test/svd_common.h - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
 // Copyright (C) 2009 Benoit Jacob <jacob.benoit.1@gmail.com>
 //
 // 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/.

 #ifndef SVD_DEFAULT
 #error a macro SVD_DEFAULT(MatrixType) must be defined prior to including svd_common.h
 #endif

 #ifndef SVD_FOR_MIN_NORM
 #error a macro SVD_FOR_MIN_NORM(MatrixType) must be defined prior to including svd_common.h
 #endif

 #include "svd_fill.h"

 // Check that the matrix m is properly reconstructed and that the U and V factors are unitary
 // The SVD must have already been computed.
 template<typename SvdType, typename MatrixType>
 void svd_check_full(const MatrixType& m, const SvdType& svd)
 {
   typedef typename MatrixType::Index Index;
   Index rows = m.rows();
   Index cols = m.cols();

   enum {
     RowsAtCompileTime = MatrixType::RowsAtCompileTime,
     ColsAtCompileTime = MatrixType::ColsAtCompileTime
   };

   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::RealScalar RealScalar;
   typedef Matrix<Scalar, RowsAtCompileTime, RowsAtCompileTime> MatrixUType;
   typedef Matrix<Scalar, ColsAtCompileTime, ColsAtCompileTime> MatrixVType;

   MatrixType sigma = MatrixType::Zero(rows,cols);
   sigma.diagonal() = svd.singularValues().template cast<Scalar>();
   MatrixUType u = svd.matrixU();
   MatrixVType v = svd.matrixV();
   RealScalar scaling = m.cwiseAbs().maxCoeff();
   if(scaling<(std::numeric_limits<RealScalar>::min)())
   {
     VERIFY(sigma.cwiseAbs().maxCoeff() <= (std::numeric_limits<RealScalar>::min)());
   }
   else
   {
     VERIFY_IS_APPROX(m/scaling, u * (sigma/scaling) * v.adjoint());
   }
   VERIFY_IS_UNITARY(u);
   VERIFY_IS_UNITARY(v);
 }

 // Compare partial SVD defined by computationOptions to a full SVD referenceSvd
 template<typename SvdType, typename MatrixType>
 void svd_compare_to_full(const MatrixType& m,
                          unsigned int computationOptions,
                          const SvdType& referenceSvd)
 {
   typedef typename MatrixType::RealScalar RealScalar;
   Index rows = m.rows();
   Index cols = m.cols();
   Index diagSize = (std::min)(rows, cols);
   RealScalar prec = test_precision<RealScalar>();

   SvdType svd(m, computationOptions);

   VERIFY_IS_APPROX(svd.singularValues(), referenceSvd.singularValues());

   if(computationOptions & (ComputeFullV|ComputeThinV))
   {
     VERIFY( (svd.matrixV().adjoint()*svd.matrixV()).isIdentity(prec) );
     VERIFY_IS_APPROX( svd.matrixV().leftCols(diagSize) * svd.singularValues().asDiagonal() * svd.matrixV().leftCols(diagSize).adjoint(),
                       referenceSvd.matrixV().leftCols(diagSize) * referenceSvd.singularValues().asDiagonal() * referenceSvd.matrixV().leftCols(diagSize).adjoint());
   }

   if(computationOptions & (ComputeFullU|ComputeThinU))
   {
     VERIFY( (svd.matrixU().adjoint()*svd.matrixU()).isIdentity(prec) );
     VERIFY_IS_APPROX( svd.matrixU().leftCols(diagSize) * svd.singularValues().cwiseAbs2().asDiagonal() * svd.matrixU().leftCols(diagSize).adjoint(),
                       referenceSvd.matrixU().leftCols(diagSize) * referenceSvd.singularValues().cwiseAbs2().asDiagonal() * referenceSvd.matrixU().leftCols(diagSize).adjoint());
   }

   // The following checks are not critical.
   // For instance, with Dived&Conquer SVD, if only the factor 'V' is computedt then different matrix-matrix product implementation will be used
   // and the resulting 'V' factor might be significantly different when the SVD decomposition is not unique, especially with single precision float.
   ++g_test_level;
   if(computationOptions & ComputeFullU)  VERIFY_IS_APPROX(svd.matrixU(), referenceSvd.matrixU());
   if(computationOptions & ComputeThinU)  VERIFY_IS_APPROX(svd.matrixU(), referenceSvd.matrixU().leftCols(diagSize));
   if(computationOptions & ComputeFullV)  VERIFY_IS_APPROX(svd.matrixV().cwiseAbs(), referenceSvd.matrixV().cwiseAbs());
   if(computationOptions & ComputeThinV)  VERIFY_IS_APPROX(svd.matrixV(), referenceSvd.matrixV().leftCols(diagSize));
   --g_test_level;
 }

 //
 template<typename SvdType, typename MatrixType>
 void svd_least_square(const MatrixType& m, unsigned int computationOptions)
 {
   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::RealScalar RealScalar;
   typedef typename MatrixType::Index Index;
   Index rows = m.rows();
   Index cols = m.cols();

   enum {
     RowsAtCompileTime = MatrixType::RowsAtCompileTime,
     ColsAtCompileTime = MatrixType::ColsAtCompileTime
   };

   typedef Matrix<Scalar, RowsAtCompileTime, Dynamic> RhsType;
   typedef Matrix<Scalar, ColsAtCompileTime, Dynamic> SolutionType;

   RhsType rhs = RhsType::Random(rows, internal::random<Index>(1, cols));
   SvdType svd(m, computationOptions);

        if(internal::is_same<RealScalar,double>::value) svd.setThreshold(1e-8);
   else if(internal::is_same<RealScalar,float>::value)  svd.setThreshold(2e-4);

   SolutionType x = svd.solve(rhs);

   RealScalar residual = (m*x-rhs).norm();
   RealScalar rhs_norm = rhs.norm();
   if(!test_isMuchSmallerThan(residual,rhs.norm()))
   {
     // ^^^ If the residual is very small, then we have an exact solution, so we are already good.

