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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.

share|improve this question
    
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: http://www.haskell.org/haskellwiki/Type_witness

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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