantee consistency.
When GTIDs are in use, the slave has no need for any nonlocal
data, such as the name of a file on the master and a position
within that file. All necessary information for synchronizing
with the master is obtained directly from the replication data
stream. GTIDs replace the file-offset pairs previously required
to determine points for starting, stopping, or resuming the flow
of data between master and slave. therefore, do not include
MASTER_LOG_FILE
or
MASTER_LOG_POS
options in the
CHANGE MASTER TO
statement used
to direct a slave to replicate from a given master; instead it
is necessary only to enable the
MASTER_AUTO_POSITION
option. For the exact
steps needed to configure and start masters and slaves using
GTID-based replication, see
Section 18.1.3.2, “Setting Up Replication Using GTIDs”.
The generation and life cycle of a GTID consist of the following steps:
A transaction is executed and committed on the master.
This transaction is assigned a GTID using the master's UUID and the smallest nonzero transaction sequence number not yet used on this server; the GTID is written to the master's binary log (immediately preceding the transaction itself in the log).
After the binary log data is transmitted to the slave and
stored in the slave's relay log (using established
mechanisms for this process—see
Section 18.2, “Replication Implementation”, for details),
the slave reads the GTID and sets the value of its
gtid_next
system variable
as this GTID. This tells the slave that the next transaction
must be logged using this GTID.
It is important to note that the slave sets
gtid_next
in a session context.
The slave verifies that this GTID has not already been used to log a transaction in its own binary log. If this GTID has not been used, the slave then writes the GTID, applies the transaction, and writes the transaction to its binary log. By reading and checking the transaction's GTID first, before processing the transaction itself, the slave guarantees not only that no previous transaction having this GTID has been applied on the slave, but also that no other session has already read this GTID but has not yet committed the associated transaction. In other words, multiple clients are not permitted to apply the same transaction concurrently.
Because gtid_next
is not
empty, the slave does not attempt to generate a GTID for
this transaction but instead writes the GTID stored in this
variable—that is, the GTID obtained from the
master—immediately preceding the transaction in its
binary log.
Beginning with MySQL 5.7.5, GTIDs are stored in a table named
gtid_executed
, in the
mysql
database. A row in this table contains,
for each GTID or set of GTIDs that it represents, the UUID of
the originating server, and the starting and ending transaction
IDs of the set; for a row referencing only a single GTID, these
last two values are the same.
The mysql.gtid_executed
table is created (if
it does not already exist) when the MySQL Server is installed or
upgraded, using a CREATE TABLE
statement similar to that shown here:
CREATE TABLE gtid_executed ( source_uuid CHAR(36) NOT NULL, interval_start BIGINT(20) NOT NULL, interval_end BIGINT(20) NOT NULL, PRIMARY KEY (source_uuid, interval_start) )
As with other MySQL system tables, do not attempt to create or modify this table yourself.
GTIDs are stored in the mysql.gtid_executed
table only when gtid_mode
is
ON
or ON_PERMISSIVE
. GTIDs
are stored in this table without regard to whether binary
logging is enabled. However, the manner in which they are stored
differs depending on whether
log_bin
is
ON
or OFF
:
If binary logging is disabled (log_bin
is
OFF
), the server stores the GTID
belonging to each transaction together with the transaction
in the table.
In addition, when binary logging is disabled, this table is compressed periodically at a user-configurable rate; see mysql.gtid_executed Table Compression, for more information.
If binary logging is enabled (log_bin
is
ON
), then in addition to storing the
GTIDs in mysql.gtid_executed
, whenever
the binary log is rotated or the server is shut down, the
server writes GTIDs for all transactions that were written
into the previous binary log into the new binary log.
In the event of the server stopping unexpectedly, the set of
GTIDs from the previous binary log is not saved in the
mysql.gtid_executed
table. In this case,
these GTIDs are added to the table and to the set of GTIDs
in the gtid_executed
system
variable during recovery.
The mysql.gtid_executed
table is reset by
RESET MASTER
.
Over the course of time, the
mysql.gtid_executed
table can become filled
with many rows referring to individual GTIDs that originate on
the same server, and whose transaction IDs make up a sequence,
similar to what is shown here:
mysql> SELECT * FROM mysql.gtid_executed;
+--------------------------------------+----------------+--------------+
| source_uuid | interval_start | interval_end |
|--------------------------------------+----------------+--------------|
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 37 | 37 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 38 | 38 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 39 | 39 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 40 | 40 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 41 | 41 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 42 | 42 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 43 | 43 |
...
Considerable space can be saved if this table is compressed periodically by replacing each such set of rows with a single row that spans the entire interval of transaction identifiers, like this:
+--------------------------------------+----------------+--------------+ | source_uuid | interval_start | interval_end | |--------------------------------------+----------------+--------------| | 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 37 | 43 | ...
When GTIDs are enabled, the server performs this type of
compression on the mysql.gtid_executed
table
periodically. You can control the number of transactions that
are allowed to elapse before the table is compressed, and thus
the compression rate, by setting the
executed_gtids_compression_period
system variable. This variable's default value is 1000;
this means that, by default, compression of the table is
performed after each 1000 transactions. Setting
executed_gtid_compression_period
to 0
prevents the compression from being performed at all; however,
you should be prepared for a potentially large increase in the
amount of disk space that may be required by the
gtid_executed
table if you do this.
When binary logging is enabled, the value of
executed_gtids_compression_period
is not used and the
mysql.gtid_executed
table is compressed on
each binary log rotation.
Compression of the mysql.gtid_executed
table
is performed by a dedicated foreground thread that is created
whenever GTIDs are enabled on the server. This thread is not
listed in the output of SHOW
PROCESSLIST
, but it can be viewed as a row in the
threads
table, as shown here:
mysql> SELECT * FROM PERFORMANCE_SCHEMA.THREADS WHERE NAME LIKE '%gtid%'\G
*************************** 1. row ***************************
THREAD_ID: 21
NAME: thread/sql/compress_gtid_table
TYPE: FOREGROUND
PROCESSLIST_ID: 139635685943104
PROCESSLIST_USER: NULL
PROCESSLIST_HOST: NULL
PROCESSLIST_DB: NULL
PROCESSLIST_COMMAND: Daemon
PROCESSLIST_TIME: 611
PROCESSLIST_STATE: Suspending
PROCESSLIST_INFO: NULL
PARENT_THREAD_ID: 1
ROLE: NULL
INSTRUMENTED: YES
This thread has the name
thread/sql/compress_gtid_table
, and normally
sleeps until
executed_gtids_compression_period
transactions have been executed, then wakes up to perform
compression of the mysql.gtid_executed
table
as described previously. It then sleeps until another
executed_gtids_compression_period
transactions have taken place, then wakes up to perform the
compression again, repeating this loop indefinitely. Setting
this value to 0 when binary logging is disabled means that the
thread always sleeps and never wakes up.
This section describes a process for configuring and starting GTID-based replication in MySQL 5.7. This is a “cold start” procedure that assumes either that you are starting the replication master for the first time, or that it is possible to stop it; for information about provisioning replication slaves using GTIDs from a running master, see Section 18.1.3.3, “Using GTIDs for Failover and Scaleout”. For information about changing GTID mode on servers online, see Section 18.1.5, “Changing Replication Modes on Online Servers”.
The key steps in this startup process for the simplest possible GTID replication topology—consisting of one master and one slave—are as follows:
If replication is already running, synchronize both servers by making them read-only.
Stop both servers.
Restart both servers with GTIDs enabled and the correct options configured.
The mysqld options necessary to start the servers as described are discussed in the example that follows later in this section.
server_uuid
must exist for
GTIDs to function correctly.
Instruct the slave to use the master as the replication data source and to use auto-positioning, and then start the slave.
The SQL statements needed to accomplish this step are described in the example that follows later in this section.
Enable read mode again on both servers, so that they can accept updates.
In the following example, two servers are already running as master and slave, using MySQL's binary log position-based replication protocol. If you are starting with new servers, see Section 18.1.2.2, “Creating a User for Replication” for information about adding a specific user for replication connections and Section 18.1.2.1, “Setting the Replication Master Configuration” for information about setting the server-id. The following examples show how to use startup options when running mysqld. Alternatively you can store startup options in an option file, see Section 5.2.6, “Using Option Files” for more information.
Most of the steps that follow require the use of the MySQL
root
account or another MySQL user account that
has the SUPER
privilege.
mysqladmin shutdown
requires
either the SUPER
privilege or the
SHUTDOWN
privilege.
Step 1: Synchronize the servers.
Make the servers read-only. To do this, enable the
read_only
system variable by
executing the following statement on both servers:
mysql> SET @@global.read_only = ON;
Then, allow the slave to catch up with the master. It is extremely important that you make sure the slave has processed all updates before continuing.
Step 2: Stop both servers.
Stop each server using mysqladmin as shown
here, where username
is the user name
for a MySQL user having sufficient privileges to shut down the
server:
shell> mysqladmin -uusername
-p shutdown
Then supply this user's password at the prompt.
Step 3: Restart both servers with GTIDs enabled.
To enable GTID-based replication, each server must be started
with GTID mode enabled, by setting the
--gtid-mode
option to
ON
, and with the
--enforce-gtid-consistency
option
enabled to ensure that only statements which are safe for
GTID-based replication are logged. In addition, you should start
the slave with the
--skip-slave-start
option before
configuring the slave settings. For more information on GTID
related options, see
Section 18.1.6.5, “Global Transaction ID Options and Variables”.
It is not mandatory to have binary logging enabled in order to use GTIDs due to the addition of the mysql.gtid_executed Table in MySQL 5.7.5. This means that you can have slave servers using GTIDs but without binary logging. Masters must always have binary logging enabled in order to be able to replicate. For example, to start a slave with GTIDs enabled but without binary logging, use at least these options:
shell> mysqld --gtid-mode=ON --enforce-gtid-consistency &
In MySQL 5.7.4 and earlier, binary logging is required to use GTIDs and both master and slave servers must be started with at least these options:
shell> mysqld --gtid-mode=ON --log-bin --enforce-gtid-consistency &
Depending on your configuration, supply additional options to mysqld.
Step 4: Direct the slave to use the master.
Tell the slave to use the master as the replication data source,
and to use GTID-based auto-positioning rather than file-based
positioning. Execute a CHANGE MASTER
TO
statement on the slave, using the
MASTER_AUTO_POSITION
option to tell the slave
that transactions will be identified by GTIDs.
You may also need to supply appropriate values for the master's host name and port number as well as the user name and password for a replication user account which can be used by the slave to connect to the master; if these have already been set prior to Step 1 and no further changes need to be made, the corresponding options can safely be omitted from the statement shown here.
mysql>CHANGE MASTER TO
>MASTER_HOST =
>host
,MASTER_PORT =
>port
,MASTER_USER =
>user
,MASTER_PASSWORD =
>password
,MASTER_AUTO_POSITION = 1;
Neither the MASTER_LOG_FILE
option nor the
MASTER_LOG_POS
option may be used with
MASTER_AUTO_POSITION
set equal to 1. Attempting
to do so causes the CHANGE MASTER
TO
statement to fail with an error.
Assuming that the CHANGE MASTER TO
statement
has succeeded, you can then start the slave, like this:
mysql> START SLAVE;
Step 5: Disable read-only mode. Allow the master to begin accepting updates once again by running the following statement:
mysql> SET @@global.read_only = OFF;
GTID-based replication should now be running, and you can begin (or resume) activity on the master as before. Section 18.1.3.3, “Using GTIDs for Failover and Scaleout”, discusses creation of new slaves when using GTIDs.
There are a number of techniques when using MySQL Replication with Global Transaction Identifiers (GTIDs) for provisioning a new slave which can then be used for scaleout, being promoted to master as necessary for failover. This section describes the following techniques:
Global transaction identifiers were added to MySQL Replication for the purpose of simplifying in general management of the replication data flow and of failover activities in particular. Each identifier uniquely identifies a set of binary log events that together make up a transaction. GTIDs play a key role in applying changes to the database: the server automatically skips any transaction having an identifier which the server recognizes as one that it has processed before. This behavior is critical for automatic replication positioning and correct failover.
The mapping between identifiers and sets of events comprising a given transaction is captured in the binary log. This poses some challenges when provisioning a new server with data from another existing server. To reproduce the identifier set on the new server, it is necessary to copy the identifiers from the old server to the new one, and to preserve the relationship between the identifiers and the actual events. This is neccessary for restoring a slave that is immediately available as a candidate to become a new master on failover or switchover.
Simple replication. The easiest way to reproduce all identifiers and transactions on a new server is to make the new server into the slave of a master that has the entire execution history, and enable global transaction identifiers on both servers. See Section 18.1.3.2, “Setting Up Replication Using GTIDs”, for more information.
Once replication is started, the new server copies the entire binary log from the master and thus obtains all information about all GTIDs.
This method is simple and effective, but requires the slave to read the binary log from the master; it can sometimes take a comparatively long time for the new slave to catch up with the master, so this method is not suitable for fast failover or restoring from backup. This section explains how to avoid fetching all of the execution history from the master by copying binary log files to the new server.
Copying data and transactions to the slave. Playing back the entire transaction history can be time-consuming, and represents a major bottleneck when setting up a new replication slave. To eliminate this requirement, a snapshot of the data set, the binary logs and the global transaction information the master contains is imported to the slave. The binary log is played back, after which replication can be started, allowing the slave to become current with any remaining transactions.
There are several variants of this method, the difference being in the manner in which data dumps and transactions from binary logs are transfered to the slave, as outlined here:
Data Set | Transaction History |
---|---|
|
If
|
See also Section 5.6.7.3, “Using mysqlbinlog to Back Up Binary Log Files”.
This method has the advantage that a new server is available almost immediately; only those transactions that were committed while the snapshot or dump file was being replayed still need to be obtained from the existing master. This means that the slave's availability is not instantanteous—but only a relatively short amount of time should be required for the slave to catch up with these few remaining transactions.
Copying over binary logs to the target server in advance is usually faster than reading the entire transaction execution history from the master in real time. However, it may not always be feasible to move these files to the target when required, due to size or other considerations. The two remaining methods for provisioning a new slave discussed in this section use other means to transfer information about transactions to the new slave.
Injecting empty transactions.
The master's global
gtid_executed
variable contains
the set of all transactions executed on the master. Rather than
copy the binary logs when taking a snapshot to provision a new
server, you can instead note the content of
gtid_executed
on the server from which the
snapshot was taken. Before adding the new server to the
replication chain, simply commit an empty transaction on the new
server for each transaction identifier contained in the
master's gtid_executed
, like this:
SET GTID_NEXT='aaa-bbb-ccc-ddd:N'; BEGIN; COMMIT; SET GTID_NEXT='AUTOMATIC';
Once all transaction identifiers have been reinstated in this way
using empty transactions, you must flush and purge the
slave's binary logs, as shown here, where
N
is the nonzero suffix of the current
binary log file name:
FLUSH LOGS;
PURGE BINARY LOGS TO 'master-bin.00000N
';
You should do this to prevent this server from flooding the
replication stream with false transactions in the event that it is
later promoted to master. (The
FLUSH LOGS
statement forces the creation of a new binary log file;
PURGE BINARY LOGS
purges the empty
transactions, but retains their identifiers.)
This method creates a server that is essentially a snapshot, but in time is able to become a master as its binary log history converges with that of the replication stream (that is, as it catches up with the master or masters). This outcome is similar in effect to that obtained using the remaining provisioning method, which we discuss in the next few paragraphs.
Excluding transactions with gtid_purged.
The master's global
gtid_purged
variable contains
the set of all transactions that have been purged from the
master's binary log. As with the method discussed
previously (see
Injecting empty transactions), you can
record the value of
gtid_executed
on the server
from which the snapshot was taken (in place of copying the
binary logs to the new server). Unlike the previous method,
there is no need to commit empty transactions (or to issue
PURGE BINARY LOGS
); instead, you
can set gtid_purged
on the
slave directly, based on the value of
gtid_executed
on the server
from which the backup or snapshot was taken.
As with the method using empty transactions, this method creates a server that is functionally a snapshot, but in time is able to become a master as its binary log history converges with that of the replication master or group.
Restoring GTID mode slaves. When restoring a slave in a GTID based replication setup that has encountered an error, injecting an empty transaction may not solve the problem because an event does not have a GTID.
Use mysqlbinlog to find the next transaction,
which is probably the first transaction in the next log file after
the event. Copy everything up to the
COMMIT
for that transaction, being
sure to include the SET @@SESSION.GTID_NEXT
.
Even if you are not using row-based replication, you can still run
binary log row events in the command line client.
Stop the slave and run the transaction you copied. The
mysqlbinlog output sets the delimiter to
/*!*/;
, so set it back:
mysql> DELIMITER ;
Restart replication from the correct position automatically:
mysql>SET GTID_NEXT=automatic;
mysql>RESET SLAVE;
mysql>START SLAVE;
Because GTID-based replication is dependent on transactions, some features otherwise available in MySQL are not supported when using it. This section provides information about restrictions on and limitations of replication with GTIDs.
Updates involving nontransactional storage engines.
When using GTIDs, updates to tables using nontransactional
storage engines such as MyISAM
cannot be made in the same statement or transaction as updates
to tables using transactional storage engines such as
InnoDB
.
This restriction is due to the fact that updates to tables that use a nontransactional storage engine mixed with updates to tables that use a transactional storage engine within the same transaction can result in multiple GTIDs being assigned to the same transaction.
Such problems can also occur when the master and the slave use different storage engines for their respective versions of the same table, where one storage engine is transactional and the other is not.
In any of the cases just mentioned, the one-to-one correspondence between transactions and GTIDs is broken, with the result that GTID-based replication cannot function correctly.
CREATE TABLE ... SELECT statements.
CREATE
TABLE ... SELECT
is not safe for statement-based
replication. When using row-based replication, this statement is
actually logged as two separate events—one for the
creation of the table, and another for the insertion of rows
from the source table into the new table just created. When this
statement is executed within a transaction, it is possible in
some cases for these two events to receive the same transaction
identifier, which means that the transaction containing the
inserts is skipped by the slave. Therefore, CREATE
TABLE ... SELECT
is not supported when using
GTID-based replication.
Temporary tables.
CREATE TEMPORARY
TABLE
and
DROP TEMPORARY
TABLE
statements are not supported inside transactions
when using GTIDs (that is, when the server was started with the
--enforce-gtid-consistency
option). It is possible to use these statements with GTIDs
enabled, but only outside of any transaction, and only with
autocommit=1
.
Preventing execution of unsupported statements.
To prevent execution of statements that would cause GTID-based
replication to fail, all servers must be started with the
--enforce-gtid-consistency
option
when enabling GTIDs. This causes statements of any of the types
discussed previously in this section to fail with an error.
For information about other required startup options when enabling GTIDs, see Section 18.1.3.2, “Setting Up Replication Using GTIDs”.
sql_slave_skip_counter
is not
supported when using GTIDs. If you need to skip transactions, use
the value of the master's
gtid_executed
variable instead;
see Injecting empty transactions, for more
information.
GTID mode and mysqldump. It is possible to import a dump made using mysqldump into a MySQL Server running with GTID mode enabled, provided that there are no GTIDs in the target server's binary log.
GTID mode and mysql_upgrade.
It is not recommended to use mysql_upgrade
with the --write-binlog
option on a MySQL Server running with
--gtid-mode=ON
because
mysql_upgrade can make
changes to system tables that use the
MyISAM
storage engine, which is
non-transactional.
This section describes MySQL Multi-Source Replication, included in MySQL 5.7.6 and later. Multi-source replication enables you to replicate from multiple immediate masters in parallel. This section describes multi-source replication, and how to configure, monitor and troubleshoot it.
MySQL Multi-Source Replication enables a replication slave to receive transactions from multiple sources simultaneously. Multi-source replication can be used to back up multiple servers to a single server, to merge table shards, and consolidate data from multiple servers to a single server. Multi-source replication does not implement any conflict detection or resolution when applying the transactions, and those tasks are left to the application if required. In a multi-source replication topology, a slave creates a replication channel for each master that it should receive transactions from. See Section 18.2.3, “Replication Channels”. The following sections describe how to set up multi-source replication.
This section provides tutorials on how to configure masters and slaves for multi-source replication, and how to start, stop and reset multi-source slaves.
This section explains how to configure a multi-source replication topology, and provides details about configuring masters and slaves. Such a topology requires at least two masters and one slave configured.
Masters in a multi-source replication topology can be configured to use either global transaction identifier (GTID) based replication, or binary log position-based replication. See Section 18.1.3.2, “Setting Up Replication Using GTIDs” for how to configure a master using GTID based replication. See Section 18.1.2.1, “Setting the Replication Master Configuration” for how to configure a master using file position based replication.
Slaves in a multi-source replication topology require
TABLE
based repositories. Multi-source
replication is not compatible with FILE
based
repositories. The type of repository being used by
mysqld can be configured either at startup,
or dynamically.
To configure the type of repository used by a replication slave at startup, start mysqld with the following options:
--master-info-repository=TABLE --relay-log-info-repository=TABLE
To modify an existing replication slave that is using a
FILE
repository to use
TABLE
repositories, convert the existing
replication repositories dynamically by running the following
commands:
STOP SLAVE;
SET GLOBAL master_info_repository = 'TABLE';
SET GLOBAL relay_log_info_repository = 'TABLE';
This section assumes you have enabled GTID based transactions on
the master using gtid_mode=ON
,
enabled a replication user, and ensured that the slave is using
TABLE
based replication repositories. Use the
CHANGE MASTER TO
statement to add
a new master to a channel by using a FOR CHANNEL
clause. For more
information on replication channels, see
Section 18.2.3, “Replication Channels”
channel
For example, to add a new master with the host name
master1
using port
3451
to a channel called
master-1
:
CHANGE MASTER TO MASTER_HOST='master1', MASTER_USER='rpl', MASTER_PORT=3451, MASTER_PASSWORD='', \
MASTER_AUTO_POSITION = 1 FOR CHANNEL 'master-1';
Multi-source replication is compatible with auto-positioning. See Section 14.4.2.1, “CHANGE MASTER TO Syntax” for more information.
Repeat this process for each extra master that you want to add to a channel, changing the host name, port and channel as appropriate.
This section assumes you have enabled binary logging on the
master using --log-bin
, enabled
a replication user, noted the current binary log position, and
ensured that the slave is using TABLE
based
replication repositories. You need to know the current
MASTER_LOG_FILE
and
MASTER_LOG_POSITION
. Use the
CHANGE MASTER TO
statement to add
a new master to a channel by specifying a FOR CHANNEL
clause. For
example, to add a new master with the host name
channel
master1
using port
3451
to a channel called
master-1
:
CHANGE MASTER TO MASTER_HOST='master1', MASTER_USER='rpl', MASTER_PORT=3451, MASTER_PASSWORD='' \
MASTER_LOG_FILE='master1-bin.000006', MASTER_LOG_POS=628 FOR CHANNEL 'master-1';
Repeat this process for each extra master that you want to add to a channel, changing the host name, port and channel as appropriate.
Once you have added all of the channels you want to use as
replication masters, use a START SLAVE
statement to
start replication. When you have enabled multiple channels on a
slave, you can choose to either start all channels, or select a
specific channel to start.
thread_types
To start all currently configured replication channels:
START SLAVE thread_types
;
To start only a named channel, use a FOR CHANNEL
clause:
channel
START SLAVE thread_types
FOR CHANNEL channel
;
Use the thread_types
option to choose
specific threads you want the above statements to start on the
slave. See Section 14.4.2.6, “START SLAVE Syntax” for more information.
The STOP SLAVE
statement can be used to stop
a multi-source replication slave. By default, if you use the
STOP SLAVE
statement on a multi-source
replication slave all channels are stopped. Optionally, use the
FOR CHANNEL
clause to stop only
a specific channel.
channel
To stop all currently configured replication channels:
STOP SLAVE thread_types
;
To stop only a named channel, use a FOR CHANNEL
clause:
channel
STOP SLAVE thread_types
FOR CHANNEL channel
;
Use the thread_types
option to choose
specific threads you want the above statements to stop on the
slave. See Section 14.4.2.7, “STOP SLAVE Syntax” for more information.
The RESET SLAVE
statement can be used to
reset a multi-source replication slave. By default, if you use
the RESET SLAVE
statement on a multi-source
replication slave all channels are reset. Optionally, use the
FOR CHANNEL
clause to reset
only a specific channel.
channel
To reset all currently configured replication channels:
RESET SLAVE;
To reset only a named channel, use a FOR CHANNEL
clause:
channel
RESET SLAVE FOR CHANNEL channel
;
See Section 14.4.2.4, “RESET SLAVE Syntax” for more information.
To monitor the status of replication channels the following options exist:
Using the replication Performance Schema tables. The first
column of these tables is Channel_Name
.
This enables you to write complex queries based on
Channel_Name
as a key. See
Section 25.10.11, “Performance Schema Replication Tables”.
Using SHOW SLAVE STATUS FOR CHANNEL
. By default,
if the channel_name
FOR CHANNEL
clause is
not used, this statement shows the slave status for all
channels with one row per channel. The identifier
channel_name
channel_name
is added as a column in the
result set. If a FOR CHANNEL
clause is
provided, the results show the status of only the named
replication channel.
channel_name
The SHOW VARIABLES
statement does
not work with multiple replication channels. The information
that was available through these variables has been migrated to
the replication performance tables. Using a
SHOW VARIABLES
statement in a
topology with multiple channels shows the status of only the
default channel.
This section explains how to use the replication Performance Schema tables to monitor channels. You can choose to monitor all channels, or a subset of the existing channels.
To monitor the connection status of all channels:
mysql> SELECT * FROM replication_connection_status\G;
*************************** 1. row ***************************
CHANNEL_NAME: master1
GROUP_NAME:
SOURCE_UUID: 046e41f8-a223-11e4-a975-0811960cc264
THREAD_ID: 24
SERVICE_STATE: ON
COUNT_RECEIVED_HEARTBEATS: 0
LAST_HEARTBEAT_TIMESTAMP: 0000-00-00 00:00:00
RECEIVED_TRANSACTION_SET: 046e41f8-a223-11e4-a975-0811960cc264:4-37
LAST_ERROR_NUMBER: 0
LAST_ERROR_MESSAGE:
LAST_ERROR_TIMESTAMP: 0000-00-00 00:00:00
*************************** 2. row ***************************
CHANNEL_NAME: master2
GROUP_NAME:
SOURCE_UUID: 7475e474-a223-11e4-a978-0811960cc264
THREAD_ID: 26
SERVICE_STATE: ON
COUNT_RECEIVED_HEARTBEATS: 0
LAST_HEARTBEAT_TIMESTAMP: 0000-00-00 00:00:00
RECEIVED_TRANSACTION_SET: 7475e474-a223-11e4-a978-0811960cc264:4-6
LAST_ERROR_NUMBER: 0
LAST_ERROR_MESSAGE:
LAST_ERROR_TIMESTAMP: 0000-00-00 00:00:00
2 rows in set (0.00 sec)
In the above output there are two channels enabled, and as shown
by the CHANNEL_NAME
field they are called
master1
and master2
.
The addition of the CHANNEL_NAME
field
enables you to query the Performance Schema tables for a
specific channel. To monitor the connection status of a named
channel, use a WHERE
channel_name=
clause:
channel
mysql> SELECT * FROM replication_connection_status WHERE channel_name='master1'\G
*************************** 1. row ***************************
CHANNEL_NAME: master1
GROUP_NAME:
SOURCE_UUID: 046e41f8-a223-11e4-a975-0811960cc264
THREAD_ID: 24
SERVICE_STATE: ON
COUNT_RECEIVED_HEARTBEATS: 0
LAST_HEARTBEAT_TIMESTAMP: 0000-00-00 00:00:00
RECEIVED_TRANSACTION_SET: 046e41f8-a223-11e4-a975-0811960cc264:4-37
LAST_ERROR_NUMBER: 0
LAST_ERROR_MESSAGE:
LAST_ERROR_TIMESTAMP: 0000-00-00 00:00:00
1 row in set (0.00 sec)
Similarly, the WHERE
channel_name=
clause
can be used to monitor the other replication Performance Schema
tables for a specific channel. For more information, see
Section 25.10.11, “Performance Schema Replication Tables”.
channel
New error codes and messages have been added to MySQL 5.7.6 to provide information about errors encountered in a multi-source replication topology. These error codes and messages are only emitted when multi-source replication is enabled, and provide information related to the channel which generated the error. For example:
Slave is already running and Slave is already stopped have been replaced with Replication thread(s) for channel channel_name are already running and Replication threads(s) for channel channel_name are already stopped respectively.
The server log messages have also been changed to indicate which channel the log messages relate to. This makes debugging and tracing easier.
This section describes how to change the mode of replication being used without having to take the server offline. This is new functionality added in MySQL 5.7.6.
To be able to safely configure the replication mode of an online server it is important to understand some key concepts of replication. This section explains these concepts and is essential reading before attempting to modify the replication mode of an online server.
The modes of replication available in MySQL rely on different techniques for identifying transactions which are logged. The types of transactions used by replication are as follows:
GTID transactions are identified by a global transaction
identifier (GTID) in the form UUID:NUMBER
.
Every GTID transaction in a log is always preceded by a
Gtid_log_event
. GTID transactions can be
addressed using either the GTID or using the file name and
position.
Anonymous transactions do not have a GTID assigned, and MySQL
5.7.6 and later ensures that every anonymous transaction in a
log is preceded by an
Anonymous_gtid_log_event
. In previous
versions, anonymous transactions were not preceded by any
particular event. Anonymous transactions can only be addressed
using file name and position.
When using GTIDs you can take advantage of auto-positioning and
automatic fail-over, as well as use
WAIT_FOR_EXECUTED_GTID_SET()
,
session_track_gtids
, and monitor
replicated transactions using Performance Schema tables. With
GTIDs enabled you cannot use
sql_slave_skip_counter
, instead
use empty transactions.
The changes introduced by MySQL 5.7.6 mean that transactions in a
relay log that was received from a master running a previous
version of MySQL may not be preceded by any particular event at
all, but after being replayed and logged in the slave's
binary log, they are preceded with an
Anonymous_gtid_log_event
.
The ability to configure the replication mode online means that
the gtid_mode
and
enforce_gtid_consistency
variables are now both dynamic and can be set by
SUPER
from a top-level statement.
In previous versions, both of these variables could only be
configured using the appropriate option at server start, meaning
that changes to the replication mode required a server restart. In
all versions gtid_mode
could be
set to ON
or OFF
, which
corresponded to whether GTIDs were used to identify transactions
or not. When gtid_mode=ON
it is
not possible to replicate anonymous transactions, and when
gtid_mode=OFF
only anonymous
transactions can be replicated. As of MySQL 5.7.6, the
gtid_mode
variable has two
additional states, OFF_PERMISSIVE
and
ON_PERMISSIVE
. When
gtid_mode=OFF_PERMISSIVE
then
new transactions are anonymous while
permitting replicated transactions to be either GTID or anonymous
transactions. When
gtid_mode=ON_PERMISSIVE
then
new transactions use GTIDs while permitting
replicated transactions to be either GTID or anonymous
transactions. This means it is possible to have a replication
topology that has servers using both anonymous and GTID
transactions. For example a master with
gtid_mode=ON
could be replicating
to a slave with
gtid_mode=ON_PERMISSIVE
. The
valid values for gtid_mode
are as
follows and in this order:
OFF
OFF_PERMISSIVE
ON_PERMISSIVE
ON
It is important to note that the state of
gtid_mode
can only be changed by
one step at a time based on the above order. For example, if
gtid_mode
is currently set to
OFF_PERMISSIVE
, it is possible to change to
OFF
or ON_PERMISSIVE
but not
to ON
. This is to ensure that the process of
changing from anonymous transactions to GTID transactions online
is correctly handled by the server. When you switch between
gtid_mode=ON
and
gtid_mode=OFF
, the GTID state (in
other words the value of
gtid_executed
) is persistent.
This ensures that the GTID set that has been applied by the server
is always retained, regardless of changes between types of
gtid_mode
.
As part of the changes introduced by MySQL 5.7.6, the fields
related to GTIDs have been modified so that they display the
correct information regardless of the currently selected
gtid_mode
. This means that fields
which display GTID sets, such as
gtid_executed
,
gtid_purged
,
RECEIVED_TRANSACTION_SET
in the
replication_connection_status
Performance Schema table, and the GTID related results of
SHOW SLAVE STATUS
, now return the
empty string when there are no GTIDs present. Fields that display
a single GTID, such as CURRENT_TRANSACTION
in
the replication_applier_status_by_worker
Performance Schema table, now display
ANONYMOUS
when GTID transactions are not being
used.
Replication from a master using
gtid_mode=ON
provides the ability
to use auto-positioning, configured using the CHANGE
MASTER TO MASTER_AUTO_POSITION = 1;
statement. The
replication topology being used impacts on whether it is possible
to enable auto-positioning or not, as this feature relies on GTIDs
and is not compatible with anonymous transactions. An error is
generated if auto-positioning is enabled and an anonymous
transaction is encountered. It is strongly recommended to ensure
there are no anonymous transactions remaining in the topology
before enabling auto-positioning, see
Section 18.1.5.2, “Enabling GTID Transactions Online”.
The valid combinations of
gtid_mode
and auto-positioning on
master and slave are shown in the following table, where the
master's gtid_mode
is shown
on the horizontal and the slave's
gtid_mode
is on the vertical:
Table 18.1 Valid Combinations of Master and Slave gtid_mode
Master/Slave
|
|
|
|
|
---|---|---|---|---|
| Y | Y | N | N |
| Y | Y | Y | Y* |
| Y | Y | Y | Y* |
| N | N | Y | Y* |
In the above table, the entries are:
The currently selected gtid_mode
also impacts on the gtid_next
variable. The following table shows the behavior of the server for
the different values of gtid_mode
and gtid_next
.
Table 18.2 Valid Combinations of gtid_mode and gtid_next
AUTOMATIC binary log on | AUTOMATIC binary log off | ANONYMOUS | UUID:NUMBER | |
---|---|---|---|---|
| ANONYMOUS | ANONYMOUS | ANONYMOUS | Error |
| ANONYMOUS | ANONYMOUS | ANONYMOUS | UUID:NUMBER |
| New GTID | ANONYMOUS | ANONYMOUS | UUID:NUMBER |
| New GTID | ANONYMOUS | Error | UUID:NUMBER |
In the above table, the entries are:
ANONYMOUS
: generate an anonymous
transaction.
Error
: generate an error and fail to
execute SET GTID_NEXT
.
UUID:NUMBER
: generate a GTID with the
specified UUID:NUMBER.
New GTID
: generate a GTID with an
automatically generated number.
When the binary log is off and
gtid_next
is set to
AUTOMATIC
, then no GTID is generated. This is
consistent with the behavior of previous versions.
This section describes how to enable GTID transactions, and optionally auto-positioning, on servers that are already online and using anonymous transactions. This procedure does not require taking the server offline and is suited to use in production. However, if you have the possibility to take the servers offline when enabling GTID transactions that process is easier.
Before you start, ensure that the servers meet the following pre-conditions:
All servers in your topology must use MySQL 5.7.6 or later. You cannot enable GTID transactions online on any single server unless all servers which are in the topology are using this version.
All servers have gtid_mode
set to the default value OFF
.
The following procedure can be paused at any time and later resumed where it was, or reversed by jumping to the corresponding step of Section 18.1.5.3, “Disabling GTID Transactions Online”, the online procedure to disable GTIDs. This makes the procedure fault-tolerant because any unrelated issues that may appear in the middle of the procedure can be handled as usual, and then the procedure continued where it was left off.
It is crucial that you complete every step before continuing to the next step.
To enable GTID transactions:
On each server, execute:
SET @@GLOBAL.ENFORCE_GTID_CONSISTENCY = WARN;
Let the server run for a while with your normal workload and monitor the logs. If this step causes any warnings in the log, adjust your application so that it only uses GTID-compatible features and does not generate any warnings.
This is the first important step. You must ensure that no warnings are being generated in the error logs before going to the next step.
On each server, execute:
SET @@GLOBAL.ENFORCE_GTID_CONSISTENCY = ON;
On each server, execute:
SET @@GLOBAL.GTID_MODE = OFF_PERMISSIVE;
It does not matter which server executes this statement first, but it is important that all servers complete this step before any server begins the next step.
On each server, execute:
SET @@GLOBAL.GTID_MODE = ON_PERMISSIVE;
It does not matter which server executes this statement first.
On each server, wait until the status variable
ONGOING_ANONYMOUS_TRANSACTION_COUNT
is
zero. This can be checked using:
SHOW STATUS LIKE 'ONGOING_ANONYMOUS_TRANSACTION_COUNT';
On a replication slave, it is theoretically possible that this shows zero and then non-zero again. This is not a problem, it suffices that it shows zero once.
Wait for all transactions generated up to step 5 to replicate to all servers. You can do this without stopping updates: the only important thing is that all anonymous transactions get replicated.
See Section 18.1.5.4, “Verifying Replication of Anonymous Transactions” for one method of checking that all anonymous transactions have replicated to all servers.
If you use binary logs for anything other than replication, for example point in time backup and restore, wait until you do not need the old binary logs having transactions without GTIDs.
For instance, after step 6 has completed, you can execute
FLUSH LOGS
on
the server where you are taking backups. Then either
explicitly take a backup or wait for the next iteration of any
periodic backup routine you may have set up.
Ideally, wait for the server to purge all binary logs that existed when step 6 was completed. Also wait for any backup taken before step 6 to expire.
This is the second important point. It is vital to understand that binary logs containing anonymous transactions, without GTIDs cannot be used after the next step. After this step, you must be sure that transactions without GTIDs do not exist anywhere in the topology.
On each server, execute:
SET @@GLOBAL.GTID_MODE = ON;
On each server, add gtid-mode=ON
to
my.cnf
.
You are now guaranteed that all transactions have a GTID
(except transactions generated in step 5 or earlier, which
have already been processed). To start using the GTID protocol
so that you can later perform automatic fail-over, execute the
following on each slave. Optionally, if you use multi-source
replication, do this for each channel and include the
FOR CHANNEL
clause:
channel
STOP SLAVE [FOR CHANNEL 'channel'];
CHANGE MASTER TO MASTER_AUTO_POSITION = 1 [FOR CHANNEL 'channel'];
START SLAVE [FOR CHANNEL 'channel'];
This section describes how to disable GTID transactions on servers that are already online. This procedure does not require taking the server offline and is suited to use in production. However, if you have the possibility to take the servers offline when disabling GTIDs mode that process is easier.
The process is similar to enabling GTID transactions while the server is online, but reversing the steps. The only thing that differs is the point at which you wait for logged transactions to replicate.
Before you start, ensure that the servers meet the following pre-conditions:
All servers in your topology must use MySQL 5.7.6 or later. You cannot disable GTID transactions online on any single server unless all servers which are in the topology are using this version.
All servers have gtid_mode
set to ON
.
Execute the following on each slave, and if you using
multi-source replication, do it for each channel and include
the FOR CHANNEL
channel clause:
STOP SLAVE [FOR CHANNEL 'channel'];
CHANGE MASTER TO MASTER_AUTO_POSITION = 0, MASTER_LOG_FILE = file, \
MASTER_LOG_POS = position [FOR CHANNEL 'channel'];
START SLAVE [FOR CHANNEL 'channel'];
On each server, execute:
SET @@GLOBAL.GTID_MODE = ON_PERMISSIVE;
On each server, execute:
SET @@GLOBAL.GTID_MODE = OFF_PERMISSIVE;
On each server, wait until the variable @@GLOBAL.GTID_OWNED is equal to the empty string. This can be checked using:
SELECT @@GLOBAL.GTID_OWNED;
On a replication slave, it is theoretically possible that this is empty and then nonempty again. This is not a problem, it suffices that it is empty once.
Wait for all transactions that currently exist in any binary log to replicate to all slaves. See Section 18.1.5.4, “Verifying Replication of Anonymous Transactions” for one method of checking that all anonymous transactions have replicated to all servers.
If you use binary logs for anything else than replication, for example to do point in time backup or restore: wait until you do not need the old binary logs having GTID transactions.
For instance, after step 5 has completed, you can execute
FLUSH LOGS
on
the server where you are taking the backup. Then either
explicitly take a backup or wait for the next iteration of any
periodic backup routine you may have set up.
Ideally, wait for the server to purge all binary logs that existed when step 5 was completed. Also wait for any backup taken before step 5 to expire.
This is the one important point during this procedure. It is important to understand that logs containing GTID transactions cannot be used after the next step. Before proceeding you must be sure that GTID transactions do not exist anywhere in the topology.
On each server, execute:
SET @@GLOBAL.GTID_MODE = OFF;
On each server, set
gtid-mode=OFF
in
my.cnf
.
If you want to set
enforce_gtid_consistency=OFF
,
you can do so now. After setting it, you should add
enforce_gtid_consistency=OFF
to your configuration file.
If you want to downgrade to an earlier version of MySQL, you can do so now, using the normal downgrade procedure.
This section explains how to monitor a replication topology and verify that all anonymous transactions have been replicated. This is helpful when changing the replication mode online as you can verify that it is safe to change to GTID transactions.
There are several possible ways to wait for transactions to replicate:
The simplest method, which works regardless of your topology but relies on timing is as follows: if you are sure that the slave never lags more than N seconds, just wait for a bit more than N seconds. Or wait for a day, or whatever time period you consider safe for your deployment.
A safer method in the sense that it does not depend on timing: if you only have a master with one or more slaves, do the following:
On the master, execute:
SHOW MASTER STATUS;
Note down the values in the File
and
Position
column.
On every slave, use the file and position information from the master to execute:
SELECT MASTER_POS_WAIT(file, position);
If you have a master and multiple levels of slaves, or in other words you have slaves of slaves, repeat step 2 on each level, starting from the master, then all the direct slaves, then all the slaves of slaves, and so on.
If you use a circular replication topology where multiple servers may have write clients, perform step 2 for each master-slave connection, until you have completed the full circle. Repeat the whole process so that you do the full circle twice.
For example, suppose you have three servers A, B, and C, replicating in a circle so that A -> B -> C -> A. The procedure is then:
Do step 1 on A and step 2 on B.
Do step 1 on B and step 2 on C.
Do step 1 on C and step 2 on A.
Do step 1 on A and step 2 on B.
Do step 1 on B and step 2 on C.
Do step 1 on C and step 2 on A.
