示例#1
0
TEX_NAMESPACE_BEGIN

std::size_t remove_redundant_faces(mve::VertexInfoList::ConstPtr vertex_infos, mve::TriangleMesh::Ptr mesh) {
    mve::TriangleMesh::FaceList & faces = mesh->get_faces();
    mve::TriangleMesh::FaceList new_faces;
    new_faces.reserve(faces.size());

    std::size_t num_redundant = 0;
    for (std::size_t i = 0; i < faces.size(); i += 3) {
        std::size_t face_id = i / 3;
        bool redundant = false;
        for (std::size_t j = 0; !redundant && j < 3; ++j) {
            mve::MeshVertexInfo::FaceRefList const & adj_faces = vertex_infos->at(faces[i + j]).faces;
            for (std::size_t k = 0; !redundant && k < adj_faces.size(); ++k) {
                std::size_t adj_face_id = adj_faces[k];

                /* Remove only the redundant face with smaller id. */
                if (face_id < adj_face_id) {
                    bool identical = true;
                    /* Faces are considered identical if they consist of the same vertices. */
                    for(std::size_t l = 0; l < 3; ++l) {
                        std::size_t vertex = faces[adj_face_id * 3 + l];
                        if (std::find(&faces[i], &faces[i + 3], vertex) == &faces[i + 3]) {
                            identical = false;
                            break;
                        }
                    }

                    redundant = identical;
                }
            }
        }

        if (redundant) {
            ++num_redundant;
        } else {
            new_faces.insert(new_faces.end(), &faces[i], &faces[i + 3]);
        }
    }

    faces.swap(new_faces);

    return num_redundant;
}
void
generate_texture_patches(UniGraph const & graph, std::vector<TextureView> const & texture_views,
    mve::TriangleMesh::ConstPtr mesh, mve::VertexInfoList::ConstPtr vertex_infos,
    std::vector<std::vector<VertexProjectionInfo> > * vertex_projection_infos,
    std::vector<TexturePatch> * texture_patches) {

    util::WallTimer timer;

    mve::TriangleMesh::FaceList const & mesh_faces = mesh->get_faces();
    mve::TriangleMesh::VertexList const & vertices = mesh->get_vertices();
    vertex_projection_infos->resize(vertices.size());

    std::size_t num_patches = 0;

    std::cout << "\tRunning... " << std::flush;
    #pragma omp parallel for schedule(dynamic)
    for (std::size_t i = 0; i < texture_views.size(); ++i) {

        std::vector<std::vector<std::size_t> > subgraphs;
        int const label = i + 1;
        graph.get_subgraphs(label, &subgraphs);

        std::list<TexturePatchCandidate> candidates;
        for (std::size_t j = 0; j < subgraphs.size(); ++j) {
            candidates.push_back(generate_candidate(label, texture_views[i], subgraphs[j], mesh));
        }

        /* Merge candidates which contain the same image content. */
        std::list<TexturePatchCandidate>::iterator it, sit;
        for (it = candidates.begin(); it != candidates.end(); ++it) {
            for (sit = candidates.begin(); sit != candidates.end();) {
                Rect<int> bounding_box = sit->bounding_box;
                if (it != sit && bounding_box.is_inside(&it->bounding_box)) {
                    TexturePatch::Faces & faces = it->texture_patch.get_faces();
                    TexturePatch::Faces & ofaces = sit->texture_patch.get_faces();
                    faces.insert(faces.end(), ofaces.begin(), ofaces.end());

                    TexturePatch::Texcoords & texcoords = it->texture_patch.get_texcoords();
                    TexturePatch::Texcoords & otexcoords = sit->texture_patch.get_texcoords();
                    math::Vec2f offset;
                    offset[0] = sit->bounding_box.min_x - it->bounding_box.min_x;
                    offset[1] = sit->bounding_box.min_y - it->bounding_box.min_y;
                    for (std::size_t i = 0; i < otexcoords.size(); ++i) {
                        texcoords.push_back(otexcoords[i] + offset);
                    }

                    sit = candidates.erase(sit);
                } else {
                    ++sit;
                }
            }
        }

        it = candidates.begin();
        for (; it != candidates.end(); ++it) {
            std::size_t texture_patch_id;

