doc/v616/TVectorT_8h_source.html

// @(#)root/matrix:$Id$

// Authors: Fons Rademakers, Eddy Offermann   Nov 2003


/*************************************************************************

 * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers.               *

 * All rights reserved.                                                  *

 *                                                                       *

 * For the licensing terms see $ROOTSYS/LICENSE.                         *

 * For the list of contributors see $ROOTSYS/README/CREDITS.             *

 *************************************************************************/


#ifndef ROOT_TVectorT

#define ROOT_TVectorT


//////////////////////////////////////////////////////////////////////////

//                                                                      //

// TVectorT                                                             //

//                                                                      //

// Template class of Vectors in the linear algebra package              //

//                                                                      //

//////////////////////////////////////////////////////////////////////////


#include "TMatrixT.h"

#include "TMatrixTSym.h"

#include "TMatrixTSparse.h"


template<class Element> class TVectorT : public TObject {


protected:

   Int_t    fNrows{0};                // number of rows

   Int_t    fRowLwb{0};               // lower bound of the row index

   Element *fElements{nullptr};             //[fNrows] elements themselves


   enum {kSizeMax = 5};             // size data container on stack, see New_m(),Delete_m()

   enum {kWorkMax = 100};           // size of work array's in several routines


   Element  fDataStack[kSizeMax];  //! data container

   Bool_t   fIsOwner{kTRUE};              //!default kTRUE, when Use array kFALSE


   Element* New_m   (Int_t size);

   void     Delete_m(Int_t size,Element*&);

   Int_t    Memcpy_m(Element *newp,const Element *oldp,Int_t copySize,

                     Int_t newSize,Int_t oldSize);


   void     Allocate(Int_t nrows,Int_t row_lwb = 0,Int_t init = 0);


   enum EVectorStatusBits {

     kStatus = BIT(14) // set if vector object is valid

   };


public:


   TVectorT() : fNrows(0), fRowLwb(0), fElements(0), fDataStack (), fIsOwner(kTRUE) { }

   explicit TVectorT(Int_t n);

   TVectorT(Int_t lwb,Int_t upb);

   TVectorT(Int_t n,const Element *elements);

   TVectorT(Int_t lwb,Int_t upb,const Element *elements);

   TVectorT(const TVectorT            <Element> &another);

   TVectorT(const TMatrixTRow_const   <Element> &mr);

   TVectorT(const TMatrixTColumn_const<Element> &mc);

   TVectorT(const TMatrixTDiag_const  <Element> &md);

   template <class Element2> TVectorT(const TVectorT<Element2> &another)

   {

      R__ASSERT(another.IsValid());

      Allocate(another.GetUpb()-another.GetLwb()+1,another.GetLwb());

      *this = another;

   }

#ifndef __CINT__

   TVectorT(Int_t lwb,Int_t upb,Double_t iv1, ...);

#endif

   virtual ~TVectorT() { Clear(); }


   inline          Int_t     GetLwb       () const { return fRowLwb; }

   inline          Int_t     GetUpb       () const { return fNrows+fRowLwb-1; }

   inline          Int_t     GetNrows     () const { return fNrows; }

   inline          Int_t     GetNoElements() const { return fNrows; }


   inline          Element  *GetMatrixArray  ()       { return fElements; }

   inline const    Element  *GetMatrixArray  () const { return fElements; }


   inline void     Invalidate ()       { SetBit(kStatus); }

   inline void     MakeValid  ()       { ResetBit(kStatus); }

   inline Bool_t   IsValid    () const { return !TestBit(kStatus); }

   inline Bool_t   IsOwner    () const { return fIsOwner; }

   inline void     SetElements(const Element *elements) { R__ASSERT(IsValid());

                                                          memcpy(fElements,elements,fNrows*sizeof(Element)); }

   inline TVectorT<Element> &Shift     (Int_t row_shift)            { fRowLwb += row_shift; return *this; }

          TVectorT<Element> &ResizeTo  (Int_t lwb,Int_t upb);

   inline TVectorT<Element> &ResizeTo  (Int_t n)                    { return ResizeTo(0,n-1); }

   inline TVectorT<Element> &ResizeTo  (const TVectorT<Element> &v) { return ResizeTo(v.GetLwb(),v.GetUpb()); }


