- Authors
- Simon Giraudot, Pierre Alliez, Frédéric Cazals, Gaël Guennebaud, Bruno Lévy, Marc Pouget, Laurent Saboret, and Liangliang Nan
Several CGAL packages have to solve linear systems with dense or sparse matrices, linear integer programs. This package provides concepts and models for that purpose.
For linear systems, we generally provide models using the Eigen library. Wrappers for the Eigen classes Eigen_matrix
and Eigen_vector
are also provided when needed. It is straightforward to develop equivalent models for other solvers, for example those found in the Intel Math Kernel Library (MKL).
For mixed integer programs (either constrained or unconstrained), we provide models using SCIP and GLPK libraries. It is also possible to derive new models from other high performance libraries, e.g., CBC , Gurobi .
Matrix Diagonalization
The concept DiagonalizeTraits<T,dim>
defines an interface for the diagonalization and computation of eigenvectors and eigenvalues of a symmetric matrix. T
is the number type and dim
is the dimension of the matrices and vector (set to 3 by default). We provide the model Eigen_diagonalize_traits<T,dim>
that uses the Eigen library.
This is an example of an eigen decomposition of a matrix using this class:
File Solver_interface/diagonalize_matrix.cpp
#include <iostream>
#include <CGAL/Eigen_diagonalize_traits.h>
typedef double FT;
typedef std::array<FT, 6> Eigen_matrix;
typedef std::array<FT, 3> Eigen_vector;
typedef std::array<FT, 9> Eigen_three_vectors;
int main(void)
{
Eigen_matrix covariance = {{ 0., 0., 0., 0., 0., 0. }};
for(std::size_t i=0; i<6; ++i)
covariance[i] = rand();
Eigen_vector eigenvalues;
Eigen_three_vectors eigenvectors;
if(!(Diagonalize_traits::diagonalize_selfadjoint_covariance_matrix(covariance,
eigenvalues,
eigenvectors)))
{
std::cerr << "Error: cannot diagonalize matrix" << std::endl;
return -1;
}
for(std::size_t i=0; i<3; ++i)
{
std::cout << "Eigenvalue " << i+1 << " = " << eigenvalues[i] << std::endl
<< " with eigenvector [ ";
for(std::size_t j=0; j<3; ++j)
std::cout << eigenvectors[3*i + j] << " ";
std::cout << "]" << std::endl;
}
return 0;
}
Singular Value Decomposition
The concept SvdTraits
defines an interface for solving in the least square sense a linear system with a singular value decomposition. The field type is double
. We provide the model Eigen_svd
that uses the Eigen library.
Here is a simple example that shows how to handle matrices, vectors and this solver:
File Solver_interface/singular_value_decomposition.cpp
#ifdef CGAL_EIGEN3_ENABLED
#include <CGAL/Eigen_matrix.h>
#include <CGAL/Eigen_vector.h>
#include <CGAL/Eigen_svd.h>
#endif
typedef Svd::FT FT;
typedef Svd::Vector Eigen_vector;
typedef Svd::Matrix Eigen_matrix;
int main(void)
{
std::size_t degree = 3;
Eigen_vector B(degree);
Eigen_matrix M(degree, degree);
for(std::size_t i=0; i<degree; ++i)
{
B.set(i, rand());
for(std::size_t j = 0; j < degree; ++j)
M.set(i, j, rand());
}
std::cout << Svd::solve(M, B) << std::endl;
std::cout << "Solution of SVD = [ ";
for(std::size_t i=0; i<degree; ++i)
std::cout << B.vector()[i] << " ";
std::cout << "]" << std::endl;
return 0;
}
Sparse Solvers
We define 3 concepts for sparse linear algebra:
An interface to the sparse solvers from the Eigen library is provided as a model for these 3 concepts through the class Eigen_solver_traits<T>
. This solver traits class can be used for an iterative or a direct, symmetric or general sparse solvers. The specific solver to be used must be given as template parameter.
