关于对doCreateBean方法下的的createBeanInstance方法的分析

一、前言

最近在看Spring的相关源码,这次来分析一下createBeanInstance()方法。在getBean()的时候调用了doGetBean(),而doGetBean()内最为核心的就是doCreateBean()方法,在doCreateBean()方法下又有很多步骤而其中bean真正被创建的时机就在createBeanInstance()方法内。故此我们今天来分析一下这个方法。算是新的学习,也算是对这两天学习的一个总结。

那对于上面的话做一个总结就是:

getBean()->doGetBean()->doCreateBean()->createBeanInstance()

二、分析

在分析源码之前,大家要谨记这次分析的方法是createBeanInstance。

那既然如此,这个方法就和Spring创建Bean的方式离不开了,传送->关于Spring创建Bean的方式

创建方式大体上分为两种:一类是工厂创建,一类是构造创建。

那可以猜测createBeanInstance() 也无非是通过这两种方法来创建Bean,附上源码:

/**
	 * Create a new instance for the specified bean, using an appropriate instantiation strategy:
	 * factory method, constructor autowiring, or simple instantiation.
	 * @param beanName the name of the bean
	 * @param mbd the bean definition for the bean
	 * @param args explicit arguments to use for constructor or factory method invocation
	 * @return a BeanWrapper for the new instance
	 * @see #obtainFromSupplier
	 * @see #instantiateUsingFactoryMethod
	 * @see #autowireConstructor
	 * @see #instantiateBean
	 */
	protected BeanWrapper createBeanInstance(String beanName, RootBeanDefinition mbd, @Nullable Object[] args) {
		// 对传入的参数进行解析
		Class beanClass = resolveBeanClass(mbd, beanName);
        
		if (beanClass != null && !Modifier.isPublic(beanClass.getModifiers()) && !mbd.isNonPublicAccessAllowed()) {
			throw new BeanCreationException(mbd.getResourceDescription(), beanName,
					"Bean class isn't public, and non-public access not allowed: " + beanClass.getName());
		}
        
        //选取不同的策略
		Supplier instanceSupplier = mbd.getInstanceSupplier();
		if (instanceSupplier != null) {
			return obtainFromSupplier(instanceSupplier, beanName);
		}

		if (mbd.getFactoryMethodName() != null) {
            //使用工厂创建
			return instantiateUsingFactoryMethod(beanName, mbd, args);
		}

		// Shortcut when re-creating the same bean...
		boolean resolved = false;
		boolean autowireNecessary = false;
		if (args == null) {
			synchronized (mbd.constructorArgumentLock) {
				if (mbd.resolvedConstructorOrFactoryMethod != null) {
					resolved = true;
					autowireNecessary = mbd.constructorArgumentsResolved;
				}
			}
		}
       //缓存不为空
		if (resolved) {
			if (autowireNecessary) {
                //使用有参创建
				return autowireConstructor(beanName, mbd, null, null);
			}
			else {
               //使用无参创建
				return instantiateBean(beanName, mbd);
			}
		}

		// Candidate constructors for autowiring?
        //尝试从配置文件中读取
		Constructor[] ctors = determineConstructorsFromBeanPostProcessors(beanClass, beanName);
		if (ctors != null || mbd.getResolvedAutowireMode() == AUTOWIRE_CONSTRUCTOR ||
				mbd.hasConstructorArgumentValues() || !ObjectUtils.isEmpty(args)) {
			    //同上有参构造
                return autowireConstructor(beanName, mbd, ctors, args);
		}

		// Preferred constructors for default construction?
		ctors = mbd.getPreferredConstructors();
		if (ctors != null) {
			return autowireConstructor(beanName, mbd, ctors, null);
		}

		// No special handling: simply use no-arg constructor.
		return instantiateBean(beanName, mbd);//无参构造

	}

 以上就关注三个方法即可:

1.instantiateUsingFactoryMethod

2.autowireConstructor

3.instantiateBean

我们逐个来分析,追到instantiateUsingFactoryMethod的源码

/**
	 * Instantiate the bean using a named factory method. The method may be static, if the
	 * bean definition parameter specifies a class, rather than a "factory-bean", or
	 * an instance variable on a factory object itself configured using Dependency Injection.
	 * 

