LA_library/nonclass.h

#ifndef _LA_NONCLASS_H_
#define _LA_NONCLASS_H_

#include "vec.h"
#include "smat.h"
#include "mat.h"
#include "la_traits.h"


//MISC
export template <class T>
const NRMat<T> diagonalmatrix(const NRVec<T> &x)
{
int n=x.size();
NRMat<T> result((T)0,n,n);
T *p = result[0];
for(int j=0; j<n; j++) {*p  = x[j]; p+=(n+1);}
return result;
}


//more efficient commutator for a special case of full matrices
template<class T>
inline const NRMat<T> commutator ( const NRMat<T> &x, const NRMat<T> &y, const bool trx=0, const bool tryy=0)
{
NRMat<T> r(trx?x.ncols():x.nrows(), tryy?y.nrows():y.ncols());
r.gemm((T)0,x,trx?'t':'n',y,tryy?'t':'n',(T)1);
r.gemm((T)1,y,tryy?'t':'n',x,trx?'t':'n',(T)-1);
return r;
}

//more efficient commutator for a special case of full matrices
template<class T>
inline const NRMat<T> anticommutator ( const NRMat<T> &x, const NRMat<T> &y, const bool trx=0, const bool tryy=0)
{
NRMat<T> r(trx?x.ncols():x.nrows(), tryy?y.nrows():y.ncols());
r.gemm((T)0,x,trx?'t':'n',y,tryy?'t':'n',(T)1);
r.gemm((T)1,y,tryy?'t':'n',x,trx?'t':'n',(T)1);
return r;
}


//////////////////////
// LAPACK interface //
//////////////////////

#define declare_la(T) \
extern const  NRVec<T> diagofproduct(const NRMat<T> &a, const NRMat<T> &b,\
		bool trb=0, bool conjb=0); \
extern T trace2(const NRMat<T> &a, const NRMat<T> &b, bool trb=0); \
extern T trace2(const NRSMat<T> &a, const NRSMat<T> &b, const bool diagscaled=0);\
extern void linear_solve(NRMat<T> &a, NRMat<T> *b, double *det=0,int n=0); \
extern void linear_solve(NRSMat<T> &a, NRMat<T> *b, double *det=0, int n=0); \
extern void linear_solve(NRMat<T> &a, NRVec<T> &b, double *det=0, int n=0); \
extern void linear_solve(NRSMat<T> &a, NRVec<T> &b, double *det=0, int n=0); \
extern void diagonalize(NRMat<T> &a, NRVec<T> &w, const bool eivec=1, const bool corder=1, int n=0, NRMat<T> *b=NULL, const int itype=1); \
extern void diagonalize(NRSMat<T> &a, NRVec<T> &w, NRMat<T> *v, const bool corder=1, int n=0, NRSMat<T> *b=NULL, const int itype=1);\
extern void singular_decomposition(NRMat<T> &a, NRMat<T> *u, NRVec<T> &s,\
		NRMat<T> *v, const bool corder=1, int m=0, int n=0);

declare_la(double)
declare_la(complex<double>)

// Separate declarations
//general nonsymmetric matrix and generalized diagonalization
extern void gdiagonalize(NRMat<double> &a, NRVec<double> &wr, NRVec<double> &wi,
		NRMat<double> *vl, NRMat<double> *vr, const bool corder=1, int n=0,
		NRMat<double> *b=NULL, NRVec<double> *beta=NULL);
extern void gdiagonalize(NRMat<double> &a, NRVec< complex<double> > &w,
		 NRMat< complex<double> >*vl, NRMat< complex<double> > *vr,
		 const bool corder=1, int n=0, NRMat<double> *b=NULL, NRVec<double> *beta=NULL);
extern NRMat<double> matrixfunction(NRSMat<double> a, double (*f) (double));
extern NRMat<double> matrixfunction(NRMat<double> a, complex<double> (*f)(const complex<double> &),const bool adjust=0);

//functions on matrices
inline NRMat<double>  sqrt(const NRSMat<double> &a) { return matrixfunction(a,&sqrt); }
inline NRMat<double>  log(const NRSMat<double> &a) { return matrixfunction(a,&log); }
extern NRMat<double> log(const NRMat<double> &a);


extern const NRMat<double> realpart(const NRMat< complex<double> >&);
extern const NRMat<double> imagpart(const NRMat< complex<double> >&);
extern const NRMat< complex<double> > realmatrix (const NRMat<double>&);
extern const NRMat< complex<double> > imagmatrix (const NRMat<double>&);

