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Multi-threaded Client/Server Socket Class

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10 Feb 2009 18  
A multi-threaded based Client/Server Socket Communication class

Screenshots

Note: The demo can be started in Client or Server mode, executed with "/C" (or "/CLIENT") or "/S" (or "/SERVER", which is the default).

Server Socket App - Screenshot

Client Socket App - Screenshot

Introduction

This article is about a client/server multi-threaded socket class. The thread is optional since the developer/designer is still responsible for deciding if he/she needs it. There are other Socket classes here and other places over the Internet, but none of them can provide feedback (event detection) to your application like this one does. It provides you with the following events detection: connection established, connection dropped, connection failed and data reception (including 0 byte packet).

Description

This article presents a new socket class which supports both TCP and UDP communication. It provides some advantages compared to other classes that you may find here or on some other Socket Programming articles. First of all, this class doesn't have any limitation like the need to provide a window handle to be used. This limitation is bad if all you want is a simple console application. So, this library doesn't have such a limitation. It also provides threading support automatically for you, which handles the socket connection and disconnection to a peer. It also features some options not yet found in any socket classes that I have seen so far. It supports both client and server sockets. A server socket can be referred as to a socket that can accept many connections. A client socket is a socket that is connected to a server socket. You may still use this class to communicate between two applications without establishing a connection. In the latter case, you will want to create two UDP server sockets (one for each application). This class also helps reduce coding needed to create chat-like applications and IPC (Inter-Process Communication) between two or more applications (processes). Reliable communication between two peers is also supported with TCP/IP with error handling. You may want to use the smart addressing operation to control the destination of the data being transmitted (UDP only). TCP operation of this class deals only with communication between two peers.

Now for those not familiar with IP Socket, the following section will give some details on how it works. This is also the goal with this article: to explain the basic functionality behind socket objects.

TCP/IP Stack

The TCP/IP stack is shorter than the OSI one:

TCP is a connection-oriented protocol, while UDP (User Datagram Protocol) is a connectionless protocol.

IP Datagrams

The IP layer provides a connectionless and unreliable delivery system. It considers each datagram independently of the others. Any association between datagrams must be supplied by the higher layers. The IP layer supplies a checksum that includes its own header. The header includes the source and destination addresses. The IP layer handles routing through the Internet. It is also responsible for breaking up large datagrams into smaller ones for transmission and reassembling them at the other end.

UDP

UDP is also connectionless and unreliable. What it adds to IP is a checksum for the contents of the datagram and port numbers. These are used to give a client/server model: see later.

TCP

TCP supplies logic to give a reliable connection-oriented protocol above IP. It provides a virtual circuit that two processes can use to communicate.

Internet Addresses

In order to use a service, you must be able to find it. The Internet uses an address scheme for machines so that they can be located. The address is a 32-bit integer which gives the IP address. This encodes a network ID and more addressing. The network ID falls into various classes according to the size of the network address.

Network Address

Class A uses 8 bits for the network address with 24 bits left over for other addressing. Class B uses 16-bit network addressing; class C uses 24-bit network addressing and class D uses all 32.

Subnet Address

Internally, the Unix network is divided into subnetworks. Building 11 is currently on one subnetwork and uses 10-bit addressing, allowing 1024 different hosts.

Host Address

8 bits are finally used for host addresses within our subnet. This places a limit of 256 machines that can be on the subnet.

Total Address

The 32-bit address is usually written as 4 integers separated by dots.

Port Addresses

A service exists on a host and is identified by its port. This is a 16-bit number. To send a message to a server, you send it to the port for that service of the host that it is running on. This is not location transparency! Some of these ports are "well known." For example:

tcpmux 1 TCP
echo 7 UDP
echo 7 TCP
systat 11 TCP
netstat 15 TCP
ftp-data 20 TCP File Transfer Protocol (data)
ftp 21 TCP File Transfer Protocol
smtp 25 TCP Simple Mail Transfer Protocol
time 37 TCP Time Server
time 37 UDP Time Server
name 42 UDP Name Server
whois 43 TCP nicname
domain 53 UDP
domain 53 TCP
tftp 69 UDP
rje 77 TCP
finger 79 TCP
link 87 TCP ttylink
supdup 95 TCP
hostname 101 TCP hostname
pop-2 109 TCP Post Office Protocol
uucp-path 117 TCP
nntp 119 TCP Network News Transfer Protocol
ntp 123 TCP Network Time Protocol

Ports in the region 1-255 are reserved by TCP/IP. The system may reserve more. User processes may have their own ports above 1023. The function getservbyname can be used to find the port for a service that is registered.

