• Spring源码系列 — Bean生命周期


    前言

    上篇文章中介绍了Spring容器的扩展点,这个是在Bean的创建过程之前执行的逻辑。承接扩展点之后,就是Spring容器的另一个核心:Bean的生命周期过程。这个生命周期过程大致经历了一下的几个阶段

    在本节中重点介绍实例化、填充装配、唤醒Aware方法、BeanPostProcessor后置处理、初始化等过程。关于Bean的销毁过程这里不再介绍。由于Bean的生命周期的维护过程实际上都是由BeanFactory负责,所以在开始Bean的生命周期过程详解之前,先概览性了解BeanFactory。本文目录:

    • BeanFactory概览
    • Bean的实例化
    • Bean的装配
    • Bean的后置处理
    • Bean的初始化

    BeanFactory概览

    简单点说,BeanFactory就是Spring框架的内核,它负责Bean的整个生命周期的管理。在Spring中对该抽象出了一套BeanFactory的接口,仍然遵守接口隔离,单一职责原则。

    Spring将BeanFactory抽象出了最顶层接口,主要提供给client一个Spring容器的视图。
    下面都是根据BeanFactory的功能进行划分拆分隔离出不同功能的Bean工厂:

    1. 具有层次的BeanFactory,存在父子关系
    2. 可罗列的BeanFactory,提供获取Bean定义个数、获取所有的Bean名称、获取所有Bean定义等等的可罗列的能力
    3. 具有装配能力的BeanFactory,提供自动装配Bean的能力,这个可谓是Spring的核心,自动装配依赖注入
    4. 可配置的BeanFactory,提供配置父BeanFactory、类加载器、转换服务等等能力

    这一套BeanFactory可谓抽象的淋漓尽致。从这里也可以看出Spring设计上的优秀程度,也提现作者们的面向对象的思维和设计模式的功底。

    再者就是实现,其中AbstractBeanFactory无疑是核心,它是BeanFactory的基本能力的实现,提供了以下几点特性:

    1. 能够获取BeanDefinition,所以可以被实现可罗列的BeanFactory继承扩展
    2. 提供基本的单例创建的模板方法doGetBean,同时继承了SingletonBeanRegistry的实现DefaultSingletonBeanRegistry,从而具有单例缓存能力
    3. 实现了HierarchicalBeanFactory和ConfigurableBeanFactory接口,从而具有BeanFactory的层次能力,也具有配置BeanFactory的能力

    AbstractAutowireCapableBeanFactory在AbstractBeanFactory的基础上扩展实现AutowireCapableBeanFactory接口,从而具有装配能力的BeanFactory。

    DefaultListableBeanFactory是继承AbstractAutowireCapableBeanFactory并且实现ListableBeanFactory接口,从而具有可罗列的功能。它也是Spring中核心实现。基本上所有的上下文都是通过持有该BeanFactory实现,从而具有管理Bean的能力。

    为了更形象直观的了解Bean的实现细节,先看下Bean的实例化、装配、后置处理、初始化的时序图:

    Bean的实例化

    Bean的实例化过程非常复杂,但是简单的概括,也就一个逻辑:从BeanDefinition华丽的转身至配置的Bean对象的过程,这节承接上篇文章扩展点,继续看AbstractApplicationContext的模板方法refresh后续的实例化Bean的逻辑流程。关于Bean的属性,如:Lazy-Init/Scope/Autowired Way等等,这里不再介绍,读者可以移步至Spring官网翻阅文档。

    首先依然从源头refresh的模板方法着手:

    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);
    	
    	... 忽略
    
    	// 模板方法中,这一步完成Bean工厂中遗留下的非惰性的Bean的实例化
    	// Instantiate all remaining (non-lazy-init) singletons.
    	finishBeanFactoryInitialization(beanFactory);
    	// Last step: publish corresponding event.
    	finishRefresh();
    }catch (BeansException ex) {
    	... 忽略
    }
    

    finishBeanFactoryInitialization该方法是正式开始实例化应用配置的Bean的核心步骤(并不是所有的Bean都是这一步骤中实例化,如前篇文章中的那些扩张点,在这之前就已经实例化)

    protected void finishBeanFactoryInitialization(ConfigurableListableBeanFactory beanFactory) {
    	// 在实例化剩余的Bean之前,需要针对BeanFactory进行配置
    	// 1. 配置BeanFactory的转换service
    	// 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));
    	}
    	// 配置值解析器
    	// 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);
    			}
    		});
    	}
    	// 过早实例化LoadTimeWeaverAware
    	// 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);
    	}
    	// 停止使用temporary ClassLoader
    	// Stop using the temporary ClassLoader for type matching.
    	beanFactory.setTempClassLoader(null);
    	// 冻结配置,已经在实例化阶段且经过了BeanFactoryPostProcessor,不允许修改Bean定义
    	// Allow for caching all bean definition metadata, not expecting further changes.
    	beanFactory.freezeConfiguration();
    	// 实例化遗留的非惰性单例Bean
    	// Instantiate all remaining (non-lazy-init) singletons.
    	beanFactory.preInstantiateSingletons();
    }
    

    preInstantiateSingletons是ConfigurableListableBeanFactory工厂接口抽象的接口,确保非惰性的单例能够被实例化。默认实现是DefaultListableBeanFactory:

    @Override
    public void preInstantiateSingletons() throws BeansException {
    	if (logger.isDebugEnabled()) {
    		logger.debug("Pre-instantiating singletons in " + this);
    	}
    	// 在bean定义的拷贝上迭代,当是非规则的factory,初始化方法仍然能增加bean定义,也能正常规则
    	// 非规则的factory,很少使用,这里不做太多关注
    	// 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.
    	List<String> beanNames = new ArrayList<String>(this.beanDefinitionNames);
    	// 这里出发非惰性的单例的实例化
    	// Trigger initialization of all non-lazy singleton beans...
    	// 迭代每个bean名称,按名称逐个实例化
    	for (String beanName : beanNames) {
    		// 根据bean名称获取其对应的RootBeanDefinition
    		RootBeanDefinition bd = getMergedLocalBeanDefinition(beanName);
    		// 当是非抽象,且是单例,非惰性bean,则进行初始化;否则迭代下一个bean
    		if (!bd.isAbstract() && bd.isSingleton() && !bd.isLazyInit()) {
    			// 判断该名称的bean是否为工厂bean
    			if (isFactoryBean(beanName)) {
    				// 是工厂bean,则先获取该Bean对应的FactoryBean,在Spring中FactoryBean的名称命名规则为:"&" + "beanName"
    				final FactoryBean<?> factory = (FactoryBean<?>) getBean(FACTORY_BEAN_PREFIX + beanName);
    				boolean isEagerInit;
    				// 判断该工厂Bean是否可以过早实例化
    				// 标准的FactoryBean是不过早实例化的,只有在被调用进行实际访问时才实例化
    				// 而SmartFactoryBean提供了可以设置是否尽早实例化
    				if (System.getSecurityManager() != null && factory instanceof SmartFactoryBean) {
    					isEagerInit = AccessController.doPrivileged(new PrivilegedAction<Boolean>() {
    						@Override
    						public Boolean run() {
    							return ((SmartFactoryBean<?>) factory).isEagerInit();
    						}
    					}, getAccessControlContext());
    				}
    				else {
    					// 非SmartFactoryBean时,则不实例化;如果是,则判断SmartFactoryBean的尽早实例化的设置参数
    					isEagerInit = (factory instanceof SmartFactoryBean &&
    							((SmartFactoryBean<?>) factory).isEagerInit());
    				}
    				// 如果非过早实例化,则迭代下一个Bean名称
    				if (isEagerInit) {
    					getBean(beanName);
    				}
    			}
    			// 非工厂bean
    			else {
    				// 获取该Bean名称对应的单例对象
    				// getBean是BeanFactory接口定义的接口,是面向Spring内部和应用的接口
    				// 其中包含了Bean的生命周期的部分
    				// getBean非常重要,是触发Bean的入口,也是获取Bean工厂中已存在单例的手段
    				getBean(beanName);
    			}
    		}
    	}
    	// Trigger post-initialization callback for all applicable beans...
    	// 针对所有Bean触发后置实例化回调,这里忽略
    	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();
    			}
    		}
    	}
    }
    

