引言
本文主要梳理了Spring框架Bean创建过程中应对循环依赖问题的相关源码。我在手写super-mini-webpack的时候也介绍过解决循环依赖的算法:Map+记忆化搜索。可以猜测这段源码也实现了这个算法,所以在看这段源码的时候,我们可以先找到递归点,再去分析调用栈涉及的那些函数,顺便找出其用到的Map数据结构。
本文所用工程,工程创建方式:用VSCode插件Spring Initializr Java Support
,ctrl + shift + P
,Spring Initializr: Create a Maven Project
。具体看参考链接1。
-
JDK Version:17
-
SpringBoot Version:3.1.2
-
Spring Version:6.0.11
作者:hans774882968以及hans774882968以及hans774882968
本文CSDN
本文juejin
本文52pojie:https://www.52pojie.cn/thread-1814835-1-1.html
三级缓存数据结构简介
三级缓存数据结构定义和操作三级缓存的函数都位于:spring-beans/src/main/java/org/springframework/beans/factory/support/DefaultSingletonBeanRegistry.java
/** Cache of singleton objects: bean name to bean instance. */
private final Map<String, Object> singletonObjects = new ConcurrentHashMap<>(256);
/** Cache of singleton factories: bean name to ObjectFactory. */
private final Map<String, ObjectFactory<?>> singletonFactories = new HashMap<>(16);
/** Cache of early singleton objects: bean name to bean instance. */
private final Map<String, Object> earlySingletonObjects = new ConcurrentHashMap<>(16);
缓存先找到第1级,第1级没有才查第2级,依此类推。singletonObjects, earlySingletonObjects, singletonFactories
分别是1到3级。第1级缓存是bean名到成品bean的映射;第2级缓存是bean名到半成品bean的映射;第3级缓存是bean名到函数式接口的映射,作用为延迟调用函数。
@FunctionalInterface
public interface ObjectFactory<T> {
/**
* Return an instance (possibly shared or independent)
* of the object managed by this factory.
* @return the resulting instance
* @throws BeansException in case of creation errors
*/
T getObject() throws BeansException;
}
第3级缓存的Value里的函数的调用方式就是调用.getObject()
。
为什么需要2级缓存?因为要体现一个分层的思想,半成品bean原则上是不能暴露到外部的。TODO:外部是指?这里我没研究清楚,就先引用了52pojie@特别的你~
大佬的解释。“防止线程切换时,其他线程取到半成品bean”,我觉得很有道理。
外部可能是调用spring容器中BEAN的其他参与者?有些应用启动时(如果懒加载将会是使用时)极其复杂,如果多线程调用将会出现问题(2级缓存加锁是防止多线程创建,这里指该BEAN如果没有创建好,而且只有一个容器,那么其他线程就会使用到,认为是完整的BEAN)。
为什么需要第3级缓存?如果所有bean都没有代理对象就不需要第3级缓存。TODO:补充说明。
源码阅读
如何启动调试?
新建一个普通的SpringBoot项目。然后可以尝试通过xml配置文件和注解等方式构造循环引用。后文称为场景1和场景2。
场景1:通过xml配置文件来构造循环引用
入口src\main\java\com\hans\bean_dependency_cycle\HansApplication.java
:
package com.hans.bean_dependency_cycle;
import org.springframework.boot.autoconfigure.SpringBootApplication;
import org.springframework.context.support.AbstractApplicationContext;
import org.springframework.context.support.ClassPathXmlApplicationContext;
@SpringBootApplication
public class HansApplication {
public static void main(String[] args) {
AbstractApplicationContext ac = new ClassPathXmlApplicationContext("cycle.xml");
A beanA = ac.getBean(A.class);
System.out.println(beanA);
System.out.println(beanA.getB());
B beanB = ac.getBean(B.class);
System.out.println(beanB);
System.out.println(beanB.getA());
ac.close();
}
}
src\main\resources\cycle.xml
:
<?xml version="1.0" encoding="UTF-8"?>
<beans
xmlns="http://www.springframework.org/schema/beans"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xmlns:context="http://www.springframework.org/schema/context"
xmlns:mvc="http://www.springframework.org/schema/mvc"
xmlns:p="http://www.springframework.org/schema/p"
xsi:schemaLocation="http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd
http://www.springframework.org/schema/context http://www.springframework.org/schema/context/spring-context.xsd
http://www.springframework.org/schema/mvc http://www.springframework.org/schema/mvc/spring-mvc.xsd
"
>
<bean id="a" class="com.hans.bean_dependency_cycle.A">
<property name="b" ref="b"></property>
</bean>
<bean id="b" class="com.hans.bean_dependency_cycle.B">
<property name="a" ref="a"></property>
</bean>
</beans>
A.java
和B.java
:
// A 和 B 不能都使用 lombok,否则无法打印。这里选择了 B 不使用 lombok
package com.hans.bean_dependency_cycle;
import lombok.Data;
@Data
public class A {
private B b;
public String toString(A o) {
return o.getClass().getName() + "@" +
Integer.toHexString(System.identityHashCode(o));
}
}
package com.hans.bean_dependency_cycle;
public class B {
private A a;
public A getA() {
return this.a;
}
public void setA(A a) {
this.a = a;
}
}
期望输出:
A(b=com.hans.bean_dependency_cycle.B@750e2b97)
com.hans.bean_dependency_cycle.B@750e2b97
com.hans.bean_dependency_cycle.B@750e2b97
A(b=com.hans.bean_dependency_cycle.B@750e2b97)
场景1不需要配置spring.main.allow-circular-references
为true也能得到期望输出,TODO:原因未知。
【Optional】顺便补充一下场景1的单测src\test\java\com\hans\bean_dependency_cycleApplicationTests.java
:
package com.hans.bean_dependency_cycle;
import org.junit.jupiter.api.Assertions;
import org.junit.jupiter.api.Test;
import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.boot.test.context.SpringBootTest;
import org.springframework.context.ApplicationContext;
import org.springframework.test.context.ContextConfiguration;
// 自动收集 cycle.xml 的 bean
@ContextConfiguration(locations = { "classpath:cycle.xml" })
@SpringBootTest(classes = HansApplication.class)
class HansApplicationTests {
@Autowired
ApplicationContext ac;
@Test
void contextLoads() {
A beanA = ac.getBean(A.class);
Assertions.assertNotNull(beanA);
B beanB = ac.getBean(B.class);
Assertions.assertNotNull(beanB);
Assertions.assertEquals(beanA, beanB.getA());
Assertions.assertEquals(beanB, beanA.getB());
}
}
场景2:通过注解+自动装配属性来构造循环引用:以@Controller
为例
入口src\main\java\com\hans\bean_dependency_cycle\AnotherEntry.java
:
package com.hans.bean_dependency_cycle;
import org.springframework.boot.SpringApplication;
import org.springframework.boot.autoconfigure.SpringBootApplication;
import org.springframework.boot.autoconfigure.jdbc.DataSourceAutoConfiguration;
import org.springframework.context.ConfigurableApplicationContext;
@SpringBootApplication(exclude = { DataSourceAutoConfiguration.class })
public class AnotherEntry {
public static void main(String[] args) {
ConfigurableApplicationContext cac = SpringApplication.run(AnotherEntry.class, args);
ControllerA beanA = cac.getBean(ControllerA.class);
System.out.println(beanA);
System.out.println(beanA.getCb());
ControllerB beanB = cac.getBean(ControllerB.class);
System.out.println(beanB);
System.out.println(beanB.getCa());
}
}
根据参考链接2,接下来一定要记得修改application.yml
:
spring:
main:
allow-circular-references: true
否则会报错:
***************************
APPLICATION FAILED TO START
***************************
Description:
The dependencies of some of the beans in the application context form a cycle:
┌─────┐
| controllerA (field private com.hans.bean_dependency_cycle.ControllerB com.hansn_dependency_cycle.hans.ControllerA.cb)
↑ ↓
| controllerB (field private com.hans.bean_dependency_cycle.ControllerA com.hansn_dependency_cycle.hans.ControllerB.ca)
└─────┘
Action:
Relying upon circular references is discouraged and they are prohibited by default. Up your application to remove the dependency cycle between beans. As a last resort, it me possible to break the cycle automatically by setting spring.main.allow-circular-refees to true.