     // evaluate normal equation which works also for least-squares solutions
     if(internal::is_same<RealScalar,double>::value || svd.rank()==m.diagonal().size())
     {
       using std::sqrt;
       // This test is not stable with single precision.
       // This is probably because squaring m signicantly affects the precision.
       if(internal::is_same<RealScalar,float>::value) ++g_test_level;

       VERIFY_IS_APPROX(m.adjoint()*(m*x),m.adjoint()*rhs);

       if(internal::is_same<RealScalar,float>::value) --g_test_level;
     }

     // Check that there is no significantly better solution in the neighborhood of x
     for(Index k=0;k<x.rows();++k)
     {
       using std::abs;

       SolutionType y(x);
       y.row(k) = (RealScalar(1)+2*NumTraits<RealScalar>::epsilon())*x.row(k);
       RealScalar residual_y = (m*y-rhs).norm();
       VERIFY( test_isMuchSmallerThan(abs(residual_y-residual), rhs_norm) || residual < residual_y );
       if(internal::is_same<RealScalar,float>::value) ++g_test_level;
       VERIFY( test_isApprox(residual_y,residual) || residual < residual_y );
       if(internal::is_same<RealScalar,float>::value) --g_test_level;

       y.row(k) = (RealScalar(1)-2*NumTraits<RealScalar>::epsilon())*x.row(k);
       residual_y = (m*y-rhs).norm();
       VERIFY( test_isMuchSmallerThan(abs(residual_y-residual), rhs_norm) || residual < residual_y );
       if(internal::is_same<RealScalar,float>::value) ++g_test_level;
       VERIFY( test_isApprox(residual_y,residual) || residual < residual_y );
       if(internal::is_same<RealScalar,float>::value) --g_test_level;
     }
   }
 }

 // check minimal norm solutions, the inoput matrix m is only used to recover problem size
 template<typename MatrixType>
 void svd_min_norm(const MatrixType& m, unsigned int computationOptions)
 {
   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::Index Index;
   Index cols = m.cols();

   enum {
     ColsAtCompileTime = MatrixType::ColsAtCompileTime
   };

   typedef Matrix<Scalar, ColsAtCompileTime, Dynamic> SolutionType;

   // generate a full-rank m x n problem with m<n
   enum {
     RankAtCompileTime2 = ColsAtCompileTime==Dynamic ? Dynamic : (ColsAtCompileTime)/2+1,
     RowsAtCompileTime3 = ColsAtCompileTime==Dynamic ? Dynamic : ColsAtCompileTime+1
   };
   typedef Matrix<Scalar, RankAtCompileTime2, ColsAtCompileTime> MatrixType2;
   typedef Matrix<Scalar, RankAtCompileTime2, 1> RhsType2;
   typedef Matrix<Scalar, ColsAtCompileTime, RankAtCompileTime2> MatrixType2T;
   Index rank = RankAtCompileTime2==Dynamic ? internal::random<Index>(1,cols) : Index(RankAtCompileTime2);
   MatrixType2 m2(rank,cols);
   int guard = 0;
   do {
     m2.setRandom();
   } while(SVD_FOR_MIN_NORM(MatrixType2)(m2).setThreshold(test_precision<Scalar>()).rank()!=rank && (++guard)<10);
   VERIFY(guard<10);

   RhsType2 rhs2 = RhsType2::Random(rank);
   // use QR to find a reference minimal norm solution
   HouseholderQR<MatrixType2T> qr(m2.adjoint());
   Matrix<Scalar,Dynamic,1> tmp = qr.matrixQR().topLeftCorner(rank,rank).template triangularView<Upper>().adjoint().solve(rhs2);
   tmp.conservativeResize(cols);
   tmp.tail(cols-rank).setZero();
   SolutionType x21 = qr.householderQ() * tmp;
   // now check with SVD
   SVD_FOR_MIN_NORM(MatrixType2) svd2(m2, computationOptions);
   SolutionType x22 = svd2.solve(rhs2);
   VERIFY_IS_APPROX(m2*x21, rhs2);
   VERIFY_IS_APPROX(m2*x22, rhs2);
   VERIFY_IS_APPROX(x21, x22);

   // Now check with a rank deficient matrix
   typedef Matrix<Scalar, RowsAtCompileTime3, ColsAtCompileTime> MatrixType3;
   typedef Matrix<Scalar, RowsAtCompileTime3, 1> RhsType3;
   Index rows3 = RowsAtCompileTime3==Dynamic ? internal::random<Index>(rank+1,2*cols) : Index(RowsAtCompileTime3);
   Matrix<Scalar,RowsAtCompileTime3,Dynamic> C = Matrix<Scalar,RowsAtCompileTime3,Dynamic>::Random(rows3,rank);
   MatrixType3 m3 = C * m2;
   RhsType3 rhs3 = C * rhs2;
   SVD_FOR_MIN_NORM(MatrixType3) svd3(m3, computationOptions);
   SolutionType x3 = svd3.solve(rhs3);
   VERIFY_IS_APPROX(m3*x3, rhs3);
   VERIFY_IS_APPROX(m3*x21, rhs3);
   VERIFY_IS_APPROX(m2*x3, rhs2);
   VERIFY_IS_APPROX(x21, x3);
 }

