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ROOT » MATH » MATRIX » TMatrixTSym<double>

class TMatrixTSym<double>: public TMatrixTBase<double>


TMatrixTSym

Template class of a symmetric matrix in the linear algebra package

Note that in this implementation both matrix element m[i][j] and
m[j][i] are updated and stored in memory . However, when making the
object persistent only the upper right triangle is stored .

This class is also known as (typedefs to this class)

TMatrixTSym<Double_t>, TMatrixDSym

Function Members (Methods)

public:

	TMatrixTSym<double>()
	TMatrixTSym<double>(Int_t nrows)
	TMatrixTSym<double>(const TMatrixTSym<double>& another)
	TMatrixTSym<double>(const TMatrixTSymLazy<double>& lazy_constructor)
	TMatrixTSym<double>(Int_t row_lwb, Int_t row_upb)
	TMatrixTSym<double>(TMatrixTSym<double>::EMatrixCreatorsOp1 op, const TMatrixTSym<double>& prototype)
	TMatrixTSym<double>(TMatrixTSym<double>::EMatrixCreatorsOp1 op, const TMatrixT<double>& prototype)
	TMatrixTSym<double>(Int_t nrows, const double* data, Option_t* option = "")
	TMatrixTSym<double>(const TMatrixTSym<double>& a, TMatrixTSym<double>::EMatrixCreatorsOp2 op, const TMatrixTSym<double>& b)
	TMatrixTSym<double>(Int_t row_lwb, Int_t row_upb, const double* data, Option_t* option = "")
virtual	~TMatrixTSym<double>()
virtual TMatrixTBase<double>&	TMatrixTBase<double>::Abs()
void	TObject::AbstractMethod(const char* method) const
virtual void	TObject::AppendPad(Option_t* option = "")
virtual TMatrixTBase<double>&	Apply(const TElementActionT<double>& action)
virtual TMatrixTBase<double>&	Apply(const TElementPosActionT<double>& action)
virtual void	TObject::Browse(TBrowser* b)
static TClass*	Class()
virtual const char*	TObject::ClassName() const
virtual void	Clear(Option_t* = "")
virtual TObject*	TObject::Clone(const char* newname = "") const
virtual double	TMatrixTBase<double>::ColNorm() const
virtual Int_t	TObject::Compare(const TObject* obj) const
virtual void	TObject::Copy(TObject& object) const
virtual void	TObject::Delete(Option_t* option = "")MENU
virtual Double_t	Determinant() const
virtual void	Determinant(Double_t& d1, Double_t& d2) const
virtual Int_t	TObject::DistancetoPrimitive(Int_t px, Int_t py)
virtual void	TMatrixTBase<double>::Draw(Option_t* option = "")MENU
virtual void	TObject::DrawClass() constMENU
virtual TObject*	TObject::DrawClone(Option_t* option = "") constMENU
virtual void	TObject::Dump() constMENU
virtual double	TMatrixTBase<double>::E2Norm() const
const TMatrixT<double>	EigenVectors(TVectorT<double>& eigenValues) const
virtual void	TObject::Error(const char* method, const char* msgfmt) const
virtual void	TObject::Execute(const char* method, const char* params, Int_t* error = 0)
virtual void	TObject::Execute(TMethod* method, TObjArray* params, Int_t* error = 0)
virtual void	TObject::ExecuteEvent(Int_t event, Int_t px, Int_t py)
virtual void	TMatrixTBase<double>::ExtractRow(Int_t row, Int_t col, double* v, Int_t n = -1) const
virtual void	TObject::Fatal(const char* method, const char* msgfmt) const
virtual TObject*	TObject::FindObject(const char* name) const
virtual TObject*	TObject::FindObject(const TObject* obj) const
virtual const Int_t*	GetColIndexArray() const
virtual Int_t*	GetColIndexArray()
Int_t	TMatrixTBase<double>::GetColLwb() const
Int_t	TMatrixTBase<double>::GetColUpb() const
virtual Option_t*	TObject::GetDrawOption() const
static Long_t	TObject::GetDtorOnly()
virtual const char*	TObject::GetIconName() const
virtual void	TMatrixTBase<double>::GetMatrix2Array(double* data, Option_t* option = "") const
virtual const double*	GetMatrixArray() const
virtual double*	GetMatrixArray()
virtual const char*	TObject::GetName() const
Int_t	TMatrixTBase<double>::GetNcols() const