两个普通的Controller:
// src\main\java\com\hans\bean_dependency_cycle\ControllerA.java
package com.hans.bean_dependency_cycle;
import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.web.bind.annotation.RequestMapping;
import org.springframework.web.bind.annotation.RestController;
@RestController
public class ControllerA {
@Autowired
private ControllerB cb;
public ControllerB getCb() {
return cb;
}
@RequestMapping("/controllerA")
public String index() {
return "hello controllerA!";
}
}
// src\main\java\com\hans\bean_dependency_cycle\ControllerB.java
package com.hans.bean_dependency_cycle;
import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.web.bind.annotation.RequestMapping;
import org.springframework.web.bind.annotation.RestController;
@RestController
public class ControllerB {
@Autowired
private ControllerA ca;
public ControllerA getCa() {
return ca;
}
@RequestMapping("/controllerB")
public String index() {
return "hello controllerB!";
}
}
期望输出:
com.hans.bean_dependency_cycle.ControllerA@39f82681
com.hans.bean_dependency_cycle.ControllerB@4bd9e7fd
com.hans.bean_dependency_cycle.ControllerB@4bd9e7fd
com.hans.bean_dependency_cycle.ControllerA@39f82681
【Optional】顺便补充一下场景2的单测src\test\java\com\hans\bean_dependency_cycle\AnotherEntryTests.java
package com.hans.bean_dependency_cycle;
import org.junit.jupiter.api.Assertions;
import org.junit.jupiter.api.Test;
import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.boot.test.context.SpringBootTest;
@SpringBootTest(classes = AnotherEntry.class)
class AnotherEntryTests {
@Autowired
ControllerA ca;
@Autowired
ControllerB cb;
@Test
void contextLoads() {
Assertions.assertNotNull(ca);
Assertions.assertNotNull(cb);
Assertions.assertEquals(ca, cb.getCa());
Assertions.assertEquals(cb, ca.getCb());
}
}
脉络
根据参考链接3,有一个经验:“do”开头的方法名是真正含有大量逻辑的方法。参考链接3Java之父精选的脉络函数如下:
getBean
doGetBean
createBean
doCreateBean
createBeanInstance
populateBean
场景1到递归点为止的调用链:preInstantiateSingletons > getBean > doGetBean > getSingleton函数有多个,其中调用了beforeSingletonCreation的函数调用singletonFactory.getObject()时才真正调用了createBean > createBean > doCreateBean > createBeanInstance, populateBean 都在 doCreateBean 的实现里 > populateBean调用了applyPropertyValues > resolveValueIfNecessary > resolveReference > getBean
。
场景2的调用链到populateBean
开始和场景1的调用链岔开,两个场景的差异放在后文《Controller和普通Bean解决循环依赖过程的相同点与不同点》分析。
场景1递归到A -> B -> A
时的调用链:getBean > doGetBean > 未调用beforeSingletonCreation的getSingleton,操作第2级缓存后离开
。
操作三级缓存的函数都位于https://github.com/spring-projects/spring-framework/blob/502997d8e986dcfde1f49b2b2f443a32b5488b13/spring-beans/src/main/java/org/springframework/beans/factory/support/DefaultSingletonBeanRegistry.java
:
- 放入第3级缓存的函数:
doCreateBean
调用的addSingletonFactory
。
- 放入第2级缓存的函数:首先要知道
getSingleton
在DefaultSingletonBeanRegistry.java
里本质上的实现有两个,一个public Object getSingleton(String beanName, ObjectFactory<?> singletonFactory)
调用了beforeSingletonCreation
并间接调用了createBean
;另一个protected Object getSingleton(String beanName, boolean allowEarlyReference)
则是操作了第2级缓存。
- 放入第1级缓存的函数:
addSingleton
。在间接调用了createBean
函数的getSingleton
处调用。
场景1的执行过程
真正意义上的入口:spring-context/src/main/java/org/springframework/context/support/AbstractApplicationContext.java的beanFactory.preInstantiateSingletons();
。这里的beanFactory
就有singletonObjects
那3级缓存的对象。于是跳到https://github.com/spring-projects/spring-framework/blob/bbde68c49e66c3c531920cb80a55742262507be7/spring-beans/src/main/java/org/springframework/beans/factory/support/DefaultListableBeanFactory.java
:
@Override
public void preInstantiateSingletons() throws BeansException {
if (logger.isTraceEnabled()) {
logger.trace("Pre-instantiating singletons in " + this);
}
// 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<>(this.beanDefinitionNames);
// 触发所有非延迟加载的(non-lazy)单例 bean 的初始化
// Trigger initialization of all non-lazy singleton beans...
for (String beanName : beanNames) {
// 假如先遍历 A 再遍历 B 那么遍历到 B 的时候,因为循环引用解决的关系,B 已经放到了第1级缓存,所以 doGetBean 的 getSingleton 可以直接从第1级缓存取到值,不用再走一遍 createBean 方法
// 合并父类 BeanDefinition
RootBeanDefinition bd = getMergedLocalBeanDefinition(beanName);
// 非抽象、是单例、非懒加载
if (!bd.isAbstract() && bd.isSingleton() && !bd.isLazyInit()) {
// 如果实现了 FactoryBean 接口则是 FactoryBean
if (isFactoryBean(beanName)) {
Object bean = getBean(FACTORY_BEAN_PREFIX + beanName); // 比如:FACTORY_BEAN_PREFIX + beanName = "&A"
if (bean instanceof SmartFactoryBean<?> smartFactoryBean && smartFactoryBean.isEagerInit()) {
getBean(beanName);
}
}
else {
// 不是 FactoryBean,只是普通 Bean,则走这个分支
getBean(beanName);
}
}
}
// 触发所有 SmartInitializingSingleton 的后初始化回调
// Trigger post-initialization callback for all applicable beans...
for (String beanName : beanNames) {
Object singletonInstance = getSingleton(beanName);
if (singletonInstance instanceof SmartInitializingSingleton smartSingleton) {
StartupStep smartInitialize = getApplicationStartup().start("spring.beans.smart-initialize")
.tag("beanName", beanName);
smartSingleton.afterSingletonsInstantiated();
smartInitialize.end();
}
}
}
顺便看下isFactoryBean
的实现https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractBeanFactory.java
:
@Override
public boolean isFactoryBean(String name) throws NoSuchBeanDefinitionException {
String beanName = transformedBeanName(name);
Object beanInstance = getSingleton(beanName, false);
if (beanInstance != null) {
return (beanInstance instanceof FactoryBean);
}
// No singleton instance found -> check bean definition.
if (!containsBeanDefinition(beanName) && getParentBeanFactory() instanceof ConfigurableBeanFactory cbf) {
// No bean definition found in this factory -> delegate to parent.
return cbf.isFactoryBean(name);
}
return isFactoryBean(beanName, getMergedLocalBeanDefinition(beanName));
}
getBean
和isFactoryBean
都位于https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractBeanFactory.java
,getBean
只有1行
@Override
public Object getBean(String name) throws BeansException {
return doGetBean(name, null, null, false);
}
doGetBean
和getBean, isFactoryBean
都在AbstractBeanFactory.java
:
/**
* Return an instance, which may be shared or independent, of the specified bean.
