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【源码讲解】Spring事务是如何应用到你的业务场景中的?

时间:2020-09-14 20:02:19      阅读:61      评论:0      收藏:0      [点我收藏+]

初衷

日常开发中经常用到@Transaction注解,那你知道它是怎么应用到你的业务代码中的吗?本篇文章将从以下两个方面阐述Spring事务实现原理:

  1. 解析并加载事务配置:本质上是解析xml文件将标签加载成 BeanDefinition 对象;
  2. 生成事务代理对象并运行:本质上是Spring AOP在事务这块的应用,将业务Bean替换成事务代理对象(JdkDynamicAopProxy:JDK代理,CglibAopProxy:CGLIB代理);

本文使用的源码版本是Spring 4.3.18.RELEASE,使用的是XML开启事务。

关键类

这里列出几个核心类,提前留个印象,后面会讲解什么时候调用

  1. XmlBeanDefinitionReader 加载XML定义的Bean入口
  2. TxNamespaceHandler 解析XML中的事务标签: advice、annotation-driven等;
  3. InfrastructureAdvisorAutoProxyCreator 该类实现了 BeanPostProcessor 接口(可以在Bean初始化后进行替换),是生成事务代理类并替换的关键类;
  4. AnnotationTransactionAttributeSource 用来解析业务方法使用注解 @Transaction 上的配置,提供给 TransactionInterceptor 使用;
  5. TransactionInterceptor 事务拦截类:真正处理事务的类,开启、回滚事务,可以理解成切面中的通知:做什么;
  6. BeanFactoryTransactionAttributeSourceAdvisor 实现了Advisor接口,可以理解为切面:切点(TransactionAttributeSourcePointcut) + 通知(TransactionInterceptor)。

示例代码:

	public class TransactionService {
	
	    @Transactional(rollbackFor = Throwable.class)
	    public void testTransaction(){
	        System.out.println("方法逻辑");
	    }
	}
     ClassPathXmlApplicationContext context = new ClassPathXmlApplicationContext("config.xml");
     TransactionService transactionService = context.getBean(TransactionService.class);
     transactionService.testTransaction();
<?xml version="1.0" encoding="UTF-8"?>
<beans xmlns="http://www.springframework.org/schema/beans"
       xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
       xmlns:aop="http://www.springframework.org/schema/aop"
       xmlns:context="http://www.springframework.org/schema/context"
       xmlns:jee="http://www.springframework.org/schema/jee"
       xmlns:tx="http://www.springframework.org/schema/tx"
       xmlns:task="http://www.springframework.org/schema/task"
       xsi:schemaLocation="
        http://www.springframework.org/schema/aop http://www.springframework.org/schema/aop/spring-aop-4.0.xsd
        http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans-4.0.xsd
        http://www.springframework.org/schema/context http://www.springframework.org/schema/context/spring-context-4.3.xsd
        http://www.springframework.org/schema/jee http://www.springframework.org/schema/jee/spring-jee-4.0.xsd
        http://www.springframework.org/schema/tx http://www.springframework.org/schema/tx/spring-tx-4.0.xsd
        http://www.springframework.org/schema/task http://www.springframework.org/schema/task/spring-task-4.0.xsd">
    <bean id="transactionService" class="com.yangwq.spring.transaction.TransactionService"/>

    <bean id="dataSource" class="org.springframework.jdbc.datasource.DriverManagerDataSource">
        <property name="driverClassName" value="com.mysql.jdbc.Driver"/>
        <property name="url" value="jdbc:mysql://127.0.0.1:3306/blog"/>
        <property name="username" value="root"/>
        <property name="password" value="11"/>
    </bean>

    <!-- 定义事务管理器 -->
    <bean id="transactionManager"
          class="org.springframework.jdbc.datasource.DataSourceTransactionManager">
        <property name="dataSource" ref="dataSource"/>
    </bean>
    <!--使用注释事务 -->
    <tx:annotation-driven/>

</beans>

1. 解析并加载事务配置

加载的入口(同时也是Spring容器加载的核心代码):

synchronized (this.startupShutdownMonitor) {
			// Prepare this context for refreshing.
			prepareRefresh();

			// 重点,这里是Spring初始化默认的容器,在这一步会通过解析配置文件将定义的bean转换为 BeanDefinition,
			// 保存在 beanDefinitionMap 中
			ConfigurableListableBeanFactory beanFactory = obtainFreshBeanFactory();

			// Prepare the bean factory for use in this context.
			prepareBeanFactory(beanFactory);

			try {
				// Allows post-processing of the bean factory in context subclasses.
				postProcessBeanFactory(beanFactory);

				// Invoke factory processors registered as beans in the context.
				invokeBeanFactoryPostProcessors(beanFactory);

				// Register bean processors that intercept bean creation.
				registerBeanPostProcessors(beanFactory);

				// Initialize message source for this context.
				initMessageSource();

				// Initialize event multicaster for this context.
				initApplicationEventMulticaster();

				// Initialize other special beans in specific context subclasses.
				onRefresh();

				// Check for listener beans and register them.
				registerListeners();

				// 重点,初始化所有非懒加载bean的方法,也可以理解为根据特定规则将 BeanDefinition 转成 Bean对象的方法
				finishBeanFactoryInitialization(beanFactory);

				// Last step: publish corresponding event.
				finishRefresh();
			}

			catch (BeansException ex) {
				if (logger.isWarnEnabled()) {
					logger.warn("Exception encountered during context initialization - " +
							"cancelling refresh attempt: " + ex);
				}

				// Destroy already created singletons to avoid dangling resources.
				destroyBeans();

				// Reset ‘active‘ flag.
				cancelRefresh(ex);

				// Propagate exception to caller.
				throw ex;
			}

			finally {
				// Reset common introspection caches in Spring‘s core, since we
				// might not ever need metadata for singleton beans anymore...
				resetCommonCaches();
			}
		}

事务配置的解析在上面的obtainFreshBeanFactory,由于我们使用的是ClassPathXmlApplicationContext 作为容器,它的解析类为:XmlBeanDefinitionReader;核心方法:

public int loadBeanDefinitions(EncodedResource encodedResource) throws BeanDefinitionStoreException {
		Assert.notNull(encodedResource, "EncodedResource must not be null");
		if (logger.isInfoEnabled()) {
			logger.info("Loading XML bean definitions from " + encodedResource.getResource());
		}

