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- // This file is part of libigl, a simple c++ geometry processing library.
- //
- // Copyright (C) 2018 Zhongshi Jiang <jiangzs@nyu.edu>
- //
- // This Source Code Form is subject to the terms of the Mozilla Public License
- // v. 2.0. If a copy of the MPL was not distributed with this file, You can
- // obtain one at http://mozilla.org/MPL/2.0/.
- #include "scaf.h"
- #include <Eigen/Dense>
- #include <Eigen/IterativeLinearSolvers>
- #include <Eigen/Sparse>
- #include <Eigen/SparseCholesky>
- #include <Eigen/SparseQR>
- #include <igl/PI.h>
- #include <igl/Timer.h>
- #include <igl/boundary_loop.h>
- #include <igl/cat.h>
- #include <igl/doublearea.h>
- #include <igl/flip_avoiding_line_search.h>
- #include <igl/flipped_triangles.h>
- #include <igl/grad.h>
- #include <igl/harmonic.h>
- #include <igl/local_basis.h>
- #include <igl/map_vertices_to_circle.h>
- #include <igl/polar_svd.h>
- #include <igl/readOBJ.h>
- #include <igl/slice.h>
- #include <igl/slice_into.h>
- #include <igl/slim.h>
- #include <igl/triangle/triangulate.h>
- #include "mapping_energy_with_jacobians.h"
- #include <iostream>
- #include <map>
- #include <algorithm>
- #include <set>
- #include <vector>
- namespace igl
- {
- namespace scaf
- {
- void update_scaffold(igl::SCAFData &s)
- {
- s.mv_num = s.m_V.rows();
- s.mf_num = s.m_T.rows();
- s.v_num = s.w_uv.rows();
- s.sf_num = s.s_T.rows();
- s.sv_num = s.v_num - s.mv_num;
- s.f_num = s.sf_num + s.mf_num;
- s.s_M = Eigen::VectorXd::Constant(s.sf_num, s.scaffold_factor);
- }
- void adjusted_grad(Eigen::MatrixXd &V,
- Eigen::MatrixXi &F,
- double area_threshold,
- Eigen::SparseMatrix<double> &Dx,
- Eigen::SparseMatrix<double> &Dy,
- Eigen::SparseMatrix<double> &Dz)
- {
- Eigen::VectorXd M;
- igl::doublearea(V, F, M);
- std::vector<int> degen;
- for (int i = 0; i < M.size(); i++)
- if (M(i) < area_threshold)
- degen.push_back(i);
- Eigen::SparseMatrix<double> G;
- igl::grad(V, F, G);
- Dx = G.topRows(F.rows());
- Dy = G.block(F.rows(), 0, F.rows(), V.rows());
- Dz = G.bottomRows(F.rows());
- // handcraft uniform gradient for faces area falling below threshold.
- double sin60 = std::sin(M_PI / 3);
- double cos60 = std::cos(M_PI / 3);
- double deno = std::sqrt(sin60 * area_threshold);
- Eigen::MatrixXd standard_grad(3, 3);
- standard_grad << -sin60 / deno, sin60 / deno, 0,
- -cos60 / deno, -cos60 / deno, 1 / deno,
- 0, 0, 0;
- for (auto k : degen)
- for (int j = 0; j < 3; j++)
- {
- Dx.coeffRef(k, F(k, j)) = standard_grad(0, j);
- Dy.coeffRef(k, F(k, j)) = standard_grad(1, j);
- Dz.coeffRef(k, F(k, j)) = standard_grad(2, j);
- }
- }
- void compute_scaffold_gradient_matrix(SCAFData &s,
- Eigen::SparseMatrix<double> &D1,