* @param name the name of the bean to retrieve
* @param requiredType the required type of the bean to retrieve
* @param args arguments to use when creating a bean instance using explicit arguments
* (only applied when creating a new instance as opposed to retrieving an existing one)
* @param typeCheckOnly whether the instance is obtained for a type check,
* not for actual use
* @return an instance of the bean
* @throws BeansException if the bean could not be created
*/
@SuppressWarnings("unchecked")
protected <T> T doGetBean(
String name, @Nullable Class<T> requiredType, @Nullable Object[] args, boolean typeCheckOnly)
throws BeansException {
String beanName = transformedBeanName(name);
Object beanInstance;
// 提前检查单例缓存中是否有手动注册的单例对象,跟循环依赖有关。如果是初次进这里,比如 controllerA 初次进这个方法,肯定是拿不到值的,就会是 null
// 对于最简单的循环依赖,controllerA -> controllerB -> controllerA 之后,需要进入 getSingleton 了,这里的逻辑就是要从第3级缓存里拿到工厂函数,调用后得到 controllerA 半成品,从而可以直接 return
// Eagerly check singleton cache for manually registered singletons.
Object sharedInstance = getSingleton(beanName);
if (sharedInstance != null && args == null) {
if (logger.isTraceEnabled()) {
if (isSingletonCurrentlyInCreation(beanName)) {
logger.trace("Returning eagerly cached instance of singleton bean '" + beanName +
"' that is not fully initialized yet - a consequence of a circular reference");
}
else {
logger.trace("Returning cached instance of singleton bean '" + beanName + "'");
}
}
beanInstance = getObjectForBeanInstance(sharedInstance, name, beanName, null);
}
else {
// Fail if we're already creating this bean instance:
// We're assumably within a circular reference.
if (isPrototypeCurrentlyInCreation(beanName)) {
throw new BeanCurrentlyInCreationException(beanName);
}
// Check if bean definition exists in this factory.
BeanFactory parentBeanFactory = getParentBeanFactory();
if (parentBeanFactory != null && !containsBeanDefinition(beanName)) {
// Not found -> check parent.
String nameToLookup = originalBeanName(name);
if (parentBeanFactory instanceof AbstractBeanFactory abf) {
return abf.doGetBean(nameToLookup, requiredType, args, typeCheckOnly);
}
else if (args != null) {
// Delegation to parent with explicit args.
return (T) parentBeanFactory.getBean(nameToLookup, args);
}
else if (requiredType != null) {
// No args -> delegate to standard getBean method.
return parentBeanFactory.getBean(nameToLookup, requiredType);
}
else {
return (T) parentBeanFactory.getBean(nameToLookup);
}
}
if (!typeCheckOnly) {
markBeanAsCreated(beanName);
}
StartupStep beanCreation = this.applicationStartup.start("spring.beans.instantiate")
.tag("beanName", name);
try {
if (requiredType != null) {
beanCreation.tag("beanType", requiredType::toString);
}
RootBeanDefinition mbd = getMergedLocalBeanDefinition(beanName);
checkMergedBeanDefinition(mbd, beanName, args);
// Guarantee initialization of beans that the current bean depends on.
String[] dependsOn = mbd.getDependsOn();
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);
}
}
}
// Create bean instance.
if (mbd.isSingleton()) {
// 返回 beanName 的原始单例对象。如果尚未注册,则使用 singletonFactory 创建并注册一个对象
sharedInstance = getSingleton(beanName, () -> {
try {
// 为给定的合并后的 BeanDefinition 和参数创建一个 bean 实例
// createBean 真实执行时机是调用了 beforeSingletonCreation 方法的 getSingleton 方法执行 singletonObject = singletonFactory.getObject() 时
// 首次运行到 beanName = "controllerA" 时 args = null
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.
// 显式地从单例缓存中删除bean实例:因为这个实例可能是由创建过程急切地放在那里的,放在那里的目的是允许循环引用解析。
// 还要删除所有被这个bean临时引用的所有bean。如果找到相应的一次性bean实例,则委托给 destroyBean
destroySingleton(beanName);
throw ex;
}
});
beanInstance = 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);
}
beanInstance = getObjectForBeanInstance(prototypeInstance, name, beanName, mbd);
}
else {
String scopeName = mbd.getScope();
if (!StringUtils.hasLength(scopeName)) {
throw new IllegalStateException("No scope name defined for bean '" + beanName + "'");
}
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, () -> {
beforePrototypeCreation(beanName);
try {
return createBean(beanName, mbd, args);
}
finally {
afterPrototypeCreation(beanName);
}
});
beanInstance = getObjectForBeanInstance(scopedInstance, name, beanName, mbd);
}
catch (IllegalStateException ex) {
throw new ScopeNotActiveException(beanName, scopeName, ex);
}
}
}
catch (BeansException ex) {
beanCreation.tag("exception", ex.getClass().toString());
beanCreation.tag("message", String.valueOf(ex.getMessage()));
cleanupAfterBeanCreationFailure(beanName);
throw ex;
}
finally {
beanCreation.end();
}
}
return adaptBeanInstance(name, beanInstance, requiredType);
}
我们先只关注createBean
,所以需要关注getSingleton
。注意:
getSingleton
的函数在DefaultSingletonBeanRegistry.java
里本质上的实现有两个,一个调用了beforeSingletonCreation
并间接调用了createBean
;另一个则是操作了第2级缓存。
所以目前我们需要关注的是调用了beforeSingletonCreation
的getSingleton
方法。路径:https://github.com/spring-projects/spring-framework/blob/502997d8e986dcfde1f49b2b2f443a32b5488b13/spring-beans/src/main/java/org/springframework/beans/factory/support/DefaultSingletonBeanRegistry.java
/**
* Return the (raw) singleton object registered under the given name,
* creating and registering a new one if none registered yet.
