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/***************************************************************************
* Copyright (c) 2017 Lorenz Lechner *
* *
* This file is part of the FreeCAD CAx development system. *
* *
* This library is free software; you can redistribute it and/or *
* modify it under the terms of the GNU Library General Public *
* License as published by the Free Software Foundation; either *
* version 2 of the License, or (at your option) any later version. *
* *
* This library is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU Library General Public License for more details. *
* *
* You should have received a copy of the GNU Library General Public *
* License along with this library; see the file COPYING.LIB. If not, *
* write to the Free Software Foundation, Inc., 59 Temple Place, *
* Suite 330, Boston, MA 02111-1307, USA *
* *
***************************************************************************/
#include <cmath>
#include <iostream>
#include "MeshFlatteningNurbs.h"
// clang-format off
namespace nurbs{
double divide(double a, double b)
{
if (fabs(b) < 10e-14)
return 0;
else
return a / b;
}
Eigen::VectorXd NurbsBase1D::getKnotSequence(double u_min, double u_max, int u_deg, int num_u_poles)
{
// boarder poles are on the surface
std::vector<double> u_knots;
for (int i=0; i < u_deg; i++)
u_knots.push_back(u_min);
for (int i=0; i < num_u_poles; i++)
u_knots.push_back(u_min + (u_max - u_min) * i / (num_u_poles - 1));
for (int i=0; i < u_deg; i++)
u_knots.push_back(u_max);
return Eigen::Map<Eigen::VectorXd>(u_knots.data(), u_knots.size());
}
Eigen::VectorXd NurbsBase1D::getWeightList(Eigen::VectorXd knots, int u_deg)
{
Eigen::VectorXd weights;
weights.resize(knots.rows() - u_deg - 1);
weights.setOnes();
return weights;
}
// DE BOOR ALGORITHM FROM OPENGLIDER
std::function<double(double)> get_basis(int degree, int i, Eigen::VectorXd knots)
// Return a basis_function for the given degree """
{
if (degree == 0)
{
return [degree, i, knots](double t)
{
// The basis function for degree = 0 as per eq. 7
(void)degree;
double t_this = knots[i];
double t_next = knots[i+1];
if (t == knots[0])
return (double)(t_next >= t && t >= t_this);
return (double)(t_next >= t && t > t_this);
};
}
else
{
return [degree, i, knots](double t)
{
// The basis function for degree > 0 as per eq. 8
if (t < knots[0])
return get_basis(degree, i, knots)(knots[0]);
else if (t > knots[knots.rows() - 1])
return get_basis(degree, i, knots)(knots[knots.rows() - 1]);
double out = 0.;
double t_this = knots[i];
double t_next = knots[i + 1];
double t_precog = knots[i + degree];
double t_horizon = knots[i + degree + 1];
if (t_this == t_horizon)
return 0.;
double bottom = (t_precog - t_this);
out = divide(t - t_this, bottom) * get_basis(degree - 1, i, knots)(t);
bottom = (t_horizon - t_next);
out += divide(t_horizon - t, bottom) * get_basis(degree - 1, i + 1, knots)(t);
return out;
};
}
}
std::function<double(double)> get_basis_derivative(int order, int degree, int i, Eigen::VectorXd knots)
// Return the derivation of the basis function
// order of basis function
// degree of basis function
//
// knots sequence
{
if (order == 1)
{
return [degree, i, knots, order](double t)
{
(void)order;
double out = 0;
if (!(knots[i + degree] - knots[i] == 0))
{
out += get_basis(degree - 1, i, knots)(t) *
degree / (knots[i + degree] - knots[i]);
}
if (!(knots[i + degree + 1] - knots[i + 1] == 0))
{
out -= get_basis(degree - 1, i + 1, knots)(t) *
degree / (knots[i + degree + 1] - knots[i + 1]);
}
return out;
};
}
else
{
return [degree, i, knots, order](double t)
{
double out = 0;
if (!(knots[i + degree] - knots[i] == 0))
{
out += get_basis_derivative(order - 1, degree - 1, i, knots)(t) *
