I've came across this paragraph in the Documentations which says:
Binary buffered objects (instances of
BufferedRWPair) protect their internal structures using a lock; it is therefore safe to call them from multiple threads at once.
I'm not sure why they need to "protect" their internal structures given the GIL is in action. Who cares? I didn't care much until I found out that this lock has some significance, consider this piece of code:
from _thread import start_new_thread import time def start(): for i in range(10): print("SPAM SPAM SPAM!") for i in range(10): start_new_thread(start, ()) time.sleep(0.0001) print("main thread exited")
Output when run on Python 3.X:
...many SPAM... SPAM SPAM SPAM! SPAM SPAM SPAM! SPAM SPAM SPAM! main thread exited SPAM SPAM SPAM! SPAM SPAM SPAM! SPAM SPAM SPAM! SPAM SPAM SPAM! SPAM SPAM SPAM! Fatal Python error: could not acquire lock for <_io.BufferedWritername='<stdout>'> at interpreter shutdown, possibly due to daemon threads
Under Python 2.7, no errors. I'm not aware why would this happen, however, I've been looking around in bufferedio.c. Another code that behaves similarly to the above snippet that was tested on Python 3.X, sometimes I got
Fatal Python error and sometimes I did not. Any threaded function with a loop plus
std[out][err].write causes this fatal error. It's really hard to define the characteristics of this error and to the best of my knowledge the Documentation doesn't mention anything about it. I'm not sure even if it's a bug, I hope not.
My explanation of this behavior goes like this, *I could be totally wrong:
The main thread exited while its holding the lock of
sys.stdout.buffer. However, this seems contrary to the fact that threads are terminated when the main thread exits on the system on which I'm running Python, Linux.
I'm posting this as answer, it just can't be done in the comment section.
This behavior isn't just limited to
write it affects
read as well as
flush calls on those objects
1) On Linux and probably on Windows too, when the main thread exits, its child threads are terminated. How does this affect the mentioned behavior in question? If the main thread was able to exit during its time slice, before being context switched with another thread, no fatal error occurs as all threads get terminated. Nothing guarantees however, that the main thread will exit as soon as it starts.
2) The fatal error takes place between the finalization process (shutdown) of the interpreter and the
flush call and possibly other operations on the
Buffered* object. The finalization process acquires the lock of the those objects, any
write for example to the
BufferedWriter object results in
Fatal Python error.
os._exit terminates the interpreter without the finalization steps and hence the interpreter will not own the lock of the object that we are talking about, this is another example:
from _thread import start_new_thread import time, sys, os def start(myId): for i in range(10): sys.stdout.buffer.write(b"SPAM\n") for i in range(2): start_new_thread(start, (i,)) x = print("main thread") print(x) #os._exit(0)
In above code, if the main thread exits as soon as it starts, that's it, no fatal error occurs and all spawned threads are terminated immediately (at least in Linux) this is platform-dependent though. If you're unlucky enough and another thread started to play on the field before the main threads exits, without
os._exit(0) call the interpreter goes through its normal cycle of finalization to acquire the lock of
sys.stdout.buffer which results in fatal error. Run this code multiple times to notice its different behaviors.