顺序和并行处理

multithreading java synchronization locking

2022-09-02 23:44:35

我有一个生产者和许多消费者。

生产者速度快，产生很多结果
具有相同值的令牌需要按顺序处理
必须并行处理具有不同值的令牌
创建新的Runnables将非常昂贵，并且生产代码也可以使用100k的Token（为了创建Runnable，我必须传递给构造函数一些复杂的来构建对象）

我可以使用更简单的算法获得相同的结果吗？使用重入锁定嵌套同步块似乎有点不自然。您是否注意到任何争用条件？

更新：我发现的第二个解决方案是使用3个集合。一个用于缓存生产者结果，第二个是阻塞队列，第三个使用列表来跟踪正在进行的任务。再次有点复杂。

我的代码版本

import java.util.*;
import java.util.concurrent.*;
import java.util.concurrent.locks.ReentrantLock;

public class Main1 {
    static class Token {
        private int order;
        private String value;
        Token() {

        }
        Token(int o, String v) {
            order = o;
            value = v;
        }

        int getOrder() {
            return order;
        }

        String getValue() {
            return value;
        }
    }

    private final static BlockingQueue<Token> queue = new ArrayBlockingQueue<Token>(10);
    private final static ConcurrentMap<String, Object> locks = new ConcurrentHashMap<String, Object>();
    private final static ReentrantLock reentrantLock = new ReentrantLock();
    private final static Token STOP_TOKEN = new Token();
    private final static List<String> lockList = Collections.synchronizedList(new ArrayList<String>());

    public static void main(String[] args) {
        ExecutorService producerExecutor = Executors.newSingleThreadExecutor();
        producerExecutor.submit(new Runnable() {
            public void run() {
                Random random = new Random();
                    try {
                        for (int i = 1; i <= 100; i++) {
                            Token token = new Token(i, String.valueOf(random.nextInt(1)));

                            queue.put(token);
                        }

                        queue.put(STOP_TOKEN);
                    }catch(InterruptedException e){
                        e.printStackTrace();
                    }
                }
        });

        ExecutorService consumerExecutor = Executors.newFixedThreadPool(10);
        for(int i=1; i<=10;i++) {

            // creating to many runnable would be inefficient because of this complex not thread safe object
            final Object dependecy = new Object(); //new ComplexDependecy()
            consumerExecutor.submit(new Runnable() {
                public void run() {
                    while(true) {
                        try {
                            //not in order


                            Token token = queue.take();
                            if (token == STOP_TOKEN) {
                                queue.add(STOP_TOKEN);
                                return;
                            }


                            System.out.println("Task start" + Thread.currentThread().getId() + " order "  + token.getOrder());

                            Random random = new Random();
                            Thread.sleep(random.nextInt(200)); //doLongRunningTask(dependecy)
                            lockList.remove(token.getValue());

                        } catch (InterruptedException e) {
                            e.printStackTrace();
                        }
                    }
            }});

    }
}}

答案 1

您可以预先创建一组将挑选传入任务（令牌）并根据其订单值将它们放入队列中。Runnables

正如评论中指出的那样，不能保证具有不同值的令牌将始终并行执行（总而言之，您至少受到框中物理内核数量的限制）。但是，可以保证具有相同订单的令牌将按到达顺序执行。

示例代码：

/**
 * Executor which ensures incoming tasks are executed in queues according to provided key (see {@link Task#getOrder()}).
 */
public class TasksOrderingExecutor {

    public interface Task extends Runnable {
        /**
         * @return ordering value which will be used to sequence tasks with the same value.<br>
         * Tasks with different ordering values <i>may</i> be executed in parallel, but not guaranteed to.
         */
        String getOrder();
    }

    private static class Worker implements Runnable {

        private final LinkedBlockingQueue<Task> tasks = new LinkedBlockingQueue<>();

        private volatile boolean stopped;

        void schedule(Task task) {
            tasks.add(task);
        }

        void stop() {
            stopped = true;
        }

        @Override
        public void run() {
            while (!stopped) {
                try {
                    Task task = tasks.take();
                    task.run();
                } catch (InterruptedException ie) {
                    // perhaps, handle somehow
                }
            }
        }
    }

    private final Worker[] workers;
    private final ExecutorService executorService;

    /**
     * @param queuesNr nr of concurrent task queues
     */
    public TasksOrderingExecutor(int queuesNr) {
        Preconditions.checkArgument(queuesNr >= 1, "queuesNr >= 1");
        executorService = new ThreadPoolExecutor(queuesNr, queuesNr, 0, TimeUnit.SECONDS, new SynchronousQueue<>());
        workers = new Worker[queuesNr];
        for (int i = 0; i < queuesNr; i++) {
            Worker worker = new Worker();
            executorService.submit(worker);
            workers[i] = worker;
        }
    }

    public void submit(Task task) {
        Worker worker = getWorker(task);
        worker.schedule(task);
    }

    public void stop() {
        for (Worker w : workers) w.stop();
        executorService.shutdown();
    }

    private Worker getWorker(Task task) {
        return workers[task.getOrder().hashCode() % workers.length];
    }
}

