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So far I've seen many posts dealing with equality of floating point numbers. The standard answer to a question like "how should we decide if x and y are equal?" is

abs(x - y) < epsilon

where epsilon is a fixed, small constant. This is because the "operands" x and y are often the results of some computation where a rounding error is involved, hence the standard equality operator == is not what we mean, and what we should really ask is whether x and y are close, not equal.

Now, I feel that if x is "almost equal" to y, then also x*10^20 should be "almost equal" to y*10^20, in the sense that the relative error should be the same (but "relative" to what?). But with these big numbers, the above test would fail, i.e. that solution does not "scale".

How would you deal with this issue? Should we rescale the numbers or rescale epsilon? How? (Or is my intuition wrong?)

Here is a related question, but I don't like its accepted answer, for the reinterpret_cast thing seems a bit tricky to me, I don't understand what's going on. Please try to provide a simple test.

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3 Answers 3

up vote 15 down vote accepted

It all depends on the specific problem domain. Yes, using relative error will be more correct in the general case, but it can be significantly less efficient since it involves an extra floating-point division. If you know the approximate scale of the numbers in your problem, using an absolute error is acceptable.

This page outlines a number of techniques for comparing floats. It also goes over a number of important issues, such as those with subnormals, infinities, and NaNs. It's a great read, I highly recommend reading it all the way through.

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Thank you. The paper also explains the motivations behind the rude cast to int (although in ordinary code I would opt for understandability and use one of the all-float solutions :) –  Federico A. Ramponi Nov 30 '08 at 5:40
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Updated version of the link above is Comparing floating point numbers, 2012 edition –  sfstewman Mar 27 '13 at 8:04

As an alternative solution, why not just round or truncate the numbers and then make a straight comparison? By setting the number of significant digits in advance, you can be certain of the accuracy within that bound.

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Rounding and truncation work poorly. If we round (to nearest) to three digits then 1.499999999999 and 1.5000000000001 will compare ad different, despite being ridiculously close. If we truncate then 1.999999999999 and 2.00000000000001 will compare as different despite being extremely close. Any rounding or truncation scheme will have cusps like this. Any solution has to start by subtracting the numbers and then deciding whether the different is large enough to be significant. –  Bruce Dawson May 27 at 22:27

The problem is that with very big numbers, comparing to epsilon will fail.

Perhaps a better (but slower) solution would be to use division, example:

div(max(a, b), min(a, b)) < eps + 1

Now the 'error' will be relative.

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Precisely, it is relative to the minimum between a and b, isn't it? –  Federico A. Ramponi Nov 30 '08 at 5:59
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Hmmm. Beware of divisions by zero :) –  Federico A. Ramponi Nov 30 '08 at 5:59
    
And pay attention to their sign. The paper in Adam's answer suggests comparison relative absolute maximum. –  Federico A. Ramponi Nov 30 '08 at 6:02
    
I actually just went thru that link now. Very good info :) –  leppie Nov 30 '08 at 6:48

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