def reverseList(L1):
reverseL1 = LinkedList()
current = L1.head
while current != None:
reverseL1.addNode(current.value)
current = current.next
return reverseL1
def reverseList(L1): reverseL1 = LinkedList() current = L1.head while current != None: reverseL1.addNode(current.value) current = current.next return reverseL1
def __init__(self, node=None):
"""
Initialization method for a queue object
Args:
node: Node object as the first element in the queue
"""
# Create a linked-list object with FIFO structure
self.list = LinkedList(node)
def __init__(self, top=None):
"""
Create a stack by calling this initialization method
Args:
top: Node class default to None. This will be the first element in the stack
"""
# Stack can be implemented with linked-lists as well :D
self.list = LinkedList(top)
def create_linked_list(arr: list) -> LinkedList:
""" Description: Convert a python list into a custom Linked List
Params: arr { list } - python list to convert
Return: { LinkedList } - resulting linked list
"""
ll = LinkedList()
for i in arr:
ll.insert(i)
return ll
def addLists_rev(L1, L2):
p1 = L1.head
p2 = L2.head
carry = 0
linkedlist_sum = LinkedList()
while (p1 != None) or (p2 != None) or (carry != 0):
dig_sum = carry
if p1 != None:
dig_sum += p1.value
p1 = p1.next
if p2 != None:
dig_sum += p2.value
p2 = p2.next
linkedlist_sum.addNode(dig_sum%10)
carry = dig_sum/10
return linkedlist_sum
def addLists_fwd_2(L1, L2):
# compare length of linked lists and pad the shorter one with 0
l1_len = lengthOfLinkedlist(L1)
l2_len = lengthOfLinkedlist(L2)
if l1_len < l2_len:
L1 = padInFront(L1, l2_len - l1_len)
else:
L2 = padInFront(L2, l1_len - l2_len)
# Add lists
sumandcarry = addListsFwd2Helper(L1.head, L2.head)
result = LinkedList()
result.head = sumandcarry[0]
# If the carry is not 0, insert this at the front of the linked list
if sumandcarry[1] != 0:
addNodeInFront(result, sumandcarry[1])
return result
def addLists_rev(L1, L2):
p1 = L1.head
p2 = L2.head
carry = 0
linkedlist_sum = LinkedList()
while (p1 != None) or (p2 != None) or (carry != 0):
dig_sum = carry
if p1 != None:
dig_sum += p1.value
p1 = p1.next
if p2 != None:
dig_sum += p2.value
p2 = p2.next
linkedlist_sum.addNode(dig_sum % 10)
carry = dig_sum / 10
return linkedlist_sum
def reverseLinkedlist(linkedlist):
current = linkedlist.head
newlinkedlist = LinkedList()
while current != None:
addNodeInFront(newlinkedlist, current.value)
current = current.next
return newlinkedlist
def addLists_fwd_2(L1, L2):
# compare length of linked lists and pad the shorter one with 0
l1_len = lengthOfLinkedlist(L1)
l2_len = lengthOfLinkedlist(L2)
if l1_len < l2_len:
L1 = padInFront(L1, l2_len - l1_len)
else:
L2 = padInFront(L2, l1_len - l2_len)
# Add lists
sumandcarry = addListsFwd2Helper(L1.head, L2.head)
result = LinkedList()
result.head = sumandcarry[0]
# If the carry is not 0, insert this at the front of the linked list
if sumandcarry[1] != 0:
addNodeInFront(result, sumandcarry[1])
return result
class Stack:
"""
Stack class implementation
"""
def __init__(self, top=None):
"""
Create a stack by calling this initialization method
Args:
top: Node class default to None. This will be the first element in the stack
"""
# Stack can be implemented with linked-lists as well :D
self.list = LinkedList(top)
def push(self, node):
"""
This operation adds a node into a stack
Args:
node: Node class. The node is added on top of the stack in LIFO manner
Returns:
"""
# This will add an element at the head of the linked-list
self.list.append_left(node)
def pop(self):
"""
This operation will get an element from a stack in LIFO manner
Returns:
Node: top node object within the stack.
