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I have a program that is making a huge number of calls to Long.bitCount(), so many that it is taking 33% of cycles on one CPU core. Is there a way to implement it that is faster than the Sun JDK version?

I have tried:

  • This algorithm (I think this is exactly how the JDK implements it)
  • lookup tables of various sizes between 28 and 222 (looking at a few bits at a time and adding the results)

But I couldn't do any better than a 216-entry lookup table with a manually-unrolled loop (about 27% CPU.)
How else might this be optimized for Java?


Note: this question is about Java-specific optimization, but this similar (language-agnostic) question has many other algorithms.

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4  
Out of curiosity, what is it that you're doing that's making this many calls to that function? –  templatetypedef Jan 29 '11 at 20:08
8  
+1: Hurrah! A question about optimization where the questioner has actually profiled. –  Oliver Charlesworth Jan 29 '11 at 20:10
3  
Unfortunately, if there were a faster way, the JDK would probably already have adopted it. –  Oliver Charlesworth Jan 29 '11 at 20:23
1  
@finnw: to help us determine whether profiling or language overhead is overshadowing the timing result, please try implement the bit-counting code in a lower-level language such as C, C++ or Assembly, perform the timing test with 1 billion elements on the same machine, and post the timing results of both the Java and the native implementation. (I understand that your final implementation still needs to be in Java, but we have to establish the baseline machine performance first.) –  rwong May 8 '11 at 12:32
1  
I'll add too that you should consider performance only if you consider that your software is too slow. In that case you should have something like : This processing is too slow. User are complaining or the computer can keep up with needed througput. Then optimize for this objective. But here the objective is somewhat different. You want less % of time passer in this part of the program. In a sense slowing down others part would do the trick. What the interrest of foccussing of %CPU usage ? –  Nicolas Bousquet May 11 '11 at 12:09

8 Answers 8

up vote 5 down vote accepted

If you are on a recent x86 CPU there is an instruction for this, popcnt.

In recent versions of Java, Long.bitCount() uses this instruction. Just use -XX:+UsePopCountInstruction (this is the default in recent versions)

However, there are some bugs with it in JRE 6.0_u18 through 7.0_u5: http://bugs.sun.com/bugdatabase/view_bug.do?bug_id=7063674

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This seems like one of those problems that is simply perfect for the GPU to work on. It should be able to slash your time by a couple orders of magnitude.

Otherwise I think you may have to deal with it at a higher level. Having multiple threads working on different segments of data at a time (which I'm sure you already do), processing the data while you are collecting it, sharing the work around multiple systems--something like that.

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Although this function could be split among threads, the other cores have plenty of work to do already so I don't think it could increase the overall throughput. –  finnw Jan 30 '11 at 3:13
    
@finnw I agree with the threads--the GPU is by far your best means of accelerating this job. It's also the most work, of course. –  Bill K Feb 4 '11 at 1:02
    
For the other threads, you tried ? Or this is a supposition ?. –  Nicolas Bousquet May 11 '11 at 7:53
1  
And for the GPU? You don't want to try? There are API for that in JAVA. I know that a GPU is not so common on servers, but with some testing you could discover than one high end GPU (+/- 500$) could perform as good a dozen CPU cores in this type of situations. Because your CPU seem to be already busy, you'll gaim more parallelism. –  Nicolas Bousquet May 11 '11 at 8:08
1  
@finnw although I haven't done it, this seems appropriate: code.google.com/p/java-gpu –  Bill K May 14 '11 at 0:40

If you machine has an integer ALU that can process data wider than some multiples of 64 bits (also known as SIMD, such as SSE2 or VMX), you can compute the bit counts on several 64-bit elements at once.

Unfortunately, this will require you to provide machine-specific implementations in a lower-level language than Java.

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I suspect that your app is memory-bound rather than CPU-bound, i.e. it spends more time fetching the values from memory than counting their bits. In that case you should try to reduce the size of the working set or improve access locality to reduce cache misses (if the algorithm allows it).

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2  
Probably (it's hard to tell from the profiler output) but I don't think there is much room for improvement as I search sequentially through the array of keys. –  finnw May 10 '11 at 15:30

I'm no expert in the subject, but in case you haven't seen these pages, they may help:

http://www.reddit.com/r/programming/comments/84sht/fast_bit_couting_algorithms/

http://www-graphics.stanford.edu/~seander/bithacks.html

You may also want to poke around the many graphics libraries out there, especially those that are lower-level and/or speak directly to hardware.

