This section describes lock types used by InnoDB
.
InnoDB
implements standard row-level locking where there are two types of locks, shared (S
) locks and exclusive (X
) locks.
A shared (S
) lock permits the transaction that holds the lock to read a row.
An exclusive (X
) lock permits the transaction that holds the lock to update or delete a row.
If transaction T1
holds a shared (S
) lock on row r
, then requests from some distinct transaction T2
for a lock on row r
are handled as follows:
A request by T2
for an S
lock can be granted immediately. As a result, both T1
and T2
hold an S
lock on r
.
A request by T2
for an X
lock cannot be granted immediately.
If a transaction T1
holds an exclusive (X
) lock on row r
, a request from some distinct transaction T2
for a lock of either type on r
cannot be granted immediately. Instead, transaction T2
has to wait for transaction T1
to release its lock on row r
.
InnoDB
supports multiple granularity locking which permits coexistence of row locks and table locks. For example, a statement such as LOCK TABLES ... WRITE
takes an exclusive lock (an X
lock) on the specified table. To make locking at multiple granularity levels practical, InnoDB
uses intention locks. Intention locks are table-level locks that indicate which type of lock (shared or exclusive) a transaction requires later for a row in a table. There are two types of intention locks:
An intention shared lock (IS
) indicates that a transaction intends to set a shared lock on individual rows in a table.
An intention exclusive lock (IX
) indicates that a transaction intends to set an exclusive lock on individual rows in a table.
For example, SELECT ... LOCK IN SHARE MODE
sets an IS
lock, and SELECT ... FOR UPDATE
sets an IX
lock.
The intention locking protocol is as follows:
Before a transaction can acquire a shared lock on a row in a table, it must first acquire an IS
lock or stronger on the table.
Before a transaction can acquire an exclusive lock on a row in a table, it must first acquire an IX
lock on the table.
Table-level lock type compatibility is summarized in the following matrix.
X | IX | S | IS | |
---|---|---|---|---|
X | Conflict | Conflict | Conflict | Conflict |
IX | Conflict | Compatible | Conflict | Compatible |
S | Conflict | Conflict | Compatible | Compatible |
IS | Conflict | Compatible | Compatible | Compatible |
A lock is granted to a requesting transaction if it is compatible with existing locks, but not if it conflicts with existing locks. A transaction waits until the conflicting existing lock is released. If a lock request conflicts with an existing lock and cannot be granted because it would cause deadlock, an error occurs.
Intention locks do not block anything except full table requests (for example, LOCK TABLES ... WRITE
). The main purpose of intention locks is to show that someone is locking a row, or going to lock a row in the table.
Transaction data for an intention lock appears similar to the following in SHOW ENGINE INNODB STATUS
and InnoDB monitor output:
TABLE LOCK table `test`.`t` trx id 10080 lock mode IX
A record lock is a lock on an index record. For example, SELECT c1 FROM t WHERE c1 = 10 FOR UPDATE;
prevents any other transaction from inserting, updating, or deleting rows where the value of t.c1
is 10
.
Record locks always lock index records, even if a table is defined with no indexes. For such cases, InnoDB
creates a hidden clustered index and uses this index for record locking. See Section 14.6.2.1, “Clustered and Secondary Indexes”.
Transaction data for a record lock appears similar to the following in SHOW ENGINE INNODB STATUS
and InnoDB monitor output:
RECORD LOCKS space id 58 page no 3 n bits 72 index `PRIMARY` of table `test`.`t` trx id 10078 lock_mode X locks rec but not gap Record lock, heap no 2 PHYSICAL RECORD: n_fields 3; compact format; info bits 0 0: len 4; hex 8000000a; asc ;; 1: len 6; hex 00000000274f; asc ‘O;; 2: len 7; hex b60000019d0110; asc ;;
A gap lock is a lock on a gap between index records, or a lock on the gap before the first or after the last index record. For example, SELECT c1 FROM t WHERE c1 BETWEEN 10 and 20 FOR UPDATE;
prevents other transactions from inserting a value of 15
into column t.c1
, whether or not there was already any such value in the column, because the gaps between all existing values in the range are locked.
A gap might span a single index value, multiple index values, or even be empty.
Gap locks are part of the tradeoff between performance and concurrency, and are used in some transaction isolation levels and not others.
Gap locking is not needed for statements that lock rows using a unique index to search for a unique row. (This does not include the case that the search condition includes only some columns of a multiple-column unique index; in that case, gap locking does occur.) For example, if the id
column has a unique index, the following statement uses only an index-record lock for the row having id
value 100 and it does not matter whether other sessions insert rows in the preceding gap:
SELECT * FROM child WHERE id = 100;
If id
is not indexed or has a nonunique index, the statement does lock the preceding gap.