"""
# Temporary get the top element
top_element = self.list.head
# Now remove the reference to the next node by calling remove method
self.list.remove(top_element)
# Simply return the top element
return top_element
def peek(self):
"""
You can look up the top element in O(1) time with this method without popping it out
Returns:
int: integer value for the top element in the stack
"""
# Return integer value of the top element
return self.list.head.value
class Queue:
"""
Queue class implementation
"""
def __init__(self, node=None):
"""
Initialization method for a queue object
Args:
node: Node object as the first element in the queue
"""
# Create a linked-list object with FIFO structure
self.list = LinkedList(node)
def enqueue(self, node):
"""
This method will add an element into the queue
Args:
node: Node object to add into the queue
Returns:
"""
# Append the element at the tail of the list
self.list.append_right(node)
def dequeue(self):
"""
This method will get an element from the queue in FIFO manner
Returns:
"""
# Temporary get the head element
head_element = self.list.head
# Remove the head element
self.list.remove(head_element)
# Simply return the node object
return head_element
def peek(self):
"""
This method will return an integer value of the first element
Returns:
"""
# Return the head element in the queue
return self.list.head.value
def setUp(self):
"""
Setup method to initialize a linked-list
Returns:
"""
# Create test nodes
self.head_node = Node(1)
self.second_node = Node(2)
self.third_node = Node(3)
# Create test linked-list
self.list = LinkedList(self.head_node)
# Append nodes such that the list is: 1->2->3
self.list.append_right(self.second_node)
self.list.append_right(self.third_node)
def add1(self):
# say list's head is smallest digit
carrie = 0
current_node1 = l1.head
current_node2 = l2.head
res = LinkedList()
while current_node1 or current_node2:
val1 = current_node1.val if current_node1 else 0
val2 = current_node2.val if current_node2 else 0
sum_result = val1 + val2 + carrie
carrie = sum_result // 10
number = sum_result % 10
res.add_node(Node(number))
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
return res
def add1(self):
# say list's head is smallest digit
carrie = 0
current_node1 = l1.head
current_node2 = l2.head
res = LinkedList()
while current_node1 or current_node2:
val1 = current_node1.val if current_node1 else 0
val2 = current_node2.val if current_node2 else 0
sum_result = val1 + val2 + carrie
carrie = sum_result // 10
number = sum_result % 10
res.add_node(Node(number))
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
return res
def devide_by(self, k):
smaller = LinkedList()
larger = LinkedList()
current_node = ll.head
while current_node:
inserted_node = Node(current_node.val) # 参照渡すのを防ぐため。
if current_node.val < k:
last_smaller_node = inserted_node
smaller.add_node(inserted_node)
else:
larger.add_node(inserted_node)
current_node = current_node.next
last_smaller_node.next = larger.head
return smaller
def create_lists_and_get_height(self, root):
if root == None:
return 0
if root.height != None:
return height
else:
root.height = max(self.create_lists_and_get_height(root.left),
self.create_lists_and_get_height(root.right)) + 1
if not root.height in self.lists:
self.lists[root.height] = LinkedList()
self.lists[root.height].add_node(Node(root.value))
return root.height
def partition_list(l, x):
less = LinkedList()
greater = LinkedList()
curr = l.head
while curr.next != None:
if curr.value < x:
less.add_node(curr.value)
else:
greater.add_node(curr.value)
curr = curr.next
less.tail.next = greater.head
less.tail = greater.tail
return less
def devide_by(self, k):
smaller = LinkedList()
larger = LinkedList()
current_node = ll.head
while current_node:
inserted_node = Node(current_node.val) # 参照渡すのを防ぐため。
if current_node.val < k:
last_smaller_node = inserted_node
smaller.add_node(inserted_node)
else:
larger.add_node(inserted_node)
current_node = current_node.next
last_smaller_node.next = larger.head
return smaller
def lengthOfLinkedlist(linkedlist):
length = 0
current = linkedlist.head
while current != None:
length += 1
current = current.next
return length
# -------------------test------------------
L1 = randomLinkedList(3, 3, 4)
print "L2:", L1
print "isPalindrome_iter: ", isPalindrome_iter(L1)
print "isPalindrome_recu: ", isPalindrome_recu(L1)
