前言
在前面的doCreateBean方法中,我们了解到,populateBean是负责填充Bean实例属性的。此时Bean中需要依赖注入的成员已经在applyMergedBeanDefinitionPostProcessors中被对应的后置处理器进行了存储,最终的成员被封装到了AutowiredAnnotationBeanPostProcessor#injectionMetadataCache这个集合中.
1. Dependencies和Dependency Injection
很多人可能还不清除什么是依赖和依赖注入.这是理解Spring IoC的一个核心概念.下面简单从代码的角度谈谈什么是依赖和依赖注入.
- 一个简单的MVC登陆入口
@RestController
@RequestMapping("/web")
public class UserController {
@Autowired
@Qualifier("normalUserService")
private UserService userService;
/**
* 用户登陆入口
*/
@PostMapping("/login")
public void login(User user) {
userService.login(user);
}
}
软件架构设计原则中要求面向接口编程,为此MVC架构中往往采取的是上面代码展示的这种结构,
UserController依赖于UserService接口的实现类.此时,UserController就与UserService直接形成了依赖关系.
此时,如果没有Spring,我们有三种方式去将UserService注入进来:
- 每次调用login的时候,
new UserService();- 通过setter的方式进行注入.即UserController中提供
setUserService(UserService userService).- 通过构造方法进行注入,
public UserController(UserService userService).其中,new的方式是耦合度较高的做法。所以在Spring中,提供了
构造注入和setter注入的方式来落地IoC思想(Inversion of Control).
与用户主动调用的方式不同,在Spring框架中,往往只需要声明好依赖关系,框架就会自动生成好用户需要的Java对象,这就是所谓的Bean.我们一般将UserController中去注入UserService这个过程称为依赖注入,即专业术语上的DI(Dependency Injection).
2. 自动装配
@Autowired注解和@Resource注解都是自动装配的代表,思考一下,自动装配大概是什么过程?
从前面的文章中我们学习了,Spring将Java对象中的信息抽象成了BeanDefinition,最后通过getBean方法来加载非延迟加载的单例Bean,每当getBean装配完一个Bean之后,就会添加到单例缓存中.
那么自动装配的过程,就是按规则(如果指定)从容器中获取到依赖的Bean,然后通过反射进行赋值完成装配的的过程.
3. populateBean的总体流程
-
激活InstantiationAwareBeanPostProcessor后置处理器的InstantiationAwareBeanPostProcessor方法: 在实例化bean之后,Spring属性填充之前执行的钩子方法,
这是在Spring的自动装配开始之前对该bean实例执行自定义字段注入的回调,也是最后一次机会在自动装配前修改Bean的属性值。 - 解析依赖注入的方式,将属性装配到PropertyValues中: resolvedAutowireMode.
- 激活InstantiationAwareBeanPostProcessor#postProcessProperties: 对@AutoWired标记的属性进行依赖注入.
- 依赖检查: checkDependencies.
- 将解析的值用BeanWrapper进行包装: applyPropertyValues.
3.1 InstantiationAwareBeanPostProcessor#postProcessAfterInstantiation
- AbstractAutowireCapableBeanFactory#populateBean
// InstantiationAwareBeanPostProcessors最后一次进行对bean的属性修改
// 采用职责链的方式对所有实现了InstantiationAwareBeanPostProcessor的后置处理器调用.
// 直到某个InstantiationAwareBeanPostProcessor在postProcessAfterInstantiation中返回了false
if (!mbd.isSynthetic() && hasInstantiationAwareBeanPostProcessors()) {
for (BeanPostProcessor bp : getBeanPostProcessors()) {
if (bp instanceof InstantiationAwareBeanPostProcessor) {
InstantiationAwareBeanPostProcessor ibp = (InstantiationAwareBeanPostProcessor) bp;
// 如果返回了false,直接中断,不进行下面的操作
if (!ibp.postProcessAfterInstantiation(bw.getWrappedInstance(), beanName)) {
return;
}
}
}
}
populateBean中,首先会经过判空校验,校验通过后.
