`cast`

alone can't do this because it needs to know the types of all variables, but its implementation is quite simple so you can write your own. `cast`

checks `a`

and `b`

are the same type and `unsafeCoerce`

s it if they match.

You can do something using `typeRepCon`

. This deconstructs a `TypeRep`

into the type constructer and a list of types that make it's parameters. First match the type constructors to make sure it's a `Value`

, then check if `y`

is the same. If everything matches you can `unsafeCoerce`

.

```
{-# LANGUAGE GADTs #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE ImpredicativeTypes #-}
import Unsafe.Coerce
import Data.Typeable
data Value x y = Value x y
deriving Typeable
data Box where
Box :: Typeable a => a -> Box
value :: Value Int Char
value = Value 3 'a'
box :: Box
box = Box value
box2 :: Box
box2 = Box 'Z'
getValueY :: forall a y. (Typeable a, Typeable y) => a -> Maybe (forall x. Value x y)
getValueY a
| con == typeRepTyCon (typeOf value) && y == typeRep (Proxy :: Proxy y)
= Just $ unsafeCoerce a
| otherwise = Nothing
where
(con, ~[_x, y]) = splitTyConApp (typeOf a)
valueChar :: Value x Char -> Char
valueChar (Value _ c) = c
boxChar :: Box -> Maybe Char
boxChar (Box b) =
case getValueY b of
Just v -> Just (valueChar v)
Nothing -> Nothing
```

which gives

```
>>> getY box
Just 'a'
>>> getY box2
Nothing
```

The impredicative type (`forall x. Value x y`

) is here to make sure you can't choose what x is, otherwise you could make it whatever you want as long as the `y`

matches. Another (possibly nicer) solution is make another wrapper like

```
data YValue y where
YValue :: Value x y -> YValue y
deriving Typeable
```

A lot of the trouble comes from not even knowing it's a `Value`

, otherwise you could use `gcast`

.

**Edit**: you can avoid `ImpredicativeTypes`

completely by giving it a `forall x. Value x y -> b`

function:

```
withValueY :: forall a y b. (Typeable a, Typeable y)
=> (forall x. Value x y -> b) -> a -> Maybe b
withValueY f a
| con == typeRepTyCon (typeOf value) && y == typeRep (Proxy :: Proxy y)
= Just $ f (unsafeCoerce a)
| otherwise = Nothing
where
(con, ~[_x, y]) = splitTyConApp (typeOf a)
boxChar :: Box -> Maybe Char
boxChar (Box b) = withValueY valueChar b
```

`Value`

.`cast`

to change types arbitrarily, it will fail. If`v :: Value Int Char`

, then`cast v :: Maybe (Value Int Bool)`

will return`Nothing`

. I think you need a real conversion function, which exploits`Value`

's constructors.