test/loops/MultipleProducersSingleConsumerLoops.java

/*
 * 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/publicdomain/zero/1.0/
 */

import java.util.concurrent.ArrayBlockingQueue;
import java.util.concurrent.BlockingQueue;
import java.util.concurrent.CyclicBarrier;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.LinkedBlockingDeque;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.LinkedTransferQueue;
import java.util.concurrent.Phaser;
import java.util.concurrent.PriorityBlockingQueue;
import java.util.concurrent.SynchronousQueue;

public class MultipleProducersSingleConsumerLoops {
    static final int NCPUS = Runtime.getRuntime().availableProcessors();
    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;
        for (int k = 1, 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<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("LinkedBlockingQueue     ");
        oneRun(new LinkedBlockingQueue<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("LinkedBlockingQueue(cap)");
        oneRun(new LinkedBlockingQueue<Integer>(POOL_SIZE), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("LinkedBlockingDeque     ");
        oneRun(new LinkedBlockingDeque<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("ArrayBlockingQueue      ");
        oneRun(new ArrayBlockingQueue<Integer>(POOL_SIZE), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("SynchronousQueue        ");
        oneRun(new SynchronousQueue<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("SynchronousQueue(fair)  ");
        oneRun(new SynchronousQueue<Integer>(true), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("LinkedTransferQueue(xfer)");
        oneRun(new LTQasSQ<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("LinkedTransferQueue(half)");
        oneRun(new HalfSyncLTQ<Integer>(), n, iters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("PriorityBlockingQueue   ");
        oneRun(new PriorityBlockingQueue<Integer>(), n, fairIters);

        Thread.sleep(100); // System.gc();
        if (print)
            System.out.print("ArrayBlockingQueue(fair)");
        oneRun(new ArrayBlockingQueue<Integer>(POOL_SIZE, true), n, fairIters);
    }

    abstract static class Stage implements Runnable {
        final int iters;
        final BlockingQueue<Integer> queue;
        final CyclicBarrier barrier;
        final Phaser lagPhaser;
        final int lag;
        Stage(BlockingQueue<Integer> 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<Integer> 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<Integer> 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<Integer> 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<T> extends LinkedTransferQueue<T> {
        LTQasSQ() { super(); }
        public void put(T x) {
            try { super.transfer(x);
            } catch (InterruptedException ex) { throw new Error(); }
        }
    }

