【Spring源码分析】AOP源码解析(下篇)

时间:2021-08-06 12:33:32

AspectJAwareAdvisorAutoProxyCreator及为Bean生成代理时机分析

上篇文章说了,org.springframework.aop.aspectj.autoproxy.AspectJAwareAdvisorAutoProxyCreator这个类是Spring提供给开发者的AOP的核心类,就是AspectJAwareAdvisorAutoProxyCreator完成了【类/接口-->代理】的转换过程,首先我们看一下AspectJAwareAdvisorAutoProxyCreator的层次结构:

【Spring源码分析】AOP源码解析(下篇)

这里最值得注意的一点是最左下角的那个方框,我用几句话总结一下:

  1. AspectJAwareAdvisorAutoProxyCreator是BeanPostProcessor接口的实现类
  2. postProcessBeforeInitialization方法与postProcessAfterInitialization方法实现在父类AbstractAutoProxyCreator
  3. postProcessBeforeInitialization方法是一个空实现
  4. 逻辑代码在postProcessAfterInitialization方法中

基于以上的分析,将Bean生成代理的时机已经一目了然了:在每个Bean初始化之后,如果需要,调用AspectJAwareAdvisorAutoProxyCreator中的postProcessBeforeInitialization为Bean生成代理

代理对象实例化----判断是否为<bean>生成代理

上文分析了Bean生成代理的时机是在每个Bean初始化之后,下面把代码定位到Bean初始化之后,先是AbstractAutowireCapableBeanFactory的initializeBean方法进行初始化:

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

初始化之前是第16行的applyBeanPostProcessorsBeforeInitialization方法,初始化之后即29行的applyBeanPostProcessorsAfterInitialization方法:

 public Object applyBeanPostProcessorsAfterInitialization(Object existingBean, String beanName)
throws BeansException { Object result = existingBean;
for (BeanPostProcessor beanProcessor : getBeanPostProcessors()) {
result = beanProcessor.postProcessAfterInitialization(result, beanName);
if (result == null) {
return result;
}
}
return result;
}

这里调用每个BeanPostProcessor的postProcessBeforeInitialization方法。按照之前的分析,看一下AbstractAutoProxyCreator的postProcessAfterInitialization方法实现:

 public Object postProcessAfterInitialization(Object bean, String beanName) throws BeansException {
if (bean != null) {
Object cacheKey = getCacheKey(bean.getClass(), beanName);
if (!this.earlyProxyReferences.contains(cacheKey)) {
return wrapIfNecessary(bean, beanName, cacheKey);
}
}
return bean;
}

跟一下第5行的方法wrapIfNecessary:

 protected Object wrapIfNecessary(Object bean, String beanName, Object cacheKey) {
if (this.targetSourcedBeans.contains(beanName)) {
return bean;
}
if (this.nonAdvisedBeans.contains(cacheKey)) {
return bean;
}
if (isInfrastructureClass(bean.getClass()) || shouldSkip(bean.getClass(), beanName)) {
this.nonAdvisedBeans.add(cacheKey);
return bean;
} // Create proxy if we have advice.
Object[] specificInterceptors = getAdvicesAndAdvisorsForBean(bean.getClass(), beanName, null);
if (specificInterceptors != DO_NOT_PROXY) {
this.advisedBeans.add(cacheKey);
Object proxy = createProxy(bean.getClass(), beanName, specificInterceptors, new SingletonTargetSource(bean));
this.proxyTypes.put(cacheKey, proxy.getClass());
return proxy;
} this.nonAdvisedBeans.add(cacheKey);
return bean;
}

第2行~第11行是一些不需要生成代理的场景判断,这里略过。首先我们要思考的第一个问题是:哪些目标对象需要生成代理因为配置文件里面有很多Bean,肯定不能对每个Bean都生成代理,因此需要一套规则判断Bean是不是需要生成代理,这套规则就是第14行的代码getAdvicesAndAdvisorsForBean:

 protected List<Advisor> findEligibleAdvisors(Class beanClass, String beanName) {
List<Advisor> candidateAdvisors = findCandidateAdvisors();
List<Advisor> eligibleAdvisors = findAdvisorsThatCanApply(candidateAdvisors, beanClass, beanName);
extendAdvisors(eligibleAdvisors);
if (!eligibleAdvisors.isEmpty()) {
eligibleAdvisors = sortAdvisors(eligibleAdvisors);
}
return eligibleAdvisors;
}

