Description
Your job in this assignment is to write the classic arcade game of
Breakout, which was invented by Steve Wozniak before he
founded Apple with Steve Jobs. It is a large assignment, but
entirely manageable as long as you break the problem up into
pieces. The decomposition is discussed in this handout, and
there are several suggestions for staying on top of things in the
“Strategy and tactics” section later in this handout.
The Breakout game
In Breakout, the initial configuration of the world appears as
shown on the right. The colored rectangles in the top part of the
screen are bricks, and the slightly larger rectangle at the bottom is
the paddle. The paddle is in a fixed position in the vertical
dimension, but moves back and forth across the screen along
with the mouse until it reaches the edge of its space.
A complete game consists of three turns. On each turn, a ball is
launched from the center of the window toward the bottom of the
screen at a random angle. That ball bounces off the paddle and
the walls of the world, in accordance with the physical principle
generally expressed as “the angle of incidence equals the angle of
reflection” (which turns out to be very easy to implement as
discussed later in this handout). Thus, after two bounces—one
off the paddle and one off the right wall—the ball might have the
trajectory shown in the second diagram. (Note that the dotted line
is there to show the ball’s path and won’t appear on the screen.)
As you can see from the second diagram, the ball is about to
collide with one of the bricks on the bottom row. When that
happens, the ball bounces just as it does on any other collision,
but the brick disappears. The third diagram shows what the
game looks like after that collision and after the player has
moved the paddle to put it in line with the oncoming ball.
The play on a turn continues in this way until one of two
conditions occurs:
1. The ball hits the lower wall, which means that the player
must have missed it with the paddle. In this case, the turn
ends and the next ball is served if the player has any turns
left. If not, the game ends in a loss for the player.
2. The last brick is eliminated. In this case, the player wins, and
the game ends immediately.
– 2 –
After all the bricks in a particular column have been cleared, a
path will open to the top wall. When this situation occurs, the ball
will often bounce back and forth several times between the top
wall and the upper line of bricks without the user ever having to
worry about hitting the ball with the paddle. This condition is
called “breaking out” and gives meaning to the name of the game.
The diagram on the right shows the situation shortly after the first
ball has broken through the wall. That ball will go on to clear
several more bricks before it comes back down an open channel.
It is important to note that, even though breaking out is a very
exciting part of the player’s experience, you don’t have to do
anything special in your program to make it happen. The game is
simply operating by the same rules it always applies: bouncing off
walls, clearing bricks, and otherwise obeying the laws of physics.
The starter file
The starter project for this assignment has a little more in it than it has in the past, but none of the
important parts of the program. The starting contents of the Breakout.java file appear in
Figure 1 (on the next page). This file takes care of the following details:
• It includes the imports you will need for writing the game.
• It defines the named constants that control the game parameters, such as the dimensions of the
various objects. Your code should use these constants internally so that changing them in your
file changes the behavior of your program accordingly.
Success in this assignment will depend on breaking up the problem into manageable pieces and
getting each one working before you move on to the next. The next few sections describe a
reasonable staged approach to the problem.
Set up the bricks
Before you start playing the game, you have to set up the various pieces. Thus, it probably makes
sense to implement the run method as two method calls: one that sets up the game and one that
plays it. An important part of the setup consists of creating the rows of bricks at the top of the
game, which look like this:
The number, dimensions, and spacing of the bricks are specified using named constants in the
starter file, as is the distance from the top of the window to the first line of bricks. The only
value you need to compute is the x coordinate of the first column, which should be chosen so that
the bricks are centered in the window, with the leftover space divided equally on the left and
right sides. The color of the bricks remain constant for two rows and run in the following
rainbow-like sequence: RED, ORANGE, YELLOW, GREEN, CYAN.
– 3 –
Figure 1. The Breakout.java starter file
/*
* File: Breakout.java
* ——————-
* This file will eventually implement the game of Breakout.
