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Where does the x86-64's SSE instructions (vector instructions) outperform the normal instructions. Because what I'm seeing is that the frequent loads and stores that are required for executing SSE instructions is nullifying any gain we have due to vector calculation. So could someone give me an example SSE code where it performs better than the normal code.

Its maybe because I am passing each parameter separately, like this...

__m128i a = _mm_set_epi32(pa[0], pa[1], pa[2], pa[3]);
__m128i b = _mm_set_epi32(pb[0], pb[1], pb[2], pb[3]);
__m128i res = _mm_add_epi32(a, b);

for( i = 0; i < 4; i++ )
 po[i] = res.m128i_i32[i];

Isn't there a way I can pass all the 4 integers at one go, I mean pass the whole 128 bytes of pa at one go? And assign res.m128i_i32 to po at one go?

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Basically, whenever you have an extremely high computation/load-store ratio. –  Mysticial Apr 25 '12 at 10:03
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Yeah, you definitely don't want to use _mm_set_epi32() like that. Use _mm_load_si128(). And if you can't align the data, you can use _mm_loadu_si128() at a performance penalty. –  Mysticial Apr 25 '12 at 10:11
    
Align the data? What do u mean by that? –  user1018562 Apr 25 '12 at 10:12
    
SSE aligned load/stores require that the address be aligned to 16 bytes. If you can't guarantee that, you can use misaligned load/stores - but at a performance penalty. –  Mysticial Apr 25 '12 at 10:13
    
I have numerous examples of SSE and AVX showing massive speedup over normal code. But they're all too large to be posted here. A good rule of thumb is to have at least 3 - 4 operations for every memory access. In your example, even if you used _mm_load_si128() and _mm_store_si128() properly, you have 1 operation for 3 memory accesses. That's why you aren't getting any speedup. –  Mysticial Apr 25 '12 at 10:18

1 Answer 1

up vote 6 down vote accepted

Summarizing comments into an answer:

You have basically fallen into the same trap that catches most first-timers. Basically there are two problems in your example:

  1. You are misusing _mm_set_epi32().
  2. You have a very low computation/load-store ratio. (1 to 3 in your example)

_mm_set_epi32() is a very expensive intrinsic. Although it's convenient to use, it doesn't compile to a single instruction. Some compilers (such as VS2010) can generate very poor performing code when using _mm_set_epi32().

Instead, since you are loading contiguous blocks of memory, you should use _mm_load_si128(). That requires that the pointer is aligned to 16 bytes. If you can't guarantee this alignment, you can use _mm_loadu_si128() - but with a performance penalty. Ideally, you should properly align your data so that don't need to resort to using _mm_loadu_si128().


The be truly efficient with SSE, you'll also want to maximize your computation/load-store ratio. A target that I shoot for is 3 - 4 arithmetic instructions per memory-access. This is a fairly high ratio. Typically you have to refactor the code or redesign the algorithm to increase it. Combining passes over the data is a common approach.

Loop unrolling is often necessary to maximize performance when you have large loop bodies with long dependency chains.


Some examples of SO questions that successfully use SSE to achieve speedup.

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