Using trig functions `sin()/cos()`

is expensive in time and introduces loss of precision. Much better to use the `remainder()`

function. Note the result has the same sign as `x`

and magnitude less than the magnitude of `y`

, if able.

OP was on the right track! The below solution is easy to adjust per the edge values of -180 and + 180.0.

```
#include <math.h>
// Reduce to (-180.0, 180.0]
double Limit_Longitude(double longitude_degrees) {
// A good implementation of `fmod()` will introduce _no_ loss of precision.
// -360.0 <= longitude_reduced <=- 360.0
double longitude_reduced = fmod(longitude_degrees, 360.0);
if (longitude_reduced > 180.0) {
longitude_reduced -= 360.0;
} else if (longitude_reduced <= -180.0) {
longitude_reduced += 360.0;
}
return longitude_reduced;
}
```

Limiting Latitude to [-90 to +90] is trickier as a latitude of +91 degrees is going over the North Pole but switching the longitude +/- 180 degrees. To preserve longitude precision, adjust by 180 toward 0 degrees.

```
void Limit_Latitude_Longitude(double *latitude_degrees,
double *longitude_degrees) {
*latitude_degrees = Limit_Longitude(*latitude_degrees);
int flip = 0;
if (*latitude_degrees > 90.0) {
*latitude_degrees = 180.0 - *latitude_degrees;
flip = 1;
} else if (*latitude_degrees < -90.0) {
*latitude_degrees = -180.0 - *latitude_degrees;
flip = 1;
}
if (flip) {
*longitude_degrees += *longitude_degrees > 0 ? -180.0 : 180.0;
}
*longitude_degrees = Limit_Longitude(*longitude_degrees);
}
```