dft_tools/triqs/gfs/deprecated/refreq_imtime.hpp

/*******************************************************************************
 * 
 * TRIQS: a Toolbox for Research in Interacting Quantum Systems
 *
 * Copyright (C) 2012 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/>.
 *
 ******************************************************************************/
#ifndef TRIQS_GF_IMTIME_REFREQ_TIMES_H
#define TRIQS_GF_IMTIME_REFREQ_TIMES_H
#include "./tools.hpp"
#include "./gf.hpp"
#include "./imtime.hpp"
#include "./refreq.hpp"
#include "./meshes/product.hpp"

namespace triqs { namespace gfs {

 struct refreq_imtime {};

 // the mesh
 template<typename Opt> struct gf_mesh<refreq_imtime,Opt> :mesh_product<gf_mesh<refreq,Opt>,gf_mesh<imtime,Opt>>  {
  typedef gf_mesh<refreq,Opt> m1_t; 
  typedef gf_mesh<imtime,Opt> m2_t; 
  typedef mesh_product<m1_t,m2_t> B;
  gf_mesh () = default;
  gf_mesh(B const & x) : B(x) {}
  gf_mesh (double wmin, double wmax, size_t n_freq, double beta, statistic_enum S, size_t nt, mesh_kind mk=full_bins ) :
   B {gf_mesh<refreq,Opt>(wmin,wmax,n_freq), gf_mesh<imtime,Opt>(beta,S,nt,mk)} {}
 };

 namespace gfs_implementation { 
  // singularity
  //template<typename Opt> struct singularity<refreq_imtime,scalar_valued,Opt>  { typedef gf<retime,scalar_valued> type;};

  // h5 name
  template<typename Opt> struct h5_name<refreq_imtime,scalar_valued,Opt> { static std::string invoke(){ return  "GfReFreqImTime";}};

  /// ---------------------------  data access  ---------------------------------

  template<typename Opt> struct data_proxy<refreq_imtime,scalar_valued,Opt> : data_proxy_array<std::complex<double>,1> {};

  /// ---------------------------  evaluator ---------------------------------

  template<typename Opt>
   struct evaluator<refreq_imtime,scalar_valued,Opt> {
    static constexpr int arity = 2;
    template<typename G>
     std::complex<double> operator() (G const * g, double omega, double tau)  const {
      double beta = std::get<1>(g->mesh().components()).domain().beta;
      int p = std::floor(tau/beta);
      tau -= p*beta;
      size_t n1,n2; double w1,w2; bool in;
      std::tie(in, n1, w1) = windowing( std::get<0>(g->mesh().components()),omega);
      if (!in) TRIQS_RUNTIME_ERROR <<" Evaluation out of bounds";
      std::tie(in, n2, w2) = windowing( std::get<1>(g->mesh().components()),tau);
      if (!in) TRIQS_RUNTIME_ERROR <<" Evaluation out of bounds";
      auto gg = on_mesh(*g); //[g]( size_t n1, size_t n2) {return g->on_mesh(n1,n2);};
      auto res =  w1 *( w2*gg(n1,n2) + (1-w2)*gg(n1,n2+1)) + (1-w1) * ( w2*gg(n1+1,n2) + (1-w2)*gg(n1+1,n2+1));

      //std::cout  << "eval reref imtim"<< n1 << " "<< n2 << " "<< w1 << " " << w2 << " "<< omega << " "<< tau<<  std::endl;

      return ((std::get<1>(g->mesh().components()).domain().statistic == Fermion) && (p%2==1) ? -res : res);
     } 
   };

  // -------------------------------   Factories  --------------------------------------------------

  template<typename Opt> struct factories<refreq_imtime, scalar_valued,Opt> {
   typedef gf<refreq_imtime, scalar_valued,Opt> gf_t;
   struct target_shape_t {};

   template<typename MeshType>
    static gf_t make_gf(MeshType && m) {
     typename gf_t::data_regular_t A(m.size());
     A() =0;
     return gf_t (m, std::move(A), nothing(), nothing() ) ;
    }

   static gf_t make_gf(double wmin, double wmax, size_t n_freq, double beta, statistic_enum S, size_t nt, mesh_kind mk=full_bins) { 
    auto m =  gf_mesh<refreq_imtime,Opt>(wmin, wmax, n_freq, beta,S, nt, mk);
    typename gf_t::data_regular_t A(m.size()); 
    A() =0;
    return gf_t (m, std::move(A), nothing(), nothing() ) ;
   }
  };

 } // gfs_implementation

 //slices
 inline gf_view<refreq,scalar_valued> slice_mesh_imtime (gf_view<refreq_imtime,scalar_valued> g, size_t index) { 
  auto arr = reinterpret_linear_array(g.mesh(),g.data()); // view it as a 2d array
  return { std::get<0>(g.mesh().components()), arr(arrays::range(),index), local::tail(1,1), nothing() };
 }

