# Explanations some Python Code

this is a basic example of a barrier, of how some threads are waited to enter a barrier for an entrance and another barrier for an exit.
Although the code is fine, I don't really understand in depth how it works...
For instance, I don't understand why a thread that enters the barrier() function, after it does n = n-1, can immediately make n = n+1 and so influence the global n ...? why it seems like all the threads after they make n = n-1 stop somewhere , and then they make n = n+1 in synchronization?

``````import threading
import time
import random
def usage(x):
for i in range(2):
print "[ENTER]: ",x
barrier()
print "[EXIT]: ",x
barrier()

def barrier():
region.acquire();
n = n - 1;
if n==0:
bar1.release();
region.release();
bar1.acquire();
region.acquire()
n = n + 1
bar2.release()
region.release()
bar2.acquire()

random.seed()
``````
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Could you explain where this code came from and what its goal is? –  David Heffernan Mar 13 '11 at 19:19
This sounds to me like some homework; in this case, my personal suggestion is to just throw it away and implement it from the scratch, because the quality of the fragment is quite poor. –  Roberto Liffredo Mar 13 '11 at 19:25
@Roberto Liffredo. No it's not a homework, it's an example made at the lab..which i didnt understand. if it's poor can you come back with a better variant? thanks –  shaku Mar 13 '11 at 19:29
@David. the goal is purely theoretical. –  shaku Mar 13 '11 at 19:31
@shaku Do you mean to say don't know what it's supposed to do? If you don't care what it should do, why should we? –  David Heffernan Mar 13 '11 at 19:32

`n` is the number of threads that still have to reach the rendezvous point. `region` is a mutex, protecting access to `n`. `bar1` and `bar2` are semaphores, indicating the number of threads that can proceed, initialized to 0.
In the first part of `barrier()`, each thread enters in turn, decreases `n`, and blocks on the `bar1` semaphore. The last thread to enter (the one that makes `n` == 0) posts the semaphore `threads` times, allowing that many threads to proceed.
The second part is symmetrical to the first, this time waiting for the last thread to increment `n`.