## One way to get the effect your sample seems to be going for

I first want to describe a way to accomplish what it appears you're going for. Let's look at your last code sample again:

```
-- Note, Frob is an instance of class Frobbable
getFrobbable :: (Frobbable a) => Frob -> a
getFrobbable x = x
```

This is essentially a casting operation. It takes a `Frob`

and simply forgets what it is, retaining only the knowledge that you've got an instance of `Frobbable`

.

There is an idiom in Haskell for accomplishing this. It requires the `ExistentialQuantification`

extension in GHC. Here is some sample code:

```
{-# LANGUAGE ExistentialQuantification #-}
module Foo where
class Frobbable a where
getInt :: a -> Int
data Frob = Frob Int
instance Frobbable Frob where
getInt (Frob i) = i
data FrobbableWrapper = forall a . Frobbable a => FW a
instance Frobbable FrobbableWrapper where
getInt (FW i) = getInt i
```

The key part is the `FrobbableWrapper`

data structure. With it, you can write the following version of your `getFrobbable`

casting function:

```
getFrobbable :: Frobbable a => a -> FrobbableWrapper
getFrobbable x = FW x
```

This idiom is useful if you want to have a heterogeneous list whose elements share a common typeclass, even though they may not share a common type. For instance, while `Frobbable a => [a]`

wouldn't allow you to mix different instances of `Frobbable`

, the list `[FrobbableWrapper]`

certainly would.

## Why the code you posted isn't allowed

Now, why can't you write your casting operation as-is? It's all about what could be accomplished if your original `getFrobbable`

function was permitted to type check.

The equation `getFrobbable x = x`

really should be thought of as an equation. `x`

isn't being modified in any way; thus, neither is its type. This is done for the following reason:

Let's compare `getFrobbable`

to another object. Consider

```
anonymousFrobbable :: Frobbable a => a
anonymousFrobbable = undefined
```

(Code involving `undefined`

are a great source of awkward behavior when you want to really push on your intuition.)

Now suppose someone comes along and introduces a data definition and a function like

```
data Frob2 = Frob2 Int Int
instance Frobbable Frob2 where
getInt (Frob2 x y) = y
useFrobbable :: Frob2 -> [Int]
useFrobbable fb2 = []
```

If we jump into ghci we can do the following:

```
*Foo> useFrobbable anonymousFrobbable
[]
```

No problems: the signature of `anonymousFrobbable`

means "You pick an instance of Frobbable, and I'll pretend I'm of that type."

Now if we tried to use your version of `getFrobbable`

, a call like

```
useFrobbable (getFrobbable someFrob)
```

would lead to the following:

`someFrob`

must be of type `Frob`

, since it is being given to `getFrobbable`

.
`(getFrobbable someFrob)`

must be of type `Frob2`

since it is being given to `useFrobbable`

- But by the equation
`getFrobbable someFrob = someFrob`

, we know that `getFrobbable someFrob`

and `someFrob`

have the same type.

Thus the system concludes that `Frob`

and `Frob2`

are the same type, even though they are not. Hence this reasoning is unsound, which is ultimately the type of rational behind why the version of `getFrobbable`

you posted doesn't type-check.