2 of 3 explained the question better, corrected spelling, and asked for a simpler solution for a beginner.

How do I implement a append in linear and constant time on a linked list in Python?

A textbook exercise I am working on asks me to implement the append method of a linked list on Python. It assumes my first try will be done in linear time. It then asks me to add an instance variable to my LinkedList class that will help me turn my append method into constant time. I'm looking for a solution that is simple enough for a beginner. My linear time solution is as follows:

First I create a Node class:

class Node:
    """
    A node class that is used to implement a linked list object.
    The node contains a data field, aka the item in the node and a
    reference to the next node.
    """
    def __init__(self, init_data):
        self.data = init_data
        self.next = None

    def get_data(self):
        return self.data

    def get_next(self):
        return self.next

    def set_data(self, new_data):
        self.data = new_data

    def set_next(self, new_next):
        self.next= new_next

I then implement append in linear time:

from node_class import Node

class UnorderedList:
    """
    An unordered list class built from a collection of nodes.
    """
    
    def __init__(self):
        self.head = None
        
    def is_empty(self):
        return self.head == None
    
    def add(self, item):
        temp = Node(item)
        temp.set_next(self.head)
        self.head = temp
        

    def size(self):
        current = self.head
        count = 0
        while current != None:
            count += 1
            current = current.get_next()

        return count

    def search(self, item):
        current = self.head
        found = False
        while current != None and not found:
            if current.get_data() == item:
                found = True
            else:
                current = current.get_next()

        return found


    def remove(self, item):
        current = self.head
        previous = None
        found = False
        while not found:
            if current.get_data() == item:
                found = True
            else:
                previous = current
                current = current.get_next()

        if previous == None:
            self.head = current.get_next()
        else:
            previous.set_next(current.get_next())

    def print_list(self):
        current = self.head
        while current != None:
            print(current.data)
            current = current.get_next()

    def append(self, item):
        new_node = Node(item)

##      Append Linear Time O(n)
        if self.head == None:
            self.head = new_node
            return 
            
        current = self.head
        found_last = False
        while not found_last:
            if current.get_next() == None:
                found_last = True
                current.set_next(new_node)
                
            else:
                current = current.get_next()

The instructions then say "What is the time complexity of the method you created? It was most likely 𝑂(𝑛). If you add an instance variable to the UnorderedList class you can create an append method that is 𝑂(1). Modify your append to be 𝑂(1). Be careful! To really do this correctly you will need to consider a couple of special cases that may require you to make a modification to the add method as well."

This is what I came up with. I am including the modified add method. Intuitively these should both work, and in practice they do work with a simple case, but is this really constant time? How could I try and see if it's not? I am assuming the instance variable the book talks about is some sort of tail variable to which I can then simply append my new node, but something feels off and I am afraid that my solution is incomplete.

from node_class import Node

class UnorderedList:
    """
    An unordered list class built from a collection of nodes.
    """
    
    def __init__(self):
        self.head = None
        self.tail = None
        
    def is_empty(self):
        return self.head == None
    
    def add(self, item):
        temp = Node(item)
        temp.set_next(self.head)
        if self.head == None:
            self.tail = temp
        self.head = temp
        

    def size(self):
        current = self.head
        count = 0
        while current != None:
            count += 1
            current = current.get_next()

        return count

    def search(self, item):
        current = self.head
        found = False
        while current != None and not found:
            if current.get_data() == item:
                found = True
            else:
                current = current.get_next()

        return found


    def remove(self, item):
        current = self.head
        previous = None
        found = False
        while not found:
            if current.get_data() == item:
                found = True
            else:
                previous = current
                current = current.get_next()

        if previous == None:
            self.head = current.get_next()
        else:
            previous.set_next(current.get_next())

    def print_list(self):
        current = self.head
        while current != None:
            print(current.data)
            current = current.get_next()

    def append(self, item):
        new_node = Node(item)
##      Append Constant Time O(1)

        if self.head == None:
            self.tail = new_node
            self.head = new_node
            return
        else:
            self.tail.set_next(new_node)
            return