Your First Program

Your first program will be short and sweet. It is going to create a drawing area and draw a diagonal line across it. To create this program you will need to:
  1. Open Notepad and type in (or cut and paste) the program
  2. Save the program
  3. Compile the program with the Java compiler to create a Java applet
  4. Fix any problems
  5. Create an HTML web page to "hold" the Java Applet you created
  6. Run the Java applet
Here is the program we will use for this demonstration:
import java.awt.Graphics;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        g.drawLine(0, 0, 200, 200);
    }
}

Step 1 - Type in the program
Create a new directory to hold your program. Open up Notepad (or any other text editor that can create TXT files). Type or cut and paste the program into the Notepad window. This is important: When you type the program in, case matters. That means that you must type the uppercase and lowercase characters exactly as they appear in the program. Review the programmer's creed above. If you do not type it EXACTLY as shown, it is not going to work.
Step 2 - Save the file
Save the file to the filename FirstApplet.java in the directory that you created in step 1. Case matters in the filename. Make sure the 'F' and 'A' are uppercase and all other characters are lowercase, as shown.
Step 3 - Compile the program
Open an MS-DOS window. Change directory ("cd") to the directory containing FirstApplet.java. Type:
javac FirstApplet.java

Case matters! Either it will work, in which case nothing will be printed to the window, or there will be errors. If there are no errors, a file named FirstApplet.class will be created in the directory right next to FirstApplet.java.
(Make sure that the file is saved to the name FirstApplet.java and not FirstApplet.java.txt. This is most easily done by typing dir in the MS-DOS window and looking at the file name. If it has a .txt extension, remove it by renaming the file. Or run the Windows Explorer and select Options in the View menu. Make sure that the "Hide MD-DOS File Extensions for file types that are registered" box is NOT checked, and then look at the filename with the explorer. Change it if necessary.)
Step 4 - Fix any problems
If there are errors, fix them. Compare your program to the program above and get them to match exactly. Keep recompiling until you see no errors. If javac seems to not be working, look back at the previous section and fix your installation.
Step 5 - Create an HTML Page
Create an HTML page to hold the applet. Open another Notepad window. Type into it the following:

<html>
<body>
<applet code=FirstApplet.class width=200 height=200>
</applet>
</body>
</html>
Save this file in the same directory with the name applet.htm.
[If you have never worked with HTML before, please read How a Web Page Works. The applet tag is how you access a Java applet from a web page.]
Step 6 - Run the Applet
In your MS-DOS window, type:
appletviewer applet.htm

You should see a diagonal line running from the upper left corner to the lower right corner:



Pull the applet viewer a little bigger to see the whole line. You should also be able to load the HTML page into any modern browser like Netscape Navigator or Microsoft Internet Explorer and see approximately the same thing.
You have successfully created your first program!!!

Understanding What Just Happened
So what just happened? First, you wrote a piece of code for an extremely simple Java applet. An applet is a Java program that can run within a Web browser, as opposed to a Java application, which is a stand-alone program that runs on your local machine (Java applications are slightly more complicated and somewhat less popular, so we will start with applets). We compiled the applet using javac. We then created an extremely simple Web page to "hold" the applet. We ran the applet using appletviewer, but you can just as easily run it in a browser. The program itself is about 10 lines long:
import java.awt.Graphics;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        g.drawLine(0, 0, 200, 200);
    }
}

This is about the simplest Java applet you can create. To fully understand it you will have to learn a fair amount, particularly in the area of object oriented programming techniques. Since I am assuming that you have zero programming experience, what I would like you to do is focus your attention on just one line in this program for the moment:
g.drawLine(0, 0, 200, 200);

This is the line in this program that does the work. It draws the diagonal line. The rest of the program is scaffolding that supports that one line, and we can ignore the scaffolding for the moment. What happened here was that we told the computer to draw one line from the upper left hand corner (0,0) to the bottom right hand corner (200, 200). The computer drew it just like we told it to. That is the essence of computer programming!
(Note also that in the HTML page, we set the size of the applet's window in step 5 above to have a width of 200 and a height of 200.)
In this program, we called a method (a.k.a. function) called drawLine and we passed it four parameters (0, 0, 200, 200). The line ends in a semicolon. The semicolon acts like the period at the end of the sentence. The line begins with g., signifying that we want to call the method named drawLine on the specific object named g (which you can see one line up is of the class Graphics -- we will get into classes and methods of classes in much more detail later in this article).
A method is simply a command -- it tells the computer to do something. In this case, drawLine tells the computer to draw a line between the points specified: (0, 0) and (200, 200). You can think of the window as having its 0,0 coordinate in the upper left corner, with positive X and Y axes extending to the right and down. Each dot on the screen (each pixel) is one increment on the scale.


