dft_tools/triqs/gf/local/fourier_real.cpp

/*******************************************************************************
 * 
 * TRIQS: a Toolbox for Research in Interacting Quantum Systems
 *
 * Copyright (C) 2011 by M. Ferrero, O. Parcollet
 *
 * TRIQS 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 3 of the License, or (at your option) any later
 * version.
 *
 * TRIQS 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
 * TRIQS. If not, see <http://www.gnu.org/licenses/>.
 *
 ******************************************************************************/

#include "fourier_real.hpp"
#include <fftw3.h>

namespace triqs { namespace gf { 
 
 namespace {
  double pi = std::acos(-1);
  dcomplex I(0,1);
  inline dcomplex th_expo(double t, double a )     { return (t > 0 ? -I * exp(-a*t) : ( t < 0 ? 0 : -0.5 * I * exp(-a*t) ) ) ; }
  inline dcomplex th_expo_neg(double t, double a ) { return (t < 0 ?  I * exp( a*t) : ( t > 0 ? 0 :  0.5 * I * exp( a*t) ) ) ; }
  inline dcomplex th_expo_inv(double w, double a )     { return 1./(w+I*a) ; }
  inline dcomplex th_expo_neg_inv(double w, double a ) { return 1./(w-I*a) ; }
 }
 
 struct impl_worker {
  
  tqa::vector<dcomplex> g_in, g_out;
  
  void direct (gf_view<refreq,scalar_valued> gw, gf_view<retime,scalar_valued> const gt){
   
   size_t L = gt.mesh().size();
   if (gw.mesh().size() != L) TRIQS_RUNTIME_ERROR << "Meshes are different";
   double test = std::abs(gt.mesh().delta() * gw.mesh().delta() * L / (2*pi) -1);
   if (test > 1.e-10) TRIQS_RUNTIME_ERROR << "Meshes are not compatible";
   
   const double tmin = gt.mesh().x_min();
   const double wmin = gw.mesh().x_min(); 
   //a is a number very larger than delta_w and very smaller than wmax-wmin, used in the tail computation
   const double a = gw.mesh().delta() * sqrt( double(L) );
   
   auto ta = gt(freq_infty());
   g_in.resize(L);
   g_in() = 0;
   g_out.resize(L);
   
   dcomplex t1 = ta(1)(0,0), t2= ta.get_or_zero(2)(0,0);
   dcomplex a1 = (t1 + I * t2/a )/2., a2 = (t1 - I * t2/a )/2.;
   
   for (auto const & t : gt.mesh())
    g_in(t.index()) = (gt(t) - (a1*th_expo(t,a) + a2*th_expo_neg(t,a))) * std::exp(I*t*wmin);
   
   details::fourier_base(g_in, g_out, L, true);
   
   for (auto const & w : gw.mesh())
    gw(w) = gt.mesh().delta() * std::exp(I*(w-wmin)*tmin) * g_out(w.index())
    + a1*th_expo_inv(w,a) + a2*th_expo_neg_inv(w,a);
   
   gw.singularity() = gt.singularity();// set tail
   
  }
  
  void inverse(gf_view<retime,scalar_valued> gt, gf_view<refreq,scalar_valued> const gw){
   
   size_t L = gw.mesh().size();
   if ( L != gt.mesh().size()) TRIQS_RUNTIME_ERROR << "Meshes are different";
   double test = std::abs(gt.mesh().delta() * gw.mesh().delta() * L / (2*pi) -1);
   if (test > 1.e-10) TRIQS_RUNTIME_ERROR << "Meshes are not compatible";
   
   const double tmin = gt.mesh().x_min();
   const double wmin = gw.mesh().x_min();
   //a is a number very larger than delta_w and very smaller than wmax-wmin, used in the tail computation
   const double a = gw.mesh().delta() * sqrt( double(L) );
   
   auto ta = gw(freq_infty());
   tqa::vector<dcomplex> g_in(L), g_out(L);
   
