Grid/lib/tensors/Tensor_unary.h

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

    Grid physics library, www.github.com/paboyle/Grid 

    Source file: ./lib/tensors/Tensor_unary.h

    Copyright (C) 2015

Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
Author: paboyle <paboyle@ph.ed.ac.uk>

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.

    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
#ifndef GRID_TENSOR_UNARY_H
#define GRID_TENSOR_UNARY_H
namespace Grid {

#define UNARY(func)\
template<class obj> inline auto func(const iScalar<obj> &z) -> iScalar<obj>\
{\
    iScalar<obj> ret;\
    ret._internal = func( (z._internal));\
    return ret;\
}\
template<class obj,int N> inline auto func(const iVector<obj,N> &z) -> iVector<obj,N>\
{\
    iVector<obj,N> ret;\
    for(int c1=0;c1<N;c1++){\
      ret._internal[c1] = func( (z._internal[c1]));\
    }\
    return ret;\
}\
template<class obj,int N> inline auto func(const iMatrix<obj,N> &z) -> iMatrix<obj,N>\
{\
    iMatrix<obj,N> ret;\
    for(int c1=0;c1<N;c1++){\
    for(int c2=0;c2<N;c2++){\
      ret._internal[c1][c2] = func( (z._internal[c1][c2]));\
    }}\
    return ret;\
}


#define BINARY_RSCALAR(func,scal)					\
template<class obj> inline iScalar<obj> func(const iScalar<obj> &z,scal y)	\
{\
    iScalar<obj> ret;\
    ret._internal = func(z._internal,y);	\
    return ret;\
}\
 template<class obj,int N> inline iVector<obj,N> func(const iVector<obj,N> &z,scal y) \
{\
    iVector<obj,N> ret;\
    for(int c1=0;c1<N;c1++){\
      ret._internal[c1] = func(z._internal[c1],y);	\
    }\
    return ret;\
}\
 template<class obj,int N> inline  iMatrix<obj,N> func(const iMatrix<obj,N> &z, scal y) \
{\
    iMatrix<obj,N> ret;\
    for(int c1=0;c1<N;c1++){\
    for(int c2=0;c2<N;c2++){\
      ret._internal[c1][c2] = func(z._internal[c1][c2],y);	\
    }}\
    return ret;\
}

UNARY(sqrt);
UNARY(rsqrt);
UNARY(sin);
UNARY(cos);
UNARY(log);
UNARY(exp);
UNARY(abs);
UNARY(Not);


template<class obj> inline auto toReal(const iScalar<obj> &z) -> typename iScalar<obj>::Realified
{
  typename iScalar<obj>::Realified ret;
  ret._internal = toReal(z._internal);
  return ret;
}
 template<class obj,int N> inline auto toReal(const iVector<obj,N> &z) -> typename iVector<obj,N>::Realified
{
  typename iVector<obj,N>::Realified ret;
  for(int c1=0;c1<N;c1++){  
    ret._internal[c1] = toReal(z._internal[c1]); 
  }
  return ret;
}
template<class obj,int N> inline auto toReal(const iMatrix<obj,N> &z) -> typename iMatrix<obj,N>::Realified
{
  typename iMatrix<obj,N>::Realified ret;
  for(int c1=0;c1<N;c1++){
  for(int c2=0;c2<N;c2++){
    ret._internal[c1][c2] = toReal(z._internal[c1][c2]);
  }}
  return ret;
}

template<class obj> inline auto toComplex(const iScalar<obj> &z) -> typename iScalar<obj>::Complexified
{
  typename iScalar<obj>::Complexified ret;
  ret._internal = toComplex(z._internal);
  return ret;
}
 template<class obj,int N> inline auto toComplex(const iVector<obj,N> &z) -> typename iVector<obj,N>::Complexified
{
  typename iVector<obj,N>::Complexified ret;
  for(int c1=0;c1<N;c1++){  
    ret._internal[c1] = toComplex(z._internal[c1]); 
  }
  return ret;
}
template<class obj,int N> inline auto toComplex(const iMatrix<obj,N> &z) -> typename iMatrix<obj,N>::Complexified
{
  typename iMatrix<obj,N>::Complexified ret;
  for(int c1=0;c1<N;c1++){
  for(int c2=0;c2<N;c2++){
    ret._internal[c1][c2] = toComplex(z._internal[c1][c2]);
  }}
  return ret;
}

BINARY_RSCALAR(div,Integer);
BINARY_RSCALAR(mod,Integer);
BINARY_RSCALAR(pow,RealD);

#undef UNARY
#undef BINARY_RSCALAR


}
#endif
Global edit adding copyright and license info to every source file. 2016-01-02 14:51:32 +00:00			`/*************************************************************************************`

			`Grid physics library, www.github.com/paboyle/Grid`

			`Source file: ./lib/tensors/Tensor_unary.h`

			`Copyright (C) 2015`

			`Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>`
			`Author: Peter Boyle <paboyle@ph.ed.ac.uk>`
			`Author: paboyle <paboyle@ph.ed.ac.uk>`

			`This program is free software; you can redistribute it and/or modify`
			`it under the terms of the GNU General Public License as published by`
			`the Free Software Foundation; either version 2 of the License, or`
			`(at your option) any later version.`

			`This program is distributed in the hope that it will be useful,`
			`but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`GNU General Public License for more details.`

			`You should have received a copy of the GNU General Public License along`
			`with this program; if not, write to the Free Software Foundation, Inc.,`
			`51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.`