*/
import acm.graphics.*;
import acm.program.*;
import acm.util.*;
import java.applet.*;
import java.awt.*;
import java.awt.event.*;
public class Breakout extends GraphicsProgram {
/** Width and height of application window in pixels */
public static final int APPLICATION_WIDTH = 400;
public static final int APPLICATION_HEIGHT = 600;
/** Dimensions of game board (usually the same) */
private static final int WIDTH = APPLICATION_WIDTH;
private static final int HEIGHT = APPLICATION_HEIGHT;
/** Dimensions of the paddle */
private static final int PADDLE_WIDTH = 60;
private static final int PADDLE_HEIGHT = 10;
/** Offset of the paddle up from the bottom */
private static final int PADDLE_Y_OFFSET = 30;
/** Number of bricks per row */
private static final int NBRICKS_PER_ROW = 10;
/** Number of rows of bricks */
private static final int NBRICK_ROWS = 10;
/** Separation between bricks */
private static final int BRICK_SEP = 4;
/** Width of a brick */
private static final int BRICK_WIDTH =
(WIDTH – (NBRICKS_PER_ROW – 1) * BRICK_SEP) / NBRICKS_PER_ROW;
/** Height of a brick */
private static final int BRICK_HEIGHT = 8;
/** Radius of the ball in pixels */
private static final int BALL_RADIUS = 10;
/** Offset of the top brick row from the top */
private static final int BRICK_Y_OFFSET = 70;
/** Number of turns */
private static final int NTURNS = 3;
public void run() {
/* You fill this in, along with any subsidiary methods */
}
}
– 4 –
This part of the assignment is almost exactly like the pyramid
problem from Assignment #2. The parts that are only a touch
more difficult are that you need to fill and color the bricks. This
extra complexity is more than compensated by the fact that there
are the same number of bricks in each row, and you don’t have to
change the coordinate calculation from row to row.
Here’s a suggestion: Why don’t you get this part of the program
working by Wednesday the 17th so that you can produce just the
diagram at the right? The display has most of what you see on
the final screen and will give you considerable confidence that
you can get the rest done. And you’ll be well on your way before
time gets short.
Create the paddle
The next step is to create the paddle. At one level, this is considerably easier than the bricks.
There is only one paddle, which is a filled GRect. You even know its position relative to the
bottom of the window.
The challenge in creating the paddle is to make it track the mouse. The technique is similar to
that discussed in Chapter 9 for dragging an object around in the window. Here, however, you
only have to pay attention to the x coordinate of the mouse because the y position of the paddle is
fixed. The only additional wrinkle is that you should not let the paddle move off the edge of the
window. Thus, you’ll have to check to see whether the x coordinate of the mouse would make
the paddle extend beyond the boundary and change it if necessary to ensure that the entire paddle
is visible in the window.
Here’s a soon-to-become-boring suggestion: Why don’t you get this part of the program working
by Friday the 19th, so that you can follow the mouse with the paddle? This entire part of the
program takes fewer than 10 code lines, so it shouldn’t take so long. The hard part lies in reading
the Graphics chapter and understanding what you need to do.
Create a ball and get it to bounce off the walls
At one level, creating the ball is easy, given that it’s just a filled GOval. The interesting part lies
in getting it to move and bounce appropriately. You are now past the “setup” phase and into the
“play” phase of the game. To start, create a ball and put it in the center of the window. As you
do so, keep in mind that the coordinates of the GOval do not specify the location of the center of
the ball but rather its upper left corner. The mathematics is not any more difficult, but may be a
bit less intuitive.
The program needs to keep track of the velocity of the ball, which consists of two separate
components, which you will presumably declare as instance variables like this:
private double vx, vy;
The velocity components represent the change in position that occurs on each time step. Initially,
the ball should be heading downward, and you might try a starting velocity of +3.0 for vy
(remember that y values in Java increase as you move down the screen). The game would be
boring if every ball took the same course, so you should choose the vx component randomly.
– 5 –
In line with our discussion of generating random numbers last week, you should simply do the
following:
1. Declare an instance variable rgen, which will serve as a random-number generator:
private RandomGenerator rgen = RandomGenerator.getInstance();
Remember that instance variables are declared outside of any method but inside the class.