顾名思义,方法的意思是为指定class寻找合适的Advisor。

第2行代码,寻找候选Advisors,根据上文的配置文件,有两个候选Advisor,分别是<aop:aspect>节点下的<aop:before>和<aop:after>这两个,这两个在XML解析的时候已经被转换生成了RootBeanDefinition。

跳过第3行的代码,先看下第4行的代码extendAdvisors方法,之后再重点看一下第3行的代码。第4行的代码extendAdvisors方法作用是向候选Advisor链的开头(也就是List.get(0)的位置)添加一个org.springframework.aop.support.DefaultPointcutAdvisor

第3行代码,根据候选Advisors,寻找可以使用的Advisor,跟一下方法实现:

 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;
}

整个方法的主要判断都围绕canApply展开方法:

 public static boolean canApply(Advisor advisor, Class<?> targetClass, boolean hasIntroductions) {
if (advisor instanceof IntroductionAdvisor) {
return ((IntroductionAdvisor) advisor).getClassFilter().matches(targetClass);
}
else if (advisor instanceof PointcutAdvisor) {
PointcutAdvisor pca = (PointcutAdvisor) advisor;
return canApply(pca.getPointcut(), targetClass, hasIntroductions);
}
else {
// It doesn't have a pointcut so we assume it applies.
return true;
}
}

第一个参数advisor的实际类型是AspectJPointcutAdvisor,它是PointcutAdvisor的子类,因此执行第7行的方法:

 public static boolean canApply(Pointcut pc, Class<?> targetClass, boolean hasIntroductions) {
if (!pc.getClassFilter().matches(targetClass)) {
return false;
} MethodMatcher methodMatcher = pc.getMethodMatcher();
IntroductionAwareMethodMatcher introductionAwareMethodMatcher = null;
if (methodMatcher instanceof IntroductionAwareMethodMatcher) {
introductionAwareMethodMatcher = (IntroductionAwareMethodMatcher) methodMatcher;
} Set<Class> classes = new HashSet<Class>(ClassUtils.getAllInterfacesForClassAsSet(targetClass));
classes.add(targetClass);
for (Class<?> clazz : classes) {
Method[] methods = clazz.getMethods();
for (Method method : methods) {
if ((introductionAwareMethodMatcher != null &&
introductionAwareMethodMatcher.matches(method, targetClass, hasIntroductions)) ||
methodMatcher.matches(method, targetClass)) {
return true;
}
}
}
return false;
}

这个方法其实就是拿当前Advisor对应的expression做了两层判断:

  1. 目标类必须满足expression的匹配规则
  2. 目标类中的方法必须满足expression的匹配规则,当然这里方法不是全部需要满足expression的匹配规则,有一个方法满足即可

如果以上两条都满足,那么容器则会判断该<bean>满足条件,需要被生成代理对象,具体方式为返回一个数组对象,该数组对象中存储的是<bean>对应的Advisor。

代理对象实例化----为<bean>生成代理代码上下文梳理

上文分析了为<bean>生成代理的条件,现在就正式看一下Spring上下文是如何为<bean>生成代理的。回到AbstractAutoProxyCreator的wrapIfNecessary方法:

 protected Object wrapIfNecessary(Object bean, String beanName, Object cacheKey) {
if (this.targetSourcedBeans.contains(beanName)) {
return bean;
}
if (this.nonAdvisedBeans.contains(cacheKey)) {
return bean;
}
if (isInfrastructureClass(bean.getClass()) || shouldSkip(bean.getClass(), beanName)) {
this.nonAdvisedBeans.add(cacheKey);
return bean;
} // Create proxy if we have advice.
Object[] specificInterceptors = getAdvicesAndAdvisorsForBean(bean.getClass(), beanName, null);
if (specificInterceptors != DO_NOT_PROXY) {
this.advisedBeans.add(cacheKey);
Object proxy = createProxy(bean.getClass(), beanName, specificInterceptors, new SingletonTargetSource(bean));
this.proxyTypes.put(cacheKey, proxy.getClass());
return proxy;
} this.nonAdvisedBeans.add(cacheKey);
return bean;
}

