Detailed Description

template<int Mode, bool LhsIsTriangular, typename Lhs, typename Rhs>
struct Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >

Definition at line 373 of file Core.

Inheritance diagram for Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >:

[legend]

List of all members.

Public Types

typedef MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > Base

typedef Lhs::Nested LhsNested

typedef internal::remove_all
< LhsNested >::type _LhsNested

typedef internal::blas_traits
< _LhsNested > LhsBlasTraits

typedef
LhsBlasTraits::DirectLinearAccessType ActualLhsType

typedef internal::remove_all
< ActualLhsType >::type _ActualLhsType

typedef internal::traits< Lhs >
::Scalar LhsScalar

typedef Rhs::Nested RhsNested

typedef internal::remove_all
< RhsNested >::type _RhsNested

typedef internal::blas_traits
< _RhsNested > RhsBlasTraits

typedef
RhsBlasTraits::DirectLinearAccessType ActualRhsType

typedef internal::remove_all
< ActualRhsType >::type _ActualRhsType

typedef internal::traits< Rhs >
::Scalar RhsScalar

typedef CoeffBasedProduct
< LhsNested, RhsNested, 0 > FullyLazyCoeffBaseProductType

typedef Base::PlainObject PlainObject

The plain matrix type corresponding to this expression.

enum

typedef Diagonal
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > DiagonalReturnType

typedef const Diagonal< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > ConstDiagonalReturnType

typedef Homogeneous
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >
, HomogeneousReturnTypeDirection > HomogeneousReturnType

typedef Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >
>::ColsAtCompileTime==1?SizeMinusOne:1,
internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >
>::ColsAtCompileTime==1?1:SizeMinusOne > ConstStartMinusOne

typedef CwiseUnaryOp
< internal::scalar_quotient1_op
< typename internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar >
, const ConstStartMinusOne > HNormalizedReturnType

typedef
internal::stem_function
< Scalar >::type StemFunction

enum

typedef internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::StorageKind StorageKind

typedef internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Index Index

The type of indices.

typedef internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar Scalar

typedef
internal::packet_traits
< Scalar >::type PacketScalar

typedef NumTraits< Scalar >::Real RealScalar

typedef Base::CoeffReturnType CoeffReturnType

typedef const Transpose< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > ConstTransposeReturnType

typedef VectorBlock
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > SegmentReturnType

typedef const VectorBlock
< const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > ConstSegmentReturnType

typedef VectorwiseOp
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, Horizontal > RowwiseReturnType

typedef const VectorwiseOp
< const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false >
, Horizontal > ConstRowwiseReturnType

typedef VectorwiseOp
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, Vertical > ColwiseReturnType

typedef const VectorwiseOp
< const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false >, Vertical > ConstColwiseReturnType

typedef Reverse
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, BothDirections > ReverseReturnType

typedef const Reverse< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, BothDirections > ConstReverseReturnType

MRPT plugin: Types

enum

typedef Scalar value_type

Type of the elements.

Public Member Functions

TriangularProduct (const Lhs &lhs, const Rhs &rhs)

template<typename Dest >

void scaleAndAddTo (Dest &dst, Scalar alpha) const

Index rows () const

Index cols () const

void evalTo (Dest &dst) const

void addTo (Dest &dst) const

void subTo (Dest &dst) const

const _LhsNested & lhs () const

const _RhsNested & rhs () const

operator const PlainObject & () const

const Diagonal< const
FullyLazyCoeffBaseProductType, 0 > diagonal () const

const Diagonal
< FullyLazyCoeffBaseProductType,
Index > diagonal () const

const Diagonal
< FullyLazyCoeffBaseProductType,
Dynamic > diagonal (Index index) const

DiagonalReturnType diagonal ()

DiagonalIndexReturnType
< Dynamic >::Type diagonal (Index index)

Base::CoeffReturnType coeff (Index row, Index col) const

Base::CoeffReturnType coeff (Index i) const

const Scalar & coeffRef (Index row, Index col) const

const Scalar & coeffRef (Index i) const

Index diagonalSize () const

const CwiseUnaryOp
< internal::scalar_opposite_op
< typename internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar >
, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > operator- () const

const ScalarMultipleReturnType operator* (const Scalar &scalar) const

const ScalarMultipleReturnType operator* (const RealScalar &scalar) const

const CwiseUnaryOp
< internal::scalar_multiple2_op
< Scalar, std::complex< Scalar >
>, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > operator* (const std::complex< Scalar > &scalar) const

Overloaded for efficient real matrix times complex scalar value.

const ProductReturnType
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, OtherDerived >
::Type operator* (const MatrixBase< OtherDerived > &other) const

const DiagonalProduct
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, DiagonalDerived,
OnTheRight > operator* (const DiagonalBase< DiagonalDerived > &diagonal) const

ScalarMultipleReturnType operator* (const UniformScaling< Scalar > &s) const

const CwiseUnaryOp
< internal::scalar_quotient1_op
< typename internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar >
, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > operator/ (const Scalar &scalar) const

internal::cast_return_type
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, const
CwiseUnaryOp
< internal::scalar_cast_op
< typename internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar,
NewType >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > >::type cast () const

ConjugateReturnType conjugate () const

RealReturnType real () const

NonConstRealReturnType real ()

const ImagReturnType imag () const

NonConstImagReturnType imag ()

const CwiseUnaryOp
< CustomUnaryOp, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > unaryExpr (const CustomUnaryOp &func=CustomUnaryOp()) const

Apply a unary operator coefficient-wise.

const CwiseUnaryView
< CustomViewOp, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > unaryViewExpr (const CustomViewOp &func=CustomViewOp()) const

EIGEN_STRONG_INLINE const
CwiseBinaryOp< CustomBinaryOp,
const TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, const
OtherDerived > binaryExpr (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other, const CustomBinaryOp &func=CustomBinaryOp()) const

EIGEN_STRONG_INLINE const
CwiseUnaryOp
< internal::scalar_abs_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cwiseAbs () const

EIGEN_STRONG_INLINE const
CwiseUnaryOp
< internal::scalar_abs2_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cwiseAbs2 () const

const CwiseUnaryOp
< internal::scalar_sqrt_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cwiseSqrt () const

const CwiseUnaryOp
< internal::scalar_inverse_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cwiseInverse () const

const CwiseUnaryOp
< std::binder1st
< std::equal_to< Scalar >
>, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > cwiseEqual (const Scalar &s) const

const CwiseBinaryOp
< std::equal_to< Scalar >
, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false >, const
OtherDerived > cwiseEqual (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

EIGEN_STRONG_INLINE const EIGEN_CWISE_PRODUCT_RETURN_TYPE (TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >, OtherDerived) cwiseProduct(const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

const CwiseBinaryOp
< std::not_equal_to< Scalar >
, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false >, const
OtherDerived > cwiseNotEqual (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

EIGEN_STRONG_INLINE const
CwiseBinaryOp
< internal::scalar_min_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, const
OtherDerived > cwiseMin (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

EIGEN_STRONG_INLINE const
CwiseBinaryOp
< internal::scalar_max_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, const
OtherDerived > cwiseMax (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

EIGEN_STRONG_INLINE const
CwiseBinaryOp
< internal::scalar_quotient_op
< Scalar >, const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, const
OtherDerived > cwiseQuotient (const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &other) const

void fill (const Scalar &value)

bool isDiagonal (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

void normalize ()

EIGEN_STRONG_INLINE void extractRow (size_t nRow, Eigen::EigenBase< OtherDerived > &v, size_t startingCol=0) const

Extract one row from the matrix into a row vector.

void extractRow (size_t nRow, std::vector< T > &v, size_t startingCol=0) const

EIGEN_STRONG_INLINE void extractRowAsCol (size_t nRow, VECTOR &v, size_t startingCol=0) const

Extract one row from the matrix into a column vector.

EIGEN_STRONG_INLINE void extractCol (size_t nCol, VECTOR &v, size_t startingRow=0) const

Extract one column from the matrix into a column vector.

void extractCol (size_t nCol, std::vector< T > &v, size_t startingRow=0) const

EIGEN_STRONG_INLINE void extractMatrix (const size_t firstRow, const size_t firstCol, MATRIX &m) const

EIGEN_STRONG_INLINE void extractMatrix (const size_t firstRow, const size_t firstCol, const size_t nRows, const size_t nCols, MATRIX &m) const

EIGEN_STRONG_INLINE void extractSubmatrix (const size_t row_first, const size_t row_last, const size_t col_first, const size_t col_last, MATRIX &out) const

Get a submatrix, given its bounds: first & last column and row (inclusive).

void extractSubmatrixSymmetricalBlocks (const size_t block_size, const std::vector< size_t > &block_indices, MATRIX &out) const

Get a submatrix from a square matrix, by collecting the elements M(idxs,idxs), where idxs is a sequence {block_indices(i):block_indices(i)+block_size-1} for all "i" up to the size of block_indices.

void extractSubmatrixSymmetrical (const std::vector< size_t > &indices, MATRIX &out) const

Get a submatrix from a square matrix, by collecting the elements M(idxs,idxs), where idxs is the sequence of indices passed as argument.

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator+= (const MatrixBase< OtherDerived > &other)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator+= (const EigenBase< OtherDerived > &other)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator-= (const MatrixBase< OtherDerived > &other)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator-= (const EigenBase< OtherDerived > &other)

const LazyProductReturnType
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, OtherDerived >
::Type lazyProduct (const MatrixBase< OtherDerived > &other) const

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator*= (const EigenBase< OtherDerived > &other)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator*= (const Scalar &other)

void applyOnTheLeft (const EigenBase< OtherDerived > &other)

void applyOnTheLeft (Index p, Index q, const JacobiRotation< OtherScalar > &j)

void applyOnTheRight (const EigenBase< OtherDerived > &other)

void applyOnTheRight (Index p, Index q, const JacobiRotation< OtherScalar > &j)

internal::scalar_product_traits
< typename internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar,
typename internal::traits
< OtherDerived >::Scalar >
::ReturnType dot (const MatrixBase< OtherDerived > &other) const

RealScalar squaredNorm () const

RealScalar norm () const

RealScalar stableNorm () const

RealScalar blueNorm () const

RealScalar hypotNorm () const

const PlainObject normalized () const

const AdjointReturnType adjoint () const

void adjointInPlace ()

TriangularViewReturnType< Mode >
::Type triangularView ()

ConstTriangularViewReturnType
< Mode >::Type triangularView () const

SelfAdjointViewReturnType
< UpLo >::Type selfadjointView ()

ConstSelfAdjointViewReturnType
< UpLo >::Type selfadjointView () const

const SparseView
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > sparseView (const Scalar &m_reference=Scalar(0), typename NumTraits< Scalar >::Real m_epsilon=NumTraits< Scalar >::dummy_precision()) const

const DiagonalWrapper< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > asDiagonal () const

const PermutationWrapper
< const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > asPermutation () const

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setIdentity ()

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setIdentity (Index rows, Index cols)

bool isIdentity (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isUpperTriangular (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isLowerTriangular (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isOrthogonal (const MatrixBase< OtherDerived > &other, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isUnitary (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool operator== (const MatrixBase< OtherDerived > &other) const

bool operator!= (const MatrixBase< OtherDerived > &other) const

NoAlias< TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false >
, Eigen::MatrixBase > noalias ()

const ForceAlignedAccess
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > forceAlignedAccess () const

ForceAlignedAccess
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > forceAlignedAccess ()

internal::add_const_on_value_type
< typename
internal::conditional< Enable,
ForceAlignedAccess
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >
>, TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & >::type >::type forceAlignedAccessIf () const

internal::conditional< Enable,
ForceAlignedAccess
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >
>, TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & >::type forceAlignedAccessIf ()

Scalar trace () const

RealScalar lpNorm () const

MatrixBase< TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > & matrix ()

const MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & matrix () const

ArrayWrapper
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > array ()

const ArrayWrapper
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > array () const

const FullPivLU< PlainObject > fullPivLu () const

const PartialPivLU< PlainObject > partialPivLu () const

const PartialPivLU< PlainObject > lu () const

const internal::inverse_impl
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > inverse () const

void computeInverseAndDetWithCheck (ResultType &inverse, typename ResultType::Scalar &determinant, bool &invertible, const RealScalar &absDeterminantThreshold=NumTraits< Scalar >::dummy_precision()) const

void computeInverseWithCheck (ResultType &inverse, bool &invertible, const RealScalar &absDeterminantThreshold=NumTraits< Scalar >::dummy_precision()) const

Scalar determinant () const

const LLT< PlainObject > llt () const

const LDLT< PlainObject > ldlt () const

const HouseholderQR< PlainObject > householderQr () const

const ColPivHouseholderQR
< PlainObject > colPivHouseholderQr () const

const FullPivHouseholderQR
< PlainObject > fullPivHouseholderQr () const

EigenvaluesReturnType eigenvalues () const

RealScalar operatorNorm () const

JacobiSVD< PlainObject > jacobiSvd (unsigned int computationOptions=0) const

cross_product_return_type
< OtherDerived >::type cross (const MatrixBase< OtherDerived > &other) const

PlainObject cross3 (const MatrixBase< OtherDerived > &other) const

PlainObject unitOrthogonal (void) const

Matrix< Scalar, 3, 1 > eulerAngles (Index a0, Index a1, Index a2) const

HomogeneousReturnType homogeneous () const

const HNormalizedReturnType hnormalized () const

void makeHouseholderInPlace (Scalar &tau, RealScalar &beta)

void makeHouseholder (EssentialPart &essential, Scalar &tau, RealScalar &beta) const

void applyHouseholderOnTheLeft (const EssentialPart &essential, const Scalar &tau, Scalar *workspace)

void applyHouseholderOnTheRight (const EssentialPart &essential, const Scalar &tau, Scalar *workspace)

const
MatrixExponentialReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > exp () const

const
MatrixFunctionReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > matrixFunction (StemFunction f) const

const
MatrixFunctionReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cosh () const

const
MatrixFunctionReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > sinh () const

const
MatrixFunctionReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > cos () const

const
MatrixFunctionReturnValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > sin () const

Index nonZeros () const

Index outerSize () const

Index innerSize () const

void resize (Index size)

Only plain matrices/arrays, not expressions, may be resized; therefore the only useful resize methods are Matrix::resize() and Array::resize().

void resize (Index rows, Index cols)

Only plain matrices/arrays, not expressions, may be resized; therefore the only useful resize methods are Matrix::resize() and Array::resize().

CommaInitializer
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > operator<< (const Scalar &s)

CommaInitializer
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > operator<< (const DenseBase< OtherDerived > &other)

const Flagged
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, Added, Removed > flagged () const

Eigen::Transpose
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > transpose ()

ConstTransposeReturnType transpose () const

void transposeInPlace ()

SegmentReturnType segment (Index start, Index size)

DenseBase::ConstSegmentReturnType segment (Index start, Index size) const

FixedSegmentReturnType< Size >
::Type segment (Index start)

ConstFixedSegmentReturnType
< Size >::Type segment (Index start) const

SegmentReturnType head (Index size)

DenseBase::ConstSegmentReturnType head (Index size) const

FixedSegmentReturnType< Size >
::Type head ()

ConstFixedSegmentReturnType
< Size >::Type head () const

SegmentReturnType tail (Index size)

DenseBase::ConstSegmentReturnType tail (Index size) const

FixedSegmentReturnType< Size >
::Type tail ()

ConstFixedSegmentReturnType
< Size >::Type tail () const

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setConstant (const Scalar &value)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setLinSpaced (Index size, const Scalar &low, const Scalar &high)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setLinSpaced (const Scalar &low, const Scalar &high)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setZero ()

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setOnes ()

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & setRandom ()

bool isApprox (const DenseBase< OtherDerived > &other, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isMuchSmallerThan (const RealScalar &other, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isMuchSmallerThan (const DenseBase< OtherDerived > &other, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isApproxToConstant (const Scalar &value, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isConstant (const Scalar &value, RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isZero (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

bool isOnes (RealScalar prec=NumTraits< Scalar >::dummy_precision()) const

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator/= (const Scalar &other)

EIGEN_STRONG_INLINE const
internal::eval
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::type eval () const

void swap (const DenseBase< OtherDerived > &other, int=OtherDerived::ThisConstantIsPrivateInPlainObjectBase)

swaps *this with the expression other.

void swap (PlainObjectBase< OtherDerived > &other)

swaps *this with the matrix or array other.

const NestByValue
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > nestByValue () const

Scalar sum () const

Scalar prod () const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar minCoeff () const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar minCoeff (IndexType *row, IndexType *col) const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar minCoeff (IndexType *index) const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar maxCoeff () const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar maxCoeff (IndexType *row, IndexType *col) const

internal::traits
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > >::Scalar maxCoeff (IndexType *index) const

void visit (Visitor &func) const

const WithFormat
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > format (const IOFormat &fmt) const

CoeffReturnType value () const

bool all (void) const

bool any (void) const

Index count () const

ConstRowwiseReturnType rowwise () const

RowwiseReturnType rowwise ()

ConstColwiseReturnType colwise () const

ColwiseReturnType colwise ()

const Select
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, ThenDerived,
ElseDerived > select (const DenseBase< ThenDerived > &thenMatrix, const DenseBase< ElseDerived > &elseMatrix) const

const Select
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, ThenDerived,
typename
ThenDerived::ConstantReturnType > select (const DenseBase< ThenDerived > &thenMatrix, typename ThenDerived::Scalar elseScalar) const

const Select
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, typename
ElseDerived::ConstantReturnType,
ElseDerived > select (typename ElseDerived::Scalar thenScalar, const DenseBase< ElseDerived > &elseMatrix) const

const Replicate
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, RowFactor,
ColFactor > replicate () const

const Replicate
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, Dynamic, Dynamic > replicate (Index rowFacor, Index colFactor) const

ReverseReturnType reverse ()

ConstReverseReturnType reverse () const

void reverseInPlace ()

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > block (Index startRow, Index startCol, Index blockRows, Index blockCols)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > block (Index startRow, Index startCol, Index blockRows, Index blockCols) const

This is the const version of block(Index,Index,Index,Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, BlockRows,
BlockCols > block (Index startRow, Index startCol)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, BlockRows,
BlockCols > block (Index startRow, Index startCol) const

This is the const version of block<>(Index, Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > topRightCorner (Index cRows, Index cCols)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > topRightCorner (Index cRows, Index cCols) const

This is the const version of topRightCorner(Index, Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > topRightCorner ()

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > topRightCorner () const

This is the const version of topRightCorner<int, int>().

