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I was just running some multithreaded code on a 4-core machine in the hopes that it would be faster than on a single-core machine. Here's the idea: I got a fixed number of threads (in my case one thread per core). Every thread executes a Runnable of the form:

private static int[] data; // data shared across all threads

public void run() {

    int i = 0;

    while (i++ < 5000) {

        // do some work
        for (int j = 0; j < 10000 / numberOfThreads) {
            // each thread performs calculations and reads from and
            // writes to a different part of the data array

        // wait for the other threads

On a quadcore machine, this code performs worse with 4 threads than it does with 1 thread. Even with the CyclicBarrier's overhead, I would have thought that the code should perform at least 2 times faster. Why does it run slower?

EDIT: Here's a busy wait implementation I tried. Unfortunately, it makes the program run slower on more cores (also being discussed in a separate question here):

public void run() {

    // do work

    synchronized (this) {

        if (atomicInt.decrementAndGet() == 0) {


            for (int i = 0; i < threads.length; i++)

    while (!Thread.interrupted()) {}
share|improve this question
Can you tell use why you expect this to run faster on more cores? –  Mat Jun 30 '11 at 21:09
It suggests to me that each thread is not running in a separate core, and that makes sense because you've not told it specifically to do this (and can't with standard Java 1.6). –  Hovercraft Full Of Eels Jun 30 '11 at 21:10
@Mat: With more threads, each Runnable sleeps shorter. Since they sleep concurrently, they should "wake up" faster. –  ryyst Jun 30 '11 at 21:11
@bestsss: If it's so trivial, why don't you explain it? –  ryyst Jun 30 '11 at 21:15
Ah, okay. Then it was neither of the two, but rather not my type of humor. –  aioobe Jun 30 '11 at 22:08

5 Answers 5

up vote 7 down vote accepted

Adding more threads is not necessarily guarenteed to improve performance. There are a number of possible causes for decreased performance with additional threads:

  • Coarse-grained locking may overly serialize execution - that is, a lock may result in only one thread running at a time. You get all the overhead of multiple threads but none of the benefits. Try to reduce how long locks are held.
  • The same applies to overly frequent barriers and other synchronization structures. If the inner j loop completes quickly, you might spend most of your time in the barrier. Try to do more work between synchronization points.
  • If your code runs too quickly, there may be no time to migrate threads to other CPU cores. This usually isn't a problem unless you create a lot of very short-lived threads. Using thread pools, or simply giving each thread more work can help. If your threads run for more than a second or so each, this is unlikely to be a problem.
  • If your threads are working on a lot of shared read/write data, cache line bouncing may decrease performance. That said, although this often results in performance degradation, this alone is unlikely to result in performance worse than the single threaded case. Try to make sure the data that each thread writes is separated from other threads' data by the size of a cache line (usually around 64 bytes). In particular, don't have output arrays laid out like [thread A, B, C, D, A, B, C, D ...]

Since you haven't shown your code, I can't really speak in any more detail here.

share|improve this answer
Thank you! I guess my problems is a combination of spending most of the time in the barrier and cache line bouncing. I'd love to show the code, but even though it's only basic computations, it's quite a lot of code... –  ryyst Jun 30 '11 at 21:32
@bdonlan, false sharing combined w/ tight waiting on the cyclic barrier can have the result, i.e. the context switches could be more expensive than the work done (which is additionally worsen by the cache trashing). Also waiting like that on the barrier will impose extra switching latency (too high value for the park) –  bestsss Jun 30 '11 at 21:33
@ryyst, you can try busy waiting (seriously) instead of cyclic barrier. –  bestsss Jun 30 '11 at 21:36
@bestsss: Do you have any suggestions on how to implement busy waiting? –  ryyst Jun 30 '11 at 22:31
@Suhail, here is a link to wikipedia false sharing: en.wikipedia.org/wiki/False_sharing –  bestsss Jul 1 '11 at 7:56

You're sleeping nano-seconds instead of milli-seconds.

I changed from

Thread.sleep(0, 100000 / numberOfThreads); // sleep 0.025 ms for 4 threads


Thread.sleep(100000 / numberOfThreads);

and got a speed-up proportional to the number of threads started just as expected.

I invented a CPU-intensive "countPrimes". Full test code available here.

I get the following speed-up on my quad-core machine:

4 threads: 1625
1 thread: 3747

(the CPU-load monitor indeed shows that 4 course are busy in the former case, and that 1 core is busy in the latter case.)

Conclusion: You're doing comparatively small portions of work in each thread between synchronization. The synchronization takes much much more time than the actual CPU-intensive computation work.