EDIT: looks like you can use the relatively newly introduced POPCNT instruction (available on some recent AMD and Intel processors) for a potential speed increase, if you have the option to write low-level platform-specific code, and can target that specific architecture. http://kent-vandervelden.blogspot.com/2009/10/counting-bits-population-count-and.html and another article with benchmarks: http://www.strchr.com/crc32_popcnt

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From my understanding:

I would use the 33% as an indicator only as profiling for small methods could really change the overall performance. So i would run the algorithm on some big dataset and see the total time. And I would consider the efficiancies of my optimization based on that total time changes. I would also include a warning up phase so that the JIT can do it's optimisations.

In fact the bit counting thing seem to be one of the key part of your algorithm anyway... if you optimize everything, and manage to get 10 time faster for all key part, you still profile something near 33% for this part. That's not bad by essence.

Inspiring from this link http://bmagic.sourceforge.net/bmsse2opt.html you could try to use SSE instruction present in all intel/AMD processor now if I remember right (you could alway failback to JAVA otherwise). An interresting part concerning the article is... That most of the time, it is memory bound anyway. But I would still try to see how this could work for you.

A GPU would be a perfect fit for insanely fast processing (easy hundred time one of a CPU core) and bandwidth. Main problem would be pushing data to CPU dedicated memory and getting result back. But if you don't just perform bit counting but more more operation, this could bring huge gains.

There is not shortcut anyway, you must try several approach and see what bring the most gain. Don't count % through but total time spent.

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I am now using this method, which interleaves four popcnt operations at a time. It is based on this C implementation.

private static final long M0=0x5555555555555555L,
                          M1=0x3333333333333333L,
                          M2=0x0f0f0f0f0f0f0f0fL;
public void store4Tags(long tag0, long tag1, long tag2, long tag3) {
    long count0 = tag0,
         count1 = tag1,
         count2 = tag2,
         count3 = tag3;
    count0 = (count0 & M0) + ((count0 >>> 1) & M0);
    count1 = (count1 & M0) + ((count1 >>> 1) & M0);
    count2 = (count2 & M0) + ((count2 >>> 1) & M0);
    count3 = (count3 & M0) + ((count3 >>> 1) & M0);

    count0 = (count0 & M1) + ((count0 >>> 2) & M1);
    count1 = (count1 & M1) + ((count1 >>> 2) & M1);
    count2 = (count2 & M1) + ((count2 >>> 2) & M1);
    count3 = (count3 & M1) + ((count3 >>> 2) & M1);

    count0 = (count0 + (count0 >>> 4)) & M2;
    count1 = (count1 + (count1 >>> 4)) & M2;
    count2 = (count2 + (count2 >>> 4)) & M2;
    count3 = (count3 + (count3 >>> 4)) & M2;

    count0 += count0 >>> 8;
    count1 += count1 >>> 8;
    count2 += count2 >>> 8;
    count3 += count3 >>> 8;

    count0 += count0 >>> 16;
    count1 += count1 >>> 16;
    count2 += count2 >>> 16;
    count3 += count3 >>> 16;

    count0 += count0 >>> 32;
    count1 += count1 >>> 32;
    count2 += count2 >>> 32;
    count3 += count3 >>> 32;

    storeWithPopCnt(tag0, 0x3f & (int) count0);
    storeWithPopCnt(tag1, 0x3f & (int) count1);
    storeWithPopCnt(tag2, 0x3f & (int) count2);
    storeWithPopCnt(tag3, 0x3f & (int) count3);
}

This outperforms the lookup table version slightly, and consumes no cache.

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Rather than optimise this function, you are likely to be better off optimising the usage of this function. E.g. you could keep a counter.

public void set(int n) {
   if(!get(n)) bitCount++;
   // set the bit
}
public void clear(int n) {
   if(get(n)) bitCount--;
   // clear the bit
}
public int bitCount() {
   return bitCount;
}

This avoids scanning the data by keeping track of the number of the count of bits set. This moves the overhead to how often bits and set or cleared and makes getting the number of bits set trivial. It appears in your use case, the later is much more often.

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Won't help in my application, as the most common use case is bitCount(a ^ b) to compute the Hamming distance between a and b. It is not practical to maintain counts for all pairs. –  finnw May 8 '11 at 11:08
    
@finnw: based on your profiling, do you find that (a == 0 || b == 0 || a == b) occurs frequently in your application? If so, you might just take that as a shortcut. –  rwong May 8 '11 at 12:23
    
@rwong, no, zeros are very rare. –  finnw May 8 '11 at 12:43
    
If zeros are very rare you can check for ~0 first. (Or are they not that rare?) –  Peter Lawrey May 8 '11 at 13:44
    
I mean whole words of zeros, not zero bits –  finnw May 9 '11 at 7:39

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