L2 = LinkedList()
for i in range(1,4):
L2.addNode(i)
for i in range(3, 0, -1):
L2.addNode(i)
print "L3:", L2
print "isPalindrome_iter: ", isPalindrome_iter(L2)
print "isPalindrome_recu: ", isPalindrome_recu(L2)
# Another method: reverse the list and check if they are the same
def isPalindrome(L1):
reverseL1 = reverseList(L1)
return isEqual(L1, reverseL1)
def reverseList(L1):
reverseL1 = LinkedList()
class TestLinkedList(TestCase):
"""
Unit test implementation for LinkedList class
"""
def setUp(self):
"""
Setup method to initialize a linked-list
Returns:
"""
# Create test nodes
self.head_node = Node(1)
self.second_node = Node(2)
self.third_node = Node(3)
# Create test linked-list
self.list = LinkedList(self.head_node)
# Append nodes such that the list is: 1->2->3
self.list.append_right(self.second_node)
self.list.append_right(self.third_node)
def test_append_right(self):
"""
Unit-test for append method in LinkedList class
Returns:
"""
# Append new node with value of 4 such that: 1->2->3->4
current = self.list.head
new_node = Node(4)
self.list.append_right(new_node)
# Check if all values are the same as 1 to 4
for i in range(1, 5):
self.assertEqual(current.value, i)
current = current.next
# Check if the tail element is the new_node
self.assertEqual(new_node.value, self.list.tail.value)
def test_append_left(self):
"""
Unit-test for appending an element as the new head of the
linked-list
Returns:
"""
# Create potential head node
new_node = Node(0)
# Then call the function to set it as the head node
self.list.append_left(new_node)
# Create current node to traverse
current = self.list.head
# Traverse the list, then check the values
for i in range(4):
self.assertEqual(current.value, i)
current = current.next
def test_insert(self):
"""
Unit-test for insert method in LinkedList class
Returns:
"""
# Insert node as the new head: 0->1->2->3
new_node = Node(0)
self.list.insert(new_node, 1)
# Check if correctly inserted or not
self.assertEqual(self.list.head.value, new_node.value)
self.assertEqual(self.list.tail.value, self.third_node.value)
# Insert in the middle of the list: 0->1->5->2->3
new_node = Node(5)
self.list.insert(new_node, 3)
# Check if correctly inserted or not
self.assertEqual(self.list.head.next.next.value, new_node.value)
# Insert node as the tail of the list: 0->1->5->2->3->9
new_node = Node(9)
self.list.insert(new_node, 6)
# Check if correctly inserted or not
self.assertEqual(self.list.tail.value, new_node.value)
# Get temporary access to the list's head
current = self.list.head
# Get the tail node from the list
while current.next:
current = current.next
# Check if correctly inserted or not
self.assertEqual(current.value, new_node.value)
self.assertEqual(current.value, self.list.tail.value)
def test_search(self):
"""
Unit-test for search method in LinkedList class
Returns:
"""
# Check for the head node
head_node = self.list.search(1)
self.assertEqual(head_node, self.head_node)
# Check for the second node
second_node = self.list.search(2)
self.assertEqual(second_node, self.second_node)
# Check for the third node
third_node = self.list.search(3)
self.assertEqual(third_node, self.third_node)
def test_remove(self):
"""
Unit-test for remove method in LinkedList class
Returns:
"""
# Remove the first node in the list: 2->3
self.list.remove(self.head_node)
current = self.list.head
# Check for all nodes which range from 2 to 3
for i in range(2, 4):
self.assertEqual(current.value, i)
current = current.next
# Check is list's head is updated properly
self.assertEqual(self.list.head, self.second_node)
self.assertEqual(self.list.tail, self.third_node)
# Remove the second node in the list: 3
self.list.remove(self.second_node)
self.assertEqual(self.list.head.value, self.third_node.value)
self.assertEqual(self.list.tail, self.third_node)
# Remove the third node in the list, so the head should be None
self.list.remove(self.third_node)
self.assertIsNone(self.list.head)
self.assertIsNone(self.list.tail)
def test_lookup(self):
"""
Unit-test for lookup operation in LinkedList object
Returns:
"""
for i in range(1, 4):
self.assertEqual(self.list.lookup(i), i)
def tearDown(self):
"""
if fast == None or fast.next == None:
return None
# Move one runner to head. Making them move at same pace, they will meet at the beginning of the loop
fast = linkedlist.head
while fast != slow:
slow = slow.next
