I have a large piece of code, part of whose body contains this piece of code:

```
result = (nx * m_Lx + ny * m_Ly + m_Lz) / sqrt(nx * nx + ny * ny + 1);
```

which I have vectorized as follows (everything is already a `float`

):

```
__m128 r = _mm_mul_ps(_mm_set_ps(ny, nx, ny, nx),
_mm_set_ps(ny, nx, m_Ly, m_Lx));
__declspec(align(16)) int asInt[4] = {
_mm_extract_ps(r,0), _mm_extract_ps(r,1),
_mm_extract_ps(r,2), _mm_extract_ps(r,3)
};
float (&res)[4] = reinterpret_cast<float (&)[4]>(asInt);
result = (res[0] + res[1] + m_Lz) / sqrt(res[2] + res[3] + 1);
```

The result is correct; however, my benchmarking shows that the vectorized version is *slower*:

- The non-vectorized version takes 3750 ms
- The vectorized version takes 4050 ms
- Setting
`result`

to`0`

directly (and removing this part of the code entirely) reduces the entire process to 2500 ms

Given that the vectorized version only contains *one* set of SSE multiplications (instead of four individual FPU multiplications), why is it slower? Is the FPU indeed faster than SSE, or is there a confounding variable here?

(I'm on a mobile Core i5.)