# How can I prove this operation over Binary search trees?

I'd want you to give me a hint to prove this exercise from the book of Cormen: "Prove that no matter what node we start at in a height-h binary search tree, k successive calls to TREE-SUCCESSOR take O(k+h) time."

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• Let `x` be the starting node and `z` be the ending node after `k` successive calls to TREE-SUCCESSOR.
• Let `p` be the simple path between `x` and `z` inclusive.
• Let `y` be the common ancestor of `x` and `z` that `p` visits.
• The length of `p` is at most `2h`, which is `O(h)`.
• Let `output` be the elements that their values are between `x.key` and `z.key` inclusive.
• The size of `output` is `O(k)`.
• In the execution of `k` successive calls to TREE-SUCCESSOR, the nodes that are in `p` are visited, and besides the nodes `x`, `y` and `z`, if a sub tree of a node in `p` is visited then all its elements are in `output`.
• So the running time is `O(h+k)`.
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`In the execution of k successive calls to TREE-SUCCESSOR, the nodes that are in p are visited, and besides the nodes x, y and z` Can you please explain what is `y` here? –  Rafi Kamal Dec 11 '12 at 13:24
I added `y` to the answer. –  Avi Cohen Dec 11 '12 at 15:41

Hint: work out a small example, observe the result, try to extrapolate the reason.

To get started, here are some things to consider.

Start at a certain node, k succesive calls to Tree-Succcesor consititutes a partial tree walk. How many (at least and at most) nodes does this walk visit? (Hint: Think about key(x)). Keep in mind that an edge is visited at most twice (why?).

Final hint: The result is `O(2h+k)`.

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A node is visited at most trice. –  Avi Cohen Sep 8 '12 at 11:58