检查用户是否有注册InstantiationAwareBeanPostProcessor,如果有,使用责任链模式激活这些后置器中的postProcessAfterInstantiation方法,如果某个后置处理器返回了false,那么Spring就不会执行框架的自动装配逻辑了.官方的建议是不建议去扩展此后置处理器,而是推荐扩展自BeanPostProcessor或从InstantiationAwareBeanPostProcessorAdapter派生.
3.2 根据注入方式解析属性到PropertyValues
// 这里的pvs其实是一个MutablePropertyValues实例
// 提供对属性的读写操作实现,同时可以通过构造函数实现深拷贝
// 获取BeanDefinition里面为Bean设置的属性值
PropertyValues pvs = (mbd.hasPropertyValues() ? mbd.getPropertyValues() : null);
// 根据Bean配置的依赖注入方式完成注入,默认是0,即不走以下逻辑
// 如果设置了相关的依赖装配方式,会遍历Bean的属性,根据type或者name完成相应注入
int resolvedAutowireMode = mbd.getResolvedAutowireMode();
if (resolvedAutowireMode == AUTOWIRE_BY_NAME || resolvedAutowireMode == AUTOWIRE_BY_TYPE) {
MutablePropertyValues newPvs = new MutablePropertyValues(pvs);
// Add property values based on autowire by name if applicable.
// 根据beanName进行autowired自动装配逻辑
if (resolvedAutowireMode == AUTOWIRE_BY_NAME) {
autowireByName(beanName, mbd, bw, newPvs);
}
// Add property values based on autowire by type if applicable.
// 根据Type进行autowired自动装配逻辑
if (resolvedAutowireMode == AUTOWIRE_BY_TYPE) {
autowireByType(beanName, mbd, bw, newPvs);
}
pvs = newPvs;
}
- 首先从BeanDefinition中取出
propertyValues,具体的调用方法在AbstractBeanDefinition#getPropertyValues中,返回的类型为MutablePropertyValues.- 解析依赖装配入的方式.在
AutowireCapableBeanFactory接口中声明了5种依赖注入的方式:
| resolvedAutowireMode | 依赖注入方式 | 描述 |
|---|---|---|
| 0 | AUTOWIRE_NO | 没有显式配置上装配的方式 |
| 1 | AUTOWIRE_BY_NAME | 按beanName进行装配 |
| 2 | AUTOWIRE_BY_TYPE | 按type进行装配 |
| 3 | AUTOWIRE_CONSTRUCTOR | 在构造函数中进行装配 |
| 4 | AUTOWIRE_AUTODETECT | 通过内省bean类确定适当的自动装配策略,Spring已经将其标注为@Deprecated
|
一般以注解的形式,默认都解析为0,也就是没有显式配置自动装配策略.
什么情况会进入if条件中的代码块,通常是在XML配置文件中显式指定了autowired或者在Java配置类中@Bean上,声明autowired.
简单给个示例:
@Bean(autowire = Autowire.BY_NAME)
3.3 InstantiationAwareBeanPostProcessor#postProcessProperties
如果没有显式声明自动装配的方式(
@Autowired注解),那么就会使用到InstantiationAwareBeanPostProcessor这个后置处理器的postProcessProperties方法.
// 容器是否注册了InstantiationAwareBeanPostProcessors
boolean hasInstAwareBpps = hasInstantiationAwareBeanPostProcessors();
// 是否进行依赖检查,默认为false
boolean needsDepCheck = (mbd.getDependencyCheck() != AbstractBeanDefinition.DEPENDENCY_CHECK_NONE);
PropertyDescriptor[] filteredPds = null;
if (hasInstAwareBpps) {
if (pvs == null) {
pvs = mbd.getPropertyValues();
}
for (BeanPostProcessor bp : getBeanPostProcessors()) {
if (bp instanceof InstantiationAwareBeanPostProcessor) {
InstantiationAwareBeanPostProcessor ibp = (InstantiationAwareBeanPostProcessor) bp;
// 对@AutoWired标记的属性进行依赖注入
PropertyValues pvsToUse = ibp.postProcessProperties(pvs, bw.getWrappedInstance(), beanName);
if (pvsToUse == null) {
if (filteredPds == null) {
filteredPds = filterPropertyDescriptorsForDependencyCheck(bw, mbd.allowCaching);
}
// 对解析完未设置的属性再进行处理
pvsToUse = ibp.postProcessPropertyValues(pvs, filteredPds, bw.getWrappedInstance(), beanName);
if (pvsToUse == null) {
return;
}
}
pvs = pvsToUse;
}
}
}
- AutowiredAnnotationBeanPostProcessor#postProcessProperties
public PropertyValues postProcessProperties(PropertyValues pvs, Object bean, String beanName) {
// 获取指定类中被@Autowired注解标记的metadata.
