# Correct Way to Compare Floating-point Numbers [duplicate]

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 StackExchange.ready(function() { if (StackExchange.options.isMobile) return; \$('.dupe-hammer-message-hover:not(.hover-bound)').each(function() { var \$hover = \$(this).addClass('hover-bound'), \$msg = \$hover.siblings('.dupe-hammer-message'); \$hover.hover( function() { \$hover.showInfoMessage('', { messageElement: \$msg.clone().show(), transient: false, position: { my: 'bottom left', at: 'top center', offsetTop: -7 }, dismissable: false, relativeToBody: true }); }, function() { StackExchange.helpers.removeMessages(); } ); }); }); Dec 25 '14 at 20:55

• 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
• 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
• @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
• 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 width`EPSILON`. 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.