/* * Written by Doug Lea with assistance from members of JCP JSR-166 * Expert Group and released to the public domain, as explained at * http://creativecommons.org/licenses/publicdomain */ import java.util.*; import java.util.concurrent.*; //import jsr166y.*; public class MultipleProducersSingleConsumerLoops { static final int NCPUS = Runtime.getRuntime().availableProcessors(); static final Random rng = new Random(); static final ExecutorService pool = Executors.newCachedThreadPool(); static boolean print = false; static int producerSum; static int consumerSum; static synchronized void addProducerSum(int x) { producerSum += x; } static synchronized void addConsumerSum(int x) { consumerSum += x; } static synchronized void checkSum() { if (producerSum != consumerSum) throw new Error("CheckSum mismatch"); } // Number of elements passed around -- must be power of two // Elements are reused from pool to minimize alloc impact static final int POOL_SIZE = 1 << 8; static final int POOL_MASK = POOL_SIZE-1; static final Integer[] intPool = new Integer[POOL_SIZE]; static { for (int i = 0; i < POOL_SIZE; ++i) intPool[i] = Integer.valueOf(i); } // Number of puts by producers or takes by consumers static final int ITERS = 1 << 20; // max lag between a producer and consumer to avoid // this becoming a GC test rather than queue test. static final int LAG = (1 << 12); static final int LAG_MASK = LAG - 1; public static void main(String[] args) throws Exception { int maxn = 12; // NCPUS * 3 / 2; if (args.length > 0) maxn = Integer.parseInt(args[0]); warmup(); print = true; int k = 1; for (int i = 1; i <= maxn;) { System.out.println("Producers:" + i); oneTest(i, ITERS); if (i == k) { k = i << 1; i = i + (i >>> 1); } else i = k; } pool.shutdown(); } static void warmup() throws Exception { print = false; System.out.print("Warmup "); int it = 2000; for (int j = 5; j > 0; --j) { oneTest(j, it); System.out.print("."); it += 1000; } System.gc(); it = 20000; for (int j = 5; j > 0; --j) { oneTest(j, it); System.out.print("."); it += 10000; } System.gc(); System.out.println(); } static void oneTest(int n, int iters) throws Exception { int fairIters = iters/16; Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedTransferQueue "); oneRun(new LinkedTransferQueue(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedBlockingQueue "); oneRun(new LinkedBlockingQueue(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedBlockingQueue(cap)"); oneRun(new LinkedBlockingQueue(POOL_SIZE), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedBlockingDeque "); oneRun(new LinkedBlockingDeque(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("ArrayBlockingQueue "); oneRun(new ArrayBlockingQueue(POOL_SIZE), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("SynchronousQueue "); oneRun(new SynchronousQueue(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("SynchronousQueue(fair) "); oneRun(new SynchronousQueue(true), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedTransferQueue(xfer)"); oneRun(new LTQasSQ(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("LinkedTransferQueue(half)"); oneRun(new HalfSyncLTQ(), n, iters); Thread.sleep(100); // System.gc(); if (print) System.out.print("PriorityBlockingQueue "); oneRun(new PriorityBlockingQueue(), n, fairIters); Thread.sleep(100); // System.gc(); if (print) System.out.print("ArrayBlockingQueue(fair)"); oneRun(new ArrayBlockingQueue(POOL_SIZE, true), n, fairIters); } abstract static class Stage implements Runnable { final int iters; final BlockingQueue queue; final CyclicBarrier barrier; final Phaser lagPhaser; final int lag; Stage(BlockingQueue q, CyclicBarrier b, Phaser s, int iters, int lag) { queue = q; barrier = b; lagPhaser = s; this.iters = iters; this.lag = lag; } } static class Producer extends Stage { Producer(BlockingQueue q, CyclicBarrier b, Phaser s, int iters, int lag) { super(q, b, s, iters, lag); } public void run() { try { barrier.await(); int ps = 0; int r = hashCode(); int j = 0; for (int i = 0; i < iters; ++i) { r = LoopHelpers.compute7(r); Integer v = intPool[r & POOL_MASK]; int k = v.intValue(); queue.put(v); ps += k; if (++j == lag) { j = 0; lagPhaser.arriveAndAwaitAdvance(); } } addProducerSum(ps); barrier.await(); } catch (Exception ie) { ie.printStackTrace(); return; } } } static class Consumer extends Stage { Consumer(BlockingQueue q, CyclicBarrier b, Phaser s, int iters, int lag) { super(q, b, s, iters, lag); } public void run() { try { barrier.await(); int cs = 0; int j = 0; for (int i = 0; i < iters; ++i) { Integer v = queue.take(); int k = v.intValue(); cs += k; if (++j == lag) { j = 0; lagPhaser.arriveAndAwaitAdvance(); } } addConsumerSum(cs); barrier.await(); } catch (Exception ie) { ie.printStackTrace(); return; } } } static void oneRun(BlockingQueue q, int n, int iters) throws Exception { LoopHelpers.BarrierTimer timer = new LoopHelpers.BarrierTimer(); CyclicBarrier barrier = new CyclicBarrier(n + 2, timer); Phaser s = new Phaser(n + 1); for (int i = 0; i < n; ++i) { pool.execute(new Producer(q, barrier, s, iters, LAG)); } pool.execute(new Consumer(q, barrier, s, iters * n, LAG * n)); barrier.await(); barrier.await(); long time = timer.getTime(); checkSum(); if (print) System.out.println("\t: " + LoopHelpers.rightJustify(time / (iters * (n + 1))) + " ns per transfer"); } static final class LTQasSQ extends LinkedTransferQueue { LTQasSQ() { super(); } public void put(T x) { try { super.transfer(x); } catch (InterruptedException ex) { throw new Error(); } } } static final class HalfSyncLTQ extends LinkedTransferQueue { int calls; HalfSyncLTQ() { super(); } public void put(T x) { if ((++calls & 1) == 0) super.put(x); else { try { super.transfer(x); } catch (InterruptedException ex) { throw new Error(); } } } } }