Implementation requires iterating over the static or instance methods with the * name specified in the RootBeanDefinition (the method may be overloaded) and trying * to match with the parameters. We don't have the types attached to constructor args, * so trial and error is the only way to go here. The explicitArgs array may contain * argument values passed in programmatically via the corresponding getBean method. * @param beanName the name of the bean * @param mbd the merged bean definition for the bean * @param explicitArgs argument values passed in programmatically via the getBean * method, or {@code null} if none (-> use constructor argument values from bean definition) * @return a BeanWrapper for the new instance */ public BeanWrapper instantiateUsingFactoryMethod( String beanName, RootBeanDefinition mbd, @Nullable Object[] explicitArgs) { BeanWrapperImpl bw = new BeanWrapperImpl(); this.beanFactory.initBeanWrapper(bw); Object factoryBean; Class factoryClass; boolean isStatic; String factoryBeanName = mbd.getFactoryBeanName(); if (factoryBeanName != null) { if (factoryBeanName.equals(beanName)) { throw new BeanDefinitionStoreException(mbd.getResourceDescription(), beanName, "factory-bean reference points back to the same bean definition"); } factoryBean = this.beanFactory.getBean(factoryBeanName); if (mbd.isSingleton() && this.beanFactory.containsSingleton(beanName)) { throw new ImplicitlyAppearedSingletonException(); } factoryClass = factoryBean.getClass(); isStatic = false; } else { // It's a static factory method on the bean class. if (!mbd.hasBeanClass()) { throw new BeanDefinitionStoreException(mbd.getResourceDescription(), beanName, "bean definition declares neither a bean class nor a factory-bean reference"); } factoryBean = null; factoryClass = mbd.getBeanClass(); isStatic = true; } Method factoryMethodToUse = null; ArgumentsHolder argsHolderToUse = null; Object[] argsToUse = null; if (explicitArgs != null) { argsToUse = explicitArgs; } else { Object[] argsToResolve = null; synchronized (mbd.constructorArgumentLock) { factoryMethodToUse = (Method) mbd.resolvedConstructorOrFactoryMethod; if (factoryMethodToUse != null && mbd.constructorArgumentsResolved) { // Found a cached factory method... argsToUse = mbd.resolvedConstructorArguments; if (argsToUse == null) { argsToResolve = mbd.preparedConstructorArguments; } } } if (argsToResolve != null) { argsToUse = resolvePreparedArguments(beanName, mbd, bw, factoryMethodToUse, argsToResolve, true); } } if (factoryMethodToUse == null || argsToUse == null) { // Need to determine the factory method... // Try all methods with this name to see if they match the given arguments. factoryClass = ClassUtils.getUserClass(factoryClass); Method[] rawCandidates = getCandidateMethods(factoryClass, mbd); List candidateList = new ArrayList<>(); for (Method candidate : rawCandidates) { if (Modifier.isStatic(candidate.getModifiers()) == isStatic && mbd.isFactoryMethod(candidate)) { candidateList.add(candidate); } } if (candidateList.size() == 1 && explicitArgs == null && !mbd.hasConstructorArgumentValues()) { Method uniqueCandidate = candidateList.get(0); if (uniqueCandidate.getParameterCount() == 0) { mbd.factoryMethodToIntrospect = uniqueCandidate; synchronized (mbd.constructorArgumentLock) { mbd.resolvedConstructorOrFactoryMethod = uniqueCandidate; mbd.constructorArgumentsResolved = true; mbd.resolvedConstructorArguments = EMPTY_ARGS; } bw.setBeanInstance(instantiate(beanName, mbd, factoryBean, uniqueCandidate, EMPTY_ARGS)); return bw; } } Method[] candidates = candidateList.toArray(new Method[0]); AutowireUtils.sortFactoryMethods(candidates); ConstructorArgumentValues resolvedValues = null; boolean autowiring = (mbd.getResolvedAutowireMode() == AutowireCapableBeanFactory.AUTOWIRE_CONSTRUCTOR); int minTypeDiffWeight = Integer.MAX_VALUE; Set ambiguousFactoryMethods = null; int minNrOfArgs; if (explicitArgs != null) { minNrOfArgs = explicitArgs.length; } else { // We don't have arguments passed in programmatically, so we need to resolve the // arguments specified in the constructor arguments held in the bean definition. if (mbd.hasConstructorArgumentValues()) { ConstructorArgumentValues cargs = mbd.getConstructorArgumentValues(); resolvedValues = new ConstructorArgumentValues(); minNrOfArgs = resolveConstructorArguments(beanName, mbd, bw, cargs, resolvedValues); } else { minNrOfArgs = 0; } } LinkedList causes = null; for (Method candidate : candidates) { Class[] paramTypes = candidate.getParameterTypes(); if (paramTypes.length >= minNrOfArgs) { ArgumentsHolder argsHolder; if (explicitArgs != null) { // Explicit arguments given -> arguments length must match exactly. if (paramTypes.length != explicitArgs.length) { continue; } argsHolder = new ArgumentsHolder(explicitArgs); } else { // Resolved constructor arguments: type conversion and/or autowiring necessary. try { String[] paramNames = null; ParameterNameDiscoverer pnd = this.beanFactory.getParameterNameDiscoverer(); if (pnd != null) { paramNames = pnd.getParameterNames(candidate); } argsHolder = createArgumentArray(beanName, mbd, resolvedValues, bw, paramTypes, paramNames, candidate, autowiring, candidates.length == 1); } catch (UnsatisfiedDependencyException ex) { if (logger.isTraceEnabled()) { logger.trace("Ignoring factory method [" + candidate + "] of bean '" + beanName + "': " + ex); } // Swallow and try next overloaded factory method. if (causes == null) { causes = new LinkedList<>(); } causes.add(ex); continue; } } int typeDiffWeight = (mbd.isLenientConstructorResolution() ? argsHolder.getTypeDifferenceWeight(paramTypes) : argsHolder.getAssignabilityWeight(paramTypes)); // Choose this factory method if it represents the closest match. if (typeDiffWeight < minTypeDiffWeight) { factoryMethodToUse = candidate; argsHolderToUse = argsHolder; argsToUse = argsHolder.arguments; minTypeDiffWeight = typeDiffWeight; ambiguousFactoryMethods = null; } // Find out about ambiguity: In case of the same type difference weight // for methods with the same number of parameters, collect such candidates // and eventually raise an ambiguity exception. // However, only perform that check in non-lenient constructor resolution mode, // and explicitly ignore overridden methods (with the same parameter signature). else if (factoryMethodToUse != null && typeDiffWeight == minTypeDiffWeight && !mbd.isLenientConstructorResolution() && paramTypes.length == factoryMethodToUse.getParameterCount() && !Arrays.equals(paramTypes, factoryMethodToUse.getParameterTypes())) { if (ambiguousFactoryMethods == null) { ambiguousFactoryMethods = new LinkedHashSet<>(); ambiguousFactoryMethods.add(factoryMethodToUse); } ambiguousFactoryMethods.add(candidate); } } } if (factoryMethodToUse == null) { if (causes != null) { UnsatisfiedDependencyException ex = causes.removeLast(); for (Exception cause : causes) { this.beanFactory.onSuppressedException(cause); } throw ex; } List argTypes = new ArrayList<>(minNrOfArgs); if (explicitArgs != null) { for (Object arg : explicitArgs) { argTypes.add(arg != null ? arg.getClass().getSimpleName() : "null"); } } else if (resolvedValues != null) { Set valueHolders = new LinkedHashSet<>(resolvedValues.getArgumentCount()); valueHolders.addAll(resolvedValues.getIndexedArgumentValues().values()); valueHolders.addAll(resolvedValues.getGenericArgumentValues()); for (ValueHolder value : valueHolders) { String argType = (value.getType() != null ? ClassUtils.getShortName(value.getType()) : (value.getValue() != null ? value.getValue().getClass().getSimpleName() : "null")); argTypes.add(argType); } } String argDesc = StringUtils.collectionToCommaDelimitedString(argTypes); throw new BeanCreationException(mbd.getResourceDescription(), beanName, "No matching factory method found: " + (mbd.getFactoryBeanName() != null ? "factory bean '" + mbd.getFactoryBeanName() + "'; " : "") + "factory method '" + mbd.getFactoryMethodName() + "(" + argDesc + ")'. " + "Check that a method with the specified name " + (minNrOfArgs > 0 ? "and arguments " : "") + "exists and that it is " + (isStatic ? "static" : "non-static") + "."); } else if (void.class == factoryMethodToUse.getReturnType()) { throw new BeanCreationException(mbd.getResourceDescription(), beanName, "Invalid factory method '" + mbd.getFactoryMethodName() + "': needs to have a non-void return type!"); } else if (ambiguousFactoryMethods != null) { throw new BeanCreationException(mbd.getResourceDescription(), beanName, "Ambiguous factory method matches found in bean '" + beanName + "' " + "(hint: specify index/type/name arguments for simple parameters to avoid type ambiguities): " + ambiguousFactoryMethods); } if (explicitArgs == null && argsHolderToUse != null) { mbd.factoryMethodToIntrospect = factoryMethodToUse; argsHolderToUse.storeCache(mbd, factoryMethodToUse); } } Assert.state(argsToUse != null, "Unresolved factory method arguments"); bw.setBeanInstance(instantiate(beanName, mbd, factoryBean, factoryMethodToUse, argsToUse)); return bw; }

