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)
```

or

```
toEnum n = (toEnum n, toEnum n)
```

or

```
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 → ℤ^{2} 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 → ℕ^{2} as well, which is important because some `Enum`

instances don't go into the negative range and others do.

## Implementation:

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.

`toEnum = y`

supposed to do? – sepp2k Apr 1 '12 at 20:01`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`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`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`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