# Detect if a set of points in an array that are the vertices of a complex polygon were defined in a clockwise or counterclockwise order?

EDIT: I updated the program with the answer and it works great!

I am making a program (feel free to try it out) that lets users draw polygons which it then triangulates. They can click to add vertices and hit enter to triangulate. Anyways, the algorithm works fine as long as I tell it if the points were drawn in a clockwise or counterclockwise fashion (right now I have it set only to work with clockwise polygons). I have been trying to figure this out for days, but have no idea how to determine whether the points are clockwise or counterclockwise. Try drawing shapes with the program mentioned earlier to get a better idea, you can experience what I am talking about better than I can try to explain it.

Here is how the points are defined:

``````function Point(x, y) {
this.x = x;
this.y = y;
}

var vertices = [];

// Called on click
function addPoint(mouseX, mouseY) {
vertices.push(new Point(mouseX, mouseY));
}
``````

Here is an image of a clockwise polygon:

Here is an image of a counterclockwise polygon:

If you could help me figure out how to determine the "clockwise-ness" of the points, I would be very grateful!

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Measure the angle between every three points, and sum for the entire polygon. In one direction you will get a positive, and in another you will get a negative total. Corresponding to the Clock-wise-ness of your Polygon. –  TMB Jan 24 '13 at 16:53
Just found this question: stackoverflow.com/questions/1165647/… The accepted answer has a similar solution, but probably simpler than mine. –  kodkod Jan 25 '13 at 10:35

Compute the polygon area using the shoelace formula, but without the absolute value sign. If the result is positive, the points are ordered counterclockwise, and if negative - clockwise.

``````function polygonArea() {
var area = 0;
for (var i = 0; i < vertices.length; i++) {
j = (i + 1) % vertices.length;
area += vertices[i].x * vertices[j].y;
area -= vertices[j].x * vertices[i].y;
}
return area / 2;
}
var clockwise = polygonArea() > 0;
``````
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Works perfectly! I added some code for future viewers. Thanks a million! –  Conner Ruhl Jan 24 '13 at 18:03
Since we only care about the sign there's no need to divide by two; not that it makes much difference. –  Samuel Edwin Ward Jan 24 '13 at 18:18

A general idea would be to take a look at the convex hull of your polygone and guess the orientation from there. However, I think that you do not need to build the whole hull to find the orientation, but just one segment belonging to it.

So:

• Find two points of your polygones so that all the other points are on one side of this line.
• If all the points are on the left (just check one of the points), it's counterclockwise. If they are on the right, it's clockwise.

Example:

On the top figure: 4-5 let the figure on the right, 5-11 let the figure on the right, ... On the bottom figure: 6-7 let the figure on the left, 7-14 let the figure on the left, ...

Warning: While "walking" on your polygon, do not restart the numeration, otherwise it will be wrong. On the top figure, 4-(n-1) let the figure on the left!

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Your intuitive definition of clockwisedness is not well defined. For example, If I draw a horseshoe:

``````   /---a-b--\
/   _d_c_  \
/  /       \ \
| |        | |
| |        | |
\ \       / /
\ \     / /
--     --
``````

If `0 = a < b < b < d` and I look at `a` and `b` I would conclude from your description that the shape has been drawn clockwise, but if `0 = c < d < a < b` I would conclude that the shape has been drawn anticlockwise. Since both of these scenarios involve the same direction in which the points were drawn, just from different starting points, I can only conclude that your definition is lacking.

The horseshoe I drew isn't the best; the idea is that it is almost a circle with just a small hole at the bottom, to allow the other side to be drawn in the opposite direction.

If you are interested in defining things more strictly, then I suggest something along the following lines:

Considering any finite simple polygon as separating the plane into two distinct areas (one finite and one infinite), we can always consider the finite area to be the interior of the polygon. In such a scenario we define a vertex ordering to be clockwise iff the order of the points runs with the exterior along its right-hand side. This is called curve orientation.

Once you have this more solid definition, implementation can be as simple as counting the winding number. Take the midpoint of any ordered pair, say 0 and 1, take a line segment to the right of the ordered pair (at any angle, say perpendicular), and count how many intersections it has with other line segments: The curve is clockwise iff the number is odd.

This is simple to implement, linear in time `O(n)`, and adds constant space `O(1)`.

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You can always "walk" on the polygon so that the interior is on the left. If the numeration agrees with this "walking" direction, it's counterclockwise (positive in maths), otherwise it's clockwise. So this notion is well-defined! –  Dr_Sam Jan 24 '13 at 17:02
@Dr_Sam, that's correct, but that's not what the OP defined. Show me where interior and exterior were defined in the question and I'll agree with you. If they weren't, then there can be no orientation, just like my example explains. –  davin Jan 24 '13 at 17:13
As you said in your edited answer, there's a bounded region and an unbounded region, which define implicitly what is the interior and the exterior. And the question was about triangulating the polygon, so I guess the interior, i.e. bounded part. By the way, great answer! –  Dr_Sam Jan 25 '13 at 7:36

This a function function that specialized for OpenLayers. As You Can See The Condition Of Clockwise Polygon Is area<0 This Reference Confirm It.

``````function IsClockwise(feature)
{
if(feature.geometry==null)return -1;
var vertices=feature.geometry.getVertices();
var area=0;
for (var i = 0; i < (vertices.length); i++)
{
j = (i + 1) % vertices.length;
area += vertices[i].x * vertices[j].y;
area -= vertices[j].x * vertices[i].y;
// console.log(area);
}
return (area < 0);
}
``````
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