I need to write a simple app that runs two threads: - thread 1: runs at timed periods, let's say every 1 minute - thread 2: just a 'normal' while True loop that does 'stuff'

if not the requirement to run at timed interval I would have not looked at twisted at all, but simple sleep(60) is not good enough and construction like:

l = task.LoopingCall(timed_thread)

Looked really simple to achieve what I wanted there.

Now, how do I 'properly' add another thread?

I see two options here:

  • Use threading library and run two 'python threads' one executing my while loop, and another running reactor.run(). But Google seems to object this approach and suggests using twisted threading
  • Use twisted threading. That's what I've tried, but somehow this looks bit clumsy to me.

Here's what I came up with:

def timed_thread():
    print 'i will be called every 1 minute'

def normal_thread():
    print 'this is a normal thread'

l = task.LoopingCall(timed_thread)

That seems to work, but! I can't stop the app. If I press ^C it wouldn't do anything (without 'callInThread' it just stops as you'd expect it to). ^Z bombs out to shell, and if I then do 'kill %1' it seems to kill the process (shell reports that), but the 'normal' thread keeps on running. kill PID wouldn't get rid of it, and the only cure is kill -9. Really strange.

So. What am I doing wrong? Is it a correct approach to implement two threads in twisted? Should I not bother with twisted? What other 'standard' alternatives are to implement timed calls? ('Standard' I mean I can easy_install or yum install them, I don't want to start downloading and using some random scripts from random web pages).

  • You use threads in twisted (and in python in general) very carefully. What is it that your "main" is doing? A frequent use-case for twisted is as a protocol client/server, making requests or listening for requests. The reactor will handle those requests, and assuming that they are non-blocking, will be able to fire off a particular function at a particular time interval. – MattH Feb 11 '10 at 9:39
  • The danger with threads is that if you aren't careful one thread might modify data while it is being used by another thread causing unpredictable behaviour. – MattH Feb 11 '10 at 9:44
  • all 'main' is meant to do is just to fire these two threads (in fact it's only 4 lines as you can see in the sample), both functions are bit more elaborate but nothing unusual in terms of processing other one just inspects it, but that doesn't really matter). these two thread are not sharing any data btw – rytis Feb 11 '10 at 9:45
up vote 2 down vote accepted

Assuming that your main is relatively non-blocking:

import random
from twisted.internet import task

class MyProcess:
  def __init__(self):
    self.stats = []
    self.lp = None
  def myloopingCall(self):
    print "I have %s stats" % len(self.stats)
  def myMainFunction(self,reactor):
  def start(self,reactor):
    self.lp = task.LoopingCall(self.myloopingCall)
  def stop(self):
    if self.lp is not None:
    print "I'm done"

if __name__ == '__main__':
  myproc = MyProcess()
  from twisted.internet import reactor
$ python bleh.py
I have 0 stats
I have 33375 stats
I have 66786 stats
I have 100254 stats
I have 133625 stats
I'm done
  • This doesn't use threads. – MattH Feb 11 '10 at 10:12
  • you mean this doesn't use python threads. i suspect it's still threaded by the twisted lib? – rytis Feb 11 '10 at 10:44
  • 2
    Nope, this is singled threaded. Twisted only uses threads if you tell it to. Have a read of twistedmatrix.com/documents/current/core/howto/threading.html – MattH Feb 11 '10 at 11:17
  • ah i see now... hhmm... so how to make this 'truly' threaded app??? your example kind of does what's needed, but is restricted by time, ie main loop in some cases may take more than a minute to execute and i don't want two of them running at the same time.... – rytis Feb 11 '10 at 12:52
  • 1
    task.loopingCall won't run twice if another function is blocking when it "would" be called. It will be called when there is the opportunity (i.e. the blocking call has returned) and it's next call will be rescheduled according to when it was actually called. – MattH Feb 11 '10 at 13:07

You didn't explain why you actually need threads here. If you had, I might have been able to explain why you don't need them. ;)

That aside, I can confirm that your basic understanding of things is correct. One possible misunderstanding I can clear up, though, is the notion that "python threads" and "Twisted threads" are at all different from each other. They're not. Python provides a threading library. All of Twisted's thread APIs are implemented in terms of Python's threading library. Only the API is different.

As far as shutdown goes, you have two options.

  • Start your run-forever thread using Python's threading APIs directly and make the thread a daemon. Your process can exit even while daemon threads are still running. A possible problem with this solution is that some versions of Python have issues with daemon threads that will lead to a crash at shutdown time.
  • Create your thread using either Twisted's APIs or the stdlib threading APIs but also add a Twisted shutdown hook using reactor.addSystemEventTrigger('before', 'shutdown', f). In that hook, communicate with the work thread and tell it to shut down. For example, you could share a threading.Event between the Twisted thread and your work thread and have the hook set it. The work thread can periodically check to see if it has been set and exit when it notices that it has been. Aside from not crashing, this gives another advantage over daemon threads - it will let you run some cleanup or finalization code in your work thread before the process exits.
  • +1 Hi JP, thanks for the assist. I don't think I'm up to the task of a twisted proponent. – MattH Feb 11 '10 at 14:15
  • np Matt. :) I think your answer was pretty good, except for dealing with the mysterious cases which "may take more than a minute" to complete. If we knew what those cases were, we might be able to suggest a way to adapt your solution to deal with them and actually eliminate the use of threads. – Jean-Paul Calderone Feb 11 '10 at 18:29
  • see the description in Matt's answer comment. hard to explain, there are various cases that i need to deal with. take this as an example (which is quite close to reality): t1 reads even entries from let's say 1mil calendars and puts events that scheduled to happen that minute into a DB table. that's it. t2 (t3,4,...) crawls through the table and performs instructions from it. there's no req that event needs to be processed that exact minute, it's just that it needs to get into the queue at that precise moment in time. so t2(3,4,...) have all the time in the world, but t1 is constrained. – rytis Feb 11 '10 at 23:16
  • sorry if that sounds vague, but that's what i have to deal with :) – rytis Feb 11 '10 at 23:16
  • oh.. why timed and within a minutes interval.. because 'calendars' are updated constantly and if I don't pull the data off them, it'll get lost. It's just a strange way of implementing queues, but it's out of my control i'm afraid. why not more often? because the data is updated in there exactly at minutes interval and I have 2 choices: have flag read_it (for a mil or so of them - really ugly) or wait a minute and rely on fact that it's going to be new data. reading might take longer than a minute, but int that case i'll just miss a beat - not good, but not catastrophic either. – rytis Feb 11 '10 at 23:22

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