一、前言
在前面的文章中spring源码解读系列(五),我们详解了spring工厂调用BeanFactoryPostProcessors的过程,今天我介绍一下spring工厂中最重要的一个BeanFactoryPostProcessor,即ConfigurationClassPostProcessor,该类是实现spring注解开发的基石,是零配置开发的基础。该类的主要作用是:完成我们常用注解的解析,例如@Configuration,@Bean,@Component,@ComponentScan,@Import,@ImportResource,并将对应的类或者扫描到的类解析成BeanDefinition,注册到BeanFactory工厂中。
二、ConfigurationClassPostProcessor类图
通过类图,主要发现两点:
1.实现了ResourceLoaderAware, BeanClassLoaderAware, EnvironmentAware,完成spring内置对象的设置
2.继承了BeanDefinitionRegistryPostProcessor,根据spring源码解读系列(五)中的分析,在执行BeanFactoryPostProcessor的过程中,会先调用该类的postProcessBeanDefinitionRegistry(BeanDefinitionRegistry registry)方法,然后调用postProcessBeanFactory(ConfigurableListableBeanFactory beanFactory)方法。
三、执行流程图解
四 源码解析processConfigBeanDefinitions
/**
* 构建和验证一个类是否被@Configuration修饰,并做相关的解析工作
*
* 如果你对此方法了解清楚了,那么springboot的自动装配原理就清楚了
*
* Build and validate a configuration model based on the registry of
* {@link Configuration} classes.
*/
public void processConfigBeanDefinitions(BeanDefinitionRegistry registry) {
// 创建存放BeanDefinitionHolder的对象集合,BeanDefinitionHolder是BeanDefinition的包装类
List<BeanDefinitionHolder> configCandidates = new ArrayList<>();
// 当前registry就是DefaultListableBeanFactory,获取所有已经注册的BeanDefinition的beanName
String[] candidateNames = registry.getBeanDefinitionNames();
// 遍历所有要处理的beanDefinition的名称,筛选对应的beanDefinition(被注解修饰的)
for (String beanName : candidateNames) {
// 获取指定名称的BeanDefinition对象
BeanDefinition beanDef = registry.getBeanDefinition(beanName);
// 如果beanDefinition中的configurationClass属性不等于空,那么意味着已经处理过,输出日志信息
if (beanDef.getAttribute(ConfigurationClassUtils.CONFIGURATION_CLASS_ATTRIBUTE) != null) {
if (logger.isDebugEnabled()) {
logger.debug("Bean definition has already been processed as a configuration class: " + beanDef);
}
}
// 判断当前BeanDefinition是否是一个配置类,并为BeanDefinition设置属性为lite或者full,此处设置属性值是为了后续进行调用
// 如果Configuration配置proxyBeanMethods代理为true则为full
// 如果加了@Bean、@Component、@ComponentScan、@Import、@ImportResource注解,则设置为lite
// 如果配置类上被@Order注解标注,则设置BeanDefinition的order属性值
else if (ConfigurationClassUtils.checkConfigurationClassCandidate(beanDef, this.metadataReaderFactory)) {
// 添加到对应的集合对象中
configCandidates.add(new BeanDefinitionHolder(beanDef, beanName));
}
}
// Return immediately if no @Configuration classes were found
// 如果没有发现任何配置类,则直接返回
if (configCandidates.isEmpty()) {
return;
}
// Sort by previously determined @Order value, if applicable
// 如果适用,则按照先前确定的@Order的值排序
configCandidates.sort((bd1, bd2) -> {
int i1 = ConfigurationClassUtils.getOrder(bd1.getBeanDefinition());
int i2 = ConfigurationClassUtils.getOrder(bd2.getBeanDefinition());
return Integer.compare(i1, i2);
});
// Detect any custom bean name generation strategy supplied through the enclosing application context
// 判断当前类型是否是SingletonBeanRegistry类型
SingletonBeanRegistry sbr = null;
if (registry instanceof SingletonBeanRegistry) {
// 类型的强制转换
sbr = (SingletonBeanRegistry) registry;
// 判断是否有自定义的beanName生成器
if (!this.localBeanNameGeneratorSet) {
// 获取自定义的beanName生成器
BeanNameGenerator generator = (BeanNameGenerator) sbr.getSingleton(
AnnotationConfigUtils.CONFIGURATION_BEAN_NAME_GENERATOR);
// 如果有自定义的命名生成策略
if (generator != null) {
//设置组件扫描的beanName生成策略
this.componentScanBeanNameGenerator = generator;
// 设置import bean name生成策略
this.importBeanNameGenerator = generator;
}
}
}
// 如果环境对象等于空,那么就重新创建新的环境对象