   dcomplex t1 = ta(1)(0,0), t2 = ta.get_or_zero(2)(0,0);
   dcomplex a1 = (t1 + I * t2/a )/2., a2 = (t1 - I * t2/a )/2.;
   g_in() = 0;
   
   for (auto const & w: gw.mesh())
    g_in(w.index()) = (gw(w) - a1*th_expo_inv(w,a) - a2*th_expo_neg_inv(w,a)  ) * std::exp(-I*w*tmin);
   
   details::fourier_base(g_in, g_out, L, false);
   
   const double corr = 1.0/(gt.mesh().delta()*L);
   for (auto const & t : gt.mesh())
    gt(t) = corr * std::exp(I*wmin*(tmin-t)) *
    g_out( t.index() ) + a1 * th_expo(t,a) + a2 * th_expo_neg(t,a) ;
 
   // set tail
   gt.singularity() = gw.singularity();
  }
  
 };
  
  
 //--------------------------------------------------------------------------------------
 
 void fourier_impl(gf_view<refreq,scalar_valued> gw, gf_view<retime,scalar_valued> const gt, scalar_valued){
  impl_worker w;
  w.direct(gw, gt);
 }
 
 void fourier_impl(gf_view<refreq,matrix_valued> gw, gf_view<retime,matrix_valued> const gt, matrix_valued){
  impl_worker w;
  for (size_t n1=0; n1<gw.data().shape()[1];n1++)
   for (size_t n2=0; n2<gw.data().shape()[2];n2++) {
    auto gw_sl=slice_target_to_scalar(gw, n1, n2);
    auto gt_sl=slice_target_to_scalar(gt, n1, n2);
    w.direct(gw_sl, gt_sl);
   }
 }
 
 //---------------------------------------------------------------------------
 
 void inverse_fourier_impl (gf_view<retime,scalar_valued> gt, gf_view<refreq,scalar_valued> const gw, scalar_valued){ 
  impl_worker w;
  w.inverse(gt,gw);
 }
 
 void inverse_fourier_impl (gf_view<retime,matrix_valued> gt, gf_view<refreq,matrix_valued> const gw, matrix_valued){ 
  impl_worker w;
  for (size_t n1=0; n1<gt.data().shape()[1];n1++) 
   for (size_t n2=0; n2<gt.data().shape()[2];n2++) {
    auto gt_sl=slice_target_to_scalar(gt, n1, n2);
    auto gw_sl=slice_target_to_scalar(gw, n1, n2);
    w.inverse(gt_sl, gw_sl);    
   }
 }
 
 //---------------------------------------------------------------------------
 
 void triqs_gf_view_assign_delegation( gf_view<refreq,matrix_valued> g, gf_keeper<tags::fourier,retime,matrix_valued> const & L) { fourier_impl (g,L.g, matrix_valued());}
 void triqs_gf_view_assign_delegation( gf_view<refreq,scalar_valued> g, gf_keeper<tags::fourier,retime,scalar_valued> const & L) { fourier_impl (g,L.g, scalar_valued());}
 void triqs_gf_view_assign_delegation( gf_view<retime,matrix_valued> g, gf_keeper<tags::fourier,refreq,matrix_valued> const & L) { inverse_fourier_impl(g,L.g, matrix_valued());}
 void triqs_gf_view_assign_delegation( gf_view<retime,scalar_valued> g, gf_keeper<tags::fourier,refreq,scalar_valued> const & L) { inverse_fourier_impl(g,L.g, scalar_valued());}
 
}}
First commit : triqs libs version 1.0 alpha1 for earlier commits, see TRIQS0.x repository. 2013-07-17 19:24:07 +02:00			`/*******************************************************************************`
fourier_real: scalar_valued implementation 2013-07-19 10:55:37 +02:00			`*`
First commit : triqs libs version 1.0 alpha1 for earlier commits, see TRIQS0.x repository. 2013-07-17 19:24:07 +02:00			`* TRIQS: a Toolbox for Research in Interacting Quantum Systems`
			`*`
			`* Copyright (C) 2011 by M. Ferrero, O. Parcollet`
			`*`
			`* TRIQS 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 3 of the License, or (at your option) any later`
			`* version.`
			`*`
			`* TRIQS 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`
			`* TRIQS. If not, see <http://www.gnu.org/licenses/>.`
			`*`
			`******************************************************************************/`

