# Once I have an F-Algebra, can I define Foldable and Traversable in terms of it?

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.

An F-algebra defines a recipe for evaluating a single level of a recursive data structure, after you have evaluated all the children. `Foldable` defines a way of evaluating a (not necessarily recursive) data structure, provided you know how to convert values stored in it to elements of a monoid.

To implement `foldMap` for a recursive data structure, you may start by defining an algebra, whose carrier is a monoid. You would define how to convert a leaf to a monoidal value. Then, assuming that all children of a node were evaluated to monoidal values, you'd define a way to combine them within a node. Once you've defined such an algebra, you can run a catamorphism to evaluate `foldMap` for the whole tree.

So the answer to your question is that to make a `Foldable` instance for a fixed-point data structure, you have to define an appropriate algebra whose carrier is a monoid.

Edit: Here's an implementation of Foldable:

``````data Expr e a = Branch [a] | Leaf e

newtype Ex e = Ex { unEx :: Fix (Expr e) }

evalM :: Monoid m => (e -> m) -> Algebra (Expr e) m
evalM _ (Branch xs) = mconcat xs
evalM f (Leaf   i ) = f i

instance Foldable (Ex) where
foldMap f = cata (evalM f) . unEx

tree :: Ex Int
tree = Ex \$ branch [branch [leaf 1, leaf 2], leaf 3]

x = foldMap Sum tree
``````

Implementing `Traversable` as a catamorphism is a little more involved because you want the result to be not just a summary--it must contain the complete reconstructed data structure. The carrier of the algebra must therefore be the type of the final result of `traverse`, which is `(f (Fix (Expr b)))`, where `f` is `Applicative`.

``````tAlg :: Applicative f => (e -> f b) -> Algebra (Expr e) (f (Fix (Expr b)))
``````

Here's this algebra:

``````tAlg g (Leaf e)    = leaf   <\$> g e
tAlg _ (Branch xs) = branch <\$> sequenceA xs
``````

And this is how you implement `traverse`:

``````instance Traversable Ex where
traverse g = fmap Ex . cata (tAlg g) . unEx
``````

The superclass of `Traversable` is a `Functor`, so you need to show that the fixed-point data structure is a functor. You can do it by implementing a simple algebra and running a catamorphism over it:

``````fAlg :: (a -> b) -> Algebra (Expr a) (Fix (Expr b))
fAlg g (Leaf e) = leaf (g e)
fAlg _ (Branch es) = branch es

instance Functor Ex where
fmap g = Ex . cata (fAlg g) . unEx
``````

(Michael Sloan helped me write this code.)

• Yes, but can I make it adhere to the type signature for `foldMap`? I believe my `evalSum` is the algebra you're talking about, but it kind of doesn't help. – Ignat Insarov Jan 29 '18 at 15:40
• I added code that implements foldMap. – Bartosz Milewski Jan 30 '18 at 13:45
• Oh. I didn't think of making an algebra parametric. – Ignat Insarov Jan 30 '18 at 13:53
• I also added the implementation of `Traversable`. – Bartosz Milewski Jan 30 '18 at 14:10

It's very nice, that you used `Bifunctor`. Using `Bifunctor` of a base functor (`Expr`) to define `Functor` on a fixpoint (`Fix Expr`). That approach generalises to `Bifoldable` and `Bitraversable` (they are in `base` now) too.

Let's see how this would like using `recursion-schemes`. It looks a bit different, as there we define normal recursive type, say `Tree e`, and also its base functor: `Base (Tree e) = TreeF e a` with two functions: `project :: Tree e -> TreeF e (Tree e)` and `embed :: TreeF e (Tree e) -> Tree e`. The recursion machinery is derivable using TemplateHaskell:

Note that we have `Base (Fix f) = f` (`project = unFix`, `embed = Fix`), therefore we can use `refix` convert `Tree e` to `Fix (TreeF e)` and back. But we don't need to use `Fix`, as we able to `cata` `Tree` directly!

First includes:

``````{-# LANGUAGE TemplateHaskell, KindSignatures, TypeFamilies, DeriveFunctor, DeriveFoldable, DeriveTraversable #-}
import Data.Functor.Foldable
import Data.Functor.Foldable.TH

import Data.Bifunctor
import Data.Bifoldable
import Data.Bitraversable
``````

Then the data:

``````data Tree e = Branch [Tree e] | Leaf e deriving Show

-- data TreeF e r = BranchF [r] | LeafF e
-- instance Traversable (TreeF e)
-- instance Foldable (TreeF e)
-- instance Functor (TreeF e)
makeBaseFunctor ''Tree
``````

Now as we have machinery in place, we can have catamorphisms

``````cata :: Recursive t => (Base t a -> a) -> t -> a
cata f = c where c = f . fmap c . project
``````

or (which we will need later)

``````cataBi :: (Recursive t, Bifunctor p, Base t ~ p x) => (p x a -> a) -> t -> a
cataBi f = c where c = f . second c . project
``````

First a `Functor` instance. The `Bifunctor` instance for `TreeF` is as OP has written, note how `Functor` falls out by itself.

``````instance Bifunctor TreeF where
bimap f _ (LeafF e)    = LeafF (f e)
bimap _ g (BranchF xs) = BranchF (fmap g xs)

instance Functor Tree where
fmap f = cata (embed . bimap f id)
``````

Not surprisingly, `Foldable` for fixpoint can be defined in terms of `Bifoldable` of base functor:

``````instance Bifoldable TreeF where
bifoldMap f _ (LeafF e)    = f e
bifoldMap _ g (BranchF xs) = foldMap g xs

instance Foldable Tree where
foldMap f = cata (bifoldMap f id)
``````

And finally `Traversable`:

``````instance Bitraversable TreeF where
bitraverse f _ (LeafF e)    = LeafF <\$> f e
bitraverse _ g (BranchF xs) = BranchF <\$> traverse g xs

instance Traversable Tree where
traverse f = cata (fmap embed . bitraverse f id)
``````

As you can see the definitions are very straight forward and follow similarish pattern.

Indeed we can define `traverse`-like function for every fix-point which base functor is `Bitraversable`.

``````traverseRec
:: ( Recursive t, Corecursive s, Applicative f
, Base t ~ base a, Base s ~ base b, Bitraversable base)
=> (a -> f b) -> t -> f s
traverseRec f = cataBi (fmap embed . bitraverse f id)
``````

Here we use `cataBi` to make type-signature prettier: no `Functor (base b)` as it's "implied" by `Bitraversable base`. Btw, that's a one nice function as its type signature is three times longer than the implementation).

To conclude, I must mention that `Fix` in Haskell is not perfect: We use the last argument to fix base-functor:

``````Fix :: (* -> *) -> * -- example: Tree e ~ Fix (TreeF e)
``````

Thus Bartosz needs to define `Ex` in his answer to make kinds align, however it would be nicer to fix on the first argument:

``````Fix :: (* -> k) -> k -- example: Tree e = Fix TreeF' e
``````

where `data TreeF' a e = LeafF' e | BranchF' [a]`, i.e. `TreeF` with indexes flipped. That way we could have `Functor (Fix b)` in terms of `Bifunctor f`, `Bifunctor (Fix b)` in terms of (non-existing in common libraries) `Trifunctor` etc.