Disruptor之粗糙认识
一 概述
1.Disruptor
Disruptor是一个高性能的异步处理框架,一个“生产者-消费者”模型。
2.RingBuffer
RingBuffer是一种环形数据结构,包含一个指向下一个槽点的序号,可以在线程间传递数据。
3.Event
在Disruptor框架中,生产者生产的数据叫做Event。
二 Disruptor框架基本构成
1.MyEvent:自定义对象,充当“生产者-消费者”模型中的数据。
2.MyEventFactory:实现EventFactory的接口,用于生产数据。
3.MyEventProducerWithTranslator:将数据存储到自定义对象中并发布。
4.MyEventHandler:自定义消费者。
三 Demo
初次接触Disruptor,认识停留在表面,零散,模糊,在此记一个简单的示例,以便日后深入研究。
1.自定义数据类
package com.disruptor.basic; public class LongEvent { private long value; public long getValue() { return value; } public void setValue(long value) { this.value = value; } }
2.数据生产工厂(创建数据类对象)
package com.disruptor.basic; import com.lmax.disruptor.EventFactory; public class LongEventFactory implements EventFactory<LongEvent> { public LongEvent newInstance() { // TODO Auto-generated method stub return new LongEvent(); } }
3.数据源(初始化数据对象并发布)
package com.disruptor.basic; import java.nio.ByteBuffer; import com.lmax.disruptor.EventTranslatorOneArg; import com.lmax.disruptor.RingBuffer; public class LongEventProducerWithTranslator { private final RingBuffer<LongEvent> ringBuffer; public LongEventProducerWithTranslator(RingBuffer<LongEvent> ringBuffer) { this.ringBuffer = ringBuffer; } private final EventTranslatorOneArg<LongEvent, ByteBuffer> TRANSLATOR = new EventTranslatorOneArg<LongEvent, ByteBuffer>() { /** * event:包含有消费数据的对象; sequence:分配给目标对象的RingBuffer空间序号; * bb:包含有将要被存储到目标对象中的数据的容器 */ public void translateTo(LongEvent event, long sequence, ByteBuffer bb) { // TODO Auto-generated method stub event.setValue(bb.getLong(0));// 将数据存储到目标对象中 } }; public void onData(ByteBuffer bb) { ringBuffer.publishEvent(TRANSLATOR, bb);// 发布,将数据推送给消费者 } }
4.消费者
package com.disruptor.basic; import com.lmax.disruptor.EventHandler; public class LongEventHandler implements EventHandler<LongEvent> { public void onEvent(LongEvent event, long sequence, boolean endOfBatch) throws Exception { // TODO Auto-generated method stub System.out.println("当前消费的数据="+event.getValue()); } }
5.测试类
package com.disruptor.basic; import java.nio.ByteBuffer; import java.util.concurrent.ExecutorService; import java.util.concurrent.Executors; import org.junit.Test; import com.lmax.disruptor.EventFactory; import com.lmax.disruptor.RingBuffer; import com.lmax.disruptor.YieldingWaitStrategy; import com.lmax.disruptor.dsl.Disruptor; import com.lmax.disruptor.dsl.ProducerType; public class LongEventTest { @SuppressWarnings({ "unchecked", "deprecation" }) @Test public void test01() throws InterruptedException { ExecutorService executor = Executors.newCachedThreadPool(); EventFactory<LongEvent> factory = new LongEventFactory(); int bufferSize = 1024; Disruptor<LongEvent> disruptor = new Disruptor<LongEvent>(factory, bufferSize, executor, ProducerType.SINGLE, new YieldingWaitStrategy()); disruptor.handleEventsWith(new LongEventHandler()); disruptor.start(); RingBuffer<LongEvent> ringBuffer = disruptor.getRingBuffer(); // LongEventProducer producer = new // LongEventProducer(ringBuffer); LongEventProducerWithTranslator producer = new LongEventProducerWithTranslator(ringBuffer); ByteBuffer bb = ByteBuffer.allocate(8); // long startTime = System.currentTimeMillis(); for (long a = 0; a < 100; a++) { bb.putLong(0, a); producer.onData(bb); /*if (a == 99) { long endTime = System.currentTimeMillis(); System.out.println("useTime=" + (endTime - startTime)); }*/ Thread.sleep(100); } /*long endTime = System.currentTimeMillis(); System.out.println("useTime=" + (endTime - startTime));*/ disruptor.shutdown(); executor.shutdown(); } /*@Test public void test02() { long startTime = System.currentTimeMillis(); for (long a = 0; a < 100; a++) { System.out.println(a); } long endTime = System.currentTimeMillis(); System.out.println("useTime=" + (endTime - startTime)); }*/ }
不能仅仅停滞在实现上,应该去追求代价更小、性能更优的实现