Try experimenting by using different numbers for the four parameters. Change a number or two, save your changes, recompile with javac and rerun after each change in appletviewer, and see what you discover.
What other functions are available besides drawLine? You find this out by looking at the documentation for the Graphics class. When you installed the Java development kit and unpacked the documentation, one of the files unloaded in the process is called java.awt.Graphics.html, and it is on your machine. This is the file that explains the Graphics class. On my machine, the exact path to this file is D:\jdk1.1.7\docs\api\java.awt.Graphics.html. On your machine the path is likely to be slightly different, but close -- it depends on exactly where you installed things. Find the file and open it. Up toward the top of this file there is a section called "Method Index." This is a list of all of the methods this class supports. The drawLine method is one of them, but you can see many others. You can draw, among other things:
  • Lines
  • Arcs
  • Ovals
  • Polygons
  • Rectangles
  • Strings
  • Characters
Read about and try experimenting with some of these different methods to discover what is possible. For example, try this code:
g.drawLine(0, 0, 200, 200);
        g.drawRect(0, 0, 200, 200);
        g.drawLine(200, 0, 0, 200);

It will draw a box with two diagonals (be sure to pull the window big enough to see the whole thing). Try drawing other shapes. Read about and try changing the color with the setColor method. For example:
import java.awt.Graphics;
import java.awt.Color;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        g.setColor(Color.red);
        g.fillRect(0, 0, 200, 200);
        g.setColor(Color.black);
        g.drawLine(0, 0, 200, 200);
        g.drawLine(200, 0, 0, 200);
    }
}

Note the addition of the new import line in the second line of the program. The output of this program looks like this:


One thing that might be going through your head right now is, "How did he know to use Color.red rather than simply red, and how did he know to add the second import line?" You learn things like that by example. Because I just showed you an example of how to call the setColor method, you now know that whenever you want to change the color you will use Color. followed by a color name as a parameter to the setColor method, and you will add the appropriate import line at the top of the program. If you look up setColor, it has a link that will tell you about the Color class, and in it is a list of all the valid color names along with techniques for creating new (unnamed) colors. You read that information, you store it in your head and now you know how to change colors in Java. That is the essence of becoming a computer programmer -- you learn techniques and remember them for the next program you write. You learn the techniques either by reading an example (as you did here) or by reading through the documentation or by looking at example code (as in the demo directory). If you have a brain that likes exploring and learning and remembering things, then you will love programming!
In this section, you have learned how to write linear, sequential code -- blocks of code that consist of method calls starting at the top and working toward the bottom (try drawing one of the lines before you draw the red rectangle and watch what happens -- it will be covered over by the rectangle and made invisible. The order of lines in the code sequence is important). Sequential lines of code form the basic core of any computer program. Experiment with all the different drawing methods and see what you can discover.

 Bugs and Debugging
 One thing that you are going to notice as you learn about programming is that you tend to make a fair number of mistakes and assumptions that cause your program to either: 1) not compile, or 2) produce output that you don't expect when it executes. These problems are referred to as bugs, and the act of removing them is called debugging. About half of the time of any programmer is spent debugging.
You will have plenty of time and opportunity to create your own bugs, but to get more familiar with the possibilities let's create a few. In your program, try erasing one of the semicolons at the end of a line and try compiling the program with javac. The compiler will give you an error message. This is called a compiler error, and you have to eliminate all of them before you can execute your program. Try misspelling a function name, leaving out a "{" or eliminating one of the import lines to get used to different compiler errors. The first time you see a certain type of compiler error it can be frustrating, but by experimenting like this -- with known errors that you create on purpose -- you can get familiar with many of the common errors.
A bug, also known as an execution (or run-time) error, occurs when the program compiles fine and runs, but then does not produce the output you planned on it producing. For example, this code produces a red rectangle with two diagonal lines across it:
g.setColor(Color.red);
        g.fillRect(0, 0, 200, 200);
        g.setColor(Color.black);
        g.drawLine(0, 0, 200, 200);
        g.drawLine(200, 0, 0, 200);

The following code, on the other hand, produces just the red rectangle (which covers over the two lines):
g.setColor(Color.black);
        g.drawLine(0, 0, 200, 200);
        g.drawLine(200, 0, 0, 200);
        g.setColor(Color.red);
        g.fillRect(0, 0, 200, 200);

The code is almost exactly the same but looks completely different when it executes. If you are expecting to see two diagonal lines, then the code in the second case contains a bug.
Here's another example:
g.drawLine(0, 0, 200, 200);
        g.drawRect(0, 0, 200, 200);
        g.drawLine(200, 0, 0, 200);

This code produces a black outlined box and two diagonals. This next piece of code produces only one diagonal:
g.drawLine(0, 0, 200, 200);
        g.drawRect(0, 0, 200, 200);
        g.drawLine(0, 200, 0, 200);

Again, if you expected to see two diagonals, then the second piece of code contains a bug (look at the second piece of code until you understand what went wrong). This sort of bug can take a long time to find because it is subtle.
You will have plenty of time to practice finding your own bugs. The average programmer spends about half of his or her time tracking down, finding and eliminating bugs. Try not to get frustrated when they occur -- they are a normal part of programming life.

