Is there a balanced BST with each node maintain the subtree size?

Is there a balanced BST structure that also keeps track of subtree size in each node?

In Java, TreeMap is a red-black tree, but doesn't provide subtree size in each node.

Previously, I did write some BST that could keep track subtree size of each node, but it's not balanced.

The questions are:

• Is it possible to implement such a tree, while keeping efficiency of (O(lg(n)) for basic operations)?
• If yes, then is there any 3rd-party libraries provide such an impl?
A Java impl is great, but other languages (e.g c, go) would also be helpful.

BTW:

• The subtree size should be kept track in each node.
So that could get the size without traversing the subtree.

Possible appliation:

• Keep track of rank of items, whose value (that the rank depends on) might change on fly.

The Weight Balanced Tree (also called the Adams Tree, or Bounded Balance tree) keeps the subtree size in each node.

This also makes it possible to find the Nth element, from the start or end, in log(n) time.

My implementation in Nim is on github. It has properties:

• Generic (parameterized) key,value map
• Insert (add), lookup (get), and delete (del) in O(log(N)) time
• Key-ordered iterators (inorder and revorder)
• Lookup by relative position from beginning or end (getNth) in O(log(N)) time
• Get the position (rank) by key in O(log(N)) time
• Efficient set operations using tree keys
• Map extensions to set operations with optional value merge control for duplicates

There are also implementations in Scheme and Haskell available.

Well, the AVL tree, for example, by virtue of being perfectly balanced, implicitly knows how many nodes are in each sub-tree, as long as it keeps track of the total number of nodes - the difference in size between the left and right sub-tree can be at most one element. Each node has a balance field that can be one of -1, 0, or 1, indicating left side is greater, both are equal, or right side is greater, respectively. (or maybe I have it backwards, I don't remember for sure right now - minor point).

Anyway -- so for example if you have an AVL tree with 101 elements, you already know that the two sub-trees each have 50 elements (because the tree is balanced) - (i.e. 101 elements minus the sub-tree's root element, divided by two). At the next level, with total of 50 elements, one sub-tree will have 25 elements, the other 24 (plus the one in the sub-tree's root). Which one is which is indicated by the balance field.

This principle applies recursively all the way to the leaves.

That's called an "order statistic tree": https://en.wikipedia.org/wiki/Order_statistic_tree

It's pretty easy to add the size to any kind of balanced binary tree (red-black, avl, b-tree, etc.), or you can use a balancing algorithm that works with the size directly, like weight-balanced trees (@DougCurrie answer) or (better) size-balanced trees: https://cs.wmich.edu/gupta/teaching/cs4310/lectureNotes_cs4310/Size%20Balanced%20Tree%20-%20PEGWiki%20sourceMayNotBeFullyAuthentic%20but%20description%20ok.pdf

Unfortunately, I don't think there are any standard-library implementations, but you can find open source if you look for it. You may want to roll your own.