# A Fold for Every Occasion

We can actually come up with a generic notion of folding which can apply to a whole bunch of different types. That is, we can systematically define a `fold`

function for lists, trees and more.

This generic notion of `fold`

corresponds to the catamorphisms @pelotom mentioned in his comment.

## Recursive Types

The key insight is that these `fold`

functions are defined over *recursive* types. In particular:

```
data List a = Cons a (List a) | Nil
data Tree a = Branch (Tree a) (Tree a) | Leaf a
```

Both of these types are clearly recursive--`List`

in the `Cons`

case and `Tree`

in the `Branch`

case.

### Fixed Points

Just like functions, we can rewrite these types using fixed points. Remember the definition of `fix`

:

```
fix f = f (fix f)
```

We can actually write something very similar for types, except that it has to have an extra constructor wrapper:

```
newtype Fix f = Roll (f (Fix f))
```

Just like `fix`

defines the fixed point of a *function*, this defines the fixed point of a *functor*. We can express all our recursive types using this new `Fix`

type.

This allows us to rewrite `List`

types as follows:

```
data ListContainer a rest = Cons a rest | Nil
type List a = Fix (ListContainer a)
```

Essentially, `Fix`

allows us to nest `ListContainer`

s to arbitrary depths. So we could have:

```
Roll Nil
Roll (Cons 1 (Roll Nil))
Roll (Cons 1 (Roll (Cons 2 (Roll Nil))))
```

which correspond to `[]`

, `[1]`

and `[1,2]`

respectively.

Seeing that `ListContainer`

is a `Functor`

is easy:

```
instance Functor (ListContainer a) where
fmap f (Cons a rest) = Cons a (f rest)
fmap f Nil = Nil
```

I think the mapping from `ListContainer`

to `List`

is pretty natural: instead of recursing explicitly, we make the recursive part a variable. Then we just use `Fix`

to fill that variable in as appropriate.

We can write an analogous type for `Tree`

as well.

### "Unwrapping" Fixed Points

So why do we care? We can define `fold`

for *arbitrary* types written using `Fix`

. In particular:

```
fold :: Functor f => (f a -> a) -> (Fix f -> a)
fold h = h . fmap (fold h) . unRoll
where unRoll (Roll a) = a
```

Essentially, all a fold does is unwrap the "rolled" type one layer at a time, applying a function to the result each time. This "unrolling" lets us define a fold for any recursive type and neatly and naturally generalize the concept.

For the list example, it works like this:

- At each step, we unwrap the
`Roll`

to get either a `Cons`

or a `Nil`

- We recurse over the rest of the list using
`fmap`

.
- In the
`Nil`

case, `fmap (fold h) Nil = Nil`

, so we just return `Nil`

.
- In the
`Cons`

case, the `fmap`

just continues the fold over the rest of the list.

- In the end, we get a bunch of nested calls to
`fold`

ending in a `Nil`

--just like the standard `foldr`

.

### Comparing Types

Now lets look at the types of the two fold functions. First, `foldr`

:

```
foldr :: (a -> b -> b) -> b -> [a] -> b
```

Now, `fold`

specialized to `ListContainer`

:

```
fold :: (ListContainer a b -> b) -> (Fix (ListContainer a) -> b)
```

At first, these look completely different. However, with a bit of massaging, we can show they're the same. The first two arguments to `foldr`

are `a -> b -> b`

and `b`

. We have a function and a constant. We can think of `b`

as `() -> b`

. Now we have two functions `_ -> b`

where `_`

is `()`

and `a -> b`

. To make life simpler, let's curry the second function giving us `(a, b) -> b`

. Now we can write them as a *single* function using `Either`

:

```
Either (a, b) () -> b
```

This is true because given `f :: a -> c`

and `g :: b -> c`

, we can always write the following:

```
h :: Either a b -> c
h (Left a) = f a
h (Right b) = g b
```

So now we can view `foldr`

as:

```
foldr :: (Either (a, b) () -> b) -> ([a] -> b)
```

(We are always free to add parentheses around `->`

like this as long as they're right-associative.)

