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dft_tools/triqs/arrays/h5/array_proxy_impl.hpp
Olivier Parcollet f2c7d449cc First commit : triqs libs version 1.0 alpha1
for earlier commits, see TRIQS0.x repository.
2013-07-17 19:24:07 +02:00

161 lines
6.8 KiB
C++

/*******************************************************************************
*
* TRIQS: a Toolbox for Research in Interacting Quantum Systems
*
* Copyright (C) 2011 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_ARRAYS_HDF5_ARRAY_PROXY_IMPL_H
#define TRIQS_ARRAYS_HDF5_ARRAY_PROXY_IMPL_H
//#define TRIQS_ARRAYS_DEBUG_H5_SLICE
#include "../indexmaps/cuboid/domain.hpp"
#include "./group_or_file.hpp"
#include "../impl/sliceable_object.hpp"
#include "../impl/tuple_tools.hpp"
#include <boost/shared_ptr.hpp>
#include <boost/make_shared.hpp>
namespace triqs { namespace arrays {
namespace h5 { template<int Rf> struct array_proxy_option {}; }
namespace Option {
template<class IM2, int Rf> struct Im_Opt_2_Opt<IM2, h5::array_proxy_option<Rf> > { typedef h5::array_proxy_option<Rf> type;};
}
namespace h5 {
template<int Rank, int Rank_full>
class index_system {
public :
static const unsigned int rank= Rank, rank_full = Rank_full;
typedef mini_vector<size_t, Rank> v_type;
typedef mini_vector<size_t, Rank_full> v_type_full;
typedef indexmaps::cuboid::domain<Rank> domain_type;
domain_type const & domain() const { return mydomain;}
index_system (v_type_full const & total_lengths_) {
total_lens_ = total_lengths_; lens_= total_lengths_;
for (size_t i =0; i<rank_full; ++i) stri_[i] = 1;
for (size_t i =0; i<rank; ++i) dims[i] = lens_[i];
mydomain = domain_type (dims);
}
index_system (v_type const & dims_, v_type_full const & total_lengths_, v_type_full const & lengths_,
v_type_full const & strides_, v_type_full const & offset_ ) {
dims = dims_;total_lens_ = total_lengths_; lens_= lengths_; stri_ = strides_; off_=offset_;
mydomain = domain_type (dims);
}
index_system (DataSpace const & ds, bool is_complex) {
int rf = ds.getSimpleExtentNdims();
if ( rf != rank_full + (is_complex ? 1 : 0) ) TRIQS_RUNTIME_ERROR << "H5 : dimension error";
//int ndims = ds.getSimpleExtentDims( &lens_[0], NULL);
ds.getSimpleExtentDims( &lens_[0], NULL);
for (size_t i =0; i<rank; ++i) { dims[i] = lens_[i]; stri_[i] = 1; off_[i]= 0; }
total_lens_=dims;
mydomain = domain_type (dims);
}
template<bool C> DataSpace dataspace() const { return h5::dataspace_from_LS<rank_full,C> (total_lens_, lens_,stri_,off_); }
size_t size() const { size_t _size = 1; for (size_t i =0; i<rank; ++i) _size *= lens_[i]; return _size;}
mini_vector<size_t, rank_full> total_lengths() const { return this->total_lens_;}
mini_vector<size_t, rank_full> lengths() const { return this->lens_;}
mini_vector<size_t, rank_full> strides() const { return this->stri_;}
private:
mini_vector<hsize_t,rank_full> lens_, off_, stri_;
v_type dims;
v_type_full total_lens_;
domain_type mydomain;
};
namespace slicer_impl {
template <bool BC> inline void _check_BC ( int N, int ind, size_t B) { }
template <> inline void _check_BC<true> (int N, int ind, size_t B) {
bool cond = (ind >= 0) && (ind < int(B)); // fix this int ...
if (!cond) TRIQS_ARRAYS_KEY_ERROR << " index "<<N<<" is out of domain: \n " << ind <<" is not within [0,"<< B <<"[\n";
}
template<int Rank_in, int Rank_out, int N,int P, int c, bool BoundCheck> struct slice_calc {
typedef mini_vector<size_t,Rank_in> const & i_type;
typedef mini_vector<size_t,Rank_in > & o_type;
typedef mini_vector<size_t,Rank_out > & os_type;
template< typename ArgsTuple>
static void invoke(i_type li, i_type si, os_type lo_c, o_type lo, o_type so, o_type offset, ArgsTuple const & args ) {
const int dP = boost::is_base_of<typename boost::tuples::element<N,ArgsTuple>::type, range >::type::value ;
one_step(li[N], si[N],lo[N],so[N], offset[N] ,boost::tuples::get<N>(args));
lo_c[P] = lo[N];
slice_calc<Rank_in,Rank_out,N+1,P+dP,c-1, BoundCheck>::invoke(li,si,lo_c,lo,so, offset, args);
}
static void one_step(size_t li, size_t si, size_t & lo, size_t & so, size_t & offset, size_t R){
_check_BC <BoundCheck> (N, R, li);
offset = R; lo =1; so= 1;
}
static void one_step(size_t li, size_t si, size_t & lo, size_t & so, size_t & offset, range R){
_check_BC <BoundCheck> (N, R.first(),li);
_check_BC <BoundCheck> (N, (R.last()==-1 ? li : R.last()) -1 ,li);
lo = ((R.last()==-1 ? li : R.last()) - R.first() + R.step()-1 )/R.step() ; // python behaviour
so = R.step(); offset = R.first() ;
}
};
// stop the recursion
template<int Ri, int Ro, int N, int P, bool BC> struct slice_calc <Ri,Ro,N,P,0,BC> : slice_calc<Ri,Ro,N,P,1,BC> {
template<class T1,class T2,class T3,class T4,class T5,class T6, class T7> static void invoke(T1,T2,T3,T4,T5,T6,T7 ) {}
};
}//namespace slicer_impl
} // h5
namespace indexmaps {
template<int R, int Rf, typename ArgsTuple>
struct slicer < h5::index_system<R,Rf>, ArgsTuple> {
static const unsigned int len = boost::tuples::length<ArgsTuple>::value;
static_assert(len>=R, "Too few arguments in slice");
static_assert(len<=R, "Too many arguments in slice");
static_assert( (R==Rf), "Can not slice array_proxy twice (not implemented)");
static const unsigned int R2 = R - TupleTools::CountHowManyInt<ArgsTuple>::value;
typedef h5::index_system< R2, Rf> return_type;
static return_type invoke ( h5::index_system<R,R> const & X, ArgsTuple args) {
mini_vector<size_t, R2> newdims;
mini_vector<size_t,R> newoffset, newlengths, newstrides;
h5::slicer_impl::slice_calc<R,R2,0,0,R,true>::invoke(X.lengths(),X.strides(),newdims, newlengths,newstrides, newoffset, args);
#ifdef TRIQS_ARRAYS_DEBUG_H5_SLICE
std::cerr<<"-----------------------------------------------"<<std::endl;
std::cerr<<"H5 Slicing "<< X.lengths().to_string()<<X.strides().to_string()<<newlengths.to_string()<<newstrides.to_string()<< newoffset.to_string() << args<<std::endl;
#endif
return return_type(newdims,X.total_lengths(), newlengths,newstrides,newoffset);
};
};
template<int R, int Rf> struct slicer < h5::index_system<R,Rf>, boost::tuple<> > { typedef h5::index_system< R,Rf> return_type;};
}
}}
#endif