            #pragma omp critical
            {
                texture_patches->push_back(it->texture_patch);
                texture_patch_id = num_patches++;
            }

            std::vector<std::size_t> const & faces = it->texture_patch.get_faces();
            std::vector<math::Vec2f> const & texcoords = it->texture_patch.get_texcoords();
            for (std::size_t i = 0; i < faces.size(); ++i) {
                std::size_t const face_id = faces[i];
                std::size_t const face_pos = face_id * 3;
                for (std::size_t j = 0; j < 3; ++j) {
                    std::size_t const vertex_id = mesh_faces[face_pos  + j];
                    math::Vec2f const projection = texcoords[i * 3 + j];

                    VertexProjectionInfo info = {texture_patch_id, projection, {face_id}};

                    #pragma omp critical
                    vertex_projection_infos->at(vertex_id).push_back(info);
                }
            }
        }
    }

    merge_vertex_projection_infos(vertex_projection_infos);

    std::size_t num_holes = 0;
    std::size_t num_hole_faces = 0;

    //if (!settings.skip_hole_filling) {
    {
        std::vector<std::vector<std::size_t> > subgraphs;
        graph.get_subgraphs(0, &subgraphs);

        #pragma omp parallel for schedule(dynamic)
        for (std::size_t i = 0; i < subgraphs.size(); ++i) {
            std::vector<std::size_t> const & subgraph = subgraphs[i];

            std::map<std::size_t, std::set<std::size_t> > tmp;
            for (std::size_t const face_id : subgraph) {
                std::size_t const v0 = mesh_faces[face_id * 3];
                std::size_t const v1 = mesh_faces[face_id * 3 + 1];
                std::size_t const v2 = mesh_faces[face_id * 3 + 2];
                tmp[v0].insert(face_id);
                tmp[v1].insert(face_id);
                tmp[v2].insert(face_id);
            }

            std::size_t const num_vertices = tmp.size();
            /* Only fill small holes. */
            if (num_vertices > 100) {
                //std::cerr << "Hole to large" << std::endl;
                continue;
            }


            /* Calculate 2D parameterization using the technique from libremesh/patch2d,
             * which was published as sourcecode accompanying the following paper:
             *
             * Isotropic Surface Remeshing
             * Simon Fuhrmann, Jens Ackermann, Thomas Kalbe, Michael Goesele
             */

            std::size_t seed = -1;
            std::vector<bool> is_border(num_vertices, false);
            std::vector<std::vector<std::size_t> > adj_verts_via_border(num_vertices);
            /* Index structures to map from local <-> global vertex id. */
            std::map<std::size_t, std::size_t> g2l;
            std::vector<std::size_t> l2g(num_vertices);
            /* Index structure to determine column in matrix/vector. */
            std::vector<std::size_t> idx(num_vertices);

            std::size_t num_border_vertices = 0;

            bool disk_topology = true;
            std::map<std::size_t, std::set<std::size_t> >::iterator it = tmp.begin();
            for (std::size_t j = 0; j < num_vertices; ++j, ++it) {
                std::size_t vertex_id = it->first;
                g2l[vertex_id] = j;
                l2g[j] = vertex_id;

                /* Check topology in original mesh. */
                if (vertex_infos->at(vertex_id).vclass != mve::VERTEX_CLASS_SIMPLE) {
                    //std::cerr << "Complex/Border vertex in original mesh" << std::endl;
                    disk_topology = false;
                    break;
                }

                /* Check new topology and determine if vertex is now at the border. */
                std::vector<std::size_t> const & adj_faces = vertex_infos->at(vertex_id).faces;
                std::set<std::size_t> const & adj_hole_faces = it->second;
                std::vector<std::pair<std::size_t, std::size_t> > fan;
                for (std::size_t k = 0; k < adj_faces.size(); ++k) {
                    std::size_t adj_face = adj_faces[k];
                    if (graph.get_label(adj_faces[k]) == 0 &&
                        adj_hole_faces.find(adj_face) != adj_hole_faces.end()) {
                        std::size_t curr = adj_faces[k];
                        std::size_t next = adj_faces[(k + 1) % adj_faces.size()];
                        std::pair<std::size_t, std::size_t> pair(curr, next);
                        fan.push_back(pair);
                    }
                }

                std::size_t gaps = 0;
                for (std::size_t k = 0; k < fan.size(); k++) {
                    std::size_t curr = fan[k].first;
                    std::size_t next = fan[(k + 1) % fan.size()].first;
                    if (fan[k].second != next) {
                        ++gaps;

