void
from_nvm_scene(std::string const & nvm_file, std::vector<TextureView> * texture_views) {
std::vector<mve::NVMCameraInfo> nvm_cams;
mve::Bundle::Ptr bundle = mve::load_nvm_bundle(nvm_file, &nvm_cams);
mve::Bundle::Cameras& cameras = bundle->get_cameras();
ProgressCounter view_counter("\tLoading", cameras.size());
#pragma omp parallel for
for (std::size_t i = 0; i < cameras.size(); ++i) {
view_counter.progress<SIMPLE>();
mve::CameraInfo& mve_cam = cameras[i];
mve::NVMCameraInfo const& nvm_cam = nvm_cams[i];
mve::ByteImage::Ptr image = mve::image::load_file(nvm_cam.filename);
int const maxdim = std::max(image->width(), image->height());
mve_cam.flen = mve_cam.flen / static_cast<float>(maxdim);
image = mve::image::image_undistort_vsfm<uint8_t>
(image, mve_cam.flen, nvm_cam.radial_distortion);
texture_views->push_back(TextureView(i, mve_cam, image));
view_counter.inc();
}
}
TEX_NAMESPACE_BEGIN
void
from_mve_scene(std::string const & scene_dir, std::string const & embedding_name,
std::vector<TextureView> * texture_views) {
mve::Scene::Ptr scene;
try {
scene = mve::Scene::create(scene_dir);
} catch (std::exception& e) {
std::cerr << "Could not open scene: " << e.what() << std::endl;
std::exit(EXIT_FAILURE);
}
std::size_t num_views = scene->get_views().size();
texture_views->reserve(num_views);
ProgressCounter view_counter("\tLoading", num_views);
for (std::size_t i = 0; i < num_views; ++i) {
view_counter.progress<SIMPLE>();
mve::View::Ptr view = scene->get_view_by_id(i);
if (view == NULL) {
view_counter.inc();
continue;
}
if (!view->has_embedding(embedding_name)) {
std::cout << "Warning: View " << view->get_name() << " has no embedding "
<< embedding_name << std::endl;
continue;
}
mve::ByteImage::Ptr image = view->get_byte_image(embedding_name);
if (image == NULL) {
std::cerr << "Embedding " << embedding_name << " of view " <<
view->get_name() << " is not a byte embedding!" << std::endl;
exit(EXIT_FAILURE);
}
if (image->channels() < 3) {
std::cerr << "Embedding " << embedding_name << " of view " <<
view->get_name() << " is not a color image!" << std::endl;
exit(EXIT_FAILURE);
}
texture_views->push_back(TextureView(view->get_id(), view->get_camera(), image));
view_counter.inc();
}
}
void
calculate_data_costs(mve::TriangleMesh::ConstPtr mesh, std::vector<TextureView> * texture_views,
Settings const & settings, ST * data_costs) {
mve::TriangleMesh::FaceList const & faces = mesh->get_faces();
mve::TriangleMesh::VertexList const & vertices = mesh->get_vertices();
mve::TriangleMesh::NormalList const & face_normals = mesh->get_face_normals();
std::size_t const num_faces = faces.size() / 3;
std::size_t const num_views = texture_views->size();
CollisionModel3D* model = newCollisionModel3D(true);
if (settings.geometric_visibility_test) {
/* Build up acceleration structure for the visibility test. */
ProgressCounter face_counter("\tBuilding collision model", num_faces);
model->setTriangleNumber(num_faces);
for (std::size_t i = 0; i < faces.size(); i += 3) {
face_counter.progress<SIMPLE>();
math::Vec3f v1 = vertices[faces[i]];
math::Vec3f v2 = vertices[faces[i + 1]];
math::Vec3f v3 = vertices[faces[i + 2]];
model->addTriangle(*v1, *v2, *v3);
face_counter.inc();
}
model->finalize();
}
std::vector<std::vector<ProjectedFaceInfo> > projected_face_infos(num_faces);
ProgressCounter view_counter("\tCalculating face qualities", num_views);
#pragma omp parallel
{
std::vector<std::pair<std::size_t, ProjectedFaceInfo> > projected_face_view_infos;
#pragma omp for schedule(dynamic)
for (std::uint16_t j = 0; j < texture_views->size(); ++j) {
view_counter.progress<SIMPLE>();
