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// CLASSDOC OFF
// ---------------------------------------------------------------------------
// CLASSDOC ON
//
// This file is a part of the CLHEP - a Class Library for High Energy Physics.
//
// This is the definition of the HepMatrix class.
//
// This software written by Nobu Katayama and Mike Smyth, Cornell University.
//
//
// .SS Usage
// The Matrix class does all the obvious things, in all the obvious ways.
// You declare a Matrix by saying
//
// .ft B
// HepMatrix hm1(n, m);
//
// To declare a Matrix as a copy of a Matrix hm2, say
//
// .ft B
// HepMatrix hm1(hm2);
// or
// .ft B
// HepMatrix hm1 = hm2;
//
// You can declare initilizations of a Matrix, by giving it a third
// integer argument, either 0 or 1. 0 means initialize to 0, one means
// the identity matrix. If you do not give a third argument the memory
// is not initialized.
//
// .ft B
// HepMatrix hm1(n, m, 1);
//
// ./"This code has been written by Mike Smyth, and the algorithms used are
// ./"described in the thesis "A Tracking Library for a Silicon Vertex Detector"
// ./"(Mike Smyth, Cornell University, June 1993).
// ./"This is file contains C++ stuff for doing things with Matrices.
// ./"To turn on bound checking, define MATRIX_BOUND_CHECK before including
// ./"this file.
//
// To find the number of rows or number of columns, say
//
// .ft B
// nr = hm1.num_row();
//
// or
//
// .ft B
// nc = hm1.num_col();
//
// You can print a Matrix by
//
// .ft B
// cout << hm1;
//
// You can add,
// subtract, and multiply two Matrices. You can multiply a Matrix by a
// scalar, on the left or the right. +=, *=, -= act in the obvious way.
// hm1 *= hm2 is as hm1 = hm1*hm2. You can also divide by a scalar on the
// right, or use /= to do the same thing.
//
// You can read or write a Matrix element by saying
//
// .ft B
// m(row, col) = blah. (1 <= row <= num_row(), 1 <= col <= num_col())
//
// .ft B
// blah = m(row, col) ...
//
// m(row, col) is inline, and by default does not do bound checking.
// If bound checking is desired, say #define MATRIX_BOUND_CHECK before
// including matrix.h.
//
// You can also access the element using C subscripting operator []
//
// .ft B
// m[row][col] = blah. (0 <= row < num_row(), 0 <= col < num_col())
//
// .ft B
// blah = m[row][col] ...
//
// m[row][col] is inline, and by default does not do bound checking.
// If bound checking is desired, say #define MATRIX_BOUND_CHECK before
// including matrix.h. (Notice the difference in bases in two access
// methods.)
//
// .SS Comments on precision
//
// The user would normally use "Matrix" class whose precision is the same
// as the other classes of CLHEP (ThreeVec, for example). However, he/she
// can explicitly choose Matrix (double) or MatrixF (float) if he/she wishes.
// In the former case, include "Matrix.h." In the latter case, include either
// "Matrix.h," or "MatrixF.h," or both. The only operators that can talk
// to each other are the copy constructor and assignment operator.
//
// .ft B
// Matrix d(3,4,HEP_MATRIX_IDENTITY);
//
// .ft B
// MatrixF f;
//
// .ft B
// f = d;
//
// .ft B
// MatrixF g(d);
//
// will convert from one to the other.
//
// .SS Other functions
//
// .ft B
// mt = m.T();
//
// returns the transpose of m.
//
// .ft B
// ms = hm2.sub(row_min, row_max, col_min, col_max);
//
// returns the subMatrix.
// hm2(row_min:row_max, col_min:col_max) in matlab terminology.
// If instead you say
//
// .ft B
// hm2.sub(row, col, hm1);
//
// then the subMatrix
// hm2(row:row+hm1.num_row()-1, col:col+hm1.num_col()-1) is replaced with hm1.
//
// .ft B
// md = dsum(hm1,hm2);
//
// returns the direct sum of the two matrices.
//
// Operations that do not have to be member functions or friends are listed
// towards the end of this man page.
//
//
// To invert a matrix, say
//
// .ft B
// minv = m.inverse(ierr);
//
// ierr will be non-zero if the matrix is singular.
//
// If you can overwrite the matrix, you can use the invert function to avoid
// two extra copies. Use
//
// .ft B
// m.invert(ierr);
//
// Many basic linear algebra functions such as QR decomposition are defined.