* @param beanName the name of the bean
* @param singletonFactory the ObjectFactory to lazily create the singleton
* with, if necessary
* @return the registered singleton object
*/
public Object getSingleton(String beanName, ObjectFactory<?> singletonFactory) {
Assert.notNull(beanName, "Bean name must not be null");
synchronized (this.singletonObjects) {
Object singletonObject = this.singletonObjects.get(beanName);
if (singletonObject == null) {
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 + "'");
}
// 创建单例前的回调,默认实现为:将单例注册为当前正在创建中,实现只有3行,可以看下。
beforeSingletonCreation(beanName);
// flag 表示是否生成了新的单例对象
boolean newSingleton = false;
// flag 表示是否有抑制异常的记录,true表示没有
boolean recordSuppressedExceptions = (this.suppressedExceptions == null);
if (recordSuppressedExceptions) {
// 若没有抑制异常记录,则对抑制异常列表进行初始化
this.suppressedExceptions = new LinkedHashSet<>();
}
try {
// 从单例工厂获取对象。注意 singletonFactory 是本方法第二个参数,之前也介绍了
// ObjectFactory 对象通过调 getObject 来正式执行函数,所以 createBean 在此时才真正执行
singletonObject = singletonFactory.getObject();
// 获取后,就已经生成了新的单例对象,标记为 true
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;
}
afterSingletonCreation(beanName);
}
if (newSingleton) {
// 操作第1级缓存
addSingleton(beanName, singletonObject);
}
}
return singletonObject;
}
}
在调用singletonObject = singletonFactory.getObject();
以间接调用createBean
后,会调用addSingleton
,将bean加入第1级缓存,这标志着bean变为成品。接下来我们看下addSingleton
的代码,它和getSingleton
定义于同一个文件。
/**
* Add the given singleton object to the singleton cache of this factory.
* <p>To be called for eager registration of singletons.
* @param beanName the name of the bean
* @param singletonObject the singleton object
*/
protected void addSingleton(String beanName, Object singletonObject) {
// addSingleton 在调用了 createBean 的 getSingleton 方法中被调用,标志着 bean 变为成品对象
synchronized (this.singletonObjects) {
// 第1级缓存添加,第2、3级缓存移除
this.singletonObjects.put(beanName, singletonObject);
this.singletonFactories.remove(beanName);
this.earlySingletonObjects.remove(beanName);
// 添加到已注册的单例集合。 registeredSingletons 为 Set<String>
this.registeredSingletons.add(beanName);
}
}
接下来看createBean
。https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractAutowireCapableBeanFactory.java
/**
* Central method of this class: creates a bean instance,
* populates the bean instance, applies post-processors, etc.
* @see #doCreateBean
*/
@Override
protected Object createBean(String beanName, RootBeanDefinition mbd, @Nullable Object[] args)
throws BeanCreationException {
// 首次看源码,直接看 doCreateBean 调用处
if (logger.isTraceEnabled()) {
logger.trace("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.
Class<?> resolvedClass = resolveBeanClass(mbd, beanName);
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 {
// Give BeanPostProcessors a chance to return a proxy instead of the target bean instance.
Object bean = resolveBeforeInstantiation(beanName, mbdToUse);
if (bean != null) {
return bean;
}
}
catch (Throwable ex) {
throw new BeanCreationException(mbdToUse.getResourceDescription(), beanName,
"BeanPostProcessor before instantiation of bean failed", ex);
}
try {
// 实际创建 bean
Object beanInstance = doCreateBean(beanName, mbdToUse, args);
if (logger.isTraceEnabled()) {
logger.trace("Finished creating instance of bean '" + beanName + "'");
}
return beanInstance;
}
catch (BeanCreationException | ImplicitlyAppearedSingletonException ex) {
// A previously detected exception with proper bean creation context already,
// or illegal singleton state to be communicated up to DefaultSingletonBeanRegistry.
throw ex;
}
catch (Throwable ex) {
throw new BeanCreationException(
mbdToUse.getResourceDescription(), beanName, "Unexpected exception during bean creation", ex);
}
}
createBean
目前唯一值得关注的点就是调用了doCreateBean
。doCreateBean
做了几件值得本文关注的事:
- 调用了
createBeanInstance
完成bean的实例化。
- 调用了
addSingletonFactory
,即加入了第3级缓存。
- 调用了
populateBean
完成bean的属性赋值操作。
doCreateBean
和createBean
都定义在https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractAutowireCapableBeanFactory.java
。
/**
* Actually create the specified bean. Pre-creation processing has already happened
* at this point, e.g. checking {@code postProcessBeforeInstantiation} callbacks.
* <p>Differentiates between default bean instantiation, use of a
* factory method, and autowiring a constructor.
* @param beanName the name of the bean
* @param mbd the merged bean definition for the bean
* @param args explicit arguments to use for constructor or factory method invocation
* @return a new instance of the bean
* @throws BeanCreationException if the bean could not be created
* @see #instantiateBean
* @see #instantiateUsingFactoryMethod
* @see #autowireConstructor
*/
protected Object doCreateBean(String beanName, RootBeanDefinition mbd, @Nullable Object[] args)
throws BeanCreationException {
// Instantiate the bean.
// instanceWrapper 持有创建出的 bean 对象
BeanWrapper instanceWrapper = null;
// 获取 factoryBean 实例缓存
if (mbd.isSingleton()) {
// 如果是单例对象,从 factoryBean 实例缓存中移除当前 bean 的信息
// 首次 controllerA 进来会进行移除操作,并且会调用 createBeanInstance
instanceWrapper = this.factoryBeanInstanceCache.remove(beanName);
}
// 没有就创建实例
if (instanceWrapper == null) {
// 根据执行 bean 使用对应的策略创建新的工厂实例,如:工厂方法、构造函数主动注入、简单初始化
// 第一次读源码时不需要点进去看 createBeanInstance 。下一个主干方法 populateBean 是在本函数下文调用的
instanceWrapper = createBeanInstance(beanName, mbd, args);
}
// 从包装类中获取原始 bean 。首次执行 controllerA 的时候, bean 就是普通的 controllerA 对象 ControllerA@100{cb=null}
Object bean = instanceWrapper.getWrappedInstance();
// 获取具体 bean 对象的 Class 属性
Class<?> beanType = instanceWrapper.getWrappedClass();
if (beanType != NullBean.class) {
// 不等于 NullBean 类型时就修改目标类型
mbd.resolvedTargetType = beanType;
}
// 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.markAsPostProcessed();
}
}
// Eagerly cache singletons to be able to resolve circular references
// even when triggered by lifecycle interfaces like BeanFactoryAware.
// 判断当前 bean 是否需要提前曝光,条件为:是单例 && 允许循环依赖 spring.main.allow-circular-references 配置为 true && 当前 bean 正在创建中
boolean earlySingletonExposure = (mbd.isSingleton() && this.allowCircularReferences &&
isSingletonCurrentlyInCreation(beanName));
if (earlySingletonExposure) {
if (logger.isTraceEnabled()) {
logger.trace("Eagerly caching bean '" + beanName +
"' to allow for resolving potential circular references");
}
// 为避免后期循环依赖,可以在 bean 初始化完成前将创建实例的 ObjectFactory 加入工厂
// 注意,这个方法会操作三级缓存的数据结构,尤其是第3级缓存。在 controllerA -> controllerB -> controllerA 的时候未调用 createBean 的 getSingleton 方法会真正调用这个匿名函数,从而调用 getEarlyBeanReference 进而操作第2级缓存
addSingletonFactory(beanName, () -> getEarlyBeanReference(beanName, mbd, bean));
}
// Initialize the bean instance.