 // Check full, compare_to_full, least_square, and min_norm for all possible compute-options
 template<typename SvdType, typename MatrixType>
 void svd_test_all_computation_options(const MatrixType& m, bool full_only)
 {
 //   if (QRPreconditioner == NoQRPreconditioner && m.rows() != m.cols())
 //     return;
   SvdType fullSvd(m, ComputeFullU|ComputeFullV);
   CALL_SUBTEST(( svd_check_full(m, fullSvd) ));
   CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeFullU | ComputeFullV) ));
   CALL_SUBTEST(( svd_min_norm(m, ComputeFullU | ComputeFullV) ));

   #if defined __INTEL_COMPILER
   // remark #111: statement is unreachable
   #pragma warning disable 111
   #endif
   if(full_only)
     return;

   CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullU, fullSvd) ));
   CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullV, fullSvd) ));
   CALL_SUBTEST(( svd_compare_to_full(m, 0, fullSvd) ));

   if (MatrixType::ColsAtCompileTime == Dynamic) {
     // thin U/V are only available with dynamic number of columns
     CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullU|ComputeThinV, fullSvd) ));
     CALL_SUBTEST(( svd_compare_to_full(m,              ComputeThinV, fullSvd) ));
     CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU|ComputeFullV, fullSvd) ));
     CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU             , fullSvd) ));
     CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU|ComputeThinV, fullSvd) ));

     CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeFullU | ComputeThinV) ));
     CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeThinU | ComputeFullV) ));
     CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeThinU | ComputeThinV) ));

     CALL_SUBTEST(( svd_min_norm(m, ComputeFullU | ComputeThinV) ));
     CALL_SUBTEST(( svd_min_norm(m, ComputeThinU | ComputeFullV) ));
     CALL_SUBTEST(( svd_min_norm(m, ComputeThinU | ComputeThinV) ));

     // test reconstruction
     typedef typename MatrixType::Index Index;
     Index diagSize = (std::min)(m.rows(), m.cols());
     SvdType svd(m, ComputeThinU | ComputeThinV);
     VERIFY_IS_APPROX(m, svd.matrixU().leftCols(diagSize) * svd.singularValues().asDiagonal() * svd.matrixV().leftCols(diagSize).adjoint());
   }
 }


 // work around stupid msvc error when constructing at compile time an expression that involves
 // a division by zero, even if the numeric type has floating point
 template<typename Scalar>
 EIGEN_DONT_INLINE Scalar zero() { return Scalar(0); }

 // workaround aggressive optimization in ICC
 template<typename T> EIGEN_DONT_INLINE  T sub(T a, T b) { return a - b; }

 // all this function does is verify we don't iterate infinitely on nan/inf values
 template<typename SvdType, typename MatrixType>
 void svd_inf_nan()
 {
   SvdType svd;
   typedef typename MatrixType::Scalar Scalar;
   Scalar some_inf = Scalar(1) / zero<Scalar>();
   VERIFY(sub(some_inf, some_inf) != sub(some_inf, some_inf));
   svd.compute(MatrixType::Constant(10,10,some_inf), ComputeFullU | ComputeFullV);

   Scalar nan = std::numeric_limits<Scalar>::quiet_NaN();
   VERIFY(nan != nan);
   svd.compute(MatrixType::Constant(10,10,nan), ComputeFullU | ComputeFullV);

   MatrixType m = MatrixType::Zero(10,10);
   m(internal::random<int>(0,9), internal::random<int>(0,9)) = some_inf;
   svd.compute(m, ComputeFullU | ComputeFullV);

   m = MatrixType::Zero(10,10);
   m(internal::random<int>(0,9), internal::random<int>(0,9)) = nan;
   svd.compute(m, ComputeFullU | ComputeFullV);

   // regression test for bug 791
   m.resize(3,3);
   m << 0,    2*NumTraits<Scalar>::epsilon(),  0.5,
        0,   -0.5,                             0,
        nan,  0,                               0;
   svd.compute(m, ComputeFullU | ComputeFullV);

   m.resize(4,4);
   m <<  1, 0, 0, 0,
         0, 3, 1, 2e-308,
         1, 0, 1, nan,
         0, nan, nan, 0;
   svd.compute(m, ComputeFullU | ComputeFullV);
 }

 // Regression test for bug 286: JacobiSVD loops indefinitely with some
 // matrices containing denormal numbers.
 template<typename>
 void svd_underoverflow()
 {
 #if defined __INTEL_COMPILER
 // shut up warning #239: floating point underflow
 #pragma warning push
 #pragma warning disable 239
 #endif
   Matrix2d M;
   M << -7.90884e-313, -4.94e-324,
                  0, 5.60844e-313;
   SVD_DEFAULT(Matrix2d) svd;
   svd.compute(M,ComputeFullU|ComputeFullV);
   CALL_SUBTEST( svd_check_full(M,svd) );

   // Check all 2x2 matrices made with the following coefficients:
   VectorXd value_set(9);
   value_set << 0, 1, -1, 5.60844e-313, -5.60844e-313, 4.94e-324, -4.94e-324, -4.94e-223, 4.94e-223;
   Array4i id(0,0,0,0);
   int k = 0;
   do
   {
     M << value_set(id(0)), value_set(id(1)), value_set(id(2)), value_set(id(3));
     svd.compute(M,ComputeFullU|ComputeFullV);
     CALL_SUBTEST( svd_check_full(M,svd) );

     id(k)++;
     if(id(k)>=value_set.size())
     {
       while(k<3 && id(k)>=value_set.size()) id(++k)++;
       id.head(k).setZero();
       k=0;
     }

