Project 1: The Game of Hog
I know! I'll use my
Higher-order functions to
Order higher rolls.
Introduction
In this project, you will develop a simulator and multiple strategies for the dice game Hog. You will need to use control statements and higher-order functions together, as described in Sections 1.2 through 1.6 of Composing Programs.
In Hog, two players alternate turns trying to be the first to end a turn with at least 100 total points. On each turn, the current player chooses some number of dice to roll, up to 10. That player's score for the turn is the sum of the dice outcomes.
To spice up the game, we will play with some special rules:
Pig Out. If any of the dice outcomes is a 1, the current player's score for the turn is the number of 1's rolled. Pig Out may award a maximum of 11 points minus the number of dice rolled on a turn.
- Example 1: The current player rolls 7 dice, 5 of which are 1's. They score min(11 - 7, 5) = 4 points for the turn.
- Example 2: The current player rolls 5 dice, 3 of which are 1's. They score min(11 - 5, 3) = 3 points from Pig Out. Hogtimus Prime (described below) will increase the score for the turn to 5.
- Example 3: The current player rolls 4 dice, all of which are 3's. Since Pig Out did not occur, they score 12 points for the turn.
Free Bacon. A player who chooses to roll zero dice scores one more than the largest digit in the opponent's total score.
- Example 1: If the opponent has 42 points, the current player gains 1 + max(4, 2) = 5 points by rolling zero dice.
- Example 2: If the opponent has 48 points, the current player gains 1 + max(4, 8) = 9 points by rolling zero dice.
- Example 3: If the opponent has 7 points, the current player gains 1 + max(0, 7) = 8 points by rolling zero dice.
- Hogtimus Prime. If a player's score for the turn is a prime number, then the turn score is increased to the next larger prime number. For example, if the dice outcomes sum to 11, the current player scores 13 points for the turn. This boost only applies to the current player. Note: 1 is not a prime number!
- Hog Wild. If the sum of both players' total scores is a multiple of seven (e.g., 0, 7, 14, 21, 35), then the current player rolls four-sided dice instead of the usual six-sided dice.
Swine Swap. After the turn score is added, if one of the scores is double the other, then the two scores are swapped.
- Example 1: The current player has a total score of 37 and the opponent has 92. The current player rolls two dice that total 9. The current player's new total score (46) is half of the opponent's score. These scores are swapped! The current player now has 92 points and the opponent has 46. The turn ends.
- Example 2: The current player has 91 and the opponent has 55. The current player rolls five dice that total 17, a prime that is boosted to 19 points for the turn. The current player has 110, so the scores are swapped. The opponent ends the turn with 110 and wins the game.
Download starter files
To get started, download all of the project code as a zip
archive. You only have to make changes to hog.py
.
hog.py
: A starter implementation of Hogdice.py
: Functions for rolling dicehog_gui.py
: A graphical user interface for Hogucb.py
: Utility functions for CS 61Aok
: CS 61A autogradertests
: A directory of tests used byok
images
: A directory of images used byhog_gui.py
OK now includes a collaboration environment so that you can work on the project with your partner in a browser (like Google Docs). More information is available on the demo video.
python3 ok --collab
Logistics
This is a 1-week project. You may work with one other partner. You should not share your code with students who are not your partner or copy from anyone else's solutions.
Remember that you can earn an additional bonus point by submitting the project at least 24 hours before the deadline.
In the end, you will submit one project for both partners. The project is worth 20 points. 18 points are assigned for correctness, and 2 points for the overall composition of your program.
You will turn in the following files:
hog.py
You do not need to modify or turn in any other files to complete the project. To submit the project, run the following command:
python3 ok --submit
You will be able to view your submissions on the OK dashboard.
For the functions that we ask you to complete, there may be some initial code that we provide. If you would rather not use that code, feel free to delete it and start from scratch. You may also add new function definitions as you see fit.
However, please do not modify any other functions. Doing so may result in your code failing our autograder tests. Also, please do not change any function signatures (names, argument order, or number of arguments).
