A global transaction identifier (GTID) is a unique identifier created and associated with each transaction committed on the server of origin (the source). This identifier is unique not only to the server on which it originated, but is unique across all servers in a given replication topology.
GTID assignment distinguishes between client transactions, which are committed on the source, and replicated transactions, which are reproduced on a replica. When a client transaction is committed on the source, it is assigned a new GTID, provided that the transaction was written to the binary log. Client transactions are guaranteed to have monotonically increasing GTIDs without gaps between the generated numbers. If a client transaction is not written to the binary log (for example, because the transaction was filtered out, or the transaction was read-only), it is not assigned a GTID on the server of origin.
Replicated transactions retain the same GTID that was assigned to
the transaction on the server of origin. The GTID is present
before the replicated transaction begins to execute, and is
persisted even if the replicated transaction is not written to the
binary log on the replica, or is filtered out on the replica. The
mysql.gtid_executed
system table is used to
preserve the assigned GTIDs of all the transactions applied on a
MySQL server, except those that are stored in a currently active
binary log file.
The auto-skip function for GTIDs means that a transaction committed on the source can be applied no more than once on the replica, which helps to guarantee consistency. Once a transaction with a given GTID has been committed on a given server, any attempt to execute a subsequent transaction with the same GTID is ignored by that server. No error is raised, and no statement in the transaction is executed.
If a transaction with a given GTID has started to execute on a server, but has not yet committed or rolled back, any attempt to start a concurrent transaction on the server with the same GTID blocks. The server neither begins to execute the concurrent transaction nor returns control to the client. Once the first attempt at the transaction commits or rolls back, concurrent sessions that were blocking on the same GTID may proceed. If the first attempt rolled back, one concurrent session proceeds to attempt the transaction, and any other concurrent sessions that were blocking on the same GTID remain blocked. If the first attempt committed, all the concurrent sessions stop being blocked, and auto-skip all the statements of the transaction.
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 source'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 the source. 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
The upper limit for sequence numbers for GTIDs on a server
instance is the number of non-negative values for a signed 64-bit
integer (263 - 1
, or
9223372036854775807
). If the server runs out of
GTIDs, it takes the action specified by
binlog_error_action
. A warning
message is issued when the server instance is approaching the
limit.
MySQL 9.1 also supports tagged GTIDs. A tagged GTID consists of three parts, separated by colon characters, as shown here:
GTID = source_id:tag:transaction_id
In this case, the source_id
and
transaction_id
are as defined
previously. The tag
is a user-defined
string used to identify a specific group of transactions; see the
description of the gtid_next
system variable for permitted syntax.
Example: the one-hundred-seventeenth
transaction to be committed originally on the server with the UUID
ed102faf-eb00-11eb-8f20-0c5415bfaa1d
and the
tag Domain_1
has this GTID:
ed102faf-eb00-11eb-8f20-0c5415bfaa1d:Domain_1:117
The GTID for a transaction is shown in the output from
mysqlbinlog, and it is used to identify an
individual transaction in the Performance Schema replication
status tables, for example,
replication_applier_status_by_worker
.
The value stored by the gtid_next
system variable (@@GLOBAL.gtid_next
) is a
single GTID.
A GTID set is a set comprising one or more single GTIDs or
ranges of GTIDs. GTID sets are used in a MySQL server in several
ways. For example, the values stored by the
gtid_executed
and
gtid_purged
system variables
are GTID sets. The START REPLICA
options UNTIL SQL_BEFORE_GTIDS
and
UNTIL SQL_AFTER_GTIDS
can be used to make a
replica process transactions only up to the first GTID in a GTID
set, or stop after the last GTID in a GTID set. The built-in
functions GTID_SUBSET()
and
GTID_SUBTRACT()
require GTID sets
as input.