Now lets look at `ListContainer`

. This type has two cases: `Nil`

, which carries no information and `Cons`

, which has both an `a`

and a `b`

. Put another way, `Nil`

is like `()`

and `Cons`

is like `(a, b)`

, so we can write:

```
type ListContainer a rest = Either (a, rest) ()
```

Clearly this is the same as what I used in `foldr`

above. So now we have:

```
foldr :: (Either (a, b) () -> b) -> ([a] -> b)
fold :: (Either (a, b) () -> b) -> (List a -> b)
```

So, in fact, the types are isomorphic--just different ways of writing the same thing! I think that's pretty cool.

(As a side note, if you want to know more about this sort of reasoning with types, check out The Algebra of Algebraic Data Types, a nice series of blog posts about just this.)

### Back to Trees

So, we've seen how we can define a generic `fold`

for types written as fixed points. We've also seen how this corresponds directly to `foldr`

for lists. Now lets look at your second example, the binary tree. We have the type:

```
data Tree a = Branch a (Tree a) (Tree a) | Leaf a
```

we can rewrite this using `Fix`

by following the rules I did above: we replace the recursive part with a type variable:

```
data TreeContainer a rest = Branch rest rest | Leaf a
type Tree a = Fix (TreeContainer a)
```

Now we have a tree `fold`

:

```
fold :: (TreeContainer a b -> b) -> (Tree a -> b)
```

Your original `foldTree`

looks like this:

```
foldTree :: (b -> b -> b) -> (a -> b) -> Tree a -> b
```

`foldTree`

accepts two functions; we'll combine the into one by first currying and then using `Either`

:

```
foldTree :: (Either (b, b) a -> b) -> (Tree a -> b)
```

We can also see how `Either (b, b) a`

is isomorphic to `TreeContainer a b`

. Tree container has two cases: `Branch`

, containing two `b`

s and `Leaf`

, containing one `a`

.

So these fold types are isomorphic in the same way as the list example.

### Generalizing

There is a clear pattern emerging. Given a normal recursive data type, we can systematically create a non-recursive version of the type, which lets us express the type as a fixed point of a functor. This means that we can mechanically come up with `fold`

functions for all these different types--in fact, we could probably automate the entire process using GHC Generics or something like that.

In a sense, this means that we do not really have different `fold`

functions for different types. Rather, we have a single `fold`

function which is *very* polymorphic.

## More

I first fully understood these ideas from a talk given by Conal Elliot. This goes into more detail and also talks about `unfold`

, which is the dual to `fold`

.

If you want to delve into this sort of thing even *more* deeply, read the fantastic "Functional Programming with Bananas, Lenses, Envelopes and Barbed Wire" paper. Among other things, this introduces the notions of "catamorphisms" and "anamorphisms" which correspond to folds and unfolds.

### Algebras (and Coalgebras)

Also, I can't resist adding a plug for myself :P. You can see some interesting similarities between the way we use `Either`

here and the way I used it when talking about algebras in another SO answer.

There is in fact a deep connection between `fold`

and algebras; moreover, `unfold`

--the aforementioned dual of `fold`

--is connected to coalgebras, which are the dual of algebras. The important idea is that algebraic data types correspond to "initial algebras" which also define folds as outlined in the rest of my answer.

You can see this connection in the general type of `fold`

:

```
fold :: Functor f => (f a -> a) -> (Fix f -> a)
```

The `f a -> a`

term looks very familiar! Remember that an f-algebra was defined as something like:

```
class Functor f => Algebra f a where
op :: f a -> a
```

So we can think of `fold`

as just:

```
fold :: Algebra f a => Fix f -> a
```

Essentially, `fold`

just lets us "summarize" structures defined using the algebra.

Functional Programming with Overloading and Higher-Order Polymorphism, by Mark P. Jones. – MJD May 8 '13 at 4:16`foldl`

and`foldr`

give different results. There's just more orders implied by the structure for trees. – Steve314 May 8 '13 at 14:23