fast = fast.next
return fast
# -----------------test------------------
nodes_number = 100
nodes_in_loop = 20
L = LinkedList()
current = L.head
store = [] # store nodes to help creating loop
# Create a linked list
for i in range(nodes_number):
L.addNode(i)
current = L.head if i == 0 else current.next
store.append(current)
# Creat loop
current.next = None if nodes_in_loop <= 0 else store[nodes_number -
nodes_in_loop]
beginning = findBeginning(L)
print beginning # 80
def __init__(self, ll):
self.ll = ll
def devide_by(self, k):
smaller = LinkedList()
larger = LinkedList()
current_node = ll.head
while current_node:
inserted_node = Node(current_node.val) # 参照渡すのを防ぐため。
if current_node.val < k:
last_smaller_node = inserted_node
smaller.add_node(inserted_node)
else:
larger.add_node(inserted_node)
current_node = current_node.next
last_smaller_node.next = larger.head
return smaller
ll = LinkedList()
ll.add_node(Node(3))
ll.add_node(Node(5))
ll.add_node(Node(4))
ll.add_node(Node(8))
ll.add_node(Node(6))
ll.add_node(Node(1))
dh = DeviderHelper(ll)
print 'Defo: ' + str(ll)
devided_ll = dh.devide_by(7)
print 'Result: ' + str(devided_ll)
# NOTE: Pythonでmutableなオブジェクトを渡している時は参照渡していると思って。
class AdditonHelper(object):
def __init__(self, l1, l2):
self.l1 = l1
self.l2 = l2
def add1(self):
# say list's head is smallest digit
carrie = 0
current_node1 = l1.head
current_node2 = l2.head
res = LinkedList()
while current_node1 or current_node2:
val1 = current_node1.val if current_node1 else 0
val2 = current_node2.val if current_node2 else 0
sum_result = val1 + val2 + carrie
carrie = sum_result // 10
number = sum_result % 10
res.add_node(Node(number))
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
return res
def add2(self):
# say list's head is largest digit
self.res = LinkedList()
self.__compensate_zeros_to_shorter()
self.__add_recursively(self.l1.head, self.l2.head)
return self.res
def __add_recursively(self, node1, node2):
val1 = node1.val
val2 = node2.val
if bool(node1) != bool(node2):
raise Exception('Different length lists!')
if node1.next == None and node2.next == None:
sum_res = val1 + val2
else:
sum_res = val1 + val2 + self.__add_recursively(
node1.next, node2.next)
number = sum_res % 10
self.res.add_node(Node(number))
carrie = sum_res // 10
return carrie
def __compensate_zeros_to_shorter(self):
self.__set_shorter_and_longer()
for i in range(self.diff):
node = Node(0)
node.next = self.shorter_list.head
self.shorter_list.head = node
def __set_shorter_and_longer(self):
current_node1 = self.l1.head
current_node2 = self.l2.head
self.diff = 0
while current_node1 or current_node2:
if bool(current_node1) != bool(current_node2):
self.shorter_list = self.l2 if current_node1 else self.l1
self.diff += 1
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
if self.diff == 0:
self.shorter_list = self.l1
node = Node(0)
node.next = self.shorter_list.head
self.shorter_list.head = node
def __set_shorter_and_longer(self):
current_node1 = self.l1.head
current_node2 = self.l2.head
self.diff = 0
while current_node1 or current_node2:
if bool(current_node1) != bool(current_node2):
self.shorter_list = self.l2 if current_node1 else self.l1
self.diff += 1
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
if self.diff == 0:
self.shorter_list = self.l1
l1 = LinkedList()
l1.add_node(Node(7))
l1.add_node(Node(3))
l1.add_node(Node(6))
l1.add_node(Node(8))
l2 = LinkedList()
l2.add_node(Node(6))
l2.add_node(Node(2))
ah = AdditonHelper(l1, l2)
res = ah.add2()
print res
class AdditonHelper(object):
def __init__(self, l1, l2):
self.l1 = l1
self.l2 = l2
def add1(self):
# say list's head is smallest digit
carrie = 0
current_node1 = l1.head
current_node2 = l2.head
res = LinkedList()
while current_node1 or current_node2:
val1 = current_node1.val if current_node1 else 0
val2 = current_node2.val if current_node2 else 0
sum_result = val1 + val2 + carrie
carrie = sum_result // 10
number = sum_result % 10
res.add_node(Node(number))
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
return res
def add2(self):
# say list's head is largest digit
self.res = LinkedList()
self.__compensate_zeros_to_shorter()
self.__add_recursively(self.l1.head, self.l2.head)
return self.res
def __add_recursively(self, node1, node2):
val1 = node1.val
val2 = node2.val
if bool(node1) != bool(node2):
raise Exception('Different length lists!')