    以上就是实例化Bean的触发点,逻辑也是非常直观,只要满足非惰性单例的Bean才能进行实例化。其中分为两种情形:

    • 工厂Bean,对于工厂Bean判断是否为SmartFactoryBean,决定是否可以尽早实例化
    • 非工厂Bean

    由于篇幅原因,关于isFactoryBean的实现这里不再详细介绍,可以自行阅读。接下来再继续看getBean的实现。getBean是AbstractBeanFactory中的基础实现:

    @Override
    public Object getBean(String name) throws BeansException {
    	return doGetBean(name, null, null, false);
    }
    

    其中内部调用doGetBean方法,方法参数较多:

    1. 第一个参数是Bean名称
    2. 第二个参数是被要求的类型
    3. 第三个参数是创建单例时需要使用的构造参数
    4. 第三个参标志是否为只仅仅类型检查获取,而非实际使用

    doGetBean是AbstractBeanFactory中实现获取Bean的模板方法,作为BeanFactory的基础实现类,子类可以扩展实现创建Bean的逻辑。其中实现以下模板步骤:

    1. 从单例缓存中获取Bean
    2. 从父BeanFactory中获取该Bean
    3. 先获取该Bean的依赖Bean
    4. 按照不同的Bean作用域创建该Bean,该步骤被抽象为抽象接口,由子类实现扩展
    5. 如果该Bean是工厂Bean,则调用工厂Bean的生产方法getObject生成新的Bean
    6. 检查类型是否匹配,如果不匹配,则进行类型转换
    protected <T> T doGetBean(
    		final String name, final Class<T> requiredType, final Object[] args, boolean typeCheckOnly)
    		throws BeansException {
    	// 组装bean名称
    	final String beanName = transformedBeanName(name);
    	Object bean;
    	// 检查缓存,检查是否已经过早实例化了该bean
    	// Eagerly check singleton cache for manually registered singletons.
    	Object sharedInstance = getSingleton(beanName);
    	// 如果不为空,则表示已经过早的实例化了该bean
    	if (sharedInstance != null && args == null) {
    		// 日志打印
    		if (logger.isDebugEnabled()) {
    			// Spring中使用singletonsCurrentlyInCreation Set集合来存储正在创建的单例Bean的名称
    			// 如果其中包含该beanName,则表示是循环引用
    			if (isSingletonCurrentlyInCreation(beanName)) {
    				logger.debug("Returning eagerly cached instance of singleton bean '" + beanName +
    						"' that is not fully initialized yet - a consequence of a circular reference");
    			}
    			else {
    				logger.debug("Returning cached instance of singleton bean '" + beanName + "'");
    			}
    		}
    		// 如果该bean是工厂bean,则返回生产后的bean
    		bean = getObjectForBeanInstance(sharedInstance, name, beanName, null);
    	}
    	// 如果没有过早的实例化
    	else {
    		// Fail if we're already creating this bean instance:
    		// We're assumably within a circular reference.
    		if (isPrototypeCurrentlyInCreation(beanName)) {
    			throw new BeanCurrentlyInCreationException(beanName);
    		}
    		// 	检查是否有父BeanFactory
    		// Check if bean definition exists in this factory.
    		BeanFactory parentBeanFactory = getParentBeanFactory();
    		// 如果父BeanFactory不为空,则该Bean的Bean定义被包含在BeanFactory中
    		// 则使用父BeanFactory获取该Bean,并返回创建的Bean
    		// 这里实现了层次BeanFactory的能力,有点类似Java中的类加载器委托机制
    		if (parentBeanFactory != null && !containsBeanDefinition(beanName)) {
    			// Not found -> check parent.
    			String nameToLookup = originalBeanName(name);
    			if (args != null) {
    				// Delegation to parent with explicit args.
    				return (T) parentBeanFactory.getBean(nameToLookup, args);
    			}
    			else {
    				// No args -> delegate to standard getBean method.
    				return parentBeanFactory.getBean(nameToLookup, requiredType);
    			}
    		}
    		// 如果父BeanFactory为空且非只仅仅类型检查,则标记该Bean正在被创建
    		if (!typeCheckOnly) {
    			markBeanAsCreated(beanName);
    		}
    		try {
    			// 获取该Bean对应的RootBeanDefinition
    			final RootBeanDefinition mbd = getMergedLocalBeanDefinition(beanName);
    			checkMergedBeanDefinition(mbd, beanName, args);
    			// Guarantee initialization of beans that the current bean depends on.
    			// 获取该Bean依赖的Bean名称
    			String[] dependsOn = mbd.getDependsOn();
    			// 遍历获取依赖的Bean
    			// 实例化该bean前,先实例化其依赖的Bean
    			if (dependsOn != null) {
    				for (String dep : dependsOn) {
    					if (isDependent(beanName, dep)) {
    						throw new BeanCreationException(mbd.getResourceDescription(), beanName,
    								"Circular depends-on relationship between '" + beanName + "' and '" + dep + "'");
    					}
    					registerDependentBean(dep, beanName);
    					try {
    						getBean(dep);
    					}
    					catch (NoSuchBeanDefinitionException ex) {
    						throw new BeanCreationException(mbd.getResourceDescription(), beanName,
    								"'" + beanName + "' depends on missing bean '" + dep + "'", ex);
    					}
    				}
    			}
    			// 再根据不同的作用域创建该Bean
    			// Create bean instance.
    			// 这里只重点看单例Bean的创建过程,对于其他作用域类型,读者自行阅读
    			// 这里就是模板方法的扩展点,createBean是定义的抽象接口,由子类扩展实现创建Bean的过程
    			if (mbd.isSingleton()) {
    				sharedInstance = getSingleton(beanName, new ObjectFactory<Object>() {
    					@Override
    					public Object getObject() throws BeansException {
    						try {
    							return createBean(beanName, mbd, args);
    						}
    						catch (BeansException ex) {
    							// Explicitly remove instance from singleton cache: It might have been put there
    							// eagerly by the creation process, to allow for circular reference resolution.
    							// Also remove any beans that received a temporary reference to the bean.
    							destroySingleton(beanName);
    							throw ex;
    						}
    					}
    				});
    				bean = getObjectForBeanInstance(sharedInstance, name, beanName, mbd);
    			}
    			else if (mbd.isPrototype()) {
    				// It's a prototype -> create a new instance.
    				Object prototypeInstance = null;
    				try {
    					beforePrototypeCreation(beanName);
    					prototypeInstance = createBean(beanName, mbd, args);
    				}
    				finally {
    					afterPrototypeCreation(beanName);
    				}
    				bean = getObjectForBeanInstance(prototypeInstance, name, beanName, mbd);
    			}
    			else {
    				String scopeName = mbd.getScope();
    				final Scope scope = this.scopes.get(scopeName);
    				if (scope == null) {
    					throw new IllegalStateException("No Scope registered for scope name '" + scopeName + "'");
    				}
    				try {
    					Object scopedInstance = scope.get(beanName, new ObjectFactory<Object>() {
    						@Override
    						public Object getObject() throws BeansException {
    							beforePrototypeCreation(beanName);
    							try {
    								return createBean(beanName, mbd, args);
    							}
    							finally {
    								afterPrototypeCreation(beanName);
    							}
    						}
    					});
    					bean = getObjectForBeanInstance(scopedInstance, name, beanName, mbd);
    				}
    				catch (IllegalStateException ex) {
    					throw new BeanCreationException(beanName,
    							"Scope '" + scopeName + "' is not active for the current thread; consider " +
    							"defining a scoped proxy for this bean if you intend to refer to it from a singleton",
    							ex);
    				}
    			}
    		}
    		catch (BeansException ex) {
    			cleanupAfterBeanCreationFailure(beanName);
    			throw ex;
    		}
    	}
    	// 创建完Bean后,做类型检查,是否与要求的类型匹配,如果不匹配,则进行类型转换并返回
    	// Check if required type matches the type of the actual bean instance.
    	if (requiredType != null && bean != null && !requiredType.isInstance(bean)) {
    		try {
    			return getTypeConverter().convertIfNecessary(bean, requiredType);
    		}
    		catch (TypeMismatchException ex) {
    			if (logger.isDebugEnabled()) {
    				logger.debug("Failed to convert bean '" + name + "' to required type '" +
    						ClassUtils.getQualifiedName(requiredType) + "'", ex);
    			}
    			throw new BeanNotOfRequiredTypeException(name, requiredType, bean.getClass());
    		}
    	}
    	return (T) bean;
    }
    