    static final class HalfSyncLTQ<T> extends LinkedTransferQueue<T> {
        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();
                }
            }
        }
    }
}
Revision:	1.14
Committed:	Sat Dec 31 19:54:17 2016 UTC (7 years, 4 months ago) by jsr166
Branch:	MAIN
Changes since 1.13:	+0 -1 lines
Log Message:	remove unused Randoms
#	User	Rev	Content
1	dl	1.1	/*
2			* Written by Doug Lea with assistance from members of JCP JSR-166
3	dl	1.3	* Expert Group and released to the public domain, as explained at
4	jsr166	1.8	* http://creativecommons.org/publicdomain/zero/1.0/
5	dl	1.1	*/
6
7	jsr166	1.12	import java.util.concurrent.ArrayBlockingQueue;
8			import java.util.concurrent.BlockingQueue;
9			import java.util.concurrent.CyclicBarrier;
10			import java.util.concurrent.ExecutorService;
11			import java.util.concurrent.Executors;
12			import java.util.concurrent.LinkedBlockingDeque;
13			import java.util.concurrent.LinkedBlockingQueue;
14			import java.util.concurrent.LinkedTransferQueue;
15			import java.util.concurrent.Phaser;
16			import java.util.concurrent.PriorityBlockingQueue;
17			import java.util.concurrent.SynchronousQueue;
18	dl	1.1
19			public class MultipleProducersSingleConsumerLoops {
20	dl	1.4	static final int NCPUS = Runtime.getRuntime().availableProcessors();
21	dl	1.1	static final ExecutorService pool = Executors.newCachedThreadPool();
22			static boolean print = false;
23			static int producerSum;
24			static int consumerSum;
25			static synchronized void addProducerSum(int x) {
26			producerSum += x;
27			}
28
29			static synchronized void addConsumerSum(int x) {
30			consumerSum += x;
31			}
32
33			static synchronized void checkSum() {
34			if (producerSum != consumerSum)
35			throw new Error("CheckSum mismatch");
36			}
37
38	dl	1.4	// Number of elements passed around -- must be power of two
39			// Elements are reused from pool to minimize alloc impact
40			static final int POOL_SIZE = 1 << 8;
41			static final int POOL_MASK = POOL_SIZE-1;
42			static final Integer[] intPool = new Integer[POOL_SIZE];
43			static {
44	jsr166	1.5	for (int i = 0; i < POOL_SIZE; ++i)
45	dl	1.4	intPool[i] = Integer.valueOf(i);
46			}
47
48			// Number of puts by producers or takes by consumers
49			static final int ITERS = 1 << 20;
50
51	jsr166	1.5	// max lag between a producer and consumer to avoid
52	dl	1.4	// this becoming a GC test rather than queue test.
53			static final int LAG = (1 << 12);
54			static final int LAG_MASK = LAG - 1;
55
56	dl	1.1	public static void main(String[] args) throws Exception {
57	dl	1.4	int maxn = 12; // NCPUS * 3 / 2;
58	dl	1.1
59	jsr166	1.5	if (args.length > 0)
60	dl	1.4	maxn = Integer.parseInt(args[0]);
61	dl	1.1
62	dl	1.4	warmup();
63	dl	1.1	print = true;
64	jsr166	1.9	for (int k = 1, i = 1; i <= maxn;) {
65	dl	1.1	System.out.println("Producers:" + i);
66	dl	1.4	oneTest(i, ITERS);
67			if (i == k) {
68			k = i << 1;
69			i = i + (i >>> 1);
70	jsr166	1.5	}
71			else
72	dl	1.4	i = k;
73	dl	1.1	}
74			pool.shutdown();
75	dl	1.4	}
76
77			static void warmup() throws Exception {
78			print = false;
79			System.out.print("Warmup ");
80			int it = 2000;
81			for (int j = 5; j > 0; --j) {
82	jsr166	1.5	oneTest(j, it);
83	dl	1.4	System.out.print(".");
84			it += 1000;
85			}
86			System.gc();
87			it = 20000;
88			for (int j = 5; j > 0; --j) {
89	jsr166	1.5	oneTest(j, it);
90	dl	1.4	System.out.print(".");
91			it += 10000;
92			}
93			System.gc();
94			System.out.println();
95			}
96	dl	1.1
97	dl	1.4	static void oneTest(int n, int iters) throws Exception {
98			int fairIters = iters/16;
99
100			Thread.sleep(100); // System.gc();
101	dl	1.1	if (print)
102	dl	1.4	System.out.print("LinkedTransferQueue ");
103			oneRun(new LinkedTransferQueue<Integer>(), n, iters);
104	dl	1.1
105	dl	1.4	Thread.sleep(100); // System.gc();
106	dl	1.1	if (print)
107			System.out.print("LinkedBlockingQueue ");
108	dl	1.4	oneRun(new LinkedBlockingQueue<Integer>(), n, iters);
109	dl	1.1
110	dl	1.4	Thread.sleep(100); // System.gc();
111			if (print)
112			System.out.print("LinkedBlockingQueue(cap)");
113			oneRun(new LinkedBlockingQueue<Integer>(POOL_SIZE), n, iters);
114
115			Thread.sleep(100); // System.gc();
116			if (print)
117			System.out.print("LinkedBlockingDeque ");
118			oneRun(new LinkedBlockingDeque<Integer>(), n, iters);
119	jsr166	1.5
120	dl	1.4	Thread.sleep(100); // System.gc();
121			if (print)
122			System.out.print("ArrayBlockingQueue ");
123			oneRun(new ArrayBlockingQueue<Integer>(POOL_SIZE), n, iters);
