Datasets:

adfa5456
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FastRobustICP

	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>
	//
	// 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 <iostream>
	#include <fstream>
	#include <Eigen/SparseCore>
	#include <bench/BenchTimer.h>
	#include <cstdlib>
	#include <string>
	#include <Eigen/Cholesky>
	#include <Eigen/Jacobi>
	#include <Eigen/Householder>
	#include <Eigen/IterativeLinearSolvers>
	#include <unsupported/Eigen/IterativeSolvers>
	#include <Eigen/LU>
	#include <unsupported/Eigen/SparseExtra>
	#include <Eigen/SparseLU>

	#include "spbenchstyle.h"

	#ifdef EIGEN_METIS_SUPPORT
	#include <Eigen/MetisSupport>
	#endif

	#ifdef EIGEN_CHOLMOD_SUPPORT
	#include <Eigen/CholmodSupport>
	#endif

	#ifdef EIGEN_UMFPACK_SUPPORT
	#include <Eigen/UmfPackSupport>
	#endif

	#ifdef EIGEN_KLU_SUPPORT
	#include <Eigen/KLUSupport>
	#endif

	#ifdef EIGEN_PARDISO_SUPPORT
	#include <Eigen/PardisoSupport>
	#endif

	#ifdef EIGEN_SUPERLU_SUPPORT
	#include <Eigen/SuperLUSupport>
	#endif

	#ifdef EIGEN_PASTIX_SUPPORT
	#include <Eigen/PaStiXSupport>
	#endif

	// CONSTANTS
	#define EIGEN_UMFPACK 10
	#define EIGEN_KLU 11
	#define EIGEN_SUPERLU 20
	#define EIGEN_PASTIX 30
	#define EIGEN_PARDISO 40
	#define EIGEN_SPARSELU_COLAMD 50
	#define EIGEN_SPARSELU_METIS 51
	#define EIGEN_BICGSTAB 60
	#define EIGEN_BICGSTAB_ILUT 61
	#define EIGEN_GMRES 70
	#define EIGEN_GMRES_ILUT 71
	#define EIGEN_SIMPLICIAL_LDLT 80
	#define EIGEN_CHOLMOD_LDLT 90
	#define EIGEN_PASTIX_LDLT 100
	#define EIGEN_PARDISO_LDLT 110
	#define EIGEN_SIMPLICIAL_LLT 120
	#define EIGEN_CHOLMOD_SUPERNODAL_LLT 130
	#define EIGEN_CHOLMOD_SIMPLICIAL_LLT 140
	#define EIGEN_PASTIX_LLT 150
	#define EIGEN_PARDISO_LLT 160
	#define EIGEN_CG 170
	#define EIGEN_CG_PRECOND 180

	using namespace Eigen;
	using namespace std;


	// Global variables for input parameters
	int MaximumIters; // Maximum number of iterations
	double RelErr; // Relative error of the computed solution
	double best_time_val; // Current best time overall solvers
	int best_time_id; // id of the best solver for the current system

	template<typename T> inline typename NumTraits<T>::Real test_precision() { return NumTraits<T>::dummy_precision(); }
	template<> inline float test_precision<float>() { return 1e-3f; }
	template<> inline double test_precision<double>() { return 1e-6; }
	template<> inline float test_precision<std::complex<float> >() { return test_precision<float>(); }
	template<> inline double test_precision<std::complex<double> >() { return test_precision<double>(); }

	void printStatheader(std::ofstream& out)
	{
	// Print XML header
	// NOTE It would have been much easier to write these XML documents using external libraries like tinyXML or Xerces-C++.

	out << "<?xml version='1.0' encoding='UTF-8'?> \n";
	out << "<?xml-stylesheet type='text/xsl' href='#stylesheet' ?> \n";
	out << "<!DOCTYPE BENCH [\n<!ATTLIST xsl:stylesheet\n id\t ID #REQUIRED>\n]>";
	out << "\n\n<!-- Generated by the Eigen library -->\n";

