test/sparse_solver.h - platform/external/eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2011 Gael Guennebaud <g.gael@free.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 "sparse.h"
 #include <Eigen/SparseCore>

 template<typename Solver, typename Rhs, typename DenseMat, typename DenseRhs>
 void check_sparse_solving(Solver& solver, const typename Solver::MatrixType& A, const Rhs& b, const DenseMat& dA, const DenseRhs& db)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;

   DenseRhs refX = dA.lu().solve(db);
   {
     Rhs x(b.rows(), b.cols());
     Rhs oldb = b;

     solver.compute(A);
     if (solver.info() != Success)
     {
       std::cerr << "sparse solver testing: factorization failed (check_sparse_solving)\n";
       exit(0);
       return;
     }
     x = solver.solve(b);
     if (solver.info() != Success)
     {
       std::cerr << "sparse solver testing: solving failed\n";
       return;
     }
     VERIFY(oldb.isApprox(b) && "sparse solver testing: the rhs should not be modified!");

     VERIFY(x.isApprox(refX,test_precision<Scalar>()));
     x.setZero();
     // test the analyze/factorize API
     solver.analyzePattern(A);
     solver.factorize(A);
     if (solver.info() != Success)
     {
       std::cerr << "sparse solver testing: factorization failed (check_sparse_solving)\n";
       exit(0);
       return;
     }
     x = solver.solve(b);
     if (solver.info() != Success)
     {
       std::cerr << "sparse solver testing: solving failed\n";
       return;
     }
     VERIFY(oldb.isApprox(b) && "sparse solver testing: the rhs should not be modified!");

     VERIFY(x.isApprox(refX,test_precision<Scalar>()));
   }

   // test dense Block as the result and rhs:
   {
     DenseRhs x(db.rows(), db.cols());
     DenseRhs oldb(db);
     x.setZero();
     x.block(0,0,x.rows(),x.cols()) = solver.solve(db.block(0,0,db.rows(),db.cols()));
     VERIFY(oldb.isApprox(db) && "sparse solver testing: the rhs should not be modified!");
     VERIFY(x.isApprox(refX,test_precision<Scalar>()));
   }
 }

 template<typename Solver, typename Rhs>
 void check_sparse_solving_real_cases(Solver& solver, const typename Solver::MatrixType& A, const Rhs& b, const Rhs& refX)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef typename Mat::RealScalar RealScalar;

   Rhs x(b.rows(), b.cols());

   solver.compute(A);
   if (solver.info() != Success)
   {
     std::cerr << "sparse solver testing: factorization failed (check_sparse_solving_real_cases)\n";
     exit(0);
     return;
   }
   x = solver.solve(b);
   if (solver.info() != Success)
   {
     std::cerr << "sparse solver testing: solving failed\n";
     return;
   }

   RealScalar res_error;
   // Compute the norm of the relative error
   if(refX.size() != 0)
     res_error = (refX - x).norm()/refX.norm();
   else
   {
     // Compute the relative residual norm
     res_error = (b - A * x).norm()/b.norm();
   }
   if (res_error > test_precision<Scalar>() ){
     std::cerr << "Test " << g_test_stack.back() << " failed in "EI_PP_MAKE_STRING(__FILE__)
     << " (" << EI_PP_MAKE_STRING(__LINE__) << ")" << std::endl << std::endl;
     abort();
   }

 }
 template<typename Solver, typename DenseMat>
 void check_sparse_determinant(Solver& solver, const typename Solver::MatrixType& A, const DenseMat& dA)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;

   solver.compute(A);
   if (solver.info() != Success)
   {
     std::cerr << "sparse solver testing: factorization failed (check_sparse_determinant)\n";
     return;
   }

   Scalar refDet = dA.determinant();
   VERIFY_IS_APPROX(refDet,solver.determinant());
 }
 template<typename Solver, typename DenseMat>
 void check_sparse_abs_determinant(Solver& solver, const typename Solver::MatrixType& A, const DenseMat& dA)
 {
   using std::abs;
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;

   solver.compute(A);
   if (solver.info() != Success)
   {
     std::cerr << "sparse solver testing: factorization failed (check_sparse_abs_determinant)\n";
     return;
   }