- Eigen::SparseMatrix<double> &D2)
- {
- using namespace Eigen;
- Eigen::SparseMatrix<double> G;
- MatrixXi F_s = s.s_T;
- int vn = s.v_num;
- MatrixXd V = MatrixXd::Zero(vn, 3);
- V.leftCols(2) = s.w_uv;
- double min_bnd_edge_len = INFINITY;
- int acc_bnd = 0;
- for (int i = 0; i < s.bnd_sizes.size(); i++)
- {
- int current_size = s.bnd_sizes[i];
- for (int e = acc_bnd; e < acc_bnd + current_size - 1; e++)
- {
- min_bnd_edge_len = (std::min)(min_bnd_edge_len,
- (s.w_uv.row(s.internal_bnd(e)) -
- s.w_uv.row(s.internal_bnd(e + 1)))
- .squaredNorm());
- }
- min_bnd_edge_len = (std::min)(min_bnd_edge_len,
- (s.w_uv.row(s.internal_bnd(acc_bnd)) -
- s.w_uv.row(s.internal_bnd(acc_bnd + current_size - 1)))
- .squaredNorm());
- acc_bnd += current_size;
- }
- double area_threshold = min_bnd_edge_len / 4.0;
- Eigen::SparseMatrix<double> Dx, Dy, Dz;
- adjusted_grad(V, F_s, area_threshold, Dx, Dy, Dz);
- MatrixXd F1, F2, F3;
- igl::local_basis(V, F_s, F1, F2, F3);
- D1 = F1.col(0).asDiagonal() * Dx + F1.col(1).asDiagonal() * Dy +
- F1.col(2).asDiagonal() * Dz;
- D2 = F2.col(0).asDiagonal() * Dx + F2.col(1).asDiagonal() * Dy +
- F2.col(2).asDiagonal() * Dz;
- }
- void mesh_improve(igl::SCAFData &s)
- {
- using namespace Eigen;
- MatrixXd m_uv = s.w_uv.topRows(s.mv_num);
- MatrixXd V_bnd;
- V_bnd.resize(s.internal_bnd.size(), 2);
- for (int i = 0; i < s.internal_bnd.size(); i++) // redoing step 1.
- {
- V_bnd.row(i) = m_uv.row(s.internal_bnd(i));
- }
- if (s.rect_frame_V.size() == 0)
- {
- Matrix2d ob; // = rect_corners;
- {
- VectorXd uv_max = m_uv.colwise().maxCoeff();
- VectorXd uv_min = m_uv.colwise().minCoeff();
- VectorXd uv_mid = (uv_max + uv_min) / 2.;
- Eigen::Array2d scaf_range(3, 3);
- ob.row(0) = uv_mid.array() + scaf_range * ((uv_min - uv_mid).array());
- ob.row(1) = uv_mid.array() + scaf_range * ((uv_max - uv_mid).array());
- }
- Vector2d rect_len;
- rect_len << ob(1, 0) - ob(0, 0), ob(1, 1) - ob(0, 1);
- int frame_points = 5;
- s.rect_frame_V.resize(4 * frame_points, 2);
- for (int i = 0; i < frame_points; i++)
- {
- // 0,0;0,1
- s.rect_frame_V.row(i) << ob(0, 0), ob(0, 1) + i * rect_len(1) / frame_points;
- // 0,0;1,1
- s.rect_frame_V.row(i + frame_points)
- << ob(0, 0) + i * rect_len(0) / frame_points,
- ob(1, 1);
- // 1,0;1,1
- s.rect_frame_V.row(i + 2 * frame_points) << ob(1, 0), ob(1, 1) - i * rect_len(1) / frame_points;
- // 1,0;0,1
- s.rect_frame_V.row(i + 3 * frame_points)
- << ob(1, 0) - i * rect_len(0) / frame_points,
- ob(0, 1);
- // 0,0;0,1
- }
- s.frame_ids = Eigen::VectorXi::LinSpaced(s.rect_frame_V.rows(), s.mv_num, s.mv_num + s.rect_frame_V.rows());
- }
- // Concatenate Vert and Edge
- MatrixXd V;
- MatrixXi E;
- igl::cat(1, V_bnd, s.rect_frame_V, V);
- E.resize(V.rows(), 2);