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > topLeftCorner (Index cRows, Index cCols)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > topLeftCorner (Index cRows, Index cCols) const

This is the const version of topLeftCorner(Index, Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > topLeftCorner ()

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > topLeftCorner () const

This is the const version of topLeftCorner<int, int>().

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > bottomRightCorner (Index cRows, Index cCols)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > bottomRightCorner (Index cRows, Index cCols) const

This is the const version of bottomRightCorner(Index, Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > bottomRightCorner ()

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > bottomRightCorner () const

This is the const version of bottomRightCorner<int, int>().

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > bottomLeftCorner (Index cRows, Index cCols)

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > bottomLeftCorner (Index cRows, Index cCols) const

This is the const version of bottomLeftCorner(Index, Index).

Block< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > bottomLeftCorner ()

const Block< const
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false >, CRows, CCols > bottomLeftCorner () const

This is the const version of bottomLeftCorner<int, int>().

RowsBlockXpr topRows (Index n)

ConstRowsBlockXpr topRows (Index n) const

This is the const version of topRows(Index).

NRowsBlockXpr< N >::Type topRows ()

ConstNRowsBlockXpr< N >::Type topRows () const

This is the const version of topRows<int>().

RowsBlockXpr bottomRows (Index n)

ConstRowsBlockXpr bottomRows (Index n) const

This is the const version of bottomRows(Index).

NRowsBlockXpr< N >::Type bottomRows ()

ConstNRowsBlockXpr< N >::Type bottomRows () const

This is the const version of bottomRows<int>().

RowsBlockXpr middleRows (Index startRow, Index numRows)

ConstRowsBlockXpr middleRows (Index startRow, Index numRows) const

This is the const version of middleRows(Index,Index).

NRowsBlockXpr< N >::Type middleRows (Index startRow)

ConstNRowsBlockXpr< N >::Type middleRows (Index startRow) const

This is the const version of middleRows<int>().

ColsBlockXpr leftCols (Index n)

ConstColsBlockXpr leftCols (Index n) const

This is the const version of leftCols(Index).

NColsBlockXpr< N >::Type leftCols ()

ConstNColsBlockXpr< N >::Type leftCols () const

This is the const version of leftCols<int>().

ColsBlockXpr rightCols (Index n)

ConstColsBlockXpr rightCols (Index n) const

This is the const version of rightCols(Index).

NColsBlockXpr< N >::Type rightCols ()

ConstNColsBlockXpr< N >::Type rightCols () const

This is the const version of rightCols<int>().

ColsBlockXpr middleCols (Index startCol, Index numCols)

ConstColsBlockXpr middleCols (Index startCol, Index numCols) const

This is the const version of middleCols(Index,Index).

NColsBlockXpr< N >::Type middleCols (Index startCol)

ConstNColsBlockXpr< N >::Type middleCols (Index startCol) const

This is the const version of middleCols<int>().

ColXpr col (Index i)

ConstColXpr col (Index i) const

This is the const version of col().

RowXpr row (Index i)

ConstRowXpr row (Index i) const

This is the const version of row().

MRPT plugin: Set/get/load/save and other miscelaneous methods

EIGEN_STRONG_INLINE void fill (const Scalar v)

EIGEN_STRONG_INLINE void assign (const Scalar v)

EIGEN_STRONG_INLINE void assign (size_t N, const Scalar v)

EIGEN_STRONG_INLINE size_t getRowCount () const

Get number of rows.

EIGEN_STRONG_INLINE size_t getColCount () const

Get number of columns.

EIGEN_STRONG_INLINE void unit (const size_t nRows, const Scalar diag_vals)

Make the matrix an identity matrix (the diagonal values can be 1.0 or any other value)

EIGEN_STRONG_INLINE void unit ()

Make the matrix an identity matrix.

EIGEN_STRONG_INLINE void eye ()

Make the matrix an identity matrix.

EIGEN_STRONG_INLINE void zeros ()

Set all elements to zero.

EIGEN_STRONG_INLINE void zeros (const size_t row, const size_t col)

Resize and set all elements to zero.

EIGEN_STRONG_INLINE void ones (const size_t row, const size_t col)

Resize matrix and set all elements to one.

EIGEN_STRONG_INLINE void ones ()

Set all elements to one.

EIGEN_STRONG_INLINE Scalar * get_unsafe_row (size_t row)

Fast but unsafe method to obtain a pointer to a given row of the matrix (Use only in time critical applications) VERY IMPORTANT WARNING: You must be aware of the memory layout, either Column or Row-major ordering.

EIGEN_STRONG_INLINE const Scalar * get_unsafe_row (size_t row) const

EIGEN_STRONG_INLINE Scalar get_unsafe (const size_t row, const size_t col) const

Read-only access to one element (Use with caution, bounds are not checked!)

EIGEN_STRONG_INLINE Scalar & get_unsafe (const size_t row, const size_t col)

Reference access to one element (Use with caution, bounds are not checked!)

EIGEN_STRONG_INLINE void set_unsafe (const size_t row, const size_t col, const Scalar val)

Sets an element (Use with caution, bounds are not checked!)

EIGEN_STRONG_INLINE void push_back (Scalar val)

Insert an element at the end of the container (for 1D vectors/arrays)

EIGEN_STRONG_INLINE bool isSquare () const

EIGEN_STRONG_INLINE bool isSingular (const Scalar absThreshold=0) const

bool fromMatlabStringFormat (const std::string &s, bool dumpErrorMsgToStdErr=true)

Read a matrix from a string in Matlab-like format, for example "[1 0 2; 0 4 -1]" The string must start with '[' and end with ']'.

std::string inMatlabFormat (const size_t decimal_digits=6) const

Dump matrix in matlab format.

void saveToTextFile (const std::string &file, mrpt::math::TMatrixTextFileFormat fileFormat=mrpt::math::MATRIX_FORMAT_ENG, bool appendMRPTHeader=false, const std::string &userHeader=std::string()) const

Save matrix to a text file, compatible with MATLAB text format (see also the methods of matrix classes themselves).

void loadFromTextFile (const std::string &file)

Load matrix from a text file, compatible with MATLAB text format.

void loadFromTextFile (std::istream &_input_text_stream)

EIGEN_STRONG_INLINE void multiplyColumnByScalar (size_t c, Scalar s)

EIGEN_STRONG_INLINE void multiplyRowByScalar (size_t r, Scalar s)

EIGEN_STRONG_INLINE void swapCols (size_t i1, size_t i2)

EIGEN_STRONG_INLINE void swapRows (size_t i1, size_t i2)

EIGEN_STRONG_INLINE size_t countNonZero () const

EIGEN_STRONG_INLINE Scalar maximum () const

[VECTORS OR MATRICES] Finds the maximum value

Exceptions:

std::exception On an empty input container

EIGEN_STRONG_INLINE Scalar maximum (size_t *maxIndex) const

[VECTORS ONLY] Finds the maximum value (and the corresponding zero-based index) from a given container.

EIGEN_STRONG_INLINE Scalar minimum () const

[VECTORS OR MATRICES] Finds the minimum value

EIGEN_STRONG_INLINE Scalar minimum (size_t *minIndex) const

[VECTORS ONLY] Finds the minimum value (and the corresponding zero-based index) from a given container.

EIGEN_STRONG_INLINE void minimum_maximum (Scalar &out_min, Scalar &out_max) const

[VECTORS OR MATRICES] Compute the minimum and maximum of a container at once

EIGEN_STRONG_INLINE void minimum_maximum (Scalar &out_min, Scalar &out_max, size_t *minIndex, size_t *maxIndex) const

[VECTORS ONLY] Compute the minimum and maximum of a container at once

void find_index_max_value (size_t &u, size_t &v, Scalar &valMax) const

[VECTORS OR MATRICES] Finds the maximum value (and the corresponding zero-based index) from a given container.

EIGEN_STRONG_INLINE Scalar norm_inf () const

Compute the norm-infinite of a vector ($f[ ||{v}||_ $f]), ie the maximum absolute value of the elements.

EIGEN_STRONG_INLINE Scalar squareNorm () const

Compute the square norm of a vector/array/matrix (the Euclidean distance to the origin, taking all the elements as a single vector).

EIGEN_STRONG_INLINE Scalar sumAll () const

EIGEN_STRONG_INLINE void laplacian (Eigen::MatrixBase< OtherDerived > &ret) const

Computes the laplacian of this square graph weight matrix.

EIGEN_STRONG_INLINE void setSize (size_t row, size_t col)

Changes the size of matrix, maintaining its previous content as possible and padding with zeros where applicable.

void largestEigenvector (OUTVECT &x, Scalar resolution=Scalar(0.01), size_t maxIterations=6, int *out_Iterations=NULL, float *out_estimatedResolution=NULL) const

Efficiently computes only the biggest eigenvector of the matrix using the Power Method, and returns it in the passed vector "x".

MatrixBase< TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > & operator^= (const unsigned int pow)

Combined matrix power and assignment operator.

EIGEN_STRONG_INLINE void scalarPow (const Scalar s)

Scalar power of all elements to a given power, this is diferent of ^ operator.

EIGEN_STRONG_INLINE bool isDiagonal () const

Checks for matrix type.

EIGEN_STRONG_INLINE Scalar maximumDiagonal () const

Finds the maximum value in the diagonal of the matrix.

EIGEN_STRONG_INLINE double mean () const

Computes the mean of the entire matrix.

void meanAndStd (VEC &outMeanVector, VEC &outStdVector, const bool unbiased_variance=true) const

Computes a row with the mean values of each column in the matrix and the associated vector with the standard deviation of each column.

void meanAndStdAll (double &outMean, double &outStd, const bool unbiased_variance=true) const

Computes the mean and standard deviation of all the elements in the matrix as a whole.

EIGEN_STRONG_INLINE void insertMatrix (size_t r, size_t c, const MAT &m)

Insert matrix "m" into this matrix at indices (r,c), that is, (*this)(r,c)=m(0,0) and so on.

EIGEN_STRONG_INLINE void insertMatrixTranspose (size_t r, size_t c, const MAT &m)

EIGEN_STRONG_INLINE void insertRow (size_t nRow, const MAT &aRow)

void insertRow (size_t nRow, const std::vector< R > &aRow)

EIGEN_STRONG_INLINE void insertCol (size_t nCol, const MAT &aCol)

void insertCol (size_t nCol, const std::vector< R > &aCol)

EIGEN_STRONG_INLINE void removeColumns (const std::vector< size_t > &idxsToRemove)

Remove columns of the matrix.

EIGEN_STRONG_INLINE void unsafeRemoveColumns (const std::vector< size_t > &idxs)

Remove columns of the matrix.

EIGEN_STRONG_INLINE void removeRows (const std::vector< size_t > &idxsToRemove)

Remove rows of the matrix.

EIGEN_STRONG_INLINE void unsafeRemoveRows (const std::vector< size_t > &idxs)

Remove rows of the matrix.

EIGEN_STRONG_INLINE const
AdjointReturnType t () const

Transpose.

EIGEN_STRONG_INLINE PlainObject inv () const

EIGEN_STRONG_INLINE void inv (MATRIX &outMat) const

EIGEN_STRONG_INLINE void inv_fast (MATRIX &outMat) const

EIGEN_STRONG_INLINE Scalar det () const

MRPT plugin: Multiply and extra addition functions

EIGEN_STRONG_INLINE bool empty () const

EIGEN_STRONG_INLINE void add_Ac (const OTHERMATRIX &m, const Scalar c)

EIGEN_STRONG_INLINE void substract_Ac (const OTHERMATRIX &m, const Scalar c)

EIGEN_STRONG_INLINE void substract_At (const OTHERMATRIX &m)

EIGEN_STRONG_INLINE void substract_An (const OTHERMATRIX &m, const size_t n)

EIGEN_STRONG_INLINE void add_AAt (const OTHERMATRIX &A)

EIGEN_STRONG_INLINE void substract_AAt (const OTHERMATRIX &A)

EIGEN_STRONG_INLINE void multiply (const MATRIX1 &A, const MATRIX2 &B)

EIGEN_STRONG_INLINE void multiply_AB (const MATRIX1 &A, const MATRIX2 &B)

EIGEN_STRONG_INLINE void multiply_AtB (const MATRIX1 &A, const MATRIX2 &B)

EIGEN_STRONG_INLINE void multiply_Ab (const OTHERVECTOR1 &vIn, OTHERVECTOR2 &vOut, bool accumToOutput=false) const

EIGEN_STRONG_INLINE void multiply_Atb (const OTHERVECTOR1 &vIn, OTHERVECTOR2 &vOut, bool accumToOutput=false) const

EIGEN_STRONG_INLINE void multiply_HCHt (const MAT_C &C, MAT_R &R, bool accumResultInOutput=false) const

EIGEN_STRONG_INLINE void multiply_HtCH (const MAT_C &C, MAT_R &R, bool accumResultInOutput=false) const

EIGEN_STRONG_INLINE Scalar multiply_HCHt_scalar (const MAT_C &C) const

EIGEN_STRONG_INLINE Scalar multiply_HtCH_scalar (const MAT_C &C) const

EIGEN_STRONG_INLINE void multiply_AAt_scalar (const MAT_A &A, typename MAT_A::value_type f)

EIGEN_STRONG_INLINE void multiply_AtA_scalar (const MAT_A &A, typename MAT_A::value_type f)

void multiply_A_skew3 (const MAT_A &A, const SKEW_3VECTOR &v)

void multiply_skew3_A (const SKEW_3VECTOR &v, const MAT_A &A)

EIGEN_STRONG_INLINE void multiply_subMatrix (const MAT_A &A, MAT_OUT &outResult, const size_t A_cols_offset, const size_t A_rows_offset, const size_t A_col_count) const

outResult = this * A

void multiply_ABC (const MAT_A &A, const MAT_B &B, const MAT_C &C)

void multiply_ABCt (const MAT_A &A, const MAT_B &B, const MAT_C &C)

void multiply_AtBC (const MAT_A &A, const MAT_B &B, const MAT_C &C)

EIGEN_STRONG_INLINE void multiply_ABt (const MAT_A &A, const MAT_B &B)

EIGEN_STRONG_INLINE void multiply_AAt (const MAT_A &A)

EIGEN_STRONG_INLINE void multiply_AtA (const MAT_A &A)

EIGEN_STRONG_INLINE void multiply_result_is_symmetric (const MAT_A &A, const MAT_B &B)

EIGEN_STRONG_INLINE void leftDivideSquare (const MAT2 &A, MAT3 &RES) const

Matrix left divide: RES = A^-1 * this , with A being squared (using the Eigen::ColPivHouseholderQR method)

EIGEN_STRONG_INLINE void rightDivideSquare (const MAT2 &B, MAT3 &RES) const

Matrix right divide: RES = this * B^-1, with B being squared (using the Eigen::ColPivHouseholderQR method)

MRPT plugin: Eigenvalue / Eigenvectors

EIGEN_STRONG_INLINE void eigenVectors (MATRIX1 &eVecs, MATRIX2 &eVals) const

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), both returned as matrices: eigenvectors are the columns in "eVecs", and eigenvalues in ascending order as the diagonal of "eVals".

EIGEN_STRONG_INLINE void eigenVectorsVec (MATRIX1 &eVecs, VECTOR1 &eVals) const

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), eigenvectors are the columns in "eVecs", and eigenvalues are returned in in ascending order in the vector "eVals".

EIGEN_STRONG_INLINE void eigenValues (VECTOR &eVals) const

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), and return only the eigenvalues in the vector "eVals".

EIGEN_STRONG_INLINE void eigenVectorsSymmetric (MATRIX1 &eVecs, MATRIX2 &eVals) const

[For symmetric matrices only] Compute the eigenvectors and eigenvalues (in no particular order), both returned as matrices: eigenvectors are the columns, and eigenvalues

EIGEN_STRONG_INLINE void eigenVectorsSymmetricVec (MATRIX1 &eVecs, VECTOR1 &eVals) const

[For symmetric matrices only] Compute the eigenvectors and eigenvalues (in no particular order), both returned as matrices: eigenvectors are the columns, and eigenvalues

MRPT plugin: Linear algebra & decomposition-based methods

EIGEN_STRONG_INLINE bool chol (MATRIX &U) const

Cholesky M=U^T * U decomposition for simetric matrix (upper-half of the matrix will be actually ignored)

EIGEN_STRONG_INLINE size_t rank (double threshold=0) const

Gets the rank of the matrix via the Eigen::ColPivHouseholderQR method.