The following sections contain information about mysqld options and server variables that are used in replication and for controlling the binary log. Options and variables for use on replication masters and replication slaves are covered separately, as are options and variables relating to binary logging and global transaction identifiers (GTIDs). A set of quick-reference tables providing basic information about these options and variables is also included.
Of particular importance is the
--server-id
option.
Command-Line Format | --server-id=# | ||
System Variable | Name | server_id | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
This option is common to both master and slave replication servers, and is used in replication to enable master and slave servers to identify themselves uniquely. For additional information, see Section 18.1.6.2, “Replication Master Options and Variables”, and Section 18.1.6.3, “Replication Slave Options and Variables”.
On the master and each slave, you must use the
--server-id
option to establish a
unique replication ID in the range from 1 to
232 − 1. “Unique”,
means that each ID must be different from every other ID in use by
any other replication master or slave. For example,
server-id=3
.
In MySQL 5.7.2 and earlier, if you start a master server without
using --server-id
to set its ID, the
default ID is 0. In this case, the master refuses connections from
all slaves, slaves refuse to connect to the master, and the server
sets the server_id
system variable
to 1. In MySQL 5.7.3 and later, the --server-id
must be used if binary logging is enabled, and a value of 0 is not
changed by the server. If you specify
--server-id
without an argument, the
effect is the same as using 0. In either case, if the
server_id
is 0, binary logging takes place, but
slaves cannot connect to the master, nor can any other servers
connect to it as slaves. (Bug #11763963, Bug #56718)
For more information, see Section 18.1.2.5.1, “Setting the Replication Slave Configuration”.
In MySQL 5.7, the server generates a true UUID in
addition to the --server-id
supplied
by the user. This is available as the global, read-only variable
server_uuid
.
The presence of the server_uuid
system variable in MySQL 5.7 does not change the
requirement for setting a unique
--server-id
for each MySQL server
as part of preparing and running MySQL replication, as described
earlier in this section.
System Variable | Name | server_uuid | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
When starting, the MySQL server automatically obtains a UUID as follows:
The auto.cnf
file has a format similar to that
used for my.cnf
or my.ini
files. In MySQL 5.7, auto.cnf
has
only a single [auto]
section containing a single
server_uuid
setting and value; the
file's contents appear similar to what is shown here:
[auto] server_uuid=8a94f357-aab4-11df-86ab-c80aa9429562
The auto.cnf
file is automatically generated;
do not attempt to write or modify this file.
When using MySQL replication, masters and slaves know each
other's UUIDs. The value of a slave's UUID can be seen in
the output of SHOW SLAVE HOSTS
. Once
START SLAVE
has been executed, the
value of the master's UUID is available on the slave in the
output of SHOW SLAVE STATUS
.
Issuing a STOP SLAVE
or
RESET SLAVE
statement does
not reset the master's UUID as used on
the slave.
A server's server_uuid
is also used in GTIDs
for transactions originating on that server. For more information,
see Section 18.1.3, “Replication with Global Transaction Identifiers”.
When starting, the slave I/O thread generates an error and aborts if
its master's UUID is equal to its own unless the
--replicate-same-server-id
option has
been set. In addition, the slave I/O thread generates a warning if
either of the following is true:
No master having the expected
server_uuid
exists.
The master's server_uuid
has changed, although no CHANGE MASTER
TO
statement has ever been executed.
The following tables list basic information about the MySQL command-line options and system variables applicable to replication and the binary log.
Table 18.3 Summary of Replication options and variables in MySQL 5.7
Option or Variable Name | ||
---|---|---|
Command Line | System Variable | Status Variable |
Option File | Scope | Dynamic |
Notes | ||
Yes | No | No |
Yes | No | |
DESCRIPTION: Option used by mysql-test for debugging and testing of replication |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Controls how binary logs are iterated during GTID recovery |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of CHANGE MASTER TO statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW MASTER STATUS statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW NEW MASTER statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW SLAVE HOSTS statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW SLAVE STATUS statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW SLAVE STATUS NONBLOCKING statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of START SLAVE statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of STOP SLAVE statements |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Option used by mysql-test for debugging and testing of replication |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Prevents execution of statements that cannot be logged in a transactionally safe manner |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Prevents execution of statements that cannot be logged in a transactionally safe manner |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Deprecated and will be removed in a future version. Use the renamed gtid-executed-compression-period instead. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Deprecated and will be removed in a future version. Use the renamed gtid_executed_compression_period instead. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Compress gtid_executed table each time this many transactions have occurred. 0 means never compress this table. Applies only when binary logging is disabled. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Controls whether GTID based logging is enabled and what type of transactions the logs can contain |
||
No | Yes | No |
No | Global | No |
DESCRIPTION: Global: All GTIDs in the binary log (global) or current transaction (session). Read-only. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Compress gtid_executed table each time this many transactions have occurred. 0 means never compress this table. Applies only when binary logging is disabled. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Controls whether GTID based logging is enabled and what type of transactions the logs can contain |
||
No | Yes | No |
No | Session | Yes |
DESCRIPTION: Specifies the GTID for the next statement to execute. See documentation for details. |
||
No | Yes | No |
No | Both | No |
DESCRIPTION: The set of GTIDs owned by this client (session), or by all clients, together with the thread ID of the owner (global). Read-only. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: The set of all GTIDs that have been purged from the binary log. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Statements that are executed when a slave connects to a master |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Tells the slave to log the updates performed by its SQL thread to its own binary log |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Whether the slave should log the updates performed by its SQL thread to its own binary log. Read-only; set using the --log-slave-updates server option. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Disables error 1592 warnings being written to the error log |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: The location and name of the file that remembers the master and where the I/O replication thread is in the master's binary logs |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Whether to write master status information and replication I/O thread location in the master's binary logs to a file or table. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Number of tries the slave makes to connect to the master before giving up |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Whether to write master status information and replication I/O thread location in the master's binary logs to a file or table |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: The location and base name to use for relay logs |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: The location and name to use for the file that keeps a list of the last relay logs |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: The location and name of the file that remembers where the SQL replication thread is in the relay logs |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Whether to write the replication SQL thread's location in the relay logs to a file or a table. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Enables automatic recovery of relay log files from master at startup |
||
No | Yes | No |
No | Global | No |
DESCRIPTION: Complete path to relay log, including filename |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: The name of the relay log index file |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: The name of the file in which the slave records information about the relay logs |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Whether to write the replication SQL thread's location in the relay logs to a file or a table |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Determines whether relay logs are purged |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Whether automatic recovery of relay log files from master at startup is enabled; must be enabled for a crash-safe slave. |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Maximum space to use for all relay logs |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave SQL thread to restrict replication to the specified database |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave SQL thread to restrict replication to the specified table |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave SQL thread not to replicate to the specified database |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave SQL thread not to replicate to the specified table |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Updates to a database with a different name than the original |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: In replication, if set to 1, do not skip events having our server id |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave thread to restrict replication to the tables that match the specified wildcard pattern |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave thread not to replicate to the tables that match the given wildcard pattern |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Host name or IP of the slave to be reported to the master during slave registration |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: An arbitrary password that the slave server should report to the master. Not the same as the password for the MySQL replication user account. |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Port for connecting to slave reported to the master during slave registration |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: An arbitrary user name that a slave server should report to the master. Not the same as the name used with the MySQL replication user account. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of semisynchronous slaves |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Whether semisynchronous replication is enabled on the master |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The average time the master waited for a slave reply |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total time the master waited for slave replies |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total number of times the master waited for slave replies |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of times the master turned off semisynchronous replication |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of commits not acknowledged successfully |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Whether semisynchronous replication is operational on the master |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of times the master failed when calling time functions |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Number of milliseconds to wait for slave acknowledgment |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: The semisynchronous replication debug trace level on the master |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The average time the master waited for each transaction |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total time the master waited for transactions |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total number of times the master waited for transactions |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: How many slave acknowledgments the master must receive per transaction before proceeding |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Whether master waits for timeout even with no slaves |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: The wait point for slave transaction receipt acknowledgment |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total number of times the master waited for an event with binary coordinates lower than events waited for previously |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of sessions currently waiting for slave replies |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of commits acknowledged successfully |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Whether semisynchronous replication is enabled on slave |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Whether semisynchronous replication is operational on slave |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: The semisynchronous replication debug trace level on the slave |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Set the number of seconds that STOP SLAVE waits before timing out. |
||
No | Yes | No |
No | Global | No |
DESCRIPTION: The server's globally unique ID, automatically (re)generated at server start |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Show user name and password in SHOW SLAVE HOSTS on this master |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Controls how binary logs are iterated during GTID recovery |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: If set, slave is not autostarted |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Maximum number of transactions processed by a multi-threaded slave before a checkpoint operation is called to update progress status. Not supported by MySQL Cluster. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Update progress status of multi-threaded slave and flush relay log info to disk after this number of milliseconds. Not supported by MySQL Cluster. |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: The location where the slave should put its temporary files when replicating a LOAD DATA INFILE statement |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Maximum size, in bytes, of a packet that can be sent from a replication master to a slave; overrides max_allowed_packet. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Number of seconds to wait for more data from a master/slave connection before aborting the read |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the slave to use database partioning (DATABASE) or timestamp information (LOGICAL_CLOCK) from the master to parallelize transactions. The default is DATABASE. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Number of worker threads for executing events in parallel. Set to 0 (the default) to disable slave multi-threading. Not supported by MySQL Cluster. |
||
Yes | No | No |
No | No | |
DESCRIPTION: Maximum size of slave worker queues holding events not yet applied. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Determines search algorithms used for slave update batching. Any 2 or 3 from the list INDEX_SEARCH, TABLE_SCAN, HASH_SCAN; the default is TABLE_SCAN,INDEX_SCAN. |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Tells the slave thread to continue replication when a query returns an error from the provided list |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Maximum number of transactions processed by a multi-threaded slave before a checkpoint operation is called to update progress status. Not supported by MySQL Cluster. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Update progress status of multi-threaded slave and flush relay log info to disk after this number of milliseconds. Not supported by MySQL Cluster. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Use compression on master/slave protocol |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Allows for switching the slave thread between IDEMPOTENT mode (key and some other errors suppressed) and STRICT mode; STRICT mode is the default, except for MySQL Cluster, where IDEMPOTENT is always used |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The slave's replication heartbeat interval, in seconds |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Maximum size, in bytes, of a packet that can be sent from a replication master to a slave; overrides max_allowed_packet. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of temporary tables that the slave SQL thread currently has open |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Tells the slave to use database partioning (DATABASE) or information (LOGICAL_CLOCK) from master to parallelize transactions. The default is DATABASE. |
||
Yes | Yes | No |
No | Global | Yes |
DESCRIPTION: Number of worker threads for executing events in parallel. Set to 0 (the default) to disable slave multi-threading. Not supported by MySQL Cluster. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Maximum size of slave worker queues holding events not yet applied. |
||
Yes | Yes | No |
No | Global | Yes |
DESCRIPTION: Ensures that all commits by slave workers happen in the same order as on the master to maintain consistency when using parallel worker threads. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The total number of times since startup that the replication slave SQL thread has retried transactions |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Determines search algorithms used for slave update batching. Any 2 or 3 from the list INDEX_SEARCH, TABLE_SCAN, HASH_SCAN; the default is TABLE_SCAN,INDEX_SCAN. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: The state of this server as a replication slave (slave I/O thread status) |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Number of times the slave SQL thread will retry a transaction in case it failed with a deadlock or elapsed lock wait timeout, before giving up and stopping |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Controls type conversion mode on replication slave. Value is a list of zero or more elements from the list: ALL_LOSSY, ALL_NON_LOSSY. Set to an empty string to disallow type conversions between master and slave. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Number of events from the master that a slave server should skip. Not compatible with GTID replication. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Synchronously flush binary log to disk after every #th event |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Synchronize master.info to disk after every #th event. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Synchronize relay log to disk after every #th event. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Synchronize relay.info file to disk after every #th event. |
Section 18.1.6.2, “Replication Master Options and Variables”, provides more detailed information about options and variables relating to replication master servers. For more information about options and variables relating to replication slaves, see Section 18.1.6.3, “Replication Slave Options and Variables”.
Table 18.4 Summary of Binary Logging options and variables in MySQL 5.7
Option or Variable Name | ||
---|---|---|
Command Line | System Variable | Status Variable |
Option File | Scope | Dynamic |
Notes | ||
Yes | No | No |
Yes | No | |
DESCRIPTION: Enable/disable binary log checksums |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Limits binary logging to specific databases |
||
Yes | Yes | No |
Yes | Both | Yes |
DESCRIPTION: Specifies the format of the binary log |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Tells the master that updates to the given database should not be logged to the binary log |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Binary log max event size |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Enables logging of rows query log events when using row-based logging. Disabled by default. Do not enable when producing logs for pre-5.6.2 slaves/readers. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of transactions that used a temporary file instead of the binary log cache |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Size of the cache to hold the SQL statements for the binary log during a transaction |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of transactions that used the temporary binary log cache |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Enable/disable binary log checksums |
||
Yes | Yes | No |
Yes | Both | Yes |
DESCRIPTION: Causes updates using statement format to nontransactional engines to be written directly to binary log. See documentation before using. |
||
Yes | Yes | No |
Yes | Both | Yes |
DESCRIPTION: Controls what happens when the server cannot write to the binary log. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Sets the number of microseconds to wait before synchronizing transactions to disk. |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Sets the maximum number of transactions to wait for before aborting the current delay specified by binlog_group_commit_sync_delay. |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: How long to read transactions before flushing to binary log |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Whether to commit in same order as writes to binary log |
||
Yes | Yes | No |
Yes | Both | Yes |
DESCRIPTION: Use full or minimal images when logging row changes. Allowed values are full, minimal, and noblob. |
||
No | Yes | No |
No | Both | Yes |
DESCRIPTION: When TRUE, enables logging of rows query log events in row-based logging mode. FALSE by default. Do not enable when producing logs for pre-5.6.2 replication slaves or other readers. |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of nontransactional statements that used a temporary file instead of the binary log statement cache |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Size of the cache to hold nontransactional statements for the binary log during a transaction |
||
No | No | Yes |
No | Global | No |
DESCRIPTION: Number of statements that used the temporary binary log statement cache |
||
Yes | Yes | No |
Yes | Both | Yes |
DESCRIPTION: Deprecated and will be removed in a future version. Use the renamed binlog_error_action instead. |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW BINLOG EVENTS statements |
||
No | No | Yes |
No | Both | No |
DESCRIPTION: Count of SHOW BINLOGS statements |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Use version 1 binary log row events |
||
No | Yes | No |
No | Global | No |
DESCRIPTION: Complete path to binary log, including filename |
||
Yes | Yes | No |
Yes | Global | No |
DESCRIPTION: Shows whether server is using version 1 binary log row events |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Cause master to examine checksums when reading from the binary log |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Cause master to read checksums from binary log. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Option used by mysql-test for debugging and testing of replication |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Can be used to restrict the total size used to cache a multi-statement transaction |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Binary log will be rotated automatically when size exceeds this value |
||
Yes | Yes | No |
Yes | Global | Yes |
DESCRIPTION: Can be used to restrict the total size used to cache all nontransactional statements during a transaction |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Cause slave to examine checksums when reading from the relay log |
||
No | Yes | No |
No | Global | Yes |
DESCRIPTION: Cause slave to examine checksums when reading from relay log. |
||
Yes | No | No |
Yes | No | |
DESCRIPTION: Option used by mysql-test for debugging and testing of replication |
Section 18.1.6.4, “Binary Logging Options and Variables”, provides more detailed information about options and variables relating to binary logging. For additional general information about the binary log, see Section 6.4.4, “The Binary Log”.
For information about the
sql_log_bin
and
sql_log_off
variables, see
Section 6.1.5, “Server System Variables”.
For a table showing all command-line options, system and status variables used with mysqld, see Section 6.1.3, “Server Option and Variable Reference”.
This section describes the server options and system variables
that you can use on replication master servers. You can specify
the options either on the
command line or in an
option file. You can specify
system variable values using
SET
.
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 in use by any other replication
master or slave. Example: server-id=3
.
For options used on the master for controlling binary logging, see Section 18.1.6.4, “Binary Logging Options and Variables”.
The following system variables are used to control replication masters:
System Variable | Name | auto_increment_increment | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1 | ||
Min Value | 1 | ||
Max Value | 65535 |
auto_increment_increment
and auto_increment_offset
are intended for use with master-to-master replication, and
can be used to control the operation of
AUTO_INCREMENT
columns. Both variables
have global and session values, and each can assume an
integer value between 1 and 65,535 inclusive. Setting the
value of either of these two variables to 0 causes its value
to be set to 1 instead. Attempting to set the value of
either of these two variables to an integer greater than
65,535 or less than 0 causes its value to be set to 65,535
instead. Attempting to set the value of
auto_increment_increment
or
auto_increment_offset
to a
noninteger value produces an error, and the actual value of
the variable remains unchanged.
auto_increment_increment
is also supported for use with
NDB
tables.
These two variables affect AUTO_INCREMENT
column behavior as follows:
auto_increment_increment
controls the interval between successive column values.
For example:
mysql>SHOW VARIABLES LIKE 'auto_inc%';
+--------------------------+-------+ | Variable_name | Value | +--------------------------+-------+ | auto_increment_increment | 1 | | auto_increment_offset | 1 | +--------------------------+-------+ 2 rows in set (0.00 sec) mysql>CREATE TABLE autoinc1
->(col INT NOT NULL AUTO_INCREMENT PRIMARY KEY);
Query OK, 0 rows affected (0.04 sec) mysql>SET @@auto_increment_increment=10;
Query OK, 0 rows affected (0.00 sec) mysql>SHOW VARIABLES LIKE 'auto_inc%';
+--------------------------+-------+ | Variable_name | Value | +--------------------------+-------+ | auto_increment_increment | 10 | | auto_increment_offset | 1 | +--------------------------+-------+ 2 rows in set (0.01 sec) mysql>INSERT INTO autoinc1 VALUES (NULL), (NULL), (NULL), (NULL);
Query OK, 4 rows affected (0.00 sec) Records: 4 Duplicates: 0 Warnings: 0 mysql>SELECT col FROM autoinc1;
+-----+ | col | +-----+ | 1 | | 11 | | 21 | | 31 | +-----+ 4 rows in set (0.00 sec)
auto_increment_offset
determines the starting point for the
AUTO_INCREMENT
column value. Consider
the following, assuming that these statements are
executed during the same session as the example given in
the description for
auto_increment_increment
:
mysql>SET @@auto_increment_offset=5;
Query OK, 0 rows affected (0.00 sec) mysql>SHOW VARIABLES LIKE 'auto_inc%';
+--------------------------+-------+ | Variable_name | Value | +--------------------------+-------+ | auto_increment_increment | 10 | | auto_increment_offset | 5 | +--------------------------+-------+ 2 rows in set (0.00 sec) mysql>CREATE TABLE autoinc2
->(col INT NOT NULL AUTO_INCREMENT PRIMARY KEY);
Query OK, 0 rows affected (0.06 sec) mysql>INSERT INTO autoinc2 VALUES (NULL), (NULL), (NULL), (NULL);
Query OK, 4 rows affected (0.00 sec) Records: 4 Duplicates: 0 Warnings: 0 mysql>SELECT col FROM autoinc2;
+-----+ | col | +-----+ | 5 | | 15 | | 25 | | 35 | +-----+ 4 rows in set (0.02 sec)
When the value of
auto_increment_offset
is greater than that of
auto_increment_increment
,
the value of
auto_increment_offset
is ignored.
If either of these variables is changed, and then new rows
inserted into a table containing an
AUTO_INCREMENT
column, the results may
seem counterintuitive because the series of
AUTO_INCREMENT
values is calculated
without regard to any values already present in the column,
and the next value inserted is the least value in the series
that is greater than the maximum existing value in the
AUTO_INCREMENT
column. The series is
calculated like this:
auto_increment_offset
+
N
×
auto_increment_increment
where N
is a positive integer
value in the series [1, 2, 3, ...]. For example:
mysql>SHOW VARIABLES LIKE 'auto_inc%';
+--------------------------+-------+ | Variable_name | Value | +--------------------------+-------+ | auto_increment_increment | 10 | | auto_increment_offset | 5 | +--------------------------+-------+ 2 rows in set (0.00 sec) mysql>SELECT col FROM autoinc1;
+-----+ | col | +-----+ | 1 | | 11 | | 21 | | 31 | +-----+ 4 rows in set (0.00 sec) mysql>INSERT INTO autoinc1 VALUES (NULL), (NULL), (NULL), (NULL);
Query OK, 4 rows affected (0.00 sec) Records: 4 Duplicates: 0 Warnings: 0 mysql>SELECT col FROM autoinc1;
+-----+ | col | +-----+ | 1 | | 11 | | 21 | | 31 | | 35 | | 45 | | 55 | | 65 | +-----+ 8 rows in set (0.00 sec)
The values shown for
auto_increment_increment
and auto_increment_offset
generate the series 5 + N
×
10, that is, [5, 15, 25, 35, 45, ...]. The highest value
present in the col
column prior to the
INSERT
is 31, and the next
available value in the AUTO_INCREMENT
series is 35, so the inserted values for
col
begin at that point and the results
are as shown for the SELECT
query.
It is not possible to restrict the effects of these two
variables to a single table; these variables control the
behavior of all AUTO_INCREMENT
columns in
all tables on the MySQL server. If the
global value of either variable is set, its effects persist
until the global value is changed or overridden by setting
the session value, or until mysqld is
restarted. If the local value is set, the new value affects
AUTO_INCREMENT
columns for all tables
into which new rows are inserted by the current user for the
duration of the session, unless the values are changed
during that session.
The default value of
auto_increment_increment
is
1. See
Section 18.4.1.1, “Replication and AUTO_INCREMENT”.
System Variable | Name | auto_increment_offset | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1 | ||
Min Value | 1 | ||
Max Value | 65535 |
This variable has a default value of 1. For more
information, see the description for
auto_increment_increment
.
auto_increment_offset
is also supported
for use with NDB
tables.
This section explains the server options and system variables that apply to slave replication servers and contains the following:
Startup Options for Replication Slaves
Options for Logging Slave Status to Tables
System Variables Used on Replication Slaves
Specify the options either on the
command line or in an
option file. Many of the
options can be set while the server is running by using the
CHANGE MASTER TO
statement. Specify
system variable values using
SET
.
Server ID.
On the master and each slave, you must use the
server-id
option to establish a
unique replication ID in the range from 1 to
232 − 1. “Unique”
means that each ID must be different from every other ID in use
by any other replication master or slave. Example
my.cnf
file:
[mysqld] server-id=3
This section explains startup options for controlling
replication slave servers. Many of these options can be set
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. Replication-related
system variables are discussed later in this section.
Command-Line Format | --log-slave-updates | ||
System Variable | Name | log_slave_updates | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | OFF |
Normally, a slave does not write any updates that are
received from a master server to its own binary log. This
option causes the slave to write 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.
Removed | 5.7.1 | ||
Command-Line Format | --log-slow-slave-statements (5.7.0) | ||
Permitted Values | Type | boolean | |
Default | OFF |
When the slow query log is enabled, this option enables
logging for queries that have taken more than
long_query_time
seconds to
execute on the slave.
This command-line option was removed in MySQL 5.7.1 and
replaced by the
log_slow_slave_statements
system variable. The system variable can be set on the
command line or in option files the same way as the option,
so there is no need for any changes at server startup, but
the system variable also makes it possible to examine or set
the value at runtime.
Deprecated | 5.7.2 | ||
Command-Line Format | --log-warnings[=#] | ||
System Variable | Name | log_warnings | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms, <= 5.7.1) | Type | integer | |
Default | 1 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (32-bit platforms, >= 5.7.2) | Type | integer | |
Default | 2 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms, <= 5.7.1) | Type | integer | |
Default | 1 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 | ||
Permitted Values (64-bit platforms, >= 5.7.2) | Type | integer | |
Default | 2 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
As of MySQL 5.7.2, the
log_error_verbosity
system variable is preferred over, and should be used
instead of, the
--log-warnings
option or
log_warnings
system
variable. For more information, see the descriptions of
log_error_verbosity
and
log_warnings
. The
--log-warnings
command-line
option and log_warnings
system variable are deprecated and will be removed in a
future MySQL release.
Causes the server to record 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 or connection failure, and provides information about how each slave thread started. This variable is enabled by default (the default is 1 before MySQL 5.7.2, 2 as of 5.7.2). To disable it, set it to 0. The server logs messages about statements that are unsafe for statement-based logging if the value is greater than 0. Aborted connections and access-denied errors for new connection attempts are logged if the value is greater than 1. See Section B.5.2.11, “Communication Errors and Aborted Connections”.
The effects of this option are not limited to replication. It produces warnings across a spectrum of server activities.
Command-Line Format | --master-info-file=file_name | ||
Permitted Values | Type | file name | |
Default | master.info |
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. For
information about the format of this file, see
Section 18.2.4.2, “Slave Status Logs”.
Deprecated | 5.6.1 | ||
Command-Line Format | --master-retry-count=# | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 86400 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 86400 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
The number of times that the slave tries to connect to the
master before giving up. Reconnects are attempted at
intervals set by the MASTER_CONNECT_RETRY
option of the CHANGE MASTER
TO
statement (default 60). Reconnects are
triggered when data reads by the slave time out according to
the --slave-net-timeout
option. The default value is 86400. A value of 0 means
“infinite”; the slave attempts to connect
forever.
This option is deprecated and will be removed in a future
MySQL release. Applications should be updated to use the
MASTER_RETRY_COUNT
option of the
CHANGE MASTER TO
statement
instead.
Command-Line Format | --max_relay_log_size=# | ||
System Variable | Name | max_relay_log_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 1073741824 |
The size at which the server rotates relay log files
automatically. If this value is nonzero, the relay log is
rotated automatically when its size exceeds this value. If
this value is zero (the default), the size at which relay
log rotation occurs is determined by the value of
max_binlog_size
. For more
information, see Section 18.2.4.1, “The Slave Relay Log”.
Command-Line Format | --relay-log=file_name | ||
System Variable | Name | relay_log | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name |
The base name for the relay log. For the default replication
channel, the default base name for relay logs is
.
For non-default replication channels, the default base name
for relay logs is
host_name
-relay-bin
,
where host_name
-channel
-relay-binchannel
is the name of the
replication channel recorded in this relay log. The server
writes the file in the data directory unless the base name
is given with a leading absolute path name to specify a
different directory. The server creates relay log files in
sequence by adding a numeric suffix to the base name.
Due to the manner in which MySQL parses server options, if
you specify this option, you must supply a value;
the default base name is used only if the option
is not actually specified. If you use the
--relay-log
option without
specifying a value, unexpected behavior is likely to result;
this behavior depends on the other options used, the order
in which they are specified, and whether they are specified
on the command line or in an option file. For more
information about how MySQL handles server options, see
Section 5.2.3, “Specifying Program Options”.
If you specify this option, the value specified is also used
as the base name for the relay log index file. You can
override this behavior by specifying a different relay log
index file base name using the
--relay-log-index
option.
When the server reads an entry from the index file, it
checks whether the entry contains a relative path. If it
does, the relative part of the path is replaced with the
absolute path set using the --relay-log
option. An absolute path remains unchanged; in such a case,
the index must be edited manually to enable the new path or
paths to be used. Previously, manual intervention was
required whenever relocating the binary log or relay log
files. (Bug #11745230, Bug #12133)
You may find the --relay-log
option useful in performing the following tasks:
Creating relay logs whose names are independent of host names.
If you need to put the relay logs in some area other
than the data directory because your relay logs tend to
be very large and you do not want to decrease
max_relay_log_size
.
To increase speed by using load-balancing between disks.
You can obtain the relay log file name (and path) from the
relay_log_basename
system
variable.
Command-Line Format | --relay-log-index=file_name | ||
System Variable | Name | relay_log_index | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name |
The name to use for the relay log index file. The default
name is
in the data directory, where
host_name
-relay-bin.indexhost_name
is the name of the
server. For the default replication channel, the default
name is
.
For non-default replication channels, the default name is
host_name
-relay-bin.index
,
where host_name
-channel
-relay-bin.indexchannel
is the name of the
replication channel recorded in this relay log index.
Due to the manner in which MySQL parses server options, if
you specify this option, you must supply a value;
the default base name is used only if the option
is not actually specified. If you use the
--relay-log-index
option
without specifying a value, unexpected behavior is likely to
result; this behavior depends on the other options used, the
order in which they are specified, and whether they are
specified on the command line or in an option file. For more
information about how MySQL handles server options, see
Section 5.2.3, “Specifying Program Options”.
If you specify this option, the value specified is also used
as the base name for the relay logs. You can override this
behavior by specifying a different relay log file base name
using the --relay-log
option.
--relay-log-info-file=
file_name
Command-Line Format | --relay-log-info-file=file_name | ||
Permitted Values | Type | file name | |
Default | relay-log.info |
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.
For information about the format of this file, see
Section 18.2.4.2, “Slave Status Logs”.
Command-Line Format | --relay_log_purge | ||
System Variable | Name | relay_log_purge | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | TRUE |
Disable or enable automatic purging of relay logs as soon as
they are no longer needed. The default value is 1 (enabled).
This is a global variable that can be changed dynamically
with SET GLOBAL relay_log_purge =
. Disabling purging of
relay logs when using the
N
--relay-log-recovery
option
puts data consistency at risk.
Command-Line Format | --relay-log-recovery | ||
Permitted Values | Type | boolean | |
Default | FALSE |
Enables automatic relay log recovery immediately following server startup. The recovery process creates a new relay log file, initializes the SQL thread position to this new relay log, and initializes the I/O thread to the SQL thread position. Reading of the relay log from the master then continues. This should be used following an unexpected halt of a replication slave to ensure that no possibly corrupted relay logs are processed. The default value is 0 (disabled).
This variable can be set to 1 to make a slave resilient to
unexpected halts, see
Section 18.3.2, “Handling an Unexpected Halt of a Replication Slave”
for more information. Enabling the
--relay-log-recovery
option
when relay-log-purge
is
disabled risks reading the relay log from files that were
not purged, leading to data inconsistency.
When using a multi-threaded slave (in other words
slave_parallel_workers
is
greater than 0), inconsistencies such as gaps can occur in
the sequence of transactions that have been executed from
the relay log. Enabling the
--relay-log-recovery
option
when there are inconsistencies causes an error and the
option has no effect. The solution in this situation is to
issue START
SLAVE UNTIL SQL_AFTER_MTS_GAPS
, which brings the
server to a more consistent state, then issue
RESET SLAVE
to remove the
relay logs. See
Section 18.4.1.34, “Replication and Transaction Inconsistencies”
for more information.
Command-Line Format | --relay_log_space_limit=# | ||
System Variable | Name | relay_log_space_limit | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
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 ignore
--relay-log-space-limit
temporarily.
Command-Line Format | --replicate-do-db=name | ||
Permitted Values | Type | string |
Creates a replication filter using the name of a database.
In MySQL 5.7.3 and later, such filters can also be created
using
CHANGE
REPLICATION FILTER REPLICATE_DO_DB
. The precise
effect of this filtering depends on whether statement-based
or row-based replication is in use, and are described in the
next several paragraphs.
Statement-based replication.
Tell the slave SQL thread 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; however, doing so does
not replicate cross-database
statements such as UPDATE
while a different database (or no
database) is selected.
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 when
using statement-based replication: 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 “check just 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.
Row-based replication.
Tells the slave SQL thread to restrict replication to
database db_name
. Only tables
belonging to db_name
are
changed; the current database has no effect on this.
Suppose that the slave is started with
--replicate-do-db=sales
and
row-based replication is in effect, and then the following
statements are run on the master:
USE prices; UPDATE sales.february SET amount=amount+100;
The february
table in the
sales
database on the slave is changed in
accordance with the UPDATE
statement; this occurs whether or not the
USE
statement was issued.
However, issuing the following statements on the master has
no effect on the slave when using row-based replication and
--replicate-do-db=sales
:
USE prices; UPDATE prices.march SET amount=amount-25;
Even if the statement USE prices
were
changed to USE sales
, the
UPDATE
statement's
effects would still not be replicated.
Another important difference in how
--replicate-do-db
is handled
in statement-based replication as opposed to row-based
replication occurs with regard to statements that refer to
multiple databases. Suppose that the slave is started with
--replicate-do-db=db1
, and
the following statements are executed on the master:
USE db1; UPDATE db1.table1 SET col1 = 10, db2.table2 SET col2 = 20;
If you are using statement-based replication, then both
tables are updated on the slave. However, when using
row-based replication, only table1
is
affected on the slave; since table2
is in
a different database, table2
on the slave
is not changed by the UPDATE
.
Now suppose that, instead of the USE db1
statement, a USE db4
statement had been
used:
USE db4; UPDATE db1.table1 SET col1 = 10, db2.table2 SET col2 = 20;
In this case, the UPDATE
statement would have no effect on the slave when using
statement-based replication. However, if you are using
row-based replication, the
UPDATE
would change
table1
on the slave, but not
table2
—in other words, only tables
in the database named by
--replicate-do-db
are
changed, and the choice of default database has no effect on
this behavior.
If you need cross-database updates to work, use
--replicate-wild-do-table=
instead. See Section 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
db_name
.%
This option affects replication in the same manner that
--binlog-do-db
affects
binary logging, and the effects of the replication format
on how --replicate-do-db
affects replication behavior are the same as those of the
logging format on the behavior of
--binlog-do-db
.
This option has no effect on
BEGIN
,
COMMIT
, or
ROLLBACK
statements.
Command-Line Format | --replicate-ignore-db=name | ||
Permitted Values | Type | string |
Creates a replication filter using the name of a database.
In MySQL 5.7.3 and later, such filters can also be created
using
CHANGE
REPLICATION FILTER REPLICATE_IGNORE_DB
. As with
--replicate-do-db
, the
precise effect of this filtering depends on whether
statement-based or row-based replication is in use, and are
described in the next several paragraphs.
Statement-based replication.
Tells the slave SQL thread not to replicate any statement
where the default database (that is, the one selected by
USE
) is
db_name
.
Row-based replication.
Tells the slave SQL thread not to update any tables in the
database db_name
. The default
database has no effect.
When using statement-based replication, the following
example does not work as you might expect. Suppose that the
slave is started with
--replicate-ignore-db=sales
and you issue the following statements on the master:
USE prices; UPDATE sales.january SET amount=amount+1000;
The UPDATE
statement
is replicated in such a case because
--replicate-ignore-db
applies
only to the default database (determined by the
USE
statement). Because the
sales
database was specified explicitly
in the statement, the statement has not been filtered.
However, when using row-based replication, the
UPDATE
statement's
effects are not propagated to the
slave, and the slave's copy of the
sales.january
table is unchanged; in this
instance,
--replicate-ignore-db=sales
causes all changes made to tables in
the master's copy of the sales
database to be ignored by the slave.
To specify more than one database to ignore, use this option multiple times, once for each database. 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.
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 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
If you need cross-database updates to work, use
--replicate-wild-ignore-table=
instead. See Section 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
db_name
.%
This option affects replication in the same manner that
--binlog-ignore-db
affects
binary logging, and the effects of the replication format
on how
--replicate-ignore-db
affects replication behavior are the same as those of the
logging format on the behavior of
--binlog-ignore-db
.
This option has no effect on
BEGIN
,
COMMIT
, or
ROLLBACK
statements.
--replicate-do-table=
db_name.tbl_name
Command-Line Format | --replicate-do-table=name | ||
Permitted Values | Type | string |
Creates a replication filter by telling the slave SQL thread
to restrict replication to a given table. To specify more
than one table, use this option multiple times, once for
each table. This works for both cross-database updates and
default database updates, in contrast to
--replicate-do-db
. See
Section 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
In MySQL 5.7.3 and later, you can also create such a filter
by issuing a
CHANGE
REPLICATION FILTER REPLICATE_DO_TABLE
statement.
This option affects only statements that apply to tables. It
does not affect statements that apply only to other database
objects, such as stored routines. To filter statements
operating on stored routines, use one or more of the
--replicate-*-db
options.
--replicate-ignore-table=
db_name.tbl_name
Command-Line Format | --replicate-ignore-table=name | ||
Permitted Values | Type | string |
Creates a replication filter by telling the slave SQL thread
not to 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 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
In MySQL 5.7.3 and later, you can also create such a filter
by issuing a
CHANGE
REPLICATION FILTER REPLICATE_IGNORE_TABLE
statement.
This option affects only statements that apply to tables. It
does not affect statements that apply only to other database
objects, such as stored routines. To filter statements
operating on stored routines, use one or more of the
--replicate-*-db
options.
--replicate-rewrite-db=
from_name
->to_name
Command-Line Format | --replicate-rewrite-db=old_name->new_name | ||
Permitted Values | Type | string |
Tells the slave to create a replication filter that
translates 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. To specify multiple rewrites, use this option
multiple times. The server uses the first one with a
from_name
value that matches. The
database name translation is done
before the
--replicate-*
rules are tested.
In MySQL 5.7.3 and later, you can also create such a filter
by issuing a
CHANGE
REPLICATION FILTER REPLICATE_REWRITE_DB
statement.
Statements in which table names are qualified with database
names when using this option do not work with table-level
replication filtering options such as
--replicate-do-table
. Suppose
we have a database named a
on the master,
one named b
on the slave, each containing
a table t
, and have started the master
with --replicate-rewrite-db='a->b'
. At a
later point in time, we execute
DELETE FROM
a.t
. In this case, no relevant filtering rule
works, for the reasons shown here:
--replicate-do-table=a.t
does not work
because the slave has table t
in
database b
.
--replicate-do-table=b.t
does not match
the original statement and so is ignored.
--replicate-do-table=*.t
is handled
identically to
--replicate-do-table=a.t
, and thus does
not work, either.
Similarly, the --replication-rewrite-db
option does not work with cross-database updates.
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
"
Command-Line Format | --replicate-same-server-id | ||
Permitted Values | Type | boolean | |
Default | FALSE |
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.
By default, the slave I/O thread does not write binary log
events to the relay log if they have the slave's server ID
(this optimization helps save disk usage). 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
Command-Line Format | --replicate-wild-do-table=name | ||
Permitted Values | Type | string |
Creates a replication filter by telling 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 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
In MySQL 5.7.3 and later, you can also create such a filter
by issuing a
CHANGE
REPLICATION FILTER REPLICATE_WILD_DO_TABLE
statement.
This option applies to tables, views, and triggers. It does
not apply to stored procedures and functions, or events. To
filter statements operating on the latter objects, use one
or more of the --replicate-*-db
options.
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 use 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
Command-Line Format | --replicate-wild-ignore-table=name | ||
Permitted Values | Type | string |
Creates a replication filter which keeps the slave thread from replicating a statement in which 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 Section 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
In MySQL 5.7.3 and later, you can also create such a filter
by issuing a
CHANGE
REPLICATION FILTER REPLICATE_WILD_IGNORE_TABLE
statement.
Example:
--replicate-wild-ignore-table=foo%.bar%
does not replicate updates that use a table where the
database name starts with foo
and the
table name starts with bar
.
For information about how matching works, see the
description of the
--replicate-wild-do-table
option. The rules for including literal wildcard characters
in the option value are the same as for
--replicate-wild-ignore-table
as well.
Command-Line Format | --report-host=host_name | ||
System Variable | Name | report_host | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
The host name or IP address of the slave to be reported to
the master during slave registration. This value appears in
the output of SHOW SLAVE
HOSTS
on the master server. Leave the value unset
if you do not want the slave to register itself with the
master.
It is not sufficient for the master to simply read the IP address of the slave from the TCP/IP socket after the slave connects. Due to NAT and other routing issues, that IP may not be valid for connecting to the slave from the master or other hosts.
Command-Line Format | --report-password=name | ||
System Variable | Name | report_password | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
The account password of the slave to be reported to the
master during slave registration. This value appears in the
output of SHOW SLAVE HOSTS
on
the master server if the
--show-slave-auth-info
option
is given.
Although the name of this option might imply otherwise,
--report-password
is not connected to the
MySQL user privilege system and so is not necessarily (or
even likely to be) the same as the password for the MySQL
replication user account.
Command-Line Format | --report-port=# | ||
System Variable | Name | report_port | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | integer | |
Default | [slave_port] | ||
Min Value | 0 | ||
Max Value | 65535 |
The TCP/IP port number for connecting to the slave, to be reported to the master during slave registration. Set this only if the slave is listening on a nondefault port or if you have a special tunnel from the master or other clients to the slave. If you are not sure, do not use this option.
The default value for this option is the port number
actually used by the slave (Bug #13333431). This is also the
default value displayed by SHOW SLAVE
HOSTS
.
Command-Line Format | --report-user=name | ||
System Variable | Name | report_user | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
The account user name of the slave to be reported to the
master during slave registration. This value appears in the
output of SHOW SLAVE HOSTS
on
the master server if the
--show-slave-auth-info
option
is given.
Although the name of this option might imply otherwise,
--report-user
is not connected to the MySQL
user privilege system and so is not necessarily (or even
likely to be) the same as the name of the MySQL replication
user account.
Command-Line Format | --show-slave-auth-info | ||
Permitted Values | Type | boolean | |
Default | FALSE |
Display slave user names and passwords in the output of
SHOW SLAVE HOSTS
on the
master server for slaves started with the
--report-user
and
--report-password
options.
Command-Line Format | --slave-checkpoint-group=# | ||
Permitted Values | Type | integer | |
Default | 512 | ||
Min Value | 32 | ||
Max Value | 524280 | ||
Block Size | 8 |
Sets the maximum number of transactions that can be
processed by a multi-threaded slave before a checkpoint
operation is called to update its status as shown by
SHOW SLAVE STATUS
. Setting
this option has no effect on slaves for which
multi-threading is not enabled.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this option. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
This option works in combination with the
--slave-checkpoint-period
option in such a way that, when either limit is exceeded,
the checkpoint is executed and the counters tracking both
the number of transactions and the time elapsed since the
last checkpoint are reset.
The minimum allowed value for this option is 32, unless the
server was built using
-DWITH_DEBUG
, in which case
the minimum value is 1. The effective value is always a
multiple of 8; you can set it to a value that is not such a
multiple, but the server rounds it down to the next lower
multiple of 8 before storing the value.
(Exception: No such rounding is
performed by the debug server.) Regardless of how the server
was built, the default value is 512, and the maximum allowed
value is 524280.