   Scalar refDet = abs(dA.determinant());
   VERIFY_IS_APPROX(refDet,solver.absDeterminant());
 }

 template<typename Solver, typename DenseMat>
 int generate_sparse_spd_problem(Solver& , typename Solver::MatrixType& A, typename Solver::MatrixType& halfA, DenseMat& dA, int maxSize = 300)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

   int size = internal::random<int>(1,maxSize);
   double density = (std::max)(8./(size*size), 0.01);

   Mat M(size, size);
   DenseMatrix dM(size, size);

   initSparse<Scalar>(density, dM, M, ForceNonZeroDiag);

   A = M * M.adjoint();
   dA = dM * dM.adjoint();

   halfA.resize(size,size);
   if(Solver::UpLo==(Lower|Upper))
     halfA = A;
   else
     halfA.template selfadjointView<Solver::UpLo>().rankUpdate(M);

   return size;
 }


 #ifdef TEST_REAL_CASES
 template<typename Scalar>
 inline std::string get_matrixfolder()
 {
   std::string mat_folder = TEST_REAL_CASES;
   if( internal::is_same<Scalar, std::complex<float> >::value || internal::is_same<Scalar, std::complex<double> >::value )
     mat_folder  = mat_folder + static_cast<std::string>("/complex/");
   else
     mat_folder = mat_folder + static_cast<std::string>("/real/");
   return mat_folder;
 }
 #endif

 template<typename Solver> void check_sparse_spd_solving(Solver& solver)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef SparseMatrix<Scalar,ColMajor> SpMat;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
   typedef Matrix<Scalar,Dynamic,1> DenseVector;

   // generate the problem
   Mat A, halfA;
   DenseMatrix dA;
   for (int i = 0; i < g_repeat; i++) {
     int size = generate_sparse_spd_problem(solver, A, halfA, dA);

     // generate the right hand sides
     int rhsCols = internal::random<int>(1,16);
     double density = (std::max)(8./(size*rhsCols), 0.1);
     SpMat B(size,rhsCols);
     DenseVector b = DenseVector::Random(size);
     DenseMatrix dB(size,rhsCols);
     initSparse<Scalar>(density, dB, B, ForceNonZeroDiag);

     check_sparse_solving(solver, A,     b,  dA, b);
     check_sparse_solving(solver, halfA, b,  dA, b);
     check_sparse_solving(solver, A,     dB, dA, dB);
     check_sparse_solving(solver, halfA, dB, dA, dB);
     check_sparse_solving(solver, A,     B,  dA, dB);
     check_sparse_solving(solver, halfA, B,  dA, dB);

     // check only once
     if(i==0)
     {
       b = DenseVector::Zero(size);
       check_sparse_solving(solver, A, b, dA, b);
     }
   }

   // First, get the folder
 #ifdef TEST_REAL_CASES
   if (internal::is_same<Scalar, float>::value
       || internal::is_same<Scalar, std::complex<float> >::value)
     return ;

   std::string mat_folder = get_matrixfolder<Scalar>();
   MatrixMarketIterator<Scalar> it(mat_folder);
   for (; it; ++it)
   {
     if (it.sym() == SPD){
       Mat halfA;
       PermutationMatrix<Dynamic, Dynamic, Index> pnull;
       halfA.template selfadjointView<Solver::UpLo>() = it.matrix().template triangularView<Eigen::Lower>().twistedBy(pnull);

       std::cout<< " ==== SOLVING WITH MATRIX " << it.matname() << " ==== \n";
       check_sparse_solving_real_cases(solver, it.matrix(), it.rhs(), it.refX());
       check_sparse_solving_real_cases(solver, halfA, it.rhs(), it.refX());
     }
   }
 #endif
 }

 template<typename Solver> void check_sparse_spd_determinant(Solver& solver)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

   // generate the problem
   Mat A, halfA;
   DenseMatrix dA;
   generate_sparse_spd_problem(solver, A, halfA, dA, 30);

   for (int i = 0; i < g_repeat; i++) {
     check_sparse_determinant(solver, A,     dA);
     check_sparse_determinant(solver, halfA, dA );
   }
 }

 template<typename Solver, typename DenseMat>
 int generate_sparse_square_problem(Solver&, typename Solver::MatrixType& A, DenseMat& dA, int maxSize = 300)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;

   int size = internal::random<int>(1,maxSize);
   double density = (std::max)(8./(size*size), 0.01);

