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I'm trying to implement a data structure where if I had the use of infinity for numerical comparison purposes, it would simply things greatly. Note this isn't maxBound/minBound, because a value can be <= maxbound, but all values would be < infinity.

No hope?

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up vote 13 down vote accepted

Maybe you want a Maybe type?

data Infinite a = Infinite | Only a

then write a Num instance for Num a => Infinite a, with the numeric rules you need.

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Getting obvious there is no solution, so I've basically adopt your approach: data Num a => Inf a = NegInf | Val a | PosInf. Thanks for your help. – me2 Mar 1 '10 at 9:34
Nooo, please don't put a type class constraint on a data declaration! :-) – Martijn Mar 1 '10 at 20:25

Well how about that! It turns out if you just type 1/0 it returns Infinity! On ghci:

Prelude> 1/0
Prelude> :t 1/0
1/0 :: (Fractional t) => t
Prelude> let inf=1/0
Prelude> filter (>=inf) [1..]

and then of course it runs forever, never finding a number bigger than infinity. (But see ephemient's comments below on the actual behavior of [1..])

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IMO, encodeFloat (floatRadix 0 - 1) (snd $ floatRange 0) is a better way to get Infinity (with type (RealFrac a) => a). That being said, because of floating-point imprecision [1..] is never going to get past a finite upper bound, so what you have here is a poor demonstration. – ephemient Mar 1 '10 at 17:35
Darn. I knew I shouldn't have claimed a program would run forever after watching it run for a finite amount of time. – MatrixFrog Mar 1 '10 at 18:35
You misunderstand. At some point, the tail will just be [x, x, x, x, x, ..], because floating x+1 == x when x is large enough, even though there exist higher, finite y (for example, encodeFloat (floatRadix 0 - 1) (snd (floatRange 0) - 1)). Obviously x < y < inf; my point was that this isn't a good demonstration of infinity. – ephemient Mar 1 '10 at 20:26
infinity = read "Infinity"
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I think this is the best answer if the code is floating-point. People tend to forget about floating-point infinity. – migle Sep 19 '14 at 13:52

Try something like this. However, to get Num operations (like + or -) you will need to define Num instance for Infinitable a type. Just like I've done it for Ord class.

data Infinitable a = Regular a | NegativeInfinity | PositiveInfinity deriving (Eq, Show)

instance Ord a => Ord (Infinitable a) where
    compare NegativeInfinity NegativeInfinity = EQ
    compare PositiveInfinity PositiveInfinity = EQ
    compare NegativeInfinity _ = LT
    compare PositiveInfinity _ = GT
    compare _ PositiveInfinity = LT
    compare _ NegativeInfinity = GT
    compare (Regular x) (Regular y) = compare x y    

main =
    let five = Regular 5
        pinf = PositiveInfinity::Infinitable Integer
        ninf = NegativeInfinity::Infinitable Integer
        results = [(pinf > five), (ninf < pinf), (five > ninf)]
        do putStrLn (show results)
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By the way: if you define your Infinitable data type with the NegativeInfinity case first, then the Regular and the PositiveInfinity last, you can derive Ord for free. (If you did it this way to give a relatively simple example, please disregard this comment!) – yatima2975 Mar 1 '10 at 10:43
Huh, actually I didn't know this, thanks. – Denis K Mar 1 '10 at 10:59

Take a look at my RangedSets library, which does exactly this in a very general way. I defined a "Boundary" type so that a value of type "Boundary a" is always either above or below any given "a". Boundaries can be "AboveAll", "BelowAll", "Above x" and "Below x".

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If your use case is that you have boundary conditions that sometimes need to be checked, but sometimes not, you can solve it like this:

type Bound a = Maybe a

withinBounds :: (Num a, Ord a) => Bound a -> Bound a -> a -> Bool
withinBounds lo hi v = maybe True (<=v) lo && maybe True (v<=) hi
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λ: let infinity = (read "Infinity")::Double
λ: infinity > 1e100
λ: -infinity < -1e100
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