Command-Line Format | --slave-checkpoint-period=# | ||
Permitted Values | Type | integer | |
Default | 300 | ||
Min Value | 1 | ||
Max Value | 4G |
Sets the maximum time (in milliseconds) that is allowed to
pass before a checkpoint operation is called to update the
status of a multi-threaded slave as shown by
SHOW SLAVE STATUS
. Setting
this option has no effect on slaves for which
multi-threading is not enabled.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this option. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
This option works in combination with the
--slave-checkpoint-group
option in such a way that, when either limit is exceeded,
the checkpoint is executed and the counters tracking both
the number of transactions and the time elapsed since the
last checkpoint are reset.
The minimum allowed value for this option is 1, unless the
server was built using
-DWITH_DEBUG
, in which case
the minimum value is 0. Regardless of how the server was
built, the default value is 300, and the maximum possible
value is 4294967296 (4GB).
Command-Line Format | --slave-parallel-workers=# | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 1024 |
Sets the number of slave applier threads for executing replication transactions in parallel. Setting this variable to a number greater than 0 creates a multi-threaded slave with this number of applier threads. When set to 0 (the default) parallel execution is disabled and the slave uses a single applier thread.
A multi-threaded slave provides parallel execution by using
a coordinator thread and the number of applier threads
configured by this option. The way which transactions are
distributed among applier threads is configured by
--slave-parallel-type
. For
more information about multi-threaded slaves see
slave-parallel-workers
.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this option. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
--slave-pending-jobs-size-max=
#
Command-Line Format | --slave-pending-jobs-size-max=# | ||
Permitted Values | Type | integer | |
Default | 16M | ||
Min Value | 1024 | ||
Max Value | 18EB | ||
Block Size | 1024 |
For multi-threaded slaves, this option sets the maximum amount of memory (in bytes) available to slave worker queues holding events not yet applied. Setting this option has no effect on slaves for which multi-threading is not enabled.
The minimum possible value for this option is 1024; the default is 16MB. The maximum possible value is 18446744073709551615 (16 exabytes). Values that are not exact multiples of 1024 are rounded down to the next-highest multiple of 1024 prior to being stored.
The value for this option must not be less than the
master's value for
max_allowed_packet
;
otherwise a slave worker queue may become full while there
remain events coming from the master to be processed.
Command-Line Format | --skip-slave-start | ||
Permitted Values | Type | boolean | |
Default | FALSE |
Tells the slave server not to start the slave threads when
the server starts. To start the threads later, use a
START SLAVE
statement.
--slave_compressed_protocol={0|1}
Command-Line Format | --slave_compressed_protocol | ||
System Variable | Name | slave_compressed_protocol | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | OFF |
If this option is set to 1, use compression for the slave/master protocol if both the slave and the master support it. The default is 0 (no compression).
Command-Line Format | --slave-load-tmpdir=dir_name | ||
System Variable | Name | slave_load_tmpdir | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | directory name | |
Default | /tmp |
The name of the directory where the slave creates temporary
files. This option is by default equal to the value of the
tmpdir
system variable.
When the slave SQL thread replicates a
LOAD DATA
INFILE
statement, it extracts the file to be
loaded from the relay log into temporary files, and then
loads these into the table. If the file loaded on the master
is huge, the temporary files on the slave are huge, too.
Therefore, it might be advisable to use this option to tell
the slave to put temporary files in a directory located in
some file system that has a lot of available space. In that
case, the relay logs are huge as well, so you might also
want to use the --relay-log
option to place the relay logs in that file system.
The directory specified by this option should be located in
a disk-based file system (not a memory-based file system)
because the temporary files used to replicate
LOAD DATA
INFILE
must survive machine restarts. The
directory also should not be one that is cleared by the
operating system during the system startup process.
slave-max-allowed-packet=
bytes
Command-Line Format | --slave-max-allowed-packet=# | ||
Permitted Values | Type | integer | |
Default | 1073741824 | ||
Min Value | 1024 | ||
Max Value | 1073741824 |
This option sets the maximum packet size in bytes for the
slave SQL and I/O threads, so that large updates using
row-based replication do not cause replication to fail
because an update exceeded
max_allowed_packet
. (Bug
#12400221, Bug #60926)
The corresponding server variable
slave_max_allowed_packet
always has a value that is a positive integer multiple of
1024; if you set it to some value that is not such a
multiple, the value is automatically rounded down to the
next highest multiple of 1024. (For example, if you start
the server with
--slave-max-allowed-packet=10000
, the value
used is 9216; setting 0 as the value causes 1024 to be
used.) A truncation warning is issued in such cases.
The maximum (and default) value is 1073741824 (1 GB); the minimum is 1024.
Command-Line Format | --slave-net-timeout=# | ||
System Variable | Name | slave_net_timeout | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 3600 | ||
Min Value | 1 | ||
Permitted Values (>= 5.7.7) | Type | integer | |
Default | 60 | ||
Min Value | 1 |
The number of seconds to wait for more data from the master
before the slave considers the connection broken, aborts the
read, and tries to reconnect. The first retry occurs
immediately after the timeout. The interval between retries
is controlled by the MASTER_CONNECT_RETRY
option for the CHANGE MASTER
TO
statement, and the number of reconnection
attempts is limited by the
--master-retry-count
option.
Prior to MySQL 5.7.7, the default was 3600 seconds (one
hour). In MySQL 5.7.7 and later the default is 60 (one
minute).
Introduced | 5.7.2 | ||
Command-Line Format | --slave-parallel-type=type | ||
Permitted Values | Type | enumeration | |
Default | DATABASE | ||
Valid Values | DATABASE | ||
LOGICAL_CLOCK |
When using a multi-threaded slave
(slave_parallel_workers
is
greater than 0), this option specifies the policy used to
decide which transactions are allowed to execute in parallel
on the slave. The possible values are:
DATABASE
: Transactions that update
different databases are applied in parallel. This value
is only appropriate if data is partitioned into multiple
databases which are being updated independently and
concurrently on the master. Only recommended if there
are no cross-database constraints, as such constraints
may be violated on the slave.
LOGICAL_CLOCK
: Transactions that are
part of the same binary log group commit on a master are
applied in parallel on a slave. There are no
cross-database constraints, and data does not need to be
partitioned into multiple databases.
Regardless of the value of this variable, there is no
special configuration required on the master. When
slave_preserve_commit_order=1
,
you can only use LOGICAL_CLOCK
. If your
replication topology uses multiple levels of slaves,
LOGICAL_CLOCK
may achieve less
parallelization for each level the slave is away from the
master.
slave-rows-search-algorithms=
list
Command-Line Format | --slave-rows-search-algorithms=list | ||
Permitted Values | Type | set | |
Default | TABLE_SCAN,INDEX_SCAN | ||
Valid Values | TABLE_SCAN,INDEX_SCAN | ||
INDEX_SCAN,HASH_SCAN | |||
TABLE_SCAN,HASH_SCAN | |||
TABLE_SCAN,INDEX_SCAN,HASH_SCAN (equivalent to INDEX_SCAN,HASH_SCAN) |
When preparing batches of rows for row-based logging and
replication, this option controls how the rows are searched
for matches—that is, whether or not hashing is used
for searches using a primary or unique key, some other key,
or no key at all. This option takes a comma-separated list
of any 2 (or possibly 3) values from the list
INDEX_SCAN
,
TABLE_SCAN
, HASH_SCAN
.
The list need not be quoted, but must contain no spaces,
whether or not quotes are used. Possible combinations
(lists) and their effects are shown in the following table:
Index used / option value | INDEX_SCAN,HASH_SCAN or
INDEX_SCAN,TABLE_SCAN,HASH_SCAN | INDEX_SCAN,TABLE_SCAN | TABLE_SCAN,HASH_SCAN |
---|---|---|---|
Primary key or unique key | Index scan | Index scan | Hash scan over index |
(Other) Key | Hash scan over index | Index scan | Hash scan over index |
No index | Hash scan | Table scan | Hash scan |
The order in which the algorithms are specified in the list
does not make any difference in the order in which they are
displayed by a SELECT
or
SHOW VARIABLES
statement
(which is the same as that used in the table just shown
previously).The default value is
TABLE_SCAN,INDEX_SCAN
, which means that
all searches that can use indexes do use them, and searches
without any indexes use table scans.
Specifying
INDEX_SCAN,TABLE_SCAN,HASH_SCAN
has the
same effect as specifying
INDEX_SCAN,HASH_SCAN
. To use hashing for
any searches that does not use a primary or unique key, set
this option to INDEX_SCAN,HASH_SCAN
. To
force hashing for all searches, set it
to TABLE_SCAN,HASH_SCAN
.
There is only a performance advantage for
INDEX_SCAN
and
HASH_SCAN
if the row events are big
enough. The size of row events is configured using
--binlog-row-event-max-size
. For
example, suppose a DELETE
statement which deletes 25,000 rows generates large
Delete_row_event
events. In this case
if
slave_rows_search_algorithms
is set to INDEX_SCAN
or
HASH_SCAN
there is a performance
improvement. However, if there are 25,000
DELETE
statements and each
is represented by a separate event then setting
slave_rows_search_algorithms
to INDEX_SCAN
or
HASH_SCAN
provides no performance
improvement while executing these separate events.
--slave-skip-errors=[
err_code1
,err_code2
,...|all|ddl_exist_errors]
Command-Line Format | --slave-skip-errors=name | ||
System Variable | Name | slave_skip_errors | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors | |||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors | |||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors |
Normally, replication stops when an error occurs on the slave, which gives you the opportunity to resolve the inconsistency in the data manually. This option causes the slave SQL thread to continue replication when a statement returns any of the errors listed in the option value.
Do not use this option unless you fully understand why you are getting errors. If there are no bugs in your replication setup and client programs, and no bugs in MySQL itself, an error that stops replication should never occur. Indiscriminate use of this option results in slaves becoming hopelessly out of synchrony with the master, with you having no idea why this has occurred.
For error codes, you should use the numbers provided by the
error message in your slave error log and in the output of
SHOW SLAVE STATUS
.
Appendix B, Errors, Error Codes, and Common Problems, lists server error codes.
You can also (but should not) use the very nonrecommended
value of all
to cause the slave to ignore
all error messages and keeps going regardless of what
happens. Needless to say, if you use all
,
there are no guarantees regarding the integrity of your
data. Please do not complain (or file bug reports) in this
case if the slave's data is not anywhere close to what it is
on the master. You have been warned.
MySQL 5.7 supports an additional shorthand
value ddl_exist_errors
, which is
equivalent to the error code list
1007,1008,1050,1051,1054,1060,1061,1068,1094,1146
.
Examples:
--slave-skip-errors=1062,1053 --slave-skip-errors=all --slave-skip-errors=ddl_exist_errors
--slave-sql-verify-checksum={0|1}
Command-Line Format | --slave-sql-verify-checksum=value | ||
Permitted Values | Type | boolean | |
Default | 0 | ||
Valid Values | 0 | ||
1 |
When this option is enabled, the slave examines checksums read from the relay log, in the event of a mismatch, the slave stops with an error. Disabled by default.
The following options are used internally by the MySQL test suite for replication testing and debugging. They are not intended for use in a production setting.
Command-Line Format | --abort-slave-event-count=# | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 |
When this option is set to some positive integer
value
other than 0 (the default)
it affects replication behavior as follows: After the slave
SQL thread has started, value
log
events are permitted to be executed; after that, the slave
SQL thread does not receive any more events, just as if the
network connection from the master were cut. The slave
thread continues to run, and the output from
SHOW SLAVE STATUS
displays
Yes
in both the
Slave_IO_Running
and the
Slave_SQL_Running
columns, but no further
events are read from the relay log.
--disconnect-slave-event-count
Command-Line Format | --disconnect-slave-event-count=# | ||
Permitted Values | Type | integer | |
Default | 0 |
MySQL 5.7 supports logging of replication slave status information to tables rather than files. Writing of the master info log and the relay log info log can be configured separately using the two server options listed here:
--master-info-repository={FILE|TABLE}
Command-Line Format | --master-info-repository=FILE|TABLE | ||
Permitted Values | Type | string | |
Default | FILE | ||
Valid Values | FILE | ||
TABLE |
This option causes the server to write its master info log
to a file or a table. The name of the file defaults to
master.info
; you can change the name of
the file using the
--master-info-file
server
option.
The default value for this option is
FILE
. If you use
TABLE
, the log is written to the
slave_master_info
table in the
mysql
database.
--relay-log-info-repository={FILE|TABLE}
Command-Line Format | --relay-log-info-repository=FILE|TABLE | ||
Permitted Values | Type | string | |
Default | FILE | ||
Valid Values | FILE | ||
TABLE |
This option causes the server to log its relay log info to a
file or a table. The name of the file defaults to
relay-log.info
; you can change the name
of the file using the
--relay-log-info-file
server
option.
The default value for this option is
FILE
. If you use
TABLE
, the log is written to the
slave_relay_log_info
table in the
mysql
database.
These options can be used to make replication slaves resilient to unexpected halts. See Section 18.3.2, “Handling an Unexpected Halt of a Replication Slave”, for more information.
The info log tables and their contents are considered local to a given MySQL Server. They are not replicated, and changes to them are not written to the binary log.
For more information, see Section 18.2.4, “Replication Relay and Status Logs”.
The following list describes system variables for controlling
replication slave servers. They can be set at server startup and
some of them can be changed at runtime using
SET
.
Server options used with replication slaves are listed earlier
in this section.
Command-Line Format | --init-slave=name | ||
System Variable | Name | init_slave | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | string |
This variable is similar to
init_connect
, but is a
string to be executed by a slave server each time the SQL
thread starts. The format of the string is the same as for
the init_connect
variable.
The setting of this variable takes effect for subsequent
START SLAVE
statements.
The SQL thread sends an acknowledgment to the client
before it executes
init_slave
. Therefore, it
is not guaranteed that
init_slave
has been
executed when START SLAVE
returns. See Section 14.4.2.6, “START SLAVE Syntax”, for more
information.
Introduced | 5.7.1 | ||
System Variable | Name | log_slow_slave_statements | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | OFF |
When the slow query log is enabled, this variable enables
logging for queries that have taken more than
long_query_time
seconds to
execute on the slave. This variable was added in MySQL
5.7.1. Setting this variable has no immediate effect. The
state of the variable applies on all subsequent
START SLAVE
statements.
Command-Line Format | --master-info-repository=FILE|TABLE | ||
System Variable | Name | master_info_repository | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | string | |
Default | FILE | ||
Valid Values | FILE | ||
TABLE |
The setting of this variable determines whether the slave
logs master status and connection information to a
FILE
(master.info
),
or to a TABLE
(mysql.slave_master_info
). You can only
change the value of this variable when no replication
threads are executing.
The setting of this variable also has a direct influence on
the effect had by the setting of the
sync_master_info
system
variable; see that variable's description for further
information.
This variable must be set to TABLE
before
configuring multiple replication channels. If you are using
multiple replication channels then you cannot set this
variable back to FILE
.
Command-Line Format | --relay-log=file_name | ||
System Variable | Name | relay_log | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name |
The base name of the relay log file, with no paths and no
file extension. By default relay-log
.
The file name of individual files for the default
replication channel is
relay-log.XXXXXX
, and for additional
replication channels is
relay-log-
.
channel
.XXXXXX
System Variable | Name | relay_log_basename | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name | |
Default | datadir + '/' + hostname + '-relay-bin' |
Holds the name and complete path to the relay log file.
Command-Line Format | --relay-log-index | ||
System Variable | Name | relay_log_index | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name | |
Default | *host_name*-relay-bin.index |
The name of the relay log index file for the default
replication channel. The default name is
in the data directory, where
host_name
-relay-bin.indexhost_name
is the name of the
slave server.
Command-Line Format | --relay-log-info-file=file_name | ||
System Variable | Name | relay_log_info_file | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name | |
Default | relay-log.info |
The name of the file in which the slave records information
about the relay logs, when
relay_log_info_repository=FILE
.
If
relay_log_info_repository=TABLE
,
it is the file name that would be used in case the
repository was changed to FILE
). The
default name is relay-log.info
in the
data directory.
System Variable | Name | relay_log_info_repository | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | string | |
Default | FILE | ||
Valid Values | FILE | ||
TABLE |
This variable determines whether the slave's position
in the relay logs is written to a FILE
(relay-log.info
) or to a
TABLE
(mysql.slave_relay_log_info
). You can
only change the value of this variable when no replication
threads are executing.
The setting of this variable also has a direct influence on
the effect had by the setting of the
sync_relay_log_info
system
variable; see that variable's description for further
information.
This variable must be set to TABLE
before
configuring multiple replication channels. If you are using
multiple replication channels then you cannot set this
variable back to FILE
.
Command-Line Format | --relay-log-recovery | ||
System Variable | Name | relay_log_recovery | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | FALSE |
Enables automatic relay log recovery immediately following
server startup. The recovery process creates a new relay log
file, initializes the SQL thread position to this new relay
log, and initializes the I/O thread to the SQL thread
position. Reading of the relay log from the master then
continues. In MySQL 5.7, this global variable is read-only;
its value can be changed by starting the slave with the
--relay-log-recovery
option,
which should be used following an unexpected halt of a
replication slave to ensure that no possibly corrupted relay
logs are processed. See
Section 18.3.2, “Handling an Unexpected Halt of a Replication Slave”
for more information.
This variable also interacts with
relay-log-purge
, which
controls purging of logs when they are no longer needed.
Enabling the
--relay-log-recovery
option
when relay-log-purge
is
disabled risks reading the relay log from files that were
not purged, leading to data inconsistency.
When relay_log_recovery
is enabled and
the slave has stopped due to errors encountered while
running in multi-threaded mode, you can use
START SLAVE
UNTIL SQL_AFTER_MTS_GAPS
to ensure that all gaps
are processed before switching back to single-threaded mode
or executing a CHANGE MASTER TO
statement.
Introduced | 5.7.2 | ||
Command-Line Format | --rpl-stop-slave-timeout=seconds | ||
System Variable | Name | rpl_stop_slave_timeout | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 31536000 | ||
Min Value | 2 | ||
Max Value | 31536000 |
In MySQL 5.7.2 and later, you can control the length of time
(in seconds) that STOP SLAVE
waits before timing out by setting this variable. This can
be used to avoid deadlocks between STOP
SLAVE
and other slave SQL statements using
different client connections to the slave. The maximum and
default value of rpl_stop_slave_timeout
is 31536000 seconds (1 year). The minimum is 2 seconds.
Changes to this variable take effect for subsequent
STOP SLAVE
statements. This
variable affects only the client that issues a
STOP SLAVE
statement. When
the timeout is reached, the issuing client stops waiting for
the slave threads to stop, but the slave threads continue to
try to stop.
Command-Line Format | --slave-checkpoint-group=# | ||
System Variable | Name | slave_checkpoint_group=# | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 512 | ||
Min Value | 32 | ||
Max Value | 524280 | ||
Block Size | 8 |
Sets the maximum number of transactions that can be
processed by a multi-threaded slave before a checkpoint
operation is called to update its status as shown by
SHOW SLAVE STATUS
. Setting
this variable has no effect on slaves for which
multi-threading is not enabled. Setting this variable has no
immediate effect. The state of the variable applies on all
subsequent START SLAVE
commands.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this variable. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
This variable works in combination with the
slave_checkpoint_period
system variable in such a way that, when either limit is
exceeded, the checkpoint is executed and the counters
tracking both the number of transactions and the time
elapsed since the last checkpoint are reset.
The minimum allowed value for this variable is 32, unless
the server was built using
-DWITH_DEBUG
, in which case
the minimum value is 1. The effective value is always a
multiple of 8; you can set it to a value that is not such a
multiple, but the server rounds it down to the next lower
multiple of 8 before storing the value.
(Exception: No such rounding is
performed by the debug server.) Regardless of how the server
was built, the default value is 512, and the maximum allowed
value is 524280.
Command-Line Format | --slave-checkpoint-period=# | ||
System Variable | Name | slave_checkpoint_period=# | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 300 | ||
Min Value | 1 | ||
Max Value | 4G |
Sets the maximum time (in milliseconds) that is allowed to
pass before a checkpoint operation is called to update the
status of a multi-threaded slave as shown by
SHOW SLAVE STATUS
. Setting
this variable has no effect on slaves for which
multi-threading is not enabled. Setting this variable takes
effect for all replication channels immediately, including
running channels.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this variable. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
This variable works in combination with the
slave_checkpoint_group
system variable in such a way that, when either limit is
exceeded, the checkpoint is executed and the counters
tracking both the number of transactions and the time
elapsed since the last checkpoint are reset.
The minimum allowed value for this variable is 1, unless the
server was built using
-DWITH_DEBUG
, in which case
the minimum value is 0. Regardless of how the server was
built, the default value is 300, and the maximum possible
value is 4294967296 (4GB).
Command-Line Format | --slave_compressed_protocol | ||
System Variable | Name | slave_compressed_protocol | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | OFF |
Whether to use compression of the slave/master protocol if
both the slave and the master support it. Changes to this
variable take effect on subsequent connection attempts; this
includes after issuing a START SLAVE
statement, as well as reconnections made by a
running I/O thread (for example after issuing a
CHANGE MASTER TO MASTER_RETRY_COUNT
statement).
Command-Line Format | --slave-exec-mode=mode | ||
System Variable | Name | slave_exec_mode | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | enumeration | |
Default | STRICT (ALL) | ||
Default | IDEMPOTENT (NDB) | ||
Valid Values | IDEMPOTENT | ||
STRICT |
Controls how a slave thread resolves conflicts and errors
during replication. STRICT
mode is the
default, and is suitable for most cases.
IDEMPOTENT
mode causes suppression of
duplicate-key and no-key-found errors. This mode should only
be used with MySQL Cluster Replication in some special
scenarios, such as multi-master replication, and circular
replication. (See
Section 21.6.10, “NDB Cluster Replication: Multi-Master and Circular Replication”,
and
Section 21.6.11, “NDB Cluster Replication Conflict Resolution”,
for more information.) Setting this variable takes effect
for all replication channels immediately, including running
channels.
The mysqld supplied with MySQL Cluster
ignores any value explicitly set for
slave_exec_mode
, and
always treats it as IDEMPOTENT
.
IDEMPOTENT
mode is supported only by
NDB
and is used when
replicating NDB
to
InnoDB
.
Command-Line Format | --slave-load-tmpdir=dir_name | ||
System Variable | Name | slave_load_tmpdir | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | directory name | |
Default | /tmp |
The name of the directory where the slave creates temporary
files for replicating
LOAD DATA
INFILE
statements. Setting this variable takes
effect for all replication channels immediately, including
running channels.
System Variable | Name | slave_max_allowed_packet | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1073741824 | ||
Min Value | 1024 | ||
Max Value | 1073741824 |
This variable sets the maximum packet size for the slave SQL
and I/O threads, so that large updates using row-based
replication do not cause replication to fail because an
update exceeded
max_allowed_packet
. Setting
this variable takes effect for all replication channels
immediately, including running channels.
This global variable always has a value that is a positive
integer multiple of 1024; if you set it to some value that
is not, the value is rounded down to the next highest
multiple of 1024 for it is stored or used; setting
slave_max_allowed_packet
to 0 causes 1024
to be used. (A truncation warning is issued in all such
cases.) The default and maximum value is 1073741824 (1 GB);
the minimum is 1024.
slave_max_allowed_packet
can also be set
at startup, using the
--slave-max-allowed-packet
option.
Command-Line Format | --slave-net-timeout=# | ||
System Variable | Name | slave_net_timeout | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 3600 | ||
Min Value | 1 | ||
Permitted Values (>= 5.7.7) | Type | integer | |
Default | 60 | ||
Min Value | 1 |
The number of seconds to wait for more data from a
master/slave connection before aborting the read. Setting
this variable has no immediate effect. The state of the
variable applies on all subsequent
START SLAVE
commands.
Introduced | 5.7.2 | ||
Command-Line Format | --slave-parallel-type=type | ||
Permitted Values | Type | enumeration | |
Default | DATABASE | ||
Valid Values | DATABASE | ||
LOGICAL_CLOCK |
When using a multi-threaded slave
(slave_parallel_workers
is
greater than 0), this variable specifies the policy used to
decide which transactions are allowed to execute in parallel
on the slave. See
--slave-parallel-type
for
more information.
Command-Line Format | --slave-parallel-workers=# | ||
System Variable | Name | slave_parallel_workers | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 1024 |
Sets the number of slave applier threads for executing
replication transactions in parallel. Setting this variable
to a number greater than 0 creates a multi-threaded slave
with this number of applier threads. When set to 0 (the
default) parallel execution is disabled and the slave uses a
single applier thread. Setting
slave_parallel_workers
has
no immediate effect. The state of the variable applies on
all subsequent START SLAVE
statements.
Multi-threaded slaves are not currently supported by MySQL Cluster, which silently ignores the setting for this variable. See Section 21.6.3, “Known Issues in NDB Cluster Replication”, for more information.
A multi-threaded slave provides parallel execution by using
a coordinator thread and the number of applier threads
configured by this variable. The way which transactions are
distributed among applier threads is configured by
slave_parallel_type
. The
transactions that the slave applies in parallel may commit
out of order, unless
slave_preserve_commit_order=1
.
Therefore, checking for the most recently executed
transaction does not guarantee that all previous
transactions from the master have been executed on the
slave. This has implications for logging and recovery when
using a multi-threaded slave. For example, on a
multi-threaded slave the
START SLAVE
UNTIL
statement only supports using
SQL_AFTER_MTS_GAPS
.
In MySQL 5.7.5 and later, retrying of transactions is
supported when multi-threading is enabled on a slave. In
previous versions,
slave_transaction_retries
was treated as equal to 0 when using multi-threaded slaves.
System Variable | Name | slave_pending_jobs_size_max | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 16M | ||
Min Value | 1024 | ||
Max Value | 18EB | ||
Block Size | 1024 |
For multi-threaded slaves, this variable sets the maximum
amount of memory (in bytes) available to slave worker queues
holding events not yet applied. Setting this variable has no
effect on slaves for which multi-threading is not enabled.
Setting this variable has no immediate effect. The state of
the variable applies on all subsequent
START SLAVE
commands.
The minimum possible value for this variable is 1024; the default is 16MB. The maximum possible value is 18446744073709551615 (16 exabytes). Values that are not exact multiples of 1024 are rounded down to the next-highest multiple of 1024 prior to being stored.
The value of this variable must not be less than the
master's value for
max_allowed_packet
;
otherwise a slave worker queue may become full while there
remain events coming from the master to be processed.
Introduced | 5.7.5 | ||
Command-Line Format | --slave-preserve-commit-order=value | ||
System Variable | Name | slave_preserve_commit_order | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | 0 | ||
Valid Values | 0 | ||
1 |
For multi-threaded slaves, enabling this variable ensures
that transactions are externalized on the slave in the same
order as they appear in the slave's relay log. Setting
this variable has no effect on slaves for which
multi-threading is not enabled. All replication threads (for
all replication channels if you are using multiple
replication channels) must be stopped before changing this
variable. --log-bin
and
--log-slave-updates
must be
enabled on the slave. In addition
--slave-parallel-type
must be set to
LOGICAL_CLOCK
.
Once a multi-threaded slave has been started, transactions
can begin to execute in parallel. With
slave_preserve_commit_order
enabled, the executing thread waits until all previous
transactions are committed before committing. While the
slave thread is waiting for other workers to commit their
transactions it reports its status as Waiting for
preceding transaction to commit
. (Prior to MySQL
5.7.8, this was shown as Waiting for its turn to
commit
.) Enabling this mode on a multi-threaded
slave ensures that it never enters a state that the master
was not in. This makes it well suited to using replication
for read scale-out. See
Section 18.3.4, “Using Replication for Scale-Out”.
When using a multi-threaded slave, if
slave_preserve_commit_order
is not enabled, there is a chance of gaps in the sequence of
transactions that have been executed from the slave's
relay log. When this option is enabled, there is not this
chance of gaps, but Exec_master_log_pos
may be behind the position up to which has been executed.
See
Section 18.4.1.34, “Replication and Transaction Inconsistencies”
for more information.
System Variable | Name | slave_rows_search_algorithms=list | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | set | |
Default | TABLE_SCAN,INDEX_SCAN | ||
Valid Values | TABLE_SCAN,INDEX_SCAN | ||
INDEX_SCAN,HASH_SCAN | |||
TABLE_SCAN,HASH_SCAN | |||
TABLE_SCAN,INDEX_SCAN,HASH_SCAN (equivalent to INDEX_SCAN,HASH_SCAN) |
When preparing batches of rows for row-based logging and replication, this variable controls how the rows are searched for matches—that is, whether or not hashing is used for searches using a primary or unique key, using some other key, or using no key at all. Setting this variable takes effect for all replication channels immediately, including running channels.
This variable takes a comma-separated list of at least 2
values from the list INDEX_SCAN
,
TABLE_SCAN
, HASH_SCAN
.
The value expected as a string, so the value must be quoted.
In addition, the value must not contain any spaces. Possible
combinations (lists) and their effects are shown in the
following table:
Index used / option value | INDEX_SCAN,HASH_SCAN or
INDEX_SCAN,TABLE_SCAN,HASH_SCAN | INDEX_SCAN,TABLE_SCAN | TABLE_SCAN,HASH_SCAN |
---|---|---|---|
Primary key or unique key | Index scan | index scan | Index hash |
(Other) Key | Index hash | Index scan | Index hash |
No index | Table hash | Table scan | Table hash |
The order in which the algorithms are specified in the list
does not make any difference in the order in which they are
displayed by a SELECT
or
SHOW VARIABLES
statement, as
shown here:
mysql>SET GLOBAL slave_rows_search_algorithms = "INDEX_SCAN,TABLE_SCAN";
Query OK, 0 rows affected (0.00 sec) mysql>SHOW VARIABLES LIKE '%algorithms%';
+------------------------------+-----------------------+ | Variable_name | Value | +------------------------------+-----------------------+ | slave_rows_search_algorithms | TABLE_SCAN,INDEX_SCAN | +------------------------------+-----------------------+ 1 row in set (0.00 sec) mysql>SET GLOBAL slave_rows_search_algorithms = "TABLE_SCAN,INDEX_SCAN";
Query OK, 0 rows affected (0.00 sec) mysql>SHOW VARIABLES LIKE '%algorithms%';
+------------------------------+-----------------------+ | Variable_name | Value | +------------------------------+-----------------------+ | slave_rows_search_algorithms | TABLE_SCAN,INDEX_SCAN | +------------------------------+-----------------------+ 1 row in set (0.00 sec)
The default value is
TABLE_SCAN,INDEX_SCAN
, which means that
all searches that can use indexes do use them, and searches
without any indexes use table scans.
Specifying
INDEX_SCAN,TABLE_SCAN,HASH_SCAN
has the
same effect as specifying
INDEX_SCAN,HASH_SCAN
. To use hashing for
any searches that does not use a primary or unique key, set
this variable to INDEX_SCAN,HASH_SCAN
. To
force hashing for all searches, set it
to TABLE_SCAN,HASH_SCAN
.
Command-Line Format | --slave-skip-errors=name | ||
System Variable | Name | slave_skip_errors | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors | |||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors | |||
Permitted Values | Type | string | |
Default | OFF | ||
Valid Values | OFF | ||
[list of error codes] | |||
all | |||
ddl_exist_errors |
Normally, replication stops when an error occurs on the slave, which gives you the opportunity to resolve the inconsistency in the data manually. This variable causes the slave SQL thread to continue replication when a statement returns any of the errors listed in the variable value. The setting of this variable takes effect immediately, even for running replication threads.
System Variable | Name | slave_sql_verify_checksum | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | 1 | ||
Valid Values | 0 | ||
1 |
Cause the slave SQL thread to verify data using the checksums read from the relay log. In the event of a mismatch, the slave stops with an error. Setting this variable takes effect for all replication channels immediately, including running channels.
The slave I/O thread always reads checksums if possible when accepting events from over the network.
Command-Line Format | --slave_transaction_retries=# | ||
System Variable | Name | slave_transaction_retries | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 10 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 10 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
If a replication slave SQL thread fails to execute a
transaction because of an
InnoDB
deadlock or because the
transaction's execution time exceeded
InnoDB
's
innodb_lock_wait_timeout
or
NDB
's
TransactionDeadlockDetectionTimeout
or
TransactionInactiveTimeout
,
it automatically retries
slave_transaction_retries
times before stopping with an error. The default value is
10. Setting this variable takes effect for all replication
channels immediately, including running channels.
As of MySQL 5.7.5, retrying of transactions is supported
when multi-threading is enabled on a slave. In previous
versions,
slave_transaction_retries
was treated as equal to 0 when using multi-threaded slaves.
Command-Line Format | --slave_type_conversions=set | ||
System Variable | Name | slave_type_conversions | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values (<= 5.7.1) | Type | set | |
Default |
| ||
Valid Values | ALL_LOSSY | ||
ALL_NON_LOSSY | |||
Permitted Values (>= 5.7.2) | Type | set | |
Default |
| ||
Valid Values | ALL_LOSSY | ||
ALL_NON_LOSSY | |||
ALL_SIGNED | |||
ALL_UNSIGNED |
Controls the type conversion mode in effect on the slave
when using row-based replication. In MySQL 5.7.2 and later,
its value is a comma-delimited set of zero or more elements
from the list: ALL_LOSSY
,
ALL_NON_LOSSY
,
ALL_SIGNED
,
ALL_UNSIGNED
. Set this variable to an
empty string to disallow type conversions between the master
and the slave. Setting this variable takes effect for all
replication channels immediately, including running
channels.
ALL_SIGNED
and
ALL_UNSIGNED
were added in MySQL 5.7.2
(Bug#15831300). For additional information on type
conversion modes applicable to attribute promotion and
demotion in row-based replication, see
Row-based replication: attribute promotion and demotion.
System Variable | Name | sql_slave_skip_counter | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer |
The number of events from the master that a slave server
should skip. Setting the option has no immediate effect. The
variable applies to the next START
SLAVE
statement; the next
START SLAVE
statement also
changes the value back to 0. When this variable is set to a
non-zero value and there are multiple replication channels
configured, the START SLAVE
statement can only be used with the FOR CHANNEL
clause.
channel
This option is incompatible with GTID-based replication, and
must not be set to a nonzero value when
--gtid-mode=ON
. In MySQL
5.7.1 and later, trying to do so is specifically disallowed.
(Bug #15833516) If you need to skip transactions when
employing GTIDs, use
gtid_executed
from the
master instead. See
Injecting empty transactions, for
information about how to do this.
If skipping the number of events specified by setting this variable would cause the slave to begin in the middle of an event group, the slave continues to skip until it finds the beginning of the next event group and begins from that point. For more information, see Section 14.4.2.5, “SET GLOBAL sql_slave_skip_counter Syntax”.
Command-Line Format | --sync-master-info=# | ||
System Variable | Name | sync_master_info | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
The effects of this variable on a replication slave depend
on whether the slave's
master_info_repository
is
set to FILE
or TABLE
,
as explained in the following paragraphs.
master_info_repository = FILE.
If the value of sync_master_info
is
greater than 0, the slave synchronizes its
master.info
file to disk (using
fdatasync()
) after every
sync_master_info
events. If it is 0,
the MySQL server performs no synchronization of the
master.info
file to disk; instead,
the server relies on the operating system to flush its
contents periodically as with any other file.
master_info_repository = TABLE.
If the value of sync_master_info
is
greater than 0, the slave updates its master info
repository table after every
sync_master_info
events. If it is 0,
the table is never updated.
The default value for sync_master_info
is
10000. Setting this variable takes effect for all
replication channels immediately, including running
channels.
Command-Line Format | --sync-relay-log=# | ||
System Variable | Name | sync_relay_log | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
If the value of this variable is greater than 0, the MySQL
server synchronizes its relay log to disk (using
fdatasync()
) after every
sync_relay_log
events are written to the
relay log. Setting this variable takes effect for all
replication channels immediately, including running
channels.
Setting sync_relay_log
to 0 causes no
synchronization to be done to disk; in this case, the server
relies on the operating system to flush the relay log's
contents from time to time as for any other file.
A value of 1 is the safest choice because in the event of a crash you lose at most one event from the relay log. However, it is also the slowest choice (unless the disk has a battery-backed cache, which makes synchronization very fast).
Command-Line Format | --sync-relay-log-info=# | ||
System Variable | Name | sync_relay_log_info | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 10000 | ||
Min Value | 0 | ||
Max Value | 18446744073709551615 |
The effects of this variable on the slave depend on the
server's
relay_log_info_repository
setting (FILE
or
TABLE
), and if this is
TABLE
, additionally on whether the
storage engine used by the relay log info table is
transactional (such as InnoDB
)
or not (MyISAM
). The effects of
these factors on the behavior of the server for
sync_relay_log_info
values of zero and
greater than zero are shown in the following table:
sync_relay_log_info | relay_log_info_repository | ||
---|---|---|---|
FILE | TABLE | ||
Transactional | Nontransactional | ||
|
The slave synchronizes its
|
The table is updated after each transaction.
( |
The table is updated after every
|
0 |
The MySQL server performs no synchronization of
the | The table is never updated. |
The default value for sync_relay_log_info
is 10000. Setting this variable takes effect for all
replication channels immediately, including running
channels.
Startup Options Used with Binary Logging
System Variables Used with Binary Logging
You can use the mysqld options and system variables that are described in this section to affect the operation of the binary log as well as to control which statements are written to the binary log. For additional information about the binary log, see Section 6.4.4, “The Binary Log”. For additional information about using MySQL server options and system variables, see Section 6.1.4, “Server Command Options”, and Section 6.1.5, “Server System Variables”.
The following list describes startup options for enabling and configuring the binary log. System variables used with binary logging are discussed later in this section.
Command-Line Format | --binlog-row-event-max-size=# | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 8192 | ||
Min Value | 256 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 8192 | ||
Min Value | 256 | ||
Max Value | 18446744073709551615 |
Specify the maximum size of a row-based binary log event, in bytes. Rows are grouped into events smaller than this size if possible. The value should be a multiple of 256. The default is 8192. See Section 18.2.1, “Replication Formats”.
Command-Line Format | --log-bin | ||
System Variable | Name | log_bin | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name |
Enable binary logging. The server logs all statements that change data to the binary log, which is used for backup and replication. See Section 6.4.4, “The Binary Log”.
The option value, if given, is the base name for the log
sequence. The server creates binary log files in sequence by
adding a numeric suffix to the base name. It is recommended
that you specify a base name (see Section B.5.7, “Known Issues in MySQL”,
for the reason). Otherwise, MySQL uses
as the base name.
host_name
-bin
When the server reads an entry from the index file, it
checks whether the entry contains a relative path, and if it
does, the relative part of the path in replaced with the
absolute path set using the --log-bin
option. An absolute path remains unchanged; in such a case,
the index must be edited manually to enable the new path or
paths to be used. (In older versions of MySQL, manual
intervention was required whenever relocating the binary log
or relay log files.) (Bug #11745230, Bug #12133)
Setting this option causes the
log_bin
system variable to
be set to ON
(or 1
),
and not to the base name. The binary log file name (with
path) is available as the
log_bin_basename
system
variable.
In MySQL 5.7.3 and later, if you specify this option without
also specifying a
--server-id
, the server is
not allowed to start. (Bug #11763963, Bug #56739)
Command-Line Format | --log-bin-index=file_name | ||
Permitted Values | Type | file name |
The index file for binary log file names. See
Section 6.4.4, “The Binary Log”. If you omit the file name, and
if you did not specify one with
--log-bin
, MySQL uses
as the file name.
host_name
-bin.index
--log-bin-trust-function-creators[={0|1}]
Command-Line Format | --log-bin-trust-function-creators | ||
System Variable | Name | log_bin_trust_function_creators | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | FALSE |
This option sets the corresponding
log_bin_trust_function_creators
system variable. If no argument is given, the option sets
the variable to 1.
log_bin_trust_function_creators
affects how MySQL enforces restrictions on stored function
and trigger creation. See
Section 23.7, “Binary Logging of Stored Programs”.
--log-bin-use-v1-row-events[={0|1}]
Command-Line Format | --log-bin-use-v1-row-events[={0|1}] | ||
System Variable | Name | log_bin_use_v1_row_events | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | 0 |
MySQL 5.7 uses Version 2 binary log row events,
which cannot be read by MySQL Server releases prior to MySQL
5.6.6. Setting this option to 1 causes
mysqld to write the binary log using
Version 1 logging events, which is the only version of
binary log events used in previous releases, and thus
produce binary logs that can be read by older slaves.
Setting --log-bin-use-v1-row-events
to 0
(the default) causes mysqld to use
Version 2 binary log events.
The value used for this option can be obtained from the
read-only
log_bin_use_v1_row_events
system variable.
--log-bin-use-v1-row-events
is chiefly of
interest when setting up replication conflict detection and
resolution using NDB$EPOCH_TRANS()
as the
conflict detection function, which requires Version 2 binary
log row events. Thus, this option and
--ndb-log-transaction-id
are
not compatible.
For more information, see Section 21.6.11, “NDB Cluster Replication Conflict Resolution”.
Statement selection options. The options in the following list affect which statements are written to the binary log, and thus sent by a replication master server to its slaves. There are also options for slave servers that control which statements received from the master should be executed or ignored. For details, see Section 18.1.6.3, “Replication Slave Options and Variables”.
Command-Line Format | --binlog-do-db=name | ||
Permitted Values | Type | string |
This option affects binary logging in a manner similar to
the way that
--replicate-do-db
affects
replication.
The effects of this option depend on whether the
statement-based or row-based logging format is in use, in
the same way that the effects of
--replicate-do-db
depend on
whether statement-based or row-based replication is in use.
You should keep in mind that the format used to log a given
statement may not necessarily be the same as that indicated
by the value of
binlog_format
. For example,
DDL statements such as CREATE
TABLE
and ALTER
TABLE
are always logged as statements, without
regard to the logging format in effect, so the following
statement-based rules for --binlog-do-db
always apply in determining whether or not the statement is
logged.
Statement-based logging.
Only those statements are written to the binary log 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; however, doing so does
not cause cross-database statements
such as UPDATE
to be logged while a different
database (or no database) is selected.
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, the list will be treated as the name of a single database if you supply a comma-separated list.
An example of what does not work as you might expect when
using statement-based logging: If the server is started with
--binlog-do-db=sales
and you
issue the following statements, the
UPDATE
statement is
not logged:
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.
