# Comparison between fractional type

ghci> 4 == 3.9999999999999999
True

ghci> 10.2^2 == 104.04
False

Why the 2nd expression returns False?

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lookup numeric precision and respresentation –  Mitch Wheat May 18 '11 at 0:50

Floating point values do not have a sensible notion of equality. Arguably, it is an error in Haskell that the expression even type checks. The issue is common to all languages that use floating point representations.

Some references on floating point:

Consider using the Rational type in Haskell, if you need correct math here, but note that it supports a smaller range of operations, and less hardware support.

Prelude> 4 == (3.9999999999999 :: Rational)
False
Prelude> 10.2^2 == (104.04 :: Rational)
True
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Note that this works because floating point literals are overloaded, just like integer literals, e.g. 10.2 means fromRational (102 % 10). –  hammar May 18 '11 at 1:06
@Dietrich Epp: I tend to think of float equality as similar to pointer equality of values on the heap--it tells you if things are exactly identical, not if they're distinct but equivalent in a meaningful way. –  C. A. McCann May 18 '11 at 1:26
Floating point has a perfectly sensible notion of equality. It's your expectations of the values being compared that are incorrect. –  Stephen Canon May 18 '11 at 19:22
@Stephen - if by "perfectly sensible" you mean "x == x can be false, and x == y can depend on whether or not x and/or y were roundtripped through memory since the time they were computed"... –  mokus May 19 '11 at 14:19
@Stephen - I agree that in that sense it is perfectly sensible, but I also tend to agree with @Don and others that it is not really a "notion of equality", at least not a mathematical one. The first case (x == x being false) doesn't rely on excess precision, it's in the IEEE spec. NaN == NaN is false, even for identical NaNs. That makes it not an equality relation, by definition. But then, "equality" has always been treated more pragmatically in programming than in mathematics. After all, equality of real numbers isn't actually even decidable (constructively, anyway) in the first place. –  mokus May 20 '11 at 14:20
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Stack Overflow should automatically link you to this whenever it detects a decimal point in a question :) –  hammar May 18 '11 at 1:01
I don't think this question is actually about floating point arithmetic though. I think they're aware of those issues, but were wondering why 4 == 3.9999... but 104.04 != 104.03999..., and the answer is just because GHCI rounds 3.999... if there are enough 9s. –  Jeff Burka May 18 '11 at 1:17
@hammar: only if we can also have SO automatically deduct 100 rep everytime someone posts an "answer" consisting solely of this link. –  Stephen Canon May 18 '11 at 19:29
@Stephen: Would you care to elaborate? This linked article pretty-much is the canonical answer to these type of questions. Any elaboration added by me would just be unnecessary repetition of what's in the article. –  LukeH May 18 '11 at 19:58
@LukeH: It's like answering a question about an implementation detail of red-black trees with a link to CLRS. The answer is probably in there somewhere, but that doesn't make it useful to the questioner, except in the broad "you should really read this" sense. –  Stephen Canon May 20 '11 at 3:15

### When equality tests do and do not work on floating point numbers

You should learn about representation of floating point numbers in the computer memory. See other answers for helpful links. In fact, strict comparison (==) almost never works reliably against them.

Most of the real numbers cannot be represented with machine floating point precisely. Only few of them (like i/2^n, where i and n are integers) are represented precisely. The others are not. This implies, that in general the equality test has unpredictable result on floating point numbers, and the only situation where you can use it is when you known a priory that the numbers are in the above mentioned form. This may work well when planning and writing tests.

### Three approaches

The workaround is to use less than or greater than tests on floating point numbers most of the time (or use rational numbers). When you still want to compare two floating point numbers (e.g. in tests), you can define the accuracy of comparison.

ghci> let eq tol a b = tol > abs (a-b)
ghci> eq 1e-6 4 3.9999999999999999
True
ghci> eq 1e-6 (10.2^2) 104.04
True

You may also consider using (~==) approximate comparison from ieee754 package. But accuracy of the results in most of the real-life calculations is well below the accuracy of the maching floating point types, so it still makes sense to allow some error.

Why the 2nd expression returns False?

104.04 should be 2601/25, not a number in the form i/2^n, so it cannot be represented precisely with floating point numbers (GHCi defaults to Double, probably). So it happens that on your platform 10.2^2 is not equal 104.04. On another platform they could have happened to be equal.

However, if you used rational numbers, they would be equal:

ghci> (102%10)^2 == (10404%100)
True
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I don't agree that you should compare approximately in general. Any time you compare floating point numbers for equality you should pause and think about what you are doing. It's almost always wrong to compare floating point numbers for equality. Using approximate equality just sweeps the problem under the rug. For instance, approximate equality is not an equivalence relation, i.e., a ~== b && b ~== c does not imply a ~== c as one would expect. –  augustss May 18 '11 at 11:18
Only powers of 2 are represented precisely with floating point numbers (0.5, 0.25, ...). In the rest of the situations, where floating point numbers are used, it is usually possible to compare them only approximately, either up to the precision of the type, or to the precision of the application. More often than not, the application (input data precision, methods used, etc.) dictates worse precision than the precision of type. Hence, eq. –  sastanin May 18 '11 at 12:17
I just repeat what I said. If you need to compare floating point numbers for equality, think long and hard. :) –  augustss May 18 '11 at 13:45
@augustuss I repeat what I've written in the answer, (<) or (>) is the usual way to go :-) P.S. Better if the algorithm itself is formulated without the need to compare floats, that's for sure. –  sastanin May 18 '11 at 14:05
Strict equality always works reliably the problem is with people's incorrect expectations of the values being compared, not with the comparison itself. –  Stephen Canon May 18 '11 at 19:26

It's simply a case of rounding. If you just input 3.9999999999999999 into GHCI, you'll see it gets rounded to 4.0, which is clearly equal to 4. 10.2^2 evaluates to 104.03999999999999, which does not get rounded and is not equal to 104.04. The reason it evaluates incorrectly, which you may already know, is because of floating-point arithmetic problems.

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10.2^2 does not evaluate to 104.03999999999999; the latter is an approximation using decimal notation. To find out the exact answer toRational (10.2^2) = 3660582072122081 % 35184372088832, whereas toRational 104.04 = 7321164144244163 % 70368744177664. Two entirely different rational numbers, that differ by (-1) % 70368744177664. –  augustss May 18 '11 at 7:37
@augustss In fact, what 10.2^2 evaluates to depends on its type (context). For example, (10.2^2) :: Rational evaluates to 2601 % 25, which is the exact value. The same applies also to (104.04 :: Rational). –  sastanin May 18 '11 at 14:38
augustss: Whether it evaluates to 104.03999999999999 or 3660582072122081 / 35184372088832 is a matter of perspective. They are two different representations of the same IEEE 64-bit floating point number, and so I would contend that both are equally correct in that sense. The second is correct in the sense of being the rational number it represents, but arguably it is the use of that perspective which leads to the problems people have when using floating point numbers in the first place. Floating point numbers are not reals or even rationals; not even a subset of them. –  mokus May 19 '11 at 14:11
(continuing) Of course, the second has the advantage that it is correct in both contexts :) –  mokus May 19 '11 at 14:12