MRPT plugin: Scalar and element-wise extra operators

EIGEN_STRONG_INLINE MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & Sqrt ()

EIGEN_STRONG_INLINE PlainObject Sqrt () const

EIGEN_STRONG_INLINE MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & Abs ()

EIGEN_STRONG_INLINE PlainObject Abs () const

EIGEN_STRONG_INLINE MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & Log ()

EIGEN_STRONG_INLINE PlainObject Log () const

EIGEN_STRONG_INLINE MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & Exp ()

EIGEN_STRONG_INLINE PlainObject Exp () const

EIGEN_STRONG_INLINE MatrixBase
< TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > & Square ()

EIGEN_STRONG_INLINE PlainObject Square () const

void normalize (Scalar valMin, Scalar valMax)

Scales all elements such as the minimum & maximum values are shifted to the given values.

void adjustRange (Scalar valMin, Scalar valMax)

Static Public Member Functions

static const IdentityReturnType Identity ()

static const IdentityReturnType Identity (Index rows, Index cols)

static const BasisReturnType Unit (Index size, Index i)

static const BasisReturnType Unit (Index i)

static const BasisReturnType UnitX ()

static const BasisReturnType UnitY ()

static const BasisReturnType UnitZ ()

static const BasisReturnType UnitW ()

static const ConstantReturnType Constant (Index rows, Index cols, const Scalar &value)

static const ConstantReturnType Constant (Index size, const Scalar &value)

static const ConstantReturnType Constant (const Scalar &value)

static const
SequentialLinSpacedReturnType LinSpaced (Sequential_t, Index size, const Scalar &low, const Scalar &high)

static const
RandomAccessLinSpacedReturnType LinSpaced (Index size, const Scalar &low, const Scalar &high)

static const
SequentialLinSpacedReturnType LinSpaced (Sequential_t, const Scalar &low, const Scalar &high)

static const
RandomAccessLinSpacedReturnType LinSpaced (const Scalar &low, const Scalar &high)

static const CwiseNullaryOp
< CustomNullaryOp,
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > NullaryExpr (Index rows, Index cols, const CustomNullaryOp &func)

static const CwiseNullaryOp
< CustomNullaryOp,
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > NullaryExpr (Index size, const CustomNullaryOp &func)

static const CwiseNullaryOp
< CustomNullaryOp,
TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > > NullaryExpr (const CustomNullaryOp &func)

static const ConstantReturnType Zero (Index rows, Index cols)

static const ConstantReturnType Zero (Index size)

static const ConstantReturnType Zero ()

static const ConstantReturnType Ones (Index rows, Index cols)

static const ConstantReturnType Ones (Index size)

static const ConstantReturnType Ones ()

static const CwiseNullaryOp
< internal::scalar_random_op
< Scalar >, TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > Random (Index rows, Index cols)

static const CwiseNullaryOp
< internal::scalar_random_op
< Scalar >, TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > Random (Index size)

static const CwiseNullaryOp
< internal::scalar_random_op
< Scalar >, TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > Random ()

Protected Member Functions

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator+= (const ArrayBase< OtherDerived > &)

TriangularProduct< Mode,
LhsIsTriangular, Lhs, false,
Rhs, false > & operator-= (const ArrayBase< OtherDerived > &)

void checkTransposeAliasing (const OtherDerived &other) const

Protected Attributes

const LhsNested m_lhs

const RhsNested m_rhs

PlainObject

m_result

Friends

const ScalarMultipleReturnType operator* (const Scalar &scalar, const StorageBaseType &matrix)

const CwiseUnaryOp
< internal::scalar_multiple2_op
< Scalar, std::complex< Scalar >
>, const TriangularProduct
< Mode, LhsIsTriangular, Lhs,
false, Rhs, false > > operator* (const std::complex< Scalar > &scalar, const StorageBaseType &matrix)

MRPT plugin: Basic iterators. These iterators are intended for 1D matrices only, i.e. column or row vectors.

EIGEN_STRONG_INLINE iterator begin ()

EIGEN_STRONG_INLINE const_iterator begin () const

EIGEN_STRONG_INLINE iterator end ()

EIGEN_STRONG_INLINE const_iterator end () const

typedef Scalar * iterator

typedef const Scalar * const_iterator

Member Typedef Documentation

typedef internal::remove_all<ActualLhsType>::type Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::_ActualLhsType [inherited]

Definition at line 87 of file Core.

typedef internal::remove_all<ActualRhsType>::type Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::_ActualRhsType [inherited]

Definition at line 94 of file Core.

typedef internal::remove_all<LhsNested>::type Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::_LhsNested [inherited]

Definition at line 84 of file Core.

typedef internal::remove_all<RhsNested>::type Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::_RhsNested [inherited]

Definition at line 91 of file Core.

typedef LhsBlasTraits::DirectLinearAccessType Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::ActualLhsType [inherited]

Definition at line 86 of file Core.

typedef RhsBlasTraits::DirectLinearAccessType Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::ActualRhsType [inherited]

Definition at line 93 of file Core.

typedef MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::Base [inherited]

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 80 of file Core.

typedef Base::CoeffReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::CoeffReturnType [inherited]

Definition at line 102 of file Core.

typedef VectorwiseOp<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Vertical> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ColwiseReturnType [inherited]

Definition at line 462 of file Core.

typedef const Scalar* Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::const_iterator [inherited]

Definition at line 45 of file Core.

typedef const VectorwiseOp<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Vertical> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstColwiseReturnType [inherited]

Definition at line 463 of file Core.

typedef const Diagonal<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstDiagonalReturnType [inherited]

Definition at line 228 of file Core.

typedef const Reverse<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , BothDirections> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstReverseReturnType [inherited]

Definition at line 494 of file Core.

typedef const VectorwiseOp<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Horizontal> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstRowwiseReturnType [inherited]

Definition at line 461 of file Core.

typedef const VectorBlock<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstSegmentReturnType [inherited]

Definition at line 299 of file Core.

typedef Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ColsAtCompileTime==1 ? SizeMinusOne : 1, internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ColsAtCompileTime==1 ? 1 : SizeMinusOne> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstStartMinusOne [inherited]

Definition at line 431 of file Core.

typedef const Transpose<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ConstTransposeReturnType [inherited]

Definition at line 288 of file Core.

typedef Diagonal<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::DiagonalReturnType [inherited]

Definition at line 226 of file Core.

typedef CoeffBasedProduct<LhsNested, RhsNested, 0> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::FullyLazyCoeffBaseProductType [inherited]

Definition at line 98 of file Core.

typedef CwiseUnaryOp<internal::scalar_quotient1_op<typename internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar>, const ConstStartMinusOne > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::HNormalizedReturnType [inherited]

Definition at line 433 of file Core.

typedef Homogeneous<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , HomogeneousReturnTypeDirection> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::HomogeneousReturnType [inherited]

Definition at line 422 of file Core.

typedef internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Index Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Index [inherited]

The type of indices.

To change this, #define the preprocessor symbol EIGEN_DEFAULT_DENSE_INDEX_TYPE.

See also:: TopicPreprocessorDirectives.

Definition at line 65 of file Core.

typedef Scalar* Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::iterator [inherited]

Definition at line 44 of file Core.

typedef internal::blas_traits<_LhsNested> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::LhsBlasTraits [inherited]

Definition at line 85 of file Core.

typedef Lhs::Nested Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::LhsNested [inherited]

Definition at line 83 of file Core.

typedef internal::traits<Lhs>::Scalar Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::LhsScalar [inherited]

Definition at line 88 of file Core.

typedef internal::packet_traits<Scalar>::type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::PacketScalar [inherited]

Definition at line 68 of file Core.

typedef Base::PlainObject Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::PlainObject [inherited]

The plain matrix type corresponding to this expression.

This is not necessarily exactly the return type of eval(). In the case of plain matrices, the return type of eval() is a const reference to a matrix, not a matrix! It is however guaranteed that the return type of eval() is either PlainObject or const PlainObject&.

Reimplemented from Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 102 of file Core.

typedef NumTraits<Scalar>::Real Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::RealScalar [inherited]

Definition at line 69 of file Core.

typedef Reverse<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , BothDirections> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ReverseReturnType [inherited]

Definition at line 493 of file Core.

typedef internal::blas_traits<_RhsNested> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::RhsBlasTraits [inherited]

Definition at line 92 of file Core.

typedef Rhs::Nested Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::RhsNested [inherited]

Definition at line 90 of file Core.

typedef internal::traits<Rhs>::Scalar Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::RhsScalar [inherited]

Definition at line 95 of file Core.

typedef VectorwiseOp<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Horizontal> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::RowwiseReturnType [inherited]

Definition at line 460 of file Core.

typedef internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar [inherited]

Definition at line 67 of file Core.

typedef VectorBlock<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::SegmentReturnType [inherited]

Definition at line 298 of file Core.

typedef internal::stem_function<Scalar>::type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::StemFunction [inherited]

Definition at line 461 of file Core.

typedef internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::StorageKind Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::StorageKind [inherited]

Definition at line 57 of file Core.

typedef Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::value_type [inherited]

Type of the elements.

Definition at line 36 of file Core.

Member Enumeration Documentation

anonymous enum [inherited]

Definition at line 104 of file Core.

anonymous enum [inherited]

Definition at line 185 of file Core.

anonymous enum [inherited]

Definition at line 38 of file Core.

anonymous enum [inherited]

Definition at line 421 of file Core.

anonymous enum [inherited]

Definition at line 426 of file Core.

Constructor & Destructor Documentation

template<int Mode, bool LhsIsTriangular, typename Lhs , typename Rhs >

Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >::TriangularProduct	(	const Lhs &	lhs,
		const Rhs &	rhs
	)		`[inline]`

Definition at line 378 of file Core.

Member Function Documentation

EIGEN_STRONG_INLINE MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Abs ( ) [inline, inherited]

Definition at line 740 of file Core.

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Abs ( ) const [inline, inherited]

Definition at line 741 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::add_AAt ( const OTHERMATRIX & A ) [inline, inherited]

this += A + A^T

Definition at line 518 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::add_Ac	(	const OTHERMATRIX &	m,
		const Scalar	c
	)		`[inline, inherited]`

Add c (scalar) times A to this matrix: this += A * c

Definition at line 507 of file Core.

void Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::addTo ( Dest & dst ) const [inline, inherited]

Definition at line 119 of file Core.

const AdjointReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::adjoint ( ) const [inherited]

Returns:: an expression of the adjoint (i.e. conjugate transpose) of *this.

Example:

Output:

Warning:

If you want to replace a matrix by its own adjoint, do NOT do this:

 m = m.adjoint(); // bug!!! caused by aliasing effect

Instead, use the adjointInPlace() method:

 m.adjointInPlace();

which gives Eigen good opportunities for optimization, or alternatively you can also do:

 m = m.adjoint().eval();

See also:: adjointInPlace(), transpose(), conjugate(), class Transpose, class internal::scalar_conjugate_op

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::adjointInPlace ( ) [inherited]

This is the "in place" version of adjoint(): it replaces *this by its own transpose.

Thus, doing

 m.adjointInPlace();

has the same effect on m as doing

 m = m.adjoint().eval();

and is faster and also safer because in the latter line of code, forgetting the eval() results in a bug caused by aliasing.

Notice however that this method is only useful if you want to replace a matrix by its own adjoint. If you just need the adjoint of a matrix, use adjoint().

Note:: if the matrix is not square, then *this must be a resizable matrix.

See also:: transpose(), adjoint(), transposeInPlace()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::adjustRange	(	Scalar	valMin,
		Scalar	valMax
	)		`[inline, inherited]`

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

Definition at line 764 of file Core.

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::all ( void ) const [inherited]

Returns:: true if all coefficients are true

Example:

Output:

See also:: any(), Cwise::operator<()

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::any ( void ) const [inherited]

Returns:: true if at least one coefficient is true

See also:: all()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyHouseholderOnTheLeft	(	const EssentialPart &	essential,
		const Scalar &	tau,
		Scalar *	workspace
	)		`[inherited]`

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyHouseholderOnTheRight	(	const EssentialPart &	essential,
		const Scalar &	tau,
		Scalar *	workspace
	)		`[inherited]`

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyOnTheLeft ( const EigenBase< OtherDerived > & other ) [inherited]

replaces *this by *this * other.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyOnTheLeft	(	Index	p,
		Index	q,
		const JacobiRotation< OtherScalar > &	j
	)		`[inherited]`

Applies the rotation in the plane j to the rows p and q of *this, i.e., it computes B = J * B, with $B = \left ( \begin{array}{cc} \text{*this.row}(p) \\ \text{*this.row}(q) \end{array} \right )$ .

See also:: class JacobiRotation, MatrixBase::applyOnTheRight(), internal::apply_rotation_in_the_plane()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyOnTheRight ( const EigenBase< OtherDerived > & other ) [inherited]

replaces *this by *this * other.

It is equivalent to MatrixBase::operator*=()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::applyOnTheRight	(	Index	p,
		Index	q,
		const JacobiRotation< OtherScalar > &	j
	)		`[inherited]`

Applies the rotation in the plane j to the columns p and q of *this, i.e., it computes B = B * J with $B = \left ( \begin{array}{cc} \text{*this.col}(p) & \text{*this.col}(q) \end{array} \right )$ .

See also:: class JacobiRotation, MatrixBase::applyOnTheLeft(), internal::apply_rotation_in_the_plane()

ArrayWrapper<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::array ( ) [inline, inherited]

Returns:: an Array expression of this matrix

See also:: ArrayBase::matrix()

Definition at line 332 of file Core.

const ArrayWrapper<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::array ( ) const [inline, inherited]

Definition at line 333 of file Core.

const DiagonalWrapper<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::asDiagonal ( ) const [inherited]

Returns:: a pseudo-expression of a diagonal matrix with *this as vector of diagonal coefficients

Example:

Output:

See also:: class DiagonalWrapper, class DiagonalMatrix, diagonal(), isDiagonal()

const PermutationWrapper<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::asPermutation ( ) const [inherited]

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::assign	(	size_t	N,
		const Scalar	v
	)		`[inline, inherited]`

Resize to N and set all the elements to a given value

Definition at line 64 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::assign ( const Scalar v ) [inline, inherited]

Fill all the elements with a given value

Definition at line 62 of file Core.

EIGEN_STRONG_INLINE iterator Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::begin ( ) [inline, inherited]

Definition at line 47 of file Core.

EIGEN_STRONG_INLINE const_iterator Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::begin ( ) const [inline, inherited]

Definition at line 49 of file Core.

EIGEN_STRONG_INLINE const CwiseBinaryOp<CustomBinaryOp, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::binaryExpr	(	const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > &	other,
		const CustomBinaryOp &	func = `CustomBinaryOp()`
	)		const `[inline, inherited]`

Returns:: an expression of the difference of *this and other

Note:: If you want to substract a given scalar from all coefficients, see Cwise::operator-().

See also:: class CwiseBinaryOp, operator-=()

Returns:: an expression of the sum of *this and other

Note:: If you want to add a given scalar to all coefficients, see Cwise::operator+().

See also:: class CwiseBinaryOp, operator+=()

Returns:: an expression of a custom coefficient-wise operator func of *this and other

The template parameter CustomBinaryOp is the type of the functor of the custom operator (see class CwiseBinaryOp for an example)

Here is an example illustrating the use of custom functors:

Output:

See also:: class CwiseBinaryOp, operator+(), operator-(), cwiseProduct()

Definition at line 58 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::block	(	Index	startRow,
		Index	startCol,
		Index	blockRows,
		Index	blockCols
	)		`[inline, inherited]`

Returns:: a dynamic-size expression of a block in *this.

Parameters:

startRow	the first row in the block
startCol	the first column in the block
blockRows	the number of rows in the block
blockCols	the number of columns in the block

Example:

Output:

Note:: Even though the returned expression has dynamic size, in the case when it is applied to a fixed-size matrix, it inherits a fixed maximal size, which means that evaluating it does not cause a dynamic memory allocation.

See also:: class Block, block(Index,Index)

Definition at line 70 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::block	(	Index	startRow,
		Index	startCol,
		Index	blockRows,
		Index	blockCols
	)		const `[inline, inherited]`

This is the const version of block(Index,Index,Index,Index).

Definition at line 76 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , BlockRows, BlockCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::block	(	Index	startRow,
		Index	startCol
	)		`[inline, inherited]`

Returns:: a fixed-size expression of a block in *this.

The template parameters BlockRows and BlockCols are the number of rows and columns in the block.

Parameters:

startRow	the first row in the block
startCol	the first column in the block

Example:

Output:

Note:

since block is a templated member, the keyword template has to be used if the matrix type is also a template parameter:

 m.template block<3,3>(1,1);

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 550 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , BlockRows, BlockCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::block	(	Index	startRow,
		Index	startCol
	)		const `[inline, inherited]`

This is the const version of block<>(Index, Index).

Definition at line 557 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::blueNorm ( ) const [inherited]

Returns:: the l2 norm of *this using the Blue's algorithm. A Portable Fortran Program to Find the Euclidean Norm of a Vector, ACM TOMS, Vol 4, Issue 1, 1978.

For architecture/scalar types without vectorization, this version is much faster than stableNorm(). Otherwise the stableNorm() is faster.

See also:: norm(), stableNorm(), hypotNorm()

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomLeftCorner	(	Index	cRows,
		Index	cCols
	)		`[inline, inherited]`

Returns:: a dynamic-size expression of a bottom-left corner of *this.

Parameters:

cRows	the number of rows in the corner
cCols	the number of columns in the corner

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 230 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomLeftCorner	(	Index	cRows,
		Index	cCols
	)		const `[inline, inherited]`

This is the const version of bottomLeftCorner(Index, Index).

Definition at line 236 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomLeftCorner ( ) [inline, inherited]

Returns:: an expression of a fixed-size bottom-left corner of *this.

The template parameters CRows and CCols are the number of rows and columns in the corner.