Another case which may not be self-evident occurs when a
given database is replicated even though it was not
specified when setting the option. If the server is started
with --binlog-do-db=sales
, the following
UPDATE
statement is logged
even though prices
was not included when
setting --binlog-do-db
:
USE sales; UPDATE prices.discounts SET percentage = percentage + 10;
Because sales
is the default database
when the UPDATE
statement is
issued, the UPDATE
is logged.
Row-based logging.
Logging is restricted to database
db_name
. Only changes to tables
belonging to db_name
are
logged; the default database has no effect on this.
Suppose that the server is started with
--binlog-do-db=sales
and
row-based logging is in effect, and then the following
statements are executed:
USE prices; UPDATE sales.february SET amount=amount+100;
The changes to the february
table in the
sales
database are logged in accordance
with the UPDATE
statement;
this occurs whether or not the
USE
statement was issued.
However, when using the row-based logging format and
--binlog-do-db=sales
, changes
made by the following UPDATE
are not logged:
USE prices; UPDATE prices.march SET amount=amount-25;
Even if the USE prices
statement were
changed to USE sales
, the
UPDATE
statement's
effects would still not be written to the binary log.
Another important difference in
--binlog-do-db
handling for
statement-based logging as opposed to the row-based logging
occurs with regard to statements that refer to multiple
databases. Suppose that the server is started with
--binlog-do-db=db1
, and the
following statements are executed:
USE db1; UPDATE db1.table1 SET col1 = 10, db2.table2 SET col2 = 20;
If you are using statement-based logging, the updates to
both tables are written to the binary log. However, when
using the row-based format, only the changes to
table1
are logged;
table2
is in a different database, so it
is not changed by the UPDATE
.
Now suppose that, instead of the USE db1
statement, a USE db4
statement had been
used:
USE db4; UPDATE db1.table1 SET col1 = 10, db2.table2 SET col2 = 20;
In this case, the UPDATE
statement is not written to the binary log when using
statement-based logging. However, when using row-based
logging, the change to table1
is logged,
but not that to table2
—in other
words, only changes to tables in the database named by
--binlog-do-db
are logged,
and the choice of default database has no effect on this
behavior.
Command-Line Format | --binlog-ignore-db=name | ||
Permitted Values | Type | string |
This option affects binary logging in a manner similar to
the way that
--replicate-ignore-db
affects
replication.
The effects of this option depend on whether the
statement-based or row-based logging format is in use, in
the same way that the effects of
--replicate-ignore-db
depend
on whether statement-based or row-based replication is in
use. You should keep in mind that the format used to log a
given statement may not necessarily be the same as that
indicated by the value of
binlog_format
. For example,
DDL statements such as CREATE
TABLE
and ALTER
TABLE
are always logged as statements, without
regard to the logging format in effect, so the following
statement-based rules for
--binlog-ignore-db
always apply in
determining whether or not the statement is logged.
Statement-based logging.
Tells the server to not log any statement where the
default database (that is, the one selected by
USE
) is
db_name
.
Prior to MySQL 5.7.2, this option caused any statements
containing fully qualified table names not to be logged if
there was no default database specified (that is, when
SELECT
DATABASE()
returned
NULL
). In MySQL 5.7.2 and later, when
there is no default database, no
--binlog-ignore-db
options are applied, and
such statements are always logged. (Bug #11829838, Bug
#60188)
Row-based format.
Tells the server not to log updates to any tables in the
database db_name
. The current
database has no effect.
When using statement-based logging, the following example
does not work as you might expect. Suppose that the server
is started with
--binlog-ignore-db=sales
and
you issue the following statements:
USE prices; UPDATE sales.january SET amount=amount+1000;
The UPDATE
statement
is logged in such a case because
--binlog-ignore-db
applies
only to the default database (determined by the
USE
statement). Because the
sales
database was specified explicitly
in the statement, the statement has not been filtered.
However, when using row-based logging, the
UPDATE
statement's
effects are not written to the binary
log, which means that no changes to the
sales.january
table are logged; in this
instance,
--binlog-ignore-db=sales
causes all changes made to tables in
the master's copy of the sales
database to be ignored for purposes of binary logging.
To specify more than one database to ignore, use this option multiple times, once for each database. Because database names can contain commas, the list will be treated as the name of a single database if you supply a comma-separated list.
You should not use this option if you are using cross-database updates and you do not want these updates to be logged.
Checksum options. MySQL 5.7 supports reading and writing of binary log checksums. These are enabled using the two options listed here:
--binlog-checksum={NONE|CRC32}
Command-Line Format | --binlog-checksum=type | ||
Permitted Values | Type | string | |
Default | CRC32 | ||
Valid Values | NONE | ||
CRC32 |
Enabling this option causes the master to write checksums
for events written to the binary log. Set to
NONE
to disable, or the name of the
algorithm to be used for generating checksums; currently,
only CRC32 checksums are supported, and CRC32 is the
default.
--master-verify-checksum={0|1}
Command-Line Format | --master-verify-checksum=name | ||
Permitted Values | Type | boolean | |
Default | OFF |
Enabling this option causes the master to verify events from the binary log using checksums, and to stop with an error in the event of a mismatch. Disabled by default.
To control reading of checksums by the slave (from the relay)
log, use the
--slave-sql-verify-checksum
option.
Testing and debugging options. The following binary log options are used in replication testing and debugging. They are not intended for use in normal operations.
Command-Line Format | --max-binlog-dump-events=# | ||
Permitted Values | Type | integer | |
Default | 0 |
This option is used internally by the MySQL test suite for replication testing and debugging.
Command-Line Format | --sporadic-binlog-dump-fail | ||
Permitted Values | Type | boolean | |
Default | FALSE |
This option is used internally by the MySQL test suite for replication testing and debugging.
--binlog-rows-query-log-events
Command-Line Format | --binlog-rows-query-log-events | ||
Permitted Values | Type | boolean | |
Default | FALSE |
This option enables
binlog_rows_query_log_events
.
The following list describes system variables for controlling
binary logging. They can be set at server startup and some of
them can be changed at runtime using
SET
.
Server options used to control binary logging are listed earlier
in this section. For information about the
sql_log_bin
and
sql_log_off
variables, see
Section 6.1.5, “Server System Variables”.
Command-Line Format | --binlog_cache_size=# | ||
System Variable | Name | binlog_cache_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 32768 | ||
Min Value | 4096 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 32768 | ||
Min Value | 4096 | ||
Max Value | 18446744073709551615 |
The size of the cache to hold changes to the binary log
during a transaction. A binary log cache is allocated for
each client if the server supports any transactional storage
engines and if the server has the binary log enabled
(--log-bin
option). If you
often use large transactions, you can increase this cache
size to get better performance. The
Binlog_cache_use
and
Binlog_cache_disk_use
status variables can be useful for tuning the size of this
variable. See Section 6.4.4, “The Binary Log”.
binlog_cache_size
sets the size for the
transaction cache only; the size of the statement cache is
governed by the
binlog_stmt_cache_size
system variable.
System Variable | Name | binlog_checksum | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | string | |
Default | CRC32 | ||
Valid Values | NONE | ||
CRC32 |
When enabled, this variable causes the master to write a
checksum for each event in the binary log.
binlog_checksum
supports the values
NONE
(disabled) and
CRC32
. The default is
CRC32
.
When binlog_checksum
is disabled (value
NONE
), the server verifies that it is
writing only complete events to the binary log by writing
and checking the event length (rather than a checksum) for
each event.
Changing the value of this variable causes the binary log to be rotated; checksums are always written to an entire binary log file, and never to only part of one.
Setting this variable on the master to a value unrecognized
by the slave causes the slave to set its own
binlog_checksum
value to
NONE
, and to stop replication with an
error. (Bug #13553750, Bug #61096) If backward compatibility
with older slaves is a concern, you may want to set the
value explicitly to NONE
.
binlog_direct_non_transactional_updates
Command-Line Format | --binlog_direct_non_transactional_updates[=value] | ||
System Variable | Name | binlog_direct_non_transactional_updates | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | OFF |
Due to concurrency issues, a slave can become inconsistent when a transaction contains updates to both transactional and nontransactional tables. MySQL tries to preserve causality among these statements by writing nontransactional statements to the transaction cache, which is flushed upon commit. However, problems arise when modifications done to nontransactional tables on behalf of a transaction become immediately visible to other connections because these changes may not be written immediately into the binary log.
The
binlog_direct_non_transactional_updates
variable offers one possible workaround to this issue. By
default, this variable is disabled. Enabling
binlog_direct_non_transactional_updates
causes updates to nontransactional tables to be written
directly to the binary log, rather than to the transaction
cache.
binlog_direct_non_transactional_updates
works only for statements that are replicated using the
statement-based binary logging format; that is,
it works only when the value of
binlog_format
is
STATEMENT
, or when
binlog_format
is
MIXED
and a given statement is being
replicated using the statement-based format. This variable
has no effect when the binary log format is
ROW
, or when
binlog_format
is set to
MIXED
and a given statement is replicated
using the row-based format.
Before enabling this variable, you must make certain that
there are no dependencies between transactional and
nontransactional tables; an example of such a dependency
would be the statement INSERT INTO myisam_table
SELECT * FROM innodb_table
. Otherwise, such
statements are likely to cause the slave to diverge from
the master.
In MySQL 5.7, this variable has no effect when
the binary log format is ROW
or
MIXED
. (Bug #51291)
Introduced | 5.7.6 | ||
Command-Line Format | --binlog_error_action[=value] | ||
System Variable | Name | binlog_error_action | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | enumeration | |
Default | IGNORE_ERROR | ||
Valid Values | IGNORE_ERROR | ||
ABORT_SERVER | |||
Permitted Values (>= 5.7.7) | Type | enumeration | |
Default | ABORT_SERVER | ||
Valid Values | IGNORE_ERROR | ||
ABORT_SERVER |
Controls what happens when the server encounters an error such as not being able to write to, flush or synchronize the binary log, which can cause the master's log to become inconsistent and replication slaves to lose synchronization.
In MySQL 5.7.7 and later, this variable defaults to
ABORT_SERVER
, which makes the server halt
logging and shut down whenever it encounters such an error
with the binary log. Upon server restart, all of the
previously prepared and binary logged transactions are
committed, while any transactions which were prepared but
not binary logged due to the error are aborted.
When binlog_error_action
is set to
IGNORE_ERROR
, if the server encounters
such an error it continues the ongoing transaction, logs the
error then halts logging, and continues performing updates.
To resume binary logging
log_bin
must be enabled
again. This provides backward compatibility with older
versions of MySQL.
In previous releases this variable was named
binlogging_impossible_mode
.
Command-Line Format | --binlog-format=format | ||
System Variable | Name | binlog_format | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values (<= 5.7.6) | Type | enumeration | |
Default | STATEMENT | ||
Valid Values | ROW | ||
STATEMENT | |||
MIXED | |||
Permitted Values (>= 5.7.7) | Type | enumeration | |
Default | ROW | ||
Valid Values | ROW | ||
STATEMENT | |||
MIXED |
This variable sets the binary logging format, and can be any
one of STATEMENT
, ROW
,
or MIXED
. See
Section 18.2.1, “Replication Formats”.
binlog_format
is set by the
--binlog-format
option at
startup, or by the
binlog_format
variable at
runtime.
While you can change the logging format at runtime, it is
not recommended that you change it
while replication is ongoing. This is due in part to the
fact that slaves do not honor the master's
binlog_format
setting; a
given MySQL Server can change only its own logging format.
Prior to MySQL 5.7.7, the default format was
STATEMENT
. In MySQL 5.7.7 and later the
default is ROW
.
Exception: In MySQL Cluster, the
default is MIXED
; statement-based
replication is not supported for MySQL Cluster.
You must have the SUPER
privilege to set either the global or session
binlog_format
value.
The rules governing when changes to this variable take effect and how long the effect lasts are the same as for other MySQL server system variables. For more information, see Section 14.7.4.1, “SET Syntax for Variable Assignment”.
When MIXED
is specified, statement-based
replication is used, except for cases where only row-based
replication is guaranteed to lead to proper results. For
example, this happens when statements contain user-defined
functions (UDF) or the UUID()
function. An exception to this rule is that
MIXED
always uses statement-based
replication for stored functions and triggers.
There are exceptions when you cannot switch the replication format at runtime:
From within a stored function or a trigger.
If the session is currently in row-based replication mode and has open temporary tables.
From within a transaction.
Trying to switch the format in those cases results in an error.
The binary log format affects the behavior of the following server options:
These effects are discussed in detail in the descriptions of the individual options.
binlog_group_commit_sync_delay
Introduced | 5.7.5 | ||
Command-Line Format | --binlog-group-commit-sync-delay=# | ||
System Variable | Name | binlog_group_commit_sync_delay | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 1000000 |
Controls how many microseconds the binary log commit waits
before synchronizing the binary log file to disk. By default
binlog-group-commit-sync-delay
is set to 0, meaning that there is no delay. Setting
binlog-group-commit-sync-delay
to a microsecond delay enables more transactions to be
synchronized together to disk at once, reducing the overall
time to commit a group of transactions because the larger
groups require fewer time units per group. With the correct
tuning, this can increase slave performance without
compromising the master's throughput.
binlog_group_commit_sync_no_delay_count
Introduced | 5.7.5 | ||
Command-Line Format | --binlog-group-commit-sync-no-delay-count=# | ||
System Variable | Name | binlog_group_commit_sync_no_delay_count | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 1000000 |
The maximum number of transactions to wait for before
aborting the current delay as specified by
binlog-group-commit-sync-delay
. If
binlog-group-commit-sync-delay
is set to
0, then this option has no effect.
Introduced | 5.7.5 | ||
Deprecated | 5.7.6 | ||
Command-Line Format | --binlogging_impossible_mode[=value] | ||
System Variable | Name | binlogging_impossible_mode | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | enumeration | |
Default | IGNORE_ERROR | ||
Valid Values | IGNORE_ERROR | ||
ABORT_SERVER |
This option is deprecated and will be removed in a future
MySQL release. Use the renamed
binlog_error_action
to
control what happens when the server cannot write to the
binary log.
Deprecated | 5.7.9 | ||
System Variable | Name | binlog_max_flush_queue_time | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 100000 |
Formerly, this controlled the time in microseconds to continue reading transactions from the flush queue before proceeding with group commit. In MySQL 5.7, this variable no longer has any effect.
binlog_max_flush_queue_time
is deprecated
as of MySQL 5.7.9, and is marked for eventual removal in a
future MySQL release.
System Variable | Name | binlog_order_commits | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | ON |
When this variable is enabled on a master (the default), transactions are externalized in the same order as they are written to the binary log. If disabled, transactions may be committed in parallel. In some cases, disabling this variable might produce a performance increment.
Command-Line Format | --binlog-row-image=image_type | ||
System Variable | Name | binlog_row_image=image_type | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | enumeration | |
Default | full | ||
Valid Values | full (Log all columns) | ||
minimal (Log only changed columns, and columns needed to identify rows) | |||
noblob (Log all columns, except for unneeded BLOB and TEXT columns) |
In MySQL row-based replication, each row change event contains two images, a “before” image whose columns are matched against when searching for the row to be updated, and an “after” image containing the changes. Normally, MySQL logs full rows (that is, all columns) for both the before and after images. However, it is not strictly necessary to include every column in both images, and we can often save disk, memory, and network usage by logging only those columns which are actually required.
When deleting a row, only the before image is logged, since there are no changed values to propagate following the deletion. When inserting a row, only the after image is logged, since there is no existing row to be matched. Only when updating a row are both the before and after images required, and both written to the binary log.
For the before image, it is necessary only that the minimum
set of columns required to uniquely identify rows is logged.
If the table containing the row has a primary key, then only
the primary key column or columns are written to the binary
log. Otherwise, if the table has a unique key all of whose
columns are NOT NULL
, then only the
columns in the unique key need be logged. (If the table has
neither a primary key nor a unique key without any
NULL
columns, then all columns must be
used in the before image, and logged.) In the after image,
it is necessary to log only the columns which have actually
changed.
You can cause the server to log full or minimal rows using
the binlog_row_image
system variable.
This variable actually takes one of three possible values,
as shown in the following list:
full
: Log all columns in both the
before image and the after image.
minimal
: Log only those columns in
the before image that are required to identify the row
to be changed; log only those columns in the after image
that are actually changed.
noblob
: Log all columns (same as
full
), except for
BLOB
and
TEXT
columns that are not
required to identify rows, or that have not changed.
This variable is not supported by MySQL Cluster; setting
it has no effect on the logging of
NDB
tables.
The default value is full
.
In MySQL 5.5 and earlier, full row images are always used for both before images and after images. If you need to replicate from a newer master to a slave running MySQL 5.5 or earlier, the master should always use this value.
When using minimal
or
noblob
, deletes and updates are
guaranteed to work correctly for a given table if and only
if the following conditions are true for both the source and
destination tables:
All columns must be present and in the same order; each column must use the same data type as its counterpart in the other table.
The tables must have identical primary key definitions.
(In other words, the tables must be identical with the possible exception of indexes that are not part of the tables' primary keys.)
If these conditions are not met, it is possible that the primary key column values in the destination table may prove insufficient to provide a unique match for a delete or update. In this event, no warning or error is issued; the master and slave silently diverge, thus breaking consistency.
Setting this variable has no effect when the binary logging
format is STATEMENT
. When
binlog_format
is
MIXED
, the setting for
binlog_row_image
is applied to changes
that are logged using row-based format, but this setting no
effect on changes logged as statements.
Setting binlog_row_image
on either the
global or session level does not cause an implicit commit;
this means that this variable can be changed while a
transaction is in progress without affecting the
transaction.
System Variable | Name | binlog_rows_query_log_events | |
Variable Scope | Global, Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | FALSE |
The
binlog_rows_query_log_events
system variable affects row-based logging only. When
enabled, it causes the MySQL Server to write informational
log events such as row query log events into its binary log.
This information can be used for debugging and related
purposes; such as obtaining the original query issued on the
master when it cannot be reconstructed from the row updates.
These events are normally ignored by MySQL programs reading
the binary log and so cause no issues when replicating or
restoring from backup. To view them, increase the verbosity
level by using mysqlbinlog's
--verbose
option twice,
either as "-vv" or "--verbose --verbose".
Command-Line Format | --binlog_stmt_cache_size=# | ||
System Variable | Name | binlog_stmt_cache_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 32768 | ||
Min Value | 4096 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 32768 | ||
Min Value | 4096 | ||
Max Value | 18446744073709551615 |
This variable determines the size of the cache for the
binary log to hold nontransactional statements issued during
a transaction. Separate binary log transaction and statement
caches are allocated for each client if the server supports
any transactional storage engines and if the server has the
binary log enabled (--log-bin
option). If you often use large nontransactional statements
during transactions, you can increase this cache size to get
better performance. The
Binlog_stmt_cache_use
and
Binlog_stmt_cache_disk_use
status variables can be useful for tuning the size of this
variable. See Section 6.4.4, “The Binary Log”.
The binlog_cache_size
system variable sets the size for the transaction cache.
System Variable | Name | log_bin | |
Variable Scope | Global | ||
Dynamic Variable | No |
Whether the binary log is enabled. If the
--log-bin
option is used,
then the value of this variable is ON
;
otherwise it is OFF
. This variable
reports only on the status of binary logging (enabled or
disabled); it does not actually report the value to which
--log-bin
is set.
System Variable | Name | log_bin_basename | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name | |
Default | datadir + '/' + hostname + '-bin' |
Holds the name and complete path to the binary log file.
Unlike the log_bin
system
variable, log_bin_basename
reflects the name set with the
--log-bin
server option.
System Variable | Name | log_bin_index | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | file name |
The index file for binary log file names.
Command-Line Format | --log-bin-use-v1-row-events[={0|1}] | ||
System Variable | Name | log_bin_use_v1_row_events | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | 0 |
Shows whether Version 2 binary logging is in use. A value of 1 shows that the server is writing the binary log using Version 1 logging events (the only version of binary log events used in previous releases), and thus producing a binary log that can be read by older slaves. 0 indicates that Version 2 binary log events are in use.
This variable is read-only. To switch between Version 1 and
Version 2 binary event binary logging, it is necessary to
restart mysqld with the
--log-bin-use-v1-row-events
option.
Other than when performing upgrades of MySQL Cluster
Replication, --log-bin-use-v1-events
is
chiefly of interest when setting up replication conflict
detection and resolution using
NDB$EPOCH_TRANS()
, which requires Version
2 binary row event logging. Thus, this option and
--ndb-log-transaction-id
are
not compatible.
MySQL NDB Cluster 7.5 uses Version 2 binary log row events by default. You should keep this mind when planning upgrades or downgrades, and for setups using MySQL Cluster Replication.
For more information, see Section 21.6.11, “NDB Cluster Replication Conflict Resolution”.
Command-Line Format | --log-slave-updates | ||
System Variable | Name | log_slave_updates | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | FALSE |
Whether updates received by a slave server from a master server should be logged to the slave's own binary log. Binary logging must be enabled on the slave for this variable to have any effect. See Section 18.1.6, “Replication and Binary Logging Options and Variables”.
log_statements_unsafe_for_binlog
Introduced | 5.7.11 | ||
System Variable | Name | log_statements_unsafe_for_binlog | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | ON |
If error 1592 is encountered, controls whether the generated warnings are added to the error log or not.
System Variable | Name | master_verify_checksum | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | boolean | |
Default | OFF |
Enabling this variable causes the master to examine
checksums when reading from the binary log.
master_verify_checksum
is disabled by
default; in this case, the master uses the event length from
the binary log to verify events, so that only complete
events are read from the binary log.
Command-Line Format | --max_binlog_cache_size=# | ||
System Variable | Name | max_binlog_cache_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 18446744073709551615 | ||
Min Value | 4096 | ||
Max Value | 18446744073709551615 |
If a transaction requires more than this many bytes of memory, the server generates a Multi-statement transaction required more than 'max_binlog_cache_size' bytes of storage error. The minimum value is 4096. The maximum possible value is 16EB (exabytes). The maximum recommended value is 4GB; this is due to the fact that MySQL currently cannot work with binary log positions greater than 4GB.
max_binlog_cache_size
sets the size for
the transaction cache only; the upper limit for the
statement cache is governed by the
max_binlog_stmt_cache_size
system variable.
In MySQL 5.7, the visibility to sessions of
max_binlog_cache_size
matches that of the
binlog_cache_size
system
variable; in other words, changing its value effects only
new sessions that are started after the value is changed.
Command-Line Format | --max_binlog_size=# | ||
System Variable | Name | max_binlog_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1073741824 | ||
Min Value | 4096 | ||
Max Value | 1073741824 |
If a write to the binary log causes the current log file size to exceed the value of this variable, the server rotates the binary logs (closes the current file and opens the next one). The minimum value is 4096 bytes. The maximum and default value is 1GB.
A transaction is written in one chunk to the binary log, so
it is never split between several binary logs. Therefore, if
you have big transactions, you might see binary log files
larger than
max_binlog_size
.
If max_relay_log_size
is 0,
the value of
max_binlog_size
applies to
relay logs as well.
Command-Line Format | --max_binlog_stmt_cache_size=# | ||
System Variable | Name | max_binlog_stmt_cache_size | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 18446744073709547520 | ||
Min Value | 4096 | ||
Max Value | 18446744073709547520 |
If nontransactional statements within a transaction require more than this many bytes of memory, the server generates an error. The minimum value is 4096. The maximum and default values are 4GB on 32-bit platforms and 16EB (exabytes) on 64-bit platforms.
max_binlog_stmt_cache_size
sets the size
for the statement cache only; the upper limit for the
transaction cache is governed exclusively by the
max_binlog_cache_size
system variable.
Command-Line Format | --sync-binlog=# | ||
System Variable | Name | sync_binlog | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (>= 5.7.7) | Type | integer | |
Default | 1 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (32-bit platforms) | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 4294967295 | ||
Permitted Values (64-bit platforms) | Type | integer | |
Default | 0 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
Controls the number of binary log commit groups to collect
before synchronizing the binary log to disk. When
sync_binlog=0
, the binary
log is never synchronized to disk, and when
sync_binlog
is set to a
value greater than 0 this number of binary log commit groups
is periodically synchronized to disk. When
sync_binlog=1
, all
transactions are synchronized to the binary log before they
are committed. Therefore, even in the event of an unexpected
restart, any transactions that are missing from the binary
log are only in prepared state. This causes the
server's automatic recovery routine to roll back those
transactions. This guarantees that no transaction is lost
from the binary log, and is the safest option. However this
can have a negative impact on performance because of an
increased number of disk writes. Using a higher value
improves performance, but with the increased risk of data
loss.
When sync_binlog=0
or
sync_binlog
is greater than
1, transactions are committed without having been
synchronized to disk. Therefore, in the event of a power
failure or operating system crash, it is possible that the
server has committed some transactions that have not been
synchronized to the binary log. Therefore it is impossible
for the recovery routine to recover these transactions and
they will be lost from the binary log.
Prior to MySQL 5.7.7, the default value of
sync_binlog
was 0, which
configures no synchronizing to disk—in this case, the
server relies on the operating system to flush the binary
log's contents from time to time as for any other file.
MySQL 5.7.7 and later use a default value of 1, which is the
safest choice, but as noted above can impact performance.
Startup Options Used with GTID Replication
System Variables Used with GTID Replication
The MySQL Server options and system variables described in this section are used to monitor and control Global Transaction Identifiers (GTIDs).
For additional information, see Section 18.1.3, “Replication with Global Transaction Identifiers”.
The following server startup options are used with GTID-based replication:
Command-Line Format | --enforce-gtid-consistency[=value] | ||
System Variable (<= 5.7.5) | Name | enforce_gtid_consistency | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
System Variable (>= 5.7.6) | Name | enforce_gtid_consistency | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (<= 5.7.5) | Type | boolean | |
Default | false | ||
Permitted Values (>= 5.7.6) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
ON | |||
WARN |
When enabled, the server enforces GTID consistency by
allowing execution of only statements that can be safely
logged using a GTID. You must set this
option to ON
before enabling GTID based
replication.
The values that
--enforce-gtid-consistency
can be configured to are:
OFF
: all transactions are allowed to
violate GTID consistency.
ON
: no transaction is allowed to
violate GTID consistency.
WARN
: all transactions are allowed to
violate GTID consistency, but a warning is generated in
this case. Added in MySQL 5.7.6.
Setting
--enforce-gtid-consistency
without a value is an alias for
--enforce-gtid-consistency=ON
.
This impacts on the behavior of the variable, see
enforce_gtid_consistency
.
Only statements that can be logged using GTID safe
statements can be logged when
enforce-gtid-consistency
is
set to ON
, so the operations listed here
cannot be used with this option:
CREATE
TABLE ... SELECT
statements
CREATE
TEMPORARY TABLE
or
DROP
TEMPORARY TABLE
statements inside transactions
Transactions or statements that update both transactional and nontransactional tables. There is an exception that nontransactional DML is allowed in the same transaction or in the same statement as transactional DML, if all nontransactional tables are temporary.
For more information, see Section 18.1.3.4, “Restrictions on Replication with GTIDs”.
--executed-gtids-compression-period
Introduced | 5.7.5 | ||
Deprecated | 5.7.6 | ||
Command-Line Format | --executed-gtids-compression-period=# | ||
Permitted Values | Type | integer | |
Default | 1000 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
This option is deprecated and will be removed in a future MySQL release. Use the renamed gtid_executed_compression_period to control how the gtid_executed table is compressed.
Command-Line Format | --gtid-mode=MODE | ||
System Variable (<= 5.7.5) | Name | gtid_mode | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
System Variable (>= 5.7.6) | Name | gtid_mode | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (<= 5.7.5) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
UPGRADE_STEP_1 | |||
UPGRADE_STEP_2 | |||
ON | |||
Permitted Values (>= 5.7.6) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
OFF_PERMISSIVE | |||
ON_PERMISSIVE | |||
ON |
This option specifies whether global transaction identifiers
(GTIDs) are used to identify transactions. Setting this
option to --gtid-mode=ON
requires that
enforce-gtid-consistency
be
set to ON
. Prior to MySQL 5.7.6 the
gtid_mode
variable which
this option controls could only be set at server startup. In
MySQL 5.7.6 and later the
gtid_mode
variable is
dynamic and enables GTID based replication to be configured
online. Before using this feature, see
Section 18.1.5, “Changing Replication Modes on Online Servers”.
Prior to MySQL 5.7.5, starting the server with
--gtid-mode=ON
required that
the server also be started with the
--log-bin
,
--log-slave-updates
, options.
In versions of MySQL 5.7.5 and later this is not a
requirement. See
mysql.gtid_executed Table.
--gtid-executed-compression-period
Introduced | 5.7.6 | ||
Command-Line Format | --gtid-executed-compression-period=# | ||
Permitted Values | Type | integer | |
Default | 1000 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
Compress the mysql.gtid_executed
table
each time this many transactions have taken place. A setting
of 0 means that this table is not compressed. No compression
of the table occurs when binary logging is enabled,
therefore the option has no effect unless
log_bin
is
OFF
.
See mysql.gtid_executed Table Compression, for more information.
In MySQL version 5.7.5, this variable was added as
executed_gtids_compression_period
and in MySQL version 5.7.6 it was renamed to
gtid_executed_compression_period
.
The following system variables are used with GTID-based replication:
Introduced | 5.7.6 | ||
Command-Line Format | --binlog-gtid-simple-recovery | ||
System Variable | Name | binlog_gtid_simple_recovery | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | FALSE | ||
Permitted Values (>= 5.7.7) | Type | boolean | |
Default | TRUE |
This variable controls how binary log files are iterated
during the search for GTIDs when MySQL starts or restarts.
In MySQL version 5.7.5, this variable was added as
simplified_binlog_gtid_recovery
and in
MySQL version 5.7.6 it was renamed to
binlog_gtid_simple_recovery
.
When
binlog_gtid_simple_recovery=FALSE
,
the method of iterating the binary log files is:
To initialize
gtid_executed
, binary
log files are iterated from the newest file, stopping at
the first binary log that has any
Previous_gtids_log_event
. All GTIDs
from Previous_gtids_log_event
and
Gtid_log_events
are read from this
binary log file. This GTID set is stored internally and
called gtids_in_binlog
. The value of
gtid_executed
is
computed as the union of this set and the GTIDs stored
in the mysql.gtid_executed
table.
This process could take a long time if you had a large
number of binary log files without GTID events, for
example created when
gtid_mode=OFF
.
To initialize
gtid_purged
, binary log
files are iterated from the oldest to the newest,
stopping at the first binary log that contains either a
Previous_gtids_log_event
that is
non-empty (that has at least one GTID) or that has at
least one Gtid_log_event
. From this
binary log it reads
Previous_gtids_log_event
. This GTID
set is subtracted from
gtids_in_binlog
and the result stored
in the internal variable
gtids_in_binlog_not_purged
. The value
of gtid_purged
is
initialized to the value of
gtid_executed
, minus
gtids_in_binlog_not_purged
.
When
binlog_gtid_simple_recovery=TRUE
,
which is the default in MySQL 5.7.7 and later, the server
iterates only the oldest and the newest binary log files and
the values of gtid_purged
and gtid_executed
are
computed based only on
Previous_gtids_log_event
or
Gtid_log_event
found in these files. This
ensures only two binary log files are iterated during server
restart or when binary logs are being purged.
If this option is enabled,
gtid_executed
and
gtid_purged
may be
initialized incorrectly in the following situations:
The newest binary log was generated by MySQL 5.7.5 or
older, and gtid_mode
was ON
for some binary logs but
OFF
for the newest binary log.
A SET GTID_PURGED
statement was
issued on a MySQL version prior to 5.7.7, and the
binary log that was active at the time of the
SET GTID_PURGED
has not yet been
purged.
If an incorrect GTID set is computed in either situation, it will remain incorrect even if the server is later restarted, regardless of the value of this option.
Command-Line Format | --enforce-gtid-consistency[=value] | ||
System Variable (<= 5.7.5) | Name | enforce_gtid_consistency | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
System Variable (>= 5.7.6) | Name | enforce_gtid_consistency | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (<= 5.7.5) | Type | boolean | |
Default | false | ||
Permitted Values (>= 5.7.6) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
ON | |||
WARN |
Depending on the value of this variable, the server enforces
GTID consistency by allowing execution of only statements
that can be safely logged using a GTID. You
must set this variable to
ON
before enabling GTID based
replication.
The values that
enforce_gtid_consistency
can be configured to are:
OFF
: all transactions are allowed to
violate GTID consistency.
ON
: no transaction is allowed to
violate GTID consistency.
WARN
: all transactions are allowed to
violate GTID consistency, but a warning is generated in
this case. Added in MySQL 5.7.6.
For more information on statements that can be logged using
GTID based replication, see
--enforce-gtid-consistency
.
Prior to MySQL 5.7.6, the boolean
enforce-gtid-consistency
defaulted to OFF
. To maintain
compatibility with previous versions, in MySQL 5.7.6 the
enumeration defaults to OFF
, and setting
--enforce-gtid-consistency
without a value is interpreted as setting the value to
ON
. The variable also has multiple
textual aliases for the values:
0=OFF=FALSE
,
1=ON=TRUE
,2=WARN
. This
differs from other enumeration types but maintains
compatibility with the boolean type used in previous
versions. These changes impact on what is returned by the
variable. Using SELECT
@@ENFORCE_GTID_CONSISTENCY
, SHOW
VARIABLES LIKE 'ENFORCE_GTID_CONSISTENCY'
, and
SELECT * FROM INFORMATION_SCHEMA.VARIABLES WHERE
'VARIABLE_NAME' = 'ENFORCE_GTID_CONSISTENCY'
, all
return the textual form, not the numeric form. This is an
incompatible change, since
@@ENFORCE_GTID_CONSISTENCY
returns the
numeric form for booleans but returns the textual form for
SHOW
and the Information Schema.
executed_gtids_compression_period
Introduced | 5.7.5 | ||
Deprecated | 5.7.6 | ||
System Variable (>= 5.7.5) | Name | executed_gtids_compression_period | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1000 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
This option is deprecated and will be removed in a future
MySQL release. Use the renamed
gtid_executed_compression_period
to control how the gtid_executed
table is
compressed.
System Variable | Name | gtid_executed | |
Variable Scope | Global, Session | ||
Dynamic Variable | No | ||
System Variable (>= 5.7.7) | Name | gtid_executed | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
When used with global scope, this variable contains a
representation of the set of all transactions executed on
the server and GTIDs that have been set by a
SET
gtid_purged
statement. This
is the same as the value of the
Executed_Gtid_Set
column in the output of
SHOW MASTER STATUS
and
SHOW SLAVE STATUS
. The value
of this variable is a GTID set, see
GTID Sets for
more information.
When the server starts,
@@global.gtid_executed
is initialized.
See
binlog_gtid_simple_recovery
for more information on how binary logs are iterated to
populate gtid_executed
.
GTIDs are then added to the set as transactions are
executed, or if any
SET
gtid_purged
statement is
executed.
The set of transactions that can be found in the binary logs
at any given time is equal to
GTID_SUBTRACT(@@global.gtid_executed,
@@global.gtid_purged)
; that is, to all
transactions in the binary log that have not yet been
purged.
Issuing RESET MASTER
causes
the global value (but not the session value) of this
variable to be reset to an empty string. GTIDs are not
otherwise removed from this set other than when the set is
cleared due to RESET MASTER
.
Prior to MySQL 5.7.7, this variable could also be used with session scope, where it contained a representation of the set of transactions that are written to the cache in the current session. The session scope was deprecated in MySQL 5.7.7.
gtid_executed_compression_period
Introduced | 5.7.6 | ||
System Variable (>= 5.7.6) | Name | gtid_executed_compression_period | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | integer | |
Default | 1000 | ||
Min Value | 0 | ||
Max Value | 4294967295 |
Compress the mysql.gtid_executed
table
each time this many transactions have been processed. A
setting of 0 means that this table is not compressed. Since
no compression of the table occurs when using the binary
log, setting the value of the variable has no effect unless
binary logging is disabled.
See mysql.gtid_executed Table Compression, for more information.
In MySQL version 5.7.5, this variable was added as
executed_gtids_compression_period
and in
MySQL version 5.7.6 it was renamed to
gtid_executed_compression_period
.
System Variable (<= 5.7.5) | Name | gtid_mode | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
System Variable (>= 5.7.6) | Name | gtid_mode | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values (<= 5.7.5) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
UPGRADE_STEP_1 | |||
UPGRADE_STEP_2 | |||
ON | |||
Permitted Values (>= 5.7.6) | Type | enumeration | |
Default | OFF | ||
Valid Values | OFF | ||
OFF_PERMISSIVE | |||
ON_PERMISSIVE | |||
ON |
Controls whether GTID based logging is enabled and what type
of transactions the logs can contain. Prior to MySQL 5.7.6
this variable was read-only and was set using the
--gtid-mode
option only.
MySQL 5.7.6 enables this variable to be set dynamically. You
must have the SUPER
privilege
to set this variable.
enforce_gtid_consistency
must be true before you can set
gtid_mode=ON
. Before
modifying this variable, see
Section 18.1.5, “Changing Replication Modes on Online Servers”.
Transactions logged in MySQL 5.7.6 and later can be either
anonymous or use GTIDs. Anonymous transactions rely on
binary log file and position to identify specific
transactions. GTID transactions have a unique identifier
that is used to refer to transactions. The
OFF_PERMISSIVE
and
ON_PERMISSIVE
modes added in MySQL 5.7.6
permit a mix of these transaction types in the topology. The
different modes are now:
OFF
: Both new and replicated
transactions must be anonymous.
OFF_PERMISSIVE
: New transactions are
anonymous. Replicated transactions can be either
anonymous or GTID transactions.
ON_PERMISSIVE
: New transactions are
GTID transactions. Replicated transactions can be either
anonymous or GTID transactions.
ON
: Both new and replicated
transactions must be GTID transactions.
Changes from one value to another can only be one step at a
time. For example, if
gtid_mode
is currently set
to OFF_PERMISSIVE
, it is possible to
change to OFF
or
ON_PERMISSIVE
but not to
ON
.
In MySQL 5.7.6 and later, the values of
gtid_purged
and
gtid_executed
are
persistent regardless of the value of
gtid_mode
. Therefore even
after changing the value of
gtid_mode
, these variables
contain the correct values. In MySQL 5.7.5 and earlier, the
values of gtid_purged
and
gtid_executed
are not
persistent while
gtid_mode=OFF
. Therefore,
after changing gtid_mode
to
OFF
, once all binary logs containing
GTIDs are purged, the values of these variables are lost.
System Variable | Name | gtid_next | |
Variable Scope | Session | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | enumeration | |
Default | AUTOMATIC | ||
Valid Values | AUTOMATIC | ||
ANONYMOUS | |||
UUID:NUMBER |
This variable is used to specify whether and how the next
GTID is obtained. gtid_next
can take any
of the following values:
AUTOMATIC
: Use the next
automatically-generated global transaction ID.
ANONYMOUS
: Transactions do not have
global identifiers, and are identified by file and
position only.
A global transaction ID in
UUID
:NUMBER
format.
Exactly which of the above options are valid depends on the
setting of gtid_mode
, see
Section 18.1.5.1, “Replication Mode Concepts”
for more information. Setting this variable has no effect if
gtid_mode
is
OFF
.
After this variable has been set to
UUID
:NUMBER
,
and a transaction has been committed or rolled back, an
explicit SET GTID_NEXT
statement must
again be issued before any other statement.
In MySQL 5.7.5 and later, DROP TABLE
or
DROP TEMPORARY TABLE
fails with an
explicit error when used on a combination of nontemporary
tables with temporary tables, or of temporary tables using
transactional storage engines with temporary tables using
nontransactional storage engines. Prior to MySQL 5.7.5, when
GTIDs were enabled but gtid_next
was not
AUTOMATIC
, DROP
TABLE
did not work correctly when used with either
of these combinations of tables. (Bug #17620053)
In MySQL 5.7.1, you cannot execute any of the statements
CHANGE MASTER TO
,
START SLAVE
,
STOP SLAVE
,
REPAIR TABLE
,
OPTIMIZE TABLE
,
ANALYZE TABLE
,
CHECK TABLE
,
CREATE SERVER
,
ALTER SERVER
,
DROP SERVER
,
CACHE INDEX
,
LOAD INDEX INTO
CACHE
, FLUSH
, or
RESET
when
gtid_next
is set to any
value other than AUTOMATIC
; in such
cases, the statement fails with an error. Such statements
are not disallowed in MySQL 5.7.2 and
later. (Bug #16062608, Bug #16715809, Bug #69045) (Bug
#16062608)
System Variable | Name | gtid_owned | |
Variable Scope | Global, Session | ||
Dynamic Variable | No | ||
Permitted Values | Type | string |
This read-only variable holds a list whose contents depend on its scope. When used with session scope, the list holds all GTIDs that are owned by this client; when used with global scope, it holds a list of all GTIDs along with their owners.
System Variable | Name | gtid_purged | |
Variable Scope | Global | ||
Dynamic Variable | Yes | ||
Permitted Values | Type | string |
The set of all transactions that have been purged from the
binary log. This is a subset of the set of transactions in
gtid_executed
. The value of
this variable is a GTID set, see
GTID Sets for
more information.
When the server starts, the global value of
gtid_purged
is initialized
to a set of GTIDs. See
binlog_gtid_simple_recovery
for more information on how binary logs are iterated to
populate gtid_purged
.
Issuing RESET MASTER
causes
the value of this variable to be reset to an empty string.
It is possible to update the value of this variable, but
only when gtid_executed
is
the empty string, and therefore
gtid_purged
is the empty
string. This can occur either when replication has not been
started previously, or when replication was not previously
using GTIDs. Prior to MySQL 5.7.6, this variable was
settable only when
gtid_mode=ON
. In MySQL
5.7.6 and later, this variable is settable regardless of the
value of gtid_mode
.
If all existing binary logs were generated using MySQL 5.7.6
or later, after issuing a SET gtid_purged
statement,
binlog_gtid_simple_recovery=TRUE
(the default setting in MySQL 5.7.7 and later) can safely be
used. If binary logs from MySQL 5.7.7 or earlier exist,
there is a chance that
gtid_purged
may be computed
incorrectly. See
binlog_gtid_simple_recovery
for more information. If you are using MySQL 5.7.7 or
earlier, after issuing a SET gtid_purged
statement note down the current binary log file name, which
can be checked using SHOW MASTER
STATUS
. If the server is restarted before this
file has been purged, then you should use
binlog_gtid_simple_recovery=FALSE
to avoid gtid_purged
or
gtid_executed
being
computed incorrectly.
simplified_binlog_gtid_recovery
Introduced | 5.7.5 | ||
Deprecated | 5.7.6 | ||
Command-Line Format | --simplified-binlog-gtid-recovery | ||
System Variable | Name | simplified_binlog_gtid_recovery | |
Variable Scope | Global | ||
Dynamic Variable | No | ||
Permitted Values | Type | boolean | |
Default | FALSE |
This option is deprecated and will be removed in a future
MySQL release. Use the renamed
binlog_gtid_simple_recovery
to control how MySQL iterates through binary log files after
a crash.
