jiri
/
LA_library
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

*** empty log message ***

This commit is contained in:
jiri 2019-11-12 23:52:44 +00:00
parent f8ac9262c7
commit 40469916fa
4 changed files with 143 additions and 20 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

3
ChangeLog
View File

@ -1,3 +1,6 @@
12.11.2019 fourindex_dense with nosymetry implemented
12.11.2019 fourindex.cc created for template specializations
12.11.2019 fourindex optional scaling and terminator
11.11.2019 fourindex for twobody integrals with reduced symmetry 11.11.2019 fourindex for twobody integrals with reduced symmetry
08.11.2019 Conversion constructor for NRMat_from1(NRSMat_from1) 08.11.2019 Conversion constructor for NRMat_from1(NRSMat_from1)
31.03.2019 AUTOCONF files adapted for using MKL as first option 31.03.2019 AUTOCONF files adapted for using MKL as first option

6
Makefile.am
View File

@ -1,6 +1,6 @@
lib_LTLIBRARIES = libla.la lib_LTLIBRARIES = libla.la
include_HEADERS = fortran.h cuda_la.h auxstorage.h davidson.h laerror.h mat.h qsort.h vec.h bisection.h diis.h la.h noncblas.h smat.h bitvector.h fourindex.h la_traits.h nonclass.h sparsemat.h sparsesmat.h csrmat.h conjgrad.h gmres.h matexp.h permutation.h include_HEADERS = fortran.h cuda_la.h auxstorage.h davidson.h laerror.h mat.h qsort.h vec.h bisection.h diis.h la.h noncblas.h smat.h bitvector.h fourindex.h la_traits.h nonclass.h sparsemat.h sparsesmat.h csrmat.h conjgrad.h gmres.h matexp.h permutation.h
libla_la_SOURCES = vec.cc mat.cc smat.cc sparsemat.cc sparsesmat.cc csrmat.cc laerror.cc noncblas.cc bitvector.cc strassen.cc nonclass.cc cuda_la.cc libla_la_SOURCES = vec.cc mat.cc smat.cc sparsemat.cc sparsesmat.cc csrmat.cc laerror.cc noncblas.cc bitvector.cc strassen.cc nonclass.cc cuda_la.cc fourindex.cc
check_PROGRAMS = t test check_PROGRAMS = t test
t_SOURCES = t.cc t2.cc t_SOURCES = t.cc t2.cc
test_SOURCES = test.cc test_SOURCES = test.cc
@ -22,12 +22,14 @@ AM_CXXFLAGS += -g
AM_CXXFLAGS += $(OPTIMIZEOPT) $(CUDAOPT) $(FORINTOPT) $(DEBUGOPT) $(MATPTROPT) AM_CXXFLAGS += $(OPTIMIZEOPT) $(CUDAOPT) $(FORINTOPT) $(DEBUGOPT) $(MATPTROPT)
AM_CXXFLAGS += -DNO_STRASSEN -DFORTRAN_ AM_CXXFLAGS += -DNO_STRASSEN -DFORTRAN_
AM_CXXFLAGS += $(CBLASOPT) $(CLAPACKOPT) AM_CXXFLAGS += $(CBLASOPT) $(CLAPACKOPT)
AM_CXXFLAGS += $(MKLOPT)
AM_CXXFLAGS += $(TRACEBACKOPT) AM_CXXFLAGS += $(TRACEBACKOPT)
#AM_LDFLAGS += .libs/libla.a #AM_LDFLAGS += .libs/libla.a
AM_LDFLAGS += $(CBLASLIB) AM_LDFLAGS += $(CBLASLIB)
AM_LDFLAGS += $(BLASLIB) AM_LDFLAGS += $(BLASLIB)
AM_LDFLAGS += $(ATLASLIB) AM_LDFLAGS += $(ATLASLIB)
AM_LDFLAGS += $(MKLLIB)
AM_LDFLAGS += $(CUDALIBS) AM_LDFLAGS += $(CUDALIBS)
AM_LDFLAGS += $(TRACEBACKLIB) AM_LDFLAGS += $(TRACEBACKLIB)

55
fourindex.cc Normal file
View File

@ -0,0 +1,55 @@
/*
LA: linear algebra C++ interface library
Copyright (C) 2008-2019 Jiri Pittner <jiri.pittner@jh-inst.cas.cz> or <jiri@pittnerovi.com>
This program 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.
