source: Sophya/trunk/SophyaLib/TArray/tmatrix.h@ 1099

Last change on this file since 1099 was 1099, checked in by ansari, 25 years ago

Protection integrite TMatrix,TVector - operateur = (BaseArray & pour TVector et operations entre matrices avec <> MemMapping (Pas termine) Reza 27/6/2000
File size: 6.8 KB
RevLine 
[762]1// This may look like C code, but it is really -*- C++ -*-
2// C.Magneville 04/99
3#ifndef TMatrix_SEEN
4#define TMatrix_SEEN
5
6#include "machdefs.h"
[804]7#include "tarray.h"
[762]8
9namespace SOPHYA {
10
[926]11//! Class of matrices
[762]12template <class T>
[804]13class TMatrix : public TArray<T> {
[762]14public:
15 // Creation / destruction
16 TMatrix();
[1003]17 TMatrix(uint_4 r,uint_4 c, short mm=BaseArray::AutoMemoryMapping);
[762]18 TMatrix(const TMatrix<T>& a);
[804]19 TMatrix(const TMatrix<T>& a, bool share);
20 TMatrix(const TArray<T>& a);
[1013]21 TMatrix(const TArray<T>& a, bool share, short mm=BaseArray::AutoMemoryMapping);
[1081]22 TMatrix(const BaseArray& a);
[1003]23
[762]24 virtual ~TMatrix();
25
[804]26 // Pour verifiez la compatibilite de dimensions lors de l'affectation
27 virtual TArray<T>& Set(const TArray<T>& a);
[894]28 //! Operator = between matrices
[976]29 /*! \warning Datas are copied (cloned) from \b a.
30 \sa NDataBlock::operator=(const NDataBlock<T>&) */
[804]31 inline TMatrix<T>& operator = (const TMatrix<T>& a)
[894]32 { Set(a); return(*this); }
[1099]33 //! Operator = between a matrix and an array
34 inline TMatrix<T>& operator = (const TArray<T>& a)
35 { Set(a); return(*this); }
[762]36
[1081]37 virtual TArray<T>& SetBA(const BaseArray& a);
[1099]38 //! Operator = between matrices with different types
[1081]39 inline TMatrix<T>& operator = (const BaseArray& a)
40 { SetBA(a); return(*this); }
41
[804]42 // Size - Changing the Size
[894]43 //! return number of rows
[804]44 inline uint_4 NRows() const {return Size(marowi_); }
[894]45 //! return number of columns
[804]46 inline uint_4 NCols() const {return Size(macoli_); }
[894]47 //! return number of columns
[804]48 inline uint_4 NCol() const {return Size(macoli_); } // back-compat Peida
[762]49
[1003]50 void ReSize(uint_4 r,uint_4 c, short mm=BaseArray::SameMemoryMapping); // Reallocation de place
51 void Realloc(uint_4 r,uint_4 c, short mm=BaseArray::SameMemoryMapping, bool force=false);
[762]52
[813]53 // Sub-matrix extraction $CHECK$ Reza 03/2000 Doit-on declarer ces methode const ?
54 TMatrix<T> SubMatrix(Range rline, Range rcol) const ;
[894]55 //! () : Return submatrix define by \b Range \b rline and \b rcol
[813]56 inline TMatrix<T> operator () (Range rline, Range rcol) const
57 { return SubMatrix(rline, rcol); }
58 // Lignes et colonnes de la matrice
[894]59 //! Return submatrix define by line \b ir (line vector)
[813]60 inline TMatrix<T> Row(uint_4 ir) const
61 { return SubMatrix(Range(ir,ir), Range(0,NCols()-1)); }
[894]62 //! Return submatrix define by column \b ic (column vector)
[813]63 inline TMatrix<T> Column(uint_4 ic) const
64 { return SubMatrix(Range(0,NRows()-1), Range(ic,ic)); }
[804]65
66 // Inline element acces methods
67 inline T const& operator()(uint_4 r,uint_4 c) const;
68 inline T& operator()(uint_4 r,uint_4 c);
69
[762]70 // Operations matricielles
[804]71 TMatrix<T>& Transpose();
72 //mm = SameMemoryMapping or CMemoryMapping or FortranMemoryMapping
73 TMatrix<T> Transpose(short mm);
74 // Rearranging Matrix Elements
75 TMatrix<T> Rearrange(short mm);
[762]76
77 // Operateur d'affectation
[804]78 // A = x (matrice diagonale Identite)
79 virtual TMatrix<T>& SetIdentity(IdentityMatrix imx);
[894]80 // = : fill matrix with an identity matrix \b imx
[804]81 inline TMatrix<T>& operator = (IdentityMatrix imx) { return SetIdentity(imx); }
[762]82
[894]83 // = : fill matrix with a Sequence \b seq
[813]84 inline TMatrix<T>& operator = (Sequence seq) { SetSeq(seq); return(*this); }
85
[804]86 // Operations diverses avec une constante
