Python3 Solutions to LeetCode's "Top 100 Liked Questions"
The type of code that might be useful in a coding interview. Or if John Travolta with a goatee needs you to hack the DoD in less than 60 seconds at a nightclub, that kind of stuff.
Uploaded as I answer them. Run as:
$ git clone [email protected]:JacopoPan/leetcode-top100-liked-questions.git
$ cd leetcode-top100-liked-questions
$ python3 solutions/123.\ Problem\ Name.py# import pdb; pdb.set_trace() # [s]tep into function; [l]ist 11 lines; [w]here in stack; # [p]rint (exp/var);
# [b]reak at line no; [c]ontinue to break; [q]uit; [h]elp
from functools import lru_cache # cache since Python 3.9
from typing import List, Optional
class Problem:
def __init__(self):
pass
@lru_cache
def methodZero(self, n: int=0) -> str:
return ''
def methodOne(self, argName: List[int]) -> Optional[int]:
return -1
def main():
sol = Problem()
ans = sol.methodOne([0,0,0])
assert ans == -1
print(ans)
if __name__ == "__main__":
print('Template')
main()class TreeNode:
def __init__(self, val=0, left=None, right=None):
self.val = val
self.left = left
self.right = right
class ListNode:
def __init__(self, x, next=None):
self.val = x
self.next = nextlist_root = ListNode(1, ListNode(2, ListNode(3, ListNode(4, ListNode(5)))))
def traverse_list(list_root):
while list_root:
print(list_root.val)
list_root = list_root.next
if __name__ == "__main__":
print('Traverse List')
traverse_list(list_root)list_root = ListNode(1, ListNode(2, ListNode(3, ListNode(4, ListNode(5)))))
def traverse_list_runner(list_root):
if list_root:
runner = list_root.next
while list_root:
print(list_root.val)
if runner:
print(runner.val)
if runner:
list_root = runner.next
runner = list_root.next
else:
list_root = None
if __name__ == "__main__":
print('Traverse List with Runner')
traverse_list_runner(list_root)list_root = ListNode(1, ListNode(2, ListNode(3, ListNode(4, ListNode(5)))))
def reverse_list(list_root):
prev = None
nxt = list_root
while nxt:
temp = nxt
nxt = nxt.next
temp.next = prev
prev = temp
return prev
if __name__ == "__main__":
print('Reverse List')
reverse = reverse_list(list_root)
while reverse:
print(reverse.val)
reverse = reverse.nexttree_root = TreeNode(1, TreeNode(2, TreeNode(3, TreeNode(4), TreeNode(5, TreeNode(8), TreeNode(9))), None), TreeNode(6, None, TreeNode(7)))
def tree_dfs(root):
if root: # preorder: this, l, r / inorder l, this, r / postorder l, r, this
print(root.val)
tree_dfs(root.left)
tree_dfs(root.right)
if __name__ == "__main__":
print('Tree DFS')
tree_dfs(tree_root)from collections import deque
tree_root = TreeNode(1, TreeNode(2, TreeNode(3, TreeNode(4), TreeNode(5, TreeNode(8), TreeNode(9))), None), TreeNode(6, None, TreeNode(7)))
def tree_bfs(root):
if root:
queue = deque([root])
while queue:
node = queue.popleft()
if node:
print(node.val)
queue.append(node.left)
queue.append(node.right)
if __name__ == "__main__":
print('Tree BFS')
tree_bfs(tree_root)graph = {
'A' : ['B','C'],
'B' : ['D', 'E'],
'C' : ['F'],
'D' : [],
'E' : ['F'],
'F' : []
}
visited = set()
def graph_dfs(graph, node, visited):
if node not in visited:
print(node)
visited.add(node)
for neighbour in graph[node]:
graph_dfs(graph, neighbour, visited)
if __name__ == "__main__":
print('Graph DFS')
graph_dfs(graph, 'A', visited)from collections import deque
graph = {
'A' : ['B','C'],
'B' : ['D', 'E'],
'C' : ['F'],
'D' : [],
'E' : ['F'],
'F' : []
}
visited = set()
queue = deque([])
def graph_bfs(graph, node, visited):
visited.add(node)
queue.append(node)
while queue:
node = queue.popleft()
print(node)
for neighbour in graph[node]:
if neighbour not in visited:
visited.add(neighbour)
queue.append(neighbour)
if __name__ == "__main__":
print('Graph BFS')
graph_bfs(graph, 'A', visited)graph = {
'A' : ['B','C'],
'B' : ['D', 'E'],
'C' : ['F'],
'D' : [],
'E' : ['F'], # ['F', 'A'] # cycle
'F' : []
}
def topological_sort(graph):
indegrees = {node : 0 for node in graph}
for node in graph:
for neighbor in graph[node]:
indegrees[neighbor] += 1
nodes_with_no_incoming_edges = []
for node in graph:
if indegrees[node] == 0:
nodes_with_no_incoming_edges.append(node)
topological_ordering = []
while nodes_with_no_incoming_edges:
node = nodes_with_no_incoming_edges.pop()
topological_ordering.append(node)
for neighbor in graph[node]:
indegrees[neighbor] -= 1
if indegrees[neighbor] == 0:
nodes_with_no_incoming_edges.append(neighbor)
if len(topological_ordering) == len(graph):
print(topological_ordering)
else:
print("Graph has a cycle: no topological ordering exists.")
