SpringMVC源码剖析(四)- DispatcherServlet请求转发的实现

SpringMVC完成初始化流程之后,就进入Servlet标准生命周期的第二个阶段,即“service”阶段。在“service”阶段中,每一次Http请求到来,容器都会启动一个请求线程,通过service()方法,委派到doGet()或者doPost()这些方法,完成Http请求的处理。

在初始化流程中,SpringMVC巧妙的运用依赖注入读取参数,并最终建立一个与容器上下文相关联的Spring子上下文。这个子上下文,就像Struts2中xwork容器一样,为接下来的Http处理流程中各种编程元素提供了容身之所。如果说将Spring上下文关联到Servlet容器中,是SpringMVC框架的第一个亮点,那么在请求转发流程中,SpringMVC对各种处理环节编程元素的抽象,就是另外一个独具匠心的亮点。

Struts2采取的是一种完全和Web容器隔离和解耦的事件机制。诸如Action对象、Result对象、Interceptor对象,这些都是完全脱离Servlet容器的编程元素。Struts2将数据流和事件处理完全剥离开来,从Http请求中读取数据后,下面的事件处理流程就只依赖于这些数据,而完全不知道有Web环境的存在。

反观SpringMVC,无论HandlerMapping对象、HandlerAdapter对象还是View对象,这些核心的接口所定义的方法中,HttpServletRequest和HttpServletResponse对象都是直接作为方法的参数出现的。这也就意味着,框架的设计者,直接将SpringMVC框架和容器绑定到了一起。或者说,整个SpringMVC框架,都是依托着Servlet容器元素来设计的。下面就来看一下,源码中是如何体现这一点的。

1.请求转发的入口

就像任何一个注册在容器中的Servlet一样,DispatcherServlet也是通过自己的service()方法来接收和转发Http请求到具体的doGet()或doPost()这些方法的。以一次典型的GET请求为例,经过HttpServlet基类中service()方法的委派,请求会被转发到doGet()方法中。doGet()方法,在DispatcherServlet的父类FrameworkServlet类中被覆写。

@Override
protected final void doGet(HttpServletRequest request, HttpServletResponse response)
		throws ServletException, IOException {

	processRequest(request, response);
}

可以看到,这里只是简单的转发到processRequest()这个方法。

protected final void processRequest(HttpServletRequest request, HttpServletResponse response)
		throws ServletException, IOException {

	long startTime = System.currentTimeMillis();
	Throwable failureCause = null;

	// Expose current LocaleResolver and request as LocaleContext.
	LocaleContext previousLocaleContext = LocaleContextHolder.getLocaleContext();
	LocaleContextHolder.setLocaleContext(buildLocaleContext(request), this.threadContextInheritable);

	// Expose current RequestAttributes to current thread.
	RequestAttributes previousRequestAttributes = RequestContextHolder.getRequestAttributes();
	ServletRequestAttributes requestAttributes = null;
	if (previousRequestAttributes == null || previousRequestAttributes.getClass().equals(ServletRequestAttributes.class)) {
		requestAttributes = new ServletRequestAttributes(request);
		RequestContextHolder.setRequestAttributes(requestAttributes, this.threadContextInheritable);
	}

	if (logger.isTraceEnabled()) {
		logger.trace("Bound request context to thread: " + request);
	}

	try {
		doService(request, response);
	}
	catch (ServletException ex) {
		failureCause = ex;
		throw ex;
	}
	catch (IOException ex) {
		failureCause = ex;
		throw ex;
	}
	catch (Throwable ex) {
		failureCause = ex;
		throw new NestedServletException("Request processing failed", ex);
	}

	finally {
		// Clear request attributes and reset thread-bound context.
		LocaleContextHolder.setLocaleContext(previousLocaleContext, this.threadContextInheritable);
		if (requestAttributes != null) {
			RequestContextHolder.setRequestAttributes(previousRequestAttributes, this.threadContextInheritable);
			requestAttributes.requestCompleted();
		}
		if (logger.isTraceEnabled()) {
			logger.trace("Cleared thread-bound request context: " + request);
		}