Each CGAL package using a sparse solver specifies which type of matrix and solver is required:
Here is an example that shows how to fill the sparse matrix and call the solver:
File Solver_interface/sparse_solvers.cpp
#include <CGAL/Eigen_solver_traits.h>
#include <CGAL/Eigen_matrix.h>
typedef Eigen_solver::NT FT;
typedef Eigen_solver::Matrix Eigen_matrix;
typedef Eigen_solver::Vector Eigen_vector;
int main(void)
{
srand(static_cast<unsigned int>(time (nullptr)));
std::size_t degree = 3000;
std::size_t nb_nonzero_coef = 100;
Eigen_vector B(degree);
Eigen_matrix A(degree);
for(std::size_t i=0; i<nb_nonzero_coef; ++i)
{
int x = rand() % degree;
int y = rand() % degree;
FT value = rand() / (FT)RAND_MAX;
A.add_coef(x, y, value);
A.add_coef(y, x, value);
}
Eigen_vector X(degree);
FT d;
Eigen_solver solver;
if(!(solver.linear_solver(A, B, X, d)))
{
std::cerr << "Error: linear solver failed" << std::endl;
return -1;
}
std::cerr << "Linear solve succeeded" << std::endl;
return 0;
}
Mixed Integer Program Solvers
The concept MixedIntegerProgramTraits
defines an interface for formulating and solving (constrained or unconstrained) mixed integer programs. It can also be used for general linear programs.
The field type is double
. We provide two models of this concept: CGAL::GLPK_mixed_integer_program_traits
using GLPK and CGAL::SCIP_mixed_integer_program_traits
using SCIP.
Here is an example that shows how to formulate and solve a simple mixed integer program using this solver.
File Solver_interface/mixed_integer_program.cpp
#include <iostream>
#ifdef CGAL_USE_SCIP
#include <CGAL/SCIP_mixed_integer_program_traits.h>
#elif defined(CGAL_USE_GLPK)
#include <CGAL/GLPK_mixed_integer_program_traits.h>
#endif
#if defined(CGAL_USE_GLPK) || defined(CGAL_USE_SCIP)
typedef typename MIP_Solver::Variable Variable;
typedef typename MIP_Solver::Linear_objective Linear_objective;
typedef typename MIP_Solver::Linear_constraint Linear_constraint;
int main()
{
MIP_Solver solver;
Variable* x1 = solver.create_variable(Variable::CONTINUOUS, 0, 40, "x1");
Variable* x2 = solver.create_variable();
x2->set_name("x2");
Variable* x3 = solver.create_variable();
x3->set_name("x3");
Variable* x4 = solver.create_variable(Variable::INTEGER, 2, 3, "x4");
Linear_objective * obj = solver.create_objective(Linear_objective::MAXIMIZE);
obj->add_coefficient(x1, 1.0);
obj->add_coefficient(x2, 2.0);
obj->add_coefficient(x3, 3.0);
obj->add_coefficient(x4, 1.0);
Linear_constraint* c1 = solver.create_constraint(-Linear_constraint::infinity(), 20, "c1");
c1->add_coefficient(x1, -1);
c1->add_coefficient(x2, 1);
c1->add_coefficient(x3, 1);
c1->add_coefficient(x4, 10);
Linear_constraint* c2 = solver.create_constraint(-Linear_constraint::infinity(), 30, "c2");
c2->add_coefficient(x1, 1);
c2->add_coefficient(x2, -3);
c2->add_coefficient(x3, 1);
Linear_constraint* c3 = solver.create_constraint(0, 0, "c3");
c3->add_coefficient(x2, 1);
c3->add_coefficient(x4, -3.5);
if (solver.solve()) {
std::cout << "result: " << std::endl;
const std::vector<double>& results = solver.solution();
for (std::size_t i = 0; i < results.size(); ++i) {
std::cout << "\tx" << i + 1 << ": " << results[i] << std::endl;
}
return EXIT_SUCCESS;
}
else {
std::cerr << "solving problem failed" << std::endl;
return EXIT_FAILURE;
}
}
#else
int main(int , char**)
{
std::cerr << "This test requires either GLPK or SCIP.\n";
return EXIT_SUCCESS;
}
#endif // defined(CGAL_USE_GLPK) || defined(CGAL_USE_SCIP)
Implementation History
This package is the result of the increasing needs for linear solvers in CGAL. The first packages that introduced the solver concepts were Triangulated Surface Mesh Parameterization, Poisson Surface Reconstruction and Estimation of Local Differential Properties of Point-Sampled Surfaces. At that time, these packages were relying on TAUCS, LAPACK, BLAS and OpenNL. Gaël Guennebaud then introduced new models using the Eigen library that became the only supported models by CGAL. Later on the packages Triangulated Surface Mesh Skeletonization and Triangulated Surface Mesh Deformation extended the existing concepts. Liangliang Nan introduced the concept MixedIntegerProgramTraits
and two models for solving mixed integer programs when implementing the Polygonal Surface Reconstruction package.
Simon Giraudot was responsible for gathering all concepts and classes, and also wrote this user manual with the help of Andreas Fabri.