Java的Hibernate框架数据库操作中锁的使用和查询类型
发布于 2016-08-08 04:14:39 | 115 次阅读 | 评论: 0 | 来源: 网友投递
Hibernate 开源对象关系映射框架 ORM
Hibernate是一个开放源代码的对象关系映射框架,它对JDBC进行了非常轻量级的对象封装,使得Java程序员可以随心所欲的使用对象编程思维来操纵数据库。 Hibernate可以应用在任何使用JDBC的场合,既可以在Java的客户端程序使用,也可以在Servlet/JSP的Web应用中使用,最具革命意义的是,Hibernate可以在应用EJB的J2EE架构中取代CMP,完成数据持久化的重任。
这篇文章主要介绍了Java的Hibernate框架数据库操作中锁的使用和查询类型,Hibernate是Java的SSH三大web开发框架之一,需要的朋友可以参考下
Hibernate与数据库锁
一、为什么要使用锁?
要想弄清楚锁机制存在的原因,首先要了解事务的概念。
事务是对数据库一系列相关的操作,它必须具备ACID特征:
- A(原子性):要么全部成功,要么全部撤销。
- C(一致性):要保持数据库的一致性。
- I(隔离性):不同事务操作相同数据时,要有各自的数据空间。
- D(持久性):一旦事务成功结束,它对数据库所做的更新必须永久保持。
我们常用的关系型数据库RDBMS实现了事务的这些特性。其中,原子性、
一致性和持久性都是采用日志来保证的。而隔离性就是由今天我们关注的
锁机制来实现的,这就是为什么我们需要锁机制。
如果没有锁,对隔离性不加控制,可能会造成哪些后果呢?
- 更新丢失:事务1提交的数据被事务2覆盖。
- 脏读:事务2查询到了事务1未提交的数据。
- 虚读:事务2查询到了事务1提交的新建数据。
- 不可重复读:事务2查询到了事务1提交的更新数据。
下面来看Hibernate的例子,两个线程分别开启两个事务操作tb_account表中
的同一行数据col_id=1。
package com.cdai.orm.hibernate.annotation;
import java.io.Serializable;
import javax.persistence.Column;
import javax.persistence.Entity;
import javax.persistence.Id;
import javax.persistence.Table;
@Entity
@Table(name = "tb_account")
public class Account implements Serializable {
private static final long serialVersionUID = 5018821760412231859L;
@Id
@Column(name = "col_id")
private long id;
@Column(name = "col_balance")
private long balance;
public Account() {
}
public Account(long id, long balance) {
this.id = id;
this.balance = balance;
}
public long getId() {
return id;
}
public void setId(long id) {
this.id = id;
}
public long getBalance() {
return balance;
}
public void setBalance(long balance) {
this.balance = balance;
}
@Override
public String toString() {
return "Account [id=" + id + ", balance=" + balance + "]";
}
}
package com.cdai.orm.hibernate.transaction;
import org.hibernate.Session;
import org.hibernate.SessionFactory;
import org.hibernate.Transaction;
import org.hibernate.cfg.AnnotationConfiguration;
import com.cdai.orm.hibernate.annotation.Account;
public class DirtyRead {
public static void main(String[] args) {
final SessionFactory sessionFactory = new AnnotationConfiguration().
addFile("hibernate/hibernate.cfg.xml").
configure().
addPackage("com.cdai.orm.hibernate.annotation").
addAnnotatedClass(Account.class).