// controllerA 首次执行到这里时,exposedObject = ControllerA@100{cb=null}
Object exposedObject = bean;
try {
// populateBean 是主干方法,给刚刚实例化的 bean (半成品)填充属性
populateBean(beanName, mbd, instanceWrapper);
// controllerA -> controllerB -> controllerA 之后,getSingleton 返回 controllerA 后回到这里, controllerB 的 ca 属性就有值了
// 随后递归返回到这句话且调用栈只有 controllerA 的时候,发现两者都有值了
exposedObject = initializeBean(beanName, exposedObject, mbd);
}
catch (Throwable ex) {
if (ex instanceof BeanCreationException bce && beanName.equals(bce.getBeanName())) {
throw bce;
}
else {
throw new BeanCreationException(mbd.getResourceDescription(), beanName, ex.getMessage(), ex);
}
}
if (earlySingletonExposure) {
Object earlySingletonReference = getSingleton(beanName, false);
if (earlySingletonReference != null) {
if (exposedObject == bean) {
exposedObject = earlySingletonReference;
}
else if (!this.allowRawInjectionDespiteWrapping && hasDependentBean(beanName)) {
String[] dependentBeans = getDependentBeans(beanName);
Set<String> actualDependentBeans = new LinkedHashSet<>(dependentBeans.length);
for (String dependentBean : dependentBeans) {
if (!removeSingletonIfCreatedForTypeCheckOnly(dependentBean)) {
actualDependentBeans.add(dependentBean);
}
}
if (!actualDependentBeans.isEmpty()) {
throw new BeanCurrentlyInCreationException(beanName,
"Bean with name '" + beanName + "' has been injected into other beans [" +
StringUtils.collectionToCommaDelimitedString(actualDependentBeans) +
"] in its raw version as part of a circular reference, but has eventually been " +
"wrapped. This means that said other beans do not use the final version of the " +
"bean. This is often the result of over-eager type matching - consider using " +
"'getBeanNamesForType' with the 'allowEagerInit' flag turned off, for example.");
}
}
}
}
// Register bean as disposable.
try {
registerDisposableBeanIfNecessary(beanName, bean, mbd);
}
catch (BeanDefinitionValidationException ex) {
throw new BeanCreationException(
mbd.getResourceDescription(), beanName, "Invalid destruction signature", ex);
}
return exposedObject;
}
createBeanInstance
的细节与本文主题无关,不关注。接下来我们看下addSingletonFactory
的实现。addSingletonFactory
位于https://github.com/spring-projects/spring-framework/blob/502997d8e986dcfde1f49b2b2f443a32b5488b13/spring-beans/src/main/java/org/springframework/beans/factory/support/DefaultSingletonBeanRegistry.java
,主要动作是操作第3级缓存。
/**
* Add the given singleton factory for building the specified singleton
* if necessary.
* <p>To be called for eager registration of singletons, e.g. to be able to
* resolve circular references.
* @param beanName the name of the bean
* @param singletonFactory the factory for the singleton object
*/
protected void addSingletonFactory(String beanName, ObjectFactory<?> singletonFactory) {
Assert.notNull(singletonFactory, "Singleton factory must not be null");
synchronized (this.singletonObjects) {
// controllerA 首次执行到这里,第1级缓存肯定是查不到的
if (!this.singletonObjects.containsKey(beanName)) {
// 第3级缓存放入。再回顾一下, singletonFactory存的是 beanName 到一个延迟执行的函数的映射
// controllerA 首次执行到这里的时候, singletonFactory = () -> getEarlyBeanReference(beanName, mbd, bean)
this.singletonFactories.put(beanName, singletonFactory);
// 从早期单例对象的高速缓存(即第2级缓存)移除当前 beanName 对应的缓存对象
this.earlySingletonObjects.remove(beanName);
// 添加到已注册的单例集合里,和三级缓存无关。值得注意的是, A 首次加入第3级缓存时,就是首次加入已注册的单例集合
this.registeredSingletons.add(beanName);
}
}
}
接下来关注位于https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractAutowireCapableBeanFactory.java
的populateBean
。populateBean
方法有一个功能是给bean的属性赋值,包含了递归点。在创建Bean的源码中,递归点指的是递归调用getBean
方法。
/**
* Populate the bean instance in the given BeanWrapper with the property values
* from the bean definition.
* @param beanName the name of the bean
* @param mbd the bean definition for the bean
* @param bw the BeanWrapper with bean instance
*/
protected void populateBean(String beanName, RootBeanDefinition mbd, @Nullable BeanWrapper bw) {
if (bw == null) {
if (mbd.hasPropertyValues()) {
throw new BeanCreationException(
mbd.getResourceDescription(), beanName, "Cannot apply property values to null instance");
}
else {
// Skip property population phase for null instance.
return;
}
}
if (bw.getWrappedClass().isRecord()) {
if (mbd.hasPropertyValues()) {
throw new BeanCreationException(
mbd.getResourceDescription(), beanName, "Cannot apply property values to a record");
}
else {
// Skip property population phase for records since they are immutable.
return;
}
}
// 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.
if (!mbd.isSynthetic() && hasInstantiationAwareBeanPostProcessors()) {
for (InstantiationAwareBeanPostProcessor bp : getBeanPostProcessorCache().instantiationAware) {
if (!bp.postProcessAfterInstantiation(bw.getWrappedInstance(), beanName)) {
return;
}
}
}
PropertyValues pvs = (mbd.hasPropertyValues() ? mbd.getPropertyValues() : null);
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.
if (resolvedAutowireMode == AUTOWIRE_BY_NAME) {
autowireByName(beanName, mbd, bw, newPvs);
}
// Add property values based on autowire by type if applicable.
if (resolvedAutowireMode == AUTOWIRE_BY_TYPE) {
autowireByType(beanName, mbd, bw, newPvs);
}
pvs = newPvs;
}
if (hasInstantiationAwareBeanPostProcessors()) {
if (pvs == null) {
pvs = mbd.getPropertyValues();
}
for (InstantiationAwareBeanPostProcessor bp : getBeanPostProcessorCache().instantiationAware) {
// 对于 Controller Bean 自动装配属性产生循环依赖的场景,遍历到 AutowiredAnnotationBeanPostProcessor 时,这句话包含递归点
PropertyValues pvsToUse = bp.postProcessProperties(pvs, bw.getWrappedInstance(), beanName);
if (pvsToUse == null) {
return;
}
pvs = pvsToUse;
}
}
boolean needsDepCheck = (mbd.getDependencyCheck() != AbstractBeanDefinition.DEPENDENCY_CHECK_NONE);
if (needsDepCheck) {
PropertyDescriptor[] filteredPds = filterPropertyDescriptorsForDependencyCheck(bw, mbd.allowCaching);
checkDependencies(beanName, mbd, filteredPds, pvs);
}
if (pvs != null) {
// 对于普通 Bean 的场景,这句话包含递归点
applyPropertyValues(beanName, mbd, bw, pvs);
}
}
applyPropertyValues
也位于https://github.com/spring-projects/spring-framework/blob/4786e2bf53a3f882c10e25d7ff79a18ff47b5e51/spring-beans/src/main/java/org/springframework/beans/factory/support/AbstractAutowireCapableBeanFactory.java
,主要功能为完成bean
初始化。其中,Object resolvedValue = valueResolver.resolveValueIfNecessary(pv, originalValue)
包含了递归点,通过动调可以验证bw.setPropertyValues(new MutablePropertyValues(deepCopy))
真正完成了属性赋值工作。
/**
* Apply the given property values, resolving any runtime references
* to other beans in this bean factory. Must use deep copy, so we
* don't permanently modify this property.