    这里有三点需要注意:

    • getSingleton,从单例缓存中获取该Bean,因为由于循环关系可能会导致过早初始化该Bean
    • markBeanAsCreated,防止Bean重复创建,当Bean准备开始创建钱,需要记录
    • getMergedLocalBeanDefinition,任何Bean都有可能存在父Bean,所以需要获取合并的Bean定义,在Spring中创建Bean时,都会将Bean定义转为RootBeanDefinition进行统一处理

    createBean是子类的扩展实现Bean的创建过程,在Spring中默认由AbstractAutowireCapableBeanFactory中实现了Bean的实际创建:

    @Override
    protected Object createBean(String beanName, RootBeanDefinition mbd, Object[] args) throws BeanCreationException {
    	if (logger.isDebugEnabled()) {
    		logger.debug("Creating instance of bean '" + beanName + "'");
    	}
    	RootBeanDefinition mbdToUse = mbd;
    	// Make sure bean class is actually resolved at this point, and
    	// clone the bean definition in case of a dynamically resolved Class
    	// which cannot be stored in the shared merged bean definition.
    	// 解析该Bean的Class类型
    	Class<?> resolvedClass = resolveBeanClass(mbd, beanName);
    	// 如果该Bean没有BeanClass,则设置。这里深度复制,不修改原有的Bean定义
    	if (resolvedClass != null && !mbd.hasBeanClass() && mbd.getBeanClassName() != null) {
    		mbdToUse = new RootBeanDefinition(mbd);
    		mbdToUse.setBeanClass(resolvedClass);
    	}
    	// Prepare method overrides.
    	try {
    		mbdToUse.prepareMethodOverrides();
    	}
    	catch (BeanDefinitionValidationException ex) {
    		throw new BeanDefinitionStoreException(mbdToUse.getResourceDescription(),
    				beanName, "Validation of method overrides failed", ex);
    	}
    	try {
    		// 给BeanPostProcessors返回目标Bean的代理对象
    		// Give BeanPostProcessors a chance to return a proxy instead of the target bean instance.
    		Object bean = resolveBeforeInstantiation(beanName, mbdToUse);
    		// 如果代理对象存在,则返回
    		if (bean != null) {
    			return bean;
    		}
    	}
    	catch (Throwable ex) {
    		throw new BeanCreationException(mbdToUse.getResourceDescription(), beanName,
    				"BeanPostProcessor before instantiation of bean failed", ex);
    	}
    	// 如果没有代理对象,则这里创建该Bean
    	Object beanInstance = doCreateBean(beanName, mbdToUse, args);
    	if (logger.isDebugEnabled()) {
    		logger.debug("Finished creating instance of bean '" + beanName + "'");
    	}
    	return beanInstance;
    }
    

    这里主要逻辑是:在实例化Bean钱确保解析Bean Class,在实例化之前增加扩展点,最后调用实际的创建Bean的逻辑。

    关于实例化之前的扩张点,这里不再详述,后续再介绍AOP的篇幅中再详述描述。读者也可以自行阅读InstantiationAwareBeanPostProcessor的抽象。

    接下来再继续阅读创建Bean的细节doCreateBean:

    protected Object doCreateBean(final String beanName, final RootBeanDefinition mbd, final Object[] args)
    		throws BeanCreationException {
    	// Instantiate the bean.
    	// 实例化的Bean的包装器
    	BeanWrapper instanceWrapper = null;
    	if (mbd.isSingleton()) {
    		instanceWrapper = this.factoryBeanInstanceCache.remove(beanName);
    	}
    	// 如果实例化的Bean的包装器是空,则创建Bean
    	if (instanceWrapper == null) {
    		instanceWrapper = createBeanInstance(beanName, mbd, args);
    	}
    	// 获取实例化的Bean
    	final Object bean = (instanceWrapper != null ? instanceWrapper.getWrappedInstance() : null);
    	Class<?> beanType = (instanceWrapper != null ? instanceWrapper.getWrappedClass() : null);
    	mbd.resolvedTargetType = beanType;
    	// 后置处理修改合并的RootBeanDefinition,笔者也没遇到过这种情形,这里忽略
    	// Allow post-processors to modify the merged bean definition.
    	synchronized (mbd.postProcessingLock) {
    		if (!mbd.postProcessed) {
    			try {
    				applyMergedBeanDefinitionPostProcessors(mbd, beanType, beanName);
    			}
    			catch (Throwable ex) {
    				throw new BeanCreationException(mbd.getResourceDescription(), beanName,
    						"Post-processing of merged bean definition failed", ex);
    			}
    			mbd.postProcessed = true;
    		}
    	}
    	// 尽早缓存该Bean,以便后续循环引用时可以正常解析(循环引用时,直接从缓存中获取即可,不会再重新创建Bean)
    	// Eagerly cache singletons to be able to resolve circular references
    	// even when triggered by lifecycle interfaces like BeanFactoryAware.
    	boolean earlySingletonExposure = (mbd.isSingleton() && this.allowCircularReferences &&
    			isSingletonCurrentlyInCreation(beanName));
    	if (earlySingletonExposure) {
    		if (logger.isDebugEnabled()) {
    			logger.debug("Eagerly caching bean '" + beanName +
    					"' to allow for resolving potential circular references");
    		}
    		addSingletonFactory(beanName, new ObjectFactory<Object>() {
    			@Override
    			public Object getObject() throws BeansException {
    				return getEarlyBeanReference(beanName, mbd, bean);
    			}
    		});
    	}
    	
    	... 省略部分是Bean装配和初始化的逻辑
    
    	// 返回创建的Bean
    	return exposedObject;
    }
    

    这里需要重点关注的是尽早缓存该Bean实例,主要是为了解决循环引用的问题。在下节Bean的装配中,再回到这里重点介绍。

    前文中介绍到CreateBean是由子类扩展实现相应的实例化Bean的逻辑,在Spring中,这里使用回调的方式,再回到回调的点细看getSingleton方法的实现:

    // 该方法是由单例注册器DefaultSingletonBeanRegistry实现,它具有缓存单例的能力
    public Object getSingleton(String beanName, ObjectFactory<?> singletonFactory) {
    	Assert.notNull(beanName, "'beanName' must not be null");
    	// 同步singletonObjects,保证线程安全,数据一致
    	// singletonObjects存储Spring容器中的所有单例Bean
    	synchronized (this.singletonObjects) {
    		// 首先从单例容器中获取该单例
    		Object singletonObject = this.singletonObjects.get(beanName);
    		// 如果单例不存在,则创建该单例Bean
    		if (singletonObject == null) {
    			// 判断该单例是否正在销毁中,如果正在销毁,则抛出异常
    			if (this.singletonsCurrentlyInDestruction) {
    				throw new BeanCreationNotAllowedException(beanName,
    						"Singleton bean creation not allowed while singletons of this factory are in destruction " +
    						"(Do not request a bean from a BeanFactory in a destroy method implementation!)");
    			}
    			if (logger.isDebugEnabled()) {
    				logger.debug("Creating shared instance of singleton bean '" + beanName + "'");
    			}
    			// 这里是一个扩展点,用于在创键单例钱进行回调
    			// 默认实现中是判断该单例是否正在创建,防重创建,其中使用Set保证唯一
    			beforeSingletonCreation(beanName);
    			// 创键是否为新的单例标志
    			boolean newSingleton = false;
    			boolean recordSuppressedExceptions = (this.suppressedExceptions == null);
    			if (recordSuppressedExceptions) {
    				this.suppressedExceptions = new LinkedHashSet<Exception>();
    			}
    			// 这里回调对象工厂创建单例,调用将回到CreateBean那里
    			// 并更新为新的单例的表示
    			try {
    				singletonObject = singletonFactory.getObject();
    				newSingleton = true;
    			}
    			catch (IllegalStateException ex) {
    				// Has the singleton object implicitly appeared in the meantime ->
    				// if yes, proceed with it since the exception indicates that state.
    				singletonObject = this.singletonObjects.get(beanName);
    				if (singletonObject == null) {
    					throw ex;
    				}
    			}
    			catch (BeanCreationException ex) {
    				if (recordSuppressedExceptions) {
    					for (Exception suppressedException : this.suppressedExceptions) {
    						ex.addRelatedCause(suppressedException);
    					}
    				}
    				throw ex;
    			}
    			finally {
    				if (recordSuppressedExceptions) {
    					this.suppressedExceptions = null;
    				}
    				// 创建单例的后置回调
    				afterSingletonCreation(beanName);
    			}
    			// 将新的单例存入单例容器中
    			if (newSingleton) {
    				addSingleton(beanName, singletonObject);
    			}
    		}
    		return (singletonObject != NULL_OBJECT ? singletonObject : null);
    	}
    }
    

    比较这里的单例容器和之前提到的尽早缓存单例的容器:

    1.创建单例完成,将单例存入单例容器中

    protected void addSingleton(String beanName, Object singletonObject) {
    	// 同步单例容器singletonObjects
    	synchronized (this.singletonObjects) {
    		// 存入单例,使用映射表 beanName -> singletonObject
    		this.singletonObjects.put(beanName, (singletonObject != null ? singletonObject : NULL_OBJECT));
    		// 单例已经创建完成,则清理之前的尽早缓存的单例工厂对象
    		this.singletonFactories.remove(beanName);
    		// 清理过早缓存的该单例对象
    		this.earlySingletonObjects.remove(beanName);
    		// 在已经注册的单例中,注册上该单例名称,表示该单例已经注册
    		this.registeredSingletons.add(beanName);
    	}
    }
    

    2.过早缓存单例,解决循环引用

    // 如果是单例,且Spring容器允许循环引用,该bean当前正在被创建
    boolean earlySingletonExposure = (mbd.isSingleton() && this.allowCircularReferences &&
    		isSingletonCurrentlyInCreation(beanName));
    // 如果允许过早暴露单例
    if (earlySingletonExposure) {
    	if (logger.isDebugEnabled()) {
    		logger.debug("Eagerly caching bean '" + beanName +
    				"' to allow for resolving potential circular references");
    	}
    	// 将单例的对象工厂缓存
    	addSingletonFactory(beanName, new ObjectFactory<Object>() {
    		@Override
    		public Object getObject() throws BeansException {
    			return getEarlyBeanReference(beanName, mbd, bean);
    		}
    	});
    }
    
    
    protected void addSingletonFactory(String beanName, ObjectFactory<?> singletonFactory) {
    	Assert.notNull(singletonFactory, "Singleton factory must not be null");
    	// 同步singletonObjects
    	synchronized (this.singletonObjects) {
    		// 如果singletonObjects中不包含该单例,则过早缓存
    		if (!this.singletonObjects.containsKey(beanName)) {
    			// 缓存创建这个bean对象的工厂
    			this.singletonFactories.put(beanName, singletonFactory);
    			// 从过早缓存容器中移除该bean,下次过早引用该bean时,重新从上面缓存的工厂中重新获取
    			this.earlySingletonObjects.remove(beanName);
    			// 将该bean注册到单例中
    			this.registeredSingletons.add(beanName);
    		}
    	}
    }
    
    // 过早获取该bean的单例,这里主要是为了解决循环引用问题
    protected Object getSingleton(String beanName, boolean allowEarlyReference) {
    	// 首先从singletonObjects中获取,如果有直接返回
    	Object singletonObject = this.singletonObjects.get(beanName);
    	// 如果不存在,且正在创建中
    	if (singletonObject == null && isSingletonCurrentlyInCreation(beanName)) {
    		// 同步singletonObjects
    		synchronized (this.singletonObjects) {
    			// 从过早缓存的容器中获取
    			singletonObject = this.earlySingletonObjects.get(beanName);
    			// 如果过早缓存的容器中也没有且支持过早引用
    			if (singletonObject == null && allowEarlyReference) {
    				// 获取上述中提到的过早缓存的工厂
    				ObjectFactory<?> singletonFactory = this.singletonFactories.get(beanName);
    				// 缓存工厂不为空
    				if (singletonFactory != null) {
    					// 获取该对象,将会调用getEarlyBeanReference方法
    					singletonObject = singletonFactory.getObject();
    					// 将其缓存到过早缓存中,避免下次再使用工厂获取
    					this.earlySingletonObjects.put(beanName, singletonObject);
    					// 将该工厂存缓存中移除
    					this.singletonFactories.remove(beanName);
    				}
    			}
    		}
    	}
    	// 返回该对象
    	return (singletonObject != NULL_OBJECT ? singletonObject : null);
    }
    

    Spring处理循环引用的方式非常巧妙,为了帮助理解,笔者这里整理了下流程图帮助理解:

    到这里Bean的创键基本上完成,后续就是依赖注入,将Bean装配起来。

    Bean的装配

    什么是Bean的装配,即自动解决Bean之间的相互引用,能够将其各自Set进彼此之中。比如,BeanA引用了BeanB,则Spring能自动的将连个Bean都实例化,然后将BeanB Set至BeanA中,这就是依赖注入,自动装配。

    Bean的装配发生在Bean的实例化之后,在Spring中由AbstractAutowireCapableBeanFactoryBean工厂完成。继续阅读源码:

    protected Object doCreateBean(final String beanName, final RootBeanDefinition mbd, final Object[] args)
    			throws BeanCreationException {
    		...省略,这部分是实例化逻辑,上节中已经详解
    		// Initialize the bean instance.
    		Object exposedObject = bean;
    		try {
    			// 这里处理Bean的装配
    			populateBean(beanName, mbd, instanceWrapper);
    			if (exposedObject != null) {
    				这里处理Bean的初始化
    				exposedObject = initializeBean(beanName, exposedObject, mbd);
    			}
    		}
    		catch (Throwable ex) {
    			if (ex instanceof BeanCreationException && beanName.equals(((BeanCreationException) ex).getBeanName())) {
    				throw (BeanCreationException) ex;
    			}
    			else {
    				throw new BeanCreationException(
    						mbd.getResourceDescription(), beanName, "Initialization of bean failed", ex);
    			}
    		}
    		... 省略
    		return exposedObject;
    	}
    

    Bean的装配由populateBean中实现:

    // 该实现中处理Spring中的Bean装配
    // 有按照名称、按照类型两种范式装配
    protected void populateBean(String beanName, RootBeanDefinition mbd, BeanWrapper bw) {
    	// 获取Bean定义的属性值,Bean定义的属性值代表着需要装配的成员域
    	PropertyValues pvs = mbd.getPropertyValues();
    	// 如果是空实例,则跳过返回,不装配
    	if (bw == null) {
    		if (!pvs.isEmpty()) {
    			throw new BeanCreationException(
    					mbd.getResourceDescription(), beanName, "Cannot apply property values to null instance");
    		}
    		else {
    			// Skip property population phase for null instance.
    			return;
    		}
    	}
    	// 这里是一个扩展点,用于实例化后的后置处理InstantiationAwareBeanPostProcessor
    	// InstantiationAwareBeanPostProcessor是BeanPostProcessor的扩展实现,前文中也稍微提过
    	// 对于后置处理返回false,表示不需要装配,否则需要装配
    	// Give any InstantiationAwareBeanPostProcessors the opportunity to modify the
    	// state of the bean before properties are set. This can be used, for example,
    	// to support styles of field injection.
    	boolean continueWithPropertyPopulation = true;
    	if (!mbd.isSynthetic() && hasInstantiationAwareBeanPostProcessors()) {
    		for (BeanPostProcessor bp : getBeanPostProcessors()) {
    			if (bp instanceof InstantiationAwareBeanPostProcessor) {
    				InstantiationAwareBeanPostProcessor ibp = (InstantiationAwareBeanPostProcessor) bp;
    				if (!ibp.postProcessAfterInstantiation(bw.getWrappedInstance(), beanName)) {
    					continueWithPropertyPopulation = false;
    					break;
    				}
    			}
    		}
    	}
    	// 如果不需要按照属性装配,则直接返回
    	if (!continueWithPropertyPopulation) {
    		return;
    	}
    	// 获取Bean定义中的装配模式
    	if (mbd.getResolvedAutowireMode() == RootBeanDefinition.AUTOWIRE_BY_NAME ||
    			mbd.getResolvedAutowireMode() == RootBeanDefinition.AUTOWIRE_BY_TYPE) {
    		// 重新copy一份属性值
    		MutablePropertyValues newPvs = new MutablePropertyValues(pvs);
    		// 按照名称进行属性装配
    		// Add property values based on autowire by name if applicable.
    		if (mbd.getResolvedAutowireMode() == RootBeanDefinition.AUTOWIRE_BY_NAME) {
    			autowireByName(beanName, mbd, bw, newPvs);
    		}
    		// 按照类型进行属性装配
    		// Add property values based on autowire by type if applicable.
    		if (mbd.getResolvedAutowireMode() == RootBeanDefinition.AUTOWIRE_BY_TYPE) {
    			autowireByType(beanName, mbd, bw, newPvs);
    		}
    		pvs = newPvs;
    	}
    
    	// 同样是InstantiationAwareBeanPostProcessor后置处理属性值的扩展点
    	boolean hasInstAwareBpps = hasInstantiationAwareBeanPostProcessors();
    	boolean needsDepCheck = (mbd.getDependencyCheck() != RootBeanDefinition.DEPENDENCY_CHECK_NONE);
    	if (hasInstAwareBpps || needsDepCheck) {
    		PropertyDescriptor[] filteredPds = filterPropertyDescriptorsForDependencyCheck(bw, mbd.allowCaching);
    		if (hasInstAwareBpps) {
    			for (BeanPostProcessor bp : getBeanPostProcessors()) {
    				if (bp instanceof InstantiationAwareBeanPostProcessor) {
    					InstantiationAwareBeanPostProcessor ibp = (InstantiationAwareBeanPostProcessor) bp;
    					pvs = ibp.postProcessPropertyValues(pvs, filteredPds, bw.getWrappedInstance(), beanName);
    					if (pvs == null) {
    						return;
    					}
    				}
    			}
    		}
    		if (needsDepCheck) {
    			checkDependencies(beanName, mbd, filteredPds, pvs);
    		}
    	}
    	// 应用属性值到Bean中
    	applyPropertyValues(beanName, mbd, bw, pvs);
    }
    

    其中非常重要的三个逻辑是:

    1. 按照名称进行属性装配
    2. 按照类型进行属性装配
    3. 应用属性值到Bean中

    其次是InstantiationAwareBeanPostProcessor扩展点,它提供了实例化前后的扩展。
    实例化前可以扩展实现自定义的实例化Bean逻辑;实例化后扩展可以实现自定义的装配方式。同时也提供了后置处理即将被工厂应用到Bean的属性值的扩展点。这里由于篇幅不再详述,同样在后续AOP章节中讲解。

    这里围绕按照类型进行属性装配和应用属性值到Bean中做详细讲解。其中关于如何配置装配方式,这里不再赘述,可以翻阅文档。

    Notes:
    需要注意以上的实现中由重新复制MutablePropertyValues的操作,因为在按名称和按类型进行装配的过程中,会修改Bean定义的属性,故这里将其冲洗copy一份用于修改:将装配的值解析后,覆盖写入Bean定义属性中。

    // 完成按照类型装配Bean
    // 第一个参数是Bean名称、第二个参数是该Bean对应的Bean定义,第三个参数是该bean的包装对象,第四个参数是该Bean的属性值描述
    protected void autowireByType(
    		String beanName, AbstractBeanDefinition mbd, BeanWrapper bw, MutablePropertyValues pvs) {
    	// 获取BeanFactory中配置的自定义类型转换器,如果未配置,则使用BeanWrapper
    	TypeConverter converter = getCustomTypeConverter();
    	if (converter == null) {
    		converter = bw;
    	}
    	// 指定大小,创建需要自动装配的Bean名称
    	Set<String> autowiredBeanNames = new LinkedHashSet<String>(4);
    	// 从Bean的属性描述pvs中筛选出非简单的满足装配的属性名称
    	String[] propertyNames = unsatisfiedNonSimpleProperties(mbd, bw);
    	// 遍历需要装配的属性名称
    	for (String propertyName : propertyNames) {
    		try {
    			// 这里使用javabeans技术,获取属性描述器
    			PropertyDescriptor pd = bw.getPropertyDescriptor(propertyName);
    			// 如果装配的类型是Object类型,则没有任何意义,无法装配,直接迭代下一个
    			// Don't try autowiring by type for type Object: never makes sense,
    			// even if it technically is a unsatisfied, non-simple property.
    			// 非Object类型
    			if (Object.class != pd.getPropertyType()) {
    				// 获取该成员属性的方法参数
    				MethodParameter methodParam = BeanUtils.getWriteMethodParameter(pd);
    				// Do not allow eager init for type matching in case of a prioritized post-processor.
    				boolean eager = !PriorityOrdered.class.isAssignableFrom(bw.getWrappedClass());
    				DependencyDescriptor desc = new AutowireByTypeDependencyDescriptor(methodParam, eager);
    				// 这里解析该属性成员,这里会从BeanFactory中寻找该属性的候选者,找到后,再进行实例化。返回属性对应的Bean
    				// 如A -> B,正在解析B,则这里将返回B
    				Object autowiredArgument = resolveDependency(desc, beanName, autowiredBeanNames, converter);
    				// 将属性和候选者添加到属性值中
    				if (autowiredArgument != null) {
    					pvs.add(propertyName, autowiredArgument);
    				}
    				// 注册依赖关系,正向依赖和反向依赖
    				for (String autowiredBeanName : autowiredBeanNames) {
    					registerDependentBean(autowiredBeanName, beanName);
    					if (logger.isDebugEnabled()) {
    						logger.debug("Autowiring by type from bean name '" + beanName + "' via property '" +
    								propertyName + "' to bean named '" + autowiredBeanName + "'");
    					}
    				}
    				// 清理autowiredBeanNames,继续下一个迭代
    				autowiredBeanNames.clear();
    			}
    		}
    		catch (BeansException ex) {
    			throw new UnsatisfiedDependencyException(mbd.getResourceDescription(), beanName, propertyName, ex);
    		}
    	}
    }
    

    这里的逻辑和后续解析依赖的逻辑比较复杂,这里通过举例帮助理解。

    假如:Bean A持有成员域B。配置如下:

    public class A {
    
    	private B b;
    }
    
    
    <bean id="a" class=".....A" autowire="byType">
    </bean>
    
    <bean id="b" class=".....B" autowire-candidate="true">
    </bean>
    

    A自动装配方式按照类型装配,当a实例化后,在装配时,需要对b成员进行填充。那么unsatisfiedNonSimpleProperties方法返回的属性数组中将会包含"b"。