Int_t	TMatrixTBase<double>::GetNoElements() const
Int_t	TMatrixTBase<double>::GetNrows() const
virtual char*	TObject::GetObjectInfo(Int_t px, Int_t py) const
static Bool_t	TObject::GetObjectStat()
virtual Option_t*	TObject::GetOption() const
virtual const Int_t*	GetRowIndexArray() const
virtual Int_t*	GetRowIndexArray()
Int_t	TMatrixTBase<double>::GetRowLwb() const
Int_t	TMatrixTBase<double>::GetRowUpb() const
TMatrixTSym<double>&	GetSub(Int_t row_lwb, Int_t row_upb, TMatrixTSym<double>& target, Option_t* option = "S") const
TMatrixTSym<double>	GetSub(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, Option_t* option = "S") const
virtual TMatrixTBase<double>&	GetSub(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, TMatrixTBase<double>& target, Option_t* option = "S") const
virtual const char*	TObject::GetTitle() const
double	TMatrixTBase<double>::GetTol() const
virtual UInt_t	TObject::GetUniqueID() const
virtual Bool_t	TObject::HandleTimer(TTimer* timer)
virtual ULong_t	TObject::Hash() const
virtual void	TObject::Info(const char* method, const char* msgfmt) const
virtual Bool_t	TObject::InheritsFrom(const char* classname) const
virtual Bool_t	TObject::InheritsFrom(const TClass* cl) const
virtual TMatrixTBase<double>&	TMatrixTBase<double>::InsertRow(Int_t row, Int_t col, const double* v, Int_t n = -1)
virtual void	TObject::Inspect() constMENU
void	TMatrixTBase<double>::Invalidate()
TMatrixTSym<double>&	Invert(Double_t* det = 0)
void	TObject::InvertBit(UInt_t f)
TMatrixTSym<double>&	InvertFast(Double_t* det = 0)
virtual TClass*	IsA() const
virtual Bool_t	TObject::IsEqual(const TObject* obj) const
virtual Bool_t	TObject::IsFolder() const
Bool_t	TObject::IsOnHeap() const
Bool_t	TMatrixTBase<double>::IsOwner() const
virtual Bool_t	TObject::IsSortable() const
virtual Bool_t	IsSymmetric() const
Bool_t	TMatrixTBase<double>::IsValid() const
Bool_t	TObject::IsZombie() const
virtual void	TObject::ls(Option_t* option = "") const
void	TMatrixTBase<double>::MakeValid()
virtual double	TMatrixTBase<double>::Max() const
void	TObject::MayNotUse(const char* method) const
virtual double	TMatrixTBase<double>::Min() const
void	Minus(const TMatrixTSym<double>& a, const TMatrixTSym<double>& b)
void	Mult(const TMatrixTSym<double>& a)
virtual Int_t	TMatrixTBase<double>::NonZeros() const
double	TMatrixTBase<double>::Norm1() const
virtual TMatrixTBase<double>&	TMatrixTBase<double>::NormByDiag(const TVectorT<double>& v, Option_t* option = "D")
double	TMatrixTBase<double>::NormInf() const
virtual Bool_t	TObject::Notify()
void	TObject::Obsolete(const char* method, const char* asOfVers, const char* removedFromVers) const
static void	TObject::operator delete(void* ptr)
static void	TObject::operator delete(void* ptr, void* vp)
static void	TObject::operator delete[](void* ptr)
static void	TObject::operator delete[](void* ptr, void* vp)
void*	TObject::operator new(size_t sz)
void*	TObject::operator new(size_t sz, void* vp)
void*	TObject::operator new[](size_t sz)
void*	TObject::operator new[](size_t sz, void* vp)
Bool_t	TMatrixTBase<double>::operator!=(double val) const
virtual double	operator()(Int_t rown, Int_t coln) const
virtual double&	operator()(Int_t rown, Int_t coln)
TMatrixTSym<double>&	operator*=(double val)
TMatrixTSym<double>&	operator+=(double val)
TMatrixTSym<double>&	operator+=(const TMatrixTSym<double>& source)
TMatrixTSym<double>&	operator-=(double val)
TMatrixTSym<double>&	operator-=(const TMatrixTSym<double>& source)
Bool_t	TMatrixTBase<double>::operator<(double val) const
Bool_t	TMatrixTBase<double>::operator<=(double val) const
TMatrixTSym<double>&	operator=(const TMatrixTSym<double>& source)
TMatrixTSym<double>&	operator=(const TMatrixTSymLazy<double>& source)
TMatrixTSym<double>&	operator=(double val)
