The example featured in this section consists of two applications: a client and a server. The server continuously receives datagram packets over a datagram socket. Each datagram packet received by the server indicates a client request for a quotation. When the server receives a datagram, it replies by sending a datagram packet that contains a one-line "quote of the moment" back to the client.
The client application in this example is fairly simple. It sends a single datagram packet to the server indicating that the client would like to receive a quote of the moment. The client then waits for the server to send a datagram packet in response.
Two classes implement the server application: QuoteServer
and QuoteServerThread
. A single class implements the client application: QuoteClient
.
Let's investigate these classes, starting with the class that contains the main
method for the server application.
Working With a Server-Side Application contains an applet version of the QuoteClient
class.
The
QuoteServer
class, shown here in its entirety, contains a single method: the main
method for the quote server application. The main
method simply creates a new QuoteServerThread
object and starts it:
import java.io.*; public class QuoteServer { public static void main(String[] args) throws IOException { new QuoteServerThread().start(); } }
The QuoteServerThread
class implements the main logic of the quote server.
QuoteServerThread
ClassWhen created, the
QuoteServerThread
creates a DatagramSocket
on port 4445 (arbitrarily chosen). This is the DatagramSocket
through which the server communicates with all of its clients.
public QuoteServerThread() throws IOException { this("QuoteServer"); } public QuoteServerThread(String name) throws IOException { super(name); socket = new DatagramSocket(4445); try { in = new BufferedReader( new FileReader("one-liners.txt")); } catch (FileNotFoundException e) System.err.println("Couldn't open quote file. " + "Serving time instead."); } }
Remember that certain ports are dedicated to well-known services and you cannot use them. If you specify a port that is in use, the creation of the DatagramSocket
will fail.
The constructor also opens a BufferedReader
on a file named one-liners.txt which contains a list of quotes. Each quote in the file is on a line by itself.
Now for the interesting part of the QuoteServerThread
: its run
method. The run
method overrides run
in the Thread
class and provides the implementation for the thread. For information about threads, see
Defining and Starting a Thread.
The run
method contains a while
loop that continues as long as there are more quotes in the file. During each iteration of the loop, the thread waits for a DatagramPacket
to arrive over the DatagramSocket
. The packet indicates a request from a client. In response to the client's request, the QuoteServerThread
gets a quote from the file, puts it in a DatagramPacket
and sends it over the DatagramSocket
to the client that asked for it.
Let's look first at the section that receives the requests from clients:
byte[] buf = new byte[256]; DatagramPacket packet = new DatagramPacket(buf, buf.length); socket.receive(packet);
The first statement creates an array of bytes which is then used to create a DatagramPacket
. The DatagramPacket
will be used to receive a datagram from the socket because of the constructor used to create it. This constructor requires only two arguments: a byte array that contains client-specific data and the length of the byte array. When constructing a DatagramPacket
to send over the DatagramSocket
, you also must supply the Internet address and port number of the packet's destination. You'll see this later when we discuss how the server responds to a client request.
The last statement in the previous code snippet receives a datagram from the socket (the information received from the client gets copied into the packet). The receive method waits forever until a packet is received. If no packet is received, the server makes no further progress and just waits.
Now assume that, the server has received a request from a client for a quote. Now the server must respond. This section of code in the run method constructs the response:
String dString = null; if (in == null) dString = new Date().toString(); else dString = getNextQuote(); buf = dString.getBytes();
If the quote file did not get opened for some reason, then in
equals null. If this is the case, the quote server serves up the time of day instead. Otherwise, the quote server gets the next quote from the already opened file. Finally, the code converts the string to an array of bytes.
