def test_items(self): ll = LinkedList() assert ll.items() == [] ll.append('B') assert ll.items() == ['B'] ll.prepend('A') assert ll.items() == ['A', 'B'] ll.append('C') assert ll.items() == ['A', 'B', 'C']
def test_size(self): ll = LinkedList() assert ll.size == 0 # append and prepend operations increment size ll.append('B') assert ll.size == 1 ll.prepend('A') assert ll.size == 2 ll.append('C') assert ll.size == 3 # delete operations decrement size ll.delete('B') assert ll.size == 2 ll.delete('C') assert ll.size == 1 ll.delete('A') assert ll.size == 0
def test_length(self): ll = LinkedList() assert ll.length() == 0 # append and prepend operations increase length ll.append('B') assert ll.length() == 1 ll.prepend('A') assert ll.length() == 2 ll.append('C') assert ll.length() == 3 # delete operations decrease length ll.delete('B') assert ll.length() == 2 ll.delete('C') assert ll.length() == 1 ll.delete('A') assert ll.length() == 0
def test_append(self): ll = LinkedList() ll.append('A') assert ll.head.data == 'A' # new head assert ll.tail.data == 'A' # new tail assert ll.size == 1 ll.append('B') assert ll.head.data == 'A' # unchanged assert ll.tail.data == 'B' # new tail assert ll.size == 2 ll.append('C') assert ll.head.data == 'A' # unchanged assert ll.tail.data == 'C' # new tail assert ll.size == 3
class LinkedDeque(object): # Setting our front as the head of the doubly linked list def __init__(self, iterable=None): """Initialize this deque and push_back the given items, if any.""" # Initialize a new linked list to store the items self.list = LinkedList() if iterable is not None: for item in iterable: self.push_back(item) def __repr__(self): """Return a string representation of this deque.""" return 'Queue({} items, front={})'.format(self.length(), self.front()) def is_empty(self): """Return True if this deque is empty, or False otherwise.""" return self.list.is_empty() def length(self): """Return the number of items in this deque.""" return self.list.length() def push_front(self, item): """Insert the given item at the front of the linkedlist. Running time: O(1) calling the ll prepend method by just changing the head node""" self.list.prepend(item) def push_back(self, item): """Insert the given item at the back of this deque. Running time: O(1) calling the ll append method by just changing the tail node""" self.list.append(item) def front(self): """Return the item at the front of this deque without removing it, or None if this deque is empty.""" if self.length() != 0: return self.list.head.data # returning the head else: return None def back(self): """Return the item at the end of this deque without removing it, or None if this deque is empty.""" if self.length() != 0: return self.list.tail.data # returning the tail else: return None def pop_front(self): """Remove and return the item at the front of this deque, or raise ValueError if this deque is empty. Running time: O(1) from getting the front item and removing at the head of the ll""" if self.length() != 0: front_item = self.front() self.list.delete(front_item) return front_item else: raise ValueError('No items in list to pop_front: []') def pop_back(self): """Remove and return the item at the back of this deque, or raise ValueError if this deque is empty. Running time: O(1) from getting the back item and removing at the tail of the ll""" if self.length() != 0: back_item = self.back() self.list.delete(back_item) return back_item else: raise ValueError('No items in list to pop_back: []')