Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to write a little program to send and receive UDP traffic and receive commands via an HTTP interface. The HTTP server lives in one multiprocessing.Process; the UDP server lives in another. The two processes communicate via a python multiprocessing.Pipe. I've attached the complete code below.

I have 2 related problems:

  • How do I handle multiple file descriptors/kevents with kqueue in python (socket file descriptor works, pipe file descriptor doesn't appear to- not sure if the pipe I'm using is equivalent to a file)?
  • How do I differentiate between these kevents so I can apply different functions when the pipe is to be read vs the socket?

Pseudo code for what I'd like my UDP server to do:

kq = new kqueue
udpEvent = kevent when socket read
pipeEvent = kevent when pipe read
while:
    for event in kq.conrol([udpEvent, pipeEvent]):
        if event == udpEvent:
             # do something
        elif event == pipeEvent:
             print "HTTP command via pipe:", pipe.recv()

Right now, the UDP server recognizes socket events and reads off the socket correctly. However, when I add the pipe kevent to the kqueue, the program spits out pipe events nonstop. I'm setting the filter as pipe has been written, but I assume either 1) this is wrong 2) more specifically, the python multiprocessing.Pipe is like a regular unix pipe and needs to be handled differently.

.....
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>
<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 ^C<select.kevent ident=4297866384 filter=-29216 flags=0x4000 fflags=0x1 data=0x16 udata=0x4000000000000>

main.py

import sys
from multiprocessing import Process, Pipe
# from userinterface import OSXstatusbaritem # use like so: OSXstatusbaritem.start(pipe)
from server import Server
import handler # UI thingy

# For UI, use simple HTTP server with various endpoints
# open a connection: localhost:[PORT]/open/[TARGET_IP]

def startServer(pipe):
    UDP_IP = "127.0.0.1"
    UDP_PORT = 9000

    print "starting server"
    s = Server(pipe)
    s.listen(UDP_IP, UDP_PORT)
    print "finishing server"

import BaseHTTPServer
def startUI(pipe):
    HTTP_PORT = 4567
    server_class = BaseHTTPServer.HTTPServer
    myHandler = handler.handleRequestsUsing(pipe)
    httpd = server_class(('localhost', 4567), myHandler)
    try:
        httpd.serve_forever()
    except KeyboardInterrupt:
          pass
    httpd.server_close()

def main():
    # Named full duplex pipe for communicating between server process and UI
    pipeUI, pipeServer = Pipe()

    # Start subprocesses
    pServer = Process(target=startServer, args=(pipeServer,))
    pServer.start()
    startUI(pipeUI)
    pServer.join()

if __name__ == "__main__": sys.exit(main())

server.py (UDP)

import sys
import select # for kqueue
from socket import socket, AF_INET, SOCK_DGRAM
from multiprocessing import Process, Pipe

class Server:
    def __init__(self, pipe):
        self.pipe = pipe

    def listen (self, ipaddress, port):
        print "starting!"

        # Initialize listening UDP socket
        sock = socket(AF_INET, SOCK_DGRAM)
        sock.bind((ipaddress, port))

        # Configure kqueue
        kq = select.kqueue()
        # Event for UDP socket data available
        kevent0 = select.kevent( sock.fileno(),
                                 filter=select.KQ_FILTER_READ,
                                 flags=select.KQ_EV_ADD | select.KQ_EV_ENABLE | select.KQ_EV_CLEAR)
        # Event for message queue from other processes (ui)
        kevent1 = select.kevent( self.pipe.fileno(),
                                 filter=select.KQ_FILTER_WRITE,
                                 flags=select.KQ_EV_ADD | select.KQ_EV_ENABLE)                        

        # TODO: Figure out how to handle multiple kevents on kqueue
        # TODO: Need an event for TUN data

        # Start kqueue      
        while True:
            revents = kq.control([kevent0, kevent1], 1, None)
            for event in revents:
                print event
        kq.close()
        # close file descriptors (os.close(fd))

handler.py (HTTP interface)

import BaseHTTPServer

# Simple HTTP endpoints for controlling prototype Phantom implementation.
# The following commands are supported:
# 1. Open a connection via /open/[IP]:[PORT]
# 2. ????

class RequestHandler(BaseHTTPServer.BaseHTTPRequestHandler):
    pipe = None

    def __init__(self, pipe, *args):
        RequestHandler.pipe = pipe
        BaseHTTPServer.BaseHTTPRequestHandler.__init__(self, *args)

    def do_HEAD(s):
        s.send_response(200)
        s.send_header("Content-type", "application/json")
        s.end_headers()
    def do_GET(s):
        s.send_response(200)
        s.send_header("Content-type", "application/json")
        s.end_headers()

        # Open connection command
        if s.path.startswith('/open/'):
            addrStr = s.path[6:len(s.path)]
            (address, port) = tuple(filter(None, addrStr.split(':')))
            port = int(port)
            print "opening address: ", address, "port:", port
            RequestHandler.pipe.send(['open', address, port])

def handleRequestsUsing(logic):
    return lambda *args: RequestHandler(logic, *args)

UPDATE:

I rewrote the server listen method with select. For a slow little python prototype that won't use more than 3 or 4 fds, speed doesn't matter anyway. Kqueue will be the subject for another day.

def listen (self, ipaddress, port): print "starting!"