degree / (knots[i + degree] - knots[i]);
}
if (!(knots[i + degree + 1] - knots[i + 1] == 0))
{
out -= get_basis_derivative(order - 1, degree - 1, i + 1, knots)(t) *
degree / (knots[i + degree + 1] - knots[i + 1]);
}
return out;
};
}
}
NurbsBase2D::NurbsBase2D(Eigen::VectorXd u_knots, Eigen::VectorXd v_knots,
Eigen::VectorXd weights,
int degree_u, int degree_v)
{
this->u_knots = u_knots;
this->v_knots = v_knots;
this->weights = weights;
this->degree_u = degree_u;
this->degree_v = degree_v;
for (int u_i = 0; u_i < u_knots.size() - degree_u - 1; u_i ++)
this->u_functions.push_back(get_basis(degree_u, u_i, u_knots));
for (int v_i = 0; v_i < v_knots.size() - degree_v - 1; v_i ++)
this->v_functions.push_back(get_basis(degree_v, v_i, v_knots));
}
Eigen::VectorXd NurbsBase2D::getInfluenceVector(Eigen::Vector2d u)
{
Eigen::VectorXd n_u, n_v;
double sum_weights = 0;
Eigen::VectorXd infl(this->u_functions.size() * this->v_functions.size());
int i = 0;
n_u.resize(this->u_functions.size());
n_v.resize(this->v_functions.size());
for (unsigned int i = 0; i < this->u_functions.size(); i ++)
n_u[i] = this->u_functions[i](u.x());
for (unsigned int i = 0; i < this->v_functions.size(); i ++)
n_v[i] = this->v_functions[i](u.y());
for (unsigned int u_i = 0; u_i < this->u_functions.size(); u_i++)
{
for (unsigned int v_i = 0; v_i < this->v_functions.size(); v_i++)
{
sum_weights += weights[i] * n_u[u_i] * n_v[v_i];
infl[i] = weights[i] * n_u[u_i] * n_v[v_i];
i ++;
}
}
return infl / sum_weights;
}
void add_triplets(Eigen::VectorXd values, double row, std::vector<trip> &triplets)
{
for (unsigned int i=0; i < values.size(); i++)
{
if (values(i) != 0.) {
triplets.emplace_back(trip(row, i, values(i)));
}
}
}
spMat NurbsBase2D::getInfluenceMatrix(Eigen::Matrix<double, Eigen::Dynamic, 2> U)
{
std::vector<trip> triplets;
for (unsigned int row_index = 0; row_index < U.rows(); row_index++)
add_triplets(this->getInfluenceVector(U.row(row_index)), row_index, triplets);
spMat mat(U.rows(), this->u_functions.size() * this->v_functions.size());
mat.setFromTriplets(triplets.begin(), triplets.end());
return mat;
}
void NurbsBase2D::computeFirstDerivatives()
{
for (unsigned int u_i = 0; u_i < u_functions.size(); u_i ++)
this->Du_functions.push_back(get_basis_derivative(1, this->degree_u, u_i, this->u_knots));
for (unsigned int v_i = 0; v_i < v_functions.size(); v_i ++)
this->Dv_functions.push_back(get_basis_derivative(1, this->degree_v, v_i, this->v_knots));
}
void NurbsBase2D::computeSecondDerivatives()
{
for (unsigned int u_i = 0; u_i < u_functions.size(); u_i ++)
this->DDu_functions.push_back(get_basis_derivative(2, this->degree_u, u_i, this->u_knots));
for (unsigned int v_i = 0; v_i < v_functions.size(); v_i ++)
this->DDv_functions.push_back(get_basis_derivative(2, this->degree_v, v_i, this->v_knots));
}
Eigen::VectorXd NurbsBase2D::getDuVector(Eigen::Vector2d u)
{
Eigen::VectorXd A1, A2;
double C1, C2;
A1.resize(this->u_functions.size() * this->v_functions.size());
A2.resize(this->u_functions.size() * this->v_functions.size());
double A3 = 0;
double A5 = 0;
int i = 0;
Eigen::VectorXd n_u, n_v, Dn_u;
n_u.resize(this->u_functions.size());
Dn_u.resize(this->u_functions.size());
n_v.resize(this->v_functions.size());
for (unsigned int u_i=0; u_i < this->u_functions.size(); u_i++)
{
n_u[u_i] = this->u_functions[u_i](u.x());
Dn_u[u_i] = this->Du_functions[u_i](u.x());
}
for (unsigned int v_i=0; v_i < this->v_functions.size(); v_i++)
{
n_v[v_i] = this->v_functions[v_i](u.y());
}
for (unsigned int u_i=0; u_i < this->u_functions.size(); u_i++)
{
for (unsigned int v_i=0; v_i < this->v_functions.size(); v_i++)
{
C1 = weights[i] * Dn_u[u_i] * n_v[v_i];
C2 = weights[i] * n_u[u_i] * n_v[v_i];
A1[i] = C1;
A2[i] = C2;
A3 += C2;
A5 += C1;
i ++;
}
}
