# Find If 4 Points Form a Quadrilateral

Can someone please show me an algorithm to write a function that returns true if 4 points form a quadrilateral, and false otherwise? The points do not come with any order.

I've tried to check all permutations of the 4 points and see if there's 3 points that forms a straight line. If there's 3 points that forms a straight line than it's not quadrilateral. But then I realize that there's no way to tell the order. And then I struggle for several hours of thinking and googling with no result :(

But still find no solution. In the case of 1, it can't detect another kind of quadrilateral, and in 2 it assumes that the points are quadirateral already. Are there any other way to find out if 4 points form a quadirateral?

Thanks before.

EDIT FOR CLARIFICATION:

I define quadrilateral as simple quadrilateral, basically all shapes shown in this picture:

except the shape with "quadrilateral" and "complex" caption.

As for problems with the "checking for collinear triplets" approach, I tried to check the vertical, horizontal, and diagonal lines with something like this:

``````def is_linear_line(pt1, pt2, pt3):
return (pt1[x] == pt2[x] == pt3[x] ||
pt1[y] == pt2[y] == pt3[y] ||
slope(pt1, pt2) == slope(pt2, pt3))
``````

And realize that rectangle and square will count as linear line since the slope of the points will be all the same. Hope this clears things out.

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How do you define a quadrilateral? And please explain what's wrong with checking for collinear triplets in more detail. –  tom Mar 1 '12 at 9:14
@tom: I've edited the question for clarifications. Please tell me if something's still unclear. Thanks. –  bertzzie Mar 1 '12 at 9:26
Thank you. According do this definition, any four points form a quadrilateral if you can choose the edges. –  tom Mar 1 '12 at 10:24
@tom is right. The question should be "if 4 points can form a quadrilateral". –  karatedog Mar 1 '12 at 15:38

This is for checking if a quadrilateral is convex. Not if it is a simple quadrilateral.

I did like this in objective-c https://github.com/hfossli/AGGeometryKit/

``````extern BOOL AGQuadIsConvex(AGQuad q)
{
BOOL isConvex = AGLineIntersection(AGLineMake(q.bl, q.tr), AGLineMake(q.br, q.tl), NULL);
return isConvex;
}

BOOL AGLineIntersection(AGLine l1, AGLine l2, AGPoint *out_pointOfIntersection)
{
// http://stackoverflow.com/a/565282/202451

AGPoint p = l1.start;
AGPoint q = l2.start;
AGPoint r = AGPointSubtract(l1.end, l1.start);
AGPoint s = AGPointSubtract(l2.end, l2.start);

double s_r_crossProduct = AGPointCrossProduct(r, s);
double t = AGPointCrossProduct(AGPointSubtract(q, p), s) / s_r_crossProduct;
double u = AGPointCrossProduct(AGPointSubtract(q, p), r) / s_r_crossProduct;

if(t < 0 || t > 1.0 || u < 0 || u > 1.0)
{
if(out_pointOfIntersection != NULL)
{
*out_pointOfIntersection = AGPointZero;
}
return NO;
}
else
{
if(out_pointOfIntersection != NULL)
{
AGPoint i = AGPointAdd(p, AGPointMultiply(r, t));
*out_pointOfIntersection = i;
}
return YES;
}
}
``````
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There is no way to determine both vertex order and presence of a quadrilateral in the same operation unless you use operations that are far more expensive than what you're already performing.

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the expensiveness of the operation is not a concern. Is there a way for that? –  bertzzie Mar 1 '12 at 8:58

Do you have any more inputs than the 4 points? because if 4 points succeed to your test, they can always form 3 different quadrilaterals, sometime of different family. For example, Take a square, add 2 diagonal and remove the side.

So with only 4 points as input, you cannot do better than what you are already doing.

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Nope, there's only 4 inputs. There's no more way to improve it then? –  bertzzie Mar 1 '12 at 9:37

Let A, B, C and D be the four points. You have to assume that the edges are A-B, B-C, C-D, and D-A. If you can't make that assumption, the four points will always form a quadrilateral.

``````if (A-B intersects C-D) return false
if (B-C intersects A-D) return false
return true
``````
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Checking for collinear triplets (like you did) will exclude cases where the four points form triangles or straight lines.

To exclude also the complex quadrilateral (with crossing edges):

A quadrilateral formed by the points A, B, C and D is complex, if the intersection of AB and CD (if any) lies between the points A and B, and the same applies for BC and DA.

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