Esempio n. 1
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    def test_no_loop(self):
        self.assertFalse(loop_detection_buffer(self.ll))

        self.ll.next = Node(1)
        self.ll.next.next = Node(3)

        self.assertFalse(loop_detection_buffer(self.ll))
Esempio n. 2
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def sum_linked_lists(node1, node2, carry=0):
    """Recursive solution summing two linked lists without explicit Singly
       Linked List Class
    
    :param   node1 node of first linked list
    :param   node2 node of second linked list
    :param   carry should be defaulted to zero

    :returns Sum of linked lists

    """
    if node1 is None and node2 is None and carry == 0:
        return

    data = carry

    if node1 is not None:
        data += node1.data
        node1 = node1.next

    if node2 is not None:
        data += node2.data
        node2 = node2.next

    curr = Node(data % 10)

    curr.next = sum_linked_lists(node1, node2, int(data >= 10))

    return curr
Esempio n. 3
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    def test_more_two_nodes(self):
        """Delete middle node in linked list of length > two elements"""
        node = Node(1)
        node.next = Node(3)
        node.next.next = Node(4)

        delete_middle_node(node.next)
        self.assertTrue(node.next.data == 4)
Esempio n. 4
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    def test_two_nodes(self):
        """Deletes head node in linked list with two elements"""
        node = Node(1)
        node.next = Node(2)

        delete_middle_node(node)
        self.assertIsNone(node.next)
        self.assertTrue(node.data == 2)
Esempio n. 5
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    def test_multiple_elements(self):
        self.ll.next = Node(1)

        # No loop
        self.assertFalse(loop_detection(self.ll))

        # Loop at end
        self.ll.next.next = self.ll.next
        self.assertTrue(loop_detection(self.ll) == self.ll.next)

        # Loop at beginning
        self.ll.next.next = Node(2)
        self.ll.next.next.next = self.ll.next

        self.assertTrue(loop_detection(self.ll) == self.ll.next)
Esempio n. 6
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    def pad_zeroes(head, num):
        """Pad zeroes to the front of the linked list

        :param   head head of the linked list
        :param   num  number of zeroes to add
        :returns linked list with zeroes padded to the front

        """
        new = curr = Node(0)
        num -= 1

        while num > 0:
            curr.next = Node(0)
            curr = curr.next
            num -= 1
        curr.next = head
        return new
Esempio n. 7
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    def test_even_nodes(self):
        l_list = Node(1)
        l_list.next = Node(2)
        l_list.next = Node(2)
        l_list.next = Node(3)
        self.assertFalse(is_palindrome_reverse(l_list))

        l_list.next.next = Node(1)

        self.assertTrue(is_palindrome_reverse(l_list))
Esempio n. 8
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    def test_linked_list_greater_one_element(self):
        ll_a = Node(1)
        ll_a.next = Node(3)
        ll_a.next.next = Node(4)

        ll_b = Node(0)
        ll_b.next = ll_a.next.next

        # Same Node
        self.assertTrue(is_intersection(ll_a, ll_a) == ll_a)

        # Last Node, different sizes
        self.assertTrue(is_intersection(ll_a, ll_b) == ll_b.next)

        # Last Node, same sizes
        ll_b.next = Node(4)
        ll_b.next.next = ll_a.next.next
        self.assertTrue(is_intersection(ll_a, ll_b) == ll_b.next.next)
Esempio n. 9
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    def test_loop(self):
        self.ll.next = self.ll

        # Single element
        self.assertTrue(loop_detection_buffer(self.ll) == self.ll)

        # Loop at beginning
        self.ll.next = Node(1)
        self.ll.next.next = self.ll
        self.assertTrue(loop_detection_buffer(self.ll) == self.ll)

        # Loop in middle
        self.ll.next.next = Node(2)
        self.ll.next.next = self.ll.next
        self.assertTrue(loop_detection_buffer(self.ll) == self.ll.next)

        # Loop at end
        self.ll.next.next.next = self.ll.next.next
        self.assertTrue(loop_detection_buffer(self.ll) == self.ll.next.next)
Esempio n. 10
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    def test_even_elements(self):
        list = Node(1)
        list.next = Node(2)
        list.next.next = Node(2)
        list.next.next.next = Node(3)

        self.assertFalse(is_palindrome_brute_force(list))

        list.next.next.next = Node(1)

        self.assertTrue(is_palindrome_brute_force(list))
Esempio n. 11
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    def sum_helper(node1, node2):
        """Sum helper function to recursively sum elements of equal length linked lists

        :param   node1 head of first linked list
        :param   node2 head of second linked list

        :returns sum of first and second linked lists as a set of nodes

        """
        if node1 is None and node2 is None:
            return
        curr = sum_helper(node1.next, node2.next)

        if curr is None:
            curr = Node(0)
        data = node1.data + node2.data + curr.data
        curr.data = data % 10

        next = Node(int(data >= 10))
        next.next = curr

        return next
Esempio n. 12
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    def test_single_empty_linked_list(self):
        ll_a = Node(1)

        self.assertFalse(is_intersection(ll_a, None))
        self.assertFalse(is_intersection(None, ll_a))
Esempio n. 13
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    def test_single_node(self):
        """Delete node with one element in linked list, raise IndexError"""
        node = Node(1)

        with self.assertRaises(IndexError):
            delete_middle_node(node)
Esempio n. 14
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 def setUp(self):
     self.ll = Node(0)
Esempio n. 15
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 def test_linked_list_intersection_single_element(self):
     ll_a = Node(1)
     ll_b = Node(2)
     self.assertTrue(is_intersection(ll_a, ll_a) is ll_a)
     self.assertFalse(is_intersection(ll_a, ll_b))
Esempio n. 16
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 def test_single_element(self):
     list = Node(1)
     self.assertTrue(is_palindrome_brute_force(list))
Esempio n. 17
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 def test_single_node(self):
     self.assertTrue(is_palindrome_reverse(Node(1)))