Here's a standard place where `Invariant`

shows up---higher order abstract syntax (HOAS) for embedding lambda calculus. In HOAS we like to write expression types like

```
data ExpF a
= App a a
| Lam (a -> a)
-- ((\x . x) (\x . x)) is sort of like
ex :: ExpF (ExpF a)
ex = App (Lam id) (Lam id)
-- we can use tricky types to make this repeat layering of `ExpF`s easier to work with
```

We'd love for this type to have structure like `Functor`

but sadly it cannot be since `Lam`

has `a`

s in both positive and negative position. So instead we define

```
instance Invariant ExpF where
invmap ab ba (App x y) = App (ab x) (ab y)
invmap ab ba (Lam aa) = Lam (ab . aa . ba)
```

This is really tragic because what we would really like to do is to fold this `ExpF`

type in on itself to form a recursive expression tree. If it were a `Functor`

that'd be obvious, but since it's not we get some very ugly, challenging constructions.

To resolve this, you add another type parameter and call it Parametric HOAS

```
data ExpF b a
= App a a
| Lam (b -> a)
deriving Functor
```

And we end up finding that we can build a free monad atop this type using its `Functor`

instance where binding is variable substitution. Very nice!

`Endo a`

from`Data.Monoid`

?`Endo`

should be invariant.`Contravariant`

.