Sockets

A socket is a data structure maintained by the system to handle network connections. A socket is created using the call socket. It returns an integer that is like a file descriptor. In fact, under Windows, this handle can be used with the ReadFile and WriteFile functions.

#include <sys/types.h>
#include <sys/socket.h>
int socket(int family, int type, int protocol);

Here, family will be AF_INET for IP communications, protocol will be zero and type will depend on whether TCP or UDP is used. Two processes wishing to communicate over a network create a socket each. These are similar to two ends of a pipe, but the actual pipe does not yet exist.

Connection Oriented (TCP)

One process (server) makes its socket known to the system using bind. This will allow other sockets to find it. It then "listens" on this socket to "accept" any incoming messages. The other process (client) establishes a network connection to it and then the two exchange messages. As many messages as needed may be sent along this channel, in either direction.

Server

  • Create endpoint (socket())
  • Bind address (bind())
  • Specify queue (listen())
  • Wait for connection (accept())
  • Transfer data (read()/write())

Client

  • Create endpoint (socket())
  • Connect to server (connect())
  • Transfer data (read()/write())

Connectionless (UDP)

In a connectionless protocol, both sockets have to make their existence known to the system using bind. This is because each message is treated separately, so the client has to find the server each time it sends a message and vice versa. When bind is called, it binds to a new port. It cannot bind to one already in use. If you specify the port as zero, the system gives you a currently unused port. Because of this extra task on each message send, the processes do not use read/write, but recvfrom/sendto. These functions take as parameters the socket to write to and the address of the service on the remote machine.

Server

  • Create endpoint (socket())
  • Bind address (bind())
  • Transfer data (sendto()/recvfrom())

Client

  • Create endpoint (socket())
  • Bind address (bind()) (optional if connect is called)
  • Connect to server (connect())
  • Transfer data (sendto()/recvfrom())

Version History

////////////////////////////////////////////////////////////////////////
//    File:        SocketComm.cpp
//    Version:     1.4
//
//  1.0 - Initial release.
//  1.1 - Added support for Smart Addressing mode
//  1.2 - Fixed various issues with address list (in UDP mode)
//  1.3 - Fix bug when sending message to broadcast address
//  1.4 - Add UDP multicast support
////////////////////////////////////////////////////////////////////////

How to Use

This class can be used to create a TCP or UDP socket. Its use is very simple. First of all, the CSocketComm class is not completed by itself for server operation. This class must be derived. Fortunately, only two functions need to be created, OnDataReceived and OnEvent. The default functions don't do anything. Now to create and start a server socket, do the following:

// To use TCP socket
// no smart addressing - we use connection oriented
m_SocketObject.SetSmartAddressing( false ); 
m_SocketObject.CreateSocket( m_strPort, AF_INET, SOCK_STREAM,0); // TCP

// To use UDP socket
m_SocketObject.SetSmartAddressing( true );
m_SocketObject.CreateSocket( m_strPort, 
   AF_INET, SOCK_DGRAM, SO_BROADCAST); // UDP

// Now you may start the server/client thread to do the work for you...
m_SocketObject.WatchComm();

To create and start a client socket, do the following:

// To use TCP socket
m_SocketObject.ConnectTo( strServer, m_strPort, AF_INET, SOCK_STREAM); // TCP

// To use UDP socket
m_SocketObject.ConnectTo( strServer, m_strPort, AF_INET, SOCK_DGRAM); // UDP

// Now you may start the server/client thread to do the work for you...
m_SocketObject.WatchComm();

References

History

  • Aug 31, 2002: Updated source code
  • Mar 01, 2004: Updated source code
  • Apr 02, 2004: Fixed bug when sending message to broadcast address
  • Feb 07, 2009: Updated source code (Visual Studio 2005 project)

License

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