I'm trying to implement at line-plane intersection algorithm. According to Wikipedia I need three non-colinear points on the plane to do that.

I therefore tried implementing this algorithm in C++, however. Something is definitely wrong, cause it makes no sense that I can choose whatever x and y coordinates and they'll fit in the plane. What if the plane is vertical and along the x-axis? No point with y=1 would then be in the plane.

I realize that this problem has been posted a lot on StackOverflow, and I see lots of solutions where the plane is defined by 3 points. But I only have a normal and a position. And I can't test my line-plane intersection algorithm before I sort out my non-colinear point finder.

The problem right now, is that I'm dividing by normal.z, and that obviously won't work when normal.z is 0.

I'm testing with this plane: Plane* p = new Plane(Color(), Vec3d(0.0,0.0,0.0), Vec3d(0.0,1.0,0.0)); // second parameter : position, third parameter : normal

The current code gives this incorrect answer:

```
{0 , 0 , 0} // alright, this is the original
{12.8377 , 17.2728 , -inf} // obviously this is not a non-colinear point on the given plane
```

Here's my code:

```
std::vector<Vec3d>* Plane::getThreeNonColinearPoints() {
std::vector<Vec3d>* v = new std::vector<Vec3d>();
v->push_back(Vec3d(position.x, position.y, position.z)); // original position can serve as one of the three non-colinear points.
srandom(time(NULL));
double rx, ry, rz, start;
rx = Plane::fRand(10.0, 20.0);
ry = Plane::fRand(10.0, 20.0);
// Formula from here: http://en.wikipedia.org/wiki/Plane_(geometry)#Definition_with_a_point_and_a_normal_vector
// nx(x-x0) + ny(y-y0) + nz(z-z0) = 0
// |-----------------| <- this is "start"
//I'll try to insert position as x0,y0,z0 and normal as nx,ny,nz, and solve the equation
start = normal.x * (rx - position.x) + normal.y * (ry - position.y);
// nz(z-z0) = -start
start = -start;
// (z-z0) = start/nz
start /= normal.z; // division by zero
// z = start+z0
start += position.z;
rz = start;
v->push_back(Vec3d(rx, ry, rz));
// TODO one more point
return v;
}
```

I realize that I might be trying to solve this totally wrong. If so, please link a concrete implementation of this. I'm sure it must exist, when I see so many line-plane intersection implementations.

Thanks in advance.

`ax + by + cz == d`

. Any plane with`b == 0.0`

will be parallel to the y-axis (as you describe), because in that case the value of`y`

cannot affect the (in)equality. – comingstorm Dec 5 '11 at 23:59