* @param beanName the bean name passed for better exception information
* @param mbd the merged bean definition
* @param bw the BeanWrapper wrapping the target object
* @param pvs the new property values
*/
protected void applyPropertyValues(String beanName, BeanDefinition mbd, BeanWrapper bw, PropertyValues pvs) {
// applyPropertyValues 是真正完成赋值操作的函数
// 如果 pvs 没有 PropertyValue,就直接结束
if (pvs.isEmpty()) {
return;
}
MutablePropertyValues mpvs = null;
List<PropertyValue> original;
if (pvs instanceof MutablePropertyValues _mpvs) {
mpvs = _mpvs;
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);
}
}
// 获取 mpvs 的 PropertyValue 列表
original = mpvs.getPropertyValueList();
}
else {
// 获取 pvs 的 PropertyValue 对象数组并转为列表
original = Arrays.asList(pvs.getPropertyValues());
}
// 用户自定义的类型转换器,默认转换器为 bean 的包装类对象
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());
// resolveNecessary flag 含义为是否还需要解析
boolean resolveNecessary = false;
for (PropertyValue pv : original) {
// 属性已解析过则加入 deepCopy
if (pv.isConverted()) {
deepCopy.add(pv);
}
else {
String propertyName = pv.getName();
// 获取未经类型转换的值
Object originalValue = pv.getValue();
if (originalValue == AutowiredPropertyMarker.INSTANCE) {
Method writeMethod = bw.getPropertyDescriptor(propertyName).getWriteMethod();
// 如果 setter 方法为空
if (writeMethod == null) {
// 异常:自动装配标记属性没有写方法
throw new IllegalArgumentException("Autowire marker for property without write method: " + pv);
}
originalValue = new DependencyDescriptor(new MethodParameter(writeMethod, 0), true);
}
// 交由 valueResolver 根据 pv 解析出 originalValue 所封装的对象。注意:这个函数包含递归点
Object resolvedValue = valueResolver.resolveValueIfNecessary(pv, originalValue);
Object convertedValue = resolvedValue;
// flag 含义为是否可转换: propertyName 是 bw 中的可写属性 && propertyName 不是索引属性或嵌套属性
boolean convertible = bw.isWritableProperty(propertyName) &&
!PropertyAccessorUtils.isNestedOrIndexedProperty(propertyName);
if (convertible) {
// 可转换则将 resolvedValue 转换为指定的目标属性对象
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 &&
!typedStringValue.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 {
// 完成属性赋值工作。咱们做个简单的实验,动调执行此句前后各点击调用栈看一次 populateBean 调用处的下一句的 exposedObject 或者 bean 变量,这就证实了 bean 的属性赋值确实是在这句话完成的
bw.setPropertyValues(new MutablePropertyValues(deepCopy));
}
catch (BeansException ex) {
throw new BeanCreationException(mbd.getResourceDescription(), beanName, ex.getMessage(), ex);
}
}
resolveValueIfNecessary
位于https://github.com/spring-projects/spring-framework/blob/30d6ec3398ce41add7bc44d360b8fb86ac0264b1/spring-beans/src/main/java/org/springframework/beans/factory/support/BeanDefinitionValueResolver.java
。其实现也很长,但目前只需要关注return resolveReference(argName, ref)
,因为resolveReference
包含递归点。
/**
* Given a PropertyValue, return a value, resolving any references to other
* beans in the factory if necessary. The value could be:
* <li>A BeanDefinition, which leads to the creation of a corresponding
* new bean instance. Singleton flags and names of such "inner beans"
* are always ignored: Inner beans are anonymous prototypes.
* <li>A RuntimeBeanReference, which must be resolved.
* <li>A ManagedList. This is a special collection that may contain
* RuntimeBeanReferences or Collections that will need to be resolved.
* <li>A ManagedSet. May also contain RuntimeBeanReferences or
* Collections that will need to be resolved.
* <li>A ManagedMap. In this case the value may be a RuntimeBeanReference
* or Collection that will need to be resolved.
* <li>An ordinary object or {@code null}, in which case it's left alone.
* @param argName the name of the argument that the value is defined for
* @param value the value object to resolve
* @return the resolved object
*/
@Nullable
public Object resolveValueIfNecessary(Object argName, @Nullable Object value) {
// We must check each value to see whether it requires a runtime reference
// to another bean to be resolved.
// RuntimeBeanReference:当属性值对象是工厂中另一个 bean 的引用时,使用不可变的占位符类,在运行时进行解析
if (value instanceof RuntimeBeanReference ref) {
// 解析出对应 ref 所封装的 Bean 的元信息的 Bean 对象。Bean 的元信息:Bean 名,Bean类型。注意,这个函数里包含递归点
return resolveReference(argName, ref);
}
else if (value instanceof RuntimeBeanNameReference ref) {
String refName = ref.getBeanName();
refName = String.valueOf(doEvaluate(refName));
if (!this.beanFactory.containsBean(refName)) {
throw new BeanDefinitionStoreException(
"Invalid bean name '" + refName + "' in bean reference for " + argName);
}
return refName;
}
else if (value instanceof BeanDefinitionHolder bdHolder) {
// Resolve BeanDefinitionHolder: contains BeanDefinition with name and aliases.
return resolveInnerBean(bdHolder.getBeanName(), bdHolder.getBeanDefinition(),
(name, mbd) -> resolveInnerBeanValue(argName, name, mbd));
}
else if (value instanceof BeanDefinition bd) {
return resolveInnerBean(null, bd,
(name, mbd) -> resolveInnerBeanValue(argName, name, mbd));
}
else if (value instanceof DependencyDescriptor dependencyDescriptor) {
Set<String> autowiredBeanNames = new LinkedHashSet<>(2);
Object result = this.beanFactory.resolveDependency(
dependencyDescriptor, this.beanName, autowiredBeanNames, this.typeConverter);
for (String autowiredBeanName : autowiredBeanNames) {
if (this.beanFactory.containsBean(autowiredBeanName)) {
this.beanFactory.registerDependentBean(autowiredBeanName, this.beanName);
}
}
return result;
}
else if (value instanceof ManagedArray managedArray) {
// May need to resolve contained runtime references.
Class<?> elementType = managedArray.resolvedElementType;
if (elementType == null) {
String elementTypeName = managedArray.getElementTypeName();
if (StringUtils.hasText(elementTypeName)) {
try {
elementType = ClassUtils.forName(elementTypeName, this.beanFactory.getBeanClassLoader());
managedArray.resolvedElementType = elementType;
}
catch (Throwable ex) {
// Improve the message by showing the context.
throw new BeanCreationException(
this.beanDefinition.getResourceDescription(), this.beanName,
"Error resolving array type for " + argName, ex);
}
}
else {
elementType = Object.class;
}
}
return resolveManagedArray(argName, (List<?>) value, elementType);
}
else if (value instanceof ManagedList<?> managedList) {
// May need to resolve contained runtime references.
return resolveManagedList(argName, managedList);
}
else if (value instanceof ManagedSet<?> managedSet) {
// May need to resolve contained runtime references.
return resolveManagedSet(argName, managedSet);
}
else if (value instanceof ManagedMap<?, ?> managedMap) {
// May need to resolve contained runtime references.
return resolveManagedMap(argName, managedMap);
}
else if (value instanceof ManagedProperties original) {
// Properties original = managedProperties;
Properties copy = new Properties();
original.forEach((propKey, propValue) -> {
if (propKey instanceof TypedStringValue typedStringValue) {
propKey = evaluate(typedStringValue);
}
if (propValue instanceof TypedStringValue typedStringValue) {
propValue = evaluate(typedStringValue);
}
if (propKey == null || propValue == null) {
throw new BeanCreationException(
this.beanDefinition.getResourceDescription(), this.beanName,
"Error converting Properties key/value pair for " + argName + ": resolved to null");
}
copy.put(propKey, propValue);
});
return copy;
}
else if (value instanceof TypedStringValue typedStringValue) {
// Convert value to target type here.