// In order to keep the header file a reasonable size, the functions are
// defined in MatrixLinear.h.
//
//
// .ft B
// Note that Matrices run from (1,1) to (n, m), and [0][0] to
// [n-1][m-1]. The users of the latter form should be careful about sub
// functions.
//
// ./" The program that this class was orginally used with lots of small
// ./" Matrices. It was very costly to malloc and free array space every
// ./" time a Matrix is needed. So, a number of previously freed arrays are
// ./" kept around, and when needed again one of these array is used. Right
// ./" now, a set of piles of arrays with row <= row_max and col <= col_max
// ./" are kept around. The piles of kept Matrices can be easily changed.
// ./" Array mallocing and freeing are done only in new_m() and delete_m(),
// ./" so these are the only routines that need to be rewritten.
//
// You can do things thinking of a Matrix as a list of numbers.
//
// .ft B
// m = hm1.apply(HEP_MATRIX_ELEMENT (*f)(HEP_MATRIX_ELEMENT, int r, int c));
//
// applies f to every element of hm1 and places it in m.
//
// .SS See Also:
// SymMatrix[DF].h, GenMatrix[DF].h, DiagMatrix[DF].h Vector[DF].h
// MatrixLinear[DF].h
#ifndef _Matrix_H_
#define _Matrix_H_
#ifdef GNUPRAGMA
#pragma interface
#endif
#include <vector>
#include "CLHEP/Matrix/defs.h"
#include "CLHEP/Matrix/GenMatrix.h"
namespace CLHEP {
class HepRandom;
class HepSymMatrix;
class HepDiagMatrix;
class HepVector;
class HepRotation;
/**
* @author
* @ingroup matrix
*/
class HepMatrix : public HepGenMatrix {
public:
inline HepMatrix();
// Default constructor. Gives 0 x 0 matrix. Another Matrix can be
// assigned to it.
HepMatrix(int p, int q);
// Constructor. Gives an unitialized p x q matrix.
HepMatrix(int p, int q, int i);
// Constructor. Gives an initialized p x q matrix.
// If i=0, it is initialized to all 0. If i=1, the diagonal elements
// are set to 1.0.
HepMatrix(int p, int q, HepRandom &r);
// Constructor with a Random object.
HepMatrix(const HepMatrix &hm1);
// Copy constructor.
HepMatrix(const HepSymMatrix &);
HepMatrix(const HepDiagMatrix &);
HepMatrix(const HepVector &);
// Constructors from SymMatrix, DiagMatrix and Vector.
virtual ~HepMatrix();
// Destructor.
virtual int num_row() const;
// Returns the number of rows.
virtual int num_col() const;
// Returns the number of columns.
virtual const double & operator()(int row, int col) const;
virtual double & operator()(int row, int col);
// Read or write a matrix element.
// ** Note that the indexing starts from (1,1). **
HepMatrix & operator *= (double t);
// Multiply a Matrix by a floating number.
HepMatrix & operator /= (double t);
// Divide a Matrix by a floating number.
HepMatrix & operator += ( const HepMatrix &);
HepMatrix & operator += ( const HepSymMatrix &);
HepMatrix & operator += ( const HepDiagMatrix &);
HepMatrix & operator += ( const HepVector &);
HepMatrix & operator -= ( const HepMatrix &);
HepMatrix & operator -= ( const HepSymMatrix &);
HepMatrix & operator -= ( const HepDiagMatrix &);
HepMatrix & operator -= ( const HepVector &);
// Add or subtract a Matrix.
// When adding/subtracting Vector, Matrix must have num_col of one.
HepMatrix & operator = ( const HepMatrix &);
HepMatrix & operator = ( const HepSymMatrix &);
HepMatrix & operator = ( const HepDiagMatrix &);
HepMatrix & operator = ( const HepVector &);
HepMatrix & operator = ( const HepRotation &);
// Assignment operators.
HepMatrix operator- () const;
// unary minus, ie. flip the sign of each element.
HepMatrix apply(double (*f)(double, int, int)) const;
// Apply a function to all elements of the matrix.
HepMatrix T() const;
// Returns the transpose of a Matrix.
HepMatrix sub(int min_row, int max_row, int min_col, int max_col) const;
// Returns a sub matrix of a Matrix.
// WARNING: rows and columns are numbered from 1
void sub(int row, int col, const HepMatrix &hm1);
// Sub matrix of this Matrix is replaced with hm1.