	out << "\n<BENCH> \n" ; //root XML element
	// Print the xsl style section
	printBenchStyle(out);
	// List all available solvers
	out << " <AVAILSOLVER> \n";
	#ifdef EIGEN_UMFPACK_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_UMFPACK << "'>\n";
	out << " <TYPE> LU </TYPE> \n";
	out << " <PACKAGE> UMFPACK </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	#ifdef EIGEN_KLU_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_KLU << "'>\n";
	out << " <TYPE> LU </TYPE> \n";
	out << " <PACKAGE> KLU </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	#ifdef EIGEN_SUPERLU_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_SUPERLU << "'>\n";
	out << " <TYPE> LU </TYPE> \n";
	out << " <PACKAGE> SUPERLU </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	#ifdef EIGEN_CHOLMOD_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_CHOLMOD_SIMPLICIAL_LLT << "'>\n";
	out << " <TYPE> LLT SP</TYPE> \n";
	out << " <PACKAGE> CHOLMOD </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_CHOLMOD_SUPERNODAL_LLT << "'>\n";
	out << " <TYPE> LLT</TYPE> \n";
	out << " <PACKAGE> CHOLMOD </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_CHOLMOD_LDLT << "'>\n";
	out << " <TYPE> LDLT </TYPE> \n";
	out << " <PACKAGE> CHOLMOD </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	#ifdef EIGEN_PARDISO_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_PARDISO << "'>\n";
	out << " <TYPE> LU </TYPE> \n";
	out << " <PACKAGE> PARDISO </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_PARDISO_LLT << "'>\n";
	out << " <TYPE> LLT </TYPE> \n";
	out << " <PACKAGE> PARDISO </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_PARDISO_LDLT << "'>\n";
	out << " <TYPE> LDLT </TYPE> \n";
	out << " <PACKAGE> PARDISO </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	#ifdef EIGEN_PASTIX_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_PASTIX << "'>\n";
	out << " <TYPE> LU </TYPE> \n";
	out << " <PACKAGE> PASTIX </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_PASTIX_LLT << "'>\n";
	out << " <TYPE> LLT </TYPE> \n";
	out << " <PACKAGE> PASTIX </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_PASTIX_LDLT << "'>\n";
	out << " <TYPE> LDLT </TYPE> \n";
	out << " <PACKAGE> PASTIX </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif

	out <<" <SOLVER ID='" << EIGEN_BICGSTAB << "'>\n";
	out << " <TYPE> BICGSTAB </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_BICGSTAB_ILUT << "'>\n";
	out << " <TYPE> BICGSTAB_ILUT </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_GMRES_ILUT << "'>\n";
	out << " <TYPE> GMRES_ILUT </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_SIMPLICIAL_LDLT << "'>\n";
	out << " <TYPE> LDLT </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_SIMPLICIAL_LLT << "'>\n";
	out << " <TYPE> LLT </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_CG << "'>\n";
	out << " <TYPE> CG </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	out <<" <SOLVER ID='" << EIGEN_SPARSELU_COLAMD << "'>\n";
	out << " <TYPE> LU_COLAMD </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";

	#ifdef EIGEN_METIS_SUPPORT
	out <<" <SOLVER ID='" << EIGEN_SPARSELU_METIS << "'>\n";
	out << " <TYPE> LU_METIS </TYPE> \n";
	out << " <PACKAGE> EIGEN </PACKAGE> \n";
	out << " </SOLVER> \n";
	#endif
	out << " </AVAILSOLVER> \n";

	}


	template<typename Solver, typename Scalar>
	void call_solver(Solver &solver, const int solver_id, const typename Solver::MatrixType& A, const Matrix<Scalar, Dynamic, 1>& b, const Matrix<Scalar, Dynamic, 1>& refX,std::ofstream& statbuf)
	{

	double total_time;
	double compute_time;
	double solve_time;
	double rel_error;
	Matrix<Scalar, Dynamic, 1> x;
	BenchTimer timer;
	timer.reset();
	timer.start();
	solver.compute(A);
	if (solver.info() != Success)
	{
	std::cerr << "Solver failed ... \n";
	return;
	}
	timer.stop();
	compute_time = timer.value();
	statbuf << " <TIME>\n";
	statbuf << " <COMPUTE> " << timer.value() << "</COMPUTE>\n";
	std::cout<< "COMPUTE TIME : " << timer.value() <<std::endl;

	timer.reset();
	timer.start();
	x = solver.solve(b);
	if (solver.info() == NumericalIssue)
	{
	std::cerr << "Solver failed ... \n";
	return;
	}
	timer.stop();
	solve_time = timer.value();
	statbuf << " <SOLVE> " << timer.value() << "</SOLVE>\n";
	std::cout<< "SOLVE TIME : " << timer.value() <<std::endl;

	total_time = solve_time + compute_time;
	statbuf << " <TOTAL> " << total_time << "</TOTAL>\n";
	std::cout<< "TOTAL TIME : " << total_time <<std::endl;
	statbuf << " </TIME>\n";

