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I have an infinite structure like the following (using the Stream type from the streams package):

data U x = U (Stream x) x (Stream x) deriving (Functor,Foldable)             

I want to provide an instance of Traversable for it, like this:

instance Traversable U where
    traverse f (U lstream focus rstream) = 
        let pairs =  liftA unzip 
                   . sequenceA . fmap (traversepair f) 
                   $ zip lstream rstream 
            traversepair f (a,b) = (,) <$> f a <*> f b
            rebuild c (u,v) = U u c v
        in rebuild <$> f focus <*> pairs

The documentation for Data.Traversable says that they represent the "class of data structures that can be traversed from left to right". But my definition does not traverse from left to right, it traverses outwardly. I had to define it that way to be able to lazily extract values on both sides after a sequence operation involving the Rand monad.

Is it a valid definition nonetheless? I have noticed that the Typeclassopedia entry for Traversable doesn't say anything about "left-to-right", it only talks about "commuting two functors".

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Infinite structures are not Traversable. There's no good dist :: Stream (Maybe x) -> Maybe (Stream x). I'd say that traversal defines a notion of left-to-right: if that doesn't correspond to the textual left-to-right in a program, I usually wonder why. But your example is interesting. It relies on a laziness that not all applicatives possess. Hmm. – pigworker Jan 1 '13 at 13:33
I would have been inclined to say there is no reason that an infinite structure cannot be traversable - but it does require a laziness that not all applicative functors. But so would an infinite list of course, which is traversable. Also, there are lots of options for the specific dist function for maybe across stream that you mention, although traversable instances usually don't satisfy it. For example, if the first item is Nothing, the result is nothing, otherwise the result is Just the stream filtered of nothings. – DarkOtter Jan 1 '13 at 13:37
Here is a gist with the full code: I need to use "sequence" to aggregate monadic effects inside a comonad. – danidiaz Jan 1 '13 at 14:05
I forked the gist, introduced @SjoerdVisscher's correction in the first revision, and played with it a bit more in the revisions after it. – Rhymoid Jan 1 '13 at 14:50
@pigworker: I've taken to a different way of thinking about traversals. We use infinite traversals all the time. The real culprit here is that Maybe is strict in both sides of (<*>), it isn't productive. The Maybe example fails because it needs an oracle for the halting problem, equality of streams is Pi_0^2 complete. But, you can reason perfectly well about infinite traversals if you stick to productive Applicatives and permit yourself only a finite number of reassociations to get to the next constructor. This is a pretty bad forum for this sort of discussion, though. ;) – Edward KMETT Jan 4 '13 at 1:08

1 Answer 1

up vote 10 down vote accepted

According to this thread the laws should be:

  1. traverse Identity == Identity
  2. traverse (Compose . fmap g . f) == Compose . fmap (traverse g) . traverse f

These 2 laws ensure that each element in the traversed structure is traversed exactly once. It does not matter in which order. You could even say that a Traversable instance defines what left-to-right means for that particular datatype.

There are two other requirements in the documentation:

  • In the Functor instance, fmap should be equivalent to traversal with the identity applicative functor (fmapDefault).
  • In the Foldable instance, foldMap should be equivalent to traversal with a constant applicative functor (foldMapDefault).

In your above code, you break the second requirement, because you're deriving Foldable, which will visit the elements in a different order than your Traversable instance. Creating your own instance for Foldable with foldMapDefault fixes that.

By the way, sequenceA . fmap (traversepair f) is traverse (traversepair f).

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I'd also introduce data Pair a = Pair a a here. It makes the code a bit more generic. – Rhymoid Jan 1 '13 at 14:02
I'd probably write is as traverse f (U lstream focus rstream) = (\c (unzip -> (u,v)) -> U u c v) <$> f focus <*> traverse (both f) (zip lstream rstream), using ViewPatterns, and both from the lens package. – Sjoerd Visscher Jan 1 '13 at 14:35
both seems nice. I ended up with traverse f (U p x q) = (\c (Pair u v) -> U u c v) <$> f x <*> (fmap getCompose . traverse f . Compose) (Pair p q), so Data.Functor.Compose takes care of it. – Rhymoid Jan 1 '13 at 14:43
fmap getCompose . traverse f . Compose is the same as traverse (traverse f), which does not do the zipping. You can use Compose, because the Applicative instance of Stream does the zipping, something like getCompose (traverse (Compose . traverse f) (Pair p q)), but you'd still need to unzip. – Sjoerd Visscher Jan 1 '13 at 15:07
I think I forgot to bracket it in sequenceA's, which would do the zipping and unzipping. – Rhymoid Jan 1 '13 at 15:18

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