SpringMVC中异步请求相关组件
SpringMVC在此基础上对异步请求进行了封装。提供了AsyncWebRequest类型的request,并提供了处理异步请求的管理器WebAsyncManager和工具WebAsyncUtils.
SpringMVC将异步请求返回值细分为了:Callable,WebAsyncTask,,DeferredResult 和 ListenableFuture. 后续会针对这四种不同的类型一一分析。
AsyncWebRequest
AsyncWebRequest,它是专门处理异步请求的request,定义如下:
//org.springframework.web.context.request.async.AsyncWebRequest public interface AsyncWebRequest extends NativeWebRequest { void setTimeout(Long timeout); //相当于在AsyncListener中的`onTimeout和onComplete` void addTimeoutHandler(Runnable runnable); void addCompletionHandler(Runnable runnable); void startAsync(); //判断异步请求是否开启和结束 boolean isAsyncStarted(); boolean isAsyncComplete(); void dispatch(); }
AsyncWebRequest 有两个实现类,
NoSupportAsyncWebRequest: 不支持异步请求StandardServletAsyncWebRequest: 支持异步请求。
StandardServletAsyncWebRequest 除了实现了AsyncWebRequest接口外,还实现了AsyncListener,另外它还继承了ServletWebRequest.
public class StandardServletAsyncWebRequest extends ServletWebRequest implements AsyncWebRequest, AsyncListener { private Long timeout; //封装 AsyncContext 属性 private AsyncContext asyncContext; private AtomicBoolean asyncCompleted = new AtomicBoolean(false); //AsyncListener onTimeout,onCompletion方法 调用如下handlers.. private final List<Runnable> timeoutHandlers = new ArrayList<Runnable>(); private final List<Runnable> completionHandlers = new ArrayList<Runnable>(); @Override public boolean isAsyncStarted() { return ((this.asyncContext != null) && getRequest().isAsyncStarted()); } @Override public void startAsync() { if (isAsyncStarted()) { return; } this.asyncContext = getRequest().startAsync(getRequest(), getResponse()); this.asyncContext.addListener(this); if (this.timeout != null) { this.asyncContext.setTimeout(this.timeout); } } // --- 实现 AsyncListener 方法---- @Override public void onTimeout(AsyncEvent event) throws IOException { for (Runnable handler : this.timeoutHandlers) { handler.run(); } } @Override public void onComplete(AsyncEvent event) throws IOException { for (Runnable handler : this.completionHandlers) { handler.run(); } //执行完完成时,清空asyncContext this.asyncContext = null; this.asyncCompleted.set(true); } }
WebAsyncUtils
//org.springframework.web.context.request.async.WebAsyncUtils public abstract class WebAsyncUtils { //第一次获取时,直接创建WebAsyncManager,并设置到setAttribute中。 以后获取,直接从request属性中获取。 public static WebAsyncManager getAsyncManager(ServletRequest servletRequest) { WebAsyncManager asyncManager = (WebAsyncManager) servletRequest.getAttribute(WEB_ASYNC_MANAGER_ATTRIBUTE); if (asyncManager == null) { asyncManager = new WebAsyncManager(); servletRequest.setAttribute(WEB_ASYNC_MANAGER_ATTRIBUTE, asyncManager); } return asyncManager; } public static WebAsyncManager getAsyncManager(WebRequest webRequest) { //逻辑类似 getAsyncManager(ServletRequest servletRequest) 略... } //判断ServletRequest是否有方法"startAsync"。 只有servlet环境3.0以上版本才有此方法 public static AsyncWebRequest createAsyncWebRequest(HttpServletRequest request, HttpServletResponse response) { return ClassUtils.hasMethod(ServletRequest.class, "startAsync") ? createStandardServletAsyncWebRequest(request, response) : new NoSupportAsyncWebRequest(request, response); } private static AsyncWebRequest createStandardServletAsyncWebRequest(HttpServletRequest request, HttpServletResponse response) { if (standardAsyncRequestConstructor == null) { String className = "org.springframework.web.context.request.async.StandardServletAsyncWebRequest"; Class<?> clazz = ClassUtils.forName(className, WebAsyncUtils.class.getClassLoader()); standardAsyncRequestConstructor = clazz.getConstructor(HttpServletRequest.class, HttpServletResponse.class); } return (AsyncWebRequest) BeanUtils.instantiateClass(standardAsyncRequestConstructor, request, response); } }
WebAsyncManager