			`#include "fourier_real.hpp"`
			`#include <fftw3.h>`

			`namespace triqs { namespace gf {`
fourier_real: scalar_valued implementation 2013-07-19 10:55:37 +02:00
			`namespace {`
			`double pi = std::acos(-1);`
			`dcomplex I(0,1);`
			`inline dcomplex th_expo(double t, double a ) { return (t > 0 ? -I * exp(-at) : ( t < 0 ? 0 : -0.5 I * exp(-a*t) ) ) ; }`
			`inline dcomplex th_expo_neg(double t, double a ) { return (t < 0 ? I * exp( at) : ( t > 0 ? 0 : 0.5 I * exp( a*t) ) ) ; }`
			`inline dcomplex th_expo_inv(double w, double a ) { return 1./(w+I*a) ; }`
			`inline dcomplex th_expo_neg_inv(double w, double a ) { return 1./(w-I*a) ; }`
			`}`

			`struct impl_worker {`

			`tqa::vector<dcomplex> g_in, g_out;`

			`void direct (gf_view<refreq,scalar_valued> gw, gf_view<retime,scalar_valued> const gt){`

			`size_t L = gt.mesh().size();`
			`if (gw.mesh().size() != L) TRIQS_RUNTIME_ERROR << "Meshes are different";`
			`double test = std::abs(gt.mesh().delta() * gw.mesh().delta() * L / (2*pi) -1);`
			`if (test > 1.e-10) TRIQS_RUNTIME_ERROR << "Meshes are not compatible";`

			`const double tmin = gt.mesh().x_min();`
			`const double wmin = gw.mesh().x_min();`
			`//a is a number very larger than delta_w and very smaller than wmax-wmin, used in the tail computation`
			`const double a = gw.mesh().delta() * sqrt( double(L) );`

			`auto ta = gt(freq_infty());`
			`g_in.resize(L);`
			`g_in() = 0;`
			`g_out.resize(L);`

			`dcomplex t1 = ta(1)(0,0), t2= ta.get_or_zero(2)(0,0);`
			`dcomplex a1 = (t1 + I * t2/a )/2., a2 = (t1 - I * t2/a )/2.;`

			`for (auto const & t : gt.mesh())`
			`g_in(t.index()) = (gt(t) - (a1th_expo(t,a) + a2th_expo_neg(t,a))) * std::exp(Itwmin);`

			`details::fourier_base(g_in, g_out, L, true);`

			`for (auto const & w : gw.mesh())`
			`gw(w) = gt.mesh().delta() * std::exp(I(w-wmin)tmin) * g_out(w.index())`
			`+ a1th_expo_inv(w,a) + a2th_expo_neg_inv(w,a);`

			`gw.singularity() = gt.singularity();// set tail`

First commit : triqs libs version 1.0 alpha1 for earlier commits, see TRIQS0.x repository. 2013-07-17 19:24:07 +02:00			`}`
fourier_real: scalar_valued implementation 2013-07-19 10:55:37 +02:00
			`void inverse(gf_view<retime,scalar_valued> gt, gf_view<refreq,scalar_valued> const gw){`

			`size_t L = gw.mesh().size();`
			`if ( L != gt.mesh().size()) TRIQS_RUNTIME_ERROR << "Meshes are different";`
			`double test = std::abs(gt.mesh().delta() * gw.mesh().delta() * L / (2*pi) -1);`
			`if (test > 1.e-10) TRIQS_RUNTIME_ERROR << "Meshes are not compatible";`

			`const double tmin = gt.mesh().x_min();`
			`const double wmin = gw.mesh().x_min();`
			`//a is a number very larger than delta_w and very smaller than wmax-wmin, used in the tail computation`
			`const double a = gw.mesh().delta() * sqrt( double(L) );`