Object valueObject = evaluate(typedStringValue);
try {
Class<?> resolvedTargetType = resolveTargetType(typedStringValue);
if (resolvedTargetType != null) {
return this.typeConverter.convertIfNecessary(valueObject, resolvedTargetType);
}
else {
return valueObject;
}
}
catch (Throwable ex) {
// Improve the message by showing the context.
throw new BeanCreationException(
this.beanDefinition.getResourceDescription(), this.beanName,
"Error converting typed String value for " + argName, ex);
}
}
else if (value instanceof NullBean) {
return null;
}
else {
return evaluate(value);
}
}
resolveReference
和resolveValueIfNecessary
都位于https://github.com/spring-projects/spring-framework/blob/30d6ec3398ce41add7bc44d360b8fb86ac0264b1/spring-beans/src/main/java/org/springframework/beans/factory/support/BeanDefinitionValueResolver.java
。其实现也很长,但目前只需要关注bean = this.beanFactory.getBean(resolvedName)
,因为这就是递归点。
/**
* Resolve a reference to another bean in the factory.
*/
@Nullable
private Object resolveReference(Object argName, RuntimeBeanReference ref) {
try {
Object bean;
Class<?> beanType = ref.getBeanType();
// 如果引用来自父工厂
if (ref.isToParent()) {
// 获取父工厂
BeanFactory parent = this.beanFactory.getParentBeanFactory();
if (parent == null) {
// 没有父工厂则报错:在父工厂中无法解析对 Bean 的引用,因为父工厂就不存在
throw new BeanCreationException(
this.beanDefinition.getResourceDescription(), this.beanName,
"Cannot resolve reference to bean " + ref +
" in parent factory: no parent factory available");
}
if (beanType != null) {
bean = parent.getBean(beanType);
}
else {
bean = parent.getBean(String.valueOf(doEvaluate(ref.getBeanName())));
}
}
else {
String resolvedName;
if (beanType != null) {
// 解析与 beanType 唯一匹配的 bean 实例,包括其 bean 名
NamedBeanHolder<?> namedBean = this.beanFactory.resolveNamedBean(beanType);
// 让 bean 引用 namedBean 所封装的 bean 对象
bean = namedBean.getBeanInstance();
resolvedName = namedBean.getBeanName();
}
else {
resolvedName = String.valueOf(doEvaluate(ref.getBeanName()));
// 获取 ref 所包装的 Bean 名对应的 Bean 对象
// 注意,这就是递归点了
bean = this.beanFactory.getBean(resolvedName);
}
// 注册依赖关系到 Bean 工厂
this.beanFactory.registerDependentBean(resolvedName, this.beanName);
}
if (bean instanceof NullBean) {
bean = null;
}
return bean;
}
catch (BeansException ex) {
throw new BeanCreationException(
this.beanDefinition.getResourceDescription(), this.beanName,
"Cannot resolve reference to bean '" + ref.getBeanName() + "' while setting " + argName, ex);
}
}
B
创建过程调用栈是完全一样的,接下来我们假设现在走到了A -> B -> A
,回到了doGetBean
的Object sharedInstance = getSingleton(beanName);
处。此时我们需要关注其实现了,因为这个函数要调用第3级缓存的函数,获取半成品bean,并放入第2级缓存。
/**
* Return the (raw) singleton object registered under the given name.
* <p>Checks already instantiated singletons and also allows for an early
* reference to a currently created singleton (resolving a circular reference).
* @param beanName the name of the bean to look for
* @param allowEarlyReference whether early references should be created or not
* @return the registered singleton object, or {@code null} if none found
*/
@Nullable
protected Object getSingleton(String beanName, boolean allowEarlyReference) {
// Quick check for existing instance without full singleton lock
// 该函数主要是调用放入第3级缓存的 getEarlyBeanReference 并放入第2级缓存
// 首先从第1级缓存获取 bean
Object singletonObject = this.singletonObjects.get(beanName);
// 第1级缓存没有,并且已标记为创建中
if (singletonObject == null && isSingletonCurrentlyInCreation(beanName)) {
// 从第2级缓存获取 bean.因为controllerA -> controllerB -> controllerA 的时候是创建中的 bean,只放到了第3级缓存,所以是查不到的
singletonObject = this.earlySingletonObjects.get(beanName);
// controllerA -> controllerB -> controllerA 的时候进来, allowEarlyReference 肯定是 true
if (singletonObject == null && allowEarlyReference) {
synchronized (this.singletonObjects) {
// Consistent creation of early reference within full singleton lock
// 这段做二次确认的代码让我联想到线程安全的单例模式的写法
// 从第1级缓存取
singletonObject = this.singletonObjects.get(beanName);
if (singletonObject == null) {
// 从第2级缓存取
singletonObject = this.earlySingletonObjects.get(beanName);
if (singletonObject == null) {
// 从第3级缓存取。如果是 controllerA 初次进来,因为 not in creation 所以不会进这里,就算进了这里,因为第3级缓存取不到所以还是会直接 return。如果是 controllerA -> controllerB -> controllerA 则会操作第2级缓存
ObjectFactory<?> singletonFactory = this.singletonFactories.get(beanName);
if (singletonFactory != null) {
// 回顾一下,DefaultSingletonBeanRegistry.java 的 addSingletonFactory 函数在操作第3级缓存的时候,放入的匿名函数就是:
// singletonFactory = () -> getEarlyBeanReference(beanName, mbd, bean) 所以 getEarlyBeanReference 返回值会在此被放入第2级缓存
singletonObject = singletonFactory.getObject();
// 为什么是放第2级缓存?因为 getBean 的递归还没返回
// 放入第2级缓存后,第3级缓存的就可以移除了
this.earlySingletonObjects.put(beanName, singletonObject);
this.singletonFactories.remove(beanName);
}
}
}
}
}
}
return singletonObject;
}
再回忆一遍,什么时候加入第1级缓存?调用了beforeSingletonCreation
的getSingleton
方法在间接调用createBean
后,会调用addSingleton
方法,将成品bean加入第1级缓存。
A -> B -> A
的递归返回后,A, B
两个单例bean都已经是成品,beanName
遍历到B
的时候,进入getSingleton
就能命中第1级缓存了,不用再走一遍createBean
方法。
for (String beanName : beanNames) {
// 假如先遍历 A 再遍历 B 那么遍历到 B 的时候,因为循环引用解决的关系,B 已经放到了第1级缓存,所以 doGetBean 的 getSingleton 可以直接从第1级缓存取到值,不用再走一遍 createBean 方法
// 合并父类 BeanDefinition
RootBeanDefinition bd = getMergedLocalBeanDefinition(beanName);
// 非抽象、是单例、非懒加载
if (!bd.isAbstract() && bd.isSingleton() && !bd.isLazyInit()) {
// 如果实现了 FactoryBean 接口则是 FactoryBean
