Let's say the bottleneck of my Java program really is some tight loops to compute a bunch of vector dot products. Yes I've profiled, yes it's the bottleneck, yes it's significant, yes that's just how the algorithm is, yes I've run Proguard to optimize the byte code, etc.

The work is, essentially, dot products. As in, I have two float[50] and I need to compute the sum of pairwise products. I know processor instruction sets exist to perform these kind of operations quickly and in bulk, like SSE or MMX.

Yes I can probably access these by writing some native code in JNI. The JNI call turns out to be pretty expensive.

I know you can't guarantee what a JIT will compile or not compile. Has anyone ever heard of a JIT generating code that uses these instructions? and if so, is there anything about the Java code that helps make it compilable this way?

Probably a "no"; worth asking.

up vote 39 down vote accepted

So, basically, you want your code to run faster. JNI is the answer. I know you said it didn't work for you, but let me show you that you are wrong.

Here's Dot.java:

import java.nio.FloatBuffer;
import org.bytedeco.javacpp.*;
import org.bytedeco.javacpp.annotation.*;

@Platform(include="Dot.h", compiler="fastfpu")
public class Dot {
    static { Loader.load(); }

    static float[] a = new float[50], b = new float[50];
    static float dot() {
        float sum = 0;
        for (int i = 0; i < 50; i++) {
            sum += a[i]*b[i];
        }
        return sum;
    }
    static native @MemberGetter FloatPointer ac();
    static native @MemberGetter FloatPointer bc();
    static native float dotc();

    public static void main(String[] args) {
        FloatBuffer ab = ac().capacity(50).asBuffer();
        FloatBuffer bb = bc().capacity(50).asBuffer();

        for (int i = 0; i < 10000000; i++) {
            a[i%50] = b[i%50] = dot();
            float sum = dotc();
            ab.put(i%50, sum);
            bb.put(i%50, sum);
        }
        long t1 = System.nanoTime();
        for (int i = 0; i < 10000000; i++) {
            a[i%50] = b[i%50] = dot();
        }
        long t2 = System.nanoTime();
        for (int i = 0; i < 10000000; i++) {
            float sum = dotc();
            ab.put(i%50, sum);
            bb.put(i%50, sum);
        }
        long t3 = System.nanoTime();
        System.out.println("dot(): " + (t2 - t1)/10000000 + " ns");
        System.out.println("dotc(): "  + (t3 - t2)/10000000 + " ns");
    }
}

and Dot.h:

float ac[50], bc[50];

inline float dotc() {
    float sum = 0;
    for (int i = 0; i < 50; i++) {
        sum += ac[i]*bc[i];
    }
    return sum;
}

We can compile and run that with JavaCPP using commands line these:

$ javac -cp javacpp.jar Dot.java
$ java -jar javacpp.jar Dot
$ java -cp javacpp.jar:. Dot

With an Intel Core i7-3632QM CPU @ 2.20GHz, Fedora 20, GCC 4.8.3, and OpenJDK 7 or 8, I get this kind of output:

dot(): 37 ns
dotc(): 23 ns

Or roughly 1.6 times faster. We need to use direct NIO buffers instead of arrays, but HotSpot can access direct NIO buffers as fast as arrays. On the other hand, manually unrolling the loop does not provide a measurable boost in performance, in this case.

  • 3
    Did you use OpenJDK or Oracle HotSpot? Contrary to popular belief, they are not the same. – Jonathan S. Fisher May 30 '12 at 2:47
  • @exabrial This is what "java -version" returns on this machine right now: java version "1.6.0_22" OpenJDK Runtime Environment (IcedTea6 1.10.6) (fedora-63.1.10.6.fc15-x86_64) OpenJDK 64-Bit Server VM (build 20.0-b11, mixed mode) – Samuel Audet May 30 '12 at 3:34
  • Nice one -- some of the advanced tricks here may be the key to speed. I'll have to investigate whether I can use them. – Sean Owen May 30 '12 at 10:47
  • 1
    That loop likely has a carried loop dependency. You may get a further speedup by unrolling the loop two or more times. – user2088790 Jun 18 '13 at 8:22
  • 1
    @Oliv GCC vectorizes the code with SSE, yes, but for such small data, JNI call overhead is unfortunately too large. – Samuel Audet Dec 18 '13 at 9:51

To address some of the scepticism expressed by others here I suggest anyone who wants to prove to themselves or other use the following method:

  • Create a JMH project
  • Write a small snippet of vectorizable math.
  • Run their benchmark flipping between -XX:-UseSuperWord and -XX:+UseSuperWord(default)
  • If no difference in performance is observed, your code probably didn't get vectorized
  • To make sure, run your benchmark such that it prints out the assembly. On linux you can enjoy the perfasm profiler('-prof perfasm') have a look and see if the instructions you expect get generated.

