MySQL之Innodb锁机制:Next-Key Lock 浅谈

阅读《InnoDB存储引擎》-第六章涉及锁的三种算法,整理结合转载文档:https://www.cnblogs.com/zhoujinyi/p/3435982.html

数据库使用锁是为了支持更好的并发,提供数据的完整性和一致性。InnoDB是一个支持行锁的存储引擎,锁的类型有:共享锁(S)、排他锁(X)、意向共享(IS)、意向排他(IX)。为了提供更好的并发,InnoDB提供了非锁定读:不需要等待访问行上的锁释放,读取行的一个快照。该方法是通过InnoDB的一个特性:MVCC来实现的。

InnoDB有三种行锁的算法:

1,Record Lock:单个行记录上的锁。

2,Gap Lock:间隙锁,锁定一个范围,但不包括记录本身。GAP锁的目的,是为了防止同一事务的两次当前读,出现幻读的情况。

3,Next-Key Lock:1+2,锁定一个范围,并且锁定记录本身。对于行的查询,都是采用该方法,主要目的是解决幻读的问题。

测试一:默认RR隔离级别

 

root@localhost : test 10:56:10>create table t(a int,key idx_a(a))engine =innodb;
Query OK, 0 rows affected (0.20 sec)

root@localhost : test 10:56:13>insert into t values(1),(3),(5),(8),(11);
Query OK, 5 rows affected (0.00 sec)
Records: 5  Duplicates: 0  Warnings: 0

root@localhost : test 10:56:15>select * from t;
+------+
| a    |
+------+
|    1 |
|    3 |
|    5 |
|    8 |
|   11 |
+------+
5 rows in set (0.00 sec)

section A:

root@localhost : test 10:56:27>start transaction;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 10:56:29>select * from t where a = 8 for update;
+------+
| a    |
+------+
|    8 |
+------+
1 row in set (0.00 sec)


section B:
root@localhost : test 10:54:50>begin;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 10:56:51>select * from t;
+------+
| a    |
+------+
|    1 |
|    3 |
|    5 |
|    8 |
|   11 |
+------+
5 rows in set (0.00 sec)

root@localhost : test 10:56:54>insert into t values(2);
Query OK, 1 row affected (0.00 sec)

root@localhost : test 10:57:01>insert into t values(4);
Query OK, 1 row affected (0.00 sec)

++++++++++
root@localhost : test 10:57:04>insert into t values(6);

root@localhost : test 10:57:11>insert into t values(7);

root@localhost : test 10:57:15>insert into t values(9);

root@localhost : test 10:57:33>insert into t values(10);
++++++++++
上面全被锁住,阻塞住了

root@localhost : test 10:57:39>insert into t values(12);
Query OK, 1 row affected (0.00 sec)

 

问题:

为什么section B上面的插入语句会出现锁等待的情况?InnoDB是行锁,在section A里面锁住了a=8的行,其他应该不受影响。why?

分析:

因为InnoDB对于行的查询都是采用了Next-Key Lock的算法,锁定的不是单个值,而是一个范围(GAP)。上面索引值有1,3,5,8,11,其记录的GAP的区间如下:是一个左开右闭的空间(原因是默认主键的有序自增的特性,结合后面的例子说明)

(-∞,1],(1,3],(3,5],(5,8],(8,11],(11,+∞)

特别需要注意的是,InnoDB存储引擎还会对辅助索引下一个键值加上gap lock。如上面分析,那就可以解释了。

 

root@localhost : test 10:56:29>select * from t where a = 8 for update;
+------+
| a    |
+------+
|    8 |
+------+
1 row in set (0.00 sec)

 

该SQL语句锁定的范围是(5,8],下个下个键值范围是(8,11],所以插入5~11之间的值的时候都会被锁定,要求等待。即:插入5,6,7,8,9,10 会被锁住。插入非这个范围内的值都正常。