This program 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 this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "fourindex.h"
namespace LA {
template <>
void fourindex<unsigned char,double>::fscanf(FILE *ff)
{
int i,j,k,l;
double elem;
if(5!= ::fscanf(ff,"%lf %d %d %d %d",&elem,&i,&j,&k,&l)) laerror("read error in fourindex::fscanf");
while(i!=terminator&&j!=terminator&&k!=terminator&&l!=terminator)
{
add(i,j,k,l,elem);
if(5!= ::fscanf(ff,"%lf %d %d %d %d",&elem,&i,&j,&k,&l)) laerror("read error in fourindex::fscanf");
}
}
template <>
void fourindex<unsigned char,double>::fprintf(FILE *f, char *format) const
{
fourindex<unsigned char,double>::iterator it=this->begin(),end=this->end();
while(it!=end)
{
::fprintf(f,format,it->elem,it->index.indiv.i,it->index.indiv.j,it->index.indiv.k,it->index.indiv.l);
++it;
}
::fprintf(f,format,0.,0,0,0,0);
}
/***************************************************************************//**
* forced instantization in the corresponding object file
******************************************************************************/
template class fourindex<unsigned char,double>;
template class fourindex_ext<unsigned char,double>;
template class fourindex_dense<nosymmetry,double,unsigned char>;
}

99
fourindex.h
View File

@ -1,6 +1,6 @@
/* /*
LA: linear algebra C++ interface library LA: linear algebra C++ interface library
Copyright (C) 2008 Jiri Pittner <jiri.pittner@jh-inst.cas.cz> or <jiri@pittnerovi.com> Copyright (C) 2008-2019 Jiri Pittner <jiri.pittner@jh-inst.cas.cz> or <jiri@pittnerovi.com>
This program is free software: you can redistribute it and/or modify This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by it under the terms of the GNU General Public License as published by
@ -19,6 +19,7 @@
#ifndef _fourindex_included #ifndef _fourindex_included
#define _fourindex_included #define _fourindex_included
#include <iostream> #include <iostream>
#include <stdio.h>
#include <string.h> #include <string.h>
#include <sys/types.h> #include <sys/types.h>
#include <sys/vfs.h> #include <sys/vfs.h>
@ -108,7 +109,7 @@ __attribute__((packed))
typedef enum { typedef enum {
undefined_symmetry=-1, undefined_symmetry=-1,
nosymmetry=0, nosymmetry=0,
twoelectronrealmullikan=1, twoelectronrealmullikan=1, twoelectronrealmullikanAA=1,
twoelectronrealdirac=2, twoelectronrealdirac=2,
T2ijab_aces=3, T2ijab_aces=3,
trdm2AA=3, trdm2AA=3,
@ -147,6 +148,13 @@ void symmetry_faktor(const fourindexsymtype symmetry,const union packed_index<I>
{ {
switch(symmetry) switch(symmetry)
{ {
case twoelectronrealmullikanreducedsymAA:
if(index.indiv.i==index.indiv.j && index.indiv.k==index.indiv.l) elem*=.5;
if(index.indiv.i==index.indiv.k && index.indiv.j==index.indiv.l) elem*=.5;
break;
case twoelectronrealmullikanreducedsymAB:
if(index.indiv.i==index.indiv.j && index.indiv.k==index.indiv.l) elem*=.5;
break;
case antisymtwoelectronrealdirac: case antisymtwoelectronrealdirac:
case antisymtwoelectronrealdiracAB: case antisymtwoelectronrealdiracAB:
laerror("not implemented"); laerror("not implemented");
@ -165,7 +173,7 @@ switch(symmetry)
case T2ijab_aces: break; //result will automatically vanish due to generated antisymmetry; i!=a from principle case T2ijab_aces: break; //result will automatically vanish due to generated antisymmetry; i!=a from principle