    // 获取Bean的不满足非简单的属性
    // 这里主要使用的是javabeans的自省技术,如果对这里感兴趣可以参考oracle java中的javabeans技术
    protected String[] unsatisfiedNonSimpleProperties(AbstractBeanDefinition mbd, BeanWrapper bw) {
    	// 
    	Set<String> result = new TreeSet<String>();
    	// 获取bean定义中的属性值
    	PropertyValues pvs = mbd.getPropertyValues();
    	// 获取该Bean实例中所有属性描述器
    	PropertyDescriptor[] pds = bw.getPropertyDescriptors();
    	// 遍历属性描述器
    	for (PropertyDescriptor pd : pds) {
    		// 属性描述器有写方法,且该属性没有被排除依赖,且bean定义的属性中不包含该属性,且非简单属性,则认为需要自动装配
    		if (pd.getWriteMethod() != null && !isExcludedFromDependencyCheck(pd) && !pvs.contains(pd.getName()) &&
    				!BeanUtils.isSimpleProperty(pd.getPropertyType())) {
    			result.add(pd.getName());
    		}
    	}
    	return StringUtils.toStringArray(result);
    }
    

    以上的b属性是满足,首先通过PropertyDescriptor[] pds = bw.getPropertyDescriptors()能获取到属性b的描述,然后b又未被排除依赖,在a的bean定义配置中也未配置b,且b是非简单属性。在Spring中认为这些属性是简单属性:

    public static boolean isSimpleValueType(Class<?> clazz) {
    	return (ClassUtils.isPrimitiveOrWrapper(clazz) ||
    			Enum.class.isAssignableFrom(clazz) ||
    			CharSequence.class.isAssignableFrom(clazz) ||
    			Number.class.isAssignableFrom(clazz) ||
    			Date.class.isAssignableFrom(clazz) ||
    			URI.class == clazz || URL.class == clazz ||
    			Locale.class == clazz || Class.class == clazz);
    }
    

    且如果是以上这些类型的元素数组类型,也被认为是简单类型。故b是需要被自动装配。

    后续便是从BeanFactory的Bean定义中寻找b的候选者:

    @Override
    public Object resolveDependency(DependencyDescriptor descriptor, String requestingBeanName,
    		Set<String> autowiredBeanNames, TypeConverter typeConverter) throws BeansException {
    	// 以下javaxInjectProviderClass、javaUtilOptionalClass、ObjectFactory、ObjectProvider这些都是特殊类型
    	// 这里不做讲解
    	descriptor.initParameterNameDiscovery(getParameterNameDiscoverer());
    	if (javaUtilOptionalClass == descriptor.getDependencyType()) {
    		return new OptionalDependencyFactory().createOptionalDependency(descriptor, requestingBeanName);
    	}
    	else if (ObjectFactory.class == descriptor.getDependencyType() ||
    			ObjectProvider.class == descriptor.getDependencyType()) {
    		return new DependencyObjectProvider(descriptor, requestingBeanName);
    	}
    	else if (javaxInjectProviderClass == descriptor.getDependencyType()) {
    		return new Jsr330ProviderFactory().createDependencyProvider(descriptor, requestingBeanName);
    	}
    	else {
    		// 应用配置的Bean大多数进入该分支
    		// 对实际依赖的惰性对象构造一个代理作为需要被装配成员实例
    		Object result = getAutowireCandidateResolver().getLazyResolutionProxyIfNecessary(
    				descriptor, requestingBeanName);
    		// 如果为空,则解析依赖
    		if (result == null) {
    			result = doResolveDependency(descriptor, requestingBeanName, autowiredBeanNames, typeConverter);
    		}
    		return result;
    	}
    }
    

    显然解析a对b的依赖,会进入最后一条分支,descriptor是b的属性描述器,requestingBeanName是a,autowiredBeanNames是包含"b",类型转换器是a实例的Bean包装器。

    // 这里逻辑非常复杂,只重点关注核心逻辑
    public Object doResolveDependency(DependencyDescriptor descriptor, String beanName,
    		Set<String> autowiredBeanNames, TypeConverter typeConverter) throws BeansException {
    	InjectionPoint previousInjectionPoint = ConstructorResolver.setCurrentInjectionPoint(descriptor);
    	try {
    		Object shortcut = descriptor.resolveShortcut(this);
    		if (shortcut != null) {
    			return shortcut;
    		}
    		// 根据属性描述器获取依赖对象的类型
    		Class<?> type = descriptor.getDependencyType();
    		Object value = getAutowireCandidateResolver().getSuggestedValue(descriptor);
    		if (value != null) {
    			if (value instanceof String) {
    				String strVal = resolveEmbeddedValue((String) value);
    				BeanDefinition bd = (beanName != null && containsBean(beanName) ? getMergedBeanDefinition(beanName) : null);
    				value = evaluateBeanDefinitionString(strVal, bd);
    			}
    			TypeConverter converter = (typeConverter != null ? typeConverter : getTypeConverter());
    			return (descriptor.getField() != null ?
    					converter.convertIfNecessary(value, type, descriptor.getField()) :
    					converter.convertIfNecessary(value, type, descriptor.getMethodParameter()));
    		}
    		Object multipleBeans = resolveMultipleBeans(descriptor, beanName, autowiredBeanNames, typeConverter);
    		if (multipleBeans != null) {
    			return multipleBeans;
    		}
    		// 按照类型寻找bean候选者的bean名称
    		Map<String, Object> matchingBeans = findAutowireCandidates(beanName, type, descriptor);
    		if (matchingBeans.isEmpty()) {
    			if (isRequired(descriptor)) {
    				raiseNoMatchingBeanFound(type, descriptor.getResolvableType(), descriptor);
    			}
    			return null;
    		}
    
    		// 决定候选者中的一个成为被装配的Bean
    		String autowiredBeanName;
    		Object instanceCandidate;
    		if (matchingBeans.size() > 1) {
    			autowiredBeanName = determineAutowireCandidate(matchingBeans, descriptor);
    			if (autowiredBeanName == null) {
    				if (isRequired(descriptor) || !indicatesMultipleBeans(type)) {
    					return descriptor.resolveNotUnique(type, matchingBeans);
    				}
    				else {
    					// In case of an optional Collection/Map, silently ignore a non-unique case:
    					// possibly it was meant to be an empty collection of multiple regular beans
    					// (before 4.3 in particular when we didn't even look for collection beans).
    					return null;
    				}
    			}
    			instanceCandidate = matchingBeans.get(autowiredBeanName);
    		}
    		else {
    			// We have exactly one match.
    			Map.Entry<String, Object> entry = matchingBeans.entrySet().iterator().next();
    			autowiredBeanName = entry.getKey();
    			instanceCandidate = entry.getValue();
    		}
    		if (autowiredBeanNames != null) {
    			autowiredBeanNames.add(autowiredBeanName);
    		}
    		// 实例化被装配的Bean并返回
    		return (instanceCandidate instanceof Class ?
    				descriptor.resolveCandidate(autowiredBeanName, type, this) : instanceCandidate);
    	}
    	finally {
    		ConstructorResolver.setCurrentInjectionPoint(previousInjectionPoint);
    	}
    }
    

    当按照类型B从BeanFactory中寻找后选择时,会寻找到"b"的bean名称,后续在实例化时,将实例化b配置的Bean。

    其中descriptor.resolveCandidate实例化需要重点关注:

    // 是不是很熟悉,又是调用BeanFactory的getBean,这是BeanFactory的基本能力
    // 当解析依赖的时候,这里是间接递归调用
    public Object resolveCandidate(String beanName, Class<?> requiredType, BeanFactory beanFactory)
    		throws BeansException {
    	return beanFactory.getBean(beanName, requiredType);
    }
    