- for (int i = 0; i < E.rows(); i++)
- E.row(i) << i, i + 1;
- int acc_bs = 0;
- for (auto bs : s.bnd_sizes)
- {
- E(acc_bs + bs - 1, 1) = acc_bs;
- acc_bs += bs;
- }
- E(V.rows() - 1, 1) = acc_bs;
- assert(acc_bs == s.internal_bnd.size());
- MatrixXd H = MatrixXd::Zero(s.component_sizes.size(), 2);
- {
- int hole_f = 0;
- int hole_i = 0;
- for (auto cs : s.component_sizes)
- {
- for (int i = 0; i < 3; i++)
- H.row(hole_i) += m_uv.row(s.m_T(hole_f, i)); // redoing step 2
- hole_f += cs;
- hole_i++;
- }
- }
- H /= 3.;
- MatrixXd uv2;
- igl::triangle::triangulate(V, E, H, std::basic_string<char>("qYYQ"), uv2, s.s_T);
- auto bnd_n = s.internal_bnd.size();
- for (auto i = 0; i < s.s_T.rows(); i++)
- for (auto j = 0; j < s.s_T.cols(); j++)
- {
- auto &x = s.s_T(i, j);
- if (x < bnd_n)
- x = s.internal_bnd(x);
- else
- x += m_uv.rows() - bnd_n;
- }
- igl::cat(1, s.m_T, s.s_T, s.w_T);
- s.w_uv.conservativeResize(m_uv.rows() - bnd_n + uv2.rows(), 2);
- s.w_uv.bottomRows(uv2.rows() - bnd_n) = uv2.bottomRows(-bnd_n + uv2.rows());
- update_scaffold(s);
- // after_mesh_improve
- compute_scaffold_gradient_matrix(s, s.Dx_s, s.Dy_s);
- s.Dx_s.makeCompressed();
- s.Dy_s.makeCompressed();
- s.Dz_s.makeCompressed();
- s.Ri_s = MatrixXd::Zero(s.Dx_s.rows(), s.dim * s.dim);
- s.Ji_s.resize(s.Dx_s.rows(), s.dim * s.dim);
- s.W_s.resize(s.Dx_s.rows(), s.dim * s.dim);
- }
- void add_new_patch(igl::SCAFData &s, const Eigen::MatrixXd &V_ref,
- const Eigen::MatrixXi &F_ref,
- const Eigen::RowVectorXd ¢er,
- const Eigen::MatrixXd &uv_init)
- {
- using namespace std;
- using namespace Eigen;
- assert(uv_init.rows() != 0);
- Eigen::VectorXd M;
- igl::doublearea(V_ref, F_ref, M);
- s.mesh_measure += M.sum() / 2;
- Eigen::VectorXi bnd;
- Eigen::MatrixXd bnd_uv;
- std::vector<std::vector<int>> all_bnds;
- igl::boundary_loop(F_ref, all_bnds);
- int num_holes = all_bnds.size() - 1;
- s.component_sizes.push_back(F_ref.rows());
- MatrixXd m_uv = s.w_uv.topRows(s.mv_num);
- igl::cat(1, m_uv, uv_init, s.w_uv);
- s.m_M.conservativeResize(s.mf_num + M.size());
- s.m_M.bottomRows(M.size()) = M / 2;
- for (auto cur_bnd : all_bnds)
- {
- s.internal_bnd.conservativeResize(s.internal_bnd.size() + cur_bnd.size());
- s.internal_bnd.bottomRows(cur_bnd.size()) = Map<ArrayXi>(cur_bnd.data(), cur_bnd.size()) + s.mv_num;
- s.bnd_sizes.push_back(cur_bnd.size());
- }
- s.m_T.conservativeResize(s.mf_num + F_ref.rows(), 3);
- s.m_T.bottomRows(F_ref.rows()) = F_ref.array() + s.mv_num;
- s.mf_num += F_ref.rows();
- s.m_V.conservativeResize(s.mv_num + V_ref.rows(), 3);
- s.m_V.bottomRows(V_ref.rows()) = V_ref;
- s.mv_num += V_ref.rows();
- s.rect_frame_V = MatrixXd();
- mesh_improve(s);
- }
- void compute_jacobians(SCAFData &s, const Eigen::MatrixXd &V_new, bool whole)