// metadata在实例化后的applyMergedBeanDefinitionPostProcessors中进行了存储
// 此时的findAutowiringMetadata是从injectionMetadataCache缓存中读取metadata
InjectionMetadata metadata = findAutowiringMetadata(beanName, bean.getClass(), pvs);
try {
// 对Bean的属性进行自动注入
metadata.inject(bean, beanName, pvs);
}
catch (BeanCreationException ex) {
throw ex;
}
catch (Throwable ex) {
throw new BeanCreationException(beanName, "Injection of autowired dependencies failed", ex);
}
return pvs;
}
在前面的doCreateBean中我们对
applyMergedBeanDefinitionPostProcessors进行了分析,在它的postProcessMergedBeanDefinition中已经调用了findAutowiringMetadata这个方法对Bean上被@Autowired标记的成员进行了存储,此时已经进入到了属性填充阶段,从injectionMetadataCache这个缓存区即可获取InjectionMetadata类型的metadata,即依赖注入的元数据.
InjectionMetadata中提供了一个inject方法,执行自动注入依赖的逻辑.
3.3.1 org.springframework.beans.factory.annotation.InjectionMetadata#inject
public void inject(Object target, @Nullable String beanName, @Nullable PropertyValues pvs) throws Throwable {
Collection<InjectedElement> checkedElements = this.checkedElements;
Collection<InjectedElement> elementsToIterate =
(checkedElements != null ? checkedElements : this.injectedElements);
if (!elementsToIterate.isEmpty()) {
for (InjectedElement element : elementsToIterate) {
if (logger.isTraceEnabled()) {
logger.trace("Processing injected element of bean '" + beanName + "': " + element);
}
// 调用InjectedElement#inject,这里是多态的实现
// @Autowired关注AutowiredAnnotationBeanPostProcessor.AutowiredFieldElement.inject
element.inject(target, beanName, pvs);
}
}
}
这里逻辑比较清晰,查看当前的
checkedElements是否为空,如果为空,解析injectedElements.然后遍历对element执行inject操作.
- AutowiredAnnotationBeanPostProcessor.AutowiredFieldElement#inject
protected void inject(Object bean, @Nullable String beanName, @Nullable PropertyValues pvs) throws Throwable {
// 当前存储的需要注入的成员
Field field = (Field) this.member;
Object value;
// 如果该成员的值被缓存了,从缓存中获取
if (this.cached) {
// 最终调用DefaultListableBeanFactory的resolveDependency
value = resolvedCachedArgument(beanName, this.cachedFieldValue);
}
else {
// 为该成员创建一个DependencyDescriptor.
