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Is there any way to optimize this method of searching?

for (var i=0;i<dots.length;i++) {
        var blist = [];
        for (var n=0;n<dots.length;n++) {
            if (dots[n][1]>(dots[i][1]-90) 
            && dots[n][1]<(dots[i][1]+90) 
            && dots[n][2]>(dots[i][2]-90) 
            && dots[n][2]<(dots[i][2]+90)) {
                if (!(n === i)) blist.push(n);
            }
        }

dots[x][1] is the x-coordinate and dots[x][2] is the y-coordinate.

I have 1000 dots, and need to find the dots surrounding each dot, so that results in the

if (dots[n][1]>(dots[i][1]-90) 
&& dots[n][1]<(dots[i][1]+90) 
&& dots[n][2]>(dots[i][2]-90) 
&& dots[n][2]<(dots[i][2]+90)) 

Running a million times a second, so is there a way to optimize this?

share|improve this question
    
Put the dots into a data structure. –  Travis J Dec 11 '12 at 0:18
1  
var n=i+1 on the inner loop initialisation? (With maybe some extra logic if you need two-way matches - what do you do with blist?) –  nnnnnn Dec 11 '12 at 0:36
    
@nnnnnn after this one dot is picked from blist for that dot to follow, so essentially is searches for all the dots nearby and picks one as a target –  Liam Bigelow Dec 11 '12 at 0:47
    
Sort the dots by position. –  Bergi Dec 11 '12 at 1:08
    
Is there a good reason that dots[i] looks like [100, 200] rather than {x: 100, y: 200}, (or whatever values are appropriate) which you could access as dots[i].x and dot[i].y? That would seem a more straightforward format. –  Scott Sauyet Dec 11 '12 at 2:59

3 Answers 3

up vote 1 down vote accepted

Perhaps try using a data structure for your dots like this

var Dot = function(){
 var x = 0;
 var y = 0;
 var Up;
 var Right;
 var Left;
 var Down;

 function init(xVal,yVal)
 {
  x = xVal;
  y = yVal;
 }

 function GetUp()
 {
  return Up;
 }

 function SetUp(UpDot)
 {
  Up = UpDot;
 }

 return 
 {
  init: init,
  GetUp: GetUp,
  SetUp: SetUp
 };
};

and then use it like this

var Dots = [];
var firstDot = new Dot();
Dots.push(firstDot);
var secondDot = new Dot();
secondDot.init(0,90);
secondDot.SetUp(firstDot);
Dots.push(secondDot);

Obviously, more would need to be added and configured to match your situation. However, what this would allow you to do was iterate through dots and then check weather there existed a near dot making the time O(n) instead of O(n^2) and thus saving you 900,000 checks.

share|improve this answer
    
So how would you iterate through the dots? –  Liam Bigelow Dec 11 '12 at 0:48
    
for( var i = 0, max = Dots.length; i < max; i++){ if(Dots[i].HasNeighbor()){}}; Iterate through the array of dots, and then perform a check on each one. You could set them up so that they had a simple boolean which was returned from HasNeighbor to squeeze some extra speed out of the operation. –  Travis J Dec 11 '12 at 0:58
    
Thanks, I'll restructure the whole thing and see if I can push draws out faster. –  Liam Bigelow Dec 11 '12 at 1:09
1  
@LiamBigelow: I'm not understanding how this helps, and certainly not how this reduces from O(n^2) to O(n). I see nothing to say that only certain indices could supply neighbors. Unless I'm missing something, these coordinates are likely scattered and we're trying to find the ones close to one another, not the neighbors on a fixed grid. –  Scott Sauyet Dec 11 '12 at 12:06
1  
@TravisJ: The point was that this is the wrong data structure. There are not a fixed set of neighbors to check; you have to find a way to compare with all other points. I see nothing in your suggestion that would help reduce the overall complexity. Am I missing something fundamental? –  Scott Sauyet Dec 12 '12 at 12:51

One way to cut your time in half would be not to double-check each pair:

for (var i = 0, len = dots.length; i < len - 1; i++) {
    var blist = [];
    for (var n = i + 1; n < len; n++) {
        if (dots[n][1]>(dots[i][1]-90) 
        && dots[n][1]<(dots[i][1]+90) 
        && dots[n][2]>(dots[i][2]-90) 
        && dots[n][2]<(dots[i][2]+90)) {
            blist.push(i);
            blist.push(n);
        }
    }
}

Note the change in loop boundaries. This allows me to check each pair only once and skip the (n === i) check.

I also cache dot.length, probably not a big deal, but worth doing for a tight loop.

Still, that should be an improvement of more than 50%. While that could help, it's not the orders of magnitude change that might be required for this sort of issue.

share|improve this answer
    
But then say i is 20, wouldn't the second loop only check numbers above 20? –  Liam Bigelow Dec 12 '12 at 0:12
    
Yes, but that's the point. (There was a bug, fixed above.) Your original loop compared, say dot20 with dot37, pushing dot37 onto your list. Then later it compared dot37 with dot20, pushing dot20 onto the list. It did this comparison twice, for no good reason. This one only does it once. –  Scott Sauyet Dec 12 '12 at 12:56
    
I see what you mean but after each loop the list is wiped. Each dot picks a dot around it, rinse, repeat. The dots are moving –  Liam Bigelow Dec 12 '12 at 22:08
    
No, I'm talking about your initial version, in the iteration where i = 20 and n = 37. Later you have to do i = 37, n = 20. You do essentially the same comparison in those two cases. My suggestion is simply that this duplication is unnecessary. You can avoid it by making the inner loop a little more focused. –  Scott Sauyet Dec 12 '12 at 23:15
    
I understand that double check, but not how you propose to fix it. –  Liam Bigelow Dec 12 '12 at 23:49

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.

share|improve this answer
    
But if this is run 5 times a second, it seems like it would be more processor heavy having to recalculate what squares each dot is in all the time. –  Liam Bigelow Dec 12 '12 at 22:10
    
But that's an O(n) operation. If you can do this to reduce the remaining O(n^2) operations, it's likely a good trade-off, at least for larger values of n. –  Scott Sauyet Dec 12 '12 at 23:10

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