		if (logger.isDebugEnabled()) {
			if (failureCause != null) {
				this.logger.debug("Could not complete request", failureCause);
			}
			else {
				this.logger.debug("Successfully completed request");
			}
		}
		if (this.publishEvents) {
			// Whether or not we succeeded, publish an event.
			long processingTime = System.currentTimeMillis() - startTime;
			this.webApplicationContext.publishEvent(
					new ServletRequestHandledEvent(this,
							request.getRequestURI(), request.getRemoteAddr(),
							request.getMethod(), getServletConfig().getServletName(),
							WebUtils.getSessionId(request), getUsernameForRequest(request),
							processingTime, failureCause));
		}
	}
}

代码有点长,理解的要点是以doService()方法为区隔,前一部分是将当前请求的Locale对象和属性,分别设置到LocaleContextHolder和RequestContextHolder这两个抽象类中的ThreadLocal对象中,也就是分别将这两个东西和请求线程做了绑定。在doService()处理结束后,再恢复回请求前的LocaleContextHolder和RequestContextHolder,也即解除线程绑定。每次请求处理结束后,容器上下文都发布了一个ServletRequestHandledEvent事件,你可以注册监听器来监听该事件。

可以看到,processRequest()方法只是做了一些线程安全的隔离,真正的请求处理,发生在doService()方法中。点开FrameworkServlet类中的doService()方法。

protected abstract void doService(HttpServletRequest request, HttpServletResponse response)
		throws Exception;

又是一个抽象方法,这也是SpringMVC类设计中的惯用伎俩:父类抽象处理流程,子类给予具体的实现。真正的实现是在DispatcherServlet类中。

让我们接着看DispatcherServlet类中实现的doService()方法。

@Override
protected void doService(HttpServletRequest request, HttpServletResponse response) throws Exception {
	if (logger.isDebugEnabled()) {
		String requestUri = urlPathHelper.getRequestUri(request);
		logger.debug("DispatcherServlet with name '" + getServletName() + "' processing " + request.getMethod() +
				" request for [" + requestUri + "]");
	}

	// Keep a snapshot of the request attributes in case of an include,
	// to be able to restore the original attributes after the include.
	Map attributesSnapshot = null;
	if (WebUtils.isIncludeRequest(request)) {
		logger.debug("Taking snapshot of request attributes before include");
		attributesSnapshot = new HashMap();
		Enumeration attrNames = request.getAttributeNames();
		while (attrNames.hasMoreElements()) {
			String attrName = (String) attrNames.nextElement();
			if (this.cleanupAfterInclude || attrName.startsWith("org.springframework.web.servlet")) {
				attributesSnapshot.put(attrName, request.getAttribute(attrName));
			}
		}
	}

	// Make framework objects available to handlers and view objects.
	request.setAttribute(WEB_APPLICATION_CONTEXT_ATTRIBUTE, getWebApplicationContext());
	request.setAttribute(LOCALE_RESOLVER_ATTRIBUTE, this.localeResolver);
	request.setAttribute(THEME_RESOLVER_ATTRIBUTE, this.themeResolver);
	request.setAttribute(THEME_SOURCE_ATTRIBUTE, getThemeSource());

	FlashMap inputFlashMap = this.flashMapManager.retrieveAndUpdate(request, response);
	if (inputFlashMap != null) {
		request.setAttribute(INPUT_FLASH_MAP_ATTRIBUTE, Collections.unmodifiableMap(inputFlashMap));
	}
	request.setAttribute(OUTPUT_FLASH_MAP_ATTRIBUTE, new FlashMap());
	request.setAttribute(FLASH_MAP_MANAGER_ATTRIBUTE, this.flashMapManager);

	try {
		doDispatch(request, response);
	}
	finally {
		// Restore the original attribute snapshot, in case of an include.
		if (attributesSnapshot != null) {
			restoreAttributesAfterInclude(request, attributesSnapshot);
		}
	}
}

