void PlaneDistortMaskOperation::executePixelSampled(float output[4],
float x,
float y,
PixelSampler /*sampler*/)
{
float point[2];
int inside_counter = 0;
if (this->m_motion_blur_samples == 1) {
MotionSample *sample_data = &this->m_samples[0];
for (int sample = 0; sample < this->m_osa; sample++) {
point[0] = x + this->m_jitter[sample][0];
point[1] = y + this->m_jitter[sample][1];
if (isect_point_tri_v2(point,
sample_data->frameSpaceCorners[0],
sample_data->frameSpaceCorners[1],
sample_data->frameSpaceCorners[2]) ||
isect_point_tri_v2(point,
sample_data->frameSpaceCorners[0],
sample_data->frameSpaceCorners[2],
sample_data->frameSpaceCorners[3])) {
inside_counter++;
}
}
output[0] = (float)inside_counter / this->m_osa;
}
else {
for (int motion_sample = 0; motion_sample < this->m_motion_blur_samples; ++motion_sample) {
MotionSample *sample_data = &this->m_samples[motion_sample];
for (int osa_sample = 0; osa_sample < this->m_osa; ++osa_sample) {
point[0] = x + this->m_jitter[osa_sample][0];
point[1] = y + this->m_jitter[osa_sample][1];
if (isect_point_tri_v2(point,
sample_data->frameSpaceCorners[0],
sample_data->frameSpaceCorners[1],
sample_data->frameSpaceCorners[2]) ||
isect_point_tri_v2(point,
sample_data->frameSpaceCorners[0],
sample_data->frameSpaceCorners[2],
sample_data->frameSpaceCorners[3])) {
inside_counter++;
}
}
}
output[0] = (float)inside_counter / (this->m_osa * this->m_motion_blur_samples);
}
}
void PlaneTrackMaskOperation::executePixelSampled(float output[4], float x, float y, PixelSampler sampler)
{
float point[2];
int inside_counter = 0;
for (int sample = 0; sample < this->m_osa; sample++) {
point[0] = x + this->m_jitter[sample][0];
point[1] = y + this->m_jitter[sample][1];
if (isect_point_tri_v2(point, this->m_frameSpaceCorners[0], this->m_frameSpaceCorners[1], this->m_frameSpaceCorners[2]) ||
isect_point_tri_v2(point, this->m_frameSpaceCorners[0], this->m_frameSpaceCorners[2], this->m_frameSpaceCorners[3]))
{
inside_counter++;
}
}
output[0] = (float) inside_counter / this->m_osa;
}
static PyObject *M_Geometry_intersect_point_tri_2d(PyObject *UNUSED(self), PyObject* args)
{
VectorObject *pt_vec, *tri_p1, *tri_p2, *tri_p3;
if(!PyArg_ParseTuple(args, "O!O!O!O!:intersect_point_tri_2d",
&vector_Type, &pt_vec,
&vector_Type, &tri_p1,
&vector_Type, &tri_p2,
&vector_Type, &tri_p3)
) {
return NULL;
}
if(BaseMath_ReadCallback(pt_vec) == -1 || BaseMath_ReadCallback(tri_p1) == -1 || BaseMath_ReadCallback(tri_p2) == -1 || BaseMath_ReadCallback(tri_p3) == -1)
return NULL;
return PyLong_FromLong(isect_point_tri_v2(pt_vec->vec, tri_p1->vec, tri_p2->vec, tri_p3->vec));
}
/* this function is not exact, sometimes it returns false positives,
* the main point of it is to clear out _almost_ all bucket/face non-intersections,
* returning TRUE in corner cases is ok but missing an intersection is NOT.
*
* method used
* - check if the center of the buckets bounding box is intersecting the face
* - if not get the max radius to a corner of the bucket and see how close we
* are to any of the triangle edges.