return (A1 * A3 - A2 * A5) / A3 / A3;
}
Eigen::VectorXd NurbsBase2D::getDvVector(Eigen::Vector2d u)
{
Eigen::VectorXd A1, A2;
double C1, C2;
A1.resize(this->u_functions.size() * this->v_functions.size());
A2.resize(this->u_functions.size() * this->v_functions.size());
double A3 = 0;
double A5 = 0;
int i = 0;
Eigen::VectorXd n_u, n_v, Dn_v;
n_u.resize(this->u_functions.size());
Dn_v.resize(this->v_functions.size());
n_v.resize(this->v_functions.size());
for (unsigned int u_i=0; u_i < this->u_functions.size(); u_i++)
{
n_u[u_i] = this->u_functions[u_i](u.x());
}
for (unsigned int v_i=0; v_i < this->v_functions.size(); v_i++)
{
n_v[v_i] = this->v_functions[v_i](u.y());
Dn_v[v_i] = this->Dv_functions[v_i](u.y());
}
for (unsigned int u_i=0; u_i < this->u_functions.size(); u_i++)
{
for (unsigned int v_i=0; v_i < this->v_functions.size(); v_i++)
{
C1 = weights[i] * Dn_v[v_i] * n_u[u_i];
C2 = weights[i] * n_v[v_i] * n_u[u_i];
A1[i] = C1;
A2[i] = C2;
A3 += C2;
A5 += C1;
i ++;
}
}
return (A1 * A3 - A2 * A5) / A3 / A3;
}
spMat NurbsBase2D::getDuMatrix(Eigen::Matrix<double, Eigen::Dynamic, 2> U)
{
std::vector<trip> triplets;
for (unsigned int row_index = 0; row_index < U.rows(); row_index++)
add_triplets(this->getDuVector(U.row(row_index)), row_index, triplets);
spMat mat(U.rows(), this->u_functions.size() * this->v_functions.size());
mat.setFromTriplets(triplets.begin(), triplets.end());
return mat;
}
spMat NurbsBase2D::getDvMatrix(Eigen::Matrix<double, Eigen::Dynamic, 2> U)
{
std::vector<trip> triplets;
for (unsigned int row_index = 0; row_index < U.rows(); row_index++)
add_triplets(this->getDvVector(U.row(row_index)), row_index, triplets);
spMat mat(U.rows(), this->u_functions.size() * this->v_functions.size());
mat.setFromTriplets(triplets.begin(), triplets.end());
return mat;
}
std::tuple<NurbsBase2D, Eigen::MatrixXd> NurbsBase2D::interpolateUBS(
Eigen::Matrix<double, Eigen::Dynamic, 3> poles,
int degree_u,
int degree_v,
int num_u_poles,
int num_v_poles,
int num_u_points,
int num_v_points)
{
double u_min = this->u_knots(0);
double u_max = this->u_knots(this->u_knots.size() - 1);
double v_min = this->v_knots(0);
double v_max = this->v_knots(this->v_knots.size() - 1);
Eigen::VectorXd weights, u_knots, v_knots;
u_knots = NurbsBase1D::getKnotSequence(u_min, u_max, degree_u, num_u_poles);
v_knots = NurbsBase1D::getKnotSequence(v_min, v_max, degree_v, num_v_poles);
weights.resize((u_knots.rows() - degree_u - 1) * (v_knots.rows() - degree_v - 1));
weights.setOnes();
NurbsBase2D new_base(u_knots, v_knots, weights, degree_u, degree_v);
Eigen::Matrix<double, Eigen::Dynamic, 2> uv_points = this->getUVMesh(num_u_points, num_v_points);
Eigen::Matrix<double, Eigen::Dynamic, 3> xyz_points = this->getInfluenceMatrix(uv_points) * poles;
spMat A = new_base.getInfluenceMatrix(uv_points);
Eigen::LeastSquaresConjugateGradient<spMat > solver;
solver.compute(A);
Eigen::Matrix<double, Eigen::Dynamic, 3> new_poles = solver.solve(xyz_points);
return std::tuple<NurbsBase2D, Eigen::MatrixXd >(new_base, new_poles);
}
Eigen::Matrix<double, Eigen::Dynamic, 2> NurbsBase2D::getUVMesh(int num_u_points, int num_v_points)
{
double u_min = this->u_knots(0);
double u_max = this->u_knots(this->u_knots.size() - 1);
double v_min = this->v_knots(0);
double v_max = this->v_knots(this->v_knots.size() - 1);
Eigen::Matrix<double, Eigen::Dynamic, 2> uv_points;
uv_points.resize(static_cast<Eigen::Index>(num_u_points) * static_cast<Eigen::Index>(num_v_points), 2);
int i = 0;
for (int u = 0; u < num_u_points; u++)
{
for (int v = 0; v < num_v_points; v++)
{
uv_points(i, 0) = u_min + (u_max - u_min) * u / (num_u_points - 1);
uv_points(i, 1) = v_min + (v_max - v_min) * v / (num_v_points - 1);
i++;
}
}
return uv_points;
}