	// Verify the relative error
	if(refX.size() != 0)
	rel_error = (refX - x).norm()/refX.norm();
	else
	{
	// Compute the relative residual norm
	Matrix<Scalar, Dynamic, 1> temp;
	temp = A * x;
	rel_error = (b-temp).norm()/b.norm();
	}
	statbuf << " <ERROR> " << rel_error << "</ERROR>\n";
	std::cout<< "REL. ERROR : " << rel_error << "\n\n" ;
	if ( rel_error <= RelErr )
	{
	// check the best time if convergence
	if(!best_time_val \|\| (best_time_val > total_time))
	{
	best_time_val = total_time;
	best_time_id = solver_id;
	}
	}
	}

	template<typename Solver, typename Scalar>
	void call_directsolver(Solver& solver, const int solver_id, const typename Solver::MatrixType& A, const Matrix<Scalar, Dynamic, 1>& b, const Matrix<Scalar, Dynamic, 1>& refX, std::string& statFile)
	{
	std::ofstream statbuf(statFile.c_str(), std::ios::app);
	statbuf << " <SOLVER_STAT ID='" << solver_id <<"'>\n";
	call_solver(solver, solver_id, A, b, refX,statbuf);
	statbuf << " </SOLVER_STAT>\n";
	statbuf.close();
	}

	template<typename Solver, typename Scalar>
	void call_itersolver(Solver &solver, const int solver_id, const typename Solver::MatrixType& A, const Matrix<Scalar, Dynamic, 1>& b, const Matrix<Scalar, Dynamic, 1>& refX, std::string& statFile)
	{
	solver.setTolerance(RelErr);
	solver.setMaxIterations(MaximumIters);

	std::ofstream statbuf(statFile.c_str(), std::ios::app);
	statbuf << " <SOLVER_STAT ID='" << solver_id <<"'>\n";
	call_solver(solver, solver_id, A, b, refX,statbuf);
	statbuf << " <ITER> "<< solver.iterations() << "</ITER>\n";
	statbuf << " </SOLVER_STAT>\n";
	std::cout << "ITERATIONS : " << solver.iterations() <<"\n\n\n";

	}


	template <typename Scalar>
	void SelectSolvers(const SparseMatrix<Scalar>&A, unsigned int sym, Matrix<Scalar, Dynamic, 1>& b, const Matrix<Scalar, Dynamic, 1>& refX, std::string& statFile)
	{
	typedef SparseMatrix<Scalar, ColMajor> SpMat;
	// First, deal with Nonsymmetric and symmetric matrices
	best_time_id = 0;
	best_time_val = 0.0;
	//UMFPACK
	#ifdef EIGEN_UMFPACK_SUPPORT
	{
	cout << "Solving with UMFPACK LU ... \n";
	UmfPackLU<SpMat> solver;
	call_directsolver(solver, EIGEN_UMFPACK, A, b, refX,statFile);
	}
	#endif
	//KLU
	#ifdef EIGEN_KLU_SUPPORT
	{
	cout << "Solving with KLU LU ... \n";
	KLU<SpMat> solver;
	call_directsolver(solver, EIGEN_KLU, A, b, refX,statFile);
	}
	#endif
	//SuperLU
	#ifdef EIGEN_SUPERLU_SUPPORT
	{
	cout << "\nSolving with SUPERLU ... \n";
	SuperLU<SpMat> solver;
	call_directsolver(solver, EIGEN_SUPERLU, A, b, refX,statFile);
	}
	#endif

	// PaStix LU
	#ifdef EIGEN_PASTIX_SUPPORT
	{
	cout << "\nSolving with PASTIX LU ... \n";
	PastixLU<SpMat> solver;
	call_directsolver(solver, EIGEN_PASTIX, A, b, refX,statFile) ;
	}
	#endif

