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I have an application that accepts work on a queue and then spins that work off to be completed on independent threads. The number of threads is not massive, say up to 100, but these are intensive tasks and can quickly bump the CPU up to 100%.

To get the most work done the quickest: am I best off to just launch more threads when I need to do more work and let the Java thread scheduler handle distributing the work, or would getting smarter and managing the work load to keep the CPU below 100% get me further faster?

The machine is dedicated to my java app.

EDIT:

Thanks for the fantastic input!

The tasks are of varying complexity and involve I/O so having a low thread pool of say 4 may well be only running the CPU to 20%. I have no way of knowing how many tasks will actually take the CPU to 100%.

My thought was should I monitor CPU through RMI and dynamically dial the work up and down, or should I just not care and let the OS handle it.

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4  
Use a fixed-size thread pool with as many threads as you have processors. 100% isn't necessarily bad, but you can't tell an optimal usage of 100% CPU time from overloaded situations like thrashing by just looking at CPU usage. – trutheality Apr 12 '12 at 2:15
    
I thought that you were using a pool with 100 threads. Is it that a new thread is created for every task? If so, stop doing that now and use a pool as suggested by @trutheality – Martin James Apr 12 '12 at 9:28
    
@Steve about your edit, if you can separate your threads into CPU-intensive and IO threads, then you can put CPU-intensive threads into a pool of #-of-cores, and let the IO threads spawn off without a pool. That should in theory give you the best usage. – trutheality Apr 12 '12 at 17:06
up vote 9 down vote accepted

If you have too many simultaneous compute-intensive tasks in parallel threads, you reach the point of diminishing returns very quickly. In fact, if there are N processors (cores), then you don't want more than N such threads. Now, if the tasks occasionally pause for I/O or user interaction, then the right number can be somewhat larger. But in general, if at any one moment there are more threads that want to do computation than there are cores available, then your program is wasting time on context switches -- i.e., the scheduling is costing you.

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1  
How much is it costing? If there are a lot of CPU-intensive tasks, the box is overloaded and there are always more ready threads than processors then, it is likely that the OS will resort to changing th eset of ready threads at each imer interrupt. So, no matter how many CPU-bound threads there are, the number of context-switches will be limited to one every.. 30ms or whatever. This is not significant. What you say above is true, but not any justification for extra thread micromanagement by the user, (which very often goes wrong). – Martin James Apr 12 '12 at 8:49
    
@MartinJames -- I hardly think that choosing an optimally sized thread pool is micromanagement. In any case: citation, please. Your statements fly in the face of every standard text and reference. Just one example that agrees with me: ibm.com/developerworks/library/j-jtp0730/index.html. – Ernest Friedman-Hill Apr 12 '12 at 11:26
    
I don't care about generalized texts and references from IBM. Assillias and myself did some testing. In Java, for CPU-intensive tasks, it doesn't matter much whether you have 20 or 200 threads in your pool. With non-GC C++, it doesn't matter whether there are 20 or 2000. These results are not remotely surprising to me. The OS has a queue, (OK an array[priority] of queues), of ready threads, probably a linked-list. The kernel gets [no. of cores] threads from the front of the queue and puts the old [no. of cores] at the back. Why should it matter how many entries there are in the queue? – Martin James Apr 12 '12 at 12:30
    
I should add that there are surely thread-number-related factors that should influence a choice of threads for a pool. 200/2000 stacks has a memory cost and, if that cost pushes the working-set into paging, then all those threads are going to generate a bad performance hit. However, that is nothing directly to do with context-switching overhead - add more RAM and the problem goes away. – Martin James Apr 12 '12 at 12:40
1  
This is an interesting issue, though. For years, I've seen posts about only creating [no. of cores] threads for best performance because of the 'overhead of context-switching'. Now I seem to find that a lot more threads than that is best, even with CPU-bound jobs. – Martin James Apr 12 '12 at 16:45

As you add more and more threads the overhead incurred in the context-switching, memory cache flushing, memory cache overflowing, and kernel and JVM thread management increases. As your threads hog the CPU their kernel priorities drop to some minimum and they will reach the time-slice minimum. As more and more threads crowd memory, they overflow the various internal CPU memory caches. There is a higher chance the CPU will need to swap the job in from slower memory. Internal to the JVM there is more mutex local contention and probably some (maybe small) incremental per-thread and object bandwidth GC overhead. Depending on how synchronized your user-tasks are, more threads would cause increased memory flushing and lock contention.

With any program and any architecture, there is a sweet spot where threads can optimally utilize the available processor and IO resources while limiting kernel and JVM overhead. Finding that sweet spot repeatedly will require a number of iterations and some guesswork.

I would recommend using the Executors.newFixedThreadPool(SOME_NUMBER); and submit you jobs to it. Then you can do multiple runs varying the number of threads up and down until you find the optimal number of pools running simultaneously according to the work and the architecture of the box.

Understand however, that the optimal number of threads will vary based on how many processors and other factors that may be non-trivial to determine.

