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A common idiom in Haskell, difference lists, is to represent a list xs as the value (xs ++). Then (.) becomes "(++)" and id becomes "[]" (in fact this works for any monoid or category). Since we can compose functions in constant time, this gives us a nice way to efficiently build up lists by appending.

Unfortunately the type [a] -> [a] is way bigger than the type of functions of the form (xs ++) -- most functions on lists do something other than prepend to their argument.

One approach around this (as used in dlist) is to make a special DList type with a smart constructor. Another approach (as used in ShowS) is to not enforce the constraint anywhere and hope for the best. But is there a nice way of keeping all the desired properties of difference lists while using a type that's exactly the right size?

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up vote 23 down vote accepted


We can view [a] as a free monad instance Free ((,) a) ().

Thus we can apply the scheme described by Edward Kmett in Free Monads for Less.

The type we'll get is

newtype F a = F { runF :: forall r. (() -> r) -> ((a, r) -> r) -> r }

or simply

newtype F a = F { runF :: forall r. r -> (a -> r -> r) -> r }

So runF is nothing else than the foldr function for our list!

This is called the Boehm-Berarducci encoding and it's isomorphic to the original data type (list) — so this is as small as you can possibly get.

Will Ness says:

So this type is still too "wide", it allows more than just prefixing - doesn't constrain the g function argument.

If I understood his argument correctly, he points out that you can apply the foldr (or runF) function to something different from [] and (:).

But I never claimed that you can use foldr-encoding only for concatenation. Indeed, as this name implies, you can use it to calculate any fold — and that's what Will Ness demonstrated.

It may become more clear if you forget for a moment that there's one true list type, [a]. There may be lots of list types — e.g. I can define one by

data List a = Nil | Cons a (List a)

It's be different from, but isomorphic to [a].

The foldr-encoding above is just yet another encoding of lists, like List a or [a]. It is also isomorphic to [a], as evidenced by functions \l -> F (\a f -> foldr a f l) and \x -> runF [] (:) and the fact that their compositions (in either order) is identity. But you are not obliged to convert to [a] — you can convert to List directly, using \x -> runF x Nil Cons.

The important point is that F a doesn't contain an element that is not the foldr functions for some list — nor does it contain an element that is the foldr functions for more than one list (obviously).

Thus, it doesn't contain too few or too many elements — it contains precisely as many elements as needed to exactly represent all lists.

This is not true of the difference list encoding — for example, the reverse function is not an append operation for any list.

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There is a pleasantly readable discussion of this type (more in the form Folding a = F {runF :: forall r. (Maybe (a,r) -> r) -> r} -- and some similar types, from the point of view of competing fusion rules -- short cut fusion, stream fusion -- in Roman Leshchinskiy's Squinting at fusion – applicative Nov 12 '12 at 22:25
How is this a "Yes!"? With empty = F (\r g->r) and singleton x = F (\r g-> g x r) I can still call runF (singleton 2) [1] (\a r->[a]) ==> [2] and runF (singleton 4) [3,2,1] (\a r->a:reverse r) ==> [4,1,2,3]. So this type is still too "wide", it allows more than just prefixing - doesn't constrain the g function argument. Where am I mistaken? – Will Ness Nov 13 '12 at 11:10
that's what I meant: hpaste.org/77651 ... – Will Ness Nov 13 '12 at 12:00
@WillNess: I updated my answer, hopefully that answers your question now. – Roman Cheplyaka Nov 13 '12 at 17:42
I understand that F a represents [a]; I thought the question was about representing ([a] ++). With F (hpaste.org/77691) I can say runF (fromList [1..3]) [11..14] (const reverse) as well as runF (fromList [1..3]) [11..14] (:). I need to enforce myself to use the latter, in order to represent the prefixing. Of course the former can be seen as another "kind" of "prefixing", so maybe that's all just semantics. – Will Ness Nov 14 '12 at 7:03

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