if node1.next == None and node2.next == None:
sum_res = val1 + val2
else:
sum_res = val1 + val2 + self.__add_recursively(node1.next, node2.next)
number = sum_res % 10
self.res.add_node(Node(number))
carrie = sum_res // 10
return carrie
def __compensate_zeros_to_shorter(self):
self.__set_shorter_and_longer()
for i in range(self.diff):
node = Node(0)
node.next = self.shorter_list.head
self.shorter_list.head = node
def __set_shorter_and_longer(self):
current_node1 = self.l1.head
current_node2 = self.l2.head
self.diff = 0
while current_node1 or current_node2:
if bool(current_node1) != bool(current_node2):
self.shorter_list = self.l2 if current_node1 else self.l1
self.diff += 1
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
if self.diff == 0:
self.shorter_list = self.l1
def add2(self):
# say list's head is largest digit
self.res = LinkedList()
self.__compensate_zeros_to_shorter()
self.__add_recursively(self.l1.head, self.l2.head)
return self.res
def padInFront(linkedlist, number):
padlist = LinkedList()
padlist.head = linkedlist.head
for i in range(number):
addNodeInFront(padlist, 0)
return padlist
def randomLinkedList(length, min, max):
linkedlist = LinkedList()
for i in range(length):
value = randint(min, max)
linkedlist.addNode(value)
return linkedlist
def padInFront(linkedlist, number):
padlist = LinkedList()
padlist.head = linkedlist.head
for i in range(number):
addNodeInFront(padlist, 0)
return padlist
node.next = self.shorter_list.head
self.shorter_list.head = node
def __set_shorter_and_longer(self):
current_node1 = self.l1.head
current_node2 = self.l2.head
self.diff = 0
while current_node1 or current_node2:
if bool(current_node1) != bool(current_node2):
self.shorter_list = self.l2 if current_node1 else self.l1
self.diff += 1
current_node1 = current_node1.next if current_node1 else None
current_node2 = current_node2.next if current_node2 else None
if self.diff == 0:
self.shorter_list = self.l1
l1 = LinkedList()
l1.add_node(Node(7))
l1.add_node(Node(3))
l1.add_node(Node(6))
l1.add_node(Node(8))
l2 = LinkedList()
l2.add_node(Node(6))
l2.add_node(Node(2))
ah = AdditonHelper(l1, l2)
res = ah.add2()
print res
def add2(self):
# say list's head is largest digit
self.res = LinkedList()
self.__compensate_zeros_to_shorter()
self.__add_recursively(self.l1.head, self.l2.head)
return self.res
return None
# Move one runner to head. Making them move at same pace, they will meet at the beginning of the loop
fast = linkedlist.head
while fast != slow:
slow = slow.next
fast = fast.next
return fast
# -----------------test------------------
nodes_number = 100
nodes_in_loop = 20
L = LinkedList()
current = L.head
store = [] # store nodes to help creating loop
# Create a linked list
for i in range(nodes_number):
L.addNode(i)
current = L.head if i==0 else current.next
store.append(current)
# Creat loop
current.next = None if nodes_in_loop <= 0 else store[nodes_number - nodes_in_loop]
beginning = findBeginning(L)
print beginning # 80
def devide_by(self, k):
smaller = LinkedList()
larger = LinkedList()
current_node = ll.head
while current_node:
inserted_node = Node(current_node.val) # 参照渡すのを防ぐため。
if current_node.val < k:
last_smaller_node = inserted_node
smaller.add_node(inserted_node)
else:
larger.add_node(inserted_node)
current_node = current_node.next
last_smaller_node.next = larger.head
return smaller
ll = LinkedList()
ll.add_node(Node(3))
ll.add_node(Node(5))
ll.add_node(Node(4))
ll.add_node(Node(8))
ll.add_node(Node(6))
ll.add_node(Node(1))
dh = DeviderHelper(ll)
print 'Defo: ' + str(ll)
devided_ll = dh.devide_by(7)
print 'Result: ' + str(devided_ll)
# NOTE: Pythonでmutableなオブジェクトを渡している時は参照渡していると思って。
from classes.LinkedList import *
def isPalindrome(linkedlist):
if linkedlist.head == None:
return None
fast = linkedlist.head
slow = linkedlist.head
firsthalf = []
while fast != None and fast.next != None:
firsthalf.append(slow.value)
slow = slow.next
fast = fast.next.next
if fast != None:
slow = slow.next
while slow != None:
if firsthalf.pop() != slow.value:
return False
else:
slow = slow.next
return True
L1 = randomLinkedList(3, 3, 4)
print "L2:", L1
print "Is Palindrome? ", isPalindrome(L1)
L2 = LinkedList()
for i in range(1,4):
L2.addNode(i)
for i in range(3, 0, -1):
L2.addNode(i)
print "L3:", L2
print "Is Palindrome? ", isPalindrome(L2)