   } while((id<int(value_set.size())).all());

 #if defined __INTEL_COMPILER
 #pragma warning pop
 #endif

   // Check for overflow:
   Matrix3d M3;
   M3 << 4.4331978442502944e+307, -5.8585363752028680e+307,  6.4527017443412964e+307,
         3.7841695601406358e+307,  2.4331702789740617e+306, -3.5235707140272905e+307,
        -8.7190887618028355e+307, -7.3453213709232193e+307, -2.4367363684472105e+307;

   SVD_DEFAULT(Matrix3d) svd3;
   svd3.compute(M3,ComputeFullU|ComputeFullV); // just check we don't loop indefinitely
   CALL_SUBTEST( svd_check_full(M3,svd3) );
 }

 // void jacobisvd(const MatrixType& a = MatrixType(), bool pickrandom = true)

 template<typename MatrixType>
 void svd_all_trivial_2x2( void (*cb)(const MatrixType&,bool) )
 {
   MatrixType M;
   VectorXd value_set(3);
   value_set << 0, 1, -1;
   Array4i id(0,0,0,0);
   int k = 0;
   do
   {
     M << value_set(id(0)), value_set(id(1)), value_set(id(2)), value_set(id(3));

     cb(M,false);

     id(k)++;
     if(id(k)>=value_set.size())
     {
       while(k<3 && id(k)>=value_set.size()) id(++k)++;
       id.head(k).setZero();
       k=0;
     }

   } while((id<int(value_set.size())).all());
 }

 template<typename>
 void svd_preallocate()
 {
   Vector3f v(3.f, 2.f, 1.f);
   MatrixXf m = v.asDiagonal();

   internal::set_is_malloc_allowed(false);
   VERIFY_RAISES_ASSERT(VectorXf tmp(10);)
   SVD_DEFAULT(MatrixXf) svd;
   internal::set_is_malloc_allowed(true);
   svd.compute(m);
   VERIFY_IS_APPROX(svd.singularValues(), v);

   SVD_DEFAULT(MatrixXf) svd2(3,3);
   internal::set_is_malloc_allowed(false);
   svd2.compute(m);
   internal::set_is_malloc_allowed(true);
   VERIFY_IS_APPROX(svd2.singularValues(), v);
   VERIFY_RAISES_ASSERT(svd2.matrixU());
   VERIFY_RAISES_ASSERT(svd2.matrixV());
   svd2.compute(m, ComputeFullU | ComputeFullV);
   VERIFY_IS_APPROX(svd2.matrixU(), Matrix3f::Identity());
   VERIFY_IS_APPROX(svd2.matrixV(), Matrix3f::Identity());
   internal::set_is_malloc_allowed(false);
   svd2.compute(m);
   internal::set_is_malloc_allowed(true);

   SVD_DEFAULT(MatrixXf) svd3(3,3,ComputeFullU|ComputeFullV);
   internal::set_is_malloc_allowed(false);
   svd2.compute(m);
   internal::set_is_malloc_allowed(true);
   VERIFY_IS_APPROX(svd2.singularValues(), v);
   VERIFY_IS_APPROX(svd2.matrixU(), Matrix3f::Identity());
   VERIFY_IS_APPROX(svd2.matrixV(), Matrix3f::Identity());
   internal::set_is_malloc_allowed(false);
   svd2.compute(m, ComputeFullU|ComputeFullV);
   internal::set_is_malloc_allowed(true);
 }

 template<typename SvdType,typename MatrixType>
 void svd_verify_assert(const MatrixType& m)
 {
   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::Index Index;
   Index rows = m.rows();
   Index cols = m.cols();

   enum {
     RowsAtCompileTime = MatrixType::RowsAtCompileTime,
     ColsAtCompileTime = MatrixType::ColsAtCompileTime
   };

   typedef Matrix<Scalar, RowsAtCompileTime, 1> RhsType;
   RhsType rhs(rows);
   SvdType svd;
   VERIFY_RAISES_ASSERT(svd.matrixU())
   VERIFY_RAISES_ASSERT(svd.singularValues())
   VERIFY_RAISES_ASSERT(svd.matrixV())
   VERIFY_RAISES_ASSERT(svd.solve(rhs))
   MatrixType a = MatrixType::Zero(rows, cols);
   a.setZero();
   svd.compute(a, 0);
   VERIFY_RAISES_ASSERT(svd.matrixU())
   VERIFY_RAISES_ASSERT(svd.matrixV())
   svd.singularValues();
   VERIFY_RAISES_ASSERT(svd.solve(rhs))

   if (ColsAtCompileTime == Dynamic)
   {
     svd.compute(a, ComputeThinU);
     svd.matrixU();
     VERIFY_RAISES_ASSERT(svd.matrixV())
     VERIFY_RAISES_ASSERT(svd.solve(rhs))
     svd.compute(a, ComputeThinV);
     svd.matrixV();
     VERIFY_RAISES_ASSERT(svd.matrixU())
     VERIFY_RAISES_ASSERT(svd.solve(rhs))
   }
   else
   {
     VERIFY_RAISES_ASSERT(svd.compute(a, ComputeThinU))
     VERIFY_RAISES_ASSERT(svd.compute(a, ComputeThinV))
   }
 }

 #undef SVD_DEFAULT
 #undef SVD_FOR_MIN_NORM
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
	// Copyright (C) 2009 Benoit Jacob <jacob.benoit.1@gmail.com>
	//
	// 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/.