buildSessionFactory();
Thread t1 = new Thread() {
@Override
public void run() {
Session session1 = sessionFactory.openSession();
Transaction tx1 = null;
try {
tx1 = session1.beginTransaction();
System.out.println("T1 - Begin trasaction");
Thread.sleep(500);
Account account = (Account)
session1.get(Account.class, new Long(1));
System.out.println("T1 - balance=" + account.getBalance());
Thread.sleep(500);
account.setBalance(account.getBalance() + 100);
System.out.println("T1 - Change balance:" + account.getBalance());
tx1.commit();
System.out.println("T1 - Commit transaction");
Thread.sleep(500);
}
catch (Exception e) {
e.printStackTrace();
if (tx1 != null)
tx1.rollback();
}
finally {
session1.close();
}
}
};
// 3.Run transaction 2
Thread t2 = new Thread() {
@Override
public void run() {
Session session2 = sessionFactory.openSession();
Transaction tx2 = null;
try {
tx2 = session2.beginTransaction();
System.out.println("T2 - Begin trasaction");
Thread.sleep(500);
Account account = (Account)
session2.get(Account.class, new Long(1));
System.out.println("T2 - balance=" + account.getBalance());
Thread.sleep(500);
account.setBalance(account.getBalance() - 100);
System.out.println("T2 - Change balance:" + account.getBalance());
tx2.commit();
System.out.println("T2 - Commit transaction");
Thread.sleep(500);
}
catch (Exception e) {
e.printStackTrace();
if (tx2 != null)
tx2.rollback();
}
finally {
session2.close();
}
}
};
t1.start();
t2.start();
while (t1.isAlive() || t2.isAlive()) {
try {
Thread.sleep(2000L);
} catch (InterruptedException e) {
}
}
System.out.println("Both T1 and T2 are dead.");
sessionFactory.close();
}
}
事务1将col_balance减小100,而事务2将其减少100,最终结果可能是0,也
可能是200,事务1或2的更新可能会丢失。log输出也印证了这一点,事务1和2
的log交叉打印。
T1 - Begin trasaction
T2 - Begin trasaction
Hibernate: select account0_.col_id as col1_0_0_, account0_.col_balance as col2_0_0_ from tb_account account0_ where account0_.col_id=?
Hibernate: select account0_.col_id as col1_0_0_, account0_.col_balance as col2_0_0_ from tb_account account0_ where account0_.col_id=?
T1 - balance=100
T2 - balance=100
T2 - Change balance:0
T1 - Change balance:200
Hibernate: update tb_account set col_balance=? where col_id=?
Hibernate: update tb_account set col_balance=? where col_id=?
T1 - Commit transaction
T2 - Commit transaction
Both T1 and T2 are dead.
由此可见,隔离性是一个需要慎重考虑的问题,理解锁很有必要。
二、有多少种锁?
常见的有共享锁、更新锁和独占锁。
1.共享锁:用于读数据操作,允许其他事务同时读取。当事务执行select语句时,
数据库自动为事务分配一把共享锁来锁定读取的数据。
2.独占锁:用于修改数据,其他事务不能读取也不能修改。当事务执行insert、
update和delete时,数据库会自动分配。
3.更新锁:用于避免更新操作时共享锁造成的死锁,比如事务1和2同时持有
共享锁并等待获得独占锁。当执行update时,事务先获得更新锁,然后将
更新锁升级成独占锁,这样就避免了死锁。
此外,这些锁都可以施加到数据库中不同的对象上,即这些锁可以有不同的粒度。
如数据库级锁、表级锁、页面级锁、键级锁和行级锁。
所以锁是有很多种的,这么多锁要想完全掌握灵活使用太难了,我们又不是DBA。
怎么办?还好,锁机制对于我们一般用户来说是透明的,数据库会自动添加合适的
锁,并在适当的时机自动升级、降级各种锁,真是太周到了!我们只需要做的就是
学会根据不同的业务需求,设置好隔离级别就可以了。
三、怎样设置隔离级别?
