Starter Files

Download lab10.zip. Inside the archive, you will find starter files for the questions in this lab, along with a copy of the OK autograder.

Submission

By the end of this lab, you should have submitted the lab with python3 ok --submit. You may submit more than once before the deadline; only the final submission will be graded. Check that you have successfully submitted your code on okpy.org. See this article for more instructions on okpy and submitting assignments.

Linked Lists

A linked list is either an empty linked list (Link.empty) or a first value and the rest of the linked list.

class Link:
    """
    >>> s = Link(1, Link(2, Link(3)))
    >>> s
    Link(1, Link(2, Link(3)))
    """
    empty = ()

    def __init__(self, first, rest=empty):
        assert rest is Link.empty or isinstance(rest, Link)
        self.first = first
        self.rest = rest

    def __repr__(self):
        if self.rest is not Link.empty:
            rest_str = ', ' + repr(self.rest)
        else:
            rest_str = ''
        return 'Link({0}{1})'.format(repr(self.first), rest_str)

To check if a Link is empty, compare it against the class attribute Link.empty. For example, the below function prints out whether or not the link it is handed is empty:

def test_empty(link):
    if link is Link.empty:
        print('This linked list is empty!')
    else:
        print('This linked list is not empty!')

Note: Linked lists are recursive data structures! A linked list contains the first element of the list (first) and a reference to another linked list (rest) which contains the rest of the values in the list.

Question 1: WWPP: Linked Lists

Use OK to test your knowledge with the following "What Would Python Print?" questions:

python3 ok -q link -u

If you get stuck, try loading lab10.py into an interpreter or drawing out the diagram for the linked list on a piece of paper.

>>> from lab10 import *
>>> link = Link(1, Link(2, Link(3)))
>>> link.first
______
1
>>> link.rest.first
______
2
>>> link.rest.rest.rest is Link.empty
______
True
>>> link.first = 9001 >>> link.first
______
9001
>>> link.rest = link.rest.rest >>> link.rest.first
______
3
>>> link = Link(1) >>> link.rest = link >>> link.rest.rest.rest.rest.first
______
1
>>> link = Link(2, Link(3, Link(4))) >>> link2 = Link(1, link) >>> link2.first
______
1
>>> link2.rest.first
______
2
>>> print_link(link2) # Look at print_link in lab10.py
______
<1 2 3 4>

Question 2: List to Link

Write a function list_to_link that converts a Python list to a Link.

def list_to_link(lst):
    """Takes a Python list and returns a Link with the same elements.

    >>> link = list_to_link([1, 2, 3])
    >>> print_link(link)
    <1 2 3>
    """
"*** YOUR CODE HERE ***"
if not lst: return Link.empty else: return Link(lst[0], list_to_link(lst[1:]))

Use OK to test your code:

python3 ok -q list_to_link

Question 3: Reverse

Implement reverse, which takes a linked list link and returns a linked list containing the elements of link in reverse order. The original link should be unchanged.

def reverse(link):
    """Returns a Link that is the reverse of the original.

    >>> print_link(reverse(Link(1)))
    <1>
    >>> link = Link(1, Link(2, Link(3)))
    >>> new = reverse(link)
    >>> print_link(new)
    <3 2 1>
    >>> print_link(link)
    <1 2 3>
    """
"*** YOUR CODE HERE ***"
new = Link(link.first) while link.rest is not Link.empty: link = link.rest new = Link(link.first, new) return new # Recursive solution def reverse(link): def reverse_to(link, t): if link is Link.empty: return t else: return reverse_to(link.rest, Link(link.first, t)) return reverse_to(link, Link.empty)

Use OK to test your code:

python3 ok -q reverse

Trees

Question 4: Search

Write a function search that returns the Tree, whose entry is the given value if it exists and None if it does not. You can assume all entries are unique.

def search(t, value):
    """Searches for and returns the Tree whose entry is equal to value if
    it exists and None if it does not. Assume unique entries.

    >>> t = Tree(1, [Tree(3, [Tree(5)]), Tree(7)])
    >>> search(t, 10)
    >>> search(t, 5)
    Tree(5)
    >>> search(t, 1)
    Tree(1, [Tree(3, [Tree(5)]), Tree(7)])
    """
"*** YOUR CODE HERE ***"
if t.entry == value: return t for branch in t.branches: result = search(branch, value) if result is not None: return result return

Use OK to test your code:

python3 ok -q search

Question 5: Cumulative Sum

Write a function cumulative_sum that returns a new Tree, where each entry is the sum of all entries in the corresponding subtree of the old Tree.

def cumulative_sum(t):
    """Return a new Tree, where each entry is the sum of all entries in the
    corresponding subtree of t.

    >>> t = Tree(1, [Tree(3, [Tree(5)]), Tree(7)])
    >>> cumulative = cumulative_sum(t)
    >>> t
    Tree(1, [Tree(3, [Tree(5)]), Tree(7)])
    >>> cumulative
    Tree(16, [Tree(8, [Tree(5)]), Tree(7)])
    >>> cumulative_sum(Tree(1))
    Tree(1)
    """
"*** YOUR CODE HERE ***"
subtrees = [cumulative_sum(st) for st in t.branches] new_entry = sum(st.entry for st in subtrees) + t.entry return Tree(new_entry, subtrees)

Use OK to test your code:

python3 ok -q cumulative_sum