Bool_t	TMatrixTBase<double>::operator==(double val) const
Bool_t	TMatrixTBase<double>::operator>(double val) const
Bool_t	TMatrixTBase<double>::operator>=(double val) const
const TMatrixTRow_const<double>	operator[](Int_t rown) const
TMatrixTRow<double>	operator[](Int_t rown)
virtual void	TObject::Paint(Option_t* option = "")
void	Plus(const TMatrixTSym<double>& a, const TMatrixTSym<double>& b)
virtual void	TObject::Pop()
virtual void	TMatrixTBase<double>::Print(Option_t* name = "") constMENU
virtual TMatrixTBase<double>&	Randomize(double alpha, double beta, Double_t& seed)
virtual TMatrixTSym<double>&	RandomizePD(double alpha, double beta, Double_t& seed)
TMatrixTSym<double>&	Rank1Update(const TVectorT<double>& v, double alpha = 1.0)
virtual Int_t	TObject::Read(const char* name)
virtual void	TObject::RecursiveRemove(TObject* obj)
void	TObject::ResetBit(UInt_t f)
TMatrixTBase<double>&	ResizeTo(const TMatrixTSym<double>& m)
virtual TMatrixTBase<double>&	ResizeTo(Int_t nrows, Int_t ncols, Int_t = -1)
virtual TMatrixTBase<double>&	ResizeTo(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, Int_t = -1)
virtual double	TMatrixTBase<double>::RowNorm() const
virtual void	TObject::SaveAs(const char* filename = "", Option_t* option = "") constMENU
virtual void	TObject::SavePrimitive(ostream& out, Option_t* option = "")
void	TObject::SetBit(UInt_t f)
void	TObject::SetBit(UInt_t f, Bool_t set)
virtual TMatrixTBase<double>&	SetColIndexArray(Int_t*)
virtual void	TObject::SetDrawOption(Option_t* option = "")MENU
static void	TObject::SetDtorOnly(void* obj)
virtual TMatrixTBase<double>&	SetMatrixArray(const double* data, Option_t* option = "")
static void	TObject::SetObjectStat(Bool_t stat)
virtual TMatrixTBase<double>&	SetRowIndexArray(Int_t*)
TMatrixTSym<double>&	SetSub(Int_t row_lwb, const TMatrixTBase<double>& source)
virtual TMatrixTBase<double>&	SetSub(Int_t row_lwb, Int_t col_lwb, const TMatrixTBase<double>& source)
double	TMatrixTBase<double>::SetTol(double newTol)
virtual void	TObject::SetUniqueID(UInt_t uid)
virtual TMatrixTBase<double>&	Shift(Int_t row_shift, Int_t col_shift)
virtual void	ShowMembers(TMemberInspector&)
TMatrixTSym<double>&	Similarity(const TMatrixT<double>& n)
TMatrixTSym<double>&	Similarity(const TMatrixTSym<double>& n)
double	Similarity(const TVectorT<double>& v) const
TMatrixTSym<double>&	SimilarityT(const TMatrixT<double>& n)
virtual TMatrixTBase<double>&	TMatrixTBase<double>::Sqr()
virtual TMatrixTBase<double>&	TMatrixTBase<double>::Sqrt()
virtual void	Streamer(TBuffer&)
void	StreamerNVirtual(TBuffer& ClassDef_StreamerNVirtual_b)
virtual double	TMatrixTBase<double>::Sum() const
virtual void	TObject::SysError(const char* method, const char* msgfmt) const
TMatrixTSym<double>&	T()
Bool_t	TObject::TestBit(UInt_t f) const
Int_t	TObject::TestBits(UInt_t f) const
void	TMult(const TMatrixT<double>& a)
void	TMult(const TMatrixTSym<double>& a)
TMatrixTSym<double>&	Transpose(const TMatrixTSym<double>& source)
virtual TMatrixTBase<double>&	TMatrixTBase<double>::UnitMatrix()
TMatrixTSym<double>&	Use(TMatrixTSym<double>& a)
const TMatrixTSym<double>&	Use(const TMatrixTSym<double>& a) const
TMatrixTSym<double>&	Use(Int_t nrows, double* data)
const TMatrixTSym<double>&	Use(Int_t nrows, const double* data) const
TMatrixTSym<double>&	Use(Int_t row_lwb, Int_t row_upb, double* data)
const TMatrixTSym<double>&	Use(Int_t row_lwb, Int_t row_upb, const double* data) const
virtual void	TObject::UseCurrentStyle()
virtual void	TObject::Warning(const char* method, const char* msgfmt) const
virtual Int_t	TObject::Write(const char* name = 0, Int_t option = 0, Int_t bufsize = 0)
virtual Int_t	TObject::Write(const char* name = 0, Int_t option = 0, Int_t bufsize = 0) const
virtual TMatrixTBase<double>&	TMatrixTBase<double>::Zero()