NurbsBase1D::NurbsBase1D(Eigen::VectorXd u_knots, Eigen::VectorXd weights, int degree_u)
{
this->u_knots = u_knots;
this->weights = weights;
this->degree_u = degree_u;
for (int u_i = 0; u_i < u_knots.size() - degree_u - 1; u_i ++)
this->u_functions.push_back(get_basis(degree_u, u_i, u_knots));
}
Eigen::VectorXd NurbsBase1D::getInfluenceVector(double u)
{
Eigen::VectorXd n_u;
double sum_weights = 0;
Eigen::VectorXd infl(this->u_functions.size());
n_u.resize(this->u_functions.size());
for (unsigned int i = 0; i < this->u_functions.size(); i ++)
n_u[i] = this->u_functions[i](u);
for (unsigned int u_i = 0; u_i < this->u_functions.size(); u_i++)
{
sum_weights += weights[u_i] * n_u[u_i];
infl[u_i] = weights[u_i] * n_u[u_i];
}
return infl / sum_weights;
}
spMat NurbsBase1D::getInfluenceMatrix(Eigen::VectorXd u)
{
std::vector<trip> triplets;
for (unsigned int row_index = 0; row_index < u.size(); row_index++)
add_triplets(this->getInfluenceVector(u[row_index]), row_index, triplets);
spMat mat(u.size(), this->u_functions.size());
mat.setFromTriplets(triplets.begin(), triplets.end());
return mat;
}
void NurbsBase1D::computeFirstDerivatives()
{
for (unsigned int u_i = 0; u_i < u_functions.size(); u_i ++)
this->Du_functions.push_back(get_basis_derivative(1, this->degree_u, u_i, this->u_knots));
}
void NurbsBase1D::computeSecondDerivatives()
{
for (unsigned int u_i = 0; u_i < u_functions.size(); u_i ++)
this->DDu_functions.push_back(get_basis_derivative(2, this->degree_u, u_i, this->u_knots));
}
Eigen::VectorXd NurbsBase1D::getDuVector(double u)
{
Eigen::VectorXd A1, A2;
double C1, C2;
double C3 = 0;
double C4 = 0;
int i = 0;
A1.resize(this->u_functions.size());
A2.resize(this->u_functions.size());
Eigen::VectorXd n_u, Dn_u;
n_u.resize(this->u_functions.size());
Dn_u.resize(this->u_functions.size());
for (unsigned u_i=0; u_i < this->u_functions.size(); u_i++)
{
n_u[u_i] = this->u_functions[u_i](u);
Dn_u[u_i] = this->Du_functions[u_i](u);
}
for (unsigned int u_i=0; u_i < this->Du_functions.size(); u_i++)
{
C1 = weights[i] * Dn_u[u_i];
C2 = weights[i] * n_u[u_i];
C3 += C1;
C4 += C2;
A1[i] = C1;
A2[i] = C2;
i ++;
}
return (A1 * C4 - A2 * C3) / C4 / C4 ;
}
spMat NurbsBase1D::getDuMatrix(Eigen::VectorXd U)
{
std::vector<trip> triplets;
for (unsigned int row_index = 0; row_index < U.size(); row_index++)
add_triplets(this->getDuVector(U[row_index]), row_index, triplets);
spMat mat(U.size(), this->u_functions.size());
mat.setFromTriplets(triplets.begin(), triplets.end());
return mat;
}
std::tuple<NurbsBase1D, Eigen::Matrix<double, Eigen::Dynamic, 3>> NurbsBase1D::interpolateUBS(
Eigen::Matrix<double,
Eigen::Dynamic, 3> poles,
int degree,
int num_poles,
int num_points)
{
double u_min = this->u_knots(0);
double u_max = this->u_knots(this->u_knots.size() - 1);
Eigen::VectorXd u_knots, weights;
u_knots = NurbsBase1D::getKnotSequence(u_min, u_max, degree, num_poles);
weights = NurbsBase1D::getWeightList(u_knots, degree);
NurbsBase1D new_base(u_knots, weights, degree);
Eigen::Matrix<double, Eigen::Dynamic, 1> u_points = this->getUMesh(num_points);
Eigen::Matrix<double, Eigen::Dynamic, 3> xyz_points;
xyz_points = this->getInfluenceMatrix(u_points) * poles;
spMat A = new_base.getInfluenceMatrix(u_points);
Eigen::LeastSquaresConjugateGradient<spMat > solver;
solver.compute(A);
Eigen::Matrix<double, Eigen::Dynamic, 3> new_poles = solver.solve(xyz_points);
return std::tuple<NurbsBase1D, Eigen::Matrix<double, Eigen::Dynamic, 3> >(new_base, new_poles);
}
Eigen::VectorXd NurbsBase1D::getUMesh(int num_u_points)
{
double u_min = this->u_knots(0);
double u_max = this->u_knots(this->u_knots.size() - 1);
Eigen::Matrix<double, Eigen::Dynamic, 1> u_points;
u_points.setLinSpaced(num_u_points, u_min, u_max);
return u_points;
}
}
// clang-format on
|