There is no need to make a full copy of a `Set`

in order to insert an element into it. Internally, element are stored in a tree, which means that you only need to create new nodes along the path of the insertion. Untouched nodes can be shared between the pre-insertion and post-insertion version of the `Set`

. And as Deitrich Epp pointed out, in a balanced tree `O(log(n))`

is the length of the path of the insertion. (Sorry for omitting that important fact.)

Say your `Tree`

type looks like this:

```
data Tree a = Node a (Tree a) (Tree a)
| Leaf
```

... and say you have a `Tree`

that looks like this

```
let t = Node 10 tl (Node 15 Leaf tr')
```

... where `tl`

and `tr'`

are some named subtrees. Now say you want to insert `12`

into this tree. Well, that's going to look something like this:

```
let t' = Node 10 tl (Node 15 (Node 12 Leaf Leaf) tr')
```

The subtrees `tl`

and `tr'`

are shared between `t`

and `t'`

, and you only had to construct 3 new `Nodes`

to do it, even though the size of `t`

could be much larger than 3.

**EDIT: Rebalancing**

With respect to rebalancing, think about it like this, and note that I claim no rigor here. Say you have an empty tree. Already balanced! Now say you insert an element. Already balanced! Now say you insert *another* element. Well, there's an odd number so you can't do much there.

Here's the tricky part. Say you insert *another* element. This could go two ways: left or right; balanced or unbalanced. In the case that it's unbalanced, you can clearly perform a rotation of the tree to balance it. In the case that it's balanced, already balanced!

What's important to note here is that you're *constantly* rebalancing. It's not like you have a mess of a tree, decided to insert an element, but before you do that, you rebalance, and then leave a mess after you've completed the insertion.

Now say you keep inserting elements. The tree's *gonna* get unbalanced, but not by much. And when that does happen, first off you're correcting that immediately, and secondly, the correction occurs along the path of the insertion, which is `O(log(n))`

in a balanced tree. The rotations in the paper you linked to are touching at most three nodes in the tree to perform a rotation. so you're doing `O(3 * log(n))`

work when rebalancing. That's still `O(log(n))`

.

`(:)`

is O(1) by definition --- despite the funny name, it is merely a simple constructor. – dave4420 Jan 4 '13 at 22:35