			`auto ta = gw(freq_infty());`
			`tqa::vector<dcomplex> g_in(L), g_out(L);`

			`dcomplex t1 = ta(1)(0,0), t2 = ta.get_or_zero(2)(0,0);`
			`dcomplex a1 = (t1 + I * t2/a )/2., a2 = (t1 - I * t2/a )/2.;`
			`g_in() = 0;`

			`for (auto const & w: gw.mesh())`
			`g_in(w.index()) = (gw(w) - a1th_expo_inv(w,a) - a2th_expo_neg_inv(w,a) ) * std::exp(-Iwtmin);`

			`details::fourier_base(g_in, g_out, L, false);`

			`const double corr = 1.0/(gt.mesh().delta()*L);`
			`for (auto const & t : gt.mesh())`
			`gt(t) = corr * std::exp(Iwmin(tmin-t)) *`
			`g_out( t.index() ) + a1 * th_expo(t,a) + a2 * th_expo_neg(t,a) ;`

			`// set tail`
			`gt.singularity() = gw.singularity();`
First commit : triqs libs version 1.0 alpha1 for earlier commits, see TRIQS0.x repository. 2013-07-17 19:24:07 +02:00			`}`
fourier_real: scalar_valued implementation 2013-07-19 10:55:37 +02:00
			`};`


			`//--------------------------------------------------------------------------------------`

			`void fourier_impl(gf_view<refreq,scalar_valued> gw, gf_view<retime,scalar_valued> const gt, scalar_valued){`
			`impl_worker w;`
			`w.direct(gw, gt);`
			`}`

			`void fourier_impl(gf_view<refreq,matrix_valued> gw, gf_view<retime,matrix_valued> const gt, matrix_valued){`
			`impl_worker w;`
			`for (size_t n1=0; n1<gw.data().shape()[1];n1++)`
			`for (size_t n2=0; n2<gw.data().shape()[2];n2++) {`
			`auto gw_sl=slice_target_to_scalar(gw, n1, n2);`
			`auto gt_sl=slice_target_to_scalar(gt, n1, n2);`
			`w.direct(gw_sl, gt_sl);`
			`}`
			`}`

			`//---------------------------------------------------------------------------`

			`void inverse_fourier_impl (gf_view<retime,scalar_valued> gt, gf_view<refreq,scalar_valued> const gw, scalar_valued){`
			`impl_worker w;`
			`w.inverse(gt,gw);`
			`}`

			`void inverse_fourier_impl (gf_view<retime,matrix_valued> gt, gf_view<refreq,matrix_valued> const gw, matrix_valued){`
			`impl_worker w;`
			`for (size_t n1=0; n1<gt.data().shape()[1];n1++)`
			`for (size_t n2=0; n2<gt.data().shape()[2];n2++) {`
			`auto gt_sl=slice_target_to_scalar(gt, n1, n2);`
			`auto gw_sl=slice_target_to_scalar(gw, n1, n2);`
			`w.inverse(gt_sl, gw_sl);`
			`}`
			`}`

			`//---------------------------------------------------------------------------`

			`void triqs_gf_view_assign_delegation( gf_view<refreq,matrix_valued> g, gf_keeper<tags::fourier,retime,matrix_valued> const & L) { fourier_impl (g,L.g, matrix_valued());}`
			`void triqs_gf_view_assign_delegation( gf_view<refreq,scalar_valued> g, gf_keeper<tags::fourier,retime,scalar_valued> const & L) { fourier_impl (g,L.g, scalar_valued());}`
			`void triqs_gf_view_assign_delegation( gf_view<retime,matrix_valued> g, gf_keeper<tags::fourier,refreq,matrix_valued> const & L) { inverse_fourier_impl(g,L.g, matrix_valued());}`
			`void triqs_gf_view_assign_delegation( gf_view<retime,scalar_valued> g, gf_keeper<tags::fourier,refreq,scalar_valued> const & L) { inverse_fourier_impl(g,L.g, scalar_valued());}`

First commit : triqs libs version 1.0 alpha1 for earlier commits, see TRIQS0.x repository. 2013-07-17 19:24:07 +02:00			`}}`