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I'm going to have to code a very basic checksum function, something like:

char sum(const char * data, const int len)
    char sum(0);
    for (const char * end=data+len ; data<end ; ++data)
        sum += *data;
    return sum;

That's trivial. Now, how should I optimize this? First, I should probably use some std::for_each with a lambda or something like that:

char sum2(const char * data, const int len)
    char sum(0);
    std::for_each(data, data+len, [&sum](char b){sum+=b;});
    return sum;

Next, I could use multiple threads/cores to sum up chunks, then add the results. I won't write it down, and I'm afraid the cost of creating threads (or getting them from a pool anyway), then cutting up the array, then dispatching everything, etc, would not be very good considering that I would mostly calculate checksums for small arrays, mostly 10-100 bytes, rarely up to 1000.

But what I really want is something lower level, some SIMD stuff that would sum up bytes on 128b registers, or maybe sum bytes independently between two registers without carrying the carry, or both.

Is there any such thing out there ?

Note: This IS actual premature optimization, but it's fun, so what the hell?

Edit: I still need a way to sum up all the bytes in an SSE register, something better than

char ptr[16];
_mm_storeu_si128((__m128i*)ptr, sum);
checksum += ptr[0] + ptr[1] + ptr[2]  + ptr[3]  + ptr[4]  + ptr[5]  + ptr[6]  + ptr[7]
          + ptr[8] + ptr[9] + ptr[10] + ptr[11] + ptr[12] + ptr[13] + ptr[14] + ptr[15];
share|improve this question
I have no actual proof of this, but I suspect the std::for_each version is going to be slower than the manual method... –  Mike Caron Jul 12 '11 at 22:26
I'm assuming you want Intel opps here? –  Michael Dorgan Jul 12 '11 at 23:17
@Mike Depends, it is actually slower for small packets but faster for big ones. I've tested with 100b and 900b, I don't know where the limit is for my set-up. I guess the cost of object creation has to do with this. Unsurprisingly, SSE beat both for both sizes. –  Gabriel Jul 13 '11 at 3:43
@Gabriel: It is not a premature optimization. In my project, for example, it was a slowest place. At first I unrolled it by 4, which gave a lot of boost, but it was still the slowest. So I had to re-write it using SSE intrinsics. And it is fun! :) –  user405725 Feb 23 '12 at 4:22

2 Answers 2

up vote 2 down vote accepted

Yes, there are such instructions in the MMX instruction set, called "Packed ADD":

  • _mm_add_pi8 in Visual C++
  • __builtin_ia32_paddb in gcc

And in the SSE2 instruction set:

EDIT: A faster way to add the partial sums:

__m128i sums;

sums = _mm_add_epi8(sums, _mm_srli_si128(sums, 1));
sums = _mm_add_epi8(sums, _mm_srli_si128(sums, 2));
sums = _mm_add_epi8(sums, _mm_srli_si128(sums, 4));
sums = _mm_add_epi8(sums, _mm_srli_si128(sums, 8));
checksum += _mm_cvtsi128_si32(sums);
share|improve this answer
"Precisely!" -- Doc –  Gabriel Jul 13 '11 at 1:25
Now, is any compiler badass enough to produce the right code given the loops above? –  Gabriel Jul 13 '11 at 1:33
I can't imagine that most compilers would bother to emit SSE for that first loop. It's annoying to try to load from an arbitrary pointer—the compiler doesn't know if the target is aligned, and if it can load in SSE-sized chunks, and so on. –  John Calsbeek Jul 13 '11 at 4:12
No need to use compiler names here. GCC as well as Visual C++ support the standard MMX/SSE extension headers and functions. I'm no MMX/SSE user, but check for example <mmintrin.h> for protoypes. –  rubenvb Jul 13 '11 at 13:17

Look at _mm_add_ps. Simultaneous add of 128-bit contiguous block. You'll need to zero pad your array or process the last few non SIMD style.

share|improve this answer
Floating-point addition is not useful here –  Ben Voigt Jul 12 '11 at 22:32

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