聊聊flink的RpcServer

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本文主要研究一下 flink 的 RpcServer
RpcGateway
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/RpcGateway.java
public interface RpcGateway {

/**
* Returns the fully qualified address under which the associated rpc endpoint is reachable.
*
* @return Fully qualified (RPC) address under which the associated rpc endpoint is reachable
*/
String getAddress();

/**
* Returns the fully qualified hostname under which the associated rpc endpoint is reachable.
*
* @return Fully qualified hostname under which the associated rpc endpoint is reachable
*/
String getHostname();
}
RpcGateway 定义了 getAddress、getHostname 两个方法
MainThreadExecutable
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/MainThreadExecutable.java
public interface MainThreadExecutable {

/**
* Execute the runnable in the main thread of the underlying RPC endpoint.
*
* @param runnable Runnable to be executed
*/
void runAsync(Runnable runnable);

/**
* Execute the callable in the main thread of the underlying RPC endpoint and return a future for
* the callable result. If the future is not completed within the given timeout, the returned
* future will throw a {@link TimeoutException}.
*
* @param callable Callable to be executed
* @param callTimeout Timeout for the future to complete
* @param <V> Return value of the callable
* @return Future of the callable result
*/
<V> CompletableFuture<V> callAsync(Callable<V> callable, Time callTimeout);

/**
* Execute the runnable in the main thread of the underlying RPC endpoint, with
* a delay of the given number of milliseconds.
*
* @param runnable Runnable to be executed
* @param delay The delay, in milliseconds, after which the runnable will be executed
*/
void scheduleRunAsync(Runnable runnable, long delay);
}
MainThreadExecutable 定义了 runAsync、callAsync、scheduleRunAsync 三个方法
StartStoppable
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/StartStoppable.java
public interface StartStoppable {

/**
* Starts the processing of remote procedure calls.
*/
void start();

/**
* Stops the processing of remote procedure calls.
*/
void stop();
}
StartStoppable 定义了 start、stop 方法
RpcServer
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/RpcServer.java
public interface RpcServer extends StartStoppable, MainThreadExecutable, RpcGateway {

/**
* Return a future which is completed when the rpc endpoint has been terminated.
*
* @return Future indicating when the rpc endpoint has been terminated
*/
CompletableFuture<Void> getTerminationFuture();
}
RpcServer 接口继承了 RpcGateway、MainThreadExecutable、StartStoppable 三个接口,另外定义了 getTerminationFuture 方法;它有两个实现类,分别是 AkkaInvocationHandler、FencedAkkaInvocationHandler;其中 FencedAkkaInvocationHandler 继承了 AkkaInvocationHandler
AkkaBasedEndpoint
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/akka/AkkaBasedEndpoint.java
interface AkkaBasedEndpoint extends RpcGateway {

/**
* Returns the {@link ActorRef} of the underlying RPC actor.
*
* @return the {@link ActorRef} of the underlying RPC actor
*/
ActorRef getActorRef();
}
AkkaBasedEndpoint 接口继承了 RpcGateway 接口,它另外定义了 getActorRef() 方法用于获取 ActorRef
AkkaInvocationHandler
flink-release-1.7.2/flink-runtime/src/main/java/org/apache/flink/runtime/rpc/akka/AkkaInvocationHandler.java
class AkkaInvocationHandler implements InvocationHandler, AkkaBasedEndpoint, RpcServer {
private static final Logger LOG = LoggerFactory.getLogger(AkkaInvocationHandler.class);

/**
* The Akka (RPC) address of {@link #rpcEndpoint} including host and port of the ActorSystem in
* which the actor is running.
*/
private final String address;

/**
* Hostname of the host, {@link #rpcEndpoint} is running on.
*/
private final String hostname;

private final ActorRef rpcEndpoint;

// whether the actor ref is local and thus no message serialization is needed
protected final boolean isLocal;

// default timeout for asks
private final Time timeout;

private final long maximumFramesize;

// null if gateway; otherwise non-null
@Nullable
private final CompletableFuture<Void> terminationFuture;

