Here is my suggested solution: the gist is to keep track of the subtree's current number of nodes, current height and maximum height until that point.

With the current number of nodes and height, one can calculate the root's number of nodes and height via its direct childs respective information, taking into to consideration the relation between the child heights and if they are perfect subtrees or not.

Solution is O(n) time complexity and O(h) space complexity (function call stack corresponds from the root through the unique path to the current node).

Here is the Python code for this solution, and you can find the complete gist with examples here:

```
from collections import namedtuple
class BTN():
def __init__(self, data=None, left=None, right=None):
self.data = data
self.left = left
self.right = right
# number of nodes for a perfect tree of the given height
def max_nodes_per_height(height: int) -> int:
return 2**(height + 1) - 1
def height_largest_complete_subtree(root: BTN) -> int:
CompleteInformation = namedtuple('CompleteInformation', ['height', 'num_nodes', 'max_height'])
def height_largest_complete_subtree_aux(root: BTN) -> CompleteInformation:
if (root is None):
return CompleteInformation(-1, 0, 0)
left_complete_info = height_largest_complete_subtree_aux(root.left)
right_complete_info = height_largest_complete_subtree_aux(root.right)
left_height = left_complete_info.height
right_height = right_complete_info.height
if (left_height == right_height):
if (left_complete_info.num_nodes == max_nodes_per_height(left_height)):
new_height = left_height + 1
new_num_nodes = left_complete_info.num_nodes + right_complete_info.num_nodes + 1
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
else:
new_height = left_height
new_num_nodes = max_nodes_per_height(left_height)
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
elif (left_height > right_height):
if (max_nodes_per_height(right_height) == right_complete_info.num_nodes):
new_height = right_height + 2
new_num_nodes = min(left_complete_info.num_nodes, max_nodes_per_height(right_height + 1)) + right_complete_info.num_nodes + 1
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
else:
new_height = right_height + 1
new_num_nodes = max_nodes_per_height(right_height) + right_complete_info.num_nodes + 1
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
elif (left_height < right_height):
if (left_complete_info.num_nodes == max_nodes_per_height(left_height)):
new_height = left_height + 1
new_num_nodes = left_complete_info.num_nodes + max_nodes_per_height(left_height) + 1
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
else:
new_height = left_height
new_num_nodes = (max_nodes_per_height(left_height - 1) * 2) + 1
return CompleteInformation(new_height,
new_num_nodes,
max(new_height, max(left_complete_info.max_height, right_complete_info.max_height))
)
return height_largest_complete_subtree_aux(root).max_height
```