	#ifndef SVD_DEFAULT
	#error a macro SVD_DEFAULT(MatrixType) must be defined prior to including svd_common.h
	#endif

	#ifndef SVD_FOR_MIN_NORM
	#error a macro SVD_FOR_MIN_NORM(MatrixType) must be defined prior to including svd_common.h
	#endif

	#include "svd_fill.h"

	// Check that the matrix m is properly reconstructed and that the U and V factors are unitary
	// The SVD must have already been computed.
	template<typename SvdType, typename MatrixType>
	void svd_check_full(const MatrixType& m, const SvdType& svd)
	{
	typedef typename MatrixType::Index Index;
	Index rows = m.rows();
	Index cols = m.cols();

	enum {
	RowsAtCompileTime = MatrixType::RowsAtCompileTime,
	ColsAtCompileTime = MatrixType::ColsAtCompileTime
	};

	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::RealScalar RealScalar;
	typedef Matrix<Scalar, RowsAtCompileTime, RowsAtCompileTime> MatrixUType;
	typedef Matrix<Scalar, ColsAtCompileTime, ColsAtCompileTime> MatrixVType;

	MatrixType sigma = MatrixType::Zero(rows,cols);
	sigma.diagonal() = svd.singularValues().template cast<Scalar>();
	MatrixUType u = svd.matrixU();
	MatrixVType v = svd.matrixV();
	RealScalar scaling = m.cwiseAbs().maxCoeff();
	if(scaling<(std::numeric_limits<RealScalar>::min)())
	{
	VERIFY(sigma.cwiseAbs().maxCoeff() <= (std::numeric_limits<RealScalar>::min)());
	}
	else
	{
	VERIFY_IS_APPROX(m/scaling, u * (sigma/scaling) * v.adjoint());
	}
	VERIFY_IS_UNITARY(u);
	VERIFY_IS_UNITARY(v);
	}

	// Compare partial SVD defined by computationOptions to a full SVD referenceSvd
	template<typename SvdType, typename MatrixType>
	void svd_compare_to_full(const MatrixType& m,
	unsigned int computationOptions,
	const SvdType& referenceSvd)
	{
	typedef typename MatrixType::RealScalar RealScalar;
	Index rows = m.rows();
	Index cols = m.cols();
	Index diagSize = (std::min)(rows, cols);
	RealScalar prec = test_precision<RealScalar>();

	SvdType svd(m, computationOptions);

	VERIFY_IS_APPROX(svd.singularValues(), referenceSvd.singularValues());

	if(computationOptions & (ComputeFullV\|ComputeThinV))
	{
	VERIFY( (svd.matrixV().adjoint()*svd.matrixV()).isIdentity(prec) );
	VERIFY_IS_APPROX( svd.matrixV().leftCols(diagSize) * svd.singularValues().asDiagonal() * svd.matrixV().leftCols(diagSize).adjoint(),
	referenceSvd.matrixV().leftCols(diagSize) * referenceSvd.singularValues().asDiagonal() * referenceSvd.matrixV().leftCols(diagSize).adjoint());
	}

	if(computationOptions & (ComputeFullU\|ComputeThinU))
	{
	VERIFY( (svd.matrixU().adjoint()*svd.matrixU()).isIdentity(prec) );
	VERIFY_IS_APPROX( svd.matrixU().leftCols(diagSize) * svd.singularValues().cwiseAbs2().asDiagonal() * svd.matrixU().leftCols(diagSize).adjoint(),
	referenceSvd.matrixU().leftCols(diagSize) * referenceSvd.singularValues().cwiseAbs2().asDiagonal() * referenceSvd.matrixU().leftCols(diagSize).adjoint());
	}

	// The following checks are not critical.
	// For instance, with Dived&Conquer SVD, if only the factor 'V' is computedt then different matrix-matrix product implementation will be used
	// and the resulting 'V' factor might be significantly different when the SVD decomposition is not unique, especially with single precision float.
	++g_test_level;
	if(computationOptions & ComputeFullU) VERIFY_IS_APPROX(svd.matrixU(), referenceSvd.matrixU());
	if(computationOptions & ComputeThinU) VERIFY_IS_APPROX(svd.matrixU(), referenceSvd.matrixU().leftCols(diagSize));
	if(computationOptions & ComputeFullV) VERIFY_IS_APPROX(svd.matrixV().cwiseAbs(), referenceSvd.matrixV().cwiseAbs());
	if(computationOptions & ComputeThinV) VERIFY_IS_APPROX(svd.matrixV(), referenceSvd.matrixV().leftCols(diagSize));
	--g_test_level;
	}

	//
	template<typename SvdType, typename MatrixType>
	void svd_least_square(const MatrixType& m, unsigned int computationOptions)
	{
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::RealScalar RealScalar;
	typedef typename MatrixType::Index Index;
	Index rows = m.rows();
	Index cols = m.cols();

	enum {
	RowsAtCompileTime = MatrixType::RowsAtCompileTime,
	ColsAtCompileTime = MatrixType::ColsAtCompileTime
	};

	typedef Matrix<Scalar, RowsAtCompileTime, Dynamic> RhsType;
	typedef Matrix<Scalar, ColsAtCompileTime, Dynamic> SolutionType;

	RhsType rhs = RhsType::Random(rows, internal::random<Index>(1, cols));
	SvdType svd(m, computationOptions);

	if(internal::is_same<RealScalar,double>::value) svd.setThreshold(1e-8);
	else if(internal::is_same<RealScalar,float>::value) svd.setThreshold(2e-4);

	SolutionType x = svd.solve(rhs);

	RealScalar residual = (m*x-rhs).norm();
	RealScalar rhs_norm = rhs.norm();
	if(!test_isMuchSmallerThan(residual,rhs.norm()))
	{
	// ^^^ If the residual is very small, then we have an exact solution, so we are already good.

