def sortedArrayToBST(arr):
if not arr:
return None
mid = len(arr) // 2
root = TreeNode(arr[mid])
root.left = sortedArrayToBST(arr[:mid])
root.right = sortedArrayToBST(arr[mid + 1:])
return root
def sorted_array_to_bst(array):
if len(array) == 0:
return None
elif len(array) == 1:
return TreeNode(array[0])
else:
mid = int(len(array) / 2)
root = TreeNode(array[mid])
root.left = sorted_array_to_bst(array[:mid])
root.right = sorted_array_to_bst(array[mid + 1:])
return root
def construct(inorder, preorder):
if len(inorder) == 0 or len(preorder) == 0:
return None
else:
root = preorder[0]
index = inorder.index(root)
left_inorder = inorder[:index]
right_inorder = inorder[index + 1:]
left_preorder = preorder[1:1 + len(left_inorder)]
right_preorder = preorder[1 + len(left_inorder):]
root = TreeNode(root)
root.left = construct(left_inorder, left_preorder)
root.right = construct(right_inorder, right_preorder)
return root
def min_tree(arr):
# base case
if len(arr) is 0:
return None
# make node from middle of array
mid = len(arr) / 2
node = TreeNode(arr[mid])
# recursively make node from each middle of each half of each array
node.left = min_tree(arr[:mid])
node.right = min_tree(arr[mid + 1:]) # +1 to not include current mid
# returns root
return node
childNode = parentNode.right
stack.pop()
stack.append((parentNode, parentState - 1))
if childNode:
stack.append((childNode, bothPending))
else:
if oneNodeFound and len(stack) - 1 == fcaIndex:
fcaIndex -= 1
stack.pop()
return None
if __name__ == "__main__":
one = TreeNode(1)
two = TreeNode(2)
three = TreeNode(3)
four = TreeNode(4)
five = TreeNode(5)
six = TreeNode(6)
seven = TreeNode(7)
eight = TreeNode(8)
nine = TreeNode(9)
one.left = two
one.right = three
two.left = four
two.right = five
three.left = six
three.right = seven
four.left = eight
four.right = nine
print(firstCommonAncestor(one, eight, five))
# left & right heights
left_height = root.height(root.left)
right_height = root.height(root.right)
# get positive value of difference in height
height_difference = abs(left_height - right_height)
# check height requirement satisfied
if height_difference <= 1:
# ... recursively
if check_balanced(root.left) is True and check_balanced(
root.right) is True:
return True
# if we reach here means tree is not
# height-balanced tree
return False
if __name__ == "__main__":
bal_root = min_tree([1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12])
print(check_balanced(bal_root))
unbal_root = TreeNode(5)
unbal_root.left = TreeNode(4)
unbal_root.left.left = TreeNode(3)
unbal_root.left.left.left = TreeNode(2)
unbal_root.left.left.left.left = TreeNode(1)
unbal_root.right = TreeNode(6)
print(check_balanced(unbal_root))
result.append(item)
return result
if __name__ == "__main__":
fifty = TreeNode(50)
twenty = TreeNode(20)
sixty = TreeNode(60)
ten = TreeNode(10)
twentyFive = TreeNode(25)
seventy = TreeNode(70)
five = TreeNode(5)
fifteen = TreeNode(15)
sixtyFive = TreeNode(65)
eighty = TreeNode(80)
fifty.left = twenty
fifty.right = sixty
twenty.left = ten
twenty.right = twentyFive
sixty.right = seventy
ten.left = five
ten.right = fifteen
seventy.left = sixtyFive
seventy.right = eighty
five = TreeNode(5)
four = TreeNode(4)
one = TreeNode(1)
seven = TreeNode(7)
six = TreeNode(6)
ten = TreeNode(10)
sol = Solution()
sol[level].append(node.value)
if node.left:
queue.append([node.left, level + 1])
if node.right:
queue.append([node.right, level + 1])
return sol
if __name__ == "__main__":
one = TreeNode(1)
two = TreeNode(2)
three = TreeNode(3)
four = TreeNode(4)
five = TreeNode(5)
six = TreeNode(6)
seven = TreeNode(7)
eight = TreeNode(8)
one.left = two
one.right = three
two.left = four
two.right = five
three.left = six
three.right = seven
lists = listOfDepths(one)
print(lists)
for l in lists:
curr = LinkedListNode(None)
for i in lists[l]:
curr.next = LinkedListNode(i)
curr = curr.next
return True
else:
if root.val > max_val or root.val < min_val:
return False
else:
if (root.left != None and root.val < root.left.val) or (
root.right != None and root.val > root.right.val):
return False
else:
return isValidBST(root.left, root.val, min_val) and isValidBST(
root.right, max_val, root.val)
head = TreeNode.get_sample()
print(isValidBST(head, sys.maxsize, -sys.maxsize - 1))
n1 = TreeNode(1)
n2 = TreeNode(2)
n3 = TreeNode(3)
n4 = TreeNode(4)
n5 = TreeNode(5)
n6 = TreeNode(6)
n7 = TreeNode(7)
n4.left = n2
n4.right = n5
n2.right = n3
n2.left = n1
n5.right = n6
n3.right = n7
print(isValidBST(n4, sys.maxsize, -sys.maxsize - 1))
if root != parent.right:
break
root = parent
parent = parent.parent
return parent
if __name__ == "__main__":
twenty = TreeNode(20)
eight = TreeNode(20)
four = TreeNode(4)
twelve = TreeNode(12)
ten = TreeNode(10)
fourteen = TreeNode(14)
twentytwo = TreeNode(22)
# setting Parents
eight.parent = twenty
four.parent = eight
twelve.parent = eight
ten.parent = twelve
fourteen.parent = twelve
twentytwo.parent = twenty
# left right
twenty.right = twentytwo
twenty.left = eight
eight.left = four
eight.right = twelve
twelve.left = ten
twelve.right = fourteen
print(successor(fourteen).value)
return True
elif not r1 or not r2:
return False
elif r1.value != r2.value:
return False
else:
return sameTree(r1.left, r2.left) and sameTree(r1.right, r2.right)
if __name__ == "__main__":
one = TreeNode(1)
two = TreeNode(2)
three = TreeNode(3)
four = TreeNode(4)
five = TreeNode(5)
six = TreeNode(6)
seven = TreeNode(7)
eight = TreeNode(8)
one.left = two
one.right = three
two.left = four
two.right = five
three.left = six
three.right = seven
r1 = one
newOne = TreeNode(2)
newOne.left = TreeNode(4)
newOne.right = TreeNode(5)
r2 = newOne
print(checkSubtree(r1, r2))