          TVectorT<Element> &Use       (Int_t lwb,Int_t upb,Element *data);

   const  TVectorT<Element> &Use       (Int_t lwb,Int_t upb,const Element *data) const

          { return (const TVectorT<Element>&)(const_cast<TVectorT<Element> *>(this))->Use(lwb,upb,const_cast<Element *>(data)); }

          TVectorT<Element> &Use       (Int_t n,Element *data);

   const  TVectorT<Element> &Use       (Int_t n,const Element *data) const ;

          TVectorT<Element> &Use       (TVectorT<Element> &v);

   const  TVectorT<Element> &Use       (const TVectorT<Element> &v) const ;


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

          TVectorT<Element>  GetSub    (Int_t row_lwb,Int_t row_upb,Option_t *option="S") const;

          TVectorT<Element> &SetSub    (Int_t row_lwb,const TVectorT<Element> &source);


   TVectorT<Element> &Zero();

   TVectorT<Element> &Abs ();

   TVectorT<Element> &Sqr ();

   TVectorT<Element> &Sqrt();

   TVectorT<Element> &Invert();

   TVectorT<Element> &SelectNonZeros(const TVectorT<Element> &select);


   Element Norm1   () const;

   Element Norm2Sqr() const;

   Element NormInf () const;

   Int_t   NonZeros() const;

   Element Sum     () const;

   Element Min     () const;

   Element Max     () const;


   inline const Element &operator()(Int_t index) const;

   inline       Element &operator()(Int_t index);

   inline const Element &operator[](Int_t index) const { return (*this)(index); }

   inline       Element &operator[](Int_t index)       { return (*this)(index); }


   TVectorT<Element> &operator= (const TVectorT                <Element> &source);

   TVectorT<Element> &operator= (const TMatrixTRow_const       <Element> &mr);

   TVectorT<Element> &operator= (const TMatrixTColumn_const    <Element> &mc);

   TVectorT<Element> &operator= (const TMatrixTDiag_const      <Element> &md);

   TVectorT<Element> &operator= (const TMatrixTSparseRow_const <Element> &md);

   TVectorT<Element> &operator= (const TMatrixTSparseDiag_const<Element> &md);

   template <class Element2> TVectorT<Element> &operator= (const TVectorT<Element2> &source)

   {

      if (!AreCompatible(*this,source)) {

         Error("operator=(const TVectorT2 &)","vectors not compatible");

         return *this;

      }


     TObject::operator=(source);

     const Element2 * const ps = source.GetMatrixArray();

           Element  * const pt = GetMatrixArray();

     for (Int_t i = 0; i < this->fNrows; i++)

        pt[i] = ps[i];

     return *this;

   }


   TVectorT<Element> &operator= (Element val);

   TVectorT<Element> &operator+=(Element val);

   TVectorT<Element> &operator-=(Element val);

   TVectorT<Element> &operator*=(Element val);


   TVectorT<Element> &operator+=(const TVectorT      <Element> &source);

   TVectorT<Element> &operator-=(const TVectorT      <Element> &source);

   TVectorT<Element> &operator*=(const TMatrixT      <Element> &a);

   TVectorT<Element> &operator*=(const TMatrixTSym   <Element> &a);

   TVectorT<Element> &operator*=(const TMatrixTSparse<Element> &a);


   Bool_t operator==(Element val) const;

   Bool_t operator!=(Element val) const;

   Bool_t operator< (Element val) const;

   Bool_t operator<=(Element val) const;

   Bool_t operator> (Element val) const;

   Bool_t operator>=(Element val) const;


   Bool_t MatchesNonZeroPattern(const TVectorT<Element> &select);

   Bool_t SomePositive         (const TVectorT<Element> &select);

   void   AddSomeConstant      (Element val,const TVectorT<Element> &select);


   void   Randomize            (Element alpha,Element beta,Double_t &seed);


   TVectorT<Element> &Apply(const TElementActionT   <Element> &action);

   TVectorT<Element> &Apply(const TElementPosActionT<Element> &action);


   void Add(const TVectorT<Element> &v);

   void Add(const TVectorT<Element> &v1, const TVectorT<Element> &v2);

   void Clear(Option_t * /*option*/ ="") { if (fIsOwner) Delete_m(fNrows,fElements);

                                           else fElements = 0;

                                           fNrows = 0; }

   void Draw (Option_t *option=""); // *MENU*

   void Print(Option_t *option="") const;  // *MENU*


   ClassDef(TVectorT,4)  // Template of Vector class

};


#ifndef __CINT__

// When building with -fmodules, it instantiates all pending instantiations,

// instead of delaying them until the end of the translation unit.

