I'm still pretty new to using SSE and am trying to implement a modulo of `2*Pi`

for double-precision inputs of the order `1e8`

(the result of which will be fed into some vectorised trig calculations).

My current attempt at the code is based around the idea that `mod(x, 2*Pi) = x - floor(x/(2*Pi))*2*Pi`

and looks like:

```
#define _PD_CONST(Name, Val) \
static const double _pd_##Name[2] __attribute__((aligned(16))) = { Val, Val }
_PD_CONST(2Pi, 6.283185307179586); /* = 2*pi */
_PD_CONST(recip_2Pi, 0.159154943091895); /* = 1/(2*pi) */
void vec_mod_2pi(const double * vec, int Size, double * modAns)
{
__m128d sse_a, sse_b, sse_c;
int i;
int k = 0;
double t = 0;
unsigned int initial_mode;
initial_mode = _MM_GET_ROUNDING_MODE();
_MM_SET_ROUNDING_MODE(_MM_ROUND_DOWN);
for (i = 0; i < Size; i += 2)
{
sse_a = _mm_loadu_pd(vec+i);
sse_b = _mm_mul_pd( _mm_cvtepi32_pd( _mm_cvtpd_epi32( _mm_mul_pd(sse_a, *(__m128d*)_pd_recip_2Pi) ) ), *(__m128d*)_pd_2Pi);
sse_c = _mm_sub_pd(sse_a, sse_b);
_mm_storeu_pd(modAns+i,sse_c);
}
k = i-2;
for (i = 0; i < Size%2; i++)
{
t = (double)((int)(vec[k+i] * 0.159154943091895)) * 6.283185307179586;
modAns[k+i] = vec[k+i] - t;
}
_MM_SET_ROUNDING_MODE(initial_mode);
}
```

Unfortunately, this is currently returning a lot of `NaN`

with a couple of answers of `1.128e119`

as well (some what outside the range of `0`

-> `2*Pi`

that I was aiming for!). I suspect that where I'm going wrong is in the double-to-int-to-double conversion that I'm trying to use to do the `floor`

.

Can anyone suggest where I've gone wrong and how to improve it?

P.S. sorry about the format of that code, it's the first time I've posted a question on here and can't seem to get it to give me empty lines within the code block to make it readable.