Proving equality of streams

I have a data type

``````data N a = N a [N a]
``````

of rose trees and Applicative instance

``````instance Applicative N where
pure a = N a (repeat (pure a))
(N f xs) <*> (N a ys) = N (f a) (zipWith (<*>) xs ys)
``````

and need to prove the Applicative laws for it. However, pure creates infinitely deep, infinitely branching trees. So, for instance, in proving the homomorphism law

``````pure f <*> pure a = pure (f a)
``````

I thought that proving the equality

``````zipWith (<*>) (repeat (pure f)) (repeat (pure a)) = repeat (pure (f a))
``````

by the approximation (or take) lemma would work. However, my attempts lead to "vicious circles" in the inductive step. In particular, reducing

``````approx (n + 1) (zipWith (<*>) (repeat (pure f)) (repeat (pure a))
``````

gives

``````(pure f <*> pure a) : approx n (repeat (pure (f a)))
``````

where approx is the approximation function. How can I prove the equality without an explicit coinductive proof?

-
Why would you want to prove it without using coinduction? Just as induction is the natural proof method for data like finite lists/trees, coinduction is the natural proof method for codata, like streams or your "infinitely deep, infinitely branching trees". – Alexey Romanov Mar 3 '11 at 11:56
In particular, because the proof operates at the level of "program syntax." A proof of bisimilarity does not. – danportin Mar 3 '11 at 12:03
this looks like a good candidate for the cstheory stackexchange site, especially if you stated it in slightly more general/formal terms. – sclv Mar 3 '11 at 18:15

The following is a sketch of something that I think works and remains at the level of programmatic syntax and equational reasoning.

The basic intuition is that it is much easier to reason about `repeat x` than it is to reason about a stream (and worse yet, a list) in general.

``````uncons (repeat x) = (x, repeat x)

zipWithAp xss yss =
let (x,xs) = uncons xss
(y,ys) = uncons yss
in (x <*> y) : zipWithAp xs ys

-- provide arguments to zipWithAp
zipWithAp (repeat x) (repeat y) =
let (x',xs) = uncons (repeat x)
(y',ys) = uncons (repeat y)
in (x' <*> y') : zipWithAp xs ys

-- substitute definition of uncons...
zipWithAp (repeat x) (repeat y) =
let (x,repeat x) = uncons (repeat x)
(y,repeat y) = uncons (repeat y)
in (x <*> y) : zipWithAp (repeat x) (repeat y)

-- remove now extraneous let clause
zipWithAp (repeat x) (repeat y) = (x <*> y) : zipWithAp (repeat x) (repeat y)

-- unfold identity by one step
zipWithAp (repeat x) (repeat y) = (x <*> y) : (x <*> y) : zipWithAp (repeat x) (repeat y)

-- (co-)inductive step
zipWithAp (repeat x) (repeat y) = repeat (x <*> y)
``````
-

I'd use the universal property of unfolds (since repeat and a suitably uncurried zipWith are both unfolds). There's a related discussion on my blog. But you might also like Ralf Hinze's papers on unique fixpoints ICFP2008 (and the subsequent JFP paper).

(Just checking: all your rose trees are infinitely wide and infinitely deep? I'm guessing that the laws won't hold otherwise.)

-

Why do yo need coinduction? Just induct.

``````pure f <*> pure a = pure (f a)
``````

can also be written (you need to prove the left and right equality)

``````N f [(pure f)] <*> N a [(pure a)] = N (f a) [(pure (f a))]
``````

which allows you to off one term at a time. That gives you your induction.

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I think you're missing the point. You actually get `N f (repeat \$ pure f) <*> N a (repeat \$ pure a) = N (f a) (zipWith (<*>) (repeat \$ pure f) (repeat \$ pure a))` which leads directly to the equality danportin wants to prove in the first place... – sclv Mar 10 '11 at 20:28