For a single dot-product, it's simply a vertical multiply and horizontal sum (see Fastest way to do horizontal float vector sum on x86). hadd
costs 2 shuffles + an add
. It's almost always sub-optimal for throughput when used with both inputs = the same vector.
// both elements = dot(x,y)
__m128d dot1(__m256d x, __m256d y) {
__m256d xy = _mm256_mul_pd(x, y);
__m128d xylow = _mm256_castps256_pd128(xy); // (__m128d)cast isn't portable
__m128d xyhigh = _mm256_extractf128_pd(xy, 1);
__m128d sum1 = _mm_add_pd(xylow, xyhigh);
__m128d swapped = _mm_shuffle_pd(sum1, sum1, 0b01); // or unpackhi
__m128d dotproduct = _mm_add_pd(sum1, swapped);
return dotproduct;
}
If you only need one dot product, this is better than @hirschhornsalz's single-vector answer by 1 shuffle uop on Intel, and a bigger win on AMD Jaguar / Bulldozer-family / Ryzen because it narrows down to 128b right away instead of doing a bunch of 256b stuff. AMD splits 256b ops into two 128b uops.
It can be worth using hadd
in cases like doing 2 or 4 dot products in parallel where you're using it with 2 different input vectors. Norbert's dot
of two pairs of vectors looks optimal if you want the results packed. I don't see any way to do better even with AVX2 vpermpd
as a lane-crossing shuffle.
Of course if you really want one larger dot
(of 8 or more double
s), use vertical add
(with multiple accumulators to hide vaddps
latency) and do the horizontal summing at the end. You can also use fma
if available.
haddpd
internally shuffles xy
and zw
together two different ways and feeds that to a vertical addpd
, and that's what we'd do by hand anyway. If we kept xy
and zw
separate, we'd need 2 shuffles + 2 adds for each one to get a dot product (in separate registers). So by shuffling them together with hadd
as a first step, we save on the total number of shuffles, only on adds and total uop count.
/* Norbert's version, for an Intel CPU:
__m256d temp = _mm256_hadd_pd( xy, zw ); // 2 shuffle + 1 add
__m128d hi128 = _mm256_extractf128_pd( temp, 1 ); // 1 shuffle (lane crossing, higher latency)
__m128d dotproduct = _mm_add_pd( (__m128d)temp, hi128 ); // 1 add
// 3 shuffle + 2 add
*/
But for AMD, where vextractf128
is very cheap, and 256b hadd
costs 2x as much as 128b hadd
, it could make sense to narrow each 256b product down to 128b separately and then combine with a 128b hadd.
Actually, according to Agner Fog's tables, haddpd xmm,xmm
is 4 uops on Ryzen. (And the 256b ymm version is 8 uops). So it's actually better to use 2x vshufpd
+ vaddpd
manually on Ryzen, if that data is right. It might not be: his data for Piledriver has 3 uop haddpd xmm,xmm
, and it's only 4 uops with a memory operand. It doesn't make sense to me that they couldn't implement hadd
as only 3 (or 6 for ymm) uops.
For doing 4 dot
s with the results packed into one __m256d
, the exact problem asked, I think @hirschhornsalz's answer looks very good for Intel CPUs. I haven't studied it super-carefully, but combining in pairs with hadd
is good. vperm2f128
is efficient on Intel (but quite bad on AMD: 8 uops on Ryzen with one per 3c throughput).