			`See the full license in the file "LICENSE" in the top level distribution directory`
			`*************************************************************************************/`
			`/* END LEGAL */`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`#ifndef GRID_TENSOR_UNARY_H`
			`#define GRID_TENSOR_UNARY_H`
			`namespace Grid {`

Unary funcs update 2015-06-14 00:53:18 +01:00			`#define UNARY(func)\`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`template<class obj> inline auto func(const iScalar<obj> &z) -> iScalar<obj>\`
			`{\`
			`iScalar<obj> ret;\`
			`ret._internal = func( (z._internal));\`
			`return ret;\`
			`}\`
			`template<class obj,int N> inline auto func(const iVector<obj,N> &z) -> iVector<obj,N>\`
			`{\`
			`iVector<obj,N> ret;\`
			`for(int c1=0;c1<N;c1++){\`
			`ret._internal[c1] = func( (z._internal[c1]));\`
			`}\`
			`return ret;\`
			`}\`
			`template<class obj,int N> inline auto func(const iMatrix<obj,N> &z) -> iMatrix<obj,N>\`
			`{\`
			`iMatrix<obj,N> ret;\`
			`for(int c1=0;c1<N;c1++){\`
			`for(int c2=0;c2<N;c2++){\`
			`ret._internal[c1][c2] = func( (z._internal[c1][c2]));\`
			`}}\`
			`return ret;\`
			`}`

Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00
			`#define BINARY_RSCALAR(func,scal) \`
			`template<class obj> inline iScalar<obj> func(const iScalar<obj> &z,scal y) \`
			`{\`
			`iScalar<obj> ret;\`
			`ret._internal = func(z._internal,y); \`
			`return ret;\`
			`}\`
			`template<class obj,int N> inline iVector<obj,N> func(const iVector<obj,N> &z,scal y) \`
			`{\`
			`iVector<obj,N> ret;\`
			`for(int c1=0;c1<N;c1++){\`
			`ret._internal[c1] = func(z._internal[c1],y); \`
			`}\`
			`return ret;\`
			`}\`
			`template<class obj,int N> inline iMatrix<obj,N> func(const iMatrix<obj,N> &z, scal y) \`
			`{\`
			`iMatrix<obj,N> ret;\`
			`for(int c1=0;c1<N;c1++){\`
			`for(int c2=0;c2<N;c2++){\`
			`ret._internal[c1][c2] = func(z._internal[c1][c2],y); \`
			`}}\`
			`return ret;\`
			`}`

Unary funcs update 2015-06-14 00:53:18 +01:00			`UNARY(sqrt);`
			`UNARY(rsqrt);`
			`UNARY(sin);`
			`UNARY(cos);`
			`UNARY(log);`
			`UNARY(exp);`
			`UNARY(abs);`
			`UNARY(Not);`


			`template<class obj> inline auto toReal(const iScalar<obj> &z) -> typename iScalar<obj>::Realified`
			`{`
			`typename iScalar<obj>::Realified ret;`
			`ret._internal = toReal(z._internal);`
			`return ret;`
			`}`
			`template<class obj,int N> inline auto toReal(const iVector<obj,N> &z) -> typename iVector<obj,N>::Realified`
			`{`
			`typename iVector<obj,N>::Realified ret;`
			`for(int c1=0;c1<N;c1++){`
			`ret._internal[c1] = toReal(z._internal[c1]);`
			`}`
			`return ret;`
			`}`
			`template<class obj,int N> inline auto toReal(const iMatrix<obj,N> &z) -> typename iMatrix<obj,N>::Realified`
			`{`
			`typename iMatrix<obj,N>::Realified ret;`
			`for(int c1=0;c1<N;c1++){`
			`for(int c2=0;c2<N;c2++){`
			`ret._internal[c1][c2] = toReal(z._internal[c1][c2]);`
			`}}`
			`return ret;`
			`}`

			`template<class obj> inline auto toComplex(const iScalar<obj> &z) -> typename iScalar<obj>::Complexified`
			`{`
			`typename iScalar<obj>::Complexified ret;`
			`ret._internal = toComplex(z._internal);`
			`return ret;`
			`}`
			`template<class obj,int N> inline auto toComplex(const iVector<obj,N> &z) -> typename iVector<obj,N>::Complexified`
			`{`
			`typename iVector<obj,N>::Complexified ret;`
			`for(int c1=0;c1<N;c1++){`
			`ret._internal[c1] = toComplex(z._internal[c1]);`
			`}`
			`return ret;`
			`}`
			`template<class obj,int N> inline auto toComplex(const iMatrix<obj,N> &z) -> typename iMatrix<obj,N>::Complexified`
			`{`
			`typename iMatrix<obj,N>::Complexified ret;`
			`for(int c1=0;c1<N;c1++){`
			`for(int c2=0;c2<N;c2++){`
			`ret._internal[c1][c2] = toComplex(z._internal[c1][c2]);`
			`}}`
			`return ret;`
			`}`

Integer divide useful 2015-11-29 01:01:20 +00:00			`BINARY_RSCALAR(div,Integer);`
Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`BINARY_RSCALAR(mod,Integer);`
			`BINARY_RSCALAR(pow,RealD);`

Unary funcs update 2015-06-14 00:53:18 +01:00			`#undef UNARY`
			`#undef BINARY_RSCALAR`

Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
			`}`
			`#endif`