如果只是需要用这个框架,请往下看即可。如果需要深入了解这个框架是如何一步一步实现的,从接到需求,到每一步的思考,每个类为什么这么设计,为什么有这些方法,也就是如何从0到1开发出这个框架,作者在[csdn开了专栏](https://blog.csdn.net/tianyaleixiaowu/category_9637010.html)专门讲中间件如何从0开发,包括并不限于这个小框架。京东内部同事可在cf上搜索erp也能看到。 京东同事通过引用如下maven来使用。测试下 ``` com.jd.platform asyncTool 1.4.2-SNAPSHOT ``` 外网请使用jitpack.io上打的包 先添加repositories节点 ``` jitpack.io https://jitpack.io ``` 然后添加如下maven依赖 ``` com.gitee.jd-platform-opensource asyncTool V1.4-SNAPSHOT ``` #### 基本组件 worker: 一个最小的任务执行单元。通常是一个网络调用,或一段耗时操作。 T,V两个泛型,分别是入参和出参类型。 譬如该耗时操作,入参是String,执行完毕的结果是Integer,那么就可以用泛型来定义。 多个不同的worker之间,没有关联,分别可以有不同的入参、出参类型。 ``` /** * 每个最小执行单元需要实现该接口 * @author wuweifeng wrote on 2019-11-19. */ public interface IWorker { /** * 在这里做耗时操作,如rpc请求、IO等 * * @param object * object */ V action(T object, Map allWrappers); /** * 超时、异常时,返回的默认值 * @return 默认值 */ V defaultValue(); } ``` callBack:对每个worker的回调。worker执行完毕后,会回调该接口,带着执行成功、失败、原始入参、和详细的结果。 ``` /** * 每个执行单元执行完毕后,会回调该接口

* 需要监听执行结果的,实现该接口即可 * @author wuweifeng wrote on 2019-11-19. */ public interface ICallback { void begin(); /** * 耗时操作执行完毕后,就给value注入值 * */ void result(boolean success, T param, WorkResult workResult); } ``` wrapper:组合了worker和callback,是一个 **最小的调度单元** 。通过编排wrapper之间的关系,达到组合各个worker顺序的目的。 wrapper的泛型和worker的一样,决定了入参和结果的类型。 ``` WorkerWrapper workerWrapper = new WorkerWrapper<>(w, "0", w); WorkerWrapper workerWrapper1 = new WorkerWrapper<>(w1, "1", w1); WorkerWrapper workerWrapper2 = new WorkerWrapper<>(w2, "2", w2); WorkerWrapper workerWrapper3 = new WorkerWrapper<>(w3, "3", w3); ``` 如 ![输入图片说明](https://images.gitee.com/uploads/images/2019/1225/132251_b7cfac23_303698.png "屏幕截图.png") 0执行完,同时1和2, 1\2都完成后3。3会等待2完成 此时,你可以定义一个 **worker** ``` /** * @author wuweifeng wrote on 2019-11-20. */ public class ParWorker1 implements IWorker, ICallback { @Override public String action(String object) { try { Thread.sleep(1000); } catch (InterruptedException e) { e.printStackTrace(); } return "result = " + SystemClock.now() + "---param = " + object + " from 1"; } @Override public String defaultValue() { return "worker1--default"; } @Override public void begin() { //System.out.println(Thread.currentThread().getName() + "- start --" + System.currentTimeMillis()); } @Override public void result(boolean success, String param, WorkResult workResult) { if (success) { System.out.println("callback worker1 success--" + SystemClock.now() + "----" + workResult.getResult() + "-threadName:" +Thread.currentThread().getName()); } else { System.err.println("callback worker1 failure--" + SystemClock.now() + "----" + workResult.getResult() + "-threadName:" +Thread.currentThread().getName()); } } } ``` 通过这一个类看一下,action里就是你的耗时操作,begin就是任务开始执行时的回调,result就是worker执行完毕后的回调。当你组合了多个执行单元时,每一步的执行,都在掌控之内。失败了,还会有自定义的默认值。这是CompleteableFuture无法做到的。 #### 安装教程 代码不多,直接拷贝包过去即可。 #### 使用说明 1. 