背景
在使用dubbo时,通常会遇到timeout这个属性,timeout属性的作用是:给某个服务调用设置超时时间,如果服务在设置的时间内未返回结果,则会抛出调用超时异常:TimeoutException,在使用的过程中,我们有时会对provider和consumer两个配置都会设置timeout值,那么服务调用过程中会以哪个为准?本文主要针对这个问题进行分析和扩展
三种设置方式
以provider配置为例:
- 方法级别
设置方式如下所示:
<dubbo:service interface="fy.test.service.TestService" ref="testServiceImpl">
<dubbo:method name="test" timeout="10000"/>
</dubbo:service>
- 接口级别
<dubbo:service interface="fy.test.service.TestService" ref="testServiceImpl" timeout="10000"/>
- 全局级别
<dubbo:provider timeout="10000"/>
优先级选择
在dubbo中如果provider和consumer都配置了相同的一个属性,比如本文分析的timeout,其实是有一个优先级的,优先级:
consumer方法配置 > provider方法配置 > consumer接口配置 > provider接口配置 > consumer全局配置 > provider全局配置。所以对于本文开始的提出的问题就有了结果,会以消费者配置的为准,接下结合源码来进行解析,其实源码很简单,在RegistryDirectory类中将服务列表转换为DubboInvlker方法中进行了处理:
private Map<String, Invoker<T>> toInvokers(List<URL> urls) {
Map<String, Invoker<T>> newUrlInvokerMap = new HashMap<String, Invoker<T>>();
if (urls == null || urls.isEmpty()) {
return newUrlInvokerMap;
}
Set<String> keys = new HashSet<String>();
String queryProtocols = this.queryMap.get(Constants.PROTOCOL_KEY);
for (URL providerUrl : urls) {
// If protocol is configured at the reference side, only the matching protocol is selected
if (queryProtocols != null && queryProtocols.length() > 0) {
boolean accept = false;
String[] acceptProtocols = queryProtocols.split(",");
for (String acceptProtocol : acceptProtocols) {
if (providerUrl.getProtocol().equals(acceptProtocol)) {
accept = true;
break;
}
}
if (!accept) {
continue;
}
}
if (Constants.EMPTY_PROTOCOL.equals(providerUrl.getProtocol())) {
continue;
}
if (!ExtensionLoader.getExtensionLoader(Protocol.class).hasExtension(providerUrl.getProtocol())) {
logger.error(new IllegalStateException("Unsupported protocol " + providerUrl.getProtocol() +
" in notified url: " + providerUrl + " from registry " + getUrl().getAddress() +
" to consumer " + NetUtils.getLocalHost() + ", supported protocol: " +
ExtensionLoader.getExtensionLoader(Protocol.class).getSupportedExtensions()));
continue;
}
// 重点就是下面这个方法
URL url = mergeUrl(providerUrl);
String key = url.toFullString(); // The parameter urls are sorted
if (keys.contains(key)) { // Repeated url
continue;
}
keys.add(key);
// Cache key is url that does not merge with consumer side parameters, regardless of how the consumer combines parameters, if the server url changes, then refer again
Map<String, Invoker<T>> localUrlInvokerMap = this.urlInvokerMap; // local reference
Invoker<T> invoker = localUrlInvokerMap == null ? null : localUrlInvokerMap.get(key);
if (invoker == null) { // Not in the cache, refer again
try {
boolean enabled = true;
if (url.hasParameter(Constants.DISABLED_KEY)) {
enabled = !url.getParameter(Constants.DISABLED_KEY, false);
} else {
enabled = url.getParameter(Constants.ENABLED_KEY, true);
}
if (enabled) {
invoker = new InvokerDelegate<T>(protocol.refer(serviceType, url), url, providerUrl);
}
} catch (Throwable t) {
logger.error("Failed to refer invoker for interface:" + serviceType + ",url:(" + url + ")" + t.getMessage(), t);
}
if (invoker != null) { // Put new invoker in cache
newUrlInvokerMap.put(key, invoker);
}
} else {
newUrlInvokerMap.put(key, invoker);
}
}
keys.clear();
return newUrlInvokerMap;
}
重点就是上面mergeUrl()方法,将provider和comsumer的url参数进行了整合,在
mergeUrl()方法有会调用ClusterUtils.mergeUrl方法进行整合,因为这个方法比较简单,就是对一些参数进行了整合了,会用consumer参数进行覆盖,咱们这里就不分析了,如果感兴趣的同学可以去研究一下。
超时处理
在配置设置了超时timeout,那么代码中是如何处理的,这里咱们在进行一下扩展,分析一下dubbo中是如何处理超时的,在调用服务方法,最后都会调用DubboInvoker.doInvoke方法,咱们就从这个方法开始分析:
@Override
protected Result doInvoke(final Invocation invocation) throws Throwable {
