M_PI
lsine = __log__D(M_PI / z); /* = TRUNC(log(u)) + small */
return (M_PI / (y * z));
#define __kernel_cospif(x) (__kernel_cosdf(M_PI * (x)))
#define __kernel_sinpif(x) (__kernel_sindf(M_PI * (x)))
#define __kernel_cospif(x) (__kernel_cosdf(M_PI * (x)))
#define __kernel_sinpif(x) (__kernel_sindf(M_PI * (x)))
t = __kernel_tandf(M_PI * x, 1);
t = -__kernel_tandf(M_PI * (0.5 - x), -1);
M_LN2, M_PI, -2.0, 0.0,
0, M_PI / 4, 3 * M_PI / 4, 5 * M_PI / 4,
M_PI / 4, M_PI / 2, 3 * M_PI / 4,
5 * M_PI / 4, 3 * M_PI / 2, 7 * M_PI / 4,
testall(M_PI, M_PI, NAN, NAN, ALL_STD_EXCEPT, 0);
{ M_PI, { 3.0, 3.0, 4.0 }},
S[i][k] = cosf((float)((i + 0.5) * (k - 4) * (M_PI / 8.0)));
S[i][k] = cosf((float)((i + 0.5) * (k - 2) * (M_PI / 4.0)));
S[i][k] = cosf((float)((i + 0.5) * (k + 4) * (M_PI / 8.0)));
S[i][k] = cosf((float)((i + 0.5) * (k + 2) * (M_PI / 4.0)));
#define D2R(m) ((m) / 180 * M_PI)
#define R2D(m) ((m) * 180 / M_PI)
return (0.5 + 0.5 * cos(M_PI * x));
voss_ad.sin_a[x] = sin(freq * 2.0 * M_PI * ((double)x) / ((double)len));
voss_ad.cos_a[x] = cos(freq * 2.0 * M_PI * ((double)x) / ((double)len));
voss_ad.wave[x] = sin(freq * 2.0 * M_PI * ((double)x) / ((double)len)) *
(1.0 + sin(2.0 * M_PI * ((double)x) / ((double)samples))) / 2.0;
voss_ad.sin_b[x] = sin(2.0 * M_PI * ((double)x) / ((double)samples));
voss_ad.cos_b[x] = cos(2.0 * M_PI * ((double)x) / ((double)samples));
r = (2.0 * M_PI) - r;
r = M_PI + r;
r = M_PI - r;
voss_ad_last_delay = (uint32_t)(phase * (double)(voss_ad.len_b) / (2.0 * M_PI)) - (voss_ad.len_a / 2);