# How to count identical bytes

I have two long arrays of bytes and I need to compute how many bytes on corresponding positions are identical. My solution (in JAVA) is as follows:

    int sum = 0;
for(int i = 0;i < t.length;i++)
if (t[i] == spb[i])
sum++;


Since this part of my program takes substantial time, I wonder if I can make this any faster

Obviously the length of the two arrays is identical

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Besides using previously-suggested "concurrent threads to compute partial sums for sections of the array" method (which I will comment on in a later paragraph), you can use two simple techniques to speed up the loop: (1) ?: tertiary operator instead of if test, and (2) loop unrolling.

On my old 2GHz system, using gcj java compiler, each of those techniques gives a few percent of speedup. The improvement you get on your machine (if any) may be compiler or jvm dependent.

Code examples:

    if (t[i] == spb[i]) sum++;


goes to

    sum += t[i] == spb[i] ? 1 : 0;


and

    public static int counts (byte[] A, byte[] B) {
int i, count, L=A.length;
for (count=i=0; i<L; i++)
count += A[i]==B[i] ? 1 : 0;
return count;
}


goes to (for example)

   public static int counts (byte[] A, byte[] B) {
final int S=8;
int i, count, L=A.length-S;
for(count=i=0; i<L; i+=S) {
count += A[i+0]==B[i+0] ? 1 : 0;
count += A[i+1]==B[i+1] ? 1 : 0;
count += A[i+2]==B[i+2] ? 1 : 0;
count += A[i+3]==B[i+3] ? 1 : 0;
count += A[i+4]==B[i+4] ? 1 : 0;
count += A[i+5]==B[i+5] ? 1 : 0;
count += A[i+6]==B[i+6] ? 1 : 0;
count += A[i+7]==B[i+7] ? 1 : 0;
}
for (; i<L+S; ++i)
count += A[i]==B[i] ? 1 : 0;
return count;
}


Loop unrolling could be done with S having a value larger or smaller than the S=8 shown above. However, in the tests I ran, S=16 showed little improvement over S=8. Some sample timings, with 202MB arrays:

A. 51094384 matches in 3.421857144 sec. (original loop)
E. 51094384 matches in 3.212364808 sec. (use ?: value)
F. 51094384 matches in 2.953596272 sec. (?: + S=8 unroll)
G. 51094384 matches in 2.949984214 sec. (?: + S=16 unroll)


In this run, E. timing is 6% less than A., while F. and G. are 8% less than E., and 14% less than A. (Other timings, not shown, verified that a previous answer's claim that "requesting the field of an object (t.length) takes more time than a local variable", is irrelevant.)

Regarding use of concurrent threads: Suppose you use three threads. Among other methods, you could let thread i treat contiguous bytes in the i'th third of each array, or you could let thread i handle every third byte, that is, bytes with index mod 3 = i. It would be worthwhile to benchmark the difference in execution time. I would expect it to be different, on different machines, depending on cache sizes and regimes.

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If the arrays are very long, you could use multiple concurrent threads to compute partial sums for sections of the array, and then sum up the partial sums.

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Since this is a CPU-bound activity, this would only make sense to do as long as number of threads == number of cores, right? – matt b Oct 6 '11 at 20:45
@matt b, it's not CPU-bound, it's memory bandwidth bound. The answer to your question depends on the machine. It may be number of sockets instead, or oversubscribing might even help depending on the architecture of the machine. – Adam Oct 6 '11 at 20:55

Nope, you're basically doing the right thing (at least for a single thread - Simon's idea of using multiple threads is a good one). How much time is this taking, and how long are the arrays? It ought to be pretty quick.

You might be able to speed it up by creating a ByteBuffer around the byte array, then using asLongBuffer to create a LongBuffer wrapping it again. You could then check 8 bytes at a time (as longs), only checking a single byte at a time when the long comparison returns false. This would be significantly more complicated code though - and I wouldn't be at all surprised to find that it's actually a lot slower.

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The latter approach is pretty much what strcmp does in optimized implementations, so presumably it's likely to be faster if large parts of the array are identical. – Nick Johnson Oct 6 '11 at 23:44
@NickJohnson: Well, strcmp gets to do that in a very highly optimized way - it depends on how much redirection Java is adding via LongBuffer and ByteBuffer. – Jon Skeet Oct 7 '11 at 5:49
That's true. Somehow I missed that this was Java. :) – Nick Johnson Oct 7 '11 at 8:16
@Nick: strcmp() is doing something different. In strcmp(), finding one discrepancy means you stop the comparison and return a value. This program has to count the number of discrepancies. – David Thornley Oct 7 '11 at 14:39
@DavidThornley I know - I was simply pointing out that it successfully uses a word-by-word comparison to skip over large regions of matches, like Jon suggested for this function. In C, this would almost certainly be faster unless the string had a lot of mismatches; in Java, probably not so much, as Jon points out. – Nick Johnson Oct 9 '11 at 0:07
int sum = 0;
for(int i = t.length - 1;i >= 0 ;i--)
if (t[i] == spb[i])
sum++;


In principle, requesting the field of an object (t.length) takes more time than a local variable (i). If you iterate from last to first, the most expensive instruction is executed only once.

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While (at least on my machine) this does run faster by than the OP code by 15%, if the reason was avoiding the length operator on each iteration then for(int i = 0, length = t.length; i < length; i++) would also be 15% faster, but replacing the request for the length with a local variable is not significantly faster ( array length of one, ten or hundred million ). IIRC, there is a specific optimisation in the JVM to hoist the length of arrays used in for loops. – Pete Kirkham Oct 8 '11 at 17:11