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Playing with Type Level Literals as a way to discriminate non empty container values (as with phantom types) using a Maybe like type.

This works well. (required GHC >= 7.6.1)

But trying to define a binary function (eq)

eq :: (Eq a) => TMaybe (sym :: Symbol) a -> TMaybe (sym :: Symbol) a -> Bool

that admits different groups of values, signals a compile error when it is used:

Couldn't match type "Just"' with"Nothing"'

{-# LANGUAGE DataKinds, KindSignatures, GADTs, FlexibleInstances #-} 

import GHC.TypeLits

data TMaybe :: Symbol -> * -> * where
  TNothing  :: TMaybe "Nothing" a
  TJust :: a -> TMaybe "Just" a

nonEmpty :: Maybe a -> TMaybe "Just" a
nonEmpty (Just x) = TJust x
nonEmpty Nothing = error "invalid nonEmpty data"

-- this fromJust rejects TNothing at compile time  
fromJust :: (sym ~ "Just") => TMaybe (sym :: Symbol) a -> a
fromJust (TJust x) = x

tmbToMaybe :: TMaybe (sym :: Symbol) a -> Maybe a
tmbToMaybe TNothing = Nothing
tmbToMaybe (TJust x) = Just x

mbToTNothing Nothing = TNothing

mbToTJust (Just x) = TJust x

instance Eq a => Eq (TMaybe (sym :: Symbol) a) where
     TNothing == TNothing = True
     TJust x == TJust y = x == y
     _ == _ = False    -- useless, equal types required

instance Ord a => Ord (TMaybe (sym :: Symbol) a) where
     compare TNothing TNothing = EQ
     compare (TJust x) (TJust y) = Prelude.compare x y
     compare TNothing _ = LT   -- useless, equal types required
     compare _ TNothing = GT   -- useless, equal types required

instance  Functor (TMaybe (sym :: Symbol))  where
    fmap _ TNothing       = TNothing
    fmap f (TJust a)      = TJust (f a)

instance  Monad (TMaybe "Just") where
    (TJust x) >>= k      = k x

    (TJust _) >>  k      = k

    return            = TJust
    fail _              = error "can't fail to TNothing"


-- defining eq to admit parameter types with different symbol

eq :: (Eq a) => TMaybe (sym :: Symbol) a -> TMaybe (sym :: Symbol) a -> Bool
eq TNothing TNothing = True
eq (TJust x) (TJust y) = x == y
eq _ _ = False


-- Test

main = do
        print $ fromJust $ TJust (5::Int)   -- type-checks
        -- print $ fromJust TNothing   -- as expected, does not type-check

        -- print $ TNothing == TJust (5::Int)  -- as expected, does not type-check, types required equal at function def.
        print $ TNothing `eq` TJust (5::Int)   -- does not type-check either
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1 Answer 1

up vote 9 down vote accepted

Well, your type

eq :: (Eq a) => TMaybe (sym :: Symbol) a -> TMaybe (sym :: Symbol) a -> Bool

demands that both arguments have the same type, so of course the compiler will reject an attempt to compare a TMaybe "Nothing" a and a TMaybe "Just" a.

If you change the type to

eq :: (Eq a) => TMaybe (sym :: Symbol) a -> TMaybe (sym1 :: Symbol) a -> Bool

it compiles and

TNothing `eq` TJust (5::Int)

evaluates to False. (You then need to explicitly determine the type of TNothings in many places, though.)

share|improve this answer
thanks, with the kind stuff cluttering the type, I did not pay attention to the ''sym'' variable –  Gabriel Riba Feb 7 '13 at 15:44

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