// We 'got away with' probably because the use and the definition of the

// explicit specialization do not occur in the same TU.

//

// In case we are building with -fmodules, we need to forward declare the

// specialization in order to compile the dictionary G__Matrix.cxx.

template <> TClass *TVectorT<double>::Class();

#endif // __CINT__


template<class Element> inline       TVectorT<Element> &TVectorT<Element>::Use     (Int_t n,Element *data) { return Use(0,n-1,data); }

template<class Element> inline const TVectorT<Element> &TVectorT<Element>::Use     (Int_t n,const Element *data) const { return Use(0,n-1,data); }

template<class Element> inline       TVectorT<Element> &TVectorT<Element>::Use     (TVectorT &v)

                                                                                   {

                                                                                     R__ASSERT(v.IsValid());

                                                                                     return Use(v.GetLwb(),v.GetUpb(),v.GetMatrixArray());

                                                                                   }

template<class Element> inline const TVectorT<Element> &TVectorT<Element>::Use     (const TVectorT &v) const

                                                                                   {

                                                                                     R__ASSERT(v.IsValid());

                                                                                     return Use(v.GetLwb(),v.GetUpb(),v.GetMatrixArray());

                                                                                   }

template<class Element> inline       TVectorT<Element>  TVectorT<Element>::GetSub  (Int_t row_lwb,Int_t row_upb,Option_t *option) const

                                                                                   {

                                                                                     TVectorT tmp;

                                                                                     this->GetSub(row_lwb,row_upb,tmp,option);

                                                                                     return tmp;

                                                                                   }


template<class Element> inline const Element &TVectorT<Element>::operator()(Int_t ind) const

{

   // Access a vector element.


   R__ASSERT(IsValid());

   const Int_t aind = ind-fRowLwb;

   if (aind >= fNrows || aind < 0) {

      Error("operator()","Request index(%d) outside vector range of %d - %d",ind,fRowLwb,fRowLwb+fNrows);

      return TMatrixTBase<Element>::NaNValue();

   }


   return fElements[aind];

}

template<class Element> inline Element &TVectorT<Element>::operator()(Int_t ind)

{

   // Access a vector element.


   R__ASSERT(IsValid());

   const Int_t aind = ind-fRowLwb;

   if (aind >= fNrows || aind < 0) {

      Error("operator()","Request index(%d) outside vector range of %d - %d",ind,fRowLwb,fRowLwb+fNrows);

      return TMatrixTBase<Element>::NaNValue();

   }


   return fElements[aind];

}


template<class Element> Bool_t              operator==  (const TVectorT      <Element>  &source1,const TVectorT <Element>  &source2);

template<class Element> TVectorT<Element>   operator+   (const TVectorT      <Element>  &source1,const TVectorT <Element>  &source2);

template<class Element> TVectorT<Element>   operator-   (const TVectorT      <Element>  &source1,const TVectorT <Element>  &source2);

template<class Element> Element             operator*   (const TVectorT      <Element>  &source1,const TVectorT <Element>  &source2);

template<class Element> TVectorT<Element>   operator*   (const TMatrixT      <Element>  &a,      const TVectorT <Element>  &source);

template<class Element> TVectorT<Element>   operator*   (const TMatrixTSym   <Element>  &a,      const TVectorT <Element>  &source);

template<class Element> TVectorT<Element>   operator*   (const TMatrixTSparse<Element>  &a,      const TVectorT <Element>  &source);

template<class Element> TVectorT<Element>   operator*   (      Element                   val,    const TVectorT <Element>  &source);

template<class Element>

inline

TVectorT<Element> operator*   (const TVectorT <Element>  &source, Element val) { return val * source; }


template<class Element> Element             Dot         (const TVectorT      <Element>  &source1,const TVectorT <Element>  &source2);

template <class Element1,class Element2>

                        TMatrixT<Element1>  OuterProduct(const TVectorT      <Element1> &v1,     const TVectorT <Element2> &v2);