Once replication has been started it executes without requiring much regular administration. This section describes how to check the status of replication and how to pause a slave.
The most common task when managing a replication process is to
ensure that replication is taking place and that there have been
no errors between the slave and the master. The primary
statement for this is SHOW SLAVE
STATUS
, which you must execute on each slave:
mysql> SHOW SLAVE STATUS\G
*************************** 1. row ***************************
Slave_IO_State: Waiting for master to send event
Master_Host: master1
Master_User: root
Master_Port: 3306
Connect_Retry: 60
Master_Log_File: mysql-bin.000004
Read_Master_Log_Pos: 931
Relay_Log_File: slave1-relay-bin.000056
Relay_Log_Pos: 950
Relay_Master_Log_File: mysql-bin.000004
Slave_IO_Running: Yes
Slave_SQL_Running: Yes
Replicate_Do_DB:
Replicate_Ignore_DB:
Replicate_Do_Table:
Replicate_Ignore_Table:
Replicate_Wild_Do_Table:
Replicate_Wild_Ignore_Table:
Last_Errno: 0
Last_Error:
Skip_Counter: 0
Exec_Master_Log_Pos: 931
Relay_Log_Space: 1365
Until_Condition: None
Until_Log_File:
Until_Log_Pos: 0
Master_SSL_Allowed: No
Master_SSL_CA_File:
Master_SSL_CA_Path:
Master_SSL_Cert:
Master_SSL_Cipher:
Master_SSL_Key:
Seconds_Behind_Master: 0
Master_SSL_Verify_Server_Cert: No
Last_IO_Errno: 0
Last_IO_Error:
Last_SQL_Errno: 0
Last_SQL_Error:
Replicate_Ignore_Server_Ids: 0
The key fields from the status report to examine are:
Slave_IO_State
: The current status of the
slave. See Section 9.14.5, “Replication Slave I/O Thread States”, and
Section 9.14.6, “Replication Slave SQL Thread States”, for more
information.
Slave_IO_Running
: Whether the I/O thread
for reading the master's binary log is running. Normally,
you want this to be Yes
unless you have
not yet started replication or have explicitly stopped it
with STOP SLAVE
.
Slave_SQL_Running
: Whether the SQL thread
for executing events in the relay log is running. As with
the I/O thread, this should normally be
Yes
.
Last_IO_Error
,
Last_SQL_Error
: The last errors
registered by the I/O and SQL threads when processing the
relay log. Ideally these should be blank, indicating no
errors.
Seconds_Behind_Master
: The number of
seconds that the slave SQL thread is behind processing the
master binary log. A high number (or an increasing one) can
indicate that the slave is unable to handle events from the
master in a timely fashion.
A value of 0 for Seconds_Behind_Master
can usually be interpreted as meaning that the slave has
caught up with the master, but there are some cases where
this is not strictly true. For example, this can occur if
the network connection between master and slave is broken
but the slave I/O thread has not yet noticed this—that
is, slave_net_timeout
has
not yet elapsed.
It is also possible that transient values for
Seconds_Behind_Master
may not reflect the
situation accurately. When the slave SQL thread has caught
up on I/O, Seconds_Behind_Master
displays
0; but when the slave I/O thread is still queuing up a new
event, Seconds_Behind_Master
may show a
large value until the SQL thread finishes executing the new
event. This is especially likely when the events have old
timestamps; in such cases, if you execute
SHOW SLAVE STATUS
several
times in a relatively short period, you may see this value
change back and forth repeatedly between 0 and a relatively
large value.
Several pairs of fields provide information about the progress of the slave in reading events from the master binary log and processing them in the relay log:
(Master_Log_file
,
Read_Master_Log_Pos
): Coordinates in the
master binary log indicating how far the slave I/O thread
has read events from that log.
(Relay_Master_Log_File
,
Exec_Master_Log_Pos
): Coordinates in the
master binary log indicating how far the slave SQL thread
has executed events received from that log.
(Relay_Log_File
,
Relay_Log_Pos
): Coordinates in the slave
relay log indicating how far the slave SQL thread has
executed the relay log. These correspond to the preceding
coordinates, but are expressed in slave relay log
coordinates rather than master binary log coordinates.
On the master, you can check the status of connected slaves
using SHOW PROCESSLIST
to examine
the list of running processes. Slave connections have
Binlog Dump
in the Command
field:
mysql> SHOW PROCESSLIST \G;
*************************** 4. row ***************************
Id: 10
User: root
Host: slave1:58371
db: NULL
Command: Binlog Dump
Time: 777
State: Has sent all binlog to slave; waiting for binlog to be updated
Info: NULL
Because it is the slave that drives the replication process, very little information is available in this report.
For slaves that were started with the
--report-host
option and are
connected to the master, the SHOW SLAVE
HOSTS
statement on the master shows basic information
about the slaves. The output includes the ID of the slave
server, the value of the
--report-host
option, the
connecting port, and master ID:
mysql> SHOW SLAVE HOSTS;
+-----------+--------+------+-------------------+-----------+
| Server_id | Host | Port | Rpl_recovery_rank | Master_id |
+-----------+--------+------+-------------------+-----------+
| 10 | slave1 | 3306 | 0 | 1 |
+-----------+--------+------+-------------------+-----------+
1 row in set (0.00 sec)
You can stop and start replication on the slave using the
STOP SLAVE
and
START SLAVE
statements.
To stop processing of the binary log from the master, use
STOP SLAVE
:
mysql> STOP SLAVE;
When replication is stopped, the slave I/O thread stops reading events from the master binary log and writing them to the relay log, and the SQL thread stops reading events from the relay log and executing them. You can pause the I/O or SQL thread individually by specifying the thread type:
mysql>STOP SLAVE IO_THREAD;
mysql>STOP SLAVE SQL_THREAD;
To start execution again, use the START
SLAVE
statement:
mysql> START SLAVE;
To start a particular thread, specify the thread type:
mysql>START SLAVE IO_THREAD;
mysql>START SLAVE SQL_THREAD;
For a slave that performs updates only by processing events from the master, stopping only the SQL thread can be useful if you want to perform a backup or other task. The I/O thread will continue to read events from the master but they are not executed. This makes it easier for the slave to catch up when you restart the SQL thread.
Stopping only the I/O thread enables the events in the relay log to be executed by the SQL thread up to the point where the relay log ends. This can be useful when you want to pause execution to catch up with events already received from the master, when you want to perform administration on the slave but also ensure that it has processed all updates to a specific point. This method can also be used to pause event receipt on the slave while you conduct administration on the master. Stopping the I/O thread but permitting the SQL thread to run helps ensure that there is not a massive backlog of events to be executed when replication is started again.
Replication is based on the master server keeping track of all
changes to its databases (updates, deletes, and so on) in its binary
log. The binary log serves as a written record of all events that
modify database structure or content (data) from the moment the
server was started. Typically, SELECT
statements are not recorded because they modify neither database
structure nor content.
Each slave that connects to the master requests a copy of the binary log. That is, it pulls the data from the master, rather than the master pushing the data to the slave. The slave also executes the events from the binary log that it receives. This has the effect of repeating the original changes just as they were made on the master. Tables are created or their structure modified, and data is inserted, deleted, and updated according to the changes that were originally made on the master.
Because each slave is independent, the replaying of the changes from the master's binary log occurs independently on each slave that is connected to the master. In addition, because each slave receives a copy of the binary log only by requesting it from the master, the slave is able to read and update the copy of the database at its own pace and can start and stop the replication process at will without affecting the ability to update to the latest database status on either the master or slave side.
For more information on the specifics of the replication implementation, see Section 18.2.2, “Replication Implementation Details”.
Masters and slaves report their status in respect of the replication process regularly so that you can monitor them. See Section 9.14, “Examining Thread Information”, for descriptions of all replicated-related states.
The master binary log is written to a local relay log on the slave before it is processed. The slave also records information about the current position with the master's binary log and the local relay log. See Section 18.2.4, “Replication Relay and Status Logs”.
Database changes are filtered on the slave according to a set of rules that are applied according to the various configuration options and variables that control event evaluation. For details on how these rules are applied, see Section 18.2.5, “How Servers Evaluate Replication Filtering Rules”.
Replication works because events written to the binary log are read from the master and then processed on the slave. The events are recorded within the binary log in different formats according to the type of event. The different replication formats used correspond to the binary logging format used when the events were recorded in the master's binary log. The correlation between binary logging formats and the terms used during replication are:
When using statement-based binary logging, the master writes SQL statements to the binary log. Replication of the master to the slave works by executing the SQL statements on the slave. This is called statement-based replication (often abbreviated as SBR), which corresponds to the standard MySQL statement-based binary logging format. Replication capabilities in MySQL version 5.1.4 and earlier used this format exclusively.
When using row-based logging, the master writes events to the binary log that indicate how individual table rows are changed. Replication of the master to the slave works by copying the events representing the changes to the table rows to the slave. This is called row-based replication (often abbreviated as RBR).
You can also configure MySQL to use a mix of both statement-based and row-based logging, depending on which is most appropriate for the change to be logged. This is called mixed-format logging. When using mixed-format logging, a statement-based log is used by default. Depending on certain statements, and also the storage engine being used, the log is automatically switched to row-based in particular cases. Replication using the mixed format is often referred to as mixed-based replication or mixed-format replication. For more information, see Section 6.4.4.3, “Mixed Binary Logging Format”.
Prior to MySQL 5.7.7, statement-based format was the default. In MySQL 5.7.7 and later, row-based format is the default.
NDB Cluster.
The default binary logging format in MySQL NDB Cluster 7.5 is
MIXED
. You should note that MySQL Cluster
Replication always uses row-based replication, and that the
NDB
storage engine is incompatible
with statement-based replication. See
Section 21.6.2, “General Requirements for NDB Cluster Replication”, for more
information.
When using MIXED
format, the binary logging
format is determined in part by the storage engine being used and
the statement being executed. For more information on mixed-format
logging and the rules governing the support of different logging
formats, see Section 6.4.4.3, “Mixed Binary Logging Format”.
The logging format in a running MySQL server is controlled by
setting the binlog_format
server
system variable. This variable can be set with session or global
scope. The rules governing when and how the new setting takes
effect are the same as for other MySQL server system
variables—setting the variable for the current session lasts
only until the end of that session, and the change is not visible
to other sessions; setting the variable globally requires a
restart of the server to take effect. For more information, see
Section 14.7.4.1, “SET Syntax for Variable Assignment”.
There are conditions under which you cannot change the binary logging format at runtime or doing so causes replication to fail. See Section 6.4.4.2, “Setting The Binary Log Format”.
You must have the SUPER
privilege
to set either the global or session
binlog_format
value.
The statement-based and row-based replication formats have different issues and limitations. For a comparison of their relative advantages and disadvantages, see Section 18.2.1.1, “Advantages and Disadvantages of Statement-Based and Row-Based Replication”.
With statement-based replication, you may encounter issues with replicating stored routines or triggers. You can avoid these issues by using row-based replication instead. For more information, see Section 23.7, “Binary Logging of Stored Programs”.
Each binary logging format has advantages and disadvantages. For most users, the mixed replication format should provide the best combination of data integrity and performance. If, however, you want to take advantage of the features specific to the statement-based or row-based replication format when performing certain tasks, you can use the information in this section, which provides a summary of their relative advantages and disadvantages, to determine which is best for your needs.
Proven technology.
Less data written to log files. When updates or deletes affect many rows, this results in much less storage space required for log files. This also means that taking and restoring from backups can be accomplished more quickly.
Log files contain all statements that made any changes, so they can be used to audit the database.
Statements that are unsafe for SBR.
Not all statements which modify data (such as
INSERT
DELETE
,
UPDATE
, and
REPLACE
statements) can be
replicated using statement-based replication. Any
nondeterministic behavior is difficult to replicate when
using statement-based replication. Examples of such Data
Modification Language (DML) statements include the
following:
A statement that depends on a UDF or stored program that is nondeterministic, since the value returned by such a UDF or stored program or depends on factors other than the parameters supplied to it. (Row-based replication, however, simply replicates the value returned by the UDF or stored program, so its effect on table rows and data is the same on both the master and slave.) See Section 18.4.1.12, “Replication of Invoked Features”, for more information.
DELETE
and
UPDATE
statements that
use a LIMIT
clause without an
ORDER BY
are nondeterministic. See
Section 18.4.1.17, “Replication and LIMIT”.
Deterministic UDFs must be applied on the slaves.
Statements using any of the following functions cannot be replicated properly using statement-based replication:
SYSDATE()
(unless
both the master and the slave are started with the
--sysdate-is-now
option)
However, all other functions are replicated correctly
using statement-based replication, including
NOW()
and so forth.
For more information, see Section 18.4.1.16, “Replication and System Functions”.
Statements that cannot be replicated correctly using statement-based replication are logged with a warning like the one shown here:
[Warning] Statement is not safe to log in statement format.
A similar warning is also issued to the client in such
cases. The client can display it using
SHOW WARNINGS
.
INSERT ...
SELECT
requires a greater number of row-level
locks than with row-based replication.
UPDATE
statements that
require a table scan (because no index is used in the
WHERE
clause) must lock a greater number
of rows than with row-based replication.
For InnoDB
: An
INSERT
statement that uses
AUTO_INCREMENT
blocks other
nonconflicting INSERT
statements.
For complex statements, the statement must be evaluated and executed on the slave before the rows are updated or inserted. With row-based replication, the slave only has to modify the affected rows, not execute the full statement.
If there is an error in evaluation on the slave, particularly when executing complex statements, statement-based replication may slowly increase the margin of error across the affected rows over time. See Section 18.4.1.28, “Slave Errors During Replication”.
Stored functions execute with the same
NOW()
value as the calling
statement. However, this is not true of stored procedures.
Deterministic UDFs must be applied on the slaves.
Table definitions must be (nearly) identical on master and slave. See Section 18.4.1.10, “Replication with Differing Table Definitions on Master and Slave”, for more information.
All changes can be replicated. This is the safest form of replication.
Statements that update the information in the
mysql
database—such as
GRANT
,
REVOKE
and the manipulation
of triggers, stored routines (including stored
procedures), and views—are all replicated to slaves
using statement-based replication.
For statements such as
CREATE TABLE
... SELECT
, a CREATE
statement is generated from the table definition and
replicated using statement-based format, while the row
insertions are replicated using row-based format.
Fewer row locks are required on the master, which thus achieves higher concurrency, for the following types of statements:
Fewer row locks are required on the slave for any
INSERT
,
UPDATE
, or
DELETE
statement.
RBR can generate more data that must be logged. To replicate
a DML statement (such as an
UPDATE
or
DELETE
statement),
statement-based replication writes only the statement to the
binary log. By contrast, row-based replication writes each
changed row to the binary log. If the statement changes many
rows, row-based replication may write significantly more
data to the binary log; this is true even for statements
that are rolled back. This also means that making and
restoring a backup can require more time. In addition, the
binary log is locked for a longer time to write the data,
which may cause concurrency problems. Use
binlog_row_image=minimal
to
reduce the disadvantage considerably.
Deterministic UDFs that generate large
BLOB
values take longer to
replicate with row-based replication than with
statement-based replication. This is because the
BLOB
column value is logged,
rather than the statement generating the data.
You cannot see on the slave what statements were received
from the master and executed. However, you can see what data
was changed using mysqlbinlog with the
options
--base64-output=DECODE-ROWS
and --verbose
.
Alternatively, use the
binlog_rows_query_log_events
variable, which if enabled adds a
Rows_query
event with the statement to
mysqlbinlog output when the
-vv
option is used.
For tables using the MyISAM
storage engine, a stronger lock is required on the slave for
INSERT
statements when
applying them as row-based events to the binary log than
when applying them as statements. This means that concurrent
inserts on MyISAM
tables are
not supported when using row-based replication.
MySQL uses statement-based logging (SBL), row-based logging (RBL) or mixed-format logging. The type of binary log used impacts the size and efficiency of logging.Therefore the choice between row-based replication (RBR) or statement-based replication (SBR) depends on your application and environment. This section describes known issues when using a row-based format log, and describes some best practices using it in replication.
For additional information, see Section 18.2.1, “Replication Formats”, and Section 18.2.1.1, “Advantages and Disadvantages of Statement-Based and Row-Based Replication”.
For information about issues specific to MySQL Cluster Replication (which depends on row-based replication), see Section 21.6.3, “Known Issues in NDB Cluster Replication”.
Row-based logging of temporary tables. As noted in Section 18.4.1.24, “Replication and Temporary Tables”, temporary tables are not replicated when using row-based format. When using mixed format logging, “safe” statements involving temporary tables are logged using statement-based format. For more information, see Section 18.2.1.1, “Advantages and Disadvantages of Statement-Based and Row-Based Replication”.
Temporary tables are not replicated when using row-based format because there is no need. In addition, because temporary tables can be read only from the thread which created them, there is seldom if ever any benefit obtained from replicating them, even when using statement-based format.
In MySQL 5.7, you can switch from
statement-based to row-based binary logging mode even when
temporary tables have been created. However, while using the
row-based format, the MySQL server cannot determine the
logging mode that was in effect when a given temporary table
was created. For this reason, the server in such cases logs
a DROP TEMPORARY
TABLE IF EXISTS
statement for each temporary table
that still exists for a given client session when that
session ends. While this means that it is possible that an
unnecessary DROP TEMPORARY TABLE
statement might be logged in some cases, the statement is
harmless, and does not cause an error even if the table does
not exist, due to the presence of the IF
EXISTS
option.
Nontransactional DML statements involving temporary tables
are allowed when using
binlog_format=ROW
, as long
as any nontransactional tables affected by the statements
are temporary tables (Bug #14272672).
RBL and synchronization of nontransactional tables. When many rows are affected, the set of changes is split into several events; when the statement commits, all of these events are written to the binary log. When executing on the slave, a table lock is taken on all tables involved, and then the rows are applied in batch mode. Depending on the engine used for the slave's copy of the table, this may or may not be effective.
Latency and binary log size. RBL writes changes for each row to the binary log and so its size can increase quite rapidly. This can significantly increase the time required to make changes on the slave that match those on the master. You should be aware of the potential for this delay in your applications.
Reading the binary log.
mysqlbinlog displays row-based events
in the binary log using the BINLOG
statement (see Section 14.7.6.1, “BINLOG Syntax”). This statement
displays an event as a base 64-encoded string, the meaning
of which is not evident. When invoked with the
--base64-output=DECODE-ROWS
and --verbose
options,
mysqlbinlog formats the contents of the
binary log to be human readable. When binary log events
were written in row-based format and you want to read or
recover from a replication or database failure you can use
this command to read contents of the binary log. For more
information, see Section 5.6.7.2, “mysqlbinlog Row Event Display”.
Binary log execution errors and slave_exec_mode.
Using
slave_exec_mode=IDEMPOTENT
is generally only useful with MySQL NDB Cluster
replication, for which IDEMPOTENT
is
the default value. (See
Section 21.6.10, “NDB Cluster Replication: Multi-Master and Circular Replication”).
When slave_exec_mode
is
IDEMPOTENT
, a failure to apply changes
from RBL because the original row cannot be found does not
trigger an error or cause replication to fail. This means
that it is possible that updates are not applied on the
slave, so that the master and slave are no longer
synchronized. Latency issues and use of nontransactional
tables with RBR when
slave_exec_mode
is
IDEMPOTENT
can cause the master and
slave to diverge even further. For more information about
slave_exec_mode
, see
Section 6.1.5, “Server System Variables”.
For other scenarios, setting
slave_exec_mode
to
STRICT
is normally sufficient; this is
the default value for storage engines other than
NDB
.
Lack of binary log checksums.
RBL does not use checksums, so network, disk, and other
errors may not be identified when processing the binary
log. To ensure that data is transmitted without network
corruption use SSL for replication connections. The
CHANGE MASTER TO
statement
has options to enable replication over SSL. See also
Section 14.4.2.1, “CHANGE MASTER TO Syntax”, for general
information about setting up MySQL with SSL.
Filtering based on server ID not supported.
In MySQL 5.7, you can filter based on server
ID by using the IGNORE_SERVER_IDS
option for the CHANGE MASTER
TO
statement. This option works with
statement-based and row-based logging formats. Another
method to filter out changes on some slaves is to use a
WHERE
clause that includes the relation
@@server_id <>
clause with
id_value
UPDATE
and
DELETE
statements. For
example, WHERE @@server_id <> 1
.
However, this does not work correctly with row-based
logging. To use the
server_id
system variable
for statement filtering, use statement-based logging.
Database-level replication options.
The effects of the
--replicate-do-db
,
--replicate-ignore-db
, and
--replicate-rewrite-db
options differ considerably depending on whether row-based
or statement-based logging is used. Therefore, it is
recommended to avoid database-level options and instead
use table-level options such as
--replicate-do-table
and
--replicate-ignore-table
.
For more information about these options and the impact
replication format has on how they operate, see
Section 18.1.6, “Replication and Binary Logging Options and Variables”.
RBL, nontransactional tables, and stopped slaves.
When using row-based logging, if the slave server is
stopped while a slave thread is updating a
nontransactional table, the slave database can reach an
inconsistent state. For this reason, it is recommended
that you use a transactional storage engine such as
InnoDB
for all tables
replicated using the row-based format. Use of
STOP SLAVE
or
STOP SLAVE
SQL_THREAD
prior to shutting down the slave
MySQL server helps prevent issues from occurring, and is
always recommended regardless of the logging format or
storage engine you use.
The “safeness” of a statement in MySQL Replication, refers to whether the statement and its effects can be replicated correctly using statement-based format. If this is true of the statement, we refer to the statement as safe; otherwise, we refer to it as unsafe.
In general, a statement is safe if it deterministic, and unsafe if it is not. However, certain nondeterministic functions are not considered unsafe (see Nondeterministic functions not considered unsafe, later in this section). In addition, statements using results from floating-point math functions—which are hardware-dependent—are always considered unsafe (see Section 18.4.1.13, “Replication and Floating-Point Values”).
Handling of safe and unsafe statements.
A statement is treated differently depending on whether the
statement is considered safe, and with respect to the binary
logging format (that is, the current value of
binlog_format
).
When using row-based logging, no distinction is made in the treatment of safe and unsafe statements.
When using mixed-format logging, statements flagged as unsafe are logged using the row-based format; statements regarded as safe are logged using the statement-based format.
When using statement-based logging, statements flagged as being unsafe generate a warning to this effect. Safe statements are logged normally.
Each statement flagged as unsafe generates a warning. Formerly,
if a large number of such statements were executed on the
master, this could lead to excessively large error log files. To
prevent this, MySQL 5.7 provides a warning suppression
mechanism, which behaves as follows: Whenever the 50 most recent
ER_BINLOG_UNSAFE_STATEMENT
warnings have been generated more than 50 times in any 50-second
period, warning suppression is enabled. When activated, this
causes such warnings not to be written to the error log;
instead, for each 50 warnings of this type, a note The
last warning was repeated
is written
to the error log. This continues as long as the 50 most recent
such warnings were issued in 50 seconds or less; once the rate
has decreased below this threshold, the warnings are once again
logged normally. Warning suppression has no effect on how the
safety of statements for statement-based logging is determined,
nor on how warnings are sent to the client. MySQL clients still
receive one warning for each such statement.
N
times in
last S
seconds
For more information, see Section 18.2.1, “Replication Formats”.
Statements considered unsafe. Statements with the following characteristics are considered unsafe:
Statements containing system functions that may return a different value
on slave.
These functions include
FOUND_ROWS()
,
GET_LOCK()
,
IS_FREE_LOCK()
,
IS_USED_LOCK()
,
LOAD_FILE()
,
MASTER_POS_WAIT()
,
PASSWORD()
,
RAND()
,
RELEASE_LOCK()
,
ROW_COUNT()
,
SESSION_USER()
,
SLEEP()
,
SYSDATE()
,
SYSTEM_USER()
,
USER()
,
UUID()
, and
UUID_SHORT()
.
Nondeterministic functions not considered unsafe.
Although these functions are not deterministic, they are
treated as safe for purposes of logging and replication:
CONNECTION_ID()
,
CURDATE()
,
CURRENT_DATE()
,
CURRENT_TIME()
,
CURRENT_TIMESTAMP()
,
CURTIME()
,,
LAST_INSERT_ID()
,
LOCALTIME()
,
LOCALTIMESTAMP()
,
NOW()
,
UNIX_TIMESTAMP()
,
UTC_DATE()
,
UTC_TIME()
, and
UTC_TIMESTAMP()
.
For more information, see Section 18.4.1.16, “Replication and System Functions”.
References to system variables. Most system variables are not replicated correctly using the statement-based format. See Section 18.4.1.38, “Replication and Variables”. For exceptions, see Section 6.4.4.3, “Mixed Binary Logging Format”.
UDFs. Since we have no control over what a UDF does, we must assume that it is executing unsafe statements.
Fulltext plugin. This plugin may behave differently on different MySQL servers; therefore, statements depending on it could have different results. For this reason, all statements relying on the fulltext plugin are treated as unsafe in MySQL 5.7.1 and later. (Bug #11756280, Bug #48183)
Trigger or stored program updates a table having an AUTO_INCREMENT column. This is unsafe because the order in which the rows are updated may differ on the master and the slave.
In addition, an INSERT
into a
table that has a composite primary key containing an
AUTO_INCREMENT
column that is not the
first column of this composite key is unsafe.
For more information, see Section 18.4.1.1, “Replication and AUTO_INCREMENT”.
INSERT ... ON DUPLICATE KEY UPDATE statements on tables with multiple primary or unique keys. When executed against a table that contains more than one primary or unique key, this statement is considered unsafe, being sensitive to the order in which the storage engine checks the keys, which is not deterministic, and on which the choice of rows updated by the MySQL Server depends.
An
INSERT
... ON DUPLICATE KEY UPDATE
statement against a
table having more than one unique or primary key is marked
as unsafe for statement-based replication. (Bug #11765650,
Bug #58637)
Updates using LIMIT. The order in which rows are retrieved is not specified, and is therefore considered unsafe. See Section 18.4.1.17, “Replication and LIMIT”.
Accesses or references log tables. The contents of the system log table may differ between master and slave.
Nontransactional operations after transactional operations. Within a transaction, allowing any nontransactional reads or writes to execute after any transactional reads or writes is considered unsafe.
For more information, see Section 18.4.1.33, “Replication and Transactions”.
Accesses or references self-logging tables. All reads and writes to self-logging tables are considered unsafe. Within a transaction, any statement following a read or write to self-logging tables is also considered unsafe.
LOAD DATA INFILE statements.
LOAD DATA
INFILE
is treated as unsafe and when
binlog_format=mixed
the
statement is logged in row-based format. When
binlog_format=statement
LOAD DATA
INFILE
does not generate a warning, unlike other
unsafe statements.
For additional information, see Section 18.4.1, “Replication Features and Issues”.
MySQL replication capabilities are implemented using three threads, one on the master server and two on the slave:
Binlog dump thread.
The master creates a thread to send the binary log contents
to a slave when the slave connects. This thread can be
identified in the output of SHOW
PROCESSLIST
on the master as the Binlog
Dump
thread.
The binary log dump thread acquires a lock on the master's binary log for reading each event that is to be sent to the slave. As soon as the event has been read, the lock is released, even before the event is sent to the slave.
Slave I/O thread.
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 slave I/O thread reads the updates that the master's
Binlog Dump
thread sends (see previous
item) and copies them to local files that comprise the slave's
relay log.
The state of this thread is shown as
Slave_IO_running
in the output of
SHOW SLAVE STATUS
or as
Slave_running
in the output
of SHOW STATUS
.
Slave SQL thread. The slave creates an SQL thread to read the relay log that is written by the slave I/O thread and execute the events contained therein.
In the preceding description, there are three threads per master/slave connection. A master that has multiple slaves creates one binary log dump thread for each currently connected slave, and each slave has its own I/O and SQL threads.
A slave uses two threads to separate reading updates from the master and executing them into 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.
The SHOW PROCESSLIST
statement
provides information that tells you what is happening on the
master and on the slave regarding replication. For information on
master states, see Section 9.14.4, “Replication Master Thread States”. For
slave states, see Section 9.14.5, “Replication Slave I/O Thread States”, and
Section 9.14.6, “Replication Slave SQL Thread States”.
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 that services 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, no slaves are
currently connected.
On a 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
The State
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
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 A.13, “MySQL 5.7 FAQ: Replication”. If sufficient time elapses on
the master side without activity on the Binlog
Dump
thread, the master determines that the slave is no
longer connected. As for any other client connection, the timeouts
for this depend on the values of
net_write_timeout
and
net_retry_count
; for more information about
these, see Section 6.1.5, “Server System Variables”.
The SHOW SLAVE STATUS
statement
provides additional information about replication processing on a
slave server. See
Section 18.1.7.1, “Checking Replication Status”.
MySQL 5.7.6 introduces the concept of a replication channel, which represents the path of transactions flowing from a master to a slave. This section describes how channels can be used in a replication topology, and the impact they have on single-source replication.
To provide compatibity with previous versions, the MySQL server
automatically creates on startup a default channel whose name is the
empty string (""
). This channel is always
present; it cannot be created or destroyed by the user. If no other
channels (having nonempty names) have been created, replication
statements act on the default channel only, so that all replication
statements from older slaves function as expected (see
Section 18.2.3.2, “Compatibility with Previous Replication Statements”. Statements
applying to replication channels as described in this section can be
used only when there is at least one named channel.
A replication channel encompasses the path of transactions transmitted from a master to a slave. In multi-source replication a slave opens multiple channels, one per master, and each channel has its own relay log and applier (SQL) threads. Once transactions are received by a replication channel's receiver (I/O) thread, they are added to the channel's relay log file and passed through to an applier thread. This enables channels to function independently.
A replication channel is also associated with a host name and port. You can assign multiple channels to the same combination of host name and port; in MySQL 5.7, the maximum number of channels that can be added to one slave in a multi-source replication topology is 256. Each replication channel must have a unique (nonempty) name (see Section 18.2.3.4, “Replication Channel Naming Conventions”). Channels can be configured independently.
To enable existing MySQL replication statements to act on
individual replication channels, MySQL 5.7.6 introduces the
FOR CHANNEL
option for use
with the following replication statements in managing a
replication channel independently of other channels:
channel_name
Similarly, an additional channel_name
parameter
is introduced for the following functions:
Beginning with MySQL 5.7.9, the following statements are
disallowed for the group_replication_recovery
channel.
When a replication slave has multiple channels and a FOR
CHANNEL
option
is not specified, a valid statement generally acts on all
available channels.
channel_name
For example, the following statements behave as expected:
START SLAVE
starts replication
threads for all channels. (In MySQL 5.7.9 and later, this does
not include the group_replication_recovery
channel.)
STOP SLAVE
stops replication
threads for all the channels. (In MySQL 5.7.9 and later, this
does not include the
group_replication_recovery
channel.)
SHOW SLAVE STATUS
reports the
status for all channels.
FLUSH RELAY
LOGS
flushes the relay logs for all channels.
RESET
SLAVE
resets all channels.
Use RESET SLAVE
with caution as this
statement deletes all existing channels, purges their relay log
files, and recreates only the default channel.
Some replication statements cannot operate on all channels. In
this case, error 1964 Multiple channels exist on the
slave. Please provide channel name as an argument. is
generated. The following statements and functions generate this
error when used in a multi-source replication topology and a
FOR CHANNEL
option is not
used to specify which channel to act on:
channel_name
Note that a default channel always exists in a single source replication topology, where statements and functions behave as in previous versions of MySQL.
This section describes startup options which are impacted by the addition of replication channels.
The following startup options must be configured correctly to use multi-source replication.
This must be set to TABLE
. If this option
is set to FILE
, attempting to add more
sources to a slave fails with
ER_SLAVE_NEW_CHANNEL_WRONG_REPOSITORY.
--master-info-repository
This must be set to TABLE
. If this option
is set to FILE
, attempting to add more
sources to a slave fails with
ER_SLAVE_NEW_CHANNEL_WRONG_REPOSITORY.
The following startup options now affect all channels in a replication topology.
All transactions received by the slave (even from multiple sources) are written in the binary log.
When set, each channel purges its own relay log automatically.
Applier threads of all channels retry transactions.
No replication threads start on any channels.
Execution continues and errors are skipped for all channels.
The values set for the following startup options apply on each channel; since these are mysqld startup options, they are applied on every channel.
--max-relay-log-size=
size
Maximum size of the individual relay log file for each channel; after reaching this limit, the file is rotated.
--relay-log-space-limit=
size
Upper limit for the total size of all relay logs combined, for
each individual channel. For N
channels, the combined size of these logs is limited to
relay_log_space_limit *
.
N
--slave-parallel-workers=
value
Number of slave parallel workers per channel.
--slave-checkpoint-group
Waiting time by an I/O thread for each source.
--relay-log-index=filename
Base name for each channel's relay log index file. See Section 18.2.3.4, “Replication Channel Naming Conventions”.
--relay-log=filename
Denotes the base name of each channel's relay log file. See Section 18.2.3.4, “Replication Channel Naming Conventions”.
--slave_net-timeout=N
This value is set per channel, so that each channel waits for
N
seconds to check for a broken
connection.
--slave-skip-counter=N
This value is set per channel, so that each channel skips
N
events from its master.
This section describes how naming conventions are impacted by replication channels.
Each replication channel has a unique name which is a string with a maximum length of 64 characters and is case insensitive. Because channel names are used in slave tables, the character set used for these is always UTF-8. Although you are generally free to use any name for channels, the following names are reserved:
group_replication_applier
group_replication_recovery
The name you choose for a replication channel also influences the
file names used by a multi-source replication slave. The relay log
files and index files for each channel are named
,
where base_name
-relay-bin-channel_name
.0000xbase_name
is generally a host
name (if not specified using
--log-bin
) and
channel_name
is the name of the channel
logged to this file.
During replication, a slave server creates several logs that hold the binary log events relayed from the master to the slave, and to record information about the current status and location within the relay log. There are three types of logs used in the process, listed here:
The master info log contains status and current configuration information for the slave's connection to the master. This log holds information on the master host name, login credentials, and coordinates indicating how far the slave has read from the master's binary log.
This log can be written to the
mysql.slave_master_info
table instead of a
file, by starting the slave with
--master-info-repository=TABLE
.
The relay log consists of the events read from the binary log of the master and written by the slave I/O thread. Events in the relay log are executed on the slave as part of the SQL thread.
The relay log info log holds status information about the execution point within the slave's relay log.
This log can be written to the
mysql.slave_relay_log_info
table instead of
a file by starting the slave with
--relay-log-info-repository=TABLE
.
In MySQL 5.7, setting
relay_log_info_repository
and
master_info_repository
to
TABLE
can improve resilience to unexpected
halts (crash-safe replication). See
Section 18.3.2, “Handling an Unexpected Halt of a Replication Slave”.
When using this configuration, a warning is given if
mysqld is unable to initialize the replication
logging tables, but the slave is allowed to continue starting.
This situation is most likely to occur when upgrading from a
version of MySQL that does not support slave logging tables to one
in which they are supported.
Do not attempt to update or insert rows in the
slave_master_info
or
slave_relay_log_info
table manually. Doing so
can cause undefined behavior, and is not supported.
Execution of any statement requiring a write lock on either or
both of the slave_master_info
and
slave_relay_log_info
tables is disallowed while
replication is ongoing, while statements that perform only reads
are permitted at any time.
The relay log, like the binary log, consists of a set of numbered files containing events that describe database changes, and an index file that contains the names of all used relay log files.
The term “relay log file” generally denotes an individual numbered file containing database events. The term “relay log” collectively denotes the set of numbered relay log files plus the index file.
Relay log files have the same format as binary log files and can be read using mysqlbinlog (see Section 5.6.7, “mysqlbinlog — Utility for Processing Binary Log Files”).
By default, relay log file names have the form
in the data directory, where
host_name
-relay-bin.nnnnnn
host_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 file name is
in the data directory.
host_name
-relay-bin.index
The default relay log file and relay log index file names can be
overridden with, respectively, the
--relay-log
and
--relay-log-index
server options
(see Section 18.1.6, “Replication and Binary Logging Options and Variables”).
If a slave uses the default host-based relay log file names,
changing a slave's host name after replication has been set up
can cause replication to fail with the errors Failed
to open the relay log and Could not find
target log during relay log initialization. This is
a known issue (see Bug #2122). If you anticipate that a slave's
host name might change in the future (for example, if networking
is set up on the slave such that its host name can be modified
using DHCP), you can avoid this issue entirely by using the
--relay-log
and
--relay-log-index
options to
specify relay log file names explicitly when you initially set
up the slave. This will make the names independent of server
host name changes.
If you encounter the issue after replication has already begun, one way to work around it is to stop the slave server, prepend the contents of the old relay log index file to the new one, and then restart the slave. On a Unix system, this can be done as shown here:
shell>cat
shell>new_relay_log_name
.index >>old_relay_log_name
.indexmv
old_relay_log_name
.indexnew_relay_log_name
.index
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,” 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.
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 replication slave server creates two logs. By default, these
logs are files named master.info
and
relay-log.info
and created in the data
directory. The names and locations of these files can be changed
by using the --master-info-file
and --relay-log-info-file
options, respectively. In MySQL 5.7, either or both
of these logs can also be written to tables in the
mysql
database by starting the server with
the appropriate option: use
--master-info-repository
to have
the master info log written to the
mysql.slave_master_info
table, and use
--relay-log-info-repository
to
have the relay log info log written to the
mysql.slave_relay_log_info
table. See
Section 18.1.6, “Replication and Binary Logging Options and Variables”.
The two status logs contain information like that shown in the
output of the SHOW SLAVE STATUS
statement, which is discussed in
Section 14.4.2, “SQL Statements for Controlling Slave Servers”. Because the status logs
are stored on disk, they survive a slave server's shutdown.
The next time the slave starts up, it reads the two logs to
determine how far it has proceeded in reading binary logs from
the master and in processing its own relay logs.
The master info log file or table should be protected because it contains the password for connecting to the master. See Section 7.1.2.3, “Passwords and Logging”.
The slave I/O thread updates the master info log. The following
table shows the correspondence between the lines in the
master.info
file, the columns in the
mysql.slave_master_info
table, and the
columns displayed by SHOW SLAVE
STATUS
.
Line in master.info File | slave_master_info Table Column | SHOW SLAVE STATUS Column | Description |
---|---|---|---|
1 | Number_of_lines | [None] | Number of lines in the file, or columns in the table |
2 | Master_log_name | Master_Log_File | The name of the master binary log currently being read from the master |
3 | Master_log_pos | Read_Master_Log_Pos | The current position within the master binary log that have been read from the master |
4 | Host | Master_Host | The host name of the master |
5 | User_name | Master_User | The user name used to connect to the master |
6 | User_password | Password (not shown by SHOW SLAVE STATUS ) | The password used to connect to the master |
7 | Port | Master_Port | The network port used to connect to the master |
8 | Connect_retry | Connect_Retry | The period (in seconds) that the slave will wait before trying to reconnect to the master |
9 | Enabled_ssl | Master_SSL_Allowed | Indicates whether the server supports SSL connections |
10 | Ssl_ca | Master_SSL_CA_File | The file used for the Certificate Authority (CA) certificate |
11 | Ssl_capath | Master_SSL_CA_Path | The path to the Certificate Authority (CA) certificates |
12 | Ssl_cert | Master_SSL_Cert | The name of the SSL certificate file |
13 | Ssl_cipher | Master_SSL_Cipher | The list of possible ciphers used in the handshake for the SSL connection |
14 | Ssl_key | Master_SSL_Key | The name of the SSL key file |
15 | Ssl_verify_server_cert | Master_SSL_Verify_Server_Cert | Whether to verify the server certificate |
16 | Heartbeat | [None] | Interval between replication heartbeats, in seconds |
17 | Bind | Master_Bind | Which of the slave's network interfaces should be used for connecting to the master |
18 | Ignored_server_ids | Replicate_Ignore_Server_Ids | The list of server IDs to be ignored. Note that for
Ignored_server_ids the list of server
IDs is preceded by the total number of server IDs to
ignore. |
19 | Uuid | Master_UUID | The master's unique ID |
20 | Retry_count | Master_Retry_Count | Maximum number of reconnection attempts permitted |
21 | Ssl_crl | [None] | Path to an ssl certificate revocation list file |
22 | Ssl_crl_path | [None] | Path to a directory containing ssl certificate revocation list files |
23 | Enabled_auto_position | Auto_position | If autopositioning is in use or not |
24 | Channel_name | Channel_name | The name of the replication channel |
The slave SQL thread updates the relay log info log. In MySQL
5.7, the relay-log.info
file
includes a line count and a replication delay value. The
following table shows the correspondence between the lines in
the relay-log.info
file, the columns in the
mysql.slave_relay_log_info
table, and the
columns displayed by SHOW SLAVE
STATUS
.
Line in relay-log.info | slave_relay_log_info Table Column | SHOW SLAVE STATUS Column | Description |
---|---|---|---|
1 | Number_of_lines | [None] | Number of lines in the file or columns in the table |
2 | Relay_log_name | Relay_Log_File | The name of the current relay log file |
3 | Relay_log_pos | Relay_Log_Pos | The current position within the relay log file; events up to this position have been executed on the slave database |
4 | Master_log_name | Relay_Master_Log_File | The name of the master binary log file from which the events in the relay log file were read |
5 | Master_log_pos | Exec_Master_Log_Pos | The equivalent position within the master's binary log file of events that have already been executed |
6 | Sql_delay | SQL_Delay | The number of seconds that the slave must lag the master |
7 | Number_of_workers | [None] | The number of slave worker threads for executing replication events (transactions) in parallel |
8 | Id | [None] | ID used for internal purposes; currently this is always 1 |
9 | Channel_name | Channel_name | The name of the replication channel |
In older versions of MySQL (prior to MySQL 5.6), the
relay-log.info
file does not include a line
count or a delay value (and the
slave_relay_log_info
table is not available).