(Also, if you have memory intensive code, such as tons of array-accesses in the threads, the CPU won't be the bottle-neck anyway, and you won't see any speed-up by splitting it on multiple CPUs.)

share|improve this answer
@aioobe: Updated the question... –  ryyst Jun 30 '11 at 21:22
uhm, that's bad. Now I can't reproduce. –  aioobe Jun 30 '11 at 21:23
I managed to reproduce using a "countPrimes" method. Answer updated. –  aioobe Jun 30 '11 at 21:42
Your conclusion sounds right. What are your suggestions to fix this (bestsss mentions busy waiting)? –  ryyst Jun 30 '11 at 21:47
Thread.sleep(0, 100000 / numberOfThreads); // sleep 0.025 ms for 4 threads nanoseconds sleeping i.e. Thread.sleep(long, int) affects only millis (by modifying by 1) the code is something like that if (nanos >= 500000 || (nanos != 0 && millis == 0)) millis++; So it's 1ms –  bestsss Jun 30 '11 at 21:49

The code inside runnable does not actually do anything.
In your specific example of 4 threads each thread will sleep for 2.5 seconds and wait for the others via the barier.
So all that is happening is that each thread gets on the processor to increment i and then blocks for sleep leaving processor available.
I do not see why the scheduler would alocate each thread to a separate core since all that is happening is that the threads mostly wait.
It is fair and reasonable to expect to just to use the same core and switch among threads
Just saw that you updated post saying that some work is happening in the loop. What is happening though you do not say.

share|improve this answer
I just realized that, so I updated my question. I actually do perform work, so the OS should allocate processing power to each thread. –  ryyst Jun 30 '11 at 21:19
@ryyst:But what do you do in the for loop?If you do not post the actual code I do not see how we can help you in the analysis. –  Cratylus Jun 30 '11 at 21:21
@user: Basic calculations, such as adding / multiplying ints. No locks, no synchronization, no I/O. –  ryyst Jun 30 '11 at 21:21
Still just describing does not help.Basic calculation like int addition can be done really fast and still the actual processing be so little that there is no need to use another core. –  Cratylus Jun 30 '11 at 21:24
@ryyst, show the code, you might have false sharing, morealso waiting on the barrier is quite expensive in the loop, move the barrier outside the loop. –  bestsss Jun 30 '11 at 21:29

synchronizing across cores is much slower than syncing on a single core

because on a single cored machine the JVM doesn't flush the cache (a very slow operation) during each sync

check out this blog post

share|improve this answer
what do you mean by JVM doesn't flush the cache ? –  Suhail Gupta Jul 1 '11 at 3:48

Here is a not tested SpinBarrier but it should work.

Check if that may have any improvement on the case. Since you run the code in loop extra sync only hurt performance if you have the cores on idle. Btw, I still believe you have a bug in the calc, memory intense operation. Can you tell what CPU+OS you use.

Edit, forgot the version out.

import java.util.concurrent.atomic.AtomicInteger;

public class SpinBarrier {
    final int permits;
    final AtomicInteger count;
    final AtomicInteger version;
    public SpinBarrier(int count){ 
        this.count = new AtomicInteger(count);
        this.permits= count;
        this.version = new AtomicInteger();

    public void await(){        
        for (int c = count.decrementAndGet(), v = this.version.get(); c!=0 && v==version.get(); c=count.get()){
        if (count.compareAndSet(0, permits)){;//only one succeeds here, the rest will lose the CAS

    protected void spinWait() {
share|improve this answer
I don't have the time to find out why right now, but this does not work (I tried with 4 threads). Thanks though! –  ryyst Jul 1 '11 at 10:23
@ryyst, figured I have dropped code w/o version, so when the 1st thread wins the CAS any other waiters will see the reverted count back to permits and spin forever. –  bestsss Jul 1 '11 at 10:48
Still doesn't work for me... All CPUs are @ 100% but nothing happens. I also made an update to my question. The busy wait mechanism works but runs slower if you put more threads to it. –  ryyst Jul 1 '11 at 11:04
@ryyst, busy wait works only if you have less or equal threads to the cores. Are you sure you create the SpinBarrier w/ the same amount of threads you intend to start? Also you cant use synchronized in busy waiting, it defeats any idea of busy. –  bestsss Jul 1 '11 at 11:17
I'm on a quadcore and your updated code doesn't work with 2 threads (it does with 1). Also, in my code I'm only using synchronized to decrement the counter, I busy wait outside the synchronized part, right? –  ryyst Jul 1 '11 at 20:21

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