Testing
Throughout this project, you should be testing the correctness of your code. It is good practice to test often, so that it is easy to isolate any problems. However, you should not be testing too often, to allow yourself and your partner the time to think through problems.
We have provided an autograder called ok
to help you
with testing your code and tracking your progress. The first time you run the
autograder, you will be asked to log in with your OK account using your web
browser. Please do so. Each time you run ok
, it will back up
your work and progress on our servers.
The primary purpose of ok
is to test your implementations, but
there are two things you should be aware of.
First, some of the test cases are locked. To unlock tests, run the following command from your terminal:
python3 ok -u
This command will start an interactive prompt that looks like:
===================================================================== Assignment: The Game of Hog OK, version ... ===================================================================== ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Unlocking tests At each "? ", type what you would expect the output to be. Type exit() to quit --------------------------------------------------------------------- Question 0 > Suite 1 > Case 1 (cases remaining: 1) >>> Code here ?
At the ?
, you can type what you expect the output to be. If you
are correct, then this test case will be available the next time you run the
autograder.
The idea is to understand conceptually what your program should do first, before you start writing any code.
Once you have unlocked some tests and written some code, you can check the correctness of your program using the tests that you have unlocked:
python3 ok
Most of the time, you will want to focus on a particular question. Use the
-q
option as directed in the problems below.
Second, there may be some test cases that are hidden. These test cases are not run by the command:
python3 ok
We keep test cases hidden to ensure that you write your code with the intention of solving the question at hand, not purely to pass the given tests. The hidden tests will be run when you submit your project. You will receive an email with part of the autograder results after submitting. However, the autograder has a 15 minute cooldown period. If you submit before 15 minutes have passed, the autograder will not run.
We recommend that you submit after you finish each problem. Only your last submission will be graded. It is also useful for us to have more backups of your code in case you run into a submission issue.
The tests
folder is used to store autograder tests, so
do not modify it. You may lose all your unlocking progress if you
do. If you need to get a fresh copy, you can download the
zip archive and copy it over, but you
will need to start unlocking from scratch.
If you do not want us to record a backup of your work or information about
your progress, use the --local
option when invoking
ok
. With this option, no information will be sent to our course
servers.
Graphical User Interface
A graphical user interface (GUI, for short) is provided for you.
At the moment, it doesn't work because you haven't implemented the
game logic. Once you complete the play
function, you will be able
to play a fully interactive version of Hog!
In order to render the graphics, make sure you have Tkinter, Python's main graphics library, installed on your computer. Once you've done that, you can run the GUI from your terminal:
python3 hog_gui.py
Once you complete the project, you can play against the final strategy that you've created!
python3 hog_gui.py -f
Phase 1: Simulator
In the first phase, you will develop a simulator for the game of Hog.
Problem 0 (0 pt)
The dice.py
file represents dice using non-pure zero-argument
functions. These functions are non-pure because they may have
different return values each time they are called. The documentation
of dice.py
describes the two different types of dice used in the
project:
- Dice can be fair, meaning that they produce each possible outcome with equal
probability. Examples:
four_sided
,six_sided
. - For testing functions that use dice, deterministic test dice always cycle
through a fixed sequence of values that are passed as arguments to the
make_test_dice
function.
Before we start writing any code, let's understand the make_test_dice
function by unlocking its tests.
python3 ok -q 00 -u
This should display a prompt that looks like this:
=====================================================================
Assignment: Project 1: Hog
OK, version v1.5.2
=====================================================================
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Unlocking tests
At each "? ", type what you would expect the output to be.
Type exit() to quit
---------------------------------------------------------------------
Question 0 > Suite 1 > Case 1
(cases remaining: 1)
>>> test_dice = make_test_dice(4, 1, 2)
>>> test_dice()
?
You should type in what you expect the output to be. To do so, you
need to first figure out what test_dice
will do, based on the
description above.
You can exit the unlocker by typing exit()
(without quotes). Typing Ctrl-C
on Windows to exit out of the unlocker has been known to cause problems, so
avoid doing so.