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Eh? Context-switches only happen when the OS is entered on an interrupt. If there is a large set of CPU-intensive ready threads, the OS will swap around the running set, (probably mostly after the timer interrupt). Once the set of ready threads is larger than the number of cores, the context-switch overhead is nearly constant as more thread are added. – Martin James Apr 12 '12 at 8:54
    
To me context-switching is what happen at the CPU level when either the thread yields for IO or the timer fires and there are too many jobs in the run queue. This flushes cache memory (L1), copies running state to memory, swaps in next job. I'll agree that there is a JVM/OS overhead floor but it is more complicated with cache memory overflow, CPU priority penalties, and JVM overhead to take into account. But I should in my answer talk more about the limits. – Gray Apr 12 '12 at 14:29
    
In the case of these CPU-bound jobs where the box is overloaded with manyy more redy threads than cores, there will be overhead on every change to the running set, as you describe. This can only happen on hardware interrupts or system calls. CPU-intensive tasks typically don't make frequent system calls, so that leaves interrupts. If we neglect page faults, the CPU-bound tasks won't do much IO either, so that leaves the timer interrupt. The frequency of that is independent of the number of ready threads, so the overhead it generates is independent of the number of ready threads. – Martin James Apr 12 '12 at 15:09
    
I'll agree although the time slice window is not fixed. It does drop to some floor as the kernel penalizes CPU bound jobs. Also, I'm not 100% certain that page-faults can be neglected. I'm not sure if the CPU/kernel have the ability to use memory location in scheduling these days -- probably not. – Gray Apr 12 '12 at 15:12
    
Oh and although CPU bound jobs don't make system calls they may deal with memory barriers or locks which causes JVM interrupts as well obviously. – Gray Apr 12 '12 at 15:13

The fact that your CPU is running at 100% does not tell much about how busy they are doing useful work. In your case, you are using more threads than cores so the 100% includes some context switching and uses memory unnecessarily (small impact for 100 threads), which is sub-optimal.

For CPU intensive task, I generally use this idiom:

private final int NUM_THREADS = Runtime.getRuntime().availableProcessors() + 1;
private final ExecutorService executor = Executors.newFixedThreadPool(NUM_THREADS);

Using more threads, as others have indicated, only introduces unnecessary context switching.

Obviously if the tasks do some I/O and other blocking operations, this is not applicable and a larger pool would make sense.

EDIT

To reply to @MartinJames comment, I have run a (simplistic) benchmark - result shows that going from a pool size = number of processors + 1 to 100 degrades the performance only slightly (let's call it 5%) - going to higher figures (1000 and 10000) does hit the performance significantly.

Results are the average of 10 runs:
Pool size: 9: 238 ms. //(NUM_CORES+1)
Pool size: 100: 245 ms.
Pool size: 1000: 319 ms.
Pool size: 10000: 2482 ms.

Code:

public class Test {

    private final static int NUM_CORES = Runtime.getRuntime().availableProcessors();
    private static long count;
    private static Runnable r = new Runnable() {

        @Override
        public void run() {
            int count = 0;
            for (int i = 0; i < 100_000; i++) {
                count += i;
            }
            Test.count += count;
        }
    };

    public static void main(String[] args) throws Exception {
        //warmup
        runWith(10);

        //test
        runWith(NUM_CORES + 1);
        runWith(100);
        runWith(1000);
        runWith(10000);
    }

    private static void runWith(int poolSize) throws InterruptedException {
        long average = 0;
        for (int run = 0; run < 10; run++) { //run 10 times and take the average
            Test.count = 0;
            ExecutorService executor = Executors.newFixedThreadPool(poolSize);
            long start = System.nanoTime();
            for (int i = 0; i < 50000; i++) {
                executor.submit(r);
            }
            executor.shutdown();
            executor.awaitTermination(10, TimeUnit.SECONDS);
            long end = System.nanoTime();
            average += ((end - start) / 1000000);
            System.gc();
        }
        System.out.println("Pool size: " + poolSize + ": " + average / 10 + " ms.  ");
    }
}
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'Using more threads, as others have indicated, only introduces unnecessary context switching' When number of ready threads equals the number of cores, that's as much context-switching as you are going to get. Adding more threads wil not significantly add to the overhead. – Martin James Apr 12 '12 at 9:14
    
@MartinJames See my edit. – assylias Apr 12 '12 at 9:46
    
thanks, I should have added 'more threads wil not significantly add to the overhead until the stacks etc. exceed available RAM and start getting paged out'. If taken to extremes almost everything is bad :) – Martin James Apr 12 '12 at 10:05
    
maybe you could publish your benchmark code - I would maybe have a go too! How do you measure performance? – Martin James Apr 12 '12 at 10:11
    
@MartinJames What do you mean? The code is in my answer. The only caveat is that for higher number of threads, the GC kicks in even between the calls to System.gc(). – assylias Apr 12 '12 at 10:11

'Would getting smarter and managing the work load to keep the CPU below 100% get me further faster?'

Probably not.

As others have posted, 100 threads is too many for a threadpool if most of the tasks are CPU-intensive. It won't make much difference to performance on typical systems - with that much overload it will be bad with 4 threads and bad with 400.

How did you decide on 100 threads? Why not 16, say?

'The number of threads is not massive, say up to 100' - does it vary? Just create 16 at startup and stop managing them - just pass the queue to them and forget about them.

Horrible thought - you aren't creating a new thread for each task, are you?

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Why 16? Adjusting the number of threads dynamically to the number of available processors does make sense - why not (num_processor * 1.5) for example? – assylias Apr 12 '12 at 9:53
    
num_processor * 1.5 - fine. num_processor * 15, not much different, really. Yes - get the number of processors from the sysinfo, double it and add the number you first thought of <g> – Martin James Apr 12 '12 at 10:01

You should keep 100% usage but with minimum number of threads. 100 threads looks too many.

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1  
Why? What is wrong with 100 threads, (assuming sufficient RAM to hold all the stacks etc. without continual paging)? – Martin James Apr 12 '12 at 9:12
1  
@assilias has shown that 100 threads is not a significant issue in Java. In C++, 2000 threads is not a significant issue. – Martin James Apr 12 '12 at 12:00

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