- {
- auto comp_J2 = [](const Eigen::MatrixXd &uv,
- const Eigen::SparseMatrix<double> &Dx,
- const Eigen::SparseMatrix<double> &Dy,
- Eigen::MatrixXd &Ji) {
- // Ji=[D1*u,D2*u,D1*v,D2*v];
- Ji.resize(Dx.rows(), 4);
- Ji.col(0) = Dx * uv.col(0);
- Ji.col(1) = Dy * uv.col(0);
- Ji.col(2) = Dx * uv.col(1);
- Ji.col(3) = Dy * uv.col(1);
- };
- Eigen::MatrixXd m_V_new = V_new.topRows(s.mv_num);
- comp_J2(m_V_new, s.Dx_m, s.Dy_m, s.Ji_m);
- if (whole)
- comp_J2(V_new, s.Dx_s, s.Dy_s, s.Ji_s);
- }
- double compute_energy_from_jacobians(const Eigen::MatrixXd &Ji,
- const Eigen::VectorXd &areas,
- igl::MappingEnergyType energy_type)
- {
- double energy = 0;
- if (energy_type == igl::MappingEnergyType::SYMMETRIC_DIRICHLET)
- energy = -4; // comply with paper description
- return energy + igl::mapping_energy_with_jacobians(Ji, areas, energy_type, 0);
- }
- double compute_soft_constraint_energy(const SCAFData &s)
- {
- double e = 0;
- for (auto const &x : s.soft_cons)
- e += s.soft_const_p * (x.second - s.w_uv.row(x.first)).squaredNorm();
- return e;
- }
- double compute_energy(SCAFData &s, Eigen::MatrixXd &w_uv, bool whole)
- {
- if (w_uv.rows() != s.v_num)
- assert(!whole);
- compute_jacobians(s, w_uv, whole);
- double energy = compute_energy_from_jacobians(s.Ji_m, s.m_M, s.slim_energy);
- if (whole)
- energy += compute_energy_from_jacobians(s.Ji_s, s.s_M, s.scaf_energy);
- energy += compute_soft_constraint_energy(s);
- return energy;
- }
- void buildAm(const Eigen::VectorXd &sqrt_M,
- const Eigen::SparseMatrix<double> &Dx,
- const Eigen::SparseMatrix<double> &Dy,
- const Eigen::MatrixXd &W,
- Eigen::SparseMatrix<double> &Am)
- {
- std::vector<Eigen::Triplet<double>> IJV;
- Eigen::SparseMatrix<double> Dz;
- Eigen::SparseMatrix<double> MDx = sqrt_M.asDiagonal() * Dx;
- Eigen::SparseMatrix<double> MDy = sqrt_M.asDiagonal() * Dy;
- igl::slim_buildA(MDx, MDy, Dz, W, IJV);
- Am.setFromTriplets(IJV.begin(), IJV.end());
- Am.makeCompressed();
- }
- void buildRhs(const Eigen::VectorXd &sqrt_M,
- const Eigen::MatrixXd &W,
- const Eigen::MatrixXd &Ri,
- Eigen::VectorXd &f_rhs)
- {
- const int dim = (W.cols() == 4) ? 2 : 3;
- const int f_n = W.rows();
- f_rhs.resize(dim * dim * f_n);
- for (int i = 0; i < f_n; i++)
- {
- auto sqrt_area = sqrt_M(i);
- f_rhs(i + 0 * f_n) = sqrt_area * (W(i, 0) * Ri(i, 0) + W(i, 1) * Ri(i, 1));
- f_rhs(i + 1 * f_n) = sqrt_area * (W(i, 0) * Ri(i, 2) + W(i, 1) * Ri(i, 3));
- f_rhs(i + 2 * f_n) = sqrt_area * (W(i, 2) * Ri(i, 0) + W(i, 3) * Ri(i, 1));
- f_rhs(i + 3 * f_n) = sqrt_area * (W(i, 2) * Ri(i, 2) + W(i, 3) * Ri(i, 3));
- }
- }
- void get_complement(const Eigen::VectorXi &bnd_ids, int v_n, Eigen::ArrayXi &unknown_ids)
- { // get the complement of bnd_ids.
