I am writing a multi program in MPICH2 (popular message passing interface). My program is written in Python so I use the MPI4Py Python bindings. MPI is best for situations with no shared memory, therefore, it is not ideal for multicore programming. To use the full 4 cores of my 5 node cluster I am further using threads. However, I have noticed that using threads actually slows my simulation down. My program is several tens of thousands of lines of code, so I can not put it all up, but here is the snippet which is causing problems
from threading import Thread ... threadIndeces=[[0,10],[11,20],[21,30],[31,40]] #subset for each thread for indeces in treadIndeces: t=Thread(target=foo,args=(indeces,)) t.start()
Also, I make sure to join the threads later. If I run it with no threads, and just call
foo with all the indeces, it is about 10-15x times faster. When I record the times of the multithreaded version, the creation of the threads in the call
t=Thread(target=foo,args=(indeces,)) takes around 0.05 seconds, the join similarly takes 0.05 seconds but the
t.start() calls takes a whopping 0.2 seconds.
start() an expensive call? Should I be changing my approach? I thought about keeping a pool of threads rather than creating new ones every iteration, but it does not seem like the
t=Thread(target=foo,args=(indeces,)) is what's causing the slow down.
Also, incase anyone wants to know the complexity of the
foo, here is one of the functions which gets called
i times for the
indeces every iteration (non discrete time):
def HD_training_firing_rate(HD_cell): """During training, the firing rate is governed by the difference between the current heading direction and the preferred heading direction. This is made to resemble a Gaussian distribution """ global fabs global exp global direction #loop over twice due to concurrent CW and CCW HD training for c in [0,1]: d=direction[c] dp=HD_cell.dp #directional preferance s_d=20.0 #standard deviation s_i=min(fabs(dp-d),360-fabs(dp-d)) #circular deviation from preferred dir. HD_cell.r[c]=exp(-s_i*s_i/(2*s_d*s_d)) #normal distribution