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I'm wondering what is the difference for comparing two double between this two manner :

double a1 = ...;
double a2 = ....;
  1. fabs(a1-a2) < epsilon
  2. (fabs(a1-a2)/a2) < epsilon

Is there a prefering way to do that ?


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The "prefering way" heavily depends on the surrounding algorithm. Both have their use (and also the more verbose fabs(a1 - a2) / min(a1, a2) and fabs(a1 - a2) / max(a1, a2), and especially max(fabs(a1 - a2), fabs(a1 - a2) / a1) when you don't know a priori if the numbers are close to zero or not). – Alexandre C. Feb 21 '11 at 9:51
up vote 13 down vote accepted

This article answers your question quite thoroughly, I think. You might want to skip ahead to the section "Epsilon comparisons".

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Added quote from linked article, hope you don't mind, feel free to rollback if you desire. – Binary Worrier Feb 21 '11 at 9:51
Great link. Thanks. – Alexandre C. Feb 21 '11 at 9:54
I worry that that quote is not really answering his question: I think he's aware of the precision issue, just asking why divide by a2. I considered quoting something originally, but I think the article is better left intact. I've rolled-back and edited to indicate the section most relevant. – Martin Stone Feb 21 '11 at 9:57

The former only compares the absolute values, whereas the second compares the relative values. Say that epsilon is set to 0.1: this may be sufficient if a1 and a2 are largish. However, if both values are close to zero, the first way will consider most values equal.

It really depends on what kinds of values you are dealing with. Just be sure to consider the case a2==0 if you use the somewhat more mathematically reasonable second case.

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This has already been pretty well addressed, but a few points are in order:

fabs(a1-a2) < epsilon

is comparing the absolute difference between a1 and a2 to the tolerance epsilon. This may be appropriate if you know the scaling a priori (for example, if a2 is actually a constant), but should generally be avoided if you don't know how big a1 and a2 are.

Your second option almost computes the relative difference, but has a bug; it should actually read:

fabs((a1-a2)/a2) < epsilon

(note that the division is inside the absolute value; otherwise, this condition is useless for negative a2). Relative error is more correct for most uses, because it more closely mirrors the way floating-point rounding actually happens, but there are situations in which it does not work and you need to use an absolute tolerance (usually this is because of catastrophic cancellation). You also will sometimes see relative error bounds written in this form:

fabs(a1-a2) < fabs(a2)*epsilon

which is often somewhat more efficient because it avoids a division.

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really like the last form, don't really understand in which case it doesn"t work – Guillaume07 Feb 21 '11 at 21:15
If my number are 10e-7 to 10e6 which epsilon value should I used ? – Guillaume07 Feb 22 '11 at 10:38
@Guillaume07: If the values are spread over that large of a range, you certainly want to use one of the relative error comparisons (the 2nd or 3rd options that I listed). The more subtle question is "how do I choose an appropriate value of epsilon?" – Stephen Canon Feb 22 '11 at 18:21
Note that when doing a relative difference epsilon comparison you should not just blindly divide by a2 (or a1). If you do that then you get asymmetries where compare(a,b) gives different results from compare(b,a). That would be bad. You need to consistently divide by the number with the largest or smallest absolute value. Something like this: auto largest = max(fabs(a1),fabs(a2)); return fabs(a1-a2) < fabs(largest)*epsilon; – Bruce Dawson Dec 29 '13 at 19:28

Personally, I'm using std::nextafter for comparing two double. This use the smallest epsilon on a value (or a factor of the smallest epsilon).

bool nearly_equal(double a, double b)
  return std::nextafter(a, std::numeric_limits<double>::lowest()) <= b
    && std::nextafter(a, std::numeric_limits<double>::max()) >= b;

bool nearly_equal(double a, double b, int factor /* a factor of epsilon */)
  double min_a = a - (a - std::nextafter(a, std::numeric_limits<double>::lowest())) * factor;
  double max_a = a + (std::nextafter(a, std::numeric_limits<double>::max()) - a) * factor;

  return min_a <= b && max_a >= b;
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The result of nearly_equal(..,..,epsilon) does not equal to : fabs(right-left) < epsilon ? – Guillaume07 Feb 10 at 12:27
nearly_equal(a, b, factor) checks equality with tolerance of factor * epsilon(a). fabs(a-b) < epsilon checks equality with tolerance of a given epsilon. Both expressions are good and can be used according to what we would like to test. Sometime, we want to check with a fixed epsilon (even if it's difficult to find a correct epsilon: epsilon (1e20) = 16384). Sometime, we want to check with a factor of epsilon (even if it's also difficult to find a correct factor). Now for fabs(a-b) < fabs(a) * epsilon, it would be more accurate to use nearly_equal(a, b, epsilon) instead. – Daniel Laügt Feb 10 at 13:38

Epsilon varies according to the value inside the double range. If you want to use your own and fixed epsilon, I recommand to choose an epsilon for 1.

fabs(a1-a2) < epsilon

This is not perfect. If a1 and a2 are results from operations with small numbers, the epsilon would be small. If a1 and a2 are results from operations with big numbers, the epsilon would be big.

fabs((a1-a2)/a2) < epsilon

This is a bit better as you would like to scale epsilon by a2. However, there is a division by 0 if a2 equals 0.

fabs(a1-a2) < fabs(a2)*epsilon

This is a bit better. However, this is incorrect if a2 equals 0. fabs(a2)*epsilon would be equal to 0 and the comparison of two values a1=0.000000001 and a2=0 will always fail.

fabs(a1-a2) < max(fabs(a1), fabs(a2))*epsilon

This is a bit better. However, this is incorrect because epsilon is not proportional in continuous manner. With IEEE encoding, epsilon is proportional to a value in discrete manner on base 2.

fabs(a1-a2) < 2^((int)log2(max(fabs(a1), fabs(a2)))*epsilon

This looks correct for me when both a1 and a2 are not equal to 0.

The implementation of a generic method could be:

bool nearly_equal(double a1, double a2, double epsilon)
  if (a1 == 0 && a2 == 0)
    return true;

  return std::abs(a1 - a2) < epsilon * pow (2.0, static_cast<int> (std::log2(std::max(std::abs(a1), std::abs(a2)))));
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