if __name__ == "__main__":
print('Topological Sort')
topological_sort(graph)grid = [[0,1,1],[0,0,1],[0,0,2]]
visited = set()
ans = 9999.
def matrix_dfs(grid, i, j, visited, steps):
if i<0 or j<0 or i>=len(grid) or j>=len(grid[0]):
return
if (i,j) in visited or grid[i][j] == 1:
return
if grid[i][j] == 2:
global ans
ans = min(ans, steps)
visited.add((i, j))
matrix_dfs(grid, i+1, j, visited, steps+1)
matrix_dfs(grid, i-1, j, visited, steps+1)
matrix_dfs(grid, i, j+1, visited, steps+1)
matrix_dfs(grid, i, j-1, visited, steps+1)
if __name__ == "__main__":
print('Matrix DFS')
matrix_dfs(grid, 0, 0, visited, -1)
print('Shortest path: ', ans)from collections import deque
grid = [[0,1,1],[0,1,1],[0,0,2]]
visited = set()
queue = deque([])
def matrix_bfs(grid, visited):
while queue:
x, y, dist = queue.popleft()
if x<0 or y<0 or x>=len(grid) or y>=len(grid[0]):
continue
if (x,y) in visited or grid[x][y] == 1:
continue
if grid[x][y] == 2:
return dist
visited.add((x, y))
queue.append((x+1, y, dist+1))
queue.append((x-1, y, dist+1))
queue.append((x, y+1, dist+1))
queue.append((x, y-1, dist+1))
return None
if __name__ == "__main__":
print('Matrix BFS')
queue.append((0,0,0))
print('Shortest path: ', matrix_bfs(grid, visited))unsorted_list = [3, 7, 1, 3, 6, 3, 1, 9]
def merge_sorted(list_one, list_two):
list_one_index = 0
list_two_index = 0
merged_list = []
while list_one_index < len(list_one) and list_two_index < len(list_two):
if list_one[list_one_index] <= list_two[list_two_index]:
merged_list.append(list_one[list_one_index])
list_one_index += 1
else:
merged_list.append(list_two[list_two_index])
list_two_index += 1
while list_one_index < len(list_one):
merged_list.append(list_one[list_one_index])
list_one_index += 1
while list_two_index < len(list_two):
merged_list.append(list_two[list_two_index])
list_two_index += 1
return merged_list
def merge_sort(unsorted_list):
if len(unsorted_list) <= 1:
return unsorted_list
left = unsorted_list[:len(unsorted_list) // 2]
right = unsorted_list[len(unsorted_list) // 2:]
left_sorted = merge_sort(left)
right_sorted = merge_sort(right)
ans = merge_sorted(left_sorted, right_sorted)
return ans
if __name__ == "__main__":
print('Merge Sort')
ans = merge_sort(unsorted_list)
print(ans)unsorted_list = [3, 7, 1, 3, 6, 3, 1, 9]
def partition(unsorted_list, start_index, end_index):
pivot = unsorted_list[end_index]
left_index = start_index
right_index = end_index - 1
while left_index <= right_index:
while left_index <= end_index and unsorted_list[left_index] < pivot:
left_index += 1
while right_index >= start_index and unsorted_list[right_index] >= pivot:
right_index -= 1
if left_index < right_index:
temp = unsorted_list[right_index]
unsorted_list[right_index] = unsorted_list[left_index]
unsorted_list[left_index] = temp
else:
temp = unsorted_list[end_index]
unsorted_list[end_index] = unsorted_list[left_index]
unsorted_list[left_index] = temp
return left_index
def quick_sort(unsorted_list, start_index=0, end_index=None):
if end_index == None:
end_index = len(unsorted_list)-1
if (start_index >= end_index):
return
pivot_index = partition(unsorted_list, start_index, end_index)
quick_sort(unsorted_list, start_index, pivot_index - 1)
quick_sort(unsorted_list, pivot_index + 1, end_index)
if __name__ == "__main__":
print('Quick Sort')
quick_sort(unsorted_list)
print(unsorted_list)from heapq import heappush, heappop, heapify
unsorted_list = [3, 7, 1, 3, 6, 3, 1, 9]
def heap():
heapify(unsorted_list)
print(unsorted_list)
heappush(unsorted_list, 2)
print(unsorted_list)
val = heappop(unsorted_list)