冗长的代码有点不像是Spring的一贯作风。在以前他都是拆成一个个方法,至少在上层看起来逻辑是清楚的。那就来讲一下这段代码的逻辑内容:

1.先判断是静态工厂or实例工厂

2.是否已经有指定参数explicitArgs!=null

3.尝试从缓存中提取参数

4.当缓存未命中时则自己解析参数

  4.1先拿到该类的所有方法

  4.2过滤掉无用的方法(就是看是实例还是静态工厂然后针对性的筛掉一些方法)

  4.3候选方法进行倒排

  4.4定义最小工厂方法的个数,准备循环解析

    4.4.1explicitArgs!=null则使用该参数的个数为最小个数

    4.4.2反之就从RootBeanDefinition中获取构造已确立个数

    4.4.3若RootBeanDefinition的构造为空则个数为0

5.循环候选的工厂,最后确立最终的工厂方法(就是通过权重的方式)

6.异常处理

7.用工厂创建bean

 

ok,那如果RootBeanDefinition的getFactoryMethodName()不为null,执行instantiateUsingFactoryMethod,反之则需要我们调用构造去创建Bean了。我们先从复杂的有参构造分析,当看完这个方法你再看无参就觉得很容易了。

追踪到autowireConstructor()去:

/**
	 * "autowire constructor" (with constructor arguments by type) behavior.
	 * Also applied if explicit constructor argument values are specified,
	 * matching all remaining arguments with beans from the bean factory.
	 * 