124	dl	1.1
125	dl	1.4	Thread.sleep(100); // System.gc();
126	dl	1.1	if (print)
127			System.out.print("SynchronousQueue ");
128	dl	1.4	oneRun(new SynchronousQueue<Integer>(), n, iters);
129	dl	1.1
130	dl	1.4	Thread.sleep(100); // System.gc();
131	dl	1.1	if (print)
132	dl	1.2	System.out.print("SynchronousQueue(fair) ");
133	dl	1.4	oneRun(new SynchronousQueue<Integer>(true), n, iters);
134
135			Thread.sleep(100); // System.gc();
136			if (print)
137			System.out.print("LinkedTransferQueue(xfer)");
138			oneRun(new LTQasSQ<Integer>(), n, iters);
139
140			Thread.sleep(100); // System.gc();
141			if (print)
142			System.out.print("LinkedTransferQueue(half)");
143			oneRun(new HalfSyncLTQ<Integer>(), n, iters);
144	jsr166	1.5
145	dl	1.4	Thread.sleep(100); // System.gc();
146			if (print)
147			System.out.print("PriorityBlockingQueue ");
148			oneRun(new PriorityBlockingQueue<Integer>(), n, fairIters);
149	dl	1.2
150	dl	1.4	Thread.sleep(100); // System.gc();
151	dl	1.2	if (print)
152	dl	1.1	System.out.print("ArrayBlockingQueue(fair)");
153	dl	1.4	oneRun(new ArrayBlockingQueue<Integer>(POOL_SIZE, true), n, fairIters);
154	dl	1.1	}
155	jsr166	1.5
156	jsr166	1.7	abstract static class Stage implements Runnable {
157	dl	1.1	final int iters;
158			final BlockingQueue<Integer> queue;
159			final CyclicBarrier barrier;
160	dl	1.4	final Phaser lagPhaser;
161			final int lag;
162	jsr166	1.6	Stage(BlockingQueue<Integer> q, CyclicBarrier b, Phaser s,
163			int iters, int lag) {
164	jsr166	1.5	queue = q;
165	dl	1.1	barrier = b;
166	dl	1.4	lagPhaser = s;
167	dl	1.1	this.iters = iters;
168	dl	1.4	this.lag = lag;
169	dl	1.1	}
170			}
171
172			static class Producer extends Stage {
173	dl	1.4	Producer(BlockingQueue<Integer> q, CyclicBarrier b, Phaser s,
174			int iters, int lag) {
175			super(q, b, s, iters, lag);
176	dl	1.1	}
177
178			public void run() {
179			try {
180			barrier.await();
181	dl	1.4	int ps = 0;
182			int r = hashCode();
183			int j = 0;
184	dl	1.1	for (int i = 0; i < iters; ++i) {
185	dl	1.4	r = LoopHelpers.compute7(r);
186			Integer v = intPool[r & POOL_MASK];
187			int k = v.intValue();
188			queue.put(v);
189			ps += k;
190			if (++j == lag) {
191			j = 0;
192			lagPhaser.arriveAndAwaitAdvance();
193			}
194	dl	1.1	}
195	dl	1.4	addProducerSum(ps);
196	dl	1.1	barrier.await();
197			}
198	jsr166	1.5	catch (Exception ie) {
199			ie.printStackTrace();
200			return;
201	dl	1.1	}
202			}
203			}
204
205			static class Consumer extends Stage {
206	dl	1.4	Consumer(BlockingQueue<Integer> q, CyclicBarrier b, Phaser s,
207	jsr166	1.5	int iters, int lag) {
208	dl	1.4	super(q, b, s, iters, lag);
209	dl	1.1	}
210
211			public void run() {
212			try {
213			barrier.await();
214	dl	1.4	int cs = 0;
215			int j = 0;
216	dl	1.1	for (int i = 0; i < iters; ++i) {
217	dl	1.4	Integer v = queue.take();
218			int k = v.intValue();
219			cs += k;
220			if (++j == lag) {
221			j = 0;
222			lagPhaser.arriveAndAwaitAdvance();
223			}
224	dl	1.1	}
225	dl	1.4	addConsumerSum(cs);
226	dl	1.1	barrier.await();
227			}
228	jsr166	1.5	catch (Exception ie) {
229			ie.printStackTrace();
230			return;
231	dl	1.1	}
232			}
233
234			}
235
236	dl	1.4	static void oneRun(BlockingQueue<Integer> q, int n, int iters) throws Exception {
237
238	dl	1.1	LoopHelpers.BarrierTimer timer = new LoopHelpers.BarrierTimer();
239	dl	1.4	CyclicBarrier barrier = new CyclicBarrier(n + 2, timer);
240			Phaser s = new Phaser(n + 1);
241			for (int i = 0; i < n; ++i) {
242			pool.execute(new Producer(q, barrier, s, iters, LAG));
243	dl	1.1	}
244	dl	1.4	pool.execute(new Consumer(q, barrier, s, iters * n, LAG * n));
245	dl	1.1	barrier.await();
246			barrier.await();
247			long time = timer.getTime();
248			checkSum();
249			if (print)
250	dl	1.4	System.out.println("\t: " + LoopHelpers.rightJustify(time / (iters * (n + 1))) + " ns per transfer");
251			}
252	jsr166	1.5
253	dl	1.4	static final class LTQasSQ<T> extends LinkedTransferQueue<T> {
254			LTQasSQ() { super(); }
255			public void put(T x) {
256	jsr166	1.5	try { super.transfer(x);
257	dl	1.4	} catch (InterruptedException ex) { throw new Error(); }
258			}
259	dl	1.1	}
260
261	dl	1.4	static final class HalfSyncLTQ<T> extends LinkedTransferQueue<T> {
262			int calls;
263			HalfSyncLTQ() { super(); }
264			public void put(T x) {
265			if ((++calls & 1) == 0)
266			super.put(x);
267			else {
268	jsr166	1.5	try { super.transfer(x);
269			} catch (InterruptedException ex) {
270			throw new Error();
271	dl	1.4	}
272			}
273			}
274			}
275	dl	1.1	}