WebAsyncManager是SpringMVC处理异步请求过程中最核心的类,它管理着整个异步处理的过程。
//org.springframework.web.context.request.async public final class WebAsyncManager { //两种类型的 超时 Interceptors private static final CallableProcessingInterceptor timeoutCallableInterceptor = new TimeoutCallableProcessingInterceptor(); private static final DeferredResultProcessingInterceptor timeoutDeferredResultInterceptor = new TimeoutDeferredResultProcessingInterceptor(); //持有 asyncWebRequest 对象 private AsyncWebRequest asyncWebRequest; private AsyncTaskExecutor taskExecutor = new SimpleAsyncTaskExecutor(this.getClass().getSimpleName()); //两种类型的 处理请求Interceptors private final Map<Object, CallableProcessingInterceptor> callableInterceptors = new LinkedHashMap<Object, CallableProcessingInterceptor>(); private final Map<Object, DeferredResultProcessingInterceptor> deferredResultInterceptors = new LinkedHashMap<Object, DeferredResultProcessingInterceptor>(); //用来处理Callable 和 WebAsyncTask 类型的异步请求 public void startCallableProcessing(final WebAsyncTask<?> webAsyncTask, Object... processingContext) throws Exception { } //用来处理 DeferredResult 和 ListenableFuture 类型的请求 public void startDeferredResultProcessing(final DeferredResult<?> deferredResult, Object... processingContext) throws Exception }
它最重要的两个方法是:startCallableProcessing和startDeferredResultProcessing,这两个方法是启动异步处理的入口方法,它们一共做三件事:
- 给Request设置属性(timeout,timeoutHandler,completionHandler…)
- 在相应位置,执行
interceptors逻辑 - 启动异步处理
这里重点分析下startCallableProcessing:
public void startCallableProcessing(final WebAsyncTask<?> webAsyncTask, Object... processingContext) throws Exception { //设置asyncWebRequest 属性... Long timeout = webAsyncTask.getTimeout(); if (timeout != null) { this.asyncWebRequest.setTimeout(timeout); } AsyncTaskExecutor executor = webAsyncTask.getExecutor(); if (executor != null) { this.taskExecutor = executor; } //初始化 interceptors //在asyncWebRequest 执行前后,执行完成,超时 等关键时间节点 执行 interceptors 逻辑... //启动异步处理 startAsyncProcessing(processingContext); // 线程池 执行callable方法.... this.taskExecutor.submit(new Runnable() { @Override public void run() { // interceptors 略.... Object result = callable.call(); //设置处理结果,并发送请求 setConcurrentResultAndDispatch(result); } }); } //调用asyncWebRequest.startAsync()启动异步处理 private void startAsyncProcessing(Object[] processingContext) { clearConcurrentResult(); this.concurrentResultContext = processingContext; this.asyncWebRequest.startAsync(); } //判断是否已经有异步处理结果 public boolean hasConcurrentResult() { //concurrentResult 初始化时 = RESULT_NONE return (this.concurrentResult != RESULT_NONE); } //设置处理结果,并发送请求 private void setConcurrentResultAndDispatch(Object result) { synchronized (WebAsyncManager.this) { //判断是否已经有异步处理结果 if (hasConcurrentResult()) { return; } //将result设置为当前处理结果 this.concurrentResult = result; } //如果异步请求在这里已经被设置为异步处理完成状态,则记录错误日志。(网络异常会造成此种问题) if (this.asyncWebRequest.isAsyncComplete()) { logger.error("Could not complete async processing due to timeout or network error"); return; } //再次发送请求:SpringMVC请求处理完成之后再次发送一个相同的请求。在HandlerAdapter做特殊处理 this.asyncWebRequest.dispatch(); }
SpringMVC 对异步的支持
SpringMVC想要支持异步处理,首先DispatchServlet要配置:<async-supported>true</async-supported>,其次请求方法的返回值为:Callable,WebAsyncTask,,DeferredResult 和 ListenableFuture