if (this.environment == null) {
this.environment = new StandardEnvironment();
}
// Parse each @Configuration class
// 实例化ConfigurationClassParser类,并初始化相关的参数,完成配置类的解析工作
ConfigurationClassParser parser = new ConfigurationClassParser(
this.metadataReaderFactory, this.problemReporter, this.environment,
this.resourceLoader, this.componentScanBeanNameGenerator, registry);
// 创建两个集合对象,
// 存放相关的BeanDefinitionHolder对象
Set<BeanDefinitionHolder> candidates = new LinkedHashSet<>(configCandidates);
// 存放扫描包下的所有bean
Set<ConfigurationClass> alreadyParsed = new HashSet<>(configCandidates.size());
do {
// 解析带有@Controller、@Import、@ImportResource、@ComponentScan、@ComponentScans、@Bean的BeanDefinition
parser.parse(candidates);
// 将解析完的Configuration配置类进行校验,1、配置类不能是final,2、@Bean修饰的方法必须可以重写以支持CGLIB
parser.validate();
// 获取所有的bean,包括扫描的bean对象,@Import导入的bean对象
Set<ConfigurationClass> configClasses = new LinkedHashSet<>(parser.getConfigurationClasses());
// 清除掉已经解析处理过的配置类
configClasses.removeAll(alreadyParsed);
// Read the model and create bean definitions based on its content
// 判断读取器是否为空,如果为空的话,就创建完全填充好的ConfigurationClass实例的读取器
if (this.reader == null) {
this.reader = new ConfigurationClassBeanDefinitionReader(
registry, this.sourceExtractor, this.resourceLoader, this.environment,
this.importBeanNameGenerator, parser.getImportRegistry());
}
// 核心方法,将完全填充好的ConfigurationClass实例转化为BeanDefinition注册入IOC容器
this.reader.loadBeanDefinitions(configClasses);
// 添加到已经处理的集合中
alreadyParsed.addAll(configClasses);
candidates.clear();
// 这里判断registry.getBeanDefinitionCount() > candidateNames.length的目的是为了知道reader.loadBeanDefinitions(configClasses)这一步有没有向BeanDefinitionMap中添加新的BeanDefinition
// 实际上就是看配置类(例如AppConfig类会向BeanDefinitionMap中添加bean)
// 如果有,registry.getBeanDefinitionCount()就会大于candidateNames.length
// 这样就需要再次遍历新加入的BeanDefinition,并判断这些bean是否已经被解析过了,如果未解析,需要重新进行解析
// 这里的AppConfig类向容器中添加的bean,实际上在parser.parse()这一步已经全部被解析了
if (registry.getBeanDefinitionCount() > candidateNames.length) {
String[] newCandidateNames = registry.getBeanDefinitionNames();
Set<String> oldCandidateNames = new HashSet<>(Arrays.asList(candidateNames));
Set<String> alreadyParsedClasses = new HashSet<>();
for (ConfigurationClass configurationClass : alreadyParsed) {
alreadyParsedClasses.add(configurationClass.getMetadata().getClassName());
}
// 如果有未解析的类,则将其添加到candidates中,这样candidates不为空,就会进入到下一次的while的循环中
for (String candidateName : newCandidateNames) {
if (!oldCandidateNames.contains(candidateName)) {
BeanDefinition bd = registry.getBeanDefinition(candidateName);
if (ConfigurationClassUtils.checkConfigurationClassCandidate(bd, this.metadataReaderFactory) &&
!alreadyParsedClasses.contains(bd.getBeanClassName())) {
candidates.add(new BeanDefinitionHolder(bd, candidateName));
}
}
}
candidateNames = newCandidateNames;
}
}
while (!candidates.isEmpty());
// Register the ImportRegistry as a bean in order to support ImportAware @Configuration classes
if (sbr != null && !sbr.containsSingleton(IMPORT_REGISTRY_BEAN_NAME)) {
sbr.registerSingleton(IMPORT_REGISTRY_BEAN_NAME, parser.getImportRegistry());
}
if (this.metadataReaderFactory instanceof CachingMetadataReaderFactory) {
// Clear cache in externally provided MetadataReaderFactory; this is a no-op
// for a shared cache since it'll be cleared by the ApplicationContext.