}}
#endif
draft of multi-time gf (t,tau), etc... 2013-07-19 13:30:52 +02:00			`/*******************************************************************************`
			`*`
			`* TRIQS: a Toolbox for Research in Interacting Quantum Systems`
			`*`
			`* Copyright (C) 2012 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/>.`
			`*`
			`******************************************************************************/`
			`#ifndef TRIQS_GF_IMTIME_REFREQ_TIMES_H`
			`#define TRIQS_GF_IMTIME_REFREQ_TIMES_H`
			`#include "./tools.hpp"`
			`#include "./gf.hpp"`
			`#include "./imtime.hpp"`
			`#include "./refreq.hpp"`
			`#include "./meshes/product.hpp"`

[API BREAK] gf : rename namespace gf->gfs - necessary otherwise the class gf and the namespace have the same name, leading to some confusion, and need to qualify some functions (specially on gcc). Same naming conventions as arrays. 2013-07-28 13:28:19 +02:00			`namespace triqs { namespace gfs {`
gf : mesh now the class, not a trait. simplify : mesh was a impl trait, make it the class itself. corrected the gf, tests and the cython. 2013-08-24 14:47:47 +02:00
			`struct refreq_imtime {};`

			`// the mesh`
gfs: change the name of the mesh -> gf_mesh for gcc gcc has a pb because the template mesh<Variable,Opt> has the name same as the gf mesh method (!). Clang is fine however on this... Solution : rename the template mesh<...> to gf_mesh... Not very elegant, but ok. 2013-08-27 14:20:50 +02:00			`template<typename Opt> struct gf_mesh<refreq_imtime,Opt> :mesh_product<gf_mesh<refreq,Opt>,gf_mesh<imtime,Opt>> {`
			`typedef gf_mesh<refreq,Opt> m1_t;`
			`typedef gf_mesh<imtime,Opt> m2_t;`
gf : mesh now the class, not a trait. simplify : mesh was a impl trait, make it the class itself. corrected the gf, tests and the cython. 2013-08-24 14:47:47 +02:00			`typedef mesh_product<m1_t,m2_t> B;`
gf: minor correction for 2 times, etc... -> are going to be replaced soon anyway ... 2013-09-11 20:48:03 +02:00			`gf_mesh () = default;`
			`gf_mesh(B const & x) : B(x) {}`
gfs: change the name of the mesh -> gf_mesh for gcc gcc has a pb because the template mesh<Variable,Opt> has the name same as the gf mesh method (!). Clang is fine however on this... Solution : rename the template mesh<...> to gf_mesh... Not very elegant, but ok. 2013-08-27 14:20:50 +02:00			`gf_mesh (double wmin, double wmax, size_t n_freq, double beta, statistic_enum S, size_t nt, mesh_kind mk=full_bins ) :`
			`B {gf_mesh<refreq,Opt>(wmin,wmax,n_freq), gf_mesh<imtime,Opt>(beta,S,nt,mk)} {}`
gf : mesh now the class, not a trait. simplify : mesh was a impl trait, make it the class itself. corrected the gf, tests and the cython. 2013-08-24 14:47:47 +02:00			`};`

			`namespace gfs_implementation {`
			`// singularity`
			`//template<typename Opt> struct singularity<refreq_imtime,scalar_valued,Opt> { typedef gf<retime,scalar_valued> type;};`

			`// h5 name`
			`template<typename Opt> struct h5_name<refreq_imtime,scalar_valued,Opt> { static std::string invoke(){ return "GfReFreqImTime";}};`

			`/// --------------------------- data access ---------------------------------`

			`template<typename Opt> struct data_proxy<refreq_imtime,scalar_valued,Opt> : data_proxy_array<std::complex<double>,1> {};`

			`/// --------------------------- evaluator ---------------------------------`

			`template<typename Opt>`
			`struct evaluator<refreq_imtime,scalar_valued,Opt> {`
			`static constexpr int arity = 2;`
			`template<typename G>`
			`std::complex<double> operator() (G const * g, double omega, double tau) const {`
			`double beta = std::get<1>(g->mesh().components()).domain().beta;`
			`int p = std::floor(tau/beta);`
			`tau -= p*beta;`
			`size_t n1,n2; double w1,w2; bool in;`
			`std::tie(in, n1, w1) = windowing( std::get<0>(g->mesh().components()),omega);`
			`if (!in) TRIQS_RUNTIME_ERROR <<" Evaluation out of bounds";`
			`std::tie(in, n2, w2) = windowing( std::get<1>(g->mesh().components()),tau);`
			`if (!in) TRIQS_RUNTIME_ERROR <<" Evaluation out of bounds";`
			`auto gg = on_mesh(*g); //[g]( size_t n1, size_t n2) {return g->on_mesh(n1,n2);};`
			`auto res = w1 ( w2gg(n1,n2) + (1-w2)gg(n1,n2+1)) + (1-w1) ( w2gg(n1+1,n2) + (1-w2)gg(n1+1,n2+1));`