//inverse by means of linear solve, preserving rhs intact
template<typename T>
const NRMat<T> inverse(NRMat<T> a, T *det=0)
{
#ifdef DEBUG
	if(a.nrows()!=a.ncols()) laerror("inverse() for non-square matrix");
#endif
	NRMat<T> result(a.nrows(),a.nrows());
	result = (T)1.;
	linear_solve(a, &result, det);
	return result;
}

//general determinant
template<class MAT>
const typename LA_traits<MAT>::elementtype determinant(MAT a)//again passed by value
{
typename LA_traits<MAT>::elementtype det;
if(a.nrows()!=a.ncols()) laerror("determinant of non-square matrix");
linear_solve(a,NULL,&det);
return det;
}


//auxiliary routine to adjust eigenvectors to guarantee real logarithm
extern void adjustphases(NRMat<double> &v);

#endif
* empty log message * 2005-02-01 00:08:03 +01:00			`#ifndef _LA_NONCLASS_H_`
			`#define _LA_NONCLASS_H_`

* empty log message * 2004-03-17 04:07:21 +01:00			`#include "vec.h"`
			`#include "smat.h"`
			`#include "mat.h"`
* empty log message * 2005-02-06 15:01:27 +01:00			`#include "la_traits.h"`
* empty log message * 2004-03-17 04:07:21 +01:00
* empty log message * 2005-02-04 15:31:42 +01:00
* empty log message * 2004-03-17 04:07:21 +01:00			`//MISC`
* empty log message * 2004-03-17 17:39:07 +01:00			`export template <class T>`
			`const NRMat<T> diagonalmatrix(const NRVec<T> &x)`
			`{`
			`int n=x.size();`
			`NRMat<T> result((T)0,n,n);`
			`T *p = result[0];`
			`for(int j=0; j<n; j++) {*p = x[j]; p+=(n+1);}`
			`return result;`
			`}`

* empty log message * 2004-03-17 04:07:21 +01:00
			`//more efficient commutator for a special case of full matrices`
			`template<class T>`
			`inline const NRMat<T> commutator ( const NRMat<T> &x, const NRMat<T> &y, const bool trx=0, const bool tryy=0)`
			`{`
			`NRMat<T> r(trx?x.ncols():x.nrows(), tryy?y.nrows():y.ncols());`
			`r.gemm((T)0,x,trx?'t':'n',y,tryy?'t':'n',(T)1);`
			`r.gemm((T)1,y,tryy?'t':'n',x,trx?'t':'n',(T)-1);`
			`return r;`
			`}`

			`//more efficient commutator for a special case of full matrices`
			`template<class T>`
			`inline const NRMat<T> anticommutator ( const NRMat<T> &x, const NRMat<T> &y, const bool trx=0, const bool tryy=0)`
			`{`
			`NRMat<T> r(trx?x.ncols():x.nrows(), tryy?y.nrows():y.ncols());`
			`r.gemm((T)0,x,trx?'t':'n',y,tryy?'t':'n',(T)1);`
			`r.gemm((T)1,y,tryy?'t':'n',x,trx?'t':'n',(T)1);`
			`return r;`
			`}`