@Controller @RequestMapping("/async") public class AsyncController { @RequestMapping(value = "/callable",produces = "text/plain;charset=UTF-8") @ResponseBody public Callable<String> callable(){ System.out.println("Callable进入主线程..."); Callable<String> result = new Callable<String>() { @Override public String call() throws Exception { Thread.sleep(5 * 1000); System.out.println("Callable子线程执行ing..."); return "Callable:"+"久等了"; } }; System.out.println("Callable主线程退出..."); return result; } @RequestMapping(value = "/web",produces = "text/plain;charset=UTF-8") @ResponseBody public WebAsyncTask<String> web(){ System.out.println("WebAsyncTask 进入主线程..."); WebAsyncTask task = new WebAsyncTask(new Callable() { @Override public Object call() throws Exception { Thread.sleep(5 * 1000); System.out.println("WebAsyncTask 子线程执行ing..."); return "WebAsyncTask:"+"久等了"; } }); System.out.println("WebAsyncTask 主线程退出..."); return task; } @RequestMapping(value = "/deferred",produces = "text/plain;charset=UTF-8") @ResponseBody public DeferredResult<String> deferred(){ //这里的 7 * 1000 L ,是指主线程结束之后的超时时间。 DeferredResult<String> result = new DeferredResult<String>(7 * 1000L , "超时了"); approve(result); try { Thread.sleep(10 * 1000); //在主线程执行这段代码,并不会抛出"超时了" } catch (InterruptedException e) { } return result; } private void approve(final DeferredResult<String> result) { new Thread(() -> { try { Thread.sleep(5 * 1000); result.setResult("同意:" + LocalDateTime.now()); } catch (InterruptedException e) { } }).start(); } @RequestMapping(value = "/future",produces = "text/plain;charset=UTF-8") public ListenableFuture<ResponseEntity<String>> future(){ ListenableFuture<ResponseEntity<String>> future = new AsyncRestTemplate().getForEntity("http://www.baidu.com", String.class); return future; } }
源码跟踪
springMVC异步处理请求的过程是总体上可以拆分为2次:
- 第一次,启动异步请求,并设置
timeout,completion等事件的监听,直接返回 null; - 第二次,当监听到
completion时,直接在发送一次相同的请求,并将执行结果返回。
SpringMVC执行请求方法的过程都是在HandlerAdater中进行的。
在之前解析RequestMappingHandlerAdapter#invokeHandleMethod()处理请求时,将异步请求部分给剔除了,现在回看此方法:
//org.springframework.web.servlet.mvc.method.annotation.RequestMappingHandlerAdapter private ModelAndView invokeHandleMethod(HttpServletRequest request, HttpServletResponse response, HandlerMethod handlerMethod) throws Exception { ServletWebRequest webRequest = new ServletWebRequest(request, response); WebDataBinderFactory binderFactory = getDataBinderFactory(handlerMethod); ModelFactory modelFactory = getModelFactory(handlerMethod, binderFactory); ServletInvocableHandlerMethod requestMappingMethod = createRequestMappingMethod(handlerMethod, binderFactory); //mavContainer相关略...... AsyncWebRequest asyncWebRequest = WebAsyncUtils.createAsyncWebRequest(request, response); asyncWebRequest.setTimeout(this.asyncRequestTimeout); final WebAsyncManager asyncManager = WebAsyncUtils.getAsyncManager(request); asyncManager.setTaskExecutor(this.taskExecutor); asyncManager.setAsyncWebRequest(asyncWebRequest); asyncManager.registerCallableInterceptors(this.callableInterceptors); asyncManager.registerDeferredResultInterceptors(this.deferredResultInterceptors); //异步请求是否已经完成 if (asyncManager.hasConcurrentResult()) { //如果异步请求已经处理完成,则获取执行结果 --- 1 Object result = asyncManager.getConcurrentResult(); mavContainer = (ModelAndViewContainer) asyncManager.getConcurrentResultContext()[0]; //清空执行结果 asyncManager.clearConcurrentResult(); //覆盖原有的requestMappingMethod方法; --- 2 requestMappingMethod = requestMappingMethod.wrapConcurrentResult(result); } //执行方法 -- 3 requestMappingMethod.invokeAndHandle(webRequest, mavContainer); //asyncManager是否已经启动 if (asyncManager.isConcurrentHandlingStarted()) { //-- 4 return null; } // --- 5 return getModelAndView(mavContainer, modelFactory, webRequest); }
- 第一次执行时: 会执行上述代码中的
3,4 - 第二次执行时: 执行上述代码中的
1,2,3,5。 注意步骤2,会将原有的requestMappingMethod重写.接下来会分析。
ServletInvocableHandlerMethod.invokeAndHandle(webRequest, mavContainer)
springMVC在使用RequestMappingHandlerAdapter#invokeHandleMethod()处理请求时,会调用ServletInvocableHandlerMethod#invokeAndHandle()方法,该方法在处理完毕之后,会调用
this.returnValueHandlers.handleReturnValue(returnValue, getReturnValueType(returnValue), mavContainer, webRequest);`
处理返回值,针对上述四种类型的结果,匹配不同的XXReturnValueHandler.