几个requet.setAttribute()方法的调用,将前面在初始化流程中实例化的对象设置到http请求的属性中,供下一步处理使用,其中有容器的上下文对象、本地化解析器等SpringMVC特有的编程元素。不同于Struts2中的ValueStack,SpringMVC的数据并没有从HttpServletRequest对象中抽离出来再存进另外一个编程元素,这也跟SpringMVC的设计思想有关。因为从一开始,SpringMVC的设计者就认为,不应该将请求处理过程和Web容器完全隔离

所以,你可以看到,真正发生请求转发的方法doDispatch()中,它的参数是HttpServletRequest和HttpServletResponse对象。这给我们传递的意思也很明确,从request中能获取到一切请求的数据,从response中,我们又可以往服务器端输出任何响应,Http请求的处理,就应该围绕这两个对象来设计。我们不妨可以将SpringMVC这种设计方案,是从Struts2的过度设计中吸取教训,而向Servlet编程的一种回归和简化。

2.请求转发的抽象描述

接下来让我们看看doDispatch()这个整个请求转发流程中最核心的方法。DispatcherServlet所接收的Http请求,经过层层转发,最终都是汇总到这个方法中来进行最后的请求分发和处理。doDispatch()这个方法的内容,就是SpringMVC整个框架的精华所在。它通过高度抽象的接口,描述出了一个MVC(Model-View-Controller)设计模式的实现方案。Model、View、Controller三种层次的编程元素,在SpringMVC中都有大量的实现类,各种处理细节也是千差万别。但是,它们最后都是由,也都能由doDispatch()方法来统一描述,这就是接口和抽象的威力,万变不离其宗。

先来看一下doDispatch()方法的庐山真面目。

protected void doDispatch(HttpServletRequest request, HttpServletResponse response) throws Exception {
	HttpServletRequest processedRequest = request;
	HandlerExecutionChain mappedHandler = null;
	int interceptorIndex = -1;

	try {
		ModelAndView mv;
		boolean errorView = false;

		try {
			processedRequest = checkMultipart(request);

			// Determine handler for the current request.
			mappedHandler = getHandler(processedRequest, false);
			if (mappedHandler == null || mappedHandler.getHandler() == null) {
				noHandlerFound(processedRequest, response);
				return;
			}

			// Determine handler adapter for the current request.
			HandlerAdapter ha = getHandlerAdapter(mappedHandler.getHandler());

			// Process last-modified header, if supported by the handler.
			String method = request.getMethod();
			boolean isGet = "GET".equals(method);
			if (isGet || "HEAD".equals(method)) {
				long lastModified = ha.getLastModified(request, mappedHandler.getHandler());
				if (logger.isDebugEnabled()) {
					String requestUri = urlPathHelper.getRequestUri(request);
					logger.debug("Last-Modified value for [" + requestUri + "] is: " + lastModified);
				}
				if (new ServletWebRequest(request, response).checkNotModified(lastModified) && isGet) {
					return;
				}
			}

			// Apply preHandle methods of registered interceptors.
			HandlerInterceptor[] interceptors = mappedHandler.getInterceptors();
			if (interceptors != null) {
				for (int i = 0; i < interceptors.length; i++) {
					HandlerInterceptor interceptor = interceptors[i];
					if (!interceptor.preHandle(processedRequest, response, mappedHandler.getHandler())) {
						triggerAfterCompletion(mappedHandler, interceptorIndex, processedRequest, response, null);
						return;
					}
					interceptorIndex = i;
				}
			}

			// Actually invoke the handler.
			mv = ha.handle(processedRequest, response, mappedHandler.getHandler());

			// Do we need view name translation?
			if (mv != null && !mv.hasView()) {
				mv.setViewName(getDefaultViewName(request));
			}

