Optimize search of closest four elements in two 3D arrays

I have two numpy arrays filled with 3D coordinates (x, y, z). For each point of the first array (the "target" array) I need to find the 4 closest points of the 2nd array (the "source" array). I have no problem finding the actual results using different methods, but I want to speed up the process as much as I can.

I need this because I am working on a Maya tool that transfers information stored in each vertex of a mesh to a second mesh, and they might have different number of vertices.

At this point though, it becomes more of a python problem than a Maya one since my main bottleneck is the time spent looking for the vertex matches.

The number of elements can vary from a few hundreds to hundred of thousands, and I want to make sure that I find the best way to speed up the search. I would like my tool to be as quick as possible, since it might be used really often, and waiting minutes every single time it has to run would be quite annoying.

I found some useful answers that got me in the right direction:

Here I found out about KDTrees and different algorithms and here I found some useful considerations on multithreading.

Here is some code that simulates the kind of scenario I would be working with and a few of the solutions I tried.

``````import timeit
import numpy as np
from scipy import spatial

# brut Froce
def bruteForce():
results = []
for point in sources:
dists = ((targets - [point]) ** 2).sum(axis=1)  # compute distances
ndx = dists.argsort()  # indirect sort
results.append(zip(ndx[:4], dists[ndx[:4]]))
return results

def worker(point):
dists = ((targets - [point]) ** 2).sum(axis=1)  # compute distances
ndx = dists.argsort()  # indirect sort
return zip(ndx[:4], dists[ndx[:4]])

return pool.map(worker, sources)

# KDTree implementation
def kdTree():
tree = spatial.KDTree(targets, leafsize=50)
return [tree.query(point, k=4) for point in sources]

# define the number of points for the two arrays
n_targets = 40000
n_sources = 40000

#pick some random points
targets = np.random.rand(n_targets, 3) * 100
sources = np.random.rand(n_sources, 3) * 100

print 'KDTree:   %s' % timeit.Timer(lambda: kdTree()).repeat(1, 1)
print 'bruteforce:   %s' % timeit.Timer(lambda: bruteForce()).repeat(1, 1)
``````

My results are:

``````KDTree:       10.724864464  seconds
bruteforce:   211.427750433 seconds
``````

The most promising method seems the KDTree. At first I thought that by using some Threads to split the work of the KDTree into separate tasks, I could speed up the process even more. However, after testing quickly using a basic `threading.Thread` implementation, it seemed to perform even worse when the KDTree was being computed in a Thread. Reading this scipy example I can see that KDTrees are not really suitable to be used in parallel Threads, but I did not really understood way.

I was wondering, then, if there is any other way I could optimize this code to perform quicker, maybe by using multiprocessing or some other kind of trick to parse through my arrays in parallel.

Thanks in advance for the help!

• Generally Python isn't good at multithreading because many accesses to data structures are synchronized by the global interpreter lock. `multiprocessing` can help here but must be done carefully so that copying of the data structures works and unnecessary copying is avoided (especially on Windows there can be problems due to lack of `fork` OS function). – Michael Butscher May 23 at 22:16
• Would you be able to provide an example of multiprocessing with the KDTree? – Yagalos May 24 at 6:33

There is one very simple but extremely effective thing you can do which is switching from KDTree to cKDTree. The latter being a Cython drop-in replacement of the first which is implemented in pure Python.

Also note that `.query` is vectorized, no need for a list comprehension.

``````import scipy.spatial as ss

a = np.random.random((40000,3))
b = np.random.random((40000,3))

tree_py = ss.KDTree(a)
tree_cy = ss.cKDTree(a)

timeit(lambda: tree_cy.query(b, k=4), number=10)*100
# 71.06744810007513
timeit(lambda: tree_py.query(b, k=4), number=1)*1000
# 13309.359921026044
``````

So that is an almost `200x` speedup for free.

• The reason of the list comprehension is that in general I need to anyway do some stuff while I am cycling through my points. So, in the final implementation, I would be anyway looping thorough each point, find the closest 4, and then do some other stuff that I omitted here to map the values of those 4 point to the destination. So I thought it would be a better rappresentation to use an actual cycle in the test. – Yagalos May 24 at 6:37
• I will definitely try the cKDTree. However, I can already see from your results that you get much slower computation that I do, probably since you do not specify the leafsize. I noticed that changing the leafsize can make a huge difference in performance, but the documentation does not really explains what it does and what are the suggested values. Do you have any insight on how the leafsize should be set for best speed? – Yagalos May 24 at 6:39
• Unfortunately not, but I played a bit with it just now and the trade-offs do not seem to be the same for KDTree (where it helps, but just a bit (<2x) your value, 50, seems not too far from optimal for the problem size) and for cKDTree (where trying for five minutes I couldn't find a value that beats the default). Seems to indicate that bisection overhead is more significant in pure Python than in Cython which makes sense I'd say. – Paul Panzer May 24 at 7:54

For large enough numbers of source points multiprocessing may give a speed gain. A crucial point is that each subprocess must hold a copy of the `KDTree`. With Linux (supporting `fork`) this is done automatically if creating the subprocesses after tree was built.

For Windows the tree must either be sent `pickle`d to the subprocesses as it is done automatically when sending parameters to the subprocess (which only seems to work for `cKDTree` but not for `KDTree`) or the tree must be created from scratch in each process.

Following code shows the pickling variant with multi process `cKDTree` versus single process.

``````import timeit
import numpy as np
from multiprocessing.pool import Pool
from scipy import spatial

# cKDTree implementation
def ckdTree():
tree = spatial.cKDTree(targets, leafsize=50)
return [tree.query(point, k=4) for point in sources]

# Initialization to transfer kdtree
def setKdTree(tree):
global kdtree

kdtree = tree

# Worker must not be in another function for multiprocessing
def multiprocKd_worker(point):
return kdtree.query(point, k=4)

# cKDTree process pool implementation
def multiprocCKd():
tree = spatial.cKDTree(targets, leafsize=50)

pool = Pool(initializer=setKdTree, initargs=(tree,))
return pool.map(multiprocKd_worker, sources)

if __name__ == "__main__":
# define the number of points for the two arrays
n_targets = 40000
n_sources = 40000

#pick some random points
targets = np.random.rand(n_targets, 3) * 100
sources = np.random.rand(n_sources, 3) * 100

print('cKDTree:   %s' % timeit.Timer(lambda: ckdTree()).repeat(1, 1))
print('multiprocCKd:   %s' % timeit.Timer(lambda: multiprocCKd()).repeat(1, 1))
``````