I'm not going to say I recommend what follows, but for completeness *it actually is possible to define such a Functor*.

The `Functor`

typeclass demands that you can `fmap`

*any* function into your `Functor`

. This means, normally, that it's difficult to ensure invariants which demand typeclass instances. However, we can contort this situation quite a bit and actually end up getting away with a `Functor`

instance. In practice, what it means is that we can use the type system to ensure that we we defer our rebalancing to times that are more convenient.

First, we'll introduce a demand on the above type. In particular, we'll give it a `Monoid`

instance which maintains balance. This works out fine since `Monoid`

doesn't require our container be polymorphic.

```
instance Ord a => Monoid (BalancedTree a) where
mempty = Leaf
mappend Leaf Leaf = Leaf
mappend Leaf b = b
mappend b Leaf = b
mappend (Node a l1 r1) (Node b l2 r2) = ... -- merge and rebalance here
```

Now, using this instance we can write functions which correspond *almost* to a `Monad`

instance for `BinaryTree`

. In particular, we need it in order to combine our new trees as build using `bindBin`

, the *almost* version of `(>>=)`

on binary search trees.

```
returnBin :: a -> BinaryTree a
returnBin a = Node a Leaf Leaf
bindBin :: Ord b => BinaryTree a -> (a -> BinaryTree b) -> BinaryTree b
bindBin Leaf _ = Leaf
bindBin (Node a l r) f = bindBin l f <> f a <> bindBin r f
```

Then we introduce this very strange type (which requires the `RankNTypes`

extension)

```
newtype FBinaryTree a =
FBinaryTree (forall r . Ord r => (a -> BinaryTree r) -> BinaryTree r)
```

There are many ways of thinking about this, but we'll just note that there's an isomorphism between `FBinaryTree a`

and `BinaryTree a`

witnessed, basically, by `returnBin`

and `bindBin`

.

```
toF :: BinaryTree a -> FBinaryTree a
toF bt = FBinaryTree (bindBin bt)
fromF :: Ord a => FBinaryTree a -> BinaryTree a
fromF (FBinaryTree k) = k returnBin
```

and finally, as `FBinaryTree`

inherits some of the properties of the `Cont`

monad or the `Yoneda`

lemma type, we can define a `Functor`

instance for `FBinaryTree`

!

```
instance Functor FBinaryTree where
fmap f (FBinaryTree c) = FBinaryTree (\k -> c (k . f))
```

So that now, all we must do is convert our `BinaryTree`

s into `FBinaryTree`

s, perform our `Functor`

operations there, and then drop back down to `BinaryTree`

as needed. Smooth sailing, right?

Well, almost. It turns out that there's a huge efficiency price we pay for this. In particular, it's easy to have exponential blowups occur when using types like `FBinaryTree`

. We can avoid these by sending `FBinaryTree`

through `BinaryTree`

from time to time by using

```
optimize :: Ord a => FBinaryTree a -> FBinaryTree a
optimize = toF . fromF
```

which, as the type shows, requires us to have an `Ord`

instance right there. In fact, the code will use the `Ord`

instance there to perform the needed rebalancing.