                        for (std::size_t l = 0; l < 3; ++l) {
                            if(mesh_faces[curr * 3 + l] == vertex_id) {
                                std::size_t second = mesh_faces[curr * 3 + (l + 2) % 3];
                                adj_verts_via_border[j].push_back(second);
                            }
                            if(mesh_faces[next * 3 + l] == vertex_id) {
                                std::size_t first = mesh_faces[next * 3 + (l + 1) % 3];
                                adj_verts_via_border[j].push_back(first);
                            }
                        }
                    }
                }

                is_border[j] = gaps == 1;

                /* Check if vertex is now complex. */
                if (gaps > 1) {
                    //std::cerr << "Complex vertex in hole" << std::endl;
                    disk_topology = false;
                    break;
                }

                if (is_border[j]) {
                    idx[j] = num_border_vertices++;
                    seed = vertex_id;
                } else {
                    idx[j] = j - num_border_vertices;
                }
            }
            tmp.clear();

            if (!disk_topology) continue;
            if (num_border_vertices == 0) {
                //std::cerr << "Genus zero topology" << std::endl;
                continue;
            }

            std::vector<std::size_t> border; border.reserve(num_border_vertices);
            std::size_t prev = seed;
            std::size_t curr = seed;
            while (prev == seed || curr != seed) {
                std::size_t next = std::numeric_limits<std::size_t>::max();
                std::vector<std::size_t> const & adj_verts = adj_verts_via_border[g2l[curr]];
                for (std::size_t adj_vert : adj_verts) {
                    assert(is_border[g2l[adj_vert]]);
                    if (adj_vert != prev && adj_vert != curr) {
                        next = adj_vert;
                        break;
                    }
                }
                if (next != std::numeric_limits<std::size_t>::max()) {
                    prev = curr;
                    curr = next;
                    border.push_back(next);
                } else {
                    //std::cerr << "No new border vertex" << std::endl;
                    border.clear();
                    break;
                }

                if (border.size() > num_border_vertices) {
                    //std::cerr << "Loop within border" << std::endl;
                    break;
                }
            }

            if (border.size() != num_border_vertices) {
                continue;
            }

            float total_length = 0.0f;
            float total_projection_length = 0.0f;
            for (std::size_t j = 0; j < border.size(); ++j) {
                std::size_t vi0 = border[j];
                std::size_t vi1 = border[(j + 1) % border.size()];
                std::vector<VertexProjectionInfo> const & vpi0 = vertex_projection_infos->at(vi0);
                std::vector<VertexProjectionInfo> const & vpi1 = vertex_projection_infos->at(vi0);
                /* According to the previous checks (vertex class within the origial
                 * mesh and boundary) there already has to be at least one projection
                 * of each border vertex. */
                assert(!vpi0.empty() && !vpi1.empty());
                math::Vec2f vp0(0.0f), vp1(0.0f);
                for (VertexProjectionInfo const & info0 : vpi0) {
                    for (VertexProjectionInfo const & info1 : vpi1) {
                        if (info0.texture_patch_id == info1.texture_patch_id) {
                            vp0 = info0.projection;
                            vp1 = info1.projection;
                            break;
                        }
                    }
                }
                total_projection_length += (vp0 - vp1).norm();
                math::Vec3f const & v0 = vertices[vi0];
                math::Vec3f const & v1 = vertices[vi1];
                total_length += (v0 - v1).norm();
            }
            float radius = total_projection_length / (2.0f * MATH_PI);

            float length = 0.0f;
            std::vector<math::Vec2f> projections(num_vertices);
            for (std::size_t j = 0; j < border.size(); ++j) {
                float angle = 2.0f * MATH_PI * (length / total_length);
                projections[g2l[border[j]]] = math::Vec2f(std::cos(angle), std::sin(angle));
                math::Vec3f const & v0 = vertices[border[j]];
                math::Vec3f const & v1 = vertices[border[(j + 1) % border.size()]];
                length += (v0 - v1).norm();
            }

            typedef Eigen::Triplet<float, int> Triplet;
            std::vector<Triplet> coeff;
            std::size_t matrix_size = num_vertices - border.size();

            Eigen::VectorXf xx(matrix_size), xy(matrix_size);

            if (matrix_size != 0) {
                Eigen::VectorXf bx(matrix_size);
                Eigen::VectorXf by(matrix_size);
                for (std::size_t j = 0; j < num_vertices; ++j) {
                    if (is_border[j]) continue;

                    std::size_t const vertex_id = l2g[j];

