What is the difference is between the
Fractional classes in Haskell?
The definitions of
Floating can be found in the documentation of the Prelude:
class Num a => Fractional a where (/) :: a -> a -> a recip :: a -> a fromRational :: Rational -> a
Fractional numbers, supporting real division.
class Fractional a => Floating a where pi :: a exp :: a -> a log :: a -> a sqrt :: a -> a (**) :: a -> a -> a logBase :: a -> a -> a sin :: a -> a cos :: a -> a tan :: a -> a asin :: a -> a acos :: a -> a atan :: a -> a sinh :: a -> a cosh :: a -> a tanh :: a -> a asinh :: a -> a acosh :: a -> a atanh :: a -> a
Trigonometric and hyperbolic functions and related functions.
So to translate that into English: A
Fractional is any kind of number for which I can define a division:
(/) :: Fractional a => a -> a -> a
That can for instance be the case for floating point numbers, but also for fractions (where a fraction has a numerator and denominator). This is not the case for
Int because if dividing an
Int by an
Int does not always produce an
Int (well technically floating point division on a computer is not exact, but that is another story).
A subset of
Fractional numbers are
Floating numbers where trigonometric are defined. It is for instance impossible that the
sin of a fraction always produces a fraction: a
sin is defined as an sum over an infinite sequence. Only for a very limited number of cases (like
sin 0) it holds. Basically the only numbers on a computer for which trigonometric are defined (approximatively) are floating point numbers.
Fractionalis the class of types that can represent (exactly or at least in a decent approximation) any rational number. It may ad lib also be able to represent other numbers, but that's not important.
In other terms, it's just the class of number types that have a division operation; since it's a subclass of
Numit follows from this that the types must contain the rational numbers.
Floatingis the class of number types that are closed under limits in the Cauchy sense, i.e. complete spaces. This is necessary to do any sort of calculus. The methods of the
Floatingclass are functions that are mathematically defined as limits, namely infinite sums (which are the limits of the sequence of partial sums of taylor series).
Since you can define the real numbers as limits of sequences of rational numbers and because again
Floatingis a subclass of
Floatingtype is able to represent (again, at least to a decent approximation) any real number.
A good way to visualise the difference is through topology:
Floating types are connected spaces, i.e. they form a continuum. What this means for floating point numbers is: every value is understood as a whole interval of real numbers (because floating-point always has some uncertainty). When you lay these intervals side by side, you tile the entire real numbers (at least to ±10300) without gaps.
By contrast, some
Fractional types are not connected. In particular,
Rational can exactly represent all its (rational-number) values, so each value is just an “infinitely small point”. You can never cover the entire real line with such points, and you can not compute functions like
log since the result of these functions is usually a non-rational real number.
It's worth pondering a bit what this “decent approximation” means. The Haskell standard doesn't define this. This story about every floating point number representing a whole interval of real numbers captures it quite well IMO. More generally, we might say:
Floating are the classes of types that represent equivalance classes of integer/rational/real numbers. In fact, these classes need not even be “small” intervals: in particular the finite types like
Word32 or the standard
Int can be understood in a modular arithmetic sense, manifesting in results like
(2^70 :: Int) == 0, i.e. the equivalence classes are then numbers spaces by a multiple of 264.
In cases like
Rational, the equivalence classes actually contain only a single element, i.e. the numbers are represented exactly. For real numbers, this is actually also possible, but much more tricky, it's called exact real arithmetic. There are libraries such as aern that do this.