AkkaInvocationHandler(
String address,
String hostname,
ActorRef rpcEndpoint,
Time timeout,
long maximumFramesize,
@Nullable CompletableFuture<Void> terminationFuture) {

this.address = Preconditions.checkNotNull(address);
this.hostname = Preconditions.checkNotNull(hostname);
this.rpcEndpoint = Preconditions.checkNotNull(rpcEndpoint);
this.isLocal = this.rpcEndpoint.path().address().hasLocalScope();
this.timeout = Preconditions.checkNotNull(timeout);
this.maximumFramesize = maximumFramesize;
this.terminationFuture = terminationFuture;
}

@Override
public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
Class<?> declaringClass = method.getDeclaringClass();

Object result;

if (declaringClass.equals(AkkaBasedEndpoint.class) ||
declaringClass.equals(Object.class) ||
declaringClass.equals(RpcGateway.class) ||
declaringClass.equals(StartStoppable.class) ||
declaringClass.equals(MainThreadExecutable.class) ||
declaringClass.equals(RpcServer.class)) {
result = method.invoke(this, args);
} else if (declaringClass.equals(FencedRpcGateway.class)) {
throw new UnsupportedOperationException(“AkkaInvocationHandler does not support the call FencedRpcGateway#” +
method.getName() + “. This indicates that you retrieved a FencedRpcGateway without specifying a ” +
“fencing token. Please use RpcService#connect(RpcService, F, Time) with F being the fencing token to ” +
“retrieve a properly FencedRpcGateway.”);
} else {
result = invokeRpc(method, args);
}

return result;
}

@Override
public ActorRef getActorRef() {
return rpcEndpoint;
}

@Override
public void runAsync(Runnable runnable) {
scheduleRunAsync(runnable, 0L);
}

@Override
public void scheduleRunAsync(Runnable runnable, long delayMillis) {
checkNotNull(runnable, “runnable”);
checkArgument(delayMillis >= 0, “delay must be zero or greater”);

if (isLocal) {
long atTimeNanos = delayMillis == 0 ? 0 : System.nanoTime() + (delayMillis * 1_000_000);
tell(new RunAsync(runnable, atTimeNanos));
} else {
throw new RuntimeException(“Trying to send a Runnable to a remote actor at ” +
rpcEndpoint.path() + “. This is not supported.”);
}
}

@Override
public <V> CompletableFuture<V> callAsync(Callable<V> callable, Time callTimeout) {
if (isLocal) {
@SuppressWarnings(“unchecked”)
CompletableFuture<V> resultFuture = (CompletableFuture<V>) ask(new CallAsync(callable), callTimeout);

return resultFuture;
} else {
throw new RuntimeException(“Trying to send a Callable to a remote actor at ” +
rpcEndpoint.path() + “. This is not supported.”);
}
}

@Override
public void start() {
rpcEndpoint.tell(Processing.START, ActorRef.noSender());
}

@Override
public void stop() {
rpcEndpoint.tell(Processing.STOP, ActorRef.noSender());
}

// ————————————————————————
// Private methods
// ————————————————————————

private Object invokeRpc(Method method, Object[] args) throws Exception {
String methodName = method.getName();
Class<?>[] parameterTypes = method.getParameterTypes();
Annotation[][] parameterAnnotations = method.getParameterAnnotations();
Time futureTimeout = extractRpcTimeout(parameterAnnotations, args, timeout);

final RpcInvocation rpcInvocation = createRpcInvocationMessage(methodName, parameterTypes, args);

Class<?> returnType = method.getReturnType();

final Object result;

if (Objects.equals(returnType, Void.TYPE)) {
tell(rpcInvocation);

result = null;
} else if (Objects.equals(returnType, CompletableFuture.class)) {
// execute an asynchronous call
result = ask(rpcInvocation, futureTimeout);
} else {
// execute a synchronous call
CompletableFuture<?> futureResult = ask(rpcInvocation, futureTimeout);

result = futureResult.get(futureTimeout.getSize(), futureTimeout.getUnit());
}

return result;
}

protected RpcInvocation createRpcInvocationMessage(
final String methodName,
final Class<?>[] parameterTypes,
final Object[] args) throws IOException {
final RpcInvocation rpcInvocation;

if (isLocal) {
rpcInvocation = new LocalRpcInvocation(
methodName,
parameterTypes,
args);
} else {
try {
RemoteRpcInvocation remoteRpcInvocation = new RemoteRpcInvocation(
methodName,
parameterTypes,
args);