                    /* Calculate "Mean Value Coordinates" as proposed by Michael S. Floater */
                    std::map<std::size_t, float> weights;
                    std::vector<std::size_t> const & adj_faces = vertex_infos->at(vertex_id).faces;
                    for (std::size_t adj_face : adj_faces) {
                        std::size_t v0 = mesh_faces[adj_face * 3];
                        std::size_t v1 = mesh_faces[adj_face * 3 + 1];
                        std::size_t v2 = mesh_faces[adj_face * 3 + 2];
                        if (v1 == vertex_id) std::swap(v1, v0);
                        if (v2 == vertex_id) std::swap(v2, v0);

                        math::Vec3f v01 = vertices[v1] - vertices[v0];
                        float v01n = v01.norm();
                        math::Vec3f v02 = vertices[v2] - vertices[v0];
                        float v02n = v02.norm();
                        float alpha = std::acos(v01.dot(v02) / (v01n * v02n));
                        weights[g2l[v1]] += std::tan(alpha / 2.0f) / v01n;
                        weights[g2l[v2]] += std::tan(alpha / 2.0f) / v02n;
                    }

                    std::map<std::size_t, float>::iterator it;
                    float sum = 0.0f;
                    for (it = weights.begin(); it != weights.end(); ++it)
                        sum += it->second;
                    for (it = weights.begin(); it != weights.end(); ++it)
                        it->second /= sum;

                    bx[idx[j]] = 0.0f;
                    by[idx[j]] = 0.0f;
                    for (it = weights.begin(); it != weights.end(); ++it) {
                        if (is_border[it->first]) {
                            std::size_t border_vertex_id = border[idx[it->first]];
                            bx[idx[j]] += projections[g2l[border_vertex_id]][0] * it->second;
                            by[idx[j]] += projections[g2l[border_vertex_id]][1] * it->second;
                        } else {
                            coeff.push_back(Triplet(idx[j], idx[it->first], -it->second));
                        }
                    }
                }
                for (std::size_t j = 0; j < matrix_size; ++j) {
                    coeff.push_back(Triplet(j, j, 1.0f));
                }

                typedef Eigen::SparseMatrix<float> SpMat;
                SpMat A(matrix_size, matrix_size);
                A.setFromTriplets(coeff.begin(), coeff.end());

                Eigen::SparseLU<SpMat> solver;
                solver.analyzePattern(A);
                solver.factorize(A);
                xx = solver.solve(bx);
                xy = solver.solve(by);
            }

            int image_size = std::floor(radius * 1.1f) * 2 + 4;
            int scale = image_size / 2 - texture_patch_border;
            for (std::size_t j = 0, k = 0; j < num_vertices; ++j) {
                if (!is_border[j]) {
                    projections[j] = math::Vec2f(xx[k], xy[k]) * scale + image_size / 2;
                    ++k;
                } else {
                    projections[j] = projections[j] * scale + image_size / 2;
                }
            }

            mve::ByteImage::Ptr image = mve::ByteImage::create(image_size, image_size, 3);
            //DEBUG image->fill_color(*math::Vec4uc(0, 255, 0, 255));
            std::vector<math::Vec2f> texcoords; texcoords.reserve(subgraph.size());
            for (std::size_t const face_id : subgraph) {
                for (std::size_t j = 0; j < 3; ++j) {
                    std::size_t const vertex_id = mesh_faces[face_id * 3 + j];
                    math::Vec2f const & projection = projections[g2l[vertex_id]];
                    texcoords.push_back(projection);
                }
            }
            TexturePatch texture_patch(0, subgraph, texcoords, image);
            std::size_t texture_patch_id;
            #pragma omp critical
            {
                texture_patches->push_back(texture_patch);
                texture_patch_id = num_patches++;

                num_hole_faces += subgraph.size();
                ++num_holes;
            }

            for (std::size_t j = 0; j < num_vertices; ++j) {
                std::size_t const vertex_id = l2g[j];
                std::vector<std::size_t> const & adj_faces = vertex_infos->at(vertex_id).faces;
                std::vector<std::size_t> faces; faces.reserve(adj_faces.size());
                for (std::size_t adj_face : adj_faces) {
                    if (graph.get_label(adj_face) == 0) {
                        faces.push_back(adj_face);
                    }
                }
                VertexProjectionInfo info = {texture_patch_id, projections[j], faces};
                #pragma omp critical
                vertex_projection_infos->at(vertex_id).push_back(info);
            }
        }
    }

    merge_vertex_projection_infos(vertex_projection_infos);

    std::cout << "done. (Took " << timer.get_elapsed_sec() << "s)" << std::endl;
    std::cout << "\t" << num_patches << " texture patches." << std::endl;
    std::cout << "\t" << num_holes << " holes (" << num_hole_faces << " faces)." << std::endl;
}