TextureView * texture_view = &texture_views->at(j);
texture_view->load_image();
texture_view->generate_validity_mask();
if (settings.data_term == GMI) {
texture_view->generate_gradient_magnitude();
texture_view->erode_validity_mask();
}
math::Vec3f const & view_pos = texture_view->get_pos();
math::Vec3f const & viewing_direction = texture_view->get_viewing_direction();
for (std::size_t i = 0; i < faces.size(); i += 3) {
std::size_t face_id = i / 3;
math::Vec3f const & v1 = vertices[faces[i]];
math::Vec3f const & v2 = vertices[faces[i + 1]];
math::Vec3f const & v3 = vertices[faces[i + 2]];
math::Vec3f const & face_normal = face_normals[face_id];
math::Vec3f const face_center = (v1 + v2 + v3) / 3.0f;
/* Check visibility and compute quality */
math::Vec3f view_to_face_vec = (face_center - view_pos).normalized();
math::Vec3f face_to_view_vec = (view_pos - face_center).normalized();
/* Backface culling */
float viewing_angle = face_to_view_vec.dot(face_normal);
if (viewing_angle < 0.0f || viewing_direction.dot(view_to_face_vec) < 0.0f)
continue;
if (std::acos(viewing_angle) > MATH_DEG2RAD(75.0f))
continue;
/* Projects into the valid part of the TextureView? */
if (!texture_view->inside(v1, v2, v3))
continue;
if (settings.geometric_visibility_test) {
/* Viewing rays do not collide? */
bool visible = true;
math::Vec3f const * samples[] = {&v1, &v2, &v3};
// TODO: random monte carlo samples...
for (std::size_t k = 0; k < sizeof(samples) / sizeof(samples[0]); ++k) {
math::Vec3f vertex = *samples[k];
math::Vec3f dir = view_pos - vertex;
float const dir_length = dir.norm();
dir.normalize();
if (model->rayCollision(*vertex, *dir, false, dir_length * 0.0001f, dir_length)) {
visible = false;
break;
}
}
if (!visible) continue;
}
ProjectedFaceInfo info = {j, 0.0f, math::Vec3f(0.0f, 0.0f, 0.0f)};
/* Calculate quality. */
texture_view->get_face_info(v1, v2, v3, &info, settings);
if (info.quality == 0.0) continue;
/* Change color space. */
mve::image::color_rgb_to_ycbcr(*(info.mean_color));
std::pair<std::size_t, ProjectedFaceInfo> pair(face_id, info);
projected_face_view_infos.push_back(pair);
}
texture_view->release_image();
texture_view->release_validity_mask();
if (settings.data_term == GMI) {
texture_view->release_gradient_magnitude();
}
view_counter.inc();
}
//std::sort(projected_face_view_infos.begin(), projected_face_view_infos.end());
#pragma omp critical
{
for (std::size_t i = projected_face_view_infos.size(); 0 < i; --i) {
std::size_t face_id = projected_face_view_infos[i - 1].first;
ProjectedFaceInfo const & info = projected_face_view_infos[i - 1].second;
projected_face_infos[face_id].push_back(info);
}
projected_face_view_infos.clear();
}
}
delete model;
model = NULL;
ProgressCounter face_counter("\tPostprocessing face infos", num_faces);
#pragma omp parallel for schedule(dynamic)
for (std::size_t i = 0; i < projected_face_infos.size(); ++i) {
face_counter.progress<SIMPLE>();
std::vector<ProjectedFaceInfo> & infos = projected_face_infos[i];
if (settings.outlier_removal != NONE) {
photometric_outlier_detection(&infos, settings);
infos.erase(std::remove_if(infos.begin(), infos.end(),
[](ProjectedFaceInfo const & info) -> bool {return info.quality == 0.0f;}),
infos.end());
}
std::sort(infos.begin(), infos.end());
face_counter.inc();
}
/* Determine the function for the normlization. */
float max_quality = 0.0f;
for (std::size_t i = 0; i < projected_face_infos.size(); ++i)
for (std::size_t j = 0; j < projected_face_infos[i].size(); ++j)
max_quality = std::max(max_quality, projected_face_infos[i][j].quality);
Histogram hist_qualities(0.0f, max_quality, 10000);
