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I'm trying to use SSE intrinsics to add two 32-bit signed int arrays. But I'm getting very poor performance compared to a linear addition.

Platform - Intel Core i3 550, GCC 4.4.3, Ubuntu 10.04 (bit old, yeah)

#define ITER 1000
typedef union sint4_u {
        __m128i v;
        sint32_t x[4];
} sint4;

The functions:

void compute(sint32_t *a, sint32_t *b, sint32_t *c) {
        sint32_t len = 96000;
        sint32_t i, j;

        __m128i x __attribute__ ((aligned(16)));
        __m128i y __attribute__ ((aligned(16)));
        sint4 z;

        for(j = 0; j < ITER; j++) {
                for(i = 0; i < len; i += 4) {
                        x = _mm_set_epi32(a[i + 0], a[i + 1], a[i + 2], a[i + 3]);
                        y = _mm_set_epi32(b[i + 0], b[i + 1], b[i + 2], b[i + 3]);
                        z.v = _mm_add_epi32(x, y); 
                        c[i + 0] = z.x[3];
                        c[i + 1] = z.x[2];
                        c[i + 2] = z.x[1];
                        c[i + 3] = z.x[0];
                }   
        }   

        return;
}

void compute_s(sint32_t *a, sint32_t *b, sint32_t *c) {
        sint32_t len = 96000;
        sint32_t i, j;
        for(j = 0; j < ITER; j++) {
                for(i = 0; i < len; i++) {
                        c[i] = a[i] + b[i];
                }   
        }   
        return;
}

The results:

➜  C  gcc -msse4.2 simd.c
➜  C  ./a.out            
Time Elapsed (SSE): 612.520000 mS
Time Elapsed (Scalar): 401.713000 mS
➜  C  gcc -O3 -msse4.2 simd.c
➜  C  ./a.out                
Time Elapsed (SSE): 135.124000 mS
Time Elapsed (Scalar): 46.438000 mS

On using -O3, the SSE version becomes 3 times slower (!!). What am I doing wrong? Even if I skip the loading back to c in compute, it still takes an extra 100 ms without any optimizations.

EDIT - as suggested in the comments, I replaced _mm_set with _mm_load, here are the updated times -

➜  C    gcc audproc.c -msse4    
➜  C    ./a.out             
Time Elapsed (SSE): 303.931000 mS
Time Elapsed (Scalar): 413.701000 mS
➜  C    gcc -O3 audproc.c -msse4
➜  C    ./a.out                 
Time Elapsed (SSE): 82.532000 mS
Time Elapsed (Scalar): 48.104000 mS

Much much better, but still nowhere close to the theoretical gain of 4x. Also, why is my vectorization slower at O3? Also, how do I get rid of this warning? (I tried adding __vector__ to my declaration but got more warnings instead. :( )

audproc.c: In function ‘compute’:
audproc.c:54: warning: passing argument 1 of ‘_mm_load_si128’ from incompatible pointer type /usr/lib/gcc/i486-linux-gnu/4.4.3/include/emmintrin.h:677: note: expected ‘const long long int __vector__ *’ but argument is of type ‘const sint32_t *’
share|improve this question
9  
Oh god... not again... Please don't kill puppies. – Mysticial Jun 27 '14 at 7:45
    
Oh, let me try changing that. – Ankush Jain Jun 27 '14 at 7:49
1  
At least with -O3, even gcc 4.4 should vectorize the loop better than your hand-coded version. Look at the assembly (use the -S flag and maybe -fverbose-asm) – Chris Jun 27 '14 at 8:15
1  
possible duplicate of Integer dot product using SSE/AVX? – diapir Jun 27 '14 at 9:53
up vote 2 down vote accepted

As already mentioned in the comments, in order to get the performance benefits of SIMD you should avoid scalar operations in your loop, i.e. get rid of the _mm_set_epi32 pseudo-intrinsics and the union for storing SIMD results. Here is a fixed version of your function:

void compute(const sint32_t *a, const sint32_t *b, sint32_t *c)
{
    sint32_t len = 96000;
    sint32_t i, j;

    for(j = 0; j < ITER; j++)
    {
        for(i = 0; i < len; i += 4)
        {
            __m128i x = _mm_loadu_si128((__m128i *)&a[i]);
            __m128i y = _mm_loadu_si128((__m128i *)&b[i]);
            __m128i z = _mm_add_epi32(x, y); 
            _mm_storeu_si128((__m128i *)&c[i], z);
        }   
    }   
}
share|improve this answer
1  
Although 96000 is divisible by four if a value of len is used which is not a multiple of four (e.g 96001) this will have a problem. – Z boson Jun 27 '14 at 11:01
    
Sorry for the late reply - yes, this worked great. One question though, you used _mm_loadu for loading data. My arrays were already 16-byte aligned, so I switched to _mm_load to get better performance, but saw no difference in the times. Is there no penalty in using _mm_loadu if the addresses are aligned? – Ankush Jain Jun 30 '14 at 11:45
2  
@AnkushJain, since Nahelem the latency and throughput of _mm_load and _mm_loadu are the same so there is not reason to use _mm_load anymore. – Z boson Jun 30 '14 at 13:34

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