Can anyone provide an example of a function that returns the cross product of TWO 2d vectors? I am trying to implement this algorithm.

C code would be great. Thanks.

EDIT: found another way todo it that works for 2D and is dead easy.

bool tri2d::inTriangle(vec2d pt) {
    float AB = (pt.y-p1.y)*(p2.x-p1.x) - (pt.x-p1.x)*(p2.y-p1.y);
    float CA = (pt.y-p3.y)*(p1.x-p3.x) - (pt.x-p3.x)*(p1.y-p3.y);
    float BC = (pt.y-p2.y)*(p3.x-p2.x) - (pt.x-p2.x)*(p3.y-p2.y);

    if (AB*BC>0.f && BC*CA>0.f)
        return true;
    return false;    
  • Is this for work or home work? – legends2k Feb 25 '10 at 10:39
  • This is for personal enjoyment. Why? – user181351 Feb 25 '10 at 10:46
  • dup… – jk. Feb 25 '10 at 10:47
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    @tm1rbt -- Because SOers like to know when we are doing or helping with homework so that we can claim the credit transfers to our own academic transcripts. – High Performance Mark Feb 25 '10 at 10:47
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    How on earth can you ask for a function to calculate a cross-product, accept an answer that's incorrect, and then post a function that returns a boolean? I'm voting this down and voting to close. – duffymo Feb 27 '10 at 5:33
up vote 15 down vote accepted

(Note: The cross-product of 2 vectors is only defined in 3D and 7D spaces.)

The code computes the z-component of 2 vectors lying on the xy-plane:

vec2D a, b;
double z = a.x * b.y - b.x * a.y;
return z;
  • Wow. Would like to give you an extra +1 for that link! – AakashM Feb 25 '10 at 10:51
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    @tm1rbrt: That CrossProduct should be a full 3D cross-product. You can always add back the two 0 components. – kennytm Feb 25 '10 at 11:44
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    The cross product of two vectors in 3D space is a 3D vector, yet your code only returns a double. What good is one component? – duffymo Feb 26 '10 at 2:41
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    The 3-D cross product of two vectors in the x/y plane is always along the z axis, so there's no point in providing two additional numbers known to be zero. Another way to look at it: the closest 2-D equivalent to a 3-D cross product is an operation (the one above) that returns a scalar. – comingstorm Feb 26 '10 at 5:47
  • Also, I want to assure you that the above operation will in fact work correctly with the algorithm you link to. If you work it out, the dot product of the resulting cross product vectors simplifies to a simple product of the resulting scalars. Your updated version above could be considered a simplified (and nicely symmetric!) version of this: by reducing the problem to comparing the signs of the resulting scalars, you can determine that the orientation of the original triangle is redundant. – comingstorm Feb 26 '10 at 6:23

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