# In Haskell, is there infinity :: Num a => a?

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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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
Infinity
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)]
in
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
True
λ: -infinity < -1e100
True
``````
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