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Say I have the following GADT AST:

data O a b c where 
    Add ::  O a a a
    Eq :: O a b Bool
    --... more operations

data Tree a where 
    N :: (O a b c) -> Tree a -> Tree b -> Tree c
    L :: a -> Tree a

Now I want to construct a function that replaces all L(eave)s of type a in the Tree, something like this:

f :: a -> Tree b -> Tree b
f x (L a) | typeof x == typeof a = L x
f x (L a) = L a
f x (N o a b) = N o (f x a) (f x b)

Would it be possible to construct such a function? (using classes maybe?) Could it be done if changes are made to the GADTs?

I already have a typeof function: typeof :: a -> Type within a class.

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If you want to compare types dynamically, that's usually an indication that your data structure design is not appropriate for the task at hand. Can you explain what f is used for? – Heatsink Mar 13 '13 at 23:41
f is used to change one variable (leaf) into another. See it as performing lambda substitutions: Say I have the AST of (a+1), then I want to replace a with the correct value so I can evaluate the value of the expression. One of my questions was how to design an appropriate data structure. – nulvinge Mar 14 '13 at 0:06

I dont think this is possible with the current GADT unless you are okay with having a partially defined function. You can write

--f :: (Typeable a, Typeable b) => a -> Tree b -> Tree a
f x (L a)
   | show (typeOf x) == show (typeOf a) = L x

but you can't make this function total because you would need

   | otherwise = L a

and that wont typecheck, since you just proved L a :: Tree a and L x :: Tree x are different types.

However, if you define the GADT as existentially quantified

data Tree where
    N :: (O a b c) -> Tree -> Tree -> Tree
    L :: Typeable a => a -> Tree

f :: Typeable a => a -> Tree -> Tree
f x (L a)
    | show (typeOf x) == show (typeOf a) = L x
    | otherwise = L a

you lose the type information in your Tree, but this typechecks and is total

another version that retains type information

data Tree a b c where
    N :: (O a b c) -> Tree a b c -> Tree a b c -> Tree a b c
    L :: Typeable a => a -> Tree a b c

f :: Typeable a => a -> Tree a b c -> Tree a b c
f x (L a)
    | show (typeOf x) == show (typeOf a) = L x
    | otherwise = L a

here you keep the type information for any possible value stored in a L in the Tree type. This might work if you only need a few different types, but would get bulky quickly.

share|improve this answer
Thanks for the answer. I already have some stuff to take care of the condition, but as you say it will not typecheck (I updated the question) – nulvinge Mar 14 '13 at 0:00
Great, a solution that works. Can I instead use some boxing type to maybe do something like this?: f :: (Typeable a) => Box -> Tree a -> Tree a and data Box where B :: Typeable a => a -> B. I'll try that. – nulvinge Mar 14 '13 at 14:05
The issue is that the type of your Tree GADT cant depend on the type of the values at its leaves. You want to have a Tree with some leaves containing a value of one type, and some leaves with a value of a completely different type and the type of the Tree cant be both. See my edited answer for a possible solution if you need the type information. – cdk Mar 14 '13 at 14:35
That is not the problem. And your last version of f cannot recurse on N (cannot determine a ~ b). I did solve it using some code trickery anyway. – nulvinge Mar 14 '13 at 15:15
Glad to hear you solved it. Are you sure that f cannot recurse on N? I have no problem writing f x (N o a b) = N o (f x a) (f x b) with my definition of f. – cdk Mar 14 '13 at 17:07
up vote 0 down vote accepted

The trick is to use type witnesses:

data O a b c where 
    Add ::  O a a a
    Eq :: O a b Bool

instance Show (O a b c) where
    show Add = "Add"
    show Eq = "Eq"

data Tree a where 
    T :: (Typeable a, Typeable b, Typeable c) => (O a b c) -> Tree a -> Tree b -> Tree c
    L :: a -> Tree a

instance (Show a) => Show (Tree a) where
    show (T o a b) = "(" ++ (show o) ++ " " ++ (show a) ++ " " ++ (show b) ++ ")"
    show (L a) = (show a)

class (Show a) => Typeable a where
    witness :: a -> Witness a

instance Typeable Int where
    witness _ = IntWitness

instance Typeable Bool where
    witness _ = BoolWitness

data Witness a where
    IntWitness :: Witness Int
    BoolWitness :: Witness Bool

dynamicCast :: Witness a -> Witness b -> a -> Maybe b
dynamicCast IntWitness  IntWitness a  = Just a
dynamicCast BoolWitness BoolWitness a = Just a
dynamicCast _ _ _ = Nothing

replace :: (Typeable a, Typeable b) => a -> b -> b
replace a b = case dynamicCast (witness a) (witness b) a of
    Just v  -> v
    Nothing -> b

f :: (Typeable a, Typeable b) => b -> Tree a -> Tree a
f x (L a) = L $ replace x a
f x (T o a b) = T o (f x a) (f x b)
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