3个任务并行 ![输入图片说明](https://images.gitee.com/uploads/images/2019/1226/140256_8c015621_303698.png "屏幕截图.png") ``` ParWorker w = new ParWorker(); ParWorker1 w1 = new ParWorker1(); ParWorker2 w2 = new ParWorker2(); WorkerWrapper workerWrapper2 = new WorkerWrapper.Builder() .worker(w2) .callback(w2) .param("2") .build(); WorkerWrapper workerWrapper1 = new WorkerWrapper.Builder() .worker(w1) .callback(w1) .param("1") .build(); WorkerWrapper workerWrapper = new WorkerWrapper.Builder() .worker(w) .callback(w) .param("0") .build(); long now = SystemClock.now(); System.out.println("begin-" + now); Async.beginWork(1500, workerWrapper, workerWrapper1, workerWrapper2); // Async.beginWork(800, workerWrapper, workerWrapper1, workerWrapper2); // Async.beginWork(1000, workerWrapper, workerWrapper1, workerWrapper2); System.out.println("end-" + SystemClock.now()); System.err.println("cost-" + (SystemClock.now() - now)); System.out.println(Async.getThreadCount()); System.out.println(workerWrapper.getWorkResult()); Async.shutDown(); ``` 2. 1个执行完毕后,开启另外两个,另外两个执行完毕后,开始第4个 ![输入图片说明](https://images.gitee.com/uploads/images/2019/1226/140405_93800bc7_303698.png "屏幕截图.png") ``` ParWorker w = new ParWorker(); ParWorker1 w1 = new ParWorker1(); ParWorker2 w2 = new ParWorker2(); ParWorker3 w3 = new ParWorker3(); WorkerWrapper workerWrapper3 = new WorkerWrapper.Builder() .worker(w3) .callback(w3) .param("3") .build(); WorkerWrapper workerWrapper2 = new WorkerWrapper.Builder() .worker(w2) .callback(w2) .param("2") .next(workerWrapper3) .build(); WorkerWrapper workerWrapper1 = new WorkerWrapper.Builder() .worker(w1) .callback(w1) .param("1") .next(workerWrapper3) .build(); WorkerWrapper workerWrapper = new WorkerWrapper.Builder() .worker(w) .callback(w) .param("0") .next(workerWrapper1, workerWrapper2) .build(); long now = SystemClock.now(); System.out.println("begin-" + now); Async.beginWork(3100, workerWrapper); // Async.beginWork(2100, workerWrapper); System.out.println("end-" + SystemClock.now()); System.err.println("cost-" + (SystemClock.now() - now)); System.out.println(Async.getThreadCount()); Async.shutDown(); ``` 如果觉得这样不符合左右的顺序,也可以用这种方式: ``` WorkerWrapper workerWrapper = new WorkerWrapper.Builder() .worker(w) .callback(w) .param("0") .build(); WorkerWrapper workerWrapper3 = new WorkerWrapper.Builder() .worker(w3) .callback(w3) .param("3") .build(); WorkerWrapper workerWrapper2 = new WorkerWrapper.Builder() .worker(w2) .callback(w2) .param("2") .depend(workerWrapper) .next(workerWrapper3) .build(); WorkerWrapper workerWrapper1 = new WorkerWrapper.Builder() .worker(w1) .callback(w1) .param("1") .depend(workerWrapper) .next(workerWrapper3) .build(); ``` 3. 复杂点的 ![输入图片说明](https://images.gitee.com/uploads/images/2019/1226/140445_8d52e4d6_303698.png "屏幕截图.png") 在测试类里能找到,下图是执行结果。看时间戳,就知道执行的顺序。每个执行单元都是睡1秒。 ![输入图片说明](https://images.gitee.com/uploads/images/2019/1225/133828_0c76624c_303698.png "屏幕截图.png") 4. 依赖别的worker执行结果作为入参 可以从action的参数中根据wrapper的id获取任意一个执行单元的执行结果,但请注意执行顺序,如果尚未执行,则在调用WorkerResult.getResult()会得到null! ![输入图片说明](https://images.gitee.com/uploads/images/2020/0511/215924_28af8655_303698.png "屏幕截图.png")![输入图片说明](https://images.gitee.com/uploads/images/2020/0511/215933_12e13dba_303698.png "屏幕截图.png") 5. 其他的详见test包下的测试类,支持各种形式的组合、编排。