Finding the smallest number of nodes that must be added to make a binary tree balanced?

Suppose that you are given an arbitrary binary tree. We'll call the tree balanced if the following is true for all nodes:

1. That node is a leaf, or
2. The height of the left subtree and the height of the right subtree differ by at most ±1 and the left and right subtrees are themselves balanced.

Is there an efficient algorithm for determining the minimum number of nodes that need to be added to the tree in order to make it balanced? For simplicity, we'll assume that nodes can only be inserted as leaf nodes (like the way that a node is inserted into a binary search tree that does no rebalancing).

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why would you need to add nodes. wouldn't you just rebalance it without adding new ones? – nathan hayfield Jan 18 '13 at 1:42
@nathanhayfield- If I was trying to build a balanced binary search tree, then yes, it would be best to try to rebalance the tree. This is more of a hypothetical question. – templatetypedef Jan 18 '13 at 1:44
Calculate the height at every node, done? – Alex DiCarlo Jan 18 '13 at 1:44
@AlexDiCarlo- If there is a height difference of +6 at a node, can you use that to immediately infer how many nodes must be added to the smaller tree to get the balance factor to correct to +1? – templatetypedef Jan 18 '13 at 1:44
@nathanhayfield What is zero? We're talking about re-balancing by inserting new nodes, not re-balancing by moving nodes around. – Alex DiCarlo Jan 18 '13 at 1:50

2 Answers

The following tree fits into your definition, although it doesn't seem very balanced to me:

EDIT This answer is wrong, but it has enough interesting stuff in it that I don't feel like deleting it yet. The algorithm produces a balanced tree, but not a minimal one. The number of nodes it adds is:

$\sum_{n} \sum_{i=lower(n)}^{upper(n)-2}fib(i)$

where `n` ranges over all nodes in the tree, `lower(n)` is the depth of the child of `n` with the lower depth and `upper(n)` is the depth of the child of `n` with the higher depth. Using the fact that the sum of the first `k` fibonacci numbers is `fib(k+2)-1`, we can replace the inner sum with `fib(upper(n)) - fib(lower(n) + 2)`.

The formula is (more or less) derived from the following algorithm to add nodes to the tree, making it balanced (in python, only showing the relevant algorithms):

``````def balance(tree, label):
if tree is None:
return (None, 0)
left, left_height = balance(tree.left_child, label)
right, right_height = balance(tree.right_child, label)
while left_height < right_height - 1:
left = Node(label(), left, balanced_tree(left_height - 1, label))
left_height += 1
while right_height < left_height - 1:
right = Node(label(), right, balanced_tree(right_height - 1, label))
right_height += 1
return (Node(tree.label, left, right), max(left_height, right_height) + 1)

def balanced_tree(depth, label):
if depth <= 0:
return None
else:
return Node(label(),
balanced_tree(depth - 1, label),
balanced_tree(depth - 2, label))
``````

As requested: report the count instead of creating the tree:

``````def balance(tree):
if tree is None:
return (0, 0)
left, left_height = balance(tree.left_child)
right, right_height = balance(tree.right_child)
while left_height < right_height - 1:
left += balanced_tree(left_height - 1) + 1
left_height += 1
while right_height < left_height - 1:
right += balanced_tree(right_height - 1) + 1
right_height += 1
return (left + right, max(left_height, right_height) + 1)

def balanced_tree(depth):
if depth <= 0:
return 0
else:
return (1 + balanced_tree(depth - 1)
+ balanced_tree(depth - 2))
``````

Edit: Actually, I think that other than computing the size of a minimum balanced tree of depth n more efficiently (i.e. memoizing it, or used the closed form: it's just `fibonacci(n+1)-1`), that's probably as efficient as you can get, since you have to examine every node in the tree in order to test the balance condition, and that algorithm looks at every node precisely once.

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@rici- Yep, that tree is balanced. However, I think that your code will produce the smallest balanced tree, rather than reporting the number of nodes needed to get up to balance. – templatetypedef Jan 18 '13 at 4:18
@templatetypedef: yup, that's what it does. There's probably a more efficient way of figuring out the number of nodes than just counting them, although I'm too tired to figure it out. It should be trivial to see how to modify the code to report the count rather than construct the tree. – rici Jan 18 '13 at 4:20
@templatetypedef: obviously it would be better to cache the values of balanced_tree (which is, in any case, fibonacci(i)-1), but there you go. – rici Jan 18 '13 at 4:25
@templatetypedef: actually, it doesn't produce the smallest balanced tree; although it does produce a balanced tree. I realized today that producing the smallest balanced tree is a lot harder, particularly since it may require fewer additions to increase by two the depth of a depth n-1 balanced tree than to increase by one the depth of a depth n balanced tree. So I now think it will take at least two passes, or perhaps some kind of bottom-up DP algorithm. – rici Jan 18 '13 at 20:34

Will this work?

Go recursively from the top. If the node A is imbalanced, add a node B on the short side and and enough left nodes to node B until node A is balanced.

(Of course, count the nodes added.)

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@xpda- My apologies - I had the wrong definition of balance. The left and right subtrees must also themselves be balanced, not just have the same height as one another. AS a result, I don't think this will work any more. – templatetypedef Jan 18 '13 at 2:35
Are you sure? They should be balanced as you progress downward through the tree recursively. – xpda Jan 18 '13 at 3:09