Consider the following code:

{-# LANGUAGE TypeFamilies #-}

data Twothings a b = Twothings a b

type family Leftthing a where
  Leftthing (Twothings a b) = Leftthing a
  Leftthing a = a

leftthing :: a -> Leftthing a
leftthing (Twothings a b) = leftthing a
leftthing b = b

It doesn't compile, with the following error:

Couldn't match expected type ‘a’
                  with actual type ‘Twothings a0 t0’
      ‘a’ is a rigid type variable bound by
        the type signature for:
          leftthing :: forall a. a -> Leftthing a

It complains about the line leftthing (Twothings a b) = leftthing a. If I understand correctly, it can't unify the type variable a in the type signature with the type of the constructor Twothings. Ok, this seems to make sense. But then, how can I ever define a function with type families in the type signature?

  • What is the problem you are trying to solve? I can give examples of using type families but I'd rather answer a more specific question. – erisco Sep 9 '17 at 10:28

When you declare

leftthing :: a -> Leftthing a

you are saying that the caller of leftthing gets to choose what a is.

When you then write

leftthing (Twothings a b) = leftthing a

you are presuming that they have chosen a Twothings type, and as that is not necessarily the case, your program is rejected.

You may have thought that you were testing whether they had chosen a Twothings type, but no! Type information is erased before run time, so there is no way to make such a test.

You can try to restore the necessary run time information. First let me fix the inconsistency between your Leftthing and leftthing.

type family Leftthing a where
  Leftthing (Twothings a b) = Leftthing{-you forgot the recursion!-} a
  Leftthing a = a

Now we can define the GADT of witnesses to Twothingness.

data IsItTwothings :: * -> * where
  YesItIs   :: IsItTwothings a -> IsItTwothings (Twothings a b)
  NoItIsn't :: Leftthing a ~ a => IsItTwothings a
            -- ^^^^^^^^^^^^^^^ this constraint will hold for any type
            -- which is *definitely not* a Twothings type

And then we can pass the witness as an argument:

leftthing :: IsItTwothings a -> a -> Leftthing a
leftthing (YesItIs r) (Twothings a b) = leftthing r a
leftthing NoItIsn't   b               = b

In effect, the witness is the unary encoding of the number of left-nested Twothingses at the root of your type. That's enough information to determine at run time the correct amount of unpacking to do.

> leftthing (YesItIs (YesItIs NoItIsn't)) (Twothings (Twothings True 11) (Twothings "strange" [42]))

To sum up, you can't find out a type by pattern matching on a value. Rather, you need to know the type to do pattern matching (because the type determines the memory layout, and there are no run time type tags). You can't pattern match on types directly (because they're just not there to be matched on). You can construct data types which act as run time evidence of type structure and match on those instead.

Perhaps, one day, your program will work if you give it the type

leftthing :: pi a. a -> Leftthing a

where pi is the dependent quantifier, indicating that the hidden type argument is not erased, but rather passed and matched on at run time. That day has not yet come, but I think it will.

| improve this answer | |
  • Thanks for spotting my mistake in the type family declaration! (Fixed now) – Turion Sep 9 '17 at 14:09

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.