		Set<EncodedResource> currentResources = this.resourcesCurrentlyBeingLoaded.get();
		if (currentResources == null) {
			currentResources = new HashSet<EncodedResource>(4);
			this.resourcesCurrentlyBeingLoaded.set(currentResources);
		}
		if (!currentResources.add(encodedResource)) {
			throw new BeanDefinitionStoreException(
					"Detected cyclic loading of " + encodedResource + " - check your import definitions!");
		}
		try {
			// 读取 config.xml 文件
			InputStream inputStream = encodedResource.getResource().getInputStream();
			try {
				InputSource inputSource = new InputSource(inputStream);
				if (encodedResource.getEncoding() != null) {
					inputSource.setEncoding(encodedResource.getEncoding());
				}
				// 开始加载 config.xml 文件中定义的bean,这里只是加载成BeanDefinition,初始化在另外的方法
				return doLoadBeanDefinitions(inputSource, encodedResource.getResource());
			}
			finally {
				inputStream.close();
			}
		}
		catch (IOException ex) {
			throw new BeanDefinitionStoreException(
					"IOException parsing XML document from " + encodedResource.getResource(), ex);
		}
		finally {
			currentResources.remove(encodedResource);
			if (currentResources.isEmpty()) {
				this.resourcesCurrentlyBeingLoaded.remove();
			}
		}
	}
	

doLoadBeanDefinitions 具体解析的方法是在org.springframework.beans.factory.xml.DefaultBeanDefinitionDocumentReader#doRegisterBeanDefinitions 中进行,该方法如下

		protected void doRegisterBeanDefinitions(Element root) {
		// Any nested <beans> elements will cause recursion in this method. In
		// order to propagate and preserve <beans> default-* attributes correctly,
		// keep track of the current (parent) delegate, which may be null. Create
		// the new (child) delegate with a reference to the parent for fallback purposes,
		// then ultimately reset this.delegate back to its original (parent) reference.
		// this behavior emulates a stack of delegates without actually necessitating one.
		BeanDefinitionParserDelegate parent = this.delegate;
		this.delegate = createDelegate(getReaderContext(), root, parent);

		if (this.delegate.isDefaultNamespace(root)) {
			String profileSpec = root.getAttribute(PROFILE_ATTRIBUTE);
			if (StringUtils.hasText(profileSpec)) {
				String[] specifiedProfiles = StringUtils.tokenizeToStringArray(
						profileSpec, BeanDefinitionParserDelegate.MULTI_VALUE_ATTRIBUTE_DELIMITERS);
				if (!getReaderContext().getEnvironment().acceptsProfiles(specifiedProfiles)) {
					if (logger.isInfoEnabled()) {
						logger.info("Skipped XML bean definition file due to specified profiles [" + profileSpec +
								"] not matching: " + getReaderContext().getResource());
					}
					return;
				}
			}
		}

		preProcessXml(root);
		// 真正解析config.xml文件
		parseBeanDefinitions(root, this.delegate);
		postProcessXml(root);

		this.delegate = parent;
	}
	
	protected void parseBeanDefinitions(Element root, BeanDefinitionParserDelegate delegate) {
	    // 判断根节点是不是默认的节点,实际通过判断根节点的 namespaceURI 属性是不是 http://www.springframework.org/schema/beans ,
	    // 我们这里的配置文件声明的正好是这个属性,所以返回的是true,注意bean标签也是默认标签
		if (delegate.isDefaultNamespace(root)) {
			// 获取子节点
			NodeList nl = root.getChildNodes();
			for (int i = 0; i < nl.getLength(); i++) {
				Node node = nl.item(i);
				// 判断子节点是不是标签
				if (node instanceof Element) {
					Element ele = (Element) node;
					// bean标签的解析
					if (delegate.isDefaultNamespace(ele)) {
						parseDefaultElement(ele, delegate);
					}
					// 重点:tx标签在这里进行
					else {
						delegate.parseCustomElement(ele);
					}
				}
			}
		}
		else {
			delegate.parseCustomElement(root);
		}
	}
	// 解析非bean的标签
	public BeanDefinition parseCustomElement(Element ele) {
		return parseCustomElement(ele, null);
	}
	// 解析非默认标签方法
	public BeanDefinition parseCustomElement(Element ele, BeanDefinition containingBd) {
		String namespaceUri = getNamespaceURI(ele);
		// 这里是Spring使用了策略模式解析配置,通过namespaceUri匹配对应的处理类,也就是上面的关键类 TxNamespaceHandler,
		// 这里的resolve运用了懒加载,在获取映射关系handlerMappings属性为null时会从META-INF/spring.handlers 下面获取映射关系,
		// 由于IDEA debug的时候默认会调用getHandlerMappings方法,所以使用debug的时候会发现一开始就有值
		NamespaceHandler handler = this.readerContext.getNamespaceHandlerResolver().resolve(namespaceUri);
		if (handler == null) {
			error("Unable to locate Spring NamespaceHandler for XML schema namespace [" + namespaceUri + "]", ele);
			return null;
		}
		// 获取到处理类后,让处理类开始解析配置
		return handler.parse(ele, new ParserContext(this.readerContext, this, containingBd));
	}

TxNamespaceHandler 最终交给类 AnnotationDrivenBeanDefinitionParser 进行解析事务配置;

public BeanDefinition parse(Element element, ParserContext parserContext) {
		// 注册一个事务工厂事件,允许我们自定义监听事务的提交等操作
		registerTransactionalEventListenerFactory(parserContext);
		String mode = element.getAttribute("mode");
		// 如果使用的是 aspectj 方式,走这个方法
		if ("aspectj".equals(mode)) {
			// mode="aspectj"
			registerTransactionAspect(element, parserContext);
		}
		else {
			// 默认使用的是代理模式 
			// mode="proxy"
			AopAutoProxyConfigurer.configureAutoProxyCreator(element, parserContext);
		}
		return null;
	}
	
	/**
	 * Inner class to just introduce an AOP framework dependency when actually in proxy mode.
	 */
	private static class AopAutoProxyConfigurer {

		public static void configureAutoProxyCreator(Element element, ParserContext parserContext) {
			// 重点,注册 InfrastructureAdvisorAutoProxyCreator 的 BeanDefinition,这个是个关键类,代理业务bean的操作都靠它了
			AopNamespaceUtils.registerAutoProxyCreatorIfNecessary(parserContext, element);

