Here's a Python solution which works in O(n) time, in-place with O(h) auxiliary space where h is the height of the tree; the only auxiliary data structure is the stack required for the recursive functions.

It works using a generator function which iterates over the tree *while the consumer is changing the tree*, but we make local copies of the `left`

and `right`

subtrees before yielding them, so the consumer can reassign those without breaking the generator. (Actually only a local copy of `right`

is really required, but I made local copies of both anyway.)

```
class Node:
def __init__(self, data, left=None, right=None):
self.data = data
self.left = left
self.right = right
def __repr__(self):
# display for debug/testing purposes
def _r(n):
return '*' if n is None else '(%s ← %r → %s)' % (_r(n.left), n.data, _r(n.right))
return _r(self)
def balance(root):
def _tree_iter(node):
if node is not None:
# save to local variables, could be reassigned while yielding
left, right = node.left, node.right
yield from _tree_iter(left)
yield node
yield from _tree_iter(right)
def _helper(it, k):
if k == 0:
return None
else:
half_k = (k - 1) // 2
left = _helper(it, half_k)
node = next(it)
right = _helper(it, k - half_k - 1)
node.left = left
node.right = right
return node
n = sum(1 for _ in _tree_iter(root))
return _helper(_tree_iter(root), n)
```

Example:

```
>>> root = Node(4, left=Node(3, left=Node(1, right=Node(2))), right=Node(6, left=Node(5), right=Node(8, left=Node(7), right=Node(9))))
>>> root
(((* ← 1 → (* ← 2 → *)) ← 3 → *) ← 4 → ((* ← 5 → *) ← 6 → ((* ← 7 → *) ← 8 → (* ← 9 → *))))
>>> balance(root)
(((* ← 1 → *) ← 2 → (* ← 3 → (* ← 4 → *))) ← 5 → ((* ← 6 → *) ← 7 → (* ← 8 → (* ← 9 → *))))
```

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