   A.resize(size,size);
   dA.resize(size,size);

   initSparse<Scalar>(density, dA, A, ForceNonZeroDiag);

   return size;
 }

 template<typename Solver> void check_sparse_square_solving(Solver& solver)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef SparseMatrix<Scalar,ColMajor> SpMat;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
   typedef Matrix<Scalar,Dynamic,1> DenseVector;

   int rhsCols = internal::random<int>(1,16);

   Mat A;
   DenseMatrix dA;
   for (int i = 0; i < g_repeat; i++) {
     int size = generate_sparse_square_problem(solver, A, dA);

     A.makeCompressed();
     DenseVector b = DenseVector::Random(size);
     DenseMatrix dB(size,rhsCols);
     SpMat B(size,rhsCols);
     double density = (std::max)(8./(size*rhsCols), 0.1);
     initSparse<Scalar>(density, dB, B, ForceNonZeroDiag);
     B.makeCompressed();
     check_sparse_solving(solver, A, b,  dA, b);
     check_sparse_solving(solver, A, dB, dA, dB);
     check_sparse_solving(solver, A, B,  dA, dB);

     // check only once
     if(i==0)
     {
       b = DenseVector::Zero(size);
       check_sparse_solving(solver, A, b, dA, b);
     }
   }

   // First, get the folder
 #ifdef TEST_REAL_CASES
   if (internal::is_same<Scalar, float>::value
       || internal::is_same<Scalar, std::complex<float> >::value)
     return ;

   std::string mat_folder = get_matrixfolder<Scalar>();
   MatrixMarketIterator<Scalar> it(mat_folder);
   for (; it; ++it)
   {
     std::cout<< " ==== SOLVING WITH MATRIX " << it.matname() << " ==== \n";
     check_sparse_solving_real_cases(solver, it.matrix(), it.rhs(), it.refX());
   }
 #endif

 }

 template<typename Solver> void check_sparse_square_determinant(Solver& solver)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

   // generate the problem
   Mat A;
   DenseMatrix dA;
   generate_sparse_square_problem(solver, A, dA, 30);
   A.makeCompressed();
   for (int i = 0; i < g_repeat; i++) {
     check_sparse_determinant(solver, A, dA);
   }
 }

 template<typename Solver> void check_sparse_square_abs_determinant(Solver& solver)
 {
   typedef typename Solver::MatrixType Mat;
   typedef typename Mat::Scalar Scalar;
   typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

   // generate the problem
   Mat A;
   DenseMatrix dA;
   generate_sparse_square_problem(solver, A, dA, 30);
   A.makeCompressed();
   for (int i = 0; i < g_repeat; i++) {
     check_sparse_abs_determinant(solver, A, dA);
   }
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2011 Gael Guennebaud <g.gael@free.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 "sparse.h"
	#include <Eigen/SparseCore>

	template<typename Solver, typename Rhs, typename DenseMat, typename DenseRhs>
	void check_sparse_solving(Solver& solver, const typename Solver::MatrixType& A, const Rhs& b, const DenseMat& dA, const DenseRhs& db)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;

	DenseRhs refX = dA.lu().solve(db);
	{
	Rhs x(b.rows(), b.cols());
	Rhs oldb = b;

	solver.compute(A);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: factorization failed (check_sparse_solving)\n";
	exit(0);
	return;
	}
	x = solver.solve(b);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: solving failed\n";
	return;
	}
	VERIFY(oldb.isApprox(b) && "sparse solver testing: the rhs should not be modified!");

	VERIFY(x.isApprox(refX,test_precision<Scalar>()));
	x.setZero();
	// test the analyze/factorize API
	solver.analyzePattern(A);
	solver.factorize(A);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: factorization failed (check_sparse_solving)\n";
	exit(0);
	return;
	}
	x = solver.solve(b);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: solving failed\n";
	return;
	}
	VERIFY(oldb.isApprox(b) && "sparse solver testing: the rhs should not be modified!");

	VERIFY(x.isApprox(refX,test_precision<Scalar>()));
	}

	// test dense Block as the result and rhs:
	{
	DenseRhs x(db.rows(), db.cols());
	DenseRhs oldb(db);
	x.setZero();
	x.block(0,0,x.rows(),x.cols()) = solver.solve(db.block(0,0,db.rows(),db.cols()));
	VERIFY(oldb.isApprox(db) && "sparse solver testing: the rhs should not be modified!");
	VERIFY(x.isApprox(refX,test_precision<Scalar>()));
	}
	}

	template<typename Solver, typename Rhs>
	void check_sparse_solving_real_cases(Solver& solver, const typename Solver::MatrixType& A, const Rhs& b, const Rhs& refX)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef typename Mat::RealScalar RealScalar;