[894]87 //! = : fill matrix with constant value \b x
[813]88 inline TMatrix<T>& operator = (T x) { SetT(x); return(*this); }
[894]89 //! += : add constant value \b x to matrix
[804]90 inline TMatrix<T>& operator += (T x) { Add(x); return(*this); }
[894]91 //! -= : substract constant value \b x to matrix
[804]92 inline TMatrix<T>& operator -= (T x) { Sub(x); return(*this); }
[894]93 //! *= : multiply matrix by constant value \b x
[804]94 inline TMatrix<T>& operator *= (T x) { Mul(x); return(*this); }
[894]95 //! /= : divide matrix by constant value \b x
[804]96 inline TMatrix<T>& operator /= (T x) { Div(x); return(*this); }
[762]97
[804]98 // operations avec matrices
[894]99 //! += : add a matrix
[813]100 inline TMatrix<T>& operator += (const TMatrix<T>& a) { AddElt(a); return(*this); }
[894]101 //! -= : substract a matrix
[813]102 inline TMatrix<T>& operator -= (const TMatrix<T>& a) { SubElt(a); return(*this); }
[1003]103 TMatrix<T> Multiply(const TMatrix<T>& b, short mm=BaseArray::SameMemoryMapping) const;
[1013]104 //! *= : matrix product : C = (*this)*B
[813]105 inline TMatrix<T>& operator *= (const TMatrix<T>& b)
106 { this->Set(Multiply(b)); return(*this); }
[762]107
[813]108 // I/O print, ...
109 virtual string InfoString() const;
[804]110 virtual void Print(ostream& os, int_4 maxprt=-1, bool si=false) const ;
[762]111
112protected:
113};
114
[804]115// ---- inline acces methods ------
[894]116 //! () : return element for line \b r and column \b c
[804]117template <class T>
118inline T const& TMatrix<T>::operator()(uint_4 r, uint_4 c) const
119{
120#ifdef SO_BOUNDCHECKING
121 if (marowi_ == 0) CheckBound(r, c, 0, 0, 0, 4);
122 else CheckBound(c, r, 0, 0, 0, 4);
123#endif
124 return ( *( mNDBlock.Begin()+ offset_+
125 r*step_[marowi_] + c*step_[macoli_] ) );
126}
[762]127
[894]128//! () : return element for line \b r and column \b c
[762]129template <class T>
[804]130inline T & TMatrix<T>::operator()(uint_4 r, uint_4 c)
131{
132#ifdef SO_BOUNDCHECKING
133 if (marowi_ == 0) CheckBound(r, c, 0, 0, 0, 4);
134 else CheckBound(c, r, 0, 0, 0, 4);
135#endif
136 return ( *( mNDBlock.Begin()+ offset_+
137 r*step_[marowi_] + c*step_[macoli_] ) );
138}
[762]139
[813]140// Surcharge d'operateurs C = A (+,-) B
141// $CHECK$ Reza 3/4/2000 Pas necessaire de redefinir les operateurs
142// Defini au niveau de TArray<T> - Pour ameliorer l'efficacite
143// Doit-on le faire aussi pour les constantes ? - Fin de $CHECK$ Reza 3/4/2000
144
[958]145/*! \ingroup TArray \fn operator+(const TMatrix<T>&,const TMatrix<T>&)
146 \brief + : add matrixes \b a and \b b */
[813]147template <class T>
148inline TMatrix<T> operator + (const TMatrix<T>& a,const TMatrix<T>& b)
[970]149 {TMatrix<T> result; result.SetTemp(true);
150 if (b.IsTemp()) { result.Share(b); result.AddElt(a); }
151 else { result.CloneOrShare(a); result.AddElt(b); }
152 return result; }
[813]153
[970]154
[958]155/*! \ingroup TArray \fn operator-(const TMatrix<T>&,const TMatrix<T>&)
156 \brief \- : substract matrixes \b a and \b b */
[813]157template <class T>
158inline TMatrix<T> operator - (const TMatrix<T>& a,const TMatrix<T>& b)
[970]159 {TMatrix<T> result; result.SetTemp(true);
160 if (b.IsTemp()) { result.Share(b); result.SubElt(a, true); }
161 else { result.CloneOrShare(a); result.SubElt(b); }
162 return result; }
[813]163
[804]164// Surcharge d'operateurs C = A * B
[958]165/*! \ingroup TArray \fn operator*(const TMatrix<T>&,const TMatrix<T>&)
166 \brief * : multiply matrixes \b a and \b b */
[804]167template <class T> inline TMatrix<T> operator * (const TMatrix<T>& a, const TMatrix<T>& b)
[970]168 { return(a.Multiply(b)); }
[762]169
[956]170// Typedef pour simplifier et compatibilite Peida
171/*! \ingroup TArray
172 \typedef Matrix
173 \brief To simplified TMatrix<r_8> writing
174*/
[762]175typedef TMatrix<r_8> Matrix;
176
177} // Fin du namespace
178
179#endif
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