I'll offer my take on how to approach this problem. Within the
multiprocessing module the
Queue IPC mechanisms are really the best way to go; in spite of the added complexity you allude to, it's worth learning how they work. The
Pipe is fairly straightforward so I'll use that to illustrate.
Here's the code, followed by some explanation:
def __init__(self, name, pipe):
# call this before anything else
# then any other initialization
self.name = name
self.ipcPipe = pipe
self.number1 = 0.0
self.number2 = 0.0
sys.stdout.write('[%s] created: %f\n' % (self.name, self.number1))
# Do some kind of computation
count = 0
count += 1
self.number1 = (random.uniform(0.0, 10.0)) * self.number2
sys.stdout.write('[%s]\t%d \t%g \t%g\n' % (self.name, count, self.number1, self.number2))
# Send result via pipe to parent process.
# Can send lists, whatever - anything picklable.
# Get new data from parent process
newData = self.ipcPipe.recv()
self.number2 = newData
sys.stdout.write('[%s] started ... process id: %s\n'
% (self.name, os.getpid()))
# When done, send final update to parent process and close pipe.
sys.stdout.write('[%s] task completed: %f\n' % (self.name, self.number1))
# Create pipe
parent_conn, child_conn = multiprocessing.Pipe()
# Instantiate an object which contains the computation
# (give "child process pipe" to the object so it can phone home :) )
computeTask = computing_task('foo', child_conn)
# Start process
# Continually send and receive updates to/from the child process
# receive data from child process
result = parent_conn.recv()
print "recv: ", result
# send new data to child process
print "joined, exiting"
if (__name__ == "__main__"):
I have encapsulated the computing to be done inside a class derived from
Process. This isn't strictly necessary but makes the code easier to understand and extend, in most cases. From the main process you can start your computing task with the
start() method on an instance of this class (this will start a separate process to run the contents of your object).
As you can see, we use
Pipe in the parent process to create two connectors ("ends" of the pipe) and give one to the child while the the parent holds the other. Each of these connectors is a two-way communication mechanism between the processes holding the ends, with
recv() methods for doing what their names imply. In this example I've used the pipe to transmit lists of numbers and text, but in general you can send lists, tuples, objects, or anything that's picklable (i.e. serializable with Python's pickle facility). So you've got some latitude for what you send back and forth between processes.
So you set up your connectors, invoke
start() on your new process, and you're off and computing. Here we're just multiplying two numbers, but you can see it's being done "interactively" in the subprocess with updates sent from the parent. Likewise the parent process is informed regularly of new results from the computing process.
Note that the connector's
recv() method is blocking, i.e. if the other end hasn't sent anything yet,
recv() will wait until something is there to read, and prevent anything else from happening in the meantime. So just be aware of that.
Hope this helps. Again, this is a barebones example and in real life you'll want to do more error handling, possibly use
poll() on the connection objects, and so forth, but hopefully this conveys the major ideas and gets you started.