public void setOrigin(final int win_x, final int win_y) {
final float[] in = {
win_x * m_delta.get(0) + m_constant.get(0), win_y * m_delta.get(1) + m_constant.get(1)
};
final float[] center = {
m_inverse.get(0, 0) * in[0] + m_inverse.get(0, 1) * in[1] + m_inverse.get(0, 3),
m_inverse.get(1, 0) * in[0] + m_inverse.get(1, 1) * in[1] + m_inverse.get(1, 3),
m_inverse.get(2, 0) * in[0] + m_inverse.get(2, 1) * in[1] + m_inverse.get(2, 3),
m_inverse.get(3, 0) * in[0] + m_inverse.get(3, 1) * in[1] + m_inverse.get(3, 3)
};
float[] front = {
center[0] - m_inverse.get(0, 2),
center[1] - m_inverse.get(1, 2),
center[2] - m_inverse.get(2, 2),
center[3] - m_inverse.get(3, 2)
};
final float front_inv = 1.0f / front[3];
front[0] *= front_inv;
front[1] *= front_inv;
front[2] *= front_inv;
float[] back = {
center[0] + m_inverse.get(0, 2),
center[1] + m_inverse.get(1, 2),
center[2] + m_inverse.get(2, 2),
center[3] + m_inverse.get(3, 2)
};
final float back_inv = 1.0f / back[3];
back[0] *= back_inv;
back[1] *= back_inv;
back[2] *= back_inv;
m_t = 0.0f;
m_from = new Vector3f(front[0], front[1], front[2]);
Vector3f direction = new Vector3f(back[0] - front[0], back[1] - front[1], back[2] - front[2]);
m_direction = direction.normalize();
}
public float depth() {
Vector3f point = this.point();
final float view2 =
point.getX() * m_combined.get(2, 0)
+ point.getY() * m_combined.get(2, 1)
+ point.getZ() * m_combined.get(2, 2)
+ m_combined.get(2, 3);
final float view3 =
point.getX() * m_combined.get(3, 0)
+ point.getY() * m_combined.get(3, 1)
+ point.getZ() * m_combined.get(3, 2)
+ m_combined.get(3, 3);
return ((1.0f + view2 / view3) * 0.5f);
}
public final void combine_projection_and_modelview(double[] projection, double[] modelview) {
/* Calculate a combined matrix PM in order to project the point in the
* object coordinate system onto the image plane in the window coordinate
* system. The matrix PM is composed of a modelview marix M and a projection
* matrix P. It is possible to calculate the efficiently by taking advantage
* of zero-elements in the M and P.
*
* Modelview matrix M: [ m0, m4, m8, m12 ] [ m0, m4, m8, m12 ]
* [ m1, m5, m9, m13 ] = [ m1, m5, m9, m13 ]
* [ m2, m6, m10, m14 ] [ m2, m6, m10, m14 ]
* [ m3, m7, m11, m15 ] [ 0, 0, 0, 1 ]
*
* Projection matrix P: [ p0, p4, p8, p12 ] [ p0, 0, p8, 0 ] (Pers.)
* [ p1, p5, p9, p13 ] = [ 0, p5, p9, 0 ]
* [ p2, p6, p10, p14 ] [ 0, 0, p10, p14 ]
* [ p3, p7, p11, p15 ] [ 0, 0, -1, 0 ]
*
* [ p0, 0, 0, p12 ] (Orth.)
* = [ 0, p5, 0, p13 ]
* [ 0, 0, p10, p14 ]
* [ 0, 0, 0, 1 ]
*
* if 'r == -l' in the view volume, P is denoted as follows:
*
* [ p0, 0, 0, 0 ] (Pers.) [ p0, 0, 0, 0 ] (Orth.)
* [ 0, p5, 0, 0 ] [ 0, p5, 0, 0 ]
* [ 0, 0, p10, p14 ] [ 0, 0, p10, p14 ]
* [ 0, 0, -1, 0 ] [ 0, 0, 0, 1 ]
*
* Combined matrix PM:
*
* [ p0 m0, p0 m4, p0 m8, p0 m12 ] (Pers.)
* [ p5 m1, p5 m5, p5 m9, p5 m13 ]
* [ p10 m2, p10 m6, p10 m10, p10 m14 + p14 ]
* [ -m2, -m6, -m10, -m14 ]
*
* [ p0 m0, p0 m4, p0 m8, p0 m12 ] (Orth.)
* [ p5 m1, p5 m5, p5 m9, p5 m13 ]
* [ p10 m2, p10 m6, p10 m10, p10 m14 + p14 ]
* [ 0, 0, 0, 1 ]
*/
// Row 1.
Vector4f row1 =
new Vector4f(
(float) (projection[0] * modelview[0]),
(float) (projection[0] * modelview[4]),
(float) (projection[0] * modelview[8]),
(float) (projection[0] * modelview[12]));
// Row 2.
Vector4f row2 =
new Vector4f(
(float) (projection[5] * modelview[1]),
(float) (projection[5] * modelview[5]),
(float) (projection[5] * modelview[9]),
(float) (projection[5] * modelview[13]));
// Row 3.
Vector4f row3 =
new Vector4f(
(float) (projection[10] * modelview[2]),
(float) (projection[10] * modelview[6]),
(float) (projection[10] * modelview[10]),
(float) (projection[10] * modelview[14] + projection[14]));
// Row 4.
Vector4f row4;
// Perspective.
if (kvs.core.util.Math.isZero(projection[15])) {
row4 =
new Vector4f(
(float) (-modelview[2]),
(float) (-modelview[6]),
(float) (-modelview[10]),
(float) (-modelview[14]));
}
// Orthogonal.
else {
row4 = new Vector4f(0.0f, 0.0f, 0.0f, 1.0f);
}
m_combined = new Matrix44f(row1, row2, row3, row4);
// Calculate the inverse of the PM matrix.
m_inverse = m_combined.inverse();
}
