1

In Haskell, I recently found the following function useful:

listCase :: (a -> [a] -> b) -> [a] -> [b]
listCase f [] = []
listCase f (x:xs) = f x xs : listCase f xs

I used it to generate sliding windows of size 3 from a list, like this:

*Main> listCase (\_ -> take 3) [1..5]
[[2,3,4],[3,4,5],[4,5],[5],[]]

Is there a more general recursion scheme which captures this pattern? More specifically, that allows you to generate a some structure of results by repeatedly breaking data into a "head" and "tail"?

  • 1
    Theoretically, foldr is the most general list eliminator, but one hardly wants to use it in all cases. In your example, I'd write map foo (tails list) and do the splitting by hand, or even [ f x xs | (x:xs) <- tails list ] which handles the empty tail case more gracefully. – chi Jun 18 '15 at 8:42
3

This looks like a special case of a (jargon here but it can help with googling) paramorphism, a generalisation of primitive recursion to all initial algebras.

Reimplementing ListCase

Let's have a look at how to reimplement your function using such a combinator. First we define the notion of paramorphism: a recursion principle where not only the result of the recursive call is available but also the entire substructure this call was performed on:

The type of paraList tells me that in the (:) case, I will have access to the head, the tail and the value of the recursive call on the tail and that I need to provide a value for the base case.

module ListCase where

paraList :: (a -> [a] -> b -> b) -- cons
            -> b                 -- nil
            -> [a] -> b          -- resulting function on lists
paraList c n []       = n
paraList c n (x : xs) = c x xs $ paraList c n xs

We can now give an alternative definition of listCase:

listCase' :: (a -> [a] -> b) -> [a] -> [b]
listCase' c = paraList (\ x xs tl -> c x xs : tl) []

Considering the general case

In the general case, we are interested in building a definition of paramorphism for all data structures defined as the fixpoint of a (strictly positive) functor. We use the traditional fixpoint operator:

newtype Fix f = Fix { unFix :: f (Fix f) }

This builds an inductive structure layer by layer. The layers have an f shape which maybe better grasped by recalling the definition of List using this formalism. A layer is either Nothing (we're done!) or Just (head, tail):

newtype ListF a as = ListF { unListF :: Maybe (a, as) }
type List a = Fix (ListF a)

nil :: List a
nil = Fix $ ListF $ Nothing

cons :: a -> List a -> List a
cons = curry $ Fix . ListF .Just

Now that we have this general framework, we can define para generically for all Fix f where f is a functor:

para :: Functor f => (f (Fix f, b) -> b) -> Fix f -> b
para alg = alg . fmap (\ rec -> (rec, para alg rec)) . unFix

Of course, ListF a is a functor. Meaning we could use para to reimplement paraList and listCase.

instance Functor (ListF a) where fmap f = ListF . fmap (fmap f) . unListF

paraList' :: (a -> List a -> b -> b) -> b -> List a -> b
paraList' c n = para $ maybe n (\ (a, (as, b)) -> c a as b) . unListF

listCase'' :: (a -> List a -> b) -> List a -> List b
listCase'' c = paraList' (\ x xs tl -> cons (c x xs) tl) nil

You can implement a simple bijection toList, fromList to test it if you want. I could not be bothered to reimplement take so it's pretty ugly:

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

fromList :: List a -> [a]
fromList = paraList' (\ x _ tl -> x : tl) []

*ListCase> fmap fromList . fromList . listCase'' (\ _ as -> toList $ take 3 $ fromList as). toList $ [1..5]
[[2,3,4],[3,4,5],[4,5],[5],[]]
6

What you are asking for is a comonad. This may sound scarier than monad, but is a simpler concept (YMMV).

Comonads are Functors with additional structure:

class Functor w => Comonad w where
    extract :: w a -> a
    duplicate :: w a -> w (w a)
    extend :: (w a -> b) -> w a -> w b

(extendand duplicate can be defined in terms of each other) and laws similar to the monad laws:

duplicate . extract = id
duplicate . fmap extract = id
duplicate . duplicate = fmap duplicate . duplicate

Specifically, the signature (a -> [a] -> b) takes non-empty Lists of type a. The usual type [a] is not an instance of a comonad, but the non-empty lists are:

data NE a = T a | a :. NE a deriving Functor

instance Comonad NE where
   extract (T x) = x
   extract (x :. _) = x
   duplicate z@(T _) = T z
   duplicate z@(_ :. xs) = z :. duplicate xs

The comonad laws allow only this instance for non-empty lists (actually a second one).

Your function then becomes

extend (take 3 . drop 1 . toList)

Where toList :: NE a -> [a] is obvious. This is worse than the original, but extend can be written as =>> which is simpler if applied repeatedly.

For further information, you may start at What is the Comonad typeclass in Haskell?.

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