################################### 2016-07-21 更新 

因为例子里没有主键,所以要用隐藏的ROWID来代替,数据根据Rowid进行排序。而Rowid是有一定顺序的(自增),所以其中11可以被写入,5不能被写入,不清楚的可以再看一个有主键的例子:

 

会话1:
01:43:07>create table t(id int,name varchar(10),key idx_id(id),primary key(name))engine =innodb;
Query OK, 0 rows affected (0.02 sec)

01:43:11>insert into t values(1,'a'),(3,'c'),(5,'e'),(8,'g'),(11,'j');                                                                               
Query OK, 5 rows affected (0.01 sec)
Records: 5  Duplicates: 0  Warnings: 0

01:44:03>select @@global.tx_isolation, @@tx_isolation;                                                                                                 +-----------------------+-----------------+
| @@global.tx_isolation | @@tx_isolation  |
+-----------------------+-----------------+
| REPEATABLE-READ       | REPEATABLE-READ |
+-----------------------+-----------------+
1 row in set (0.01 sec)

01:44:58>select * from t;
+------+------+
| id   | name |
+------+------+
|    1 | a    |
|    3 | c    |
|    5 | e    |
|    8 | g    |
|   11 | j    |
+------+------+
5 rows in set (0.00 sec)

01:45:07>start transaction;              

01:45:09>delete from t where id=8;
Query OK, 1 row affected (0.01 sec)


会话2:
01:50:38>select @@global.tx_isolation, @@tx_isolation;
+-----------------------+-----------------+
| @@global.tx_isolation | @@tx_isolation  |
+-----------------------+-----------------+
| REPEATABLE-READ       | REPEATABLE-READ |
+-----------------------+-----------------+
1 row in set (0.01 sec)

01:50:48>start transaction; 

01:50:51>select * from t;
+------+------+
| id   | name |
+------+------+
|    1 | a    |
|    3 | c    |
|    5 | e    |
|    8 | g    |
|   11 | j    |
+------+------+
5 rows in set (0.01 sec)

01:51:35>insert into t(id,name) values(6,'f');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:53:32>insert into t(id,name) values(5,'e1');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:53:41>insert into t(id,name) values(7,'h');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:54:43>insert into t(id,name) values(8,'gg');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:55:10>insert into t(id,name) values(9,'k');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:55:23>insert into t(id,name) values(10,'p');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

01:55:33>insert into t(id,name) values(11,'iz');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted

#########上面看到 id:5,6,7,8,9,10,11都被锁了。

#########下面看到 id:5,11 还是可以插入的
01:54:33>insert into t(id,name) values(5,'cz');
Query OK, 1 row affected (0.01 sec)

01:55:59>insert into t(id,name) values(11,'ja');
Query OK, 1 row affected (0.01 sec)

 

分析:因为会话1已经对id=8的记录加了一个X锁,由于是RR隔离级别,INNODB要防止幻读需要加GAP锁:即id=5(8的左边),id=11(8的右边)之间需要加间隙锁(GAP)。这样[5,e]和[8,g],[8,g]和[11,j]之间的数据都要被锁。上面测试已经验证了这一点,根据索引的有序性,数据按照主键(name)排序,后面写入的[5,cz]([5,e]的左边)和[11,ja]([11,j]的右边)不属于上面的范围从而可以写入。

另外一种情况,把name主键去掉会是怎么样的情况?有兴趣的同学可以测试一下。

##################################################

继续:插入超时失败后,会怎么样?