Callable : CallableMethodReturnValueHandler
//org.springframework.web.servlet.mvc.method.annotation.CallableMethodReturnValueHandler @Override public void handleReturnValue(Object returnValue, MethodParameter returnType, ModelAndViewContainer mavContainer, NativeWebRequest webRequest) throws Exception { //if 略... Callable<?> callable = (Callable<?>) returnValue; WebAsyncUtils.getAsyncManager(webRequest).startCallableProcessing(callable, mavContainer); }
WebAsyncTask : AsyncTaskMethodReturnValueHandler
//org.springframework.web.servlet.mvc.method.annotation.AsyncTaskMethodReturnValueHandler @Override public void handleReturnValue(Object returnValue, MethodParameter returnType, ModelAndViewContainer mavContainer, NativeWebRequest webRequest) throws Exception { //if 略... WebAsyncTask<?> webAsyncTask = (WebAsyncTask<?>) returnValue; webAsyncTask.setBeanFactory(this.beanFactory); WebAsyncUtils.getAsyncManager(webRequest).startCallableProcessing(webAsyncTask, mavContainer); }
这里可以看出 Callable和webAsyncTask都是用了startCallableProcessing方法。
DeferredResult: DeferredResultMethodReturnValueHandler
//org.springframework.web.servlet.mvc.method.annotation.DeferredResultMethodReturnValueHandler @Override public void handleReturnValue(Object returnValue, MethodParameter returnType, ModelAndViewContainer mavContainer, NativeWebRequest webRequest) throws Exception { //if 略... DeferredResult<?> deferredResult = (DeferredResult<?>) returnValue; WebAsyncUtils.getAsyncManager(webRequest).startDeferredResultProcessing(deferredResult, mavContainer); }
DeferredResult: DeferredResultMethodReturnValueHandler
//org.springframework.web.servlet.mvc.method.annotation.ListenableFutureReturnValueHandler @Override public void handleReturnValue(Object returnValue, MethodParameter returnType, ModelAndViewContainer mavContainer, NativeWebRequest webRequest) throws Exception { //if 略... final DeferredResult<Object> deferredResult = new DeferredResult<Object>(); WebAsyncUtils.getAsyncManager(webRequest).startDeferredResultProcessing(deferredResult, mavContainer); ListenableFuture<?> future = (ListenableFuture<?>) returnValue; future.addCallback(new ListenableFutureCallback<Object>() { @Override public void onSuccess(Object result) { deferredResult.setResult(result); } @Override public void onFailure(Throwable ex) { deferredResult.setErrorResult(ex); } }); }
自此可以说明看 DeferredResult 和 ListenableFuture都是用了startDeferredResultProcessing方法。
ServletInvocableHandlerMethod.wrapConcurrentResult(result)
第二次请求时,要重点关注此行:requestMappingMethod.wrapConcurrentResult(result),此时的result已经是异步执行后的最终结果,不是DeferredResult.
