def get_std_tree():
r = Node(1)
r.left = Node(2)
r.right = Node(3)
r.left.left = Node(4)
r.left.right = Node(5)
r.right.left = Node(6)
r.right.right = Node(7)
return r
def get_child_sum_tree():
root = Node(10)
root.left = Node(8)
root.right = Node(2)
root.left.left = Node(3)
root.left.right = Node(5)
root.right.left = Node(2)
return root
def get_std_tree():
root = Node(1)
root.left = Node(2)
root.right = Node(3)
root.left.left = Node(4)
root.left.right = Node(5)
return root
def deserialize(string, m):
global IDX
if IDX > m:
return None
if string[IDX] == '$':
IDX += 1
return None
root = Node(string[IDX])
IDX += 1
root.left = deserialize(string, m)
root.right = deserialize(string, m)
return root
def build_tree_from_po_and_io(po, io, start, end):
global PO_INDEX
if start > end:
return None
key = po[PO_INDEX]
node = Node(key)
PO_INDEX -= 1
if start == end:
return node
in_idx = search(io, start, end, key)
# start from right
node.right = build_tree_from_po_and_io(po, io, in_idx + 1, end)
node.left = build_tree_from_po_and_io(po, io, start, in_idx - 1)
return node
def create_linked_binary_tree(array):
q = Queue()
i = 0
root = Node(array[i])
q.put(root)
max_index = len(array) - 1
i += 1
while not q.empty():
node = q.get()
if i <= max_index:
node.left = Node(array[i])
i += 1
q.put(node.left)
if i <= max_index:
node.right = Node(array[i])
i += 1
q.put(node.right)
return root
while root is not None:
if root.left is None:
print root,
root = root.right
else:
pre = root.left
while pre.right is not None and pre.right != root:
pre = pre.right
if pre.right is None:
pre.right = root
root = root.left
else:
pre.right = None
print root,
root = root.right
if __name__ == '__main__':
r = Node(1)
r.left = Node(2)
r.right = Node(3)
r.left.left = Node(4)
r.left.right = Node(5)
morris_traversal(r)
s = root.data + ls + rs
is_found = False
# to consider non leaf nodes
if len(s) > 3:
if hm.get(s):
is_found = True
hm[s] = True
return is_found_left or is_found_right or is_found, s
if __name__ == '__main__':
r = Node('A')
r.left = Node('B')
r.right = Node('C')
r.left.left = Node('D')
r.left.right = Node('E')
r.right.right = Node('B')
r.right.right.left = Node('D')
r.right.right.right = Node('E')
print check_duplicate(r, {})
# false case
r = Node('A')
r.left = Node('B')
r.right = Node('C')
r.left.left = Node('D')
while not s1.is_empty() or not s2.is_empty():
while not s1.is_empty():
node = s1.pop()
print node,
if node.left:
s2.push(node.left)
if node.right:
s2.push(node.right)
while not s2.is_empty():
node = s2.pop()
print node,
if node.right:
s1.push(node.right)
if node.left:
s1.push(node.left)
root = Node(1)
root.left = Node(2)
root.right = Node(3)
root.left.left = Node(4)
root.left.right = Node(5)
root.right.left = Node(6)
root.right.right = Node(7)
spiral_print(root)
_deepest_odd_level_node = root
if l_node is not None and l_level % 2 != 0:
deepest_odd_level = l_level
_deepest_odd_level_node = l_node
if r_node is not None and r_level % 2 != 0 and deepest_odd_level < r_level:
deepest_odd_level = r_level
_deepest_odd_level_node = r_node
return _deepest_odd_level_node, deepest_odd_level
if __name__ == '__main__':
print ''
r = Node(5)
r.left = Node(10)
r.right = Node(2)
r.left.left = Node(3)
r.left.right = Node(4)
r.right.right = Node(15)
r.left.right.left = Node(44)
r.left.right.left.right = Node(12)
r.right.right.left = Node(9)
r.right.right.left = Node(8)
print deepest_odd_level_node(r, 1)
r = Node(10)
r.left = Node(28)
r.right = Node(13)
def convert_to_mirror(root):
if root is None:
return
left = root.left
root.left = root.right
root.right = left
convert_to_mirror(root.left)
convert_to_mirror(root.right)
if __name__ == '__main__':
t = Node(1)
t.left = Node(2)
t.right = Node(3)
t.left.left = Node(4)
t.left.right = Node(5)
convert_to_mirror(t)
print t, t.left, t.right, t.right.left, t.right.right
def iterative_mirror(root):
q = Queue()
q.put(root)
while not q.empty():
node = q.get()
def eval_expression_tree(root):
if is_leaf(root):
return root.data
left_val = eval_expression_tree(root.left)
right_val = eval_expression_tree(root.right)
op = root.data
funct = EXPS[op]
return funct(left_val, right_val)
if __name__ == '__main__':
print ''
r = Node('+')
r.left = Node(3)
r.right = Node('*')
r.right.left = Node('+')
r.right.right = Node(2)
r.right.left.left = Node(5)
r.right.left.right = Node(9)
print eval_expression_tree(r)
"""
amzn
http://www.geeksforgeeks.org/given-a-binary-tree-how-do-you-remove-all-the-half-nodes/
"""
def is_subtree(root1, root2):
if root1:
if root1.data == root2.data and are_trees_identical(root1, root2):
return True
is_found_left = is_subtree(root1.left, root2)
is_found_right = is_subtree(root1.right, root2)
return is_found_left or is_found_right
return False
if __name__ == '__main__':
print ''
root1 = Node(26)
root1.left = Node(10)
root1.right = Node(3)
root1.left.left = Node(4)
root1.left.right = Node(6)
root1.left.left.right = Node(30)
root1.right.right = Node(3)
root2 = Node(10)
root2.left = Node(4)
root2.right = Node(6)
root2.left.right = Node(30)
print 'is subtree'
print is_subtree(root1, root2)
"""