template <class Element1,class Element2,class Element3>

                        TMatrixT<Element1> &OuterProduct(      TMatrixT      <Element1> &target, const TVectorT <Element2> &v1,     const TVectorT      <Element3> &v2);

template <class Element1,class Element2,class Element3>

                        Element1            Mult        (const TVectorT      <Element1> &v1,     const TMatrixT <Element2> &m,      const TVectorT      <Element3> &v2);


template<class Element> TVectorT<Element>  &Add         (      TVectorT      <Element>  &target,       Element              scalar, const TVectorT      <Element>  &source);

template<class Element> TVectorT<Element>  &Add         (      TVectorT      <Element>  &target,       Element              scalar, const TMatrixT      <Element>  &a,

                                                         const TVectorT<Element> &source);

template<class Element> TVectorT<Element>  &Add         (      TVectorT      <Element>  &target,       Element              scalar, const TMatrixTSym   <Element>  &a,

                                                         const TVectorT<Element> &source);

template<class Element> TVectorT<Element>  &Add         (      TVectorT      <Element>  &target,       Element              scalar, const TMatrixTSparse<Element>  &a,

                                                         const TVectorT<Element> &source);

template<class Element> TVectorT<Element>  &AddElemMult (      TVectorT      <Element>  &target,       Element              scalar, const TVectorT      <Element>  &source1,

                                                         const TVectorT      <Element>  &source2);

template<class Element> TVectorT<Element>  &AddElemMult (      TVectorT      <Element>  &target,       Element              scalar, const TVectorT      <Element>  &source1,

                                                         const TVectorT      <Element>  &source2,const TVectorT <Element>  &select);

template<class Element> TVectorT<Element>  &AddElemDiv  (      TVectorT      <Element>  &target,       Element              scalar, const TVectorT      <Element>  &source1,

                                                         const TVectorT      <Element>  &source2);

template<class Element> TVectorT<Element>  &AddElemDiv  (      TVectorT      <Element>  &target,       Element              scalar, const TVectorT      <Element>  &source1,

                                                         const TVectorT      <Element>  &source2,const TVectorT <Element>  &select);

template<class Element> TVectorT<Element>  &ElementMult (      TVectorT      <Element>  &target, const TVectorT <Element>  &source);

template<class Element> TVectorT<Element>  &ElementMult (      TVectorT      <Element>  &target, const TVectorT <Element>  &source, const TVectorT      <Element>  &select);

template<class Element> TVectorT<Element>  &ElementDiv  (      TVectorT      <Element>  &target, const TVectorT <Element>  &source);

template<class Element> TVectorT<Element>  &ElementDiv  (      TVectorT      <Element>  &target, const TVectorT <Element>  &source, const TVectorT      <Element>  &select);


template<class Element1,class Element2> Bool_t AreCompatible(const TVectorT<Element1> &v1,const TVectorT<Element2> &v2,Int_t verbose=0);

// Check matrix and vector for compatibility in multiply:  M * v and v * M

template<class Element1,class Element2> Bool_t AreCompatible(const TMatrixT<Element1> &m, const TVectorT<Element2> &v, Int_t verbose=0);

template<class Element1,class Element2> Bool_t AreCompatible(const TVectorT<Element1> &v, const TMatrixT<Element2> &m, Int_t verbose=0);


template<class Element> void   Compare              (const TVectorT <Element>  &source1,const TVectorT <Element>  &source2);

template<class Element> Bool_t VerifyVectorValue    (const TVectorT <Element>  &m,            Element val,Int_t verbose, Element maxDevAllow);

template<class Element> Bool_t VerifyVectorValue    (const TVectorT <Element>  &m,            Element val,Int_t verbose)

                                                     { return VerifyVectorValue(m,val,verbose,Element(0.0)); }

template<class Element> Bool_t VerifyVectorValue    (const TVectorT <Element>  &m,            Element val)

                                                     { return VerifyVectorValue(m,val,1,Element(0.0)); }

template<class Element> Bool_t VerifyVectorIdentity (const TVectorT <Element>  &m1,const TVectorT <Element> &m2, Int_t verbose, Element maxDevAllow);

template<class Element> Bool_t VerifyVectorIdentity (const TVectorT <Element>  &m1,const TVectorT <Element> &m2, Int_t verbose)

