public void update(float db) {
// we can use the db value here to change the speed of the particles
loc.add(vel.mult(vel, map(db, -100, 100, .05f, 5)));
if (loc.x < 0 || loc.x > width) {
vel.x *= -1;
}
if (loc.y < 0 || loc.y > height) {
vel.y *= -1;
}
radius = constrain(db, 2, 100);
}
/**
* Given two points p1, p2 and a line passing through a,b check whether p1 and p2 are on the
* same side of the line. In our case a,b are characters and p1, p2 are cameras
*/
public boolean isInSameHalfPlane(PVector p1, PVector p2, PVector a, PVector b) {
PVector copyP1 = new PVector(p1.x, p1.y, p1.z);
PVector copyP2 = new PVector(p2.x, p2.y, p2.z);
PVector copyA = new PVector(a.x, a.y, a.z);
PVector copyB = new PVector(b.x, b.y, b.z);
copyB.sub(copyA);
copyP1.sub(copyA);
copyP2.sub(copyA);
PVector p1a = copyB.cross(copyP1);
PVector p2a = copyB.cross(copyP2);
if (p1a.dot(p2a) > 0) {
return true;
}
return false;
}
public void checkThirtyDegreeRule(
ArrayList<Cam> cameras, ArrayList<Character> characters, int selectedIdx) {
if (cameras == null || cameras.isEmpty()) {
println("No cameras in the scene!");
}
if (characters.size() != 2) {
println("Only two characters supported for now");
// TODO (sanjeet): Hack! Fix this once more characters are allowed
}
Cam selectedCamera = cameras.get(selectedIdx);
// TODO The characters.get results in a runtime error because there aren't currently any
// characters allocated in the input file.
Character ch1 = characters.get(0);
Character ch2 = characters.get(1);
// Obtaining (x,y,z) for characters and selected camera
PVector ch1Location = ch1.getTranslation();
PVector ch2Location = ch2.getTranslation();
PVector selectedCameraLocation = selectedCamera.getTranslation();
PVector cameraPoint = new PVector();
cameraPoint.add(selectedCameraLocation);
for (int i = 0; i < 100; i++) {
cameraPoint.add(selectedCamera.getZAxis());
}
PVector intersection =
getTwoLinesIntersection(
new PVector(ch1Location.x, ch1Location.z),
new PVector(ch2Location.x, ch2Location.z),
new PVector(selectedCameraLocation.x, selectedCameraLocation.z),
new PVector(cameraPoint.x, cameraPoint.z));
PVector diff = PVector.sub(selectedCameraLocation, intersection);
diff.normalize();
FloatBuffer fb = selectedCamera.modelViewMatrix;
float[] mat = fb.array();
float[] fbMatrix = new float[mat.length];
for (int i = 0; i < fbMatrix.length; i++) {
fbMatrix[i] = mat[i];
}
fbMatrix[0] = -diff.x;
fbMatrix[1] = diff.y;
fbMatrix[2] = -diff.z;
fbMatrix[9] = diff.x;
fbMatrix[10] = diff.y;
fbMatrix[11] = diff.z;
fbMatrix[13] = intersection.x;
fbMatrix[14] = intersection.y;
fbMatrix[15] = intersection.z;
PMatrix3D matrix = new PMatrix3D();
matrix.set(fbMatrix);
matrix.transpose();
pushMatrix();
applyMatrix(matrix);
rotateY(radians(30));
line(0, 0, 0, 0, 0, 1000);
rotateY(radians(-2 * 30));
line(0, 0, 0, 0, 0, 1000);
popMatrix();
for (int i = 0; i < cameras.size(); i++) {
if (i == selectedIdx) {
continue;
}
if (!cameras.get(i).isInView(ch1Location) && !cameras.get(i).isInView(ch2Location)) {
continue;
}
PVector currCamLocation = cameras.get(i).getTranslation();
PVector vect1 = PVector.sub(currCamLocation, intersection);
PVector vect2 = PVector.sub(selectedCameraLocation, intersection);
float dotP = vect1.dot(vect2) / (vect1.mag() * vect2.mag());
if (acos(dotP) <= PI / 6) {
cameras.get(i).setColor(255, 0, 0);
} else {
cameras.get(i).setColor(0, 0, 255);
}
}
}
public boolean isInView(PVector vect) {
PVector z = getZAxis();
PVector v1 = PVector.sub(vect, getTranslation());
float dotP = PVector.dot(v1, z) / (z.mag() * v1.mag());
if ((acos(dotP) * 180 / PI) <= fov) {
return true;
}
return false;
}