if (remoteRpcInvocation.getSize() > maximumFramesize) {
throw new IOException(“The rpc invocation size exceeds the maximum akka framesize.”);
} else {
rpcInvocation = remoteRpcInvocation;
}
} catch (IOException e) {
LOG.warn(“Could not create remote rpc invocation message. Failing rpc invocation because…”, e);
throw e;
}
}

return rpcInvocation;
}

// ————————————————————————
// Helper methods
// ————————————————————————

private static Time extractRpcTimeout(Annotation[][] parameterAnnotations, Object[] args, Time defaultTimeout) {
if (args != null) {
Preconditions.checkArgument(parameterAnnotations.length == args.length);

for (int i = 0; i < parameterAnnotations.length; i++) {
if (isRpcTimeout(parameterAnnotations[i])) {
if (args[i] instanceof Time) {
return (Time) args[i];
} else {
throw new RuntimeException(“The rpc timeout parameter must be of type ” +
Time.class.getName() + “. The type ” + args[i].getClass().getName() +
” is not supported.”);
}
}
}
}

return defaultTimeout;
}

private static boolean isRpcTimeout(Annotation[] annotations) {
for (Annotation annotation : annotations) {
if (annotation.annotationType().equals(RpcTimeout.class)) {
return true;
}
}

return false;
}

protected void tell(Object message) {
rpcEndpoint.tell(message, ActorRef.noSender());
}

protected CompletableFuture<?> ask(Object message, Time timeout) {
return FutureUtils.toJava(
Patterns.ask(rpcEndpoint, message, timeout.toMilliseconds()));
}

@Override
public String getAddress() {
return address;
}

@Override
public String getHostname() {
return hostname;
}

@Override
public CompletableFuture<Void> getTerminationFuture() {
return terminationFuture;
}
}

AkkaInvocationHandler 实现了 RpcServer、AkkaBasedEndpoint、jdk 的 InvocationHandler 接口;其构造器要求输入 address、hostname、rpcEndpoint(ActorRef)、terminationFuture;getAddress、getHostname、getTerminationFuture 均直接返回对应的属性
runAsync 方法内部调用的是 scheduleRunAsync;scheduleRunAsync 方法使用的是 tell 方法,调用 rpcEndpoint.tell 传递 RunAsync 消息;callAsync 方法使用的是 ask 方法,调用 Patterns.ask,传递 CallAsync 消息
start 方法执行 rpcEndpoint.tell(Processing.START, ActorRef.noSender());stop 方法执行 rpcEndpoint.tell(Processing.STOP, ActorRef.noSender());invoke 方法针对 Object、RpcGateway、MainThreadExecutable、StartStoppable、AkkaBasedEndpoint、RpcServer 的方法则对当前对象进行对应方法调用,针对 FencedRpcGateway 的方法抛出 UnsupportedOperationException,其余的方法则内部调用 invokeRpc 方法,构造 RpcInvocation 消息进行调用

小结

RpcServer 接口继承了 RpcGateway、MainThreadExecutable、StartStoppable 三个接口,另外定义了 getTerminationFuture 方法;它有两个实现类,分别是 AkkaInvocationHandler、FencedAkkaInvocationHandler;其中 FencedAkkaInvocationHandler 继承了 AkkaInvocationHandler
AkkaInvocationHandler 实现了 RpcServer、AkkaBasedEndpoint、jdk 的 InvocationHandler 接口;其构造器要求输入 address、hostname、rpcEndpoint(ActorRef)、terminationFuture;getAddress、getHostname、getTerminationFuture 均直接返回对应的属性;runAsync 方法内部调用的是 scheduleRunAsync;scheduleRunAsync 方法使用的是 tell 方法,调用 rpcEndpoint.tell 传递 RunAsync 消息;callAsync 方法使用的是 ask 方法,调用 Patterns.ask,传递 CallAsync 消息
AkkaInvocationHandler 的 start 方法执行 rpcEndpoint.tell(Processing.START, ActorRef.noSender());stop 方法执行 rpcEndpoint.tell(Processing.STOP, ActorRef.noSender());invoke 方法针对 Object、RpcGateway、MainThreadExecutable、StartStoppable、AkkaBasedEndpoint、RpcServer 的方法则对当前对象进行对应方法调用,针对 FencedRpcGateway 的方法抛出 UnsupportedOperationException,其余的方法则内部调用 invokeRpc 方法,构造 RpcInvocation 消息进行调用

doc
RpcServer

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