Here's a sketch of a solution. It may be the same idea TravisJ was suggesting, although that's not clear to me. It really is only a sketch, and would take significant code to implement.
If you partition your space into 90 unit x 90 unit sections, then a dot in a particular section can only be close enough to a dot in that section or to a dot in one of that section's eight neighbors. This could significantly reduce the number of pairs you have to compare. The cost, of course is algorithmic complexity:
- First create a data structure to represent your grid sections. They can probably be represented just by top-left corners, since their heights and widths would be fixed at 90, except maybe at the trailing edges, where it probably wouldn't matter. Assuming a rectangular surface, each one could have three, five, or eight neighbors (corners, edges, inner sections respectively).
- Loop through your dots, determining which section they live in. If your total grid starts at 0, this should be relatively straightforward, using some
Math.floor(something / 90) operations.
- For each section, run the loop above on itself and each of its neighbors to find the set of matches. You can use the shortened version of the loop from my earlier answer.
- For a further optimization, you can also reduce the number of neighbors to check. If Section3,7 does a comparison with Section3,8, then there is no reason for Section3,8 to also do the comparison with Section3,7. So you check only a certain subset of the neighbors, say those whose x and y components of their section numbers are greater than or equal to their own.
I have not tested this, except in my head. It should work, but I have not tried to write any code. And the code would not be trivial. I don't think it's weeks of work, but it's not something to whip together in a few minutes either.
I believe it could significantly increase the speed, but that will depend upon how many matches there are, how many dots there are relative to the number of sections.