CSE534 Assignment 2 SUNY Korea (Fall 2015) Delvison Castillo ([email protected])
This application is meant to allow users using the client application to connect to a server and exchange messages. Essentially, it is meant to create a chatroom that is hosted by a server. The chatroom has the following requirements:
- Each username in the chatroom must be unique.
- The server can force the disconnection of a client.
- The client can request disconnection from the server.
- The server must monitor the connection statuses of all connected clients.
- All messages sent to the server by a client must be propagated to all other clients.
The server module is implemented in the chat_server.py module. This implementation does not utilize a GUI and is completely run in the Command Line Interface (CLI). Initially, the server creates a socket bounded to a given port number and stores its instance in a hash global variable that associates a username with a socket object. The list of sockets as well as other global variables can be viewed below:
HOST = socket.gethostbyname(socket.gethostname()) # current machine's hostname
SOCKET_LIST = {} # dictionary of sockets and users = {username:socket,...}
RECV_BUFR = 4096 # buffer size for messages
PORT = 3001 # port of server being connected to
STAR = "[*] " # event marker -- tells when a person enters or leaves room
DEBUG = False # debugger flag
COMMANDS = ["HELP","KICK","LIST_USERS","EXIT"] # list of available commands
The program entires a while loop and simply adds newly connected users to the SOCKET_LIST variable.
The server module can be executed by the following command:
python3 chat_server.py
New connections as well as input into stdin is handled using python's built-in select module. The select module is a direct interface to the underlying operating system implementation that allows it to monitor sockets, open files, and pipes until they become readable or writable. Below is an example of how select was used in this server implementation.
while 1:
ready_to_read,ready_to_write,in_error =
select.select(all_sockets,[],[],0)
for sock in ready_to_read:
# a new connection request is received
if sock == server_socket:
...
# sending a message
elif sock == sys.stdin:
...
# a message from a client is received
else:
...
Disconnections are also handled by python's select module as a client who disconnects sends a TCP packet with the FIN bit set to 1. Select detects a new message in the socket and interprets it as a disconnected user. The news about the disconnected user is then broadcasted to the rest of the clients in the chat. In addition, on detection of a timeout, the server removes the corresponding user like so:
def recv_msg(server_socket, sock):
"""
Recieves a message from the given socket.
"""
# receive message
try:
...
except(UnboundLocalError):
print("ERROR: Attempted to send to user that doesnt exist.")
except(ConnectionResetError,NameError, socket.timeout) as e:
msg = STAR+username+" exited."
print("\n"+msg)
send_msg_to_all(server_socket, sock, username, msg)
Connected clients are stored in a dictionary global variable. When the server wants to send a message to all its clients, it simply iterates through the data structure like so:
def send_msg_to_all(server_socket, senders_socket,senders_username, message):
"""
Sends a message to all other connected clients.
"""
message = "["+datetime.now().strftime('%H:%M:%S')+"] "+message
for username, socket in SOCKET_LIST.items():
if socket != server_socket and socket != senders_socket:
try:
# attempt to send message to client
socket.send(bytes(message,'UTF-8'))
except:
# close socket if message fails
socket.close()
# remove client from the sockets list
remove_user(username)
# print out prompt message
prompt()
Here we can see that the server removes any client that they are not able to reach upon sending a message.
It is clear that in this chatroom setting it is important to distinguish regular messages from events such as when a user enters or leaves the chat. The server distinguishes these messages by appending the [*] special string to the start of a message. The clients then cautiously examine the messages containing this special string to decide whether an event has occurred or not.
In addition to being able to send messages the server module also supports the 4 following commands HELP, KICK, LIST_USERS, and EXIT. In order to kick a given user out one must type KICK followed by the name of the user. This action can be viewed below from the perspective of the host.
##################################################################
Chat running 10.12.9.244:3001
##################################################################
[21:11:34] Host >
[*] Spider-Man entered.
USERS: [Host,Spider-Man]
[21:12:28] Host >
[*] Ironman entered.
USERS: [Ironman,Host,Spider-Man]
[21:12:35] Host >
[21:12:52] Spider-Man > Hey Ironman, what's up?
[21:12:52] Host >
[21:14:04] Ironman > Not much, just getting ready to reveal your identity
as Peter Parker to the rest of the world!
