Instructions
Download hw03.zip (hw03.zip). Inside the archive, you will nd a le called hw03.py (hw03.py), along with a copy of the ok autograder.
Submission: When you are done, submit with python3 ok submit . You may submit more than once before the deadline; only the nal submission will be scored. Check that you have successfully submitted your code on okpy.org (https://okpy.org/). See Lab 0 (/lab/lab00#submitting-the-assignment) for more instructions on submitting assignments.
Using Ok: If you have any questions about using Ok, please refer to this guide. (/articles/using-ok)
Readings: You might nd the following references useful:
Section 1.7 (http://composingprograms.com/pages/17-recursive-functions.html)
Grading: Homework is graded based on correctness. Each incorrect problem will decrease the total score by one point. There is a homework recovery policy as stated in the syllabus. This homework is out of 2 points.
Required Questions
Q1: Num eights
Write a recursive function num_eights that takes a positive integer pos and returns the number of times the digit 8 appears in pos .
Important: Use recursion; the tests will fail if you use any assignment statements. (You can however use function de nitions if you so wish.)
def num_eights(pos):
Returns the number of times 8 appears as a digit of pos.
>>> num_eights(3)
0
>>> num_eights(8)
1
>>> num_eights(88888888)
8
>>> num_eights(2638)
1
>>> num_eights(86380)
2
>>> num_eights(12345)
0
>>> from construct_check import check
>>> # ban all assignment statements
>>> check(HW_SOURCE_FILE, num_eights,
[Assign, AnnAssign, AugAssign, NamedExpr])
True
*** YOUR CODE HERE ***
Use Ok to test your code:
python3 ok -q num_eights ✂
Q2: Ping-pong
The ping-pong sequence counts up starting from 1 and is always either counting up or counting down. At element k , the direction switches if k is a multiple of 8 or contains the digit 8. The rst 30 elements of the ping-pong sequence are listed below, with direction swaps marked using brackets at the 8th, 16th, 18th, 24th, and 28th elements:
Index | 1 | 2 | 3 | 4 | 5 | 6 | 7 | [8] | 9 | 10 | 11 | 12 | 13 | 14 | 15 | [16] | 17 | [18] | 19 | 20 | 21 | 22 | 23 | ||||||||
PingPongValue | 1 | 2 | 3 | 4 | 5 | 6 | 7 | [8] | 7 | 6 | 5 | 4 | 3 | 2 | 1 | [0] | 1 | [2] | 1 | 0 | -1 | -2 | -3 | ||||||||
Index (cont.) | [24] | 25 | 26 | 27 | [28] | 29 | 30 | ||||||||||||||||||||||||
PingPong Value | [-4] | -3 | -2 | -1 | [0] | -1 | -2 | ||||||||||||||||||||||||
Implement a function pingpong that returns the nth element of the ping-pong sequence without using any assignment statements. (You are allowed to use function de nitions.)
You may use the function num_eights , which you de ned in the previous question.
Important: Use recursion; the tests will fail if you use any assignment statements. (You can however use function de nitions if you so wish.)
Return the nth element of the ping-pong sequence.
>>> pingpong(8)
8
>>> pingpong(10)
6
>>> pingpong(15)
1 >>> pingpong(21)
-1
>>> pingpong(22)
-2
>>> pingpong(30)
-2
>>> pingpong(68)
0 >>> pingpong(69)
-1
>>> pingpong(80)
- >>> pingpong(81)
- >>> pingpong(82)
0
>>> pingpong(100)
-6
>>> from construct_check import check
>>> # ban assignment statements
>>> check(HW_SOURCE_FILE, pingpong,
[Assign, AnnAssign, AugAssign, NamedExpr])
True
*** YOUR CODE HERE ***
Use Ok to test your code:
python3 ok -q pingpong ✂
Q3: Missing Digits
Write the recursive function missing_digits that takes a number n that is sorted in non-decreasing order (for example, 12289 is valid but 15362 and 98764 are not). It returns the number of missing digits in n . A missing digit is a number between the rst and last digit of n of a that is not in n .
Important: Use recursion; the tests will fail if you use any loops.
def missing_digits(n):
Given a number a that is in sorted, non-decreasing order, return the number of missing digits in n. A missing digit is a number between the first and last digit of a that is not in n. >>> missing_digits(1248) # 3, 5, 6, 7
4 >>> missing_digits(19) # 2, 3, 4, 5, 6, 7, 8
7 >>> missing_digits(1122) # No missing numbers
0 >>> missing_digits(123456) # No missing numbers
0 >>> missing_digits(3558) # 4, 6, 7
3 >>> missing_digits(35578) # 4, 6
2 >>> missing_digits(12456) # 3
1 >>> missing_digits(16789) # 2, 3, 4, 5
4
>>> missing_digits(4) # No missing numbers between 4 and 4
0
>>> from construct_check import check
>>> # ban while or for loops >>> check(HW_SOURCE_FILE, missing_digits, [While, For])
True
*** YOUR CODE HERE ***
Use Ok to test your code:
python3 ok -q missing_digits ✂
Q4: Count coins
Given a positive integer change , a set of coins makes change for change if the sum of the values of the coins is change . Here we will use standard US Coin values: 1, 5, 10, 25. For example, the following sets make change for 15 :
15 1-cent coins
10 1-cent, 1 5-cent coins
5 1-cent, 2 5-cent coins
5 1-cent, 1 10-cent coins
3 5-cent coins
1 5-cent, 1 10-cent coin
Thus, there are 6 ways to make change for 15 . Write a recursive function count_coins that takes a positive integer change and returns the number of ways to make change for change using coins.