			`//////////////////////`
			`// LAPACK interface //`
			`//////////////////////`

			`#define declare_la(T) \`
			`extern const NRVec<T> diagofproduct(const NRMat<T> &a, const NRMat<T> &b,\`
			`bool trb=0, bool conjb=0); \`
			`extern T trace2(const NRMat<T> &a, const NRMat<T> &b, bool trb=0); \`
			`extern T trace2(const NRSMat<T> &a, const NRSMat<T> &b, const bool diagscaled=0);\`
/ 2005-02-17 23:54:27 +01:00			`extern void linear_solve(NRMat<T> &a, NRMat<T> b, double det=0,int n=0); \`
			`extern void linear_solve(NRSMat<T> &a, NRMat<T> b, double det=0, int n=0); \`
			`extern void linear_solve(NRMat<T> &a, NRVec<T> &b, double *det=0, int n=0); \`
			`extern void linear_solve(NRSMat<T> &a, NRVec<T> &b, double *det=0, int n=0); \`
			`extern void diagonalize(NRMat<T> &a, NRVec<T> &w, const bool eivec=1, const bool corder=1, int n=0, NRMat<T> *b=NULL, const int itype=1); \`
			`extern void diagonalize(NRSMat<T> &a, NRVec<T> &w, NRMat<T> v, const bool corder=1, int n=0, NRSMat<T> b=NULL, const int itype=1);\`
* empty log message * 2004-03-17 04:07:21 +01:00			`extern void singular_decomposition(NRMat<T> &a, NRMat<T> *u, NRVec<T> &s,\`
/ 2005-02-17 23:54:27 +01:00			`NRMat<T> *v, const bool corder=1, int m=0, int n=0);`
* empty log message * 2004-03-17 04:07:21 +01:00
			`declare_la(double)`
			`declare_la(complex<double>)`

			`// Separate declarations`
/ 2005-02-17 23:54:27 +01:00			`//general nonsymmetric matrix and generalized diagonalization`
* empty log message * 2004-03-17 04:07:21 +01:00			`extern void gdiagonalize(NRMat<double> &a, NRVec<double> &wr, NRVec<double> &wi,`
/ 2005-02-17 23:54:27 +01:00			`NRMat<double> vl, NRMat<double> vr, const bool corder=1, int n=0,`
			`NRMat<double> b=NULL, NRVec<double> beta=NULL);`
* empty log message * 2004-03-17 04:07:21 +01:00			`extern void gdiagonalize(NRMat<double> &a, NRVec< complex<double> > &w,`
/ 2005-02-17 23:54:27 +01:00			`NRMat< complex<double> >vl, NRMat< complex<double> > vr,`
			`const bool corder=1, int n=0, NRMat<double> b=NULL, NRVec<double> beta=NULL);`
* empty log message * 2004-03-17 04:07:21 +01:00			`extern NRMat<double> matrixfunction(NRSMat<double> a, double (*f) (double));`
			`extern NRMat<double> matrixfunction(NRMat<double> a, complex<double> (*f)(const complex<double> &),const bool adjust=0);`

			`//functions on matrices`
			`inline NRMat<double> sqrt(const NRSMat<double> &a) { return matrixfunction(a,&sqrt); }`
			`inline NRMat<double> log(const NRSMat<double> &a) { return matrixfunction(a,&log); }`
			`extern NRMat<double> log(const NRMat<double> &a);`


			`extern const NRMat<double> realpart(const NRMat< complex<double> >&);`
			`extern const NRMat<double> imagpart(const NRMat< complex<double> >&);`
			`extern const NRMat< complex<double> > realmatrix (const NRMat<double>&);`
			`extern const NRMat< complex<double> > imagmatrix (const NRMat<double>&);`

			`//inverse by means of linear solve, preserving rhs intact`
			`template<typename T>`
			`const NRMat<T> inverse(NRMat<T> a, T *det=0)`
			`{`
			`#ifdef DEBUG`
			`if(a.nrows()!=a.ncols()) laerror("inverse() for non-square matrix");`
			`#endif`
			`NRMat<T> result(a.nrows(),a.nrows());`
			`result = (T)1.;`
			`linear_solve(a, &result, det);`
			`return result;`
			`}`

* empty log message * 2005-02-06 15:01:27 +01:00			`//general determinant`
			`template<class MAT>`
* empty log message * 2005-02-14 01:10:07 +01:00			`const typename LA_traits<MAT>::elementtype determinant(MAT a)//again passed by value`
* empty log message * 2005-02-06 15:01:27 +01:00			`{`
* empty log message * 2005-02-14 01:10:07 +01:00			`typename LA_traits<MAT>::elementtype det;`
* empty log message * 2005-02-06 15:01:27 +01:00			`if(a.nrows()!=a.ncols()) laerror("determinant of non-square matrix");`
			`linear_solve(a,NULL,&det);`
			`return det;`
			`}`


			`//auxiliary routine to adjust eigenvectors to guarantee real logarithm`
			`extern void adjustphases(NRMat<double> &v);`

* empty log message * 2005-02-01 00:08:03 +01:00			`#endif`