# improve nested loop performance

I am doing a molecular dynamics simulation of an Argon liquid in Python. I have a stable version running, however it runs slowly for more than 100 atoms. I identified the bottleneck to be the following nested for loop. It's a force calculation put inside a function that is called from my main.py script:

``````def computeForce(currentPositions):
potentialEnergy = 0
force = zeros((NUMBER_PARTICLES,3))
for iParticle in range(0,NUMBER_PARTICLES-1):
for jParticle in range(iParticle + 1, NUMBER_PARTICLES):
distance = currentPositions[iParticle] - currentPositions[jParticle]
distance = distance - BOX_LENGTH * (distance/BOX_LENGTH).round()
#note: this is so much faster than scipy.dot()
distanceSquared = distance[0]*distance[0] + distance[1]*distance[1] + distance[2]*distance[2]
r2i = 1. / distanceSquared
r6i = r2i*r2i*r2i
lennardJones = 48. * r2i * r6i * (r6i - 0.5)
force[iParticle] += lennardJones*distance
force[jParticle] -= lennardJones*distance
potentialEnergy += 4.* r6i * (r6i - 1.) - CUT_OFF_ENERGY
return(force,potentialEnergy)
``````

the variables in CAPITAL letters are constant, defined in a config.py file. "currentPositions" is a 3 by number-of-particles matrix.

I have already implemented a version of the nested for loop with scipy.weave, which was inspired from this website: http://www.scipy.org/PerformancePython.

However, I don't like the loss of flexibility. I'm interested in "vectorizing" this for loop. I just don't really get how that works. Can anybody give me a clue or a good tutorial that teaches this?

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have a look at this tutorial from pyconeuro google.com/…. Will show you how to vectorize or you can just use cython.. – locojay Feb 13 '13 at 14:16
Write the computeForce function using a compiled language or use cython as suggested. For nested loops like above Python is definitely suboptimal. – Bálint Aradi Feb 13 '13 at 14:26
awesome. thanks! – seb Feb 13 '13 at 14:36
Have you tried making a 2D Numpy array of distances, then perform the operations on the array as a whole? – Paul Feb 13 '13 at 14:37

Below is my vectorized version of your code. For a dataset with 1000 points my code is roughly 50 times faster then the original:

``````In [89]: xyz = 30 * np.random.uniform(size=(1000, 3))

In [90]: %timeit a0, b0 = computeForce(xyz)
1 loops, best of 3: 7.61 s per loop

In [91]: %timeit a, b = computeForceVector(xyz)
10 loops, best of 3: 139 ms per loop
``````

The code:

``````from numpy import zeros

NUMBER_PARTICLES = 1000
BOX_LENGTH = 100
CUT_OFF_ENERGY = 1

def computeForceVector(currentPositions):
potentialEnergy = 0
force = zeros((NUMBER_PARTICLES, 3))
for iParticle in range(0, NUMBER_PARTICLES - 1):
positionsJ =  currentPositions[iParticle + 1:, :]
distance = currentPositions[iParticle, :] - positionsJ
distance = distance - BOX_LENGTH * (distance / BOX_LENGTH).round()
distanceSquared = (distance**2).sum(axis=1)

if ind.any():
r2i = 1. / distanceSquared[ind]
r6i = r2i * r2i * r2i
lennardJones = 48. * r2i * r6i * (r6i - 0.5)
ljdist = lennardJones[:, None] * distance[ind, :]
force[iParticle, :] += (ljdist).sum(axis=0)
force[iParticle+1:, :][ind, :] -= ljdist
potentialEnergy += (4.* r6i * (r6i - 1.) - CUT_OFF_ENERGY).sum()
return (force, potentialEnergy)
``````