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 251 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomLeftCorner ( ) const [inline, inherited]

This is the const version of bottomLeftCorner<int, int>().

Definition at line 258 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRightCorner	(	Index	cRows,
		Index	cCols
	)		`[inline, inherited]`

Returns:: a dynamic-size expression of a bottom-right corner of *this.

Parameters:

cRows	the number of rows in the corner
cCols	the number of columns in the corner

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 185 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRightCorner	(	Index	cRows,
		Index	cCols
	)		const `[inline, inherited]`

This is the const version of bottomRightCorner(Index, Index).

Definition at line 191 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRightCorner ( ) [inline, inherited]

Returns:: an expression of a fixed-size bottom-right corner of *this.

The template parameters CRows and CCols are the number of rows and columns in the corner.

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 206 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRightCorner ( ) const [inline, inherited]

This is the const version of bottomRightCorner<int, int>().

Definition at line 213 of file Core.

RowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRows ( Index n ) [inline, inherited]

Returns:: a block consisting of the bottom rows of *this.

Parameters:

n	the number of rows in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 318 of file Core.

ConstRowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRows ( Index n ) const [inline, inherited]

This is the const version of bottomRows(Index).

Definition at line 324 of file Core.

NRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRows ( ) [inline, inherited]

Returns:: a block consisting of the bottom rows of *this.

Template Parameters:

N	the number of rows in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 339 of file Core.

ConstNRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::bottomRows ( ) const [inline, inherited]

This is the const version of bottomRows<int>().

Definition at line 346 of file Core.

internal::cast_return_type<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,const CwiseUnaryOp<internal::scalar_cast_op<typename internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar, NewType>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > >::type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cast ( ) const [inline, inherited]

Returns:: an expression of *this with the Scalar type casted to NewScalar.

The template parameter NewScalar is the type we are casting the scalars to.

See also:: class CwiseUnaryOp

Definition at line 108 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::checkTransposeAliasing ( const OtherDerived & other ) const [protected, inherited]

EIGEN_STRONG_INLINE bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::chol ( MATRIX & U ) const [inline, inherited]

Cholesky M=U^T * U decomposition for simetric matrix (upper-half of the matrix will be actually ignored)

Definition at line 711 of file Core.

Base::CoeffReturnType Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::coeff ( Index i ) const [inline, inherited]

Definition at line 160 of file Core.

Base::CoeffReturnType Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::coeff	(	Index	row,
		Index	col
	)		const `[inline, inherited]`

Definition at line 149 of file Core.

const Scalar& Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::coeffRef ( Index i ) const [inline, inherited]

Definition at line 174 of file Core.

const Scalar& Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::coeffRef	(	Index	row,
		Index	col
	)		const `[inline, inherited]`

Definition at line 167 of file Core.

ColXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::col ( Index i ) [inline, inherited]

Returns:: an expression of the i-th column of *this. Note that the numbering starts at 0.

Example:

Output:

See also:: row(), class Block

Definition at line 568 of file Core.

ConstColXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::col ( Index i ) const [inline, inherited]

This is the const version of col().

Definition at line 574 of file Core.

const ColPivHouseholderQR<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::colPivHouseholderQr ( ) const [inherited]

Returns:: the column-pivoting Householder QR decomposition of *this.

See also:: class ColPivHouseholderQR

Index Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::cols ( void ) const [inline, inherited]

Definition at line 113 of file Core.

ConstColwiseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::colwise ( ) const [inherited]

Returns:: a VectorwiseOp wrapper of *this providing additional partial reduction operations

Example:

Output:

See also:: rowwise(), class VectorwiseOp

ColwiseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::colwise ( ) [inherited]

Returns:: a writable VectorwiseOp wrapper of *this providing additional partial reduction operations

See also:: rowwise(), class VectorwiseOp

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::computeInverseAndDetWithCheck	(	ResultType &	inverse,
		typename ResultType::Scalar &	determinant,
		bool &	invertible,
		const RealScalar &	absDeterminantThreshold = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Computation of matrix inverse and determinant, with invertibility check.

This is only for fixed-size square matrices of size up to 4x4.

Parameters:

inverse	Reference to the matrix in which to store the inverse.
determinant	Reference to the variable in which to store the inverse.
invertible	Reference to the bool variable in which to store whether the matrix is invertible.
absDeterminantThreshold	Optional parameter controlling the invertibility check. The matrix will be declared invertible if the absolute value of its determinant is greater than this threshold.

Example:

Output:

See also:: inverse(), computeInverseWithCheck()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::computeInverseWithCheck	(	ResultType &	inverse,
		bool &	invertible,
		const RealScalar &	absDeterminantThreshold = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Computation of matrix inverse, with invertibility check.

This is only for fixed-size square matrices of size up to 4x4.

Parameters:

inverse	Reference to the matrix in which to store the inverse.
invertible	Reference to the bool variable in which to store whether the matrix is invertible.
absDeterminantThreshold	Optional parameter controlling the invertibility check. The matrix will be declared invertible if the absolute value of its determinant is greater than this threshold.

Example:

Output:

See also:: inverse(), computeInverseAndDetWithCheck()

ConjugateReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::conjugate ( ) const [inline, inherited]

Returns:: an expression of the complex conjugate of *this.

See also:: adjoint()

Definition at line 117 of file Core.

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Constant	(	Index	rows,
		Index	cols,
		const Scalar &	value
	)		`[static, inherited]`

Returns:: an expression of a constant matrix of value value

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this DenseBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Zero() should be used instead.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Constant	(	Index	size,
		const Scalar &	value
	)		`[static, inherited]`

Returns:: an expression of a constant matrix of value value

The parameter size is the size of the returned vector. Must be compatible with this DenseBase type.

This variant is meant to be used for dynamic-size vector types. For fixed-size types, it is redundant to pass size as argument, so Zero() should be used instead.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Constant ( const Scalar & value ) [static, inherited]

Returns:: an expression of a constant matrix of value value

This variant is only for fixed-size DenseBase types. For dynamic-size types, you need to use the variants taking size arguments.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

const MatrixFunctionReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cos ( ) const [inherited]

const MatrixFunctionReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cosh ( ) const [inherited]

Index Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::count ( void ) const [inherited]

Returns:: the number of coefficients which evaluate to true

See also:: all(), any()

EIGEN_STRONG_INLINE size_t Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::countNonZero ( ) const [inline, inherited]

Definition at line 190 of file Core.

cross_product_return_type<OtherDerived>::type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cross ( const MatrixBase< OtherDerived > & other ) const [inherited]

Returns:: the cross product of *this and other

Here is a very good explanation of cross-product: http://xkcd.com/199/

See also:: MatrixBase::cross3()

PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cross3 ( const MatrixBase< OtherDerived > & other ) const [inherited]

Returns:: the cross product of *this and other using only the x, y, and z coefficients

The size of *this and other must be four. This function is especially useful when using 4D vectors instead of 3D ones to get advantage of SSE/AltiVec vectorization.

See also:: MatrixBase::cross()

EIGEN_STRONG_INLINE const CwiseUnaryOp<internal::scalar_abs_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseAbs ( ) const [inline, inherited]

Returns:: an expression of the coefficient-wise absolute value of *this

Example:

Output:

See also:: cwiseAbs2()

Definition at line 37 of file Core.

EIGEN_STRONG_INLINE const CwiseUnaryOp<internal::scalar_abs2_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseAbs2 ( ) const [inline, inherited]

Returns:: an expression of the coefficient-wise squared absolute value of *this

Example:

Output:

See also:: cwiseAbs()

Definition at line 47 of file Core.

const CwiseBinaryOp<std::equal_to<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseEqual ( const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > & other ) const [inline, inherited]

Returns:: an expression of the coefficient-wise == operator of *this and other

Warning:: this performs an exact comparison, which is generally a bad idea with floating-point types. In order to check for equality between two vectors or matrices with floating-point coefficients, it is generally a far better idea to use a fuzzy comparison as provided by isApprox() and isMuchSmallerThan().

Example:

Output:

See also:: cwiseNotEqual(), isApprox(), isMuchSmallerThan()

Definition at line 57 of file Core.

const CwiseUnaryOp<std::binder1st<std::equal_to<Scalar> >, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseEqual ( const Scalar & s ) const [inline, inherited]

Returns:: an expression of the coefficient-wise == operator of *this and a scalar s

Warning:: this performs an exact comparison, which is generally a bad idea with floating-point types. In order to check for equality between two vectors or matrices with floating-point coefficients, it is generally a far better idea to use a fuzzy comparison as provided by isApprox() and isMuchSmallerThan().

See also:: cwiseEqual(const MatrixBase<OtherDerived> &) const

Definition at line 79 of file Core.

const CwiseUnaryOp<internal::scalar_inverse_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseInverse ( ) const [inline, inherited]

Returns:: an expression of the coefficient-wise inverse of *this.

Example:

Output:

See also:: cwiseProduct()

Definition at line 67 of file Core.

EIGEN_STRONG_INLINE const CwiseBinaryOp<internal::scalar_max_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseMax ( const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > & other ) const [inline, inherited]

Returns:: an expression of the coefficient-wise max of *this and other

Example:

Output:

See also:: class CwiseBinaryOp, min()

Definition at line 104 of file Core.

EIGEN_STRONG_INLINE const CwiseBinaryOp<internal::scalar_min_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseMin ( const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > & other ) const [inline, inherited]

Returns:: an expression of the coefficient-wise min of *this and other

Example:

Output:

See also:: class CwiseBinaryOp, max()

Definition at line 90 of file Core.

const CwiseBinaryOp<std::not_equal_to<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseNotEqual ( const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > & other ) const [inline, inherited]

Returns:: an expression of the coefficient-wise != operator of *this and other

Warning:: this performs an exact comparison, which is generally a bad idea with floating-point types. In order to check for equality between two vectors or matrices with floating-point coefficients, it is generally a far better idea to use a fuzzy comparison as provided by isApprox() and isMuchSmallerThan().

Example:

Output:

See also:: cwiseEqual(), isApprox(), isMuchSmallerThan()

Definition at line 76 of file Core.

EIGEN_STRONG_INLINE const CwiseBinaryOp<internal::scalar_quotient_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , const OtherDerived> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseQuotient ( const EIGEN_CURRENT_STORAGE_BASE_CLASS< OtherDerived > & other ) const [inline, inherited]

Returns:: an expression of the coefficient-wise quotient of *this and other

Example:

Output:

See also:: class CwiseBinaryOp, cwiseProduct(), cwiseInverse()

Definition at line 118 of file Core.

const CwiseUnaryOp<internal::scalar_sqrt_op<Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::cwiseSqrt ( ) const [inline, inherited]

Returns:: an expression of the coefficient-wise square root of *this.

Example:

Output:

See also:: cwisePow(), cwiseSquare()

Definition at line 57 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::det ( ) const [inline, inherited]

Definition at line 496 of file Core.

Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::determinant ( ) const [inherited]

Returns:: the determinant of this matrix

const Diagonal<const FullyLazyCoeffBaseProductType,0> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::diagonal ( ) const [inline, inherited]

This is the const version of diagonal().

This is the const version of diagonal<int>().

Reimplemented from Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 138 of file Core.

const Diagonal<FullyLazyCoeffBaseProductType,Index> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::diagonal ( ) const [inline, inherited]

This is the const version of diagonal().

This is the const version of diagonal<int>().

Reimplemented from Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 142 of file Core.

DiagonalReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::diagonal ( ) [inherited]

Returns:: an expression of the main diagonal of the matrix *this

*this is not required to be square.

Example:

Output:

See also:: class Diagonal

Returns:: an expression of the DiagIndex-th sub or super diagonal of the matrix *this

*this is not required to be square.

The template parameter DiagIndex represent a super diagonal if DiagIndex > 0 and a sub diagonal otherwise. DiagIndex == 0 is equivalent to the main diagonal.

Example:

Output:

See also:: MatrixBase::diagonal(), class Diagonal

const Diagonal<FullyLazyCoeffBaseProductType,Dynamic> Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::diagonal ( Index index ) const [inline, inherited]

This is the const version of diagonal(Index).

Reimplemented from Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 145 of file Core.

DiagonalIndexReturnType<Dynamic>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::diagonal ( Index index ) [inherited]

Returns:: an expression of the DiagIndex-th sub or super diagonal of the matrix *this

*this is not required to be square.

The template parameter DiagIndex represent a super diagonal if DiagIndex > 0 and a sub diagonal otherwise. DiagIndex == 0 is equivalent to the main diagonal.

Example:

Output:

See also:: MatrixBase::diagonal(), class Diagonal

Index Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::diagonalSize ( ) const [inline, inherited]

Returns:: the size of the main diagonal, which is min(rows(),cols()).

See also:: rows(), cols(), SizeAtCompileTime.

Definition at line 115 of file Core.

internal::scalar_product_traits<typename internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar,typename internal::traits<OtherDerived>::Scalar>::ReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::dot ( const MatrixBase< OtherDerived > & other ) const [inherited]

Returns:: the dot product of *this with other.

Note:: If the scalar type is complex numbers, then this function returns the hermitian (sesquilinear) dot product, conjugate-linear in the first variable and linear in the second variable.

See also:: squaredNorm(), norm()

EIGEN_STRONG_INLINE const Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::EIGEN_CWISE_PRODUCT_RETURN_TYPE	(	TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >	,
		OtherDerived
	)		const `[inline, inherited]`

Returns:: an expression of the Schur product (coefficient wise product) of *this and other

Example:

Output:

See also:: class CwiseBinaryOp, cwiseAbs2

Definition at line 37 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenValues ( VECTOR & eVals ) const [inline, inherited]

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), and return only the eigenvalues in the vector "eVals".

Note:: Warning: Only the real part of complex eigenvectors and eigenvalues are returned.

See also:: eigenVectorsSymmetric, eigenVectorsVec

Definition at line 683 of file Core.

EigenvaluesReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenvalues ( ) const [inherited]

Computes the eigenvalues of a matrix.

Returns:: Column vector containing the eigenvalues.

This function computes the eigenvalues with the help of the EigenSolver class (for real matrices) or the ComplexEigenSolver class (for complex matrices).

The eigenvalues are repeated according to their algebraic multiplicity, so there are as many eigenvalues as rows in the matrix.

The SelfAdjointView class provides a better algorithm for selfadjoint matrices.

Example:

Output:

See also:: EigenSolver::eigenvalues(), ComplexEigenSolver::eigenvalues(), SelfAdjointView::eigenvalues()

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenVectors	(	MATRIX1 &	eVecs,
		MATRIX2 &	eVals
	)		const `[inherited]`

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), both returned as matrices: eigenvectors are the columns in "eVecs", and eigenvalues in ascending order as the diagonal of "eVals".

Compute the eigenvectors and eigenvalues, both returned as matrices: eigenvectors are the columns, and eigenvalues.

Note:: Warning: Only the real part of complex eigenvectors and eigenvalues are returned.

See also:: eigenVectorsSymmetric, eigenVectorsVec

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenVectorsSymmetric	(	MATRIX1 &	eVecs,
		MATRIX2 &	eVals
	)		const `[inherited]`

[For symmetric matrices only] Compute the eigenvectors and eigenvalues (in no particular order), both returned as matrices: eigenvectors are the columns, and eigenvalues

Compute the eigenvectors and eigenvalues, both returned as matrices: eigenvectors are the columns, and eigenvalues.

See also:: eigenVectors

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenVectorsSymmetricVec	(	MATRIX1 &	eVecs,
		VECTOR1 &	eVals
	)		const `[inherited]`

[For symmetric matrices only] Compute the eigenvectors and eigenvalues (in no particular order), both returned as matrices: eigenvectors are the columns, and eigenvalues

Compute the eigenvectors and eigenvalues, both returned as matrices: eigenvectors are the columns, and eigenvalues.

See also:: eigenVectorsVec

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eigenVectorsVec	(	MATRIX1 &	eVecs,
		VECTOR1 &	eVals
	)		const `[inherited]`

[For square matrices only] Compute the eigenvectors and eigenvalues (sorted), eigenvectors are the columns in "eVecs", and eigenvalues are returned in in ascending order in the vector "eVals".

Compute the eigenvectors and eigenvalues, both returned as matrices: eigenvectors are the columns, and eigenvalues.

Note:: Warning: Only the real part of complex eigenvectors and eigenvalues are returned.

See also:: eigenVectorsSymmetric, eigenVectorsVec

EIGEN_STRONG_INLINE bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::empty ( ) const [inline, inherited]

Definition at line 504 of file Core.

EIGEN_STRONG_INLINE iterator Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::end ( ) [inline, inherited]

Definition at line 48 of file Core.

EIGEN_STRONG_INLINE const_iterator Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::end ( ) const [inline, inherited]

Definition at line 50 of file Core.

Matrix<Scalar,3,1> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eulerAngles	(	Index	a0,
		Index	a1,
		Index	a2
	)		const `[inherited]`

Returns:: the Euler-angles of the rotation matrix *this using the convention defined by the triplet (a0,a1,a2)

Each of the three parameters a0,a1,a2 represents the respective rotation axis as an integer in {0,1,2}. For instance, in:

 Vector3f ea = mat.eulerAngles(2, 0, 2);

"2" represents the z axis and "0" the x axis, etc. The returned angles are such that we have the following equality:

 mat == AngleAxisf(ea[0], Vector3f::UnitZ())
      * AngleAxisf(ea[1], Vector3f::UnitX())
      * AngleAxisf(ea[2], Vector3f::UnitZ());

This corresponds to the right-multiply conventions (with right hand side frames).

EIGEN_STRONG_INLINE const internal::eval<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eval ( ) const [inline, inherited]

Returns:: the matrix or vector obtained by evaluating this expression.