Example:

@Benchmark
@CompilerControl(CompilerControl.Mode.DONT_INLINE) //makes looking at assembly easier
public void inc() {
    for (int i=0;i<a.length;i++)
        a[i]++;// a is an int[], I benchmarked with size 32K
}

The result with and without the flag (on recent Haswell laptop, Oracle JDK 8u60): -XX:+UseSuperWord : 475.073 ± 44.579 ns/op (nanoseconds per op) -XX:-UseSuperWord : 3376.364 ± 233.211 ns/op

The assembly for the hot loop is a bit much to format and stick in here but here's a snippet(hsdis.so is failing to format some of the AVX2 vector instructions so I ran with -XX:UseAVX=1): -XX:+UseSuperWord(with '-prof perfasm:intelSyntax=true')

  9.15%   10.90%  │││ │↗    0x00007fc09d1ece60: vmovdqu xmm1,XMMWORD PTR [r10+r9*4+0x18]
 10.63%    9.78%  │││ ││    0x00007fc09d1ece67: vpaddd xmm1,xmm1,xmm0
 12.47%   12.67%  │││ ││    0x00007fc09d1ece6b: movsxd r11,r9d
  8.54%    7.82%  │││ ││    0x00007fc09d1ece6e: vmovdqu xmm2,XMMWORD PTR [r10+r11*4+0x28]
                  │││ ││                                                  ;*iaload
                  │││ ││                                                  ; - psy.lob.saw.VectorMath::inc@17 (line 45)
 10.68%   10.36%  │││ ││    0x00007fc09d1ece75: vmovdqu XMMWORD PTR [r10+r9*4+0x18],xmm1
 10.65%   10.44%  │││ ││    0x00007fc09d1ece7c: vpaddd xmm1,xmm2,xmm0
 10.11%   11.94%  │││ ││    0x00007fc09d1ece80: vmovdqu XMMWORD PTR [r10+r11*4+0x28],xmm1
                  │││ ││                                                  ;*iastore
                  │││ ││                                                  ; - psy.lob.saw.VectorMath::inc@20 (line 45)
 11.19%   12.65%  │││ ││    0x00007fc09d1ece87: add    r9d,0x8            ;*iinc
                  │││ ││                                                  ; - psy.lob.saw.VectorMath::inc@21 (line 44)
  8.38%    9.50%  │││ ││    0x00007fc09d1ece8b: cmp    r9d,ecx
                  │││ │╰    0x00007fc09d1ece8e: jl     0x00007fc09d1ece60  ;*if_icmpge

Have fun storming the castle!

  • 1
    From the same paper: "the JITed disassembler output suggests that it is not actually that efficient in terms of calling the most optimal SIMD instructions and their scheduling. A quick hunt through the JVM JIT compiler (Hotspot) source code suggests that this is due to the non-existence of packed SIMD instruction codes." The SSE registers are being used in scalar mode. – Aleksandr Dubinsky Oct 11 '15 at 11:34
  • 1
    @AleksandrDubinsky some cases are covered, some aren't. Do you have a concrete case you are interested in? – Nitsan Wakart Oct 12 '15 at 11:55
  • 2
    Let's flip the question and ask whether the JVM will autovectorize any arithmetic operations? Can you provide an example? I do have a loop that I had to pull out and rewrite using intrinsics recently. However, rather than hope for autovectorization, I would like to see support for explicit vectorization/intrinsics (similar to agner.org/optimize/vectorclass.pdf). Even better would be to write a good Java backend for Aparapi (although the leadership of that project has some wrong goals). Do you work on the JVM? – Aleksandr Dubinsky Oct 14 '15 at 9:30
  • 1
    @AleksandrDubinsky I hope the expanded answer helps, if not perhaps an email would. Also note that "rewrite using intrinsics" implies you changed the JVM code to add new intrinsics, is that what you mean? I'm guessing you meant replacing your Java code with calls into a native implementation via JNI – Nitsan Wakart Oct 15 '15 at 7:34
  • 1
    Thank you. This should now be the official answer. I think you should remove the reference to the paper, since it is outdated and doesn't demonstrate vectorization. – Aleksandr Dubinsky Oct 15 '15 at 11:00

