Here is a proof-of-concept implementation, based on the Fast Walsh–Hadamard transform, with an optimized first pass. Compiles fine with clang-3.3 or later, and gives nice results with clang-4.0 or later (requires -O2 to properly inline relevant functions). If you don't have FMA, you need to xor the lower two elements of `hada2_`

with `-0.0`

in `hadamard4`

(and use a normal `_mm256_add_pd`

).

All gcc versions I checked would require replacing the `memcpy`

by manual load/store intrinsics to get similar results.

Also, I left handling of cases `len<16`

as exercise. And it may be worth implementing a `hadamard32`

and perhaps a `hadamard64`

similar to `hadamard16`

, to better use the available registers and reduce memory access. In C++ this could be done with a recursive template implementation.

```
#include <immintrin.h> // avx+fma
#include <assert.h> // assert
#include <string.h> // memcpy
inline __m256d hadamard4(__m256d x0123)
{
__m256d x1032 = _mm256_permute_pd(x0123, 5); // [x1, x0, x3, x2]
__m256d hada2 = _mm256_addsub_pd(x1032,x0123); // [x0+x1, x0-x1, x2+x3, x2-x3]
__m256d hada2_= _mm256_permute2f128_pd(hada2, hada2, 1); // [x2+x3, x2-x3, x0+x1, x0-x1]
// if no FMA is available, this can be done with xoring and adding:
__m256d res = _mm256_fmadd_pd(hada2_, _mm256_set_pd(1.0, 1.0, -1.0, -1.0), hada2);
return res;
}
inline void hadamard8(__m256d data[2])
{
__m256d a = hadamard4(data[0]);
__m256d b = hadamard4(data[1]);
data[0] = _mm256_add_pd(a,b);
data[1] = _mm256_sub_pd(a,b);
}
inline void hadamard16(__m256d data[4])
{
hadamard8(data+0);
hadamard8(data+2);
for(int i=0; i<2; ++i)
{
__m256d tmp = data[i];
data[i] = _mm256_add_pd(tmp, data[i+2]);
data[i+2]= _mm256_sub_pd(tmp, data[i+2]);
}
}
void hadamard(double* p, size_t len)
{
assert((len&(len-1))==0); // len must be power of 2
assert(len>=16); // TODO implement fallback for smaller sizes ...
// first pass: hadamard of 16 values each
for(size_t i=0; i<len; i+=16)
{
__m256d data[4];
memcpy(data, p+i, sizeof(data)); // should get optimized to 4x vmovupd
hadamard16(data);
memcpy(p+i, data, sizeof(data)); // should get optimized to 4x vmovupd
}
for(size_t h=32; h<len; h*=2)
{
for(size_t i=0; i<len; i+=2*h)
{
for(size_t j=i; j<i+h; j+=4)
{
__m256d x = _mm256_loadu_pd(p+j);
__m256d y = _mm256_loadu_pd(p+j+h);
_mm256_storeu_pd(p+j, _mm256_add_pd(x,y));
_mm256_storeu_pd(p+j+h, _mm256_sub_pd(x,y));
}
}
}
}
```

Benchmarking is also left as an exercise ;-)

Disclaimer: I did not test this. Looking at it, I may have mixed up `hada2_`

and `hada2`

in the `_mm256_fmadd_pd`

instruction ...

`len/2`

can be calculated only once and not all over the whole function. – Eugene Sh. Jan 8 '19 at 17:54`O(n^2)`

, but the transform can be computed in`O(n*log(n))`

: en.wikipedia.org/wiki/Fast_Walsh%E2%80%93Hadamard_transform – chtz Jan 9 '19 at 12:56`double`

each). Are you sure you need`double`

, not`float`

? With SIMD, half the element size means twice as much work per vector. On the flip side, horizontal stuff can take more shuffling of elements inside one vector. – Peter Cordes Jan 10 '19 at 10:46