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I'd like to define a tuple (x, y) as an instance of Enum class, knowing that both x and y are Enums. A following try

instance (Enum x, Enum y) => Enum (x, y) where
    toEnum = y
    enumFrom x = (x, x)

only results in error (y not in scope). I'm new to Haskell, could somebody explain how to declare such an instance?

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What is the line toEnum = y supposed to do? –  sepp2k Apr 1 '12 at 20:01
It's not actually possible to create a useful Enum (x, y) from Enum x and Enum y. You'd need additional context, like Bounded x, Bounded y, Enum x, Enum y => Enum (x, y). –  Dietrich Epp Apr 1 '12 at 20:30
@sepp2k: When you write succ (x, y), you'd want it to sometimes increment x, sometimes increment y, and somehow cover all possible (x, y). You can't make that happen when you're only given formulas for succ x and succ y. –  Dietrich Epp Apr 1 '12 at 20:50
Agreed, it seems unlikely that Enum (x, y) could be implemented in any sensible way just from this context -- if at all. –  Louis Wasserman Apr 1 '12 at 20:54
@DietrichEpp I can easily make that happen by using toEnum and fromEnum. Though now that I think about it, the fact that those methods use Int, not Integer, would become a problem after a while. –  sepp2k Apr 1 '12 at 20:55

2 Answers 2

instance (Enum x, Enum y) => Enum (x, y) where

In the above line, x and y are both types (type variables).

    toEnum = y
    enumFrom x = (x, x)

In the above two lines, x and y are both values ((value) variables). y-as-a-value has not been defined anywhere, that's what it not being in scope means.

As to how to declare such an instance, I'm not sure how you'd want fromEnum and toEnum to behave, for example.

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Not a good idea if you ask me, but anyway —

To make an instance of a type class, you need to look at the signatures.

class Enum a where
  succ :: a -> a
  pred :: a -> a
  toEnum :: Int -> a
  fromEnum :: a -> Int
  enumFrom :: a -> [a]
  enumFromThen :: a -> a -> [a]
  enumFromTo :: a -> a -> [a]
  enumFromThenTo :: a -> a -> a -> [a]

So in your case

toEnum :: Int -> (x, y)

but toEnum = y isn't even defined, because y is just a type, not a value or constructor. Possibilities would be

toEnum n = (toEnum 0, toEnum n)


toEnum n = (toEnum n, toEnum n)


toEnum n = (toEnum $ n`div`2, toEnum $ (n+1)`div`2)

As for enumFrom, your version has signature

enumFrom :: a -> (a,a)

but we need

enumFrom :: (x,y) -> [(x,y)]

what definition is suitable depends on how toEnum was defined; for my first suggestion it would be

enumFrom (x,y) = [ (x,y') | y' <- enumFrom y ]

Reading Dietrich Epp's comment

It's not actually possible to create a useful Enum (x, y) from Enum x and Enum y. You'd need additional context, like Bounded x, Bounded y, Enum x, Enum y => Enum (x, y).

I thought about ways it could actually be done meaningfully. It seems possible sure enough, a bijection ℤ → ℤ2 exists. My suggestion:

[ ...
, (-3,-3), (-3,-2), (-2,-3), (-3,-1), (-1,-3), (-3,0), (0,-3), (-3,1), (1,-3), (-3,2), (2,-3), (-3,3), (3,-3)
, (-2,3), (3,-2), (-1,3), (3,-1)
, (-2,-2), (-2,-1), (-1,-2), (-2,0), (0,-2), (-2,1), (1,-2), (-2,2), (2,-2)
, (-1,2), (2,-1)
, (-1,-1), (-1,0), (0,-1), (-1,1), (1,-1)
, (0,0)
, (1,0), (0,1), (1,1)
, (2,0), (0,2), (2,1), (1,2), (2,2)
, (3,0), (0,3), (3,1), (1,3), (3,2), (2,3), (3,3)
, ... ]

Note that this reduces to a bijection ℕ → ℕ2 as well, which is important because some Enum instances don't go into the negative range and others do.


Let's make a plain (Int,Int) instance; it's easy to generalize that to your desired one. Also, I'll only treat the positive cases.

Observe that there are k^2 tuples between (0,0) and (excluding) (k,0). All other tuples (x,y) with max x y == k come directly after it. With that, we can define fromEnum:

fromEnum (x,y) = k^2  +  2*j  +  if permuted then 1 else 0
      where k = max x y
            j = min x y
            permuted = y>x

for toEnum, we need to find an inverse of this function, i.e. knowing fromEnum -> n we want to know the parametes. k is readily calculated as floor . sqrt $ fromIntegral n. j is obtained similarly, simply with div 2 of the remainder.

toEnum n =    let k = floor . sqrt $ fromIntegral n
                  (j, permdAdd) = (n-k^2) `divMod` 2
                  permute (x,y) | permdAdd>0  = (y,x)
                                | otherwise    = (x,y)
              in permute (k,j)

With fromEnum and toEnum, all the other functions are rather trivial.

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It's not enough to have a ℤ<sup>2</sup> → ℤ bijection, since the range must be compact in order to be useful (I would say it's a rule of the Enum class). Here is a demonstration of how it breaks, since x and y don't necessarily have the same cardinality. gist.github.com/2279321 –  Dietrich Epp Apr 1 '12 at 23:09
Instances with different cardinality are of course unsolvable, so it would only give an instance (Enum a) => Enum (a,a). I found another problem with toEnum for n>3 that I don't understand yet: map (fromEnum' . toEnum') [0..] evaluates to [0,1,2,3,6,7,8,8,14..]. Hm... –  leftaroundabout Apr 1 '12 at 23:14
@DietrichEpp fixed, it had to be n-k^2 of course. gist.github.com/2279399 –  leftaroundabout Apr 1 '12 at 23:29
A thought for general (x, y) with no negative parts: using fromEnum and diagonalization one can construct a fromEnum instance for the tuple type, and using list operations (!!) and findIndex one can create toEnum and fromEnum. It doesn't even require an Eq instance (for findIndex) since it can be synthesized from \x1 x2 -> fromEnum x1 == fromEnum x2. –  Dietrich Epp Apr 1 '12 at 23:34

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