Line | Status Column | Description |
---|---|---|
1 | Relay_Log_File | The name of the current relay log file |
2 | Relay_Log_Pos | The current position within the relay log file; events up to this position have been executed on the slave database |
3 | Relay_Master_Log_File | The name of the master binary log file from which the events in the relay log file were read |
4 | Exec_Master_Log_Pos | The equivalent position within the master's binary log file of events that have already been executed |
If you downgrade a slave server to a version older than MySQL
5.6, the older server does not read the
relay-log.info
file correctly. To address
this, modify the file in a text editor by deleting the initial
line containing the number of lines.
The contents of the relay-log.info
file and
the states shown by the SHOW SLAVE
STATUS
statement might 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
(that is, mysqld
is not running). For a
running system, you can use SHOW SLAVE
STATUS
, or query the
slave_master_info
and
slave_relay_log_info
tables if you are
writing the status logs to tables.
When you back up the slave's data, you should back up these
two status logs, along with the relay log files. The status logs
are needed to resume replication after you restore the data from
the slave. If you lose the relay logs but still have the relay
log info log, 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.
If a master server does not write a statement to its binary log, the statement is not replicated. If the server does log the statement, the statement is sent to all slaves and each slave determines whether to execute it or ignore it.
On the master, you can control which databases to log changes for
by using the --binlog-do-db
and
--binlog-ignore-db
options to
control binary logging. For a description of the rules that
servers use in evaluating these options, see
Section 18.2.5.1, “Evaluation of Database-Level Replication and Binary Logging Options”. You should not use
these options to control which databases and tables are
replicated. Instead, use filtering on the slave to control the
events that are executed on the slave.
On the slave side, decisions about whether to execute or ignore
statements received from the master are made according to the
--replicate-*
options that the slave was started
with. (See Section 18.1.6, “Replication and Binary Logging Options and Variables”.) In MySQL 5.7.3
and later, the filters governed by these options can also be set
dynamically using the CHANGE REPLICATION FILTER
statement. The rules governing such filters are the same whether
they are created on startup using --replicate-*
options or while the slave server is running by CHANGE
REPLICATION FILTER
.
In the simplest case, when there are no
--replicate-*
options, the slave executes all
statements that it receives from the master. Otherwise, the result
depends on the particular options given.
Database-level options
(--replicate-do-db
,
--replicate-ignore-db
) are checked
first; see Section 18.2.5.1, “Evaluation of Database-Level Replication and Binary Logging Options”, for a
description of this process. If no database-level options are
used, option checking proceeds to any table-level options that may
be in use (see Section 18.2.5.2, “Evaluation of Table-Level Replication Options”,
for a discussion of these). If one or more database-level options
are used but none are matched, the statement is not replicated.
For statements affecting databases only (that is,
CREATE DATABASE
,
DROP DATABASE
, and
ALTER DATABASE
), database-level
options always take precedence over any
--replicate-wild-do-table
options.
In other words, for such statements,
--replicate-wild-do-table
options
are checked if and only if there are no database-level options
that apply. This is a change in behavior from previous versions of
MySQL, where the statement
CREATE DATABASE
dbx
was not replicated if the slave had been started
with --replicate-do-db=dbx
--replicate-wild-do-table=db%.t1
.
(Bug #46110)
To make it easier to determine what effect an option set will have, it is recommended that you avoid mixing “do” and “ignore” options, or wildcard and nonwildcard options.
If any --replicate-rewrite-db
options were specified, they are applied before the
--replicate-*
filtering rules are tested.
In MySQL 5.7, all replication filtering options
follow the same rules for case sensitivity that apply to names
of databases and tables elsewhere in the MySQL server, including
the effects of the
lower_case_table_names
system
variable.
This is a change from previous versions of MySQL. (Bug #51639)
When evaluating replication options, the slave begins by
checking to see whether there are any
--replicate-do-db
or
--replicate-ignore-db
options
that apply. When using
--binlog-do-db
or
--binlog-ignore-db
, the process
is similar, but the options are checked on the master.
With statement-based replication, the default database is checked for a match. With row-based replication, the database where data is to be changed is the database that is checked. Regardless of the binary logging format, checking of database-level options proceeds as shown in the following diagram.
The steps involved are listed here:
Are there any
--replicate-do-db
options?
Yes. Do any of them match the database?
Yes. Execute the statement and exit.
No. Ignore the statement and exit.
No. Continue to step 2.
Are there any
--replicate-ignore-db
options?
Yes. Do any of them match the database?
Yes. Ignore the statement and exit.
No. Continue to step 3.
No. Continue to step 3.
Proceed to checking the table-level replication options, if there are any. For a description of how these options are checked, see Section 18.2.5.2, “Evaluation of Table-Level Replication Options”.
A statement that is still permitted at this stage is not yet actually executed. The statement is not executed until all table-level options (if any) have also been checked, and the outcome of that process permits execution of the statement.
For binary logging, the steps involved are listed here:
Are there any --binlog-do-db
or --binlog-ignore-db
options?
Yes. Continue to step 2.
No. Log the statement and exit.
Is there a default database (has any database been selected
by USE
)?
Yes. Continue to step 3.
No. Ignore the statement and exit.
There is a default database. Are there any
--binlog-do-db
options?
Yes. Do any of them match the database?
Yes. Log the statement and exit.
No. Ignore the statement and exit.
No. Continue to step 4.
Do any of the
--binlog-ignore-db
options
match the database?
Yes. Ignore the statement and exit.
No. Log the statement and exit.
For statement-based logging, an exception is made in the rules
just given for the CREATE
DATABASE
, ALTER
DATABASE
, and DROP
DATABASE
statements. In those cases, the database
being created, altered, or dropped
replaces the default database when determining whether to log
or ignore updates.
--binlog-do-db
can sometimes mean
“ignore other databases”. For example, when using
statement-based logging, a server running with only
--binlog-do-db=sales
does not
write to the binary log statements for which the default
database differs from sales
. When using
row-based logging with the same option, the server logs only
those updates that change data in sales
.
The slave checks for and evaluates table options only if either of the following two conditions is true:
No matching database options were found.
One or more database options were found, and were evaluated to arrive at an “execute” condition according to the rules described in the previous section (see Section 18.2.5.1, “Evaluation of Database-Level Replication and Binary Logging Options”).
First, as a preliminary condition, the slave checks whether statement-based replication is enabled. If so, and the statement occurs within a stored function, the slave executes the statement and exits. If row-based replication is enabled, the slave does not know whether a statement occurred within a stored function on the master, so this condition does not apply.
For statement-based replication, replication events represent
statements (all changes making up a given event are associated
with a single SQL statement); for row-based replication, each
event represents a change in a single table row (thus a single
statement such as UPDATE mytable SET mycol =
1
may yield many row-based events). When viewed in
terms of events, the process of checking table options is the
same for both row-based and statement-based replication.
Having reached this point, if there are no table options, the
slave simply executes all events. If there are any
--replicate-do-table
or
--replicate-wild-do-table
options, the event must match one of these if it is to be
executed; otherwise, it is ignored. If there are any
--replicate-ignore-table
or
--replicate-wild-ignore-table
options, all events are executed except those that match any of
these options. This process is illustrated in the following
diagram.
The following steps describe this evaluation in more detail:
Are there any table options?
Yes. Continue to step 2.
No. Execute the event and exit.
Are there any
--replicate-do-table
options?
Yes. Does the table match any of them?
Yes. Execute the event and exit.
No. Continue to step 3.
No. Continue to step 3.
Are there any
--replicate-ignore-table
options?
Yes. Does the table match any of them?
Yes. Ignore the event and exit.
No. Continue to step 4.
No. Continue to step 4.
Are there any
--replicate-wild-do-table
options?
Yes. Does the table match any of them?
Yes. Execute the event and exit.
No. Continue to step 5.
No. Continue to step 5.
Are there any
--replicate-wild-ignore-table
options?
Yes. Does the table match any of them?
Yes. Ignore the event and exit.
No. Continue to step 6.
No. Continue to step 6.
Are there any
--replicate-do-table
or
--replicate-wild-do-table
options?
Yes. Ignore the event and exit.
No. Execute the event and exit.
This section provides additional explanation and examples of usage for different combinations of replication filtering options.
Some typical combinations of replication filter rule types are given in the following table:
Condition (Types of Options) | Outcome |
---|---|
No --replicate-* options at all: | The slave executes all events that it receives from the master. |
--replicate-*-db options, but no table options: | The slave accepts or ignores events using the database options. It executes all events permitted by those options because there are no table restrictions. |
--replicate-*-table options, but no database options: | All events are accepted at the database-checking stage because there are no database conditions. The slave executes or ignores events based solely on the table options. |
A combination of database and table options: | The slave accepts or ignores events using the database options. Then it evaluates all events permitted by those options according to the table options. This can sometimes lead to results that seem counterintuitive, and that may be different depending on whether you are using statement-based or row-based replication; see the text for an example. |
A more complex example follows, in which we examine the outcomes for both statement-based and row-based settings.
Suppose that we have two tables mytbl1
in
database db1
and mytbl2
in
database db2
on the master, and the slave is
running with the following options (and no other replication
filtering options):
replicate-ignore-db = db1 replicate-do-table = db2.tbl2
Now we execute the following statements on the master:
USE db1; INSERT INTO db2.tbl2 VALUES (1);
The results on the slave vary considerably depending on the binary log format, and may not match initial expectations in either case.
Statement-based replication.
The USE
statement causes
db1
to be the default database. Thus the
--replicate-ignore-db
option
matches, and the
INSERT
statement is
ignored. The table options are not checked.
Row-based replication.
The default database has no effect on how the slave reads
database options when using row-based replication. Thus, the
USE
statement makes no
difference in how the
--replicate-ignore-db
option is
handled: the database specified by this option does not match
the database where the INSERT
statement changes data, so the slave proceeds to check the
table options. The table specified by
--replicate-do-table
matches
the table to be updated, and the row is
inserted.
Replication can be used in many different environments for a range of purposes. This section provides general notes and advice on using replication for specific solution types.
For information on using replication in a backup environment, including notes on the setup, backup procedure, and files to back up, see Section 18.3.1, “Using Replication for Backups”.
For advice and tips on using different storage engines on the master and slaves, see Section 18.3.3, “Using Replication with Different Master and Slave Storage Engines”.
Using replication as a scale-out solution requires some changes in the logic and operation of applications that use the solution. See Section 18.3.4, “Using Replication for Scale-Out”.
For performance or data distribution reasons, you may want to replicate different databases to different replication slaves. See Section 18.3.5, “Replicating Different Databases to Different Slaves”
As the number of replication slaves increases, the load on the master can increase and lead to reduced performance (because of the need to replicate the binary log to each slave). For tips on improving your replication performance, including using a single secondary server as a replication master, see Section 18.3.6, “Improving Replication Performance”.
For guidance on switching masters, or converting slaves into masters as part of an emergency failover solution, see Section 18.3.7, “Switching Masters During Failover”.
To secure your replication communication, you can encrypt the communication channel. For step-by-step instructions, see Section 18.3.8, “Setting Up Replication to Use Secure Connections”.
To use replication as a backup solution, replicate data from the master to a slave, and then back up the data slave. The slave can be paused and shut down without affecting the running operation of the master, so you can produce an effective snapshot of “live” data that would otherwise require the master to be shut down.
How you back up a database depends on its size and whether you are backing up only the data, or the data and the replication slave state so that you can rebuild the slave in the event of failure. There are therefore two choices:
If you are using replication as a solution to enable you to back up the data on the master, and the size of your database is not too large, the mysqldump tool may be suitable. See Section 18.3.1.1, “Backing Up a Slave Using mysqldump”.
For larger databases, where mysqldump would be impractical or inefficient, you can back up the raw data files instead. Using the raw data files option also means that you can back up the binary and relay logs that will enable you to recreate the slave in the event of a slave failure. For more information, see Section 18.3.1.2, “Backing Up Raw Data from a Slave”.
Another backup strategy, which can be used for either master or slave servers, is to put the server in a read-only state. The backup is performed against the read-only server, which then is changed back to its usual read/write operational status. See Section 18.3.1.3, “Backing Up a Master or Slave by Making It Read Only”.
Using mysqldump to create a copy of a database enables you to capture all of the data in the database in a format that enables the information to be imported into another instance of MySQL Server (see Section 5.5.4, “mysqldump — A Database Backup Program”). Because the format of the information is SQL statements, the file can easily be distributed and applied to running servers in the event that you need access to the data in an emergency. However, if the size of your data set is very large, mysqldump may be impractical.
When using mysqldump, you should stop replication on the slave before starting the dump process to ensure that the dump contains a consistent set of data:
Stop the slave from processing requests. You can stop replication completely on the slave using mysqladmin:
shell> mysqladmin stop-slave
Alternatively, you can stop only the slave SQL thread to pause event execution:
shell> mysql -e 'STOP SLAVE SQL_THREAD;'
This enables the slave to continue to receive data change events from the master's binary log and store them in the relay logs using the I/O thread, but prevents the slave from executing these events and changing its data. Within busy replication environments, permitting the I/O thread to run during backup may speed up the catch-up process when you restart the slave SQL thread.
Run mysqldump to dump your databases. You may either dump all databases or select databases to be dumped. For example, to dump all databases:
shell> mysqldump --all-databases > fulldb.dump
Once the dump has completed, start slave operations again:
shell> mysqladmin start-slave
In the preceding example, you may want to add login credentials (user name, password) to the commands, and bundle the process up into a script that you can run automatically each day.
If you use this approach, make sure you monitor the slave replication process to ensure that the time taken to run the backup does not affect the slave's ability to keep up with events from the master. See Section 18.1.7.1, “Checking Replication Status”. If the slave is unable to keep up, you may want to add another slave and distribute the backup process. For an example of how to configure this scenario, see Section 18.3.5, “Replicating Different Databases to Different Slaves”.
To guarantee the integrity of the files that are copied, backing
up the raw data files on your MySQL replication slave should
take place while your slave server is shut down. If the MySQL
server is still running, background tasks may still be updating
the database files, particularly those involving storage engines
with background processes such as InnoDB
.
With InnoDB
, these problems should be
resolved during crash recovery, but since the slave server can
be shut down during the backup process without affecting the
execution of the master it makes sense to take advantage of this
capability.
To shut down the server and back up the files:
Shut down the slave MySQL server:
shell> mysqladmin shutdown
Copy the data files. You can use any suitable copying or archive utility, including cp, tar or WinZip. For example, assuming that the data directory is located under the current directory, you can archive the entire directory as follows:
shell> tar cf /tmp/dbbackup.tar ./data
Start the MySQL server again. Under Unix:
shell> mysqld_safe &
Under Windows:
C:\> "C:\Program Files\MySQL\MySQL Server 5.7\bin\mysqld"
Normally you should back up the entire data directory for the slave MySQL server. If you want to be able to restore the data and operate as a slave (for example, in the event of failure of the slave), then in addition to the slave's data, you should also back up the slave status files, the master info and relay log info repositories, and the relay log files. These files 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. This requires that the
binary logs still exist on the master server.
If your slave is 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 location of this directory is
the value of the
--slave-load-tmpdir
option. If
the server was not started with that option, the directory
location is the value of the
tmpdir
system variable.
It is possible to back up either master or slave servers in a
replication setup by acquiring a global read lock and
manipulating the read_only
system variable to change the read-only state of the server to
be backed up:
Make the server read-only, so that it processes only retrievals and blocks updates.
Perform the backup.
Change the server back to its normal read/write state.
The instructions in this section place the server to be backed up in a state that is safe for backup methods that get the data from the server, such as mysqldump (see Section 5.5.4, “mysqldump — A Database Backup Program”). You should not attempt to use these instructions to make a binary backup by copying files directly because the server may still have modified data cached in memory and not flushed to disk.
The following instructions describe how to do this for a master server and for a slave server. For both scenarios discussed here, suppose that you have the following replication setup:
A master server M1
A slave server S1 that has M1 as its master
A client C1 connected to M1
A client C2 connected to S1
In either scenario, the statements to acquire the global read
lock and manipulate the
read_only
variable are
performed on the server to be backed up and do not propagate to
any slaves of that server.
Scenario 1: Backup with a Read-Only Master
Put the master M1 in a read-only state by executing these statements on it:
mysql>FLUSH TABLES WITH READ LOCK;
mysql>SET GLOBAL read_only = ON;
While M1 is in a read-only state, the following properties are true:
Requests for updates sent by C1 to M1 will block because the server is in read-only mode.
Requests for query results sent by C1 to M1 will succeed.
Making a backup on M1 is safe.
Making a backup on S1 is not safe. This server is still running, and might be processing the binary log or update requests coming from client C2
While M1 is read only, perform the backup. For example, you can use mysqldump.
After the backup operation on M1 completes, restore M1 to its normal operational state by executing these statements:
mysql>SET GLOBAL read_only = OFF;
mysql>UNLOCK TABLES;
Although performing the backup on M1 is safe (as far as the backup is concerned), it is not optimal for performance because clients of M1 are blocked from executing updates.
This strategy applies to backing up a master server in a replication setup, but can also be used for a single server in a nonreplication setting.
Scenario 2: Backup with a Read-Only Slave
Put the slave S1 in a read-only state by executing these statements on it:
mysql>FLUSH TABLES WITH READ LOCK;
mysql>SET GLOBAL read_only = ON;
While S1 is in a read-only state, the following properties are true:
The master M1 will continue to operate, so making a backup on the master is not safe.
The slave S1 is stopped, so making a backup on the slave S1 is safe.
These properties provide the basis for a popular backup scenario: Having one slave busy performing a backup for a while is not a problem because it does not affect the entire network, and the system is still running during the backup. In particular, clients can still perform updates on the master server, which remains unaffected by backup activity on the slave.
While S1 is read only, perform the backup. For example, you can use mysqldump.
After the backup operation on S1 completes, restore S1 to its normal operational state by executing these statements:
mysql>SET GLOBAL read_only = OFF;
mysql>UNLOCK TABLES;
After the slave is restored to normal operation, it again synchronizes to the master by catching up with any outstanding updates from the binary log of the master.
In order for replication to be resilient to unexpected halts of the server (sometimes described as crash-safe) it must be possible for the slave to recover its state before halting. This section describes the impact of an unexpected halt of a slave during replication and how to configure a slave for the best chance of recovery to continue replication.
After an unexpected halt of a slave, upon restart the I/O thread
must recover the information about which transactions have been
received, and the SQL thread must recover which transactions have
been executed already. For information on the slave logs required
for recovery, see Section 18.2.4, “Replication Relay and Status Logs”. The information
required for recovery was traditionally stored in files, which had
the risk of losing synchrony with the master depending at which
stage of processing a transaction the slave halted at, or even
corruption of the files themselves. In MySQL 5.7 you
can instead use tables to store this information. These tables are
created using InnoDB
, and by using
this transactional storage engine the information is always
recoverable upon restart. To configure MySQL 5.7 to
store the replication information in tables, set
relay_log_info_repository
and
master_info_repository
to
TABLE
. The server then stores information
required for the recovery of the I/O thread in the
mysql.slave_master_info
table and information
required for the recovery of the SQL thread in the
mysql.slave_relay_log_info
table.
Exactly how a replication slave recovers from an unexpected halt
is influenced by the chosen method of replication, whether the
slave is single-threaded or multi-threaded, the setting of
variables such as
relay_log_recovery
, and whether
features such as MASTER_AUTO_POSITION
are being
used.
The following table shows the impact of these different factors on how a single-threaded slave recovers from an unexpected halt.
Table 18.5 Factors Influencing Single-threaded Replication Slave Recovery
GTID | MASTER_AUTO_POSITION | Crash type | Recovery guaranteed | Relay log impact | ||
---|---|---|---|---|---|---|
OFF | Any | 1 | TABLE | Any | Yes | Lost |
OFF | Any | 1 | TABLE | Server | Yes | Lost |
OFF | Any | 1 | Any | OS | No | Lost |
OFF | Any | 0 | TABLE | Server | Yes | Remains |
OFF | Any | 0 | TABLE | OS | No | Remains |
ON | ON | Any | Any | Any | Yes | Lost |
ON | OFF | 0 | TABLE | Server | Yes | Remains |
ON | OFF | 0 | Any | OS | No | Remains |
As the table shows, when using a single-threaded slave the following configurations are most resilient to unexpected halts:
When using GTIDs and MASTER_AUTO_POSITION
,
set relay_log_recovery=0
.
With this configuration the setting of
relay_log_info_repository
and
other variables does not impact on recovery.
When using file position based replication, set
relay_log_recovery=1
and
relay_log_info_repository=TABLE
.
During recovery the relay log is lost.
The following table shows the impact of these different factors on how a multi-threaded slave recovers from an unexpected halt.
Table 18.6 Factors Influencing Multi-threaded Replication Slave Recovery
GTID |
| Crash type | Recovery guaranteed | Relay log impact | |||
---|---|---|---|---|---|---|---|
OFF | 1 | Any | 1 | TABLE | Any | Yes | Lost |
OFF | >1 | Any | 1 | TABLE | Server | Yes | Lost |
OFF | >1 | Any | 1 | Any | OS | No | Lost |
OFF | 1 | Any | 0 | TABLE | Server | Yes | Remains |
OFF | 1 | Any | 0 | TABLE | OS | No | Remains |
ON | Any | ON | Any | Any | Any | Yes | Lost |
ON | 1 | OFF | 0 | TABLE | Server | Yes | Remains |
ON | 1 | OFF | 0 | Any | OS | No | Remains |
As the table shows, when using a multi-threaded slave the following configurations are most resilient to unexpected halts:
When using GTIDs and MASTER_AUTO_POSITION
,
set relay_log_recovery=0
.
With this configuration the setting of
relay_log_info_repository
and
other variables does not impact on recovery.
When using file position based replication, set
relay_log_recovery=1
,
sync_relay_log=1
, and
relay_log_info_repository=TABLE
.
During recovery the relay log is lost.
It is important to note the impact of
sync_relay_log=1
, which requires
a write of to the relay log per transaction. Although this setting
is the most resilient to an unexpected halt, with at most one
unwritten transaction being lost, it also has the potential to
greatly increase the load on storage. Without
sync_relay_log=1
, the effect of
an unexpected halt depends on how the relay log is handled by the
operating system. Also note that when
relay_log_recovery=0
, the next
time the slave is started after an unexpected halt the relay log
is processed as part of recovery. After this process completes,
the relay log is deleted.
An unexpected halt of a multi-threaded replication slave using the
recommended file position based replication configuration above
may result in a relay log with transaction inconsistencies (gaps
in the sequence of transactions) caused by the unexpected halt.
See
Section 18.4.1.34, “Replication and Transaction Inconsistencies”.
In MySQL 5.7.13 and later, if the relay log recovery process
encounters such transaction inconsistencies they are filled and
the recovery process continues automatically. In MySQL versions
prior to MySQL 5.7.13, this process is not automatic and requires
starting the server with
relay_log_recovery=0
, starting
the slave with START
SLAVE UNTIL SQL_AFTER_MTS_GAPS
to fix any transaction
inconsistencies and then restarting the slave with
relay_log_recovery=1
.
When you are using multi-source replication and
relay_log_recovery=1
, after
restarting due to an unexpected halt all replication channels go
through the relay log recovery process. Any inconsistencies found
in the relay log due to an unexpected halt of a multi-threaded
slave are filled.
It does not matter for the replication process whether the source
table on the master and the replicated table on the slave use
different engine types. In fact, the
default_storage_engine
and
storage_engine
system variables
are not replicated.
This provides a number of benefits in the replication process in
that you can take advantage of different engine types for
different replication scenarios. For example, in a typical
scale-out scenario (see
Section 18.3.4, “Using Replication for Scale-Out”), you want to use
InnoDB
tables on the master to take advantage
of the transactional functionality, but use
MyISAM
on the slaves where transaction support
is not required because the data is only read. When using
replication in a data-logging environment you may want to use the
Archive
storage engine on the slave.
Configuring different engines on the master and slave depends on how you set up the initial replication process:
If you used mysqldump to create the database snapshot on your master, you could edit the dump file text to change the engine type used on each table.
Another alternative for mysqldump is to
disable engine types that you do not want to use on the slave
before using the dump to build the data on the slave. For
example, you can add the
--skip-federated
option on your slave to disable the
FEDERATED
engine. If a specific engine does
not exist for a table to be created, MySQL will use the
default engine type, usually MyISAM
. (This
requires that the
NO_ENGINE_SUBSTITUTION
SQL
mode is not enabled.) If you want to disable additional
engines in this way, you may want to consider building a
special binary to be used on the slave that only supports the
engines you want.
If you are using raw data files (a binary backup) to set up
the slave, you will be unable to change the initial table
format. Instead, use ALTER
TABLE
to change the table types after the slave has
been started.
For new master/slave replication setups where there are currently no tables on the master, avoid specifying the engine type when creating new tables.
If you are already running a replication solution and want to convert your existing tables to another engine type, follow these steps:
Stop the slave from running replication updates:
mysql> STOP SLAVE;
This will enable you to change engine types without interruptions.
Execute an ALTER TABLE ...
ENGINE='
for
each table to be changed.
engine_type
'
Start the slave replication process again:
mysql> START SLAVE;
Although the
default_storage_engine
variable
is not replicated, be aware that CREATE
TABLE
and ALTER TABLE
statements that include the engine specification will be correctly
replicated to the slave. For example, if you have a CSV table and
you execute:
mysql> ALTER TABLE csvtable Engine='MyISAM';
The above statement will be replicated to the slave and the engine
type on the slave will be converted to MyISAM
,
even if you have previously changed the table type on the slave to
an engine other than CSV. If you want to retain engine differences
on the master and slave, you should be careful to use the
default_storage_engine
variable
on the master when creating a new table. For example, instead of:
mysql> CREATE TABLE tablea (columna int) Engine=MyISAM;
Use this format:
mysql>SET default_storage_engine=MyISAM;
mysql>CREATE TABLE tablea (columna int);
When replicated, the
default_storage_engine
variable
will be ignored, and the CREATE
TABLE
statement will execute on the slave using the
slave's default engine.
You can use replication as a scale-out solution; that is, where you want to split up the load of database queries across multiple database servers, within some reasonable limitations.
Because replication works from the distribution of one master to one or more slaves, using replication for scale-out works best in an environment where you have a high number of reads and low number of writes/updates. Most Web sites fit into this category, where users are browsing the Web site, reading articles, posts, or viewing products. Updates only occur during session management, or when making a purchase or adding a comment/message to a forum.
Replication in this situation enables you to distribute the reads over the replication slaves, while still enabling your web servers to communicate with the replication master when a write is required. You can see a sample replication layout for this scenario in Figure 18.1, “Using Replication to Improve Performance During Scale-Out”.
If the part of your code that is responsible for database access has been properly abstracted/modularized, converting it to run with a replicated setup should be very smooth and easy. Change the implementation of your database access to send all writes to the master, and to send reads to either the master or a slave. If your code does not have this level of abstraction, setting up a replicated system gives you the opportunity and motivation to clean it up. Start by creating a wrapper library or module that implements the following functions:
safe_writer_connect()
safe_reader_connect()
safe_reader_statement()
safe_writer_statement()
safe_
in each function name means that the
function takes care of handling all error conditions. You can use
different names for the functions. The important thing is to have
a unified interface for connecting for reads, connecting for
writes, doing a read, and doing a write.
Then convert your client code to use the wrapper library. This may be a painful and scary process at first, but it pays off in the long run. All applications that use the approach just described are able to take advantage of a master/slave configuration, even one involving multiple slaves. The code is much easier to maintain, and adding troubleshooting options is trivial. You need modify only one or two functions; for example, to log how long each statement took, or which statement among those issued gave you an error.
If you have written a lot of code, you may want to automate the conversion task by using the replace utility that comes with standard MySQL distributions, or write your own conversion script. Ideally, your code uses consistent programming style conventions. If not, then you are probably better off rewriting it anyway, or at least going through and manually regularizing it to use a consistent style.
There may be situations where you have a single master and want to replicate different databases to different slaves. For example, you may want to distribute different sales data to different departments to help spread the load during data analysis. A sample of this layout is shown in Figure 18.2, “Using Replication to Replicate Databases to Separate Replication Slaves”.
You can achieve this separation by configuring the master and
slaves as normal, and then limiting the binary log statements that
each slave processes by using the
--replicate-wild-do-table
configuration option on each slave.
You should not use
--replicate-do-db
for this
purpose when using statement-based replication, since
statement-based replication causes this option's affects to
vary according to the database that is currently selected. This
applies to mixed-format replication as well, since this enables
some updates to be replicated using the statement-based format.
However, it should be safe to use
--replicate-do-db
for this
purpose if you are using row-based replication only, since in
this case the currently selected database has no effect on the
option's operation.
For example, to support the separation as shown in
Figure 18.2, “Using Replication to Replicate Databases to Separate Replication Slaves”, you should
configure each replication slave as follows, before executing
START SLAVE
:
Replication slave 1 should use
--replicate-wild-do-table=databaseA.%
.
Replication slave 2 should use
--replicate-wild-do-table=databaseB.%
.
Replication slave 3 should use
--replicate-wild-do-table=databaseC.%
.
Each slave in this configuration receives the entire binary log
from the master, but executes only those events from the binary
log that apply to the databases and tables included by the
--replicate-wild-do-table
option in
effect on that slave.
If you have data that must be synchronized to the slaves before replication starts, you have a number of choices:
Synchronize all the data to each slave, and delete the databases, tables, or both that you do not want to keep.
Use mysqldump to create a separate dump file for each database and load the appropriate dump file on each slave.
Use a raw data file dump and include only the specific files and databases that you need for each slave.
This does not work with InnoDB
databases unless you use
innodb_file_per_table
.
As the number of slaves connecting to a master increases, the load, although minimal, also increases, as each slave uses a client connection to the master. Also, as each slave must receive a full copy of the master binary log, the network load on the master may also increase and create a bottleneck.
If you are using a large number of slaves connected to one master, and that master is also busy processing requests (for example, as part of a scale-out solution), then you may want to improve the performance of the replication process.
One way to improve the performance of the replication process is to create a deeper replication structure that enables the master to replicate to only one slave, and for the remaining slaves to connect to this primary slave for their individual replication requirements. A sample of this structure is shown in Figure 18.3, “Using an Additional Replication Host to Improve Performance”.
For this to work, you must configure the MySQL instances as follows:
Master 1 is the primary master where all changes and updates are written to the database. Binary logging should be enabled on this machine.
Master 2 is the slave to the Master 1 that provides the
replication functionality to the remainder of the slaves in
the replication structure. Master 2 is the only machine
permitted to connect to Master 1. Master 2 also has binary
logging enabled, and the
--log-slave-updates
option so
that replication instructions from Master 1 are also written
to Master 2's binary log so that they can then be replicated
to the true slaves.
Slave 1, Slave 2, and Slave 3 act as slaves to Master 2, and replicate the information from Master 2, which actually consists of the upgrades logged on Master 1.
The above solution reduces the client load and the network interface load on the primary master, which should improve the overall performance of the primary master when used as a direct database solution.
If your slaves are having trouble keeping up with the replication process on the master, there are a number of options available:
If possible, put the relay logs and the data files on
different physical drives. To do this, use the
--relay-log
option to specify
the location of the relay log.
If the slaves are significantly slower than the master, you may want to divide up the responsibility for replicating different databases to different slaves. See Section 18.3.5, “Replicating Different Databases to Different Slaves”.
If your master makes use of transactions and you are not
concerned about transaction support on your slaves, use
MyISAM
or another nontransactional engine
on the slaves. See
Section 18.3.3, “Using Replication with Different Master and Slave Storage Engines”.
If your slaves are not acting as masters, and you have a
potential solution in place to ensure that you can bring up a
master in the event of failure, then you can switch off
--log-slave-updates
. This
prevents “dumb” slaves from also logging events
they have executed into their own binary log.
When using replication with GTIDs (see Section 18.1.3, “Replication with Global Transaction Identifiers”), you can provide failover between master and slaves in the event of a failure using mysqlfailover, which is provided by the MySQL Utilities; see mysqlfailover — Automatic replication health monitoring and failover, for more information. If you are not using GTIDs and therefore cannot use mysqlfailover, you must set up a master and one or more slaves; then, you need to write an application or script that monitors the master to check whether it is up, and instructs the slaves and applications to change to another master in case of failure. This section discusses some of the issues encountered when setting up failover in this way.
You can tell a slave to change to a new master using the
CHANGE MASTER TO
statement. The
slave does not check whether the databases on the master are
compatible with those on the slave; it simply begins reading and
executing events from the specified coordinates in the new
master's binary log. In a failover situation, all the servers
in the group are typically executing the same events from the same
binary log file, so changing the source of the events should not
affect the structure or integrity of the database, provided that
you exercise care in making the change.
Slaves should be run with the
--log-bin
option, and if not using
GTIDs then they should also be run without
--log-slave-updates
. In this way,
the slave is ready to become a master without restarting the slave
mysqld. Assume that you have the structure
shown in Figure 18.4, “Redundancy Using Replication, Initial Structure”.
In this diagram, the MySQL Master
holds the
master database, the MySQL Slave
hosts are
replication slaves, and the Web Client
machines
are issuing database reads and writes. Web clients that issue only
reads (and would normally be connected to the slaves) are not
shown, as they do not need to switch to a new server in the event
of failure. For a more detailed example of a read/write scale-out
replication structure, see
Section 18.3.4, “Using Replication for Scale-Out”.
Each MySQL Slave (Slave 1
, Slave
2
, and Slave 3
) is a slave running
with --log-bin
and without
--log-slave-updates
. Because
updates received by a slave from the master are not logged in the
binary log unless
--log-slave-updates
is specified,
the binary log on each slave is empty initially. If for some
reason MySQL Master
becomes unavailable, you
can pick one of the slaves to become the new master. For example,
if you pick Slave 1
, all Web
Clients
should be redirected to Slave
1
, which writes the updates to its binary log.
Slave 2
and Slave 3
should
then replicate from Slave 1
.
The reason for running the slave without
--log-slave-updates
is to prevent
slaves from receiving updates twice in case you cause one of the
slaves to become the new master. If Slave 1
has
--log-slave-updates
enabled, it
writes any updates that it receives from Master
in its own binary log. This means that, when Slave
2
changes from Master
to
Slave 1
as its master, it may receive updates
from Slave 1
that it has already received from
Master
.
Make sure that all slaves have processed any statements in their
relay log. On each slave, issue STOP SLAVE
IO_THREAD
, then check the output of
SHOW PROCESSLIST
until you see
Has read all relay log
. When this is true for
all slaves, they can be reconfigured to the new setup. On the
slave Slave 1
being promoted to become the
master, issue STOP SLAVE
and
RESET MASTER
.
On the other slaves Slave 2
and Slave
3
, use STOP SLAVE
and
CHANGE MASTER TO MASTER_HOST='Slave1'
(where
'Slave1'
represents the real host name of
Slave 1
). To use CHANGE MASTER
TO
, add all information about how to connect to
Slave 1
from Slave 2
or
Slave 3
(user
,
password
,
port
). When issuing the CHANGE
MASTER TO
statement in this, there is no need to specify
the name of the Slave 1
binary log file or log
position to read from, since the first binary log file and
position 4, are the defaults. Finally, execute
START SLAVE
on Slave
2
and Slave 3
.
Once the new replication setup is in place, you need to tell each
Web Client
to direct its statements to
Slave 1
. From that point on, all updates
statements sent by Web Client
to Slave
1
are written to the binary log of Slave
1
, which then contains every update statement sent to
Slave 1
since Master
died.
The resulting server structure is shown in Figure 18.5, “Redundancy Using Replication, After Master Failure”.
When Master
becomes available again, you should
make it a slave of Slave 1
. To do this, issue
on Master
the same CHANGE
MASTER TO
statement as that issued on Slave
2
and Slave 3
previously.
Master
then becomes a slave of S1ave
1
and picks up the Web Client
writes
that it missed while it was offline.
To make Master
a master again, use the
preceding procedure as if Slave 1
was
unavailable and Master
was to be the new
master. During this procedure, do not forget to run
RESET MASTER
on
Master
before making Slave
1
, Slave 2
, and Slave
3
slaves of Master
. If you fail to do
this, the slaves may pick up stale writes from the Web
Client
applications dating from before the point at
which Master
became unavailable.
You should be aware that there is no synchronization between slaves, even when they share the same master, and thus some slaves might be considerably ahead of others. This means that in some cases the procedure outlined in the previous example might not work as expected. In practice, however, relay logs on all slaves should be relatively close together.
One way to keep applications informed about the location of the
master is to have a dynamic DNS entry for the master. With
bind
you can use nsupdate
to update the DNS dynamically.
To use a secure connection for encrypting the transfer of the binary log required during replication, both the master and the slave servers must support encrypted network connections. If either server does not support secure connections (because it has not been compiled or configured for them), replication through an encrypted connection is not possible.
Setting up secure connections for replication is similar to doing so for client/server connections. You must obtain (or create) a suitable security certificate that you can use on the master, and a similar certificate (from the same certificate authority) on each slave. You must also obtain suitable key files.
For more information on setting up a server and client for secure connections, see Section 7.4.4, “Configuring MySQL to Use Secure Connections”.
To enable secure connections on the master, you must create or
obtain suitable certificate and key files, and then add the
following configuration options to the master's configuration
within the [mysqld]
section of the master's
my.cnf
file, changing the file names as
necessary:
[mysqld] ssl-ca=cacert.pem ssl-cert=server-cert.pem ssl-key=server-key.pem
The paths to the files may be relative or absolute; we recommend that you always use complete paths for this purpose.
The options are as follows:
On the slave, there are two ways to specify the information
required for connecting securely to the master. You can either
name the slave certificate and key files in the
[client]
section of the slave's
my.cnf
file, or you can explicitly specify
that information using the CHANGE MASTER
TO
statement:
To name the slave certificate and key files using an option
file, add the following lines to the
[client]
section of the slave's
my.cnf
file, changing the file names as
necessary:
[client] ssl-ca=cacert.pem ssl-cert=client-cert.pem ssl-key=client-key.pem
Restart the slave server, using the
--skip-slave-start
option to
prevent the slave from connecting to the master. Use
CHANGE MASTER TO
to specify the
master configuration, using the MASTER_SSL
option to connect securely:
mysql>CHANGE MASTER TO
->MASTER_HOST='master_hostname',
->MASTER_USER='replicate',
->MASTER_PASSWORD='password',
->MASTER_SSL=1;
To specify the certificate and key names using the
CHANGE MASTER TO
statement,
append the appropriate
MASTER_SSL_
options:
xxx
mysql>CHANGE MASTER TO
->MASTER_HOST='master_hostname',
->MASTER_USER='replicate',
->MASTER_PASSWORD='password',
->MASTER_SSL=1,
->MASTER_SSL_CA = 'ca_file_name',
->MASTER_SSL_CAPATH = 'ca_directory_name',
->MASTER_SSL_CERT = 'cert_file_name',
->MASTER_SSL_KEY = 'key_file_name';
After the master information has been updated, start the slave replication process:
mysql> START SLAVE;
You can use the SHOW SLAVE STATUS
statement to confirm that a secure connection was established
successfully.
For more information on the CHANGE MASTER
TO
statement, see Section 14.4.2.1, “CHANGE MASTER TO Syntax”.
If you want to enforce the use of secure connections during
replication, create a user and use the REQUIRE
SSL
option, then grant that user the
REPLICATION SLAVE
privilege. For
example:
mysql>CREATE USER 'repl'@'%.mydomain.com' IDENTIFIED BY 'slavepass'
->REQUIRE SSL;
mysql>GRANT REPLICATION SLAVE ON *.*
->TO 'repl'@'%.mydomain.com';
If the account already exists, you can add REQUIRE
SSL
to it with this statement:
mysql> ALTER USER 'repl'@'%.mydomain.com' REQUIRE SSL;
In addition to the built-in asynchronous replication, MySQL 5.7 supports an interface to semisynchronous replication that is implemented by plugins. This section discusses what semisynchronous replication is and how it works. The following sections cover the administrative interface to semisynchronous replication and how to install, configure, and monitor it.
MySQL replication by default is asynchronous. The master writes events to its binary log but does not know whether or when a slave has retrieved and processed them. With asynchronous replication, if the master crashes, transactions that it has committed might not have been transmitted to any slave. Consequently, failover from master to slave in this case may result in failover to a server that is missing transactions relative to the master.
Semisynchronous replication can be used as an alternative to asynchronous replication:
A slave indicates whether it is semisynchronous-capable when it connects to the master.
If semisynchronous replication is enabled on the master side and there is at least one semisynchronous slave, a thread that performs a transaction commit on the master blocks and waits until at least one semisynchronous slave acknowledges that it has received all events for the transaction, or until a timeout occurs.
The slave acknowledges receipt of a transaction's events only after the events have been written to its relay log and flushed to disk.
If a timeout occurs without any slave having acknowledged the transaction, the master reverts to asynchronous replication. When at least one semisynchronous slave catches up, the master returns to semisynchronous replication.
Semisynchronous replication must be enabled on both the master and slave sides. If semisynchronous replication is disabled on the master, or enabled on the master but on no slaves, the master uses asynchronous replication.
While the master is blocking (waiting for acknowledgment from a slave), it does not return to the session that performed the transaction. When the block ends, the master returns to the session, which then can proceed to execute other statements. At this point, the transaction has committed on the master side, and receipt of its events has been acknowledged by at least one slave.
As of MySQL 5.7.3, the number of slave acknowledgments the master
must receive per transaction before proceeding is configurable
using the
rpl_semi_sync_master_wait_for_slave_count
system variable. The default value is 1.
Blocking also occurs after rollbacks that are written to the binary log, which occurs when a transaction that modifies nontransactional tables is rolled back. The rolled-back transaction is logged even though it has no effect for transactional tables because the modifications to the nontransactional tables cannot be rolled back and must be sent to slaves.
For statements that do not occur in transactional context (that
is, when no transaction has been started with
START
TRANSACTION
or
SET autocommit =
0
), autocommit is enabled and each statement commits
implicitly. With semisynchronous replication, the master blocks
for each such statement, just as it does for explicit transaction
commits.
To understand what the “semi” in “semisynchronous replication” means, compare it with asynchronous and fully synchronous replication:
With asynchronous replication, the master writes events to its binary log and slaves request them when they are ready. There is no guarantee that any event will ever reach any slave.
With fully synchronous replication, when a master commits a transaction, all slaves also will have committed the transaction before the master returns to the session that performed the transaction. The drawback of this is that there might be a lot of delay to complete a transaction.
