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?