A range of GTIDs originating from the same server can be collapsed into a single expression, as shown here:
3E11FA47-71CA-11E1-9E33-C80AA9429562:1-5
The above example represents the first through fifth
transactions originating on the MySQL server whose
server_uuid
is
3E11FA47-71CA-11E1-9E33-C80AA9429562
.
Multiple single GTIDs or ranges of GTIDs originating from the
same server can also be included in a single expression, with
the GTIDs or ranges separated by colons, as in the following
example:
3E11FA47-71CA-11E1-9E33-C80AA9429562:1-3:11:47-49
A GTID set can include any combination of single GTIDs and
ranges of GTIDs, and it can include GTIDs originating from
different servers. This example shows the GTID set stored in the
gtid_executed
system variable
(@@GLOBAL.gtid_executed
) of a replica that
has applied transactions from more than one source:
2174B383-5441-11E8-B90A-C80AA9429562:1-3, 24DA167-0C0C-11E8-8442-00059A3C7B00:1-19
When GTID sets are returned from server variables, UUIDs are in alphabetical order, and numeric intervals are merged and in ascending order.
When constructing a GTID set, a user-defined tag is treated as part of the UUID. This means that multiple GTIDs originating from the same server and having the same tag can be included in a single expression, as shown in this example:
3E11FA47-71CA-11E1-9E33-C80AA9429562:Domain_1:1-3:11:47-49
GTIDs originating from the same server but having different tags are treated in a manner similar to those originating from different servers, like this:
3E11FA47-71CA-11E1-9E33-C80AA9429562:Domain_1:1-3:15-21, 3E11FA47-71CA-11E1-9E33-C80AA9429562:Domain_2:8-52
The complete syntax for a GTID set is as follows:
gtid_set:
uuid_set [, uuid_set] ...
| ''
uuid_set:
uuid:[tag:]interval[:interval]...
uuid:
hhhhhhhh-hhhh-hhhh-hhhh-hhhhhhhhhhhh
h:
[0-9|A-F]
tag:
[a-z_][a-z0-9_]{0,31}
interval:
m[-n]
(m >= 1; n > m)
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, the user-defined tag (if there is one),
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 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 NOT NULL,
interval_end BIGINT NOT NULL,
gtid_tag CHAR(32) NOT NULL,
PRIMARY KEY (source_uuid, gtid_tag, interval_start)
);
As with other MySQL system tables, do not attempt to create or modify this table yourself.
The mysql.gtid_executed
table is provided for
internal use by the MySQL server. It enables a replica to use
GTIDs when binary logging is disabled on the replica, and it
enables retention of the GTID state when the binary logs have
been lost. Note that the mysql.gtid_executed
table is cleared if you issue RESET BINARY
LOGS AND GTIDS
.
GTIDs are stored in the mysql.gtid_executed
table only when gtid_mode
is
ON
or ON_PERMISSIVE
. If
binary logging is disabled (log_bin
is
OFF
), or if
log_replica_updates
is
disabled, the server stores the GTID belonging to each
transaction together with the transaction in the buffer when the
transaction is committed, and the background thread adds the
contents of the buffer periodically as one or more entries to
the mysql.gtid_executed
table. In addition,
the table is compressed periodically at a user-configurable
rate, as described in
mysql.gtid_executed Table Compression.
If binary logging is enabled (log_bin
is
ON
), for the InnoDB
storage engine only, the server updates the
mysql.gtid_executed
table in the same way as
when binary logging or replica update logging is disabled,
storing the GTID for each transaction at transaction commit
time. For other storage engines, the server updates the
mysql.gtid_executed
table only when the
binary log is rotated or the server is shut down. At these
times, the server writes GTIDs for all transactions that were
written into the previous binary log into the
mysql.gtid_executed
table.
If the mysql.gtid_executed
table cannot be
accessed for writes, and the binary log file is rotated for any
reason other than reaching the maximum file size
(max_binlog_size
), the current
binary log file continues to be used. An error message is
returned to the client that requested the rotation, and a
warning is logged on the server. If the
mysql.gtid_executed
table cannot be accessed
for writes and max_binlog_size
is reached, the server responds according to its
binlog_error_action
setting. If
IGNORE_ERROR
is set, an error is logged on
the server and binary logging is halted, or if
ABORT_SERVER
is set, the server shuts down.
