# distance matrix of curves in python

I have a set of curves defined as 2D arrays (number of points, number of coordinates). I am calculating a distance matrix for them using Hausdorff distance. My current code is as follows. Unfortunately it is too slow with 500-600 curves each having 50-100 3D points. Is there any faster way for that?

``````def distanceBetweenCurves(C1, C2):
D = scipy.spatial.distance.cdist(C1, C2, 'euclidean')

#none symmetric Hausdorff distances
H1 = np.max(np.min(D, axis=1))
H2 = np.max(np.min(D, axis=0))

return (H1 + H2) / 2.

def distanceMatrixOfCurves(Curves):
numC = len(Curves)

D = np.zeros((numC, numC))
for i in range(0, numC-1):
for j in range(i+1, numC):
D[i, j] = D[j, i] = distanceBetweenCurves(Curves[i], Curves[j])

return D
``````
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Is `scipy.spatial.distance.cdist` the slow piece or the double loop inside `distanceMatrixOfCurves` ? If these curves are convex it might be possible to optimize the first possible slow piece. Do these curves intersect or are contained inside others ? I feel like you could reuse earlier found distances to speed up new calculations. This is just babbling of course, I have myself a similar issue with min(min(..)) measures and had trouble to generalize these considerations I'm putting here. Did you try or think about anything beyond the code you posted ? –  mmgp Dec 3 '12 at 22:44
I tried to implement Euclidean distance myself (instead of using cdist), nothing much changed. I think problem is with double loop. Curves (some of them) intersect and are contained inside others... –  ahmethungari Dec 3 '12 at 22:59
@ahmethungari you should profile your code to be sure (cProfile + runsnakerun to interpret results are great) what the exact bottleneck is. I don't have a great feel for these things, but you may be able to get away without allocating the large all-pairs matrix of distances that `cdist` computes - if you can add some code that generates some small example data it will be easier to help you. –  Mr E Dec 3 '12 at 23:57
@MrE while it is certainly possible to get ride of `cdist` (just use a form of wave propagation) that might cost more memory and in the worst case it doesn't help. This doesn't mean it can't help in reducing execution time, but it is problematic. –  mmgp Dec 4 '12 at 0:07
1. Do you really need the full matrix `D`, or can you live with just upper- or lower-triangular matrix? This `D[i,j] = D[j,i] =...` is definitely no good for data locality; 2. Have you tried using list compresensions or `map` instead of double loops? –  ev-br Dec 4 '12 at 0:15

Your question might also be related to this one

This is kind of a hard problem. A possible way would be to implement the euclidian distance on your own, completely abandon `scipy` and make use of pypy's JIT compiler. But most likely this will not make you gane much.

Personally, I would recommend you to write the routine in C.

The problem is less the implementation but the way you approach this problem. You chose a brute force approach by calculating the euclidian distance for each distinct pair of points in each possible pair of the metric space subsets. This is computationally demanding:

• Assume you have 500 curves and each of them has 75 points. With the brute force approach you end up calculating the euclidean distance 500 * 499 * 75 * 75 = 1 403 437 500 times. It is not further surprising that this approach takes forever to run.

I'm not an expert with this but I know that the Hausdorff distance is extensively used in image processing. I would suggest you to browse the literature for speed optimized algorithms. A starting point might be this, or this paper. Also, often mentioned in combination with the Hausdorff distance is the Voroni diagram.

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The first linked paper is interesting, solves part of the problem. Now the other problem can be more or less formulated as this: given three sets A B C, if we know the Hausdorff distance between A and B and also the inner details obtained from such calculation, is it possible to find the Hausdorff distance from A to C with lesser computational complexity than it was to calculate for A and B if there are paths, considering some metric, from A to C that cross B ? Well, that was way longer than I expected when I started to write. I hope someone can make sense of it. –  mmgp Dec 4 '12 at 18:50
thank you for all your advices. I got the idea: "use a smarter algorithm". I hope I'll do it after using the current version for the paper deadline :) –  ahmethungari Dec 5 '12 at 0:23
@ahmethungari I'm sorry to not be able to help you more than that, but there is no easy solution for this problem. One idea for speeding up the computation I would have though: Instead of computing for a given point in Curve1 the euclid.dist. with all the points from Curve2, you could choose randomly a point from Curve2, compute the euclid.dist. (call it `r`) then for each other point from Curve2 you can compute the manhatton distance (much faster to compute) and check if each dimension of the manhatton dist. is bigger than `r`, if so... –  jojo Dec 5 '12 at 9:38
@ahmethungari the arbitrarily chosen point is closer and you do not need to compute the euclid.dist. (if you are not sure why:triangular inequality). if not, compute the euclid.dist. and if it is smaller than `r`, update `r`. You will still be running through all the points in Curve2, but you will often just have to compute the manhatton dist., which is faster. ...well, this is just an idea and there are certainly more sophisticated methods to speed up this process. –  jojo Dec 5 '12 at 9:47
@ahmethungari consider accepting this answer if you are satisfied with it. :) –  jojo Aug 7 '14 at 11:10

There are several methods you can try:

1. Using numpy-MKL which makes use of Intel's high performance Math Kernel Library instead of numpy;
2. Using Bootleneck for array functions;
3. Using Cpython for computation.
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