protected:

void	Allocate(Int_t nrows, Int_t ncols, Int_t row_lwb = 0, Int_t col_lwb = 0, Int_t init = 0, Int_t = -1)
void	Delete_m(Int_t size, double*&)
virtual void	TObject::DoError(int level, const char* location, const char* fmt, va_list va) const
static void	TMatrixTBase<double>::DoubleLexSort(Int_t n, Int_t* first, Int_t* second, double* data)
static void	TMatrixTBase<double>::IndexedLexSort(Int_t n, Int_t* first, Int_t swapFirst, Int_t* second, Int_t swapSecond, Int_t* index)
void	TObject::MakeZombie()
Int_t	Memcpy_m(double* newp, const double* oldp, Int_t copySize, Int_t newSize, Int_t oldSize)
double*	New_m(Int_t size)

Data Members

public:

enum {	kWorkMax
};
enum EMatrixCreatorsOp1 {	kZero
	kUnit
	kTransposed
	kInverted
	kAtA
};
enum EMatrixCreatorsOp2 {	kPlus
	kMinus
};
enum TMatrixTBase::[unnamed] {	kSizeMax
	kWorkMax
};
enum TMatrixTBase::EMatrixStatusBits {	kStatus
};
enum TObject::EStatusBits {	kCanDelete
	kMustCleanup
	kObjInCanvas
	kIsReferenced
	kHasUUID
	kCannotPick
	kNoContextMenu
	kInvalidObject
};
enum TObject::[unnamed] {	kIsOnHeap
	kNotDeleted
	kZombie
	kBitMask
	kSingleKey
	kOverwrite
	kWriteDelete
};

protected:

Int_t	TMatrixTBase<double>::fColLwb	lower bound of the col index
double	fDataStack[25]	! data container
double*	fElements	[fNelems] elements themselves
Bool_t	TMatrixTBase<double>::fIsOwner	!default kTRUE, when Use array kFALSE
Int_t	TMatrixTBase<double>::fNcols	number of columns
Int_t	TMatrixTBase<double>::fNelems	number of elements in matrix
Int_t	TMatrixTBase<double>::fNrowIndex	length of row index array (= fNrows+1) wich is only used for sparse matrices
Int_t	TMatrixTBase<double>::fNrows	number of rows
Int_t	TMatrixTBase<double>::fRowLwb	lower bound of the row index
double	TMatrixTBase<double>::fTol	sqrt(epsilon); epsilon is smallest number number so that 1+epsilon > 1

Class Charts

Inheritance Inherited Members Includes Libraries

Function documentation

void TMatrixTSym<Element> Delete_m(Int_t size, double*& )

 delete data pointer m, if it was assigned on the heap

Element* TMatrixTSym<Element> New_m(Int_t size)

 return data pointer . if requested size <= kSizeMax, assign pointer
 to the stack space

Int_t TMatrixTSym<Element> Memcpy_m(double* newp, const double* oldp, Int_t copySize, Int_t newSize, Int_t oldSize)

 copy copySize doubles from *oldp to *newp . However take care of the
 situation where both pointers are assigned to the same stack space

void TMatrixTSym<Element> Allocate(Int_t nrows, Int_t ncols, Int_t row_lwb = 0, Int_t col_lwb = 0, Int_t init = 0, Int_t = -1)

 Allocate new matrix. Arguments are number of rows, columns, row
 lowerbound (0 default) and column lowerbound (0 default).

void TMatrixTSym<Element> Plus(const TMatrixTSym<double>& a, const TMatrixTSym<double>& b)

 Symmetric matrix summation. Create a matrix C such that C = A + B.

void TMatrixTSym<Element> Minus(const TMatrixTSym<double>& a, const TMatrixTSym<double>& b)

 Symmetric matrix summation. Create a matrix C such that C = A + B.

void TMatrixTSym<Element> TMult(const TMatrixT<Element> &a)

 Create a matrix C such that C = A' * A. In other words,
 c[i,j] = SUM{ a[k,i] * a[k,j] }.

void TMatrixTSym<Element> TMult(const TMatrixTSym<Element> &a)

 Matrix multiplication, with A symmetric
 Create a matrix C such that C = A' * A = A * A = A * A'

TMatrixTSym<Element> &TMatrixTSym<Element> Use(Int_t row_lwb, Int_t row_upb, double* data)

TMatrixTSym<Element> &TMatrixTSym<Element> GetSub(Int_t row_lwb, Int_t row_upb, TMatrixTSym<double>& target, Option_t* option = "S") const

 Get submatrix [row_lwb..row_upb][row_lwb..row_upb]; The indexing range of the
 returned matrix depends on the argument option:

 option == "S" : return [0..row_upb-row_lwb+1][0..row_upb-row_lwb+1] (default)
 else          : return [row_lwb..row_upb][row_lwb..row_upb]

TMatrixTBase<Element> &TMatrixTSym<Element> GetSub(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, TMatrixTBase<double>& target, Option_t* option = "S") const

 Get submatrix [row_lwb..row_upb][col_lwb..col_upb]; The indexing range of the
 returned matrix depends on the argument option:

 option == "S" : return [0..row_upb-row_lwb+1][0..col_upb-col_lwb+1] (default)
 else          : return [row_lwb..row_upb][col_lwb..col_upb]

TMatrixTSym<Element> &TMatrixTSym<Element> SetSub(Int_t row_lwb, const TMatrixTBase<double>& source)

 Insert matrix source starting at [row_lwb][row_lwb], thereby overwriting the part
 [row_lwb..row_lwb+nrows_source][row_lwb..row_lwb+nrows_source];

TMatrixTBase<Element> &TMatrixTSym<Element> SetSub(Int_t row_lwb, Int_t col_lwb, const TMatrixTBase<double>& source)

