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I'm using pretty standard Threading.Event: Main thread gets to a point where its in a loop that runs:

event.wait(60)

The other blocks on a request until a reply is available and then initiates a:

event.set()

I would expect the main thread to select for 40 seconds, but this is not the case. From the Python 2.7 source Lib/threading.py:

# Balancing act:  We can't afford a pure busy loop, so we
# have to sleep; but if we sleep the whole timeout time,
# we'll be unresponsive.  The scheme here sleeps very
# little at first, longer as time goes on, but never longer
# than 20 times per second (or the timeout time remaining).
endtime = _time() + timeout
delay = 0.0005 # 500 us -> initial delay of 1 ms
while True:
   gotit = waiter.acquire(0)
   if gotit:
       break
       remaining = endtime - _time()
       if remaining <= 0:
          break
       delay = min(delay * 2, remaining, .05)
       _sleep(delay)

What we get is a select syscall run every 500us. This causes noticeable load on the machine with a pretty tight select loop.

Can someone please explain why there is a balancing act involved and why is it different than a thread waiting on a file descriptor.

and second, Is there a better way to implement a mostly sleeping main thread without such a tight loop?

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2 Answers 2

up vote 2 down vote accepted

I recently got hit by the same problem, and I also tracked it down to this exact block of code in the threading module.

It sucks.

The solution would be to either overload the threading module, or migrate to python3, where this part of the implementation has been fixed.

In my case, migrating to python3 would have been a huge effort, so I chose the former. What I did was:

  1. I created a quick .so file (using cython) with an interface to pthread. It includes python functions which invoke the corresponding pthread_mutex_* functions, and links against libpthread. Specifically, the function most relevant to the task we're interested in is pthread_mutex_timedlock.
  2. I created a new threading2 module, (and replaced all import threading lines in my codebase with import threading2). In threading2, I re-defined all the relevant classes from threading (Lock, Condition, Event), and also ones from Queue which I use a lot (Queue and PriorityQueue). The Lock class was completely re-implemented using pthread_mutex_* functions, but the rest were much easier -- I simply subclassed the original (e.g. threading.Event), and overridden __init__ to create my new Lock type. The rest just worked.

The implementation of the new Lock type was very similar to the original implementation in threading, but I based the new implemenation of acquire on the code I found in python3's threading module (which, naturally, is much simpler than the abovementioned "balancing act" block). This part was fairly easy.

(Btw, the result in my case was 30% speedup of my massively-multithreaded process. Even more than I expected.)

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I totally agree with you, this is lame.

Currently, I'm sticking with a simple select call, without timeout, and listening on a pipe created before. The wakeup is done by writing a character in the pipe.

See this sleep and wakeup functions from gunicorn.

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