You can use either of the functions given to you:
ascending_coin will return the next larger coin denomination from the input, i.e. ascending_coin(5) is 10 . descending_coin will return the next smaller coin denomination from the input, i.e. descending_coin(5) is 1 .
There are two main ways in which you can approach this problem. One way uses ascending_coin , and another uses descending_coin .
Important: Use recursion; the tests will fail if you use loops.
Hint: Refer the implementation (http://composingprograms.com/pages/17-recursive-
functions.html#example-partitions) of count_partitions for an example of how to count the ways to sum up to a nal value with smaller parts. If you need to keep track of more than one value across recursive calls, consider writing a helper function.
def ascending_coin(coin):
Returns the next ascending coin in order. >>> ascending_coin(1)
5 >>> ascending_coin(5)
10 >>> ascending_coin(10)
25 >>> ascending_coin(2) # Other values return None
if coin == 1: return 5 elif coin == 5: return 10 elif coin == 10: return 25
def descending_coin(coin):
Returns the next descending coin in order.
>>> descending_coin(25)
10
>>> descending_coin(10)
5 >>> descending_coin(5)
1 >>> descending_coin(2) # Other values return None
if coin == 25: return 10 elif coin == 10: return 5 elif coin == 5: return 1
def count_coins(change):
Return the number of ways to make change using coins of value of 1, 5, 10, 25.
>>> count_coins(15)
6
>>> count_coins(10)
4
>>> count_coins(20)
9 >>> count_coins(100) # How many ways to make change for a dollar?
242 >>> count_coins(200)
1463 >>> from construct_check import check
>>> # ban iteration >>> check(HW_SOURCE_FILE, count_coins, [While, For])
True
*** YOUR CODE HERE ***
Use Ok to test your code:
python3 ok -q count_coins ✂
Just for fun Questions
Q5: Towers of Hanoi
A classic puzzle called the Towers of Hanoi is a game that consists of three rods, and a number of disks of di erent sizes which can slide onto any rod. The puzzle starts with n disks in a neat stack in ascending order of size on a start rod, the smallest at the top, forming a conical shape.
Complete the de nition of move_stack , which prints out the steps required to move n disks from the start rod to the end rod without violating the rules. The provided print_move function will print out the
step to move a single disk from the given origin to the given destination .
Hint: Draw out a few games with various n on a piece of paper and try to nd a pattern of disk movements that applies to any n . In your solution, take the recursive leap of faith whenever you need to move any amount of disks less than n from one rod to another. If you need more help, see the following hints.
def print_move(origin, destination):
Print instructions to move a disk.
print(Move the top disk from rod, origin, to rod, destination)
def move_stack(n, start, end):
Print the moves required to move n disks on the start pole to the end pole without violating the rules of Towers of Hanoi.
n number of disks start a pole position, either 1, 2, or 3 end a pole position, either 1, 2, or 3
There are exactly three poles, and start and end must be different. Assume that the start pole has at least n disks of increasing size, and the end pole is either empty or has a top disk larger than the top n start disks.
>>> move_stack(1, 1, 3)
Move the top disk from rod 1 to rod 3
>>> move_stack(2, 1, 3)
Move the top disk from rod 1 to rod 2
Move the top disk from rod 1 to rod 3
Move the top disk from rod 2 to rod 3
>>> move_stack(3, 1, 3)
Move the top disk from rod 1 to rod 3
Move the top disk from rod 1 to rod 2
Move the top disk from rod 3 to rod 2
Move the top disk from rod 1 to rod 3
Move the top disk from rod 2 to rod 1
Move the top disk from rod 2 to rod 3 Move the top disk from rod 1 to rod 3
assert 1 <= start <= 3 and 1 <= end <= 3 and start != end, Bad start/end *** YOUR CODE HERE ***
Use Ok to test your code:
python3 ok -q move_stack ✂
Q6: Anonymous factorial
The recursive factorial function can be written as a single expression by using a conditional expression (http://docs.python.org/py3k/reference/expressions.html#conditional-expressions).
>>> fact = lambda n: 1 if n == 1 else mul(n, fact(sub(n, 1)))
>>> fact(5)
120
However, this implementation relies on the fact (no pun intended) that fact has a name, to which we refer in the body of fact . To write a recursive function, we have always given it a name using a def or assignment statement so that we can refer to the function within its own body. In this question, your job is to de ne fact recursively without giving it a name!
Write an expression that computes n factorial using only call expressions, conditional expressions, and
lambda expressions (no assignment or def statements).
The sub and mul functions from the operator module are the only built-in functions required to solve this problem.
from operator import sub, mul
def make_anonymous_factorial():
Return the value of an expression that computes factorial.
>>> make_anonymous_factorial()(5)
120
>>> from construct_check import check
>>> # ban any assignments or recursion
>>> check(HW_SOURCE_FILE, make_anonymous_factorial,
[Assign, AnnAssign, AugAssign, NamedExpr, FunctionDef, Recursion])
True
return YOUR_EXPRESSION_HERE
Use Ok to test your code:
python3 ok -q make_anonymous_factorial ✂
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