def test_two_items():
head = Node(1, next=Node(2))
expected = Node(2, next=Node(1))
actual = reverse_linked_list(head)
assert actual == expected
assert has_cycle(actual) is True
def test_example():
root = Node(2, left=Node(1), right=Node(3))
node1 = Node(1)
node2 = Node(3)
expected = 2
assert recursive_solution(root, node1, node2) == expected
def clone_graph(node):
if not node:
return None
node_map = dict()
queue = []
queue.append(node)
node_map[node] = Node(node.data, neighbors=[])
while queue:
current_node = queue.pop(0)
for neighbor in current_node.neighbors:
if neighbor not in node_map:
# add it to the map
node_map.update({neighbor: Node(neighbor.data, neighbors=[])})
# add the neighbor to queue
queue.append(neighbor)
# update the cloned graph
clone_of_current_node = node_map.get(current_node)
clone_of_current_node.neighbors.append(node_map.get(neighbor))
return node_map.get(node)
def test_non_valid_bst():
node3 = Node(3)
node6 = Node(6)
node4 = Node(4, left=node3, right=node6)
root = Node(5, left=Node(1), right=node4)
assert is_valid_bst(root) is False
def test_negative_nums():
nodeneg1 = Node(-1)
node4 = Node(4)
node2 = Node(2, left=nodeneg1, right=node4)
node3 = Node(3)
root = Node(-5, left=node2, right=node3)
assert find_max_sum_binary_tree(root) == 6
def test_basic_case():
node2leaf = Node(2)
node3leaf = Node(3)
node2 = Node(2, left=node2leaf, right=node3leaf)
node4 = Node(4)
root = Node(1, left=node2, right=node4)
assert find_max_sum_binary_tree(root) == 10
def build_complete_binary_tree(arr, root, index, node_count):
if index < node_count:
root = Node(arr[index])
root.left = build_complete_binary_tree(arr, root.left, 2 * index + 1,
node_count)
root.right = build_complete_binary_tree(arr, root.right, 2 * index + 2,
node_count)
return root
def iterative_solution(head):
temp = Node(-11)
temp.next = head
visited = set()
while temp:
if temp.next in visited:
return True
visited.add(temp.next)
temp = temp.next
return False
def test_balanced_binary_tree():
"""
a balanced binary tree is a tree in which the left and right subtrees of every node differ in height by no more than 1
1
/ \
2 5
\
6
"""
node5 = Node(5, right=Node(6))
root = Node(1, left=Node(2), right=node5)
assert inorder_traversal(root) == [2, 1, 5, 6]
def test_degenerate_binary_tree():
"""
a binary tree in which each parent node only has one child, essentially behaving like a linked list
1
\
2
/
3
"""
node3 = Node(3)
node2 = Node(2, left=node3)
root = Node(1, right=node2)
assert inorder_traversal(root) == [1, 3, 2]
def test_simple_case_should_be_true():
root = Node(3)
root_left = Node(9)
root_right = Node(20, left=Node(15), right=Node(7))
root.left = root_left
root.right = root_right
assert is_balanced(root) is True
def iterative_solution(lists):
"""
Merge two sorted linked lists and return it as a new list. The new list should be made by splicing together the nodes of the first two lists.