I've also checked that the code produces the same results

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wow! thank you, this is awesome. I'm trying to understand it right now, but will probably have to take a good night's sleep before (it's dark here in sweden). i'll implement this. i will post a comparison between your's, mine in python and mine in scipy.weave here tomorrow. thanks again! – seb Feb 13 '13 at 18:04
I tried to vectorize your vectorized code, getting rid of the remaining loop, but because that requires building arrays of `NUMBER_PARTICLESxNUMBER_PARTICLES`, it was about x5 times slower than your code for `NUMBER_PARTICLES = 1000`, similarly fast for `NUMBER_PARTICLES = 100` and faster only for smaller particles counts. – Jaime Feb 14 '13 at 1:06
@sega_sai: thanks again. your code really helped me to understand how to vectorize in numpy. just to make this post complete, I added my weaved in C code below. this runs another 10 times faster than your vectorized version. I like the vectorizing though, because it keeps the flexibility. – seb Feb 15 '13 at 8:11

Writing something like a MD engine in pure python is going to be slow. I would take a look at either Numba (http://numba.pydata.org/) or Cython (http://cython.org/). On the Cython side, I've written a simple Langevin Dynamics engine using cython that might serve as an example to get you started:

Another option, which I like quite a bit, is to use OpenMM. There is a python wrapper that allows you to put together all of the pieces of an MD engine, implement custom forces, etc. It also has the ability to target GPU devices:

https://simtk.org/home/openmm

In general though, there are so many highly tuned MD codes available, that unless you are doing this for some sort of general educational purpose, it doesn't make sense to write your own from scratch. Some of the major codes, just to name a few:

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ok, thanks for the feedback. Cython looks really interesting. I'll have a look at it. – seb Feb 13 '13 at 14:38
thanks for the feedback. i actually have to do this one from scratch, since it's a project for one of my courses. i'll pick one of the above and compare my results to it. – seb Feb 13 '13 at 18:05

just to make this post complete, I add my implementation in weaved in C code. note that you need to import weave and converters for this to work. moreover, weave only works with python 2.7 right now. thanks again for all the help! this runs another 10 times faster than the vectorized version.

``````from scipy import weave
from scipy.weave import converters
def computeForceC(currentPositions):
code = """
using namespace blitz;
Array<double,1> distance(3);
double distanceSquared, r2i, r6i, lennardJones;
double potentialEnergy = 0.;

for( int iParticle = 0; iParticle < (NUMBER_PARTICLES - 1); iParticle++){
for( int jParticle = iParticle + 1; jParticle < NUMBER_PARTICLES; jParticle++){
distance(0) = currentPositions(iParticle,0)-currentPositions(jParticle,0);
distance(0) = distance(0) - BOX_LENGTH * round(distance(0)/BOX_LENGTH);
distance(1) = currentPositions(iParticle,1)-currentPositions(jParticle,1);
distance(1) = distance(1) - BOX_LENGTH * round(distance(1)/BOX_LENGTH);
distance(2) = currentPositions(iParticle,2)-currentPositions(jParticle,2);
distance(2) = distance(2) - BOX_LENGTH * round(distance(2)/BOX_LENGTH);
distanceSquared = distance(0)*distance(0) + distance(1)*distance(1) + distance(2)*distance(2);
r2i = 1./distanceSquared;
r6i = r2i * r2i * r2i;
lennardJones = 48. * r2i * r6i * (r6i - 0.5);
force(iParticle,0) += lennardJones*distance(0);
force(iParticle,1) += lennardJones*distance(1);
force(iParticle,2) += lennardJones*distance(2);
force(jParticle,0) -= lennardJones*distance(0);
force(jParticle,1) -= lennardJones*distance(1);
force(jParticle,2) -= lennardJones*distance(2);
potentialEnergy += 4.* r6i * (r6i - 1.)-CUT_OFF_ENERGY;

}

}//end inner for loop
}//end outer for loop
return_val = potentialEnergy;

"""
#args that are passed into weave.inline and created inside computeForce
#potentialEnergy = 0.
force = zeros((NUMBER_PARTICLES,3))

#all args