case T2IjAb_aces: break; //no actual symmetry case T2IjAb_aces: break; //no actual symmetry
case nosymmetry: break; case nosymmetry: break;
default: laerror("illegal symmetry"); default: laerror("illegal symmetry or symmetry-redundant scaling factor not implemented");
} }
} }
@ -177,6 +185,8 @@ protected:
I nn; I nn;
int *count; int *count;
matel4<I,T> *list; matel4<I,T> *list;
I terminator;
bool doscaling;
private: private:
void deletelist(); void deletelist();
void copylist(const matel4<I,T> *l); void copylist(const matel4<I,T> *l);
@ -198,10 +208,14 @@ public:
const matel4<I,T> * operator->() const {return p;} const matel4<I,T> * operator->() const {return p;}
const matel4<I,T> & operator*() const {return *p;} const matel4<I,T> & operator*() const {return *p;}
}; };
void setterminator(const I terminator0) {terminator=terminator0;}
I getterminator() const {return terminator;}
void setscaling(const bool doscaling0) {doscaling=doscaling0;}
iterator begin() const {return list;} iterator begin() const {return list;}
iterator end() const {return NULL;} iterator end() const {return NULL;}
//permiterator ... iterates also over all permutations, with a possibly scaled matrix element or skips permutations yielding equivalent result //permiterator ... iterates also over all permutations, with a possibly scaled matrix element for redundant results of the permutations
//it is assumed the original fourindex is the symmetry-reduced petite list, then the results of piterator contributions can be accumulated
//has to take into account the symmetry type of the fourindex //has to take into account the symmetry type of the fourindex
class piterator { class piterator {
private: private:
@ -209,6 +223,7 @@ public:
matel4<I,T> *p; matel4<I,T> *p;
matel4<I,T> my; matel4<I,T> my;
int permindex; int permindex;
bool doscaling;
void setup(void) //make a copy of *p to my with scaled element and anti/permuted indices void setup(void) //make a copy of *p to my with scaled element and anti/permuted indices
{ {
if(symmetry==undefined_symmetry) laerror("fourindex symmetry has not been set"); if(symmetry==undefined_symmetry) laerror("fourindex symmetry has not been set");
@ -218,17 +233,17 @@ public:
my.elem = p->elem * fourindex_permutations[symmetry][permindex][4]; my.elem = p->elem * fourindex_permutations[symmetry][permindex][4];
//now treat the redundancy due to possibly equal indices by a scaling factor //now treat the redundancy due to possibly equal indices by a scaling factor
//if the processing of individual term becomes very costly, an alternative would be to screen permutations yielding identical result //if the processing of individual term becomes very costly, an alternative would be to screen permutations yielding identical result
symmetry_faktor(symmetry, p->index, my.elem); if(doscaling) symmetry_faktor(symmetry, p->index, my.elem);
}; };
public: public:
piterator() {}; piterator() {};
piterator(matel4<I,T> *pp): symmetry(nosymmetry),p(pp),permindex(0){}; piterator(matel4<I,T> *pp): symmetry(nosymmetry),p(pp),permindex(0),doscaling(true){};
~piterator() {}; ~piterator() {};
piterator(const fourindex &x): symmetry(x.symmetry),p(x.list),permindex(0) {setup();}; piterator(const fourindex &x): symmetry(x.symmetry),p(x.list),permindex(0),doscaling(x.doscaling) {setup();};
