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I'm calculating a real numeric value of the form N + fraction. Say, For example, N + fraction = 7.10987623, then N = 7 and fraction = 0.10987623 Next, I need to check to see if fraction is greater than or equal to the ratio 23269/25920.

The following, in C/C++, appears to give correct results; however, I'm not sure if it is the correct way to do the comparison:

// EPSILON is defined to be the error tolerance
// and `ratio' is defined as 23269.0/25920.0 
if(fabs(fraction - ratio) > EPSILON)
 // `fraction' is greater or equal to `ratio'

I also tried to do the other way, but it appears to give incorrect results.

if(fabs(fraction - ratio) < EPSILON)

marked as duplicate by 2501, Pascal Cuoq, tmyklebu, gsamaras, Ben Voigt c Dec 25 '14 at 20:55

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

  • The result of fabs(fraction - ratio) says nothing about whether fraction is greater or less than ratio. When testing what you think is a correct approach, there are five relevant values of fraction to test: one much smaller than ratio, one just a tiny bit smaller than ratio, one exactly equal to ratio (even if ratio is not exactly 23269/25920), one just a tiny bit larger than ratio, and one much larger than ratio. If you test your two approaches like that, you'll find that neither works. If you write out your expected results for those five cases, you'll find the answer. – user743382 Dec 24 '14 at 12:21
  • 1
    Voted for reopen, this question certainly has a lot of duplicates but the duplicate here was wrong. – ouah Dec 24 '14 at 12:22
  • How about comparing fraction * 25920 and 23269? – Kerrek SB Dec 24 '14 at 12:24
  • 1
    @2501 Absolutely not a duplicate. That question is talking about equality ==, this one is about ordering <. They may seem similar but in fact are totally different. – n.m. Dec 24 '14 at 12:44
  • 1
    It doesn't look like you understand what David Schwartz is saying. Let me try to reformulate. The mathematical comparison tells you which of the two cases takes place, (1) x < y or (2) x >= y. You have two actions to perform, do stuff when x < y and do other stuff when x >= y. The decision is easy. The machine floating-point comparison, when implemented correctly, says which of the three cases takes place: (1) x < y, (2) x > y and (3) x and y are too close to tell. You need to either invent three corresponding actions, or lump two of the cases together. – n.m. Dec 24 '14 at 12:55

You have the right way to compare equality:

fabs(fraction - ratio) < EPSILON

which establishes an equality band around ratio of widthEPSILON. Anything above that band, is strictly greater. Thus, the > check is:

fraction > ratio + EPSILON

Since we want >=, we just take the union of those two sections:

fraction > ratio - EPSILON

Rather than specifying an EPSILON, which will need to vary depending on the magnitude of N, an alternative is to add N to ratio, as then both it and fraction will incur the same rounding:

x <= floor(x) + ratio

Break a number into its whole number and fractional parts via modf().
With a good FP library, no loss of precision would be expected.

#include <math.h>
int foo(double N_plus_fraction) {
  double ipart;
  double fraction = modf(N_plus_fraction, &ipart);
  fraction = fabs(fraction);  // lets use the absolution fraction.

Break the threshold into numerator/denominator parts and scale the fraction.

  double f = fraction*25920.0;
  return f >= 23269.0;

As the product f may not be an exact mathematical product of fraction and 25920.0, but the closest rounded one, code could use an f just slightly larger (or smaller) with nextafter() depending on which way one wants to bias the result.

  double f = fraction*25920.0;
  f = nextafter(f, 2*f);  // make f the next greater FP value.
  return f >= 23269.0;

The only inexactness expected occurs in the fraction*25920.0 step.

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