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• 摘要

• spring-cache简介

• 基本机制

• 事务上下文中的问题

• 将操作绑定到数据库事务上

• spring-cache的相关实现

• TransactionSynchronizationManager和TransactionSynchronizationAdapter

• 事务相关操作注册与回调流程

• 其它应用

摘要

在开发中，我们常常会遇到（或者需要）把一些操作“绑定到数据库事务上”。也就是说，如果数据库事务成功提交，则执行这个操作；如果数据库事务回滚，则不执行这个操作（或者执行另一个操作）。

例如，《JMS与数据库事务》中介绍了一种JmsTemplate的配置方法，可以把“发送JMS消息”的操作绑定到数据库事务上。除此之外，更新缓存的操作也需要做类似的绑定处理。否则，数据库事务回滚了，而缓存中却完成了更新操作，可能导致一段时间内都会发生“脏读”。

那么，这种“绑定到数据库事务上”的功能，是如何实现的呢？spring-cache中就有一个很好的例子。

spring-cache简介

spring-cache本质上不是一个具体的缓存实现方案（例如EHCache 或者 OSCache），而是一个对缓存使用的抽象，通过在既有代码中添加少量它定义的各种 annotation，即能够简单而快捷地操作缓存。

 spring-cache提供了一个CacheManager接口，用于抽象和管理缓存；缓存则抽象为Cache接口；而业务数据的CRUD操作，则由@CachePut/@Cacheable/@CacheEviet注解来进行配置后，由Cache接口下的各种实现类来处理。此外还有一些辅助类、配置类，由于这里是“简介”，按下不表。

基本机制

显然，spring-cache使用了基于注解的AOP机制。以@CachePut注解为例，它的基本操作流程是这样的：

其中，“获取缓存实例Cache”就是由CacheManager接口负责的。这里的“缓存实例”只是一个“逻辑”上的实例；在物理实现上，它可能是同一个缓存中的不同命名空间、也可能确实是不同的物理缓存。

“将返回结果写入缓存”，以及其它的缓存读、写操作，都由Cache接口来负责。

事务上下文中的问题

在事务上下文中，上面所说的“基本流程”是存在问题的：如果“写缓存”操作成功、而数据库事务回滚了，那么缓存中就会出现一笔脏数据。如下图所示：

这种场景下，我们就需要把缓存操作绑定到数据库事务上。

将操作绑定到数据库事务上

spring-cache的相关实现

与JmsTemplate类似，Spring-cache提供了一个“绑定数据库事务”的CacheManager实现类：AbstractTransactionSupportingCacheManager。不过，这个类只提供一个“是否绑定到数据库事务上”的配置项（transactionAware），自身并不处理“绑定数据库事务”这个操作。真正实现了“绑定”处理的，是AbstractTransactionSupportingCacheManager提供的Cache实现类：TransactionAwareCacheDecorator。这个类的put方法代码如下：

TransactionAwareCacheDecorator 

public class TransactionAwareCacheDecorator implements Cache {private final Cache targetCache;@Overridepublic void put(final Object key, final Object value) {// 判断是否开启了事务if (TransactionSynchronizationManager.isSynchronizationActive()) {// 将操作注册到“afterCommit”阶段TransactionSynchronizationManager.registerSynchronization(new TransactionSynchronizationAdapter() {@Overridepublic void afterCommit() {targetCache.put(key, value);}});}else {this.targetCache.put(key, value);}}// 省略其它方法}

AbstractTransactionSupportingCacheManager是基于“继承”来提供TransactionAwareCacheDecorator。除了它之外，spring-cache还提供了一个基于“组合”的CacheManager实现类：TransactionAwareCacheManagerProxy。不过，后者本质上也要通过TransactionAwareCacheDecorator来实现所需功能。

TransactionSynchronizationManager和TransactionSynchronizationAdapter

TransactionSynchronizationManager中的代码有点复杂。但是其功能可以“一言以蔽之”：维护事务状态。在这个类中有一系列的ThreadLocal类型的类变量，它们就负责存储当前线程中的事务数据。相关代码如下：

TransactionSynchronizationManager中的ThreadLocal 

private static final ThreadLocal<Map<Object, Object>> resources =new NamedThreadLocal<Map<Object, Object>>("Transactional resources");// 关注点：事务相关操作的回调模板private static final ThreadLocal<Set<TransactionSynchronization>> synchronizations =new NamedThreadLocal<Set<TransactionSynchronization>>("Transaction synchronizations");private static final ThreadLocal<String> currentTransactionName =new NamedThreadLocal<String>("Current transaction name");private static final ThreadLocal<Boolean> currentTransactionReadOnly =new NamedThreadLocal<Boolean>("Current transaction read-only status");private static final ThreadLocal<Integer> currentTransactionIsolationLevel =new NamedThreadLocal<Integer>("Current transaction isolation level");private static final ThreadLocal<Boolean> actualTransactionActive =new NamedThreadLocal<Boolean>("Actual transaction active");