//org.springframework.web.servlet.mvc.method.annotation.ServletInvocableHandlerMethod private static final Method CALLABLE_METHOD = ClassUtils.getMethod(Callable.class, "call"); public ServletInvocableHandlerMethod(Object handler, Method method) { super(handler, method); initResponseStatus(); } ServletInvocableHandlerMethod wrapConcurrentResult(Object result) { return new ConcurrentResultHandlerMethod(result, new ConcurrentResultMethodParameter(result)); } //org.springframework.web.servlet.mvc.method.annotation.ServletInvocableHandlerMethod $ ConcurrentResultMethodParameter private class ConcurrentResultMethodParameter extends HandlerMethodParameter { private final Object returnValue; private final ResolvableType returnType; //直接传入返回值returnValue, 返回值的类型为 returnValue的类型 public ConcurrentResultMethodParameter(Object returnValue) { super(-1); this.returnValue = returnValue; this.returnType = ResolvableType.forType(super.getGenericParameterType()).getGeneric(0); } } //org.springframework.web.servlet.mvc.method.annotation.ServletInvocableHandlerMethod $ ConcurrentResultHandlerMethod private class ConcurrentResultHandlerMethod extends ServletInvocableHandlerMethod { public ConcurrentResultHandlerMethod(final Object result, ConcurrentResultMethodParameter returnType) { //调用父类的构造方法(handler,method),最终调用 method.invoke(); super(new Callable<Object>() { @Override public Object call() throws Exception { if (result instanceof Exception) { throw (Exception) result; } else if (result instanceof Throwable) { throw new NestedServletException("Async processing failed", (Throwable) result); } //此时的result即为最终异步处理的结果. return result; } }, CALLABLE_METHOD); setHandlerMethodReturnValueHandlers(ServletInvocableHandlerMethod.this.returnValueHandlers); this.returnType = returnType; } }
第二次执行 requestMappingMethod.invokeAndHandle(webRequest, mavContainer);,此时的requestMappingMethod已经是伪造后的结果,该方法的返回值也被伪造为ConcurrentResultMethodParameter,最终调用的为ConcurrentResultHandlerMethod在构造函数中定义的Callable.call();
SpringMVC想要支持异步处理,首先DispatchServlet要配置:<async-supported>true</async-supported>,其次请求方法的返回值为:Callable,WebAsyncTask,,DeferredResult 和 ListenableFuture
<task:executor />配置参数:
- id:当配置多个executor时,被@Async(“id”)指定使用;也被作为线程名的前缀。
- pool-size:
- core size:最小的线程数,缺省:1
- max size:最大的线程数,缺省:Integer.MAX_VALUE
- queue-capacity:当最小的线程数已经被占用满后,新的任务会被放进queue里面,当这个queue的capacity也被占满之后,pool里面会创建新线程处理这个任务,直到总线程数达到了max size,这时系统会拒绝这个任务并抛出TaskRejectedException异常(缺省配置的情况下,可以通过rejection-policy来决定如何处理这种情况)。缺省值为:Integer.MAX_VALUE
- keep-alive:超过core size的那些线程,任务完成后,再经过这个时长(秒)会被结束掉
- rejection-policy:当pool已经达到max size的时候,如何处理新任务
- ABORT(缺省):抛出TaskRejectedException异常,然后不执行
- DISCARD:不执行,也不抛出异常
- DISCARD_OLDEST:丢弃queue中最旧的那个任务
- CALLER_RUNS:不在新线程中执行任务,而是有调用者所在的线程来执行
Java编程方式的配置方法:
@Configuration @EnableAsync public class SpringConfig { /** Set the ThreadPoolExecutor's core pool size. */ private int corePoolSize = 10; /** Set the ThreadPoolExecutor's maximum pool size. */ private int maxPoolSize = 200; /** Set the capacity for the ThreadPoolExecutor's BlockingQueue. */ private int queueCapacity = 10; private String ThreadNamePrefix = "MyLogExecutor-"; @Bean public Executor logExecutor() { ThreadPoolTaskExecutor executor = new ThreadPoolTaskExecutor(); executor.setCorePoolSize(corePoolSize); executor.setMaxPoolSize(maxPoolSize); executor.setQueueCapacity(queueCapacity); executor.setThreadNamePrefix(ThreadNamePrefix); // rejection-policy:当pool已经达到max size的时候,如何处理新任务 // CALLER_RUNS:不在新线程中执行任务,而是有调用者所在的线程来执行 executor.setRejectedExecutionHandler(new ThreadPoolExecutor.CallerRunsPolicy()); executor.initialize(); return executor; } }