rgb_value_t Sphere::shade_reflective(Ray* ray, Light* light, std::list<Sphere*>* sphereList, coord_t* point, int ref_cnt){
rgb_value_t darkness, ret_val;
darkness.r = 0;
darkness.g = 0;
darkness.b = 0;
coord_t norm_vect;
norm_vect = subtract_coord(point, ¢er);
norm_vect = normalize_vect(&norm_vect);
coord_t reflect_dir;
reflect_dir = subtract_coord_nopt(ray->getDirection(), mult_vect(&norm_vect, 2.0*(scalar_mult_vect_nopt(norm_vect, ray->getDirection()))));
if (ref_cnt > 0) {
Ray* reflectedRay = new Ray(point, &reflect_dir);
Sphere* pointer_dummy=this;
ret_val = reflectedRay->raytrace(sphereList, light, &pointer_dummy, ref_cnt-1);
delete reflectedRay;
return ret_val;
} else {
return darkness;
}
}
rgb_value_t Sphere::shade_glass(Ray* ray, Light* light, std::list<Sphere*>* sphereList, coord_t* point, int ref_cnt){
rgb_value_t darkness, ret_val;
darkness.r = 0;
darkness.g = 0;
darkness.b = 0;
if (ref_cnt == 0) return darkness;
coord_t norm_ray_dir_vect = ray->getDirection();
norm_ray_dir_vect = normalize_vect(&norm_ray_dir_vect);
coord_t norm_vect;
norm_vect = subtract_coord(point, ¢er);
norm_vect = normalize_vect(&norm_vect);
bool ray_going_inside = (scalar_mult_vect(&norm_vect, &norm_ray_dir_vect)<=0.0) ? true : false;
coord_t refract_dir;
float r, w, k;
if (ray_going_inside) {
r = 1/brechzahl;
} else {
r = brechzahl;
}
w = -scalar_mult_vect(&norm_vect, &norm_ray_dir_vect)*r;
k = 1.0 + (w-r)*(w+r);
if (k<0.0) {
return this->shade_reflective(ray, light, sphereList, point, ref_cnt-1);
}
norm_ray_dir_vect = mult_vect(&norm_ray_dir_vect, r);
norm_vect = mult_vect(&norm_vect, (w-sqrt(k)));
refract_dir = add_coord(&norm_ray_dir_vect, &norm_vect);
Ray* refractedRay = new Ray(point, &refract_dir);
Sphere* pointer_dummy=this;
ret_val = refractedRay->raytrace(sphereList, light, &pointer_dummy, ref_cnt-1);
delete refractedRay;
return ret_val;
}
static void test_normalize() {
vec3 v;
v.x = 1;
v.y = 0;
v.z = 0;
normalize_vect(&v);
assert(v.x == 1);
assert(v.y == 0);
assert(v.z == 0);
v.x = 3;
v.y = 1;
v.z = 2;
normalize_vect(&v);
assert(equal_f3(v.x, 0.802));
assert(equal_f3(v.y, 0.267));
assert(equal_f3(v.z, 0.535));
}
int pt_lighted(t_obj *obj, t_point pt, t_light *light)
{
t_ray ray;
float dist_to_light;
ray.orig.x = pt.x;
ray.orig.y = pt.y;
ray.orig.z = pt.z;
ray.dir.x = light->orig.x - ray.oriug.x;
ray.dir.y = light->orig.y - ray.oriug.y;
ray.dir.z = light->orig.z - ray.oriug.z;
dist_to_light = vect_norm(&ray.dir);
normalize_vect(&ray, 0, obj, 0);
if (ray.inter_t <= dist_ti_light)
return (0);
return (1);
}
rgb_value_t Sphere::shade_non_reflective(Ray* ray, Light* light, std::list<Sphere*>* sphereList, coord_t* point){
rgb_value_t darkness;
darkness.r = 0;
darkness.g = 0;
darkness.b = 0;
coord_t dist_ray_vect;
float dist_ray_abs;
coord_t dist_light_vect;
float dist_light_abs;
dist_ray_vect = subtract_coord_nopt(this->getCenter(), ray->getStartPoint());
dist_ray_abs = vect_abs(&dist_ray_vect);
dist_light_vect = subtract_coord_nopt(this->getCenter(), light->getPosition());
dist_light_abs = vect_abs(&dist_light_vect);
bool light_inside = (dist_light_abs<=this->getRadius()) ? true : false;
bool ray_inside = (dist_ray_abs<=this->getRadius()) ? true : false;
if (light_inside!=ray_inside) {
return darkness;
}
if (!light_inside) {
//std::cout << "outside" << std::endl;
coord_t norm_vect;
norm_vect = subtract_coord(point, ¢er);
coord_t light_point_vect;
light_point_vect = subtract_coord_nopt(*point, light->getPosition());
float light_point_abs = vect_abs(&light_point_vect);
float parallelism = scalar_mult_vect(&norm_vect, &light_point_vect);
if (parallelism>0.0) return darkness;
coord_t light_pos = light->getPosition();
Ray* lightRay = new Ray(&light_pos, &light_point_vect);
float buffer;