一般来说,数据库系统会提供四种事务隔离级别供用户选择:
1.Serializable(串行化):当两个事务同时操纵相同数据时,事务2只能停下来等。
2.Repeatable Read(可重复读):事务1能看到事务2新插入的数据,不能看到对
已有数据的更新。
3.Read Commited(读已提交数据):事务1能看到事务2新插入和更新的数据。
4.Read Uncommited(读未提交数据):事务1能看到事务2没有提交的插入和更新
数据。
四、应用程序中的锁
当数据库采用Read Commited隔离级别时,可以在应用程序中采用悲观锁或乐观锁。
1.悲观锁:假定当前事务操作的数据肯定还会有其他事务访问,因此悲观地在应用
程序中显式指定采用独占锁来锁定数据资源。在MySQL、Oracle中支持以下形式:
select ... for update
显式地让select采用独占锁锁定查询的记录,其他事务要查询、更新或删除这些被
锁定的数据,都要等到该事务结束后才行。
在Hibernate中,可以在load时传入LockMode.UPGRADE来采用悲观锁。修改前面的例子,
在事务1和2的get方法调用处,多传入一个LockMode参数。从log中可以看出,事务1和2
不再是交叉运行,事务2等待事务1结束后才可以读取数据,所以最终col_balance值是正确
的100。
package com.cdai.orm.hibernate.transaction;
import org.hibernate.LockMode;
import org.hibernate.Session;
import org.hibernate.SessionFactory;
import org.hibernate.Transaction;
import com.cdai.orm.hibernate.annotation.Account;
import com.cdai.orm.hibernate.annotation.AnnotationHibernate;
public class UpgradeLock {
@SuppressWarnings("deprecation")
public static void main(String[] args) {
final SessionFactory sessionFactory = AnnotationHibernate.createSessionFactory();
// Run transaction 1
Thread t1 = new Thread() {
@Override
public void run() {
Session session1 = sessionFactory.openSession();
Transaction tx1 = null;
try {
tx1 = session1.beginTransaction();
System.out.println("T1 - Begin trasaction");
Thread.sleep(500);
Account account = (Account)
session1.get(Account.class, new Long(1), LockMode.UPGRADE);
System.out.println("T1 - balance=" + account.getBalance());
Thread.sleep(500);
account.setBalance(account.getBalance() + 100);
System.out.println("T1 - Change balance:" + account.getBalance());
tx1.commit();
System.out.println("T1 - Commit transaction");
Thread.sleep(500);
}
catch (Exception e) {
e.printStackTrace();
if (tx1 != null)
tx1.rollback();
}
finally {
session1.close();
}
}
};
// Run transaction 2
Thread t2 = new Thread() {
@Override
public void run() {
Session session2 = sessionFactory.openSession();
Transaction tx2 = null;
try {
tx2 = session2.beginTransaction();
System.out.println("T2 - Begin trasaction");
Thread.sleep(500);
Account account = (Account)
session2.get(Account.class, new Long(1), LockMode.UPGRADE);
System.out.println("T2 - balance=" + account.getBalance());
Thread.sleep(500);
account.setBalance(account.getBalance() - 100);
System.out.println("T2 - Change balance:" + account.getBalance());
tx2.commit();
System.out.println("T2 - Commit transaction");
Thread.sleep(500);
}
catch (Exception e) {
e.printStackTrace();
if (tx2 != null)
tx2.rollback();
}
finally {
session2.close();
}
}
};
t1.start();
t2.start();
while (t1.isAlive() || t2.isAlive()) {
try {
Thread.sleep(2000L);
} catch (InterruptedException e) {
}
}
System.out.println("Both T1 and T2 are dead.");
sessionFactory.close();
}
}
T1 - Begin trasaction
T2 - Begin trasaction
Hibernate: select account0_.col_id as col1_0_0_, account0_.col_balance as col2_0_0_ from tb_account account0_ with (updlock, rowlock) where account0_.col_id=?
Hibernate: select account0_.col_id as col1_0_0_, account0_.col_balance as col2_0_0_ from tb_account account0_ with (updlock, rowlock) where account0_.col_id=?
T2 - balance=100
T2 - Change balance:0
Hibernate: update tb_account set col_balance=? where col_id=?
T2 - Commit transaction
T1 - balance=0
T1 - Change balance:100
Hibernate: update tb_account set col_balance=? where col_id=?
T1 - Commit transaction
Both T1 and T2 are dead.
Hibernate对于SQLServer 2005会执行SQL:
select account0_.col_id as col1_0_0_, account0_.col_balance as col2_0_0_ from tb_account account0_ with (updlock, rowlock) where account0_.col_id=?