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, have the same GTID tag (if any), and whose
transaction IDs make up a range, similar to what is shown here:
+--------------------------------------+----------------+--------------+----------+
| source_uuid | interval_start | interval_end | gtid_tag |
|--------------------------------------+----------------+--------------|----------+
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 31 | 31 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 32 | 32 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 33 | 33 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 34 | 34 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 35 | 35 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 36 | 36 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 37 | 37 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 38 | 38 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 39 | 39 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 40 | 40 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 41 | 41 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 42 | 42 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 43 | 43 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 44 | 44 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 45 | 45 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 46 | 46 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 47 | 47 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 48 | 48 | Domain_1 |
...
To save space, the MySQL server can compress the
mysql.gtid_executed
table 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 | gtid_tag |
|--------------------------------------+----------------+--------------|----------+
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 31 | 35 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 36 | 39 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 40 | 43 | Domain_1 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 44 | 46 | Domain_2 |
| 3E11FA47-71CA-11E1-9E33-C80AA9429562 | 47 | 48 | Domain_1 |
...
The server can carry out compression using a dedicated
foreground thread named
thread/sql/compress_gtid_table
. 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: 26
NAME: thread/sql/compress_gtid_table
TYPE: FOREGROUND
PROCESSLIST_ID: 1
PROCESSLIST_USER: NULL
PROCESSLIST_HOST: NULL
PROCESSLIST_DB: NULL
PROCESSLIST_COMMAND: Daemon
PROCESSLIST_TIME: 1509
PROCESSLIST_STATE: Suspending
PROCESSLIST_INFO: NULL
PARENT_THREAD_ID: 1
ROLE: NULL
INSTRUMENTED: YES
HISTORY: YES
CONNECTION_TYPE: NULL
THREAD_OS_ID: 18677
When binary logging is enabled on the server, this compression
method is not used, and instead the
mysql.gtid_executed
table is compressed on
each binary log rotation. However, when binary logging is
disabled on the server, the
thread/sql/compress_gtid_table
thread sleeps
until a specified number of transactions have been executed,
then wakes up to perform compression of the
mysql.gtid_executed
table. It then sleeps
until the same number of transactions have taken place, then
wakes up to perform the compression again, repeating this loop
indefinitely. The number of transactions that elapse before the
table is compressed, and thus the compression rate, is
controlled by the value of the
gtid_executed_compression_period
system variable. Setting that value to 0 means that the thread
never wakes up, meaning that this explicit compression method is
not used. Instead, compression occurs implicitly as required.
InnoDB
transactions are written to
the mysql.gtid_executed
table by a process
separate from that used for transactions involving storage
engines other than InnoDB
. This process is
controlled by a different thread,
innodb/clone_gtid_thread
. This GTID persister
thread collects GTIDs in groups, flushes them to the
mysql.gtid_executed
table, then compresses
the table. If the server has a mix of
InnoDB
transactions and
non-InnoDB
transactions, which are
written to the mysql.gtid_executed
table
individually, the compression carried out by the
compress_gtid_table
thread interferes with
the work of the GTID persister thread and can slow it
significantly. For this reason, it is recommended that you set
gtid_executed_compression_period
to 0, so that the compress_gtid_table
thread
is never activated.
The default value for
gtid_executed_compression_period
is 0, and all transactions regardless of storage engine are
written to the mysql.gtid_executed
table by
the GTID persister thread.
When a server instance is started, if
gtid_executed_compression_period
is set to a nonzero value and the
thread/sql/compress_gtid_table
thread is
launched, in most server configurations, explicit compression is
performed for the mysql.gtid_executed
table.
Compression is triggered by the thread launch.