for (std::list<Sphere*>::iterator p = (*sphereList).begin(); p!=(*sphereList).end(); p++) {
if ((*p)!=this) {
if ((*p)->intersectsWithRay(lightRay, &buffer)) {
if (buffer<light_point_abs) {
delete lightRay;
return darkness;
}
}
}
}
delete lightRay;
norm_vect = normalize_vect(&norm_vect);
light_point_vect = div_vect(&light_point_vect, -light_point_abs);
parallelism = scalar_mult_vect(&norm_vect, &light_point_vect);
rgb_value_t rgb_ret = this->getColour();
rgb_ret.r *= parallelism;
rgb_ret.g *= parallelism;
rgb_ret.b *= parallelism;
return rgb_ret;
} else {
//std::cout << "inside" << std::endl;
coord_t norm_vect;
norm_vect = subtract_coord(point, ¢er);
coord_t light_point_vect;
light_point_vect = subtract_coord_nopt(*point, light->getPosition());
float light_point_abs = vect_abs(&light_point_vect);
coord_t light_pos = light->getPosition();
Ray* lightRay = new Ray(&light_pos, &light_point_vect);
float buffer;
for (std::list<Sphere*>::iterator p = (*sphereList).begin(); p!=(*sphereList).end(); p++) {
if ((*p)!=this) {
if ((*p)->intersectsWithRay(lightRay, &buffer)) {
if (buffer<light_point_abs) {
delete lightRay;
return darkness;
}
}
}
}
delete lightRay;
norm_vect = normalize_vect(&norm_vect);
light_point_vect = div_vect(&light_point_vect, light_point_abs);
float parallelism = scalar_mult_vect(&norm_vect, &light_point_vect);
rgb_value_t rgb_ret = this->getColour();
rgb_ret.r *= parallelism;
rgb_ret.g *= parallelism;
rgb_ret.b *= parallelism;
return rgb_ret;
}
}
void Camera::makeSnapShot(std::list<Sphere*>* sphereList, Light* light, int ref_max, bool show) {
coord_t ray_dir_temp, ray_dir, ray_dir_projection_help, focal_point;
focal_point = point_on_straight(&optical_center, &direction, -focal_length);
rgb_value_t pixel_temp;
Sphere* dummy_pointer = NULL;
Ray privateRay(&focal_point, &focal_point);
omp_set_num_threads(2);
#pragma omp parallel for firstprivate(privateRay, ray_dir_temp, ray_dir, pixel_temp, ray_dir_projection_help) schedule(static,1)
for (int i=0; i<sensor_height_px; i++) {
for (int j=0; j<sensor_width_px; j++) {
//initial Koordinatenursprung
ray_dir.y = j*px_width -sensor_width_physical/2;
ray_dir.z = i*px_height -sensor_height_physical/2;
ray_dir.x = 0.0;
//rotation um y achse
ray_dir_projection_help = direction;
ray_dir_projection_help.y= 0.0;
ray_dir_projection_help = normalize_vect(&ray_dir_projection_help);
if (ray_dir_projection_help.x < 0.0) ray_dir_projection_help.x=-ray_dir_projection_help.x;
ray_dir_temp.x = -ray_dir.z*ray_dir_projection_help.z;
ray_dir_temp.y = ray_dir.y;
ray_dir_temp.z = ray_dir.z*ray_dir_projection_help.x;
//rotation um z achse
ray_dir_projection_help = direction;
ray_dir_projection_help.z= 0.0;
ray_dir_projection_help = normalize_vect(&ray_dir_projection_help);
ray_dir.x = ray_dir_temp.x*ray_dir_projection_help.x - ray_dir_temp.y*ray_dir_projection_help.y;
ray_dir.y = ray_dir_temp.x*ray_dir_projection_help.y + ray_dir_temp.y*ray_dir_projection_help.x;
ray_dir.z = ray_dir_temp.z;
//ray_dir = ray_dir_temp;
//translation to optical center
ray_dir = add_coord(&ray_dir, &optical_center);
ray_dir = subtract_coord(&ray_dir, &focal_point);
privateRay.setStartPoint(&optical_center);
privateRay.setDirection(&ray_dir);
pixel_temp = privateRay.raytrace(sphereList, light, &dummy_pointer, ref_max);
image_matrix->at<Vec3b>(i,j)[2] = pixel_temp.r;
image_matrix->at<Vec3b>(i,j)[1] = pixel_temp.g;
image_matrix->at<Vec3b>(i,j)[0] = pixel_temp.b;
}
}
if (show) {
namedWindow( "Raytrace", CV_WINDOW_AUTOSIZE );
imshow("Raytrace", *image_matrix);
std::cout << "BLA" << std::endl;
cvWaitKey(0);
} else {
//imwrite("raytrace.jpg", image_matrix);
}
}
void Camera::setDir(coord_t dir) {
direction = normalize_vect(&dir);
}
void Ray::setDirection (coord_t* coord) {
direction = normalize_vect(coord);
}