			String txAdvisorBeanName = TransactionManagementConfigUtils.TRANSACTION_ADVISOR_BEAN_NAME;
			if (!parserContext.getRegistry().containsBeanDefinition(txAdvisorBeanName)) {
				Object eleSource = parserContext.extractSource(element);

				// 重点,注册一个全局的 TransactionAttributeSource 的BeanDefinition ,用于解析 @Transaction 定义的元数据
				RootBeanDefinition sourceDef = new RootBeanDefinition(
						"org.springframework.transaction.annotation.AnnotationTransactionAttributeSource");
				sourceDef.setSource(eleSource);
				sourceDef.setRole(BeanDefinition.ROLE_INFRASTRUCTURE);
				String sourceName = parserContext.getReaderContext().registerWithGeneratedName(sourceDef);

				// 重点,注册 TransactionInterceptor 的BeanDefinition,这个就是事务真正执行的类,可以理解为是事务切面上的通知
				RootBeanDefinition interceptorDef = new RootBeanDefinition(TransactionInterceptor.class);
				interceptorDef.setSource(eleSource);
				interceptorDef.setRole(BeanDefinition.ROLE_INFRASTRUCTURE);
				registerTransactionManager(element, interceptorDef);
				interceptorDef.getPropertyValues().add("transactionAttributeSource", new RuntimeBeanReference(sourceName));
				String interceptorName = parserContext.getReaderContext().registerWithGeneratedName(interceptorDef);

				// 重点,注册 BeanFactoryTransactionAttributeSourceAdvisor 的BeanDefinition,可以理解为事务的切面,
				// 包含了切点(TransactionAttributeSourcePointcut) + 通知(TransactionInterceptor),保存在 ProxyFactory 中,用于生成代理对象
				RootBeanDefinition advisorDef = new RootBeanDefinition(BeanFactoryTransactionAttributeSourceAdvisor.class);
				advisorDef.setSource(eleSource);
				advisorDef.setRole(BeanDefinition.ROLE_INFRASTRUCTURE);
				advisorDef.getPropertyValues().add("transactionAttributeSource", new RuntimeBeanReference(sourceName));
				advisorDef.getPropertyValues().add("adviceBeanName", interceptorName);
				if (element.hasAttribute("order")) {
					advisorDef.getPropertyValues().add("order", element.getAttribute("order"));
				}
				parserContext.getRegistry().registerBeanDefinition(txAdvisorBeanName, advisorDef);

				CompositeComponentDefinition compositeDef = new CompositeComponentDefinition(element.getTagName(), eleSource);
				compositeDef.addNestedComponent(new BeanComponentDefinition(sourceDef, sourceName));
				compositeDef.addNestedComponent(new BeanComponentDefinition(interceptorDef, interceptorName));
				compositeDef.addNestedComponent(new BeanComponentDefinition(advisorDef, txAdvisorBeanName));
				parserContext.registerComponent(compositeDef);
			}
		}
	}

到这里,事务配置的加载就结束了,上面的步骤只是将事务的关键类变成 BeanDefinition,实际上还没有生成Bean对象的,下面我们看下BeanDefinition 是如何变成Bean的(这一个步骤不是Spring事务独有的,是所有BeanDefinition 的共同逻辑),然后是如何生成业务bean代理对象并替换业务bean的。

2. 生成事务代理对象

入口在 1.解析并加载事务配置 列举的finishBeanFactoryInitialization(beanFactory) 方法中:

	/**
	 * Finish the initialization of this context‘s bean factory,
	 * initializing all remaining singleton beans.
	 */
	protected void finishBeanFactoryInitialization(ConfigurableListableBeanFactory beanFactory) {
		// Initialize conversion service for this context.
		if (beanFactory.containsBean(CONVERSION_SERVICE_BEAN_NAME) &&
				beanFactory.isTypeMatch(CONVERSION_SERVICE_BEAN_NAME, ConversionService.class)) {
			beanFactory.setConversionService(
					beanFactory.getBean(CONVERSION_SERVICE_BEAN_NAME, ConversionService.class));
		}

		// Register a default embedded value resolver if no bean post-processor
		// (such as a PropertyPlaceholderConfigurer bean) registered any before:
		// at this point, primarily for resolution in annotation attribute values.
		if (!beanFactory.hasEmbeddedValueResolver()) {
			beanFactory.addEmbeddedValueResolver(new StringValueResolver() {
				@Override
				public String resolveStringValue(String strVal) {
					return getEnvironment().resolvePlaceholders(strVal);
				}
			});
		}

		// Initialize LoadTimeWeaverAware beans early to allow for registering their transformers early.
		String[] weaverAwareNames = beanFactory.getBeanNamesForType(LoadTimeWeaverAware.class, false, false);
		for (String weaverAwareName : weaverAwareNames) {
			getBean(weaverAwareName);
		}

		// Stop using the temporary ClassLoader for type matching.
		beanFactory.setTempClassLoader(null);

		// Allow for caching all bean definition metadata, not expecting further changes.
		beanFactory.freezeConfiguration();

		// 重点,开始初始化所有非懒加载的bean
		beanFactory.preInstantiateSingletons();
	}

beanFactory.preInstantiateSingletons() 具体方法如下:

public void preInstantiateSingletons() throws BeansException {
		if (this.logger.isDebugEnabled()) {
			this.logger.debug("Pre-instantiating singletons in " + this);
		}

		// Iterate over a copy to allow for init methods which in turn register new bean definitions.
		// While this may not be part of the regular factory bootstrap, it does otherwise work fine.将所有注册的BeanDefinition 名称保存到起来
		List<String> beanNames = new ArrayList<String>(this.beanDefinitionNames);

		// Trigger initialization of all non-lazy singleton beans...
		for (String beanName : beanNames) {
			// 获取 BeanDefinition
			RootBeanDefinition bd = getMergedLocalBeanDefinition(beanName);
			// bean定义不是抽象、懒加载而且是单例bean
			if (!bd.isAbstract() && bd.isSingleton() && !bd.isLazyInit()) {
				// 工厂bean特有逻辑,这不是我们的关注点,我们关注点是else的 getBean(beanName);
				if (isFactoryBean(beanName)) {
					final FactoryBean<?> factory = (FactoryBean<?>) getBean(FACTORY_BEAN_PREFIX + beanName);
					boolean isEagerInit;
					if (System.getSecurityManager() != null && factory instanceof SmartFactoryBean) {
						isEagerInit = AccessController.doPrivileged(new PrivilegedAction<Boolean>() {
							@Override
							public Boolean run() {
								return ((SmartFactoryBean<?>) factory).isEagerInit();
							}
						}, getAccessControlContext());
					}
					else {
						isEagerInit = (factory instanceof SmartFactoryBean &&
								((SmartFactoryBean<?>) factory).isEagerInit());
					}
					if (isEagerInit) {
						getBean(beanName);
					}
				}
				else {
					// 重点,将 BeanDefinition 创建成bean的核心方法,同时也是执行 BeanPostProcessor 的入口
					getBean(beanName);
				}
			}
		}

