The function `sinpi(x)`

computes sin(πx), and the function `cospi(x)`

computes cos(πx), where the multiplication with π is implicit inside the functions. These functions were initially introduced into the C standard math library as an extension by Sun Microsystems in the late 1980s. IEEE Std 754™-2008 specifies the equivalent functions `sinPi`

and `cosPi`

in section 9.

There are numerous computations where sin(πx) and cos(πx) occur naturally. A very simple example is the Box-Muller transform (G. E. P. Box and Mervin E. Muller, "A Note on the Generation of Random Normal Deviates". *The Annals of Mathematical Statistics*, Vol. 29, No. 2, pp. 610 - 611), which, given two independent random variables U₁ and U₂ with uniform distribution, produces independent random variables Z₁ and Z₂ with standard normal distribution:

```
Z₁ = √(-2 ln U₁) cos (2 π U₂)
Z₂ = √(-2 ln U₁) sin (2 π U₂)
```

A further example is the computation of sine and cosine for degree arguments, as in this computation of great-circle distance using the Haversine formula:

```
/* This function computes the great-circle distance of two points on earth
using the Haversine formula, assuming spherical shape of the planet. A
well-known numerical issue with the formula is reduced accuracy in the
case of near antipodal points.
lat1, lon1 latitude and longitude of first point, in degrees [-90,+90]
lat2, lon2 latitude and longitude of second point, in degrees [-180,+180]
radius radius of the earth in user-defined units, e.g. 6378.2 km or
3963.2 miles
returns: distance of the two points, in the same units as radius
Reference: http://en.wikipedia.org/wiki/Great-circle_distance
*/
double haversine (double lat1, double lon1, double lat2, double lon2, double radius)
{
double dlat, dlon, c1, c2, d1, d2, a, c, t;
c1 = cospi (lat1 / 180.0);
c2 = cospi (lat2 / 180.0);
dlat = lat2 - lat1;
dlon = lon2 - lon1;
d1 = sinpi (dlat / 360.0);
d2 = sinpi (dlon / 360.0);
t = d2 * d2 * c1 * c2;
a = d1 * d1 + t;
c = 2.0 * asin (fmin (1.0, sqrt (a)));
return radius * c;
}
```

For C++, the Boost library provides `sin_pi`

and
`cos_pi`

, and some vendors offer `sinpi`

and `cospi`

functionality as extensions in system libraries. For example, Apple added `__sinpi`

, `__cospi`

and the corresponding single-precision versions `__sinpif`

, `__cospif`

to iOS 7 and OS X 10.9 (presentation, slide 101). But for many other platforms, there is no implementation readily accessible to C programs.

Compared with a traditional approach that uses e.g. `sin (M_PI * x)`

and `cos (M_PI * x)`

, the use of `sinpi`

and `cospi`

improves accuracy by reducing rounding error via the *internal* multiplication with π, and also offers performance advantages due to the much simpler argument reduction.

How can one use the standard C math library to implement `sinpi()`

and `cospi()`

functionality in a reasonably efficient and standard compliant fashion?

`fenv()`

or`fesetround()`

) to truncate/round-towards-zero is necessary. That way we can use e.g. Kahan sum/compensated sum, and split high-precision coefficients to several different limited-precision factors. Every other approach seems to rely on specific hardware (like`fma()`

, for which emulation is horribly slow) or implementation details.