# SIMD array add for arbitrary array lengths

I'm learning to use SIMD capabilities by re-writing my personal image processing library using vector intrinsics. One basic function is a simple "array `+=`," i.e.

``````void arrayAdd(unsigned char* A, unsigned char* B, size_t n) {
for(size_t i=0; i < n; i++) { B[i] += A[i] };
}
``````

For arbitrary array lengths, the obvious SIMD code (assuming aligned by 16) is something like:

``````size_t i = 0;
__m128i xmm0, xmm1;
n16 = n - (n % 16);
for (; i < n16; i+=16) {
xmm0 = _mm_load_si128( (__m128i*) (A + i) );
xmm1 = _mm_load_si128( (__m128i*) (B + i) );
xmm1 = _mm_add_epi8( xmm0, xmm1 );
_mm_store_si128( (__m128i*) (B + i), xmm1 );
}
for (; i < n; i++) { B[i] += A[i]; }
``````

But is it possible to do all the additions with SIMD instructions? I thought of trying this:

``````__m128i mask = (0x100<<8*(n - n16))-1;
``````

for the extra elements, but will that result in undefined behavior? The `mask` should guarantee no access is actually made past the array bounds (I think). The alternative is to do the extra elements first, but then the array needs to be aligned by `n-n16`, which doesn't seem right.

Is there another, more optimal pattern such vectorized loops?

-
you could ensure that in your code the array lengths are always multiples of 16 bytes (though possibly less elements are actually used), so this epilog never comes up. But the epilog is really not important in terms of speed. –  Walter Apr 16 '12 at 15:34

One option is to pad your array to a multiple of 16 bytes. Then you can do 128 bit load/add/store and simply ignore the results following the point you care about.

For large arrays though the overhead of the byte by byte "epilog" is going to be very small. Unrolling the loop may improve performance more, something like:

``````for (; i < n32; i+=32) {
xmm0 = _mm_load_si128( (__m128i*) (A + i) );
xmm1 = _mm_load_si128( (__m128i*) (B + i) );
xmm2 = _mm_load_si128( (__m128i*) (A + i + 16) );
xmm3 = _mm_load_si128( (__m128i*) (B + i + 16) );
xmm1 = _mm_add_epi8( xmm0, xmm1 );
xmm3 = _mm_add_epi8( xmm2, xmm3 );
_mm_store_si128( (__m128i*) (B + i), xmm1 );
_mm_store_si128( (__m128i*) (B + i + 16), xmm3 );
}
``````

But it's hard to say without doing some profiling.

You could also do an unaligned load/store at the end (assuming you have more than 16 bytes) though this will probably not make a big difference. E.g. if you have 20 bytes you do one load/store to offset 0 and another unaligned load/add/store (`_mm_storeu_si128`, `__mm_loadu_si128`) to offset 4.

You could use `_mm_maskmoveu_si128` but you need to get the mask into an xmm register, and your sample code isn't going to work. You probably want to set the mask register to all FF's and then use a shift to align it. At the end of the day, it will probably be slower than the unaligned load/add/store.

This would be something like:

``````mask = _mm_cmpeq_epi8(mask, mask); // Set to all FF's
``````
-
In practice I would put the masks in a lookup table. Do you think it would still be slower than the "epilog" loop? –  reve_etrange Apr 16 '12 at 3:05
@reve_etrange: Likely not slower but it is difficult to know without measuring the two solutions. Give it a try. –  Guy Sirton Apr 16 '12 at 3:43
I'll give it a shot. But is it a legal memory access? Since some value of `mask` could cause an array bounds violation. –  reve_etrange Apr 16 '12 at 3:46
@reve_etrange: The store is mostly OK, it is byte by byte, you'll still need to do a load though so you'll need to be a bit careful there. If the address is illegal you will get an exception on either the load or the store but as long as the address is good only the affected bytes will be touched. –  Guy Sirton Apr 16 '12 at 3:50
@reve_etrange: there is that risk but it doesn't mean everything has to be padded, if you have vectors in continguous memory it can be guaranteed safe if the very last one is padded. –  Guy Sirton Apr 16 '12 at 3:57