[21:14:04] Host > KICK Ironman
[*] Ironman has been kicked out.
USERS: [Host,Spider-Man]
[21:14:26] Host >
The client module was implemented in the chat_client.py module. This implementation can be executed in either GUI or CLI environments. The commands to run the client in CLI or GUI mode are:
python chat_client.py -c #cli mode
python chat_client.py #gui mode
The GUI contains input fields for a server's IP and port as well as a desired username. The client will attempt to connect to the server upon clicking connect. If the server already has a client connected with a given username then it will send a NACK to the client disallowing it a connection. Once connected, the user can send messages to the server by typing them in the textbox towards the bottom and hitting the enter key. Connected users can be viewed in a list off to the left. A screenshot of the GUI can be seen below.
The GUI runs on the main thread. Upon a successful connection, a new thread is spawned to handle all socket interactions with a reference of the GUI passed so that the thread can update it accordingly.
The server marks special events such as a new user entering or a user exiting by appending the special string [*] at the beginning of a message. The client application simply filters for these special strings to determine if it should add or remove a user to it's user list. This process can be seen below.
def recv_msg(gui,socket):
"""
Allows the program to recieve a message on the given socket. Takes in the
GUI object and the active socket connected to the server. This function is
also responsible for adding users into the chatroom in the GUI.
"""
data = socket.recv(RECV_BUFR)
if not data :
gui.disconnect()
else:
# decode newly received message
data = data.decode()
# gui.chat.insert(END,"\n"+data)
gui.display("\n"+data)
# a new user has entered. Add to the GUI
if "[*]" in data and "entered" in data and len(data.strip()) >= 1:
gui.add_user(data.split(" ")[-2])
# a user has left. Remove from the GUI
if "[*]" in data and "exited" in data:
gui.remove_user(data.split(" ")[-2])
Sending messages in this implementation requires little explanation as it is mostly self explanatory. The textbox in the gui where the user types a message is bound to a listener that executes the send message function when it detects that the return key has been hit. The send message function is as simple as:
def send_msg(server_socket,msg):
"""
Allows a user to send a message to the chat server using the given socket.
"""
server_socket.send(bytes(msg,'UTF-8'))
It is worth noting that strings must be encoding as bytes in UTF-8 format to be sent over socket.
In order to disconnect from the server and leave the chat, a user need only click the disconnect button. This action results in the program closing the socket and removing all users from the user list in the GUI.
It was originally planned for this application to also support web-based clients who could connect via the browser. Since HTTP is a protocol that can only deliver static web pages from a server to a client, an additional protocol has to be used in order to maintain a constant open connection between the client and server. The most widely used protocol for doing so is one called websockets. The issue with websockets is that it requires a special handshake to initiate a connection. An example of the handshake initiated by the client to the server can be seen below.
GET /chat HTTP/1.1
Host: example.com:8000
Upgrade: websocket
Connection: Upgrade
Sec-WebSocket-Key: dGhlIHNhbXBsZSBub25jZQ==
Sec-WebSocket-Version: 13
The most important field in this message is the Sec-WebSocket-Key field that holds a unique key which the server must read, concatenate the special string 258EAFA5-E914-47DA-95CA-C5AB0DC85B11 to, SHA-1 hash the result, and finally return the base64 encoding of the hash. This process was written in the following function:
def websock_handshake (client, data):
"""
Performs a standard websocket handshake.
"""
key = (re.search('Sec-WebSocket-Key:\s+(.*?)[\n\r]+', data).groups()[0].strip())
shake = "HTTP/1.1 101 Switching Protocols\r\n"
shake += "Upgrade: websocket\r\n"
shake += "Connection: Upgrade\r\n"
shake += "Sec-WebSocket-Accept: %s \r\n\r\n" % sha1_handshake_key(key)
return client.send(bytes(shake,'UTF-8'))
This worked successfully with the implemented python server and a php client implementation using websockets. Yet, it is important to note that message exchanges in the websocket protocol also require special formatting. Failure to correctly produce the websocket message format prevented the successful implementation of a web-based client. The easiest way to have fixed this would be to scrap the python server that was written and re-implement a server using a language with built-in support such as php.
In order to run this application in GUI mode, ensure that python's tkinter module is installed on your machine. In the arch-linux computer used to develop this application this was done with the following command:
pacman -S tk
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