print(val, unsorted_list)
# other methods: heapq.heappushpop(heap, item); heapq.heapreplace(heap, item);
# heapq.merge(); heapq.nlargest(n); heapq.nsmallest(n)
if __name__ == "__main__":
print('Heap')
heap()from heapq import heappush, heappop, heapify
points = [[2,-3],[-17,-8],[13,8],[-17,-15]]
def msp(points):
manhattan = lambda p1, p2: abs(p1[0]-p2[0]) + abs(p1[1]-p2[1])
edges = []
n = len(points)
for i in range(n):
for j in range(i+1,n):
edges.append((manhattan(points[i],points[j]),i,j))
heapify(edges)
visited = set()
ans = 0
while edges and len(visited) < n:
added = False
temp = []
while not added:
e = heappop(edges)
added = True
if not visited:
ans += e[0]
visited.add(e[1])
visited.add(e[2])
elif e[1] not in visited and e[2] in visited:
ans += e[0]
visited.add(e[1])
elif e[2] not in visited and e[1] in visited:
ans += e[0]
visited.add(e[2])
else:
temp.append(e)
added = False
for e in temp:
heappush(edges, e)
return ans
if __name__ == "__main__":
print('Minumum Spanning Tree')
print('Cost: ', msp(points))from heapq import heapify, heappop, heappush
from collections import defaultdict
costs = [[2,1,1],[2,3,1],[3,4,1]]
def dijkstra(costs, num_nodes, source):
graph = defaultdict(list)
for (node, neigh, cost) in costs:
graph[node].append((neigh, cost))
priority_queue = [(0, source)]
heapify(priority_queue)
shortest_path = {}
while priority_queue:
cost, node = heappop(priority_queue)
if node not in shortest_path:
shortest_path[node] = cost
for neigh, neigh_cost in graph[node]:
heappush(priority_queue, (cost + neigh_cost, neigh))
if len(shortest_path) == num_nodes:
return max(shortest_path.values())
else:
return -1
if __name__ == "__main__":
print('Dijkstra')
print('Delay: ', dijkstra(costs, 4, 2))word_list = ['app', 'apple', 'oath', 'pea', 'peanut']
def trie(words):
trie={}
for word in words:
temp=trie
for character in word:
if character not in temp:
temp[character]={}
temp=temp[character]
temp['#']='%'
return trie
if __name__ == "__main__":
print('Trie')
trie = trie(word_list)
print(trie)sorted_arr = [2, 3, 4, 10, 40]
target = 10
def binary_search(arr, x):
low = 0
high = len(arr)-1
while low < high:
mid = (high + low)//2
if arr[mid] < x:
low = mid + 1
elif arr[mid] >= x:
high = mid
return low
if __name__ == "__main__":
print('Binary Search')
print('Index: ', binary_search(sorted_arr, target))barriers = [1, 8, 9, 4, 11, 15, 3, 5]
def two_pointers(barriers):
i = 0
j = len(barriers)-1
max_water = (j-i)*min(barriers[i],barriers[j])
while i < j:
if barriers[i] < barriers[j]:
i += 1
else:
j -= 1
max_water = max(max_water, (j-i)*min(barriers[i],barriers[j]))
return max_water
if __name__ == "__main__":
print('Two Pointers')
print('Max water: ', two_pointers(barriers))cache = {}
def fibonacci(n):
if n <= 1:
return n
else:
if n in cache.keys():
return cache[n]
else:
ans = fibonacci(n-1) + fibonacci(n-2)
cache[n] = ans
return ans
if __name__ == "__main__":
print('Dynamic Programming: Top Down Fibonacci with Memoization')
ans = fibonacci(60)
print(ans)def perms(candidates):
if len(candidates) <=1:
return [candidates]
else:
ans = []
prev = perms(candidates[1:])
for p in prev:
for i in range(len(candidates)):
ans.append(p[:i] + candidates[0:1] + p[i:])
return ans
def combs(candidates):
if not candidates:
return [[]]
else:
ans = []
for c in combs(candidates[1:]):
ans.append(c)
ans.append(c+[candidates[0]])
return ans
if __name__ == "__main__":
print('Permutations and Combinations')
ans = perms([0,1,2])
print(ans)
ans = combs([0,1,2])
print(ans)from collections import deque
def lists():
working_list = []
