I have defined an *F-Algebra*, as per Bartosz Milewski's articles (one, two):

*(This is not to say my code is an exact embodiment of Bartosz's ideas, it's merely my limited understanding of them, and any faults are mine alone.)*

```
module Algebra where
data Expr a = Branch [a] | Leaf Int
instance Functor Expr where
fmap f (Branch xs) = Branch (fmap f xs)
fmap _ (Leaf i ) = Leaf i
newtype Fix a = Fix { unFix :: a (Fix a) }
branch = Fix . Branch
leaf = Fix . Leaf
-- | This is an example algebra.
evalSum (Branch xs) = sum xs
evalSum (Leaf i ) = i
cata f = f . fmap (cata f) . unFix
```

I can now do pretty much anything I want about it, for example, sum the leaves:

```
λ cata evalSum $ branch [branch [leaf 1, leaf 2], leaf 3]
6
```

This is a contrived example that I made up specifically for this question, but I actually tried some less trivial things (such as evaluating and simplifying polynomials with any number of variables) and it works like a charm. One may indeed fold and replace any parts of a structure as one runs a *catamorphism* through, with a suitably chosen *algebra*. So, I am pretty sure an F-Algebra subsumes a Foldable, and it even appears to subsume Traversable as well.

**Now, can I define Foldable / Traversable instances in terms of an F-Algebra?**

It seems to me that I cannot.

- I can only run a catamorphism on an
*initial algebra*, which is a nullary type constructor. And the algebra I give it has a type`a b -> b`

rather than`a -> b`

, that is to say, there is a*functional dependency*between the "in" and "out" type. - I don't see an
`Algebra a => Foldable a`

anywhere in type signatures. If this is not done, it must be impossible.

It seems to me that I cannot define `Foldable`

in terms of an F-Algebra for the reason that an `Expr`

must for that be a `Functor`

in two variables: one for *carrier*, another for *values*, and then a `Foldable`

in the second. So, it may be that a *bifunctor* is more suitable. And we can construct an F-Algebra with a bifunctor as well:

```
module Algebra2 where
import Data.Bifunctor
data Expr a i = Branch [a] | Leaf i
instance Bifunctor Expr where
bimap f _ (Branch xs) = Branch (fmap f xs)
bimap _ g (Leaf i ) = Leaf (g i)
newtype Fix2 a i = Fix2 { unFix2 :: a (Fix2 a i) i }
branch = Fix2 . Branch
leaf = Fix2 . Leaf
evalSum (Branch xs) = sum xs
evalSum (Leaf i ) = i
cata2 f g = f . bimap (cata2 f g) g . unFix2
```

It runs like this:

```
λ cata2 evalSum (+1) $ branch [branch [leaf 1, leaf 2], leaf 3]
9
```

But I still can't define a Foldable. It would have type like this:

```
instance Foldable \i -> Expr (Fix2 Expr i) i where ...
```

Unfortunately, one doesn't get lambda abstractions on types, and there's no way to put an implied type variable in two places at once.

I don't know what to do.