为选定的col_id为1的数据行加上行锁和更新锁。
2.乐观锁:假定当前事务操作的数据不会有其他事务同时访问,因此完全依靠数据库
的隔离级别来自动管理锁的工作。在应用程序中采用版本控制来避免可能低概率出现
的并发问题。
在Hibernate中,使用Version注解来定义版本号字段。
将DirtyLock中的Account对象替换成AccountVersion,其他代码不变,执行出现异常。
package com.cdai.orm.hibernate.transaction;
import javax.persistence.Column;
import javax.persistence.Entity;
import javax.persistence.Id;
import javax.persistence.Table;
import javax.persistence.Version;
@Entity
@Table(name = "tb_account_version")
public class AccountVersion {
@Id
@Column(name = "col_id")
private long id;
@Column(name = "col_balance")
private long balance;
@Version
@Column(name = "col_version")
private int version;
public AccountVersion() {
}
public AccountVersion(long id, long balance) {
this.id = id;
this.balance = balance;
}
public long getId() {
return id;
}
public void setId(long id) {
this.id = id;
}
public long getBalance() {
return balance;
}
public void setBalance(long balance) {
this.balance = balance;
}
public int getVersion() {
return version;
}
public void setVersion(int version) {
this.version = version;
}
}
log如下:
T1 - Begin trasaction
T2 - Begin trasaction
Hibernate: select accountver0_.col_id as col1_0_0_, accountver0_.col_balance as col2_0_0_, accountver0_.col_version as col3_0_0_ from tb_account_version accountver0_ where accountver0_.col_id=?
Hibernate: select accountver0_.col_id as col1_0_0_, accountver0_.col_balance as col2_0_0_, accountver0_.col_version as col3_0_0_ from tb_account_version accountver0_ where accountver0_.col_id=?
T1 - balance=1000
T2 - balance=1000
T1 - Change balance:900
T2 - Change balance:1100
Hibernate: update tb_account_version set col_balance=?, col_version=? where col_id=? and col_version=?
Hibernate: update tb_account_version set col_balance=?, col_version=? where col_id=? and col_version=?
T1 - Commit transaction
2264 [Thread-2] ERROR org.hibernate.event.def.AbstractFlushingEventListener - Could not synchronize database state with session
org.hibernate.StaleObjectStateException: Row was updated or deleted by another transaction (or unsaved-value mapping was incorrect): [com.cdai.orm.hibernate.transaction.AccountVersion#1]
at org.hibernate.persister.entity.AbstractEntityPersister.check(AbstractEntityPersister.java:1934)
at org.hibernate.persister.entity.AbstractEntityPersister.update(AbstractEntityPersister.java:2578)
at org.hibernate.persister.entity.AbstractEntityPersister.updateOrInsert(AbstractEntityPersister.java:2478)
at org.hibernate.persister.entity.AbstractEntityPersister.update(AbstractEntityPersister.java:2805)
at org.hibernate.action.EntityUpdateAction.execute(EntityUpdateAction.java:114)
at org.hibernate.engine.ActionQueue.execute(ActionQueue.java:268)
at org.hibernate.engine.ActionQueue.executeActions(ActionQueue.java:260)
at org.hibernate.engine.ActionQueue.executeActions(ActionQueue.java:180)
at org.hibernate.event.def.AbstractFlushingEventListener.performExecutions(AbstractFlushingEventListener.java:321)
at org.hibernate.event.def.DefaultFlushEventListener.onFlush(DefaultFlushEventListener.java:51)
at org.hibernate.impl.SessionImpl.flush(SessionImpl.java:1206)
at org.hibernate.impl.SessionImpl.managedFlush(SessionImpl.java:375)
at org.hibernate.transaction.JDBCTransaction.commit(JDBCTransaction.java:137)
at com.cdai.orm.hibernate.transaction.VersionLock$2.run(VersionLock.java:93)
Both T1 and T2 are dead.
