I'm trying to figure out this data structure, but I don't understand how can we tell there are O(log(n)) subtrees that represents the answer to a query?

Here is a picture for illustration:

Thanks!

1

I'm trying to figure out this data structure, but I don't understand how can we tell there are O(log(n)) subtrees that represents the answer to a query?

Here is a picture for illustration:

Thanks!

0

If we make the assumption that the above is a purely functional binary tree [wiki], so where the nodes are immutable, then we can make a "copy" of this tree such that only elements with a value larger than *x _{1}* and lower than

Let us start with a very simple case to illustrate the point. Imagine that we simply do not have any bounds, than we can simply return the entire tree. So instead of constructing a *new* tree, we return a reference to the root of the tree. So we can, without any bounds return a tree in *O(1)*, given that tree is not edited (at least not as long as we use the subtree).

The above case is of course quite simple. We simply make a "copy" (not really a copy since the data is immutable, we can just return the tree) of the entire tree. So let us aim to solve a more complex problem: we want to construct a tree that contains all elements larger than a threshold *x _{1}*. Basically we can define a recursive algorithm for that:

- the cutted version of
`None`

(or whatever represents a null reference, or a reference to an empty tree) is`None`

; - if the node has a value is smaller than the threshold, we return a "cutted" version of the right subtree; and
- if the node has a value greater than the threshold, we return an inode that has the same right subtree, and as left subchild the cutted version of the left subchild.

So in pseudo-code it looks like:

```
def treelarger(some_node, min):
if some_tree is None:
return None
if some_node.value > min:
return Node(treelarger(some_node.left, min), some_node.value, some_node.right)
else:
return treelarger(some_node.right, min)
```

This algorithm thus runs in *O(h)* with *h* the height of the tree, since for each case (except the first one), we recurse to *one* (not both) of the children, and it ends in case we have a node without children (or at least does not has a subtree in the direction we need to cut the subtree).

We thus do *not* make a *complete* copy of the tree. We *reuse* a lot of nodes in the old tree. We only construct a new "surface" but most of the "volume" is part of the old binary tree. Although the tree itself contains *O(n)* nodes, we construct, at most, *O(h)* new nodes. We can optimize the above such that, given the cutted version of one of the subtrees is the same, we do not create a new node. But that does not even matter much in terms of time complexity: we generate at most *O(h)* new nodes, and the total number of nodes is either less than the original number, or the same.

In case of a complete tree, the height of the tree *h* scales with *O(log n)*, and thus this algorithm will run in *O(log n)*.

Then how can we generate a tree with elements between two thresholds? We can easily rewrite the above into an algorithm `treesmaller`

that generates a subtree that contains all elements that are smaller:

```
def treesmaller(some_node, max):
if some_tree is None:
return None
if some_node.value < min:
return Node(some_node.left, some_node.value, treesmaller(some_node.right, max))
else:
return treesmaller(some_node.left, max)
```

so roughly speaking there are two differences:

- we change the condition from
`some_node.value > min`

to`some_node.value < max`

; and - we recurse on the
`right`

subchild in case the condition holds, and on the left if it does not hold.

Now the conclusions we draw from the previous algorithm are also conclusions that can be applied to this algorithm, since again it only introduces *O(h)* new nodes, and the total number of nodes can only decrease.

Although we *can* construct an algorithm that takes the two thresholds concurrently into account, we can simply reuse the above algorithms to construct a subtree containing only elements within range: we first pass the tree to the `treelarger`

function, and then that result through a `treesmaller`

(or vice versa).

Since in both algorithms, we introduce *O(h)* new nodes, and the height of the tree can not increase, we thus construct at most *O(2 h)* and thus *O(h)* new nodes.

Given the original tree was a *complete* tree, then it thus holds that we create *O(log n)* new nodes.

O(log n)levels, and for each of this level we either return the full node, or an edited one where we recurse one at most one subtree. – Willem Van Onsem Nov 17 '18 at 12:58