/* LA: linear algebra C++ interface library Copyright (C) 2024 Jiri Pittner or 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 . */ #include #include "tensor.h" #include "laerror.h" #include "qsort.h" #include "miscfunc.h" #include namespace LA { template int Tensor:: calcrank() { int r=0; for(int i=0; i *>(&shape))[i]; if(sh->number==0) laerror("empty index group"); r+=sh->number; } myrank=r; return r; } template LA_largeindex Tensor::calcsize() { groupsizes.resize(shape.size()); cumsizes.resize(shape.size()); LA_largeindex s=1; for(int i=0; i *>(&shape))[i]; if(sh->number==0) laerror("empty index group"); if(sh->range==0) return 0; cumsizes[i]=s; switch(sh->symmetry) { case 0: s *= groupsizes[i] = longpow(sh->range,sh->number); break; case 1: s *= groupsizes[i] = simplicial(sh->number,sh->range); break; case -1: s *= groupsizes[i] = simplicial(sh->number,sh->range-sh->number+1); break; default: laerror("illegal index group symmetry"); break; } } return s; } LA_largeindex subindex(int *sign, const INDEXGROUP &g, const NRVec &I) //index of one subgroup { #ifdef DEBUG if(I.size()<=0) laerror("empty index group in subindex"); if(g.number!=I.size()) laerror("mismatch in the number of indices in a group"); for(int i=0; i= g.offset+g.range) laerror("index out of range in tensor subindex"); #endif switch(I.size()) //a few special cases for efficiency { case 0: *sign=0; return 0; break; case 1: *sign=1; return I[0]-g.offset; break; case 2: { *sign=1; if(g.symmetry==0) return (I[1]-g.offset)*g.range+I[0]-g.offset; LA_index i0,i1; if(I[0]>I[1]) {i1=I[0]; i0=I[1]; if(g.symmetry<0) *sign = -1;} else {i1=I[1]; i0=I[0];} i0 -= g.offset; i1 -= g.offset; if(g.symmetry<0) { if(i0==i1) {*sign=0; return -1;} return i1*(i1-1)/2+i0; } else { return i1*(i1+1)/2+i0; } } break; default: //general case { *sign=1; if(g.symmetry==0) //rectangular case { LA_largeindex r=0; for(int i=I.size()-1; i>=0; --i) { r*= g.range; r+= I[i]-g.offset; } return r; } } //compressed storage case NRVec II(I); II.copyonwrite(); if(g.offset!=0) II -= g.offset; int parity=netsort(II.size(),&II[0]); if(g.symmetry<0 && (parity&1)) *sign= -1; if(g.symmetry<0) //antisymmetric { for(int i=0; i inverse_subindex(const INDEXGROUP &g, LA_largeindex s) { NRVec I(g.number); if(g.number==1) {I[0]=s+g.offset; return I;} switch(g.symmetry) { case 0: for(int i=0; i0; --i) { I[i-1] = inverse_simplicial(i,s); s -= simplicial(i,I[i-1]); } break; case -1: for(int i=g.number-1; i>=0; --i) { I[i] = i + inverse_simplicial(i+1,s); s -= simplicial(i+1,I[i]-i); } break; default: laerror("illegal index symmetry"); } if(g.offset!=0) I += g.offset; return I; } template SUPERINDEX Tensor::inverse_index(LA_largeindex s) const { SUPERINDEX I(shape.size()); for(int g=shape.size()-1; g>=0; --g) { LA_largeindex groupindex; if(g>0) { groupindex = s/cumsizes[g]; s %= cumsizes[g]; } else groupindex=s; I[g] = inverse_subindex(shape[g],groupindex); } return I; } template LA_largeindex Tensor::index(int *sign, const SUPERINDEX &I) const { //check index structure and ranges #ifdef DEBUG if(I.size()!=shape.size()) laerror("mismatch in the number of tensor index groups"); for(int i=0; i= shape[i].offset+shape[i].range) { std::cerr<<"error in index group no. "< LA_largeindex Tensor::index(int *sign, const FLATINDEX &I) const { #ifdef DEBUG if(rank()!=I.size()) laerror("tensor rank mismatch in index"); #endif LA_largeindex r=0; *sign=1; int gstart=0; for(int g=0; g subI = I.subvector(gstart,gend); gstart=gend+1; LA_largeindex groupindex = subindex(&gsign,shape[g],subI); //std::cout <<"FLATINDEX TEST group "< LA_largeindex Tensor::vindex(int *sign, LA_index i1, va_list args) const { NRVec I(rank()); I[0]=i1; for(int i=1; i void Tensor::put(int fd) const { shape.put(fd,true); groupsizes.put(fd,true); cumsizes.put(fd,true); data.put(fd,true); } template void Tensor::get(int fd) { shape.get(fd,true); myrank=calcrank(); //is not stored but