if (isFactoryBean(beanName)) {
Object bean = getBean(FACTORY_BEAN_PREFIX + beanName); // 比如:FACTORY_BEAN_PREFIX + beanName = "&A"
if (bean instanceof SmartFactoryBean<?> smartFactoryBean && smartFactoryBean.isEagerInit()) {
getBean(beanName);
}
}
else {
// 不是 FactoryBean,只是普通 Bean,则走这个分支
getBean(beanName);
}
}
}
经过上面的分析,我们来看更简单的情况:如果没有循环依赖,比如只有A
依赖B
,对三级缓存数据结构的操作是怎样的?梳理出调用栈如下:A doGetBean -> A doCreateBean -> A addSingletonFactory -> A applyPropertyValues -> B doGetBean -> B doCreateBean -> B addSingletonFactory -> B applyPropertyValues不走到递归点 -> B回到getSingleton调用addSingleton -> A addSingleton
。可见如果没有循环依赖,就不会操作第2级缓存,但仍然会操作第1级缓存。第3级缓存虽然被操作但没有影响。
至此,场景1的递归点和三级缓存的操作时机都已经清楚了。
@Controller
+自动装配属性和普通Bean解决循环依赖过程的相同点与不同点
场景2的Controller使用了@Autowired
注解来构造循环依赖。动调可知,这个场景并不是在populateBean
的applyPropertyValues(beanName, mbd, bw, pvs);
完成修改的,而是在populateBean
的:
for (InstantiationAwareBeanPostProcessor bp : getBeanPostProcessorCache().instantiationAware) {
PropertyValues pvsToUse = bp.postProcessProperties(pvs, bw.getWrappedInstance(), beanName);
if (pvsToUse == null) {
return;
}
pvs = pvsToUse;
}
这个循环里完成属性赋值的。动调发现getBeanPostProcessorCache().instantiationAware
有一个元素是AutowiredAnnotationBeanPostProcessor@133
(所有元素分别是ConfigurationClassPostProcessor$ImportAwareBeanPostProcessor@129, InfrastructureAdvisorAutoProxyCreator@130, PersistenceExceptionTranslationPostProcessor@131, CommonAnnotationBeanPostProcessor@132, AutowiredAnnotationBeanPostProcessor@133
),遍历到这个元素时执行的操作完成了自动装配属性的赋值。那我们跟进去看下。
AutowiredAnnotationBeanPostProcessor.postProcessProperties
位于https://github.com/spring-projects/spring-framework/blob/6183f0684684912802021556dce916ba26228c26/spring-beans/src/main/java/org/springframework/beans/factory/annotation/AutowiredAnnotationBeanPostProcessor.java
@Override
public PropertyValues postProcessProperties(PropertyValues pvs, Object bean, String beanName) {
InjectionMetadata metadata = findAutowiringMetadata(beanName, bean.getClass(), pvs);
try {
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;
}
显然是在metadata.inject
处完成自动装配的。InjectionMetadata.inject
位于https://github.com/spring-projects/spring-framework/blob/2f33e77ab49f136d83b6ebf5eeb72d200fe23c0b/spring-beans/src/main/java/org/springframework/beans/factory/annotation/InjectionMetadata.java
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) {
element.inject(target, beanName, pvs);
}
}
}
element.inject
最终跳入的是https://github.com/spring-projects/spring-framework/blob/6183f0684684912802021556dce916ba26228c26/spring-beans/src/main/java/org/springframework/beans/factory/annotation/AutowiredAnnotationBeanPostProcessor.java
的protected void inject(Object bean, @Nullable String beanName, @Nullable PropertyValues pvs) throws Throwable
。AutowiredFieldElement, AutowiredMethodElement
都有inject
方法,显然这个case里我们调用的是AutowiredFieldElement
的inject
方法。
@Override
protected void inject(Object bean, @Nullable String beanName, @Nullable PropertyValues pvs) throws Throwable {
Field field = (Field) this.member;
Object value;
if (this.cached) {
try {
value = resolveCachedArgument(beanName, this.cachedFieldValue);
}
catch (BeansException ex) {
// Unexpected target bean mismatch for cached argument -> re-resolve
this.cached = false;
logger.debug("Failed to resolve cached argument", ex);
value = resolveFieldValue(field, bean, beanName);
}
}
else {
value = resolveFieldValue(field, bean, beanName);
}
if (value != null) {
ReflectionUtils.makeAccessible(field);
field.set(bean, value);
}
}
显然field.set(bean, value);
最终完成了属性的自动装配。值得注意的是,动调看到resolveFieldValue
获取到的cb
是已经装配好的,这里一定存在递归调用。我们用一个简单的动态调试技巧来找到递归点:在执行到value = resolveFieldValue(field, bean, beanName)
时,给doGetBean
函数下一个临时的断点。得到的调用栈如下:
AutowiredAnnotationBeanPostProcessor.AutowiredFieldElement.inject()
AutowiredAnnotationBeanPostProcessor.AutowiredFieldElement.resolveFieldValue()
的value = beanFactory.resolveDependency(desc, beanName, autowiredBeanNames, typeConverter);
DefaultListableBeanFactory.java
的resolveDependency
方法的result = doResolveDependency(descriptor, requestingBeanName, autowiredBeanNames, typeConverter);
DefaultListableBeanFactory.java
的doResolveDependency
方法的instanceCandidate = descriptor.resolveCandidate(autowiredBeanName, type, this);
https://github.com/spring-projects/spring-framework/blob/f1fe16e3cda66b164f77489f82287116477197bc/spring-beans/src/main/java/org/springframework/beans/factory/config/DependencyDescriptor.java
的resolveCandidate
方法的return beanFactory.getBean(beanName);
,这就是递归点了,beanName = controllerB
。
总而言之,Controller的bean自动装配属性的场景和普通的bean的递归点不一样,但对三级缓存的操作逻辑是完全一致的。谜底已揭晓~
一些扩展结论
【1】为什么Spring不能解决构造器的循环依赖?
在doCreateBean
调用createBeanInstance
时,一二三级缓存都没有Bean的相关信息,在实例化之后才调用addSingletonFactory
放入第3级缓存中,因此当getBean的时候缓存不会命中,所以会抛出循环依赖的异常。
【2】为什么多实例Bean不能解决循环依赖?
多实例Bean是每次创建都会调用doGetBean
方法,mbd.isSingleton()
是false,不走sharedInstance = getSingleton(beanName, () -> {
这个分支,所以也不会使用三级缓存,不能解决循环依赖。
总结
- 根据常识猜测Spring创建Bean过程解决循环依赖的算法也是Map+记忆化搜索。所以我们可以先找到递归点,再去分析调用栈涉及的那些函数,顺便找出其用到的Map数据结构。
- 在不了解Spring框架的情况下可以用一个动态调试技巧快速找到递归点:在执行到某条顺序靠后的语句时,给顺序靠前的语句下一个断点,若下断成功,则说明找到了递归点。剩下的工作就是关注调用栈涉及的函数。
参考资料
- VSCode搭建Java开发环境(SpringBoot项目创建、运行、调试):https://www.cnblogs.com/miskis/p/9816135.html
- 痛快!SpringBoot终于禁掉了循环依赖!https://juejin.cn/post/7096798740593246222
- https://www.bilibili.com/video/BV1J14y1A7eE/?p=82
震惊!这位零基础前端同学在学习Java的第7天就可以研究Spring框架源码了!这是怎么做到的呢?噢!原来是站在了Java之父🐎士兵的肩膀上!