		// Trigger post-initialization callback for all applicable beans...
		for (String beanName : beanNames) {
			Object singletonInstance = getSingleton(beanName);
			if (singletonInstance instanceof SmartInitializingSingleton) {
				final SmartInitializingSingleton smartSingleton = (SmartInitializingSingleton) singletonInstance;
				if (System.getSecurityManager() != null) {
					AccessController.doPrivileged(new PrivilegedAction<Object>() {
						@Override
						public Object run() {
							smartSingleton.afterSingletonsInstantiated();
							return null;
						}
					}, getAccessControlContext());
				}
				else {
					smartSingleton.afterSingletonsInstantiated();
				}
			}
		}
	}

getBean(beanName) 方法比较复杂,这里只列举出关键点:AbstractAutowireCapableBeanFactory 的 initializeBean方法,所有bean的创建都绕不开这个方法,这个方法是执行实现了 BeanPostProcessor 的bean的逻辑:

protected Object initializeBean(final String beanName, final Object bean, RootBeanDefinition mbd) {
		if (System.getSecurityManager() != null) {
			AccessController.doPrivileged(new PrivilegedAction<Object>() {
				@Override
				public Object run() {
					invokeAwareMethods(beanName, bean);
					return null;
				}
			}, getAccessControlContext());
		}
		else {
			invokeAwareMethods(beanName, bean);
		}

		Object wrappedBean = bean;
		if (mbd == null || !mbd.isSynthetic()) {
			// 执行 BeanPostProcessor 的 postProcessBeforeInitialization 方法
			wrappedBean = applyBeanPostProcessorsBeforeInitialization(wrappedBean, beanName);
		}

		try {
			invokeInitMethods(beanName, wrappedBean, mbd);
		}
		catch (Throwable ex) {
			throw new BeanCreationException(
					(mbd != null ? mbd.getResourceDescription() : null),
					beanName, "Invocation of init method failed", ex);
		}
		if (mbd == null || !mbd.isSynthetic()) {
			// 重点,InfrastructureAdvisorAutoProxyCreator 实现了BeanPostProcessor 接口,所以这里会调用 InfrastructureAdvisorAutoProxyCreator 的postProcessBeforeInitialization 方法,
			// wrappedBean 是生成代理后对象,wrappedBean 会替换掉传入的bean,如果当前bean需要事务,wrappedBean就是被JDK或者CGLIB代理后的bean
			wrappedBean = postProcessAfterInitialization(wrappedBean, beanName);
		}
		return wrappedBean;
	}

InfrastructureAdvisorAutoProxyCreator 的 postProcessAfterInitialization 定义在父类:AbstractAutoProxyCreator,AbstractAutoProxyCreator这个类同时是Spring AOP处理的入口,并不是说事务处理独有的,具体实现如下:

	public Object postProcessAfterInitialization(Object bean, String beanName) throws BeansException {
		if (bean != null) {
			Object cacheKey = getCacheKey(bean.getClass(), beanName);
			if (!this.earlyProxyReferences.contains(cacheKey)) {
				// 重点,AOP生成代理对象的入口,这里也会生成事务代理对象
				return wrapIfNecessary(bean, beanName, cacheKey);
			}
		}
		return bean;
	}
	
	// 从Spring容器中获取所有切面bean,并判断是否在切面中,如果是的话生成一个代理对象,怎么代理由具体的切面定义
	protected Object wrapIfNecessary(Object bean, String beanName, Object cacheKey) {
		if (beanName != null && this.targetSourcedBeans.contains(beanName)) {
			return bean;
		}
		if (Boolean.FALSE.equals(this.advisedBeans.get(cacheKey))) {
			return bean;
		}
		// 这里就是用来判断当前bean 能不能代理
		if (isInfrastructureClass(bean.getClass()) || shouldSkip(bean.getClass(), beanName)) {
			this.advisedBeans.put(cacheKey, Boolean.FALSE);
			return bean;
		}

		// 首先查找切面Bean,对于本篇文章就是我们上面定义的 BeanFactoryTransactionAttributeSourceAdvisor 的 BeanDefinition,注意:实际应用场景肯定不仅只有一个切面的。
		// spring现在只有BeanDefinition,这个方法先通过获取切面 beanNames ,然后再调用上面的 getBean 方法生成 BeanFactoryTransactionAttributeSourceAdvisor bean对象
		Object[] specificInterceptors = getAdvicesAndAdvisorsForBean(bean.getClass(), beanName, null);
		// 需要代理,生成代理对象
		if (specificInterceptors != DO_NOT_PROXY) {
			// 加入缓存中
			this.advisedBeans.put(cacheKey, Boolean.TRUE);
			// 真正生成代理的地方
			Object proxy = createProxy(
					bean.getClass(), beanName, specificInterceptors, new SingletonTargetSource(bean));
			this.proxyTypes.put(cacheKey, proxy.getClass());
			// 返回代理后的bean
			return proxy;
		}

		this.advisedBeans.put(cacheKey, Boolean.FALSE);
		// 不代理,返回原始bean
		return bean;
	}
	
	// 获取切面bean,先通过获取切面BeanNames ,然后通过获取bean
	protected Object[] getAdvicesAndAdvisorsForBean(Class<?> beanClass, String beanName, TargetSource targetSource) {
		List<Advisor> advisors = findEligibleAdvisors(beanClass, beanName);
		if (advisors.isEmpty()) {
			return DO_NOT_PROXY;
		}
		return advisors.toArray();
	}
	
	protected List<Advisor> findEligibleAdvisors(Class<?> beanClass, String beanName) {
		// 这个方法就是获取切面bean,首先从容器中获取实现了 Advisor 的beanNames,然后通过beanName再获取Bean,
		// 对于本篇文章只定义了一个事务切面,所以这里返回的结果是 BeanFactoryTransactionAttributeSourceAdvisor Bean对象
		List<Advisor> candidateAdvisors = findCandidateAdvisors();
		// 判断当前bean是否能被切面应用,判断规则在下面有说明
		List<Advisor> eligibleAdvisors = findAdvisorsThatCanApply(candidateAdvisors, beanClass, beanName);
		extendAdvisors(eligibleAdvisors);
		if (!eligibleAdvisors.isEmpty()) {
			eligibleAdvisors = sortAdvisors(eligibleAdvisors);
		}
		return eligibleAdvisors;
	}
	
