- 13.3 MySQL Transactional and Locking Statements
- 13.3.1 START TRANSACTION, COMMIT, and ROLLBACK Syntax
- 13.3.2 Statements That Cannot Be Rolled Back
- 13.3.3 Statements That Cause an Implicit Commit
- 13.3.4 SAVEPOINT and ROLLBACK TO SAVEPOINT Syntax
- 13.3.5 LOCK TABLES and UNLOCK TABLES Syntax
- 13.3.6 SET TRANSACTION Syntax
- 13.3.7 XA Transactions
START TRANSACTION
[transaction_characteristic [, transaction_characteristic] ...]
transaction_characteristic:
WITH CONSISTENT SNAPSHOT
| READ WRITE
| READ ONLY
BEGIN [WORK]
COMMIT [WORK] [AND [NO] CHAIN] [[NO] RELEASE]
ROLLBACK [WORK] [AND [NO] CHAIN] [[NO] RELEASE]
SET autocommit = {0 | 1}
These statements provide control over use of transactions:
START TRANSACTIONorBEGINstart a new transactionCOMMITcommits the current transaction, making its changes permanentROLLBACKrolls back the current transaction, canceling its changesSET autocommitdisables or enables the default autocommit mode for the current session
By default, MySQL runs with autocommit mode enabled. This means that as soon as you execute a statement that updates (modifies) a table, MySQL stores the update on disk to make it permanent.
To disable autocommit mode implicitly for a single series of
statements, use the START
TRANSACTION statement:
START TRANSACTION; SELECT @A:=SUM(salary) FROM table1 WHERE type=1; UPDATE table2 SET summary=@A WHERE type=1; COMMIT;
With START
TRANSACTION, autocommit remains disabled until you end
the transaction with COMMIT or
ROLLBACK. The
autocommit mode then reverts to its previous state.
START
TRANSACTION permits several modifiers that control
transaction characteristics. To specify multiple modifiers,
separate them by commas.
The
WITH CONSISTENT SNAPSHOTmodifier starts a consistent read for storage engines that are capable of it. This applies only toInnoDB. The effect is the same as issuing aSTART TRANSACTIONfollowed by aSELECTfrom anyInnoDBtable. See Section 14.2.4.3, “Consistent Nonlocking Reads”. TheWITH CONSISTENT SNAPSHOTmodifier does not change the current transaction isolation level, so it provides a consistent snapshot only if the current isolation level is one that permits consistent read (REPEATABLE READorSERIALIZABLE).-
The
READ WRITEandREAD ONLYmodifiers set the transaction access mode. They permit or prohibit changes to tables used in the transaction. If no access mode is specified, the default mode applies. Unless the default has been changed, it is read/write. It is not permitted to specify bothREAD WRITEandREAD ONLYin the same statement.In read-only mode, it remains possible to change tables created with the
TEMPORARYkeyword using DML statements. Changes made with DDL statements are not permitted, just as with permanent tables.For additional information about transaction access mode, including ways to change the default mode, see Section 13.3.6, “
SET TRANSACTIONSyntax”.If the
read_onlysystem variable is enabled, explicitly starting a transaction withSTART TRANSACTION READ WRITErequires theSUPERprivilege.
Many APIs used for writing MySQL client applications (such as
JDBC) provide their own methods for starting transactions that
can (and sometimes should) be used instead of sending a
START
TRANSACTION statement from the client. See
Chapter 21, Connectors and APIs, or the documentation for your
API, for more information.
To disable autocommit mode explicitly, use the following statement:
SET autocommit=0;
After disabling autocommit mode by setting the
autocommit variable to zero,
changes to transaction-safe tables (such as those for
InnoDB or
NDBCLUSTER) are not made permanent
immediately. You must use COMMIT to
store your changes to disk or
ROLLBACK to
ignore the changes.
autocommit is a session variable
and must be set for each session. To disable autocommit mode for
each new connection, see the description of the
autocommit system variable at
Section 5.1.3, “Server System Variables”.