piterator& operator++() {if(++permindex>=fourindex_permnumbers[symmetry]) {permindex=0; p=p->next;} setup(); return *this;} piterator& operator++() {if(++permindex>=fourindex_permnumbers[symmetry]) {permindex=0; p=p->next;} setup(); return *this;}
const matel4<I,T> & operator*() const {return my;} const matel4<I,T> & operator*() const {return my;}
const matel4<I,T> * operator->() const {return &my;} const matel4<I,T> * operator->() const {return &my;}
piterator operator++(int) {laerror("postincrement not possible on permute-iterator");} piterator operator++(int) {laerror("postincrement not possible on permute-iterator"); return *this;}
bool operator!=(const piterator &rhs) const {return p!=rhs.p;} //should only be used for comparison with pend() bool operator!=(const piterator &rhs) const {return p!=rhs.p;} //should only be used for comparison with pend()
bool end(void) {return !p;} bool end(void) {return !p;}
bool notend(void) {return p;} bool notend(void) {return p;}
@ -237,8 +252,8 @@ public:
piterator pend() const {return piterator(NULL);}//inefficient, use end() or notend() instead piterator pend() const {return piterator(NULL);}//inefficient, use end() or notend() instead
//constructors etc. //constructors etc.
inline fourindex() :symmetry(undefined_symmetry),nn(0),count(NULL),list(NULL) {}; inline fourindex() :symmetry(undefined_symmetry),nn(0),count(NULL),list(NULL),terminator(-1),doscaling(true) {};
inline fourindex(const I n) :symmetry(undefined_symmetry),nn(n),count(new int(1)),list(NULL) {}; inline fourindex(const I n, const fourindexsymtype symmetry0=undefined_symmetry, const I terminator0= -1, const bool doscaling0=true) :nn(n),count(new int(1)),list(NULL),symmetry(symmetry0),terminator(terminator0),doscaling(doscaling0) {};
fourindex(const fourindex &rhs); //copy constructor fourindex(const fourindex &rhs); //copy constructor
inline int getcount() const {return count?*count:0;} inline int getcount() const {return count?*count:0;}
fourindex & operator=(const fourindex &rhs); fourindex & operator=(const fourindex &rhs);
@ -267,6 +282,8 @@ public:
{matel4<I,T> *ltmp= new matel4<I,T>; ltmp->next=list; list=ltmp; memcpy(&list->index.packed, &rhs.index, sizeof(union packed_index<I>)); list->elem=rhs.elem;} {matel4<I,T> *ltmp= new matel4<I,T>; ltmp->next=list; list=ltmp; memcpy(&list->index.packed, &rhs.index, sizeof(union packed_index<I>)); list->elem=rhs.elem;}
unsigned long put(int fd,bool withattr=true) const; unsigned long put(int fd,bool withattr=true) const;
unsigned long get(int fd,bool withattr=true); unsigned long get(int fd,bool withattr=true);
void fscanf(FILE *f); //C-style formatted IO
void fprintf(FILE *f, char *format) const;
}; };
@ -292,6 +309,8 @@ protected:
unsigned int nread; unsigned int nread;
fourindexsymtype symmetry; fourindexsymtype symmetry;
I nn; I nn;
bool doscaling;
I terminator;
//methods //methods
void tryread() const void tryread() const
@ -315,8 +334,11 @@ protected:
public: public:
void setterminator(const I terminator0) {terminator=terminator0;}
I getterminator() const {return terminator;}
void setscaling(const bool doscaling0) {doscaling=doscaling0;}
void resize(I n) {nn=n;} void resize(I n) {nn=n;}
fourindex_ext(const int file, const fourindexsymtype s=undefined_symmetry, const I n=0, const unsigned int b=1024) :current(NULL),fd(file),nread(0),symmetry(s),nn(n) fourindex_ext(const int file, const fourindexsymtype s=undefined_symmetry, const I n=0, const unsigned int b=1024, const I terminator0= -1, const bool doscaling0= true) :current(NULL),fd(file),nread(0),symmetry(s),nn(n)