Semisynchronous replication falls between asynchronous and fully synchronous replication. The master waits only until at least one slave has received and logged the events. It does not wait for all slaves to acknowledge receipt, and it requires only receipt, not that the events have been fully executed and committed on the slave side.
Compared to asynchronous replication, semisynchronous replication
provides improved data integrity because when a commit returns
successfully, it is known that the data exists in at least two
places. Until a semisynchronous master receives acknowledgment
from the number of slaves configured by
rpl_semi_sync_master_wait_for_slave_count
,
the transaction is on hold and not committed.
Semisynchronous replication also places a rate limit on busy sessions by constraining the speed at which binary log events can be sent from master to slave. When one user is too busy, this will slow it down, which is useful in some deployment situations.
Semisynchronous replication does have some performance impact because commits are slower due to the need to wait for slaves. This is the tradeoff for increased data integrity. The amount of slowdown is at least the TCP/IP roundtrip time to send the commit to the slave and wait for the acknowledgment of receipt by the slave. This means that semisynchronous replication works best for close servers communicating over fast networks, and worst for distant servers communicating over slow networks.
The
rpl_semi_sync_master_wait_point
system variable controls the point at which a semisynchronous
replication master waits for slave acknowledgment of transaction
receipt before returning a status to the client that committed the
transaction. These values are permitted:
AFTER_SYNC
(the default): The master writes
each transaction to its binary log and the slave, and syncs
the binary log to disk. The master waits for slave
acknowledgment of transaction receipt after the sync. Upon
receiving acknowledgment, the master commits the transaction
to the storage engine and returns a result to the client,
which then can proceed.
AFTER_COMMIT
: The master writes each
transaction to its binary log and the slave, syncs the binary
log, and commits the transaction to the storage engine. The
master waits for slave acknowledgment of transaction receipt
after the commit. Upon receiving acknowledgment, the master
returns a result to the client, which then can proceed.
The replication characteristics of these settings differ as follows:
With AFTER_SYNC
, all clients see the
committed transaction at the same time: After it has been
acknowledged by the slave and committed to the storage engine
on the master. Thus, all clients see the same data on the
master.
In the event of master failure, all transactions committed on the master have been replicated to the slave (saved to its relay log). A crash of the master and failover to the slave is lossless because the slave is up to date.
With AFTER_COMMIT
, the client issuing the
transaction gets a return status only after the server commits
to the storage engine and receives slave acknowledgment. After
the commit and before slave acknowledgment, other clients can
see the committed transaction before the committing client.
If something goes wrong such that the slave does not process the transaction, then in the event of a master crash and failover to the slave, it is possible that such clients will see a loss of data relative to what they saw on the master.
The administrative interface to semisynchronous replication has several components:
Two plugins implement semisynchronous capability. There is one plugin for the master side and one for the slave side.
System variables control plugin behavior. Some examples:
Controls whether semisynchronous replication is enabled on the master. To enable or disable the plugin, set this variable to 1 or 0, respectively. The default is 0 (off).
A value in milliseconds that controls how long the master waits on a commit for acknowledgment from a slave before timing out and reverting to asynchronous replication. The default value is 10000 (10 seconds).
Similar to
rpl_semi_sync_master_enabled
,
but controls the slave plugin.
All
rpl_semi_sync_
system variables are described at
Section 6.1.5, “Server System Variables”.
xxx
Status variables enable semisynchronous replication monitoring. Some examples:
The number of semisynchronous slaves.
Whether semisynchronous replication currently is operational on the master. The value is 1 if the plugin has been enabled and a commit acknowledgment has not occurred. It is 0 if the plugin is not enabled or the master has fallen back to asynchronous replication due to commit acknowledgment timeout.
The number of commits that were not acknowledged successfully by a slave.
The number of commits that were acknowledged successfully by a slave.
Whether semisynchronous replication currently is operational on the slave. This is 1 if the plugin has been enabled and the slave I/O thread is running, 0 otherwise.
All
Rpl_semi_sync_
status variables are described at
Section 6.1.7, “Server Status Variables”.
xxx
The system and status variables are available only if the
appropriate master or slave plugin has been installed with
INSTALL PLUGIN
.
Semisynchronous replication is implemented using plugins, so the plugins must be installed into the server to make them available. After a plugin has been installed, you control it by means of the system variables associated with it. These system variables are unavailable until the associated plugin has been installed.
This section describes how to install the semisynchronous replication plugins. For general information about installing plugins, see Section 6.5.2, “Installing and Uninstalling Plugins”.
To use semisynchronous replication, the following requirements must be satisfied:
MySQL 5.5 or higher must be installed.
The capability of installing plugins requires a MySQL server
that supports dynamic loading. To verify this, check that
the value of the
have_dynamic_loading
system
variable is YES
. Binary distributions
should support dynamic loading.
Replication must already be working, see Section 18.1, “Configuring Replication”.
There must not be multiple replication channels configured. Semisynchronous replication is only compatible with the default replication channel. See Section 18.2.3, “Replication Channels”.
To set up semisynchronous replication, use the following
instructions. The INSTALL PLUGIN
,
SET
GLOBAL
, STOP SLAVE
, and
START SLAVE
statements mentioned
here require the SUPER
privilege.
MySQL distributions include semisynchronous replication plugin files for the master side and the slave side.
To be usable by a master or slave server, the appropriate plugin
library file must be located in the MySQL plugin directory (the
directory named by the
plugin_dir
system variable). If
necessary, set the value of
plugin_dir
at server startup to
tell the server the plugin directory location.
The plugin library file base names are
semisync_master
and
semisync_slave
. The file name suffix differs
per platform (for example, .so
for Unix and
Unix-like systems, .dll
for Windows).
The master plugin library file must be present in the plugin directory of the master server. The slave plugin library file must be present in the plugin directory of each slave server.
To load the plugins, use the INSTALL
PLUGIN
statement on the master and on each slave that
is to be semisynchronous (adjust the .so
suffix for your platform as necessary).
On the master:
INSTALL PLUGIN rpl_semi_sync_master SONAME 'semisync_master.so';
On each slave:
INSTALL PLUGIN rpl_semi_sync_slave SONAME 'semisync_slave.so';
If an attempt to install a plugin results in an error on Linux
similar to that shown here, you must install
libimf
:
mysql> INSTALL PLUGIN rpl_semi_sync_master SONAME 'semisync_master.so';
ERROR 1126 (HY000): Can't open shared library
'/usr/local/mysql/lib/plugin/semisync_master.so'
(errno: 22 libimf.so: cannot open shared object file:
No such file or directory)
You can obtain libimf
from
http://dev.mysql.com/downloads/os-linux.html.
To see which plugins are installed, use the
SHOW PLUGINS
statement, or query
the INFORMATION_SCHEMA.PLUGINS
table.
To verify plugin installation, examine the
INFORMATION_SCHEMA.PLUGINS
table or
use the SHOW PLUGINS
statement
(see Section 6.5.3, “Obtaining Server Plugin Information”). For
example:
mysql>SELECT PLUGIN_NAME, PLUGIN_STATUS FROM INFORMATION_SCHEMA.PLUGINS
->WHERE PLUGIN_NAME LIKE '%semi%';
+----------------------+---------------+ | PLUGIN_NAME | PLUGIN_STATUS | +----------------------+---------------+ | rpl_semi_sync_master | ACTIVE | +----------------------+---------------+
After a semisynchronous replication plugin has been installed, it is disabled by default. The plugins must be enabled both on the master side and the slave side to enable semisynchronous replication. If only one side is enabled, replication will be asynchronous.
To control whether an installed plugin is enabled, set the
appropriate system variables. You can set these variables at
runtime using SET
GLOBAL
, or at server startup on the command line or in
an option file.
At runtime, these master-side system variables are available:
SET GLOBAL rpl_semi_sync_master_enabled = {0|1};
SET GLOBAL rpl_semi_sync_master_timeout = N
;
On the slave side, this system variable is available:
SET GLOBAL rpl_semi_sync_slave_enabled = {0|1};
For
rpl_semi_sync_master_enabled
or
rpl_semi_sync_slave_enabled
,
the value should be 1 to enable semisynchronous replication or 0
to disable it. By default, these variables are set to 0.
For
rpl_semi_sync_master_timeout
,
the value N
is given in milliseconds.
The default value is 10000 (10 seconds).
If you enable semisynchronous replication on a slave at runtime, you must also start the slave I/O thread (stopping it first if it is already running) to cause the slave to connect to the master and register as a semisynchronous slave:
STOP SLAVE IO_THREAD; START SLAVE IO_THREAD;
If the I/O thread is already running and you do not restart it, the slave continues to use asynchronous replication.
At server startup, the variables that control semisynchronous
replication can be set as command-line options or in an option
file. A setting listed in an option file takes effect each time
the server starts. For example, you can set the variables in
my.cnf
files on the master and slave sides
as follows.
On the master:
[mysqld] rpl_semi_sync_master_enabled=1 rpl_semi_sync_master_timeout=1000 # 1 second
On each slave:
[mysqld] rpl_semi_sync_slave_enabled=1
The plugins for the semisynchronous replication capability expose several system and status variables that you can examine to determine its configuration and operational state.
The system variable reflect how semisynchronous replication is
configured. To check their values, use SHOW
VARIABLES
:
mysql> SHOW VARIABLES LIKE 'rpl_semi_sync%';
The status variables enable you to monitor the operation of
semisynchronous replication. To check their values, use
SHOW STATUS
:
mysql> SHOW STATUS LIKE 'Rpl_semi_sync%';
When the master switches between asynchronous or semisynchronous
replication due to commit-blocking timeout or a slave catching
up, it sets the value of the
Rpl_semi_sync_master_status
status variable appropriately. Automatic fallback from
semisynchronous to asynchronous replication on the master means
that it is possible for the
rpl_semi_sync_master_enabled
system variable to have a value of 1 on the master side even
when semisynchronous replication is in fact not operational at
the moment. You can monitor the
Rpl_semi_sync_master_status
status variable to determine whether the master currently is
using asynchronous or semisynchronous replication.
To see how many semisynchronous slaves are connected, check
Rpl_semi_sync_master_clients
.
The number of commits that have been acknowledged successfully
or unsuccessfully by slaves are indicated by the
Rpl_semi_sync_master_yes_tx
and Rpl_semi_sync_master_no_tx
variables.
On the slave side,
Rpl_semi_sync_slave_status
indicates whether semisynchronous replication currently is
operational.
MySQL 5.7 supports delayed replication such that a
slave server deliberately lags behind the master by at least a
specified amount of time. The default delay is 0 seconds. Use the
MASTER_DELAY
option for
CHANGE MASTER TO
to set the delay
to N
seconds:
CHANGE MASTER TO MASTER_DELAY = N
;
An event received from the master is not executed until at least
N
seconds later than its execution on
the master. The exceptions are that there is no delay for format
description events or log file rotation events, which affect only
the internal state of the SQL thread.
Delayed replication can be used for several purposes:
To protect against user mistakes on the master. A DBA can roll back a delayed slave to the time just before the disaster.
To test how the system behaves when there is a lag. For example, in an application, a lag might be caused by a heavy load on the slave. However, it can be difficult to generate this load level. Delayed replication can simulate the lag without having to simulate the load. It can also be used to debug conditions related to a lagging slave.
To inspect what the database looked like long ago, without having to reload a backup. For example, if the delay is one week and the DBA needs to see what the database looked like before the last few days' worth of development, the delayed slave can be inspected.
START SLAVE
and
STOP SLAVE
take effect immediately
and ignore any delay. RESET SLAVE
resets the delay to 0.
SHOW SLAVE STATUS
has three fields
that provide information about the delay:
SQL_Delay
: A nonnegative integer indicating
the number of seconds that the slave must lag the master.
SQL_Remaining_Delay
: When
Slave_SQL_Running_State
is Waiting
until MASTER_DELAY seconds after master executed
event
, this field contains an integer indicating the
number of seconds left of the delay. At other times, this
field is NULL
.
Slave_SQL_Running_State
: A string
indicating the state of the SQL thread (analogous to
Slave_IO_State
). The value is identical to
the State
value of the SQL thread as
displayed by SHOW PROCESSLIST
.
When the slave SQL thread is waiting for the delay to elapse
before executing an event, SHOW
PROCESSLIST
displays its State
value
as Waiting until MASTER_DELAY seconds after master
executed event
.
The following sections provide information about what is supported and what is not in MySQL replication, and about specific issues and situations that may occur when replicating certain statements.
Statement-based replication depends on compatibility at the SQL level between the master and slave. In others, successful SBR requires that any SQL features used be supported by both the master and the slave servers. For example, if you use a feature on the master server that is available only in MySQL 5.7 (or later), you cannot replicate to a slave that uses MySQL 5.6 (or earlier).
Such incompatibilities also can occur within a release series when
using pre-production releases of MySQL. For example, the
SLEEP()
function is available
beginning with MySQL 5.0.12. If you use this function on the
master, you cannot replicate to a slave that uses MySQL 5.0.11 or
earlier.
For this reason, use Generally Available (GA) releases of MySQL for statement-based replication in a production setting, since we do not introduce new SQL statements or change their behavior within a given release series once that series reaches GA release status.
If you are planning to use statement-based replication between MySQL 5.7 and a previous MySQL release series, it is also a good idea to consult the edition of the MySQL Reference Manual corresponding to the earlier release series for information regarding the replication characteristics of that series.
With MySQL's statement-based replication, there may be issues with replicating stored routines or triggers. You can avoid these issues by using MySQL's row-based replication instead. For a detailed list of issues, see Section 23.7, “Binary Logging of Stored Programs”. For more information about row-based logging and row-based replication, see Section 6.4.4.1, “Binary Logging Formats”, and Section 18.2.1, “Replication Formats”.
For additional information specific to replication and
InnoDB
, see
Section 15.19, “InnoDB and MySQL Replication”. For information
relating to replication with MySQL Cluster, see
Section 21.6, “NDB Cluster Replication”.
Statement-based replication of
AUTO_INCREMENT
,
LAST_INSERT_ID()
, and
TIMESTAMP
values is done
correctly, subject to the following exceptions:
When using statement-based replication prior to MySQL 5.7.1,
AUTO_INCREMENT
columns in tables on the
slave must match the same columns on the master; that is,
AUTO_INCREMENT
columns must be replicated
to AUTO_INCREMENT
columns.
A statement invoking a trigger or function that causes an
update to an AUTO_INCREMENT
column is not
replicated correctly using statement-based replication. In
MySQL 5.7, such statements are marked as
unsafe. (Bug #45677)
An INSERT
into a table that
has a composite primary key that includes an
AUTO_INCREMENT
column that is not the
first column of this composite key is not safe for
statement-based logging or replication. In MySQL
5.7 and later, such statements are marked as
unsafe. (Bug #11754117, Bug #45670)
This issue does not affect tables using the
InnoDB
storage engine, since an
InnoDB
table with an
AUTO_INCREMENT
column requires at least one key where the auto-increment
column is the only or leftmost column.
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 a
table t1
that has columns
col1
and col2
, 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;
To guarantee the same ordering on both master and slave,
the ORDER BY
clause must name
all columns of t1
.
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;
The BLACKHOLE
storage engine
accepts data but discards it and does not store it. When
performing binary logging, all inserts to such tables are always
logged, regardless of the logging format in use. Updates and
deletes are handled differently depending on whether statement
based or row based logging is in use. With the statement based
logging format, all statements affecting
BLACKHOLE
tables are logged, but their
effects ignored. When using row-based logging, updates and
deletes to such tables are simply skipped—they are not
written to the binary log. In MySQL 5.7.2 and later, a warning
is logged whenever this occurs (Bug #13004581)
For this reason we recommend when you replicate to tables using
the BLACKHOLE
storage engine that
you have the binlog_format
server variable set to STATEMENT
, and not to
either ROW
or MIXED
.
The following applies to replication between MySQL servers that use different character sets:
If the master has databases with a character set different
from the global
character_set_server
value,
you should design your CREATE
TABLE
statements so that they do not implicitly
rely on the database default character set. A good
workaround is to state the character set and collation
explicitly in CREATE TABLE
statements.
CHECKSUM TABLE
returns a checksum
that is calculated row by row, using a method that depends on
the table row storage format, which is not guaranteed to remain
the same between MySQL release series. For example, the storage
format for temporal types such as
TIME
,
DATETIME
, and
TIMESTAMP
changed in MySQL 5.6
prior to MySQL 5.6.5, so if a 5.5 table is upgraded to MySQL
5.6, the checksum value may change.
MySQL applies these rules when various CREATE ... IF
NOT EXISTS
statements are replicated:
Every
CREATE
DATABASE IF NOT EXISTS
statement is replicated,
whether or not the database already exists on the master.
Similarly, every
CREATE TABLE
IF NOT EXISTS
statement without a
SELECT
is replicated, whether
or not the table already exists on the master. This includes
CREATE
TABLE IF NOT EXISTS ... LIKE
. Replication of
CREATE
TABLE IF NOT EXISTS ... SELECT
follows somewhat
different rules; see
Section 18.4.1.6, “Replication of CREATE TABLE ... SELECT Statements”, for
more information.
CREATE EVENT
IF NOT EXISTS
is always replicated in MySQL
5.7, whether or not the event named in the
statement already exists on the master.
See also Bug #45574.
This section discusses how MySQL replicates
CREATE
TABLE ... SELECT
statements.
MySQL 5.7 does not allow a
CREATE
TABLE ... SELECT
statement to make any changes in
tables other than the table that is created by the statement.
Some older versions of MySQL permitted these statements to do
so; this means that, when using statement-based replication
between a MySQL 5.6 or later slave and a master running a
previous version of MySQL, a
CREATE
TABLE ... SELECT
statement causing changes in other
tables on the master fails on the slave, causing replication to
stop. To prevent this from happening, you should use row-based
replication, rewrite the offending statement before running it
on the master, or upgrade the master to MySQL 5.7.
(If you choose to upgrade the master, keep in mind that such a
CREATE
TABLE ... SELECT
statement fails following the upgrade
unless it is rewritten to remove any side effects on other
tables.) This is not an issue when using row-based replication,
because the statement is logged as a CREATE
TABLE
statement with any changes to table data logged
as row-insert events, rather than as the entire
CREATE
TABLE ... SELECT
.
These behaviors are not dependent on MySQL version:
CREATE
TABLE ... SELECT
always performs an implicit
commit (Section 14.3.3, “Statements That Cause an Implicit Commit”).
If destination table does not exist, logging occurs as
follows. It does not matter whether IF NOT
EXISTS
is present.
STATEMENT
or MIXED
format: The statement is logged as written.
ROW
format: The statement is logged
as a CREATE TABLE
statement followed by a series of insert-row events.
If the statement fails, nothing is logged. This includes the
case that the destination table exists and IF NOT
EXISTS
is not given.
When the destination table exists and IF NOT
EXISTS
is given, MySQL 5.7 ignores the
statement completely; nothing is inserted or logged. The
handling of such statements in this regard has changed
considerably in previous MySQL releases; if you are replicating
from a MySQL 5.5.6 or older master to a newer slave, see
Replication of CREATE ... IF NOT EXISTS Statements,
for more information.
In MySQL 5.7, the statements
CREATE SERVER
,
ALTER SERVER
, and
DROP SERVER
are not written to
the binary log, regardless of the binary logging format that is
in use.
The following statements support use of the
CURRENT_USER()
function to take
the place of the name of (and, possibly, the host for) an
affected user or a definer; in such cases,
CURRENT_USER()
is expanded where
and as needed:
When CURRENT_USER()
or
CURRENT_USER
is used as the
definer in any of the statements CREATE
FUNCTION
, CREATE
PROCEDURE
, CREATE
TRIGGER
, CREATE EVENT
,
CREATE VIEW
, or
ALTER VIEW
when binary logging is
enabled, the function reference is expanded before it is written
to the binary log, so that the statement refers to the same user
on both the master and the slave when the statement is
replicated. CURRENT_USER()
or
CURRENT_USER
is also expanded
prior to being written to the binary log when used in
DROP USER
,
RENAME USER
,
GRANT
,
REVOKE
, or
ALTER EVENT
.
The DROP DATABASE
IF EXISTS
,
DROP TABLE IF
EXISTS
, and
DROP VIEW IF
EXISTS
statements are always replicated, even if the
database, table, or view to be dropped does not exist on the
master. This is to ensure that the object to be dropped no
longer exists on either the master or the slave, once the slave
has caught up with the master.
DROP ... IF EXISTS
statements for stored
programs (stored procedures and functions, triggers, and events)
are also replicated, even if the stored program to be dropped
does not exist on the master.
Source and target tables for replication do not have to be identical. A table on the master can have more or fewer columns than the slave's copy of the table. In addition, corresponding table columns on the master and the slave can use different data types, subject to certain conditions.
Replication between tables which are partitioned differently from one another is not supported. See Section 18.4.1.19, “Replication and Partitioning”.
In all cases where the source and target tables do not have identical definitions, the database and table names must be the same on both the master and the slave. Additional conditions are discussed, with examples, in the following two sections.
You can replicate a table from the master to the slave such that the master and slave copies of the table have differing numbers of columns, subject to the following conditions:
Columns common to both versions of the table must be defined in the same order on the master and the slave.
(This is true even if both tables have the same number of columns.)
Columns common to both versions of the table must be defined before any additional columns.
This means that executing an ALTER
TABLE
statement on the slave where a new column
is inserted into the table within the range of columns
common to both tables causes replication to fail, as shown
in the following example:
Suppose that a table t
, existing on the
master and the slave, is defined by the following
CREATE TABLE
statement:
CREATE TABLE t ( c1 INT, c2 INT, c3 INT );
Suppose that the ALTER
TABLE
statement shown here is executed on the
slave:
ALTER TABLE t ADD COLUMN cnew1 INT AFTER c3;
The previous ALTER TABLE
is
permitted on the slave because the columns
c1
, c2
, and
c3
that are common to both versions of
table t
remain grouped together in both
versions of the table, before any columns that differ.
However, the following ALTER
TABLE
statement cannot be executed on the slave
without causing replication to break:
ALTER TABLE t ADD COLUMN cnew2 INT AFTER c2;
Replication fails after execution on the slave of the
ALTER TABLE
statement just
shown, because the new column cnew2
comes between columns common to both versions of
t
.
Each “extra” column in the version of the table having more columns must have a default value.
A column's default value is determined by a number of
factors, including its type, whether it is defined with a
DEFAULT
option, whether it is declared
as NULL
, and the server SQL mode in
effect at the time of its creation; for more information,
see Section 12.7, “Data Type Default Values”).
In addition, when the slave's copy of the table has more columns than the master's copy, each column common to the tables must use the same data type in both tables.
Examples. The following examples illustrate some valid and invalid table definitions:
More columns on the master. The following table definitions are valid and replicate correctly:
master>CREATE TABLE t1 (c1 INT, c2 INT, c3 INT);
slave>CREATE TABLE t1 (c1 INT, c2 INT);
The following table definitions would raise an error because the definitions of the columns common to both versions of the table are in a different order on the slave than they are on the master:
master>CREATE TABLE t1 (c1 INT, c2 INT, c3 INT);
slave>CREATE TABLE t1 (c2 INT, c1 INT);
The following table definitions would also raise an error because the definition of the extra column on the master appears before the definitions of the columns common to both versions of the table:
master>CREATE TABLE t1 (c3 INT, c1 INT, c2 INT);
slave>CREATE TABLE t1 (c1 INT, c2 INT);
More columns on the slave. The following table definitions are valid and replicate correctly:
master>CREATE TABLE t1 (c1 INT, c2 INT);
slave>CREATE TABLE t1 (c1 INT, c2 INT, c3 INT);
The following definitions raise an error because the columns common to both versions of the table are not defined in the same order on both the master and the slave:
master>CREATE TABLE t1 (c1 INT, c2 INT);
slave>CREATE TABLE t1 (c2 INT, c1 INT, c3 INT);
The following table definitions also raise an error because the definition for the extra column in the slave's version of the table appears before the definitions for the columns which are common to both versions of the table:
master>CREATE TABLE t1 (c1 INT, c2 INT);
slave>CREATE TABLE t1 (c3 INT, c1 INT, c2 INT);
The following table definitions fail because the slave's
version of the table has additional columns compared to the
master's version, and the two versions of the table use
different data types for the common column
c2
:
master>CREATE TABLE t1 (c1 INT, c2 BIGINT);
slave>CREATE TABLE t1 (c1 INT, c2 INT, c3 INT);
Corresponding columns on the master's and the slave's copies of the same table ideally should have the same data type. However, this is not always strictly enforced, as long as certain conditions are met.
It is usually possible to replicate from a column of a given
data type to another column of the same type and same size or
width, where applicable, or larger. For example, you can
replicate from a CHAR(10)
column to another
CHAR(10)
, or from a
CHAR(10)
column to a
CHAR(25)
column without any problems. In
certain cases, it also possible to replicate from a column
having one data type (on the master) to a column having a
different data type (on the slave); when the data type of the
master's version of the column is promoted to a type that
is the same size or larger on the slave, this is known as
attribute promotion.
Attribute promotion can be used with both statement-based and row-based replication, and is not dependent on the storage engine used by either the master or the slave. However, the choice of logging format does have an effect on the type conversions that are permitted; the particulars are discussed later in this section.
Whether you use statement-based or row-based replication, the slave's copy of the table cannot contain more columns than the master's copy if you wish to employ attribute promotion.
Statement-based replication.
When using statement-based replication, a simple rule of
thumb to follow is, “If the statement run on the
master would also execute successfully on the slave, it
should also replicate successfully”. In other words,
if the statement uses a value that is compatible with the
type of a given column on the slave, the statement can be
replicated. For example, you can insert any value that fits
in a TINYINT
column into a
BIGINT
column as well; it follows that,
even if you change the type of a TINYINT
column in the slave's copy of a table to
BIGINT
, any insert into that column on
the master that succeeds should also succeed on the slave,
since it is impossible to have a legal
TINYINT
value that is large enough to
exceed a BIGINT
column.
Prior to MySQL 5.7.1, when using statement-based replication,
AUTO_INCREMENT
columns were required to be
the same on both the master and the slave; otherwise, updates
could be applied to the wrong table on the slave. (Bug
#12669186)
Row-based replication: attribute promotion and demotion. Row-based replication in MySQL 5.7 supports attribute promotion and demotion between smaller data types and larger types. It is also possible to specify whether or not to permit lossy (truncated) or non-lossy conversions of demoted column values, as explained later in this section.
Lossy and non-lossy conversions. In the event that the target type cannot represent the value being inserted, a decision must be made on how to handle the conversion. If we permit the conversion but truncate (or otherwise modify) the source value to achieve a “fit” in the target column, we make what is known as a lossy conversion. A conversion which does not require truncation or similar modifications to fit the source column value in the target column is a non-lossy conversion.
Type conversion modes (slave_type_conversions variable).
The setting of the slave_type_conversions
global server variable controls the type conversion mode
used on the slave. This variable takes a set of values from
the following table, which shows the effects of each mode on
the slave's type-conversion behavior:
Mode | Effect |
---|---|
ALL_LOSSY | In this mode, type conversions that would mean loss of information are permitted.
This does not imply that non-lossy conversions are
permitted, merely that only cases requiring either
lossy conversions or no conversion at all are
permitted; for example, enabling
only this mode permits an
|
ALL_NON_LOSSY | This mode permits conversions that do not require truncation or other special handling of the source value; that is, it permits conversions where the target type has a wider range than the source type.
Setting this mode has no bearing on whether lossy
conversions are permitted; this is controlled with
the |
ALL_LOSSY,ALL_NON_LOSSY | When this mode is set, all supported type conversions are permitted, whether or not they are lossy conversions. |
ALL_SIGNED | Treat promoted integer types as signed values (the default behavior). |
ALL_UNSIGNED | Treat promoted integer types as unsigned values. |
ALL_SIGNED,ALL_UNSIGNED | Treat promoted integer types as signed if possible, otherwise as unsigned. |
[empty] |
When This mode is the default. |
When an integer type is promoted, its signedness is not
preserved. By default, the slave treats all such values as
signed. Beginning with MySQL 5.7.2, you can control this
behavior using ALL_SIGNED
,
ALL_UNSIGNED
, or both. (Bug#15831300)
ALL_SIGNED
tells the slave to treat all
promoted integer types as signed;
ALL_UNSIGNED
instructs it to treat these as
unsigned. Specifying both causes the slave to treat the value
as signed if possible, otherwise to treat it as unsigned; the
order in which they are listed is not significant. Neither
ALL_SIGNED
nor
ALL_UNSIGNED
has any effect if at least one
of ALL_LOSSY
or
ALL_NONLOSSY
is not also used.
Changing the type conversion mode requires restarting the
slave with the new slave_type_conversions
setting.
Supported conversions. Supported conversions between different but similar data types are shown in the following list:
Between any of the integer types
TINYINT
,
SMALLINT
,
MEDIUMINT
,
INT
, and
BIGINT
.
This includes conversions between the signed and unsigned versions of these types.
Lossy conversions are made by truncating the source value
to the maximum (or minimum) permitted by the target
column. For ensuring non-lossy conversions when going from
unsigned to signed types, the target column must be large
enough to accommodate the range of values in the source
column. For example, you can demote TINYINT
UNSIGNED
non-lossily to
SMALLINT
, but not to
TINYINT
.
Between any of the decimal types
DECIMAL
,
FLOAT
,
DOUBLE
, and
NUMERIC
.
FLOAT
to DOUBLE
is a
non-lossy conversion; DOUBLE
to
FLOAT
can only be handled lossily. A
conversion from
DECIMAL(
to
M
,D
)DECIMAL(
where M'
,D'
)
and
D'
>=
D
(
)
is non-lossy; for any case where
M'
-D'
)
>=
(M
-D
,
M'
<
M
, or both, only a
lossy conversion can be made.
D'
<
D
For any of the decimal types, if a value to be stored cannot be fit in the target type, the value is rounded down according to the rounding rules defined for the server elsewhere in the documentation. See Section 13.21.4, “Rounding Behavior”, for information about how this is done for decimal types.
Between any of the string types
CHAR
,
VARCHAR
, and
TEXT
, including conversions
between different widths.
Conversion of a CHAR
,
VARCHAR
, or TEXT
to
a CHAR
, VARCHAR
, or
TEXT
column the same size or larger is
never lossy. Lossy conversion is handled by inserting only
the first N
characters of the
string on the slave, where N
is
the width of the target column.
Replication between columns using different character sets is not supported.
Between any of the binary data types
BINARY
,
VARBINARY
, and
BLOB
, including conversions
between different widths.
Conversion of a BINARY
,
VARBINARY
, or BLOB
to a BINARY
,
VARBINARY
, or BLOB
column the same size or larger is never lossy. Lossy
conversion is handled by inserting only the first
N
bytes of the string on the
slave, where N
is the width of
the target column.
Between any 2 BIT
columns
of any 2 sizes.
When inserting a value from a
BIT(
column into a
M
)BIT(
column, where M'
)
, the most
significant bits of the
M'
>
M
BIT(
columns are cleared (set to zero) and the
M'
)M
bits of the
BIT(
value
are set as the least significant bits of the
M
)BIT(
column.
M'
)
When inserting a value from a source
BIT(
column into a target
M
)BIT(
column, where M'
)
, the maximum
possible value for the
M'
<
M
BIT(
column is assigned; in other words, an
“all-set” value is assigned to the target
column.
M'
)
Conversions between types not in the previous list are not permitted.
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 file system or if it exists but is not accessible to
the slave server. This can be overridden by using the
NO_DIR_IN_CREATE
server SQL
mode on the slave, which causes the slave to ignore 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.
For more information, see Section 6.1.8, “Server SQL Modes”.
Replication of invoked features such as user-defined functions (UDFs) and stored programs (stored procedures and functions, triggers, and events) provides the following characteristics:
The effects of the feature are always replicated.
The following statements are replicated using statement-based replication:
However, the effects of features created, modified, or dropped using these statements are replicated using row-based replication.
Attempting to replicate invoked features using statement-based replication produces the warning Statement is not safe to log in statement format. For example, trying to replicate a UDF with statement-based replication generates this warning because it currently cannot be determined by the MySQL server whether the UDF is deterministic. If you are absolutely certain that the invoked feature's effects are deterministic, you can safely disregard such warnings.
In the case of CREATE EVENT
and ALTER EVENT
:
The status of the event is set to
SLAVESIDE_DISABLED
on the slave
regardless of the state specified (this does not apply
to DROP EVENT
).
The master on which the event was created is identified
on the slave by its server ID. The
ORIGINATOR
column in
INFORMATION_SCHEMA.EVENTS
and the originator
column in
mysql.event
store this information.
See Section 24.7, “The INFORMATION_SCHEMA EVENTS Table”, and
Section 14.7.5.18, “SHOW EVENTS Syntax”, for more information.
The feature implementation resides on the slave in a renewable state so that if the master fails, the slave can be used as the master without loss of event processing.
To determine whether there are any scheduled events on a MySQL
server that were created on a different server (that was acting
as a replication master), query the
INFORMATION_SCHEMA.EVENTS
table in
a manner similar to what is shown here:
SELECT EVENT_SCHEMA, EVENT_NAME FROM INFORMATION_SCHEMA.EVENTS WHERE STATUS = 'SLAVESIDE_DISABLED';
Alternatively, you can use the SHOW
EVENTS
statement, like this:
SHOW EVENTS WHERE STATUS = 'SLAVESIDE_DISABLED';
When promoting a replication slave having such events to a
replication master, you must enable each event using
ALTER EVENT
, where
event_name
ENABLEevent_name
is the name of the event.
If more than one master was involved in creating events on this
slave, and you wish to identify events that were created only on
a given master having the server ID
master_id
, modify the previous query
on the EVENTS
table to include the
ORIGINATOR
column, as shown here:
SELECT EVENT_SCHEMA, EVENT_NAME, ORIGINATOR
FROM INFORMATION_SCHEMA.EVENTS
WHERE STATUS = 'SLAVESIDE_DISABLED'
AND ORIGINATOR = 'master_id
'
You can employ ORIGINATOR
with the
SHOW EVENTS
statement in a
similar fashion:
SHOW EVENTS
WHERE STATUS = 'SLAVESIDE_DISABLED'
AND ORIGINATOR = 'master_id
'
Before enabling events that were replicated from the master, you
should disable the MySQL Event Scheduler on the slave (using a
statement such as SET GLOBAL event_scheduler =
OFF;
), run any necessary ALTER
EVENT
statements, restart the server, then re-enable
the Event Scheduler on the slave afterward (using a statement
such as SET GLOBAL event_scheduler = ON;
)-
If you later demote the new master back to being a replication
slave, you must disable manually all events enabled by the
ALTER EVENT
statements. You can
do this by storing in a separate table the event names from the
SELECT
statement shown
previously, or using ALTER EVENT
statements to rename the events with a common prefix such as
replicated_
to identify them.
If you rename the events, then when demoting this server back to
being a replication slave, you can identify the events by
querying the EVENTS
table, as shown
here:
SELECT CONCAT(EVENT_SCHEMA, '.', EVENT_NAME) AS 'Db.Event' FROM INFORMATION_SCHEMA.EVENTS WHERE INSTR(EVENT_NAME, 'replicated_') = 1;
With statement-based replication, values are converted from decimal to binary. Because conversions between decimal and binary representations of them may be approximate, comparisons involving floating-point values are inexact. This is true for operations that use floating-point values explicitly, or that use 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 13.2, “Type Conversion in Expression Evaluation”, and Section B.5.4.8, “Problems with Floating-Point Values”.
MySQL 5.7 permits fractional seconds for
TIME
,
DATETIME
, and
TIMESTAMP
values, with up to
microseconds (6 digits) precision. See
Section 12.3.6, “Fractional Seconds in Time Values”.
There may be problems replicating from a master server that understands fractional seconds to an older slave (MySQL 5.6.3 and earlier) that does not:
For CREATE TABLE
statements
containing columns that have an
fsp
(fractional seconds
precision) value greater than 0, replication will fail due
to parser errors.
Statements that use temporal data types with an
fsp
value of 0 will work for with
statement-based logging but not row-based logging. In the
latter case, the data types have binary formats and type
codes on the master that differ from those on the slave.
Some expression results will differ on master and slave.
Examples: On the master, the timestamp
system variable returns a value that includes a microseconds
fractional part; on the slave, it returns an integer. On the
master, functions that return a result that includes the
current time (such as
CURTIME()
,
SYSDATE()
, or
UTC_TIMESTAMP()
) interpret an
argument as an fsp
value and the
return value includes a fractional seconds part of that many
digits. On the slave, these functions permit an argument but
ignore it.
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 14.7.6.3, “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 behavior 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
.
Certain functions do not replicate well under some conditions:
The USER()
,
CURRENT_USER()
(or
CURRENT_USER
),
UUID()
,
VERSION()
, and
LOAD_FILE()
functions are
replicated without change and thus do not work reliably on
the slave unless row-based replication is enabled. (See
Section 18.2.1, “Replication Formats”.)
USER()
and
CURRENT_USER()
are
automatically replicated using row-based replication when
using MIXED
mode, and generate a warning
in STATEMENT
mode. (See also
Section 18.4.1.8, “Replication of CURRENT_USER()”.) This
is also true for VERSION()
and RAND()
.
For NOW()
, the binary log
includes the timestamp. This means that the value
as returned by the call to this function on the
master is replicated to the slave. To avoid
unexpected results when replicating between MySQL servers in
different time zones, set the time zone on both master and
slave. See also
Section 18.4.1.32, “Replication and Time Zones”
To explain the potential problems when replicating between
servers which are in different time zones, suppose that the
master is located in New York, the slave is located in
Stockholm, and both servers are using local time. Suppose
further that, on the master, you create a table
mytable
, perform an
INSERT
statement on this
table, and then select from the table, as shown here:
mysql>CREATE TABLE mytable (mycol TEXT);
Query OK, 0 rows affected (0.06 sec) mysql>INSERT INTO mytable VALUES ( NOW() );
Query OK, 1 row affected (0.00 sec) mysql>SELECT * FROM mytable;
+---------------------+ | mycol | +---------------------+ | 2009-09-01 12:00:00 | +---------------------+ 1 row in set (0.00 sec)
Local time in Stockholm is 6 hours later than in New York;
so, if you issue SELECT NOW()
on the
slave at that exact same instant, the value
2009-09-01 18:00:00
is returned. For this
reason, if you select from the slave's copy of
mytable
after the
CREATE TABLE
and
INSERT
statements just shown
have been replicated, you might expect
mycol
to contain the value
2009-09-01 18:00:00
. However, this is not
the case; when you select from the slave's copy of
mytable
, you obtain exactly the same
result as on the master:
mysql> SELECT * FROM mytable;
+---------------------+
| mycol |
+---------------------+
| 2009-09-01 12:00:00 |
+---------------------+
1 row in set (0.00 sec)
Unlike NOW()
, the
SYSDATE()
function is not
replication-safe because it is not affected by SET
TIMESTAMP
statements in the binary log and is
nondeterministic if statement-based logging is used. This is
not a problem if row-based logging is used.
An alternative is to use the
--sysdate-is-now
option to
cause SYSDATE()
to be an
alias for NOW()
. This must be
done on the master and the slave to work correctly. In such
cases, a warning is still issued by this function, but can
safely be ignored as long as
--sysdate-is-now
is used on
both the master and the slave.
SYSDATE()
is automatically
replicated using row-based replication when using
MIXED
mode, and generates a warning in
STATEMENT
mode.
The following restriction applies to
statement-based replication only, not to row-based
replication. 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 the master. Therefore,
these functions should not be used to insert into a master
table because the content on the slave would differ. For
example, do not issue a statement such as INSERT
INTO mytable VALUES(GET_LOCK(...))
.
These functions are automatically replicated using row-based
replication when using MIXED
mode, and
generate a warning in STATEMENT
mode.
As a workaround for the preceding limitations when
statement-based replication is in effect, 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;
Within a stored function, RAND()
replicates correctly as long as it is invoked only once during
the execution of the function. (You can consider the function
execution timestamp and random number seed as implicit inputs
that are identical on the master and slave.)
The FOUND_ROWS()
and
ROW_COUNT()
functions are not
replicated reliably using statement-based replication. A
workaround is to store the result of the function call in a user
variable, and then use that in the
INSERT
statement. For example, if
you wish to store the result in a table named
mytable
, you might normally do so like this:
SELECT SQL_CALC_FOUND_ROWS FROM mytable LIMIT 1; INSERT INTO mytable VALUES( FOUND_ROWS() );
However, if you are replicating mytable
, you
should use SELECT
... INTO
, and then store the variable in the table,
like this:
SELECT SQL_CALC_FOUND_ROWS INTO @found_rows FROM mytable LIMIT 1; INSERT INTO mytable VALUES(@found_rows);
In this way, the user variable is replicated as part of the context, and applied on the slave correctly.
These functions are automatically replicated using row-based
replication when using MIXED
mode, and
generate a warning in STATEMENT
mode. (Bug
#12092, Bug #30244)
Prior to MySQL 5.7.3, the value of
LAST_INSERT_ID()
was not
replicated correctly if any filtering options such as
--replicate-ignore-db
and
--replicate-do-table
were enabled
on the slave. (Bug #17234370, BUG# 69861)
Statement-based replication of LIMIT
clauses
in DELETE
,
UPDATE
, and
INSERT ...
SELECT
statements is unsafe since the order of the
rows affected is not defined. (Such statements can be replicated
correctly with statement-based replication only if they also
contain an ORDER BY
clause.) When such a
statement is encountered:
When using STATEMENT
mode, a warning that
the statement is not safe for statement-based replication is
now issued.
When using STATEMENT
mode, warnings are
issued for DML statements containing
LIMIT
even when they also have an
ORDER BY
clause (and so are made
deterministic). This is a known issue. (Bug #42851)
When using MIXED
mode, the statement is
now automatically replicated using row-based mode.
In MySQL 5.7,
LOAD DATA
INFILE
is considered unsafe (see
Section 18.2.1.3, “Determination of Safe and Unsafe Statements in Binary Logging”).
Replication is supported between partitioned tables as long as they use the same partitioning scheme and otherwise have the same structure except where an exception is specifically allowed (see Section 18.4.1.10, “Replication with Differing Table Definitions on Master and Slave”).