BEGIN and
BEGIN WORK are
supported as aliases of
START
TRANSACTION for initiating a transaction.
START
TRANSACTION is standard SQL syntax, is the recommended
way to start an ad-hoc transaction, and permits modifiers that
BEGIN does not.
The BEGIN
statement differs from the use of the BEGIN
keyword that starts a
BEGIN ... END
compound statement. The latter does not begin a transaction. See
Section 13.6.1, “BEGIN ... END
Compound-Statement Syntax”.
Within all stored programs (stored procedures and functions,
triggers, and events), the parser treats
BEGIN [WORK]
as the beginning of a
BEGIN ...
END block. Begin a transaction in this context with
START
TRANSACTION instead.
The optional WORK keyword is supported for
COMMIT and
ROLLBACK, as are
the CHAIN and RELEASE
clauses. CHAIN and RELEASE
can be used for additional control over transaction completion.
The value of the completion_type
system variable determines the default completion behavior. See
Section 5.1.3, “Server System Variables”.
The AND CHAIN clause causes a new transaction
to begin as soon as the current one ends, and the new transaction
has the same isolation level as the just-terminated transaction.
The RELEASE clause causes the server to
disconnect the current client session after terminating the
current transaction. Including the NO keyword
suppresses CHAIN or RELEASE
completion, which can be useful if the
completion_type system variable
is set to cause chaining or release completion by default.
Beginning a transaction causes any pending transaction to be committed. See Section 13.3.3, “Statements That Cause an Implicit Commit”, for more information.
Beginning a transaction also causes table locks acquired with
LOCK TABLES to be released, as
though you had executed
UNLOCK
TABLES. Beginning a transaction does not release a
global read lock acquired with
FLUSH TABLES WITH READ
LOCK.
For best results, transactions should be performed using only tables managed by a single transaction-safe storage engine. Otherwise, the following problems can occur:
If you use tables from more than one transaction-safe storage engine (such as
InnoDB), and the transaction isolation level is notSERIALIZABLE, it is possible that when one transaction commits, another ongoing transaction that uses the same tables will see only some of the changes made by the first transaction. That is, the atomicity of transactions is not guaranteed with mixed engines and inconsistencies can result. (If mixed-engine transactions are infrequent, you can useSET TRANSACTION ISOLATION LEVELto set the isolation level toSERIALIZABLEon a per-transaction basis as necessary.)If you use tables that are not transaction-safe within a transaction, changes to those tables are stored at once, regardless of the status of autocommit mode.
If you issue a
ROLLBACKstatement after updating a nontransactional table within a transaction, anER_WARNING_NOT_COMPLETE_ROLLBACKwarning occurs. Changes to transaction-safe tables are rolled back, but not changes to nontransaction-safe tables.
Each transaction is stored in the binary log in one chunk, upon
COMMIT. Transactions that are
rolled back are not logged.
(Exception: Modifications to
nontransactional tables cannot be rolled back. If a transaction
that is rolled back includes modifications to nontransactional
tables, the entire transaction is logged with a
ROLLBACK
statement at the end to ensure that modifications to the
nontransactional tables are replicated.) See
Section 5.2.4, “The Binary Log”.
You can change the isolation level or access mode for transactions
with the SET TRANSACTION statement.
See Section 13.3.6, “SET TRANSACTION Syntax”.
Rolling back can be a slow operation that may occur implicitly
without the user having explicitly asked for it (for example, when
an error occurs). Because of this, SHOW
PROCESSLIST displays Rolling back in
the State column for the session, not only for
explicit rollbacks performed with the
ROLLBACK
statement but also for implicit rollbacks.
In MySQL 5.6, BEGIN,
COMMIT, and ROLLBACK are
not affected by --replicate-do-db
or --replicate-ignore-db rules.
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