DependencyDescriptor desc = new DependencyDescriptor(field, this.required);
// 设置当前bean的Class
desc.setContainingClass(bean.getClass());
Set<String> autowiredBeanNames = new LinkedHashSet<>(1);
Assert.state(beanFactory != null, "No BeanFactory available");
// 获取类型转换器
TypeConverter typeConverter = beanFactory.getTypeConverter();
try {
// 最终调用DefaultListableBeanFactory的resolveDependency
value = beanFactory.resolveDependency(desc, beanName, autowiredBeanNames, typeConverter);
}
catch (BeansException ex) {
throw new UnsatisfiedDependencyException(null, beanName, new InjectionPoint(field), ex);
}
synchronized (this) {
// 如果成员变量的值没有缓存
if (!this.cached) {
// 成员变量的值不为null,并且required==true
if (value != null || this.required) {
this.cachedFieldValue = desc;
// 注册依赖关系
registerDependentBeans(beanName, autowiredBeanNames);
if (autowiredBeanNames.size() == 1) {
String autowiredBeanName = autowiredBeanNames.iterator().next();
// 依赖对象类型和字段类型匹配,默认按类型注入
if (beanFactory.containsBean(autowiredBeanName) &&
beanFactory.isTypeMatch(autowiredBeanName, field.getType())) {
this.cachedFieldValue = new ShortcutDependencyDescriptor(
desc, autowiredBeanName, field.getType());
}
}
}
else {
this.cachedFieldValue = null;
}
this.cached = true;
}
}
}
if (value != null) {
ReflectionUtils.makeAccessible(field);
// 调用反射进行赋值
field.set(bean, value);
}
}
}
OK,来到解析依赖的关键步骤了.
- 先尝试从缓存中获取该依赖对应的Bean.
- 如果BeanFactory中没有该依赖对应的Bean.为该成员创建一个
DependencyDescriptor,然后调用beanFactory.resolveDependency来加载Bean.- 注册Bean之间的依赖关系.
- 将获取到的Bean调用反射进行填充.
field.set(bean, value),注意在这一步之前,Spring对field的权限进行了设置,field.setAccessible(true)其中,自动装配的逻辑就封装在了
beanFactory.resolveDependency中.继续前进一探究竟.
3.3.2 DefaultListableBeanFactory#resolveDependency
public Object resolveDependency(DependencyDescriptor descriptor, @Nullable String requestingBeanName,
@Nullable Set<String> autowiredBeanNames, @Nullable TypeConverter typeConverter) throws BeansException {
descriptor.initParameterNameDiscovery(getParameterNameDiscoverer());
if (Optional.class == descriptor.getDependencyType()) {
return 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 Jsr330Factory().createDependencyProvider(descriptor, requestingBeanName);
}
else {
Object result = getAutowireCandidateResolver().getLazyResolutionProxyIfNecessary(
descriptor, requestingBeanName);
if (result == null) {
// 解析依赖
result = doResolveDependency(descriptor, requestingBeanName, autowiredBeanNames, typeConverter);
}
return result;
}
}
这里Spring会对依赖做一些适配,我们主要看
doResolveDependency这个解析依赖的方法.
- DefaultListableBeanFactory#doResolveDependency
public Object doResolveDependency(DependencyDescriptor descriptor, @Nullable String beanName,
@Nullable Set<String> autowiredBeanNames, @Nullable TypeConverter typeConverter) throws BeansException {
InjectionPoint previousInjectionPoint = ConstructorResolver.setCurrentInjectionPoint(descriptor);
try {
// 从容器中获取依赖,在debug环境下点进去会发现,会到达beanFactory.getBean()中
Object shortcut = descriptor.resolveShortcut(this);
// 如果可以从容器中获取到bean,直接返回
if (shortcut != null) {
return shortcut;
}
Class<?> type = descriptor.getDependencyType();
// 处理@Value注解
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());
try {
return converter.convertIfNecessary(value, type, descriptor.getTypeDescriptor());
}
catch (UnsupportedOperationException ex) {
// A custom TypeConverter which does not support TypeDescriptor resolution...
return (descriptor.getField() != null ?
converter.convertIfNecessary(value, type, descriptor.getField()) :
converter.convertIfNecessary(value, type, descriptor.getMethodParameter()));
}
}
// 如果标识@Autowired注解的成员变量是复合类型,如:数组、List、Map等.