                                                     { return VerifyVectorIdentity(m1,m2,verbose,Element(0.0)); }

template<class Element> Bool_t VerifyVectorIdentity (const TVectorT <Element>  &m1,const TVectorT <Element> &m2)

                                                     { return VerifyVectorIdentity(m1,m2,1,Element(0.0)); }


#endif

v
SVector< double, 2 > v
Definition: Dict.h:5

init
static Int_t init()
Definition: RooClassFactory.cxx:52

Int_t
int Int_t
Definition: RtypesCore.h:41

Bool_t
bool Bool_t
Definition: RtypesCore.h:59

Double_t
double Double_t
Definition: RtypesCore.h:55

kTRUE
const Bool_t kTRUE
Definition: RtypesCore.h:87

Option_t
const char Option_t
Definition: RtypesCore.h:62

ClassDef
#define ClassDef(name, id)
Definition: Rtypes.h:324

BIT
#define BIT(n)
Definition: Rtypes.h:82

R__ASSERT
#define R__ASSERT(e)
Definition: TError.h:96

Error
void Error(const char *location, const char *msgfmt,...)

TMatrixTSparse.h

TMatrixTSym.h

TMatrixT.h

ElementDiv
TVectorT< Element > & ElementDiv(TVectorT< Element > &target, const TVectorT< Element > &source)
Divide target by the source, element-by-element.
Definition: TVectorT.cxx:2073

VerifyVectorValue
Bool_t VerifyVectorValue(const TVectorT< Element > &m, Element val, Int_t verbose, Element maxDevAllow)
Validate that all elements of vector have value val within maxDevAllow .
Definition: TVectorT.cxx:2260

VerifyVectorIdentity
Bool_t VerifyVectorIdentity(const TVectorT< Element > &m1, const TVectorT< Element > &m2, Int_t verbose, Element maxDevAllow)
Verify that elements of the two vectors are equal within maxDevAllow .
Definition: TVectorT.cxx:2295

Dot
Element Dot(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
return inner-produvt v1 . v2
Definition: TVectorT.cxx:1476

operator+
TVectorT< Element > operator+(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Return source1+source2.
Definition: TVectorT.cxx:1410

Add
TVectorT< Element > & Add(TVectorT< Element > &target, Element scalar, const TVectorT< Element > &source)
Modify addition: target += scalar * source.
Definition: TVectorT.cxx:1585

operator==
Bool_t operator==(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Check to see if two vectors are identical.
Definition: TVectorT.cxx:1384

AddElemDiv
TVectorT< Element > & AddElemDiv(TVectorT< Element > &target, Element scalar, const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Modify addition: target += scalar * ElementDiv(source1,source2) .
Definition: TVectorT.cxx:1915

AddElemMult
TVectorT< Element > & AddElemMult(TVectorT< Element > &target, Element scalar, const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Modify addition: target += scalar * ElementMult(source1,source2) .
Definition: TVectorT.cxx:1842

operator*
Element operator*(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Compute the scalar product.
Definition: TVectorT.cxx:1394

operator-
TVectorT< Element > operator-(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Return source1-source2.
Definition: TVectorT.cxx:1421

ElementMult
TVectorT< Element > & ElementMult(TVectorT< Element > &target, const TVectorT< Element > &source)
Multiply target by the source, element-by-element.
Definition: TVectorT.cxx:2030

OuterProduct
TMatrixT< Element1 > OuterProduct(const TVectorT< Element1 > &v1, const TVectorT< Element2 > &v2)
Return the matrix M = v1 * v2'.
Definition: TVectorT.cxx:1493

Mult
Element1 Mult(const TVectorT< Element1 > &v1, const TMatrixT< Element2 > &m, const TVectorT< Element3 > &v2)
Perform v1 * M * v2, a scalar result.
Definition: TVectorT.cxx:1540

Compare
void Compare(const TVectorT< Element > &source1, const TVectorT< Element > &source2)
Compare two vectors and print out the result of the comparison.
Definition: TVectorT.cxx:2207

AreCompatible
Bool_t AreCompatible(const TVectorT< Element1 > &v1, const TVectorT< Element2 > &v2, Int_t verbose=0)
Check if v1 and v2 are both valid and have the same shape.
Definition: TVectorT.cxx:2129