# Initialize listening non-blocking UDP socket
sock = socket(AF_INET, SOCK_DGRAM)
sock.setblocking(0)
sock.bind((ipaddress, port))

inputs = [sock, self.pipe] # stuff we read
outputs = [] # stuff we expect to write
while inputs:
    readable, writable, exceptional = select.select(inputs, outputs, inputs)

    for event in readable:
        if event is sock:
            self.handleUDPData( sock.recvfrom(1024) )
        if event is self.pipe:
            print "pipe event", self.pipe.recv()
share|improve this question
    
Not really an answer, but: you'd want the pipe filter to be "pipe is readable", not "pipe is writeable". But you also need to set the pipe non-blocking and collect partial inputs, and I have no idea off-hand how to do that. Also, revents = kq.control([kevent0, kevent1], 1, None) smells wrong: in general you do exactly one control-to-add per fd (and one control-to-delete to remove fd, although they're auto-cleaned-up on close), and then kcontrol(None,<args>) to read events. This call is inside a loop, re-adding. But again, I haven't looked closely at any of this. –  torek Jun 17 '13 at 6:50
    
Yup, I've tried to find some examples but haven't seen anything for python, and haven't had the heart to go into C mode for a day. So I rewrote it with select (see update) in all of 3 minutes and it works great, so good enough for a python prototype. –  nflacco Jun 23 '13 at 5:50

1 Answer 1

up vote 1 down vote accepted

I know this is an old question, but I can give you an example of kqueue socket polling that I am using for a multithreaded HTTP server, that I figured out after reading C source code and the man pages for kqueue.

#bsd socket polling
#I make all the relevant flags more C like to match the kqueue man pages
from select import kevent, kqueue
from select import KQ_EV_ADD as EV_ADD, KQ_EV_ONESHOT as EV_ONESHOT   
from select import KQ_EV_EOF as EV_EOF

from .common import Client_Thread #a parent class who's implementation is irrelevant to the question, lol

class BSD_Client(Client_Thread):
    def __init__(self, *args):
        Client_Thread.__init__(self, *args)
        #Make a kqueue object for the thread 
        kq = kqueue()
        #Make a one-shot kev for this kqueue for when the kill socket is
        #connected to. The connection is only made once, so why not tell
        #that to our kqueue? The default filter is EVFILT_READ, so we don't
        #need to specify that. The default flag is just EV_ADD.
        kill_kev = kevent(self.kill_fd, flags=EV_ADD|EV_ONESHOT)
        #using defaults for the client socket.
        client_kev = kevent(self.client_sock)
        #we only need to keep track of the kqueue's control func.
        #This also makes things prettier in the run func.
        self.control = kq.control
        #now, we add thel list of events we just made to our kqueue.
        #The first 0 means we want a list of at most 0 length in return.
        #the second 0 means we want no timeout (i.e. do this in a 
        #non-blocking way.) 
        self.control([client_kev, kill_kev], 0, 0)

    def run(self):
        while True:
            #Here we poll the kqueue object.
            #The empty list means we are adding no new events to the kqueue.
            #The one means we want a list of at most 1 element. Then None
            #Means we want block until an event is triggered.
            events = self.control([], 1, None)
            #If we have an event, and the event is for the kill socket 
            #(meaning somebody made a connection to it), then we break the 
            #loop and die.
            if events and events[0].ident == self.kill_fd:
                self.die()
                break
            #If all that is left is an EOF in our socket, then we break
            #the loop and die. Kqueues will keep returning a kevent
            #that has been read once, even when they are empty.
            if events and events[0].flags & EV_EOF:
                self.die()
                break
            #Finally, if we have an event that isn't for the kill socket and
            #does not have the EOF flag set, then there is work to do. If
            #the handle client function (defined in the parent class) returns
            #1, then we are done serving a page and we can die.
            if events and self.handle_client():
                self.die()
                break
        client.close()

All self.die does is puts the clients ip:port string onto a Queue used for messaging. A different thread gets that string from the queue, prints a message and joins the relevant thread object. Of course, I am not using an pipes for this, only sockets. I did find this on an online manpage for kqueue though

Fifos, Pipes
Returns when the there is data to read; data contains the number of
bytes available.

When the last writer disconnects, the filter will set EV_EOF in
flags. This may be cleared by passing in EV_CLEAR, at which point the
filter will resume waiting for data to become available before re-
turning

So perhaps in your udp server, where you loop through the revents list, you should do as the man page says? Actually, you don't even need to loop through a list that is a most 1 long. Perhaps your listen function should look something like this...

def listen(self, ip, port):
    print "Starting!"
    sock = socket.socket(AF_INET, SOCK_DGRAM)
    sock.bind((ip, port))
    kq = select.kqueue()
    kev0 = select.kevent(sock)
    kev1 = select.kevent(self.pipe)
    kq.control([kev0, kev1], 0, 0)
    while True: #this loop never breaks! so this whole function blocks forever like this
        revents = kq.control([], 1, None)
        if revents:
            event = revents[0]
            if event.flags & select.KQ_EV_EOF:
                new_event = select.kevent(event.ident, flags=select.KQ_EV_CLEAR)
                kq.control([new_event], 0, 0)
            else:
                print event

I really recommend importing the flags and functions the way I do though, It makes it more similar to the C based manpages you will have to compare to, and I think it looks prettier. I also want to point out that my class is a bit different from what you have, because each new client is going to get an instance of this, and each will run in it's own thread.

share|improve this answer
    
Awesome, that's really cool –  nflacco Mar 24 '14 at 2:55

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.