This corresponds to constructor injection: In this mode, a Spring * bean factory is able to host components that expect constructor-based * dependency resolution. * @param beanName the name of the bean * @param mbd the merged bean definition for the bean * @param chosenCtors chosen candidate constructors (or {@code null} if none) * @param explicitArgs argument values passed in programmatically via the getBean method, * or {@code null} if none (-> use constructor argument values from bean definition) * @return a BeanWrapper for the new instance */ public BeanWrapper autowireConstructor(String beanName, RootBeanDefinition mbd, @Nullable Constructor[] chosenCtors, @Nullable Object[] explicitArgs) { BeanWrapperImpl bw = new BeanWrapperImpl(); this.beanFactory.initBeanWrapper(bw); Constructor constructorToUse = null; ArgumentsHolder argsHolderToUse = null; Object[] argsToUse = null; if (explicitArgs != null) { argsToUse = explicitArgs; } else { Object[] argsToResolve = null; synchronized (mbd.constructorArgumentLock) { constructorToUse = (Constructor) mbd.resolvedConstructorOrFactoryMethod; if (constructorToUse != null && mbd.constructorArgumentsResolved) { // Found a cached constructor... argsToUse = mbd.resolvedConstructorArguments; if (argsToUse == null) { argsToResolve = mbd.preparedConstructorArguments; } } } if (argsToResolve != null) { argsToUse = resolvePreparedArguments(beanName, mbd, bw, constructorToUse, argsToResolve, true); } } if (constructorToUse == null || argsToUse == null) { // Take specified constructors, if any. Constructor[] candidates = chosenCtors; if (candidates == null) { Class beanClass = mbd.getBeanClass(); try { candidates = (mbd.isNonPublicAccessAllowed() ? beanClass.getDeclaredConstructors() : beanClass.getConstructors()); } catch (Throwable ex) { throw new BeanCreationException(mbd.getResourceDescription(), beanName, "Resolution of declared constructors on bean Class [" + beanClass.getName() + "] from ClassLoader [" + beanClass.getClassLoader() + "] failed", ex); } } if (candidates.length == 1 && explicitArgs == null && !mbd.hasConstructorArgumentValues()) { Constructor uniqueCandidate = candidates[0]; if (uniqueCandidate.getParameterCount() == 0) { synchronized (mbd.constructorArgumentLock) { mbd.resolvedConstructorOrFactoryMethod = uniqueCandidate; mbd.constructorArgumentsResolved = true; mbd.resolvedConstructorArguments = EMPTY_ARGS; } bw.setBeanInstance(instantiate(beanName, mbd, uniqueCandidate, EMPTY_ARGS)); return bw; } } // Need to resolve the constructor. boolean autowiring = (chosenCtors != null || mbd.getResolvedAutowireMode() == AutowireCapableBeanFactory.AUTOWIRE_CONSTRUCTOR); ConstructorArgumentValues resolvedValues = null; int minNrOfArgs; if (explicitArgs != null) { minNrOfArgs = explicitArgs.length; } else { ConstructorArgumentValues cargs = mbd.getConstructorArgumentValues(); resolvedValues = new ConstructorArgumentValues(); minNrOfArgs = resolveConstructorArguments(beanName, mbd, bw, cargs, resolvedValues); } AutowireUtils.sortConstructors(candidates); int minTypeDiffWeight = Integer.MAX_VALUE; Set> ambiguousConstructors = null; LinkedList causes = null; for (Constructor candidate : candidates) { Class[] paramTypes = candidate.getParameterTypes(); if (constructorToUse != null && argsToUse != null && argsToUse.length > paramTypes.length) { // Already found greedy constructor that can be satisfied -> // do not look any further, there are only less greedy constructors left. break; } if (paramTypes.length < minNrOfArgs) { continue; } ArgumentsHolder argsHolder; if (resolvedValues != null) { try { String[] paramNames = ConstructorPropertiesChecker.evaluate(candidate, paramTypes.length); if (paramNames == null) { ParameterNameDiscoverer pnd = this.beanFactory.getParameterNameDiscoverer(); if (pnd != null) { paramNames = pnd.getParameterNames(candidate); } } argsHolder = createArgumentArray(beanName, mbd, resolvedValues, bw, paramTypes, paramNames, getUserDeclaredConstructor(candidate), autowiring, candidates.length == 1); } catch (UnsatisfiedDependencyException ex) { if (logger.isTraceEnabled()) { logger.trace("Ignoring constructor [" + candidate + "] of bean '" + beanName + "': " + ex); } // Swallow and try next constructor. if (causes == null) { causes = new LinkedList<>(); } causes.add(ex); continue; } } else { // Explicit arguments given -> arguments length must match exactly. if (paramTypes.length != explicitArgs.length) { continue; } argsHolder = new ArgumentsHolder(explicitArgs); } int typeDiffWeight = (mbd.isLenientConstructorResolution() ? argsHolder.getTypeDifferenceWeight(paramTypes) : argsHolder.getAssignabilityWeight(paramTypes)); // Choose this constructor if it represents the closest match. if (typeDiffWeight < minTypeDiffWeight) { constructorToUse = candidate; argsHolderToUse = argsHolder; argsToUse = argsHolder.arguments; minTypeDiffWeight = typeDiffWeight; ambiguousConstructors = null; } else if (constructorToUse != null && typeDiffWeight == minTypeDiffWeight) { if (ambiguousConstructors == null) { ambiguousConstructors = new LinkedHashSet<>(); ambiguousConstructors.add(constructorToUse); } ambiguousConstructors.add(candidate); } } if (constructorToUse == null) { if (causes != null) { UnsatisfiedDependencyException ex = causes.removeLast(); for (Exception cause : causes) { this.beanFactory.onSuppressedException(cause); } throw ex; } throw new BeanCreationException(mbd.getResourceDescription(), beanName, "Could not resolve matching constructor " + "(hint: specify index/type/name arguments for simple parameters to avoid type ambiguities)"); } else if (ambiguousConstructors != null && !mbd.isLenientConstructorResolution()) { throw new BeanCreationException(mbd.getResourceDescription(), beanName, "Ambiguous constructor matches found in bean '" + beanName + "' " + "(hint: specify index/type/name arguments for simple parameters to avoid type ambiguities): " + ambiguousConstructors); } if (explicitArgs == null && argsHolderToUse != null) { argsHolderToUse.storeCache(mbd, constructorToUse); } } Assert.state(argsToUse != null, "Unresolved constructor arguments"); bw.setBeanInstance(instantiate(beanName, mbd, constructorToUse, argsToUse)); return bw; }