	// findAdvisorsThatCanApply(candidateAdvisors, beanClass, beanName) 具体实现逻辑在org.springframework.aop.support.AopUtils#findAdvisorsThatCanApply 
	public static List<Advisor> findAdvisorsThatCanApply(List<Advisor> candidateAdvisors, Class<?> clazz) {
		if (candidateAdvisors.isEmpty()) {
			return candidateAdvisors;
		}
		List<Advisor> eligibleAdvisors = new LinkedList<Advisor>();
		for (Advisor candidate : candidateAdvisors) {
			if (candidate instanceof IntroductionAdvisor && canApply(candidate, clazz)) {
				eligibleAdvisors.add(candidate);
			}
		}
		boolean hasIntroductions = !eligibleAdvisors.isEmpty();
		for (Advisor candidate : candidateAdvisors) {
			if (candidate instanceof IntroductionAdvisor) {
				// already processed
				continue;
			}
			if (canApply(candidate, clazz, hasIntroductions)) {
				eligibleAdvisors.add(candidate);
			}
		}
		return eligibleAdvisors;
	}
	
	//  请注意,这个方法是AOP通用判断是否能应用切面的方法,不是事务处理独有的
	public static boolean canApply(Pointcut pc, Class<?> targetClass, boolean hasIntroductions) {
		Assert.notNull(pc, "Pointcut must not be null");
		// 首先判断类能不能匹配上,匹配不上就返回false, BeanFactoryTransactionAttributeSourceAdvisor 的切点类:
		// TransactionAttributeSourcePointcut,默认ClassFilter 返回true,所以这里不会进if
		if (!pc.getClassFilter().matches(targetClass)) {
			return false;
		}

		// 然后判断方法匹配,TransactionAttributeSourcePointcut 通过继承关系可以看到不是 MethodMatcher.TRUE,所以不会进if
		MethodMatcher methodMatcher = pc.getMethodMatcher();
		if (methodMatcher == MethodMatcher.TRUE) {
			// No need to iterate the methods if we‘re matching any method anyway...
			return true;
		}

		// 判断是不是引介方法匹配,什么是引介增强:为目标类追加方法,属于类的增强,
		// 而 PointcutAdvisor 属于拦截目标类的方法并增强,TransactionAttributeSourcePointcut  是 PointcutAdvisor 的子类,不属于引介增强
		IntroductionAwareMethodMatcher introductionAwareMethodMatcher = null;
		if (methodMatcher instanceof IntroductionAwareMethodMatcher) {
			introductionAwareMethodMatcher = (IntroductionAwareMethodMatcher) methodMatcher;
		}
		
		// 开始读取目标类的每一个方法,判断是否在切面中
		Set<Class<?>> classes = new LinkedHashSet<Class<?>>(ClassUtils.getAllInterfacesForClassAsSet(targetClass));
		classes.add(targetClass);
		for (Class<?> clazz : classes) {
			Method[] methods = ReflectionUtils.getAllDeclaredMethods(clazz);
			for (Method method : methods) {
				// 对于事务而言,判断条件重点在 TransactionAttributeSourcePointcut 的 matches 方法
				if ((introductionAwareMethodMatcher != null &&
						introductionAwareMethodMatcher.matches(method, targetClass, hasIntroductions)) ||
						methodMatcher.matches(method, targetClass)) {
					return true;
				}
			}
		}

		return false;
	}
 	// TransactionAttributeSourcePointcut 的 matches 方法核心逻辑在 SpringTransactionAnnotationParser#parseTransactionAnnotation(java.lang.reflect.AnnotatedElement)
	// 注意:只会判断 public 的方法,判断有没有 Transactional 注解;判断的顺序为:先判断方法上面有没有,再判断类上面有没有。
	// 判断核心就是看方法或类上面有没有 Transactional 注解,有这个注解就解析这个注解的元数据
	public TransactionAttribute parseTransactionAnnotation(AnnotatedElement ae) {
		AnnotationAttributes attributes = AnnotatedElementUtils.getMergedAnnotationAttributes(ae, Transactional.class);
		if (attributes != null) {
			return parseTransactionAnnotation(attributes);
		}
		else {
			return null;
		}
	}
	// 解析 Transactional  注解元数据
	protected TransactionAttribute parseTransactionAnnotation(AnnotationAttributes attributes) {
		RuleBasedTransactionAttribute rbta = new RuleBasedTransactionAttribute();
		Propagation propagation = attributes.getEnum("propagation");
		rbta.setPropagationBehavior(propagation.value());
		Isolation isolation = attributes.getEnum("isolation");
		rbta.setIsolationLevel(isolation.value());
		rbta.setTimeout(attributes.getNumber("timeout").intValue());
		rbta.setReadOnly(attributes.getBoolean("readOnly"));
		rbta.setQualifier(attributes.getString("value"));
		ArrayList<RollbackRuleAttribute> rollBackRules = new ArrayList<RollbackRuleAttribute>();
		Class<?>[] rbf = attributes.getClassArray("rollbackFor");
		for (Class<?> rbRule : rbf) {
			RollbackRuleAttribute rule = new RollbackRuleAttribute(rbRule);
			rollBackRules.add(rule);
		}
		String[] rbfc = attributes.getStringArray("rollbackForClassName");
		for (String rbRule : rbfc) {
			RollbackRuleAttribute rule = new RollbackRuleAttribute(rbRule);
			rollBackRules.add(rule);
		}
		Class<?>[] nrbf = attributes.getClassArray("noRollbackFor");
		for (Class<?> rbRule : nrbf) {
			NoRollbackRuleAttribute rule = new NoRollbackRuleAttribute(rbRule);
			rollBackRules.add(rule);
		}
		String[] nrbfc = attributes.getStringArray("noRollbackForClassName");
		for (String rbRule : nrbfc) {
			NoRollbackRuleAttribute rule = new NoRollbackRuleAttribute(rbRule);
			rollBackRules.add(rule);
		}
		rbta.getRollbackRules().addAll(rollBackRules);
		return rbta;
	}
	// 以上就是 findAdvisorsThatCanApply(candidateAdvisors, beanClass, beanName) 的逻辑

