I read a bit about using SSE intrinsics and tried my luck with implementing quaternion rotation with doubles. Below are the normal and SSE functions I wrote,

```
void quat_rot(quat_t a, REAL* restrict b){
///////////////////////////////////////////
// Multiply vector b by quaternion a //
///////////////////////////////////////////
REAL cross_temp[3],result[3];
cross_temp[0]=a.el[2]*b[2]-a.el[3]*b[1]+a.el[0]*b[0];
cross_temp[1]=a.el[3]*b[0]-a.el[1]*b[2]+a.el[0]*b[1];
cross_temp[2]=a.el[1]*b[1]-a.el[2]*b[0]+a.el[0]*b[2];
result[0]=b[0]+2.0*(a.el[2]*cross_temp[2]-a.el[3]*cross_temp[1]);
result[1]=b[1]+2.0*(a.el[3]*cross_temp[0]-a.el[1]*cross_temp[2]);
result[2]=b[2]+2.0*(a.el[1]*cross_temp[1]-a.el[2]*cross_temp[0]);
b[0]=result[0];
b[1]=result[1];
b[2]=result[2];
}
```

**With SSE**

```
inline void cross_p(__m128d *a, __m128d *b, __m128d *c){
const __m128d SIGN_NP = _mm_set_pd(0.0, -0.0);
__m128d l1 = _mm_mul_pd( _mm_unpacklo_pd(a[1], a[1]), b[0] );
__m128d l2 = _mm_mul_pd( _mm_unpacklo_pd(b[1], b[1]), a[0] );
__m128d m1 = _mm_sub_pd(l1, l2);
m1 = _mm_shuffle_pd(m1, m1, 1);
m1 = _mm_xor_pd(m1, SIGN_NP);
l1 = _mm_mul_pd( a[0], _mm_shuffle_pd(b[0], b[0], 1) );
__m128d m2 = _mm_sub_sd(l1, _mm_unpackhi_pd(l1, l1));
c[0] = m1;
c[1] = m2;
}
void quat_rotSSE(quat_t a, REAL* restrict b){
///////////////////////////////////////////
// Multiply vector b by quaternion a //
///////////////////////////////////////////
__m128d axb[2];
__m128d aa[2];
aa[0] = _mm_load_pd(a.el+1);
aa[1] = _mm_load_sd(a.el+3);
__m128d bb[2];
bb[0] = _mm_load_pd(b);
bb[1] = _mm_load_sd(b+2);
cross_p(aa, bb, axb);
__m128d w = _mm_set1_pd(a.el[0]);
axb[0] = _mm_add_pd(axb[0], _mm_mul_pd(w, bb[0]));
axb[1] = _mm_add_sd(axb[1], _mm_mul_sd(w, bb[1]));
cross_p(aa, axb, axb);
_mm_store_pd(b, _mm_add_pd(bb[0], _mm_add_pd(axb[0], axb[0])));
_mm_store_sd(b+2, _mm_add_pd(bb[1], _mm_add_sd(axb[1], axb[1])));
}
```

The rotation is basically done using the function,

I then run the following test to check how much time each function takes to do a set of rotations,

```
int main(int argc, char *argv[]){
REAL a[] __attribute__ ((aligned(16))) = {0.2, 1.3, 2.6};
quat_t q = {{0.1, 0.7, -0.3, -3.2}};
REAL sum = 0.0;
for(int i = 0; i < 4; i++) sum += q.el[i] * q.el[i];
sum = sqrt(sum);
for(int i = 0; i < 4; i++) q.el[i] /= sum;
int N = 1000000000;
for(int i = 0; i < N; i++){
quat_rotSSE(q, a);
}
printf("rot = ");
for(int i = 0; i < 3; i++) printf("%f, ", a[i]);
printf("\n");
return 0;
}
```

I compiled using gcc 4.6.3 with -O3 -std=c99 -msse3.

The timings for the normal function, using the unix `time`

, was 18.841s and 21.689s for the SSE one.

Am I missing something, why is the SSE implementation 15% slower than the normal one? In which cases would an SSE implementation be faster for double precision?

**EDIT**: Taking advice from the comments, I tried several things,

- -O1 option gives very similar results.
- Tried using
`restrict`

on the`cross_p`

function and added an __m128d to hold the second cross product. This had no difference in the assembly produced. - The assembly produced for the normal function, from what I understand, only contains scalar instructions except of some
`movapd`

.

The assembly code generated for the SSE function is only 4 lines less than the normal one.

**EDIT**: Added links to the assembly generated,

withoutoptimization to get a proper baseline. – Some programmer dude Jan 19 '13 at 16:54