# The hunt for the fastest Hamming Distance C implementation [duplicate]

I want to find how many different characters two strings of equal length have. I have found that xoring algorithms are considered to be the fastest, but they return distance expressed in bits. I want the results expressed in characters. Suppose that "pet" and "pit" have distance 1 expressed in characters but 'e' and 'i' might have two different bits, so xoring returns 2.

The function i wrote is:

// na = length of both strings
unsigned int HammingDistance(const char* a, unsigned int na, const char* b) {

unsigned int num_mismatches = 0;
while (na) {
if (*a != *b)
++num_mismatches;

--na;
++a;
++b;
}

return num_mismatches;
}

Could it become any faster? Maybe using some lower level commands or implementing a different algorithm?

System: Gcc 4.7.2 on Intel Xeon X5650

Thank you

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Do you have any problems with performance so that you try to optimize it? –  Andrey Apr 13 at 12:12
xoring at the individual caracters could work, since you want to detect if there is a difference between 2 chars, you xor them and check that the result is different of 0. However it might not optimal, if a shorter branchless instruction sequence can be devised - look up branchless condtionals or branchless code. –  didierc Apr 13 at 14:44
@Andrey 2 It's a vital part of a very intensive process. It runs 5 billion times in a program of mine. –  Petros Drakoulis Apr 13 at 14:50

## marked as duplicate by TemplateRex, Nicholas Wilson, rekire, Neil, AnandApr 13 at 15:34

You can make your comparison compare more bytes at a time by doing a bitwise operator on the native integer size.

In your code, you're comparing equality of a byte at a time, but your CPU can compare at least a word in a single cycle, and 8 bytes if it's x86-64. The exact performance capabilities depend on the CPU architecture, of course.

But if you would advance through the two pointers with a stride the size of 8, it could sure be faster in some scenarios. When it has to read from the strings from main memory, the memory load time will actually dominate the performance. But if the strings are in the CPU cache, You might be able to do an XOR, and interpret the results by testing where in the 64bit value the bits are changed.

Counting the buckets that aren't 0 can be done with a variant of the SWAR algorithm starting from 0x33333333 instead of 0x55555555.

The algorithm will be harder to work with, because it will require using uint64_t pointers that have proper memory alignment. You'll need a preamble and postscript that covers the leftover bytes. Maybe you should read the assembly the compiler outputs and see if it's not doing something more clever before you try something more complicated in code.

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I thought about it. While it has better best case (stings are equal), the average will not be significantly lower. Especially considering that this implementation will be significantly more complex (esp. alignment). –  Andrey Apr 13 at 12:44
@Andrey Yeah, I can't say I would recommend trying it. –  vipw Apr 13 at 14:25
I did not try this due to complexity and the relatively small size of strings involved. Thank you anyway though –  Petros Drakoulis Apr 22 at 22:52

if (*a != *b)
++num_mismatches;

this would be faster on some architectures (with 8 bit bytes) because it avoids the branch:

int bits = *a ^ *b;
bits |= bits >> 4;
bits |= bits >> 2;
bits |= bits >> 1;
num_mismatches += bits & 1;
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I just tried this on an Intel Xeon and runs slower than original. Thank you for trying to help me though. –  Petros Drakoulis Apr 13 at 14:51

while (na >= 8){
num_mismatches += (a[0] != b[0]);
num_mismatches += (a[1] != b[1]);
num_mismatches += (a[2] != b[2]);
num_mismatches += (a[3] != b[3]);
num_mismatches += (a[4] != b[4]);
num_mismatches += (a[5] != b[5]);
num_mismatches += (a[6] != b[6]);
num_mismatches += (a[7] != b[7]);
a += 8; b += 8; na -= 8;
}
if (na >= 4){
num_mismatches += (a[0] != b[0]);
num_mismatches += (a[1] != b[1]);
num_mismatches += (a[2] != b[2]);
num_mismatches += (a[3] != b[3]);
a += 4; b += 4; na -= 4;
}
if (na >= 2){
num_mismatches += (a[0] != b[0]);
num_mismatches += (a[1] != b[1]);
a += 2; b += 2; na -= 2;
}
if (na >= 1){
num_mismatches += (a[0] != b[0]);
a += 1; b += 1; na -= 1;
}

Also, if you know there are long stretches of equal characters, you could cast the pointers to long* and compare them 4 at a time, and only if not equal look at the individual characters. This code is based on memset and memcpy being fast. It copies the strings into long arrays to 1) eliminate alignment issues, and 2) pad the strings with zeros out to an integer number of longs. As it compares each pair of longs, if they are not equal, it casts the pointers to char* and counts up the unequal characters. The main loop could also be unrolled, similar to the above.

long la[BIG_ENOUGH];
long lb[BIG_ENOUGH];
memset(la, 0, sizeof(la));
memset(lb, 0, sizeof(lb));
memcpy(la, a, na);
memcpy(lb, b, nb);
int nla = (na + 3) & ~3; // assuming sizeof(long) = 4
long *pa = la, *pb = lb;
while(nla >= 1){
if (pa[0] != pb[0]){
num_mismatches += (((char*)pa[0])[0] != ((char*)pb[0])[0])
+ (((char*)pa[0])[1] != ((char*)pb[0])[1])
+ (((char*)pa[0])[2] != ((char*)pb[0])[2])
+ (((char*)pa[0])[3] != ((char*)pb[0])[3])
;
}
pa += 1;pb += 1; nla -= 1;
}
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I just tried your loop unrolling. Its slower than original on an Intel Xeon. I have trouble implementing your second solution. Thanks for helping me anyway. –  Petros Drakoulis Apr 13 at 15:01
@Petros: Hmm... The first unrolling solution shouldn't be slower than your basic character loop, unless maybe na is typically pretty short. –  Mike Dunlavey Apr 13 at 15:06
Newer Intel's don't really like unrolling - at least, not always. The loop overhead is typically smaller than the instruction redecoding time (due to the loop not fitting in the loop buffer). –  harold Apr 13 at 15:08
@harold: Maybe that's it. I guess it really depends on the processor. –  Mike Dunlavey Apr 13 at 15:09
@MikeDunlavey na is between 4 and 32 at most, between 6 and 9 on average case. –  Petros Drakoulis Apr 13 at 15:19

If the strings are padded with zero to always be 32 bytes and their addresses are 16-aligned, you could do something like this: (code neither tested nor profiled)

movdqa xmm0, [a]
movdqa xmm1, [a + 16]
pcmpeqb xmm0, [b]
pcmpeqb xmm1, [b + 16]
pxor xmm2, xmm2
pextrw ax, xmm0, 0
pextrw dx, xmm1, 0
movsx eax, ax
neg eax

But if the strings are usually tiny, it does a lot of unnecessary work and it may not be any faster. It should be faster if the strings are usually (nearly) 32 bytes though.

edit: I wrote this answer before I saw your updated comment - if the strings are usually that tiny, this is probably not very good. A 16-byte version could (maybe) be useful though (run the second iteration conditionally, the branch for that should be well-predicted because it'll be rarely taken). But with such short strings, the normal code is hard to beat.

movdqa xmm0, [a]
pxor xmm1, xmm1
pcmpeqb xmm0, [b]