Dune Core Modules (2.7.1)

Matrix and Vector classes that support a block recursive structure capable of representing the natural structure from Finite Element discretisations. More...

Modules

 Block Recursive Iterative Kernels
 
 IO for matrices and vectors.
 Provides methods for reading and writing matrices and vectors in various formats.
 
 Dense Matrix and Vector Template Library
 Type traits to retrieve the field and the real type of classes.
 

Files

file  matrixmatrix.hh
 provides functions for sparse matrix matrix multiplication.
 
file  matrixutils.hh
 Some handy generic functions for ISTL matrices.
 

Classes

struct  Dune::CompressionStatistics< size_type >
 Statistics about compression achieved in implicit mode. More...
 
class  Dune::ImplicitMatrixBuilder< M_ >
 A wrapper for uniform access to the BCRSMatrix during and after the build stage in implicit build mode. More...
 
class  Dune::BCRSMatrix< B, A >
 A sparse block matrix with compressed row storage. More...
 
class  Dune::BDMatrix< B, A >
 A block-diagonal matrix. More...
 
class  Dune::BTDMatrix< B, A >
 A block-tridiagonal matrix. More...
 
class  Dune::BlockVector< B, A >
 A vector of blocks with memory management. More...
 
class  Dune::Matrix< T, A >
 A generic dynamic dense matrix. More...
 
struct  Dune::MatMultMatResult< M1, M2 >
 Helper TMP to get the result type of a sparse matrix matrix multiplication ( \(C=A*B\)) More...
 
struct  Dune::TransposedMatMultMatResult< M1, M2 >
 Helper TMP to get the result type of a sparse matrix matrix multiplication ( \(C=A*B\)) More...
 
struct  Dune::CheckIfDiagonalPresent< Matrix, blocklevel, l >
 Check whether the a matrix has diagonal values on blocklevel recursion levels. More...
 
class  Dune::MultiTypeBlockMatrix< FirstRow, Args >
 A Matrix class to support different block types. More...
 
class  Dune::MultiTypeBlockMatrix_Solver_Col< I, crow, ccol, remain_col >
 part of solvers for MultiTypeBlockVector & MultiTypeBlockMatrix types More...
 
class  Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >
 solver for MultiTypeBlockVector & MultiTypeBlockMatrix types More...
 
class  Dune::MultiTypeBlockVector< Args >
 A Vector class to support different block types. More...
 
class  Dune::VariableBlockVector< B, A >
 A Vector of blocks with different blocksizes. More...
 

Typedefs

typedef MultiTypeBlockMatrix< FirstRow, Args... > Dune::MultiTypeBlockMatrix< FirstRow, Args >::type
 
using Dune::MultiTypeBlockMatrix< FirstRow, Args >::size_type = std::size_t
 Type used for sizes.
 
using Dune::MultiTypeBlockVector< Args >::size_type = std::size_t
 Type used for vector sizes.
 
typedef MultiTypeBlockVector< Args... > Dune::MultiTypeBlockVector< Args >::type
 
typedef double Dune::MultiTypeBlockVector< Args >::field_type
 The type used for scalars. More...
 

Functions

template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::matMultTransposeMat (BCRSMatrix< FieldMatrix< T, n, k >, A > &res, const BCRSMatrix< FieldMatrix< T, n, m >, A1 > &mat, const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &matt, bool tryHard=false)
 Calculate product of a sparse matrix with a transposed sparse matrices ( \(C=A*B^T\)). More...
 
template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::matMultMat (BCRSMatrix< FieldMatrix< T, n, m >, A > &res, const BCRSMatrix< FieldMatrix< T, n, k >, A1 > &mat, const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &matt, bool tryHard=false)
 Calculate product of two sparse matrices ( \(C=A*B\)). More...
 
template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::transposeMatMultMat (BCRSMatrix< FieldMatrix< T, n, m >, A > &res, const BCRSMatrix< FieldMatrix< T, k, n >, A1 > &mat, const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &matt, bool tryHard=false)
 Calculate product of a transposed sparse matrix with another sparse matrices ( \(C=A^T*B\)). More...
 
template<class M >
auto Dune::countNonZeros (const M &matrix, typename std::enable_if_t< Dune::IsNumber< M >::value > *sfinae=nullptr)
 Get the number of nonzero fields in the matrix. More...
 
static constexpr size_type Dune::MultiTypeBlockMatrix< FirstRow, Args >::N ()
 Return the number of matrix rows.
 
static constexpr size_type Dune::MultiTypeBlockMatrix< FirstRow, Args >::size ()
 Return the number of matrix rows. More...
 
static constexpr size_type Dune::MultiTypeBlockMatrix< FirstRow, Args >::M ()
 Return the number of matrix columns.
 
template<size_type index>
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator[] (const std::integral_constant< size_type, index > indexVariable) -> decltype(std::get< index >(*this))
 Random-access operator. More...
 
template<size_type index>
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator[] (const std::integral_constant< size_type, index > indexVariable) const -> decltype(std::get< index >(*this))
 Const random-access operator. More...
 
template<typename T >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator= (const T &newval)
 
MultiTypeBlockMatrixDune::MultiTypeBlockMatrix< FirstRow, Args >::operator*= (const field_type &k)
 vector space multiplication with scalar
 
MultiTypeBlockMatrixDune::MultiTypeBlockMatrix< FirstRow, Args >::operator/= (const field_type &k)
 vector space division by scalar
 
MultiTypeBlockMatrixDune::MultiTypeBlockMatrix< FirstRow, Args >::operator+= (const MultiTypeBlockMatrix &b)
 Add the entries of another matrix to this one. More...
 
MultiTypeBlockMatrixDune::MultiTypeBlockMatrix< FirstRow, Args >::operator-= (const MultiTypeBlockMatrix &b)
 Subtract the entries of another matrix from this one. More...
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::mv (const X &x, Y &y) const
 y = A x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::umv (const X &x, Y &y) const
 y += A x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::mmv (const X &x, Y &y) const
 y -= A x
 
template<typename AlphaType , typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::usmv (const AlphaType &alpha, const X &x, Y &y) const
 y += alpha A x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::mtv (const X &x, Y &y) const
 y = A^T x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::umtv (const X &x, Y &y) const
 y += A^T x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::mmtv (const X &x, Y &y) const
 y -= A^T x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::usmtv (const field_type &alpha, const X &x, Y &y) const
 y += alpha A^T x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::umhv (const X &x, Y &y) const
 y += A^H x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::mmhv (const X &x, Y &y) const
 y -= A^H x
 
template<typename X , typename Y >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::usmhv (const field_type &alpha, const X &x, Y &y) const
 y += alpha A^H x
 
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::frobenius_norm2 () const
 square of frobenius norm, need for block recursion
 
FieldTraits< field_type >::real_type Dune::MultiTypeBlockMatrix< FirstRow, Args >::frobenius_norm () const
 frobenius norm: sqrt(sum over squared values of entries)
 
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::infinity_norm () const
 Bastardized version of the infinity-norm / row-sum norm.
 
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::infinity_norm_real () const
 Bastardized version of the infinity-norm / row-sum norm.
 
template<typename T1 , typename... Args>
std::ostream & Dune::operator<< (std::ostream &s, const MultiTypeBlockMatrix< T1, Args... > &m)
 << operator for a MultiTypeBlockMatrix More...
 
template<typename Trhs , typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver_Col< I, crow, ccol, remain_col >::calc_rhs (const TMatrix &A, TVector &x, TVector &v, Trhs &b, const K &w)
 
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::dbgs (const TMatrix &A, TVector &x, const TVector &b, const K &w)
 
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::bsorf (const TMatrix &A, TVector &x, const TVector &b, const K &w)
 
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::bsorb (const TMatrix &A, TVector &x, const TVector &b, const K &w)
 
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::dbjac (const TMatrix &A, TVector &x, const TVector &b, const K &w)
 
static constexpr size_type Dune::MultiTypeBlockVector< Args >::size ()
 Return the number of non-zero vector entries. More...
 
static constexpr size_type Dune::MultiTypeBlockVector< Args >::N ()
 Number of elements.
 
int Dune::MultiTypeBlockVector< Args >::count () const
 
size_type Dune::MultiTypeBlockVector< Args >::dim () const
 Number of scalar elements.
 
template<size_type index>
std::tuple_element< index, TupleType >::typeDune::MultiTypeBlockVector< Args >::operator[] (const std::integral_constant< size_type, index > indexVariable)
 Random-access operator. More...
 
template<size_type index>
const std::tuple_element< index, TupleType >::typeDune::MultiTypeBlockVector< Args >::operator[] (const std::integral_constant< size_type, index > indexVariable) const
 Const random-access operator. More...
 
template<typename T >
void Dune::MultiTypeBlockVector< Args >::operator= (const T &newval)
 Assignment operator.
 
void Dune::MultiTypeBlockVector< Args >::operator+= (const type &newv)
 
void Dune::MultiTypeBlockVector< Args >::operator-= (const type &newv)
 
template<class T , std::enable_if_t< IsNumber< T >::value, int > = 0>
void Dune::MultiTypeBlockVector< Args >::operator*= (const T &w)
 Multiplication with a scalar.
 
template<class T , std::enable_if_t< IsNumber< T >::value, int > = 0>
void Dune::MultiTypeBlockVector< Args >::operator/= (const T &w)
 Division by a scalar.
 
auto Dune::MultiTypeBlockVector< Args >::one_norm () const
 Compute the 1-norm.
 
auto Dune::MultiTypeBlockVector< Args >::one_norm_real () const
 Compute the simplified 1-norm (uses 1-norm also for complex values)
 
FieldTraits< field_type >::real_type Dune::MultiTypeBlockVector< Args >::two_norm2 () const
 Compute the squared Euclidean norm.
 
FieldTraits< field_type >::real_type Dune::MultiTypeBlockVector< Args >::two_norm () const
 Compute the Euclidean norm.
 
FieldTraits< field_type >::real_type Dune::MultiTypeBlockVector< Args >::infinity_norm () const
 Compute the maximum norm.
 
FieldTraits< field_type >::real_type Dune::MultiTypeBlockVector< Args >::infinity_norm_real () const
 Compute the simplified maximum norm (uses 1-norm for complex values)
 
template<typename Ta >
void Dune::MultiTypeBlockVector< Args >::axpy (const Ta &a, const type &y)
 Axpy operation on this vector (*this += a * y) More...
 
template<typename... Args>
std::ostream & Dune::operator<< (std::ostream &s, const MultiTypeBlockVector< Args... > &v)
 Send MultiTypeBlockVector to an outstream.
 

Detailed Description

Matrix and Vector classes that support a block recursive structure capable of representing the natural structure from Finite Element discretisations.

The interface of our matrices is designed according to what they represent from a mathematical point of view. The vector classes are representations of vector spaces:

  • FieldVector represents a vector space \(V=K^n\) where the field \(K\) is represented by a numeric type (e.g. double, float, complex). \(n\) is known at compile time.
  • BlockVector represents a vector space \(V=W\times W \times W \times\cdots\times W\) where W is itself a vector space.
  • VariableBlockVector represents a vector space having a two-level block structure of the form \(V=B^{n_1}\times B^{n_2}\times\ldots \times B^{n_m}\), i.e. it is constructed from \(m\) vector spaces, \(i=1,\ldots,m\).

The matrix classes represent linear maps \(A: V \mapsto W\) from vector space \(V\) to vector space \(W\) the recursive block structure of the matrix rows and columns immediately follows from the recursive block structure of the vectors representing the domain and range of the mapping, respectively:

  • FieldMatrix represents a linear map \(M: V_1 \to V_2\) where \(V_1=K^n\) and \(V_2=K^m\) are vector spaces over the same field represented by a numerix type.
  • BCRSMatrix represents a linear map \(M: V_1 \to V_2\) where \(V_1=W\times W \times W \times\cdots\times W\) and \(V_2=W\times W \times W \times\cdots\times W\) where W is itself a vector space.
  • VariableBCRSMatrix is not yet implemented.

Typedef Documentation

◆ field_type

template<typename... Args>
typedef double Dune::MultiTypeBlockVector< Args >::field_type

The type used for scalars.

The current code hardwires it to 'double', which is far from nice. On the other hand, it is not clear what the correct type is. If the MultiTypeBlockVector class is instantiated with several vectors of different field_types, what should the resulting field_type be?

◆ type [1/2]

template<typename FirstRow , typename... Args>
typedef MultiTypeBlockMatrix<FirstRow, Args...> Dune::MultiTypeBlockMatrix< FirstRow, Args >::type

own class' type

◆ type [2/2]

template<typename... Args>
typedef MultiTypeBlockVector<Args...> Dune::MultiTypeBlockVector< Args >::type

own class' type

Function Documentation

◆ axpy()

template<typename... Args>
template<typename Ta >
void Dune::MultiTypeBlockVector< Args >::axpy ( const Ta &  a,
const type y 
)
inline

Axpy operation on this vector (*this += a * y)

Template Parameters
TaType of the scalar 'a'

References Dune::Hybrid::forEach(), and Dune::Hybrid::integralRange().

◆ bsorb()

template<int I, int crow, int remain_row>
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::bsorb ( const TMatrix &  A,
TVector &  x,
const TVector &  b,
const K &  w 
)
inlinestatic

◆ bsorf()

template<int I, int crow, int remain_row>
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::bsorf ( const TMatrix &  A,
TVector &  x,
const TVector &  b,
const K &  w 
)
inlinestatic

◆ calc_rhs()

template<int I, int crow, int ccol, int remain_col>
template<typename Trhs , typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver_Col< I, crow, ccol, remain_col >::calc_rhs ( const TMatrix &  A,
TVector &  x,
TVector &  v,
Trhs &  b,
const K &  w 
)
inlinestatic

iterating over one row in MultiTypeBlockMatrix to calculate right side b-A[i][j]*x[j]

◆ count()

template<typename... Args>
int Dune::MultiTypeBlockVector< Args >::count ( ) const
inline

number of elements

Deprecated:
"Use method 'N' instead"

◆ countNonZeros()

template<class M >
auto Dune::countNonZeros ( const M &  matrix,
typename std::enable_if_t< Dune::IsNumber< M >::value > *  sfinae = nullptr 
)
inline

Get the number of nonzero fields in the matrix.

This is not the number of nonzero blocks, but the number of non zero scalar entries (on blocklevel 1) if the matrix is viewed as a flat matrix.

For FieldMatrix this is simply the number of columns times the number of rows, for a BCRSMatrix<FieldMatrix<K,n,m>> this is the number of nonzero blocks time n*m.

Referenced by Dune::Amg::MatrixHierarchy< M, PI, A >::build().

◆ dbgs()

template<int I, int crow, int remain_row>
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::dbgs ( const TMatrix &  A,
TVector &  x,
const TVector &  b,
const K &  w 
)
inlinestatic

Gauss-Seidel solver for MultiTypeBlockMatrix & MultiTypeBlockVector types

◆ dbjac()

template<int I, int crow, int remain_row>
template<typename TVector , typename TMatrix , typename K >
static void Dune::MultiTypeBlockMatrix_Solver< I, crow, remain_row >::dbjac ( const TMatrix &  A,
TVector &  x,
const TVector &  b,
const K &  w 
)
inlinestatic

Jacobi solver for MultiTypeBlockMatrix & MultiTypeBlockVector types

◆ matMultMat()

template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::matMultMat ( BCRSMatrix< FieldMatrix< T, n, m >, A > &  res,
const BCRSMatrix< FieldMatrix< T, n, k >, A1 > &  mat,
const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &  matt,
bool  tryHard = false 
)

Calculate product of two sparse matrices ( \(C=A*B\)).

Parameters
resMatrix for the result of the computation.
matMatrix A.
mattMatrix B.
tryHardignored

◆ matMultTransposeMat()

template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::matMultTransposeMat ( BCRSMatrix< FieldMatrix< T, n, k >, A > &  res,
const BCRSMatrix< FieldMatrix< T, n, m >, A1 > &  mat,
const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &  matt,
bool  tryHard = false 
)

Calculate product of a sparse matrix with a transposed sparse matrices ( \(C=A*B^T\)).

Parameters
resMatrix for the result of the computation.
matMatrix A.
mattMatrix B, which will be transposed before the multiplication.
tryHardignored

◆ operator+=() [1/2]

template<typename FirstRow , typename... Args>
MultiTypeBlockMatrix& Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator+= ( const MultiTypeBlockMatrix< FirstRow, Args > &  b)
inline

Add the entries of another matrix to this one.

Parameters
bThe matrix to add to this one. Its sparsity pattern has to be subset of the sparsity pattern of this matrix.

References Dune::Hybrid::forEach(), Dune::Hybrid::integralRange(), and Dune::MultiTypeBlockMatrix< FirstRow, Args >::size().

◆ operator+=() [2/2]

template<typename... Args>
void Dune::MultiTypeBlockVector< Args >::operator+= ( const type newv)
inline

◆ operator-=() [1/2]

template<typename FirstRow , typename... Args>
MultiTypeBlockMatrix& Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator-= ( const MultiTypeBlockMatrix< FirstRow, Args > &  b)
inline

Subtract the entries of another matrix from this one.

Parameters
bThe matrix to subtract from this one. Its sparsity pattern has to be subset of the sparsity pattern of this matrix.

References Dune::Hybrid::forEach(), Dune::Hybrid::integralRange(), and Dune::MultiTypeBlockMatrix< FirstRow, Args >::size().

◆ operator-=() [2/2]

template<typename... Args>
void Dune::MultiTypeBlockVector< Args >::operator-= ( const type newv)
inline

◆ operator<<()

template<typename T1 , typename... Args>
std::ostream& Dune::operator<< ( std::ostream &  s,
const MultiTypeBlockMatrix< T1, Args... > &  m 
)

◆ operator=()

template<typename FirstRow , typename... Args>
template<typename T >
void Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator= ( const T &  newval)
inline

◆ operator[]() [1/4]

template<typename... Args>
template<size_type index>
std::tuple_element<index,TupleType>::type& Dune::MultiTypeBlockVector< Args >::operator[] ( const std::integral_constant< size_type, index >  indexVariable)
inline

Random-access operator.

This method mimicks the behavior of normal vector access with square brackets like, e.g., v[5] = 1. The problem is that the return type is different for each value of the argument in the brackets. Therefore we implement a trick using std::integral_constant. To access the first entry of a MultiTypeBlockVector named v write

MultiTypeBlockVector<A,B,C,D> v;
std::integral_constant<std::size_t,0> _0;
v[_0] = ...
constexpr index_constant< 0 > _0
Compile time index with value 0.
Definition: indices.hh:51

The name '_0' used here as a static replacement of the integer number zero is arbitrary. Any other variable name can be used. If you don't like the separate variable, you can writee

MultiTypeBlockVector<A,B,C,D> v;
v[std::integral_constant<std::size_t,0>()] = ...

References DUNE_UNUSED_PARAMETER.

◆ operator[]() [2/4]

template<typename FirstRow , typename... Args>
template<size_type index>
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator[] ( const std::integral_constant< size_type, index >  indexVariable) -> decltype(std::get<index>(*this))
inline

Random-access operator.

This method mimicks the behavior of normal vector access with square brackets like, e.g., m[5] = .... The problem is that the return type is different for each value of the argument in the brackets. Therefore we implement a trick using std::integral_constant. To access the first row of a MultiTypeBlockMatrix named m write

std::integral_constant<size_type,0> _0;
m[_0] = ...

The name '_0' used here as a static replacement of the integer number zero is arbitrary. Any other variable name can be used. If you don't like the separate variable, you can write

m[std::integral_constant<size_type,0>()] = ...

References DUNE_UNUSED_PARAMETER.

◆ operator[]() [3/4]

template<typename... Args>
template<size_type index>
const std::tuple_element<index,TupleType>::type& Dune::MultiTypeBlockVector< Args >::operator[] ( const std::integral_constant< size_type, index >  indexVariable) const
inline

Const random-access operator.

This is the const version of the random-access operator. See the non-const version for a full explanation of how to use it.

References DUNE_UNUSED_PARAMETER.

◆ operator[]() [4/4]

template<typename FirstRow , typename... Args>
template<size_type index>
auto Dune::MultiTypeBlockMatrix< FirstRow, Args >::operator[] ( const std::integral_constant< size_type, index >  indexVariable) const -> decltype(std::get<index>(*this))
inline

Const random-access operator.

This is the const version of the random-access operator. See the non-const version for a full explanation of how to use it.

References DUNE_UNUSED_PARAMETER.

◆ size() [1/2]

◆ size() [2/2]

template<typename... Args>
static constexpr size_type Dune::MultiTypeBlockVector< Args >::size ( )
inlinestaticconstexpr

Return the number of non-zero vector entries.

As this is a dense vector data structure, all entries are non-zero, and hence 'size' returns the same number as 'N'.

◆ transposeMatMultMat()

template<class T , class A , class A1 , class A2 , int n, int m, int k>
void Dune::transposeMatMultMat ( BCRSMatrix< FieldMatrix< T, n, m >, A > &  res,
const BCRSMatrix< FieldMatrix< T, k, n >, A1 > &  mat,
const BCRSMatrix< FieldMatrix< T, k, m >, A2 > &  matt,
bool  tryHard = false 
)

Calculate product of a transposed sparse matrix with another sparse matrices ( \(C=A^T*B\)).

Parameters
resMatrix for the result of the computation.
matMatrix A, which will be transposed before the multiplication.
mattMatrix B.
tryHardignored

Referenced by MatrixInfo< BCRSMatrix >::computeNonSymCond2().

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