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I have two pieces of code that are identical in C# and Java. But the Java one goes twice as fast. I want to know why. Both work with the same principal of using a big lookup table for performance.

Why is the Java going 50% faster than C#?

Java code:

    int h1, h2, h3, h4, h5, h6, h7;
    int u0, u1, u2, u3, u4, u5;
    long time = System.nanoTime();
    long sum = 0;
    for (h1 = 1; h1 < 47; h1++) {
        u0 = handRanksj[53 + h1];
        for (h2 = h1 + 1; h2 < 48; h2++) {
            u1 = handRanksj[u0 + h2];
            for (h3 = h2 + 1; h3 < 49; h3++) {
                u2 = handRanksj[u1 + h3];
                for (h4 = h3 + 1; h4 < 50; h4++) {
                    u3 = handRanksj[u2 + h4];
                    for (h5 = h4 + 1; h5 < 51; h5++) {
                        u4 = handRanksj[u3 + h5];
                        for (h6 = h5 + 1; h6 < 52; h6++) {
                            u5 = handRanksj[u4 + h6];
                            for (h7 = h6 + 1; h7 < 53; h7++) {
                                sum += handRanksj[u5 + h7];
    }}}}}}}
    double rtime = (System.nanoTime() - time)/1e9; // time given is start time
    System.out.println(sum);

It just enumerates through all possible 7 card combinations. The C# version is identical except at the end it uses Console.writeLine.

The lookuptable is defined as:

static int handRanksj[];

Its size in memory is about 120 Megabytes.

The C# version has the same test code. It's measured with Stopwatch instead of nanoTime() and uses Console.WriteLine instead of System.out.println("") but it takes at least double the time.

Java takes about 400ms. For compilation in java I use the -server flag. In C# the build is set to release without debug or trace defines.

What is responsible for the speed difference?

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16  
Are you only running it once? If so, that will include JIT time. I suggest you run it several times, but ignore the first few. –  Jon Skeet Mar 11 '11 at 17:13
4  
I would try and run this code at least a few hundred times in a row and measure the combined time - this will give a better overview over the performance differences. –  BrokenGlass Mar 11 '11 at 17:14
    
@Jon, doesn't Java also have something similar to the .NET JIT? –  Thomas Levesque Mar 11 '11 at 17:18
4  
@Thomas: Absolutely, but maybe the .NET JIT is slower. It's an obvious potential difference. –  Jon Skeet Mar 11 '11 at 17:19
1  
(Server HotSpot will, I believe, concentrate on the excessively hot inner loop. Server HotSpot does a fair amount of profiling, unlike the cut down Client HotSpot.) –  Tom Hawtin - tackline Mar 11 '11 at 17:32
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2 Answers 2

up vote 10 down vote accepted

If you're timing a C# Debug build, or a Release build from within Visual Studio, you're going to get very misleading timings. Compile in Release mode and either run from the command line or run in Visual Studio without debugging. That is, rather than F5 to run, press Ctrl+F5 to run without debugging.

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4  
On a C# console application that I have for doing batch processing when I would run it in release mode with F5 the initialization to get to my task runner was significant,upwards of 40-50 seconds of waiting. Once I published and ran the same file from disk it went to < 1s. –  Chris Marisic Mar 11 '11 at 17:31
    
Thanks, this was the main problem. Now the C# version is down to 480ms. It's still a bit slower but in the same area. –  michael Mar 11 '11 at 18:29
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Is it possible that one of them is accessing sequential memory in the array (ie. adjacent elements) in sequence while the other is bouncing around all over the place? If so one of them will receive a serious boost from the processor pre-fetching adjacent array elements while the other will not.

That said, when doing a poker hand simulator you may want to try a Monte Carlo simulation instead. The results of the hand will converge far before you've tried all possible 7 card combinations.

If you use a deck of cards object just fix the hands and the board at their current values, then deal out a random board from the deck, shuffle, repeat x amount of times. The values should converge on the actual probabilities long before you've enumerated every possibility.

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It is reserved in both cases as one array with the same content. I have another evaluator for Monte Carlo but he computes not even 1/20 of the cards in the same time. –  michael Mar 11 '11 at 18:07
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