It is also worth noting here that conflicting locks can be held on a gap by different transactions. For example, transaction A can hold a shared gap lock (gap S-lock) on a gap while transaction B holds an exclusive gap lock (gap X-lock) on the same gap. The reason conflicting gap locks are allowed is that if a record is purged from an index, the gap locks held on the record by different transactions must be merged.
Gap locks in InnoDB
are “purely inhibitive”, which means that their only purpose is to prevent other transactions from inserting to the gap. Gap locks can co-exist. A gap lock taken by one transaction does not prevent another transaction from taking a gap lock on the same gap. There is no difference between shared and exclusive gap locks. They do not conflict with each other, and they perform the same function.
Gap locking can be disabled explicitly. This occurs if you change the transaction isolation level to READ COMMITTED
or enable theinnodb_locks_unsafe_for_binlog
system variable (which is now deprecated). Under these circumstances, gap locking is disabled for searches and index scans and is used only for foreign-key constraint checking and duplicate-key checking.
There are also other effects of using the READ COMMITTED
isolation level or enabling innodb_locks_unsafe_for_binlog
. Record locks for nonmatching rows are released after MySQL has evaluated the WHERE
condition. For UPDATE
statements, InnoDB
does a “semi-consistent” read, such that it returns the latest committed version to MySQL so that MySQL can determine whether the row matches the WHERE
condition of the UPDATE
.
A next-key lock is a combination of a record lock on the index record and a gap lock on the gap before the index record.
InnoDB
performs row-level locking in such a way that when it searches or scans a table index, it sets shared or exclusive locks on the index records it encounters. Thus, the row-level locks are actually index-record locks. A next-key lock on an index record also affects the “gap” before that index record. That is, a next-key lock is an index-record lock plus a gap lock on the gap preceding the index record. If one session has a shared or exclusive lock on record R
in an index, another session cannot insert a new index record in the gap immediately before R
in the index order.
Suppose that an index contains the values 10, 11, 13, and 20. The possible next-key locks for this index cover the following intervals, where a round bracket denotes exclusion of the interval endpoint and a square bracket denotes inclusion of the endpoint:
(negative infinity, 10](10, 11](11, 13](13, 20](20, positive infinity)
For the last interval, the next-key lock locks the gap above the largest value in the index and the “supremum” pseudo-record having a value higher than any value actually in the index. The supremum is not a real index record, so, in effect, this next-key lock locks only the gap following the largest index value.
By default, InnoDB
operates in REPEATABLE READ
transaction isolation level. In this case, InnoDB
uses next-key locks for searches and index scans, which prevents phantom rows (see Section 14.7.4, “Phantom Rows”).
Transaction data for a next-key lock appears similar to the following in SHOW ENGINE INNODB STATUS
and InnoDB monitor output:
RECORD LOCKS space id 58 page no 3 n bits 72 index `PRIMARY` of table `test`.`t` trx id 10080 lock_mode X Record lock, heap no 1 PHYSICAL RECORD: n_fields 1; compact format; info bits 0 0: len 8; hex 73757072656d756d; asc supremum;; Record lock, heap no 2 PHYSICAL RECORD: n_fields 3; compact format; info bits 0 0: len 4; hex 8000000a; asc ;; 1: len 6; hex 00000000274f; asc ‘O;; 2: len 7; hex b60000019d0110; asc ;;
An insert intention lock is a type of gap lock set by INSERT
operations prior to row insertion. This lock signals the intent to insert in such a way that multiple transactions inserting into the same index gap need not wait for each other if they are not inserting at the same position within the gap. Suppose that there are index records with values of 4 and 7. Separate transactions that attempt to insert values of 5 and 6, respectively, each lock the gap between 4 and 7 with insert intention locks prior to obtaining the exclusive lock on the inserted row, but do not block each other because the rows are nonconflicting.
The following example demonstrates a transaction taking an insert intention lock prior to obtaining an exclusive lock on the inserted record. The example involves two clients, A and B.
