Mercurial > octave-nkf
view src/minmax.cc @ 2847:8b262e771614
[project @ 1997-03-27 16:18:26 by jwe]
| author | jwe |
|---|---|
| date | Thu, 27 Mar 1997 16:19:58 +0000 |
| parents | 9aeba8e006a4 |
| children |
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/* Copyright (C) 1996, 1997 John W. Eaton 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 2, 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, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include "lo-ieee.h" #include "oct-math.h" #include "defun-dld.h" #include "error.h" #include "gripes.h" #include "help.h" #include "oct-obj.h" #ifndef MAX #define MAX(a,b) ((a) > (b) ? (a) : (b)) #endif #ifndef MIN #define MIN(a,b) ((a) < (b) ? (a) : (b)) #endif // XXX FIXME XXX -- it would be nice to share code among the min/max // functions below. static Matrix min (double d, const Matrix& m) { int nr = m.rows (); int nc = m.columns (); Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double m_elem = m (i, j); result (i, j) = MIN (d, m_elem); } return result; } static Matrix min (const Matrix& m, double d) { int nr = m.rows (); int nc = m.columns (); Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double m_elem = m (i, j); result (i, j) = MIN (m_elem, d); } return result; } static ComplexMatrix min (const Complex& c, const ComplexMatrix& m) { int nr = m.rows (); int nc = m.columns (); ComplexMatrix result (nr, nc); double abs_c = abs (c); for (int j = 0; j < nc; j++) { for (int i = 0; i < nr; i++) { double abs_m_elem = abs (m (i, j)); if (abs_c < abs_m_elem) result (i, j) = c; else result (i, j) = m (i, j); } } return result; } static ComplexMatrix min (const ComplexMatrix& m, const Complex& c) { int nr = m.rows (); int nc = m.columns (); ComplexMatrix result (nr, nc); double abs_c = abs (c); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double abs_m_elem = abs (m (i, j)); if (abs_m_elem < abs_c) result (i, j) = m (i, j); else result (i, j) = c; } return result; } static Matrix min (const Matrix& a, const Matrix& b) { int nr = a.rows (); int nc = a.columns (); if (nr != b.rows () || nc != b.columns ()) { error ("two-arg min expecting args of same size"); return Matrix (); } Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double a_elem = a (i, j); double b_elem = b (i, j); result (i, j) = MIN (a_elem, b_elem); } return result; } static ComplexMatrix min (const ComplexMatrix& a, const ComplexMatrix& b) { int nr = a.rows (); int nc = a.columns (); if (nr != b.rows () || nc != b.columns ()) { error ("two-arg min expecting args of same size"); return ComplexMatrix (); } ComplexMatrix result (nr, nc); for (int j = 0; j < nc; j++) { int columns_are_real_only = 1; for (int i = 0; i < nr; i++) if (imag (a (i, j)) != 0.0 && imag (b (i, j)) != 0.0) { columns_are_real_only = 0; break; } if (columns_are_real_only) { for (int i = 0; i < nr; i++) { double a_elem = real (a (i, j)); double b_elem = real (b (i, j)); if (a_elem < b_elem) result (i, j) = a_elem; else result (i, j) = b_elem; } } else { for (int i = 0; i < nr; i++) { double abs_a_elem = abs (a (i, j)); double abs_b_elem = abs (b (i, j)); if (abs_a_elem < abs_b_elem) result (i, j) = a (i, j); else result (i, j) = b (i, j); } } } return result; } static Matrix max (double d, const Matrix& m) { int nr = m.rows (); int nc = m.columns (); Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double m_elem = m (i, j); result (i, j) = MAX (d, m_elem); } return result; } static Matrix max (const Matrix& m, double d) { int nr = m.rows (); int nc = m.columns (); Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double m_elem = m (i, j); result (i, j) = MAX (m_elem, d); } return result; } static ComplexMatrix max (const Complex& c, const ComplexMatrix& m) { int nr = m.rows (); int nc = m.columns (); ComplexMatrix result (nr, nc); double abs_c = abs (c); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double abs_m_elem = abs (m (i, j)); if (abs_c > abs_m_elem) result (i, j) = c; else result (i, j) = m (i, j); } return result; } static ComplexMatrix max (const