Mercurial > octave-nkf
view liboctave/MSparse.cc @ 14138:72c96de7a403 stable
maint: update copyright notices for 2012
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Mon, 02 Jan 2012 14:25:41 -0500 |
| parents | 89789bc755a1 |
| children | 460a3c6d8bf1 |
line wrap: on
line source
/* Copyright (C) 2004-2012 David Bateman Copyright (C) 1998-2004 Andy Adler This file is part of Octave. Octave 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. Octave 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 Octave; see the file COPYING. If not, see <http://www.gnu.org/licenses/>. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include <functional> #include "quit.h" #include "lo-error.h" #include "MArray.h" #include "Array-util.h" #include "MSparse.h" #include "MSparse-defs.h" // sparse array with math ops. // Element by element MSparse by MSparse ops. template <class T, class OP> MSparse<T>& plus_or_minus (MSparse<T>& a, const MSparse<T>& b, OP op, const char* op_name) { MSparse<T> r; octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (a_nr != b_nr || a_nc != b_nc) gripe_nonconformant (op_name , a_nr, a_nc, b_nr, b_nc); else { r = MSparse<T> (a_nr, a_nc, (a.nnz () + b.nnz ())); octave_idx_type jx = 0; for (octave_idx_type i = 0 ; i < a_nc ; i++) { octave_idx_type ja = a.cidx(i); octave_idx_type ja_max = a.cidx(i+1); bool ja_lt_max= ja < ja_max; octave_idx_type jb = b.cidx(i); octave_idx_type jb_max = b.cidx(i+1); bool jb_lt_max = jb < jb_max; while (ja_lt_max || jb_lt_max ) { octave_quit (); if ((! jb_lt_max) || (ja_lt_max && (a.ridx(ja) < b.ridx(jb)))) { r.ridx(jx) = a.ridx(ja); r.data(jx) = op (a.data(ja), 0.); jx++; ja++; ja_lt_max= ja < ja_max; } else if (( !ja_lt_max ) || (jb_lt_max && (b.ridx(jb) < a.ridx(ja)) ) ) { r.ridx(jx) = b.ridx(jb); r.data(jx) = op (0., b.data(jb)); jx++; jb++; jb_lt_max= jb < jb_max; } else { if (op (a.data(ja), b.data(jb)) != 0.) { r.data(jx) = op (a.data(ja), b.data(jb)); r.ridx(jx) = a.ridx(ja); jx++; } ja++; ja_lt_max= ja < ja_max; jb++; jb_lt_max= jb < jb_max; } } r.cidx(i+1) = jx; } a = r.maybe_compress (); } return a; } template <typename T> MSparse<T>& operator += (MSparse<T>& a, const MSparse<T>& b) { return plus_or_minus (a, b, std::plus<T> (), "operator +="); } template <typename T> MSparse<T>& operator -= (MSparse<T>& a, const MSparse<T>& b) { return plus_or_minus (a, b, std::minus<T> (), "operator -="); } // Element by element MSparse by scalar ops. template <class T, class OP> MArray<T> plus_or_minus (const MSparse<T>& a, const T& s, OP op) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); MArray<T> r (dim_vector (nr, nc), op (0.0, s)); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = a.cidx(j); i < a.cidx(j+1); i++) r.elem (a.ridx (i), j) = op (a.data (i), s); return r; } template <typename T> MArray<T> operator + (const MSparse<T>& a, const T& s) { return plus_or_minus (a, s, std::plus<T> ()); } template <typename T> MArray<T> operator - (const MSparse<T>& a, const T& s) { return plus_or_minus (a, s, std::minus<T> ()); } template <class T, class OP> MSparse<T> times_or_divide (const MSparse<T>& a, const T& s, OP op) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); octave_idx_type nz = a.nnz (); MSparse<T> r (nr, nc, nz); for (octave_idx_type i = 0; i < nz; i++) { r.data(i) = op (a.data(i), s); r.ridx(i) = a.ridx(i); } for (octave_idx_type i = 0; i < nc + 1; i++) r.cidx(i) = a.cidx(i); r.maybe_compress (true); return r; } template <typename T> MSparse<T> operator * (const MSparse<T>& a, const T& s) { return times_or_divide (a, s, std::multiplies<T> ()); } template <typename T> MSparse<T> operator / (const MSparse<T>& a, const T& s) { return times_or_divide (a, s, std::divides<T> ()); } // Element by element scalar by MSparse ops. template <class T, class OP> MArray<T> plus_or_minus (const T& s, const MSparse<T>& a, OP op) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); MArray<T> r (dim_vector (nr, nc), op (s, 0.0)); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = a.cidx(j); i < a.cidx(j+1); i++) r.elem (a.ridx (i), j) = op (s, a.data (i)); return r; } template <typename T> MArray<T> operator + (const T& s, const MSparse<T>& a) { return plus_or_minus (s, a, std::plus<T> ()); } template <typename T> MArray<T> operator - (const T& s, const MSparse<T>& a) { return plus_or_minus (s, a, std::minus<T> ()); } template <class T, class OP> MSparse<T> times_or_divides (const T& s, const MSparse<T>& a, OP op) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); octave_idx_type nz = a.nnz (); MSparse<T> r (nr, nc, nz); for (octave_idx_type i = 0; i < nz; i++) { r.data(i) = op (s, a.data(i)); r.ridx(i) = a.ridx(i); } for (octave_idx_type i = 0; i < nc + 1; i++) r.cidx(i) = a.cidx(i); r.maybe_compress (true); return r; } template <class T> MSparse<T> operator * (const T& s, const MSparse<T>& a) { return times_or_divides (s, a, std::multiplies<T> ()); } template <class T> MSparse<T> operator / (const T& s, const MSparse<T>& a) { return times_or_divides (s, a, std::divides<T> ()); } // Element by element MSparse by MSparse ops. template <class T, class OP> MSparse<T> plus_or_minus (const MSparse<T>& a, const MSparse<T>& b, OP op, const char* op_name, bool negate) { MSparse<T> r; octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (a_nr == 1 && a_nc == 1) { if (a.elem(0,0) == 0.) if (negate) r = -MSparse<T> (b); else r = MSparse<T> (b); else { r = MSparse<T> (b_nr, b_nc, op (a.data(0), 0.)); for (octave_idx_type j = 0 ; j < b_nc ; j++) { octave_quit (); octave_idx_type idxj = j * b_nr; for (octave_idx_type i = b.cidx(j) ; i < b.cidx(j+1) ; i++) { octave_quit (); r.data(idxj + b.ridx(i)) = op (a.data(0), b.data(i)); } } r.maybe_compress (); } } else if (b_nr == 1 && b_nc == 1) { if (b.elem(0,0) == 0.) r = MSparse<T> (a); else { r = MSparse<T> (a_nr, a_nc, op (0.0, b.data(0))); for (octave_idx_type j = 0 ; j < a_nc ; j++) { octave_quit (); octave_idx_type idxj = j * a_nr; for (octave_idx_type i = a.cidx(j) ; i < a.cidx(j+1) ; i++) { octave_quit (); r.data(idxj + a.ridx(i)) = op (a.data(i), b.data(0)); } } r.maybe_compress (); } } else if (a_nr != b_nr || a_nc != b_nc) gripe_nonconformant (op_name, a_nr, a_nc, b_nr, b_nc); else { r = MSparse<T> (a_nr, a_nc, (a.nnz () + b.nnz ())); octave_idx_type jx = 0; r.cidx (0) = 0; for (octave_idx_type i = 0 ; i < a_nc ; i++) { octave_idx_type ja = a.cidx(i); octave_idx_type ja_max = a.cidx(i+1); bool ja_lt_max= ja < ja_max; octave_idx_type jb = b.cidx(i); octave_idx_type jb_max = b.cidx(i+1); bool jb_lt_max = jb < jb_max; while (ja_lt_max || jb_lt_max ) { octave_quit (); if ((! jb_lt_max) || (ja_lt_max && (a.ridx(ja) < b.ridx(jb)))) { r.ridx(jx) = a.ridx(ja); r.data(jx) = op (a.data(ja), 0.); jx++; ja++; ja_lt_max= ja < ja_max; } else if (( !ja_lt_max ) || (jb_lt_max && (b.ridx(jb) < a.ridx(ja)) ) ) { r.ridx(jx) = b.ridx(jb); r.data(jx) = op (0., b.data(jb)); jx++; jb++; jb_lt_max= jb < jb_max; } else { if (op (a.data(ja), b.data(jb)) != 0.) { r.data(jx) = op (a.data(ja), b.data(jb)); r.ridx(jx) = a.ridx(ja); jx++; } ja++; ja_lt_max= ja < ja_max; jb++; jb_lt_max= jb < jb_max; } } r.cidx(i+1) = jx; } r.maybe_compress (); } return r; } template <class T> MSparse<T> operator+ (const MSparse<T>& a, const MSparse<T>& b) { return plus_or_minus (a, b, std::plus<T> (), "operator +", false); } template <class T> MSparse<T> operator- (const MSparse<T>& a, const MSparse<T>& b) { return plus_or_minus (a, b, std::minus<T> (), "operator -", true); } template <class T> MSparse<T> product (const MSparse<T>& a, const MSparse<T>& b) { MSparse<T> r; octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (a_nr == 1 && a_nc == 1) { if (a.elem(0,0) == 0.) r = MSparse<T> (b_nr, b_nc); else { r = MSparse<T> (b); octave_idx_type b_nnz = b.nnz(); for (octave_idx_type i = 0 ; i < b_nnz ; i++) { octave_quit (); r.data (i) = a.data(0) * r.data(i); } r.maybe_compress (); } } else if (b_nr == 1 && b_nc == 1) { if (b.elem(0,0) == 0.) r = MSparse<T> (a_nr, a_nc); else { r = MSparse<T> (a); octave_idx_type a_nnz = a.nnz(); for (octave_idx_type i = 0 ; i < a_nnz ; i++) { octave_quit (); r.data (i) = r.data(i) * b.data(0); } r.maybe_compress (); } } else if (a_nr != b_nr || a_nc != b_nc) gripe_nonconformant ("product", a_nr, a_nc, b_nr, b_nc); else { r = MSparse<T> (a_nr, a_nc, (a.nnz () > b.nnz () ? a.nnz () : b.nnz ())); octave_idx_type jx = 0; r.cidx (0) = 0; for (octave_idx_type i = 0 ; i < a_nc ; i++) { octave_idx_type ja = a.cidx(i); octave_idx_type ja_max = a.cidx(i+1); bool ja_lt_max= ja < ja_max; octave_idx_type jb = b.cidx(i); octave_idx_type jb_max = b.cidx(i+1); bool jb_lt_max = jb < jb_max; while (ja_lt_max || jb_lt_max ) { octave_quit (); if ((! jb_lt_max) || (ja_lt_max && (a.ridx(ja) < b.ridx(jb)))) { ja++; ja_lt_max= ja < ja_max; } else if (( !ja_lt_max ) || (jb_lt_max && (b.ridx(jb) < a.ridx(ja)) ) ) { jb++; jb_lt_max= jb < jb_max; } else { if ((a.data(ja) * b.data(jb)) != 0.) { r.data(jx) = a.data(ja) * b.data(jb); r.ridx(jx) = a.ridx(ja); jx++; } ja++; ja_lt_max= ja < ja_max; jb++; jb_lt_max= jb < jb_max; } } r.cidx(i+1) = jx; } r.maybe_compress (); } return r; } template <class T> MSparse<T> quotient (const MSparse<T>& a, const MSparse<T>& b) { MSparse<T> r; T Zero = T (); octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (a_nr == 1 && a_nc == 1) { T val = a.elem (0,0); T fill = val / T(); if (fill == T()) { octave_idx_type b_nnz = b.nnz(); r = MSparse<T> (b); for (octave_idx_type i = 0 ; i < b_nnz ; i++) r.data (i) = val / r.data(i); r.maybe_compress (); } else { r = MSparse<T> (b_nr, b_nc, fill); for (octave_idx_type j = 0 ; j < b_nc ; j++) { octave_quit (); octave_idx_type idxj = j * b_nr; for (octave_idx_type i = b.cidx(j) ; i < b.cidx(j+1) ; i++) { octave_quit (); r.data(idxj + b.ridx(i)) = val / b.data(i); } } r.maybe_compress (); } } else if (b_nr == 1 && b_nc == 1) { T val = b.elem (0,0); T fill = T() / val; if (fill == T()) { octave_idx_type a_nnz = a.nnz(); r = MSparse<T> (a); for (octave_idx_type i = 0 ; i < a_nnz ; i++) r.data (i) = r.data(i) / val; r.maybe_compress (); } else { r = MSparse<T> (a_nr, a_nc, fill); for (octave_idx_type j = 0 ; j < a_nc ; j++) { octave_quit (); octave_idx_type idxj = j * a_nr; for (octave_idx_type i = a.cidx(j) ; i < a.cidx(j+1) ; i++) { octave_quit (); r.data(idxj + a.ridx(i)) = a.data(i) / val; } } r.maybe_compress (); } } else if (a_nr != b_nr || a_nc != b_nc) gripe_nonconformant ("quotient", a_nr, a_nc, b_nr, b_nc); else { r = MSparse<T>( a_nr, a_nc, (Zero / Zero)); for (octave_idx_type i = 0 ; i < a_nc ; i++) { octave_idx_type ja = a.cidx(i); octave_idx_type ja_max = a.cidx(i+1); bool ja_lt_max= ja < ja_max; octave_idx_type jb = b.cidx(i); octave_idx_type jb_max = b.cidx(i+1); bool jb_lt_max = jb < jb_max; while (ja_lt_max || jb_lt_max ) { octave_quit (); if ((! jb_lt_max) || (ja_lt_max && (a.ridx(ja) < b.ridx(jb)))) { r.elem (a.ridx(ja),i) = a.data(ja) / Zero; ja++; ja_lt_max= ja < ja_max; } else if (( !ja_lt_max ) || (jb_lt_max && (b.ridx(jb) < a.ridx(ja)) ) ) { r.elem (b.ridx(jb),i) = Zero / b.data(jb); jb++; jb_lt_max= jb < jb_max; } else { r.elem (a.ridx(ja),i) = a.data(ja) / b.data(jb); ja++; ja_lt_max= ja < ja_max; jb++; jb_lt_max= jb < jb_max; } } } r.maybe_compress (true); } return r; } // Unary MSparse ops. template <class T> MSparse<T> operator + (const MSparse<T>& a) { return a; } template <class T> MSparse<T> operator - (const MSparse<T>& a) { MSparse<T> retval (a); octave_idx_type nz = a.nnz (); for (octave_idx_type i = 0; i < nz; i++) retval.data(i) = - retval.data(i); return retval; }