Client A creates a table containing two index records (90 and 102) and then starts a transaction that places an exclusive lock on index records with an ID greater than 100. The exclusive lock includes a gap lock before record 102:
mysql> CREATE TABLE child (id int(11) NOT NULL, PRIMARY KEY(id)) ENGINE=InnoDB; mysql> INSERT INTO child (id) values (90),(102); mysql> START TRANSACTION; mysql> SELECT * FROM child WHERE id > 100 FOR UPDATE; +-----+ | id | +-----+ | 102 | +-----+
Client B begins a transaction to insert a record into the gap. The transaction takes an insert intention lock while it waits to obtain an exclusive lock.
mysql> START TRANSACTION; mysql> INSERT INTO child (id) VALUES (101);
Transaction data for an insert intention lock appears similar to the following in SHOW ENGINE INNODB STATUS
and InnoDB monitor output:
RECORD LOCKS space id 31 page no 3 n bits 72 index `PRIMARY` of table `test`.`child` trx id 8731 lock_mode X locks gap before rec insert intention waiting Record lock, heap no 3 PHYSICAL RECORD: n_fields 3; compact format; info bits 0 0: len 4; hex 80000066; asc f;; 1: len 6; hex 000000002215; asc " ;; 2: len 7; hex 9000000172011c; asc r ;;...
An AUTO-INC
lock is a special table-level lock taken by transactions inserting into tables with AUTO_INCREMENT
columns. In the simplest case, if one transaction is inserting values into the table, any other transactions must wait to do their own inserts into that table, so that rows inserted by the first transaction receive consecutive primary key values.
The innodb_autoinc_lock_mode
configuration option controls the algorithm used for auto-increment locking. It allows you to choose how to trade off between predictable sequences of auto-increment values and maximum concurrency for insert operations.
For more information, see Section 14.6.1.4, “AUTO_INCREMENT Handling in InnoDB”.
InnoDB
supports SPATIAL
indexing of columns containing spatial columns (see Section 11.5.8, “Optimizing Spatial Analysis”).
To handle locking for operations involving SPATIAL
indexes, next-key locking does not work well to support REPEATABLE READ
or SERIALIZABLE
transaction isolation levels. There is no absolute ordering concept in multidimensional data, so it is not clear which is the “next” key.
To enable support of isolation levels for tables with SPATIAL
indexes, InnoDB
uses predicate locks. A SPATIAL
index contains minimum bounding rectangle (MBR) values, so InnoDB
enforces consistent read on the index by setting a predicate lock on the MBR value used for a query. Other transactions cannot insert or modify a row that would match the query condition.
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The so-called phantom problem occurs within a transaction when the same query produces different sets of rows at different times. For example, if a SELECT
is executed twice, but returns a row the second time that was not returned the first time, the row is a “phantom” row.
Suppose that there is an index on the id
column of the child
table and that you want to read and lock all rows from the table having an identifier value larger than 100, with the intention of updating some column in the selected rows later:
SELECT * FROM child WHERE id > 100 FOR UPDATE;
The query scans the index starting from the first record where id
is bigger than 100. Let the table contain rows having id
values of 90 and 102. If the locks set on the index records in the scanned range do not lock out inserts made in the gaps (in this case, the gap between 90 and 102), another session can insert a new row into the table with an id
of 101. If you were to execute the same SELECT
within the same transaction, you would see a new row with an id
of 101 (a“phantom”) in the result set returned by the query. If we regard a set of rows as a data item, the new phantom child would violate the isolation principle of transactions that a transaction should be able to run so that the data it has read does not change during the transaction.
To prevent phantoms, InnoDB
uses an algorithm called next-key locking that combines index-row locking with gap locking. InnoDB
performs row-level locking in such a way that when it searches or scans a table index, it sets shared or exclusive locks on the index records it encounters. Thus, the row-level locks are actually index-record locks. In addition, a next-key lock on an index record also affects the “gap” before that index record. That is, a next-key lock is an index-record lock plus a gap lock on the gap preceding the index record. If one session has a shared or exclusive lock on record R
in an index, another session cannot insert a new index record in the gap immediately before R
in the index order.
When InnoDB
scans an index, it can also lock the gap after the last record in the index. Just that happens in the preceding example: To prevent any insert into the table where id
would be bigger than 100, the locks set by InnoDB
include a lock on the gap following id
value 102.
You can use next-key locking to implement a uniqueness check in your application: If you read your data in share mode and do not see a duplicate for a row you are going to insert, then you can safely insert your row and know that the next-key lock set on the successor of your row during the read prevents anyone meanwhile inserting a duplicate for your row. Thus, the next-key locking enables you to “lock” the nonexistence of something in your table.
Gap locking can be disabled as discussed in Section 14.7.1, “InnoDB Locking”. This may cause phantom problems because other sessions can insert new rows into the gaps when gap locking is disabled.
参考:
https://dev.mysql.com/doc/refman/5.7/en/innodb-locking.html
https://dev.mysql.com/doc/refman/5.7/en/innodb-next-key-locking.html