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dft_tools/triqs/gfs/curry.hpp

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/*******************************************************************************
*
* TRIQS: a Toolbox for Research in Interacting Quantum Systems
*
* Copyright (C) 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/>.
*
******************************************************************************/
#ifndef TRIQS_GF_CURRY_H
#define TRIQS_GF_CURRY_H
#include "./product.hpp"
#ifndef TRIQS_COMPILER_IS_C11_COMPLIANT
#error "This header requires a fully C++11 compliant compiler"
#endif
namespace triqs { namespace gfs {
template<typename F> struct lambda_valued {};
namespace gfs_implementation {
/// --------------------------- data access ---------------------------------
template<typename Opt, typename F, typename M> struct data_proxy<M,lambda_valued<F>,Opt> : data_proxy_lambda<F> {};
/// --------------------------- Factories ---------------------------------
template<typename F, typename Opt, typename ... Ms>
struct factories<cartesian_product<Ms...>, lambda_valued<F>, Opt> {};
/// --------------------------- partial_eval ---------------------------------
// partial_eval<0> (g, 1) returns : x -> g(1,x)
// partial_eval<1> (g, 3) returns : x -> g(x,3)
// a technical trait: from a tuple of mesh, return the mesh (either M if it is a tuple of size 1, or the corresponding cartesian_product<M..>).
template<typename ... Ms> struct cart_prod_impl;
template<typename ... Ms> using cart_prod = typename cart_prod_impl<Ms...>::type;
template<typename ... Ms> struct cart_prod_impl<std::tuple<Ms...>> { using type = cartesian_product<Ms...>;};
template<typename M> struct cart_prod_impl<std::tuple<M>> { typedef M type;}; //using type = M;};
template<typename M0, typename M1, typename ...M> auto rm_tuple_of_size_one(std::tuple<M0,M1,M...> const & t) DECL_AND_RETURN(t);
template<typename M> auto rm_tuple_of_size_one(std::tuple<M> const & t) DECL_AND_RETURN(std::get<0>(t));
template<int ... pos, typename Opt, typename Target, bool B, typename IT, typename ... Ms>
gf_view< typename cart_prod_impl< triqs::tuple::filter_out_t<std::tuple<Ms...>, pos...>>::type ,Target, Opt>
partial_eval(gf_impl< cartesian_product<Ms...>, Target,Opt,B> const & g, IT index) {
// meshes of the returned gf_view : just drop the mesh of the evaluated variables
auto meshes_tuple_partial = triqs::tuple::filter_out<pos...>(g.mesh().components());
// a view of the array of g, with the dimension sizeof...(Ms)
auto arr = reinterpret_linear_array(g.mesh(),g.data());
// now rebuild a tuple of the size sizeof...(Ms), containing the indices and range at the position of evaluated variables.
auto arr_args = triqs::tuple::inverse_filter<sizeof...(Ms),pos...>(index, arrays::range());
// from it, we make a slice of the array of g, corresponding to the data of the returned gf_view
auto arr2 = triqs::tuple::apply(arr, arr_args);
// finally, we build the view on this data.
using r_t = gf_view< cart_prod< triqs::tuple::filter_out_t<std::tuple<Ms...>, pos...>> ,Target, Opt>;
return r_t{ rm_tuple_of_size_one(meshes_tuple_partial), arr2, typename r_t::singularity_non_view_t{}, typename r_t::symmetry_t{} };
}
/// --------------------------- curry ---------------------------------
// curry<0>(g) returns : x-> y... -> g(x,y...)
// curry<1>(g) returns : y-> x,z... -> g(x,y,z...)
// to adapt the partial_eval as a polymorphic lambda (replace by a lambda in c++14)
template<typename Gview, int ... pos> struct curry_polymorphic_lambda {
Gview g;
template<typename ...I> auto operator()(I ... i) const DECL_AND_RETURN(partial_eval<pos...>(g,std::make_tuple(i...)));
};
// curry function ...
template<int ... pos, typename Target, typename Opt, bool B, typename ... Ms>
gf_view<cart_prod< triqs::tuple::filter_t<std::tuple<Ms...>,pos...> >,
lambda_valued<curry_polymorphic_lambda<gf_view<cartesian_product<Ms...>, Target,Opt>,pos...>>,
Opt>
curry (gf_impl<cartesian_product<Ms...>, Target,Opt,B> const & g) {
// pick up the meshed corresponding to the curryed variables
auto meshes_tuple = triqs::tuple::filter<pos...>(g.mesh().components());
// building the view
return {rm_tuple_of_size_one(meshes_tuple),curry_polymorphic_lambda<gf_view<cartesian_product<Ms...>, Target,Opt>, pos ...>{g}, nothing(), nothing()};
//using m_t = gf_mesh< cart_prod< triqs::tuple::filter_t<std::tuple<Ms...>,pos...>>>;
//return {triqs::tuple::apply_construct<m_t>(meshes_tuple),curry_polymorphic_lambda<gf_view<cartesian_product<Ms...>, Target,Opt>, pos ...>{g}, nothing(), nothing()};
};
} // gf_implementation
using gfs_implementation::partial_eval;
using gfs_implementation::curry;
}}
#endif