这些类变量中，我们需要关注的是synchronizations 。在TransactionAwareCacheDecorator中使用到的TransactionSynchronizationManager.isSynchronizationActive()、TransactionSynchronizationManager.registerSynchronization()和new TransactionSynchronizationAdapter()，都与它有关。

先看isSynchronizationActive()方法。它的代码实现非常简单，仅仅是判断了synchronizations中是否有数据（Set<TransactionSynchronization>非null即可，并不要求其中有TransactionSynchronization实例）。之所以可以这样判断，是因为Spring在开启数据库事务（无论是使用@Transactional注解，还是用xml配置）时，都会向其中写入一个实例，用于自动处理Connection的获取、提交或回滚等操作。这个方法的代码如下：

isSynchronizationActive() :

/*** Return if transaction synchronization is active for the current thread.* Can be called before register to avoid unnecessary instance creation.* @see #registerSynchronization*/public static boolean isSynchronizationActive() {return (synchronizations.get() != null);}

再看registerSynchronization()方法。它其实也非常简单：首先调用isSynchronizationActive()做一个校验；然后将入参synchronization添加到synchronizations 中。入参synchronization中的方法不会在这里执行，而是要等到事务执行到一定阶段时才会被调用。这个方法的代码如下：

registerSynchronization() :

/*** Register a new transaction synchronization for the current thread.* Typically called by resource management code.* <p>Note that synchronizations can implement the* {@link org.springframework.core.Ordered} interface.* They will be executed in an order according to their order value (if any).* @param synchronization the synchronization object to register* @throws IllegalStateException if transaction synchronization is not active* @see org.springframework.core.Ordered*/public static void registerSynchronization(TransactionSynchronization synchronization)throws IllegalStateException {Assert.notNull(synchronization, "TransactionSynchronization must not be null");if (!isSynchronizationActive()) {throw new IllegalStateException("Transaction synchronization is not active");}synchronizations.get().add(synchronization);}

比较复杂的是TransactionSynchronizationAdapter类。在进入这个类之前，我们得先看看TransactionSynchronization接口。

TransactionSynchronization接口定义了一系列的回调方法，对应一个事务执行的不同阶段：挂起、恢复、flush、提交（前、后）、完成（事务成功或失败）等。当事务运行到对应阶段时，事务管理器会从TransactionSynchronizationManager维护的synchronizations中拿出所有的回调器，逐个回调其中的对应方法。这个接口的代码如下：