    当解析依赖的时候,将会间接递归调用getBean方法。这里将会getBean("b", .....B)。

    当解析到被装配的Bean后,就会加入至属性映射pvs中。最后再调用applyPropertyValues将属性填入。这里即将b填充至a中。

    protected void applyPropertyValues(String beanName, BeanDefinition mbd, BeanWrapper bw, PropertyValues pvs) {
    	// 如果没有属性,则直接返回,无可应用
    	if (pvs == null || pvs.isEmpty()) {
    		return;
    	}
    	if (System.getSecurityManager() != null && bw instanceof BeanWrapperImpl) {
    		((BeanWrapperImpl) bw).setSecurityContext(getAccessControlContext());
    	}
    	MutablePropertyValues mpvs = null;
    	List<PropertyValue> original;
    	// 如果MutablePropertyValues是已经被转换,则直接短路填充
    	if (pvs instanceof MutablePropertyValues) {
    		mpvs = (MutablePropertyValues) pvs;
    		if (mpvs.isConverted()) {
    			// Shortcut: use the pre-converted values as-is.
    			try {
    				bw.setPropertyValues(mpvs);
    				return;
    			}
    			catch (BeansException ex) {
    				throw new BeanCreationException(
    						mbd.getResourceDescription(), beanName, "Error setting property values", ex);
    			}
    		}
    		original = mpvs.getPropertyValueList();
    	}
    	else {
    		original = Arrays.asList(pvs.getPropertyValues());
    	}
    	// 否则获取自定义转换器
    	TypeConverter converter = getCustomTypeConverter();
    	if (converter == null) {
    		converter = bw;
    	}
    	// 构建Bean定义值解析器
    	BeanDefinitionValueResolver valueResolver = new BeanDefinitionValueResolver(this, beanName, mbd, converter);
    	// Create a deep copy, resolving any references for values.
    	List<PropertyValue> deepCopy = new ArrayList<PropertyValue>(original.size());
    	boolean resolveNecessary = false;
    	// 遍历属性值
    	for (PropertyValue pv : original) {
    		// 如果属性值已经被转换,直接加入到列表中
    		if (pv.isConverted()) {
    			deepCopy.add(pv);
    		}
    		else {
    			// 获取属性名,属性值
    			String propertyName = pv.getName();
    			Object originalValue = pv.getValue();
    			// 解析属性值
    			Object resolvedValue = valueResolver.resolveValueIfNecessary(pv, originalValue);
    			Object convertedValue = resolvedValue;
    			boolean convertible = bw.isWritableProperty(propertyName) &&
    					!PropertyAccessorUtils.isNestedOrIndexedProperty(propertyName);
    			if (convertible) {
    				convertedValue = convertForProperty(resolvedValue, propertyName, bw, converter);
    			}
    			// 避免重新装换,存入到合并的bean定义中
    			// Possibly store converted value in merged bean definition,
    			// in order to avoid re-conversion for every created bean instance.
    			if (resolvedValue == originalValue) {
    				if (convertible) {
    					pv.setConvertedValue(convertedValue);
    				}
    				deepCopy.add(pv);
    			}
    			else if (convertible && originalValue instanceof TypedStringValue &&
    					!((TypedStringValue) originalValue).isDynamic() &&
    					!(convertedValue instanceof Collection || ObjectUtils.isArray(convertedValue))) {
    				pv.setConvertedValue(convertedValue);
    				deepCopy.add(pv);
    			}
    			else {
    				resolveNecessary = true;
    				deepCopy.add(new PropertyValue(pv, convertedValue));
    			}
    		}
    	}
    	if (mpvs != null && !resolveNecessary) {
    		mpvs.setConverted();
    	}
    	// 填充属性值
    	// Set our (possibly massaged) deep copy.
    	try {
    		bw.setPropertyValues(new MutablePropertyValues(deepCopy));
    	}
    	catch (BeansException ex) {
    		throw new BeanCreationException(
    				mbd.getResourceDescription(), beanName, "Error setting property values", ex);
    	}
    }
    

    这里需要关注的是resolveValueIfNecessary方法。当未按照类型和名称进行自动装配时,BeanDefinitionValueResolver帮助类将会解析被包含在Bean定义中的值为实际的Bean并且将其填充到目标Bean实例中,

    上述的Notes中提到有MutablePropertyValues重新copy,然后将解析的依赖值覆盖写入到属性中,这里resolveValueIfNecessary中将会抉择Bean定义属性值的类型,如果是实际待装配填充的值,则不做任何处理;否则将会根据Bean定义属性的值类型,做相应处理,具体细节这里不再赘述。

    Bean的后置处理

    在Bean装配完毕后,这个Bean就已经初具形态,基本上是一个完整的Bean。因为对象就是成员与行为的集合,装配即补齐其依赖的成员。这是便可以执行Bean的初始化了,但是Spring提供了扩展点,在初始化前后都为应用预留了扩张点。

    上篇文章中介绍到BeanPostProcessor的容器扩展点,只是讲解了Spring上下文如何实例化和注册BeanPostProcessor,单对于BeanPostProcessor的唤醒调用没有提及,这里有了Bean创建的基础,再来看该问题。

    继续源码分析,在装配完成后,开始初始化:

    protected Object initializeBean(final String beanName, final Object bean, RootBeanDefinition mbd) {
    	// 由于部分对象可能会有访问安全控制,所以需要做权限访问
    	// 在初始化和后置处理前,需要处理Spring中的另一个扩展点Aware接口
    	if (System.getSecurityManager() != null) {
    		AccessController.doPrivileged(new PrivilegedAction<Object>() {
    			@Override
    			public Object run() {
    				// 带有权限控制,唤醒Aware接口,注入相应的Bean
    				invokeAwareMethods(beanName, bean);
    				return null;
    			}
    		}, getAccessControlContext());
    	}
    	else {
    		// 唤醒Aware接口,注入相应的Bean
    		invokeAwareMethods(beanName, bean);
    	}
    	// 初始化前的后置处理,唤醒BeanPostProcessor的applyBeanPostProcessorsBeforeInitialization
    	Object wrappedBean = bean;
    	if (mbd == null || !mbd.isSynthetic()) {
    		wrappedBean = applyBeanPostProcessorsBeforeInitialization(wrappedBean, beanName);
    	}
    	try {
    		// 唤醒初始化方法,初始化Bean
    		invokeInitMethods(beanName, wrappedBean, mbd);
    	}
    	catch (Throwable ex) {
    		throw new BeanCreationException(
    				(mbd != null ? mbd.getResourceDescription() : null),
    				beanName, "Invocation of init method failed", ex);
    	}
    	// 初始化完成后的后置处理,唤醒BeanPostProcessor的applyBeanPostProcessorsAfterInitialization
    	if (mbd == null || !mbd.isSynthetic()) {
    		wrappedBean = applyBeanPostProcessorsAfterInitialization(wrappedBean, beanName);
    	}
    	return wrappedBean;
    }
    

    这里重点看前后的后置处理,至于Aware接口的处理和初始化的执行,下节再详细分析。

    1.初始化前的后置处理

    @Override
    public Object applyBeanPostProcessorsBeforeInitialization(Object existingBean, String beanName)
    		throws BeansException {
    	// 遍历调用BeanFactory中的BeanPostProcessor,然后后置处理该Bean
    	Object result = existingBean;
    	for (BeanPostProcessor processor : getBeanPostProcessors()) {
    		result = processor.postProcessBeforeInitialization(result, beanName);
    		if (result == null) {
    			return result;
    		}
    	}
    	// 返回结果
    	return result;
    }
    

    2.初始化后的后置处理

    @Override
    public Object applyBeanPostProcessorsAfterInitialization(Object existingBean, String beanName)
    		throws BeansException {
    	// 遍历调用BeanFactory中的BeanPostProcessor后置处理初始化后的Bean
    	Object result = existingBean;
    	for (BeanPostProcessor processor : getBeanPostProcessors()) {
    		result = processor.postProcessAfterInitialization(result, beanName);
    		if (result == null) {
    			return result;
    		}
    	}
    	// 返回处理后的结果
    	return result;
    }
    

    Bean的初始化

    上节Bean的后置处理中已经初步提及到初始化的过程:

    1. 处理Spring的Aware系列接口
    2. 初始化前的后置处理
    3. 唤醒Bean的初始化
    4. 初始化后的后置处理

    1.处理Aware接口

    private void invokeAwareMethods(final String beanName, final Object bean) {
    	// 首先如果该Bean是Aware实例
    	if (bean instanceof Aware) {
    		// 如果该bean是BeanNameAware实例
    		if (bean instanceof BeanNameAware) {
    			// 则将该Beand的beanName set进该Bean中
    			((BeanNameAware) bean).setBeanName(beanName);
    		}
    		// 如果该Bean是BeanClassLoaderAware实例
    		if (bean instanceof BeanClassLoaderAware) {
    			// 则将加载该Bean的类加载器set进该beanzhong 
    			((BeanClassLoaderAware) bean).setBeanClassLoader(getBeanClassLoader());
    		}
    		// 如果该Bean是BeanFactoryAware的实例
    		if (bean instanceof BeanFactoryAware) {
    			// 则将BeanFactory set进该Bean中
    			((BeanFactoryAware) bean).setBeanFactory(AbstractAutowireCapableBeanFactory.this);
    		}
    	}
    }
    

    这里只处理BeanNameAware、BeanClassLoaderAware和BeanFactoryAware三个Aware接口。但是在Spring中还有很多Aware接口,如:

    • 经常使用的ApplicationContextAware接口
    • ResourceLoaderAware接口
    • MessageSourceAware接口
    • EnvironmentAware接口

    等等,它们是在何处处理的?Spring中针对这些接口使用了BeanPostProcessor的方式注入相应的Bean。

    以上的这些Aware接口要求注入分别是ApplicationContext,ResourceLoader,MessageSource,Environment。

    但是这些都是更偏上层应用,BeanFactory属于更底层的基础组件,所以不可能依赖倒转,在BeanFactory中处理这些Aware接口,将处理这些Aware接口的依赖注入。这样势必会造成BeanFactory依赖反转,与上层的这些接口耦合,那样违背设计。

    同时需要注意到的是,ApplicationContext,ResourceLoader,MessageSource,Environment这些组件都是可以通过ApplicationContext一致对外提供接口,所以只要向实现这些接口的Bean中注入ApplicationContext即可。

    Spring中使用ApplicationContextAwareProcessor的BeanPostProcessor后置处理,完成ApplicationContext注入到实现以上接口的Bean中:

    @Override
    public Object postProcessBeforeInitialization(final Object bean, String beanName) throws BeansException {
    	// 后置处理注入ApplicationContext至实现了Aware接口中
    	// 区分访问安全权限
    	AccessControlContext acc = null;
    	if (System.getSecurityManager() != null &&
    			(bean instanceof EnvironmentAware || bean instanceof EmbeddedValueResolverAware ||
    					bean instanceof ResourceLoaderAware || bean instanceof ApplicationEventPublisherAware ||
    					bean instanceof MessageSourceAware || bean instanceof ApplicationContextAware)) {
    		acc = this.applicationContext.getBeanFactory().getAccessControlContext();
    	}
    	if (acc != null) {
    		AccessController.doPrivileged(new PrivilegedAction<Object>() {
    			@Override
    			public Object run() {
    				invokeAwareInterfaces(bean);
    				return null;
    			}
    		}, acc);
    	}
    	else {
    		invokeAwareInterfaces(bean);
    	}
    	// 返回Bean,Spring需要处理返回结果,将其注册到单例容器中
    	return bean;
    }
    
    // 唤醒Aware接口处理,这里处理逻辑与之前的处理Aware接口基本类似
    private void invokeAwareInterfaces(Object bean) {
    	// 如果该Bean是Aware接口实例,则再按照不同的具体的接口,注入相应的对象进入该Bean
    	if (bean instanceof Aware) {
    		// 如果是EnvironmentAware实例,注入Environment
    		if (bean instanceof EnvironmentAware) {
    			((EnvironmentAware) bean).setEnvironment(this.applicationContext.getEnvironment());
    		}
    		// 如果是EmbeddedValueResolverAware实例,注入解析器
    		if (bean instanceof EmbeddedValueResolverAware) {
    			((EmbeddedValueResolverAware) bean).setEmbeddedValueResolver(this.embeddedValueResolver);
    		}
    		// 如果是ResourceLoaderAware实例,注入上下文
    		if (bean instanceof ResourceLoaderAware) {
    			((ResourceLoaderAware) bean).setResourceLoader(this.applicationContext);
    		}
    		// 如果是ApplicationEventPublisherAware实例,注入上下文
    		if (bean instanceof ApplicationEventPublisherAware) {
    			((ApplicationEventPublisherAware) bean).setApplicationEventPublisher(this.applicationContext);
    		}
    		// 如果是EmbeddedValueResolverAware实例,注入上下文
    		if (bean instanceof MessageSourceAware) {
    			((MessageSourceAware) bean).setMessageSource(this.applicationContext);
    		}
    		// 如果是ApplicationContextAware实例,注入上下文
    		if (bean instanceof ApplicationContextAware) {
    			((ApplicationContextAware) bean).setApplicationContext(this.applicationContext);
    		}
    	}
    }
    

    在处理完Aware接口后,就是Bean的初始化。但是Spring针对初始化做了增强处理,能够支持多种形态的初始化方式:

    • 实现了InitializingBean的方式
    • 自定义指定init-method方式
    • j2EE中定义的@PostConstruct初始化方式

    下面就让我们逐个进行分析

    // 该方法主要是针对Bean进行初始化
    protected void invokeInitMethods(String beanName, final Object bean, RootBeanDefinition mbd)
    		throws Throwable {
    	// 判断该Bean是否为InitializingBean实例
    	boolean isInitializingBean = (bean instanceof InitializingBean);
    	// 如果是InitializingBean实例且afterPropertiesSet方法不是额外的管理初始化方法
    	// 则调用afterPropertiesSet方法执行Bean的初始化逻辑
    	if (isInitializingBean && (mbd == null || !mbd.isExternallyManagedInitMethod("afterPropertiesSet"))) {
    		if (logger.isDebugEnabled()) {
    			logger.debug("Invoking afterPropertiesSet() on bean with name '" + beanName + "'");
    		}
    		if (System.getSecurityManager() != null) {
    			try {
    				AccessController.doPrivileged(new PrivilegedExceptionAction<Object>() {
    					@Override
    					public Object run() throws Exception {
    						((InitializingBean) bean).afterPropertiesSet();
    						return null;
    					}
    				}, getAccessControlContext());
    			}
    			catch (PrivilegedActionException pae) {
    				throw pae.getException();
    			}
    		}
    		else {
    			((InitializingBean) bean).afterPropertiesSet();
    		}
    	}
    	// 如果bean定义不为空
    	if (mbd != null) {
    		// 获取Bean定义的初始化方法
    		String initMethodName = mbd.getInitMethodName();
    		// 如果初始化方法不为空,且不是isInitializingBean和afterPropertiesSet方法,则执行自定义的初始化方法
    		if (initMethodName != null && !(isInitializingBean && "afterPropertiesSet".equals(initMethodName)) &&
    				!mbd.isExternallyManagedInitMethod(initMethodName)) {
    			invokeCustomInitMethod(beanName, bean, mbd);
    		}
    	}
    }
    

    初始化中分为两种情况,一种是实现InitializingBean,另一种是非实现的InitializingBean。前者执行afterPropertiesSet初始化,后者执行自定义配置的initMethod进行初始化。

    总结

    至此Spring的Bean生命周期的大部分就讲完了,主要过程就是:

    • 实例化Bean
    • 实例化的后置处理
    • 装配Bean
    • 执行Aware接口处理
    • 初始化前的后置处理
    • 初始化Bean
    • 初始化后的后置处理
    • Bean使用阶段
    • 执行DisposableBean销毁Bean
    • 执行自定义销毁方法
    • 被GC回收

    同样至此,Spring源码系列的基于XML配置的IOC也结束了,后续Spring源码分析将进入第二阶段:基于注解配置的IOC源码。

    第三阶段将是Spring框架的另一个模块:Spring AOP的源码解析。

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  • 原文地址:https://www.cnblogs.com/lxyit/p/10120886.html
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