/*******************************************************************************
*
* 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 .
*
******************************************************************************/
#ifndef TRIQS_GF_BLOCK_H
#define TRIQS_GF_BLOCK_H
#include "./tools.hpp"
#include "./gf.hpp"
#include "./local/tail.hpp"
#include "./meshes/discrete.hpp"
namespace triqs {
namespace gfs {
struct block_index {};
template struct gf_mesh : discrete_mesh {
typedef discrete_mesh B;
gf_mesh() = default;
gf_mesh(int s) : B(s) {}
gf_mesh(discrete_domain const &d) : B(d) {}
gf_mesh(std::initializer_list const &s) : B(s) {}
};
namespace gfs_implementation {
/// --------------------------- hdf5 ---------------------------------
template struct h5_name {
static std::string invoke() { return "BlockGf"; }
};
template struct h5_rw {
static void write(h5::group gr, gf_const_view g) {
for (size_t i = 0; i < g.mesh().size(); ++i) h5_write(gr, g.mesh().domain().names()[i], g._data[i]);
// h5_write(gr,"symmetry",g._symmetry);
}
template static void read(h5::group gr, gf_impl &g) {
// does not work : need to read the block name and remake the mesh...
g._mesh = gf_mesh(gr.get_all_subgroup_names());
g._data.resize(g._mesh.size());
// if (g._data.size() != g._mesh.size()) TRIQS_RUNTIME_ERROR << "h5 read block gf : number of block mismatch";
for (size_t i = 0; i < g.mesh().size(); ++i) h5_read(gr, g.mesh().domain().names()[i], g._data[i]);
// h5_read(gr,"symmetry",g._symmetry);
}
};
/// --------------------------- data access ---------------------------------
template
struct data_proxy : data_proxy_vector::type> {};
// ------------------------------- Factories --------------------------------------------------
template struct factories {
typedef gf_mesh mesh_t;
typedef gf gf_t;
typedef gf_view gf_view_t;
struct target_shape_t {};
static typename gf_t::data_t make_data(mesh_t const &m, target_shape_t) { return std::vector(m.size()); }
static typename gf_t::singularity_t make_singularity(mesh_t const &m, target_shape_t) {
return {};
}
};
} // gfs_implementation
// ------------------------------- aliases --------------------------------------------------
template using block_gf = gf>;
template using block_gf_view = gf_view>;
template using block_gf_const_view = gf_const_view>;
// ------------------------------- Free Factories for regular type --------------------------------------------------
// from a number and a gf to be copied
template
block_gf make_block_gf(int n, gf const &g) {
auto V = std::vector>{};
for (int i = 0; i < n; ++i) V.push_back(g);
return {{n}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// from a vector of gf (moving directly)
template
block_gf make_block_gf(std::vector> V) {
return {{int(V.size())}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// from a vector of gf : generalized to have a different type of gf in the vector (e.g. views...)
template
block_gf make_block_gf(std::vector const &V) {
auto V2 = std::vector>{};
for (auto const &g : V) V2.push_back(g);
return {{int(V.size())}, std::move(V2), nothing{}, nothing{}, nothing{}};
}
// from a init list of GF with the correct type
template
block_gf make_block_gf(std::initializer_list> const &V) {
return {{int(V.size())}, V, nothing{}, nothing{}, nothing{}};
}
// from vector and a gf to be copied
template
block_gf make_block_gf(std::vector block_names, gf const &g) {
auto V = std::vector>{};
for (int i = 0; i < block_names.size(); ++i) V.push_back(g);
return {{block_names}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// from vector, vector
template
block_gf make_block_gf(std::vector block_names, std::vector> V) {
if (block_names.size() != V.size())
TRIQS_RUNTIME_ERROR << "make_block_gf(vector, vector) : the two vectors do not have the same size !";
return {{block_names}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// from vector, init_list
template
block_gf make_block_gf(std::vector block_names,
std::initializer_list> const &V) {
if (block_names.size() != V.size()) TRIQS_RUNTIME_ERROR << "make_block_gf(vector, init_list) : size mismatch !";
return {{block_names}, V, nothing{}, nothing{}, nothing{}};
}
// ------------------------------- Free Factories for view type --------------------------------------------------
template
gf_view::type::view_type> make_block_gf_view(G0 &&g0, G &&... g) {
auto V = std::vector::type::view_type>{std::forward(g0), std::forward(g)...};
return {{int(V.size())}, std::move(V), nothing{}, nothing{}, nothing{}};
// return { gf_mesh {int(V.size())}, std::move(V), nothing{}, nothing{} } ;
}
template gf_view make_block_gf_view_from_vector(std::vector V) {
return {{int(V.size())}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// for cython proxy only. do not document.
