Consider the following typeclass that defines pairs of types:

class Constraint a b where
  g :: a -> b

For all instances of constraint we can derive a set of types a, essentially an implicit typeclass, let's call it A. For each instance of typeclass A there is another implicit typeclass B which is includes all possible types b for Constraint A b.

So here is a piece of code.

{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE MultiParamTypeClasses #-}
import Debug.Trace

-- Contraining class
class (Show a, Show b) => QandA a b where
  g :: a -> b

-- Some data types
data A = A1 | A2 deriving (Show, Eq)
data B = B1 | B2 deriving (Show, Eq)
data C = C1 | C2 deriving (Show, Eq)

instance QandA A B where
  g A1 = B1
  g A2 = B2

instance QandA A C where
  g A1 = C1
  g A2 = C2

-- We want to define a set of types that includes all the types that
-- have Constraint a b given a. This can be done via an intermediate
-- type.
data DefaultAnswer q = forall a . (DefaultingQuestion q, QandA q a) => DefaultAnswer {answer :: a};

-- Polymorphism
class DefaultingQuestion q where
  def :: DefaultAnswer q

instance DefaultingQuestion A where
  def = DefaultAnswer C1

Which typechecks but in ghci

> (def :: DefaultAnswer A)
(def :: DefaultAnswer A) :: DefaultAnswer A


> answer (def :: DefaultAnswer A)
    Cannot use record selector "answer" as a function due to escaped type variables
    Probable fix: use pattern-matching syntax instead
    In the expression: answer (def :: DefaultAnswer A)
    In an equation for "it": it = answer (def :: DefaultAnswer A)

Now the way I understand it is that, since I use existential types, GHC does not really look for the type of answer, it just makes sure there could be one even if it has no way of figuring out which one it is. So then when I actually want to run answer it can't figure out how to deal with it.

So my question is: is there a way to define a default answer for each type that implements DefaultingQuestion

  • 3
    I don't think this is going to work, unless you want to add a Typeable constraint or something. Can you give some concrete examples of why you want this? – dfeuer Mar 21 '16 at 13:16
  • The Typeable (or Data) constraint is an acceptable compromise, but I couldn't figure out how to do it event with those... – fakedrake Mar 21 '16 at 13:28
  • 2
    This code is so ... weird ... that I can't give any concrete advice without more background about what, concretely, you're trying to accomplish. Do you have a use-case? – dfeuer Mar 21 '16 at 13:32

Why not:

import Data.Proxy

class DefaultingQuestion q a where
  def :: Proxy q -> a

instance DefaultingQuestion A where
  def _ = C1
  • Yes proxy was exactly the kind of thing I was looking for – fakedrake Mar 22 '16 at 14:17

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