bench/spbench/sp_solver.cpp - eigen - Git at Google

 // Small bench routine for Eigen available in Eigen
 // (C) Desire NUENTSA WAKAM, INRIA

 #include <iostream>
 #include <fstream>
 #include <iomanip>
 #include <Eigen/Jacobi>
 #include <Eigen/Householder>
 #include <Eigen/IterativeLinearSolvers>
 #include <Eigen/LU>
 #include <unsupported/Eigen/SparseExtra>
 //#include <Eigen/SparseLU>
 #include <Eigen/SuperLUSupport>
 // #include <unsupported/Eigen/src/IterativeSolvers/Scaling.h>
 #include <bench/BenchTimer.h>
 #include <unsupported/Eigen/IterativeSolvers>
 using namespace std;
 using namespace Eigen;

 int main(int argc, char **args)
 {
   SparseMatrix<double, ColMajor> A;
   typedef SparseMatrix<double, ColMajor>::Index Index;
   typedef Matrix<double, Dynamic, Dynamic> DenseMatrix;
   typedef Matrix<double, Dynamic, 1> DenseRhs;
   VectorXd b, x, tmp;
   BenchTimer timer,totaltime;
   //SparseLU<SparseMatrix<double, ColMajor> >   solver;
 //   SuperLU<SparseMatrix<double, ColMajor> >   solver;
   ConjugateGradient<SparseMatrix<double, ColMajor>, Lower,IncompleteCholesky<double,Lower> > solver;
   ifstream matrix_file;
   string line;
   int  n;
   // Set parameters
 //   solver.iparm(IPARM_THREAD_NBR) = 4;
   /* Fill the matrix with sparse matrix stored in Matrix-Market coordinate column-oriented format */
   if (argc < 2) assert(false && "please, give the matrix market file ");

   timer.start();
   totaltime.start();
   loadMarket(A, args[1]);
   cout << "End charging matrix " << endl;
   bool iscomplex=false, isvector=false;
   int sym;
   getMarketHeader(args[1], sym, iscomplex, isvector);
   if (iscomplex) { cout<< " Not for complex matrices \n"; return -1; }
   if (isvector) { cout << "The provided file is not a matrix file\n"; return -1;}
   if (sym != 0) { // symmetric matrices, only the lower part is stored
     SparseMatrix<double, ColMajor> temp;
     temp = A;
     A = temp.selfadjointView<Lower>();
   }
   timer.stop();

   n = A.cols();
   // ====== TESTS FOR SPARSE TUTORIAL ======
 //   cout<< "OuterSize " << A.outerSize() << " inner " << A.innerSize() << endl;
 //   SparseMatrix<double, RowMajor> mat1(A);
 //   SparseMatrix<double, RowMajor> mat2;
 //   cout << " norm of A " << mat1.norm() << endl; ;
 //   PermutationMatrix<Dynamic, Dynamic, int> perm(n);
 //   perm.resize(n,1);
 //   perm.indices().setLinSpaced(n, 0, n-1);
 //   mat2 = perm * mat1;
 //   mat.subrows();
 //   mat2.resize(n,n);
 //   mat2.reserve(10);
 //   mat2.setConstant();
 //   std::cout<< "NORM " << mat1.squaredNorm()<< endl;

   cout<< "Time to load the matrix " << timer.value() <<endl;
   /* Fill the right hand side */

 //   solver.set_restart(374);
   if (argc > 2)
     loadMarketVector(b, args[2]);
   else
   {
     b.resize(n);
     tmp.resize(n);
 //       tmp.setRandom();
     for (int i = 0; i < n; i++) tmp(i) = i;
     b = A * tmp ;
   }
 //   Scaling<SparseMatrix<double> > scal;
 //   scal.computeRef(A);
 //   b = scal.LeftScaling().cwiseProduct(b);

   /* Compute the factorization */
   cout<< "Starting the factorization "<< endl;
   timer.reset();
   timer.start();
   cout<< "Size of Input Matrix "<< b.size()<<"\n\n";
   cout<< "Rows and columns "<< A.rows() <<" " <<A.cols() <<"\n";
   solver.compute(A);
 //   solver.analyzePattern(A);
 //   solver.factorize(A);
   if (solver.info() != Success) {
     std::cout<< "The solver failed \n";
     return -1;
   }
   timer.stop();
   float time_comp = timer.value();
   cout <<" Compute Time " << time_comp<< endl;

   timer.reset();
   timer.start();
   x = solver.solve(b);
 //   x = scal.RightScaling().cwiseProduct(x);
   timer.stop();
   float time_solve = timer.value();
   cout<< " Time to solve " << time_solve << endl;

   /* Check the accuracy */
   VectorXd tmp2 = b - A*x;
   double tempNorm = tmp2.norm()/b.norm();
   cout << "Relative norm of the computed solution : " << tempNorm <<"\n";
 //   cout << "Iterations : " << solver.iterations() << "\n";

   totaltime.stop();
   cout << "Total time " << totaltime.value() << "\n";
 //  std::cout<<x.transpose()<<"\n";

   return 0;
 }
	// Small bench routine for Eigen available in Eigen
	// (C) Desire NUENTSA WAKAM, INRIA