*/
static bool layer_bucket_isect_test(
MaskRasterLayer *layer, unsigned int face_index,
const unsigned int bucket_x, const unsigned int bucket_y,
const float bucket_size_x, const float bucket_size_y,
const float bucket_max_rad_squared)
{
unsigned int *face = layer->face_array[face_index];
float (*cos)[3] = layer->face_coords;
const float xmin = layer->bounds.xmin + (bucket_size_x * (float)bucket_x);
const float ymin = layer->bounds.ymin + (bucket_size_y * (float)bucket_y);
const float xmax = xmin + bucket_size_x;
const float ymax = ymin + bucket_size_y;
const float cent[2] = {(xmin + xmax) * 0.5f,
(ymin + ymax) * 0.5f};
if (face[3] == TRI_VERT) {
const float *v1 = cos[face[0]];
const float *v2 = cos[face[1]];
const float *v3 = cos[face[2]];
if (isect_point_tri_v2(cent, v1, v2, v3)) {
return TRUE;
}
else {
if ((dist_squared_to_line_segment_v2(cent, v1, v2) < bucket_max_rad_squared) ||
(dist_squared_to_line_segment_v2(cent, v2, v3) < bucket_max_rad_squared) ||
(dist_squared_to_line_segment_v2(cent, v3, v1) < bucket_max_rad_squared))
{
return TRUE;
}
else {
// printf("skip tri\n");
return FALSE;
}
}
}
else {
const float *v1 = cos[face[0]];
const float *v2 = cos[face[1]];
const float *v3 = cos[face[2]];
const float *v4 = cos[face[3]];
if (isect_point_tri_v2(cent, v1, v2, v3)) {
return TRUE;
}
else if (isect_point_tri_v2(cent, v1, v3, v4)) {
return TRUE;
}
else {
if ((dist_squared_to_line_segment_v2(cent, v1, v2) < bucket_max_rad_squared) ||
(dist_squared_to_line_segment_v2(cent, v2, v3) < bucket_max_rad_squared) ||
(dist_squared_to_line_segment_v2(cent, v3, v4) < bucket_max_rad_squared) ||
(dist_squared_to_line_segment_v2(cent, v4, v1) < bucket_max_rad_squared))
{
return TRUE;
}
else {
// printf("skip quad\n");
return FALSE;
}
}
}
}
static float maskrasterize_layer_isect(unsigned int *face, float (*cos)[3], const float dist_orig, const float xy[2])
{
/* we always cast from same place only need xy */
if (face[3] == TRI_VERT) {
/* --- tri --- */
#if 0
/* not essential but avoids unneeded extra lookups */
if ((cos[0][2] < dist_orig) ||
(cos[1][2] < dist_orig) ||
(cos[2][2] < dist_orig))
{
if (isect_point_tri_v2_cw(xy, cos[face[0]], cos[face[1]], cos[face[2]])) {
/* we know all tris are close for now */
return maskrasterize_layer_z_depth_tri(xy, cos[face[0]], cos[face[1]], cos[face[2]]);
}
}
#else
/* we know all tris are close for now */
if (1) {
if (isect_point_tri_v2_cw(xy, cos[face[0]], cos[face[1]], cos[face[2]])) {
return 0.0f;
}
}
#endif
}
else {
/* --- quad --- */
/* not essential but avoids unneeded extra lookups */
if ((cos[0][2] < dist_orig) ||
(cos[1][2] < dist_orig) ||
(cos[2][2] < dist_orig) ||
(cos[3][2] < dist_orig))
{
/* needs work */
#if 1
/* quad check fails for bow-tie, so keep using 2 tri checks */
//if (isect_point_quad_v2(xy, cos[face[0]], cos[face[1]], cos[face[2]], cos[face[3]]))
if (isect_point_tri_v2(xy, cos[face[0]], cos[face[1]], cos[face[2]]) ||
isect_point_tri_v2(xy, cos[face[0]], cos[face[2]], cos[face[3]]))
{
return maskrasterize_layer_z_depth_quad(xy, cos[face[0]], cos[face[1]], cos[face[2]], cos[face[3]]);
}
#elif 1
/* don't use isect_point_tri_v2_cw because we could have bow-tie quads */
if (isect_point_tri_v2(xy, cos[face[0]], cos[face[1]], cos[face[2]])) {
return maskrasterize_layer_z_depth_tri(xy, cos[face[0]], cos[face[1]], cos[face[2]]);
}
else if (isect_point_tri_v2(xy, cos[face[0]], cos[face[2]], cos[face[3]])) {
return maskrasterize_layer_z_depth_tri(xy, cos[face[0]], cos[face[2]], cos[face[3]]);
}
#else
/* cheat - we know first 2 verts are z0.0f and second 2 are z 1.0f */
/* ... worth looking into */
#endif
}
}
return 1.0f;
}