 Insert matrix source starting at [row_lwb][col_lwb] in a symmetric fashion, thereby overwriting the part
 [row_lwb..row_lwb+nrows_source][row_lwb..row_lwb+nrows_source];

TMatrixTBase<Element> &TMatrixTSym<Element> SetMatrixArray(const double* data, Option_t* option = "")

TMatrixTBase<Element> &TMatrixTSym<Element> Shift(Int_t row_shift, Int_t col_shift)

TMatrixTBase<Element> &TMatrixTSym<Element> ResizeTo(Int_t nrows, Int_t ncols, Int_t = -1)

 Set size of the matrix to nrows x ncols
 New dynamic elements are created, the overlapping part of the old ones are
 copied to the new structures, then the old elements are deleted.

TMatrixTBase<Element> &TMatrixTSym<Element> ResizeTo(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, Int_t = -1)

 Set size of the matrix to [row_lwb:row_upb] x [col_lwb:col_upb]
 New dynamic elemenst are created, the overlapping part of the old ones are
 copied to the new structures, then the old elements are deleted.

Double_t TMatrixTSym<Element> Determinant() const

void TMatrixTSym<Element> Determinant(Double_t& d1, Double_t& d2) const

TMatrixTSym<Element> &TMatrixTSym<Element> Invert(Double_t* det = 0)

 Invert the matrix and calculate its determinant
 Notice that the LU decomposition is used instead of Bunch-Kaufman
 Bunch-Kaufman guarantees a symmetric inverted matrix but is slower than LU .
 The user can access Bunch-Kaufman through the TDecompBK class .

TMatrixTSym<Element> &TMatrixTSym<Element> InvertFast(Double_t* det = 0)

 Invert the matrix and calculate its determinant

TMatrixTSym<Element> &TMatrixTSym<Element> Transpose(const TMatrixTSym<double>& source)

 Transpose a matrix.

TMatrixTSym<Element> &TMatrixTSym<Element> Rank1Update(const TVectorT<double>& v, double alpha = 1.0)

 Perform a rank 1 operation on the matrix:
     A += alpha * v * v^T

TMatrixTSym<Element> &TMatrixTSym<Element> Similarity(const TMatrixT<Element> &b)

 Calculate B * (*this) * B^T , final matrix will be (nrowsb x nrowsb)
 This is a similarity transform when B is orthogonal . It is more
 efficient than applying the actual multiplication because this
 routine realizes that  the final matrix is symmetric .

TMatrixTSym<Element> &TMatrixTSym<Element> Similarity(const TMatrixTSym<Element> &b)

 Calculate B * (*this) * B^T , final matrix will be (nrowsb x nrowsb)
 This is a similarity transform when B is orthogonal . It is more
 efficient than applying the actual multiplication because this
 routine realizes that  the final matrix is symmetric .

Element TMatrixTSym<Element> Similarity(const TVectorT<double>& v) const

 Calculate scalar v * (*this) * v^T

TMatrixTSym<Element> &TMatrixTSym<Element> SimilarityT(const TMatrixT<double>& n)

 Calculate B^T * (*this) * B , final matrix will be (ncolsb x ncolsb)
 It is more efficient than applying the actual multiplication because this
 routine realizes that  the final matrix is symmetric .

TMatrixTSym<Element> &TMatrixTSym<Element> operator=(const TMatrixTSym<Element> &source)

TMatrixTSym<Element> &TMatrixTSym<Element> operator=(const TMatrixTSymLazy<Element> &lazy_constructor)

TMatrixTSym<Element> &TMatrixTSym<Element> operator=(Element val)

 Assign val to every element of the matrix.

TMatrixTSym<Element> &TMatrixTSym<Element> operator+=(Element val)

 Add val to every element of the matrix.

TMatrixTSym<Element> &TMatrixTSym<Element> operator-=(Element val)

 Subtract val from every element of the matrix.

TMatrixTSym<Element> &TMatrixTSym<Element> operator*=(double val)

 Multiply every element of the matrix with val.

