# Time analysis of binary search tree operations

I read about binary search trees that if it is a complete tree (all nodes except leaf nodes have two children) having n nodes, then no path can have more than 1+log n nodes.

Here is the calculation I did... can you show me where did I go wrong....

``````the first level of bst has only one node(i.e. the root)-->2^0
the second level have 2 nodes(the children of root)---->2^1
the third level has 2^3=8 nodes
.
.
the (x+1)th level has 2^x nodes

so the total number of nodes =n = 2^0 +2^1 +2^2 +...+2^x = 2^(x+1)-1
so, x=log(n+1)-1

now as it is a 'complete' tree...the longest path(which has most no of nodes)=x
and so the nodes experienced in this path is x+1= log(n+1)
``````

Then how did the number 1+log n come up...?

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What is your definition of path? Do you view the tree as a directed (edges go only from parent to children nodes) or undirected (edges go "both ways") graph? –  Philippe Sep 26 '11 at 17:31
@Philippe...it is an undirected graph –  avinash Sep 26 '11 at 17:38
OK... the log(n+1) - 1 bound seems to correspond to the maximum length for a path from the root to any node, though. –  Philippe Sep 26 '11 at 17:41
Shorter answer: the number `x` of levels in a complete (or perfect) binary tree is `log2(n+1)`, where `n` is the number of nodes (alternatively, `n = 2^(x-1)`). A tree with `x` levels has height `x-1`. The longest path from the root to any node contains `x = log2(n+1)` nodes (and `x-1` edges).
Now because `n+1` is a power of 2, we have that `log2(n+1) = 1 + floor(log2(n))`. In other words, `1 + log2(n)` is a correct upper-bound, but it is never an integer.
It is unclear to me whether the `x` in your computation refers to the height or the number of levels.