Python/data_structures/linked_list/singly_linked_list.py
Hanif Ali 4c37eb7d07 Improved on Singly Linked List Programs (#1558)
* Improved Singly Linked List
Added String Representations of Nodes and Linked Lists
Added support for indexing and changing of Node data using indices.

* Added a few comments to Linked Lists

* Reformatted to conform to PEP8

* Added from_sequence.py
Convert a Python List to Linked List comprising of Nodes and return head.

* Added print_reverse.py
Recursive program to print the elements of a Linked List in reverse.

* Change 'is not None' for more Pythonicness
2019-11-10 09:47:04 +01:00

154 lines
4.5 KiB
Python

class Node: # create a Node
def __init__(self, data):
self.data = data # given data
self.next = None # given next to None
def __repr__(self): # String Representation of a Node
return f"<Node: {self.data}>"
class LinkedList:
def __init__(self):
self.head = None # Initialize head to None
def insert_tail(self, data):
if self.head is None:
self.insert_head(data) # If this is first node, call insert_head
else:
temp = self.head
while temp.next: # traverse to last node
temp = temp.next
temp.next = Node(data) # create node & link to tail
def insert_head(self, data):
newNod = Node(data) # create a new node
if self.head:
newNod.next = self.head # link newNode to head
self.head = newNod # make NewNode as head
def printList(self): # print every node data
temp = self.head
while temp:
print(temp.data)
temp = temp.next
def delete_head(self): # delete from head
temp = self.head
if self.head:
self.head = self.head.next
temp.next = None
return temp
def delete_tail(self): # delete from tail
temp = self.head
if self.head:
if self.head.next is None: # if head is the only Node in the Linked List
self.head = None
else:
while temp.next.next: # find the 2nd last element
temp = temp.next
temp.next, temp = (
None,
temp.next,
) # (2nd last element).next = None and temp = last element
return temp
def isEmpty(self):
return self.head is None # Return if head is none
def reverse(self):
prev = None
current = self.head
while current:
# Store the current node's next node.
next_node = current.next
# Make the current node's next point backwards
current.next = prev
# Make the previous node be the current node
prev = current
# Make the current node the next node (to progress iteration)
current = next_node
# Return prev in order to put the head at the end
self.head = prev
def __repr__(self): # String representation/visualization of a Linked Lists
current = self.head
string_repr = ""
while current:
string_repr += f"{current} ---> "
current = current.next
# END represents end of the LinkedList
string_repr += "END"
return string_repr
# Indexing Support. Used to get a node at particaular position
def __getitem__(self, index):
current = self.head
# If LinkedList is Empty
if current is None:
raise IndexError("The Linked List is empty")
# Move Forward 'index' times
for _ in range(index):
# If the LinkedList ends before reaching specified node
if current.next is None:
raise IndexError("Index out of range.")
current = current.next
return current
# Used to change the data of a particular node
def __setitem__(self, index, data):
current = self.head
# If list is empty
if current is None:
raise IndexError("The Linked List is empty")
for i in range(index):
if current.next is None:
raise IndexError("Index out of range.")
current = current.next
current.data = data
def main():
A = LinkedList()
print("Inserting 1st at head")
a1 = input()
A.insert_head(a1)
print("Inserting 2nd at head")
a2 = input()
A.insert_head(a2)
print("\nPrint List : ")
A.printList()
print("\nInserting 1st at Tail")
a3 = input()
A.insert_tail(a3)
print("Inserting 2nd at Tail")
a4 = input()
A.insert_tail(a4)
print("\nPrint List : ")
A.printList()
print("\nDelete head")
A.delete_head()
print("Delete Tail")
A.delete_tail()
print("\nPrint List : ")
A.printList()
print("\nReverse Linked List")
A.reverse()
print("\nPrint List : ")
A.printList()
print("\nString Representation of Linked List:")
print(A)
print("\n Reading/Changing Node Data using Indexing:")
print(f"Element at Position 1: {A[1]}")
p1 = input("Enter New Value: ")
A[1] = p1
print("New List:")
print(A)
if __name__ == "__main__":
main()