			// Apply postHandle methods of registered interceptors.
			if (interceptors != null) {
				for (int i = interceptors.length - 1; i >= 0; i--) {
					HandlerInterceptor interceptor = interceptors[i];
					interceptor.postHandle(processedRequest, response, mappedHandler.getHandler(), mv);
				}
			}
		}
		catch (ModelAndViewDefiningException ex) {
			logger.debug("ModelAndViewDefiningException encountered", ex);
			mv = ex.getModelAndView();
		}
		catch (Exception ex) {
			Object handler = (mappedHandler != null ? mappedHandler.getHandler() : null);
			mv = processHandlerException(processedRequest, response, handler, ex);
			errorView = (mv != null);
		}

		// Did the handler return a view to render?
		if (mv != null && !mv.wasCleared()) {
			render(mv, processedRequest, response);
			if (errorView) {
				WebUtils.clearErrorRequestAttributes(request);
			}
		}
		else {
			if (logger.isDebugEnabled()) {
				logger.debug("Null ModelAndView returned to DispatcherServlet with name '" + getServletName() +
						"': assuming HandlerAdapter completed request handling");
			}
		}

		// Trigger after-completion for successful outcome.
		triggerAfterCompletion(mappedHandler, interceptorIndex, processedRequest, response, null);
	}

	catch (Exception ex) {
		// Trigger after-completion for thrown exception.
		triggerAfterCompletion(mappedHandler, interceptorIndex, processedRequest, response, ex);
		throw ex;
	}
	catch (Error err) {
		ServletException ex = new NestedServletException("Handler processing failed", err);
		// Trigger after-completion for thrown exception.
		triggerAfterCompletion(mappedHandler, interceptorIndex, processedRequest, response, ex);
		throw ex;
	}

	finally {
		// Clean up any resources used by a multipart request.
		if (processedRequest != request) {
			cleanupMultipart(processedRequest);
		}
	}
}

真是千呼万唤始出来,犹抱琵琶半遮面。我们在第一篇《SpringMVC源码剖析(一)- 从抽象和接口说起》中所描述的各种编程元素,依次出现在该方法中。HandlerMapping、HandlerAdapter、View这些接口的设计,我们在第一篇中已经讲过。现在我们来重点关注一下HandlerExecutionChain这个对象。

从上面的代码中,很明显可以看出一条线索,整个方法是围绕着如何获取HandlerExecutionChain对象,执行HandlerExecutionChain对象得到相应的视图对象,再对视图进行渲染这条主线来展开的。HandlerExecutionChain对象显得异常重要。

因为Http请求要进入SpringMVC的处理体系,必须由HandlerMapping接口的实现类映射Http请求,得到一个封装后的HandlerExecutionChain对象。再由HandlerAdapter接口的实现类来处理这个HandlerExecutionChain对象所包装的处理对象,来得到最后渲染的视图对象。

视图对象是用ModelAndView对象来描述的,名字已经非常直白,就是数据和视图,其中的数据,由HttpServletRequest的属性得到,视图就是由HandlerExecutionChain封装的处理对象处理后得到。当然HandlerExecutionChain中的拦截器列表HandlerInterceptor,会在处理过程的前后依次被调用,为处理过程留下充足的扩展点。

所有的SpringMVC框架元素,都是围绕着HandlerExecutionChain这个执行链来发挥效用。我们来看看,HandlerExecutionChain类的代码。

package org.springframework.web.servlet;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;

import org.springframework.util.CollectionUtils;

public class HandlerExecutionChain {

	private final Object handler;

	private HandlerInterceptor[] interceptors;

	private List interceptorList;

	public HandlerExecutionChain(Object handler) {
		this(handler, null);
	}

	public HandlerExecutionChain(Object handler, HandlerInterceptor[] interceptors) {
		if (handler instanceof HandlerExecutionChain) {
			HandlerExecutionChain originalChain = (HandlerExecutionChain) handler;
			this.handler = originalChain.getHandler();
			this.interceptorList = new ArrayList();
			CollectionUtils.mergeArrayIntoCollection(originalChain.getInterceptors(), this.interceptorList);
			CollectionUtils.mergeArrayIntoCollection(interceptors, this.interceptorList);
		}
		else {
			this.handler = handler;
			this.interceptors = interceptors;
		}
	}