Notice that in the case of a plain matrix or vector (not an expression) this function just returns a const reference, in order to avoid a useless copy.

Definition at line 385 of file Core.

void Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::evalTo ( Dest & dst ) const [inline, inherited]

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 116 of file Core.

const MatrixExponentialReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::exp ( ) const [inherited]

EIGEN_STRONG_INLINE MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Exp ( ) [inline, inherited]

Definition at line 746 of file Core.

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Exp ( ) const [inline, inherited]

Definition at line 747 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractCol	(	size_t	nCol,
		VECTOR &	v,
		size_t	startingRow = `0`
	)		const `[inline, inherited]`

Extract one column from the matrix into a column vector.

Definition at line 787 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractCol	(	size_t	nCol,
		std::vector< T > &	v,
		size_t	startingRow = `0`
	)		const `[inline, inherited]`

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

Definition at line 791 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractMatrix	(	const size_t	firstRow,
		const size_t	firstCol,
		MATRIX &	m
	)		const `[inline, inherited]`

Definition at line 797 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractMatrix	(	const size_t	firstRow,
		const size_t	firstCol,
		const size_t	nRows,
		const size_t	nCols,
		MATRIX &	m
	)		const `[inline, inherited]`

Definition at line 801 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractRow	(	size_t	nRow,
		Eigen::EigenBase< OtherDerived > &	v,
		size_t	startingCol = `0`
	)		const `[inline, inherited]`

Extract one row from the matrix into a row vector.

Definition at line 770 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractRow	(	size_t	nRow,
		std::vector< T > &	v,
		size_t	startingCol = `0`
	)		const `[inline, inherited]`

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

Definition at line 774 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractRowAsCol	(	size_t	nRow,
		VECTOR &	v,
		size_t	startingCol = `0`
	)		const `[inline, inherited]`

Extract one row from the matrix into a column vector.

Definition at line 780 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractSubmatrix	(	const size_t	row_first,
		const size_t	row_last,
		const size_t	col_first,
		const size_t	col_last,
		MATRIX &	out
	)		const `[inline, inherited]`

Get a submatrix, given its bounds: first & last column and row (inclusive).

Definition at line 809 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractSubmatrixSymmetrical	(	const std::vector< size_t > &	indices,
		MATRIX &	out
	)		const `[inline, inherited]`

Get a submatrix from a square matrix, by collecting the elements M(idxs,idxs), where idxs is the sequence of indices passed as argument.

A perfect application of this method is in extracting covariance matrices of a subset of variables from the full covariance matrix.

See also:: extractSubmatrix, extractSubmatrixSymmetricalBlocks

Definition at line 852 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::extractSubmatrixSymmetricalBlocks	(	const size_t	block_size,
		const std::vector< size_t > &	block_indices,
		MATRIX &	out
	)		const `[inline, inherited]`

Get a submatrix from a square matrix, by collecting the elements M(idxs,idxs), where idxs is a sequence {block_indices(i):block_indices(i)+block_size-1} for all "i" up to the size of block_indices.

A perfect application of this method is in extracting covariance matrices of a subset of variables from the full covariance matrix.

See also:: extractSubmatrix, extractSubmatrixSymmetrical

Definition at line 820 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::eye ( ) [inline, inherited]

Make the matrix an identity matrix.

Definition at line 84 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::fill ( const Scalar & value ) [inherited]

Alias for setConstant(): sets all coefficients in this expression to value.

See also:: setConstant(), Constant(), class CwiseNullaryOp

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::fill ( const Scalar v ) [inline, inherited]

Fill all the elements with a given value

Definition at line 59 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::find_index_max_value	(	size_t &	u,
		size_t &	v,
		Scalar &	valMax
	)		const `[inline, inherited]`

[VECTORS OR MATRICES] Finds the maximum value (and the corresponding zero-based index) from a given container.

Exceptions:

std::exception On an empty input vector

Definition at line 237 of file Core.

const Flagged<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Added, Removed> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::flagged ( ) const [inherited]

Returns:: an expression of *this with added and removed flags

This is mostly for internal use.

See also:: class Flagged

const ForceAlignedAccess<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::forceAlignedAccess ( ) const [inline, inherited]

Returns:: an expression of *this with forced aligned access

See also:: forceAlignedAccessIf(),class ForceAlignedAccess

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

ForceAlignedAccess<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::forceAlignedAccess ( ) [inline, inherited]

Returns:: an expression of *this with forced aligned access

See also:: forceAlignedAccessIf(), class ForceAlignedAccess

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

internal::add_const_on_value_type<typename internal::conditional<Enable,ForceAlignedAccess<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >,TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > &>::type>::type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::forceAlignedAccessIf ( ) const [inline, inherited]

Returns:: an expression of *this with forced aligned access if Enable is true.

See also:: forceAlignedAccess(), class ForceAlignedAccess

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

internal::conditional<Enable,ForceAlignedAccess<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >,TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > &>::type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::forceAlignedAccessIf ( ) [inline, inherited]

Returns:: an expression of *this with forced aligned access if Enable is true.

See also:: forceAlignedAccess(), class ForceAlignedAccess

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

const WithFormat<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::format ( const IOFormat & fmt ) const [inline, inherited]

Returns:: a WithFormat proxy object allowing to print a matrix the with given format fmt.

See class IOFormat for some examples.

See also:: class IOFormat, class WithFormat

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::fromMatlabStringFormat	(	const std::string &	s,
		bool	dumpErrorMsgToStdErr = `true`
	)		`[inherited]`

Read a matrix from a string in Matlab-like format, for example "[1 0 2; 0 4 -1]" The string must start with '[' and end with ']'.

Rows are separated by semicolons ';' and columns in each row by one or more whitespaces ' ', commas ',' or tabs ''.

This format is also used for CConfigFile::read_matrix.

This template method can be instantiated for matrices of the types: int, long, unsinged int, unsigned long, float, double, long double

Returns:: true on success. false if the string is malformed, and then the matrix will be resized to 0x0.

See also:: inMatlabFormat, CConfigFile::read_matrix

const FullPivHouseholderQR<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::fullPivHouseholderQr ( ) const [inherited]

Returns:: the full-pivoting Householder QR decomposition of *this.

See also:: class FullPivHouseholderQR

const FullPivLU<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::fullPivLu ( ) const [inherited]

Returns:: the full-pivoting LU decomposition of *this.

See also:: class FullPivLU

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::get_unsafe	(	const size_t	row,
		const size_t	col
	)		const `[inline, inherited]`

Read-only access to one element (Use with caution, bounds are not checked!)

Definition at line 103 of file Core.

EIGEN_STRONG_INLINE Scalar& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::get_unsafe	(	const size_t	row,
		const size_t	col
	)		`[inline, inherited]`

Reference access to one element (Use with caution, bounds are not checked!)

Definition at line 111 of file Core.

EIGEN_STRONG_INLINE Scalar* Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::get_unsafe_row ( size_t row ) [inline, inherited]

Fast but unsafe method to obtain a pointer to a given row of the matrix (Use only in time critical applications) VERY IMPORTANT WARNING: You must be aware of the memory layout, either Column or Row-major ordering.

Definition at line 99 of file Core.

EIGEN_STRONG_INLINE const Scalar* Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::get_unsafe_row ( size_t row ) const [inline, inherited]

Definition at line 100 of file Core.

EIGEN_STRONG_INLINE size_t Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::getColCount ( ) const [inline, inherited]

Get number of columns.

Definition at line 69 of file Core.

EIGEN_STRONG_INLINE size_t Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::getRowCount ( ) const [inline, inherited]

Get number of rows.

Definition at line 67 of file Core.

SegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::head ( Index size ) [inherited]

Returns:: a dynamic-size expression of the first coefficients of *this.

Parameters:

size	the number of coefficients in the block

Example:

Output:

Note:: Even though the returned expression has dynamic size, in the case when it is applied to a fixed-size vector, it inherits a fixed maximal size, which means that evaluating it does not cause a dynamic memory allocation.

See also:: class Block, block(Index,Index)

DenseBase::ConstSegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::head ( Index size ) const [inherited]

This is the const version of head(Index).

FixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::head ( ) [inherited]

Returns:: a fixed-size expression of the first coefficients of *this.

The template parameter Size is the number of coefficients in the block

Example:

Output:

See also:: class Block

ConstFixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::head ( ) const [inherited]

This is the const version of head<int>().

const HNormalizedReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::hnormalized ( ) const [inherited]

Returns:: an expression of the homogeneous normalized vector of *this

Example:

Output:

See also:: VectorwiseOp::hnormalized()

HomogeneousReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::homogeneous ( ) const [inherited]

Returns:: an expression of the equivalent homogeneous vector

Example:

Output:

See also:: class Homogeneous

const HouseholderQR<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::householderQr ( ) const [inherited]

Returns:: the Householder QR decomposition of *this.

See also:: class HouseholderQR

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::hypotNorm ( ) const [inherited]

Returns:: the l2 norm of *this avoiding undeflow and overflow. This version use a concatenation of hypot() calls, and it is very slow.

See also:: norm(), stableNorm()

static const IdentityReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Identity ( ) [static, inherited]

Returns:: an expression of the identity matrix (not necessarily square).

This variant is only for fixed-size MatrixBase types. For dynamic-size types, you need to use the variant taking size arguments.

Example:

Output:

See also:: Identity(Index,Index), setIdentity(), isIdentity()

static const IdentityReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Identity	(	Index	rows,
		Index	cols
	)		`[static, inherited]`

Returns:: an expression of the identity matrix (not necessarily square).

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Identity() should be used instead.

Example:

Output:

See also:: Identity(), setIdentity(), isIdentity()

const ImagReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::imag ( ) const [inline, inherited]

Returns:: an read-only expression of the imaginary part of *this.

See also:: real()

Definition at line 132 of file Core.

NonConstImagReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::imag ( ) [inline, inherited]

Returns:: a non const expression of the imaginary part of *this.

See also:: real()

Definition at line 188 of file Core.

std::string Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::inMatlabFormat ( const size_t decimal_digits = 6 ) const [inherited]

Dump matrix in matlab format.

This template method can be instantiated for matrices of the types: int, long, unsinged int, unsigned long, float, double, long double

See also:: fromMatlabStringFormat

Index Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::innerSize ( ) const [inline, inherited]

Returns:: the inner size.

Note:: For a vector, this is just the size. For a matrix (non-vector), this is the minor dimension with respect to the storage order, i.e., the number of rows for a column-major matrix, and the number of columns for a row-major matrix.

Definition at line 211 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertCol	(	size_t	nCol,
		const MAT &	aCol
	)		`[inline, inherited]`

Definition at line 427 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertCol	(	size_t	nCol,
		const std::vector< R > &	aCol
	)		`[inline, inherited]`

Definition at line 435 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertMatrix	(	size_t	r,
		size_t	c,
		const MAT &	m
	)		`[inline, inherited]`

Insert matrix "m" into this matrix at indices (r,c), that is, (*this)(r,c)=m(0,0) and so on.

Definition at line 421 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertMatrixTranspose	(	size_t	r,
		size_t	c,
		const MAT &	m
	)		`[inline, inherited]`

Definition at line 424 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertRow	(	size_t	nRow,
		const std::vector< R > &	aRow
	)		`[inline, inherited]`

Definition at line 429 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::insertRow	(	size_t	nRow,
		const MAT &	aRow
	)		`[inline, inherited]`

Definition at line 426 of file Core.

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::inv ( ) const [inline, inherited]

Definition at line 493 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::inv ( MATRIX & outMat ) const [inline, inherited]

Definition at line 494 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::inv_fast ( MATRIX & outMat ) const [inline, inherited]

Definition at line 495 of file Core.

const internal::inverse_impl<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::inverse ( ) const [inherited]

Returns:: the matrix inverse of this matrix.

For small fixed sizes up to 4x4, this method uses cofactors. In the general case, this method uses class PartialPivLU.

Note:

This matrix must be invertible, otherwise the result is undefined. If you need an invertibility check, do the following:

for fixed sizes up to 4x4, use computeInverseAndDetWithCheck().
for the general case, use class FullPivLU.

Example:

Output:

See also:: computeInverseAndDetWithCheck()

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isApprox	(	const DenseBase< OtherDerived > &	other,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Returns:: true if *this is approximately equal to other, within the precision determined by prec.

Note:: The fuzzy compares are done multiplicatively. Two vectors and are considered to be approximately equal within precision if
$\Vert v - w \Vert \leqslant p ~ min(\Vert v\Vert, \Vert w\Vert).$
For matrices, the comparison is done using the Hilbert-Schmidt norm (aka Frobenius norm L2 norm).; Because of the multiplicativeness of this comparison, one can't use this function to check whether *this is approximately equal to the zero matrix or vector. Indeed, isApprox(zero) returns false unless *this itself is exactly the zero matrix or vector. If you want to test whether *this is zero, use internal::isMuchSmallerThan(const RealScalar&, RealScalar) instead.

See also:: internal::isMuchSmallerThan(const RealScalar&, RealScalar) const

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isApproxToConstant	(	const Scalar &	value,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Returns:: true if all coefficients in this matrix are approximately equal to value, to within precision prec

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isConstant	(	const Scalar &	value,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

This is just an alias for isApproxToConstant().

Returns:: true if all coefficients in this matrix are approximately equal to value, to within precision prec

EIGEN_STRONG_INLINE bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isDiagonal ( ) const [inline, inherited]

Checks for matrix type.

Definition at line 360 of file Core.

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isDiagonal ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to a diagonal matrix, within the precision given by prec.

Example:

Output:

See also:: asDiagonal()

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isIdentity ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to the identity matrix (not necessarily square), within the precision given by prec.

Example:

Output:

See also:: class CwiseNullaryOp, Identity(), Identity(Index,Index), setIdentity()

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isLowerTriangular ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to a lower triangular matrix, within the precision given by prec.

See also:: isUpperTriangular()

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isMuchSmallerThan	(	const RealScalar &	other,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isMuchSmallerThan	(	const DenseBase< OtherDerived > &	other,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Returns:: true if the norm of *this is much smaller than the norm of other, within the precision determined by prec.

Note:: The fuzzy compares are done multiplicatively. A vector is considered to be much smaller than a vector within precision if
$\Vert v \Vert \leqslant p\,\Vert w\Vert.$
For matrices, the comparison is done using the Hilbert-Schmidt norm.

See also:: isApprox(), isMuchSmallerThan(const RealScalar&, RealScalar) const

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isOnes ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to the matrix where all coefficients are equal to 1, within the precision given by prec.

Example:

Output:

See also:: class CwiseNullaryOp, Ones()

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isOrthogonal	(	const MatrixBase< OtherDerived > &	other,
		RealScalar	prec = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

Returns:: true if *this is approximately orthogonal to other, within the precision given by prec.

Example:

Output:

EIGEN_STRONG_INLINE bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isSingular ( const Scalar absThreshold = 0 ) const [inline, inherited]

Definition at line 134 of file Core.

EIGEN_STRONG_INLINE bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isSquare ( ) const [inline, inherited]

Definition at line 133 of file Core.

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isUnitary ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately an unitary matrix, within the precision given by prec. In the case where the Scalar type is real numbers, a unitary matrix is an orthogonal matrix, whence the name.

Note:: This can be used to check whether a family of vectors forms an orthonormal basis. Indeed, m.isUnitary() returns true if and only if the columns (equivalently, the rows) of m form an orthonormal basis.

Example:

Output:

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isUpperTriangular ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to an upper triangular matrix, within the precision given by prec.

See also:: isLowerTriangular()

bool Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::isZero ( RealScalar prec = NumTraits<Scalar>::dummy_precision() ) const [inherited]

Returns:: true if *this is approximately equal to the zero matrix, within the precision given by prec.

Example:

Output:

See also:: class CwiseNullaryOp, Zero()

JacobiSVD<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::jacobiSvd ( unsigned int computationOptions = 0 ) const [inherited]

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::laplacian ( Eigen::MatrixBase< OtherDerived > & ret ) const [inline, inherited]

Computes the laplacian of this square graph weight matrix.

The laplacian matrix is L = D - W, with D a diagonal matrix with the degree of each node, W the

Definition at line 284 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::largestEigenvector	(	OUTVECT &	x,
		Scalar	resolution = `Scalar(0.01)`,
		size_t	maxIterations = `6`,
		int *	out_Iterations = `NULL`,
		float *	out_estimatedResolution = `NULL`
	)		const `[inline, inherited]`

Efficiently computes only the biggest eigenvector of the matrix using the Power Method, and returns it in the passed vector "x".

Definition at line 320 of file Core.

const LazyProductReturnType<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,OtherDerived>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::lazyProduct ( const MatrixBase< OtherDerived > & other ) const [inherited]

Returns:: an expression of the matrix product of *this and other without implicit evaluation.

The returned product will behave like any other expressions: the coefficients of the product will be computed once at a time as requested. This might be useful in some extremely rare cases when only a small and no coherent fraction of the result's coefficients have to be computed.

Warning:: This version of the matrix product can be much much slower. So use it only if you know what you are doing and that you measured a true speed improvement.

See also:: operator*(const MatrixBase&)

const LDLT<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ldlt ( ) const [inherited]

Returns:: the Cholesky decomposition with full pivoting without square root of *this

ColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::leftCols ( Index n ) [inline, inherited]

Returns:: a block consisting of the left columns of *this.

Parameters:

n	the number of columns in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 408 of file Core.

ConstColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::leftCols ( Index n ) const [inline, inherited]

This is the const version of leftCols(Index).

Definition at line 414 of file Core.

NColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::leftCols ( ) [inline, inherited]

Returns:: a block consisting of the left columns of *this.

Template Parameters:

N	the number of columns in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 429 of file Core.

ConstNColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::leftCols ( ) const [inline, inherited]

This is the const version of leftCols<int>().

Definition at line 436 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::leftDivideSquare	(	const MAT2 &	A,
		MAT3 &	RES
	)		const `[inline, inherited]`

Matrix left divide: RES = A^-1 * this , with A being squared (using the Eigen::ColPivHouseholderQR method)

Definition at line 640 of file Core.

const _LhsNested& Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::lhs ( ) const [inline, inherited]

Definition at line 127 of file Core.

static const SequentialLinSpacedReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::LinSpaced	(	Sequential_t	,
		Index	size,
		const Scalar &	low,
		const Scalar &	high
	)		`[static, inherited]`

Sets a linearly space vector.

The function generates 'size' equally spaced values in the closed interval [low,high]. This particular version of LinSpaced() uses sequential access, i.e. vector access is assumed to be a(0), a(1), ..., a(size). This assumption allows for better vectorization and yields faster code than the random access version.

Example:

Output:

See also:: setLinSpaced(Index,const Scalar&,const Scalar&), LinSpaced(Index,Scalar,Scalar), CwiseNullaryOp

static const SequentialLinSpacedReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::LinSpaced	(	Sequential_t	,
		const Scalar &	low,
		const Scalar &	high
	)		`[static, inherited]`

Special version for fixed size types which does not require the size parameter.

static const RandomAccessLinSpacedReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::LinSpaced	(	const Scalar &	low,
		const Scalar &	high
	)		`[static, inherited]`

Special version for fixed size types which does not require the size parameter.

static const RandomAccessLinSpacedReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::LinSpaced	(	Index	size,
		const Scalar &	low,
		const Scalar &	high
	)		`[static, inherited]`

Sets a linearly space vector.

The function generates 'size' equally spaced values in the closed interval [low,high].

Example:

Output:

See also:: setLinSpaced(Index,const Scalar&,const Scalar&), LinSpaced(Sequential_t,Index,const Scalar&,const Scalar&,Index), CwiseNullaryOp

const LLT<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::llt ( ) const [inherited]

Returns:: the LLT decomposition of *this

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::loadFromTextFile ( const std::string & file ) [inherited]

Load matrix from a text file, compatible with MATLAB text format.

Lines starting with '%' or '#' are interpreted as comments and ignored.

See also:: saveToTextFile, fromMatlabStringFormat

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::loadFromTextFile ( std::istream & _input_text_stream ) [inherited]

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Log ( ) const [inline, inherited]

Definition at line 744 of file Core.

EIGEN_STRONG_INLINE MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Log ( ) [inline, inherited]

Definition at line 743 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::lpNorm ( ) const [inherited]

Returns:: the $\ell^p$ norm of *this, that is, returns the p-th root of the sum of the p-th powers of the absolute values of the coefficients of *this. If p is the special value Eigen::Infinity, this function returns the $\ell^\infty$ norm, that is the maximum of the absolute values of the coefficients of *this.

See also:: norm()

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

const PartialPivLU<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::lu ( ) const [inherited]

Synonym of partialPivLu().

Returns:: the partial-pivoting LU decomposition of *this.

See also:: class PartialPivLU

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::makeHouseholder	(	EssentialPart &	essential,
		Scalar &	tau,
		RealScalar &	beta
	)		const `[inherited]`

Computes the elementary reflector H such that: $ H *this = [ beta 0 ... 0]^T $ where the transformation H is: $ H = I - tau v v^*$ and the vector v is: $ v^T = [1 essential^T] $ .

On output:

Parameters:

essential	the essential part of the vector `v`
tau	the scaling factor of the householder transformation
beta	the result of H * `*this`

See also:: MatrixBase::makeHouseholderInPlace(), MatrixBase::applyHouseholderOnTheLeft(), MatrixBase::applyHouseholderOnTheRight()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::makeHouseholderInPlace	(	Scalar &	tau,
		RealScalar &	beta
	)		`[inherited]`

MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::matrix ( ) [inline, inherited]

Definition at line 327 of file Core.

const MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::matrix ( ) const [inline, inherited]

Definition at line 328 of file Core.

const MatrixFunctionReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::matrixFunction ( StemFunction f ) const [inherited]

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maxCoeff ( ) const [inherited]

Returns:: the maximum of all coefficients of *this

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maxCoeff	(	IndexType *	row,
		IndexType *	col
	)		const `[inherited]`

Returns:: the maximum of all coefficients of *this and puts in *row and *col its location.

See also:: DenseBase::minCoeff(IndexType*,IndexType*), DenseBase::visitor(), DenseBase::maxCoeff()

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maxCoeff ( IndexType * index ) const [inherited]

Returns:: the maximum of all coefficients of *this and puts in *index its location.

See also:: DenseBase::maxCoeff(IndexType*,IndexType*), DenseBase::minCoeff(IndexType*,IndexType*), DenseBase::visitor(), DenseBase::maxCoeff()

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maximum ( ) const [inline, inherited]

[VECTORS OR MATRICES] Finds the maximum value

Exceptions:

std::exception On an empty input container

Definition at line 195 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maximum ( size_t * maxIndex ) const [inline, inherited]

[VECTORS ONLY] Finds the maximum value (and the corresponding zero-based index) from a given container.

Exceptions:

std::exception On an empty input vector

Definition at line 225 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::maximumDiagonal ( ) const [inline, inherited]

Finds the maximum value in the diagonal of the matrix.

Definition at line 370 of file Core.

EIGEN_STRONG_INLINE double Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::mean ( ) const [inline, inherited]

Computes the mean of the entire matrix.

See also:: meanAndStdAll

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

Definition at line 374 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::meanAndStd	(	VEC &	outMeanVector,
		VEC &	outStdVector,
		const bool	unbiased_variance = `true`
	)		const `[inline, inherited]`

Computes a row with the mean values of each column in the matrix and the associated vector with the standard deviation of each column.

See also:: mean,meanAndStdAll

Exceptions:

std::exception If the matrix/vector is empty.

Parameters:

unbiased_variance Standard deviation is sum(vals-mean)/K, with K=N-1 or N for unbiased_variance=true or false, respectively.

Definition at line 385 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::meanAndStdAll	(	double &	outMean,
		double &	outStd,
		const bool	unbiased_variance = `true`
	)		const `[inline, inherited]`

Computes the mean and standard deviation of all the elements in the matrix as a whole.

See also:: mean,meanAndStd

Exceptions:

std::exception If the matrix/vector is empty.

Parameters:

unbiased_variance Standard deviation is sum(vals-mean)/K, with K=N-1 or N for unbiased_variance=true or false, respectively.

Definition at line 407 of file Core.

ConstColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleCols	(	Index	startCol,
		Index	numCols
	)		const `[inline, inherited]`

This is the const version of middleCols(Index,Index).

Definition at line 503 of file Core.

NColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleCols ( Index startCol ) [inline, inherited]

Returns:: a block consisting of a range of columns of *this.

Template Parameters:

N	the number of columns in the block

Parameters:

startCol the index of the first column in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 519 of file Core.

ColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleCols	(	Index	startCol,
		Index	numCols
	)		`[inline, inherited]`

Returns:: a block consisting of a range of columns of *this.

Parameters:

startCol	the index of the first column in the block
numCols	the number of columns in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 497 of file Core.

ConstNColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleCols ( Index startCol ) const [inline, inherited]

This is the const version of middleCols<int>().

Definition at line 526 of file Core.

NRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleRows ( Index startRow ) [inline, inherited]

Returns:: a block consisting of a range of rows of *this.

Template Parameters:

N	the number of rows in the block

Parameters:

startRow the index of the first row in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 385 of file Core.

ConstNRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleRows ( Index startRow ) const [inline, inherited]

This is the const version of middleRows<int>().

Definition at line 392 of file Core.

ConstRowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleRows	(	Index	startRow,
		Index	numRows
	)		const `[inline, inherited]`

This is the const version of middleRows(Index,Index).

Definition at line 369 of file Core.

RowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::middleRows	(	Index	startRow,
		Index	numRows
	)		`[inline, inherited]`

Returns:: a block consisting of a range of rows of *this.

Parameters:

startRow	the index of the first row in the block
numRows	the number of rows in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 363 of file Core.

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minCoeff ( ) const [inherited]

Returns:: the minimum of all coefficients of *this

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minCoeff	(	IndexType *	row,
		IndexType *	col
	)		const `[inherited]`

Returns:: the minimum of all coefficients of *this and puts in *row and *col its location.

See also:: DenseBase::minCoeff(Index*), DenseBase::maxCoeff(Index*,Index*), DenseBase::visitor(), DenseBase::minCoeff()

internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minCoeff ( IndexType * index ) const [inherited]

Returns:: the minimum of all coefficients of *this and puts in *index its location.

See also:: DenseBase::minCoeff(IndexType*,IndexType*), DenseBase::maxCoeff(IndexType*,IndexType*), DenseBase::visitor(), DenseBase::minCoeff()

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minimum ( ) const [inline, inherited]

[VECTORS OR MATRICES] Finds the minimum value

See also:: maximum, minimum_maximum

Exceptions:

std::exception On an empty input container

Definition at line 204 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minimum ( size_t * minIndex ) const [inline, inherited]

[VECTORS ONLY] Finds the minimum value (and the corresponding zero-based index) from a given container.

See also:: maximum, minimum_maximum

Exceptions:

std::exception On an empty input vector

Definition at line 249 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minimum_maximum	(	Scalar &	out_min,
		Scalar &	out_max
	)		const `[inline, inherited]`

[VECTORS OR MATRICES] Compute the minimum and maximum of a container at once

See also:: maximum, minimum

Exceptions:

std::exception On an empty input container

Definition at line 213 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::minimum_maximum	(	Scalar &	out_min,
		Scalar &	out_max,
		size_t *	minIndex,
		size_t *	maxIndex
	)		const `[inline, inherited]`

[VECTORS ONLY] Compute the minimum and maximum of a container at once

See also:: maximum, minimum

Exceptions:

std::exception On an empty input vector

Definition at line 261 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply	(	const MATRIX1 &	A,
		const MATRIX2 &	B
	)		`[inline, inherited]`

Parameters:

B	this = A * B

Definition at line 524 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_A_skew3	(	const MAT_A &	A,
		const SKEW_3VECTOR &	v
	)		`[inline, inherited]`

this = A * skew(v), with v being a 3-vector (or 3-array) and skew(v) the skew symmetric matrix of v (see mrpt::math::skew_symmetric3)

Definition at line 588 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AAt ( const MAT_A & A ) [inline, inherited]

Parameters:

A	this = A * A^T

Definition at line 623 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AAt_scalar	(	const MAT_A &	A,
		typename MAT_A::value_type	f
	)		`[inline, inherited]`

this = C * C^T * f (with a matrix C and a scalar f).

Definition at line 578 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_Ab	(	const OTHERVECTOR1 &	vIn,
		OTHERVECTOR2 &	vOut,
		bool	accumToOutput = `false`
	)		const `[inline, inherited]`

Computes the vector vOut = this * vIn, where "vIn" is a column vector of the appropriate length.

Definition at line 538 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AB	(	const MATRIX1 &	A,
		const MATRIX2 &	B
	)		`[inline, inherited]`

Parameters:

B	this = A * B

Definition at line 527 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_ABC	(	const MAT_A &	A,
		const MAT_B &	B,
		const MAT_C &	C
	)		`[inline, inherited]`

Parameters:

C	this = ABC

Definition at line 603 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_ABCt	(	const MAT_A &	A,
		const MAT_B &	B,
		const MAT_C &	C
	)		`[inline, inherited]`

Parameters:

C	this = AB(C^T)

Definition at line 608 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_ABt	(	const MAT_A &	A,
		const MAT_B &	B
	)		`[inline, inherited]`

Parameters:

B	this = A * B^T

Definition at line 618 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AtA ( const MAT_A & A ) [inline, inherited]

Parameters:

A	this = A^T * A

Definition at line 628 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AtA_scalar	(	const MAT_A &	A,
		typename MAT_A::value_type	f
	)		`[inline, inherited]`

this = C^T * C * f (with a matrix C and a scalar f).

Definition at line 583 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AtB	(	const MATRIX1 &	A,
		const MATRIX2 &	B
	)		`[inline, inherited]`

Parameters:

B	this=A^t * B

Definition at line 532 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_Atb	(	const OTHERVECTOR1 &	vIn,
		OTHERVECTOR2 &	vOut,
		bool	accumToOutput = `false`
	)		const `[inline, inherited]`

Computes the vector vOut = this^T * vIn, where "vIn" is a column vector of the appropriate length.

Definition at line 545 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_AtBC	(	const MAT_A &	A,
		const MAT_B &	B,
		const MAT_C &	C
	)		`[inline, inherited]`

Parameters:

C	this = A(^T)BC

Definition at line 613 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_HCHt	(	const MAT_C &	C,
		MAT_R &	R,
		bool	accumResultInOutput = `false`
	)		const `[inline, inherited]`

< R = this * C * this^T

Definition at line 551 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_HCHt_scalar ( const MAT_C & C ) const [inline, inherited]

R = H * C * H^T (with a vector H and a symmetric matrix C) In fact when H is a vector, multiply_HCHt_scalar and multiply_HtCH_scalar are exactly equivalent

Definition at line 566 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_HtCH	(	const MAT_C &	C,
		MAT_R &	R,
		bool	accumResultInOutput = `false`
	)		const `[inline, inherited]`

< R = this^T * C * this

Definition at line 558 of file Core.

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_HtCH_scalar ( const MAT_C & C ) const [inline, inherited]

R = H^T * C * H (with a vector H and a symmetric matrix C) In fact when H is a vector, multiply_HCHt_scalar and multiply_HtCH_scalar are exactly equivalent

Definition at line 572 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_result_is_symmetric	(	const MAT_A &	A,
		const MAT_B &	B
	)		`[inline, inherited]`

Parameters:

B	this = A * B (result is symmetric)

Definition at line 633 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_skew3_A	(	const SKEW_3VECTOR &	v,
		const MAT_A &	A
	)		`[inline, inherited]`

this = skew(v)*A, with v being a 3-vector (or 3-array) and skew(v) the skew symmetric matrix of v (see mrpt::math::skew_symmetric3)

Definition at line 592 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiply_subMatrix	(	const MAT_A &	A,
		MAT_OUT &	outResult,
		const size_t	A_cols_offset,
		const size_t	A_rows_offset,
		const size_t	A_col_count
	)		const `[inline, inherited]`

outResult = this * A

Definition at line 598 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiplyColumnByScalar	(	size_t	c,
		Scalar	s
	)		`[inline, inherited]`

Definition at line 184 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::multiplyRowByScalar	(	size_t	r,
		Scalar	s
	)		`[inline, inherited]`

Definition at line 185 of file Core.

const NestByValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::nestByValue ( ) const [inline, inherited]

Returns:: an expression of the temporary version of *this.

NoAlias<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,Eigen::MatrixBase > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::noalias ( ) [inherited]

Returns:: a pseudo expression of *this with an operator= assuming no aliasing between *this and the source expression.

More precisely, noalias() allows to bypass the EvalBeforeAssignBit flag. Currently, even though several expressions may alias, only product expressions have this flag. Therefore, noalias() is only usefull when the source expression contains a matrix product.

Here are some examples where noalias is usefull:

 D.noalias()  = A * B;
 D.noalias() += A.transpose() * B;
 D.noalias() -= 2 * A * B.adjoint();

On the other hand the following example will lead to a wrong result:

 A.noalias() = A * B;

because the result matrix A is also an operand of the matrix product. Therefore, there is no alternative than evaluating A * B in a temporary, that is the default behavior when you write:

 A = A * B;

See also:: class NoAlias

Index Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::nonZeros ( ) const [inline, inherited]

Returns:: the number of nonzero coefficients which is in practice the number of stored coefficients.

Definition at line 189 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::norm ( ) const [inherited]

Returns:: , for vectors, the l2 norm of *this, and for matrices the Frobenius norm. In both cases, it consists in the square root of the sum of the square of all the matrix entries. For vectors, this is also equals to the square root of the dot product of *this with itself.

See also:: dot(), squaredNorm()

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::norm_inf ( ) const [inline, inherited]

Compute the norm-infinite of a vector ($f[ ||{v}||_ $f]), ie the maximum absolute value of the elements.

Definition at line 272 of file Core.

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::normalize ( void ) [inherited]

Normalizes the vector, i.e.

divides it by its own norm.

See also:: norm(), normalized()

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::normalize	(	Scalar	valMin,
		Scalar	valMax
	)		`[inline, inherited]`

Scales all elements such as the minimum & maximum values are shifted to the given values.

Definition at line 753 of file Core.

const PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::normalized ( ) const [inherited]

Returns:: an expression of the quotient of *this by its own norm.

See also:: norm(), normalize()

static const CwiseNullaryOp<CustomNullaryOp, TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::NullaryExpr	(	Index	rows,
		Index	cols,
		const CustomNullaryOp &	func
	)		`[static, inherited]`

Returns:: an expression of a matrix defined by a custom functor func

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Zero() should be used instead.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

static const CwiseNullaryOp<CustomNullaryOp, TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::NullaryExpr ( const CustomNullaryOp & func ) [static, inherited]

Returns:: an expression of a matrix defined by a custom functor func

This variant is only for fixed-size DenseBase types. For dynamic-size types, you need to use the variants taking size arguments.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

static const CwiseNullaryOp<CustomNullaryOp, TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::NullaryExpr	(	Index	size,
		const CustomNullaryOp &	func
	)		`[static, inherited]`

Returns:: an expression of a matrix defined by a custom functor func

The parameter size is the size of the returned vector. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size vector types. For fixed-size types, it is redundant to pass size as argument, so Zero() should be used instead.