recomputed groupsizes.put(fd,true); cumsizes.get(fd,true); data.get(fd,true); } template Tensor::Tensor(const NRVec &x) : data(x) { myrank=1; shape.resize(1); shape[0].number=1; shape[0].symmetry=0; #ifndef LA_TENSOR_ZERO_OFFSET shape[0].offset=0; #endif shape[0].range=x.size(); calcsize(); } template Tensor::Tensor(const NRMat &x) : data(&x(0,0),x.nrows()*x.ncols()) { myrank=2; if(x.nrows()==x.ncols()) { shape.resize(1); shape[0].number=2; shape[0].symmetry=0; #ifndef LA_TENSOR_ZERO_OFFSET shape[0].offset=0; #endif shape[0].range=x.nrows(); } else { shape.resize(2); shape[0].number=1; shape[1].number=1; shape[0].symmetry=0; shape[1].symmetry=0; #ifndef LA_TENSOR_ZERO_OFFSET shape[0].offset=0; shape[1].offset=0; #endif shape[0].range=x.ncols(); shape[1].range=x.nrows(); } calcsize(); } template Tensor::Tensor(const NRSMat &x) : data(NRVec(x)) { myrank=2; shape.resize(1); shape[0].number=2; shape[0].symmetry=1; #ifndef LA_TENSOR_ZERO_OFFSET shape[0].offset=0; #endif shape[0].range=x.nrows(); calcsize(); } template void loopingroups(Tensor &t, int ngroup, int igroup, T **p, SUPERINDEX &I, void (*callback)(const SUPERINDEX &, T *)) { LA_index istart,iend; const indexgroup *sh = &(* const_cast *>(&t.shape))[ngroup]; switch(sh->symmetry) { case 0: istart= sh->offset; iend= sh->offset+sh->range-1; break; case 1: istart= sh->offset; if(igroup==sh->number-1) iend= sh->offset+sh->range-1; else iend = I[ngroup][igroup+1]; break; case -1: istart= sh->offset + igroup; if(igroup==sh->number-1) iend= sh->offset+sh->range-1; else iend = I[ngroup][igroup+1]-1; break; } for(LA_index i = istart; i<=iend; ++i) { I[ngroup][igroup]=i; if(ngroup==0 && igroup==0) { int sign; //std::cout <<"TEST "< *>(&t.shape))[newngroup]; newigroup=sh2->number-1; } loopingroups(t,newngroup,newigroup,p,I,callback); } } } template void Tensor::loopover(void (*callback)(const SUPERINDEX &, T *)) { SUPERINDEX I(shape.size()); for(int i=0; i *>(&shape))[i]; I[i].resize(sh->number); I[i] = sh->offset; } T *pp=&data[0]; int ss=shape.size()-1; const indexgroup *sh = &(* const_cast *>(&shape))[ss]; loopingroups(*this,ss,sh->number-1,&pp,I,callback); } static std::ostream *sout; template static void outputcallback(const SUPERINDEX &I, T *v) { //print indices flat for(int i=0; i>(std::istream &s, INDEXGROUP &x) { s>>x.number>>x.symmetry; #ifndef LA_TENSOR_ZERO_OFFSET s>>x.offset; #endif s>>x.range; return s; } template std::ostream & operator<<(std::ostream &s, const Tensor &x) { s< *>(&x)->loopover(&outputcallback); return s; } template std::istream & operator>>(std::istream &s, Tensor &x) { s>>x.shape; x.data.resize(x.calcsize()); x.calcrank(); FLATINDEX I(x.rank()); for(LA_largeindex i=0; i>I[j]; T val; s>>val; x.lhs(I) = val; } return s; } template void loopovergroups(Tensor &t, int ngroup, T **p, GROUPINDEX &I, void (*callback)(const GROUPINDEX &, T *)) { for(LA_largeindex i = 0; i void Tensor::grouploopover(void (*callback)(const GROUPINDEX &, T *)) { GROUPINDEX I(shape.size()); T *pp=&data[0]; loopovergroups(*this,shape.size()-1,&pp,I,callback); } const NRPerm *help_p; template Tensor *help_t; template static void permutecallback(const GROUPINDEX &I, T *v) { LA_largeindex target=0; for(int i=0; i< help_t->shape.size(); ++i) { target += I[(*help_p)[i+1]-1] * help_t->cumsizes[i]; } help_t->data[target] = *v; } template Tensor Tensor::permute_index_groups(const NRPerm &p) const { NRVec newshape=shape.permuted(p); Tensor r(newshape); //prepare statics for the callback help_p = &p; help_t = &r; //now rearrange the data const_cast *>(this)->grouploopover(permutecallback); return r; } template class Tensor; template class Tensor >; template std::ostream & operator<<(std::ostream &s, const Tensor &x); template std::ostream & operator<<(std::ostream &s, const Tensor > &x); template std::istream & operator>>(std::istream &s, Tensor &x); template std::istream & operator>>(std::istream &s, Tensor > &x); }//namespace