	Rhs x(b.rows(), b.cols());

	solver.compute(A);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: factorization failed (check_sparse_solving_real_cases)\n";
	exit(0);
	return;
	}
	x = solver.solve(b);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: solving failed\n";
	return;
	}

	RealScalar res_error;
	// Compute the norm of the relative error
	if(refX.size() != 0)
	res_error = (refX - x).norm()/refX.norm();
	else
	{
	// Compute the relative residual norm
	res_error = (b - A * x).norm()/b.norm();
	}
	if (res_error > test_precision<Scalar>() ){
	std::cerr << "Test " << g_test_stack.back() << " failed in "EI_PP_MAKE_STRING(__FILE__)
	<< " (" << EI_PP_MAKE_STRING(__LINE__) << ")" << std::endl << std::endl;
	abort();
	}

	}
	template<typename Solver, typename DenseMat>
	void check_sparse_determinant(Solver& solver, const typename Solver::MatrixType& A, const DenseMat& dA)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;

	solver.compute(A);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: factorization failed (check_sparse_determinant)\n";
	return;
	}

	Scalar refDet = dA.determinant();
	VERIFY_IS_APPROX(refDet,solver.determinant());
	}
	template<typename Solver, typename DenseMat>
	void check_sparse_abs_determinant(Solver& solver, const typename Solver::MatrixType& A, const DenseMat& dA)
	{
	using std::abs;
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;

	solver.compute(A);
	if (solver.info() != Success)
	{
	std::cerr << "sparse solver testing: factorization failed (check_sparse_abs_determinant)\n";
	return;
	}

	Scalar refDet = abs(dA.determinant());
	VERIFY_IS_APPROX(refDet,solver.absDeterminant());
	}

	template<typename Solver, typename DenseMat>
	int generate_sparse_spd_problem(Solver& , typename Solver::MatrixType& A, typename Solver::MatrixType& halfA, DenseMat& dA, int maxSize = 300)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

	int size = internal::random<int>(1,maxSize);
	double density = (std::max)(8./(size*size), 0.01);

	Mat M(size, size);
	DenseMatrix dM(size, size);

	initSparse<Scalar>(density, dM, M, ForceNonZeroDiag);

	A = M * M.adjoint();
	dA = dM * dM.adjoint();

	halfA.resize(size,size);
	if(Solver::UpLo==(Lower\|Upper))
	halfA = A;
	else
	halfA.template selfadjointView<Solver::UpLo>().rankUpdate(M);

	return size;
	}


	#ifdef TEST_REAL_CASES
	template<typename Scalar>
	inline std::string get_matrixfolder()
	{
	std::string mat_folder = TEST_REAL_CASES;
	if( internal::is_same<Scalar, std::complex<float> >::value \|\| internal::is_same<Scalar, std::complex<double> >::value )
	mat_folder = mat_folder + static_cast<std::string>("/complex/");
	else
	mat_folder = mat_folder + static_cast<std::string>("/real/");
	return mat_folder;
	}
	#endif

	template<typename Solver> void check_sparse_spd_solving(Solver& solver)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef SparseMatrix<Scalar,ColMajor> SpMat;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
	typedef Matrix<Scalar,Dynamic,1> DenseVector;

	// generate the problem
	Mat A, halfA;
	DenseMatrix dA;
	for (int i = 0; i < g_repeat; i++) {
	int size = generate_sparse_spd_problem(solver, A, halfA, dA);

	// generate the right hand sides
	int rhsCols = internal::random<int>(1,16);
	double density = (std::max)(8./(size*rhsCols), 0.1);
	SpMat B(size,rhsCols);
	DenseVector b = DenseVector::Random(size);
	DenseMatrix dB(size,rhsCols);
	initSparse<Scalar>(density, dB, B, ForceNonZeroDiag);

	check_sparse_solving(solver, A, b, dA, b);
	check_sparse_solving(solver, halfA, b, dA, b);
	check_sparse_solving(solver, A, dB, dA, dB);
	check_sparse_solving(solver, halfA, dB, dA, dB);
	check_sparse_solving(solver, A, B, dA, dB);
	check_sparse_solving(solver, halfA, B, dA, dB);

	// check only once
	if(i==0)
	{
	b = DenseVector::Zero(size);
	check_sparse_solving(solver, A, b, dA, b);
	}
	}