答案 2

根据代码的性质，保证以串行方式处理具有相同值的令牌的唯一方法是等待STOP_TOKEN到达。

您需要单生产者-单使用者设置，消费者按其值收集和排序令牌（例如，进入多地图）。

只有这样，您才知道哪些令牌可以按顺序处理，哪些令牌可以并行处理。

无论如何，我建议你看看LMAX Disruptor，它为线程之间的数据共享提供了非常有效的方法。

它不会像执行器那样遭受同步开销的影响，因为它是无锁的（这可能会给你带来不错的性能优势，这取决于你处理数据的方式）。

使用两个颠覆者的解决方案

// single thread for processing as there will be only on consumer
Disruptor<InEvent> inboundDisruptor = new Disruptor<>(InEvent::new, 32, Executors.newSingleThreadExecutor());

// outbound disruptor that uses 3 threads for event processing
Disruptor<OutEvent> outboundDisruptor = new Disruptor<>(OutEvent::new, 32, Executors.newFixedThreadPool(3));

inboundDisruptor.handleEventsWith(new InEventHandler(outboundDisruptor));

// setup 3 event handlers, doing round robin consuming, effectively processing OutEvents in 3 threads
outboundDisruptor.handleEventsWith(new OutEventHandler(0, 3, new Object()));
outboundDisruptor.handleEventsWith(new OutEventHandler(1, 3, new Object()));
outboundDisruptor.handleEventsWith(new OutEventHandler(2, 3, new Object()));

inboundDisruptor.start();
outboundDisruptor.start();

// publisher code
for (int i = 0; i < 10; i++) {
    inboundDisruptor.publishEvent(InEventTranslator.INSTANCE, new Token());
}

入站中断器上的事件处理程序仅收集传入的令牌。当收到 STOP 令牌时，它会将一系列令牌发布到出站中断器以进行进一步处理：

public class InEventHandler implements EventHandler<InEvent> {

    private ListMultimap<String, Token> tokensByValue = ArrayListMultimap.create();
    private Disruptor<OutEvent> outboundDisruptor;

    public InEventHandler(Disruptor<OutEvent> outboundDisruptor) {
        this.outboundDisruptor = outboundDisruptor;
    }

    @Override
    public void onEvent(InEvent event, long sequence, boolean endOfBatch) throws Exception {
        if (event.token == STOP_TOKEN) {
            // publish indexed tokens to outbound disruptor for parallel processing
            tokensByValue.asMap().entrySet().stream().forEach(entry -> outboundDisruptor.publishEvent(OutEventTranslator.INSTANCE, entry.getValue()));
        } else {
            tokensByValue.put(event.token.value, event.token);
        }
    }
}

出站事件处理程序按顺序处理相同值的令牌：

public class OutEventHandler implements EventHandler<OutEvent> {

    private final long order;
    private final long allHandlersCount;
    private Object yourComplexDependency;

    public OutEventHandler(long order, long allHandlersCount, Object yourComplexDependency) {
        this.order = order;
        this.allHandlersCount = allHandlersCount;
        this.yourComplexDependency = yourComplexDependency;
    }

    @Override
    public void onEvent(OutEvent event, long sequence, boolean endOfBatch) throws Exception {
        if (sequence % allHandlersCount != order ) {
            // round robin, do not consume every event to allow parallel processing
            return;
        }

        for (Token token : event.tokensToProcessSerially) {
            // do procesing of the token using your complex class
        }

    }
}

其余所需的基础结构（在 Disruptor 文档中描述的目的）：

public class InEventTranslator implements EventTranslatorOneArg<InEvent, Token> {

    public static final InEventTranslator INSTANCE = new InEventTranslator();

    @Override
    public void translateTo(InEvent event, long sequence, Token arg0) {
        event.token = arg0;
    }

}

public class OutEventTranslator implements EventTranslatorOneArg<OutEvent, Collection<Token>> {

    public static final OutEventTranslator INSTANCE = new OutEventTranslator();

    @Override
    public void translateTo(OutEvent event, long sequence, Collection<Token> tokens) {
        event.tokensToProcessSerially = tokens;
    }
}


public class InEvent {

    // Note that no synchronization is used here,
    // even though the field is used among multiple threads.
    // Memory barrier used by Disruptor guarantee changes are visible.
    public Token token;
}

public class OutEvent {
    // ... again, no locks.
    public Collection<Token> tokensToProcessSerially;

}

public class Token {
    String value;

}