- int assign = 0, i = 0;
- for (int get = 0; i < v_n && get < bnd_ids.size(); i++)
- {
- if (bnd_ids(get) == i)
- get++;
- else
- unknown_ids(assign++) = i;
- }
- while (i < v_n)
- unknown_ids(assign++) = i++;
- assert(assign + bnd_ids.size() == v_n);
- }
- void build_surface_linear_system(const SCAFData &s, Eigen::SparseMatrix<double> &L, Eigen::VectorXd &rhs)
- {
- using namespace Eigen;
- using namespace std;
- const int v_n = s.v_num - (s.frame_ids.size());
- const int dim = s.dim;
- const int f_n = s.mf_num;
- // to get the complete A
- Eigen::VectorXd sqrtM = s.m_M.array().sqrt();
- Eigen::SparseMatrix<double> A(dim * dim * f_n, dim * v_n);
- auto decoy_Dx_m = s.Dx_m;
- decoy_Dx_m.conservativeResize(s.W_m.rows(), v_n);
- auto decoy_Dy_m = s.Dy_m;
- decoy_Dy_m.conservativeResize(s.W_m.rows(), v_n);
- buildAm(sqrtM, decoy_Dx_m, decoy_Dy_m, s.W_m, A);
- const VectorXi &bnd_ids = s.fixed_ids;
- auto bnd_n = bnd_ids.size();
- if (bnd_n == 0)
- {
- Eigen::SparseMatrix<double> At = A.transpose();
- At.makeCompressed();
- Eigen::SparseMatrix<double> id_m(At.rows(), At.rows());
- id_m.setIdentity();
- L = At * A;
- Eigen::VectorXd frhs;
- buildRhs(sqrtM, s.W_m, s.Ri_m, frhs);
- rhs = At * frhs;
- }
- else
- {
- MatrixXd bnd_pos;
- igl::slice(s.w_uv, bnd_ids, 1, bnd_pos);
- ArrayXi known_ids(bnd_ids.size() * dim);
- ArrayXi unknown_ids((v_n - bnd_ids.rows()) * dim);
- get_complement(bnd_ids, v_n, unknown_ids);
- VectorXd known_pos(bnd_ids.size() * dim);
- for (int d = 0; d < dim; d++)
- {
- auto n_b = bnd_ids.rows();
- known_ids.segment(d * n_b, n_b) = bnd_ids.array() + d * v_n;
- known_pos.segment(d * n_b, n_b) = bnd_pos.col(d);
- unknown_ids.block(d * (v_n - n_b), 0, v_n - n_b, unknown_ids.cols()) =
- unknown_ids.topRows(v_n - n_b) + d * v_n;
- }
- Eigen::SparseMatrix<double> Au, Ae;
- igl::slice(A, unknown_ids, 2, Au);
- igl::slice(A, known_ids, 2, Ae);
- Eigen::SparseMatrix<double> Aut = Au.transpose();
- Aut.makeCompressed();
- L = Aut * Au;
- Eigen::VectorXd frhs;
- buildRhs(sqrtM, s.W_m, s.Ri_m, frhs);
- rhs = Aut * (frhs - Ae * known_pos);
- }
- // add soft constraints.
- for (auto const &x : s.soft_cons)
- {
- int v_idx = x.first;
- for (int d = 0; d < dim; d++)
- {
- rhs(d * (v_n) + v_idx) += s.soft_const_p * x.second(d); // rhs
- L.coeffRef(d * v_n + v_idx,
- d * v_n + v_idx) += s.soft_const_p; // diagonal
- }
- }
- }
- void build_scaffold_linear_system(const SCAFData &s, Eigen::SparseMatrix<double> &L, Eigen::VectorXd &rhs)
- {
- using namespace Eigen;
- const int f_n = s.W_s.rows();
- const int v_n = s.Dx_s.cols();
- const int dim = s.dim;
- Eigen::VectorXd sqrtM = s.s_M.array().sqrt();
- Eigen::SparseMatrix<double> A(dim * dim * f_n, dim * v_n);
- buildAm(sqrtM, s.Dx_s, s.Dy_s, s.W_s, A);
- VectorXi bnd_ids;
- igl::cat(1, s.fixed_ids, s.frame_ids, bnd_ids);
- auto bnd_n = bnd_ids.size();
- assert(bnd_n > 0);
- MatrixXd bnd_pos;
- igl::slice(s.w_uv, bnd_ids, 1, bnd_pos);
- ArrayXi known_ids(bnd_ids.size() * dim);
- ArrayXi unknown_ids((v_n - bnd_ids.rows()) * dim);
- get_complement(bnd_ids, v_n, unknown_ids);