	// First, get the folder
	#ifdef TEST_REAL_CASES
	if (internal::is_same<Scalar, float>::value
	\|\| internal::is_same<Scalar, std::complex<float> >::value)
	return ;

	std::string mat_folder = get_matrixfolder<Scalar>();
	MatrixMarketIterator<Scalar> it(mat_folder);
	for (; it; ++it)
	{
	if (it.sym() == SPD){
	Mat halfA;
	PermutationMatrix<Dynamic, Dynamic, Index> pnull;
	halfA.template selfadjointView<Solver::UpLo>() = it.matrix().template triangularView<Eigen::Lower>().twistedBy(pnull);

	std::cout<< " ==== SOLVING WITH MATRIX " << it.matname() << " ==== \n";
	check_sparse_solving_real_cases(solver, it.matrix(), it.rhs(), it.refX());
	check_sparse_solving_real_cases(solver, halfA, it.rhs(), it.refX());
	}
	}
	#endif
	}

	template<typename Solver> void check_sparse_spd_determinant(Solver& solver)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

	// generate the problem
	Mat A, halfA;
	DenseMatrix dA;
	generate_sparse_spd_problem(solver, A, halfA, dA, 30);

	for (int i = 0; i < g_repeat; i++) {
	check_sparse_determinant(solver, A, dA);
	check_sparse_determinant(solver, halfA, dA );
	}
	}

	template<typename Solver, typename DenseMat>
	int generate_sparse_square_problem(Solver&, typename Solver::MatrixType& A, DenseMat& dA, int maxSize = 300)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;

	int size = internal::random<int>(1,maxSize);
	double density = (std::max)(8./(size*size), 0.01);

	A.resize(size,size);
	dA.resize(size,size);

	initSparse<Scalar>(density, dA, A, ForceNonZeroDiag);

	return size;
	}

	template<typename Solver> void check_sparse_square_solving(Solver& solver)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef SparseMatrix<Scalar,ColMajor> SpMat;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
	typedef Matrix<Scalar,Dynamic,1> DenseVector;

	int rhsCols = internal::random<int>(1,16);

	Mat A;
	DenseMatrix dA;
	for (int i = 0; i < g_repeat; i++) {
	int size = generate_sparse_square_problem(solver, A, dA);

	A.makeCompressed();
	DenseVector b = DenseVector::Random(size);
	DenseMatrix dB(size,rhsCols);
	SpMat B(size,rhsCols);
	double density = (std::max)(8./(size*rhsCols), 0.1);
	initSparse<Scalar>(density, dB, B, ForceNonZeroDiag);
	B.makeCompressed();
	check_sparse_solving(solver, A, b, dA, b);
	check_sparse_solving(solver, A, dB, dA, dB);
	check_sparse_solving(solver, A, B, dA, dB);

	// check only once
	if(i==0)
	{
	b = DenseVector::Zero(size);
	check_sparse_solving(solver, A, b, dA, b);
	}
	}

	// First, get the folder
	#ifdef TEST_REAL_CASES
	if (internal::is_same<Scalar, float>::value
	\|\| internal::is_same<Scalar, std::complex<float> >::value)
	return ;

	std::string mat_folder = get_matrixfolder<Scalar>();
	MatrixMarketIterator<Scalar> it(mat_folder);
	for (; it; ++it)
	{
	std::cout<< " ==== SOLVING WITH MATRIX " << it.matname() << " ==== \n";
	check_sparse_solving_real_cases(solver, it.matrix(), it.rhs(), it.refX());
	}
	#endif

	}

	template<typename Solver> void check_sparse_square_determinant(Solver& solver)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

	// generate the problem
	Mat A;
	DenseMatrix dA;
	generate_sparse_square_problem(solver, A, dA, 30);
	A.makeCompressed();
	for (int i = 0; i < g_repeat; i++) {
	check_sparse_determinant(solver, A, dA);
	}
	}

	template<typename Solver> void check_sparse_square_abs_determinant(Solver& solver)
	{
	typedef typename Solver::MatrixType Mat;
	typedef typename Mat::Scalar Scalar;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;

	// generate the problem
	Mat A;
	DenseMatrix dA;
	generate_sparse_square_problem(solver, A, dA, 30);
	A.makeCompressed();
	for (int i = 0; i < g_repeat; i++) {
	check_sparse_abs_determinant(solver, A, dA);
	}
	}