Let's start by defining a data type that we will use as an example:

```
data Nat = S Nat | Z
```

This data type encodes the natural numbers in Peano style. This means that we have 0 and a way to produce the successor of any natural number.

We can construct new natural numbers from integers easily:

```
-- Allow us to construct Nats
mkNat :: Integer -> Nat
mkNat n | n < 0 = error "cannot construct negative natural number"
mkNat 0 = Z
mkNat n = S $ mkNat (n-1)
```

Now, we'll first define a catamorphism for this type, because a histomorphism is quite similar to it and a catamorphism is easier to understand.

A catamorphism allows to "fold" or "tear down" a structure. It only expects a function that knows how to fold the structure *when all recursive terms* have been folded already. Let's define such a type, similar to Nat, but with all recursive instances replaced by some value of type `a`

:

```
data NatF a = SF a | ZF -- Aside: this is just Maybe
```

Now, we can define the type of our catamorphism for Nat:

```
cata :: (NatF a -> a)
-> (Nat -> a)
```

Given a function that knows how to fold the non-recursive structure `NatF a`

to an `a`

, `cata`

turns that into a function to fold a whole `Nat`

.

The implementation of cata is quite simple: first fold the recursive subterm (if there is any) and the apply our function:

```
cata f Z = f ZF -- No subterm to fold, base case
cata f (S subterm) = f $ SF $ cata f subterm -- Fold subterm first, recursive case
```

We can use this catamorphism to convert `Nat`

s back to `Integer`

s, like this:

```
natToInteger :: Nat -> Integer
natToInteger = cata phi where
-- We only need to provide a function to fold
-- a non-recursive Nat-like structure
phi :: NatF Integer -> Integer
phi ZF = 0
phi (SF x) = x + 1
```

So with `cata`

, we get access to the value of the immediate subterm. But imagine we like to access the values of transitive subterms too, for example, when defining a fibonacci function. Then, we need not only access to the previous value, but also to the 2-nd previous value. This is where histomorphisms come into play.

A histomorphism (histo sounds a lot like "history") allows us to access *all* previous values, not just the most recent one. This means we now get a list of values, not just a single one, so the type of histomorphism is:

```
-- We could use the type NatF (NonEmptyList a) here.
-- But because NatF is Maybe, NatF (NonEmptyList a) is equal to [a].
-- Using just [a] is a lot simpler
histo :: ([a] -> a)
-> Nat -> a
histo f = head . go where
-- go :: Nat -> [a] -- This signature would need ScopedTVs
go Z = [f []]
go (S x) = let subvalues = go x in f subvalues : subvalues
```

Now, we can define `fibN`

as follows:

```
-- Example: calculate the n-th fibonacci number
fibN :: Nat -> Integer
fibN = histo $ \x -> case x of
(x:y:_) -> x + y
_ -> 1
```

Aside: even though it might appear so, histo is not more powerful than cata. You can see that yourself by implementing histo in terms of cata and the other way around.

What I didn't show in the above example is that `cata`

and `histo`

can be implemented very generally if you define your type as a fixpoint of a functor. Our `Nat`

type is just the fixed point of the Functor `NatF`

.

If you define `histo`

in the generic way, then you also need to come up with a type like the `NonEmptyList`

in our example, but for any functor. This type is precisely `Cofree f`

, where `f`

is the functor you took the fixed point of. You can see that it works for our example: `NonEmptyList`

is just `Cofree Maybe`

. This is how you get to the generic type of `histo`

:

```
histo :: Functor f
=> (f (Cofree f a) -> a)
-> Fix f -- ^ This is the fixed point of f
-> a
```

You can think of `f (Cofree f a)`

as kind of a stack, where with each "layer", you can see a less-folded structure. At the top of the stack, every immediate subterm is folded. Then, if you go one layer deeper, the immediate subterm is no longer folded, but the sub-subterms are all already folded (or evaluated, which might make more sense to say in the case of ASTs). So you can basically see "the sequence of reductions" that has been applied (= the history).

`histo :: (Mu a,Functor (PF a)) => Ann a -> (F a (Histo a c) -> c) -> a -> c`

`recursion-schemes`

has`histo`

and`dyna`

is just`histo`

that works on any coalgebra, not just final ones. The most trivial interesting example I can think of is a rather direct`tail`

built off a generalized`foldr :: (a -> b -> b -> b) -> (a -> b -> b) -> b -> [a] -> b`