{ {
struct statfs sfs; struct statfs sfs;
struct stat64 sf; struct stat64 sf;
@ -334,6 +356,8 @@ public:
buffer = (matel4stored<I,T> *) buf; buffer = (matel4stored<I,T> *) buf;
mlock(buf,bufsize); //ignore error when not root, hope we will not be paged out anyway mlock(buf,bufsize); //ignore error when not root, hope we will not be paged out anyway
bufsize /= sizeof(matel4stored<I,T>); bufsize /= sizeof(matel4stored<I,T>);
terminator=terminator0;
doscaling=doscaling0;
} }
~fourindex_ext() {if(buffer0) delete[] buffer0;} ~fourindex_ext() {if(buffer0) delete[] buffer0;}
void setsymmetry(fourindexsymtype s) {symmetry=s;}; void setsymmetry(fourindexsymtype s) {symmetry=s;};
@ -384,7 +408,7 @@ public:
~iterator() {}; ~iterator() {};
bool operator!=(const iterator &rhs) const {return base!=rhs.base;} //should only be used for comparison with end() bool operator!=(const iterator &rhs) const {return base!=rhs.base;} //should only be used for comparison with end()
iterator &operator++() {if(base) base->next(); if(base->eof()) base=NULL; return *this;} iterator &operator++() {if(base) base->next(); if(base->eof()) base=NULL; return *this;}
iterator operator++(int) {laerror("postincrement not possible");} iterator operator++(int) {laerror("postincrement not possible"); return *this;}
const matel4stored<I,T> * operator->() const {return base->current;} const matel4stored<I,T> * operator->() const {return base->current;}
const matel4stored<I,T> & operator*() const {return *base->current;} const matel4stored<I,T> & operator*() const {return *base->current;}
bool notNULL() const {return base;} bool notNULL() const {return base;}
@ -411,7 +435,7 @@ public:
my.elem = it->elem * fourindex_permutations[base->symmetry][permindex][4]; my.elem = it->elem * fourindex_permutations[base->symmetry][permindex][4];
//redundancy due to possibly equal indices //redundancy due to possibly equal indices
//if the processing of individual term becomes very costly, an alternative would be to screen permutations yielding identical result //if the processing of individual term becomes very costly, an alternative would be to screen permutations yielding identical result
symmetry_faktor(base->symmetry, it->index, my.elem); if(base->doscaling) symmetry_faktor(base->symmetry, it->index, my.elem);
}; };
public: public:
piterator() {}; piterator() {};
@ -420,7 +444,7 @@ public:
~piterator() {}; ~piterator() {};
bool operator!=(const piterator &rhs) const {return base!=rhs.base;} //should only be used for comparison with end() bool operator!=(const piterator &rhs) const {return base!=rhs.base;} //should only be used for comparison with end()
piterator &operator++() {if(++permindex>=fourindex_permnumbers[base->symmetry]) {permindex=0; ++it;} if(it.notNULL()) setup(); else base=NULL; return *this;} piterator &operator++() {if(++permindex>=fourindex_permnumbers[base->symmetry]) {permindex=0; ++it;} if(it.notNULL()) setup(); else base=NULL; return *this;}
piterator operator++(int) {laerror("postincrement not possible");} piterator operator++(int) {laerror("postincrement not possible"); return *this;}
const matel4<I,T> * operator->() const {return &my;} const matel4<I,T> * operator->() const {return &my;}