超时时间的参数:innodb_lock_wait_timeout ,默认是50秒。
超时是否回滚参数:innodb_rollback_on_timeout 默认是OFF。

 

section A:

root@localhost : test 04:48:51>start transaction;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 04:48:53>select * from t where a = 8 for update;
+------+
| a    |
+------+
|    8 |
+------+
1 row in set (0.01 sec)


section B:

root@localhost : test 04:49:04>start transaction;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 04:49:07>insert into t values(12);
Query OK, 1 row affected (0.00 sec)

root@localhost : test 04:49:13>insert into t values(10);
ERROR 1205 (HY000): Lock wait timeout exceeded; try restarting transaction
root@localhost : test 04:50:06>select * from t;
+------+
| a    |
+------+
|    1 |
|    3 |
|    5 |
|    8 |
|   11 |
|   12 |
+------+
6 rows in set (0.00 sec)

经过测试,不会回滚超时引发的异常,当参数innodb_rollback_on_timeout 设置成ON时,则可以回滚,会把插进去的12回滚掉。

默认情况下,InnoDB存储引擎不会回滚超时引发的异常,除死锁外。

既然InnoDB有三种算法,那Record Lock什么时候用?还是用上面的列子,把辅助索引改成唯一属性的索引。

测试二:

 

root@localhost : test 04:58:49>create table t(a int primary key)engine =innodb;
Query OK, 0 rows affected (0.19 sec)

root@localhost : test 04:59:02>insert into t values(1),(3),(5),(8),(11);
Query OK, 5 rows affected (0.00 sec)
Records: 5  Duplicates: 0  Warnings: 0

root@localhost : test 04:59:10>select * from t;
+----+
| a  |
+----+
|  1 |
|  3 |
|  5 |
|  8 |
| 11 |
+----+
5 rows in set (0.00 sec)

section A:

root@localhost : test 04:59:30>start transaction;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 04:59:33>select * from t where a = 8 for update;
+---+
| a |
+---+
| 8 |
+---+
1 row in set (0.00 sec)

section B:

root@localhost : test 04:58:41>start transaction;
Query OK, 0 rows affected (0.00 sec)

root@localhost : test 04:59:45>insert into t values(6);
Query OK, 1 row affected (0.00 sec)

root@localhost : test 05:00:05>insert into t values(7);
Query OK, 1 row affected (0.00 sec)

root@localhost : test 05:00:08>insert into t values(9);
Query OK, 1 row affected (0.00 sec)

root@localhost : test 05:00:10>insert into t values(10);
Query OK, 1 row affected (0.00 sec)

 

问题:

为什么section B上面的插入语句可以正常,和测试一不一样?

分析:

因为InnoDB对于行的查询都是采用了Next-Key Lock的算法,锁定的不是单个值,而是一个范围,按照这个方法是会和第一次测试结果一样。但是,当查询的索引含有唯一属性的时候,Next-Key Lock 会进行优化,将其降级为Record Lock,即仅锁住索引本身,不是范围。

注意:通过主键或则唯一索引来锁定不存在的值,也会产生GAP锁定。即: 

 

会话1:
04:22:38>show create table t\G
*************************** 1. row ***************************
       Table: t
Create Table: CREATE TABLE `t` (
  `id` int(11) NOT NULL,
  `name` varchar(10) DEFAULT NULL,
  PRIMARY KEY (`id`)
) ENGINE=InnoDB DEFAULT CHARSET=utf8mb4
1 row in set (0.00 sec)

04:22:49>start transaction;

04:23:16>select * from t where id = 15 for update;
Empty set (0.00 sec)

会话2:
04:26:10>insert into t(id,name) values(10,'k');
Query OK, 1 row affected (0.01 sec)

04:26:26>insert into t(id,name) values(12,'k');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted
04:29:32>insert into t(id,name) values(16,'kxx');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted
04:29:39>insert into t(id,name) values(160,'kxx');
^CCtrl-C -- sending "KILL QUERY 9851" to server ...
Ctrl-C -- query aborted.
ERROR 1317 (70100): Query execution was interrupted 

 

如何让测试一不阻塞?可以显式的关闭Gap Lock:

1:把事务隔离级别改成:Read Committed,提交读、不可重复读。SET SESSION TRANSACTION ISOLATION LEVEL READ COMMITTED;

2:修改参数:innodb_locks_unsafe_for_binlog 设置为1。

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