// 从这里获取@Autowired中的值
Object multipleBeans = resolveMultipleBeans(descriptor, beanName, autowiredBeanNames, typeConverter);
if (multipleBeans != null) {
return multipleBeans;
}
// 如果被@Autowired标注的成员并非复合对象
Map<String, Object> matchingBeans = findAutowireCandidates(beanName, type, descriptor);
if (matchingBeans.isEmpty()) {
// 如果找不到,校验当前是否标注了required为true.
if (isRequired(descriptor)) {
// 如果@Autowired标注了(required = true),但是无法匹配到相应的bean,抛出NoSuchBeanDefinitionException异常
raiseNoMatchingBeanFound(type, descriptor.getResolvableType(), descriptor);
}
return null;
}
String autowiredBeanName;
Object instanceCandidate;
// 如果匹配到了不止一个Bean,看看是否标注了@Primary和@Priority
if (matchingBeans.size() > 1) {
autowiredBeanName = determineAutowireCandidate(matchingBeans, descriptor);
if (autowiredBeanName == null) {
if (isRequired(descriptor) || !indicatesMultipleBeans(type)) {
// 如果没有声明,则直接抛出NoUniqueBeanDefinitionException
return descriptor.resolveNotUnique(descriptor.getResolvableType(), 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();
// key为被依赖的候选者名称,例如:UserController依赖UserService.
// 此时autowiredBeanName=userService
autowiredBeanName = entry.getKey();
// Class,先选举,选举结束之后再进行实例化
instanceCandidate = entry.getValue();
}
if (autowiredBeanNames != null) {
autowiredBeanNames.add(autowiredBeanName);
}
if (instanceCandidate instanceof Class) {
// 将获取到的候选者Class进行getBean
instanceCandidate = descriptor.resolveCandidate(autowiredBeanName, type, this);
}
Object result = instanceCandidate;
if (result instanceof NullBean) {
if (isRequired(descriptor)) {
raiseNoMatchingBeanFound(type, descriptor.getResolvableType(), descriptor);
}
result = null;
}
if (!ClassUtils.isAssignableValue(type, result)) {
throw new BeanNotOfRequiredTypeException(autowiredBeanName, type, instanceCandidate.getClass());
}
return result;
}
finally {
ConstructorResolver.setCurrentInjectionPoint(previousInjectionPoint);
}
}
这里的代码逻辑就跟我们平时编程是息息相关的了。
- 调用
descriptor.resolveShortcut查看当前工厂是否已经加载过相同的Bean,如果是则直接返回.- 处理
@Value解析的逻辑.- 如果当前注入的是复合对象,调用
resolveMultipleBeans.- 如果只是注入普通的Bean对象,查找符合条件的候选名单.返回一个Map.
为什么返回一个Map呢,这是因为一个接口可以有多个实现类,按照类型查找,就会把实现该接口的实现类返回.在应对这种多个候选Bean的时候,Spring会去判断是是否声明了@Primary注解或者@Order注解来决定注入哪个Bean.如果没有声明,再判断是否声明了required=false),如果required为默认的,则抛出NoUniqueBeanDefinitionException异常。- 匹配完候选名单后,对候选名单进行
resolveCandidate操作,点进去方法会发现,其实是调用了beanFactory.getBean(beanName).
什么是复合对象?
Spring不仅仅只可以注入单一的Bean对象,还支持数组、集合、Stream、Map等方式的注入.
3.3.3 如果Autowired按byType的方式无法挑选出最合适的Bean如何进行降级处理
答案在
determineAutowireCandidate中,在通过byType的方式无法选出最合适的Bean后,Spring会用byName的方式对比出当前属性名与候选Bean名单中的candidateName是否匹配来做最终的处理.
- DefaultListableBeanFactory#determineAutowireCandidate
protected String determineAutowireCandidate(Map<String, Object> candidates, DependencyDescriptor descriptor) {
Class<?> requiredType = descriptor.getDependencyType();
// 根据@Primary注解标签来选择最优解
String primaryCandidate = determinePrimaryCandidate(candidates, requiredType);
if (primaryCandidate != null) {
return primaryCandidate;
}
// 根据@Order、@Priority以及实现了Order接口的序号来最合适的Bean(序号越小越合适)进行注入
String priorityCandidate = determineHighestPriorityCandidate(candidates, requiredType);
if (priorityCandidate != null) {
return priorityCandidate;
}
// Fallback
for (Map.Entry<String, Object> entry : candidates.entrySet()) {
String candidateName = entry.getKey();
Object beanInstance = entry.getValue();
// 如果无法通过上面两个方法找到最优解的Bean:
// 如果类型已经在resolvableDependencies中,直接返回已经注册的对象.