- VectorXd known_pos(bnd_ids.size() * dim);
- for (int d = 0; d < dim; d++)
- {
- auto n_b = bnd_ids.rows();
- known_ids.segment(d * n_b, n_b) = bnd_ids.array() + d * v_n;
- known_pos.segment(d * n_b, n_b) = bnd_pos.col(d);
- unknown_ids.block(d * (v_n - n_b), 0, v_n - n_b, unknown_ids.cols()) =
- unknown_ids.topRows(v_n - n_b) + d * v_n;
- }
- Eigen::VectorXd sqrt_M = s.s_M.array().sqrt();
- // manual slicing for A(:, unknown/known)'
- Eigen::SparseMatrix<double> Au, Ae;
- igl::slice(A, unknown_ids, 2, Au);
- igl::slice(A, known_ids, 2, Ae);
- Eigen::SparseMatrix<double> Aut = Au.transpose();
- Aut.makeCompressed();
- L = Aut * Au;
- Eigen::VectorXd frhs;
- buildRhs(sqrtM, s.W_s, s.Ri_s, frhs);
- rhs = Aut * (frhs - Ae * known_pos);
- }
- void solve_weighted_arap(SCAFData &s, Eigen::MatrixXd &uv)
- {
- using namespace Eigen;
- using namespace std;
- int dim = s.dim;
- igl::Timer timer;
- timer.start();
- VectorXi bnd_ids;
- igl::cat(1, s.fixed_ids, s.frame_ids, bnd_ids);
- const auto v_n = s.v_num;
- const auto bnd_n = bnd_ids.size();
- assert(bnd_n > 0);
- MatrixXd bnd_pos;
- igl::slice(s.w_uv, bnd_ids, 1, bnd_pos);
- ArrayXi known_ids(bnd_n * dim);
- ArrayXi unknown_ids((v_n - bnd_n) * dim);
- get_complement(bnd_ids, v_n, unknown_ids);
- VectorXd known_pos(bnd_ids.size() * dim);
- for (int d = 0; d < dim; d++)
- {
- auto n_b = bnd_ids.rows();
- known_ids.segment(d * n_b, n_b) = bnd_ids.array() + d * v_n;
- known_pos.segment(d * n_b, n_b) = bnd_pos.col(d);
- unknown_ids.block(d * (v_n - n_b), 0, v_n - n_b, unknown_ids.cols()) =
- unknown_ids.topRows(v_n - n_b) + d * v_n;
- }
- Eigen::SparseMatrix<double> L;
- Eigen::VectorXd rhs;
- // fixed frame solving:
- // x_e as the fixed frame, x_u for unknowns (mesh + unknown scaffold)
- // min ||(A_u*x_u + A_e*x_e) - b||^2
- // => A_u'*A_u*x_u = Au'* (b - A_e*x_e) := Au'* b_u
- //
- // separate matrix build:
- // min ||A_m x_m - b_m||^2 + ||A_s x_all - b_s||^2 + soft + proximal
- // First change dimension of A_m to fit for x_all
- // (Not just at the end, since x_all is flattened along dimensions)
- // L = A_m'*A_m + A_s'*A_s + soft + proximal
- // rhs = A_m'* b_m + A_s' * b_s + soft + proximal
- //
- Eigen::SparseMatrix<double> L_m, L_s;
- Eigen::VectorXd rhs_m, rhs_s;
- build_surface_linear_system(s, L_m, rhs_m); // complete Am, with soft
- build_scaffold_linear_system(s, L_s, rhs_s); // complete As, without proximal
- L = L_m + L_s;
- rhs = rhs_m + rhs_s;
- L.makeCompressed();
- Eigen::VectorXd unknown_Uc((v_n - s.frame_ids.size() - s.fixed_ids.size()) * dim), Uc(dim * v_n);
- SimplicialLDLT<Eigen::SparseMatrix<double>> solver;
- unknown_Uc = solver.compute(L).solve(rhs);
- igl::slice_into(unknown_Uc, unknown_ids.matrix(), 1, Uc);
- igl::slice_into(known_pos, known_ids.matrix(), 1, Uc);
- uv = Map<Matrix<double, -1, -1, Eigen::ColMajor>>(Uc.data(), v_n, dim);
- }
- double perform_iteration(SCAFData &s)
- {
- Eigen::MatrixXd V_out = s.w_uv;
- compute_jacobians(s, V_out, true);
- igl::slim_update_weights_and_closest_rotations_with_jacobians(s.Ji_m, s.slim_energy, 0, s.W_m, s.Ri_m);