ComplexMatrix& m, const Complex& c) { int nr = m.rows (); int nc = m.columns (); ComplexMatrix result (nr, nc); double abs_c = abs (c); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double abs_m_elem = abs (m (i, j)); if (abs_m_elem > abs_c) result (i, j) = m (i, j); else result (i, j) = c; } return result; } static Matrix max (const Matrix& a, const Matrix& b) { int nr = a.rows (); int nc = a.columns (); if (nr != b.rows () || nc != b.columns ()) { error ("two-arg max expecting args of same size"); return Matrix (); } Matrix result (nr, nc); for (int j = 0; j < nc; j++) for (int i = 0; i < nr; i++) { double a_elem = a (i, j); double b_elem = b (i, j); result (i, j) = MAX (a_elem, b_elem); } return result; } static ComplexMatrix max (const ComplexMatrix& a, const ComplexMatrix& b) { int nr = a.rows (); int nc = a.columns (); if (nr != b.rows () || nc != b.columns ()) { error ("two-arg max expecting args of same size"); return ComplexMatrix (); } ComplexMatrix result (nr, nc); for (int j = 0; j < nc; j++) { int columns_are_real_only = 1; for (int i = 0; i < nr; i++) if (imag (a (i, j)) != 0.0 && imag (b (i, j)) != 0.0) { columns_are_real_only = 0; break; } if (columns_are_real_only) { for (int i = 0; i < nr; i++) { double a_elem = real (a (i, j)); double b_elem = real (b (i, j)); if (a_elem > b_elem) result (i, j) = a_elem; else result (i, j) = b_elem; } } else { for (int i = 0; i < nr; i++) { double abs_a_elem = abs (a (i, j)); double abs_b_elem = abs (b (i, j)); if (abs_a_elem > abs_b_elem) result (i, j) = a (i, j); else result (i, j) = b (i, j); } } } return result; } DEFUN_DLD (min, args, nargout, "min (X): minimum value(s) of a vector (matrix)") { octave_value_list retval; int nargin = args.length (); if (nargin < 1 || nargin > 2 || nargout > 2) { print_usage ("min"); return retval; } octave_value arg1; octave_value arg2; switch (nargin) { case 2: arg2 = args(1); // Fall through... case 1: arg1 = args(0); break; default: panic_impossible (); break; } if (nargin == 1 && (nargout == 1 || nargout == 0)) { if (arg1.is_real_type ()) { Matrix m = arg1.matrix_value (); if (! error_state) { if (m.rows () == 1) retval(0) = m.row_min (); else retval(0) = octave_value (m.column_min (), 0); } } else if (arg1.is_complex_type ()) { ComplexMatrix m = arg1.complex_matrix_value (); if (! error_state) { if (m.rows () == 1) retval(0) = m.row_min (); else retval(0) = octave_value (m.column_min (), 0); } } else gripe_wrong_type_arg ("min", arg1); } else if (nargin == 1 && nargout == 2) { Array<int> index; if (arg1.is_real_type ()) { Matrix m = arg1.matrix_value (); if (! error_state) { retval.resize (2); if (m.rows () == 1) retval(0) = m.row_min (index); else retval(0) = octave_value (m.column_min (index), 0); } } else if (arg1.is_complex_type ()) { ComplexMatrix m = arg1.complex_matrix_value (); if (! error_state) { retval.resize (2); if (m.rows () == 1) retval(0) = m.row_min (index); else retval(0) = octave_value (m.column_min (index), 0); } } else gripe_wrong_type_arg ("min", arg1); int len = index.length (); if (len > 0) { RowVector idx (len); for (int i = 0; i < len; i++) { int tmp = index.elem (i) + 1; idx.elem (i) = (tmp <= 0) ? octave_NaN : static_cast<double> (tmp); } retval(1) = octave_value (idx, 0); } } else if (nargin == 2) { int arg1_is_scalar = arg1.is_scalar_type (); int arg2_is_scalar = arg2.is_scalar_type (); int arg1_is_complex = arg1.is_complex_type (); int arg2_is_complex = arg2.is_complex_type (); if (arg1_is_scalar) { if (arg1_is_complex || arg2_is_complex) { Complex c1 = arg1.complex_value (); ComplexMatrix m2 = arg2.complex_matrix_value (); if (! error_state) { ComplexMatrix result = min (c1, m2); if (! error_state) retval(0) = result; } } else { double d1 = arg1.double_value (); Matrix m2 = arg2.matrix_value (); if (! error_state) { Matrix result = min (d1, m2); if (! error_state) retval(0) = result; } } } else if (arg2_is_scalar) { if (arg1_is_complex || arg2_is_complex) { ComplexMatrix m1 = arg1.complex_matrix_value (); if (! error_state) { Complex c2 = arg2.complex_value (); ComplexMatrix result = min (m1, c2); if (! error_state) retval(0) = result; } } else { Matrix m1 = arg1.matrix_value (); if (! error_state) { double d2 = arg2.double_value (); Matrix result = min (m1, d2); if (! error_state) retval(0) = result; } } } else { if (arg1_is_complex || arg2_is_complex) { ComplexMatrix m1 = arg1.complex_matrix_value (); if (! error_state) { ComplexMatrix m2 = arg2.complex_matrix_value (); if (! error_state) { ComplexMatrix result = min (m1, m2); if (! error_state) retval(0) = result; } } } else { Matrix m1 = arg1.matrix_value (); if (! error_state) { Matrix m2 = arg2.matrix_value (); if (! error_state) { Matrix result = min (m1, m2); if (! error_state) retval(0) = result; } } } } } else panic_impossible (); return retval; } DEFUN_DLD (max, args, nargout, "max (X): maximum value(s) of a vector (matrix)") { octave_value_list retval; int nargin = args.length (); if (nargin < 1 || nargin > 2 || nargout > 2) { print_usage ("max"); return retval; } octave_value arg1; octave_value arg2; switch (nargin) { case 2: arg2 = args(1); // Fall through... case 1: arg1 = args(0); break; default: panic_impossible (); break; } if (nargin == 1 && (nargout == 1 || nargout == 0)) { if (arg1.is_real_type ()) { Matrix m = arg1.matrix_value (); if (! error_state) { if (m.rows () == 1) retval(0) = m.row_max (); else retval(0) = octave_value (m.column_max (), 0); } } else if (arg1.is_complex_type ()) { ComplexMatrix m = arg1.complex_matrix_value (); if (! error_state) { if (m.rows () == 1) retval(0) = m.row_max (); else retval(0) = octave_value (m.column_max (), 0); } } else gripe_wrong_type_arg ("max", arg1); } else if (nargin == 1 && nargout == 2) { Array<int> index; if (arg1.is_real_type ()) { Matrix m = arg1.matrix_value (); if (! error_state) { retval.resize (2); if (m.rows () == 1) retval(0) = m.row_max (index); else retval(0) = octave_value (m.column_max (index), 0); } } else if (arg1.is_complex_type ()) { ComplexMatrix m = arg1.complex_matrix_value (); if (! error_state) { retval.resize (2); if (m.rows () == 1) retval(0) = m.row_max (index); else retval(0) = octave_value (m.column_max (index), 0); } } else gripe_wrong_type_arg ("max", arg1); int len = index.length (); if (len > 0) { RowVector idx (len); for (int i = 0; i < len; i++) { int tmp = index.elem (i) + 1; idx.elem (i) = (tmp <= 0) ? octave_NaN : static_cast<double> (tmp); } retval(1) = octave_value (idx, 0); } } else if (nargin == 2) { int arg1_is_scalar = arg1.is_scalar_type (); int arg2_is_scalar = arg2.is_scalar_type (); int arg1_is_complex = arg1.is_complex_type (); int arg2_is_complex = arg2.is_complex_type (); if (arg1_is_scalar) { if (arg1_is_complex || arg2_is_complex) { Complex c1 = arg1.complex_value (); ComplexMatrix m2 = arg2.complex_matrix_value (); if (! error_state) { ComplexMatrix result = max (c1, m2); if (! error_state) retval(0) = result; } } else { double d1 = arg1.double_value (); Matrix m2 = arg2.matrix_value (); if (! error_state) { Matrix result = max (d1, m2); if (! error_state) retval(0) = result; } } } else if (arg2_is_scalar) { if (arg1_is_complex || arg2_is_complex) { ComplexMatrix m1 = arg1.complex_matrix_value (); if (! error_state) { Complex c2 = arg2.complex_value (); ComplexMatrix result = max (m1, c2); if (! error_state) retval(0) = result; } } else { Matrix m1 = arg1.matrix_value (); if (! error_state) { double d2 = arg2.double_value (); Matrix result = max (m1, d2); if (! error_state) retval(0) = result; } } } else { if (arg1_is_complex || arg2_is_complex) { ComplexMatrix m1 = arg1.complex_matrix_value (); if (! error_state) { ComplexMatrix m2 = arg2.complex_matrix_value (); if (! error_state) { ComplexMatrix result = max (m1, m2); if (! error_state) retval(0) = result; } } } else { Matrix m1 = arg1.matrix_value (); if (! error_state) { Matrix m2 = arg2.matrix_value (); if (! error_state) { Matrix result = max (m1, m2); if (! error_state) retval(0) = result; } } } } } else panic_impossible (); return retval; } /* ;;; Local Variables: *** ;;; mode: C++ *** ;;; End: *** */