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Just for fun, I wanted to create a Type level list that knows how long it is. Something like this:

{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE TypeOperators #-}

import GHC.TypeLits

data family TypeList a (n::Nat)

data instance TypeList a (0) = EmptyList
data instance TypeList a (1) = TL1 a (TypeList a (0))
data instance TypeList a (2) = TL2 a (TypeList a (1))
data instance TypeList a (3) = TL3 a (TypeList a (2))

But, of course I'd like to generalize this to something like:

data instance TypeList a (n)   = TL3 a (TypeList a (n-1))

But this generates an error:

    TypeList.hs:15:53: parse error on input `-'
    Failed, modules loaded: none.

Another attempt:

data instance TypeList a (n+1) = TL3 a (TypeList a (n))

Also generates an error:

    Illegal type synonym family application in instance: n + 1
    In the data instance declaration for `TypeList'

I assume something like this must be possible. It's definitely possible using the notation:

data Zero
data Succ a

But I can't figure it out with the nicer looking version.

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2 Answers 2

up vote 3 down vote accepted

The type-level Nat improvements have landed in GHC 7.8 and this is now possible!

{-# LANGUAGE DataKinds, KindSignatures #-}
{-# LANGUAGE TypeFamilies, TypeOperators #-}

import GHC.TypeLits

data family List (n :: Nat) a
data instance List 0 a = Nil
data instance List n a = a ::: List (n - 1) a

infixr 8 :::

using List is just as natural as any []-like data structure you'd write yourself:

λ. :t 'a' ::: 'b' ::: 'c' ::: Nil
'a' ::: 'b' ::: 'c' ::: Nil :: List 3 Char
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When I've tried to use the type-level Nat stuff in 7.8, the problem I ran into was that while it now works for fixed finite Nats (e.g. it can work out that List (0 + (1 + (1 + 1))) is List 3 Char), when you try to write generic operations like <++> :: List n a -> List m a -> List (n + m) a you get errors like Could not deduce (((n1 + m) + 1) ~ (n + m)) from the context (n ~ (n1 + 1)). So it seems like there's still more work needed before it can really replace the Zero/Succ based approaches - although I'm far from expert, so maybe I'm missing something. –  Ben Apr 3 at 6:02
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As they are in GHC 7.6, type-level Nats won't let you do this sort of thing. There's currently more or less no relation between the types 0 :: Nat and 1 :: Nat, despite what the names suggest (unlike, say, your Zero and Succ Zero, which you can do useful things with). This is going to be better in future versions of GHC.

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Is that the plan for 7.8, or is it not exactly spelled out yet? –  Mike Izbicki Dec 16 '12 at 7:56
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