# Quickly counting particles in grid

I've written some python code to calculate a certain quantity from a cosmological simulation. It does this by checking whether a particle in contained within a box of size 8,000^3, starting at the origin and advancing the box when all particles contained within it are found. As I am counting ~2 million particles altogether, and the total size of the simulation volume is 150,000^3, this is taking a long time.

I'll post my code below, does anybody have any suggestions on how to improve it?

``````from __future__ import division
import numpy as np

def check_range(pos, i, j, k):
a = 0
if i <= pos[2] < i+8000:
if j <= pos[3] < j+8000:
if k <= pos[4] < k+8000:
a = 1
return a

def sigma8(data):

N = []

to_do = data

print 'Counting number of particles per cell...'

for k in range(0,150001,8000):
for j in range(0,150001,8000):
for i in range(0,150001,8000):
temp = []
n = []
for count in range(len(to_do)):
n.append(check_range(to_do[count],i,j,k))
to_do[count][1] = n[count]
if to_do[count][1] == 0:
temp.append(to_do[count])
#Only particles that have not been found are
# searched for again

to_do = temp
N.append(sum(n))
print 'Next row'
print 'Next slice, %i still to find' % len(to_do)

print 'Calculating sigma8...'

if not sum(N) == len(data):
return 'Error!\nN measured = {0}, total N = {1}'.format(sum(N), len(data))

else:
return 'sigma8 = %.4f, variance = %.4f, mean = %.4f' % (np.sqrt(sum((N-np.mean(N))**2)/len(N))/np.mean(N), np.var(N),np.mean(N))
``````
-

I'll try to post some code, but my general idea is the following: create a Particle class that knows about the box that it lives in, which is calculated in the `__init__`. Each box should have a unique name, which might be the coordinate of the bottom left corner (or whatever you use to locate your boxes).

Get a new instance of the Particle class for each particle, then use a Counter (from the collections module).

Particle class looks something like:

``````# static consts - outside so that every instance of Particle doesn't take them along
# for the ride...
MAX_X = 150,000
X_STEP = 8000
# etc.

class Particle(object):

def __init__(self, data):
self.x = data[xvalue]
self.y = data[yvalue]
self.z = data[zvalue]
self.compute_box_label()

def compute_box_label(self):
import math

x_label = math.floor(self.x / X_STEP)
y_label = math.floor(self.y / Y_STEP)
z_label = math.floor(self.z / Z_STEP)
self.box_label = str(x_label) + '-' + str(y_label) + '-' + str(z_label)
``````

Anyway, I imagine your `sigma8` function might look like:

``````def sigma8(data):
import collections as col

particles = [Particle(x) for x in data]
boxes = col.Counter([x.box_label for x in particles])
counts = boxes.most_common()

#some other stuff
``````

`counts` will be a list of tuples which map a box label to the number of particles in that box. (Here we're treating particles as indistinguishable.)

Using list comprehensions is much faster than using loops---I think the reason is that you're basically relying more on the underlying C, but I'm not the person to ask. Counter is (supposedly) highly-optimized as well.

Note: None of this code has been tested, so you shouldn't try the cut-and-paste-and-hope-it-works method here.

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That's fantastic, thanks! I'm still fairly new to this whole class business, it wasn't ever part of our python classes. It actually worked pretty much as is, I just had to set up an array of zeros so that I still counted those cells that had no particles in. Thanks again for your help, Ross –  Ross Feb 26 '13 at 23:39
I'm interested: how much performance did you get? Anyway, I wish I would have had Python when I was in grad school---it's much nicer than the thousands of lines of C++ I wrote. –  BenDundee Feb 27 '13 at 1:14
Well, initially it was taking ~5 hours to run. This cut it down to minutes, which is incredible as far as I'm concerned. –  Ross Feb 27 '13 at 12:29
It's pretty funny: I see for loops as pretty much a last resort, especially when dealing with Python –  BenDundee Feb 27 '13 at 15:44