			`//std::cout << "eval reref imtim"<< n1 << " "<< n2 << " "<< w1 << " " << w2 << " "<< omega << " "<< tau<< std::endl;`

			`return ((std::get<1>(g->mesh().components()).domain().statistic == Fermion) && (p%2==1) ? -res : res);`
			`}`
			`};`

			`// ------------------------------- Factories --------------------------------------------------`

			`template<typename Opt> struct factories<refreq_imtime, scalar_valued,Opt> {`
			`typedef gf<refreq_imtime, scalar_valued,Opt> gf_t;`
[API change] gf : factories -> constructors - Make more general constructors for the gf. gf( mesh, target_shape_t) - remove the old make_gf for the basic gf. - 2 var non generic gf removed. - clean evaluator - add tensor_valued - add a simple vertex test. - clean specialisation - Fix bug introduced in 1906dc3 - forgot to resize the gf in new version of operator = - Fix make_singularity in gf.hpp - clean resize in operator = - update h5 read/write for block gf - changed a bit the general trait to save all the gf. - allows a more general specialization, then a correct for blocks - NOT FINISHED : need to save the block indice for python. How to reread ? Currently it read the blocks names and reconstitute the mesh from it. Is it sufficient ? - clean block constructors - block constructors simplest possible : an int for the number of blocks - rest in free factories. - fixed the generic constructor from GfType for the regular type : only enable iif GfType is ImmutableGreenFunction - multivar. fix linear index in C, and h5 format - linear index now correctly flatten in C mode (was in fortran mode), using a simple reverse of the tuple in the folding. - fix the h5 read write of the multivar fonctions in order to write an array on dimension # variables + dim_target i.e. without flattening the indices of the meshes. Easier for later data analysis, e.g. in Python. - merge matrix/tensor_valued. improve factories - matrix_valued now = tensor_valued<2> (simplifies generic code for h5). - factories_one_var -> factories : this is the generic case ... only a few specialization, code is simpler. - clef expression call with rvalue for this - generalize matrix_proxy to tensor and clean - clean exception catch in tests - exception catching catch in need in test because the silly OS X does not print anything, just "exception occurred". Very convenient for the developer... - BUT, one MUST add return 1, or the make test will pass* !! - --> systematically replace the catch by a macro TRIQS_CATCH_AND_ABORT which return a non zero error code. - exception : curry_and_fourier which does not work at this stage (mesh incompatible). - gf: clean draft of gf 2 times - comment the python interface for the moment. - rm useless tests 2013-10-16 23:55:26 +02:00			`struct target_shape_t {};`
gf : mesh now the class, not a trait. simplify : mesh was a impl trait, make it the class itself. corrected the gf, tests and the cython. 2013-08-24 14:47:47 +02:00
			`template<typename MeshType>`
			`static gf_t make_gf(MeshType && m) {`
			`typename gf_t::data_regular_t A(m.size());`
			`A() =0;`
			`return gf_t (m, std::move(A), nothing(), nothing() ) ;`
			`}`

			`static gf_t make_gf(double wmin, double wmax, size_t n_freq, double beta, statistic_enum S, size_t nt, mesh_kind mk=full_bins) {`
gfs: change the name of the mesh -> gf_mesh for gcc gcc has a pb because the template mesh<Variable,Opt> has the name same as the gf mesh method (!). Clang is fine however on this... Solution : rename the template mesh<...> to gf_mesh... Not very elegant, but ok. 2013-08-27 14:20:50 +02:00			`auto m = gf_mesh<refreq_imtime,Opt>(wmin, wmax, n_freq, beta,S, nt, mk);`
gf : mesh now the class, not a trait. simplify : mesh was a impl trait, make it the class itself. corrected the gf, tests and the cython. 2013-08-24 14:47:47 +02:00			`typename gf_t::data_regular_t A(m.size());`
			`A() =0;`
			`return gf_t (m, std::move(A), nothing(), nothing() ) ;`
			`}`
			`};`

			`} // gfs_implementation`

			`//slices`
gf: clean h5name - _s automatically done for scalar_valued. - add simple reinterpretation of gf scalar to matrix view to easy h5 saving to plot in python 2013-07-29 17:56:31 +02:00			`inline gf_view<refreq,scalar_valued> slice_mesh_imtime (gf_view<refreq_imtime,scalar_valued> g, size_t index) {`
draft of multi-time gf (t,tau), etc... 2013-07-19 13:30:52 +02:00			`auto arr = reinterpret_linear_array(g.mesh(),g.data()); // view it as a 2d array`
refreq_imtime.hpp: bug corrected 2013-07-19 11:33:11 +02:00			`return { std::get<0>(g.mesh().components()), arr(arrays::range(),index), local::tail(1,1), nothing() };`
draft of multi-time gf (t,tau), etc... 2013-07-19 13:30:52 +02:00			`}`

			`}}`
			`#endif`