```
class Tree:
def __init__(self, new_key):
self.__key = new_key # Root key value
self.__children = [] # List of children
self.__num_of_descendants = 0 # Number of Descendants of this node
# Prints the given tree
def printTree(self):
return self.printTreeGivenPrefix("", True)
# Prints the given tree with the given prefix for the line
# last_child indicates whether the node is the last of its parent"s child
# or not
def printTreeGivenPrefix(self, line_prefix, last_child):
print(line_prefix, end="")
if last_child:
print("â””--> ", end="")
else:
print("|--> ", end="")
print(self.__key)
if len(self.__children) > 0:
next_pre = line_prefix
if last_child:
next_pre += " "
else:
next_pre += "| "
for child_index in range(len(self.__children)-1):
self.__children[child_index].\
printTreeGivenPrefix(next_pre, False)
self.__children[-1].printTreeGivenPrefix(next_pre, True)
def __repr__(self):
return "[" + str(self.__key) + "".join(
[ repr(child) for child in self.__children ]) + "]"
# This static function will load a tree with the format of below:
# [root[child_1][child_2]...[child_n]]
# Each child_i can be a tree with the above format, too
# pos is the position in the given string
@staticmethod
def loadTree(tree_str, pos = 0):
new_node = None
while pos < len(tree_str):
if tree_str[pos] == "[":
pos += 1
new_node = Tree(tree_str[pos])
while pos < len(tree_str) and tree_str[pos + 1] != "]":
pos += 1
child_tree, pos = Tree.loadTree(tree_str, pos)
if child_tree:
new_node.__children.append(child_tree)
new_node.__num_of_descendants += \
1 + child_tree.__num_of_descendants
return new_node, pos + 1
else:
pos += 1
return new_node, pos
def find_largest(self):
if self.__num_of_descendants == 1:
return self.__children[0]
else:
largest_child = self.__children[0]
for child in self.__children:
if child.__num_of_descendants > \
largest_child.__num_of_descendants:
largest_child = child
if child.__num_of_descendants == \
largest_child.__num_of_descendants:
if child.__key > largest_child.__key:
largest_child = child
return largest_child
def convert_to_binary_tree(self):
if self.__num_of_descendants != 0:
if self.__num_of_descendants < 3:
for child in self.__children:
child.convert_to_binary_tree()
if self.__num_of_descendants > 2:
left_child = self.__children[0]
for child in self.__children[1:]:
if len(child.__children) > len(left_child.__children):
left_child = child
elif len(child.__children) == len(left_child.__children):
if child.__key > left_child.__key:
left_child = child
self.__children.remove(left_child)
self.__num_of_descendants -= 1
right_child = self.__children[0]
for child in self.__children[1:]:
if len(child.__children) > len(right_child.__children):
right_child = child
elif len(child.__children) == len(right_child.__children):
if child.__key > right_child.__key:
right_child = child
self.__children.remove(right_child)
self.__num_of_descendants -= 1
print(self.__num_of_descendants)
print(self.__children)
print(left_child)
print(right_child)
#Move remaining children two either left_child or right_child.
while self.__num_of_descendants != 0:
largest_child = self.find_largest()
print(largest_child)
if left_child.__num_of_descendants < \
right_child.__num_of_descendants:
left_child.__children.append(largest_child)
left_child.__num_of_descendants += 1
self.__children.remove(largest_child)
self.__num_of_descendants -= 1
elif left_child.__num_of_descendants > \
right_child.__num_of_descendants:
right_child.__children.append(largest_child)
right_child.__num_of_descendants += 1
self.__children.remove(largest_child)
self.__num_of_descendants -= 1
elif left_child.__num_of_descendants == \
right_child.__num_of_descendants:
if left_child.__key > right_child.__key:
left_child.__children.append(largest_child)
left_child.__num_of_descendants += 1
self.__children.remove(largest_child)
self.__num_of_descendants -= 1
else:
right_child.__children.append(largest_child)
right_child.__num_of_descendants += 1
self.__children.remove(largest_child)
self.__num_of_descendants -= 1
#Now run recursion on left and right binary children.
self.__children.append(left_child)
self.__children.append(right_child)
self.__num_of_descendants = 2
print(self.__children)
for child in self.__children:
child.convert_to_binary_tree()
def main():
tree, processed_chars = Tree.loadTree('[z[y][x][w][v]]]')
tree.convert_to_binary_tree()
tree.printTree()
print(tree)
if __name__ == "__main__":
main()
```

I have to convert a given tree into a binary tree. If a node in the tree has more than 2 children, I have to assign the child with the most descendants as the left node and the child with the second largest number of descendents as the right child. The remaining children are added as following: 1) Take child with largest number of descendants 2) Add it to Left/Right node. Whichever has fewer children at that time.

*If at any time I need to select the child with the largest number of descendants, but there are two+ with the same number of descendents, I take the one with the larger key value.

```
I get a print out like this...
2 #Number of 'z' children after left and right node chosen.
[[w], [v]] #Children of 'z'
[y] #Binary left child of 'z'
[x] #Binary right child of 'z'
[w] #This is a bug. It should be choosing 'v' as larger child of 'z' and assigning it to left child 'y'
[v] #This is a bug. see above.
[[y[w]], [x[v]]] #These are the children of node 'z'
â””--> z #schematic of binary tree
|--> y
| â””--> w
â””--> x
â””--> v
[z[y[w]][x[v]]] #final binary tree
```

`__`

here. If you insist, you can use`_`

as a friendly reminder that some aren't meant to be modified outside of the class, but even that's often overkill. – DSM Mar 27 '14 at 3:39`main`

function and`if __name__ == "__main__"`

boilerplate really indented under the`class`

, or are they actually at the top level? – Blckknght Mar 27 '14 at 3:49name== "main" are at main level. – zachary Mar 27 '14 at 3:57