	// 下面回到wrapIfNecessary方法,如果当前bean需要生成代理对象,会调用下面的这个方法
	protected Object createProxy(
			Class<?> beanClass, String beanName, Object[] specificInterceptors, TargetSource targetSource) {

		if (this.beanFactory instanceof ConfigurableListableBeanFactory) {
			AutoProxyUtils.exposeTargetClass((ConfigurableListableBeanFactory) this.beanFactory, beanName, beanClass);
		}

		// 创建代理工厂,用于创建代理bean
		ProxyFactory proxyFactory = new ProxyFactory();
		proxyFactory.copyFrom(this);

		// 判断是否配置了代理目标类,配置了这个选项会全部使用cglib代理
		if (!proxyFactory.isProxyTargetClass()) {
			if (shouldProxyTargetClass(beanClass, beanName)) {
				proxyFactory.setProxyTargetClass(true);
			}
			else {
				evaluateProxyInterfaces(beanClass, proxyFactory);
			}
		}
		// 把所有的切面类放入 ProxyFactory
		Advisor[] advisors = buildAdvisors(beanName, specificInterceptors);
		proxyFactory.addAdvisors(advisors);
		proxyFactory.setTargetSource(targetSource);
		customizeProxyFactory(proxyFactory);

		proxyFactory.setFrozen(this.freezeProxy);
		if (advisorsPreFiltered()) {
			proxyFactory.setPreFiltered(true);
		}
		
		// 开始创建代理bean
		return proxyFactory.getProxy(getProxyClassLoader());
	}

proxyFactory.getProxy(getProxyClassLoader()) 方法实现:

	public Object getProxy(ClassLoader classLoader) {
		return createAopProxy().getProxy(classLoader);
	}
	
	// createAopProxy方法逻辑,config 其实就是上面的 proxyFactory 对象,这个对象包含了目标对象以及切面类:
	public AopProxy createAopProxy(AdvisedSupport config) throws AopConfigException {
		// optimize:代理是否应该执行优化,一般用不上
		// proxyTargetClass:这个属性为treu时,不管目标类是不是实现的接口,都使用cglib代理
		// hasNoUserSuppliedProxyInterfaces:是否只使用了Spring支持的代理接口,如果用户自定义了代理接口不能进行cglib代理
		if (config.isOptimize() || config.isProxyTargetClass() || hasNoUserSuppliedProxyInterfaces(config)) {
			Class<?> targetClass = config.getTargetClass();
			if (targetClass == null) {
				throw new AopConfigException("TargetSource cannot determine target class: " +
						"Either an interface or a target is required for proxy creation.");
			}
			// 如果目标类是接口或者已经被jdk代理过了,使用jdk代理
			if (targetClass.isInterface() || Proxy.isProxyClass(targetClass)) {
				return new JdkDynamicAopProxy(config);
			}
			// 其他情况使用CGLIB代理
			return new ObjenesisCglibAopProxy(config);
		}
		// 使用JDK代理
		else {
			return new JdkDynamicAopProxy(config);
		}
	}

	// ObjenesisCglibAopProxy 的 getProxy(classLoader) 方法,cglib是使用Enhancer创建代理对象的 :
	public Object getProxy(ClassLoader classLoader) {
		if (logger.isDebugEnabled()) {
			logger.debug("Creating CGLIB proxy: target source is " + this.advised.getTargetSource());
		}

		try {
			// 获取目标类
			Class<?> rootClass = this.advised.getTargetClass();
			Assert.state(rootClass != null, "Target class must be available for creating a CGLIB proxy");
			// 代理类的父类,默认是目标类
			Class<?> proxySuperClass = rootClass;
			// 如果目标类以及是cglib代理类,
			if (ClassUtils.isCglibProxyClass(rootClass)) {
				// 取cglib代理类的父类作为代理类的父类
				proxySuperClass = rootClass.getSuperclass();
				// 获取代理类的接口追加到当前类的接口集合中
				Class<?>[] additionalInterfaces = rootClass.getInterfaces();
				for (Class<?> additionalInterface : additionalInterfaces) {
					this.advised.addInterface(additionalInterface);
				}
			}

			// 验证目标类是否能被代理,仅仅是打印日志,不做其他处理
			validateClassIfNecessary(proxySuperClass, classLoader);

			// 使用Enhancer 来构造cglib代理对象
			Enhancer enhancer = createEnhancer();
			if (classLoader != null) {
				enhancer.setClassLoader(classLoader);
				if (classLoader instanceof SmartClassLoader &&
						((SmartClassLoader) classLoader).isClassReloadable(proxySuperClass)) {
					enhancer.setUseCache(false);
				}
			}
			enhancer.setSuperclass(proxySuperClass);
			enhancer.setInterfaces(AopProxyUtils.completeProxiedInterfaces(this.advised));
			enhancer.setNamingPolicy(SpringNamingPolicy.INSTANCE);
			enhancer.setStrategy(new ClassLoaderAwareUndeclaredThrowableStrategy(classLoader));

			// 重点,设置回调的类,很重要的一个类 DynamicAdvisedInterceptor,这个类就是应用AOP 通知的地方,对于本篇文章就是应用TransactionInterceptor
			Callback[] callbacks = getCallbacks(rootClass);
			Class<?>[] types = new Class<?>[callbacks.length];
			for (int x = 0; x < types.length; x++) {
				types[x] = callbacks[x].getClass();
			}
			// fixedInterceptorMap only populated at this point, after getCallbacks call above
			enhancer.setCallbackFilter(new ProxyCallbackFilter(
					this.advised.getConfigurationOnlyCopy(), this.fixedInterceptorMap, this.fixedInterceptorOffset));
			enhancer.setCallbackTypes(types);

			// 创建代理类的字节码,并创建实例,实例设置回调
			return createProxyClassAndInstance(enhancer, callbacks);
		}
		catch (CodeGenerationException ex) {
			throw new AopConfigException("Could not generate CGLIB subclass of " + this.advised.getTargetClass() +
					": Common causes of this problem include using a final class or a non-visible class",
					ex);
		}
		catch (IllegalArgumentException ex) {
			throw new AopConfigException("Could not generate CGLIB subclass of " + this.advised.getTargetClass() +
					": Common causes of this problem include using a final class or a non-visible class",
					ex);
		}
		catch (Throwable ex) {
			// TargetSource.getTarget() failed
			throw new AopConfigException("Unexpected AOP exception", ex);
		}
	}