print(working_list)
working_list.append(1)
print(working_list)
working_list.extend([2, 4])
print(working_list)
working_list.insert(2, 3)
print(working_list)
working_list.remove(3)
print(working_list)
working_list.pop()
print(working_list)
working_list.pop(0)
print(working_list)
del working_list[0]
print(working_list)
working_list = [1, 2, 3, 4]
idx = working_list.index(3)
print(idx, working_list)
count = working_list.count(3)
print(count, working_list)
working_list.sort(reverse=True)
print(working_list)
working_list.reverse()
print(working_list)
queue = deque([1, 2, 3, 4])
print(queue)
queue.popleft()
print(queue)
if __name__ == "__main__":
print('Lists')
lists()a = [1, 2, 3, 4, 5, 6, 7, 8]
start = 2
stop = 5
step = 1
def slicing():
print(a)
# Basic
print(a[start:stop]) # items start through stop-1
print(a[start:]) # items start through the rest of the array
print(a[:stop]) # items from the beginning through stop-1
print(a[:]) # a copy of the whole array
print(a[start:stop:step]) # start through not past stop, by step
# Negative index
print(a[-1]) # last item in the array
print(a[-2:]) # last two items in the array
print(a[:-2]) # everything except the last two items
# Negative step
print(a[::-1]) # all items in the array, reversed
print(a[1::-1]) # the first two items, reversed
print(a[:-3:-1]) # the last two items, reversed
print(a[-3::-1]) # everything except the last two items, reversed
if __name__ == "__main__":
print('Slicing')
slicing()from functools import reduce
from collections import defaultdict
from collections import deque
def syntax():
# Map
items = [1, 2, 3, 4, 5]
squared = list(map(lambda x: x**2, items))
print(items, 'maps to', squared)
# Filter
items = list(range(-5, 5))
less_than_zero = list(filter(lambda x: x < 0, items))
print(items, 'filtered to', less_than_zero)
# Reduce
items = [1, 2, 3, 4]
product = reduce((lambda x, y: x * y), items)
print(items, 'reduced to', product)
# Ternary
value_if_true, condition, value_if_false = 1, True, -1
assigned = value_if_true if condition else value_if_false
print('assigned is', assigned, 'because', condition)
# Set
items = [1, 1, 3, 3]
set_of_items = set(items)
print(set_of_items, 'is set of', items)
# Defaultdict
# Defaultdict
def_dict = defaultdict(list)
def_dict['key'].append(1)
print(def_dict)
def_dict = defaultdict(dict)
def_dict['new_key']['second_key'] = 0
print(def_dict)
# Queue
queue = deque(list(range(5)))
val = queue.popleft()
print(val, 'popped on the left and rest of the queue', queue)
# Decorator
def decor(func):
def wrapping():
print("Work before func()")
func()
print("Work after func()")
return wrapping
@decor
def function_to_decor():
print("Decorated work")
function_to_decor()
# Enumerate
items = ['apple', 'banana', 'grapes', 'pear']
for idx, elem in enumerate(items):
print(idx, elem)
# Zip
first_name = ['Joe','Earnst','Thomas','Martin','Charles']
last_name = ['Schmoe','Ehlmann','Fischer','Walter','Rogan','Green']
age = [23, 65, 11, 36, 83]
zipped = list(zip(first_name,last_name, age))
first_name, last_name, age = list(zip(*zipped))
print(zipped, first_name, last_name, age)
# Comprehension
input_list = [1,2,3,4,5,6,7,8,9,10]
new_list = [x**2 for x in input_list if x%2 == 0]
print(input_list, 'to', new_list)
input_dict = {'a': 4, 'b': 6, 'c': 8}
new_dict = {k+'_new': v//2 for k, v in input_dict.items() if v > 5}
print(input_dict, 'to', new_dict)
# Lambda
list_of_pairs = [(1, 2), (4, 1), (9, 10), (13, -3)]
list_of_pairs.sort(key=lambda x: x[1])
print(list_of_pairs)
if __name__ == "__main__":
print('Syntax Tips')
syntax()