I really like the idea of working with catamorphisms/anamorphisms in a generic way, but it seems to me it has a significant performance drawback:

Suppose we want to work with a tree structure in the categorical way - to describe different folding using a generic catamorphism function:

```
newtype Fix f = Fix { unfix :: f (Fix f) }
data TreeT r = Leaf | Tree r r
instance Functor TreeT where
fmap f Leaf = Leaf
fmap f (Tree l r) = Tree (f l) (f r)
type Tree = Fix TreeT
catam :: (Functor f) => (f a -> a) -> (Fix f -> a)
catam f = f . fmap (catam f) . unfix
```

Now we can write functions like:

```
depth1 :: Tree -> Int
depth1 = catam g
where
g Leaf = 0
g (Tree l r) = max l r
```

Unfortunately, this approach has a significant drawback: During the computation, new instances of `TreeT Int`

are created at every level in `fmap`

just to be immediately consumed by `g`

. Compared to the classical definition

```
depth2 :: Tree -> Int
depth2 (Fix Leaf) = 0
depth2 (Fix (Tree l r)) = max (depth1 l) (depth1 r)
```

our `depth1`

will be always slower making unnecessary strain on the GC. One solution would be to use hylomorphisms and combine creation and folding trees together. But often we don't want to do that, we may want a tree to be created on one place and then passed somewhere else to be folded later. Or, to be folder several times with different catamorphisms.

Is there a way to make GHC optimize `depth1`

? Something like inlining `catam g`

and then fusing/deforesting `g . fmap ...`

inside?