The template parameter CustomNullaryOp is the type of the functor.

See also:: class CwiseNullaryOp

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ones ( ) [inline, inherited]

Set all elements to one.

Definition at line 94 of file Core.

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Ones	(	Index	rows,
		Index	cols
	)		`[static, inherited]`

Returns:: an expression of a matrix where all coefficients equal one.

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Ones() should be used instead.

Example:

Output:

See also:: Ones(), Ones(Index), isOnes(), class Ones

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Ones ( ) [static, inherited]

Returns:: an expression of a fixed-size matrix or vector where all coefficients equal one.

This variant is only for fixed-size MatrixBase types. For dynamic-size types, you need to use the variants taking size arguments.

Example:

Output:

See also:: Ones(Index), Ones(Index,Index), isOnes(), class Ones

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Ones ( Index size ) [static, inherited]

Returns:: an expression of a vector where all coefficients equal one.

The parameter size is the size of the returned vector. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size vector types. For fixed-size types, it is redundant to pass size as argument, so Ones() should be used instead.

Example:

Output:

See also:: Ones(), Ones(Index,Index), isOnes(), class Ones

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::ones	(	const size_t	row,
		const size_t	col
	)		`[inline, inherited]`

Resize matrix and set all elements to one.

Definition at line 92 of file Core.

Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::operator const PlainObject & ( ) const [inline, inherited]

Definition at line 131 of file Core.

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator!= ( const MatrixBase< OtherDerived > & other ) const [inline, inherited]

Returns:: true if at least one pair of coefficients of *this and other are not exactly equal to each other.

Warning:: When using floating point scalar values you probably should rather use a fuzzy comparison such as isApprox()

See also:: isApprox(), operator==

Definition at line 311 of file Core.

const ScalarMultipleReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const Scalar & scalar ) const [inline, inherited]

Returns:: an expression of *this scaled by the scalar factor scalar

Definition at line 65 of file Core.

const ScalarMultipleReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const RealScalar & scalar ) const [inherited]

const CwiseUnaryOp<internal::scalar_multiple2_op<Scalar,std::complex<Scalar> >, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const std::complex< Scalar > & scalar ) const [inline, inherited]

Overloaded for efficient real matrix times complex scalar value.

Definition at line 85 of file Core.

const ProductReturnType<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,OtherDerived>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const MatrixBase< OtherDerived > & other ) const [inherited]

Returns:: the matrix product of *this and other.

Note:: If instead of the matrix product you want the coefficient-wise product, see Cwise::operator*().

See also:: lazyProduct(), operator*=(const MatrixBase&), Cwise::operator*()

const DiagonalProduct<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , DiagonalDerived, OnTheRight> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const DiagonalBase< DiagonalDerived > & diagonal ) const [inherited]

Returns:: the diagonal matrix product of *this by the diagonal matrix diagonal.

ScalarMultipleReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator* ( const UniformScaling< Scalar > & s ) const [inherited]

Concatenates a linear transformation matrix and a uniform scaling.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator*= ( const Scalar & other ) [inline, inherited]

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator*= ( const EigenBase< OtherDerived > & other ) [inherited]

replaces *this by *this * other.

Returns:: a reference to *this

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator+= ( const EigenBase< OtherDerived > & other ) [inherited]

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator+= ( const MatrixBase< OtherDerived > & other ) [inherited]

replaces *this by *this + other.

Returns:: a reference to *this

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator+= ( const ArrayBase< OtherDerived > & ) [inline, protected, inherited]

Definition at line 513 of file Core.

const CwiseUnaryOp<internal::scalar_opposite_op<typename internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator- ( ) const [inline, inherited]

Returns:: an expression of the opposite of *this

Definition at line 60 of file Core.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator-= ( const MatrixBase< OtherDerived > & other ) [inherited]

replaces *this by *this - other.

Returns:: a reference to *this

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator-= ( const ArrayBase< OtherDerived > & ) [inline, protected, inherited]

Definition at line 516 of file Core.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator-= ( const EigenBase< OtherDerived > & other ) [inherited]

const CwiseUnaryOp<internal::scalar_quotient1_op<typename internal::traits<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Scalar>, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator/ ( const Scalar & scalar ) const [inline, inherited]

Returns:: an expression of *this divided by the scalar value scalar

Definition at line 77 of file Core.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator/= ( const Scalar & other ) [inline, inherited]

CommaInitializer<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator<< ( const Scalar & s ) [inherited]

Convenient operator to set the coefficients of a matrix.

The coefficients must be provided in a row major order and exactly match the size of the matrix. Otherwise an assertion is raised.

Example:

Output:

See also:: CommaInitializer::finished(), class CommaInitializer

CommaInitializer<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator<< ( const DenseBase< OtherDerived > & other ) [inherited]

See also:: operator<<(const Scalar&)

bool Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator== ( const MatrixBase< OtherDerived > & other ) const [inline, inherited]

Returns:: true if each coefficients of *this and other are all exactly equal.

Warning:: When using floating point scalar values you probably should rather use a fuzzy comparison such as isApprox()

See also:: isApprox(), operator!=

Definition at line 303 of file Core.

MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operator^= ( const unsigned int pow ) [inline, inherited]

Combined matrix power and assignment operator.

Definition at line 346 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::operatorNorm ( ) const [inherited]

Computes the L2 operator norm.

Returns:: Operator norm of the matrix.

This function computes the L2 operator norm of a matrix, which is also known as the spectral norm. The norm of a matrix $ A $ is defined to be

$\|A\|_2 = \max_x \frac{\|Ax\|_2}{\|x\|_2}$

where the maximum is over all vectors and the norm on the right is the Euclidean vector norm. The norm equals the largest singular value, which is the square root of the largest eigenvalue of the positive semi-definite matrix $ A^*A $ .

The current implementation uses the eigenvalues of $ A^*A $ , as computed by SelfAdjointView::eigenvalues(), to compute the operator norm of a matrix. The SelfAdjointView class provides a better algorithm for selfadjoint matrices.

Example:

Output:

See also:: SelfAdjointView::eigenvalues(), SelfAdjointView::operatorNorm()

Index Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::outerSize ( ) const [inline, inherited]

Returns:

true if either the number of rows or the number of columns is equal to 1. In other words, this function returns

 rows()==1 || cols()==1

See also:: rows(), cols(), IsVectorAtCompileTime.

Returns:: the outer size.

Note:: For a vector, this returns just 1. For a matrix (non-vector), this is the major dimension with respect to the storage order, i.e., the number of columns for a column-major matrix, and the number of rows for a row-major matrix.

Definition at line 200 of file Core.

const PartialPivLU<PlainObject> Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::partialPivLu ( ) const [inherited]

Returns:: the partial-pivoting LU decomposition of *this.

See also:: class PartialPivLU

Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::prod ( ) const [inherited]

Returns:: the product of all coefficients of *this

Example:

Output:

See also:: sum(), mean(), trace()

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::push_back ( Scalar val ) [inline, inherited]

Insert an element at the end of the container (for 1D vectors/arrays)

Definition at line 126 of file Core.

static const CwiseNullaryOp<internal::scalar_random_op<Scalar>,TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Random ( Index size ) [static, inherited]

Returns:: a random vector expression

The parameter size is the size of the returned vector. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size vector types. For fixed-size types, it is redundant to pass size as argument, so Random() should be used instead.

Example:

Output:

This expression has the "evaluate before nesting" flag so that it will be evaluated into a temporary vector whenever it is nested in a larger expression. This prevents unexpected behavior with expressions involving random matrices.

See also:: MatrixBase::setRandom(), MatrixBase::Random(Index,Index), MatrixBase::Random()

static const CwiseNullaryOp<internal::scalar_random_op<Scalar>,TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Random	(	Index	rows,
		Index	cols
	)		`[static, inherited]`

Returns:: a random matrix expression

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Random() should be used instead.

Example:

Output:

This expression has the "evaluate before nesting" flag so that it will be evaluated into a temporary matrix whenever it is nested in a larger expression. This prevents unexpected behavior with expressions involving random matrices.

See also:: MatrixBase::setRandom(), MatrixBase::Random(Index), MatrixBase::Random()

static const CwiseNullaryOp<internal::scalar_random_op<Scalar>,TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Random ( ) [static, inherited]

Returns:: a fixed-size random matrix or vector expression

This variant is only for fixed-size MatrixBase types. For dynamic-size types, you need to use the variants taking size arguments.

Example:

Output:

This expression has the "evaluate before nesting" flag so that it will be evaluated into a temporary matrix whenever it is nested in a larger expression. This prevents unexpected behavior with expressions involving random matrices.

See also:: MatrixBase::setRandom(), MatrixBase::Random(Index,Index), MatrixBase::Random(Index)

EIGEN_STRONG_INLINE size_t Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rank ( double threshold = 0 ) const [inline, inherited]

Gets the rank of the matrix via the Eigen::ColPivHouseholderQR method.

Parameters:

threshold If set to >0, it's used as threshold instead of Eigen's default one.

Definition at line 723 of file Core.

RealReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::real ( ) const [inline, inherited]

Returns:: a read-only expression of the real part of *this.

See also:: imag()

Definition at line 126 of file Core.

NonConstRealReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::real ( ) [inline, inherited]

Returns:: a non const expression of the real part of *this.

See also:: imag()

Definition at line 182 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::removeColumns ( const std::vector< size_t > & idxsToRemove ) [inline, inherited]

Remove columns of the matrix.

Definition at line 443 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::removeRows ( const std::vector< size_t > & idxsToRemove ) [inline, inherited]

Remove rows of the matrix.

Definition at line 467 of file Core.

const Replicate<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,Dynamic,Dynamic> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::replicate	(	Index	rowFacor,
		Index	colFactor
	)		const `[inherited]`

Returns:: an expression of the replication of *this

Example:

Output:

See also:: VectorwiseOp::replicate(), DenseBase::replicate<int,int>(), class Replicate

const Replicate<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,RowFactor,ColFactor> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::replicate ( ) const [inherited]

Returns:: an expression of the replication of *this

Example:

Output:

See also:: VectorwiseOp::replicate(), DenseBase::replicate(Index,Index), class Replicate

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::resize	(	Index	rows,
		Index	cols
	)		`[inline, inherited]`

Only plain matrices/arrays, not expressions, may be resized; therefore the only useful resize methods are Matrix::resize() and Array::resize().

The present method only asserts that the new size equals the old size, and does nothing else.

Definition at line 231 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::resize ( Index size ) [inline, inherited]

Only plain matrices/arrays, not expressions, may be resized; therefore the only useful resize methods are Matrix::resize() and Array::resize().

The present method only asserts that the new size equals the old size, and does nothing else.

Definition at line 221 of file Core.

ConstReverseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::reverse ( ) const [inherited]

This is the const version of reverse().

ReverseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::reverse ( ) [inherited]

Returns:: an expression of the reverse of *this.

Example:

Output:

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::reverseInPlace ( ) [inherited]

This is the "in place" version of reverse: it reverses *this.

In most cases it is probably better to simply use the reversed expression of a matrix. However, when reversing the matrix data itself is really needed, then this "in-place" version is probably the right choice because it provides the following additional features:

less error prone: doing the same operation with .reverse() requires special care:
```
 m = m.reverse().eval(); 
```
this API allows to avoid creating a temporary (the current implementation creates a temporary, but that could be avoided using swap)
it allows future optimizations (cache friendliness, etc.)

See also:: reverse()

const _RhsNested& Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::rhs ( ) const [inline, inherited]

Definition at line 128 of file Core.

ColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rightCols ( Index n ) [inline, inherited]

Returns:: a block consisting of the right columns of *this.

Parameters:

n	the number of columns in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 452 of file Core.

ConstColsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rightCols ( Index n ) const [inline, inherited]

This is the const version of rightCols(Index).

Definition at line 458 of file Core.

NColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rightCols ( ) [inline, inherited]

Returns:: a block consisting of the right columns of *this.

Template Parameters:

N	the number of columns in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 473 of file Core.

ConstNColsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rightCols ( ) const [inline, inherited]

This is the const version of rightCols<int>().

Definition at line 480 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rightDivideSquare	(	const MAT2 &	B,
		MAT3 &	RES
	)		const `[inline, inherited]`

Matrix right divide: RES = this * B^-1, with B being squared (using the Eigen::ColPivHouseholderQR method)

Definition at line 649 of file Core.

RowXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::row ( Index i ) [inline, inherited]

Returns:: an expression of the i-th row of *this. Note that the numbering starts at 0.

Example:

Output:

See also:: col(), class Block

Definition at line 585 of file Core.

ConstRowXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::row ( Index i ) const [inline, inherited]

This is the const version of row().

Definition at line 591 of file Core.

Index Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::rows ( void ) const [inline, inherited]

Definition at line 112 of file Core.

ConstRowwiseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rowwise ( ) const [inherited]

Returns:: a VectorwiseOp wrapper of *this providing additional partial reduction operations

Example:

Output:

See also:: colwise(), class VectorwiseOp

RowwiseReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::rowwise ( ) [inherited]

Returns:: a writable VectorwiseOp wrapper of *this providing additional partial reduction operations

See also:: colwise(), class VectorwiseOp

void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::saveToTextFile	(	const std::string &	file,
		mrpt::math::TMatrixTextFileFormat	fileFormat = `mrpt::math::MATRIX_FORMAT_ENG`,
		bool	appendMRPTHeader = `false`,
		const std::string &	userHeader = `std::string()`
	)		const `[inherited]`

Save matrix to a text file, compatible with MATLAB text format (see also the methods of matrix classes themselves).

Parameters:

theMatrix	It can be a CMatrixTemplate or a CMatrixFixedNumeric.
file	The target filename.
fileFormat	See TMatrixTextFileFormat. The format of the numbers in the text file.
appendMRPTHeader	Insert this header to the file "% File generated by MRPT. Load with MATLAB with: VAR=load(FILENAME);"
userHeader	Additional text to be written at the head of the file. Typically MALAB comments "% This file blah blah". Final end-of-line is not needed.

See also:: loadFromTextFile, CMatrixTemplate::inMatlabFormat, SAVE_MATRIX

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::scalarPow ( const Scalar s ) [inline, inherited]

Scalar power of all elements to a given power, this is diferent of ^ operator.

Definition at line 357 of file Core.

template<int Mode, bool LhsIsTriangular, typename Lhs , typename Rhs >

template<typename Dest >

void Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >::scaleAndAddTo	(	Dest &	dst,
		Scalar	alpha
	)		const `[inline]`

Reimplemented from Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >, Lhs, Rhs >.

Definition at line 380 of file Core.

DenseBase::ConstSegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::segment	(	Index	start,
		Index	size
	)		const `[inherited]`

This is the const version of segment(Index,Index).

FixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::segment ( Index start ) [inherited]

Returns:: a fixed-size expression of a segment (i.e. a vector block) in *this

The template parameter Size is the number of coefficients in the block

Parameters:

start the index of the first element of the sub-vector

Example:

Output:

See also:: class Block

ConstFixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::segment ( Index start ) const [inherited]

This is the const version of segment<int>(Index).

SegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::segment	(	Index	start,
		Index	size
	)		`[inherited]`

Returns:: a dynamic-size expression of a segment (i.e. a vector block) in *this.

Parameters:

start	the first coefficient in the segment
size	the number of coefficients in the segment

Example:

Output:

Note:: Even though the returned expression has dynamic size, in the case when it is applied to a fixed-size vector, it inherits a fixed maximal size, which means that evaluating it does not cause a dynamic memory allocation.

See also:: class Block, segment(Index)

const Select<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,ThenDerived, typename ThenDerived::ConstantReturnType> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::select	(	const DenseBase< ThenDerived > &	thenMatrix,
		typename ThenDerived::Scalar	elseScalar
	)		const `[inline, inherited]`

Version of DenseBase::select(const DenseBase&, const DenseBase&) with the else expression being a scalar value.

See also:: DenseBase::select(const DenseBase<ThenDerived>&, const DenseBase<ElseDerived>&) const, class Select

const Select<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , typename ElseDerived::ConstantReturnType, ElseDerived > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::select	(	typename ElseDerived::Scalar	thenScalar,
		const DenseBase< ElseDerived > &	elseMatrix
	)		const `[inline, inherited]`

Version of DenseBase::select(const DenseBase&, const DenseBase&) with the then expression being a scalar value.

See also:: DenseBase::select(const DenseBase<ThenDerived>&, const DenseBase<ElseDerived>&) const, class Select

const Select<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > ,ThenDerived,ElseDerived> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::select	(	const DenseBase< ThenDerived > &	thenMatrix,
		const DenseBase< ElseDerived > &	elseMatrix
	)		const `[inherited]`

Returns:: a matrix where each coefficient (i,j) is equal to thenMatrix(i,j) if *this(i,j), and elseMatrix(i,j) otherwise.

Example:

Output:

See also:: class Select

SelfAdjointViewReturnType<UpLo>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::selfadjointView ( ) [inherited]

ConstSelfAdjointViewReturnType<UpLo>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::selfadjointView ( ) const [inherited]

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::set_unsafe	(	const size_t	row,
		const size_t	col,
		const Scalar	val
	)		`[inline, inherited]`

Sets an element (Use with caution, bounds are not checked!)

Definition at line 118 of file Core.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setConstant ( const Scalar & value ) [inherited]

Sets all coefficients in this expression to value.