// WARNING: rows and columns are numbered from 1
friend inline void swap(HepMatrix &hm1, HepMatrix &hm2);
// Swap hm1 with hm2.
inline HepMatrix inverse(int& ierr) const;
// Invert a Matrix. Matrix must be square and is not changed.
// Returns ierr = 0 (zero) when successful, otherwise non-zero.
virtual void invert(int& ierr);
// Invert a Matrix. Matrix must be square.
// N.B. the contents of the matrix are replaced by the inverse.
// Returns ierr = 0 (zero) when successful, otherwise non-zero.
// This method has less overhead then inverse().
inline void invert();
// Invert a matrix. Throw std::runtime_error on failure.
inline HepMatrix inverse() const;
// Invert a matrix. Throw std::runtime_error on failure.
double determinant() const;
// calculate the determinant of the matrix.
double trace() const;
// calculate the trace of the matrix (sum of diagonal elements).
class HepMatrix_row {
public:
inline HepMatrix_row(HepMatrix&,int);
double & operator[](int);
private:
HepMatrix& _a;
int _r;
};
class HepMatrix_row_const {
public:
inline HepMatrix_row_const (const HepMatrix&,int);
const double & operator[](int) const;
private:
const HepMatrix& _a;
int _r;
};
// helper classes for implementing m[i][j]
inline HepMatrix_row operator[] (int);
inline const HepMatrix_row_const operator[] (int) const;
// Read or write a matrix element.
// While it may not look like it, you simply do m[i][j] to get an
// element.
// ** Note that the indexing starts from [0][0]. **
protected:
virtual int num_size() const;
virtual void invertHaywood4(int& ierr);
virtual void invertHaywood5(int& ierr);
virtual void invertHaywood6(int& ierr);
private:
friend class HepMatrix_row;
friend class HepMatrix_row_const;
friend class HepVector;
friend class HepSymMatrix;
friend class HepDiagMatrix;
// Friend classes.
friend HepMatrix operator+(const HepMatrix &hm1, const HepMatrix &hm2);
friend HepMatrix operator-(const HepMatrix &hm1, const HepMatrix &hm2);
friend HepMatrix operator*(const HepMatrix &hm1, const HepMatrix &hm2);
friend HepMatrix operator*(const HepMatrix &hm1, const HepSymMatrix &hm2);
friend HepMatrix operator*(const HepMatrix &hm1, const HepDiagMatrix &hm2);
friend HepMatrix operator*(const HepSymMatrix &hm1, const HepMatrix &hm2);
friend HepMatrix operator*(const HepDiagMatrix &hm1, const HepMatrix &hm2);
friend HepMatrix operator*(const HepVector &hm1, const HepMatrix &hm2);
friend HepVector operator*(const HepMatrix &hm1, const HepVector &hm2);
friend HepMatrix operator*(const HepSymMatrix &hm1, const HepSymMatrix &hm2);
// Multiply a Matrix by a Matrix or Vector.
friend HepVector solve(const HepMatrix &, const HepVector &);
// solve the system of linear eq
friend HepVector qr_solve(HepMatrix *, const HepVector &);
friend HepMatrix qr_solve(HepMatrix *, const HepMatrix &b);
friend void tridiagonal(HepSymMatrix *a,HepMatrix *hsm);
friend void row_house(HepMatrix *,const HepMatrix &, double,
int, int, int, int);
friend void row_house(HepMatrix *,const HepVector &, double,
int, int);
friend void back_solve(const HepMatrix &R, HepVector *b);
friend void back_solve(const HepMatrix &R, HepMatrix *b);
friend void col_givens(HepMatrix *A, double c,
double s, int k1, int k2,
int rowmin, int rowmax);
// Does a column Givens update.
friend void row_givens(HepMatrix *A, double c,
double s, int k1, int k2,
int colmin, int colmax);
friend void col_house(HepMatrix *,const HepMatrix &, double,
int, int, int, int);
friend HepVector house(const HepMatrix &a,int row,int col);
friend void house_with_update(HepMatrix *a,int row,int col);
friend void house_with_update(HepMatrix *a,HepMatrix *v,int row,int col);
friend void house_with_update2(HepSymMatrix *a,HepMatrix *v,
int row,int col);
int dfact_matrix(double &det, int *ir);
// factorize the matrix. If successful, the return code is 0. On
// return, det is the determinant and ir[] is row-interchange
// matrix. See CERNLIB's DFACT routine.
int dfinv_matrix(int *ir);
// invert the matrix. See CERNLIB DFINV.