TMatrixTSym<Element> &TMatrixTSym<Element> operator+=(const TMatrixTSym<Element> &source)

 Add the source matrix.

TMatrixTSym<Element> &TMatrixTSym<Element> operator-=(const TMatrixTSym<Element> &source)

 Subtract the source matrix.

TMatrixTBase<Element> &TMatrixTSym<Element> Apply(const TElementActionT<Element> &action)

TMatrixTBase<Element> &TMatrixTSym<Element> Apply(const TElementPosActionT<Element> &action)

 Apply action to each element of the matrix. To action the location
 of the current element is passed.

TMatrixTBase<Element> &TMatrixTSym<Element> Randomize(double alpha, double beta, Double_t& seed)

 randomize matrix element values but keep matrix symmetric

TMatrixTSym<Element> &TMatrixTSym<Element> RandomizePD(double alpha, double beta, Double_t& seed)

 randomize matrix element values but keep matrix symmetric positive definite

const TMatrixT<Element> TMatrixTSym<Element> EigenVectors(TVectorT<double>& eigenValues) const

 Return a matrix containing the eigen-vectors ordered by descending eigen-values.
 For full functionality use TMatrixDSymEigen .

void TMatrixTSym<Element> Streamer(TBuffer& )

 Stream an object of class TMatrixTSym.

template <class Element> inline const Element *TMatrixTSym<Element> GetMatrixArray() const

{ return fElements; }

template <class Element> inline Element *TMatrixTSym<Element> GetMatrixArray()

{ return fElements; }

template <class Element> inline TMatrixTSym<Element> &TMatrixTSym<Element> Use(Int_t nrows, double* data)

{ return Use(0,nrows-1,data); }

template <class Element> inline const TMatrixTSym<Element> &TMatrixTSym<Element> Use(Int_t nrows, const double* data) const

{ return Use(0,nrows-1,data); }

template <class Element> inline TMatrixTSym<Element> &TMatrixTSym<Element> Use(TMatrixTSym<double>& a)

{ return Use(a.GetRowLwb(),a.GetRowUpb(),a.GetMatrixArray()); }

template <class Element> inline const TMatrixTSym<Element> &TMatrixTSym<Element> Use(const TMatrixTSym<double>& a) const

{ return Use(a.GetRowLwb(),a.GetRowUpb(),a.GetMatrixArray()); }

template <class Element> inline TMatrixTSym<Element> TMatrixTSym<Element> GetSub(Int_t row_lwb, Int_t row_upb, Int_t col_lwb, Int_t col_upb, Option_t* option = "S") const

template <class Element> inline Element TMatrixTSym<Element> operator()(Int_t rown, Int_t coln) const

template <class Element> inline Element &TMatrixTSym<Element> operator()(Int_t rown, Int_t coln)

void Mult(const TMatrixTSym<double>& a)

{ TMult(a); }

const Int_t * GetRowIndexArray() const

{ return 0; }

Int_t * GetRowIndexArray()

{ return 0; }

const Int_t * GetColIndexArray() const

{ return 0; }

Int_t * GetColIndexArray()

{ return 0; }

TMatrixTBase<Element> & SetRowIndexArray(Int_t* )

{ MayNotUse("SetRowIndexArray(Int_t *)"); return *this; }

TMatrixTBase<Element> & SetColIndexArray(Int_t* )

{ MayNotUse("SetColIndexArray(Int_t *)"); return *this; }

void Clear(Option_t* = "")

Bool_t IsSymmetric() const

{ return kTRUE; }

TMatrixTSym <Element> & Use(Int_t row_lwb, Int_t row_upb, double* data)

TMatrixTBase<Element> & ResizeTo(Int_t nrows, Int_t ncols, Int_t = -1)

const TMatrixTRow_const<Element> operator[](Int_t rown) const

 or as a[i][j]

{ return TMatrixTRow_const<Element>(*this,rown); }

TMatrixTRow <Element> operator[](Int_t rown)

{ return TMatrixTRow <Element>(*this,rown); }