const matel4<I,T> & operator*() const {return my;} const matel4<I,T> & operator*() const {return my;}
bool end(void) {return !base;} bool end(void) {return !base;}
@ -504,6 +528,8 @@ if(! &rhs) laerror("fourindex copy constructor with NULL argument");
if(rhs.list&&!rhs.count) laerror("some inconsistency in fourindex contructors or assignments"); if(rhs.list&&!rhs.count) laerror("some inconsistency in fourindex contructors or assignments");
list=rhs.list; list=rhs.list;
if(list) {count=rhs.count; (*count)++;} else count=new int(1); //make the matrix defined, but empty and not shared if(list) {count=rhs.count; (*count)++;} else count=new int(1); //make the matrix defined, but empty and not shared
terminator=rhs.terminator;
doscaling=rhs.doscaling;
} }
@ -518,6 +544,8 @@ fourindex<I,T> & fourindex<I,T>::operator=(const fourindex<I,T> &rhs)
if(--(*count) ==0) {deletelist(); delete count;} // old stuff obsolete if(--(*count) ==0) {deletelist(); delete count;} // old stuff obsolete
list=rhs.list; list=rhs.list;
nn=rhs.nn; nn=rhs.nn;
terminator=rhs.terminator;
doscaling=rhs.doscaling;
if(list) count=rhs.count; else count= new int(0); //make the matrix defined, but empty and not shared, count will be incremented below if(list) count=rhs.count; else count= new int(0); //make the matrix defined, but empty and not shared, count will be incremented below
if(count) (*count)++; if(count) (*count)++;
} }
@ -622,6 +650,7 @@ while(l)
return n; return n;
} }
template <class I, class T> template <class I, class T>
std::ostream& operator<<(std::ostream &s, const fourindex_ext<I,T> &x) std::ostream& operator<<(std::ostream &s, const fourindex_ext<I,T> &x)
{ {
@ -634,7 +663,7 @@ std::ostream& operator<<(std::ostream &s, const fourindex_ext<I,T> &x)
s << (typename LA_traits_io<I>::IOtype)it->index.indiv.i << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.j<< ' ' <<(typename LA_traits_io<I>::IOtype)it->index.indiv.k << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.l << ' ' << (typename LA_traits_io<T>::IOtype) it->elem << '\n'; s << (typename LA_traits_io<I>::IOtype)it->index.indiv.i << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.j<< ' ' <<(typename LA_traits_io<I>::IOtype)it->index.indiv.k << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.l << ' ' << (typename LA_traits_io<T>::IOtype) it->elem << '\n';
++it; ++it;
} }
s << "-1 -1 -1 -1 0.\n"; s << (typename LA_traits_io<I>::IOtype) x.getterminator() << ' ' << (typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' <<(typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' << (typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' << (typename LA_traits_io<T>::IOtype) 0 << '\n';
return s; return s;
} }
@ -652,7 +681,7 @@ std::ostream& operator<<(std::ostream &s, const fourindex<I,T> &x)
s << (typename LA_traits_io<I>::IOtype)it->index.indiv.i << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.j<< ' ' <<(typename LA_traits_io<I>::IOtype)it->index.indiv.k << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.l << ' ' << (typename LA_traits_io<T>::IOtype) it->elem << '\n'; s << (typename LA_traits_io<I>::IOtype)it->index.indiv.i << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.j<< ' ' <<(typename LA_traits_io<I>::IOtype)it->index.indiv.k << ' ' << (typename LA_traits_io<I>::IOtype)it->index.indiv.l << ' ' << (typename LA_traits_io<T>::IOtype) it->elem << '\n';