第14行拿到<bean>对应的Advisor数组,第15行判断只要Advisor数组不为空,那么就会通过第17行的代码为<bean>创建代理:

 protected Object createProxy(
Class<?> beanClass, String beanName, Object[] specificInterceptors, TargetSource targetSource) { ProxyFactory proxyFactory = new ProxyFactory();
// Copy our properties (proxyTargetClass etc) inherited from ProxyConfig.
proxyFactory.copyFrom(this); if (!shouldProxyTargetClass(beanClass, beanName)) {
// Must allow for introductions; can't just set interfaces to
// the target's interfaces only.
Class<?>[] targetInterfaces = ClassUtils.getAllInterfacesForClass(beanClass, this.proxyClassLoader);
for (Class<?> targetInterface : targetInterfaces) {
proxyFactory.addInterface(targetInterface);
}
} Advisor[] advisors = buildAdvisors(beanName, specificInterceptors);
for (Advisor advisor : advisors) {
proxyFactory.addAdvisor(advisor);
} proxyFactory.setTargetSource(targetSource);
customizeProxyFactory(proxyFactory); proxyFactory.setFrozen(this.freezeProxy);
if (advisorsPreFiltered()) {
proxyFactory.setPreFiltered(true);
} return proxyFactory.getProxy(this.proxyClassLoader);
}

第4行~第6行new出了一个ProxyFactory,Proxy,顾名思义,代理工厂的意思,提供了简单的方式使用代码获取和配置AOP代理。

第8行的代码做了一个判断,判断的内容是<aop:config>这个节点中proxy-target-class="false"或者proxy-target-class不配置,即不使用CGLIB生成代理。如果满足条件,进判断,获取当前Bean实现的所有接口,讲这些接口Class对象都添加到ProxyFactory中。

第17行~第28行的代码没什么看的必要,向ProxyFactory中添加一些参数而已。重点看第30行proxyFactory.getProxy(this.proxyClassLoader)这句:

 public Object getProxy(ClassLoader classLoader) {
return createAopProxy().getProxy(classLoader);
}

实现代码就一行,但是却明确告诉我们做了两件事情:

  1. 创建AopProxy接口实现类
  2. 通过AopProxy接口的实现类的getProxy方法获取<bean>对应的代理

就从这两个点出发,分两部分分析一下。

代理对象实例化----创建AopProxy接口实现类

看一下createAopProxy()方法的实现,它位于DefaultAopProxyFactory类中:

 protected final synchronized AopProxy createAopProxy() {
if (!this.active) {
activate();
}
return getAopProxyFactory().createAopProxy(this);
}

前面的部分没什么必要看,直接进入重点即createAopProxy方法:

 public AopProxy createAopProxy(AdvisedSupport config) throws AopConfigException {
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.");
}
if (targetClass.isInterface()) {
return new JdkDynamicAopProxy(config);
}
if (!cglibAvailable) {
throw new AopConfigException(
"Cannot proxy target class because CGLIB2 is not available. " +
"Add CGLIB to the class path or specify proxy interfaces.");
}
return CglibProxyFactory.createCglibProxy(config);
}
else {
return new JdkDynamicAopProxy(config);
}
}

平时我们说AOP原理三句话就能概括:

  1. 对类生成代理使用CGLIB
  2. 对接口生成代理使用JDK原生的Proxy
  3. 可以通过配置文件指定对接口使用CGLIB生成代理

这三句话的出处就是createAopProxy方法。看到默认是第19行的代码使用JDK自带的Proxy生成代理,碰到以下三种情况例外:

  1. ProxyConfig的isOptimize方法为true,这表示让Spring自己去优化而不是用户指定
  2. ProxyConfig的isProxyTargetClass方法为true,这表示配置了proxy-target-class="true"
  3. ProxyConfig满足hasNoUserSuppliedProxyInterfaces方法执行结果为true,这表示<bean>对象没有实现任何接口或者实现的接口是SpringProxy接口

在进入第2行的if判断之后再根据目标<bean>的类型决定返回哪种AopProxy。简单总结起来就是:

  1. proxy-target-class没有配置或者proxy-target-class="false",返回JdkDynamicAopProxy
  2. proxy-target-class="true"或者<bean>对象没有实现任何接口或者只实现了SpringProxy接口,返回Cglib2AopProxy

当然,不管是JdkDynamicAopProxy还是Cglib2AopProxy,AdvisedSupport都是作为构造函数参数传入的,里面存储了具体的Advisor。

代理对象实例化----通过getProxy方法获取<bean>对应的代理

其实代码已经分析到了JdkDynamicAopProxy和Cglib2AopProxy,剩下的就没什么好讲的了,无非就是看对这两种方式生成代理的熟悉程度而已。

Cglib2AopProxy生成代理的代码就不看了,对Cglib不熟悉的朋友可以看Cglib及其基本使用一文。

JdkDynamicAopProxy生成代理的方式稍微看一下:

 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);
findDefinedEqualsAndHashCodeMethods(proxiedInterfaces);
return Proxy.newProxyInstance(classLoader, proxiedInterfaces, this);
}

这边解释一下第5行和第6行的代码,第5行代码的作用是拿到所有要代理的接口,第6行代码的作用是尝试寻找这些接口方法里面有没有equals方法和hashCode方法,同时都有的话打个标记,寻找结束,equals方法和hashCode方法有特殊处理。

最终通过第7行的Proxy.newProxyInstance方法获取接口/类对应的代理对象,Proxy是JDK原生支持的生成代理的方式。

代理方法调用原理

前面已经详细分析了为接口/类生成代理的原理,生成代理之后就要调用方法了,这里看一下使用JdkDynamicAopProxy调用方法的原理。

由于JdkDynamicAopProxy本身实现了InvocationHandler接口,因此具体代理前后处理的逻辑在invoke方法中:

 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]);
}
if (!this.hashCodeDefined && AopUtils.isHashCodeMethod(method)) {
// The target does not implement the hashCode() method itself.
return hashCode();
}
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();
} // Get the interception chain for this method.
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.
retVal = AopUtils.invokeJoinpointUsingReflection(target, method, args);
}
else {
// We need to create a method invocation...
invocation = new ReflectiveMethodInvocation(proxy, target, method, args, targetClass, chain);
// Proceed to the joinpoint through the interceptor chain.
retVal = invocation.proceed();
} // Massage return value if necessary.
if (retVal != null && retVal == target && method.getReturnType().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;
}
return retVal;
}
finally {
if (target != null && !targetSource.isStatic()) {
// Must have come from TargetSource.
targetSource.releaseTarget(target);
}
if (setProxyContext) {
// Restore old proxy.
AopContext.setCurrentProxy(oldProxy);
}
}
}

第11行~第18行的代码,表示equals方法与hashCode方法即使满足expression规则,也不会为之产生代理内容,调用的是JdkDynamicAopProxy的equals方法与hashCode方法。至于这两个方法是什么作用,可以自己查看一下源代码。

第19行~第23行的代码,表示方法所属的Class是一个接口并且方法所属的Class是AdvisedSupport的父类或者父接口,直接通过反射调用该方法。

第27行~第30行的代码,是用于判断是否将代理暴露出去的,由<aop:config>标签中的expose-proxy="true/false"配置。

第41行的代码,获取AdvisedSupport中的所有拦截器和动态拦截器列表,用于拦截方法,具体到我们的实际代码,列表中有三个Object,分别是:

  • chain.get(0):ExposeInvocationInterceptor,这是一个默认的拦截器,对应的原Advisor为DefaultPointcutAdvisor
  • chain.get(1):MethodBeforeAdviceInterceptor,用于在实际方法调用之前的拦截,对应的原Advisor为AspectJMethodBeforeAdvice
  • chain.get(2):AspectJAfterAdvice,用于在实际方法调用之后的处理

第45行~第50行的代码,如果拦截器列表为空,很正常,因为某个类/接口下的某个方法可能不满足expression的匹配规则,因此此时通过反射直接调用该方法。

第51行~第56行的代码,如果拦截器列表不为空,按照注释的意思,需要一个ReflectiveMethodInvocation,并通过proceed方法对原方法进行拦截,proceed方法感兴趣的朋友可以去看一下,里面使用到了递归的思想对chain中的Object进行了层层的调用。