// 如果byType的方式找不到,尝试使用byName的方式寻找依赖
// 如果属性名称和某个候选者的Bean名称或者别名一致,则直接将该Bean返回
if ((beanInstance != null && this.resolvableDependencies.containsValue(beanInstance)) ||
matchesBeanName(candidateName, descriptor.getDependencyName())) {
return candidateName;
}
}
return null;
}
假设
UserService有两个实现类,VipUserService的beanName被主动声明为vip,NormalUserService声明为normal,那么你在Controller中可以这样写来注入VipUserService:
@Autowired
UserService vip;
4. 依赖检查
Spring在最新的版本已经不推荐使用,所以这里我们也不做重点讲解.
5. 将解析的值用BeanWrapper进行包装-applyPropertyValues.
通过注解形式配置的Bean并不会往pvs中填充值,笔者在一些书上看到都是重点解析这个方法,目前Spring5.1的版本进行debug未发现进入到这个方法中,所以也不做详细的讲解。我更倾向于这是为了兼容XML的做法留下的方法.
protected void applyPropertyValues(String beanName, BeanDefinition mbd, BeanWrapper bw, PropertyValues pvs) {
if (pvs.isEmpty()) {
return;
}
if (System.getSecurityManager() != null && bw instanceof BeanWrapperImpl) {
((BeanWrapperImpl) bw).setSecurityContext(getAccessControlContext());
}
MutablePropertyValues mpvs = null;
List<PropertyValue> original;
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());
}
TypeConverter converter = getCustomTypeConverter();
if (converter == null) {
converter = bw;
}
BeanDefinitionValueResolver valueResolver = new BeanDefinitionValueResolver(this, beanName, mbd, converter);
// Create a deep copy, resolving any references for values.
List<PropertyValue> deepCopy = new ArrayList<>(original.size());
boolean resolveNecessary = false;
for (PropertyValue pv : original) {
if (pv.isConverted()) {
deepCopy.add(pv);
}
else {
String propertyName = pv.getName();
Object originalValue = pv.getValue();
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);
}
// 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();
}
// 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);
}
}
/**
* Convert the given value for the specified target property.
*/
@Nullable
private Object convertForProperty(
@Nullable Object value, String propertyName, BeanWrapper bw, TypeConverter converter) {
if (converter instanceof BeanWrapperImpl) {
return ((BeanWrapperImpl) converter).convertForProperty(value, propertyName);
}
else {
PropertyDescriptor pd = bw.getPropertyDescriptor(propertyName);
MethodParameter methodParam = BeanUtils.getWriteMethodParameter(pd);
return converter.convertIfNecessary(value, pd.getPropertyType(), methodParam);
}
}
从XML中配置的<bean>将所有的属性声明为了字符串,因此在这里需要做一些类型的解析和强转.核心方法:
- 解析
Object resolvedValue = valueResolver.resolveValueIfNecessary(pv, originalValue);- 注入
bw.setPropertyValues(new MutablePropertyValues(deepCopy));
总结
- 注解驱动的Bean执行属性填充并不在
autowireByName和autowireByType中,而是在AutowiredAnnotationBeanPostProcessor这个后置处理器的postProcessProperties中. - 在做属性填充时,如果当前的Bean实例依赖的成员(另一个Bean)未被加载,会进入选举候选名单的逻辑中,进行各种判断后,选出最适合的Bean实例进行
getBean操作. -
@Autowired在进行自动装配的过程中,默认按照"byType"的方式进行Bean加载,如果出现无法挑选出合适的Bean的情况,再将属性名与候选Bean名单中的beanName进行对比. - 正确地声明
@Primary和Order等注解让Bean在多态的选举中优选胜出. -
required=false可以让程序在找不到Bean的时候不抛出异常,但是调用期间还是会报错(缓兵之计),不建议这种使用. - XML的自动装配模式与注解驱动的模式在代码上是不同的分岔.