	// evaluate normal equation which works also for least-squares solutions
	if(internal::is_same<RealScalar,double>::value \|\| svd.rank()==m.diagonal().size())
	{
	using std::sqrt;
	// This test is not stable with single precision.
	// This is probably because squaring m signicantly affects the precision.
	if(internal::is_same<RealScalar,float>::value) ++g_test_level;

	VERIFY_IS_APPROX(m.adjoint()(mx),m.adjoint()*rhs);

	if(internal::is_same<RealScalar,float>::value) --g_test_level;
	}

	// Check that there is no significantly better solution in the neighborhood of x
	for(Index k=0;k<x.rows();++k)
	{
	using std::abs;

	SolutionType y(x);
	y.row(k) = (RealScalar(1)+2NumTraits<RealScalar>::epsilon())x.row(k);
	RealScalar residual_y = (m*y-rhs).norm();
	VERIFY( test_isMuchSmallerThan(abs(residual_y-residual), rhs_norm) \|\| residual < residual_y );
	if(internal::is_same<RealScalar,float>::value) ++g_test_level;
	VERIFY( test_isApprox(residual_y,residual) \|\| residual < residual_y );
	if(internal::is_same<RealScalar,float>::value) --g_test_level;

	y.row(k) = (RealScalar(1)-2NumTraits<RealScalar>::epsilon())x.row(k);
	residual_y = (m*y-rhs).norm();
	VERIFY( test_isMuchSmallerThan(abs(residual_y-residual), rhs_norm) \|\| residual < residual_y );
	if(internal::is_same<RealScalar,float>::value) ++g_test_level;
	VERIFY( test_isApprox(residual_y,residual) \|\| residual < residual_y );
	if(internal::is_same<RealScalar,float>::value) --g_test_level;
	}
	}
	}

	// check minimal norm solutions, the inoput matrix m is only used to recover problem size
	template<typename MatrixType>
	void svd_min_norm(const MatrixType& m, unsigned int computationOptions)
	{
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::Index Index;
	Index cols = m.cols();

	enum {
	ColsAtCompileTime = MatrixType::ColsAtCompileTime
	};

	typedef Matrix<Scalar, ColsAtCompileTime, Dynamic> SolutionType;

	// generate a full-rank m x n problem with m<n
	enum {
	RankAtCompileTime2 = ColsAtCompileTime==Dynamic ? Dynamic : (ColsAtCompileTime)/2+1,
	RowsAtCompileTime3 = ColsAtCompileTime==Dynamic ? Dynamic : ColsAtCompileTime+1
	};
	typedef Matrix<Scalar, RankAtCompileTime2, ColsAtCompileTime> MatrixType2;
	typedef Matrix<Scalar, RankAtCompileTime2, 1> RhsType2;
	typedef Matrix<Scalar, ColsAtCompileTime, RankAtCompileTime2> MatrixType2T;
	Index rank = RankAtCompileTime2==Dynamic ? internal::random<Index>(1,cols) : Index(RankAtCompileTime2);
	MatrixType2 m2(rank,cols);
	int guard = 0;
	do {
	m2.setRandom();
	} while(SVD_FOR_MIN_NORM(MatrixType2)(m2).setThreshold(test_precision<Scalar>()).rank()!=rank && (++guard)<10);
	VERIFY(guard<10);

	RhsType2 rhs2 = RhsType2::Random(rank);
	// use QR to find a reference minimal norm solution
	HouseholderQR<MatrixType2T> qr(m2.adjoint());
	Matrix<Scalar,Dynamic,1> tmp = qr.matrixQR().topLeftCorner(rank,rank).template triangularView<Upper>().adjoint().solve(rhs2);
	tmp.conservativeResize(cols);
	tmp.tail(cols-rank).setZero();
	SolutionType x21 = qr.householderQ() * tmp;
	// now check with SVD
	SVD_FOR_MIN_NORM(MatrixType2) svd2(m2, computationOptions);
	SolutionType x22 = svd2.solve(rhs2);
	VERIFY_IS_APPROX(m2*x21, rhs2);
	VERIFY_IS_APPROX(m2*x22, rhs2);
	VERIFY_IS_APPROX(x21, x22);

	// Now check with a rank deficient matrix
	typedef Matrix<Scalar, RowsAtCompileTime3, ColsAtCompileTime> MatrixType3;
	typedef Matrix<Scalar, RowsAtCompileTime3, 1> RhsType3;
	Index rows3 = RowsAtCompileTime3==Dynamic ? internal::random<Index>(rank+1,2*cols) : Index(RowsAtCompileTime3);
	Matrix<Scalar,RowsAtCompileTime3,Dynamic> C = Matrix<Scalar,RowsAtCompileTime3,Dynamic>::Random(rows3,rank);
	MatrixType3 m3 = C * m2;
	RhsType3 rhs3 = C * rhs2;
	SVD_FOR_MIN_NORM(MatrixType3) svd3(m3, computationOptions);
	SolutionType x3 = svd3.solve(rhs3);
	VERIFY_IS_APPROX(m3*x3, rhs3);
	VERIFY_IS_APPROX(m3*x21, rhs3);
	VERIFY_IS_APPROX(m2*x3, rhs2);
	VERIFY_IS_APPROX(x21, x3);
	}

	// Check full, compare_to_full, least_square, and min_norm for all possible compute-options
	template<typename SvdType, typename MatrixType>
	void svd_test_all_computation_options(const MatrixType& m, bool full_only)
	{
	// if (QRPreconditioner == NoQRPreconditioner && m.rows() != m.cols())
	// return;
	SvdType fullSvd(m, ComputeFullU\|ComputeFullV);
	CALL_SUBTEST(( svd_check_full(m, fullSvd) ));
	CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeFullU \| ComputeFullV) ));
	CALL_SUBTEST(( svd_min_norm(m, ComputeFullU \| ComputeFullV) ));

	#if defined __INTEL_COMPILER
	// remark #111: statement is unreachable
	#pragma warning disable 111
	#endif
	if(full_only)
	return;

	CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullU, fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullV, fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, 0, fullSvd) ));

	if (MatrixType::ColsAtCompileTime == Dynamic) {
	// thin U/V are only available with dynamic number of columns
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeFullU\|ComputeThinV, fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinV, fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU\|ComputeFullV, fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU , fullSvd) ));
	CALL_SUBTEST(( svd_compare_to_full(m, ComputeThinU\|ComputeThinV, fullSvd) ));

	CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeFullU \| ComputeThinV) ));
	CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeThinU \| ComputeFullV) ));
	CALL_SUBTEST(( svd_least_square<SvdType>(m, ComputeThinU \| ComputeThinV) ));

	CALL_SUBTEST(( svd_min_norm(m, ComputeFullU \| ComputeThinV) ));
	CALL_SUBTEST(( svd_min_norm(m, ComputeThinU \| ComputeFullV) ));
	CALL_SUBTEST(( svd_min_norm(m, ComputeThinU \| ComputeThinV) ));

	// test reconstruction
	typedef typename MatrixType::Index Index;
	Index diagSize = (std::min)(m.rows(), m.cols());
	SvdType svd(m, ComputeThinU \| ComputeThinV);
	VERIFY_IS_APPROX(m, svd.matrixU().leftCols(diagSize) * svd.singularValues().asDiagonal() * svd.matrixV().leftCols(diagSize).adjoint());
	}
	}


	// work around stupid msvc error when constructing at compile time an expression that involves
	// a division by zero, even if the numeric type has floating point
	template<typename Scalar>
	EIGEN_DONT_INLINE Scalar zero() { return Scalar(0); }

	// workaround aggressive optimization in ICC
	template<typename T> EIGEN_DONT_INLINE T sub(T a, T b) { return a - b; }

	// all this function does is verify we don't iterate infinitely on nan/inf values
	template<typename SvdType, typename MatrixType>
	void svd_inf_nan()
	{
	SvdType svd;
	typedef typename MatrixType::Scalar Scalar;
	Scalar some_inf = Scalar(1) / zero<Scalar>();
	VERIFY(sub(some_inf, some_inf) != sub(some_inf, some_inf));
	svd.compute(MatrixType::Constant(10,10,some_inf), ComputeFullU \| ComputeFullV);

	Scalar nan = std::numeric_limits<Scalar>::quiet_NaN();
	VERIFY(nan != nan);
	svd.compute(MatrixType::Constant(10,10,nan), ComputeFullU \| ComputeFullV);

	MatrixType m = MatrixType::Zero(10,10);
	m(internal::random<int>(0,9), internal::random<int>(0,9)) = some_inf;
	svd.compute(m, ComputeFullU \| ComputeFullV);

	m = MatrixType::Zero(10,10);
	m(internal::random<int>(0,9), internal::random<int>(0,9)) = nan;
	svd.compute(m, ComputeFullU \| ComputeFullV);

	// regression test for bug 791
	m.resize(3,3);
	m << 0, 2*NumTraits<Scalar>::epsilon(), 0.5,
	0, -0.5, 0,
	nan, 0, 0;
	svd.compute(m, ComputeFullU \| ComputeFullV);

	m.resize(4,4);
	m << 1, 0, 0, 0,
	0, 3, 1, 2e-308,
	1, 0, 1, nan,
	0, nan, nan, 0;
	svd.compute(m, ComputeFullU \| ComputeFullV);
	}

	// Regression test for bug 286: JacobiSVD loops indefinitely with some
	// matrices containing denormal numbers.
	template<typename>
	void svd_underoverflow()
	{
	#if defined __INTEL_COMPILER
	// shut up warning #239: floating point underflow
	#pragma warning push
	#pragma warning disable 239
	#endif
	Matrix2d M;
	M << -7.90884e-313, -4.94e-324,
	0, 5.60844e-313;
	SVD_DEFAULT(Matrix2d) svd;
	svd.compute(M,ComputeFullU\|ComputeFullV);
	CALL_SUBTEST( svd_check_full(M,svd) );

	// Check all 2x2 matrices made with the following coefficients:
	VectorXd value_set(9);
	value_set << 0, 1, -1, 5.60844e-313, -5.60844e-313, 4.94e-324, -4.94e-324, -4.94e-223, 4.94e-223;
	Array4i id(0,0,0,0);
	int k = 0;
	do
	{
	M << value_set(id(0)), value_set(id(1)), value_set(id(2)), value_set(id(3));
	svd.compute(M,ComputeFullU\|ComputeFullV);
	CALL_SUBTEST( svd_check_full(M,svd) );

	id(k)++;
	if(id(k)>=value_set.size())
	{
	while(k<3 && id(k)>=value_set.size()) id(++k)++;
	id.head(k).setZero();
	k=0;
	}