#ifdef DISABLE_ALLOC
std::vector<double > m;
#else
std::vector<double,Alloc<double,25> > m;
#endif
int nrow, ncol;
int size_;
};
// Operations other than member functions for Matrix
// implemented in Matrix.cc and Matrix.icc (inline).
HepMatrix operator*(const HepMatrix &, const HepMatrix &);
HepMatrix operator*(double t, const HepMatrix &);
HepMatrix operator*(const HepMatrix &, double );
// Multiplication operators
// Note that m *= hm1 is always faster than m = m * hm1.
HepMatrix operator/(const HepMatrix &, double );
// m = hm1 / t. (m /= t is faster if you can use it.)
HepMatrix operator+(const HepMatrix &hm1, const HepMatrix &hm2);
// m = hm1 + hm2;
// Note that m += hm1 is always faster than m = m + hm1.
HepMatrix operator-(const HepMatrix &hm1, const HepMatrix &hm2);
// m = hm1 - hm2;
// Note that m -= hm1 is always faster than m = m - hm1.
HepMatrix dsum(const HepMatrix&, const HepMatrix&);
// Direct sum of two matrices. The direct sum of A and B is the matrix
// A 0
// 0 B
HepVector solve(const HepMatrix &, const HepVector &);
// solve the system of linear equations using LU decomposition.
std::ostream& operator<<(std::ostream &s, const HepMatrix &q);
// Read in, write out Matrix into a stream.
//
// Specialized linear algebra functions
//
HepVector qr_solve(const HepMatrix &A, const HepVector &b);
HepVector qr_solve(HepMatrix *A, const HepVector &b);
HepMatrix qr_solve(const HepMatrix &A, const HepMatrix &b);
HepMatrix qr_solve(HepMatrix *A, const HepMatrix &b);
// Works like backsolve, except matrix does not need to be upper
// triangular. For nonsquare matrix, it solves in the least square sense.
HepMatrix qr_inverse(const HepMatrix &A);
HepMatrix qr_inverse(HepMatrix *A);
// Finds the inverse of a matrix using QR decomposition. Note, often what
// you really want is solve or backsolve, they can be much quicker than
// inverse in many calculations.
void qr_decomp(HepMatrix *A, HepMatrix *hsm);
HepMatrix qr_decomp(HepMatrix *A);
// Does a QR decomposition of a matrix.
void back_solve(const HepMatrix &R, HepVector *b);
void back_solve(const HepMatrix &R, HepMatrix *b);
// Solves R*x = b where R is upper triangular. Also has a variation that
// solves a number of equations of this form in one step, where b is a matrix
// with each column a different vector. See also solve.
void col_house(HepMatrix *a, const HepMatrix &v, double vnormsq,
int row, int col, int row_start, int col_start);
void col_house(HepMatrix *a, const HepMatrix &v, int row, int col,
int row_start, int col_start);
// Does a column Householder update.
void col_givens(HepMatrix *A, double c, double s,
int k1, int k2, int row_min=1, int row_max=0);
// do a column Givens update
void row_givens(HepMatrix *A, double c, double s,
int k1, int k2, int col_min=1, int col_max=0);
// do a row Givens update
void givens(double a, double b, double *c, double *s);
// algorithm 5.1.5 in Golub and Van Loan
HepVector house(const HepMatrix &a, int row=1, int col=1);
// Returns a Householder vector to zero elements.
void house_with_update(HepMatrix *a, int row=1, int col=1);
void house_with_update(HepMatrix *a, HepMatrix *v, int row=1, int col=1);
// Finds and does Householder reflection on matrix.
void row_house(HepMatrix *a, const HepVector &v, double vnormsq,
int row=1, int col=1);
void row_house(HepMatrix *a, const HepMatrix &v, double vnormsq,
int row, int col, int row_start, int col_start);
void row_house(HepMatrix *a, const HepMatrix &v, int row, int col,
int row_start, int col_start);
// Does a row Householder update.
} // namespace CLHEP
#ifdef ENABLE_BACKWARDS_COMPATIBILITY
// backwards compatibility will be enabled ONLY in CLHEP 1.9
using namespace CLHEP;
#endif
#ifndef HEP_DEBUG_INLINE
#include "CLHEP/Matrix/Matrix.icc"
#endif
#endif /*_Matrix_H*/
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