如何编写可观察量以避免给定的嵌套和依赖回调?

2022-09-02 03:22:39

这篇博客中,他给出了这个(复制/粘贴以下代码)回调地狱的例子。但是,没有提到如何使用反应式扩展来消除此问题。

所以这里 F3 依赖于 F1 完成,F4 和 F5 依赖于 F2 完成。

  1. 想知道Rx中的功能等效物是什么。
  2. 如何在Rx中表示F1,F2,F3,F4和F5都应该异步拉动?

注意:我目前正在尝试围绕Rx进行思考,因此在提出此问题之前,我没有尝试解决此示例。

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.ThreadPoolExecutor;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicReference;

public class CallbackB {

    /**
     * Demonstration of nested callbacks which then need to composes their responses together.
     * <p>
     * Various different approaches for composition can be done but eventually they end up relying upon
     * synchronization techniques such as the CountDownLatch used here or converge on callback design
     * changes similar to <a href="https://github.com/Netflix/RxJava">Rx</a>.
     */
    public static void run() throws Exception {
        final ExecutorService executor = new ThreadPoolExecutor(4, 4, 1, TimeUnit.MINUTES, new LinkedBlockingQueue<Runnable>());
        /* the following are used to synchronize and compose the asynchronous callbacks */
        final CountDownLatch latch = new CountDownLatch(3);
        final AtomicReference<String> f3Value = new AtomicReference<String>();
        final AtomicReference<Integer> f4Value = new AtomicReference<Integer>();
        final AtomicReference<Integer> f5Value = new AtomicReference<Integer>();

        try {
            // get f3 with dependent result from f1
            executor.execute(new CallToRemoteServiceA(new Callback<String>() {

                @Override
                public void call(String f1) {
                    executor.execute(new CallToRemoteServiceC(new Callback<String>() {

                        @Override
                        public void call(String f3) {
                            // we have f1 and f3 now need to compose with others
                            System.out.println("intermediate callback: " + f3 + " => " + ("f4 * f5"));
                            // set to thread-safe variable accessible by external scope 
                            f3Value.set(f3);
                            latch.countDown();
                        }

                    }, f1));
                }

            }));

            // get f4/f5 after dependency f2 completes 
            executor.execute(new CallToRemoteServiceB(new Callback<Integer>() {

                @Override
                public void call(Integer f2) {
                    executor.execute(new CallToRemoteServiceD(new Callback<Integer>() {

                        @Override
                        public void call(Integer f4) {
                            // we have f2 and f4 now need to compose with others
                            System.out.println("intermediate callback: f3" + " => " + (f4 + " * f5"));
                            // set to thread-safe variable accessible by external scope 
                            f4Value.set(f4);
                            latch.countDown();
                        }

                    }, f2));
                    executor.execute(new CallToRemoteServiceE(new Callback<Integer>() {

                        @Override
                        public void call(Integer f5) {
                            // we have f2 and f5 now need to compose with others
                            System.out.println("intermediate callback: f3" + " => " + ("f4 * " + f5));
                            // set to thread-safe variable accessible by external scope 
                            f5Value.set(f5);
                            latch.countDown();
                        }

                    }, f2));
                }

            }));

            /* we must wait for all callbacks to complete */
            latch.await();
            System.out.println(f3Value.get() + " => " + (f4Value.get() * f5Value.get()));
        } finally {
            executor.shutdownNow();
        }
    }

    public static void main(String[] args) {
        try {
            run();
        } catch (Exception e) {
            e.printStackTrace();
        }
    }

    private static final class CallToRemoteServiceA implements Runnable {

        private final Callback<String> callback;

        private CallToRemoteServiceA(Callback<String> callback) {
            this.callback = callback;
        }

        @Override
        public void run() {
            // simulate fetching data from remote service
            try {
                Thread.sleep(100);
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
            callback.call("responseA");
        }
    }

    private static final class CallToRemoteServiceB implements Runnable {

        private final Callback<Integer> callback;

        private CallToRemoteServiceB(Callback<Integer> callback) {
            this.callback = callback;
        }

        @Override
        public void run() {
            // simulate fetching data from remote service
            try {
                Thread.sleep(40);
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
            callback.call(100);
        }
    }

    private static final class CallToRemoteServiceC implements Runnable {

        private final Callback<String> callback;
        private final String dependencyFromA;

        private CallToRemoteServiceC(Callback<String> callback, String dependencyFromA) {
            this.callback = callback;
            this.dependencyFromA = dependencyFromA;
        }

