In using double fmod(double x, double y) and y is an integer, the result appears to be always exact.

(That is y a whole exact number, not meaning int here.)

Maybe C does not require fmod() to provide an exact answers in these select cases, but on compilers I've tried, the result is exact, even when the quotient of x/y is not exactly representable.

  1. Are exact answers expected when y is an integer?
  2. If not, please supply a counter example.


double x = 1e10;
// x = 10000000000
printf("%.50g\n", fmod(x, 100));
// prints 0

x = 1e60;
// x = 999999999999999949387135297074018866963645011013410073083904
printf("%.50g\n", fmod(x, 100));
// prints 4

x = DBL_MAX;
// x = 179769313486231570...6184124858368
printf("%.50g\n", fmod(x, 100));
// prints 68

x = 123400000000.0 / 9999;
// x = 12341234.1234123408794403076171875
printf("%.50g %a\n", fmod(x, 100), fmod(x, 100));
// prints 34.1234123408794403076171875 0x1.10fcbf9cp+5

My double appears to the IEEE 754 binary64 compliant.
The limitations of printf() are not at issue here, just fmod().


Note: By "Are exact answers expected", I was asking if the the fmod() result and the mathematical result are exactly the same.

  • What do you mean by "exact" here? As in "matches the mathematical result"? – Oliver Charlesworth Jan 4 '14 at 23:57
  • You are correct. Apologies, Bit sleepy – Mitch Wheat Jan 4 '14 at 23:59
  • @OliCharlesworth Yes, "matches the mathematical result" – chux - Reinstate Monica Jan 5 '14 at 0:18

The IEEE Standard 754 defines the remainder operation x REM y as the mathematical operation x - (round(x/y)*y). The result is exact by definition, even when the intermediate operations x/y, round(x/y), etc. have inexact representations.

As pointed out by aka.nice, the definition above matches the library function remainder in libm. fmod is defined in a different way, requiring that the result has the same sign as x. However, since the difference between fmod and remainder is either 0 or y, I believe that this still explains why the result is exact.

  • +1 for the citation. I was looking for a quick intuitive explanation of why there's always an exact result for x - (round(x/y)*y) within the original precision, but it was getting too complicated so I left it out of my answer. – R.. Jan 5 '14 at 1:58
  • 2
    I don't think there is an easy explanation. Naively calculating x-round(x/y)*y is not identical to fmod(x, y) for some extreme cases that I tried (x = pow(2, 53)*100 and y = 100, for instance). Implementations have to perform tricks like iterative subtraction to keep the result mathematically exact. – Emilio Silva Jan 5 '14 at 2:02
  • The best explanation I know starts by subtracting r^n * y where r is the radix and n is the exponent that yields a result whose exponent is the same as the exponent of x; this reduces the number of places of precision by at least one and yields a value congruent to x mod y. I suspect you apply this argument inductively to get the conclusion, but the details (especially when sign flips) are a pain. – R.. Jan 5 '14 at 2:14
  • 2
    @R.. What about the following explanation: let r be the mathematical result. Both x and y are floating-point numbers larger than r and therefore multiples of ulp(r). Therefore r is a multiple of ulp(r), therefore r is exactly representable as a floating-point number. – Pascal Cuoq Jan 5 '14 at 9:39
  • @PascalCuoq: Not all exact multiples of ulp(r) are representable. For instance, LLONG_MAX*ulp(r) most certainly is not. – R.. Jan 5 '14 at 19:25

The result of fmod is always exact; whether y is an integer is irrelevant. Of course, if x and/or y are already approximations of some real numbers a and b, then fmod(x,y) is unlikely to be exactly equal to a mod b.

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