Variables
 All programs use variables to hold pieces of data temporarily. For example, if at some point in a program you ask a user for a number, you will store it in a variable so that you can use it later.
Variables must be defined (or declared) in a program before you can use them, and you must give each variable a specific type. For example, you might declare one variable to have a type that allows it to hold numbers, and another variable to have a type that allows it to hold a person's name. (Because Java requires you to specifically define variables before you use them and state the type of value you plan to store in a variable, Java is called a strongly typed language. Certain languages don't have these requirements. In general, when creating large programs, strong typing tends to reduce the number of programming errors that you make.)
import java.awt.Graphics;
import java.awt.Color;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        int width = 200;
        int height = 200;
        g.drawRect(0, 0, width, height);
        g.drawLine(0, 0, width, height);
        g.drawLine(width, 0, 0, height);
    }
}

In this program, we have declared two variables named width and height. We have declared their type to be int. An int variable can hold an integer (a whole number such as 1, 2, 3). We have initialized both variables to 200. We could just as easily have said:
int width;
        width = 200;
        int height;
        height = 200;

The first form is simply a bit quicker to type.
The act of setting a variable to its first value is called initializing the variable. A common programming bug occurs when you forget to initialize a variable. To see that bug, try eliminating the initialization part of the code (the "= 200" part) and recompile the program to see what happens. What you will find is that the compiler complains about this problem. That's a very nice feature, by the way. It will save you lots of wasted time.
There are two types of variables in Java -- simple (primitive) variables and classes.
The int type is simple. The variable can hold a number. That is all that it can do. You declare an int , set it to a value and use it. Classes, on the other hand, can contain multiple parts and have methods that make them easier to use. A good example of a straightforward class is the Rectangle class, so let's start with it.
One of the limitations of the program we have been working on so far is the fact that it assumes the window is 200 by 200 pixels. What if we wanted to ask the window, "How big are you?," and then size our rectangle and diagonals to fit? If you go back and look on the documentation page for the Graphics class (java.awt.Graphics.html -- the file that lists all the available drawing functions), you will see that one of the functions is called getClipBounds. Click on this function name to see the full description. This function accepts no parameters but instead returns a value of type Rectangle. The rectangle it returns contains the width and height of the available drawing area. If you click on Rectangle in this documentation page you will be taken to the documentation page for the Rectangle class (java.awt.Graphics.html). Looking in the Variable Index section at the top of the page, you find that this class contains four variables named x, y, width and height, respectively. What we want to do, therefore, is get the clip boundary rectangle using getClipBounds and then extract the width and height from that rectangle and save the values in the width and height variables we created in the previous example, like this:
import java.awt.Graphics;
import java.awt.Color;
import java.awt.Rectangle;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        int width;
        int height;
        Rectangle r;

        r = g.getClipBounds();
        width = r.width - 1;
        height = r.height - 1;

        g.drawRect(0, 0, width, height);
        g.drawLine(0, 0, width, height);
        g.drawLine(width, 0, 0, height);
    }
}

When you run this example, what you will notice is that the rectangle and diagonals exactly fit the drawing area. Plus, when you change the size of the window, the rectangle and diagonals redraw themselves at the new size automatically. There are five new concepts introduced in this code, so let's look at them:
  1. First, because we are using the Rectangle class we need to import java.awt.Rectangle on the third line of the program.
  2. We have declared three variables in this program. Two (width and height) are of type int and one (r) is of type Rectangle.
  3. We used the getClipBounds function to get the size of the drawing area. It accepts no parameters so we passed it none ("()"), but it returns a Rectangle. We wrote the line, "r = g.getClipBounds();" to say, "Please place the returned rectangle into the variable r."
  4. The variable r, being of the class Rectangle, actually contains four variables -- x, y, width, and height (you learn these names by reading the documentation for the Rectangle class). To access them you use the "." (dot) operator. So the phrase "r.width" says, "Inside the variable r retrieve the value named width." That value is placed into our local variable called width. In the process, we subtracted 1. Try leaving the subtraction out and see what happens. Also try subtracting five instead and see what happens.
  5. Finally, we used width and height in the drawing functions.
One question commonly asked at this point is, "Did we really need to declare variables named width and height?" The answer is, "No." We could have typed r.width - 1 directly into the drawing function. Creating the variables simply makes things a little easier to read, and it's therefore a good habit to fall into. Java supports several simple variable types. Here are three of the most common:
  • int - integer (whole number) values (1, 2, 3...)
  • float - decimal values (3.14159, for example)
  • char - character values (a, b, c...)
You can perform math operations on simple types. Java understands + (addition), - (subtraction), * (multiplication), / (division) and several others. Here's an example of how you might use these operations in a program. Let's say that you want to calculate the volume of a sphere with a diameter of 10 feet. The following code would handle it:
float diameter = 10;
float radius;
float volume;

radius = diameter / 2.0;
volume = 4.0 / 3.0 * 3.14159 * radius * radius * radius;