++it; ++it;
} }
s << "-1 -1 -1 -1 0.\n"; s << (typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' << (typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' <<(typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' << (typename LA_traits_io<I>::IOtype)x.getterminator() << ' ' << (typename LA_traits_io<T>::IOtype) 0 << '\n';
return s; return s;
} }
@ -665,7 +694,7 @@ std::istream& operator>>(std::istream &s, fourindex<I,T> &x)
s >> n ; s >> n ;
x.resize(n); x.resize(n);
s >> i >> j >>k >>l; s >> i >> j >>k >>l;
while(i!= (typename LA_traits_io<I>::IOtype)-1 && j!= (typename LA_traits_io<I>::IOtype)-1 && k != (typename LA_traits_io<I>::IOtype)-1 && l!= (typename LA_traits_io<I>::IOtype)-1) while(i!= (typename LA_traits_io<I>::IOtype)x.getterminator() && j!= (typename LA_traits_io<I>::IOtype)x.getterminator() && k != (typename LA_traits_io<I>::IOtype)x.getterminator() && l!= (typename LA_traits_io<I>::IOtype)x.getterminator())
{ {
s>>elem; s>>elem;
x.add((I)i,(I)j,(I)k,(I)l,(T)elem); x.add((I)i,(I)j,(I)k,(I)l,(T)elem);
@ -684,7 +713,7 @@ std::istream& operator>>(std::istream &s, fourindex_ext<I,T> &x)
typename LA_traits_io<T>::IOtype elem; typename LA_traits_io<T>::IOtype elem;
s >> i >> j >>k >>l; s >> i >> j >>k >>l;
while(i!= (typename LA_traits_io<I>::IOtype)-1 && j!= (typename LA_traits_io<I>::IOtype)-1 && k != (typename LA_traits_io<I>::IOtype)-1 && l!= (typename LA_traits_io<I>::IOtype)-1) while(i!= (typename LA_traits_io<I>::IOtype)x.getterminator() && j!= (typename LA_traits_io<I>::IOtype)x.getterminator() && k != (typename LA_traits_io<I>::IOtype)x.getterminator() && l!= (typename LA_traits_io<I>::IOtype)x.getterminator())
{ {
s>>elem; s>>elem;
x.put((I)i,(I)j,(I)k,(I)l,(T)elem); x.put((I)i,(I)j,(I)k,(I)l,(T)elem);
@ -919,6 +948,40 @@ int J = SMat_index_1(k,l);
return NRSMat<T>::v[SMat_index(I,J)]; return NRSMat<T>::v[SMat_index(I,J)];
} }
template<class T, class I>
class fourindex_dense<nosymmetry,T,I> : public NRMat<T> {
protected:
unsigned int nn;
friend class explicit_t2;
public:
fourindex_dense(): NRMat<T>() {nn=0;};
void resize(const int nnn) {nn=nnn; (*this).NRMat<T>::resize(nn*nn,nn*nn);};
explicit fourindex_dense(const int nnn): NRMat<T>(nnn*nnn,nnn*nnn) {nn=nnn;};
inline T& operator() (unsigned int i, unsigned int j, unsigned int a, unsigned int b)
{
#ifdef DEBUG
if(i<1||i>nn ||j<1||j>nn|| a<1||a>nn||b<1||b>nn) laerror("nosymmetry fourindex out of range");
if (!NRMat<T>::v) laerror("access to unallocated fourindex_dense");
#endif
return (*this).NRMat<T>::operator() ((j-1)*nn+i-1,(b-1)*nn+a-1);
}
inline const T& operator() (unsigned int i, unsigned int j, unsigned int a, unsigned int b) const
{
#ifdef DEBUG
if(i<1||i>nn ||j<1||j>nn|| a<1||a>nn||b<1||b>nn) laerror("nosymmetry fourindex out of range");
if (!NRMat<T>::v) laerror("access to unallocated fourindex_dense");
#endif
return (*this).NRMat<T>::operator() ((j-1)*nn+i-1,(b-1)*nn+a-1);
}
void print(std::ostream &out) const
{
unsigned int i,j,a,b;
for(i=1; i<=nn; ++i) for(j=1; j<=nn; ++j) for(a=1; a<=nn; ++a) for(b=1; b<=nn; ++b) out << i<<" "<<j<<" "<<a<<" "<<b<<" "<<(*this)(i,j,a,b)<<std::endl;
}
};
//access to spin-blocks of T2 amplitudes in aces storage order //access to spin-blocks of T2 amplitudes in aces storage order
//both occupied and virtual indices start from 1 //both occupied and virtual indices start from 1