template gf_view make_block_gf_view_from_vector_of_cython_proxy(std::vector V) {
return {{int(V.size())}, std::move(V), nothing{}, nothing{}, nothing{}};
}
// ------------------------------- Extend reinterpret_scalar_valued_gf_as_matrix_valued for block gf ------
template
gf_view, Opt2, IsConst>
reinterpret_scalar_valued_gf_as_matrix_valued(gf_view, Opt2, IsConst> bg) {
std::vector> V;
for (auto &g : bg) V.push_back(reinterpret_scalar_valued_gf_as_matrix_valued(g));
return make_block_gf_view_from_vector(std::move(V));
}
template
gf_const_view, Opt2>
reinterpret_scalar_valued_gf_as_matrix_valued(gf, Opt2> const &bg) {
return reinterpret_scalar_valued_gf_as_matrix_valued(bg());
}
template
gf_view, Opt2>
reinterpret_scalar_valued_gf_as_matrix_valued(gf, Opt2> &bg) {
return reinterpret_scalar_valued_gf_as_matrix_valued(bg());
}
// ------------------------------- Free functions --------------------------------------------------
// a simple function to get the number of blocks
template size_t n_blocks(gf const &g) { return g.mesh().size(); }
template size_t n_blocks(gf_view const &g) { return g.mesh().size(); }
// ------------------------------- an iterator over the blocks --------------------------------------------------
template using __get_target = typename std::remove_reference()[0])>::type;
// iterator
template
class block_gf_iterator
: public boost::iterator_facade, __get_target, boost::forward_traversal_tag, __get_target &> {
friend class boost::iterator_core_access;
typedef typename std::remove_reference::type big_gf_t;
big_gf_t &big_gf;
typedef typename big_gf_t::mesh_t::const_iterator mesh_iterator_t;
mesh_iterator_t mesh_it;
__get_target &dereference() const { return big_gf[*mesh_it]; }
bool equal(block_gf_iterator const &other) const { return ((mesh_it == other.mesh_it)); }
public:
block_gf_iterator(big_gf_t &bgf, bool at_end = false) : big_gf(bgf), mesh_it(&big_gf.mesh(), at_end) {}
void increment() { ++mesh_it; }
bool at_end() const { return mesh_it.at_end(); }
};
//------------
template
block_gf_iterator> begin(gf_impl &bgf) {
return {bgf, false};
}
//------------
template
block_gf_iterator> end(gf_impl &bgf) {
return {bgf, true};
}
//----- const iterator
template
class block_gf_const_iterator
: public boost::iterator_facade, __get_target, boost::forward_traversal_tag, __get_target const &> {
friend class boost::iterator_core_access;
typedef typename std::remove_reference::type big_gf_t;
big_gf_t const &big_gf;
typedef typename big_gf_t::mesh_t::const_iterator mesh_iterator_t;
mesh_iterator_t mesh_it;
__get_target const &dereference() const { return big_gf[*mesh_it]; }
bool equal(block_gf_const_iterator const &other) const { return ((mesh_it == other.mesh_it)); }
public:
block_gf_const_iterator(big_gf_t const &bgf, bool at_end = false) : big_gf(bgf), mesh_it(&big_gf.mesh(), at_end) {}
void increment() { ++mesh_it; }
bool at_end() const { return mesh_it.at_end(); }
};
template
block_gf_const_iterator> begin(gf_impl const &bgf) {
return {bgf, false};
}
template
block_gf_const_iterator> end(gf_impl const &bgf) {
return {bgf, true};
}
template
block_gf_const_iterator> cbegin(gf_impl const &bgf) {
return {bgf, false};
}
template
block_gf_const_iterator> cend(gf_impl const &bgf) {
return {bgf, true};
}
}
}
#endif