The mathematics works the same for floating-point types as it does for integer types: If *n* is a power of the radix (two for binary), then *f* modulo *n* can be computed by zeroing digits representing values *n* or greater (also known as the high bits or high digits).

So, for a binary integer with bits b_{15} b_{14} b_{13} b_{12} b_{11} b_{10} b_{9} b_{8} b_{7} b_{6} b_{5} b_{4} b_{3} b_{2} b_{1} b_{0}, we can compute the residue modulo four simply by setting b_{15} to b_{2} to zero, leaving only b_{1} b_{0}.

Similarly, if the radix of the floating-point format is two, we can compute the residue modulo four by removing all digits whose value is four or greater. This does not require a division, but it does require examining the bits representing the value. A simple bit mask alone will not suffice.

The C standard characterizes a floating-point type as a sign (±1), a base *b*, an exponent, and some number of base *b* digits. Thus, if we know the format a particular C implementation uses to represent a floating-point type (the way that the sign, exponent, and digits are encoded into bits), an algorithm for calculating *f* modulo *n*, where *n* is a power of *b*, is:

- Let
*y* = *f*.
- Use the difference between the exponent of
*y* and the exponent of *n* to decide which digits in *y* have position values less than *n*.
- Change those digits to zero.
- Return
*f* − *y*.

Some notes:

- The algorithm has to handle infinities, NaNs, subnormals, and other special cases.
- The purpose of zeroing low digits in the copy
*y* and subtracting from *f* rather than zeroing high digits directly in *f* is to avoid the need to zero the implicit bit in the IEEE 754 format. (In the algorithm as stated, if the implicit bit in *y* needs to be zeroed, then all of *y* is zeroed, so it is easy.)
- Although no division is used, the manipulations are not as simplistic as a bit mask and are unlikely to be useful generally. However, there are special situations, often with known values of
*d* and limited values of *x*, where such bit manipulations of floating-point representations are useful.

Sample code:

```
// This code assumes double is IEEE 754 basic 64-bit binary floating-point.
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
// Return the bits representable double x.
static uint64_t Bits(double x)
{ return (union { double d; uint64_t u; }) { x } .u; }
// Return the double represented by bits x.
static double Double(uint64_t x)
{ return (union { uint64_t u; double d; }) { x } .d; }
// Return x modulo 2**E.
static double Mod(double x, int E)
{
uint64_t b = Bits(x);
int e = b >> 52 & 0x7ff;
// If x is a NaN, return it.
if (x != x) return x;
// Is x is infinite, return a NaN.
if (!isfinite(x)) return NAN;
// If x is subnormal, adjust its exponent.
if (e == 0) e = 1;
// Remove the encoding bias from e and get the difference in exponents.
e = (e-1023) - E;
// Calculate number of bits to keep. (Could be consolidated above, kept for illustration.)
e = 52 - e;
if (e <= 0) return 0;
if (53 <= e) return x;
// Remove the low e bits (temporarily).
b = b >> e << e;
/* Convert b to a double and subtract the bits we left in it from the
original number, thus leaving the bits that were removed from b.
*/
return x - Double(b);
}
static void Try(double x, int E)
{
double expected = fmod(x, scalb(1, E));
double observed = Mod(x, E);
if (expected == observed)
printf("Mod(%a, %d) = %a.\n", x, E, observed);
else
{
printf("Error, Mod(%g, %d) = %g, but expected %g.\n",
x, E, observed, expected);
exit(EXIT_FAILURE);
}
}
int main(void)
{
double n = 4;
// Calculate the base-two logarithm of n.
int E;
frexp(n, &E);
E -= 1;
Try(7, E);
Try(0x1p53 + 2, E);
Try(0x1p53 + 6, E);
Try(3.75, E);
Try(-7, E);
Try(0x1p-1049, E);
}
```

`fmod(x,y)`

. Good compilers, may detect optimizations available for select`x,y`

and emit fast code. – chux - Reinstate Monica Mar 6 '18 at 20:24`f`

was a general floating-point number rather than an integral floating-point number. – Mark Dickinson Mar 6 '18 at 20:27`f%1 == f`

what?!`f%1 = 0`

is a better candidate, yet even that has issues. – chux - Reinstate Monica Mar 6 '18 at 20:329more comments