In HotSpot versions beginning with Java 7u40, the server compiler provides support for auto-vectorisation. According to JDK-6340864

However, this seems to be true only for "simple loops" - at least for the moment. For example, accumulating an array cannot be vectorised yet JDK-7192383

  • Vectorization is there in JDK6 as well for some cases, though the targeted SIMD instruction set is not as wide. – Nitsan Wakart May 8 '15 at 6:38
  • 3
    Compiler vectorization support in HotSpot was improved a lot lately (June 2017) due to contributions by Intel. Performance-wise the yet unreleased jdk9 (b163 and later) currently wins over jdk8 due to bug-fixes enabling AVX2. Loops must fulfill a few constraints for auto-vectorization to work, e.g. use: int counter, constant counter increment, one termination condition with loop-invariant variables, loop body without method calls(?), no manual loop unfolding! Details are available in: cr.openjdk.java.net/~vlivanov/talks/… – Vedran Jun 23 '17 at 13:16
  • Vectorized fused-multiple-add (FMA) support does not look good currently (as of June 2017): it's either vectorization or scalar FMA(?). However, Oracle has apparently just accepted Intel's contribution to the HotSpot that enables FMA vectorization using AVX-512. To the delight of auto-vectorization fans and those lucky ones to have access to AVX-512 hardware, this may (with some luck) appear in one of the next jdk9 EA builds (beyond b175). – Vedran Jun 23 '17 at 13:38
  • A link to support the previous statement (RFR(M): 8181616: FMA Vectorization on x86): mail.openjdk.java.net/pipermail/hotspot-compiler-dev/2017-June/… – Vedran Jun 28 '17 at 15:10
  • 1
    A small benchmark demonstrating acceleration by a factor of 4 on integers through loop vectorization using AVX2 instructions: prestodb.rocks/code/simd – Vedran Jun 28 '17 at 15:14

Here is nice article about experimenting with Java and SIMD instructions written by my friend: http://prestodb.rocks/code/simd/

Its general outcome is that you can expect JIT to use some SSE operations in 1.8 (and some more in 1.9). Though you should not expect much and you need to be careful.

  • 1
    It would help if you summarized some key insights of the article you linked to. – Aleksandr Dubinsky Oct 6 '17 at 15:32

You could write OpenCl kernel to do the computing and run it from java http://www.jocl.org/.

Code can be run on CPU and/or GPU and OpenCL language supports also vector types so you should be able to take explicitly advantage of e.g. SSE3/4 instructions.

I'm guessing you wrote this question before you found out about netlib-java ;-) it provides exactly the native API you require, with machine optimised implementations, and does not have any cost at the native boundary due thanks to memory pinning.

  • 1
    Yeah, long time ago. I was more hoping to hear that this is automagically translated to vectorized instructions. But clearly it's not that hard to make it happen manually. – Sean Owen Dec 1 '15 at 17:29

Have a look at Performance comparison between Java and JNI for optimal implementation of computational micro-kernels. They show that Java HotSpot VM server compiler supports auto-vectorization using Super-word Level Parallelism, which is limited to simple cases of inside the loop parallelism. This article will also give you some guidance whether your data size is large enough to justify going JNI route.

I dont believe most if any VMs are ever smart enough for this sort of optimisations. To be fair most optimisations are much simpler, such as shifting instead of multiplication whena power of two. The mono project introduced their own vector and other methods with native backings to help performance.

  • 2
    Currently, no Java hotspot compiler does this, but it isn't much harder than things that they do do. They do use SIMD instructions to copy multiple array values at once. You just have to write some more pattern matching and code generation code, which is pretty straightforward after doing some loop unrolling. I think the people at Sun just got lazy, but it looks like it will now happen at Oracle (yay Vladimir! this should help our code a lot!): mail.openjdk.java.net/pipermail/hotspot-compiler-dev/… – Christopher Manning Jun 27 '12 at 5:24

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