	//PARDISO LU
	#ifdef EIGEN_PARDISO_SUPPORT
	{
	cout << "\nSolving with PARDISO LU ... \n";
	PardisoLU<SpMat> solver;
	call_directsolver(solver, EIGEN_PARDISO, A, b, refX,statFile);
	}
	#endif

	// Eigen SparseLU METIS
	cout << "\n Solving with Sparse LU AND COLAMD ... \n";
	SparseLU<SpMat, COLAMDOrdering<int> > solver;
	call_directsolver(solver, EIGEN_SPARSELU_COLAMD, A, b, refX, statFile);
	// Eigen SparseLU METIS
	#ifdef EIGEN_METIS_SUPPORT
	{
	cout << "\n Solving with Sparse LU AND METIS ... \n";
	SparseLU<SpMat, MetisOrdering<int> > solver;
	call_directsolver(solver, EIGEN_SPARSELU_METIS, A, b, refX, statFile);
	}
	#endif

	//BiCGSTAB
	{
	cout << "\nSolving with BiCGSTAB ... \n";
	BiCGSTAB<SpMat> solver;
	call_itersolver(solver, EIGEN_BICGSTAB, A, b, refX,statFile);
	}
	//BiCGSTAB+ILUT
	{
	cout << "\nSolving with BiCGSTAB and ILUT ... \n";
	BiCGSTAB<SpMat, IncompleteLUT<Scalar> > solver;
	call_itersolver(solver, EIGEN_BICGSTAB_ILUT, A, b, refX,statFile);
	}


	//GMRES
	// {
	// cout << "\nSolving with GMRES ... \n";
	// GMRES<SpMat> solver;
	// call_itersolver(solver, EIGEN_GMRES, A, b, refX,statFile);
	// }
	//GMRES+ILUT
	{
	cout << "\nSolving with GMRES and ILUT ... \n";
	GMRES<SpMat, IncompleteLUT<Scalar> > solver;
	call_itersolver(solver, EIGEN_GMRES_ILUT, A, b, refX,statFile);
	}

	// Hermitian and not necessarily positive-definites
	if (sym != NonSymmetric)
	{
	// Internal Cholesky
	{
	cout << "\nSolving with Simplicial LDLT ... \n";
	SimplicialLDLT<SpMat, Lower> solver;
	call_directsolver(solver, EIGEN_SIMPLICIAL_LDLT, A, b, refX,statFile);
	}

	// CHOLMOD
	#ifdef EIGEN_CHOLMOD_SUPPORT
	{
	cout << "\nSolving with CHOLMOD LDLT ... \n";
	CholmodDecomposition<SpMat, Lower> solver;
	solver.setMode(CholmodLDLt);
	call_directsolver(solver,EIGEN_CHOLMOD_LDLT, A, b, refX,statFile);
	}
	#endif

	//PASTIX LLT
	#ifdef EIGEN_PASTIX_SUPPORT
	{
	cout << "\nSolving with PASTIX LDLT ... \n";
	PastixLDLT<SpMat, Lower> solver;
	call_directsolver(solver,EIGEN_PASTIX_LDLT, A, b, refX,statFile);
	}
	#endif

	//PARDISO LLT
	#ifdef EIGEN_PARDISO_SUPPORT
	{
	cout << "\nSolving with PARDISO LDLT ... \n";
	PardisoLDLT<SpMat, Lower> solver;
	call_directsolver(solver,EIGEN_PARDISO_LDLT, A, b, refX,statFile);
	}
	#endif
	}

	// Now, symmetric POSITIVE DEFINITE matrices
	if (sym == SPD)
	{

	//Internal Sparse Cholesky
	{
	cout << "\nSolving with SIMPLICIAL LLT ... \n";
	SimplicialLLT<SpMat, Lower> solver;
	call_directsolver(solver,EIGEN_SIMPLICIAL_LLT, A, b, refX,statFile);
	}

	// CHOLMOD
	#ifdef EIGEN_CHOLMOD_SUPPORT
	{
	// CholMOD SuperNodal LLT
	cout << "\nSolving with CHOLMOD LLT (Supernodal)... \n";
	CholmodDecomposition<SpMat, Lower> solver;
	solver.setMode(CholmodSupernodalLLt);
	call_directsolver(solver,EIGEN_CHOLMOD_SUPERNODAL_LLT, A, b, refX,statFile);
	// CholMod Simplicial LLT
	cout << "\nSolving with CHOLMOD LLT (Simplicial) ... \n";
	solver.setMode(CholmodSimplicialLLt);
	call_directsolver(solver,EIGEN_CHOLMOD_SIMPLICIAL_LLT, A, b, refX,statFile);
	}
	#endif