for (std::size_t i = 0; i < projected_face_infos.size(); ++i)
for (std::size_t j = 0; j < projected_face_infos[i].size(); ++j)
hist_qualities.add_value(projected_face_infos[i][j].quality);
float percentile = hist_qualities.get_approx_percentile(0.995f);
/* Calculate the costs. */
assert(num_faces < std::numeric_limits<std::uint32_t>::max());
assert(num_views < std::numeric_limits<std::uint16_t>::max());
assert(MRF_MAX_ENERGYTERM < std::numeric_limits<float>::max());
for (std::uint32_t i = 0; i < static_cast<std::uint32_t>(projected_face_infos.size()); ++i) {
for (std::size_t j = 0; j < projected_face_infos[i].size(); ++j) {
ProjectedFaceInfo const & info = projected_face_infos[i][j];
/* Clamp to percentile and normalize. */
float normalized_quality = std::min(1.0f, info.quality / percentile);
float data_cost = (1.0f - normalized_quality) * MRF_MAX_ENERGYTERM;
data_costs->set_value(i, info.view_id, data_cost);
}
/* Ensure that all memory is freeed. */
projected_face_infos[i].clear();
projected_face_infos[i].shrink_to_fit();
}
std::cout << "\tMaximum quality of a face within an image: " << max_quality << std::endl;
std::cout << "\tClamping qualities to " << percentile << " within normalization." << std::endl;
}
void
calculate_face_projection_infos(mve::TriangleMesh::ConstPtr mesh,
std::vector<TextureView> * texture_views, Settings const & settings,
FaceProjectionInfos * face_projection_infos) {
std::vector<unsigned int> const & faces = mesh->get_faces();
std::vector<math::Vec3f> const & vertices = mesh->get_vertices();
mve::TriangleMesh::NormalList const & face_normals = mesh->get_face_normals();
std::size_t const num_views = texture_views->size();
util::WallTimer timer;
std::cout << "\tBuilding BVH from " << faces.size() / 3 << " faces... " << std::flush;
BVHTree bvh_tree(faces, vertices);
std::cout << "done. (Took: " << timer.get_elapsed() << " ms)" << std::endl;
ProgressCounter view_counter("\tCalculating face qualities", num_views);
#pragma omp parallel
{
std::vector<std::pair<std::size_t, FaceProjectionInfo> > projected_face_view_infos;
#pragma omp for schedule(dynamic)
for (std::uint16_t j = 0; j < texture_views->size(); ++j) {
view_counter.progress<SIMPLE>();
TextureView * texture_view = &texture_views->at(j);
texture_view->load_image();
texture_view->generate_validity_mask();
if (settings.data_term == DATA_TERM_GMI) {
texture_view->generate_gradient_magnitude();
texture_view->erode_validity_mask();
}
math::Vec3f const & view_pos = texture_view->get_pos();
math::Vec3f const & viewing_direction = texture_view->get_viewing_direction();
for (std::size_t i = 0; i < faces.size(); i += 3) {
std::size_t face_id = i / 3;
math::Vec3f const & v1 = vertices[faces[i]];
math::Vec3f const & v2 = vertices[faces[i + 1]];
math::Vec3f const & v3 = vertices[faces[i + 2]];
math::Vec3f const & face_normal = face_normals[face_id];
math::Vec3f const face_center = (v1 + v2 + v3) / 3.0f;
/* Check visibility and compute quality */
math::Vec3f view_to_face_vec = (face_center - view_pos).normalized();
math::Vec3f face_to_view_vec = (view_pos - face_center).normalized();
/* Backface and basic frustum culling */
float viewing_angle = face_to_view_vec.dot(face_normal);
if (viewing_angle < 0.0f || viewing_direction.dot(view_to_face_vec) < 0.0f)
continue;
if (std::acos(viewing_angle) > MATH_DEG2RAD(75.0f))
continue;
/* Projects into the valid part of the TextureView? */
if (!texture_view->inside(v1, v2, v3))
continue;
if (settings.geometric_visibility_test) {
/* Viewing rays do not collide? */
bool visible = true;
math::Vec3f const * samples[] = {&v1, &v2, &v3};
// TODO: random monte carlo samples...