- igl::slim_update_weights_and_closest_rotations_with_jacobians(s.Ji_s, s.scaf_energy, 0, s.W_s, s.Ri_s);
- solve_weighted_arap(s, V_out);
- auto whole_E = [&s](Eigen::MatrixXd &uv) { return compute_energy(s, uv, true); };
- Eigen::MatrixXi w_T;
- if (s.m_T.cols() == s.s_T.cols())
- igl::cat(1, s.m_T, s.s_T, w_T);
- else
- w_T = s.s_T;
- return igl::flip_avoiding_line_search(w_T, s.w_uv, V_out,
- whole_E, -1) /
- s.mesh_measure;
- }
- }
- }
- IGL_INLINE void igl::scaf_precompute(
- const Eigen::MatrixXd &V,
- const Eigen::MatrixXi &F,
- const Eigen::MatrixXd &V_init,
- igl::SCAFData &data,
- igl::MappingEnergyType slim_energy,
- Eigen::VectorXi &b,
- Eigen::MatrixXd &bc,
- double soft_p)
- {
- Eigen::MatrixXd CN;
- Eigen::MatrixXi FN;
- igl::scaf::add_new_patch(data, V, F, Eigen::RowVector2d(0, 0), V_init);
- data.soft_const_p = soft_p;
- for (int i = 0; i < b.rows(); i++)
- data.soft_cons[b(i)] = bc.row(i);
- data.slim_energy = slim_energy;
- auto &s = data;
- if (!data.has_pre_calc)
- {
- int v_n = s.mv_num + s.sv_num;
- int f_n = s.mf_num + s.sf_num;
- int dim = s.dim;
- Eigen::MatrixXd F1, F2, F3;
- igl::local_basis(s.m_V, s.m_T, F1, F2, F3);
- auto face_proj = [](Eigen::MatrixXd& F){
- std::vector<Eigen::Triplet<double> >IJV;
- int f_num = F.rows();
- for(int i=0; i<F.rows(); i++) {
- IJV.push_back(Eigen::Triplet<double>(i, i, F(i,0)));
- IJV.push_back(Eigen::Triplet<double>(i, i+f_num, F(i,1)));
- IJV.push_back(Eigen::Triplet<double>(i, i+2*f_num, F(i,2)));
- }
- Eigen::SparseMatrix<double> P(f_num, 3*f_num);
- P.setFromTriplets(IJV.begin(), IJV.end());
- return P;
- };
- Eigen::SparseMatrix<double> G;
- igl::grad(s.m_V, s.m_T, G);
- s.Dx_m = face_proj(F1) * G;
- s.Dy_m = face_proj(F2) * G;
- igl::scaf::compute_scaffold_gradient_matrix(s, s.Dx_s, s.Dy_s);
- s.Dx_m.makeCompressed();
- s.Dy_m.makeCompressed();
- s.Ri_m = Eigen::MatrixXd::Zero(s.Dx_m.rows(), dim * dim);
- s.Ji_m.resize(s.Dx_m.rows(), dim * dim);
- s.W_m.resize(s.Dx_m.rows(), dim * dim);
- s.Dx_s.makeCompressed();
- s.Dy_s.makeCompressed();
- s.Ri_s = Eigen::MatrixXd::Zero(s.Dx_s.rows(), dim * dim);
- s.Ji_s.resize(s.Dx_s.rows(), dim * dim);
- s.W_s.resize(s.Dx_s.rows(), dim * dim);
- data.has_pre_calc = true;
- }
- }
- IGL_INLINE Eigen::MatrixXd igl::scaf_solve(SCAFData &s, int iter_num)
- {
- using namespace std;
- using namespace Eigen;
- s.energy = igl::scaf::compute_energy(s, s.w_uv, false) / s.mesh_measure;
- for (int it = 0; it < iter_num; it++)
- {
- s.total_energy = igl::scaf::compute_energy(s, s.w_uv, true) / s.mesh_measure;
- s.rect_frame_V = Eigen::MatrixXd();
- igl::scaf::mesh_improve(s);
- double new_weight = s.mesh_measure * s.energy / (s.sf_num * 100);
- s.scaffold_factor = new_weight;
- igl::scaf::update_scaffold(s);
- s.total_energy = igl::scaf::perform_iteration(s);
- s.energy =
- igl::scaf::compute_energy(s, s.w_uv, false) / s.mesh_measure;
- }
- return s.w_uv.topRows(s.mv_num);
- }
- #ifdef IGL_STATIC_LIBRARY
- #endif
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