TransactionSynchronization 

/*** Interface for transaction synchronization callbacks.* Supported by AbstractPlatformTransactionManager.** <p>TransactionSynchronization implementations can implement the Ordered interface* to influence their execution order. A synchronization that does not implement the* Ordered interface is appended to the end of the synchronization chain.** <p>System synchronizations performed by Spring itself use specific order values,* allowing for fine-grained interaction with their execution order (if necessary).** @author Juergen Hoeller* @since 02.06.2003* @see TransactionSynchronizationManager* @see AbstractPlatformTransactionManager* @see org.springframework.jdbc.datasource.DataSourceUtils#CONNECTION_SYNCHRONIZATION_ORDER*/public interface TransactionSynchronization extends Flushable {/** Completion status in case of proper commit */int STATUS_COMMITTED = 0;/** Completion status in case of proper rollback */int STATUS_ROLLED_BACK = 1;/** Completion status in case of heuristic mixed completion or system errors */int STATUS_UNKNOWN = 2;/*** Suspend this synchronization.* Supposed to unbind resources from TransactionSynchronizationManager if managing any.* @see TransactionSynchronizationManager#unbindResource*/void suspend();/*** Resume this synchronization.* Supposed to rebind resources to TransactionSynchronizationManager if managing any.* @see TransactionSynchronizationManager#bindResource*/void resume();/*** Flush the underlying session to the datastore, if applicable:* for example, a Hibernate/JPA session.* @see org.springframework.transaction.TransactionStatus#flush()*/@Overridevoid flush();/*** Invoked before transaction commit (before "beforeCompletion").* Can e.g. flush transactional O/R Mapping sessions to the database.* <p>This callback does <i>not</i> mean that the transaction will actually be committed.* A rollback decision can still occur after this method has been called. This callback* is rather meant to perform work that's only relevant if a commit still has a chance* to happen, such as flushing SQL statements to the database.* <p>Note that exceptions will get propagated to the commit caller and cause a* rollback of the transaction.* @param readOnly whether the transaction is defined as read-only transaction* @throws RuntimeException in case of errors; will be <b>propagated to the caller</b>* (note: do not throw TransactionException subclasses here!)* @see #beforeCompletion*/void beforeCommit(boolean readOnly);/*** Invoked before transaction commit/rollback.* Can perform resource cleanup <i>before</i> transaction completion.* <p>This method will be invoked after {@code beforeCommit}, even when* {@code beforeCommit} threw an exception. This callback allows for* closing resources before transaction completion, for any outcome.* @throws RuntimeException in case of errors; will be <b>logged but not propagated</b>* (note: do not throw TransactionException subclasses here!)* @see #beforeCommit* @see #afterCompletion*/void beforeCompletion();/*** Invoked after transaction commit. Can perform further operations right* <i>after</i> the main transaction has <i>successfully</i> committed.* <p>Can e.g. commit further operations that are supposed to follow on a successful* commit of the main transaction, like confirmation messages or emails.* <p><b>NOTE:</b> The transaction will have been committed already, but the* transactional resources might still be active and accessible. As a consequence,* any data access code triggered at this point will still "participate" in the* original transaction, allowing to perform some cleanup (with no commit following* anymore!), unless it explicitly declares that it needs to run in a separate* transaction. Hence: <b>Use {@code PROPAGATION_REQUIRES_NEW} for any* transactional operation that is called from here.</b>* @throws RuntimeException in case of errors; will be <b>propagated to the caller</b>* (note: do not throw TransactionException subclasses here!)*/void afterCommit();/*** Invoked after transaction commit/rollback.* Can perform resource cleanup <i>after</i> transaction completion.* <p><b>NOTE:</b> The transaction will have been committed or rolled back already,* but the transactional resources might still be active and accessible. As a* consequence, any data access code triggered at this point will still "participate"* in the original transaction, allowing to perform some cleanup (with no commit* following anymore!), unless it explicitly declares that it needs to run in a* separate transaction. Hence: <b>Use {@code PROPAGATION_REQUIRES_NEW}* for any transactional operation that is called from here.</b>* @param status completion status according to the {@code STATUS_*} constants* @throws RuntimeException in case of errors; will be <b>logged but not propagated</b>* (note: do not throw TransactionException subclasses here!)* @see #STATUS_COMMITTED* @see #STATUS_ROLLED_BACK* @see #STATUS_UNKNOWN* @see #beforeCompletion*/void afterCompletion(int status);}

TransactionSynchronizationAdapter显然是一个适配器：它实现了TransactionSynchronization接口，并为每一个接口方法提供了一个空的实现。这类适配器的基本思想是：接口中定义了很多方法，然而业务代码往往只需要实现其中一小部分。利用这种“空实现”适配器，我们可以专注于业务上需要处理的回调方法，而不用在业务类中放大量而且重复的空方法。

TransactionSynchronizationAdapter类的代码如下：

TransactionSynchronizationAdapter 

public abstract class TransactionSynchronizationAdapter implements TransactionSynchronization, Ordered {@Overridepublic int getOrder() {return Ordered.LOWEST_PRECEDENCE;}@Overridepublic void suspend() {}@Overridepublic void resume() {}@Overridepublic void flush() {}@Overridepublic void beforeCommit(boolean readOnly) {}@Overridepublic void beforeCompletion() {}@Overridepublic void afterCommit() {}@Overridepublic void afterCompletion(int status) {}}

事务相关操作注册与回调流程

说了这么多，都是静态的代码，抽象而费解。这里再提供一张流程图（省略了一些与缓存操作不太相关的事务相关操作），希望能帮助大家更好的理解相关代码和机制。

上图与事务上下文中的问题相比，所谓“写入”缓存操作实际并没有真正去操作缓存，而仅仅是注册了一个回调实例。直到数据库事务执行到afterCommit阶段时，这个回调实例才会被调用，并真正地向缓存中写入新的数据。

顺带一提，TransactionSynchronization中没有afterRollback()。如果需要在事务回滚后做某些处理，需要在afterCompletion(int)方法中判断入参的值，然后再做处理。

其它应用

“绑定到数据库事务上”这一功能，除了JmsTemplate、Cache操作中可以用到之外，在一些弱/最终一致性分布式事务中也有应用。如TCC模型中，业务代码中只调用Try服务，而在afterCommit或afterCompletion中处理Commit或Cancel服务。两阶段也是类似地在"afterRollback"中去调用第二阶段的回滚服务。