Replication between tables having different partitioning is
generally not supported. This because statements (such as
ALTER
TABLE ... DROP PARTITION
) acting directly on
partitions in such cases may produce different results on master
and slave. In the case where a table is partitioned on the
master but not on the slave, any statements operating on
partitions on the master's copy of the slave fail on the
slave. When the slave's copy of the table is partitioned
but the master's copy is not, statements acting on
partitions cannot be run on the master without causing errors
there.
Due to these dangers of causing replication to fail entirely (on account of failed statements) and of inconsistencies (when the result of a partition-level SQL statement produces different results on master and slave), we recommend that insure that the partitioning of any tables to be replicated from the master is matched by the slave's versions of these tables.
When used on a corrupted or otherwise damaged table, it is
possible for the REPAIR TABLE
statement to delete rows that cannot be recovered. However, any
such modifications of table data performed by this statement are
not replicated, which can cause master and slave to lose
synchronization. For this reason, in the event that a table on
the master becomes damaged and you use
REPAIR TABLE
to repair it, you
should first stop replication (if it is still running) before
using REPAIR TABLE
, then
afterward compare the master's and slave's copies of
the table and be prepared to correct any discrepancies manually,
before restarting replication.
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 CHANGE MASTER TO
statement. 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 18.3.2, “Handling an Unexpected Halt of a Replication Slave”.
An unclean shutdown (for example, a crash) on the master side
can result in the master binary log having a final position less
than the most recent position read by the slave, due to the
master 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.
Shutting down a slave cleanly is safe because it keeps track of where it left off. However, be careful that the slave does not have temporary tables open; see Section 18.4.1.24, “Replication and Temporary Tables”. Unclean shutdowns might produce problems, especially if the disk cache was not flushed to disk before the problem occurred:
For transactions, the slave commits and then updates
relay-log.info
. If a crash occurs
between these two operations, relay log processing will have
proceeded further than the information file indicates and
the slave will re-execute the events from the last
transaction in the relay log after it has been restarted.
A similar problem can occur if the slave updates
relay-log.info
but the server host
crashes before the write has been flushed to disk. To
minimize the chance of this occurring, set
sync_relay_log_info=1
in
the slave my.cnf
file. Setting
sync_relay_log_info
to 0
causes no writes to be forced to disk and the server relies
on the operating system to flush the file from time to time.
The fault tolerance of your system for these types of problems is greatly increased if you have a good uninterruptible power supply.
max_allowed_packet
sets an
upper limit on the size of any single message between the MySQL
server and clients, including replication slaves. If you are
replicating large column values (such as might be found in
TEXT
or
BLOB
columns) and
max_allowed_packet
is too small
on the master, the master fails with an error, and the slave
shuts down the I/O thread. If
max_allowed_packet
is too small
on the slave, this also causes the slave to stop the I/O thread.
Row-based replication currently sends all columns and column
values for updated rows from the master to the slave, including
values of columns that were not actually changed by the update.
This means that, when you are replicating large column values
using row-based replication, you must take care to set
max_allowed_packet
large enough
to accommodate the largest row in any table to be replicated,
even if you are replicating updates only, or you are inserting
only relatively small values.
When a master server shuts down and restarts, its
MEMORY
tables become empty. To
replicate this effect to slaves, the first time that the master
uses a given MEMORY
table after
startup, it logs an event that notifies slaves that the table
must to be emptied by writing a
DELETE
statement for that table
to the binary log.
When a slave server shuts down and restarts, its
MEMORY
tables become empty. This
causes the slave to be out of synchrony with the master and may
lead to other failures or cause the slave to stop:
Row-format updates and deletes received from the master may
fail with Can't find record in
'
.
memory_table
'
Statements such as
INSERT INTO
... SELECT FROM
may insert
a different set of rows on the master and slave.
memory_table
The safe way to restart a slave that is replicating
MEMORY
tables is to first drop or
delete all rows from the MEMORY
tables on the master and wait until those changes have
replicated to the slave. Then it is safe to restart the slave.
An alternative restart method may apply in some cases. When
binlog_format=ROW
, you can
prevent the slave from stopping if you set
slave_exec_mode=IDEMPOTENT
before you start the slave again. This allows the slave to
continue to replicate, but its
MEMORY
tables will still be
different from those on the master. This can be okay if the
application logic is such that the contents of
MEMORY
tables can be safely lost
(for example, if the MEMORY
tables
are used for caching).
slave_exec_mode=IDEMPOTENT
applies globally to all tables, so it may hide other replication
errors in non-MEMORY
tables.
(The method just described is not applicable in MySQL Cluster,
where slave_exec_mode
is always
IDEMPOTENT
, and cannot be changed.)
The size of MEMORY
tables is
limited by the value of the
max_heap_table_size
system
variable, which is not replicated (see
Section 18.4.1.38, “Replication and Variables”). A change in
max_heap_table_size
takes effect for
MEMORY
tables that are created or updated
using ALTER TABLE
... ENGINE = MEMORY
or TRUNCATE
TABLE
following the change, or for all
MEMORY
tables following a server
restart. If you increase the value of this variable on the
master without doing so on the slave, it becomes possible for a
table on the master to grow larger than its counterpart on the
slave, leading to inserts that succeed on the master but fail on
the slave with Table is full errors. This
is a known issue (Bug #48666). In such cases, you must set the
global value of
max_heap_table_size
on the
slave as well as on the master, then restart replication. It is
also recommended that you restart both the master and slave
MySQL servers, to insure that the new value takes complete
(global) effect on each of them.
See Section 16.3, “The MEMORY Storage Engine”, for more
information about MEMORY
tables.
The discussion in the following paragraphs does not apply when
binlog_format=ROW
because, in
that case, temporary tables are not replicated; this means that
there are never any temporary tables on the slave to be lost in
the event of an unplanned shutdown by the slave. The remainder
of this section applies only when using statement-based or
mixed-format replication. Loss of replicated temporary tables on
the slave can be an issue, whenever
binlog_format
is
STATEMENT
or MIXED
, for
statements involving temporary tables that can be logged safely
using statement-based format. For more information about
row-based replication and temporary tables, see
Row-based logging of temporary tables.
Safe slave shutdown when using temporary tables. Temporary tables are replicated except in the case where you stop the slave server (not just the slave threads) and you have replicated temporary tables that are open for use in updates that have not yet been executed on the slave. If you stop 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 SQL_THREAD
statement.
Use SHOW STATUS
to check the
value of the
Slave_open_temp_tables
variable.
If the value is not 0, restart the slave SQL thread with
START SLAVE SQL_THREAD
and repeat the
procedure later.
When the value is 0, issue a mysqladmin shutdown command to stop the slave.
Temporary tables and replication options.
By default, all temporary tables are replicated; this happens
whether or not there are any matching
--replicate-do-db
,
--replicate-do-table
, or
--replicate-wild-do-table
options in effect. However, the
--replicate-ignore-table
and
--replicate-wild-ignore-table
options are honored for temporary tables.
A recommended practice when using statement-based or
mixed-format replication is to designate a prefix for exclusive
use in naming temporary tables that you do not want replicated,
then employ a
--replicate-wild-ignore-table
option to match that prefix. For example, you might give all
such tables names beginning with norep
(such
as norepmytable
,
norepyourtable
, and so on), then use
--replicate-wild-ignore-table=norep%
to prevent them from being replicated.
Data modification statements made to tables in the
mysql
database are replicated according to
the value of binlog_format
; if
this value is MIXED
, these statements are
replicated using row-based format. However, statements that
would normally update this information indirectly—such
GRANT
,
REVOKE
, and statements
manipulating triggers, stored routines, and views—are
replicated to slaves using statement-based replication.
It is possible for the data on the master and slave to become
different if a statement is written in such a way that the data
modification is nondeterministic; that is, left up the query
optimizer. (In general, this is not a good practice, even
outside of replication.) Examples of nondeterministic statements
include DELETE
or
UPDATE
statements that use
LIMIT
with no ORDER BY
clause; see Section 18.4.1.17, “Replication and LIMIT”, for a
detailed discussion of these.
You can encounter problems when you attempt to replicate from an
older master to a newer slave and you make use of identifiers on
the master that are reserved words in the newer MySQL version
running on the slave. An example of this is using a table column
named virtual
on a 5.6 master that is
replicating to a 5.7 or higher slave because
VIRTUAL
is a reserved word beginning in MySQL
5.7. Replication can fail in such cases with Error 1064
You have an error in your SQL syntax...,
even if a database or table named using the reserved
word or a table having a column named using the reserved word is
excluded from replication. This is due to the fact
that each SQL event must be parsed by the slave prior to
execution, so that the slave knows which database object or
objects would be affected; only after the event is parsed can
the slave apply any filtering rules defined by
--replicate-do-db
,
--replicate-do-table
,
--replicate-ignore-db
, and
--replicate-ignore-table
.
To work around the problem of database, table, or column names on the master which would be regarded as reserved words by the slave, do one of the following:
Use one or more ALTER TABLE
statements on the master to change the names of any database
objects where these names would be considered reserved words
on the slave, and change any SQL statements that use the old
names to use the new names instead.
In any SQL statements using these database object names,
write the names as quoted identifiers using backtick
characters (`
).
For listings of reserved words by MySQL version, see Reserved Words, in the MySQL Server Version Reference. For identifier quoting rules, see Section 10.2, “Schema Object Names”.
If a statement produces the same error (identical error code) on both the master and the slave, the error is logged, but replication continues.
If a statement produces different errors on the master and the
slave, the slave SQL thread terminates, and the slave writes a
message to its error log and waits for the database
administrator to decide what to do about the error. This
includes the case that a statement produces an error on the
master or the slave, but not both. To address the issue, connect
to the slave manually and determine the cause of the problem.
SHOW SLAVE STATUS
is useful for
this. Then fix the problem and run START
SLAVE
. For example, you might need to create a
nonexistent table before you can start the slave again.
If this error code validation behavior is not desirable, some or
all errors can be masked out (ignored) with the
--slave-skip-errors
option.
For nontransactional storage engines such as
MyISAM
, 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 expects execution of the
statement to result in the same error code. If it does not, the
slave SQL thread stops as described previously.
If you are replicating between tables that use different storage
engines on the master and slave, keep in mind that the same
statement might produce a different error when run against one
version of the table, but not the other, or might cause an error
for one version of the table, but not the other. For example,
since MyISAM
ignores foreign key constraints,
an INSERT
or
UPDATE
statement accessing an
InnoDB
table on the master might cause a
foreign key violation but the same statement performed on a
MyISAM
version of the same table on the slave
would produce no such error, causing replication to stop.
The server maintains tables in the mysql
database that store information for the
HELP
statement (see
Section 14.8.3, “HELP Syntax”. These tables can be loaded manually as
described at Section 6.1.10, “Server-Side Help”.
Help table content is derived from the MySQL Reference Manual. There are versions of the manual specific to each MySQL release series, so help content is specific to each series as well. Normally, you load a version of help content that matches the server version. This has implications for replication. For example, you would load MySQL 5.6 help content into a MySQL 5.6 master server, but not necessarily replicate that content to a MySQL 5.7 slave server for which 5.7 help content is more appropriate.
This section describes how to manage help table content upgrades when your servers participate in replication. Server versions are one factor in this task. Another is that the help table structure may differ between the master and the slave.
Assume that help content is stored in a file named
fill_help_tables.sql
. In MySQL
distributions, this file is located under the
share
or share/mysql
directory, and the most recent version is always available for
download from http://dev.mysql.com/doc/index-other.html.
To upgrade help tables, using the following procedure.
Connection parameters are not shown for the
mysql commands discussed here; in all cases,
connect to the server using an account such as
root
that has privileges for modifying tables
in the mysql
database.
Upgrade your servers by running mysql_upgrade, first on the slaves and then on the master. This is the usual principle of upgrading slaves first.
Decide whether you want to replicate help table content from the master to its slaves. If not, load the content on the master and each slave individually. Otherwise, check for and resolve any incompatibilities between help table structure on the master and its slaves, then load the content into the master and let it replicate to the slaves.
More detail about these two methods of loading help table content follows.
To load help table content without replication, run this command
on the master and each slave individually, using a
fill_help_tables.sql
file containing
content appropriate to the server version (enter the command on
one line):
mysql --init-command="SET sql_log_bin=0" mysql < fill_help_tables.sql
Use the --init-command
option on
each server, including the slaves, in case a slave also acts as
a master to other slaves in your replication topology. The
SET
statement suppresses binary logging.
After the command has been run on each server to be upgraded,
you are done.
As of MySQL 5.7.5, the
fill_help_tables.sql
file includes the
SET
statement to cause the file contents
not to replicate. Thus, for 5.7.5 and higher, the command is
simpler:
mysql mysql < fill_help_tables.sql
As mentioned previously,
fill_help_tables.sql
in MySQL 5.7.5 and
up includes a SET
statement to suppress
binary logging of the file contents. If you want to replicate
help table contents for MySQL 5.7.5 or later, you must edit
fill_help_tables.sql
to remove the
SET
statement. This should rarely be
desireable because help table contents are specific to the
version of the server into which they are loaded, which may
differ for master and slave.
If you do want to replicate help table content, check for help
table incompatibilities between your master and its slaves. The
url
column in the
help_category
and
help_topic
tables was originally
CHAR(128)
, but is TEXT
in
newer MySQL versions to accommodate longer URLs. To check help
table structure, use this statement:
SELECT TABLE_NAME, COLUMN_NAME, COLUMN_TYPE FROM INFORMATION_SCHEMA.COLUMNS WHERE TABLE_SCHEMA = 'mysql' AND COLUMN_NAME = 'url';
For tables with the old structure, the statement produces this result:
+---------------+-------------+-------------+ | TABLE_NAME | COLUMN_NAME | COLUMN_TYPE | +---------------+-------------+-------------+ | help_category | url | char(128) | | help_topic | url | char(128) | +---------------+-------------+-------------+
For tables with the new structure, the statement produces this result:
+---------------+-------------+-------------+ | TABLE_NAME | COLUMN_NAME | COLUMN_TYPE | +---------------+-------------+-------------+ | help_category | url | text | | help_topic | url | text | +---------------+-------------+-------------+
If the master and slave both have the old structure or both have the new structure, they are compatible and you can replicate help table content by executing this command on the master:
mysql mysql < fill_help_tables.sql
The table content will load into the master, then replicate to the slaves.
If the master and slave have incompatible help tables (one server has the old structure and the other has the new), you have a choice between not replicating help table content after all, or making the table structures compatible so that you can replicate the content.
If you decide not to replicate the content after all,
upgrade the master and slaves individually using
mysql with the
--init-command
option, as
described previously.
If instead you decide to make the table structures compatible, upgrade the tables on the server that has the old structure. Suppose that your master server has the old table structure. Upgrade its tables to the new structure manually by executing these statements (binary logging is disabled here to prevent replication of the changes to the slaves, which already have the new structure):
SET sql_log_bin=0; ALTER TABLE mysql.help_category ALTER COLUMN url TEXT; ALTER TABLE mysql.help_topic ALTER COLUMN url TEXT;
Then run this command on the master:
mysql mysql < fill_help_tables.sql
The table content will load into the master, then replicate to the slaves.
Using different server SQL mode settings on the master and the
slave may cause the same INSERT
statements to be handled differently on the master and the
slave, leading the master and slave to diverge. For best
results, you should always use the same server SQL mode on the
master and on the slave. This advice applies whether you are
using statement-based or row-based replication.
If you are replicating partitioned tables, using different SQL modes on the master and the slave is likely to cause issues. At a minimum, this is likely to cause the distribution of data among partitions to be different in the master's and slave's copies of a given table. It may also cause inserts into partitioned tables that succeed on the master to fail on the slave.
For more information, see Section 6.1.8, “Server SQL Modes”. In particular, see SQL Mode Changes in MySQL 5.7, which describes changes in MySQL 5.7 so that you can assess whether your applications will be affected.
The global system variable
slave_transaction_retries
affects replication as follows: If the slave SQL thread fails to
execute a transaction because of an InnoDB
deadlock or because it exceeded the InnoDB
innodb_lock_wait_timeout
value,
or the NDB
TransactionDeadlockDetectionTimeout
or
TransactionInactiveTimeout
value, the slave
automatically retries the transaction
slave_transaction_retries
times
before stopping with an error. The default value is 10. The
total retry count can be seen in the output of
SHOW STATUS
; see
Section 6.1.7, “Server Status Variables”.
By default, master and slave servers assume that they are in the
same time zone. If you are replicating between servers in
different time zones, the time zone must be set on both master
and slave. Otherwise, statements depending on the local time on
the master are not replicated properly, such as statements that
use the NOW()
or
FROM_UNIXTIME()
functions. Set
the time zone in which MySQL server runs by using the
--timezone=
option of the timezone_name
mysqld_safe
script or by
setting the TZ
environment variable. See also
Section 18.4.1.16, “Replication and System Functions”.
Mixing transactional and nontransactional statements within the same transaction. In general, you should avoid transactions that update both transactional and nontransactional tables in a replication environment. You should also avoid using any statement that accesses both transactional (or temporary) and nontransactional tables and writes to any of them.
The server uses these rules for binary logging:
If the initial statements in a transaction are nontransactional, they are written to the binary log immediately. The remaining statements in the transaction are cached and not written to the binary log until the transaction is committed. (If the transaction is rolled back, the cached statements are written to the binary log only if they make nontransactional changes that cannot be rolled back. Otherwise, they are discarded.)
For statement-based logging, logging of nontransactional
statements is affected by the
binlog_direct_non_transactional_updates
system variable. When this variable is
OFF
(the default), logging is as just
described. When this variable is ON
,
logging occurs immediately for nontransactional statements
occurring anywhere in the transaction (not just initial
nontransactional statements). Other statements are kept in
the transaction cache and logged when the transaction
commits.
binlog_direct_non_transactional_updates
has no effect for row-format or mixed-format binary logging.
Transactional, nontransactional, and mixed statements. To apply those rules, the server considers a statement nontransactional if it changes only nontransactional tables, and transactional if it changes only transactional tables. In MySQL 5.7, a statement that references both nontransactional and transactional tables and updates any of the tables involved, is considered a “mixed” statement. (In previous MySQL release series, a statement that changed both nontransactional and transactional tables was considered mixed.) Mixed statements, like transactional statements, are cached and logged when the transaction commits.
A mixed statement that updates a transactional table is considered unsafe if the statement also performs either of the following actions:
Updates or reads a transactional table
Reads a nontransactional table and the transaction isolation level is less than REPEATABLE_READ
A mixed statement following the update of a transactional table within a transaction is considered unsafe if it performs either of the following actions:
Updates any table and reads from any temporary table
Updates a nontransactional table and binlog_direct_non_trans_update is OFF
For more information, see Section 18.2.1.3, “Determination of Safe and Unsafe Statements in Binary Logging”.
A mixed statement is unrelated to mixed binary logging format.
In situations where transactions mix updates to transactional
and nontransactional 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 nontransactional
table before the first connection transaction is complete,
statements can be logged out of order because the second
connection update is written immediately after it is performed,
regardless of the state of the transaction being performed by
the first connection.
Using different storage engines on master and slave.
It is possible to replicate transactional tables on the master
using nontransactional 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.
In MySQL 5.7, it is also safe to replicate
transactions from MyISAM
tables on
the master to transactional tables—such as tables that use
the InnoDB
storage engine—on
the slave. In such cases, an
AUTOCOMMIT=1
statement issued on the master is replicated, thus enforcing
AUTOCOMMIT
mode on the slave.
When the storage engine type of the slave is nontransactional, transactions on the master that mix updates of transactional and nontransactional tables should be avoided because they can cause inconsistency of the data between the master transactional table and the slave nontransactional table. That is, such transactions can lead to master storage engine-specific behavior with the possible effect of replication going out of synchrony. MySQL does not issue a warning about this currently, so extra care should be taken when replicating transactional tables from the master to nontransactional tables on the slaves.
Changing the binary logging format within transactions.
The binlog_format
system
variable is read-only as long as a transaction is in progress.
Every transaction (including
autocommit
transactions) is
recorded in the binary log as though it starts with a
BEGIN
statement, and ends with either a
COMMIT
or a
ROLLBACK
statement. In MySQL 5.7, this true is even for
statements affecting tables that use a nontransactional storage
engine (such as MyISAM
).
Inconsistencies in the sequence of transactions that have been executed from the relay log can occur depending on your replication configuration. This section explains how to avoid inconsistencies and solve any problems they cause.
The following types of inconsistencies can exist:
Half-applied transactions. A transaction which updates non-transactional tables has applied some but not all of its changes.
Gaps. A gap is a transaction that has
not been (fully) applied, even though some later transaction
has been applied. Gaps can only appear when using a
multi-threaded slave. To avoid gaps occurring, set
slave_preserve_commit_order=1
,
which requires
slave_parallel_type=LOGICAL_CLOCK
,
and that log-bin
and
log-slave-updates
are also
enabled.
Gap-free low-watermark position. Even
in the absence of gaps, it is possible that transactions
after Exec_master_log_pos
have not been
applied. That is, all transactions up to point
N
have been applied, and no transactions
after N
have been applied, but
Exec_master_log_pos
has a value smaller
than N.
This can only happen on
multi-threaded slaves. Enabling
slave_preserve_commit_order
does not prevent gap-free low-watermark
positions.
The following scenarios are relevant to the existence of half-applied transactions, gaps, and gap-free low-watermark position inconsistencies:
While slave threads are running, there may be gaps and half-applied transactions.
mysqld shuts down. Both clean and unclean shutdown abort ongoing transactions and may leave gaps and half-applied transactions.
KILL
of replication threads
(the SQL thread when using a single-threaded slave, the
coordinator thread when using a multi-threaded slave). This
aborts ongoing transactions and may leave gaps and
half-applied transactions.
Error in applier threads. This may leave gaps. If the error is in a mixed transaction, that transaction is half-applied. When using a multi-threaded slave, workers which have not received an error complete their queues, so it may take time to stop all threads.
STOP SLAVE
when using a
multi-threaded slave. After issuing
STOP SLAVE
, the slave waits
for any gaps to be filled and then updates
Exec_master_log_pos
. This ensures it
never leaves gaps or gap-free low-watermark positions,
unless any of the cases above applies (in other words,
before STOP SLAVE
completes,
either an error happens, or another thread issues
KILL
, or the server restarts.
In these cases, STOP SLAVE
returns successfully.)
If the last transaction in the relay log is only
half-received and the multi-threaded slave coordinator has
started to schedule the transaction to a worker, then
STOP SLAVE
waits up to 60
seconds for the transaction to be received. After this
timeout, the coordinator gives up and aborts the
transaction. If the transaction is mixed, it may be left
half-completed.
STOP SLAVE
when using a
single-threaded slave. If the ongoing transaction only
updates transactional tables, it is rolled back and
STOP SLAVE
stops immediately.
If the ongoing transaction is mixed,
STOP SLAVE
waits up to 60
seconds for the transaction to complete. After this timeout,
it aborts the transaction, so it may be left half-completed.
The global variable
rpl_stop_slave_timeout
is
unrelated to the process of stopping the replication threads. It
only makes the client that issues STOP
SLAVE
return to the client, but the replication
threads continue to try to stop.
If a replication channel has gaps, it has the following consequences:
The slave database is in a state that may never have existed on the master.
The field Exec_master_log_pos
in
SHOW SLAVE STATUS
is only a
"low-watermark". In other words, transactions appearing
before the position are guaranteed to have committed, but
transactions after the position may have committed or not.
CHANGE MASTER TO
statements
for that channel fail with an error, unless the applier
threads are running and the CHANGE
MASTER TO
statement only sets receiver options.
If mysqld is started with
--relay-log-recovery
, no
recovery is done for that channel, and a warning is printed.
If mysqldump is used with
--dump-slave
, it does not
record the existence of gaps; thus it prints
CHANGE MASTER TO
with
RELAY_LOG_POS
set to the low-watermark
position in Exec_master_log_pos
.
After applying the dump on another server, and starting the
replication threads, transactions appearing after the
position are replicated again. Note that this is harmless if
GTIDs are enabled (however, in that case it is not
recommended to use
--dump-slave
).
If a replication channel has a gap-free low-watermark position, cases 2 to 5 above apply, but case 1 does not.
The gap-free low-watermark position information is persisted in
binary format in the internal table
mysql.slave_worker_info
.
START SLAVE
[SQL_THREAD]
always consults this information so that
it applies only the correct transactions. This remains true even
if slave_parallel_workers
has
been changed to 0 before START
SLAVE
, and even if START
SLAVE
is used with UNTIL
clauses.
START SLAVE UNTIL
SQL_AFTER_MTS_GAPS
only applies as many transactions
as needed in order to fill in the gaps. If
START SLAVE
is used with
UNTIL
clauses that tell it to stop before it
has consumed all the gaps, then it leaves remaining gaps.
RESET SLAVE
removes the relay
logs and resets the replication position. Thus issuing
RESET SLAVE
on a slave with
gaps means the slave loses any information about the gaps,
without correcting the gaps.
slave-preserve-commit-order
ensures that there are no gaps. However, it is still possible
that Exec_master_log_pos
is just a gap-free
low-watermark position in scenarios 1 to 4 above. That is, there
may be transactions after Exec_master_log_pos
which have been applied. Therefore the cases numbered 2 to 5
above (but not case 1) apply, even when
slave-preserve-commit-order
is
enabled.
With statement-based replication, triggers executed on the master also execute on the slave. With row-based replication, triggers executed on the master do not execute on the slave. Instead, the row changes on the master resulting from trigger execution are replicated and applied on the slave.
This behavior is by design. If under row-based replication the slave applied the triggers as well as the row changes caused by them, the changes would in effect be applied twice on the slave, leading to different data on the master and the slave.
If you want triggers to execute on both the master and the slave—perhaps because you have different triggers on the master and slave—you must use statement-based replication. However, to enable slave-side triggers, it is not necessary to use statement-based replication exclusively. It is sufficient to switch to statement-based replication only for those statements where you want this effect, and to use row-based replication the rest of the time.
A statement invoking a trigger (or function) that causes an
update to an AUTO_INCREMENT
column is not
replicated correctly using statement-based replication. MySQL
5.7 marks such statements as unsafe. (Bug #45677)
A trigger can have triggers for different combinations of
trigger event (INSERT
,
UPDATE
,
DELETE
) and action time
(BEFORE
, AFTER
), but
before MySQL 5.7.2 cannot have multiple triggers that have the
same trigger event and action time. MySQL 5.7.2 lifts this
limitation and multiple triggers are permitted. This change has
replication implications for upgrades and downgrades.
For brevity, “multiple triggers” here is shorthand for “multiple triggers that have the same trigger event and action time.”
Upgrades. Suppose that you upgrade an old server that does not support multiple triggers to MySQL 5.7.2 or higher. If the new server is a replication master and has old slaves that do not support multiple triggers, an error occurs on those slaves if a trigger is created on the master for a table that already has a trigger with the same trigger event and action time. To avoid this problem, upgrade the slaves first, then upgrade the master.
Downgrades. If you downgrade a server that supports multiple triggers to an older version that does not, the downgrade has these effects:
For each table that has triggers, all trigger definitions
remain in the .TRG
file for the table.
However, if there are multiple triggers with the same
trigger event and action time, the server executes only one
of them when the trigger event occurs. For information about
.TRG
files, see
Table
Trigger Storage.
If triggers for the table are added or dropped subsequent to
the downgrade, the server rewrites the table's
.TRG
file. The rewritten file retains
only one trigger per combination of trigger event and action
time; the others are lost.
To avoid these problems, modify your triggers before downgrading. For each table that has multiple triggers per combination of trigger event and action time, convert each such set of triggers to a single trigger as follows:
For each trigger, create a stored routine that contains all
the code in the trigger. Values accessed using
NEW
and OLD
can be
passed to the routine using parameters. If the trigger needs
a single result value from the code, you can put the code in
a stored function and have the function return the value. If
the trigger needs multiple result values from the code, you
can put the code in a stored procedure and return the values
using OUT
parameters.
Drop all triggers for the table.
Create one new trigger for the table that invokes the stored routines just created. The effect for this trigger is thus the same as the multiple triggers it replaces.
TRUNCATE TABLE
is normally
regarded as a DML statement, and so would be expected to be
logged and replicated using row-based format when the binary
logging mode is ROW
or
MIXED
. However this caused issues when
logging or replicating, in STATEMENT
or
MIXED
mode, tables that used transactional
storage engines such as InnoDB
when
the transaction isolation level was READ
COMMITTED
or READ UNCOMMITTED
,
which precludes statement-based logging.
TRUNCATE TABLE
is treated for
purposes of logging and replication as DDL rather than DML so
that it can be logged and replicated as a statement. However,
the effects of the statement as applicable to
InnoDB
and other transactional
tables on replication slaves still follow the rules described in
Section 14.1.34, “TRUNCATE TABLE Syntax” governing such tables. (Bug
#36763)
The maximum length of MySQL user names was increased from 16 characters to 32 characters in MySQL 5.7.8. Replication of user names longer than 16 characters to a slave that supports only shorter user names will fail. However, this should occur only when replicating from a newer master to an older slave, which is not a recommended configuration.
System variables are not replicated correctly when using
STATEMENT
mode, except for the following
variables when they are used with session scope:
When MIXED
mode is used, the variables in the
preceding list, when used with session scope, cause a switch
from statement-based to row-based logging. See
Section 6.4.4.3, “Mixed Binary Logging Format”.
sql_mode
is also replicated
except for the
NO_DIR_IN_CREATE
mode; the
slave always preserves its own value for
NO_DIR_IN_CREATE
, regardless
of changes to it on the master. This is true for all replication
formats.
However, when mysqlbinlog parses a
SET @@sql_mode =
statement, the full
mode
mode
value, including
NO_DIR_IN_CREATE
, is passed to
the receiving server. For this reason, replication of such a
statement may not be safe when STATEMENT
mode
is in use.
The default_storage_engine
and
storage_engine
system variables
are not replicated, regardless of the logging mode; this is
intended to facilitate replication between different storage
engines.
The read_only
system variable
is not replicated. In addition, the enabling this variable has
different effects with regard to temporary tables, table
locking, and the SET PASSWORD
statement in different MySQL versions.
The max_heap_table_size
system
variable is not replicated. Increasing the value of this
variable on the master without doing so on the slave can lead
eventually to Table is full errors on the
slave when trying to execute
INSERT
statements on a
MEMORY
table on the master that is
thus permitted to grow larger than its counterpart on the slave.
For more information, see
Section 18.4.1.23, “Replication and MEMORY Tables”.
In statement-based replication, session variables are not replicated properly when used in statements that update tables. For example, the following sequence of statements will not insert the same data on the master and the slave:
SET max_join_size=1000; INSERT INTO mytable VALUES(@@max_join_size);
This does not apply to the common sequence:
SET time_zone=...; INSERT INTO mytable VALUES(CONVERT_TZ(..., ..., @@time_zone));
Replication of session variables is not a problem when row-based replication is being used, in which case, session variables are always replicated safely. See Section 18.2.1, “Replication Formats”.
In MySQL 5.7, the following session variables are written to the binary log and honored by the replication slave when parsing the binary log, regardless of the logging format:
Even though session variables relating to character sets and collations are written to the binary log, replication between different character sets is not supported.
To help reduce possible confusion, we recommend that you always
use the same setting for the
lower_case_table_names
system
variable on both master and slave, especially when you are
running MySQL on platforms with case-sensitive file systems.
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.
Replication from a table to a same-named view is supported using statement-based logging, but not when using row-based logging. In MySQL 5.7.1 and later, trying to do so when row-based logging is in effect causes an error. (Bug #11752707, Bug #43975)
MySQL supports replication from one release series to the next higher release series. For example, you can replicate from a master running MySQL 5.5 to a slave running MySQL 5.6, from a master running MySQL 5.6 to a slave running MySQL 5.7, and so on.
However, you may encounter difficulties when replicating from an
older master to a newer slave if the master uses statements or
relies on behavior no longer supported in the version of MySQL
used on the slave. For example, in MySQL 5.5,
CREATE TABLE
... SELECT
statements are permitted to change tables
other than the one being created, but are no longer allowed to do
so in MySQL 5.6 (see
Section 18.4.1.6, “Replication of CREATE TABLE ... SELECT Statements”).
The use of more than two MySQL Server versions is not supported in replication setups involving multiple masters, regardless of the number of master or slave MySQL servers. This restriction applies not only to release series, but to version numbers within the same release series as well. For example, if you are using a chained or circular replication setup, you cannot use MySQL 5.7.1, MySQL 5.7.2, and MySQL 5.7.4 concurrently, although you could use any two of these releases together.
It is strongly recommended to use the most recent release available within a given MySQL release series because replication (and other) capabilities are continually being improved. It is also recommended to upgrade masters and slaves that use early releases of a release series of MySQL to GA (production) releases when the latter become available for that release series.
Replication from newer masters to older slaves may be possible, but is generally not supported. This is due to a number of factors:
Binary log format changes. The binary log format can change between major releases. While we attempt to maintain backward compatibility, this is not always possible.
This also has significant implications for upgrading replication servers; see Section 18.4.3, “Upgrading a Replication Setup”, for more information.
For more information about row-based replication, see Section 18.2.1, “Replication Formats”.
SQL incompatibilities. You cannot replicate from a newer master to an older slave using statement-based replication if the statements to be replicated use SQL features available on the master but not on the slave.
However, if both the master and the slave support row-based replication, and there are no data definition statements to be replicated that depend on SQL features found on the master but not on the slave, you can use row-based replication to replicate the effects of data modification statements even if the DDL run on the master is not supported on the slave.
For more information on potential replication issues, see Section 18.4.1, “Replication Features and Issues”.
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 provides information about how upgrading affects replication. For general information about upgrading MySQL, see Section 2.11.1, “Upgrading MySQL”
When you upgrade a master to 5.7 from an earlier MySQL release series, you should first ensure that all the slaves of this master are using the same 5.7.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 5.7.x version, restart it, and restart replication. Relay logs created by the slave after the upgrade are in 5.7 format.
Changes affecting operations in strict SQL mode may result in
replication failure on an updated slave. For example, as of MySQL
5.7.2, the server restricts insertion of a
DEFAULT
value of 0 for temporal data types in
strict mode (STRICT_TRANS_TABLES
or STRICT_ALL_TABLES
). A
resulting incompatibility for replication if you use
statement-based logging
(binlog_format=STATEMENT
) is that
if a slave is upgraded, a nonupgraded master will execute
statements without error that may fail on the slave and
replication will stop. To deal with this, stop all new statements
on the master and wait until the slaves catch up. Then upgrade the
slaves. Alternatively, if you cannot stop new statements,
temporarily change to row-based logging on the master
(binlog_format=ROW
) and wait
until all slaves have processed all binary logs produced up to the
point of this change. Then upgrade the slaves.
After the slaves have been upgraded, shut down the master, upgrade it to the same 5.7.x release as the slaves, and restart it. If you had temporarily changed the master to row-based logging, change it back to statement-based logging. The 5.7 master is able to read the old binary logs written prior to the upgrade and to send them to the 5.7 slaves. The slaves recognize the old format and handle it properly. Binary logs created by the master subsequent to the upgrade are in 5.7 format. These too are recognized by the 5.7 slaves.
In other words, when upgrading to MySQL 5.7, the slaves must be MySQL 5.7 before you can upgrade the master to 5.7. Note that downgrading from 5.7 to older versions does not work so simply: You must ensure that any 5.7 binary log or relay log has been fully processed, so that you can remove it before proceeding with the downgrade.
Downgrading a replication setup to a previous version cannot be done once you have switched from statement-based to row-based replication, and after the first row-based statement has been written to the binary log. See Section 18.2.1, “Replication Formats”.
Some upgrades may require that you drop and re-create database objects when you move from one MySQL series to the next. For example, collation changes might require that table indexes be rebuilt. Such operations, if necessary, are detailed at Section 2.11.1.1, “Changes Affecting Upgrades to MySQL 5.7”. It is safest to perform these operations separately on the slaves and the master, and to disable replication of these operations from the master to the slave. To achieve this, use the following procedure:
Stop all the slaves and upgrade them. Restart them with the
--skip-slave-start
option so
that they do not connect to the master. Perform any table
repair or rebuilding operations needed to re-create database
objects, such as use of REPAIR TABLE
or
ALTER TABLE
, or dumping and reloading
tables or triggers.
Disable the binary log on the master. To do this without
restarting the master, execute a SET sql_log_bin =
0
statement. Alternatively, stop the master and
restart it without the
--log-bin
option. If you
restart the master, you might also want to disallow client
connections. For example, if all clients connect using TCP/IP,
use the --skip-networking
option when you restart the master.
With the binary log disabled, perform any table repair or rebuilding operations needed to re-create database objects. The binary log must be disabled during this step to prevent these operations from being logged and sent to the slaves later.
Re-enable the binary log on the master. If you set
sql_log_bin
to 0 earlier,
execute a SET sql_log_bin = 1
statement. If
you restarted the master to disable the binary log, restart it
with --log-bin
, and without
--skip-networking
so that
clients and slaves can connect.
Restart the slaves, this time without the
--skip-slave-start
option.
If you are upgrading an existing replication setup from a version
of MySQL that does not support global transaction identifiers to a
version that does, you should not enable GTIDs on either the
master or the slave before making sure that the setup meets all
the requirements for GTID-based replication. For example
server_uuid
, which was added in
MySQL 5.6, must exist for GTIDs to function correctly. See
Section 18.1.3.2, “Setting Up Replication Using GTIDs”, which contains
information about converting existing replication setups to use
GTID-based replication.
If you have followed the instructions but your replication setup is not working, the first thing to do is check the error log for messages. Many users have lost time by not doing this soon enough after encountering problems.
If you cannot tell from the error log what the problem was, try the following techniques:
Verify that the master has binary logging enabled by issuing a
SHOW MASTER STATUS
statement.
If logging is enabled, Position
is nonzero.
If binary logging is not enabled, verify that you are running
the master with the --log-bin
option.
Verify that the master and slave both were started with the
--server-id
option and that the
ID value is unique on each server.
Verify that the slave is running. Use
SHOW SLAVE STATUS
to check
whether the Slave_IO_Running
and
Slave_SQL_Running
values are both
Yes
. If not, verify the options that were
used when starting the slave server. For example,
--skip-slave-start
prevents the
slave threads from starting until you issue a
START SLAVE
statement.
If the slave is running, check whether it established a
connection to the master. Use SHOW
PROCESSLIST
, find the I/O and SQL threads and check
their State
column to see what they
display. See
Section 18.2.2, “Replication Implementation Details”. If the
I/O thread state says Connecting to master
,
check the following:
Verify the privileges for the user being used for replication on the master.
Check that the host name of the master is correct and that
you are using the correct port to connect to the master.
The port used for replication is the same as used for
client network communication (the default is
3306
). For the host name, ensure that
the name resolves to the correct IP address.
Check that networking has not been disabled on the master
or slave. Look for the
skip-networking
option in
the configuration file. If present, comment it out or
remove it.
If the master has a firewall or IP filtering configuration, ensure that the network port being used for MySQL is not being filtered.
Check that you can reach the master by using
ping
or
traceroute
/tracert
to reach the host.
If the slave was running previously but has stopped, the reason usually is that some statement that succeeded on the master failed on the slave. This should never happen if you have taken a proper snapshot of the master, and never modified the data on the slave outside of the slave thread. If the slave stops unexpectedly, it is a bug or you have encountered one of the known replication limitations described in Section 18.4.1, “Replication Features and Issues”. If it is a bug, see Section 18.4.5, “How to Report Replication Bugs or Problems”, for instructions on how to report it.
If a statement that succeeded on the master refuses to run on the slave, try the following procedure if it is not feasible to do a full database resynchronization by deleting the slave's databases and copying a new snapshot from the master:
Determine whether the affected table on the slave is
different from the master table. Try to understand how
this happened. Then make the slave's table identical to
the master's and run START
SLAVE
.
If the preceding step does not work or does not apply, try to understand whether it would be safe to make the update manually (if needed) and then ignore the next statement from the master.
If you decide that the slave can skip the next statement from the master, issue the following statements:
mysql>SET GLOBAL sql_slave_skip_counter =
mysql>N
;START SLAVE;
The value of N
should be 1 if
the next statement from the master does not use
AUTO_INCREMENT
or
LAST_INSERT_ID()
.
Otherwise, the value should be 2. The reason for using a
value of 2 for statements that use
AUTO_INCREMENT
or
LAST_INSERT_ID()
is that
they take two events in the binary log of the master.
See also Section 14.4.2.5, “SET GLOBAL sql_slave_skip_counter Syntax”.
If you are sure that the slave started out perfectly synchronized with the master, and that no one has updated the tables involved outside of the slave thread, then presumably the discrepancy is the result of a bug. If you are running the most recent version of MySQL, please report the problem. If you are running an older version, try upgrading to the latest production release to determine whether the problem persists.
When you have determined that there is no user error involved, and replication still either does not work at all or is unstable, it is time to send us a bug report. We need to obtain as much information as possible from you to be able to track down the bug. Please spend some time and effort in preparing a good bug report.
If you have a repeatable test case that demonstrates the bug, please enter it into our bugs database using the instructions given in Section 1.7, “How to Report Bugs or Problems”. If you have a “phantom” problem (one that you cannot duplicate at will), use the following procedure:
Verify that no user error is involved. For example, if you update the slave outside of the slave thread, the data goes out of synchrony, and you can have unique key violations on updates. In this case, the slave thread stops and waits for you to clean up the tables manually to bring them into synchrony. This is not a replication problem. It is a problem of outside interference causing replication to fail.
Run the slave with the
--log-slave-updates
and
--log-bin
options. These
options cause the slave to log the updates that it receives
from the master into its own binary logs.
Save all evidence before resetting the replication state. If we have no information or only sketchy information, it becomes difficult or impossible for us to track down the problem. The evidence you should collect is:
All binary log files from the master
All binary log files from the slave
The output of SHOW MASTER
STATUS
from the master at the time you
discovered the problem
The output of SHOW SLAVE
STATUS
from the slave at the time you discovered
the problem
Error logs from the master and the slave
Use mysqlbinlog to examine the binary logs.
The following should be helpful to find the problem statement.
log_file
and
log_pos
are the
Master_Log_File
and
Read_Master_Log_Pos
values from
SHOW SLAVE STATUS
.
shell> mysqlbinlog --start-position=log_pos
log_file
| head
After you have collected the evidence for the problem, try to isolate it as a separate test case first. Then enter the problem with as much information as possible into our bugs database using the instructions at Section 1.7, “How to Report Bugs or Problems”.