# Optimizing Python distance calculation while accounting for periodic boundary conditions

I have written a Python script to calculate the distance between two points in 3D space while accounting for periodic boundary conditions. The problem is that I need to do this calculation for many, many points and the calculation is quite slow. Here is my function.

``````def PBCdist(coord1,coord2,UC):
dx = coord1[0] - coord2[0]
if (abs(dx) > UC[0]*0.5):
dx = UC[0] - dx
dy = coord1[1] - coord2[1]
if (abs(dy) > UC[1]*0.5):
dy = UC[1] - dy
dz = coord1[2] - coord2[2]
if (abs(dz) > UC[2]*0.5):
dz = UC[2] - dz
dist = np.sqrt(dx**2 + dy**2 + dz**2)
return dist
``````

I then call the function as so

``````for i, coord2 in enumerate(coordlist):
do something with i
``````

Recently I read that I can greatly increase performance by using list comprehension. The following works for the non-PBC case, but not for the PBC case

``````coord_indices = [i for i, y in enumerate([np.sqrt(np.sum((coord2-coord1)**2)) for coord2 in coordlist]) if y < radius]
for i in coord_indices:
do something
``````

Is there some way to do the equivalent of this for the PBC case? Is there an alternative that would work better?

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You are using NumPy, so you should vectorise the loop to improve performance. What exactly is the structure of `coordlist`? It should be a two-dimensional NumPy array to be able to optimise the loop with NumPy ufuncs. –  Sven Marnach Jun 19 '12 at 20:30
coordlist is a numpy array with shape approx (5711,3). coordlist itself comes from a larger list, so I effectively loop over coordlist 20,000 times and that list of coordlist gets looped over about 50 times...you get the picture. –  johnjax Jun 19 '12 at 20:43
I looked up the vectorize function in NumPy. The documentation says: "The vectorize function is provided primarily for convenience, not for performance. The implementation is essentially a for loop." –  johnjax Jun 19 '12 at 20:48
"Vectorising" in the context of NumPy means that you use NumPy ufuncs to move loops you would otherwise have to do in Python code to C code (like I did in my answer). I recommend reading up on NumPy a bit if you are concerned about performance. –  Sven Marnach Jun 19 '12 at 21:14

You should write your `distance()` function in a way that you can vectorise the loop over the 5711 points. The following implementation accepts an array of points as either the `x0` or `x1` parameter:

``````def distance(x0, x1, dimensions):
delta = numpy.abs(x0 - x1)
delta = numpy.where(delta > 0.5 * dimensions, dimensions - delta, delta)
return numpy.sqrt((delta ** 2).sum(axis=-1))
``````

Example:

``````>>> dimensions = numpy.array([3.0, 4.0, 5.0])
>>> points = numpy.array([[2.7, 1.5, 4.3], [1.2, 0.3, 4.2]])
>>> distance(points, [1.5, 2.0, 2.5], dimensions)
array([ 2.22036033,  2.42280829])
``````

The result is the array of distances between the points passed as second parameter to `distance()` and each point in `points`.

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This led to about a 5 fold speed up in my code. Thanks! For those looking for an alternative, the answer by lazyr also performed just as well. –  johnjax Jun 20 '12 at 14:48
``````import numpy as np

bounds = np.array([10, 10, 10])
a = np.array([[0, 3, 9], [1, 1, 1]])
b = np.array([[2, 9, 1], [5, 6, 7]])

min_dists = np.min(np.dstack(((a - b) % bounds, (b - a) % bounds)), axis = 2)
dists = np.sqrt(np.sum(min_dists ** 2, axis = 1))
``````

Here `a` and `b` are lists of vectors you wish to calculate the distance between and `bounds` are the boundaries of the space (so here all three dimensions go from 0 to 10 and then wrap). It calculates the distances between `a[0]` and `b[0]`, `a[1]` and `b[1]`, and so on.

I'm sure numpy experts could do better, but this will probably be an order of magnitude faster than what you're doing, since most of the work is now done in C.

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I tried this approach as well. It also led to about a 5 fold enhancement in code. Unfortunately I can only check 1 answer as the correct one :/ –  johnjax Jun 20 '12 at 14:49
@johnjax For what it's worth, I would have accepted Sven Marnach's answer too, had I been in your shoes. It's more directly applicable than mine. –  Lauritz V. Thaulow Jun 20 '12 at 15:11

Have a look at Ian Ozsvalds high performance python tutorial. It contains lots of suggestions on where you can go next.

Including:

• vectorization
• cython
• pypy
• numexpr
• pycuda
• multiprocesing
• parallel python
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