Problem 1 (1 pt)
Implement the roll_dice
function in hog.py
. It takes two arguments: a
positive integer called num_rolls
giving the number of dice to roll and a
dice
function. It returns the number of points scored by rolling the dice that
number of times in a turn: either the sum of the outcomes or the number of ones
rolled (Pig Out). You should also enforce the cap on Pig Out points here.
To obtain a single outcome of a dice roll, call dice()
. You should call
dice()
exactly num_rolls
times in the body of roll_dice
.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 01 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 01
The roll_dice
function has a default argument value
for dice
that is a random six-sided dice function. The tests use test_dice
.
Problem 2 (2 pt)
Implement the take_turn
function, which returns the number of points scored
for a turn by the current player. Your implementation should call roll_dice
when possible.
You will need to implement the Free Bacon rule. You can assume that
opponent_score
is less than 100. For a score less than 10, assume that the
first of the two digits is 0. To make your life easier later in the project,
first implement the free_bacon
helper function that returns the number of
points scored by rolling 0 dice. Call free_bacon
in your implementation of
take_turn
. There are no autograder tests written for free_bacon
but you can
test it interactively by entering python3 -i hog.py
in terminal and then
calling free_bacon
with various inputs.
You will also need to implement the Hogtimus Prime rule, which applies to both
regular turns and Free Bacon turns! To implement Hogtimus Prime, write your
own helper functions above the take_turn
function. One approach is to write
two helper functions: is_prime
and next_prime
. There are no tests for
is_prime
and next_prime
, but you can test them on your own using interactive
mode again. Remember, 1 isn't prime!
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 02 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 02
Problem 3 (1 pt)
Implement the select_dice
function, which helps enforce the Hog Wild rule.
select_dice
takes two arguments: the scores for the current and opposing
players. It returns the dice to be used for the turn: either four_sided
or
six_sided
.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 03 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 03
Problem 4 (1 pt)
To help you implement the Swine Swap rule, write a function called is_swap
that checks to see if one score is double the other.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 04 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 04
Problem 5 (3 pt)
Implement the play
function, which simulates a full game of Hog. Players
alternate turns, each using their respective strategy function (Player 0 uses
strategy0
, etc.), until one of the players reaches the goal
score. When the
game ends, play
returns the final total scores of both players, with Player
0's score first, and Player 1's score second.
Here are some hints:
- You should use the functions you have already written! You will need to call
take_turn
with all three arguments. - Enforce the remaining special rules: Hog Wild and Swine Swap.
- You can get the number of the other player (either 0 or 1) by calling
the provided function
other
. - A strategy is a function that, given a player's score and their opponent's
score, returns how many dice the player wants to roll. A strategy function
(such as
strategy0
andstrategy1
) takes two arguments: scores for the current player and opposing player, which both must be non-negative integers. A strategy function returns the number of dice that the current player wants to roll in the turn. Each strategy function should be called only once per turn. Don't worry about the details of implementing strategies yet. You will develop them in Phase 2.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 05 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 05
The last test for Question 5 is a fuzz test, which checks that your
play
function works for a large number of different inputs. Failing this test means something is wrong, but you should look at other tests to see where the problem might be.Hint: If you fail the fuzz test, check that you're only calling
take_turn
once per turn!
Once you are finished, you will be able to play a graphical version of
the game. We have provided a file called hog_gui.py
that
you can run from the terminal:
python3 hog_gui.py
If you don't already have Tkinter (Python's graphics library) installed, you'll need to install it first before you can run the GUI.
The GUI relies on your implementation, so if you have any bugs in your code, they will be reflected in the GUI. This means you can also use the GUI as a debugging tool; however, it's better to run the tests first.
Congratulations! You have finished Phase 1 of this project!
Phase 2: Strategies
In the second phase, you will experiment with ways to improve upon the basic strategy of always rolling a fixed number of dice. First, you need to develop some tools to evaluate strategies.
