1

I need to perform a block of code like the following:

x = some_number;
y = some_other_number;

u = a_vector_of_numbers;
v = another_vector_of_numbers;
% u and v are of equal size

r1 = ((x == u) | (x == v));   % Expensive!
r2 = ((y == u) | (y == v));   % Expensive!

q = any(r1 & r2);

You can think of this as: x and y are two nodes on graph, and unless I am mistaken, this checks if x and y are connected using an adjacency list [r1, r2]. In other words, I am trying to answer the question: "Is there such an index i that both x and y can be found at r1(i) or r2(i)?"

I need to do this repeatedly. Both r1 and r2 can potentially contain up to thousands of unique values (number of nodes on the graph on the order of 104) and their length is hundreds of thousands (number of edges on the order of 106).

My profiler tells me the two lines I have indicated with comments consume 99% of run-time, and my program takes quite a while to run, so I am wondering: How much more can this be optimized? What is the fundamental limit to the minimum computation time, and how close to it am I?

Also, it would be quite easy to outsource this particular code to another language. Could do that ever result in a significant performance gain?

2
  • Can there be more than one such i? If so, do you need all of them or just the first/last? Feb 23, 2012 at 0:33
  • In theory, there should not be more than one such i in my data, because my graph is undirected. In practice, the data is sometimes dirty. In any case, I don't even need the first or last- I just want to know if such an i exists. But if your answer would rely on it, it's possible to do some preprocessing on r1/r2 and guarantee that such an i will never be found more than one time for any given x-y pair.
    – Superbest
    Feb 23, 2012 at 10:52

2 Answers 2

4

If your first check (r1) is likely to remove most of the results, your second check can be pre-filtered to only check the possible matches. The code for that would look like this:

mask_r1 = ((x == u) | (x == v));   % Expensive!
r2 = ((y == u(mask_r1)) | (y == v(mask_r1)));   % Less expensive!
q = any(r2);

I have even seen cases (usually in older versions of Matlab), where adding a find to the first line improved performance. But I don't think that is true anymore (they've pulled that optimization into the parser.) Some timing results of the three methods (original, using a logical mask, using an explicit index list) are below:

x = 2;
y = 3;
v = randi(200,1e5,1);
u = randi(200,1e5,1);

tic;
for ix = 1:1000
    r1 = ((x == u) | (x == v));   % Expensive!
    r2 = ((y == u) | (y == v));   % Expensive!
    q = any(r1 & r2);
end
toc;  %1.175234


tic;
for ix = 1:1000
    mask_r1 = ((x == u) | (x == v));   % Expensive!
    r2 = ((y == u(mask_r1)) | (y == v(mask_r1)));   % Less expensive!
    q = any(r2);
end
toc;  %0.878857

tic;
for ix = 1:1000
    ixs_r1 = find(((x == u) | (x == v)));   % Expensive!
    r2 = ((y == u(r1)) | (y == v(r1)));   % Less expensive!
    q = any(r2);
end
toc;  %1.118103
1
  • I think in the best case, this can at most halve the time I need. I was more interested in an order-of-magnitude reduction in run-time. This is still a great idea and very helpful to me though, thanks!
    – Superbest
    Feb 23, 2012 at 10:57
3

I haven't tested this suggestion, too much effort to set up some realistic test data, but ...

Have you tried creating an adjacency matrix for your graph and using that for your enquiries ? While creating the matrix (once) would be a relatively expensive operation, the check for the presence of an edge would be much cheaper than reading both adjacency lists (I think).

If you stick with your current algorithm (or, more to the point, with your current data structure) I'd be surprised if you got much speed-up simply by offloading the work to an implementation in another language. Using another language doesn't change the fact that you are reading through long vectors of data looking for values.

4
  • I'll try to let you know what happens after I implement this.
    – Superbest
    Feb 23, 2012 at 11:47
  • With my real-world data, I was able to reduce running time from 18 minutes to about 0.3 minutes. Thanks!
    – Superbest
    Feb 23, 2012 at 14:10
  • Nice example of SPACE vs. TIME trade-off.
    – upperBound
    Feb 23, 2012 at 16:42
  • I forgot to suggest considering using a sparse matrix for the adjacency matrix. Not sure how that will affect execution time. Feb 23, 2012 at 17:40

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