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dft_tools/triqs/gfs/imfreq.hpp
Olivier Parcollet 7cf7d09c77 Fix #112 and put back g +=/-= matrix for imfreq
- The issue comes from the fact that the default generated
  += and co by the Python API is the one for immutable types, like int.
- Indeed, in python, for an int :
  x=1
  id(x)
  140266967205832
  x+=1
  id(x)
  140266967205808
- For a mutable type, like a gf, it is necessary to
  add explicitly the xxx_inplace_add functions.
- Added :
   - the generation of the inplace_xxx functions
   - a method in class_ in the wrapper generator that
     deduce all += operator from the + operators.
   - this assumes that the +=, ... are defined in C++.
   - The generation of such operators are optional, with option
     with_inplace_operators in the arithmetic flag.
- Also, added the overload g += M and g -= M for
  g : GfImfreq, M a complex matrix.
  Mainly for legacy Python codes.
2014-09-06 19:07:34 +02:00

183 lines
7.3 KiB
C++

/*******************************************************************************
*
* TRIQS: a Toolbox for Research in Interacting Quantum Systems
*
* Copyright (C) 2012-2013 by 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/>.
*
******************************************************************************/
#pragma once
#include "./tools.hpp"
#include "./gf.hpp"
#include "./local/tail.hpp"
#include "./local/no_tail.hpp"
#include "./meshes/matsubara_freq.hpp"
#include "./evaluators.hpp"
namespace triqs {
namespace gfs {
struct imfreq {};
template <typename Opt> struct gf_mesh<imfreq, Opt> : matsubara_freq_mesh {
template <typename... T> gf_mesh(T &&... x) : matsubara_freq_mesh(std::forward<T>(x)...) {}
//using matsubara_freq_mesh::matsubara_freq_mesh;
};
namespace gfs_implementation {
// singularity
template <> struct singularity<imfreq, matrix_valued, void> {
using type = local::tail;
};
template <> struct singularity<imfreq, scalar_valued, void> {
using type = local::tail;
};
// h5 name
template <typename Opt> struct h5_name<imfreq, matrix_valued, Opt> {
static std::string invoke() { return "ImFreq"; }
};
/// --------------------------- evaluator ---------------------------------
// simple evaluation : take the point on the grid...
template <> struct evaluator_fnt_on_mesh<imfreq> {
long n;
double w;
evaluator_fnt_on_mesh() = default;
template <typename MeshType> evaluator_fnt_on_mesh(MeshType const &m, long p) { n = p; w=1; }
template <typename MeshType> evaluator_fnt_on_mesh(MeshType const &m, matsubara_freq const &p) {
if ((p.n >= m.first_index()) && (p.n < m.size()+m.first_index())) {w=1; n =p.n;}
else {w=0; n=0;}
}
template <typename F> auto operator()(F const &f) const DECL_AND_RETURN(w*f(n));
};
// ------------- evaluator -------------------
// handle the case where the matsu. freq is out of grid...