2. Initialize the vx variable as follows:
vx = rgen.nextDouble(1.0, 3.0);
if (rgen.nextBoolean(0.5)) vx = -vx;
This code sets vx to be a random double in the range 1.0 to 3.0 and then makes it negative
half the time. This strategy works much better for Breakout than calling
nextDouble(-3.0, +3.0)
which might generate a ball going more or less straight down. That would make life far too
easy for the player.
Once you’ve done that, your next challenge is to get the ball to bounce around the world,
ignoring entirely the paddle and the bricks. To do so, you need to check to see if the coordinates
of the ball have gone beyond the boundary, taking into account that the ball has a nonzero size.
Thus, to see if the ball has bounced off the right wall, you need to see whether the coordinate of
the right edge of the ball has become greater than the width of the window; the other three
directions are treated similarly. For now, have the ball bounce off the bottom wall so that you
can watch it make its path around the world. You can change that test later so that hitting the
bottom wall signifies the end of a turn.
Computing what happens after a bounce is extremely simple. If a ball bounces off the top or
bottom wall, all you need to do is reverse the sign of vy. Symmetrically, bounces off the side
walls simply reverse the sign of vx.
Checking for collisions
Now comes the interesting part. In order to make Breakout into a real game, you have to be able
to tell whether the ball is colliding with another object in the window. As scientists often do, it
helps to begin by making a simplifying assumption and then relaxing that assumption later.
Suppose the ball were a single point rather than a circle. In that case, how could you tell whether
it had collided with another object?
If you look in Chapter 9 (page 299) at the methods that are defined at the GraphicsProgram
level, you will discover that there is a method
public GObject getElementAt(double x, double y)
that takes a position in the window and returns the graphical object at that location, if any. If
there are no graphical objects that cover that position, getElementAt returns the special constant
null. If there is more than one, getElementAt always chooses the one closest to the top of the
stack, which is the one that appears to be in front on the display.
– 6 –
What happens if you call
getElementAt(x, y)
where x and y are the coordinates of the ball? If the point (x, y) is underneath an object, this
call returns the graphical object with which the ball has collided. If there are no objects at the
point (x, y), you’ll get the value null.
So far, so good. But, unfortunately, the ball is not a single point. It occupies physical area and
therefore may collide with something on the screen even though its center does not. The easiest
thing to do—which is in fact typical of the simplifying assumptions made in real computer
games—is to check a few carefully chosen points on the outside of the ball and see whether any
of those points has collided with anything. As soon as you find something at one of those points,
you can declare that the ball has collided with that object.
In your implementation, the easiest thing to do is to check the four corner points on the square in
which the ball is inscribed. Remember that a GOval is defined in terms of its bounding rectangle,
so that if the upper left corner of the ball is at the point (x, y), the other corners will be at the
locations shown in this diagram:
(x , y ) (x + 2r, y )
(x , y + 2r) (x + 2r, y + 2r)
These points have the advantage of being outside the ball—which means that getElementAt
can’t return the ball itself—but nonetheless close enough to make it appear that collisions have
occurred. Thus, for each of these four points, you need to:
1. Call getElementAt on that location to see whether anything is there.
2. If the value you get back is not null, then you need look no farther and can take that value as
the GObject with which the collision occurred.
3. If getElementAt returns null for a particular corner, go on and try the next corner.
4. If you get through all four corners without finding a collision, then no collision exists.
It would be very useful to write this section of code as a separate method
private GObject getCollidingObject()
that returns the object involved in the collision, if any, and null otherwise. You could then use
it in a declaration like
GObject collider = getCollidingObject();
which assigns that value to a variable called collider.
– 7 –
From here, the only remaining thing you need to do is decide what to do when a collision occurs.
There are only two possibilities. First, the object you get back might be the paddle, which you
can test by checking
if (collider == paddle) . . .
If it is the paddle, you need to bounce the ball so that it starts traveling up. If it isn’t the paddle,
the only other thing it might be is a brick, since those are the only other objects in the world.
Once again, you need to cause a bounce in the vertical direction, but you also need to take the
brick away. To do so, all you need to do is remove it from the screen by calling the remove
method.
Finishing up
If you’ve gotten to here, you’ve done all the hard parts. There are, however, a few more details
you need to take into account:
• You’ve got to take care of the case when the ball hits the bottom wall. In the prototype you’ve
been building, the ball just bounces off this wall like all the others, but that makes the game
pretty hard to lose. You’ve got to modify your loop structure so that it tests for hitting the
bottom wall as one of its terminating conditions.
• You’ve got to check for the other terminating condition, which is hitting the last brick. How
do you know when you’ve done so? Although there are other ways to do it, one of the easiest
is to have your program keep track of the number of bricks remaining. Every time you hit one,
subtract one from that counter. When the count reaches zero, you must be done. In terms of
the requirements of the assignment, you can simply stop at that point, but it would be nice to
give the player a little feedback that at least indicates whether the game was won or lost.
• You’ve got to experiment with the settings that control the speed of your program. How long
should you pause in the loop that updates the ball? Do you need to change the velocity values
to get better play action?
• You’ve got to test your program to see that it works. Play for a while and make sure that as
many parts of it as you can check are working. If you think everything is working, here is
something to try: Just before the ball is going to pass the paddle level, move the paddle
quickly so that the paddle collides with the ball rather than vice-versa. Does everything still
work, or does your ball seem to get “glued” to the paddle? If you get this error, try to
understand why it occurs and how you might fix it.
Strategy and tactics
Here are some survival hints for this assignment:
• Start as soon as possible. This assignment is due in just over a week, which will be here
before you know it. If you wait until the day before this assignment is due, you will have a
very hard time getting it all together.
• Implement the program in stages, as described in this handout. Don’t try to get everything
working all at once. Implement the various pieces of the project one at a time and make sure
that each one is working before you move on to the next phase.
– 8 –
• Set up a milestone schedule. In the handout, I’ve suggested that you get the brick display up
and running by this coming Wednesday and the paddle moving by Friday. If you do, you’ll
have lots of time for the more interesting parts of the assignment and for implementing
extensions.
• Don’t try to extend the program until you get the basic functionality working. The following
section describes several ways in which you could extend the implementation. Several of
those are lots of fun. Don’t start them, however, until the basic assignment is working. If you
add extensions too early, you’ll find that the debugging process gets really difficult.
Possible extensions
This assignment is perfect for those of you who are looking for + or (dare I say it) ++ scores,
because there are so many possible extensions. Remember that if you are going to create a
version of your program with extensions, you should submit two versions of the assignment: the
basic version that meets all the assignment requirements and the extended version. Here are a
few ideas of for possible extensions (of course, we encourage you to use your imagination to
come up with other ideas as well):
• Add sounds. The version that is running as an applet on the CS 106A assignment page plays a
short bounce sound every time the ball collides with a brick or the paddle. This extension
turns out to be very easy. The starter project contains an audio clip file called bounce.au that
contains that sound. You can load the sound by writing
AudioClip bounceClip = MediaTools.loadAudioClip(“bounce.au”);
and later play it by calling
bounceClip.play();
The Java libraries do make some things easy.
• Add messages. The web version waits for the user to click the mouse before serving each ball
and announces whether the player has won or lost at the end of the game. These are just
GLabel objects that you can add and remove at the appropriate time.
• Improve the user control over bounces. The program gets rather boring if the only thing the
player has to do is hit the ball. It is far more interesting, if the player can control the ball by
hitting it at different parts of the paddle. The way the old arcade game worked was that the
ball would bounce in both the x and y directions if you hit it on the edge of the paddle from
which the ball was coming. The web version implements this feature.
• Add in the “kicker.” The arcade version of Breakout lured you in by starting off slowly. But,
as soon as you thought you were getting the hang of things, the program sped up, making life
just a bit more exciting. The applet version implements this feature by doubling the horizontal
velocity of the ball the seventh time it hits the paddle, figuring that’s the time the player is
growing complacent.
• Keep score. You could easily keep score, generating points for each brick. In the arcade
game, bricks were more valuable higher up in the array, so that you got more points for red
bricks than cyan bricks. You could display the score underneath the paddle, since it won’t get
in the way there.
• Use your imagination. What else have you always wanted a game like this to do?