        @Override
        public void run() {
            // simulate fetching data from remote service
            try {
                Thread.sleep(60);
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
            callback.call("responseB_" + dependencyFromA);
        }
    }

    private static final class CallToRemoteServiceD implements Runnable {

        private final Callback<Integer> callback;
        private final Integer dependencyFromB;

        private CallToRemoteServiceD(Callback<Integer> callback, Integer dependencyFromB) {
            this.callback = callback;
            this.dependencyFromB = dependencyFromB;
        }

        @Override
        public void run() {
            // simulate fetching data from remote service
            try {
                Thread.sleep(140);
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
            callback.call(40 + dependencyFromB);
        }
    }

    private static final class CallToRemoteServiceE implements Runnable {

        private final Callback<Integer> callback;
        private final Integer dependencyFromB;

        private CallToRemoteServiceE(Callback<Integer> callback, Integer dependencyFromB) {
            this.callback = callback;
            this.dependencyFromB = dependencyFromB;
        }

        @Override
        public void run() {
            // simulate fetching data from remote service
            try {
                Thread.sleep(55);
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
            callback.call(5000 + dependencyFromB);
        }
    }

    private static interface Callback<T> {
        public void call(T value);
    }
}

答案 1

我是关于回调和Java Futures的引用博客文章的原始作者。下面是使用 flatMap、zip 和 merge 异步执行服务组合的示例。

它获取一个 User 对象,然后同时获取社交和个性化目录数据,然后对于个性化目录中的每个视频,同时获取书签、评级和元数据,将它们压缩在一起,并将所有响应合并到一个渐进式流输出中,作为服务器发送的事件。

return getUser(userId).flatMap(user -> {
    Observable<Map<String, Object>> catalog = getPersonalizedCatalog(user)
            .flatMap(catalogList -> catalogList.videos().<Map<String, Object>> flatMap(
                    video -> {
                        Observable<Bookmark> bookmark = getBookmark(video);
                        Observable<Rating> rating = getRatings(video);
                        Observable<VideoMetadata> metadata = getVideoMetadata(video);
                        return Observable.zip(bookmark, rating, metadata, (b, r, m) -> combineVideoData(video, b, r, m));
                    }));

    Observable<Map<String, Object>> social = getSocial(user).map(s -> {
        return s.getDataAsMap();
    });

    return Observable.merge(catalog, social);
}).flatMap(data -> {
    String json = SimpleJson.mapToJson(data);
    return response.writeStringAndFlush("data: " + json + "\n");
});

此示例可以在正常运行的应用程序的上下文中看到,https://github.com/Netflix/ReactiveLab/blob/952362b89a4d4115ae0eecf0e73f273ecb27ba98/reactive-lab-gateway/src/main/java/io/reactivex/lab/gateway/routes/RouteForDeviceHome.java#L33

由于我无法在此处提供所有信息,因此您也可以在 https://speakerdeck.com/benjchristensen/reactive-streams-with-rx-at-javaone-2014?slide=32 找到演示形式的解释(带有视频链接)。


答案 2

根据您的代码。假设远程调用是使用 完成的。Observable

 Observable<Integer>  callRemoveServiceA()  { /* async call */  }

/* .... */

Observable<Integer>  callRemoveServiceE(Integer f2) { /* async call */  }

你想要什么 :

  • 调用然后调用的结果serviceAserviceBserviceA
  • 呼叫然后呼叫并带有结果serviceCserviceDserviceEserviceC
  • 用 和 的结果,建立一个新的值serviceEserviceD
  • 显示新值,其结果为serviceB

使用RxJava,您将通过以下代码实现这一点:

Observable<Integer> f3 = callRemoveServiceA() // call serviceA
            // call serviceB with the result of serviceA
            .flatMap((f1) -> callRemoveServiceB(f1)); 


Observable<Integer> f4Andf5 = callRemoveServiceC() // call serviceC
                    // call serviceD and serviceE then build a new value
                    .flatMap((f2) -> callRemoveServiceD(f2).zipWith(callRemoveServiceE(f2), (f4, f5) -> f4 * f5));

// compute the string to display from f3, and the f4, f5 pair
f3.zipWith(f4Andf5, (childF3, childF4Andf5) -> childF3 + " => " + childF4Andf5)
            // display the value
            .subscribe(System.out::println);

这里重要的部分是使用和(或flapMapzipzipWith)

你可以在这里获得更多关于flapMap的信息:你什么时候在RxJava中使用map与flatMap?