template <typename Target, typename Opt> struct evaluator<imfreq, Target, Opt> {
static constexpr int arity = 1;
private:
template <typename G> int sh(G const * g) const { return (g->mesh().domain().statistic == Fermion ? 1 : 0);}
// dispatch for 2x2 cases : matrix/scalar and tail/no_tail ( true means no_tail)
template <typename G>
std::complex<double> _call_impl(G const *g, matsubara_freq const &f, scalar_valued, std::false_type) const {
if (g->mesh().positive_only()){//only positive Matsubara frequencies
if ((f.n >= 0) && (f.n < g->mesh().size())) return (*g)[f.n];
if ((f.n < 0) && ((-f.n-sh(g)) < g->mesh().size())) return conj((*g)[-f.n-sh(g)]);
}
else{
if ((f.n >= g->mesh().first_index()) && (f.n < g->mesh().size()+g->mesh().first_index())) return (*g)[f.n];
}
return g->singularity().evaluate(f)(0, 0);
}
template <typename G>
std::complex<double> _call_impl(G const *g, matsubara_freq const &f, scalar_valued, std::true_type) const {
if (g->mesh().positive_only()){//only positive Matsubara frequencies
if ((f.n >= 0) && (f.n < g->mesh().size())) return (*g)[f.n];
if ((f.n < 0) && ((-f.n-sh(g)) < g->mesh().size())) return conj((*g)[-f.n-sh(g)]);
}
else{
if ((f.n >= g->mesh().first_index()) && (f.n < g->mesh().size()+g->mesh().first_index())) return (*g)[f.n];
}
return 0;
}
template <typename G>
arrays::matrix_const_view<std::complex<double>> _call_impl(G const *g, matsubara_freq const &f, matrix_valued,
std::false_type) const {
if (g->mesh().positive_only()){//only positive Matsubara frequencies
if ((f.n >= 0) && (f.n < g->mesh().size())) return (*g)[f.n]();
if ((f.n < 0) && ((-f.n-sh(g)) < g->mesh().size()))
return arrays::matrix<std::complex<double>>{conj((*g)[-f.n-sh(g)]())};
}
else{
if ((f.n >= g->mesh().first_index()) && (f.n < g->mesh().size()+g->mesh().first_index())) return (*g)[f.n];
}
return g->singularity().evaluate(f);
}
template <typename G>
arrays::matrix_const_view<std::complex<double>> _call_impl(G const *g, matsubara_freq const &f, matrix_valued,
std::true_type) const {
if (g->mesh().positive_only()){//only positive Matsubara frequencies
if ((f.n >= 0) && (f.n < g->mesh().size())) return (*g)[f.n]();
if ((f.n < 0) && ((-f.n-sh(g)) < g->mesh().size()))
return arrays::matrix<std::complex<double>>{conj((*g)[-f.n-sh(g)]())};
}
else{
if ((f.n >= g->mesh().first_index()) && (f.n < g->mesh().size()+g->mesh().first_index())) return (*g)[f.n];
}
auto r = arrays::matrix<std::complex<double>>{get_target_shape(*g)};
r() = 0;
return r;
}
// does not work on gcc 4.8.1 ???
/* template <typename G>
auto operator()(G const *g, matsubara_freq const &f) const
DECL_AND_RETURN(_call_impl(g, f, Target{}, std::integral_constant<bool, std::is_same<Opt, no_tail>::value>{}));
*/
public:
template <typename G>
typename std::conditional<std::is_same<Target, matrix_valued>::value, arrays::matrix_const_view<std::complex<double>>,
std::complex<double>>::type
operator()(G const *g, matsubara_freq const &f) const {
return _call_impl(g, f, Target{}, std::integral_constant<bool, std::is_same<Opt, no_tail>::value>{});
}
// int -> replace by matsubara_freq
template <typename G> auto operator()(G const *g, int n) const DECL_AND_RETURN((*g)(matsubara_freq(n,g->mesh().domain().beta,g->mesh().domain().statistic)));
#ifdef __clang__
// to generate a clearer error message ? . Only ok on clang ?
template <int n> struct error {
static_assert(n > 0, "Green function cannot be evaluated on a complex number !");
};
template <typename G> error<0> operator()(G const *g, std::complex<double>) const {
return {};
}
#endif
template <typename G> typename G::singularity_t const &operator()(G const *g, freq_infty const &) const {
return g->singularity();
}
};
/// --------------------------- data access ---------------------------------
template <typename Opt> struct data_proxy<imfreq, matrix_valued, Opt> : data_proxy_array<std::complex<double>, 3> {};
template <typename Opt> struct data_proxy<imfreq, scalar_valued, Opt> : data_proxy_array<std::complex<double>, 1> {};
} // gfs_implementation
// specific operations (for legacy python code).
// +=, -= with a matrix
inline void operator+=(gf_view<imfreq> g, arrays::matrix<std::complex<double>> m) {
for (int u = 0; u < first_dim(g.data()); ++u) g.data()(u, arrays::ellipsis()) += m;
g.singularity()(0) += m;
}
inline void operator-=(gf_view<imfreq> g, arrays::matrix<std::complex<double>> m) {
for (int u = 0; u < first_dim(g.data()); ++u) g.data()(u, arrays::ellipsis()) -= m;
g.singularity()(0) -= m;
}
}
}