TClass
The ROOT global object gROOT contains a list of all defined classes.
Definition: TClass.h:75

TElementActionT
Definition: TMatrixTUtils.h:56

TElementPosActionT
Definition: TMatrixTUtils.h:86

TMatrixTBase::NaNValue
static Element & NaNValue()
Definition: TMatrixTBase.cxx:1282

TMatrixTColumn_const
Definition: TMatrixTUtils.h:214

TMatrixTDiag_const
Definition: TMatrixTUtils.h:316

TMatrixTRow_const
Definition: TMatrixTUtils.h:114

TMatrixTSparseDiag_const
Definition: TMatrixTUtils.h:651

TMatrixTSparseRow_const
Definition: TMatrixTUtils.h:585

TMatrixTSparse
TMatrixTSparse.
Definition: TMatrixTSparse.h:35

TMatrixTSym
TMatrixTSym.
Definition: TMatrixTSym.h:34

TMatrixT
TMatrixT.
Definition: TMatrixT.h:39

TObject
Mother of all ROOT objects.
Definition: TObject.h:37

TObject::operator=
TObject & operator=(const TObject &rhs)
TObject assignment operator.
Definition: TObject.h:271

TObject::TestBit
R__ALWAYS_INLINE Bool_t TestBit(UInt_t f) const
Definition: TObject.h:172

TObject::SetBit
void SetBit(UInt_t f, Bool_t set)
Set or unset the user status bits as specified in f.
Definition: TObject.cxx:694

TObject::Error
virtual void Error(const char *method, const char *msgfmt,...) const
Issue error message.
Definition: TObject.cxx:880

TObject::ResetBit
void ResetBit(UInt_t f)
Definition: TObject.h:171

TVectorT
TVectorT.
Definition: TVectorT.h:27

TVectorT::Zero
TVectorT< Element > & Zero()
Set vector elements to zero.
Definition: TVectorT.cxx:451

TVectorT::operator>=
Bool_t operator>=(Element val) const
Are all vector elements >= val?
Definition: TVectorT.cxx:1219

TVectorT::New_m
Element * New_m(Int_t size)
default kTRUE, when Use array kFALSE
Definition: TVectorT.cxx:65

TVectorT::MakeValid
void MakeValid()
Definition: TVectorT.h:82

TVectorT::Apply
TVectorT< Element > & Apply(const TElementActionT< Element > &action)
Apply action to each element of the vector.
Definition: TVectorT.cxx:1320

TVectorT::SetElements
void SetElements(const Element *elements)
Definition: TVectorT.h:85

TVectorT::Allocate
void Allocate(Int_t nrows, Int_t row_lwb=0, Int_t init=0)
Allocate new vector.
Definition: TVectorT.cxx:149

TVectorT::Sqr
TVectorT< Element > & Sqr()
Square each element of the vector.
Definition: TVectorT.cxx:480

TVectorT::operator[]
Element & operator[](Int_t index)
Definition: TVectorT.h:122

TVectorT::fNrows
Int_t fNrows
Definition: TVectorT.h:30

TVectorT::Min
Element Min() const
return minimum vector element value
Definition: TVectorT.cxx:652

TVectorT::Memcpy_m
Int_t Memcpy_m(Element *newp, const Element *oldp, Int_t copySize, Int_t newSize, Int_t oldSize)
Copy copySize doubles from *oldp to *newp .
Definition: TVectorT.cxx:122

TVectorT::Clear
void Clear(Option_t *="")
Definition: TVectorT.h:174

TVectorT::operator()
Element & operator()(Int_t index)
Definition: TVectorT.h:226

TVectorT::Use
TVectorT< Element > & Use(TVectorT< Element > &v)
Definition: TVectorT.h:196

TVectorT::Norm1
Element Norm1() const
Compute the 1-norm of the vector SUM{ |v[i]| }.
Definition: TVectorT.cxx:565

TVectorT::Delete_m
void Delete_m(Int_t size, Element *&)
Delete data pointer m, if it was assigned on the heap.
Definition: TVectorT.cxx:51

TVectorT::TVectorT
TVectorT(const TVectorT< Element2 > &another)
Definition: TVectorT.h:62

TVectorT::NormInf
Element NormInf() const
Compute the infinity-norm of the vector MAX{ |v[i]| }.
Definition: TVectorT.cxx:601

