I may be able to help, although such beast are inevitably a bit involved. Here's a pattern I sometimes use in developing well-scoped syntax with binding and de Bruijn indexing, bottled.

```
mkRenSub ::
forall v t x y. -- variables represented by v, terms by t
(forall x. v x -> t x) -> -- how to embed variables into terms
(forall x. v x -> v (Maybe x)) -> -- how to shift variables
(forall i x y. -- for thingies, i, how to traverse terms...
(forall z. v z -> i z) -> -- how to make a thingy from a variable
(forall z. i z -> t z) -> -- how to make a term from a thingy
(forall z. i z -> i (Maybe z)) -> -- how to weaken a thingy
(v x -> i y) -> -- ...turning variables into thingies
t x -> t y) -> -- wherever they appear
((v x -> v y) -> t x -> t y, (v x -> t y) -> t x -> t y)
-- acquire renaming and substitution
mkRenSub var weak mangle = (ren, sub) where
ren = mangle id var weak -- take thingies to be vars to get renaming
sub = mangle var id (ren weak) -- take thingies to be terms to get substitution
```

Normally, I'd use type classes to hide the worst of the gore, but if you unpack the dictionaries, this is what you'll find.

The point is that `mangle`

is a rank-2 operation which takes a notion of thingy equipped with suitable operations polymorphic in the variable sets over which they work: operations which map variables to thingies get turned into term-transformers. The whole thing shows how to use `mangle`

to generate both renaming and substitution.

Here's a concrete instance of that pattern:

```
data Id x = Id x
data Tm x
= Var (Id x)
| App (Tm x) (Tm x)
| Lam (Tm (Maybe x))
tmMangle :: forall i x y.
(forall z. Id z -> i z) ->
(forall z. i z -> Tm z) ->
(forall z. i z -> i (Maybe z)) ->
(Id x -> i y) -> Tm x -> Tm y
tmMangle v t w f (Var i) = t (f i)
tmMangle v t w f (App m n) = App (tmMangle v t w f m) (tmMangle v t w f n)
tmMangle v t w f (Lam m) = Lam (tmMangle v t w g m) where
g (Id Nothing) = v (Id Nothing)
g (Id (Just x)) = w (f (Id x))
subst :: (Id x -> Tm y) -> Tm x -> Tm y
subst = snd (mkRenSub Var (\ (Id x) -> Id (Just x)) tmMangle)
```

We implement the term traversal just once, but in a very general way, then we get substitution by deploying the mkRenSub pattern (which uses the general traversal in two different ways).

For another example, consider polymorphic operations between type operators

```
type (f :-> g) = forall x. f x -> g x
```

An `IMonad`

(indexed monad) is some `m :: (* -> *) -> * -> *`

equipped with polymorphic operators

```
ireturn :: forall p. p :-> m p
iextend :: forall p q. (p :-> m q) -> m p :-> m q
```

so those operations are rank 2.

Now any operation which is parametrized by an arbitrary indexed monad is rank 3. So, for example, constructing the usual monadic composition,

```
compose :: forall m p q r. IMonad m => (q :-> m r) -> (p :-> m q) -> p :-> m r
compose qr pq = iextend qr . pq
```

relies on rank 3 quantification, once you unpack the definition of `IMonad`

.

Moral of story: once you're doing higher order programming over polymorphic/indexed notions, your dictionaries of useful kit become rank 2, and your generic programs become rank 3. This is, of course, an escalation that can happen again.