MySQL 9.1 Release Notes
Transaction isolation is one of the foundations of database processing. Isolation is the I in the acronym ACID; the isolation level is the setting that fine-tunes the balance between performance and reliability, consistency, and reproducibility of results when multiple transactions are making changes and performing queries at the same time.
InnoDB offers all four transaction isolation
levels described by the SQL:1992 standard:
READ UNCOMMITTED,
READ COMMITTED,
REPEATABLE READ, and
SERIALIZABLE. The default
isolation level for InnoDB is
REPEATABLE READ.
A user can change the isolation level for a single session or
for all subsequent connections with the SET
TRANSACTION statement. To set the server's default
isolation level for all connections, use the
--transaction-isolation option on
the command line or in an option file. For detailed information
about isolation levels and level-setting syntax, see
Section 15.3.7, “SET TRANSACTION Statement”.
InnoDB supports each of the transaction
isolation levels described here using different
locking strategies. You can
enforce a high degree of consistency with the default
REPEATABLE READ level, for
operations on crucial data where
ACID compliance is important.
Or you can relax the consistency rules with
READ COMMITTED or even
READ UNCOMMITTED, in
situations such as bulk reporting where precise consistency and
repeatable results are less important than minimizing the amount
of overhead for locking.
SERIALIZABLE enforces even
stricter rules than REPEATABLE
READ, and is used mainly in specialized situations,
such as with XA transactions and
for troubleshooting issues with concurrency and
deadlocks.
The following list describes how MySQL supports the different transaction levels. The list goes from the most commonly used level to the least used.
This is the default isolation level for
InnoDB. Consistent reads within the same transaction read the snapshot established by the first read. This means that if you issue several plain (nonlocking)SELECTstatements within the same transaction, theseSELECTstatements are consistent also with respect to each other. See Section 17.7.2.3, “Consistent Nonlocking Reads”.For locking reads (
SELECTwithFOR UPDATEorFOR SHARE),UPDATE, andDELETEstatements, locking depends on whether the statement uses a unique index with a unique search condition, or a range-type search condition.For a unique index with a unique search condition,
InnoDBlocks only the index record found, not the gap before it.For other search conditions,
InnoDBlocks the index range scanned, using gap locks or next-key locks to block insertions by other sessions into the gaps covered by the range. For information about gap locks and next-key locks, see Section 17.7.1, “InnoDB Locking”.
It is not recommended to mix locking statements (
UPDATE,INSERT,DELETE, orSELECT ... FOR ...) with non-lockingSELECTstatements in a singleREPEATABLE READtransaction, because typically in such cases you wantSERIALIZABLE. This is because a non-lockingSELECTstatement presents the state of the database from a read view which consists of transactions committed before the read view was created, and before the current transaction's own writes, while the locking statements use the most recent state of the database to use locking. In general, these two different table states are inconsistent with each other and difficult to parse.Each consistent read, even within the same transaction, sets and reads its own fresh snapshot. For information about consistent reads, see Section 17.7.2.3, “Consistent Nonlocking Reads”.
For locking reads (
SELECTwithFOR UPDATEorFOR SHARE),UPDATEstatements, andDELETEstatements,InnoDBlocks only index records, not the gaps before them, and thus permits the free insertion of new records next to locked records. Gap locking is only used for foreign-key constraint checking and duplicate-key checking.Because gap locking is disabled, phantom row problems may occur, as other sessions can insert new rows into the gaps. For information about phantom rows, see Section 17.7.4, “Phantom Rows”.
Only row-based binary logging is supported with the
READ COMMITTEDisolation level. If you useREAD COMMITTEDwithbinlog_format=MIXED, the server automatically uses row-based logging.Using
READ COMMITTEDhas additional effects:For
UPDATEorDELETEstatements,InnoDBholds locks only for rows that it updates or deletes. Record locks for nonmatching rows are released after MySQL has evaluated theWHEREcondition. This greatly reduces the probability of deadlocks, but they can still happen.For
UPDATEstatements, if a row is already locked,InnoDBperforms a “semi-consistent” read, returning the latest committed version to MySQL so that MySQL can determine whether the row matches theWHEREcondition of theUPDATE. If the row matches (must be updated), MySQL reads the row again and this timeInnoDBeither locks it or waits for a lock on it.