不知道你是否耐心的读完了这段代码,其实它和工厂创建的方法的思想其实都是同样的。

1.尝试检测是否已经指定了参数

2.尝试从缓存中读取

3.反之就从配置中拿

4.解析参数

5.构造排序

6.循环检查

  这里需要提示的就是当constructorToUse!=null,最小个数>当前个数时则跳过本次循环

  另外当RootBeanDefinition的参数个数!=当前个数时同样跳过本次循环

7.选中确立构造

8.缓存起来

9.创建并返回实例

 

再有就是对无参构造的分析:

/**
	 * Instantiate the given bean using its default constructor.
	 * @param beanName the name of the bean
	 * @param mbd the bean definition for the bean
	 * @return a BeanWrapper for the new instance
	 */
	protected BeanWrapper instantiateBean(final String beanName, final RootBeanDefinition mbd) {
		try {
			Object beanInstance;
			final BeanFactory parent = this;
			if (System.getSecurityManager() != null) {
				beanInstance = AccessController.doPrivileged((PrivilegedAction) () ->
						getInstantiationStrategy().instantiate(mbd, beanName, parent),
						getAccessControlContext());
			}
			else {
				beanInstance = getInstantiationStrategy().instantiate(mbd, beanName, parent);
			}
			BeanWrapper bw = new BeanWrapperImpl(beanInstance);
			initBeanWrapper(bw);
			return bw;
		}
		catch (Throwable ex) {
			throw new BeanCreationException(
					mbd.getResourceDescription(), beanName, "Instantiation of bean failed", ex);
		}
	} 
  

其实无参方法来说就比较简单了,总体上就有一个重要的方法instantiate 

我们接下来跟进去看看

@Override
	public Object instantiate(RootBeanDefinition bd, @Nullable String beanName, BeanFactory owner) {
		// Don't override the class with CGLIB if no overrides.
		if (!bd.hasMethodOverrides()) {
			Constructor constructorToUse;
			synchronized (bd.constructorArgumentLock) {
				constructorToUse = (Constructor) bd.resolvedConstructorOrFactoryMethod;
				if (constructorToUse == null) {
					final Class clazz = bd.getBeanClass();
					if (clazz.isInterface()) {
						throw new BeanInstantiationException(clazz, "Specified class is an interface");
					}
					try {
						if (System.getSecurityManager() != null) {
							constructorToUse = AccessController.doPrivileged(
									(PrivilegedExceptionAction>) clazz::getDeclaredConstructor);
						}
						else {
							constructorToUse = clazz.getDeclaredConstructor();
						}
						bd.resolvedConstructorOrFactoryMethod = constructorToUse;
					}
					catch (Throwable ex) {
						throw new BeanInstantiationException(clazz, "No default constructor found", ex);
					}
				}
			}
			return BeanUtils.instantiateClass(constructorToUse);
		}
		else {
			// Must generate CGLIB subclass.
			return instantiateWithMethodInjection(bd, beanName, owner);
		}
	}

简单来讲就是Spring真是考虑的很全面我们以为无参的构造就是通过构造方法去创建Bean,但是Spring会:

判断当前Bean是否有look-method和replace-method属性标签,有则不能直接用构造创建,它是通过cglib进行的增强返回的代理类。

反之才使用构造区创建bean

 

ok,以上。

其实这里面还有ObjectFactory相关的知识概念没有引入进来,这个牵扯到Spring对单例Bean的循环依赖的解决办法,这个我们下次再讲。有不足之处欢迎指正!

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