TVectorT::Sum
Element Sum() const
Compute sum of elements.
Definition: TVectorT.cxx:635

TVectorT::AddSomeConstant
void AddSomeConstant(Element val, const TVectorT< Element > &select)
Add to vector elements as selected through array select the value val.
Definition: TVectorT.cxx:1282

TVectorT::operator!=
Bool_t operator!=(Element val) const
Are all vector elements not equal to val?
Definition: TVectorT.cxx:1151

TVectorT::Invalidate
void Invalidate()
Definition: TVectorT.h:81

TVectorT::fRowLwb
Int_t fRowLwb
Definition: TVectorT.h:31

TVectorT::IsOwner
Bool_t IsOwner() const
Definition: TVectorT.h:84

TVectorT::MatchesNonZeroPattern
Bool_t MatchesNonZeroPattern(const TVectorT< Element > &select)
Check if vector elements as selected through array select are non-zero.
Definition: TVectorT.cxx:1236

TVectorT::GetSub
TVectorT< Element > & GetSub(Int_t row_lwb, Int_t row_upb, TVectorT< Element > &target, Option_t *option="S") const
Get subvector [row_lwb..row_upb]; The indexing range of the returned vector depends on the argument o...
Definition: TVectorT.cxx:371

TVectorT::Shift
TVectorT< Element > & Shift(Int_t row_shift)
Definition: TVectorT.h:87

TVectorT::Abs
TVectorT< Element > & Abs()
Take an absolute value of a vector, i.e. apply Abs() to each element.
Definition: TVectorT.cxx:462

TVectorT::operator==
Bool_t operator==(Element val) const
Are all vector elements equal to val?
Definition: TVectorT.cxx:1134

TVectorT::operator>
Bool_t operator>(Element val) const
Are all vector elements > val?
Definition: TVectorT.cxx:1202

TVectorT::ResizeTo
TVectorT< Element > & ResizeTo(Int_t n)
Definition: TVectorT.h:89

TVectorT::ResizeTo
TVectorT< Element > & ResizeTo(Int_t lwb, Int_t upb)
Resize the vector to [lwb:upb] .
Definition: TVectorT.cxx:292

TVectorT::Draw
void Draw(Option_t *option="")
Draw this vector The histogram is named "TVectorT" by default and no title.
Definition: TVectorT.cxx:1351

TVectorT::operator=
TVectorT< Element > & operator=(const TVectorT< Element > &source)
Notice that this assignment does NOT change the ownership : if the storage space was adopted,...
Definition: TVectorT.cxx:678

TVectorT::GetNrows
Int_t GetNrows() const
Definition: TVectorT.h:75

TVectorT::GetUpb
Int_t GetUpb() const
Definition: TVectorT.h:74

TVectorT::SetSub
TVectorT< Element > & SetSub(Int_t row_lwb, const TVectorT< Element > &source)
Insert vector source starting at [row_lwb], thereby overwriting the part [row_lwb....
Definition: TVectorT.cxx:420

TVectorT::Class
TClass * Class()

TVectorT::Randomize
void Randomize(Element alpha, Element beta, Double_t &seed)
randomize vector elements value
Definition: TVectorT.cxx:1303

TVectorT::Use
TVectorT< Element > & Use(Int_t n, Element *data)
Definition: TVectorT.h:194

TVectorT::IsValid
Bool_t IsValid() const
Definition: TVectorT.h:83

TVectorT::Add
void Add(const TVectorT< Element > &v)
Add vector v to this vector.
Definition: TVectorT.cxx:82

TVectorT::operator()
const Element & operator()(Int_t index) const
Definition: TVectorT.h:213

TVectorT::operator+=
TVectorT< Element > & operator+=(Element val)
Add val to every element of the vector.
Definition: TVectorT.cxx:861

TVectorT::Use
TVectorT< Element > & Use(Int_t lwb, Int_t upb, Element *data)
Use the array data to fill the vector lwb..upb].
Definition: TVectorT.cxx:347

TVectorT::Use
const TVectorT< Element > & Use(Int_t lwb, Int_t upb, const Element *data) const
Definition: TVectorT.h:93

TVectorT::SelectNonZeros
TVectorT< Element > & SelectNonZeros(const TVectorT< Element > &select)
Keep only element as selected through array select non-zero.
Definition: TVectorT.cxx:542