Consider the table created and populated like this:
CREATE TABLE t (a INT NOT NULL, b INT) ENGINE = InnoDB; INSERT INTO t VALUES (1,2),(2,3),(3,2),(4,3),(5,2); COMMIT;In this case, the table has no indexes, so searches and index scans use the hidden clustered index for record locking (see Section 17.6.2.1, “Clustered and Secondary Indexes”) rather than indexed columns.
Suppose that one session performs an
UPDATEusing these statements:# Session A START TRANSACTION; UPDATE t SET b = 5 WHERE b = 3;Suppose also that a second session performs an
UPDATEby executing these statements following those of the first session:# Session B UPDATE t SET b = 4 WHERE b = 2;As
InnoDBexecutes eachUPDATE, it first acquires an exclusive lock for each row, and then determines whether to modify it. IfInnoDBdoes not modify the row, it releases the lock. Otherwise,InnoDBretains the lock until the end of the transaction. This affects transaction processing as follows.When using the default
REPEATABLE READisolation level, the firstUPDATEacquires an x-lock on each row that it reads and does not release any of them:x-lock(1,2); retain x-lock x-lock(2,3); update(2,3) to (2,5); retain x-lock x-lock(3,2); retain x-lock x-lock(4,3); update(4,3) to (4,5); retain x-lock x-lock(5,2); retain x-lockThe second
UPDATEblocks as soon as it tries to acquire any locks (because first update has retained locks on all rows), and does not proceed until the firstUPDATEcommits or rolls back:x-lock(1,2); block and wait for first UPDATE to commit or roll backIf
READ COMMITTEDis used instead, the firstUPDATEacquires an x-lock on each row that it reads and releases those for rows that it does not modify:x-lock(1,2); unlock(1,2) x-lock(2,3); update(2,3) to (2,5); retain x-lock x-lock(3,2); unlock(3,2) x-lock(4,3); update(4,3) to (4,5); retain x-lock x-lock(5,2); unlock(5,2)For the second
UPDATE,InnoDBdoes a “semi-consistent” read, returning the latest committed version of each row that it reads to MySQL so that MySQL can determine whether the row matches theWHEREcondition of theUPDATE:x-lock(1,2); update(1,2) to (1,4); retain x-lock x-lock(2,3); unlock(2,3) x-lock(3,2); update(3,2) to (3,4); retain x-lock x-lock(4,3); unlock(4,3) x-lock(5,2); update(5,2) to (5,4); retain x-lockHowever, if the
WHEREcondition includes an indexed column, andInnoDBuses the index, only the indexed column is considered when taking and retaining record locks. In the following example, the firstUPDATEtakes and retains an x-lock on each row where b = 2. The secondUPDATEblocks when it tries to acquire x-locks on the same records, as it also uses the index defined on column b.CREATE TABLE t (a INT NOT NULL, b INT, c INT, INDEX (b)) ENGINE = InnoDB; INSERT INTO t VALUES (1,2,3),(2,2,4); COMMIT; # Session A START TRANSACTION; UPDATE t SET b = 3 WHERE b = 2 AND c = 3; # Session B UPDATE t SET b = 4 WHERE b = 2 AND c = 4;The
READ COMMITTEDisolation level can be set at startup or changed at runtime. At runtime, it can be set globally for all sessions, or individually per session.SELECTstatements are performed in a nonlocking fashion, but a possible earlier version of a row might be used. Thus, using this isolation level, such reads are not consistent. This is also called a dirty read. Otherwise, this isolation level works likeREAD COMMITTED.This level is like
REPEATABLE READ, butInnoDBimplicitly converts all plainSELECTstatements toSELECT ... FOR SHAREifautocommitis disabled. Ifautocommitis enabled, theSELECTis its own transaction. It therefore is known to be read only and can be serialized if performed as a consistent (nonlocking) read and need not block for other transactions. (To force a plainSELECTto block if other transactions have modified the selected rows, disableautocommit.)DML operations that read data from MySQL grant tables (through a join list or subquery) but do not modify them do not acquire read locks on the MySQL grant tables, regardless of the isolation level. For more information, see Grant Table Concurrency.