	
// JdkDynamicAopProxy  的 getProxy(classLoader) 方法:
public Object getProxy(ClassLoader classLoader) {
		if (logger.isDebugEnabled()) {
			logger.debug("Creating JDK dynamic proxy: target source is " + this.advised.getTargetSource());
		}
		Class<?>[] proxiedInterfaces = AopProxyUtils.completeProxiedInterfaces(this.advised, true);
		findDefinedEqualsAndHashCodeMethods(proxiedInterfaces);
		return Proxy.newProxyInstance(classLoader, proxiedInterfaces, this);
	}

通过2. 生成事务代理对象,此时创建的bean就是以及被JDK或者CGLIB代理的类,这一步是Spring AOP通用的处理逻辑,那具体是怎么运行的呢?

JDK动态代理运行:

	// 本质是调用org.springframework.aop.framework.JdkDynamicAopProxy#invoke方法
	public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
		MethodInvocation invocation;
		Object oldProxy = null;
		boolean setProxyContext = false;

		TargetSource targetSource = this.advised.targetSource;
		Class<?> targetClass = null;
		Object target = null;

		try {
			if (!this.equalsDefined && AopUtils.isEqualsMethod(method)) {
				// The target does not implement the equals(Object) method itself.
				return equals(args[0]);
			}
			else if (!this.hashCodeDefined && AopUtils.isHashCodeMethod(method)) {
				// The target does not implement the hashCode() method itself.
				return hashCode();
			}
			else if (method.getDeclaringClass() == DecoratingProxy.class) {
				// There is only getDecoratedClass() declared -> dispatch to proxy config.
				return AopProxyUtils.ultimateTargetClass(this.advised);
			}
			else if (!this.advised.opaque && method.getDeclaringClass().isInterface() &&
					method.getDeclaringClass().isAssignableFrom(Advised.class)) {
				// Service invocations on ProxyConfig with the proxy config...
				return AopUtils.invokeJoinpointUsingReflection(this.advised, method, args);
			}

			Object retVal;

			if (this.advised.exposeProxy) {
				// Make invocation available if necessary.
				oldProxy = AopContext.setCurrentProxy(proxy);
				setProxyContext = true;
			}

			// May be null. Get as late as possible to minimize the time we "own" the target,
			// in case it comes from a pool.
			target = targetSource.getTarget();
			if (target != null) {
				targetClass = target.getClass();
			}

			// 获取方法的拦截器链,对于本篇文章就是关键类:BeanFactoryTransactionAttributeSourceAdvisor
			List<Object> chain = this.advised.getInterceptorsAndDynamicInterceptionAdvice(method, targetClass);

			// Check whether we have any advice. If we don‘t, we can fallback on direct
			// reflective invocation of the target, and avoid creating a MethodInvocation.
			if (chain.isEmpty()) {
				// We can skip creating a MethodInvocation: just invoke the target directly
				// Note that the final invoker must be an InvokerInterceptor so we know it does
				// nothing but a reflective operation on the target, and no hot swapping or fancy proxying.
				Object[] argsToUse = AopProxyUtils.adaptArgumentsIfNecessary(method, args);
				retVal = AopUtils.invokeJoinpointUsingReflection(target, method, argsToUse);
			}
			else {
				// 将所有参数:代理对象,目标对象,方法,参数,拦截器链封装到一个ReflectiveMethodInvocation对象中
				invocation = new ReflectiveMethodInvocation(proxy, target, method, args, targetClass, chain);
				// 然后调用ReflectiveMethodInvocation的proceed方法,会执行拦截器
				retVal = invocation.proceed();
			}

			// Massage return value if necessary.
			Class<?> returnType = method.getReturnType();
			if (retVal != null && retVal == target &&
					returnType != Object.class && returnType.isInstance(proxy) &&
					!RawTargetAccess.class.isAssignableFrom(method.getDeclaringClass())) {
				// Special case: it returned "this" and the return type of the method
				// is type-compatible. Note that we can‘t help if the target sets
				// a reference to itself in another returned object.
				retVal = proxy;
			}
			else if (retVal == null && returnType != Void.TYPE && returnType.isPrimitive()) {
				throw new AopInvocationException(
						"Null return value from advice does not match primitive return type for: " + method);
			}
			return retVal;
		}
		finally {
			if (target != null && !targetSource.isStatic()) {
				// Must have come from TargetSource.
				targetSource.releaseTarget(target);
			}
			if (setProxyContext) {
				// Restore old proxy.
				AopContext.setCurrentProxy(oldProxy);
			}
		}
	}

org.springframework.aop.framework.ReflectiveMethodInvocation#proceed 方法:

	public Object proceed() throws Throwable {
		// 所有拦截器调用完成,一般情况是没有匹配到任意的拦截器,这里会执行目标类本身的方法
		if (this.currentInterceptorIndex == this.interceptorsAndDynamicMethodMatchers.size() - 1) {
			return invokeJoinpoint();
		}
		
		// 获取拦截器链中的第一个拦截器
		Object interceptorOrInterceptionAdvice =
				this.interceptorsAndDynamicMethodMatchers.get(++this.currentInterceptorIndex);
		// 通知器或通知是动态匹配方法拦截器类型,对于本篇文章,interceptorOrInterceptionAdvice 是TransactionInterceptor对象,
		// 所有走的是else,直接执行TransactionInterceptor的invoke方法
		if (interceptorOrInterceptionAdvice instanceof InterceptorAndDynamicMethodMatcher) {
			// 动态匹配方法拦截器
			InterceptorAndDynamicMethodMatcher dm =
					(InterceptorAndDynamicMethodMatcher) interceptorOrInterceptionAdvice;
			// 匹配成功就执行对应的拦截器
			if (dm.methodMatcher.matches(this.method, this.targetClass, this.arguments)) {
				return dm.interceptor.invoke(this);
			}
			else {
				// 如果不匹配,就跳过此拦截器,递归执行下一个拦截器
				return proceed();
			}
		}
		else {
			// 如果是一个interceptor,直接调用这个interceptor对应的方法
			return ((MethodInterceptor) interceptorOrInterceptionAdvice).invoke(this);
		}
	}

