响应式编程Reactor优化Callback回调地狱

1. Reactor是什么

• Reactor 是一个基于Reactive Streams规范的响应式编程框架。它提供了一组用于构建异步、事件驱动、响应式应用程序的工具和库。Reactor 的核心是 Flux（表示一个包含零到多个元素的异步序列）和 Mono表示一个包含零或一个元素的异步序列）。
• Reactor 通过提供响应式的操作符，如map、filter、flatMap等，使得开发者能够方便地进行数据流的转换和处理。

2. Reactor、Callback、CompletableFuture三种形式异步编码对比

• 编码简洁程度Reactor最优
• Reactor线程利用率最高（因实现了Reactive Streams规范，拥有背压+事件驱动特性，此处暂不展开)

代码如下：

pom依赖

<dependencyManagement> <dependencies> <dependency> <groupId>io.projectreactor</groupId> <artifactId>reactor-bom</artifactId> <version>2023.0.0</version> <type>pom</type> <scope>import</scope> </dependency> </dependencies></dependencyManagement><dependencies> <dependency> <groupId>io.projectreactor</groupId> <artifactId>reactor-core</artifactId> </dependency></dependencies>

Callback回调地狱

interface FirstCallback {void onCompleteFirst(String result);void onErrorFirst(Exception e);}interface SecondCallback {void onCompleteSecond(String result);void onErrorSecond(Exception e);}interface ThirdCallback {void onCompleteThird(String result);void onErrorThird(Exception e);}class AsyncOperations {static void firstOperation(FirstCallback firstCallback) {new Thread(() -> {try {// 模拟异步操作Thread.sleep(2000);// 操作完成后调用回调函数firstCallback.onCompleteFirst("First operation completed");} catch (Exception e) {// 发生异常时调用错误回调firstCallback.onErrorFirst(e);}}).start();}static void secondOperation(String input, SecondCallback secondCallback) {new Thread(() -> {try {// 模拟异步操作Thread.sleep(2000);// 操作完成后调用回调函数secondCallback.onCompleteSecond("Second operation completed with input: " + input);} catch (Exception e) {// 发生异常时调用错误回调secondCallback.onErrorSecond(e);}}).start();}static void thirdOperation(String input, ThirdCallback thirdCallback) {new Thread(() -> {try {// 模拟异步操作Thread.sleep(2000);// 操作完成后调用回调函数thirdCallback.onCompleteThird("Third operation completed with input: " + input);} catch (Exception e) {// 发生异常时调用错误回调thirdCallback.onErrorThird(e);}}).start();}}public class CallbackHellExample {public static void main(String[] args) {AsyncOperations.firstOperation(new FirstCallback() {@Overridepublic void onCompleteFirst(String result) {System.out.println("First Callback: " + result);// 第一次操作完成后调用第二次操作AsyncOperations.secondOperation(result, new SecondCallback() {@Overridepublic void onCompleteSecond(String result) {System.out.println("Second Callback: " + result);// 第二次操作完成后调用第三次操作AsyncOperations.thirdOperation(result, new ThirdCallback() {@Overridepublic void onCompleteThird(String result) {System.out.println("Third Callback: " + result);}@Overridepublic void onErrorThird(Exception e) {System.out.println("Error in Third Callback: " + e.getMessage());}});}@Overridepublic void onErrorSecond(Exception e) {System.out.println("Error in Second Callback: " + e.getMessage());}});}@Overridepublic void onErrorFirst(Exception e) {System.out.println("Error in First Callback: " + e.getMessage());}});// 主线程继续执行其他操作System.out.println("Main thread continues...");}}

CompletableFuture优化Callback回调地狱

public class CompletableFutureExample {public static void main(String[] args) {CompletableFuture<String> firstOperation = CompletableFuture.supplyAsync(() -> {try {// 模拟异步操作Thread.sleep(2000);return "First operation completed";} catch (InterruptedException e) {throw new RuntimeException(e);}});CompletableFuture<String> secondOperation = firstOperation.thenApplyAsync(result -> {System.out.println("First CompletableFuture: " + result);try {// 模拟异步操作Thread.sleep(2000);return "Second operation completed with input: " + result;} catch (InterruptedException e) {throw new RuntimeException(e);}});CompletableFuture<String> thirdOperation = secondOperation.thenApplyAsync(result -> {System.out.println("Second CompletableFuture: " + result);try {// 模拟异步操作Thread.sleep(2000);return "Third operation completed with input: " + result;} catch (InterruptedException e) {throw new RuntimeException(e);}});thirdOperation.whenComplete((result, throwable) -> {if (throwable == null) {System.out.println("Third CompletableFuture: " + result);} else {System.out.println("Error in CompletableFuture: " + throwable.getMessage());}});// 主线程继续执行其他操作System.out.println("Main thread continues...");// 等待所有操作完成CompletableFuture.allOf(firstOperation, secondOperation, thirdOperation).join();}}

Reactor优化Callback回调地狱

public class ReactorOptimizedExample {public static void main(String[] args) {Mono.fromCallable(() -> {// 模拟异步操作Thread.sleep(2000);return "First operation completed";}).subscribeOn(Schedulers.boundedElastic()).flatMap(result -> {System.out.println("First Reactor: " + result);return Mono.fromCallable(() -> {// 模拟异步操作Thread.sleep(2000);return "Second operation completed with input: " + result;}).subscribeOn(Schedulers.boundedElastic());}).flatMap(result -> {System.out.println("Second Reactor: " + result);return Mono.fromCallable(() -> {// 模拟异步操作Thread.sleep(2000);return "Third operation completed with input: " + result;}).subscribeOn(Schedulers.boundedElastic());}).doOnSuccess(result -> System.out.println("Third Reactor: " + result)).doOnError(error -> System.out.println("Error in Reactor: " + error.getMessage())).block(); // 阻塞等待操作完成// 主线程继续执行其他操作System.out.println("Main thread continues...");}}

学习打卡：Java学习笔记-day06-响应式编程Reactor优化Callback回调地狱