# Can someone help me analyze my Convex Hull Algo

Am just curious to see if it is efficient or not. Basically it finds the left and right most outer points then finds the top "Half" by searching for the largest angle and does the same for the button "Half" I put "Half" in quotes cause its not always the half. This is my code

``````private void findCH(){
findRightLeft();
paintP.setConvexHull(true, chPoints.toArray(new Point[0]));
}

// Finds the left and right most points
private void findRightLeft(){

points = paintP.getPoints();
rightMost = points[0];
leftMost = points[0];

for(Point p: points){
if(p.x < leftMost.x){
leftMost = p;
}else if(p.x > rightMost.x){
rightMost = p;
}
}
}

//Gets the Top points
private ArrayList<Point> getTopCHPoints(){
Point nextLp = leftMost;
Point nextRp = rightMost;
ArrayList<Point> p = new ArrayList<>();

while(true){
nextLp = getTopNextPoint(nextLp);
if(nextLp.x == nextRp.x && nextLp.y == nextRp.y){
break;
}
nextRp = getTopNextPoint(nextRp);
if(nextLp.x == nextRp.x && nextLp.y == nextRp.y){
break;
}
}
Collections.sort(p, new PointCompare());
return p;

}

//Gets the button Points
private ArrayList<Point> getButtonCHPoints(){
Point nextLp = leftMost;
Point nextRp = rightMost;
ArrayList<Point> p = new ArrayList<>();

while(true){
nextLp = getButtomNextPoint(nextLp);
if(nextLp.x == nextRp.x && nextLp.y == nextRp.y){
break;
}
nextRp = getButtomNextPoint(nextRp);
if(nextLp.x == nextRp.x && nextLp.y == nextRp.y){
break;
}
}

Collections.sort(p, new PointCompare());
Collections.reverse(p);
return p;

}

//gets the next Top Point
private Point getTopNextPoint(Point poi){
int f  = Arrays.asList(points).indexOf(poi);
double h;
double a;
double angle = -1;
Point returnP = null;

for(int i = 0; i < f; i++ ){
a = Math.abs(points[i].x - poi.x);
h = poi.distance(points[i]);
if(Math.acos(a/h) > angle){
angle = Math.acos(a/h);
returnP = points[i];
}
}
if(returnP == null){
return poi;
}else{
return returnP;
}
}

//Gets the next button point
private Point getButtomNextPoint(Point poi){
int f  = Arrays.asList(points).indexOf(poi);
double h;
double a;
double angle = -1;
Point returnP = null;

for(int i = f; i < points.length; i++ ){
a = Math.abs(points[i].x - poi.x);
h = poi.distance(points[i]);
if(Math.acos(a/h) > angle){
angle = Math.acos(a/h);
returnP = points[i];
}
}

if(returnP == null){
return poi;
}else{
return returnP;
}
}
``````
-
I think you should use complex numbers. If you find the left-most point or right-most point, then you can start with a vertical line for finding the point with the lowest angle. Top-most or bottom most can use a horizontal line. After you get two points, iterate through your list of points for the one with the smallest angle. If I have P1, P2, and P3 (all complex), where P3 is a test point, P1 and P2 are former points, then take (P3-P2)*((P1-P2).Conjugate.Normalize). The point with the smallest imaginary term will be the next point. –  Robert Richter Feb 10 '13 at 0:32
This expression (P3-P2)*((P1-P2).Conjugate) is derived as follows: Move everything so P2 (Your last point) is at the origin. Move P1 to the negative X axis to cause a rotation. Then normalize the result to get the straightest point 3. I forgot to mention above that P3 must have a positive R term when normalized, or it must be discarded. –  Robert Richter Feb 10 '13 at 0:36
This belongs on Code Review –  Jim Garrison Feb 10 '13 at 9:42
@RobertRichter strange using complex number for convex hull calculations –  AlexWien Feb 10 '13 at 16:07
Fir st you should delcare what is the name of the algorithm? I think it is Quickhull (analog quicksort) in a nonrecurdive implementation –  AlexWien Feb 10 '13 at 16:08