Problem 6 (1 pt)
Implement the check_strategy
function , which takes a strategy function as an
argument and returns None
. It calls the strategy with all valid inputs and
verifies that the strategy always returns a valid output. Use the provided
check_strategy_roll
function to raise an error with a helpful message if
num_rolls
is an invalid output.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 06 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 06
Problem 7 (2 pt)
Implement the make_averaged
function, which is a higher-order function that
takes a function fn
as an argument. It returns another function that takes
the same number of arguments as fn
(the function originally passed into
make_averaged
). This returned function differs from the input function in that
it returns the average value of repeatedly calling fn
on the same arguments.
This function should call fn
a total of num_samples
times and return the
average of the results.
To implement this function, you need a new piece of Python syntax! You must write a function that accepts an arbitrary number of arguments, then calls another function using exactly those arguments. Here's how it works.
Instead of listing formal parameters for a function, we write *args
.
To call another function using exactly those arguments, we call it
again with *args
. For example,
>>> def printed(fn):
... def print_and_return(*args):
... result = fn(*args)
... print('Result:', result)
... return result
... return print_and_return
>>> printed_pow = printed(pow)
>>> printed_pow(2, 8)
Result: 256
256
>>> printed_abs = printed(abs)
>>> printed_abs(-10)
Result: 10
10
Read the docstring for make_averaged
carefully to understand how it
is meant to work.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 07 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 07
Problem 8 (1 pt)
Implement the max_scoring_num_rolls
function, which runs an
experiment to determine the number of rolls (from 1 to 10) that gives
the maximum average score for a turn. Your implementation should use
make_averaged
and roll_dice
.
If two numbers of rolls are tied for the maximum average score, return the lower number. For example, if both 3 and 6 achieve a maximum average score, return 3.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 08 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 08
To run this experiment on randomized dice, call run_experiments
using
the -r
option:
python3 hog.py -r
Running experiments For the remainder of this project,
you can change the implementation of run_experiments
as you wish.
By calling average_win_rate
, you can evaluate various Hog
strategies. For example, change the first if False:
to if
True:
in order to evaluate always_roll(8)
against the
baseline strategy of always_roll(4)
. You should find that it wins slightly
more often than it loses, giving a win rate around 0.5.
Some of the experiments may take up to a minute to run. You can always reduce
the number of samples in make_averaged
to speed up experiments.
Problem 9 (1 pt)
A strategy can take advantage of the Free Bacon rule by rolling 0 when it is
most beneficial to do so. Implement bacon_strategy
, which returns 0 whenever
rolling 0 would give at least margin
points and returns num_rolls
otherwise. Don't forget about the Hogtimus Prime rule!
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 09 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 09
Once you have implemented this strategy, change run_experiments
to evaluate
your new strategy against the baseline. You should find that it wins more than
half of the time.
Problem 10 (2 pt)
A strategy can also take advantage of the Swine Swap rule. The swap_strategy
rolls 0 if it would cause a beneficial swap. It also returns 0 if rolling 0
would give at least margin
points and would not cause a
swap. Otherwise, the strategy rolls num_rolls
.
Before writing any code, unlock the tests to verify your understanding of the question.
python3 ok -q 10 -u
Once you are done unlocking, begin implementing your solution. You can check your correctness with:
python3 ok -q 10
Once you have implemented this strategy, update run_experiments
to
evaluate your new strategy against the baseline. You should find that
it gives a significant edge over always_roll(4)
.
Problem 11 (3 pt)
Implement final_strategy
, which combines these ideas and any other ideas you
have to achieve a win rate of at least 0.65 (for full credit) against the
baseline always_roll(4)
strategy. Partial credit is also given if you are
close. Some suggestions:
swap_strategy
is a good default strategy to start with.- There's no point in scoring more than 100. Check for chances to win. If you are in the lead, you might take fewer risks.
- Try to force a beneficial swap.
- Choose the
num_rolls
andmargin
arguments carefully. If Hog Wild is in effect, you may want to have a differentnum_rolls
andmargin
.
You can check your final strategy win rate by running OK.
python3 ok -q 11
At this point, run the entire autograder to see if there are any tests that don't pass.
python3 ok
You can also play against your final strategy with the graphical user interface:
python3 hog_gui.py -f
The GUI will alternate which player is controlled by you.
Congratulations, you have reached the end of your first CS 61A project!