	public Object getHandler() {
		return this.handler;
	}

	public void addInterceptor(HandlerInterceptor interceptor) {
		initInterceptorList();
		this.interceptorList.add(interceptor);
	}

	public void addInterceptors(HandlerInterceptor[] interceptors) {
		if (interceptors != null) {
			initInterceptorList();
			this.interceptorList.addAll(Arrays.asList(interceptors));
		}
	}

	private void initInterceptorList() {
		if (this.interceptorList == null) {
			this.interceptorList = new ArrayList();
		}
		if (this.interceptors != null) {
			this.interceptorList.addAll(Arrays.asList(this.interceptors));
			this.interceptors = null;
		}
	}

	public HandlerInterceptor[] getInterceptors() {
		if (this.interceptors == null && this.interceptorList != null) {
			this.interceptors = this.interceptorList.toArray(new HandlerInterceptor[this.interceptorList.size()]);
		}
		return this.interceptors;
	}

	@Override
	public String toString() {
		if (this.handler == null) {
			return "HandlerExecutionChain with no handler";
		}
		StringBuilder sb = new StringBuilder();
		sb.append("HandlerExecutionChain with handler [").append(this.handler).append("]");
		if (!CollectionUtils.isEmpty(this.interceptorList)) {
			sb.append(" and ").append(this.interceptorList.size()).append(" interceptor");
			if (this.interceptorList.size() > 1) {
				sb.append("s");
			}
		}
		return sb.toString();
	}

}

一个拦截器列表,一个执行对象,这个类的内容十分的简单,它蕴含的设计思想,却十分的丰富。

1.拦截器组成的列表,在执行对象被调用的前后,会依次执行。这里可以看成是一个的AOP环绕通知,拦截器可以对处理对象随心所欲的进行处理和增强。这里明显是吸收了Struts2中拦截器的设计思想。这种AOP环绕式的扩展点设计,也几乎成为所有框架必备的内容。

2.实际的处理对象,即handler对象,是由Object对象来引用的。

private final Object handler;

之所以要用一个java世界最基础的Object对象引用来引用这个handler对象,是因为连特定的接口也不希望绑定在这个handler对象上,从而使handler对象具有最大程度的选择性和灵活性。

我们常说,一个框架最高层次的抽象是接口,但是这里SpringMVC更进了一步。在最后的处理对象上面,SpringMVC没有对它做任何的限制,只要是java世界中的对象,都可以用来作为最后的处理对象,来生成视图。极端一点来说,你甚至可以将另外一个MVC框架集成到SpringMVC中来,也就是为什么SpringMVC官方文档中,居然还有集成其他表现层框架的内容。这一点,在所有表现层框架中,是独领风骚,冠绝群雄的。

SpringMVC源码剖析(四)- DispatcherServlet请求转发的实现_第1张图片

3.结语

SpringMVC的成功,源于它对开闭原则的运用和遵守。也正因此,才使得整个框架具有如此强大的描述和扩展能力。这也许和SpringMVC出现和兴起的时间有关,正是经历了Struts1到Struts2这些Web开发领域MVC框架的更新换代,它的设计者才能站在前人的肩膀上。知道了如何将事情做的糟糕之后,你或许才知道如何将事情做得好。

希望在这个系列里面分享的SpringMVC源码阅读经验,能帮助读者们从更高的层次来审视SpringMVC框架的设计,也希望这里所描述的一些基本设计思想,能在你更深入的了解SpringMVC的细节时,对你有帮助。哲学才是唯一的、最终的武器,在一个框架的设计上,尤其是如此。经常地体会一个框架设计者的设计思想,对你更好的使用它,是有莫大的益处的。


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