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The C++ FAQ lite "[29.17] Why doesn't my floating-point comparison work?" recommends this equality test:

#include <cmath>  /* for std::abs(double) */

inline bool isEqual(double x, double y)
  const double epsilon = /* some small number such as 1e-5 */;
  return std::abs(x - y) <= epsilon * std::abs(x);
  // see Knuth section 4.2.2 pages 217-218
  1. Is it correct, that this implies that the only numbers which are equal to zero are +0 and -0?
  2. Should one use this function also when testing for zero or rather a test like |x| < epsilon?


As pointed out by Daniel Daranas the function should probably better be called isNearlyEqual(which is the case I care about).

Someone pointed out this link, which I want to share more prominently.

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I've a sentence in my head which says, never test a double to equal. Only greater or smaller. –  user743414 Nov 7 '13 at 13:49
@user743414 in some scenarios, it is totally fine to test a double to equal. E.g. if(counter > 10.0) { counter = 0.0; //dostuff } and elsewhere in code: if(counter == 0.0){//oh I know that counter is reseted} else{//do other stuff}... –  relaxxx Nov 7 '13 at 14:14
What do you actually want to do? As for question 1, then yes, the only values that compare equal to +0.0 (or indeed -0.0) are +0.0 and -0.0. But I don't see that the code in the question implies that. –  David Heffernan Nov 7 '13 at 15:42
@relaxxx: counters are integers. –  n.m. Nov 7 '13 at 17:04

5 Answers 5

up vote 10 down vote accepted

You are correct with your observation.

If x == 0.0, then abs(x) * epsilon is zero and you're testing whether abs(y) <= 0.0.

If y == 0.0 then you're testing abs(x) <= abs(x) * epsilon which means either epsilon >= 1 (it isn't) or x == 0.0.

So either is_equal(val, 0.0) or is_equal(0.0, val) would be pointless, and you could just say val == 0.0. If you want to only accept exactly +0.0 and -0.0.

The FAQ's recommendation in this case is of limited utility. There is no "one size fits all" floating-point comparison. You have to think about the semantics of your variables, the acceptable range of values, and the magnitude of error introduced by your computations. Even the FAQ mentions a caveat, saying this function is not usually a problem "when the magnitudes of x and y are significantly larger than epsilon, but your mileage may vary".

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+1 There is indeed no "one size fits all" advice here. –  David Heffernan Nov 7 '13 at 16:59


Equality is equality.

This function will not test two doubles for equality, as its name promises. It will only test if two doubles are "close enough" to each other.

If you really want to test two doubles for equality, use this one:

inline bool isEqual(double x, double y)
   return x == y;

Note: Coding standards usually recommend against comparing two doubles for exact equality. But that is a different subject. If you actually want to compare two doubles for exact equality, x == y is the code you want.

10.00000000000000001 is not equal to 10.0, whatever they tell you.

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I usually delete my negatively voted answers. However, I will keep this one, because it is correct. –  Daniel Daranas Nov 7 '13 at 16:21
I didn't -1, but your isEqual function will surprise you one day :) Probably when you realize how precise floating points are. –  BЈовић Nov 7 '13 at 16:34
@BЈовић No. It will not surprise me. I will seldom use it, but when I do, I will mean to check that one double is equal to another one. 10.00000000000000001 is not equal to 10.0. –  Daniel Daranas Nov 7 '13 at 16:52
@kfsone Considering that +0.0 == -0.0 for any compiler that implements either exactly IEEE 754 or something close to IEEE 754, I have no idea what you are talking about. x == 0.0 is true if and only if x is -0.0 or +0.0. –  Pascal Cuoq Nov 7 '13 at 17:35
I guess ultimately the problem is people using floating precision when what they actually want is fixed. Daniel's argument (10.00000000000000001 is not 10.0) is fair, except that people don't expect it to be a factor when they are comparing "5.0 + 5.0" vs "15.0 - 5.0". –  kfsone Nov 7 '13 at 20:07

Like @Exceptyon pointed out, this function is 'relative' to the values you're comparing. The Epsilon * abs(x) measure will scale based on the value of x, so that you'll get a comparison result as accurately as epsilon, irrespective of the range of values in x or y.

If you're comparing zero(y) to another really small value(x), say 1e-8, abs(x-y) = 1e-8 will still be much larger than epsilon *abs(x) = 1e-13. So unless you're dealing with extremely small number that can't be represented in a double type, this function should do the job and will match zero only against +0 and -0.

The function seems perfectly valid for zero comparison. If you're planning to use it, I suggest you use it everywhere there're floats involved, and not have special cases for things like zero, just so that there's uniformity in the code.

ps: This is a neat function. Thanks for pointing to it.

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notice, that code is:

std::abs((x - y)/x) <= epsilon

you are requiring that the "relative error" on the var is <= epsilon, not that the absolute difference is

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This is only equivalent if x is not 0. –  Daniel Daranas Nov 7 '13 at 15:42

2 + 2 = 5(*)

(for some floating-precision values of 2)

This problem frequently arises when engineers perceive "floating point" storage as a way to increase precision who then run afoul of the "floating" part, but the way modern floating point numbers are achieved means that what they actually get is a non-sequential number space with variable granularity.

E.g. instead of providing you a space that can store "0.0001", "0.0002" and "0.0003" it might be storing "0.0001001", "0.00029", "0.00033" where truncation/rounding make the numbers look right.

But what happens if you perform "0.0003 - 0.0002"? We expect 1, but the values we are working with are actually "0.00033" - "0.00029" = "0.000004". But there might not be a precise way to store "0.00004" the value we can store might be 0 or 0.000006.

With current floating point math operations, it is not guaranteed that (a / b) * b == a.

#include <stdio.h>

// defeat inline optimizations of 'a / b * b' to 'a'
extern double bodge(int base, int divisor) {
    return static_cast<double>(base) / static_cast<double>(divisor);

int main() {
    int errors = 0;
    for (int b = 1; b < 100; ++b) {
        for (int d = 1; d < 100; ++d) {
            // b / d * d ... should == b
            double res = bodge(b, d) * static_cast<double>(d);
            // but it doesn't always
            if (res != static_cast<double>(b))
    printf("errors: %d\n", errors);

ideone reports 599 instances where (b * d) / d != b using just the 10,000 combinations of 1 <= b <= 100 and 1 <= d <= 100 .

The solution described in the FAQ is essentially to apply a granularity constraint - to test if (a == b +/- epsilon).

An alternative approach is to avoid the problem entirely by using fixed point precision or by using your desired granularity as the base unit for your storage. E.g. if you want times stored with nanosecond precision, use nanoseconds as your unit of storage.

C++11 introduced std::ratio as the basis for fixed-point conversions between different time units.

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