For school, I have recently started creating my own raytracer. However, I’ve hit a snag with either computing the viewing rays, or checking for an intersection between a triangle and a ray. As far as I can tell, the computations seem to be executed correctly, as I place my camera in the origin and have it face the -z axis towards an object right in front of it, allowing for simple vector maths by hand. Everything seems to check out, but nothing gets painted on the screen.
I will post the code I am using the calculate the viewing rays.
public Ray generateRay(float nX, float nY , Point2f coordinates)
{
// Compute l, r, b and t.
Vector3f temp = VectorHelper.multiply(u, nX/2.0f);
float r = temp.x + Position.x;
temp = VectorHelper.multiply(u, -nX/2.0f);
float l = temp.x + Position.x;
temp = VectorHelper.multiply(v, nY/2.0f);
float t = temp.y + Position.y;
temp = VectorHelper.multiply(v, -nY/2.0f);
float b = temp.y + Position.y;
// Compute the u and v coordinates.
float uCo = (l + (r - l) * (coordinates.x + 0.5f)/nX);
float vCo = (b + (t - b) * (coordinates.y + 0.5f)/nY);
// Compute the ray's direction.
Vector3f rayDirection = VectorHelper.multiply(w, -FocalLength);
temp = VectorHelper.add(VectorHelper.multiply(u, uCo), VectorHelper.multiply(v, vCo));
rayDirection = VectorHelper.add(rayDirection, temp);
rayDirection = VectorHelper.add(rayDirection, Position);
rayDirection = VectorHelper.normalize(VectorHelper.add(rayDirection, temp));
// Create and return the ray.
return new Ray(Position, rayDirection);
}
The following code is what I use to calculate an intersection. It uses Cramer’s Rule to solve the matrix equation.
public static Point3f rayTriangleIntersection(
Ray ray, Point3f vertexA, Point3f vertexB, Point3f vertexC)
{
// Solve the linear system formed by the ray and the parametric surface
// formed by the points of the triangle.
// | a d g | | B | | j |
// | b e h | * | Y | = | k |
// | c f i | * | t | = | l |
// The following uses Cramer's rule to that effect.
float a = vertexA.x - vertexB.x; float d = vertexA.x - vertexC.x; float g = ray.getDirection().x;
float b = vertexA.y - vertexB.y; float e = vertexA.y - vertexC.y; float h = ray.getDirection().y;
float c = vertexA.z - vertexB.z; float f = vertexA.z - vertexC.z; float i = ray.getDirection().z;
float j = vertexA.x - ray.getOrigin().x;
float k = vertexA.y - ray.getOrigin().y;
float l = vertexA.z - ray.getOrigin().z;
// Compute some subterms in advance.
float eihf = (e * i) - (h * f);
float gfdi = (g * f) - (d * i);
float dheg = (d * h) - (e * g);
float akjb = (a * k) - (j * b);
float jcal = (j * c) - (a * l);
float blkc = (b * l) - (k * c);
// Compute common division number.
float m = (a * eihf) + (b * gfdi) + (c * dheg);
// Compute unknown t and check whether the point is within the given
// depth interval.
float t = -((f * akjb) + (e * jcal) + (d * blkc)) / m;
if (t < 0)
return null;
// Compute unknown gamma and check whether the point intersects the
// triangle.
float gamma = ((i * akjb) + (h * jcal) + (g * blkc)) / m;
if (gamma < 0 || gamma > 1)
return null;
// Compute unknown beta and check whether the point intersects the
// triangle.
float beta = ((j * eihf) + (k * gfdi) + (l * dheg)) / m;
if (beta < 0 || beta > (1 - gamma))
return null;
// Else, compute the intersection point and return it.
Point3f result = new Point3f();
result.x = ray.getOrigin().x + t * ray.getDirection().x;
result.y = ray.getOrigin().y + t * ray.getDirection().y;
result.z = ray.getOrigin().z + t * ray.getDirection().z;
return result;
}
My question is rather simple. What am I doing wrong? I’ve looked and debugged this code to death and cannot single out the errors, google offers little more than the theory I already have in the book I am using. Also, the code is still rather rough as I’m just focusing on getting it to work before cleaning it up.
Thanks in advance,
Kevin
Hard to say precisely what is going wrong. Especially since you aren’t using descriptive variable names (what are nX, nY etc.??)
Here are some tips:
Example set-up that should work:
Then your ray direction should be something like (for a pixel [screenX, screenY]):