	#include <iostream>
	#include <fstream>
	#include <iomanip>
	#include <Eigen/Jacobi>
	#include <Eigen/Householder>
	#include <Eigen/IterativeLinearSolvers>
	#include <Eigen/LU>
	#include <unsupported/Eigen/SparseExtra>
	//#include <Eigen/SparseLU>
	#include <Eigen/SuperLUSupport>
	// #include <unsupported/Eigen/src/IterativeSolvers/Scaling.h>
	#include <bench/BenchTimer.h>
	#include <unsupported/Eigen/IterativeSolvers>
	using namespace std;
	using namespace Eigen;

	int main(int argc, char **args)
	{
	SparseMatrix<double, ColMajor> A;
	typedef SparseMatrix<double, ColMajor>::Index Index;
	typedef Matrix<double, Dynamic, Dynamic> DenseMatrix;
	typedef Matrix<double, Dynamic, 1> DenseRhs;
	VectorXd b, x, tmp;
	BenchTimer timer,totaltime;
	//SparseLU<SparseMatrix<double, ColMajor> > solver;
	// SuperLU<SparseMatrix<double, ColMajor> > solver;
	ConjugateGradient<SparseMatrix<double, ColMajor>, Lower,IncompleteCholesky<double,Lower> > solver;
	ifstream matrix_file;
	string line;
	int n;
	// Set parameters
	// solver.iparm(IPARM_THREAD_NBR) = 4;
	/* Fill the matrix with sparse matrix stored in Matrix-Market coordinate column-oriented format */
	if (argc < 2) assert(false && "please, give the matrix market file ");

	timer.start();
	totaltime.start();
	loadMarket(A, args[1]);
	cout << "End charging matrix " << endl;
	bool iscomplex=false, isvector=false;
	int sym;
	getMarketHeader(args[1], sym, iscomplex, isvector);
	if (iscomplex) { cout<< " Not for complex matrices \n"; return -1; }
	if (isvector) { cout << "The provided file is not a matrix file\n"; return -1;}
	if (sym != 0) { // symmetric matrices, only the lower part is stored
	SparseMatrix<double, ColMajor> temp;
	temp = A;
	A = temp.selfadjointView<Lower>();
	}
	timer.stop();

	n = A.cols();
	// ====== TESTS FOR SPARSE TUTORIAL ======
	// cout<< "OuterSize " << A.outerSize() << " inner " << A.innerSize() << endl;
	// SparseMatrix<double, RowMajor> mat1(A);
	// SparseMatrix<double, RowMajor> mat2;
	// cout << " norm of A " << mat1.norm() << endl; ;
	// PermutationMatrix<Dynamic, Dynamic, int> perm(n);
	// perm.resize(n,1);
	// perm.indices().setLinSpaced(n, 0, n-1);
	// mat2 = perm * mat1;
	// mat.subrows();
	// mat2.resize(n,n);
	// mat2.reserve(10);
	// mat2.setConstant();
	// std::cout<< "NORM " << mat1.squaredNorm()<< endl;

	cout<< "Time to load the matrix " << timer.value() <<endl;
	/* Fill the right hand side */

	// solver.set_restart(374);
	if (argc > 2)
	loadMarketVector(b, args[2]);
	else
	{
	b.resize(n);
	tmp.resize(n);
	// tmp.setRandom();
	for (int i = 0; i < n; i++) tmp(i) = i;
	b = A * tmp ;
	}
	// Scaling<SparseMatrix<double> > scal;
	// scal.computeRef(A);
	// b = scal.LeftScaling().cwiseProduct(b);

	/* Compute the factorization */
	cout<< "Starting the factorization "<< endl;
	timer.reset();
	timer.start();
	cout<< "Size of Input Matrix "<< b.size()<<"\n\n";
	cout<< "Rows and columns "<< A.rows() <<" " <<A.cols() <<"\n";
	solver.compute(A);
	// solver.analyzePattern(A);
	// solver.factorize(A);
	if (solver.info() != Success) {
	std::cout<< "The solver failed \n";
	return -1;
	}
	timer.stop();
	float time_comp = timer.value();
	cout <<" Compute Time " << time_comp<< endl;

	timer.reset();
	timer.start();
	x = solver.solve(b);
	// x = scal.RightScaling().cwiseProduct(x);
	timer.stop();
	float time_solve = timer.value();
	cout<< " Time to solve " << time_solve << endl;

	/* Check the accuracy */
	VectorXd tmp2 = b - A*x;
	double tempNorm = tmp2.norm()/b.norm();
	cout << "Relative norm of the computed solution : " << tempNorm <<"\n";
	// cout << "Iterations : " << solver.iterations() << "\n";

	totaltime.stop();
	cout << "Total time " << totaltime.value() << "\n";
	// std::cout<<x.transpose()<<"\n";

	return 0;
	}