# Is it possible to use church encodings without breaking equational reasoning?

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??

• 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
• 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
• @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
• It is okay, I don't know too. – MaiaVictor Aug 11 '15 at 1:02
• 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

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])
``````
• 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

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.

• 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
• 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
• This isn't really constructive but I love dfeuer's reaction, no less than I expected heh – MaiaVictor Aug 11 '15 at 3:06
• 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
• 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

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 `forall`s 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: `forall`s are introduced via the "generalization" rule, by default, at `let`s (and other, equivalent named bindings) alone.