RpcInvocation inv = (RpcInvocation) invocation;
final String methodName = RpcUtils.getMethodName(invocation);
inv.setAttachment(Constants.PATH_KEY, getUrl().getPath());
inv.setAttachment(Constants.VERSION_KEY, version);
ExchangeClient currentClient;
if (clients.length == 1) {
currentClient = clients[0];
} else {
currentClient = clients[index.getAndIncrement() % clients.length];
}
try {
boolean isAsync = RpcUtils.isAsync(getUrl(), invocation);
boolean isAsyncFuture = RpcUtils.isReturnTypeFuture(inv);
boolean isOneway = RpcUtils.isOneway(getUrl(), invocation);
int timeout = getUrl().getMethodParameter(methodName, Constants.TIMEOUT_KEY, Constants.DEFAULT_TIMEOUT);
if (isOneway) {
boolean isSent = getUrl().getMethodParameter(methodName, Constants.SENT_KEY, false);
currentClient.send(inv, isSent);
RpcContext.getContext().setFuture(null);
return new RpcResult();
} else if (isAsync) {
ResponseFuture future = currentClient.request(inv, timeout);
// For compatibility
FutureAdapter<Object> futureAdapter = new FutureAdapter<>(future);
RpcContext.getContext().setFuture(futureAdapter);
Result result;
// 异步处理
if (isAsyncFuture) {
// register resultCallback, sometimes we need the async result being processed by the filter chain.
result = new AsyncRpcResult(futureAdapter, futureAdapter.getResultFuture(), false);
} else {
result = new SimpleAsyncRpcResult(futureAdapter, futureAdapter.getResultFuture(), false);
}
return result;
} else {
// 同步处理
RpcContext.getContext().setFuture(null);
return (Result) currentClient.request(inv, timeout).get();
}
} catch (TimeoutException e) {
throw new RpcException(RpcException.TIMEOUT_EXCEPTION, "Invoke remote method timeout. method: " + invocation.getMethodName() + ", provider: " + getUrl() + ", cause: " + e.getMessage(), e);
} catch (RemotingException e) {
throw new RpcException(RpcException.NETWORK_EXCEPTION, "Failed to invoke remote method: " + invocation.getMethodName() + ", provider: " + getUrl() + ", cause: " + e.getMessage(), e);
}
}
在这个方法中,咱们就以同步模式进行分析,看request方法,request()方法会返回一个DefaultFuture类,在去调用DefaultFuture.get()方法,这里其实涉及到一个在异步中实现同步的技巧,咱们这里不做分析,所以重点就在get()方法里:
@Override
public Object get() throws RemotingException {
return get(timeout);
}
@Override
public Object get(int timeout) throws RemotingException {
if (timeout <= 0) {
timeout = Constants.DEFAULT_TIMEOUT;
}
if (!isDone()) {
long start = System.currentTimeMillis();
lock.lock();
try {
while (!isDone()) {
done.await(timeout, TimeUnit.MILLISECONDS);
if (isDone() || System.currentTimeMillis() - start > timeout) {
break;
}
}
} catch (InterruptedException e) {
throw new RuntimeException(e);
} finally {
lock.unlock();
}
if (!isDone()) {
throw new TimeoutException(sent > 0, channel, getTimeoutMessage(false));
}
}
return returnFromResponse();
}
在调用get()方法时,会去调用get(timeout)这个方法,在这个方法中会传一个timeout字段,在和timeout就是咱们配置的那个参数,在这个方法中咱们要关注下面一个代码块:
if (!isDone()) {
long start = System.currentTimeMillis();
lock.lock();
try {
while (!isDone()) {
// 线程阻塞
done.await(timeout, TimeUnit.MILLISECONDS);
if (isDone() || System.currentTimeMillis() - start > timeout) {
break;
}
}
} catch (InterruptedException e) {
throw new RuntimeException(e);
} finally {
lock.unlock();
}
// 在超时时间里,还没有结果,则抛出超时异常
if (!isDone()) {
throw new TimeoutException(sent > 0, channel, getTimeoutMessage(false));
}
}
重点看await()方法,会进行阻塞timeout时间,如果阻塞时间到了,则会唤醒往下执行,超时跳出while循环中,判断是否有结果返回,如果没有(这个地方要注意:只有有结果返回,或超时才跳出循环中),则抛出超时异常。讲到这里,超时原理基本上其实差不多了,DefaultFuture这个类还有个地方需要注意,在初始化DefaultFuture对象时,会去创建一个超时的延迟任务,延迟时间就是timeout值,在这个延迟任务中也会调用signal()方法唤醒阻塞
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