	//PASTIX LLT
	#ifdef EIGEN_PASTIX_SUPPORT
	{
	cout << "\nSolving with PASTIX LLT ... \n";
	PastixLLT<SpMat, Lower> solver;
	call_directsolver(solver,EIGEN_PASTIX_LLT, A, b, refX,statFile);
	}
	#endif

	//PARDISO LLT
	#ifdef EIGEN_PARDISO_SUPPORT
	{
	cout << "\nSolving with PARDISO LLT ... \n";
	PardisoLLT<SpMat, Lower> solver;
	call_directsolver(solver,EIGEN_PARDISO_LLT, A, b, refX,statFile);
	}
	#endif

	// Internal CG
	{
	cout << "\nSolving with CG ... \n";
	ConjugateGradient<SpMat, Lower> solver;
	call_itersolver(solver,EIGEN_CG, A, b, refX,statFile);
	}
	//CG+IdentityPreconditioner
	// {
	// cout << "\nSolving with CG and IdentityPreconditioner ... \n";
	// ConjugateGradient<SpMat, Lower, IdentityPreconditioner> solver;
	// call_itersolver(solver,EIGEN_CG_PRECOND, A, b, refX,statFile);
	// }
	} // End SPD matrices
	}

	/* Browse all the matrices available in the specified folder
	* and solve the associated linear system.
	* The results of each solve are printed in the standard output
	* and optionally in the provided html file
	*/
	template <typename Scalar>
	void Browse_Matrices(const string folder, bool statFileExists, std::string& statFile, int maxiters, double tol)
	{
	MaximumIters = maxiters; // Maximum number of iterations, global variable
	RelErr = tol; //Relative residual error as stopping criterion for iterative solvers
	MatrixMarketIterator<Scalar> it(folder);
	for ( ; it; ++it)
	{
	//print the infos for this linear system
	if(statFileExists)
	{
	std::ofstream statbuf(statFile.c_str(), std::ios::app);
	statbuf << "<LINEARSYSTEM> \n";
	statbuf << " <MATRIX> \n";
	statbuf << " <NAME> " << it.matname() << " </NAME>\n";
	statbuf << " <SIZE> " << it.matrix().rows() << " </SIZE>\n";
	statbuf << " <ENTRIES> " << it.matrix().nonZeros() << "</ENTRIES>\n";
	if (it.sym()!=NonSymmetric)
	{
	statbuf << " <SYMMETRY> Symmetric </SYMMETRY>\n" ;
	if (it.sym() == SPD)
	statbuf << " <POSDEF> YES </POSDEF>\n";
	else
	statbuf << " <POSDEF> NO </POSDEF>\n";

	}
	else
	{
	statbuf << " <SYMMETRY> NonSymmetric </SYMMETRY>\n" ;
	statbuf << " <POSDEF> NO </POSDEF>\n";
	}
	statbuf << " </MATRIX> \n";
	statbuf.close();
	}

	cout<< "\n\n===================================================== \n";
	cout<< " ====== SOLVING WITH MATRIX " << it.matname() << " ====\n";
	cout<< " =================================================== \n\n";
	Matrix<Scalar, Dynamic, 1> refX;
	if(it.hasrefX()) refX = it.refX();
	// Call all suitable solvers for this linear system
	SelectSolvers<Scalar>(it.matrix(), it.sym(), it.rhs(), refX, statFile);

	if(statFileExists)
	{
	std::ofstream statbuf(statFile.c_str(), std::ios::app);
	statbuf << " <BEST_SOLVER ID='"<< best_time_id
	<< "'></BEST_SOLVER>\n";
	statbuf << " </LINEARSYSTEM> \n";
	statbuf.close();
	}
	}
	}

	bool get_options(int argc, char *args, string option, string value=0)
	{
	int idx = 1, found=false;
	while (idx<argc && !found){
	if (option.compare(args[idx]) == 0){
	found = true;
	if(value) *value = args[idx+1];
	}
	idx+=2;
	}
	return found;
	}