(Disclaimer: This is outside my area of expertise. I believe I'm correct (with caveats provided at different points), but ... Verify it yourself.)

A catamorphism can be thought of as a function that replaces constructors of a data type with other functions.

(In this example, I will be using the following data types:

```
data [a] = [] | a : [a]
data BinTree a = Leaf a | Branch (BinTree a) (BinTree a)
data Nat = Zero | Succ Nat
```

)

For example:

```
length :: [a] -> Nat
length = catamorphism
[] -> 0
(_:) -> (1+)
```

(Sadly, the `catamorphism {..}`

syntax is not available in Haskell (I saw something similar in Pola). I've been meaning to write a quasiquoter for it.)

So, what is `length [1,2,3]`

?

```
length [1,2,3]
length (1 : 2 : 3 : [])
length (1: 2: 3: [])
1+ (1+ (1+ (0 )))
3
```

That said, for reasons that will become apparent later, it is nicer to define it as the trivially equivalent:

```
length :: [a] -> Nat
length = catamorphism
[] -> Zero
(_:) -> Succ
```

Let's consider a few more example catamorphisms:

```
map :: (a -> b) -> [a] -> b
map f = catamorphism
[] -> []
(a:) -> (f a :)
binTreeDepth :: Tree a -> Nat
binTreeDepth = catamorphism
Leaf _ -> 0
Branch -> \a b -> 1 + max a b
binTreeRightDepth :: Tree a -> Nat
binTreeRightDepth = catamorphism
Leaf _ -> 0
Branch -> \a b -> 1 + b
binTreeLeaves :: Tree a -> Nat
binTreeLeaves = catamorphism
Leaf _ -> 1
Branch -> (+)
double :: Nat -> Nat
double = catamorphism
Succ -> Succ . Succ
Zero -> Zero
```

Many of these can be nicely composed to form new catamorphisms. For example:

```
double . length . map f = catamorphism
[] -> Zero
(a:) -> Succ . Succ
double . binTreeRightDepth = catamorphism
Leaf a -> Zero
Branch -> \a b -> Succ (Succ b)
```

`double . binTreeDepth`

also works, but it is almost a miracle, in a certain sense.

```
double . binTreeDepth = catamorphism
Leaf a -> Zero
Branch -> \a b -> Succ (Succ (max a b))
```

This only works because `double`

distributes over `max`

... Which is pure coincidence. (The same is true with `double . binTreeLeaves`

.) If we replaced `max`

with something that didn't play as nicely with doubling... Well, let's define ourselves a new friend (that doesn't get along as well with the others). For a binary operators that `double`

doesn't distribute over, we'll use `(*)`

.

```
binTreeProdSize :: Tree a -> Nat
binTreeProdSize = catamorphism
Leaf _ -> 0
Branch -> \a b -> 1 + a*b
```

Let's try to establish sufficient conditions for two catamorphisms two compose. Clearly, any catamorphism will quite happily be composed with `length`

, `double`

and `map f`

because they yield their data structure without looking at the child results. For example, in the case of `length`

, you can just replace `Succ`

and `Zero`

with what ever you want and you have your new catamorphism.

**If the first catamorphism yields a data structure without looking at what happens to its children, two catamorphisms will compose into a catamorphism.**

Beyond this, things become more complicated. Let's differentiate between normal constructor arguments and "recursive arguments" (which we will mark with a % sign). So `Leaf a`

has no recursive arguments, but `Branch %a %b`

does. Let's use the term "recursive-fixity" of a constructor to refer to the number of recursive arguments it has. (I've made up both these terms! I have no idea what proper terminology is, if there is one! Be wary of using them elsewhere!)

If the first catamorphism maps something into a zero recursive fixity constructor, everything is good!

```
a | b | cata(b.a)
===============================|=========================|================
F a %b %c .. -> Z | Z -> G a b .. | True
```

If we map children directly into a new constructor, we're also good.

```
a | b | cata(b.a)
===============================|=========================|=================
F a %b %c .. -> H %c %d .. | H %a %b -> G a b .. | True
```

If we map into a recursive fixity one constructor...

```
a | b | cata(b.a)
===============================|=========================|=================
F a %b %c .. -> A (f %b %c..) | A %a -> B (g %a) | Implied by g
| | distributes over f
```

But it isn't iff. For example, if there exist `g1`

`g2`

such that `g (f a b..) = f (g1 a) (g2 b) ..`

, that also works.

From here, the rules will just get messier, I expect.