// // LAPACK++ 1.1 Linear Algebra Package 1.1 // University of Tennessee, Knoxvilee, TN. // Oak Ridge National Laboratory, Oak Ridge, TN. // Authors: J. J. Dongarra, E. Greaser, R. Pozo, D. Walker // (C) 1992-1996 All Rights Reserved // // NOTICE // // Permission to use, copy, modify, and distribute this software and // its documentation for any purpose and without fee is hereby granted // provided that the above copyright notice appear in all copies and // that both the copyright notice and this permission notice appear in // supporting documentation. // // Neither the Institutions (University of Tennessee, and Oak Ridge National // Laboratory) nor the Authors make any representations about the suitability // of this software for any purpose. This software is provided ``as is'' // without express or implied warranty. // // LAPACK++ was funded in part by the U.S. Department of Energy, the // National Science Foundation and the State of Tennessee. #ifdef HAVE_CONFIG_H # include #endif #include "arch.h" #include "lafnames.h" #include LA_UNIT_UPPER_TRIANG_MAT_DOUBLE_H DLLIMPORT double LaUnitUpperTriangMatDouble::outofbounds_= 0; // set outofbounds_. DLLIMPORT int LaUnitUpperTriangMatDouble::debug_= 0; // turn off debug flag. DLLIMPORT int* LaUnitUpperTriangMatDouble::info_= new int; // turn off info print flag. double& LaUnitUpperTriangMatDouble::operator()(int i, int j) { #ifdef UNIT_UPPER_INDEX_CHK if (j<=i) { std::cout << "Warning, index to Upper Triular matrix out of range!\n"; std::cout << " i = " << i << " " <<" j = " << j << std::endl; } #endif if ((j==0)&&(i==0)) // this special case allows us to pass unit matrices return data_(0,0); // by accessing the first element of the matrix else if (j<=i) // which under normal circumstances would return return outofbounds_; //outofbounds_. else return data_(i,j); } double& LaUnitUpperTriangMatDouble::operator()(int i, int j) const { #ifdef UNIT_UPPER_INDEX_CHK if (j<=i) { std::cout << "Warning, index to Upper Triular matrix out of range!\n"; std::cout << " i = " << i << " " <<" j = " << j << std::endl; } #endif if ((j==0)&&(i==0)) // this special case allows us to pass unit matrices return data_(0,0); // by accessing the first element of the matrix else if (j<=i) // which under normal circumstances would return return outofbounds_; //outofbounds_. else return data_(i,j); } LaUnitUpperTriangMatDouble& LaUnitUpperTriangMatDouble::copy(LaUnitUpperTriangMatDouble &ob) { if (debug()) { std::cout << " ob: " << ob.info() << std::endl; } int M = ob.size(0); int N = ob.size(1); int i,j; resize(ob); for (i=0; ii) (*this)(i,j) = ob(i,j); if (debug()) { std::cout << " *this: " << this->info() << std::endl; } return *this; } LaUnitUpperTriangMatDouble& LaUnitUpperTriangMatDouble::operator=(const double &s) { int M = (*this).size(0); int N = (*this).size(1); int i,j; for (j=0; ji) (*this)(i,j) = s; return *this; } std::ostream &operator<<(std::ostream &s, const LaUnitUpperTriangMatDouble &ob) { if (*(ob.info_)) // print out only matrix info, not actual values { *(ob.info_) = 0; // reset the flag s << "(" << ob.size(0) << "x" << ob.size(1) << ") " ; s << "Indices: " << ob.index(0) << " " << ob.index(1); s << " #ref: " << ob.ref_count() ; s << " sa:" << ob.shallow(); } else { int M = ob.size(0); int N = ob.size(1); int i,j; for (i=0; ii) s << ob(i,j) << " "; } s << std::endl; } } return s; }