((CachingMetadataReaderFactory) this.metadataReaderFactory).clearCache();
}
}
五、源码解析doProcessConfigurationClass
通过执行流程图,我们可以发现,解析注解的核心方法主要是ConfigurationClassParser.parse方法,这个方法的调用流程如图:
我们分析下核心方法ConfigurationClassParser.doProcessConfigurationClass的源码
@Nullable
protected final SourceClass doProcessConfigurationClass(
ConfigurationClass configClass, SourceClass sourceClass, Predicate<String> filter)
throws IOException {
// @Configuration继承了@Component
if (configClass.getMetadata().isAnnotated(Component.class.getName())) {
// Recursively process any member (nested) classes first
// 递归处理内部类,因为内部类也是一个配置类,配置类上有@configuration注解,该注解继承@Component,if判断为true,调用processMemberClasses方法,递归解析配置类中的内部类
processMemberClasses(configClass, sourceClass, filter);
}
// Process any @PropertySource annotations
// 如果配置类上加了@PropertySource注解,那么就解析加载properties文件,并将属性添加到spring上下文中
for (AnnotationAttributes propertySource : AnnotationConfigUtils.attributesForRepeatable(
sourceClass.getMetadata(), PropertySources.class,
org.springframework.context.annotation.PropertySource.class)) {
if (this.environment instanceof ConfigurableEnvironment) {
processPropertySource(propertySource);
}
else {
logger.info("Ignoring @PropertySource annotation on [" + sourceClass.getMetadata().getClassName() +
"]. Reason: Environment must implement ConfigurableEnvironment");
}
}
// Process any @ComponentScan annotations
// 处理@ComponentScan或者@ComponentScans注解,并将扫描包下的所有bean转换成填充后的ConfigurationClass
// 此处就是将自定义的bean加载到IOC容器,因为扫描到的类可能也添加了@ComponentScan和@ComponentScans注解,因此需要进行递归解析
Set<AnnotationAttributes> componentScans = AnnotationConfigUtils.attributesForRepeatable(
sourceClass.getMetadata(), ComponentScans.class, ComponentScan.class);
if (!componentScans.isEmpty() &&
!this.conditionEvaluator.shouldSkip(sourceClass.getMetadata(), ConfigurationPhase.REGISTER_BEAN)) {
for (AnnotationAttributes componentScan : componentScans) {
// The config class is annotated with @ComponentScan -> perform the scan immediately
// 解析@ComponentScan和@ComponentScans配置的扫描的包所包含的类
// 比如 basePackages = com.mashibing, 那么在这一步会扫描出这个包及子包下的class,然后将其解析成BeanDefinition
// (BeanDefinition可以理解为等价于BeanDefinitionHolder)
Set<BeanDefinitionHolder> scannedBeanDefinitions =
this.componentScanParser.parse(componentScan, sourceClass.getMetadata().getClassName());
// Check the set of scanned definitions for any further config classes and parse recursively if needed
// 通过上一步扫描包com.mashibing,有可能扫描出来的bean中可能也添加了ComponentScan或者ComponentScans注解.
//所以这里需要循环遍历一次,进行递归(parse),继续解析,直到解析出的类上没有ComponentScan和ComponentScans
for (BeanDefinitionHolder holder : scannedBeanDefinitions) {
BeanDefinition bdCand = holder.getBeanDefinition().getOriginatingBeanDefinition();
if (bdCand == null) {
bdCand = holder.getBeanDefinition();
}
// 判断是否是一个配置类,并设置full或lite属性
if (ConfigurationClassUtils.checkConfigurationClassCandidate(bdCand, this.metadataReaderFactory)) {
// 通过递归方法进行解析
parse(bdCand.getBeanClassName(), holder.getBeanName());
}
}
}
}
// Process any @Import annotations
// 处理@Import注解
processImports(configClass, sourceClass, getImports(sourceClass), filter, true);
// Process any @ImportResource annotations
// 处理@ImportResource注解,导入spring的配置文件
AnnotationAttributes importResource =
AnnotationConfigUtils.attributesFor(sourceClass.getMetadata(), ImportResource.class);
if (importResource != null) {
String[] resources = importResource.getStringArray("locations");
Class<? extends BeanDefinitionReader> readerClass = importResource.getClass("reader");
for (String resource : resources) {
String resolvedResource = this.environment.resolveRequiredPlaceholders(resource);
configClass.addImportedResource(resolvedResource, readerClass);
}
}
// Process individual @Bean methods
// 处理加了@Bean注解的方法,将@Bean方法转化为BeanMethod对象,保存再集合中
Set<MethodMetadata> beanMethods = retrieveBeanMethodMetadata(sourceClass);
for (MethodMetadata methodMetadata : beanMethods) {
configClass.addBeanMethod(new BeanMethod(methodMetadata, configClass));
}
// Process default methods on interfaces
// 处理接口的默认方法实现,从jdk8开始,接口中的方法可以有自己的默认实现,因此如果这个接口的方法加了@Bean注解,也需要被解析
processInterfaces(configClass, sourceClass);
// Process superclass, if any
// 解析父类,如果被解析的配置类继承了某个类,那么配置类的父类也会被进行解析
if (sourceClass.getMetadata().hasSuperClass()) {
String superclass = sourceClass.getMetadata().getSuperClassName();
if (superclass != null && !superclass.startsWith("java") &&
!this.knownSuperclasses.containsKey(superclass)) {
this.knownSuperclasses.put(superclass, configClass);
// Superclass found, return its annotation metadata and recurse
return sourceClass.getSuperClass();
}
}
// No superclass -> processing is complete
return null;
}