Example:
Input: 1->2->4, 1->3->4
Output: 1->1->2->3->4->4
"""
pre_root = Node(-1)
current = pre_root
while list1 and list2:
if list1.data <= list2.data:
current.next = list1
list1 = list1.next
else:
current.next = list2
list2 = list2.next
current = current.next
if not list1:
current.next = list2
else:
current.next = list1
return pre_root.next
def test_example():
head = Node(1)
temp = head
for i in range(2, 6):
temp.next = Node(i)
temp = temp.next
expected = Node(5)
new_temp = expected
for i in range(4, 0, -1):
new_temp.next = Node(i)
new_temp = new_temp.next
actual = reverse_linked_list(head)
assert actual == expected
assert has_cycle(actual) is True
def test_ancestor_on_right():
root = Node(2, left=Node(0), right=Node(4, left=Node(3), right=Node(5)))
node1 = Node(0)
node2 = Node(2)
expected = 2
assert recursive_solution(root, node1, node2) == expected
def two_pointers_solution(head, n):
ans = Node(-1, next=head)
left = ans
right = ans
for _ in range(n + 1):
right = right.next
while right:
right = right.next
left = left.next
left.next = left.next.next
return ans.next
def get_length_then_remove_nth_node(head, n):
length = 0
ans = Node(-1, next=head)
temp = ans
while temp:
length += 1
temp = temp.next
steps_to_nth_plus_one_node = length - n
temp = ans
while steps_to_nth_plus_one_node > 0:
steps_to_nth_plus_one_node -= 1
temp = temp.next
temp.next = temp.next.next
return ans.next
def test_full_binary_tree():
"""
a full binary tree is a tree in which every node has 0 or 2 children
5
/ \
42 10
/ \
6 10
/ \
3 4
"""
node10 = Node(10, left=Node(3), right=Node(4))
node42 = Node(42, left=Node(6), right=node10)
root = Node(5, left=node42, right=Node(10))
assert inorder_traversal(root) == [6, 42, 3, 10, 4, 5, 10]
def test_left_branch():
assert get_nearest_ancestor(root, 5, 19) == Node(10)
def test_typical_case():
assert get_nearest_ancestor(root, 10, 30) == Node(20)
import pytest
from src.algorithms.tree_questions.get_nearest_ancestor import get_nearest_ancestor
from src.algorithms.node import Node
def test_typical_case():
assert get_nearest_ancestor(root, 10, 30) == Node(20)
def test_left_branch():
assert get_nearest_ancestor(root, 5, 19) == Node(10)
root = Node(20)
root.left = Node(10)
root.right = Node(30)
root.left.left = Node(5)
root.left.right = Node(19)
root.right.left = Node(25)
root.right.right = Node(41)
def test_simplest_valid_bst():
root = Node(2, left=Node(1), right=Node(3))
assert is_valid_bst(root) is True
def test_same_value_nodes_should_not_be_valid_bst():
root = Node(1, left=Node(1), right=Node(1))
assert is_valid_bst(root) is False
def test_easy_case():
assert get_nearest_ancestor_v2(left_child, right_child) == Node(42)
def test_list1_is_longer():
list2 = Node(1, next=Node(2, next=Node(4)))
list1 = Node(1, next=Node(3, next=Node(4, next=Node(5))))
expected = Node(
1,
next=Node(
1,
next=Node(2,
next=Node(2,
next=Node(3,
next=Node(4,
next=Node(
4, next=Node(5)))))),
),
)
assert merge_two_lists(list1, list2) == expected
def test_unbalanced_at_right_child():
root = Node(1)
root_left = Node(2, left=Node(3), right=Node(4))
root.left = root_left
root_right = Node(5)
root_right_right = Node(6, left=Node(7))
root_right.right = root_right_right
root.right = root_right
assert is_balanced(root) is False
def test_single_node_should_be_true():
assert is_balanced(Node(2)) is True
def test_simple_case_should_be_false():
root = Node(1)
root_right = Node(2)
root_left = Node(2)
root_left.right = Node(3)
root_lower_left = Node(3, left=Node(4), right=Node(4))
root_left.left = root_lower_left
root.left = root_left
root.right = root_right
assert is_balanced(root) is False
def test_list2_is_null():
list2 = None
list1 = Node(1, next=Node(3, next=Node(4, next=Node(5))))
expected = Node(1, next=Node(3, next=Node(4, next=Node(5))))
assert merge_two_lists(list1, list2) == expected
def test_example():
list1 = Node(1, next=Node(2, next=Node(4)))
list2 = Node(1, next=Node(3, next=Node(4)))
expected = Node(
1,
next=Node(1,
next=Node(2,
next=Node(2,
next=Node(3, next=Node(4,
next=Node(4)))))),
)
assert merge_two_lists(list1, list2) == expected
def test_single_tree():
assert inorder_traversal(Node(2)) == [2]