CGLIB代理运行:

	// 其实就是创建代理对象时设置的回调类DynamicAdvisedInterceptor
	private static class DynamicAdvisedInterceptor implements MethodInterceptor, Serializable {

		private final AdvisedSupport advised;

		public DynamicAdvisedInterceptor(AdvisedSupport advised) {
			this.advised = advised;
		}

		// 主要是这个方法执行拦截,处理逻辑大致和JDK动态代理差不多,都是获取拦截器链,
		// 然后构建ReflectiveMethodInvocation的子类CglibMethodInvocation对象,
		// 执行ReflectiveMethodInvocation的proceed方法
		@Override
		public Object intercept(Object proxy, Method method, Object[] args, MethodProxy methodProxy) throws Throwable {
			Object oldProxy = null;
			boolean setProxyContext = false;
			Class<?> targetClass = null;
			Object target = null;
			try {
				if (this.advised.exposeProxy) {
					// Make invocation available if necessary.
					oldProxy = AopContext.setCurrentProxy(proxy);
					setProxyContext = true;
				}
				// May be null. Get as late as possible to minimize the time we
				// "own" the target, in case it comes from a pool...
				target = getTarget();
				if (target != null) {
					targetClass = target.getClass();
				}
				// 获取方法的拦截器链,对于本篇文章就是关键类:BeanFactoryTransactionAttributeSourceAdvisor
				List<Object> chain = this.advised.getInterceptorsAndDynamicInterceptionAdvice(method, targetClass);
				Object retVal;
				// Check whether we only have one InvokerInterceptor: that is,
				// no real advice, but just reflective invocation of the target.
				if (chain.isEmpty() && Modifier.isPublic(method.getModifiers())) {
					// We can skip creating a MethodInvocation: just invoke the target directly.
					// Note that the final invoker must be an InvokerInterceptor, so we know
					// it does nothing but a reflective operation on the target, and no hot
					// swapping or fancy proxying.
					Object[] argsToUse = AopProxyUtils.adaptArgumentsIfNecessary(method, args);
					retVal = methodProxy.invoke(target, argsToUse);
				}
				else {
					// 将参数封装成CglibMethodInvocation对象并执行proceed方法,CglibMethodInvocation 其实是ReflectiveMethodInvocation的子类,可以理解为ReflectiveMethodInvocation是模板类,CglibMethodInvocation通过重写了部分方法,proceed是两种代理处理的共同逻辑
					retVal = new CglibMethodInvocation(proxy, target, method, args, targetClass, chain, methodProxy).proceed();
				}
				retVal = processReturnType(proxy, target, method, retVal);
				return retVal;
			}
			finally {
				if (target != null) {
					releaseTarget(target);
				}
				if (setProxyContext) {
					// Restore old proxy.
					AopContext.setCurrentProxy(oldProxy);
				}
			}
		}

		@Override
		public boolean equals(Object other) {
			return (this == other ||
					(other instanceof DynamicAdvisedInterceptor &&
							this.advised.equals(((DynamicAdvisedInterceptor) other).advised)));
		}

		/**
		 * CGLIB uses this to drive proxy creation.
		 */
		@Override
		public int hashCode() {
			return this.advised.hashCode();
		}

		protected Object getTarget() throws Exception {
			return this.advised.getTargetSource().getTarget();
		}

		protected void releaseTarget(Object target) throws Exception {
			this.advised.getTargetSource().releaseTarget(target);
		}
	}

事务的最终执行类 TransactionInterceptor 的invoke 方法:

	public Object invoke(final MethodInvocation invocation) throws Throwable {
		// Work out the target class: may be {@code null}.
		// The TransactionAttributeSource should be passed the target class
		// as well as the method, which may be from an interface.
		Class<?> targetClass = (invocation.getThis() != null ? AopUtils.getTargetClass(invocation.getThis()) : null);

		// Adapt to TransactionAspectSupport‘s invokeWithinTransaction...
		return invokeWithinTransaction(invocation.getMethod(), targetClass, new InvocationCallback() {
			@Override
			public Object proceedWithInvocation() throws Throwable {
				// 事务执行完毕后调用链继续向下执行
				return invocation.proceed();
			}
		});
	}

	protected Object invokeWithinTransaction(Method method, Class<?> targetClass, final InvocationCallback invocation)
			throws Throwable {

		// 获取当前方法的事务属性
		final TransactionAttribute txAttr = getTransactionAttributeSource().getTransactionAttribute(method, targetClass);
		// 获取事务管理器
		final PlatformTransactionManager tm = determineTransactionManager(txAttr);
		// 方法名
		final String joinpointIdentification = methodIdentification(method, targetClass, txAttr);

		// 如果方法没有事务或者事务管理器不属于CallbackPreferringPlatformTransactionManager,CallbackPreferringPlatformTransactionManager需要回调函数来实现事务流程,而我们常用的DataSourceTransactionManager就不是CallbackPreferringPlatformTransactionManager
		if (txAttr == null || !(tm instanceof CallbackPreferringPlatformTransactionManager)) {
			// 创建TransactionInfo事务对象,事务的管理都是通过TransactionInfo对象来完成,这里创建事务会使用到Spring的事务隔离级别,具体的逻辑可以自行查看
			TransactionInfo txInfo = createTransactionIfNecessary(tm, txAttr, joinpointIdentification);
			Object retVal = null;
			try {
				// 拦截器链继续向下执行
				retVal = invocation.proceedWithInvocation();
			}
			catch (Throwable ex) {
				// 抛出异常时提交或者回滚事务
				completeTransactionAfterThrowing(txInfo, ex);
				throw ex;
			}
			finally {
				// 重置TransactionInfo 的 ThreadLocal
				cleanupTransactionInfo(txInfo);
			}
			// 提交/回滚事务
			commitTransactionAfterReturning(txInfo);
			return retVal;
		}
		// else使用的是CallbackPreferringPlatformTransactionManager,
		else {
			// .......略
		}
	}

总结

以上就是事务应用到业务场景中的原理,可以简单理解:Spring事务是在Spring AOP的基础上开发的,关注关键类:TransactionInterceptor 的实现就行了,不管是JDK动态代理还是CGLIB代理都是要用到这个类去提交/回滚事务的。如有错误欢迎指出。

【源码讲解】Spring事务是如何应用到你的业务场景中的?

原文:https://www.cnblogs.com/winkin/p/13667568.html

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