由于乐观锁完全将事务隔离交给数据库来控制,所以事务1和2交叉运行了,事务1提交
成功并将col_version改为1,然而事务2提交时已经找不到col_version为0的数据了,所以
抛出了异常。
Hibernate查询方法比较
Hibernate主要有三种查询方法:
1.HQL (Hibernate Query Language)
和SQL很类似,支持分页、连接、分组、聚集函数和子查询等特性,
但HQL是面向对象的,而不是面向关系数据库中的表。正因查询语句
是面向Domain对象的,所以使用HQL可以获得跨平台的好处,Hibernate
会自动帮我们根据不同的数据库翻译成不同的SQL语句。这在需要支持
多种数据库或者数据库迁移的应用中是十分方便的。
但得到方便的同时,由于SQL语句是由Hibernate自动生成的,所以这不
利于SQL语句的效率优化和调试,当数据量很大时可能会有效率问题,
出了问题也不便于排查解决。
2.QBC/QBE (Query by Criteria/Example)
QBC/QBE是通过组装查询条件或者模板对象来执行查询的。这在需要
灵活地支持许多查询条件自由组合的应用中是比较方便的。同样的问题
是由于查询语句是自由组装的,创建一条语句的代码可能很长,并且
包含许多分支条件,很不便于优化和调试。
3.SQL
Hibernate也支持直接执行SQL的查询方式。这种方式牺牲了Hibernate跨
数据库的优点,手工地编写底层SQL语句,从而获得最好的执行效率,
相对前两种方法,优化和调试方便了一些。
下面来看一组简单的例子。
package com.cdai.orm.hibernate.query;
import java.util.Arrays;
import java.util.List;
import org.hibernate.Criteria;
import org.hibernate.Query;
import org.hibernate.Session;
import org.hibernate.SessionFactory;
import org.hibernate.cfg.AnnotationConfiguration;
import org.hibernate.criterion.Criterion;
import org.hibernate.criterion.Example;
import org.hibernate.criterion.Expression;
import com.cdai.orm.hibernate.annotation.Account;
public class BasicQuery {
public static void main(String[] args) {
SessionFactory sessionFactory = new AnnotationConfiguration().
addFile("hibernate/hibernate.cfg.xml").
configure().
addPackage("com.cdai.orm.hibernate.annotation").
addAnnotatedClass(Account.class).
buildSessionFactory();
Session session = sessionFactory.openSession();
// 1.HQL
Query query = session.createQuery("from Account as a where a.id=:id");
query.setLong("id", 1);
List result = query.list();
for (Object row : result) {
System.out.println(row);
}
// 2.QBC
Criteria criteria = session.createCriteria(Account.class);
criteria.add(Expression.eq("id", new Long(2)));
result = criteria.list();
for (Object row : result) {
System.out.println(row);
}
// 3.QBE
Account example= new Account();
example.setBalance(100);
result = session.createCriteria(Account.class).
add(Example.create(example)).
list();
for (Object row : result) {
System.out.println(row);
}
// 4.SQL
query = session.createSQLQuery(
" select top 10 * from tb_account order by col_id desc ");
result = query.list();
for (Object row : result) {
System.out.println(Arrays.toString((Object[]) row));
}
session.close();
}
}
Hibernate: select account0_.col_id as col1_0_, account0_.col_balance as col2_0_ from tb_account account0_ where account0_.col_id=?
Account [id=1, balance=100]
Hibernate: select this_.col_id as col1_0_0_, this_.col_balance as col2_0_0_ from tb_account this_ where this_.col_id=?
Account [id=2, balance=100]
Hibernate: select this_.col_id as col1_0_0_, this_.col_balance as col2_0_0_ from tb_account this_ where (this_.col_balance=?)
Account [id=1, balance=100]
Account [id=2, balance=100]
Hibernate: select top 10 * from tb_account order by col_id desc
[2, 100]
[1, 100]
从log中可以清楚的看到Hibernate对于生成的SQL语句的控制,具体选择
哪种查询方式就要看具体应用了。
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