I was wondering if there is a suitable algorithm for maintaining the balance of a binary tree, when it is known that elements are always inserted in order.
One option for this would be to use the standard method of creating a balanced tree from a sorted array or linked list, as discussed in this question, and also this other question. However, I would like a method where a few elements can be inserted into the tree, lookups then performed on it, and other elements then added later, without having to decompose the tree to a list and re-make the whole thing.
Another option would be to use one of the many self-balancing tree implementations, AVL, AA, Red-Black, etc. etc. However, all of these impose some sort of overhead in the process of insertion, and I was wondering if there may be a way to avoid this given the constraint that elements are always inserted in increasing order.
So, for clarity, I would like know if there is a method by which I can maintain a balanced binary tree, such that I can insert an arbitrary new element into it at any point and keep the balance of the tree, providing that the new element is greater in the ordering of the tree than all elements already present in the tree.
As an example, suppose I had the following tree:
4 / \ / \ 2 6 / \ / \ 1 3 5 7
Is there a simple way to maintain the balance when inserting a new element, if I know that the element will be larger than 7?