Now, the run
method sends the response to the client over the DatagramSocket
with this code:
InetAddress address = packet.getAddress(); int port = packet.getPort(); packet = new DatagramPacket(buf, buf.length, address, port); socket.send(packet);
The first two statements in this code segment get the Internet address and the port number, respectively, from the datagram packet received from the client. The Internet address and port number indicate where the datagram packet came from. This is where the server must send its response. In this example, the byte array of the datagram packet contains no relevant information. The arrival of the packet itself indicates a request from a client that can be found at the Internet address and port number indicated in the datagram packet.
The third statement creates a new DatagramPacket
object intended for sending a datagram message over the datagram socket. You can tell that the new DatagramPacket
is intended to send data over the socket because of the constructor used to create it. This constructor requires four arguments. The first two arguments are the same required by the constructor used to create receiving datagrams: a byte array containing the message from the sender to the receiver and the length of this array. The next two arguments are different: an Internet address and a port number. These two arguments are the complete address of the destination of the datagram packet and must be supplied by the sender of the datagram. The last line of code sends the DatagramPacket
on its way.
When the server has read all the quotes from the quote file, the while
loop terminates and the run
method cleans up:
socket.close();
The
QuoteClient
class implements a client application for the QuoteServer
. This application sends a request to the QuoteServer
, waits for the response, and, when the response is received, displays it to the standard output. Let's look at the code in detail.
The QuoteClient
class contains one method, the main
method for the client application. The top of the main
method declares several local variables for its use:
int port; InetAddress address; DatagramSocket socket = null; DatagramPacket packet; byte[] sendBuf = new byte[256];
First, the main
method processes the command-line arguments used to invoke the QuoteClient
application:
if (args.length != 1) { System.out.println("Usage: java QuoteClient <hostname>"); return; }
The QuoteClient
application requires one command-line arguments: the name of the machine on which the QuoteServer
is running.
Next, the main
method creates a DatagramSocket
:
DatagramSocket socket = new DatagramSocket();
The client uses a constructor that does not require a port number. This constructor just binds the DatagramSocket
to any available local port. It doesn't matter what port the client is bound to because the DatagramPacket
s contain the addressing information. The server gets the port number from the DatagramPacket
s and send its response to that port.
Next, the QuoteClient
program sends a request to the server:
byte[] buf = new byte[256]; InetAddress address = InetAddress.getByName(args[0]); DatagramPacket packet = new DatagramPacket(buf, buf.length, address, 4445); socket.send(packet);
The code segment gets the Internet address for the host named on the command line (presumably the name of the machine on which the server is running). This InetAddress
and the port number 4445 (the port number that the server used to create its DatagramSocket
) are then used to create DatagramPacket
destined for that Internet address and port number. Therefore the DatagramPacket
will be delivered to the quote server.
Note that the code creates a DatagramPacket
with an empty byte array. The byte array is empty because this datagram packet is simply a request to the server for information. All the server needs to know to send a response--the address and port number to which reply--is automatically part of the packet.
Next, the client gets a response from the server and displays it:
packet = new DatagramPacket(buf, buf.length); socket.receive(packet); String received = new String(packet.getData(), 0, packet.getLength()); System.out.println("Quote of the Moment: " + received);
To get a response from the server, the client creates a "receive" packet and uses the DatagramSocket
receive method to receive the reply from the server. The receive method waits until a datagram packet destined for the client comes through the socket. Note that if the server's reply is somehow lost, the client will wait forever because of the no-guarantee policy of the datagram model. Normally, a client sets a timer so that it doesn't wait forever for a reply; if no reply arrives, the timer goes off and the client retransmits.
When the client receives a reply from the server, the client uses the getData method to retrieve that data from the packet. The client then converts the data to a string and displays it.
After you've successfully compiled the server and the client programs, you run them. You have to run the server program first. Just use the Java interpreter and specify the QuoteServer
class name.
Once the server has started, you can run the client program. Remember to run the client program with one command-line argument: the name of the host on which the QuoteServer
is running.
After the client sends a request and receives a response from the server, you should see output similar to this:
Quote of the Moment: Good programming is 99% sweat and 1% coffee.