The first calculation says, "Divide the value in the variable named diameter by 2.0 and place the result in the variable named radius." You can see that the "=" sign here means, "Place the result from the calculation on the right into the variable named on the left."

Looping
One of the things that computers do very well is perform repetitive calculations or operations. In the previous sections, we have seen how to write "sequential blocks of code," so the next thing we should discuss is the techniques for causing a sequential block of code to occur repeatedly. For example, let's say that I ask you to draw the following figure:


A good place to start would be to draw the horizontal lines, like this:


One way to draw the lines would be to create a sequential block of code:
import java.awt.Graphics;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        int y;
        y = 10;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
        y = y + 25;
        g.drawLine(10, y, 210, y);
    }
}

(For some new programmers, the statement "y = y + 25;" looks odd the first time they see it. What it means is, "Take the value currently in the variable y, add 25 to it and place the result back into the variable y." So if y contains 10 before the line is executed, it will contain 35 immediately after the line is executed.)
Most people who look at this code immediately notice that it contains the same two lines repeated over and over. In this particular case the repetition is not so bad, but you can imagine that if you wanted to create a grid with thousands of rows and columns, this approach would make program-writing very tiring. The solution to this problem is a loop, as shown below:
import java.awt.Graphics;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        int y;
        y = 10;
        while (y <= 210)
        {
            g.drawLine(10, y, 210, y);
            y = y + 25;
        }
    }
}

When you run this program, you will see that it draws nine horizontal lines 200 pixels long.
The while statement is a looping statement in Java. The statement tells Java to behave in the following way: At the while statement, Java looks at the expression in the parentheses and asks, "Is y less than or equal to 210?"
  • If the answer is yes, then Java enters the block of code bracketed by braces -- "{" and "}". The looping part occurs at the end of the block of code. When Java reaches the ending brace, it loops back up to the while statement and asks the question again. This looping sequence may occur many times.
  • If the answer is no, it skips over the code bracketed by braces and continues.
So you can see that when you run this program, initially y is 10. Ten is less than 210, so Java enters the block in braces, draws a line from (10,10) to (210, 10), sets y to 35 and then goes back up to the while statement. Thirty-five is less than 210, so Java enters the block in braces, draws a line from (10,35) to (210, 35), sets y to 60 and then goes back up to the while statement. This sequence repeats until y eventually gets to be greater than 210. Then the program quits. We can complete our grid by adding a second loop to the program, like this:
import java.awt.Graphics;

public class FirstApplet extends java.applet.Applet
{

    public void paint(Graphics g)
    {
        int x, y;
        y = 10;
        while (y <= 210)
        {
            g.drawLine(10, y, 210, y);
            y = y + 25;
        }
        x = 10;
        while (x <= 210)
        {
            g.drawLine(x, 10, x, 210);
            x = x + 25;
        }
    }
}

You can see that a while statement has three parts:
  • There is an initialization step that sets y to 10.
  • Then there is an evaluation step inside the parentheses of the while statement.
  • Then, somewhere in the while statement there is an increment step that increases the value of y.
Java supports another way of doing the same thing that is a little more compact than a while statement. It is called a for statement. If you have a while statement that looks like this:
y = 10;
        while (y <= 210)
        {
            g.drawLine(10, y, 210, y);
            y = y + 25;
        }

then the equivalent for statement looks like this:
for (y = 10; y <= 210; y = y + 25)
        {
            g.drawLine(10, y, 210, y);
        }

You can see that all the for statement does is condense the initialization, evaluation and incrementing lines into a short, single line. It simply shortens the programs you write, nothing more.
While we are here, two quick points about loops:
  • In many cases, it would be just as easy to initialize y to 210 and then decrement it by 25 each time through the loop. The evaluation would ask, "Is y greater than or equal to 10?" The choice is yours. Most people find it easier to add than subtract in their heads, but you might be different.
  • The increment step is very important. Let's say you were to accidentally leave out the part that says "y = y + 25;" inside the loop. What would happen is that the value of y would never change -- it would always be 10. So it would never become greater than 210 and the loop would continue forever (or until you stop it by turning off the computer or closing the window). This condition is called an infinite loop. It is a bug that is pretty common.
To get some practice with looping, try writing programs to draw the following figures: