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Examples of client and server socket programs make up the rest of this section. These programs illustrate how to use the sockets interface to establish a connection and transmit data between hosts using TCP.
To send data between stream sockets (type SOCK_STREAM),
the sockets must be connected.
``Sample UNIX server''
and
``Sample UNIX client''
show two programs that create such a connection.
The client program is relatively simple.
To initiate a connection, this program simply creates
a stream socket, then calls connect,
specifying the address of the socket to which
it wishes its socket connected. Provided that the target socket exists and
is prepared to handle a connection, connection will be complete,
and the program can begin to send
messages. Messages will be delivered in order without message
boundaries, as with pipes. The connection is destroyed when either
socket is closed (or soon thereafter). If a process persists
in sending messages after the connection is closed, a SIGPIPE
signal is sent to the process by the operating system.
Unless explicit action is taken to handle the signal (see
signal(S))
the process terminates, and the shell
prints the message broken pipe.
Forming a connection is asymmetrical; one process, such as the program in ``Sample UNIX client'', requests a connection with a particular socket, the other process accepts connection requests. Before a connection can be accepted a socket must be created and an address bound to it.
If there are several possible communicants, one socket might receive several requests for connections. As a result, a new socket is created for each connection. This new socket is the endpoint for communication within this process for this connection. A connection may be destroyed by closing the corresponding socket.
The program in
``Sample UNIX server''
is a simple example of a server.
It creates a socket to which it binds a name,
which it then advertises.
(In this case, it prints out the socket pathname.)
The program then calls listen for this socket.
Since several clients may attempt to connect more or less
simultaneously, a queue of pending connections is maintained
in the system address space. listen
marks the socket as willing to accept
connections and initializes the queue.
When a connection is requested, it is listed in the queue.
If the queue is full, an error status may be returned to the requester.
The maximum length of this queue is specified by the second argument of
listen; the maximum length is limited by the system.
Once the listen call has been completed,
the program enters an infinite loop.
On each pass through the loop, a new connection is
accepted and removed from the queue,
and thus a new socket for the connection is created.
The following code creates a server that waits for client connection requests. The manual page for each routine defines the necessary #include files when calling that routine.
This program creates a socket in the UNIX domain and binds a name to it. After printing the socket's name it begins a loop. Each time through the loop it accepts a connection and prints out messages from it. When the connection breaks, or a termination message comes through, the program accepts a new connection.
Sample UNIX server
1 #include <sys/types.h> 2 #include <sys/socket.h> 3 #include <sys/un.h> 4 #include <stdio.h>5 #define NAME "socket"
6 main() 7 { 8 int sock, msgsock, rval; 9 struct sockaddr_un server; 10 char buf[1024];
11 sock = socket(AF_UNIX, SOCK_STREAM, 0); 12 if (sock < 0) { 13 perror("opening stream socket"); 14 exit(1); 15 } 16 server.sun_family = AF_UNIX; 17 strcpy(server.sun_path, NAME); 18 if (bind(sock, (struct sockaddr *) &server, sizeof(struct sockaddr_un))) { 19 perror("binding stream socket"); 20 exit(1); 21 } 22 printf("Socket has name %s\n", server.sun_path); 23 listen(sock, 5); 24 for (;;) { 25 msgsock = accept(sock, 0, 0); 26 if (msgsock == -1) 27 perror("accept"); 28 else do { 29 bzero(buf, sizeof(buf)); 30 if ((rval = read(msgsock, buf, 1024)) < 0) 31 perror("reading stream message"); 32 else if (rval == 0) 33 printf("Ending connection\n"); 34 else 35 printf("-->%s\n", buf); 36 } while (rval > 0); 37 close(msgsock); 38 } 39 close(sock); 40 unlink(NAME); 41 }
This program connects to the socket named in the command line and sends a
one line message to that socket.
The form of the command line is:
programname pathname
Sample UNIX client
1 #include <sys/types.h> 2 #include <sys/socket.h> 3 #include <sys/un.h> 4 #include <stdio.h>5 #define DATA "Half a league, half a league . . ."
6 main(argc, argv) 7 int argc; 8 char *argv[]; 9 { 10 int sock; 11 struct sockaddr_un server; 12 char buf[1024];
13 if (argc < 2) { 14 printf("usage:%s <pathname>", argv[0]); 15 exit(1); 16 }
17 sock = socket(AF_UNIX, SOCK_STREAM, 0); 18 if (sock < 0) { 19 perror("opening stream socket"); 20 exit(1); 21 } 22 server.sun_family = AF_UNIX; 23 strcpy(server.sun_path, argv[1]);
24 if (connect(sock, (struct sockaddr *) &server, sizeof(struct sockaddr_un)) < 0) { 25 close(sock); 26 perror("connecting stream socket"); 27 exit(1); 28 } 29 if (write(sock, DATA, sizeof(DATA)) < 0) 30 perror("writing on stream socket"); 31 close(sock); 32 }