# time complexity of the following algorithm

Suppose a Node (in a BST) is defined as follows (ignore all the setters/getters/inits).

``````class Node
{

Node parent;
Node leftChild;
Node rightChild;
int value;
// ... other stuff
}
``````

Given some a reference to some `Node` in a BST (called `startNode`) and another `Node` (called `target`), one is to check whether the tree containing `startNode` has any node whose `value` is equal to `target.value`.

I have two algorithms to do this:

Algorithm #1:

``````- From `startNode`, trace the way to the root node (using the `Node.parent` reference) : O(n)
- From the root node, do a regular binary search for the target : O(log(n))
``````

T(n) = O(log(n) + n)

Algorithm #2: Basically perform a DFS (Psuedo-code only)

``````current_node = startnode
While the root has not been reached
go up one level from the current_node
perform a binary-search from this node downward (excluding the branch from which we just go up)
``````

What is the time-complexity of this algorithm?

The naive answer would be `O(n * log(n))`, where `n` is for the `while` loop, as there are at most `n` nodes, and `log(n)` is for the binary-search. But obviously, that is way-overestimating!

The best (partial) answer I could come up with was:

• Suppose each sub-branch has some `m_i` nodes and that there are `k` sub-branches. In other words, `k` is the number of nodes between `startNode` and the root node

• The total time would be

.

``````T(n) = log(m1) + log(m2) + ... + log(mk)
= log(m1 * m2 * ... * mk)
Where m1 + m2 + ... + mk = n (the total number of nodes in the tree)
``````

(This is the best estimation I could get as I forgot most of my maths to do any better!)

So I have two questions:

``````0) What is the time-complexity of algorithm #2 in terms of n
1) Which algorithm does better in term of time-complexity?
``````
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Ok, after digging through my old Maths books, I was able to find that the upper bound of a product of `k` numbers whose sum is `n` is `p <= (n /k) ^k`.

With that said, the `T(n)` function would become:

``````T(n) = O(f(n, k))
Where
f(n, k) = log((n/k)^k)
= k * log(n/k)
= k * log(n) - k * log(k)
``````

(Remember, k is the number nodes between the startNode and the root, while n is the total number of node)

How would I go from here? (ie., how do I simplify the f(n, k)? Or is that good enough for Big-O analysis? )

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