See also:: fill(), setConstant(Index,const Scalar&), setConstant(Index,Index,const Scalar&), setZero(), setOnes(), Constant(), class CwiseNullaryOp, setZero(), setOnes()

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setIdentity	(	Index	rows,
		Index	cols
	)		`[inherited]`

Resizes to the given size, and writes the identity expression (not necessarily square) into *this.

Parameters:

rows	the new number of rows
cols	the new number of columns

Example:

Output:

See also:: MatrixBase::setIdentity(), class CwiseNullaryOp, MatrixBase::Identity()

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setIdentity ( ) [inherited]

Writes the identity expression (not necessarily square) into *this.

Example:

Output:

See also:: class CwiseNullaryOp, Identity(), Identity(Index,Index), isIdentity()

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setLinSpaced	(	Index	size,
		const Scalar &	low,
		const Scalar &	high
	)		`[inherited]`

Sets a linearly space vector.

The function generates 'size' equally spaced values in the closed interval [low,high].

Example:

Output:

See also:: CwiseNullaryOp

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setLinSpaced	(	const Scalar &	low,
		const Scalar &	high
	)		`[inherited]`

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setOnes ( ) [inherited]

Sets all coefficients in this expression to one.

Example:

Output:

See also:: class CwiseNullaryOp, Ones()

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setRandom ( ) [inherited]

Sets all coefficients in this expression to random values.

Example:

Output:

See also:: class CwiseNullaryOp, setRandom(Index), setRandom(Index,Index)

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setSize	(	size_t	row,
		size_t	col
	)		`[inline, inherited]`

Changes the size of matrix, maintaining its previous content as possible and padding with zeros where applicable.

**WARNING**: MRPT's add-on method setSize() pads with zeros, while Eigen's resize() does NOT (new elements are undefined).

Definition at line 301 of file Core.

TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > & Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::setZero ( ) [inherited]

Sets all coefficients in this expression to zero.

Example:

Output:

See also:: class CwiseNullaryOp, Zero()

const MatrixFunctionReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::sin ( ) const [inherited]

const MatrixFunctionReturnValue<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::sinh ( ) const [inherited]

const SparseView<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::sparseView	(	const Scalar &	m_reference = `Scalar(0)`,
		typename NumTraits< Scalar >::Real	m_epsilon = `NumTraits<Scalar>::dummy_precision()`
	)		const `[inherited]`

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Sqrt ( ) const [inline, inherited]

Definition at line 738 of file Core.

EIGEN_STRONG_INLINE MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Sqrt ( ) [inline, inherited]

Definition at line 737 of file Core.

EIGEN_STRONG_INLINE MatrixBase<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >& Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Square ( ) [inline, inherited]

Definition at line 749 of file Core.

EIGEN_STRONG_INLINE PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Square ( ) const [inline, inherited]

Definition at line 750 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::squaredNorm ( ) const [inherited]

Returns:: , for vectors, the squared l2 norm of *this, and for matrices the Frobenius norm. In both cases, it consists in the sum of the square of all the matrix entries. For vectors, this is also equals to the dot product of *this with itself.

See also:: dot(), norm()

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::squareNorm ( ) const [inline, inherited]

Compute the square norm of a vector/array/matrix (the Euclidean distance to the origin, taking all the elements as a single vector).

See also:: norm

Definition at line 275 of file Core.

RealScalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::stableNorm ( ) const [inherited]

Returns:: the l2 norm of *this avoiding underflow and overflow. This version use a blockwise two passes algorithm: 1 - find the absolute largest coefficient s 2 - compute $s \Vert \frac{*this}{s} \Vert$ in a standard way

For architecture/scalar types supporting vectorization, this version is faster than blueNorm(). Otherwise the blueNorm() is much faster.

See also:: norm(), blueNorm(), hypotNorm()

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::substract_AAt ( const OTHERMATRIX & A ) [inline, inherited]

this -= A + A^T

Definition at line 521 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::substract_Ac	(	const OTHERMATRIX &	m,
		const Scalar	c
	)		`[inline, inherited]`

Substract c (scalar) times A to this matrix: this -= A * c

Definition at line 509 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::substract_An	(	const OTHERMATRIX &	m,
		const size_t	n
	)		`[inline, inherited]`

Substract n (integer) times A to this matrix: this -= A * n

Definition at line 515 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::substract_At ( const OTHERMATRIX & m ) [inline, inherited]

Substract A transposed to this matrix: this -= A.adjoint()

Definition at line 512 of file Core.

void Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::subTo ( Dest & dst ) const [inline, inherited]

Definition at line 122 of file Core.

Scalar Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::sum ( ) const [inherited]

Returns:: the sum of all coefficients of *this

See also:: trace(), prod(), mean()

EIGEN_STRONG_INLINE Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::sumAll ( ) const [inline, inherited]

Sum all the elements, returning a value of the same type than the container

Definition at line 278 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::swap ( PlainObjectBase< OtherDerived > & other ) [inline, inherited]

swaps *this with the matrix or array other.

Definition at line 407 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::swap	(	const DenseBase< OtherDerived > &	other,
		int	= `OtherDerived::ThisConstantIsPrivateInPlainObjectBase`
	)		`[inline, inherited]`

swaps *this with the expression other.

Definition at line 397 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::swapCols	(	size_t	i1,
		size_t	i2
	)		`[inline, inherited]`

Definition at line 187 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::swapRows	(	size_t	i1,
		size_t	i2
	)		`[inline, inherited]`

Definition at line 188 of file Core.

EIGEN_STRONG_INLINE const AdjointReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::t ( ) const [inline, inherited]

Transpose.

Definition at line 491 of file Core.

SegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::tail ( Index size ) [inherited]

Returns:: a dynamic-size expression of the last coefficients of *this.

Parameters:

size	the number of coefficients in the block

Example:

Output:

Note:: Even though the returned expression has dynamic size, in the case when it is applied to a fixed-size vector, it inherits a fixed maximal size, which means that evaluating it does not cause a dynamic memory allocation.

See also:: class Block, block(Index,Index)

ConstFixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::tail ( ) const [inherited]

This is the const version of tail<int>.

FixedSegmentReturnType<Size>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::tail ( ) [inherited]

Returns:: a fixed-size expression of the last coefficients of *this.

The template parameter Size is the number of coefficients in the block

Example:

Output:

See also:: class Block

DenseBase::ConstSegmentReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::tail ( Index size ) const [inherited]

This is the const version of tail(Index).

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topLeftCorner ( ) [inline, inherited]

Returns:: an expression of a fixed-size top-left corner of *this.

The template parameters CRows and CCols are the number of rows and columns in the corner.

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 161 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topLeftCorner	(	Index	cRows,
		Index	cCols
	)		const `[inline, inherited]`

This is the const version of topLeftCorner(Index, Index).

Definition at line 146 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topLeftCorner	(	Index	cRows,
		Index	cCols
	)		`[inline, inherited]`

Returns:: a dynamic-size expression of a top-left corner of *this.

Parameters:

cRows	the number of rows in the corner
cCols	the number of columns in the corner

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 140 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topLeftCorner ( ) const [inline, inherited]

This is the const version of topLeftCorner<int, int>().

Definition at line 168 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRightCorner	(	Index	cRows,
		Index	cCols
	)		`[inline, inherited]`

Returns:: a dynamic-size expression of a top-right corner of *this.

Parameters:

cRows	the number of rows in the corner
cCols	the number of columns in the corner

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 94 of file Core.

Block<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRightCorner ( ) [inline, inherited]

Returns:: an expression of a fixed-size top-right corner of *this.

The template parameters CRows and CCols are the number of rows and columns in the corner.

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 115 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRightCorner	(	Index	cRows,
		Index	cCols
	)		const `[inline, inherited]`

This is the const version of topRightCorner(Index, Index).

Definition at line 100 of file Core.

const Block<const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , CRows, CCols> Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRightCorner ( ) const [inline, inherited]

This is the const version of topRightCorner<int, int>().

Definition at line 122 of file Core.

ConstNRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRows ( ) const [inline, inherited]

This is the const version of topRows<int>().

Definition at line 302 of file Core.

NRowsBlockXpr<N>::Type Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRows ( ) [inline, inherited]

Returns:: a block consisting of the top rows of *this.

Template Parameters:

N	the number of rows in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 295 of file Core.

RowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRows ( Index n ) [inline, inherited]

Returns:: a block consisting of the top rows of *this.

Parameters:

n	the number of rows in the block

Example:

Output:

See also:: class Block, block(Index,Index,Index,Index)

Definition at line 274 of file Core.

ConstRowsBlockXpr Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::topRows ( Index n ) const [inline, inherited]

This is the const version of topRows(Index).

Definition at line 280 of file Core.

Scalar Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::trace ( ) const [inherited]

Returns:: the trace of *this, i.e. the sum of the coefficients on the main diagonal.

*this can be any matrix, not necessarily square.

See also:: diagonal(), sum()

Reimplemented from Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >.

ConstTransposeReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::transpose ( ) const [inherited]

This is the const version of transpose().

Make sure you read the warning for transpose() !

See also:: transposeInPlace(), adjoint()

Eigen::Transpose<TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::transpose ( ) [inherited]

Returns:: an expression of the transpose of *this.

Example:

Output:

Warning:

If you want to replace a matrix by its own transpose, do NOT do this:

 m = m.transpose(); // bug!!! caused by aliasing effect

Instead, use the transposeInPlace() method:

 m.transposeInPlace();

which gives Eigen good opportunities for optimization, or alternatively you can also do:

 m = m.transpose().eval();

See also:: transposeInPlace(), adjoint()

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::transposeInPlace ( ) [inherited]

This is the "in place" version of transpose(): it replaces *this by its own transpose.

Thus, doing

 m.transposeInPlace();

has the same effect on m as doing

 m = m.transpose().eval();

and is faster and also safer because in the latter line of code, forgetting the eval() results in a bug caused by aliasing.

Notice however that this method is only useful if you want to replace a matrix by its own transpose. If you just need the transpose of a matrix, use transpose().

Note:: if the matrix is not square, then *this must be a resizable matrix.

See also:: transpose(), adjoint(), adjointInPlace()

ConstTriangularViewReturnType<Mode>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::triangularView ( ) const [inherited]

This is the const version of MatrixBase::triangularView()

TriangularViewReturnType<Mode>::Type Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::triangularView ( ) [inherited]

Returns:: an expression of a triangular view extracted from the current matrix

The parameter Mode can have the following values: #Upper, #StrictlyUpper, #UnitUpper, #Lower, #StrictlyLower, #UnitLower.

Example:

Output:

See also:: class TriangularView

const CwiseUnaryOp<CustomUnaryOp, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unaryExpr ( const CustomUnaryOp & func = CustomUnaryOp() ) const [inline, inherited]

Apply a unary operator coefficient-wise.

Parameters:

[in] func Functor implementing the unary operator

Template Parameters:

CustomUnaryOp Type of func

Returns:: An expression of a custom coefficient-wise unary operator func of *this

The function ptr_fun() from the C++ standard library can be used to make functors out of normal functions.

Example:

Output:

Genuine functors allow for more possibilities, for instance it may contain a state.

Example:

Output:

See also:: class CwiseUnaryOp, class CwiseBinaryOp

Definition at line 155 of file Core.

const CwiseUnaryView<CustomViewOp, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unaryViewExpr ( const CustomViewOp & func = CustomViewOp() ) const [inline, inherited]

Returns:: an expression of a custom coefficient-wise unary operator func of *this

The template parameter CustomUnaryOp is the type of the functor of the custom unary operator.

Example:

Output:

See also:: class CwiseUnaryOp, class CwiseBinaryOp

Definition at line 173 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unit	(	const size_t	nRows,
		const Scalar	diag_vals
	)		`[inline, inherited]`

Make the matrix an identity matrix (the diagonal values can be 1.0 or any other value)

Definition at line 72 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unit ( ) [inline, inherited]

Make the matrix an identity matrix.

Definition at line 82 of file Core.

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Unit ( Index i ) [static, inherited]

Returns:: an expression of the i-th unit (basis) vector.

This variant is for fixed-size vector only.

See also:: MatrixBase::Unit(Index,Index), MatrixBase::UnitX(), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Unit	(	Index	size,
		Index	i
	)		`[static, inherited]`

Returns:: an expression of the i-th unit (basis) vector.

See also:: MatrixBase::Unit(Index), MatrixBase::UnitX(), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

PlainObject Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unitOrthogonal ( void ) const [inherited]

Returns:: a unit vector which is orthogonal to *this

The size of *this must be at least 2. If the size is exactly 2, then the returned vector is a counter clock wise rotation of *this, i.e., (-y,x).normalized().

See also:: cross()

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::UnitW ( ) [static, inherited]

Returns:: an expression of the W axis unit vector (0,0,0,1)

See also:: MatrixBase::Unit(Index,Index), MatrixBase::Unit(Index), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::UnitX ( ) [static, inherited]

Returns:: an expression of the X axis unit vector (1{,0}^*)

See also:: MatrixBase::Unit(Index,Index), MatrixBase::Unit(Index), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::UnitY ( ) [static, inherited]

Returns:: an expression of the Y axis unit vector (0,1{,0}^*)

See also:: MatrixBase::Unit(Index,Index), MatrixBase::Unit(Index), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

static const BasisReturnType Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::UnitZ ( ) [static, inherited]

Returns:: an expression of the Z axis unit vector (0,0,1{,0}^*)

See also:: MatrixBase::Unit(Index,Index), MatrixBase::Unit(Index), MatrixBase::UnitY(), MatrixBase::UnitZ(), MatrixBase::UnitW()

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unsafeRemoveColumns ( const std::vector< size_t > & idxs ) [inline, inherited]

Remove columns of the matrix.

The unsafe version assumes that, the indices are sorted in ascending order.

Definition at line 454 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::unsafeRemoveRows ( const std::vector< size_t > & idxs ) [inline, inherited]

Remove rows of the matrix.

The unsafe version assumes that, the indices are sorted in ascending order.

Definition at line 478 of file Core.

CoeffReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::value ( void ) const [inline, inherited]

Returns:: the unique coefficient of a 1x1 expression

Definition at line 447 of file Core.

void Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::visit ( Visitor & func ) const [inherited]

Applies the visitor visitor to the whole coefficients of the matrix or vector.

The template parameter Visitor is the type of the visitor and provides the following interface:

 struct MyVisitor {
   // called for the first coefficient
   void init(const Scalar& value, Index i, Index j);
   // called for all other coefficients
   void operator() (const Scalar& value, Index i, Index j);
 };

Note:: compared to one or two for loops, visitors offer automatic unrolling for small fixed size matrix.

See also:: minCoeff(Index*,Index*), maxCoeff(Index*,Index*), DenseBase::redux()

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Zero ( Index size ) [static, inherited]

Returns:: an expression of a zero vector.

The parameter size is the size of the returned vector. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size vector types. For fixed-size types, it is redundant to pass size as argument, so Zero() should be used instead.

Example:

Output:

See also:: Zero(), Zero(Index,Index)

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Zero ( ) [static, inherited]

Returns:: an expression of a fixed-size zero matrix or vector.

This variant is only for fixed-size MatrixBase types. For dynamic-size types, you need to use the variants taking size arguments.

Example:

Output:

See also:: Zero(Index), Zero(Index,Index)

static const ConstantReturnType Eigen::DenseBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::Zero	(	Index	rows,
		Index	cols
	)		`[static, inherited]`

Returns:: an expression of a zero matrix.

The parameters rows and cols are the number of rows and of columns of the returned matrix. Must be compatible with this MatrixBase type.

This variant is meant to be used for dynamic-size matrix types. For fixed-size types, it is redundant to pass rows and cols as arguments, so Zero() should be used instead.

Example:

Output:

See also:: Zero(), Zero(Index)

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::zeros	(	const size_t	row,
		const size_t	col
	)		`[inline, inherited]`

Resize and set all elements to zero.

Definition at line 89 of file Core.

EIGEN_STRONG_INLINE void Eigen::MatrixBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > >::zeros ( ) [inline, inherited]

Set all elements to zero.

Definition at line 87 of file Core.

Friends And Related Function Documentation

const ScalarMultipleReturnType operator*	(	const Scalar &	scalar,
		const StorageBaseType &	matrix
	)		`[friend, inherited]`

Definition at line 92 of file Core.

const CwiseUnaryOp<internal::scalar_multiple2_op<Scalar,std::complex<Scalar> >, const TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > > operator*	(	const std::complex< Scalar > &	scalar,
		const StorageBaseType &	matrix
	)		`[friend, inherited]`

Definition at line 96 of file Core.

Member Data Documentation

const LhsNested Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::m_lhs [protected, inherited]

Definition at line 183 of file Core.

PlainObject Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::m_result [mutable, protected, inherited]

Definition at line 186 of file Core.

const RhsNested Eigen::ProductBase< TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false > , Lhs, Rhs >::m_rhs [protected, inherited]

Definition at line 184 of file Core.

Detailed Description

template<int Mode, bool LhsIsTriangular, typename Lhs, typename Rhs> struct Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >

Public Types

Public Member Functions

Static Public Member Functions

Protected Member Functions

Protected Attributes

Friends

MRPT plugin: Basic iterators. These iterators are intended for 1D matrices only, i.e. column or row vectors.

Member Typedef Documentation

Member Enumeration Documentation

Constructor & Destructor Documentation

Member Function Documentation

Friends And Related Function Documentation

Member Data Documentation

template<int Mode, bool LhsIsTriangular, typename Lhs, typename Rhs>
struct Eigen::TriangularProduct< Mode, LhsIsTriangular, Lhs, false, Rhs, false >