TVectorT::kWorkMax
@ kWorkMax
Definition: TVectorT.h:35

TVectorT::Max
Element Max() const
return maximum vector element value
Definition: TVectorT.cxx:664

TVectorT::operator<
Bool_t operator<(Element val) const
Are all vector elements < val?
Definition: TVectorT.cxx:1168

TVectorT::operator<=
Bool_t operator<=(Element val) const
Are all vector elements <= val?
Definition: TVectorT.cxx:1185

TVectorT::operator*=
TVectorT< Element > & operator*=(Element val)
Multiply every element of the vector with val.
Definition: TVectorT.cxx:893

TVectorT::Print
void Print(Option_t *option="") const
Print the vector as a list of elements.
Definition: TVectorT.cxx:1361

TVectorT::Use
const TVectorT< Element > & Use(const TVectorT< Element > &v) const
Definition: TVectorT.h:201

TVectorT::SomePositive
Bool_t SomePositive(const TVectorT< Element > &select)
Check if vector elements as selected through array select are all positive.
Definition: TVectorT.cxx:1259

TVectorT::fElements
Element * fElements
Definition: TVectorT.h:32

TVectorT::operator[]
const Element & operator[](Int_t index) const
Definition: TVectorT.h:121

TVectorT::NonZeros
Int_t NonZeros() const
Compute the number of elements != 0.0.
Definition: TVectorT.cxx:618

TVectorT::fIsOwner
Bool_t fIsOwner
data container
Definition: TVectorT.h:38

TVectorT::ResizeTo
TVectorT< Element > & ResizeTo(const TVectorT< Element > &v)
Definition: TVectorT.h:90

TVectorT::GetLwb
Int_t GetLwb() const
Definition: TVectorT.h:73

TVectorT::EVectorStatusBits
EVectorStatusBits
Definition: TVectorT.h:47

TVectorT::kStatus
@ kStatus
Definition: TVectorT.h:48

TVectorT::Use
const TVectorT< Element > & Use(Int_t n, const Element *data) const
Definition: TVectorT.h:195

TVectorT::Invert
TVectorT< Element > & Invert()
v[i] = 1/v[i]
Definition: TVectorT.cxx:520

TVectorT::TVectorT
TVectorT()
Definition: TVectorT.h:53

TVectorT::GetNoElements
Int_t GetNoElements() const
Definition: TVectorT.h:76

TVectorT::kSizeMax
@ kSizeMax
Definition: TVectorT.h:34

TVectorT::Norm2Sqr
Element Norm2Sqr() const
Compute the square of the 2-norm SUM{ v[i]^2 }.
Definition: TVectorT.cxx:582

TVectorT::GetMatrixArray
Element * GetMatrixArray()
Definition: TVectorT.h:78

TVectorT::~TVectorT
virtual ~TVectorT()
Definition: TVectorT.h:71

TVectorT::GetMatrixArray
const Element * GetMatrixArray() const
Definition: TVectorT.h:79

TVectorT::operator-=
TVectorT< Element > & operator-=(Element val)
Subtract val from every element of the vector.
Definition: TVectorT.cxx:877

TVectorT::fDataStack
Element fDataStack[kSizeMax]
Definition: TVectorT.h:37

TVectorT::GetSub
TVectorT< Element > GetSub(Int_t row_lwb, Int_t row_upb, Option_t *option="S") const
Definition: TVectorT.h:206

TVectorT::Sqrt
TVectorT< Element > & Sqrt()
Take square root of all elements.
Definition: TVectorT.cxx:498

pt
TPaveText * pt
Definition: entrylist_figure1.C:7

ROOT::Math::beta
double beta(double x, double y)
Calculates the beta function.
Definition: SpecFuncMathCore.cxx:111

n
const Int_t n
Definition: legend1.C:16

ApplicationClassificationKeras.data
data
Definition: ApplicationClassificationKeras.py:17

TGeoUnit::ps
static constexpr double ps
Definition: TGeoSystemOfUnits.h:165

TGeoUnit::m2
static constexpr double m2
Definition: TGeoSystemOfUnits.h:123

m
auto * m
Definition: textangle.C:8

a
auto * a
Definition: textangle.C:12