for (std::size_t k = 0; k < sizeof(samples) / sizeof(samples[0]); ++k) {
BVHTree::Ray ray;
ray.origin = *samples[k];
ray.dir = view_pos - ray.origin;
ray.tmax = ray.dir.norm();
ray.tmin = ray.tmax * 0.0001f;
ray.dir.normalize();
BVHTree::Hit hit;
if (bvh_tree.intersect(ray, &hit)) {
visible = false;
break;
}
}
if (!visible) continue;
}
FaceProjectionInfo info = {j, 0.0f, math::Vec3f(0.0f, 0.0f, 0.0f)};
/* Calculate quality. */
texture_view->get_face_info(v1, v2, v3, &info, settings);
if (info.quality == 0.0) continue;
/* Change color space. */
mve::image::color_rgb_to_ycbcr(*(info.mean_color));
std::pair<std::size_t, FaceProjectionInfo> pair(face_id, info);
projected_face_view_infos.push_back(pair);
}
texture_view->release_image();
texture_view->release_validity_mask();
if (settings.data_term == DATA_TERM_GMI) {
texture_view->release_gradient_magnitude();
}
view_counter.inc();
}
//std::sort(projected_face_view_infos.begin(), projected_face_view_infos.end());
#pragma omp critical
{
for (std::size_t i = projected_face_view_infos.size(); 0 < i; --i) {
std::size_t face_id = projected_face_view_infos[i - 1].first;
FaceProjectionInfo const & info = projected_face_view_infos[i - 1].second;
face_projection_infos->at(face_id).push_back(info);
}
projected_face_view_infos.clear();
}
}
}
void
from_images_and_camera_files(std::string const & path, std::vector<TextureView> * texture_views) {
util::fs::Directory dir(path);
std::sort(dir.begin(), dir.end());
std::vector<std::string> files;
for (std::size_t i = 0; i < dir.size(); ++i) {
util::fs::File const & cam_file = dir[i];
if (cam_file.is_dir) continue;
std::string cam_file_ext = util::string::uppercase(util::string::right(cam_file.name, 4));
if (cam_file_ext != ".CAM") continue;
std::string prefix = util::string::left(cam_file.name, cam_file.name.size() - 4);
if (prefix.empty()) continue;
/* Find corresponding image file. */
int step = 1;
for (std::size_t j = i + 1; j < dir.size(); j += step) {
util::fs::File const & img_file = dir[j];
/* Since the files are sorted we can break - no more files with the same prefix exist. */
if (util::string::left(img_file.name, prefix.size()) != prefix) {
if (step == 1) {
j = i;
step = -1;
continue;
} else {
break;
}
}
/* Image file (based on extension)? */
std::string img_file_ext = util::string::uppercase(util::string::right(img_file.name, 4));
if (img_file_ext != ".PNG" && img_file_ext != ".JPG" &&
img_file_ext != "TIFF" && img_file_ext != "JPEG") continue;
files.push_back(cam_file.get_absolute_name());
files.push_back(img_file.get_absolute_name());
break;
}
}
ProgressCounter view_counter("\tLoading", files.size() / 2);
#pragma omp parallel for
for (std::size_t i = 0; i < files.size(); i += 2) {
view_counter.progress<SIMPLE>();
std::string cam_file = files[i];
std::string img_file = files[i + 1];
mve::ByteImage::Ptr image = mve::image::load_file(img_file);
/* Read CAM file. */
std::ifstream infile(cam_file.c_str(), std::ios::binary);
if (!infile.good())
throw util::FileException(util::fs::basename(cam_file), std::strerror(errno));
std::string cam_int_str, cam_ext_str;
std::getline(infile, cam_ext_str);
std::getline(infile, cam_int_str);
util::Tokenizer tok_ext, tok_int;
tok_ext.split(cam_ext_str);
tok_int.split(cam_int_str);
#pragma omp critical
if (tok_ext.size() != 12 || tok_int.size() < 1) {
std::cerr << "Invalid CAM file: " << util::fs::basename(cam_file) << std::endl;
std::exit(EXIT_FAILURE);
}
/* Create cam_info and eventually undistort image. */
mve::CameraInfo cam_info;
cam_info.from_ext_string(cam_ext_str);
cam_info.from_int_string(cam_int_str);
mve::ByteImage::Ptr undist;
if (cam_info.dist[0] != 0.0f) {
if (cam_info.dist[1] != 0.0f) {
undist = mve::image::image_undistort_bundler<uint8_t>(image,
cam_info.flen, cam_info.dist[0], cam_info.dist[1]);
} else {
undist = mve::image::image_undistort_vsfm<uint8_t>(image,
cam_info.flen, cam_info.dist[0]);
}
} else {
undist = image;
}
mve::image::save_png_file(undist, std::string("/tmp/") + util::fs::basename(img_file));
#pragma omp critical
texture_views->push_back(TextureView(i / 2, cam_info, undist));
view_counter.inc();
}
}
