# Algorithm for ordering points on a map?

I have an array of points, where each point is a coordinate on a map. I'd like to make it so that when I add a point to the map, it's added to my array in between the closest two points.

Additionally, I'd like to render the points, so that there are never any crossovers between the different points. New points should be added to the outside edge of the resulting polygon, and connected to the closest two.

Is there an algorithm for doing this?

Edit:

For clarity, I have the following screenshot. I'd like to achieve method B:

Edit 2:

Here's a bunch of code I wrote to try and solve the problem. Assume that MBCoordinates are just that, coordinates:

``````//
//  Detect which coordinate is the closest to the supplied coordinate
//

- (void) insertCoordinateBetweenClosestNeighbors:(MBCoordinate *)coordinate{

if (![self points] || [[self points] count] < 3) {
return;
}

NSMutableSet *pointSet = [NSMutableSet setWithArray:[self points]];

MBCoordinate *closestCoordinate = [self closestCoordinateToCoordinate:coordinate inSet:pointSet];
[pointSet removeObject:closestCoordinate];

MBCoordinate *nextClosestCoordinate = [self closestCoordinateToCoordinate:coordinate inSet:pointSet];

NSUInteger indexOfClosestCoordinate, indexOfSecondClosestCoordinate, insertionIndex;

for (NSUInteger i=0; i < [[self points] count]; i++) {

if ([[self points][i] isEqual:closestCoordinate]) {
indexOfClosestCoordinate = i;
}

if ([[self points][i] isEqual:nextClosestCoordinate]) {
indexOfSecondClosestCoordinate = i;
}
}

if(indexOfSecondClosestCoordinate == indexOfClosestCoordinate-1){
insertionIndex = indexOfSecondClosestCoordinate+1;
}else{
insertionIndex = indexOfClosestCoordinate+1;
}

[[self points] insertObject:coordinate atIndex:insertionIndex];

/*

Not in use in my program, but an alternate attempt:
[self sortPointsByDistance];
*/
}

- (void) sortPointsByDistance{

//
//  Points that need sorting
//

NSMutableSet *unprocessedPoints = [NSMutableSet setWithArray:[self points]];

//
//  All of the unsorted points
//

NSMutableSet *unsortedPoints = [NSMutableSet setWithArray:[self points]];

//
//  The unsorted points minus the closest one
//

NSMutableSet *unsortedPointsExceptClosest = [NSMutableSet setWithArray:[self points]];

//
//  We put the point into here in the correct order
//

NSMutableArray *sortedPoints = [@[] mutableCopy];

//
//  Prime the pump
//

MBCoordinate *workingCoordinate = [self points][0];
[unprocessedPoints removeObject:workingCoordinate];

while([unprocessedPoints count] > 0){

MBCoordinate *closestCoordinate = [self closestCoordinateToCoordinate:workingCoordinate inSet:unsortedPoints];
MBCoordinate *secondClosestCoordinate = nil;

//
//  The closest point might be sorted already!
//
//  If it is, then we have to find the closest point.
//

if ([sortedPoints containsObject:closestCoordinate]) {

NSInteger indexOfClosest = [sortedPoints indexOfObject:closestCoordinate];
NSInteger indexOfSecondClosest = indexOfClosest;
NSInteger targetIndex = indexOfClosest+1;

if (!secondClosestCoordinate) {
[unsortedPoints removeObject:closestCoordinate];
secondClosestCoordinate = [self closestCoordinateToCoordinate:workingCoordinate inSet:unsortedPointsExceptClosest];

if ([sortedPoints containsObject:secondClosestCoordinate]) {

//
//  Insert between the two points
//

indexOfSecondClosest = [sortedPoints indexOfObject:secondClosestCoordinate];

}
}

if (indexOfSecondClosest < indexOfClosest) {
targetIndex = indexOfSecondClosest + 1;
}

[sortedPoints insertObject:workingCoordinate atIndex:targetIndex];
workingCoordinate = [unprocessedPoints anyObject];

break;

}else{
workingCoordinate = closestCoordinate;
}

[unprocessedPoints removeObject:workingCoordinate];
unsortedPointsExceptClosest = [unsortedPoints copy];
secondClosestCoordinate = nil;

}

[self setPoints:sortedPoints];
}

- (MBCoordinate *) closestCoordinateToCoordinate:(MBCoordinate *)coordinate inSet:(NSSet *)aSet{

MBCoordinate *closest = nil;
CGFloat closestDistance;

for (MBCoordinate *coordinateInSet in aSet) {

if ([coordinateInSet isEqual:coordinate]) {
continue;
}

if (!closest) {
closest = coordinateInSet;
closestDistance = [self distanceBetweenCoordinate:coordinate andCoordinate:coordinateInSet];
}

CGFloat distanceBetweenPoints = [self distanceBetweenCoordinate:coordinate andCoordinate:coordinateInSet];

if (distanceBetweenPoints < closestDistance) {
closest = coordinateInSet;
closestDistance = distanceBetweenPoints;
}

}

return closest;
}

//
//  Determines the distance between two coordinates
//

- (CGFloat) distanceBetweenCoordinate:(MBCoordinate *)coordinate andCoordinate:(MBCoordinate *)anotherCoordinate{

CGFloat xDistance, yDistance;

xDistance = coordinate.latitude-anotherCoordinate.latitude;
yDistance = coordinate.longitude-anotherCoordinate.longitude;

float distance = xDistance/yDistance;

//
//  Absolute value of floats...
//

if (distance < 0) {
distance *= -1;
}

return distance;

}
``````
-
Are you assuming convexity? Also, suppose P is a regular polygon with center C and a point is added at C; what should happen? –  jwpat7 Sep 24 '12 at 4:56
@jwpat7 I haven't considered those things. Is there a way to "optimize" that? Like, assume one way or the other depending on the points? –  Moshe Sep 24 '12 at 5:01
If you assume the resulting polygon is always convex as points are added, it's straightforward to add the n'th point in O(n) time. If you don't assume convexity, eg allow star shapes, the problem might not be solvable. Re convex hull, complexity of it is Ω(n log n) but you can get O(n) complexity if you assume no points are in the interior of the hull. –  jwpat7 Sep 24 '12 at 5:05
Well, I want to allow for star shapes, etc, but attempt to position wherever possible, in the right spot with the proper connections. –  Moshe Sep 24 '12 at 5:10