14

Mind this program:

{-# LANGUAGE RankNTypes #-}

import Prelude hiding (sum)

type List h = forall t . (h -> t -> t) -> t -> t

sum_ :: (Num a) => List a -> a
sum_ = \ list -> list (+) 0

toList :: [a] -> List a
toList = \ list cons nil -> foldr cons nil list

sum :: (Num a) => [a] -> a
-- sum = sum_ . toList        -- does not work
sum = \ a -> sum_ (toList a)  -- works

main = print (sum [1,2,3])

Both definitions of sum are identical up to equational reasoning. Yet, compiling the second definition of works, but the first one doesn't, with this error:

tmpdel.hs:17:14:
    Couldn't match type ‘(a -> t0 -> t0) -> t0 -> t0’
                  with ‘forall t. (a -> t -> t) -> t -> t’
    Expected type: [a] -> List a
      Actual type: [a] -> (a -> t0 -> t0) -> t0 -> t0
    Relevant bindings include sum :: [a] -> a (bound at tmpdel.hs:17:1)
    In the second argument of ‘(.)’, namely ‘toList’
    In the expression: sum_ . toList

It seems that RankNTypes breaks equational reasoning. Is there any way to have church-encoded lists in Haskell without breaking it??

  • 6
    Yes, but it will involve hacking on a compiler... rank-2 type inference is decidable, but nobody's implemented it. Rank-3 type inference is undecidable (hence the existence of both Rank2Types and RankNTypes, even though they currently do the same thing). – Daniel Wagner Aug 11 '15 at 0:49
  • 1
    It's very hard for me to understand what you mean by "equational reasoning" here. You're working with an isomorphism that is quite clearly not the usual equality. – dfeuer Aug 11 '15 at 0:55
  • 1
    @dfeuer I'm not sure I know what equational reasoning means, then. I assumed it meant you are free to always inline definitions / beta reduce functions. – MaiaVictor Aug 11 '15 at 0:56
  • 4
    It is okay, I don't know too. – MaiaVictor Aug 11 '15 at 1:02
  • 4
    Note that [a] -> List a is a type that doesn't actually exist in GHC, which makes sum_ . toList just plain ill-typed. – András Kovács Aug 11 '15 at 8:29
13

I have the impression that ghc percolates all for-alls as left as possible:

forall a t. [a] -> (a -> t -> t) -> t -> t)

and

forall a. [a] -> forall t . (h -> t -> t) -> t -> t

can be used interchangeably as witnessed by:

toList' :: forall a t. [a] -> (a -> t -> t) -> t -> t
toList' = toList

toList :: [a] -> List a
toList = toList'

Which could explain why sum's type cannot be checked. You can avoid this sort of issues by packaging your polymorphic definition in a newtype wrapper to avoid such hoisting (that paragraph does not appear in newer versions of the doc hence my using the conditional earlier).

{-# LANGUAGE RankNTypes #-}
import Prelude hiding (sum)

newtype List h = List { runList :: forall t . (h -> t -> t) -> t -> t }

sum_ :: (Num a) => List a -> a
sum_ xs = runList xs (+) 0

toList :: [a] -> List a
toList xs = List $ \ c n -> foldr c n xs

sum :: (Num a) => [a] -> a
sum = sum_ . toList

main = print (sum [1,2,3])
  • 4
    This is indeed how you should define List. GHC has a rather second class treatment of rank-n types, and using them without a newtype wrapper is going to hurt. – augustss Aug 11 '15 at 14:55
  • Great answer, I hope yours gets accepted over mine. =D – Daniel Wagner Aug 11 '15 at 17:10
  • It should also be noted that newtypes add no overhead. – PyRulez Aug 30 '15 at 18:09
9

Here is a somewhat frightening trick you could try. Everywhere you would have a rank-2 type variable, use an empty type instead; and everywhere you would pick an instantiation of the type variable, use unsafeCoerce. Using an empty type ensures (so much as it's possible) that you don't do anything that can observe what should be an unobservable value. Hence:

import Data.Void
import Unsafe.Coerce

type List a = (a -> Void -> Void) -> Void -> Void

toList :: [a] -> List a
toList xs = \cons nil -> foldr cons nil xs

sum_ :: Num a => List a -> a
sum_ xs = unsafeCoerce xs (+) 0

main :: IO ()
main = print (sum_ . toList $ [1,2,3])

You might like to write a slightly safer version of unsafeCoerce, like:

instantiate :: List a -> (a -> r -> r) -> r -> r
instantiate = unsafeCoerce

Then sum_ xs = instantiate xs (+) 0 works just fine as an alternative definition, and you don't run the risk of turning your List a into something TRULY arbitrary.

  • 2
    That again... I think I'll just lose the fear and start adopting unsafeCoerce on my vocabulary. You're creating a monster, sir. – MaiaVictor Aug 11 '15 at 2:15
  • 9
    Dunno. Not that. Sometimes the cure is worse than the disease. I don't really see the problem that needs to be solved here. – dfeuer Aug 11 '15 at 2:57
  • 2
    This isn't really constructive but I love dfeuer's reaction, no less than I expected heh – MaiaVictor Aug 11 '15 at 3:06
  • 4
    That's horrible. There are no guarantees about unsafeCoerce in general. Any use outside implementation specific modules should be punished in the harshest possible way. – augustss Aug 11 '15 at 4:40
  • 4
    After type checking, my ideal compiler would optimize f :: T -> Void as roughly \_ -> undefined, and g :: T -> () as \_ -> () when a termination checker succeeds (similarly for other single-value types, e.g. a:~:b). Since GHC is not (yet) that smart, I guess unsafeCoerce should work, for now. It looks quite dangerous, though. – chi Aug 11 '15 at 8:38
6

Generally equational reasoning only holds in the "underlying System F" that Haskell represents. In this case, as others have noted, you're getting tripped up because Haskell moves foralls leftward and automatically applies the proper types at various points. You can fix it by providing cues as to where type application should occur via newtype wrappers. As you've seen you can also manipulate when type application occurs by eta expansion since the Hindley-Milner typing rules are different for let and for lambda: foralls are introduced via the "generalization" rule, by default, at lets (and other, equivalent named bindings) alone.

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