	} while((id<int(value_set.size())).all());

	#if defined __INTEL_COMPILER
	#pragma warning pop
	#endif

	// Check for overflow:
	Matrix3d M3;
	M3 << 4.4331978442502944e+307, -5.8585363752028680e+307, 6.4527017443412964e+307,
	3.7841695601406358e+307, 2.4331702789740617e+306, -3.5235707140272905e+307,
	-8.7190887618028355e+307, -7.3453213709232193e+307, -2.4367363684472105e+307;

	SVD_DEFAULT(Matrix3d) svd3;
	svd3.compute(M3,ComputeFullU\|ComputeFullV); // just check we don't loop indefinitely
	CALL_SUBTEST( svd_check_full(M3,svd3) );
	}

	// void jacobisvd(const MatrixType& a = MatrixType(), bool pickrandom = true)

	template<typename MatrixType>
	void svd_all_trivial_2x2( void (*cb)(const MatrixType&,bool) )
	{
	MatrixType M;
	VectorXd value_set(3);
	value_set << 0, 1, -1;
	Array4i id(0,0,0,0);
	int k = 0;
	do
	{
	M << value_set(id(0)), value_set(id(1)), value_set(id(2)), value_set(id(3));

	cb(M,false);

	id(k)++;
	if(id(k)>=value_set.size())
	{
	while(k<3 && id(k)>=value_set.size()) id(++k)++;
	id.head(k).setZero();
	k=0;
	}

	} while((id<int(value_set.size())).all());
	}

	template<typename>
	void svd_preallocate()
	{
	Vector3f v(3.f, 2.f, 1.f);
	MatrixXf m = v.asDiagonal();

	internal::set_is_malloc_allowed(false);
	VERIFY_RAISES_ASSERT(VectorXf tmp(10);)
	SVD_DEFAULT(MatrixXf) svd;
	internal::set_is_malloc_allowed(true);
	svd.compute(m);
	VERIFY_IS_APPROX(svd.singularValues(), v);

	SVD_DEFAULT(MatrixXf) svd2(3,3);
	internal::set_is_malloc_allowed(false);
	svd2.compute(m);
	internal::set_is_malloc_allowed(true);
	VERIFY_IS_APPROX(svd2.singularValues(), v);
	VERIFY_RAISES_ASSERT(svd2.matrixU());
	VERIFY_RAISES_ASSERT(svd2.matrixV());
	svd2.compute(m, ComputeFullU \| ComputeFullV);
	VERIFY_IS_APPROX(svd2.matrixU(), Matrix3f::Identity());
	VERIFY_IS_APPROX(svd2.matrixV(), Matrix3f::Identity());
	internal::set_is_malloc_allowed(false);
	svd2.compute(m);
	internal::set_is_malloc_allowed(true);

	SVD_DEFAULT(MatrixXf) svd3(3,3,ComputeFullU\|ComputeFullV);
	internal::set_is_malloc_allowed(false);
	svd2.compute(m);
	internal::set_is_malloc_allowed(true);
	VERIFY_IS_APPROX(svd2.singularValues(), v);
	VERIFY_IS_APPROX(svd2.matrixU(), Matrix3f::Identity());
	VERIFY_IS_APPROX(svd2.matrixV(), Matrix3f::Identity());
	internal::set_is_malloc_allowed(false);
	svd2.compute(m, ComputeFullU\|ComputeFullV);
	internal::set_is_malloc_allowed(true);
	}

	template<typename SvdType,typename MatrixType>
	void svd_verify_assert(const MatrixType& m)
	{
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::Index Index;
	Index rows = m.rows();
	Index cols = m.cols();

	enum {
	RowsAtCompileTime = MatrixType::RowsAtCompileTime,
	ColsAtCompileTime = MatrixType::ColsAtCompileTime
	};

	typedef Matrix<Scalar, RowsAtCompileTime, 1> RhsType;
	RhsType rhs(rows);
	SvdType svd;
	VERIFY_RAISES_ASSERT(svd.matrixU())
	VERIFY_RAISES_ASSERT(svd.singularValues())
	VERIFY_RAISES_ASSERT(svd.matrixV())
	VERIFY_RAISES_ASSERT(svd.solve(rhs))
	MatrixType a = MatrixType::Zero(rows, cols);
	a.setZero();
	svd.compute(a, 0);
	VERIFY_RAISES_ASSERT(svd.matrixU())
	VERIFY_RAISES_ASSERT(svd.matrixV())
	svd.singularValues();
	VERIFY_RAISES_ASSERT(svd.solve(rhs))

	if (ColsAtCompileTime == Dynamic)
	{
	svd.compute(a, ComputeThinU);
	svd.matrixU();
	VERIFY_RAISES_ASSERT(svd.matrixV())
	VERIFY_RAISES_ASSERT(svd.solve(rhs))
	svd.compute(a, ComputeThinV);
	svd.matrixV();
	VERIFY_RAISES_ASSERT(svd.matrixU())
	VERIFY_RAISES_ASSERT(svd.solve(rhs))
	}
	else
	{
	VERIFY_RAISES_ASSERT(svd.compute(a, ComputeThinU))
	VERIFY_RAISES_ASSERT(svd.compute(a, ComputeThinV))
	}
	}

	#undef SVD_DEFAULT
	#undef SVD_FOR_MIN_NORM